parameter-golf-scylla / code /train_gpt_window.py

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	from __future__ import annotations
	import copy
	import glob
	import io
	import lzma
	import math
	import os
	import random
	import subprocess
	import sys
	import time
	import uuid
	from pathlib import Path
	import numpy as np
	import sentencepiece as spm
	import torch
	import torch.distributed as dist
	import torch.nn.functional as F
	from torch import Tensor, nn
	from torch.nn.parallel import DistributedDataParallel as DDP
	from flash_attn_interface import flash_attn_func as flash_attn_3_func
	class Hyperparameters:
	data_path = os.environ.get("DATA_PATH", "./data/datasets/fineweb10B_sp1024")
	train_files = os.path.join(data_path, "fineweb_train_*.bin")
	val_files = os.path.join(data_path, "fineweb_val_*.bin")
	tokenizer_path = os.environ.get("TOKENIZER_PATH", "./data/tokenizers/fineweb_1024_bpe.model")
	run_id = os.environ.get("RUN_ID", str(uuid.uuid4()))
	seed = int(os.environ.get("SEED", 1337))
	val_batch_size = int(os.environ.get("VAL_BATCH_SIZE", 524_288))
	val_loss_every = int(os.environ.get("VAL_LOSS_EVERY", 4000))
	train_log_every = int(os.environ.get("TRAIN_LOG_EVERY", 500))
	iterations = int(os.environ.get("ITERATIONS", 20000))
	warmdown_iters = int(os.environ.get("WARMDOWN_ITERS", 3500))
	warmup_steps = int(os.environ.get("WARMUP_STEPS", 20))
	train_batch_tokens = int(os.environ.get("TRAIN_BATCH_TOKENS", 786_432))
	train_seq_len = int(os.environ.get("TRAIN_SEQ_LEN", 2048))
	eval_seq_len = int(os.environ.get("EVAL_SEQ_LEN", 2048))
	max_wallclock_seconds = float(os.environ.get("MAX_WALLCLOCK_SECONDS", 600.0))
	qk_gain_init = float(os.environ.get("QK_GAIN_INIT", 1.5))
	vocab_size = int(os.environ.get("VOCAB_SIZE", 1024))
	num_layers = int(os.environ.get("NUM_LAYERS", 11))
	num_kv_heads = int(os.environ.get("NUM_KV_HEADS", 4))
	model_dim = int(os.environ.get("MODEL_DIM", 512))
	num_heads = int(os.environ.get("NUM_HEADS", 8))
	mlp_mult = float(os.environ.get("MLP_MULT", 3.0))
	tie_embeddings = bool(int(os.environ.get("TIE_EMBEDDINGS", "1")))
	rope_base = float(os.environ.get("ROPE_BASE", 10000.0))
	logit_softcap = float(os.environ.get("LOGIT_SOFTCAP", 30.0))
	embed_lr = float(os.environ.get("EMBED_LR", 0.6))
	head_lr = float(os.environ.get("HEAD_LR", 0.008))
	tied_embed_lr = float(os.environ.get("TIED_EMBED_LR", 0.035))
	tied_embed_init_std = float(os.environ.get("TIED_EMBED_INIT_STD", 0.005))
	matrix_lr = float(os.environ.get("MATRIX_LR", 0.025))
	scalar_lr = float(os.environ.get("SCALAR_LR", 0.025))
	muon_momentum = float(os.environ.get("MUON_MOMENTUM", 0.99))
	muon_backend_steps = int(os.environ.get("MUON_BACKEND_STEPS", 5))
	muon_momentum_warmup_start = float(os.environ.get("MUON_MOMENTUM_WARMUP_START", 0.92))
	muon_momentum_warmup_steps = int(os.environ.get("MUON_MOMENTUM_WARMUP_STEPS", 1500))
	beta1 = float(os.environ.get("BETA1", 0.9))
	beta2 = float(os.environ.get("BETA2", 0.95))
	adam_eps = float(os.environ.get("ADAM_EPS", 1e-8))
	grad_clip_norm = float(os.environ.get("GRAD_CLIP_NORM", 0.3))
	eval_stride = int(os.environ.get("EVAL_STRIDE", 64))
	muon_beta2 = float(os.environ.get("MUON_BETA2", 0.95))
	swa_enabled = bool(int(os.environ.get("SWA_ENABLED", "1")))
	swa_every = int(os.environ.get("SWA_EVERY", 50))
	muon_wd = float(os.environ.get("MUON_WD", 0.04))
	adam_wd = float(os.environ.get("ADAM_WD", 0.04))
	bigram_vocab_size = int(os.environ.get("BIGRAM_VOCAB_SIZE", 2048))
	bigram_dim = int(os.environ.get("BIGRAM_DIM", 128))
	xsa_last_n = int(os.environ.get("XSA_LAST_N", 4))
	rope_dims = int(os.environ.get("ROPE_DIMS", 16))
	ln_scale = bool(int(os.environ.get("LN_SCALE", "1")))
	ve_enabled = bool(int(os.environ.get("VE_ENABLED", "1")))
	ve_dim = int(os.environ.get("VE_DIM", 128))
	ve_layers = os.environ.get("VE_LAYERS", "9,10")
	ttt_enabled = bool(int(os.environ.get("TTT_ENABLED", "0")))
	ttt_lr = float(os.environ.get("TTT_LR", 0.002))
	ttt_epochs = int(os.environ.get("TTT_EPOCHS", 3))
	ttt_chunk_tokens = int(os.environ.get("TTT_CHUNK_TOKENS", 32768))
	ttt_freeze_blocks = int(os.environ.get("TTT_FREEZE_BLOCKS", 2))
	ttt_momentum = float(os.environ.get("TTT_MOMENTUM", 0.9))
	ttt_batch_seqs = int(os.environ.get("TTT_BATCH_SEQS", 32))
	ttt_grad_clip = float(os.environ.get("TTT_GRAD_CLIP", 1.0))
	negative_slope = float(os.environ.get("NEGATIVE_SLOPE", 0.5))
	window_attn_size = int(os.environ.get("WINDOW_ATTN_SIZE", 0)) # 0=disabled, 512=recommended
	window_attn_layers = os.environ.get("WINDOW_ATTN_LAYERS", "2,4,6,8,10") # which layers get window
	num_sink_tokens = int(os.environ.get("NUM_SINK_TOKENS", 0)) # 0=disabled, 4=recommended
	train_seq_len_long = int(os.environ.get("TRAIN_SEQ_LEN_LONG", 0)) # 0=disabled, 6144=recommended
	num_gpus_long = int(os.environ.get("NUM_GPUS_LONG", 0)) # how many GPUs train at long seq_len
	use_gptq = bool(int(os.environ.get("USE_GPTQ", "0")))
	gptq_calib_samples = int(os.environ.get("GPTQ_CALIB_SAMPLES", "64"))
	gptq_reserve_ms = float(os.environ.get("GPTQ_RESERVE_MS", "14000"))
	quant_clip_range = int(os.environ.get("QUANT_CLIP_RANGE", 31))
	tokenizer_meta_path = os.environ.get("TOKENIZER_META_PATH", "")
	tokenizer_meta_validate = bool(int(os.environ.get("TOKENIZER_META_VALIDATE", "0")))

	# --- Batched Newton-Schulz orthogonalization ---

	def zeropower_via_newtonschulz5(G: Tensor, steps: int = 5, eps: float = 1e-7) -> Tensor:
	"""Batched Newton-Schulz orthogonalization. G: (B,M,N) or (M,N)."""
	a, b, c = (3.4445, -4.7750, 2.0315)
	was_2d = G.ndim == 2
	if was_2d:
	G = G.unsqueeze(0)
	X = G.bfloat16()
	transposed = X.size(-2) > X.size(-1)
	if transposed:
	X = X.mT
	X = X / (X.norm(dim=(-2, -1), keepdim=True) + eps)
	for _ in range(steps):
	A = X @ X.mT
	B = b * A + c * (A @ A)
	X = a * X + B @ X
	if transposed:
	X = X.mT
	if was_2d:
	X = X.squeeze(0)
	return X

	# --- Parallel Muon optimizer ---

	class Muon(torch.optim.Optimizer):
	"""Parallel Muon: post-backward reduce-scatter -> local NS5 -> all-gather.

	No DDP for bank params. After backward, this optimizer:
	1. Launches async reduce-scatter for all banks (biggest first)
	2. Returns control so Adam can step on small params while RS is in-flight
	3. Waits for each RS, runs local NS5 on the shard, launches async all-gather
	4. Each all-gather overlaps with next bank's NS5
	"""
	def __init__(self, params, lr: float, momentum: float, backend_steps: int,
	nesterov: bool = True, weight_decay: float = 0.0):
	super().__init__(
	params,
	dict(lr=lr, momentum=momentum, backend_steps=backend_steps,
	nesterov=nesterov, weight_decay=weight_decay),
	)
	self._built = False

	def _build(self):
	self._distributed = dist.is_available() and dist.is_initialized()
	self._world_size = dist.get_world_size() if self._distributed else 1
	self._rank = dist.get_rank() if self._distributed else 0
	ws = self._world_size

	self._bank_meta = []
	for group in self.param_groups:
	for p in group["params"]:
	B = p.shape[0]
	padded_B = ((B + ws - 1) // ws) * ws
	shard_B = padded_B // ws
	tail = p.shape[1:]
	dev = p.device
	self._bank_meta.append({
	'p': p,
	'B': B,
	'padded_grad': torch.zeros(padded_B, *tail, device=dev, dtype=torch.bfloat16),
	'shard': torch.zeros(shard_B, *tail, device=dev, dtype=torch.bfloat16),
	'shard_mom': torch.zeros(shard_B, *tail, device=dev, dtype=torch.bfloat16),
	'full_update': torch.zeros(padded_B, *tail, device=dev, dtype=torch.bfloat16),
	'scale': max(1, p.shape[-2] / p.shape[-1]) ** 0.5,
	})
	# Sort by size descending -- launch biggest reduce-scatters first
	self._bank_meta.sort(key=lambda m: -m['p'].numel())
	self._built = True

	def launch_reduce_scatters(self):
	"""Phase 1: launch async reduce-scatter for all banks. Call right after backward."""
	if not self._built:
	self._build()
	if not self._distributed:
	return
	self._rs_futures = []
	for m in self._bank_meta:
	p = m['p']
	if p.grad is None:
	self._rs_futures.append(None)
	continue
	pg = m['padded_grad']
	pg[:m['B']].copy_(p.grad.bfloat16())
	if pg.shape[0] > m['B']:
	pg[m['B']:].zero_()
	fut = dist.reduce_scatter_tensor(m['shard'], pg, op=dist.ReduceOp.AVG, async_op=True)
	self._rs_futures.append(fut)

	@torch.no_grad()
	def step(self, closure=None):
	"""Phase 3: wait for RS, local NS5, all-gather. Call AFTER Adam steps."""
	loss = None
	if closure is not None:
	with torch.enable_grad():
	loss = closure()

	if not self._built:
	self._build()

	for group in self.param_groups:
	lr = group["lr"]
	momentum = group["momentum"]
	backend_steps = group["backend_steps"]
	nesterov = group["nesterov"]
	wd = group.get("weight_decay", 0.0)

	prev_ag_handle = None
	prev_m = None

	sharded = self._distributed and hasattr(self, '_rs_futures')

	for i, m in enumerate(self._bank_meta):
	p = m['p']
	if p.grad is None:
	continue

	if prev_ag_handle is not None:
	prev_ag_handle.wait()
	pp = prev_m['p']
	upd = prev_m['full_update'][:prev_m['B']]
	if wd > 0.0:
	pp.data.mul_(1.0 - lr * wd)
	pp.add_(upd.to(dtype=pp.dtype), alpha=-lr * prev_m['scale'])

	if sharded and self._rs_futures[i] is not None:
	self._rs_futures[i].wait()
	g = m['shard']
	buf = m['shard_mom']
	else:
	g = p.grad.bfloat16()
	state = self.state[p]
	if "momentum_buffer" not in state:
	state["momentum_buffer"] = torch.zeros_like(g)
	buf = state["momentum_buffer"]

	buf.mul_(momentum).add_(g)
	if nesterov:
	update = g.add(buf, alpha=momentum)
	else:
	update = buf

	update = zeropower_via_newtonschulz5(update, steps=backend_steps)

	if sharded:
	prev_ag_handle = dist.all_gather_into_tensor(
	m['full_update'], update, async_op=True)
	prev_m = m
	else:
	if wd > 0.0:
	p.data.mul_(1.0 - lr * wd)
	p.add_(update.to(dtype=p.dtype), alpha=-lr * m['scale'])

	if prev_ag_handle is not None:
	prev_ag_handle.wait()
	pp = prev_m['p']
	upd = prev_m['full_update'][:prev_m['B']]
	if wd > 0.0:
	pp.data.mul_(1.0 - lr * wd)
	pp.add_(upd.to(dtype=pp.dtype), alpha=-lr * prev_m['scale'])

	if hasattr(self, '_rs_futures'):
	del self._rs_futures

	return loss

	# --- Tokenizer evaluation helpers ---

	def build_sentencepiece_luts(
	sp: spm.SentencePieceProcessor, vocab_size: int, device: torch.device
	) -> tuple[Tensor, Tensor, Tensor]:
	sp_vocab_size = int(sp.vocab_size())
	table_size = max(sp_vocab_size, vocab_size)
	base_bytes_np = np.zeros((table_size,), dtype=np.int16)
	has_leading_space_np = np.zeros((table_size,), dtype=np.bool_)
	is_boundary_token_np = np.ones((table_size,), dtype=np.bool_)
	for token_id in range(sp_vocab_size):
	if sp.is_control(token_id) or sp.is_unknown(token_id) or sp.is_unused(token_id):
	continue
	is_boundary_token_np[token_id] = False
	if sp.is_byte(token_id):
	base_bytes_np[token_id] = 1
	continue
	piece = sp.id_to_piece(token_id)
	if piece.startswith("\u2581"):
	has_leading_space_np[token_id] = True
	piece = piece[1:]
	base_bytes_np[token_id] = len(piece.encode("utf-8"))
	return (
	torch.tensor(base_bytes_np, dtype=torch.int16, device=device),
	torch.tensor(has_leading_space_np, dtype=torch.bool, device=device),
	torch.tensor(is_boundary_token_np, dtype=torch.bool, device=device),
	)

