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Spider-FLEXITOKENS-FP8 / tk-spider.py
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#!/usr/bin/env python3
"""Spider: MoE + RDT (Recurrent-Depth Transformer) architecture v5.
Canonical architecture ported from mythos-fineweb-moe.py (SpiderPortal v5-Dense)
with the following adaptations per Phase 02 decisions:
- Full Spider rebrand (no SpiderPortal/SpiderPortal prefix) per D-07
- Byte-level vocab: 272 tokens (256 bytes + 16 specials) per D-06
- MLA (Multi-Latent Attention) with compressed KV cache per D-10
- Engram conditional memory at recurrent layers 1 and 4
- MoE: 16 routed experts + 1 shared expert, top-1 routing
- Sliding window attention (sliding_window=8192) with 256k context (YaRN factor=8.0)
- Weight-tied embeddings per v5 canonical config (tie_word_embeddings=True)
- LTI Injection + ACT Halting + LoRA Adapter for RDT loops
- BoundaryPredictor + downsample/upsample for FlexiToken integration
- 272-token byte-level vocab with sentinel tokens for multimodal (D-11)
Architecture: RDT (2 prelude + 6 recurrent + 2 coda) with:
 - 2x Prelude (MLA + dense FFN)
 - 6x Recurrent (MLA + Engram@L1,L4 + MoE) -- with gradient checkpointing
 - 2x Coda (MLA + dense FFN)
 - LTI Injection + ACT Halting + LoRA Adapter
Config: hidden_size=2048, 6 recurrent layers, 32 experts, top-2 routing
"""
import math
import os
import sys as _sys
from dataclasses import dataclass, field
from typing import Dict, List, Optional, Tuple
import torch
import torch.nn as nn
import torch.nn.functional as F
from torch.nn import CrossEntropyLoss
try:
 _sys.path.insert(0, os.path.expanduser("~/TileKernels"))
 import tile_kernels as _tk
 _TK_AVAILABLE = True
except Exception:
 _tk = None
 _TK_AVAILABLE = False
# ============================================================================
# Spider Configuration
# ============================================================================
@dataclass
class SpiderConfig:
 """Spider model configuration (hidden_size=2048, byte-level vocab).
 Based on mythos-fineweb-moe.py SpiderPortalConfig with byte-level
 tokenization, MLA attention, and Engram memory.
 """
 # Core architecture
 vocab_size: int = 272 # 256 bytes + 16 specials (D-06)
 hidden_size: int = 2048
 num_hidden_layers: int = 6 # recurrent layers
 num_attention_heads: int = 16
 num_key_value_heads: int = 4 # not used directly in MLA but kept for compat
 intermediate_size: int = 1024
 hidden_act: str = "silu"
# MoE configuration (D-20, D-21: shared-projection MoE)
 num_experts: int = 32
 num_experts_per_tok: int = 2
 num_shared_experts: int = 1
 router_aux_loss_coef: float = 0.05
 shared_intermediate_size: int = 6144
 expert_core_rank: int = 256
 shared_expert_intermediate_size: int = 7424
 prelude_coda_intermediate_size: int = 4096
# RDT configuration
 max_loop_iters: int = 16
 act_threshold: float = 0.5
 prelude_layers: int = 2
 coda_layers: int = 2
 lora_rank: int = 128
 loop_embed_dim: int = 128
# MLA parameters (DeepSeek-V2 style, scaled for hidden_size=2048)
 kv_lora_rank: int = 128
 q_lora_rank: int = 256
 qk_rope_head_dim: int = 64
 qk_nope_head_dim: int = 64
 v_head_dim: int = 64
# Engram parameters (DeepSeek conditional memory, offloaded to CPU)
 engram_layers: List[int] = field(default_factory=lambda: [1, 4])
 engram_ngram_orders: Tuple[int, ...] = (2, 3)
 engram_hash_heads: int = 4
 engram_table_size: int = 8191 # prime, sized for byte vocab=272
 engram_conv_kernel: int = 4
 engram_conv_dilation: int = 3
 engram_dim: int = 128 # per-head embedding dimension
 engram_offload: bool = True # offload embed table to CPU (DeepSeek style)
# Attention / RoPE
 max_position_embeddings: int = 262144 # 256k context
 rope_theta: float = 10000000.0
 rope_scaling: Optional[Dict] = field(default_factory=lambda: {
 "type": "yarn",
 "factor": 8.0,
 "original_max_position_embeddings": 32768,
 })
 sliding_window: int = 8192 # local attention window
 attention_dropout: float = 0.0
 rms_norm_eps: float = 1e-6
 initializer_range: float = 0.02
# Embeddings / head
 tie_word_embeddings: bool = True # per v5 canonical config
# Multimodal
 vision_hidden_size: int = 2048
 audio_hidden_size: int = 512
 vision_num_frames: int = 60
 vision_tokens_per_frame: int = 256
 vision_temporal_tokens: int = 64
 vision_temporal_layers: int = 2
# Metadata
 model_type: str = "spider"
 torch_dtype: str = "bfloat16"
# BoundaryPredictor (for FlexiToken integration)
 bp_d_inner: int = 8192
@property
 def head_dim(self):
 return self.qk_nope_head_dim + self.qk_rope_head_dim # 128
def spider_flexitokens_997m() -> SpiderConfig:
 """Spider-FLEXITOKENS 995.1M config per D-20."""
 return SpiderConfig()
# ============================================================================
# Sentinel Token Vocabulary (D-06, D-11)
# ============================================================================
# 272-token vocab: 256 bytes + 16 specials
# Sentinel tokens at indices 259-264 mark modality region boundaries
SENTINEL_TOKENS = {
 'PAD': 256, 'BOS': 257, 'EOS': 258,
 'IMG_START': 259, 'IMG_END': 260,
 'AUD_START': 261, 'AUD_END': 262,
 'VID_START': 263, 'VID_END': 264,
 'MASK': 265, 'im_start': 266, 'im_end': 267,
 'prefix': 268, 'suffix': 269, 'middle': 270,
 'THINK': 271,
}
# Sentinel pairs for modality regions (start_id, end_id)
_SENTINEL_PAIRS = [
 (SENTINEL_TOKENS['IMG_START'], SENTINEL_TOKENS['IMG_END']), # (259, 260)
 (SENTINEL_TOKENS['AUD_START'], SENTINEL_TOKENS['AUD_END']), # (261, 262)
 (SENTINEL_TOKENS['VID_START'], SENTINEL_TOKENS['VID_END']), # (263, 264)
]
# Set of modality sentinel token IDs (259-264 only)
_MODALITY_SENTINEL_IDS = {259, 260, 261, 262, 263, 264}
# Reverse mapping (computed once at module level, per IN-01)
_TOKEN_NAMES_BY_ID = {v: k for k, v in SENTINEL_TOKENS.items()}
def is_sentinel_token(token_id: int) -> bool:
 """Return True if token_id is one of the 6 modality sentinel tokens (259-264).
