code
string | repo_name
string | path
string | language
string | license
string | size
int64 |
|---|---|---|---|---|---|
"""Read resources contained within a package."""
from ._common import (
as_file,
files,
Package,
)
from ._legacy import (
contents,
open_binary,
read_binary,
open_text,
read_text,
is_resource,
path,
Resource,
)
from .abc import ResourceReader
__all__ = [
'Package',
'Resource',
'ResourceReader',
'as_file',
'contents',
'files',
'is_resource',
'open_binary',
'open_text',
'path',
'read_binary',
'read_text',
]
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/importlib_resources/__init__.py
|
Python
|
mit
| 506 |
from contextlib import suppress
from io import TextIOWrapper
from . import abc
class SpecLoaderAdapter:
"""
Adapt a package spec to adapt the underlying loader.
"""
def __init__(self, spec, adapter=lambda spec: spec.loader):
self.spec = spec
self.loader = adapter(spec)
def __getattr__(self, name):
return getattr(self.spec, name)
class TraversableResourcesLoader:
"""
Adapt a loader to provide TraversableResources.
"""
def __init__(self, spec):
self.spec = spec
def get_resource_reader(self, name):
return CompatibilityFiles(self.spec)._native()
def _io_wrapper(file, mode='r', *args, **kwargs):
if mode == 'r':
return TextIOWrapper(file, *args, **kwargs)
elif mode == 'rb':
return file
raise ValueError(
"Invalid mode value '{}', only 'r' and 'rb' are supported".format(mode)
)
class CompatibilityFiles:
"""
Adapter for an existing or non-existent resource reader
to provide a compatibility .files().
"""
class SpecPath(abc.Traversable):
"""
Path tied to a module spec.
Can be read and exposes the resource reader children.
"""
def __init__(self, spec, reader):
self._spec = spec
self._reader = reader
def iterdir(self):
if not self._reader:
return iter(())
return iter(
CompatibilityFiles.ChildPath(self._reader, path)
for path in self._reader.contents()
)
def is_file(self):
return False
is_dir = is_file
def joinpath(self, other):
if not self._reader:
return CompatibilityFiles.OrphanPath(other)
return CompatibilityFiles.ChildPath(self._reader, other)
@property
def name(self):
return self._spec.name
def open(self, mode='r', *args, **kwargs):
return _io_wrapper(self._reader.open_resource(None), mode, *args, **kwargs)
class ChildPath(abc.Traversable):
"""
Path tied to a resource reader child.
Can be read but doesn't expose any meaningful children.
"""
def __init__(self, reader, name):
self._reader = reader
self._name = name
def iterdir(self):
return iter(())
def is_file(self):
return self._reader.is_resource(self.name)
def is_dir(self):
return not self.is_file()
def joinpath(self, other):
return CompatibilityFiles.OrphanPath(self.name, other)
@property
def name(self):
return self._name
def open(self, mode='r', *args, **kwargs):
return _io_wrapper(
self._reader.open_resource(self.name), mode, *args, **kwargs
)
class OrphanPath(abc.Traversable):
"""
Orphan path, not tied to a module spec or resource reader.
Can't be read and doesn't expose any meaningful children.
"""
def __init__(self, *path_parts):
if len(path_parts) < 1:
raise ValueError('Need at least one path part to construct a path')
self._path = path_parts
def iterdir(self):
return iter(())
def is_file(self):
return False
is_dir = is_file
def joinpath(self, other):
return CompatibilityFiles.OrphanPath(*self._path, other)
@property
def name(self):
return self._path[-1]
def open(self, mode='r', *args, **kwargs):
raise FileNotFoundError("Can't open orphan path")
def __init__(self, spec):
self.spec = spec
@property
def _reader(self):
with suppress(AttributeError):
return self.spec.loader.get_resource_reader(self.spec.name)
def _native(self):
"""
Return the native reader if it supports files().
"""
reader = self._reader
return reader if hasattr(reader, 'files') else self
def __getattr__(self, attr):
return getattr(self._reader, attr)
def files(self):
return CompatibilityFiles.SpecPath(self.spec, self._reader)
def wrap_spec(package):
"""
Construct a package spec with traversable compatibility
on the spec/loader/reader.
"""
return SpecLoaderAdapter(package.__spec__, TraversableResourcesLoader)
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/importlib_resources/_adapters.py
|
Python
|
mit
| 4,504 |
import os
import pathlib
import tempfile
import functools
import contextlib
import types
import importlib
from typing import Union, Optional
from .abc import ResourceReader, Traversable
from ._compat import wrap_spec
Package = Union[types.ModuleType, str]
def files(package):
# type: (Package) -> Traversable
"""
Get a Traversable resource from a package
"""
return from_package(get_package(package))
def get_resource_reader(package):
# type: (types.ModuleType) -> Optional[ResourceReader]
"""
Return the package's loader if it's a ResourceReader.
"""
# We can't use
# a issubclass() check here because apparently abc.'s __subclasscheck__()
# hook wants to create a weak reference to the object, but
# zipimport.zipimporter does not support weak references, resulting in a
# TypeError. That seems terrible.
spec = package.__spec__
reader = getattr(spec.loader, 'get_resource_reader', None) # type: ignore
if reader is None:
return None
return reader(spec.name) # type: ignore
def resolve(cand):
# type: (Package) -> types.ModuleType
return cand if isinstance(cand, types.ModuleType) else importlib.import_module(cand)
def get_package(package):
# type: (Package) -> types.ModuleType
"""Take a package name or module object and return the module.
Raise an exception if the resolved module is not a package.
"""
resolved = resolve(package)
if wrap_spec(resolved).submodule_search_locations is None:
raise TypeError(f'{package!r} is not a package')
return resolved
def from_package(package):
"""
Return a Traversable object for the given package.
"""
spec = wrap_spec(package)
reader = spec.loader.get_resource_reader(spec.name)
return reader.files()
@contextlib.contextmanager
def _tempfile(reader, suffix=''):
# Not using tempfile.NamedTemporaryFile as it leads to deeper 'try'
# blocks due to the need to close the temporary file to work on Windows
# properly.
fd, raw_path = tempfile.mkstemp(suffix=suffix)
try:
try:
os.write(fd, reader())
finally:
os.close(fd)
del reader
yield pathlib.Path(raw_path)
finally:
try:
os.remove(raw_path)
except FileNotFoundError:
pass
@functools.singledispatch
def as_file(path):
"""
Given a Traversable object, return that object as a
path on the local file system in a context manager.
"""
return _tempfile(path.read_bytes, suffix=path.name)
@as_file.register(pathlib.Path)
@contextlib.contextmanager
def _(path):
"""
Degenerate behavior for pathlib.Path objects.
"""
yield path
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/importlib_resources/_common.py
|
Python
|
mit
| 2,741 |
# flake8: noqa
import abc
import sys
import pathlib
from contextlib import suppress
if sys.version_info >= (3, 10):
from zipfile import Path as ZipPath # type: ignore
else:
from ..zipp import Path as ZipPath # type: ignore
try:
from typing import runtime_checkable # type: ignore
except ImportError:
def runtime_checkable(cls): # type: ignore
return cls
try:
from typing import Protocol # type: ignore
except ImportError:
Protocol = abc.ABC # type: ignore
class TraversableResourcesLoader:
"""
Adapt loaders to provide TraversableResources and other
compatibility.
Used primarily for Python 3.9 and earlier where the native
loaders do not yet implement TraversableResources.
"""
def __init__(self, spec):
self.spec = spec
@property
def path(self):
return self.spec.origin
def get_resource_reader(self, name):
from . import readers, _adapters
def _zip_reader(spec):
with suppress(AttributeError):
return readers.ZipReader(spec.loader, spec.name)
def _namespace_reader(spec):
with suppress(AttributeError, ValueError):
return readers.NamespaceReader(spec.submodule_search_locations)
def _available_reader(spec):
with suppress(AttributeError):
return spec.loader.get_resource_reader(spec.name)
def _native_reader(spec):
reader = _available_reader(spec)
return reader if hasattr(reader, 'files') else None
def _file_reader(spec):
try:
path = pathlib.Path(self.path)
except TypeError:
return None
if path.exists():
return readers.FileReader(self)
return (
# native reader if it supplies 'files'
_native_reader(self.spec)
or
# local ZipReader if a zip module
_zip_reader(self.spec)
or
# local NamespaceReader if a namespace module
_namespace_reader(self.spec)
or
# local FileReader
_file_reader(self.spec)
# fallback - adapt the spec ResourceReader to TraversableReader
or _adapters.CompatibilityFiles(self.spec)
)
def wrap_spec(package):
"""
Construct a package spec with traversable compatibility
on the spec/loader/reader.
Supersedes _adapters.wrap_spec to use TraversableResourcesLoader
from above for older Python compatibility (<3.10).
"""
from . import _adapters
return _adapters.SpecLoaderAdapter(package.__spec__, TraversableResourcesLoader)
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/importlib_resources/_compat.py
|
Python
|
mit
| 2,706 |
from itertools import filterfalse
from typing import (
Callable,
Iterable,
Iterator,
Optional,
Set,
TypeVar,
Union,
)
# Type and type variable definitions
_T = TypeVar('_T')
_U = TypeVar('_U')
def unique_everseen(
iterable: Iterable[_T], key: Optional[Callable[[_T], _U]] = None
) -> Iterator[_T]:
"List unique elements, preserving order. Remember all elements ever seen."
# unique_everseen('AAAABBBCCDAABBB') --> A B C D
# unique_everseen('ABBCcAD', str.lower) --> A B C D
seen: Set[Union[_T, _U]] = set()
seen_add = seen.add
if key is None:
for element in filterfalse(seen.__contains__, iterable):
seen_add(element)
yield element
else:
for element in iterable:
k = key(element)
if k not in seen:
seen_add(k)
yield element
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/importlib_resources/_itertools.py
|
Python
|
mit
| 884 |
import functools
import os
import pathlib
import types
import warnings
from typing import Union, Iterable, ContextManager, BinaryIO, TextIO, Any
from . import _common
Package = Union[types.ModuleType, str]
Resource = str
def deprecated(func):
@functools.wraps(func)
def wrapper(*args, **kwargs):
warnings.warn(
f"{func.__name__} is deprecated. Use files() instead. "
"Refer to https://importlib-resources.readthedocs.io"
"/en/latest/using.html#migrating-from-legacy for migration advice.",
DeprecationWarning,
stacklevel=2,
)
return func(*args, **kwargs)
return wrapper
def normalize_path(path):
# type: (Any) -> str
"""Normalize a path by ensuring it is a string.
If the resulting string contains path separators, an exception is raised.
"""
str_path = str(path)
parent, file_name = os.path.split(str_path)
if parent:
raise ValueError(f'{path!r} must be only a file name')
return file_name
@deprecated
def open_binary(package: Package, resource: Resource) -> BinaryIO:
"""Return a file-like object opened for binary reading of the resource."""
return (_common.files(package) / normalize_path(resource)).open('rb')
@deprecated
def read_binary(package: Package, resource: Resource) -> bytes:
"""Return the binary contents of the resource."""
return (_common.files(package) / normalize_path(resource)).read_bytes()
@deprecated
def open_text(
package: Package,
resource: Resource,
encoding: str = 'utf-8',
errors: str = 'strict',
) -> TextIO:
"""Return a file-like object opened for text reading of the resource."""
return (_common.files(package) / normalize_path(resource)).open(
'r', encoding=encoding, errors=errors
)
@deprecated
def read_text(
package: Package,
resource: Resource,
encoding: str = 'utf-8',
errors: str = 'strict',
) -> str:
"""Return the decoded string of the resource.
The decoding-related arguments have the same semantics as those of
bytes.decode().
"""
with open_text(package, resource, encoding, errors) as fp:
return fp.read()
@deprecated
def contents(package: Package) -> Iterable[str]:
"""Return an iterable of entries in `package`.
Note that not all entries are resources. Specifically, directories are
not considered resources. Use `is_resource()` on each entry returned here
to check if it is a resource or not.
"""
return [path.name for path in _common.files(package).iterdir()]
@deprecated
def is_resource(package: Package, name: str) -> bool:
"""True if `name` is a resource inside `package`.
Directories are *not* resources.
"""
resource = normalize_path(name)
return any(
traversable.name == resource and traversable.is_file()
for traversable in _common.files(package).iterdir()
)
@deprecated
def path(
package: Package,
resource: Resource,
) -> ContextManager[pathlib.Path]:
"""A context manager providing a file path object to the resource.
If the resource does not already exist on its own on the file system,
a temporary file will be created. If the file was created, the file
will be deleted upon exiting the context manager (no exception is
raised if the file was deleted prior to the context manager
exiting).
"""
return _common.as_file(_common.files(package) / normalize_path(resource))
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/importlib_resources/_legacy.py
|
Python
|
mit
| 3,494 |
import abc
from typing import BinaryIO, Iterable, Text
from ._compat import runtime_checkable, Protocol
class ResourceReader(metaclass=abc.ABCMeta):
"""Abstract base class for loaders to provide resource reading support."""
@abc.abstractmethod
def open_resource(self, resource: Text) -> BinaryIO:
"""Return an opened, file-like object for binary reading.
The 'resource' argument is expected to represent only a file name.
If the resource cannot be found, FileNotFoundError is raised.
"""
# This deliberately raises FileNotFoundError instead of
# NotImplementedError so that if this method is accidentally called,
# it'll still do the right thing.
raise FileNotFoundError
@abc.abstractmethod
def resource_path(self, resource: Text) -> Text:
"""Return the file system path to the specified resource.
The 'resource' argument is expected to represent only a file name.
If the resource does not exist on the file system, raise
FileNotFoundError.
"""
# This deliberately raises FileNotFoundError instead of
# NotImplementedError so that if this method is accidentally called,
# it'll still do the right thing.
raise FileNotFoundError
@abc.abstractmethod
def is_resource(self, path: Text) -> bool:
"""Return True if the named 'path' is a resource.
Files are resources, directories are not.
"""
raise FileNotFoundError
@abc.abstractmethod
def contents(self) -> Iterable[str]:
"""Return an iterable of entries in `package`."""
raise FileNotFoundError
@runtime_checkable
class Traversable(Protocol):
"""
An object with a subset of pathlib.Path methods suitable for
traversing directories and opening files.
"""
@abc.abstractmethod
def iterdir(self):
"""
Yield Traversable objects in self
"""
def read_bytes(self):
"""
Read contents of self as bytes
"""
with self.open('rb') as strm:
return strm.read()
def read_text(self, encoding=None):
"""
Read contents of self as text
"""
with self.open(encoding=encoding) as strm:
return strm.read()
@abc.abstractmethod
def is_dir(self) -> bool:
"""
Return True if self is a directory
"""
@abc.abstractmethod
def is_file(self) -> bool:
"""
Return True if self is a file
"""
@abc.abstractmethod
def joinpath(self, child):
"""
Return Traversable child in self
"""
def __truediv__(self, child):
"""
Return Traversable child in self
"""
return self.joinpath(child)
@abc.abstractmethod
def open(self, mode='r', *args, **kwargs):
"""
mode may be 'r' or 'rb' to open as text or binary. Return a handle
suitable for reading (same as pathlib.Path.open).
When opening as text, accepts encoding parameters such as those
accepted by io.TextIOWrapper.
"""
@abc.abstractproperty
def name(self) -> str:
"""
The base name of this object without any parent references.
"""
class TraversableResources(ResourceReader):
"""
The required interface for providing traversable
resources.
"""
@abc.abstractmethod
def files(self):
"""Return a Traversable object for the loaded package."""
def open_resource(self, resource):
return self.files().joinpath(resource).open('rb')
def resource_path(self, resource):
raise FileNotFoundError(resource)
def is_resource(self, path):
return self.files().joinpath(path).is_file()
def contents(self):
return (item.name for item in self.files().iterdir())
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/importlib_resources/abc.py
|
Python
|
mit
| 3,886 |
import collections
import pathlib
import operator
from . import abc
from ._itertools import unique_everseen
from ._compat import ZipPath
def remove_duplicates(items):
return iter(collections.OrderedDict.fromkeys(items))
class FileReader(abc.TraversableResources):
def __init__(self, loader):
self.path = pathlib.Path(loader.path).parent
def resource_path(self, resource):
"""
Return the file system path to prevent
`resources.path()` from creating a temporary
copy.
"""
return str(self.path.joinpath(resource))
def files(self):
return self.path
class ZipReader(abc.TraversableResources):
def __init__(self, loader, module):
_, _, name = module.rpartition('.')
self.prefix = loader.prefix.replace('\\', '/') + name + '/'
self.archive = loader.archive
def open_resource(self, resource):
try:
return super().open_resource(resource)
except KeyError as exc:
raise FileNotFoundError(exc.args[0])
def is_resource(self, path):
# workaround for `zipfile.Path.is_file` returning true
# for non-existent paths.
target = self.files().joinpath(path)
return target.is_file() and target.exists()
def files(self):
return ZipPath(self.archive, self.prefix)
class MultiplexedPath(abc.Traversable):
"""
Given a series of Traversable objects, implement a merged
version of the interface across all objects. Useful for
namespace packages which may be multihomed at a single
name.
"""
def __init__(self, *paths):
self._paths = list(map(pathlib.Path, remove_duplicates(paths)))
if not self._paths:
message = 'MultiplexedPath must contain at least one path'
raise FileNotFoundError(message)
if not all(path.is_dir() for path in self._paths):
raise NotADirectoryError('MultiplexedPath only supports directories')
def iterdir(self):
files = (file for path in self._paths for file in path.iterdir())
return unique_everseen(files, key=operator.attrgetter('name'))
def read_bytes(self):
raise FileNotFoundError(f'{self} is not a file')
def read_text(self, *args, **kwargs):
raise FileNotFoundError(f'{self} is not a file')
def is_dir(self):
return True
def is_file(self):
return False
def joinpath(self, child):
# first try to find child in current paths
for file in self.iterdir():
if file.name == child:
return file
# if it does not exist, construct it with the first path
return self._paths[0] / child
__truediv__ = joinpath
def open(self, *args, **kwargs):
raise FileNotFoundError(f'{self} is not a file')
@property
def name(self):
return self._paths[0].name
def __repr__(self):
paths = ', '.join(f"'{path}'" for path in self._paths)
return f'MultiplexedPath({paths})'
class NamespaceReader(abc.TraversableResources):
def __init__(self, namespace_path):
if 'NamespacePath' not in str(namespace_path):
raise ValueError('Invalid path')
self.path = MultiplexedPath(*list(namespace_path))
def resource_path(self, resource):
"""
Return the file system path to prevent
`resources.path()` from creating a temporary
copy.
"""
return str(self.path.joinpath(resource))
def files(self):
return self.path
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/importlib_resources/readers.py
|
Python
|
mit
| 3,566 |
"""
Interface adapters for low-level readers.
"""
import abc
import io
import itertools
from typing import BinaryIO, List
from .abc import Traversable, TraversableResources
class SimpleReader(abc.ABC):
"""
The minimum, low-level interface required from a resource
provider.
"""
@abc.abstractproperty
def package(self):
# type: () -> str
"""
The name of the package for which this reader loads resources.
"""
@abc.abstractmethod
def children(self):
# type: () -> List['SimpleReader']
"""
Obtain an iterable of SimpleReader for available
child containers (e.g. directories).
"""
@abc.abstractmethod
def resources(self):
# type: () -> List[str]
"""
Obtain available named resources for this virtual package.
"""
@abc.abstractmethod
def open_binary(self, resource):
# type: (str) -> BinaryIO
"""
Obtain a File-like for a named resource.
"""
@property
def name(self):
return self.package.split('.')[-1]
class ResourceHandle(Traversable):
"""
Handle to a named resource in a ResourceReader.
"""
def __init__(self, parent, name):
# type: (ResourceContainer, str) -> None
self.parent = parent
self.name = name # type: ignore
def is_file(self):
return True
def is_dir(self):
return False
def open(self, mode='r', *args, **kwargs):
stream = self.parent.reader.open_binary(self.name)
if 'b' not in mode:
stream = io.TextIOWrapper(*args, **kwargs)
return stream
def joinpath(self, name):
raise RuntimeError("Cannot traverse into a resource")
class ResourceContainer(Traversable):
"""
Traversable container for a package's resources via its reader.
"""
def __init__(self, reader):
# type: (SimpleReader) -> None
self.reader = reader
def is_dir(self):
return True
def is_file(self):
return False
def iterdir(self):
files = (ResourceHandle(self, name) for name in self.reader.resources)
dirs = map(ResourceContainer, self.reader.children())
return itertools.chain(files, dirs)
def open(self, *args, **kwargs):
raise IsADirectoryError()
def joinpath(self, name):
return next(
traversable for traversable in self.iterdir() if traversable.name == name
)
class TraversableReader(TraversableResources, SimpleReader):
"""
A TraversableResources based on SimpleReader. Resource providers
may derive from this class to provide the TraversableResources
interface by supplying the SimpleReader interface.
"""
def files(self):
return ResourceContainer(self)
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/importlib_resources/simple.py
|
Python
|
mit
| 2,836 |
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/jaraco/__init__.py
|
Python
|
mit
| 0 |
|
import os
import subprocess
import contextlib
import functools
import tempfile
import shutil
import operator
@contextlib.contextmanager
def pushd(dir):
orig = os.getcwd()
os.chdir(dir)
try:
yield dir
finally:
os.chdir(orig)
@contextlib.contextmanager
def tarball_context(url, target_dir=None, runner=None, pushd=pushd):
"""
Get a tarball, extract it, change to that directory, yield, then
clean up.
`runner` is the function to invoke commands.
`pushd` is a context manager for changing the directory.
"""
if target_dir is None:
target_dir = os.path.basename(url).replace('.tar.gz', '').replace('.tgz', '')
if runner is None:
runner = functools.partial(subprocess.check_call, shell=True)
# In the tar command, use --strip-components=1 to strip the first path and
# then
# use -C to cause the files to be extracted to {target_dir}. This ensures
# that we always know where the files were extracted.
runner('mkdir {target_dir}'.format(**vars()))
try:
getter = 'wget {url} -O -'
extract = 'tar x{compression} --strip-components=1 -C {target_dir}'
cmd = ' | '.join((getter, extract))
runner(cmd.format(compression=infer_compression(url), **vars()))
with pushd(target_dir):
yield target_dir
finally:
runner('rm -Rf {target_dir}'.format(**vars()))
def infer_compression(url):
"""
Given a URL or filename, infer the compression code for tar.
"""
# cheat and just assume it's the last two characters
compression_indicator = url[-2:]
mapping = dict(gz='z', bz='j', xz='J')
# Assume 'z' (gzip) if no match
return mapping.get(compression_indicator, 'z')
@contextlib.contextmanager
def temp_dir(remover=shutil.rmtree):
"""
Create a temporary directory context. Pass a custom remover
to override the removal behavior.
"""
temp_dir = tempfile.mkdtemp()
try:
yield temp_dir
finally:
remover(temp_dir)
@contextlib.contextmanager
def repo_context(url, branch=None, quiet=True, dest_ctx=temp_dir):
"""
Check out the repo indicated by url.
If dest_ctx is supplied, it should be a context manager
to yield the target directory for the check out.
"""
exe = 'git' if 'git' in url else 'hg'
with dest_ctx() as repo_dir:
cmd = [exe, 'clone', url, repo_dir]
if branch:
cmd.extend(['--branch', branch])
devnull = open(os.path.devnull, 'w')
stdout = devnull if quiet else None
subprocess.check_call(cmd, stdout=stdout)
yield repo_dir
@contextlib.contextmanager
def null():
yield
class ExceptionTrap:
"""
A context manager that will catch certain exceptions and provide an
indication they occurred.
>>> with ExceptionTrap() as trap:
... raise Exception()
>>> bool(trap)
True
>>> with ExceptionTrap() as trap:
... pass
>>> bool(trap)
False
>>> with ExceptionTrap(ValueError) as trap:
... raise ValueError("1 + 1 is not 3")
>>> bool(trap)
True
>>> with ExceptionTrap(ValueError) as trap:
... raise Exception()
Traceback (most recent call last):
...
Exception
>>> bool(trap)
False
"""
exc_info = None, None, None
def __init__(self, exceptions=(Exception,)):
self.exceptions = exceptions
def __enter__(self):
return self
@property
def type(self):
return self.exc_info[0]
@property
def value(self):
return self.exc_info[1]
@property
def tb(self):
return self.exc_info[2]
def __exit__(self, *exc_info):
type = exc_info[0]
matches = type and issubclass(type, self.exceptions)
if matches:
self.exc_info = exc_info
return matches
def __bool__(self):
return bool(self.type)
def raises(self, func, *, _test=bool):
"""
Wrap func and replace the result with the truth
value of the trap (True if an exception occurred).
First, give the decorator an alias to support Python 3.8
Syntax.
>>> raises = ExceptionTrap(ValueError).raises
Now decorate a function that always fails.
>>> @raises
... def fail():
... raise ValueError('failed')
>>> fail()
True
"""
@functools.wraps(func)
def wrapper(*args, **kwargs):
with ExceptionTrap(self.exceptions) as trap:
func(*args, **kwargs)
return _test(trap)
return wrapper
def passes(self, func):
"""
Wrap func and replace the result with the truth
value of the trap (True if no exception).
First, give the decorator an alias to support Python 3.8
Syntax.
>>> passes = ExceptionTrap(ValueError).passes
Now decorate a function that always fails.
>>> @passes
... def fail():
... raise ValueError('failed')
>>> fail()
False
"""
return self.raises(func, _test=operator.not_)
class suppress(contextlib.suppress, contextlib.ContextDecorator):
"""
A version of contextlib.suppress with decorator support.
>>> @suppress(KeyError)
... def key_error():
... {}['']
>>> key_error()
"""
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/jaraco/context.py
|
Python
|
mit
| 5,420 |
import functools
import time
import inspect
import collections
import types
import itertools
import pkg_resources.extern.more_itertools
from typing import Callable, TypeVar
CallableT = TypeVar("CallableT", bound=Callable[..., object])
def compose(*funcs):
"""
Compose any number of unary functions into a single unary function.
>>> import textwrap
>>> expected = str.strip(textwrap.dedent(compose.__doc__))
>>> strip_and_dedent = compose(str.strip, textwrap.dedent)
>>> strip_and_dedent(compose.__doc__) == expected
True
Compose also allows the innermost function to take arbitrary arguments.
>>> round_three = lambda x: round(x, ndigits=3)
>>> f = compose(round_three, int.__truediv__)
>>> [f(3*x, x+1) for x in range(1,10)]
[1.5, 2.0, 2.25, 2.4, 2.5, 2.571, 2.625, 2.667, 2.7]
"""
def compose_two(f1, f2):
return lambda *args, **kwargs: f1(f2(*args, **kwargs))
return functools.reduce(compose_two, funcs)
def method_caller(method_name, *args, **kwargs):
"""
Return a function that will call a named method on the
target object with optional positional and keyword
arguments.
>>> lower = method_caller('lower')
>>> lower('MyString')
'mystring'
"""
def call_method(target):
func = getattr(target, method_name)
return func(*args, **kwargs)
return call_method
def once(func):
"""
Decorate func so it's only ever called the first time.
This decorator can ensure that an expensive or non-idempotent function
will not be expensive on subsequent calls and is idempotent.
>>> add_three = once(lambda a: a+3)
>>> add_three(3)
6
>>> add_three(9)
6
>>> add_three('12')
6
To reset the stored value, simply clear the property ``saved_result``.
>>> del add_three.saved_result
>>> add_three(9)
12
>>> add_three(8)
12
Or invoke 'reset()' on it.
>>> add_three.reset()
>>> add_three(-3)
0
>>> add_three(0)
0
"""
@functools.wraps(func)
def wrapper(*args, **kwargs):
if not hasattr(wrapper, 'saved_result'):
wrapper.saved_result = func(*args, **kwargs)
return wrapper.saved_result
wrapper.reset = lambda: vars(wrapper).__delitem__('saved_result')
return wrapper
def method_cache(
method: CallableT,
cache_wrapper: Callable[
[CallableT], CallableT
] = functools.lru_cache(), # type: ignore[assignment]
) -> CallableT:
"""
Wrap lru_cache to support storing the cache data in the object instances.
Abstracts the common paradigm where the method explicitly saves an
underscore-prefixed protected property on first call and returns that
subsequently.
>>> class MyClass:
... calls = 0
...
... @method_cache
... def method(self, value):
... self.calls += 1
... return value
>>> a = MyClass()
>>> a.method(3)
3
>>> for x in range(75):
... res = a.method(x)
>>> a.calls
75
Note that the apparent behavior will be exactly like that of lru_cache
except that the cache is stored on each instance, so values in one
instance will not flush values from another, and when an instance is
deleted, so are the cached values for that instance.
>>> b = MyClass()
>>> for x in range(35):
... res = b.method(x)
>>> b.calls
35
>>> a.method(0)
0
>>> a.calls
75
Note that if method had been decorated with ``functools.lru_cache()``,
a.calls would have been 76 (due to the cached value of 0 having been
flushed by the 'b' instance).
Clear the cache with ``.cache_clear()``
>>> a.method.cache_clear()
Same for a method that hasn't yet been called.
>>> c = MyClass()
>>> c.method.cache_clear()
Another cache wrapper may be supplied:
>>> cache = functools.lru_cache(maxsize=2)
>>> MyClass.method2 = method_cache(lambda self: 3, cache_wrapper=cache)
>>> a = MyClass()
>>> a.method2()
3
Caution - do not subsequently wrap the method with another decorator, such
as ``@property``, which changes the semantics of the function.
See also
http://code.activestate.com/recipes/577452-a-memoize-decorator-for-instance-methods/
for another implementation and additional justification.
"""
def wrapper(self: object, *args: object, **kwargs: object) -> object:
# it's the first call, replace the method with a cached, bound method
bound_method: CallableT = types.MethodType( # type: ignore[assignment]
method, self
)
cached_method = cache_wrapper(bound_method)
setattr(self, method.__name__, cached_method)
return cached_method(*args, **kwargs)
# Support cache clear even before cache has been created.
wrapper.cache_clear = lambda: None # type: ignore[attr-defined]
return ( # type: ignore[return-value]
_special_method_cache(method, cache_wrapper) or wrapper
)
def _special_method_cache(method, cache_wrapper):
"""
Because Python treats special methods differently, it's not
possible to use instance attributes to implement the cached
methods.
Instead, install the wrapper method under a different name
and return a simple proxy to that wrapper.
https://github.com/jaraco/jaraco.functools/issues/5
"""
name = method.__name__
special_names = '__getattr__', '__getitem__'
if name not in special_names:
return
wrapper_name = '__cached' + name
def proxy(self, *args, **kwargs):
if wrapper_name not in vars(self):
bound = types.MethodType(method, self)
cache = cache_wrapper(bound)
setattr(self, wrapper_name, cache)
else:
cache = getattr(self, wrapper_name)
return cache(*args, **kwargs)
return proxy
def apply(transform):
"""
Decorate a function with a transform function that is
invoked on results returned from the decorated function.
>>> @apply(reversed)
... def get_numbers(start):
... "doc for get_numbers"
... return range(start, start+3)
>>> list(get_numbers(4))
[6, 5, 4]
>>> get_numbers.__doc__
'doc for get_numbers'
"""
def wrap(func):
return functools.wraps(func)(compose(transform, func))
return wrap
def result_invoke(action):
r"""
Decorate a function with an action function that is
invoked on the results returned from the decorated
function (for its side-effect), then return the original
result.
>>> @result_invoke(print)
... def add_two(a, b):
... return a + b
>>> x = add_two(2, 3)
5
>>> x
5
"""
def wrap(func):
@functools.wraps(func)
def wrapper(*args, **kwargs):
result = func(*args, **kwargs)
action(result)
return result
return wrapper
return wrap
def call_aside(f, *args, **kwargs):
"""
Call a function for its side effect after initialization.
>>> @call_aside
... def func(): print("called")
called
>>> func()
called
Use functools.partial to pass parameters to the initial call
>>> @functools.partial(call_aside, name='bingo')
... def func(name): print("called with", name)
called with bingo
"""
f(*args, **kwargs)
return f
class Throttler:
"""
Rate-limit a function (or other callable)
"""
def __init__(self, func, max_rate=float('Inf')):
if isinstance(func, Throttler):
func = func.func
self.func = func
self.max_rate = max_rate
self.reset()
def reset(self):
self.last_called = 0
def __call__(self, *args, **kwargs):
self._wait()
return self.func(*args, **kwargs)
def _wait(self):
"ensure at least 1/max_rate seconds from last call"
elapsed = time.time() - self.last_called
must_wait = 1 / self.max_rate - elapsed
time.sleep(max(0, must_wait))
self.last_called = time.time()
def __get__(self, obj, type=None):
return first_invoke(self._wait, functools.partial(self.func, obj))
def first_invoke(func1, func2):
"""
Return a function that when invoked will invoke func1 without
any parameters (for its side-effect) and then invoke func2
with whatever parameters were passed, returning its result.
"""
def wrapper(*args, **kwargs):
func1()
return func2(*args, **kwargs)
return wrapper
def retry_call(func, cleanup=lambda: None, retries=0, trap=()):
"""
Given a callable func, trap the indicated exceptions
for up to 'retries' times, invoking cleanup on the
exception. On the final attempt, allow any exceptions
to propagate.
"""
attempts = itertools.count() if retries == float('inf') else range(retries)
for attempt in attempts:
try:
return func()
except trap:
cleanup()
return func()
def retry(*r_args, **r_kwargs):
"""
Decorator wrapper for retry_call. Accepts arguments to retry_call
except func and then returns a decorator for the decorated function.
Ex:
>>> @retry(retries=3)
... def my_func(a, b):
... "this is my funk"
... print(a, b)
>>> my_func.__doc__
'this is my funk'
"""
def decorate(func):
@functools.wraps(func)
def wrapper(*f_args, **f_kwargs):
bound = functools.partial(func, *f_args, **f_kwargs)
return retry_call(bound, *r_args, **r_kwargs)
return wrapper
return decorate
def print_yielded(func):
"""
Convert a generator into a function that prints all yielded elements
>>> @print_yielded
... def x():
... yield 3; yield None
>>> x()
3
None
"""
print_all = functools.partial(map, print)
print_results = compose(more_itertools.consume, print_all, func)
return functools.wraps(func)(print_results)
def pass_none(func):
"""
Wrap func so it's not called if its first param is None
>>> print_text = pass_none(print)
>>> print_text('text')
text
>>> print_text(None)
"""
@functools.wraps(func)
def wrapper(param, *args, **kwargs):
if param is not None:
return func(param, *args, **kwargs)
return wrapper
def assign_params(func, namespace):
"""
Assign parameters from namespace where func solicits.
>>> def func(x, y=3):
... print(x, y)
>>> assigned = assign_params(func, dict(x=2, z=4))
>>> assigned()
2 3
The usual errors are raised if a function doesn't receive
its required parameters:
>>> assigned = assign_params(func, dict(y=3, z=4))
>>> assigned()
Traceback (most recent call last):
TypeError: func() ...argument...
It even works on methods:
>>> class Handler:
... def meth(self, arg):
... print(arg)
>>> assign_params(Handler().meth, dict(arg='crystal', foo='clear'))()
crystal
"""
sig = inspect.signature(func)
params = sig.parameters.keys()
call_ns = {k: namespace[k] for k in params if k in namespace}
return functools.partial(func, **call_ns)
def save_method_args(method):
"""
Wrap a method such that when it is called, the args and kwargs are
saved on the method.
>>> class MyClass:
... @save_method_args
... def method(self, a, b):
... print(a, b)
>>> my_ob = MyClass()
>>> my_ob.method(1, 2)
1 2
>>> my_ob._saved_method.args
(1, 2)
>>> my_ob._saved_method.kwargs
{}
>>> my_ob.method(a=3, b='foo')
3 foo
>>> my_ob._saved_method.args
()
>>> my_ob._saved_method.kwargs == dict(a=3, b='foo')
True
The arguments are stored on the instance, allowing for
different instance to save different args.
>>> your_ob = MyClass()
>>> your_ob.method({str('x'): 3}, b=[4])
{'x': 3} [4]
>>> your_ob._saved_method.args
({'x': 3},)
>>> my_ob._saved_method.args
()
"""
args_and_kwargs = collections.namedtuple('args_and_kwargs', 'args kwargs')
@functools.wraps(method)
def wrapper(self, *args, **kwargs):
attr_name = '_saved_' + method.__name__
attr = args_and_kwargs(args, kwargs)
setattr(self, attr_name, attr)
return method(self, *args, **kwargs)
return wrapper
def except_(*exceptions, replace=None, use=None):
"""
Replace the indicated exceptions, if raised, with the indicated
literal replacement or evaluated expression (if present).
>>> safe_int = except_(ValueError)(int)
>>> safe_int('five')
>>> safe_int('5')
5
Specify a literal replacement with ``replace``.
>>> safe_int_r = except_(ValueError, replace=0)(int)
>>> safe_int_r('five')
0
Provide an expression to ``use`` to pass through particular parameters.
>>> safe_int_pt = except_(ValueError, use='args[0]')(int)
>>> safe_int_pt('five')
'five'
"""
def decorate(func):
@functools.wraps(func)
def wrapper(*args, **kwargs):
try:
return func(*args, **kwargs)
except exceptions:
try:
return eval(use)
except TypeError:
return replace
return wrapper
return decorate
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/jaraco/functools.py
|
Python
|
mit
| 13,515 |
import re
import itertools
import textwrap
import functools
try:
from importlib.resources import files # type: ignore
except ImportError: # pragma: nocover
from pkg_resources.extern.importlib_resources import files # type: ignore
from pkg_resources.extern.jaraco.functools import compose, method_cache
from pkg_resources.extern.jaraco.context import ExceptionTrap
def substitution(old, new):
"""
Return a function that will perform a substitution on a string
"""
return lambda s: s.replace(old, new)
def multi_substitution(*substitutions):
"""
Take a sequence of pairs specifying substitutions, and create
a function that performs those substitutions.
>>> multi_substitution(('foo', 'bar'), ('bar', 'baz'))('foo')
'baz'
"""
substitutions = itertools.starmap(substitution, substitutions)
# compose function applies last function first, so reverse the
# substitutions to get the expected order.
substitutions = reversed(tuple(substitutions))
return compose(*substitutions)
class FoldedCase(str):
"""
A case insensitive string class; behaves just like str
except compares equal when the only variation is case.
>>> s = FoldedCase('hello world')
>>> s == 'Hello World'
True
>>> 'Hello World' == s
True
>>> s != 'Hello World'
False
>>> s.index('O')
4
>>> s.split('O')
['hell', ' w', 'rld']
>>> sorted(map(FoldedCase, ['GAMMA', 'alpha', 'Beta']))
['alpha', 'Beta', 'GAMMA']
Sequence membership is straightforward.
>>> "Hello World" in [s]
True
>>> s in ["Hello World"]
True
You may test for set inclusion, but candidate and elements
must both be folded.
>>> FoldedCase("Hello World") in {s}
True
>>> s in {FoldedCase("Hello World")}
True
String inclusion works as long as the FoldedCase object
is on the right.
>>> "hello" in FoldedCase("Hello World")
True
But not if the FoldedCase object is on the left:
>>> FoldedCase('hello') in 'Hello World'
False
In that case, use ``in_``:
>>> FoldedCase('hello').in_('Hello World')
True
>>> FoldedCase('hello') > FoldedCase('Hello')
False
"""
def __lt__(self, other):
return self.lower() < other.lower()
def __gt__(self, other):
return self.lower() > other.lower()
def __eq__(self, other):
return self.lower() == other.lower()
def __ne__(self, other):
return self.lower() != other.lower()
def __hash__(self):
return hash(self.lower())
def __contains__(self, other):
return super().lower().__contains__(other.lower())
def in_(self, other):
"Does self appear in other?"
return self in FoldedCase(other)
# cache lower since it's likely to be called frequently.
@method_cache
def lower(self):
return super().lower()
def index(self, sub):
return self.lower().index(sub.lower())
def split(self, splitter=' ', maxsplit=0):
pattern = re.compile(re.escape(splitter), re.I)
return pattern.split(self, maxsplit)
# Python 3.8 compatibility
_unicode_trap = ExceptionTrap(UnicodeDecodeError)
@_unicode_trap.passes
def is_decodable(value):
r"""
Return True if the supplied value is decodable (using the default
encoding).
>>> is_decodable(b'\xff')
False
>>> is_decodable(b'\x32')
True
"""
value.decode()
def is_binary(value):
r"""
Return True if the value appears to be binary (that is, it's a byte
string and isn't decodable).
>>> is_binary(b'\xff')
True
>>> is_binary('\xff')
False
"""
return isinstance(value, bytes) and not is_decodable(value)
def trim(s):
r"""
Trim something like a docstring to remove the whitespace that
is common due to indentation and formatting.
>>> trim("\n\tfoo = bar\n\t\tbar = baz\n")
'foo = bar\n\tbar = baz'
"""
return textwrap.dedent(s).strip()
def wrap(s):
"""
Wrap lines of text, retaining existing newlines as
paragraph markers.
>>> print(wrap(lorem_ipsum))
Lorem ipsum dolor sit amet, consectetur adipiscing elit, sed do
eiusmod tempor incididunt ut labore et dolore magna aliqua. Ut enim ad
minim veniam, quis nostrud exercitation ullamco laboris nisi ut
aliquip ex ea commodo consequat. Duis aute irure dolor in
reprehenderit in voluptate velit esse cillum dolore eu fugiat nulla
pariatur. Excepteur sint occaecat cupidatat non proident, sunt in
culpa qui officia deserunt mollit anim id est laborum.
<BLANKLINE>
Curabitur pretium tincidunt lacus. Nulla gravida orci a odio. Nullam
varius, turpis et commodo pharetra, est eros bibendum elit, nec luctus
magna felis sollicitudin mauris. Integer in mauris eu nibh euismod
gravida. Duis ac tellus et risus vulputate vehicula. Donec lobortis
risus a elit. Etiam tempor. Ut ullamcorper, ligula eu tempor congue,
eros est euismod turpis, id tincidunt sapien risus a quam. Maecenas
fermentum consequat mi. Donec fermentum. Pellentesque malesuada nulla
a mi. Duis sapien sem, aliquet nec, commodo eget, consequat quis,
neque. Aliquam faucibus, elit ut dictum aliquet, felis nisl adipiscing
sapien, sed malesuada diam lacus eget erat. Cras mollis scelerisque
nunc. Nullam arcu. Aliquam consequat. Curabitur augue lorem, dapibus
quis, laoreet et, pretium ac, nisi. Aenean magna nisl, mollis quis,
molestie eu, feugiat in, orci. In hac habitasse platea dictumst.
"""
paragraphs = s.splitlines()
wrapped = ('\n'.join(textwrap.wrap(para)) for para in paragraphs)
return '\n\n'.join(wrapped)
def unwrap(s):
r"""
Given a multi-line string, return an unwrapped version.
>>> wrapped = wrap(lorem_ipsum)
>>> wrapped.count('\n')
20
>>> unwrapped = unwrap(wrapped)
>>> unwrapped.count('\n')
1
>>> print(unwrapped)
Lorem ipsum dolor sit amet, consectetur adipiscing ...
Curabitur pretium tincidunt lacus. Nulla gravida orci ...
"""
paragraphs = re.split(r'\n\n+', s)
cleaned = (para.replace('\n', ' ') for para in paragraphs)
return '\n'.join(cleaned)
class Splitter(object):
"""object that will split a string with the given arguments for each call
>>> s = Splitter(',')
>>> s('hello, world, this is your, master calling')
['hello', ' world', ' this is your', ' master calling']
"""
def __init__(self, *args):
self.args = args
def __call__(self, s):
return s.split(*self.args)
def indent(string, prefix=' ' * 4):
"""
>>> indent('foo')
' foo'
"""
return prefix + string
class WordSet(tuple):
"""
Given an identifier, return the words that identifier represents,
whether in camel case, underscore-separated, etc.
>>> WordSet.parse("camelCase")
('camel', 'Case')
>>> WordSet.parse("under_sep")
('under', 'sep')
Acronyms should be retained
>>> WordSet.parse("firstSNL")
('first', 'SNL')
>>> WordSet.parse("you_and_I")
('you', 'and', 'I')
>>> WordSet.parse("A simple test")
('A', 'simple', 'test')
Multiple caps should not interfere with the first cap of another word.
>>> WordSet.parse("myABCClass")
('my', 'ABC', 'Class')
The result is a WordSet, so you can get the form you need.
>>> WordSet.parse("myABCClass").underscore_separated()
'my_ABC_Class'
>>> WordSet.parse('a-command').camel_case()
'ACommand'
>>> WordSet.parse('someIdentifier').lowered().space_separated()
'some identifier'
Slices of the result should return another WordSet.
>>> WordSet.parse('taken-out-of-context')[1:].underscore_separated()
'out_of_context'
>>> WordSet.from_class_name(WordSet()).lowered().space_separated()
'word set'
>>> example = WordSet.parse('figured it out')
>>> example.headless_camel_case()
'figuredItOut'
>>> example.dash_separated()
'figured-it-out'
"""
_pattern = re.compile('([A-Z]?[a-z]+)|([A-Z]+(?![a-z]))')
def capitalized(self):
return WordSet(word.capitalize() for word in self)
def lowered(self):
return WordSet(word.lower() for word in self)
def camel_case(self):
return ''.join(self.capitalized())
def headless_camel_case(self):
words = iter(self)
first = next(words).lower()
new_words = itertools.chain((first,), WordSet(words).camel_case())
return ''.join(new_words)
def underscore_separated(self):
return '_'.join(self)
def dash_separated(self):
return '-'.join(self)
def space_separated(self):
return ' '.join(self)
def trim_right(self, item):
"""
Remove the item from the end of the set.
>>> WordSet.parse('foo bar').trim_right('foo')
('foo', 'bar')
>>> WordSet.parse('foo bar').trim_right('bar')
('foo',)
>>> WordSet.parse('').trim_right('bar')
()
"""
return self[:-1] if self and self[-1] == item else self
def trim_left(self, item):
"""
Remove the item from the beginning of the set.
>>> WordSet.parse('foo bar').trim_left('foo')
('bar',)
>>> WordSet.parse('foo bar').trim_left('bar')
('foo', 'bar')
>>> WordSet.parse('').trim_left('bar')
()
"""
return self[1:] if self and self[0] == item else self
def trim(self, item):
"""
>>> WordSet.parse('foo bar').trim('foo')
('bar',)
"""
return self.trim_left(item).trim_right(item)
def __getitem__(self, item):
result = super(WordSet, self).__getitem__(item)
if isinstance(item, slice):
result = WordSet(result)
return result
@classmethod
def parse(cls, identifier):
matches = cls._pattern.finditer(identifier)
return WordSet(match.group(0) for match in matches)
@classmethod
def from_class_name(cls, subject):
return cls.parse(subject.__class__.__name__)
# for backward compatibility
words = WordSet.parse
def simple_html_strip(s):
r"""
Remove HTML from the string `s`.
>>> str(simple_html_strip(''))
''
>>> print(simple_html_strip('A <bold>stormy</bold> day in paradise'))
A stormy day in paradise
>>> print(simple_html_strip('Somebody <!-- do not --> tell the truth.'))
Somebody tell the truth.
>>> print(simple_html_strip('What about<br/>\nmultiple lines?'))
What about
multiple lines?
"""
html_stripper = re.compile('(<!--.*?-->)|(<[^>]*>)|([^<]+)', re.DOTALL)
texts = (match.group(3) or '' for match in html_stripper.finditer(s))
return ''.join(texts)
class SeparatedValues(str):
"""
A string separated by a separator. Overrides __iter__ for getting
the values.
>>> list(SeparatedValues('a,b,c'))
['a', 'b', 'c']
Whitespace is stripped and empty values are discarded.
>>> list(SeparatedValues(' a, b , c, '))
['a', 'b', 'c']
"""
separator = ','
def __iter__(self):
parts = self.split(self.separator)
return filter(None, (part.strip() for part in parts))
class Stripper:
r"""
Given a series of lines, find the common prefix and strip it from them.
>>> lines = [
... 'abcdefg\n',
... 'abc\n',
... 'abcde\n',
... ]
>>> res = Stripper.strip_prefix(lines)
>>> res.prefix
'abc'
>>> list(res.lines)
['defg\n', '\n', 'de\n']
If no prefix is common, nothing should be stripped.
>>> lines = [
... 'abcd\n',
... '1234\n',
... ]
>>> res = Stripper.strip_prefix(lines)
>>> res.prefix = ''
>>> list(res.lines)
['abcd\n', '1234\n']
"""
def __init__(self, prefix, lines):
self.prefix = prefix
self.lines = map(self, lines)
@classmethod
def strip_prefix(cls, lines):
prefix_lines, lines = itertools.tee(lines)
prefix = functools.reduce(cls.common_prefix, prefix_lines)
return cls(prefix, lines)
def __call__(self, line):
if not self.prefix:
return line
null, prefix, rest = line.partition(self.prefix)
return rest
@staticmethod
def common_prefix(s1, s2):
"""
Return the common prefix of two lines.
"""
index = min(len(s1), len(s2))
while s1[:index] != s2[:index]:
index -= 1
return s1[:index]
def remove_prefix(text, prefix):
"""
Remove the prefix from the text if it exists.
>>> remove_prefix('underwhelming performance', 'underwhelming ')
'performance'
>>> remove_prefix('something special', 'sample')
'something special'
"""
null, prefix, rest = text.rpartition(prefix)
return rest
def remove_suffix(text, suffix):
"""
Remove the suffix from the text if it exists.
>>> remove_suffix('name.git', '.git')
'name'
>>> remove_suffix('something special', 'sample')
'something special'
"""
rest, suffix, null = text.partition(suffix)
return rest
def normalize_newlines(text):
r"""
Replace alternate newlines with the canonical newline.
>>> normalize_newlines('Lorem Ipsum\u2029')
'Lorem Ipsum\n'
>>> normalize_newlines('Lorem Ipsum\r\n')
'Lorem Ipsum\n'
>>> normalize_newlines('Lorem Ipsum\x85')
'Lorem Ipsum\n'
"""
newlines = ['\r\n', '\r', '\n', '\u0085', '\u2028', '\u2029']
pattern = '|'.join(newlines)
return re.sub(pattern, '\n', text)
def _nonblank(str):
return str and not str.startswith('#')
@functools.singledispatch
def yield_lines(iterable):
r"""
Yield valid lines of a string or iterable.
>>> list(yield_lines(''))
[]
>>> list(yield_lines(['foo', 'bar']))
['foo', 'bar']
>>> list(yield_lines('foo\nbar'))
['foo', 'bar']
>>> list(yield_lines('\nfoo\n#bar\nbaz #comment'))
['foo', 'baz #comment']
>>> list(yield_lines(['foo\nbar', 'baz', 'bing\n\n\n']))
['foo', 'bar', 'baz', 'bing']
"""
return itertools.chain.from_iterable(map(yield_lines, iterable))
@yield_lines.register(str)
def _(text):
return filter(_nonblank, map(str.strip, text.splitlines()))
def drop_comment(line):
"""
Drop comments.
>>> drop_comment('foo # bar')
'foo'
A hash without a space may be in a URL.
>>> drop_comment('http://example.com/foo#bar')
'http://example.com/foo#bar'
"""
return line.partition(' #')[0]
def join_continuation(lines):
r"""
Join lines continued by a trailing backslash.
>>> list(join_continuation(['foo \\', 'bar', 'baz']))
['foobar', 'baz']
>>> list(join_continuation(['foo \\', 'bar', 'baz']))
['foobar', 'baz']
>>> list(join_continuation(['foo \\', 'bar \\', 'baz']))
['foobarbaz']
Not sure why, but...
The character preceeding the backslash is also elided.
>>> list(join_continuation(['goo\\', 'dly']))
['godly']
A terrible idea, but...
If no line is available to continue, suppress the lines.
>>> list(join_continuation(['foo', 'bar\\', 'baz\\']))
['foo']
"""
lines = iter(lines)
for item in lines:
while item.endswith('\\'):
try:
item = item[:-2].strip() + next(lines)
except StopIteration:
return
yield item
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/jaraco/text/__init__.py
|
Python
|
mit
| 15,526 |
from .more import * # noqa
from .recipes import * # noqa
__version__ = '8.12.0'
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/more_itertools/__init__.py
|
Python
|
mit
| 83 |
import warnings
from collections import Counter, defaultdict, deque, abc
from collections.abc import Sequence
from functools import partial, reduce, wraps
from heapq import merge, heapify, heapreplace, heappop
from itertools import (
chain,
compress,
count,
cycle,
dropwhile,
groupby,
islice,
repeat,
starmap,
takewhile,
tee,
zip_longest,
)
from math import exp, factorial, floor, log
from queue import Empty, Queue
from random import random, randrange, uniform
from operator import itemgetter, mul, sub, gt, lt, ge, le
from sys import hexversion, maxsize
from time import monotonic
from .recipes import (
consume,
flatten,
pairwise,
powerset,
take,
unique_everseen,
)
__all__ = [
'AbortThread',
'SequenceView',
'UnequalIterablesError',
'adjacent',
'all_unique',
'always_iterable',
'always_reversible',
'bucket',
'callback_iter',
'chunked',
'chunked_even',
'circular_shifts',
'collapse',
'collate',
'combination_index',
'consecutive_groups',
'consumer',
'count_cycle',
'countable',
'difference',
'distinct_combinations',
'distinct_permutations',
'distribute',
'divide',
'duplicates_everseen',
'duplicates_justseen',
'exactly_n',
'filter_except',
'first',
'groupby_transform',
'ichunked',
'ilen',
'interleave',
'interleave_evenly',
'interleave_longest',
'intersperse',
'is_sorted',
'islice_extended',
'iterate',
'last',
'locate',
'lstrip',
'make_decorator',
'map_except',
'map_if',
'map_reduce',
'mark_ends',
'minmax',
'nth_or_last',
'nth_permutation',
'nth_product',
'numeric_range',
'one',
'only',
'padded',
'partitions',
'peekable',
'permutation_index',
'product_index',
'raise_',
'repeat_each',
'repeat_last',
'replace',
'rlocate',
'rstrip',
'run_length',
'sample',
'seekable',
'set_partitions',
'side_effect',
'sliced',
'sort_together',
'split_after',
'split_at',
'split_before',
'split_into',
'split_when',
'spy',
'stagger',
'strip',
'strictly_n',
'substrings',
'substrings_indexes',
'time_limited',
'unique_in_window',
'unique_to_each',
'unzip',
'value_chain',
'windowed',
'windowed_complete',
'with_iter',
'zip_broadcast',
'zip_equal',
'zip_offset',
]
_marker = object()
def chunked(iterable, n, strict=False):
"""Break *iterable* into lists of length *n*:
>>> list(chunked([1, 2, 3, 4, 5, 6], 3))
[[1, 2, 3], [4, 5, 6]]
By the default, the last yielded list will have fewer than *n* elements
if the length of *iterable* is not divisible by *n*:
>>> list(chunked([1, 2, 3, 4, 5, 6, 7, 8], 3))
[[1, 2, 3], [4, 5, 6], [7, 8]]
To use a fill-in value instead, see the :func:`grouper` recipe.
If the length of *iterable* is not divisible by *n* and *strict* is
``True``, then ``ValueError`` will be raised before the last
list is yielded.
"""
iterator = iter(partial(take, n, iter(iterable)), [])
if strict:
if n is None:
raise ValueError('n must not be None when using strict mode.')
def ret():
for chunk in iterator:
if len(chunk) != n:
raise ValueError('iterable is not divisible by n.')
yield chunk
return iter(ret())
else:
return iterator
def first(iterable, default=_marker):
"""Return the first item of *iterable*, or *default* if *iterable* is
empty.
>>> first([0, 1, 2, 3])
0
>>> first([], 'some default')
'some default'
If *default* is not provided and there are no items in the iterable,
raise ``ValueError``.
:func:`first` is useful when you have a generator of expensive-to-retrieve
values and want any arbitrary one. It is marginally shorter than
``next(iter(iterable), default)``.
"""
try:
return next(iter(iterable))
except StopIteration as e:
if default is _marker:
raise ValueError(
'first() was called on an empty iterable, and no '
'default value was provided.'
) from e
return default
def last(iterable, default=_marker):
"""Return the last item of *iterable*, or *default* if *iterable* is
empty.
>>> last([0, 1, 2, 3])
3
>>> last([], 'some default')
'some default'
If *default* is not provided and there are no items in the iterable,
raise ``ValueError``.
"""
try:
if isinstance(iterable, Sequence):
return iterable[-1]
# Work around https://bugs.python.org/issue38525
elif hasattr(iterable, '__reversed__') and (hexversion != 0x030800F0):
return next(reversed(iterable))
else:
return deque(iterable, maxlen=1)[-1]
except (IndexError, TypeError, StopIteration):
if default is _marker:
raise ValueError(
'last() was called on an empty iterable, and no default was '
'provided.'
)
return default
def nth_or_last(iterable, n, default=_marker):
"""Return the nth or the last item of *iterable*,
or *default* if *iterable* is empty.
>>> nth_or_last([0, 1, 2, 3], 2)
2
>>> nth_or_last([0, 1], 2)
1
>>> nth_or_last([], 0, 'some default')
'some default'
If *default* is not provided and there are no items in the iterable,
raise ``ValueError``.
"""
return last(islice(iterable, n + 1), default=default)
class peekable:
"""Wrap an iterator to allow lookahead and prepending elements.
Call :meth:`peek` on the result to get the value that will be returned
by :func:`next`. This won't advance the iterator:
>>> p = peekable(['a', 'b'])
>>> p.peek()
'a'
>>> next(p)
'a'
Pass :meth:`peek` a default value to return that instead of raising
``StopIteration`` when the iterator is exhausted.
>>> p = peekable([])
>>> p.peek('hi')
'hi'
peekables also offer a :meth:`prepend` method, which "inserts" items
at the head of the iterable:
>>> p = peekable([1, 2, 3])
>>> p.prepend(10, 11, 12)
>>> next(p)
10
>>> p.peek()
11
>>> list(p)
[11, 12, 1, 2, 3]
peekables can be indexed. Index 0 is the item that will be returned by
:func:`next`, index 1 is the item after that, and so on:
The values up to the given index will be cached.
>>> p = peekable(['a', 'b', 'c', 'd'])
>>> p[0]
'a'
>>> p[1]
'b'
>>> next(p)
'a'
Negative indexes are supported, but be aware that they will cache the
remaining items in the source iterator, which may require significant
storage.
To check whether a peekable is exhausted, check its truth value:
>>> p = peekable(['a', 'b'])
>>> if p: # peekable has items
... list(p)
['a', 'b']
>>> if not p: # peekable is exhausted
... list(p)
[]
"""
def __init__(self, iterable):
self._it = iter(iterable)
self._cache = deque()
def __iter__(self):
return self
def __bool__(self):
try:
self.peek()
except StopIteration:
return False
return True
def peek(self, default=_marker):
"""Return the item that will be next returned from ``next()``.
Return ``default`` if there are no items left. If ``default`` is not
provided, raise ``StopIteration``.
"""
if not self._cache:
try:
self._cache.append(next(self._it))
except StopIteration:
if default is _marker:
raise
return default
return self._cache[0]
def prepend(self, *items):
"""Stack up items to be the next ones returned from ``next()`` or
``self.peek()``. The items will be returned in
first in, first out order::
>>> p = peekable([1, 2, 3])
>>> p.prepend(10, 11, 12)
>>> next(p)
10
>>> list(p)
[11, 12, 1, 2, 3]
It is possible, by prepending items, to "resurrect" a peekable that
previously raised ``StopIteration``.
>>> p = peekable([])
>>> next(p)
Traceback (most recent call last):
...
StopIteration
>>> p.prepend(1)
>>> next(p)
1
>>> next(p)
Traceback (most recent call last):
...
StopIteration
"""
self._cache.extendleft(reversed(items))
def __next__(self):
if self._cache:
return self._cache.popleft()
return next(self._it)
def _get_slice(self, index):
# Normalize the slice's arguments
step = 1 if (index.step is None) else index.step
if step > 0:
start = 0 if (index.start is None) else index.start
stop = maxsize if (index.stop is None) else index.stop
elif step < 0:
start = -1 if (index.start is None) else index.start
stop = (-maxsize - 1) if (index.stop is None) else index.stop
else:
raise ValueError('slice step cannot be zero')
# If either the start or stop index is negative, we'll need to cache
# the rest of the iterable in order to slice from the right side.
if (start < 0) or (stop < 0):
self._cache.extend(self._it)
# Otherwise we'll need to find the rightmost index and cache to that
# point.
else:
n = min(max(start, stop) + 1, maxsize)
cache_len = len(self._cache)
if n >= cache_len:
self._cache.extend(islice(self._it, n - cache_len))
return list(self._cache)[index]
def __getitem__(self, index):
if isinstance(index, slice):
return self._get_slice(index)
cache_len = len(self._cache)
if index < 0:
self._cache.extend(self._it)
elif index >= cache_len:
self._cache.extend(islice(self._it, index + 1 - cache_len))
return self._cache[index]
def collate(*iterables, **kwargs):
"""Return a sorted merge of the items from each of several already-sorted
*iterables*.
>>> list(collate('ACDZ', 'AZ', 'JKL'))
['A', 'A', 'C', 'D', 'J', 'K', 'L', 'Z', 'Z']
Works lazily, keeping only the next value from each iterable in memory. Use
:func:`collate` to, for example, perform a n-way mergesort of items that
don't fit in memory.
If a *key* function is specified, the iterables will be sorted according
to its result:
>>> key = lambda s: int(s) # Sort by numeric value, not by string
>>> list(collate(['1', '10'], ['2', '11'], key=key))
['1', '2', '10', '11']
If the *iterables* are sorted in descending order, set *reverse* to
``True``:
>>> list(collate([5, 3, 1], [4, 2, 0], reverse=True))
[5, 4, 3, 2, 1, 0]
If the elements of the passed-in iterables are out of order, you might get
unexpected results.
On Python 3.5+, this function is an alias for :func:`heapq.merge`.
"""
warnings.warn(
"collate is no longer part of more_itertools, use heapq.merge",
DeprecationWarning,
)
return merge(*iterables, **kwargs)
def consumer(func):
"""Decorator that automatically advances a PEP-342-style "reverse iterator"
to its first yield point so you don't have to call ``next()`` on it
manually.
>>> @consumer
... def tally():
... i = 0
... while True:
... print('Thing number %s is %s.' % (i, (yield)))
... i += 1
...
>>> t = tally()
>>> t.send('red')
Thing number 0 is red.
>>> t.send('fish')
Thing number 1 is fish.
Without the decorator, you would have to call ``next(t)`` before
``t.send()`` could be used.
"""
@wraps(func)
def wrapper(*args, **kwargs):
gen = func(*args, **kwargs)
next(gen)
return gen
return wrapper
def ilen(iterable):
"""Return the number of items in *iterable*.
>>> ilen(x for x in range(1000000) if x % 3 == 0)
333334
This consumes the iterable, so handle with care.
"""
# This approach was selected because benchmarks showed it's likely the
# fastest of the known implementations at the time of writing.
# See GitHub tracker: #236, #230.
counter = count()
deque(zip(iterable, counter), maxlen=0)
return next(counter)
def iterate(func, start):
"""Return ``start``, ``func(start)``, ``func(func(start))``, ...
>>> from itertools import islice
>>> list(islice(iterate(lambda x: 2*x, 1), 10))
[1, 2, 4, 8, 16, 32, 64, 128, 256, 512]
"""
while True:
yield start
start = func(start)
def with_iter(context_manager):
"""Wrap an iterable in a ``with`` statement, so it closes once exhausted.
For example, this will close the file when the iterator is exhausted::
upper_lines = (line.upper() for line in with_iter(open('foo')))
Any context manager which returns an iterable is a candidate for
``with_iter``.
"""
with context_manager as iterable:
yield from iterable
def one(iterable, too_short=None, too_long=None):
"""Return the first item from *iterable*, which is expected to contain only
that item. Raise an exception if *iterable* is empty or has more than one
item.
:func:`one` is useful for ensuring that an iterable contains only one item.
For example, it can be used to retrieve the result of a database query
that is expected to return a single row.
If *iterable* is empty, ``ValueError`` will be raised. You may specify a
different exception with the *too_short* keyword:
>>> it = []
>>> one(it) # doctest: +IGNORE_EXCEPTION_DETAIL
Traceback (most recent call last):
...
ValueError: too many items in iterable (expected 1)'
>>> too_short = IndexError('too few items')
>>> one(it, too_short=too_short) # doctest: +IGNORE_EXCEPTION_DETAIL
Traceback (most recent call last):
...
IndexError: too few items
Similarly, if *iterable* contains more than one item, ``ValueError`` will
be raised. You may specify a different exception with the *too_long*
keyword:
>>> it = ['too', 'many']
>>> one(it) # doctest: +IGNORE_EXCEPTION_DETAIL
Traceback (most recent call last):
...
ValueError: Expected exactly one item in iterable, but got 'too',
'many', and perhaps more.
>>> too_long = RuntimeError
>>> one(it, too_long=too_long) # doctest: +IGNORE_EXCEPTION_DETAIL
Traceback (most recent call last):
...
RuntimeError
Note that :func:`one` attempts to advance *iterable* twice to ensure there
is only one item. See :func:`spy` or :func:`peekable` to check iterable
contents less destructively.
"""
it = iter(iterable)
try:
first_value = next(it)
except StopIteration as e:
raise (
too_short or ValueError('too few items in iterable (expected 1)')
) from e
try:
second_value = next(it)
except StopIteration:
pass
else:
msg = (
'Expected exactly one item in iterable, but got {!r}, {!r}, '
'and perhaps more.'.format(first_value, second_value)
)
raise too_long or ValueError(msg)
return first_value
def raise_(exception, *args):
raise exception(*args)
def strictly_n(iterable, n, too_short=None, too_long=None):
"""Validate that *iterable* has exactly *n* items and return them if
it does. If it has fewer than *n* items, call function *too_short*
with those items. If it has more than *n* items, call function
*too_long* with the first ``n + 1`` items.
>>> iterable = ['a', 'b', 'c', 'd']
>>> n = 4
>>> list(strictly_n(iterable, n))
['a', 'b', 'c', 'd']
By default, *too_short* and *too_long* are functions that raise
``ValueError``.
>>> list(strictly_n('ab', 3)) # doctest: +IGNORE_EXCEPTION_DETAIL
Traceback (most recent call last):
...
ValueError: too few items in iterable (got 2)
>>> list(strictly_n('abc', 2)) # doctest: +IGNORE_EXCEPTION_DETAIL
Traceback (most recent call last):
...
ValueError: too many items in iterable (got at least 3)
You can instead supply functions that do something else.
*too_short* will be called with the number of items in *iterable*.
*too_long* will be called with `n + 1`.
>>> def too_short(item_count):
... raise RuntimeError
>>> it = strictly_n('abcd', 6, too_short=too_short)
>>> list(it) # doctest: +IGNORE_EXCEPTION_DETAIL
Traceback (most recent call last):
...
RuntimeError
>>> def too_long(item_count):
... print('The boss is going to hear about this')
>>> it = strictly_n('abcdef', 4, too_long=too_long)
>>> list(it)
The boss is going to hear about this
['a', 'b', 'c', 'd']
"""
if too_short is None:
too_short = lambda item_count: raise_(
ValueError,
'Too few items in iterable (got {})'.format(item_count),
)
if too_long is None:
too_long = lambda item_count: raise_(
ValueError,
'Too many items in iterable (got at least {})'.format(item_count),
)
it = iter(iterable)
for i in range(n):
try:
item = next(it)
except StopIteration:
too_short(i)
return
else:
yield item
try:
next(it)
except StopIteration:
pass
else:
too_long(n + 1)
def distinct_permutations(iterable, r=None):
"""Yield successive distinct permutations of the elements in *iterable*.
>>> sorted(distinct_permutations([1, 0, 1]))
[(0, 1, 1), (1, 0, 1), (1, 1, 0)]
Equivalent to ``set(permutations(iterable))``, except duplicates are not
generated and thrown away. For larger input sequences this is much more
efficient.
Duplicate permutations arise when there are duplicated elements in the
input iterable. The number of items returned is
`n! / (x_1! * x_2! * ... * x_n!)`, where `n` is the total number of
items input, and each `x_i` is the count of a distinct item in the input
sequence.
If *r* is given, only the *r*-length permutations are yielded.
>>> sorted(distinct_permutations([1, 0, 1], r=2))
[(0, 1), (1, 0), (1, 1)]
>>> sorted(distinct_permutations(range(3), r=2))
[(0, 1), (0, 2), (1, 0), (1, 2), (2, 0), (2, 1)]
"""
# Algorithm: https://w.wiki/Qai
def _full(A):
while True:
# Yield the permutation we have
yield tuple(A)
# Find the largest index i such that A[i] < A[i + 1]
for i in range(size - 2, -1, -1):
if A[i] < A[i + 1]:
break
# If no such index exists, this permutation is the last one
else:
return
# Find the largest index j greater than j such that A[i] < A[j]
for j in range(size - 1, i, -1):
if A[i] < A[j]:
break
# Swap the value of A[i] with that of A[j], then reverse the
# sequence from A[i + 1] to form the new permutation
A[i], A[j] = A[j], A[i]
A[i + 1 :] = A[: i - size : -1] # A[i + 1:][::-1]
# Algorithm: modified from the above
def _partial(A, r):
# Split A into the first r items and the last r items
head, tail = A[:r], A[r:]
right_head_indexes = range(r - 1, -1, -1)
left_tail_indexes = range(len(tail))
while True:
# Yield the permutation we have
yield tuple(head)
# Starting from the right, find the first index of the head with
# value smaller than the maximum value of the tail - call it i.
pivot = tail[-1]
for i in right_head_indexes:
if head[i] < pivot:
break
pivot = head[i]
else:
return
# Starting from the left, find the first value of the tail
# with a value greater than head[i] and swap.
for j in left_tail_indexes:
if tail[j] > head[i]:
head[i], tail[j] = tail[j], head[i]
break
# If we didn't find one, start from the right and find the first
# index of the head with a value greater than head[i] and swap.
else:
for j in right_head_indexes:
if head[j] > head[i]:
head[i], head[j] = head[j], head[i]
break
# Reverse head[i + 1:] and swap it with tail[:r - (i + 1)]
tail += head[: i - r : -1] # head[i + 1:][::-1]
i += 1
head[i:], tail[:] = tail[: r - i], tail[r - i :]
items = sorted(iterable)
size = len(items)
if r is None:
r = size
if 0 < r <= size:
return _full(items) if (r == size) else _partial(items, r)
return iter(() if r else ((),))
def intersperse(e, iterable, n=1):
"""Intersperse filler element *e* among the items in *iterable*, leaving
*n* items between each filler element.
>>> list(intersperse('!', [1, 2, 3, 4, 5]))
[1, '!', 2, '!', 3, '!', 4, '!', 5]
>>> list(intersperse(None, [1, 2, 3, 4, 5], n=2))
[1, 2, None, 3, 4, None, 5]
"""
if n == 0:
raise ValueError('n must be > 0')
elif n == 1:
# interleave(repeat(e), iterable) -> e, x_0, e, x_1, e, x_2...
# islice(..., 1, None) -> x_0, e, x_1, e, x_2...
return islice(interleave(repeat(e), iterable), 1, None)
else:
# interleave(filler, chunks) -> [e], [x_0, x_1], [e], [x_2, x_3]...
# islice(..., 1, None) -> [x_0, x_1], [e], [x_2, x_3]...
# flatten(...) -> x_0, x_1, e, x_2, x_3...
filler = repeat([e])
chunks = chunked(iterable, n)
return flatten(islice(interleave(filler, chunks), 1, None))
def unique_to_each(*iterables):
"""Return the elements from each of the input iterables that aren't in the
other input iterables.
For example, suppose you have a set of packages, each with a set of
dependencies::
{'pkg_1': {'A', 'B'}, 'pkg_2': {'B', 'C'}, 'pkg_3': {'B', 'D'}}
If you remove one package, which dependencies can also be removed?
If ``pkg_1`` is removed, then ``A`` is no longer necessary - it is not
associated with ``pkg_2`` or ``pkg_3``. Similarly, ``C`` is only needed for
``pkg_2``, and ``D`` is only needed for ``pkg_3``::
>>> unique_to_each({'A', 'B'}, {'B', 'C'}, {'B', 'D'})
[['A'], ['C'], ['D']]
If there are duplicates in one input iterable that aren't in the others
they will be duplicated in the output. Input order is preserved::
>>> unique_to_each("mississippi", "missouri")
[['p', 'p'], ['o', 'u', 'r']]
It is assumed that the elements of each iterable are hashable.
"""
pool = [list(it) for it in iterables]
counts = Counter(chain.from_iterable(map(set, pool)))
uniques = {element for element in counts if counts[element] == 1}
return [list(filter(uniques.__contains__, it)) for it in pool]
def windowed(seq, n, fillvalue=None, step=1):
"""Return a sliding window of width *n* over the given iterable.
>>> all_windows = windowed([1, 2, 3, 4, 5], 3)
>>> list(all_windows)
[(1, 2, 3), (2, 3, 4), (3, 4, 5)]
When the window is larger than the iterable, *fillvalue* is used in place
of missing values:
>>> list(windowed([1, 2, 3], 4))
[(1, 2, 3, None)]
Each window will advance in increments of *step*:
>>> list(windowed([1, 2, 3, 4, 5, 6], 3, fillvalue='!', step=2))
[(1, 2, 3), (3, 4, 5), (5, 6, '!')]
To slide into the iterable's items, use :func:`chain` to add filler items
to the left:
>>> iterable = [1, 2, 3, 4]
>>> n = 3
>>> padding = [None] * (n - 1)
>>> list(windowed(chain(padding, iterable), 3))
[(None, None, 1), (None, 1, 2), (1, 2, 3), (2, 3, 4)]
"""
if n < 0:
raise ValueError('n must be >= 0')
if n == 0:
yield tuple()
return
if step < 1:
raise ValueError('step must be >= 1')
window = deque(maxlen=n)
i = n
for _ in map(window.append, seq):
i -= 1
if not i:
i = step
yield tuple(window)
size = len(window)
if size < n:
yield tuple(chain(window, repeat(fillvalue, n - size)))
elif 0 < i < min(step, n):
window += (fillvalue,) * i
yield tuple(window)
def substrings(iterable):
"""Yield all of the substrings of *iterable*.
>>> [''.join(s) for s in substrings('more')]
['m', 'o', 'r', 'e', 'mo', 'or', 're', 'mor', 'ore', 'more']
Note that non-string iterables can also be subdivided.
>>> list(substrings([0, 1, 2]))
[(0,), (1,), (2,), (0, 1), (1, 2), (0, 1, 2)]
"""
# The length-1 substrings
seq = []
for item in iter(iterable):
seq.append(item)
yield (item,)
seq = tuple(seq)
item_count = len(seq)
# And the rest
for n in range(2, item_count + 1):
for i in range(item_count - n + 1):
yield seq[i : i + n]
def substrings_indexes(seq, reverse=False):
"""Yield all substrings and their positions in *seq*
The items yielded will be a tuple of the form ``(substr, i, j)``, where
``substr == seq[i:j]``.
This function only works for iterables that support slicing, such as
``str`` objects.
>>> for item in substrings_indexes('more'):
... print(item)
('m', 0, 1)
('o', 1, 2)
('r', 2, 3)
('e', 3, 4)
('mo', 0, 2)
('or', 1, 3)
('re', 2, 4)
('mor', 0, 3)
('ore', 1, 4)
('more', 0, 4)
Set *reverse* to ``True`` to yield the same items in the opposite order.
"""
r = range(1, len(seq) + 1)
if reverse:
r = reversed(r)
return (
(seq[i : i + L], i, i + L) for L in r for i in range(len(seq) - L + 1)
)
class bucket:
"""Wrap *iterable* and return an object that buckets it iterable into
child iterables based on a *key* function.
>>> iterable = ['a1', 'b1', 'c1', 'a2', 'b2', 'c2', 'b3']
>>> s = bucket(iterable, key=lambda x: x[0]) # Bucket by 1st character
>>> sorted(list(s)) # Get the keys
['a', 'b', 'c']
>>> a_iterable = s['a']
>>> next(a_iterable)
'a1'
>>> next(a_iterable)
'a2'
>>> list(s['b'])
['b1', 'b2', 'b3']
The original iterable will be advanced and its items will be cached until
they are used by the child iterables. This may require significant storage.
By default, attempting to select a bucket to which no items belong will
exhaust the iterable and cache all values.
If you specify a *validator* function, selected buckets will instead be
checked against it.
>>> from itertools import count
>>> it = count(1, 2) # Infinite sequence of odd numbers
>>> key = lambda x: x % 10 # Bucket by last digit
>>> validator = lambda x: x in {1, 3, 5, 7, 9} # Odd digits only
>>> s = bucket(it, key=key, validator=validator)
>>> 2 in s
False
>>> list(s[2])
[]
"""
def __init__(self, iterable, key, validator=None):
self._it = iter(iterable)
self._key = key
self._cache = defaultdict(deque)
self._validator = validator or (lambda x: True)
def __contains__(self, value):
if not self._validator(value):
return False
try:
item = next(self[value])
except StopIteration:
return False
else:
self._cache[value].appendleft(item)
return True
def _get_values(self, value):
"""
Helper to yield items from the parent iterator that match *value*.
Items that don't match are stored in the local cache as they
are encountered.
"""
while True:
# If we've cached some items that match the target value, emit
# the first one and evict it from the cache.
if self._cache[value]:
yield self._cache[value].popleft()
# Otherwise we need to advance the parent iterator to search for
# a matching item, caching the rest.
else:
while True:
try:
item = next(self._it)
except StopIteration:
return
item_value = self._key(item)
if item_value == value:
yield item
break
elif self._validator(item_value):
self._cache[item_value].append(item)
def __iter__(self):
for item in self._it:
item_value = self._key(item)
if self._validator(item_value):
self._cache[item_value].append(item)
yield from self._cache.keys()
def __getitem__(self, value):
if not self._validator(value):
return iter(())
return self._get_values(value)
def spy(iterable, n=1):
"""Return a 2-tuple with a list containing the first *n* elements of
*iterable*, and an iterator with the same items as *iterable*.
This allows you to "look ahead" at the items in the iterable without
advancing it.
There is one item in the list by default:
>>> iterable = 'abcdefg'
>>> head, iterable = spy(iterable)
>>> head
['a']
>>> list(iterable)
['a', 'b', 'c', 'd', 'e', 'f', 'g']
You may use unpacking to retrieve items instead of lists:
>>> (head,), iterable = spy('abcdefg')
>>> head
'a'
>>> (first, second), iterable = spy('abcdefg', 2)
>>> first
'a'
>>> second
'b'
The number of items requested can be larger than the number of items in
the iterable:
>>> iterable = [1, 2, 3, 4, 5]
>>> head, iterable = spy(iterable, 10)
>>> head
[1, 2, 3, 4, 5]
>>> list(iterable)
[1, 2, 3, 4, 5]
"""
it = iter(iterable)
head = take(n, it)
return head.copy(), chain(head, it)
def interleave(*iterables):
"""Return a new iterable yielding from each iterable in turn,
until the shortest is exhausted.
>>> list(interleave([1, 2, 3], [4, 5], [6, 7, 8]))
[1, 4, 6, 2, 5, 7]
For a version that doesn't terminate after the shortest iterable is
exhausted, see :func:`interleave_longest`.
"""
return chain.from_iterable(zip(*iterables))
def interleave_longest(*iterables):
"""Return a new iterable yielding from each iterable in turn,
skipping any that are exhausted.
>>> list(interleave_longest([1, 2, 3], [4, 5], [6, 7, 8]))
[1, 4, 6, 2, 5, 7, 3, 8]
This function produces the same output as :func:`roundrobin`, but may
perform better for some inputs (in particular when the number of iterables
is large).
"""
i = chain.from_iterable(zip_longest(*iterables, fillvalue=_marker))
return (x for x in i if x is not _marker)
def interleave_evenly(iterables, lengths=None):
"""
Interleave multiple iterables so that their elements are evenly distributed
throughout the output sequence.
>>> iterables = [1, 2, 3, 4, 5], ['a', 'b']
>>> list(interleave_evenly(iterables))
[1, 2, 'a', 3, 4, 'b', 5]
>>> iterables = [[1, 2, 3], [4, 5], [6, 7, 8]]
>>> list(interleave_evenly(iterables))
[1, 6, 4, 2, 7, 3, 8, 5]
This function requires iterables of known length. Iterables without
``__len__()`` can be used by manually specifying lengths with *lengths*:
>>> from itertools import combinations, repeat
>>> iterables = [combinations(range(4), 2), ['a', 'b', 'c']]
>>> lengths = [4 * (4 - 1) // 2, 3]
>>> list(interleave_evenly(iterables, lengths=lengths))
[(0, 1), (0, 2), 'a', (0, 3), (1, 2), 'b', (1, 3), (2, 3), 'c']
Based on Bresenham's algorithm.
"""
if lengths is None:
try:
lengths = [len(it) for it in iterables]
except TypeError:
raise ValueError(
'Iterable lengths could not be determined automatically. '
'Specify them with the lengths keyword.'
)
elif len(iterables) != len(lengths):
raise ValueError('Mismatching number of iterables and lengths.')
dims = len(lengths)
# sort iterables by length, descending
lengths_permute = sorted(
range(dims), key=lambda i: lengths[i], reverse=True
)
lengths_desc = [lengths[i] for i in lengths_permute]
iters_desc = [iter(iterables[i]) for i in lengths_permute]
# the longest iterable is the primary one (Bresenham: the longest
# distance along an axis)
delta_primary, deltas_secondary = lengths_desc[0], lengths_desc[1:]
iter_primary, iters_secondary = iters_desc[0], iters_desc[1:]
errors = [delta_primary // dims] * len(deltas_secondary)
to_yield = sum(lengths)
while to_yield:
yield next(iter_primary)
to_yield -= 1
# update errors for each secondary iterable
errors = [e - delta for e, delta in zip(errors, deltas_secondary)]
# those iterables for which the error is negative are yielded
# ("diagonal step" in Bresenham)
for i, e in enumerate(errors):
if e < 0:
yield next(iters_secondary[i])
to_yield -= 1
errors[i] += delta_primary
def collapse(iterable, base_type=None, levels=None):
"""Flatten an iterable with multiple levels of nesting (e.g., a list of
lists of tuples) into non-iterable types.
>>> iterable = [(1, 2), ([3, 4], [[5], [6]])]
>>> list(collapse(iterable))
[1, 2, 3, 4, 5, 6]
Binary and text strings are not considered iterable and
will not be collapsed.
To avoid collapsing other types, specify *base_type*:
>>> iterable = ['ab', ('cd', 'ef'), ['gh', 'ij']]
>>> list(collapse(iterable, base_type=tuple))
['ab', ('cd', 'ef'), 'gh', 'ij']
Specify *levels* to stop flattening after a certain level:
>>> iterable = [('a', ['b']), ('c', ['d'])]
>>> list(collapse(iterable)) # Fully flattened
['a', 'b', 'c', 'd']
>>> list(collapse(iterable, levels=1)) # Only one level flattened
['a', ['b'], 'c', ['d']]
"""
def walk(node, level):
if (
((levels is not None) and (level > levels))
or isinstance(node, (str, bytes))
or ((base_type is not None) and isinstance(node, base_type))
):
yield node
return
try:
tree = iter(node)
except TypeError:
yield node
return
else:
for child in tree:
yield from walk(child, level + 1)
yield from walk(iterable, 0)
def side_effect(func, iterable, chunk_size=None, before=None, after=None):
"""Invoke *func* on each item in *iterable* (or on each *chunk_size* group
of items) before yielding the item.
`func` must be a function that takes a single argument. Its return value
will be discarded.
*before* and *after* are optional functions that take no arguments. They
will be executed before iteration starts and after it ends, respectively.
`side_effect` can be used for logging, updating progress bars, or anything
that is not functionally "pure."
Emitting a status message:
>>> from more_itertools import consume
>>> func = lambda item: print('Received {}'.format(item))
>>> consume(side_effect(func, range(2)))
Received 0
Received 1
Operating on chunks of items:
>>> pair_sums = []
>>> func = lambda chunk: pair_sums.append(sum(chunk))
>>> list(side_effect(func, [0, 1, 2, 3, 4, 5], 2))
[0, 1, 2, 3, 4, 5]
>>> list(pair_sums)
[1, 5, 9]
Writing to a file-like object:
>>> from io import StringIO
>>> from more_itertools import consume
>>> f = StringIO()
>>> func = lambda x: print(x, file=f)
>>> before = lambda: print(u'HEADER', file=f)
>>> after = f.close
>>> it = [u'a', u'b', u'c']
>>> consume(side_effect(func, it, before=before, after=after))
>>> f.closed
True
"""
try:
if before is not None:
before()
if chunk_size is None:
for item in iterable:
func(item)
yield item
else:
for chunk in chunked(iterable, chunk_size):
func(chunk)
yield from chunk
finally:
if after is not None:
after()
def sliced(seq, n, strict=False):
"""Yield slices of length *n* from the sequence *seq*.
>>> list(sliced((1, 2, 3, 4, 5, 6), 3))
[(1, 2, 3), (4, 5, 6)]
By the default, the last yielded slice will have fewer than *n* elements
if the length of *seq* is not divisible by *n*:
>>> list(sliced((1, 2, 3, 4, 5, 6, 7, 8), 3))
[(1, 2, 3), (4, 5, 6), (7, 8)]
If the length of *seq* is not divisible by *n* and *strict* is
``True``, then ``ValueError`` will be raised before the last
slice is yielded.
This function will only work for iterables that support slicing.
For non-sliceable iterables, see :func:`chunked`.
"""
iterator = takewhile(len, (seq[i : i + n] for i in count(0, n)))
if strict:
def ret():
for _slice in iterator:
if len(_slice) != n:
raise ValueError("seq is not divisible by n.")
yield _slice
return iter(ret())
else:
return iterator
def split_at(iterable, pred, maxsplit=-1, keep_separator=False):
"""Yield lists of items from *iterable*, where each list is delimited by
an item where callable *pred* returns ``True``.
>>> list(split_at('abcdcba', lambda x: x == 'b'))
[['a'], ['c', 'd', 'c'], ['a']]
>>> list(split_at(range(10), lambda n: n % 2 == 1))
[[0], [2], [4], [6], [8], []]
At most *maxsplit* splits are done. If *maxsplit* is not specified or -1,
then there is no limit on the number of splits:
>>> list(split_at(range(10), lambda n: n % 2 == 1, maxsplit=2))
[[0], [2], [4, 5, 6, 7, 8, 9]]
By default, the delimiting items are not included in the output.
The include them, set *keep_separator* to ``True``.
>>> list(split_at('abcdcba', lambda x: x == 'b', keep_separator=True))
[['a'], ['b'], ['c', 'd', 'c'], ['b'], ['a']]
"""
if maxsplit == 0:
yield list(iterable)
return
buf = []
it = iter(iterable)
for item in it:
if pred(item):
yield buf
if keep_separator:
yield [item]
if maxsplit == 1:
yield list(it)
return
buf = []
maxsplit -= 1
else:
buf.append(item)
yield buf
def split_before(iterable, pred, maxsplit=-1):
"""Yield lists of items from *iterable*, where each list ends just before
an item for which callable *pred* returns ``True``:
>>> list(split_before('OneTwo', lambda s: s.isupper()))
[['O', 'n', 'e'], ['T', 'w', 'o']]
>>> list(split_before(range(10), lambda n: n % 3 == 0))
[[0, 1, 2], [3, 4, 5], [6, 7, 8], [9]]
At most *maxsplit* splits are done. If *maxsplit* is not specified or -1,
then there is no limit on the number of splits:
>>> list(split_before(range(10), lambda n: n % 3 == 0, maxsplit=2))
[[0, 1, 2], [3, 4, 5], [6, 7, 8, 9]]
"""
if maxsplit == 0:
yield list(iterable)
return
buf = []
it = iter(iterable)
for item in it:
if pred(item) and buf:
yield buf
if maxsplit == 1:
yield [item] + list(it)
return
buf = []
maxsplit -= 1
buf.append(item)
if buf:
yield buf
def split_after(iterable, pred, maxsplit=-1):
"""Yield lists of items from *iterable*, where each list ends with an
item where callable *pred* returns ``True``:
>>> list(split_after('one1two2', lambda s: s.isdigit()))
[['o', 'n', 'e', '1'], ['t', 'w', 'o', '2']]
>>> list(split_after(range(10), lambda n: n % 3 == 0))
[[0], [1, 2, 3], [4, 5, 6], [7, 8, 9]]
At most *maxsplit* splits are done. If *maxsplit* is not specified or -1,
then there is no limit on the number of splits:
>>> list(split_after(range(10), lambda n: n % 3 == 0, maxsplit=2))
[[0], [1, 2, 3], [4, 5, 6, 7, 8, 9]]
"""
if maxsplit == 0:
yield list(iterable)
return
buf = []
it = iter(iterable)
for item in it:
buf.append(item)
if pred(item) and buf:
yield buf
if maxsplit == 1:
yield list(it)
return
buf = []
maxsplit -= 1
if buf:
yield buf
def split_when(iterable, pred, maxsplit=-1):
"""Split *iterable* into pieces based on the output of *pred*.
*pred* should be a function that takes successive pairs of items and
returns ``True`` if the iterable should be split in between them.
For example, to find runs of increasing numbers, split the iterable when
element ``i`` is larger than element ``i + 1``:
>>> list(split_when([1, 2, 3, 3, 2, 5, 2, 4, 2], lambda x, y: x > y))
[[1, 2, 3, 3], [2, 5], [2, 4], [2]]
At most *maxsplit* splits are done. If *maxsplit* is not specified or -1,
then there is no limit on the number of splits:
>>> list(split_when([1, 2, 3, 3, 2, 5, 2, 4, 2],
... lambda x, y: x > y, maxsplit=2))
[[1, 2, 3, 3], [2, 5], [2, 4, 2]]
"""
if maxsplit == 0:
yield list(iterable)
return
it = iter(iterable)
try:
cur_item = next(it)
except StopIteration:
return
buf = [cur_item]
for next_item in it:
if pred(cur_item, next_item):
yield buf
if maxsplit == 1:
yield [next_item] + list(it)
return
buf = []
maxsplit -= 1
buf.append(next_item)
cur_item = next_item
yield buf
def split_into(iterable, sizes):
"""Yield a list of sequential items from *iterable* of length 'n' for each
integer 'n' in *sizes*.
>>> list(split_into([1,2,3,4,5,6], [1,2,3]))
[[1], [2, 3], [4, 5, 6]]
If the sum of *sizes* is smaller than the length of *iterable*, then the
remaining items of *iterable* will not be returned.
>>> list(split_into([1,2,3,4,5,6], [2,3]))
[[1, 2], [3, 4, 5]]
If the sum of *sizes* is larger than the length of *iterable*, fewer items
will be returned in the iteration that overruns *iterable* and further
lists will be empty:
>>> list(split_into([1,2,3,4], [1,2,3,4]))
[[1], [2, 3], [4], []]
When a ``None`` object is encountered in *sizes*, the returned list will
contain items up to the end of *iterable* the same way that itertools.slice
does:
>>> list(split_into([1,2,3,4,5,6,7,8,9,0], [2,3,None]))
[[1, 2], [3, 4, 5], [6, 7, 8, 9, 0]]
:func:`split_into` can be useful for grouping a series of items where the
sizes of the groups are not uniform. An example would be where in a row
from a table, multiple columns represent elements of the same feature
(e.g. a point represented by x,y,z) but, the format is not the same for
all columns.
"""
# convert the iterable argument into an iterator so its contents can
# be consumed by islice in case it is a generator
it = iter(iterable)
for size in sizes:
if size is None:
yield list(it)
return
else:
yield list(islice(it, size))
def padded(iterable, fillvalue=None, n=None, next_multiple=False):
"""Yield the elements from *iterable*, followed by *fillvalue*, such that
at least *n* items are emitted.
>>> list(padded([1, 2, 3], '?', 5))
[1, 2, 3, '?', '?']
If *next_multiple* is ``True``, *fillvalue* will be emitted until the
number of items emitted is a multiple of *n*::
>>> list(padded([1, 2, 3, 4], n=3, next_multiple=True))
[1, 2, 3, 4, None, None]
If *n* is ``None``, *fillvalue* will be emitted indefinitely.
"""
it = iter(iterable)
if n is None:
yield from chain(it, repeat(fillvalue))
elif n < 1:
raise ValueError('n must be at least 1')
else:
item_count = 0
for item in it:
yield item
item_count += 1
remaining = (n - item_count) % n if next_multiple else n - item_count
for _ in range(remaining):
yield fillvalue
def repeat_each(iterable, n=2):
"""Repeat each element in *iterable* *n* times.
>>> list(repeat_each('ABC', 3))
['A', 'A', 'A', 'B', 'B', 'B', 'C', 'C', 'C']
"""
return chain.from_iterable(map(repeat, iterable, repeat(n)))
def repeat_last(iterable, default=None):
"""After the *iterable* is exhausted, keep yielding its last element.
>>> list(islice(repeat_last(range(3)), 5))
[0, 1, 2, 2, 2]
If the iterable is empty, yield *default* forever::
>>> list(islice(repeat_last(range(0), 42), 5))
[42, 42, 42, 42, 42]
"""
item = _marker
for item in iterable:
yield item
final = default if item is _marker else item
yield from repeat(final)
def distribute(n, iterable):
"""Distribute the items from *iterable* among *n* smaller iterables.
>>> group_1, group_2 = distribute(2, [1, 2, 3, 4, 5, 6])
>>> list(group_1)
[1, 3, 5]
>>> list(group_2)
[2, 4, 6]
If the length of *iterable* is not evenly divisible by *n*, then the
length of the returned iterables will not be identical:
>>> children = distribute(3, [1, 2, 3, 4, 5, 6, 7])
>>> [list(c) for c in children]
[[1, 4, 7], [2, 5], [3, 6]]
If the length of *iterable* is smaller than *n*, then the last returned
iterables will be empty:
>>> children = distribute(5, [1, 2, 3])
>>> [list(c) for c in children]
[[1], [2], [3], [], []]
This function uses :func:`itertools.tee` and may require significant
storage. If you need the order items in the smaller iterables to match the
original iterable, see :func:`divide`.
"""
if n < 1:
raise ValueError('n must be at least 1')
children = tee(iterable, n)
return [islice(it, index, None, n) for index, it in enumerate(children)]
def stagger(iterable, offsets=(-1, 0, 1), longest=False, fillvalue=None):
"""Yield tuples whose elements are offset from *iterable*.
The amount by which the `i`-th item in each tuple is offset is given by
the `i`-th item in *offsets*.
>>> list(stagger([0, 1, 2, 3]))
[(None, 0, 1), (0, 1, 2), (1, 2, 3)]
>>> list(stagger(range(8), offsets=(0, 2, 4)))
[(0, 2, 4), (1, 3, 5), (2, 4, 6), (3, 5, 7)]
By default, the sequence will end when the final element of a tuple is the
last item in the iterable. To continue until the first element of a tuple
is the last item in the iterable, set *longest* to ``True``::
>>> list(stagger([0, 1, 2, 3], longest=True))
[(None, 0, 1), (0, 1, 2), (1, 2, 3), (2, 3, None), (3, None, None)]
By default, ``None`` will be used to replace offsets beyond the end of the
sequence. Specify *fillvalue* to use some other value.
"""
children = tee(iterable, len(offsets))
return zip_offset(
*children, offsets=offsets, longest=longest, fillvalue=fillvalue
)
class UnequalIterablesError(ValueError):
def __init__(self, details=None):
msg = 'Iterables have different lengths'
if details is not None:
msg += (': index 0 has length {}; index {} has length {}').format(
*details
)
super().__init__(msg)
def _zip_equal_generator(iterables):
for combo in zip_longest(*iterables, fillvalue=_marker):
for val in combo:
if val is _marker:
raise UnequalIterablesError()
yield combo
def _zip_equal(*iterables):
# Check whether the iterables are all the same size.
try:
first_size = len(iterables[0])
for i, it in enumerate(iterables[1:], 1):
size = len(it)
if size != first_size:
break
else:
# If we didn't break out, we can use the built-in zip.
return zip(*iterables)
# If we did break out, there was a mismatch.
raise UnequalIterablesError(details=(first_size, i, size))
# If any one of the iterables didn't have a length, start reading
# them until one runs out.
except TypeError:
return _zip_equal_generator(iterables)
def zip_equal(*iterables):
"""``zip`` the input *iterables* together, but raise
``UnequalIterablesError`` if they aren't all the same length.
>>> it_1 = range(3)
>>> it_2 = iter('abc')
>>> list(zip_equal(it_1, it_2))
[(0, 'a'), (1, 'b'), (2, 'c')]
>>> it_1 = range(3)
>>> it_2 = iter('abcd')
>>> list(zip_equal(it_1, it_2)) # doctest: +IGNORE_EXCEPTION_DETAIL
Traceback (most recent call last):
...
more_itertools.more.UnequalIterablesError: Iterables have different
lengths
"""
if hexversion >= 0x30A00A6:
warnings.warn(
(
'zip_equal will be removed in a future version of '
'more-itertools. Use the builtin zip function with '
'strict=True instead.'
),
DeprecationWarning,
)
return _zip_equal(*iterables)
def zip_offset(*iterables, offsets, longest=False, fillvalue=None):
"""``zip`` the input *iterables* together, but offset the `i`-th iterable
by the `i`-th item in *offsets*.
>>> list(zip_offset('0123', 'abcdef', offsets=(0, 1)))
[('0', 'b'), ('1', 'c'), ('2', 'd'), ('3', 'e')]
This can be used as a lightweight alternative to SciPy or pandas to analyze
data sets in which some series have a lead or lag relationship.
By default, the sequence will end when the shortest iterable is exhausted.
To continue until the longest iterable is exhausted, set *longest* to
``True``.
>>> list(zip_offset('0123', 'abcdef', offsets=(0, 1), longest=True))
[('0', 'b'), ('1', 'c'), ('2', 'd'), ('3', 'e'), (None, 'f')]
By default, ``None`` will be used to replace offsets beyond the end of the
sequence. Specify *fillvalue* to use some other value.
"""
if len(iterables) != len(offsets):
raise ValueError("Number of iterables and offsets didn't match")
staggered = []
for it, n in zip(iterables, offsets):
if n < 0:
staggered.append(chain(repeat(fillvalue, -n), it))
elif n > 0:
staggered.append(islice(it, n, None))
else:
staggered.append(it)
if longest:
return zip_longest(*staggered, fillvalue=fillvalue)
return zip(*staggered)
def sort_together(iterables, key_list=(0,), key=None, reverse=False):
"""Return the input iterables sorted together, with *key_list* as the
priority for sorting. All iterables are trimmed to the length of the
shortest one.
This can be used like the sorting function in a spreadsheet. If each
iterable represents a column of data, the key list determines which
columns are used for sorting.
By default, all iterables are sorted using the ``0``-th iterable::
>>> iterables = [(4, 3, 2, 1), ('a', 'b', 'c', 'd')]
>>> sort_together(iterables)
[(1, 2, 3, 4), ('d', 'c', 'b', 'a')]
Set a different key list to sort according to another iterable.
Specifying multiple keys dictates how ties are broken::
>>> iterables = [(3, 1, 2), (0, 1, 0), ('c', 'b', 'a')]
>>> sort_together(iterables, key_list=(1, 2))
[(2, 3, 1), (0, 0, 1), ('a', 'c', 'b')]
To sort by a function of the elements of the iterable, pass a *key*
function. Its arguments are the elements of the iterables corresponding to
the key list::
>>> names = ('a', 'b', 'c')
>>> lengths = (1, 2, 3)
>>> widths = (5, 2, 1)
>>> def area(length, width):
... return length * width
>>> sort_together([names, lengths, widths], key_list=(1, 2), key=area)
[('c', 'b', 'a'), (3, 2, 1), (1, 2, 5)]
Set *reverse* to ``True`` to sort in descending order.
>>> sort_together([(1, 2, 3), ('c', 'b', 'a')], reverse=True)
[(3, 2, 1), ('a', 'b', 'c')]
"""
if key is None:
# if there is no key function, the key argument to sorted is an
# itemgetter
key_argument = itemgetter(*key_list)
else:
# if there is a key function, call it with the items at the offsets
# specified by the key function as arguments
key_list = list(key_list)
if len(key_list) == 1:
# if key_list contains a single item, pass the item at that offset
# as the only argument to the key function
key_offset = key_list[0]
key_argument = lambda zipped_items: key(zipped_items[key_offset])
else:
# if key_list contains multiple items, use itemgetter to return a
# tuple of items, which we pass as *args to the key function
get_key_items = itemgetter(*key_list)
key_argument = lambda zipped_items: key(
*get_key_items(zipped_items)
)
return list(
zip(*sorted(zip(*iterables), key=key_argument, reverse=reverse))
)
def unzip(iterable):
"""The inverse of :func:`zip`, this function disaggregates the elements
of the zipped *iterable*.
The ``i``-th iterable contains the ``i``-th element from each element
of the zipped iterable. The first element is used to to determine the
length of the remaining elements.
>>> iterable = [('a', 1), ('b', 2), ('c', 3), ('d', 4)]
>>> letters, numbers = unzip(iterable)
>>> list(letters)
['a', 'b', 'c', 'd']
>>> list(numbers)
[1, 2, 3, 4]
This is similar to using ``zip(*iterable)``, but it avoids reading
*iterable* into memory. Note, however, that this function uses
:func:`itertools.tee` and thus may require significant storage.
"""
head, iterable = spy(iter(iterable))
if not head:
# empty iterable, e.g. zip([], [], [])
return ()
# spy returns a one-length iterable as head
head = head[0]
iterables = tee(iterable, len(head))
def itemgetter(i):
def getter(obj):
try:
return obj[i]
except IndexError:
# basically if we have an iterable like
# iter([(1, 2, 3), (4, 5), (6,)])
# the second unzipped iterable would fail at the third tuple
# since it would try to access tup[1]
# same with the third unzipped iterable and the second tuple
# to support these "improperly zipped" iterables,
# we create a custom itemgetter
# which just stops the unzipped iterables
# at first length mismatch
raise StopIteration
return getter
return tuple(map(itemgetter(i), it) for i, it in enumerate(iterables))
def divide(n, iterable):
"""Divide the elements from *iterable* into *n* parts, maintaining
order.
>>> group_1, group_2 = divide(2, [1, 2, 3, 4, 5, 6])
>>> list(group_1)
[1, 2, 3]
>>> list(group_2)
[4, 5, 6]
If the length of *iterable* is not evenly divisible by *n*, then the
length of the returned iterables will not be identical:
>>> children = divide(3, [1, 2, 3, 4, 5, 6, 7])
>>> [list(c) for c in children]
[[1, 2, 3], [4, 5], [6, 7]]
If the length of the iterable is smaller than n, then the last returned
iterables will be empty:
>>> children = divide(5, [1, 2, 3])
>>> [list(c) for c in children]
[[1], [2], [3], [], []]
This function will exhaust the iterable before returning and may require
significant storage. If order is not important, see :func:`distribute`,
which does not first pull the iterable into memory.
"""
if n < 1:
raise ValueError('n must be at least 1')
try:
iterable[:0]
except TypeError:
seq = tuple(iterable)
else:
seq = iterable
q, r = divmod(len(seq), n)
ret = []
stop = 0
for i in range(1, n + 1):
start = stop
stop += q + 1 if i <= r else q
ret.append(iter(seq[start:stop]))
return ret
def always_iterable(obj, base_type=(str, bytes)):
"""If *obj* is iterable, return an iterator over its items::
>>> obj = (1, 2, 3)
>>> list(always_iterable(obj))
[1, 2, 3]
If *obj* is not iterable, return a one-item iterable containing *obj*::
>>> obj = 1
>>> list(always_iterable(obj))
[1]
If *obj* is ``None``, return an empty iterable:
>>> obj = None
>>> list(always_iterable(None))
[]
By default, binary and text strings are not considered iterable::
>>> obj = 'foo'
>>> list(always_iterable(obj))
['foo']
If *base_type* is set, objects for which ``isinstance(obj, base_type)``
returns ``True`` won't be considered iterable.
>>> obj = {'a': 1}
>>> list(always_iterable(obj)) # Iterate over the dict's keys
['a']
>>> list(always_iterable(obj, base_type=dict)) # Treat dicts as a unit
[{'a': 1}]
Set *base_type* to ``None`` to avoid any special handling and treat objects
Python considers iterable as iterable:
>>> obj = 'foo'
>>> list(always_iterable(obj, base_type=None))
['f', 'o', 'o']
"""
if obj is None:
return iter(())
if (base_type is not None) and isinstance(obj, base_type):
return iter((obj,))
try:
return iter(obj)
except TypeError:
return iter((obj,))
def adjacent(predicate, iterable, distance=1):
"""Return an iterable over `(bool, item)` tuples where the `item` is
drawn from *iterable* and the `bool` indicates whether
that item satisfies the *predicate* or is adjacent to an item that does.
For example, to find whether items are adjacent to a ``3``::
>>> list(adjacent(lambda x: x == 3, range(6)))
[(False, 0), (False, 1), (True, 2), (True, 3), (True, 4), (False, 5)]
Set *distance* to change what counts as adjacent. For example, to find
whether items are two places away from a ``3``:
>>> list(adjacent(lambda x: x == 3, range(6), distance=2))
[(False, 0), (True, 1), (True, 2), (True, 3), (True, 4), (True, 5)]
This is useful for contextualizing the results of a search function.
For example, a code comparison tool might want to identify lines that
have changed, but also surrounding lines to give the viewer of the diff
context.
The predicate function will only be called once for each item in the
iterable.
See also :func:`groupby_transform`, which can be used with this function
to group ranges of items with the same `bool` value.
"""
# Allow distance=0 mainly for testing that it reproduces results with map()
if distance < 0:
raise ValueError('distance must be at least 0')
i1, i2 = tee(iterable)
padding = [False] * distance
selected = chain(padding, map(predicate, i1), padding)
adjacent_to_selected = map(any, windowed(selected, 2 * distance + 1))
return zip(adjacent_to_selected, i2)
def groupby_transform(iterable, keyfunc=None, valuefunc=None, reducefunc=None):
"""An extension of :func:`itertools.groupby` that can apply transformations
to the grouped data.
* *keyfunc* is a function computing a key value for each item in *iterable*
* *valuefunc* is a function that transforms the individual items from
*iterable* after grouping
* *reducefunc* is a function that transforms each group of items
>>> iterable = 'aAAbBBcCC'
>>> keyfunc = lambda k: k.upper()
>>> valuefunc = lambda v: v.lower()
>>> reducefunc = lambda g: ''.join(g)
>>> list(groupby_transform(iterable, keyfunc, valuefunc, reducefunc))
[('A', 'aaa'), ('B', 'bbb'), ('C', 'ccc')]
Each optional argument defaults to an identity function if not specified.
:func:`groupby_transform` is useful when grouping elements of an iterable
using a separate iterable as the key. To do this, :func:`zip` the iterables
and pass a *keyfunc* that extracts the first element and a *valuefunc*
that extracts the second element::
>>> from operator import itemgetter
>>> keys = [0, 0, 1, 1, 1, 2, 2, 2, 3]
>>> values = 'abcdefghi'
>>> iterable = zip(keys, values)
>>> grouper = groupby_transform(iterable, itemgetter(0), itemgetter(1))
>>> [(k, ''.join(g)) for k, g in grouper]
[(0, 'ab'), (1, 'cde'), (2, 'fgh'), (3, 'i')]
Note that the order of items in the iterable is significant.
Only adjacent items are grouped together, so if you don't want any
duplicate groups, you should sort the iterable by the key function.
"""
ret = groupby(iterable, keyfunc)
if valuefunc:
ret = ((k, map(valuefunc, g)) for k, g in ret)
if reducefunc:
ret = ((k, reducefunc(g)) for k, g in ret)
return ret
class numeric_range(abc.Sequence, abc.Hashable):
"""An extension of the built-in ``range()`` function whose arguments can
be any orderable numeric type.
With only *stop* specified, *start* defaults to ``0`` and *step*
defaults to ``1``. The output items will match the type of *stop*:
>>> list(numeric_range(3.5))
[0.0, 1.0, 2.0, 3.0]
With only *start* and *stop* specified, *step* defaults to ``1``. The
output items will match the type of *start*:
>>> from decimal import Decimal
>>> start = Decimal('2.1')
>>> stop = Decimal('5.1')
>>> list(numeric_range(start, stop))
[Decimal('2.1'), Decimal('3.1'), Decimal('4.1')]
With *start*, *stop*, and *step* specified the output items will match
the type of ``start + step``:
>>> from fractions import Fraction
>>> start = Fraction(1, 2) # Start at 1/2
>>> stop = Fraction(5, 2) # End at 5/2
>>> step = Fraction(1, 2) # Count by 1/2
>>> list(numeric_range(start, stop, step))
[Fraction(1, 2), Fraction(1, 1), Fraction(3, 2), Fraction(2, 1)]
If *step* is zero, ``ValueError`` is raised. Negative steps are supported:
>>> list(numeric_range(3, -1, -1.0))
[3.0, 2.0, 1.0, 0.0]
Be aware of the limitations of floating point numbers; the representation
of the yielded numbers may be surprising.
``datetime.datetime`` objects can be used for *start* and *stop*, if *step*
is a ``datetime.timedelta`` object:
>>> import datetime
>>> start = datetime.datetime(2019, 1, 1)
>>> stop = datetime.datetime(2019, 1, 3)
>>> step = datetime.timedelta(days=1)
>>> items = iter(numeric_range(start, stop, step))
>>> next(items)
datetime.datetime(2019, 1, 1, 0, 0)
>>> next(items)
datetime.datetime(2019, 1, 2, 0, 0)
"""
_EMPTY_HASH = hash(range(0, 0))
def __init__(self, *args):
argc = len(args)
if argc == 1:
(self._stop,) = args
self._start = type(self._stop)(0)
self._step = type(self._stop - self._start)(1)
elif argc == 2:
self._start, self._stop = args
self._step = type(self._stop - self._start)(1)
elif argc == 3:
self._start, self._stop, self._step = args
elif argc == 0:
raise TypeError(
'numeric_range expected at least '
'1 argument, got {}'.format(argc)
)
else:
raise TypeError(
'numeric_range expected at most '
'3 arguments, got {}'.format(argc)
)
self._zero = type(self._step)(0)
if self._step == self._zero:
raise ValueError('numeric_range() arg 3 must not be zero')
self._growing = self._step > self._zero
self._init_len()
def __bool__(self):
if self._growing:
return self._start < self._stop
else:
return self._start > self._stop
def __contains__(self, elem):
if self._growing:
if self._start <= elem < self._stop:
return (elem - self._start) % self._step == self._zero
else:
if self._start >= elem > self._stop:
return (self._start - elem) % (-self._step) == self._zero
return False
def __eq__(self, other):
if isinstance(other, numeric_range):
empty_self = not bool(self)
empty_other = not bool(other)
if empty_self or empty_other:
return empty_self and empty_other # True if both empty
else:
return (
self._start == other._start
and self._step == other._step
and self._get_by_index(-1) == other._get_by_index(-1)
)
else:
return False
def __getitem__(self, key):
if isinstance(key, int):
return self._get_by_index(key)
elif isinstance(key, slice):
step = self._step if key.step is None else key.step * self._step
if key.start is None or key.start <= -self._len:
start = self._start
elif key.start >= self._len:
start = self._stop
else: # -self._len < key.start < self._len
start = self._get_by_index(key.start)
if key.stop is None or key.stop >= self._len:
stop = self._stop
elif key.stop <= -self._len:
stop = self._start
else: # -self._len < key.stop < self._len
stop = self._get_by_index(key.stop)
return numeric_range(start, stop, step)
else:
raise TypeError(
'numeric range indices must be '
'integers or slices, not {}'.format(type(key).__name__)
)
def __hash__(self):
if self:
return hash((self._start, self._get_by_index(-1), self._step))
else:
return self._EMPTY_HASH
def __iter__(self):
values = (self._start + (n * self._step) for n in count())
if self._growing:
return takewhile(partial(gt, self._stop), values)
else:
return takewhile(partial(lt, self._stop), values)
def __len__(self):
return self._len
def _init_len(self):
if self._growing:
start = self._start
stop = self._stop
step = self._step
else:
start = self._stop
stop = self._start
step = -self._step
distance = stop - start
if distance <= self._zero:
self._len = 0
else: # distance > 0 and step > 0: regular euclidean division
q, r = divmod(distance, step)
self._len = int(q) + int(r != self._zero)
def __reduce__(self):
return numeric_range, (self._start, self._stop, self._step)
def __repr__(self):
if self._step == 1:
return "numeric_range({}, {})".format(
repr(self._start), repr(self._stop)
)
else:
return "numeric_range({}, {}, {})".format(
repr(self._start), repr(self._stop), repr(self._step)
)
def __reversed__(self):
return iter(
numeric_range(
self._get_by_index(-1), self._start - self._step, -self._step
)
)
def count(self, value):
return int(value in self)
def index(self, value):
if self._growing:
if self._start <= value < self._stop:
q, r = divmod(value - self._start, self._step)
if r == self._zero:
return int(q)
else:
if self._start >= value > self._stop:
q, r = divmod(self._start - value, -self._step)
if r == self._zero:
return int(q)
raise ValueError("{} is not in numeric range".format(value))
def _get_by_index(self, i):
if i < 0:
i += self._len
if i < 0 or i >= self._len:
raise IndexError("numeric range object index out of range")
return self._start + i * self._step
def count_cycle(iterable, n=None):
"""Cycle through the items from *iterable* up to *n* times, yielding
the number of completed cycles along with each item. If *n* is omitted the
process repeats indefinitely.
>>> list(count_cycle('AB', 3))
[(0, 'A'), (0, 'B'), (1, 'A'), (1, 'B'), (2, 'A'), (2, 'B')]
"""
iterable = tuple(iterable)
if not iterable:
return iter(())
counter = count() if n is None else range(n)
return ((i, item) for i in counter for item in iterable)
def mark_ends(iterable):
"""Yield 3-tuples of the form ``(is_first, is_last, item)``.
>>> list(mark_ends('ABC'))
[(True, False, 'A'), (False, False, 'B'), (False, True, 'C')]
Use this when looping over an iterable to take special action on its first
and/or last items:
>>> iterable = ['Header', 100, 200, 'Footer']
>>> total = 0
>>> for is_first, is_last, item in mark_ends(iterable):
... if is_first:
... continue # Skip the header
... if is_last:
... continue # Skip the footer
... total += item
>>> print(total)
300
"""
it = iter(iterable)
try:
b = next(it)
except StopIteration:
return
try:
for i in count():
a = b
b = next(it)
yield i == 0, False, a
except StopIteration:
yield i == 0, True, a
def locate(iterable, pred=bool, window_size=None):
"""Yield the index of each item in *iterable* for which *pred* returns
``True``.
*pred* defaults to :func:`bool`, which will select truthy items:
>>> list(locate([0, 1, 1, 0, 1, 0, 0]))
[1, 2, 4]
Set *pred* to a custom function to, e.g., find the indexes for a particular
item.
>>> list(locate(['a', 'b', 'c', 'b'], lambda x: x == 'b'))
[1, 3]
If *window_size* is given, then the *pred* function will be called with
that many items. This enables searching for sub-sequences:
>>> iterable = [0, 1, 2, 3, 0, 1, 2, 3, 0, 1, 2, 3]
>>> pred = lambda *args: args == (1, 2, 3)
>>> list(locate(iterable, pred=pred, window_size=3))
[1, 5, 9]
Use with :func:`seekable` to find indexes and then retrieve the associated
items:
>>> from itertools import count
>>> from more_itertools import seekable
>>> source = (3 * n + 1 if (n % 2) else n // 2 for n in count())
>>> it = seekable(source)
>>> pred = lambda x: x > 100
>>> indexes = locate(it, pred=pred)
>>> i = next(indexes)
>>> it.seek(i)
>>> next(it)
106
"""
if window_size is None:
return compress(count(), map(pred, iterable))
if window_size < 1:
raise ValueError('window size must be at least 1')
it = windowed(iterable, window_size, fillvalue=_marker)
return compress(count(), starmap(pred, it))
def lstrip(iterable, pred):
"""Yield the items from *iterable*, but strip any from the beginning
for which *pred* returns ``True``.
For example, to remove a set of items from the start of an iterable:
>>> iterable = (None, False, None, 1, 2, None, 3, False, None)
>>> pred = lambda x: x in {None, False, ''}
>>> list(lstrip(iterable, pred))
[1, 2, None, 3, False, None]
This function is analogous to to :func:`str.lstrip`, and is essentially
an wrapper for :func:`itertools.dropwhile`.
"""
return dropwhile(pred, iterable)
def rstrip(iterable, pred):
"""Yield the items from *iterable*, but strip any from the end
for which *pred* returns ``True``.
For example, to remove a set of items from the end of an iterable:
>>> iterable = (None, False, None, 1, 2, None, 3, False, None)
>>> pred = lambda x: x in {None, False, ''}
>>> list(rstrip(iterable, pred))
[None, False, None, 1, 2, None, 3]
This function is analogous to :func:`str.rstrip`.
"""
cache = []
cache_append = cache.append
cache_clear = cache.clear
for x in iterable:
if pred(x):
cache_append(x)
else:
yield from cache
cache_clear()
yield x
def strip(iterable, pred):
"""Yield the items from *iterable*, but strip any from the
beginning and end for which *pred* returns ``True``.
For example, to remove a set of items from both ends of an iterable:
>>> iterable = (None, False, None, 1, 2, None, 3, False, None)
>>> pred = lambda x: x in {None, False, ''}
>>> list(strip(iterable, pred))
[1, 2, None, 3]
This function is analogous to :func:`str.strip`.
"""
return rstrip(lstrip(iterable, pred), pred)
class islice_extended:
"""An extension of :func:`itertools.islice` that supports negative values
for *stop*, *start*, and *step*.
>>> iterable = iter('abcdefgh')
>>> list(islice_extended(iterable, -4, -1))
['e', 'f', 'g']
Slices with negative values require some caching of *iterable*, but this
function takes care to minimize the amount of memory required.
For example, you can use a negative step with an infinite iterator:
>>> from itertools import count
>>> list(islice_extended(count(), 110, 99, -2))
[110, 108, 106, 104, 102, 100]
You can also use slice notation directly:
>>> iterable = map(str, count())
>>> it = islice_extended(iterable)[10:20:2]
>>> list(it)
['10', '12', '14', '16', '18']
"""
def __init__(self, iterable, *args):
it = iter(iterable)
if args:
self._iterable = _islice_helper(it, slice(*args))
else:
self._iterable = it
def __iter__(self):
return self
def __next__(self):
return next(self._iterable)
def __getitem__(self, key):
if isinstance(key, slice):
return islice_extended(_islice_helper(self._iterable, key))
raise TypeError('islice_extended.__getitem__ argument must be a slice')
def _islice_helper(it, s):
start = s.start
stop = s.stop
if s.step == 0:
raise ValueError('step argument must be a non-zero integer or None.')
step = s.step or 1
if step > 0:
start = 0 if (start is None) else start
if start < 0:
# Consume all but the last -start items
cache = deque(enumerate(it, 1), maxlen=-start)
len_iter = cache[-1][0] if cache else 0
# Adjust start to be positive
i = max(len_iter + start, 0)
# Adjust stop to be positive
if stop is None:
j = len_iter
elif stop >= 0:
j = min(stop, len_iter)
else:
j = max(len_iter + stop, 0)
# Slice the cache
n = j - i
if n <= 0:
return
for index, item in islice(cache, 0, n, step):
yield item
elif (stop is not None) and (stop < 0):
# Advance to the start position
next(islice(it, start, start), None)
# When stop is negative, we have to carry -stop items while
# iterating
cache = deque(islice(it, -stop), maxlen=-stop)
for index, item in enumerate(it):
cached_item = cache.popleft()
if index % step == 0:
yield cached_item
cache.append(item)
else:
# When both start and stop are positive we have the normal case
yield from islice(it, start, stop, step)
else:
start = -1 if (start is None) else start
if (stop is not None) and (stop < 0):
# Consume all but the last items
n = -stop - 1
cache = deque(enumerate(it, 1), maxlen=n)
len_iter = cache[-1][0] if cache else 0
# If start and stop are both negative they are comparable and
# we can just slice. Otherwise we can adjust start to be negative
# and then slice.
if start < 0:
i, j = start, stop
else:
i, j = min(start - len_iter, -1), None
for index, item in list(cache)[i:j:step]:
yield item
else:
# Advance to the stop position
if stop is not None:
m = stop + 1
next(islice(it, m, m), None)
# stop is positive, so if start is negative they are not comparable
# and we need the rest of the items.
if start < 0:
i = start
n = None
# stop is None and start is positive, so we just need items up to
# the start index.
elif stop is None:
i = None
n = start + 1
# Both stop and start are positive, so they are comparable.
else:
i = None
n = start - stop
if n <= 0:
return
cache = list(islice(it, n))
yield from cache[i::step]
def always_reversible(iterable):
"""An extension of :func:`reversed` that supports all iterables, not
just those which implement the ``Reversible`` or ``Sequence`` protocols.
>>> print(*always_reversible(x for x in range(3)))
2 1 0
If the iterable is already reversible, this function returns the
result of :func:`reversed()`. If the iterable is not reversible,
this function will cache the remaining items in the iterable and
yield them in reverse order, which may require significant storage.
"""
try:
return reversed(iterable)
except TypeError:
return reversed(list(iterable))
def consecutive_groups(iterable, ordering=lambda x: x):
"""Yield groups of consecutive items using :func:`itertools.groupby`.
The *ordering* function determines whether two items are adjacent by
returning their position.
By default, the ordering function is the identity function. This is
suitable for finding runs of numbers:
>>> iterable = [1, 10, 11, 12, 20, 30, 31, 32, 33, 40]
>>> for group in consecutive_groups(iterable):
... print(list(group))
[1]
[10, 11, 12]
[20]
[30, 31, 32, 33]
[40]
For finding runs of adjacent letters, try using the :meth:`index` method
of a string of letters:
>>> from string import ascii_lowercase
>>> iterable = 'abcdfgilmnop'
>>> ordering = ascii_lowercase.index
>>> for group in consecutive_groups(iterable, ordering):
... print(list(group))
['a', 'b', 'c', 'd']
['f', 'g']
['i']
['l', 'm', 'n', 'o', 'p']
Each group of consecutive items is an iterator that shares it source with
*iterable*. When an an output group is advanced, the previous group is
no longer available unless its elements are copied (e.g., into a ``list``).
>>> iterable = [1, 2, 11, 12, 21, 22]
>>> saved_groups = []
>>> for group in consecutive_groups(iterable):
... saved_groups.append(list(group)) # Copy group elements
>>> saved_groups
[[1, 2], [11, 12], [21, 22]]
"""
for k, g in groupby(
enumerate(iterable), key=lambda x: x[0] - ordering(x[1])
):
yield map(itemgetter(1), g)
def difference(iterable, func=sub, *, initial=None):
"""This function is the inverse of :func:`itertools.accumulate`. By default
it will compute the first difference of *iterable* using
:func:`operator.sub`:
>>> from itertools import accumulate
>>> iterable = accumulate([0, 1, 2, 3, 4]) # produces 0, 1, 3, 6, 10
>>> list(difference(iterable))
[0, 1, 2, 3, 4]
*func* defaults to :func:`operator.sub`, but other functions can be
specified. They will be applied as follows::
A, B, C, D, ... --> A, func(B, A), func(C, B), func(D, C), ...
For example, to do progressive division:
>>> iterable = [1, 2, 6, 24, 120]
>>> func = lambda x, y: x // y
>>> list(difference(iterable, func))
[1, 2, 3, 4, 5]
If the *initial* keyword is set, the first element will be skipped when
computing successive differences.
>>> it = [10, 11, 13, 16] # from accumulate([1, 2, 3], initial=10)
>>> list(difference(it, initial=10))
[1, 2, 3]
"""
a, b = tee(iterable)
try:
first = [next(b)]
except StopIteration:
return iter([])
if initial is not None:
first = []
return chain(first, starmap(func, zip(b, a)))
class SequenceView(Sequence):
"""Return a read-only view of the sequence object *target*.
:class:`SequenceView` objects are analogous to Python's built-in
"dictionary view" types. They provide a dynamic view of a sequence's items,
meaning that when the sequence updates, so does the view.
>>> seq = ['0', '1', '2']
>>> view = SequenceView(seq)
>>> view
SequenceView(['0', '1', '2'])
>>> seq.append('3')
>>> view
SequenceView(['0', '1', '2', '3'])
Sequence views support indexing, slicing, and length queries. They act
like the underlying sequence, except they don't allow assignment:
>>> view[1]
'1'
>>> view[1:-1]
['1', '2']
>>> len(view)
4
Sequence views are useful as an alternative to copying, as they don't
require (much) extra storage.
"""
def __init__(self, target):
if not isinstance(target, Sequence):
raise TypeError
self._target = target
def __getitem__(self, index):
return self._target[index]
def __len__(self):
return len(self._target)
def __repr__(self):
return '{}({})'.format(self.__class__.__name__, repr(self._target))
class seekable:
"""Wrap an iterator to allow for seeking backward and forward. This
progressively caches the items in the source iterable so they can be
re-visited.
Call :meth:`seek` with an index to seek to that position in the source
iterable.
To "reset" an iterator, seek to ``0``:
>>> from itertools import count
>>> it = seekable((str(n) for n in count()))
>>> next(it), next(it), next(it)
('0', '1', '2')
>>> it.seek(0)
>>> next(it), next(it), next(it)
('0', '1', '2')
>>> next(it)
'3'
You can also seek forward:
>>> it = seekable((str(n) for n in range(20)))
>>> it.seek(10)
>>> next(it)
'10'
>>> it.seek(20) # Seeking past the end of the source isn't a problem
>>> list(it)
[]
>>> it.seek(0) # Resetting works even after hitting the end
>>> next(it), next(it), next(it)
('0', '1', '2')
Call :meth:`peek` to look ahead one item without advancing the iterator:
>>> it = seekable('1234')
>>> it.peek()
'1'
>>> list(it)
['1', '2', '3', '4']
>>> it.peek(default='empty')
'empty'
Before the iterator is at its end, calling :func:`bool` on it will return
``True``. After it will return ``False``:
>>> it = seekable('5678')
>>> bool(it)
True
>>> list(it)
['5', '6', '7', '8']
>>> bool(it)
False
You may view the contents of the cache with the :meth:`elements` method.
That returns a :class:`SequenceView`, a view that updates automatically:
>>> it = seekable((str(n) for n in range(10)))
>>> next(it), next(it), next(it)
('0', '1', '2')
>>> elements = it.elements()
>>> elements
SequenceView(['0', '1', '2'])
>>> next(it)
'3'
>>> elements
SequenceView(['0', '1', '2', '3'])
By default, the cache grows as the source iterable progresses, so beware of
wrapping very large or infinite iterables. Supply *maxlen* to limit the
size of the cache (this of course limits how far back you can seek).