	TOKENIZER_META_FORMAT_VERSION = 1
	TOKENIZER_META_SUFFIX = ".meta.npz"


	def _derive_tokenizer_meta_path(tokenizer_path: str) -> Path:
	tokenizer = Path(tokenizer_path)
	if tokenizer.suffix == ".model":
	return tokenizer.with_suffix(TOKENIZER_META_SUFFIX)
	return tokenizer.with_name(tokenizer.name + TOKENIZER_META_SUFFIX)


	def build_sentencepiece_luts_np(
	sp: spm.SentencePieceProcessor, vocab_size: int
	) -> tuple[np.ndarray, np.ndarray, np.ndarray]:
	sp_vocab_size = int(sp.vocab_size())
	table_size = max(sp_vocab_size, vocab_size)
	base_bytes_np = np.zeros((table_size,), dtype=np.int16)
	has_leading_space_np = np.zeros((table_size,), dtype=np.bool_)
	is_boundary_token_np = np.ones((table_size,), dtype=np.bool_)
	for token_id in range(sp_vocab_size):
	if sp.is_control(token_id) or sp.is_unknown(token_id) or sp.is_unused(token_id):
	continue
	is_boundary_token_np[token_id] = False
	if sp.is_byte(token_id):
	base_bytes_np[token_id] = 1
	continue
	piece = sp.id_to_piece(token_id)
	if piece.startswith("\u2581"):
	has_leading_space_np[token_id] = True
	piece = piece[1:]
	base_bytes_np[token_id] = len(piece.encode("utf-8"))
	return base_bytes_np, has_leading_space_np, is_boundary_token_np


	def load_tokenizer_meta_luts_np(
	meta_path: Path, vocab_size: int
	) -> tuple[np.ndarray, np.ndarray, np.ndarray, dict[str, object]]:
	def _scalar(value):
	arr = np.asarray(value)
	if arr.ndim == 0:
	return arr.item()
	first = arr.reshape(-1)[0]
	return first.item() if hasattr(first, "item") else first

	with np.load(meta_path, allow_pickle=False) as data:
	format_version = int(_scalar(data["format_version"]))
	if format_version != TOKENIZER_META_FORMAT_VERSION:
	raise ValueError(
	f"Unsupported tokenizer meta format_version={format_version} "
	f"expected={TOKENIZER_META_FORMAT_VERSION}"
	)
	meta_vocab_size = int(_scalar(data["vocab_size"]))
	tokenizer_kind = str(_scalar(data["tokenizer_kind"]))
	source_model_name = str(_scalar(data["source_model_name"]))
	base_bytes_np = np.asarray(data["base_bytes"], dtype=np.int16)
	has_leading_space_np = np.asarray(data["has_leading_space"], dtype=np.bool_)
	is_boundary_token_np = np.asarray(data["is_boundary_token"], dtype=np.bool_)
	table_size = max(meta_vocab_size, vocab_size)
	if base_bytes_np.shape[0] < table_size:
	padded_base_bytes = np.zeros((table_size,), dtype=np.int16)
	padded_has_leading_space = np.zeros((table_size,), dtype=np.bool_)
	padded_is_boundary = np.ones((table_size,), dtype=np.bool_)
	padded_base_bytes[: base_bytes_np.shape[0]] = base_bytes_np
	padded_has_leading_space[: has_leading_space_np.shape[0]] = has_leading_space_np
	padded_is_boundary[: is_boundary_token_np.shape[0]] = is_boundary_token_np
	base_bytes_np = padded_base_bytes
	has_leading_space_np = padded_has_leading_space
	is_boundary_token_np = padded_is_boundary
	metadata = {
	"format_version": format_version,
	"tokenizer_kind": tokenizer_kind,
	"source_model_name": source_model_name,
	"vocab_size": meta_vocab_size,
	"meta_path": str(meta_path),
	}
	return base_bytes_np, has_leading_space_np, is_boundary_token_np, metadata


	def load_tokenizer_luts(
	tokenizer_path: str,
	tokenizer_meta_path: str,
	vocab_size: int,
	device: torch.device,
	*,
	validate_meta: bool = False,
	) -> tuple[tuple[Tensor, Tensor, Tensor], dict[str, object]]:
	meta_path = (
	Path(tokenizer_meta_path) if tokenizer_meta_path
	else _derive_tokenizer_meta_path(tokenizer_path)
	)
	if meta_path.exists():
	base_bytes_np, has_leading_space_np, is_boundary_token_np, metadata = (
	load_tokenizer_meta_luts_np(meta_path, vocab_size)
	)
	if validate_meta and str(tokenizer_path).endswith(".model"):
	sp = spm.SentencePieceProcessor(model_file=tokenizer_path)
	sp_luts = build_sentencepiece_luts_np(sp, vocab_size)
	if not (
	np.array_equal(base_bytes_np, sp_luts[0])
	and np.array_equal(has_leading_space_np, sp_luts[1])
	and np.array_equal(is_boundary_token_np, sp_luts[2])
	):
	raise ValueError(f"Tokenizer metadata mismatch for {meta_path}")
	return (
	torch.tensor(base_bytes_np, dtype=torch.int16, device=device),
	torch.tensor(has_leading_space_np, dtype=torch.bool, device=device),
	torch.tensor(is_boundary_token_np, dtype=torch.bool, device=device),
	), metadata
	if not str(tokenizer_path).endswith(".model"):
	raise FileNotFoundError(f"TOKENIZER_META_PATH does not exist: {meta_path}")
	sp = spm.SentencePieceProcessor(model_file=tokenizer_path)
	return build_sentencepiece_luts(sp, vocab_size, device), {
	"tokenizer_kind": "sentencepiece",
	"source_model_name": str(tokenizer_path),
	"vocab_size": int(sp.vocab_size()),
	"meta_path": None,
	"fallback": True,
	}

	def load_validation_tokens(pattern: str, seq_len: int) -> Tensor:
	files = [Path(p) for p in sorted(glob.glob(pattern))]
	if not files:
	raise FileNotFoundError(f"No files found for pattern: {pattern}")
	tokens = torch.cat([load_data_shard(file) for file in files]).contiguous()
	usable = ((tokens.numel() - 1) // seq_len) * seq_len
	if usable <= 0:
	raise ValueError(f"Validation split is too short for TRAIN_SEQ_LEN={seq_len}")
	return tokens[: usable + 1]
	def eval_val(
	args: Hyperparameters,
	model: nn.Module,
	rank: int,
	world_size: int,
	device: torch.device,
	grad_accum_steps: int,
	val_tokens: Tensor,
	base_bytes_lut: Tensor,
	has_leading_space_lut: Tensor,
	is_boundary_token_lut: Tensor,
	eval_seq_len: int \| None = None,
	) -> tuple[float, float]:
	seq_len = eval_seq_len or args.train_seq_len
	local_batch_tokens = args.val_batch_size // (world_size * grad_accum_steps)
	if local_batch_tokens < seq_len:
	raise ValueError(
	"VAL_BATCH_SIZE must provide at least one sequence per rank; "
	f"got VAL_BATCH_SIZE={args.val_batch_size}, WORLD_SIZE={world_size}, "
	f"GRAD_ACCUM_STEPS={grad_accum_steps}, seq_len={seq_len}"
	)
	local_batch_seqs = local_batch_tokens // seq_len
	total_seqs = (val_tokens.numel() - 1) // seq_len
	seq_start = (total_seqs * rank) // world_size
	seq_end = (total_seqs * (rank + 1)) // world_size
	val_loss_sum = torch.zeros((), device=device, dtype=torch.float64)
	val_token_count = torch.zeros((), device=device, dtype=torch.float64)
	val_byte_count = torch.zeros((), device=device, dtype=torch.float64)
	model.eval()
	with torch.inference_mode():
	for batch_seq_start in range(seq_start, seq_end, local_batch_seqs):
	batch_seq_end = min(batch_seq_start + local_batch_seqs, seq_end)
	raw_start = batch_seq_start * seq_len
	raw_end = batch_seq_end * seq_len + 1
	local = val_tokens[raw_start:raw_end].to(device=device, dtype=torch.int64, non_blocking=True)
	x = local[:-1].reshape(-1, seq_len)
	y = local[1:].reshape(-1, seq_len)
	with torch.autocast(device_type="cuda", dtype=torch.bfloat16, enabled=True):
	batch_loss = model(x, y).detach()
	batch_token_count = float(y.numel())
	val_loss_sum += batch_loss.to(torch.float64) * batch_token_count
	val_token_count += batch_token_count
	prev_ids = x.reshape(-1)
	tgt_ids = y.reshape(-1)
	token_bytes = base_bytes_lut[tgt_ids].to(dtype=torch.int16)
	token_bytes += (has_leading_space_lut[tgt_ids] & ~is_boundary_token_lut[prev_ids]).to(dtype=torch.int16)
	val_byte_count += token_bytes.to(torch.float64).sum()
	if dist.is_available() and dist.is_initialized():
	dist.all_reduce(val_loss_sum, op=dist.ReduceOp.SUM)
	dist.all_reduce(val_token_count, op=dist.ReduceOp.SUM)
	dist.all_reduce(val_byte_count, op=dist.ReduceOp.SUM)
	val_loss = val_loss_sum / val_token_count
	bits_per_token = val_loss.item() / math.log(2.0)
	tokens_per_byte = val_token_count.item() / val_byte_count.item()
	model.train()
	return float(val_loss.item()), float(bits_per_token * tokens_per_byte)

	# --- Quantization helpers ---

	CONTROL_TENSOR_NAME_PATTERNS = tuple(
	pattern
	for pattern in os.environ.get(
	"CONTROL_TENSOR_NAME_PATTERNS",
	"attn_scale,attn_scales,mlp_scale,mlp_scales,resid_mix,resid_mixes,q_gain,skip_weight,skip_weights,smear,dtg_gate,ve_layer_scales,ve_shared.scale,attn_gate,vr_lambda",
	).split(",")
	if pattern
	)
	INT8_KEEP_FLOAT_FP32_NAME_PATTERNS = tuple(
	pattern
	for pattern in os.environ.get(
	"INT8_KEEP_FLOAT_FP32_NAME_PATTERNS",
	",".join(CONTROL_TENSOR_NAME_PATTERNS),
	).split(",")
	if pattern
	)
	INT8_KEEP_FLOAT_MAX_NUMEL = 65_536
	INT8_KEEP_FLOAT_STORE_DTYPE = torch.float16
	INT8_PER_ROW_SCALE_DTYPE = torch.float16
	INT8_CLIP_PERCENTILE = 99.99984
	INT8_CLIP_Q = INT8_CLIP_PERCENTILE / 100.0
	def tensor_nbytes(t: Tensor) -> int:
	return int(t.numel()) * int(t.element_size())
	def keep_float_tensor(name: str, t: Tensor, passthrough_orig_dtypes: dict[str, str]) -> Tensor:
	if any(pattern in name for pattern in INT8_KEEP_FLOAT_FP32_NAME_PATTERNS):
	return t.float().contiguous()
	if t.dtype in {torch.float32, torch.bfloat16}:
	passthrough_orig_dtypes[name] = str(t.dtype).removeprefix("torch.")
	return t.to(dtype=INT8_KEEP_FLOAT_STORE_DTYPE).contiguous()
	return t
	def quantize_float_tensor(t: Tensor) -> tuple[Tensor, Tensor]:
	t32 = t.float()
	if t32.ndim == 2:
	clip_abs = (
	torch.quantile(t32.abs(), INT8_CLIP_Q, dim=1)
	if t32.numel()
	else torch.empty((t32.shape[0],), dtype=torch.float32)
	)
	clipped = torch.maximum(torch.minimum(t32, clip_abs[:, None]), -clip_abs[:, None])
	scale = (clip_abs / 127.0).clamp_min(1.0 / 127.0)
	q = torch.clamp(torch.round(clipped / scale[:, None]), -127, 127).to(torch.int8).contiguous()
	return q, scale.to(dtype=INT8_PER_ROW_SCALE_DTYPE).contiguous()
	clip_abs = float(torch.quantile(t32.abs().flatten(), INT8_CLIP_Q).item()) if t32.numel() else 0.0
	scale = torch.tensor(clip_abs / 127.0 if clip_abs > 0 else 1.0, dtype=torch.float32)
	q = torch.clamp(torch.round(torch.clamp(t32, -clip_abs, clip_abs) / scale), -127, 127).to(torch.int8).contiguous()
	return q, scale
	def quantize_state_dict_int8(state_dict: dict[str, Tensor]):
	quantized: dict[str, Tensor] = {}
	scales: dict[str, Tensor] = {}
	dtypes: dict[str, str] = {}
	passthrough: dict[str, Tensor] = {}
	passthrough_orig_dtypes: dict[str, str] = {}
	qmeta: dict[str, dict[str, object]] = {}
	stats = dict.fromkeys(
	("param_count", "num_tensors", "num_float_tensors", "num_nonfloat_tensors", "baseline_tensor_bytes", "int8_payload_bytes"),
	0,
	)
	for name, tensor in state_dict.items():
	t = tensor.detach().to("cpu").contiguous()
	stats["param_count"] += int(t.numel())
	stats["num_tensors"] += 1
	stats["baseline_tensor_bytes"] += tensor_nbytes(t)
	if not t.is_floating_point():
	stats["num_nonfloat_tensors"] += 1
	passthrough[name] = t
	stats["int8_payload_bytes"] += tensor_nbytes(t)
	continue
	if t.numel() <= INT8_KEEP_FLOAT_MAX_NUMEL:
	kept = keep_float_tensor(name, t, passthrough_orig_dtypes)
	passthrough[name] = kept
	stats["int8_payload_bytes"] += tensor_nbytes(kept)
	continue
	stats["num_float_tensors"] += 1
	q, s = quantize_float_tensor(t)
	if s.ndim > 0:
	qmeta[name] = {"scheme": "per_row", "axis": 0}
	quantized[name] = q
	scales[name] = s
	dtypes[name] = str(t.dtype).removeprefix("torch.")
	stats["int8_payload_bytes"] += tensor_nbytes(q) + tensor_nbytes(s)
	obj: dict[str, object] = {
	"__quant_format__": "int8_clean_per_row_v1",
	"quantized": quantized,
	"scales": scales,
	"dtypes": dtypes,
	"passthrough": passthrough,
	}
	if qmeta:
	obj["qmeta"] = qmeta
	if passthrough_orig_dtypes:
	obj["passthrough_orig_dtypes"] = passthrough_orig_dtypes
	return obj, stats
	def dequantize_state_dict_int8(obj: dict[str, object]) -> dict[str, Tensor]:
	out: dict[str, Tensor] = {}
	qmeta = obj.get("qmeta", {})
	passthrough_orig_dtypes = obj.get("passthrough_orig_dtypes", {})
	for name, q in obj["quantized"].items():
	dtype = getattr(torch, obj["dtypes"][name])
	s = obj["scales"][name]
	if qmeta.get(name, {}).get("scheme") == "per_row" or s.ndim > 0:
	s = s.to(dtype=torch.float32)
	out[name] = (q.float() * s.view(q.shape[0], ([1] (q.ndim - 1)))).to(dtype=dtype).contiguous()
	else:
	scale = float(s.item())
	out[name] = (q.float() * scale).to(dtype=dtype).contiguous()
	for name, t in obj["passthrough"].items():
	out_t = t.detach().to("cpu").contiguous()
	orig_dtype = passthrough_orig_dtypes.get(name)
	if isinstance(orig_dtype, str):
	out_t = out_t.to(dtype=getattr(torch, orig_dtype)).contiguous()
	out[name] = out_t
	return out