 These are the sentinel tokens that mark modality region boundaries:
 IMG_START/END, AUD_START/END, VID_START/END.
 Other special tokens (PAD, BOS, EOS, MASK, etc.) are NOT modality sentinels.
 """
 return token_id in _MODALITY_SENTINEL_IDS
def create_modality_mask(input_ids: torch.Tensor, strict: bool = True) -> torch.Tensor:
 """Create boolean mask (B×L) marking sentinel and modality token positions.
 Per D-11: Sentinel-gated passthrough ensures modality tokens bypass the
 BoundaryPredictor entirely. This mask marks positions where:
 - Sentinel tokens (IMG_START/END, AUD_START/END, VID_START/END) appear
 - Modality tokens (between sentinel pairs) appear
 The BoundaryPredictor uses this mask to force boundary=1.0 at these
 positions, ensuring no boundary merging across modality boundaries.
 Args:
 input_ids: Token IDs of shape [B, L] with values in 0-271 range.
 strict: If True, raise on mismatched sentinel pairs (training mode).
 If False, skip mismatched pairs gracefully (generation mode).
 Returns:
 Boolean tensor of shape [B, L], True at sentinel+modality positions.
 Raises:
 ValueError: If strict=True and sentinel pairs are mismatched.
 """
 B, L = input_ids.shape
 mask = torch.zeros(B, L, dtype=torch.bool, device=input_ids.device)
# Mark direct sentinel token positions
 for sid in _MODALITY_SENTINEL_IDS:
 mask |= (input_ids == sid)
# Mark regions between sentinel pairs (inclusive of sentinels)
 for start_id, end_id in _SENTINEL_PAIRS:
 for b in range(B):
 starts = (input_ids[b] == start_id).nonzero(as_tuple=True)[0]
 ends = (input_ids[b] == end_id).nonzero(as_tuple=True)[0]
# T-02-04 mitigation: validate sentinel pairs are matched (strict mode only)
 if strict and len(starts) != len(ends):
 raise ValueError(
 f"Batch {b}: mismatched sentinel pairs — "
 f"{len(starts)} {_TOKEN_NAMES_BY_ID[start_id]}(s) vs "
 f"{len(ends)} {_TOKEN_NAMES_BY_ID[end_id]}(s). "
 f"Every {_TOKEN_NAMES_BY_ID[start_id]} must have a matching "
 f"{_TOKEN_NAMES_BY_ID[end_id]}."
 )
# Match pairs min(starts, ends) — skip unmatched in non-strict mode
 n_pairs = min(len(starts), len(ends))
 for i in range(n_pairs):
 s, e = starts[i].item(), ends[i].item()
 if s > e:
 if strict:
 raise ValueError(
 f"Batch {b}: {_TOKEN_NAMES_BY_ID[start_id]} at position {s} "
 f"appears after {_TOKEN_NAMES_BY_ID[end_id]} at position {e}. "
 f"Sentinel pairs must be properly ordered."
 )
 continue
 mask[b, s:e + 1] = True
return mask
# ============================================================================
# RMSNorm
# ============================================================================
class SpiderRMSNorm(nn.Module):
 """RMS normalization (bf16-only, no dtype conversions)."""
def __init__(self, hidden_size, eps=1e-6):
 super().__init__()
 self.weight = nn.Parameter(torch.ones(hidden_size, dtype=torch.float32)) # IN-02: RMSNorm weight is float32 per convention
 self.variance_epsilon = eps
def forward(self, hidden_states):
 variance = hidden_states.pow(2).mean(-1, keepdim=True)
 hidden_states = hidden_states * torch.rsqrt(variance + self.variance_epsilon)
 return self.weight * hidden_states
# ============================================================================
# MLA: Multi-Latent Attention (DeepSeek-V2 style)
# ============================================================================
class SpiderMLA(nn.Module):
 """Multi-Latent Attention with compressed KV cache.
 For hidden_size=2048, num_heads=16:
 - qk_nope_head_dim=64, qk_rope_head_dim=64 -> total head_dim=128
 - kv_lora_rank=128 -> 10.7x compression vs full 2048-dim KV
 - v_head_dim=64 -> value projection
 - sliding_window=8192 -> local attention window
 """
def __init__(self, config: SpiderConfig):
 super().__init__()
 self.config = config
 self.hidden_size = config.hidden_size
 self.num_heads = config.num_attention_heads
 self.kv_lora_rank = config.kv_lora_rank
 self.q_lora_rank = config.q_lora_rank
 self.qk_rope_head_dim = config.qk_rope_head_dim
 self.qk_nope_head_dim = config.qk_nope_head_dim
 self.v_head_dim = config.v_head_dim
 self.head_dim = self.qk_nope_head_dim + self.qk_rope_head_dim
 self.sliding_window = getattr(config, 'sliding_window', 0)
# Q projection: optional low-rank -> full Q
 if self.q_lora_rank > 0:
 self.q_a_proj = nn.Linear(config.hidden_size, self.q_lora_rank, bias=False)
 self.q_a_layernorm = SpiderRMSNorm(self.q_lora_rank)
 self.q_b_proj = nn.Linear(self.q_lora_rank, self.num_heads * self.head_dim, bias=False)
 else:
 self.q_proj = nn.Linear(config.hidden_size, self.num_heads * self.head_dim, bias=False)
# KV compression: hidden -> kv_lora_rank (shared latent)
 self.kv_a_proj_with_mqa = nn.Linear(
 config.hidden_size,
 self.kv_lora_rank + self.qk_rope_head_dim,
 bias=False,
 )
 self.kv_a_layernorm = SpiderRMSNorm(self.kv_lora_rank)
 # Decompress: kv_lora_rank -> nope heads + v heads
 self.kv_b_proj = nn.Linear(
 self.kv_lora_rank,
 self.num_heads * (self.qk_nope_head_dim + self.v_head_dim),
 bias=False,
 )
 # Output projection: [hidden_size, num_heads * v_head_dim]
 # Per D-08 and MLA architecture: o_proj maps from num_heads*v_head_dim back to hidden_size
 self.o_proj = nn.Linear(self.num_heads * self.v_head_dim, config.hidden_size, bias=False)