>>> from itertools import count
>>> it = seekable((str(n) for n in count()), maxlen=2)
>>> next(it), next(it), next(it), next(it)
('0', '1', '2', '3')
>>> list(it.elements())
['2', '3']
>>> it.seek(0)
>>> next(it), next(it), next(it), next(it)
('2', '3', '4', '5')
>>> next(it)
'6'
"""
def __init__(self, iterable, maxlen=None):
self._source = iter(iterable)
if maxlen is None:
self._cache = []
else:
self._cache = deque([], maxlen)
self._index = None
def __iter__(self):
return self
def __next__(self):
if self._index is not None:
try:
item = self._cache[self._index]
except IndexError:
self._index = None
else:
self._index += 1
return item
item = next(self._source)
self._cache.append(item)
return item
def __bool__(self):
try:
self.peek()
except StopIteration:
return False
return True
def peek(self, default=_marker):
try:
peeked = next(self)
except StopIteration:
if default is _marker:
raise
return default
if self._index is None:
self._index = len(self._cache)
self._index -= 1
return peeked
def elements(self):
return SequenceView(self._cache)
def seek(self, index):
self._index = index
remainder = index - len(self._cache)
if remainder > 0:
consume(self, remainder)
class run_length:
"""
:func:`run_length.encode` compresses an iterable with run-length encoding.
It yields groups of repeated items with the count of how many times they
were repeated:
>>> uncompressed = 'abbcccdddd'
>>> list(run_length.encode(uncompressed))
[('a', 1), ('b', 2), ('c', 3), ('d', 4)]
:func:`run_length.decode` decompresses an iterable that was previously
compressed with run-length encoding. It yields the items of the
decompressed iterable:
>>> compressed = [('a', 1), ('b', 2), ('c', 3), ('d', 4)]
>>> list(run_length.decode(compressed))
['a', 'b', 'b', 'c', 'c', 'c', 'd', 'd', 'd', 'd']
"""
@staticmethod
def encode(iterable):
return ((k, ilen(g)) for k, g in groupby(iterable))
@staticmethod
def decode(iterable):
return chain.from_iterable(repeat(k, n) for k, n in iterable)
def exactly_n(iterable, n, predicate=bool):
"""Return ``True`` if exactly ``n`` items in the iterable are ``True``
according to the *predicate* function.
>>> exactly_n([True, True, False], 2)
True
>>> exactly_n([True, True, False], 1)
False
>>> exactly_n([0, 1, 2, 3, 4, 5], 3, lambda x: x < 3)
True
The iterable will be advanced until ``n + 1`` truthy items are encountered,
so avoid calling it on infinite iterables.
"""
return len(take(n + 1, filter(predicate, iterable))) == n
def circular_shifts(iterable):
"""Return a list of circular shifts of *iterable*.
>>> circular_shifts(range(4))
[(0, 1, 2, 3), (1, 2, 3, 0), (2, 3, 0, 1), (3, 0, 1, 2)]
"""
lst = list(iterable)
return take(len(lst), windowed(cycle(lst), len(lst)))
def make_decorator(wrapping_func, result_index=0):
"""Return a decorator version of *wrapping_func*, which is a function that
modifies an iterable. *result_index* is the position in that function's
signature where the iterable goes.
This lets you use itertools on the "production end," i.e. at function
definition. This can augment what the function returns without changing the
function's code.
For example, to produce a decorator version of :func:`chunked`:
>>> from more_itertools import chunked
>>> chunker = make_decorator(chunked, result_index=0)
>>> @chunker(3)
... def iter_range(n):
... return iter(range(n))
...
>>> list(iter_range(9))
[[0, 1, 2], [3, 4, 5], [6, 7, 8]]
To only allow truthy items to be returned:
>>> truth_serum = make_decorator(filter, result_index=1)
>>> @truth_serum(bool)
... def boolean_test():
... return [0, 1, '', ' ', False, True]
...
>>> list(boolean_test())
[1, ' ', True]
The :func:`peekable` and :func:`seekable` wrappers make for practical
decorators:
>>> from more_itertools import peekable
>>> peekable_function = make_decorator(peekable)
>>> @peekable_function()
... def str_range(*args):
... return (str(x) for x in range(*args))
...
>>> it = str_range(1, 20, 2)
>>> next(it), next(it), next(it)
('1', '3', '5')
>>> it.peek()
'7'
>>> next(it)
'7'
"""
# See https://sites.google.com/site/bbayles/index/decorator_factory for
# notes on how this works.
def decorator(*wrapping_args, **wrapping_kwargs):
def outer_wrapper(f):
def inner_wrapper(*args, **kwargs):
result = f(*args, **kwargs)
wrapping_args_ = list(wrapping_args)
wrapping_args_.insert(result_index, result)
return wrapping_func(*wrapping_args_, **wrapping_kwargs)
return inner_wrapper
return outer_wrapper
return decorator
def map_reduce(iterable, keyfunc, valuefunc=None, reducefunc=None):
"""Return a dictionary that maps the items in *iterable* to categories
defined by *keyfunc*, transforms them with *valuefunc*, and
then summarizes them by category with *reducefunc*.
*valuefunc* defaults to the identity function if it is unspecified.
If *reducefunc* is unspecified, no summarization takes place:
>>> keyfunc = lambda x: x.upper()
>>> result = map_reduce('abbccc', keyfunc)
>>> sorted(result.items())
[('A', ['a']), ('B', ['b', 'b']), ('C', ['c', 'c', 'c'])]
Specifying *valuefunc* transforms the categorized items:
>>> keyfunc = lambda x: x.upper()
>>> valuefunc = lambda x: 1
>>> result = map_reduce('abbccc', keyfunc, valuefunc)
>>> sorted(result.items())
[('A', [1]), ('B', [1, 1]), ('C', [1, 1, 1])]
Specifying *reducefunc* summarizes the categorized items:
>>> keyfunc = lambda x: x.upper()
>>> valuefunc = lambda x: 1
>>> reducefunc = sum
>>> result = map_reduce('abbccc', keyfunc, valuefunc, reducefunc)
>>> sorted(result.items())
[('A', 1), ('B', 2), ('C', 3)]
You may want to filter the input iterable before applying the map/reduce
procedure:
>>> all_items = range(30)
>>> items = [x for x in all_items if 10 <= x <= 20] # Filter
>>> keyfunc = lambda x: x % 2 # Evens map to 0; odds to 1
>>> categories = map_reduce(items, keyfunc=keyfunc)
>>> sorted(categories.items())
[(0, [10, 12, 14, 16, 18, 20]), (1, [11, 13, 15, 17, 19])]
>>> summaries = map_reduce(items, keyfunc=keyfunc, reducefunc=sum)
>>> sorted(summaries.items())
[(0, 90), (1, 75)]
Note that all items in the iterable are gathered into a list before the
summarization step, which may require significant storage.
The returned object is a :obj:`collections.defaultdict` with the
``default_factory`` set to ``None``, such that it behaves like a normal
dictionary.
"""
valuefunc = (lambda x: x) if (valuefunc is None) else valuefunc
ret = defaultdict(list)
for item in iterable:
key = keyfunc(item)
value = valuefunc(item)
ret[key].append(value)
if reducefunc is not None:
for key, value_list in ret.items():
ret[key] = reducefunc(value_list)
ret.default_factory = None
return ret
def rlocate(iterable, pred=bool, window_size=None):
"""Yield the index of each item in *iterable* for which *pred* returns
``True``, starting from the right and moving left.
*pred* defaults to :func:`bool`, which will select truthy items:
>>> list(rlocate([0, 1, 1, 0, 1, 0, 0])) # Truthy at 1, 2, and 4
[4, 2, 1]
Set *pred* to a custom function to, e.g., find the indexes for a particular
item:
>>> iterable = iter('abcb')
>>> pred = lambda x: x == 'b'
>>> list(rlocate(iterable, pred))
[3, 1]
If *window_size* is given, then the *pred* function will be called with
that many items. This enables searching for sub-sequences:
>>> iterable = [0, 1, 2, 3, 0, 1, 2, 3, 0, 1, 2, 3]
>>> pred = lambda *args: args == (1, 2, 3)
>>> list(rlocate(iterable, pred=pred, window_size=3))
[9, 5, 1]
Beware, this function won't return anything for infinite iterables.
If *iterable* is reversible, ``rlocate`` will reverse it and search from
the right. Otherwise, it will search from the left and return the results
in reverse order.
See :func:`locate` to for other example applications.
"""
if window_size is None:
try:
len_iter = len(iterable)
return (len_iter - i - 1 for i in locate(reversed(iterable), pred))
except TypeError:
pass
return reversed(list(locate(iterable, pred, window_size)))
def replace(iterable, pred, substitutes, count=None, window_size=1):
"""Yield the items from *iterable*, replacing the items for which *pred*
returns ``True`` with the items from the iterable *substitutes*.
>>> iterable = [1, 1, 0, 1, 1, 0, 1, 1]
>>> pred = lambda x: x == 0
>>> substitutes = (2, 3)
>>> list(replace(iterable, pred, substitutes))
[1, 1, 2, 3, 1, 1, 2, 3, 1, 1]
If *count* is given, the number of replacements will be limited:
>>> iterable = [1, 1, 0, 1, 1, 0, 1, 1, 0]
>>> pred = lambda x: x == 0
>>> substitutes = [None]
>>> list(replace(iterable, pred, substitutes, count=2))
[1, 1, None, 1, 1, None, 1, 1, 0]
Use *window_size* to control the number of items passed as arguments to
*pred*. This allows for locating and replacing subsequences.
>>> iterable = [0, 1, 2, 5, 0, 1, 2, 5]
>>> window_size = 3
>>> pred = lambda *args: args == (0, 1, 2) # 3 items passed to pred
>>> substitutes = [3, 4] # Splice in these items
>>> list(replace(iterable, pred, substitutes, window_size=window_size))
[3, 4, 5, 3, 4, 5]
"""
if window_size < 1:
raise ValueError('window_size must be at least 1')
# Save the substitutes iterable, since it's used more than once
substitutes = tuple(substitutes)
# Add padding such that the number of windows matches the length of the
# iterable
it = chain(iterable, [_marker] * (window_size - 1))
windows = windowed(it, window_size)
n = 0
for w in windows:
# If the current window matches our predicate (and we haven't hit
# our maximum number of replacements), splice in the substitutes
# and then consume the following windows that overlap with this one.
# For example, if the iterable is (0, 1, 2, 3, 4...)
# and the window size is 2, we have (0, 1), (1, 2), (2, 3)...
# If the predicate matches on (0, 1), we need to zap (0, 1) and (1, 2)
if pred(*w):
if (count is None) or (n < count):
n += 1
yield from substitutes
consume(windows, window_size - 1)
continue
# If there was no match (or we've reached the replacement limit),
# yield the first item from the window.
if w and (w[0] is not _marker):
yield w[0]
def partitions(iterable):
"""Yield all possible order-preserving partitions of *iterable*.
>>> iterable = 'abc'
>>> for part in partitions(iterable):
... print([''.join(p) for p in part])
['abc']
['a', 'bc']
['ab', 'c']
['a', 'b', 'c']
This is unrelated to :func:`partition`.
"""
sequence = list(iterable)
n = len(sequence)
for i in powerset(range(1, n)):
yield [sequence[i:j] for i, j in zip((0,) + i, i + (n,))]
def set_partitions(iterable, k=None):
"""
Yield the set partitions of *iterable* into *k* parts. Set partitions are
not order-preserving.
>>> iterable = 'abc'
>>> for part in set_partitions(iterable, 2):
... print([''.join(p) for p in part])
['a', 'bc']
['ab', 'c']
['b', 'ac']
If *k* is not given, every set partition is generated.
>>> iterable = 'abc'
>>> for part in set_partitions(iterable):
... print([''.join(p) for p in part])
['abc']
['a', 'bc']
['ab', 'c']
['b', 'ac']
['a', 'b', 'c']
"""
L = list(iterable)
n = len(L)
if k is not None:
if k < 1:
raise ValueError(
"Can't partition in a negative or zero number of groups"
)
elif k > n:
return
def set_partitions_helper(L, k):
n = len(L)
if k == 1:
yield [L]
elif n == k:
yield [[s] for s in L]
else:
e, *M = L
for p in set_partitions_helper(M, k - 1):
yield [[e], *p]
for p in set_partitions_helper(M, k):
for i in range(len(p)):
yield p[:i] + [[e] + p[i]] + p[i + 1 :]
if k is None:
for k in range(1, n + 1):
yield from set_partitions_helper(L, k)
else:
yield from set_partitions_helper(L, k)
class time_limited:
"""
Yield items from *iterable* until *limit_seconds* have passed.
If the time limit expires before all items have been yielded, the
``timed_out`` parameter will be set to ``True``.
>>> from time import sleep
>>> def generator():
... yield 1
... yield 2
... sleep(0.2)
... yield 3
>>> iterable = time_limited(0.1, generator())
>>> list(iterable)
[1, 2]
>>> iterable.timed_out
True
Note that the time is checked before each item is yielded, and iteration
stops if the time elapsed is greater than *limit_seconds*. If your time
limit is 1 second, but it takes 2 seconds to generate the first item from
the iterable, the function will run for 2 seconds and not yield anything.
"""
def __init__(self, limit_seconds, iterable):
if limit_seconds < 0:
raise ValueError('limit_seconds must be positive')
self.limit_seconds = limit_seconds
self._iterable = iter(iterable)
self._start_time = monotonic()
self.timed_out = False
def __iter__(self):
return self
def __next__(self):
item = next(self._iterable)
if monotonic() - self._start_time > self.limit_seconds:
self.timed_out = True
raise StopIteration
return item
def only(iterable, default=None, too_long=None):
"""If *iterable* has only one item, return it.
If it has zero items, return *default*.
If it has more than one item, raise the exception given by *too_long*,
which is ``ValueError`` by default.
>>> only([], default='missing')
'missing'
>>> only([1])
1
>>> only([1, 2]) # doctest: +IGNORE_EXCEPTION_DETAIL
Traceback (most recent call last):
...
ValueError: Expected exactly one item in iterable, but got 1, 2,
and perhaps more.'
>>> only([1, 2], too_long=TypeError) # doctest: +IGNORE_EXCEPTION_DETAIL
Traceback (most recent call last):
...
TypeError
Note that :func:`only` attempts to advance *iterable* twice to ensure there
is only one item. See :func:`spy` or :func:`peekable` to check
iterable contents less destructively.
"""
it = iter(iterable)
first_value = next(it, default)
try:
second_value = next(it)
except StopIteration:
pass
else:
msg = (
'Expected exactly one item in iterable, but got {!r}, {!r}, '
'and perhaps more.'.format(first_value, second_value)
)
raise too_long or ValueError(msg)
return first_value
def ichunked(iterable, n):
"""Break *iterable* into sub-iterables with *n* elements each.
:func:`ichunked` is like :func:`chunked`, but it yields iterables
instead of lists.
If the sub-iterables are read in order, the elements of *iterable*
won't be stored in memory.
If they are read out of order, :func:`itertools.tee` is used to cache
elements as necessary.
>>> from itertools import count
>>> all_chunks = ichunked(count(), 4)
>>> c_1, c_2, c_3 = next(all_chunks), next(all_chunks), next(all_chunks)
>>> list(c_2) # c_1's elements have been cached; c_3's haven't been
[4, 5, 6, 7]
>>> list(c_1)
[0, 1, 2, 3]
>>> list(c_3)
[8, 9, 10, 11]
"""
source = iter(iterable)
while True:
# Check to see whether we're at the end of the source iterable
item = next(source, _marker)
if item is _marker:
return
# Clone the source and yield an n-length slice
source, it = tee(chain([item], source))
yield islice(it, n)
# Advance the source iterable
consume(source, n)
def distinct_combinations(iterable, r):
"""Yield the distinct combinations of *r* items taken from *iterable*.
>>> list(distinct_combinations([0, 0, 1], 2))
[(0, 0), (0, 1)]
Equivalent to ``set(combinations(iterable))``, except duplicates are not
generated and thrown away. For larger input sequences this is much more
efficient.
"""
if r < 0:
raise ValueError('r must be non-negative')
elif r == 0:
yield ()
return
pool = tuple(iterable)
generators = [unique_everseen(enumerate(pool), key=itemgetter(1))]
current_combo = [None] * r
level = 0
while generators:
try:
cur_idx, p = next(generators[-1])
except StopIteration:
generators.pop()
level -= 1
continue
current_combo[level] = p
if level + 1 == r:
yield tuple(current_combo)
else:
generators.append(
unique_everseen(
enumerate(pool[cur_idx + 1 :], cur_idx + 1),
key=itemgetter(1),
)
)
level += 1
def filter_except(validator, iterable, *exceptions):
"""Yield the items from *iterable* for which the *validator* function does
not raise one of the specified *exceptions*.
*validator* is called for each item in *iterable*.
It should be a function that accepts one argument and raises an exception
if that item is not valid.
>>> iterable = ['1', '2', 'three', '4', None]
>>> list(filter_except(int, iterable, ValueError, TypeError))
['1', '2', '4']
If an exception other than one given by *exceptions* is raised by
*validator*, it is raised like normal.
"""
for item in iterable:
try:
validator(item)
except exceptions:
pass
else:
yield item
def map_except(function, iterable, *exceptions):
"""Transform each item from *iterable* with *function* and yield the
result, unless *function* raises one of the specified *exceptions*.
*function* is called to transform each item in *iterable*.
It should accept one argument.
>>> iterable = ['1', '2', 'three', '4', None]
>>> list(map_except(int, iterable, ValueError, TypeError))
[1, 2, 4]
If an exception other than one given by *exceptions* is raised by
*function*, it is raised like normal.
"""
for item in iterable:
try:
yield function(item)
except exceptions:
pass
def map_if(iterable, pred, func, func_else=lambda x: x):
"""Evaluate each item from *iterable* using *pred*. If the result is
equivalent to ``True``, transform the item with *func* and yield it.
Otherwise, transform the item with *func_else* and yield it.
*pred*, *func*, and *func_else* should each be functions that accept
one argument. By default, *func_else* is the identity function.
>>> from math import sqrt
>>> iterable = list(range(-5, 5))
>>> iterable
[-5, -4, -3, -2, -1, 0, 1, 2, 3, 4]
>>> list(map_if(iterable, lambda x: x > 3, lambda x: 'toobig'))
[-5, -4, -3, -2, -1, 0, 1, 2, 3, 'toobig']
>>> list(map_if(iterable, lambda x: x >= 0,
... lambda x: f'{sqrt(x):.2f}', lambda x: None))
[None, None, None, None, None, '0.00', '1.00', '1.41', '1.73', '2.00']
"""
for item in iterable:
yield func(item) if pred(item) else func_else(item)
def _sample_unweighted(iterable, k):
# Implementation of "Algorithm L" from the 1994 paper by Kim-Hung Li:
# "Reservoir-Sampling Algorithms of Time Complexity O(n(1+log(N/n)))".
# Fill up the reservoir (collection of samples) with the first `k` samples
reservoir = take(k, iterable)
# Generate random number that's the largest in a sample of k U(0,1) numbers
# Largest order statistic: https://en.wikipedia.org/wiki/Order_statistic
W = exp(log(random()) / k)
# The number of elements to skip before changing the reservoir is a random
# number with a geometric distribution. Sample it using random() and logs.
next_index = k + floor(log(random()) / log(1 - W))
for index, element in enumerate(iterable, k):
if index == next_index:
reservoir[randrange(k)] = element
# The new W is the largest in a sample of k U(0, `old_W`) numbers
W *= exp(log(random()) / k)
next_index += floor(log(random()) / log(1 - W)) + 1
return reservoir
def _sample_weighted(iterable, k, weights):
# Implementation of "A-ExpJ" from the 2006 paper by Efraimidis et al. :
# "Weighted random sampling with a reservoir".
# Log-transform for numerical stability for weights that are small/large
weight_keys = (log(random()) / weight for weight in weights)
# Fill up the reservoir (collection of samples) with the first `k`
# weight-keys and elements, then heapify the list.
reservoir = take(k, zip(weight_keys, iterable))
heapify(reservoir)
# The number of jumps before changing the reservoir is a random variable
# with an exponential distribution. Sample it using random() and logs.
smallest_weight_key, _ = reservoir[0]
weights_to_skip = log(random()) / smallest_weight_key
for weight, element in zip(weights, iterable):
if weight >= weights_to_skip:
# The notation here is consistent with the paper, but we store
# the weight-keys in log-space for better numerical stability.
smallest_weight_key, _ = reservoir[0]
t_w = exp(weight * smallest_weight_key)
r_2 = uniform(t_w, 1) # generate U(t_w, 1)
weight_key = log(r_2) / weight
heapreplace(reservoir, (weight_key, element))
smallest_weight_key, _ = reservoir[0]
weights_to_skip = log(random()) / smallest_weight_key
else:
weights_to_skip -= weight
# Equivalent to [element for weight_key, element in sorted(reservoir)]
return [heappop(reservoir)[1] for _ in range(k)]
def sample(iterable, k, weights=None):
"""Return a *k*-length list of elements chosen (without replacement)
from the *iterable*. Like :func:`random.sample`, but works on iterables
of unknown length.
>>> iterable = range(100)
>>> sample(iterable, 5) # doctest: +SKIP
[81, 60, 96, 16, 4]
An iterable with *weights* may also be given:
>>> iterable = range(100)
>>> weights = (i * i + 1 for i in range(100))
>>> sampled = sample(iterable, 5, weights=weights) # doctest: +SKIP
[79, 67, 74, 66, 78]
The algorithm can also be used to generate weighted random permutations.
The relative weight of each item determines the probability that it
appears late in the permutation.
>>> data = "abcdefgh"
>>> weights = range(1, len(data) + 1)
>>> sample(data, k=len(data), weights=weights) # doctest: +SKIP
['c', 'a', 'b', 'e', 'g', 'd', 'h', 'f']
"""
if k == 0:
return []
iterable = iter(iterable)
if weights is None:
return _sample_unweighted(iterable, k)
else:
weights = iter(weights)
return _sample_weighted(iterable, k, weights)
def is_sorted(iterable, key=None, reverse=False, strict=False):
"""Returns ``True`` if the items of iterable are in sorted order, and
``False`` otherwise. *key* and *reverse* have the same meaning that they do
in the built-in :func:`sorted` function.
>>> is_sorted(['1', '2', '3', '4', '5'], key=int)
True
>>> is_sorted([5, 4, 3, 1, 2], reverse=True)
False
If *strict*, tests for strict sorting, that is, returns ``False`` if equal
elements are found:
>>> is_sorted([1, 2, 2])
True
>>> is_sorted([1, 2, 2], strict=True)
False
The function returns ``False`` after encountering the first out-of-order
item. If there are no out-of-order items, the iterable is exhausted.
"""
compare = (le if reverse else ge) if strict else (lt if reverse else gt)
it = iterable if key is None else map(key, iterable)
return not any(starmap(compare, pairwise(it)))
class AbortThread(BaseException):
pass
class callback_iter:
"""Convert a function that uses callbacks to an iterator.
Let *func* be a function that takes a `callback` keyword argument.
For example:
>>> def func(callback=None):
... for i, c in [(1, 'a'), (2, 'b'), (3, 'c')]:
... if callback:
... callback(i, c)
... return 4
Use ``with callback_iter(func)`` to get an iterator over the parameters
that are delivered to the callback.
>>> with callback_iter(func) as it:
... for args, kwargs in it:
... print(args)
(1, 'a')
(2, 'b')
(3, 'c')
The function will be called in a background thread. The ``done`` property
indicates whether it has completed execution.
>>> it.done
True
If it completes successfully, its return value will be available
in the ``result`` property.
>>> it.result
4
Notes:
* If the function uses some keyword argument besides ``callback``, supply
*callback_kwd*.
* If it finished executing, but raised an exception, accessing the
``result`` property will raise the same exception.
* If it hasn't finished executing, accessing the ``result``
property from within the ``with`` block will raise ``RuntimeError``.
* If it hasn't finished executing, accessing the ``result`` property from
outside the ``with`` block will raise a
``more_itertools.AbortThread`` exception.
* Provide *wait_seconds* to adjust how frequently the it is polled for
output.
"""
def __init__(self, func, callback_kwd='callback', wait_seconds=0.1):
self._func = func
self._callback_kwd = callback_kwd
self._aborted = False
self._future = None
self._wait_seconds = wait_seconds
self._executor = __import__("concurrent.futures").futures.ThreadPoolExecutor(max_workers=1)
self._iterator = self._reader()
def __enter__(self):
return self
def __exit__(self, exc_type, exc_value, traceback):
self._aborted = True
self._executor.shutdown()
def __iter__(self):
return self
def __next__(self):
return next(self._iterator)
@property
def done(self):
if self._future is None:
return False
return self._future.done()
@property
def result(self):
if not self.done:
raise RuntimeError('Function has not yet completed')
return self._future.result()
def _reader(self):
q = Queue()
def callback(*args, **kwargs):
if self._aborted:
raise AbortThread('canceled by user')
q.put((args, kwargs))
self._future = self._executor.submit(
self._func, **{self._callback_kwd: callback}
)
while True:
try:
item = q.get(timeout=self._wait_seconds)
except Empty:
pass
else:
q.task_done()
yield item
if self._future.done():
break
remaining = []
while True:
try:
item = q.get_nowait()
except Empty:
break
else:
q.task_done()
remaining.append(item)
q.join()
yield from remaining
def windowed_complete(iterable, n):
"""
Yield ``(beginning, middle, end)`` tuples, where:
* Each ``middle`` has *n* items from *iterable*
* Each ``beginning`` has the items before the ones in ``middle``
* Each ``end`` has the items after the ones in ``middle``
>>> iterable = range(7)
>>> n = 3
>>> for beginning, middle, end in windowed_complete(iterable, n):
... print(beginning, middle, end)
() (0, 1, 2) (3, 4, 5, 6)
(0,) (1, 2, 3) (4, 5, 6)
(0, 1) (2, 3, 4) (5, 6)
(0, 1, 2) (3, 4, 5) (6,)
(0, 1, 2, 3) (4, 5, 6) ()
Note that *n* must be at least 0 and most equal to the length of
*iterable*.
This function will exhaust the iterable and may require significant
storage.
"""
if n < 0:
raise ValueError('n must be >= 0')
seq = tuple(iterable)
size = len(seq)
if n > size:
raise ValueError('n must be <= len(seq)')
for i in range(size - n + 1):
beginning = seq[:i]
middle = seq[i : i + n]
end = seq[i + n :]
yield beginning, middle, end
def all_unique(iterable, key=None):
"""
Returns ``True`` if all the elements of *iterable* are unique (no two
elements are equal).
>>> all_unique('ABCB')
False
If a *key* function is specified, it will be used to make comparisons.
>>> all_unique('ABCb')
True
>>> all_unique('ABCb', str.lower)
False
The function returns as soon as the first non-unique element is
encountered. Iterables with a mix of hashable and unhashable items can
be used, but the function will be slower for unhashable items.
"""
seenset = set()
seenset_add = seenset.add
seenlist = []
seenlist_add = seenlist.append
for element in map(key, iterable) if key else iterable:
try:
if element in seenset:
return False
seenset_add(element)
except TypeError:
if element in seenlist:
return False
seenlist_add(element)
return True
def nth_product(index, *args):
"""Equivalent to ``list(product(*args))[index]``.
The products of *args* can be ordered lexicographically.
:func:`nth_product` computes the product at sort position *index* without
computing the previous products.
>>> nth_product(8, range(2), range(2), range(2), range(2))
(1, 0, 0, 0)
``IndexError`` will be raised if the given *index* is invalid.
"""
pools = list(map(tuple, reversed(args)))
ns = list(map(len, pools))
c = reduce(mul, ns)
if index < 0:
index += c
if not 0 <= index < c:
raise IndexError
result = []
for pool, n in zip(pools, ns):
result.append(pool[index % n])
index //= n
return tuple(reversed(result))
def nth_permutation(iterable, r, index):
"""Equivalent to ``list(permutations(iterable, r))[index]```
The subsequences of *iterable* that are of length *r* where order is
important can be ordered lexicographically. :func:`nth_permutation`
computes the subsequence at sort position *index* directly, without
computing the previous subsequences.
>>> nth_permutation('ghijk', 2, 5)
('h', 'i')
``ValueError`` will be raised If *r* is negative or greater than the length
of *iterable*.
``IndexError`` will be raised if the given *index* is invalid.
"""
pool = list(iterable)
n = len(pool)
if r is None or r == n:
r, c = n, factorial(n)
elif not 0 <= r < n:
raise ValueError
else:
c = factorial(n) // factorial(n - r)
if index < 0:
index += c
if not 0 <= index < c:
raise IndexError
if c == 0:
return tuple()
result = [0] * r
q = index * factorial(n) // c if r < n else index
for d in range(1, n + 1):
q, i = divmod(q, d)
if 0 <= n - d < r:
result[n - d] = i
if q == 0:
break
return tuple(map(pool.pop, result))
def value_chain(*args):
"""Yield all arguments passed to the function in the same order in which
they were passed. If an argument itself is iterable then iterate over its
values.
>>> list(value_chain(1, 2, 3, [4, 5, 6]))
[1, 2, 3, 4, 5, 6]
Binary and text strings are not considered iterable and are emitted
as-is:
>>> list(value_chain('12', '34', ['56', '78']))
['12', '34', '56', '78']
Multiple levels of nesting are not flattened.
"""
for value in args:
if isinstance(value, (str, bytes)):
yield value
continue
try:
yield from value
except TypeError:
yield value
def product_index(element, *args):
"""Equivalent to ``list(product(*args)).index(element)``
The products of *args* can be ordered lexicographically.
:func:`product_index` computes the first index of *element* without
computing the previous products.
>>> product_index([8, 2], range(10), range(5))
42
``ValueError`` will be raised if the given *element* isn't in the product
of *args*.
"""
index = 0
for x, pool in zip_longest(element, args, fillvalue=_marker):
if x is _marker or pool is _marker:
raise ValueError('element is not a product of args')
pool = tuple(pool)
index = index * len(pool) + pool.index(x)
return index
def combination_index(element, iterable):
"""Equivalent to ``list(combinations(iterable, r)).index(element)``
The subsequences of *iterable* that are of length *r* can be ordered
lexicographically. :func:`combination_index` computes the index of the
first *element*, without computing the previous combinations.
>>> combination_index('adf', 'abcdefg')
10
``ValueError`` will be raised if the given *element* isn't one of the
combinations of *iterable*.
"""
element = enumerate(element)
k, y = next(element, (None, None))
if k is None:
return 0
indexes = []
pool = enumerate(iterable)
for n, x in pool:
if x == y:
indexes.append(n)
tmp, y = next(element, (None, None))
if tmp is None:
break
else:
k = tmp
else:
raise ValueError('element is not a combination of iterable')
n, _ = last(pool, default=(n, None))
# Python versiosn below 3.8 don't have math.comb
index = 1
for i, j in enumerate(reversed(indexes), start=1):
j = n - j
if i <= j:
index += factorial(j) // (factorial(i) * factorial(j - i))
return factorial(n + 1) // (factorial(k + 1) * factorial(n - k)) - index
def permutation_index(element, iterable):
"""Equivalent to ``list(permutations(iterable, r)).index(element)```
The subsequences of *iterable* that are of length *r* where order is
important can be ordered lexicographically. :func:`permutation_index`
computes the index of the first *element* directly, without computing
the previous permutations.
>>> permutation_index([1, 3, 2], range(5))
19
``ValueError`` will be raised if the given *element* isn't one of the
permutations of *iterable*.
"""
index = 0
pool = list(iterable)
for i, x in zip(range(len(pool), -1, -1), element):
r = pool.index(x)
index = index * i + r
del pool[r]
return index
class countable:
"""Wrap *iterable* and keep a count of how many items have been consumed.
The ``items_seen`` attribute starts at ``0`` and increments as the iterable
is consumed:
>>> iterable = map(str, range(10))
>>> it = countable(iterable)
>>> it.items_seen
0
>>> next(it), next(it)
('0', '1')
>>> list(it)
['2', '3', '4', '5', '6', '7', '8', '9']
>>> it.items_seen
10
"""
def __init__(self, iterable):
self._it = iter(iterable)
self.items_seen = 0
def __iter__(self):
return self
def __next__(self):
item = next(self._it)
self.items_seen += 1
return item
def chunked_even(iterable, n):
"""Break *iterable* into lists of approximately length *n*.
Items are distributed such the lengths of the lists differ by at most
1 item.
>>> iterable = [1, 2, 3, 4, 5, 6, 7]
>>> n = 3
>>> list(chunked_even(iterable, n)) # List lengths: 3, 2, 2
[[1, 2, 3], [4, 5], [6, 7]]
>>> list(chunked(iterable, n)) # List lengths: 3, 3, 1
[[1, 2, 3], [4, 5, 6], [7]]
"""
len_method = getattr(iterable, '__len__', None)
if len_method is None:
return _chunked_even_online(iterable, n)
else:
return _chunked_even_finite(iterable, len_method(), n)
def _chunked_even_online(iterable, n):
buffer = []
maxbuf = n + (n - 2) * (n - 1)
for x in iterable:
buffer.append(x)
if len(buffer) == maxbuf:
yield buffer[:n]
buffer = buffer[n:]
yield from _chunked_even_finite(buffer, len(buffer), n)
def _chunked_even_finite(iterable, N, n):
if N < 1:
return
# Lists are either size `full_size <= n` or `partial_size = full_size - 1`
q, r = divmod(N, n)
num_lists = q + (1 if r > 0 else 0)
q, r = divmod(N, num_lists)
full_size = q + (1 if r > 0 else 0)
partial_size = full_size - 1
num_full = N - partial_size * num_lists
num_partial = num_lists - num_full
buffer = []
iterator = iter(iterable)
# Yield num_full lists of full_size
for x in iterator:
buffer.append(x)
if len(buffer) == full_size:
yield buffer
buffer = []
num_full -= 1
if num_full <= 0:
break
# Yield num_partial lists of partial_size
for x in iterator:
buffer.append(x)
if len(buffer) == partial_size:
yield buffer
buffer = []
num_partial -= 1
def zip_broadcast(*objects, scalar_types=(str, bytes), strict=False):
"""A version of :func:`zip` that "broadcasts" any scalar
(i.e., non-iterable) items into output tuples.
>>> iterable_1 = [1, 2, 3]
>>> iterable_2 = ['a', 'b', 'c']
>>> scalar = '_'
>>> list(zip_broadcast(iterable_1, iterable_2, scalar))
[(1, 'a', '_'), (2, 'b', '_'), (3, 'c', '_')]
The *scalar_types* keyword argument determines what types are considered
scalar. It is set to ``(str, bytes)`` by default. Set it to ``None`` to
treat strings and byte strings as iterable:
>>> list(zip_broadcast('abc', 0, 'xyz', scalar_types=None))
[('a', 0, 'x'), ('b', 0, 'y'), ('c', 0, 'z')]
If the *strict* keyword argument is ``True``, then
``UnequalIterablesError`` will be raised if any of the iterables have
different lengthss.
"""
def is_scalar(obj):
if scalar_types and isinstance(obj, scalar_types):
return True
try:
iter(obj)
except TypeError:
return True
else:
return False
size = len(objects)
if not size:
return
iterables, iterable_positions = [], []
scalars, scalar_positions = [], []
for i, obj in enumerate(objects):
if is_scalar(obj):
scalars.append(obj)
scalar_positions.append(i)
else:
iterables.append(iter(obj))
iterable_positions.append(i)
if len(scalars) == size:
yield tuple(objects)
return
zipper = _zip_equal if strict else zip
for item in zipper(*iterables):
new_item = [None] * size
for i, elem in zip(iterable_positions, item):
new_item[i] = elem
for i, elem in zip(scalar_positions, scalars):
new_item[i] = elem
yield tuple(new_item)
def unique_in_window(iterable, n, key=None):
"""Yield the items from *iterable* that haven't been seen recently.
*n* is the size of the lookback window.
>>> iterable = [0, 1, 0, 2, 3, 0]
>>> n = 3
>>> list(unique_in_window(iterable, n))
[0, 1, 2, 3, 0]
The *key* function, if provided, will be used to determine uniqueness:
>>> list(unique_in_window('abAcda', 3, key=lambda x: x.lower()))
['a', 'b', 'c', 'd', 'a']
The items in *iterable* must be hashable.
"""
if n <= 0:
raise ValueError('n must be greater than 0')
window = deque(maxlen=n)
uniques = set()
use_key = key is not None
for item in iterable:
k = key(item) if use_key else item
if k in uniques:
continue
if len(uniques) == n:
uniques.discard(window[0])
uniques.add(k)
window.append(k)
yield item
def duplicates_everseen(iterable, key=None):
"""Yield duplicate elements after their first appearance.
>>> list(duplicates_everseen('mississippi'))
['s', 'i', 's', 's', 'i', 'p', 'i']
>>> list(duplicates_everseen('AaaBbbCccAaa', str.lower))
['a', 'a', 'b', 'b', 'c', 'c', 'A', 'a', 'a']
This function is analagous to :func:`unique_everseen` and is subject to
the same performance considerations.
"""
seen_set = set()
seen_list = []
use_key = key is not None
for element in iterable:
k = key(element) if use_key else element
try:
if k not in seen_set:
seen_set.add(k)
else:
yield element
except TypeError:
if k not in seen_list:
seen_list.append(k)
else:
yield element
def duplicates_justseen(iterable, key=None):
"""Yields serially-duplicate elements after their first appearance.
>>> list(duplicates_justseen('mississippi'))
['s', 's', 'p']
>>> list(duplicates_justseen('AaaBbbCccAaa', str.lower))
['a', 'a', 'b', 'b', 'c', 'c', 'a', 'a']
This function is analagous to :func:`unique_justseen`.
"""
return flatten(
map(
lambda group_tuple: islice_extended(group_tuple[1])[1:],
groupby(iterable, key),
)
)
def minmax(iterable_or_value, *others, key=None, default=_marker):
"""Returns both the smallest and largest items in an iterable
or the largest of two or more arguments.
>>> minmax([3, 1, 5])
(1, 5)
>>> minmax(4, 2, 6)
(2, 6)
If a *key* function is provided, it will be used to transform the input
items for comparison.
>>> minmax([5, 30], key=str) # '30' sorts before '5'
(30, 5)
If a *default* value is provided, it will be returned if there are no
input items.
>>> minmax([], default=(0, 0))
(0, 0)
Otherwise ``ValueError`` is raised.
This function is based on the
`recipe <http://code.activestate.com/recipes/577916/>`__ by
Raymond Hettinger and takes care to minimize the number of comparisons
performed.
"""
iterable = (iterable_or_value, *others) if others else iterable_or_value
it = iter(iterable)
try:
lo = hi = next(it)
except StopIteration as e:
if default is _marker:
raise ValueError(
'`minmax()` argument is an empty iterable. '
'Provide a `default` value to suppress this error.'
) from e
return default
# Different branches depending on the presence of key. This saves a lot
# of unimportant copies which would slow the "key=None" branch
# significantly down.
if key is None:
for x, y in zip_longest(it, it, fillvalue=lo):
if y < x:
x, y = y, x
if x < lo:
lo = x
if hi < y:
hi = y
else:
lo_key = hi_key = key(lo)
for x, y in zip_longest(it, it, fillvalue=lo):
x_key, y_key = key(x), key(y)
if y_key < x_key:
x, y, x_key, y_key = y, x, y_key, x_key
if x_key < lo_key:
lo, lo_key = x, x_key
if hi_key < y_key:
hi, hi_key = y, y_key
return lo, hi
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/more_itertools/more.py
|
Python
|
mit
| 132,569 |
"""Imported from the recipes section of the itertools documentation.
All functions taken from the recipes section of the itertools library docs
[1]_.
Some backward-compatible usability improvements have been made.
.. [1] http://docs.python.org/library/itertools.html#recipes
"""
import warnings
from collections import deque
from itertools import (
chain,
combinations,
count,
cycle,
groupby,
islice,
repeat,
starmap,
tee,
zip_longest,
)
import operator
from random import randrange, sample, choice
__all__ = [
'all_equal',
'before_and_after',
'consume',
'convolve',
'dotproduct',
'first_true',
'flatten',
'grouper',
'iter_except',
'ncycles',
'nth',
'nth_combination',
'padnone',
'pad_none',
'pairwise',
'partition',
'powerset',
'prepend',
'quantify',
'random_combination_with_replacement',
'random_combination',
'random_permutation',
'random_product',
'repeatfunc',
'roundrobin',
'sliding_window',
'tabulate',
'tail',
'take',
'triplewise',
'unique_everseen',
'unique_justseen',
]
def take(n, iterable):
"""Return first *n* items of the iterable as a list.
>>> take(3, range(10))
[0, 1, 2]
If there are fewer than *n* items in the iterable, all of them are
returned.
>>> take(10, range(3))
[0, 1, 2]
"""
return list(islice(iterable, n))
def tabulate(function, start=0):
"""Return an iterator over the results of ``func(start)``,
``func(start + 1)``, ``func(start + 2)``...
*func* should be a function that accepts one integer argument.
If *start* is not specified it defaults to 0. It will be incremented each
time the iterator is advanced.
>>> square = lambda x: x ** 2
>>> iterator = tabulate(square, -3)
>>> take(4, iterator)
[9, 4, 1, 0]
"""
return map(function, count(start))
def tail(n, iterable):
"""Return an iterator over the last *n* items of *iterable*.
>>> t = tail(3, 'ABCDEFG')
>>> list(t)
['E', 'F', 'G']
"""
return iter(deque(iterable, maxlen=n))
def consume(iterator, n=None):
"""Advance *iterable* by *n* steps. If *n* is ``None``, consume it
entirely.
Efficiently exhausts an iterator without returning values. Defaults to
consuming the whole iterator, but an optional second argument may be
provided to limit consumption.
>>> i = (x for x in range(10))
>>> next(i)
0
>>> consume(i, 3)
>>> next(i)
4
>>> consume(i)
>>> next(i)
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
StopIteration
If the iterator has fewer items remaining than the provided limit, the
whole iterator will be consumed.
>>> i = (x for x in range(3))
>>> consume(i, 5)
>>> next(i)
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
StopIteration
"""
# Use functions that consume iterators at C speed.
if n is None:
# feed the entire iterator into a zero-length deque
deque(iterator, maxlen=0)
else:
# advance to the empty slice starting at position n
next(islice(iterator, n, n), None)
def nth(iterable, n, default=None):
"""Returns the nth item or a default value.
>>> l = range(10)
>>> nth(l, 3)
3
>>> nth(l, 20, "zebra")
'zebra'
"""
return next(islice(iterable, n, None), default)
def all_equal(iterable):
"""
Returns ``True`` if all the elements are equal to each other.
>>> all_equal('aaaa')
True
>>> all_equal('aaab')
False
"""
g = groupby(iterable)
return next(g, True) and not next(g, False)
def quantify(iterable, pred=bool):
"""Return the how many times the predicate is true.
>>> quantify([True, False, True])
2
"""
return sum(map(pred, iterable))
def pad_none(iterable):
"""Returns the sequence of elements and then returns ``None`` indefinitely.
>>> take(5, pad_none(range(3)))
[0, 1, 2, None, None]
Useful for emulating the behavior of the built-in :func:`map` function.
See also :func:`padded`.
"""
return chain(iterable, repeat(None))
padnone = pad_none
def ncycles(iterable, n):
"""Returns the sequence elements *n* times
>>> list(ncycles(["a", "b"], 3))
['a', 'b', 'a', 'b', 'a', 'b']
"""
return chain.from_iterable(repeat(tuple(iterable), n))
def dotproduct(vec1, vec2):
"""Returns the dot product of the two iterables.
>>> dotproduct([10, 10], [20, 20])
400
"""
return sum(map(operator.mul, vec1, vec2))
def flatten(listOfLists):
"""Return an iterator flattening one level of nesting in a list of lists.
>>> list(flatten([[0, 1], [2, 3]]))
[0, 1, 2, 3]
See also :func:`collapse`, which can flatten multiple levels of nesting.
"""
return chain.from_iterable(listOfLists)
def repeatfunc(func, times=None, *args):
"""Call *func* with *args* repeatedly, returning an iterable over the
results.
If *times* is specified, the iterable will terminate after that many
repetitions:
>>> from operator import add
>>> times = 4
>>> args = 3, 5
>>> list(repeatfunc(add, times, *args))
[8, 8, 8, 8]
If *times* is ``None`` the iterable will not terminate:
>>> from random import randrange
>>> times = None
>>> args = 1, 11
>>> take(6, repeatfunc(randrange, times, *args)) # doctest:+SKIP
[2, 4, 8, 1, 8, 4]
"""
if times is None:
return starmap(func, repeat(args))
return starmap(func, repeat(args, times))
def _pairwise(iterable):
"""Returns an iterator of paired items, overlapping, from the original
>>> take(4, pairwise(count()))
[(0, 1), (1, 2), (2, 3), (3, 4)]
On Python 3.10 and above, this is an alias for :func:`itertools.pairwise`.
"""
a, b = tee(iterable)
next(b, None)
yield from zip(a, b)
try:
from itertools import pairwise as itertools_pairwise
except ImportError:
pairwise = _pairwise
else:
def pairwise(iterable):
yield from itertools_pairwise(iterable)
pairwise.__doc__ = _pairwise.__doc__
def grouper(iterable, n, fillvalue=None):
"""Collect data into fixed-length chunks or blocks.
>>> list(grouper('ABCDEFG', 3, 'x'))
[('A', 'B', 'C'), ('D', 'E', 'F'), ('G', 'x', 'x')]
"""
if isinstance(iterable, int):
warnings.warn(
"grouper expects iterable as first parameter", DeprecationWarning
)
n, iterable = iterable, n
args = [iter(iterable)] * n
return zip_longest(fillvalue=fillvalue, *args)
def roundrobin(*iterables):
"""Yields an item from each iterable, alternating between them.
>>> list(roundrobin('ABC', 'D', 'EF'))
['A', 'D', 'E', 'B', 'F', 'C']
This function produces the same output as :func:`interleave_longest`, but
may perform better for some inputs (in particular when the number of
iterables is small).
"""
# Recipe credited to George Sakkis
pending = len(iterables)
nexts = cycle(iter(it).__next__ for it in iterables)
while pending:
try:
for next in nexts:
yield next()
except StopIteration:
pending -= 1
nexts = cycle(islice(nexts, pending))
def partition(pred, iterable):
"""
Returns a 2-tuple of iterables derived from the input iterable.
The first yields the items that have ``pred(item) == False``.
The second yields the items that have ``pred(item) == True``.
>>> is_odd = lambda x: x % 2 != 0
>>> iterable = range(10)
>>> even_items, odd_items = partition(is_odd, iterable)
>>> list(even_items), list(odd_items)
([0, 2, 4, 6, 8], [1, 3, 5, 7, 9])
If *pred* is None, :func:`bool` is used.
>>> iterable = [0, 1, False, True, '', ' ']
>>> false_items, true_items = partition(None, iterable)
>>> list(false_items), list(true_items)
([0, False, ''], [1, True, ' '])
"""
if pred is None:
pred = bool
evaluations = ((pred(x), x) for x in iterable)
t1, t2 = tee(evaluations)
return (
(x for (cond, x) in t1 if not cond),
(x for (cond, x) in t2 if cond),
)
def powerset(iterable):
"""Yields all possible subsets of the iterable.
>>> list(powerset([1, 2, 3]))
[(), (1,), (2,), (3,), (1, 2), (1, 3), (2, 3), (1, 2, 3)]
:func:`powerset` will operate on iterables that aren't :class:`set`
instances, so repeated elements in the input will produce repeated elements
in the output. Use :func:`unique_everseen` on the input to avoid generating
duplicates:
>>> seq = [1, 1, 0]
>>> list(powerset(seq))
[(), (1,), (1,), (0,), (1, 1), (1, 0), (1, 0), (1, 1, 0)]
>>> from more_itertools import unique_everseen
>>> list(powerset(unique_everseen(seq)))
[(), (1,), (0,), (1, 0)]
"""
s = list(iterable)
return chain.from_iterable(combinations(s, r) for r in range(len(s) + 1))
def unique_everseen(iterable, key=None):
"""
Yield unique elements, preserving order.
>>> list(unique_everseen('AAAABBBCCDAABBB'))
['A', 'B', 'C', 'D']
>>> list(unique_everseen('ABBCcAD', str.lower))
['A', 'B', 'C', 'D']
Sequences with a mix of hashable and unhashable items can be used.
The function will be slower (i.e., `O(n^2)`) for unhashable items.
Remember that ``list`` objects are unhashable - you can use the *key*
parameter to transform the list to a tuple (which is hashable) to
avoid a slowdown.
>>> iterable = ([1, 2], [2, 3], [1, 2])
>>> list(unique_everseen(iterable)) # Slow
[[1, 2], [2, 3]]
>>> list(unique_everseen(iterable, key=tuple)) # Faster
[[1, 2], [2, 3]]
Similary, you may want to convert unhashable ``set`` objects with
``key=frozenset``. For ``dict`` objects,
``key=lambda x: frozenset(x.items())`` can be used.
"""
seenset = set()
seenset_add = seenset.add
seenlist = []
seenlist_add = seenlist.append
use_key = key is not None
for element in iterable:
k = key(element) if use_key else element
try:
if k not in seenset:
seenset_add(k)
yield element
except TypeError:
if k not in seenlist:
seenlist_add(k)
yield element
def unique_justseen(iterable, key=None):
"""Yields elements in order, ignoring serial duplicates
>>> list(unique_justseen('AAAABBBCCDAABBB'))
['A', 'B', 'C', 'D', 'A', 'B']
>>> list(unique_justseen('ABBCcAD', str.lower))
['A', 'B', 'C', 'A', 'D']
"""
return map(next, map(operator.itemgetter(1), groupby(iterable, key)))
def iter_except(func, exception, first=None):
"""Yields results from a function repeatedly until an exception is raised.
Converts a call-until-exception interface to an iterator interface.
Like ``iter(func, sentinel)``, but uses an exception instead of a sentinel
to end the loop.
>>> l = [0, 1, 2]
>>> list(iter_except(l.pop, IndexError))
[2, 1, 0]
Multiple exceptions can be specified as a stopping condition:
>>> l = [1, 2, 3, '...', 4, 5, 6]
>>> list(iter_except(lambda: 1 + l.pop(), (IndexError, TypeError)))
[7, 6, 5]
>>> list(iter_except(lambda: 1 + l.pop(), (IndexError, TypeError)))
[4, 3, 2]
>>> list(iter_except(lambda: 1 + l.pop(), (IndexError, TypeError)))
[]
"""
try:
if first is not None:
yield first()
while 1:
yield func()
except exception:
pass
def first_true(iterable, default=None, pred=None):
"""
Returns the first true value in the iterable.
If no true value is found, returns *default*
If *pred* is not None, returns the first item for which
``pred(item) == True`` .
>>> first_true(range(10))
1
>>> first_true(range(10), pred=lambda x: x > 5)
6
>>> first_true(range(10), default='missing', pred=lambda x: x > 9)
'missing'
"""
return next(filter(pred, iterable), default)
def random_product(*args, repeat=1):
"""Draw an item at random from each of the input iterables.
>>> random_product('abc', range(4), 'XYZ') # doctest:+SKIP
('c', 3, 'Z')
If *repeat* is provided as a keyword argument, that many items will be
drawn from each iterable.
>>> random_product('abcd', range(4), repeat=2) # doctest:+SKIP
('a', 2, 'd', 3)
This equivalent to taking a random selection from
``itertools.product(*args, **kwarg)``.
"""
pools = [tuple(pool) for pool in args] * repeat
return tuple(choice(pool) for pool in pools)
def random_permutation(iterable, r=None):
"""Return a random *r* length permutation of the elements in *iterable*.
If *r* is not specified or is ``None``, then *r* defaults to the length of
*iterable*.
>>> random_permutation(range(5)) # doctest:+SKIP
(3, 4, 0, 1, 2)
This equivalent to taking a random selection from
``itertools.permutations(iterable, r)``.
"""
pool = tuple(iterable)
r = len(pool) if r is None else r
return tuple(sample(pool, r))
def random_combination(iterable, r):
"""Return a random *r* length subsequence of the elements in *iterable*.
>>> random_combination(range(5), 3) # doctest:+SKIP
(2, 3, 4)
This equivalent to taking a random selection from
``itertools.combinations(iterable, r)``.
"""
pool = tuple(iterable)
n = len(pool)
indices = sorted(sample(range(n), r))
return tuple(pool[i] for i in indices)
def random_combination_with_replacement(iterable, r):
"""Return a random *r* length subsequence of elements in *iterable*,
allowing individual elements to be repeated.
>>> random_combination_with_replacement(range(3), 5) # doctest:+SKIP
(0, 0, 1, 2, 2)
This equivalent to taking a random selection from
``itertools.combinations_with_replacement(iterable, r)``.
"""
pool = tuple(iterable)
n = len(pool)
indices = sorted(randrange(n) for i in range(r))
return tuple(pool[i] for i in indices)
def nth_combination(iterable, r, index):
"""Equivalent to ``list(combinations(iterable, r))[index]``.
The subsequences of *iterable* that are of length *r* can be ordered
lexicographically. :func:`nth_combination` computes the subsequence at
sort position *index* directly, without computing the previous
subsequences.
>>> nth_combination(range(5), 3, 5)
(0, 3, 4)
``ValueError`` will be raised If *r* is negative or greater than the length
of *iterable*.
``IndexError`` will be raised if the given *index* is invalid.
"""
pool = tuple(iterable)
n = len(pool)
if (r < 0) or (r > n):
raise ValueError
c = 1
k = min(r, n - r)
for i in range(1, k + 1):
c = c * (n - k + i) // i
if index < 0:
index += c
if (index < 0) or (index >= c):
raise IndexError
result = []
while r:
c, n, r = c * r // n, n - 1, r - 1
while index >= c:
index -= c
c, n = c * (n - r) // n, n - 1
result.append(pool[-1 - n])
return tuple(result)
def prepend(value, iterator):
"""Yield *value*, followed by the elements in *iterator*.
>>> value = '0'
>>> iterator = ['1', '2', '3']
>>> list(prepend(value, iterator))
['0', '1', '2', '3']
To prepend multiple values, see :func:`itertools.chain`
or :func:`value_chain`.
"""
return chain([value], iterator)
def convolve(signal, kernel):
"""Convolve the iterable *signal* with the iterable *kernel*.
>>> signal = (1, 2, 3, 4, 5)
>>> kernel = [3, 2, 1]
>>> list(convolve(signal, kernel))
[3, 8, 14, 20, 26, 14, 5]
Note: the input arguments are not interchangeable, as the *kernel*
is immediately consumed and stored.
"""
kernel = tuple(kernel)[::-1]
n = len(kernel)
window = deque([0], maxlen=n) * n
for x in chain(signal, repeat(0, n - 1)):
window.append(x)
yield sum(map(operator.mul, kernel, window))
def before_and_after(predicate, it):
"""A variant of :func:`takewhile` that allows complete access to the
remainder of the iterator.
>>> it = iter('ABCdEfGhI')
>>> all_upper, remainder = before_and_after(str.isupper, it)
>>> ''.join(all_upper)
'ABC'
>>> ''.join(remainder) # takewhile() would lose the 'd'
'dEfGhI'
Note that the first iterator must be fully consumed before the second
iterator can generate valid results.
"""
it = iter(it)
transition = []
def true_iterator():
for elem in it:
if predicate(elem):
yield elem
else:
transition.append(elem)
return
def remainder_iterator():
yield from transition
yield from it
return true_iterator(), remainder_iterator()
def triplewise(iterable):
"""Return overlapping triplets from *iterable*.
>>> list(triplewise('ABCDE'))
[('A', 'B', 'C'), ('B', 'C', 'D'), ('C', 'D', 'E')]
"""
for (a, _), (b, c) in pairwise(pairwise(iterable)):
yield a, b, c
def sliding_window(iterable, n):
"""Return a sliding window of width *n* over *iterable*.
>>> list(sliding_window(range(6), 4))
[(0, 1, 2, 3), (1, 2, 3, 4), (2, 3, 4, 5)]
If *iterable* has fewer than *n* items, then nothing is yielded:
>>> list(sliding_window(range(3), 4))
[]
For a variant with more features, see :func:`windowed`.
"""
it = iter(iterable)
window = deque(islice(it, n), maxlen=n)
if len(window) == n:
yield tuple(window)
for x in it:
window.append(x)
yield tuple(window)
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/more_itertools/recipes.py
|
Python
|
mit
| 18,410 |
# This file is dual licensed under the terms of the Apache License, Version
# 2.0, and the BSD License. See the LICENSE file in the root of this repository
# for complete details.
__all__ = [
"__title__",
"__summary__",
"__uri__",
"__version__",
"__author__",
"__email__",
"__license__",
"__copyright__",
]
__title__ = "packaging"
__summary__ = "Core utilities for Python packages"
__uri__ = "https://github.com/pypa/packaging"
__version__ = "21.3"
__author__ = "Donald Stufft and individual contributors"
__email__ = "donald@stufft.io"
__license__ = "BSD-2-Clause or Apache-2.0"
__copyright__ = "2014-2019 %s" % __author__
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/packaging/__about__.py
|
Python
|
mit
| 661 |
# This file is dual licensed under the terms of the Apache License, Version
# 2.0, and the BSD License. See the LICENSE file in the root of this repository
# for complete details.
from .__about__ import (
__author__,
__copyright__,
__email__,
__license__,
__summary__,
__title__,
__uri__,
__version__,
)
__all__ = [
"__title__",
"__summary__",
"__uri__",
"__version__",
"__author__",
"__email__",
"__license__",
"__copyright__",
]
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/packaging/__init__.py
|
Python
|
mit
| 497 |
import collections
import functools
import os
import re
import struct
import sys
import warnings
from typing import IO, Dict, Iterator, NamedTuple, Optional, Tuple
# Python does not provide platform information at sufficient granularity to
# identify the architecture of the running executable in some cases, so we
# determine it dynamically by reading the information from the running
# process. This only applies on Linux, which uses the ELF format.
class _ELFFileHeader:
# https://en.wikipedia.org/wiki/Executable_and_Linkable_Format#File_header
class _InvalidELFFileHeader(ValueError):
"""
An invalid ELF file header was found.
"""
ELF_MAGIC_NUMBER = 0x7F454C46
ELFCLASS32 = 1
ELFCLASS64 = 2
ELFDATA2LSB = 1
ELFDATA2MSB = 2
EM_386 = 3
EM_S390 = 22
EM_ARM = 40
EM_X86_64 = 62
EF_ARM_ABIMASK = 0xFF000000
EF_ARM_ABI_VER5 = 0x05000000
EF_ARM_ABI_FLOAT_HARD = 0x00000400
def __init__(self, file: IO[bytes]) -> None:
def unpack(fmt: str) -> int:
try:
data = file.read(struct.calcsize(fmt))
result: Tuple[int, ...] = struct.unpack(fmt, data)
except struct.error:
raise _ELFFileHeader._InvalidELFFileHeader()
return result[0]
self.e_ident_magic = unpack(">I")
if self.e_ident_magic != self.ELF_MAGIC_NUMBER:
raise _ELFFileHeader._InvalidELFFileHeader()
self.e_ident_class = unpack("B")
if self.e_ident_class not in {self.ELFCLASS32, self.ELFCLASS64}:
raise _ELFFileHeader._InvalidELFFileHeader()
self.e_ident_data = unpack("B")
if self.e_ident_data not in {self.ELFDATA2LSB, self.ELFDATA2MSB}:
raise _ELFFileHeader._InvalidELFFileHeader()
self.e_ident_version = unpack("B")
self.e_ident_osabi = unpack("B")
self.e_ident_abiversion = unpack("B")
self.e_ident_pad = file.read(7)
format_h = "<H" if self.e_ident_data == self.ELFDATA2LSB else ">H"
format_i = "<I" if self.e_ident_data == self.ELFDATA2LSB else ">I"
format_q = "<Q" if self.e_ident_data == self.ELFDATA2LSB else ">Q"
format_p = format_i if self.e_ident_class == self.ELFCLASS32 else format_q
self.e_type = unpack(format_h)
self.e_machine = unpack(format_h)
self.e_version = unpack(format_i)
self.e_entry = unpack(format_p)
self.e_phoff = unpack(format_p)
self.e_shoff = unpack(format_p)
self.e_flags = unpack(format_i)
self.e_ehsize = unpack(format_h)
self.e_phentsize = unpack(format_h)
self.e_phnum = unpack(format_h)
self.e_shentsize = unpack(format_h)
self.e_shnum = unpack(format_h)
self.e_shstrndx = unpack(format_h)
def _get_elf_header() -> Optional[_ELFFileHeader]:
try:
with open(sys.executable, "rb") as f:
elf_header = _ELFFileHeader(f)
except (OSError, TypeError, _ELFFileHeader._InvalidELFFileHeader):
return None
return elf_header
def _is_linux_armhf() -> bool:
# hard-float ABI can be detected from the ELF header of the running
# process
# https://static.docs.arm.com/ihi0044/g/aaelf32.pdf
elf_header = _get_elf_header()
if elf_header is None:
return False
result = elf_header.e_ident_class == elf_header.ELFCLASS32
result &= elf_header.e_ident_data == elf_header.ELFDATA2LSB
result &= elf_header.e_machine == elf_header.EM_ARM
result &= (
elf_header.e_flags & elf_header.EF_ARM_ABIMASK
) == elf_header.EF_ARM_ABI_VER5
result &= (
elf_header.e_flags & elf_header.EF_ARM_ABI_FLOAT_HARD
) == elf_header.EF_ARM_ABI_FLOAT_HARD
return result
def _is_linux_i686() -> bool:
elf_header = _get_elf_header()
if elf_header is None:
return False
result = elf_header.e_ident_class == elf_header.ELFCLASS32
result &= elf_header.e_ident_data == elf_header.ELFDATA2LSB
result &= elf_header.e_machine == elf_header.EM_386
return result
def _have_compatible_abi(arch: str) -> bool:
if arch == "armv7l":
return _is_linux_armhf()
if arch == "i686":
return _is_linux_i686()
return arch in {"x86_64", "aarch64", "ppc64", "ppc64le", "s390x"}
# If glibc ever changes its major version, we need to know what the last
# minor version was, so we can build the complete list of all versions.
# For now, guess what the highest minor version might be, assume it will
# be 50 for testing. Once this actually happens, update the dictionary
# with the actual value.
_LAST_GLIBC_MINOR: Dict[int, int] = collections.defaultdict(lambda: 50)
class _GLibCVersion(NamedTuple):
major: int
minor: int
def _glibc_version_string_confstr() -> Optional[str]:
"""
Primary implementation of glibc_version_string using os.confstr.
"""
# os.confstr is quite a bit faster than ctypes.DLL. It's also less likely
# to be broken or missing. This strategy is used in the standard library
# platform module.
# https://github.com/python/cpython/blob/fcf1d003bf4f0100c/Lib/platform.py#L175-L183
try:
# os.confstr("CS_GNU_LIBC_VERSION") returns a string like "glibc 2.17".
version_string = os.confstr("CS_GNU_LIBC_VERSION")
assert version_string is not None
_, version = version_string.split()
except (AssertionError, AttributeError, OSError, ValueError):
# os.confstr() or CS_GNU_LIBC_VERSION not available (or a bad value)...
return None
return version
def _glibc_version_string_ctypes() -> Optional[str]:
"""
Fallback implementation of glibc_version_string using ctypes.
"""
try:
import ctypes
except ImportError:
return None
# ctypes.CDLL(None) internally calls dlopen(NULL), and as the dlopen
# manpage says, "If filename is NULL, then the returned handle is for the
# main program". This way we can let the linker do the work to figure out
# which libc our process is actually using.
#
# We must also handle the special case where the executable is not a
# dynamically linked executable. This can occur when using musl libc,
# for example. In this situation, dlopen() will error, leading to an
# OSError. Interestingly, at least in the case of musl, there is no
# errno set on the OSError. The single string argument used to construct
# OSError comes from libc itself and is therefore not portable to
# hard code here. In any case, failure to call dlopen() means we
# can proceed, so we bail on our attempt.
try:
process_namespace = ctypes.CDLL(None)
except OSError:
return None
try:
gnu_get_libc_version = process_namespace.gnu_get_libc_version
except AttributeError:
# Symbol doesn't exist -> therefore, we are not linked to
# glibc.
return None
# Call gnu_get_libc_version, which returns a string like "2.5"
gnu_get_libc_version.restype = ctypes.c_char_p
version_str: str = gnu_get_libc_version()
# py2 / py3 compatibility:
if not isinstance(version_str, str):
version_str = version_str.decode("ascii")
return version_str
def _glibc_version_string() -> Optional[str]:
"""Returns glibc version string, or None if not using glibc."""
return _glibc_version_string_confstr() or _glibc_version_string_ctypes()
def _parse_glibc_version(version_str: str) -> Tuple[int, int]:
"""Parse glibc version.
We use a regexp instead of str.split because we want to discard any
random junk that might come after the minor version -- this might happen
in patched/forked versions of glibc (e.g. Linaro's version of glibc
uses version strings like "2.20-2014.11"). See gh-3588.
"""
m = re.match(r"(?P<major>[0-9]+)\.(?P<minor>[0-9]+)", version_str)
if not m:
warnings.warn(
"Expected glibc version with 2 components major.minor,"
" got: %s" % version_str,
RuntimeWarning,
)
return -1, -1
return int(m.group("major")), int(m.group("minor"))
@functools.lru_cache()
def _get_glibc_version() -> Tuple[int, int]:
version_str = _glibc_version_string()
if version_str is None:
return (-1, -1)
return _parse_glibc_version(version_str)
# From PEP 513, PEP 600
def _is_compatible(name: str, arch: str, version: _GLibCVersion) -> bool:
sys_glibc = _get_glibc_version()
if sys_glibc < version:
return False
# Check for presence of _manylinux module.
try:
import _manylinux # noqa
except ImportError:
return True
if hasattr(_manylinux, "manylinux_compatible"):
result = _manylinux.manylinux_compatible(version[0], version[1], arch)
if result is not None:
return bool(result)
return True
if version == _GLibCVersion(2, 5):
if hasattr(_manylinux, "manylinux1_compatible"):
return bool(_manylinux.manylinux1_compatible)
if version == _GLibCVersion(2, 12):
if hasattr(_manylinux, "manylinux2010_compatible"):
return bool(_manylinux.manylinux2010_compatible)
if version == _GLibCVersion(2, 17):
if hasattr(_manylinux, "manylinux2014_compatible"):
return bool(_manylinux.manylinux2014_compatible)
return True
_LEGACY_MANYLINUX_MAP = {
# CentOS 7 w/ glibc 2.17 (PEP 599)
(2, 17): "manylinux2014",
# CentOS 6 w/ glibc 2.12 (PEP 571)
(2, 12): "manylinux2010",
# CentOS 5 w/ glibc 2.5 (PEP 513)
(2, 5): "manylinux1",
}
def platform_tags(linux: str, arch: str) -> Iterator[str]:
if not _have_compatible_abi(arch):
return
# Oldest glibc to be supported regardless of architecture is (2, 17).
too_old_glibc2 = _GLibCVersion(2, 16)
if arch in {"x86_64", "i686"}:
# On x86/i686 also oldest glibc to be supported is (2, 5).
too_old_glibc2 = _GLibCVersion(2, 4)
current_glibc = _GLibCVersion(*_get_glibc_version())
glibc_max_list = [current_glibc]
# We can assume compatibility across glibc major versions.
# https://sourceware.org/bugzilla/show_bug.cgi?id=24636
#
# Build a list of maximum glibc versions so that we can
# output the canonical list of all glibc from current_glibc
# down to too_old_glibc2, including all intermediary versions.
for glibc_major in range(current_glibc.major - 1, 1, -1):
glibc_minor = _LAST_GLIBC_MINOR[glibc_major]
glibc_max_list.append(_GLibCVersion(glibc_major, glibc_minor))
for glibc_max in glibc_max_list:
if glibc_max.major == too_old_glibc2.major:
min_minor = too_old_glibc2.minor
else:
# For other glibc major versions oldest supported is (x, 0).
min_minor = -1
for glibc_minor in range(glibc_max.minor, min_minor, -1):
glibc_version = _GLibCVersion(glibc_max.major, glibc_minor)
tag = "manylinux_{}_{}".format(*glibc_version)
if _is_compatible(tag, arch, glibc_version):
yield linux.replace("linux", tag)
# Handle the legacy manylinux1, manylinux2010, manylinux2014 tags.
if glibc_version in _LEGACY_MANYLINUX_MAP:
legacy_tag = _LEGACY_MANYLINUX_MAP[glibc_version]
if _is_compatible(legacy_tag, arch, glibc_version):
yield linux.replace("linux", legacy_tag)
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/packaging/_manylinux.py
|
Python
|
mit
| 11,488 |
"""PEP 656 support.
This module implements logic to detect if the currently running Python is
linked against musl, and what musl version is used.
"""
import contextlib
import functools
import operator
import os
import re
import struct
import subprocess
import sys
from typing import IO, Iterator, NamedTuple, Optional, Tuple
def _read_unpacked(f: IO[bytes], fmt: str) -> Tuple[int, ...]:
return struct.unpack(fmt, f.read(struct.calcsize(fmt)))
def _parse_ld_musl_from_elf(f: IO[bytes]) -> Optional[str]:
"""Detect musl libc location by parsing the Python executable.
Based on: https://gist.github.com/lyssdod/f51579ae8d93c8657a5564aefc2ffbca
ELF header: https://refspecs.linuxfoundation.org/elf/gabi4+/ch4.eheader.html
"""
f.seek(0)
try:
ident = _read_unpacked(f, "16B")
except struct.error:
return None
if ident[:4] != tuple(b"\x7fELF"): # Invalid magic, not ELF.
return None
f.seek(struct.calcsize("HHI"), 1) # Skip file type, machine, and version.
try:
# e_fmt: Format for program header.
# p_fmt: Format for section header.
# p_idx: Indexes to find p_type, p_offset, and p_filesz.
e_fmt, p_fmt, p_idx = {
1: ("IIIIHHH", "IIIIIIII", (0, 1, 4)), # 32-bit.
2: ("QQQIHHH", "IIQQQQQQ", (0, 2, 5)), # 64-bit.
}[ident[4]]
except KeyError:
return None
else:
p_get = operator.itemgetter(*p_idx)
# Find the interpreter section and return its content.
try:
_, e_phoff, _, _, _, e_phentsize, e_phnum = _read_unpacked(f, e_fmt)
except struct.error:
return None
for i in range(e_phnum + 1):
f.seek(e_phoff + e_phentsize * i)
try:
p_type, p_offset, p_filesz = p_get(_read_unpacked(f, p_fmt))
except struct.error:
return None
if p_type != 3: # Not PT_INTERP.
continue
f.seek(p_offset)
interpreter = os.fsdecode(f.read(p_filesz)).strip("\0")
if "musl" not in interpreter:
return None
return interpreter
return None
class _MuslVersion(NamedTuple):
major: int
minor: int
def _parse_musl_version(output: str) -> Optional[_MuslVersion]:
lines = [n for n in (n.strip() for n in output.splitlines()) if n]
if len(lines) < 2 or lines[0][:4] != "musl":
return None
m = re.match(r"Version (\d+)\.(\d+)", lines[1])
if not m:
return None
return _MuslVersion(major=int(m.group(1)), minor=int(m.group(2)))
@functools.lru_cache()
def _get_musl_version(executable: str) -> Optional[_MuslVersion]:
"""Detect currently-running musl runtime version.
This is done by checking the specified executable's dynamic linking
information, and invoking the loader to parse its output for a version
string. If the loader is musl, the output would be something like::
musl libc (x86_64)
Version 1.2.2
Dynamic Program Loader
"""
with contextlib.ExitStack() as stack:
try:
f = stack.enter_context(open(executable, "rb"))
except OSError:
return None
ld = _parse_ld_musl_from_elf(f)
if not ld:
return None
proc = subprocess.run([ld], stderr=subprocess.PIPE, universal_newlines=True)
return _parse_musl_version(proc.stderr)
def platform_tags(arch: str) -> Iterator[str]:
"""Generate musllinux tags compatible to the current platform.
:param arch: Should be the part of platform tag after the ``linux_``
prefix, e.g. ``x86_64``. The ``linux_`` prefix is assumed as a
prerequisite for the current platform to be musllinux-compatible.
:returns: An iterator of compatible musllinux tags.
"""
sys_musl = _get_musl_version(sys.executable)
if sys_musl is None: # Python not dynamically linked against musl.
return
for minor in range(sys_musl.minor, -1, -1):
yield f"musllinux_{sys_musl.major}_{minor}_{arch}"
if __name__ == "__main__": # pragma: no cover
import sysconfig
plat = sysconfig.get_platform()
assert plat.startswith("linux-"), "not linux"
print("plat:", plat)
print("musl:", _get_musl_version(sys.executable))
print("tags:", end=" ")
for t in platform_tags(re.sub(r"[.-]", "_", plat.split("-", 1)[-1])):
print(t, end="\n ")
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/packaging/_musllinux.py
|
Python
|
mit
| 4,378 |
# This file is dual licensed under the terms of the Apache License, Version
# 2.0, and the BSD License. See the LICENSE file in the root of this repository
# for complete details.
class InfinityType:
def __repr__(self) -> str:
return "Infinity"
def __hash__(self) -> int:
return hash(repr(self))
def __lt__(self, other: object) -> bool:
return False
def __le__(self, other: object) -> bool:
return False
def __eq__(self, other: object) -> bool:
return isinstance(other, self.__class__)
def __gt__(self, other: object) -> bool:
return True
def __ge__(self, other: object) -> bool:
return True
def __neg__(self: object) -> "NegativeInfinityType":
return NegativeInfinity
Infinity = InfinityType()
class NegativeInfinityType:
def __repr__(self) -> str:
return "-Infinity"
def __hash__(self) -> int:
return hash(repr(self))
def __lt__(self, other: object) -> bool:
return True
def __le__(self, other: object) -> bool:
return True
def __eq__(self, other: object) -> bool:
return isinstance(other, self.__class__)
def __gt__(self, other: object) -> bool:
return False
def __ge__(self, other: object) -> bool:
return False
def __neg__(self: object) -> InfinityType:
return Infinity
NegativeInfinity = NegativeInfinityType()
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/packaging/_structures.py
|
Python
|
mit
| 1,431 |
# This file is dual licensed under the terms of the Apache License, Version
# 2.0, and the BSD License. See the LICENSE file in the root of this repository
# for complete details.
import operator
import os
import platform
import sys
from typing import Any, Callable, Dict, List, Optional, Tuple, Union
from pkg_resources.extern.pyparsing import ( # noqa: N817
Forward,
Group,
Literal as L,
ParseException,
ParseResults,
QuotedString,
ZeroOrMore,
stringEnd,
stringStart,
)
from .specifiers import InvalidSpecifier, Specifier
__all__ = [
"InvalidMarker",
"UndefinedComparison",
"UndefinedEnvironmentName",
"Marker",
"default_environment",
]
Operator = Callable[[str, str], bool]
class InvalidMarker(ValueError):
"""
An invalid marker was found, users should refer to PEP 508.
"""
class UndefinedComparison(ValueError):
"""
An invalid operation was attempted on a value that doesn't support it.
"""
class UndefinedEnvironmentName(ValueError):
"""
A name was attempted to be used that does not exist inside of the
environment.
"""
class Node:
def __init__(self, value: Any) -> None:
self.value = value
def __str__(self) -> str:
return str(self.value)
def __repr__(self) -> str:
return f"<{self.__class__.__name__}('{self}')>"
def serialize(self) -> str:
raise NotImplementedError
class Variable(Node):
def serialize(self) -> str:
return str(self)
class Value(Node):
def serialize(self) -> str:
return f'"{self}"'
class Op(Node):
def serialize(self) -> str:
return str(self)
VARIABLE = (
L("implementation_version")
| L("platform_python_implementation")
| L("implementation_name")
| L("python_full_version")
| L("platform_release")
| L("platform_version")
| L("platform_machine")
| L("platform_system")
| L("python_version")
| L("sys_platform")
| L("os_name")
| L("os.name") # PEP-345
| L("sys.platform") # PEP-345
| L("platform.version") # PEP-345
| L("platform.machine") # PEP-345
| L("platform.python_implementation") # PEP-345
| L("python_implementation") # undocumented setuptools legacy
| L("extra") # PEP-508
)
ALIASES = {
"os.name": "os_name",
"sys.platform": "sys_platform",
"platform.version": "platform_version",
"platform.machine": "platform_machine",
"platform.python_implementation": "platform_python_implementation",
"python_implementation": "platform_python_implementation",
}
VARIABLE.setParseAction(lambda s, l, t: Variable(ALIASES.get(t[0], t[0])))
VERSION_CMP = (
L("===") | L("==") | L(">=") | L("<=") | L("!=") | L("~=") | L(">") | L("<")
)
MARKER_OP = VERSION_CMP | L("not in") | L("in")
MARKER_OP.setParseAction(lambda s, l, t: Op(t[0]))
MARKER_VALUE = QuotedString("'") | QuotedString('"')
MARKER_VALUE.setParseAction(lambda s, l, t: Value(t[0]))
BOOLOP = L("and") | L("or")
MARKER_VAR = VARIABLE | MARKER_VALUE
MARKER_ITEM = Group(MARKER_VAR + MARKER_OP + MARKER_VAR)
MARKER_ITEM.setParseAction(lambda s, l, t: tuple(t[0]))
LPAREN = L("(").suppress()
RPAREN = L(")").suppress()
MARKER_EXPR = Forward()
MARKER_ATOM = MARKER_ITEM | Group(LPAREN + MARKER_EXPR + RPAREN)
MARKER_EXPR << MARKER_ATOM + ZeroOrMore(BOOLOP + MARKER_EXPR)
MARKER = stringStart + MARKER_EXPR + stringEnd
def _coerce_parse_result(results: Union[ParseResults, List[Any]]) -> List[Any]:
if isinstance(results, ParseResults):
return [_coerce_parse_result(i) for i in results]
else:
return results
def _format_marker(
marker: Union[List[str], Tuple[Node, ...], str], first: Optional[bool] = True
) -> str:
assert isinstance(marker, (list, tuple, str))
# Sometimes we have a structure like [[...]] which is a single item list
# where the single item is itself it's own list. In that case we want skip
# the rest of this function so that we don't get extraneous () on the
# outside.
if (
isinstance(marker, list)
and len(marker) == 1
and isinstance(marker[0], (list, tuple))
):
return _format_marker(marker[0])
if isinstance(marker, list):
inner = (_format_marker(m, first=False) for m in marker)
if first:
return " ".join(inner)
else:
return "(" + " ".join(inner) + ")"
elif isinstance(marker, tuple):
return " ".join([m.serialize() for m in marker])
else:
return marker
_operators: Dict[str, Operator] = {
"in": lambda lhs, rhs: lhs in rhs,
"not in": lambda lhs, rhs: lhs not in rhs,
"<": operator.lt,
"<=": operator.le,
"==": operator.eq,
"!=": operator.ne,
">=": operator.ge,
">": operator.gt,
}
def _eval_op(lhs: str, op: Op, rhs: str) -> bool:
try:
spec = Specifier("".join([op.serialize(), rhs]))
except InvalidSpecifier:
pass
else:
return spec.contains(lhs)
oper: Optional[Operator] = _operators.get(op.serialize())
if oper is None:
raise UndefinedComparison(f"Undefined {op!r} on {lhs!r} and {rhs!r}.")
return oper(lhs, rhs)
class Undefined:
pass
_undefined = Undefined()
def _get_env(environment: Dict[str, str], name: str) -> str:
value: Union[str, Undefined] = environment.get(name, _undefined)
if isinstance(value, Undefined):
raise UndefinedEnvironmentName(
f"{name!r} does not exist in evaluation environment."
)
return value
def _evaluate_markers(markers: List[Any], environment: Dict[str, str]) -> bool:
groups: List[List[bool]] = [[]]
for marker in markers:
assert isinstance(marker, (list, tuple, str))
if isinstance(marker, list):
groups[-1].append(_evaluate_markers(marker, environment))
elif isinstance(marker, tuple):
lhs, op, rhs = marker
if isinstance(lhs, Variable):
lhs_value = _get_env(environment, lhs.value)
rhs_value = rhs.value
else:
lhs_value = lhs.value
rhs_value = _get_env(environment, rhs.value)
groups[-1].append(_eval_op(lhs_value, op, rhs_value))
else:
assert marker in ["and", "or"]
if marker == "or":
groups.append([])
return any(all(item) for item in groups)
def format_full_version(info: "sys._version_info") -> str:
version = "{0.major}.{0.minor}.{0.micro}".format(info)
kind = info.releaselevel
if kind != "final":
version += kind[0] + str(info.serial)
return version
def default_environment() -> Dict[str, str]:
iver = format_full_version(sys.implementation.version)
implementation_name = sys.implementation.name
return {
"implementation_name": implementation_name,
"implementation_version": iver,
"os_name": os.name,
"platform_machine": platform.machine(),
"platform_release": platform.release(),
"platform_system": platform.system(),
"platform_version": platform.version(),
"python_full_version": platform.python_version(),
"platform_python_implementation": platform.python_implementation(),
"python_version": ".".join(platform.python_version_tuple()[:2]),
"sys_platform": sys.platform,
}
class Marker:
def __init__(self, marker: str) -> None:
try:
self._markers = _coerce_parse_result(MARKER.parseString(marker))
except ParseException as e:
raise InvalidMarker(
f"Invalid marker: {marker!r}, parse error at "
f"{marker[e.loc : e.loc + 8]!r}"
)
def __str__(self) -> str:
return _format_marker(self._markers)
def __repr__(self) -> str:
return f"<Marker('{self}')>"
def evaluate(self, environment: Optional[Dict[str, str]] = None) -> bool:
"""Evaluate a marker.
Return the boolean from evaluating the given marker against the
environment. environment is an optional argument to override all or
part of the determined environment.
The environment is determined from the current Python process.
"""
current_environment = default_environment()
if environment is not None:
current_environment.update(environment)
return _evaluate_markers(self._markers, current_environment)
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/packaging/markers.py
|
Python
|
mit
| 8,496 |
# This file is dual licensed under the terms of the Apache License, Version
# 2.0, and the BSD License. See the LICENSE file in the root of this repository
# for complete details.
import re
import string
import urllib.parse
from typing import List, Optional as TOptional, Set
from pkg_resources.extern.pyparsing import ( # noqa
Combine,
Literal as L,
Optional,
ParseException,
Regex,
Word,
ZeroOrMore,
originalTextFor,
stringEnd,
stringStart,
)
from .markers import MARKER_EXPR, Marker
from .specifiers import LegacySpecifier, Specifier, SpecifierSet
class InvalidRequirement(ValueError):
"""
An invalid requirement was found, users should refer to PEP 508.
"""
ALPHANUM = Word(string.ascii_letters + string.digits)
LBRACKET = L("[").suppress()
RBRACKET = L("]").suppress()
LPAREN = L("(").suppress()
RPAREN = L(")").suppress()
COMMA = L(",").suppress()
SEMICOLON = L(";").suppress()
AT = L("@").suppress()
PUNCTUATION = Word("-_.")
IDENTIFIER_END = ALPHANUM | (ZeroOrMore(PUNCTUATION) + ALPHANUM)
IDENTIFIER = Combine(ALPHANUM + ZeroOrMore(IDENTIFIER_END))
NAME = IDENTIFIER("name")
EXTRA = IDENTIFIER
URI = Regex(r"[^ ]+")("url")
URL = AT + URI
EXTRAS_LIST = EXTRA + ZeroOrMore(COMMA + EXTRA)
EXTRAS = (LBRACKET + Optional(EXTRAS_LIST) + RBRACKET)("extras")
VERSION_PEP440 = Regex(Specifier._regex_str, re.VERBOSE | re.IGNORECASE)
VERSION_LEGACY = Regex(LegacySpecifier._regex_str, re.VERBOSE | re.IGNORECASE)
VERSION_ONE = VERSION_PEP440 ^ VERSION_LEGACY
VERSION_MANY = Combine(
VERSION_ONE + ZeroOrMore(COMMA + VERSION_ONE), joinString=",", adjacent=False
)("_raw_spec")
_VERSION_SPEC = Optional((LPAREN + VERSION_MANY + RPAREN) | VERSION_MANY)
_VERSION_SPEC.setParseAction(lambda s, l, t: t._raw_spec or "")
VERSION_SPEC = originalTextFor(_VERSION_SPEC)("specifier")
VERSION_SPEC.setParseAction(lambda s, l, t: t[1])
MARKER_EXPR = originalTextFor(MARKER_EXPR())("marker")
MARKER_EXPR.setParseAction(
lambda s, l, t: Marker(s[t._original_start : t._original_end])
)
MARKER_SEPARATOR = SEMICOLON
MARKER = MARKER_SEPARATOR + MARKER_EXPR
VERSION_AND_MARKER = VERSION_SPEC + Optional(MARKER)
URL_AND_MARKER = URL + Optional(MARKER)
NAMED_REQUIREMENT = NAME + Optional(EXTRAS) + (URL_AND_MARKER | VERSION_AND_MARKER)
REQUIREMENT = stringStart + NAMED_REQUIREMENT + stringEnd
# pkg_resources.extern.pyparsing isn't thread safe during initialization, so we do it eagerly, see
# issue #104
REQUIREMENT.parseString("x[]")
class Requirement:
"""Parse a requirement.
Parse a given requirement string into its parts, such as name, specifier,
URL, and extras. Raises InvalidRequirement on a badly-formed requirement
string.
"""
# TODO: Can we test whether something is contained within a requirement?
# If so how do we do that? Do we need to test against the _name_ of
# the thing as well as the version? What about the markers?
# TODO: Can we normalize the name and extra name?
def __init__(self, requirement_string: str) -> None:
try:
req = REQUIREMENT.parseString(requirement_string)
except ParseException as e:
raise InvalidRequirement(
f'Parse error at "{ requirement_string[e.loc : e.loc + 8]!r}": {e.msg}'
)
self.name: str = req.name
if req.url:
parsed_url = urllib.parse.urlparse(req.url)
if parsed_url.scheme == "file":
if urllib.parse.urlunparse(parsed_url) != req.url:
raise InvalidRequirement("Invalid URL given")
elif not (parsed_url.scheme and parsed_url.netloc) or (
not parsed_url.scheme and not parsed_url.netloc
):
raise InvalidRequirement(f"Invalid URL: {req.url}")
self.url: TOptional[str] = req.url
else:
self.url = None
self.extras: Set[str] = set(req.extras.asList() if req.extras else [])
self.specifier: SpecifierSet = SpecifierSet(req.specifier)
self.marker: TOptional[Marker] = req.marker if req.marker else None
def __str__(self) -> str:
parts: List[str] = [self.name]
if self.extras:
formatted_extras = ",".join(sorted(self.extras))
parts.append(f"[{formatted_extras}]")
if self.specifier:
parts.append(str(self.specifier))
if self.url:
parts.append(f"@ {self.url}")
if self.marker:
parts.append(" ")
if self.marker:
parts.append(f"; {self.marker}")
return "".join(parts)
def __repr__(self) -> str:
return f"<Requirement('{self}')>"
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/packaging/requirements.py
|
Python
|
mit
| 4,706 |
# This file is dual licensed under the terms of the Apache License, Version
# 2.0, and the BSD License. See the LICENSE file in the root of this repository
# for complete details.
import abc
import functools
import itertools
import re
import warnings
from typing import (
Callable,
Dict,
Iterable,
Iterator,
List,
Optional,
Pattern,
Set,
Tuple,
TypeVar,
Union,
)
from .utils import canonicalize_version
from .version import LegacyVersion, Version, parse
ParsedVersion = Union[Version, LegacyVersion]
UnparsedVersion = Union[Version, LegacyVersion, str]
VersionTypeVar = TypeVar("VersionTypeVar", bound=UnparsedVersion)
CallableOperator = Callable[[ParsedVersion, str], bool]
class InvalidSpecifier(ValueError):
"""
An invalid specifier was found, users should refer to PEP 440.
"""
class BaseSpecifier(metaclass=abc.ABCMeta):
@abc.abstractmethod
def __str__(self) -> str:
"""
Returns the str representation of this Specifier like object. This
should be representative of the Specifier itself.
"""
@abc.abstractmethod
def __hash__(self) -> int:
"""
Returns a hash value for this Specifier like object.
"""
@abc.abstractmethod
def __eq__(self, other: object) -> bool:
"""
Returns a boolean representing whether or not the two Specifier like
objects are equal.
"""
@abc.abstractproperty
def prereleases(self) -> Optional[bool]:
"""
Returns whether or not pre-releases as a whole are allowed by this
specifier.
"""
@prereleases.setter
def prereleases(self, value: bool) -> None:
"""
Sets whether or not pre-releases as a whole are allowed by this
specifier.
"""
@abc.abstractmethod
def contains(self, item: str, prereleases: Optional[bool] = None) -> bool:
"""
Determines if the given item is contained within this specifier.
"""
@abc.abstractmethod
def filter(
self, iterable: Iterable[VersionTypeVar], prereleases: Optional[bool] = None
) -> Iterable[VersionTypeVar]:
"""
Takes an iterable of items and filters them so that only items which
are contained within this specifier are allowed in it.
"""
class _IndividualSpecifier(BaseSpecifier):
_operators: Dict[str, str] = {}
_regex: Pattern[str]
def __init__(self, spec: str = "", prereleases: Optional[bool] = None) -> None:
match = self._regex.search(spec)
if not match:
raise InvalidSpecifier(f"Invalid specifier: '{spec}'")
self._spec: Tuple[str, str] = (
match.group("operator").strip(),
match.group("version").strip(),
)
# Store whether or not this Specifier should accept prereleases
self._prereleases = prereleases
def __repr__(self) -> str:
pre = (
f", prereleases={self.prereleases!r}"
if self._prereleases is not None
else ""
)
return f"<{self.__class__.__name__}({str(self)!r}{pre})>"
def __str__(self) -> str:
return "{}{}".format(*self._spec)
@property
def _canonical_spec(self) -> Tuple[str, str]:
return self._spec[0], canonicalize_version(self._spec[1])
def __hash__(self) -> int:
return hash(self._canonical_spec)
def __eq__(self, other: object) -> bool:
if isinstance(other, str):
try:
other = self.__class__(str(other))
except InvalidSpecifier:
return NotImplemented
elif not isinstance(other, self.__class__):
return NotImplemented
return self._canonical_spec == other._canonical_spec
def _get_operator(self, op: str) -> CallableOperator:
operator_callable: CallableOperator = getattr(
self, f"_compare_{self._operators[op]}"
)
return operator_callable
def _coerce_version(self, version: UnparsedVersion) -> ParsedVersion:
if not isinstance(version, (LegacyVersion, Version)):
version = parse(version)
return version
@property
def operator(self) -> str:
return self._spec[0]
@property
def version(self) -> str:
return self._spec[1]
@property
def prereleases(self) -> Optional[bool]:
return self._prereleases
@prereleases.setter
def prereleases(self, value: bool) -> None:
self._prereleases = value
def __contains__(self, item: str) -> bool:
return self.contains(item)
def contains(
self, item: UnparsedVersion, prereleases: Optional[bool] = None
) -> bool:
# Determine if prereleases are to be allowed or not.
if prereleases is None:
prereleases = self.prereleases
# Normalize item to a Version or LegacyVersion, this allows us to have
# a shortcut for ``"2.0" in Specifier(">=2")
normalized_item = self._coerce_version(item)
# Determine if we should be supporting prereleases in this specifier
# or not, if we do not support prereleases than we can short circuit
# logic if this version is a prereleases.
if normalized_item.is_prerelease and not prereleases:
return False
# Actually do the comparison to determine if this item is contained
# within this Specifier or not.
operator_callable: CallableOperator = self._get_operator(self.operator)
return operator_callable(normalized_item, self.version)
def filter(
self, iterable: Iterable[VersionTypeVar], prereleases: Optional[bool] = None
) -> Iterable[VersionTypeVar]:
yielded = False
found_prereleases = []
kw = {"prereleases": prereleases if prereleases is not None else True}
# Attempt to iterate over all the values in the iterable and if any of
# them match, yield them.
for version in iterable:
parsed_version = self._coerce_version(version)
if self.contains(parsed_version, **kw):
# If our version is a prerelease, and we were not set to allow
# prereleases, then we'll store it for later in case nothing
# else matches this specifier.
if parsed_version.is_prerelease and not (
prereleases or self.prereleases
):
found_prereleases.append(version)
# Either this is not a prerelease, or we should have been
# accepting prereleases from the beginning.
else:
yielded = True
yield version
# Now that we've iterated over everything, determine if we've yielded
# any values, and if we have not and we have any prereleases stored up
# then we will go ahead and yield the prereleases.
if not yielded and found_prereleases:
for version in found_prereleases:
yield version
class LegacySpecifier(_IndividualSpecifier):
_regex_str = r"""
(?P<operator>(==|!=|<=|>=|<|>))
\s*
(?P<version>
[^,;\s)]* # Since this is a "legacy" specifier, and the version
# string can be just about anything, we match everything
# except for whitespace, a semi-colon for marker support,
# a closing paren since versions can be enclosed in
# them, and a comma since it's a version separator.
)
"""
_regex = re.compile(r"^\s*" + _regex_str + r"\s*$", re.VERBOSE | re.IGNORECASE)
_operators = {
"==": "equal",
"!=": "not_equal",
"<=": "less_than_equal",
">=": "greater_than_equal",
"<": "less_than",
">": "greater_than",
}
def __init__(self, spec: str = "", prereleases: Optional[bool] = None) -> None:
super().__init__(spec, prereleases)
warnings.warn(
"Creating a LegacyVersion has been deprecated and will be "
"removed in the next major release",
DeprecationWarning,
)
def _coerce_version(self, version: UnparsedVersion) -> LegacyVersion:
if not isinstance(version, LegacyVersion):
version = LegacyVersion(str(version))
return version
def _compare_equal(self, prospective: LegacyVersion, spec: str) -> bool:
return prospective == self._coerce_version(spec)
def _compare_not_equal(self, prospective: LegacyVersion, spec: str) -> bool:
return prospective != self._coerce_version(spec)
def _compare_less_than_equal(self, prospective: LegacyVersion, spec: str) -> bool:
return prospective <= self._coerce_version(spec)
def _compare_greater_than_equal(
self, prospective: LegacyVersion, spec: str
) -> bool:
return prospective >= self._coerce_version(spec)
def _compare_less_than(self, prospective: LegacyVersion, spec: str) -> bool:
return prospective < self._coerce_version(spec)
def _compare_greater_than(self, prospective: LegacyVersion, spec: str) -> bool:
return prospective > self._coerce_version(spec)
def _require_version_compare(
fn: Callable[["Specifier", ParsedVersion, str], bool]
) -> Callable[["Specifier", ParsedVersion, str], bool]:
@functools.wraps(fn)
def wrapped(self: "Specifier", prospective: ParsedVersion, spec: str) -> bool:
if not isinstance(prospective, Version):
return False
return fn(self, prospective, spec)
return wrapped
class Specifier(_IndividualSpecifier):
_regex_str = r"""
(?P<operator>(~=|==|!=|<=|>=|<|>|===))
(?P<version>
(?:
# The identity operators allow for an escape hatch that will
# do an exact string match of the version you wish to install.
# This will not be parsed by PEP 440 and we cannot determine
# any semantic meaning from it. This operator is discouraged
# but included entirely as an escape hatch.
(?<====) # Only match for the identity operator
\s*
[^\s]* # We just match everything, except for whitespace
# since we are only testing for strict identity.
)
|
(?:
# The (non)equality operators allow for wild card and local
# versions to be specified so we have to define these two
# operators separately to enable that.
(?<===|!=) # Only match for equals and not equals
\s*
v?
(?:[0-9]+!)? # epoch
[0-9]+(?:\.[0-9]+)* # release
(?: # pre release
[-_\.]?
(a|b|c|rc|alpha|beta|pre|preview)
[-_\.]?
[0-9]*
)?
(?: # post release
(?:-[0-9]+)|(?:[-_\.]?(post|rev|r)[-_\.]?[0-9]*)
)?
# You cannot use a wild card and a dev or local version
# together so group them with a | and make them optional.
(?:
(?:[-_\.]?dev[-_\.]?[0-9]*)? # dev release
(?:\+[a-z0-9]+(?:[-_\.][a-z0-9]+)*)? # local
|
\.\* # Wild card syntax of .*
)?
)
|
(?:
# The compatible operator requires at least two digits in the
# release segment.
(?<=~=) # Only match for the compatible operator
\s*
v?
(?:[0-9]+!)? # epoch
[0-9]+(?:\.[0-9]+)+ # release (We have a + instead of a *)
(?: # pre release
[-_\.]?
(a|b|c|rc|alpha|beta|pre|preview)
[-_\.]?
[0-9]*
)?
(?: # post release
(?:-[0-9]+)|(?:[-_\.]?(post|rev|r)[-_\.]?[0-9]*)
)?
(?:[-_\.]?dev[-_\.]?[0-9]*)? # dev release
)
|
(?:
# All other operators only allow a sub set of what the
# (non)equality operators do. Specifically they do not allow
# local versions to be specified nor do they allow the prefix
# matching wild cards.
(?<!==|!=|~=) # We have special cases for these
# operators so we want to make sure they
# don't match here.
\s*
v?
(?:[0-9]+!)? # epoch
[0-9]+(?:\.[0-9]+)* # release
(?: # pre release
[-_\.]?
(a|b|c|rc|alpha|beta|pre|preview)
[-_\.]?
[0-9]*
)?
(?: # post release
(?:-[0-9]+)|(?:[-_\.]?(post|rev|r)[-_\.]?[0-9]*)
)?
(?:[-_\.]?dev[-_\.]?[0-9]*)? # dev release
)
)
"""
_regex = re.compile(r"^\s*" + _regex_str + r"\s*$", re.VERBOSE | re.IGNORECASE)
_operators = {
"~=": "compatible",
"==": "equal",
"!=": "not_equal",
"<=": "less_than_equal",
">=": "greater_than_equal",
"<": "less_than",
">": "greater_than",
"===": "arbitrary",
}
@_require_version_compare
def _compare_compatible(self, prospective: ParsedVersion, spec: str) -> bool:
# Compatible releases have an equivalent combination of >= and ==. That
# is that ~=2.2 is equivalent to >=2.2,==2.*. This allows us to
# implement this in terms of the other specifiers instead of
# implementing it ourselves. The only thing we need to do is construct
# the other specifiers.
# We want everything but the last item in the version, but we want to
# ignore suffix segments.
prefix = ".".join(
list(itertools.takewhile(_is_not_suffix, _version_split(spec)))[:-1]
)
# Add the prefix notation to the end of our string
prefix += ".*"
return self._get_operator(">=")(prospective, spec) and self._get_operator("==")(
prospective, prefix
)
@_require_version_compare
def _compare_equal(self, prospective: ParsedVersion, spec: str) -> bool:
# We need special logic to handle prefix matching
if spec.endswith(".*"):
# In the case of prefix matching we want to ignore local segment.
prospective = Version(prospective.public)
# Split the spec out by dots, and pretend that there is an implicit
# dot in between a release segment and a pre-release segment.
split_spec = _version_split(spec[:-2]) # Remove the trailing .*
# Split the prospective version out by dots, and pretend that there
# is an implicit dot in between a release segment and a pre-release
# segment.
split_prospective = _version_split(str(prospective))
# Shorten the prospective version to be the same length as the spec
# so that we can determine if the specifier is a prefix of the
# prospective version or not.
shortened_prospective = split_prospective[: len(split_spec)]
# Pad out our two sides with zeros so that they both equal the same
# length.
padded_spec, padded_prospective = _pad_version(
split_spec, shortened_prospective
)
return padded_prospective == padded_spec
else:
# Convert our spec string into a Version
spec_version = Version(spec)
# If the specifier does not have a local segment, then we want to
# act as if the prospective version also does not have a local
# segment.
if not spec_version.local:
prospective = Version(prospective.public)
return prospective == spec_version
@_require_version_compare
def _compare_not_equal(self, prospective: ParsedVersion, spec: str) -> bool:
return not self._compare_equal(prospective, spec)
@_require_version_compare
def _compare_less_than_equal(self, prospective: ParsedVersion, spec: str) -> bool:
# NB: Local version identifiers are NOT permitted in the version
# specifier, so local version labels can be universally removed from
# the prospective version.
return Version(prospective.public) <= Version(spec)
@_require_version_compare
def _compare_greater_than_equal(
self, prospective: ParsedVersion, spec: str
) -> bool:
# NB: Local version identifiers are NOT permitted in the version
# specifier, so local version labels can be universally removed from
# the prospective version.
return Version(prospective.public) >= Version(spec)
@_require_version_compare
def _compare_less_than(self, prospective: ParsedVersion, spec_str: str) -> bool:
# Convert our spec to a Version instance, since we'll want to work with
# it as a version.
spec = Version(spec_str)
# Check to see if the prospective version is less than the spec
# version. If it's not we can short circuit and just return False now
# instead of doing extra unneeded work.
if not prospective < spec:
return False
# This special case is here so that, unless the specifier itself
# includes is a pre-release version, that we do not accept pre-release
# versions for the version mentioned in the specifier (e.g. <3.1 should
# not match 3.1.dev0, but should match 3.0.dev0).
if not spec.is_prerelease and prospective.is_prerelease:
if Version(prospective.base_version) == Version(spec.base_version):
return False
# If we've gotten to here, it means that prospective version is both
# less than the spec version *and* it's not a pre-release of the same
# version in the spec.
return True
@_require_version_compare
def _compare_greater_than(self, prospective: ParsedVersion, spec_str: str) -> bool:
# Convert our spec to a Version instance, since we'll want to work with
# it as a version.
spec = Version(spec_str)
# Check to see if the prospective version is greater than the spec
# version. If it's not we can short circuit and just return False now
# instead of doing extra unneeded work.
if not prospective > spec:
return False
# This special case is here so that, unless the specifier itself
# includes is a post-release version, that we do not accept
# post-release versions for the version mentioned in the specifier
# (e.g. >3.1 should not match 3.0.post0, but should match 3.2.post0).
if not spec.is_postrelease and prospective.is_postrelease:
if Version(prospective.base_version) == Version(spec.base_version):
return False
# Ensure that we do not allow a local version of the version mentioned
# in the specifier, which is technically greater than, to match.
if prospective.local is not None:
if Version(prospective.base_version) == Version(spec.base_version):
return False
# If we've gotten to here, it means that prospective version is both
# greater than the spec version *and* it's not a pre-release of the
# same version in the spec.
return True
def _compare_arbitrary(self, prospective: Version, spec: str) -> bool:
return str(prospective).lower() == str(spec).lower()
@property
def prereleases(self) -> bool:
# If there is an explicit prereleases set for this, then we'll just
# blindly use that.
if self._prereleases is not None:
return self._prereleases
# Look at all of our specifiers and determine if they are inclusive
# operators, and if they are if they are including an explicit
# prerelease.
operator, version = self._spec
if operator in ["==", ">=", "<=", "~=", "==="]:
# The == specifier can include a trailing .*, if it does we
# want to remove before parsing.
if operator == "==" and version.endswith(".*"):
version = version[:-2]
# Parse the version, and if it is a pre-release than this
# specifier allows pre-releases.
if parse(version).is_prerelease:
return True
return False
@prereleases.setter
def prereleases(self, value: bool) -> None:
self._prereleases = value
_prefix_regex = re.compile(r"^([0-9]+)((?:a|b|c|rc)[0-9]+)$")
def _version_split(version: str) -> List[str]:
result: List[str] = []
for item in version.split("."):
match = _prefix_regex.search(item)
if match:
result.extend(match.groups())
else:
result.append(item)
return result
def _is_not_suffix(segment: str) -> bool:
return not any(
segment.startswith(prefix) for prefix in ("dev", "a", "b", "rc", "post")
)
def _pad_version(left: List[str], right: List[str]) -> Tuple[List[str], List[str]]:
left_split, right_split = [], []
# Get the release segment of our versions
left_split.append(list(itertools.takewhile(lambda x: x.isdigit(), left)))
right_split.append(list(itertools.takewhile(lambda x: x.isdigit(), right)))
# Get the rest of our versions
left_split.append(left[len(left_split[0]) :])
right_split.append(right[len(right_split[0]) :])
# Insert our padding
left_split.insert(1, ["0"] * max(0, len(right_split[0]) - len(left_split[0])))
right_split.insert(1, ["0"] * max(0, len(left_split[0]) - len(right_split[0])))
return (list(itertools.chain(*left_split)), list(itertools.chain(*right_split)))
class SpecifierSet(BaseSpecifier):
def __init__(
self, specifiers: str = "", prereleases: Optional[bool] = None
) -> None:
# Split on , to break each individual specifier into it's own item, and
# strip each item to remove leading/trailing whitespace.
split_specifiers = [s.strip() for s in specifiers.split(",") if s.strip()]
# Parsed each individual specifier, attempting first to make it a
# Specifier and falling back to a LegacySpecifier.
parsed: Set[_IndividualSpecifier] = set()
for specifier in split_specifiers:
try:
parsed.add(Specifier(specifier))
except InvalidSpecifier:
parsed.add(LegacySpecifier(specifier))
# Turn our parsed specifiers into a frozen set and save them for later.
self._specs = frozenset(parsed)
# Store our prereleases value so we can use it later to determine if
# we accept prereleases or not.
self._prereleases = prereleases
def __repr__(self) -> str:
pre = (
f", prereleases={self.prereleases!r}"
if self._prereleases is not None
else ""
)
return f"<SpecifierSet({str(self)!r}{pre})>"
def __str__(self) -> str:
return ",".join(sorted(str(s) for s in self._specs))
def __hash__(self) -> int:
return hash(self._specs)
def __and__(self, other: Union["SpecifierSet", str]) -> "SpecifierSet":
if isinstance(other, str):
other = SpecifierSet(other)
elif not isinstance(other, SpecifierSet):
return NotImplemented
specifier = SpecifierSet()
specifier._specs = frozenset(self._specs | other._specs)
if self._prereleases is None and other._prereleases is not None:
specifier._prereleases = other._prereleases
elif self._prereleases is not None and other._prereleases is None:
specifier._prereleases = self._prereleases
elif self._prereleases == other._prereleases:
specifier._prereleases = self._prereleases
else:
raise ValueError(
"Cannot combine SpecifierSets with True and False prerelease "
"overrides."
)
return specifier
def __eq__(self, other: object) -> bool:
if isinstance(other, (str, _IndividualSpecifier)):
other = SpecifierSet(str(other))
elif not isinstance(other, SpecifierSet):
return NotImplemented
return self._specs == other._specs
def __len__(self) -> int:
return len(self._specs)
def __iter__(self) -> Iterator[_IndividualSpecifier]:
return iter(self._specs)
@property
def prereleases(self) -> Optional[bool]:
# If we have been given an explicit prerelease modifier, then we'll
# pass that through here.
if self._prereleases is not None:
return self._prereleases
# If we don't have any specifiers, and we don't have a forced value,
# then we'll just return None since we don't know if this should have
# pre-releases or not.
if not self._specs:
return None
# Otherwise we'll see if any of the given specifiers accept
# prereleases, if any of them do we'll return True, otherwise False.
return any(s.prereleases for s in self._specs)
@prereleases.setter
def prereleases(self, value: bool) -> None:
self._prereleases = value
def __contains__(self, item: UnparsedVersion) -> bool:
return self.contains(item)
def contains(
self, item: UnparsedVersion, prereleases: Optional[bool] = None
) -> bool:
# Ensure that our item is a Version or LegacyVersion instance.
if not isinstance(item, (LegacyVersion, Version)):
item = parse(item)
# Determine if we're forcing a prerelease or not, if we're not forcing
# one for this particular filter call, then we'll use whatever the
# SpecifierSet thinks for whether or not we should support prereleases.
if prereleases is None:
prereleases = self.prereleases
# We can determine if we're going to allow pre-releases by looking to
# see if any of the underlying items supports them. If none of them do
# and this item is a pre-release then we do not allow it and we can
# short circuit that here.
# Note: This means that 1.0.dev1 would not be contained in something
# like >=1.0.devabc however it would be in >=1.0.debabc,>0.0.dev0
if not prereleases and item.is_prerelease:
return False
# We simply dispatch to the underlying specs here to make sure that the
# given version is contained within all of them.
# Note: This use of all() here means that an empty set of specifiers
# will always return True, this is an explicit design decision.
return all(s.contains(item, prereleases=prereleases) for s in self._specs)
def filter(
self, iterable: Iterable[VersionTypeVar], prereleases: Optional[bool] = None
) -> Iterable[VersionTypeVar]:
# Determine if we're forcing a prerelease or not, if we're not forcing
# one for this particular filter call, then we'll use whatever the
# SpecifierSet thinks for whether or not we should support prereleases.
if prereleases is None:
prereleases = self.prereleases
# If we have any specifiers, then we want to wrap our iterable in the
# filter method for each one, this will act as a logical AND amongst
# each specifier.
if self._specs:
for spec in self._specs:
iterable = spec.filter(iterable, prereleases=bool(prereleases))
return iterable
# If we do not have any specifiers, then we need to have a rough filter
# which will filter out any pre-releases, unless there are no final
# releases, and which will filter out LegacyVersion in general.
else:
filtered: List[VersionTypeVar] = []
found_prereleases: List[VersionTypeVar] = []
item: UnparsedVersion
parsed_version: Union[Version, LegacyVersion]
for item in iterable:
# Ensure that we some kind of Version class for this item.
if not isinstance(item, (LegacyVersion, Version)):
parsed_version = parse(item)
else:
parsed_version = item
# Filter out any item which is parsed as a LegacyVersion
if isinstance(parsed_version, LegacyVersion):
continue
# Store any item which is a pre-release for later unless we've
# already found a final version or we are accepting prereleases
if parsed_version.is_prerelease and not prereleases:
if not filtered:
found_prereleases.append(item)
else:
filtered.append(item)
# If we've found no items except for pre-releases, then we'll go
# ahead and use the pre-releases
if not filtered and found_prereleases and prereleases is None:
return found_prereleases
return filtered
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/packaging/specifiers.py
|
Python
|
mit
| 30,110 |
# This file is dual licensed under the terms of the Apache License, Version
# 2.0, and the BSD License. See the LICENSE file in the root of this repository
# for complete details.
import logging
import platform
import sys
import sysconfig
from importlib.machinery import EXTENSION_SUFFIXES
from typing import (
Dict,
FrozenSet,
Iterable,
Iterator,
List,
Optional,
Sequence,
Tuple,
Union,
cast,
)
from . import _manylinux, _musllinux
logger = logging.getLogger(__name__)
PythonVersion = Sequence[int]
MacVersion = Tuple[int, int]
INTERPRETER_SHORT_NAMES: Dict[str, str] = {
"python": "py", # Generic.
"cpython": "cp",
"pypy": "pp",
"ironpython": "ip",
"jython": "jy",
}
_32_BIT_INTERPRETER = sys.maxsize <= 2 ** 32
class Tag:
"""
A representation of the tag triple for a wheel.
Instances are considered immutable and thus are hashable. Equality checking
is also supported.
"""
__slots__ = ["_interpreter", "_abi", "_platform", "_hash"]
def __init__(self, interpreter: str, abi: str, platform: str) -> None:
self._interpreter = interpreter.lower()
self._abi = abi.lower()
self._platform = platform.lower()
# The __hash__ of every single element in a Set[Tag] will be evaluated each time
# that a set calls its `.disjoint()` method, which may be called hundreds of
# times when scanning a page of links for packages with tags matching that
# Set[Tag]. Pre-computing the value here produces significant speedups for
# downstream consumers.
self._hash = hash((self._interpreter, self._abi, self._platform))
@property
def interpreter(self) -> str:
return self._interpreter
@property
def abi(self) -> str:
return self._abi
@property
def platform(self) -> str:
return self._platform
def __eq__(self, other: object) -> bool:
if not isinstance(other, Tag):
return NotImplemented
return (
(self._hash == other._hash) # Short-circuit ASAP for perf reasons.
and (self._platform == other._platform)
and (self._abi == other._abi)
and (self._interpreter == other._interpreter)
)
def __hash__(self) -> int:
return self._hash
def __str__(self) -> str:
return f"{self._interpreter}-{self._abi}-{self._platform}"
def __repr__(self) -> str:
return f"<{self} @ {id(self)}>"
def parse_tag(tag: str) -> FrozenSet[Tag]:
"""
Parses the provided tag (e.g. `py3-none-any`) into a frozenset of Tag instances.
Returning a set is required due to the possibility that the tag is a
compressed tag set.
"""
tags = set()
interpreters, abis, platforms = tag.split("-")
for interpreter in interpreters.split("."):
for abi in abis.split("."):
for platform_ in platforms.split("."):
tags.add(Tag(interpreter, abi, platform_))
return frozenset(tags)
def _get_config_var(name: str, warn: bool = False) -> Union[int, str, None]:
value = sysconfig.get_config_var(name)
if value is None and warn:
logger.debug(
"Config variable '%s' is unset, Python ABI tag may be incorrect", name
)
return value
def _normalize_string(string: str) -> str:
return string.replace(".", "_").replace("-", "_")
def _abi3_applies(python_version: PythonVersion) -> bool:
"""
Determine if the Python version supports abi3.
PEP 384 was first implemented in Python 3.2.
"""
return len(python_version) > 1 and tuple(python_version) >= (3, 2)
def _cpython_abis(py_version: PythonVersion, warn: bool = False) -> List[str]:
py_version = tuple(py_version) # To allow for version comparison.
abis = []
version = _version_nodot(py_version[:2])
debug = pymalloc = ucs4 = ""
with_debug = _get_config_var("Py_DEBUG", warn)
has_refcount = hasattr(sys, "gettotalrefcount")
# Windows doesn't set Py_DEBUG, so checking for support of debug-compiled
# extension modules is the best option.
# https://github.com/pypa/pip/issues/3383#issuecomment-173267692
has_ext = "_d.pyd" in EXTENSION_SUFFIXES
if with_debug or (with_debug is None and (has_refcount or has_ext)):
debug = "d"
if py_version < (3, 8):
with_pymalloc = _get_config_var("WITH_PYMALLOC", warn)
if with_pymalloc or with_pymalloc is None:
pymalloc = "m"
if py_version < (3, 3):
unicode_size = _get_config_var("Py_UNICODE_SIZE", warn)
if unicode_size == 4 or (
unicode_size is None and sys.maxunicode == 0x10FFFF
):
ucs4 = "u"
elif debug:
# Debug builds can also load "normal" extension modules.
# We can also assume no UCS-4 or pymalloc requirement.
abis.append(f"cp{version}")
abis.insert(
0,
"cp{version}{debug}{pymalloc}{ucs4}".format(
version=version, debug=debug, pymalloc=pymalloc, ucs4=ucs4
),
)
return abis
def cpython_tags(
python_version: Optional[PythonVersion] = None,
abis: Optional[Iterable[str]] = None,
platforms: Optional[Iterable[str]] = None,
*,
warn: bool = False,
) -> Iterator[Tag]:
"""
Yields the tags for a CPython interpreter.
The tags consist of:
- cp<python_version>-<abi>-<platform>
- cp<python_version>-abi3-<platform>
- cp<python_version>-none-<platform>
- cp<less than python_version>-abi3-<platform> # Older Python versions down to 3.2.
If python_version only specifies a major version then user-provided ABIs and
the 'none' ABItag will be used.
If 'abi3' or 'none' are specified in 'abis' then they will be yielded at
their normal position and not at the beginning.
"""
if not python_version:
python_version = sys.version_info[:2]
interpreter = f"cp{_version_nodot(python_version[:2])}"
if abis is None:
if len(python_version) > 1:
abis = _cpython_abis(python_version, warn)
else:
abis = []
abis = list(abis)
# 'abi3' and 'none' are explicitly handled later.
for explicit_abi in ("abi3", "none"):
try:
abis.remove(explicit_abi)
except ValueError:
pass
platforms = list(platforms or platform_tags())
for abi in abis:
for platform_ in platforms:
yield Tag(interpreter, abi, platform_)
if _abi3_applies(python_version):
yield from (Tag(interpreter, "abi3", platform_) for platform_ in platforms)
yield from (Tag(interpreter, "none", platform_) for platform_ in platforms)
if _abi3_applies(python_version):
for minor_version in range(python_version[1] - 1, 1, -1):
for platform_ in platforms:
interpreter = "cp{version}".format(
version=_version_nodot((python_version[0], minor_version))
)
yield Tag(interpreter, "abi3", platform_)
def _generic_abi() -> Iterator[str]:
abi = sysconfig.get_config_var("SOABI")
if abi:
yield _normalize_string(abi)
def generic_tags(
interpreter: Optional[str] = None,
abis: Optional[Iterable[str]] = None,
platforms: Optional[Iterable[str]] = None,
*,
warn: bool = False,
) -> Iterator[Tag]:
"""
Yields the tags for a generic interpreter.
The tags consist of:
- <interpreter>-<abi>-<platform>
The "none" ABI will be added if it was not explicitly provided.
"""
if not interpreter:
interp_name = interpreter_name()
interp_version = interpreter_version(warn=warn)
interpreter = "".join([interp_name, interp_version])
if abis is None:
abis = _generic_abi()
platforms = list(platforms or platform_tags())
abis = list(abis)
if "none" not in abis:
abis.append("none")
for abi in abis:
for platform_ in platforms:
yield Tag(interpreter, abi, platform_)
def _py_interpreter_range(py_version: PythonVersion) -> Iterator[str]:
"""
Yields Python versions in descending order.
After the latest version, the major-only version will be yielded, and then
all previous versions of that major version.
"""
if len(py_version) > 1:
yield f"py{_version_nodot(py_version[:2])}"
yield f"py{py_version[0]}"
if len(py_version) > 1:
for minor in range(py_version[1] - 1, -1, -1):
yield f"py{_version_nodot((py_version[0], minor))}"
def compatible_tags(
python_version: Optional[PythonVersion] = None,
interpreter: Optional[str] = None,
platforms: Optional[Iterable[str]] = None,
) -> Iterator[Tag]:
"""
Yields the sequence of tags that are compatible with a specific version of Python.
The tags consist of:
- py*-none-<platform>
- <interpreter>-none-any # ... if `interpreter` is provided.
- py*-none-any
"""
if not python_version:
python_version = sys.version_info[:2]
platforms = list(platforms or platform_tags())
for version in _py_interpreter_range(python_version):
for platform_ in platforms:
yield Tag(version, "none", platform_)
if interpreter:
yield Tag(interpreter, "none", "any")
for version in _py_interpreter_range(python_version):
yield Tag(version, "none", "any")
def _mac_arch(arch: str, is_32bit: bool = _32_BIT_INTERPRETER) -> str:
if not is_32bit:
return arch
if arch.startswith("ppc"):
return "ppc"
return "i386"
def _mac_binary_formats(version: MacVersion, cpu_arch: str) -> List[str]:
formats = [cpu_arch]
if cpu_arch == "x86_64":
if version < (10, 4):
return []
formats.extend(["intel", "fat64", "fat32"])
elif cpu_arch == "i386":
if version < (10, 4):
return []
formats.extend(["intel", "fat32", "fat"])
elif cpu_arch == "ppc64":
# TODO: Need to care about 32-bit PPC for ppc64 through 10.2?
if version > (10, 5) or version < (10, 4):
return []
formats.append("fat64")
elif cpu_arch == "ppc":
if version > (10, 6):
return []
formats.extend(["fat32", "fat"])
if cpu_arch in {"arm64", "x86_64"}:
formats.append("universal2")
if cpu_arch in {"x86_64", "i386", "ppc64", "ppc", "intel"}:
formats.append("universal")
return formats
def mac_platforms(
version: Optional[MacVersion] = None, arch: Optional[str] = None
) -> Iterator[str]:
"""
Yields the platform tags for a macOS system.
The `version` parameter is a two-item tuple specifying the macOS version to
generate platform tags for. The `arch` parameter is the CPU architecture to
generate platform tags for. Both parameters default to the appropriate value
for the current system.
"""
version_str, _, cpu_arch = platform.mac_ver()
if version is None:
version = cast("MacVersion", tuple(map(int, version_str.split(".")[:2])))
else:
version = version
if arch is None:
arch = _mac_arch(cpu_arch)
else:
arch = arch
if (10, 0) <= version and version < (11, 0):
# Prior to Mac OS 11, each yearly release of Mac OS bumped the
# "minor" version number. The major version was always 10.
for minor_version in range(version[1], -1, -1):
compat_version = 10, minor_version
binary_formats = _mac_binary_formats(compat_version, arch)
for binary_format in binary_formats:
yield "macosx_{major}_{minor}_{binary_format}".format(
major=10, minor=minor_version, binary_format=binary_format
)
if version >= (11, 0):
# Starting with Mac OS 11, each yearly release bumps the major version
# number. The minor versions are now the midyear updates.
for major_version in range(version[0], 10, -1):
compat_version = major_version, 0
binary_formats = _mac_binary_formats(compat_version, arch)
for binary_format in binary_formats:
yield "macosx_{major}_{minor}_{binary_format}".format(
major=major_version, minor=0, binary_format=binary_format
)
if version >= (11, 0):
# Mac OS 11 on x86_64 is compatible with binaries from previous releases.
# Arm64 support was introduced in 11.0, so no Arm binaries from previous
# releases exist.
#
# However, the "universal2" binary format can have a
# macOS version earlier than 11.0 when the x86_64 part of the binary supports
# that version of macOS.
if arch == "x86_64":
for minor_version in range(16, 3, -1):
compat_version = 10, minor_version
binary_formats = _mac_binary_formats(compat_version, arch)
for binary_format in binary_formats:
yield "macosx_{major}_{minor}_{binary_format}".format(
major=compat_version[0],
minor=compat_version[1],
binary_format=binary_format,
)
else:
for minor_version in range(16, 3, -1):
compat_version = 10, minor_version
binary_format = "universal2"
yield "macosx_{major}_{minor}_{binary_format}".format(
major=compat_version[0],
minor=compat_version[1],
binary_format=binary_format,
)
def _linux_platforms(is_32bit: bool = _32_BIT_INTERPRETER) -> Iterator[str]:
linux = _normalize_string(sysconfig.get_platform())
if is_32bit:
if linux == "linux_x86_64":
linux = "linux_i686"
elif linux == "linux_aarch64":
linux = "linux_armv7l"
_, arch = linux.split("_", 1)
yield from _manylinux.platform_tags(linux, arch)
yield from _musllinux.platform_tags(arch)
yield linux
def _generic_platforms() -> Iterator[str]:
yield _normalize_string(sysconfig.get_platform())
def platform_tags() -> Iterator[str]:
"""
Provides the platform tags for this installation.
"""
if platform.system() == "Darwin":
return mac_platforms()
elif platform.system() == "Linux":
return _linux_platforms()
else:
return _generic_platforms()
def interpreter_name() -> str:
"""
Returns the name of the running interpreter.
"""
name = sys.implementation.name
return INTERPRETER_SHORT_NAMES.get(name) or name
def interpreter_version(*, warn: bool = False) -> str:
"""
Returns the version of the running interpreter.
"""
version = _get_config_var("py_version_nodot", warn=warn)
if version:
version = str(version)
else:
version = _version_nodot(sys.version_info[:2])
return version
def _version_nodot(version: PythonVersion) -> str:
return "".join(map(str, version))
def sys_tags(*, warn: bool = False) -> Iterator[Tag]:
"""
Returns the sequence of tag triples for the running interpreter.
The order of the sequence corresponds to priority order for the
interpreter, from most to least important.
"""
interp_name = interpreter_name()
if interp_name == "cp":
yield from cpython_tags(warn=warn)
else:
yield from generic_tags()
if interp_name == "pp":
yield from compatible_tags(interpreter="pp3")
else:
yield from compatible_tags()
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/packaging/tags.py
|
Python
|
mit
| 15,699 |
# This file is dual licensed under the terms of the Apache License, Version
# 2.0, and the BSD License. See the LICENSE file in the root of this repository
# for complete details.
import re
from typing import FrozenSet, NewType, Tuple, Union, cast
from .tags import Tag, parse_tag
from .version import InvalidVersion, Version
BuildTag = Union[Tuple[()], Tuple[int, str]]
NormalizedName = NewType("NormalizedName", str)
class InvalidWheelFilename(ValueError):
"""
An invalid wheel filename was found, users should refer to PEP 427.
"""
class InvalidSdistFilename(ValueError):
"""
An invalid sdist filename was found, users should refer to the packaging user guide.
"""
_canonicalize_regex = re.compile(r"[-_.]+")
# PEP 427: The build number must start with a digit.
_build_tag_regex = re.compile(r"(\d+)(.*)")
def canonicalize_name(name: str) -> NormalizedName:
# This is taken from PEP 503.
value = _canonicalize_regex.sub("-", name).lower()
return cast(NormalizedName, value)
def canonicalize_version(version: Union[Version, str]) -> str:
"""
This is very similar to Version.__str__, but has one subtle difference
with the way it handles the release segment.
"""
if isinstance(version, str):
try:
parsed = Version(version)
except InvalidVersion:
# Legacy versions cannot be normalized
return version
else:
parsed = version
parts = []
# Epoch
if parsed.epoch != 0:
parts.append(f"{parsed.epoch}!")