	# --- Data loading ---

	def load_data_shard(file: Path) -> Tensor:
	header_bytes = 256 * np.dtype("<i4").itemsize
	token_bytes = np.dtype("<u2").itemsize
	header = np.fromfile(file, dtype="<i4", count=256)
	if header.size != 256 or int(header[0]) != 20240520 or int(header[1]) != 1:
	raise ValueError(f"Unexpected shard header for {file}")
	num_tokens = int(header[2])
	expected_size = header_bytes + num_tokens * token_bytes
	if file.stat().st_size != expected_size:
	raise ValueError(f"Shard size mismatch for {file}: expected {expected_size} bytes")
	tokens_np = np.fromfile(file, dtype="<u2", count=num_tokens, offset=header_bytes)
	if tokens_np.size != num_tokens:
	raise ValueError(f"Short read for {file}")
	return torch.from_numpy(tokens_np.astype(np.uint16, copy=False))
	_SHARD_HEADER_BYTES = 256 * np.dtype("<i4").itemsize
	_SHARD_NTOKENS_CACHE: dict[str, int] = {}
	_MMAP_CACHE: dict[str, np.memmap] = {}

	def _read_num_tokens(file: Path) -> int:
	key = str(file)
	cached = _SHARD_NTOKENS_CACHE.get(key)
	if cached is not None:
	return cached
	header = np.fromfile(file, dtype="<i4", count=256)
	if header.size != 256 or int(header[0]) != 20240520 or int(header[1]) != 1:
	raise ValueError(f"Unexpected shard header for {file}")
	n = int(header[2])
	_SHARD_NTOKENS_CACHE[key] = n
	return n

	def _get_shard_memmap(file: Path) -> np.memmap:
	key = str(file)
	mm = _MMAP_CACHE.get(key)
	if mm is not None:
	return mm
	n = _read_num_tokens(file)
	mm = np.memmap(file, mode="r", dtype="<u2", offset=_SHARD_HEADER_BYTES, shape=(n,))
	_MMAP_CACHE[key] = mm
	return mm

	class DistributedTokenLoader:
	"""Coprime-stride + multi-shard loader (PR #726 style). No daemon thread / prefetch."""
	def __init__(self, pattern: str, rank: int, world_size: int, device: torch.device):
	self.rank = rank
	self.world_size = world_size
	self.device = device
	self.files = [Path(p) for p in sorted(glob.glob(pattern))]
	if not self.files:
	raise FileNotFoundError(f"No files found for pattern: {pattern}")
	self._num_tokens = np.array([_read_num_tokens(f) for f in self.files], dtype=np.int64)
	seed = 0
	for f in self.files:
	for b in str(f).encode():
	seed = ((seed ^ b) * 1099511628211) & 0xFFFFFFFFFFFFFFFF
	self._rng = np.random.Generator(np.random.PCG64(seed))
	self._cfg: tuple[int, int, int, int] \| None = None
	self._eligible_shards: np.ndarray \| None = None
	self._base_block_counts: np.ndarray \| None = None
	n = len(self.files)
	self._cursor_phase = np.zeros(n, dtype=np.int64)
	self._cursor_block_count = np.zeros(n, dtype=np.int64)
	self._cursor_next = np.zeros(n, dtype=np.int64)
	self._cursor_start = np.zeros(n, dtype=np.int64)
	self._cursor_stride = np.ones(n, dtype=np.int64)
	self._cursor_init = np.zeros(n, dtype=np.bool_)
	self._batches_built = 0
	def _pick_coprime_stride(self, n: int) -> int:
	if n <= 1:
	return 1
	while True:
	s = int(self._rng.integers(1, n))
	if math.gcd(s, n) == 1:
	return s
	def _reset_cursor(self, si: int, seq_len: int) -> None:
	nt = int(self._num_tokens[si])
	max_phase = min(seq_len - 1, max(0, nt - seq_len - 1))
	phase = int(self._rng.integers(max_phase + 1)) if max_phase > 0 else 0
	bc = (nt - 1 - phase) // seq_len
	self._cursor_phase[si] = phase
	self._cursor_block_count[si] = bc
	self._cursor_next[si] = 0
	self._cursor_start[si] = int(self._rng.integers(bc)) if bc > 1 else 0
	self._cursor_stride[si] = self._pick_coprime_stride(bc)
	self._cursor_init[si] = True
	def _ensure_cursor(self, si: int, seq_len: int) -> None:
	if not self._cursor_init[si] or self._cursor_next[si] >= self._cursor_block_count[si]:
	self._reset_cursor(si, seq_len)
	def _take_from_shard(self, si: int, seq_len: int, count: int, out: list[tuple[int, int]]) -> None:
	rem = count
	while rem > 0:
	self._ensure_cursor(si, seq_len)
	bc = int(self._cursor_block_count[si])
	ni = int(self._cursor_next[si])
	take = min(rem, bc - ni)
	phase = int(self._cursor_phase[si])
	start = int(self._cursor_start[si])
	stride = int(self._cursor_stride[si])
	for j in range(take):
	bi = (start + (ni + j) * stride) % bc
	out.append((si, phase + bi * seq_len))
	self._cursor_next[si] = ni + take
	rem -= take
	def _init_pipeline(self, global_tokens: int, seq_len: int, grad_accum_steps: int) -> None:
	local_tokens = global_tokens // (self.world_size * grad_accum_steps)
	num_seqs = local_tokens // seq_len
	global_num_seqs = num_seqs * self.world_size
	self._cfg = (local_tokens, seq_len, num_seqs, global_num_seqs)
	bbc = (self._num_tokens - 1) // seq_len
	eligible = bbc > 0
	self._eligible_shards = np.nonzero(eligible)[0].astype(np.int64)
	self._base_block_counts = bbc[self._eligible_shards].astype(np.int64)
	def _sample_global_windows(self) -> list[tuple[int, int]]:
	assert self._cfg is not None and self._eligible_shards is not None
	_, seq_len, _, gns = self._cfg
	ec = int(self._eligible_shards.size)
	progress = min(self._batches_built / 1800.0, 1.0)
	remaining = np.empty(ec, dtype=np.float64)
	for i, si in enumerate(self._eligible_shards.tolist()):
	if self._cursor_init[si]:
	r = int(self._cursor_block_count[si]) - int(self._cursor_next[si])
	remaining[i] = float(max(r, 1))
	else:
	remaining[i] = float(self._base_block_counts[i])
	alpha = 0.90 - 0.40 * progress
	weights = np.power(remaining, alpha)
	ws = float(weights.sum())
	if not np.isfinite(ws) or ws <= 0.0:
	weights = np.ones(ec, dtype=np.float64)
	ws = float(weights.sum())
	probs = weights / ws
	low = min(max(8, self.world_size), ec, gns)
	high = min(max(32, self.world_size * 8), ec, gns)
	mix = max(1, min(int(round(low + progress * (high - low))), ec, gns))
	cp = self._rng.choice(ec, size=mix, replace=False, p=probs)
	cs = self._eligible_shards[cp]
	cpr = probs[cp].copy()
	cpr /= cpr.sum()
	counts = np.ones(mix, dtype=np.int64)
	extra = gns - mix
	if extra > 0:
	counts += self._rng.multinomial(extra, cpr).astype(np.int64)
	perm = self._rng.permutation(mix)
	cs, counts = cs[perm], counts[perm]
	buckets: list[list[tuple[int, int]]] = []
	for si, cnt in zip(cs.tolist(), counts.tolist()):
	b: list[tuple[int, int]] = []
	self._take_from_shard(int(si), seq_len, int(cnt), b)
	if b:
	if len(b) > 1:
	bp = self._rng.permutation(len(b))
	b = [b[int(k)] for k in bp.tolist()]
	buckets.append(b)
	windows: list[tuple[int, int]] = []
	active = [i for i, bk in enumerate(buckets) if bk]
	while active:
	order = self._rng.permutation(len(active))
	new_active: list[int] = []
	for oi in order.tolist():
	bi = active[oi]
	if buckets[bi]:
	windows.append(buckets[bi].pop())
	if buckets[bi]:
	new_active.append(bi)
	active = new_active
	return windows
	def next_batch(self, global_tokens: int, seq_len: int, grad_accum_steps: int) -> tuple[Tensor, Tensor]:
	if self._cfg is None:
	self._init_pipeline(global_tokens, seq_len, grad_accum_steps)
	_, _, num_seqs, gns = self._cfg
	gw = self._sample_global_windows()
	local_w = gw[self.rank::self.world_size]
	x = torch.empty((num_seqs, seq_len), dtype=torch.int64)
	y = torch.empty((num_seqs, seq_len), dtype=torch.int64)
	for slot, (si, pos) in enumerate(local_w):
	mm = _get_shard_memmap(self.files[si])
	window = torch.as_tensor(np.array(mm[pos:pos + seq_len + 1], dtype=np.int64))
	x[slot] = window[:-1]
	y[slot] = window[1:]
	self._batches_built += 1
	return x.to(self.device, non_blocking=True), y.to(self.device, non_blocking=True)

	# --- Transformer modules ---

	class RMSNorm(nn.Module):
	def __init__(self, eps: float \| None = None):
	super().__init__()
	self.eps = eps
	def forward(self, x: Tensor) -> Tensor:
	return F.rms_norm(x, (x.size(-1),), eps=self.eps)
	class CastedLinear(nn.Linear):
	def forward(self, x: Tensor) -> Tensor:
	w = self.weight.to(x.dtype)
	bias = self.bias.to(x.dtype) if self.bias is not None else None
	return F.linear(x, w, bias)
	def restore_low_dim_params_to_fp32(module: nn.Module) -> None:
	with torch.no_grad():
	for name, param in module.named_parameters():
	if (param.ndim < 2 or any(pattern in name for pattern in CONTROL_TENSOR_NAME_PATTERNS)) and param.dtype != torch.float32:
	param.data = param.data.float()
	class Rotary(nn.Module):
	def __init__(self, dim: int, base: float = 10000.0, train_seq_len: int = 1024, rope_dims: int = 0):
	super().__init__()
	self.dim = dim
	self.base = base
	self.train_seq_len = train_seq_len
	self.rope_dims = rope_dims if rope_dims > 0 else dim
	inv_freq = 1.0 / (base ** (torch.arange(0, self.rope_dims, 2, dtype=torch.float32) / self.rope_dims))
	self.register_buffer("inv_freq", inv_freq, persistent=False)
	self._seq_len_cached = 0
	self._cos_cached: Tensor \| None = None
	self._sin_cached: Tensor \| None = None
	def forward(self, seq_len: int, device: torch.device, dtype: torch.dtype) -> tuple[Tensor, Tensor]:
	if (
	self._cos_cached is None
	or self._sin_cached is None
	or self._seq_len_cached != seq_len
	or self._cos_cached.device != device
	):
	rd = self.rope_dims
	if seq_len > self.train_seq_len:
	scale = seq_len / self.train_seq_len
	new_base = self.base * (scale ** (rd / (rd - 2)))
	inv_freq = 1.0 / (new_base ** (torch.arange(0, rd, 2, dtype=torch.float32, device=device) / rd))
	else:
	inv_freq = self.inv_freq.to(device)
	t = torch.arange(seq_len, device=device, dtype=inv_freq.dtype)
	freqs = torch.outer(t, inv_freq)
	self._cos_cached = freqs.cos()[None, :, None, :]
	self._sin_cached = freqs.sin()[None, :, None, :]
	self._seq_len_cached = seq_len
	return self._cos_cached.to(dtype=dtype), self._sin_cached.to(dtype=dtype)
	def apply_rotary_emb(x: Tensor, cos: Tensor, sin: Tensor, rope_dims: int = 0) -> Tensor:
	if rope_dims > 0 and rope_dims < x.size(-1):
	x_rope, x_pass = x[..., :rope_dims], x[..., rope_dims:]
	half = rope_dims // 2
	x1, x2 = x_rope[..., :half], x_rope[..., half:]
	x_rope = torch.cat((x1 * cos + x2 * sin, x1 * (-sin) + x2 * cos), dim=-1)
	return torch.cat((x_rope, x_pass), dim=-1)
	half = x.size(-1) // 2
	x1, x2 = x[..., :half], x[..., half:]
	return torch.cat((x1 * cos + x2 * sin, x1 * (-sin) + x2 * cos), dim=-1)

