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	import math
	import struct
	import inspect
	from dataclasses import dataclass
	from typing import Any, Optional, Tuple

	import numpy as np
	import torch
	import torch.nn.functional as F
	from torch import nn

	@dataclass
	class ModelArgs:
	# default hyperparameters for the Llama 7B model
	dim: int = 4096
	n_layers: int = 32
	n_heads: int = 32
	n_kv_heads: Optional[int] = None
	vocab_size: int = 32000
	hidden_dim: Optional[int] = None
	multiple_of: int = 256 # MLP hidden layer size will be multiple of
	norm_eps: float = 1e-5
	max_seq_len: int = 2048
	dropout: float = 0.0


	class RMSNorm(torch.nn.Module):
	def __init__(self, dim: int, eps: float):
	super().__init__()
	self.eps = eps
	self.weight = nn.Parameter(torch.ones(dim))

	def _norm(self, x):
	return x * torch.rsqrt(x.pow(2).mean(-1, keepdim=True) + self.eps)

	def forward(self, x):
	output = self._norm(x.float()).type_as(x)
	return output * self.weight


	def precompute_freqs_cis(dim: int, end: int, theta: float = 10000.0):
	freqs = 1.0 / (theta ** (torch.arange(0, dim, 2)[: (dim // 2)].float() / dim))
	t = torch.arange(end, device=freqs.device) # type: ignore
	freqs = torch.outer(t, freqs).float() # type: ignore
	freqs_cos = torch.cos(freqs) # real part
	freqs_sin = torch.sin(freqs) # imaginary part
	return freqs_cos, freqs_sin

	def reshape_for_broadcast(freqs_cis: torch.Tensor, x: torch.Tensor):
	ndim = x.ndim
	assert 0 <= 1 < ndim
	assert freqs_cis.shape == (x.shape[1], x.shape[-1])
	shape = [d if i == 1 or i == ndim - 1 else 1 for i, d in enumerate(x.shape)]
	return freqs_cis.view(shape)

	def apply_rotary_emb(
	xq: torch.Tensor,
	xk: torch.Tensor,
	freqs_cos: torch.Tensor,
	freqs_sin: torch.Tensor
	) -> Tuple[torch.Tensor, torch.Tensor]:

	# reshape xq and xk to match the complex representation
	xq_r, xq_i = xq.float().reshape(xq.shape[:-1] + (-1, 2)).unbind(-1)
	xk_r, xk_i = xk.float().reshape(xk.shape[:-1] + (-1, 2)).unbind(-1)

	# reshape freqs_cos and freqs_sin for broadcasting
	freqs_cos = reshape_for_broadcast(freqs_cos, xq_r)
	freqs_sin = reshape_for_broadcast(freqs_sin, xq_r)

	# apply rotation using real numbers
	xq_out_r = xq_r * freqs_cos - xq_i * freqs_sin
	xq_out_i = xq_r * freqs_sin + xq_i * freqs_cos
	xk_out_r = xk_r * freqs_cos - xk_i * freqs_sin
	xk_out_i = xk_r * freqs_sin + xk_i * freqs_cos

	# flatten last two dimensions
	xq_out = torch.stack([xq_out_r, xq_out_i], dim=-1).flatten(3)
	xk_out = torch.stack([xk_out_r, xk_out_i], dim=-1).flatten(3)

	return xq_out.type_as(xq), xk_out.type_as(xk)

	def repeat_kv(x: torch.Tensor, n_rep: int) -> torch.Tensor:
	"""torch.repeat_interleave(x, dim=2, repeats=n_rep)"""
	bs, slen, n_kv_heads, head_dim = x.shape
	if n_rep == 1:
	return x
	return (
	x[:, :, :, None, :]
	.expand(bs, slen, n_kv_heads, n_rep, head_dim)
	.reshape(bs, slen, n_kv_heads * n_rep, head_dim)
	)