# Release segment
# NB: This strips trailing '.0's to normalize
parts.append(re.sub(r"(\.0)+$", "", ".".join(str(x) for x in parsed.release)))
# Pre-release
if parsed.pre is not None:
parts.append("".join(str(x) for x in parsed.pre))
# Post-release
if parsed.post is not None:
parts.append(f".post{parsed.post}")
# Development release
if parsed.dev is not None:
parts.append(f".dev{parsed.dev}")
# Local version segment
if parsed.local is not None:
parts.append(f"+{parsed.local}")
return "".join(parts)
def parse_wheel_filename(
filename: str,
) -> Tuple[NormalizedName, Version, BuildTag, FrozenSet[Tag]]:
if not filename.endswith(".whl"):
raise InvalidWheelFilename(
f"Invalid wheel filename (extension must be '.whl'): {filename}"
)
filename = filename[:-4]
dashes = filename.count("-")
if dashes not in (4, 5):
raise InvalidWheelFilename(
f"Invalid wheel filename (wrong number of parts): {filename}"
)
parts = filename.split("-", dashes - 2)
name_part = parts[0]
# See PEP 427 for the rules on escaping the project name
if "__" in name_part or re.match(r"^[\w\d._]*$", name_part, re.UNICODE) is None:
raise InvalidWheelFilename(f"Invalid project name: {filename}")
name = canonicalize_name(name_part)
version = Version(parts[1])
if dashes == 5:
build_part = parts[2]
build_match = _build_tag_regex.match(build_part)
if build_match is None:
raise InvalidWheelFilename(
f"Invalid build number: {build_part} in '{filename}'"
)
build = cast(BuildTag, (int(build_match.group(1)), build_match.group(2)))
else:
build = ()
tags = parse_tag(parts[-1])
return (name, version, build, tags)
def parse_sdist_filename(filename: str) -> Tuple[NormalizedName, Version]:
if filename.endswith(".tar.gz"):
file_stem = filename[: -len(".tar.gz")]
elif filename.endswith(".zip"):
file_stem = filename[: -len(".zip")]
else:
raise InvalidSdistFilename(
f"Invalid sdist filename (extension must be '.tar.gz' or '.zip'):"
f" {filename}"
)
# We are requiring a PEP 440 version, which cannot contain dashes,
# so we split on the last dash.
name_part, sep, version_part = file_stem.rpartition("-")
if not sep:
raise InvalidSdistFilename(f"Invalid sdist filename: {filename}")
name = canonicalize_name(name_part)
version = Version(version_part)
return (name, version)
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/packaging/utils.py
|
Python
|
mit
| 4,200 |
# This file is dual licensed under the terms of the Apache License, Version
# 2.0, and the BSD License. See the LICENSE file in the root of this repository
# for complete details.
import collections
import itertools
import re
import warnings
from typing import Callable, Iterator, List, Optional, SupportsInt, Tuple, Union
from ._structures import Infinity, InfinityType, NegativeInfinity, NegativeInfinityType
__all__ = ["parse", "Version", "LegacyVersion", "InvalidVersion", "VERSION_PATTERN"]
InfiniteTypes = Union[InfinityType, NegativeInfinityType]
PrePostDevType = Union[InfiniteTypes, Tuple[str, int]]
SubLocalType = Union[InfiniteTypes, int, str]
LocalType = Union[
NegativeInfinityType,
Tuple[
Union[
SubLocalType,
Tuple[SubLocalType, str],
Tuple[NegativeInfinityType, SubLocalType],
],
...,
],
]
CmpKey = Tuple[
int, Tuple[int, ...], PrePostDevType, PrePostDevType, PrePostDevType, LocalType
]
LegacyCmpKey = Tuple[int, Tuple[str, ...]]
VersionComparisonMethod = Callable[
[Union[CmpKey, LegacyCmpKey], Union[CmpKey, LegacyCmpKey]], bool
]
_Version = collections.namedtuple(
"_Version", ["epoch", "release", "dev", "pre", "post", "local"]
)
def parse(version: str) -> Union["LegacyVersion", "Version"]:
"""
Parse the given version string and return either a :class:`Version` object
or a :class:`LegacyVersion` object depending on if the given version is
a valid PEP 440 version or a legacy version.
"""
try:
return Version(version)
except InvalidVersion:
return LegacyVersion(version)
class InvalidVersion(ValueError):
"""
An invalid version was found, users should refer to PEP 440.
"""
class _BaseVersion:
_key: Union[CmpKey, LegacyCmpKey]
def __hash__(self) -> int:
return hash(self._key)
# Please keep the duplicated `isinstance` check
# in the six comparisons hereunder
# unless you find a way to avoid adding overhead function calls.
def __lt__(self, other: "_BaseVersion") -> bool:
if not isinstance(other, _BaseVersion):
return NotImplemented
return self._key < other._key
def __le__(self, other: "_BaseVersion") -> bool:
if not isinstance(other, _BaseVersion):
return NotImplemented
return self._key <= other._key
def __eq__(self, other: object) -> bool:
if not isinstance(other, _BaseVersion):
return NotImplemented
return self._key == other._key
def __ge__(self, other: "_BaseVersion") -> bool:
if not isinstance(other, _BaseVersion):
return NotImplemented
return self._key >= other._key
def __gt__(self, other: "_BaseVersion") -> bool:
if not isinstance(other, _BaseVersion):
return NotImplemented
return self._key > other._key
def __ne__(self, other: object) -> bool:
if not isinstance(other, _BaseVersion):
return NotImplemented
return self._key != other._key
class LegacyVersion(_BaseVersion):
def __init__(self, version: str) -> None:
self._version = str(version)
self._key = _legacy_cmpkey(self._version)
warnings.warn(
"Creating a LegacyVersion has been deprecated and will be "
"removed in the next major release",
DeprecationWarning,
)
def __str__(self) -> str:
return self._version
def __repr__(self) -> str:
return f"<LegacyVersion('{self}')>"
@property
def public(self) -> str:
return self._version
@property
def base_version(self) -> str:
return self._version
@property
def epoch(self) -> int:
return -1
@property
def release(self) -> None:
return None
@property
def pre(self) -> None:
return None
@property
def post(self) -> None:
return None
@property
def dev(self) -> None:
return None
@property
def local(self) -> None:
return None
@property
def is_prerelease(self) -> bool:
return False
@property
def is_postrelease(self) -> bool:
return False
@property
def is_devrelease(self) -> bool:
return False
_legacy_version_component_re = re.compile(r"(\d+ | [a-z]+ | \.| -)", re.VERBOSE)
_legacy_version_replacement_map = {
"pre": "c",
"preview": "c",
"-": "final-",
"rc": "c",
"dev": "@",
}
def _parse_version_parts(s: str) -> Iterator[str]:
for part in _legacy_version_component_re.split(s):
part = _legacy_version_replacement_map.get(part, part)
if not part or part == ".":
continue
if part[:1] in "0123456789":
# pad for numeric comparison
yield part.zfill(8)
else:
yield "*" + part
# ensure that alpha/beta/candidate are before final
yield "*final"
def _legacy_cmpkey(version: str) -> LegacyCmpKey:
# We hardcode an epoch of -1 here. A PEP 440 version can only have a epoch
# greater than or equal to 0. This will effectively put the LegacyVersion,
# which uses the defacto standard originally implemented by setuptools,
# as before all PEP 440 versions.
epoch = -1
# This scheme is taken from pkg_resources.parse_version setuptools prior to
# it's adoption of the packaging library.
parts: List[str] = []
for part in _parse_version_parts(version.lower()):
if part.startswith("*"):
# remove "-" before a prerelease tag
if part < "*final":
while parts and parts[-1] == "*final-":
parts.pop()
# remove trailing zeros from each series of numeric parts
while parts and parts[-1] == "00000000":
parts.pop()
parts.append(part)
return epoch, tuple(parts)
# Deliberately not anchored to the start and end of the string, to make it
# easier for 3rd party code to reuse
VERSION_PATTERN = r"""
v?
(?:
(?:(?P<epoch>[0-9]+)!)? # epoch
(?P<release>[0-9]+(?:\.[0-9]+)*) # release segment
(?P<pre> # pre-release
[-_\.]?
(?P<pre_l>(a|b|c|rc|alpha|beta|pre|preview))
[-_\.]?
(?P<pre_n>[0-9]+)?
)?
(?P<post> # post release
(?:-(?P<post_n1>[0-9]+))
|
(?:
[-_\.]?
(?P<post_l>post|rev|r)
[-_\.]?
(?P<post_n2>[0-9]+)?
)
)?
(?P<dev> # dev release
[-_\.]?
(?P<dev_l>dev)
[-_\.]?
(?P<dev_n>[0-9]+)?
)?
)
(?:\+(?P<local>[a-z0-9]+(?:[-_\.][a-z0-9]+)*))? # local version
"""
class Version(_BaseVersion):
_regex = re.compile(r"^\s*" + VERSION_PATTERN + r"\s*$", re.VERBOSE | re.IGNORECASE)
def __init__(self, version: str) -> None:
# Validate the version and parse it into pieces
match = self._regex.search(version)
if not match:
raise InvalidVersion(f"Invalid version: '{version}'")
# Store the parsed out pieces of the version
self._version = _Version(
epoch=int(match.group("epoch")) if match.group("epoch") else 0,
release=tuple(int(i) for i in match.group("release").split(".")),
pre=_parse_letter_version(match.group("pre_l"), match.group("pre_n")),
post=_parse_letter_version(
match.group("post_l"), match.group("post_n1") or match.group("post_n2")
),
dev=_parse_letter_version(match.group("dev_l"), match.group("dev_n")),
local=_parse_local_version(match.group("local")),
)
# Generate a key which will be used for sorting
self._key = _cmpkey(
self._version.epoch,
self._version.release,
self._version.pre,
self._version.post,
self._version.dev,
self._version.local,
)
def __repr__(self) -> str:
return f"<Version('{self}')>"
def __str__(self) -> str:
parts = []
# Epoch
if self.epoch != 0:
parts.append(f"{self.epoch}!")
# Release segment
parts.append(".".join(str(x) for x in self.release))
# Pre-release
if self.pre is not None:
parts.append("".join(str(x) for x in self.pre))
# Post-release
if self.post is not None:
parts.append(f".post{self.post}")
# Development release
if self.dev is not None:
parts.append(f".dev{self.dev}")
# Local version segment
if self.local is not None:
parts.append(f"+{self.local}")
return "".join(parts)
@property
def epoch(self) -> int:
_epoch: int = self._version.epoch
return _epoch
@property
def release(self) -> Tuple[int, ...]:
_release: Tuple[int, ...] = self._version.release
return _release
@property
def pre(self) -> Optional[Tuple[str, int]]:
_pre: Optional[Tuple[str, int]] = self._version.pre
return _pre
@property
def post(self) -> Optional[int]:
return self._version.post[1] if self._version.post else None
@property
def dev(self) -> Optional[int]:
return self._version.dev[1] if self._version.dev else None
@property
def local(self) -> Optional[str]:
if self._version.local:
return ".".join(str(x) for x in self._version.local)
else:
return None
@property
def public(self) -> str:
return str(self).split("+", 1)[0]
@property
def base_version(self) -> str:
parts = []
# Epoch
if self.epoch != 0:
parts.append(f"{self.epoch}!")
# Release segment
parts.append(".".join(str(x) for x in self.release))
return "".join(parts)
@property
def is_prerelease(self) -> bool:
return self.dev is not None or self.pre is not None
@property
def is_postrelease(self) -> bool:
return self.post is not None
@property
def is_devrelease(self) -> bool:
return self.dev is not None
@property
def major(self) -> int:
return self.release[0] if len(self.release) >= 1 else 0
@property
def minor(self) -> int:
return self.release[1] if len(self.release) >= 2 else 0
@property
def micro(self) -> int:
return self.release[2] if len(self.release) >= 3 else 0
def _parse_letter_version(
letter: str, number: Union[str, bytes, SupportsInt]
) -> Optional[Tuple[str, int]]:
if letter:
# We consider there to be an implicit 0 in a pre-release if there is
# not a numeral associated with it.
if number is None:
number = 0
# We normalize any letters to their lower case form
letter = letter.lower()
# We consider some words to be alternate spellings of other words and
# in those cases we want to normalize the spellings to our preferred
# spelling.
if letter == "alpha":
letter = "a"
elif letter == "beta":
letter = "b"
elif letter in ["c", "pre", "preview"]:
letter = "rc"
elif letter in ["rev", "r"]:
letter = "post"
return letter, int(number)
if not letter and number:
# We assume if we are given a number, but we are not given a letter
# then this is using the implicit post release syntax (e.g. 1.0-1)
letter = "post"
return letter, int(number)
return None
_local_version_separators = re.compile(r"[\._-]")
def _parse_local_version(local: str) -> Optional[LocalType]:
"""
Takes a string like abc.1.twelve and turns it into ("abc", 1, "twelve").
"""
if local is not None:
return tuple(
part.lower() if not part.isdigit() else int(part)
for part in _local_version_separators.split(local)
)
return None
def _cmpkey(
epoch: int,
release: Tuple[int, ...],
pre: Optional[Tuple[str, int]],
post: Optional[Tuple[str, int]],
dev: Optional[Tuple[str, int]],
local: Optional[Tuple[SubLocalType]],
) -> CmpKey:
# When we compare a release version, we want to compare it with all of the
# trailing zeros removed. So we'll use a reverse the list, drop all the now
# leading zeros until we come to something non zero, then take the rest
# re-reverse it back into the correct order and make it a tuple and use
# that for our sorting key.
_release = tuple(
reversed(list(itertools.dropwhile(lambda x: x == 0, reversed(release))))
)
# We need to "trick" the sorting algorithm to put 1.0.dev0 before 1.0a0.
# We'll do this by abusing the pre segment, but we _only_ want to do this
# if there is not a pre or a post segment. If we have one of those then
# the normal sorting rules will handle this case correctly.
if pre is None and post is None and dev is not None:
_pre: PrePostDevType = NegativeInfinity
# Versions without a pre-release (except as noted above) should sort after
# those with one.
elif pre is None:
_pre = Infinity
else:
_pre = pre
# Versions without a post segment should sort before those with one.
if post is None:
_post: PrePostDevType = NegativeInfinity
else:
_post = post
# Versions without a development segment should sort after those with one.
if dev is None:
_dev: PrePostDevType = Infinity
else:
_dev = dev
if local is None:
# Versions without a local segment should sort before those with one.
_local: LocalType = NegativeInfinity
else:
# Versions with a local segment need that segment parsed to implement
# the sorting rules in PEP440.
# - Alpha numeric segments sort before numeric segments
# - Alpha numeric segments sort lexicographically
# - Numeric segments sort numerically
# - Shorter versions sort before longer versions when the prefixes
# match exactly
_local = tuple(
(i, "") if isinstance(i, int) else (NegativeInfinity, i) for i in local
)
return epoch, _release, _pre, _post, _dev, _local
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/packaging/version.py
|
Python
|
mit
| 14,665 |
# module pyparsing.py
#
# Copyright (c) 2003-2022 Paul T. McGuire
#
# Permission is hereby granted, free of charge, to any person obtaining
# a copy of this software and associated documentation files (the
# "Software"), to deal in the Software without restriction, including
# without limitation the rights to use, copy, modify, merge, publish,
# distribute, sublicense, and/or sell copies of the Software, and to
# permit persons to whom the Software is furnished to do so, subject to
# the following conditions:
#
# The above copyright notice and this permission notice shall be
# included in all copies or substantial portions of the Software.
#
# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
# EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
# MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
# IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
# CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
# TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
# SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
#
__doc__ = """
pyparsing module - Classes and methods to define and execute parsing grammars
=============================================================================
The pyparsing module is an alternative approach to creating and
executing simple grammars, vs. the traditional lex/yacc approach, or the
use of regular expressions. With pyparsing, you don't need to learn
a new syntax for defining grammars or matching expressions - the parsing
module provides a library of classes that you use to construct the
grammar directly in Python.
Here is a program to parse "Hello, World!" (or any greeting of the form
``"<salutation>, <addressee>!"``), built up using :class:`Word`,
:class:`Literal`, and :class:`And` elements
(the :meth:`'+'<ParserElement.__add__>` operators create :class:`And` expressions,
and the strings are auto-converted to :class:`Literal` expressions)::
from pyparsing import Word, alphas
# define grammar of a greeting
greet = Word(alphas) + "," + Word(alphas) + "!"
hello = "Hello, World!"
print(hello, "->", greet.parse_string(hello))
The program outputs the following::
Hello, World! -> ['Hello', ',', 'World', '!']
The Python representation of the grammar is quite readable, owing to the
self-explanatory class names, and the use of :class:`'+'<And>`,
:class:`'|'<MatchFirst>`, :class:`'^'<Or>` and :class:`'&'<Each>` operators.
The :class:`ParseResults` object returned from
:class:`ParserElement.parseString` can be
accessed as a nested list, a dictionary, or an object with named
attributes.
The pyparsing module handles some of the problems that are typically
vexing when writing text parsers:
- extra or missing whitespace (the above program will also handle
"Hello,World!", "Hello , World !", etc.)
- quoted strings
- embedded comments
Getting Started -
-----------------
Visit the classes :class:`ParserElement` and :class:`ParseResults` to
see the base classes that most other pyparsing
classes inherit from. Use the docstrings for examples of how to:
- construct literal match expressions from :class:`Literal` and
:class:`CaselessLiteral` classes
- construct character word-group expressions using the :class:`Word`
class
- see how to create repetitive expressions using :class:`ZeroOrMore`
and :class:`OneOrMore` classes
- use :class:`'+'<And>`, :class:`'|'<MatchFirst>`, :class:`'^'<Or>`,
and :class:`'&'<Each>` operators to combine simple expressions into
more complex ones
- associate names with your parsed results using
:class:`ParserElement.setResultsName`
- access the parsed data, which is returned as a :class:`ParseResults`
object
- find some helpful expression short-cuts like :class:`delimitedList`
and :class:`oneOf`
- find more useful common expressions in the :class:`pyparsing_common`
namespace class
"""
from typing import NamedTuple
class version_info(NamedTuple):
major: int
minor: int
micro: int
releaselevel: str
serial: int
@property
def __version__(self):
return (
"{}.{}.{}".format(self.major, self.minor, self.micro)
+ (
"{}{}{}".format(
"r" if self.releaselevel[0] == "c" else "",
self.releaselevel[0],
self.serial,
),
"",
)[self.releaselevel == "final"]
)
def __str__(self):
return "{} {} / {}".format(__name__, self.__version__, __version_time__)
def __repr__(self):
return "{}.{}({})".format(
__name__,
type(self).__name__,
", ".join("{}={!r}".format(*nv) for nv in zip(self._fields, self)),
)
__version_info__ = version_info(3, 0, 9, "final", 0)
__version_time__ = "05 May 2022 07:02 UTC"
__version__ = __version_info__.__version__
__versionTime__ = __version_time__
__author__ = "Paul McGuire <ptmcg.gm+pyparsing@gmail.com>"
from .util import *
from .exceptions import *
from .actions import *
from .core import __diag__, __compat__
from .results import *
from .core import *
from .core import _builtin_exprs as core_builtin_exprs
from .helpers import *
from .helpers import _builtin_exprs as helper_builtin_exprs
from .unicode import unicode_set, UnicodeRangeList, pyparsing_unicode as unicode
from .testing import pyparsing_test as testing
from .common import (
pyparsing_common as common,
_builtin_exprs as common_builtin_exprs,
)
# define backward compat synonyms
if "pyparsing_unicode" not in globals():
pyparsing_unicode = unicode
if "pyparsing_common" not in globals():
pyparsing_common = common
if "pyparsing_test" not in globals():
pyparsing_test = testing
core_builtin_exprs += common_builtin_exprs + helper_builtin_exprs
__all__ = [
"__version__",
"__version_time__",
"__author__",
"__compat__",
"__diag__",
"And",
"AtLineStart",
"AtStringStart",
"CaselessKeyword",
"CaselessLiteral",
"CharsNotIn",
"Combine",
"Dict",
"Each",
"Empty",
"FollowedBy",
"Forward",
"GoToColumn",
"Group",
"IndentedBlock",
"Keyword",
"LineEnd",
"LineStart",
"Literal",
"Located",
"PrecededBy",
"MatchFirst",
"NoMatch",
"NotAny",
"OneOrMore",
"OnlyOnce",
"OpAssoc",
"Opt",
"Optional",
"Or",
"ParseBaseException",
"ParseElementEnhance",
"ParseException",
"ParseExpression",
"ParseFatalException",
"ParseResults",
"ParseSyntaxException",
"ParserElement",
"PositionToken",
"QuotedString",
"RecursiveGrammarException",
"Regex",
"SkipTo",
"StringEnd",
"StringStart",
"Suppress",
"Token",
"TokenConverter",
"White",
"Word",
"WordEnd",
"WordStart",
"ZeroOrMore",
"Char",
"alphanums",
"alphas",
"alphas8bit",
"any_close_tag",
"any_open_tag",
"c_style_comment",
"col",
"common_html_entity",
"counted_array",
"cpp_style_comment",
"dbl_quoted_string",
"dbl_slash_comment",
"delimited_list",
"dict_of",
"empty",
"hexnums",
"html_comment",
"identchars",
"identbodychars",
"java_style_comment",
"line",
"line_end",
"line_start",
"lineno",
"make_html_tags",
"make_xml_tags",
"match_only_at_col",
"match_previous_expr",
"match_previous_literal",
"nested_expr",
"null_debug_action",
"nums",
"one_of",
"printables",
"punc8bit",
"python_style_comment",
"quoted_string",
"remove_quotes",
"replace_with",
"replace_html_entity",
"rest_of_line",
"sgl_quoted_string",
"srange",
"string_end",
"string_start",
"trace_parse_action",
"unicode_string",
"with_attribute",
"indentedBlock",
"original_text_for",
"ungroup",
"infix_notation",
"locatedExpr",
"with_class",
"CloseMatch",
"token_map",
"pyparsing_common",
"pyparsing_unicode",
"unicode_set",
"condition_as_parse_action",
"pyparsing_test",
# pre-PEP8 compatibility names
"__versionTime__",
"anyCloseTag",
"anyOpenTag",
"cStyleComment",
"commonHTMLEntity",
"countedArray",
"cppStyleComment",
"dblQuotedString",
"dblSlashComment",
"delimitedList",
"dictOf",
"htmlComment",
"javaStyleComment",
"lineEnd",
"lineStart",
"makeHTMLTags",
"makeXMLTags",
"matchOnlyAtCol",
"matchPreviousExpr",
"matchPreviousLiteral",
"nestedExpr",
"nullDebugAction",
"oneOf",
"opAssoc",
"pythonStyleComment",
"quotedString",
"removeQuotes",
"replaceHTMLEntity",
"replaceWith",
"restOfLine",
"sglQuotedString",
"stringEnd",
"stringStart",
"traceParseAction",
"unicodeString",
"withAttribute",
"indentedBlock",
"originalTextFor",
"infixNotation",
"locatedExpr",
"withClass",
"tokenMap",
"conditionAsParseAction",
"autoname_elements",
]
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/pyparsing/__init__.py
|
Python
|
mit
| 9,159 |
# actions.py
from .exceptions import ParseException
from .util import col
class OnlyOnce:
"""
Wrapper for parse actions, to ensure they are only called once.
"""
def __init__(self, method_call):
from .core import _trim_arity
self.callable = _trim_arity(method_call)
self.called = False
def __call__(self, s, l, t):
if not self.called:
results = self.callable(s, l, t)
self.called = True
return results
raise ParseException(s, l, "OnlyOnce obj called multiple times w/out reset")
def reset(self):
"""
Allow the associated parse action to be called once more.
"""
self.called = False
def match_only_at_col(n):
"""
Helper method for defining parse actions that require matching at
a specific column in the input text.
"""
def verify_col(strg, locn, toks):
if col(locn, strg) != n:
raise ParseException(strg, locn, "matched token not at column {}".format(n))
return verify_col
def replace_with(repl_str):
"""
Helper method for common parse actions that simply return
a literal value. Especially useful when used with
:class:`transform_string<ParserElement.transform_string>` ().
Example::
num = Word(nums).set_parse_action(lambda toks: int(toks[0]))
na = one_of("N/A NA").set_parse_action(replace_with(math.nan))
term = na | num
term[1, ...].parse_string("324 234 N/A 234") # -> [324, 234, nan, 234]
"""
return lambda s, l, t: [repl_str]
def remove_quotes(s, l, t):
"""
Helper parse action for removing quotation marks from parsed
quoted strings.
Example::
# by default, quotation marks are included in parsed results
quoted_string.parse_string("'Now is the Winter of our Discontent'") # -> ["'Now is the Winter of our Discontent'"]
# use remove_quotes to strip quotation marks from parsed results
quoted_string.set_parse_action(remove_quotes)
quoted_string.parse_string("'Now is the Winter of our Discontent'") # -> ["Now is the Winter of our Discontent"]
"""
return t[0][1:-1]
def with_attribute(*args, **attr_dict):
"""
Helper to create a validating parse action to be used with start
tags created with :class:`make_xml_tags` or
:class:`make_html_tags`. Use ``with_attribute`` to qualify
a starting tag with a required attribute value, to avoid false
matches on common tags such as ``<TD>`` or ``<DIV>``.
Call ``with_attribute`` with a series of attribute names and
values. Specify the list of filter attributes names and values as:
- keyword arguments, as in ``(align="right")``, or
- as an explicit dict with ``**`` operator, when an attribute
name is also a Python reserved word, as in ``**{"class":"Customer", "align":"right"}``
- a list of name-value tuples, as in ``(("ns1:class", "Customer"), ("ns2:align", "right"))``
For attribute names with a namespace prefix, you must use the second
form. Attribute names are matched insensitive to upper/lower case.
If just testing for ``class`` (with or without a namespace), use
:class:`with_class`.
To verify that the attribute exists, but without specifying a value,
pass ``with_attribute.ANY_VALUE`` as the value.
Example::
html = '''
<div>
Some text
<div type="grid">1 4 0 1 0</div>
<div type="graph">1,3 2,3 1,1</div>
<div>this has no type</div>
</div>
'''
div,div_end = make_html_tags("div")
# only match div tag having a type attribute with value "grid"
div_grid = div().set_parse_action(with_attribute(type="grid"))
grid_expr = div_grid + SkipTo(div | div_end)("body")
for grid_header in grid_expr.search_string(html):
print(grid_header.body)
# construct a match with any div tag having a type attribute, regardless of the value
div_any_type = div().set_parse_action(with_attribute(type=with_attribute.ANY_VALUE))
div_expr = div_any_type + SkipTo(div | div_end)("body")
for div_header in div_expr.search_string(html):
print(div_header.body)
prints::
1 4 0 1 0
1 4 0 1 0
1,3 2,3 1,1
"""
if args:
attrs = args[:]
else:
attrs = attr_dict.items()
attrs = [(k, v) for k, v in attrs]
def pa(s, l, tokens):
for attrName, attrValue in attrs:
if attrName not in tokens:
raise ParseException(s, l, "no matching attribute " + attrName)
if attrValue != with_attribute.ANY_VALUE and tokens[attrName] != attrValue:
raise ParseException(
s,
l,
"attribute {!r} has value {!r}, must be {!r}".format(
attrName, tokens[attrName], attrValue
),
)
return pa
with_attribute.ANY_VALUE = object()
def with_class(classname, namespace=""):
"""
Simplified version of :class:`with_attribute` when
matching on a div class - made difficult because ``class`` is
a reserved word in Python.
Example::
html = '''
<div>
Some text
<div class="grid">1 4 0 1 0</div>
<div class="graph">1,3 2,3 1,1</div>
<div>this <div> has no class</div>
</div>
'''
div,div_end = make_html_tags("div")
div_grid = div().set_parse_action(with_class("grid"))
grid_expr = div_grid + SkipTo(div | div_end)("body")
for grid_header in grid_expr.search_string(html):
print(grid_header.body)
div_any_type = div().set_parse_action(with_class(withAttribute.ANY_VALUE))
div_expr = div_any_type + SkipTo(div | div_end)("body")
for div_header in div_expr.search_string(html):
print(div_header.body)
prints::
1 4 0 1 0
1 4 0 1 0
1,3 2,3 1,1
"""
classattr = "{}:class".format(namespace) if namespace else "class"
return with_attribute(**{classattr: classname})
# pre-PEP8 compatibility symbols
replaceWith = replace_with
removeQuotes = remove_quotes
withAttribute = with_attribute
withClass = with_class
matchOnlyAtCol = match_only_at_col
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/pyparsing/actions.py
|
Python
|
mit
| 6,426 |
# common.py
from .core import *
from .helpers import delimited_list, any_open_tag, any_close_tag
from datetime import datetime
# some other useful expressions - using lower-case class name since we are really using this as a namespace
class pyparsing_common:
"""Here are some common low-level expressions that may be useful in
jump-starting parser development:
- numeric forms (:class:`integers<integer>`, :class:`reals<real>`,
:class:`scientific notation<sci_real>`)
- common :class:`programming identifiers<identifier>`
- network addresses (:class:`MAC<mac_address>`,
:class:`IPv4<ipv4_address>`, :class:`IPv6<ipv6_address>`)
- ISO8601 :class:`dates<iso8601_date>` and
:class:`datetime<iso8601_datetime>`
- :class:`UUID<uuid>`
- :class:`comma-separated list<comma_separated_list>`
- :class:`url`
Parse actions:
- :class:`convertToInteger`
- :class:`convertToFloat`
- :class:`convertToDate`
- :class:`convertToDatetime`
- :class:`stripHTMLTags`
- :class:`upcaseTokens`
- :class:`downcaseTokens`
Example::
pyparsing_common.number.runTests('''
# any int or real number, returned as the appropriate type
100
-100
+100
3.14159
6.02e23
1e-12
''')
pyparsing_common.fnumber.runTests('''
# any int or real number, returned as float
100
-100
+100
3.14159
6.02e23
1e-12
''')
pyparsing_common.hex_integer.runTests('''
# hex numbers
100
FF
''')
pyparsing_common.fraction.runTests('''
# fractions
1/2
-3/4
''')
pyparsing_common.mixed_integer.runTests('''
# mixed fractions
1
1/2
-3/4
1-3/4
''')
import uuid
pyparsing_common.uuid.setParseAction(tokenMap(uuid.UUID))
pyparsing_common.uuid.runTests('''
# uuid
12345678-1234-5678-1234-567812345678
''')
prints::
# any int or real number, returned as the appropriate type
100
[100]
-100
[-100]
+100
[100]
3.14159
[3.14159]
6.02e23
[6.02e+23]
1e-12
[1e-12]
# any int or real number, returned as float
100
[100.0]
-100
[-100.0]
+100
[100.0]
3.14159
[3.14159]
6.02e23
[6.02e+23]
1e-12
[1e-12]
# hex numbers
100
[256]
FF
[255]
# fractions
1/2
[0.5]
-3/4
[-0.75]
# mixed fractions
1
[1]
1/2
[0.5]
-3/4
[-0.75]
1-3/4
[1.75]
# uuid
12345678-1234-5678-1234-567812345678
[UUID('12345678-1234-5678-1234-567812345678')]
"""
convert_to_integer = token_map(int)
"""
Parse action for converting parsed integers to Python int
"""
convert_to_float = token_map(float)
"""
Parse action for converting parsed numbers to Python float
"""
integer = Word(nums).set_name("integer").set_parse_action(convert_to_integer)
"""expression that parses an unsigned integer, returns an int"""
hex_integer = (
Word(hexnums).set_name("hex integer").set_parse_action(token_map(int, 16))
)
"""expression that parses a hexadecimal integer, returns an int"""
signed_integer = (
Regex(r"[+-]?\d+")
.set_name("signed integer")
.set_parse_action(convert_to_integer)
)
"""expression that parses an integer with optional leading sign, returns an int"""
fraction = (
signed_integer().set_parse_action(convert_to_float)
+ "/"
+ signed_integer().set_parse_action(convert_to_float)
).set_name("fraction")
"""fractional expression of an integer divided by an integer, returns a float"""
fraction.add_parse_action(lambda tt: tt[0] / tt[-1])
mixed_integer = (
fraction | signed_integer + Opt(Opt("-").suppress() + fraction)
).set_name("fraction or mixed integer-fraction")
"""mixed integer of the form 'integer - fraction', with optional leading integer, returns float"""
mixed_integer.add_parse_action(sum)
real = (
Regex(r"[+-]?(?:\d+\.\d*|\.\d+)")
.set_name("real number")
.set_parse_action(convert_to_float)
)
"""expression that parses a floating point number and returns a float"""
sci_real = (
Regex(r"[+-]?(?:\d+(?:[eE][+-]?\d+)|(?:\d+\.\d*|\.\d+)(?:[eE][+-]?\d+)?)")
.set_name("real number with scientific notation")
.set_parse_action(convert_to_float)
)
"""expression that parses a floating point number with optional
scientific notation and returns a float"""
# streamlining this expression makes the docs nicer-looking
number = (sci_real | real | signed_integer).setName("number").streamline()
"""any numeric expression, returns the corresponding Python type"""
fnumber = (
Regex(r"[+-]?\d+\.?\d*([eE][+-]?\d+)?")
.set_name("fnumber")
.set_parse_action(convert_to_float)
)
"""any int or real number, returned as float"""
identifier = Word(identchars, identbodychars).set_name("identifier")
"""typical code identifier (leading alpha or '_', followed by 0 or more alphas, nums, or '_')"""
ipv4_address = Regex(
r"(25[0-5]|2[0-4][0-9]|1?[0-9]{1,2})(\.(25[0-5]|2[0-4][0-9]|1?[0-9]{1,2})){3}"
).set_name("IPv4 address")
"IPv4 address (``0.0.0.0 - 255.255.255.255``)"
_ipv6_part = Regex(r"[0-9a-fA-F]{1,4}").set_name("hex_integer")
_full_ipv6_address = (_ipv6_part + (":" + _ipv6_part) * 7).set_name(
"full IPv6 address"
)
_short_ipv6_address = (
Opt(_ipv6_part + (":" + _ipv6_part) * (0, 6))
+ "::"
+ Opt(_ipv6_part + (":" + _ipv6_part) * (0, 6))
).set_name("short IPv6 address")
_short_ipv6_address.add_condition(
lambda t: sum(1 for tt in t if pyparsing_common._ipv6_part.matches(tt)) < 8
)
_mixed_ipv6_address = ("::ffff:" + ipv4_address).set_name("mixed IPv6 address")
ipv6_address = Combine(
(_full_ipv6_address | _mixed_ipv6_address | _short_ipv6_address).set_name(
"IPv6 address"
)
).set_name("IPv6 address")
"IPv6 address (long, short, or mixed form)"
mac_address = Regex(
r"[0-9a-fA-F]{2}([:.-])[0-9a-fA-F]{2}(?:\1[0-9a-fA-F]{2}){4}"
).set_name("MAC address")
"MAC address xx:xx:xx:xx:xx (may also have '-' or '.' delimiters)"
@staticmethod
def convert_to_date(fmt: str = "%Y-%m-%d"):
"""
Helper to create a parse action for converting parsed date string to Python datetime.date
Params -
- fmt - format to be passed to datetime.strptime (default= ``"%Y-%m-%d"``)
Example::
date_expr = pyparsing_common.iso8601_date.copy()
date_expr.setParseAction(pyparsing_common.convertToDate())
print(date_expr.parseString("1999-12-31"))
prints::
[datetime.date(1999, 12, 31)]
"""
def cvt_fn(ss, ll, tt):
try:
return datetime.strptime(tt[0], fmt).date()
except ValueError as ve:
raise ParseException(ss, ll, str(ve))
return cvt_fn
@staticmethod
def convert_to_datetime(fmt: str = "%Y-%m-%dT%H:%M:%S.%f"):
"""Helper to create a parse action for converting parsed
datetime string to Python datetime.datetime
Params -
- fmt - format to be passed to datetime.strptime (default= ``"%Y-%m-%dT%H:%M:%S.%f"``)
Example::
dt_expr = pyparsing_common.iso8601_datetime.copy()
dt_expr.setParseAction(pyparsing_common.convertToDatetime())
print(dt_expr.parseString("1999-12-31T23:59:59.999"))
prints::
[datetime.datetime(1999, 12, 31, 23, 59, 59, 999000)]
"""
def cvt_fn(s, l, t):
try:
return datetime.strptime(t[0], fmt)
except ValueError as ve:
raise ParseException(s, l, str(ve))
return cvt_fn
iso8601_date = Regex(
r"(?P<year>\d{4})(?:-(?P<month>\d\d)(?:-(?P<day>\d\d))?)?"
).set_name("ISO8601 date")
"ISO8601 date (``yyyy-mm-dd``)"
iso8601_datetime = Regex(
r"(?P<year>\d{4})-(?P<month>\d\d)-(?P<day>\d\d)[T ](?P<hour>\d\d):(?P<minute>\d\d)(:(?P<second>\d\d(\.\d*)?)?)?(?P<tz>Z|[+-]\d\d:?\d\d)?"
).set_name("ISO8601 datetime")
"ISO8601 datetime (``yyyy-mm-ddThh:mm:ss.s(Z|+-00:00)``) - trailing seconds, milliseconds, and timezone optional; accepts separating ``'T'`` or ``' '``"
uuid = Regex(r"[0-9a-fA-F]{8}(-[0-9a-fA-F]{4}){3}-[0-9a-fA-F]{12}").set_name("UUID")
"UUID (``xxxxxxxx-xxxx-xxxx-xxxx-xxxxxxxxxxxx``)"
_html_stripper = any_open_tag.suppress() | any_close_tag.suppress()
@staticmethod
def strip_html_tags(s: str, l: int, tokens: ParseResults):
"""Parse action to remove HTML tags from web page HTML source
Example::
# strip HTML links from normal text
text = '<td>More info at the <a href="https://github.com/pyparsing/pyparsing/wiki">pyparsing</a> wiki page</td>'
td, td_end = makeHTMLTags("TD")
table_text = td + SkipTo(td_end).setParseAction(pyparsing_common.stripHTMLTags)("body") + td_end
print(table_text.parseString(text).body)
Prints::
More info at the pyparsing wiki page
"""
return pyparsing_common._html_stripper.transform_string(tokens[0])
_commasepitem = (
Combine(
OneOrMore(
~Literal(",")
+ ~LineEnd()
+ Word(printables, exclude_chars=",")
+ Opt(White(" \t") + ~FollowedBy(LineEnd() | ","))
)
)
.streamline()
.set_name("commaItem")
)
comma_separated_list = delimited_list(
Opt(quoted_string.copy() | _commasepitem, default="")
).set_name("comma separated list")
"""Predefined expression of 1 or more printable words or quoted strings, separated by commas."""
upcase_tokens = staticmethod(token_map(lambda t: t.upper()))
"""Parse action to convert tokens to upper case."""
downcase_tokens = staticmethod(token_map(lambda t: t.lower()))
"""Parse action to convert tokens to lower case."""
# fmt: off
url = Regex(
# https://mathiasbynens.be/demo/url-regex
# https://gist.github.com/dperini/729294
r"^" +
# protocol identifier (optional)
# short syntax // still required
r"(?:(?:(?P<scheme>https?|ftp):)?\/\/)" +
# user:pass BasicAuth (optional)
r"(?:(?P<auth>\S+(?::\S*)?)@)?" +
r"(?P<host>" +
# IP address exclusion
# private & local networks
r"(?!(?:10|127)(?:\.\d{1,3}){3})" +
r"(?!(?:169\.254|192\.168)(?:\.\d{1,3}){2})" +
r"(?!172\.(?:1[6-9]|2\d|3[0-1])(?:\.\d{1,3}){2})" +
# IP address dotted notation octets
# excludes loopback network 0.0.0.0
# excludes reserved space >= 224.0.0.0
# excludes network & broadcast addresses
# (first & last IP address of each class)
r"(?:[1-9]\d?|1\d\d|2[01]\d|22[0-3])" +
r"(?:\.(?:1?\d{1,2}|2[0-4]\d|25[0-5])){2}" +
r"(?:\.(?:[1-9]\d?|1\d\d|2[0-4]\d|25[0-4]))" +
r"|" +
# host & domain names, may end with dot
# can be replaced by a shortest alternative
# (?![-_])(?:[-\w\u00a1-\uffff]{0,63}[^-_]\.)+
r"(?:" +
r"(?:" +
r"[a-z0-9\u00a1-\uffff]" +
r"[a-z0-9\u00a1-\uffff_-]{0,62}" +
r")?" +
r"[a-z0-9\u00a1-\uffff]\." +
r")+" +
# TLD identifier name, may end with dot
r"(?:[a-z\u00a1-\uffff]{2,}\.?)" +
r")" +
# port number (optional)
r"(:(?P<port>\d{2,5}))?" +
# resource path (optional)
r"(?P<path>\/[^?# ]*)?" +
# query string (optional)
r"(\?(?P<query>[^#]*))?" +
# fragment (optional)
r"(#(?P<fragment>\S*))?" +
r"$"
).set_name("url")
# fmt: on
# pre-PEP8 compatibility names
convertToInteger = convert_to_integer
convertToFloat = convert_to_float
convertToDate = convert_to_date
convertToDatetime = convert_to_datetime
stripHTMLTags = strip_html_tags
upcaseTokens = upcase_tokens
downcaseTokens = downcase_tokens
_builtin_exprs = [
v for v in vars(pyparsing_common).values() if isinstance(v, ParserElement)
]
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/pyparsing/common.py
|
Python
|
mit
| 12,936 |
#
# core.py
#
import os
import typing
from typing import (
NamedTuple,
Union,
Callable,
Any,
Generator,
Tuple,
List,
TextIO,
Set,
Sequence,
)
from abc import ABC, abstractmethod
from enum import Enum
import string
import copy
import warnings
import re
import sys
from collections.abc import Iterable
import traceback
import types
from operator import itemgetter
from functools import wraps
from threading import RLock
from pathlib import Path
from .util import (
_FifoCache,
_UnboundedCache,
__config_flags,
_collapse_string_to_ranges,
_escape_regex_range_chars,
_bslash,
_flatten,
LRUMemo as _LRUMemo,
UnboundedMemo as _UnboundedMemo,
)
from .exceptions import *
from .actions import *
from .results import ParseResults, _ParseResultsWithOffset
from .unicode import pyparsing_unicode
_MAX_INT = sys.maxsize
str_type: Tuple[type, ...] = (str, bytes)
#
# Copyright (c) 2003-2022 Paul T. McGuire
#
# Permission is hereby granted, free of charge, to any person obtaining
# a copy of this software and associated documentation files (the
# "Software"), to deal in the Software without restriction, including
# without limitation the rights to use, copy, modify, merge, publish,
# distribute, sublicense, and/or sell copies of the Software, and to
# permit persons to whom the Software is furnished to do so, subject to
# the following conditions:
#
# The above copyright notice and this permission notice shall be
# included in all copies or substantial portions of the Software.
#
# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
# EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
# MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
# IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
# CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
# TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
# SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
#
if sys.version_info >= (3, 8):
from functools import cached_property
else:
class cached_property:
def __init__(self, func):
self._func = func
def __get__(self, instance, owner=None):
ret = instance.__dict__[self._func.__name__] = self._func(instance)
return ret
class __compat__(__config_flags):
"""
A cross-version compatibility configuration for pyparsing features that will be
released in a future version. By setting values in this configuration to True,
those features can be enabled in prior versions for compatibility development
and testing.
- ``collect_all_And_tokens`` - flag to enable fix for Issue #63 that fixes erroneous grouping
of results names when an :class:`And` expression is nested within an :class:`Or` or :class:`MatchFirst`;
maintained for compatibility, but setting to ``False`` no longer restores pre-2.3.1
behavior
"""
_type_desc = "compatibility"
collect_all_And_tokens = True
_all_names = [__ for __ in locals() if not __.startswith("_")]
_fixed_names = """
collect_all_And_tokens
""".split()
class __diag__(__config_flags):
_type_desc = "diagnostic"
warn_multiple_tokens_in_named_alternation = False
warn_ungrouped_named_tokens_in_collection = False
warn_name_set_on_empty_Forward = False
warn_on_parse_using_empty_Forward = False
warn_on_assignment_to_Forward = False
warn_on_multiple_string_args_to_oneof = False
warn_on_match_first_with_lshift_operator = False
enable_debug_on_named_expressions = False
_all_names = [__ for __ in locals() if not __.startswith("_")]
_warning_names = [name for name in _all_names if name.startswith("warn")]
_debug_names = [name for name in _all_names if name.startswith("enable_debug")]
@classmethod
def enable_all_warnings(cls) -> None:
for name in cls._warning_names:
cls.enable(name)
class Diagnostics(Enum):
"""
Diagnostic configuration (all default to disabled)
- ``warn_multiple_tokens_in_named_alternation`` - flag to enable warnings when a results
name is defined on a :class:`MatchFirst` or :class:`Or` expression with one or more :class:`And` subexpressions
- ``warn_ungrouped_named_tokens_in_collection`` - flag to enable warnings when a results
name is defined on a containing expression with ungrouped subexpressions that also
have results names
- ``warn_name_set_on_empty_Forward`` - flag to enable warnings when a :class:`Forward` is defined
with a results name, but has no contents defined
- ``warn_on_parse_using_empty_Forward`` - flag to enable warnings when a :class:`Forward` is
defined in a grammar but has never had an expression attached to it
- ``warn_on_assignment_to_Forward`` - flag to enable warnings when a :class:`Forward` is defined
but is overwritten by assigning using ``'='`` instead of ``'<<='`` or ``'<<'``
- ``warn_on_multiple_string_args_to_oneof`` - flag to enable warnings when :class:`one_of` is
incorrectly called with multiple str arguments
- ``enable_debug_on_named_expressions`` - flag to auto-enable debug on all subsequent
calls to :class:`ParserElement.set_name`
Diagnostics are enabled/disabled by calling :class:`enable_diag` and :class:`disable_diag`.
All warnings can be enabled by calling :class:`enable_all_warnings`.
"""
warn_multiple_tokens_in_named_alternation = 0
warn_ungrouped_named_tokens_in_collection = 1
warn_name_set_on_empty_Forward = 2
warn_on_parse_using_empty_Forward = 3
warn_on_assignment_to_Forward = 4
warn_on_multiple_string_args_to_oneof = 5
warn_on_match_first_with_lshift_operator = 6
enable_debug_on_named_expressions = 7
def enable_diag(diag_enum: Diagnostics) -> None:
"""
Enable a global pyparsing diagnostic flag (see :class:`Diagnostics`).
"""
__diag__.enable(diag_enum.name)
def disable_diag(diag_enum: Diagnostics) -> None:
"""
Disable a global pyparsing diagnostic flag (see :class:`Diagnostics`).
"""
__diag__.disable(diag_enum.name)
def enable_all_warnings() -> None:
"""
Enable all global pyparsing diagnostic warnings (see :class:`Diagnostics`).
"""
__diag__.enable_all_warnings()
# hide abstract class
del __config_flags
def _should_enable_warnings(
cmd_line_warn_options: typing.Iterable[str], warn_env_var: typing.Optional[str]
) -> bool:
enable = bool(warn_env_var)
for warn_opt in cmd_line_warn_options:
w_action, w_message, w_category, w_module, w_line = (warn_opt + "::::").split(
":"
)[:5]
if not w_action.lower().startswith("i") and (
not (w_message or w_category or w_module) or w_module == "pyparsing"
):
enable = True
elif w_action.lower().startswith("i") and w_module in ("pyparsing", ""):
enable = False
return enable
if _should_enable_warnings(
sys.warnoptions, os.environ.get("PYPARSINGENABLEALLWARNINGS")
):
enable_all_warnings()
# build list of single arg builtins, that can be used as parse actions
_single_arg_builtins = {
sum,
len,
sorted,
reversed,
list,
tuple,
set,
any,
all,
min,
max,
}
_generatorType = types.GeneratorType
ParseAction = Union[
Callable[[], Any],
Callable[[ParseResults], Any],
Callable[[int, ParseResults], Any],
Callable[[str, int, ParseResults], Any],
]
ParseCondition = Union[
Callable[[], bool],
Callable[[ParseResults], bool],
Callable[[int, ParseResults], bool],
Callable[[str, int, ParseResults], bool],
]
ParseFailAction = Callable[[str, int, "ParserElement", Exception], None]
DebugStartAction = Callable[[str, int, "ParserElement", bool], None]
DebugSuccessAction = Callable[
[str, int, int, "ParserElement", ParseResults, bool], None
]
DebugExceptionAction = Callable[[str, int, "ParserElement", Exception, bool], None]
alphas = string.ascii_uppercase + string.ascii_lowercase
identchars = pyparsing_unicode.Latin1.identchars
identbodychars = pyparsing_unicode.Latin1.identbodychars
nums = "0123456789"
hexnums = nums + "ABCDEFabcdef"
alphanums = alphas + nums
printables = "".join([c for c in string.printable if c not in string.whitespace])
_trim_arity_call_line: traceback.StackSummary = None
def _trim_arity(func, max_limit=3):
"""decorator to trim function calls to match the arity of the target"""
global _trim_arity_call_line
if func in _single_arg_builtins:
return lambda s, l, t: func(t)
limit = 0
found_arity = False
def extract_tb(tb, limit=0):
frames = traceback.extract_tb(tb, limit=limit)
frame_summary = frames[-1]
return [frame_summary[:2]]
# synthesize what would be returned by traceback.extract_stack at the call to
# user's parse action 'func', so that we don't incur call penalty at parse time
# fmt: off
LINE_DIFF = 7
# IF ANY CODE CHANGES, EVEN JUST COMMENTS OR BLANK LINES, BETWEEN THE NEXT LINE AND
# THE CALL TO FUNC INSIDE WRAPPER, LINE_DIFF MUST BE MODIFIED!!!!
_trim_arity_call_line = (_trim_arity_call_line or traceback.extract_stack(limit=2)[-1])
pa_call_line_synth = (_trim_arity_call_line[0], _trim_arity_call_line[1] + LINE_DIFF)
def wrapper(*args):
nonlocal found_arity, limit
while 1:
try:
ret = func(*args[limit:])
found_arity = True
return ret
except TypeError as te:
# re-raise TypeErrors if they did not come from our arity testing
if found_arity:
raise
else:
tb = te.__traceback__
trim_arity_type_error = (
extract_tb(tb, limit=2)[-1][:2] == pa_call_line_synth
)
del tb
if trim_arity_type_error:
if limit < max_limit:
limit += 1
continue
raise
# fmt: on
# copy func name to wrapper for sensible debug output
# (can't use functools.wraps, since that messes with function signature)
func_name = getattr(func, "__name__", getattr(func, "__class__").__name__)
wrapper.__name__ = func_name
wrapper.__doc__ = func.__doc__
return wrapper
def condition_as_parse_action(
fn: ParseCondition, message: str = None, fatal: bool = False
) -> ParseAction:
"""
Function to convert a simple predicate function that returns ``True`` or ``False``
into a parse action. Can be used in places when a parse action is required
and :class:`ParserElement.add_condition` cannot be used (such as when adding a condition
to an operator level in :class:`infix_notation`).
Optional keyword arguments:
- ``message`` - define a custom message to be used in the raised exception
- ``fatal`` - if True, will raise :class:`ParseFatalException` to stop parsing immediately;
otherwise will raise :class:`ParseException`
"""
msg = message if message is not None else "failed user-defined condition"
exc_type = ParseFatalException if fatal else ParseException
fn = _trim_arity(fn)
@wraps(fn)
def pa(s, l, t):
if not bool(fn(s, l, t)):
raise exc_type(s, l, msg)
return pa
def _default_start_debug_action(
instring: str, loc: int, expr: "ParserElement", cache_hit: bool = False
):
cache_hit_str = "*" if cache_hit else ""
print(
(
"{}Match {} at loc {}({},{})\n {}\n {}^".format(
cache_hit_str,
expr,
loc,
lineno(loc, instring),
col(loc, instring),
line(loc, instring),
" " * (col(loc, instring) - 1),
)
)
)
def _default_success_debug_action(
instring: str,
startloc: int,
endloc: int,
expr: "ParserElement",
toks: ParseResults,
cache_hit: bool = False,
):
cache_hit_str = "*" if cache_hit else ""
print("{}Matched {} -> {}".format(cache_hit_str, expr, toks.as_list()))
def _default_exception_debug_action(
instring: str,
loc: int,
expr: "ParserElement",
exc: Exception,
cache_hit: bool = False,
):
cache_hit_str = "*" if cache_hit else ""
print(
"{}Match {} failed, {} raised: {}".format(
cache_hit_str, expr, type(exc).__name__, exc
)
)
def null_debug_action(*args):
"""'Do-nothing' debug action, to suppress debugging output during parsing."""
class ParserElement(ABC):
"""Abstract base level parser element class."""
DEFAULT_WHITE_CHARS: str = " \n\t\r"
verbose_stacktrace: bool = False
_literalStringClass: typing.Optional[type] = None
@staticmethod
def set_default_whitespace_chars(chars: str) -> None:
r"""
Overrides the default whitespace chars
Example::
# default whitespace chars are space, <TAB> and newline
Word(alphas)[1, ...].parse_string("abc def\nghi jkl") # -> ['abc', 'def', 'ghi', 'jkl']
# change to just treat newline as significant
ParserElement.set_default_whitespace_chars(" \t")
Word(alphas)[1, ...].parse_string("abc def\nghi jkl") # -> ['abc', 'def']
"""
ParserElement.DEFAULT_WHITE_CHARS = chars
# update whitespace all parse expressions defined in this module
for expr in _builtin_exprs:
if expr.copyDefaultWhiteChars:
expr.whiteChars = set(chars)
@staticmethod
def inline_literals_using(cls: type) -> None:
"""
Set class to be used for inclusion of string literals into a parser.
Example::
# default literal class used is Literal
integer = Word(nums)
date_str = integer("year") + '/' + integer("month") + '/' + integer("day")
date_str.parse_string("1999/12/31") # -> ['1999', '/', '12', '/', '31']
# change to Suppress
ParserElement.inline_literals_using(Suppress)
date_str = integer("year") + '/' + integer("month") + '/' + integer("day")
date_str.parse_string("1999/12/31") # -> ['1999', '12', '31']
"""
ParserElement._literalStringClass = cls
class DebugActions(NamedTuple):
debug_try: typing.Optional[DebugStartAction]
debug_match: typing.Optional[DebugSuccessAction]
debug_fail: typing.Optional[DebugExceptionAction]
def __init__(self, savelist: bool = False):
self.parseAction: List[ParseAction] = list()
self.failAction: typing.Optional[ParseFailAction] = None
self.customName = None
self._defaultName = None
self.resultsName = None
self.saveAsList = savelist
self.skipWhitespace = True
self.whiteChars = set(ParserElement.DEFAULT_WHITE_CHARS)
self.copyDefaultWhiteChars = True
# used when checking for left-recursion
self.mayReturnEmpty = False
self.keepTabs = False
self.ignoreExprs: List["ParserElement"] = list()
self.debug = False
self.streamlined = False
# optimize exception handling for subclasses that don't advance parse index
self.mayIndexError = True
self.errmsg = ""
# mark results names as modal (report only last) or cumulative (list all)
self.modalResults = True
# custom debug actions
self.debugActions = self.DebugActions(None, None, None)
# avoid redundant calls to preParse
self.callPreparse = True
self.callDuringTry = False
self.suppress_warnings_: List[Diagnostics] = []
def suppress_warning(self, warning_type: Diagnostics) -> "ParserElement":
"""
Suppress warnings emitted for a particular diagnostic on this expression.
Example::
base = pp.Forward()
base.suppress_warning(Diagnostics.warn_on_parse_using_empty_Forward)
# statement would normally raise a warning, but is now suppressed
print(base.parseString("x"))
"""
self.suppress_warnings_.append(warning_type)
return self
def copy(self) -> "ParserElement":
"""
Make a copy of this :class:`ParserElement`. Useful for defining
different parse actions for the same parsing pattern, using copies of
the original parse element.
Example::
integer = Word(nums).set_parse_action(lambda toks: int(toks[0]))
integerK = integer.copy().add_parse_action(lambda toks: toks[0] * 1024) + Suppress("K")
integerM = integer.copy().add_parse_action(lambda toks: toks[0] * 1024 * 1024) + Suppress("M")
print((integerK | integerM | integer)[1, ...].parse_string("5K 100 640K 256M"))
prints::
[5120, 100, 655360, 268435456]
Equivalent form of ``expr.copy()`` is just ``expr()``::
integerM = integer().add_parse_action(lambda toks: toks[0] * 1024 * 1024) + Suppress("M")
"""
cpy = copy.copy(self)
cpy.parseAction = self.parseAction[:]
cpy.ignoreExprs = self.ignoreExprs[:]
if self.copyDefaultWhiteChars:
cpy.whiteChars = set(ParserElement.DEFAULT_WHITE_CHARS)
return cpy
def set_results_name(
self, name: str, list_all_matches: bool = False, *, listAllMatches: bool = False
) -> "ParserElement":
"""
Define name for referencing matching tokens as a nested attribute
of the returned parse results.
Normally, results names are assigned as you would assign keys in a dict:
any existing value is overwritten by later values. If it is necessary to
keep all values captured for a particular results name, call ``set_results_name``
with ``list_all_matches`` = True.
NOTE: ``set_results_name`` returns a *copy* of the original :class:`ParserElement` object;
this is so that the client can define a basic element, such as an
integer, and reference it in multiple places with different names.
You can also set results names using the abbreviated syntax,
``expr("name")`` in place of ``expr.set_results_name("name")``
- see :class:`__call__`. If ``list_all_matches`` is required, use
``expr("name*")``.
Example::
date_str = (integer.set_results_name("year") + '/'
+ integer.set_results_name("month") + '/'
+ integer.set_results_name("day"))
# equivalent form:
date_str = integer("year") + '/' + integer("month") + '/' + integer("day")
"""
listAllMatches = listAllMatches or list_all_matches
return self._setResultsName(name, listAllMatches)
def _setResultsName(self, name, listAllMatches=False):
if name is None:
return self
newself = self.copy()
if name.endswith("*"):
name = name[:-1]
listAllMatches = True
newself.resultsName = name
newself.modalResults = not listAllMatches
return newself
def set_break(self, break_flag: bool = True) -> "ParserElement":
"""
Method to invoke the Python pdb debugger when this element is
about to be parsed. Set ``break_flag`` to ``True`` to enable, ``False`` to
disable.
"""
if break_flag:
_parseMethod = self._parse
def breaker(instring, loc, doActions=True, callPreParse=True):
import pdb
# this call to pdb.set_trace() is intentional, not a checkin error
pdb.set_trace()
return _parseMethod(instring, loc, doActions, callPreParse)
breaker._originalParseMethod = _parseMethod
self._parse = breaker
else:
if hasattr(self._parse, "_originalParseMethod"):
self._parse = self._parse._originalParseMethod
return self
def set_parse_action(self, *fns: ParseAction, **kwargs) -> "ParserElement":
"""
Define one or more actions to perform when successfully matching parse element definition.
Parse actions can be called to perform data conversions, do extra validation,
update external data structures, or enhance or replace the parsed tokens.
Each parse action ``fn`` is a callable method with 0-3 arguments, called as
``fn(s, loc, toks)`` , ``fn(loc, toks)`` , ``fn(toks)`` , or just ``fn()`` , where:
- s = the original string being parsed (see note below)
- loc = the location of the matching substring
- toks = a list of the matched tokens, packaged as a :class:`ParseResults` object
The parsed tokens are passed to the parse action as ParseResults. They can be
modified in place using list-style append, extend, and pop operations to update
the parsed list elements; and with dictionary-style item set and del operations
to add, update, or remove any named results. If the tokens are modified in place,
it is not necessary to return them with a return statement.
Parse actions can also completely replace the given tokens, with another ``ParseResults``
object, or with some entirely different object (common for parse actions that perform data
conversions). A convenient way to build a new parse result is to define the values
using a dict, and then create the return value using :class:`ParseResults.from_dict`.
If None is passed as the ``fn`` parse action, all previously added parse actions for this
expression are cleared.
Optional keyword arguments:
- call_during_try = (default= ``False``) indicate if parse action should be run during
lookaheads and alternate testing. For parse actions that have side effects, it is
important to only call the parse action once it is determined that it is being
called as part of a successful parse. For parse actions that perform additional
validation, then call_during_try should be passed as True, so that the validation
code is included in the preliminary "try" parses.
Note: the default parsing behavior is to expand tabs in the input string
before starting the parsing process. See :class:`parse_string` for more
information on parsing strings containing ``<TAB>`` s, and suggested
methods to maintain a consistent view of the parsed string, the parse
location, and line and column positions within the parsed string.
Example::
# parse dates in the form YYYY/MM/DD
# use parse action to convert toks from str to int at parse time
def convert_to_int(toks):
return int(toks[0])
# use a parse action to verify that the date is a valid date
def is_valid_date(instring, loc, toks):
from datetime import date
year, month, day = toks[::2]
try:
date(year, month, day)
except ValueError:
raise ParseException(instring, loc, "invalid date given")
integer = Word(nums)
date_str = integer + '/' + integer + '/' + integer
# add parse actions
integer.set_parse_action(convert_to_int)
date_str.set_parse_action(is_valid_date)
# note that integer fields are now ints, not strings
date_str.run_tests('''
# successful parse - note that integer fields were converted to ints
1999/12/31
# fail - invalid date
1999/13/31
''')
"""
if list(fns) == [None]:
self.parseAction = []
else:
if not all(callable(fn) for fn in fns):
raise TypeError("parse actions must be callable")
self.parseAction = [_trim_arity(fn) for fn in fns]
self.callDuringTry = kwargs.get(
"call_during_try", kwargs.get("callDuringTry", False)
)
return self
def add_parse_action(self, *fns: ParseAction, **kwargs) -> "ParserElement":
"""
Add one or more parse actions to expression's list of parse actions. See :class:`set_parse_action`.
See examples in :class:`copy`.
"""
self.parseAction += [_trim_arity(fn) for fn in fns]
self.callDuringTry = self.callDuringTry or kwargs.get(
"call_during_try", kwargs.get("callDuringTry", False)
)
return self
def add_condition(self, *fns: ParseCondition, **kwargs) -> "ParserElement":
"""Add a boolean predicate function to expression's list of parse actions. See
:class:`set_parse_action` for function call signatures. Unlike ``set_parse_action``,
functions passed to ``add_condition`` need to return boolean success/fail of the condition.
Optional keyword arguments:
- message = define a custom message to be used in the raised exception
- fatal = if True, will raise ParseFatalException to stop parsing immediately; otherwise will raise
ParseException
- call_during_try = boolean to indicate if this method should be called during internal tryParse calls,
default=False
Example::
integer = Word(nums).set_parse_action(lambda toks: int(toks[0]))
year_int = integer.copy()
year_int.add_condition(lambda toks: toks[0] >= 2000, message="Only support years 2000 and later")
date_str = year_int + '/' + integer + '/' + integer
result = date_str.parse_string("1999/12/31") # -> Exception: Only support years 2000 and later (at char 0),
(line:1, col:1)
"""
for fn in fns:
self.parseAction.append(
condition_as_parse_action(
fn, message=kwargs.get("message"), fatal=kwargs.get("fatal", False)
)
)
self.callDuringTry = self.callDuringTry or kwargs.get(
"call_during_try", kwargs.get("callDuringTry", False)
)
return self
def set_fail_action(self, fn: ParseFailAction) -> "ParserElement":
"""
Define action to perform if parsing fails at this expression.
Fail acton fn is a callable function that takes the arguments
``fn(s, loc, expr, err)`` where:
- s = string being parsed
- loc = location where expression match was attempted and failed
- expr = the parse expression that failed
- err = the exception thrown
The function returns no value. It may throw :class:`ParseFatalException`
if it is desired to stop parsing immediately."""
self.failAction = fn
return self
def _skipIgnorables(self, instring, loc):
exprsFound = True
while exprsFound:
exprsFound = False
for e in self.ignoreExprs:
try:
while 1:
loc, dummy = e._parse(instring, loc)
exprsFound = True
except ParseException:
pass
return loc
def preParse(self, instring, loc):
if self.ignoreExprs:
loc = self._skipIgnorables(instring, loc)
if self.skipWhitespace:
instrlen = len(instring)
white_chars = self.whiteChars
while loc < instrlen and instring[loc] in white_chars:
loc += 1
return loc
def parseImpl(self, instring, loc, doActions=True):
return loc, []
def postParse(self, instring, loc, tokenlist):
return tokenlist
# @profile
def _parseNoCache(
self, instring, loc, doActions=True, callPreParse=True
) -> Tuple[int, ParseResults]:
TRY, MATCH, FAIL = 0, 1, 2
debugging = self.debug # and doActions)
len_instring = len(instring)
if debugging or self.failAction:
# print("Match {} at loc {}({}, {})".format(self, loc, lineno(loc, instring), col(loc, instring)))
try:
if callPreParse and self.callPreparse:
pre_loc = self.preParse(instring, loc)
else:
pre_loc = loc
tokens_start = pre_loc
if self.debugActions.debug_try:
self.debugActions.debug_try(instring, tokens_start, self, False)
if self.mayIndexError or pre_loc >= len_instring:
try:
loc, tokens = self.parseImpl(instring, pre_loc, doActions)
except IndexError:
raise ParseException(instring, len_instring, self.errmsg, self)
else:
loc, tokens = self.parseImpl(instring, pre_loc, doActions)
except Exception as err:
# print("Exception raised:", err)
if self.debugActions.debug_fail:
self.debugActions.debug_fail(
instring, tokens_start, self, err, False
)
if self.failAction:
self.failAction(instring, tokens_start, self, err)
raise
else:
if callPreParse and self.callPreparse:
pre_loc = self.preParse(instring, loc)
else:
pre_loc = loc
tokens_start = pre_loc
if self.mayIndexError or pre_loc >= len_instring:
try:
loc, tokens = self.parseImpl(instring, pre_loc, doActions)
except IndexError:
raise ParseException(instring, len_instring, self.errmsg, self)
else:
loc, tokens = self.parseImpl(instring, pre_loc, doActions)
tokens = self.postParse(instring, loc, tokens)
ret_tokens = ParseResults(
tokens, self.resultsName, asList=self.saveAsList, modal=self.modalResults
)
if self.parseAction and (doActions or self.callDuringTry):
if debugging:
try:
for fn in self.parseAction:
try:
tokens = fn(instring, tokens_start, ret_tokens)
except IndexError as parse_action_exc:
exc = ParseException("exception raised in parse action")
raise exc from parse_action_exc
if tokens is not None and tokens is not ret_tokens:
ret_tokens = ParseResults(
tokens,
self.resultsName,
asList=self.saveAsList
and isinstance(tokens, (ParseResults, list)),
modal=self.modalResults,
)
except Exception as err:
# print "Exception raised in user parse action:", err
if self.debugActions.debug_fail:
self.debugActions.debug_fail(
instring, tokens_start, self, err, False
)
raise
else:
for fn in self.parseAction:
try:
tokens = fn(instring, tokens_start, ret_tokens)
except IndexError as parse_action_exc:
exc = ParseException("exception raised in parse action")
raise exc from parse_action_exc
if tokens is not None and tokens is not ret_tokens:
ret_tokens = ParseResults(
tokens,
self.resultsName,
asList=self.saveAsList
and isinstance(tokens, (ParseResults, list)),
modal=self.modalResults,
)
if debugging:
# print("Matched", self, "->", ret_tokens.as_list())
if self.debugActions.debug_match:
self.debugActions.debug_match(
instring, tokens_start, loc, self, ret_tokens, False
)
return loc, ret_tokens
def try_parse(self, instring: str, loc: int, raise_fatal: bool = False) -> int:
try:
return self._parse(instring, loc, doActions=False)[0]
except ParseFatalException:
if raise_fatal:
raise
raise ParseException(instring, loc, self.errmsg, self)
def can_parse_next(self, instring: str, loc: int) -> bool:
try:
self.try_parse(instring, loc)
except (ParseException, IndexError):
return False
else:
return True
# cache for left-recursion in Forward references
recursion_lock = RLock()
recursion_memos: typing.Dict[
Tuple[int, "Forward", bool], Tuple[int, Union[ParseResults, Exception]]
] = {}
# argument cache for optimizing repeated calls when backtracking through recursive expressions
packrat_cache = (
{}
) # this is set later by enabled_packrat(); this is here so that reset_cache() doesn't fail
packrat_cache_lock = RLock()
packrat_cache_stats = [0, 0]
# this method gets repeatedly called during backtracking with the same arguments -
# we can cache these arguments and save ourselves the trouble of re-parsing the contained expression
def _parseCache(
self, instring, loc, doActions=True, callPreParse=True
) -> Tuple[int, ParseResults]:
HIT, MISS = 0, 1
TRY, MATCH, FAIL = 0, 1, 2
lookup = (self, instring, loc, callPreParse, doActions)
with ParserElement.packrat_cache_lock:
cache = ParserElement.packrat_cache
value = cache.get(lookup)
if value is cache.not_in_cache:
ParserElement.packrat_cache_stats[MISS] += 1
try:
value = self._parseNoCache(instring, loc, doActions, callPreParse)
except ParseBaseException as pe:
# cache a copy of the exception, without the traceback
cache.set(lookup, pe.__class__(*pe.args))
raise
else:
cache.set(lookup, (value[0], value[1].copy(), loc))
return value
else:
ParserElement.packrat_cache_stats[HIT] += 1
if self.debug and self.debugActions.debug_try:
try:
self.debugActions.debug_try(instring, loc, self, cache_hit=True)
except TypeError:
pass
if isinstance(value, Exception):
if self.debug and self.debugActions.debug_fail:
try:
self.debugActions.debug_fail(
instring, loc, self, value, cache_hit=True
)
except TypeError:
pass
raise value
loc_, result, endloc = value[0], value[1].copy(), value[2]
if self.debug and self.debugActions.debug_match:
try:
self.debugActions.debug_match(
instring, loc_, endloc, self, result, cache_hit=True
)
except TypeError:
pass
return loc_, result
_parse = _parseNoCache
@staticmethod
def reset_cache() -> None:
ParserElement.packrat_cache.clear()
ParserElement.packrat_cache_stats[:] = [0] * len(
ParserElement.packrat_cache_stats
)
ParserElement.recursion_memos.clear()
_packratEnabled = False
_left_recursion_enabled = False
@staticmethod
def disable_memoization() -> None:
"""
Disables active Packrat or Left Recursion parsing and their memoization
This method also works if neither Packrat nor Left Recursion are enabled.
This makes it safe to call before activating Packrat nor Left Recursion
to clear any previous settings.
"""
ParserElement.reset_cache()
ParserElement._left_recursion_enabled = False
ParserElement._packratEnabled = False
ParserElement._parse = ParserElement._parseNoCache
@staticmethod
def enable_left_recursion(
cache_size_limit: typing.Optional[int] = None, *, force=False
) -> None:
"""
Enables "bounded recursion" parsing, which allows for both direct and indirect
left-recursion. During parsing, left-recursive :class:`Forward` elements are
repeatedly matched with a fixed recursion depth that is gradually increased
until finding the longest match.
Example::
import pyparsing as pp
pp.ParserElement.enable_left_recursion()
E = pp.Forward("E")
num = pp.Word(pp.nums)
# match `num`, or `num '+' num`, or `num '+' num '+' num`, ...
E <<= E + '+' - num | num
print(E.parse_string("1+2+3"))
Recursion search naturally memoizes matches of ``Forward`` elements and may
thus skip reevaluation of parse actions during backtracking. This may break
programs with parse actions which rely on strict ordering of side-effects.
Parameters:
- cache_size_limit - (default=``None``) - memoize at most this many
``Forward`` elements during matching; if ``None`` (the default),
memoize all ``Forward`` elements.
Bounded Recursion parsing works similar but not identical to Packrat parsing,
thus the two cannot be used together. Use ``force=True`` to disable any
previous, conflicting settings.
"""
if force:
ParserElement.disable_memoization()
elif ParserElement._packratEnabled:
raise RuntimeError("Packrat and Bounded Recursion are not compatible")
if cache_size_limit is None:
ParserElement.recursion_memos = _UnboundedMemo()
elif cache_size_limit > 0:
ParserElement.recursion_memos = _LRUMemo(capacity=cache_size_limit)
else:
raise NotImplementedError("Memo size of %s" % cache_size_limit)
ParserElement._left_recursion_enabled = True
@staticmethod
def enable_packrat(cache_size_limit: int = 128, *, force: bool = False) -> None:
"""
Enables "packrat" parsing, which adds memoizing to the parsing logic.
Repeated parse attempts at the same string location (which happens
often in many complex grammars) can immediately return a cached value,
instead of re-executing parsing/validating code. Memoizing is done of
both valid results and parsing exceptions.
Parameters:
- cache_size_limit - (default= ``128``) - if an integer value is provided
will limit the size of the packrat cache; if None is passed, then
the cache size will be unbounded; if 0 is passed, the cache will
be effectively disabled.
This speedup may break existing programs that use parse actions that
have side-effects. For this reason, packrat parsing is disabled when
you first import pyparsing. To activate the packrat feature, your
program must call the class method :class:`ParserElement.enable_packrat`.
For best results, call ``enable_packrat()`` immediately after
importing pyparsing.
Example::
import pyparsing
pyparsing.ParserElement.enable_packrat()
Packrat parsing works similar but not identical to Bounded Recursion parsing,
thus the two cannot be used together. Use ``force=True`` to disable any
previous, conflicting settings.
"""
if force:
ParserElement.disable_memoization()
elif ParserElement._left_recursion_enabled:
raise RuntimeError("Packrat and Bounded Recursion are not compatible")
if not ParserElement._packratEnabled:
ParserElement._packratEnabled = True
if cache_size_limit is None:
ParserElement.packrat_cache = _UnboundedCache()
else:
ParserElement.packrat_cache = _FifoCache(cache_size_limit)
ParserElement._parse = ParserElement._parseCache
def parse_string(
self, instring: str, parse_all: bool = False, *, parseAll: bool = False
) -> ParseResults:
"""
Parse a string with respect to the parser definition. This function is intended as the primary interface to the
client code.
:param instring: The input string to be parsed.
:param parse_all: If set, the entire input string must match the grammar.
:param parseAll: retained for pre-PEP8 compatibility, will be removed in a future release.
:raises ParseException: Raised if ``parse_all`` is set and the input string does not match the whole grammar.
:returns: the parsed data as a :class:`ParseResults` object, which may be accessed as a `list`, a `dict`, or
an object with attributes if the given parser includes results names.
If the input string is required to match the entire grammar, ``parse_all`` flag must be set to ``True``. This
is also equivalent to ending the grammar with :class:`StringEnd`().
To report proper column numbers, ``parse_string`` operates on a copy of the input string where all tabs are
converted to spaces (8 spaces per tab, as per the default in ``string.expandtabs``). If the input string
contains tabs and the grammar uses parse actions that use the ``loc`` argument to index into the string
being parsed, one can ensure a consistent view of the input string by doing one of the following:
- calling ``parse_with_tabs`` on your grammar before calling ``parse_string`` (see :class:`parse_with_tabs`),
- define your parse action using the full ``(s,loc,toks)`` signature, and reference the input string using the
parse action's ``s`` argument, or
- explicitly expand the tabs in your input string before calling ``parse_string``.
Examples:
By default, partial matches are OK.
>>> res = Word('a').parse_string('aaaaabaaa')
>>> print(res)
['aaaaa']
The parsing behavior varies by the inheriting class of this abstract class. Please refer to the children
directly to see more examples.
It raises an exception if parse_all flag is set and instring does not match the whole grammar.
>>> res = Word('a').parse_string('aaaaabaaa', parse_all=True)
Traceback (most recent call last):
...
pyparsing.ParseException: Expected end of text, found 'b' (at char 5), (line:1, col:6)
"""
parseAll = parse_all or parseAll
ParserElement.reset_cache()
if not self.streamlined:
self.streamline()
for e in self.ignoreExprs:
e.streamline()
if not self.keepTabs:
instring = instring.expandtabs()
try:
loc, tokens = self._parse(instring, 0)
if parseAll:
loc = self.preParse(instring, loc)
se = Empty() + StringEnd()
se._parse(instring, loc)
except ParseBaseException as exc:
if ParserElement.verbose_stacktrace:
raise
else:
# catch and re-raise exception from here, clearing out pyparsing internal stack trace
raise exc.with_traceback(None)
else:
return tokens
def scan_string(
self,
instring: str,
max_matches: int = _MAX_INT,
overlap: bool = False,
*,
debug: bool = False,
maxMatches: int = _MAX_INT,
) -> Generator[Tuple[ParseResults, int, int], None, None]:
"""
Scan the input string for expression matches. Each match will return the
matching tokens, start location, and end location. May be called with optional
``max_matches`` argument, to clip scanning after 'n' matches are found. If
``overlap`` is specified, then overlapping matches will be reported.
Note that the start and end locations are reported relative to the string
being parsed. See :class:`parse_string` for more information on parsing
strings with embedded tabs.
Example::
source = "sldjf123lsdjjkf345sldkjf879lkjsfd987"
print(source)
for tokens, start, end in Word(alphas).scan_string(source):
print(' '*start + '^'*(end-start))
print(' '*start + tokens[0])
prints::
sldjf123lsdjjkf345sldkjf879lkjsfd987
^^^^^
sldjf
^^^^^^^
lsdjjkf
^^^^^^
sldkjf
^^^^^^
lkjsfd
"""
maxMatches = min(maxMatches, max_matches)
if not self.streamlined:
self.streamline()
for e in self.ignoreExprs:
e.streamline()
if not self.keepTabs:
instring = str(instring).expandtabs()
instrlen = len(instring)
loc = 0
preparseFn = self.preParse
parseFn = self._parse
ParserElement.resetCache()
matches = 0
try:
while loc <= instrlen and matches < maxMatches:
try:
preloc = preparseFn(instring, loc)
nextLoc, tokens = parseFn(instring, preloc, callPreParse=False)
except ParseException:
loc = preloc + 1
else:
if nextLoc > loc:
matches += 1
if debug:
print(
{
"tokens": tokens.asList(),
"start": preloc,
"end": nextLoc,
}
)
yield tokens, preloc, nextLoc
if overlap:
nextloc = preparseFn(instring, loc)
if nextloc > loc:
loc = nextLoc
else:
loc += 1
else:
loc = nextLoc
else:
loc = preloc + 1
except ParseBaseException as exc:
if ParserElement.verbose_stacktrace:
raise
else:
# catch and re-raise exception from here, clears out pyparsing internal stack trace
raise exc.with_traceback(None)
def transform_string(self, instring: str, *, debug: bool = False) -> str:
"""
Extension to :class:`scan_string`, to modify matching text with modified tokens that may
be returned from a parse action. To use ``transform_string``, define a grammar and
attach a parse action to it that modifies the returned token list.
Invoking ``transform_string()`` on a target string will then scan for matches,
and replace the matched text patterns according to the logic in the parse
action. ``transform_string()`` returns the resulting transformed string.
Example::
wd = Word(alphas)
wd.set_parse_action(lambda toks: toks[0].title())
print(wd.transform_string("now is the winter of our discontent made glorious summer by this sun of york."))
prints::
Now Is The Winter Of Our Discontent Made Glorious Summer By This Sun Of York.
"""
out: List[str] = []
lastE = 0
# force preservation of <TAB>s, to minimize unwanted transformation of string, and to
# keep string locs straight between transform_string and scan_string
self.keepTabs = True
try:
for t, s, e in self.scan_string(instring, debug=debug):
out.append(instring[lastE:s])
if t:
if isinstance(t, ParseResults):
out += t.as_list()
elif isinstance(t, Iterable) and not isinstance(t, str_type):
out.extend(t)
else:
out.append(t)
lastE = e
out.append(instring[lastE:])
out = [o for o in out if o]
return "".join([str(s) for s in _flatten(out)])
except ParseBaseException as exc:
if ParserElement.verbose_stacktrace:
raise
else:
# catch and re-raise exception from here, clears out pyparsing internal stack trace
raise exc.with_traceback(None)
def search_string(
self,
instring: str,
max_matches: int = _MAX_INT,
*,
debug: bool = False,
maxMatches: int = _MAX_INT,
) -> ParseResults:
"""
Another extension to :class:`scan_string`, simplifying the access to the tokens found
to match the given parse expression. May be called with optional
``max_matches`` argument, to clip searching after 'n' matches are found.
Example::
# a capitalized word starts with an uppercase letter, followed by zero or more lowercase letters
cap_word = Word(alphas.upper(), alphas.lower())
print(cap_word.search_string("More than Iron, more than Lead, more than Gold I need Electricity"))
# the sum() builtin can be used to merge results into a single ParseResults object
print(sum(cap_word.search_string("More than Iron, more than Lead, more than Gold I need Electricity")))
prints::
[['More'], ['Iron'], ['Lead'], ['Gold'], ['I'], ['Electricity']]
['More', 'Iron', 'Lead', 'Gold', 'I', 'Electricity']
"""
maxMatches = min(maxMatches, max_matches)
try:
return ParseResults(
[t for t, s, e in self.scan_string(instring, maxMatches, debug=debug)]
)
except ParseBaseException as exc:
if ParserElement.verbose_stacktrace:
raise
else:
# catch and re-raise exception from here, clears out pyparsing internal stack trace
raise exc.with_traceback(None)
def split(
self,
instring: str,
maxsplit: int = _MAX_INT,
include_separators: bool = False,
*,
includeSeparators=False,
) -> Generator[str, None, None]:
"""
Generator method to split a string using the given expression as a separator.
May be called with optional ``maxsplit`` argument, to limit the number of splits;
and the optional ``include_separators`` argument (default= ``False``), if the separating
matching text should be included in the split results.
Example::
punc = one_of(list(".,;:/-!?"))
print(list(punc.split("This, this?, this sentence, is badly punctuated!")))
prints::
['This', ' this', '', ' this sentence', ' is badly punctuated', '']
"""
includeSeparators = includeSeparators or include_separators
last = 0
for t, s, e in self.scan_string(instring, max_matches=maxsplit):
yield instring[last:s]
if includeSeparators:
yield t[0]
last = e
yield instring[last:]
def __add__(self, other) -> "ParserElement":
"""
Implementation of ``+`` operator - returns :class:`And`. Adding strings to a :class:`ParserElement`
converts them to :class:`Literal`s by default.
Example::
greet = Word(alphas) + "," + Word(alphas) + "!"
hello = "Hello, World!"
print(hello, "->", greet.parse_string(hello))
prints::
Hello, World! -> ['Hello', ',', 'World', '!']
``...`` may be used as a parse expression as a short form of :class:`SkipTo`.
Literal('start') + ... + Literal('end')
is equivalent to:
Literal('start') + SkipTo('end')("_skipped*") + Literal('end')
Note that the skipped text is returned with '_skipped' as a results name,
and to support having multiple skips in the same parser, the value returned is
a list of all skipped text.
"""
if other is Ellipsis:
return _PendingSkip(self)
if isinstance(other, str_type):
other = self._literalStringClass(other)
if not isinstance(other, ParserElement):
raise TypeError(
"Cannot combine element of type {} with ParserElement".format(
type(other).__name__
)
)
return And([self, other])
def __radd__(self, other) -> "ParserElement":
"""
Implementation of ``+`` operator when left operand is not a :class:`ParserElement`
"""
if other is Ellipsis:
return SkipTo(self)("_skipped*") + self
if isinstance(other, str_type):
other = self._literalStringClass(other)
if not isinstance(other, ParserElement):
raise TypeError(
"Cannot combine element of type {} with ParserElement".format(
type(other).__name__
)
)
return other + self
def __sub__(self, other) -> "ParserElement":
"""
Implementation of ``-`` operator, returns :class:`And` with error stop
"""
if isinstance(other, str_type):
other = self._literalStringClass(other)
if not isinstance(other, ParserElement):
raise TypeError(
"Cannot combine element of type {} with ParserElement".format(
type(other).__name__
)
)
return self + And._ErrorStop() + other
def __rsub__(self, other) -> "ParserElement":
"""
Implementation of ``-`` operator when left operand is not a :class:`ParserElement`
"""
if isinstance(other, str_type):
other = self._literalStringClass(other)
if not isinstance(other, ParserElement):
raise TypeError(
"Cannot combine element of type {} with ParserElement".format(
type(other).__name__
)
)
return other - self
def __mul__(self, other) -> "ParserElement":
"""
Implementation of ``*`` operator, allows use of ``expr * 3`` in place of
``expr + expr + expr``. Expressions may also be multiplied by a 2-integer
tuple, similar to ``{min, max}`` multipliers in regular expressions. Tuples
may also include ``None`` as in:
- ``expr*(n, None)`` or ``expr*(n, )`` is equivalent
to ``expr*n + ZeroOrMore(expr)``
(read as "at least n instances of ``expr``")
- ``expr*(None, n)`` is equivalent to ``expr*(0, n)``
(read as "0 to n instances of ``expr``")
- ``expr*(None, None)`` is equivalent to ``ZeroOrMore(expr)``
- ``expr*(1, None)`` is equivalent to ``OneOrMore(expr)``
Note that ``expr*(None, n)`` does not raise an exception if
more than n exprs exist in the input stream; that is,
``expr*(None, n)`` does not enforce a maximum number of expr
occurrences. If this behavior is desired, then write
``expr*(None, n) + ~expr``
"""
if other is Ellipsis:
other = (0, None)
elif isinstance(other, tuple) and other[:1] == (Ellipsis,):
other = ((0,) + other[1:] + (None,))[:2]
if isinstance(other, int):
minElements, optElements = other, 0
elif isinstance(other, tuple):
other = tuple(o if o is not Ellipsis else None for o in other)
other = (other + (None, None))[:2]
if other[0] is None:
other = (0, other[1])
if isinstance(other[0], int) and other[1] is None:
if other[0] == 0:
return ZeroOrMore(self)
if other[0] == 1:
return OneOrMore(self)
else:
return self * other[0] + ZeroOrMore(self)
elif isinstance(other[0], int) and isinstance(other[1], int):
minElements, optElements = other
optElements -= minElements
else:
raise TypeError(
"cannot multiply ParserElement and ({}) objects".format(
",".join(type(item).__name__ for item in other)
)
)
else:
raise TypeError(
"cannot multiply ParserElement and {} objects".format(
type(other).__name__
)
)
if minElements < 0:
raise ValueError("cannot multiply ParserElement by negative value")
if optElements < 0:
raise ValueError(
"second tuple value must be greater or equal to first tuple value"
)
if minElements == optElements == 0:
return And([])
if optElements:
def makeOptionalList(n):
if n > 1:
return Opt(self + makeOptionalList(n - 1))
else:
return Opt(self)
if minElements:
if minElements == 1:
ret = self + makeOptionalList(optElements)
else:
ret = And([self] * minElements) + makeOptionalList(optElements)
else:
ret = makeOptionalList(optElements)
else:
if minElements == 1:
ret = self
else:
ret = And([self] * minElements)
return ret
def __rmul__(self, other) -> "ParserElement":
return self.__mul__(other)
def __or__(self, other) -> "ParserElement":
"""
Implementation of ``|`` operator - returns :class:`MatchFirst`
"""
if other is Ellipsis:
return _PendingSkip(self, must_skip=True)
if isinstance(other, str_type):
other = self._literalStringClass(other)
if not isinstance(other, ParserElement):
raise TypeError(
"Cannot combine element of type {} with ParserElement".format(
type(other).__name__
)
)
return MatchFirst([self, other])
def __ror__(self, other) -> "ParserElement":
"""
Implementation of ``|`` operator when left operand is not a :class:`ParserElement`
"""
if isinstance(other, str_type):
other = self._literalStringClass(other)
if not isinstance(other, ParserElement):
raise TypeError(
"Cannot combine element of type {} with ParserElement".format(
type(other).__name__
)
)
return other | self
def __xor__(self, other) -> "ParserElement":
"""
Implementation of ``^`` operator - returns :class:`Or`
"""
if isinstance(other, str_type):
other = self._literalStringClass(other)
if not isinstance(other, ParserElement):
raise TypeError(
"Cannot combine element of type {} with ParserElement".format(
type(other).__name__
)
)
return Or([self, other])
def __rxor__(self, other) -> "ParserElement":
"""
Implementation of ``^`` operator when left operand is not a :class:`ParserElement`
"""
if isinstance(other, str_type):
other = self._literalStringClass(other)
if not isinstance(other, ParserElement):
raise TypeError(
"Cannot combine element of type {} with ParserElement".format(
type(other).__name__
)
)
return other ^ self
def __and__(self, other) -> "ParserElement":
"""
Implementation of ``&`` operator - returns :class:`Each`
"""
if isinstance(other, str_type):
other = self._literalStringClass(other)
if not isinstance(other, ParserElement):
raise TypeError(
"Cannot combine element of type {} with ParserElement".format(
type(other).__name__
)
)
return Each([self, other])
def __rand__(self, other) -> "ParserElement":
"""
Implementation of ``&`` operator when left operand is not a :class:`ParserElement`
"""
if isinstance(other, str_type):
other = self._literalStringClass(other)
if not isinstance(other, ParserElement):
raise TypeError(
"Cannot combine element of type {} with ParserElement".format(
type(other).__name__
)
)
return other & self
def __invert__(self) -> "ParserElement":
"""
Implementation of ``~`` operator - returns :class:`NotAny`
"""
return NotAny(self)
# disable __iter__ to override legacy use of sequential access to __getitem__ to
# iterate over a sequence
__iter__ = None
def __getitem__(self, key):
"""
use ``[]`` indexing notation as a short form for expression repetition:
- ``expr[n]`` is equivalent to ``expr*n``
- ``expr[m, n]`` is equivalent to ``expr*(m, n)``
- ``expr[n, ...]`` or ``expr[n,]`` is equivalent
to ``expr*n + ZeroOrMore(expr)``
(read as "at least n instances of ``expr``")
- ``expr[..., n]`` is equivalent to ``expr*(0, n)``
(read as "0 to n instances of ``expr``")
- ``expr[...]`` and ``expr[0, ...]`` are equivalent to ``ZeroOrMore(expr)``
- ``expr[1, ...]`` is equivalent to ``OneOrMore(expr)``
``None`` may be used in place of ``...``.
Note that ``expr[..., n]`` and ``expr[m, n]``do not raise an exception
if more than ``n`` ``expr``s exist in the input stream. If this behavior is
desired, then write ``expr[..., n] + ~expr``.
"""
# convert single arg keys to tuples
try:
if isinstance(key, str_type):
key = (key,)
iter(key)
except TypeError:
key = (key, key)
if len(key) > 2:
raise TypeError(
"only 1 or 2 index arguments supported ({}{})".format(
key[:5], "... [{}]".format(len(key)) if len(key) > 5 else ""
)
)
# clip to 2 elements
ret = self * tuple(key[:2])
return ret
def __call__(self, name: str = None) -> "ParserElement":
"""
Shortcut for :class:`set_results_name`, with ``list_all_matches=False``.
If ``name`` is given with a trailing ``'*'`` character, then ``list_all_matches`` will be
passed as ``True``.
If ``name` is omitted, same as calling :class:`copy`.
Example::
# these are equivalent
userdata = Word(alphas).set_results_name("name") + Word(nums + "-").set_results_name("socsecno")
userdata = Word(alphas)("name") + Word(nums + "-")("socsecno")
"""
if name is not None:
return self._setResultsName(name)
else:
return self.copy()
def suppress(self) -> "ParserElement":
"""
Suppresses the output of this :class:`ParserElement`; useful to keep punctuation from
cluttering up returned output.
"""
return Suppress(self)
def ignore_whitespace(self, recursive: bool = True) -> "ParserElement":
"""
Enables the skipping of whitespace before matching the characters in the
:class:`ParserElement`'s defined pattern.
:param recursive: If ``True`` (the default), also enable whitespace skipping in child elements (if any)
"""
self.skipWhitespace = True
return self
def leave_whitespace(self, recursive: bool = True) -> "ParserElement":
"""
Disables the skipping of whitespace before matching the characters in the
:class:`ParserElement`'s defined pattern. This is normally only used internally by
the pyparsing module, but may be needed in some whitespace-sensitive grammars.
:param recursive: If true (the default), also disable whitespace skipping in child elements (if any)
"""
self.skipWhitespace = False
return self
def set_whitespace_chars(
self, chars: Union[Set[str], str], copy_defaults: bool = False
) -> "ParserElement":
"""
Overrides the default whitespace chars
"""
self.skipWhitespace = True
self.whiteChars = set(chars)
self.copyDefaultWhiteChars = copy_defaults
return self
def parse_with_tabs(self) -> "ParserElement":
"""
Overrides default behavior to expand ``<TAB>`` s to spaces before parsing the input string.
Must be called before ``parse_string`` when the input grammar contains elements that
match ``<TAB>`` characters.
"""
self.keepTabs = True
return self
def ignore(self, other: "ParserElement") -> "ParserElement":
"""
Define expression to be ignored (e.g., comments) while doing pattern
matching; may be called repeatedly, to define multiple comment or other
ignorable patterns.
Example::
patt = Word(alphas)[1, ...]
patt.parse_string('ablaj /* comment */ lskjd')
# -> ['ablaj']
patt.ignore(c_style_comment)
patt.parse_string('ablaj /* comment */ lskjd')
# -> ['ablaj', 'lskjd']
"""
import typing
if isinstance(other, str_type):
other = Suppress(other)
if isinstance(other, Suppress):
if other not in self.ignoreExprs:
self.ignoreExprs.append(other)
else:
self.ignoreExprs.append(Suppress(other.copy()))
return self
def set_debug_actions(
self,
start_action: DebugStartAction,
success_action: DebugSuccessAction,
exception_action: DebugExceptionAction,
) -> "ParserElement":
"""
Customize display of debugging messages while doing pattern matching:
- ``start_action`` - method to be called when an expression is about to be parsed;
should have the signature ``fn(input_string: str, location: int, expression: ParserElement, cache_hit: bool)``
- ``success_action`` - method to be called when an expression has successfully parsed;
should have the signature ``fn(input_string: str, start_location: int, end_location: int, expression: ParserELement, parsed_tokens: ParseResults, cache_hit: bool)``
- ``exception_action`` - method to be called when expression fails to parse;
should have the signature ``fn(input_string: str, location: int, expression: ParserElement, exception: Exception, cache_hit: bool)``
"""
self.debugActions = self.DebugActions(
start_action or _default_start_debug_action,
success_action or _default_success_debug_action,
exception_action or _default_exception_debug_action,
)
self.debug = True
return self
def set_debug(self, flag: bool = True) -> "ParserElement":
"""
Enable display of debugging messages while doing pattern matching.
Set ``flag`` to ``True`` to enable, ``False`` to disable.
Example::
wd = Word(alphas).set_name("alphaword")
integer = Word(nums).set_name("numword")
term = wd | integer
# turn on debugging for wd
wd.set_debug()
term[1, ...].parse_string("abc 123 xyz 890")
prints::
Match alphaword at loc 0(1,1)
Matched alphaword -> ['abc']
Match alphaword at loc 3(1,4)
Exception raised:Expected alphaword (at char 4), (line:1, col:5)
Match alphaword at loc 7(1,8)
Matched alphaword -> ['xyz']
Match alphaword at loc 11(1,12)
Exception raised:Expected alphaword (at char 12), (line:1, col:13)
Match alphaword at loc 15(1,16)
Exception raised:Expected alphaword (at char 15), (line:1, col:16)
The output shown is that produced by the default debug actions - custom debug actions can be
specified using :class:`set_debug_actions`. Prior to attempting
to match the ``wd`` expression, the debugging message ``"Match <exprname> at loc <n>(<line>,<col>)"``
is shown. Then if the parse succeeds, a ``"Matched"`` message is shown, or an ``"Exception raised"``
message is shown. Also note the use of :class:`set_name` to assign a human-readable name to the expression,
which makes debugging and exception messages easier to understand - for instance, the default
name created for the :class:`Word` expression without calling ``set_name`` is ``"W:(A-Za-z)"``.
"""
if flag:
self.set_debug_actions(
_default_start_debug_action,
_default_success_debug_action,
_default_exception_debug_action,
)
else:
self.debug = False
return self
@property
def default_name(self) -> str:
if self._defaultName is None:
self._defaultName = self._generateDefaultName()
return self._defaultName
@abstractmethod
def _generateDefaultName(self):
"""
Child classes must define this method, which defines how the ``default_name`` is set.
"""
def set_name(self, name: str) -> "ParserElement":
"""
Define name for this expression, makes debugging and exception messages clearer.
Example::
Word(nums).parse_string("ABC") # -> Exception: Expected W:(0-9) (at char 0), (line:1, col:1)
Word(nums).set_name("integer").parse_string("ABC") # -> Exception: Expected integer (at char 0), (line:1, col:1)
"""
self.customName = name
self.errmsg = "Expected " + self.name
if __diag__.enable_debug_on_named_expressions:
self.set_debug()
return self
@property
def name(self) -> str:
# This will use a user-defined name if available, but otherwise defaults back to the auto-generated name
return self.customName if self.customName is not None else self.default_name
def __str__(self) -> str:
return self.name
def __repr__(self) -> str:
return str(self)
def streamline(self) -> "ParserElement":
self.streamlined = True
self._defaultName = None
return self
def recurse(self) -> Sequence["ParserElement"]:
return []
def _checkRecursion(self, parseElementList):
subRecCheckList = parseElementList[:] + [self]
for e in self.recurse():
e._checkRecursion(subRecCheckList)
def validate(self, validateTrace=None) -> None:
"""
Check defined expressions for valid structure, check for infinite recursive definitions.
"""
self._checkRecursion([])
def parse_file(
self,
file_or_filename: Union[str, Path, TextIO],
encoding: str = "utf-8",
parse_all: bool = False,
*,
parseAll: bool = False,
) -> ParseResults:
"""
Execute the parse expression on the given file or filename.
If a filename is specified (instead of a file object),
the entire file is opened, read, and closed before parsing.
"""
parseAll = parseAll or parse_all
try:
file_contents = file_or_filename.read()
except AttributeError:
with open(file_or_filename, "r", encoding=encoding) as f:
file_contents = f.read()
try:
return self.parse_string(file_contents, parseAll)
except ParseBaseException as exc:
if ParserElement.verbose_stacktrace:
raise
else:
# catch and re-raise exception from here, clears out pyparsing internal stack trace
raise exc.with_traceback(None)
def __eq__(self, other):
if self is other:
return True
elif isinstance(other, str_type):
return self.matches(other, parse_all=True)
elif isinstance(other, ParserElement):
return vars(self) == vars(other)
return False
def __hash__(self):
return id(self)
def matches(
self, test_string: str, parse_all: bool = True, *, parseAll: bool = True
) -> bool:
"""
Method for quick testing of a parser against a test string. Good for simple
inline microtests of sub expressions while building up larger parser.
Parameters:
- ``test_string`` - to test against this expression for a match
- ``parse_all`` - (default= ``True``) - flag to pass to :class:`parse_string` when running tests
Example::
expr = Word(nums)
assert expr.matches("100")
"""
parseAll = parseAll and parse_all
try:
self.parse_string(str(test_string), parse_all=parseAll)
return True
except ParseBaseException:
return False
def run_tests(
self,
tests: Union[str, List[str]],
parse_all: bool = True,
comment: typing.Optional[Union["ParserElement", str]] = "#",
full_dump: bool = True,
print_results: bool = True,
failure_tests: bool = False,
post_parse: Callable[[str, ParseResults], str] = None,
file: typing.Optional[TextIO] = None,
with_line_numbers: bool = False,
*,
parseAll: bool = True,
fullDump: bool = True,
printResults: bool = True,
failureTests: bool = False,
postParse: Callable[[str, ParseResults], str] = None,
) -> Tuple[bool, List[Tuple[str, Union[ParseResults, Exception]]]]:
"""
Execute the parse expression on a series of test strings, showing each
test, the parsed results or where the parse failed. Quick and easy way to
run a parse expression against a list of sample strings.
Parameters:
- ``tests`` - a list of separate test strings, or a multiline string of test strings
- ``parse_all`` - (default= ``True``) - flag to pass to :class:`parse_string` when running tests
- ``comment`` - (default= ``'#'``) - expression for indicating embedded comments in the test
string; pass None to disable comment filtering
- ``full_dump`` - (default= ``True``) - dump results as list followed by results names in nested outline;
if False, only dump nested list
- ``print_results`` - (default= ``True``) prints test output to stdout
- ``failure_tests`` - (default= ``False``) indicates if these tests are expected to fail parsing
- ``post_parse`` - (default= ``None``) optional callback for successful parse results; called as
`fn(test_string, parse_results)` and returns a string to be added to the test output
- ``file`` - (default= ``None``) optional file-like object to which test output will be written;
if None, will default to ``sys.stdout``
- ``with_line_numbers`` - default= ``False``) show test strings with line and column numbers
Returns: a (success, results) tuple, where success indicates that all tests succeeded
(or failed if ``failure_tests`` is True), and the results contain a list of lines of each
test's output
Example::
number_expr = pyparsing_common.number.copy()
result = number_expr.run_tests('''
# unsigned integer
100
# negative integer
-100
# float with scientific notation
6.02e23
# integer with scientific notation
1e-12
''')
print("Success" if result[0] else "Failed!")
result = number_expr.run_tests('''
# stray character
100Z
# missing leading digit before '.'
-.100
# too many '.'
3.14.159
''', failure_tests=True)
print("Success" if result[0] else "Failed!")
prints::
# unsigned integer
100
[100]
# negative integer
-100
[-100]
# float with scientific notation
6.02e23
[6.02e+23]
# integer with scientific notation
1e-12
[1e-12]
Success
# stray character
100Z
^
FAIL: Expected end of text (at char 3), (line:1, col:4)
# missing leading digit before '.'
-.100
^
FAIL: Expected {real number with scientific notation | real number | signed integer} (at char 0), (line:1, col:1)
# too many '.'
3.14.159
^
FAIL: Expected end of text (at char 4), (line:1, col:5)
Success
Each test string must be on a single line. If you want to test a string that spans multiple
lines, create a test like this::
expr.run_tests(r"this is a test\\n of strings that spans \\n 3 lines")
(Note that this is a raw string literal, you must include the leading ``'r'``.)
"""
from .testing import pyparsing_test
parseAll = parseAll and parse_all
fullDump = fullDump and full_dump
printResults = printResults and print_results
failureTests = failureTests or failure_tests
postParse = postParse or post_parse
if isinstance(tests, str_type):
line_strip = type(tests).strip
tests = [line_strip(test_line) for test_line in tests.rstrip().splitlines()]
if isinstance(comment, str_type):
comment = Literal(comment)
if file is None:
file = sys.stdout
print_ = file.write
result: Union[ParseResults, Exception]
allResults = []
comments = []
success = True
NL = Literal(r"\n").add_parse_action(replace_with("\n")).ignore(quoted_string)
BOM = "\ufeff"
for t in tests:
if comment is not None and comment.matches(t, False) or comments and not t:
comments.append(
pyparsing_test.with_line_numbers(t) if with_line_numbers else t
)
continue
if not t:
continue
out = [
"\n" + "\n".join(comments) if comments else "",
pyparsing_test.with_line_numbers(t) if with_line_numbers else t,
]
comments = []
try:
# convert newline marks to actual newlines, and strip leading BOM if present
t = NL.transform_string(t.lstrip(BOM))
result = self.parse_string(t, parse_all=parseAll)
except ParseBaseException as pe:
fatal = "(FATAL)" if isinstance(pe, ParseFatalException) else ""
out.append(pe.explain())
out.append("FAIL: " + str(pe))
if ParserElement.verbose_stacktrace:
out.extend(traceback.format_tb(pe.__traceback__))
success = success and failureTests
result = pe
except Exception as exc:
out.append("FAIL-EXCEPTION: {}: {}".format(type(exc).__name__, exc))
if ParserElement.verbose_stacktrace:
out.extend(traceback.format_tb(exc.__traceback__))
success = success and failureTests
result = exc
else:
success = success and not failureTests
if postParse is not None:
try:
pp_value = postParse(t, result)
if pp_value is not None:
if isinstance(pp_value, ParseResults):
out.append(pp_value.dump())
else:
out.append(str(pp_value))
else:
out.append(result.dump())
except Exception as e:
out.append(result.dump(full=fullDump))
out.append(
"{} failed: {}: {}".format(
postParse.__name__, type(e).__name__, e
)
)
else:
out.append(result.dump(full=fullDump))
out.append("")
if printResults:
print_("\n".join(out))
allResults.append((t, result))
return success, allResults
def create_diagram(
self,
output_html: Union[TextIO, Path, str],
vertical: int = 3,
show_results_names: bool = False,
show_groups: bool = False,
**kwargs,
) -> None:
"""
Create a railroad diagram for the parser.
Parameters:
- output_html (str or file-like object) - output target for generated
diagram HTML
- vertical (int) - threshold for formatting multiple alternatives vertically
instead of horizontally (default=3)
- show_results_names - bool flag whether diagram should show annotations for
defined results names
- show_groups - bool flag whether groups should be highlighted with an unlabeled surrounding box
Additional diagram-formatting keyword arguments can also be included;
see railroad.Diagram class.
"""
try:
from .diagram import to_railroad, railroad_to_html
except ImportError as ie:
raise Exception(
"must ``pip install pyparsing[diagrams]`` to generate parser railroad diagrams"
) from ie
self.streamline()
railroad = to_railroad(
self,
vertical=vertical,
show_results_names=show_results_names,
show_groups=show_groups,
diagram_kwargs=kwargs,
)
if isinstance(output_html, (str, Path)):
with open(output_html, "w", encoding="utf-8") as diag_file:
diag_file.write(railroad_to_html(railroad))
else:
# we were passed a file-like object, just write to it
output_html.write(railroad_to_html(railroad))
setDefaultWhitespaceChars = set_default_whitespace_chars
inlineLiteralsUsing = inline_literals_using
setResultsName = set_results_name
setBreak = set_break
setParseAction = set_parse_action
addParseAction = add_parse_action
addCondition = add_condition
setFailAction = set_fail_action
tryParse = try_parse
canParseNext = can_parse_next
resetCache = reset_cache
enableLeftRecursion = enable_left_recursion
enablePackrat = enable_packrat
parseString = parse_string
scanString = scan_string
searchString = search_string
transformString = transform_string
setWhitespaceChars = set_whitespace_chars
parseWithTabs = parse_with_tabs
setDebugActions = set_debug_actions
setDebug = set_debug
defaultName = default_name
setName = set_name
parseFile = parse_file
runTests = run_tests
ignoreWhitespace = ignore_whitespace
leaveWhitespace = leave_whitespace
class _PendingSkip(ParserElement):
# internal placeholder class to hold a place were '...' is added to a parser element,
# once another ParserElement is added, this placeholder will be replaced with a SkipTo
def __init__(self, expr: ParserElement, must_skip: bool = False):
super().__init__()
self.anchor = expr
self.must_skip = must_skip
def _generateDefaultName(self):
return str(self.anchor + Empty()).replace("Empty", "...")
def __add__(self, other) -> "ParserElement":
skipper = SkipTo(other).set_name("...")("_skipped*")
if self.must_skip:
def must_skip(t):
if not t._skipped or t._skipped.as_list() == [""]:
del t[0]
t.pop("_skipped", None)
def show_skip(t):
if t._skipped.as_list()[-1:] == [""]:
t.pop("_skipped")
t["_skipped"] = "missing <" + repr(self.anchor) + ">"
return (
self.anchor + skipper().add_parse_action(must_skip)
| skipper().add_parse_action(show_skip)
) + other
return self.anchor + skipper + other
def __repr__(self):
return self.defaultName
def parseImpl(self, *args):
raise Exception(
"use of `...` expression without following SkipTo target expression"
)
class Token(ParserElement):
"""Abstract :class:`ParserElement` subclass, for defining atomic
matching patterns.
"""
def __init__(self):
super().__init__(savelist=False)
def _generateDefaultName(self):
return type(self).__name__
class Empty(Token):
"""
An empty token, will always match.
"""
def __init__(self):
super().__init__()
self.mayReturnEmpty = True
self.mayIndexError = False
class NoMatch(Token):
"""
A token that will never match.
"""
def __init__(self):
super().__init__()
self.mayReturnEmpty = True
self.mayIndexError = False
self.errmsg = "Unmatchable token"
def parseImpl(self, instring, loc, doActions=True):
raise ParseException(instring, loc, self.errmsg, self)
class Literal(Token):
"""
Token to exactly match a specified string.
Example::
Literal('blah').parse_string('blah') # -> ['blah']
Literal('blah').parse_string('blahfooblah') # -> ['blah']
Literal('blah').parse_string('bla') # -> Exception: Expected "blah"
For case-insensitive matching, use :class:`CaselessLiteral`.
For keyword matching (force word break before and after the matched string),
use :class:`Keyword` or :class:`CaselessKeyword`.
"""
def __init__(self, match_string: str = "", *, matchString: str = ""):
super().__init__()
match_string = matchString or match_string
self.match = match_string
self.matchLen = len(match_string)
try:
self.firstMatchChar = match_string[0]
except IndexError:
raise ValueError("null string passed to Literal; use Empty() instead")
self.errmsg = "Expected " + self.name
self.mayReturnEmpty = False
self.mayIndexError = False
# Performance tuning: modify __class__ to select
# a parseImpl optimized for single-character check
if self.matchLen == 1 and type(self) is Literal:
self.__class__ = _SingleCharLiteral
def _generateDefaultName(self):
return repr(self.match)
def parseImpl(self, instring, loc, doActions=True):
if instring[loc] == self.firstMatchChar and instring.startswith(
self.match, loc
):
return loc + self.matchLen, self.match
raise ParseException(instring, loc, self.errmsg, self)
class _SingleCharLiteral(Literal):
def parseImpl(self, instring, loc, doActions=True):
if instring[loc] == self.firstMatchChar:
return loc + 1, self.match
raise ParseException(instring, loc, self.errmsg, self)
ParserElement._literalStringClass = Literal
class Keyword(Token):
"""
Token to exactly match a specified string as a keyword, that is,
it must be immediately followed by a non-keyword character. Compare
with :class:`Literal`:
- ``Literal("if")`` will match the leading ``'if'`` in
``'ifAndOnlyIf'``.
- ``Keyword("if")`` will not; it will only match the leading
``'if'`` in ``'if x=1'``, or ``'if(y==2)'``
Accepts two optional constructor arguments in addition to the
keyword string:
- ``identChars`` is a string of characters that would be valid
identifier characters, defaulting to all alphanumerics + "_" and
"$"
- ``caseless`` allows case-insensitive matching, default is ``False``.
Example::
Keyword("start").parse_string("start") # -> ['start']
Keyword("start").parse_string("starting") # -> Exception
For case-insensitive matching, use :class:`CaselessKeyword`.
"""
DEFAULT_KEYWORD_CHARS = alphanums + "_$"
def __init__(
self,
match_string: str = "",
ident_chars: typing.Optional[str] = None,
caseless: bool = False,
*,
matchString: str = "",
identChars: typing.Optional[str] = None,
):
super().__init__()
identChars = identChars or ident_chars
if identChars is None:
identChars = Keyword.DEFAULT_KEYWORD_CHARS
match_string = matchString or match_string
self.match = match_string
self.matchLen = len(match_string)
try:
self.firstMatchChar = match_string[0]
except IndexError:
raise ValueError("null string passed to Keyword; use Empty() instead")
self.errmsg = "Expected {} {}".format(type(self).__name__, self.name)
self.mayReturnEmpty = False
self.mayIndexError = False
self.caseless = caseless
if caseless:
self.caselessmatch = match_string.upper()
identChars = identChars.upper()
self.identChars = set(identChars)
def _generateDefaultName(self):
return repr(self.match)
def parseImpl(self, instring, loc, doActions=True):
errmsg = self.errmsg
errloc = loc
if self.caseless:
if instring[loc : loc + self.matchLen].upper() == self.caselessmatch:
if loc == 0 or instring[loc - 1].upper() not in self.identChars:
if (
loc >= len(instring) - self.matchLen
or instring[loc + self.matchLen].upper() not in self.identChars
):
return loc + self.matchLen, self.match
else:
# followed by keyword char
errmsg += ", was immediately followed by keyword character"
errloc = loc + self.matchLen
else:
# preceded by keyword char
errmsg += ", keyword was immediately preceded by keyword character"
errloc = loc - 1
# else no match just raise plain exception
else:
if (
instring[loc] == self.firstMatchChar
and self.matchLen == 1
or instring.startswith(self.match, loc)
):
if loc == 0 or instring[loc - 1] not in self.identChars:
if (
loc >= len(instring) - self.matchLen
or instring[loc + self.matchLen] not in self.identChars
):
return loc + self.matchLen, self.match
else:
# followed by keyword char
errmsg += (
", keyword was immediately followed by keyword character"
)
errloc = loc + self.matchLen
else:
# preceded by keyword char
errmsg += ", keyword was immediately preceded by keyword character"
errloc = loc - 1
# else no match just raise plain exception
raise ParseException(instring, errloc, errmsg, self)
@staticmethod
def set_default_keyword_chars(chars) -> None:
"""
Overrides the default characters used by :class:`Keyword` expressions.
"""
Keyword.DEFAULT_KEYWORD_CHARS = chars
setDefaultKeywordChars = set_default_keyword_chars
class CaselessLiteral(Literal):
"""
Token to match a specified string, ignoring case of letters.
Note: the matched results will always be in the case of the given
match string, NOT the case of the input text.
Example::
CaselessLiteral("CMD")[1, ...].parse_string("cmd CMD Cmd10")
# -> ['CMD', 'CMD', 'CMD']
(Contrast with example for :class:`CaselessKeyword`.)
"""
def __init__(self, match_string: str = "", *, matchString: str = ""):
match_string = matchString or match_string
super().__init__(match_string.upper())
# Preserve the defining literal.
self.returnString = match_string
self.errmsg = "Expected " + self.name
def parseImpl(self, instring, loc, doActions=True):
if instring[loc : loc + self.matchLen].upper() == self.match:
return loc + self.matchLen, self.returnString
raise ParseException(instring, loc, self.errmsg, self)
class CaselessKeyword(Keyword):
"""
Caseless version of :class:`Keyword`.
Example::
CaselessKeyword("CMD")[1, ...].parse_string("cmd CMD Cmd10")
# -> ['CMD', 'CMD']
(Contrast with example for :class:`CaselessLiteral`.)
"""
def __init__(
self,
match_string: str = "",
ident_chars: typing.Optional[str] = None,
*,
matchString: str = "",
identChars: typing.Optional[str] = None,
):
identChars = identChars or ident_chars
match_string = matchString or match_string
super().__init__(match_string, identChars, caseless=True)
class CloseMatch(Token):
"""A variation on :class:`Literal` which matches "close" matches,
that is, strings with at most 'n' mismatching characters.
:class:`CloseMatch` takes parameters:
- ``match_string`` - string to be matched
- ``caseless`` - a boolean indicating whether to ignore casing when comparing characters
- ``max_mismatches`` - (``default=1``) maximum number of
mismatches allowed to count as a match
The results from a successful parse will contain the matched text
from the input string and the following named results:
- ``mismatches`` - a list of the positions within the
match_string where mismatches were found
- ``original`` - the original match_string used to compare
against the input string
If ``mismatches`` is an empty list, then the match was an exact
match.
Example::
patt = CloseMatch("ATCATCGAATGGA")
patt.parse_string("ATCATCGAAXGGA") # -> (['ATCATCGAAXGGA'], {'mismatches': [[9]], 'original': ['ATCATCGAATGGA']})
patt.parse_string("ATCAXCGAAXGGA") # -> Exception: Expected 'ATCATCGAATGGA' (with up to 1 mismatches) (at char 0), (line:1, col:1)
# exact match
patt.parse_string("ATCATCGAATGGA") # -> (['ATCATCGAATGGA'], {'mismatches': [[]], 'original': ['ATCATCGAATGGA']})
# close match allowing up to 2 mismatches
patt = CloseMatch("ATCATCGAATGGA", max_mismatches=2)
patt.parse_string("ATCAXCGAAXGGA") # -> (['ATCAXCGAAXGGA'], {'mismatches': [[4, 9]], 'original': ['ATCATCGAATGGA']})
"""
def __init__(
self,
match_string: str,
max_mismatches: int = None,
*,
maxMismatches: int = 1,
caseless=False,
):
maxMismatches = max_mismatches if max_mismatches is not None else maxMismatches
super().__init__()
self.match_string = match_string
self.maxMismatches = maxMismatches
self.errmsg = "Expected {!r} (with up to {} mismatches)".format(
self.match_string, self.maxMismatches
)
self.caseless = caseless
self.mayIndexError = False
self.mayReturnEmpty = False
def _generateDefaultName(self):
return "{}:{!r}".format(type(self).__name__, self.match_string)
def parseImpl(self, instring, loc, doActions=True):
start = loc
instrlen = len(instring)
maxloc = start + len(self.match_string)
if maxloc <= instrlen:
match_string = self.match_string
match_stringloc = 0
mismatches = []
maxMismatches = self.maxMismatches
for match_stringloc, s_m in enumerate(
zip(instring[loc:maxloc], match_string)
):
src, mat = s_m
if self.caseless:
src, mat = src.lower(), mat.lower()
if src != mat:
mismatches.append(match_stringloc)
if len(mismatches) > maxMismatches:
break
else:
loc = start + match_stringloc + 1
results = ParseResults([instring[start:loc]])
results["original"] = match_string
results["mismatches"] = mismatches
return loc, results
raise ParseException(instring, loc, self.errmsg, self)
class Word(Token):
"""Token for matching words composed of allowed character sets.
Parameters:
- ``init_chars`` - string of all characters that should be used to
match as a word; "ABC" will match "AAA", "ABAB", "CBAC", etc.;
if ``body_chars`` is also specified, then this is the string of
initial characters
- ``body_chars`` - string of characters that
can be used for matching after a matched initial character as
given in ``init_chars``; if omitted, same as the initial characters
(default=``None``)
- ``min`` - minimum number of characters to match (default=1)
- ``max`` - maximum number of characters to match (default=0)
- ``exact`` - exact number of characters to match (default=0)
- ``as_keyword`` - match as a keyword (default=``False``)
- ``exclude_chars`` - characters that might be
found in the input ``body_chars`` string but which should not be
accepted for matching ;useful to define a word of all
printables except for one or two characters, for instance
(default=``None``)
:class:`srange` is useful for defining custom character set strings
for defining :class:`Word` expressions, using range notation from
regular expression character sets.
A common mistake is to use :class:`Word` to match a specific literal
string, as in ``Word("Address")``. Remember that :class:`Word`
uses the string argument to define *sets* of matchable characters.
This expression would match "Add", "AAA", "dAred", or any other word
made up of the characters 'A', 'd', 'r', 'e', and 's'. To match an
exact literal string, use :class:`Literal` or :class:`Keyword`.
pyparsing includes helper strings for building Words:
- :class:`alphas`
- :class:`nums`
- :class:`alphanums`
- :class:`hexnums`
- :class:`alphas8bit` (alphabetic characters in ASCII range 128-255
- accented, tilded, umlauted, etc.)
- :class:`punc8bit` (non-alphabetic characters in ASCII range
128-255 - currency, symbols, superscripts, diacriticals, etc.)
- :class:`printables` (any non-whitespace character)
``alphas``, ``nums``, and ``printables`` are also defined in several
Unicode sets - see :class:`pyparsing_unicode``.
Example::
# a word composed of digits
integer = Word(nums) # equivalent to Word("0123456789") or Word(srange("0-9"))
# a word with a leading capital, and zero or more lowercase
capital_word = Word(alphas.upper(), alphas.lower())
# hostnames are alphanumeric, with leading alpha, and '-'
hostname = Word(alphas, alphanums + '-')
# roman numeral (not a strict parser, accepts invalid mix of characters)
roman = Word("IVXLCDM")
# any string of non-whitespace characters, except for ','
csv_value = Word(printables, exclude_chars=",")
"""
def __init__(
self,
init_chars: str = "",
body_chars: typing.Optional[str] = None,
min: int = 1,
max: int = 0,
exact: int = 0,
as_keyword: bool = False,
exclude_chars: typing.Optional[str] = None,
*,
initChars: typing.Optional[str] = None,
bodyChars: typing.Optional[str] = None,
asKeyword: bool = False,
excludeChars: typing.Optional[str] = None,
):
initChars = initChars or init_chars
bodyChars = bodyChars or body_chars
asKeyword = asKeyword or as_keyword
excludeChars = excludeChars or exclude_chars
super().__init__()
if not initChars:
raise ValueError(
"invalid {}, initChars cannot be empty string".format(
type(self).__name__
)
)
initChars = set(initChars)
self.initChars = initChars
if excludeChars:
excludeChars = set(excludeChars)
initChars -= excludeChars
if bodyChars:
bodyChars = set(bodyChars) - excludeChars
self.initCharsOrig = "".join(sorted(initChars))
if bodyChars:
self.bodyCharsOrig = "".join(sorted(bodyChars))
self.bodyChars = set(bodyChars)
else:
self.bodyCharsOrig = "".join(sorted(initChars))
self.bodyChars = set(initChars)
self.maxSpecified = max > 0
if min < 1:
raise ValueError(
"cannot specify a minimum length < 1; use Opt(Word()) if zero-length word is permitted"
)
self.minLen = min
if max > 0:
self.maxLen = max
else:
self.maxLen = _MAX_INT
if exact > 0:
self.maxLen = exact
self.minLen = exact
self.errmsg = "Expected " + self.name
self.mayIndexError = False
self.asKeyword = asKeyword
# see if we can make a regex for this Word
if " " not in self.initChars | self.bodyChars and (min == 1 and exact == 0):
if self.bodyChars == self.initChars:
if max == 0:
repeat = "+"
elif max == 1:
repeat = ""
else:
repeat = "{{{},{}}}".format(
self.minLen, "" if self.maxLen == _MAX_INT else self.maxLen
)
self.reString = "[{}]{}".format(
_collapse_string_to_ranges(self.initChars),
repeat,
)
elif len(self.initChars) == 1:
if max == 0:
repeat = "*"
else:
repeat = "{{0,{}}}".format(max - 1)
self.reString = "{}[{}]{}".format(
re.escape(self.initCharsOrig),
_collapse_string_to_ranges(self.bodyChars),
repeat,
)
else:
if max == 0:
repeat = "*"
elif max == 2:
repeat = ""
else:
repeat = "{{0,{}}}".format(max - 1)
self.reString = "[{}][{}]{}".format(
_collapse_string_to_ranges(self.initChars),
_collapse_string_to_ranges(self.bodyChars),
repeat,
)
if self.asKeyword:
self.reString = r"\b" + self.reString + r"\b"
try:
self.re = re.compile(self.reString)
except re.error:
self.re = None
else:
self.re_match = self.re.match
self.__class__ = _WordRegex
def _generateDefaultName(self):
def charsAsStr(s):
max_repr_len = 16
s = _collapse_string_to_ranges(s, re_escape=False)
if len(s) > max_repr_len:
return s[: max_repr_len - 3] + "..."
else:
return s
if self.initChars != self.bodyChars:
base = "W:({}, {})".format(
charsAsStr(self.initChars), charsAsStr(self.bodyChars)
)
else:
base = "W:({})".format(charsAsStr(self.initChars))
# add length specification
if self.minLen > 1 or self.maxLen != _MAX_INT:
if self.minLen == self.maxLen:
if self.minLen == 1:
return base[2:]
else:
return base + "{{{}}}".format(self.minLen)
elif self.maxLen == _MAX_INT:
return base + "{{{},...}}".format(self.minLen)
else:
return base + "{{{},{}}}".format(self.minLen, self.maxLen)
return base
def parseImpl(self, instring, loc, doActions=True):
if instring[loc] not in self.initChars:
raise ParseException(instring, loc, self.errmsg, self)
start = loc
loc += 1
instrlen = len(instring)
bodychars = self.bodyChars
maxloc = start + self.maxLen
maxloc = min(maxloc, instrlen)
while loc < maxloc and instring[loc] in bodychars:
loc += 1
throwException = False
if loc - start < self.minLen:
throwException = True
elif self.maxSpecified and loc < instrlen and instring[loc] in bodychars:
throwException = True
elif self.asKeyword:
if (
start > 0
and instring[start - 1] in bodychars
or loc < instrlen
and instring[loc] in bodychars
):
throwException = True
if throwException:
raise ParseException(instring, loc, self.errmsg, self)
return loc, instring[start:loc]
class _WordRegex(Word):
def parseImpl(self, instring, loc, doActions=True):
result = self.re_match(instring, loc)
if not result:
raise ParseException(instring, loc, self.errmsg, self)
loc = result.end()
return loc, result.group()
class Char(_WordRegex):
"""A short-cut class for defining :class:`Word` ``(characters, exact=1)``,
when defining a match of any single character in a string of
characters.
"""
def __init__(
self,
charset: str,
as_keyword: bool = False,
exclude_chars: typing.Optional[str] = None,
*,
asKeyword: bool = False,
excludeChars: typing.Optional[str] = None,
):
asKeyword = asKeyword or as_keyword
excludeChars = excludeChars or exclude_chars
super().__init__(
charset, exact=1, asKeyword=asKeyword, excludeChars=excludeChars
)
self.reString = "[{}]".format(_collapse_string_to_ranges(self.initChars))
if asKeyword:
self.reString = r"\b{}\b".format(self.reString)
self.re = re.compile(self.reString)
self.re_match = self.re.match
class Regex(Token):
r"""Token for matching strings that match a given regular
expression. Defined with string specifying the regular expression in
a form recognized by the stdlib Python `re module <https://docs.python.org/3/library/re.html>`_.
If the given regex contains named groups (defined using ``(?P<name>...)``),
these will be preserved as named :class:`ParseResults`.
If instead of the Python stdlib ``re`` module you wish to use a different RE module
(such as the ``regex`` module), you can do so by building your ``Regex`` object with
a compiled RE that was compiled using ``regex``.
Example::
realnum = Regex(r"[+-]?\d+\.\d*")
# ref: https://stackoverflow.com/questions/267399/how-do-you-match-only-valid-roman-numerals-with-a-regular-expression
roman = Regex(r"M{0,4}(CM|CD|D?{0,3})(XC|XL|L?X{0,3})(IX|IV|V?I{0,3})")
# named fields in a regex will be returned as named results
date = Regex(r'(?P<year>\d{4})-(?P<month>\d\d?)-(?P<day>\d\d?)')
# the Regex class will accept re's compiled using the regex module
import regex
parser = pp.Regex(regex.compile(r'[0-9]'))
"""
def __init__(
self,
pattern: Any,
flags: Union[re.RegexFlag, int] = 0,
as_group_list: bool = False,
as_match: bool = False,
*,
asGroupList: bool = False,
asMatch: bool = False,
):
"""The parameters ``pattern`` and ``flags`` are passed
to the ``re.compile()`` function as-is. See the Python
`re module <https://docs.python.org/3/library/re.html>`_ module for an
explanation of the acceptable patterns and flags.
"""
super().__init__()
asGroupList = asGroupList or as_group_list
asMatch = asMatch or as_match
if isinstance(pattern, str_type):
if not pattern:
raise ValueError("null string passed to Regex; use Empty() instead")
self._re = None
self.reString = self.pattern = pattern
self.flags = flags
elif hasattr(pattern, "pattern") and hasattr(pattern, "match"):
self._re = pattern
self.pattern = self.reString = pattern.pattern
self.flags = flags
else:
raise TypeError(
"Regex may only be constructed with a string or a compiled RE object"
)
self.errmsg = "Expected " + self.name
self.mayIndexError = False
self.asGroupList = asGroupList
self.asMatch = asMatch
if self.asGroupList:
self.parseImpl = self.parseImplAsGroupList
if self.asMatch:
self.parseImpl = self.parseImplAsMatch
@cached_property
def re(self):
if self._re:
return self._re
else:
try:
return re.compile(self.pattern, self.flags)
except re.error:
raise ValueError(
"invalid pattern ({!r}) passed to Regex".format(self.pattern)
)
@cached_property
def re_match(self):
return self.re.match
@cached_property
def mayReturnEmpty(self):
return self.re_match("") is not None
def _generateDefaultName(self):
return "Re:({})".format(repr(self.pattern).replace("\\\\", "\\"))
def parseImpl(self, instring, loc, doActions=True):
result = self.re_match(instring, loc)
if not result:
raise ParseException(instring, loc, self.errmsg, self)
loc = result.end()
ret = ParseResults(result.group())
d = result.groupdict()
if d:
for k, v in d.items():
ret[k] = v
return loc, ret
def parseImplAsGroupList(self, instring, loc, doActions=True):
result = self.re_match(instring, loc)
if not result:
raise ParseException(instring, loc, self.errmsg, self)
loc = result.end()
ret = result.groups()
return loc, ret
def parseImplAsMatch(self, instring, loc, doActions=True):
result = self.re_match(instring, loc)
if not result:
raise ParseException(instring, loc, self.errmsg, self)
loc = result.end()
ret = result
return loc, ret
def sub(self, repl: str) -> ParserElement:
r"""
Return :class:`Regex` with an attached parse action to transform the parsed
result as if called using `re.sub(expr, repl, string) <https://docs.python.org/3/library/re.html#re.sub>`_.
