"""
train_gpt.py — FarnsworthEngine v2: SOTA254 base + TTT v2 (cosine decay, discriminative LR,
low momentum) + Seq-Length Curriculum + Batch Warmup + D2Z LR Schedule + XSA + Mousse +
Temperature Scaling + all v1 techniques.
"""

from __future__ import annotations

import copy
import glob
import io
import math
import os
import random
import subprocess
import sys
import time
import uuid
import zlib
from pathlib import Path

try:
    import zstandard
    _COMPRESSOR = "zstd"
except ImportError:
    _COMPRESSOR = "zlib"

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

# -----------------------------
# HYPERPARAMETERS
# -----------------------------
# Default Simple Baseline run:
# - 9 transformer blocks at width 512
# - 8 attention heads with 4 KV heads (GQA) and 2x MLP expansion
# - vocab size 1024, sequence length 1024, tied embeddings
# - 524,288 train tokens per step for 20,000 iterations with a ~10 minute cap

class Hyperparameters:
    # Data paths are shard globs produced by the existing preprocessing pipeline.
    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))

    # Validation cadence and batch size. Validation always uses the full fineweb_val split.
    val_batch_size = int(os.environ.get("VAL_BATCH_SIZE", 524_288))
    val_loss_every = int(os.environ.get("VAL_LOSS_EVERY", 1000))
    train_log_every = int(os.environ.get("TRAIN_LOG_EVERY", 200))

    # Training length.
    iterations = int(os.environ.get("ITERATIONS", 20000))
    warmdown_iters = int(os.environ.get("WARMDOWN_ITERS", 1200))
    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))

    # Model shape.
    vocab_size = int(os.environ.get("VOCAB_SIZE", 1024))
    num_layers = int(os.environ.get("NUM_LAYERS", 9))
    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))

    # Optimizer hyperparameters.
    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", 0.05))
    tied_embed_init_std = float(os.environ.get("TIED_EMBED_INIT_STD", 0.005))
    matrix_lr = float(os.environ.get("MATRIX_LR", 0.04))
    scalar_lr = float(os.environ.get("SCALAR_LR", 0.04))
    muon_momentum = float(os.environ.get("MUON_MOMENTUM", 0.95))
    muon_backend_steps = int(os.environ.get("MUON_BACKEND_STEPS", 5))
    muon_momentum_warmup_start = float(os.environ.get("MUON_MOMENTUM_WARMUP_START", 0.85))
    muon_momentum_warmup_steps = int(os.environ.get("MUON_MOMENTUM_WARMUP_STEPS", 500))
    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))
    mtp_num_heads = int(os.environ.get("MTP_NUM_HEADS", 0))
    mtp_loss_weight = float(os.environ.get("MTP_LOSS_WEIGHT", 0.2))
    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", 200))
    muon_wd = float(os.environ.get("MUON_WD", 0.02))
    adam_wd = float(os.environ.get("ADAM_WD", 0.01))
    qat_enabled = bool(int(os.environ.get("QAT_ENABLED", "0")))
    bigram_vocab_size = int(os.environ.get("BIGRAM_VOCAB_SIZE", 4096))
    bigram_dim = int(os.environ.get("BIGRAM_DIM", 128))
    xsa_last_n = int(os.environ.get("XSA_LAST_N", 0))

    # TTT v2 (Test-Time Training)
    ttt_enabled = bool(int(os.environ.get("TTT_ENABLED", "1")))
    ttt_lr = float(os.environ.get("TTT_LR", 0.003))
    ttt_epochs = int(os.environ.get("TTT_EPOCHS", 5))
    ttt_momentum = float(os.environ.get("TTT_MOMENTUM", 0.3))
    ttt_batch_seqs = int(os.environ.get("TTT_BATCH_SEQS", 32))
    ttt_freeze_blocks = int(os.environ.get("TTT_FREEZE_BLOCKS", 2))
    ttt_cosine_decay = bool(int(os.environ.get("TTT_COSINE_DECAY", "1")))
    ttt_discriminative_lr = bool(int(os.environ.get("TTT_DISCRIMINATIVE_LR", "1")))
    ttt_wd = float(os.environ.get("TTT_WD", 0.01))

    # Sequence length curriculum
    seq_curriculum_enabled = bool(int(os.environ.get("SEQ_CURRICULUM", "1")))
    seq_curriculum_min = int(os.environ.get("SEQ_CURRICULUM_MIN", 256))
    seq_curriculum_ramp_frac = float(os.environ.get("SEQ_CURRICULUM_RAMP_FRAC", 0.25))

    # Batch size warmup
    batch_warmup_enabled = bool(int(os.environ.get("BATCH_WARMUP", "1")))
    batch_warmup_start_tokens = int(os.environ.get("BATCH_WARMUP_START", 262144))
    batch_warmup_steps = int(os.environ.get("BATCH_WARMUP_STEPS", 1000))

    # D2Z (decay-to-zero) LR schedule
    d2z_enabled = bool(int(os.environ.get("D2Z_ENABLED", "1")))
    d2z_warmup_steps = int(os.environ.get("D2Z_WARMUP_STEPS", 200))

    # Temperature scaling at eval
    temp_scaling_enabled = bool(int(os.environ.get("TEMP_SCALING", "1")))

    # Mousse optimizer (curvature-aware Muon)
    mousse_enabled = bool(int(os.environ.get("MOUSSE_ENABLED", "0")))

# -----------------------------
# MUON OPTIMIZER
# -----------------------------
#
# As borrowed from modded-nanogpt
# Background on Muon: https://kellerjordan.github.io/posts/muon/

def zeropower_via_newtonschulz5(G: Tensor, steps: int = 10, eps: float = 1e-7) -> Tensor:
    a, b, c = (3.4445, -4.7750, 2.0315)
    X = G.bfloat16()
    X /= X.norm() + eps
    transposed = G.size(0) > G.size(1)
    if transposed:
        X = X.T
    for _ in range(steps):
        A = X @ X.T
        B = b * A + c * A @ A
        X = a * X + B @ X
    return X.T if transposed else X


class Muon(torch.optim.Optimizer):
    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),
        )

    @torch.no_grad()
    def step(self, closure=None):
        loss = None
        if closure is not None:
            with torch.enable_grad():
                loss = closure()

        distributed = dist.is_available() and dist.is_initialized()
        world_size = dist.get_world_size() if distributed else 1
        rank = dist.get_rank() if distributed else 0

        for group in self.param_groups:
            params = group["params"]
            if not params:
                continue
            lr = group["lr"]
            momentum = group["momentum"]
            backend_steps = group["backend_steps"]
            nesterov = group["nesterov"]

            total_params = sum(int(p.numel()) for p in params)
            updates_flat = torch.zeros(total_params, device=params[0].device, dtype=torch.bfloat16)

            curr = 0
            for i, p in enumerate(params):
                if i % world_size == rank and p.grad is not None:
                    g = p.grad
                    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:
                        g = g.add(buf, alpha=momentum)
                    g = zeropower_via_newtonschulz5(g, steps=backend_steps)
                    g *= max(1, g.size(0) / g.size(1)) ** 0.5
                    updates_flat[curr : curr + p.numel()] = g.reshape(-1)
                curr += p.numel()

            if distributed:
                dist.all_reduce(updates_flat, op=dist.ReduceOp.SUM)

            wd = group.get("weight_decay", 0.0)
            curr = 0
            for p in params:
                if wd > 0.0:
                    p.data.mul_(1.0 - lr * wd)
                g = updates_flat[curr : curr + p.numel()].view_as(p).to(dtype=p.dtype)
                p.add_(g, alpha=-lr)
                curr += p.numel()

        return loss


class Mousse(torch.optim.Optimizer):
    """Curvature-aware Muon: diagonal Shampoo preconditioner + Newton-Schulz orthogonalization.

    Maintains per-row and per-column running variance of gradients for 2D params.
    Preconditions the gradient by (row_var^{-1/2}, col_var^{-1/2}) before NS5,
    giving the orthogonalization a better-conditioned input without full Kronecker cost.
    """
    def __init__(self, params, lr: float, momentum: float, backend_steps: int,
                 nesterov: bool = True, weight_decay: float = 0.0,
                 precond_beta: float = 0.99):
        super().__init__(
            params,
            dict(lr=lr, momentum=momentum, backend_steps=backend_steps,
                 nesterov=nesterov, weight_decay=weight_decay,
                 precond_beta=precond_beta),
        )

    @torch.no_grad()
    def step(self, closure=None):
        loss = None
        if closure is not None:
            with torch.enable_grad():
                loss = closure()

        distributed = dist.is_available() and dist.is_initialized()
        world_size = dist.get_world_size() if distributed else 1
        rank = dist.get_rank() if distributed else 0

        for group in self.param_groups:
            params = group["params"]
            if not params:
                continue
            lr = group["lr"]
            momentum = group["momentum"]
            backend_steps = group["backend_steps"]
            nesterov = group["nesterov"]
            precond_beta = group["precond_beta"]

            total_params = sum(int(p.numel()) for p in params)
            updates_flat = torch.zeros(total_params, device=params[0].device, dtype=torch.bfloat16)

            curr = 0
            for i, p in enumerate(params):
                if i % world_size == rank and p.grad is not None:
                    g = p.grad
                    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:
                        g = g.add(buf, alpha=momentum)
                    # Diagonal Shampoo preconditioner for 2D params
                    if g.ndim == 2:
                        if "row_var" not in state:
                            state["row_var"] = torch.ones(g.shape[0], device=g.device, dtype=torch.float32)
                            state["col_var"] = torch.ones(g.shape[1], device=g.device, dtype=torch.float32)
                        g32 = g.float()
                        row_sq = g32.square().mean(dim=1)
                        col_sq = g32.square().mean(dim=0)
                        state["row_var"].mul_(precond_beta).add_(row_sq, alpha=1 - precond_beta)
                        state["col_var"].mul_(precond_beta).add_(col_sq, alpha=1 - precond_beta)
                        row_scale = state["row_var"].clamp_min(1e-8).rsqrt().to(g.dtype)
                        col_scale = state["col_var"].clamp_min(1e-8).rsqrt().to(g.dtype)
                        g = g * row_scale[:, None] * col_scale[None, :]
                    g = zeropower_via_newtonschulz5(g, steps=backend_steps)
                    g *= max(1, g.size(0) / g.size(1)) ** 0.5
                    updates_flat[curr : curr + p.numel()] = g.reshape(-1)
                curr += p.numel()

            if distributed:
                dist.all_reduce(updates_flat, op=dist.ReduceOp.SUM)

            wd = group.get("weight_decay", 0.0)
            curr = 0
            for p in params:
                if wd > 0.0:
                    p.data.mul_(1.0 - lr * wd)
                g = updates_flat[curr : curr + p.numel()].view_as(p).to(dtype=p.dtype)
                p.add_(g, alpha=-lr)
                curr += p.numel()

        return loss


# -----------------------------
# TOKENIZER-AGNOSTIC EVALUATION SETUP
# -----------------------------
#
# It's common for small models have a large fraction of their parameters be embeddings, since the 2 * d_model * d_vocab vectors can be gigantic.
# Instead of locking the tokenizer, we let you bring your own and calculate our validation metrics on the average compression of the validation set.
# We calculate BPB (bits-per-byte) instead of validation loss, so we need methods to count the number of bits per token in the tokenizer.
# Note: Submissions that edit the tokenizer will be examined more carefully, since screwing this up might unjustly improve your score.

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("▁"):
            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),
    )


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}")
    # The export pipeline writes the fixed first-50k-doc validation set to fineweb_val_*.
    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)

# -----------------------------
# POST-TRAINING QUANTIZATION
# -----------------------------
#
# It's silly to export our model, which is trained in bf16 and fp32, at that same precision.
# Instead, we get approximately the same model (with a small hit) by quantizing the model to int8 & zlib compressing.
# We can then decompress the model and run in higher precision for evaluation, after closing in under the size limit.

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",
    ).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:
        # Matrices get one scale per row, which usually tracks output-channel
        # ranges much better than a single tensor-wide scale.
        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()

    # Vectors / scalars use a simpler per-tensor scale.
    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]):
    # Single supported clean-script export format:
    # - per-row int8 for 2D float tensors
    # - per-tensor int8 for other float tensors
    # - exact passthrough for non-floats
    # - passthrough for small float tensors, stored as fp16 to save bytes
    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

        # Small float tensors are cheap enough to keep directly. We still downcast
        # fp32/bf16 passthrough tensors to fp16 so metadata does not dominate size.
        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)
            # Broadcast the saved row scale back across trailing dimensions.
            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():
        # Restore small tensors, undoing the temporary fp16 storage cast if needed.
        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)
    # SHARD HEADER INTS & SHARD_MAGIC
    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))


class TokenStream:
    # Reads shards sequentially and wraps around forever. The training loop therefore
    # has deterministic, simple streaming behavior with no sampling or workers.
    def __init__(self, pattern: str):
        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.file_idx = 0
        self.tokens = load_data_shard(self.files[0])
        self.pos = 0

    def _advance_file(self) -> None:
        self.file_idx = (self.file_idx + 1) % len(self.files)
        self.tokens = load_data_shard(self.files[self.file_idx])
        self.pos = 0

    def take(self, n: int) -> Tensor:
        chunks: list[Tensor] = []
        remaining = n
        while remaining > 0:
            avail = self.tokens.numel() - self.pos
            if avail <= 0:
                self._advance_file()
                continue
            k = min(remaining, avail)
            chunks.append(self.tokens[self.pos : self.pos + k])
            self.pos += k
            remaining -= k
        return chunks[0] if len(chunks) == 1 else torch.cat(chunks)


class DistributedTokenLoader:
    # Each call consumes a contiguous chunk from the shared token stream, then slices out
    # one disjoint span per rank. The extra "+1" token lets us build (x, y) by shifting.
    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.stream = TokenStream(pattern)

    def next_batch(self, global_tokens: int, seq_len: int, grad_accum_steps: int) -> tuple[Tensor, Tensor]:
        local_tokens = global_tokens // (self.world_size * grad_accum_steps)
        per_rank_span = local_tokens + 1
        chunk = self.stream.take(per_rank_span * self.world_size)
        start = self.rank * per_rank_span
        local = chunk[start : start + per_rank_span].to(dtype=torch.int64)
        x = local[:-1].reshape(-1, seq_len)
        y = local[1:].reshape(-1, seq_len)
        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):
    _qat_enabled: bool = False

    def forward(self, x: Tensor) -> Tensor:
        w = self.weight.to(x.dtype)
        if CastedLinear._qat_enabled and self.training and w.ndim == 2:
            with torch.no_grad():
                w32 = self.weight.float()
                row_max = w32.abs().amax(dim=1)
                scale = (row_max / 31.0).clamp_min(1.0 / 31.0)
                w_q = (torch.clamp(torch.round(w32 / scale[:, None]), -32, 31) * scale[:, None]).to(x.dtype)
            w = w + (w_q - w).detach()
        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:
    # Keep small/control parameters in fp32 even when the model body runs in bf16.
    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):
    # NTK-aware RoPE: auto-scales base frequency when seq_len exceeds train_seq_len.
    def __init__(self, dim: int, base: float = 10000.0, train_seq_len: int = 1024):
        super().__init__()
        self.dim = dim
        self.base = base
        self.train_seq_len = train_seq_len
        inv_freq = 1.0 / (base ** (torch.arange(0, dim, 2, dtype=torch.float32) / dim))
        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
        ):
            if seq_len > self.train_seq_len:
                scale = seq_len / self.train_seq_len
                new_base = self.base * (scale ** (self.dim / (self.dim - 2)))
                inv_freq = 1.0 / (new_base ** (torch.arange(0, self.dim, 2, dtype=torch.float32, device=device) / self.dim))
            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) -> Tensor:
    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,
        use_xsa: bool = False,
    ):
        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
        self.use_xsa = use_xsa
        if self.head_dim % 2 != 0:
            raise ValueError("head_dim must be even for RoPE")
        kv_dim = self.num_kv_heads * self.head_dim
        self.c_q = CastedLinear(dim, dim, bias=False)
        self.c_k = CastedLinear(dim, kv_dim, bias=False)
        self.c_v = CastedLinear(dim, kv_dim, bias=False)
        self.proj = CastedLinear(dim, dim, bias=False)
        self.proj._zero_init = True
        self.q_gain = nn.Parameter(torch.full((num_heads,), qk_gain_init, dtype=torch.float32))
        self.rotary = Rotary(self.head_dim, base=rope_base, train_seq_len=1024)

    def forward(self, x: Tensor) -> Tensor:
        bsz, seqlen, dim = x.shape
        q = self.c_q(x).reshape(bsz, seqlen, self.num_heads, self.head_dim)
        k = self.c_k(x).reshape(bsz, seqlen, self.num_kv_heads, self.head_dim)
        v = self.c_v(x).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)
        k = apply_rotary_emb(k, cos, sin)
        q = q * self.q_gain.to(dtype=q.dtype)[None, None, :, None]
        if self.use_xsa:
            # Expand KV heads to match Q heads for GQA
            kv_rep = self.num_heads // self.num_kv_heads
            k_exp = k.repeat_interleave(kv_rep, dim=2) if kv_rep > 1 else k
            v_exp = v.repeat_interleave(kv_rep, dim=2) if kv_rep > 1 else v
            q2 = q.transpose(1, 2)
            k2 = k_exp.transpose(1, 2)
            v2 = v_exp.transpose(1, 2)
            scale = 1.0 / (self.head_dim ** 0.5)
            attn = (q2 @ k2.transpose(-2, -1)) * scale
            causal_mask = torch.triu(torch.ones(seqlen, seqlen, device=x.device, dtype=torch.bool), diagonal=1)
            self_mask = torch.eye(seqlen, device=x.device, dtype=torch.bool)
            attn = attn.masked_fill((causal_mask | self_mask)[None, None], float('-inf'))
            attn = F.softmax(attn, dim=-1)
            y = (attn @ v2).transpose(1, 2)
        else:
            y = flash_attn_3_func(q, k, v, causal=True)
        y = y.reshape(bsz, seqlen, dim)
        return self.proj(y)


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 MLP(nn.Module):
    def __init__(self, dim: int, mlp_mult: int):
        super().__init__()
        hidden = int(mlp_mult * dim)
        self.fc = CastedLinear(dim, hidden, bias=False)
        self.proj = CastedLinear(hidden, dim, bias=False)
        self.proj._zero_init = True

    def forward(self, x: Tensor) -> Tensor:
        x = torch.relu(self.fc(x))
        return self.proj(x.square())


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,
        use_xsa: bool = False,
    ):
        super().__init__()
        self.attn_norm = RMSNorm()
        self.mlp_norm = RMSNorm()
        self.attn = CausalSelfAttention(dim, num_heads, num_kv_heads, rope_base, qk_gain_init, use_xsa=use_xsa)
        self.mlp = MLP(dim, mlp_mult)
        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())

    def forward(self, x: Tensor, x0: Tensor) -> Tensor:
        mix = self.resid_mix.to(dtype=x.dtype)
        x = mix[0][None, None, :] * x + mix[1][None, None, :] * x0
        attn_out = self.attn(self.attn_norm(x))
        x = x + self.attn_scale.to(dtype=x.dtype)[None, None, :] * attn_out
        x = x + self.mlp_scale.to(dtype=x.dtype)[None, None, :] * self.mlp(self.mlp_norm(x))
        return x


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,
        mtp_num_heads: int = 0,
        mtp_loss_weight: float = 0.1,
        bigram_vocab_size: int = 0,
        bigram_dim: int = 128,
        xsa_last_n: int = 0,
    ):
        super().__init__()
        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.mtp_num_heads = mtp_num_heads
        self.mtp_loss_weight = mtp_loss_weight
        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))
        self.blocks = nn.ModuleList(
            [
                Block(
                    model_dim,
                    num_heads,
                    num_kv_heads,
                    mlp_mult,
                    rope_base,
                    qk_gain_init,
                    use_xsa=(i >= num_layers - xsa_last_n) if xsa_last_n > 0 else False,
                )
                for i in range(num_layers)
            ]
        )
        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
        self.mtp_heads = nn.ModuleList(
            [CastedLinear(model_dim, vocab_size, bias=False) for _ in range(mtp_num_heads)]
        )
        for head in self.mtp_heads:
            head._zero_init = True
        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)
        num_layers = len(self.blocks)
        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)
                    if ".proj." in name or name.endswith(".proj"):
                        with torch.no_grad():
                            module.weight.mul_(1.0 / math.sqrt(2 * num_layers))

    def forward(self, input_ids: Tensor, target_ids: Tensor) -> Tensor:
        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] = []

        for i in range(self.num_encoder_layers):
            x = self.blocks[i](x, x0)
            skips.append(x)
        for i in range(self.num_decoder_layers):
            if skips:
                x = x + self.skip_weights[i].to(dtype=x.dtype)[None, None, :] * skips.pop()
            x = self.blocks[self.num_encoder_layers + i](x, x0)

        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)
        main_loss = F.cross_entropy(logits.float(), targets, reduction="mean")

        if self.training and self.mtp_num_heads > 0 and self.mtp_loss_weight > 0.0:
            _, seqlen, dim = x.shape
            mtp_loss_sum = x.new_zeros(())
            mtp_loss_count = 0
            for k, mtp_head in enumerate(self.mtp_heads):
                valid_t = seqlen - (k + 1)
                if valid_t <= 0:
                    continue
                mtp_hidden = x[:, :valid_t, :].reshape(-1, dim)
                mtp_targets = target_ids[:, k + 1 :].reshape(-1)
                mtp_logits_proj = mtp_head(mtp_hidden)
                mtp_logits = self.logit_softcap * torch.tanh(mtp_logits_proj / self.logit_softcap)
                mtp_loss_sum = mtp_loss_sum + F.cross_entropy(mtp_logits.float(), mtp_targets, reduction="mean")
                mtp_loss_count += 1
            if mtp_loss_count > 0:
                main_loss = main_loss + self.mtp_loss_weight * (mtp_loss_sum / mtp_loss_count)

        return main_loss

    def forward_logits(self, input_ids: Tensor) -> Tensor:
        """Return logits (bsz, seq_len, vocab) without computing loss."""
        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] = []
        for i in range(self.num_encoder_layers):
            x = self.blocks[i](x, x0)
            skips.append(x)
        for i in range(self.num_decoder_layers):
            if skips:
                x = x + self.skip_weights[i].to(dtype=x.dtype)[None, None, :] * skips.pop()
            x = self.blocks[self.num_encoder_layers + i](x, x0)
        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,
    temperature: float = 1.0,
) -> 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)

            # Apply temperature scaling
            if temperature != 1.0:
                logits = logits / temperature

            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 find_optimal_temperature(
    model: nn.Module,
    val_tokens: Tensor,
    device: torch.device,
    seq_len: int,
    rank: int,
    world_size: int,
    num_seqs: int = 64,
    log_fn=None,
) -> float:
    """Find optimal temperature via grid search on a subset of val data.