	class Attention(nn.Module):
	def __init__(self, args: ModelArgs):
	super().__init__()
	self.n_kv_heads = args.n_heads if args.n_kv_heads is None else args.n_kv_heads
	assert args.n_heads % self.n_kv_heads == 0
	model_parallel_size = 1
	self.n_local_heads = args.n_heads // model_parallel_size
	self.n_local_kv_heads = self.n_kv_heads // model_parallel_size
	self.n_rep = self.n_local_heads // self.n_local_kv_heads
	self.head_dim = args.dim // args.n_heads
	self.wq = nn.Linear(args.dim, args.n_heads * self.head_dim, bias=False)
	self.wk = nn.Linear(args.dim, self.n_kv_heads * self.head_dim, bias=False)
	self.wv = nn.Linear(args.dim, self.n_kv_heads * self.head_dim, bias=False)
	self.wo = nn.Linear(args.n_heads * self.head_dim, args.dim, bias=False)
	self.attn_dropout = nn.Dropout(args.dropout)
	self.resid_dropout = nn.Dropout(args.dropout)
	self.dropout = args.dropout

	# use flash attention or a manual implementation?
	self.flash = hasattr(torch.nn.functional, 'scaled_dot_product_attention')
	if not self.flash:
	print("WARNING: using slow attention. Flash Attention requires PyTorch >= 2.0")
	mask = torch.full((1, 1, args.max_seq_len, args.max_seq_len), float("-inf"))
	mask = torch.triu(mask, diagonal=1)
	self.register_buffer("mask", mask)

	def forward(
	self,
	x: torch.Tensor,
	freqs_cos: torch.Tensor,
	freqs_sin: torch.Tensor,
	):
	bsz, seqlen, _ = x.shape

	# QKV
	xq, xk, xv = self.wq(x), self.wk(x), self.wv(x)
	xq = xq.view(bsz, seqlen, self.n_local_heads, self.head_dim)
	xk = xk.view(bsz, seqlen, self.n_local_kv_heads, self.head_dim)
	xv = xv.view(bsz, seqlen, self.n_local_kv_heads, self.head_dim)

	# RoPE relative positional embeddings
	xq, xk = apply_rotary_emb(xq, xk, freqs_cos, freqs_sin)

	# grouped multiquery attention: expand out keys and values
	xk = repeat_kv(xk, self.n_rep) # (bs, seqlen, n_local_heads, head_dim)
	xv = repeat_kv(xv, self.n_rep) # (bs, seqlen, n_local_heads, head_dim)

	# make heads into a batch dimension
	xq = xq.transpose(1, 2) # (bs, n_local_heads, seqlen, head_dim)
	xk = xk.transpose(1, 2)
	xv = xv.transpose(1, 2)

	# flash implementation
	if self.flash:
	output = torch.nn.functional.scaled_dot_product_attention(xq, xk, xv, attn_mask=None, dropout_p=self.dropout if self.training else 0.0, is_causal=True)
	else:
	# manual implementation
	scores = torch.matmul(xq, xk.transpose(2, 3)) / math.sqrt(self.head_dim)
	assert hasattr(self, 'mask')
	scores = scores + self.mask[:, :, :seqlen, :seqlen] # (bs, n_local_heads, seqlen, cache_len + seqlen)
	scores = F.softmax(scores.float(), dim=-1).type_as(xq)
	scores = self.attn_dropout(scores)
	output = torch.matmul(scores, xv) # (bs, n_local_heads, seqlen, head_dim)

	# restore time as batch dimension and concat heads
	output = output.transpose(1, 2).contiguous().view(bsz, seqlen, -1)

	# final projection into the residual stream
	output = self.wo(output)
	output = self.resid_dropout(output)
	return output


	class FeedForward(nn.Module):
	def __init__(self, dim: int, hidden_dim: int, multiple_of: int, dropout: float):
	super().__init__()
	if hidden_dim is None:
	hidden_dim = 4 * dim
	hidden_dim = int(2 * hidden_dim / 3)
	hidden_dim = multiple_of * ((hidden_dim + multiple_of - 1) // multiple_of)
	self.w1 = nn.Linear(dim, hidden_dim, bias=False)
	self.w2 = nn.Linear(hidden_dim, dim, bias=False)
	self.w3 = nn.Linear(dim, hidden_dim, bias=False)
	self.dropout = nn.Dropout(dropout)