	class CausalSelfAttention(nn.Module):
	def __init__(
	self,
	dim: int,
	num_heads: int,
	num_kv_heads: int,
	rope_base: float,
	qk_gain_init: float,
	):
	super().__init__()
	if dim % num_heads != 0:
	raise ValueError("model_dim must be divisible by num_heads")
	if num_heads % num_kv_heads != 0:
	raise ValueError("num_heads must be divisible by num_kv_heads")
	self.num_heads = num_heads
	self.num_kv_heads = num_kv_heads
	self.head_dim = dim // num_heads
	if self.head_dim % 2 != 0:
	raise ValueError("head_dim must be even for RoPE")
	# No CastedLinear -- weights come from banks
	self.q_gain = nn.Parameter(torch.full((num_heads,), qk_gain_init, dtype=torch.float32))
	self.rope_dims = 0 # set by GPT.__init__ for partial RoPE
	self.rotary = Rotary(self.head_dim, base=rope_base, train_seq_len=1024)
	self.window_size = 0 # 0 = full attention, >0 = sliding window
	self.num_sink_tokens = 0 # 0 = disabled, >0 = always attend to first N tokens
	self.use_xsa = False # set by GPT.__init__ for deep layers only
	def _attn_with_sinks(self, q: Tensor, k: Tensor, v: Tensor, ws: tuple) -> Tensor:
	"""Window attention + sink tokens. Works on both SDPA shim and real FA3."""
	S = self.num_sink_tokens
	W = ws[0]
	T = q.shape[1]
	try:
	# Local SDPA shim path: supports num_sink_tokens kwarg
	return flash_attn_3_func(q, k, v, causal=True, window_size=ws, num_sink_tokens=S)
	except TypeError:
	# Real FA3 path: two-pass with log-sum-exp combining
	# For positions where sinks are within the window (pos < W + S),
	# normal causal attention already covers everything needed.
	# For positions >= W + S, sinks fall outside the window — need two passes.
	if T <= W + S:
	# All sinks within window for all positions — just use causal
	return flash_attn_3_func(q, k, v, causal=True)
	# Pass 1: window attention over full sequence
	y_win, lse_win = flash_attn_3_func(q, k, v, causal=True, window_size=ws, return_attn_probs=True)
	# Pass 2: causal attention to sink K/V only (disjoint from window for pos >= W + S)
	k_sink, v_sink = k[:, :S], v[:, :S]
	y_sink, lse_sink = flash_attn_3_func(q, k_sink, v_sink, causal=True, return_attn_probs=True)
	# For positions < W (sinks are inside window), use window-only result.
	# For positions >= W, combine via log-sum-exp.
	# lse shape from FA3: [B, H, T]
	lse_w = lse_win.permute(0, 2, 1).unsqueeze(-1) # [B, T, H, 1]
	lse_s = lse_sink.permute(0, 2, 1).unsqueeze(-1) # [B, T, H, 1]
	max_lse = torch.maximum(lse_w, lse_s)
	exp_w = torch.exp(lse_w - max_lse)
	exp_s = torch.exp(lse_s - max_lse)
	y = (exp_w * y_win + exp_s * y_sink) / (exp_w + exp_s)
	# For early positions (< W), sinks are already in window — use window result directly
	# to avoid double-counting
	y[:, :W] = y_win[:, :W]
	return y

	def _xsa_efficient(self, y: Tensor, v: Tensor) -> Tensor:
	"""Efficient XSA: subtract self-value projection via GQA-aware reshape (no repeat_interleave).
	y: [B, T, H, D], v: [B, T, Hkv, D]. H must be divisible by Hkv."""
	B, T, H, D = y.shape
	Hkv = v.size(-2)
	group = H // Hkv
	y_g = y.reshape(B, T, Hkv, group, D) # [B, T, Hkv, group, D]
	vn = F.normalize(v, dim=-1).unsqueeze(-2) # [B, T, Hkv, 1, D] -- broadcast ready
	proj = (y_g * vn).sum(dim=-1, keepdim=True) * vn
	return (y_g - proj).reshape(B, T, H, D)
	def forward(self, x: Tensor, q_w: Tensor, k_w: Tensor, v_w: Tensor, out_w: Tensor, v_embed: Tensor \| None = None) -> Tensor:
	if getattr(self, '_save_gptq', False):
	self._gptq_qkv_in = x.detach()
	bsz, seqlen, dim = x.shape
	q = F.linear(x, q_w.to(x.dtype)).reshape(bsz, seqlen, self.num_heads, self.head_dim)
	k = F.linear(x, k_w.to(x.dtype)).reshape(bsz, seqlen, self.num_kv_heads, self.head_dim)
	v = F.linear(x, v_w.to(x.dtype))
	if v_embed is not None:
	v = v + v_embed
	v = v.reshape(bsz, seqlen, self.num_kv_heads, self.head_dim)
	q = F.rms_norm(q, (q.size(-1),))
	k = F.rms_norm(k, (k.size(-1),))
	cos, sin = self.rotary(seqlen, x.device, q.dtype)
	q = apply_rotary_emb(q, cos, sin, self.rope_dims)
	k = apply_rotary_emb(k, cos, sin, self.rope_dims)
	q = q * self.q_gain.to(dtype=q.dtype)[None, None, :, None]
	if self.window_size > 0:
	ws = (self.window_size, self.window_size)
	if self.num_sink_tokens > 0:
	y = self._attn_with_sinks(q, k, v, ws)
	else:
	y = flash_attn_3_func(q, k, v, causal=True, window_size=ws)
	else:
	y = flash_attn_3_func(q, k, v, causal=True)
	if self.use_xsa:
	y = self._xsa_efficient(y, v)
	y = y.reshape(bsz, seqlen, dim)
	if getattr(self, '_save_gptq', False):
	self._gptq_o_in = y.detach()
	return F.linear(y, out_w.to(x.dtype))

	class SmearGate(nn.Module):
	def __init__(self, dim: int):
	super().__init__()
	self.gate = nn.Parameter(torch.zeros(dim, dtype=torch.float32))
	def forward(self, x: Tensor) -> Tensor:
	g = torch.sigmoid(self.gate.to(dtype=x.dtype))[None, None, :]
	x_prev = torch.cat([torch.zeros_like(x[:, :1]), x[:, :-1]], dim=1)
	return (1 - g) * x + g * x_prev

	class BigramHashEmbedding(nn.Module):
	def __init__(self, bigram_vocab_size: int, bigram_dim: int, model_dim: int):
	super().__init__()
	self.bigram_vocab_size = bigram_vocab_size
	self.embed = nn.Embedding(bigram_vocab_size, bigram_dim)
	nn.init.zeros_(self.embed.weight)
	self.proj = CastedLinear(bigram_dim, model_dim, bias=False) if bigram_dim != model_dim else None
	if self.proj is not None:
	nn.init.zeros_(self.proj.weight)
	self.scale = nn.Parameter(torch.tensor(0.05, dtype=torch.float32))
	def bigram_hash(self, tokens: Tensor) -> Tensor:
	t = tokens.to(torch.int32)
	mod = self.bigram_vocab_size - 1
	out = torch.empty_like(t)
	out[..., 0] = mod
	out[..., 1:] = torch.bitwise_xor(36313 * t[..., 1:], 27191 * t[..., :-1]) % mod
	return out.long()
	def forward(self, token_ids: Tensor) -> Tensor:
	h = self.embed(self.bigram_hash(token_ids))
	if self.proj is not None:
	h = self.proj(h)
	return h * self.scale.to(dtype=h.dtype)

	class ValueEmbedding(nn.Module):
	"""Reinject token identity into attention values at specific layers.
	Each table maps vocab tokens to a low-dim embedding, projected to model_dim."""
	def __init__(self, vocab_size: int, ve_dim: int, model_dim: int):
	super().__init__()
	self.embed = nn.Embedding(vocab_size, ve_dim)
	nn.init.normal_(self.embed.weight, std=0.01)
	self.proj = CastedLinear(ve_dim, model_dim, bias=False) if ve_dim != model_dim else None
	if self.proj is not None:
	nn.init.zeros_(self.proj.weight)
	self.scale = nn.Parameter(torch.tensor(0.1, dtype=torch.float32))
	def forward(self, token_ids: Tensor) -> Tensor:
	h = self.embed(token_ids)
	if self.proj is not None:
	h = self.proj(h)
	return h * self.scale.to(dtype=h.dtype)

	class MLP(nn.Module):
	def __init__(self, dim: int, mlp_mult: int, neg_slope: float = 0.5):
	super().__init__()
	self.neg_slope = neg_slope
	# No CastedLinear -- weights come from banks
	def forward(self, x: Tensor, up_w: Tensor, down_w: Tensor) -> Tensor:
	if getattr(self, '_save_gptq', False):
	self._gptq_up_in = x.detach()
	x = F.leaky_relu(F.linear(x, up_w.to(x.dtype)), negative_slope=self.neg_slope)
	x2 = x.square()
	if getattr(self, '_save_gptq', False):
	self._gptq_down_in = x2.detach()
	return F.linear(x2, down_w.to(x.dtype))

	class Block(nn.Module):
	def __init__(
	self,
	dim: int,
	num_heads: int,
	num_kv_heads: int,
	mlp_mult: int,
	rope_base: float,
	qk_gain_init: float,
	layer_idx: int = 0,
	ln_scale: bool = False,
	neg_slope: float = 0.5,
	):
	super().__init__()
	self.layer_idx = layer_idx
	self.attn_norm = RMSNorm()
	self.mlp_norm = RMSNorm()
	self.attn = CausalSelfAttention(dim, num_heads, num_kv_heads, rope_base, qk_gain_init)
	self.mlp = MLP(dim, mlp_mult, neg_slope=neg_slope)
	self.attn_scale = nn.Parameter(torch.ones(dim, dtype=torch.float32))
	self.mlp_scale = nn.Parameter(torch.ones(dim, dtype=torch.float32))
	self.resid_mix = nn.Parameter(torch.stack((torch.ones(dim), torch.zeros(dim))).float())
	self.ln_scale_factor = 1.0 / math.sqrt(layer_idx + 1) if ln_scale else 1.0
	def forward(self, x: Tensor, x0: Tensor, q_w: Tensor, k_w: Tensor, v_w: Tensor, out_w: Tensor, up_w: Tensor, down_w: Tensor, v_embed: Tensor \| None = None) -> Tensor:
	mix = self.resid_mix.to(dtype=x.dtype)
	x_in = mix[0][None, None, :] * x + mix[1][None, None, :] * x0
	attn_out = self.attn(self.attn_norm(x_in) * self.ln_scale_factor, q_w, k_w, v_w, out_w, v_embed=v_embed)
	x_out = x_in + self.attn_scale.to(dtype=x_in.dtype)[None, None, :] * attn_out
	mlp_out = self.mlp_scale.to(dtype=x_out.dtype)[None, None, :] * self.mlp(self.mlp_norm(x_out) * self.ln_scale_factor, up_w, down_w)
	return x_out + mlp_out