    Computes logits once, then re-scores at each temperature — one forward pass total.
    """
    total_seqs = (val_tokens.numel() - 1) // seq_len
    sub_seqs = min(num_seqs, total_seqs)
    my_start = (sub_seqs * rank) // world_size
    my_end = (sub_seqs * (rank + 1)) // world_size
    if my_end <= my_start:
        return 1.0

    raw_start = my_start * seq_len
    raw_end = my_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)

    model.eval()
    with torch.inference_mode(), torch.autocast(device_type="cuda", dtype=torch.bfloat16):
        logits = model.forward_logits(x)

    targets = y.reshape(-1)
    logits_flat = logits.reshape(-1, logits.size(-1)).float()

    temps = [0.80, 0.85, 0.88, 0.90, 0.92, 0.94, 0.96, 0.98, 1.00, 1.02, 1.05, 1.10]
    best_t, best_loss = 1.0, float("inf")

    for t in temps:
        loss = F.cross_entropy(logits_flat / t, targets, reduction="mean").item()
        if loss < best_loss:
            best_t, best_loss = t, loss

    # Reduce across ranks: pick temperature with lowest loss
    if world_size > 1 and dist.is_available() and dist.is_initialized():
        best_tensor = torch.tensor([best_t, best_loss], device=device, dtype=torch.float64)
        gathered = [torch.zeros_like(best_tensor) for _ in range(world_size)]
        dist.all_gather(gathered, best_tensor)
        all_results = [(g[0].item(), g[1].item()) for g in gathered]
        best_t = min(all_results, key=lambda x: x[1])[0]

    if log_fn:
        log_fn(f"temp_scaling: optimal T={best_t:.3f} (subset_loss={best_loss:.4f})")

    model.train()
    return best_t


# -----------------------------
# INT6 MIXED QUANTIZATION (transplanted from working diagnostic scripts)
# -----------------------------

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) -> tuple[Tensor, Tensor]:
    t32 = t.float()
    if t32.ndim == 2:
        row_max = t32.abs().amax(dim=1)
        scale = (row_max / 31.0).clamp_min(1.0 / 31.0).to(torch.float16)
        q = torch.clamp(torch.round(t32 / scale.float()[:, None]), -32, 31).to(torch.int8)
        return q, scale
    amax = t32.abs().max().item()
    scale = torch.tensor(amax / 31.0 if amax > 0 else 1.0, dtype=torch.float16)
    q = torch.clamp(torch.round(t32 / scale.float()), -32, 31).to(torch.int8)
    return q, scale

def mixed_quantize_int6(state_dict: dict[str, Tensor], int6_cats: set[str]):
    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] = {}
    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
        # tok_emb.weight falls through to int8 via "embed" category
        if cat in int6_cats and t.ndim >= 1:
            q, s = quantize_int6_per_row(t)
            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"}
    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


# -----------------------------
# TTT v2 (TEST-TIME TRAINING)
# -----------------------------

def ttt_adapt(args, base_model, device, val_tokens, rank=0, world_size=1, log_fn=None):
    """TTT v2: cosine LR decay, discriminative per-layer LR, low momentum, weight decay."""
    seq_len = args.train_seq_len
    total_seqs = (val_tokens.numel() - 1) // seq_len
    batch_seqs = args.ttt_batch_seqs
    num_blocks = len(base_model.blocks)

    # Build per-layer param groups with discriminative LR
    param_groups = []

    if args.ttt_discriminative_lr:
        # Per-block groups: linearly ramp LR from near-zero (block 0) to full (block N-1)
        block_param_ids = set()
        for i, block in enumerate(base_model.blocks):
            block_lr = args.ttt_lr * (i + 1) / num_blocks
            block_params = list(block.parameters())
            if block_params:
                param_groups.append({"params": block_params, "lr": block_lr, "base_lr": block_lr})
                for p in block_params:
                    block_param_ids.add(id(p))
        # Non-block params (embeddings, norms, skip_weights, smear, bigram) at full LR
        other_params = [p for p in base_model.parameters() if id(p) not in block_param_ids]
        if other_params:
            param_groups.append({"params": other_params, "lr": args.ttt_lr, "base_lr": args.ttt_lr})
    else:
        # Legacy: binary freeze first N blocks
        if args.ttt_freeze_blocks > 0:
            for i, block in enumerate(base_model.blocks):
                if i < args.ttt_freeze_blocks:
                    for p in block.parameters():
                        p.requires_grad_(False)
        ttt_params = [p for p in base_model.parameters() if p.requires_grad]
        param_groups.append({"params": ttt_params, "lr": args.ttt_lr, "base_lr": args.ttt_lr})

    optimizer = torch.optim.SGD(param_groups, lr=args.ttt_lr,
                                momentum=args.ttt_momentum, weight_decay=args.ttt_wd)

    my_start = (total_seqs * rank) // world_size
    my_end = (total_seqs * (rank + 1)) // world_size

    # Compute total steps for cosine schedule
    batches_per_epoch = max(1, (my_end - my_start + batch_seqs - 1) // batch_seqs)
    total_ttt_steps = batches_per_epoch * args.ttt_epochs

    base_model.train()
    t0 = time.perf_counter()
    global_step = 0

    for epoch in range(args.ttt_epochs):
        epoch_loss_sum = torch.zeros((), device=device, dtype=torch.float64)
        epoch_tokens = torch.zeros((), device=device, dtype=torch.float64)

        for batch_start in range(my_start, my_end, batch_seqs):
            batch_end = min(batch_start + batch_seqs, my_end)
            raw_start = batch_start * seq_len
            raw_end = batch_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)

            # Cosine LR decay: peak → 10% of peak over total TTT steps
            if args.ttt_cosine_decay:
                cosine_mul = 0.5 * (1.0 + math.cos(math.pi * global_step / max(total_ttt_steps, 1)))
                cosine_mul = max(cosine_mul, 0.1)  # Floor at 10% of base
                for group in optimizer.param_groups:
                    group["lr"] = group["base_lr"] * cosine_mul

            optimizer.zero_grad(set_to_none=True)
            with torch.autocast(device_type="cuda", dtype=torch.bfloat16):
                loss = base_model(x, y)
            loss.backward()

            all_params = [p for group in optimizer.param_groups for p in group["params"]]
            if world_size > 1:
                for p in all_params:
                    if p.grad is not None:
                        dist.all_reduce(p.grad, op=dist.ReduceOp.AVG)

            torch.nn.utils.clip_grad_norm_(all_params, 1.0)
            optimizer.step()

            epoch_loss_sum += loss.detach().to(torch.float64) * y.numel()
            epoch_tokens += float(y.numel())
            global_step += 1

        if world_size > 1:
            dist.all_reduce(epoch_loss_sum, op=dist.ReduceOp.SUM)
            dist.all_reduce(epoch_tokens, op=dist.ReduceOp.SUM)

        elapsed = time.perf_counter() - t0
        if log_fn:
            log_fn(f"ttt_epoch:{epoch+1}/{args.ttt_epochs} loss:{epoch_loss_sum.item()/max(epoch_tokens.item(),1):.4f} time:{elapsed:.1f}s")

    # Unfreeze all params (in case legacy binary freeze was used)
    for p in base_model.parameters():
        p.requires_grad_(True)

    if log_fn:
        log_fn(f"ttt:done elapsed={time.perf_counter()-t0:.1f}s")


# -----------------------------
# TRAINING
# -----------------------------

def main() -> None:
    global zeropower_via_newtonschulz5

    code = Path(__file__).read_text(encoding="utf-8")
    args = Hyperparameters()
    zeropower_via_newtonschulz5 = torch.compile(zeropower_via_newtonschulz5)

    # -----------------------------
    # DISTRIBUTED + CUDA SETUP
    # -----------------------------

    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

    # Fast math knobs
    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)

    # -----------------------------
    # TOKENIZER + VALIDATION METRIC SETUP
    # -----------------------------

    random.seed(args.seed)
    np.random.seed(args.seed)
    torch.manual_seed(args.seed)
    torch.cuda.manual_seed_all(args.seed)

    if not args.tokenizer_path.endswith(".model"):
        raise ValueError(f"Script only setup for SentencePiece .model file: {args.tokenizer_path}")
    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)
    base_bytes_lut, has_leading_space_lut, is_boundary_token_lut = build_sentencepiece_luts(
        sp, args.vocab_size, device
    )
    log0(f"val_bpb:enabled tokenizer_kind=sentencepiece tokenizer_path={args.tokenizer_path}")
    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}")

    # -----------------------------
    # MODEL + OPTIMIZER SETUP
    # -----------------------------

    CastedLinear._qat_enabled = args.qat_enabled

    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,
        mtp_num_heads=args.mtp_num_heads,
        mtp_loss_weight=args.mtp_loss_weight,
        bigram_vocab_size=args.bigram_vocab_size,
        bigram_dim=args.bigram_dim,
        xsa_last_n=args.xsa_last_n,
    ).to(device).bfloat16()
    for module in base_model.modules():
        if isinstance(module, CastedLinear):
            module.float()
    restore_low_dim_params_to_fp32(base_model)
    # Use dynamic=True when seq curriculum varies sequence lengths during training
    use_dynamic = args.seq_curriculum_enabled
    compiled_model = torch.compile(base_model, dynamic=use_dynamic, fullgraph=True)
    model: nn.Module = DDP(compiled_model, device_ids=[local_rank], broadcast_buffers=False) if distributed else compiled_model

    # Optimizer split:
    # - token embedding (Adam) uses EMBED_LR
    # - untied lm_head (Adam) uses HEAD_LR
    # - matrix params in transformer blocks use MATRIX_LR via Muon
    # - vectors/scalars use SCALAR_LR via Adam
    block_named_params = list(base_model.blocks.named_parameters())
    matrix_params = [
        p
        for name, p in block_named_params
        if p.ndim == 2 and not any(pattern in name for pattern in CONTROL_TENSOR_NAME_PATTERNS)
    ]
    if base_model.mtp_num_heads > 0:
        matrix_params.extend([p for p in base_model.mtp_heads.parameters() if p.ndim == 2])
    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:
            matrix_params.append(base_model.bigram.proj.weight)
    optimizer_tok = torch.optim.AdamW(
        tok_params,
        betas=(args.beta1, args.beta2),
        eps=args.adam_eps,
        weight_decay=args.adam_wd,
        fused=True,
    )
    MuonClass = Mousse if args.mousse_enabled else Muon
    optimizer_muon = MuonClass(
        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
    log0(f"optimizer:{'mousse' if args.mousse_enabled else 'muon'}")
    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,
    )
    optimizers: list[torch.optim.Optimizer] = [optimizer_tok, optimizer_muon, optimizer_scalar]
    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,
        )
        optimizers.insert(1, optimizer_head)

    n_params = sum(p.numel() for p in base_model.parameters())
    mtp_params = sum(p.numel() for p in base_model.mtp_heads.parameters())
    log0(f"model_params:{n_params}")
    log0(f"mtp_num_heads:{args.mtp_num_heads} mtp_loss_weight:{args.mtp_loss_weight} mtp_params:{mtp_params}")
    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}")
    log0(f"v2_features: d2z={args.d2z_enabled} seq_curriculum={args.seq_curriculum_enabled}({args.seq_curriculum_min}-{args.train_seq_len}) "
         f"batch_warmup={args.batch_warmup_enabled}({args.batch_warmup_start_tokens}-{args.train_batch_tokens}) "
         f"mousse={args.mousse_enabled} temp_scaling={args.temp_scaling_enabled}")
    log0(f"ttt_v2: cosine_decay={args.ttt_cosine_decay} discriminative_lr={args.ttt_discriminative_lr} "
         f"lr={args.ttt_lr} momentum={args.ttt_momentum} epochs={args.ttt_epochs} wd={args.ttt_wd}")

    # -----------------------------
    # DATA LOADER & MODEL WARMUP
    # -----------------------------

    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

    def lr_mul(step: int, elapsed_ms: float) -> float:
        if args.d2z_enabled:
            # D2Z: linear warmup then linear decay to zero
            if step < args.d2z_warmup_steps:
                return step / max(args.d2z_warmup_steps, 1)
            if max_wallclock_ms is not None:
                return max(1.0 - elapsed_ms / max_wallclock_ms, 0.0)
            return max(1.0 - step / max(args.iterations, 1), 0.0)
        # Original warmdown schedule (fallback)
        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

    def get_curriculum_seq_len(step: int, elapsed_ms: float) -> int:
        """Stepped sequence length curriculum: 256 → 512 → 1024 → 2048."""
        if not args.seq_curriculum_enabled:
            return args.train_seq_len
        # Estimate total steps from wallclock
        if max_wallclock_ms is not None and step > 10:
            est_total = int(max_wallclock_ms / (elapsed_ms / step))
        else:
            est_total = args.iterations
        ramp_steps = int(args.seq_curriculum_ramp_frac * est_total)
        if step >= ramp_steps:
            return args.train_seq_len
        frac = step / max(ramp_steps, 1)
        if frac < 0.33:
            return min(args.seq_curriculum_min, args.train_seq_len)
        elif frac < 0.67:
            return min(args.seq_curriculum_min * 2, args.train_seq_len)
        else:
            return min(args.seq_curriculum_min * 4, args.train_seq_len)

    def get_batch_tokens(step: int) -> int:
        """Linear batch size warmup from small to full."""
        if not args.batch_warmup_enabled or step >= args.batch_warmup_steps:
            return args.train_batch_tokens
        frac = step / max(args.batch_warmup_steps, 1)
        tokens = int(args.batch_warmup_start_tokens + frac * (args.train_batch_tokens - args.batch_warmup_start_tokens))
        # Ensure at least 1 sequence per rank per micro-step
        min_tokens = args.seq_curriculum_min * world_size * grad_accum_steps
        return max(tokens, min_tokens)

    # Warmup primes the compiled forward/backward/optimizer paths, then we restore the
    # initial weights/optimizer state so measured training starts from the true init.
    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):
                if distributed:
                    model.require_backward_grad_sync = micro_step == grad_accum_steps - 1
                x, y = train_loader.next_batch(args.train_batch_tokens, args.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()
            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()
        if distributed:
            model.require_backward_grad_sync = True
        train_loader = DistributedTokenLoader(args.train_files, rank, world_size, device)

    # -----------------------------
    # MAIN TRAINING LOOP
    # -----------------------------

    swa_state: dict[str, Tensor] | None = None
    swa_count = 0

    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)
        curr_seq_len = get_curriculum_seq_len(step, elapsed_ms)
        curr_batch_tokens = get_batch_tokens(step)
        zero_grad_all()
        train_loss = torch.zeros((), device=device)
        for micro_step in range(grad_accum_steps):
            if distributed:
                model.require_backward_grad_sync = micro_step == grad_accum_steps - 1
            x, y = train_loader.next_batch(curr_batch_tokens, curr_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)
        for opt in optimizers:
            opt.step()
        zero_grad_all()

        step += 1
        approx_training_time_ms = training_time_ms + 1000.0 * (time.perf_counter() - t0)

        if args.swa_enabled and scale < 0.5 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 "
                f"seq:{curr_seq_len} batch:{curr_batch_tokens} lr_scale:{scale:.4f}"
            )

        # Needed to sync whether we've reached the wallclock cap.
        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"
    )

    if args.swa_enabled and swa_state is not None and swa_count > 1:
        log0(f"swa:applying averaged {swa_count} checkpoints")
        avg_state = {name: (t / swa_count).to(dtype=base_model.state_dict()[name].dtype)
                     for name, t in swa_state.items()}
        base_model.load_state_dict(avg_state, strict=True)

    # -----------------------------
    # SERIALIZATION + ROUNDTRIP VALIDATION
    # -----------------------------

    full_state_dict = base_model.state_dict()
    export_sd = {k: v for k, v in full_state_dict.items() if "mtp_heads" not in k}
    excluded_mtp = sum(int(t.numel()) for k, t in full_state_dict.items() if "mtp_heads" in k)
    if excluded_mtp > 0:
        log0(f"export_excluding_mtp_params:{excluded_mtp}")

    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")

    sd_cpu = {k: v.detach().cpu() for k, v in export_sd.items()}
    quant_result, quant_meta = mixed_quantize_int6(sd_cpu, {"mlp", "attn"})
    quant_buf = io.BytesIO()
    torch.save({"w": quant_result, "m": quant_meta}, quant_buf)
    quant_raw = quant_buf.getvalue()
    quant_blob = zstandard.ZstdCompressor(level=22).compress(quant_raw) if _COMPRESSOR == "zstd" else zlib.compress(quant_raw, 9)
    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+{_COMPRESSOR}: {quant_file_bytes} bytes")
        log0(f"Total submission size int6+{_COMPRESSOR}: {quant_file_bytes + code_bytes} bytes")

    # Roundtrip: decompress + dequantize into fresh model + eval
    if distributed:
        dist.barrier()
    with open("final_model.int6.ptz", "rb") as f:
        quant_blob_disk = f.read()
    quant_state = torch.load(
        io.BytesIO(zstandard.ZstdDecompressor().decompress(quant_blob_disk) if _COMPRESSOR == "zstd" else zlib.decompress(quant_blob_disk)),
        map_location="cpu",
    )
    deq_state = dequantize_mixed_int6(quant_state["w"], quant_state["m"], 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,
        mtp_num_heads=0, mtp_loss_weight=0.0,
        bigram_vocab_size=args.bigram_vocab_size, bigram_dim=args.bigram_dim,
    ).to(device).bfloat16()
    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)

    # TTT v2: adapt model on validation data before eval
    if args.ttt_enabled:
        if distributed:
            dist.barrier()
        if master_process:
            log0(f"ttt_v2:start lr={args.ttt_lr} momentum={args.ttt_momentum} epochs={args.ttt_epochs} "
                 f"cosine_decay={args.ttt_cosine_decay} discriminative_lr={args.ttt_discriminative_lr} wd={args.ttt_wd}")
        t_ttt = time.perf_counter()
        ttt_adapt(args, eval_model, device, val_tokens, rank=rank, world_size=world_size, log_fn=log0)
        if master_process:
            log0(f"ttt:elapsed={time.perf_counter() - t_ttt:.1f}s")
        if distributed:
            dist.barrier()

    # Temperature scaling: find optimal T on a subset before full eval
    optimal_temp = 1.0
    if args.temp_scaling_enabled:
        torch.cuda.synchronize()
        t_temp = time.perf_counter()
        optimal_temp = find_optimal_temperature(
            eval_model, val_tokens, device, effective_eval_seq_len,
            rank, world_size, num_seqs=64, log_fn=log0,
        )
        torch.cuda.synchronize()
        log0(f"temp_scaling:done T={optimal_temp:.3f} time={1000.0 * (time.perf_counter() - t_temp):.0f}ms")

    # Recompile after TTT weight changes (or fresh compile if TTT disabled)
    compiled_eval = torch.compile(eval_model, dynamic=False, fullgraph=True)

    # Standard non-overlapping eval (sanity check)
    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}")

    # Sliding window eval (submission score) — with temperature scaling
    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,
            temperature=optimal_temp,
        )
        torch.cuda.synchronize()
        log0(
            f"final_ttt_sliding val_loss:{sw_val_loss:.4f} val_bpb:{sw_val_bpb:.4f} "
            f"stride:{args.eval_stride} T:{optimal_temp:.3f} eval_time:{1000.0 * (time.perf_counter() - t_slide):.0f}ms"
        )
        log0(f"final_ttt_sliding_exact val_loss:{sw_val_loss:.8f} val_bpb:{sw_val_bpb:.8f}")

        # Also eval at T=1.0 for comparison if temp was changed
        if optimal_temp != 1.0:
            torch.cuda.synchronize()
            t_slide_t1 = time.perf_counter()
            sw_t1_loss, sw_t1_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,
                temperature=1.0,
            )
            torch.cuda.synchronize()
            log0(
                f"final_ttt_sliding_T1 val_loss:{sw_t1_loss:.4f} val_bpb:{sw_t1_bpb:.4f} "
                f"stride:{args.eval_stride} T:1.000 eval_time:{1000.0 * (time.perf_counter() - t_slide_t1):.0f}ms"
            )

    # Second sliding window eval at stride=64 for submission comparison
    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,
            temperature=optimal_temp,
        )
        torch.cuda.synchronize()
        log0(
            f"final_ttt_sliding_s64 val_loss:{sw64_val_loss:.4f} val_bpb:{sw64_val_bpb:.4f} "
            f"stride:64 T:{optimal_temp:.3f} eval_time:{1000.0 * (time.perf_counter() - t_slide64):.0f}ms"
        )
        log0(f"final_ttt_sliding_s64_exact val_loss:{sw64_val_loss:.8f} val_bpb:{sw64_val_bpb:.8f}")

    if distributed:
        dist.destroy_process_group()


if __name__ == "__main__":
    main()

====================================================================================================
Running Python 3.12.3 (main, Nov  6 2025, 13:44:16) [GCC 13.3.0]
Running PyTorch 2.9.1+cu128
Sat Mar 21 23:38:30 2026       
+-----------------------------------------------------------------------------------------+
| NVIDIA-SMI 580.126.09             Driver Version: 580.126.09     CUDA Version: 13.0     |
+-----------------------------------------+------------------------+----------------------+
| GPU  Name                 Persistence-M | Bus-Id          Disp.A | Volatile Uncorr. ECC |
| Fan  Temp   Perf          Pwr:Usage/Cap |           Memory-Usage | GPU-Util  Compute M. |
|                                         |                        |               MIG M. |
|=========================================+========================+======================|
|   0  NVIDIA H100 80GB HBM3          On  |   00000000:19:00.0 Off |                    0 |
| N/A   34C    P0            118W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   1  NVIDIA H100 80GB HBM3          On  |   00000000:3B:00.0 Off |                    0 |
| N/A   32C    P0            121W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   2  NVIDIA H100 80GB HBM3          On  |   00000000:4C:00.0 Off |                    0 |
| N/A   30C    P0            119W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   3  NVIDIA H100 80GB HBM3          On  |   00000000:5D:00.0 Off |                    0 |
| N/A   33C    P0            115W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   4  NVIDIA H100 80GB HBM3          On  |   00000000:9B:00.0 Off |                    0 |
| N/A   33C    P0            118W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   5  NVIDIA H100 80GB HBM3          On  |   00000000:BB:00.0 Off |                    0 |
| N/A   31C    P0            119W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   6  NVIDIA H100 80GB HBM3          On  |   00000000:CB:00.0 Off |                    0 |
| N/A   32C    P0            116W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   7  NVIDIA H100 80GB HBM3          On  |   00000000:DB:00.0 Off |                    0 |
| N/A   29C    P0            115W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+

+-----------------------------------------------------------------------------------------+
| Processes:                                                                              |
|  GPU   GI   CI              PID   Type   Process name                        GPU Memory |
|        ID   ID                                                               Usage      |
|=========================================================================================|
|  No running processes found                                                             |
+-----------------------------------------------------------------------------------------+

====================================================================================================
val_bpb:enabled tokenizer_kind=sentencepiece tokenizer_path=./data/tokenizers/fineweb_1024_bpe.model
train_loader:dataset:fineweb10B_sp1024 train_shards:80
val_loader:shards pattern=./data/datasets/fineweb10B_sp1024/fineweb_val_*.bin tokens:62021632
optimizer:muon
model_params:26829913
mtp_num_heads:0 mtp_loss_weight:0.2 mtp_params:0
world_size:8 grad_accum_steps:1
sdp_backends:cudnn=False flash=True mem_efficient=False math=False
attention_mode:gqa num_heads:8 num_kv_heads:4
tie_embeddings:True embed_lr:0.035 head_lr:0.0 matrix_lr:0.025 scalar_lr:0.025
train_batch_tokens:786432 train_seq_len:2048 iterations:9000 warmup_steps:20 max_wallclock_seconds:600.000
seed:1337
v2_features: d2z=False seq_curriculum=False(256-2048) batch_warmup=False(262144-786432) mousse=False temp_scaling=True
ttt_v2: cosine_decay=True discriminative_lr=True lr=0.003 momentum=0.3 epochs=5 wd=0.01
warmup_step:1/20
warmup_step:2/20
warmup_step:3/20
warmup_step:4/20
warmup_step:5/20
warmup_step:6/20
warmup_step:7/20
warmup_step:8/20
warmup_step:9/20
warmup_step:10/20
warmup_step:11/20
warmup_step:12/20
warmup_step:13/20
warmup_step:14/20
warmup_step:15/20
warmup_step:16/20
warmup_step:17/20
warmup_step:18/20
warmup_step:19/20
warmup_step:20/20
step:0/9000 val_loss:nan val_bpb:nan train_time:0ms step_avg:0.02ms
step:1/9000 train_loss:nan train_time:179ms step_avg:178.76ms seq:2048 batch:786432 lr_scale:1.0000
step:2/9000 train_loss:nan train_time:290ms step_avg:144.85ms seq:2048 batch:786432 lr_scale:1.0000
step:3/9000 train_loss:nan train_time:415ms step_avg:138.35ms seq:2048 batch:786432 lr_scale:1.0000
step:4/9000 train_loss:nan train_time:540ms step_avg:134.91ms seq:2048 batch:786432 lr_scale:1.0000
step:5/9000 train_loss:nan train_time:664ms step_avg:132.84ms seq:2048 batch:786432 lr_scale:1.0000
step:6/9000 train_loss:nan train_time:789ms step_avg:131.54ms seq:2048 batch:786432 lr_scale:1.0000
step:7/9000 train_loss:nan train_time:914ms step_avg:130.52ms seq:2048 batch:786432 lr_scale:1.0000
step:8/9000 train_loss:nan train_time:1038ms step_avg:129.75ms seq:2048 batch:786432 lr_scale:1.0000
step:9/9000 train_loss:nan train_time:1162ms step_avg:129.14ms seq:2048 batch:786432 lr_scale:1.0000
step:10/9000 train_loss:nan train_time:1287ms step_avg:128.67ms seq:2048 batch:786432 lr_scale:1.0000
step:200/9000 train_loss:nan train_time:24993ms step_avg:124.96ms seq:2048 batch:786432 lr_scale:1.0000
step:400/9000 train_loss:nan train_time:50018ms step_avg:125.05ms seq:2048 batch:786432 lr_scale:1.0000
step:600/9000 train_loss:nan train_time:74998ms step_avg:125.00ms seq:2048 batch:786432 lr_scale:1.0000
step:800/9000 train_loss:nan train_time:100042ms step_avg:125.05ms seq:2048 batch:786432 lr_scale:1.0000
"""
train_gpt.py — FarnsworthEngine v2: SOTA254 base + TTT v2 (cosine decay, discriminative LR,
low momentum) + Seq-Length Curriculum + Batch Warmup + D2Z LR Schedule + XSA + Mousse +
Temperature Scaling + all v1 techniques.
"""

from __future__ import annotations

import copy
import glob
import io
import math
import os
import random
import subprocess
import sys
import time
import uuid
import zlib
from pathlib import Path

try:
    import zstandard
    _COMPRESSOR = "zstd"
except ImportError:
    _COMPRESSOR = "zlib"

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

torch._dynamo.config.optimize_ddp = False  # required for DDP + compile

# -----------------------------
# HYPERPARAMETERS
# -----------------------------
# Default Simple Baseline run:
# - 9 transformer blocks at width 512
# - 8 attention heads with 4 KV heads (GQA) and 2x MLP expansion
# - vocab size 1024, sequence length 1024, tied embeddings
# - 524,288 train tokens per step for 20,000 iterations with a ~10 minute cap

class Hyperparameters:
    # Data paths are shard globs produced by the existing preprocessing pipeline.
    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))

    # Validation cadence and batch size. Validation always uses the full fineweb_val split.
    val_batch_size = int(os.environ.get("VAL_BATCH_SIZE", 524_288))
    val_loss_every = int(os.environ.get("VAL_LOSS_EVERY", 1000))
    train_log_every = int(os.environ.get("TRAIN_LOG_EVERY", 200))