Example::
make_html = Regex(r"(\w+):(.*?):").sub(r"<\1>\2</\1>")
print(make_html.transform_string("h1:main title:"))
# prints "<h1>main title</h1>"
"""
if self.asGroupList:
raise TypeError("cannot use sub() with Regex(asGroupList=True)")
if self.asMatch and callable(repl):
raise TypeError("cannot use sub() with a callable with Regex(asMatch=True)")
if self.asMatch:
def pa(tokens):
return tokens[0].expand(repl)
else:
def pa(tokens):
return self.re.sub(repl, tokens[0])
return self.add_parse_action(pa)
class QuotedString(Token):
r"""
Token for matching strings that are delimited by quoting characters.
Defined with the following parameters:
- ``quote_char`` - string of one or more characters defining the
quote delimiting string
- ``esc_char`` - character to re_escape quotes, typically backslash
(default= ``None``)
- ``esc_quote`` - special quote sequence to re_escape an embedded quote
string (such as SQL's ``""`` to re_escape an embedded ``"``)
(default= ``None``)
- ``multiline`` - boolean indicating whether quotes can span
multiple lines (default= ``False``)
- ``unquote_results`` - boolean indicating whether the matched text
should be unquoted (default= ``True``)
- ``end_quote_char`` - string of one or more characters defining the
end of the quote delimited string (default= ``None`` => same as
quote_char)
- ``convert_whitespace_escapes`` - convert escaped whitespace
(``'\t'``, ``'\n'``, etc.) to actual whitespace
(default= ``True``)
Example::
qs = QuotedString('"')
print(qs.search_string('lsjdf "This is the quote" sldjf'))
complex_qs = QuotedString('{{', end_quote_char='}}')
print(complex_qs.search_string('lsjdf {{This is the "quote"}} sldjf'))
sql_qs = QuotedString('"', esc_quote='""')
print(sql_qs.search_string('lsjdf "This is the quote with ""embedded"" quotes" sldjf'))
prints::
[['This is the quote']]
[['This is the "quote"']]
[['This is the quote with "embedded" quotes']]
"""
ws_map = ((r"\t", "\t"), (r"\n", "\n"), (r"\f", "\f"), (r"\r", "\r"))
def __init__(
self,
quote_char: str = "",
esc_char: typing.Optional[str] = None,
esc_quote: typing.Optional[str] = None,
multiline: bool = False,
unquote_results: bool = True,
end_quote_char: typing.Optional[str] = None,
convert_whitespace_escapes: bool = True,
*,
quoteChar: str = "",
escChar: typing.Optional[str] = None,
escQuote: typing.Optional[str] = None,
unquoteResults: bool = True,
endQuoteChar: typing.Optional[str] = None,
convertWhitespaceEscapes: bool = True,
):
super().__init__()
escChar = escChar or esc_char
escQuote = escQuote or esc_quote
unquoteResults = unquoteResults and unquote_results
endQuoteChar = endQuoteChar or end_quote_char
convertWhitespaceEscapes = (
convertWhitespaceEscapes and convert_whitespace_escapes
)
quote_char = quoteChar or quote_char
# remove white space from quote chars - wont work anyway
quote_char = quote_char.strip()
if not quote_char:
raise ValueError("quote_char cannot be the empty string")
if endQuoteChar is None:
endQuoteChar = quote_char
else:
endQuoteChar = endQuoteChar.strip()
if not endQuoteChar:
raise ValueError("endQuoteChar cannot be the empty string")
self.quoteChar = quote_char
self.quoteCharLen = len(quote_char)
self.firstQuoteChar = quote_char[0]
self.endQuoteChar = endQuoteChar
self.endQuoteCharLen = len(endQuoteChar)
self.escChar = escChar
self.escQuote = escQuote
self.unquoteResults = unquoteResults
self.convertWhitespaceEscapes = convertWhitespaceEscapes
sep = ""
inner_pattern = ""
if escQuote:
inner_pattern += r"{}(?:{})".format(sep, re.escape(escQuote))
sep = "|"
if escChar:
inner_pattern += r"{}(?:{}.)".format(sep, re.escape(escChar))
sep = "|"
self.escCharReplacePattern = re.escape(self.escChar) + "(.)"
if len(self.endQuoteChar) > 1:
inner_pattern += (
"{}(?:".format(sep)
+ "|".join(
"(?:{}(?!{}))".format(
re.escape(self.endQuoteChar[:i]),
re.escape(self.endQuoteChar[i:]),
)
for i in range(len(self.endQuoteChar) - 1, 0, -1)
)
+ ")"
)
sep = "|"
if multiline:
self.flags = re.MULTILINE | re.DOTALL
inner_pattern += r"{}(?:[^{}{}])".format(
sep,
_escape_regex_range_chars(self.endQuoteChar[0]),
(_escape_regex_range_chars(escChar) if escChar is not None else ""),
)
else:
self.flags = 0
inner_pattern += r"{}(?:[^{}\n\r{}])".format(
sep,
_escape_regex_range_chars(self.endQuoteChar[0]),
(_escape_regex_range_chars(escChar) if escChar is not None else ""),
)
self.pattern = "".join(
[
re.escape(self.quoteChar),
"(?:",
inner_pattern,
")*",
re.escape(self.endQuoteChar),
]
)
try:
self.re = re.compile(self.pattern, self.flags)
self.reString = self.pattern
self.re_match = self.re.match
except re.error:
raise ValueError(
"invalid pattern {!r} passed to Regex".format(self.pattern)
)
self.errmsg = "Expected " + self.name
self.mayIndexError = False
self.mayReturnEmpty = True
def _generateDefaultName(self):
if self.quoteChar == self.endQuoteChar and isinstance(self.quoteChar, str_type):
return "string enclosed in {!r}".format(self.quoteChar)
return "quoted string, starting with {} ending with {}".format(
self.quoteChar, self.endQuoteChar
)
def parseImpl(self, instring, loc, doActions=True):
result = (
instring[loc] == self.firstQuoteChar
and self.re_match(instring, loc)
or None
)
if not result:
raise ParseException(instring, loc, self.errmsg, self)
loc = result.end()
ret = result.group()
if self.unquoteResults:
# strip off quotes
ret = ret[self.quoteCharLen : -self.endQuoteCharLen]
if isinstance(ret, str_type):
# replace escaped whitespace
if "\\" in ret and self.convertWhitespaceEscapes:
for wslit, wschar in self.ws_map:
ret = ret.replace(wslit, wschar)
# replace escaped characters
if self.escChar:
ret = re.sub(self.escCharReplacePattern, r"\g<1>", ret)
# replace escaped quotes
if self.escQuote:
ret = ret.replace(self.escQuote, self.endQuoteChar)
return loc, ret
class CharsNotIn(Token):
"""Token for matching words composed of characters *not* in a given
set (will include whitespace in matched characters if not listed in
the provided exclusion set - see example). Defined with string
containing all disallowed characters, and an optional minimum,
maximum, and/or exact length. The default value for ``min`` is
1 (a minimum value < 1 is not valid); the default values for
``max`` and ``exact`` are 0, meaning no maximum or exact
length restriction.
Example::
# define a comma-separated-value as anything that is not a ','
csv_value = CharsNotIn(',')
print(delimited_list(csv_value).parse_string("dkls,lsdkjf,s12 34,@!#,213"))
prints::
['dkls', 'lsdkjf', 's12 34', '@!#', '213']
"""
def __init__(
self,
not_chars: str = "",
min: int = 1,
max: int = 0,
exact: int = 0,
*,
notChars: str = "",
):
super().__init__()
self.skipWhitespace = False
self.notChars = not_chars or notChars
self.notCharsSet = set(self.notChars)
if min < 1:
raise ValueError(
"cannot specify a minimum length < 1; use "
"Opt(CharsNotIn()) if zero-length char group is permitted"
)
self.minLen = min
if max > 0:
self.maxLen = max
else:
self.maxLen = _MAX_INT
if exact > 0:
self.maxLen = exact
self.minLen = exact
self.errmsg = "Expected " + self.name
self.mayReturnEmpty = self.minLen == 0
self.mayIndexError = False
def _generateDefaultName(self):
not_chars_str = _collapse_string_to_ranges(self.notChars)
if len(not_chars_str) > 16:
return "!W:({}...)".format(self.notChars[: 16 - 3])
else:
return "!W:({})".format(self.notChars)
def parseImpl(self, instring, loc, doActions=True):
notchars = self.notCharsSet
if instring[loc] in notchars:
raise ParseException(instring, loc, self.errmsg, self)
start = loc
loc += 1
maxlen = min(start + self.maxLen, len(instring))
while loc < maxlen and instring[loc] not in notchars:
loc += 1
if loc - start < self.minLen:
raise ParseException(instring, loc, self.errmsg, self)
return loc, instring[start:loc]
class White(Token):
"""Special matching class for matching whitespace. Normally,
whitespace is ignored by pyparsing grammars. This class is included
when some whitespace structures are significant. Define with
a string containing the whitespace characters to be matched; default
is ``" \\t\\r\\n"``. Also takes optional ``min``,
``max``, and ``exact`` arguments, as defined for the
:class:`Word` class.
"""
whiteStrs = {
" ": "<SP>",
"\t": "<TAB>",
"\n": "<LF>",
"\r": "<CR>",
"\f": "<FF>",
"\u00A0": "<NBSP>",
"\u1680": "<OGHAM_SPACE_MARK>",
"\u180E": "<MONGOLIAN_VOWEL_SEPARATOR>",
"\u2000": "<EN_QUAD>",
"\u2001": "<EM_QUAD>",
"\u2002": "<EN_SPACE>",
"\u2003": "<EM_SPACE>",
"\u2004": "<THREE-PER-EM_SPACE>",
"\u2005": "<FOUR-PER-EM_SPACE>",
"\u2006": "<SIX-PER-EM_SPACE>",
"\u2007": "<FIGURE_SPACE>",
"\u2008": "<PUNCTUATION_SPACE>",
"\u2009": "<THIN_SPACE>",
"\u200A": "<HAIR_SPACE>",
"\u200B": "<ZERO_WIDTH_SPACE>",
"\u202F": "<NNBSP>",
"\u205F": "<MMSP>",
"\u3000": "<IDEOGRAPHIC_SPACE>",
}
def __init__(self, ws: str = " \t\r\n", min: int = 1, max: int = 0, exact: int = 0):
super().__init__()
self.matchWhite = ws
self.set_whitespace_chars(
"".join(c for c in self.whiteStrs if c not in self.matchWhite),
copy_defaults=True,
)
# self.leave_whitespace()
self.mayReturnEmpty = True
self.errmsg = "Expected " + self.name
self.minLen = min
if max > 0:
self.maxLen = max
else:
self.maxLen = _MAX_INT
if exact > 0:
self.maxLen = exact
self.minLen = exact
def _generateDefaultName(self):
return "".join(White.whiteStrs[c] for c in self.matchWhite)
def parseImpl(self, instring, loc, doActions=True):
if instring[loc] not in self.matchWhite:
raise ParseException(instring, loc, self.errmsg, self)
start = loc
loc += 1
maxloc = start + self.maxLen
maxloc = min(maxloc, len(instring))
while loc < maxloc and instring[loc] in self.matchWhite:
loc += 1
if loc - start < self.minLen:
raise ParseException(instring, loc, self.errmsg, self)
return loc, instring[start:loc]
class PositionToken(Token):
def __init__(self):
super().__init__()
self.mayReturnEmpty = True
self.mayIndexError = False
class GoToColumn(PositionToken):
"""Token to advance to a specific column of input text; useful for
tabular report scraping.
"""
def __init__(self, colno: int):
super().__init__()
self.col = colno
def preParse(self, instring, loc):
if col(loc, instring) != self.col:
instrlen = len(instring)
if self.ignoreExprs:
loc = self._skipIgnorables(instring, loc)
while (
loc < instrlen
and instring[loc].isspace()
and col(loc, instring) != self.col
):
loc += 1
return loc
def parseImpl(self, instring, loc, doActions=True):
thiscol = col(loc, instring)
if thiscol > self.col:
raise ParseException(instring, loc, "Text not in expected column", self)
newloc = loc + self.col - thiscol
ret = instring[loc:newloc]
return newloc, ret
class LineStart(PositionToken):
r"""Matches if current position is at the beginning of a line within
the parse string
Example::
test = '''\
AAA this line
AAA and this line
AAA but not this one
B AAA and definitely not this one
'''
for t in (LineStart() + 'AAA' + restOfLine).search_string(test):
print(t)
prints::
['AAA', ' this line']
['AAA', ' and this line']
"""
def __init__(self):
super().__init__()
self.leave_whitespace()
self.orig_whiteChars = set() | self.whiteChars
self.whiteChars.discard("\n")
self.skipper = Empty().set_whitespace_chars(self.whiteChars)
self.errmsg = "Expected start of line"
def preParse(self, instring, loc):
if loc == 0:
return loc
else:
ret = self.skipper.preParse(instring, loc)
if "\n" in self.orig_whiteChars:
while instring[ret : ret + 1] == "\n":
ret = self.skipper.preParse(instring, ret + 1)
return ret
def parseImpl(self, instring, loc, doActions=True):
if col(loc, instring) == 1:
return loc, []
raise ParseException(instring, loc, self.errmsg, self)
class LineEnd(PositionToken):
"""Matches if current position is at the end of a line within the
parse string
"""
def __init__(self):
super().__init__()
self.whiteChars.discard("\n")
self.set_whitespace_chars(self.whiteChars, copy_defaults=False)
self.errmsg = "Expected end of line"
def parseImpl(self, instring, loc, doActions=True):
if loc < len(instring):
if instring[loc] == "\n":
return loc + 1, "\n"
else:
raise ParseException(instring, loc, self.errmsg, self)
elif loc == len(instring):
return loc + 1, []
else:
raise ParseException(instring, loc, self.errmsg, self)
class StringStart(PositionToken):
"""Matches if current position is at the beginning of the parse
string
"""
def __init__(self):
super().__init__()
self.errmsg = "Expected start of text"
def parseImpl(self, instring, loc, doActions=True):
if loc != 0:
# see if entire string up to here is just whitespace and ignoreables
if loc != self.preParse(instring, 0):
raise ParseException(instring, loc, self.errmsg, self)
return loc, []
class StringEnd(PositionToken):
"""
Matches if current position is at the end of the parse string
"""
def __init__(self):
super().__init__()
self.errmsg = "Expected end of text"
def parseImpl(self, instring, loc, doActions=True):
if loc < len(instring):
raise ParseException(instring, loc, self.errmsg, self)
elif loc == len(instring):
return loc + 1, []
elif loc > len(instring):
return loc, []
else:
raise ParseException(instring, loc, self.errmsg, self)
class WordStart(PositionToken):
"""Matches if the current position is at the beginning of a
:class:`Word`, and is not preceded by any character in a given
set of ``word_chars`` (default= ``printables``). To emulate the
``\b`` behavior of regular expressions, use
``WordStart(alphanums)``. ``WordStart`` will also match at
the beginning of the string being parsed, or at the beginning of
a line.
"""
def __init__(self, word_chars: str = printables, *, wordChars: str = printables):
wordChars = word_chars if wordChars == printables else wordChars
super().__init__()
self.wordChars = set(wordChars)
self.errmsg = "Not at the start of a word"
def parseImpl(self, instring, loc, doActions=True):
if loc != 0:
if (
instring[loc - 1] in self.wordChars
or instring[loc] not in self.wordChars
):
raise ParseException(instring, loc, self.errmsg, self)
return loc, []
class WordEnd(PositionToken):
"""Matches if the current position is at the end of a :class:`Word`,
and is not followed by any character in a given set of ``word_chars``
(default= ``printables``). To emulate the ``\b`` behavior of
regular expressions, use ``WordEnd(alphanums)``. ``WordEnd``
will also match at the end of the string being parsed, or at the end
of a line.
"""
def __init__(self, word_chars: str = printables, *, wordChars: str = printables):
wordChars = word_chars if wordChars == printables else wordChars
super().__init__()
self.wordChars = set(wordChars)
self.skipWhitespace = False
self.errmsg = "Not at the end of a word"
def parseImpl(self, instring, loc, doActions=True):
instrlen = len(instring)
if instrlen > 0 and loc < instrlen:
if (
instring[loc] in self.wordChars
or instring[loc - 1] not in self.wordChars
):
raise ParseException(instring, loc, self.errmsg, self)
return loc, []
class ParseExpression(ParserElement):
"""Abstract subclass of ParserElement, for combining and
post-processing parsed tokens.
"""
def __init__(self, exprs: typing.Iterable[ParserElement], savelist: bool = False):
super().__init__(savelist)
self.exprs: List[ParserElement]
if isinstance(exprs, _generatorType):
exprs = list(exprs)
if isinstance(exprs, str_type):
self.exprs = [self._literalStringClass(exprs)]
elif isinstance(exprs, ParserElement):
self.exprs = [exprs]
elif isinstance(exprs, Iterable):
exprs = list(exprs)
# if sequence of strings provided, wrap with Literal
if any(isinstance(expr, str_type) for expr in exprs):
exprs = (
self._literalStringClass(e) if isinstance(e, str_type) else e
for e in exprs
)
self.exprs = list(exprs)
else:
try:
self.exprs = list(exprs)
except TypeError:
self.exprs = [exprs]
self.callPreparse = False
def recurse(self) -> Sequence[ParserElement]:
return self.exprs[:]
def append(self, other) -> ParserElement:
self.exprs.append(other)
self._defaultName = None
return self
def leave_whitespace(self, recursive: bool = True) -> ParserElement:
"""
Extends ``leave_whitespace`` defined in base class, and also invokes ``leave_whitespace`` on
all contained expressions.
"""
super().leave_whitespace(recursive)
if recursive:
self.exprs = [e.copy() for e in self.exprs]
for e in self.exprs:
e.leave_whitespace(recursive)
return self
def ignore_whitespace(self, recursive: bool = True) -> ParserElement:
"""
Extends ``ignore_whitespace`` defined in base class, and also invokes ``leave_whitespace`` on
all contained expressions.
"""
super().ignore_whitespace(recursive)
if recursive:
self.exprs = [e.copy() for e in self.exprs]
for e in self.exprs:
e.ignore_whitespace(recursive)
return self
def ignore(self, other) -> ParserElement:
if isinstance(other, Suppress):
if other not in self.ignoreExprs:
super().ignore(other)
for e in self.exprs:
e.ignore(self.ignoreExprs[-1])
else:
super().ignore(other)
for e in self.exprs:
e.ignore(self.ignoreExprs[-1])
return self
def _generateDefaultName(self):
return "{}:({})".format(self.__class__.__name__, str(self.exprs))
def streamline(self) -> ParserElement:
if self.streamlined:
return self
super().streamline()
for e in self.exprs:
e.streamline()
# collapse nested :class:`And`'s of the form ``And(And(And(a, b), c), d)`` to ``And(a, b, c, d)``
# but only if there are no parse actions or resultsNames on the nested And's
# (likewise for :class:`Or`'s and :class:`MatchFirst`'s)
if len(self.exprs) == 2:
other = self.exprs[0]
if (
isinstance(other, self.__class__)
and not other.parseAction
and other.resultsName is None
and not other.debug
):
self.exprs = other.exprs[:] + [self.exprs[1]]
self._defaultName = None
self.mayReturnEmpty |= other.mayReturnEmpty
self.mayIndexError |= other.mayIndexError
other = self.exprs[-1]
if (
isinstance(other, self.__class__)
and not other.parseAction
and other.resultsName is None
and not other.debug
):
self.exprs = self.exprs[:-1] + other.exprs[:]
self._defaultName = None
self.mayReturnEmpty |= other.mayReturnEmpty
self.mayIndexError |= other.mayIndexError
self.errmsg = "Expected " + str(self)
return self
def validate(self, validateTrace=None) -> None:
tmp = (validateTrace if validateTrace is not None else [])[:] + [self]
for e in self.exprs:
e.validate(tmp)
self._checkRecursion([])
def copy(self) -> ParserElement:
ret = super().copy()
ret.exprs = [e.copy() for e in self.exprs]
return ret
def _setResultsName(self, name, listAllMatches=False):
if (
__diag__.warn_ungrouped_named_tokens_in_collection
and Diagnostics.warn_ungrouped_named_tokens_in_collection
not in self.suppress_warnings_
):
for e in self.exprs:
if (
isinstance(e, ParserElement)
and e.resultsName
and Diagnostics.warn_ungrouped_named_tokens_in_collection
not in e.suppress_warnings_
):
warnings.warn(
"{}: setting results name {!r} on {} expression "
"collides with {!r} on contained expression".format(
"warn_ungrouped_named_tokens_in_collection",
name,
type(self).__name__,
e.resultsName,
),
stacklevel=3,
)
return super()._setResultsName(name, listAllMatches)
ignoreWhitespace = ignore_whitespace
leaveWhitespace = leave_whitespace
class And(ParseExpression):
"""
Requires all given :class:`ParseExpression` s to be found in the given order.
Expressions may be separated by whitespace.
May be constructed using the ``'+'`` operator.
May also be constructed using the ``'-'`` operator, which will
suppress backtracking.
Example::
integer = Word(nums)
name_expr = Word(alphas)[1, ...]
expr = And([integer("id"), name_expr("name"), integer("age")])
# more easily written as:
expr = integer("id") + name_expr("name") + integer("age")
"""
class _ErrorStop(Empty):
def __init__(self, *args, **kwargs):
super().__init__(*args, **kwargs)
self.leave_whitespace()
def _generateDefaultName(self):
return "-"
def __init__(
self, exprs_arg: typing.Iterable[ParserElement], savelist: bool = True
):
exprs: List[ParserElement] = list(exprs_arg)
if exprs and Ellipsis in exprs:
tmp = []
for i, expr in enumerate(exprs):
if expr is Ellipsis:
if i < len(exprs) - 1:
skipto_arg: ParserElement = (Empty() + exprs[i + 1]).exprs[-1]
tmp.append(SkipTo(skipto_arg)("_skipped*"))
else:
raise Exception(
"cannot construct And with sequence ending in ..."
)
else:
tmp.append(expr)
exprs[:] = tmp
super().__init__(exprs, savelist)
if self.exprs:
self.mayReturnEmpty = all(e.mayReturnEmpty for e in self.exprs)
if not isinstance(self.exprs[0], White):
self.set_whitespace_chars(
self.exprs[0].whiteChars,
copy_defaults=self.exprs[0].copyDefaultWhiteChars,
)
self.skipWhitespace = self.exprs[0].skipWhitespace
else:
self.skipWhitespace = False
else:
self.mayReturnEmpty = True
self.callPreparse = True
def streamline(self) -> ParserElement:
# collapse any _PendingSkip's
if self.exprs:
if any(
isinstance(e, ParseExpression)
and e.exprs
and isinstance(e.exprs[-1], _PendingSkip)
for e in self.exprs[:-1]
):
for i, e in enumerate(self.exprs[:-1]):
if e is None:
continue
if (
isinstance(e, ParseExpression)
and e.exprs
and isinstance(e.exprs[-1], _PendingSkip)
):
e.exprs[-1] = e.exprs[-1] + self.exprs[i + 1]
self.exprs[i + 1] = None
self.exprs = [e for e in self.exprs if e is not None]
super().streamline()
# link any IndentedBlocks to the prior expression
for prev, cur in zip(self.exprs, self.exprs[1:]):
# traverse cur or any first embedded expr of cur looking for an IndentedBlock
# (but watch out for recursive grammar)
seen = set()
while cur:
if id(cur) in seen:
break
seen.add(id(cur))
if isinstance(cur, IndentedBlock):
prev.add_parse_action(
lambda s, l, t, cur_=cur: setattr(
cur_, "parent_anchor", col(l, s)
)
)
break
subs = cur.recurse()
cur = next(iter(subs), None)
self.mayReturnEmpty = all(e.mayReturnEmpty for e in self.exprs)
return self
def parseImpl(self, instring, loc, doActions=True):
# pass False as callPreParse arg to _parse for first element, since we already
# pre-parsed the string as part of our And pre-parsing
loc, resultlist = self.exprs[0]._parse(
instring, loc, doActions, callPreParse=False
)
errorStop = False
for e in self.exprs[1:]:
# if isinstance(e, And._ErrorStop):
if type(e) is And._ErrorStop:
errorStop = True
continue
if errorStop:
try:
loc, exprtokens = e._parse(instring, loc, doActions)
except ParseSyntaxException:
raise
except ParseBaseException as pe:
pe.__traceback__ = None
raise ParseSyntaxException._from_exception(pe)
except IndexError:
raise ParseSyntaxException(
instring, len(instring), self.errmsg, self
)
else:
loc, exprtokens = e._parse(instring, loc, doActions)
if exprtokens or exprtokens.haskeys():
resultlist += exprtokens
return loc, resultlist
def __iadd__(self, other):
if isinstance(other, str_type):
other = self._literalStringClass(other)
return self.append(other) # And([self, other])
def _checkRecursion(self, parseElementList):
subRecCheckList = parseElementList[:] + [self]
for e in self.exprs:
e._checkRecursion(subRecCheckList)
if not e.mayReturnEmpty:
break
def _generateDefaultName(self):
inner = " ".join(str(e) for e in self.exprs)
# strip off redundant inner {}'s
while len(inner) > 1 and inner[0 :: len(inner) - 1] == "{}":
inner = inner[1:-1]
return "{" + inner + "}"
class Or(ParseExpression):
"""Requires that at least one :class:`ParseExpression` is found. If
two expressions match, the expression that matches the longest
string will be used. May be constructed using the ``'^'``
operator.
Example::
# construct Or using '^' operator
number = Word(nums) ^ Combine(Word(nums) + '.' + Word(nums))
print(number.search_string("123 3.1416 789"))
prints::
[['123'], ['3.1416'], ['789']]
"""
def __init__(self, exprs: typing.Iterable[ParserElement], savelist: bool = False):
super().__init__(exprs, savelist)
if self.exprs:
self.mayReturnEmpty = any(e.mayReturnEmpty for e in self.exprs)
self.skipWhitespace = all(e.skipWhitespace for e in self.exprs)
else:
self.mayReturnEmpty = True
def streamline(self) -> ParserElement:
super().streamline()
if self.exprs:
self.mayReturnEmpty = any(e.mayReturnEmpty for e in self.exprs)
self.saveAsList = any(e.saveAsList for e in self.exprs)
self.skipWhitespace = all(
e.skipWhitespace and not isinstance(e, White) for e in self.exprs
)
else:
self.saveAsList = False
return self
def parseImpl(self, instring, loc, doActions=True):
maxExcLoc = -1
maxException = None
matches = []
fatals = []
if all(e.callPreparse for e in self.exprs):
loc = self.preParse(instring, loc)
for e in self.exprs:
try:
loc2 = e.try_parse(instring, loc, raise_fatal=True)
except ParseFatalException as pfe:
pfe.__traceback__ = None
pfe.parserElement = e
fatals.append(pfe)
maxException = None
maxExcLoc = -1
except ParseException as err:
if not fatals:
err.__traceback__ = None
if err.loc > maxExcLoc:
maxException = err
maxExcLoc = err.loc
except IndexError:
if len(instring) > maxExcLoc:
maxException = ParseException(
instring, len(instring), e.errmsg, self
)
maxExcLoc = len(instring)
else:
# save match among all matches, to retry longest to shortest
matches.append((loc2, e))
if matches:
# re-evaluate all matches in descending order of length of match, in case attached actions
# might change whether or how much they match of the input.
matches.sort(key=itemgetter(0), reverse=True)
if not doActions:
# no further conditions or parse actions to change the selection of
# alternative, so the first match will be the best match
best_expr = matches[0][1]
return best_expr._parse(instring, loc, doActions)
longest = -1, None
for loc1, expr1 in matches:
if loc1 <= longest[0]:
# already have a longer match than this one will deliver, we are done
return longest
try:
loc2, toks = expr1._parse(instring, loc, doActions)
except ParseException as err:
err.__traceback__ = None
if err.loc > maxExcLoc:
maxException = err
maxExcLoc = err.loc
else:
if loc2 >= loc1:
return loc2, toks
# didn't match as much as before
elif loc2 > longest[0]:
longest = loc2, toks
if longest != (-1, None):
return longest
if fatals:
if len(fatals) > 1:
fatals.sort(key=lambda e: -e.loc)
if fatals[0].loc == fatals[1].loc:
fatals.sort(key=lambda e: (-e.loc, -len(str(e.parserElement))))
max_fatal = fatals[0]
raise max_fatal
if maxException is not None:
maxException.msg = self.errmsg
raise maxException
else:
raise ParseException(
instring, loc, "no defined alternatives to match", self
)
def __ixor__(self, other):
if isinstance(other, str_type):
other = self._literalStringClass(other)
return self.append(other) # Or([self, other])
def _generateDefaultName(self):
return "{" + " ^ ".join(str(e) for e in self.exprs) + "}"
def _setResultsName(self, name, listAllMatches=False):
if (
__diag__.warn_multiple_tokens_in_named_alternation
and Diagnostics.warn_multiple_tokens_in_named_alternation
not in self.suppress_warnings_
):
if any(
isinstance(e, And)
and Diagnostics.warn_multiple_tokens_in_named_alternation
not in e.suppress_warnings_
for e in self.exprs
):
warnings.warn(
"{}: setting results name {!r} on {} expression "
"will return a list of all parsed tokens in an And alternative, "
"in prior versions only the first token was returned; enclose "
"contained argument in Group".format(
"warn_multiple_tokens_in_named_alternation",
name,
type(self).__name__,
),
stacklevel=3,
)
return super()._setResultsName(name, listAllMatches)
class MatchFirst(ParseExpression):
"""Requires that at least one :class:`ParseExpression` is found. If
more than one expression matches, the first one listed is the one that will
match. May be constructed using the ``'|'`` operator.
Example::
# construct MatchFirst using '|' operator
# watch the order of expressions to match
number = Word(nums) | Combine(Word(nums) + '.' + Word(nums))
print(number.search_string("123 3.1416 789")) # Fail! -> [['123'], ['3'], ['1416'], ['789']]
# put more selective expression first
number = Combine(Word(nums) + '.' + Word(nums)) | Word(nums)
print(number.search_string("123 3.1416 789")) # Better -> [['123'], ['3.1416'], ['789']]
"""
def __init__(self, exprs: typing.Iterable[ParserElement], savelist: bool = False):
super().__init__(exprs, savelist)
if self.exprs:
self.mayReturnEmpty = any(e.mayReturnEmpty for e in self.exprs)
self.skipWhitespace = all(e.skipWhitespace for e in self.exprs)
else:
self.mayReturnEmpty = True
def streamline(self) -> ParserElement:
if self.streamlined:
return self
super().streamline()
if self.exprs:
self.saveAsList = any(e.saveAsList for e in self.exprs)
self.mayReturnEmpty = any(e.mayReturnEmpty for e in self.exprs)
self.skipWhitespace = all(
e.skipWhitespace and not isinstance(e, White) for e in self.exprs
)
else:
self.saveAsList = False
self.mayReturnEmpty = True
return self
def parseImpl(self, instring, loc, doActions=True):
maxExcLoc = -1
maxException = None
for e in self.exprs:
try:
return e._parse(
instring,
loc,
doActions,
)
except ParseFatalException as pfe:
pfe.__traceback__ = None
pfe.parserElement = e
raise
except ParseException as err:
if err.loc > maxExcLoc:
maxException = err
maxExcLoc = err.loc
except IndexError:
if len(instring) > maxExcLoc:
maxException = ParseException(
instring, len(instring), e.errmsg, self
)
maxExcLoc = len(instring)
if maxException is not None:
maxException.msg = self.errmsg
raise maxException
else:
raise ParseException(
instring, loc, "no defined alternatives to match", self
)
def __ior__(self, other):
if isinstance(other, str_type):
other = self._literalStringClass(other)
return self.append(other) # MatchFirst([self, other])
def _generateDefaultName(self):
return "{" + " | ".join(str(e) for e in self.exprs) + "}"
def _setResultsName(self, name, listAllMatches=False):
if (
__diag__.warn_multiple_tokens_in_named_alternation
and Diagnostics.warn_multiple_tokens_in_named_alternation
not in self.suppress_warnings_
):
if any(
isinstance(e, And)
and Diagnostics.warn_multiple_tokens_in_named_alternation
not in e.suppress_warnings_
for e in self.exprs
):
warnings.warn(
"{}: setting results name {!r} on {} expression "
"will return a list of all parsed tokens in an And alternative, "
"in prior versions only the first token was returned; enclose "
"contained argument in Group".format(
"warn_multiple_tokens_in_named_alternation",
name,
type(self).__name__,
),
stacklevel=3,
)
return super()._setResultsName(name, listAllMatches)
class Each(ParseExpression):
"""Requires all given :class:`ParseExpression` s to be found, but in
any order. Expressions may be separated by whitespace.
May be constructed using the ``'&'`` operator.
Example::
color = one_of("RED ORANGE YELLOW GREEN BLUE PURPLE BLACK WHITE BROWN")
shape_type = one_of("SQUARE CIRCLE TRIANGLE STAR HEXAGON OCTAGON")
integer = Word(nums)
shape_attr = "shape:" + shape_type("shape")
posn_attr = "posn:" + Group(integer("x") + ',' + integer("y"))("posn")
color_attr = "color:" + color("color")
size_attr = "size:" + integer("size")
# use Each (using operator '&') to accept attributes in any order
# (shape and posn are required, color and size are optional)
shape_spec = shape_attr & posn_attr & Opt(color_attr) & Opt(size_attr)
shape_spec.run_tests('''
shape: SQUARE color: BLACK posn: 100, 120
shape: CIRCLE size: 50 color: BLUE posn: 50,80
color:GREEN size:20 shape:TRIANGLE posn:20,40
'''
)
prints::
shape: SQUARE color: BLACK posn: 100, 120
['shape:', 'SQUARE', 'color:', 'BLACK', 'posn:', ['100', ',', '120']]
- color: BLACK
- posn: ['100', ',', '120']
- x: 100
- y: 120
- shape: SQUARE
shape: CIRCLE size: 50 color: BLUE posn: 50,80
['shape:', 'CIRCLE', 'size:', '50', 'color:', 'BLUE', 'posn:', ['50', ',', '80']]
- color: BLUE
- posn: ['50', ',', '80']
- x: 50
- y: 80
- shape: CIRCLE
- size: 50
color: GREEN size: 20 shape: TRIANGLE posn: 20,40
['color:', 'GREEN', 'size:', '20', 'shape:', 'TRIANGLE', 'posn:', ['20', ',', '40']]
- color: GREEN
- posn: ['20', ',', '40']
- x: 20
- y: 40
- shape: TRIANGLE
- size: 20
"""
def __init__(self, exprs: typing.Iterable[ParserElement], savelist: bool = True):
super().__init__(exprs, savelist)
if self.exprs:
self.mayReturnEmpty = all(e.mayReturnEmpty for e in self.exprs)
else:
self.mayReturnEmpty = True
self.skipWhitespace = True
self.initExprGroups = True
self.saveAsList = True
def streamline(self) -> ParserElement:
super().streamline()
if self.exprs:
self.mayReturnEmpty = all(e.mayReturnEmpty for e in self.exprs)
else:
self.mayReturnEmpty = True
return self
def parseImpl(self, instring, loc, doActions=True):
if self.initExprGroups:
self.opt1map = dict(
(id(e.expr), e) for e in self.exprs if isinstance(e, Opt)
)
opt1 = [e.expr for e in self.exprs if isinstance(e, Opt)]
opt2 = [
e
for e in self.exprs
if e.mayReturnEmpty and not isinstance(e, (Opt, Regex, ZeroOrMore))
]
self.optionals = opt1 + opt2
self.multioptionals = [
e.expr.set_results_name(e.resultsName, list_all_matches=True)
for e in self.exprs
if isinstance(e, _MultipleMatch)
]
self.multirequired = [
e.expr.set_results_name(e.resultsName, list_all_matches=True)
for e in self.exprs
if isinstance(e, OneOrMore)
]
self.required = [
e for e in self.exprs if not isinstance(e, (Opt, ZeroOrMore, OneOrMore))
]
self.required += self.multirequired
self.initExprGroups = False
tmpLoc = loc
tmpReqd = self.required[:]
tmpOpt = self.optionals[:]
multis = self.multioptionals[:]
matchOrder = []
keepMatching = True
failed = []
fatals = []
while keepMatching:
tmpExprs = tmpReqd + tmpOpt + multis
failed.clear()
fatals.clear()
for e in tmpExprs:
try:
tmpLoc = e.try_parse(instring, tmpLoc, raise_fatal=True)
except ParseFatalException as pfe:
pfe.__traceback__ = None
pfe.parserElement = e
fatals.append(pfe)
failed.append(e)
except ParseException:
failed.append(e)
else:
matchOrder.append(self.opt1map.get(id(e), e))
if e in tmpReqd:
tmpReqd.remove(e)
elif e in tmpOpt:
tmpOpt.remove(e)
if len(failed) == len(tmpExprs):
keepMatching = False
# look for any ParseFatalExceptions
if fatals:
if len(fatals) > 1:
fatals.sort(key=lambda e: -e.loc)
if fatals[0].loc == fatals[1].loc:
fatals.sort(key=lambda e: (-e.loc, -len(str(e.parserElement))))
max_fatal = fatals[0]
raise max_fatal
if tmpReqd:
missing = ", ".join([str(e) for e in tmpReqd])
raise ParseException(
instring,
loc,
"Missing one or more required elements ({})".format(missing),
)
# add any unmatched Opts, in case they have default values defined
matchOrder += [e for e in self.exprs if isinstance(e, Opt) and e.expr in tmpOpt]
total_results = ParseResults([])
for e in matchOrder:
loc, results = e._parse(instring, loc, doActions)
total_results += results
return loc, total_results
def _generateDefaultName(self):
return "{" + " & ".join(str(e) for e in self.exprs) + "}"
class ParseElementEnhance(ParserElement):
"""Abstract subclass of :class:`ParserElement`, for combining and
post-processing parsed tokens.
"""
def __init__(self, expr: Union[ParserElement, str], savelist: bool = False):
super().__init__(savelist)
if isinstance(expr, str_type):
if issubclass(self._literalStringClass, Token):
expr = self._literalStringClass(expr)
elif issubclass(type(self), self._literalStringClass):
expr = Literal(expr)
else:
expr = self._literalStringClass(Literal(expr))
self.expr = expr
if expr is not None:
self.mayIndexError = expr.mayIndexError
self.mayReturnEmpty = expr.mayReturnEmpty
self.set_whitespace_chars(
expr.whiteChars, copy_defaults=expr.copyDefaultWhiteChars
)
self.skipWhitespace = expr.skipWhitespace
self.saveAsList = expr.saveAsList
self.callPreparse = expr.callPreparse
self.ignoreExprs.extend(expr.ignoreExprs)
def recurse(self) -> Sequence[ParserElement]:
return [self.expr] if self.expr is not None else []
def parseImpl(self, instring, loc, doActions=True):
if self.expr is not None:
return self.expr._parse(instring, loc, doActions, callPreParse=False)
else:
raise ParseException(instring, loc, "No expression defined", self)
def leave_whitespace(self, recursive: bool = True) -> ParserElement:
super().leave_whitespace(recursive)
if recursive:
self.expr = self.expr.copy()
if self.expr is not None:
self.expr.leave_whitespace(recursive)
return self
def ignore_whitespace(self, recursive: bool = True) -> ParserElement:
super().ignore_whitespace(recursive)
if recursive:
self.expr = self.expr.copy()
if self.expr is not None:
self.expr.ignore_whitespace(recursive)
return self
def ignore(self, other) -> ParserElement:
if isinstance(other, Suppress):
if other not in self.ignoreExprs:
super().ignore(other)
if self.expr is not None:
self.expr.ignore(self.ignoreExprs[-1])
else:
super().ignore(other)
if self.expr is not None:
self.expr.ignore(self.ignoreExprs[-1])
return self
def streamline(self) -> ParserElement:
super().streamline()
if self.expr is not None:
self.expr.streamline()
return self
def _checkRecursion(self, parseElementList):
if self in parseElementList:
raise RecursiveGrammarException(parseElementList + [self])
subRecCheckList = parseElementList[:] + [self]
if self.expr is not None:
self.expr._checkRecursion(subRecCheckList)
def validate(self, validateTrace=None) -> None:
if validateTrace is None:
validateTrace = []
tmp = validateTrace[:] + [self]
if self.expr is not None:
self.expr.validate(tmp)
self._checkRecursion([])
def _generateDefaultName(self):
return "{}:({})".format(self.__class__.__name__, str(self.expr))
ignoreWhitespace = ignore_whitespace
leaveWhitespace = leave_whitespace
class IndentedBlock(ParseElementEnhance):
"""
Expression to match one or more expressions at a given indentation level.
Useful for parsing text where structure is implied by indentation (like Python source code).
"""
class _Indent(Empty):
def __init__(self, ref_col: int):
super().__init__()
self.errmsg = "expected indent at column {}".format(ref_col)
self.add_condition(lambda s, l, t: col(l, s) == ref_col)
class _IndentGreater(Empty):
def __init__(self, ref_col: int):
super().__init__()
self.errmsg = "expected indent at column greater than {}".format(ref_col)
self.add_condition(lambda s, l, t: col(l, s) > ref_col)
def __init__(
self, expr: ParserElement, *, recursive: bool = False, grouped: bool = True
):
super().__init__(expr, savelist=True)
# if recursive:
# raise NotImplementedError("IndentedBlock with recursive is not implemented")
self._recursive = recursive
self._grouped = grouped
self.parent_anchor = 1
def parseImpl(self, instring, loc, doActions=True):
# advance parse position to non-whitespace by using an Empty()
# this should be the column to be used for all subsequent indented lines
anchor_loc = Empty().preParse(instring, loc)
# see if self.expr matches at the current location - if not it will raise an exception
# and no further work is necessary
self.expr.try_parse(instring, anchor_loc, doActions)
indent_col = col(anchor_loc, instring)
peer_detect_expr = self._Indent(indent_col)
inner_expr = Empty() + peer_detect_expr + self.expr
if self._recursive:
sub_indent = self._IndentGreater(indent_col)
nested_block = IndentedBlock(
self.expr, recursive=self._recursive, grouped=self._grouped
)
nested_block.set_debug(self.debug)
nested_block.parent_anchor = indent_col
inner_expr += Opt(sub_indent + nested_block)
inner_expr.set_name(f"inner {hex(id(inner_expr))[-4:].upper()}@{indent_col}")
block = OneOrMore(inner_expr)
trailing_undent = self._Indent(self.parent_anchor) | StringEnd()
if self._grouped:
wrapper = Group
else:
wrapper = lambda expr: expr
return (wrapper(block) + Optional(trailing_undent)).parseImpl(
instring, anchor_loc, doActions
)
class AtStringStart(ParseElementEnhance):
"""Matches if expression matches at the beginning of the parse
string::
AtStringStart(Word(nums)).parse_string("123")
# prints ["123"]
AtStringStart(Word(nums)).parse_string(" 123")
# raises ParseException
"""
def __init__(self, expr: Union[ParserElement, str]):
super().__init__(expr)
self.callPreparse = False
def parseImpl(self, instring, loc, doActions=True):
if loc != 0:
raise ParseException(instring, loc, "not found at string start")
return super().parseImpl(instring, loc, doActions)
class AtLineStart(ParseElementEnhance):
r"""Matches if an expression matches at the beginning of a line within
the parse string
Example::
test = '''\
AAA this line
AAA and this line
AAA but not this one
B AAA and definitely not this one
'''
for t in (AtLineStart('AAA') + restOfLine).search_string(test):
print(t)
prints::
['AAA', ' this line']
['AAA', ' and this line']
"""
def __init__(self, expr: Union[ParserElement, str]):
super().__init__(expr)
self.callPreparse = False
def parseImpl(self, instring, loc, doActions=True):
if col(loc, instring) != 1:
raise ParseException(instring, loc, "not found at line start")
return super().parseImpl(instring, loc, doActions)
class FollowedBy(ParseElementEnhance):
"""Lookahead matching of the given parse expression.
``FollowedBy`` does *not* advance the parsing position within
the input string, it only verifies that the specified parse
expression matches at the current position. ``FollowedBy``
always returns a null token list. If any results names are defined
in the lookahead expression, those *will* be returned for access by
name.
Example::
# use FollowedBy to match a label only if it is followed by a ':'
data_word = Word(alphas)
label = data_word + FollowedBy(':')
attr_expr = Group(label + Suppress(':') + OneOrMore(data_word, stop_on=label).set_parse_action(' '.join))
attr_expr[1, ...].parse_string("shape: SQUARE color: BLACK posn: upper left").pprint()
prints::
[['shape', 'SQUARE'], ['color', 'BLACK'], ['posn', 'upper left']]
"""
def __init__(self, expr: Union[ParserElement, str]):
super().__init__(expr)
self.mayReturnEmpty = True
def parseImpl(self, instring, loc, doActions=True):
# by using self._expr.parse and deleting the contents of the returned ParseResults list
# we keep any named results that were defined in the FollowedBy expression
_, ret = self.expr._parse(instring, loc, doActions=doActions)
del ret[:]
return loc, ret
class PrecededBy(ParseElementEnhance):
"""Lookbehind matching of the given parse expression.
``PrecededBy`` does not advance the parsing position within the
input string, it only verifies that the specified parse expression
matches prior to the current position. ``PrecededBy`` always
returns a null token list, but if a results name is defined on the
given expression, it is returned.
Parameters:
- expr - expression that must match prior to the current parse
location
- retreat - (default= ``None``) - (int) maximum number of characters
to lookbehind prior to the current parse location
If the lookbehind expression is a string, :class:`Literal`,
:class:`Keyword`, or a :class:`Word` or :class:`CharsNotIn`
with a specified exact or maximum length, then the retreat
parameter is not required. Otherwise, retreat must be specified to
give a maximum number of characters to look back from
the current parse position for a lookbehind match.
Example::
# VB-style variable names with type prefixes
int_var = PrecededBy("#") + pyparsing_common.identifier
str_var = PrecededBy("$") + pyparsing_common.identifier
"""
def __init__(
self, expr: Union[ParserElement, str], retreat: typing.Optional[int] = None
):
super().__init__(expr)
self.expr = self.expr().leave_whitespace()
self.mayReturnEmpty = True
self.mayIndexError = False
self.exact = False
if isinstance(expr, str_type):
retreat = len(expr)
self.exact = True
elif isinstance(expr, (Literal, Keyword)):
retreat = expr.matchLen
self.exact = True
elif isinstance(expr, (Word, CharsNotIn)) and expr.maxLen != _MAX_INT:
retreat = expr.maxLen
self.exact = True
elif isinstance(expr, PositionToken):
retreat = 0
self.exact = True
self.retreat = retreat
self.errmsg = "not preceded by " + str(expr)
self.skipWhitespace = False
self.parseAction.append(lambda s, l, t: t.__delitem__(slice(None, None)))
def parseImpl(self, instring, loc=0, doActions=True):
if self.exact:
if loc < self.retreat:
raise ParseException(instring, loc, self.errmsg)
start = loc - self.retreat
_, ret = self.expr._parse(instring, start)
else:
# retreat specified a maximum lookbehind window, iterate
test_expr = self.expr + StringEnd()
instring_slice = instring[max(0, loc - self.retreat) : loc]
last_expr = ParseException(instring, loc, self.errmsg)
for offset in range(1, min(loc, self.retreat + 1) + 1):
try:
# print('trying', offset, instring_slice, repr(instring_slice[loc - offset:]))
_, ret = test_expr._parse(
instring_slice, len(instring_slice) - offset
)
except ParseBaseException as pbe:
last_expr = pbe
else:
break
else:
raise last_expr
return loc, ret
class Located(ParseElementEnhance):
"""
Decorates a returned token with its starting and ending
locations in the input string.
This helper adds the following results names:
- ``locn_start`` - location where matched expression begins
- ``locn_end`` - location where matched expression ends
- ``value`` - the actual parsed results
Be careful if the input text contains ``<TAB>`` characters, you
may want to call :class:`ParserElement.parse_with_tabs`
Example::
wd = Word(alphas)
for match in Located(wd).search_string("ljsdf123lksdjjf123lkkjj1222"):
print(match)
prints::
[0, ['ljsdf'], 5]
[8, ['lksdjjf'], 15]
[18, ['lkkjj'], 23]
"""
def parseImpl(self, instring, loc, doActions=True):
start = loc
loc, tokens = self.expr._parse(instring, start, doActions, callPreParse=False)
ret_tokens = ParseResults([start, tokens, loc])
ret_tokens["locn_start"] = start
ret_tokens["value"] = tokens
ret_tokens["locn_end"] = loc
if self.resultsName:
# must return as a list, so that the name will be attached to the complete group
return loc, [ret_tokens]
else:
return loc, ret_tokens
class NotAny(ParseElementEnhance):
"""
Lookahead to disallow matching with the given parse expression.
``NotAny`` does *not* advance the parsing position within the
input string, it only verifies that the specified parse expression
does *not* match at the current position. Also, ``NotAny`` does
*not* skip over leading whitespace. ``NotAny`` always returns
a null token list. May be constructed using the ``'~'`` operator.
Example::
AND, OR, NOT = map(CaselessKeyword, "AND OR NOT".split())
# take care not to mistake keywords for identifiers
ident = ~(AND | OR | NOT) + Word(alphas)
boolean_term = Opt(NOT) + ident
# very crude boolean expression - to support parenthesis groups and
# operation hierarchy, use infix_notation
boolean_expr = boolean_term + ((AND | OR) + boolean_term)[...]
# integers that are followed by "." are actually floats
integer = Word(nums) + ~Char(".")
"""
def __init__(self, expr: Union[ParserElement, str]):
super().__init__(expr)
# do NOT use self.leave_whitespace(), don't want to propagate to exprs
# self.leave_whitespace()
self.skipWhitespace = False
self.mayReturnEmpty = True
self.errmsg = "Found unwanted token, " + str(self.expr)
def parseImpl(self, instring, loc, doActions=True):
if self.expr.can_parse_next(instring, loc):
raise ParseException(instring, loc, self.errmsg, self)
return loc, []
def _generateDefaultName(self):
return "~{" + str(self.expr) + "}"
class _MultipleMatch(ParseElementEnhance):
def __init__(
self,
expr: ParserElement,
stop_on: typing.Optional[Union[ParserElement, str]] = None,
*,
stopOn: typing.Optional[Union[ParserElement, str]] = None,
):
super().__init__(expr)
stopOn = stopOn or stop_on
self.saveAsList = True
ender = stopOn
if isinstance(ender, str_type):
ender = self._literalStringClass(ender)
self.stopOn(ender)
def stopOn(self, ender) -> ParserElement:
if isinstance(ender, str_type):
ender = self._literalStringClass(ender)
self.not_ender = ~ender if ender is not None else None
return self
def parseImpl(self, instring, loc, doActions=True):
self_expr_parse = self.expr._parse
self_skip_ignorables = self._skipIgnorables
check_ender = self.not_ender is not None
if check_ender:
try_not_ender = self.not_ender.tryParse
# must be at least one (but first see if we are the stopOn sentinel;
# if so, fail)
if check_ender:
try_not_ender(instring, loc)
loc, tokens = self_expr_parse(instring, loc, doActions)
try:
hasIgnoreExprs = not not self.ignoreExprs
while 1:
if check_ender:
try_not_ender(instring, loc)
if hasIgnoreExprs:
preloc = self_skip_ignorables(instring, loc)
else:
preloc = loc
loc, tmptokens = self_expr_parse(instring, preloc, doActions)
if tmptokens or tmptokens.haskeys():
tokens += tmptokens
except (ParseException, IndexError):
pass
return loc, tokens
def _setResultsName(self, name, listAllMatches=False):
if (
__diag__.warn_ungrouped_named_tokens_in_collection
and Diagnostics.warn_ungrouped_named_tokens_in_collection
not in self.suppress_warnings_
):
for e in [self.expr] + self.expr.recurse():
if (
isinstance(e, ParserElement)
and e.resultsName
and Diagnostics.warn_ungrouped_named_tokens_in_collection
not in e.suppress_warnings_
):
warnings.warn(
"{}: setting results name {!r} on {} expression "
"collides with {!r} on contained expression".format(
"warn_ungrouped_named_tokens_in_collection",
name,
type(self).__name__,
e.resultsName,
),
stacklevel=3,
)
return super()._setResultsName(name, listAllMatches)
class OneOrMore(_MultipleMatch):
"""
Repetition of one or more of the given expression.
Parameters:
- expr - expression that must match one or more times
- stop_on - (default= ``None``) - expression for a terminating sentinel
(only required if the sentinel would ordinarily match the repetition
expression)
Example::
data_word = Word(alphas)
label = data_word + FollowedBy(':')
attr_expr = Group(label + Suppress(':') + OneOrMore(data_word).set_parse_action(' '.join))
text = "shape: SQUARE posn: upper left color: BLACK"
attr_expr[1, ...].parse_string(text).pprint() # Fail! read 'color' as data instead of next label -> [['shape', 'SQUARE color']]
# use stop_on attribute for OneOrMore to avoid reading label string as part of the data
attr_expr = Group(label + Suppress(':') + OneOrMore(data_word, stop_on=label).set_parse_action(' '.join))
OneOrMore(attr_expr).parse_string(text).pprint() # Better -> [['shape', 'SQUARE'], ['posn', 'upper left'], ['color', 'BLACK']]
# could also be written as
(attr_expr * (1,)).parse_string(text).pprint()
"""
def _generateDefaultName(self):
return "{" + str(self.expr) + "}..."
class ZeroOrMore(_MultipleMatch):
"""
Optional repetition of zero or more of the given expression.
Parameters:
- ``expr`` - expression that must match zero or more times
- ``stop_on`` - expression for a terminating sentinel
(only required if the sentinel would ordinarily match the repetition
expression) - (default= ``None``)
Example: similar to :class:`OneOrMore`
"""
def __init__(
self,
expr: ParserElement,
stop_on: typing.Optional[Union[ParserElement, str]] = None,
*,
stopOn: typing.Optional[Union[ParserElement, str]] = None,
):
super().__init__(expr, stopOn=stopOn or stop_on)
self.mayReturnEmpty = True
def parseImpl(self, instring, loc, doActions=True):
try:
return super().parseImpl(instring, loc, doActions)
except (ParseException, IndexError):
return loc, ParseResults([], name=self.resultsName)
def _generateDefaultName(self):
return "[" + str(self.expr) + "]..."
class _NullToken:
def __bool__(self):
return False
def __str__(self):
return ""
class Opt(ParseElementEnhance):
"""
Optional matching of the given expression.
Parameters:
- ``expr`` - expression that must match zero or more times
- ``default`` (optional) - value to be returned if the optional expression is not found.
Example::
# US postal code can be a 5-digit zip, plus optional 4-digit qualifier
zip = Combine(Word(nums, exact=5) + Opt('-' + Word(nums, exact=4)))
zip.run_tests('''
# traditional ZIP code
12345
# ZIP+4 form
12101-0001
# invalid ZIP
98765-
''')
prints::
# traditional ZIP code
12345
['12345']
# ZIP+4 form
12101-0001
['12101-0001']
# invalid ZIP
98765-
^
FAIL: Expected end of text (at char 5), (line:1, col:6)
"""
__optionalNotMatched = _NullToken()
def __init__(
self, expr: Union[ParserElement, str], default: Any = __optionalNotMatched
):
super().__init__(expr, savelist=False)
self.saveAsList = self.expr.saveAsList
self.defaultValue = default
self.mayReturnEmpty = True
def parseImpl(self, instring, loc, doActions=True):
self_expr = self.expr
try:
loc, tokens = self_expr._parse(instring, loc, doActions, callPreParse=False)
except (ParseException, IndexError):
default_value = self.defaultValue
if default_value is not self.__optionalNotMatched:
if self_expr.resultsName:
tokens = ParseResults([default_value])
tokens[self_expr.resultsName] = default_value
else:
tokens = [default_value]
else:
tokens = []
return loc, tokens
def _generateDefaultName(self):
inner = str(self.expr)
# strip off redundant inner {}'s
while len(inner) > 1 and inner[0 :: len(inner) - 1] == "{}":
inner = inner[1:-1]
return "[" + inner + "]"
Optional = Opt
class SkipTo(ParseElementEnhance):
"""
Token for skipping over all undefined text until the matched
expression is found.
Parameters:
- ``expr`` - target expression marking the end of the data to be skipped
- ``include`` - if ``True``, the target expression is also parsed
(the skipped text and target expression are returned as a 2-element
list) (default= ``False``).
- ``ignore`` - (default= ``None``) used to define grammars (typically quoted strings and
comments) that might contain false matches to the target expression
- ``fail_on`` - (default= ``None``) define expressions that are not allowed to be
included in the skipped test; if found before the target expression is found,
the :class:`SkipTo` is not a match
Example::
report = '''
Outstanding Issues Report - 1 Jan 2000
# | Severity | Description | Days Open
-----+----------+-------------------------------------------+-----------
101 | Critical | Intermittent system crash | 6
94 | Cosmetic | Spelling error on Login ('log|n') | 14
79 | Minor | System slow when running too many reports | 47
'''
integer = Word(nums)
SEP = Suppress('|')
# use SkipTo to simply match everything up until the next SEP
# - ignore quoted strings, so that a '|' character inside a quoted string does not match
# - parse action will call token.strip() for each matched token, i.e., the description body
string_data = SkipTo(SEP, ignore=quoted_string)
string_data.set_parse_action(token_map(str.strip))
ticket_expr = (integer("issue_num") + SEP
+ string_data("sev") + SEP
+ string_data("desc") + SEP
+ integer("days_open"))
for tkt in ticket_expr.search_string(report):
print tkt.dump()
prints::
['101', 'Critical', 'Intermittent system crash', '6']
- days_open: '6'
- desc: 'Intermittent system crash'
- issue_num: '101'
- sev: 'Critical'
['94', 'Cosmetic', "Spelling error on Login ('log|n')", '14']
- days_open: '14'
- desc: "Spelling error on Login ('log|n')"
- issue_num: '94'
- sev: 'Cosmetic'
['79', 'Minor', 'System slow when running too many reports', '47']
- days_open: '47'
- desc: 'System slow when running too many reports'
- issue_num: '79'
- sev: 'Minor'
"""
def __init__(
self,
other: Union[ParserElement, str],
include: bool = False,
ignore: bool = None,
fail_on: typing.Optional[Union[ParserElement, str]] = None,
*,
failOn: Union[ParserElement, str] = None,
):
super().__init__(other)
failOn = failOn or fail_on
self.ignoreExpr = ignore
self.mayReturnEmpty = True
self.mayIndexError = False
self.includeMatch = include
self.saveAsList = False
if isinstance(failOn, str_type):
self.failOn = self._literalStringClass(failOn)
else:
self.failOn = failOn
self.errmsg = "No match found for " + str(self.expr)
def parseImpl(self, instring, loc, doActions=True):
startloc = loc
instrlen = len(instring)
self_expr_parse = self.expr._parse
self_failOn_canParseNext = (
self.failOn.canParseNext if self.failOn is not None else None
)
self_ignoreExpr_tryParse = (
self.ignoreExpr.tryParse if self.ignoreExpr is not None else None
)
tmploc = loc
while tmploc <= instrlen:
if self_failOn_canParseNext is not None:
# break if failOn expression matches
if self_failOn_canParseNext(instring, tmploc):
break
if self_ignoreExpr_tryParse is not None:
# advance past ignore expressions
while 1:
try:
tmploc = self_ignoreExpr_tryParse(instring, tmploc)
except ParseBaseException:
break
try:
self_expr_parse(instring, tmploc, doActions=False, callPreParse=False)
except (ParseException, IndexError):
# no match, advance loc in string
tmploc += 1
else:
# matched skipto expr, done
break
else:
# ran off the end of the input string without matching skipto expr, fail
raise ParseException(instring, loc, self.errmsg, self)
# build up return values
loc = tmploc
skiptext = instring[startloc:loc]
skipresult = ParseResults(skiptext)
if self.includeMatch:
loc, mat = self_expr_parse(instring, loc, doActions, callPreParse=False)
skipresult += mat
return loc, skipresult
class Forward(ParseElementEnhance):
"""
Forward declaration of an expression to be defined later -
used for recursive grammars, such as algebraic infix notation.
When the expression is known, it is assigned to the ``Forward``
variable using the ``'<<'`` operator.
Note: take care when assigning to ``Forward`` not to overlook
precedence of operators.
Specifically, ``'|'`` has a lower precedence than ``'<<'``, so that::
fwd_expr << a | b | c
will actually be evaluated as::
(fwd_expr << a) | b | c
thereby leaving b and c out as parseable alternatives. It is recommended that you
explicitly group the values inserted into the ``Forward``::
fwd_expr << (a | b | c)
Converting to use the ``'<<='`` operator instead will avoid this problem.
See :class:`ParseResults.pprint` for an example of a recursive
parser created using ``Forward``.
"""
def __init__(self, other: typing.Optional[Union[ParserElement, str]] = None):
self.caller_frame = traceback.extract_stack(limit=2)[0]
super().__init__(other, savelist=False)
self.lshift_line = None
def __lshift__(self, other):
if hasattr(self, "caller_frame"):
del self.caller_frame
if isinstance(other, str_type):
other = self._literalStringClass(other)
self.expr = other
self.mayIndexError = self.expr.mayIndexError
self.mayReturnEmpty = self.expr.mayReturnEmpty
self.set_whitespace_chars(
self.expr.whiteChars, copy_defaults=self.expr.copyDefaultWhiteChars
)
self.skipWhitespace = self.expr.skipWhitespace
self.saveAsList = self.expr.saveAsList
self.ignoreExprs.extend(self.expr.ignoreExprs)
self.lshift_line = traceback.extract_stack(limit=2)[-2]
return self
def __ilshift__(self, other):
return self << other
def __or__(self, other):
caller_line = traceback.extract_stack(limit=2)[-2]
if (
__diag__.warn_on_match_first_with_lshift_operator
and caller_line == self.lshift_line
and Diagnostics.warn_on_match_first_with_lshift_operator
not in self.suppress_warnings_
):
warnings.warn(
"using '<<' operator with '|' is probably an error, use '<<='",
stacklevel=2,
)
ret = super().__or__(other)
return ret
def __del__(self):
# see if we are getting dropped because of '=' reassignment of var instead of '<<=' or '<<'
if (
self.expr is None
and __diag__.warn_on_assignment_to_Forward
and Diagnostics.warn_on_assignment_to_Forward not in self.suppress_warnings_
):
warnings.warn_explicit(
"Forward defined here but no expression attached later using '<<=' or '<<'",
UserWarning,
filename=self.caller_frame.filename,
lineno=self.caller_frame.lineno,
)
def parseImpl(self, instring, loc, doActions=True):
if (
self.expr is None
and __diag__.warn_on_parse_using_empty_Forward
and Diagnostics.warn_on_parse_using_empty_Forward
not in self.suppress_warnings_
):
# walk stack until parse_string, scan_string, search_string, or transform_string is found
parse_fns = [
"parse_string",
"scan_string",
"search_string",
"transform_string",
]
tb = traceback.extract_stack(limit=200)
for i, frm in enumerate(reversed(tb), start=1):
if frm.name in parse_fns:
stacklevel = i + 1
break
else:
stacklevel = 2
warnings.warn(
"Forward expression was never assigned a value, will not parse any input",
stacklevel=stacklevel,
)
if not ParserElement._left_recursion_enabled:
return super().parseImpl(instring, loc, doActions)
# ## Bounded Recursion algorithm ##
# Recursion only needs to be processed at ``Forward`` elements, since they are
# the only ones that can actually refer to themselves. The general idea is
# to handle recursion stepwise: We start at no recursion, then recurse once,
# recurse twice, ..., until more recursion offers no benefit (we hit the bound).
#
# The "trick" here is that each ``Forward`` gets evaluated in two contexts
# - to *match* a specific recursion level, and
# - to *search* the bounded recursion level
# and the two run concurrently. The *search* must *match* each recursion level
# to find the best possible match. This is handled by a memo table, which
# provides the previous match to the next level match attempt.
#
# See also "Left Recursion in Parsing Expression Grammars", Medeiros et al.
#
# There is a complication since we not only *parse* but also *transform* via
# actions: We do not want to run the actions too often while expanding. Thus,
# we expand using `doActions=False` and only run `doActions=True` if the next
# recursion level is acceptable.
with ParserElement.recursion_lock:
memo = ParserElement.recursion_memos
try:
# we are parsing at a specific recursion expansion - use it as-is
prev_loc, prev_result = memo[loc, self, doActions]
if isinstance(prev_result, Exception):
raise prev_result
return prev_loc, prev_result.copy()
except KeyError:
act_key = (loc, self, True)
peek_key = (loc, self, False)
# we are searching for the best recursion expansion - keep on improving
# both `doActions` cases must be tracked separately here!
prev_loc, prev_peek = memo[peek_key] = (
loc - 1,
ParseException(
instring, loc, "Forward recursion without base case", self
),
)
if doActions:
memo[act_key] = memo[peek_key]
while True:
try:
new_loc, new_peek = super().parseImpl(instring, loc, False)
except ParseException:
# we failed before getting any match – do not hide the error
if isinstance(prev_peek, Exception):
raise
new_loc, new_peek = prev_loc, prev_peek
# the match did not get better: we are done
if new_loc <= prev_loc:
if doActions:
# replace the match for doActions=False as well,
# in case the action did backtrack
prev_loc, prev_result = memo[peek_key] = memo[act_key]
del memo[peek_key], memo[act_key]
return prev_loc, prev_result.copy()
del memo[peek_key]
return prev_loc, prev_peek.copy()
# the match did get better: see if we can improve further
else:
if doActions:
try:
memo[act_key] = super().parseImpl(instring, loc, True)
except ParseException as e:
memo[peek_key] = memo[act_key] = (new_loc, e)
raise
prev_loc, prev_peek = memo[peek_key] = new_loc, new_peek
def leave_whitespace(self, recursive: bool = True) -> ParserElement:
self.skipWhitespace = False
return self
def ignore_whitespace(self, recursive: bool = True) -> ParserElement:
self.skipWhitespace = True
return self
def streamline(self) -> ParserElement:
if not self.streamlined:
self.streamlined = True
if self.expr is not None:
self.expr.streamline()
return self
def validate(self, validateTrace=None) -> None:
if validateTrace is None:
validateTrace = []
if self not in validateTrace:
tmp = validateTrace[:] + [self]
if self.expr is not None:
self.expr.validate(tmp)
self._checkRecursion([])
def _generateDefaultName(self):
# Avoid infinite recursion by setting a temporary _defaultName
self._defaultName = ": ..."
# Use the string representation of main expression.
retString = "..."
try:
if self.expr is not None:
retString = str(self.expr)[:1000]
else:
retString = "None"
finally:
return self.__class__.__name__ + ": " + retString
def copy(self) -> ParserElement:
if self.expr is not None:
return super().copy()
else:
ret = Forward()
ret <<= self
return ret
def _setResultsName(self, name, list_all_matches=False):
if (
__diag__.warn_name_set_on_empty_Forward
and Diagnostics.warn_name_set_on_empty_Forward
not in self.suppress_warnings_
):
if self.expr is None:
warnings.warn(
"{}: setting results name {!r} on {} expression "
"that has no contained expression".format(
"warn_name_set_on_empty_Forward", name, type(self).__name__
),
stacklevel=3,
)
return super()._setResultsName(name, list_all_matches)
ignoreWhitespace = ignore_whitespace
leaveWhitespace = leave_whitespace
class TokenConverter(ParseElementEnhance):
"""
Abstract subclass of :class:`ParseExpression`, for converting parsed results.
"""
def __init__(self, expr: Union[ParserElement, str], savelist=False):
super().__init__(expr) # , savelist)
self.saveAsList = False
class Combine(TokenConverter):
"""Converter to concatenate all matching tokens to a single string.
By default, the matching patterns must also be contiguous in the
input string; this can be disabled by specifying
``'adjacent=False'`` in the constructor.
Example::
real = Word(nums) + '.' + Word(nums)
print(real.parse_string('3.1416')) # -> ['3', '.', '1416']
# will also erroneously match the following
print(real.parse_string('3. 1416')) # -> ['3', '.', '1416']
real = Combine(Word(nums) + '.' + Word(nums))
print(real.parse_string('3.1416')) # -> ['3.1416']
# no match when there are internal spaces
print(real.parse_string('3. 1416')) # -> Exception: Expected W:(0123...)
"""
def __init__(
self,
expr: ParserElement,
join_string: str = "",
adjacent: bool = True,
*,
joinString: typing.Optional[str] = None,
):
super().__init__(expr)
joinString = joinString if joinString is not None else join_string
# suppress whitespace-stripping in contained parse expressions, but re-enable it on the Combine itself
if adjacent:
self.leave_whitespace()
self.adjacent = adjacent
self.skipWhitespace = True
self.joinString = joinString
self.callPreparse = True
def ignore(self, other) -> ParserElement:
if self.adjacent:
ParserElement.ignore(self, other)
else:
super().ignore(other)
return self
def postParse(self, instring, loc, tokenlist):
retToks = tokenlist.copy()
del retToks[:]
retToks += ParseResults(
["".join(tokenlist._asStringList(self.joinString))], modal=self.modalResults
)
if self.resultsName and retToks.haskeys():
return [retToks]
else:
return retToks
class Group(TokenConverter):
"""Converter to return the matched tokens as a list - useful for
returning tokens of :class:`ZeroOrMore` and :class:`OneOrMore` expressions.
The optional ``aslist`` argument when set to True will return the
parsed tokens as a Python list instead of a pyparsing ParseResults.
Example::
ident = Word(alphas)
num = Word(nums)
term = ident | num
func = ident + Opt(delimited_list(term))
print(func.parse_string("fn a, b, 100"))
# -> ['fn', 'a', 'b', '100']
func = ident + Group(Opt(delimited_list(term)))
print(func.parse_string("fn a, b, 100"))
# -> ['fn', ['a', 'b', '100']]
"""
def __init__(self, expr: ParserElement, aslist: bool = False):
super().__init__(expr)
self.saveAsList = True
self._asPythonList = aslist
def postParse(self, instring, loc, tokenlist):
if self._asPythonList:
return ParseResults.List(
tokenlist.asList()
if isinstance(tokenlist, ParseResults)
else list(tokenlist)
)
else:
return [tokenlist]
class Dict(TokenConverter):
"""Converter to return a repetitive expression as a list, but also
as a dictionary. Each element can also be referenced using the first
token in the expression as its key. Useful for tabular report
scraping when the first column can be used as a item key.
The optional ``asdict`` argument when set to True will return the
parsed tokens as a Python dict instead of a pyparsing ParseResults.
Example::
data_word = Word(alphas)
label = data_word + FollowedBy(':')
text = "shape: SQUARE posn: upper left color: light blue texture: burlap"
attr_expr = (label + Suppress(':') + OneOrMore(data_word, stop_on=label).set_parse_action(' '.join))
# print attributes as plain groups
print(attr_expr[1, ...].parse_string(text).dump())
# instead of OneOrMore(expr), parse using Dict(Group(expr)[1, ...]) - Dict will auto-assign names
result = Dict(Group(attr_expr)[1, ...]).parse_string(text)
print(result.dump())
# access named fields as dict entries, or output as dict
print(result['shape'])
print(result.as_dict())
prints::
['shape', 'SQUARE', 'posn', 'upper left', 'color', 'light blue', 'texture', 'burlap']
[['shape', 'SQUARE'], ['posn', 'upper left'], ['color', 'light blue'], ['texture', 'burlap']]
- color: 'light blue'
- posn: 'upper left'
- shape: 'SQUARE'
- texture: 'burlap'
SQUARE
{'color': 'light blue', 'posn': 'upper left', 'texture': 'burlap', 'shape': 'SQUARE'}
See more examples at :class:`ParseResults` of accessing fields by results name.
"""
def __init__(self, expr: ParserElement, asdict: bool = False):
super().__init__(expr)
self.saveAsList = True
self._asPythonDict = asdict
def postParse(self, instring, loc, tokenlist):
for i, tok in enumerate(tokenlist):
if len(tok) == 0:
continue
ikey = tok[0]
if isinstance(ikey, int):
ikey = str(ikey).strip()
if len(tok) == 1:
tokenlist[ikey] = _ParseResultsWithOffset("", i)
elif len(tok) == 2 and not isinstance(tok[1], ParseResults):
tokenlist[ikey] = _ParseResultsWithOffset(tok[1], i)
else:
try:
dictvalue = tok.copy() # ParseResults(i)
except Exception:
exc = TypeError(
"could not extract dict values from parsed results"
" - Dict expression must contain Grouped expressions"
)
raise exc from None
del dictvalue[0]
if len(dictvalue) != 1 or (
isinstance(dictvalue, ParseResults) and dictvalue.haskeys()
):
tokenlist[ikey] = _ParseResultsWithOffset(dictvalue, i)
else:
tokenlist[ikey] = _ParseResultsWithOffset(dictvalue[0], i)
if self._asPythonDict:
return [tokenlist.as_dict()] if self.resultsName else tokenlist.as_dict()
else:
return [tokenlist] if self.resultsName else tokenlist
class Suppress(TokenConverter):
"""Converter for ignoring the results of a parsed expression.
Example::
source = "a, b, c,d"
wd = Word(alphas)
wd_list1 = wd + (',' + wd)[...]
print(wd_list1.parse_string(source))
# often, delimiters that are useful during parsing are just in the
# way afterward - use Suppress to keep them out of the parsed output
wd_list2 = wd + (Suppress(',') + wd)[...]
print(wd_list2.parse_string(source))
# Skipped text (using '...') can be suppressed as well
source = "lead in START relevant text END trailing text"
start_marker = Keyword("START")
end_marker = Keyword("END")
find_body = Suppress(...) + start_marker + ... + end_marker
print(find_body.parse_string(source)
prints::
['a', ',', 'b', ',', 'c', ',', 'd']
['a', 'b', 'c', 'd']
['START', 'relevant text ', 'END']
(See also :class:`delimited_list`.)
"""
def __init__(self, expr: Union[ParserElement, str], savelist: bool = False):
if expr is ...:
expr = _PendingSkip(NoMatch())
super().__init__(expr)
def __add__(self, other) -> "ParserElement":
if isinstance(self.expr, _PendingSkip):
return Suppress(SkipTo(other)) + other
else:
return super().__add__(other)
def __sub__(self, other) -> "ParserElement":
if isinstance(self.expr, _PendingSkip):
return Suppress(SkipTo(other)) - other
else:
return super().__sub__(other)
def postParse(self, instring, loc, tokenlist):
return []
def suppress(self) -> ParserElement:
return self
def trace_parse_action(f: ParseAction) -> ParseAction:
"""Decorator for debugging parse actions.
When the parse action is called, this decorator will print
``">> entering method-name(line:<current_source_line>, <parse_location>, <matched_tokens>)"``.
When the parse action completes, the decorator will print
``"<<"`` followed by the returned value, or any exception that the parse action raised.
Example::
wd = Word(alphas)
@trace_parse_action
def remove_duplicate_chars(tokens):
return ''.join(sorted(set(''.join(tokens))))
wds = wd[1, ...].set_parse_action(remove_duplicate_chars)
print(wds.parse_string("slkdjs sld sldd sdlf sdljf"))
prints::
>>entering remove_duplicate_chars(line: 'slkdjs sld sldd sdlf sdljf', 0, (['slkdjs', 'sld', 'sldd', 'sdlf', 'sdljf'], {}))
<<leaving remove_duplicate_chars (ret: 'dfjkls')
['dfjkls']
"""
f = _trim_arity(f)
def z(*paArgs):
thisFunc = f.__name__
s, l, t = paArgs[-3:]
if len(paArgs) > 3:
thisFunc = paArgs[0].__class__.__name__ + "." + thisFunc
sys.stderr.write(
">>entering {}(line: {!r}, {}, {!r})\n".format(thisFunc, line(l, s), l, t)
)
try:
ret = f(*paArgs)
except Exception as exc:
sys.stderr.write("<<leaving {} (exception: {})\n".format(thisFunc, exc))
raise
sys.stderr.write("<<leaving {} (ret: {!r})\n".format(thisFunc, ret))
return ret
z.__name__ = f.__name__
return z
# convenience constants for positional expressions
empty = Empty().set_name("empty")
line_start = LineStart().set_name("line_start")
line_end = LineEnd().set_name("line_end")
string_start = StringStart().set_name("string_start")
string_end = StringEnd().set_name("string_end")
_escapedPunc = Word(_bslash, r"\[]-*.$+^?()~ ", exact=2).set_parse_action(
lambda s, l, t: t[0][1]
)
_escapedHexChar = Regex(r"\\0?[xX][0-9a-fA-F]+").set_parse_action(
lambda s, l, t: chr(int(t[0].lstrip(r"\0x"), 16))
)
_escapedOctChar = Regex(r"\\0[0-7]+").set_parse_action(
lambda s, l, t: chr(int(t[0][1:], 8))
)
_singleChar = (
_escapedPunc | _escapedHexChar | _escapedOctChar | CharsNotIn(r"\]", exact=1)
)
_charRange = Group(_singleChar + Suppress("-") + _singleChar)
_reBracketExpr = (
Literal("[")
+ Opt("^").set_results_name("negate")
+ Group(OneOrMore(_charRange | _singleChar)).set_results_name("body")
+ "]"
)
def srange(s: str) -> str:
r"""Helper to easily define string ranges for use in :class:`Word`
construction. Borrows syntax from regexp ``'[]'`` string range
definitions::
srange("[0-9]") -> "0123456789"
srange("[a-z]") -> "abcdefghijklmnopqrstuvwxyz"
srange("[a-z$_]") -> "abcdefghijklmnopqrstuvwxyz$_"
The input string must be enclosed in []'s, and the returned string
is the expanded character set joined into a single string. The
values enclosed in the []'s may be:
- a single character
- an escaped character with a leading backslash (such as ``\-``
or ``\]``)
- an escaped hex character with a leading ``'\x'``
(``\x21``, which is a ``'!'`` character) (``\0x##``
is also supported for backwards compatibility)
- an escaped octal character with a leading ``'\0'``
(``\041``, which is a ``'!'`` character)
- a range of any of the above, separated by a dash (``'a-z'``,
etc.)
- any combination of the above (``'aeiouy'``,
``'a-zA-Z0-9_$'``, etc.)
"""
_expanded = (
lambda p: p
if not isinstance(p, ParseResults)
else "".join(chr(c) for c in range(ord(p[0]), ord(p[1]) + 1))
)
try:
return "".join(_expanded(part) for part in _reBracketExpr.parse_string(s).body)
except Exception:
return ""
def token_map(func, *args) -> ParseAction:
"""Helper to define a parse action by mapping a function to all
elements of a :class:`ParseResults` list. If any additional args are passed,
they are forwarded to the given function as additional arguments
after the token, as in
``hex_integer = Word(hexnums).set_parse_action(token_map(int, 16))``,
which will convert the parsed data to an integer using base 16.
Example (compare the last to example in :class:`ParserElement.transform_string`::
hex_ints = Word(hexnums)[1, ...].set_parse_action(token_map(int, 16))
hex_ints.run_tests('''
00 11 22 aa FF 0a 0d 1a
''')
upperword = Word(alphas).set_parse_action(token_map(str.upper))
upperword[1, ...].run_tests('''
my kingdom for a horse
''')
wd = Word(alphas).set_parse_action(token_map(str.title))
wd[1, ...].set_parse_action(' '.join).run_tests('''
now is the winter of our discontent made glorious summer by this sun of york
''')
prints::
00 11 22 aa FF 0a 0d 1a
[0, 17, 34, 170, 255, 10, 13, 26]
my kingdom for a horse
['MY', 'KINGDOM', 'FOR', 'A', 'HORSE']
now is the winter of our discontent made glorious summer by this sun of york
['Now Is The Winter Of Our Discontent Made Glorious Summer By This Sun Of York']
"""
def pa(s, l, t):
return [func(tokn, *args) for tokn in t]
func_name = getattr(func, "__name__", getattr(func, "__class__").__name__)
pa.__name__ = func_name
return pa
def autoname_elements() -> None:
"""
Utility to simplify mass-naming of parser elements, for
generating railroad diagram with named subdiagrams.
"""
for name, var in sys._getframe().f_back.f_locals.items():
if isinstance(var, ParserElement) and not var.customName:
var.set_name(name)
dbl_quoted_string = Combine(
Regex(r'"(?:[^"\n\r\\]|(?:"")|(?:\\(?:[^x]|x[0-9a-fA-F]+)))*') + '"'
).set_name("string enclosed in double quotes")
sgl_quoted_string = Combine(
Regex(r"'(?:[^'\n\r\\]|(?:'')|(?:\\(?:[^x]|x[0-9a-fA-F]+)))*") + "'"
).set_name("string enclosed in single quotes")
quoted_string = Combine(
Regex(r'"(?:[^"\n\r\\]|(?:"")|(?:\\(?:[^x]|x[0-9a-fA-F]+)))*') + '"'
| Regex(r"'(?:[^'\n\r\\]|(?:'')|(?:\\(?:[^x]|x[0-9a-fA-F]+)))*") + "'"
).set_name("quotedString using single or double quotes")
unicode_string = Combine("u" + quoted_string.copy()).set_name("unicode string literal")
alphas8bit = srange(r"[\0xc0-\0xd6\0xd8-\0xf6\0xf8-\0xff]")
punc8bit = srange(r"[\0xa1-\0xbf\0xd7\0xf7]")
# build list of built-in expressions, for future reference if a global default value
# gets updated
_builtin_exprs: List[ParserElement] = [
v for v in vars().values() if isinstance(v, ParserElement)
]
# backward compatibility names
tokenMap = token_map
conditionAsParseAction = condition_as_parse_action
nullDebugAction = null_debug_action
sglQuotedString = sgl_quoted_string
dblQuotedString = dbl_quoted_string
quotedString = quoted_string
unicodeString = unicode_string
lineStart = line_start
lineEnd = line_end
stringStart = string_start
stringEnd = string_end
traceParseAction = trace_parse_action
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/pyparsing/core.py
|
Python
|
mit
| 213,310 |
import railroad
import pyparsing
import typing
from typing import (
List,
NamedTuple,
Generic,
TypeVar,
Dict,
Callable,
Set,
Iterable,
)
from jinja2 import Template
from io import StringIO
import inspect
jinja2_template_source = """\
<!DOCTYPE html>
<html>
<head>
{% if not head %}
<style type="text/css">
.railroad-heading {
font-family: monospace;
}
</style>
{% else %}
{{ head | safe }}
{% endif %}
</head>
<body>
{{ body | safe }}
{% for diagram in diagrams %}
<div class="railroad-group">
<h1 class="railroad-heading">{{ diagram.title }}</h1>
<div class="railroad-description">{{ diagram.text }}</div>
<div class="railroad-svg">
{{ diagram.svg }}
</div>
</div>
{% endfor %}
</body>
</html>
"""
template = Template(jinja2_template_source)
# Note: ideally this would be a dataclass, but we're supporting Python 3.5+ so we can't do this yet
NamedDiagram = NamedTuple(
"NamedDiagram",
[("name", str), ("diagram", typing.Optional[railroad.DiagramItem]), ("index", int)],
)
"""
A simple structure for associating a name with a railroad diagram
"""
T = TypeVar("T")
class EachItem(railroad.Group):
"""
Custom railroad item to compose a:
- Group containing a
- OneOrMore containing a
- Choice of the elements in the Each
with the group label indicating that all must be matched
"""
all_label = "[ALL]"
def __init__(self, *items):
choice_item = railroad.Choice(len(items) - 1, *items)
one_or_more_item = railroad.OneOrMore(item=choice_item)
super().__init__(one_or_more_item, label=self.all_label)
class AnnotatedItem(railroad.Group):
"""
Simple subclass of Group that creates an annotation label
"""
def __init__(self, label: str, item):
super().__init__(item=item, label="[{}]".format(label) if label else label)
class EditablePartial(Generic[T]):
"""
Acts like a functools.partial, but can be edited. In other words, it represents a type that hasn't yet been
constructed.
"""
# We need this here because the railroad constructors actually transform the data, so can't be called until the
# entire tree is assembled
def __init__(self, func: Callable[..., T], args: list, kwargs: dict):
self.func = func
self.args = args
self.kwargs = kwargs
@classmethod
def from_call(cls, func: Callable[..., T], *args, **kwargs) -> "EditablePartial[T]":
"""
If you call this function in the same way that you would call the constructor, it will store the arguments
as you expect. For example EditablePartial.from_call(Fraction, 1, 3)() == Fraction(1, 3)
"""
return EditablePartial(func=func, args=list(args), kwargs=kwargs)
@property
def name(self):
return self.kwargs["name"]
def __call__(self) -> T:
"""
Evaluate the partial and return the result
"""
args = self.args.copy()
kwargs = self.kwargs.copy()
# This is a helpful hack to allow you to specify varargs parameters (e.g. *args) as keyword args (e.g.
# args=['list', 'of', 'things'])
arg_spec = inspect.getfullargspec(self.func)
if arg_spec.varargs in self.kwargs:
args += kwargs.pop(arg_spec.varargs)
return self.func(*args, **kwargs)
def railroad_to_html(diagrams: List[NamedDiagram], **kwargs) -> str:
"""
Given a list of NamedDiagram, produce a single HTML string that visualises those diagrams
:params kwargs: kwargs to be passed in to the template
"""
data = []
for diagram in diagrams:
if diagram.diagram is None:
continue
io = StringIO()
diagram.diagram.writeSvg(io.write)
title = diagram.name
if diagram.index == 0:
title += " (root)"
data.append({"title": title, "text": "", "svg": io.getvalue()})
return template.render(diagrams=data, **kwargs)
def resolve_partial(partial: "EditablePartial[T]") -> T:
"""
Recursively resolves a collection of Partials into whatever type they are
"""
if isinstance(partial, EditablePartial):
partial.args = resolve_partial(partial.args)
partial.kwargs = resolve_partial(partial.kwargs)
return partial()
elif isinstance(partial, list):
return [resolve_partial(x) for x in partial]
elif isinstance(partial, dict):
return {key: resolve_partial(x) for key, x in partial.items()}
else:
return partial
def to_railroad(
element: pyparsing.ParserElement,
diagram_kwargs: typing.Optional[dict] = None,
vertical: int = 3,
show_results_names: bool = False,
show_groups: bool = False,
) -> List[NamedDiagram]:
"""
Convert a pyparsing element tree into a list of diagrams. This is the recommended entrypoint to diagram
creation if you want to access the Railroad tree before it is converted to HTML
:param element: base element of the parser being diagrammed
:param diagram_kwargs: kwargs to pass to the Diagram() constructor
:param vertical: (optional) - int - limit at which number of alternatives should be
shown vertically instead of horizontally
:param show_results_names - bool to indicate whether results name annotations should be
included in the diagram
:param show_groups - bool to indicate whether groups should be highlighted with an unlabeled
surrounding box
"""
# Convert the whole tree underneath the root
lookup = ConverterState(diagram_kwargs=diagram_kwargs or {})
_to_diagram_element(
element,
lookup=lookup,
parent=None,
vertical=vertical,
show_results_names=show_results_names,
show_groups=show_groups,
)
root_id = id(element)
# Convert the root if it hasn't been already
if root_id in lookup:
if not element.customName:
lookup[root_id].name = ""
lookup[root_id].mark_for_extraction(root_id, lookup, force=True)
# Now that we're finished, we can convert from intermediate structures into Railroad elements
diags = list(lookup.diagrams.values())
if len(diags) > 1:
# collapse out duplicate diags with the same name
seen = set()
deduped_diags = []
for d in diags:
# don't extract SkipTo elements, they are uninformative as subdiagrams
if d.name == "...":
continue
if d.name is not None and d.name not in seen:
seen.add(d.name)
deduped_diags.append(d)
resolved = [resolve_partial(partial) for partial in deduped_diags]
else:
# special case - if just one diagram, always display it, even if
# it has no name
resolved = [resolve_partial(partial) for partial in diags]
return sorted(resolved, key=lambda diag: diag.index)
def _should_vertical(
specification: int, exprs: Iterable[pyparsing.ParserElement]
) -> bool:
"""
Returns true if we should return a vertical list of elements
"""
if specification is None:
return False
else:
return len(_visible_exprs(exprs)) >= specification
class ElementState:
"""
State recorded for an individual pyparsing Element
"""
# Note: this should be a dataclass, but we have to support Python 3.5
def __init__(
self,
element: pyparsing.ParserElement,
converted: EditablePartial,
parent: EditablePartial,
number: int,
name: str = None,
parent_index: typing.Optional[int] = None,
):
#: The pyparsing element that this represents
self.element: pyparsing.ParserElement = element
#: The name of the element
self.name: typing.Optional[str] = name
#: The output Railroad element in an unconverted state
self.converted: EditablePartial = converted
#: The parent Railroad element, which we store so that we can extract this if it's duplicated
self.parent: EditablePartial = parent
#: The order in which we found this element, used for sorting diagrams if this is extracted into a diagram
self.number: int = number
#: The index of this inside its parent
self.parent_index: typing.Optional[int] = parent_index
#: If true, we should extract this out into a subdiagram
self.extract: bool = False
#: If true, all of this element's children have been filled out
self.complete: bool = False
def mark_for_extraction(
self, el_id: int, state: "ConverterState", name: str = None, force: bool = False
):
"""
Called when this instance has been seen twice, and thus should eventually be extracted into a sub-diagram
:param el_id: id of the element
:param state: element/diagram state tracker
:param name: name to use for this element's text
:param force: If true, force extraction now, regardless of the state of this. Only useful for extracting the
root element when we know we're finished
"""
self.extract = True
# Set the name
if not self.name:
if name:
# Allow forcing a custom name
self.name = name
elif self.element.customName:
self.name = self.element.customName
else:
self.name = ""
# Just because this is marked for extraction doesn't mean we can do it yet. We may have to wait for children
# to be added
# Also, if this is just a string literal etc, don't bother extracting it
if force or (self.complete and _worth_extracting(self.element)):
state.extract_into_diagram(el_id)
class ConverterState:
"""
Stores some state that persists between recursions into the element tree
"""
def __init__(self, diagram_kwargs: typing.Optional[dict] = None):
#: A dictionary mapping ParserElements to state relating to them
self._element_diagram_states: Dict[int, ElementState] = {}
#: A dictionary mapping ParserElement IDs to subdiagrams generated from them
self.diagrams: Dict[int, EditablePartial[NamedDiagram]] = {}
#: The index of the next unnamed element
self.unnamed_index: int = 1
#: The index of the next element. This is used for sorting
self.index: int = 0
#: Shared kwargs that are used to customize the construction of diagrams
self.diagram_kwargs: dict = diagram_kwargs or {}
self.extracted_diagram_names: Set[str] = set()
def __setitem__(self, key: int, value: ElementState):
self._element_diagram_states[key] = value
def __getitem__(self, key: int) -> ElementState:
return self._element_diagram_states[key]
def __delitem__(self, key: int):
del self._element_diagram_states[key]
def __contains__(self, key: int):
return key in self._element_diagram_states
def generate_unnamed(self) -> int:
"""
Generate a number used in the name of an otherwise unnamed diagram
"""
self.unnamed_index += 1
return self.unnamed_index
def generate_index(self) -> int:
"""
Generate a number used to index a diagram
"""
self.index += 1
return self.index
def extract_into_diagram(self, el_id: int):
"""
Used when we encounter the same token twice in the same tree. When this
happens, we replace all instances of that token with a terminal, and
create a new subdiagram for the token
"""
position = self[el_id]
# Replace the original definition of this element with a regular block
if position.parent:
ret = EditablePartial.from_call(railroad.NonTerminal, text=position.name)
if "item" in position.parent.kwargs:
position.parent.kwargs["item"] = ret
elif "items" in position.parent.kwargs:
position.parent.kwargs["items"][position.parent_index] = ret
# If the element we're extracting is a group, skip to its content but keep the title
if position.converted.func == railroad.Group:
content = position.converted.kwargs["item"]
else:
content = position.converted
self.diagrams[el_id] = EditablePartial.from_call(
NamedDiagram,
name=position.name,
diagram=EditablePartial.from_call(
railroad.Diagram, content, **self.diagram_kwargs
),
index=position.number,
)
del self[el_id]
def _worth_extracting(element: pyparsing.ParserElement) -> bool:
"""
Returns true if this element is worth having its own sub-diagram. Simply, if any of its children
themselves have children, then its complex enough to extract
"""
children = element.recurse()
return any(child.recurse() for child in children)
def _apply_diagram_item_enhancements(fn):
"""
decorator to ensure enhancements to a diagram item (such as results name annotations)
get applied on return from _to_diagram_element (we do this since there are several
returns in _to_diagram_element)
"""
def _inner(
element: pyparsing.ParserElement,
parent: typing.Optional[EditablePartial],
lookup: ConverterState = None,
vertical: int = None,
index: int = 0,
name_hint: str = None,
show_results_names: bool = False,
show_groups: bool = False,
) -> typing.Optional[EditablePartial]:
ret = fn(
element,
parent,
lookup,
vertical,
index,
name_hint,
show_results_names,
show_groups,
)
# apply annotation for results name, if present
if show_results_names and ret is not None:
element_results_name = element.resultsName
if element_results_name:
# add "*" to indicate if this is a "list all results" name
element_results_name += "" if element.modalResults else "*"
ret = EditablePartial.from_call(
railroad.Group, item=ret, label=element_results_name
)
return ret
return _inner
def _visible_exprs(exprs: Iterable[pyparsing.ParserElement]):
non_diagramming_exprs = (
pyparsing.ParseElementEnhance,
pyparsing.PositionToken,
pyparsing.And._ErrorStop,
)
return [
e
for e in exprs
if not (e.customName or e.resultsName or isinstance(e, non_diagramming_exprs))
]
@_apply_diagram_item_enhancements
def _to_diagram_element(
element: pyparsing.ParserElement,
parent: typing.Optional[EditablePartial],
lookup: ConverterState = None,
vertical: int = None,
index: int = 0,
name_hint: str = None,
show_results_names: bool = False,
show_groups: bool = False,
) -> typing.Optional[EditablePartial]:
"""
Recursively converts a PyParsing Element to a railroad Element
:param lookup: The shared converter state that keeps track of useful things
:param index: The index of this element within the parent
:param parent: The parent of this element in the output tree
:param vertical: Controls at what point we make a list of elements vertical. If this is an integer (the default),
it sets the threshold of the number of items before we go vertical. If True, always go vertical, if False, never
do so
:param name_hint: If provided, this will override the generated name
:param show_results_names: bool flag indicating whether to add annotations for results names
:returns: The converted version of the input element, but as a Partial that hasn't yet been constructed
:param show_groups: bool flag indicating whether to show groups using bounding box
"""
exprs = element.recurse()
name = name_hint or element.customName or element.__class__.__name__
# Python's id() is used to provide a unique identifier for elements
el_id = id(element)
element_results_name = element.resultsName
# Here we basically bypass processing certain wrapper elements if they contribute nothing to the diagram
if not element.customName:
if isinstance(
element,
(
# pyparsing.TokenConverter,
# pyparsing.Forward,
pyparsing.Located,
),
):
# However, if this element has a useful custom name, and its child does not, we can pass it on to the child
if exprs:
if not exprs[0].customName:
propagated_name = name
else:
propagated_name = None
return _to_diagram_element(
element.expr,
parent=parent,
lookup=lookup,
vertical=vertical,
index=index,
name_hint=propagated_name,
show_results_names=show_results_names,
show_groups=show_groups,
)
# If the element isn't worth extracting, we always treat it as the first time we say it
if _worth_extracting(element):
if el_id in lookup:
# If we've seen this element exactly once before, we are only just now finding out that it's a duplicate,
# so we have to extract it into a new diagram.
looked_up = lookup[el_id]
looked_up.mark_for_extraction(el_id, lookup, name=name_hint)
ret = EditablePartial.from_call(railroad.NonTerminal, text=looked_up.name)
return ret
elif el_id in lookup.diagrams:
# If we have seen the element at least twice before, and have already extracted it into a subdiagram, we
# just put in a marker element that refers to the sub-diagram
ret = EditablePartial.from_call(
railroad.NonTerminal, text=lookup.diagrams[el_id].kwargs["name"]
)
return ret
# Recursively convert child elements
# Here we find the most relevant Railroad element for matching pyparsing Element
# We use ``items=[]`` here to hold the place for where the child elements will go once created
if isinstance(element, pyparsing.And):
# detect And's created with ``expr*N`` notation - for these use a OneOrMore with a repeat
# (all will have the same name, and resultsName)
if not exprs:
return None
if len(set((e.name, e.resultsName) for e in exprs)) == 1:
ret = EditablePartial.from_call(
railroad.OneOrMore, item="", repeat=str(len(exprs))
)
elif _should_vertical(vertical, exprs):
ret = EditablePartial.from_call(railroad.Stack, items=[])
else:
ret = EditablePartial.from_call(railroad.Sequence, items=[])
elif isinstance(element, (pyparsing.Or, pyparsing.MatchFirst)):
if not exprs:
return None
if _should_vertical(vertical, exprs):
ret = EditablePartial.from_call(railroad.Choice, 0, items=[])
else:
ret = EditablePartial.from_call(railroad.HorizontalChoice, items=[])
elif isinstance(element, pyparsing.Each):
if not exprs:
return None
ret = EditablePartial.from_call(EachItem, items=[])
elif isinstance(element, pyparsing.NotAny):
ret = EditablePartial.from_call(AnnotatedItem, label="NOT", item="")
elif isinstance(element, pyparsing.FollowedBy):
ret = EditablePartial.from_call(AnnotatedItem, label="LOOKAHEAD", item="")
elif isinstance(element, pyparsing.PrecededBy):
ret = EditablePartial.from_call(AnnotatedItem, label="LOOKBEHIND", item="")
elif isinstance(element, pyparsing.Group):
if show_groups:
ret = EditablePartial.from_call(AnnotatedItem, label="", item="")
else:
ret = EditablePartial.from_call(railroad.Group, label="", item="")
elif isinstance(element, pyparsing.TokenConverter):
ret = EditablePartial.from_call(
AnnotatedItem, label=type(element).__name__.lower(), item=""
)
elif isinstance(element, pyparsing.Opt):
ret = EditablePartial.from_call(railroad.Optional, item="")
elif isinstance(element, pyparsing.OneOrMore):
ret = EditablePartial.from_call(railroad.OneOrMore, item="")
elif isinstance(element, pyparsing.ZeroOrMore):
ret = EditablePartial.from_call(railroad.ZeroOrMore, item="")
elif isinstance(element, pyparsing.Group):
ret = EditablePartial.from_call(
railroad.Group, item=None, label=element_results_name
)
elif isinstance(element, pyparsing.Empty) and not element.customName:
# Skip unnamed "Empty" elements
ret = None
elif len(exprs) > 1:
ret = EditablePartial.from_call(railroad.Sequence, items=[])
elif len(exprs) > 0 and not element_results_name:
ret = EditablePartial.from_call(railroad.Group, item="", label=name)
else:
terminal = EditablePartial.from_call(railroad.Terminal, element.defaultName)
ret = terminal
if ret is None:
return
# Indicate this element's position in the tree so we can extract it if necessary
lookup[el_id] = ElementState(
element=element,
converted=ret,
parent=parent,
parent_index=index,
number=lookup.generate_index(),
)
if element.customName:
lookup[el_id].mark_for_extraction(el_id, lookup, element.customName)
i = 0
for expr in exprs:
# Add a placeholder index in case we have to extract the child before we even add it to the parent
if "items" in ret.kwargs:
ret.kwargs["items"].insert(i, None)
item = _to_diagram_element(
expr,
parent=ret,
lookup=lookup,
vertical=vertical,
index=i,
show_results_names=show_results_names,
show_groups=show_groups,
)
# Some elements don't need to be shown in the diagram
if item is not None:
if "item" in ret.kwargs:
ret.kwargs["item"] = item
elif "items" in ret.kwargs:
# If we've already extracted the child, don't touch this index, since it's occupied by a nonterminal
ret.kwargs["items"][i] = item
i += 1
elif "items" in ret.kwargs:
# If we're supposed to skip this element, remove it from the parent
del ret.kwargs["items"][i]
# If all this items children are none, skip this item
if ret and (
("items" in ret.kwargs and len(ret.kwargs["items"]) == 0)
or ("item" in ret.kwargs and ret.kwargs["item"] is None)
):
ret = EditablePartial.from_call(railroad.Terminal, name)
# Mark this element as "complete", ie it has all of its children
if el_id in lookup:
lookup[el_id].complete = True
if el_id in lookup and lookup[el_id].extract and lookup[el_id].complete:
lookup.extract_into_diagram(el_id)
if ret is not None:
ret = EditablePartial.from_call(
railroad.NonTerminal, text=lookup.diagrams[el_id].kwargs["name"]
)
return ret
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/pyparsing/diagram/__init__.py
|
Python
|
mit
| 23,668 |
# exceptions.py
import re
import sys
import typing
from .util import col, line, lineno, _collapse_string_to_ranges
from .unicode import pyparsing_unicode as ppu
class ExceptionWordUnicode(ppu.Latin1, ppu.LatinA, ppu.LatinB, ppu.Greek, ppu.Cyrillic):
pass
_extract_alphanums = _collapse_string_to_ranges(ExceptionWordUnicode.alphanums)
_exception_word_extractor = re.compile("([" + _extract_alphanums + "]{1,16})|.")
class ParseBaseException(Exception):
"""base exception class for all parsing runtime exceptions"""
# Performance tuning: we construct a *lot* of these, so keep this
# constructor as small and fast as possible
def __init__(
self,
pstr: str,
loc: int = 0,
msg: typing.Optional[str] = None,
elem=None,
):
self.loc = loc
if msg is None:
self.msg = pstr
self.pstr = ""
else:
self.msg = msg
self.pstr = pstr
self.parser_element = self.parserElement = elem
self.args = (pstr, loc, msg)
@staticmethod
def explain_exception(exc, depth=16):
"""
Method to take an exception and translate the Python internal traceback into a list
of the pyparsing expressions that caused the exception to be raised.
Parameters:
- exc - exception raised during parsing (need not be a ParseException, in support
of Python exceptions that might be raised in a parse action)
- depth (default=16) - number of levels back in the stack trace to list expression
and function names; if None, the full stack trace names will be listed; if 0, only
the failing input line, marker, and exception string will be shown
Returns a multi-line string listing the ParserElements and/or function names in the
exception's stack trace.
"""
import inspect
from .core import ParserElement
if depth is None:
depth = sys.getrecursionlimit()
ret = []
if isinstance(exc, ParseBaseException):
ret.append(exc.line)
ret.append(" " * (exc.column - 1) + "^")
ret.append("{}: {}".format(type(exc).__name__, exc))
if depth > 0:
callers = inspect.getinnerframes(exc.__traceback__, context=depth)
seen = set()
for i, ff in enumerate(callers[-depth:]):
frm = ff[0]
f_self = frm.f_locals.get("self", None)
if isinstance(f_self, ParserElement):
if frm.f_code.co_name not in ("parseImpl", "_parseNoCache"):
continue
if id(f_self) in seen:
continue
seen.add(id(f_self))
self_type = type(f_self)
ret.append(
"{}.{} - {}".format(
self_type.__module__, self_type.__name__, f_self
)
)
elif f_self is not None:
self_type = type(f_self)
ret.append("{}.{}".format(self_type.__module__, self_type.__name__))
else:
code = frm.f_code
if code.co_name in ("wrapper", "<module>"):
continue
ret.append("{}".format(code.co_name))
depth -= 1
if not depth:
break
return "\n".join(ret)
@classmethod
def _from_exception(cls, pe):
"""
internal factory method to simplify creating one type of ParseException
from another - avoids having __init__ signature conflicts among subclasses
"""
return cls(pe.pstr, pe.loc, pe.msg, pe.parserElement)
@property
def line(self) -> str:
"""
Return the line of text where the exception occurred.
"""
return line(self.loc, self.pstr)
@property
def lineno(self) -> int:
"""
Return the 1-based line number of text where the exception occurred.
"""
return lineno(self.loc, self.pstr)
@property
def col(self) -> int:
"""
Return the 1-based column on the line of text where the exception occurred.
"""
return col(self.loc, self.pstr)
@property
def column(self) -> int:
"""
Return the 1-based column on the line of text where the exception occurred.
"""
return col(self.loc, self.pstr)
def __str__(self) -> str:
if self.pstr:
if self.loc >= len(self.pstr):
foundstr = ", found end of text"
else:
# pull out next word at error location
found_match = _exception_word_extractor.match(self.pstr, self.loc)
if found_match is not None:
found = found_match.group(0)
else:
found = self.pstr[self.loc : self.loc + 1]
foundstr = (", found %r" % found).replace(r"\\", "\\")
else:
foundstr = ""
return "{}{} (at char {}), (line:{}, col:{})".format(
self.msg, foundstr, self.loc, self.lineno, self.column
)
def __repr__(self):
return str(self)
def mark_input_line(self, marker_string: str = None, *, markerString=">!<") -> str:
"""
Extracts the exception line from the input string, and marks
the location of the exception with a special symbol.
"""
markerString = marker_string if marker_string is not None else markerString
line_str = self.line
line_column = self.column - 1
if markerString:
line_str = "".join(
(line_str[:line_column], markerString, line_str[line_column:])
)
return line_str.strip()
def explain(self, depth=16) -> str:
"""
Method to translate the Python internal traceback into a list
of the pyparsing expressions that caused the exception to be raised.
Parameters:
- depth (default=16) - number of levels back in the stack trace to list expression
and function names; if None, the full stack trace names will be listed; if 0, only
the failing input line, marker, and exception string will be shown
Returns a multi-line string listing the ParserElements and/or function names in the
exception's stack trace.
Example::
expr = pp.Word(pp.nums) * 3
try:
expr.parse_string("123 456 A789")
except pp.ParseException as pe:
print(pe.explain(depth=0))
prints::
123 456 A789
^
ParseException: Expected W:(0-9), found 'A' (at char 8), (line:1, col:9)
Note: the diagnostic output will include string representations of the expressions
that failed to parse. These representations will be more helpful if you use `set_name` to
give identifiable names to your expressions. Otherwise they will use the default string
forms, which may be cryptic to read.
Note: pyparsing's default truncation of exception tracebacks may also truncate the
stack of expressions that are displayed in the ``explain`` output. To get the full listing
of parser expressions, you may have to set ``ParserElement.verbose_stacktrace = True``
"""
return self.explain_exception(self, depth)
markInputline = mark_input_line
class ParseException(ParseBaseException):
"""
Exception thrown when a parse expression doesn't match the input string
Example::
try:
Word(nums).set_name("integer").parse_string("ABC")
except ParseException as pe:
print(pe)
print("column: {}".format(pe.column))
prints::
Expected integer (at char 0), (line:1, col:1)
column: 1
"""
class ParseFatalException(ParseBaseException):
"""
User-throwable exception thrown when inconsistent parse content
is found; stops all parsing immediately
"""
class ParseSyntaxException(ParseFatalException):
"""
Just like :class:`ParseFatalException`, but thrown internally
when an :class:`ErrorStop<And._ErrorStop>` ('-' operator) indicates
that parsing is to stop immediately because an unbacktrackable
syntax error has been found.
"""
class RecursiveGrammarException(Exception):
"""
Exception thrown by :class:`ParserElement.validate` if the
grammar could be left-recursive; parser may need to enable
left recursion using :class:`ParserElement.enable_left_recursion<ParserElement.enable_left_recursion>`
"""
def __init__(self, parseElementList):
self.parseElementTrace = parseElementList
def __str__(self) -> str:
return "RecursiveGrammarException: {}".format(self.parseElementTrace)
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/pyparsing/exceptions.py
|
Python
|
mit
| 9,023 |
# helpers.py
import html.entities
import re
import typing
from . import __diag__
from .core import *
from .util import _bslash, _flatten, _escape_regex_range_chars
#
# global helpers
#
def delimited_list(
expr: Union[str, ParserElement],
delim: Union[str, ParserElement] = ",",
combine: bool = False,
min: typing.Optional[int] = None,
max: typing.Optional[int] = None,
*,
allow_trailing_delim: bool = False,
) -> ParserElement:
"""Helper to define a delimited list of expressions - the delimiter
defaults to ','. By default, the list elements and delimiters can
have intervening whitespace, and comments, but this can be
overridden by passing ``combine=True`` in the constructor. If
``combine`` is set to ``True``, the matching tokens are
returned as a single token string, with the delimiters included;
otherwise, the matching tokens are returned as a list of tokens,
with the delimiters suppressed.
If ``allow_trailing_delim`` is set to True, then the list may end with
a delimiter.
Example::
delimited_list(Word(alphas)).parse_string("aa,bb,cc") # -> ['aa', 'bb', 'cc']
delimited_list(Word(hexnums), delim=':', combine=True).parse_string("AA:BB:CC:DD:EE") # -> ['AA:BB:CC:DD:EE']
"""
if isinstance(expr, str_type):
expr = ParserElement._literalStringClass(expr)
dlName = "{expr} [{delim} {expr}]...{end}".format(
expr=str(expr.copy().streamline()),
delim=str(delim),
end=" [{}]".format(str(delim)) if allow_trailing_delim else "",
)
if not combine:
delim = Suppress(delim)
if min is not None:
if min < 1:
raise ValueError("min must be greater than 0")
min -= 1
if max is not None:
if min is not None and max <= min:
raise ValueError("max must be greater than, or equal to min")
max -= 1
delimited_list_expr = expr + (delim + expr)[min, max]
if allow_trailing_delim:
delimited_list_expr += Opt(delim)
if combine:
return Combine(delimited_list_expr).set_name(dlName)
else:
return delimited_list_expr.set_name(dlName)
def counted_array(
expr: ParserElement,
int_expr: typing.Optional[ParserElement] = None,
*,
intExpr: typing.Optional[ParserElement] = None,
) -> ParserElement:
"""Helper to define a counted list of expressions.
This helper defines a pattern of the form::
integer expr expr expr...
where the leading integer tells how many expr expressions follow.
The matched tokens returns the array of expr tokens as a list - the
leading count token is suppressed.
If ``int_expr`` is specified, it should be a pyparsing expression
that produces an integer value.
Example::
counted_array(Word(alphas)).parse_string('2 ab cd ef') # -> ['ab', 'cd']
# in this parser, the leading integer value is given in binary,
# '10' indicating that 2 values are in the array
binary_constant = Word('01').set_parse_action(lambda t: int(t[0], 2))
counted_array(Word(alphas), int_expr=binary_constant).parse_string('10 ab cd ef') # -> ['ab', 'cd']
# if other fields must be parsed after the count but before the
# list items, give the fields results names and they will
# be preserved in the returned ParseResults:
count_with_metadata = integer + Word(alphas)("type")
typed_array = counted_array(Word(alphanums), int_expr=count_with_metadata)("items")
result = typed_array.parse_string("3 bool True True False")
print(result.dump())
# prints
# ['True', 'True', 'False']
# - items: ['True', 'True', 'False']
# - type: 'bool'
"""
intExpr = intExpr or int_expr
array_expr = Forward()
def count_field_parse_action(s, l, t):
nonlocal array_expr
n = t[0]
array_expr <<= (expr * n) if n else Empty()
# clear list contents, but keep any named results
del t[:]
if intExpr is None:
intExpr = Word(nums).set_parse_action(lambda t: int(t[0]))
else:
intExpr = intExpr.copy()
intExpr.set_name("arrayLen")
intExpr.add_parse_action(count_field_parse_action, call_during_try=True)
return (intExpr + array_expr).set_name("(len) " + str(expr) + "...")
def match_previous_literal(expr: ParserElement) -> ParserElement:
"""Helper to define an expression that is indirectly defined from
the tokens matched in a previous expression, that is, it looks for
a 'repeat' of a previous expression. For example::
first = Word(nums)
second = match_previous_literal(first)
match_expr = first + ":" + second
will match ``"1:1"``, but not ``"1:2"``. Because this
matches a previous literal, will also match the leading
``"1:1"`` in ``"1:10"``. If this is not desired, use
:class:`match_previous_expr`. Do *not* use with packrat parsing
enabled.
"""
rep = Forward()
def copy_token_to_repeater(s, l, t):
if t:
if len(t) == 1:
rep << t[0]
else:
# flatten t tokens
tflat = _flatten(t.as_list())
rep << And(Literal(tt) for tt in tflat)
else:
rep << Empty()
expr.add_parse_action(copy_token_to_repeater, callDuringTry=True)
rep.set_name("(prev) " + str(expr))
return rep
def match_previous_expr(expr: ParserElement) -> ParserElement:
"""Helper to define an expression that is indirectly defined from
the tokens matched in a previous expression, that is, it looks for
a 'repeat' of a previous expression. For example::
first = Word(nums)
second = match_previous_expr(first)
match_expr = first + ":" + second
will match ``"1:1"``, but not ``"1:2"``. Because this
matches by expressions, will *not* match the leading ``"1:1"``
in ``"1:10"``; the expressions are evaluated first, and then
compared, so ``"1"`` is compared with ``"10"``. Do *not* use
with packrat parsing enabled.
"""
rep = Forward()
e2 = expr.copy()
rep <<= e2
def copy_token_to_repeater(s, l, t):
matchTokens = _flatten(t.as_list())
def must_match_these_tokens(s, l, t):
theseTokens = _flatten(t.as_list())
if theseTokens != matchTokens:
raise ParseException(
s, l, "Expected {}, found{}".format(matchTokens, theseTokens)
)
rep.set_parse_action(must_match_these_tokens, callDuringTry=True)
expr.add_parse_action(copy_token_to_repeater, callDuringTry=True)
rep.set_name("(prev) " + str(expr))
return rep
def one_of(
strs: Union[typing.Iterable[str], str],
caseless: bool = False,
use_regex: bool = True,
as_keyword: bool = False,
*,
useRegex: bool = True,
asKeyword: bool = False,
) -> ParserElement:
"""Helper to quickly define a set of alternative :class:`Literal` s,
and makes sure to do longest-first testing when there is a conflict,
regardless of the input order, but returns
a :class:`MatchFirst` for best performance.
Parameters:
- ``strs`` - a string of space-delimited literals, or a collection of
string literals
- ``caseless`` - treat all literals as caseless - (default= ``False``)
- ``use_regex`` - as an optimization, will
generate a :class:`Regex` object; otherwise, will generate
a :class:`MatchFirst` object (if ``caseless=True`` or ``asKeyword=True``, or if
creating a :class:`Regex` raises an exception) - (default= ``True``)
- ``as_keyword`` - enforce :class:`Keyword`-style matching on the
generated expressions - (default= ``False``)
- ``asKeyword`` and ``useRegex`` are retained for pre-PEP8 compatibility,
but will be removed in a future release
Example::
comp_oper = one_of("< = > <= >= !=")
var = Word(alphas)
number = Word(nums)
term = var | number
comparison_expr = term + comp_oper + term
print(comparison_expr.search_string("B = 12 AA=23 B<=AA AA>12"))
prints::
[['B', '=', '12'], ['AA', '=', '23'], ['B', '<=', 'AA'], ['AA', '>', '12']]
"""
asKeyword = asKeyword or as_keyword
useRegex = useRegex and use_regex
if (
isinstance(caseless, str_type)
and __diag__.warn_on_multiple_string_args_to_oneof
):
warnings.warn(
"More than one string argument passed to one_of, pass"
" choices as a list or space-delimited string",
stacklevel=2,
)
if caseless:
isequal = lambda a, b: a.upper() == b.upper()
masks = lambda a, b: b.upper().startswith(a.upper())
parseElementClass = CaselessKeyword if asKeyword else CaselessLiteral
else:
isequal = lambda a, b: a == b
masks = lambda a, b: b.startswith(a)
parseElementClass = Keyword if asKeyword else Literal
symbols: List[str] = []
if isinstance(strs, str_type):
symbols = strs.split()
elif isinstance(strs, Iterable):
symbols = list(strs)
else:
raise TypeError("Invalid argument to one_of, expected string or iterable")
if not symbols:
return NoMatch()
# reorder given symbols to take care to avoid masking longer choices with shorter ones
# (but only if the given symbols are not just single characters)
if any(len(sym) > 1 for sym in symbols):
i = 0
while i < len(symbols) - 1:
cur = symbols[i]
for j, other in enumerate(symbols[i + 1 :]):
if isequal(other, cur):
del symbols[i + j + 1]
break
elif masks(cur, other):
del symbols[i + j + 1]
symbols.insert(i, other)
break
else:
i += 1
if useRegex:
re_flags: int = re.IGNORECASE if caseless else 0
try:
if all(len(sym) == 1 for sym in symbols):
# symbols are just single characters, create range regex pattern
patt = "[{}]".format(
"".join(_escape_regex_range_chars(sym) for sym in symbols)
)
else:
patt = "|".join(re.escape(sym) for sym in symbols)
# wrap with \b word break markers if defining as keywords
if asKeyword:
patt = r"\b(?:{})\b".format(patt)
ret = Regex(patt, flags=re_flags).set_name(" | ".join(symbols))
if caseless:
# add parse action to return symbols as specified, not in random
# casing as found in input string
symbol_map = {sym.lower(): sym for sym in symbols}
ret.add_parse_action(lambda s, l, t: symbol_map[t[0].lower()])
return ret
except re.error:
warnings.warn(
"Exception creating Regex for one_of, building MatchFirst", stacklevel=2
)
# last resort, just use MatchFirst
return MatchFirst(parseElementClass(sym) for sym in symbols).set_name(
" | ".join(symbols)
)
def dict_of(key: ParserElement, value: ParserElement) -> ParserElement:
"""Helper to easily and clearly define a dictionary by specifying
the respective patterns for the key and value. Takes care of
defining the :class:`Dict`, :class:`ZeroOrMore`, and
:class:`Group` tokens in the proper order. The key pattern
can include delimiting markers or punctuation, as long as they are
suppressed, thereby leaving the significant key text. The value
pattern can include named results, so that the :class:`Dict` results
can include named token fields.
Example::
text = "shape: SQUARE posn: upper left color: light blue texture: burlap"
attr_expr = (label + Suppress(':') + OneOrMore(data_word, stop_on=label).set_parse_action(' '.join))
print(attr_expr[1, ...].parse_string(text).dump())
attr_label = label
attr_value = Suppress(':') + OneOrMore(data_word, stop_on=label).set_parse_action(' '.join)
# similar to Dict, but simpler call format
result = dict_of(attr_label, attr_value).parse_string(text)
print(result.dump())
print(result['shape'])
print(result.shape) # object attribute access works too
print(result.as_dict())
prints::
[['shape', 'SQUARE'], ['posn', 'upper left'], ['color', 'light blue'], ['texture', 'burlap']]
- color: 'light blue'
- posn: 'upper left'
- shape: 'SQUARE'
- texture: 'burlap'
SQUARE
SQUARE
{'color': 'light blue', 'shape': 'SQUARE', 'posn': 'upper left', 'texture': 'burlap'}
"""
return Dict(OneOrMore(Group(key + value)))
def original_text_for(
expr: ParserElement, as_string: bool = True, *, asString: bool = True
) -> ParserElement:
"""Helper to return the original, untokenized text for a given
expression. Useful to restore the parsed fields of an HTML start
tag into the raw tag text itself, or to revert separate tokens with
intervening whitespace back to the original matching input text. By
default, returns astring containing the original parsed text.
If the optional ``as_string`` argument is passed as
``False``, then the return value is
a :class:`ParseResults` containing any results names that
were originally matched, and a single token containing the original
matched text from the input string. So if the expression passed to
:class:`original_text_for` contains expressions with defined
results names, you must set ``as_string`` to ``False`` if you
want to preserve those results name values.
The ``asString`` pre-PEP8 argument is retained for compatibility,
but will be removed in a future release.
Example::
src = "this is test <b> bold <i>text</i> </b> normal text "
for tag in ("b", "i"):
opener, closer = make_html_tags(tag)
patt = original_text_for(opener + SkipTo(closer) + closer)
print(patt.search_string(src)[0])
prints::
['<b> bold <i>text</i> </b>']
['<i>text</i>']
"""
asString = asString and as_string
locMarker = Empty().set_parse_action(lambda s, loc, t: loc)
endlocMarker = locMarker.copy()
endlocMarker.callPreparse = False
matchExpr = locMarker("_original_start") + expr + endlocMarker("_original_end")
if asString:
extractText = lambda s, l, t: s[t._original_start : t._original_end]
else:
def extractText(s, l, t):
t[:] = [s[t.pop("_original_start") : t.pop("_original_end")]]
matchExpr.set_parse_action(extractText)
matchExpr.ignoreExprs = expr.ignoreExprs
matchExpr.suppress_warning(Diagnostics.warn_ungrouped_named_tokens_in_collection)
return matchExpr
def ungroup(expr: ParserElement) -> ParserElement:
"""Helper to undo pyparsing's default grouping of And expressions,
even if all but one are non-empty.
"""
return TokenConverter(expr).add_parse_action(lambda t: t[0])
def locatedExpr(expr: ParserElement) -> ParserElement:
"""
(DEPRECATED - future code should use the Located class)
Helper to decorate a returned token with its starting and ending
locations in the input string.
This helper adds the following results names:
- ``locn_start`` - location where matched expression begins
- ``locn_end`` - location where matched expression ends
- ``value`` - the actual parsed results
Be careful if the input text contains ``<TAB>`` characters, you
may want to call :class:`ParserElement.parseWithTabs`
Example::
wd = Word(alphas)
for match in locatedExpr(wd).searchString("ljsdf123lksdjjf123lkkjj1222"):
print(match)
prints::
[[0, 'ljsdf', 5]]
[[8, 'lksdjjf', 15]]
[[18, 'lkkjj', 23]]
"""
locator = Empty().set_parse_action(lambda ss, ll, tt: ll)
return Group(
locator("locn_start")
+ expr("value")
+ locator.copy().leaveWhitespace()("locn_end")
)
def nested_expr(
opener: Union[str, ParserElement] = "(",
closer: Union[str, ParserElement] = ")",
content: typing.Optional[ParserElement] = None,
ignore_expr: ParserElement = quoted_string(),
*,
ignoreExpr: ParserElement = quoted_string(),
) -> ParserElement:
"""Helper method for defining nested lists enclosed in opening and
closing delimiters (``"("`` and ``")"`` are the default).
Parameters:
- ``opener`` - opening character for a nested list
(default= ``"("``); can also be a pyparsing expression
- ``closer`` - closing character for a nested list
(default= ``")"``); can also be a pyparsing expression
- ``content`` - expression for items within the nested lists
(default= ``None``)
- ``ignore_expr`` - expression for ignoring opening and closing delimiters
(default= :class:`quoted_string`)
- ``ignoreExpr`` - this pre-PEP8 argument is retained for compatibility
but will be removed in a future release
If an expression is not provided for the content argument, the
nested expression will capture all whitespace-delimited content
between delimiters as a list of separate values.
Use the ``ignore_expr`` argument to define expressions that may
contain opening or closing characters that should not be treated as
opening or closing characters for nesting, such as quoted_string or
a comment expression. Specify multiple expressions using an
:class:`Or` or :class:`MatchFirst`. The default is
:class:`quoted_string`, but if no expressions are to be ignored, then
pass ``None`` for this argument.
Example::
data_type = one_of("void int short long char float double")
decl_data_type = Combine(data_type + Opt(Word('*')))
ident = Word(alphas+'_', alphanums+'_')
number = pyparsing_common.number
arg = Group(decl_data_type + ident)
LPAR, RPAR = map(Suppress, "()")
code_body = nested_expr('{', '}', ignore_expr=(quoted_string | c_style_comment))
c_function = (decl_data_type("type")
+ ident("name")
+ LPAR + Opt(delimited_list(arg), [])("args") + RPAR
+ code_body("body"))
c_function.ignore(c_style_comment)
source_code = '''
int is_odd(int x) {
return (x%2);
}
int dec_to_hex(char hchar) {
if (hchar >= '0' && hchar <= '9') {
return (ord(hchar)-ord('0'));
} else {
return (10+ord(hchar)-ord('A'));
}
}
'''
for func in c_function.search_string(source_code):
print("%(name)s (%(type)s) args: %(args)s" % func)
prints::
is_odd (int) args: [['int', 'x']]
dec_to_hex (int) args: [['char', 'hchar']]
"""
if ignoreExpr != ignore_expr:
ignoreExpr = ignore_expr if ignoreExpr == quoted_string() else ignoreExpr
if opener == closer:
raise ValueError("opening and closing strings cannot be the same")
if content is None:
if isinstance(opener, str_type) and isinstance(closer, str_type):
if len(opener) == 1 and len(closer) == 1:
if ignoreExpr is not None:
content = Combine(
OneOrMore(
~ignoreExpr
+ CharsNotIn(
opener + closer + ParserElement.DEFAULT_WHITE_CHARS,
exact=1,
)
)
).set_parse_action(lambda t: t[0].strip())
else:
content = empty.copy() + CharsNotIn(
opener + closer + ParserElement.DEFAULT_WHITE_CHARS
).set_parse_action(lambda t: t[0].strip())
else:
if ignoreExpr is not None:
content = Combine(
OneOrMore(
~ignoreExpr
+ ~Literal(opener)
+ ~Literal(closer)
+ CharsNotIn(ParserElement.DEFAULT_WHITE_CHARS, exact=1)
)
).set_parse_action(lambda t: t[0].strip())
else:
content = Combine(
OneOrMore(
~Literal(opener)
+ ~Literal(closer)
+ CharsNotIn(ParserElement.DEFAULT_WHITE_CHARS, exact=1)
)
).set_parse_action(lambda t: t[0].strip())
else:
raise ValueError(
"opening and closing arguments must be strings if no content expression is given"
)
ret = Forward()
if ignoreExpr is not None:
ret <<= Group(
Suppress(opener) + ZeroOrMore(ignoreExpr | ret | content) + Suppress(closer)
)
else:
ret <<= Group(Suppress(opener) + ZeroOrMore(ret | content) + Suppress(closer))
ret.set_name("nested %s%s expression" % (opener, closer))
return ret
def _makeTags(tagStr, xml, suppress_LT=Suppress("<"), suppress_GT=Suppress(">")):
"""Internal helper to construct opening and closing tag expressions, given a tag name"""
if isinstance(tagStr, str_type):
resname = tagStr
tagStr = Keyword(tagStr, caseless=not xml)
else:
resname = tagStr.name
tagAttrName = Word(alphas, alphanums + "_-:")
if xml:
tagAttrValue = dbl_quoted_string.copy().set_parse_action(remove_quotes)
openTag = (
suppress_LT
+ tagStr("tag")
+ Dict(ZeroOrMore(Group(tagAttrName + Suppress("=") + tagAttrValue)))
+ Opt("/", default=[False])("empty").set_parse_action(
lambda s, l, t: t[0] == "/"
)
+ suppress_GT
)
else:
tagAttrValue = quoted_string.copy().set_parse_action(remove_quotes) | Word(
printables, exclude_chars=">"
)
openTag = (
suppress_LT
+ tagStr("tag")
+ Dict(
ZeroOrMore(
Group(
tagAttrName.set_parse_action(lambda t: t[0].lower())
+ Opt(Suppress("=") + tagAttrValue)
)
)
)
+ Opt("/", default=[False])("empty").set_parse_action(
lambda s, l, t: t[0] == "/"
)
+ suppress_GT
)
closeTag = Combine(Literal("</") + tagStr + ">", adjacent=False)
openTag.set_name("<%s>" % resname)
# add start<tagname> results name in parse action now that ungrouped names are not reported at two levels
openTag.add_parse_action(
lambda t: t.__setitem__(
"start" + "".join(resname.replace(":", " ").title().split()), t.copy()
)
)
closeTag = closeTag(
"end" + "".join(resname.replace(":", " ").title().split())
).set_name("</%s>" % resname)
openTag.tag = resname
closeTag.tag = resname
openTag.tag_body = SkipTo(closeTag())
return openTag, closeTag
def make_html_tags(
tag_str: Union[str, ParserElement]
) -> Tuple[ParserElement, ParserElement]:
"""Helper to construct opening and closing tag expressions for HTML,
given a tag name. Matches tags in either upper or lower case,
attributes with namespaces and with quoted or unquoted values.