	class GPT(nn.Module):
	def __init__(
	self,
	vocab_size: int,
	num_layers: int,
	model_dim: int,
	num_heads: int,
	num_kv_heads: int,
	mlp_mult: int,
	tie_embeddings: bool,
	tied_embed_init_std: float,
	logit_softcap: float,
	rope_base: float,
	qk_gain_init: float,
	bigram_vocab_size: int = 0,
	bigram_dim: int = 128,
	xsa_last_n: int = 0,
	rope_dims: int = 0,
	ln_scale: bool = False,
	ve_enabled: bool = False,
	ve_dim: int = 128,
	ve_layers: str = "9,10",
	neg_slope: float = 0.5,
	window_attn_size: int = 0,
	window_attn_layers: str = "2,4,6,8,10",
	num_sink_tokens: int = 0,
	train_seq_len: int = 2048,
	train_seq_len_long: int = 0,
	):
	super().__init__()
	max_seq_len = max(train_seq_len, train_seq_len_long) if train_seq_len_long > 0 else train_seq_len
	self._ve_target_dim = num_kv_heads * (model_dim // num_heads) # kv_dim for value projection
	if logit_softcap <= 0.0:
	raise ValueError(f"logit_softcap must be positive, got {logit_softcap}")
	self.tie_embeddings = tie_embeddings
	self.tied_embed_init_std = tied_embed_init_std
	self.logit_softcap = logit_softcap
	self.tok_emb = nn.Embedding(vocab_size, model_dim)
	self.bigram = BigramHashEmbedding(bigram_vocab_size, bigram_dim, model_dim) if bigram_vocab_size > 0 else None
	self.smear = SmearGate(model_dim)
	self.num_encoder_layers = num_layers // 2
	self.num_decoder_layers = num_layers - self.num_encoder_layers
	self.num_skip_weights = min(self.num_encoder_layers, self.num_decoder_layers)
	self.skip_weights = nn.Parameter(torch.ones(self.num_skip_weights, model_dim, dtype=torch.float32))
	# Parameter banks: contiguous 3D tensors for batched optimizer
	head_dim = model_dim // num_heads
	kv_dim = num_kv_heads * head_dim
	mlp_dim = int(mlp_mult * model_dim)
	self.num_layers = num_layers
	self.qo_bank = nn.Parameter(torch.empty(2 * num_layers, model_dim, model_dim))
	self.kv_bank = nn.Parameter(torch.empty(2 * num_layers, kv_dim, model_dim))
	self.mlp_up_bank = nn.Parameter(torch.empty(num_layers, mlp_dim, model_dim))
	self.mlp_down_bank = nn.Parameter(torch.empty(num_layers, model_dim, mlp_dim))
	self.blocks = nn.ModuleList(
	[
	Block(
	model_dim,
	num_heads,
	num_kv_heads,
	mlp_mult,
	rope_base,
	qk_gain_init,
	layer_idx=i,
	ln_scale=ln_scale,
	neg_slope=neg_slope,
	)
	for i in range(num_layers)
	]
	)
	head_dim = model_dim // num_heads
	for block in self.blocks:
	if rope_dims > 0:
	block.attn.rope_dims = rope_dims
	block.attn.rotary = Rotary(head_dim, base=rope_base, train_seq_len=max_seq_len, rope_dims=rope_dims if rope_dims > 0 else 0)
	self.ve_layer_indices = [int(x) for x in ve_layers.split(",") if x.strip()] if ve_enabled else []
	kv_dim_ve = self._ve_target_dim
	if self.ve_layer_indices:
	self.ve_shared = ValueEmbedding(vocab_size, ve_dim, kv_dim_ve)
	self.ve_layer_scales = nn.ParameterList(
	[nn.Parameter(torch.ones(1, dtype=torch.float32)) for _ in self.ve_layer_indices]
	)
	else:
	self.ve_shared = None
	self.ve_layer_scales = nn.ParameterList()
	self.value_embeds = nn.ModuleList() # keep empty for compat
	self.final_norm = RMSNorm()
	self.lm_head = None if tie_embeddings else CastedLinear(model_dim, vocab_size, bias=False)
	if self.lm_head is not None:
	self.lm_head._zero_init = True
	if xsa_last_n > 0:
	for i in range(max(0, num_layers - xsa_last_n), num_layers):
	self.blocks[i].attn.use_xsa = True
	if window_attn_size > 0:
	window_layer_indices = [int(x) for x in window_attn_layers.split(",") if x.strip()]
	for i in window_layer_indices:
	if i < len(self.blocks):
	self.blocks[i].attn.window_size = window_attn_size
	self.blocks[i].attn.num_sink_tokens = num_sink_tokens
	self._init_weights()
	def _init_weights(self) -> None:
	if self.tie_embeddings:
	nn.init.normal_(self.tok_emb.weight, mean=0.0, std=self.tied_embed_init_std)
	n = self.num_layers
	proj_scale = 1.0 / math.sqrt(2 * n)
	# Init banks: orthogonal, with proj layers scaled down and out/down zero-init
	for i in range(n):
	nn.init.orthogonal_(self.qo_bank.data[i], gain=1.0) # Q
	nn.init.zeros_(self.qo_bank.data[n + i]) # Out (zero init)
	nn.init.orthogonal_(self.kv_bank.data[i], gain=1.0) # K
	nn.init.orthogonal_(self.kv_bank.data[n + i], gain=1.0) # V
	nn.init.orthogonal_(self.mlp_up_bank.data[i], gain=1.0) # MLP up
	nn.init.zeros_(self.mlp_down_bank.data[i]) # MLP down (zero init)
	# Scale proj layers (out_proj and mlp_down are "proj" layers)
	self.qo_bank.data[n + i].mul_(proj_scale)
	self.mlp_down_bank.data[i].mul_(proj_scale)
	# Init remaining nn.Linear modules (bigram proj, lm_head)
	for name, module in self.named_modules():
	if isinstance(module, nn.Linear):
	if getattr(module, "_zero_init", False):
	nn.init.zeros_(module.weight)
	elif module.weight.ndim == 2 and module.weight.shape[0] >= 64 and module.weight.shape[1] >= 64:
	nn.init.orthogonal_(module.weight, gain=1.0)
	def _get_ve(self, layer_idx: int, input_ids: Tensor, ve_cache: dict \| None = None) -> Tensor \| None:
	"""Get value embedding for a specific layer using shared table + per-layer scale."""
	if self.ve_shared is None or layer_idx not in self.ve_layer_indices:
	return None
	if ve_cache is not None and 've' not in ve_cache:
	ve_cache['ve'] = self.ve_shared(input_ids)
	ve_base = ve_cache['ve'] if ve_cache is not None else self.ve_shared(input_ids)
	ve_idx = self.ve_layer_indices.index(layer_idx)
	return ve_base * self.ve_layer_scales[ve_idx].to(dtype=ve_base.dtype)
	def forward(self, input_ids: Tensor, target_ids: Tensor) -> Tensor:
	n = self.num_layers
	x = self.tok_emb(input_ids)
	if self.bigram is not None:
	x = x + self.bigram(input_ids)
	x = F.rms_norm(x, (x.size(-1),))
	x = self.smear(x)
	x0 = x
	skips: list[Tensor] = []
	ve_cache: dict = {}
	for i in range(self.num_encoder_layers):
	ve = self._get_ve(i, input_ids, ve_cache)
	x = self.blocks[i](x, x0,
	self.qo_bank[i], self.kv_bank[i], self.kv_bank[n + i],
	self.qo_bank[n + i], self.mlp_up_bank[i], self.mlp_down_bank[i],
	v_embed=ve)
	skips.append(x)
	for i in range(self.num_decoder_layers):
	bi = self.num_encoder_layers + i
	if skips:
	x = x + self.skip_weights[i].to(dtype=x.dtype)[None, None, :] * skips.pop()
	ve = self._get_ve(bi, input_ids, ve_cache)
	x = self.blocks[bi](x, x0,
	self.qo_bank[bi], self.kv_bank[bi], self.kv_bank[n + bi],
	self.qo_bank[n + bi], self.mlp_up_bank[bi], self.mlp_down_bank[bi],
	v_embed=ve)
	x = self.final_norm(x)
	x_flat = x.reshape(-1, x.size(-1))
	targets = target_ids.reshape(-1)
	if self.tie_embeddings:
	logits_proj = F.linear(x_flat, self.tok_emb.weight)
	else:
	if self.lm_head is None:
	raise RuntimeError("lm_head is required when tie_embeddings=False")
	logits_proj = self.lm_head(x_flat)
	logits = self.logit_softcap * torch.tanh(logits_proj / self.logit_softcap)
	return F.cross_entropy(logits.float(), targets, reduction="mean")
	def forward_logits(self, input_ids: Tensor) -> Tensor:
	"""Return logits (bsz, seq_len, vocab) without computing loss."""
	n = self.num_layers
	x = self.tok_emb(input_ids)
	if self.bigram is not None:
	x = x + self.bigram(input_ids)
	x = F.rms_norm(x, (x.size(-1),))
	x = self.smear(x)
	x0 = x
	skips: list[Tensor] = []
	ve_cache: dict = {}
	for i in range(self.num_encoder_layers):
	ve = self._get_ve(i, input_ids, ve_cache)
	x = self.blocks[i](x, x0,
	self.qo_bank[i], self.kv_bank[i], self.kv_bank[n + i],
	self.qo_bank[n + i], self.mlp_up_bank[i], self.mlp_down_bank[i],
	v_embed=ve)
	skips.append(x)
	for i in range(self.num_decoder_layers):
	bi = self.num_encoder_layers + i
	if skips:
	x = x + self.skip_weights[i].to(dtype=x.dtype)[None, None, :] * skips.pop()
	ve = self._get_ve(bi, input_ids, ve_cache)
	x = self.blocks[bi](x, x0,
	self.qo_bank[bi], self.kv_bank[bi], self.kv_bank[n + bi],
	self.qo_bank[n + bi], self.mlp_up_bank[bi], self.mlp_down_bank[bi],
	v_embed=ve)
	x = self.final_norm(x)
	if self.tie_embeddings:
	logits_proj = F.linear(x, self.tok_emb.weight)
	else:
	logits_proj = self.lm_head(x)
	return self.logit_softcap * torch.tanh(logits_proj / self.logit_softcap)

	# --- Sliding window evaluation ---

	def eval_val_sliding(
	args: Hyperparameters,
	base_model: nn.Module,
	rank: int,
	world_size: int,
	device: torch.device,
	val_tokens: Tensor,
	base_bytes_lut: Tensor,
	has_leading_space_lut: Tensor,
	is_boundary_token_lut: Tensor,
	stride: int,
	batch_seqs: int = 32,
	eval_seq_len: int \| None = None,
	) -> tuple[float, float]:
	"""Sliding window evaluation: each token scored with maximum context."""
	seq_len = eval_seq_len or args.train_seq_len
	total_tokens = val_tokens.numel() - 1
	window_starts = [ws for ws in range(0, total_tokens, stride)
	if min(ws + seq_len, total_tokens) - ws >= 1]
	total_windows = len(window_starts)
	my_s = (total_windows * rank) // world_size
	my_e = (total_windows * (rank + 1)) // world_size
	my_windows = window_starts[my_s:my_e]
	loss_sum = torch.zeros((), device=device, dtype=torch.float64)
	token_count = torch.zeros((), device=device, dtype=torch.float64)
	byte_count = torch.zeros((), device=device, dtype=torch.float64)
	base_model.eval()
	compiled_logits = torch.compile(base_model.forward_logits, dynamic=False, fullgraph=True)
	with torch.inference_mode():
	for bi in range(0, len(my_windows), batch_seqs):
	batch_ws = my_windows[bi:bi + batch_seqs]
	bsz = len(batch_ws)
	x_batch = torch.zeros(bsz, seq_len, dtype=torch.int64, device=device)
	y_batch = torch.zeros(bsz, seq_len, dtype=torch.int64, device=device)
	wlens: list[int] = []
	for i, ws in enumerate(batch_ws):
	end = min(ws + seq_len, total_tokens)
	wlen = end - ws
	wlens.append(wlen)
	chunk = val_tokens[ws:end + 1].to(dtype=torch.int64, device=device)
	x_batch[i, :wlen] = chunk[:-1]
	y_batch[i, :wlen] = chunk[1:]
	with torch.autocast(device_type="cuda", dtype=torch.bfloat16):
	logits = compiled_logits(x_batch)
	nll = F.cross_entropy(
	logits.reshape(-1, logits.size(-1)).float(),
	y_batch.reshape(-1),
	reduction="none",
	).reshape(bsz, seq_len)
	for i, ws in enumerate(batch_ws):
	wlen = wlens[i]
	s = 0 if ws == 0 else max(wlen - stride, 0)
	scored_nll = nll[i, s:wlen].to(torch.float64)
	loss_sum += scored_nll.sum()
	token_count += float(wlen - s)
	tgt = y_batch[i, s:wlen]
	prev = x_batch[i, s:wlen]
	tb = base_bytes_lut[tgt].to(torch.float64)
	tb += (has_leading_space_lut[tgt] & ~is_boundary_token_lut[prev]).to(torch.float64)
	byte_count += tb.sum()
	if dist.is_available() and dist.is_initialized():
	dist.all_reduce(loss_sum, op=dist.ReduceOp.SUM)
	dist.all_reduce(token_count, op=dist.ReduceOp.SUM)
	dist.all_reduce(byte_count, op=dist.ReduceOp.SUM)
	val_loss = (loss_sum / token_count).item()
	bits_per_token = val_loss / math.log(2.0)
	tokens_per_byte = token_count.item() / byte_count.item()
	base_model.train()
	return val_loss, bits_per_token * tokens_per_byte


	def eval_val_sliding_ttt(
	args: Hyperparameters, base_model: nn.Module, rank: int, world_size: int,
	device: torch.device, val_tokens: Tensor, base_bytes_lut: Tensor,
	has_leading_space_lut: Tensor, is_boundary_token_lut: Tensor,
	stride: int, batch_seqs: int = 32, log0=print,
	) -> tuple[float, float]:
	"""Legal score-first TTT (PR #461 recipe): score each chunk with sliding windows,
	then train on it. Every token scored BEFORE any update that could use it."""
	seq_len = args.train_seq_len
	total_tokens = val_tokens.numel() - 1
	ttt_chunk = args.ttt_chunk_tokens

	# Pre-compute all window starts
	window_starts = [ws for ws in range(0, total_tokens, stride)
	if min(ws + seq_len, total_tokens) - ws >= stride or ws == 0]

	# Assign each window to a chunk based on the first token it scores
	num_chunks = (total_tokens + ttt_chunk - 1) // ttt_chunk
	chunk_windows: list[list[int]] = [[] for _ in range(num_chunks)]
	for ws in window_starts:
	end = min(ws + seq_len, total_tokens)
	wlen = end - ws
	s = 0 if ws == 0 else max(wlen - stride, 0)
	scored_start = ws + s
	ci = min(scored_start // ttt_chunk, num_chunks - 1)
	chunk_windows[ci].append(ws)

	log0(f"ttt_sliding:start chunks={num_chunks} chunk_tokens={ttt_chunk} "
	f"total_windows={len(window_starts)} stride={stride} "
	f"ttt_lr={args.ttt_lr} ttt_epochs={args.ttt_epochs} "
	f"freeze_blocks={args.ttt_freeze_blocks}")

	loss_sum = torch.zeros((), device=device, dtype=torch.float64)
	token_count = torch.zeros((), device=device, dtype=torch.float64)
	byte_count = torch.zeros((), device=device, dtype=torch.float64)

	# Freeze first N blocks
	frozen_block_ids = set(range(min(args.ttt_freeze_blocks, len(base_model.blocks))))
	ttt_params = []
	for name, p in base_model.named_parameters():
	freeze = False
	for bi in frozen_block_ids:
	if f"blocks.{bi}." in name:
	freeze = True
	break
	if freeze:
	p.requires_grad_(False)
	else:
	p.requires_grad_(True)
	ttt_params.append(p)

	log0(f"ttt_sliding:params unfrozen={sum(p.numel() for p in ttt_params)} "
	f"frozen={sum(p.numel() for p in base_model.parameters() if not p.requires_grad)}")

	optimizer = torch.optim.SGD(ttt_params, lr=args.ttt_lr, momentum=args.ttt_momentum)
	t0 = time.perf_counter()

	for ci in range(num_chunks):
	windows = chunk_windows[ci]
	if not windows:
	continue
	chunk_start = ci * ttt_chunk
	chunk_end = min((ci + 1) * ttt_chunk, total_tokens)

	# --- Phase 1: SCORE this chunk's windows (inference_mode) ---
	my_s = (len(windows) * rank) // world_size
	my_e = (len(windows) * (rank + 1)) // world_size
	my_windows = windows[my_s:my_e]

	base_model.eval()
	with torch.inference_mode():
	for bi in range(0, len(my_windows), batch_seqs):
	batch_ws = my_windows[bi:bi + batch_seqs]
	bsz = len(batch_ws)
	x_batch = torch.zeros(bsz, seq_len, dtype=torch.int64, device=device)
	y_batch = torch.zeros(bsz, seq_len, dtype=torch.int64, device=device)
	wlens: list[int] = []
	for i, ws in enumerate(batch_ws):
	end = min(ws + seq_len, total_tokens)
	wlen = end - ws
	wlens.append(wlen)
	chunk_tok = val_tokens[ws:end + 1].to(dtype=torch.int64, device=device)
	x_batch[i, :wlen] = chunk_tok[:-1]
	y_batch[i, :wlen] = chunk_tok[1:]
	with torch.autocast(device_type="cuda", dtype=torch.bfloat16):
	logits = base_model.forward_logits(x_batch)
	nll = F.cross_entropy(
	logits.reshape(-1, logits.size(-1)).float(),
	y_batch.reshape(-1), reduction="none",
	).reshape(bsz, seq_len)
	for i, ws in enumerate(batch_ws):
	wlen = wlens[i]
	s = 0 if ws == 0 else max(wlen - stride, 0)
	scored_nll = nll[i, s:wlen].to(torch.float64)
	loss_sum += scored_nll.sum()
	token_count += float(wlen - s)
	tgt, prev = y_batch[i, s:wlen], x_batch[i, s:wlen]
	tb = base_bytes_lut[tgt].to(torch.float64)
	tb += (has_leading_space_lut[tgt] & ~is_boundary_token_lut[prev]).to(torch.float64)
	byte_count += tb.sum()