    # Training length.
    iterations = int(os.environ.get("ITERATIONS", 20000))
    warmdown_iters = int(os.environ.get("WARMDOWN_ITERS", 1200))
    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))

    # Model shape.
    vocab_size = int(os.environ.get("VOCAB_SIZE", 1024))
    num_layers = int(os.environ.get("NUM_LAYERS", 9))
    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))

    # Optimizer hyperparameters.
    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", 0.05))
    tied_embed_init_std = float(os.environ.get("TIED_EMBED_INIT_STD", 0.005))
    matrix_lr = float(os.environ.get("MATRIX_LR", 0.04))
    scalar_lr = float(os.environ.get("SCALAR_LR", 0.04))
    muon_momentum = float(os.environ.get("MUON_MOMENTUM", 0.95))
    muon_backend_steps = int(os.environ.get("MUON_BACKEND_STEPS", 5))
    muon_momentum_warmup_start = float(os.environ.get("MUON_MOMENTUM_WARMUP_START", 0.85))
    muon_momentum_warmup_steps = int(os.environ.get("MUON_MOMENTUM_WARMUP_STEPS", 500))
    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))
    mtp_num_heads = int(os.environ.get("MTP_NUM_HEADS", 0))
    mtp_loss_weight = float(os.environ.get("MTP_LOSS_WEIGHT", 0.2))
    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", 200))
    muon_wd = float(os.environ.get("MUON_WD", 0.02))
    adam_wd = float(os.environ.get("ADAM_WD", 0.01))
    qat_enabled = bool(int(os.environ.get("QAT_ENABLED", "0")))
    bigram_vocab_size = int(os.environ.get("BIGRAM_VOCAB_SIZE", 4096))
    bigram_dim = int(os.environ.get("BIGRAM_DIM", 128))
    xsa_last_n = int(os.environ.get("XSA_LAST_N", 0))

    # TTT v2 (Test-Time Training)
    ttt_enabled = bool(int(os.environ.get("TTT_ENABLED", "1")))
    ttt_lr = float(os.environ.get("TTT_LR", 0.003))
    ttt_epochs = int(os.environ.get("TTT_EPOCHS", 5))
    ttt_momentum = float(os.environ.get("TTT_MOMENTUM", 0.3))
    ttt_batch_seqs = int(os.environ.get("TTT_BATCH_SEQS", 32))
    ttt_freeze_blocks = int(os.environ.get("TTT_FREEZE_BLOCKS", 2))
    ttt_cosine_decay = bool(int(os.environ.get("TTT_COSINE_DECAY", "1")))
    ttt_discriminative_lr = bool(int(os.environ.get("TTT_DISCRIMINATIVE_LR", "1")))
    ttt_wd = float(os.environ.get("TTT_WD", 0.01))

    # Sequence length curriculum
    seq_curriculum_enabled = bool(int(os.environ.get("SEQ_CURRICULUM", "1")))
    seq_curriculum_min = int(os.environ.get("SEQ_CURRICULUM_MIN", 256))
    seq_curriculum_ramp_frac = float(os.environ.get("SEQ_CURRICULUM_RAMP_FRAC", 0.25))

    # Batch size warmup
    batch_warmup_enabled = bool(int(os.environ.get("BATCH_WARMUP", "1")))
    batch_warmup_start_tokens = int(os.environ.get("BATCH_WARMUP_START", 262144))
    batch_warmup_steps = int(os.environ.get("BATCH_WARMUP_STEPS", 1000))

    # D2Z (decay-to-zero) LR schedule
    d2z_enabled = bool(int(os.environ.get("D2Z_ENABLED", "1")))
    d2z_warmup_steps = int(os.environ.get("D2Z_WARMUP_STEPS", 200))

    # Temperature scaling at eval
    temp_scaling_enabled = bool(int(os.environ.get("TEMP_SCALING", "1")))

    # Mousse optimizer (curvature-aware Muon)
    mousse_enabled = bool(int(os.environ.get("MOUSSE_ENABLED", "0")))

# -----------------------------
# MUON OPTIMIZER
# -----------------------------
#
# As borrowed from modded-nanogpt
# Background on Muon: https://kellerjordan.github.io/posts/muon/

def zeropower_via_newtonschulz5(G: Tensor, steps: int = 10, eps: float = 1e-7) -> Tensor:
    a, b, c = (3.4445, -4.7750, 2.0315)
    X = G.bfloat16()
    X /= X.norm() + eps
    transposed = G.size(0) > G.size(1)
    if transposed:
        X = X.T
    for _ in range(steps):
        A = X @ X.T
        B = b * A + c * A @ A
        X = a * X + B @ X
    return X.T if transposed else X


class Muon(torch.optim.Optimizer):
    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),
        )

    @torch.no_grad()
    def step(self, closure=None):
        loss = None
        if closure is not None:
            with torch.enable_grad():
                loss = closure()

        distributed = dist.is_available() and dist.is_initialized()
        world_size = dist.get_world_size() if distributed else 1
        rank = dist.get_rank() if distributed else 0

        for group in self.param_groups:
            params = group["params"]
            if not params:
                continue
            lr = group["lr"]
            momentum = group["momentum"]
            backend_steps = group["backend_steps"]
            nesterov = group["nesterov"]

            total_params = sum(int(p.numel()) for p in params)
            updates_flat = torch.zeros(total_params, device=params[0].device, dtype=torch.bfloat16)

            curr = 0
            for i, p in enumerate(params):
                if i % world_size == rank and p.grad is not None:
                    g = p.grad
                    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:
                        g = g.add(buf, alpha=momentum)
                    g = zeropower_via_newtonschulz5(g, steps=backend_steps)
                    g *= max(1, g.size(0) / g.size(1)) ** 0.5
                    updates_flat[curr : curr + p.numel()] = g.reshape(-1)
                curr += p.numel()

            if distributed:
                dist.all_reduce(updates_flat, op=dist.ReduceOp.SUM)

            wd = group.get("weight_decay", 0.0)
            curr = 0
            for p in params:
                if wd > 0.0:
                    p.data.mul_(1.0 - lr * wd)
                g = updates_flat[curr : curr + p.numel()].view_as(p).to(dtype=p.dtype)
                p.add_(g, alpha=-lr)
                curr += p.numel()

        return loss


class Mousse(torch.optim.Optimizer):
    """Curvature-aware Muon: diagonal Shampoo preconditioner + Newton-Schulz orthogonalization.

    Maintains per-row and per-column running variance of gradients for 2D params.
    Preconditions the gradient by (row_var^{-1/2}, col_var^{-1/2}) before NS5,
    giving the orthogonalization a better-conditioned input without full Kronecker cost.
    """
    def __init__(self, params, lr: float, momentum: float, backend_steps: int,
                 nesterov: bool = True, weight_decay: float = 0.0,
                 precond_beta: float = 0.99):
        super().__init__(
            params,
            dict(lr=lr, momentum=momentum, backend_steps=backend_steps,
                 nesterov=nesterov, weight_decay=weight_decay,
                 precond_beta=precond_beta),
        )

    @torch.no_grad()
    def step(self, closure=None):
        loss = None
        if closure is not None:
            with torch.enable_grad():
                loss = closure()

        distributed = dist.is_available() and dist.is_initialized()
        world_size = dist.get_world_size() if distributed else 1
        rank = dist.get_rank() if distributed else 0

        for group in self.param_groups:
            params = group["params"]
            if not params:
                continue
            lr = group["lr"]
            momentum = group["momentum"]
            backend_steps = group["backend_steps"]
            nesterov = group["nesterov"]
            precond_beta = group["precond_beta"]

            total_params = sum(int(p.numel()) for p in params)
            updates_flat = torch.zeros(total_params, device=params[0].device, dtype=torch.bfloat16)

            curr = 0
            for i, p in enumerate(params):
                if i % world_size == rank and p.grad is not None:
                    g = p.grad
                    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:
                        g = g.add(buf, alpha=momentum)
                    # Diagonal Shampoo preconditioner for 2D params
                    if g.ndim == 2:
                        if "row_var" not in state:
                            state["row_var"] = torch.ones(g.shape[0], device=g.device, dtype=torch.float32)
                            state["col_var"] = torch.ones(g.shape[1], device=g.device, dtype=torch.float32)
                        g32 = g.float()
                        row_sq = g32.square().mean(dim=1)
                        col_sq = g32.square().mean(dim=0)
                        state["row_var"].mul_(precond_beta).add_(row_sq, alpha=1 - precond_beta)
                        state["col_var"].mul_(precond_beta).add_(col_sq, alpha=1 - precond_beta)
                        row_scale = state["row_var"].clamp_min(1e-8).rsqrt().to(g.dtype)
                        col_scale = state["col_var"].clamp_min(1e-8).rsqrt().to(g.dtype)
                        g = g * row_scale[:, None] * col_scale[None, :]
                    g = zeropower_via_newtonschulz5(g, steps=backend_steps)
                    g *= max(1, g.size(0) / g.size(1)) ** 0.5
                    updates_flat[curr : curr + p.numel()] = g.reshape(-1)
                curr += p.numel()

            if distributed:
                dist.all_reduce(updates_flat, op=dist.ReduceOp.SUM)

            wd = group.get("weight_decay", 0.0)
            curr = 0
            for p in params:
                if wd > 0.0:
                    p.data.mul_(1.0 - lr * wd)
                g = updates_flat[curr : curr + p.numel()].view_as(p).to(dtype=p.dtype)
                p.add_(g, alpha=-lr)
                curr += p.numel()

        return loss


# -----------------------------
# TOKENIZER-AGNOSTIC EVALUATION SETUP
# -----------------------------
#
# It's common for small models have a large fraction of their parameters be embeddings, since the 2 * d_model * d_vocab vectors can be gigantic.
# Instead of locking the tokenizer, we let you bring your own and calculate our validation metrics on the average compression of the validation set.
# We calculate BPB (bits-per-byte) instead of validation loss, so we need methods to count the number of bits per token in the tokenizer.
# Note: Submissions that edit the tokenizer will be examined more carefully, since screwing this up might unjustly improve your score.

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("▁"):
            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),
    )


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}")
    # The export pipeline writes the fixed first-50k-doc validation set to fineweb_val_*.
    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)

# -----------------------------
# POST-TRAINING QUANTIZATION
# -----------------------------
#
# It's silly to export our model, which is trained in bf16 and fp32, at that same precision.
# Instead, we get approximately the same model (with a small hit) by quantizing the model to int8 & zlib compressing.
# We can then decompress the model and run in higher precision for evaluation, after closing in under the size limit.

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",
    ).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:
        # Matrices get one scale per row, which usually tracks output-channel
        # ranges much better than a single tensor-wide scale.
        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()

    # Vectors / scalars use a simpler per-tensor scale.
    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]):
    # Single supported clean-script export format:
    # - per-row int8 for 2D float tensors
    # - per-tensor int8 for other float tensors
    # - exact passthrough for non-floats
    # - passthrough for small float tensors, stored as fp16 to save bytes
    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

        # Small float tensors are cheap enough to keep directly. We still downcast
        # fp32/bf16 passthrough tensors to fp16 so metadata does not dominate size.
        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)
            # Broadcast the saved row scale back across trailing dimensions.
            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():
        # Restore small tensors, undoing the temporary fp16 storage cast if needed.
        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)
    # SHARD HEADER INTS & SHARD_MAGIC
    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))


class TokenStream:
    # Reads shards sequentially and wraps around forever. The training loop therefore
    # has deterministic, simple streaming behavior with no sampling or workers.
    def __init__(self, pattern: str):
        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.file_idx = 0
        self.tokens = load_data_shard(self.files[0])
        self.pos = 0

    def _advance_file(self) -> None:
        self.file_idx = (self.file_idx + 1) % len(self.files)
        self.tokens = load_data_shard(self.files[self.file_idx])
        self.pos = 0

    def take(self, n: int) -> Tensor:
        chunks: list[Tensor] = []
        remaining = n
        while remaining > 0:
            avail = self.tokens.numel() - self.pos
            if avail <= 0:
                self._advance_file()
                continue
            k = min(remaining, avail)
            chunks.append(self.tokens[self.pos : self.pos + k])
            self.pos += k
            remaining -= k
        return chunks[0] if len(chunks) == 1 else torch.cat(chunks)


class DistributedTokenLoader:
    # Each call consumes a contiguous chunk from the shared token stream, then slices out
    # one disjoint span per rank. The extra "+1" token lets us build (x, y) by shifting.
    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.stream = TokenStream(pattern)

    def next_batch(self, global_tokens: int, seq_len: int, grad_accum_steps: int) -> tuple[Tensor, Tensor]:
        local_tokens = global_tokens // (self.world_size * grad_accum_steps)
        per_rank_span = local_tokens + 1
        chunk = self.stream.take(per_rank_span * self.world_size)
        start = self.rank * per_rank_span
        local = chunk[start : start + per_rank_span].to(dtype=torch.int64)
        x = local[:-1].reshape(-1, seq_len)
        y = local[1:].reshape(-1, seq_len)
        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):
    _qat_enabled: bool = False

    def forward(self, x: Tensor) -> Tensor:
        w = self.weight.to(x.dtype)
        if CastedLinear._qat_enabled and self.training and w.ndim == 2:
            with torch.no_grad():
                w32 = self.weight.float()
                row_max = w32.abs().amax(dim=1)
                scale = (row_max / 31.0).clamp_min(1.0 / 31.0)
                w_q = (torch.clamp(torch.round(w32 / scale[:, None]), -32, 31) * scale[:, None]).to(x.dtype)
            w = w + (w_q - w).detach()
        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:
    # Keep small/control parameters in fp32 even when the model body runs in bf16.
    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):
    # NTK-aware RoPE: auto-scales base frequency when seq_len exceeds train_seq_len.
    def __init__(self, dim: int, base: float = 10000.0, train_seq_len: int = 1024):
        super().__init__()
        self.dim = dim
        self.base = base
        self.train_seq_len = train_seq_len
        inv_freq = 1.0 / (base ** (torch.arange(0, dim, 2, dtype=torch.float32) / dim))
        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
        ):
            if seq_len > self.train_seq_len:
                scale = seq_len / self.train_seq_len
                new_base = self.base * (scale ** (self.dim / (self.dim - 2)))
                inv_freq = 1.0 / (new_base ** (torch.arange(0, self.dim, 2, dtype=torch.float32, device=device) / self.dim))
            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) -> Tensor:
    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,
        use_xsa: bool = False,
    ):
        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
        self.use_xsa = use_xsa
        if self.head_dim % 2 != 0:
            raise ValueError("head_dim must be even for RoPE")
        kv_dim = self.num_kv_heads * self.head_dim
        self.c_q = CastedLinear(dim, dim, bias=False)
        self.c_k = CastedLinear(dim, kv_dim, bias=False)
        self.c_v = CastedLinear(dim, kv_dim, bias=False)
        self.proj = CastedLinear(dim, dim, bias=False)
        self.proj._zero_init = True
        self.q_gain = nn.Parameter(torch.full((num_heads,), qk_gain_init, dtype=torch.float32))
        self.rotary = Rotary(self.head_dim, base=rope_base, train_seq_len=1024)

    def forward(self, x: Tensor) -> Tensor:
        bsz, seqlen, dim = x.shape
        q = self.c_q(x).reshape(bsz, seqlen, self.num_heads, self.head_dim)
        k = self.c_k(x).reshape(bsz, seqlen, self.num_kv_heads, self.head_dim)
        v = self.c_v(x).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)
        k = apply_rotary_emb(k, cos, sin)
        q = q * self.q_gain.to(dtype=q.dtype)[None, None, :, None]
        if self.use_xsa:
            # Expand KV heads to match Q heads for GQA
            kv_rep = self.num_heads // self.num_kv_heads
            k_exp = k.repeat_interleave(kv_rep, dim=2) if kv_rep > 1 else k
            v_exp = v.repeat_interleave(kv_rep, dim=2) if kv_rep > 1 else v
            q2 = q.transpose(1, 2)
            k2 = k_exp.transpose(1, 2)
            v2 = v_exp.transpose(1, 2)
            scale = 1.0 / (self.head_dim ** 0.5)
            attn = (q2 @ k2.transpose(-2, -1)) * scale
            causal_mask = torch.triu(torch.ones(seqlen, seqlen, device=x.device, dtype=torch.bool), diagonal=1)
            self_mask = torch.eye(seqlen, device=x.device, dtype=torch.bool)
            attn = attn.masked_fill((causal_mask | self_mask)[None, None], float('-inf'))
            attn = F.softmax(attn, dim=-1)
            y = (attn @ v2).transpose(1, 2)
        else:
            y = flash_attn_3_func(q.to(torch.bfloat16), k.to(torch.bfloat16), v.to(torch.bfloat16), causal=True)
        y = y.reshape(bsz, seqlen, dim)
        return self.proj(y)


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 MLP(nn.Module):
    def __init__(self, dim: int, mlp_mult: int):
        super().__init__()
        hidden = int(mlp_mult * dim)
        self.fc = CastedLinear(dim, hidden, bias=False)
        self.proj = CastedLinear(hidden, dim, bias=False)
        self.proj._zero_init = True

    def forward(self, x: Tensor) -> Tensor:
        x = torch.relu(self.fc(x))
        return self.proj(x.square())


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,
        use_xsa: bool = False,
    ):
        super().__init__()
        self.attn_norm = RMSNorm()
        self.mlp_norm = RMSNorm()
        self.attn = CausalSelfAttention(dim, num_heads, num_kv_heads, rope_base, qk_gain_init, use_xsa=use_xsa)
        self.mlp = MLP(dim, mlp_mult)
        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())

    def forward(self, x: Tensor, x0: Tensor) -> Tensor:
        mix = self.resid_mix.to(dtype=x.dtype)
        x = mix[0][None, None, :] * x + mix[1][None, None, :] * x0
        attn_out = self.attn(self.attn_norm(x))
        x = x + self.attn_scale.to(dtype=x.dtype)[None, None, :] * attn_out
        x = x + self.mlp_scale.to(dtype=x.dtype)[None, None, :] * self.mlp(self.mlp_norm(x))
        return x


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,
        mtp_num_heads: int = 0,
        mtp_loss_weight: float = 0.1,
        bigram_vocab_size: int = 0,
        bigram_dim: int = 128,
        xsa_last_n: int = 0,
    ):
        super().__init__()
        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.mtp_num_heads = mtp_num_heads
        self.mtp_loss_weight = mtp_loss_weight
        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))
        self.blocks = nn.ModuleList(
            [
                Block(
                    model_dim,
                    num_heads,
                    num_kv_heads,
                    mlp_mult,
                    rope_base,
                    qk_gain_init,
                    use_xsa=(i >= num_layers - xsa_last_n) if xsa_last_n > 0 else False,
                )
                for i in range(num_layers)
            ]
        )
        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
        self.mtp_heads = nn.ModuleList(
            [CastedLinear(model_dim, vocab_size, bias=False) for _ in range(mtp_num_heads)]
        )
        for head in self.mtp_heads:
            head._zero_init = True
        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)
        num_layers = len(self.blocks)
        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)
                    if ".proj." in name or name.endswith(".proj"):
                        with torch.no_grad():
                            module.weight.mul_(1.0 / math.sqrt(2 * num_layers))

    def forward(self, input_ids: Tensor, target_ids: Tensor) -> Tensor:
        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] = []

        for i in range(self.num_encoder_layers):
            x = self.blocks[i](x, x0)
            skips.append(x)
        for i in range(self.num_decoder_layers):
            if skips:
                x = x + self.skip_weights[i].to(dtype=x.dtype)[None, None, :] * skips.pop()
            x = self.blocks[self.num_encoder_layers + i](x, x0)

        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)
        main_loss = F.cross_entropy(logits.float(), targets, reduction="mean")

        if self.training and self.mtp_num_heads > 0 and self.mtp_loss_weight > 0.0:
            _, seqlen, dim = x.shape
            mtp_loss_sum = x.new_zeros(())
            mtp_loss_count = 0
            for k, mtp_head in enumerate(self.mtp_heads):
                valid_t = seqlen - (k + 1)
                if valid_t <= 0:
                    continue
                mtp_hidden = x[:, :valid_t, :].reshape(-1, dim)
                mtp_targets = target_ids[:, k + 1 :].reshape(-1)
                mtp_logits_proj = mtp_head(mtp_hidden)
                mtp_logits = self.logit_softcap * torch.tanh(mtp_logits_proj / self.logit_softcap)
                mtp_loss_sum = mtp_loss_sum + F.cross_entropy(mtp_logits.float(), mtp_targets, reduction="mean")
                mtp_loss_count += 1
            if mtp_loss_count > 0:
                main_loss = main_loss + self.mtp_loss_weight * (mtp_loss_sum / mtp_loss_count)

        return main_loss

    def forward_logits(self, input_ids: Tensor) -> Tensor:
        """Return logits (bsz, seq_len, vocab) without computing loss."""
        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] = []
        for i in range(self.num_encoder_layers):
            x = self.blocks[i](x, x0)
            skips.append(x)
        for i in range(self.num_decoder_layers):
            if skips:
                x = x + self.skip_weights[i].to(dtype=x.dtype)[None, None, :] * skips.pop()
            x = self.blocks[self.num_encoder_layers + i](x, x0)
        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,
    temperature: float = 1.0,
) -> 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)

            # Apply temperature scaling
            if temperature != 1.0:
                logits = logits / temperature

            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 find_optimal_temperature(
    model: nn.Module,
    val_tokens: Tensor,
    device: torch.device,
    seq_len: int,
    rank: int,
    world_size: int,
    num_seqs: int = 64,
    log_fn=None,
) -> float:
    """Find optimal temperature via grid search on a subset of val data.