# RoPE frequencies
 rope_scaling = getattr(config, 'rope_scaling', None)
 if rope_scaling and rope_scaling.get("type") == "yarn":
 factor = rope_scaling.get("factor", 1.0)
 orig_max_pos = rope_scaling.get(
 "original_max_position_embeddings", config.max_position_embeddings
 )
 inv_freq = self._compute_yarn_inv_freq(
 self.qk_rope_head_dim, config.rope_theta, factor, orig_max_pos
 )
 else:
 inv_freq = 1.0 / (
 config.rope_theta
 ** (torch.arange(0, self.qk_rope_head_dim, 2).float() / self.qk_rope_head_dim)
 )
 self.register_buffer("inv_freq", inv_freq, persistent=False)
@staticmethod
 def _compute_yarn_inv_freq(head_dim, rope_theta, factor, orig_max, beta_fast=32.0, beta_slow=1.0):
 dim = head_dim
 orig_inv_freq = 1.0 / (rope_theta ** (torch.arange(0, dim, 2).float() / dim))
 pos_freqs = torch.arange(0, dim, 2).float() / dim
 beta = (pos_freqs * math.log(rope_theta) / math.log(orig_max))
 scale = torch.where(
 beta < beta_slow, torch.ones_like(beta),
 torch.where(
 beta > beta_fast, torch.ones_like(beta) / factor,
 1.0 - (beta - beta_slow) / (beta_fast - beta_slow) * (1.0 - 1.0 / factor)
 )
 )
 return orig_inv_freq * scale
def _rotate_half(self, x):
 x1 = x[..., :x.shape[-1] // 2]
 x2 = x[..., x.shape[-1] // 2:]
 return torch.cat((-x2, x1), dim=-1)
def _apply_rotary(self, x, cos, sin):
 return (x * cos) + (self._rotate_half(x) * sin)
def forward(
 self,
 hidden_states: torch.Tensor,
 attention_mask=None,
 position_ids=None,
 past_key_value=None,
 use_cache=False,
 ):
 bsz, q_len, _ = hidden_states.size()
# Q projection
 if self.q_lora_rank > 0:
 q = self.q_b_proj(self.q_a_layernorm(self.q_a_proj(hidden_states)))
 else:
 q = self.q_proj(hidden_states)
 q = q.view(bsz, q_len, self.num_heads, self.head_dim).transpose(1, 2)
 q_nope, q_rope = torch.split(q, [self.qk_nope_head_dim, self.qk_rope_head_dim], dim=-1)
# KV: compress to latent, then decompress
 kv_hidden = self.kv_a_proj_with_mqa(hidden_states)
 kv_latent, k_rope = torch.split(
 kv_hidden, [self.kv_lora_rank, self.qk_rope_head_dim], dim=-1
 )
 kv_latent_norm = self.kv_a_layernorm(kv_latent)
 kv_b_out = self.kv_b_proj(kv_latent_norm)
 k_nope, v = torch.split(
 kv_b_out,
 [self.num_heads * self.qk_nope_head_dim, self.num_heads * self.v_head_dim],
 dim=-1,
 )
k_nope = k_nope.view(bsz, q_len, self.num_heads, self.qk_nope_head_dim).transpose(1, 2)
 v = v.view(bsz, q_len, self.num_heads, self.v_head_dim).transpose(1, 2)
 k_rope = k_rope.unsqueeze(1) # [B, 1, L, qk_rope_head_dim]
# RoPE on Q and K rope parts
 if position_ids is None:
 position_ids = torch.arange(q_len, device=hidden_states.device).unsqueeze(0).expand(bsz, -1)
 max_pos = position_ids.max().item() + 1
 seq_len = max(max_pos, q_len)
 t = torch.arange(seq_len, device=hidden_states.device, dtype=self.inv_freq.dtype)
 freqs = torch.outer(t, self.inv_freq)
 emb = torch.cat((freqs, freqs), dim=-1)
 cos, sin = emb.cos(), emb.sin()
 cos_full = cos[position_ids].unsqueeze(1)
 sin_full = sin[position_ids].unsqueeze(1)
q_rope = self._apply_rotary(q_rope, cos_full, sin_full)
 k_rope = self._apply_rotary(k_rope, cos_full, sin_full)
# Assemble full K
 k_rope_expanded = k_rope.expand(-1, self.num_heads, -1, -1)
 k_full = torch.cat([k_nope, k_rope_expanded], dim=-1)
 q_full = torch.cat([q_nope, q_rope], dim=-1)
# KV cache
 past_kv = None
 if past_key_value is not None:
 k_full = torch.cat([past_key_value[0], k_full], dim=2)
 v = torch.cat([past_key_value[1], v], dim=2)
 if use_cache:
 past_kv = (k_full, v)
# Attention with SDPA
 attn_mask = None
 if self.sliding_window > 0 and k_full.shape[2] > self.sliding_window:
 kv_len = k_full.shape[2]
 q_positions = torch.arange(kv_len - q_len, kv_len, device=q_full.device)
 k_positions = torch.arange(kv_len, device=q_full.device)
 diff = q_positions.unsqueeze(1) - k_positions.unsqueeze(0)
 causal = diff >= 0
 window = diff < self.sliding_window
 attn_mask = (causal & window).float().unsqueeze(0).unsqueeze(0)
 attn_mask = attn_mask.masked_fill(attn_mask == 0, float('-inf'))
attn_output = F.scaled_dot_product_attention(
 q_full, k_full, v,
 attn_mask=attn_mask,
 dropout_p=self.config.attention_dropout if self.training else 0.0,
 is_causal=(attn_mask is None),
 )
 attn_output = attn_output.transpose(1, 2).contiguous()
 attn_output = attn_output.reshape(bsz, q_len, self.num_heads * self.v_head_dim)
 return self.o_proj(attn_output), past_kv
# ============================================================================
# Engram: Conditional Memory via Scalable Lookup (DeepSeek style)
# ============================================================================
def _tokenizer_compress(token_ids, vocab_size=272):
 """Simulate NFKC + lowercase canonical ID projection.
 Per D-06: vocab_size=272 for byte-level Spider vocab.
 """
 return token_ids % (vocab_size * 77 // 100)
class SpiderEngram(nn.Module):
 """Conditional memory module via NN-gram lookup.
 Applied only at specific recurrent layers (config.engram_layers).
 Ported from SpiderPortalEngram in mythos-fineweb-moe.py.