Example::
text = '<td>More info at the <a href="https://github.com/pyparsing/pyparsing/wiki">pyparsing</a> wiki page</td>'
# make_html_tags returns pyparsing expressions for the opening and
# closing tags as a 2-tuple
a, a_end = make_html_tags("A")
link_expr = a + SkipTo(a_end)("link_text") + a_end
for link in link_expr.search_string(text):
# attributes in the <A> tag (like "href" shown here) are
# also accessible as named results
print(link.link_text, '->', link.href)
prints::
pyparsing -> https://github.com/pyparsing/pyparsing/wiki
"""
return _makeTags(tag_str, False)
def make_xml_tags(
tag_str: Union[str, ParserElement]
) -> Tuple[ParserElement, ParserElement]:
"""Helper to construct opening and closing tag expressions for XML,
given a tag name. Matches tags only in the given upper/lower case.
Example: similar to :class:`make_html_tags`
"""
return _makeTags(tag_str, True)
any_open_tag: ParserElement
any_close_tag: ParserElement
any_open_tag, any_close_tag = make_html_tags(
Word(alphas, alphanums + "_:").set_name("any tag")
)
_htmlEntityMap = {k.rstrip(";"): v for k, v in html.entities.html5.items()}
common_html_entity = Regex("&(?P<entity>" + "|".join(_htmlEntityMap) + ");").set_name(
"common HTML entity"
)
def replace_html_entity(t):
"""Helper parser action to replace common HTML entities with their special characters"""
return _htmlEntityMap.get(t.entity)
class OpAssoc(Enum):
LEFT = 1
RIGHT = 2
InfixNotationOperatorArgType = Union[
ParserElement, str, Tuple[Union[ParserElement, str], Union[ParserElement, str]]
]
InfixNotationOperatorSpec = Union[
Tuple[
InfixNotationOperatorArgType,
int,
OpAssoc,
typing.Optional[ParseAction],
],
Tuple[
InfixNotationOperatorArgType,
int,
OpAssoc,
],
]
def infix_notation(
base_expr: ParserElement,
op_list: List[InfixNotationOperatorSpec],
lpar: Union[str, ParserElement] = Suppress("("),
rpar: Union[str, ParserElement] = Suppress(")"),
) -> ParserElement:
"""Helper method for constructing grammars of expressions made up of
operators working in a precedence hierarchy. Operators may be unary
or binary, left- or right-associative. Parse actions can also be
attached to operator expressions. The generated parser will also
recognize the use of parentheses to override operator precedences
(see example below).
Note: if you define a deep operator list, you may see performance
issues when using infix_notation. See
:class:`ParserElement.enable_packrat` for a mechanism to potentially
improve your parser performance.
Parameters:
- ``base_expr`` - expression representing the most basic operand to
be used in the expression
- ``op_list`` - list of tuples, one for each operator precedence level
in the expression grammar; each tuple is of the form ``(op_expr,
num_operands, right_left_assoc, (optional)parse_action)``, where:
- ``op_expr`` is the pyparsing expression for the operator; may also
be a string, which will be converted to a Literal; if ``num_operands``
is 3, ``op_expr`` is a tuple of two expressions, for the two
operators separating the 3 terms
- ``num_operands`` is the number of terms for this operator (must be 1,
2, or 3)
- ``right_left_assoc`` is the indicator whether the operator is right
or left associative, using the pyparsing-defined constants
``OpAssoc.RIGHT`` and ``OpAssoc.LEFT``.
- ``parse_action`` is the parse action to be associated with
expressions matching this operator expression (the parse action
tuple member may be omitted); if the parse action is passed
a tuple or list of functions, this is equivalent to calling
``set_parse_action(*fn)``
(:class:`ParserElement.set_parse_action`)
- ``lpar`` - expression for matching left-parentheses; if passed as a
str, then will be parsed as Suppress(lpar). If lpar is passed as
an expression (such as ``Literal('(')``), then it will be kept in
the parsed results, and grouped with them. (default= ``Suppress('(')``)
- ``rpar`` - expression for matching right-parentheses; if passed as a
str, then will be parsed as Suppress(rpar). If rpar is passed as
an expression (such as ``Literal(')')``), then it will be kept in
the parsed results, and grouped with them. (default= ``Suppress(')')``)
Example::
# simple example of four-function arithmetic with ints and
# variable names
integer = pyparsing_common.signed_integer
varname = pyparsing_common.identifier
arith_expr = infix_notation(integer | varname,
[
('-', 1, OpAssoc.RIGHT),
(one_of('* /'), 2, OpAssoc.LEFT),
(one_of('+ -'), 2, OpAssoc.LEFT),
])
arith_expr.run_tests('''
5+3*6
(5+3)*6
-2--11
''', full_dump=False)
prints::
5+3*6
[[5, '+', [3, '*', 6]]]
(5+3)*6
[[[5, '+', 3], '*', 6]]
-2--11
[[['-', 2], '-', ['-', 11]]]
"""
# captive version of FollowedBy that does not do parse actions or capture results names
class _FB(FollowedBy):
def parseImpl(self, instring, loc, doActions=True):
self.expr.try_parse(instring, loc)
return loc, []
_FB.__name__ = "FollowedBy>"
ret = Forward()
if isinstance(lpar, str):
lpar = Suppress(lpar)
if isinstance(rpar, str):
rpar = Suppress(rpar)
# if lpar and rpar are not suppressed, wrap in group
if not (isinstance(rpar, Suppress) and isinstance(rpar, Suppress)):
lastExpr = base_expr | Group(lpar + ret + rpar)
else:
lastExpr = base_expr | (lpar + ret + rpar)
for i, operDef in enumerate(op_list):
opExpr, arity, rightLeftAssoc, pa = (operDef + (None,))[:4]
if isinstance(opExpr, str_type):
opExpr = ParserElement._literalStringClass(opExpr)
if arity == 3:
if not isinstance(opExpr, (tuple, list)) or len(opExpr) != 2:
raise ValueError(
"if numterms=3, opExpr must be a tuple or list of two expressions"
)
opExpr1, opExpr2 = opExpr
term_name = "{}{} term".format(opExpr1, opExpr2)
else:
term_name = "{} term".format(opExpr)
if not 1 <= arity <= 3:
raise ValueError("operator must be unary (1), binary (2), or ternary (3)")
if rightLeftAssoc not in (OpAssoc.LEFT, OpAssoc.RIGHT):
raise ValueError("operator must indicate right or left associativity")
thisExpr: Forward = Forward().set_name(term_name)
if rightLeftAssoc is OpAssoc.LEFT:
if arity == 1:
matchExpr = _FB(lastExpr + opExpr) + Group(lastExpr + opExpr[1, ...])
elif arity == 2:
if opExpr is not None:
matchExpr = _FB(lastExpr + opExpr + lastExpr) + Group(
lastExpr + (opExpr + lastExpr)[1, ...]
)
else:
matchExpr = _FB(lastExpr + lastExpr) + Group(lastExpr[2, ...])
elif arity == 3:
matchExpr = _FB(
lastExpr + opExpr1 + lastExpr + opExpr2 + lastExpr
) + Group(lastExpr + OneOrMore(opExpr1 + lastExpr + opExpr2 + lastExpr))
elif rightLeftAssoc is OpAssoc.RIGHT:
if arity == 1:
# try to avoid LR with this extra test
if not isinstance(opExpr, Opt):
opExpr = Opt(opExpr)
matchExpr = _FB(opExpr.expr + thisExpr) + Group(opExpr + thisExpr)
elif arity == 2:
if opExpr is not None:
matchExpr = _FB(lastExpr + opExpr + thisExpr) + Group(
lastExpr + (opExpr + thisExpr)[1, ...]
)
else:
matchExpr = _FB(lastExpr + thisExpr) + Group(
lastExpr + thisExpr[1, ...]
)
elif arity == 3:
matchExpr = _FB(
lastExpr + opExpr1 + thisExpr + opExpr2 + thisExpr
) + Group(lastExpr + opExpr1 + thisExpr + opExpr2 + thisExpr)
if pa:
if isinstance(pa, (tuple, list)):
matchExpr.set_parse_action(*pa)
else:
matchExpr.set_parse_action(pa)
thisExpr <<= (matchExpr | lastExpr).setName(term_name)
lastExpr = thisExpr
ret <<= lastExpr
return ret
def indentedBlock(blockStatementExpr, indentStack, indent=True, backup_stacks=[]):
"""
(DEPRECATED - use IndentedBlock class instead)
Helper method for defining space-delimited indentation blocks,
such as those used to define block statements in Python source code.
Parameters:
- ``blockStatementExpr`` - expression defining syntax of statement that
is repeated within the indented block
- ``indentStack`` - list created by caller to manage indentation stack
(multiple ``statementWithIndentedBlock`` expressions within a single
grammar should share a common ``indentStack``)
- ``indent`` - boolean indicating whether block must be indented beyond
the current level; set to ``False`` for block of left-most statements
(default= ``True``)
A valid block must contain at least one ``blockStatement``.
(Note that indentedBlock uses internal parse actions which make it
incompatible with packrat parsing.)
Example::
data = '''
def A(z):
A1
B = 100
G = A2
A2
A3
B
def BB(a,b,c):
BB1
def BBA():
bba1
bba2
bba3
C
D
def spam(x,y):
def eggs(z):
pass
'''
indentStack = [1]
stmt = Forward()
identifier = Word(alphas, alphanums)
funcDecl = ("def" + identifier + Group("(" + Opt(delimitedList(identifier)) + ")") + ":")
func_body = indentedBlock(stmt, indentStack)
funcDef = Group(funcDecl + func_body)
rvalue = Forward()
funcCall = Group(identifier + "(" + Opt(delimitedList(rvalue)) + ")")
rvalue << (funcCall | identifier | Word(nums))
assignment = Group(identifier + "=" + rvalue)
stmt << (funcDef | assignment | identifier)
module_body = stmt[1, ...]
parseTree = module_body.parseString(data)
parseTree.pprint()
prints::
[['def',
'A',
['(', 'z', ')'],
':',
[['A1'], [['B', '=', '100']], [['G', '=', 'A2']], ['A2'], ['A3']]],
'B',
['def',
'BB',
['(', 'a', 'b', 'c', ')'],
':',
[['BB1'], [['def', 'BBA', ['(', ')'], ':', [['bba1'], ['bba2'], ['bba3']]]]]],
'C',
'D',
['def',
'spam',
['(', 'x', 'y', ')'],
':',
[[['def', 'eggs', ['(', 'z', ')'], ':', [['pass']]]]]]]
"""
backup_stacks.append(indentStack[:])
def reset_stack():
indentStack[:] = backup_stacks[-1]
def checkPeerIndent(s, l, t):
if l >= len(s):
return
curCol = col(l, s)
if curCol != indentStack[-1]:
if curCol > indentStack[-1]:
raise ParseException(s, l, "illegal nesting")
raise ParseException(s, l, "not a peer entry")
def checkSubIndent(s, l, t):
curCol = col(l, s)
if curCol > indentStack[-1]:
indentStack.append(curCol)
else:
raise ParseException(s, l, "not a subentry")
def checkUnindent(s, l, t):
if l >= len(s):
return
curCol = col(l, s)
if not (indentStack and curCol in indentStack):
raise ParseException(s, l, "not an unindent")
if curCol < indentStack[-1]:
indentStack.pop()
NL = OneOrMore(LineEnd().set_whitespace_chars("\t ").suppress())
INDENT = (Empty() + Empty().set_parse_action(checkSubIndent)).set_name("INDENT")
PEER = Empty().set_parse_action(checkPeerIndent).set_name("")
UNDENT = Empty().set_parse_action(checkUnindent).set_name("UNINDENT")
if indent:
smExpr = Group(
Opt(NL)
+ INDENT
+ OneOrMore(PEER + Group(blockStatementExpr) + Opt(NL))
+ UNDENT
)
else:
smExpr = Group(
Opt(NL)
+ OneOrMore(PEER + Group(blockStatementExpr) + Opt(NL))
+ Opt(UNDENT)
)
# add a parse action to remove backup_stack from list of backups
smExpr.add_parse_action(
lambda: backup_stacks.pop(-1) and None if backup_stacks else None
)
smExpr.set_fail_action(lambda a, b, c, d: reset_stack())
blockStatementExpr.ignore(_bslash + LineEnd())
return smExpr.set_name("indented block")
# it's easy to get these comment structures wrong - they're very common, so may as well make them available
c_style_comment = Combine(Regex(r"/\*(?:[^*]|\*(?!/))*") + "*/").set_name(
"C style comment"
)
"Comment of the form ``/* ... */``"
html_comment = Regex(r"<!--[\s\S]*?-->").set_name("HTML comment")
"Comment of the form ``<!-- ... -->``"
rest_of_line = Regex(r".*").leave_whitespace().set_name("rest of line")
dbl_slash_comment = Regex(r"//(?:\\\n|[^\n])*").set_name("// comment")
"Comment of the form ``// ... (to end of line)``"
cpp_style_comment = Combine(
Regex(r"/\*(?:[^*]|\*(?!/))*") + "*/" | dbl_slash_comment
).set_name("C++ style comment")
"Comment of either form :class:`c_style_comment` or :class:`dbl_slash_comment`"
java_style_comment = cpp_style_comment
"Same as :class:`cpp_style_comment`"
python_style_comment = Regex(r"#.*").set_name("Python style comment")
"Comment of the form ``# ... (to end of line)``"
# build list of built-in expressions, for future reference if a global default value
# gets updated
_builtin_exprs: List[ParserElement] = [
v for v in vars().values() if isinstance(v, ParserElement)
]
# pre-PEP8 compatible names
delimitedList = delimited_list
countedArray = counted_array
matchPreviousLiteral = match_previous_literal
matchPreviousExpr = match_previous_expr
oneOf = one_of
dictOf = dict_of
originalTextFor = original_text_for
nestedExpr = nested_expr
makeHTMLTags = make_html_tags
makeXMLTags = make_xml_tags
anyOpenTag, anyCloseTag = any_open_tag, any_close_tag
commonHTMLEntity = common_html_entity
replaceHTMLEntity = replace_html_entity
opAssoc = OpAssoc
infixNotation = infix_notation
cStyleComment = c_style_comment
htmlComment = html_comment
restOfLine = rest_of_line
dblSlashComment = dbl_slash_comment
cppStyleComment = cpp_style_comment
javaStyleComment = java_style_comment
pythonStyleComment = python_style_comment
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/pyparsing/helpers.py
|
Python
|
mit
| 39,129 |
# results.py
from collections.abc import MutableMapping, Mapping, MutableSequence, Iterator
import pprint
from weakref import ref as wkref
from typing import Tuple, Any
str_type: Tuple[type, ...] = (str, bytes)
_generator_type = type((_ for _ in ()))
class _ParseResultsWithOffset:
__slots__ = ["tup"]
def __init__(self, p1, p2):
self.tup = (p1, p2)
def __getitem__(self, i):
return self.tup[i]
def __getstate__(self):
return self.tup
def __setstate__(self, *args):
self.tup = args[0]
class ParseResults:
"""Structured parse results, to provide multiple means of access to
the parsed data:
- as a list (``len(results)``)
- by list index (``results[0], results[1]``, etc.)
- by attribute (``results.<results_name>`` - see :class:`ParserElement.set_results_name`)
Example::
integer = Word(nums)
date_str = (integer.set_results_name("year") + '/'
+ integer.set_results_name("month") + '/'
+ integer.set_results_name("day"))
# equivalent form:
# date_str = (integer("year") + '/'
# + integer("month") + '/'
# + integer("day"))
# parse_string returns a ParseResults object
result = date_str.parse_string("1999/12/31")
def test(s, fn=repr):
print("{} -> {}".format(s, fn(eval(s))))
test("list(result)")
test("result[0]")
test("result['month']")
test("result.day")
test("'month' in result")
test("'minutes' in result")
test("result.dump()", str)
prints::
list(result) -> ['1999', '/', '12', '/', '31']
result[0] -> '1999'
result['month'] -> '12'
result.day -> '31'
'month' in result -> True
'minutes' in result -> False
result.dump() -> ['1999', '/', '12', '/', '31']
- day: '31'
- month: '12'
- year: '1999'
"""
_null_values: Tuple[Any, ...] = (None, [], "", ())
__slots__ = [
"_name",
"_parent",
"_all_names",
"_modal",
"_toklist",
"_tokdict",
"__weakref__",
]
class List(list):
"""
Simple wrapper class to distinguish parsed list results that should be preserved
as actual Python lists, instead of being converted to :class:`ParseResults`:
LBRACK, RBRACK = map(pp.Suppress, "[]")
element = pp.Forward()
item = ppc.integer
element_list = LBRACK + pp.delimited_list(element) + RBRACK
# add parse actions to convert from ParseResults to actual Python collection types
def as_python_list(t):
return pp.ParseResults.List(t.as_list())
element_list.add_parse_action(as_python_list)
element <<= item | element_list
element.run_tests('''
100
[2,3,4]
[[2, 1],3,4]
[(2, 1),3,4]
(2,3,4)
''', post_parse=lambda s, r: (r[0], type(r[0])))
prints:
100
(100, <class 'int'>)
[2,3,4]
([2, 3, 4], <class 'list'>)
[[2, 1],3,4]
([[2, 1], 3, 4], <class 'list'>)
(Used internally by :class:`Group` when `aslist=True`.)
"""
def __new__(cls, contained=None):
if contained is None:
contained = []
if not isinstance(contained, list):
raise TypeError(
"{} may only be constructed with a list,"
" not {}".format(cls.__name__, type(contained).__name__)
)
return list.__new__(cls)
def __new__(cls, toklist=None, name=None, **kwargs):
if isinstance(toklist, ParseResults):
return toklist
self = object.__new__(cls)
self._name = None
self._parent = None
self._all_names = set()
if toklist is None:
self._toklist = []
elif isinstance(toklist, (list, _generator_type)):
self._toklist = (
[toklist[:]]
if isinstance(toklist, ParseResults.List)
else list(toklist)
)
else:
self._toklist = [toklist]
self._tokdict = dict()
return self
# Performance tuning: we construct a *lot* of these, so keep this
# constructor as small and fast as possible
def __init__(
self, toklist=None, name=None, asList=True, modal=True, isinstance=isinstance
):
self._modal = modal
if name is not None and name != "":
if isinstance(name, int):
name = str(name)
if not modal:
self._all_names = {name}
self._name = name
if toklist not in self._null_values:
if isinstance(toklist, (str_type, type)):
toklist = [toklist]
if asList:
if isinstance(toklist, ParseResults):
self[name] = _ParseResultsWithOffset(
ParseResults(toklist._toklist), 0
)
else:
self[name] = _ParseResultsWithOffset(
ParseResults(toklist[0]), 0
)
self[name]._name = name
else:
try:
self[name] = toklist[0]
except (KeyError, TypeError, IndexError):
if toklist is not self:
self[name] = toklist
else:
self._name = name
def __getitem__(self, i):
if isinstance(i, (int, slice)):
return self._toklist[i]
else:
if i not in self._all_names:
return self._tokdict[i][-1][0]
else:
return ParseResults([v[0] for v in self._tokdict[i]])
def __setitem__(self, k, v, isinstance=isinstance):
if isinstance(v, _ParseResultsWithOffset):
self._tokdict[k] = self._tokdict.get(k, list()) + [v]
sub = v[0]
elif isinstance(k, (int, slice)):
self._toklist[k] = v
sub = v
else:
self._tokdict[k] = self._tokdict.get(k, list()) + [
_ParseResultsWithOffset(v, 0)
]
sub = v
if isinstance(sub, ParseResults):
sub._parent = wkref(self)
def __delitem__(self, i):
if isinstance(i, (int, slice)):
mylen = len(self._toklist)
del self._toklist[i]
# convert int to slice
if isinstance(i, int):
if i < 0:
i += mylen
i = slice(i, i + 1)
# get removed indices
removed = list(range(*i.indices(mylen)))
removed.reverse()
# fixup indices in token dictionary
for name, occurrences in self._tokdict.items():
for j in removed:
for k, (value, position) in enumerate(occurrences):
occurrences[k] = _ParseResultsWithOffset(
value, position - (position > j)
)
else:
del self._tokdict[i]
def __contains__(self, k) -> bool:
return k in self._tokdict
def __len__(self) -> int:
return len(self._toklist)
def __bool__(self) -> bool:
return not not (self._toklist or self._tokdict)
def __iter__(self) -> Iterator:
return iter(self._toklist)
def __reversed__(self) -> Iterator:
return iter(self._toklist[::-1])
def keys(self):
return iter(self._tokdict)
def values(self):
return (self[k] for k in self.keys())
def items(self):
return ((k, self[k]) for k in self.keys())
def haskeys(self) -> bool:
"""
Since ``keys()`` returns an iterator, this method is helpful in bypassing
code that looks for the existence of any defined results names."""
return bool(self._tokdict)
def pop(self, *args, **kwargs):
"""
Removes and returns item at specified index (default= ``last``).
Supports both ``list`` and ``dict`` semantics for ``pop()``. If
passed no argument or an integer argument, it will use ``list``
semantics and pop tokens from the list of parsed tokens. If passed
a non-integer argument (most likely a string), it will use ``dict``
semantics and pop the corresponding value from any defined results
names. A second default return value argument is supported, just as in
``dict.pop()``.
Example::
numlist = Word(nums)[...]
print(numlist.parse_string("0 123 321")) # -> ['0', '123', '321']
def remove_first(tokens):
tokens.pop(0)
numlist.add_parse_action(remove_first)
print(numlist.parse_string("0 123 321")) # -> ['123', '321']
label = Word(alphas)
patt = label("LABEL") + Word(nums)[1, ...]
print(patt.parse_string("AAB 123 321").dump())
# Use pop() in a parse action to remove named result (note that corresponding value is not
# removed from list form of results)
def remove_LABEL(tokens):
tokens.pop("LABEL")
return tokens
patt.add_parse_action(remove_LABEL)
print(patt.parse_string("AAB 123 321").dump())
prints::
['AAB', '123', '321']
- LABEL: 'AAB'
['AAB', '123', '321']
"""
if not args:
args = [-1]
for k, v in kwargs.items():
if k == "default":
args = (args[0], v)
else:
raise TypeError(
"pop() got an unexpected keyword argument {!r}".format(k)
)
if isinstance(args[0], int) or len(args) == 1 or args[0] in self:
index = args[0]
ret = self[index]
del self[index]
return ret
else:
defaultvalue = args[1]
return defaultvalue
def get(self, key, default_value=None):
"""
Returns named result matching the given key, or if there is no
such name, then returns the given ``default_value`` or ``None`` if no
``default_value`` is specified.
Similar to ``dict.get()``.
Example::
integer = Word(nums)
date_str = integer("year") + '/' + integer("month") + '/' + integer("day")
result = date_str.parse_string("1999/12/31")
print(result.get("year")) # -> '1999'
print(result.get("hour", "not specified")) # -> 'not specified'
print(result.get("hour")) # -> None
"""
if key in self:
return self[key]
else:
return default_value
def insert(self, index, ins_string):
"""
Inserts new element at location index in the list of parsed tokens.
Similar to ``list.insert()``.
Example::
numlist = Word(nums)[...]
print(numlist.parse_string("0 123 321")) # -> ['0', '123', '321']
# use a parse action to insert the parse location in the front of the parsed results
def insert_locn(locn, tokens):
tokens.insert(0, locn)
numlist.add_parse_action(insert_locn)
print(numlist.parse_string("0 123 321")) # -> [0, '0', '123', '321']
"""
self._toklist.insert(index, ins_string)
# fixup indices in token dictionary
for name, occurrences in self._tokdict.items():
for k, (value, position) in enumerate(occurrences):
occurrences[k] = _ParseResultsWithOffset(
value, position + (position > index)
)
def append(self, item):
"""
Add single element to end of ``ParseResults`` list of elements.
Example::
numlist = Word(nums)[...]
print(numlist.parse_string("0 123 321")) # -> ['0', '123', '321']
# use a parse action to compute the sum of the parsed integers, and add it to the end
def append_sum(tokens):
tokens.append(sum(map(int, tokens)))
numlist.add_parse_action(append_sum)
print(numlist.parse_string("0 123 321")) # -> ['0', '123', '321', 444]
"""
self._toklist.append(item)
def extend(self, itemseq):
"""
Add sequence of elements to end of ``ParseResults`` list of elements.
Example::
patt = Word(alphas)[1, ...]
# use a parse action to append the reverse of the matched strings, to make a palindrome
def make_palindrome(tokens):
tokens.extend(reversed([t[::-1] for t in tokens]))
return ''.join(tokens)
patt.add_parse_action(make_palindrome)
print(patt.parse_string("lskdj sdlkjf lksd")) # -> 'lskdjsdlkjflksddsklfjkldsjdksl'
"""
if isinstance(itemseq, ParseResults):
self.__iadd__(itemseq)
else:
self._toklist.extend(itemseq)
def clear(self):
"""
Clear all elements and results names.
"""
del self._toklist[:]
self._tokdict.clear()
def __getattr__(self, name):
try:
return self[name]
except KeyError:
if name.startswith("__"):
raise AttributeError(name)
return ""
def __add__(self, other) -> "ParseResults":
ret = self.copy()
ret += other
return ret
def __iadd__(self, other) -> "ParseResults":
if other._tokdict:
offset = len(self._toklist)
addoffset = lambda a: offset if a < 0 else a + offset
otheritems = other._tokdict.items()
otherdictitems = [
(k, _ParseResultsWithOffset(v[0], addoffset(v[1])))
for k, vlist in otheritems
for v in vlist
]
for k, v in otherdictitems:
self[k] = v
if isinstance(v[0], ParseResults):
v[0]._parent = wkref(self)
self._toklist += other._toklist
self._all_names |= other._all_names
return self
def __radd__(self, other) -> "ParseResults":
if isinstance(other, int) and other == 0:
# useful for merging many ParseResults using sum() builtin
return self.copy()
else:
# this may raise a TypeError - so be it
return other + self
def __repr__(self) -> str:
return "{}({!r}, {})".format(type(self).__name__, self._toklist, self.as_dict())
def __str__(self) -> str:
return (
"["
+ ", ".join(
[
str(i) if isinstance(i, ParseResults) else repr(i)
for i in self._toklist
]
)
+ "]"
)
def _asStringList(self, sep=""):
out = []
for item in self._toklist:
if out and sep:
out.append(sep)
if isinstance(item, ParseResults):
out += item._asStringList()
else:
out.append(str(item))
return out
def as_list(self) -> list:
"""
Returns the parse results as a nested list of matching tokens, all converted to strings.
Example::
patt = Word(alphas)[1, ...]
result = patt.parse_string("sldkj lsdkj sldkj")
# even though the result prints in string-like form, it is actually a pyparsing ParseResults
print(type(result), result) # -> <class 'pyparsing.ParseResults'> ['sldkj', 'lsdkj', 'sldkj']
# Use as_list() to create an actual list
result_list = result.as_list()
print(type(result_list), result_list) # -> <class 'list'> ['sldkj', 'lsdkj', 'sldkj']
"""
return [
res.as_list() if isinstance(res, ParseResults) else res
for res in self._toklist
]
def as_dict(self) -> dict:
"""
Returns the named parse results as a nested dictionary.
Example::
integer = Word(nums)
date_str = integer("year") + '/' + integer("month") + '/' + integer("day")
result = date_str.parse_string('12/31/1999')
print(type(result), repr(result)) # -> <class 'pyparsing.ParseResults'> (['12', '/', '31', '/', '1999'], {'day': [('1999', 4)], 'year': [('12', 0)], 'month': [('31', 2)]})
result_dict = result.as_dict()
print(type(result_dict), repr(result_dict)) # -> <class 'dict'> {'day': '1999', 'year': '12', 'month': '31'}
# even though a ParseResults supports dict-like access, sometime you just need to have a dict
import json
print(json.dumps(result)) # -> Exception: TypeError: ... is not JSON serializable
print(json.dumps(result.as_dict())) # -> {"month": "31", "day": "1999", "year": "12"}
"""
def to_item(obj):
if isinstance(obj, ParseResults):
return obj.as_dict() if obj.haskeys() else [to_item(v) for v in obj]
else:
return obj
return dict((k, to_item(v)) for k, v in self.items())
def copy(self) -> "ParseResults":
"""
Returns a new copy of a :class:`ParseResults` object.
"""
ret = ParseResults(self._toklist)
ret._tokdict = self._tokdict.copy()
ret._parent = self._parent
ret._all_names |= self._all_names
ret._name = self._name
return ret
def get_name(self):
r"""
Returns the results name for this token expression. Useful when several
different expressions might match at a particular location.
Example::
integer = Word(nums)
ssn_expr = Regex(r"\d\d\d-\d\d-\d\d\d\d")
house_number_expr = Suppress('#') + Word(nums, alphanums)
user_data = (Group(house_number_expr)("house_number")
| Group(ssn_expr)("ssn")
| Group(integer)("age"))
user_info = user_data[1, ...]
result = user_info.parse_string("22 111-22-3333 #221B")
for item in result:
print(item.get_name(), ':', item[0])
prints::
age : 22
ssn : 111-22-3333
house_number : 221B
"""
if self._name:
return self._name
elif self._parent:
par = self._parent()
def find_in_parent(sub):
return next(
(
k
for k, vlist in par._tokdict.items()
for v, loc in vlist
if sub is v
),
None,
)
return find_in_parent(self) if par else None
elif (
len(self) == 1
and len(self._tokdict) == 1
and next(iter(self._tokdict.values()))[0][1] in (0, -1)
):
return next(iter(self._tokdict.keys()))
else:
return None
def dump(self, indent="", full=True, include_list=True, _depth=0) -> str:
"""
Diagnostic method for listing out the contents of
a :class:`ParseResults`. Accepts an optional ``indent`` argument so
that this string can be embedded in a nested display of other data.
Example::
integer = Word(nums)
date_str = integer("year") + '/' + integer("month") + '/' + integer("day")
result = date_str.parse_string('1999/12/31')
print(result.dump())
prints::
['1999', '/', '12', '/', '31']
- day: '31'
- month: '12'
- year: '1999'
"""
out = []
NL = "\n"
out.append(indent + str(self.as_list()) if include_list else "")
if full:
if self.haskeys():
items = sorted((str(k), v) for k, v in self.items())
for k, v in items:
if out:
out.append(NL)
out.append("{}{}- {}: ".format(indent, (" " * _depth), k))
if isinstance(v, ParseResults):
if v:
out.append(
v.dump(
indent=indent,
full=full,
include_list=include_list,
_depth=_depth + 1,
)
)
else:
out.append(str(v))
else:
out.append(repr(v))
if any(isinstance(vv, ParseResults) for vv in self):
v = self
for i, vv in enumerate(v):
if isinstance(vv, ParseResults):
out.append(
"\n{}{}[{}]:\n{}{}{}".format(
indent,
(" " * (_depth)),
i,
indent,
(" " * (_depth + 1)),
vv.dump(
indent=indent,
full=full,
include_list=include_list,
_depth=_depth + 1,
),
)
)
else:
out.append(
"\n%s%s[%d]:\n%s%s%s"
% (
indent,
(" " * (_depth)),
i,
indent,
(" " * (_depth + 1)),
str(vv),
)
)
return "".join(out)
def pprint(self, *args, **kwargs):
"""
Pretty-printer for parsed results as a list, using the
`pprint <https://docs.python.org/3/library/pprint.html>`_ module.
Accepts additional positional or keyword args as defined for
`pprint.pprint <https://docs.python.org/3/library/pprint.html#pprint.pprint>`_ .
Example::
ident = Word(alphas, alphanums)
num = Word(nums)
func = Forward()
term = ident | num | Group('(' + func + ')')
func <<= ident + Group(Optional(delimited_list(term)))
result = func.parse_string("fna a,b,(fnb c,d,200),100")
result.pprint(width=40)
prints::
['fna',
['a',
'b',
['(', 'fnb', ['c', 'd', '200'], ')'],
'100']]
"""
pprint.pprint(self.as_list(), *args, **kwargs)
# add support for pickle protocol
def __getstate__(self):
return (
self._toklist,
(
self._tokdict.copy(),
self._parent is not None and self._parent() or None,
self._all_names,
self._name,
),
)
def __setstate__(self, state):
self._toklist, (self._tokdict, par, inAccumNames, self._name) = state
self._all_names = set(inAccumNames)
if par is not None:
self._parent = wkref(par)
else:
self._parent = None
def __getnewargs__(self):
return self._toklist, self._name
def __dir__(self):
return dir(type(self)) + list(self.keys())
@classmethod
def from_dict(cls, other, name=None) -> "ParseResults":
"""
Helper classmethod to construct a ``ParseResults`` from a ``dict``, preserving the
name-value relations as results names. If an optional ``name`` argument is
given, a nested ``ParseResults`` will be returned.
"""
def is_iterable(obj):
try:
iter(obj)
except Exception:
return False
else:
return not isinstance(obj, str_type)
ret = cls([])
for k, v in other.items():
if isinstance(v, Mapping):
ret += cls.from_dict(v, name=k)
else:
ret += cls([v], name=k, asList=is_iterable(v))
if name is not None:
ret = cls([ret], name=name)
return ret
asList = as_list
asDict = as_dict
getName = get_name
MutableMapping.register(ParseResults)
MutableSequence.register(ParseResults)
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/pyparsing/results.py
|
Python
|
mit
| 25,341 |
# testing.py
from contextlib import contextmanager
import typing
from .core import (
ParserElement,
ParseException,
Keyword,
__diag__,
__compat__,
)
class pyparsing_test:
"""
namespace class for classes useful in writing unit tests
"""
class reset_pyparsing_context:
"""
Context manager to be used when writing unit tests that modify pyparsing config values:
- packrat parsing
- bounded recursion parsing
- default whitespace characters.
- default keyword characters
- literal string auto-conversion class
- __diag__ settings
Example::
with reset_pyparsing_context():
# test that literals used to construct a grammar are automatically suppressed
ParserElement.inlineLiteralsUsing(Suppress)
term = Word(alphas) | Word(nums)
group = Group('(' + term[...] + ')')
# assert that the '()' characters are not included in the parsed tokens
self.assertParseAndCheckList(group, "(abc 123 def)", ['abc', '123', 'def'])
# after exiting context manager, literals are converted to Literal expressions again
"""
def __init__(self):
self._save_context = {}
def save(self):
self._save_context["default_whitespace"] = ParserElement.DEFAULT_WHITE_CHARS
self._save_context["default_keyword_chars"] = Keyword.DEFAULT_KEYWORD_CHARS
self._save_context[
"literal_string_class"
] = ParserElement._literalStringClass
self._save_context["verbose_stacktrace"] = ParserElement.verbose_stacktrace
self._save_context["packrat_enabled"] = ParserElement._packratEnabled
if ParserElement._packratEnabled:
self._save_context[
"packrat_cache_size"
] = ParserElement.packrat_cache.size
else:
self._save_context["packrat_cache_size"] = None
self._save_context["packrat_parse"] = ParserElement._parse
self._save_context[
"recursion_enabled"
] = ParserElement._left_recursion_enabled
self._save_context["__diag__"] = {
name: getattr(__diag__, name) for name in __diag__._all_names
}
self._save_context["__compat__"] = {
"collect_all_And_tokens": __compat__.collect_all_And_tokens
}
return self
def restore(self):
# reset pyparsing global state
if (
ParserElement.DEFAULT_WHITE_CHARS
!= self._save_context["default_whitespace"]
):
ParserElement.set_default_whitespace_chars(
self._save_context["default_whitespace"]
)
ParserElement.verbose_stacktrace = self._save_context["verbose_stacktrace"]
Keyword.DEFAULT_KEYWORD_CHARS = self._save_context["default_keyword_chars"]
ParserElement.inlineLiteralsUsing(
self._save_context["literal_string_class"]
)
for name, value in self._save_context["__diag__"].items():
(__diag__.enable if value else __diag__.disable)(name)
ParserElement._packratEnabled = False
if self._save_context["packrat_enabled"]:
ParserElement.enable_packrat(self._save_context["packrat_cache_size"])
else:
ParserElement._parse = self._save_context["packrat_parse"]
ParserElement._left_recursion_enabled = self._save_context[
"recursion_enabled"
]
__compat__.collect_all_And_tokens = self._save_context["__compat__"]
return self
def copy(self):
ret = type(self)()
ret._save_context.update(self._save_context)
return ret
def __enter__(self):
return self.save()
def __exit__(self, *args):
self.restore()
class TestParseResultsAsserts:
"""
A mixin class to add parse results assertion methods to normal unittest.TestCase classes.
"""
def assertParseResultsEquals(
self, result, expected_list=None, expected_dict=None, msg=None
):
"""
Unit test assertion to compare a :class:`ParseResults` object with an optional ``expected_list``,
and compare any defined results names with an optional ``expected_dict``.
"""
if expected_list is not None:
self.assertEqual(expected_list, result.as_list(), msg=msg)
if expected_dict is not None:
self.assertEqual(expected_dict, result.as_dict(), msg=msg)
def assertParseAndCheckList(
self, expr, test_string, expected_list, msg=None, verbose=True
):
"""
Convenience wrapper assert to test a parser element and input string, and assert that
the resulting ``ParseResults.asList()`` is equal to the ``expected_list``.
"""
result = expr.parse_string(test_string, parse_all=True)
if verbose:
print(result.dump())
else:
print(result.as_list())
self.assertParseResultsEquals(result, expected_list=expected_list, msg=msg)
def assertParseAndCheckDict(
self, expr, test_string, expected_dict, msg=None, verbose=True
):
"""
Convenience wrapper assert to test a parser element and input string, and assert that
the resulting ``ParseResults.asDict()`` is equal to the ``expected_dict``.
"""
result = expr.parse_string(test_string, parseAll=True)
if verbose:
print(result.dump())
else:
print(result.as_list())
self.assertParseResultsEquals(result, expected_dict=expected_dict, msg=msg)
def assertRunTestResults(
self, run_tests_report, expected_parse_results=None, msg=None
):
"""
Unit test assertion to evaluate output of ``ParserElement.runTests()``. If a list of
list-dict tuples is given as the ``expected_parse_results`` argument, then these are zipped
with the report tuples returned by ``runTests`` and evaluated using ``assertParseResultsEquals``.
Finally, asserts that the overall ``runTests()`` success value is ``True``.
:param run_tests_report: tuple(bool, [tuple(str, ParseResults or Exception)]) returned from runTests
:param expected_parse_results (optional): [tuple(str, list, dict, Exception)]
"""
run_test_success, run_test_results = run_tests_report
if expected_parse_results is not None:
merged = [
(*rpt, expected)
for rpt, expected in zip(run_test_results, expected_parse_results)
]
for test_string, result, expected in merged:
# expected should be a tuple containing a list and/or a dict or an exception,
# and optional failure message string
# an empty tuple will skip any result validation
fail_msg = next(
(exp for exp in expected if isinstance(exp, str)), None
)
expected_exception = next(
(
exp
for exp in expected
if isinstance(exp, type) and issubclass(exp, Exception)
),
None,
)
if expected_exception is not None:
with self.assertRaises(
expected_exception=expected_exception, msg=fail_msg or msg
):
if isinstance(result, Exception):
raise result
else:
expected_list = next(
(exp for exp in expected if isinstance(exp, list)), None
)
expected_dict = next(
(exp for exp in expected if isinstance(exp, dict)), None
)
if (expected_list, expected_dict) != (None, None):
self.assertParseResultsEquals(
result,
expected_list=expected_list,
expected_dict=expected_dict,
msg=fail_msg or msg,
)
else:
# warning here maybe?
print("no validation for {!r}".format(test_string))
# do this last, in case some specific test results can be reported instead
self.assertTrue(
run_test_success, msg=msg if msg is not None else "failed runTests"
)
@contextmanager
def assertRaisesParseException(self, exc_type=ParseException, msg=None):
with self.assertRaises(exc_type, msg=msg):
yield
@staticmethod
def with_line_numbers(
s: str,
start_line: typing.Optional[int] = None,
end_line: typing.Optional[int] = None,
expand_tabs: bool = True,
eol_mark: str = "|",
mark_spaces: typing.Optional[str] = None,
mark_control: typing.Optional[str] = None,
) -> str:
"""
Helpful method for debugging a parser - prints a string with line and column numbers.
(Line and column numbers are 1-based.)
:param s: tuple(bool, str - string to be printed with line and column numbers
:param start_line: int - (optional) starting line number in s to print (default=1)
:param end_line: int - (optional) ending line number in s to print (default=len(s))
:param expand_tabs: bool - (optional) expand tabs to spaces, to match the pyparsing default
:param eol_mark: str - (optional) string to mark the end of lines, helps visualize trailing spaces (default="|")
:param mark_spaces: str - (optional) special character to display in place of spaces
:param mark_control: str - (optional) convert non-printing control characters to a placeholding
character; valid values:
- "unicode" - replaces control chars with Unicode symbols, such as "␍" and "␊"
- any single character string - replace control characters with given string
- None (default) - string is displayed as-is
:return: str - input string with leading line numbers and column number headers
"""
if expand_tabs:
s = s.expandtabs()
if mark_control is not None:
if mark_control == "unicode":
tbl = str.maketrans(
{c: u for c, u in zip(range(0, 33), range(0x2400, 0x2433))}
| {127: 0x2421}
)
eol_mark = ""
else:
tbl = str.maketrans(
{c: mark_control for c in list(range(0, 32)) + [127]}
)
s = s.translate(tbl)
if mark_spaces is not None and mark_spaces != " ":
if mark_spaces == "unicode":
tbl = str.maketrans({9: 0x2409, 32: 0x2423})
s = s.translate(tbl)
else:
s = s.replace(" ", mark_spaces)
if start_line is None:
start_line = 1
if end_line is None:
end_line = len(s)
end_line = min(end_line, len(s))
start_line = min(max(1, start_line), end_line)
if mark_control != "unicode":
s_lines = s.splitlines()[start_line - 1 : end_line]
else:
s_lines = [line + "␊" for line in s.split("␊")[start_line - 1 : end_line]]
if not s_lines:
return ""
lineno_width = len(str(end_line))
max_line_len = max(len(line) for line in s_lines)
lead = " " * (lineno_width + 1)
if max_line_len >= 99:
header0 = (
lead
+ "".join(
"{}{}".format(" " * 99, (i + 1) % 100)
for i in range(max(max_line_len // 100, 1))
)
+ "\n"
)
else:
header0 = ""
header1 = (
header0
+ lead
+ "".join(
" {}".format((i + 1) % 10)
for i in range(-(-max_line_len // 10))
)
+ "\n"
)
header2 = lead + "1234567890" * (-(-max_line_len // 10)) + "\n"
return (
header1
+ header2
+ "\n".join(
"{:{}d}:{}{}".format(i, lineno_width, line, eol_mark)
for i, line in enumerate(s_lines, start=start_line)
)
+ "\n"
)
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/pyparsing/testing.py
|
Python
|
mit
| 13,402 |
# unicode.py
import sys
from itertools import filterfalse
from typing import List, Tuple, Union
class _lazyclassproperty:
def __init__(self, fn):
self.fn = fn
self.__doc__ = fn.__doc__
self.__name__ = fn.__name__
def __get__(self, obj, cls):
if cls is None:
cls = type(obj)
if not hasattr(cls, "_intern") or any(
cls._intern is getattr(superclass, "_intern", [])
for superclass in cls.__mro__[1:]
):
cls._intern = {}
attrname = self.fn.__name__
if attrname not in cls._intern:
cls._intern[attrname] = self.fn(cls)
return cls._intern[attrname]
UnicodeRangeList = List[Union[Tuple[int, int], Tuple[int]]]
class unicode_set:
"""
A set of Unicode characters, for language-specific strings for
``alphas``, ``nums``, ``alphanums``, and ``printables``.
A unicode_set is defined by a list of ranges in the Unicode character
set, in a class attribute ``_ranges``. Ranges can be specified using
2-tuples or a 1-tuple, such as::
_ranges = [
(0x0020, 0x007e),
(0x00a0, 0x00ff),
(0x0100,),
]
Ranges are left- and right-inclusive. A 1-tuple of (x,) is treated as (x, x).
A unicode set can also be defined using multiple inheritance of other unicode sets::
class CJK(Chinese, Japanese, Korean):
pass
"""
_ranges: UnicodeRangeList = []
@_lazyclassproperty
def _chars_for_ranges(cls):
ret = []
for cc in cls.__mro__:
if cc is unicode_set:
break
for rr in getattr(cc, "_ranges", ()):
ret.extend(range(rr[0], rr[-1] + 1))
return [chr(c) for c in sorted(set(ret))]
@_lazyclassproperty
def printables(cls):
"all non-whitespace characters in this range"
return "".join(filterfalse(str.isspace, cls._chars_for_ranges))
@_lazyclassproperty
def alphas(cls):
"all alphabetic characters in this range"
return "".join(filter(str.isalpha, cls._chars_for_ranges))
@_lazyclassproperty
def nums(cls):
"all numeric digit characters in this range"
return "".join(filter(str.isdigit, cls._chars_for_ranges))
@_lazyclassproperty
def alphanums(cls):
"all alphanumeric characters in this range"
return cls.alphas + cls.nums
@_lazyclassproperty
def identchars(cls):
"all characters in this range that are valid identifier characters, plus underscore '_'"
return "".join(
sorted(
set(
"".join(filter(str.isidentifier, cls._chars_for_ranges))
+ "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyzªµº"
+ "ÀÁÂÃÄÅÆÇÈÉÊËÌÍÎÏÐÑÒÓÔÕÖØÙÚÛÜÝÞßàáâãäåæçèéêëìíîïðñòóôõöøùúûüýþÿ"
+ "_"
)
)
)
@_lazyclassproperty
def identbodychars(cls):
"""
all characters in this range that are valid identifier body characters,
plus the digits 0-9
"""
return "".join(
sorted(
set(
cls.identchars
+ "0123456789"
+ "".join(
[c for c in cls._chars_for_ranges if ("_" + c).isidentifier()]
)
)
)
)
class pyparsing_unicode(unicode_set):
"""
A namespace class for defining common language unicode_sets.
"""
# fmt: off
# define ranges in language character sets
_ranges: UnicodeRangeList = [
(0x0020, sys.maxunicode),
]
class BasicMultilingualPlane(unicode_set):
"Unicode set for the Basic Multilingual Plane"
_ranges: UnicodeRangeList = [
(0x0020, 0xFFFF),
]
class Latin1(unicode_set):
"Unicode set for Latin-1 Unicode Character Range"
_ranges: UnicodeRangeList = [
(0x0020, 0x007E),
(0x00A0, 0x00FF),
]
class LatinA(unicode_set):
"Unicode set for Latin-A Unicode Character Range"
_ranges: UnicodeRangeList = [
(0x0100, 0x017F),
]
class LatinB(unicode_set):
"Unicode set for Latin-B Unicode Character Range"
_ranges: UnicodeRangeList = [
(0x0180, 0x024F),
]
class Greek(unicode_set):
"Unicode set for Greek Unicode Character Ranges"
_ranges: UnicodeRangeList = [
(0x0342, 0x0345),
(0x0370, 0x0377),
(0x037A, 0x037F),
(0x0384, 0x038A),
(0x038C,),
(0x038E, 0x03A1),
(0x03A3, 0x03E1),
(0x03F0, 0x03FF),
(0x1D26, 0x1D2A),
(0x1D5E,),
(0x1D60,),
(0x1D66, 0x1D6A),
(0x1F00, 0x1F15),
(0x1F18, 0x1F1D),
(0x1F20, 0x1F45),
(0x1F48, 0x1F4D),
(0x1F50, 0x1F57),
(0x1F59,),
(0x1F5B,),
(0x1F5D,),
(0x1F5F, 0x1F7D),
(0x1F80, 0x1FB4),
(0x1FB6, 0x1FC4),
(0x1FC6, 0x1FD3),
(0x1FD6, 0x1FDB),
(0x1FDD, 0x1FEF),
(0x1FF2, 0x1FF4),
(0x1FF6, 0x1FFE),
(0x2129,),
(0x2719, 0x271A),
(0xAB65,),
(0x10140, 0x1018D),
(0x101A0,),
(0x1D200, 0x1D245),
(0x1F7A1, 0x1F7A7),
]
class Cyrillic(unicode_set):
"Unicode set for Cyrillic Unicode Character Range"
_ranges: UnicodeRangeList = [
(0x0400, 0x052F),
(0x1C80, 0x1C88),
(0x1D2B,),
(0x1D78,),
(0x2DE0, 0x2DFF),
(0xA640, 0xA672),
(0xA674, 0xA69F),
(0xFE2E, 0xFE2F),
]
class Chinese(unicode_set):
"Unicode set for Chinese Unicode Character Range"
_ranges: UnicodeRangeList = [
(0x2E80, 0x2E99),
(0x2E9B, 0x2EF3),
(0x31C0, 0x31E3),
(0x3400, 0x4DB5),
(0x4E00, 0x9FEF),
(0xA700, 0xA707),
(0xF900, 0xFA6D),
(0xFA70, 0xFAD9),
(0x16FE2, 0x16FE3),
(0x1F210, 0x1F212),
(0x1F214, 0x1F23B),
(0x1F240, 0x1F248),
(0x20000, 0x2A6D6),
(0x2A700, 0x2B734),
(0x2B740, 0x2B81D),
(0x2B820, 0x2CEA1),
(0x2CEB0, 0x2EBE0),
(0x2F800, 0x2FA1D),
]
class Japanese(unicode_set):
"Unicode set for Japanese Unicode Character Range, combining Kanji, Hiragana, and Katakana ranges"
_ranges: UnicodeRangeList = []
class Kanji(unicode_set):
"Unicode set for Kanji Unicode Character Range"
_ranges: UnicodeRangeList = [
(0x4E00, 0x9FBF),
(0x3000, 0x303F),
]
class Hiragana(unicode_set):
"Unicode set for Hiragana Unicode Character Range"
_ranges: UnicodeRangeList = [
(0x3041, 0x3096),
(0x3099, 0x30A0),
(0x30FC,),
(0xFF70,),
(0x1B001,),
(0x1B150, 0x1B152),
(0x1F200,),
]
class Katakana(unicode_set):
"Unicode set for Katakana Unicode Character Range"
_ranges: UnicodeRangeList = [
(0x3099, 0x309C),
(0x30A0, 0x30FF),
(0x31F0, 0x31FF),
(0x32D0, 0x32FE),
(0xFF65, 0xFF9F),
(0x1B000,),
(0x1B164, 0x1B167),
(0x1F201, 0x1F202),
(0x1F213,),
]
class Hangul(unicode_set):
"Unicode set for Hangul (Korean) Unicode Character Range"
_ranges: UnicodeRangeList = [
(0x1100, 0x11FF),
(0x302E, 0x302F),
(0x3131, 0x318E),
(0x3200, 0x321C),
(0x3260, 0x327B),
(0x327E,),
(0xA960, 0xA97C),
(0xAC00, 0xD7A3),
(0xD7B0, 0xD7C6),
(0xD7CB, 0xD7FB),
(0xFFA0, 0xFFBE),
(0xFFC2, 0xFFC7),
(0xFFCA, 0xFFCF),
(0xFFD2, 0xFFD7),
(0xFFDA, 0xFFDC),
]
Korean = Hangul
class CJK(Chinese, Japanese, Hangul):
"Unicode set for combined Chinese, Japanese, and Korean (CJK) Unicode Character Range"
class Thai(unicode_set):
"Unicode set for Thai Unicode Character Range"
_ranges: UnicodeRangeList = [
(0x0E01, 0x0E3A),
(0x0E3F, 0x0E5B)
]
class Arabic(unicode_set):
"Unicode set for Arabic Unicode Character Range"
_ranges: UnicodeRangeList = [
(0x0600, 0x061B),
(0x061E, 0x06FF),
(0x0700, 0x077F),
]
class Hebrew(unicode_set):
"Unicode set for Hebrew Unicode Character Range"
_ranges: UnicodeRangeList = [
(0x0591, 0x05C7),
(0x05D0, 0x05EA),
(0x05EF, 0x05F4),
(0xFB1D, 0xFB36),
(0xFB38, 0xFB3C),
(0xFB3E,),
(0xFB40, 0xFB41),
(0xFB43, 0xFB44),
(0xFB46, 0xFB4F),
]
class Devanagari(unicode_set):
"Unicode set for Devanagari Unicode Character Range"
_ranges: UnicodeRangeList = [
(0x0900, 0x097F),
(0xA8E0, 0xA8FF)
]
# fmt: on
pyparsing_unicode.Japanese._ranges = (
pyparsing_unicode.Japanese.Kanji._ranges
+ pyparsing_unicode.Japanese.Hiragana._ranges
+ pyparsing_unicode.Japanese.Katakana._ranges
)
pyparsing_unicode.BMP = pyparsing_unicode.BasicMultilingualPlane
# add language identifiers using language Unicode
pyparsing_unicode.العربية = pyparsing_unicode.Arabic
pyparsing_unicode.中文 = pyparsing_unicode.Chinese
pyparsing_unicode.кириллица = pyparsing_unicode.Cyrillic
pyparsing_unicode.Ελληνικά = pyparsing_unicode.Greek
pyparsing_unicode.עִברִית = pyparsing_unicode.Hebrew
pyparsing_unicode.日本語 = pyparsing_unicode.Japanese
pyparsing_unicode.Japanese.漢字 = pyparsing_unicode.Japanese.Kanji
pyparsing_unicode.Japanese.カタカナ = pyparsing_unicode.Japanese.Katakana
pyparsing_unicode.Japanese.ひらがな = pyparsing_unicode.Japanese.Hiragana
pyparsing_unicode.한국어 = pyparsing_unicode.Korean
pyparsing_unicode.ไทย = pyparsing_unicode.Thai
pyparsing_unicode.देवनागरी = pyparsing_unicode.Devanagari
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/pyparsing/unicode.py
|
Python
|
mit
| 10,787 |
# util.py
import warnings
import types
import collections
import itertools
from functools import lru_cache
from typing import List, Union, Iterable
_bslash = chr(92)
class __config_flags:
"""Internal class for defining compatibility and debugging flags"""
_all_names: List[str] = []
_fixed_names: List[str] = []
_type_desc = "configuration"
@classmethod
def _set(cls, dname, value):
if dname in cls._fixed_names:
warnings.warn(
"{}.{} {} is {} and cannot be overridden".format(
cls.__name__,
dname,
cls._type_desc,
str(getattr(cls, dname)).upper(),
)
)
return
if dname in cls._all_names:
setattr(cls, dname, value)
else:
raise ValueError("no such {} {!r}".format(cls._type_desc, dname))
enable = classmethod(lambda cls, name: cls._set(name, True))
disable = classmethod(lambda cls, name: cls._set(name, False))
@lru_cache(maxsize=128)
def col(loc: int, strg: str) -> int:
"""
Returns current column within a string, counting newlines as line separators.
The first column is number 1.
Note: the default parsing behavior is to expand tabs in the input string
before starting the parsing process. See
:class:`ParserElement.parseString` for more
information on parsing strings containing ``<TAB>`` s, and suggested
methods to maintain a consistent view of the parsed string, the parse
location, and line and column positions within the parsed string.
"""
s = strg
return 1 if 0 < loc < len(s) and s[loc - 1] == "\n" else loc - s.rfind("\n", 0, loc)
@lru_cache(maxsize=128)
def lineno(loc: int, strg: str) -> int:
"""Returns current line number within a string, counting newlines as line separators.
The first line is number 1.
Note - the default parsing behavior is to expand tabs in the input string
before starting the parsing process. See :class:`ParserElement.parseString`
for more information on parsing strings containing ``<TAB>`` s, and
suggested methods to maintain a consistent view of the parsed string, the
parse location, and line and column positions within the parsed string.
"""
return strg.count("\n", 0, loc) + 1
@lru_cache(maxsize=128)
def line(loc: int, strg: str) -> str:
"""
Returns the line of text containing loc within a string, counting newlines as line separators.
"""
last_cr = strg.rfind("\n", 0, loc)
next_cr = strg.find("\n", loc)
return strg[last_cr + 1 : next_cr] if next_cr >= 0 else strg[last_cr + 1 :]
class _UnboundedCache:
def __init__(self):
cache = {}
cache_get = cache.get
self.not_in_cache = not_in_cache = object()
def get(_, key):
return cache_get(key, not_in_cache)
def set_(_, key, value):
cache[key] = value
def clear(_):
cache.clear()
self.size = None
self.get = types.MethodType(get, self)
self.set = types.MethodType(set_, self)
self.clear = types.MethodType(clear, self)
class _FifoCache:
def __init__(self, size):
self.not_in_cache = not_in_cache = object()
cache = collections.OrderedDict()
cache_get = cache.get
def get(_, key):
return cache_get(key, not_in_cache)
def set_(_, key, value):
cache[key] = value
while len(cache) > size:
cache.popitem(last=False)
def clear(_):
cache.clear()
self.size = size
self.get = types.MethodType(get, self)
self.set = types.MethodType(set_, self)
self.clear = types.MethodType(clear, self)
class LRUMemo:
"""
A memoizing mapping that retains `capacity` deleted items
The memo tracks retained items by their access order; once `capacity` items
are retained, the least recently used item is discarded.
"""
def __init__(self, capacity):
self._capacity = capacity
self._active = {}
self._memory = collections.OrderedDict()
def __getitem__(self, key):
try:
return self._active[key]
except KeyError:
self._memory.move_to_end(key)
return self._memory[key]
def __setitem__(self, key, value):
self._memory.pop(key, None)
self._active[key] = value
def __delitem__(self, key):
try:
value = self._active.pop(key)
except KeyError:
pass
else:
while len(self._memory) >= self._capacity:
self._memory.popitem(last=False)
self._memory[key] = value
def clear(self):
self._active.clear()
self._memory.clear()
class UnboundedMemo(dict):
"""
A memoizing mapping that retains all deleted items
"""
def __delitem__(self, key):
pass
def _escape_regex_range_chars(s: str) -> str:
# escape these chars: ^-[]
for c in r"\^-[]":
s = s.replace(c, _bslash + c)
s = s.replace("\n", r"\n")
s = s.replace("\t", r"\t")
return str(s)
def _collapse_string_to_ranges(
s: Union[str, Iterable[str]], re_escape: bool = True
) -> str:
def is_consecutive(c):
c_int = ord(c)
is_consecutive.prev, prev = c_int, is_consecutive.prev
if c_int - prev > 1:
is_consecutive.value = next(is_consecutive.counter)
return is_consecutive.value
is_consecutive.prev = 0
is_consecutive.counter = itertools.count()
is_consecutive.value = -1
def escape_re_range_char(c):
return "\\" + c if c in r"\^-][" else c
def no_escape_re_range_char(c):
return c
if not re_escape:
escape_re_range_char = no_escape_re_range_char
ret = []
s = "".join(sorted(set(s)))
if len(s) > 3:
for _, chars in itertools.groupby(s, key=is_consecutive):
first = last = next(chars)
last = collections.deque(
itertools.chain(iter([last]), chars), maxlen=1
).pop()
if first == last:
ret.append(escape_re_range_char(first))
else:
sep = "" if ord(last) == ord(first) + 1 else "-"
ret.append(
"{}{}{}".format(
escape_re_range_char(first), sep, escape_re_range_char(last)
)
)
else:
ret = [escape_re_range_char(c) for c in s]
return "".join(ret)
def _flatten(ll: list) -> list:
ret = []
for i in ll:
if isinstance(i, list):
ret.extend(_flatten(i))
else:
ret.append(i)
return ret
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/pyparsing/util.py
|
Python
|
mit
| 6,805 |
import io
import posixpath
import zipfile
import itertools
import contextlib
import sys
import pathlib
if sys.version_info < (3, 7):
from collections import OrderedDict
else:
OrderedDict = dict
__all__ = ['Path']
def _parents(path):
"""
Given a path with elements separated by
posixpath.sep, generate all parents of that path.
>>> list(_parents('b/d'))
['b']
>>> list(_parents('/b/d/'))
['/b']
>>> list(_parents('b/d/f/'))
['b/d', 'b']
>>> list(_parents('b'))
[]
>>> list(_parents(''))
[]
"""
return itertools.islice(_ancestry(path), 1, None)
def _ancestry(path):
"""
Given a path with elements separated by
posixpath.sep, generate all elements of that path
>>> list(_ancestry('b/d'))
['b/d', 'b']
>>> list(_ancestry('/b/d/'))
['/b/d', '/b']
>>> list(_ancestry('b/d/f/'))
['b/d/f', 'b/d', 'b']
>>> list(_ancestry('b'))
['b']
>>> list(_ancestry(''))
[]
"""
path = path.rstrip(posixpath.sep)
while path and path != posixpath.sep:
yield path
path, tail = posixpath.split(path)
_dedupe = OrderedDict.fromkeys
"""Deduplicate an iterable in original order"""
def _difference(minuend, subtrahend):
"""
Return items in minuend not in subtrahend, retaining order
with O(1) lookup.
"""
return itertools.filterfalse(set(subtrahend).__contains__, minuend)
class CompleteDirs(zipfile.ZipFile):
"""
A ZipFile subclass that ensures that implied directories
are always included in the namelist.
"""
@staticmethod
def _implied_dirs(names):
parents = itertools.chain.from_iterable(map(_parents, names))
as_dirs = (p + posixpath.sep for p in parents)
return _dedupe(_difference(as_dirs, names))
def namelist(self):
names = super(CompleteDirs, self).namelist()
return names + list(self._implied_dirs(names))
def _name_set(self):
return set(self.namelist())
def resolve_dir(self, name):
"""
If the name represents a directory, return that name
as a directory (with the trailing slash).
"""
names = self._name_set()
dirname = name + '/'
dir_match = name not in names and dirname in names
return dirname if dir_match else name
@classmethod
def make(cls, source):
"""
Given a source (filename or zipfile), return an
appropriate CompleteDirs subclass.
"""
if isinstance(source, CompleteDirs):
return source
if not isinstance(source, zipfile.ZipFile):
return cls(_pathlib_compat(source))
# Only allow for FastLookup when supplied zipfile is read-only
if 'r' not in source.mode:
cls = CompleteDirs
source.__class__ = cls
return source
class FastLookup(CompleteDirs):
"""
ZipFile subclass to ensure implicit
dirs exist and are resolved rapidly.
"""
def namelist(self):
with contextlib.suppress(AttributeError):
return self.__names
self.__names = super(FastLookup, self).namelist()
return self.__names
def _name_set(self):
with contextlib.suppress(AttributeError):
return self.__lookup
self.__lookup = super(FastLookup, self)._name_set()
return self.__lookup
def _pathlib_compat(path):
"""
For path-like objects, convert to a filename for compatibility
on Python 3.6.1 and earlier.
"""
try:
return path.__fspath__()
except AttributeError:
return str(path)
class Path:
"""
A pathlib-compatible interface for zip files.
Consider a zip file with this structure::
.
├── a.txt
└── b
├── c.txt
└── d
└── e.txt
>>> data = io.BytesIO()
>>> zf = zipfile.ZipFile(data, 'w')
>>> zf.writestr('a.txt', 'content of a')
>>> zf.writestr('b/c.txt', 'content of c')
>>> zf.writestr('b/d/e.txt', 'content of e')
>>> zf.filename = 'mem/abcde.zip'
Path accepts the zipfile object itself or a filename
>>> root = Path(zf)
From there, several path operations are available.
Directory iteration (including the zip file itself):
>>> a, b = root.iterdir()
>>> a
Path('mem/abcde.zip', 'a.txt')
>>> b
Path('mem/abcde.zip', 'b/')
name property:
>>> b.name
'b'
join with divide operator:
>>> c = b / 'c.txt'
>>> c
Path('mem/abcde.zip', 'b/c.txt')
>>> c.name
'c.txt'
Read text:
>>> c.read_text()
'content of c'
existence:
>>> c.exists()
True
>>> (b / 'missing.txt').exists()
False
Coercion to string:
>>> import os
>>> str(c).replace(os.sep, posixpath.sep)
'mem/abcde.zip/b/c.txt'
At the root, ``name``, ``filename``, and ``parent``
resolve to the zipfile. Note these attributes are not
valid and will raise a ``ValueError`` if the zipfile
has no filename.
>>> root.name
'abcde.zip'
>>> str(root.filename).replace(os.sep, posixpath.sep)
'mem/abcde.zip'
>>> str(root.parent)
'mem'
"""
__repr = "{self.__class__.__name__}({self.root.filename!r}, {self.at!r})"
def __init__(self, root, at=""):
"""
Construct a Path from a ZipFile or filename.
Note: When the source is an existing ZipFile object,
its type (__class__) will be mutated to a
specialized type. If the caller wishes to retain the
original type, the caller should either create a
separate ZipFile object or pass a filename.
"""
self.root = FastLookup.make(root)
self.at = at
def open(self, mode='r', *args, pwd=None, **kwargs):
"""
Open this entry as text or binary following the semantics
of ``pathlib.Path.open()`` by passing arguments through
to io.TextIOWrapper().
"""
if self.is_dir():
raise IsADirectoryError(self)
zip_mode = mode[0]
if not self.exists() and zip_mode == 'r':
raise FileNotFoundError(self)
stream = self.root.open(self.at, zip_mode, pwd=pwd)
if 'b' in mode:
if args or kwargs:
raise ValueError("encoding args invalid for binary operation")
return stream
return io.TextIOWrapper(stream, *args, **kwargs)
@property
def name(self):
return pathlib.Path(self.at).name or self.filename.name
@property
def suffix(self):
return pathlib.Path(self.at).suffix or self.filename.suffix
@property
def suffixes(self):
return pathlib.Path(self.at).suffixes or self.filename.suffixes
@property
def stem(self):
return pathlib.Path(self.at).stem or self.filename.stem
@property
def filename(self):
return pathlib.Path(self.root.filename).joinpath(self.at)
def read_text(self, *args, **kwargs):
with self.open('r', *args, **kwargs) as strm:
return strm.read()
def read_bytes(self):
with self.open('rb') as strm:
return strm.read()
def _is_child(self, path):
return posixpath.dirname(path.at.rstrip("/")) == self.at.rstrip("/")
def _next(self, at):
return self.__class__(self.root, at)
def is_dir(self):
return not self.at or self.at.endswith("/")
def is_file(self):
return self.exists() and not self.is_dir()
def exists(self):
return self.at in self.root._name_set()
def iterdir(self):
if not self.is_dir():
raise ValueError("Can't listdir a file")
subs = map(self._next, self.root.namelist())
return filter(self._is_child, subs)
def __str__(self):
return posixpath.join(self.root.filename, self.at)
def __repr__(self):
return self.__repr.format(self=self)
def joinpath(self, *other):
next = posixpath.join(self.at, *map(_pathlib_compat, other))
return self._next(self.root.resolve_dir(next))
__truediv__ = joinpath
@property
def parent(self):
if not self.at:
return self.filename.parent
parent_at = posixpath.dirname(self.at.rstrip('/'))
if parent_at:
parent_at += '/'
return self._next(parent_at)
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/_vendor/zipp.py
|
Python
|
mit
| 8,425 |
import importlib.util
import sys
class VendorImporter:
"""
A PEP 302 meta path importer for finding optionally-vendored
or otherwise naturally-installed packages from root_name.
"""
def __init__(self, root_name, vendored_names=(), vendor_pkg=None):
self.root_name = root_name
self.vendored_names = set(vendored_names)
self.vendor_pkg = vendor_pkg or root_name.replace('extern', '_vendor')
@property
def search_path(self):
"""
Search first the vendor package then as a natural package.
"""
yield self.vendor_pkg + '.'
yield ''
def _module_matches_namespace(self, fullname):
"""Figure out if the target module is vendored."""
root, base, target = fullname.partition(self.root_name + '.')
return not root and any(map(target.startswith, self.vendored_names))
def load_module(self, fullname):
"""
Iterate over the search path to locate and load fullname.
"""
root, base, target = fullname.partition(self.root_name + '.')
for prefix in self.search_path:
try:
extant = prefix + target
__import__(extant)
mod = sys.modules[extant]
sys.modules[fullname] = mod
return mod
except ImportError:
pass
else:
raise ImportError(
"The '{target}' package is required; "
"normally this is bundled with this package so if you get "
"this warning, consult the packager of your "
"distribution.".format(**locals())
)
def create_module(self, spec):
return self.load_module(spec.name)
def exec_module(self, module):
pass
def find_spec(self, fullname, path=None, target=None):
"""Return a module spec for vendored names."""
return (
importlib.util.spec_from_loader(fullname, self)
if self._module_matches_namespace(fullname) else None
)
def install(self):
"""
Install this importer into sys.meta_path if not already present.
"""
if self not in sys.meta_path:
sys.meta_path.append(self)
names = (
'packaging', 'pyparsing', 'appdirs', 'jaraco', 'importlib_resources',
'more_itertools',
)
VendorImporter(__name__, names).install()
|
castiel248/Convert
|
Lib/site-packages/pkg_resources/extern/__init__.py
|
Python
|
mit
| 2,426 |
pip
|
castiel248/Convert
|
Lib/site-packages/setuptools-65.5.0.dist-info/INSTALLER
|
none
|
mit
| 4 |
Metadata-Version: 2.1
Name: setuptools
Version: 65.5.0
Summary: Easily download, build, install, upgrade, and uninstall Python packages
Home-page: https://github.com/pypa/setuptools
Author: Python Packaging Authority
Author-email: distutils-sig@python.org
Project-URL: Documentation, https://setuptools.pypa.io/
Project-URL: Changelog, https://setuptools.pypa.io/en/stable/history.html
Keywords: CPAN PyPI distutils eggs package management
Classifier: Development Status :: 5 - Production/Stable
Classifier: Intended Audience :: Developers
Classifier: License :: OSI Approved :: MIT License
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3 :: Only
Classifier: Topic :: Software Development :: Libraries :: Python Modules
Classifier: Topic :: System :: Archiving :: Packaging
Classifier: Topic :: System :: Systems Administration
Classifier: Topic :: Utilities
Requires-Python: >=3.7
License-File: LICENSE
Provides-Extra: certs
Provides-Extra: docs
Requires-Dist: sphinx (>=3.5) ; extra == 'docs'
Requires-Dist: jaraco.packaging (>=9) ; extra == 'docs'
Requires-Dist: rst.linker (>=1.9) ; extra == 'docs'
Requires-Dist: furo ; extra == 'docs'
Requires-Dist: jaraco.tidelift (>=1.4) ; extra == 'docs'
Requires-Dist: pygments-github-lexers (==0.0.5) ; extra == 'docs'
Requires-Dist: sphinx-favicon ; extra == 'docs'
Requires-Dist: sphinx-inline-tabs ; extra == 'docs'
Requires-Dist: sphinx-reredirects ; extra == 'docs'
Requires-Dist: sphinxcontrib-towncrier ; extra == 'docs'
Requires-Dist: sphinx-notfound-page (==0.8.3) ; extra == 'docs'
Requires-Dist: sphinx-hoverxref (<2) ; extra == 'docs'
Provides-Extra: ssl
Provides-Extra: testing
Requires-Dist: pytest (>=6) ; extra == 'testing'
Requires-Dist: pytest-checkdocs (>=2.4) ; extra == 'testing'
Requires-Dist: pytest-flake8 ; extra == 'testing'
Requires-Dist: flake8 (<5) ; extra == 'testing'
Requires-Dist: pytest-enabler (>=1.3) ; extra == 'testing'
Requires-Dist: pytest-perf ; extra == 'testing'
Requires-Dist: mock ; extra == 'testing'
Requires-Dist: flake8-2020 ; extra == 'testing'
Requires-Dist: virtualenv (>=13.0.0) ; extra == 'testing'
Requires-Dist: wheel ; extra == 'testing'
Requires-Dist: pip (>=19.1) ; extra == 'testing'
Requires-Dist: jaraco.envs (>=2.2) ; extra == 'testing'
Requires-Dist: pytest-xdist ; extra == 'testing'
Requires-Dist: jaraco.path (>=3.2.0) ; extra == 'testing'
Requires-Dist: build[virtualenv] ; extra == 'testing'
Requires-Dist: filelock (>=3.4.0) ; extra == 'testing'
Requires-Dist: pip-run (>=8.8) ; extra == 'testing'
Requires-Dist: ini2toml[lite] (>=0.9) ; extra == 'testing'
Requires-Dist: tomli-w (>=1.0.0) ; extra == 'testing'
Provides-Extra: testing-integration
Requires-Dist: pytest ; extra == 'testing-integration'
Requires-Dist: pytest-xdist ; extra == 'testing-integration'
Requires-Dist: pytest-enabler ; extra == 'testing-integration'
Requires-Dist: virtualenv (>=13.0.0) ; extra == 'testing-integration'
Requires-Dist: tomli ; extra == 'testing-integration'
Requires-Dist: wheel ; extra == 'testing-integration'
Requires-Dist: jaraco.path (>=3.2.0) ; extra == 'testing-integration'
Requires-Dist: jaraco.envs (>=2.2) ; extra == 'testing-integration'
Requires-Dist: build[virtualenv] ; extra == 'testing-integration'
Requires-Dist: filelock (>=3.4.0) ; extra == 'testing-integration'
Requires-Dist: pytest-black (>=0.3.7) ; (platform_python_implementation != "PyPy") and extra == 'testing'
Requires-Dist: pytest-cov ; (platform_python_implementation != "PyPy") and extra == 'testing'
Requires-Dist: pytest-mypy (>=0.9.1) ; (platform_python_implementation != "PyPy") and extra == 'testing'
.. image:: https://raw.githubusercontent.com/pypa/setuptools/main/docs/images/banner-640x320.svg
:align: center
|
.. image:: https://img.shields.io/pypi/v/setuptools.svg
:target: `PyPI link`_
.. image:: https://img.shields.io/pypi/pyversions/setuptools.svg
:target: `PyPI link`_
.. _PyPI link: https://pypi.org/project/setuptools
.. image:: https://github.com/pypa/setuptools/workflows/tests/badge.svg
:target: https://github.com/pypa/setuptools/actions?query=workflow%3A%22tests%22
:alt: tests
.. image:: https://img.shields.io/badge/code%20style-black-000000.svg
:target: https://github.com/psf/black
:alt: Code style: Black
.. image:: https://img.shields.io/readthedocs/setuptools/latest.svg
:target: https://setuptools.pypa.io
.. image:: https://img.shields.io/badge/skeleton-2022-informational
:target: https://blog.jaraco.com/skeleton
.. image:: https://img.shields.io/codecov/c/github/pypa/setuptools/master.svg?logo=codecov&logoColor=white
:target: https://codecov.io/gh/pypa/setuptools
.. image:: https://tidelift.com/badges/github/pypa/setuptools?style=flat
:target: https://tidelift.com/subscription/pkg/pypi-setuptools?utm_source=pypi-setuptools&utm_medium=readme
.. image:: https://img.shields.io/discord/803025117553754132
:target: https://discord.com/channels/803025117553754132/815945031150993468
:alt: Discord
See the `Installation Instructions
<https://packaging.python.org/installing/>`_ in the Python Packaging
User's Guide for instructions on installing, upgrading, and uninstalling
Setuptools.
Questions and comments should be directed to `GitHub Discussions
<https://github.com/pypa/setuptools/discussions>`_.
Bug reports and especially tested patches may be
submitted directly to the `bug tracker
<https://github.com/pypa/setuptools/issues>`_.
Code of Conduct
===============
Everyone interacting in the setuptools project's codebases, issue trackers,
chat rooms, and fora is expected to follow the
`PSF Code of Conduct <https://github.com/pypa/.github/blob/main/CODE_OF_CONDUCT.md>`_.
For Enterprise
==============
Available as part of the Tidelift Subscription.
Setuptools and the maintainers of thousands of other packages are working with Tidelift to deliver one enterprise subscription that covers all of the open source you use.
`Learn more <https://tidelift.com/subscription/pkg/pypi-setuptools?utm_source=pypi-setuptools&utm_medium=referral&utm_campaign=github>`_.
Security Contact
================
To report a security vulnerability, please use the
`Tidelift security contact <https://tidelift.com/security>`_.
Tidelift will coordinate the fix and disclosure.
|
castiel248/Convert
|
Lib/site-packages/setuptools-65.5.0.dist-info/METADATA
|
none
|
mit
| 6,301 |
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castiel248/Convert
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Lib/site-packages/setuptools-65.5.0.dist-info/RECORD
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none
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mit
| 37,228 |
castiel248/Convert
|
Lib/site-packages/setuptools-65.5.0.dist-info/REQUESTED
|
none
|
mit
| 0 |
|
Wheel-Version: 1.0
Generator: bdist_wheel (0.37.1)
Root-Is-Purelib: true
Tag: py3-none-any
|
castiel248/Convert
|
Lib/site-packages/setuptools-65.5.0.dist-info/WHEEL
|
none
|
mit
| 92 |
[distutils.commands]
alias = setuptools.command.alias:alias
bdist_egg = setuptools.command.bdist_egg:bdist_egg
bdist_rpm = setuptools.command.bdist_rpm:bdist_rpm
build = setuptools.command.build:build
build_clib = setuptools.command.build_clib:build_clib
build_ext = setuptools.command.build_ext:build_ext
build_py = setuptools.command.build_py:build_py
develop = setuptools.command.develop:develop
dist_info = setuptools.command.dist_info:dist_info
easy_install = setuptools.command.easy_install:easy_install
editable_wheel = setuptools.command.editable_wheel:editable_wheel
egg_info = setuptools.command.egg_info:egg_info
install = setuptools.command.install:install
install_egg_info = setuptools.command.install_egg_info:install_egg_info
install_lib = setuptools.command.install_lib:install_lib
install_scripts = setuptools.command.install_scripts:install_scripts
rotate = setuptools.command.rotate:rotate
saveopts = setuptools.command.saveopts:saveopts
sdist = setuptools.command.sdist:sdist
setopt = setuptools.command.setopt:setopt
test = setuptools.command.test:test
upload_docs = setuptools.command.upload_docs:upload_docs
[distutils.setup_keywords]
dependency_links = setuptools.dist:assert_string_list
eager_resources = setuptools.dist:assert_string_list
entry_points = setuptools.dist:check_entry_points
exclude_package_data = setuptools.dist:check_package_data
extras_require = setuptools.dist:check_extras
include_package_data = setuptools.dist:assert_bool
install_requires = setuptools.dist:check_requirements
namespace_packages = setuptools.dist:check_nsp
package_data = setuptools.dist:check_package_data
packages = setuptools.dist:check_packages
python_requires = setuptools.dist:check_specifier
setup_requires = setuptools.dist:check_requirements
test_loader = setuptools.dist:check_importable
test_runner = setuptools.dist:check_importable
test_suite = setuptools.dist:check_test_suite
tests_require = setuptools.dist:check_requirements
use_2to3 = setuptools.dist:invalid_unless_false
zip_safe = setuptools.dist:assert_bool
[egg_info.writers]
PKG-INFO = setuptools.command.egg_info:write_pkg_info
dependency_links.txt = setuptools.command.egg_info:overwrite_arg
depends.txt = setuptools.command.egg_info:warn_depends_obsolete
eager_resources.txt = setuptools.command.egg_info:overwrite_arg
entry_points.txt = setuptools.command.egg_info:write_entries
namespace_packages.txt = setuptools.command.egg_info:overwrite_arg
requires.txt = setuptools.command.egg_info:write_requirements
top_level.txt = setuptools.command.egg_info:write_toplevel_names
[setuptools.finalize_distribution_options]
keywords = setuptools.dist:Distribution._finalize_setup_keywords
parent_finalize = setuptools.dist:_Distribution.finalize_options
|
castiel248/Convert
|
Lib/site-packages/setuptools-65.5.0.dist-info/entry_points.txt
|
Text
|
mit
| 2,740 |
_distutils_hack
pkg_resources
setuptools
|
castiel248/Convert
|
Lib/site-packages/setuptools-65.5.0.dist-info/top_level.txt
|
Text
|
mit
| 41 |
"""Extensions to the 'distutils' for large or complex distributions"""
import functools
import os
import re
import warnings
import _distutils_hack.override # noqa: F401
import distutils.core
from distutils.errors import DistutilsOptionError
from distutils.util import convert_path as _convert_path
from ._deprecation_warning import SetuptoolsDeprecationWarning
import setuptools.version
from setuptools.extension import Extension
from setuptools.dist import Distribution
from setuptools.depends import Require
from setuptools.discovery import PackageFinder, PEP420PackageFinder
from . import monkey
from . import logging
__all__ = [
'setup',
'Distribution',
'Command',
'Extension',
'Require',
'SetuptoolsDeprecationWarning',
'find_packages',
'find_namespace_packages',
]
__version__ = setuptools.version.__version__
bootstrap_install_from = None
find_packages = PackageFinder.find
find_namespace_packages = PEP420PackageFinder.find
def _install_setup_requires(attrs):
# Note: do not use `setuptools.Distribution` directly, as
# our PEP 517 backend patch `distutils.core.Distribution`.
class MinimalDistribution(distutils.core.Distribution):
"""
A minimal version of a distribution for supporting the
fetch_build_eggs interface.
"""
def __init__(self, attrs):
_incl = 'dependency_links', 'setup_requires'
filtered = {k: attrs[k] for k in set(_incl) & set(attrs)}
super().__init__(filtered)
# Prevent accidentally triggering discovery with incomplete set of attrs
self.set_defaults._disable()
def _get_project_config_files(self, filenames=None):
"""Ignore ``pyproject.toml``, they are not related to setup_requires"""
try:
cfg, toml = super()._split_standard_project_metadata(filenames)
return cfg, ()
except Exception:
return filenames, ()
def finalize_options(self):
"""
Disable finalize_options to avoid building the working set.
Ref #2158.
"""
dist = MinimalDistribution(attrs)
# Honor setup.cfg's options.
dist.parse_config_files(ignore_option_errors=True)
if dist.setup_requires:
dist.fetch_build_eggs(dist.setup_requires)
def setup(**attrs):
# Make sure we have any requirements needed to interpret 'attrs'.
logging.configure()
_install_setup_requires(attrs)
return distutils.core.setup(**attrs)
setup.__doc__ = distutils.core.setup.__doc__
_Command = monkey.get_unpatched(distutils.core.Command)
class Command(_Command):
"""
Setuptools internal actions are organized using a *command design pattern*.
This means that each action (or group of closely related actions) executed during
the build should be implemented as a ``Command`` subclass.
These commands are abstractions and do not necessarily correspond to a command that
can (or should) be executed via a terminal, in a CLI fashion (although historically
they would).
When creating a new command from scratch, custom defined classes **SHOULD** inherit
from ``setuptools.Command`` and implement a few mandatory methods.
Between these mandatory methods, are listed:
.. method:: initialize_options(self)
Set or (reset) all options/attributes/caches used by the command
to their default values. Note that these values may be overwritten during
the build.
.. method:: finalize_options(self)
Set final values for all options/attributes used by the command.
Most of the time, each option/attribute/cache should only be set if it does not
have any value yet (e.g. ``if self.attr is None: self.attr = val``).
.. method:: run(self)
Execute the actions intended by the command.
(Side effects **SHOULD** only take place when ``run`` is executed,
for example, creating new files or writing to the terminal output).
A useful analogy for command classes is to think of them as subroutines with local
variables called "options". The options are "declared" in ``initialize_options()``
and "defined" (given their final values, aka "finalized") in ``finalize_options()``,
both of which must be defined by every command class. The "body" of the subroutine,
(where it does all the work) is the ``run()`` method.
Between ``initialize_options()`` and ``finalize_options()``, ``setuptools`` may set
the values for options/attributes based on user's input (or circumstance),
which means that the implementation should be careful to not overwrite values in
``finalize_options`` unless necessary.
Please note that other commands (or other parts of setuptools) may also overwrite
the values of the command's options/attributes multiple times during the build
process.
Therefore it is important to consistently implement ``initialize_options()`` and
``finalize_options()``. For example, all derived attributes (or attributes that
depend on the value of other attributes) **SHOULD** be recomputed in
``finalize_options``.
When overwriting existing commands, custom defined classes **MUST** abide by the
same APIs implemented by the original class. They also **SHOULD** inherit from the
original class.
"""
command_consumes_arguments = False
def __init__(self, dist, **kw):
"""
Construct the command for dist, updating
vars(self) with any keyword parameters.
"""
super().__init__(dist)
vars(self).update(kw)
def _ensure_stringlike(self, option, what, default=None):
val = getattr(self, option)
if val is None:
setattr(self, option, default)
return default
elif not isinstance(val, str):
raise DistutilsOptionError(
"'%s' must be a %s (got `%s`)" % (option, what, val)
)
return val
def ensure_string_list(self, option):
r"""Ensure that 'option' is a list of strings. If 'option' is
currently a string, we split it either on /,\s*/ or /\s+/, so
"foo bar baz", "foo,bar,baz", and "foo, bar baz" all become
["foo", "bar", "baz"].
..
TODO: This method seems to be similar to the one in ``distutils.cmd``
Probably it is just here for backward compatibility with old Python versions?
:meta private:
"""
val = getattr(self, option)
if val is None:
return
elif isinstance(val, str):
setattr(self, option, re.split(r',\s*|\s+', val))
else:
if isinstance(val, list):
ok = all(isinstance(v, str) for v in val)
else:
ok = False
if not ok:
raise DistutilsOptionError(
"'%s' must be a list of strings (got %r)" % (option, val)
)
def reinitialize_command(self, command, reinit_subcommands=0, **kw):
cmd = _Command.reinitialize_command(self, command, reinit_subcommands)
vars(cmd).update(kw)
return cmd
def _find_all_simple(path):
"""
Find all files under 'path'
"""
results = (
os.path.join(base, file)
for base, dirs, files in os.walk(path, followlinks=True)
for file in files
)
return filter(os.path.isfile, results)
def findall(dir=os.curdir):
"""
Find all files under 'dir' and return the list of full filenames.
Unless dir is '.', return full filenames with dir prepended.
"""
files = _find_all_simple(dir)
if dir == os.curdir:
make_rel = functools.partial(os.path.relpath, start=dir)
files = map(make_rel, files)
return list(files)
@functools.wraps(_convert_path)
def convert_path(pathname):
from inspect import cleandoc
msg = """
The function `convert_path` is considered internal and not part of the public API.
Its direct usage by 3rd-party packages is considered deprecated and the function
may be removed in the future.
"""
warnings.warn(cleandoc(msg), SetuptoolsDeprecationWarning)
return _convert_path(pathname)
class sic(str):
"""Treat this string as-is (https://en.wikipedia.org/wiki/Sic)"""
# Apply monkey patches
monkey.patch_all()
|
castiel248/Convert
|
Lib/site-packages/setuptools/__init__.py
|
Python
|
mit
| 8,429 |
class SetuptoolsDeprecationWarning(Warning):
"""
Base class for warning deprecations in ``setuptools``
This class is not derived from ``DeprecationWarning``, and as such is
visible by default.
"""
|
castiel248/Convert
|
Lib/site-packages/setuptools/_deprecation_warning.py
|
Python
|
mit
| 218 |
"""distutils
The main package for the Python Module Distribution Utilities. Normally
used from a setup script as
from distutils.core import setup
setup (...)
"""
import sys
import importlib
__version__ = sys.version[: sys.version.index(' ')]
try:
# Allow Debian and pkgsrc (only) to customize system
# behavior. Ref pypa/distutils#2 and pypa/distutils#16.
# This hook is deprecated and no other environments
# should use it.
importlib.import_module('_distutils_system_mod')
except ImportError:
pass
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/__init__.py
|
Python
|
mit
| 537 |
import collections
import itertools
# from jaraco.collections 3.5.1
class DictStack(list, collections.abc.Mapping):
"""
A stack of dictionaries that behaves as a view on those dictionaries,
giving preference to the last.
>>> stack = DictStack([dict(a=1, c=2), dict(b=2, a=2)])
>>> stack['a']
2
>>> stack['b']
2
>>> stack['c']
2
>>> len(stack)
3
>>> stack.push(dict(a=3))
>>> stack['a']
3
>>> set(stack.keys()) == set(['a', 'b', 'c'])
True
>>> set(stack.items()) == set([('a', 3), ('b', 2), ('c', 2)])
True
>>> dict(**stack) == dict(stack) == dict(a=3, c=2, b=2)
True
>>> d = stack.pop()
>>> stack['a']
2
>>> d = stack.pop()
>>> stack['a']
1
>>> stack.get('b', None)
>>> 'c' in stack
True
"""
def __iter__(self):
dicts = list.__iter__(self)
return iter(set(itertools.chain.from_iterable(c.keys() for c in dicts)))
def __getitem__(self, key):
for scope in reversed(tuple(list.__iter__(self))):
if key in scope:
return scope[key]
raise KeyError(key)
push = list.append
def __contains__(self, other):
return collections.abc.Mapping.__contains__(self, other)
def __len__(self):
return len(list(iter(self)))
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/_collections.py
|
Python
|
mit
| 1,330 |
import functools
# from jaraco.functools 3.5
def pass_none(func):
"""
Wrap func so it's not called if its first param is None
>>> print_text = pass_none(print)
>>> print_text('text')
text
>>> print_text(None)
"""
@functools.wraps(func)
def wrapper(param, *args, **kwargs):
if param is not None:
return func(param, *args, **kwargs)
return wrapper
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/_functools.py
|
Python
|
mit
| 411 |
import sys
import importlib
def bypass_compiler_fixup(cmd, args):
return cmd
if sys.platform == 'darwin':
compiler_fixup = importlib.import_module('_osx_support').compiler_fixup
else:
compiler_fixup = bypass_compiler_fixup
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/_macos_compat.py
|
Python
|
mit
| 239 |
"""distutils._msvccompiler
Contains MSVCCompiler, an implementation of the abstract CCompiler class
for Microsoft Visual Studio 2015.
The module is compatible with VS 2015 and later. You can find legacy support
for older versions in distutils.msvc9compiler and distutils.msvccompiler.
"""
# Written by Perry Stoll
# hacked by Robin Becker and Thomas Heller to do a better job of
# finding DevStudio (through the registry)
# ported to VS 2005 and VS 2008 by Christian Heimes
# ported to VS 2015 by Steve Dower
import os
import subprocess
import contextlib
import warnings
import unittest.mock as mock
with contextlib.suppress(ImportError):
import winreg
from distutils.errors import (
DistutilsExecError,
DistutilsPlatformError,
CompileError,
LibError,
LinkError,
)
from distutils.ccompiler import CCompiler, gen_lib_options
from distutils import log
from distutils.util import get_platform
from itertools import count
def _find_vc2015():
try:
key = winreg.OpenKeyEx(
winreg.HKEY_LOCAL_MACHINE,
r"Software\Microsoft\VisualStudio\SxS\VC7",
access=winreg.KEY_READ | winreg.KEY_WOW64_32KEY,
)
except OSError:
log.debug("Visual C++ is not registered")
return None, None
best_version = 0
best_dir = None
with key:
for i in count():
try:
v, vc_dir, vt = winreg.EnumValue(key, i)
except OSError:
break
if v and vt == winreg.REG_SZ and os.path.isdir(vc_dir):
try:
version = int(float(v))
except (ValueError, TypeError):
continue
if version >= 14 and version > best_version:
best_version, best_dir = version, vc_dir
return best_version, best_dir
def _find_vc2017():
"""Returns "15, path" based on the result of invoking vswhere.exe
If no install is found, returns "None, None"
The version is returned to avoid unnecessarily changing the function
result. It may be ignored when the path is not None.
If vswhere.exe is not available, by definition, VS 2017 is not
installed.
"""
root = os.environ.get("ProgramFiles(x86)") or os.environ.get("ProgramFiles")
if not root:
return None, None
try:
path = subprocess.check_output(
[
os.path.join(
root, "Microsoft Visual Studio", "Installer", "vswhere.exe"
),
"-latest",
"-prerelease",
"-requires",
"Microsoft.VisualStudio.Component.VC.Tools.x86.x64",
"-property",
"installationPath",
"-products",
"*",
],
encoding="mbcs",
errors="strict",
).strip()
except (subprocess.CalledProcessError, OSError, UnicodeDecodeError):
return None, None
path = os.path.join(path, "VC", "Auxiliary", "Build")
if os.path.isdir(path):
return 15, path
return None, None
PLAT_SPEC_TO_RUNTIME = {
'x86': 'x86',
'x86_amd64': 'x64',
'x86_arm': 'arm',
'x86_arm64': 'arm64',
}
def _find_vcvarsall(plat_spec):
# bpo-38597: Removed vcruntime return value
_, best_dir = _find_vc2017()
if not best_dir:
best_version, best_dir = _find_vc2015()
if not best_dir:
log.debug("No suitable Visual C++ version found")
return None, None
vcvarsall = os.path.join(best_dir, "vcvarsall.bat")
if not os.path.isfile(vcvarsall):
log.debug("%s cannot be found", vcvarsall)
return None, None
return vcvarsall, None
def _get_vc_env(plat_spec):
if os.getenv("DISTUTILS_USE_SDK"):
return {key.lower(): value for key, value in os.environ.items()}
vcvarsall, _ = _find_vcvarsall(plat_spec)
if not vcvarsall:
raise DistutilsPlatformError("Unable to find vcvarsall.bat")
try:
out = subprocess.check_output(
f'cmd /u /c "{vcvarsall}" {plat_spec} && set',
stderr=subprocess.STDOUT,
).decode('utf-16le', errors='replace')
except subprocess.CalledProcessError as exc:
log.error(exc.output)
raise DistutilsPlatformError(f"Error executing {exc.cmd}")
env = {
key.lower(): value
for key, _, value in (line.partition('=') for line in out.splitlines())
if key and value
}
return env
def _find_exe(exe, paths=None):
"""Return path to an MSVC executable program.
Tries to find the program in several places: first, one of the
MSVC program search paths from the registry; next, the directories
in the PATH environment variable. If any of those work, return an
absolute path that is known to exist. If none of them work, just
return the original program name, 'exe'.
"""
if not paths:
paths = os.getenv('path').split(os.pathsep)
for p in paths:
fn = os.path.join(os.path.abspath(p), exe)
if os.path.isfile(fn):
return fn
return exe
# A map keyed by get_platform() return values to values accepted by
# 'vcvarsall.bat'. Always cross-compile from x86 to work with the
# lighter-weight MSVC installs that do not include native 64-bit tools.
PLAT_TO_VCVARS = {
'win32': 'x86',
'win-amd64': 'x86_amd64',
'win-arm32': 'x86_arm',
'win-arm64': 'x86_arm64',
}
class MSVCCompiler(CCompiler):
"""Concrete class that implements an interface to Microsoft Visual C++,
as defined by the CCompiler abstract class."""
compiler_type = 'msvc'
# Just set this so CCompiler's constructor doesn't barf. We currently
# don't use the 'set_executables()' bureaucracy provided by CCompiler,
# as it really isn't necessary for this sort of single-compiler class.
# Would be nice to have a consistent interface with UnixCCompiler,
# though, so it's worth thinking about.
executables = {}
# Private class data (need to distinguish C from C++ source for compiler)
_c_extensions = ['.c']
_cpp_extensions = ['.cc', '.cpp', '.cxx']
_rc_extensions = ['.rc']
_mc_extensions = ['.mc']
# Needed for the filename generation methods provided by the
# base class, CCompiler.
src_extensions = _c_extensions + _cpp_extensions + _rc_extensions + _mc_extensions
res_extension = '.res'
obj_extension = '.obj'
static_lib_extension = '.lib'
shared_lib_extension = '.dll'
static_lib_format = shared_lib_format = '%s%s'
exe_extension = '.exe'
def __init__(self, verbose=0, dry_run=0, force=0):
super().__init__(verbose, dry_run, force)
# target platform (.plat_name is consistent with 'bdist')
self.plat_name = None
self.initialized = False
@classmethod
def _configure(cls, vc_env):
"""
Set class-level include/lib dirs.
"""
cls.include_dirs = cls._parse_path(vc_env.get('include', ''))
cls.library_dirs = cls._parse_path(vc_env.get('lib', ''))
@staticmethod
def _parse_path(val):
return [dir.rstrip(os.sep) for dir in val.split(os.pathsep) if dir]
def initialize(self, plat_name=None):
# multi-init means we would need to check platform same each time...
assert not self.initialized, "don't init multiple times"
if plat_name is None:
plat_name = get_platform()
# sanity check for platforms to prevent obscure errors later.
if plat_name not in PLAT_TO_VCVARS:
raise DistutilsPlatformError(
f"--plat-name must be one of {tuple(PLAT_TO_VCVARS)}"
)
# Get the vcvarsall.bat spec for the requested platform.
plat_spec = PLAT_TO_VCVARS[plat_name]
vc_env = _get_vc_env(plat_spec)
if not vc_env:
raise DistutilsPlatformError(
"Unable to find a compatible " "Visual Studio installation."
)
self._configure(vc_env)
self._paths = vc_env.get('path', '')
paths = self._paths.split(os.pathsep)
self.cc = _find_exe("cl.exe", paths)
self.linker = _find_exe("link.exe", paths)
self.lib = _find_exe("lib.exe", paths)
self.rc = _find_exe("rc.exe", paths) # resource compiler
self.mc = _find_exe("mc.exe", paths) # message compiler
self.mt = _find_exe("mt.exe", paths) # message compiler
self.preprocess_options = None
# bpo-38597: Always compile with dynamic linking
# Future releases of Python 3.x will include all past
# versions of vcruntime*.dll for compatibility.
self.compile_options = ['/nologo', '/O2', '/W3', '/GL', '/DNDEBUG', '/MD']
self.compile_options_debug = [
'/nologo',
'/Od',
'/MDd',
'/Zi',
'/W3',
'/D_DEBUG',
]
ldflags = ['/nologo', '/INCREMENTAL:NO', '/LTCG']
ldflags_debug = ['/nologo', '/INCREMENTAL:NO', '/LTCG', '/DEBUG:FULL']
self.ldflags_exe = [*ldflags, '/MANIFEST:EMBED,ID=1']
self.ldflags_exe_debug = [*ldflags_debug, '/MANIFEST:EMBED,ID=1']
self.ldflags_shared = [
*ldflags,
'/DLL',
'/MANIFEST:EMBED,ID=2',
'/MANIFESTUAC:NO',
]
self.ldflags_shared_debug = [
*ldflags_debug,
'/DLL',
'/MANIFEST:EMBED,ID=2',
'/MANIFESTUAC:NO',
]
self.ldflags_static = [*ldflags]
self.ldflags_static_debug = [*ldflags_debug]
self._ldflags = {
(CCompiler.EXECUTABLE, None): self.ldflags_exe,
(CCompiler.EXECUTABLE, False): self.ldflags_exe,
(CCompiler.EXECUTABLE, True): self.ldflags_exe_debug,
(CCompiler.SHARED_OBJECT, None): self.ldflags_shared,
(CCompiler.SHARED_OBJECT, False): self.ldflags_shared,
(CCompiler.SHARED_OBJECT, True): self.ldflags_shared_debug,
(CCompiler.SHARED_LIBRARY, None): self.ldflags_static,
(CCompiler.SHARED_LIBRARY, False): self.ldflags_static,
(CCompiler.SHARED_LIBRARY, True): self.ldflags_static_debug,
}
self.initialized = True
# -- Worker methods ------------------------------------------------
@property
def out_extensions(self):
return {
**super().out_extensions,
**{
ext: self.res_extension
for ext in self._rc_extensions + self._mc_extensions
},
}
def compile( # noqa: C901
self,
sources,
output_dir=None,
macros=None,
include_dirs=None,
debug=0,
extra_preargs=None,
extra_postargs=None,
depends=None,
):
if not self.initialized:
self.initialize()
compile_info = self._setup_compile(
output_dir, macros, include_dirs, sources, depends, extra_postargs
)
macros, objects, extra_postargs, pp_opts, build = compile_info
compile_opts = extra_preargs or []
compile_opts.append('/c')
if debug:
compile_opts.extend(self.compile_options_debug)
else:
compile_opts.extend(self.compile_options)
add_cpp_opts = False
for obj in objects:
try:
src, ext = build[obj]
except KeyError:
continue
if debug:
# pass the full pathname to MSVC in debug mode,
# this allows the debugger to find the source file
# without asking the user to browse for it
src = os.path.abspath(src)
if ext in self._c_extensions:
input_opt = "/Tc" + src
elif ext in self._cpp_extensions:
input_opt = "/Tp" + src
add_cpp_opts = True
elif ext in self._rc_extensions:
# compile .RC to .RES file
input_opt = src
output_opt = "/fo" + obj
try:
self.spawn([self.rc] + pp_opts + [output_opt, input_opt])
except DistutilsExecError as msg:
raise CompileError(msg)
continue
elif ext in self._mc_extensions:
# Compile .MC to .RC file to .RES file.
# * '-h dir' specifies the directory for the
# generated include file
# * '-r dir' specifies the target directory of the
# generated RC file and the binary message resource
# it includes
#
# For now (since there are no options to change this),
# we use the source-directory for the include file and
# the build directory for the RC file and message
# resources. This works at least for win32all.
h_dir = os.path.dirname(src)
rc_dir = os.path.dirname(obj)
try:
# first compile .MC to .RC and .H file
self.spawn([self.mc, '-h', h_dir, '-r', rc_dir, src])
base, _ = os.path.splitext(os.path.basename(src))
rc_file = os.path.join(rc_dir, base + '.rc')
# then compile .RC to .RES file
self.spawn([self.rc, "/fo" + obj, rc_file])
except DistutilsExecError as msg:
raise CompileError(msg)
continue
else:
# how to handle this file?
raise CompileError(f"Don't know how to compile {src} to {obj}")
args = [self.cc] + compile_opts + pp_opts
if add_cpp_opts:
args.append('/EHsc')
args.append(input_opt)
args.append("/Fo" + obj)
args.extend(extra_postargs)
try:
self.spawn(args)
except DistutilsExecError as msg:
raise CompileError(msg)
return objects
def create_static_lib(
self, objects, output_libname, output_dir=None, debug=0, target_lang=None
):
if not self.initialized:
self.initialize()
objects, output_dir = self._fix_object_args(objects, output_dir)
output_filename = self.library_filename(output_libname, output_dir=output_dir)
if self._need_link(objects, output_filename):
lib_args = objects + ['/OUT:' + output_filename]
if debug:
pass # XXX what goes here?
try:
log.debug('Executing "%s" %s', self.lib, ' '.join(lib_args))
self.spawn([self.lib] + lib_args)
except DistutilsExecError as msg:
raise LibError(msg)
else:
log.debug("skipping %s (up-to-date)", output_filename)
def link(
self,
target_desc,
objects,
output_filename,
output_dir=None,
libraries=None,
library_dirs=None,
runtime_library_dirs=None,
export_symbols=None,
debug=0,
extra_preargs=None,
extra_postargs=None,
build_temp=None,
target_lang=None,
):
if not self.initialized:
self.initialize()
objects, output_dir = self._fix_object_args(objects, output_dir)
fixed_args = self._fix_lib_args(libraries, library_dirs, runtime_library_dirs)
libraries, library_dirs, runtime_library_dirs = fixed_args
if runtime_library_dirs:
self.warn(
"I don't know what to do with 'runtime_library_dirs': "
+ str(runtime_library_dirs)
)
lib_opts = gen_lib_options(self, library_dirs, runtime_library_dirs, libraries)
if output_dir is not None:
output_filename = os.path.join(output_dir, output_filename)
if self._need_link(objects, output_filename):
ldflags = self._ldflags[target_desc, debug]
export_opts = ["/EXPORT:" + sym for sym in (export_symbols or [])]
ld_args = (
ldflags + lib_opts + export_opts + objects + ['/OUT:' + output_filename]
)
# The MSVC linker generates .lib and .exp files, which cannot be
# suppressed by any linker switches. The .lib files may even be
# needed! Make sure they are generated in the temporary build
# directory. Since they have different names for debug and release
# builds, they can go into the same directory.
build_temp = os.path.dirname(objects[0])
if export_symbols is not None:
(dll_name, dll_ext) = os.path.splitext(
os.path.basename(output_filename)
)
implib_file = os.path.join(build_temp, self.library_filename(dll_name))
ld_args.append('/IMPLIB:' + implib_file)
if extra_preargs:
ld_args[:0] = extra_preargs
if extra_postargs:
ld_args.extend(extra_postargs)
output_dir = os.path.dirname(os.path.abspath(output_filename))
self.mkpath(output_dir)
try:
log.debug('Executing "%s" %s', self.linker, ' '.join(ld_args))
self.spawn([self.linker] + ld_args)
except DistutilsExecError as msg:
raise LinkError(msg)
else:
log.debug("skipping %s (up-to-date)", output_filename)
def spawn(self, cmd):
env = dict(os.environ, PATH=self._paths)
with self._fallback_spawn(cmd, env) as fallback:
return super().spawn(cmd, env=env)
return fallback.value
@contextlib.contextmanager
def _fallback_spawn(self, cmd, env):
"""
Discovered in pypa/distutils#15, some tools monkeypatch the compiler,
so the 'env' kwarg causes a TypeError. Detect this condition and
restore the legacy, unsafe behavior.
"""
bag = type('Bag', (), {})()
try:
yield bag
except TypeError as exc:
if "unexpected keyword argument 'env'" not in str(exc):
raise
else:
return
warnings.warn("Fallback spawn triggered. Please update distutils monkeypatch.")
with mock.patch.dict('os.environ', env):
bag.value = super().spawn(cmd)
# -- Miscellaneous methods -----------------------------------------
# These are all used by the 'gen_lib_options() function, in
# ccompiler.py.
def library_dir_option(self, dir):
return "/LIBPATH:" + dir
def runtime_library_dir_option(self, dir):
raise DistutilsPlatformError(
"don't know how to set runtime library search path for MSVC"
)
def library_option(self, lib):
return self.library_filename(lib)
def find_library_file(self, dirs, lib, debug=0):
# Prefer a debugging library if found (and requested), but deal
# with it if we don't have one.
if debug:
try_names = [lib + "_d", lib]
else:
try_names = [lib]
for dir in dirs:
for name in try_names:
libfile = os.path.join(dir, self.library_filename(name))
if os.path.isfile(libfile):
return libfile
else:
# Oops, didn't find it in *any* of 'dirs'
return None
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/_msvccompiler.py
|
Python
|
mit
| 19,672 |
"""distutils.archive_util
Utility functions for creating archive files (tarballs, zip files,
that sort of thing)."""
import os
from warnings import warn
import sys
try:
import zipfile
except ImportError:
zipfile = None
from distutils.errors import DistutilsExecError
from distutils.spawn import spawn
from distutils.dir_util import mkpath
from distutils import log
try:
from pwd import getpwnam
except ImportError:
getpwnam = None
try:
from grp import getgrnam
except ImportError:
getgrnam = None
def _get_gid(name):
"""Returns a gid, given a group name."""
if getgrnam is None or name is None:
return None
try:
result = getgrnam(name)
except KeyError:
result = None
if result is not None:
return result[2]
return None
def _get_uid(name):
"""Returns an uid, given a user name."""
if getpwnam is None or name is None:
return None
try:
result = getpwnam(name)
except KeyError:
result = None
if result is not None:
return result[2]
return None
def make_tarball(
base_name, base_dir, compress="gzip", verbose=0, dry_run=0, owner=None, group=None
):
"""Create a (possibly compressed) tar file from all the files under
'base_dir'.
'compress' must be "gzip" (the default), "bzip2", "xz", "compress", or
None. ("compress" will be deprecated in Python 3.2)
'owner' and 'group' can be used to define an owner and a group for the
archive that is being built. If not provided, the current owner and group
will be used.
The output tar file will be named 'base_dir' + ".tar", possibly plus
the appropriate compression extension (".gz", ".bz2", ".xz" or ".Z").
Returns the output filename.
"""
tar_compression = {
'gzip': 'gz',
'bzip2': 'bz2',
'xz': 'xz',
None: '',
'compress': '',
}
compress_ext = {'gzip': '.gz', 'bzip2': '.bz2', 'xz': '.xz', 'compress': '.Z'}
# flags for compression program, each element of list will be an argument
if compress is not None and compress not in compress_ext.keys():
raise ValueError(
"bad value for 'compress': must be None, 'gzip', 'bzip2', "
"'xz' or 'compress'"
)
archive_name = base_name + '.tar'
if compress != 'compress':
archive_name += compress_ext.get(compress, '')
mkpath(os.path.dirname(archive_name), dry_run=dry_run)
# creating the tarball
import tarfile # late import so Python build itself doesn't break
log.info('Creating tar archive')
uid = _get_uid(owner)
gid = _get_gid(group)
def _set_uid_gid(tarinfo):
if gid is not None:
tarinfo.gid = gid
tarinfo.gname = group
if uid is not None:
tarinfo.uid = uid
tarinfo.uname = owner
return tarinfo
if not dry_run:
tar = tarfile.open(archive_name, 'w|%s' % tar_compression[compress])
try:
tar.add(base_dir, filter=_set_uid_gid)
finally:
tar.close()
# compression using `compress`
if compress == 'compress':
warn("'compress' is deprecated.", DeprecationWarning)
# the option varies depending on the platform
compressed_name = archive_name + compress_ext[compress]
if sys.platform == 'win32':
cmd = [compress, archive_name, compressed_name]
else:
cmd = [compress, '-f', archive_name]
spawn(cmd, dry_run=dry_run)
return compressed_name
return archive_name
def make_zipfile(base_name, base_dir, verbose=0, dry_run=0): # noqa: C901
"""Create a zip file from all the files under 'base_dir'.
The output zip file will be named 'base_name' + ".zip". Uses either the
"zipfile" Python module (if available) or the InfoZIP "zip" utility
(if installed and found on the default search path). If neither tool is
available, raises DistutilsExecError. Returns the name of the output zip
file.
"""
zip_filename = base_name + ".zip"
mkpath(os.path.dirname(zip_filename), dry_run=dry_run)
# If zipfile module is not available, try spawning an external
# 'zip' command.
if zipfile is None:
if verbose:
zipoptions = "-r"
else:
zipoptions = "-rq"
try:
spawn(["zip", zipoptions, zip_filename, base_dir], dry_run=dry_run)
except DistutilsExecError:
# XXX really should distinguish between "couldn't find
# external 'zip' command" and "zip failed".
raise DistutilsExecError(
(
"unable to create zip file '%s': "
"could neither import the 'zipfile' module nor "
"find a standalone zip utility"
)
% zip_filename
)
else:
log.info("creating '%s' and adding '%s' to it", zip_filename, base_dir)
if not dry_run:
try:
zip = zipfile.ZipFile(
zip_filename, "w", compression=zipfile.ZIP_DEFLATED
)
except RuntimeError:
zip = zipfile.ZipFile(zip_filename, "w", compression=zipfile.ZIP_STORED)
with zip:
if base_dir != os.curdir:
path = os.path.normpath(os.path.join(base_dir, ''))
zip.write(path, path)
log.info("adding '%s'", path)
for dirpath, dirnames, filenames in os.walk(base_dir):
for name in dirnames:
path = os.path.normpath(os.path.join(dirpath, name, ''))
zip.write(path, path)
log.info("adding '%s'", path)
for name in filenames:
path = os.path.normpath(os.path.join(dirpath, name))
if os.path.isfile(path):
zip.write(path, path)
log.info("adding '%s'", path)
return zip_filename
ARCHIVE_FORMATS = {
'gztar': (make_tarball, [('compress', 'gzip')], "gzip'ed tar-file"),
'bztar': (make_tarball, [('compress', 'bzip2')], "bzip2'ed tar-file"),
'xztar': (make_tarball, [('compress', 'xz')], "xz'ed tar-file"),
'ztar': (make_tarball, [('compress', 'compress')], "compressed tar file"),
'tar': (make_tarball, [('compress', None)], "uncompressed tar file"),
'zip': (make_zipfile, [], "ZIP file"),
}
def check_archive_formats(formats):
"""Returns the first format from the 'format' list that is unknown.
If all formats are known, returns None
"""
for format in formats:
if format not in ARCHIVE_FORMATS:
return format
return None
def make_archive(
base_name,
format,
root_dir=None,
base_dir=None,
verbose=0,
dry_run=0,
owner=None,
group=None,
):
"""Create an archive file (eg. zip or tar).
'base_name' is the name of the file to create, minus any format-specific
extension; 'format' is the archive format: one of "zip", "tar", "gztar",
"bztar", "xztar", or "ztar".
'root_dir' is a directory that will be the root directory of the
archive; ie. we typically chdir into 'root_dir' before creating the
archive. 'base_dir' is the directory where we start archiving from;
ie. 'base_dir' will be the common prefix of all files and
directories in the archive. 'root_dir' and 'base_dir' both default
to the current directory. Returns the name of the archive file.
'owner' and 'group' are used when creating a tar archive. By default,
uses the current owner and group.
"""
save_cwd = os.getcwd()
if root_dir is not None:
log.debug("changing into '%s'", root_dir)
base_name = os.path.abspath(base_name)
if not dry_run:
os.chdir(root_dir)
if base_dir is None:
base_dir = os.curdir
kwargs = {'dry_run': dry_run}
try:
format_info = ARCHIVE_FORMATS[format]
except KeyError:
raise ValueError("unknown archive format '%s'" % format)
func = format_info[0]
for arg, val in format_info[1]:
kwargs[arg] = val
if format != 'zip':
kwargs['owner'] = owner
kwargs['group'] = group
try:
filename = func(base_name, base_dir, **kwargs)
finally:
if root_dir is not None:
log.debug("changing back to '%s'", save_cwd)
os.chdir(save_cwd)
return filename
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/archive_util.py
|
Python
|
mit
| 8,603 |
"""distutils.bcppcompiler
Contains BorlandCCompiler, an implementation of the abstract CCompiler class
for the Borland C++ compiler.
"""
# This implementation by Lyle Johnson, based on the original msvccompiler.py
# module and using the directions originally published by Gordon Williams.
# XXX looks like there's a LOT of overlap between these two classes:
# someone should sit down and factor out the common code as
# WindowsCCompiler! --GPW
import os
import warnings
from distutils.errors import (
DistutilsExecError,
CompileError,
LibError,
LinkError,
UnknownFileError,
)
from distutils.ccompiler import CCompiler, gen_preprocess_options
from distutils.file_util import write_file
from distutils.dep_util import newer
from distutils import log
warnings.warn(
"bcppcompiler is deprecated and slated to be removed "
"in the future. Please discontinue use or file an issue "
"with pypa/distutils describing your use case.",
DeprecationWarning,
)
class BCPPCompiler(CCompiler):
"""Concrete class that implements an interface to the Borland C/C++
compiler, as defined by the CCompiler abstract class.
"""
compiler_type = 'bcpp'
# Just set this so CCompiler's constructor doesn't barf. We currently
# don't use the 'set_executables()' bureaucracy provided by CCompiler,
# as it really isn't necessary for this sort of single-compiler class.
# Would be nice to have a consistent interface with UnixCCompiler,
# though, so it's worth thinking about.
executables = {}
# Private class data (need to distinguish C from C++ source for compiler)
_c_extensions = ['.c']
_cpp_extensions = ['.cc', '.cpp', '.cxx']
# Needed for the filename generation methods provided by the
# base class, CCompiler.
src_extensions = _c_extensions + _cpp_extensions
obj_extension = '.obj'
static_lib_extension = '.lib'
shared_lib_extension = '.dll'
static_lib_format = shared_lib_format = '%s%s'
exe_extension = '.exe'
def __init__(self, verbose=0, dry_run=0, force=0):
super().__init__(verbose, dry_run, force)
# These executables are assumed to all be in the path.
# Borland doesn't seem to use any special registry settings to
# indicate their installation locations.
self.cc = "bcc32.exe"
self.linker = "ilink32.exe"
self.lib = "tlib.exe"
self.preprocess_options = None
self.compile_options = ['/tWM', '/O2', '/q', '/g0']
self.compile_options_debug = ['/tWM', '/Od', '/q', '/g0']
self.ldflags_shared = ['/Tpd', '/Gn', '/q', '/x']
self.ldflags_shared_debug = ['/Tpd', '/Gn', '/q', '/x']
self.ldflags_static = []
self.ldflags_exe = ['/Gn', '/q', '/x']
self.ldflags_exe_debug = ['/Gn', '/q', '/x', '/r']
# -- Worker methods ------------------------------------------------
def compile( # noqa: C901
self,
sources,
output_dir=None,
macros=None,
include_dirs=None,
debug=0,
extra_preargs=None,
extra_postargs=None,
depends=None,
):
macros, objects, extra_postargs, pp_opts, build = self._setup_compile(
output_dir, macros, include_dirs, sources, depends, extra_postargs
)
compile_opts = extra_preargs or []
compile_opts.append('-c')
if debug:
compile_opts.extend(self.compile_options_debug)
else:
compile_opts.extend(self.compile_options)
for obj in objects:
try:
src, ext = build[obj]
except KeyError:
continue
# XXX why do the normpath here?
src = os.path.normpath(src)
obj = os.path.normpath(obj)
# XXX _setup_compile() did a mkpath() too but before the normpath.
# Is it possible to skip the normpath?
self.mkpath(os.path.dirname(obj))
if ext == '.res':
# This is already a binary file -- skip it.
continue # the 'for' loop
if ext == '.rc':
# This needs to be compiled to a .res file -- do it now.
try:
self.spawn(["brcc32", "-fo", obj, src])
except DistutilsExecError as msg:
raise CompileError(msg)
continue # the 'for' loop
# The next two are both for the real compiler.
if ext in self._c_extensions:
input_opt = ""
elif ext in self._cpp_extensions:
input_opt = "-P"
else:
# Unknown file type -- no extra options. The compiler
# will probably fail, but let it just in case this is a
# file the compiler recognizes even if we don't.
input_opt = ""
output_opt = "-o" + obj
# Compiler command line syntax is: "bcc32 [options] file(s)".
# Note that the source file names must appear at the end of
# the command line.
try:
self.spawn(
[self.cc]
+ compile_opts
+ pp_opts
+ [input_opt, output_opt]
+ extra_postargs
+ [src]
)
except DistutilsExecError as msg:
raise CompileError(msg)
return objects
# compile ()
def create_static_lib(
self, objects, output_libname, output_dir=None, debug=0, target_lang=None
):
(objects, output_dir) = self._fix_object_args(objects, output_dir)
output_filename = self.library_filename(output_libname, output_dir=output_dir)
if self._need_link(objects, output_filename):
lib_args = [output_filename, '/u'] + objects
if debug:
pass # XXX what goes here?
try:
self.spawn([self.lib] + lib_args)
except DistutilsExecError as msg:
raise LibError(msg)
else:
log.debug("skipping %s (up-to-date)", output_filename)
# create_static_lib ()
def link( # noqa: C901
self,
target_desc,
objects,
output_filename,
output_dir=None,
libraries=None,
library_dirs=None,
runtime_library_dirs=None,
export_symbols=None,
debug=0,
extra_preargs=None,
extra_postargs=None,
build_temp=None,
target_lang=None,
):
# XXX this ignores 'build_temp'! should follow the lead of
# msvccompiler.py
(objects, output_dir) = self._fix_object_args(objects, output_dir)
(libraries, library_dirs, runtime_library_dirs) = self._fix_lib_args(
libraries, library_dirs, runtime_library_dirs
)
if runtime_library_dirs:
log.warn(
"I don't know what to do with 'runtime_library_dirs': %s",
str(runtime_library_dirs),
)
if output_dir is not None:
output_filename = os.path.join(output_dir, output_filename)
if self._need_link(objects, output_filename):
# Figure out linker args based on type of target.
if target_desc == CCompiler.EXECUTABLE:
startup_obj = 'c0w32'
if debug:
ld_args = self.ldflags_exe_debug[:]
else:
ld_args = self.ldflags_exe[:]
else:
startup_obj = 'c0d32'
if debug:
ld_args = self.ldflags_shared_debug[:]
else:
ld_args = self.ldflags_shared[:]
# Create a temporary exports file for use by the linker
if export_symbols is None:
def_file = ''
else:
head, tail = os.path.split(output_filename)
modname, ext = os.path.splitext(tail)
temp_dir = os.path.dirname(objects[0]) # preserve tree structure
def_file = os.path.join(temp_dir, '%s.def' % modname)
contents = ['EXPORTS']
for sym in export_symbols or []:
contents.append(' {}=_{}'.format(sym, sym))
self.execute(write_file, (def_file, contents), "writing %s" % def_file)
# Borland C++ has problems with '/' in paths
objects2 = map(os.path.normpath, objects)
# split objects in .obj and .res files
# Borland C++ needs them at different positions in the command line
objects = [startup_obj]
resources = []
for file in objects2:
(base, ext) = os.path.splitext(os.path.normcase(file))
if ext == '.res':
resources.append(file)
else:
objects.append(file)
for ell in library_dirs:
ld_args.append("/L%s" % os.path.normpath(ell))
ld_args.append("/L.") # we sometimes use relative paths
# list of object files
ld_args.extend(objects)
# XXX the command-line syntax for Borland C++ is a bit wonky;
# certain filenames are jammed together in one big string, but
# comma-delimited. This doesn't mesh too well with the
# Unix-centric attitude (with a DOS/Windows quoting hack) of
# 'spawn()', so constructing the argument list is a bit
# awkward. Note that doing the obvious thing and jamming all
# the filenames and commas into one argument would be wrong,
# because 'spawn()' would quote any filenames with spaces in
# them. Arghghh!. Apparently it works fine as coded...
# name of dll/exe file
ld_args.extend([',', output_filename])
# no map file and start libraries
ld_args.append(',,')
for lib in libraries:
# see if we find it and if there is a bcpp specific lib
# (xxx_bcpp.lib)
libfile = self.find_library_file(library_dirs, lib, debug)
if libfile is None:
ld_args.append(lib)
# probably a BCPP internal library -- don't warn
else:
# full name which prefers bcpp_xxx.lib over xxx.lib
ld_args.append(libfile)
# some default libraries
ld_args.append('import32')
ld_args.append('cw32mt')
# def file for export symbols
ld_args.extend([',', def_file])
# add resource files
ld_args.append(',')
ld_args.extend(resources)
if extra_preargs:
ld_args[:0] = extra_preargs
if extra_postargs:
ld_args.extend(extra_postargs)
self.mkpath(os.path.dirname(output_filename))
try:
self.spawn([self.linker] + ld_args)
except DistutilsExecError as msg:
raise LinkError(msg)
else:
log.debug("skipping %s (up-to-date)", output_filename)
# link ()
# -- Miscellaneous methods -----------------------------------------
def find_library_file(self, dirs, lib, debug=0):
# List of effective library names to try, in order of preference:
# xxx_bcpp.lib is better than xxx.lib
# and xxx_d.lib is better than xxx.lib if debug is set
#
# The "_bcpp" suffix is to handle a Python installation for people
# with multiple compilers (primarily Distutils hackers, I suspect
# ;-). The idea is they'd have one static library for each
# compiler they care about, since (almost?) every Windows compiler
# seems to have a different format for static libraries.
if debug:
dlib = lib + "_d"
try_names = (dlib + "_bcpp", lib + "_bcpp", dlib, lib)
else:
try_names = (lib + "_bcpp", lib)
for dir in dirs:
for name in try_names:
libfile = os.path.join(dir, self.library_filename(name))
if os.path.exists(libfile):
return libfile
else:
# Oops, didn't find it in *any* of 'dirs'
return None
# overwrite the one from CCompiler to support rc and res-files
def object_filenames(self, source_filenames, strip_dir=0, output_dir=''):
if output_dir is None:
output_dir = ''
obj_names = []
for src_name in source_filenames:
# use normcase to make sure '.rc' is really '.rc' and not '.RC'
(base, ext) = os.path.splitext(os.path.normcase(src_name))
if ext not in (self.src_extensions + ['.rc', '.res']):
raise UnknownFileError(
"unknown file type '{}' (from '{}')".format(ext, src_name)
)
if strip_dir:
base = os.path.basename(base)
if ext == '.res':
# these can go unchanged
obj_names.append(os.path.join(output_dir, base + ext))
elif ext == '.rc':
# these need to be compiled to .res-files
obj_names.append(os.path.join(output_dir, base + '.res'))
else:
obj_names.append(os.path.join(output_dir, base + self.obj_extension))
return obj_names
# object_filenames ()
def preprocess(
self,
source,
output_file=None,
macros=None,
include_dirs=None,
extra_preargs=None,
extra_postargs=None,
):
(_, macros, include_dirs) = self._fix_compile_args(None, macros, include_dirs)
pp_opts = gen_preprocess_options(macros, include_dirs)
pp_args = ['cpp32.exe'] + pp_opts
if output_file is not None:
pp_args.append('-o' + output_file)
if extra_preargs:
pp_args[:0] = extra_preargs
if extra_postargs:
pp_args.extend(extra_postargs)
pp_args.append(source)
# We need to preprocess: either we're being forced to, or the
# source file is newer than the target (or the target doesn't
# exist).
if self.force or output_file is None or newer(source, output_file):
if output_file:
self.mkpath(os.path.dirname(output_file))
try:
self.spawn(pp_args)
except DistutilsExecError as msg:
print(msg)
raise CompileError(msg)
# preprocess()
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/bcppcompiler.py
|
Python
|
mit
| 14,789 |
"""distutils.ccompiler
Contains CCompiler, an abstract base class that defines the interface
for the Distutils compiler abstraction model."""
import sys
import os
import re
from distutils.errors import (
CompileError,
LinkError,
UnknownFileError,
DistutilsPlatformError,
DistutilsModuleError,
)
from distutils.spawn import spawn
from distutils.file_util import move_file
from distutils.dir_util import mkpath
from distutils.dep_util import newer_group
from distutils.util import split_quoted, execute
from distutils import log
class CCompiler:
"""Abstract base class to define the interface that must be implemented
by real compiler classes. Also has some utility methods used by
several compiler classes.