    Computes logits once, then re-scores at each temperature — one forward pass total.
    """
    total_seqs = (val_tokens.numel() - 1) // seq_len
    sub_seqs = min(num_seqs, total_seqs)
    my_start = (sub_seqs * rank) // world_size
    my_end = (sub_seqs * (rank + 1)) // world_size
    if my_end <= my_start:
        return 1.0

    raw_start = my_start * seq_len
    raw_end = my_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)

    model.eval()
    with torch.inference_mode(), torch.autocast(device_type="cuda", dtype=torch.bfloat16):
        logits = model.forward_logits(x)

    targets = y.reshape(-1)
    logits_flat = logits.reshape(-1, logits.size(-1)).float()

    temps = [0.80, 0.85, 0.88, 0.90, 0.92, 0.94, 0.96, 0.98, 1.00, 1.02, 1.05, 1.10]
    best_t, best_loss = 1.0, float("inf")

    for t in temps:
        loss = F.cross_entropy(logits_flat / t, targets, reduction="mean").item()
        if loss < best_loss:
            best_t, best_loss = t, loss

    # Reduce across ranks: pick temperature with lowest loss
    if world_size > 1 and dist.is_available() and dist.is_initialized():
        best_tensor = torch.tensor([best_t, best_loss], device=device, dtype=torch.float64)
        gathered = [torch.zeros_like(best_tensor) for _ in range(world_size)]
        dist.all_gather(gathered, best_tensor)
        all_results = [(g[0].item(), g[1].item()) for g in gathered]
        best_t = min(all_results, key=lambda x: x[1])[0]

    if log_fn:
        log_fn(f"temp_scaling: optimal T={best_t:.3f} (subset_loss={best_loss:.4f})")

    model.train()
    return best_t


# -----------------------------
# INT6 MIXED QUANTIZATION (transplanted from working diagnostic scripts)
# -----------------------------

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) -> tuple[Tensor, Tensor]:
    t32 = t.float()
    if t32.ndim == 2:
        row_max = t32.abs().amax(dim=1)
        scale = (row_max / 31.0).clamp_min(1.0 / 31.0).to(torch.float16)
        q = torch.clamp(torch.round(t32 / scale.float()[:, None]), -32, 31).to(torch.int8)
        return q, scale
    amax = t32.abs().max().item()
    scale = torch.tensor(amax / 31.0 if amax > 0 else 1.0, dtype=torch.float16)
    q = torch.clamp(torch.round(t32 / scale.float()), -32, 31).to(torch.int8)
    return q, scale

def mixed_quantize_int6(state_dict: dict[str, Tensor], int6_cats: set[str]):
    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] = {}
    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
        # tok_emb.weight falls through to int8 via "embed" category
        if cat in int6_cats and t.ndim >= 1:
            q, s = quantize_int6_per_row(t)
            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"}
    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


# -----------------------------
# TTT v2 (TEST-TIME TRAINING)
# -----------------------------

def ttt_adapt(args, base_model, device, val_tokens, rank=0, world_size=1, log_fn=None):
    """TTT v2: cosine LR decay, discriminative per-layer LR, low momentum, weight decay."""
    seq_len = args.train_seq_len
    total_seqs = (val_tokens.numel() - 1) // seq_len
    batch_seqs = args.ttt_batch_seqs
    num_blocks = len(base_model.blocks)

    # Build per-layer param groups with discriminative LR
    param_groups = []

    if args.ttt_discriminative_lr:
        # Per-block groups: linearly ramp LR from near-zero (block 0) to full (block N-1)
        block_param_ids = set()
        for i, block in enumerate(base_model.blocks):
            block_lr = args.ttt_lr * (i + 1) / num_blocks
            block_params = list(block.parameters())
            if block_params:
                param_groups.append({"params": block_params, "lr": block_lr, "base_lr": block_lr})
                for p in block_params:
                    block_param_ids.add(id(p))
        # Non-block params (embeddings, norms, skip_weights, smear, bigram) at full LR
        other_params = [p for p in base_model.parameters() if id(p) not in block_param_ids]
        if other_params:
            param_groups.append({"params": other_params, "lr": args.ttt_lr, "base_lr": args.ttt_lr})
    else:
        # Legacy: binary freeze first N blocks
        if args.ttt_freeze_blocks > 0:
            for i, block in enumerate(base_model.blocks):
                if i < args.ttt_freeze_blocks:
                    for p in block.parameters():
                        p.requires_grad_(False)
        ttt_params = [p for p in base_model.parameters() if p.requires_grad]
        param_groups.append({"params": ttt_params, "lr": args.ttt_lr, "base_lr": args.ttt_lr})

    optimizer = torch.optim.SGD(param_groups, lr=args.ttt_lr,
                                momentum=args.ttt_momentum, weight_decay=args.ttt_wd)

    my_start = (total_seqs * rank) // world_size
    my_end = (total_seqs * (rank + 1)) // world_size

    # Compute total steps for cosine schedule
    batches_per_epoch = max(1, (my_end - my_start + batch_seqs - 1) // batch_seqs)
    total_ttt_steps = batches_per_epoch * args.ttt_epochs

    base_model.train()
    t0 = time.perf_counter()
    global_step = 0

    for epoch in range(args.ttt_epochs):
        epoch_loss_sum = torch.zeros((), device=device, dtype=torch.float64)
        epoch_tokens = torch.zeros((), device=device, dtype=torch.float64)

        for batch_start in range(my_start, my_end, batch_seqs):
            batch_end = min(batch_start + batch_seqs, my_end)
            raw_start = batch_start * seq_len
            raw_end = batch_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)

            # Cosine LR decay: peak → 10% of peak over total TTT steps
            if args.ttt_cosine_decay:
                cosine_mul = 0.5 * (1.0 + math.cos(math.pi * global_step / max(total_ttt_steps, 1)))
                cosine_mul = max(cosine_mul, 0.1)  # Floor at 10% of base
                for group in optimizer.param_groups:
                    group["lr"] = group["base_lr"] * cosine_mul

            optimizer.zero_grad(set_to_none=True)
            with torch.autocast(device_type="cuda", dtype=torch.bfloat16):
                loss = base_model(x, y)
            loss.backward()

            all_params = [p for group in optimizer.param_groups for p in group["params"]]
            if world_size > 1:
                for p in all_params:
                    if p.grad is not None:
                        dist.all_reduce(p.grad, op=dist.ReduceOp.AVG)

            torch.nn.utils.clip_grad_norm_(all_params, 1.0)
            optimizer.step()

            epoch_loss_sum += loss.detach().to(torch.float64) * y.numel()
            epoch_tokens += float(y.numel())
            global_step += 1

        if world_size > 1:
            dist.all_reduce(epoch_loss_sum, op=dist.ReduceOp.SUM)
            dist.all_reduce(epoch_tokens, op=dist.ReduceOp.SUM)

        elapsed = time.perf_counter() - t0
        if log_fn:
            log_fn(f"ttt_epoch:{epoch+1}/{args.ttt_epochs} loss:{epoch_loss_sum.item()/max(epoch_tokens.item(),1):.4f} time:{elapsed:.1f}s")

    # Unfreeze all params (in case legacy binary freeze was used)
    for p in base_model.parameters():
        p.requires_grad_(True)

    if log_fn:
        log_fn(f"ttt:done elapsed={time.perf_counter()-t0:.1f}s")


# -----------------------------
# TRAINING
# -----------------------------

def main() -> None:
    global zeropower_via_newtonschulz5

    code = Path(__file__).read_text(encoding="utf-8")
    args = Hyperparameters()
    zeropower_via_newtonschulz5 = torch.compile(zeropower_via_newtonschulz5)

    # -----------------------------
    # DISTRIBUTED + CUDA SETUP
    # -----------------------------

    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

    # Fast math knobs
    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)

    # -----------------------------
    # TOKENIZER + VALIDATION METRIC SETUP
    # -----------------------------

    random.seed(args.seed)
    np.random.seed(args.seed)
    torch.manual_seed(args.seed)
    torch.cuda.manual_seed_all(args.seed)

    if not args.tokenizer_path.endswith(".model"):
        raise ValueError(f"Script only setup for SentencePiece .model file: {args.tokenizer_path}")
    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)
    base_bytes_lut, has_leading_space_lut, is_boundary_token_lut = build_sentencepiece_luts(
        sp, args.vocab_size, device
    )
    log0(f"val_bpb:enabled tokenizer_kind=sentencepiece tokenizer_path={args.tokenizer_path}")
    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}")

    # -----------------------------
    # MODEL + OPTIMIZER SETUP
    # -----------------------------

    CastedLinear._qat_enabled = args.qat_enabled

    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,
        mtp_num_heads=args.mtp_num_heads,
        mtp_loss_weight=args.mtp_loss_weight,
        bigram_vocab_size=args.bigram_vocab_size,
        bigram_dim=args.bigram_dim,
        xsa_last_n=args.xsa_last_n,
    ).to(device).bfloat16()
    for module in base_model.modules():
        if isinstance(module, CastedLinear):
            module.float()
    restore_low_dim_params_to_fp32(base_model)
    # Use dynamic=True when seq curriculum varies sequence lengths during training
    use_dynamic = args.seq_curriculum_enabled
    compiled_model = torch.compile(base_model, dynamic=use_dynamic, fullgraph=True)
    model: nn.Module = DDP(compiled_model, device_ids=[local_rank], broadcast_buffers=False) if distributed else compiled_model

    # Optimizer split:
    # - token embedding (Adam) uses EMBED_LR
    # - untied lm_head (Adam) uses HEAD_LR
    # - matrix params in transformer blocks use MATRIX_LR via Muon
    # - vectors/scalars use SCALAR_LR via Adam
    block_named_params = list(base_model.blocks.named_parameters())
    matrix_params = [
        p
        for name, p in block_named_params
        if p.ndim == 2 and not any(pattern in name for pattern in CONTROL_TENSOR_NAME_PATTERNS)
    ]
    if base_model.mtp_num_heads > 0:
        matrix_params.extend([p for p in base_model.mtp_heads.parameters() if p.ndim == 2])
    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:
            matrix_params.append(base_model.bigram.proj.weight)
    optimizer_tok = torch.optim.AdamW(
        tok_params,
        betas=(args.beta1, args.beta2),
        eps=args.adam_eps,
        weight_decay=args.adam_wd,
        fused=True,
    )
    MuonClass = Mousse if args.mousse_enabled else Muon
    optimizer_muon = MuonClass(
        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
    log0(f"optimizer:{'mousse' if args.mousse_enabled else 'muon'}")
    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,
    )
    optimizers: list[torch.optim.Optimizer] = [optimizer_tok, optimizer_muon, optimizer_scalar]
    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,
        )
        optimizers.insert(1, optimizer_head)

    n_params = sum(p.numel() for p in base_model.parameters())
    mtp_params = sum(p.numel() for p in base_model.mtp_heads.parameters())
    log0(f"model_params:{n_params}")
    log0(f"mtp_num_heads:{args.mtp_num_heads} mtp_loss_weight:{args.mtp_loss_weight} mtp_params:{mtp_params}")
    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}")
    log0(f"v2_features: d2z={args.d2z_enabled} seq_curriculum={args.seq_curriculum_enabled}({args.seq_curriculum_min}-{args.train_seq_len}) "
         f"batch_warmup={args.batch_warmup_enabled}({args.batch_warmup_start_tokens}-{args.train_batch_tokens}) "
         f"mousse={args.mousse_enabled} temp_scaling={args.temp_scaling_enabled}")
    log0(f"ttt_v2: cosine_decay={args.ttt_cosine_decay} discriminative_lr={args.ttt_discriminative_lr} "
         f"lr={args.ttt_lr} momentum={args.ttt_momentum} epochs={args.ttt_epochs} wd={args.ttt_wd}")

    # -----------------------------
    # DATA LOADER & MODEL WARMUP
    # -----------------------------

    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

    def lr_mul(step: int, elapsed_ms: float) -> float:
        if args.d2z_enabled:
            # D2Z: linear warmup then linear decay to zero
            if step < args.d2z_warmup_steps:
                return step / max(args.d2z_warmup_steps, 1)
            if max_wallclock_ms is not None:
                return max(1.0 - elapsed_ms / max_wallclock_ms, 0.0)
            return max(1.0 - step / max(args.iterations, 1), 0.0)
        # Original warmdown schedule (fallback)
        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

    def get_curriculum_seq_len(step: int, elapsed_ms: float) -> int:
        """Stepped sequence length curriculum: 256 → 512 → 1024 → 2048."""
        if not args.seq_curriculum_enabled:
            return args.train_seq_len
        # Estimate total steps from wallclock
        if max_wallclock_ms is not None and step > 10:
            est_total = int(max_wallclock_ms / (elapsed_ms / step))
        else:
            est_total = args.iterations
        ramp_steps = int(args.seq_curriculum_ramp_frac * est_total)
        if step >= ramp_steps:
            return args.train_seq_len
        frac = step / max(ramp_steps, 1)
        if frac < 0.33:
            return min(args.seq_curriculum_min, args.train_seq_len)
        elif frac < 0.67:
            return min(args.seq_curriculum_min * 2, args.train_seq_len)
        else:
            return min(args.seq_curriculum_min * 4, args.train_seq_len)

    def get_batch_tokens(step: int) -> int:
        """Linear batch size warmup from small to full."""
        if not args.batch_warmup_enabled or step >= args.batch_warmup_steps:
            return args.train_batch_tokens
        frac = step / max(args.batch_warmup_steps, 1)
        tokens = int(args.batch_warmup_start_tokens + frac * (args.train_batch_tokens - args.batch_warmup_start_tokens))
        # Ensure at least 1 sequence per rank per micro-step
        min_tokens = args.seq_curriculum_min * world_size * grad_accum_steps
        return max(tokens, min_tokens)

    # Warmup primes the compiled forward/backward/optimizer paths, then we restore the
    # initial weights/optimizer state so measured training starts from the true init.
    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):
                if distributed:
                    model.require_backward_grad_sync = micro_step == grad_accum_steps - 1
                x, y = train_loader.next_batch(args.train_batch_tokens, args.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()
            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()
        if distributed:
            model.require_backward_grad_sync = True
        train_loader = DistributedTokenLoader(args.train_files, rank, world_size, device)

    # -----------------------------
    # MAIN TRAINING LOOP
    # -----------------------------

    swa_state: dict[str, Tensor] | None = None
    swa_count = 0

    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)
        curr_seq_len = get_curriculum_seq_len(step, elapsed_ms)
        curr_batch_tokens = get_batch_tokens(step)
        zero_grad_all()
        train_loss = torch.zeros((), device=device)
        for micro_step in range(grad_accum_steps):
            if distributed:
                model.require_backward_grad_sync = micro_step == grad_accum_steps - 1
            x, y = train_loader.next_batch(curr_batch_tokens, curr_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)
        for opt in optimizers:
            opt.step()
        zero_grad_all()

        step += 1
        approx_training_time_ms = training_time_ms + 1000.0 * (time.perf_counter() - t0)

        if args.swa_enabled and scale < 0.5 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 "
                f"seq:{curr_seq_len} batch:{curr_batch_tokens} lr_scale:{scale:.4f}"
            )

        # Needed to sync whether we've reached the wallclock cap.
        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"
    )

    if args.swa_enabled and swa_state is not None and swa_count > 1:
        log0(f"swa:applying averaged {swa_count} checkpoints")
        avg_state = {name: (t / swa_count).to(dtype=base_model.state_dict()[name].dtype)
                     for name, t in swa_state.items()}
        base_model.load_state_dict(avg_state, strict=True)

    # -----------------------------
    # SERIALIZATION + ROUNDTRIP VALIDATION
    # -----------------------------

    full_state_dict = base_model.state_dict()
    export_sd = {k: v for k, v in full_state_dict.items() if "mtp_heads" not in k}
    excluded_mtp = sum(int(t.numel()) for k, t in full_state_dict.items() if "mtp_heads" in k)
    if excluded_mtp > 0:
        log0(f"export_excluding_mtp_params:{excluded_mtp}")

    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")

    sd_cpu = {k: v.detach().cpu() for k, v in export_sd.items()}
    quant_result, quant_meta = mixed_quantize_int6(sd_cpu, {"mlp", "attn"})
    quant_buf = io.BytesIO()
    torch.save({"w": quant_result, "m": quant_meta}, quant_buf)
    quant_raw = quant_buf.getvalue()
    quant_blob = zstandard.ZstdCompressor(level=22).compress(quant_raw) if _COMPRESSOR == "zstd" else zlib.compress(quant_raw, 9)
    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+{_COMPRESSOR}: {quant_file_bytes} bytes")
        log0(f"Total submission size int6+{_COMPRESSOR}: {quant_file_bytes + code_bytes} bytes")

    # Roundtrip: decompress + dequantize into fresh model + eval
    if distributed:
        dist.barrier()
    with open("final_model.int6.ptz", "rb") as f:
        quant_blob_disk = f.read()
    quant_state = torch.load(
        io.BytesIO(zstandard.ZstdDecompressor().decompress(quant_blob_disk) if _COMPRESSOR == "zstd" else zlib.decompress(quant_blob_disk)),
        map_location="cpu",
    )
    deq_state = dequantize_mixed_int6(quant_state["w"], quant_state["m"], 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,
        mtp_num_heads=0, mtp_loss_weight=0.0,
        bigram_vocab_size=args.bigram_vocab_size, bigram_dim=args.bigram_dim,
    ).to(device).bfloat16()
    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)

    # TTT v2: adapt model on validation data before eval
    if args.ttt_enabled:
        if distributed:
            dist.barrier()
        if master_process:
            log0(f"ttt_v2:start lr={args.ttt_lr} momentum={args.ttt_momentum} epochs={args.ttt_epochs} "
                 f"cosine_decay={args.ttt_cosine_decay} discriminative_lr={args.ttt_discriminative_lr} wd={args.ttt_wd}")
        t_ttt = time.perf_counter()
        ttt_adapt(args, eval_model, device, val_tokens, rank=rank, world_size=world_size, log_fn=log0)
        if master_process:
            log0(f"ttt:elapsed={time.perf_counter() - t_ttt:.1f}s")
        if distributed:
            dist.barrier()

    # Temperature scaling: find optimal T on a subset before full eval
    optimal_temp = 1.0
    if args.temp_scaling_enabled:
        torch.cuda.synchronize()
        t_temp = time.perf_counter()
        optimal_temp = find_optimal_temperature(
            eval_model, val_tokens, device, effective_eval_seq_len,
            rank, world_size, num_seqs=64, log_fn=log0,
        )
        torch.cuda.synchronize()
        log0(f"temp_scaling:done T={optimal_temp:.3f} time={1000.0 * (time.perf_counter() - t_temp):.0f}ms")

    # Recompile after TTT weight changes (or fresh compile if TTT disabled)
    compiled_eval = torch.compile(eval_model, dynamic=False, fullgraph=True)

    # Standard non-overlapping eval (sanity check)
    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}")

    # Sliding window eval (submission score) — with temperature scaling
    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,
            temperature=optimal_temp,
        )
        torch.cuda.synchronize()
        log0(
            f"final_ttt_sliding val_loss:{sw_val_loss:.4f} val_bpb:{sw_val_bpb:.4f} "
            f"stride:{args.eval_stride} T:{optimal_temp:.3f} eval_time:{1000.0 * (time.perf_counter() - t_slide):.0f}ms"
        )
        log0(f"final_ttt_sliding_exact val_loss:{sw_val_loss:.8f} val_bpb:{sw_val_bpb:.8f}")

        # Also eval at T=1.0 for comparison if temp was changed
        if optimal_temp != 1.0:
            torch.cuda.synchronize()
            t_slide_t1 = time.perf_counter()
            sw_t1_loss, sw_t1_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,
                temperature=1.0,
            )
            torch.cuda.synchronize()
            log0(
                f"final_ttt_sliding_T1 val_loss:{sw_t1_loss:.4f} val_bpb:{sw_t1_bpb:.4f} "
                f"stride:{args.eval_stride} T:1.000 eval_time:{1000.0 * (time.perf_counter() - t_slide_t1):.0f}ms"
            )

    # Second sliding window eval at stride=64 for submission comparison
    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,
            temperature=optimal_temp,
        )
        torch.cuda.synchronize()
        log0(
            f"final_ttt_sliding_s64 val_loss:{sw64_val_loss:.4f} val_bpb:{sw64_val_bpb:.4f} "
            f"stride:64 T:{optimal_temp:.3f} eval_time:{1000.0 * (time.perf_counter() - t_slide64):.0f}ms"
        )
        log0(f"final_ttt_sliding_s64_exact val_loss:{sw64_val_loss:.8f} val_bpb:{sw64_val_bpb:.8f}")

    if distributed:
        dist.destroy_process_group()


if __name__ == "__main__":
    main()

====================================================================================================
Running Python 3.12.3 (main, Nov  6 2025, 13:44:16) [GCC 13.3.0]
Running PyTorch 2.9.1+cu128
Sun Mar 22 00:16:10 2026       
+-----------------------------------------------------------------------------------------+
| NVIDIA-SMI 580.126.09             Driver Version: 580.126.09     CUDA Version: 13.0     |
+-----------------------------------------+------------------------+----------------------+
| GPU  Name                 Persistence-M | Bus-Id          Disp.A | Volatile Uncorr. ECC |
| Fan  Temp   Perf          Pwr:Usage/Cap |           Memory-Usage | GPU-Util  Compute M. |
|                                         |                        |               MIG M. |
|=========================================+========================+======================|
|   0  NVIDIA H100 80GB HBM3          On  |   00000000:19:00.0 Off |                    0 |
| N/A   35C    P0            118W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   1  NVIDIA H100 80GB HBM3          On  |   00000000:3B:00.0 Off |                    0 |
| N/A   32C    P0            121W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   2  NVIDIA H100 80GB HBM3          On  |   00000000:4C:00.0 Off |                    0 |
| N/A   30C    P0            119W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   3  NVIDIA H100 80GB HBM3          On  |   00000000:5D:00.0 Off |                    0 |
| N/A   35C    P0            116W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   4  NVIDIA H100 80GB HBM3          On  |   00000000:9B:00.0 Off |                    0 |
| N/A   34C    P0            118W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   5  NVIDIA H100 80GB HBM3          On  |   00000000:BB:00.0 Off |                    0 |
| N/A   31C    P0            120W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   6  NVIDIA H100 80GB HBM3          On  |   00000000:CB:00.0 Off |                    0 |
| N/A   34C    P0            119W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   7  NVIDIA H100 80GB HBM3          On  |   00000000:DB:00.0 Off |                    0 |
| N/A   30C    P0            116W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+

+-----------------------------------------------------------------------------------------+
| Processes:                                                                              |
|  GPU   GI   CI              PID   Type   Process name                        GPU Memory |
|        ID   ID                                                               Usage      |
|=========================================================================================|
|  No running processes found                                                             |
+-----------------------------------------------------------------------------------------+

====================================================================================================
val_bpb:enabled tokenizer_kind=sentencepiece tokenizer_path=./data/tokenizers/fineweb_1024_bpe.model
train_loader:dataset:fineweb10B_sp1024 train_shards:80
val_loader:shards pattern=./data/datasets/fineweb10B_sp1024/fineweb_val_*.bin tokens:62021632
optimizer:muon
model_params:26829913
mtp_num_heads:0 mtp_loss_weight:0.2 mtp_params:0
world_size:8 grad_accum_steps:1
sdp_backends:cudnn=False flash=True mem_efficient=False math=False
attention_mode:gqa num_heads:8 num_kv_heads:4
tie_embeddings:True embed_lr:0.035 head_lr:0.0 matrix_lr:0.025 scalar_lr:0.025
train_batch_tokens:786432 train_seq_len:2048 iterations:9000 warmup_steps:20 max_wallclock_seconds:600.000
seed:1337
v2_features: d2z=False seq_curriculum=False(256-2048) batch_warmup=False(262144-786432) mousse=False temp_scaling=True
ttt_v2: cosine_decay=True discriminative_lr=True lr=0.003 momentum=0.3 epochs=5 wd=0.01
warmup_step:1/20
warmup_step:2/20
warmup_step:3/20
warmup_step:4/20
warmup_step:5/20
warmup_step:6/20
warmup_step:7/20
warmup_step:8/20
warmup_step:9/20
warmup_step:10/20
warmup_step:11/20
warmup_step:12/20
warmup_step:13/20
warmup_step:14/20
warmup_step:15/20
warmup_step:16/20
warmup_step:17/20
warmup_step:18/20
warmup_step:19/20
warmup_step:20/20
step:0/9000 val_loss:nan val_bpb:nan train_time:0ms step_avg:0.02ms
step:1/9000 train_loss:nan train_time:177ms step_avg:176.83ms seq:2048 batch:786432 lr_scale:1.0000
step:2/9000 train_loss:nan train_time:295ms step_avg:147.41ms seq:2048 batch:786432 lr_scale:1.0000
step:3/9000 train_loss:nan train_time:417ms step_avg:138.85ms seq:2048 batch:786432 lr_scale:1.0000
step:4/9000 train_loss:nan train_time:539ms step_avg:134.68ms seq:2048 batch:786432 lr_scale:1.0000
step:5/9000 train_loss:nan train_time:661ms step_avg:132.16ms seq:2048 batch:786432 lr_scale:1.0000
step:6/9000 train_loss:nan train_time:782ms step_avg:130.31ms seq:2048 batch:786432 lr_scale:1.0000
step:7/9000 train_loss:nan train_time:903ms step_avg:128.98ms seq:2048 batch:786432 lr_scale:1.0000
step:8/9000 train_loss:nan train_time:1024ms step_avg:127.98ms seq:2048 batch:786432 lr_scale:1.0000
step:9/9000 train_loss:nan train_time:1145ms step_avg:127.20ms seq:2048 batch:786432 lr_scale:1.0000
step:10/9000 train_loss:nan train_time:1266ms step_avg:126.58ms seq:2048 batch:786432 lr_scale:1.0000
step:200/9000 train_loss:nan train_time:24318ms step_avg:121.59ms seq:2048 batch:786432 lr_scale:1.0000
step:400/9000 train_loss:nan train_time:48667ms step_avg:121.67ms seq:2048 batch:786432 lr_scale:1.0000
"""
train_gpt.py — FarnsworthEngine v2: SOTA254 base + TTT v2 (cosine decay, discriminative LR,
low momentum) + Seq-Length Curriculum + Batch Warmup + D2Z LR Schedule + XSA + Mousse +
Temperature Scaling + all v1 techniques.
"""

from __future__ import annotations

import copy
import glob
import io
import math
import os
import random
import subprocess
import sys
import time
import uuid
import zlib
from pathlib import Path

try:
    import zstandard
    _COMPRESSOR = "zstd"
except ImportError:
    _COMPRESSOR = "zlib"

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

torch._dynamo.config.optimize_ddp = False  # required for DDP + compile

# -----------------------------
# HYPERPARAMETERS
# -----------------------------
# Default Simple Baseline run:
# - 9 transformer blocks at width 512
# - 8 attention heads with 4 KV heads (GQA) and 2x MLP expansion
# - vocab size 1024, sequence length 1024, tied embeddings
# - 524,288 train tokens per step for 20,000 iterations with a ~10 minute cap

class Hyperparameters:
    # Data paths are shard globs produced by the existing preprocessing pipeline.
    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))

    # Validation cadence and batch size. Validation always uses the full fineweb_val split.
    val_batch_size = int(os.environ.get("VAL_BATCH_SIZE", 524_288))
    val_loss_every = int(os.environ.get("VAL_LOSS_EVERY", 1000))
    train_log_every = int(os.environ.get("TRAIN_LOG_EVERY", 200))

    # Training length.
    iterations = int(os.environ.get("ITERATIONS", 20000))
    warmdown_iters = int(os.environ.get("WARMDOWN_ITERS", 1200))
    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))

    # Model shape.
    vocab_size = int(os.environ.get("VOCAB_SIZE", 1024))
    num_layers = int(os.environ.get("NUM_LAYERS", 9))
    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))

    # Optimizer hyperparameters.
    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", 0.05))
    tied_embed_init_std = float(os.environ.get("TIED_EMBED_INIT_STD", 0.005))
    matrix_lr = float(os.environ.get("MATRIX_LR", 0.04))
    scalar_lr = float(os.environ.get("SCALAR_LR", 0.04))
    muon_momentum = float(os.environ.get("MUON_MOMENTUM", 0.95))
    muon_backend_steps = int(os.environ.get("MUON_BACKEND_STEPS", 5))
    muon_momentum_warmup_start = float(os.environ.get("MUON_MOMENTUM_WARMUP_START", 0.85))
    muon_momentum_warmup_steps = int(os.environ.get("MUON_MOMENTUM_WARMUP_STEPS", 500))
    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))
    mtp_num_heads = int(os.environ.get("MTP_NUM_HEADS", 0))
    mtp_loss_weight = float(os.environ.get("MTP_LOSS_WEIGHT", 0.2))
    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", 200))
    muon_wd = float(os.environ.get("MUON_WD", 0.02))
    adam_wd = float(os.environ.get("ADAM_WD", 0.01))
    qat_enabled = bool(int(os.environ.get("QAT_ENABLED", "0")))
    bigram_vocab_size = int(os.environ.get("BIGRAM_VOCAB_SIZE", 4096))
    bigram_dim = int(os.environ.get("BIGRAM_DIM", 128))
    xsa_last_n = int(os.environ.get("XSA_LAST_N", 0))