 """
def __init__(self, config: SpiderConfig):
 super().__init__()
 self.config = config
 self.ngram_orders = list(config.engram_ngram_orders)
 self.num_heads_per_order = config.engram_hash_heads
 self.table_size = config.engram_table_size
 self.d_mem = config.engram_dim
self.total_mem_dim = len(self.ngram_orders) * self.num_heads_per_order * self.d_mem
# Stacked embedding table with offsets: [orders, heads, table_size, d_mem]
 # Per DeepSeek Engram: static memory, offloaded to CPU, accessed via deterministic hash.
 embed_data = torch.randn(len(self.ngram_orders), self.num_heads_per_order, self.table_size, self.d_mem) * 0.02
 if config.engram_offload:
 self.register_buffer("embed", embed_data, persistent=True)
 else:
 self.embed = nn.Parameter(embed_data)
seeds = []
 for _order in self.ngram_orders:
 for h in range(self.num_heads_per_order):
 seeds.append((h + 1) * 2654435761)
 self.register_buffer("hash_seeds", torch.tensor(seeds, dtype=torch.int64), persistent=False)
self.W_k = nn.Linear(self.total_mem_dim, config.hidden_size, bias=False)
 self.W_v = nn.Linear(self.total_mem_dim, config.hidden_size, bias=False)
self.conv = nn.Conv1d(
 config.hidden_size, config.hidden_size,
 kernel_size=config.engram_conv_kernel,
 padding=config.engram_conv_kernel - 1,
 groups=config.hidden_size,
 )
 self.conv_dilation = config.engram_conv_dilation
with torch.no_grad():
 self.conv.weight.zero_()
 if self.conv.bias is not None:
 self.conv.bias.zero_()
self.q_norm = SpiderRMSNorm(config.hidden_size)
 self.k_norm = SpiderRMSNorm(config.hidden_size)
def _compute_hash(self, compressed, n, head_counter, bsz, seq_len):
 """Compute n-gram hash indices (PyTorch-only path, no Numba/CUDA dependency)."""
 pad = torch.zeros(bsz, n - 1, dtype=compressed.dtype, device=compressed.device)
 padded = torch.cat([pad, compressed], dim=1)
 ngrams = torch.stack([padded[:, i : i + seq_len] for i in range(n)], dim=-1)
 h_val = torch.zeros(bsz, seq_len, dtype=torch.int64, device=compressed.device)
 for i in range(n):
 h_val = h_val * 31 + ngrams[:, :, i].to(torch.int64)
 h_val = h_val % self.table_size
 return h_val
def _retrieve(self, token_ids):
 """Retrieve memory vectors for a batch of token sequences."""
 bsz, seq_len = token_ids.shape
 compressed = _tokenizer_compress(token_ids)
# PyTorch fallback (CPU and GPU, no external kernel dependency)
 all_parts = []
 head_counter = 0
 for order_idx, n in enumerate(self.ngram_orders):
 h_val = self._compute_hash(compressed, n, head_counter, bsz, seq_len)
 seeds_slice = self.hash_seeds[head_counter : head_counter + self.num_heads_per_order]
 indices_pt = (h_val.unsqueeze(-1) * seeds_slice.view(1, 1, -1)) % self.table_size
 emb_table = self.embed[order_idx]
 idx = indices_pt.permute(0, 2, 1).unsqueeze(-1).expand(-1, -1, -1, self.d_mem)
 mem = torch.gather(emb_table.unsqueeze(0).expand(bsz, -1, -1, -1), dim=2, index=idx)
 mem = mem.permute(0, 2, 1, 3).reshape(bsz, seq_len, self.num_heads_per_order * self.d_mem)
 all_parts.append(mem)
 head_counter += self.num_heads_per_order
 return torch.cat(all_parts, dim=-1)
def forward(self, hidden_states, token_ids, layer_id: int):
 mem = self._retrieve(token_ids)
q = hidden_states
 k = self.W_k(mem)
 v = self.W_v(mem)
 q_norm = self.q_norm(q)
 k_norm = self.k_norm(k)
 alpha = torch.sigmoid(
 (q_norm * k_norm).sum(dim=-1, keepdim=True) / math.sqrt(q.shape[-1])
 )
 v_gated = alpha * v
 v_gated_t = v_gated.transpose(1, 2)
 conv_out = self.conv(v_gated_t)
 conv_out = conv_out[:, :, :v_gated_t.shape[-1]]
 conv_out = conv_out.transpose(1, 2)
y = F.silu(conv_out) + v_gated
 return y
# ============================================================================
# FFN Expert (SwiGLU)
# ============================================================================
class SpiderExpert(nn.Module):
 """SwiGLU FFN expert for dense layers and MoE shared expert."""
def __init__(self, config: SpiderConfig, intermediate_size=None):
 super().__init__()
 inter_size = intermediate_size or config.intermediate_size
 self.gate_proj = nn.Linear(config.hidden_size, inter_size, bias=False)
 self.up_proj = nn.Linear(config.hidden_size, inter_size, bias=False)
 self.down_proj = nn.Linear(inter_size, config.hidden_size, bias=False)
 self.act_fn = nn.SiLU()
def forward(self, hidden_states):
 return self.down_proj(self.act_fn(self.gate_proj(hidden_states)) * self.up_proj(hidden_states))
# ============================================================================
# Shared-Projection MoE (D-20, D-21: top-2 routing with shared projections)
# ============================================================================
class SimpleMoE(nn.Module):
 """Mixture of Experts with top-1 routing and shared expert.
 Uses TileKernels for fused routing when available.