	def forward(self, x):
	return self.dropout(self.w2(F.silu(self.w1(x)) * self.w3(x)))


	class TransformerBlock(nn.Module):
	def __init__(self, layer_id: int, args: ModelArgs):
	super().__init__()
	self.n_heads = args.n_heads
	self.dim = args.dim
	self.head_dim = args.dim // args.n_heads
	self.attention = Attention(args)
	self.feed_forward = FeedForward(
	dim=args.dim,
	hidden_dim=args.hidden_dim,
	multiple_of=args.multiple_of,
	dropout=args.dropout,
	)
	self.layer_id = layer_id
	self.attention_norm = RMSNorm(args.dim, eps=args.norm_eps)
	self.ffn_norm = RMSNorm(args.dim, eps=args.norm_eps)

	def forward(self, x, freqs_cos, freqs_sin):
	h = x + self.attention.forward(self.attention_norm(x), freqs_cos, freqs_sin)
	out = h + self.feed_forward.forward(self.ffn_norm(h))
	return out


	class Transformer(nn.Module):
	last_loss: Optional[torch.Tensor]

	def __init__(self, params: ModelArgs):
	super().__init__()
	self.params = params
	self.vocab_size = params.vocab_size
	self.n_layers = params.n_layers

	self.tok_embeddings = nn.Embedding(params.vocab_size, params.dim)
	self.dropout = nn.Dropout(params.dropout)
	self.layers = torch.nn.ModuleList()
	for layer_id in range(params.n_layers):
	self.layers.append(TransformerBlock(layer_id, params))
	self.norm = RMSNorm(params.dim, eps=params.norm_eps)
	self.output = nn.Linear(params.dim, params.vocab_size, bias=False)

	# share the unembedding parameters with the embedding parameters
	self.tok_embeddings.weight = self.output.weight # https://paperswithcode.com/method/weight-tying

	# some useful precompute for the RoPE relative positional embeddings
	freqs_cos, freqs_sin = precompute_freqs_cis(self.params.dim // self.params.n_heads, self.params.max_seq_len)
	self.register_buffer("freqs_cos", freqs_cos, persistent=False)
	self.register_buffer("freqs_sin", freqs_sin, persistent=False)

	# init all weights
	self.apply(self._init_weights)
	# apply special scaled init to the residual projections, per GPT-2 paper
	for pn, p in self.named_parameters():
	if pn.endswith('w3.weight') or pn.endswith('wo.weight'):
	torch.nn.init.normal_(p, mean=0.0, std=0.02/math.sqrt(2 * params.n_layers))

	# Initialize attribute for the loss of the last forward call. This will be set if the forward is called with a targets tensor.
	self.last_loss = None

	def _init_weights(self, module):
	if isinstance(module, nn.Linear):
	torch.nn.init.normal_(module.weight, mean=0.0, std=0.02)
	if module.bias is not None:
	torch.nn.init.zeros_(module.bias)
	elif isinstance(module, nn.Embedding):
	torch.nn.init.normal_(module.weight, mean=0.0, std=0.02)

	def forward(self, tokens: torch.Tensor, targets: Optional[torch.Tensor] = None) -> torch.Tensor:
	_bsz, seqlen = tokens.shape
	h = self.tok_embeddings(tokens)
	h = self.dropout(h)
	freqs_cos = self.freqs_cos[:seqlen]
	freqs_sin = self.freqs_sin[:seqlen]

	for layer in self.layers:
	h = layer(h, freqs_cos, freqs_sin)
	h = self.norm(h)

	if targets is not None:
	# if we are given some desired targets also calculate the loss
	logits = self.output(h)
	self.last_loss = F.cross_entropy(logits.view(-1, logits.size(-1)), targets.view(-1), ignore_index=-1)
	else:
	# inference-time mini-optimization: only forward the output on the very last position
	logits = self.output(h[:, [-1], :]) # note: using list [-1] to preserve the time dim
	self.last_loss = None