	# --- Phase 2: TRAIN on this chunk (already scored = legal) ---
	is_last_chunk = (ci == num_chunks - 1)
	if not is_last_chunk and args.ttt_epochs > 0:
	base_model.train()
	chunk_seqs = (chunk_end - chunk_start) // seq_len
	if chunk_seqs > 0:
	cos_lr = args.ttt_lr * 0.5 * (1.0 + math.cos(math.pi * ci / max(num_chunks - 1, 1)))
	for pg in optimizer.param_groups:
	pg['lr'] = cos_lr
	my_seq_s = (chunk_seqs * rank) // world_size
	my_seq_e = (chunk_seqs * (rank + 1)) // world_size
	my_chunk_seqs = my_seq_e - my_seq_s
	for _ep in range(args.ttt_epochs):
	for bs in range(0, my_chunk_seqs, args.ttt_batch_seqs):
	be = min(bs + args.ttt_batch_seqs, my_chunk_seqs)
	actual_bs = my_seq_s + bs
	start_tok = chunk_start + actual_bs * seq_len
	end_tok = chunk_start + (my_seq_s + be) * seq_len + 1
	if end_tok > val_tokens.numel():
	continue
	local = val_tokens[start_tok:end_tok].to(device=device, dtype=torch.int64)
	x = local[:-1].reshape(-1, seq_len)
	y = local[1:].reshape(-1, seq_len)
	optimizer.zero_grad(set_to_none=True)
	with torch.autocast(device_type="cuda", dtype=torch.bfloat16):
	loss = base_model(x, y)
	loss.backward()
	if world_size > 1:
	for p in ttt_params:
	if p.grad is not None:
	dist.all_reduce(p.grad, op=dist.ReduceOp.AVG)
	torch.nn.utils.clip_grad_norm_(ttt_params, args.ttt_grad_clip)
	optimizer.step()

	if rank == 0 and (ci % 10 == 0 or ci == num_chunks - 1):
	elapsed = time.perf_counter() - t0
	rl = loss_sum.item() / max(token_count.item(), 1)
	rbpb = rl / math.log(2.0) * (token_count.item() / max(byte_count.item(), 1)) if token_count.item() > 0 else 0.0
	log0(f" ttt_chunk [{ci+1}/{num_chunks}] bpb={rbpb:.6f} time={elapsed:.1f}s")

	if dist.is_available() and dist.is_initialized():
	dist.all_reduce(loss_sum, op=dist.ReduceOp.SUM)
	dist.all_reduce(token_count, op=dist.ReduceOp.SUM)
	dist.all_reduce(byte_count, op=dist.ReduceOp.SUM)

	val_loss = (loss_sum / token_count).item()
	val_bpb = val_loss / math.log(2.0) * (token_count.item() / byte_count.item())

	for p in base_model.parameters():
	p.requires_grad_(True)
	base_model.eval()

	log0(f"ttt_sliding:done val_loss={val_loss:.6f} val_bpb={val_bpb:.6f} "
	f"elapsed={time.perf_counter() - t0:.1f}s")
	return val_loss, val_bpb


	# --- GPTQ-lite int6 quantization ---

	def _classify_param(name: str) -> str:
	if "tok_emb" in name or "lm_head" in name:
	return "embed"
	if ".mlp." in name:
	return "mlp"
	if ".attn." in name or (".proj." in name and ".mlp." not in name):
	return "attn"
	return "other"
	def quantize_int6_per_row(t: Tensor, clip_range: int = 31) -> tuple[Tensor, Tensor]:
	t32 = t.float()
	if t32.ndim == 2:
	best_q, best_s, best_err = None, None, float('inf')
	for pct in [0.9990, 0.9995, 0.9999, 0.99999, 1.0]:
	if pct < 1.0:
	row_clip = torch.quantile(t32.abs(), pct, dim=1)
	else:
	row_clip = t32.abs().amax(dim=1)
	s = (row_clip / clip_range).clamp_min(1.0 / clip_range).to(torch.float16)
	q = torch.clamp(torch.round(t32 / s.float()[:, None]), -clip_range, clip_range).to(torch.int8)
	recon = q.float() * s.float()[:, None]
	err = (t32 - recon).pow(2).mean().item()
	if err < best_err:
	best_q, best_s, best_err = q, s, err
	return best_q, best_s
	amax = t32.abs().max().item()
	scale = torch.tensor(amax / clip_range if amax > 0 else 1.0, dtype=torch.float16)
	q = torch.clamp(torch.round(t32 / scale.float()), -clip_range, clip_range).to(torch.int8)
	return q, scale

	def _unbank_state_dict(sd: dict[str, Tensor], num_layers: int) -> dict[str, Tensor]:
	"""Convert 3D bank tensors into individual 2D tensors with standard names."""
	out: dict[str, Tensor] = {}
	n = num_layers
	for name, tensor in sd.items():
	if name == "qo_bank":
	for i in range(n):
	out[f"blocks.{i}.attn.c_q.weight"] = tensor[i]
	out[f"blocks.{i}.attn.proj.weight"] = tensor[n + i]
	elif name == "kv_bank":
	for i in range(n):
	out[f"blocks.{i}.attn.c_k.weight"] = tensor[i]
	out[f"blocks.{i}.attn.c_v.weight"] = tensor[n + i]
	elif name == "mlp_up_bank":
	for i in range(n):
	out[f"blocks.{i}.mlp.fc.weight"] = tensor[i]
	elif name == "mlp_down_bank":
	for i in range(n):
	out[f"blocks.{i}.mlp.proj.weight"] = tensor[i]
	else:
	out[name] = tensor
	return out

	def _rebank_state_dict(sd: dict[str, Tensor], num_layers: int, template_sd: dict[str, Tensor]) -> dict[str, Tensor]:
	"""Convert individual 2D tensors back into 3D bank tensors."""
	out: dict[str, Tensor] = {}
	n = num_layers
	# Reconstruct banks from individual weight keys
	qo_slices = [None] * (2 * n)
	kv_slices = [None] * (2 * n)
	up_slices = [None] * n
	down_slices = [None] * n
	consumed = set()
	for i in range(n):
	qk = f"blocks.{i}.attn.c_q.weight"
	if qk in sd:
	qo_slices[i] = sd[qk]
	consumed.add(qk)
	ok = f"blocks.{i}.attn.proj.weight"
	if ok in sd:
	qo_slices[n + i] = sd[ok]
	consumed.add(ok)
	kk = f"blocks.{i}.attn.c_k.weight"
	if kk in sd:
	kv_slices[i] = sd[kk]
	consumed.add(kk)
	vk = f"blocks.{i}.attn.c_v.weight"
	if vk in sd:
	kv_slices[n + i] = sd[vk]
	consumed.add(vk)
	fk = f"blocks.{i}.mlp.fc.weight"
	if fk in sd:
	up_slices[i] = sd[fk]
	consumed.add(fk)
	dk = f"blocks.{i}.mlp.proj.weight"
	if dk in sd:
	down_slices[i] = sd[dk]
	consumed.add(dk)
	out["qo_bank"] = torch.stack(qo_slices).to(dtype=template_sd["qo_bank"].dtype)
	out["kv_bank"] = torch.stack(kv_slices).to(dtype=template_sd["kv_bank"].dtype)
	out["mlp_up_bank"] = torch.stack(up_slices).to(dtype=template_sd["mlp_up_bank"].dtype)
	out["mlp_down_bank"] = torch.stack(down_slices).to(dtype=template_sd["mlp_down_bank"].dtype)
	for name, tensor in sd.items():
	if name not in consumed:
	out[name] = tensor
	return out

	def mixed_quantize_int6(state_dict: dict[str, Tensor], int6_cats: set[str], clip_range: int = 31,
	hessians: dict[str, Tensor] \| None = None):
	num_layers_total = max(
	(int(k.split(".")[1]) for k in state_dict if k.startswith("blocks.")),
	default=0,
	) + 1
	late_k_layers = set(range(num_layers_total - 2, num_layers_total))
	result: dict[str, Tensor] = {}
	meta: dict[str, object] = {}
	gptq_count, naive_count = 0, 0
	for name, tensor in state_dict.items():
	t = tensor.detach().cpu().contiguous()
	cat = _classify_param(name)
	if not t.is_floating_point() or t.numel() <= 65536:
	result[name] = t.to(torch.float16) if t.is_floating_point() else t
	meta[name] = "passthrough"
	continue
	if any(p in name for p in CONTROL_TENSOR_NAME_PATTERNS):
	result[name] = t.float()
	meta[name] = "passthrough_ctrl"
	continue
	if cat in int6_cats and t.ndim >= 1:
	H = hessians.get(name) if hessians else None
	if H is not None and t.ndim == 2:
	q, s = gptq_quantize_weight(t, H.cpu(), clip_range=clip_range)
	gptq_count += 1
	else:
	q, s = quantize_int6_per_row(t, clip_range=clip_range)
	naive_count += 1
	result[name + ".q"] = q
	result[name + ".scale"] = s
	meta[name] = {"type": "int6"}
	else:
	q, s = quantize_float_tensor(t)
	result[name + ".q"] = q
	result[name + ".scale"] = s
	meta[name] = {"type": "int8"}
	if hessians:
	print(f"gptq_quantize: {gptq_count} GPTQ layers, {naive_count} naive layers", flush=True)
	return result, meta
	def dequantize_mixed_int6(result: dict[str, Tensor], meta: dict[str, object],
	template_sd: dict[str, Tensor]) -> dict[str, Tensor]:
	out: dict[str, Tensor] = {}
	for name, orig in template_sd.items():
	info = meta.get(name)
	if info is None:
	continue
	orig_dtype = orig.dtype
	if info in ("passthrough", "passthrough_ctrl", "passthrough_fp16"):
	t = result[name]
	if t.dtype == torch.float16 and orig_dtype in (torch.float32, torch.bfloat16):
	t = t.to(orig_dtype)
	out[name] = t
	continue
	q, s = result[name + ".q"], result[name + ".scale"]
	if s.ndim > 0:
	out[name] = (q.float() * s.float().view(q.shape[0], ([1] (q.ndim - 1)))).to(orig_dtype)
	else:
	out[name] = (q.float() * float(s.item())).to(orig_dtype)
	return out

	# --- Full Hessian GPTQ ---

	def gptq_quantize_weight(W: Tensor, H: Tensor, clip_range: int = 31,
	block_size: int = 128, percdamp: float = 0.01) -> tuple[Tensor, Tensor]:
	"""GPTQ with Cholesky error compensation and actorder (Frantar et al., ICLR 2023)."""
	W_orig = W.float().clone()
	rows, cols = W_orig.shape
	H = H.float().clone()
	dead = torch.diag(H) == 0
	H[dead, dead] = 1
	damp = percdamp * H.diag().mean()
	H.diagonal().add_(damp)
	perm = torch.argsort(H.diag(), descending=True)
	invperm = torch.argsort(perm)
	W_perm = W_orig[:, perm].clone()
	W_perm[:, dead[perm]] = 0
	H = H[perm][:, perm]
	try:
	Hinv = torch.cholesky_inverse(torch.linalg.cholesky(H))
	Hinv = torch.linalg.cholesky(Hinv, upper=True)
	except torch.linalg.LinAlgError:
	return quantize_int6_per_row(W_orig, clip_range)
	best_q, best_scale, best_err = None, None, float('inf')
	for pct in [0.9990, 0.9995, 0.9999, 0.99999, 1.0]:
	if pct < 1.0:
	row_clip = torch.quantile(W_orig.abs(), pct, dim=1)
	else:
	row_clip = W_orig.abs().amax(dim=1)
	s = (row_clip / clip_range).clamp_min(1.0 / clip_range).to(torch.float16)
	sf = s.float()
	Q = torch.zeros(rows, cols, dtype=torch.int8)
	W_work = W_perm.clone()
	for i1 in range(0, cols, block_size):
	i2 = min(i1 + block_size, cols)
	W_block = W_work[:, i1:i2].clone()
	Hinv_block = Hinv[i1:i2, i1:i2]
	Err = torch.zeros(rows, i2 - i1)
	for j in range(i2 - i1):
	w_col = W_block[:, j]
	d = Hinv_block[j, j]
	q_col = torch.clamp(torch.round(w_col / sf), -clip_range, clip_range)
	Q[:, i1 + j] = q_col.to(torch.int8)
	err = (w_col - q_col.float() * sf) / d
	Err[:, j] = err
	W_block[:, j:] -= err.unsqueeze(1) * Hinv_block[j, j:].unsqueeze(0)
	if i2 < cols:
	W_work[:, i2:] -= Err @ Hinv[i1:i2, i2:]
	recon = Q.float() * sf[:, None]
	mse = (W_perm - recon).pow(2).mean().item()
	if mse < best_err:
	best_q, best_scale, best_err = Q, s, mse
	best_q = best_q[:, invperm]
	return best_q, best_scale

	def _init_hessians(nl: int, dim: int, mlp_dim: int, device: torch.device) -> dict[str, Tensor]:
	h: dict[str, Tensor] = {}
	for i in range(nl):
	for k in ['c_q', 'c_k', 'c_v']:
	h[f'blocks.{i}.attn.{k}.weight'] = torch.zeros(dim, dim, dtype=torch.float32, device=device)
	h[f'blocks.{i}.attn.proj.weight'] = torch.zeros(dim, dim, dtype=torch.float32, device=device)
	h[f'blocks.{i}.mlp.fc.weight'] = torch.zeros(dim, dim, dtype=torch.float32, device=device)
	h[f'blocks.{i}.mlp.proj.weight'] = torch.zeros(mlp_dim, mlp_dim, dtype=torch.float32, device=device)
	return h

	def _accum_hessians(hessians: dict[str, Tensor], blocks: nn.ModuleList, dim: int, mlp_dim: int) -> None:
	for i, block in enumerate(blocks):
	qkv_in = block.attn._gptq_qkv_in.float().reshape(-1, dim)
	h_qkv = qkv_in.t() @ qkv_in
	hessians[f'blocks.{i}.attn.c_q.weight'] += h_qkv
	hessians[f'blocks.{i}.attn.c_k.weight'] += h_qkv
	hessians[f'blocks.{i}.attn.c_v.weight'] += h_qkv
	o_in = block.attn._gptq_o_in.float().reshape(-1, dim)
	hessians[f'blocks.{i}.attn.proj.weight'] += o_in.t() @ o_in
	up_in = block.mlp._gptq_up_in.float().reshape(-1, dim)
	hessians[f'blocks.{i}.mlp.fc.weight'] += up_in.t() @ up_in
	down_in = block.mlp._gptq_down_in.float().reshape(-1, mlp_dim)
	hessians[f'blocks.{i}.mlp.proj.weight'] += down_in.t() @ down_in

	def _finalize_hessians(hessians: dict[str, Tensor], num_batches: int) -> None:
	for name in hessians:
	hessians[name] = hessians[name].cpu() / num_batches
	damp = 0.01 * torch.diag(hessians[name]).mean().clamp_min(1e-6)
	hessians[name] += damp * torch.eye(hessians[name].shape[0])

	def gptq_collect_hessians(base_model: nn.Module, train_loader, device: torch.device,
	num_batches: int, batch_tokens: int, seq_len: int,
	grad_accum_steps: int) -> dict[str, Tensor]:
	"""Collect Hessians H = X^T X from training data."""
	nl = base_model.num_layers
	dim = base_model.tok_emb.weight.shape[1]
	mlp_dim = base_model.mlp_up_bank.shape[1]
	hessians = _init_hessians(nl, dim, mlp_dim, device)
	for block in base_model.blocks:
	block.attn._save_gptq = True
	block.mlp._save_gptq = True
	base_model.eval()
	with torch.inference_mode(), torch.autocast(device_type='cuda', dtype=torch.bfloat16):
	for _ in range(num_batches):
	x, y = train_loader.next_batch(batch_tokens, seq_len, grad_accum_steps)
	base_model(x, y)
	_accum_hessians(hessians, base_model.blocks, dim, mlp_dim)
	for block in base_model.blocks:
	block.attn._save_gptq = False
	block.mlp._save_gptq = False
	_finalize_hessians(hessians, num_batches)
	base_model.train()
	return hessians