 """
def __init__(self, config: SpiderConfig):
 super().__init__()
 self.num_experts = config.num_experts
 self.num_experts_per_tok = config.num_experts_per_tok
# Shared expert
 self.shared_expert = SpiderExpert(config, intermediate_size=config.intermediate_size)
# Routed experts
 self.experts = nn.ModuleList([
 SpiderExpert(config, intermediate_size=config.intermediate_size)
 for _ in range(config.num_experts)
 ])
# Router
 self.router = nn.Linear(config.hidden_size, config.num_experts, bias=True)
 self.router.bias = nn.Parameter(torch.zeros(config.num_experts, dtype=torch.float32))
def _forward_tilekernels(self, x: torch.Tensor) -> Tuple[torch.Tensor, torch.Tensor]:
 B, L, D = x.shape
 num_tokens = B * L
shared_out = self.shared_expert(x)
router_logits = self.router(x)
 router_probs = F.softmax(router_logits.float(), dim=-1)
 router_probs_2d = router_probs.reshape(num_tokens, self.num_experts).contiguous()
topk_idx = _tk.moe.topk_gate(router_probs_2d, num_topk=1)
 topk_weights = torch.gather(router_probs_2d, -1, topk_idx)
 _, topk_weights_norm = _tk.moe.normalize_weight(topk_weights)
(pos_to_expert, pos_to_token, pos_to_token_topk,
 token_topk_to_pos, expert_start, expert_end,
 num_tokens_per_expert, ntp_list) = _tk.moe.get_fused_mapping_kernel.get_fused_mapping(
 topk_idx, self.num_experts, num_expanded_tokens=0, alignment=64,
 )
x_flat = x.reshape(num_tokens, D).contiguous()
 x_expanded = _tk.moe.expand_to_fused(x_flat, token_topk_to_pos, pos_to_expert)
expanded_out = torch.empty_like(x_expanded)
 for e in range(self.num_experts):
 es = expert_start[e].item()
 ee = expert_end[e].item()
 if es >= ee:
 continue
 expanded_out[es:ee] = self.experts[e](x_expanded[es:ee])
routed_out = _tk.moe.reduce_fused(expanded_out, topk_weights_norm, token_topk_to_pos)
 routed_out = routed_out.reshape(B, L, D)
z_loss = (router_logits.logsumexp(dim=-1) ** 2).mean()
 return shared_out + routed_out, z_loss
def _forward_python(self, x: torch.Tensor) -> Tuple[torch.Tensor, torch.Tensor]:
 B, L, D = x.shape
shared_out = self.shared_expert(x)
router_logits = self.router(x)
 router_probs = F.softmax(router_logits, dim=-1)
top1_indices = router_probs.argmax(dim=-1)
 top1_probs = router_probs.gather(-1, top1_indices.unsqueeze(-1)).squeeze(-1)
x_flat = x.reshape(B * L, D)
 top1_flat = top1_indices.reshape(B * L)
expert_outs = torch.zeros_like(x_flat)
 for e in range(self.num_experts):
 mask = (top1_flat == e)
 if mask.any():
 expert_input = x_flat[mask]
 expert_out = self.experts[e](expert_input)
 expert_outs[mask] = expert_out
expert_outs = expert_outs.reshape(B, L, D)
 routed_out = expert_outs * top1_probs.unsqueeze(-1)
z_loss = (router_logits.logsumexp(dim=-1) ** 2).mean()
 return shared_out + routed_out, z_loss
def forward(self, x: torch.Tensor) -> Tuple[torch.Tensor, torch.Tensor]:
 if _TK_AVAILABLE and x.is_cuda:
 return self._forward_tilekernels(x)
 return self._forward_python(x)
# ============================================================================
# Shared-Projection MoE (D-20, D-21: top-2 routing with shared projections)
# ============================================================================
class SharedProjectionMoE(nn.Module):
 """Mixture of Experts with shared projections and low-rank expert cores.
 Per D-20: 32 experts, top-2 routing, shared_intermediate_size=6144.
 Per D-21: Shared up/down projections computed once per token, rank-192
 expert cores specialize on the shared representation.
 Architecture:
 - shared_up: Linear(hidden, shared_inter) — computed once for all experts
 - shared_down: Linear(shared_inter, hidden) — computed once for all experts
 - W_gate: [num_experts, hidden, expert_core_rank] — per-expert gating
 - W_transform: [num_experts, expert_core_rank, shared_inter] — per-expert transform
 - shared_expert: SpiderExpert(hidden, shared_expert_inter=4096) — always active
 Forward: shared_hidden = SiLU(shared_up(x))
 routed_out = sum(top2_weights * shared_down(core_i(shared_hidden)))
 output = routed_out + shared_expert(x)
 Uses TileKernels for fused routing (topk_gate, normalize_weight,
 get_fused_mapping, expand_to_fused, reduce_fused, aux_fi) when available.
 Falls back to Python loop otherwise.
 """
def __init__(self, config: SpiderConfig):
 super().__init__()
 self.num_experts = config.num_experts
 self.num_experts_per_tok = config.num_experts_per_tok
 self.shared_inter = config.shared_intermediate_size
 self.expert_core_rank = config.expert_core_rank
 self.hidden_size = config.hidden_size
self.shared_up = nn.Linear(config.hidden_size, config.shared_intermediate_size, bias=False)
 self.shared_down = nn.Linear(config.shared_intermediate_size, config.hidden_size, bias=False)
self.W_gate = nn.Parameter(
 torch.randn(config.num_experts, config.hidden_size, config.expert_core_rank) * 0.02
 )
 self.W_transform = nn.Parameter(
 torch.randn(config.num_experts, config.expert_core_rank, config.shared_intermediate_size) * 0.02
 )
self.shared_expert = SpiderExpert(config, intermediate_size=config.shared_expert_intermediate_size)
self.router = nn.Linear(config.hidden_size, config.num_experts, bias=True)
 self.router.bias = nn.Parameter(torch.zeros(config.num_experts, dtype=torch.float32))
def _forward_tilekernels(self, x: torch.Tensor) -> Tuple[torch.Tensor, torch.Tensor]:
 B, L, D = x.shape
 num_tokens = B * L
shared_hidden = F.silu(self.shared_up(x))
 shared_out = self.shared_expert(x)
router_logits = self.router(x)
 router_probs = F.softmax(router_logits.float(), dim=-1)
 router_probs_2d = router_probs.reshape(num_tokens, self.num_experts).contiguous()
top2_indices = _tk.moe.topk_gate(router_probs_2d, num_topk=self.num_experts_per_tok)
 top2_weights = torch.gather(router_probs_2d, -1, top2_indices)
 _, top2_weights_norm = _tk.moe.normalize_weight(top2_weights)
(pos_to_expert, pos_to_token, pos_to_token_topk,
 token_topk_to_pos, expert_start, expert_end,
 num_tokens_per_expert, ntp_list) = _tk.moe.get_fused_mapping_kernel.get_fused_mapping(
 top2_indices, self.num_experts, num_expanded_tokens=0, alignment=64,
 )
x_flat = x.reshape(num_tokens, D).contiguous()
 sh_flat = shared_hidden.reshape(num_tokens, self.shared_inter).contiguous()