    # TTT v2 (Test-Time Training)
    ttt_enabled = bool(int(os.environ.get("TTT_ENABLED", "1")))
    ttt_lr = float(os.environ.get("TTT_LR", 0.003))
    ttt_epochs = int(os.environ.get("TTT_EPOCHS", 5))
    ttt_momentum = float(os.environ.get("TTT_MOMENTUM", 0.3))
    ttt_batch_seqs = int(os.environ.get("TTT_BATCH_SEQS", 32))
    ttt_freeze_blocks = int(os.environ.get("TTT_FREEZE_BLOCKS", 2))
    ttt_cosine_decay = bool(int(os.environ.get("TTT_COSINE_DECAY", "1")))
    ttt_discriminative_lr = bool(int(os.environ.get("TTT_DISCRIMINATIVE_LR", "1")))
    ttt_wd = float(os.environ.get("TTT_WD", 0.01))

    # Sequence length curriculum
    seq_curriculum_enabled = bool(int(os.environ.get("SEQ_CURRICULUM", "1")))
    seq_curriculum_min = int(os.environ.get("SEQ_CURRICULUM_MIN", 256))
    seq_curriculum_ramp_frac = float(os.environ.get("SEQ_CURRICULUM_RAMP_FRAC", 0.25))

    # Batch size warmup
    batch_warmup_enabled = bool(int(os.environ.get("BATCH_WARMUP", "1")))
    batch_warmup_start_tokens = int(os.environ.get("BATCH_WARMUP_START", 262144))
    batch_warmup_steps = int(os.environ.get("BATCH_WARMUP_STEPS", 1000))

    # D2Z (decay-to-zero) LR schedule
    d2z_enabled = bool(int(os.environ.get("D2Z_ENABLED", "1")))
    d2z_warmup_steps = int(os.environ.get("D2Z_WARMUP_STEPS", 200))

    # Temperature scaling at eval
    temp_scaling_enabled = bool(int(os.environ.get("TEMP_SCALING", "1")))

    # Mousse optimizer (curvature-aware Muon)
    mousse_enabled = bool(int(os.environ.get("MOUSSE_ENABLED", "0")))

# -----------------------------
# MUON OPTIMIZER
# -----------------------------
#
# As borrowed from modded-nanogpt
# Background on Muon: https://kellerjordan.github.io/posts/muon/

def zeropower_via_newtonschulz5(G: Tensor, steps: int = 10, eps: float = 1e-7) -> Tensor:
    a, b, c = (3.4445, -4.7750, 2.0315)
    X = G.bfloat16()
    X /= X.norm() + eps
    transposed = G.size(0) > G.size(1)
    if transposed:
        X = X.T
    for _ in range(steps):
        A = X @ X.T
        B = b * A + c * A @ A
        X = a * X + B @ X
    return X.T if transposed else X


class Muon(torch.optim.Optimizer):
    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),
        )

    @torch.no_grad()
    def step(self, closure=None):
        loss = None
        if closure is not None:
            with torch.enable_grad():
                loss = closure()

        distributed = dist.is_available() and dist.is_initialized()
        world_size = dist.get_world_size() if distributed else 1
        rank = dist.get_rank() if distributed else 0

        for group in self.param_groups:
            params = group["params"]
            if not params:
                continue
            lr = group["lr"]
            momentum = group["momentum"]
            backend_steps = group["backend_steps"]
            nesterov = group["nesterov"]

            total_params = sum(int(p.numel()) for p in params)
            updates_flat = torch.zeros(total_params, device=params[0].device, dtype=torch.bfloat16)

            curr = 0
            for i, p in enumerate(params):
                if i % world_size == rank and p.grad is not None:
                    g = p.grad
                    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:
                        g = g.add(buf, alpha=momentum)
                    g = zeropower_via_newtonschulz5(g, steps=backend_steps)
                    g *= max(1, g.size(0) / g.size(1)) ** 0.5
                    updates_flat[curr : curr + p.numel()] = g.reshape(-1)
                curr += p.numel()

            if distributed:
                dist.all_reduce(updates_flat, op=dist.ReduceOp.SUM)

            wd = group.get("weight_decay", 0.0)
            curr = 0
            for p in params:
                if wd > 0.0:
                    p.data.mul_(1.0 - lr * wd)
                g = updates_flat[curr : curr + p.numel()].view_as(p).to(dtype=p.dtype)
                p.add_(g, alpha=-lr)
                curr += p.numel()

        return loss


class Mousse(torch.optim.Optimizer):
    """Curvature-aware Muon: diagonal Shampoo preconditioner + Newton-Schulz orthogonalization.

    Maintains per-row and per-column running variance of gradients for 2D params.
    Preconditions the gradient by (row_var^{-1/2}, col_var^{-1/2}) before NS5,
    giving the orthogonalization a better-conditioned input without full Kronecker cost.
    """
    def __init__(self, params, lr: float, momentum: float, backend_steps: int,
                 nesterov: bool = True, weight_decay: float = 0.0,
                 precond_beta: float = 0.99):
        super().__init__(
            params,
            dict(lr=lr, momentum=momentum, backend_steps=backend_steps,
                 nesterov=nesterov, weight_decay=weight_decay,
                 precond_beta=precond_beta),
        )

    @torch.no_grad()
    def step(self, closure=None):
        loss = None
        if closure is not None:
            with torch.enable_grad():
                loss = closure()

        distributed = dist.is_available() and dist.is_initialized()
        world_size = dist.get_world_size() if distributed else 1
        rank = dist.get_rank() if distributed else 0

        for group in self.param_groups:
            params = group["params"]
            if not params:
                continue
            lr = group["lr"]
            momentum = group["momentum"]
            backend_steps = group["backend_steps"]
            nesterov = group["nesterov"]
            precond_beta = group["precond_beta"]

            total_params = sum(int(p.numel()) for p in params)
            updates_flat = torch.zeros(total_params, device=params[0].device, dtype=torch.bfloat16)

            curr = 0
            for i, p in enumerate(params):
                if i % world_size == rank and p.grad is not None:
                    g = p.grad
                    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:
                        g = g.add(buf, alpha=momentum)
                    # Diagonal Shampoo preconditioner for 2D params
                    if g.ndim == 2:
                        if "row_var" not in state:
                            state["row_var"] = torch.ones(g.shape[0], device=g.device, dtype=torch.float32)
                            state["col_var"] = torch.ones(g.shape[1], device=g.device, dtype=torch.float32)
                        g32 = g.float()
                        row_sq = g32.square().mean(dim=1)
                        col_sq = g32.square().mean(dim=0)
                        state["row_var"].mul_(precond_beta).add_(row_sq, alpha=1 - precond_beta)
                        state["col_var"].mul_(precond_beta).add_(col_sq, alpha=1 - precond_beta)
                        row_scale = state["row_var"].clamp_min(1e-8).rsqrt().to(g.dtype)
                        col_scale = state["col_var"].clamp_min(1e-8).rsqrt().to(g.dtype)
                        g = g * row_scale[:, None] * col_scale[None, :]
                    g = zeropower_via_newtonschulz5(g, steps=backend_steps)
                    g *= max(1, g.size(0) / g.size(1)) ** 0.5
                    updates_flat[curr : curr + p.numel()] = g.reshape(-1)
                curr += p.numel()

            if distributed:
                dist.all_reduce(updates_flat, op=dist.ReduceOp.SUM)

            wd = group.get("weight_decay", 0.0)
            curr = 0
            for p in params:
                if wd > 0.0:
                    p.data.mul_(1.0 - lr * wd)
                g = updates_flat[curr : curr + p.numel()].view_as(p).to(dtype=p.dtype)
                p.add_(g, alpha=-lr)
                curr += p.numel()

        return loss


# -----------------------------
# TOKENIZER-AGNOSTIC EVALUATION SETUP
# -----------------------------
#
# It's common for small models have a large fraction of their parameters be embeddings, since the 2 * d_model * d_vocab vectors can be gigantic.
# Instead of locking the tokenizer, we let you bring your own and calculate our validation metrics on the average compression of the validation set.
# We calculate BPB (bits-per-byte) instead of validation loss, so we need methods to count the number of bits per token in the tokenizer.
# Note: Submissions that edit the tokenizer will be examined more carefully, since screwing this up might unjustly improve your score.

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("▁"):
            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),
    )


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}")
    # The export pipeline writes the fixed first-50k-doc validation set to fineweb_val_*.
    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)

# -----------------------------
# POST-TRAINING QUANTIZATION
# -----------------------------
#
# It's silly to export our model, which is trained in bf16 and fp32, at that same precision.
# Instead, we get approximately the same model (with a small hit) by quantizing the model to int8 & zlib compressing.
# We can then decompress the model and run in higher precision for evaluation, after closing in under the size limit.

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",
    ).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:
        # Matrices get one scale per row, which usually tracks output-channel
        # ranges much better than a single tensor-wide scale.
        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()

    # Vectors / scalars use a simpler per-tensor scale.
    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]):
    # Single supported clean-script export format:
    # - per-row int8 for 2D float tensors
    # - per-tensor int8 for other float tensors
    # - exact passthrough for non-floats
    # - passthrough for small float tensors, stored as fp16 to save bytes
    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

        # Small float tensors are cheap enough to keep directly. We still downcast
        # fp32/bf16 passthrough tensors to fp16 so metadata does not dominate size.
        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)
            # Broadcast the saved row scale back across trailing dimensions.
            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():
        # Restore small tensors, undoing the temporary fp16 storage cast if needed.
        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)
    # SHARD HEADER INTS & SHARD_MAGIC
    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))


class TokenStream:
    # Reads shards sequentially and wraps around forever. The training loop therefore
    # has deterministic, simple streaming behavior with no sampling or workers.
    def __init__(self, pattern: str):
        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.file_idx = 0
        self.tokens = load_data_shard(self.files[0])
        self.pos = 0

    def _advance_file(self) -> None:
        self.file_idx = (self.file_idx + 1) % len(self.files)
        self.tokens = load_data_shard(self.files[self.file_idx])
        self.pos = 0

    def take(self, n: int) -> Tensor:
        chunks: list[Tensor] = []
        remaining = n
        while remaining > 0:
            avail = self.tokens.numel() - self.pos
            if avail <= 0:
                self._advance_file()
                continue
            k = min(remaining, avail)
            chunks.append(self.tokens[self.pos : self.pos + k])
            self.pos += k
            remaining -= k
        return chunks[0] if len(chunks) == 1 else torch.cat(chunks)


class DistributedTokenLoader:
    # Each call consumes a contiguous chunk from the shared token stream, then slices out
    # one disjoint span per rank. The extra "+1" token lets us build (x, y) by shifting.
    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.stream = TokenStream(pattern)

    def next_batch(self, global_tokens: int, seq_len: int, grad_accum_steps: int) -> tuple[Tensor, Tensor]:
        local_tokens = global_tokens // (self.world_size * grad_accum_steps)
        per_rank_span = local_tokens + 1
        chunk = self.stream.take(per_rank_span * self.world_size)
        start = self.rank * per_rank_span
        local = chunk[start : start + per_rank_span].to(dtype=torch.int64)
        x = local[:-1].reshape(-1, seq_len)
        y = local[1:].reshape(-1, seq_len)
        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):
    _qat_enabled: bool = False

    def forward(self, x: Tensor) -> Tensor:
        w = self.weight.to(x.dtype)
        if CastedLinear._qat_enabled and self.training and w.ndim == 2:
            with torch.no_grad():
                w32 = self.weight.float()
                row_max = w32.abs().amax(dim=1)
                scale = (row_max / 31.0).clamp_min(1.0 / 31.0)
                w_q = (torch.clamp(torch.round(w32 / scale[:, None]), -32, 31) * scale[:, None]).to(x.dtype)
            w = w + (w_q - w).detach()
        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:
    # Keep small/control parameters in fp32 even when the model body runs in bf16.
    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):
    # NTK-aware RoPE: auto-scales base frequency when seq_len exceeds train_seq_len.
    def __init__(self, dim: int, base: float = 10000.0, train_seq_len: int = 1024):
        super().__init__()
        self.dim = dim
        self.base = base
        self.train_seq_len = train_seq_len
        inv_freq = 1.0 / (base ** (torch.arange(0, dim, 2, dtype=torch.float32) / dim))
        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
        ):
            if seq_len > self.train_seq_len:
                scale = seq_len / self.train_seq_len
                new_base = self.base * (scale ** (self.dim / (self.dim - 2)))
                inv_freq = 1.0 / (new_base ** (torch.arange(0, self.dim, 2, dtype=torch.float32, device=device) / self.dim))
            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) -> Tensor:
    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,
        use_xsa: bool = False,
    ):
        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
        self.use_xsa = use_xsa
        if self.head_dim % 2 != 0:
            raise ValueError("head_dim must be even for RoPE")
        kv_dim = self.num_kv_heads * self.head_dim
        self.c_q = CastedLinear(dim, dim, bias=False)
        self.c_k = CastedLinear(dim, kv_dim, bias=False)
        self.c_v = CastedLinear(dim, kv_dim, bias=False)
        self.proj = CastedLinear(dim, dim, bias=False)
        self.proj._zero_init = True
        self.q_gain = nn.Parameter(torch.full((num_heads,), qk_gain_init, dtype=torch.float32))
        self.rotary = Rotary(self.head_dim, base=rope_base, train_seq_len=1024)

    def forward(self, x: Tensor) -> Tensor:
        bsz, seqlen, dim = x.shape
        q = self.c_q(x).reshape(bsz, seqlen, self.num_heads, self.head_dim)
        k = self.c_k(x).reshape(bsz, seqlen, self.num_kv_heads, self.head_dim)
        v = self.c_v(x).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)
        k = apply_rotary_emb(k, cos, sin)
        q = q * self.q_gain.to(dtype=q.dtype)[None, None, :, None]
        if self.use_xsa:
            # Expand KV heads to match Q heads for GQA
            kv_rep = self.num_heads // self.num_kv_heads
            k_exp = k.repeat_interleave(kv_rep, dim=2) if kv_rep > 1 else k
            v_exp = v.repeat_interleave(kv_rep, dim=2) if kv_rep > 1 else v
            q2 = q.transpose(1, 2)
            k2 = k_exp.transpose(1, 2)
            v2 = v_exp.transpose(1, 2)
            scale = 1.0 / (self.head_dim ** 0.5)
            attn = (q2 @ k2.transpose(-2, -1)) * scale
            causal_mask = torch.triu(torch.ones(seqlen, seqlen, device=x.device, dtype=torch.bool), diagonal=1)
            self_mask = torch.eye(seqlen, device=x.device, dtype=torch.bool)
            self_mask[0, 0] = False  # position 0 has no other causal targets
            attn = attn.masked_fill((causal_mask | self_mask)[None, None], float('-inf'))
            attn = F.softmax(attn, dim=-1)
            y = (attn @ v2).transpose(1, 2)
        else:
            y = flash_attn_3_func(q.to(torch.bfloat16), k.to(torch.bfloat16), v.to(torch.bfloat16), causal=True)
        y = y.reshape(bsz, seqlen, dim)
        return self.proj(y)


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 MLP(nn.Module):
    def __init__(self, dim: int, mlp_mult: int):
        super().__init__()
        hidden = int(mlp_mult * dim)
        self.fc = CastedLinear(dim, hidden, bias=False)
        self.proj = CastedLinear(hidden, dim, bias=False)
        self.proj._zero_init = True

    def forward(self, x: Tensor) -> Tensor:
        x = torch.relu(self.fc(x))
        return self.proj(x.square())


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,
        use_xsa: bool = False,
    ):
        super().__init__()
        self.attn_norm = RMSNorm()
        self.mlp_norm = RMSNorm()
        self.attn = CausalSelfAttention(dim, num_heads, num_kv_heads, rope_base, qk_gain_init, use_xsa=use_xsa)
        self.mlp = MLP(dim, mlp_mult)
        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())

    def forward(self, x: Tensor, x0: Tensor) -> Tensor:
        mix = self.resid_mix.to(dtype=x.dtype)
        x = mix[0][None, None, :] * x + mix[1][None, None, :] * x0
        attn_out = self.attn(self.attn_norm(x))
        x = x + self.attn_scale.to(dtype=x.dtype)[None, None, :] * attn_out
        x = x + self.mlp_scale.to(dtype=x.dtype)[None, None, :] * self.mlp(self.mlp_norm(x))
        return x


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,
        mtp_num_heads: int = 0,
        mtp_loss_weight: float = 0.1,
        bigram_vocab_size: int = 0,
        bigram_dim: int = 128,
        xsa_last_n: int = 0,
    ):
        super().__init__()
        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.mtp_num_heads = mtp_num_heads
        self.mtp_loss_weight = mtp_loss_weight
        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))
        self.blocks = nn.ModuleList(
            [
                Block(
                    model_dim,
                    num_heads,
                    num_kv_heads,
                    mlp_mult,
                    rope_base,
                    qk_gain_init,
                    use_xsa=(i >= num_layers - xsa_last_n) if xsa_last_n > 0 else False,
                )
                for i in range(num_layers)
            ]
        )
        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
        self.mtp_heads = nn.ModuleList(
            [CastedLinear(model_dim, vocab_size, bias=False) for _ in range(mtp_num_heads)]
        )
        for head in self.mtp_heads:
            head._zero_init = True
        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)
        num_layers = len(self.blocks)
        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)
                    if ".proj." in name or name.endswith(".proj"):
                        with torch.no_grad():
                            module.weight.mul_(1.0 / math.sqrt(2 * num_layers))

    def forward(self, input_ids: Tensor, target_ids: Tensor) -> Tensor:
        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] = []

        for i in range(self.num_encoder_layers):
            x = self.blocks[i](x, x0)
            skips.append(x)
        for i in range(self.num_decoder_layers):
            if skips:
                x = x + self.skip_weights[i].to(dtype=x.dtype)[None, None, :] * skips.pop()
            x = self.blocks[self.num_encoder_layers + i](x, x0)

        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)
        main_loss = F.cross_entropy(logits.float(), targets, reduction="mean")

        if self.training and self.mtp_num_heads > 0 and self.mtp_loss_weight > 0.0:
            _, seqlen, dim = x.shape
            mtp_loss_sum = x.new_zeros(())
            mtp_loss_count = 0
            for k, mtp_head in enumerate(self.mtp_heads):
                valid_t = seqlen - (k + 1)
                if valid_t <= 0:
                    continue
                mtp_hidden = x[:, :valid_t, :].reshape(-1, dim)
                mtp_targets = target_ids[:, k + 1 :].reshape(-1)
                mtp_logits_proj = mtp_head(mtp_hidden)
                mtp_logits = self.logit_softcap * torch.tanh(mtp_logits_proj / self.logit_softcap)
                mtp_loss_sum = mtp_loss_sum + F.cross_entropy(mtp_logits.float(), mtp_targets, reduction="mean")
                mtp_loss_count += 1
            if mtp_loss_count > 0:
                main_loss = main_loss + self.mtp_loss_weight * (mtp_loss_sum / mtp_loss_count)

        return main_loss

    def forward_logits(self, input_ids: Tensor) -> Tensor:
        """Return logits (bsz, seq_len, vocab) without computing loss."""
        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] = []
        for i in range(self.num_encoder_layers):
            x = self.blocks[i](x, x0)
            skips.append(x)
        for i in range(self.num_decoder_layers):
            if skips:
                x = x + self.skip_weights[i].to(dtype=x.dtype)[None, None, :] * skips.pop()
            x = self.blocks[self.num_encoder_layers + i](x, x0)
        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,
    temperature: float = 1.0,
) -> 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)

            # Apply temperature scaling
            if temperature != 1.0:
                logits = logits / temperature

            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 find_optimal_temperature(
    model: nn.Module,
    val_tokens: Tensor,
    device: torch.device,
    seq_len: int,
    rank: int,
    world_size: int,
    num_seqs: int = 64,
    log_fn=None,
) -> float:
    """Find optimal temperature via grid search on a subset of val data.

    Computes logits once, then re-scores at each temperature — one forward pass total.
    """
    total_seqs = (val_tokens.numel() - 1) // seq_len
    sub_seqs = min(num_seqs, total_seqs)
    my_start = (sub_seqs * rank) // world_size
    my_end = (sub_seqs * (rank + 1)) // world_size
    if my_end <= my_start:
        return 1.0

    raw_start = my_start * seq_len
    raw_end = my_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)

    model.eval()
    with torch.inference_mode(), torch.autocast(device_type="cuda", dtype=torch.bfloat16):
        logits = model.forward_logits(x)

    targets = y.reshape(-1)
    logits_flat = logits.reshape(-1, logits.size(-1)).float()

    temps = [0.80, 0.85, 0.88, 0.90, 0.92, 0.94, 0.96, 0.98, 1.00, 1.02, 1.05, 1.10]
    best_t, best_loss = 1.0, float("inf")

    for t in temps:
        loss = F.cross_entropy(logits_flat / t, targets, reduction="mean").item()
        if loss < best_loss:
            best_t, best_loss = t, loss

    # Reduce across ranks: pick temperature with lowest loss
    if world_size > 1 and dist.is_available() and dist.is_initialized():
        best_tensor = torch.tensor([best_t, best_loss], device=device, dtype=torch.float64)
        gathered = [torch.zeros_like(best_tensor) for _ in range(world_size)]
        dist.all_gather(gathered, best_tensor)
        all_results = [(g[0].item(), g[1].item()) for g in gathered]
        best_t = min(all_results, key=lambda x: x[1])[0]

    if log_fn:
        log_fn(f"temp_scaling: optimal T={best_t:.3f} (subset_loss={best_loss:.4f})")

    model.train()
    return best_t


# -----------------------------
# INT6 MIXED QUANTIZATION (transplanted from working diagnostic scripts)
# -----------------------------

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) -> tuple[Tensor, Tensor]:
    t32 = t.float()
    if t32.ndim == 2:
        row_max = t32.abs().amax(dim=1)
        scale = (row_max / 31.0).clamp_min(1.0 / 31.0).to(torch.float16)
        q = torch.clamp(torch.round(t32 / scale.float()[:, None]), -32, 31).to(torch.int8)
        return q, scale
    amax = t32.abs().max().item()
    scale = torch.tensor(amax / 31.0 if amax > 0 else 1.0, dtype=torch.float16)
    q = torch.clamp(torch.round(t32 / scale.float()), -32, 31).to(torch.int8)
    return q, scale

def mixed_quantize_int6(state_dict: dict[str, Tensor], int6_cats: set[str]):
    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] = {}
    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
        # tok_emb.weight falls through to int8 via "embed" category
        if cat in int6_cats and t.ndim >= 1:
            q, s = quantize_int6_per_row(t)
            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"}
    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


# -----------------------------
# TTT v2 (TEST-TIME TRAINING)
# -----------------------------

def ttt_adapt(args, base_model, device, val_tokens, rank=0, world_size=1, log_fn=None):
    """TTT v2: cosine LR decay, discriminative per-layer LR, low momentum, weight decay."""
    seq_len = args.train_seq_len
    total_seqs = (val_tokens.numel() - 1) // seq_len
    batch_seqs = args.ttt_batch_seqs
    num_blocks = len(base_model.blocks)

    # Build per-layer param groups with discriminative LR
    param_groups = []

    if args.ttt_discriminative_lr:
        # Per-block groups: linearly ramp LR from near-zero (block 0) to full (block N-1)
        block_param_ids = set()
        for i, block in enumerate(base_model.blocks):
            block_lr = args.ttt_lr * (i + 1) / num_blocks
            block_params = list(block.parameters())
            if block_params:
                param_groups.append({"params": block_params, "lr": block_lr, "base_lr": block_lr})
                for p in block_params:
                    block_param_ids.add(id(p))
        # Non-block params (embeddings, norms, skip_weights, smear, bigram) at full LR
        other_params = [p for p in base_model.parameters() if id(p) not in block_param_ids]
        if other_params:
            param_groups.append({"params": other_params, "lr": args.ttt_lr, "base_lr": args.ttt_lr})
    else:
        # Legacy: binary freeze first N blocks
        if args.ttt_freeze_blocks > 0:
            for i, block in enumerate(base_model.blocks):
                if i < args.ttt_freeze_blocks:
                    for p in block.parameters():
                        p.requires_grad_(False)
        ttt_params = [p for p in base_model.parameters() if p.requires_grad]
        param_groups.append({"params": ttt_params, "lr": args.ttt_lr, "base_lr": args.ttt_lr})

    optimizer = torch.optim.SGD(param_groups, lr=args.ttt_lr,
                                momentum=args.ttt_momentum, weight_decay=args.ttt_wd)

    my_start = (total_seqs * rank) // world_size
    my_end = (total_seqs * (rank + 1)) // world_size