	# --- Training ---

	def main() -> None:
	code = Path(__file__).read_text(encoding="utf-8")
	args = Hyperparameters()
	# zeropower_via_newtonschulz5 runs eagerly with bmm -- do NOT compile
	distributed = "RANK" in os.environ and "WORLD_SIZE" in os.environ
	rank = int(os.environ.get("RANK", "0"))
	world_size = int(os.environ.get("WORLD_SIZE", "1"))
	local_rank = int(os.environ.get("LOCAL_RANK", "0"))
	if world_size <= 0:
	raise ValueError(f"WORLD_SIZE must be positive, got {world_size}")
	if 8 % world_size != 0:
	raise ValueError(f"WORLD_SIZE={world_size} must divide 8 so grad_accum_steps stays integral")
	grad_accum_steps = 8 // world_size
	grad_scale = 1.0 / grad_accum_steps
	if not torch.cuda.is_available():
	raise RuntimeError("CUDA is required")
	device = torch.device("cuda", local_rank)
	torch.cuda.set_device(device)
	if distributed:
	dist.init_process_group(backend="nccl", device_id=device)
	dist.barrier()
	master_process = rank == 0
	torch.backends.cuda.matmul.allow_tf32 = True
	torch.backends.cudnn.allow_tf32 = True
	from torch.backends.cuda import enable_cudnn_sdp, enable_flash_sdp, enable_math_sdp, enable_mem_efficient_sdp
	enable_cudnn_sdp(False)
	enable_flash_sdp(True)
	enable_mem_efficient_sdp(False)
	enable_math_sdp(False)
	logfile = None
	if master_process:
	os.makedirs("logs", exist_ok=True)
	logfile = f"logs/{args.run_id}.txt"
	print(logfile)
	def log0(msg: str, console: bool = True) -> None:
	if not master_process:
	return
	if console:
	print(msg)
	if logfile is not None:
	with open(logfile, "a", encoding="utf-8") as f:
	print(msg, file=f)
	log0(code, console=False)
	log0("=" * 100, console=False)
	log0(f"Running Python {sys.version}", console=False)
	log0(f"Running PyTorch {torch.__version__}", console=False)
	log0(
	subprocess.run(["nvidia-smi"], stdout=subprocess.PIPE, stderr=subprocess.PIPE, text=True, check=False).stdout,
	console=False,
	)
	log0("=" * 100, console=False)
	random.seed(args.seed)
	np.random.seed(args.seed)
	torch.manual_seed(args.seed)
	torch.cuda.manual_seed_all(args.seed)
	(base_bytes_lut, has_leading_space_lut, is_boundary_token_lut), tokenizer_metadata = load_tokenizer_luts(
	args.tokenizer_path, args.tokenizer_meta_path, args.vocab_size, device,
	validate_meta=args.tokenizer_meta_validate,
	)
	log0(f"tokenizer: kind={tokenizer_metadata.get('tokenizer_kind', 'unknown')} vocab={tokenizer_metadata.get('vocab_size', '?')}")
	if tokenizer_metadata.get('tokenizer_kind') == 'sentencepiece':
	sp = spm.SentencePieceProcessor(model_file=args.tokenizer_path)
	if int(sp.vocab_size()) != args.vocab_size:
	raise ValueError(
	f"VOCAB_SIZE={args.vocab_size} does not match tokenizer vocab_size={int(sp.vocab_size())}"
	)
	dataset_dir = Path(args.data_path).resolve()
	actual_train_files = len(list(dataset_dir.glob("fineweb_train_*.bin")))
	effective_eval_seq_len = args.eval_seq_len if args.eval_seq_len > 0 else args.train_seq_len
	val_seq_len = max(args.train_seq_len, effective_eval_seq_len)
	val_tokens = load_validation_tokens(args.val_files, val_seq_len)
	log0(f"train_loader:dataset:{dataset_dir.name} train_shards:{actual_train_files}")
	log0(f"val_loader:shards pattern={args.val_files} tokens:{val_tokens.numel() - 1}")
	base_model = GPT(
	vocab_size=args.vocab_size,
	num_layers=args.num_layers,
	model_dim=args.model_dim,
	num_heads=args.num_heads,
	num_kv_heads=args.num_kv_heads,
	mlp_mult=args.mlp_mult,
	tie_embeddings=args.tie_embeddings,
	tied_embed_init_std=args.tied_embed_init_std,
	logit_softcap=args.logit_softcap,
	rope_base=args.rope_base,
	qk_gain_init=args.qk_gain_init,
	bigram_vocab_size=args.bigram_vocab_size,
	bigram_dim=args.bigram_dim,
	xsa_last_n=args.xsa_last_n,
	rope_dims=args.rope_dims,
	ln_scale=args.ln_scale,
	ve_enabled=args.ve_enabled,
	ve_dim=args.ve_dim,
	ve_layers=args.ve_layers,
	neg_slope=args.negative_slope,
	window_attn_size=args.window_attn_size,
	window_attn_layers=args.window_attn_layers,
	num_sink_tokens=args.num_sink_tokens,
	train_seq_len=args.train_seq_len,
	train_seq_len_long=args.train_seq_len_long,
	).to(device).bfloat16()
	# Banks stay FP32 (like CastedLinear weights), cast to BF16 in forward
	base_model.qo_bank.data = base_model.qo_bank.data.float()
	base_model.kv_bank.data = base_model.kv_bank.data.float()
	base_model.mlp_up_bank.data = base_model.mlp_up_bank.data.float()
	base_model.mlp_down_bank.data = base_model.mlp_down_bank.data.float()
	for module in base_model.modules():
	if isinstance(module, CastedLinear):
	module.float()
	restore_low_dim_params_to_fp32(base_model)
	# No DDP -- Parallel Muon handles bank grad communication via reduce-scatter,
	# and non-bank grads are manually all-reduced before Adam steps.
	compiled_model = torch.compile(base_model, dynamic=False, fullgraph=True)
	model = compiled_model

	# Optimizer split:
	# - 4 parameter banks -> Muon (batched Newton-Schulz)
	# - token embedding -> Adam
	# - scalars/control tensors -> Adam
	# - bigram proj, VE proj -> Adam (small matrix params not worth banking)
	matrix_params = [
	base_model.qo_bank, base_model.kv_bank,
	base_model.mlp_up_bank, base_model.mlp_down_bank,
	]
	block_named_params = list(base_model.blocks.named_parameters())
	scalar_params = [
	p
	for name, p in block_named_params
	if p.ndim < 2 or any(pattern in name for pattern in CONTROL_TENSOR_NAME_PATTERNS)
	]
	if base_model.skip_weights.numel() > 0:
	scalar_params.append(base_model.skip_weights)
	scalar_params.append(base_model.smear.gate)
	if base_model.bigram is not None:
	scalar_params.append(base_model.bigram.scale)
	token_lr = args.tied_embed_lr if args.tie_embeddings else args.embed_lr
	tok_params = [{"params": [base_model.tok_emb.weight], "lr": token_lr, "base_lr": token_lr}]
	if base_model.bigram is not None:
	tok_params.append({"params": [base_model.bigram.embed.weight], "lr": token_lr, "base_lr": token_lr})
	if base_model.bigram.proj is not None:
	scalar_params.append(base_model.bigram.proj.weight)
	if base_model.ve_shared is not None:
	tok_params.append({"params": [base_model.ve_shared.embed.weight], "lr": token_lr, "base_lr": token_lr})
	if base_model.ve_shared.proj is not None:
	scalar_params.append(base_model.ve_shared.proj.weight)
	scalar_params.append(base_model.ve_shared.scale)
	for s in base_model.ve_layer_scales:
	scalar_params.append(s)
	optimizer_tok = torch.optim.AdamW(
	tok_params,
	betas=(args.beta1, args.beta2),
	eps=args.adam_eps,
	weight_decay=args.adam_wd,
	fused=True,
	)
	optimizer_muon = Muon(
	matrix_params,
	lr=args.matrix_lr,
	momentum=args.muon_momentum,
	backend_steps=args.muon_backend_steps,
	weight_decay=args.muon_wd,
	)
	for group in optimizer_muon.param_groups:
	group["base_lr"] = args.matrix_lr
	optimizer_scalar = torch.optim.AdamW(
	[{"params": scalar_params, "lr": args.scalar_lr, "base_lr": args.scalar_lr}],
	betas=(args.beta1, args.beta2),
	eps=args.adam_eps,
	weight_decay=args.adam_wd,
	fused=True,
	)
	# Non-bank params that need manual all-reduce (replicated across GPUs)
	replicated_params = list(optimizer_tok.param_groups[0]["params"])
	for pg in optimizer_tok.param_groups[1:]:
	replicated_params.extend(pg["params"])
	replicated_params.extend(scalar_params)