The basic idea behind a compiler abstraction class is that each
instance can be used for all the compile/link steps in building a
single project. Thus, attributes common to all of those compile and
link steps -- include directories, macros to define, libraries to link
against, etc. -- are attributes of the compiler instance. To allow for
variability in how individual files are treated, most of those
attributes may be varied on a per-compilation or per-link basis.
"""
# 'compiler_type' is a class attribute that identifies this class. It
# keeps code that wants to know what kind of compiler it's dealing with
# from having to import all possible compiler classes just to do an
# 'isinstance'. In concrete CCompiler subclasses, 'compiler_type'
# should really, really be one of the keys of the 'compiler_class'
# dictionary (see below -- used by the 'new_compiler()' factory
# function) -- authors of new compiler interface classes are
# responsible for updating 'compiler_class'!
compiler_type = None
# XXX things not handled by this compiler abstraction model:
# * client can't provide additional options for a compiler,
# e.g. warning, optimization, debugging flags. Perhaps this
# should be the domain of concrete compiler abstraction classes
# (UnixCCompiler, MSVCCompiler, etc.) -- or perhaps the base
# class should have methods for the common ones.
# * can't completely override the include or library searchg
# path, ie. no "cc -I -Idir1 -Idir2" or "cc -L -Ldir1 -Ldir2".
# I'm not sure how widely supported this is even by Unix
# compilers, much less on other platforms. And I'm even less
# sure how useful it is; maybe for cross-compiling, but
# support for that is a ways off. (And anyways, cross
# compilers probably have a dedicated binary with the
# right paths compiled in. I hope.)
# * can't do really freaky things with the library list/library
# dirs, e.g. "-Ldir1 -lfoo -Ldir2 -lfoo" to link against
# different versions of libfoo.a in different locations. I
# think this is useless without the ability to null out the
# library search path anyways.
# Subclasses that rely on the standard filename generation methods
# implemented below should override these; see the comment near
# those methods ('object_filenames()' et. al.) for details:
src_extensions = None # list of strings
obj_extension = None # string
static_lib_extension = None
shared_lib_extension = None # string
static_lib_format = None # format string
shared_lib_format = None # prob. same as static_lib_format
exe_extension = None # string
# Default language settings. language_map is used to detect a source
# file or Extension target language, checking source filenames.
# language_order is used to detect the language precedence, when deciding
# what language to use when mixing source types. For example, if some
# extension has two files with ".c" extension, and one with ".cpp", it
# is still linked as c++.
language_map = {
".c": "c",
".cc": "c++",
".cpp": "c++",
".cxx": "c++",
".m": "objc",
}
language_order = ["c++", "objc", "c"]
include_dirs = []
"""
include dirs specific to this compiler class
"""
library_dirs = []
"""
library dirs specific to this compiler class
"""
def __init__(self, verbose=0, dry_run=0, force=0):
self.dry_run = dry_run
self.force = force
self.verbose = verbose
# 'output_dir': a common output directory for object, library,
# shared object, and shared library files
self.output_dir = None
# 'macros': a list of macro definitions (or undefinitions). A
# macro definition is a 2-tuple (name, value), where the value is
# either a string or None (no explicit value). A macro
# undefinition is a 1-tuple (name,).
self.macros = []
# 'include_dirs': a list of directories to search for include files
self.include_dirs = []
# 'libraries': a list of libraries to include in any link
# (library names, not filenames: eg. "foo" not "libfoo.a")
self.libraries = []
# 'library_dirs': a list of directories to search for libraries
self.library_dirs = []
# 'runtime_library_dirs': a list of directories to search for
# shared libraries/objects at runtime
self.runtime_library_dirs = []
# 'objects': a list of object files (or similar, such as explicitly
# named library files) to include on any link
self.objects = []
for key in self.executables.keys():
self.set_executable(key, self.executables[key])
def set_executables(self, **kwargs):
"""Define the executables (and options for them) that will be run
to perform the various stages of compilation. The exact set of
executables that may be specified here depends on the compiler
class (via the 'executables' class attribute), but most will have:
compiler the C/C++ compiler
linker_so linker used to create shared objects and libraries
linker_exe linker used to create binary executables
archiver static library creator
On platforms with a command-line (Unix, DOS/Windows), each of these
is a string that will be split into executable name and (optional)
list of arguments. (Splitting the string is done similarly to how
Unix shells operate: words are delimited by spaces, but quotes and
backslashes can override this. See
'distutils.util.split_quoted()'.)
"""
# Note that some CCompiler implementation classes will define class
# attributes 'cpp', 'cc', etc. with hard-coded executable names;
# this is appropriate when a compiler class is for exactly one
# compiler/OS combination (eg. MSVCCompiler). Other compiler
# classes (UnixCCompiler, in particular) are driven by information
# discovered at run-time, since there are many different ways to do
# basically the same things with Unix C compilers.
for key in kwargs:
if key not in self.executables:
raise ValueError(
"unknown executable '%s' for class %s"
% (key, self.__class__.__name__)
)
self.set_executable(key, kwargs[key])
def set_executable(self, key, value):
if isinstance(value, str):
setattr(self, key, split_quoted(value))
else:
setattr(self, key, value)
def _find_macro(self, name):
i = 0
for defn in self.macros:
if defn[0] == name:
return i
i += 1
return None
def _check_macro_definitions(self, definitions):
"""Ensures that every element of 'definitions' is a valid macro
definition, ie. either (name,value) 2-tuple or a (name,) tuple. Do
nothing if all definitions are OK, raise TypeError otherwise.
"""
for defn in definitions:
if not (
isinstance(defn, tuple)
and (
len(defn) in (1, 2)
and (isinstance(defn[1], str) or defn[1] is None)
)
and isinstance(defn[0], str)
):
raise TypeError(
("invalid macro definition '%s': " % defn)
+ "must be tuple (string,), (string, string), or "
+ "(string, None)"
)
# -- Bookkeeping methods -------------------------------------------
def define_macro(self, name, value=None):
"""Define a preprocessor macro for all compilations driven by this
compiler object. The optional parameter 'value' should be a
string; if it is not supplied, then the macro will be defined
without an explicit value and the exact outcome depends on the
compiler used (XXX true? does ANSI say anything about this?)
"""
# Delete from the list of macro definitions/undefinitions if
# already there (so that this one will take precedence).
i = self._find_macro(name)
if i is not None:
del self.macros[i]
self.macros.append((name, value))
def undefine_macro(self, name):
"""Undefine a preprocessor macro for all compilations driven by
this compiler object. If the same macro is defined by
'define_macro()' and undefined by 'undefine_macro()' the last call
takes precedence (including multiple redefinitions or
undefinitions). If the macro is redefined/undefined on a
per-compilation basis (ie. in the call to 'compile()'), then that
takes precedence.
"""
# Delete from the list of macro definitions/undefinitions if
# already there (so that this one will take precedence).
i = self._find_macro(name)
if i is not None:
del self.macros[i]
undefn = (name,)
self.macros.append(undefn)
def add_include_dir(self, dir):
"""Add 'dir' to the list of directories that will be searched for
header files. The compiler is instructed to search directories in
the order in which they are supplied by successive calls to
'add_include_dir()'.
"""
self.include_dirs.append(dir)
def set_include_dirs(self, dirs):
"""Set the list of directories that will be searched to 'dirs' (a
list of strings). Overrides any preceding calls to
'add_include_dir()'; subsequence calls to 'add_include_dir()' add
to the list passed to 'set_include_dirs()'. This does not affect
any list of standard include directories that the compiler may
search by default.
"""
self.include_dirs = dirs[:]
def add_library(self, libname):
"""Add 'libname' to the list of libraries that will be included in
all links driven by this compiler object. Note that 'libname'
should *not* be the name of a file containing a library, but the
name of the library itself: the actual filename will be inferred by
the linker, the compiler, or the compiler class (depending on the
platform).
The linker will be instructed to link against libraries in the
order they were supplied to 'add_library()' and/or
'set_libraries()'. It is perfectly valid to duplicate library
names; the linker will be instructed to link against libraries as
many times as they are mentioned.
"""
self.libraries.append(libname)
def set_libraries(self, libnames):
"""Set the list of libraries to be included in all links driven by
this compiler object to 'libnames' (a list of strings). This does
not affect any standard system libraries that the linker may
include by default.
"""
self.libraries = libnames[:]
def add_library_dir(self, dir):
"""Add 'dir' to the list of directories that will be searched for
libraries specified to 'add_library()' and 'set_libraries()'. The
linker will be instructed to search for libraries in the order they
are supplied to 'add_library_dir()' and/or 'set_library_dirs()'.
"""
self.library_dirs.append(dir)
def set_library_dirs(self, dirs):
"""Set the list of library search directories to 'dirs' (a list of
strings). This does not affect any standard library search path
that the linker may search by default.
"""
self.library_dirs = dirs[:]
def add_runtime_library_dir(self, dir):
"""Add 'dir' to the list of directories that will be searched for
shared libraries at runtime.
"""
self.runtime_library_dirs.append(dir)
def set_runtime_library_dirs(self, dirs):
"""Set the list of directories to search for shared libraries at
runtime to 'dirs' (a list of strings). This does not affect any
standard search path that the runtime linker may search by
default.
"""
self.runtime_library_dirs = dirs[:]
def add_link_object(self, object):
"""Add 'object' to the list of object files (or analogues, such as
explicitly named library files or the output of "resource
compilers") to be included in every link driven by this compiler
object.
"""
self.objects.append(object)
def set_link_objects(self, objects):
"""Set the list of object files (or analogues) to be included in
every link to 'objects'. This does not affect any standard object
files that the linker may include by default (such as system
libraries).
"""
self.objects = objects[:]
# -- Private utility methods --------------------------------------
# (here for the convenience of subclasses)
# Helper method to prep compiler in subclass compile() methods
def _setup_compile(self, outdir, macros, incdirs, sources, depends, extra):
"""Process arguments and decide which source files to compile."""
outdir, macros, incdirs = self._fix_compile_args(outdir, macros, incdirs)
if extra is None:
extra = []
# Get the list of expected output (object) files
objects = self.object_filenames(sources, strip_dir=0, output_dir=outdir)
assert len(objects) == len(sources)
pp_opts = gen_preprocess_options(macros, incdirs)
build = {}
for i in range(len(sources)):
src = sources[i]
obj = objects[i]
ext = os.path.splitext(src)[1]
self.mkpath(os.path.dirname(obj))
build[obj] = (src, ext)
return macros, objects, extra, pp_opts, build
def _get_cc_args(self, pp_opts, debug, before):
# works for unixccompiler, cygwinccompiler
cc_args = pp_opts + ['-c']
if debug:
cc_args[:0] = ['-g']
if before:
cc_args[:0] = before
return cc_args
def _fix_compile_args(self, output_dir, macros, include_dirs):
"""Typecheck and fix-up some of the arguments to the 'compile()'
method, and return fixed-up values. Specifically: if 'output_dir'
is None, replaces it with 'self.output_dir'; ensures that 'macros'
is a list, and augments it with 'self.macros'; ensures that
'include_dirs' is a list, and augments it with 'self.include_dirs'.
Guarantees that the returned values are of the correct type,
i.e. for 'output_dir' either string or None, and for 'macros' and
'include_dirs' either list or None.
"""
if output_dir is None:
output_dir = self.output_dir
elif not isinstance(output_dir, str):
raise TypeError("'output_dir' must be a string or None")
if macros is None:
macros = self.macros
elif isinstance(macros, list):
macros = macros + (self.macros or [])
else:
raise TypeError("'macros' (if supplied) must be a list of tuples")
if include_dirs is None:
include_dirs = self.include_dirs
elif isinstance(include_dirs, (list, tuple)):
include_dirs = list(include_dirs) + (self.include_dirs or [])
else:
raise TypeError("'include_dirs' (if supplied) must be a list of strings")
# add include dirs for class
include_dirs += self.__class__.include_dirs
return output_dir, macros, include_dirs
def _prep_compile(self, sources, output_dir, depends=None):
"""Decide which source files must be recompiled.
Determine the list of object files corresponding to 'sources',
and figure out which ones really need to be recompiled.
Return a list of all object files and a dictionary telling
which source files can be skipped.
"""
# Get the list of expected output (object) files
objects = self.object_filenames(sources, output_dir=output_dir)
assert len(objects) == len(sources)
# Return an empty dict for the "which source files can be skipped"
# return value to preserve API compatibility.
return objects, {}
def _fix_object_args(self, objects, output_dir):
"""Typecheck and fix up some arguments supplied to various methods.
Specifically: ensure that 'objects' is a list; if output_dir is
None, replace with self.output_dir. Return fixed versions of
'objects' and 'output_dir'.
"""
if not isinstance(objects, (list, tuple)):
raise TypeError("'objects' must be a list or tuple of strings")
objects = list(objects)
if output_dir is None:
output_dir = self.output_dir
elif not isinstance(output_dir, str):
raise TypeError("'output_dir' must be a string or None")
return (objects, output_dir)
def _fix_lib_args(self, libraries, library_dirs, runtime_library_dirs):
"""Typecheck and fix up some of the arguments supplied to the
'link_*' methods. Specifically: ensure that all arguments are
lists, and augment them with their permanent versions
(eg. 'self.libraries' augments 'libraries'). Return a tuple with
fixed versions of all arguments.
"""
if libraries is None:
libraries = self.libraries
elif isinstance(libraries, (list, tuple)):
libraries = list(libraries) + (self.libraries or [])
else:
raise TypeError("'libraries' (if supplied) must be a list of strings")
if library_dirs is None:
library_dirs = self.library_dirs
elif isinstance(library_dirs, (list, tuple)):
library_dirs = list(library_dirs) + (self.library_dirs or [])
else:
raise TypeError("'library_dirs' (if supplied) must be a list of strings")
# add library dirs for class
library_dirs += self.__class__.library_dirs
if runtime_library_dirs is None:
runtime_library_dirs = self.runtime_library_dirs
elif isinstance(runtime_library_dirs, (list, tuple)):
runtime_library_dirs = list(runtime_library_dirs) + (
self.runtime_library_dirs or []
)
else:
raise TypeError(
"'runtime_library_dirs' (if supplied) " "must be a list of strings"
)
return (libraries, library_dirs, runtime_library_dirs)
def _need_link(self, objects, output_file):
"""Return true if we need to relink the files listed in 'objects'
to recreate 'output_file'.
"""
if self.force:
return True
else:
if self.dry_run:
newer = newer_group(objects, output_file, missing='newer')
else:
newer = newer_group(objects, output_file)
return newer
def detect_language(self, sources):
"""Detect the language of a given file, or list of files. Uses
language_map, and language_order to do the job.
"""
if not isinstance(sources, list):
sources = [sources]
lang = None
index = len(self.language_order)
for source in sources:
base, ext = os.path.splitext(source)
extlang = self.language_map.get(ext)
try:
extindex = self.language_order.index(extlang)
if extindex < index:
lang = extlang
index = extindex
except ValueError:
pass
return lang
# -- Worker methods ------------------------------------------------
# (must be implemented by subclasses)
def preprocess(
self,
source,
output_file=None,
macros=None,
include_dirs=None,
extra_preargs=None,
extra_postargs=None,
):
"""Preprocess a single C/C++ source file, named in 'source'.
Output will be written to file named 'output_file', or stdout if
'output_file' not supplied. 'macros' is a list of macro
definitions as for 'compile()', which will augment the macros set
with 'define_macro()' and 'undefine_macro()'. 'include_dirs' is a
list of directory names that will be added to the default list.
Raises PreprocessError on failure.
"""
pass
def compile(
self,
sources,
output_dir=None,
macros=None,
include_dirs=None,
debug=0,
extra_preargs=None,
extra_postargs=None,
depends=None,
):
"""Compile one or more source files.
'sources' must be a list of filenames, most likely C/C++
files, but in reality anything that can be handled by a
particular compiler and compiler class (eg. MSVCCompiler can
handle resource files in 'sources'). Return a list of object
filenames, one per source filename in 'sources'. Depending on
the implementation, not all source files will necessarily be
compiled, but all corresponding object filenames will be
returned.
If 'output_dir' is given, object files will be put under it, while
retaining their original path component. That is, "foo/bar.c"
normally compiles to "foo/bar.o" (for a Unix implementation); if
'output_dir' is "build", then it would compile to
"build/foo/bar.o".
'macros', if given, must be a list of macro definitions. A macro
definition is either a (name, value) 2-tuple or a (name,) 1-tuple.
The former defines a macro; if the value is None, the macro is
defined without an explicit value. The 1-tuple case undefines a
macro. Later definitions/redefinitions/ undefinitions take
precedence.
'include_dirs', if given, must be a list of strings, the
directories to add to the default include file search path for this
compilation only.
'debug' is a boolean; if true, the compiler will be instructed to
output debug symbols in (or alongside) the object file(s).
'extra_preargs' and 'extra_postargs' are implementation- dependent.
On platforms that have the notion of a command-line (e.g. Unix,
DOS/Windows), they are most likely lists of strings: extra
command-line arguments to prepend/append to the compiler command
line. On other platforms, consult the implementation class
documentation. In any event, they are intended as an escape hatch
for those occasions when the abstract compiler framework doesn't
cut the mustard.
'depends', if given, is a list of filenames that all targets
depend on. If a source file is older than any file in
depends, then the source file will be recompiled. This
supports dependency tracking, but only at a coarse
granularity.
Raises CompileError on failure.
"""
# A concrete compiler class can either override this method
# entirely or implement _compile().
macros, objects, extra_postargs, pp_opts, build = self._setup_compile(
output_dir, macros, include_dirs, sources, depends, extra_postargs
)
cc_args = self._get_cc_args(pp_opts, debug, extra_preargs)
for obj in objects:
try:
src, ext = build[obj]
except KeyError:
continue
self._compile(obj, src, ext, cc_args, extra_postargs, pp_opts)
# Return *all* object filenames, not just the ones we just built.
return objects
def _compile(self, obj, src, ext, cc_args, extra_postargs, pp_opts):
"""Compile 'src' to product 'obj'."""
# A concrete compiler class that does not override compile()
# should implement _compile().
pass
def create_static_lib(
self, objects, output_libname, output_dir=None, debug=0, target_lang=None
):
"""Link a bunch of stuff together to create a static library file.
The "bunch of stuff" consists of the list of object files supplied
as 'objects', the extra object files supplied to
'add_link_object()' and/or 'set_link_objects()', the libraries
supplied to 'add_library()' and/or 'set_libraries()', and the
libraries supplied as 'libraries' (if any).
'output_libname' should be a library name, not a filename; the
filename will be inferred from the library name. 'output_dir' is
the directory where the library file will be put.
'debug' is a boolean; if true, debugging information will be
included in the library (note that on most platforms, it is the
compile step where this matters: the 'debug' flag is included here
just for consistency).
'target_lang' is the target language for which the given objects
are being compiled. This allows specific linkage time treatment of
certain languages.
Raises LibError on failure.
"""
pass
# values for target_desc parameter in link()
SHARED_OBJECT = "shared_object"
SHARED_LIBRARY = "shared_library"
EXECUTABLE = "executable"
def link(
self,
target_desc,
objects,
output_filename,
output_dir=None,
libraries=None,
library_dirs=None,
runtime_library_dirs=None,
export_symbols=None,
debug=0,
extra_preargs=None,
extra_postargs=None,
build_temp=None,
target_lang=None,
):
"""Link a bunch of stuff together to create an executable or
shared library file.
The "bunch of stuff" consists of the list of object files supplied
as 'objects'. 'output_filename' should be a filename. If
'output_dir' is supplied, 'output_filename' is relative to it
(i.e. 'output_filename' can provide directory components if
needed).
'libraries' is a list of libraries to link against. These are
library names, not filenames, since they're translated into
filenames in a platform-specific way (eg. "foo" becomes "libfoo.a"
on Unix and "foo.lib" on DOS/Windows). However, they can include a
directory component, which means the linker will look in that
specific directory rather than searching all the normal locations.
'library_dirs', if supplied, should be a list of directories to
search for libraries that were specified as bare library names
(ie. no directory component). These are on top of the system
default and those supplied to 'add_library_dir()' and/or
'set_library_dirs()'. 'runtime_library_dirs' is a list of
directories that will be embedded into the shared library and used
to search for other shared libraries that *it* depends on at
run-time. (This may only be relevant on Unix.)
'export_symbols' is a list of symbols that the shared library will
export. (This appears to be relevant only on Windows.)
'debug' is as for 'compile()' and 'create_static_lib()', with the
slight distinction that it actually matters on most platforms (as
opposed to 'create_static_lib()', which includes a 'debug' flag
mostly for form's sake).
'extra_preargs' and 'extra_postargs' are as for 'compile()' (except
of course that they supply command-line arguments for the
particular linker being used).
'target_lang' is the target language for which the given objects
are being compiled. This allows specific linkage time treatment of
certain languages.
Raises LinkError on failure.
"""
raise NotImplementedError
# Old 'link_*()' methods, rewritten to use the new 'link()' method.
def link_shared_lib(
self,
objects,
output_libname,
output_dir=None,
libraries=None,
library_dirs=None,
runtime_library_dirs=None,
export_symbols=None,
debug=0,
extra_preargs=None,
extra_postargs=None,
build_temp=None,
target_lang=None,
):
self.link(
CCompiler.SHARED_LIBRARY,
objects,
self.library_filename(output_libname, lib_type='shared'),
output_dir,
libraries,
library_dirs,
runtime_library_dirs,
export_symbols,
debug,
extra_preargs,
extra_postargs,
build_temp,
target_lang,
)
def link_shared_object(
self,
objects,
output_filename,
output_dir=None,
libraries=None,
library_dirs=None,
runtime_library_dirs=None,
export_symbols=None,
debug=0,
extra_preargs=None,
extra_postargs=None,
build_temp=None,
target_lang=None,
):
self.link(
CCompiler.SHARED_OBJECT,
objects,
output_filename,
output_dir,
libraries,
library_dirs,
runtime_library_dirs,
export_symbols,
debug,
extra_preargs,
extra_postargs,
build_temp,
target_lang,
)
def link_executable(
self,
objects,
output_progname,
output_dir=None,
libraries=None,
library_dirs=None,
runtime_library_dirs=None,
debug=0,
extra_preargs=None,
extra_postargs=None,
target_lang=None,
):
self.link(
CCompiler.EXECUTABLE,
objects,
self.executable_filename(output_progname),
output_dir,
libraries,
library_dirs,
runtime_library_dirs,
None,
debug,
extra_preargs,
extra_postargs,
None,
target_lang,
)
# -- Miscellaneous methods -----------------------------------------
# These are all used by the 'gen_lib_options() function; there is
# no appropriate default implementation so subclasses should
# implement all of these.
def library_dir_option(self, dir):
"""Return the compiler option to add 'dir' to the list of
directories searched for libraries.
"""
raise NotImplementedError
def runtime_library_dir_option(self, dir):
"""Return the compiler option to add 'dir' to the list of
directories searched for runtime libraries.
"""
raise NotImplementedError
def library_option(self, lib):
"""Return the compiler option to add 'lib' to the list of libraries
linked into the shared library or executable.
"""
raise NotImplementedError
def has_function( # noqa: C901
self,
funcname,
includes=None,
include_dirs=None,
libraries=None,
library_dirs=None,
):
"""Return a boolean indicating whether funcname is supported on
the current platform. The optional arguments can be used to
augment the compilation environment.
"""
# this can't be included at module scope because it tries to
# import math which might not be available at that point - maybe
# the necessary logic should just be inlined?
import tempfile
if includes is None:
includes = []
if include_dirs is None:
include_dirs = []
if libraries is None:
libraries = []
if library_dirs is None:
library_dirs = []
fd, fname = tempfile.mkstemp(".c", funcname, text=True)
f = os.fdopen(fd, "w")
try:
for incl in includes:
f.write("""#include "%s"\n""" % incl)
f.write(
"""\
int main (int argc, char **argv) {
%s();
return 0;
}
"""
% funcname
)
finally:
f.close()
try:
objects = self.compile([fname], include_dirs=include_dirs)
except CompileError:
return False
finally:
os.remove(fname)
try:
self.link_executable(
objects, "a.out", libraries=libraries, library_dirs=library_dirs
)
except (LinkError, TypeError):
return False
else:
os.remove(os.path.join(self.output_dir or '', "a.out"))
finally:
for fn in objects:
os.remove(fn)
return True
def find_library_file(self, dirs, lib, debug=0):
"""Search the specified list of directories for a static or shared
library file 'lib' and return the full path to that file. If
'debug' true, look for a debugging version (if that makes sense on
the current platform). Return None if 'lib' wasn't found in any of
the specified directories.
"""
raise NotImplementedError
# -- Filename generation methods -----------------------------------
# The default implementation of the filename generating methods are
# prejudiced towards the Unix/DOS/Windows view of the world:
# * object files are named by replacing the source file extension
# (eg. .c/.cpp -> .o/.obj)
# * library files (shared or static) are named by plugging the
# library name and extension into a format string, eg.
# "lib%s.%s" % (lib_name, ".a") for Unix static libraries
# * executables are named by appending an extension (possibly
# empty) to the program name: eg. progname + ".exe" for
# Windows
#
# To reduce redundant code, these methods expect to find
# several attributes in the current object (presumably defined
# as class attributes):
# * src_extensions -
# list of C/C++ source file extensions, eg. ['.c', '.cpp']
# * obj_extension -
# object file extension, eg. '.o' or '.obj'
# * static_lib_extension -
# extension for static library files, eg. '.a' or '.lib'
# * shared_lib_extension -
# extension for shared library/object files, eg. '.so', '.dll'
# * static_lib_format -
# format string for generating static library filenames,
# eg. 'lib%s.%s' or '%s.%s'
# * shared_lib_format
# format string for generating shared library filenames
# (probably same as static_lib_format, since the extension
# is one of the intended parameters to the format string)
# * exe_extension -
# extension for executable files, eg. '' or '.exe'
def object_filenames(self, source_filenames, strip_dir=0, output_dir=''):
if output_dir is None:
output_dir = ''
return list(
self._make_out_path(output_dir, strip_dir, src_name)
for src_name in source_filenames
)
@property
def out_extensions(self):
return dict.fromkeys(self.src_extensions, self.obj_extension)
def _make_out_path(self, output_dir, strip_dir, src_name):
base, ext = os.path.splitext(src_name)
base = self._make_relative(base)
try:
new_ext = self.out_extensions[ext]
except LookupError:
raise UnknownFileError(
"unknown file type '{}' (from '{}')".format(ext, src_name)
)
if strip_dir:
base = os.path.basename(base)
return os.path.join(output_dir, base + new_ext)
@staticmethod
def _make_relative(base):
"""
In order to ensure that a filename always honors the
indicated output_dir, make sure it's relative.
Ref python/cpython#37775.
"""
# Chop off the drive
no_drive = os.path.splitdrive(base)[1]
# If abs, chop off leading /
return no_drive[os.path.isabs(no_drive) :]
def shared_object_filename(self, basename, strip_dir=0, output_dir=''):
assert output_dir is not None
if strip_dir:
basename = os.path.basename(basename)
return os.path.join(output_dir, basename + self.shared_lib_extension)
def executable_filename(self, basename, strip_dir=0, output_dir=''):
assert output_dir is not None
if strip_dir:
basename = os.path.basename(basename)
return os.path.join(output_dir, basename + (self.exe_extension or ''))
def library_filename(
self, libname, lib_type='static', strip_dir=0, output_dir='' # or 'shared'
):
assert output_dir is not None
expected = '"static", "shared", "dylib", "xcode_stub"'
if lib_type not in eval(expected):
raise ValueError(f"'lib_type' must be {expected}")
fmt = getattr(self, lib_type + "_lib_format")
ext = getattr(self, lib_type + "_lib_extension")
dir, base = os.path.split(libname)
filename = fmt % (base, ext)
if strip_dir:
dir = ''
return os.path.join(output_dir, dir, filename)
# -- Utility methods -----------------------------------------------
def announce(self, msg, level=1):
log.debug(msg)
def debug_print(self, msg):
from distutils.debug import DEBUG
if DEBUG:
print(msg)
def warn(self, msg):
sys.stderr.write("warning: %s\n" % msg)
def execute(self, func, args, msg=None, level=1):
execute(func, args, msg, self.dry_run)
def spawn(self, cmd, **kwargs):
spawn(cmd, dry_run=self.dry_run, **kwargs)
def move_file(self, src, dst):
return move_file(src, dst, dry_run=self.dry_run)
def mkpath(self, name, mode=0o777):
mkpath(name, mode, dry_run=self.dry_run)
# Map a sys.platform/os.name ('posix', 'nt') to the default compiler
# type for that platform. Keys are interpreted as re match
# patterns. Order is important; platform mappings are preferred over
# OS names.
_default_compilers = (
# Platform string mappings
# on a cygwin built python we can use gcc like an ordinary UNIXish
# compiler
('cygwin.*', 'unix'),
# OS name mappings
('posix', 'unix'),
('nt', 'msvc'),
)
def get_default_compiler(osname=None, platform=None):
"""Determine the default compiler to use for the given platform.
osname should be one of the standard Python OS names (i.e. the
ones returned by os.name) and platform the common value
returned by sys.platform for the platform in question.
The default values are os.name and sys.platform in case the
parameters are not given.
"""
if osname is None:
osname = os.name
if platform is None:
platform = sys.platform
for pattern, compiler in _default_compilers:
if (
re.match(pattern, platform) is not None
or re.match(pattern, osname) is not None
):
return compiler
# Default to Unix compiler
return 'unix'
# Map compiler types to (module_name, class_name) pairs -- ie. where to
# find the code that implements an interface to this compiler. (The module
# is assumed to be in the 'distutils' package.)
compiler_class = {
'unix': ('unixccompiler', 'UnixCCompiler', "standard UNIX-style compiler"),
'msvc': ('_msvccompiler', 'MSVCCompiler', "Microsoft Visual C++"),
'cygwin': (
'cygwinccompiler',
'CygwinCCompiler',
"Cygwin port of GNU C Compiler for Win32",
),
'mingw32': (
'cygwinccompiler',
'Mingw32CCompiler',
"Mingw32 port of GNU C Compiler for Win32",
),
'bcpp': ('bcppcompiler', 'BCPPCompiler', "Borland C++ Compiler"),
}
def show_compilers():
"""Print list of available compilers (used by the "--help-compiler"
options to "build", "build_ext", "build_clib").
"""
# XXX this "knows" that the compiler option it's describing is
# "--compiler", which just happens to be the case for the three
# commands that use it.
from distutils.fancy_getopt import FancyGetopt
compilers = []
for compiler in compiler_class.keys():
compilers.append(("compiler=" + compiler, None, compiler_class[compiler][2]))
compilers.sort()
pretty_printer = FancyGetopt(compilers)
pretty_printer.print_help("List of available compilers:")
def new_compiler(plat=None, compiler=None, verbose=0, dry_run=0, force=0):
"""Generate an instance of some CCompiler subclass for the supplied
platform/compiler combination. 'plat' defaults to 'os.name'
(eg. 'posix', 'nt'), and 'compiler' defaults to the default compiler
for that platform. Currently only 'posix' and 'nt' are supported, and
the default compilers are "traditional Unix interface" (UnixCCompiler
class) and Visual C++ (MSVCCompiler class). Note that it's perfectly
possible to ask for a Unix compiler object under Windows, and a
Microsoft compiler object under Unix -- if you supply a value for
'compiler', 'plat' is ignored.
"""
if plat is None:
plat = os.name
try:
if compiler is None:
compiler = get_default_compiler(plat)
(module_name, class_name, long_description) = compiler_class[compiler]
except KeyError:
msg = "don't know how to compile C/C++ code on platform '%s'" % plat
if compiler is not None:
msg = msg + " with '%s' compiler" % compiler
raise DistutilsPlatformError(msg)
try:
module_name = "distutils." + module_name
__import__(module_name)
module = sys.modules[module_name]
klass = vars(module)[class_name]
except ImportError:
raise DistutilsModuleError(
"can't compile C/C++ code: unable to load module '%s'" % module_name
)
except KeyError:
raise DistutilsModuleError(
"can't compile C/C++ code: unable to find class '%s' "
"in module '%s'" % (class_name, module_name)
)
# XXX The None is necessary to preserve backwards compatibility
# with classes that expect verbose to be the first positional
# argument.
return klass(None, dry_run, force)
def gen_preprocess_options(macros, include_dirs):
"""Generate C pre-processor options (-D, -U, -I) as used by at least
two types of compilers: the typical Unix compiler and Visual C++.
'macros' is the usual thing, a list of 1- or 2-tuples, where (name,)
means undefine (-U) macro 'name', and (name,value) means define (-D)
macro 'name' to 'value'. 'include_dirs' is just a list of directory
names to be added to the header file search path (-I). Returns a list
of command-line options suitable for either Unix compilers or Visual
C++.
"""
# XXX it would be nice (mainly aesthetic, and so we don't generate
# stupid-looking command lines) to go over 'macros' and eliminate
# redundant definitions/undefinitions (ie. ensure that only the
# latest mention of a particular macro winds up on the command
# line). I don't think it's essential, though, since most (all?)
# Unix C compilers only pay attention to the latest -D or -U
# mention of a macro on their command line. Similar situation for
# 'include_dirs'. I'm punting on both for now. Anyways, weeding out
# redundancies like this should probably be the province of
# CCompiler, since the data structures used are inherited from it
# and therefore common to all CCompiler classes.
pp_opts = []
for macro in macros:
if not (isinstance(macro, tuple) and 1 <= len(macro) <= 2):
raise TypeError(
"bad macro definition '%s': "
"each element of 'macros' list must be a 1- or 2-tuple" % macro
)
if len(macro) == 1: # undefine this macro
pp_opts.append("-U%s" % macro[0])
elif len(macro) == 2:
if macro[1] is None: # define with no explicit value
pp_opts.append("-D%s" % macro[0])
else:
# XXX *don't* need to be clever about quoting the
# macro value here, because we're going to avoid the
# shell at all costs when we spawn the command!
pp_opts.append("-D%s=%s" % macro)
for dir in include_dirs:
pp_opts.append("-I%s" % dir)
return pp_opts
def gen_lib_options(compiler, library_dirs, runtime_library_dirs, libraries):
"""Generate linker options for searching library directories and
linking with specific libraries. 'libraries' and 'library_dirs' are,
respectively, lists of library names (not filenames!) and search
directories. Returns a list of command-line options suitable for use
with some compiler (depending on the two format strings passed in).
"""
lib_opts = []
for dir in library_dirs:
lib_opts.append(compiler.library_dir_option(dir))
for dir in runtime_library_dirs:
opt = compiler.runtime_library_dir_option(dir)
if isinstance(opt, list):
lib_opts = lib_opts + opt
else:
lib_opts.append(opt)
# XXX it's important that we *not* remove redundant library mentions!
# sometimes you really do have to say "-lfoo -lbar -lfoo" in order to
# resolve all symbols. I just hope we never have to say "-lfoo obj.o
# -lbar" to get things to work -- that's certainly a possibility, but a
# pretty nasty way to arrange your C code.
for lib in libraries:
(lib_dir, lib_name) = os.path.split(lib)
if lib_dir:
lib_file = compiler.find_library_file([lib_dir], lib_name)
if lib_file:
lib_opts.append(lib_file)
else:
compiler.warn(
"no library file corresponding to " "'%s' found (skipping)" % lib
)
else:
lib_opts.append(compiler.library_option(lib))
return lib_opts
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/ccompiler.py
|
Python
|
mit
| 47,369 |
"""distutils.cmd
Provides the Command class, the base class for the command classes
in the distutils.command package.
"""
import sys
import os
import re
from distutils.errors import DistutilsOptionError
from distutils import util, dir_util, file_util, archive_util, dep_util
from distutils import log
class Command:
"""Abstract base class for defining command classes, the "worker bees"
of the Distutils. A useful analogy for command classes is to think of
them as subroutines with local variables called "options". The options
are "declared" in 'initialize_options()' and "defined" (given their
final values, aka "finalized") in 'finalize_options()', both of which
must be defined by every command class. The distinction between the
two is necessary because option values might come from the outside
world (command line, config file, ...), and any options dependent on
other options must be computed *after* these outside influences have
been processed -- hence 'finalize_options()'. The "body" of the
subroutine, where it does all its work based on the values of its
options, is the 'run()' method, which must also be implemented by every
command class.
"""
# 'sub_commands' formalizes the notion of a "family" of commands,
# eg. "install" as the parent with sub-commands "install_lib",
# "install_headers", etc. The parent of a family of commands
# defines 'sub_commands' as a class attribute; it's a list of
# (command_name : string, predicate : unbound_method | string | None)
# tuples, where 'predicate' is a method of the parent command that
# determines whether the corresponding command is applicable in the
# current situation. (Eg. we "install_headers" is only applicable if
# we have any C header files to install.) If 'predicate' is None,
# that command is always applicable.
#
# 'sub_commands' is usually defined at the *end* of a class, because
# predicates can be unbound methods, so they must already have been
# defined. The canonical example is the "install" command.
sub_commands = []
# -- Creation/initialization methods -------------------------------
def __init__(self, dist):
"""Create and initialize a new Command object. Most importantly,
invokes the 'initialize_options()' method, which is the real
initializer and depends on the actual command being
instantiated.
"""
# late import because of mutual dependence between these classes
from distutils.dist import Distribution
if not isinstance(dist, Distribution):
raise TypeError("dist must be a Distribution instance")
if self.__class__ is Command:
raise RuntimeError("Command is an abstract class")
self.distribution = dist
self.initialize_options()
# Per-command versions of the global flags, so that the user can
# customize Distutils' behaviour command-by-command and let some
# commands fall back on the Distribution's behaviour. None means
# "not defined, check self.distribution's copy", while 0 or 1 mean
# false and true (duh). Note that this means figuring out the real
# value of each flag is a touch complicated -- hence "self._dry_run"
# will be handled by __getattr__, below.
# XXX This needs to be fixed.
self._dry_run = None
# verbose is largely ignored, but needs to be set for
# backwards compatibility (I think)?
self.verbose = dist.verbose
# Some commands define a 'self.force' option to ignore file
# timestamps, but methods defined *here* assume that
# 'self.force' exists for all commands. So define it here
# just to be safe.
self.force = None
# The 'help' flag is just used for command-line parsing, so
# none of that complicated bureaucracy is needed.
self.help = 0
# 'finalized' records whether or not 'finalize_options()' has been
# called. 'finalize_options()' itself should not pay attention to
# this flag: it is the business of 'ensure_finalized()', which
# always calls 'finalize_options()', to respect/update it.
self.finalized = 0
# XXX A more explicit way to customize dry_run would be better.
def __getattr__(self, attr):
if attr == 'dry_run':
myval = getattr(self, "_" + attr)
if myval is None:
return getattr(self.distribution, attr)
else:
return myval
else:
raise AttributeError(attr)
def ensure_finalized(self):
if not self.finalized:
self.finalize_options()
self.finalized = 1
# Subclasses must define:
# initialize_options()
# provide default values for all options; may be customized by
# setup script, by options from config file(s), or by command-line
# options
# finalize_options()
# decide on the final values for all options; this is called
# after all possible intervention from the outside world
# (command-line, option file, etc.) has been processed
# run()
# run the command: do whatever it is we're here to do,
# controlled by the command's various option values
def initialize_options(self):
"""Set default values for all the options that this command
supports. Note that these defaults may be overridden by other
commands, by the setup script, by config files, or by the
command-line. Thus, this is not the place to code dependencies
between options; generally, 'initialize_options()' implementations
are just a bunch of "self.foo = None" assignments.
This method must be implemented by all command classes.
"""
raise RuntimeError(
"abstract method -- subclass %s must override" % self.__class__
)
def finalize_options(self):
"""Set final values for all the options that this command supports.
This is always called as late as possible, ie. after any option
assignments from the command-line or from other commands have been
done. Thus, this is the place to code option dependencies: if
'foo' depends on 'bar', then it is safe to set 'foo' from 'bar' as
long as 'foo' still has the same value it was assigned in
'initialize_options()'.
This method must be implemented by all command classes.
"""
raise RuntimeError(
"abstract method -- subclass %s must override" % self.__class__
)
def dump_options(self, header=None, indent=""):
from distutils.fancy_getopt import longopt_xlate
if header is None:
header = "command options for '%s':" % self.get_command_name()
self.announce(indent + header, level=log.INFO)
indent = indent + " "
for (option, _, _) in self.user_options:
option = option.translate(longopt_xlate)
if option[-1] == "=":
option = option[:-1]
value = getattr(self, option)
self.announce(indent + "{} = {}".format(option, value), level=log.INFO)
def run(self):
"""A command's raison d'etre: carry out the action it exists to
perform, controlled by the options initialized in
'initialize_options()', customized by other commands, the setup
script, the command-line, and config files, and finalized in
'finalize_options()'. All terminal output and filesystem
interaction should be done by 'run()'.
This method must be implemented by all command classes.
"""
raise RuntimeError(
"abstract method -- subclass %s must override" % self.__class__
)
def announce(self, msg, level=1):
"""If the current verbosity level is of greater than or equal to
'level' print 'msg' to stdout.
"""
log.log(level, msg)
def debug_print(self, msg):
"""Print 'msg' to stdout if the global DEBUG (taken from the
DISTUTILS_DEBUG environment variable) flag is true.
"""
from distutils.debug import DEBUG
if DEBUG:
print(msg)
sys.stdout.flush()
# -- Option validation methods -------------------------------------
# (these are very handy in writing the 'finalize_options()' method)
#
# NB. the general philosophy here is to ensure that a particular option
# value meets certain type and value constraints. If not, we try to
# force it into conformance (eg. if we expect a list but have a string,
# split the string on comma and/or whitespace). If we can't force the
# option into conformance, raise DistutilsOptionError. Thus, command
# classes need do nothing more than (eg.)
# self.ensure_string_list('foo')
# and they can be guaranteed that thereafter, self.foo will be
# a list of strings.
def _ensure_stringlike(self, option, what, default=None):
val = getattr(self, option)
if val is None:
setattr(self, option, default)
return default
elif not isinstance(val, str):
raise DistutilsOptionError(
"'{}' must be a {} (got `{}`)".format(option, what, val)
)
return val
def ensure_string(self, option, default=None):
"""Ensure that 'option' is a string; if not defined, set it to
'default'.
"""
self._ensure_stringlike(option, "string", default)
def ensure_string_list(self, option):
r"""Ensure that 'option' is a list of strings. If 'option' is
currently a string, we split it either on /,\s*/ or /\s+/, so
"foo bar baz", "foo,bar,baz", and "foo, bar baz" all become
["foo", "bar", "baz"].
"""
val = getattr(self, option)
if val is None:
return
elif isinstance(val, str):
setattr(self, option, re.split(r',\s*|\s+', val))
else:
if isinstance(val, list):
ok = all(isinstance(v, str) for v in val)
else:
ok = False
if not ok:
raise DistutilsOptionError(
"'{}' must be a list of strings (got {!r})".format(option, val)
)
def _ensure_tested_string(self, option, tester, what, error_fmt, default=None):
val = self._ensure_stringlike(option, what, default)
if val is not None and not tester(val):
raise DistutilsOptionError(
("error in '%s' option: " + error_fmt) % (option, val)
)
def ensure_filename(self, option):
"""Ensure that 'option' is the name of an existing file."""
self._ensure_tested_string(
option, os.path.isfile, "filename", "'%s' does not exist or is not a file"
)
def ensure_dirname(self, option):
self._ensure_tested_string(
option,
os.path.isdir,
"directory name",
"'%s' does not exist or is not a directory",
)
# -- Convenience methods for commands ------------------------------
def get_command_name(self):
if hasattr(self, 'command_name'):
return self.command_name
else:
return self.__class__.__name__
def set_undefined_options(self, src_cmd, *option_pairs):
"""Set the values of any "undefined" options from corresponding
option values in some other command object. "Undefined" here means
"is None", which is the convention used to indicate that an option
has not been changed between 'initialize_options()' and
'finalize_options()'. Usually called from 'finalize_options()' for
options that depend on some other command rather than another
option of the same command. 'src_cmd' is the other command from
which option values will be taken (a command object will be created
for it if necessary); the remaining arguments are
'(src_option,dst_option)' tuples which mean "take the value of
'src_option' in the 'src_cmd' command object, and copy it to
'dst_option' in the current command object".
"""
# Option_pairs: list of (src_option, dst_option) tuples
src_cmd_obj = self.distribution.get_command_obj(src_cmd)
src_cmd_obj.ensure_finalized()
for (src_option, dst_option) in option_pairs:
if getattr(self, dst_option) is None:
setattr(self, dst_option, getattr(src_cmd_obj, src_option))
def get_finalized_command(self, command, create=1):
"""Wrapper around Distribution's 'get_command_obj()' method: find
(create if necessary and 'create' is true) the command object for
'command', call its 'ensure_finalized()' method, and return the
finalized command object.
"""
cmd_obj = self.distribution.get_command_obj(command, create)
cmd_obj.ensure_finalized()
return cmd_obj
# XXX rename to 'get_reinitialized_command()'? (should do the
# same in dist.py, if so)
def reinitialize_command(self, command, reinit_subcommands=0):
return self.distribution.reinitialize_command(command, reinit_subcommands)
def run_command(self, command):
"""Run some other command: uses the 'run_command()' method of
Distribution, which creates and finalizes the command object if
necessary and then invokes its 'run()' method.
"""
self.distribution.run_command(command)
def get_sub_commands(self):
"""Determine the sub-commands that are relevant in the current
distribution (ie., that need to be run). This is based on the
'sub_commands' class attribute: each tuple in that list may include
a method that we call to determine if the subcommand needs to be
run for the current distribution. Return a list of command names.
"""
commands = []
for (cmd_name, method) in self.sub_commands:
if method is None or method(self):
commands.append(cmd_name)
return commands
# -- External world manipulation -----------------------------------
def warn(self, msg):
log.warn("warning: %s: %s\n", self.get_command_name(), msg)
def execute(self, func, args, msg=None, level=1):
util.execute(func, args, msg, dry_run=self.dry_run)
def mkpath(self, name, mode=0o777):
dir_util.mkpath(name, mode, dry_run=self.dry_run)
def copy_file(
self, infile, outfile, preserve_mode=1, preserve_times=1, link=None, level=1
):
"""Copy a file respecting verbose, dry-run and force flags. (The
former two default to whatever is in the Distribution object, and
the latter defaults to false for commands that don't define it.)"""
return file_util.copy_file(
infile,
outfile,
preserve_mode,
preserve_times,
not self.force,
link,
dry_run=self.dry_run,
)
def copy_tree(
self,
infile,
outfile,
preserve_mode=1,
preserve_times=1,
preserve_symlinks=0,
level=1,
):
"""Copy an entire directory tree respecting verbose, dry-run,
and force flags.
"""
return dir_util.copy_tree(
infile,
outfile,
preserve_mode,
preserve_times,
preserve_symlinks,
not self.force,
dry_run=self.dry_run,
)
def move_file(self, src, dst, level=1):
"""Move a file respecting dry-run flag."""
return file_util.move_file(src, dst, dry_run=self.dry_run)
def spawn(self, cmd, search_path=1, level=1):
"""Spawn an external command respecting dry-run flag."""
from distutils.spawn import spawn
spawn(cmd, search_path, dry_run=self.dry_run)
def make_archive(
self, base_name, format, root_dir=None, base_dir=None, owner=None, group=None
):
return archive_util.make_archive(
base_name,
format,
root_dir,
base_dir,
dry_run=self.dry_run,
owner=owner,
group=group,
)
def make_file(
self, infiles, outfile, func, args, exec_msg=None, skip_msg=None, level=1
):
"""Special case of 'execute()' for operations that process one or
more input files and generate one output file. Works just like
'execute()', except the operation is skipped and a different
message printed if 'outfile' already exists and is newer than all
files listed in 'infiles'. If the command defined 'self.force',
and it is true, then the command is unconditionally run -- does no
timestamp checks.
"""
if skip_msg is None:
skip_msg = "skipping %s (inputs unchanged)" % outfile
# Allow 'infiles' to be a single string
if isinstance(infiles, str):
infiles = (infiles,)
elif not isinstance(infiles, (list, tuple)):
raise TypeError("'infiles' must be a string, or a list or tuple of strings")
if exec_msg is None:
exec_msg = "generating {} from {}".format(outfile, ', '.join(infiles))
# If 'outfile' must be regenerated (either because it doesn't
# exist, is out-of-date, or the 'force' flag is true) then
# perform the action that presumably regenerates it
if self.force or dep_util.newer_group(infiles, outfile):
self.execute(func, args, exec_msg, level)
# Otherwise, print the "skip" message
else:
log.debug(skip_msg)
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/cmd.py
|
Python
|
mit
| 17,973 |
"""distutils.command
Package containing implementation of all the standard Distutils
commands."""
__all__ = [ # noqa: F822
'build',
'build_py',
'build_ext',
'build_clib',
'build_scripts',
'clean',
'install',
'install_lib',
'install_headers',
'install_scripts',
'install_data',
'sdist',
'register',
'bdist',
'bdist_dumb',
'bdist_rpm',
'check',
'upload',
]
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/__init__.py
|
Python
|
mit
| 430 |
"""
Backward compatibility for homebrew builds on macOS.
"""
import sys
import os
import functools
import subprocess
import sysconfig
@functools.lru_cache()
def enabled():
"""
Only enabled for Python 3.9 framework homebrew builds
except ensurepip and venv.
"""
PY39 = (3, 9) < sys.version_info < (3, 10)
framework = sys.platform == 'darwin' and sys._framework
homebrew = "Cellar" in sysconfig.get_config_var('projectbase')
venv = sys.prefix != sys.base_prefix
ensurepip = os.environ.get("ENSUREPIP_OPTIONS")
return PY39 and framework and homebrew and not venv and not ensurepip
schemes = dict(
osx_framework_library=dict(
stdlib='{installed_base}/{platlibdir}/python{py_version_short}',
platstdlib='{platbase}/{platlibdir}/python{py_version_short}',
purelib='{homebrew_prefix}/lib/python{py_version_short}/site-packages',
platlib='{homebrew_prefix}/{platlibdir}/python{py_version_short}/site-packages',
include='{installed_base}/include/python{py_version_short}{abiflags}',
platinclude='{installed_platbase}/include/python{py_version_short}{abiflags}',
scripts='{homebrew_prefix}/bin',
data='{homebrew_prefix}',
)
)
@functools.lru_cache()
def vars():
if not enabled():
return {}
homebrew_prefix = subprocess.check_output(['brew', '--prefix'], text=True).strip()
return locals()
def scheme(name):
"""
Override the selected scheme for posix_prefix.
"""
if not enabled() or not name.endswith('_prefix'):
return name
return 'osx_framework_library'
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/_framework_compat.py
|
Python
|
mit
| 1,614 |
"""distutils.command.bdist
Implements the Distutils 'bdist' command (create a built [binary]
distribution)."""
import os
import warnings
from distutils.core import Command
from distutils.errors import DistutilsPlatformError, DistutilsOptionError
from distutils.util import get_platform
def show_formats():
"""Print list of available formats (arguments to "--format" option)."""
from distutils.fancy_getopt import FancyGetopt
formats = []
for format in bdist.format_commands:
formats.append(("formats=" + format, None, bdist.format_commands[format][1]))
pretty_printer = FancyGetopt(formats)
pretty_printer.print_help("List of available distribution formats:")
class ListCompat(dict):
# adapter to allow for Setuptools compatibility in format_commands
def append(self, item):
warnings.warn(
"""format_commands is now a dict. append is deprecated.""",
DeprecationWarning,
stacklevel=2,
)
class bdist(Command):
description = "create a built (binary) distribution"
user_options = [
('bdist-base=', 'b', "temporary directory for creating built distributions"),
(
'plat-name=',
'p',
"platform name to embed in generated filenames "
"(default: %s)" % get_platform(),
),
('formats=', None, "formats for distribution (comma-separated list)"),
(
'dist-dir=',
'd',
"directory to put final built distributions in " "[default: dist]",
),
('skip-build', None, "skip rebuilding everything (for testing/debugging)"),
(
'owner=',
'u',
"Owner name used when creating a tar file" " [default: current user]",
),
(
'group=',
'g',
"Group name used when creating a tar file" " [default: current group]",
),
]
boolean_options = ['skip-build']
help_options = [
('help-formats', None, "lists available distribution formats", show_formats),
]
# The following commands do not take a format option from bdist
no_format_option = ('bdist_rpm',)
# This won't do in reality: will need to distinguish RPM-ish Linux,
# Debian-ish Linux, Solaris, FreeBSD, ..., Windows, Mac OS.
default_format = {'posix': 'gztar', 'nt': 'zip'}
# Define commands in preferred order for the --help-formats option
format_commands = ListCompat(
{
'rpm': ('bdist_rpm', "RPM distribution"),
'gztar': ('bdist_dumb', "gzip'ed tar file"),
'bztar': ('bdist_dumb', "bzip2'ed tar file"),
'xztar': ('bdist_dumb', "xz'ed tar file"),
'ztar': ('bdist_dumb', "compressed tar file"),
'tar': ('bdist_dumb', "tar file"),
'zip': ('bdist_dumb', "ZIP file"),
}
)
# for compatibility until consumers only reference format_commands
format_command = format_commands
def initialize_options(self):
self.bdist_base = None
self.plat_name = None
self.formats = None
self.dist_dir = None
self.skip_build = 0
self.group = None
self.owner = None
def finalize_options(self):
# have to finalize 'plat_name' before 'bdist_base'
if self.plat_name is None:
if self.skip_build:
self.plat_name = get_platform()
else:
self.plat_name = self.get_finalized_command('build').plat_name
# 'bdist_base' -- parent of per-built-distribution-format
# temporary directories (eg. we'll probably have
# "build/bdist.<plat>/dumb", "build/bdist.<plat>/rpm", etc.)
if self.bdist_base is None:
build_base = self.get_finalized_command('build').build_base
self.bdist_base = os.path.join(build_base, 'bdist.' + self.plat_name)
self.ensure_string_list('formats')
if self.formats is None:
try:
self.formats = [self.default_format[os.name]]
except KeyError:
raise DistutilsPlatformError(
"don't know how to create built distributions "
"on platform %s" % os.name
)
if self.dist_dir is None:
self.dist_dir = "dist"
def run(self):
# Figure out which sub-commands we need to run.
commands = []
for format in self.formats:
try:
commands.append(self.format_commands[format][0])
except KeyError:
raise DistutilsOptionError("invalid format '%s'" % format)
# Reinitialize and run each command.
for i in range(len(self.formats)):
cmd_name = commands[i]
sub_cmd = self.reinitialize_command(cmd_name)
if cmd_name not in self.no_format_option:
sub_cmd.format = self.formats[i]
# passing the owner and group names for tar archiving
if cmd_name == 'bdist_dumb':
sub_cmd.owner = self.owner
sub_cmd.group = self.group
# If we're going to need to run this command again, tell it to
# keep its temporary files around so subsequent runs go faster.
if cmd_name in commands[i + 1 :]:
sub_cmd.keep_temp = 1
self.run_command(cmd_name)
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/bdist.py
|
Python
|
mit
| 5,441 |
"""distutils.command.bdist_dumb
Implements the Distutils 'bdist_dumb' command (create a "dumb" built
distribution -- i.e., just an archive to be unpacked under $prefix or
$exec_prefix)."""
import os
from distutils.core import Command
from distutils.util import get_platform
from distutils.dir_util import remove_tree, ensure_relative
from distutils.errors import DistutilsPlatformError
from distutils.sysconfig import get_python_version
from distutils import log
class bdist_dumb(Command):
description = "create a \"dumb\" built distribution"
user_options = [
('bdist-dir=', 'd', "temporary directory for creating the distribution"),
(
'plat-name=',
'p',
"platform name to embed in generated filenames "
"(default: %s)" % get_platform(),
),
(
'format=',
'f',
"archive format to create (tar, gztar, bztar, xztar, " "ztar, zip)",
),
(
'keep-temp',
'k',
"keep the pseudo-installation tree around after "
+ "creating the distribution archive",
),
('dist-dir=', 'd', "directory to put final built distributions in"),
('skip-build', None, "skip rebuilding everything (for testing/debugging)"),
(
'relative',
None,
"build the archive using relative paths " "(default: false)",
),
(
'owner=',
'u',
"Owner name used when creating a tar file" " [default: current user]",
),
(
'group=',
'g',
"Group name used when creating a tar file" " [default: current group]",
),
]
boolean_options = ['keep-temp', 'skip-build', 'relative']
default_format = {'posix': 'gztar', 'nt': 'zip'}
def initialize_options(self):
self.bdist_dir = None
self.plat_name = None
self.format = None
self.keep_temp = 0
self.dist_dir = None
self.skip_build = None
self.relative = 0
self.owner = None
self.group = None
def finalize_options(self):
if self.bdist_dir is None:
bdist_base = self.get_finalized_command('bdist').bdist_base
self.bdist_dir = os.path.join(bdist_base, 'dumb')
if self.format is None:
try:
self.format = self.default_format[os.name]
except KeyError:
raise DistutilsPlatformError(
"don't know how to create dumb built distributions "
"on platform %s" % os.name
)
self.set_undefined_options(
'bdist',
('dist_dir', 'dist_dir'),
('plat_name', 'plat_name'),
('skip_build', 'skip_build'),
)
def run(self):
if not self.skip_build:
self.run_command('build')
install = self.reinitialize_command('install', reinit_subcommands=1)
install.root = self.bdist_dir
install.skip_build = self.skip_build
install.warn_dir = 0
log.info("installing to %s", self.bdist_dir)
self.run_command('install')
# And make an archive relative to the root of the
# pseudo-installation tree.
archive_basename = "{}.{}".format(
self.distribution.get_fullname(), self.plat_name
)
pseudoinstall_root = os.path.join(self.dist_dir, archive_basename)
if not self.relative:
archive_root = self.bdist_dir
else:
if self.distribution.has_ext_modules() and (
install.install_base != install.install_platbase
):
raise DistutilsPlatformError(
"can't make a dumb built distribution where "
"base and platbase are different (%s, %s)"
% (repr(install.install_base), repr(install.install_platbase))
)
else:
archive_root = os.path.join(
self.bdist_dir, ensure_relative(install.install_base)
)
# Make the archive
filename = self.make_archive(
pseudoinstall_root,
self.format,
root_dir=archive_root,
owner=self.owner,
group=self.group,
)
if self.distribution.has_ext_modules():
pyversion = get_python_version()
else:
pyversion = 'any'
self.distribution.dist_files.append(('bdist_dumb', pyversion, filename))
if not self.keep_temp:
remove_tree(self.bdist_dir, dry_run=self.dry_run)
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/bdist_dumb.py
|
Python
|
mit
| 4,701 |
"""distutils.command.bdist_rpm
Implements the Distutils 'bdist_rpm' command (create RPM source and binary
distributions)."""
import subprocess
import sys
import os
from distutils.core import Command
from distutils.debug import DEBUG
from distutils.file_util import write_file
from distutils.errors import (
DistutilsOptionError,
DistutilsPlatformError,
DistutilsFileError,
DistutilsExecError,
)
from distutils.sysconfig import get_python_version
from distutils import log
class bdist_rpm(Command):
description = "create an RPM distribution"
user_options = [
('bdist-base=', None, "base directory for creating built distributions"),
(
'rpm-base=',
None,
"base directory for creating RPMs (defaults to \"rpm\" under "
"--bdist-base; must be specified for RPM 2)",
),
(
'dist-dir=',
'd',
"directory to put final RPM files in " "(and .spec files if --spec-only)",
),
(
'python=',
None,
"path to Python interpreter to hard-code in the .spec file "
"(default: \"python\")",
),
(
'fix-python',
None,
"hard-code the exact path to the current Python interpreter in "
"the .spec file",
),
('spec-only', None, "only regenerate spec file"),
('source-only', None, "only generate source RPM"),
('binary-only', None, "only generate binary RPM"),
('use-bzip2', None, "use bzip2 instead of gzip to create source distribution"),
# More meta-data: too RPM-specific to put in the setup script,
# but needs to go in the .spec file -- so we make these options
# to "bdist_rpm". The idea is that packagers would put this
# info in setup.cfg, although they are of course free to
# supply it on the command line.
(
'distribution-name=',
None,
"name of the (Linux) distribution to which this "
"RPM applies (*not* the name of the module distribution!)",
),
('group=', None, "package classification [default: \"Development/Libraries\"]"),
('release=', None, "RPM release number"),
('serial=', None, "RPM serial number"),
(
'vendor=',
None,
"RPM \"vendor\" (eg. \"Joe Blow <joe@example.com>\") "
"[default: maintainer or author from setup script]",
),
(
'packager=',
None,
"RPM packager (eg. \"Jane Doe <jane@example.net>\") " "[default: vendor]",
),
('doc-files=', None, "list of documentation files (space or comma-separated)"),
('changelog=', None, "RPM changelog"),
('icon=', None, "name of icon file"),
('provides=', None, "capabilities provided by this package"),
('requires=', None, "capabilities required by this package"),
('conflicts=', None, "capabilities which conflict with this package"),
('build-requires=', None, "capabilities required to build this package"),
('obsoletes=', None, "capabilities made obsolete by this package"),
('no-autoreq', None, "do not automatically calculate dependencies"),
# Actions to take when building RPM
('keep-temp', 'k', "don't clean up RPM build directory"),
('no-keep-temp', None, "clean up RPM build directory [default]"),
(
'use-rpm-opt-flags',
None,
"compile with RPM_OPT_FLAGS when building from source RPM",
),
('no-rpm-opt-flags', None, "do not pass any RPM CFLAGS to compiler"),
('rpm3-mode', None, "RPM 3 compatibility mode (default)"),
('rpm2-mode', None, "RPM 2 compatibility mode"),
# Add the hooks necessary for specifying custom scripts
('prep-script=', None, "Specify a script for the PREP phase of RPM building"),
('build-script=', None, "Specify a script for the BUILD phase of RPM building"),
(
'pre-install=',
None,
"Specify a script for the pre-INSTALL phase of RPM building",
),
(
'install-script=',
None,
"Specify a script for the INSTALL phase of RPM building",
),
(
'post-install=',
None,
"Specify a script for the post-INSTALL phase of RPM building",
),
(
'pre-uninstall=',
None,
"Specify a script for the pre-UNINSTALL phase of RPM building",
),
(
'post-uninstall=',
None,
"Specify a script for the post-UNINSTALL phase of RPM building",
),
('clean-script=', None, "Specify a script for the CLEAN phase of RPM building"),
(
'verify-script=',
None,
"Specify a script for the VERIFY phase of the RPM build",
),
# Allow a packager to explicitly force an architecture
('force-arch=', None, "Force an architecture onto the RPM build process"),
('quiet', 'q', "Run the INSTALL phase of RPM building in quiet mode"),
]
boolean_options = [
'keep-temp',
'use-rpm-opt-flags',
'rpm3-mode',
'no-autoreq',
'quiet',
]
negative_opt = {
'no-keep-temp': 'keep-temp',
'no-rpm-opt-flags': 'use-rpm-opt-flags',
'rpm2-mode': 'rpm3-mode',
}
def initialize_options(self):
self.bdist_base = None
self.rpm_base = None
self.dist_dir = None
self.python = None
self.fix_python = None
self.spec_only = None
self.binary_only = None
self.source_only = None
self.use_bzip2 = None
self.distribution_name = None
self.group = None
self.release = None
self.serial = None
self.vendor = None
self.packager = None
self.doc_files = None
self.changelog = None
self.icon = None
self.prep_script = None
self.build_script = None
self.install_script = None
self.clean_script = None
self.verify_script = None
self.pre_install = None
self.post_install = None
self.pre_uninstall = None
self.post_uninstall = None
self.prep = None
self.provides = None
self.requires = None
self.conflicts = None
self.build_requires = None
self.obsoletes = None
self.keep_temp = 0
self.use_rpm_opt_flags = 1
self.rpm3_mode = 1
self.no_autoreq = 0
self.force_arch = None
self.quiet = 0
def finalize_options(self):
self.set_undefined_options('bdist', ('bdist_base', 'bdist_base'))
if self.rpm_base is None:
if not self.rpm3_mode:
raise DistutilsOptionError("you must specify --rpm-base in RPM 2 mode")
self.rpm_base = os.path.join(self.bdist_base, "rpm")
if self.python is None:
if self.fix_python:
self.python = sys.executable
else:
self.python = "python3"
elif self.fix_python:
raise DistutilsOptionError(
"--python and --fix-python are mutually exclusive options"
)
if os.name != 'posix':
raise DistutilsPlatformError(
"don't know how to create RPM " "distributions on platform %s" % os.name
)
if self.binary_only and self.source_only:
raise DistutilsOptionError(
"cannot supply both '--source-only' and '--binary-only'"
)
# don't pass CFLAGS to pure python distributions
if not self.distribution.has_ext_modules():
self.use_rpm_opt_flags = 0
self.set_undefined_options('bdist', ('dist_dir', 'dist_dir'))
self.finalize_package_data()
def finalize_package_data(self):
self.ensure_string('group', "Development/Libraries")
self.ensure_string(
'vendor',
"%s <%s>"
% (self.distribution.get_contact(), self.distribution.get_contact_email()),
)
self.ensure_string('packager')
self.ensure_string_list('doc_files')
if isinstance(self.doc_files, list):
for readme in ('README', 'README.txt'):
if os.path.exists(readme) and readme not in self.doc_files:
self.doc_files.append(readme)
self.ensure_string('release', "1")
self.ensure_string('serial') # should it be an int?
self.ensure_string('distribution_name')
self.ensure_string('changelog')
# Format changelog correctly
self.changelog = self._format_changelog(self.changelog)
self.ensure_filename('icon')
self.ensure_filename('prep_script')
self.ensure_filename('build_script')
self.ensure_filename('install_script')
self.ensure_filename('clean_script')
self.ensure_filename('verify_script')
self.ensure_filename('pre_install')
self.ensure_filename('post_install')
self.ensure_filename('pre_uninstall')
self.ensure_filename('post_uninstall')
# XXX don't forget we punted on summaries and descriptions -- they
# should be handled here eventually!
# Now *this* is some meta-data that belongs in the setup script...
self.ensure_string_list('provides')
self.ensure_string_list('requires')
self.ensure_string_list('conflicts')
self.ensure_string_list('build_requires')
self.ensure_string_list('obsoletes')
self.ensure_string('force_arch')
def run(self): # noqa: C901
if DEBUG:
print("before _get_package_data():")
print("vendor =", self.vendor)
print("packager =", self.packager)
print("doc_files =", self.doc_files)
print("changelog =", self.changelog)
# make directories
if self.spec_only:
spec_dir = self.dist_dir
self.mkpath(spec_dir)
else:
rpm_dir = {}
for d in ('SOURCES', 'SPECS', 'BUILD', 'RPMS', 'SRPMS'):
rpm_dir[d] = os.path.join(self.rpm_base, d)
self.mkpath(rpm_dir[d])
spec_dir = rpm_dir['SPECS']
# Spec file goes into 'dist_dir' if '--spec-only specified',
# build/rpm.<plat> otherwise.
spec_path = os.path.join(spec_dir, "%s.spec" % self.distribution.get_name())
self.execute(
write_file, (spec_path, self._make_spec_file()), "writing '%s'" % spec_path
)
if self.spec_only: # stop if requested
return
# Make a source distribution and copy to SOURCES directory with
# optional icon.
saved_dist_files = self.distribution.dist_files[:]
sdist = self.reinitialize_command('sdist')
if self.use_bzip2:
sdist.formats = ['bztar']
else:
sdist.formats = ['gztar']
self.run_command('sdist')
self.distribution.dist_files = saved_dist_files
source = sdist.get_archive_files()[0]
source_dir = rpm_dir['SOURCES']
self.copy_file(source, source_dir)
if self.icon:
if os.path.exists(self.icon):
self.copy_file(self.icon, source_dir)
else:
raise DistutilsFileError("icon file '%s' does not exist" % self.icon)
# build package
log.info("building RPMs")
rpm_cmd = ['rpmbuild']
if self.source_only: # what kind of RPMs?
rpm_cmd.append('-bs')
elif self.binary_only:
rpm_cmd.append('-bb')
else:
rpm_cmd.append('-ba')
rpm_cmd.extend(['--define', '__python %s' % self.python])
if self.rpm3_mode:
rpm_cmd.extend(['--define', '_topdir %s' % os.path.abspath(self.rpm_base)])
if not self.keep_temp:
rpm_cmd.append('--clean')
if self.quiet:
rpm_cmd.append('--quiet')
rpm_cmd.append(spec_path)
# Determine the binary rpm names that should be built out of this spec
# file
# Note that some of these may not be really built (if the file
# list is empty)
nvr_string = "%{name}-%{version}-%{release}"
src_rpm = nvr_string + ".src.rpm"
non_src_rpm = "%{arch}/" + nvr_string + ".%{arch}.rpm"
q_cmd = r"rpm -q --qf '{} {}\n' --specfile '{}'".format(
src_rpm,
non_src_rpm,
spec_path,
)
out = os.popen(q_cmd)
try:
binary_rpms = []
source_rpm = None
while True:
line = out.readline()
if not line:
break
ell = line.strip().split()
assert len(ell) == 2
binary_rpms.append(ell[1])
# The source rpm is named after the first entry in the spec file
if source_rpm is None:
source_rpm = ell[0]
status = out.close()
if status:
raise DistutilsExecError("Failed to execute: %s" % repr(q_cmd))
finally:
out.close()
self.spawn(rpm_cmd)
if not self.dry_run:
if self.distribution.has_ext_modules():
pyversion = get_python_version()
else:
pyversion = 'any'
if not self.binary_only:
srpm = os.path.join(rpm_dir['SRPMS'], source_rpm)
assert os.path.exists(srpm)
self.move_file(srpm, self.dist_dir)
filename = os.path.join(self.dist_dir, source_rpm)
self.distribution.dist_files.append(('bdist_rpm', pyversion, filename))
if not self.source_only:
for rpm in binary_rpms:
rpm = os.path.join(rpm_dir['RPMS'], rpm)
if os.path.exists(rpm):
self.move_file(rpm, self.dist_dir)
filename = os.path.join(self.dist_dir, os.path.basename(rpm))
self.distribution.dist_files.append(
('bdist_rpm', pyversion, filename)
)
def _dist_path(self, path):
return os.path.join(self.dist_dir, os.path.basename(path))
def _make_spec_file(self): # noqa: C901
"""Generate the text of an RPM spec file and return it as a
list of strings (one per line).
"""
# definitions and headers
spec_file = [
'%define name ' + self.distribution.get_name(),
'%define version ' + self.distribution.get_version().replace('-', '_'),
'%define unmangled_version ' + self.distribution.get_version(),
'%define release ' + self.release.replace('-', '_'),
'',
'Summary: ' + (self.distribution.get_description() or "UNKNOWN"),
]
# Workaround for #14443 which affects some RPM based systems such as
# RHEL6 (and probably derivatives)
vendor_hook = subprocess.getoutput('rpm --eval %{__os_install_post}')
# Generate a potential replacement value for __os_install_post (whilst
# normalizing the whitespace to simplify the test for whether the
# invocation of brp-python-bytecompile passes in __python):
vendor_hook = '\n'.join(
[' %s \\' % line.strip() for line in vendor_hook.splitlines()]
)
problem = "brp-python-bytecompile \\\n"
fixed = "brp-python-bytecompile %{__python} \\\n"
fixed_hook = vendor_hook.replace(problem, fixed)
if fixed_hook != vendor_hook:
spec_file.append('# Workaround for http://bugs.python.org/issue14443')
spec_file.append('%define __os_install_post ' + fixed_hook + '\n')
# put locale summaries into spec file
# XXX not supported for now (hard to put a dictionary
# in a config file -- arg!)
# for locale in self.summaries.keys():
# spec_file.append('Summary(%s): %s' % (locale,
# self.summaries[locale]))
spec_file.extend(
[
'Name: %{name}',
'Version: %{version}',
'Release: %{release}',
]
)
# XXX yuck! this filename is available from the "sdist" command,
# but only after it has run: and we create the spec file before
# running "sdist", in case of --spec-only.
if self.use_bzip2:
spec_file.append('Source0: %{name}-%{unmangled_version}.tar.bz2')
else:
spec_file.append('Source0: %{name}-%{unmangled_version}.tar.gz')
spec_file.extend(
[
'License: ' + (self.distribution.get_license() or "UNKNOWN"),
'Group: ' + self.group,
'BuildRoot: %{_tmppath}/%{name}-%{version}-%{release}-buildroot',
'Prefix: %{_prefix}',
]
)
if not self.force_arch:
# noarch if no extension modules
if not self.distribution.has_ext_modules():
spec_file.append('BuildArch: noarch')
else:
spec_file.append('BuildArch: %s' % self.force_arch)
for field in (
'Vendor',
'Packager',
'Provides',
'Requires',
'Conflicts',
'Obsoletes',
):
val = getattr(self, field.lower())
if isinstance(val, list):
spec_file.append('{}: {}'.format(field, ' '.join(val)))
elif val is not None:
spec_file.append('{}: {}'.format(field, val))
if self.distribution.get_url():
spec_file.append('Url: ' + self.distribution.get_url())
if self.distribution_name:
spec_file.append('Distribution: ' + self.distribution_name)
if self.build_requires:
spec_file.append('BuildRequires: ' + ' '.join(self.build_requires))
if self.icon:
spec_file.append('Icon: ' + os.path.basename(self.icon))
if self.no_autoreq:
spec_file.append('AutoReq: 0')
spec_file.extend(
[
'',
'%description',
self.distribution.get_long_description() or "",
]
)
# put locale descriptions into spec file
# XXX again, suppressed because config file syntax doesn't
# easily support this ;-(
# for locale in self.descriptions.keys():
# spec_file.extend([
# '',
# '%description -l ' + locale,
# self.descriptions[locale],
# ])
# rpm scripts
# figure out default build script
def_setup_call = "{} {}".format(self.python, os.path.basename(sys.argv[0]))
def_build = "%s build" % def_setup_call
if self.use_rpm_opt_flags:
def_build = 'env CFLAGS="$RPM_OPT_FLAGS" ' + def_build
# insert contents of files
# XXX this is kind of misleading: user-supplied options are files
# that we open and interpolate into the spec file, but the defaults
# are just text that we drop in as-is. Hmmm.
install_cmd = (
'%s install -O1 --root=$RPM_BUILD_ROOT ' '--record=INSTALLED_FILES'
) % def_setup_call
script_options = [
('prep', 'prep_script', "%setup -n %{name}-%{unmangled_version}"),
('build', 'build_script', def_build),
('install', 'install_script', install_cmd),
('clean', 'clean_script', "rm -rf $RPM_BUILD_ROOT"),
('verifyscript', 'verify_script', None),
('pre', 'pre_install', None),
('post', 'post_install', None),
('preun', 'pre_uninstall', None),
('postun', 'post_uninstall', None),
]
for (rpm_opt, attr, default) in script_options:
# Insert contents of file referred to, if no file is referred to
# use 'default' as contents of script
val = getattr(self, attr)
if val or default:
spec_file.extend(
[
'',
'%' + rpm_opt,
]
)
if val:
with open(val) as f:
spec_file.extend(f.read().split('\n'))
else:
spec_file.append(default)
# files section
spec_file.extend(
[
'',
'%files -f INSTALLED_FILES',
'%defattr(-,root,root)',
]
)
if self.doc_files:
spec_file.append('%doc ' + ' '.join(self.doc_files))
if self.changelog:
spec_file.extend(
[
'',
'%changelog',
]
)
spec_file.extend(self.changelog)
return spec_file
def _format_changelog(self, changelog):
"""Format the changelog correctly and convert it to a list of strings"""
if not changelog:
return changelog
new_changelog = []
for line in changelog.strip().split('\n'):
line = line.strip()
if line[0] == '*':
new_changelog.extend(['', line])
elif line[0] == '-':
new_changelog.append(line)
else:
new_changelog.append(' ' + line)
# strip trailing newline inserted by first changelog entry
if not new_changelog[0]:
del new_changelog[0]
return new_changelog
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/bdist_rpm.py
|
Python
|
mit
| 22,051 |
"""distutils.command.build
Implements the Distutils 'build' command."""
import sys
import os
from distutils.core import Command
from distutils.errors import DistutilsOptionError
from distutils.util import get_platform
def show_compilers():
from distutils.ccompiler import show_compilers
show_compilers()
class build(Command):
description = "build everything needed to install"
user_options = [
('build-base=', 'b', "base directory for build library"),
('build-purelib=', None, "build directory for platform-neutral distributions"),
('build-platlib=', None, "build directory for platform-specific distributions"),
(
'build-lib=',
None,
"build directory for all distribution (defaults to either "
+ "build-purelib or build-platlib",
),
('build-scripts=', None, "build directory for scripts"),
('build-temp=', 't', "temporary build directory"),
(
'plat-name=',
'p',
"platform name to build for, if supported "
"(default: %s)" % get_platform(),
),
('compiler=', 'c', "specify the compiler type"),
('parallel=', 'j', "number of parallel build jobs"),
('debug', 'g', "compile extensions and libraries with debugging information"),
('force', 'f', "forcibly build everything (ignore file timestamps)"),
('executable=', 'e', "specify final destination interpreter path (build.py)"),
]
boolean_options = ['debug', 'force']
help_options = [
('help-compiler', None, "list available compilers", show_compilers),
]
def initialize_options(self):
self.build_base = 'build'
# these are decided only after 'build_base' has its final value
# (unless overridden by the user or client)
self.build_purelib = None
self.build_platlib = None
self.build_lib = None
self.build_temp = None
self.build_scripts = None
self.compiler = None
self.plat_name = None
self.debug = None
self.force = 0
self.executable = None
self.parallel = None
def finalize_options(self): # noqa: C901
if self.plat_name is None:
self.plat_name = get_platform()
else:
# plat-name only supported for windows (other platforms are
# supported via ./configure flags, if at all). Avoid misleading
# other platforms.
if os.name != 'nt':
raise DistutilsOptionError(
"--plat-name only supported on Windows (try "
"using './configure --help' on your platform)"
)
plat_specifier = ".{}-{}".format(self.plat_name, sys.implementation.cache_tag)
# Make it so Python 2.x and Python 2.x with --with-pydebug don't
# share the same build directories. Doing so confuses the build
# process for C modules
if hasattr(sys, 'gettotalrefcount'):
plat_specifier += '-pydebug'
# 'build_purelib' and 'build_platlib' just default to 'lib' and
# 'lib.<plat>' under the base build directory. We only use one of
# them for a given distribution, though --
if self.build_purelib is None:
self.build_purelib = os.path.join(self.build_base, 'lib')
if self.build_platlib is None:
self.build_platlib = os.path.join(self.build_base, 'lib' + plat_specifier)
# 'build_lib' is the actual directory that we will use for this
# particular module distribution -- if user didn't supply it, pick
# one of 'build_purelib' or 'build_platlib'.
if self.build_lib is None:
if self.distribution.has_ext_modules():
self.build_lib = self.build_platlib
else:
self.build_lib = self.build_purelib
# 'build_temp' -- temporary directory for compiler turds,
# "build/temp.<plat>"
if self.build_temp is None:
self.build_temp = os.path.join(self.build_base, 'temp' + plat_specifier)
if self.build_scripts is None:
self.build_scripts = os.path.join(
self.build_base, 'scripts-%d.%d' % sys.version_info[:2]
)
if self.executable is None and sys.executable:
self.executable = os.path.normpath(sys.executable)
if isinstance(self.parallel, str):
try:
self.parallel = int(self.parallel)
except ValueError:
raise DistutilsOptionError("parallel should be an integer")
def run(self):
# Run all relevant sub-commands. This will be some subset of:
# - build_py - pure Python modules
# - build_clib - standalone C libraries
# - build_ext - Python extensions
# - build_scripts - (Python) scripts
for cmd_name in self.get_sub_commands():
self.run_command(cmd_name)
# -- Predicates for the sub-command list ---------------------------
def has_pure_modules(self):
return self.distribution.has_pure_modules()
def has_c_libraries(self):
return self.distribution.has_c_libraries()
def has_ext_modules(self):
return self.distribution.has_ext_modules()
def has_scripts(self):
return self.distribution.has_scripts()
sub_commands = [
('build_py', has_pure_modules),
('build_clib', has_c_libraries),
('build_ext', has_ext_modules),
('build_scripts', has_scripts),
]
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/build.py
|
Python
|
mit
| 5,617 |
"""distutils.command.build_clib
Implements the Distutils 'build_clib' command, to build a C/C++ library
that is included in the module distribution and needed by an extension
module."""
# XXX this module has *lots* of code ripped-off quite transparently from
# build_ext.py -- not surprisingly really, as the work required to build
# a static library from a collection of C source files is not really all
# that different from what's required to build a shared object file from
# a collection of C source files. Nevertheless, I haven't done the
# necessary refactoring to account for the overlap in code between the
# two modules, mainly because a number of subtle details changed in the
# cut 'n paste. Sigh.
import os
from distutils.core import Command
from distutils.errors import DistutilsSetupError
from distutils.sysconfig import customize_compiler
from distutils import log
def show_compilers():
from distutils.ccompiler import show_compilers
show_compilers()
class build_clib(Command):
description = "build C/C++ libraries used by Python extensions"
user_options = [
('build-clib=', 'b', "directory to build C/C++ libraries to"),
('build-temp=', 't', "directory to put temporary build by-products"),
('debug', 'g', "compile with debugging information"),
('force', 'f', "forcibly build everything (ignore file timestamps)"),
('compiler=', 'c', "specify the compiler type"),
]
boolean_options = ['debug', 'force']
help_options = [
('help-compiler', None, "list available compilers", show_compilers),
]
def initialize_options(self):
self.build_clib = None
self.build_temp = None
# List of libraries to build
self.libraries = None
# Compilation options for all libraries
self.include_dirs = None
self.define = None
self.undef = None
self.debug = None
self.force = 0
self.compiler = None
def finalize_options(self):
# This might be confusing: both build-clib and build-temp default
# to build-temp as defined by the "build" command. This is because
# I think that C libraries are really just temporary build
# by-products, at least from the point of view of building Python
# extensions -- but I want to keep my options open.
self.set_undefined_options(
'build',
('build_temp', 'build_clib'),
('build_temp', 'build_temp'),
('compiler', 'compiler'),
('debug', 'debug'),
('force', 'force'),
)
self.libraries = self.distribution.libraries
if self.libraries:
self.check_library_list(self.libraries)
if self.include_dirs is None:
self.include_dirs = self.distribution.include_dirs or []
if isinstance(self.include_dirs, str):
self.include_dirs = self.include_dirs.split(os.pathsep)
# XXX same as for build_ext -- what about 'self.define' and
# 'self.undef' ?
def run(self):
if not self.libraries:
return
# Yech -- this is cut 'n pasted from build_ext.py!
from distutils.ccompiler import new_compiler
self.compiler = new_compiler(
compiler=self.compiler, dry_run=self.dry_run, force=self.force
)
customize_compiler(self.compiler)
if self.include_dirs is not None:
self.compiler.set_include_dirs(self.include_dirs)
if self.define is not None:
# 'define' option is a list of (name,value) tuples
for (name, value) in self.define:
self.compiler.define_macro(name, value)
if self.undef is not None:
for macro in self.undef:
self.compiler.undefine_macro(macro)
self.build_libraries(self.libraries)
def check_library_list(self, libraries):
"""Ensure that the list of libraries is valid.
`library` is presumably provided as a command option 'libraries'.
This method checks that it is a list of 2-tuples, where the tuples
are (library_name, build_info_dict).
Raise DistutilsSetupError if the structure is invalid anywhere;
just returns otherwise.
"""
if not isinstance(libraries, list):
raise DistutilsSetupError("'libraries' option must be a list of tuples")
for lib in libraries:
if not isinstance(lib, tuple) and len(lib) != 2:
raise DistutilsSetupError("each element of 'libraries' must a 2-tuple")
name, build_info = lib
if not isinstance(name, str):
raise DistutilsSetupError(
"first element of each tuple in 'libraries' "
"must be a string (the library name)"
)
if '/' in name or (os.sep != '/' and os.sep in name):
raise DistutilsSetupError(
"bad library name '%s': "
"may not contain directory separators" % lib[0]
)
if not isinstance(build_info, dict):
raise DistutilsSetupError(
"second element of each tuple in 'libraries' "
"must be a dictionary (build info)"
)
def get_library_names(self):
# Assume the library list is valid -- 'check_library_list()' is
# called from 'finalize_options()', so it should be!
if not self.libraries:
return None
lib_names = []
for (lib_name, build_info) in self.libraries:
lib_names.append(lib_name)
return lib_names
def get_source_files(self):
self.check_library_list(self.libraries)
filenames = []
for (lib_name, build_info) in self.libraries:
sources = build_info.get('sources')
if sources is None or not isinstance(sources, (list, tuple)):
raise DistutilsSetupError(
"in 'libraries' option (library '%s'), "
"'sources' must be present and must be "
"a list of source filenames" % lib_name
)
filenames.extend(sources)
return filenames
def build_libraries(self, libraries):
for (lib_name, build_info) in libraries:
sources = build_info.get('sources')
if sources is None or not isinstance(sources, (list, tuple)):
raise DistutilsSetupError(
"in 'libraries' option (library '%s'), "
"'sources' must be present and must be "
"a list of source filenames" % lib_name
)
sources = list(sources)
log.info("building '%s' library", lib_name)
# First, compile the source code to object files in the library
# directory. (This should probably change to putting object
# files in a temporary build directory.)
macros = build_info.get('macros')
include_dirs = build_info.get('include_dirs')
objects = self.compiler.compile(
sources,
output_dir=self.build_temp,
macros=macros,
include_dirs=include_dirs,
debug=self.debug,
)
# Now "link" the object files together into a static library.
# (On Unix at least, this isn't really linking -- it just
# builds an archive. Whatever.)
self.compiler.create_static_lib(
objects, lib_name, output_dir=self.build_clib, debug=self.debug
)
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/build_clib.py
|
Python
|
mit
| 7,728 |
"""distutils.command.build_ext
Implements the Distutils 'build_ext' command, for building extension
modules (currently limited to C extensions, should accommodate C++
extensions ASAP)."""
import contextlib
import os
import re
import sys
from distutils.core import Command
from distutils.errors import (
DistutilsOptionError,
DistutilsSetupError,
CCompilerError,
DistutilsError,
CompileError,
DistutilsPlatformError,
)
from distutils.sysconfig import customize_compiler, get_python_version
from distutils.sysconfig import get_config_h_filename
from distutils.dep_util import newer_group
from distutils.extension import Extension
from distutils.util import get_platform
from distutils import log
from . import py37compat
from site import USER_BASE
# An extension name is just a dot-separated list of Python NAMEs (ie.
# the same as a fully-qualified module name).
extension_name_re = re.compile(r'^[a-zA-Z_][a-zA-Z_0-9]*(\.[a-zA-Z_][a-zA-Z_0-9]*)*$')
def show_compilers():
from distutils.ccompiler import show_compilers
show_compilers()
class build_ext(Command):
description = "build C/C++ extensions (compile/link to build directory)"
# XXX thoughts on how to deal with complex command-line options like
# these, i.e. how to make it so fancy_getopt can suck them off the
# command line and make it look like setup.py defined the appropriate
# lists of tuples of what-have-you.
# - each command needs a callback to process its command-line options
# - Command.__init__() needs access to its share of the whole
# command line (must ultimately come from
# Distribution.parse_command_line())
# - it then calls the current command class' option-parsing
# callback to deal with weird options like -D, which have to
# parse the option text and churn out some custom data
# structure
# - that data structure (in this case, a list of 2-tuples)
# will then be present in the command object by the time
# we get to finalize_options() (i.e. the constructor
# takes care of both command-line and client options
# in between initialize_options() and finalize_options())
sep_by = " (separated by '%s')" % os.pathsep
user_options = [
('build-lib=', 'b', "directory for compiled extension modules"),
('build-temp=', 't', "directory for temporary files (build by-products)"),
(
'plat-name=',
'p',
"platform name to cross-compile for, if supported "
"(default: %s)" % get_platform(),
),
(
'inplace',
'i',
"ignore build-lib and put compiled extensions into the source "
+ "directory alongside your pure Python modules",
),
(
'include-dirs=',
'I',
"list of directories to search for header files" + sep_by,
),
('define=', 'D', "C preprocessor macros to define"),
('undef=', 'U', "C preprocessor macros to undefine"),
('libraries=', 'l', "external C libraries to link with"),
(
'library-dirs=',
'L',
"directories to search for external C libraries" + sep_by,
),
('rpath=', 'R', "directories to search for shared C libraries at runtime"),
('link-objects=', 'O', "extra explicit link objects to include in the link"),
('debug', 'g', "compile/link with debugging information"),
('force', 'f', "forcibly build everything (ignore file timestamps)"),
('compiler=', 'c', "specify the compiler type"),
('parallel=', 'j', "number of parallel build jobs"),
('swig-cpp', None, "make SWIG create C++ files (default is C)"),
('swig-opts=', None, "list of SWIG command line options"),
('swig=', None, "path to the SWIG executable"),
('user', None, "add user include, library and rpath"),
]
boolean_options = ['inplace', 'debug', 'force', 'swig-cpp', 'user']
help_options = [
('help-compiler', None, "list available compilers", show_compilers),
]
def initialize_options(self):
self.extensions = None
self.build_lib = None
self.plat_name = None
self.build_temp = None
self.inplace = 0
self.package = None
self.include_dirs = None
self.define = None
self.undef = None
self.libraries = None
self.library_dirs = None
self.rpath = None
self.link_objects = None
self.debug = None
self.force = None
self.compiler = None
self.swig = None
self.swig_cpp = None
self.swig_opts = None
self.user = None
self.parallel = None
def finalize_options(self): # noqa: C901
from distutils import sysconfig
self.set_undefined_options(
'build',
('build_lib', 'build_lib'),
('build_temp', 'build_temp'),
('compiler', 'compiler'),
('debug', 'debug'),
('force', 'force'),
('parallel', 'parallel'),
('plat_name', 'plat_name'),
)
if self.package is None:
self.package = self.distribution.ext_package
self.extensions = self.distribution.ext_modules
# Make sure Python's include directories (for Python.h, pyconfig.h,
# etc.) are in the include search path.
py_include = sysconfig.get_python_inc()
plat_py_include = sysconfig.get_python_inc(plat_specific=1)
if self.include_dirs is None:
self.include_dirs = self.distribution.include_dirs or []
if isinstance(self.include_dirs, str):
self.include_dirs = self.include_dirs.split(os.pathsep)
# If in a virtualenv, add its include directory
# Issue 16116
if sys.exec_prefix != sys.base_exec_prefix:
self.include_dirs.append(os.path.join(sys.exec_prefix, 'include'))
# Put the Python "system" include dir at the end, so that
# any local include dirs take precedence.
self.include_dirs.extend(py_include.split(os.path.pathsep))
if plat_py_include != py_include:
self.include_dirs.extend(plat_py_include.split(os.path.pathsep))
self.ensure_string_list('libraries')
self.ensure_string_list('link_objects')
# Life is easier if we're not forever checking for None, so
# simplify these options to empty lists if unset
if self.libraries is None:
self.libraries = []
if self.library_dirs is None:
self.library_dirs = []
elif isinstance(self.library_dirs, str):
self.library_dirs = self.library_dirs.split(os.pathsep)
if self.rpath is None:
self.rpath = []
elif isinstance(self.rpath, str):
self.rpath = self.rpath.split(os.pathsep)
# for extensions under windows use different directories
# for Release and Debug builds.
# also Python's library directory must be appended to library_dirs
if os.name == 'nt':
# the 'libs' directory is for binary installs - we assume that
# must be the *native* platform. But we don't really support
# cross-compiling via a binary install anyway, so we let it go.
self.library_dirs.append(os.path.join(sys.exec_prefix, 'libs'))
if sys.base_exec_prefix != sys.prefix: # Issue 16116
self.library_dirs.append(os.path.join(sys.base_exec_prefix, 'libs'))
if self.debug:
self.build_temp = os.path.join(self.build_temp, "Debug")
else:
self.build_temp = os.path.join(self.build_temp, "Release")
# Append the source distribution include and library directories,
# this allows distutils on windows to work in the source tree
self.include_dirs.append(os.path.dirname(get_config_h_filename()))
self.library_dirs.append(sys.base_exec_prefix)
# Use the .lib files for the correct architecture
if self.plat_name == 'win32':
suffix = 'win32'
else:
# win-amd64
suffix = self.plat_name[4:]
new_lib = os.path.join(sys.exec_prefix, 'PCbuild')
if suffix:
new_lib = os.path.join(new_lib, suffix)
self.library_dirs.append(new_lib)
# For extensions under Cygwin, Python's library directory must be
# appended to library_dirs
if sys.platform[:6] == 'cygwin':
if not sysconfig.python_build:
# building third party extensions
self.library_dirs.append(
os.path.join(
sys.prefix, "lib", "python" + get_python_version(), "config"
)
)
else:
# building python standard extensions
self.library_dirs.append('.')
# For building extensions with a shared Python library,
# Python's library directory must be appended to library_dirs
# See Issues: #1600860, #4366
if sysconfig.get_config_var('Py_ENABLE_SHARED'):
if not sysconfig.python_build:
# building third party extensions
self.library_dirs.append(sysconfig.get_config_var('LIBDIR'))
else:
# building python standard extensions
self.library_dirs.append('.')
# The argument parsing will result in self.define being a string, but
# it has to be a list of 2-tuples. All the preprocessor symbols
# specified by the 'define' option will be set to '1'. Multiple
# symbols can be separated with commas.
if self.define:
defines = self.define.split(',')
self.define = [(symbol, '1') for symbol in defines]
# The option for macros to undefine is also a string from the
# option parsing, but has to be a list. Multiple symbols can also
# be separated with commas here.
if self.undef:
self.undef = self.undef.split(',')
if self.swig_opts is None:
self.swig_opts = []
else:
self.swig_opts = self.swig_opts.split(' ')
# Finally add the user include and library directories if requested
if self.user:
user_include = os.path.join(USER_BASE, "include")
user_lib = os.path.join(USER_BASE, "lib")
if os.path.isdir(user_include):
self.include_dirs.append(user_include)
if os.path.isdir(user_lib):
self.library_dirs.append(user_lib)
self.rpath.append(user_lib)
if isinstance(self.parallel, str):
try:
self.parallel = int(self.parallel)
except ValueError:
raise DistutilsOptionError("parallel should be an integer")
def run(self): # noqa: C901
from distutils.ccompiler import new_compiler
# 'self.extensions', as supplied by setup.py, is a list of
# Extension instances. See the documentation for Extension (in
# distutils.extension) for details.
#
# For backwards compatibility with Distutils 0.8.2 and earlier, we
# also allow the 'extensions' list to be a list of tuples:
# (ext_name, build_info)
# where build_info is a dictionary containing everything that
# Extension instances do except the name, with a few things being
# differently named. We convert these 2-tuples to Extension
# instances as needed.
if not self.extensions:
return
# If we were asked to build any C/C++ libraries, make sure that the
# directory where we put them is in the library search path for
# linking extensions.
if self.distribution.has_c_libraries():
build_clib = self.get_finalized_command('build_clib')
self.libraries.extend(build_clib.get_library_names() or [])
self.library_dirs.append(build_clib.build_clib)
# Setup the CCompiler object that we'll use to do all the
# compiling and linking
self.compiler = new_compiler(
compiler=self.compiler,
verbose=self.verbose,
dry_run=self.dry_run,
force=self.force,
)
customize_compiler(self.compiler)
# If we are cross-compiling, init the compiler now (if we are not
# cross-compiling, init would not hurt, but people may rely on
# late initialization of compiler even if they shouldn't...)
if os.name == 'nt' and self.plat_name != get_platform():
self.compiler.initialize(self.plat_name)
# And make sure that any compile/link-related options (which might
# come from the command-line or from the setup script) are set in
# that CCompiler object -- that way, they automatically apply to
# all compiling and linking done here.
if self.include_dirs is not None:
self.compiler.set_include_dirs(self.include_dirs)
if self.define is not None:
# 'define' option is a list of (name,value) tuples
for (name, value) in self.define:
self.compiler.define_macro(name, value)
if self.undef is not None:
for macro in self.undef:
self.compiler.undefine_macro(macro)
if self.libraries is not None:
self.compiler.set_libraries(self.libraries)
if self.library_dirs is not None:
self.compiler.set_library_dirs(self.library_dirs)
if self.rpath is not None:
self.compiler.set_runtime_library_dirs(self.rpath)
if self.link_objects is not None:
self.compiler.set_link_objects(self.link_objects)
# Now actually compile and link everything.
self.build_extensions()
def check_extensions_list(self, extensions): # noqa: C901
"""Ensure that the list of extensions (presumably provided as a
command option 'extensions') is valid, i.e. it is a list of
Extension objects. We also support the old-style list of 2-tuples,
where the tuples are (ext_name, build_info), which are converted to
Extension instances here.
Raise DistutilsSetupError if the structure is invalid anywhere;
just returns otherwise.
"""
if not isinstance(extensions, list):
raise DistutilsSetupError(
"'ext_modules' option must be a list of Extension instances"
)
for i, ext in enumerate(extensions):
if isinstance(ext, Extension):
continue # OK! (assume type-checking done
# by Extension constructor)
if not isinstance(ext, tuple) or len(ext) != 2:
raise DistutilsSetupError(
"each element of 'ext_modules' option must be an "
"Extension instance or 2-tuple"
)
ext_name, build_info = ext
log.warn(
"old-style (ext_name, build_info) tuple found in "
"ext_modules for extension '%s' "
"-- please convert to Extension instance",
ext_name,
)
if not (isinstance(ext_name, str) and extension_name_re.match(ext_name)):
raise DistutilsSetupError(
"first element of each tuple in 'ext_modules' "
"must be the extension name (a string)"
)
if not isinstance(build_info, dict):
raise DistutilsSetupError(
"second element of each tuple in 'ext_modules' "
"must be a dictionary (build info)"
)
# OK, the (ext_name, build_info) dict is type-safe: convert it
# to an Extension instance.
ext = Extension(ext_name, build_info['sources'])
# Easy stuff: one-to-one mapping from dict elements to
# instance attributes.
for key in (
'include_dirs',
'library_dirs',
'libraries',
'extra_objects',
'extra_compile_args',
'extra_link_args',
):
val = build_info.get(key)
if val is not None:
setattr(ext, key, val)
# Medium-easy stuff: same syntax/semantics, different names.
ext.runtime_library_dirs = build_info.get('rpath')
if 'def_file' in build_info:
log.warn("'def_file' element of build info dict " "no longer supported")
# Non-trivial stuff: 'macros' split into 'define_macros'
# and 'undef_macros'.
macros = build_info.get('macros')
if macros:
ext.define_macros = []
ext.undef_macros = []
for macro in macros:
if not (isinstance(macro, tuple) and len(macro) in (1, 2)):
raise DistutilsSetupError(
"'macros' element of build info dict "
"must be 1- or 2-tuple"
)
if len(macro) == 1:
ext.undef_macros.append(macro[0])
elif len(macro) == 2:
ext.define_macros.append(macro)
extensions[i] = ext
def get_source_files(self):
self.check_extensions_list(self.extensions)
filenames = []
# Wouldn't it be neat if we knew the names of header files too...
for ext in self.extensions:
filenames.extend(ext.sources)
return filenames
def get_outputs(self):
# Sanity check the 'extensions' list -- can't assume this is being
# done in the same run as a 'build_extensions()' call (in fact, we
# can probably assume that it *isn't*!).
self.check_extensions_list(self.extensions)
# And build the list of output (built) filenames. Note that this
# ignores the 'inplace' flag, and assumes everything goes in the
# "build" tree.
outputs = []
for ext in self.extensions:
outputs.append(self.get_ext_fullpath(ext.name))
return outputs
def build_extensions(self):
# First, sanity-check the 'extensions' list
self.check_extensions_list(self.extensions)
if self.parallel:
self._build_extensions_parallel()
else:
self._build_extensions_serial()
def _build_extensions_parallel(self):
workers = self.parallel
if self.parallel is True:
workers = os.cpu_count() # may return None
try:
from concurrent.futures import ThreadPoolExecutor
except ImportError:
workers = None
if workers is None:
self._build_extensions_serial()
return
with ThreadPoolExecutor(max_workers=workers) as executor:
futures = [
executor.submit(self.build_extension, ext) for ext in self.extensions
]
for ext, fut in zip(self.extensions, futures):
with self._filter_build_errors(ext):
fut.result()
def _build_extensions_serial(self):
for ext in self.extensions:
with self._filter_build_errors(ext):
self.build_extension(ext)
@contextlib.contextmanager
def _filter_build_errors(self, ext):
try:
yield
except (CCompilerError, DistutilsError, CompileError) as e:
if not ext.optional:
raise
self.warn('building extension "{}" failed: {}'.format(ext.name, e))
def build_extension(self, ext):
sources = ext.sources
if sources is None or not isinstance(sources, (list, tuple)):
raise DistutilsSetupError(
"in 'ext_modules' option (extension '%s'), "
"'sources' must be present and must be "
"a list of source filenames" % ext.name
)
# sort to make the resulting .so file build reproducible
sources = sorted(sources)
ext_path = self.get_ext_fullpath(ext.name)
depends = sources + ext.depends
if not (self.force or newer_group(depends, ext_path, 'newer')):
log.debug("skipping '%s' extension (up-to-date)", ext.name)
return
else:
log.info("building '%s' extension", ext.name)
# First, scan the sources for SWIG definition files (.i), run
# SWIG on 'em to create .c files, and modify the sources list
# accordingly.
sources = self.swig_sources(sources, ext)
# Next, compile the source code to object files.
# XXX not honouring 'define_macros' or 'undef_macros' -- the
# CCompiler API needs to change to accommodate this, and I
# want to do one thing at a time!
# Two possible sources for extra compiler arguments:
# - 'extra_compile_args' in Extension object
# - CFLAGS environment variable (not particularly
# elegant, but people seem to expect it and I
# guess it's useful)
# The environment variable should take precedence, and
# any sensible compiler will give precedence to later
# command line args. Hence we combine them in order:
extra_args = ext.extra_compile_args or []
macros = ext.define_macros[:]
for undef in ext.undef_macros:
macros.append((undef,))
objects = self.compiler.compile(
sources,
output_dir=self.build_temp,
macros=macros,
include_dirs=ext.include_dirs,
debug=self.debug,
extra_postargs=extra_args,
depends=ext.depends,
)
# XXX outdated variable, kept here in case third-part code
# needs it.
self._built_objects = objects[:]
# Now link the object files together into a "shared object" --
# of course, first we have to figure out all the other things
# that go into the mix.
if ext.extra_objects:
objects.extend(ext.extra_objects)
extra_args = ext.extra_link_args or []
# Detect target language, if not provided
language = ext.language or self.compiler.detect_language(sources)
self.compiler.link_shared_object(
objects,
ext_path,
libraries=self.get_libraries(ext),
library_dirs=ext.library_dirs,
runtime_library_dirs=ext.runtime_library_dirs,
extra_postargs=extra_args,
export_symbols=self.get_export_symbols(ext),
debug=self.debug,
build_temp=self.build_temp,
target_lang=language,
)
def swig_sources(self, sources, extension):
"""Walk the list of source files in 'sources', looking for SWIG
interface (.i) files. Run SWIG on all that are found, and
return a modified 'sources' list with SWIG source files replaced
by the generated C (or C++) files.
"""
new_sources = []
swig_sources = []
swig_targets = {}
# XXX this drops generated C/C++ files into the source tree, which
# is fine for developers who want to distribute the generated
# source -- but there should be an option to put SWIG output in
# the temp dir.
if self.swig_cpp:
log.warn("--swig-cpp is deprecated - use --swig-opts=-c++")
if (
self.swig_cpp
or ('-c++' in self.swig_opts)
or ('-c++' in extension.swig_opts)
):
target_ext = '.cpp'
else:
target_ext = '.c'
for source in sources:
(base, ext) = os.path.splitext(source)
if ext == ".i": # SWIG interface file
new_sources.append(base + '_wrap' + target_ext)
swig_sources.append(source)
swig_targets[source] = new_sources[-1]
else:
new_sources.append(source)
if not swig_sources:
return new_sources
swig = self.swig or self.find_swig()
swig_cmd = [swig, "-python"]
swig_cmd.extend(self.swig_opts)
if self.swig_cpp:
swig_cmd.append("-c++")
# Do not override commandline arguments
if not self.swig_opts:
for o in extension.swig_opts:
swig_cmd.append(o)
for source in swig_sources:
target = swig_targets[source]
log.info("swigging %s to %s", source, target)
self.spawn(swig_cmd + ["-o", target, source])
return new_sources
def find_swig(self):
"""Return the name of the SWIG executable. On Unix, this is
just "swig" -- it should be in the PATH. Tries a bit harder on
Windows.
"""
if os.name == "posix":
return "swig"
elif os.name == "nt":
# Look for SWIG in its standard installation directory on
# Windows (or so I presume!). If we find it there, great;
# if not, act like Unix and assume it's in the PATH.
for vers in ("1.3", "1.2", "1.1"):
fn = os.path.join("c:\\swig%s" % vers, "swig.exe")
if os.path.isfile(fn):
return fn
else:
return "swig.exe"
else:
raise DistutilsPlatformError(
"I don't know how to find (much less run) SWIG "
"on platform '%s'" % os.name
)
# -- Name generators -----------------------------------------------
# (extension names, filenames, whatever)
def get_ext_fullpath(self, ext_name):
"""Returns the path of the filename for a given extension.
The file is located in `build_lib` or directly in the package
(inplace option).
"""
fullname = self.get_ext_fullname(ext_name)
modpath = fullname.split('.')
filename = self.get_ext_filename(modpath[-1])
if not self.inplace:
# no further work needed
# returning :
# build_dir/package/path/filename
filename = os.path.join(*modpath[:-1] + [filename])
return os.path.join(self.build_lib, filename)
# the inplace option requires to find the package directory
# using the build_py command for that
package = '.'.join(modpath[0:-1])
build_py = self.get_finalized_command('build_py')
package_dir = os.path.abspath(build_py.get_package_dir(package))
# returning
# package_dir/filename
return os.path.join(package_dir, filename)
def get_ext_fullname(self, ext_name):
"""Returns the fullname of a given extension name.
Adds the `package.` prefix"""
if self.package is None:
return ext_name
else:
return self.package + '.' + ext_name
def get_ext_filename(self, ext_name):
r"""Convert the name of an extension (eg. "foo.bar") into the name
of the file from which it will be loaded (eg. "foo/bar.so", or
"foo\bar.pyd").
"""
from distutils.sysconfig import get_config_var
ext_path = ext_name.split('.')
ext_suffix = get_config_var('EXT_SUFFIX')
return os.path.join(*ext_path) + ext_suffix
def get_export_symbols(self, ext):
"""Return the list of symbols that a shared extension has to
export. This either uses 'ext.export_symbols' or, if it's not
provided, "PyInit_" + module_name. Only relevant on Windows, where
the .pyd file (DLL) must export the module "PyInit_" function.
"""
name = ext.name.split('.')[-1]
try:
# Unicode module name support as defined in PEP-489
# https://www.python.org/dev/peps/pep-0489/#export-hook-name
name.encode('ascii')
except UnicodeEncodeError:
suffix = 'U_' + name.encode('punycode').replace(b'-', b'_').decode('ascii')
else:
suffix = "_" + name
initfunc_name = "PyInit" + suffix
if initfunc_name not in ext.export_symbols:
ext.export_symbols.append(initfunc_name)
return ext.export_symbols
def get_libraries(self, ext): # noqa: C901
"""Return the list of libraries to link against when building a
shared extension. On most platforms, this is just 'ext.libraries';
on Windows, we add the Python library (eg. python20.dll).
"""
# The python library is always needed on Windows. For MSVC, this
# is redundant, since the library is mentioned in a pragma in
# pyconfig.h that MSVC groks. The other Windows compilers all seem
# to need it mentioned explicitly, though, so that's what we do.
# Append '_d' to the python import library on debug builds.
if sys.platform == "win32":
from distutils._msvccompiler import MSVCCompiler
if not isinstance(self.compiler, MSVCCompiler):
template = "python%d%d"
if self.debug:
template = template + '_d'
pythonlib = template % (
sys.hexversion >> 24,
(sys.hexversion >> 16) & 0xFF,
)
# don't extend ext.libraries, it may be shared with other
# extensions, it is a reference to the original list
return ext.libraries + [pythonlib]
else:
# On Android only the main executable and LD_PRELOADs are considered
# to be RTLD_GLOBAL, all the dependencies of the main executable
# remain RTLD_LOCAL and so the shared libraries must be linked with
# libpython when python is built with a shared python library (issue
# bpo-21536).
# On Cygwin (and if required, other POSIX-like platforms based on
# Windows like MinGW) it is simply necessary that all symbols in
# shared libraries are resolved at link time.
from distutils.sysconfig import get_config_var
link_libpython = False
if get_config_var('Py_ENABLE_SHARED'):
# A native build on an Android device or on Cygwin
if hasattr(sys, 'getandroidapilevel'):
link_libpython = True
elif sys.platform == 'cygwin':
link_libpython = True
elif '_PYTHON_HOST_PLATFORM' in os.environ:
# We are cross-compiling for one of the relevant platforms
if get_config_var('ANDROID_API_LEVEL') != 0:
link_libpython = True
elif get_config_var('MACHDEP') == 'cygwin':
link_libpython = True
if link_libpython:
ldversion = get_config_var('LDVERSION')
return ext.libraries + ['python' + ldversion]
return ext.libraries + py37compat.pythonlib()
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/build_ext.py
|
Python
|
mit
| 31,558 |
"""distutils.command.build_py
Implements the Distutils 'build_py' command."""
import os
import importlib.util
import sys
import glob
from distutils.core import Command
from distutils.errors import DistutilsOptionError, DistutilsFileError
from distutils.util import convert_path
from distutils import log
class build_py(Command):
description = "\"build\" pure Python modules (copy to build directory)"
user_options = [
('build-lib=', 'd', "directory to \"build\" (copy) to"),
('compile', 'c', "compile .py to .pyc"),
('no-compile', None, "don't compile .py files [default]"),
(
'optimize=',
'O',
"also compile with optimization: -O1 for \"python -O\", "
"-O2 for \"python -OO\", and -O0 to disable [default: -O0]",
),
('force', 'f', "forcibly build everything (ignore file timestamps)"),
]
boolean_options = ['compile', 'force']
negative_opt = {'no-compile': 'compile'}
def initialize_options(self):
self.build_lib = None
self.py_modules = None
self.package = None
self.package_data = None
self.package_dir = None
self.compile = 0
self.optimize = 0
self.force = None
def finalize_options(self):
self.set_undefined_options(
'build', ('build_lib', 'build_lib'), ('force', 'force')
)
# Get the distribution options that are aliases for build_py
# options -- list of packages and list of modules.
self.packages = self.distribution.packages
self.py_modules = self.distribution.py_modules
self.package_data = self.distribution.package_data
self.package_dir = {}
if self.distribution.package_dir:
for name, path in self.distribution.package_dir.items():
self.package_dir[name] = convert_path(path)
self.data_files = self.get_data_files()
# Ick, copied straight from install_lib.py (fancy_getopt needs a
# type system! Hell, *everything* needs a type system!!!)
if not isinstance(self.optimize, int):
try:
self.optimize = int(self.optimize)
assert 0 <= self.optimize <= 2
except (ValueError, AssertionError):
raise DistutilsOptionError("optimize must be 0, 1, or 2")
def run(self):
# XXX copy_file by default preserves atime and mtime. IMHO this is
# the right thing to do, but perhaps it should be an option -- in
# particular, a site administrator might want installed files to
# reflect the time of installation rather than the last
# modification time before the installed release.
# XXX copy_file by default preserves mode, which appears to be the
# wrong thing to do: if a file is read-only in the working
# directory, we want it to be installed read/write so that the next
# installation of the same module distribution can overwrite it
# without problems. (This might be a Unix-specific issue.) Thus
# we turn off 'preserve_mode' when copying to the build directory,
# since the build directory is supposed to be exactly what the
# installation will look like (ie. we preserve mode when
# installing).
# Two options control which modules will be installed: 'packages'
# and 'py_modules'. The former lets us work with whole packages, not
# specifying individual modules at all; the latter is for
# specifying modules one-at-a-time.
if self.py_modules:
self.build_modules()
if self.packages:
self.build_packages()
self.build_package_data()
self.byte_compile(self.get_outputs(include_bytecode=0))
def get_data_files(self):
"""Generate list of '(package,src_dir,build_dir,filenames)' tuples"""
data = []
if not self.packages:
return data
for package in self.packages:
# Locate package source directory
src_dir = self.get_package_dir(package)
# Compute package build directory
build_dir = os.path.join(*([self.build_lib] + package.split('.')))
# Length of path to strip from found files
plen = 0
if src_dir:
plen = len(src_dir) + 1
# Strip directory from globbed filenames
filenames = [file[plen:] for file in self.find_data_files(package, src_dir)]
data.append((package, src_dir, build_dir, filenames))
return data
def find_data_files(self, package, src_dir):
"""Return filenames for package's data files in 'src_dir'"""
globs = self.package_data.get('', []) + self.package_data.get(package, [])
files = []
for pattern in globs:
# Each pattern has to be converted to a platform-specific path
filelist = glob.glob(
os.path.join(glob.escape(src_dir), convert_path(pattern))
)
# Files that match more than one pattern are only added once
files.extend(
[fn for fn in filelist if fn not in files and os.path.isfile(fn)]
)
return files
def build_package_data(self):
"""Copy data files into build directory"""
for package, src_dir, build_dir, filenames in self.data_files:
for filename in filenames:
target = os.path.join(build_dir, filename)
self.mkpath(os.path.dirname(target))
self.copy_file(
os.path.join(src_dir, filename), target, preserve_mode=False
)
def get_package_dir(self, package):
"""Return the directory, relative to the top of the source
distribution, where package 'package' should be found
(at least according to the 'package_dir' option, if any)."""
path = package.split('.')
if not self.package_dir:
if path:
return os.path.join(*path)
else:
return ''
else:
tail = []
while path:
try:
pdir = self.package_dir['.'.join(path)]
except KeyError:
tail.insert(0, path[-1])
del path[-1]
else:
tail.insert(0, pdir)
return os.path.join(*tail)
else:
# Oops, got all the way through 'path' without finding a
# match in package_dir. If package_dir defines a directory
# for the root (nameless) package, then fallback on it;
# otherwise, we might as well have not consulted
# package_dir at all, as we just use the directory implied
# by 'tail' (which should be the same as the original value
# of 'path' at this point).
pdir = self.package_dir.get('')
if pdir is not None:
tail.insert(0, pdir)
if tail:
return os.path.join(*tail)
else:
return ''
def check_package(self, package, package_dir):
# Empty dir name means current directory, which we can probably
# assume exists. Also, os.path.exists and isdir don't know about
# my "empty string means current dir" convention, so we have to
# circumvent them.
if package_dir != "":
if not os.path.exists(package_dir):
raise DistutilsFileError(
"package directory '%s' does not exist" % package_dir
)
if not os.path.isdir(package_dir):
raise DistutilsFileError(
"supposed package directory '%s' exists, "
"but is not a directory" % package_dir
)
# Directories without __init__.py are namespace packages (PEP 420).
if package:
init_py = os.path.join(package_dir, "__init__.py")
if os.path.isfile(init_py):
return init_py
# Either not in a package at all (__init__.py not expected), or
# __init__.py doesn't exist -- so don't return the filename.
return None
def check_module(self, module, module_file):
if not os.path.isfile(module_file):
log.warn("file %s (for module %s) not found", module_file, module)
return False
else:
return True
def find_package_modules(self, package, package_dir):
self.check_package(package, package_dir)
module_files = glob.glob(os.path.join(glob.escape(package_dir), "*.py"))
modules = []
setup_script = os.path.abspath(self.distribution.script_name)
for f in module_files:
abs_f = os.path.abspath(f)
if abs_f != setup_script:
module = os.path.splitext(os.path.basename(f))[0]
modules.append((package, module, f))
else:
self.debug_print("excluding %s" % setup_script)
return modules
def find_modules(self):
"""Finds individually-specified Python modules, ie. those listed by
module name in 'self.py_modules'. Returns a list of tuples (package,
module_base, filename): 'package' is a tuple of the path through
package-space to the module; 'module_base' is the bare (no
packages, no dots) module name, and 'filename' is the path to the
".py" file (relative to the distribution root) that implements the
module.
"""
# Map package names to tuples of useful info about the package:
# (package_dir, checked)
# package_dir - the directory where we'll find source files for
# this package
# checked - true if we have checked that the package directory
# is valid (exists, contains __init__.py, ... ?)
packages = {}
# List of (package, module, filename) tuples to return
modules = []
# We treat modules-in-packages almost the same as toplevel modules,
# just the "package" for a toplevel is empty (either an empty
# string or empty list, depending on context). Differences:
# - don't check for __init__.py in directory for empty package
for module in self.py_modules:
path = module.split('.')
package = '.'.join(path[0:-1])
module_base = path[-1]
try:
(package_dir, checked) = packages[package]
except KeyError:
package_dir = self.get_package_dir(package)
checked = 0
if not checked:
init_py = self.check_package(package, package_dir)
packages[package] = (package_dir, 1)
if init_py:
modules.append((package, "__init__", init_py))
# XXX perhaps we should also check for just .pyc files
# (so greedy closed-source bastards can distribute Python
# modules too)
module_file = os.path.join(package_dir, module_base + ".py")
if not self.check_module(module, module_file):
continue
modules.append((package, module_base, module_file))
return modules
def find_all_modules(self):
"""Compute the list of all modules that will be built, whether
they are specified one-module-at-a-time ('self.py_modules') or
by whole packages ('self.packages'). Return a list of tuples
(package, module, module_file), just like 'find_modules()' and
'find_package_modules()' do."""
modules = []
if self.py_modules:
modules.extend(self.find_modules())
if self.packages:
for package in self.packages:
package_dir = self.get_package_dir(package)
m = self.find_package_modules(package, package_dir)
modules.extend(m)
return modules
def get_source_files(self):
return [module[-1] for module in self.find_all_modules()]
def get_module_outfile(self, build_dir, package, module):
outfile_path = [build_dir] + list(package) + [module + ".py"]
return os.path.join(*outfile_path)
def get_outputs(self, include_bytecode=1):
modules = self.find_all_modules()
outputs = []
for (package, module, module_file) in modules:
package = package.split('.')
filename = self.get_module_outfile(self.build_lib, package, module)
outputs.append(filename)
if include_bytecode:
if self.compile:
outputs.append(
importlib.util.cache_from_source(filename, optimization='')
)
if self.optimize > 0:
outputs.append(
importlib.util.cache_from_source(
filename, optimization=self.optimize
)
)
outputs += [
os.path.join(build_dir, filename)
for package, src_dir, build_dir, filenames in self.data_files
for filename in filenames
]
return outputs
def build_module(self, module, module_file, package):
if isinstance(package, str):
package = package.split('.')
elif not isinstance(package, (list, tuple)):
raise TypeError(
"'package' must be a string (dot-separated), list, or tuple"
)
# Now put the module source file into the "build" area -- this is
# easy, we just copy it somewhere under self.build_lib (the build
# directory for Python source).
outfile = self.get_module_outfile(self.build_lib, package, module)
dir = os.path.dirname(outfile)
self.mkpath(dir)
return self.copy_file(module_file, outfile, preserve_mode=0)
def build_modules(self):
modules = self.find_modules()
for (package, module, module_file) in modules:
# Now "build" the module -- ie. copy the source file to
# self.build_lib (the build directory for Python source).
# (Actually, it gets copied to the directory for this package
# under self.build_lib.)
self.build_module(module, module_file, package)
def build_packages(self):
for package in self.packages:
# Get list of (package, module, module_file) tuples based on
# scanning the package directory. 'package' is only included
# in the tuple so that 'find_modules()' and
# 'find_package_tuples()' have a consistent interface; it's
# ignored here (apart from a sanity check). Also, 'module' is
# the *unqualified* module name (ie. no dots, no package -- we
# already know its package!), and 'module_file' is the path to
# the .py file, relative to the current directory
# (ie. including 'package_dir').
package_dir = self.get_package_dir(package)
modules = self.find_package_modules(package, package_dir)
# Now loop over the modules we found, "building" each one (just
# copy it to self.build_lib).
for (package_, module, module_file) in modules:
assert package == package_
self.build_module(module, module_file, package)
def byte_compile(self, files):
if sys.dont_write_bytecode:
self.warn('byte-compiling is disabled, skipping.')
return
from distutils.util import byte_compile
prefix = self.build_lib
if prefix[-1] != os.sep:
prefix = prefix + os.sep
# XXX this code is essentially the same as the 'byte_compile()
# method of the "install_lib" command, except for the determination
# of the 'prefix' string. Hmmm.
if self.compile:
byte_compile(
files, optimize=0, force=self.force, prefix=prefix, dry_run=self.dry_run
)
if self.optimize > 0:
byte_compile(
files,
optimize=self.optimize,
force=self.force,
prefix=prefix,
dry_run=self.dry_run,
)
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/build_py.py
|
Python
|
mit
| 16,568 |
"""distutils.command.build_scripts
Implements the Distutils 'build_scripts' command."""
import os
import re
from stat import ST_MODE
from distutils import sysconfig
from distutils.core import Command
from distutils.dep_util import newer
from distutils.util import convert_path
from distutils import log
import tokenize
shebang_pattern = re.compile('^#!.*python[0-9.]*([ \t].*)?$')
"""
Pattern matching a Python interpreter indicated in first line of a script.
"""
# for Setuptools compatibility
first_line_re = shebang_pattern
class build_scripts(Command):
description = "\"build\" scripts (copy and fixup #! line)"
user_options = [
('build-dir=', 'd', "directory to \"build\" (copy) to"),
('force', 'f', "forcibly build everything (ignore file timestamps"),
('executable=', 'e', "specify final destination interpreter path"),
]
boolean_options = ['force']
def initialize_options(self):
self.build_dir = None
self.scripts = None
self.force = None
self.executable = None
def finalize_options(self):
self.set_undefined_options(
'build',
('build_scripts', 'build_dir'),
('force', 'force'),
('executable', 'executable'),
)
self.scripts = self.distribution.scripts
def get_source_files(self):
return self.scripts
def run(self):
if not self.scripts:
return
self.copy_scripts()
def copy_scripts(self):
"""
Copy each script listed in ``self.scripts``.
If a script is marked as a Python script (first line matches
'shebang_pattern', i.e. starts with ``#!`` and contains
"python"), then adjust in the copy the first line to refer to
the current Python interpreter.
"""
self.mkpath(self.build_dir)
outfiles = []
updated_files = []
for script in self.scripts:
self._copy_script(script, outfiles, updated_files)
self._change_modes(outfiles)
return outfiles, updated_files
def _copy_script(self, script, outfiles, updated_files): # noqa: C901
shebang_match = None
script = convert_path(script)
outfile = os.path.join(self.build_dir, os.path.basename(script))
outfiles.append(outfile)
if not self.force and not newer(script, outfile):
log.debug("not copying %s (up-to-date)", script)
return
# Always open the file, but ignore failures in dry-run mode
# in order to attempt to copy directly.
try:
f = tokenize.open(script)
except OSError:
if not self.dry_run:
raise
f = None
else:
first_line = f.readline()
if not first_line:
self.warn("%s is an empty file (skipping)" % script)
return
shebang_match = shebang_pattern.match(first_line)
updated_files.append(outfile)
if shebang_match:
log.info("copying and adjusting %s -> %s", script, self.build_dir)
if not self.dry_run:
if not sysconfig.python_build:
executable = self.executable
else:
executable = os.path.join(
sysconfig.get_config_var("BINDIR"),
"python%s%s"
% (
sysconfig.get_config_var("VERSION"),
sysconfig.get_config_var("EXE"),
),
)
post_interp = shebang_match.group(1) or ''
shebang = "#!" + executable + post_interp + "\n"
self._validate_shebang(shebang, f.encoding)
with open(outfile, "w", encoding=f.encoding) as outf:
outf.write(shebang)
outf.writelines(f.readlines())
if f:
f.close()
else:
if f:
f.close()
self.copy_file(script, outfile)
def _change_modes(self, outfiles):
if os.name != 'posix':
return
for file in outfiles:
self._change_mode(file)
def _change_mode(self, file):
if self.dry_run:
log.info("changing mode of %s", file)
return
oldmode = os.stat(file)[ST_MODE] & 0o7777
newmode = (oldmode | 0o555) & 0o7777
if newmode != oldmode:
log.info("changing mode of %s from %o to %o", file, oldmode, newmode)
os.chmod(file, newmode)
@staticmethod
def _validate_shebang(shebang, encoding):
# Python parser starts to read a script using UTF-8 until
# it gets a #coding:xxx cookie. The shebang has to be the
# first line of a file, the #coding:xxx cookie cannot be
# written before. So the shebang has to be encodable to
# UTF-8.
try:
shebang.encode('utf-8')
except UnicodeEncodeError:
raise ValueError(
"The shebang ({!r}) is not encodable " "to utf-8".format(shebang)
)
# If the script is encoded to a custom encoding (use a
# #coding:xxx cookie), the shebang has to be encodable to
# the script encoding too.
try:
shebang.encode(encoding)
except UnicodeEncodeError:
raise ValueError(
"The shebang ({!r}) is not encodable "
"to the script encoding ({})".format(shebang, encoding)
)
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/build_scripts.py
|
Python
|
mit
| 5,624 |
"""distutils.command.check
Implements the Distutils 'check' command.
"""
import contextlib
from distutils.core import Command
from distutils.errors import DistutilsSetupError
with contextlib.suppress(ImportError):
import docutils.utils
import docutils.parsers.rst
import docutils.frontend
import docutils.nodes
class SilentReporter(docutils.utils.Reporter):
def __init__(
self,
source,
report_level,
halt_level,
stream=None,
debug=0,
encoding='ascii',
error_handler='replace',
):
self.messages = []
super().__init__(
source, report_level, halt_level, stream, debug, encoding, error_handler
)
def system_message(self, level, message, *children, **kwargs):
self.messages.append((level, message, children, kwargs))
return docutils.nodes.system_message(
message, level=level, type=self.levels[level], *children, **kwargs
)
class check(Command):
"""This command checks the meta-data of the package."""
description = "perform some checks on the package"
user_options = [
('metadata', 'm', 'Verify meta-data'),
(
'restructuredtext',
'r',
(
'Checks if long string meta-data syntax '
'are reStructuredText-compliant'
),
),
('strict', 's', 'Will exit with an error if a check fails'),
]
boolean_options = ['metadata', 'restructuredtext', 'strict']
def initialize_options(self):
"""Sets default values for options."""
self.restructuredtext = 0
self.metadata = 1
self.strict = 0
self._warnings = 0
def finalize_options(self):
pass
def warn(self, msg):
"""Counts the number of warnings that occurs."""
self._warnings += 1
return Command.warn(self, msg)
def run(self):
"""Runs the command."""