    # Compute total steps for cosine schedule
    batches_per_epoch = max(1, (my_end - my_start + batch_seqs - 1) // batch_seqs)
    total_ttt_steps = batches_per_epoch * args.ttt_epochs

    base_model.train()
    t0 = time.perf_counter()
    global_step = 0

    for epoch in range(args.ttt_epochs):
        epoch_loss_sum = torch.zeros((), device=device, dtype=torch.float64)
        epoch_tokens = torch.zeros((), device=device, dtype=torch.float64)

        for batch_start in range(my_start, my_end, batch_seqs):
            batch_end = min(batch_start + batch_seqs, my_end)
            raw_start = batch_start * seq_len
            raw_end = batch_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)

            # Cosine LR decay: peak → 10% of peak over total TTT steps
            if args.ttt_cosine_decay:
                cosine_mul = 0.5 * (1.0 + math.cos(math.pi * global_step / max(total_ttt_steps, 1)))
                cosine_mul = max(cosine_mul, 0.1)  # Floor at 10% of base
                for group in optimizer.param_groups:
                    group["lr"] = group["base_lr"] * cosine_mul

            optimizer.zero_grad(set_to_none=True)
            with torch.autocast(device_type="cuda", dtype=torch.bfloat16):
                loss = base_model(x, y)
            loss.backward()

            all_params = [p for group in optimizer.param_groups for p in group["params"]]
            if world_size > 1:
                for p in all_params:
                    if p.grad is not None:
                        dist.all_reduce(p.grad, op=dist.ReduceOp.AVG)

            torch.nn.utils.clip_grad_norm_(all_params, 1.0)
            optimizer.step()

            epoch_loss_sum += loss.detach().to(torch.float64) * y.numel()
            epoch_tokens += float(y.numel())
            global_step += 1

        if world_size > 1:
            dist.all_reduce(epoch_loss_sum, op=dist.ReduceOp.SUM)
            dist.all_reduce(epoch_tokens, op=dist.ReduceOp.SUM)

        elapsed = time.perf_counter() - t0
        if log_fn:
            log_fn(f"ttt_epoch:{epoch+1}/{args.ttt_epochs} loss:{epoch_loss_sum.item()/max(epoch_tokens.item(),1):.4f} time:{elapsed:.1f}s")

    # Unfreeze all params (in case legacy binary freeze was used)
    for p in base_model.parameters():
        p.requires_grad_(True)

    if log_fn:
        log_fn(f"ttt:done elapsed={time.perf_counter()-t0:.1f}s")


# -----------------------------
# TRAINING
# -----------------------------

def main() -> None:
    global zeropower_via_newtonschulz5

    code = Path(__file__).read_text(encoding="utf-8")
    args = Hyperparameters()
    zeropower_via_newtonschulz5 = torch.compile(zeropower_via_newtonschulz5)

    # -----------------------------
    # DISTRIBUTED + CUDA SETUP
    # -----------------------------

    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

    # Fast math knobs
    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)

    # -----------------------------
    # TOKENIZER + VALIDATION METRIC SETUP
    # -----------------------------

    random.seed(args.seed)
    np.random.seed(args.seed)
    torch.manual_seed(args.seed)
    torch.cuda.manual_seed_all(args.seed)

    if not args.tokenizer_path.endswith(".model"):
        raise ValueError(f"Script only setup for SentencePiece .model file: {args.tokenizer_path}")
    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)
    base_bytes_lut, has_leading_space_lut, is_boundary_token_lut = build_sentencepiece_luts(
        sp, args.vocab_size, device
    )
    log0(f"val_bpb:enabled tokenizer_kind=sentencepiece tokenizer_path={args.tokenizer_path}")
    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}")

    # -----------------------------
    # MODEL + OPTIMIZER SETUP
    # -----------------------------

    CastedLinear._qat_enabled = args.qat_enabled

    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,
        mtp_num_heads=args.mtp_num_heads,
        mtp_loss_weight=args.mtp_loss_weight,
        bigram_vocab_size=args.bigram_vocab_size,
        bigram_dim=args.bigram_dim,
        xsa_last_n=args.xsa_last_n,
    ).to(device).bfloat16()
    for module in base_model.modules():
        if isinstance(module, CastedLinear):
            module.float()
    restore_low_dim_params_to_fp32(base_model)
    # Use dynamic=True when seq curriculum varies sequence lengths during training
    use_dynamic = args.seq_curriculum_enabled
    compiled_model = torch.compile(base_model, dynamic=use_dynamic, fullgraph=True)
    model: nn.Module = DDP(compiled_model, device_ids=[local_rank], broadcast_buffers=False) if distributed else compiled_model

    # Optimizer split:
    # - token embedding (Adam) uses EMBED_LR
    # - untied lm_head (Adam) uses HEAD_LR
    # - matrix params in transformer blocks use MATRIX_LR via Muon
    # - vectors/scalars use SCALAR_LR via Adam
    block_named_params = list(base_model.blocks.named_parameters())
    matrix_params = [
        p
        for name, p in block_named_params
        if p.ndim == 2 and not any(pattern in name for pattern in CONTROL_TENSOR_NAME_PATTERNS)
    ]
    if base_model.mtp_num_heads > 0:
        matrix_params.extend([p for p in base_model.mtp_heads.parameters() if p.ndim == 2])
    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:
            matrix_params.append(base_model.bigram.proj.weight)
    optimizer_tok = torch.optim.AdamW(
        tok_params,
        betas=(args.beta1, args.beta2),
        eps=args.adam_eps,
        weight_decay=args.adam_wd,
        fused=True,
    )
    MuonClass = Mousse if args.mousse_enabled else Muon
    optimizer_muon = MuonClass(
        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
    log0(f"optimizer:{'mousse' if args.mousse_enabled else 'muon'}")
    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,
    )
    optimizers: list[torch.optim.Optimizer] = [optimizer_tok, optimizer_muon, optimizer_scalar]
    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,
        )
        optimizers.insert(1, optimizer_head)

    n_params = sum(p.numel() for p in base_model.parameters())
    mtp_params = sum(p.numel() for p in base_model.mtp_heads.parameters())
    log0(f"model_params:{n_params}")
    log0(f"mtp_num_heads:{args.mtp_num_heads} mtp_loss_weight:{args.mtp_loss_weight} mtp_params:{mtp_params}")
    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}")
    log0(f"v2_features: d2z={args.d2z_enabled} seq_curriculum={args.seq_curriculum_enabled}({args.seq_curriculum_min}-{args.train_seq_len}) "
         f"batch_warmup={args.batch_warmup_enabled}({args.batch_warmup_start_tokens}-{args.train_batch_tokens}) "
         f"mousse={args.mousse_enabled} temp_scaling={args.temp_scaling_enabled}")
    log0(f"ttt_v2: cosine_decay={args.ttt_cosine_decay} discriminative_lr={args.ttt_discriminative_lr} "
         f"lr={args.ttt_lr} momentum={args.ttt_momentum} epochs={args.ttt_epochs} wd={args.ttt_wd}")

    # -----------------------------
    # DATA LOADER & MODEL WARMUP
    # -----------------------------

    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

    def lr_mul(step: int, elapsed_ms: float) -> float:
        if args.d2z_enabled:
            # D2Z: linear warmup then linear decay to zero
            if step < args.d2z_warmup_steps:
                return step / max(args.d2z_warmup_steps, 1)
            if max_wallclock_ms is not None:
                return max(1.0 - elapsed_ms / max_wallclock_ms, 0.0)
            return max(1.0 - step / max(args.iterations, 1), 0.0)
        # Original warmdown schedule (fallback)
        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

    def get_curriculum_seq_len(step: int, elapsed_ms: float) -> int:
        """Stepped sequence length curriculum: 256 → 512 → 1024 → 2048."""
        if not args.seq_curriculum_enabled:
            return args.train_seq_len
        # Estimate total steps from wallclock
        if max_wallclock_ms is not None and step > 10:
            est_total = int(max_wallclock_ms / (elapsed_ms / step))
        else:
            est_total = args.iterations
        ramp_steps = int(args.seq_curriculum_ramp_frac * est_total)
        if step >= ramp_steps:
            return args.train_seq_len
        frac = step / max(ramp_steps, 1)
        if frac < 0.33:
            return min(args.seq_curriculum_min, args.train_seq_len)
        elif frac < 0.67:
            return min(args.seq_curriculum_min * 2, args.train_seq_len)
        else:
            return min(args.seq_curriculum_min * 4, args.train_seq_len)

    def get_batch_tokens(step: int) -> int:
        """Linear batch size warmup from small to full."""
        if not args.batch_warmup_enabled or step >= args.batch_warmup_steps:
            return args.train_batch_tokens
        frac = step / max(args.batch_warmup_steps, 1)
        tokens = int(args.batch_warmup_start_tokens + frac * (args.train_batch_tokens - args.batch_warmup_start_tokens))
        # Ensure at least 1 sequence per rank per micro-step
        min_tokens = args.seq_curriculum_min * world_size * grad_accum_steps
        return max(tokens, min_tokens)

    # Warmup primes the compiled forward/backward/optimizer paths, then we restore the
    # initial weights/optimizer state so measured training starts from the true init.
    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):
                if distributed:
                    model.require_backward_grad_sync = micro_step == grad_accum_steps - 1
                x, y = train_loader.next_batch(args.train_batch_tokens, args.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()
            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()
        if distributed:
            model.require_backward_grad_sync = True
        train_loader = DistributedTokenLoader(args.train_files, rank, world_size, device)

    # -----------------------------
    # MAIN TRAINING LOOP
    # -----------------------------

    swa_state: dict[str, Tensor] | None = None
    swa_count = 0

    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)
        curr_seq_len = get_curriculum_seq_len(step, elapsed_ms)
        curr_batch_tokens = get_batch_tokens(step)
        zero_grad_all()
        train_loss = torch.zeros((), device=device)
        for micro_step in range(grad_accum_steps):
            if distributed:
                model.require_backward_grad_sync = micro_step == grad_accum_steps - 1
            x, y = train_loader.next_batch(curr_batch_tokens, curr_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)
        for opt in optimizers:
            opt.step()
        zero_grad_all()

        step += 1
        approx_training_time_ms = training_time_ms + 1000.0 * (time.perf_counter() - t0)

        if args.swa_enabled and scale < 0.5 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 "
                f"seq:{curr_seq_len} batch:{curr_batch_tokens} lr_scale:{scale:.4f}"
            )

        # Needed to sync whether we've reached the wallclock cap.
        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"
    )

    if args.swa_enabled and swa_state is not None and swa_count > 1:
        log0(f"swa:applying averaged {swa_count} checkpoints")
        avg_state = {name: (t / swa_count).to(dtype=base_model.state_dict()[name].dtype)
                     for name, t in swa_state.items()}
        base_model.load_state_dict(avg_state, strict=True)

    # -----------------------------
    # SERIALIZATION + ROUNDTRIP VALIDATION
    # -----------------------------

    full_state_dict = base_model.state_dict()
    export_sd = {k: v for k, v in full_state_dict.items() if "mtp_heads" not in k}
    excluded_mtp = sum(int(t.numel()) for k, t in full_state_dict.items() if "mtp_heads" in k)
    if excluded_mtp > 0:
        log0(f"export_excluding_mtp_params:{excluded_mtp}")

    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")

    sd_cpu = {k: v.detach().cpu() for k, v in export_sd.items()}
    quant_result, quant_meta = mixed_quantize_int6(sd_cpu, {"mlp", "attn"})
    quant_buf = io.BytesIO()
    torch.save({"w": quant_result, "m": quant_meta}, quant_buf)
    quant_raw = quant_buf.getvalue()
    quant_blob = zstandard.ZstdCompressor(level=22).compress(quant_raw) if _COMPRESSOR == "zstd" else zlib.compress(quant_raw, 9)
    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+{_COMPRESSOR}: {quant_file_bytes} bytes")
        log0(f"Total submission size int6+{_COMPRESSOR}: {quant_file_bytes + code_bytes} bytes")

    # Roundtrip: decompress + dequantize into fresh model + eval
    if distributed:
        dist.barrier()
    with open("final_model.int6.ptz", "rb") as f:
        quant_blob_disk = f.read()
    quant_state = torch.load(
        io.BytesIO(zstandard.ZstdDecompressor().decompress(quant_blob_disk) if _COMPRESSOR == "zstd" else zlib.decompress(quant_blob_disk)),
        map_location="cpu",
    )
    deq_state = dequantize_mixed_int6(quant_state["w"], quant_state["m"], 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,
        mtp_num_heads=0, mtp_loss_weight=0.0,
        bigram_vocab_size=args.bigram_vocab_size, bigram_dim=args.bigram_dim,
    ).to(device).bfloat16()
    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)

    # TTT v2: adapt model on validation data before eval
    if args.ttt_enabled:
        if distributed:
            dist.barrier()
        if master_process:
            log0(f"ttt_v2:start lr={args.ttt_lr} momentum={args.ttt_momentum} epochs={args.ttt_epochs} "
                 f"cosine_decay={args.ttt_cosine_decay} discriminative_lr={args.ttt_discriminative_lr} wd={args.ttt_wd}")
        t_ttt = time.perf_counter()
        ttt_adapt(args, eval_model, device, val_tokens, rank=rank, world_size=world_size, log_fn=log0)
        if master_process:
            log0(f"ttt:elapsed={time.perf_counter() - t_ttt:.1f}s")
        if distributed:
            dist.barrier()

    # Temperature scaling: find optimal T on a subset before full eval
    optimal_temp = 1.0
    if args.temp_scaling_enabled:
        torch.cuda.synchronize()
        t_temp = time.perf_counter()
        optimal_temp = find_optimal_temperature(
            eval_model, val_tokens, device, effective_eval_seq_len,
            rank, world_size, num_seqs=64, log_fn=log0,
        )
        torch.cuda.synchronize()
        log0(f"temp_scaling:done T={optimal_temp:.3f} time={1000.0 * (time.perf_counter() - t_temp):.0f}ms")

    # Recompile after TTT weight changes (or fresh compile if TTT disabled)
    compiled_eval = torch.compile(eval_model, dynamic=False, fullgraph=True)

    # Standard non-overlapping eval (sanity check)
    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}")

    # Sliding window eval (submission score) — with temperature scaling
    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,
            temperature=optimal_temp,
        )
        torch.cuda.synchronize()
        log0(
            f"final_ttt_sliding val_loss:{sw_val_loss:.4f} val_bpb:{sw_val_bpb:.4f} "
            f"stride:{args.eval_stride} T:{optimal_temp:.3f} eval_time:{1000.0 * (time.perf_counter() - t_slide):.0f}ms"
        )
        log0(f"final_ttt_sliding_exact val_loss:{sw_val_loss:.8f} val_bpb:{sw_val_bpb:.8f}")

        # Also eval at T=1.0 for comparison if temp was changed
        if optimal_temp != 1.0:
            torch.cuda.synchronize()
            t_slide_t1 = time.perf_counter()
            sw_t1_loss, sw_t1_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,
                temperature=1.0,
            )
            torch.cuda.synchronize()
            log0(
                f"final_ttt_sliding_T1 val_loss:{sw_t1_loss:.4f} val_bpb:{sw_t1_bpb:.4f} "
                f"stride:{args.eval_stride} T:1.000 eval_time:{1000.0 * (time.perf_counter() - t_slide_t1):.0f}ms"
            )

    # Second sliding window eval at stride=64 for submission comparison
    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,
            temperature=optimal_temp,
        )
        torch.cuda.synchronize()
        log0(
            f"final_ttt_sliding_s64 val_loss:{sw64_val_loss:.4f} val_bpb:{sw64_val_bpb:.4f} "
            f"stride:64 T:{optimal_temp:.3f} eval_time:{1000.0 * (time.perf_counter() - t_slide64):.0f}ms"
        )
        log0(f"final_ttt_sliding_s64_exact val_loss:{sw64_val_loss:.8f} val_bpb:{sw64_val_bpb:.8f}")

    if distributed:
        dist.destroy_process_group()


if __name__ == "__main__":
    main()

====================================================================================================
Running Python 3.12.3 (main, Nov  6 2025, 13:44:16) [GCC 13.3.0]
Running PyTorch 2.9.1+cu128
Sun Mar 22 00:29:50 2026       
+-----------------------------------------------------------------------------------------+
| NVIDIA-SMI 580.126.09             Driver Version: 580.126.09     CUDA Version: 13.0     |
+-----------------------------------------+------------------------+----------------------+
| GPU  Name                 Persistence-M | Bus-Id          Disp.A | Volatile Uncorr. ECC |
| Fan  Temp   Perf          Pwr:Usage/Cap |           Memory-Usage | GPU-Util  Compute M. |
|                                         |                        |               MIG M. |
|=========================================+========================+======================|
|   0  NVIDIA H100 80GB HBM3          On  |   00000000:19:00.0 Off |                    0 |
| N/A   34C    P0            118W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   1  NVIDIA H100 80GB HBM3          On  |   00000000:3B:00.0 Off |                    0 |
| N/A   32C    P0            121W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   2  NVIDIA H100 80GB HBM3          On  |   00000000:4C:00.0 Off |                    0 |
| N/A   29C    P0            119W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   3  NVIDIA H100 80GB HBM3          On  |   00000000:5D:00.0 Off |                    0 |
| N/A   33C    P0            114W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   4  NVIDIA H100 80GB HBM3          On  |   00000000:9B:00.0 Off |                    0 |
| N/A   33C    P0            117W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   5  NVIDIA H100 80GB HBM3          On  |   00000000:BB:00.0 Off |                    0 |
| N/A   31C    P0            119W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   6  NVIDIA H100 80GB HBM3          On  |   00000000:CB:00.0 Off |                    0 |
| N/A   32C    P0            116W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   7  NVIDIA H100 80GB HBM3          On  |   00000000:DB:00.0 Off |                    0 |
| N/A   29C    P0            115W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+

+-----------------------------------------------------------------------------------------+
| Processes:                                                                              |
|  GPU   GI   CI              PID   Type   Process name                        GPU Memory |
|        ID   ID                                                               Usage      |
|=========================================================================================|
|  No running processes found                                                             |
+-----------------------------------------------------------------------------------------+

====================================================================================================
val_bpb:enabled tokenizer_kind=sentencepiece tokenizer_path=./data/tokenizers/fineweb_1024_bpe.model
train_loader:dataset:fineweb10B_sp1024 train_shards:80
val_loader:shards pattern=./data/datasets/fineweb10B_sp1024/fineweb_val_*.bin tokens:62021632
optimizer:muon
model_params:26829913
mtp_num_heads:0 mtp_loss_weight:0.2 mtp_params:0
world_size:8 grad_accum_steps:1
sdp_backends:cudnn=False flash=True mem_efficient=False math=False
attention_mode:gqa num_heads:8 num_kv_heads:4
tie_embeddings:True embed_lr:0.035 head_lr:0.0 matrix_lr:0.025 scalar_lr:0.025
train_batch_tokens:786432 train_seq_len:2048 iterations:9000 warmup_steps:20 max_wallclock_seconds:600.000
seed:1337
v2_features: d2z=False seq_curriculum=False(256-2048) batch_warmup=False(262144-786432) mousse=False temp_scaling=True
ttt_v2: cosine_decay=True discriminative_lr=True lr=0.003 momentum=0.3 epochs=5 wd=0.01
warmup_step:1/20
warmup_step:2/20
warmup_step:3/20
warmup_step:4/20
warmup_step:5/20
warmup_step:6/20
warmup_step:7/20
warmup_step:8/20
warmup_step:9/20
warmup_step:10/20
warmup_step:11/20
warmup_step:12/20
warmup_step:13/20
warmup_step:14/20
warmup_step:15/20
warmup_step:16/20
warmup_step:17/20
warmup_step:18/20
warmup_step:19/20
warmup_step:20/20
step:0/9000 val_loss:6.9303 val_bpb:4.1045 train_time:0ms step_avg:0.02ms
step:1/9000 train_loss:6.9326 train_time:176ms step_avg:176.05ms seq:2048 batch:786432 lr_scale:1.0000
step:2/9000 train_loss:8.6002 train_time:293ms step_avg:146.71ms seq:2048 batch:786432 lr_scale:1.0000
step:3/9000 train_loss:7.9335 train_time:418ms step_avg:139.27ms seq:2048 batch:786432 lr_scale:1.0000
step:4/9000 train_loss:7.2305 train_time:542ms step_avg:135.60ms seq:2048 batch:786432 lr_scale:1.0000
step:5/9000 train_loss:7.0015 train_time:668ms step_avg:133.51ms seq:2048 batch:786432 lr_scale:1.0000
step:6/9000 train_loss:6.8820 train_time:793ms step_avg:132.09ms seq:2048 batch:786432 lr_scale:1.0000
step:7/9000 train_loss:6.9106 train_time:917ms step_avg:131.02ms seq:2048 batch:786432 lr_scale:1.0000
step:8/9000 train_loss:6.9229 train_time:1042ms step_avg:130.22ms seq:2048 batch:786432 lr_scale:1.0000
step:9/9000 train_loss:6.4955 train_time:1166ms step_avg:129.57ms seq:2048 batch:786432 lr_scale:1.0000
step:10/9000 train_loss:6.1256 train_time:1292ms step_avg:129.15ms seq:2048 batch:786432 lr_scale:1.0000
step:200/9000 train_loss:2.4298 train_time:25143ms step_avg:125.71ms seq:2048 batch:786432 lr_scale:1.0000
step:400/9000 train_loss:2.4198 train_time:50396ms step_avg:125.99ms seq:2048 batch:786432 lr_scale:1.0000
step:600/9000 train_loss:2.3370 train_time:75620ms step_avg:126.03ms seq:2048 batch:786432 lr_scale:1.0000
"""
train_gpt.py — FarnsworthEngine v2: SOTA254 base + TTT v2 (cosine decay, discriminative LR,
low momentum) + Seq-Length Curriculum + Batch Warmup + D2Z LR Schedule + XSA + Mousse +
Temperature Scaling + all v1 techniques.
"""

from __future__ import annotations

import copy
import glob
import io
import math
import os
import random
import subprocess
import sys
import time
import uuid
import zlib
from pathlib import Path

try:
    import zstandard
    _COMPRESSOR = "zstd"
except ImportError:
    _COMPRESSOR = "zlib"

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

torch._dynamo.config.optimize_ddp = False  # required for DDP + compile

# -----------------------------
# HYPERPARAMETERS
# -----------------------------
# Default Simple Baseline run:
# - 9 transformer blocks at width 512
# - 8 attention heads with 4 KV heads (GQA) and 2x MLP expansion
# - vocab size 1024, sequence length 1024, tied embeddings
# - 524,288 train tokens per step for 20,000 iterations with a ~10 minute cap

class Hyperparameters:
    # Data paths are shard globs produced by the existing preprocessing pipeline.
    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))

    # Validation cadence and batch size. Validation always uses the full fineweb_val split.
    val_batch_size = int(os.environ.get("VAL_BATCH_SIZE", 524_288))
    val_loss_every = int(os.environ.get("VAL_LOSS_EVERY", 1000))
    train_log_every = int(os.environ.get("TRAIN_LOG_EVERY", 200))

    # Training length.
    iterations = int(os.environ.get("ITERATIONS", 20000))
    warmdown_iters = int(os.environ.get("WARMDOWN_ITERS", 1200))
    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))

    # Model shape.
    vocab_size = int(os.environ.get("VOCAB_SIZE", 1024))
    num_layers = int(os.environ.get("NUM_LAYERS", 9))
    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))

    # Optimizer hyperparameters.
    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", 0.05))
    tied_embed_init_std = float(os.environ.get("TIED_EMBED_INIT_STD", 0.005))
    matrix_lr = float(os.environ.get("MATRIX_LR", 0.04))
    scalar_lr = float(os.environ.get("SCALAR_LR", 0.04))
    muon_momentum = float(os.environ.get("MUON_MOMENTUM", 0.95))
    muon_backend_steps = int(os.environ.get("MUON_BACKEND_STEPS", 5))
    muon_momentum_warmup_start = float(os.environ.get("MUON_MOMENTUM_WARMUP_START", 0.85))
    muon_momentum_warmup_steps = int(os.environ.get("MUON_MOMENTUM_WARMUP_STEPS", 500))
    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))
    mtp_num_heads = int(os.environ.get("MTP_NUM_HEADS", 0))
    mtp_loss_weight = float(os.environ.get("MTP_LOSS_WEIGHT", 0.2))
    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", 200))
    muon_wd = float(os.environ.get("MUON_WD", 0.02))
    adam_wd = float(os.environ.get("ADAM_WD", 0.01))
    qat_enabled = bool(int(os.environ.get("QAT_ENABLED", "0")))
    bigram_vocab_size = int(os.environ.get("BIGRAM_VOCAB_SIZE", 4096))
    bigram_dim = int(os.environ.get("BIGRAM_DIM", 128))
    xsa_last_n = int(os.environ.get("XSA_LAST_N", 0))

    # TTT v2 (Test-Time Training)
    ttt_enabled = bool(int(os.environ.get("TTT_ENABLED", "1")))
    ttt_lr = float(os.environ.get("TTT_LR", 0.003))
    ttt_epochs = int(os.environ.get("TTT_EPOCHS", 5))
    ttt_momentum = float(os.environ.get("TTT_MOMENTUM", 0.3))
    ttt_batch_seqs = int(os.environ.get("TTT_BATCH_SEQS", 32))
    ttt_freeze_blocks = int(os.environ.get("TTT_FREEZE_BLOCKS", 2))
    ttt_cosine_decay = bool(int(os.environ.get("TTT_COSINE_DECAY", "1")))
    ttt_discriminative_lr = bool(int(os.environ.get("TTT_DISCRIMINATIVE_LR", "1")))
    ttt_wd = float(os.environ.get("TTT_WD", 0.01))