x_expanded = _tk.moe.expand_to_fused(x_flat, token_topk_to_pos, pos_to_expert)
 sh_expanded = _tk.moe.expand_to_fused(sh_flat, token_topk_to_pos, pos_to_expert)
expanded_out = torch.empty_like(x_expanded)
 for e in range(self.num_experts):
 es = expert_start[e].item()
 ee = expert_end[e].item()
 if es >= ee:
 continue
 expert_x = x_expanded[es:ee]
 expert_sh = sh_expanded[es:ee]
 gate = expert_x @ self.W_gate[e]
 core = gate @ self.W_transform[e]
 expanded_out[es:ee] = self.shared_down(core * expert_sh)
routed_out = _tk.moe.reduce_fused(expanded_out, top2_weights_norm, token_topk_to_pos)
 routed_out = routed_out.reshape(B, L, D)
z_loss = (router_logits.logsumexp(dim=-1) ** 2).mean()
return shared_out + routed_out, z_loss
def _forward_python(self, x: torch.Tensor) -> Tuple[torch.Tensor, torch.Tensor]:
 B, L, D = x.shape
shared_hidden = F.silu(self.shared_up(x))
 shared_out = self.shared_expert(x)
router_logits = self.router(x)
 router_probs = F.softmax(router_logits, dim=-1)
top2_probs, top2_indices = router_probs.topk(self.num_experts_per_tok, dim=-1)
 top2_probs = top2_probs / top2_probs.sum(dim=-1, keepdim=True)
x_flat = x.reshape(B * L, D)
 shared_hidden_flat = shared_hidden.reshape(B * L, self.shared_inter)
routed_out = torch.zeros(B * L, D, device=x.device, dtype=x.dtype)
for k in range(self.num_experts_per_tok):
 expert_indices = top2_indices[:, :, k].reshape(B * L)
 expert_weights = top2_probs[:, :, k].reshape(B * L)
for e in range(self.num_experts):
 mask = (expert_indices == e)
 if not mask.any():
 continue
 expert_input = x_flat[mask]
 expert_sh = shared_hidden_flat[mask]
gate = expert_input @ self.W_gate[e]
 core = gate @ self.W_transform[e]
 expert_output = self.shared_down(core * expert_sh)
routed_out[mask] += expert_weights[mask].unsqueeze(-1) * expert_output
routed_out = routed_out.reshape(B, L, D)
z_loss = (router_logits.logsumexp(dim=-1) ** 2).mean()
return shared_out + routed_out, z_loss
def forward(self, x: torch.Tensor) -> Tuple[torch.Tensor, torch.Tensor]:
 if _TK_AVAILABLE and x.is_cuda:
 return self._forward_tilekernels(x)
 return self._forward_python(x)
# ============================================================================
# Prelude/Coda Dense Layer (uses MLA)
# ============================================================================
class SpiderDenseLayer(nn.Module):
 """Prelude/coda dense layer with MLA attention."""
def __init__(self, config: SpiderConfig):
 super().__init__()
 self.self_attn = SpiderMLA(config)
 dense_intermediate = config.prelude_coda_intermediate_size
 self.ffn = SpiderExpert(config, intermediate_size=dense_intermediate)
 self.input_layernorm = SpiderRMSNorm(config.hidden_size, eps=config.rms_norm_eps)
 self.post_attention_layernorm = SpiderRMSNorm(config.hidden_size, eps=config.rms_norm_eps)
def forward(
 self,
 hidden_states,
 attention_mask=None,
 position_ids=None,
 past_key_value=None,
 use_cache=False,
 ):
 attn_input = self.input_layernorm(hidden_states)
 attn_output, past_kv = self.self_attn(
 attn_input, attention_mask=attention_mask,
 position_ids=position_ids,
 past_key_value=past_key_value,
 use_cache=use_cache,
 )
 hidden_states = hidden_states + attn_output
 ffn_input = self.post_attention_layernorm(hidden_states)
 ffn_output = self.ffn(ffn_input)
 hidden_states = hidden_states + ffn_output
 return hidden_states, past_kv
# ============================================================================
# Recurrent Layer (uses MLA + optional Engram + MoE)
# ============================================================================
class SpiderRecurrentLayer(nn.Module):
 """Recurrent layer with MLA attention, optional Engram memory, and MoE."""
def __init__(self, config: SpiderConfig, layer_idx: int, has_engram: bool = False):
 super().__init__()
 self.layer_idx = layer_idx
 self.has_engram = has_engram
 self.self_attn = SpiderMLA(config)
 if has_engram:
 self.engram = SpiderEngram(config)
 self.moe = SharedProjectionMoE(config)
 self.input_layernorm = SpiderRMSNorm(config.hidden_size, eps=config.rms_norm_eps)
 self.post_attention_layernorm = SpiderRMSNorm(config.hidden_size, eps=config.rms_norm_eps)
 self.post_engram_layernorm = (
 SpiderRMSNorm(config.hidden_size, eps=config.rms_norm_eps)
 if has_engram else None
 )
def forward(
 self,
 hidden_states,
 token_ids=None,
 attention_mask=None,
 position_ids=None,
 past_key_value=None,
 use_cache=False,
 ):
 attn_input = self.input_layernorm(hidden_states)
 attn_output, past_kv = self.self_attn(
 attn_input, attention_mask=attention_mask,
 position_ids=position_ids,
 past_key_value=past_key_value,
 use_cache=use_cache,
 )
 hidden_states = hidden_states + attn_output
if self.has_engram and token_ids is not None:
 engram_out = self.engram(hidden_states, token_ids, layer_id=self.layer_idx)
 hidden_states = hidden_states + engram_out
 if self.post_engram_layernorm is not None:
 hidden_states = self.post_engram_layernorm(hidden_states)
ffn_input = self.post_attention_layernorm(hidden_states)
 ffn_output, aux_loss = self.moe(ffn_input)
 hidden_states = hidden_states + ffn_output
 return hidden_states, aux_loss, past_kv
# ============================================================================
# BoundaryPredictor (D-04, D-11)
# ============================================================================
class BoundaryPredictor(nn.Module):
 """Boundary predictor for learnable byte-level tokenization.
 2-layer MLP that predicts merge boundaries between tokens.
 Per D-11: When modality_mask is provided, forces boundary=1.0 at
 sentinel and modality token positions, preventing cross-modality merges.
 Architecture: Linear(d_model, d_inner) -> GELU -> Linear(d_inner, 1)
 Uses Gumbel-Softmax straight-through estimator for differentiable
 boundary decisions (ported from FLEXITOKENS fxt.py).
 """
def __init__(
 self,
 config: SpiderConfig,
 temp: float = 1.0,
 threshold: float = 0.5,
 ):
 super().__init__()
 self.temp = temp
 self.threshold = threshold
self.boundary_predictor = nn.Sequential(
 nn.Linear(config.hidden_size, config.bp_d_inner),
 nn.GELU(),
 nn.Linear(config.bp_d_inner, 1),
 )
def forward(self, hidden, modality_mask=None):
 """Predict boundary decisions for token merging.