# perform the various tests
if self.metadata:
self.check_metadata()
if self.restructuredtext:
if 'docutils' in globals():
try:
self.check_restructuredtext()
except TypeError as exc:
raise DistutilsSetupError(str(exc))
elif self.strict:
raise DistutilsSetupError('The docutils package is needed.')
# let's raise an error in strict mode, if we have at least
# one warning
if self.strict and self._warnings > 0:
raise DistutilsSetupError('Please correct your package.')
def check_metadata(self):
"""Ensures that all required elements of meta-data are supplied.
Required fields:
name, version
Warns if any are missing.
"""
metadata = self.distribution.metadata
missing = []
for attr in 'name', 'version':
if not getattr(metadata, attr, None):
missing.append(attr)
if missing:
self.warn("missing required meta-data: %s" % ', '.join(missing))
def check_restructuredtext(self):
"""Checks if the long string fields are reST-compliant."""
data = self.distribution.get_long_description()
for warning in self._check_rst_data(data):
line = warning[-1].get('line')
if line is None:
warning = warning[1]
else:
warning = '{} (line {})'.format(warning[1], line)
self.warn(warning)
def _check_rst_data(self, data):
"""Returns warnings when the provided data doesn't compile."""
# the include and csv_table directives need this to be a path
source_path = self.distribution.script_name or 'setup.py'
parser = docutils.parsers.rst.Parser()
settings = docutils.frontend.OptionParser(
components=(docutils.parsers.rst.Parser,)
).get_default_values()
settings.tab_width = 4
settings.pep_references = None
settings.rfc_references = None
reporter = SilentReporter(
source_path,
settings.report_level,
settings.halt_level,
stream=settings.warning_stream,
debug=settings.debug,
encoding=settings.error_encoding,
error_handler=settings.error_encoding_error_handler,
)
document = docutils.nodes.document(settings, reporter, source=source_path)
document.note_source(source_path, -1)
try:
parser.parse(data, document)
except AttributeError as e:
reporter.messages.append(
(-1, 'Could not finish the parsing: %s.' % e, '', {})
)
return reporter.messages
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/check.py
|
Python
|
mit
| 4,888 |
"""distutils.command.clean
Implements the Distutils 'clean' command."""
# contributed by Bastian Kleineidam <calvin@cs.uni-sb.de>, added 2000-03-18
import os
from distutils.core import Command
from distutils.dir_util import remove_tree
from distutils import log
class clean(Command):
description = "clean up temporary files from 'build' command"
user_options = [
('build-base=', 'b', "base build directory (default: 'build.build-base')"),
(
'build-lib=',
None,
"build directory for all modules (default: 'build.build-lib')",
),
('build-temp=', 't', "temporary build directory (default: 'build.build-temp')"),
(
'build-scripts=',
None,
"build directory for scripts (default: 'build.build-scripts')",
),
('bdist-base=', None, "temporary directory for built distributions"),
('all', 'a', "remove all build output, not just temporary by-products"),
]
boolean_options = ['all']
def initialize_options(self):
self.build_base = None
self.build_lib = None
self.build_temp = None
self.build_scripts = None
self.bdist_base = None
self.all = None
def finalize_options(self):
self.set_undefined_options(
'build',
('build_base', 'build_base'),
('build_lib', 'build_lib'),
('build_scripts', 'build_scripts'),
('build_temp', 'build_temp'),
)
self.set_undefined_options('bdist', ('bdist_base', 'bdist_base'))
def run(self):
# remove the build/temp.<plat> directory (unless it's already
# gone)
if os.path.exists(self.build_temp):
remove_tree(self.build_temp, dry_run=self.dry_run)
else:
log.debug("'%s' does not exist -- can't clean it", self.build_temp)
if self.all:
# remove build directories
for directory in (self.build_lib, self.bdist_base, self.build_scripts):
if os.path.exists(directory):
remove_tree(directory, dry_run=self.dry_run)
else:
log.warn("'%s' does not exist -- can't clean it", directory)
# just for the heck of it, try to remove the base build directory:
# we might have emptied it right now, but if not we don't care
if not self.dry_run:
try:
os.rmdir(self.build_base)
log.info("removing '%s'", self.build_base)
except OSError:
pass
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/clean.py
|
Python
|
mit
| 2,603 |
"""distutils.command.config
Implements the Distutils 'config' command, a (mostly) empty command class
that exists mainly to be sub-classed by specific module distributions and
applications. The idea is that while every "config" command is different,
at least they're all named the same, and users always see "config" in the
list of standard commands. Also, this is a good place to put common
configure-like tasks: "try to compile this C code", or "figure out where
this header file lives".
"""
import os
import re
from distutils.core import Command
from distutils.errors import DistutilsExecError
from distutils.sysconfig import customize_compiler
from distutils import log
LANG_EXT = {"c": ".c", "c++": ".cxx"}
class config(Command):
description = "prepare to build"
user_options = [
('compiler=', None, "specify the compiler type"),
('cc=', None, "specify the compiler executable"),
('include-dirs=', 'I', "list of directories to search for header files"),
('define=', 'D', "C preprocessor macros to define"),
('undef=', 'U', "C preprocessor macros to undefine"),
('libraries=', 'l', "external C libraries to link with"),
('library-dirs=', 'L', "directories to search for external C libraries"),
('noisy', None, "show every action (compile, link, run, ...) taken"),
(
'dump-source',
None,
"dump generated source files before attempting to compile them",
),
]
# The three standard command methods: since the "config" command
# does nothing by default, these are empty.
def initialize_options(self):
self.compiler = None
self.cc = None
self.include_dirs = None
self.libraries = None
self.library_dirs = None
# maximal output for now
self.noisy = 1
self.dump_source = 1
# list of temporary files generated along-the-way that we have
# to clean at some point
self.temp_files = []
def finalize_options(self):
if self.include_dirs is None:
self.include_dirs = self.distribution.include_dirs or []
elif isinstance(self.include_dirs, str):
self.include_dirs = self.include_dirs.split(os.pathsep)
if self.libraries is None:
self.libraries = []
elif isinstance(self.libraries, str):
self.libraries = [self.libraries]
if self.library_dirs is None:
self.library_dirs = []
elif isinstance(self.library_dirs, str):
self.library_dirs = self.library_dirs.split(os.pathsep)
def run(self):
pass
# Utility methods for actual "config" commands. The interfaces are
# loosely based on Autoconf macros of similar names. Sub-classes
# may use these freely.
def _check_compiler(self):
"""Check that 'self.compiler' really is a CCompiler object;
if not, make it one.
"""
# We do this late, and only on-demand, because this is an expensive
# import.
from distutils.ccompiler import CCompiler, new_compiler
if not isinstance(self.compiler, CCompiler):
self.compiler = new_compiler(
compiler=self.compiler, dry_run=self.dry_run, force=1
)
customize_compiler(self.compiler)
if self.include_dirs:
self.compiler.set_include_dirs(self.include_dirs)
if self.libraries:
self.compiler.set_libraries(self.libraries)
if self.library_dirs:
self.compiler.set_library_dirs(self.library_dirs)
def _gen_temp_sourcefile(self, body, headers, lang):
filename = "_configtest" + LANG_EXT[lang]
with open(filename, "w") as file:
if headers:
for header in headers:
file.write("#include <%s>\n" % header)
file.write("\n")
file.write(body)
if body[-1] != "\n":
file.write("\n")
return filename
def _preprocess(self, body, headers, include_dirs, lang):
src = self._gen_temp_sourcefile(body, headers, lang)
out = "_configtest.i"
self.temp_files.extend([src, out])
self.compiler.preprocess(src, out, include_dirs=include_dirs)
return (src, out)
def _compile(self, body, headers, include_dirs, lang):
src = self._gen_temp_sourcefile(body, headers, lang)
if self.dump_source:
dump_file(src, "compiling '%s':" % src)
(obj,) = self.compiler.object_filenames([src])
self.temp_files.extend([src, obj])
self.compiler.compile([src], include_dirs=include_dirs)
return (src, obj)
def _link(self, body, headers, include_dirs, libraries, library_dirs, lang):
(src, obj) = self._compile(body, headers, include_dirs, lang)
prog = os.path.splitext(os.path.basename(src))[0]
self.compiler.link_executable(
[obj],
prog,
libraries=libraries,
library_dirs=library_dirs,
target_lang=lang,
)
if self.compiler.exe_extension is not None:
prog = prog + self.compiler.exe_extension
self.temp_files.append(prog)
return (src, obj, prog)
def _clean(self, *filenames):
if not filenames:
filenames = self.temp_files
self.temp_files = []
log.info("removing: %s", ' '.join(filenames))
for filename in filenames:
try:
os.remove(filename)
except OSError:
pass
# XXX these ignore the dry-run flag: what to do, what to do? even if
# you want a dry-run build, you still need some sort of configuration
# info. My inclination is to make it up to the real config command to
# consult 'dry_run', and assume a default (minimal) configuration if
# true. The problem with trying to do it here is that you'd have to
# return either true or false from all the 'try' methods, neither of
# which is correct.
# XXX need access to the header search path and maybe default macros.
def try_cpp(self, body=None, headers=None, include_dirs=None, lang="c"):
"""Construct a source file from 'body' (a string containing lines
of C/C++ code) and 'headers' (a list of header files to include)
and run it through the preprocessor. Return true if the
preprocessor succeeded, false if there were any errors.
('body' probably isn't of much use, but what the heck.)
"""
from distutils.ccompiler import CompileError
self._check_compiler()
ok = True
try:
self._preprocess(body, headers, include_dirs, lang)
except CompileError:
ok = False
self._clean()
return ok
def search_cpp(self, pattern, body=None, headers=None, include_dirs=None, lang="c"):
"""Construct a source file (just like 'try_cpp()'), run it through
the preprocessor, and return true if any line of the output matches
'pattern'. 'pattern' should either be a compiled regex object or a
string containing a regex. If both 'body' and 'headers' are None,
preprocesses an empty file -- which can be useful to determine the
symbols the preprocessor and compiler set by default.
"""
self._check_compiler()
src, out = self._preprocess(body, headers, include_dirs, lang)
if isinstance(pattern, str):
pattern = re.compile(pattern)
with open(out) as file:
match = False
while True:
line = file.readline()
if line == '':
break
if pattern.search(line):
match = True
break
self._clean()
return match
def try_compile(self, body, headers=None, include_dirs=None, lang="c"):
"""Try to compile a source file built from 'body' and 'headers'.
Return true on success, false otherwise.
"""
from distutils.ccompiler import CompileError
self._check_compiler()
try:
self._compile(body, headers, include_dirs, lang)
ok = True
except CompileError:
ok = False
log.info(ok and "success!" or "failure.")
self._clean()
return ok
def try_link(
self,
body,
headers=None,
include_dirs=None,
libraries=None,
library_dirs=None,
lang="c",
):
"""Try to compile and link a source file, built from 'body' and
'headers', to executable form. Return true on success, false
otherwise.
"""
from distutils.ccompiler import CompileError, LinkError
self._check_compiler()
try:
self._link(body, headers, include_dirs, libraries, library_dirs, lang)
ok = True
except (CompileError, LinkError):
ok = False
log.info(ok and "success!" or "failure.")
self._clean()
return ok
def try_run(
self,
body,
headers=None,
include_dirs=None,
libraries=None,
library_dirs=None,
lang="c",
):
"""Try to compile, link to an executable, and run a program
built from 'body' and 'headers'. Return true on success, false
otherwise.
"""
from distutils.ccompiler import CompileError, LinkError
self._check_compiler()
try:
src, obj, exe = self._link(
body, headers, include_dirs, libraries, library_dirs, lang
)
self.spawn([exe])
ok = True
except (CompileError, LinkError, DistutilsExecError):
ok = False
log.info(ok and "success!" or "failure.")
self._clean()
return ok
# -- High-level methods --------------------------------------------
# (these are the ones that are actually likely to be useful
# when implementing a real-world config command!)
def check_func(
self,
func,
headers=None,
include_dirs=None,
libraries=None,
library_dirs=None,
decl=0,
call=0,
):
"""Determine if function 'func' is available by constructing a
source file that refers to 'func', and compiles and links it.
If everything succeeds, returns true; otherwise returns false.
The constructed source file starts out by including the header
files listed in 'headers'. If 'decl' is true, it then declares
'func' (as "int func()"); you probably shouldn't supply 'headers'
and set 'decl' true in the same call, or you might get errors about
a conflicting declarations for 'func'. Finally, the constructed
'main()' function either references 'func' or (if 'call' is true)
calls it. 'libraries' and 'library_dirs' are used when
linking.
"""
self._check_compiler()
body = []
if decl:
body.append("int %s ();" % func)
body.append("int main () {")
if call:
body.append(" %s();" % func)
else:
body.append(" %s;" % func)
body.append("}")
body = "\n".join(body) + "\n"
return self.try_link(body, headers, include_dirs, libraries, library_dirs)
def check_lib(
self,
library,
library_dirs=None,
headers=None,
include_dirs=None,
other_libraries=[],
):
"""Determine if 'library' is available to be linked against,
without actually checking that any particular symbols are provided
by it. 'headers' will be used in constructing the source file to
be compiled, but the only effect of this is to check if all the
header files listed are available. Any libraries listed in
'other_libraries' will be included in the link, in case 'library'
has symbols that depend on other libraries.
"""
self._check_compiler()
return self.try_link(
"int main (void) { }",
headers,
include_dirs,
[library] + other_libraries,
library_dirs,
)
def check_header(self, header, include_dirs=None, library_dirs=None, lang="c"):
"""Determine if the system header file named by 'header_file'
exists and can be found by the preprocessor; return true if so,
false otherwise.
"""
return self.try_cpp(
body="/* No body */", headers=[header], include_dirs=include_dirs
)
def dump_file(filename, head=None):
"""Dumps a file content into log.info.
If head is not None, will be dumped before the file content.
"""
if head is None:
log.info('%s', filename)
else:
log.info(head)
file = open(filename)
try:
log.info(file.read())
finally:
file.close()
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/config.py
|
Python
|
mit
| 13,137 |
"""distutils.command.install
Implements the Distutils 'install' command."""
import sys
import os
import contextlib
import sysconfig
import itertools
from distutils import log
from distutils.core import Command
from distutils.debug import DEBUG
from distutils.sysconfig import get_config_vars
from distutils.file_util import write_file
from distutils.util import convert_path, subst_vars, change_root
from distutils.util import get_platform
from distutils.errors import DistutilsOptionError, DistutilsPlatformError
from . import _framework_compat as fw
from .. import _collections
from site import USER_BASE
from site import USER_SITE
HAS_USER_SITE = True
WINDOWS_SCHEME = {
'purelib': '{base}/Lib/site-packages',
'platlib': '{base}/Lib/site-packages',
'headers': '{base}/Include/{dist_name}',
'scripts': '{base}/Scripts',
'data': '{base}',
}
INSTALL_SCHEMES = {
'posix_prefix': {
'purelib': '{base}/lib/{implementation_lower}{py_version_short}/site-packages',
'platlib': '{platbase}/{platlibdir}/{implementation_lower}'
'{py_version_short}/site-packages',
'headers': '{base}/include/{implementation_lower}'
'{py_version_short}{abiflags}/{dist_name}',
'scripts': '{base}/bin',
'data': '{base}',
},
'posix_home': {
'purelib': '{base}/lib/{implementation_lower}',
'platlib': '{base}/{platlibdir}/{implementation_lower}',
'headers': '{base}/include/{implementation_lower}/{dist_name}',
'scripts': '{base}/bin',
'data': '{base}',
},
'nt': WINDOWS_SCHEME,
'pypy': {
'purelib': '{base}/site-packages',
'platlib': '{base}/site-packages',
'headers': '{base}/include/{dist_name}',
'scripts': '{base}/bin',
'data': '{base}',
},
'pypy_nt': {
'purelib': '{base}/site-packages',
'platlib': '{base}/site-packages',
'headers': '{base}/include/{dist_name}',
'scripts': '{base}/Scripts',
'data': '{base}',
},
}
# user site schemes
if HAS_USER_SITE:
INSTALL_SCHEMES['nt_user'] = {
'purelib': '{usersite}',
'platlib': '{usersite}',
'headers': '{userbase}/{implementation}{py_version_nodot_plat}'
'/Include/{dist_name}',
'scripts': '{userbase}/{implementation}{py_version_nodot_plat}/Scripts',
'data': '{userbase}',
}
INSTALL_SCHEMES['posix_user'] = {
'purelib': '{usersite}',
'platlib': '{usersite}',
'headers': '{userbase}/include/{implementation_lower}'
'{py_version_short}{abiflags}/{dist_name}',
'scripts': '{userbase}/bin',
'data': '{userbase}',
}
INSTALL_SCHEMES.update(fw.schemes)
# The keys to an installation scheme; if any new types of files are to be
# installed, be sure to add an entry to every installation scheme above,
# and to SCHEME_KEYS here.
SCHEME_KEYS = ('purelib', 'platlib', 'headers', 'scripts', 'data')
def _load_sysconfig_schemes():
with contextlib.suppress(AttributeError):
return {
scheme: sysconfig.get_paths(scheme, expand=False)
for scheme in sysconfig.get_scheme_names()
}
def _load_schemes():
"""
Extend default schemes with schemes from sysconfig.
"""
sysconfig_schemes = _load_sysconfig_schemes() or {}
return {
scheme: {
**INSTALL_SCHEMES.get(scheme, {}),
**sysconfig_schemes.get(scheme, {}),
}
for scheme in set(itertools.chain(INSTALL_SCHEMES, sysconfig_schemes))
}
def _get_implementation():
if hasattr(sys, 'pypy_version_info'):
return 'PyPy'
else:
return 'Python'
def _select_scheme(ob, name):
scheme = _inject_headers(name, _load_scheme(_resolve_scheme(name)))
vars(ob).update(_remove_set(ob, _scheme_attrs(scheme)))
def _remove_set(ob, attrs):
"""
Include only attrs that are None in ob.
"""
return {key: value for key, value in attrs.items() if getattr(ob, key) is None}
def _resolve_scheme(name):
os_name, sep, key = name.partition('_')
try:
resolved = sysconfig.get_preferred_scheme(key)
except Exception:
resolved = fw.scheme(_pypy_hack(name))
return resolved
def _load_scheme(name):
return _load_schemes()[name]
def _inject_headers(name, scheme):
"""
Given a scheme name and the resolved scheme,
if the scheme does not include headers, resolve
the fallback scheme for the name and use headers
from it. pypa/distutils#88
"""
# Bypass the preferred scheme, which may not
# have defined headers.
fallback = _load_scheme(_pypy_hack(name))
scheme.setdefault('headers', fallback['headers'])
return scheme
def _scheme_attrs(scheme):
"""Resolve install directories by applying the install schemes."""
return {f'install_{key}': scheme[key] for key in SCHEME_KEYS}
def _pypy_hack(name):
PY37 = sys.version_info < (3, 8)
old_pypy = hasattr(sys, 'pypy_version_info') and PY37
prefix = not name.endswith(('_user', '_home'))
pypy_name = 'pypy' + '_nt' * (os.name == 'nt')
return pypy_name if old_pypy and prefix else name
class install(Command):
description = "install everything from build directory"
user_options = [
# Select installation scheme and set base director(y|ies)
('prefix=', None, "installation prefix"),
('exec-prefix=', None, "(Unix only) prefix for platform-specific files"),
('home=', None, "(Unix only) home directory to install under"),
# Or, just set the base director(y|ies)
(
'install-base=',
None,
"base installation directory (instead of --prefix or --home)",
),
(
'install-platbase=',
None,
"base installation directory for platform-specific files "
+ "(instead of --exec-prefix or --home)",
),
('root=', None, "install everything relative to this alternate root directory"),
# Or, explicitly set the installation scheme
(
'install-purelib=',
None,
"installation directory for pure Python module distributions",
),
(
'install-platlib=',
None,
"installation directory for non-pure module distributions",
),
(
'install-lib=',
None,
"installation directory for all module distributions "
+ "(overrides --install-purelib and --install-platlib)",
),
('install-headers=', None, "installation directory for C/C++ headers"),
('install-scripts=', None, "installation directory for Python scripts"),
('install-data=', None, "installation directory for data files"),
# Byte-compilation options -- see install_lib.py for details, as
# these are duplicated from there (but only install_lib does
# anything with them).
('compile', 'c', "compile .py to .pyc [default]"),
('no-compile', None, "don't compile .py files"),
(
'optimize=',
'O',
"also compile with optimization: -O1 for \"python -O\", "
"-O2 for \"python -OO\", and -O0 to disable [default: -O0]",
),
# Miscellaneous control options
('force', 'f', "force installation (overwrite any existing files)"),
('skip-build', None, "skip rebuilding everything (for testing/debugging)"),
# Where to install documentation (eventually!)
# ('doc-format=', None, "format of documentation to generate"),
# ('install-man=', None, "directory for Unix man pages"),
# ('install-html=', None, "directory for HTML documentation"),
# ('install-info=', None, "directory for GNU info files"),
('record=', None, "filename in which to record list of installed files"),
]
boolean_options = ['compile', 'force', 'skip-build']
if HAS_USER_SITE:
user_options.append(
('user', None, "install in user site-package '%s'" % USER_SITE)
)
boolean_options.append('user')
negative_opt = {'no-compile': 'compile'}
def initialize_options(self):
"""Initializes options."""
# High-level options: these select both an installation base
# and scheme.
self.prefix = None
self.exec_prefix = None
self.home = None
self.user = 0
# These select only the installation base; it's up to the user to
# specify the installation scheme (currently, that means supplying
# the --install-{platlib,purelib,scripts,data} options).
self.install_base = None
self.install_platbase = None
self.root = None
# These options are the actual installation directories; if not
# supplied by the user, they are filled in using the installation
# scheme implied by prefix/exec-prefix/home and the contents of
# that installation scheme.
self.install_purelib = None # for pure module distributions
self.install_platlib = None # non-pure (dists w/ extensions)
self.install_headers = None # for C/C++ headers
self.install_lib = None # set to either purelib or platlib
self.install_scripts = None
self.install_data = None
self.install_userbase = USER_BASE
self.install_usersite = USER_SITE
self.compile = None
self.optimize = None
# Deprecated
# These two are for putting non-packagized distributions into their
# own directory and creating a .pth file if it makes sense.
# 'extra_path' comes from the setup file; 'install_path_file' can
# be turned off if it makes no sense to install a .pth file. (But
# better to install it uselessly than to guess wrong and not
# install it when it's necessary and would be used!) Currently,
# 'install_path_file' is always true unless some outsider meddles
# with it.
self.extra_path = None
self.install_path_file = 1
# 'force' forces installation, even if target files are not
# out-of-date. 'skip_build' skips running the "build" command,
# handy if you know it's not necessary. 'warn_dir' (which is *not*
# a user option, it's just there so the bdist_* commands can turn
# it off) determines whether we warn about installing to a
# directory not in sys.path.
self.force = 0
self.skip_build = 0
self.warn_dir = 1
# These are only here as a conduit from the 'build' command to the
# 'install_*' commands that do the real work. ('build_base' isn't
# actually used anywhere, but it might be useful in future.) They
# are not user options, because if the user told the install
# command where the build directory is, that wouldn't affect the
# build command.
self.build_base = None
self.build_lib = None
# Not defined yet because we don't know anything about
# documentation yet.
# self.install_man = None
# self.install_html = None
# self.install_info = None
self.record = None
# -- Option finalizing methods -------------------------------------
# (This is rather more involved than for most commands,
# because this is where the policy for installing third-
# party Python modules on various platforms given a wide
# array of user input is decided. Yes, it's quite complex!)
def finalize_options(self): # noqa: C901
"""Finalizes options."""
# This method (and its helpers, like 'finalize_unix()',
# 'finalize_other()', and 'select_scheme()') is where the default
# installation directories for modules, extension modules, and
# anything else we care to install from a Python module
# distribution. Thus, this code makes a pretty important policy
# statement about how third-party stuff is added to a Python
# installation! Note that the actual work of installation is done
# by the relatively simple 'install_*' commands; they just take
# their orders from the installation directory options determined
# here.
# Check for errors/inconsistencies in the options; first, stuff
# that's wrong on any platform.
if (self.prefix or self.exec_prefix or self.home) and (
self.install_base or self.install_platbase
):
raise DistutilsOptionError(
"must supply either prefix/exec-prefix/home or "
+ "install-base/install-platbase -- not both"
)
if self.home and (self.prefix or self.exec_prefix):
raise DistutilsOptionError(
"must supply either home or prefix/exec-prefix -- not both"
)
if self.user and (
self.prefix
or self.exec_prefix
or self.home
or self.install_base
or self.install_platbase
):
raise DistutilsOptionError(
"can't combine user with prefix, "
"exec_prefix/home, or install_(plat)base"
)
# Next, stuff that's wrong (or dubious) only on certain platforms.
if os.name != "posix":
if self.exec_prefix:
self.warn("exec-prefix option ignored on this platform")
self.exec_prefix = None
# Now the interesting logic -- so interesting that we farm it out
# to other methods. The goal of these methods is to set the final
# values for the install_{lib,scripts,data,...} options, using as
# input a heady brew of prefix, exec_prefix, home, install_base,
# install_platbase, user-supplied versions of
# install_{purelib,platlib,lib,scripts,data,...}, and the
# install schemes. Phew!
self.dump_dirs("pre-finalize_{unix,other}")
if os.name == 'posix':
self.finalize_unix()
else:
self.finalize_other()
self.dump_dirs("post-finalize_{unix,other}()")
# Expand configuration variables, tilde, etc. in self.install_base
# and self.install_platbase -- that way, we can use $base or
# $platbase in the other installation directories and not worry
# about needing recursive variable expansion (shudder).
py_version = sys.version.split()[0]
(prefix, exec_prefix) = get_config_vars('prefix', 'exec_prefix')
try:
abiflags = sys.abiflags
except AttributeError:
# sys.abiflags may not be defined on all platforms.
abiflags = ''
local_vars = {
'dist_name': self.distribution.get_name(),
'dist_version': self.distribution.get_version(),
'dist_fullname': self.distribution.get_fullname(),
'py_version': py_version,
'py_version_short': '%d.%d' % sys.version_info[:2],
'py_version_nodot': '%d%d' % sys.version_info[:2],
'sys_prefix': prefix,
'prefix': prefix,
'sys_exec_prefix': exec_prefix,
'exec_prefix': exec_prefix,
'abiflags': abiflags,
'platlibdir': getattr(sys, 'platlibdir', 'lib'),
'implementation_lower': _get_implementation().lower(),
'implementation': _get_implementation(),
}
# vars for compatibility on older Pythons
compat_vars = dict(
# Python 3.9 and earlier
py_version_nodot_plat=getattr(sys, 'winver', '').replace('.', ''),
)
if HAS_USER_SITE:
local_vars['userbase'] = self.install_userbase
local_vars['usersite'] = self.install_usersite
self.config_vars = _collections.DictStack(
[fw.vars(), compat_vars, sysconfig.get_config_vars(), local_vars]
)
self.expand_basedirs()
self.dump_dirs("post-expand_basedirs()")
# Now define config vars for the base directories so we can expand
# everything else.
local_vars['base'] = self.install_base
local_vars['platbase'] = self.install_platbase
if DEBUG:
from pprint import pprint
print("config vars:")
pprint(dict(self.config_vars))
# Expand "~" and configuration variables in the installation
# directories.
self.expand_dirs()
self.dump_dirs("post-expand_dirs()")
# Create directories in the home dir:
if self.user:
self.create_home_path()
# Pick the actual directory to install all modules to: either
# install_purelib or install_platlib, depending on whether this
# module distribution is pure or not. Of course, if the user
# already specified install_lib, use their selection.
if self.install_lib is None:
if self.distribution.has_ext_modules(): # has extensions: non-pure
self.install_lib = self.install_platlib
else:
self.install_lib = self.install_purelib
# Convert directories from Unix /-separated syntax to the local
# convention.
self.convert_paths(
'lib',
'purelib',
'platlib',
'scripts',
'data',
'headers',
'userbase',
'usersite',
)
# Deprecated
# Well, we're not actually fully completely finalized yet: we still
# have to deal with 'extra_path', which is the hack for allowing
# non-packagized module distributions (hello, Numerical Python!) to
# get their own directories.
self.handle_extra_path()
self.install_libbase = self.install_lib # needed for .pth file
self.install_lib = os.path.join(self.install_lib, self.extra_dirs)
# If a new root directory was supplied, make all the installation
# dirs relative to it.
if self.root is not None:
self.change_roots(
'libbase', 'lib', 'purelib', 'platlib', 'scripts', 'data', 'headers'
)
self.dump_dirs("after prepending root")
# Find out the build directories, ie. where to install from.
self.set_undefined_options(
'build', ('build_base', 'build_base'), ('build_lib', 'build_lib')
)
# Punt on doc directories for now -- after all, we're punting on
# documentation completely!
def dump_dirs(self, msg):
"""Dumps the list of user options."""
if not DEBUG:
return
from distutils.fancy_getopt import longopt_xlate
log.debug(msg + ":")
for opt in self.user_options:
opt_name = opt[0]
if opt_name[-1] == "=":
opt_name = opt_name[0:-1]
if opt_name in self.negative_opt:
opt_name = self.negative_opt[opt_name]
opt_name = opt_name.translate(longopt_xlate)
val = not getattr(self, opt_name)
else:
opt_name = opt_name.translate(longopt_xlate)
val = getattr(self, opt_name)
log.debug(" %s: %s", opt_name, val)
def finalize_unix(self):
"""Finalizes options for posix platforms."""
if self.install_base is not None or self.install_platbase is not None:
incomplete_scheme = (
(
self.install_lib is None
and self.install_purelib is None
and self.install_platlib is None
)
or self.install_headers is None
or self.install_scripts is None
or self.install_data is None
)
if incomplete_scheme:
raise DistutilsOptionError(
"install-base or install-platbase supplied, but "
"installation scheme is incomplete"
)
return
if self.user:
if self.install_userbase is None:
raise DistutilsPlatformError("User base directory is not specified")
self.install_base = self.install_platbase = self.install_userbase
self.select_scheme("posix_user")
elif self.home is not None:
self.install_base = self.install_platbase = self.home
self.select_scheme("posix_home")
else:
if self.prefix is None:
if self.exec_prefix is not None:
raise DistutilsOptionError(
"must not supply exec-prefix without prefix"
)
# Allow Fedora to add components to the prefix
_prefix_addition = getattr(sysconfig, '_prefix_addition', "")
self.prefix = os.path.normpath(sys.prefix) + _prefix_addition
self.exec_prefix = os.path.normpath(sys.exec_prefix) + _prefix_addition
else:
if self.exec_prefix is None:
self.exec_prefix = self.prefix
self.install_base = self.prefix
self.install_platbase = self.exec_prefix
self.select_scheme("posix_prefix")
def finalize_other(self):
"""Finalizes options for non-posix platforms"""
if self.user:
if self.install_userbase is None:
raise DistutilsPlatformError("User base directory is not specified")
self.install_base = self.install_platbase = self.install_userbase
self.select_scheme(os.name + "_user")
elif self.home is not None:
self.install_base = self.install_platbase = self.home
self.select_scheme("posix_home")
else:
if self.prefix is None:
self.prefix = os.path.normpath(sys.prefix)
self.install_base = self.install_platbase = self.prefix
try:
self.select_scheme(os.name)
except KeyError:
raise DistutilsPlatformError(
"I don't know how to install stuff on '%s'" % os.name
)
def select_scheme(self, name):
_select_scheme(self, name)
def _expand_attrs(self, attrs):
for attr in attrs:
val = getattr(self, attr)
if val is not None:
if os.name == 'posix' or os.name == 'nt':
val = os.path.expanduser(val)
val = subst_vars(val, self.config_vars)
setattr(self, attr, val)
def expand_basedirs(self):
"""Calls `os.path.expanduser` on install_base, install_platbase and
root."""
self._expand_attrs(['install_base', 'install_platbase', 'root'])
def expand_dirs(self):
"""Calls `os.path.expanduser` on install dirs."""
self._expand_attrs(
[
'install_purelib',
'install_platlib',
'install_lib',
'install_headers',
'install_scripts',
'install_data',
]
)
def convert_paths(self, *names):
"""Call `convert_path` over `names`."""
for name in names:
attr = "install_" + name
setattr(self, attr, convert_path(getattr(self, attr)))
def handle_extra_path(self):
"""Set `path_file` and `extra_dirs` using `extra_path`."""
if self.extra_path is None:
self.extra_path = self.distribution.extra_path
if self.extra_path is not None:
log.warn(
"Distribution option extra_path is deprecated. "
"See issue27919 for details."
)
if isinstance(self.extra_path, str):
self.extra_path = self.extra_path.split(',')
if len(self.extra_path) == 1:
path_file = extra_dirs = self.extra_path[0]
elif len(self.extra_path) == 2:
path_file, extra_dirs = self.extra_path
else:
raise DistutilsOptionError(
"'extra_path' option must be a list, tuple, or "
"comma-separated string with 1 or 2 elements"
)
# convert to local form in case Unix notation used (as it
# should be in setup scripts)
extra_dirs = convert_path(extra_dirs)
else:
path_file = None
extra_dirs = ''
# XXX should we warn if path_file and not extra_dirs? (in which
# case the path file would be harmless but pointless)
self.path_file = path_file
self.extra_dirs = extra_dirs
def change_roots(self, *names):
"""Change the install directories pointed by name using root."""
for name in names:
attr = "install_" + name
setattr(self, attr, change_root(self.root, getattr(self, attr)))
def create_home_path(self):
"""Create directories under ~."""
if not self.user:
return
home = convert_path(os.path.expanduser("~"))
for name, path in self.config_vars.items():
if str(path).startswith(home) and not os.path.isdir(path):
self.debug_print("os.makedirs('%s', 0o700)" % path)
os.makedirs(path, 0o700)
# -- Command execution methods -------------------------------------
def run(self):
"""Runs the command."""
# Obviously have to build before we can install
if not self.skip_build:
self.run_command('build')
# If we built for any other platform, we can't install.
build_plat = self.distribution.get_command_obj('build').plat_name
# check warn_dir - it is a clue that the 'install' is happening
# internally, and not to sys.path, so we don't check the platform
# matches what we are running.
if self.warn_dir and build_plat != get_platform():
raise DistutilsPlatformError("Can't install when " "cross-compiling")
# Run all sub-commands (at least those that need to be run)
for cmd_name in self.get_sub_commands():
self.run_command(cmd_name)
if self.path_file:
self.create_path_file()
# write list of installed files, if requested.
if self.record:
outputs = self.get_outputs()
if self.root: # strip any package prefix
root_len = len(self.root)
for counter in range(len(outputs)):
outputs[counter] = outputs[counter][root_len:]
self.execute(
write_file,
(self.record, outputs),
"writing list of installed files to '%s'" % self.record,
)
sys_path = map(os.path.normpath, sys.path)
sys_path = map(os.path.normcase, sys_path)
install_lib = os.path.normcase(os.path.normpath(self.install_lib))
if (
self.warn_dir
and not (self.path_file and self.install_path_file)
and install_lib not in sys_path
):
log.debug(
(
"modules installed to '%s', which is not in "
"Python's module search path (sys.path) -- "
"you'll have to change the search path yourself"
),
self.install_lib,
)
def create_path_file(self):
"""Creates the .pth file"""
filename = os.path.join(self.install_libbase, self.path_file + ".pth")
if self.install_path_file:
self.execute(
write_file, (filename, [self.extra_dirs]), "creating %s" % filename
)
else:
self.warn("path file '%s' not created" % filename)
# -- Reporting methods ---------------------------------------------
def get_outputs(self):
"""Assembles the outputs of all the sub-commands."""
outputs = []
for cmd_name in self.get_sub_commands():
cmd = self.get_finalized_command(cmd_name)
# Add the contents of cmd.get_outputs(), ensuring
# that outputs doesn't contain duplicate entries
for filename in cmd.get_outputs():
if filename not in outputs:
outputs.append(filename)
if self.path_file and self.install_path_file:
outputs.append(os.path.join(self.install_libbase, self.path_file + ".pth"))
return outputs
def get_inputs(self):
"""Returns the inputs of all the sub-commands"""
# XXX gee, this looks familiar ;-(
inputs = []
for cmd_name in self.get_sub_commands():
cmd = self.get_finalized_command(cmd_name)
inputs.extend(cmd.get_inputs())
return inputs
# -- Predicates for sub-command list -------------------------------
def has_lib(self):
"""Returns true if the current distribution has any Python
modules to install."""
return (
self.distribution.has_pure_modules() or self.distribution.has_ext_modules()
)
def has_headers(self):
"""Returns true if the current distribution has any headers to
install."""
return self.distribution.has_headers()
def has_scripts(self):
"""Returns true if the current distribution has any scripts to.
install."""
return self.distribution.has_scripts()
def has_data(self):
"""Returns true if the current distribution has any data to.
install."""
return self.distribution.has_data_files()
# 'sub_commands': a list of commands this command might have to run to
# get its work done. See cmd.py for more info.
sub_commands = [
('install_lib', has_lib),
('install_headers', has_headers),
('install_scripts', has_scripts),
('install_data', has_data),
('install_egg_info', lambda self: True),
]
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/install.py
|
Python
|
mit
| 30,221 |
"""distutils.command.install_data
Implements the Distutils 'install_data' command, for installing
platform-independent data files."""
# contributed by Bastian Kleineidam
import os
from distutils.core import Command
from distutils.util import change_root, convert_path
class install_data(Command):
description = "install data files"
user_options = [
(
'install-dir=',
'd',
"base directory for installing data files "
"(default: installation base dir)",
),
('root=', None, "install everything relative to this alternate root directory"),
('force', 'f', "force installation (overwrite existing files)"),
]
boolean_options = ['force']
def initialize_options(self):
self.install_dir = None
self.outfiles = []
self.root = None
self.force = 0
self.data_files = self.distribution.data_files
self.warn_dir = 1
def finalize_options(self):
self.set_undefined_options(
'install',
('install_data', 'install_dir'),
('root', 'root'),
('force', 'force'),
)
def run(self):
self.mkpath(self.install_dir)
for f in self.data_files:
if isinstance(f, str):
# it's a simple file, so copy it
f = convert_path(f)
if self.warn_dir:
self.warn(
"setup script did not provide a directory for "
"'%s' -- installing right in '%s'" % (f, self.install_dir)
)
(out, _) = self.copy_file(f, self.install_dir)
self.outfiles.append(out)
else:
# it's a tuple with path to install to and a list of files
dir = convert_path(f[0])
if not os.path.isabs(dir):
dir = os.path.join(self.install_dir, dir)
elif self.root:
dir = change_root(self.root, dir)
self.mkpath(dir)
if f[1] == []:
# If there are no files listed, the user must be
# trying to create an empty directory, so add the
# directory to the list of output files.
self.outfiles.append(dir)
else:
# Copy files, adding them to the list of output files.
for data in f[1]:
data = convert_path(data)
(out, _) = self.copy_file(data, dir)
self.outfiles.append(out)
def get_inputs(self):
return self.data_files or []
def get_outputs(self):
return self.outfiles
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/install_data.py
|
Python
|
mit
| 2,779 |
"""
distutils.command.install_egg_info
Implements the Distutils 'install_egg_info' command, for installing
a package's PKG-INFO metadata.
"""
import os
import sys
import re
from distutils.cmd import Command
from distutils import log, dir_util
class install_egg_info(Command):
"""Install an .egg-info file for the package"""
description = "Install package's PKG-INFO metadata as an .egg-info file"
user_options = [
('install-dir=', 'd', "directory to install to"),
]
def initialize_options(self):
self.install_dir = None
@property
def basename(self):
"""
Allow basename to be overridden by child class.
Ref pypa/distutils#2.
"""
return "%s-%s-py%d.%d.egg-info" % (
to_filename(safe_name(self.distribution.get_name())),
to_filename(safe_version(self.distribution.get_version())),
*sys.version_info[:2],
)
def finalize_options(self):
self.set_undefined_options('install_lib', ('install_dir', 'install_dir'))
self.target = os.path.join(self.install_dir, self.basename)
self.outputs = [self.target]
def run(self):
target = self.target
if os.path.isdir(target) and not os.path.islink(target):
dir_util.remove_tree(target, dry_run=self.dry_run)
elif os.path.exists(target):
self.execute(os.unlink, (self.target,), "Removing " + target)
elif not os.path.isdir(self.install_dir):
self.execute(
os.makedirs, (self.install_dir,), "Creating " + self.install_dir
)
log.info("Writing %s", target)
if not self.dry_run:
with open(target, 'w', encoding='UTF-8') as f:
self.distribution.metadata.write_pkg_file(f)
def get_outputs(self):
return self.outputs
# The following routines are taken from setuptools' pkg_resources module and
# can be replaced by importing them from pkg_resources once it is included
# in the stdlib.
def safe_name(name):
"""Convert an arbitrary string to a standard distribution name
Any runs of non-alphanumeric/. characters are replaced with a single '-'.
"""
return re.sub('[^A-Za-z0-9.]+', '-', name)
def safe_version(version):
"""Convert an arbitrary string to a standard version string
Spaces become dots, and all other non-alphanumeric characters become
dashes, with runs of multiple dashes condensed to a single dash.
"""
version = version.replace(' ', '.')
return re.sub('[^A-Za-z0-9.]+', '-', version)
def to_filename(name):
"""Convert a project or version name to its filename-escaped form
Any '-' characters are currently replaced with '_'.
"""
return name.replace('-', '_')
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/install_egg_info.py
|
Python
|
mit
| 2,785 |
"""distutils.command.install_headers
Implements the Distutils 'install_headers' command, to install C/C++ header
files to the Python include directory."""
from distutils.core import Command
# XXX force is never used
class install_headers(Command):
description = "install C/C++ header files"
user_options = [
('install-dir=', 'd', "directory to install header files to"),
('force', 'f', "force installation (overwrite existing files)"),
]
boolean_options = ['force']
def initialize_options(self):
self.install_dir = None
self.force = 0
self.outfiles = []
def finalize_options(self):
self.set_undefined_options(
'install', ('install_headers', 'install_dir'), ('force', 'force')
)
def run(self):
headers = self.distribution.headers
if not headers:
return
self.mkpath(self.install_dir)
for header in headers:
(out, _) = self.copy_file(header, self.install_dir)
self.outfiles.append(out)
def get_inputs(self):
return self.distribution.headers or []
def get_outputs(self):
return self.outfiles
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/install_headers.py
|
Python
|
mit
| 1,189 |
"""distutils.command.install_lib
Implements the Distutils 'install_lib' command
(install all Python modules)."""
import os
import importlib.util
import sys
from distutils.core import Command
from distutils.errors import DistutilsOptionError
# Extension for Python source files.
PYTHON_SOURCE_EXTENSION = ".py"
class install_lib(Command):
description = "install all Python modules (extensions and pure Python)"
# The byte-compilation options are a tad confusing. Here are the
# possible scenarios:
# 1) no compilation at all (--no-compile --no-optimize)
# 2) compile .pyc only (--compile --no-optimize; default)
# 3) compile .pyc and "opt-1" .pyc (--compile --optimize)
# 4) compile "opt-1" .pyc only (--no-compile --optimize)
# 5) compile .pyc and "opt-2" .pyc (--compile --optimize-more)
# 6) compile "opt-2" .pyc only (--no-compile --optimize-more)
#
# The UI for this is two options, 'compile' and 'optimize'.
# 'compile' is strictly boolean, and only decides whether to
# generate .pyc files. 'optimize' is three-way (0, 1, or 2), and
# decides both whether to generate .pyc files and what level of
# optimization to use.
user_options = [
('install-dir=', 'd', "directory to install to"),
('build-dir=', 'b', "build directory (where to install from)"),
('force', 'f', "force installation (overwrite existing files)"),
('compile', 'c', "compile .py to .pyc [default]"),
('no-compile', None, "don't compile .py files"),
(
'optimize=',
'O',
"also compile with optimization: -O1 for \"python -O\", "
"-O2 for \"python -OO\", and -O0 to disable [default: -O0]",
),
('skip-build', None, "skip the build steps"),
]
boolean_options = ['force', 'compile', 'skip-build']
negative_opt = {'no-compile': 'compile'}
def initialize_options(self):
# let the 'install' command dictate our installation directory
self.install_dir = None
self.build_dir = None
self.force = 0
self.compile = None
self.optimize = None
self.skip_build = None
def finalize_options(self):
# Get all the information we need to install pure Python modules
# from the umbrella 'install' command -- build (source) directory,
# install (target) directory, and whether to compile .py files.
self.set_undefined_options(
'install',
('build_lib', 'build_dir'),
('install_lib', 'install_dir'),
('force', 'force'),
('compile', 'compile'),
('optimize', 'optimize'),
('skip_build', 'skip_build'),
)
if self.compile is None:
self.compile = True
if self.optimize is None:
self.optimize = False
if not isinstance(self.optimize, int):
try:
self.optimize = int(self.optimize)
if self.optimize not in (0, 1, 2):
raise AssertionError
except (ValueError, AssertionError):
raise DistutilsOptionError("optimize must be 0, 1, or 2")
def run(self):
# Make sure we have built everything we need first
self.build()
# Install everything: simply dump the entire contents of the build
# directory to the installation directory (that's the beauty of
# having a build directory!)
outfiles = self.install()
# (Optionally) compile .py to .pyc
if outfiles is not None and self.distribution.has_pure_modules():
self.byte_compile(outfiles)
# -- Top-level worker functions ------------------------------------
# (called from 'run()')
def build(self):
if not self.skip_build:
if self.distribution.has_pure_modules():
self.run_command('build_py')
if self.distribution.has_ext_modules():
self.run_command('build_ext')
def install(self):
if os.path.isdir(self.build_dir):
outfiles = self.copy_tree(self.build_dir, self.install_dir)
else:
self.warn(
"'%s' does not exist -- no Python modules to install" % self.build_dir
)
return
return outfiles
def byte_compile(self, files):
if sys.dont_write_bytecode:
self.warn('byte-compiling is disabled, skipping.')
return
from distutils.util import byte_compile
# Get the "--root" directory supplied to the "install" command,
# and use it as a prefix to strip off the purported filename
# encoded in bytecode files. This is far from complete, but it
# should at least generate usable bytecode in RPM distributions.
install_root = self.get_finalized_command('install').root
if self.compile:
byte_compile(
files,
optimize=0,
force=self.force,
prefix=install_root,
dry_run=self.dry_run,
)
if self.optimize > 0:
byte_compile(
files,
optimize=self.optimize,
force=self.force,
prefix=install_root,
verbose=self.verbose,
dry_run=self.dry_run,
)
# -- Utility methods -----------------------------------------------
def _mutate_outputs(self, has_any, build_cmd, cmd_option, output_dir):
if not has_any:
return []
build_cmd = self.get_finalized_command(build_cmd)
build_files = build_cmd.get_outputs()
build_dir = getattr(build_cmd, cmd_option)
prefix_len = len(build_dir) + len(os.sep)
outputs = []
for file in build_files:
outputs.append(os.path.join(output_dir, file[prefix_len:]))
return outputs
def _bytecode_filenames(self, py_filenames):
bytecode_files = []
for py_file in py_filenames:
# Since build_py handles package data installation, the
# list of outputs can contain more than just .py files.
# Make sure we only report bytecode for the .py files.
ext = os.path.splitext(os.path.normcase(py_file))[1]
if ext != PYTHON_SOURCE_EXTENSION:
continue
if self.compile:
bytecode_files.append(
importlib.util.cache_from_source(py_file, optimization='')
)
if self.optimize > 0:
bytecode_files.append(
importlib.util.cache_from_source(
py_file, optimization=self.optimize
)
)
return bytecode_files
# -- External interface --------------------------------------------
# (called by outsiders)
def get_outputs(self):
"""Return the list of files that would be installed if this command
were actually run. Not affected by the "dry-run" flag or whether
modules have actually been built yet.
"""
pure_outputs = self._mutate_outputs(
self.distribution.has_pure_modules(),
'build_py',
'build_lib',
self.install_dir,
)
if self.compile:
bytecode_outputs = self._bytecode_filenames(pure_outputs)
else:
bytecode_outputs = []
ext_outputs = self._mutate_outputs(
self.distribution.has_ext_modules(),
'build_ext',
'build_lib',
self.install_dir,
)
return pure_outputs + bytecode_outputs + ext_outputs
def get_inputs(self):
"""Get the list of files that are input to this command, ie. the
files that get installed as they are named in the build tree.
The files in this list correspond one-to-one to the output
filenames returned by 'get_outputs()'.
"""
inputs = []
if self.distribution.has_pure_modules():
build_py = self.get_finalized_command('build_py')
inputs.extend(build_py.get_outputs())
if self.distribution.has_ext_modules():
build_ext = self.get_finalized_command('build_ext')
inputs.extend(build_ext.get_outputs())
return inputs
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/install_lib.py
|
Python
|
mit
| 8,434 |
"""distutils.command.install_scripts
Implements the Distutils 'install_scripts' command, for installing
Python scripts."""
# contributed by Bastian Kleineidam
import os
from distutils.core import Command
from distutils import log
from stat import ST_MODE
class install_scripts(Command):
description = "install scripts (Python or otherwise)"
user_options = [
('install-dir=', 'd', "directory to install scripts to"),
('build-dir=', 'b', "build directory (where to install from)"),
('force', 'f', "force installation (overwrite existing files)"),
('skip-build', None, "skip the build steps"),
]
boolean_options = ['force', 'skip-build']
def initialize_options(self):
self.install_dir = None
self.force = 0
self.build_dir = None
self.skip_build = None
def finalize_options(self):
self.set_undefined_options('build', ('build_scripts', 'build_dir'))
self.set_undefined_options(
'install',
('install_scripts', 'install_dir'),
('force', 'force'),
('skip_build', 'skip_build'),
)
def run(self):
if not self.skip_build:
self.run_command('build_scripts')
self.outfiles = self.copy_tree(self.build_dir, self.install_dir)
if os.name == 'posix':
# Set the executable bits (owner, group, and world) on
# all the scripts we just installed.
for file in self.get_outputs():
if self.dry_run:
log.info("changing mode of %s", file)
else:
mode = ((os.stat(file)[ST_MODE]) | 0o555) & 0o7777
log.info("changing mode of %s to %o", file, mode)
os.chmod(file, mode)
def get_inputs(self):
return self.distribution.scripts or []
def get_outputs(self):
return self.outfiles or []
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/install_scripts.py
|
Python
|
mit
| 1,936 |
import sys
def _pythonlib_compat():
"""
On Python 3.7 and earlier, distutils would include the Python
library. See pypa/distutils#9.
"""
from distutils import sysconfig
if not sysconfig.get_config_var('Py_ENABLED_SHARED'):
return
yield 'python{}.{}{}'.format(
sys.hexversion >> 24,
(sys.hexversion >> 16) & 0xFF,
sysconfig.get_config_var('ABIFLAGS'),
)
def compose(f1, f2):
return lambda *args, **kwargs: f1(f2(*args, **kwargs))
pythonlib = (
compose(list, _pythonlib_compat)
if sys.version_info < (3, 8)
and sys.platform != 'darwin'
and sys.platform[:3] != 'aix'
else list
)
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/py37compat.py
|
Python
|
mit
| 672 |
"""distutils.command.register
Implements the Distutils 'register' command (register with the repository).
"""
# created 2002/10/21, Richard Jones
import getpass
import io
import urllib.parse
import urllib.request
from warnings import warn
from distutils.core import PyPIRCCommand
from distutils import log
class register(PyPIRCCommand):
description = "register the distribution with the Python package index"
user_options = PyPIRCCommand.user_options + [
('list-classifiers', None, 'list the valid Trove classifiers'),
(
'strict',
None,
'Will stop the registering if the meta-data are not fully compliant',
),
]
boolean_options = PyPIRCCommand.boolean_options + [
'verify',
'list-classifiers',
'strict',
]
sub_commands = [('check', lambda self: True)]
def initialize_options(self):
PyPIRCCommand.initialize_options(self)
self.list_classifiers = 0
self.strict = 0
def finalize_options(self):
PyPIRCCommand.finalize_options(self)
# setting options for the `check` subcommand
check_options = {
'strict': ('register', self.strict),
'restructuredtext': ('register', 1),
}
self.distribution.command_options['check'] = check_options
def run(self):
self.finalize_options()
self._set_config()
# Run sub commands
for cmd_name in self.get_sub_commands():
self.run_command(cmd_name)
if self.dry_run:
self.verify_metadata()
elif self.list_classifiers:
self.classifiers()
else:
self.send_metadata()
def check_metadata(self):
"""Deprecated API."""
warn(
"distutils.command.register.check_metadata is deprecated; "
"use the check command instead",
DeprecationWarning,
)
check = self.distribution.get_command_obj('check')
check.ensure_finalized()
check.strict = self.strict
check.restructuredtext = 1
check.run()
def _set_config(self):
'''Reads the configuration file and set attributes.'''
config = self._read_pypirc()
if config != {}:
self.username = config['username']
self.password = config['password']
self.repository = config['repository']
self.realm = config['realm']
self.has_config = True
else:
if self.repository not in ('pypi', self.DEFAULT_REPOSITORY):
raise ValueError('%s not found in .pypirc' % self.repository)
if self.repository == 'pypi':
self.repository = self.DEFAULT_REPOSITORY
self.has_config = False
def classifiers(self):
'''Fetch the list of classifiers from the server.'''
url = self.repository + '?:action=list_classifiers'
response = urllib.request.urlopen(url)
log.info(self._read_pypi_response(response))
def verify_metadata(self):
'''Send the metadata to the package index server to be checked.'''
# send the info to the server and report the result
(code, result) = self.post_to_server(self.build_post_data('verify'))
log.info('Server response (%s): %s', code, result)
def send_metadata(self): # noqa: C901
'''Send the metadata to the package index server.
Well, do the following:
1. figure who the user is, and then
2. send the data as a Basic auth'ed POST.
First we try to read the username/password from $HOME/.pypirc,
which is a ConfigParser-formatted file with a section
[distutils] containing username and password entries (both
in clear text). Eg:
[distutils]
index-servers =
pypi
[pypi]
username: fred
password: sekrit
Otherwise, to figure who the user is, we offer the user three
choices:
1. use existing login,
2. register as a new user, or
3. set the password to a random string and email the user.
'''
# see if we can short-cut and get the username/password from the
# config
if self.has_config:
choice = '1'
username = self.username
password = self.password
else:
choice = 'x'
username = password = ''
# get the user's login info
choices = '1 2 3 4'.split()
while choice not in choices:
self.announce(
'''\
We need to know who you are, so please choose either:
1. use your existing login,
2. register as a new user,
3. have the server generate a new password for you (and email it to you), or
4. quit
Your selection [default 1]: ''',
log.INFO,
)
choice = input()
if not choice:
choice = '1'
elif choice not in choices:
print('Please choose one of the four options!')
if choice == '1':
# get the username and password
while not username:
username = input('Username: ')
while not password:
password = getpass.getpass('Password: ')
# set up the authentication
auth = urllib.request.HTTPPasswordMgr()
host = urllib.parse.urlparse(self.repository)[1]
auth.add_password(self.realm, host, username, password)
# send the info to the server and report the result
code, result = self.post_to_server(self.build_post_data('submit'), auth)
self.announce('Server response ({}): {}'.format(code, result), log.INFO)
# possibly save the login
if code == 200:
if self.has_config:
# sharing the password in the distribution instance
# so the upload command can reuse it
self.distribution.password = password
else:
self.announce(
(
'I can store your PyPI login so future '
'submissions will be faster.'
),
log.INFO,
)
self.announce(
'(the login will be stored in %s)' % self._get_rc_file(),
log.INFO,
)
choice = 'X'
while choice.lower() not in 'yn':
choice = input('Save your login (y/N)?')
if not choice:
choice = 'n'
if choice.lower() == 'y':
self._store_pypirc(username, password)
elif choice == '2':
data = {':action': 'user'}
data['name'] = data['password'] = data['email'] = ''
data['confirm'] = None
while not data['name']:
data['name'] = input('Username: ')
while data['password'] != data['confirm']:
while not data['password']:
data['password'] = getpass.getpass('Password: ')
while not data['confirm']:
data['confirm'] = getpass.getpass(' Confirm: ')
if data['password'] != data['confirm']:
data['password'] = ''
data['confirm'] = None
print("Password and confirm don't match!")
while not data['email']:
data['email'] = input(' EMail: ')
code, result = self.post_to_server(data)
if code != 200:
log.info('Server response (%s): %s', code, result)
else:
log.info('You will receive an email shortly.')
log.info('Follow the instructions in it to ' 'complete registration.')
elif choice == '3':
data = {':action': 'password_reset'}
data['email'] = ''
while not data['email']:
data['email'] = input('Your email address: ')
code, result = self.post_to_server(data)
log.info('Server response (%s): %s', code, result)
def build_post_data(self, action):
# figure the data to send - the metadata plus some additional
# information used by the package server
meta = self.distribution.metadata
data = {
':action': action,
'metadata_version': '1.0',
'name': meta.get_name(),
'version': meta.get_version(),
'summary': meta.get_description(),
'home_page': meta.get_url(),
'author': meta.get_contact(),
'author_email': meta.get_contact_email(),
'license': meta.get_licence(),
'description': meta.get_long_description(),
'keywords': meta.get_keywords(),
'platform': meta.get_platforms(),
'classifiers': meta.get_classifiers(),
'download_url': meta.get_download_url(),
# PEP 314
'provides': meta.get_provides(),
'requires': meta.get_requires(),
'obsoletes': meta.get_obsoletes(),
}
if data['provides'] or data['requires'] or data['obsoletes']:
data['metadata_version'] = '1.1'
return data
def post_to_server(self, data, auth=None): # noqa: C901
'''Post a query to the server, and return a string response.'''
if 'name' in data:
self.announce(
'Registering {} to {}'.format(data['name'], self.repository), log.INFO
)
# Build up the MIME payload for the urllib2 POST data
boundary = '--------------GHSKFJDLGDS7543FJKLFHRE75642756743254'
sep_boundary = '\n--' + boundary
end_boundary = sep_boundary + '--'
body = io.StringIO()
for key, value in data.items():
# handle multiple entries for the same name
if type(value) not in (type([]), type(())):
value = [value]
for value in value:
value = str(value)
body.write(sep_boundary)
body.write('\nContent-Disposition: form-data; name="%s"' % key)
body.write("\n\n")
body.write(value)
if value and value[-1] == '\r':
body.write('\n') # write an extra newline (lurve Macs)
body.write(end_boundary)
body.write("\n")
body = body.getvalue().encode("utf-8")
# build the Request
headers = {
'Content-type': 'multipart/form-data; boundary=%s; charset=utf-8'
% boundary,
'Content-length': str(len(body)),
}
req = urllib.request.Request(self.repository, body, headers)
# handle HTTP and include the Basic Auth handler
opener = urllib.request.build_opener(
urllib.request.HTTPBasicAuthHandler(password_mgr=auth)
)
data = ''
try:
result = opener.open(req)
except urllib.error.HTTPError as e:
if self.show_response:
data = e.fp.read()
result = e.code, e.msg
except urllib.error.URLError as e:
result = 500, str(e)
else:
if self.show_response:
data = self._read_pypi_response(result)
result = 200, 'OK'
if self.show_response:
msg = '\n'.join(('-' * 75, data, '-' * 75))
self.announce(msg, log.INFO)
return result
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/register.py
|
Python
|
mit
| 11,765 |
"""distutils.command.sdist
Implements the Distutils 'sdist' command (create a source distribution)."""
import os
import sys
from glob import glob
from warnings import warn
from distutils.core import Command
from distutils import dir_util
from distutils import file_util
from distutils import archive_util
from distutils.text_file import TextFile
from distutils.filelist import FileList
from distutils import log
from distutils.util import convert_path
from distutils.errors import DistutilsOptionError, DistutilsTemplateError
def show_formats():
"""Print all possible values for the 'formats' option (used by
the "--help-formats" command-line option).
"""
from distutils.fancy_getopt import FancyGetopt
from distutils.archive_util import ARCHIVE_FORMATS
formats = []
for format in ARCHIVE_FORMATS.keys():
formats.append(("formats=" + format, None, ARCHIVE_FORMATS[format][2]))
formats.sort()
FancyGetopt(formats).print_help("List of available source distribution formats:")
class sdist(Command):
description = "create a source distribution (tarball, zip file, etc.)"
def checking_metadata(self):
"""Callable used for the check sub-command.
Placed here so user_options can view it"""
return self.metadata_check
user_options = [
('template=', 't', "name of manifest template file [default: MANIFEST.in]"),
('manifest=', 'm', "name of manifest file [default: MANIFEST]"),
(
'use-defaults',
None,
"include the default file set in the manifest "
"[default; disable with --no-defaults]",
),
('no-defaults', None, "don't include the default file set"),
(
'prune',
None,
"specifically exclude files/directories that should not be "
"distributed (build tree, RCS/CVS dirs, etc.) "
"[default; disable with --no-prune]",
),
('no-prune', None, "don't automatically exclude anything"),
(
'manifest-only',
'o',
"just regenerate the manifest and then stop " "(implies --force-manifest)",
),
(
'force-manifest',
'f',
"forcibly regenerate the manifest and carry on as usual. "
"Deprecated: now the manifest is always regenerated.",
),
('formats=', None, "formats for source distribution (comma-separated list)"),
(
'keep-temp',
'k',
"keep the distribution tree around after creating " + "archive file(s)",
),
(
'dist-dir=',
'd',
"directory to put the source distribution archive(s) in " "[default: dist]",
),
(
'metadata-check',
None,
"Ensure that all required elements of meta-data "
"are supplied. Warn if any missing. [default]",
),
(
'owner=',
'u',
"Owner name used when creating a tar file [default: current user]",
),
(
'group=',
'g',
"Group name used when creating a tar file [default: current group]",
),
]
boolean_options = [
'use-defaults',
'prune',
'manifest-only',
'force-manifest',
'keep-temp',
'metadata-check',
]
help_options = [
('help-formats', None, "list available distribution formats", show_formats),
]
negative_opt = {'no-defaults': 'use-defaults', 'no-prune': 'prune'}
sub_commands = [('check', checking_metadata)]
READMES = ('README', 'README.txt', 'README.rst')
def initialize_options(self):
# 'template' and 'manifest' are, respectively, the names of
# the manifest template and manifest file.
self.template = None
self.manifest = None
# 'use_defaults': if true, we will include the default file set
# in the manifest
self.use_defaults = 1
self.prune = 1
self.manifest_only = 0
self.force_manifest = 0
self.formats = ['gztar']
self.keep_temp = 0
self.dist_dir = None
self.archive_files = None
self.metadata_check = 1
self.owner = None
self.group = None
def finalize_options(self):
if self.manifest is None:
self.manifest = "MANIFEST"
if self.template is None:
self.template = "MANIFEST.in"
self.ensure_string_list('formats')
bad_format = archive_util.check_archive_formats(self.formats)
if bad_format:
raise DistutilsOptionError("unknown archive format '%s'" % bad_format)
if self.dist_dir is None:
self.dist_dir = "dist"
def run(self):
# 'filelist' contains the list of files that will make up the
# manifest
self.filelist = FileList()
# Run sub commands
for cmd_name in self.get_sub_commands():
self.run_command(cmd_name)
# Do whatever it takes to get the list of files to process
# (process the manifest template, read an existing manifest,
# whatever). File list is accumulated in 'self.filelist'.
self.get_file_list()
# If user just wanted us to regenerate the manifest, stop now.
if self.manifest_only:
return
# Otherwise, go ahead and create the source distribution tarball,
# or zipfile, or whatever.
self.make_distribution()
def check_metadata(self):
"""Deprecated API."""
warn(
"distutils.command.sdist.check_metadata is deprecated, \
use the check command instead",
PendingDeprecationWarning,
)
check = self.distribution.get_command_obj('check')
check.ensure_finalized()
check.run()
def get_file_list(self):
"""Figure out the list of files to include in the source
distribution, and put it in 'self.filelist'. This might involve
reading the manifest template (and writing the manifest), or just
reading the manifest, or just using the default file set -- it all
depends on the user's options.
"""
# new behavior when using a template:
# the file list is recalculated every time because
# even if MANIFEST.in or setup.py are not changed
# the user might have added some files in the tree that
# need to be included.
#
# This makes --force the default and only behavior with templates.
template_exists = os.path.isfile(self.template)
if not template_exists and self._manifest_is_not_generated():
self.read_manifest()
self.filelist.sort()
self.filelist.remove_duplicates()
return
if not template_exists:
self.warn(
("manifest template '%s' does not exist " + "(using default file list)")
% self.template
)
self.filelist.findall()
if self.use_defaults:
self.add_defaults()
if template_exists:
self.read_template()
if self.prune:
self.prune_file_list()
self.filelist.sort()
self.filelist.remove_duplicates()
self.write_manifest()
def add_defaults(self):
"""Add all the default files to self.filelist:
- README or README.txt
- setup.py
- test/test*.py
- all pure Python modules mentioned in setup script
- all files pointed by package_data (build_py)
- all files defined in data_files.
- all files defined as scripts.
- all C sources listed as part of extensions or C libraries
in the setup script (doesn't catch C headers!)
Warns if (README or README.txt) or setup.py are missing; everything
else is optional.
"""
self._add_defaults_standards()
self._add_defaults_optional()
self._add_defaults_python()
self._add_defaults_data_files()
self._add_defaults_ext()
self._add_defaults_c_libs()
self._add_defaults_scripts()
@staticmethod
def _cs_path_exists(fspath):
"""
Case-sensitive path existence check
>>> sdist._cs_path_exists(__file__)
True
>>> sdist._cs_path_exists(__file__.upper())
False
"""
if not os.path.exists(fspath):
return False
# make absolute so we always have a directory
abspath = os.path.abspath(fspath)
directory, filename = os.path.split(abspath)
return filename in os.listdir(directory)
def _add_defaults_standards(self):
standards = [self.READMES, self.distribution.script_name]
for fn in standards:
if isinstance(fn, tuple):
alts = fn
got_it = False
for fn in alts:
if self._cs_path_exists(fn):
got_it = True
self.filelist.append(fn)
break
if not got_it:
self.warn(
"standard file not found: should have one of " + ', '.join(alts)
)
else:
if self._cs_path_exists(fn):
self.filelist.append(fn)
else:
self.warn("standard file '%s' not found" % fn)
def _add_defaults_optional(self):
optional = ['test/test*.py', 'setup.cfg']
for pattern in optional:
files = filter(os.path.isfile, glob(pattern))
self.filelist.extend(files)
def _add_defaults_python(self):
# build_py is used to get:
# - python modules
# - files defined in package_data
build_py = self.get_finalized_command('build_py')
# getting python files
if self.distribution.has_pure_modules():
self.filelist.extend(build_py.get_source_files())
# getting package_data files
# (computed in build_py.data_files by build_py.finalize_options)
for pkg, src_dir, build_dir, filenames in build_py.data_files:
for filename in filenames:
self.filelist.append(os.path.join(src_dir, filename))
def _add_defaults_data_files(self):
# getting distribution.data_files
if self.distribution.has_data_files():
for item in self.distribution.data_files:
if isinstance(item, str):
# plain file
item = convert_path(item)
if os.path.isfile(item):
self.filelist.append(item)
else:
# a (dirname, filenames) tuple
dirname, filenames = item
for f in filenames:
f = convert_path(f)
if os.path.isfile(f):
self.filelist.append(f)
def _add_defaults_ext(self):
if self.distribution.has_ext_modules():
build_ext = self.get_finalized_command('build_ext')
self.filelist.extend(build_ext.get_source_files())
def _add_defaults_c_libs(self):
if self.distribution.has_c_libraries():
build_clib = self.get_finalized_command('build_clib')
self.filelist.extend(build_clib.get_source_files())
def _add_defaults_scripts(self):
if self.distribution.has_scripts():
build_scripts = self.get_finalized_command('build_scripts')
self.filelist.extend(build_scripts.get_source_files())
def read_template(self):
"""Read and parse manifest template file named by self.template.
(usually "MANIFEST.in") The parsing and processing is done by
'self.filelist', which updates itself accordingly.
"""
log.info("reading manifest template '%s'", self.template)
template = TextFile(
self.template,
strip_comments=1,
skip_blanks=1,
join_lines=1,
lstrip_ws=1,
rstrip_ws=1,
collapse_join=1,
)
try:
while True:
line = template.readline()
if line is None: # end of file
break
try:
self.filelist.process_template_line(line)
# the call above can raise a DistutilsTemplateError for
# malformed lines, or a ValueError from the lower-level
# convert_path function
except (DistutilsTemplateError, ValueError) as msg:
self.warn(
"%s, line %d: %s"
% (template.filename, template.current_line, msg)
)
finally:
template.close()
def prune_file_list(self):
"""Prune off branches that might slip into the file list as created
by 'read_template()', but really don't belong there:
* the build tree (typically "build")
* the release tree itself (only an issue if we ran "sdist"
previously with --keep-temp, or it aborted)
* any RCS, CVS, .svn, .hg, .git, .bzr, _darcs directories
"""
build = self.get_finalized_command('build')
base_dir = self.distribution.get_fullname()
self.filelist.exclude_pattern(None, prefix=build.build_base)
self.filelist.exclude_pattern(None, prefix=base_dir)
if sys.platform == 'win32':
seps = r'/|\\'
else:
seps = '/'
vcs_dirs = ['RCS', 'CVS', r'\.svn', r'\.hg', r'\.git', r'\.bzr', '_darcs']
vcs_ptrn = r'(^|{})({})({}).*'.format(seps, '|'.join(vcs_dirs), seps)
self.filelist.exclude_pattern(vcs_ptrn, is_regex=1)
def write_manifest(self):
"""Write the file list in 'self.filelist' (presumably as filled in
by 'add_defaults()' and 'read_template()') to the manifest file
named by 'self.manifest'.
"""
if self._manifest_is_not_generated():
log.info(
"not writing to manually maintained "
"manifest file '%s'" % self.manifest
)
return
content = self.filelist.files[:]
content.insert(0, '# file GENERATED by distutils, do NOT edit')
self.execute(
file_util.write_file,
(self.manifest, content),
"writing manifest file '%s'" % self.manifest,
)
def _manifest_is_not_generated(self):
# check for special comment used in 3.1.3 and higher
if not os.path.isfile(self.manifest):
return False
fp = open(self.manifest)
try:
first_line = fp.readline()
finally:
fp.close()
return first_line != '# file GENERATED by distutils, do NOT edit\n'
def read_manifest(self):
"""Read the manifest file (named by 'self.manifest') and use it to
fill in 'self.filelist', the list of files to include in the source
distribution.
"""
log.info("reading manifest file '%s'", self.manifest)
with open(self.manifest) as manifest:
for line in manifest:
# ignore comments and blank lines
line = line.strip()
if line.startswith('#') or not line:
continue
self.filelist.append(line)
def make_release_tree(self, base_dir, files):
"""Create the directory tree that will become the source
distribution archive. All directories implied by the filenames in
'files' are created under 'base_dir', and then we hard link or copy
(if hard linking is unavailable) those files into place.
Essentially, this duplicates the developer's source tree, but in a
directory named after the distribution, containing only the files
to be distributed.
"""
# Create all the directories under 'base_dir' necessary to
# put 'files' there; the 'mkpath()' is just so we don't die
# if the manifest happens to be empty.
self.mkpath(base_dir)
dir_util.create_tree(base_dir, files, dry_run=self.dry_run)
# And walk over the list of files, either making a hard link (if
# os.link exists) to each one that doesn't already exist in its
# corresponding location under 'base_dir', or copying each file
# that's out-of-date in 'base_dir'. (Usually, all files will be
# out-of-date, because by default we blow away 'base_dir' when
# we're done making the distribution archives.)
if hasattr(os, 'link'): # can make hard links on this system
link = 'hard'
msg = "making hard links in %s..." % base_dir
else: # nope, have to copy
link = None
msg = "copying files to %s..." % base_dir
if not files:
log.warn("no files to distribute -- empty manifest?")
else:
log.info(msg)
for file in files:
if not os.path.isfile(file):
log.warn("'%s' not a regular file -- skipping", file)
else:
dest = os.path.join(base_dir, file)
self.copy_file(file, dest, link=link)
self.distribution.metadata.write_pkg_info(base_dir)
def make_distribution(self):
"""Create the source distribution(s). First, we create the release
tree with 'make_release_tree()'; then, we create all required
archive files (according to 'self.formats') from the release tree.
Finally, we clean up by blowing away the release tree (unless
'self.keep_temp' is true). The list of archive files created is
stored so it can be retrieved later by 'get_archive_files()'.
"""
# Don't warn about missing meta-data here -- should be (and is!)
# done elsewhere.
base_dir = self.distribution.get_fullname()
base_name = os.path.join(self.dist_dir, base_dir)
self.make_release_tree(base_dir, self.filelist.files)
archive_files = [] # remember names of files we create
# tar archive must be created last to avoid overwrite and remove
if 'tar' in self.formats:
self.formats.append(self.formats.pop(self.formats.index('tar')))
for fmt in self.formats:
file = self.make_archive(
base_name, fmt, base_dir=base_dir, owner=self.owner, group=self.group
)
archive_files.append(file)
self.distribution.dist_files.append(('sdist', '', file))
self.archive_files = archive_files
if not self.keep_temp:
dir_util.remove_tree(base_dir, dry_run=self.dry_run)
def get_archive_files(self):
"""Return the list of archive files created when the command
was run, or None if the command hasn't run yet.
"""
return self.archive_files
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/sdist.py
|
Python
|
mit
| 19,241 |
"""
distutils.command.upload
Implements the Distutils 'upload' subcommand (upload package to a package
index).
"""
import os
import io
import hashlib
from base64 import standard_b64encode
from urllib.request import urlopen, Request, HTTPError
from urllib.parse import urlparse
from distutils.errors import DistutilsError, DistutilsOptionError
from distutils.core import PyPIRCCommand
from distutils.spawn import spawn
from distutils import log
# PyPI Warehouse supports MD5, SHA256, and Blake2 (blake2-256)
# https://bugs.python.org/issue40698
_FILE_CONTENT_DIGESTS = {
"md5_digest": getattr(hashlib, "md5", None),
"sha256_digest": getattr(hashlib, "sha256", None),
"blake2_256_digest": getattr(hashlib, "blake2b", None),
}
class upload(PyPIRCCommand):
description = "upload binary package to PyPI"
user_options = PyPIRCCommand.user_options + [
('sign', 's', 'sign files to upload using gpg'),
('identity=', 'i', 'GPG identity used to sign files'),
]
boolean_options = PyPIRCCommand.boolean_options + ['sign']
def initialize_options(self):
PyPIRCCommand.initialize_options(self)
self.username = ''
self.password = ''
self.show_response = 0
self.sign = False
self.identity = None
def finalize_options(self):
PyPIRCCommand.finalize_options(self)
if self.identity and not self.sign:
raise DistutilsOptionError("Must use --sign for --identity to have meaning")
config = self._read_pypirc()
if config != {}:
self.username = config['username']
self.password = config['password']
self.repository = config['repository']
self.realm = config['realm']
# getting the password from the distribution
# if previously set by the register command
if not self.password and self.distribution.password:
self.password = self.distribution.password
def run(self):
if not self.distribution.dist_files:
msg = (
"Must create and upload files in one command "
"(e.g. setup.py sdist upload)"
)
raise DistutilsOptionError(msg)
for command, pyversion, filename in self.distribution.dist_files:
self.upload_file(command, pyversion, filename)
def upload_file(self, command, pyversion, filename): # noqa: C901
# Makes sure the repository URL is compliant
schema, netloc, url, params, query, fragments = urlparse(self.repository)
if params or query or fragments:
raise AssertionError("Incompatible url %s" % self.repository)
if schema not in ('http', 'https'):
raise AssertionError("unsupported schema " + schema)
# Sign if requested
if self.sign:
gpg_args = ["gpg", "--detach-sign", "-a", filename]
if self.identity:
gpg_args[2:2] = ["--local-user", self.identity]
spawn(gpg_args, dry_run=self.dry_run)
# Fill in the data - send all the meta-data in case we need to
# register a new release
f = open(filename, 'rb')
try:
content = f.read()
finally:
f.close()
meta = self.distribution.metadata
data = {
# action
':action': 'file_upload',
'protocol_version': '1',
# identify release
'name': meta.get_name(),
'version': meta.get_version(),
# file content
'content': (os.path.basename(filename), content),
'filetype': command,
'pyversion': pyversion,
# additional meta-data
'metadata_version': '1.0',
'summary': meta.get_description(),
'home_page': meta.get_url(),
'author': meta.get_contact(),
'author_email': meta.get_contact_email(),
'license': meta.get_licence(),
'description': meta.get_long_description(),
'keywords': meta.get_keywords(),
'platform': meta.get_platforms(),
'classifiers': meta.get_classifiers(),
'download_url': meta.get_download_url(),
# PEP 314
'provides': meta.get_provides(),
'requires': meta.get_requires(),
'obsoletes': meta.get_obsoletes(),
}
data['comment'] = ''
# file content digests
for digest_name, digest_cons in _FILE_CONTENT_DIGESTS.items():
if digest_cons is None:
continue
try:
data[digest_name] = digest_cons(content).hexdigest()
except ValueError:
# hash digest not available or blocked by security policy
pass
if self.sign:
with open(filename + ".asc", "rb") as f:
data['gpg_signature'] = (os.path.basename(filename) + ".asc", f.read())
# set up the authentication
user_pass = (self.username + ":" + self.password).encode('ascii')
# The exact encoding of the authentication string is debated.
# Anyway PyPI only accepts ascii for both username or password.
auth = "Basic " + standard_b64encode(user_pass).decode('ascii')
# Build up the MIME payload for the POST data
boundary = '--------------GHSKFJDLGDS7543FJKLFHRE75642756743254'
sep_boundary = b'\r\n--' + boundary.encode('ascii')
end_boundary = sep_boundary + b'--\r\n'
body = io.BytesIO()
for key, value in data.items():
title = '\r\nContent-Disposition: form-data; name="%s"' % key
# handle multiple entries for the same name
if not isinstance(value, list):
value = [value]
for value in value:
if type(value) is tuple:
title += '; filename="%s"' % value[0]
value = value[1]
else:
value = str(value).encode('utf-8')
body.write(sep_boundary)
body.write(title.encode('utf-8'))
body.write(b"\r\n\r\n")
body.write(value)
body.write(end_boundary)
body = body.getvalue()
msg = "Submitting {} to {}".format(filename, self.repository)
self.announce(msg, log.INFO)
# build the Request
headers = {
'Content-type': 'multipart/form-data; boundary=%s' % boundary,
'Content-length': str(len(body)),
'Authorization': auth,
}
request = Request(self.repository, data=body, headers=headers)
# send the data
try:
result = urlopen(request)
status = result.getcode()
reason = result.msg
except HTTPError as e:
status = e.code
reason = e.msg
except OSError as e:
self.announce(str(e), log.ERROR)
raise
if status == 200:
self.announce('Server response ({}): {}'.format(status, reason), log.INFO)
if self.show_response:
text = self._read_pypi_response(result)
msg = '\n'.join(('-' * 75, text, '-' * 75))
self.announce(msg, log.INFO)
else:
msg = 'Upload failed ({}): {}'.format(status, reason)
self.announce(msg, log.ERROR)
raise DistutilsError(msg)
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/command/upload.py
|
Python
|
mit
| 7,477 |
"""distutils.pypirc
Provides the PyPIRCCommand class, the base class for the command classes
that uses .pypirc in the distutils.command package.
"""
import os
from configparser import RawConfigParser
from distutils.cmd import Command
DEFAULT_PYPIRC = """\
[distutils]
index-servers =
pypi
[pypi]
username:%s
password:%s
"""
class PyPIRCCommand(Command):
"""Base command that knows how to handle the .pypirc file"""
DEFAULT_REPOSITORY = 'https://upload.pypi.org/legacy/'
DEFAULT_REALM = 'pypi'
repository = None
realm = None
user_options = [
('repository=', 'r', "url of repository [default: %s]" % DEFAULT_REPOSITORY),
('show-response', None, 'display full response text from server'),
]
boolean_options = ['show-response']
def _get_rc_file(self):
"""Returns rc file path."""
return os.path.join(os.path.expanduser('~'), '.pypirc')
def _store_pypirc(self, username, password):
"""Creates a default .pypirc file."""
rc = self._get_rc_file()
with os.fdopen(os.open(rc, os.O_CREAT | os.O_WRONLY, 0o600), 'w') as f:
f.write(DEFAULT_PYPIRC % (username, password))
def _read_pypirc(self): # noqa: C901
"""Reads the .pypirc file."""
rc = self._get_rc_file()
if os.path.exists(rc):
self.announce('Using PyPI login from %s' % rc)
repository = self.repository or self.DEFAULT_REPOSITORY
config = RawConfigParser()
config.read(rc)
sections = config.sections()
if 'distutils' in sections:
# let's get the list of servers
index_servers = config.get('distutils', 'index-servers')
_servers = [
server.strip()
for server in index_servers.split('\n')
if server.strip() != ''
]
if _servers == []:
# nothing set, let's try to get the default pypi
if 'pypi' in sections:
_servers = ['pypi']
else:
# the file is not properly defined, returning
# an empty dict
return {}
for server in _servers:
current = {'server': server}
current['username'] = config.get(server, 'username')
# optional params
for key, default in (
('repository', self.DEFAULT_REPOSITORY),
('realm', self.DEFAULT_REALM),
('password', None),
):
if config.has_option(server, key):
current[key] = config.get(server, key)
else:
current[key] = default
# work around people having "repository" for the "pypi"
# section of their config set to the HTTP (rather than
# HTTPS) URL
if server == 'pypi' and repository in (
self.DEFAULT_REPOSITORY,
'pypi',
):
current['repository'] = self.DEFAULT_REPOSITORY
return current
if (
current['server'] == repository
or current['repository'] == repository
):
return current
elif 'server-login' in sections:
# old format
server = 'server-login'
if config.has_option(server, 'repository'):
repository = config.get(server, 'repository')
else:
repository = self.DEFAULT_REPOSITORY
return {
'username': config.get(server, 'username'),
'password': config.get(server, 'password'),
'repository': repository,
'server': server,
'realm': self.DEFAULT_REALM,
}
return {}
def _read_pypi_response(self, response):
"""Read and decode a PyPI HTTP response."""
import cgi
content_type = response.getheader('content-type', 'text/plain')
encoding = cgi.parse_header(content_type)[1].get('charset', 'ascii')
return response.read().decode(encoding)
def initialize_options(self):
"""Initialize options."""
self.repository = None
self.realm = None
self.show_response = 0
def finalize_options(self):
"""Finalizes options."""
if self.repository is None:
self.repository = self.DEFAULT_REPOSITORY
if self.realm is None:
self.realm = self.DEFAULT_REALM
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/config.py
|
Python
|
mit
| 4,920 |
"""distutils.core
The only module that needs to be imported to use the Distutils; provides
the 'setup' function (which is to be called from the setup script). Also
indirectly provides the Distribution and Command classes, although they are
really defined in distutils.dist and distutils.cmd.
"""
import os
import sys
import tokenize
from distutils.debug import DEBUG
from distutils.errors import (
DistutilsSetupError,
DistutilsError,
CCompilerError,
DistutilsArgError,
)
# Mainly import these so setup scripts can "from distutils.core import" them.
from distutils.dist import Distribution
from distutils.cmd import Command
from distutils.config import PyPIRCCommand
from distutils.extension import Extension
__all__ = ['Distribution', 'Command', 'PyPIRCCommand', 'Extension', 'setup']
# This is a barebones help message generated displayed when the user
# runs the setup script with no arguments at all. More useful help
# is generated with various --help options: global help, list commands,
# and per-command help.
USAGE = """\
usage: %(script)s [global_opts] cmd1 [cmd1_opts] [cmd2 [cmd2_opts] ...]
or: %(script)s --help [cmd1 cmd2 ...]
or: %(script)s --help-commands
or: %(script)s cmd --help
"""
def gen_usage(script_name):
script = os.path.basename(script_name)
return USAGE % locals()
# Some mild magic to control the behaviour of 'setup()' from 'run_setup()'.
_setup_stop_after = None
_setup_distribution = None
# Legal keyword arguments for the setup() function
setup_keywords = (
'distclass',
'script_name',
'script_args',
'options',
'name',
'version',
'author',
'author_email',
'maintainer',
'maintainer_email',
'url',
'license',
'description',
'long_description',
'keywords',
'platforms',
'classifiers',
'download_url',
'requires',
'provides',
'obsoletes',
)
# Legal keyword arguments for the Extension constructor
extension_keywords = (
'name',
'sources',
'include_dirs',
'define_macros',
'undef_macros',
'library_dirs',
'libraries',
'runtime_library_dirs',
'extra_objects',
'extra_compile_args',
'extra_link_args',
'swig_opts',
'export_symbols',
'depends',
'language',
)
def setup(**attrs): # noqa: C901
"""The gateway to the Distutils: do everything your setup script needs
to do, in a highly flexible and user-driven way. Briefly: create a
Distribution instance; find and parse config files; parse the command
line; run each Distutils command found there, customized by the options
supplied to 'setup()' (as keyword arguments), in config files, and on
the command line.
The Distribution instance might be an instance of a class supplied via
the 'distclass' keyword argument to 'setup'; if no such class is
supplied, then the Distribution class (in dist.py) is instantiated.
All other arguments to 'setup' (except for 'cmdclass') are used to set
attributes of the Distribution instance.
The 'cmdclass' argument, if supplied, is a dictionary mapping command
names to command classes. Each command encountered on the command line
will be turned into a command class, which is in turn instantiated; any
class found in 'cmdclass' is used in place of the default, which is
(for command 'foo_bar') class 'foo_bar' in module
'distutils.command.foo_bar'. The command class must provide a
'user_options' attribute which is a list of option specifiers for
'distutils.fancy_getopt'. Any command-line options between the current
and the next command are used to set attributes of the current command
object.
When the entire command-line has been successfully parsed, calls the
'run()' method on each command object in turn. This method will be
driven entirely by the Distribution object (which each command object
has a reference to, thanks to its constructor), and the
command-specific options that became attributes of each command
object.
"""
global _setup_stop_after, _setup_distribution
# Determine the distribution class -- either caller-supplied or
# our Distribution (see below).
klass = attrs.get('distclass')
if klass:
del attrs['distclass']
else:
klass = Distribution
if 'script_name' not in attrs:
attrs['script_name'] = os.path.basename(sys.argv[0])
if 'script_args' not in attrs:
attrs['script_args'] = sys.argv[1:]
# Create the Distribution instance, using the remaining arguments
# (ie. everything except distclass) to initialize it
try:
_setup_distribution = dist = klass(attrs)
except DistutilsSetupError as msg:
if 'name' not in attrs:
raise SystemExit("error in setup command: %s" % msg)
else:
raise SystemExit("error in {} setup command: {}".format(attrs['name'], msg))
if _setup_stop_after == "init":
return dist
# Find and parse the config file(s): they will override options from
# the setup script, but be overridden by the command line.
dist.parse_config_files()
if DEBUG:
print("options (after parsing config files):")
dist.dump_option_dicts()
if _setup_stop_after == "config":
return dist
# Parse the command line and override config files; any
# command-line errors are the end user's fault, so turn them into
# SystemExit to suppress tracebacks.
try:
ok = dist.parse_command_line()
except DistutilsArgError as msg:
raise SystemExit(gen_usage(dist.script_name) + "\nerror: %s" % msg)
if DEBUG:
print("options (after parsing command line):")
dist.dump_option_dicts()
if _setup_stop_after == "commandline":
return dist
# And finally, run all the commands found on the command line.
if ok:
return run_commands(dist)
return dist
# setup ()
def run_commands(dist):
"""Given a Distribution object run all the commands,
raising ``SystemExit`` errors in the case of failure.
This function assumes that either ``sys.argv`` or ``dist.script_args``
is already set accordingly.
"""
try:
dist.run_commands()
except KeyboardInterrupt:
raise SystemExit("interrupted")
except OSError as exc:
if DEBUG:
sys.stderr.write("error: {}\n".format(exc))
raise
else:
raise SystemExit("error: {}".format(exc))
except (DistutilsError, CCompilerError) as msg:
if DEBUG:
raise
else:
raise SystemExit("error: " + str(msg))
return dist
def run_setup(script_name, script_args=None, stop_after="run"):
"""Run a setup script in a somewhat controlled environment, and
return the Distribution instance that drives things. This is useful
if you need to find out the distribution meta-data (passed as
keyword args from 'script' to 'setup()', or the contents of the
config files or command-line.
'script_name' is a file that will be read and run with 'exec()';
'sys.argv[0]' will be replaced with 'script' for the duration of the
call. 'script_args' is a list of strings; if supplied,
'sys.argv[1:]' will be replaced by 'script_args' for the duration of
the call.
'stop_after' tells 'setup()' when to stop processing; possible
values:
init
stop after the Distribution instance has been created and
populated with the keyword arguments to 'setup()'
config
stop after config files have been parsed (and their data
stored in the Distribution instance)
commandline
stop after the command-line ('sys.argv[1:]' or 'script_args')
have been parsed (and the data stored in the Distribution)
run [default]
stop after all commands have been run (the same as if 'setup()'
had been called in the usual way
Returns the Distribution instance, which provides all information
used to drive the Distutils.
"""
if stop_after not in ('init', 'config', 'commandline', 'run'):
raise ValueError("invalid value for 'stop_after': {!r}".format(stop_after))
global _setup_stop_after, _setup_distribution
_setup_stop_after = stop_after
save_argv = sys.argv.copy()
g = {'__file__': script_name, '__name__': '__main__'}
try:
try:
sys.argv[0] = script_name
if script_args is not None:
sys.argv[1:] = script_args
# tokenize.open supports automatic encoding detection
with tokenize.open(script_name) as f:
code = f.read().replace(r'\r\n', r'\n')
exec(code, g)
finally:
sys.argv = save_argv
_setup_stop_after = None
except SystemExit:
# Hmm, should we do something if exiting with a non-zero code
# (ie. error)?
pass
if _setup_distribution is None:
raise RuntimeError(
(
"'distutils.core.setup()' was never called -- "
"perhaps '%s' is not a Distutils setup script?"
)
% script_name
)
# I wonder if the setup script's namespace -- g and l -- would be of
# any interest to callers?
# print "_setup_distribution:", _setup_distribution
return _setup_distribution
# run_setup ()
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/core.py
|
Python
|
mit
| 9,451 |
"""distutils.cygwinccompiler
Provides the CygwinCCompiler class, a subclass of UnixCCompiler that
handles the Cygwin port of the GNU C compiler to Windows. It also contains
the Mingw32CCompiler class which handles the mingw32 port of GCC (same as
cygwin in no-cygwin mode).
"""
import os
import sys
import copy
import shlex
import warnings
from subprocess import check_output
from distutils.unixccompiler import UnixCCompiler
from distutils.file_util import write_file
from distutils.errors import (
DistutilsExecError,
DistutilsPlatformError,
CCompilerError,
CompileError,
)
from distutils.version import LooseVersion, suppress_known_deprecation
def get_msvcr():
"""Include the appropriate MSVC runtime library if Python was built
with MSVC 7.0 or later.
"""
msc_pos = sys.version.find('MSC v.')
if msc_pos != -1:
msc_ver = sys.version[msc_pos + 6 : msc_pos + 10]
if msc_ver == '1300':
# MSVC 7.0
return ['msvcr70']
elif msc_ver == '1310':
# MSVC 7.1
return ['msvcr71']
elif msc_ver == '1400':
# VS2005 / MSVC 8.0
return ['msvcr80']
elif msc_ver == '1500':
# VS2008 / MSVC 9.0
return ['msvcr90']
elif msc_ver == '1600':
# VS2010 / MSVC 10.0
return ['msvcr100']
elif msc_ver == '1700':
# VS2012 / MSVC 11.0
return ['msvcr110']
elif msc_ver == '1800':
# VS2013 / MSVC 12.0
return ['msvcr120']
elif 1900 <= int(msc_ver) < 2000:
# VS2015 / MSVC 14.0
return ['ucrt', 'vcruntime140']
else:
raise ValueError("Unknown MS Compiler version %s " % msc_ver)
_runtime_library_dirs_msg = (
"Unable to set runtime library search path on Windows, "
"usually indicated by `runtime_library_dirs` parameter to Extension"
)
class CygwinCCompiler(UnixCCompiler):
"""Handles the Cygwin port of the GNU C compiler to Windows."""
compiler_type = 'cygwin'
obj_extension = ".o"
static_lib_extension = ".a"
shared_lib_extension = ".dll.a"
dylib_lib_extension = ".dll"
static_lib_format = "lib%s%s"
shared_lib_format = "lib%s%s"
dylib_lib_format = "cyg%s%s"
exe_extension = ".exe"
def __init__(self, verbose=0, dry_run=0, force=0):
super().__init__(verbose, dry_run, force)
status, details = check_config_h()
self.debug_print(
"Python's GCC status: {} (details: {})".format(status, details)
)
if status is not CONFIG_H_OK:
self.warn(
"Python's pyconfig.h doesn't seem to support your compiler. "
"Reason: %s. "
"Compiling may fail because of undefined preprocessor macros." % details
)
self.cc = os.environ.get('CC', 'gcc')
self.cxx = os.environ.get('CXX', 'g++')
self.linker_dll = self.cc
shared_option = "-shared"
self.set_executables(
compiler='%s -mcygwin -O -Wall' % self.cc,
compiler_so='%s -mcygwin -mdll -O -Wall' % self.cc,
compiler_cxx='%s -mcygwin -O -Wall' % self.cxx,
linker_exe='%s -mcygwin' % self.cc,
linker_so=('{} -mcygwin {}'.format(self.linker_dll, shared_option)),
)
# Include the appropriate MSVC runtime library if Python was built
# with MSVC 7.0 or later.
self.dll_libraries = get_msvcr()
@property
def gcc_version(self):
# Older numpy dependend on this existing to check for ancient
# gcc versions. This doesn't make much sense with clang etc so
# just hardcode to something recent.
# https://github.com/numpy/numpy/pull/20333
warnings.warn(
"gcc_version attribute of CygwinCCompiler is deprecated. "
"Instead of returning actual gcc version a fixed value 11.2.0 is returned.",
DeprecationWarning,
stacklevel=2,
)
with suppress_known_deprecation():
return LooseVersion("11.2.0")
def _compile(self, obj, src, ext, cc_args, extra_postargs, pp_opts):
"""Compiles the source by spawning GCC and windres if needed."""
if ext == '.rc' or ext == '.res':
# gcc needs '.res' and '.rc' compiled to object files !!!
try:
self.spawn(["windres", "-i", src, "-o", obj])
except DistutilsExecError as msg:
raise CompileError(msg)
else: # for other files use the C-compiler
try:
self.spawn(
self.compiler_so + cc_args + [src, '-o', obj] + extra_postargs
)
except DistutilsExecError as msg:
raise CompileError(msg)
def link(
self,
target_desc,
objects,
output_filename,
output_dir=None,
libraries=None,
library_dirs=None,
runtime_library_dirs=None,
export_symbols=None,
debug=0,
extra_preargs=None,
extra_postargs=None,
build_temp=None,
target_lang=None,
):
"""Link the objects."""
# use separate copies, so we can modify the lists
extra_preargs = copy.copy(extra_preargs or [])
libraries = copy.copy(libraries or [])
objects = copy.copy(objects or [])
if runtime_library_dirs:
self.warn(_runtime_library_dirs_msg)
# Additional libraries
libraries.extend(self.dll_libraries)
# handle export symbols by creating a def-file
# with executables this only works with gcc/ld as linker
if (export_symbols is not None) and (
target_desc != self.EXECUTABLE or self.linker_dll == "gcc"
):
# (The linker doesn't do anything if output is up-to-date.
# So it would probably better to check if we really need this,
# but for this we had to insert some unchanged parts of
# UnixCCompiler, and this is not what we want.)
# we want to put some files in the same directory as the
# object files are, build_temp doesn't help much
# where are the object files
temp_dir = os.path.dirname(objects[0])
# name of dll to give the helper files the same base name
(dll_name, dll_extension) = os.path.splitext(
os.path.basename(output_filename)
)
# generate the filenames for these files
def_file = os.path.join(temp_dir, dll_name + ".def")
# Generate .def file
contents = ["LIBRARY %s" % os.path.basename(output_filename), "EXPORTS"]
for sym in export_symbols:
contents.append(sym)
self.execute(write_file, (def_file, contents), "writing %s" % def_file)
# next add options for def-file
# for gcc/ld the def-file is specified as any object files
objects.append(def_file)
# end: if ((export_symbols is not None) and
# (target_desc != self.EXECUTABLE or self.linker_dll == "gcc")):
# who wants symbols and a many times larger output file
# should explicitly switch the debug mode on
# otherwise we let ld strip the output file
# (On my machine: 10KiB < stripped_file < ??100KiB
# unstripped_file = stripped_file + XXX KiB
# ( XXX=254 for a typical python extension))
if not debug:
extra_preargs.append("-s")
UnixCCompiler.link(
self,
target_desc,
objects,
output_filename,
output_dir,
libraries,
library_dirs,
runtime_library_dirs,
None, # export_symbols, we do this in our def-file
debug,
extra_preargs,
extra_postargs,
build_temp,
target_lang,
)
def runtime_library_dir_option(self, dir):
# cygwin doesn't support rpath. While in theory we could error
# out like MSVC does, code might expect it to work like on Unix, so
# just warn and hope for the best.
self.warn(_runtime_library_dirs_msg)
return []
# -- Miscellaneous methods -----------------------------------------
def _make_out_path(self, output_dir, strip_dir, src_name):
# use normcase to make sure '.rc' is really '.rc' and not '.RC'
norm_src_name = os.path.normcase(src_name)
return super()._make_out_path(output_dir, strip_dir, norm_src_name)
@property
def out_extensions(self):
"""
Add support for rc and res files.
"""
return {
**super().out_extensions,
**{ext: ext + self.obj_extension for ext in ('.res', '.rc')},
}
# the same as cygwin plus some additional parameters
class Mingw32CCompiler(CygwinCCompiler):
"""Handles the Mingw32 port of the GNU C compiler to Windows."""
compiler_type = 'mingw32'
def __init__(self, verbose=0, dry_run=0, force=0):
super().__init__(verbose, dry_run, force)
shared_option = "-shared"
if is_cygwincc(self.cc):
raise CCompilerError('Cygwin gcc cannot be used with --compiler=mingw32')
self.set_executables(
compiler='%s -O -Wall' % self.cc,
compiler_so='%s -mdll -O -Wall' % self.cc,
compiler_cxx='%s -O -Wall' % self.cxx,
linker_exe='%s' % self.cc,
linker_so='{} {}'.format(self.linker_dll, shared_option),
)
# Maybe we should also append -mthreads, but then the finished
# dlls need another dll (mingwm10.dll see Mingw32 docs)
# (-mthreads: Support thread-safe exception handling on `Mingw32')
# no additional libraries needed
self.dll_libraries = []
# Include the appropriate MSVC runtime library if Python was built
# with MSVC 7.0 or later.
self.dll_libraries = get_msvcr()
def runtime_library_dir_option(self, dir):
raise DistutilsPlatformError(_runtime_library_dirs_msg)
# Because these compilers aren't configured in Python's pyconfig.h file by
# default, we should at least warn the user if he is using an unmodified
# version.
CONFIG_H_OK = "ok"
CONFIG_H_NOTOK = "not ok"
CONFIG_H_UNCERTAIN = "uncertain"
def check_config_h():
"""Check if the current Python installation appears amenable to building
extensions with GCC.
Returns a tuple (status, details), where 'status' is one of the following
constants:
- CONFIG_H_OK: all is well, go ahead and compile
- CONFIG_H_NOTOK: doesn't look good
- CONFIG_H_UNCERTAIN: not sure -- unable to read pyconfig.h
'details' is a human-readable string explaining the situation.
Note there are two ways to conclude "OK": either 'sys.version' contains
the string "GCC" (implying that this Python was built with GCC), or the
installed "pyconfig.h" contains the string "__GNUC__".
"""
# XXX since this function also checks sys.version, it's not strictly a
# "pyconfig.h" check -- should probably be renamed...
from distutils import sysconfig
# if sys.version contains GCC then python was compiled with GCC, and the
# pyconfig.h file should be OK
if "GCC" in sys.version:
return CONFIG_H_OK, "sys.version mentions 'GCC'"
# Clang would also work
if "Clang" in sys.version:
return CONFIG_H_OK, "sys.version mentions 'Clang'"
# let's see if __GNUC__ is mentioned in python.h
fn = sysconfig.get_config_h_filename()
try:
config_h = open(fn)
try:
if "__GNUC__" in config_h.read():
return CONFIG_H_OK, "'%s' mentions '__GNUC__'" % fn
else:
return CONFIG_H_NOTOK, "'%s' does not mention '__GNUC__'" % fn
finally:
config_h.close()
except OSError as exc:
return (CONFIG_H_UNCERTAIN, "couldn't read '{}': {}".format(fn, exc.strerror))
def is_cygwincc(cc):
'''Try to determine if the compiler that would be used is from cygwin.'''
out_string = check_output(shlex.split(cc) + ['-dumpmachine'])
return out_string.strip().endswith(b'cygwin')
get_versions = None
"""
A stand-in for the previous get_versions() function to prevent failures
when monkeypatched. See pypa/setuptools#2969.
"""
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/cygwinccompiler.py
|
Python
|
mit
| 12,537 |
import os
# If DISTUTILS_DEBUG is anything other than the empty string, we run in
# debug mode.
DEBUG = os.environ.get('DISTUTILS_DEBUG')
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/debug.py
|
Python
|
mit
| 139 |
"""distutils.dep_util
Utility functions for simple, timestamp-based dependency of files
and groups of files; also, function based entirely on such
timestamp dependency analysis."""
import os
from distutils.errors import DistutilsFileError
def newer(source, target):
"""Return true if 'source' exists and is more recently modified than
'target', or if 'source' exists and 'target' doesn't. Return false if
both exist and 'target' is the same age or younger than 'source'.
Raise DistutilsFileError if 'source' does not exist.
"""
if not os.path.exists(source):
raise DistutilsFileError("file '%s' does not exist" % os.path.abspath(source))
if not os.path.exists(target):
return 1
from stat import ST_MTIME
mtime1 = os.stat(source)[ST_MTIME]
mtime2 = os.stat(target)[ST_MTIME]
return mtime1 > mtime2
# newer ()
def newer_pairwise(sources, targets):
"""Walk two filename lists in parallel, testing if each source is newer
than its corresponding target. Return a pair of lists (sources,
targets) where source is newer than target, according to the semantics
of 'newer()'.
"""
if len(sources) != len(targets):
raise ValueError("'sources' and 'targets' must be same length")
# build a pair of lists (sources, targets) where source is newer
n_sources = []
n_targets = []
for i in range(len(sources)):
if newer(sources[i], targets[i]):
n_sources.append(sources[i])
n_targets.append(targets[i])
return (n_sources, n_targets)
# newer_pairwise ()
def newer_group(sources, target, missing='error'):
"""Return true if 'target' is out-of-date with respect to any file
listed in 'sources'. In other words, if 'target' exists and is newer
than every file in 'sources', return false; otherwise return true.
'missing' controls what we do when a source file is missing; the
default ("error") is to blow up with an OSError from inside 'stat()';
if it is "ignore", we silently drop any missing source files; if it is
"newer", any missing source files make us assume that 'target' is
out-of-date (this is handy in "dry-run" mode: it'll make you pretend to
carry out commands that wouldn't work because inputs are missing, but
that doesn't matter because you're not actually going to run the
commands).
"""
# If the target doesn't even exist, then it's definitely out-of-date.
if not os.path.exists(target):
return 1
# Otherwise we have to find out the hard way: if *any* source file
# is more recent than 'target', then 'target' is out-of-date and
# we can immediately return true. If we fall through to the end
# of the loop, then 'target' is up-to-date and we return false.
from stat import ST_MTIME
target_mtime = os.stat(target)[ST_MTIME]
for source in sources:
if not os.path.exists(source):
if missing == 'error': # blow up when we stat() the file
pass
elif missing == 'ignore': # missing source dropped from
continue # target's dependency list
elif missing == 'newer': # missing source means target is
return 1 # out-of-date
source_mtime = os.stat(source)[ST_MTIME]
if source_mtime > target_mtime:
return 1
else:
return 0
# newer_group ()
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/dep_util.py
|
Python
|
mit
| 3,423 |
"""distutils.dir_util
Utility functions for manipulating directories and directory trees."""
import os
import errno
from distutils.errors import DistutilsInternalError, DistutilsFileError
from distutils import log
# cache for by mkpath() -- in addition to cheapening redundant calls,
# eliminates redundant "creating /foo/bar/baz" messages in dry-run mode
_path_created = {}
def mkpath(name, mode=0o777, verbose=1, dry_run=0): # noqa: C901
"""Create a directory and any missing ancestor directories.
If the directory already exists (or if 'name' is the empty string, which
means the current directory, which of course exists), then do nothing.
Raise DistutilsFileError if unable to create some directory along the way
(eg. some sub-path exists, but is a file rather than a directory).
If 'verbose' is true, print a one-line summary of each mkdir to stdout.
Return the list of directories actually created.
os.makedirs is not used because:
a) It's new to Python 1.5.2, and
b) it blows up if the directory already exists (in which case it should
silently succeed).
"""
global _path_created
# Detect a common bug -- name is None
if not isinstance(name, str):
raise DistutilsInternalError(
"mkpath: 'name' must be a string (got {!r})".format(name)
)
# XXX what's the better way to handle verbosity? print as we create
# each directory in the path (the current behaviour), or only announce
# the creation of the whole path? (quite easy to do the latter since
# we're not using a recursive algorithm)
name = os.path.normpath(name)
created_dirs = []
if os.path.isdir(name) or name == '':
return created_dirs
if _path_created.get(os.path.abspath(name)):
return created_dirs
(head, tail) = os.path.split(name)
tails = [tail] # stack of lone dirs to create
while head and tail and not os.path.isdir(head):
(head, tail) = os.path.split(head)
tails.insert(0, tail) # push next higher dir onto stack
# now 'head' contains the deepest directory that already exists
# (that is, the child of 'head' in 'name' is the highest directory
# that does *not* exist)
for d in tails:
# print "head = %s, d = %s: " % (head, d),
head = os.path.join(head, d)
abs_head = os.path.abspath(head)
if _path_created.get(abs_head):
continue
if verbose >= 1:
log.info("creating %s", head)
if not dry_run:
try:
os.mkdir(head, mode)
except OSError as exc:
if not (exc.errno == errno.EEXIST and os.path.isdir(head)):
raise DistutilsFileError(
"could not create '{}': {}".format(head, exc.args[-1])
)
created_dirs.append(head)
_path_created[abs_head] = 1
return created_dirs
def create_tree(base_dir, files, mode=0o777, verbose=1, dry_run=0):
"""Create all the empty directories under 'base_dir' needed to put 'files'
there.
'base_dir' is just the name of a directory which doesn't necessarily
exist yet; 'files' is a list of filenames to be interpreted relative to
'base_dir'. 'base_dir' + the directory portion of every file in 'files'
will be created if it doesn't already exist. 'mode', 'verbose' and
'dry_run' flags are as for 'mkpath()'.
"""
# First get the list of directories to create
need_dir = set()
for file in files:
need_dir.add(os.path.join(base_dir, os.path.dirname(file)))
# Now create them
for dir in sorted(need_dir):
mkpath(dir, mode, verbose=verbose, dry_run=dry_run)
def copy_tree( # noqa: C901
src,
dst,
preserve_mode=1,
preserve_times=1,
preserve_symlinks=0,
update=0,
verbose=1,
dry_run=0,
):
"""Copy an entire directory tree 'src' to a new location 'dst'.
Both 'src' and 'dst' must be directory names. If 'src' is not a
directory, raise DistutilsFileError. If 'dst' does not exist, it is
created with 'mkpath()'. The end result of the copy is that every
file in 'src' is copied to 'dst', and directories under 'src' are
recursively copied to 'dst'. Return the list of files that were
copied or might have been copied, using their output name. The
return value is unaffected by 'update' or 'dry_run': it is simply
the list of all files under 'src', with the names changed to be
under 'dst'.
'preserve_mode' and 'preserve_times' are the same as for
'copy_file'; note that they only apply to regular files, not to
directories. If 'preserve_symlinks' is true, symlinks will be
copied as symlinks (on platforms that support them!); otherwise
(the default), the destination of the symlink will be copied.
'update' and 'verbose' are the same as for 'copy_file'.
"""
from distutils.file_util import copy_file
if not dry_run and not os.path.isdir(src):
raise DistutilsFileError("cannot copy tree '%s': not a directory" % src)
try:
names = os.listdir(src)
except OSError as e:
if dry_run:
names = []
else:
raise DistutilsFileError(
"error listing files in '{}': {}".format(src, e.strerror)
)
if not dry_run:
mkpath(dst, verbose=verbose)
outputs = []
for n in names:
src_name = os.path.join(src, n)
dst_name = os.path.join(dst, n)
if n.startswith('.nfs'):
# skip NFS rename files
continue
if preserve_symlinks and os.path.islink(src_name):
link_dest = os.readlink(src_name)
if verbose >= 1:
log.info("linking %s -> %s", dst_name, link_dest)
if not dry_run:
os.symlink(link_dest, dst_name)
outputs.append(dst_name)
elif os.path.isdir(src_name):
outputs.extend(
copy_tree(
src_name,
dst_name,
preserve_mode,
preserve_times,
preserve_symlinks,
update,
verbose=verbose,
dry_run=dry_run,
)
)
else:
copy_file(
src_name,
dst_name,
preserve_mode,
preserve_times,
update,
verbose=verbose,
dry_run=dry_run,
)
outputs.append(dst_name)
return outputs
def _build_cmdtuple(path, cmdtuples):
"""Helper for remove_tree()."""
for f in os.listdir(path):
real_f = os.path.join(path, f)
if os.path.isdir(real_f) and not os.path.islink(real_f):
_build_cmdtuple(real_f, cmdtuples)
else:
cmdtuples.append((os.remove, real_f))
cmdtuples.append((os.rmdir, path))
def remove_tree(directory, verbose=1, dry_run=0):
"""Recursively remove an entire directory tree.
Any errors are ignored (apart from being reported to stdout if 'verbose'
is true).
"""
global _path_created
if verbose >= 1:
log.info("removing '%s' (and everything under it)", directory)
if dry_run:
return
cmdtuples = []
_build_cmdtuple(directory, cmdtuples)
for cmd in cmdtuples:
try:
cmd[0](cmd[1])
# remove dir from cache if it's already there
abspath = os.path.abspath(cmd[1])
if abspath in _path_created:
del _path_created[abspath]
except OSError as exc:
log.warn("error removing %s: %s", directory, exc)
def ensure_relative(path):
"""Take the full path 'path', and make it a relative path.
This is useful to make 'path' the second argument to os.path.join().
"""
drive, path = os.path.splitdrive(path)
if path[0:1] == os.sep:
path = drive + path[1:]
return path
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/dir_util.py
|
Python
|
mit
| 8,082 |
"""distutils.dist
Provides the Distribution class, which represents the module distribution
being built/installed/distributed.
"""
import sys
import os
import re
import pathlib
import contextlib
from email import message_from_file
try:
import warnings
except ImportError:
warnings = None
from distutils.errors import (
DistutilsOptionError,
DistutilsModuleError,
DistutilsArgError,
DistutilsClassError,
)
from distutils.fancy_getopt import FancyGetopt, translate_longopt
from distutils.util import check_environ, strtobool, rfc822_escape
from distutils import log
from distutils.debug import DEBUG
# Regex to define acceptable Distutils command names. This is not *quite*
# the same as a Python NAME -- I don't allow leading underscores. The fact
# that they're very similar is no coincidence; the default naming scheme is
# to look for a Python module named after the command.
command_re = re.compile(r'^[a-zA-Z]([a-zA-Z0-9_]*)$')
def _ensure_list(value, fieldname):
if isinstance(value, str):
# a string containing comma separated values is okay. It will
# be converted to a list by Distribution.finalize_options().
pass
elif not isinstance(value, list):
# passing a tuple or an iterator perhaps, warn and convert
typename = type(value).__name__
msg = "Warning: '{fieldname}' should be a list, got type '{typename}'"
msg = msg.format(**locals())
log.log(log.WARN, msg)
value = list(value)
return value
class Distribution:
"""The core of the Distutils. Most of the work hiding behind 'setup'
is really done within a Distribution instance, which farms the work out
to the Distutils commands specified on the command line.
Setup scripts will almost never instantiate Distribution directly,
unless the 'setup()' function is totally inadequate to their needs.
However, it is conceivable that a setup script might wish to subclass
Distribution for some specialized purpose, and then pass the subclass
to 'setup()' as the 'distclass' keyword argument. If so, it is
necessary to respect the expectations that 'setup' has of Distribution.
See the code for 'setup()', in core.py, for details.
"""
# 'global_options' describes the command-line options that may be
# supplied to the setup script prior to any actual commands.
# Eg. "./setup.py -n" or "./setup.py --quiet" both take advantage of
# these global options. This list should be kept to a bare minimum,
# since every global option is also valid as a command option -- and we
# don't want to pollute the commands with too many options that they
# have minimal control over.
# The fourth entry for verbose means that it can be repeated.
global_options = [
('verbose', 'v', "run verbosely (default)", 1),
('quiet', 'q', "run quietly (turns verbosity off)"),
('dry-run', 'n', "don't actually do anything"),
('help', 'h', "show detailed help message"),
('no-user-cfg', None, 'ignore pydistutils.cfg in your home directory'),
]
# 'common_usage' is a short (2-3 line) string describing the common
# usage of the setup script.
common_usage = """\
Common commands: (see '--help-commands' for more)
setup.py build will build the package underneath 'build/'
setup.py install will install the package
"""
# options that are not propagated to the commands
display_options = [
('help-commands', None, "list all available commands"),
('name', None, "print package name"),
('version', 'V', "print package version"),
('fullname', None, "print <package name>-<version>"),
('author', None, "print the author's name"),
('author-email', None, "print the author's email address"),
('maintainer', None, "print the maintainer's name"),
('maintainer-email', None, "print the maintainer's email address"),
('contact', None, "print the maintainer's name if known, else the author's"),
(
'contact-email',
None,
"print the maintainer's email address if known, else the author's",
),
('url', None, "print the URL for this package"),
('license', None, "print the license of the package"),
('licence', None, "alias for --license"),
('description', None, "print the package description"),
('long-description', None, "print the long package description"),
('platforms', None, "print the list of platforms"),
('classifiers', None, "print the list of classifiers"),
('keywords', None, "print the list of keywords"),
('provides', None, "print the list of packages/modules provided"),
('requires', None, "print the list of packages/modules required"),
('obsoletes', None, "print the list of packages/modules made obsolete"),
]
display_option_names = [translate_longopt(x[0]) for x in display_options]
# negative options are options that exclude other options
negative_opt = {'quiet': 'verbose'}
# -- Creation/initialization methods -------------------------------
def __init__(self, attrs=None): # noqa: C901
"""Construct a new Distribution instance: initialize all the
attributes of a Distribution, and then use 'attrs' (a dictionary
mapping attribute names to values) to assign some of those
attributes their "real" values. (Any attributes not mentioned in
'attrs' will be assigned to some null value: 0, None, an empty list
or dictionary, etc.) Most importantly, initialize the
'command_obj' attribute to the empty dictionary; this will be
filled in with real command objects by 'parse_command_line()'.
"""
# Default values for our command-line options
self.verbose = 1
self.dry_run = 0
self.help = 0
for attr in self.display_option_names:
setattr(self, attr, 0)
# Store the distribution meta-data (name, version, author, and so
# forth) in a separate object -- we're getting to have enough
# information here (and enough command-line options) that it's
# worth it. Also delegate 'get_XXX()' methods to the 'metadata'
# object in a sneaky and underhanded (but efficient!) way.
self.metadata = DistributionMetadata()
for basename in self.metadata._METHOD_BASENAMES:
method_name = "get_" + basename
setattr(self, method_name, getattr(self.metadata, method_name))
# 'cmdclass' maps command names to class objects, so we
# can 1) quickly figure out which class to instantiate when
# we need to create a new command object, and 2) have a way
# for the setup script to override command classes
self.cmdclass = {}
# 'command_packages' is a list of packages in which commands
# are searched for. The factory for command 'foo' is expected
# to be named 'foo' in the module 'foo' in one of the packages
# named here. This list is searched from the left; an error
# is raised if no named package provides the command being
# searched for. (Always access using get_command_packages().)
self.command_packages = None
# 'script_name' and 'script_args' are usually set to sys.argv[0]
# and sys.argv[1:], but they can be overridden when the caller is
# not necessarily a setup script run from the command-line.
self.script_name = None
self.script_args = None
# 'command_options' is where we store command options between
# parsing them (from config files, the command-line, etc.) and when
# they are actually needed -- ie. when the command in question is
# instantiated. It is a dictionary of dictionaries of 2-tuples:
# command_options = { command_name : { option : (source, value) } }
self.command_options = {}
# 'dist_files' is the list of (command, pyversion, file) that
# have been created by any dist commands run so far. This is
# filled regardless of whether the run is dry or not. pyversion
# gives sysconfig.get_python_version() if the dist file is
# specific to a Python version, 'any' if it is good for all
# Python versions on the target platform, and '' for a source
# file. pyversion should not be used to specify minimum or
# maximum required Python versions; use the metainfo for that
# instead.
self.dist_files = []
# These options are really the business of various commands, rather
# than of the Distribution itself. We provide aliases for them in
# Distribution as a convenience to the developer.
self.packages = None
self.package_data = {}
self.package_dir = None
self.py_modules = None
self.libraries = None
self.headers = None
self.ext_modules = None
self.ext_package = None
self.include_dirs = None
self.extra_path = None
self.scripts = None
self.data_files = None
self.password = ''
# And now initialize bookkeeping stuff that can't be supplied by
# the caller at all. 'command_obj' maps command names to
# Command instances -- that's how we enforce that every command
# class is a singleton.
self.command_obj = {}
# 'have_run' maps command names to boolean values; it keeps track
# of whether we have actually run a particular command, to make it
# cheap to "run" a command whenever we think we might need to -- if
# it's already been done, no need for expensive filesystem
# operations, we just check the 'have_run' dictionary and carry on.
# It's only safe to query 'have_run' for a command class that has
# been instantiated -- a false value will be inserted when the
# command object is created, and replaced with a true value when
# the command is successfully run. Thus it's probably best to use
# '.get()' rather than a straight lookup.
self.have_run = {}
# Now we'll use the attrs dictionary (ultimately, keyword args from
# the setup script) to possibly override any or all of these
# distribution options.
if attrs:
# Pull out the set of command options and work on them
# specifically. Note that this order guarantees that aliased
# command options will override any supplied redundantly
# through the general options dictionary.
options = attrs.get('options')
if options is not None:
del attrs['options']
for (command, cmd_options) in options.items():
opt_dict = self.get_option_dict(command)
for (opt, val) in cmd_options.items():
opt_dict[opt] = ("setup script", val)
if 'licence' in attrs:
attrs['license'] = attrs['licence']
del attrs['licence']
msg = "'licence' distribution option is deprecated; use 'license'"
if warnings is not None:
warnings.warn(msg)
else:
sys.stderr.write(msg + "\n")
# Now work on the rest of the attributes. Any attribute that's
# not already defined is invalid!
for (key, val) in attrs.items():
if hasattr(self.metadata, "set_" + key):
getattr(self.metadata, "set_" + key)(val)
elif hasattr(self.metadata, key):
setattr(self.metadata, key, val)
elif hasattr(self, key):
setattr(self, key, val)
else:
msg = "Unknown distribution option: %s" % repr(key)
warnings.warn(msg)
# no-user-cfg is handled before other command line args
# because other args override the config files, and this
# one is needed before we can load the config files.
# If attrs['script_args'] wasn't passed, assume false.
#
# This also make sure we just look at the global options
self.want_user_cfg = True
if self.script_args is not None:
for arg in self.script_args:
if not arg.startswith('-'):
break
if arg == '--no-user-cfg':
self.want_user_cfg = False
break
self.finalize_options()
def get_option_dict(self, command):
"""Get the option dictionary for a given command. If that
command's option dictionary hasn't been created yet, then create it
and return the new dictionary; otherwise, return the existing
option dictionary.
"""
dict = self.command_options.get(command)
if dict is None:
dict = self.command_options[command] = {}
return dict
def dump_option_dicts(self, header=None, commands=None, indent=""):
from pprint import pformat
if commands is None: # dump all command option dicts
commands = sorted(self.command_options.keys())
if header is not None:
self.announce(indent + header)
indent = indent + " "
if not commands:
self.announce(indent + "no commands known yet")
return
for cmd_name in commands:
opt_dict = self.command_options.get(cmd_name)
if opt_dict is None:
self.announce(indent + "no option dict for '%s' command" % cmd_name)
else:
self.announce(indent + "option dict for '%s' command:" % cmd_name)
out = pformat(opt_dict)
for line in out.split('\n'):
self.announce(indent + " " + line)
# -- Config file finding/parsing methods ---------------------------
def find_config_files(self):
"""Find as many configuration files as should be processed for this
platform, and return a list of filenames in the order in which they
should be parsed. The filenames returned are guaranteed to exist
(modulo nasty race conditions).
There are multiple possible config files:
- distutils.cfg in the Distutils installation directory (i.e.
where the top-level Distutils __inst__.py file lives)
- a file in the user's home directory named .pydistutils.cfg
on Unix and pydistutils.cfg on Windows/Mac; may be disabled
with the ``--no-user-cfg`` option
- setup.cfg in the current directory
- a file named by an environment variable
"""
check_environ()
files = [str(path) for path in self._gen_paths() if os.path.isfile(path)]
if DEBUG:
self.announce("using config files: %s" % ', '.join(files))
return files
def _gen_paths(self):
# The system-wide Distutils config file
sys_dir = pathlib.Path(sys.modules['distutils'].__file__).parent
yield sys_dir / "distutils.cfg"
# The per-user config file
prefix = '.' * (os.name == 'posix')
filename = prefix + 'pydistutils.cfg'
if self.want_user_cfg:
yield pathlib.Path('~').expanduser() / filename
# All platforms support local setup.cfg
yield pathlib.Path('setup.cfg')
# Additional config indicated in the environment
with contextlib.suppress(TypeError):
yield pathlib.Path(os.getenv("DIST_EXTRA_CONFIG"))
def parse_config_files(self, filenames=None): # noqa: C901
from configparser import ConfigParser
# Ignore install directory options if we have a venv
if sys.prefix != sys.base_prefix:
ignore_options = [
'install-base',
'install-platbase',
'install-lib',
'install-platlib',
'install-purelib',
'install-headers',
'install-scripts',
'install-data',
'prefix',
'exec-prefix',
'home',
'user',
'root',
]
else:
ignore_options = []
ignore_options = frozenset(ignore_options)
if filenames is None:
filenames = self.find_config_files()
if DEBUG:
self.announce("Distribution.parse_config_files():")
parser = ConfigParser()
for filename in filenames:
if DEBUG:
self.announce(" reading %s" % filename)
parser.read(filename)
for section in parser.sections():
options = parser.options(section)
opt_dict = self.get_option_dict(section)
for opt in options:
if opt != '__name__' and opt not in ignore_options:
val = parser.get(section, opt)
opt = opt.replace('-', '_')
opt_dict[opt] = (filename, val)
# Make the ConfigParser forget everything (so we retain
# the original filenames that options come from)
parser.__init__()
# If there was a "global" section in the config file, use it
# to set Distribution options.
if 'global' in self.command_options:
for (opt, (src, val)) in self.command_options['global'].items():
alias = self.negative_opt.get(opt)
try:
if alias:
setattr(self, alias, not strtobool(val))
elif opt in ('verbose', 'dry_run'): # ugh!
setattr(self, opt, strtobool(val))
else:
setattr(self, opt, val)
except ValueError as msg:
raise DistutilsOptionError(msg)
# -- Command-line parsing methods ----------------------------------
def parse_command_line(self):
"""Parse the setup script's command line, taken from the
'script_args' instance attribute (which defaults to 'sys.argv[1:]'
-- see 'setup()' in core.py). This list is first processed for
"global options" -- options that set attributes of the Distribution
instance. Then, it is alternately scanned for Distutils commands
and options for that command. Each new command terminates the
options for the previous command. The allowed options for a
command are determined by the 'user_options' attribute of the
command class -- thus, we have to be able to load command classes
in order to parse the command line. Any error in that 'options'
attribute raises DistutilsGetoptError; any error on the
command-line raises DistutilsArgError. If no Distutils commands
were found on the command line, raises DistutilsArgError. Return
true if command-line was successfully parsed and we should carry
on with executing commands; false if no errors but we shouldn't
execute commands (currently, this only happens if user asks for
help).
"""
#
# We now have enough information to show the Macintosh dialog
# that allows the user to interactively specify the "command line".
#
toplevel_options = self._get_toplevel_options()
# We have to parse the command line a bit at a time -- global
# options, then the first command, then its options, and so on --
# because each command will be handled by a different class, and
# the options that are valid for a particular class aren't known
# until we have loaded the command class, which doesn't happen
# until we know what the command is.
self.commands = []
parser = FancyGetopt(toplevel_options + self.display_options)
parser.set_negative_aliases(self.negative_opt)
parser.set_aliases({'licence': 'license'})
args = parser.getopt(args=self.script_args, object=self)
option_order = parser.get_option_order()
log.set_verbosity(self.verbose)
# for display options we return immediately
if self.handle_display_options(option_order):
return
while args:
args = self._parse_command_opts(parser, args)
if args is None: # user asked for help (and got it)
return
# Handle the cases of --help as a "global" option, ie.
# "setup.py --help" and "setup.py --help command ...". For the
# former, we show global options (--verbose, --dry-run, etc.)
# and display-only options (--name, --version, etc.); for the
# latter, we omit the display-only options and show help for
# each command listed on the command line.
if self.help:
self._show_help(
parser, display_options=len(self.commands) == 0, commands=self.commands
)
return
# Oops, no commands found -- an end-user error
if not self.commands:
raise DistutilsArgError("no commands supplied")
# All is well: return true
return True
def _get_toplevel_options(self):
"""Return the non-display options recognized at the top level.