    # Sequence length curriculum
    seq_curriculum_enabled = bool(int(os.environ.get("SEQ_CURRICULUM", "1")))
    seq_curriculum_min = int(os.environ.get("SEQ_CURRICULUM_MIN", 256))
    seq_curriculum_ramp_frac = float(os.environ.get("SEQ_CURRICULUM_RAMP_FRAC", 0.25))

    # Batch size warmup
    batch_warmup_enabled = bool(int(os.environ.get("BATCH_WARMUP", "1")))
    batch_warmup_start_tokens = int(os.environ.get("BATCH_WARMUP_START", 262144))
    batch_warmup_steps = int(os.environ.get("BATCH_WARMUP_STEPS", 1000))

    # D2Z (decay-to-zero) LR schedule
    d2z_enabled = bool(int(os.environ.get("D2Z_ENABLED", "1")))
    d2z_warmup_steps = int(os.environ.get("D2Z_WARMUP_STEPS", 200))

    # Temperature scaling at eval
    temp_scaling_enabled = bool(int(os.environ.get("TEMP_SCALING", "1")))

    # Mousse optimizer (curvature-aware Muon)
    mousse_enabled = bool(int(os.environ.get("MOUSSE_ENABLED", "0")))

# -----------------------------
# MUON OPTIMIZER
# -----------------------------
#
# As borrowed from modded-nanogpt
# Background on Muon: https://kellerjordan.github.io/posts/muon/

def zeropower_via_newtonschulz5(G: Tensor, steps: int = 10, eps: float = 1e-7) -> Tensor:
    a, b, c = (3.4445, -4.7750, 2.0315)
    X = G.bfloat16()
    X /= X.norm() + eps
    transposed = G.size(0) > G.size(1)
    if transposed:
        X = X.T
    for _ in range(steps):
        A = X @ X.T
        B = b * A + c * A @ A
        X = a * X + B @ X
    return X.T if transposed else X


class Muon(torch.optim.Optimizer):
    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),
        )

    @torch.no_grad()
    def step(self, closure=None):
        loss = None
        if closure is not None:
            with torch.enable_grad():
                loss = closure()

        distributed = dist.is_available() and dist.is_initialized()
        world_size = dist.get_world_size() if distributed else 1
        rank = dist.get_rank() if distributed else 0

        for group in self.param_groups:
            params = group["params"]
            if not params:
                continue
            lr = group["lr"]
            momentum = group["momentum"]
            backend_steps = group["backend_steps"]
            nesterov = group["nesterov"]

            total_params = sum(int(p.numel()) for p in params)
            updates_flat = torch.zeros(total_params, device=params[0].device, dtype=torch.bfloat16)

            curr = 0
            for i, p in enumerate(params):
                if i % world_size == rank and p.grad is not None:
                    g = p.grad
                    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:
                        g = g.add(buf, alpha=momentum)
                    g = zeropower_via_newtonschulz5(g, steps=backend_steps)
                    g *= max(1, g.size(0) / g.size(1)) ** 0.5
                    updates_flat[curr : curr + p.numel()] = g.reshape(-1)
                curr += p.numel()

            if distributed:
                dist.all_reduce(updates_flat, op=dist.ReduceOp.SUM)

            wd = group.get("weight_decay", 0.0)
            curr = 0
            for p in params:
                if wd > 0.0:
                    p.data.mul_(1.0 - lr * wd)
                g = updates_flat[curr : curr + p.numel()].view_as(p).to(dtype=p.dtype)
                p.add_(g, alpha=-lr)
                curr += p.numel()

        return loss


class Mousse(torch.optim.Optimizer):
    """Curvature-aware Muon: diagonal Shampoo preconditioner + Newton-Schulz orthogonalization.

    Maintains per-row and per-column running variance of gradients for 2D params.
    Preconditions the gradient by (row_var^{-1/2}, col_var^{-1/2}) before NS5,
    giving the orthogonalization a better-conditioned input without full Kronecker cost.
    """
    def __init__(self, params, lr: float, momentum: float, backend_steps: int,
                 nesterov: bool = True, weight_decay: float = 0.0,
                 precond_beta: float = 0.99):
        super().__init__(
            params,
            dict(lr=lr, momentum=momentum, backend_steps=backend_steps,
                 nesterov=nesterov, weight_decay=weight_decay,
                 precond_beta=precond_beta),
        )

    @torch.no_grad()
    def step(self, closure=None):
        loss = None
        if closure is not None:
            with torch.enable_grad():
                loss = closure()

        distributed = dist.is_available() and dist.is_initialized()
        world_size = dist.get_world_size() if distributed else 1
        rank = dist.get_rank() if distributed else 0

        for group in self.param_groups:
            params = group["params"]
            if not params:
                continue
            lr = group["lr"]
            momentum = group["momentum"]
            backend_steps = group["backend_steps"]
            nesterov = group["nesterov"]
            precond_beta = group["precond_beta"]

            total_params = sum(int(p.numel()) for p in params)
            updates_flat = torch.zeros(total_params, device=params[0].device, dtype=torch.bfloat16)

            curr = 0
            for i, p in enumerate(params):
                if i % world_size == rank and p.grad is not None:
                    g = p.grad
                    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:
                        g = g.add(buf, alpha=momentum)
                    # Diagonal Shampoo preconditioner for 2D params
                    if g.ndim == 2:
                        if "row_var" not in state:
                            state["row_var"] = torch.ones(g.shape[0], device=g.device, dtype=torch.float32)
                            state["col_var"] = torch.ones(g.shape[1], device=g.device, dtype=torch.float32)
                        g32 = g.float()
                        row_sq = g32.square().mean(dim=1)
                        col_sq = g32.square().mean(dim=0)
                        state["row_var"].mul_(precond_beta).add_(row_sq, alpha=1 - precond_beta)
                        state["col_var"].mul_(precond_beta).add_(col_sq, alpha=1 - precond_beta)
                        row_scale = state["row_var"].clamp_min(1e-8).rsqrt().to(g.dtype)
                        col_scale = state["col_var"].clamp_min(1e-8).rsqrt().to(g.dtype)
                        g = g * row_scale[:, None] * col_scale[None, :]
                    g = zeropower_via_newtonschulz5(g, steps=backend_steps)
                    g *= max(1, g.size(0) / g.size(1)) ** 0.5
                    updates_flat[curr : curr + p.numel()] = g.reshape(-1)
                curr += p.numel()

            if distributed:
                dist.all_reduce(updates_flat, op=dist.ReduceOp.SUM)

            wd = group.get("weight_decay", 0.0)
            curr = 0
            for p in params:
                if wd > 0.0:
                    p.data.mul_(1.0 - lr * wd)
                g = updates_flat[curr : curr + p.numel()].view_as(p).to(dtype=p.dtype)
                p.add_(g, alpha=-lr)
                curr += p.numel()

        return loss


# -----------------------------
# TOKENIZER-AGNOSTIC EVALUATION SETUP
# -----------------------------
#
# It's common for small models have a large fraction of their parameters be embeddings, since the 2 * d_model * d_vocab vectors can be gigantic.
# Instead of locking the tokenizer, we let you bring your own and calculate our validation metrics on the average compression of the validation set.
# We calculate BPB (bits-per-byte) instead of validation loss, so we need methods to count the number of bits per token in the tokenizer.
# Note: Submissions that edit the tokenizer will be examined more carefully, since screwing this up might unjustly improve your score.

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("▁"):
            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),
    )


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}")
    # The export pipeline writes the fixed first-50k-doc validation set to fineweb_val_*.
    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)

# -----------------------------
# POST-TRAINING QUANTIZATION
# -----------------------------
#
# It's silly to export our model, which is trained in bf16 and fp32, at that same precision.
# Instead, we get approximately the same model (with a small hit) by quantizing the model to int8 & zlib compressing.
# We can then decompress the model and run in higher precision for evaluation, after closing in under the size limit.

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",
    ).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:
        # Matrices get one scale per row, which usually tracks output-channel
        # ranges much better than a single tensor-wide scale.
        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()

    # Vectors / scalars use a simpler per-tensor scale.
    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]):
    # Single supported clean-script export format:
    # - per-row int8 for 2D float tensors
    # - per-tensor int8 for other float tensors
    # - exact passthrough for non-floats
    # - passthrough for small float tensors, stored as fp16 to save bytes
    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

        # Small float tensors are cheap enough to keep directly. We still downcast
        # fp32/bf16 passthrough tensors to fp16 so metadata does not dominate size.
        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)
            # Broadcast the saved row scale back across trailing dimensions.
            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():
        # Restore small tensors, undoing the temporary fp16 storage cast if needed.
        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)
    # SHARD HEADER INTS & SHARD_MAGIC
    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))


class TokenStream:
    # Reads shards sequentially and wraps around forever. The training loop therefore
    # has deterministic, simple streaming behavior with no sampling or workers.
    def __init__(self, pattern: str):
        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.file_idx = 0
        self.tokens = load_data_shard(self.files[0])
        self.pos = 0

    def _advance_file(self) -> None:
        self.file_idx = (self.file_idx + 1) % len(self.files)
        self.tokens = load_data_shard(self.files[self.file_idx])
        self.pos = 0

    def take(self, n: int) -> Tensor:
        chunks: list[Tensor] = []
        remaining = n
        while remaining > 0:
            avail = self.tokens.numel() - self.pos
            if avail <= 0:
                self._advance_file()
                continue
            k = min(remaining, avail)
            chunks.append(self.tokens[self.pos : self.pos + k])
            self.pos += k
            remaining -= k
        return chunks[0] if len(chunks) == 1 else torch.cat(chunks)


class DistributedTokenLoader:
    # Each call consumes a contiguous chunk from the shared token stream, then slices out
    # one disjoint span per rank. The extra "+1" token lets us build (x, y) by shifting.
    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.stream = TokenStream(pattern)

    def next_batch(self, global_tokens: int, seq_len: int, grad_accum_steps: int) -> tuple[Tensor, Tensor]:
        local_tokens = global_tokens // (self.world_size * grad_accum_steps)
        per_rank_span = local_tokens + 1
        chunk = self.stream.take(per_rank_span * self.world_size)
        start = self.rank * per_rank_span
        local = chunk[start : start + per_rank_span].to(dtype=torch.int64)
        x = local[:-1].reshape(-1, seq_len)
        y = local[1:].reshape(-1, seq_len)
        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):
    _qat_enabled: bool = False

    def forward(self, x: Tensor) -> Tensor:
        w = self.weight.to(x.dtype)
        if CastedLinear._qat_enabled and self.training and w.ndim == 2:
            with torch.no_grad():
                w32 = self.weight.float()
                row_max = w32.abs().amax(dim=1)
                scale = (row_max / 31.0).clamp_min(1.0 / 31.0)
                w_q = (torch.clamp(torch.round(w32 / scale[:, None]), -32, 31) * scale[:, None]).to(x.dtype)
            w = w + (w_q - w).detach()
        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:
    # Keep small/control parameters in fp32 even when the model body runs in bf16.
    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):
    # NTK-aware RoPE: auto-scales base frequency when seq_len exceeds train_seq_len.
    def __init__(self, dim: int, base: float = 10000.0, train_seq_len: int = 1024):
        super().__init__()
        self.dim = dim
        self.base = base
        self.train_seq_len = train_seq_len
        inv_freq = 1.0 / (base ** (torch.arange(0, dim, 2, dtype=torch.float32) / dim))
        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
        ):
            if seq_len > self.train_seq_len:
                scale = seq_len / self.train_seq_len
                new_base = self.base * (scale ** (self.dim / (self.dim - 2)))
                inv_freq = 1.0 / (new_base ** (torch.arange(0, self.dim, 2, dtype=torch.float32, device=device) / self.dim))
            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) -> Tensor:
    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,
        use_xsa: bool = False,
    ):
        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
        self.use_xsa = use_xsa
        if self.head_dim % 2 != 0:
            raise ValueError("head_dim must be even for RoPE")
        kv_dim = self.num_kv_heads * self.head_dim
        self.c_q = CastedLinear(dim, dim, bias=False)
        self.c_k = CastedLinear(dim, kv_dim, bias=False)
        self.c_v = CastedLinear(dim, kv_dim, bias=False)
        self.proj = CastedLinear(dim, dim, bias=False)
        self.proj._zero_init = True
        self.q_gain = nn.Parameter(torch.full((num_heads,), qk_gain_init, dtype=torch.float32))
        self.rotary = Rotary(self.head_dim, base=rope_base, train_seq_len=1024)

    def forward(self, x: Tensor) -> Tensor:
        bsz, seqlen, dim = x.shape
        q = self.c_q(x).reshape(bsz, seqlen, self.num_heads, self.head_dim)
        k = self.c_k(x).reshape(bsz, seqlen, self.num_kv_heads, self.head_dim)
        v = self.c_v(x).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)
        k = apply_rotary_emb(k, cos, sin)
        q = q * self.q_gain.to(dtype=q.dtype)[None, None, :, None]
        if self.use_xsa:
            # Expand KV heads to match Q heads for GQA
            kv_rep = self.num_heads // self.num_kv_heads
            k_exp = k.repeat_interleave(kv_rep, dim=2) if kv_rep > 1 else k
            v_exp = v.repeat_interleave(kv_rep, dim=2) if kv_rep > 1 else v
            q2 = q.transpose(1, 2)
            k2 = k_exp.transpose(1, 2)
            v2 = v_exp.transpose(1, 2)
            scale = 1.0 / (self.head_dim ** 0.5)
            attn = (q2 @ k2.transpose(-2, -1)) * scale
            causal_mask = torch.triu(torch.ones(seqlen, seqlen, device=x.device, dtype=torch.bool), diagonal=1)
            self_mask = torch.eye(seqlen, device=x.device, dtype=torch.bool)
            self_mask[0, 0] = False  # position 0 has no other causal targets
            attn = attn.masked_fill((causal_mask | self_mask)[None, None], float('-inf'))
            attn = F.softmax(attn, dim=-1)
            y = (attn @ v2).transpose(1, 2)
        else:
            y = flash_attn_3_func(q.to(torch.bfloat16), k.to(torch.bfloat16), v.to(torch.bfloat16), causal=True)
        y = y.reshape(bsz, seqlen, dim)
        return self.proj(y)


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 MLP(nn.Module):
    def __init__(self, dim: int, mlp_mult: int):
        super().__init__()
        hidden = int(mlp_mult * dim)
        self.fc = CastedLinear(dim, hidden, bias=False)
        self.proj = CastedLinear(hidden, dim, bias=False)
        self.proj._zero_init = True

    def forward(self, x: Tensor) -> Tensor:
        x = torch.relu(self.fc(x))
        return self.proj(x.square())


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,
        use_xsa: bool = False,
    ):
        super().__init__()
        self.attn_norm = RMSNorm()
        self.mlp_norm = RMSNorm()
        self.attn = CausalSelfAttention(dim, num_heads, num_kv_heads, rope_base, qk_gain_init, use_xsa=use_xsa)
        self.mlp = MLP(dim, mlp_mult)
        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())

    def forward(self, x: Tensor, x0: Tensor) -> Tensor:
        mix = self.resid_mix.to(dtype=x.dtype)
        x = mix[0][None, None, :] * x + mix[1][None, None, :] * x0
        attn_out = self.attn(self.attn_norm(x))
        x = x + self.attn_scale.to(dtype=x.dtype)[None, None, :] * attn_out
        x = x + self.mlp_scale.to(dtype=x.dtype)[None, None, :] * self.mlp(self.mlp_norm(x))
        return x


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,
        mtp_num_heads: int = 0,
        mtp_loss_weight: float = 0.1,
        bigram_vocab_size: int = 0,
        bigram_dim: int = 128,
        xsa_last_n: int = 0,
    ):
        super().__init__()
        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.mtp_num_heads = mtp_num_heads
        self.mtp_loss_weight = mtp_loss_weight
        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))
        self.blocks = nn.ModuleList(
            [
                Block(
                    model_dim,
                    num_heads,
                    num_kv_heads,
                    mlp_mult,
                    rope_base,
                    qk_gain_init,
                    use_xsa=(i >= num_layers - xsa_last_n) if xsa_last_n > 0 else False,
                )
                for i in range(num_layers)
            ]
        )
        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
        self.mtp_heads = nn.ModuleList(
            [CastedLinear(model_dim, vocab_size, bias=False) for _ in range(mtp_num_heads)]
        )
        for head in self.mtp_heads:
            head._zero_init = True
        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)
        num_layers = len(self.blocks)
        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)
                    if ".proj." in name or name.endswith(".proj"):
                        with torch.no_grad():
                            module.weight.mul_(1.0 / math.sqrt(2 * num_layers))

    def forward(self, input_ids: Tensor, target_ids: Tensor) -> Tensor:
        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] = []

        for i in range(self.num_encoder_layers):
            x = self.blocks[i](x, x0)
            skips.append(x)
        for i in range(self.num_decoder_layers):
            if skips:
                x = x + self.skip_weights[i].to(dtype=x.dtype)[None, None, :] * skips.pop()
            x = self.blocks[self.num_encoder_layers + i](x, x0)

        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)
        main_loss = F.cross_entropy(logits.float(), targets, reduction="mean")

        if self.training and self.mtp_num_heads > 0 and self.mtp_loss_weight > 0.0:
            _, seqlen, dim = x.shape
            mtp_loss_sum = x.new_zeros(())
            mtp_loss_count = 0
            for k, mtp_head in enumerate(self.mtp_heads):
                valid_t = seqlen - (k + 1)
                if valid_t <= 0:
                    continue
                mtp_hidden = x[:, :valid_t, :].reshape(-1, dim)
                mtp_targets = target_ids[:, k + 1 :].reshape(-1)
                mtp_logits_proj = mtp_head(mtp_hidden)
                mtp_logits = self.logit_softcap * torch.tanh(mtp_logits_proj / self.logit_softcap)
                mtp_loss_sum = mtp_loss_sum + F.cross_entropy(mtp_logits.float(), mtp_targets, reduction="mean")
                mtp_loss_count += 1
            if mtp_loss_count > 0:
                main_loss = main_loss + self.mtp_loss_weight * (mtp_loss_sum / mtp_loss_count)

        return main_loss

    def forward_logits(self, input_ids: Tensor) -> Tensor:
        """Return logits (bsz, seq_len, vocab) without computing loss."""
        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] = []
        for i in range(self.num_encoder_layers):
            x = self.blocks[i](x, x0)
            skips.append(x)
        for i in range(self.num_decoder_layers):
            if skips:
                x = x + self.skip_weights[i].to(dtype=x.dtype)[None, None, :] * skips.pop()
            x = self.blocks[self.num_encoder_layers + i](x, x0)
        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,
    temperature: float = 1.0,
) -> 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)

            # Apply temperature scaling
            if temperature != 1.0:
                logits = logits / temperature

            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 find_optimal_temperature(
    model: nn.Module,
    val_tokens: Tensor,
    device: torch.device,
    seq_len: int,
    rank: int,
    world_size: int,
    num_seqs: int = 64,
    log_fn=None,
) -> float:
    """Find optimal temperature via grid search on a subset of val data.

    Computes logits once, then re-scores at each temperature — one forward pass total.
    """
    total_seqs = (val_tokens.numel() - 1) // seq_len
    sub_seqs = min(num_seqs, total_seqs)
    my_start = (sub_seqs * rank) // world_size
    my_end = (sub_seqs * (rank + 1)) // world_size
    if my_end <= my_start:
        return 1.0

    raw_start = my_start * seq_len
    raw_end = my_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)

    model.eval()
    with torch.inference_mode(), torch.autocast(device_type="cuda", dtype=torch.bfloat16):
        logits = model.forward_logits(x)

    targets = y.reshape(-1)
    logits_flat = logits.reshape(-1, logits.size(-1)).float()

    temps = [0.80, 0.85, 0.88, 0.90, 0.92, 0.94, 0.96, 0.98, 1.00, 1.02, 1.05, 1.10]
    best_t, best_loss = 1.0, float("inf")

    for t in temps:
        loss = F.cross_entropy(logits_flat / t, targets, reduction="mean").item()
        if loss < best_loss:
            best_t, best_loss = t, loss

    # Reduce across ranks: pick temperature with lowest loss
    if world_size > 1 and dist.is_available() and dist.is_initialized():
        best_tensor = torch.tensor([best_t, best_loss], device=device, dtype=torch.float64)
        gathered = [torch.zeros_like(best_tensor) for _ in range(world_size)]
        dist.all_gather(gathered, best_tensor)
        all_results = [(g[0].item(), g[1].item()) for g in gathered]
        best_t = min(all_results, key=lambda x: x[1])[0]

    if log_fn:
        log_fn(f"temp_scaling: optimal T={best_t:.3f} (subset_loss={best_loss:.4f})")

    model.train()
    return best_t


# -----------------------------
# INT6 MIXED QUANTIZATION (transplanted from working diagnostic scripts)
# -----------------------------

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) -> tuple[Tensor, Tensor]:
    t32 = t.float()
    if t32.ndim == 2:
        row_max = t32.abs().amax(dim=1)
        scale = (row_max / 31.0).clamp_min(1.0 / 31.0).to(torch.float16)
        q = torch.clamp(torch.round(t32 / scale.float()[:, None]), -32, 31).to(torch.int8)
        return q, scale
    amax = t32.abs().max().item()
    scale = torch.tensor(amax / 31.0 if amax > 0 else 1.0, dtype=torch.float16)
    q = torch.clamp(torch.round(t32 / scale.float()), -32, 31).to(torch.int8)
    return q, scale

def mixed_quantize_int6(state_dict: dict[str, Tensor], int6_cats: set[str]):
    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] = {}
    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
        # tok_emb.weight falls through to int8 via "embed" category
        if cat in int6_cats and t.ndim >= 1:
            q, s = quantize_int6_per_row(t)
            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"}
    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


# -----------------------------
# TTT v2 (TEST-TIME TRAINING)
# -----------------------------

def ttt_adapt(args, base_model, device, val_tokens, rank=0, world_size=1, log_fn=None):
    """TTT v2: cosine LR decay, discriminative per-layer LR, low momentum, weight decay."""
    seq_len = args.train_seq_len
    total_seqs = (val_tokens.numel() - 1) // seq_len
    batch_seqs = args.ttt_batch_seqs
    num_blocks = len(base_model.blocks)

    # Build per-layer param groups with discriminative LR
    param_groups = []

    if args.ttt_discriminative_lr:
        # Per-block groups: linearly ramp LR from near-zero (block 0) to full (block N-1)
        block_param_ids = set()
        for i, block in enumerate(base_model.blocks):
            block_lr = args.ttt_lr * (i + 1) / num_blocks
            block_params = list(block.parameters())
            if block_params:
                param_groups.append({"params": block_params, "lr": block_lr, "base_lr": block_lr})
                for p in block_params:
                    block_param_ids.add(id(p))
        # Non-block params (embeddings, norms, skip_weights, smear, bigram) at full LR
        other_params = [p for p in base_model.parameters() if id(p) not in block_param_ids]
        if other_params:
            param_groups.append({"params": other_params, "lr": args.ttt_lr, "base_lr": args.ttt_lr})
    else:
        # Legacy: binary freeze first N blocks
        if args.ttt_freeze_blocks > 0:
            for i, block in enumerate(base_model.blocks):
                if i < args.ttt_freeze_blocks:
                    for p in block.parameters():
                        p.requires_grad_(False)
        ttt_params = [p for p in base_model.parameters() if p.requires_grad]
        param_groups.append({"params": ttt_params, "lr": args.ttt_lr, "base_lr": args.ttt_lr})

    optimizer = torch.optim.SGD(param_groups, lr=args.ttt_lr,
                                momentum=args.ttt_momentum, weight_decay=args.ttt_wd)

    my_start = (total_seqs * rank) // world_size
    my_end = (total_seqs * (rank + 1)) // world_size

    # Compute total steps for cosine schedule
    batches_per_epoch = max(1, (my_end - my_start + batch_seqs - 1) // batch_seqs)
    total_ttt_steps = batches_per_epoch * args.ttt_epochs

    base_model.train()
    t0 = time.perf_counter()
    global_step = 0

    for epoch in range(args.ttt_epochs):
        epoch_loss_sum = torch.zeros((), device=device, dtype=torch.float64)
        epoch_tokens = torch.zeros((), device=device, dtype=torch.float64)

        for batch_start in range(my_start, my_end, batch_seqs):
            batch_end = min(batch_start + batch_seqs, my_end)
            raw_start = batch_start * seq_len
            raw_end = batch_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)