	optimizer_head = None
	if base_model.lm_head is not None:
	optimizer_head = torch.optim.Adam(
	[{"params": [base_model.lm_head.weight], "lr": args.head_lr, "base_lr": args.head_lr}],
	betas=(args.beta1, args.beta2),
	eps=args.adam_eps,
	fused=True,
	)
	replicated_params.append(base_model.lm_head.weight)
	optimizers: list[torch.optim.Optimizer] = [optimizer_tok, optimizer_muon, optimizer_scalar]
	if optimizer_head is not None:
	optimizers.append(optimizer_head)
	log0(f"model_params:{sum(p.numel() for p in base_model.parameters())}")
	xsa_layers = [i for i, b in enumerate(base_model.blocks) if b.attn.use_xsa]
	log0(f"XSA:last_{args.xsa_last_n} active_layers:{xsa_layers}")
	window_layers = [i for i, b in enumerate(base_model.blocks) if b.attn.window_size > 0]
	if window_layers:
	sink_str = f" sink_tokens={args.num_sink_tokens}" if args.num_sink_tokens > 0 else ""
	log0(f"window_attn:size={args.window_attn_size} layers:{window_layers}{sink_str}")
	log0(f"world_size:{world_size} grad_accum_steps:{grad_accum_steps}")
	log0("sdp_backends:cudnn=False flash=True mem_efficient=False math=False")
	log0(f"attention_mode:gqa num_heads:{args.num_heads} num_kv_heads:{args.num_kv_heads}")
	log0(
	f"tie_embeddings:{args.tie_embeddings} embed_lr:{token_lr} "
	f"head_lr:{args.head_lr if base_model.lm_head is not None else 0.0} "
	f"matrix_lr:{args.matrix_lr} scalar_lr:{args.scalar_lr}"
	)
	log0(
	f"train_batch_tokens:{args.train_batch_tokens} train_seq_len:{args.train_seq_len} "
	f"iterations:{args.iterations} warmup_steps:{args.warmup_steps} "
	f"max_wallclock_seconds:{args.max_wallclock_seconds:.3f}"
	)
	log0(f"seed:{args.seed}")
	# Mixed sequence length training: last num_gpus_long ranks use long sequences
	if args.train_seq_len_long > 0 and args.num_gpus_long > 0:
	if rank >= world_size - args.num_gpus_long:
	effective_train_seq_len = args.train_seq_len_long
	else:
	effective_train_seq_len = args.train_seq_len
	else:
	effective_train_seq_len = args.train_seq_len
	log0(f"rank:{rank} effective_train_seq_len:{effective_train_seq_len}")
	train_loader = DistributedTokenLoader(args.train_files, rank, world_size, device)
	def zero_grad_all() -> None:
	for opt in optimizers:
	opt.zero_grad(set_to_none=True)
	max_wallclock_ms = 1000.0 * args.max_wallclock_seconds if args.max_wallclock_seconds > 0 else None
	if args.use_gptq and max_wallclock_ms is not None:
	max_wallclock_ms -= args.gptq_reserve_ms
	log0(f"gptq:reserving {args.gptq_reserve_ms:.0f}ms from training budget, effective={max_wallclock_ms:.0f}ms")
	def lr_mul(step: int, elapsed_ms: float) -> float:
	if args.warmdown_iters <= 0:
	return 1.0
	if max_wallclock_ms is None:
	warmdown_start = max(args.iterations - args.warmdown_iters, 0)
	return max((args.iterations - step) / max(args.warmdown_iters, 1), 0.0) if warmdown_start <= step < args.iterations else 1.0
	step_ms = elapsed_ms / max(step, 1)
	warmdown_ms = args.warmdown_iters * step_ms
	remaining_ms = max(max_wallclock_ms - elapsed_ms, 0.0)
	return remaining_ms / max(warmdown_ms, 1e-9) if remaining_ms <= warmdown_ms else 1.0
	if args.warmup_steps > 0:
	initial_model_state = {name: tensor.detach().cpu().clone() for name, tensor in base_model.state_dict().items()}
	initial_optimizer_states = [copy.deepcopy(opt.state_dict()) for opt in optimizers]
	model.train()
	for warmup_step in range(args.warmup_steps):
	zero_grad_all()
	for micro_step in range(grad_accum_steps):
	x, y = train_loader.next_batch(args.train_batch_tokens, effective_train_seq_len, grad_accum_steps)
	with torch.autocast(device_type="cuda", dtype=torch.bfloat16, enabled=True):
	warmup_loss = model(x, y)
	(warmup_loss * grad_scale).backward()
	# All-reduce all grads for warmup (simple, not optimized)
	if distributed:
	for p in base_model.parameters():
	if p.grad is not None:
	dist.all_reduce(p.grad, op=dist.ReduceOp.AVG)
	for opt in optimizers:
	opt.step()
	zero_grad_all()
	if args.warmup_steps <= 20 or (warmup_step + 1) % 10 == 0 or warmup_step + 1 == args.warmup_steps:
	log0(f"warmup_step:{warmup_step + 1}/{args.warmup_steps}")
	base_model.load_state_dict(initial_model_state, strict=True)
	for opt, state in zip(optimizers, initial_optimizer_states, strict=True):
	opt.load_state_dict(state)
	zero_grad_all()
	train_loader = DistributedTokenLoader(args.train_files, rank, world_size, device)
	swa_state: dict[str, Tensor] \| None = None
	swa_count = 0
	ema_state = {name: t.detach().float().clone() for name, t in base_model.state_dict().items()}
	ema_decay = 0.997
	training_time_ms = 0.0
	stop_after_step: int \| None = None
	torch.cuda.synchronize()
	t0 = time.perf_counter()
	step = 0
	while True:
	last_step = step == args.iterations or (stop_after_step is not None and step >= stop_after_step)
	should_validate = last_step or (args.val_loss_every > 0 and step % args.val_loss_every == 0)
	if should_validate:
	torch.cuda.synchronize()
	training_time_ms += 1000.0 * (time.perf_counter() - t0)
	val_loss, val_bpb = eval_val(
	args,
	model,
	rank,
	world_size,
	device,
	grad_accum_steps,
	val_tokens,
	base_bytes_lut,
	has_leading_space_lut,
	is_boundary_token_lut,
	)
	log0(
	f"step:{step}/{args.iterations} val_loss:{val_loss:.4f} val_bpb:{val_bpb:.4f} "
	f"train_time:{training_time_ms:.0f}ms step_avg:{training_time_ms / max(step, 1):.2f}ms"
	)
	torch.cuda.synchronize()
	t0 = time.perf_counter()
	if last_step:
	if stop_after_step is not None and step < args.iterations:
	log0(
	f"stopping_early: wallclock_cap train_time:{training_time_ms:.0f}ms "
	f"step:{step}/{args.iterations}"
	)
	break
	elapsed_ms = training_time_ms + 1000.0 * (time.perf_counter() - t0)
	scale = lr_mul(step, elapsed_ms)
	zero_grad_all()
	train_loss = torch.zeros((), device=device)
	for micro_step in range(grad_accum_steps):
	x, y = train_loader.next_batch(args.train_batch_tokens, effective_train_seq_len, grad_accum_steps)
	with torch.autocast(device_type="cuda", dtype=torch.bfloat16, enabled=True):
	loss = model(x, y)
	train_loss += loss.detach()
	(loss * grad_scale).backward()
	train_loss /= grad_accum_steps
	frac = min(step / args.muon_momentum_warmup_steps, 1.0) if args.muon_momentum_warmup_steps > 0 else 1.0
	muon_momentum = (1 - frac) * args.muon_momentum_warmup_start + frac * args.muon_momentum
	for group in optimizer_muon.param_groups:
	group["momentum"] = muon_momentum
	for opt in optimizers:
	for group in opt.param_groups:
	group["lr"] = group["base_lr"] * scale
	if args.grad_clip_norm > 0:
	torch.nn.utils.clip_grad_norm_(base_model.parameters(), args.grad_clip_norm)
	# === 3-phase overlapped optimizer step ===
	# Phase 1: Launch async reduce-scatter for banks (biggest first)
	optimizer_muon.launch_reduce_scatters()
	# Phase 2: All-reduce non-bank grads + step Adam (while bank RS is in-flight)
	if distributed:
	for p in replicated_params:
	if p.grad is not None:
	dist.all_reduce(p.grad, op=dist.ReduceOp.AVG)
	optimizer_tok.step()
	optimizer_scalar.step()
	if optimizer_head is not None:
	optimizer_head.step()
	# Phase 3: Wait for RS, local NS5, all-gather (banks processed last)
	optimizer_muon.step()
	zero_grad_all()
	# EMA update
	with torch.no_grad():
	for name, t in base_model.state_dict().items():
	ema_state[name].mul_(ema_decay).add_(t.detach().float(), alpha=1.0 - ema_decay)
	step += 1
	approx_training_time_ms = training_time_ms + 1000.0 * (time.perf_counter() - t0)
	if args.swa_enabled and scale < 0.2 and step % args.swa_every == 0:
	if swa_state is None:
	swa_state = {name: t.detach().cpu().clone() for name, t in base_model.state_dict().items()}
	swa_count = 1
	log0(f"swa:start step:{step}")
	else:
	for name, t in base_model.state_dict().items():
	swa_state[name] += t.detach().cpu()
	swa_count += 1
	should_log_train = (
	args.train_log_every > 0
	and (step <= 10 or step % args.train_log_every == 0 or stop_after_step is not None)
	)
	if should_log_train:
	log0(
	f"step:{step}/{args.iterations} train_loss:{train_loss.item():.4f} "
	f"train_time:{approx_training_time_ms:.0f}ms step_avg:{approx_training_time_ms / step:.2f}ms"
	)
	reached_cap = max_wallclock_ms is not None and approx_training_time_ms >= max_wallclock_ms
	if distributed and max_wallclock_ms is not None:
	reached_cap_tensor = torch.tensor(int(reached_cap), device=device)
	dist.all_reduce(reached_cap_tensor, op=dist.ReduceOp.MAX)
	reached_cap = bool(reached_cap_tensor.item())
	if stop_after_step is None and reached_cap:
	stop_after_step = step
	log0(
	f"peak memory allocated: {torch.cuda.max_memory_allocated() // 1024 // 1024} MiB "
	f"reserved: {torch.cuda.max_memory_reserved() // 1024 // 1024} MiB"
	)
	# Apply EMA weights
	log0("ema:applying EMA weights")
	current_state = base_model.state_dict()
	avg_state = {name: t.to(dtype=current_state[name].dtype) for name, t in ema_state.items()}
	base_model.load_state_dict(avg_state, strict=True)
	torch.cuda.synchronize()
	t_diag = time.perf_counter()
	diag_val_loss, diag_val_bpb = eval_val(
	args, compiled_model, rank, world_size, device, grad_accum_steps,
	val_tokens, base_bytes_lut, has_leading_space_lut, is_boundary_token_lut,
	)
	torch.cuda.synchronize()
	log0(
	f"DIAGNOSTIC post_ema val_loss:{diag_val_loss:.4f} val_bpb:{diag_val_bpb:.4f} "
	f"eval_time:{1000.0 * (time.perf_counter() - t_diag):.0f}ms"
	)
	export_sd = base_model.state_dict()
	if master_process:
	torch.save(export_sd, "final_model.pt")
	model_bytes = os.path.getsize("final_model.pt")
	code_bytes = len(code.encode("utf-8"))
	log0(f"Serialized model: {model_bytes} bytes")
	log0(f"Code size: {code_bytes} bytes")
	# Unbank 3D tensors into individual 2D tensors for quantization
	sd_cpu = {k: v.detach().cpu() for k, v in export_sd.items()}
	unbanked_sd = _unbank_state_dict(sd_cpu, args.num_layers)
	# GPTQ calibration: collect Hessians from training data
	gptq_hessians = None
	if args.use_gptq:
	t_gptq = time.perf_counter()
	log0(f"gptq:calibrating with {args.gptq_calib_samples} batches (training data)...")
	calib_loader = DistributedTokenLoader(args.train_files, rank, world_size, device)
	gptq_hessians = gptq_collect_hessians(
	base_model, calib_loader, device, num_batches=args.gptq_calib_samples,
	batch_tokens=args.train_batch_tokens, seq_len=args.train_seq_len,
	grad_accum_steps=grad_accum_steps)
	del calib_loader
	gptq_elapsed = time.perf_counter() - t_gptq
	log0(f"gptq:calibrated {len(gptq_hessians)} layers in {gptq_elapsed:.1f}s")
	torch.cuda.empty_cache()
	quant_result, quant_meta = mixed_quantize_int6(unbanked_sd, {"mlp", "attn"}, clip_range=args.quant_clip_range, hessians=gptq_hessians)
	quant_buf = io.BytesIO()
	torch.save({"w": quant_result, "m": quant_meta}, quant_buf)
	quant_raw = quant_buf.getvalue()
	quant_blob = lzma.compress(quant_raw, preset=6)
	if master_process:
	with open("final_model.int6.ptz", "wb") as f:
	f.write(quant_blob)
	quant_file_bytes = len(quant_blob)
	code_bytes = len(code.encode("utf-8"))
	log0(f"Serialized model int6+lzma: {quant_file_bytes} bytes")
	log0(f"Total submission size int6+lzma: {quant_file_bytes + code_bytes} bytes")
	if distributed:
	dist.barrier()
	with open("final_model.int6.ptz", "rb") as f:
	quant_blob_disk = f.read()
	quant_state = torch.load(
	io.BytesIO(lzma.decompress(quant_blob_disk)),
	map_location="cpu",
	)
	deq_unbanked = dequantize_mixed_int6(quant_state["w"], quant_state["m"], unbanked_sd)
	# Re-bank the dequantized tensors
	deq_state = _rebank_state_dict(deq_unbanked, args.num_layers, sd_cpu)
	eval_model = GPT(
	vocab_size=args.vocab_size, num_layers=args.num_layers, model_dim=args.model_dim,
	num_heads=args.num_heads, num_kv_heads=args.num_kv_heads, mlp_mult=args.mlp_mult,
	tie_embeddings=args.tie_embeddings, tied_embed_init_std=args.tied_embed_init_std,
	logit_softcap=args.logit_softcap, rope_base=args.rope_base, qk_gain_init=args.qk_gain_init,
	bigram_vocab_size=args.bigram_vocab_size, bigram_dim=args.bigram_dim,
	xsa_last_n=args.xsa_last_n,
	rope_dims=args.rope_dims, ln_scale=args.ln_scale,
	ve_enabled=args.ve_enabled, ve_dim=args.ve_dim, ve_layers=args.ve_layers,
	neg_slope=args.negative_slope,
	window_attn_size=args.window_attn_size,
	window_attn_layers=args.window_attn_layers,
	num_sink_tokens=args.num_sink_tokens,
	train_seq_len=args.train_seq_len,
	train_seq_len_long=args.train_seq_len_long,
	).to(device).bfloat16()
	eval_model.qo_bank.data = eval_model.qo_bank.data.float()
	eval_model.kv_bank.data = eval_model.kv_bank.data.float()
	eval_model.mlp_up_bank.data = eval_model.mlp_up_bank.data.float()
	eval_model.mlp_down_bank.data = eval_model.mlp_down_bank.data.float()
	for m in eval_model.modules():
	if isinstance(m, CastedLinear):
	m.float()
	restore_low_dim_params_to_fp32(eval_model)
	eval_model.load_state_dict(deq_state, strict=True)
	compiled_eval = torch.compile(eval_model, dynamic=False, fullgraph=True)
	torch.cuda.synchronize()
	t_qeval = time.perf_counter()
	q_val_loss, q_val_bpb = eval_val(
	args, compiled_eval, rank, world_size, device, grad_accum_steps,
	val_tokens, base_bytes_lut, has_leading_space_lut, is_boundary_token_lut,
	eval_seq_len=effective_eval_seq_len,
	)
	torch.cuda.synchronize()
	log0(
	f"final_int6_roundtrip val_loss:{q_val_loss:.4f} val_bpb:{q_val_bpb:.4f} "
	f"eval_time:{1000.0 * (time.perf_counter() - t_qeval):.0f}ms"
	)
	log0(f"final_int6_roundtrip_exact val_loss:{q_val_loss:.8f} val_bpb:{q_val_bpb:.8f}")
	sw_seq_len = effective_eval_seq_len
	if args.eval_stride > 0 and args.eval_stride < sw_seq_len:
	torch.cuda.synchronize()
	t_slide = time.perf_counter()
	sw_val_loss, sw_val_bpb = eval_val_sliding(
	args, eval_model, rank, world_size, device,
	val_tokens, base_bytes_lut, has_leading_space_lut, is_boundary_token_lut,
	stride=args.eval_stride,
	eval_seq_len=sw_seq_len,
	)
	torch.cuda.synchronize()
	log0(
	f"final_int6_sliding_window val_loss:{sw_val_loss:.4f} val_bpb:{sw_val_bpb:.4f} "
	f"stride:{args.eval_stride} eval_time:{1000.0 * (time.perf_counter() - t_slide):.0f}ms"
	)
	log0(f"final_int6_sliding_window_exact val_loss:{sw_val_loss:.8f} val_bpb:{sw_val_bpb:.8f}")
	log0(f"final_int8_zlib_roundtrip_exact val_loss:{sw_val_loss:.8f} val_bpb:{sw_val_bpb:.8f}")
	if args.eval_stride != 64 and 64 < sw_seq_len:
	torch.cuda.synchronize()
	t_slide64 = time.perf_counter()
	sw64_val_loss, sw64_val_bpb = eval_val_sliding(
	args, eval_model, rank, world_size, device,
	val_tokens, base_bytes_lut, has_leading_space_lut, is_boundary_token_lut,
	stride=64,
	eval_seq_len=sw_seq_len,
	)
	torch.cuda.synchronize()
	log0(
	f"final_int6_sliding_window_s64 val_loss:{sw64_val_loss:.4f} val_bpb:{sw64_val_bpb:.4f} "
	f"stride:64 eval_time:{1000.0 * (time.perf_counter() - t_slide64):.0f}ms"
	)
	log0(f"final_int6_sliding_window_s64_exact val_loss:{sw64_val_loss:.8f} val_bpb:{sw64_val_bpb:.8f}")
	log0(f"final_int8_zlib_roundtrip_exact val_loss:{sw64_val_loss:.8f} val_bpb:{sw64_val_bpb:.8f}")
	# Legal score-first TTT (PR #461 recipe)
	if args.ttt_enabled:
	torch.cuda.synchronize()
	t_ttt = time.perf_counter()
	ttt_loss, ttt_bpb = eval_val_sliding_ttt(
	args, eval_model, rank, world_size, device,
	val_tokens, base_bytes_lut, has_leading_space_lut, is_boundary_token_lut,
	stride=args.eval_stride, log0=log0,
	)
	torch.cuda.synchronize()
	log0(f"legal_ttt val_loss:{ttt_loss:.4f} val_bpb:{ttt_bpb:.4f} "
	f"eval_time:{1000.0 * (time.perf_counter() - t_ttt):.0f}ms")
	log0(f"legal_ttt_exact val_loss:{ttt_loss:.8f} val_bpb:{ttt_bpb:.8f}")
	if distributed:
	dist.destroy_process_group()
	if __name__ == "__main__":
	main()