This includes options that are recognized *only* at the top
level as well as options recognized for commands.
"""
return self.global_options + [
(
"command-packages=",
None,
"list of packages that provide distutils commands",
),
]
def _parse_command_opts(self, parser, args): # noqa: C901
"""Parse the command-line options for a single command.
'parser' must be a FancyGetopt instance; 'args' must be the list
of arguments, starting with the current command (whose options
we are about to parse). Returns a new version of 'args' with
the next command at the front of the list; will be the empty
list if there are no more commands on the command line. Returns
None if the user asked for help on this command.
"""
# late import because of mutual dependence between these modules
from distutils.cmd import Command
# Pull the current command from the head of the command line
command = args[0]
if not command_re.match(command):
raise SystemExit("invalid command name '%s'" % command)
self.commands.append(command)
# Dig up the command class that implements this command, so we
# 1) know that it's a valid command, and 2) know which options
# it takes.
try:
cmd_class = self.get_command_class(command)
except DistutilsModuleError as msg:
raise DistutilsArgError(msg)
# Require that the command class be derived from Command -- want
# to be sure that the basic "command" interface is implemented.
if not issubclass(cmd_class, Command):
raise DistutilsClassError(
"command class %s must subclass Command" % cmd_class
)
# Also make sure that the command object provides a list of its
# known options.
if not (
hasattr(cmd_class, 'user_options')
and isinstance(cmd_class.user_options, list)
):
msg = (
"command class %s must provide "
"'user_options' attribute (a list of tuples)"
)
raise DistutilsClassError(msg % cmd_class)
# If the command class has a list of negative alias options,
# merge it in with the global negative aliases.
negative_opt = self.negative_opt
if hasattr(cmd_class, 'negative_opt'):
negative_opt = negative_opt.copy()
negative_opt.update(cmd_class.negative_opt)
# Check for help_options in command class. They have a different
# format (tuple of four) so we need to preprocess them here.
if hasattr(cmd_class, 'help_options') and isinstance(
cmd_class.help_options, list
):
help_options = fix_help_options(cmd_class.help_options)
else:
help_options = []
# All commands support the global options too, just by adding
# in 'global_options'.
parser.set_option_table(
self.global_options + cmd_class.user_options + help_options
)
parser.set_negative_aliases(negative_opt)
(args, opts) = parser.getopt(args[1:])
if hasattr(opts, 'help') and opts.help:
self._show_help(parser, display_options=0, commands=[cmd_class])
return
if hasattr(cmd_class, 'help_options') and isinstance(
cmd_class.help_options, list
):
help_option_found = 0
for (help_option, short, desc, func) in cmd_class.help_options:
if hasattr(opts, parser.get_attr_name(help_option)):
help_option_found = 1
if callable(func):
func()
else:
raise DistutilsClassError(
"invalid help function %r for help option '%s': "
"must be a callable object (function, etc.)"
% (func, help_option)
)
if help_option_found:
return
# Put the options from the command-line into their official
# holding pen, the 'command_options' dictionary.
opt_dict = self.get_option_dict(command)
for (name, value) in vars(opts).items():
opt_dict[name] = ("command line", value)
return args
def finalize_options(self):
"""Set final values for all the options on the Distribution
instance, analogous to the .finalize_options() method of Command
objects.
"""
for attr in ('keywords', 'platforms'):
value = getattr(self.metadata, attr)
if value is None:
continue
if isinstance(value, str):
value = [elm.strip() for elm in value.split(',')]
setattr(self.metadata, attr, value)
def _show_help(self, parser, global_options=1, display_options=1, commands=[]):
"""Show help for the setup script command-line in the form of
several lists of command-line options. 'parser' should be a
FancyGetopt instance; do not expect it to be returned in the
same state, as its option table will be reset to make it
generate the correct help text.
If 'global_options' is true, lists the global options:
--verbose, --dry-run, etc. If 'display_options' is true, lists
the "display-only" options: --name, --version, etc. Finally,
lists per-command help for every command name or command class
in 'commands'.
"""
# late import because of mutual dependence between these modules
from distutils.core import gen_usage
from distutils.cmd import Command
if global_options:
if display_options:
options = self._get_toplevel_options()
else:
options = self.global_options
parser.set_option_table(options)
parser.print_help(self.common_usage + "\nGlobal options:")
print('')
if display_options:
parser.set_option_table(self.display_options)
parser.print_help(
"Information display options (just display "
+ "information, ignore any commands)"
)
print('')
for command in self.commands:
if isinstance(command, type) and issubclass(command, Command):
klass = command
else:
klass = self.get_command_class(command)
if hasattr(klass, 'help_options') and isinstance(klass.help_options, list):
parser.set_option_table(
klass.user_options + fix_help_options(klass.help_options)
)
else:
parser.set_option_table(klass.user_options)
parser.print_help("Options for '%s' command:" % klass.__name__)
print('')
print(gen_usage(self.script_name))
def handle_display_options(self, option_order):
"""If there were any non-global "display-only" options
(--help-commands or the metadata display options) on the command
line, display the requested info and return true; else return
false.
"""
from distutils.core import gen_usage
# User just wants a list of commands -- we'll print it out and stop
# processing now (ie. if they ran "setup --help-commands foo bar",
# we ignore "foo bar").
if self.help_commands:
self.print_commands()
print('')
print(gen_usage(self.script_name))
return 1
# If user supplied any of the "display metadata" options, then
# display that metadata in the order in which the user supplied the
# metadata options.
any_display_options = 0
is_display_option = {}
for option in self.display_options:
is_display_option[option[0]] = 1
for (opt, val) in option_order:
if val and is_display_option.get(opt):
opt = translate_longopt(opt)
value = getattr(self.metadata, "get_" + opt)()
if opt in ['keywords', 'platforms']:
print(','.join(value))
elif opt in ('classifiers', 'provides', 'requires', 'obsoletes'):
print('\n'.join(value))
else:
print(value)
any_display_options = 1
return any_display_options
def print_command_list(self, commands, header, max_length):
"""Print a subset of the list of all commands -- used by
'print_commands()'.
"""
print(header + ":")
for cmd in commands:
klass = self.cmdclass.get(cmd)
if not klass:
klass = self.get_command_class(cmd)
try:
description = klass.description
except AttributeError:
description = "(no description available)"
print(" %-*s %s" % (max_length, cmd, description))
def print_commands(self):
"""Print out a help message listing all available commands with a
description of each. The list is divided into "standard commands"
(listed in distutils.command.__all__) and "extra commands"
(mentioned in self.cmdclass, but not a standard command). The
descriptions come from the command class attribute
'description'.
"""
import distutils.command
std_commands = distutils.command.__all__
is_std = {}
for cmd in std_commands:
is_std[cmd] = 1
extra_commands = []
for cmd in self.cmdclass.keys():
if not is_std.get(cmd):
extra_commands.append(cmd)
max_length = 0
for cmd in std_commands + extra_commands:
if len(cmd) > max_length:
max_length = len(cmd)
self.print_command_list(std_commands, "Standard commands", max_length)
if extra_commands:
print()
self.print_command_list(extra_commands, "Extra commands", max_length)
def get_command_list(self):
"""Get a list of (command, description) tuples.
The list is divided into "standard commands" (listed in
distutils.command.__all__) and "extra commands" (mentioned in
self.cmdclass, but not a standard command). The descriptions come
from the command class attribute 'description'.
"""
# Currently this is only used on Mac OS, for the Mac-only GUI
# Distutils interface (by Jack Jansen)
import distutils.command
std_commands = distutils.command.__all__
is_std = {}
for cmd in std_commands:
is_std[cmd] = 1
extra_commands = []
for cmd in self.cmdclass.keys():
if not is_std.get(cmd):
extra_commands.append(cmd)
rv = []
for cmd in std_commands + extra_commands:
klass = self.cmdclass.get(cmd)
if not klass:
klass = self.get_command_class(cmd)
try:
description = klass.description
except AttributeError:
description = "(no description available)"
rv.append((cmd, description))
return rv
# -- Command class/object methods ----------------------------------
def get_command_packages(self):
"""Return a list of packages from which commands are loaded."""
pkgs = self.command_packages
if not isinstance(pkgs, list):
if pkgs is None:
pkgs = ''
pkgs = [pkg.strip() for pkg in pkgs.split(',') if pkg != '']
if "distutils.command" not in pkgs:
pkgs.insert(0, "distutils.command")
self.command_packages = pkgs
return pkgs
def get_command_class(self, command):
"""Return the class that implements the Distutils command named by
'command'. First we check the 'cmdclass' dictionary; if the
command is mentioned there, we fetch the class object from the
dictionary and return it. Otherwise we load the command module
("distutils.command." + command) and fetch the command class from
the module. The loaded class is also stored in 'cmdclass'
to speed future calls to 'get_command_class()'.
Raises DistutilsModuleError if the expected module could not be
found, or if that module does not define the expected class.
"""
klass = self.cmdclass.get(command)
if klass:
return klass
for pkgname in self.get_command_packages():
module_name = "{}.{}".format(pkgname, command)
klass_name = command
try:
__import__(module_name)
module = sys.modules[module_name]
except ImportError:
continue
try:
klass = getattr(module, klass_name)
except AttributeError:
raise DistutilsModuleError(
"invalid command '%s' (no class '%s' in module '%s')"
% (command, klass_name, module_name)
)
self.cmdclass[command] = klass
return klass
raise DistutilsModuleError("invalid command '%s'" % command)
def get_command_obj(self, command, create=1):
"""Return the command object for 'command'. Normally this object
is cached on a previous call to 'get_command_obj()'; if no command
object for 'command' is in the cache, then we either create and
return it (if 'create' is true) or return None.
"""
cmd_obj = self.command_obj.get(command)
if not cmd_obj and create:
if DEBUG:
self.announce(
"Distribution.get_command_obj(): "
"creating '%s' command object" % command
)
klass = self.get_command_class(command)
cmd_obj = self.command_obj[command] = klass(self)
self.have_run[command] = 0
# Set any options that were supplied in config files
# or on the command line. (NB. support for error
# reporting is lame here: any errors aren't reported
# until 'finalize_options()' is called, which means
# we won't report the source of the error.)
options = self.command_options.get(command)
if options:
self._set_command_options(cmd_obj, options)
return cmd_obj
def _set_command_options(self, command_obj, option_dict=None): # noqa: C901
"""Set the options for 'command_obj' from 'option_dict'. Basically
this means copying elements of a dictionary ('option_dict') to
attributes of an instance ('command').
'command_obj' must be a Command instance. If 'option_dict' is not
supplied, uses the standard option dictionary for this command
(from 'self.command_options').
"""
command_name = command_obj.get_command_name()
if option_dict is None:
option_dict = self.get_option_dict(command_name)
if DEBUG:
self.announce(" setting options for '%s' command:" % command_name)
for (option, (source, value)) in option_dict.items():
if DEBUG:
self.announce(" {} = {} (from {})".format(option, value, source))
try:
bool_opts = [translate_longopt(o) for o in command_obj.boolean_options]
except AttributeError:
bool_opts = []
try:
neg_opt = command_obj.negative_opt
except AttributeError:
neg_opt = {}
try:
is_string = isinstance(value, str)
if option in neg_opt and is_string:
setattr(command_obj, neg_opt[option], not strtobool(value))
elif option in bool_opts and is_string:
setattr(command_obj, option, strtobool(value))
elif hasattr(command_obj, option):
setattr(command_obj, option, value)
else:
raise DistutilsOptionError(
"error in %s: command '%s' has no such option '%s'"
% (source, command_name, option)
)
except ValueError as msg:
raise DistutilsOptionError(msg)
def reinitialize_command(self, command, reinit_subcommands=0):
"""Reinitializes a command to the state it was in when first
returned by 'get_command_obj()': ie., initialized but not yet
finalized. This provides the opportunity to sneak option
values in programmatically, overriding or supplementing
user-supplied values from the config files and command line.
You'll have to re-finalize the command object (by calling
'finalize_options()' or 'ensure_finalized()') before using it for
real.
'command' should be a command name (string) or command object. If
'reinit_subcommands' is true, also reinitializes the command's
sub-commands, as declared by the 'sub_commands' class attribute (if
it has one). See the "install" command for an example. Only
reinitializes the sub-commands that actually matter, ie. those
whose test predicates return true.
Returns the reinitialized command object.
"""
from distutils.cmd import Command
if not isinstance(command, Command):
command_name = command
command = self.get_command_obj(command_name)
else:
command_name = command.get_command_name()
if not command.finalized:
return command
command.initialize_options()
command.finalized = 0
self.have_run[command_name] = 0
self._set_command_options(command)
if reinit_subcommands:
for sub in command.get_sub_commands():
self.reinitialize_command(sub, reinit_subcommands)
return command
# -- Methods that operate on the Distribution ----------------------
def announce(self, msg, level=log.INFO):
log.log(level, msg)
def run_commands(self):
"""Run each command that was seen on the setup script command line.
Uses the list of commands found and cache of command objects
created by 'get_command_obj()'.
"""
for cmd in self.commands:
self.run_command(cmd)
# -- Methods that operate on its Commands --------------------------
def run_command(self, command):
"""Do whatever it takes to run a command (including nothing at all,
if the command has already been run). Specifically: if we have
already created and run the command named by 'command', return
silently without doing anything. If the command named by 'command'
doesn't even have a command object yet, create one. Then invoke
'run()' on that command object (or an existing one).
"""
# Already been here, done that? then return silently.
if self.have_run.get(command):
return
log.info("running %s", command)
cmd_obj = self.get_command_obj(command)
cmd_obj.ensure_finalized()
cmd_obj.run()
self.have_run[command] = 1
# -- Distribution query methods ------------------------------------
def has_pure_modules(self):
return len(self.packages or self.py_modules or []) > 0
def has_ext_modules(self):
return self.ext_modules and len(self.ext_modules) > 0
def has_c_libraries(self):
return self.libraries and len(self.libraries) > 0
def has_modules(self):
return self.has_pure_modules() or self.has_ext_modules()
def has_headers(self):
return self.headers and len(self.headers) > 0
def has_scripts(self):
return self.scripts and len(self.scripts) > 0
def has_data_files(self):
return self.data_files and len(self.data_files) > 0
def is_pure(self):
return (
self.has_pure_modules()
and not self.has_ext_modules()
and not self.has_c_libraries()
)
# -- Metadata query methods ----------------------------------------
# If you're looking for 'get_name()', 'get_version()', and so forth,
# they are defined in a sneaky way: the constructor binds self.get_XXX
# to self.metadata.get_XXX. The actual code is in the
# DistributionMetadata class, below.
class DistributionMetadata:
"""Dummy class to hold the distribution meta-data: name, version,
author, and so forth.
"""
_METHOD_BASENAMES = (
"name",
"version",
"author",
"author_email",
"maintainer",
"maintainer_email",
"url",
"license",
"description",
"long_description",
"keywords",
"platforms",
"fullname",
"contact",
"contact_email",
"classifiers",
"download_url",
# PEP 314
"provides",
"requires",
"obsoletes",
)
def __init__(self, path=None):
if path is not None:
self.read_pkg_file(open(path))
else:
self.name = None
self.version = None
self.author = None
self.author_email = None
self.maintainer = None
self.maintainer_email = None
self.url = None
self.license = None
self.description = None
self.long_description = None
self.keywords = None
self.platforms = None
self.classifiers = None
self.download_url = None
# PEP 314
self.provides = None
self.requires = None
self.obsoletes = None
def read_pkg_file(self, file):
"""Reads the metadata values from a file object."""
msg = message_from_file(file)
def _read_field(name):
value = msg[name]
if value and value != "UNKNOWN":
return value
def _read_list(name):
values = msg.get_all(name, None)
if values == []:
return None
return values
metadata_version = msg['metadata-version']
self.name = _read_field('name')
self.version = _read_field('version')
self.description = _read_field('summary')
# we are filling author only.
self.author = _read_field('author')
self.maintainer = None
self.author_email = _read_field('author-email')
self.maintainer_email = None
self.url = _read_field('home-page')
self.license = _read_field('license')
if 'download-url' in msg:
self.download_url = _read_field('download-url')
else:
self.download_url = None
self.long_description = _read_field('description')
self.description = _read_field('summary')
if 'keywords' in msg:
self.keywords = _read_field('keywords').split(',')
self.platforms = _read_list('platform')
self.classifiers = _read_list('classifier')
# PEP 314 - these fields only exist in 1.1
if metadata_version == '1.1':
self.requires = _read_list('requires')
self.provides = _read_list('provides')
self.obsoletes = _read_list('obsoletes')
else:
self.requires = None
self.provides = None
self.obsoletes = None
def write_pkg_info(self, base_dir):
"""Write the PKG-INFO file into the release tree."""
with open(
os.path.join(base_dir, 'PKG-INFO'), 'w', encoding='UTF-8'
) as pkg_info:
self.write_pkg_file(pkg_info)
def write_pkg_file(self, file):
"""Write the PKG-INFO format data to a file object."""
version = '1.0'
if (
self.provides
or self.requires
or self.obsoletes
or self.classifiers
or self.download_url
):
version = '1.1'
# required fields
file.write('Metadata-Version: %s\n' % version)
file.write('Name: %s\n' % self.get_name())
file.write('Version: %s\n' % self.get_version())
def maybe_write(header, val):
if val:
file.write(f"{header}: {val}\n")
# optional fields
maybe_write("Summary", self.get_description())
maybe_write("Home-page", self.get_url())
maybe_write("Author", self.get_contact())
maybe_write("Author-email", self.get_contact_email())
maybe_write("License", self.get_license())
maybe_write("Download-URL", self.download_url)
maybe_write("Description", rfc822_escape(self.get_long_description() or ""))
maybe_write("Keywords", ",".join(self.get_keywords()))
self._write_list(file, 'Platform', self.get_platforms())
self._write_list(file, 'Classifier', self.get_classifiers())
# PEP 314
self._write_list(file, 'Requires', self.get_requires())
self._write_list(file, 'Provides', self.get_provides())
self._write_list(file, 'Obsoletes', self.get_obsoletes())
def _write_list(self, file, name, values):
values = values or []
for value in values:
file.write('{}: {}\n'.format(name, value))
# -- Metadata query methods ----------------------------------------
def get_name(self):
return self.name or "UNKNOWN"
def get_version(self):
return self.version or "0.0.0"
def get_fullname(self):
return "{}-{}".format(self.get_name(), self.get_version())
def get_author(self):
return self.author
def get_author_email(self):
return self.author_email
def get_maintainer(self):
return self.maintainer
def get_maintainer_email(self):
return self.maintainer_email
def get_contact(self):
return self.maintainer or self.author
def get_contact_email(self):
return self.maintainer_email or self.author_email
def get_url(self):
return self.url
def get_license(self):
return self.license
get_licence = get_license
def get_description(self):
return self.description
def get_long_description(self):
return self.long_description
def get_keywords(self):
return self.keywords or []
def set_keywords(self, value):
self.keywords = _ensure_list(value, 'keywords')
def get_platforms(self):
return self.platforms
def set_platforms(self, value):
self.platforms = _ensure_list(value, 'platforms')
def get_classifiers(self):
return self.classifiers or []
def set_classifiers(self, value):
self.classifiers = _ensure_list(value, 'classifiers')
def get_download_url(self):
return self.download_url
# PEP 314
def get_requires(self):
return self.requires or []
def set_requires(self, value):
import distutils.versionpredicate
for v in value:
distutils.versionpredicate.VersionPredicate(v)
self.requires = list(value)
def get_provides(self):
return self.provides or []
def set_provides(self, value):
value = [v.strip() for v in value]
for v in value:
import distutils.versionpredicate
distutils.versionpredicate.split_provision(v)
self.provides = value
def get_obsoletes(self):
return self.obsoletes or []
def set_obsoletes(self, value):
import distutils.versionpredicate
for v in value:
distutils.versionpredicate.VersionPredicate(v)
self.obsoletes = list(value)
def fix_help_options(options):
"""Convert a 4-tuple 'help_options' list as found in various command
classes to the 3-tuple form required by FancyGetopt.
"""
new_options = []
for help_tuple in options:
new_options.append(help_tuple[0:3])
return new_options
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/dist.py
|
Python
|
mit
| 50,186 |
"""distutils.errors
Provides exceptions used by the Distutils modules. Note that Distutils
modules may raise standard exceptions; in particular, SystemExit is
usually raised for errors that are obviously the end-user's fault
(eg. bad command-line arguments).
This module is safe to use in "from ... import *" mode; it only exports
symbols whose names start with "Distutils" and end with "Error"."""
class DistutilsError(Exception):
"""The root of all Distutils evil."""
pass
class DistutilsModuleError(DistutilsError):
"""Unable to load an expected module, or to find an expected class
within some module (in particular, command modules and classes)."""
pass
class DistutilsClassError(DistutilsError):
"""Some command class (or possibly distribution class, if anyone
feels a need to subclass Distribution) is found not to be holding
up its end of the bargain, ie. implementing some part of the
"command "interface."""
pass
class DistutilsGetoptError(DistutilsError):
"""The option table provided to 'fancy_getopt()' is bogus."""
pass
class DistutilsArgError(DistutilsError):
"""Raised by fancy_getopt in response to getopt.error -- ie. an
error in the command line usage."""
pass
class DistutilsFileError(DistutilsError):
"""Any problems in the filesystem: expected file not found, etc.
Typically this is for problems that we detect before OSError
could be raised."""
pass
class DistutilsOptionError(DistutilsError):
"""Syntactic/semantic errors in command options, such as use of
mutually conflicting options, or inconsistent options,
badly-spelled values, etc. No distinction is made between option
values originating in the setup script, the command line, config
files, or what-have-you -- but if we *know* something originated in
the setup script, we'll raise DistutilsSetupError instead."""
pass
class DistutilsSetupError(DistutilsError):
"""For errors that can be definitely blamed on the setup script,
such as invalid keyword arguments to 'setup()'."""
pass
class DistutilsPlatformError(DistutilsError):
"""We don't know how to do something on the current platform (but
we do know how to do it on some platform) -- eg. trying to compile
C files on a platform not supported by a CCompiler subclass."""
pass
class DistutilsExecError(DistutilsError):
"""Any problems executing an external program (such as the C
compiler, when compiling C files)."""
pass
class DistutilsInternalError(DistutilsError):
"""Internal inconsistencies or impossibilities (obviously, this
should never be seen if the code is working!)."""
pass
class DistutilsTemplateError(DistutilsError):
"""Syntax error in a file list template."""
class DistutilsByteCompileError(DistutilsError):
"""Byte compile error."""
# Exception classes used by the CCompiler implementation classes
class CCompilerError(Exception):
"""Some compile/link operation failed."""
class PreprocessError(CCompilerError):
"""Failure to preprocess one or more C/C++ files."""
class CompileError(CCompilerError):
"""Failure to compile one or more C/C++ source files."""
class LibError(CCompilerError):
"""Failure to create a static library from one or more C/C++ object
files."""
class LinkError(CCompilerError):
"""Failure to link one or more C/C++ object files into an executable
or shared library file."""
class UnknownFileError(CCompilerError):
"""Attempt to process an unknown file type."""
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/errors.py
|
Python
|
mit
| 3,589 |
"""distutils.extension
Provides the Extension class, used to describe C/C++ extension
modules in setup scripts."""
import os
import warnings
# This class is really only used by the "build_ext" command, so it might
# make sense to put it in distutils.command.build_ext. However, that
# module is already big enough, and I want to make this class a bit more
# complex to simplify some common cases ("foo" module in "foo.c") and do
# better error-checking ("foo.c" actually exists).
#
# Also, putting this in build_ext.py means every setup script would have to
# import that large-ish module (indirectly, through distutils.core) in
# order to do anything.
class Extension:
"""Just a collection of attributes that describes an extension
module and everything needed to build it (hopefully in a portable
way, but there are hooks that let you be as unportable as you need).
Instance attributes:
name : string
the full name of the extension, including any packages -- ie.
*not* a filename or pathname, but Python dotted name
sources : [string]
list of source filenames, relative to the distribution root
(where the setup script lives), in Unix form (slash-separated)
for portability. Source files may be C, C++, SWIG (.i),
platform-specific resource files, or whatever else is recognized
by the "build_ext" command as source for a Python extension.
include_dirs : [string]
list of directories to search for C/C++ header files (in Unix
form for portability)
define_macros : [(name : string, value : string|None)]
list of macros to define; each macro is defined using a 2-tuple,
where 'value' is either the string to define it to or None to
define it without a particular value (equivalent of "#define
FOO" in source or -DFOO on Unix C compiler command line)
undef_macros : [string]
list of macros to undefine explicitly
library_dirs : [string]
list of directories to search for C/C++ libraries at link time
libraries : [string]
list of library names (not filenames or paths) to link against
runtime_library_dirs : [string]
list of directories to search for C/C++ libraries at run time
(for shared extensions, this is when the extension is loaded)
extra_objects : [string]
list of extra files to link with (eg. object files not implied
by 'sources', static library that must be explicitly specified,
binary resource files, etc.)
extra_compile_args : [string]
any extra platform- and compiler-specific information to use
when compiling the source files in 'sources'. For platforms and
compilers where "command line" makes sense, this is typically a
list of command-line arguments, but for other platforms it could
be anything.
extra_link_args : [string]
any extra platform- and compiler-specific information to use
when linking object files together to create the extension (or
to create a new static Python interpreter). Similar
interpretation as for 'extra_compile_args'.
export_symbols : [string]
list of symbols to be exported from a shared extension. Not
used on all platforms, and not generally necessary for Python
extensions, which typically export exactly one symbol: "init" +
extension_name.
swig_opts : [string]
any extra options to pass to SWIG if a source file has the .i
extension.
depends : [string]
list of files that the extension depends on
language : string
extension language (i.e. "c", "c++", "objc"). Will be detected
from the source extensions if not provided.
optional : boolean
specifies that a build failure in the extension should not abort the
build process, but simply not install the failing extension.
"""
# When adding arguments to this constructor, be sure to update
# setup_keywords in core.py.
def __init__(
self,
name,
sources,
include_dirs=None,
define_macros=None,
undef_macros=None,
library_dirs=None,
libraries=None,
runtime_library_dirs=None,
extra_objects=None,
extra_compile_args=None,
extra_link_args=None,
export_symbols=None,
swig_opts=None,
depends=None,
language=None,
optional=None,
**kw # To catch unknown keywords
):
if not isinstance(name, str):
raise AssertionError("'name' must be a string")
if not (isinstance(sources, list) and all(isinstance(v, str) for v in sources)):
raise AssertionError("'sources' must be a list of strings")
self.name = name
self.sources = sources
self.include_dirs = include_dirs or []
self.define_macros = define_macros or []
self.undef_macros = undef_macros or []
self.library_dirs = library_dirs or []
self.libraries = libraries or []
self.runtime_library_dirs = runtime_library_dirs or []
self.extra_objects = extra_objects or []
self.extra_compile_args = extra_compile_args or []
self.extra_link_args = extra_link_args or []
self.export_symbols = export_symbols or []
self.swig_opts = swig_opts or []
self.depends = depends or []
self.language = language
self.optional = optional
# If there are unknown keyword options, warn about them
if len(kw) > 0:
options = [repr(option) for option in kw]
options = ', '.join(sorted(options))
msg = "Unknown Extension options: %s" % options
warnings.warn(msg)
def __repr__(self):
return '<{}.{}({!r}) at {:#x}>'.format(
self.__class__.__module__,
self.__class__.__qualname__,
self.name,
id(self),
)
def read_setup_file(filename): # noqa: C901
"""Reads a Setup file and returns Extension instances."""
from distutils.sysconfig import parse_makefile, expand_makefile_vars, _variable_rx
from distutils.text_file import TextFile
from distutils.util import split_quoted
# First pass over the file to gather "VAR = VALUE" assignments.
vars = parse_makefile(filename)
# Second pass to gobble up the real content: lines of the form
# <module> ... [<sourcefile> ...] [<cpparg> ...] [<library> ...]
file = TextFile(
filename,
strip_comments=1,
skip_blanks=1,
join_lines=1,
lstrip_ws=1,
rstrip_ws=1,
)
try:
extensions = []
while True:
line = file.readline()
if line is None: # eof
break
if _variable_rx.match(line): # VAR=VALUE, handled in first pass
continue
if line[0] == line[-1] == "*":
file.warn("'%s' lines not handled yet" % line)
continue
line = expand_makefile_vars(line, vars)
words = split_quoted(line)
# NB. this parses a slightly different syntax than the old
# makesetup script: here, there must be exactly one extension per
# line, and it must be the first word of the line. I have no idea
# why the old syntax supported multiple extensions per line, as
# they all wind up being the same.
module = words[0]
ext = Extension(module, [])
append_next_word = None
for word in words[1:]:
if append_next_word is not None:
append_next_word.append(word)
append_next_word = None
continue
suffix = os.path.splitext(word)[1]
switch = word[0:2]
value = word[2:]
if suffix in (".c", ".cc", ".cpp", ".cxx", ".c++", ".m", ".mm"):
# hmm, should we do something about C vs. C++ sources?
# or leave it up to the CCompiler implementation to
# worry about?
ext.sources.append(word)
elif switch == "-I":
ext.include_dirs.append(value)
elif switch == "-D":
equals = value.find("=")
if equals == -1: # bare "-DFOO" -- no value
ext.define_macros.append((value, None))
else: # "-DFOO=blah"
ext.define_macros.append((value[0:equals], value[equals + 2 :]))
elif switch == "-U":
ext.undef_macros.append(value)
elif switch == "-C": # only here 'cause makesetup has it!
ext.extra_compile_args.append(word)
elif switch == "-l":
ext.libraries.append(value)
elif switch == "-L":
ext.library_dirs.append(value)
elif switch == "-R":
ext.runtime_library_dirs.append(value)
elif word == "-rpath":
append_next_word = ext.runtime_library_dirs
elif word == "-Xlinker":
append_next_word = ext.extra_link_args
elif word == "-Xcompiler":
append_next_word = ext.extra_compile_args
elif switch == "-u":
ext.extra_link_args.append(word)
if not value:
append_next_word = ext.extra_link_args
elif suffix in (".a", ".so", ".sl", ".o", ".dylib"):
# NB. a really faithful emulation of makesetup would
# append a .o file to extra_objects only if it
# had a slash in it; otherwise, it would s/.o/.c/
# and append it to sources. Hmmmm.
ext.extra_objects.append(word)
else:
file.warn("unrecognized argument '%s'" % word)
extensions.append(ext)
finally:
file.close()
return extensions
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/extension.py
|
Python
|
mit
| 10,270 |
"""distutils.fancy_getopt
Wrapper around the standard getopt module that provides the following
additional features:
* short and long options are tied together
* options have help strings, so fancy_getopt could potentially
create a complete usage summary
* options set attributes of a passed-in object
"""
import sys
import string
import re
import getopt
from distutils.errors import DistutilsGetoptError, DistutilsArgError
# Much like command_re in distutils.core, this is close to but not quite
# the same as a Python NAME -- except, in the spirit of most GNU
# utilities, we use '-' in place of '_'. (The spirit of LISP lives on!)
# The similarities to NAME are again not a coincidence...
longopt_pat = r'[a-zA-Z](?:[a-zA-Z0-9-]*)'
longopt_re = re.compile(r'^%s$' % longopt_pat)
# For recognizing "negative alias" options, eg. "quiet=!verbose"
neg_alias_re = re.compile("^({})=!({})$".format(longopt_pat, longopt_pat))
# This is used to translate long options to legitimate Python identifiers
# (for use as attributes of some object).
longopt_xlate = str.maketrans('-', '_')
class FancyGetopt:
"""Wrapper around the standard 'getopt()' module that provides some
handy extra functionality:
* short and long options are tied together
* options have help strings, and help text can be assembled
from them
* options set attributes of a passed-in object
* boolean options can have "negative aliases" -- eg. if
--quiet is the "negative alias" of --verbose, then "--quiet"
on the command line sets 'verbose' to false
"""
def __init__(self, option_table=None):
# The option table is (currently) a list of tuples. The
# tuples may have 3 or four values:
# (long_option, short_option, help_string [, repeatable])
# if an option takes an argument, its long_option should have '='
# appended; short_option should just be a single character, no ':'
# in any case. If a long_option doesn't have a corresponding
# short_option, short_option should be None. All option tuples
# must have long options.
self.option_table = option_table
# 'option_index' maps long option names to entries in the option
# table (ie. those 3-tuples).
self.option_index = {}
if self.option_table:
self._build_index()
# 'alias' records (duh) alias options; {'foo': 'bar'} means
# --foo is an alias for --bar
self.alias = {}
# 'negative_alias' keeps track of options that are the boolean
# opposite of some other option
self.negative_alias = {}
# These keep track of the information in the option table. We
# don't actually populate these structures until we're ready to
# parse the command-line, since the 'option_table' passed in here
# isn't necessarily the final word.
self.short_opts = []
self.long_opts = []
self.short2long = {}
self.attr_name = {}
self.takes_arg = {}
# And 'option_order' is filled up in 'getopt()'; it records the
# original order of options (and their values) on the command-line,
# but expands short options, converts aliases, etc.
self.option_order = []
def _build_index(self):
self.option_index.clear()
for option in self.option_table:
self.option_index[option[0]] = option
def set_option_table(self, option_table):
self.option_table = option_table
self._build_index()
def add_option(self, long_option, short_option=None, help_string=None):
if long_option in self.option_index:
raise DistutilsGetoptError(
"option conflict: already an option '%s'" % long_option
)
else:
option = (long_option, short_option, help_string)
self.option_table.append(option)
self.option_index[long_option] = option
def has_option(self, long_option):
"""Return true if the option table for this parser has an
option with long name 'long_option'."""
return long_option in self.option_index
def get_attr_name(self, long_option):
"""Translate long option name 'long_option' to the form it
has as an attribute of some object: ie., translate hyphens
to underscores."""
return long_option.translate(longopt_xlate)
def _check_alias_dict(self, aliases, what):
assert isinstance(aliases, dict)
for (alias, opt) in aliases.items():
if alias not in self.option_index:
raise DistutilsGetoptError(
("invalid %s '%s': " "option '%s' not defined")
% (what, alias, alias)
)
if opt not in self.option_index:
raise DistutilsGetoptError(
("invalid %s '%s': " "aliased option '%s' not defined")
% (what, alias, opt)
)
def set_aliases(self, alias):
"""Set the aliases for this option parser."""
self._check_alias_dict(alias, "alias")
self.alias = alias
def set_negative_aliases(self, negative_alias):
"""Set the negative aliases for this option parser.
'negative_alias' should be a dictionary mapping option names to
option names, both the key and value must already be defined
in the option table."""
self._check_alias_dict(negative_alias, "negative alias")
self.negative_alias = negative_alias
def _grok_option_table(self): # noqa: C901
"""Populate the various data structures that keep tabs on the
option table. Called by 'getopt()' before it can do anything
worthwhile.
"""
self.long_opts = []
self.short_opts = []
self.short2long.clear()
self.repeat = {}
for option in self.option_table:
if len(option) == 3:
long, short, help = option
repeat = 0
elif len(option) == 4:
long, short, help, repeat = option
else:
# the option table is part of the code, so simply
# assert that it is correct
raise ValueError("invalid option tuple: {!r}".format(option))
# Type- and value-check the option names
if not isinstance(long, str) or len(long) < 2:
raise DistutilsGetoptError(
("invalid long option '%s': " "must be a string of length >= 2")
% long
)
if not ((short is None) or (isinstance(short, str) and len(short) == 1)):
raise DistutilsGetoptError(
"invalid short option '%s': "
"must a single character or None" % short
)
self.repeat[long] = repeat
self.long_opts.append(long)
if long[-1] == '=': # option takes an argument?
if short:
short = short + ':'
long = long[0:-1]
self.takes_arg[long] = 1
else:
# Is option is a "negative alias" for some other option (eg.
# "quiet" == "!verbose")?
alias_to = self.negative_alias.get(long)
if alias_to is not None:
if self.takes_arg[alias_to]:
raise DistutilsGetoptError(
"invalid negative alias '%s': "
"aliased option '%s' takes a value" % (long, alias_to)
)
self.long_opts[-1] = long # XXX redundant?!
self.takes_arg[long] = 0
# If this is an alias option, make sure its "takes arg" flag is
# the same as the option it's aliased to.
alias_to = self.alias.get(long)
if alias_to is not None:
if self.takes_arg[long] != self.takes_arg[alias_to]:
raise DistutilsGetoptError(
"invalid alias '%s': inconsistent with "
"aliased option '%s' (one of them takes a value, "
"the other doesn't" % (long, alias_to)
)
# Now enforce some bondage on the long option name, so we can
# later translate it to an attribute name on some object. Have
# to do this a bit late to make sure we've removed any trailing
# '='.
if not longopt_re.match(long):
raise DistutilsGetoptError(
"invalid long option name '%s' "
"(must be letters, numbers, hyphens only" % long
)
self.attr_name[long] = self.get_attr_name(long)
if short:
self.short_opts.append(short)
self.short2long[short[0]] = long
def getopt(self, args=None, object=None): # noqa: C901
"""Parse command-line options in args. Store as attributes on object.
If 'args' is None or not supplied, uses 'sys.argv[1:]'. If
'object' is None or not supplied, creates a new OptionDummy
object, stores option values there, and returns a tuple (args,
object). If 'object' is supplied, it is modified in place and
'getopt()' just returns 'args'; in both cases, the returned
'args' is a modified copy of the passed-in 'args' list, which
is left untouched.
"""
if args is None:
args = sys.argv[1:]
if object is None:
object = OptionDummy()
created_object = True
else:
created_object = False
self._grok_option_table()
short_opts = ' '.join(self.short_opts)
try:
opts, args = getopt.getopt(args, short_opts, self.long_opts)
except getopt.error as msg:
raise DistutilsArgError(msg)
for opt, val in opts:
if len(opt) == 2 and opt[0] == '-': # it's a short option
opt = self.short2long[opt[1]]
else:
assert len(opt) > 2 and opt[:2] == '--'
opt = opt[2:]
alias = self.alias.get(opt)
if alias:
opt = alias
if not self.takes_arg[opt]: # boolean option?
assert val == '', "boolean option can't have value"
alias = self.negative_alias.get(opt)
if alias:
opt = alias
val = 0
else:
val = 1
attr = self.attr_name[opt]
# The only repeating option at the moment is 'verbose'.
# It has a negative option -q quiet, which should set verbose = 0.
if val and self.repeat.get(attr) is not None:
val = getattr(object, attr, 0) + 1
setattr(object, attr, val)
self.option_order.append((opt, val))
# for opts
if created_object:
return args, object
else:
return args
def get_option_order(self):
"""Returns the list of (option, value) tuples processed by the
previous run of 'getopt()'. Raises RuntimeError if
'getopt()' hasn't been called yet.
"""
if self.option_order is None:
raise RuntimeError("'getopt()' hasn't been called yet")
else:
return self.option_order
def generate_help(self, header=None): # noqa: C901
"""Generate help text (a list of strings, one per suggested line of
output) from the option table for this FancyGetopt object.
"""
# Blithely assume the option table is good: probably wouldn't call
# 'generate_help()' unless you've already called 'getopt()'.
# First pass: determine maximum length of long option names
max_opt = 0
for option in self.option_table:
long = option[0]
short = option[1]
ell = len(long)
if long[-1] == '=':
ell = ell - 1
if short is not None:
ell = ell + 5 # " (-x)" where short == 'x'
if ell > max_opt:
max_opt = ell
opt_width = max_opt + 2 + 2 + 2 # room for indent + dashes + gutter
# Typical help block looks like this:
# --foo controls foonabulation
# Help block for longest option looks like this:
# --flimflam set the flim-flam level
# and with wrapped text:
# --flimflam set the flim-flam level (must be between
# 0 and 100, except on Tuesdays)
# Options with short names will have the short name shown (but
# it doesn't contribute to max_opt):
# --foo (-f) controls foonabulation
# If adding the short option would make the left column too wide,
# we push the explanation off to the next line
# --flimflam (-l)
# set the flim-flam level
# Important parameters:
# - 2 spaces before option block start lines
# - 2 dashes for each long option name
# - min. 2 spaces between option and explanation (gutter)
# - 5 characters (incl. space) for short option name
# Now generate lines of help text. (If 80 columns were good enough
# for Jesus, then 78 columns are good enough for me!)
line_width = 78
text_width = line_width - opt_width
big_indent = ' ' * opt_width
if header:
lines = [header]
else:
lines = ['Option summary:']
for option in self.option_table:
long, short, help = option[:3]
text = wrap_text(help, text_width)
if long[-1] == '=':
long = long[0:-1]
# Case 1: no short option at all (makes life easy)
if short is None:
if text:
lines.append(" --%-*s %s" % (max_opt, long, text[0]))
else:
lines.append(" --%-*s " % (max_opt, long))
# Case 2: we have a short option, so we have to include it
# just after the long option
else:
opt_names = "{} (-{})".format(long, short)
if text:
lines.append(" --%-*s %s" % (max_opt, opt_names, text[0]))
else:
lines.append(" --%-*s" % opt_names)
for ell in text[1:]:
lines.append(big_indent + ell)
return lines
def print_help(self, header=None, file=None):
if file is None:
file = sys.stdout
for line in self.generate_help(header):
file.write(line + "\n")
def fancy_getopt(options, negative_opt, object, args):
parser = FancyGetopt(options)
parser.set_negative_aliases(negative_opt)
return parser.getopt(args, object)
WS_TRANS = {ord(_wschar): ' ' for _wschar in string.whitespace}
def wrap_text(text, width):
"""wrap_text(text : string, width : int) -> [string]
Split 'text' into multiple lines of no more than 'width' characters
each, and return the list of strings that results.
"""
if text is None:
return []
if len(text) <= width:
return [text]
text = text.expandtabs()
text = text.translate(WS_TRANS)
chunks = re.split(r'( +|-+)', text)
chunks = [ch for ch in chunks if ch] # ' - ' results in empty strings
lines = []
while chunks:
cur_line = [] # list of chunks (to-be-joined)
cur_len = 0 # length of current line
while chunks:
ell = len(chunks[0])
if cur_len + ell <= width: # can squeeze (at least) this chunk in
cur_line.append(chunks[0])
del chunks[0]
cur_len = cur_len + ell
else: # this line is full
# drop last chunk if all space
if cur_line and cur_line[-1][0] == ' ':
del cur_line[-1]
break
if chunks: # any chunks left to process?
# if the current line is still empty, then we had a single
# chunk that's too big too fit on a line -- so we break
# down and break it up at the line width
if cur_len == 0:
cur_line.append(chunks[0][0:width])
chunks[0] = chunks[0][width:]
# all-whitespace chunks at the end of a line can be discarded
# (and we know from the re.split above that if a chunk has
# *any* whitespace, it is *all* whitespace)
if chunks[0][0] == ' ':
del chunks[0]
# and store this line in the list-of-all-lines -- as a single
# string, of course!
lines.append(''.join(cur_line))
return lines
def translate_longopt(opt):
"""Convert a long option name to a valid Python identifier by
changing "-" to "_".
"""
return opt.translate(longopt_xlate)
class OptionDummy:
"""Dummy class just used as a place to hold command-line option
values as instance attributes."""
def __init__(self, options=[]):
"""Create a new OptionDummy instance. The attributes listed in
'options' will be initialized to None."""
for opt in options:
setattr(self, opt, None)
if __name__ == "__main__":
text = """\
Tra-la-la, supercalifragilisticexpialidocious.
How *do* you spell that odd word, anyways?
(Someone ask Mary -- she'll know [or she'll
say, "How should I know?"].)"""
for w in (10, 20, 30, 40):
print("width: %d" % w)
print("\n".join(wrap_text(text, w)))
print()
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/fancy_getopt.py
|
Python
|
mit
| 17,910 |
"""distutils.file_util
Utility functions for operating on single files.
"""
import os
from distutils.errors import DistutilsFileError
from distutils import log
# for generating verbose output in 'copy_file()'
_copy_action = {None: 'copying', 'hard': 'hard linking', 'sym': 'symbolically linking'}
def _copy_file_contents(src, dst, buffer_size=16 * 1024): # noqa: C901
"""Copy the file 'src' to 'dst'; both must be filenames. Any error
opening either file, reading from 'src', or writing to 'dst', raises
DistutilsFileError. Data is read/written in chunks of 'buffer_size'
bytes (default 16k). No attempt is made to handle anything apart from
regular files.
"""
# Stolen from shutil module in the standard library, but with
# custom error-handling added.
fsrc = None
fdst = None
try:
try:
fsrc = open(src, 'rb')
except OSError as e:
raise DistutilsFileError("could not open '{}': {}".format(src, e.strerror))
if os.path.exists(dst):
try:
os.unlink(dst)
except OSError as e:
raise DistutilsFileError(
"could not delete '{}': {}".format(dst, e.strerror)
)
try:
fdst = open(dst, 'wb')
except OSError as e:
raise DistutilsFileError(
"could not create '{}': {}".format(dst, e.strerror)
)
while True:
try:
buf = fsrc.read(buffer_size)
except OSError as e:
raise DistutilsFileError(
"could not read from '{}': {}".format(src, e.strerror)
)
if not buf:
break
try:
fdst.write(buf)
except OSError as e:
raise DistutilsFileError(
"could not write to '{}': {}".format(dst, e.strerror)
)
finally:
if fdst:
fdst.close()
if fsrc:
fsrc.close()
def copy_file( # noqa: C901
src,
dst,
preserve_mode=1,
preserve_times=1,
update=0,
link=None,
verbose=1,
dry_run=0,
):
"""Copy a file 'src' to 'dst'. If 'dst' is a directory, then 'src' is
copied there with the same name; otherwise, it must be a filename. (If
the file exists, it will be ruthlessly clobbered.) If 'preserve_mode'
is true (the default), the file's mode (type and permission bits, or
whatever is analogous on the current platform) is copied. If
'preserve_times' is true (the default), the last-modified and
last-access times are copied as well. If 'update' is true, 'src' will
only be copied if 'dst' does not exist, or if 'dst' does exist but is
older than 'src'.
'link' allows you to make hard links (os.link) or symbolic links
(os.symlink) instead of copying: set it to "hard" or "sym"; if it is
None (the default), files are copied. Don't set 'link' on systems that
don't support it: 'copy_file()' doesn't check if hard or symbolic
linking is available. If hardlink fails, falls back to
_copy_file_contents().
Under Mac OS, uses the native file copy function in macostools; on
other systems, uses '_copy_file_contents()' to copy file contents.
Return a tuple (dest_name, copied): 'dest_name' is the actual name of
the output file, and 'copied' is true if the file was copied (or would
have been copied, if 'dry_run' true).
"""
# XXX if the destination file already exists, we clobber it if
# copying, but blow up if linking. Hmmm. And I don't know what
# macostools.copyfile() does. Should definitely be consistent, and
# should probably blow up if destination exists and we would be
# changing it (ie. it's not already a hard/soft link to src OR
# (not update) and (src newer than dst).
from distutils.dep_util import newer
from stat import ST_ATIME, ST_MTIME, ST_MODE, S_IMODE
if not os.path.isfile(src):
raise DistutilsFileError(
"can't copy '%s': doesn't exist or not a regular file" % src
)
if os.path.isdir(dst):
dir = dst
dst = os.path.join(dst, os.path.basename(src))
else:
dir = os.path.dirname(dst)
if update and not newer(src, dst):
if verbose >= 1:
log.debug("not copying %s (output up-to-date)", src)
return (dst, 0)
try:
action = _copy_action[link]
except KeyError:
raise ValueError("invalid value '%s' for 'link' argument" % link)
if verbose >= 1:
if os.path.basename(dst) == os.path.basename(src):
log.info("%s %s -> %s", action, src, dir)
else:
log.info("%s %s -> %s", action, src, dst)
if dry_run:
return (dst, 1)
# If linking (hard or symbolic), use the appropriate system call
# (Unix only, of course, but that's the caller's responsibility)
elif link == 'hard':
if not (os.path.exists(dst) and os.path.samefile(src, dst)):
try:
os.link(src, dst)
return (dst, 1)
except OSError:
# If hard linking fails, fall back on copying file
# (some special filesystems don't support hard linking
# even under Unix, see issue #8876).
pass
elif link == 'sym':
if not (os.path.exists(dst) and os.path.samefile(src, dst)):
os.symlink(src, dst)
return (dst, 1)
# Otherwise (non-Mac, not linking), copy the file contents and
# (optionally) copy the times and mode.
_copy_file_contents(src, dst)
if preserve_mode or preserve_times:
st = os.stat(src)
# According to David Ascher <da@ski.org>, utime() should be done
# before chmod() (at least under NT).
if preserve_times:
os.utime(dst, (st[ST_ATIME], st[ST_MTIME]))
if preserve_mode:
os.chmod(dst, S_IMODE(st[ST_MODE]))
return (dst, 1)
# XXX I suspect this is Unix-specific -- need porting help!
def move_file(src, dst, verbose=1, dry_run=0): # noqa: C901
"""Move a file 'src' to 'dst'. If 'dst' is a directory, the file will
be moved into it with the same name; otherwise, 'src' is just renamed
to 'dst'. Return the new full name of the file.
Handles cross-device moves on Unix using 'copy_file()'. What about
other systems???
"""
from os.path import exists, isfile, isdir, basename, dirname
import errno
if verbose >= 1:
log.info("moving %s -> %s", src, dst)
if dry_run:
return dst
if not isfile(src):
raise DistutilsFileError("can't move '%s': not a regular file" % src)
if isdir(dst):
dst = os.path.join(dst, basename(src))
elif exists(dst):
raise DistutilsFileError(
"can't move '{}': destination '{}' already exists".format(src, dst)
)
if not isdir(dirname(dst)):
raise DistutilsFileError(
"can't move '{}': destination '{}' not a valid path".format(src, dst)
)
copy_it = False
try:
os.rename(src, dst)
except OSError as e:
(num, msg) = e.args
if num == errno.EXDEV:
copy_it = True
else:
raise DistutilsFileError(
"couldn't move '{}' to '{}': {}".format(src, dst, msg)
)
if copy_it:
copy_file(src, dst, verbose=verbose)
try:
os.unlink(src)
except OSError as e:
(num, msg) = e.args
try:
os.unlink(dst)
except OSError:
pass
raise DistutilsFileError(
"couldn't move '%s' to '%s' by copy/delete: "
"delete '%s' failed: %s" % (src, dst, src, msg)
)
return dst
def write_file(filename, contents):
"""Create a file with the specified name and write 'contents' (a
sequence of strings without line terminators) to it.
"""
f = open(filename, "w")
try:
for line in contents:
f.write(line + "\n")
finally:
f.close()
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/file_util.py
|
Python
|
mit
| 8,226 |
"""distutils.filelist
Provides the FileList class, used for poking about the filesystem
and building lists of files.
"""
import os
import re
import fnmatch
import functools
from distutils.util import convert_path
from distutils.errors import DistutilsTemplateError, DistutilsInternalError
from distutils import log
class FileList:
"""A list of files built by on exploring the filesystem and filtered by
applying various patterns to what we find there.
Instance attributes:
dir
directory from which files will be taken -- only used if
'allfiles' not supplied to constructor
files
list of filenames currently being built/filtered/manipulated
allfiles
complete list of files under consideration (ie. without any
filtering applied)
"""
def __init__(self, warn=None, debug_print=None):
# ignore argument to FileList, but keep them for backwards
# compatibility
self.allfiles = None
self.files = []
def set_allfiles(self, allfiles):
self.allfiles = allfiles
def findall(self, dir=os.curdir):
self.allfiles = findall(dir)
def debug_print(self, msg):
"""Print 'msg' to stdout if the global DEBUG (taken from the
DISTUTILS_DEBUG environment variable) flag is true.
"""
from distutils.debug import DEBUG
if DEBUG:
print(msg)
# Collection methods
def append(self, item):
self.files.append(item)
def extend(self, items):
self.files.extend(items)
def sort(self):
# Not a strict lexical sort!
sortable_files = sorted(map(os.path.split, self.files))
self.files = []
for sort_tuple in sortable_files:
self.files.append(os.path.join(*sort_tuple))
# Other miscellaneous utility methods
def remove_duplicates(self):
# Assumes list has been sorted!
for i in range(len(self.files) - 1, 0, -1):
if self.files[i] == self.files[i - 1]:
del self.files[i]
# "File template" methods
def _parse_template_line(self, line):
words = line.split()
action = words[0]
patterns = dir = dir_pattern = None
if action in ('include', 'exclude', 'global-include', 'global-exclude'):
if len(words) < 2:
raise DistutilsTemplateError(
"'%s' expects <pattern1> <pattern2> ..." % action
)
patterns = [convert_path(w) for w in words[1:]]
elif action in ('recursive-include', 'recursive-exclude'):
if len(words) < 3:
raise DistutilsTemplateError(
"'%s' expects <dir> <pattern1> <pattern2> ..." % action
)
dir = convert_path(words[1])
patterns = [convert_path(w) for w in words[2:]]
elif action in ('graft', 'prune'):
if len(words) != 2:
raise DistutilsTemplateError(
"'%s' expects a single <dir_pattern>" % action
)
dir_pattern = convert_path(words[1])
else:
raise DistutilsTemplateError("unknown action '%s'" % action)
return (action, patterns, dir, dir_pattern)
def process_template_line(self, line): # noqa: C901
# Parse the line: split it up, make sure the right number of words
# is there, and return the relevant words. 'action' is always
# defined: it's the first word of the line. Which of the other
# three are defined depends on the action; it'll be either
# patterns, (dir and patterns), or (dir_pattern).
(action, patterns, dir, dir_pattern) = self._parse_template_line(line)
# OK, now we know that the action is valid and we have the
# right number of words on the line for that action -- so we
# can proceed with minimal error-checking.
if action == 'include':
self.debug_print("include " + ' '.join(patterns))
for pattern in patterns:
if not self.include_pattern(pattern, anchor=1):
log.warn("warning: no files found matching '%s'", pattern)
elif action == 'exclude':
self.debug_print("exclude " + ' '.join(patterns))
for pattern in patterns:
if not self.exclude_pattern(pattern, anchor=1):
log.warn(
(
"warning: no previously-included files "
"found matching '%s'"
),
pattern,
)
elif action == 'global-include':
self.debug_print("global-include " + ' '.join(patterns))
for pattern in patterns:
if not self.include_pattern(pattern, anchor=0):
log.warn(
(
"warning: no files found matching '%s' "
"anywhere in distribution"
),
pattern,
)
elif action == 'global-exclude':
self.debug_print("global-exclude " + ' '.join(patterns))
for pattern in patterns:
if not self.exclude_pattern(pattern, anchor=0):
log.warn(
(
"warning: no previously-included files matching "
"'%s' found anywhere in distribution"
),
pattern,
)
elif action == 'recursive-include':
self.debug_print("recursive-include {} {}".format(dir, ' '.join(patterns)))
for pattern in patterns:
if not self.include_pattern(pattern, prefix=dir):
msg = (
"warning: no files found matching '%s' " "under directory '%s'"
)
log.warn(msg, pattern, dir)
elif action == 'recursive-exclude':
self.debug_print("recursive-exclude {} {}".format(dir, ' '.join(patterns)))
for pattern in patterns:
if not self.exclude_pattern(pattern, prefix=dir):
log.warn(
(
"warning: no previously-included files matching "
"'%s' found under directory '%s'"
),
pattern,
dir,
)
elif action == 'graft':
self.debug_print("graft " + dir_pattern)
if not self.include_pattern(None, prefix=dir_pattern):
log.warn("warning: no directories found matching '%s'", dir_pattern)
elif action == 'prune':
self.debug_print("prune " + dir_pattern)
if not self.exclude_pattern(None, prefix=dir_pattern):
log.warn(
("no previously-included directories found " "matching '%s'"),
dir_pattern,
)
else:
raise DistutilsInternalError(
"this cannot happen: invalid action '%s'" % action
)
# Filtering/selection methods
def include_pattern(self, pattern, anchor=1, prefix=None, is_regex=0):
"""Select strings (presumably filenames) from 'self.files' that
match 'pattern', a Unix-style wildcard (glob) pattern. Patterns
are not quite the same as implemented by the 'fnmatch' module: '*'
and '?' match non-special characters, where "special" is platform-
dependent: slash on Unix; colon, slash, and backslash on
DOS/Windows; and colon on Mac OS.
If 'anchor' is true (the default), then the pattern match is more
stringent: "*.py" will match "foo.py" but not "foo/bar.py". If
'anchor' is false, both of these will match.
If 'prefix' is supplied, then only filenames starting with 'prefix'
(itself a pattern) and ending with 'pattern', with anything in between
them, will match. 'anchor' is ignored in this case.
If 'is_regex' is true, 'anchor' and 'prefix' are ignored, and
'pattern' is assumed to be either a string containing a regex or a
regex object -- no translation is done, the regex is just compiled
and used as-is.
Selected strings will be added to self.files.
Return True if files are found, False otherwise.
"""
# XXX docstring lying about what the special chars are?
files_found = False
pattern_re = translate_pattern(pattern, anchor, prefix, is_regex)
self.debug_print("include_pattern: applying regex r'%s'" % pattern_re.pattern)
# delayed loading of allfiles list
if self.allfiles is None:
self.findall()
for name in self.allfiles:
if pattern_re.search(name):
self.debug_print(" adding " + name)
self.files.append(name)
files_found = True
return files_found
def exclude_pattern(self, pattern, anchor=1, prefix=None, is_regex=0):
"""Remove strings (presumably filenames) from 'files' that match
'pattern'. Other parameters are the same as for
'include_pattern()', above.
The list 'self.files' is modified in place.
Return True if files are found, False otherwise.
"""
files_found = False
pattern_re = translate_pattern(pattern, anchor, prefix, is_regex)
self.debug_print("exclude_pattern: applying regex r'%s'" % pattern_re.pattern)
for i in range(len(self.files) - 1, -1, -1):
if pattern_re.search(self.files[i]):
self.debug_print(" removing " + self.files[i])
del self.files[i]
files_found = True
return files_found
# Utility functions
def _find_all_simple(path):
"""
Find all files under 'path'
"""
all_unique = _UniqueDirs.filter(os.walk(path, followlinks=True))
results = (
os.path.join(base, file) for base, dirs, files in all_unique for file in files
)
return filter(os.path.isfile, results)
class _UniqueDirs(set):
"""
Exclude previously-seen dirs from walk results,
avoiding infinite recursion.
Ref https://bugs.python.org/issue44497.
"""
def __call__(self, walk_item):
"""
Given an item from an os.walk result, determine
if the item represents a unique dir for this instance
and if not, prevent further traversal.
"""
base, dirs, files = walk_item
stat = os.stat(base)
candidate = stat.st_dev, stat.st_ino
found = candidate in self
if found:
del dirs[:]
self.add(candidate)
return not found
@classmethod
def filter(cls, items):
return filter(cls(), items)
def findall(dir=os.curdir):
"""
Find all files under 'dir' and return the list of full filenames.
Unless dir is '.', return full filenames with dir prepended.
"""
files = _find_all_simple(dir)
if dir == os.curdir:
make_rel = functools.partial(os.path.relpath, start=dir)
files = map(make_rel, files)
return list(files)
def glob_to_re(pattern):
"""Translate a shell-like glob pattern to a regular expression; return
a string containing the regex. Differs from 'fnmatch.translate()' in
that '*' does not match "special characters" (which are
platform-specific).
"""
pattern_re = fnmatch.translate(pattern)
# '?' and '*' in the glob pattern become '.' and '.*' in the RE, which
# IMHO is wrong -- '?' and '*' aren't supposed to match slash in Unix,
# and by extension they shouldn't match such "special characters" under
# any OS. So change all non-escaped dots in the RE to match any
# character except the special characters (currently: just os.sep).
sep = os.sep
if os.sep == '\\':
# we're using a regex to manipulate a regex, so we need
# to escape the backslash twice
sep = r'\\\\'
escaped = r'\1[^%s]' % sep
pattern_re = re.sub(r'((?<!\\)(\\\\)*)\.', escaped, pattern_re)
return pattern_re
def translate_pattern(pattern, anchor=1, prefix=None, is_regex=0):
"""Translate a shell-like wildcard pattern to a compiled regular
expression. Return the compiled regex. If 'is_regex' true,
then 'pattern' is directly compiled to a regex (if it's a string)
or just returned as-is (assumes it's a regex object).
"""
if is_regex:
if isinstance(pattern, str):
return re.compile(pattern)
else:
return pattern
# ditch start and end characters
start, _, end = glob_to_re('_').partition('_')
if pattern:
pattern_re = glob_to_re(pattern)
assert pattern_re.startswith(start) and pattern_re.endswith(end)
else:
pattern_re = ''
if prefix is not None:
prefix_re = glob_to_re(prefix)
assert prefix_re.startswith(start) and prefix_re.endswith(end)
prefix_re = prefix_re[len(start) : len(prefix_re) - len(end)]
sep = os.sep
if os.sep == '\\':
sep = r'\\'
pattern_re = pattern_re[len(start) : len(pattern_re) - len(end)]
pattern_re = r'{}\A{}{}.*{}{}'.format(start, prefix_re, sep, pattern_re, end)
else: # no prefix -- respect anchor flag
if anchor:
pattern_re = r'{}\A{}'.format(start, pattern_re[len(start) :])
return re.compile(pattern_re)
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/filelist.py
|
Python
|
mit
| 13,713 |
"""A simple log mechanism styled after PEP 282."""
# The class here is styled after PEP 282 so that it could later be
# replaced with a standard Python logging implementation.
import sys
DEBUG = 1
INFO = 2
WARN = 3
ERROR = 4
FATAL = 5
class Log:
def __init__(self, threshold=WARN):
self.threshold = threshold
def _log(self, level, msg, args):
if level not in (DEBUG, INFO, WARN, ERROR, FATAL):
raise ValueError('%s wrong log level' % str(level))
if level >= self.threshold:
if args:
msg = msg % args
if level in (WARN, ERROR, FATAL):
stream = sys.stderr
else:
stream = sys.stdout
try:
stream.write('%s\n' % msg)
except UnicodeEncodeError:
# emulate backslashreplace error handler
encoding = stream.encoding
msg = msg.encode(encoding, "backslashreplace").decode(encoding)
stream.write('%s\n' % msg)
stream.flush()
def log(self, level, msg, *args):
self._log(level, msg, args)
def debug(self, msg, *args):
self._log(DEBUG, msg, args)
def info(self, msg, *args):
self._log(INFO, msg, args)
def warn(self, msg, *args):
self._log(WARN, msg, args)
def error(self, msg, *args):
self._log(ERROR, msg, args)
def fatal(self, msg, *args):
self._log(FATAL, msg, args)
_global_log = Log()
log = _global_log.log
debug = _global_log.debug
info = _global_log.info
warn = _global_log.warn
error = _global_log.error
fatal = _global_log.fatal
def set_threshold(level):
# return the old threshold for use from tests
old = _global_log.threshold
_global_log.threshold = level
return old
def set_verbosity(v):
if v <= 0:
set_threshold(WARN)
elif v == 1:
set_threshold(INFO)
elif v >= 2:
set_threshold(DEBUG)
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/log.py
|
Python
|
mit
| 1,972 |
"""distutils.msvc9compiler
Contains MSVCCompiler, an implementation of the abstract CCompiler class
for the Microsoft Visual Studio 2008.
The module is compatible with VS 2005 and VS 2008. You can find legacy support
for older versions of VS in distutils.msvccompiler.
"""
# Written by Perry Stoll
# hacked by Robin Becker and Thomas Heller to do a better job of
# finding DevStudio (through the registry)
# ported to VS2005 and VS 2008 by Christian Heimes
import os
import subprocess
import sys
import re
import warnings
from distutils.errors import (
DistutilsExecError,
DistutilsPlatformError,
CompileError,
LibError,
LinkError,
)
from distutils.ccompiler import CCompiler, gen_lib_options
from distutils import log
from distutils.util import get_platform
import winreg
warnings.warn(
"msvc9compiler is deprecated and slated to be removed "
"in the future. Please discontinue use or file an issue "
"with pypa/distutils describing your use case.",
DeprecationWarning,
)
RegOpenKeyEx = winreg.OpenKeyEx
RegEnumKey = winreg.EnumKey
RegEnumValue = winreg.EnumValue
RegError = winreg.error
HKEYS = (
winreg.HKEY_USERS,
winreg.HKEY_CURRENT_USER,
winreg.HKEY_LOCAL_MACHINE,
winreg.HKEY_CLASSES_ROOT,
)
NATIVE_WIN64 = sys.platform == 'win32' and sys.maxsize > 2**32
if NATIVE_WIN64:
# Visual C++ is a 32-bit application, so we need to look in
# the corresponding registry branch, if we're running a
# 64-bit Python on Win64
VS_BASE = r"Software\Wow6432Node\Microsoft\VisualStudio\%0.1f"
WINSDK_BASE = r"Software\Wow6432Node\Microsoft\Microsoft SDKs\Windows"
NET_BASE = r"Software\Wow6432Node\Microsoft\.NETFramework"
else:
VS_BASE = r"Software\Microsoft\VisualStudio\%0.1f"
WINSDK_BASE = r"Software\Microsoft\Microsoft SDKs\Windows"
NET_BASE = r"Software\Microsoft\.NETFramework"
# A map keyed by get_platform() return values to values accepted by
# 'vcvarsall.bat'. Note a cross-compile may combine these (eg, 'x86_amd64' is
# the param to cross-compile on x86 targeting amd64.)
PLAT_TO_VCVARS = {
'win32': 'x86',
'win-amd64': 'amd64',
}
class Reg:
"""Helper class to read values from the registry"""
def get_value(cls, path, key):
for base in HKEYS:
d = cls.read_values(base, path)
if d and key in d:
return d[key]
raise KeyError(key)
get_value = classmethod(get_value)
def read_keys(cls, base, key):
"""Return list of registry keys."""
try:
handle = RegOpenKeyEx(base, key)
except RegError:
return None
L = []
i = 0
while True:
try:
k = RegEnumKey(handle, i)
except RegError:
break
L.append(k)
i += 1
return L
read_keys = classmethod(read_keys)
def read_values(cls, base, key):
"""Return dict of registry keys and values.
All names are converted to lowercase.
"""
try:
handle = RegOpenKeyEx(base, key)
except RegError:
return None
d = {}
i = 0
while True:
try:
name, value, type = RegEnumValue(handle, i)
except RegError:
break
name = name.lower()
d[cls.convert_mbcs(name)] = cls.convert_mbcs(value)
i += 1
return d
read_values = classmethod(read_values)
def convert_mbcs(s):
dec = getattr(s, "decode", None)
if dec is not None:
try:
s = dec("mbcs")
except UnicodeError:
pass
return s
convert_mbcs = staticmethod(convert_mbcs)
class MacroExpander:
def __init__(self, version):
self.macros = {}
self.vsbase = VS_BASE % version
self.load_macros(version)
def set_macro(self, macro, path, key):
self.macros["$(%s)" % macro] = Reg.get_value(path, key)
def load_macros(self, version):
self.set_macro("VCInstallDir", self.vsbase + r"\Setup\VC", "productdir")
self.set_macro("VSInstallDir", self.vsbase + r"\Setup\VS", "productdir")
self.set_macro("FrameworkDir", NET_BASE, "installroot")
try:
if version >= 8.0:
self.set_macro("FrameworkSDKDir", NET_BASE, "sdkinstallrootv2.0")
else:
raise KeyError("sdkinstallrootv2.0")
except KeyError:
raise DistutilsPlatformError(
"""Python was built with Visual Studio 2008;
extensions must be built with a compiler than can generate compatible binaries.
Visual Studio 2008 was not found on this system. If you have Cygwin installed,
you can try compiling with MingW32, by passing "-c mingw32" to setup.py."""
)
if version >= 9.0:
self.set_macro("FrameworkVersion", self.vsbase, "clr version")
self.set_macro("WindowsSdkDir", WINSDK_BASE, "currentinstallfolder")
else:
p = r"Software\Microsoft\NET Framework Setup\Product"
for base in HKEYS:
try:
h = RegOpenKeyEx(base, p)
except RegError:
continue
key = RegEnumKey(h, 0)
d = Reg.get_value(base, r"{}\{}".format(p, key))
self.macros["$(FrameworkVersion)"] = d["version"]
def sub(self, s):
for k, v in self.macros.items():
s = s.replace(k, v)
return s
def get_build_version():
"""Return the version of MSVC that was used to build Python.
For Python 2.3 and up, the version number is included in
sys.version. For earlier versions, assume the compiler is MSVC 6.
"""
prefix = "MSC v."
i = sys.version.find(prefix)
if i == -1:
return 6
i = i + len(prefix)
s, rest = sys.version[i:].split(" ", 1)
majorVersion = int(s[:-2]) - 6
if majorVersion >= 13:
# v13 was skipped and should be v14
majorVersion += 1
minorVersion = int(s[2:3]) / 10.0
# I don't think paths are affected by minor version in version 6
if majorVersion == 6:
minorVersion = 0
if majorVersion >= 6:
return majorVersion + minorVersion
# else we don't know what version of the compiler this is
return None
def normalize_and_reduce_paths(paths):
"""Return a list of normalized paths with duplicates removed.
The current order of paths is maintained.
"""
# Paths are normalized so things like: /a and /a/ aren't both preserved.
reduced_paths = []
for p in paths:
np = os.path.normpath(p)
# XXX(nnorwitz): O(n**2), if reduced_paths gets long perhaps use a set.
if np not in reduced_paths:
reduced_paths.append(np)
return reduced_paths
def removeDuplicates(variable):
"""Remove duplicate values of an environment variable."""
oldList = variable.split(os.pathsep)
newList = []
for i in oldList:
if i not in newList:
newList.append(i)
newVariable = os.pathsep.join(newList)
return newVariable
def find_vcvarsall(version):
"""Find the vcvarsall.bat file
At first it tries to find the productdir of VS 2008 in the registry. If
that fails it falls back to the VS90COMNTOOLS env var.
"""
vsbase = VS_BASE % version
try:
productdir = Reg.get_value(r"%s\Setup\VC" % vsbase, "productdir")
except KeyError:
log.debug("Unable to find productdir in registry")
productdir = None
if not productdir or not os.path.isdir(productdir):
toolskey = "VS%0.f0COMNTOOLS" % version
toolsdir = os.environ.get(toolskey, None)
if toolsdir and os.path.isdir(toolsdir):
productdir = os.path.join(toolsdir, os.pardir, os.pardir, "VC")
productdir = os.path.abspath(productdir)
if not os.path.isdir(productdir):
log.debug("%s is not a valid directory" % productdir)
return None
else:
log.debug("Env var %s is not set or invalid" % toolskey)
if not productdir:
log.debug("No productdir found")
return None
vcvarsall = os.path.join(productdir, "vcvarsall.bat")
if os.path.isfile(vcvarsall):
return vcvarsall
log.debug("Unable to find vcvarsall.bat")
return None
def query_vcvarsall(version, arch="x86"):
"""Launch vcvarsall.bat and read the settings from its environment"""
vcvarsall = find_vcvarsall(version)
interesting = {"include", "lib", "libpath", "path"}
result = {}
if vcvarsall is None:
raise DistutilsPlatformError("Unable to find vcvarsall.bat")
log.debug("Calling 'vcvarsall.bat %s' (version=%s)", arch, version)
popen = subprocess.Popen(
'"{}" {} & set'.format(vcvarsall, arch),
stdout=subprocess.PIPE,
stderr=subprocess.PIPE,
)
try:
stdout, stderr = popen.communicate()
if popen.wait() != 0:
raise DistutilsPlatformError(stderr.decode("mbcs"))
stdout = stdout.decode("mbcs")
for line in stdout.split("\n"):
line = Reg.convert_mbcs(line)
if '=' not in line:
continue
line = line.strip()
key, value = line.split('=', 1)
key = key.lower()
if key in interesting:
if value.endswith(os.pathsep):
value = value[:-1]
result[key] = removeDuplicates(value)
finally:
popen.stdout.close()
popen.stderr.close()
if len(result) != len(interesting):
raise ValueError(str(list(result.keys())))
return result
# More globals
VERSION = get_build_version()
# MACROS = MacroExpander(VERSION)
class MSVCCompiler(CCompiler):
"""Concrete class that implements an interface to Microsoft Visual C++,
as defined by the CCompiler abstract class."""
compiler_type = 'msvc'
# Just set this so CCompiler's constructor doesn't barf. We currently
# don't use the 'set_executables()' bureaucracy provided by CCompiler,
# as it really isn't necessary for this sort of single-compiler class.
# Would be nice to have a consistent interface with UnixCCompiler,
# though, so it's worth thinking about.
executables = {}
# Private class data (need to distinguish C from C++ source for compiler)
_c_extensions = ['.c']
_cpp_extensions = ['.cc', '.cpp', '.cxx']
_rc_extensions = ['.rc']
_mc_extensions = ['.mc']
# Needed for the filename generation methods provided by the
# base class, CCompiler.
src_extensions = _c_extensions + _cpp_extensions + _rc_extensions + _mc_extensions
res_extension = '.res'
obj_extension = '.obj'
static_lib_extension = '.lib'
shared_lib_extension = '.dll'
static_lib_format = shared_lib_format = '%s%s'
exe_extension = '.exe'
def __init__(self, verbose=0, dry_run=0, force=0):
super().__init__(verbose, dry_run, force)
self.__version = VERSION
self.__root = r"Software\Microsoft\VisualStudio"
# self.__macros = MACROS
self.__paths = []
# target platform (.plat_name is consistent with 'bdist')
self.plat_name = None
self.__arch = None # deprecated name
self.initialized = False
def initialize(self, plat_name=None): # noqa: C901
# multi-init means we would need to check platform same each time...
assert not self.initialized, "don't init multiple times"
if self.__version < 8.0:
raise DistutilsPlatformError(
"VC %0.1f is not supported by this module" % self.__version
)
if plat_name is None:
plat_name = get_platform()
# sanity check for platforms to prevent obscure errors later.
ok_plats = 'win32', 'win-amd64'
if plat_name not in ok_plats:
raise DistutilsPlatformError(
"--plat-name must be one of {}".format(ok_plats)
)
if (
"DISTUTILS_USE_SDK" in os.environ
and "MSSdk" in os.environ
and self.find_exe("cl.exe")
):
# Assume that the SDK set up everything alright; don't try to be
# smarter
self.cc = "cl.exe"
self.linker = "link.exe"
self.lib = "lib.exe"
self.rc = "rc.exe"
self.mc = "mc.exe"
else:
# On x86, 'vcvars32.bat amd64' creates an env that doesn't work;
# to cross compile, you use 'x86_amd64'.
# On AMD64, 'vcvars32.bat amd64' is a native build env; to cross
# compile use 'x86' (ie, it runs the x86 compiler directly)
if plat_name == get_platform() or plat_name == 'win32':
# native build or cross-compile to win32
plat_spec = PLAT_TO_VCVARS[plat_name]
else:
# cross compile from win32 -> some 64bit
plat_spec = (
PLAT_TO_VCVARS[get_platform()] + '_' + PLAT_TO_VCVARS[plat_name]
)
vc_env = query_vcvarsall(VERSION, plat_spec)
self.__paths = vc_env['path'].split(os.pathsep)
os.environ['lib'] = vc_env['lib']
os.environ['include'] = vc_env['include']
if len(self.__paths) == 0:
raise DistutilsPlatformError(
"Python was built with %s, "
"and extensions need to be built with the same "
"version of the compiler, but it isn't installed." % self.__product
)
self.cc = self.find_exe("cl.exe")
self.linker = self.find_exe("link.exe")
self.lib = self.find_exe("lib.exe")
self.rc = self.find_exe("rc.exe") # resource compiler
self.mc = self.find_exe("mc.exe") # message compiler
# self.set_path_env_var('lib')
# self.set_path_env_var('include')
# extend the MSVC path with the current path
try:
for p in os.environ['path'].split(';'):
self.__paths.append(p)
except KeyError:
pass
self.__paths = normalize_and_reduce_paths(self.__paths)
os.environ['path'] = ";".join(self.__paths)
self.preprocess_options = None
if self.__arch == "x86":
self.compile_options = ['/nologo', '/O2', '/MD', '/W3', '/DNDEBUG']
self.compile_options_debug = [
'/nologo',
'/Od',
'/MDd',
'/W3',
'/Z7',
'/D_DEBUG',
]
else:
# Win64
self.compile_options = ['/nologo', '/O2', '/MD', '/W3', '/GS-', '/DNDEBUG']
self.compile_options_debug = [
'/nologo',
'/Od',
'/MDd',
'/W3',
'/GS-',
'/Z7',
'/D_DEBUG',
]
self.ldflags_shared = ['/DLL', '/nologo', '/INCREMENTAL:NO']
if self.__version >= 7:
self.ldflags_shared_debug = ['/DLL', '/nologo', '/INCREMENTAL:no', '/DEBUG']
self.ldflags_static = ['/nologo']
self.initialized = True
# -- Worker methods ------------------------------------------------
def object_filenames(self, source_filenames, strip_dir=0, output_dir=''):
# Copied from ccompiler.py, extended to return .res as 'object'-file
# for .rc input file
if output_dir is None:
output_dir = ''
obj_names = []
for src_name in source_filenames:
(base, ext) = os.path.splitext(src_name)
base = os.path.splitdrive(base)[1] # Chop off the drive
base = base[os.path.isabs(base) :] # If abs, chop off leading /
if ext not in self.src_extensions:
# Better to raise an exception instead of silently continuing
# and later complain about sources and targets having
# different lengths
raise CompileError("Don't know how to compile %s" % src_name)
if strip_dir:
base = os.path.basename(base)
if ext in self._rc_extensions:
obj_names.append(os.path.join(output_dir, base + self.res_extension))
elif ext in self._mc_extensions:
obj_names.append(os.path.join(output_dir, base + self.res_extension))
else:
obj_names.append(os.path.join(output_dir, base + self.obj_extension))
return obj_names
def compile( # noqa: C901
self,
sources,
output_dir=None,
macros=None,
include_dirs=None,
debug=0,
extra_preargs=None,
extra_postargs=None,
depends=None,
):
if not self.initialized:
self.initialize()
compile_info = self._setup_compile(
output_dir, macros, include_dirs, sources, depends, extra_postargs
)
macros, objects, extra_postargs, pp_opts, build = compile_info
compile_opts = extra_preargs or []
compile_opts.append('/c')
if debug:
compile_opts.extend(self.compile_options_debug)
else:
compile_opts.extend(self.compile_options)
for obj in objects:
try:
src, ext = build[obj]
except KeyError:
continue
if debug:
# pass the full pathname to MSVC in debug mode,
# this allows the debugger to find the source file
# without asking the user to browse for it
src = os.path.abspath(src)
if ext in self._c_extensions:
input_opt = "/Tc" + src
elif ext in self._cpp_extensions:
input_opt = "/Tp" + src
elif ext in self._rc_extensions:
# compile .RC to .RES file
input_opt = src
output_opt = "/fo" + obj
try:
self.spawn([self.rc] + pp_opts + [output_opt] + [input_opt])
except DistutilsExecError as msg:
raise CompileError(msg)
continue
elif ext in self._mc_extensions:
# Compile .MC to .RC file to .RES file.
# * '-h dir' specifies the directory for the
# generated include file
# * '-r dir' specifies the target directory of the
# generated RC file and the binary message resource
# it includes
#
# For now (since there are no options to change this),
# we use the source-directory for the include file and
# the build directory for the RC file and message
# resources. This works at least for win32all.
h_dir = os.path.dirname(src)
rc_dir = os.path.dirname(obj)
try:
# first compile .MC to .RC and .H file
self.spawn([self.mc] + ['-h', h_dir, '-r', rc_dir] + [src])
base, _ = os.path.splitext(os.path.basename(src))
rc_file = os.path.join(rc_dir, base + '.rc')
# then compile .RC to .RES file
self.spawn([self.rc] + ["/fo" + obj] + [rc_file])
except DistutilsExecError as msg:
raise CompileError(msg)
continue
else:
# how to handle this file?
raise CompileError(
"Don't know how to compile {} to {}".format(src, obj)
)
output_opt = "/Fo" + obj
try:
self.spawn(
[self.cc]
+ compile_opts
+ pp_opts
+ [input_opt, output_opt]
+ extra_postargs
)
except DistutilsExecError as msg:
raise CompileError(msg)
return objects
def create_static_lib(
self, objects, output_libname, output_dir=None, debug=0, target_lang=None
):
if not self.initialized:
self.initialize()
(objects, output_dir) = self._fix_object_args(objects, output_dir)
output_filename = self.library_filename(output_libname, output_dir=output_dir)
if self._need_link(objects, output_filename):
lib_args = objects + ['/OUT:' + output_filename]
if debug:
pass # XXX what goes here?
try:
self.spawn([self.lib] + lib_args)
except DistutilsExecError as msg:
raise LibError(msg)
else:
log.debug("skipping %s (up-to-date)", output_filename)
def link( # noqa: C901
self,
target_desc,
objects,
output_filename,
output_dir=None,
libraries=None,
library_dirs=None,
runtime_library_dirs=None,
export_symbols=None,
debug=0,
extra_preargs=None,
extra_postargs=None,
build_temp=None,
target_lang=None,
):
if not self.initialized:
self.initialize()
(objects, output_dir) = self._fix_object_args(objects, output_dir)
fixed_args = self._fix_lib_args(libraries, library_dirs, runtime_library_dirs)
(libraries, library_dirs, runtime_library_dirs) = fixed_args
if runtime_library_dirs:
self.warn(
"I don't know what to do with 'runtime_library_dirs': "
+ str(runtime_library_dirs)
)
lib_opts = gen_lib_options(self, library_dirs, runtime_library_dirs, libraries)
if output_dir is not None:
output_filename = os.path.join(output_dir, output_filename)
if self._need_link(objects, output_filename):
if target_desc == CCompiler.EXECUTABLE:
if debug:
ldflags = self.ldflags_shared_debug[1:]
else:
ldflags = self.ldflags_shared[1:]
else:
if debug:
ldflags = self.ldflags_shared_debug
else:
ldflags = self.ldflags_shared
export_opts = []
for sym in export_symbols or []:
export_opts.append("/EXPORT:" + sym)
ld_args = (
ldflags + lib_opts + export_opts + objects + ['/OUT:' + output_filename]
)
# The MSVC linker generates .lib and .exp files, which cannot be
# suppressed by any linker switches. The .lib files may even be
# needed! Make sure they are generated in the temporary build
# directory. Since they have different names for debug and release
# builds, they can go into the same directory.
build_temp = os.path.dirname(objects[0])
if export_symbols is not None:
(dll_name, dll_ext) = os.path.splitext(
os.path.basename(output_filename)
)
implib_file = os.path.join(build_temp, self.library_filename(dll_name))
ld_args.append('/IMPLIB:' + implib_file)
self.manifest_setup_ldargs(output_filename, build_temp, ld_args)
if extra_preargs:
ld_args[:0] = extra_preargs
if extra_postargs:
ld_args.extend(extra_postargs)
self.mkpath(os.path.dirname(output_filename))
try:
self.spawn([self.linker] + ld_args)
except DistutilsExecError as msg:
raise LinkError(msg)
# embed the manifest
# XXX - this is somewhat fragile - if mt.exe fails, distutils
# will still consider the DLL up-to-date, but it will not have a
# manifest. Maybe we should link to a temp file? OTOH, that
# implies a build environment error that shouldn't go undetected.
mfinfo = self.manifest_get_embed_info(target_desc, ld_args)
if mfinfo is not None:
mffilename, mfid = mfinfo
out_arg = '-outputresource:{};{}'.format(output_filename, mfid)
try:
self.spawn(['mt.exe', '-nologo', '-manifest', mffilename, out_arg])
except DistutilsExecError as msg:
raise LinkError(msg)
else:
log.debug("skipping %s (up-to-date)", output_filename)
def manifest_setup_ldargs(self, output_filename, build_temp, ld_args):
# If we need a manifest at all, an embedded manifest is recommended.
# See MSDN article titled
# "How to: Embed a Manifest Inside a C/C++ Application"
# (currently at http://msdn2.microsoft.com/en-us/library/ms235591(VS.80).aspx)
# Ask the linker to generate the manifest in the temp dir, so
# we can check it, and possibly embed it, later.
temp_manifest = os.path.join(
build_temp, os.path.basename(output_filename) + ".manifest"
)
ld_args.append('/MANIFESTFILE:' + temp_manifest)
def manifest_get_embed_info(self, target_desc, ld_args):
# If a manifest should be embedded, return a tuple of
# (manifest_filename, resource_id). Returns None if no manifest
# should be embedded. See http://bugs.python.org/issue7833 for why
# we want to avoid any manifest for extension modules if we can)
for arg in ld_args:
if arg.startswith("/MANIFESTFILE:"):
temp_manifest = arg.split(":", 1)[1]
break
else:
# no /MANIFESTFILE so nothing to do.
return None
if target_desc == CCompiler.EXECUTABLE:
# by default, executables always get the manifest with the
# CRT referenced.
mfid = 1
else:
# Extension modules try and avoid any manifest if possible.
mfid = 2
temp_manifest = self._remove_visual_c_ref(temp_manifest)
if temp_manifest is None:
return None
return temp_manifest, mfid
def _remove_visual_c_ref(self, manifest_file):
try:
# Remove references to the Visual C runtime, so they will
# fall through to the Visual C dependency of Python.exe.
# This way, when installed for a restricted user (e.g.
# runtimes are not in WinSxS folder, but in Python's own
# folder), the runtimes do not need to be in every folder
# with .pyd's.
# Returns either the filename of the modified manifest or
# None if no manifest should be embedded.
manifest_f = open(manifest_file)
try:
manifest_buf = manifest_f.read()
finally:
manifest_f.close()
pattern = re.compile(
r"""<assemblyIdentity.*?name=("|')Microsoft\."""
r"""VC\d{2}\.CRT("|').*?(/>|</assemblyIdentity>)""",
re.DOTALL,
)
manifest_buf = re.sub(pattern, "", manifest_buf)
pattern = r"<dependentAssembly>\s*</dependentAssembly>"
manifest_buf = re.sub(pattern, "", manifest_buf)
# Now see if any other assemblies are referenced - if not, we
# don't want a manifest embedded.
pattern = re.compile(
r"""<assemblyIdentity.*?name=(?:"|')(.+?)(?:"|')"""
r""".*?(?:/>|</assemblyIdentity>)""",
re.DOTALL,
)
if re.search(pattern, manifest_buf) is None:
return None
manifest_f = open(manifest_file, 'w')
try:
manifest_f.write(manifest_buf)
return manifest_file
finally:
manifest_f.close()
except OSError:
pass
# -- Miscellaneous methods -----------------------------------------
# These are all used by the 'gen_lib_options() function, in
# ccompiler.py.
def library_dir_option(self, dir):
return "/LIBPATH:" + dir
def runtime_library_dir_option(self, dir):
raise DistutilsPlatformError(
"don't know how to set runtime library search path for MSVC++"
)
def library_option(self, lib):
return self.library_filename(lib)
def find_library_file(self, dirs, lib, debug=0):
# Prefer a debugging library if found (and requested), but deal
# with it if we don't have one.
if debug:
try_names = [lib + "_d", lib]
else:
try_names = [lib]
for dir in dirs:
for name in try_names:
libfile = os.path.join(dir, self.library_filename(name))
if os.path.exists(libfile):
return libfile
else:
# Oops, didn't find it in *any* of 'dirs'
return None
# Helper methods for using the MSVC registry settings
def find_exe(self, exe):
"""Return path to an MSVC executable program.
Tries to find the program in several places: first, one of the
MSVC program search paths from the registry; next, the directories
in the PATH environment variable. If any of those work, return an
absolute path that is known to exist. If none of them work, just
return the original program name, 'exe'.
"""
for p in self.__paths:
fn = os.path.join(os.path.abspath(p), exe)
if os.path.isfile(fn):
return fn
# didn't find it; try existing path
for p in os.environ['Path'].split(';'):
fn = os.path.join(os.path.abspath(p), exe)
if os.path.isfile(fn):
return fn
return exe
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/msvc9compiler.py
|
Python
|
mit
| 30,235 |
"""distutils.msvccompiler
Contains MSVCCompiler, an implementation of the abstract CCompiler class
for the Microsoft Visual Studio.
"""
# Written by Perry Stoll
# hacked by Robin Becker and Thomas Heller to do a better job of
# finding DevStudio (through the registry)
import sys
import os
import warnings
from distutils.errors import (
DistutilsExecError,
DistutilsPlatformError,
CompileError,
LibError,
LinkError,
)
from distutils.ccompiler import CCompiler, gen_lib_options
from distutils import log
_can_read_reg = False
try:
import winreg
_can_read_reg = True
hkey_mod = winreg
RegOpenKeyEx = winreg.OpenKeyEx
RegEnumKey = winreg.EnumKey
RegEnumValue = winreg.EnumValue
RegError = winreg.error
except ImportError:
try:
import win32api
import win32con
_can_read_reg = True
hkey_mod = win32con
RegOpenKeyEx = win32api.RegOpenKeyEx
RegEnumKey = win32api.RegEnumKey
RegEnumValue = win32api.RegEnumValue
RegError = win32api.error
except ImportError:
log.info(
"Warning: Can't read registry to find the "
"necessary compiler setting\n"
"Make sure that Python modules winreg, "
"win32api or win32con are installed."
)
pass
if _can_read_reg:
HKEYS = (
hkey_mod.HKEY_USERS,
hkey_mod.HKEY_CURRENT_USER,
hkey_mod.HKEY_LOCAL_MACHINE,
hkey_mod.HKEY_CLASSES_ROOT,
)
warnings.warn(
"msvccompiler is deprecated and slated to be removed "
"in the future. Please discontinue use or file an issue "
"with pypa/distutils describing your use case.",
DeprecationWarning,
)
def read_keys(base, key):
"""Return list of registry keys."""
try:
handle = RegOpenKeyEx(base, key)
except RegError:
return None
L = []
i = 0
while True:
try:
k = RegEnumKey(handle, i)
except RegError:
break
L.append(k)
i += 1
return L
def read_values(base, key):
"""Return dict of registry keys and values.
All names are converted to lowercase.
"""
try:
handle = RegOpenKeyEx(base, key)
except RegError:
return None
d = {}
i = 0
while True:
try:
name, value, type = RegEnumValue(handle, i)
except RegError:
break
name = name.lower()
d[convert_mbcs(name)] = convert_mbcs(value)
i += 1
return d
def convert_mbcs(s):
dec = getattr(s, "decode", None)
if dec is not None:
try:
s = dec("mbcs")
except UnicodeError:
pass
return s
class MacroExpander:
def __init__(self, version):
self.macros = {}
self.load_macros(version)
def set_macro(self, macro, path, key):
for base in HKEYS:
d = read_values(base, path)
if d:
self.macros["$(%s)" % macro] = d[key]
break
def load_macros(self, version):
vsbase = r"Software\Microsoft\VisualStudio\%0.1f" % version
self.set_macro("VCInstallDir", vsbase + r"\Setup\VC", "productdir")
self.set_macro("VSInstallDir", vsbase + r"\Setup\VS", "productdir")
net = r"Software\Microsoft\.NETFramework"
self.set_macro("FrameworkDir", net, "installroot")
try:
if version > 7.0:
self.set_macro("FrameworkSDKDir", net, "sdkinstallrootv1.1")
else:
self.set_macro("FrameworkSDKDir", net, "sdkinstallroot")
except KeyError:
raise DistutilsPlatformError(
"""Python was built with Visual Studio 2003;
extensions must be built with a compiler than can generate compatible binaries.
Visual Studio 2003 was not found on this system. If you have Cygwin installed,
you can try compiling with MingW32, by passing "-c mingw32" to setup.py."""
)
p = r"Software\Microsoft\NET Framework Setup\Product"
for base in HKEYS:
try:
h = RegOpenKeyEx(base, p)
except RegError:
continue
key = RegEnumKey(h, 0)
d = read_values(base, r"{}\{}".format(p, key))
self.macros["$(FrameworkVersion)"] = d["version"]
def sub(self, s):
for k, v in self.macros.items():
s = s.replace(k, v)
return s
def get_build_version():
"""Return the version of MSVC that was used to build Python.
For Python 2.3 and up, the version number is included in
sys.version. For earlier versions, assume the compiler is MSVC 6.
"""
prefix = "MSC v."
i = sys.version.find(prefix)
if i == -1:
return 6
i = i + len(prefix)
s, rest = sys.version[i:].split(" ", 1)
majorVersion = int(s[:-2]) - 6
if majorVersion >= 13:
# v13 was skipped and should be v14
majorVersion += 1
minorVersion = int(s[2:3]) / 10.0
# I don't think paths are affected by minor version in version 6
if majorVersion == 6:
minorVersion = 0
if majorVersion >= 6:
return majorVersion + minorVersion
# else we don't know what version of the compiler this is
return None
def get_build_architecture():
"""Return the processor architecture.
Possible results are "Intel" or "AMD64".
"""
prefix = " bit ("
i = sys.version.find(prefix)
if i == -1:
return "Intel"
j = sys.version.find(")", i)
return sys.version[i + len(prefix) : j]
def normalize_and_reduce_paths(paths):
"""Return a list of normalized paths with duplicates removed.
The current order of paths is maintained.
"""
# Paths are normalized so things like: /a and /a/ aren't both preserved.
reduced_paths = []
for p in paths:
np = os.path.normpath(p)
# XXX(nnorwitz): O(n**2), if reduced_paths gets long perhaps use a set.
if np not in reduced_paths:
reduced_paths.append(np)
return reduced_paths
class MSVCCompiler(CCompiler):
"""Concrete class that implements an interface to Microsoft Visual C++,
as defined by the CCompiler abstract class."""
compiler_type = 'msvc'
# Just set this so CCompiler's constructor doesn't barf. We currently
# don't use the 'set_executables()' bureaucracy provided by CCompiler,
# as it really isn't necessary for this sort of single-compiler class.
# Would be nice to have a consistent interface with UnixCCompiler,
# though, so it's worth thinking about.
executables = {}
# Private class data (need to distinguish C from C++ source for compiler)
_c_extensions = ['.c']
_cpp_extensions = ['.cc', '.cpp', '.cxx']
_rc_extensions = ['.rc']
_mc_extensions = ['.mc']
# Needed for the filename generation methods provided by the
# base class, CCompiler.
src_extensions = _c_extensions + _cpp_extensions + _rc_extensions + _mc_extensions
res_extension = '.res'
obj_extension = '.obj'
static_lib_extension = '.lib'
shared_lib_extension = '.dll'
static_lib_format = shared_lib_format = '%s%s'
exe_extension = '.exe'
def __init__(self, verbose=0, dry_run=0, force=0):
super().__init__(verbose, dry_run, force)
self.__version = get_build_version()
self.__arch = get_build_architecture()
if self.__arch == "Intel":
# x86
if self.__version >= 7:
self.__root = r"Software\Microsoft\VisualStudio"
self.__macros = MacroExpander(self.__version)
else:
self.__root = r"Software\Microsoft\Devstudio"
self.__product = "Visual Studio version %s" % self.__version
else:
# Win64. Assume this was built with the platform SDK
self.__product = "Microsoft SDK compiler %s" % (self.__version + 6)
self.initialized = False
def initialize(self):
self.__paths = []
if (
"DISTUTILS_USE_SDK" in os.environ
and "MSSdk" in os.environ
and self.find_exe("cl.exe")
):
# Assume that the SDK set up everything alright; don't try to be
# smarter
self.cc = "cl.exe"
self.linker = "link.exe"
self.lib = "lib.exe"
self.rc = "rc.exe"
self.mc = "mc.exe"
else:
self.__paths = self.get_msvc_paths("path")
if len(self.__paths) == 0:
raise DistutilsPlatformError(
"Python was built with %s, "
"and extensions need to be built with the same "
"version of the compiler, but it isn't installed." % self.__product
)
self.cc = self.find_exe("cl.exe")
self.linker = self.find_exe("link.exe")
self.lib = self.find_exe("lib.exe")
self.rc = self.find_exe("rc.exe") # resource compiler
self.mc = self.find_exe("mc.exe") # message compiler
self.set_path_env_var('lib')
self.set_path_env_var('include')
# extend the MSVC path with the current path
try:
for p in os.environ['path'].split(';'):
self.__paths.append(p)
except KeyError:
pass
self.__paths = normalize_and_reduce_paths(self.__paths)
os.environ['path'] = ";".join(self.__paths)
self.preprocess_options = None
if self.__arch == "Intel":
self.compile_options = ['/nologo', '/O2', '/MD', '/W3', '/GX', '/DNDEBUG']
self.compile_options_debug = [
'/nologo',
'/Od',
'/MDd',
'/W3',
'/GX',
'/Z7',
'/D_DEBUG',
]
else:
# Win64
self.compile_options = ['/nologo', '/O2', '/MD', '/W3', '/GS-', '/DNDEBUG']
self.compile_options_debug = [
'/nologo',
'/Od',
'/MDd',
'/W3',
'/GS-',
'/Z7',
'/D_DEBUG',
]
self.ldflags_shared = ['/DLL', '/nologo', '/INCREMENTAL:NO']
if self.__version >= 7:
self.ldflags_shared_debug = ['/DLL', '/nologo', '/INCREMENTAL:no', '/DEBUG']
else:
self.ldflags_shared_debug = [
'/DLL',
'/nologo',
'/INCREMENTAL:no',
'/pdb:None',
'/DEBUG',
]
self.ldflags_static = ['/nologo']
self.initialized = True
# -- Worker methods ------------------------------------------------
def object_filenames(self, source_filenames, strip_dir=0, output_dir=''):
# Copied from ccompiler.py, extended to return .res as 'object'-file
# for .rc input file
if output_dir is None:
output_dir = ''
obj_names = []
for src_name in source_filenames:
(base, ext) = os.path.splitext(src_name)
base = os.path.splitdrive(base)[1] # Chop off the drive
base = base[os.path.isabs(base) :] # If abs, chop off leading /
if ext not in self.src_extensions:
# Better to raise an exception instead of silently continuing
# and later complain about sources and targets having
# different lengths
raise CompileError("Don't know how to compile %s" % src_name)
if strip_dir:
base = os.path.basename(base)
if ext in self._rc_extensions:
obj_names.append(os.path.join(output_dir, base + self.res_extension))
elif ext in self._mc_extensions:
obj_names.append(os.path.join(output_dir, base + self.res_extension))
else:
obj_names.append(os.path.join(output_dir, base + self.obj_extension))
return obj_names
def compile( # noqa: C901
self,
sources,
output_dir=None,
macros=None,
include_dirs=None,
debug=0,
extra_preargs=None,
extra_postargs=None,
depends=None,
):
if not self.initialized:
self.initialize()
compile_info = self._setup_compile(
output_dir, macros, include_dirs, sources, depends, extra_postargs
)
macros, objects, extra_postargs, pp_opts, build = compile_info
compile_opts = extra_preargs or []
compile_opts.append('/c')
if debug:
compile_opts.extend(self.compile_options_debug)
else:
compile_opts.extend(self.compile_options)
for obj in objects:
try:
src, ext = build[obj]
except KeyError:
continue
if debug:
# pass the full pathname to MSVC in debug mode,
# this allows the debugger to find the source file
# without asking the user to browse for it
src = os.path.abspath(src)
if ext in self._c_extensions:
input_opt = "/Tc" + src
elif ext in self._cpp_extensions:
input_opt = "/Tp" + src
elif ext in self._rc_extensions:
# compile .RC to .RES file
input_opt = src
output_opt = "/fo" + obj
try:
self.spawn([self.rc] + pp_opts + [output_opt] + [input_opt])
except DistutilsExecError as msg:
raise CompileError(msg)
continue
elif ext in self._mc_extensions:
# Compile .MC to .RC file to .RES file.
# * '-h dir' specifies the directory for the
# generated include file
# * '-r dir' specifies the target directory of the
# generated RC file and the binary message resource
# it includes
#
# For now (since there are no options to change this),
# we use the source-directory for the include file and
# the build directory for the RC file and message
# resources. This works at least for win32all.
h_dir = os.path.dirname(src)
rc_dir = os.path.dirname(obj)
try:
# first compile .MC to .RC and .H file
self.spawn([self.mc] + ['-h', h_dir, '-r', rc_dir] + [src])
base, _ = os.path.splitext(os.path.basename(src))
rc_file = os.path.join(rc_dir, base + '.rc')
# then compile .RC to .RES file
self.spawn([self.rc] + ["/fo" + obj] + [rc_file])
except DistutilsExecError as msg:
raise CompileError(msg)
continue
else:
# how to handle this file?
raise CompileError(
"Don't know how to compile {} to {}".format(src, obj)
)
output_opt = "/Fo" + obj
try:
self.spawn(
[self.cc]
+ compile_opts
+ pp_opts
+ [input_opt, output_opt]
+ extra_postargs
)
except DistutilsExecError as msg:
raise CompileError(msg)
return objects
def create_static_lib(
self, objects, output_libname, output_dir=None, debug=0, target_lang=None
):
if not self.initialized:
self.initialize()
(objects, output_dir) = self._fix_object_args(objects, output_dir)
output_filename = self.library_filename(output_libname, output_dir=output_dir)
if self._need_link(objects, output_filename):
lib_args = objects + ['/OUT:' + output_filename]
if debug:
pass # XXX what goes here?
try:
self.spawn([self.lib] + lib_args)
except DistutilsExecError as msg:
raise LibError(msg)
else:
log.debug("skipping %s (up-to-date)", output_filename)
def link( # noqa: C901
self,
target_desc,
objects,
output_filename,
output_dir=None,
libraries=None,
library_dirs=None,
runtime_library_dirs=None,
export_symbols=None,
debug=0,
extra_preargs=None,
extra_postargs=None,
build_temp=None,
target_lang=None,
):
if not self.initialized:
self.initialize()
(objects, output_dir) = self._fix_object_args(objects, output_dir)
fixed_args = self._fix_lib_args(libraries, library_dirs, runtime_library_dirs)
(libraries, library_dirs, runtime_library_dirs) = fixed_args
if runtime_library_dirs:
self.warn(
"I don't know what to do with 'runtime_library_dirs': "
+ str(runtime_library_dirs)
)
lib_opts = gen_lib_options(self, library_dirs, runtime_library_dirs, libraries)
if output_dir is not None:
output_filename = os.path.join(output_dir, output_filename)
if self._need_link(objects, output_filename):
if target_desc == CCompiler.EXECUTABLE:
if debug:
ldflags = self.ldflags_shared_debug[1:]
else:
ldflags = self.ldflags_shared[1:]
else:
if debug:
ldflags = self.ldflags_shared_debug
else:
ldflags = self.ldflags_shared
export_opts = []
for sym in export_symbols or []:
export_opts.append("/EXPORT:" + sym)
ld_args = (
ldflags + lib_opts + export_opts + objects + ['/OUT:' + output_filename]
)
# The MSVC linker generates .lib and .exp files, which cannot be
# suppressed by any linker switches. The .lib files may even be
# needed! Make sure they are generated in the temporary build
# directory. Since they have different names for debug and release
# builds, they can go into the same directory.
if export_symbols is not None:
(dll_name, dll_ext) = os.path.splitext(
os.path.basename(output_filename)
)
implib_file = os.path.join(
os.path.dirname(objects[0]), self.library_filename(dll_name)
)
ld_args.append('/IMPLIB:' + implib_file)
if extra_preargs:
ld_args[:0] = extra_preargs
if extra_postargs:
ld_args.extend(extra_postargs)
self.mkpath(os.path.dirname(output_filename))
try:
self.spawn([self.linker] + ld_args)
except DistutilsExecError as msg:
raise LinkError(msg)
else:
log.debug("skipping %s (up-to-date)", output_filename)
# -- Miscellaneous methods -----------------------------------------
# These are all used by the 'gen_lib_options() function, in
# ccompiler.py.
def library_dir_option(self, dir):
return "/LIBPATH:" + dir
def runtime_library_dir_option(self, dir):
raise DistutilsPlatformError(
"don't know how to set runtime library search path for MSVC++"
)
def library_option(self, lib):
return self.library_filename(lib)
def find_library_file(self, dirs, lib, debug=0):
# Prefer a debugging library if found (and requested), but deal
# with it if we don't have one.
if debug:
try_names = [lib + "_d", lib]
else:
try_names = [lib]
for dir in dirs:
for name in try_names:
libfile = os.path.join(dir, self.library_filename(name))
if os.path.exists(libfile):
return libfile
else:
# Oops, didn't find it in *any* of 'dirs'
return None
# Helper methods for using the MSVC registry settings
def find_exe(self, exe):
"""Return path to an MSVC executable program.
Tries to find the program in several places: first, one of the
MSVC program search paths from the registry; next, the directories
in the PATH environment variable. If any of those work, return an
absolute path that is known to exist. If none of them work, just
return the original program name, 'exe'.
"""
for p in self.__paths:
fn = os.path.join(os.path.abspath(p), exe)
if os.path.isfile(fn):
return fn
# didn't find it; try existing path
for p in os.environ['Path'].split(';'):
fn = os.path.join(os.path.abspath(p), exe)
if os.path.isfile(fn):
return fn
return exe
def get_msvc_paths(self, path, platform='x86'):
"""Get a list of devstudio directories (include, lib or path).
Return a list of strings. The list will be empty if unable to
access the registry or appropriate registry keys not found.
"""
if not _can_read_reg:
return []
path = path + " dirs"
if self.__version >= 7:
key = r"{}\{:0.1f}\VC\VC_OBJECTS_PLATFORM_INFO\Win32\Directories".format(
self.__root,
self.__version,
)
else:
key = (
r"%s\6.0\Build System\Components\Platforms"
r"\Win32 (%s)\Directories" % (self.__root, platform)
)
for base in HKEYS:
d = read_values(base, key)
if d:
if self.__version >= 7:
return self.__macros.sub(d[path]).split(";")
else:
return d[path].split(";")
# MSVC 6 seems to create the registry entries we need only when
# the GUI is run.
if self.__version == 6:
for base in HKEYS:
if read_values(base, r"%s\6.0" % self.__root) is not None:
self.warn(
"It seems you have Visual Studio 6 installed, "
"but the expected registry settings are not present.\n"
"You must at least run the Visual Studio GUI once "
"so that these entries are created."
)
break
return []
def set_path_env_var(self, name):
"""Set environment variable 'name' to an MSVC path type value.
This is equivalent to a SET command prior to execution of spawned
commands.
"""
if name == "lib":
p = self.get_msvc_paths("library")
else:
p = self.get_msvc_paths(name)
if p:
os.environ[name] = ';'.join(p)
if get_build_version() >= 8.0:
log.debug("Importing new compiler from distutils.msvc9compiler")
OldMSVCCompiler = MSVCCompiler
from distutils.msvc9compiler import MSVCCompiler
# get_build_architecture not really relevant now we support cross-compile
from distutils.msvc9compiler import MacroExpander # noqa: F811
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/msvccompiler.py
|
Python
|
mit
| 23,602 |
def aix_platform(osname, version, release):
try:
import _aix_support
return _aix_support.aix_platform()
except ImportError:
pass
return "{}-{}.{}".format(osname, version, release)
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/py38compat.py
|
Python
|
mit
| 217 |
import sys
import platform
def add_ext_suffix_39(vars):
"""
Ensure vars contains 'EXT_SUFFIX'. pypa/distutils#130
"""
import _imp
ext_suffix = _imp.extension_suffixes()[0]
vars.update(
EXT_SUFFIX=ext_suffix,
# sysconfig sets SO to match EXT_SUFFIX, so maintain
# that expectation.
# https://github.com/python/cpython/blob/785cc6770588de087d09e89a69110af2542be208/Lib/sysconfig.py#L671-L673
SO=ext_suffix,
)
needs_ext_suffix = sys.version_info < (3, 10) and platform.system() == 'Windows'
add_ext_suffix = add_ext_suffix_39 if needs_ext_suffix else lambda vars: None
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/py39compat.py
|
Python
|
mit
| 639 |
"""distutils.spawn
Provides the 'spawn()' function, a front-end to various platform-
specific functions for launching another program in a sub-process.
Also provides the 'find_executable()' to search the path for a given
executable name.
"""
import sys
import os
import subprocess
from distutils.errors import DistutilsExecError
from distutils.debug import DEBUG
from distutils import log
def spawn(cmd, search_path=1, verbose=0, dry_run=0, env=None): # noqa: C901
"""Run another program, specified as a command list 'cmd', in a new process.
'cmd' is just the argument list for the new process, ie.
cmd[0] is the program to run and cmd[1:] are the rest of its arguments.
There is no way to run a program with a name different from that of its
executable.
If 'search_path' is true (the default), the system's executable
search path will be used to find the program; otherwise, cmd[0]
must be the exact path to the executable. If 'dry_run' is true,
the command will not actually be run.
Raise DistutilsExecError if running the program fails in any way; just
return on success.
"""
# cmd is documented as a list, but just in case some code passes a tuple
# in, protect our %-formatting code against horrible death
cmd = list(cmd)
log.info(subprocess.list2cmdline(cmd))
if dry_run:
return
if search_path:
executable = find_executable(cmd[0])
if executable is not None:
cmd[0] = executable
env = env if env is not None else dict(os.environ)
if sys.platform == 'darwin':
from distutils.util import MACOSX_VERSION_VAR, get_macosx_target_ver
macosx_target_ver = get_macosx_target_ver()
if macosx_target_ver:
env[MACOSX_VERSION_VAR] = macosx_target_ver
try:
proc = subprocess.Popen(cmd, env=env)
proc.wait()
exitcode = proc.returncode
except OSError as exc:
if not DEBUG:
cmd = cmd[0]
raise DistutilsExecError(
"command {!r} failed: {}".format(cmd, exc.args[-1])
) from exc
if exitcode:
if not DEBUG:
cmd = cmd[0]
raise DistutilsExecError(
"command {!r} failed with exit code {}".format(cmd, exitcode)
)
def find_executable(executable, path=None):
"""Tries to find 'executable' in the directories listed in 'path'.
A string listing directories separated by 'os.pathsep'; defaults to
os.environ['PATH']. Returns the complete filename or None if not found.
"""
_, ext = os.path.splitext(executable)
if (sys.platform == 'win32') and (ext != '.exe'):
executable = executable + '.exe'
if os.path.isfile(executable):
return executable
if path is None:
path = os.environ.get('PATH', None)
if path is None:
try:
path = os.confstr("CS_PATH")
except (AttributeError, ValueError):
# os.confstr() or CS_PATH is not available
path = os.defpath
# bpo-35755: Don't use os.defpath if the PATH environment variable is
# set to an empty string
# PATH='' doesn't match, whereas PATH=':' looks in the current directory
if not path:
return None
paths = path.split(os.pathsep)
for p in paths:
f = os.path.join(p, executable)
if os.path.isfile(f):
# the file exists, we have a shot at spawn working
return f
return None
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/spawn.py
|
Python
|
mit
| 3,517 |
"""Provide access to Python's configuration information. The specific
configuration variables available depend heavily on the platform and
configuration. The values may be retrieved using
get_config_var(name), and the list of variables is available via
get_config_vars().keys(). Additional convenience functions are also
available.
Written by: Fred L. Drake, Jr.
Email: <fdrake@acm.org>
"""
import os
import re
import sys
import sysconfig
import pathlib
from .errors import DistutilsPlatformError
from . import py39compat
from ._functools import pass_none
IS_PYPY = '__pypy__' in sys.builtin_module_names
# These are needed in a couple of spots, so just compute them once.
PREFIX = os.path.normpath(sys.prefix)
EXEC_PREFIX = os.path.normpath(sys.exec_prefix)
BASE_PREFIX = os.path.normpath(sys.base_prefix)
BASE_EXEC_PREFIX = os.path.normpath(sys.base_exec_prefix)
# Path to the base directory of the project. On Windows the binary may
# live in project/PCbuild/win32 or project/PCbuild/amd64.
# set for cross builds
if "_PYTHON_PROJECT_BASE" in os.environ:
project_base = os.path.abspath(os.environ["_PYTHON_PROJECT_BASE"])
else:
if sys.executable:
project_base = os.path.dirname(os.path.abspath(sys.executable))
else:
# sys.executable can be empty if argv[0] has been changed and Python is
# unable to retrieve the real program name
project_base = os.getcwd()
def _is_python_source_dir(d):
"""
Return True if the target directory appears to point to an
un-installed Python.
"""
modules = pathlib.Path(d).joinpath('Modules')
return any(modules.joinpath(fn).is_file() for fn in ('Setup', 'Setup.local'))
_sys_home = getattr(sys, '_home', None)
def _is_parent(dir_a, dir_b):
"""
Return True if a is a parent of b.
"""
return os.path.normcase(dir_a).startswith(os.path.normcase(dir_b))
if os.name == 'nt':
@pass_none
def _fix_pcbuild(d):
# In a venv, sys._home will be inside BASE_PREFIX rather than PREFIX.
prefixes = PREFIX, BASE_PREFIX
matched = (
prefix
for prefix in prefixes
if _is_parent(d, os.path.join(prefix, "PCbuild"))
)
return next(matched, d)
project_base = _fix_pcbuild(project_base)
_sys_home = _fix_pcbuild(_sys_home)
def _python_build():
if _sys_home:
return _is_python_source_dir(_sys_home)
return _is_python_source_dir(project_base)
python_build = _python_build()
# Calculate the build qualifier flags if they are defined. Adding the flags
# to the include and lib directories only makes sense for an installation, not
# an in-source build.
build_flags = ''
try:
if not python_build:
build_flags = sys.abiflags
except AttributeError:
# It's not a configure-based build, so the sys module doesn't have
# this attribute, which is fine.
pass
def get_python_version():
"""Return a string containing the major and minor Python version,
leaving off the patchlevel. Sample return values could be '1.5'
or '2.2'.
"""
return '%d.%d' % sys.version_info[:2]
def get_python_inc(plat_specific=0, prefix=None):
"""Return the directory containing installed Python header files.
If 'plat_specific' is false (the default), this is the path to the
non-platform-specific header files, i.e. Python.h and so on;
otherwise, this is the path to platform-specific header files
(namely pyconfig.h).
If 'prefix' is supplied, use it instead of sys.base_prefix or
sys.base_exec_prefix -- i.e., ignore 'plat_specific'.
"""
default_prefix = BASE_EXEC_PREFIX if plat_specific else BASE_PREFIX
resolved_prefix = prefix if prefix is not None else default_prefix
try:
getter = globals()[f'_get_python_inc_{os.name}']
except KeyError:
raise DistutilsPlatformError(
"I don't know where Python installs its C header files "
"on platform '%s'" % os.name
)
return getter(resolved_prefix, prefix, plat_specific)
def _get_python_inc_posix(prefix, spec_prefix, plat_specific):
if IS_PYPY and sys.version_info < (3, 8):
return os.path.join(prefix, 'include')
return (
_get_python_inc_posix_python(plat_specific)
or _get_python_inc_from_config(plat_specific, spec_prefix)
or _get_python_inc_posix_prefix(prefix)
)
def _get_python_inc_posix_python(plat_specific):
"""
Assume the executable is in the build directory. The
pyconfig.h file should be in the same directory. Since
the build directory may not be the source directory,
use "srcdir" from the makefile to find the "Include"
directory.
"""
if not python_build:
return
if plat_specific:
return _sys_home or project_base
incdir = os.path.join(get_config_var('srcdir'), 'Include')
return os.path.normpath(incdir)
def _get_python_inc_from_config(plat_specific, spec_prefix):
"""
If no prefix was explicitly specified, provide the include
directory from the config vars. Useful when
cross-compiling, since the config vars may come from
the host
platform Python installation, while the current Python
executable is from the build platform installation.
>>> monkeypatch = getfixture('monkeypatch')
>>> gpifc = _get_python_inc_from_config
>>> monkeypatch.setitem(gpifc.__globals__, 'get_config_var', str.lower)
>>> gpifc(False, '/usr/bin/')
>>> gpifc(False, '')
>>> gpifc(False, None)
'includepy'
>>> gpifc(True, None)
'confincludepy'
"""
if spec_prefix is None:
return get_config_var('CONF' * plat_specific + 'INCLUDEPY')
def _get_python_inc_posix_prefix(prefix):
implementation = 'pypy' if IS_PYPY else 'python'
python_dir = implementation + get_python_version() + build_flags
return os.path.join(prefix, "include", python_dir)
def _get_python_inc_nt(prefix, spec_prefix, plat_specific):
if python_build:
# Include both the include and PC dir to ensure we can find
# pyconfig.h
return (
os.path.join(prefix, "include")
+ os.path.pathsep
+ os.path.join(prefix, "PC")
)
return os.path.join(prefix, "include")
# allow this behavior to be monkey-patched. Ref pypa/distutils#2.
def _posix_lib(standard_lib, libpython, early_prefix, prefix):
if standard_lib:
return libpython
else:
return os.path.join(libpython, "site-packages")
def get_python_lib(plat_specific=0, standard_lib=0, prefix=None):
"""Return the directory containing the Python library (standard or
site additions).
If 'plat_specific' is true, return the directory containing
platform-specific modules, i.e. any module from a non-pure-Python
module distribution; otherwise, return the platform-shared library
directory. If 'standard_lib' is true, return the directory
containing standard Python library modules; otherwise, return the
directory for site-specific modules.
If 'prefix' is supplied, use it instead of sys.base_prefix or
sys.base_exec_prefix -- i.e., ignore 'plat_specific'.
"""
if IS_PYPY and sys.version_info < (3, 8):
# PyPy-specific schema
if prefix is None:
prefix = PREFIX
if standard_lib:
return os.path.join(prefix, "lib-python", sys.version[0])
return os.path.join(prefix, 'site-packages')
early_prefix = prefix
if prefix is None:
if standard_lib:
prefix = plat_specific and BASE_EXEC_PREFIX or BASE_PREFIX
else:
prefix = plat_specific and EXEC_PREFIX or PREFIX
if os.name == "posix":
if plat_specific or standard_lib:
# Platform-specific modules (any module from a non-pure-Python
# module distribution) or standard Python library modules.
libdir = getattr(sys, "platlibdir", "lib")
else:
# Pure Python
libdir = "lib"
implementation = 'pypy' if IS_PYPY else 'python'
libpython = os.path.join(prefix, libdir, implementation + get_python_version())
return _posix_lib(standard_lib, libpython, early_prefix, prefix)
elif os.name == "nt":
if standard_lib:
return os.path.join(prefix, "Lib")
else:
return os.path.join(prefix, "Lib", "site-packages")
else:
raise DistutilsPlatformError(
"I don't know where Python installs its library "
"on platform '%s'" % os.name
)
def customize_compiler(compiler): # noqa: C901
"""Do any platform-specific customization of a CCompiler instance.
Mainly needed on Unix, so we can plug in the information that
varies across Unices and is stored in Python's Makefile.
"""
if compiler.compiler_type == "unix":
if sys.platform == "darwin":
# Perform first-time customization of compiler-related
# config vars on OS X now that we know we need a compiler.
# This is primarily to support Pythons from binary
# installers. The kind and paths to build tools on
# the user system may vary significantly from the system
# that Python itself was built on. Also the user OS
# version and build tools may not support the same set
# of CPU architectures for universal builds.
global _config_vars
# Use get_config_var() to ensure _config_vars is initialized.
if not get_config_var('CUSTOMIZED_OSX_COMPILER'):
import _osx_support
_osx_support.customize_compiler(_config_vars)
_config_vars['CUSTOMIZED_OSX_COMPILER'] = 'True'
(
cc,
cxx,
cflags,
ccshared,
ldshared,
shlib_suffix,
ar,
ar_flags,
) = get_config_vars(
'CC',
'CXX',
'CFLAGS',
'CCSHARED',
'LDSHARED',
'SHLIB_SUFFIX',
'AR',
'ARFLAGS',
)
if 'CC' in os.environ:
newcc = os.environ['CC']
if 'LDSHARED' not in os.environ and ldshared.startswith(cc):
# If CC is overridden, use that as the default
# command for LDSHARED as well
ldshared = newcc + ldshared[len(cc) :]
cc = newcc
if 'CXX' in os.environ:
cxx = os.environ['CXX']
if 'LDSHARED' in os.environ:
ldshared = os.environ['LDSHARED']
if 'CPP' in os.environ:
cpp = os.environ['CPP']
else:
cpp = cc + " -E" # not always
if 'LDFLAGS' in os.environ:
ldshared = ldshared + ' ' + os.environ['LDFLAGS']
if 'CFLAGS' in os.environ:
cflags = cflags + ' ' + os.environ['CFLAGS']
ldshared = ldshared + ' ' + os.environ['CFLAGS']
if 'CPPFLAGS' in os.environ:
cpp = cpp + ' ' + os.environ['CPPFLAGS']
cflags = cflags + ' ' + os.environ['CPPFLAGS']
ldshared = ldshared + ' ' + os.environ['CPPFLAGS']
if 'AR' in os.environ:
ar = os.environ['AR']
if 'ARFLAGS' in os.environ:
archiver = ar + ' ' + os.environ['ARFLAGS']
else:
archiver = ar + ' ' + ar_flags
cc_cmd = cc + ' ' + cflags
compiler.set_executables(
preprocessor=cpp,
compiler=cc_cmd,
compiler_so=cc_cmd + ' ' + ccshared,
compiler_cxx=cxx,
linker_so=ldshared,
linker_exe=cc,
archiver=archiver,
)
if 'RANLIB' in os.environ and compiler.executables.get('ranlib', None):
compiler.set_executables(ranlib=os.environ['RANLIB'])
compiler.shared_lib_extension = shlib_suffix
def get_config_h_filename():
"""Return full pathname of installed pyconfig.h file."""
if python_build:
if os.name == "nt":
inc_dir = os.path.join(_sys_home or project_base, "PC")
else:
inc_dir = _sys_home or project_base
return os.path.join(inc_dir, 'pyconfig.h')
else:
return sysconfig.get_config_h_filename()
def get_makefile_filename():
"""Return full pathname of installed Makefile from the Python build."""
return sysconfig.get_makefile_filename()
def parse_config_h(fp, g=None):
"""Parse a config.h-style file.
A dictionary containing name/value pairs is returned. If an
optional dictionary is passed in as the second argument, it is
used instead of a new dictionary.
"""
return sysconfig.parse_config_h(fp, vars=g)
# Regexes needed for parsing Makefile (and similar syntaxes,
# like old-style Setup files).
_variable_rx = re.compile(r"([a-zA-Z][a-zA-Z0-9_]+)\s*=\s*(.*)")
_findvar1_rx = re.compile(r"\$\(([A-Za-z][A-Za-z0-9_]*)\)")
_findvar2_rx = re.compile(r"\${([A-Za-z][A-Za-z0-9_]*)}")
def parse_makefile(fn, g=None): # noqa: C901
"""Parse a Makefile-style file.
A dictionary containing name/value pairs is returned. If an
optional dictionary is passed in as the second argument, it is
used instead of a new dictionary.
"""
from distutils.text_file import TextFile
fp = TextFile(
fn, strip_comments=1, skip_blanks=1, join_lines=1, errors="surrogateescape"
)
if g is None:
g = {}
done = {}
notdone = {}
while True:
line = fp.readline()
if line is None: # eof
break
m = _variable_rx.match(line)
if m:
n, v = m.group(1, 2)
v = v.strip()
# `$$' is a literal `$' in make
tmpv = v.replace('$$', '')
if "$" in tmpv:
notdone[n] = v
else:
try:
v = int(v)
except ValueError:
# insert literal `$'
done[n] = v.replace('$$', '$')
else:
done[n] = v
# Variables with a 'PY_' prefix in the makefile. These need to
# be made available without that prefix through sysconfig.
# Special care is needed to ensure that variable expansion works, even
# if the expansion uses the name without a prefix.
renamed_variables = ('CFLAGS', 'LDFLAGS', 'CPPFLAGS')
# do variable interpolation here
while notdone:
for name in list(notdone):
value = notdone[name]
m = _findvar1_rx.search(value) or _findvar2_rx.search(value)
if m:
n = m.group(1)
found = True
if n in done:
item = str(done[n])
elif n in notdone:
# get it on a subsequent round
found = False
elif n in os.environ:
# do it like make: fall back to environment
item = os.environ[n]
elif n in renamed_variables:
if name.startswith('PY_') and name[3:] in renamed_variables:
item = ""
elif 'PY_' + n in notdone:
found = False
else:
item = str(done['PY_' + n])
else:
done[n] = item = ""
if found:
after = value[m.end() :]
value = value[: m.start()] + item + after
if "$" in after:
notdone[name] = value
else:
try:
value = int(value)
except ValueError:
done[name] = value.strip()
else:
done[name] = value
del notdone[name]
if name.startswith('PY_') and name[3:] in renamed_variables:
name = name[3:]
if name not in done:
done[name] = value
else:
# bogus variable reference; just drop it since we can't deal
del notdone[name]
fp.close()
# strip spurious spaces
for k, v in done.items():
if isinstance(v, str):
done[k] = v.strip()
# save the results in the global dictionary
g.update(done)
return g
def expand_makefile_vars(s, vars):
"""Expand Makefile-style variables -- "${foo}" or "$(foo)" -- in
'string' according to 'vars' (a dictionary mapping variable names to
values). Variables not present in 'vars' are silently expanded to the
empty string. The variable values in 'vars' should not contain further
variable expansions; if 'vars' is the output of 'parse_makefile()',
you're fine. Returns a variable-expanded version of 's'.
"""
# This algorithm does multiple expansion, so if vars['foo'] contains
# "${bar}", it will expand ${foo} to ${bar}, and then expand
# ${bar}... and so forth. This is fine as long as 'vars' comes from
# 'parse_makefile()', which takes care of such expansions eagerly,
# according to make's variable expansion semantics.
while True:
m = _findvar1_rx.search(s) or _findvar2_rx.search(s)
if m:
(beg, end) = m.span()
s = s[0:beg] + vars.get(m.group(1)) + s[end:]
else:
break
return s
_config_vars = None
def get_config_vars(*args):
"""With no arguments, return a dictionary of all configuration
variables relevant for the current platform. Generally this includes
everything needed to build extensions and install both pure modules and
extensions. On Unix, this means every variable defined in Python's
installed Makefile; on Windows it's a much smaller set.
With arguments, return a list of values that result from looking up
each argument in the configuration variable dictionary.
"""
global _config_vars
if _config_vars is None:
_config_vars = sysconfig.get_config_vars().copy()
py39compat.add_ext_suffix(_config_vars)
if args:
vals = []
for name in args:
vals.append(_config_vars.get(name))
return vals
else:
return _config_vars
def get_config_var(name):
"""Return the value of a single variable using the dictionary
returned by 'get_config_vars()'. Equivalent to
get_config_vars().get(name)
"""
if name == 'SO':
import warnings
warnings.warn('SO is deprecated, use EXT_SUFFIX', DeprecationWarning, 2)
return get_config_vars().get(name)
|
castiel248/Convert
|
Lib/site-packages/setuptools/_distutils/sysconfig.py
|
Python
|
mit
| 18,858 |
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