            # Cosine LR decay: peak → 10% of peak over total TTT steps
            if args.ttt_cosine_decay:
                cosine_mul = 0.5 * (1.0 + math.cos(math.pi * global_step / max(total_ttt_steps, 1)))
                cosine_mul = max(cosine_mul, 0.1)  # Floor at 10% of base
                for group in optimizer.param_groups:
                    group["lr"] = group["base_lr"] * cosine_mul

            optimizer.zero_grad(set_to_none=True)
            with torch.autocast(device_type="cuda", dtype=torch.bfloat16):
                loss = base_model(x, y)
            loss.backward()

            all_params = [p for group in optimizer.param_groups for p in group["params"]]
            if world_size > 1:
                for p in all_params:
                    if p.grad is not None:
                        dist.all_reduce(p.grad, op=dist.ReduceOp.AVG)

            torch.nn.utils.clip_grad_norm_(all_params, 1.0)
            optimizer.step()

            epoch_loss_sum += loss.detach().to(torch.float64) * y.numel()
            epoch_tokens += float(y.numel())
            global_step += 1

        if world_size > 1:
            dist.all_reduce(epoch_loss_sum, op=dist.ReduceOp.SUM)
            dist.all_reduce(epoch_tokens, op=dist.ReduceOp.SUM)

        elapsed = time.perf_counter() - t0
        if log_fn:
            log_fn(f"ttt_epoch:{epoch+1}/{args.ttt_epochs} loss:{epoch_loss_sum.item()/max(epoch_tokens.item(),1):.4f} time:{elapsed:.1f}s")

    # Unfreeze all params (in case legacy binary freeze was used)
    for p in base_model.parameters():
        p.requires_grad_(True)

    if log_fn:
        log_fn(f"ttt:done elapsed={time.perf_counter()-t0:.1f}s")


# -----------------------------
# TRAINING
# -----------------------------

def main() -> None:
    global zeropower_via_newtonschulz5

    code = Path(__file__).read_text(encoding="utf-8")
    args = Hyperparameters()
    zeropower_via_newtonschulz5 = torch.compile(zeropower_via_newtonschulz5)

    # -----------------------------
    # DISTRIBUTED + CUDA SETUP
    # -----------------------------

    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

    # Fast math knobs
    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)

    # -----------------------------
    # TOKENIZER + VALIDATION METRIC SETUP
    # -----------------------------

    random.seed(args.seed)
    np.random.seed(args.seed)
    torch.manual_seed(args.seed)
    torch.cuda.manual_seed_all(args.seed)

    if not args.tokenizer_path.endswith(".model"):
        raise ValueError(f"Script only setup for SentencePiece .model file: {args.tokenizer_path}")
    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)
    base_bytes_lut, has_leading_space_lut, is_boundary_token_lut = build_sentencepiece_luts(
        sp, args.vocab_size, device
    )
    log0(f"val_bpb:enabled tokenizer_kind=sentencepiece tokenizer_path={args.tokenizer_path}")
    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}")

    # -----------------------------
    # MODEL + OPTIMIZER SETUP
    # -----------------------------

    CastedLinear._qat_enabled = args.qat_enabled

    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,
        mtp_num_heads=args.mtp_num_heads,
        mtp_loss_weight=args.mtp_loss_weight,
        bigram_vocab_size=args.bigram_vocab_size,
        bigram_dim=args.bigram_dim,
        xsa_last_n=args.xsa_last_n,
    ).to(device).bfloat16()
    for module in base_model.modules():
        if isinstance(module, CastedLinear):
            module.float()
    restore_low_dim_params_to_fp32(base_model)
    # Use dynamic=True when seq curriculum varies sequence lengths during training
    use_dynamic = args.seq_curriculum_enabled
    compiled_model = torch.compile(base_model, dynamic=use_dynamic, fullgraph=True)
    model: nn.Module = DDP(compiled_model, device_ids=[local_rank], broadcast_buffers=False) if distributed else compiled_model

    # Optimizer split:
    # - token embedding (Adam) uses EMBED_LR
    # - untied lm_head (Adam) uses HEAD_LR
    # - matrix params in transformer blocks use MATRIX_LR via Muon
    # - vectors/scalars use SCALAR_LR via Adam
    block_named_params = list(base_model.blocks.named_parameters())
    matrix_params = [
        p
        for name, p in block_named_params
        if p.ndim == 2 and not any(pattern in name for pattern in CONTROL_TENSOR_NAME_PATTERNS)
    ]
    if base_model.mtp_num_heads > 0:
        matrix_params.extend([p for p in base_model.mtp_heads.parameters() if p.ndim == 2])
    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:
            matrix_params.append(base_model.bigram.proj.weight)
    optimizer_tok = torch.optim.AdamW(
        tok_params,
        betas=(args.beta1, args.beta2),
        eps=args.adam_eps,
        weight_decay=args.adam_wd,
        fused=True,
    )
    MuonClass = Mousse if args.mousse_enabled else Muon
    optimizer_muon = MuonClass(
        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
    log0(f"optimizer:{'mousse' if args.mousse_enabled else 'muon'}")
    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,
    )
    optimizers: list[torch.optim.Optimizer] = [optimizer_tok, optimizer_muon, optimizer_scalar]
    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,
        )
        optimizers.insert(1, optimizer_head)

    n_params = sum(p.numel() for p in base_model.parameters())
    mtp_params = sum(p.numel() for p in base_model.mtp_heads.parameters())
    log0(f"model_params:{n_params}")
    log0(f"mtp_num_heads:{args.mtp_num_heads} mtp_loss_weight:{args.mtp_loss_weight} mtp_params:{mtp_params}")
    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}")
    log0(f"v2_features: d2z={args.d2z_enabled} seq_curriculum={args.seq_curriculum_enabled}({args.seq_curriculum_min}-{args.train_seq_len}) "
         f"batch_warmup={args.batch_warmup_enabled}({args.batch_warmup_start_tokens}-{args.train_batch_tokens}) "
         f"mousse={args.mousse_enabled} temp_scaling={args.temp_scaling_enabled}")
    log0(f"ttt_v2: cosine_decay={args.ttt_cosine_decay} discriminative_lr={args.ttt_discriminative_lr} "
         f"lr={args.ttt_lr} momentum={args.ttt_momentum} epochs={args.ttt_epochs} wd={args.ttt_wd}")

    # -----------------------------
    # DATA LOADER & MODEL WARMUP
    # -----------------------------

    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

    def lr_mul(step: int, elapsed_ms: float) -> float:
        if args.d2z_enabled:
            # D2Z: linear warmup then linear decay to zero
            if step < args.d2z_warmup_steps:
                return step / max(args.d2z_warmup_steps, 1)
            if max_wallclock_ms is not None:
                return max(1.0 - elapsed_ms / max_wallclock_ms, 0.0)
            return max(1.0 - step / max(args.iterations, 1), 0.0)
        # Original warmdown schedule (fallback)
        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

    def get_curriculum_seq_len(step: int, elapsed_ms: float) -> int:
        """Stepped sequence length curriculum: 256 → 512 → 1024 → 2048."""
        if not args.seq_curriculum_enabled:
            return args.train_seq_len
        # Estimate total steps from wallclock
        if max_wallclock_ms is not None and step > 10:
            est_total = int(max_wallclock_ms / (elapsed_ms / step))
        else:
            est_total = args.iterations
        ramp_steps = int(args.seq_curriculum_ramp_frac * est_total)
        if step >= ramp_steps:
            return args.train_seq_len
        frac = step / max(ramp_steps, 1)
        if frac < 0.33:
            return min(args.seq_curriculum_min, args.train_seq_len)
        elif frac < 0.67:
            return min(args.seq_curriculum_min * 2, args.train_seq_len)
        else:
            return min(args.seq_curriculum_min * 4, args.train_seq_len)

    def get_batch_tokens(step: int) -> int:
        """Linear batch size warmup from small to full."""
        if not args.batch_warmup_enabled or step >= args.batch_warmup_steps:
            return args.train_batch_tokens
        frac = step / max(args.batch_warmup_steps, 1)
        tokens = int(args.batch_warmup_start_tokens + frac * (args.train_batch_tokens - args.batch_warmup_start_tokens))
        # Ensure at least 1 sequence per rank per micro-step
        min_tokens = args.seq_curriculum_min * world_size * grad_accum_steps
        return max(tokens, min_tokens)

    # Warmup primes the compiled forward/backward/optimizer paths, then we restore the
    # initial weights/optimizer state so measured training starts from the true init.
    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):
                if distributed:
                    model.require_backward_grad_sync = micro_step == grad_accum_steps - 1
                x, y = train_loader.next_batch(args.train_batch_tokens, args.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()
            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()
        if distributed:
            model.require_backward_grad_sync = True
        train_loader = DistributedTokenLoader(args.train_files, rank, world_size, device)

    # -----------------------------
    # MAIN TRAINING LOOP
    # -----------------------------

    swa_state: dict[str, Tensor] | None = None
    swa_count = 0

    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)
        curr_seq_len = get_curriculum_seq_len(step, elapsed_ms)
        curr_batch_tokens = get_batch_tokens(step)
        zero_grad_all()
        train_loss = torch.zeros((), device=device)
        for micro_step in range(grad_accum_steps):
            if distributed:
                model.require_backward_grad_sync = micro_step == grad_accum_steps - 1
            x, y = train_loader.next_batch(curr_batch_tokens, curr_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)
        for opt in optimizers:
            opt.step()
        zero_grad_all()

        step += 1
        approx_training_time_ms = training_time_ms + 1000.0 * (time.perf_counter() - t0)

        if args.swa_enabled and scale < 0.5 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 "
                f"seq:{curr_seq_len} batch:{curr_batch_tokens} lr_scale:{scale:.4f}"
            )

        # Needed to sync whether we've reached the wallclock cap.
        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"
    )

    if args.swa_enabled and swa_state is not None and swa_count > 1:
        log0(f"swa:applying averaged {swa_count} checkpoints")
        avg_state = {name: (t / swa_count).to(dtype=base_model.state_dict()[name].dtype)
                     for name, t in swa_state.items()}
        base_model.load_state_dict(avg_state, strict=True)

    # -----------------------------
    # SERIALIZATION + ROUNDTRIP VALIDATION
    # -----------------------------

    full_state_dict = base_model.state_dict()
    export_sd = {k: v for k, v in full_state_dict.items() if "mtp_heads" not in k}
    excluded_mtp = sum(int(t.numel()) for k, t in full_state_dict.items() if "mtp_heads" in k)
    if excluded_mtp > 0:
        log0(f"export_excluding_mtp_params:{excluded_mtp}")

    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")

    sd_cpu = {k: v.detach().cpu() for k, v in export_sd.items()}
    quant_result, quant_meta = mixed_quantize_int6(sd_cpu, {"mlp", "attn"})
    quant_buf = io.BytesIO()
    torch.save({"w": quant_result, "m": quant_meta}, quant_buf)
    quant_raw = quant_buf.getvalue()
    quant_blob = zstandard.ZstdCompressor(level=22).compress(quant_raw) if _COMPRESSOR == "zstd" else zlib.compress(quant_raw, 9)
    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+{_COMPRESSOR}: {quant_file_bytes} bytes")
        log0(f"Total submission size int6+{_COMPRESSOR}: {quant_file_bytes + code_bytes} bytes")

    # Roundtrip: decompress + dequantize into fresh model + eval
    if distributed:
        dist.barrier()
    with open("final_model.int6.ptz", "rb") as f:
        quant_blob_disk = f.read()
    quant_state = torch.load(
        io.BytesIO(zstandard.ZstdDecompressor().decompress(quant_blob_disk) if _COMPRESSOR == "zstd" else zlib.decompress(quant_blob_disk)),
        map_location="cpu",
    )
    deq_state = dequantize_mixed_int6(quant_state["w"], quant_state["m"], 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,
        mtp_num_heads=0, mtp_loss_weight=0.0,
        bigram_vocab_size=args.bigram_vocab_size, bigram_dim=args.bigram_dim,
    ).to(device).bfloat16()
    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)

    # TTT v2: adapt model on validation data before eval
    if args.ttt_enabled:
        if distributed:
            dist.barrier()
        if master_process:
            log0(f"ttt_v2:start lr={args.ttt_lr} momentum={args.ttt_momentum} epochs={args.ttt_epochs} "
                 f"cosine_decay={args.ttt_cosine_decay} discriminative_lr={args.ttt_discriminative_lr} wd={args.ttt_wd}")
        t_ttt = time.perf_counter()
        ttt_adapt(args, eval_model, device, val_tokens, rank=rank, world_size=world_size, log_fn=log0)
        if master_process:
            log0(f"ttt:elapsed={time.perf_counter() - t_ttt:.1f}s")
        if distributed:
            dist.barrier()

    # Temperature scaling: find optimal T on a subset before full eval
    optimal_temp = 1.0
    if args.temp_scaling_enabled:
        torch.cuda.synchronize()
        t_temp = time.perf_counter()
        optimal_temp = find_optimal_temperature(
            eval_model, val_tokens, device, effective_eval_seq_len,
            rank, world_size, num_seqs=64, log_fn=log0,
        )
        torch.cuda.synchronize()
        log0(f"temp_scaling:done T={optimal_temp:.3f} time={1000.0 * (time.perf_counter() - t_temp):.0f}ms")

    # Recompile after TTT weight changes (or fresh compile if TTT disabled)
    compiled_eval = torch.compile(eval_model, dynamic=False, fullgraph=True)

    # Standard non-overlapping eval (sanity check)
    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}")

    # Sliding window eval (submission score) — with temperature scaling
    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,
            temperature=optimal_temp,
        )
        torch.cuda.synchronize()
        log0(
            f"final_ttt_sliding val_loss:{sw_val_loss:.4f} val_bpb:{sw_val_bpb:.4f} "
            f"stride:{args.eval_stride} T:{optimal_temp:.3f} eval_time:{1000.0 * (time.perf_counter() - t_slide):.0f}ms"
        )
        log0(f"final_ttt_sliding_exact val_loss:{sw_val_loss:.8f} val_bpb:{sw_val_bpb:.8f}")

        # Also eval at T=1.0 for comparison if temp was changed
        if optimal_temp != 1.0:
            torch.cuda.synchronize()
            t_slide_t1 = time.perf_counter()
            sw_t1_loss, sw_t1_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,
                temperature=1.0,
            )
            torch.cuda.synchronize()
            log0(
                f"final_ttt_sliding_T1 val_loss:{sw_t1_loss:.4f} val_bpb:{sw_t1_bpb:.4f} "
                f"stride:{args.eval_stride} T:1.000 eval_time:{1000.0 * (time.perf_counter() - t_slide_t1):.0f}ms"
            )

    # Second sliding window eval at stride=64 for submission comparison
    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,
            temperature=optimal_temp,
        )
        torch.cuda.synchronize()
        log0(
            f"final_ttt_sliding_s64 val_loss:{sw64_val_loss:.4f} val_bpb:{sw64_val_bpb:.4f} "
            f"stride:64 T:{optimal_temp:.3f} eval_time:{1000.0 * (time.perf_counter() - t_slide64):.0f}ms"
        )
        log0(f"final_ttt_sliding_s64_exact val_loss:{sw64_val_loss:.8f} val_bpb:{sw64_val_bpb:.8f}")

    if distributed:
        dist.destroy_process_group()


if __name__ == "__main__":
    main()

====================================================================================================
Running Python 3.12.3 (main, Nov  6 2025, 13:44:16) [GCC 13.3.0]
Running PyTorch 2.9.1+cu128
Sun Mar 22 00:34:21 2026       
+-----------------------------------------------------------------------------------------+
| NVIDIA-SMI 580.126.09             Driver Version: 580.126.09     CUDA Version: 13.0     |
+-----------------------------------------+------------------------+----------------------+
| GPU  Name                 Persistence-M | Bus-Id          Disp.A | Volatile Uncorr. ECC |
| Fan  Temp   Perf          Pwr:Usage/Cap |           Memory-Usage | GPU-Util  Compute M. |
|                                         |                        |               MIG M. |
|=========================================+========================+======================|
|   0  NVIDIA H100 80GB HBM3          On  |   00000000:19:00.0 Off |                    0 |
| N/A   38C    P0            118W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   1  NVIDIA H100 80GB HBM3          On  |   00000000:3B:00.0 Off |                    0 |
| N/A   33C    P0            120W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   2  NVIDIA H100 80GB HBM3          On  |   00000000:4C:00.0 Off |                    0 |
| N/A   31C    P0            119W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   3  NVIDIA H100 80GB HBM3          On  |   00000000:5D:00.0 Off |                    0 |
| N/A   37C    P0            116W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   4  NVIDIA H100 80GB HBM3          On  |   00000000:9B:00.0 Off |                    0 |
| N/A   37C    P0            120W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   5  NVIDIA H100 80GB HBM3          On  |   00000000:BB:00.0 Off |                    0 |
| N/A   32C    P0            119W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   6  NVIDIA H100 80GB HBM3          On  |   00000000:CB:00.0 Off |                    0 |
| N/A   36C    P0            117W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+
|   7  NVIDIA H100 80GB HBM3          On  |   00000000:DB:00.0 Off |                    0 |
| N/A   31C    P0            115W /  700W |    1521MiB /  81559MiB |      0%      Default |
|                                         |                        |             Disabled |
+-----------------------------------------+------------------------+----------------------+

+-----------------------------------------------------------------------------------------+
| Processes:                                                                              |
|  GPU   GI   CI              PID   Type   Process name                        GPU Memory |
|        ID   ID                                                               Usage      |
|=========================================================================================|
|  No running processes found                                                             |
+-----------------------------------------------------------------------------------------+

====================================================================================================
val_bpb:enabled tokenizer_kind=sentencepiece tokenizer_path=./data/tokenizers/fineweb_1024_bpe.model
train_loader:dataset:fineweb10B_sp1024 train_shards:80
val_loader:shards pattern=./data/datasets/fineweb10B_sp1024/fineweb_val_*.bin tokens:62021632
optimizer:muon
model_params:26829913
mtp_num_heads:0 mtp_loss_weight:0.2 mtp_params:0
world_size:8 grad_accum_steps:1
sdp_backends:cudnn=False flash=True mem_efficient=False math=False
attention_mode:gqa num_heads:8 num_kv_heads:4
tie_embeddings:True embed_lr:0.035 head_lr:0.0 matrix_lr:0.025 scalar_lr:0.025
train_batch_tokens:786432 train_seq_len:2048 iterations:9000 warmup_steps:20 max_wallclock_seconds:600.000
seed:1337
v2_features: d2z=False seq_curriculum=False(256-2048) batch_warmup=False(262144-786432) mousse=False temp_scaling=True
ttt_v2: cosine_decay=True discriminative_lr=True lr=0.003 momentum=0.3 epochs=5 wd=0.01
warmup_step:1/20
warmup_step:2/20
warmup_step:3/20
warmup_step:4/20
warmup_step:5/20
warmup_step:6/20
warmup_step:7/20
warmup_step:8/20
warmup_step:9/20
warmup_step:10/20
warmup_step:11/20
warmup_step:12/20
warmup_step:13/20
warmup_step:14/20
warmup_step:15/20
warmup_step:16/20
warmup_step:17/20
warmup_step:18/20
warmup_step:19/20
warmup_step:20/20
step:0/9000 val_loss:6.9303 val_bpb:4.1045 train_time:0ms step_avg:0.02ms
step:1/9000 train_loss:6.9326 train_time:175ms step_avg:175.28ms seq:2048 batch:786432 lr_scale:1.0000
step:2/9000 train_loss:8.6002 train_time:293ms step_avg:146.57ms seq:2048 batch:786432 lr_scale:1.0000
step:3/9000 train_loss:7.9335 train_time:417ms step_avg:138.91ms seq:2048 batch:786432 lr_scale:1.0000
step:4/9000 train_loss:7.2305 train_time:543ms step_avg:135.72ms seq:2048 batch:786432 lr_scale:1.0000
step:5/9000 train_loss:7.0017 train_time:668ms step_avg:133.61ms seq:2048 batch:786432 lr_scale:1.0000
step:6/9000 train_loss:6.8821 train_time:792ms step_avg:131.95ms seq:2048 batch:786432 lr_scale:1.0000
step:7/9000 train_loss:6.9106 train_time:916ms step_avg:130.88ms seq:2048 batch:786432 lr_scale:1.0000
step:8/9000 train_loss:6.9231 train_time:1041ms step_avg:130.06ms seq:2048 batch:786432 lr_scale:1.0000
step:9/9000 train_loss:6.4954 train_time:1168ms step_avg:129.78ms seq:2048 batch:786432 lr_scale:1.0000
step:10/9000 train_loss:6.1258 train_time:1292ms step_avg:129.20ms seq:2048 batch:786432 lr_scale:1.0000
step:200/9000 train_loss:2.4271 train_time:25181ms step_avg:125.90ms seq:2048 batch:786432 lr_scale:1.0000
step:400/9000 train_loss:2.4210 train_time:50442ms step_avg:126.11ms seq:2048 batch:786432 lr_scale:1.0000
step:600/9000 train_loss:2.3383 train_time:75673ms step_avg:126.12ms seq:2048 batch:786432 lr_scale:1.0000
step:800/9000 train_loss:2.2391 train_time:100941ms step_avg:126.18ms seq:2048 batch:786432 lr_scale:1.0000
step:1000/9000 train_loss:2.2728 train_time:126119ms step_avg:126.12ms seq:2048 batch:786432 lr_scale:1.0000
step:1000/9000 val_loss:2.2282 val_bpb:1.3196 train_time:126125ms step_avg:126.13ms
step:1200/9000 train_loss:2.3506 train_time:151329ms step_avg:126.11ms seq:2048 batch:786432 lr_scale:1.0000
step:1400/9000 train_loss:2.1820 train_time:176518ms step_avg:126.08ms seq:2048 batch:786432 lr_scale:1.0000
step:1600/9000 train_loss:2.0751 train_time:201629ms step_avg:126.02ms seq:2048 batch:786432 lr_scale:1.0000
step:1800/9000 train_loss:2.1526 train_time:226787ms step_avg:125.99ms seq:2048 batch:786432 lr_scale:0.9877
step:2000/9000 train_loss:2.0588 train_time:251882ms step_avg:125.94ms seq:2048 batch:786432 lr_scale:0.9217
step:2000/9000 val_loss:2.1245 val_bpb:1.2582 train_time:251889ms step_avg:125.94ms
step:2200/9000 train_loss:2.1247 train_time:277028ms step_avg:125.92ms seq:2048 batch:786432 lr_scale:0.8553
step:2400/9000 train_loss:2.0486 train_time:302175ms step_avg:125.91ms seq:2048 batch:786432 lr_scale:0.7888
step:2600/9000 train_loss:2.0865 train_time:327320ms step_avg:125.89ms seq:2048 batch:786432 lr_scale:0.7223
step:2800/9000 train_loss:2.1278 train_time:352451ms step_avg:125.88ms seq:2048 batch:786432 lr_scale:0.6558
step:3000/9000 train_loss:2.1294 train_time:377519ms step_avg:125.84ms seq:2048 batch:786432 lr_scale:0.5896
step:3000/9000 val_loss:2.0574 val_bpb:1.2185 train_time:377526ms step_avg:125.84ms
step:3200/9000 train_loss:2.1337 train_time:402637ms step_avg:125.82ms seq:2048 batch:786432 lr_scale:0.5232
swa:start step:3400
step:3400/9000 train_loss:1.9777 train_time:427704ms step_avg:125.80ms seq:2048 batch:786432 lr_scale:0.4569
step:3600/9000 train_loss:2.0431 train_time:452913ms step_avg:125.81ms seq:2048 batch:786432 lr_scale:0.3900
step:3800/9000 train_loss:2.0132 train_time:478013ms step_avg:125.79ms seq:2048 batch:786432 lr_scale:0.3236
step:4000/9000 train_loss:1.9112 train_time:503172ms step_avg:125.79ms seq:2048 batch:786432 lr_scale:0.2569
step:4000/9000 val_loss:2.0014 val_bpb:1.1853 train_time:503224ms step_avg:125.81ms
step:4200/9000 train_loss:2.0810 train_time:528332ms step_avg:125.79ms seq:2048 batch:786432 lr_scale:0.1902
step:4400/9000 train_loss:1.9594 train_time:553436ms step_avg:125.78ms seq:2048 batch:786432 lr_scale:0.1237
step:4600/9000 train_loss:1.7699 train_time:578606ms step_avg:125.78ms seq:2048 batch:786432 lr_scale:0.0570
step:4771/9000 val_loss:1.9572 val_bpb:1.1592 train_time:600112ms step_avg:125.78ms
stopping_early: wallclock_cap train_time:600112ms step:4771/9000
peak memory allocated: 39223 MiB reserved: 45432 MiB
swa:applying averaged 7 checkpoints
Serialized model: 105783807 bytes
Code size: 83219 bytes
Serialized model int6+zstd: 15839512 bytes
Total submission size int6+zstd: 15922731 bytes
ttt_v2:start lr=0.003 momentum=0.3 epochs=5 cosine_decay=True discriminative_lr=True wd=0.01
ttt_epoch:1/5 loss:2.0465 time:15.0s
ttt_epoch:2/5 loss:2.0336 time:29.8s
ttt_epoch:3/5 loss:2.0290 time:44.5s
ttt_epoch:4/5 loss:2.0258 time:59.3s
ttt_epoch:5/5 loss:2.0248 time:74.1s
ttt:done elapsed=74.2s
ttt:elapsed=74.2s
temp_scaling: optimal T=1.000 (subset_loss=2.1656)
temp_scaling:done T=1.000 time=16ms
final_int6_roundtrip val_loss:2.0232 val_bpb:1.1982 eval_time:22323ms
final_int6_roundtrip_exact val_loss:2.02318754 val_bpb:1.19824562
final_ttt_sliding val_loss:1.9920 val_bpb:1.1797 stride:64 T:1.000 eval_time:80856ms
final_ttt_sliding_exact val_loss:1.99195166 val_bpb:1.17974909