 Args:
 hidden: Hidden states of shape [B, L, D] (batch-first per D-08).
 modality_mask: Optional boolean tensor [B, L], True at positions
 where sentinel/modality tokens appear. Per D-11,
 forces boundary=1.0 at these positions.
 Returns:
 Tuple of (soft_boundaries, hard_boundaries), each [B, L].
 - soft_boundaries: Differentiable boundary probabilities
 - hard_boundaries: Binary boundary decisions (straight-through)
 """
 boundary_logits = self.boundary_predictor(hidden).squeeze(-1)
 boundary_probs = torch.sigmoid(boundary_logits)
# Gumbel-Softmax straight-through for differentiable boundary decisions
 bernoulli = torch.distributions.relaxed_bernoulli.RelaxedBernoulli(
 temperature=self.temp,
 probs=boundary_probs,
 )
 soft_boundaries = bernoulli.rsample()
hard_boundaries = (soft_boundaries > self.threshold).float()
 # Straight-through estimator: gradient flows through soft, forward uses hard
 hard_boundaries = (
 hard_boundaries - soft_boundaries.detach() + soft_boundaries
 )
# Per D-11: Force boundaries at sentinel/modality positions
 if modality_mask is not None:
 soft_boundaries = soft_boundaries.masked_fill(modality_mask, 1.0)
 hard_boundaries = hard_boundaries.masked_fill(modality_mask, 1.0)
return soft_boundaries, hard_boundaries
# ============================================================================
# Downsample / Upsample (D-05, D-08, D-11)
# ============================================================================
def _downsample_common(boundaries: torch.Tensor, upsample: bool = False):
 """Common helper for downsample/upsample einsum weight computation.
 Computes the assignment matrix that maps original positions to groups.
 Based on FLEXITOKENS shortening.py, adapted for batch-first (B*L*D) layout.
 Args:
 boundaries: [B, L] binary boundary tensor (1 = new group starts)
 upsample: If True, compute upsample weights; else downsample weights
 Returns:
 Assignment tensor [B, L, S] or None if n_segments == 0
 """
 boundaries = boundaries.clone()
 n_segments = int(boundaries.sum(dim=-1).max().item())
if upsample:
 n_segments += 1
if n_segments == 0:
 return None
tmp = torch.zeros_like(boundaries).unsqueeze(2) + torch.arange(
 start=0, end=n_segments, device=boundaries.device, dtype=boundaries.dtype
 )
 hh1 = boundaries.cumsum(dim=-1)
if not upsample:
 hh1 -= boundaries # Subtract current boundary so position belongs to previous group
foo = tmp - hh1.unsqueeze(-1)
# WR-01 fix: zero out unused columns for batch items with fewer segments
 # When n_segments is set to the max across the batch, items with fewer
 # segments have unused columns that would produce NaN on normalization.
 item_segment_counts = boundaries.sum(dim=-1)
 for b in range(boundaries.shape[0]):
 item_segs = int(item_segment_counts[b].item())
 if upsample:
 item_segs += 1
 if item_segs < n_segments:
 foo[b, :, item_segs:] = 0
return foo
def _downsample_final(foo: torch.Tensor, upsample: bool = False) -> torch.Tensor:
 """Normalize assignment weights for downsample/upsample einsum."""
 autoregressive = foo != 0
 lel = 1.0 - foo.float()
 lel[autoregressive] = 0.0
 dim = 2 if upsample else 1
 lel = lel / (lel.sum(dim=dim, keepdim=True) + 1e-9)
 return lel.to(foo.dtype)
def downsample(boundaries: torch.Tensor, hidden: torch.Tensor, null_group: torch.Tensor) -> torch.Tensor:
 """Downsample hidden states using boundary decisions.
 Per D-05: Exact einsum port from FLEXITOKENS shortening.py.
 Per D-08: Batch-first layout [B, L, D].
 Per D-11: Sentinel tokens forced to boundary=1 by modality_mask ->
 downsample treats each sentinel+modality group as a separate merge
 group -> groups appear intact in shortened sequence.
 Args:
 boundaries: [B, L] binary boundary tensor (1 = new group starts)
 hidden: [B, L, D] hidden states (batch-first per D-08)
 null_group: [1, B, D] null group token prepended to output
 Returns:
 shortened_hidden: [S, B, D] shortened sequence (LBD format for
 compatibility with FLEXITOKENS upsample which expects SBD input)
 """
 foo = _downsample_common(boundaries, upsample=False)
 if foo is None:
 return null_group.repeat(1, hidden.size(0), 1)
 else:
 bar = _downsample_final(foo, upsample=False)
 # Einsum: B*L*D @ B*L*S -> B*S*D, then transpose to S*B*D
 shortened_hidden = torch.einsum('bld,bls->bsd', hidden, bar.to(hidden.dtype))
 shortened_hidden = shortened_hidden.permute(1, 0, 2)
 # Prepend null_group: [1, B, D] -> cat along dim=0 -> [S+1, B, D]
 shortened_hidden = torch.cat([null_group, shortened_hidden], dim=0)
 return shortened_hidden
def upsample(boundaries: torch.Tensor, shortened_hidden: torch.Tensor) -> torch.Tensor:
 """Upsample shortened hidden states back to original sequence length.
 Per D-05: Exact einsum port from FLEXITOKENS shortening.py.
 Per D-08: Batch-first layout.
 Args:
 boundaries: [B, L] binary boundary tensor
 shortened_hidden: [S, B, D] shortened sequence
 Returns:
 upsampled_hidden: [B, L, D] upsampled sequence
 """
 foo = _downsample_common(boundaries, upsample=True)
 bar = _downsample_final(foo, upsample=True)
 upsampled_hidden = torch.einsum('sbd,bls->bld', shortened_hidden, bar.to(shortened_hidden.dtype))
 return upsampled_hidden
# ============================================================================
# LTI Injection, ACT Halting, LoRA Adapter
# ============================================================================
class LTIInjection(nn.Module):
 """Linear Time-Invariant injection module."""
def __init__(self, config: SpiderConfig):
 super().__init__()
 self.hidden_size = config.hidden_size
 self.log_A = nn.Parameter(torch.full((config.hidden_size,), -2.0))
 self.delta_t = nn.Parameter(torch.tensor(1.0))
 self.B = nn.Linear(config.hidden_size, config.hidden_size, bias=False)
 with torch.no_grad():
 self.B.weight.data.normal_(mean=0.0, std=0.01)
def get_A(self):
 return -torch.exp(self.log_A)
def forward(self, h_t, e):
 A = self.get_A()
 return A * h_t + self.B(e)
class ACTHalting(nn.Module):
 """Adaptive Computation Time halting module."""
def __init__(self, config: SpiderConfig):
 super().__init__()
 self.halt_predictor = nn.Linear(config.hidden_size, 1)
 self.threshold = config.act_threshold
def forward(self, hidden_states):
 return torch.sigmoid(self.halt_predictor(hidden_states))
class LoRAAdapter(nn.Module):
 """LoRA adapter for per-loop adaptation in recurrent layers.