	return logits

	def configure_optimizers(self, weight_decay, learning_rate, betas, device_type):
	# start with all of the candidate parameters
	param_dict = {pn: p for pn, p in self.named_parameters()}
	# filter out those that do not require grad
	param_dict = {pn: p for pn, p in param_dict.items() if p.requires_grad}
	# create optim groups. Any parameters that is 2D will be weight decayed, otherwise no.
	# i.e. all weight tensors in matmuls + embeddings decay, all biases and layernorms don't.
	decay_params = [p for n, p in param_dict.items() if p.dim() >= 2]
	nodecay_params = [p for n, p in param_dict.items() if p.dim() < 2]
	optim_groups = [
	{'params': decay_params, 'weight_decay': weight_decay},
	{'params': nodecay_params, 'weight_decay': 0.0}
	]
	num_decay_params = sum(p.numel() for p in decay_params)
	num_nodecay_params = sum(p.numel() for p in nodecay_params)
	print(f"num decayed parameter tensors: {len(decay_params)}, with {num_decay_params:,} parameters")
	print(f"num non-decayed parameter tensors: {len(nodecay_params)}, with {num_nodecay_params:,} parameters")
	# Create AdamW optimizer and use the fused version if it is available
	fused_available = 'fused' in inspect.signature(torch.optim.AdamW).parameters
	use_fused = fused_available and device_type == 'cuda'
	extra_args = dict(fused=True) if use_fused else dict()
	optimizer = torch.optim.AdamW(optim_groups, lr=learning_rate, betas=betas, **extra_args)
	print(f"using fused AdamW: {use_fused}")

	return optimizer

	def estimate_mfu(self, fwdbwd_per_iter, dt):
	""" estimate model flops utilization (MFU) in units of A100 bfloat16 peak FLOPS """
	# first estimate the number of flops we do per iteration.
	# see PaLM paper Appendix B as ref: https://arxiv.org/abs/2204.02311
	N = sum(p.numel() for p in self.parameters())
	cfg = self.params
	L, H, Q, T = cfg.n_layers, cfg.n_heads, cfg.dim//cfg.n_heads, cfg.max_seq_len
	flops_per_token = 6N + 12LHQ*T
	flops_per_fwdbwd = flops_per_token * T
	flops_per_iter = flops_per_fwdbwd * fwdbwd_per_iter
	# express our flops throughput as ratio of A100 bfloat16 peak flops
	flops_achieved = flops_per_iter * (1.0/dt) # per second
	flops_promised = 312e12 # A100 GPU bfloat16 peak flops is 312 TFLOPS
	mfu = flops_achieved / flops_promised
	return mfu

	@torch.inference_mode()
	def generate(self, idx, max_new_tokens, temperature=1.0, top_k=None):
	"""
	Take a conditioning sequence of indices idx (LongTensor of shape (b,t)) and complete
	the sequence max_new_tokens times, feeding the predictions back into the model each time.
	Most likely you'll want to make sure to be in model.eval() mode of operation for this.
	Also note this is a super inefficient version of sampling with no key/value cache.
	"""
	for _ in range(max_new_tokens):
	# if the sequence context is growing too long we must crop it at block_size
	idx_cond = idx if idx.size(1) <= self.params.max_seq_len else idx[:, -self.params.max_seq_len:]
	# forward the model to get the logits for the index in the sequence
	logits = self(idx_cond)
	logits = logits[:, -1, :] # crop to just the final time step
	if temperature == 0.0:
	# "sample" the single most likely index
	_, idx_next = torch.topk(logits, k=1, dim=-1)
	else:
	# pluck the logits at the final step and scale by desired temperature
	logits = logits / temperature
	# optionally crop the logits to only the top k options
	if top_k is not None:
	v, _ = torch.topk(logits, min(top_k, logits.size(-1)))
	logits[logits < v[:, [-1]]] = -float('Inf')
	# apply softmax to convert logits to (normalized) probabilities
	probs = F.softmax(logits, dim=-1)
	idx_next = torch.multinomial(probs, num_samples=1)
	# append sampled index to the running sequence and continue
	idx = torch.cat((idx, idx_next), dim=1)

	return idx