 Per CR-01 fix: up-projection (self.B) is initialized to EXACTLY ZERO
 so that LoRA adapter output is zero at initialization -- meaning the
 model starts behaving identically to the base model. This follows
 standard LoRA convention (Hu et al., 2021).
 """
def __init__(self, config: SpiderConfig):
 super().__init__()
 rank = config.lora_rank
 self.down = nn.Linear(config.hidden_size, rank, bias=False)
 self.B = nn.Parameter(torch.zeros(rank, config.hidden_size, dtype=torch.float32)) # CR-01 fix: zeros, not randn*0.02; IN-02
 self.scale = nn.Embedding(config.max_loop_iters, rank)
 with torch.no_grad():
 self.scale.weight.data.zero_()
 self.down.weight.data.normal_(mean=0.0, std=0.001)
def forward(self, x, loop_t):
 max_t = self.scale.num_embeddings - 1
 t_idx = min(loop_t, max_t)
 s = self.scale(torch.tensor(t_idx, device=x.device))
 down = self.down(x) * s
 return down @ self.B
def _loop_index_embedding(h, loop_t, loop_dim, theta=10000.0):
 """Sinusoidal loop index embedding for RDT depth differentiation."""
 freqs = 1.0 / (theta ** (torch.arange(0, loop_dim, 2, device=h.device, dtype=h.dtype) / loop_dim))
 angles = loop_t * freqs
 emb = torch.cat([angles.sin(), angles.cos()], dim=-1)[:loop_dim]
 emb_full = torch.zeros(h.shape[-1], device=h.device, dtype=h.dtype)
 emb_full[:loop_dim] = emb
 return h + emb_full.unsqueeze(0).unsqueeze(0)
def _checkpoint(func, *args, **kwargs):
 """Gradient checkpointing wrapper -- saves VRAM at ~20% compute cost."""
 if torch.is_grad_enabled():
 return torch.utils.checkpoint.checkpoint(func, *args, use_reentrant=False, **kwargs)
 return func(*args, **kwargs)
# ============================================================================
# Full Spider Model (with FlexiToken integration)
# ============================================================================
class SpiderModel(nn.Module):
 """Full RDT model with MLA attention + Engram memory + FlexiToken.
 Architecture:
 2x Prelude (MLA + dense FFN)
 6x Recurrent (MLA + Engram@L1,L4 + MoE) -- with gradient checkpointing
 2x Coda (MLA + dense FFN)
 LTI Injection + ACT Halting + LoRA Adapter
 BoundaryPredictor + downsample/upsample for FlexiToken
 """
def __init__(self, config: SpiderConfig):
 super().__init__()
 self.config = config
 self.prelude_layers = nn.ModuleList([
 SpiderDenseLayer(config) for _ in range(config.prelude_layers)
 ])
 self.recurrent_layers = nn.ModuleList([
 SpiderRecurrentLayer(config, i, has_engram=(i in config.engram_layers))
 for i in range(config.num_hidden_layers)
 ])
 self.coda_layers = nn.ModuleList([
 SpiderDenseLayer(config) for _ in range(config.coda_layers)
 ])
 self.norm = SpiderRMSNorm(config.hidden_size, eps=config.rms_norm_eps)
 self.injection = LTIInjection(config)
 self.act_halting = ACTHalting(config)
 self.lora_adapter = LoRAAdapter(config)
 self.loop_embed_dim = config.loop_embed_dim
 self._gradient_checkpointing = False
def gradient_checkpointing_enable(self):
 self._gradient_checkpointing = True
def gradient_checkpointing_disable(self):
 self._gradient_checkpointing = False
def forward(
 self,
 hidden_states,
 input_embedding=None,
 attention_mask=None,
 position_ids=None,
 past_key_values=None,
 use_cache=False,
 n_loops=None,
 token_ids=None,
 hard_boundaries=None,
 ):
 n_loops = n_loops or 1
 input_embedding = input_embedding if input_embedding is not None else hidden_states
# Prelude layers
 for layer in self.prelude_layers:
 if self._gradient_checkpointing and torch.is_grad_enabled():
 hidden_states, _ = _checkpoint(
 layer, hidden_states,
 attention_mask=attention_mask,
 position_ids=position_ids,
 )
 else:
 hidden_states, _ = layer(
 hidden_states, attention_mask=attention_mask,
 position_ids=position_ids,
 )
# FlexiToken: if hard_boundaries provided, downsample before recurrent core
 if hard_boundaries is not None:
 # Apply norm before downsample
 hidden_normed = self.norm(hidden_states)
 null_group = torch.zeros(
 1, hidden_states.shape[0], hidden_states.shape[-1],
 device=hidden_states.device, dtype=hidden_states.dtype,
 )
 shortened = downsample(hard_boundaries, hidden_normed, null_group)
 # shortened: [S, B, D] -> [B, S, D]
 hidden_states = shortened.permute(1, 0, 2)
# Shorten token_ids to match downsampled sequence length.
 # Take the first token in each boundary group so the Engram
 # hash-based lookup gets a representative token per group.
 # hard_boundaries: [B, L], cumsum gives group index per position.
 # Pick the first position (where boundary=1) of each group.
 if token_ids is not None:
 group_ids = hard_boundaries.cumsum(dim=-1) # [B, L], 1-based group indices
 n_groups = int(group_ids.max().item()) # number of groups
 B = hard_boundaries.shape[0]
 # For each group g (1..n_groups), find the first position where group_ids == g
 short_ids = torch.zeros(B, n_groups, device=token_ids.device, dtype=token_ids.dtype)
 for g in range(1, n_groups + 1):
 # mask of positions belonging to group g
 mask = (group_ids == g)
 # first position in group g
 first_pos = mask.float().argmax(dim=-1) # [B]
 short_ids[:, g - 1] = token_ids.gather(1, first_pos.unsqueeze(1)).squeeze(1)
 # Prepend a dummy token (0) for the null_group entry
 null_token = torch.zeros(B, 1, device=token_ids.device, dtype=token_ids.dtype)
 token_ids = torch.cat([null_token, short_ids], dim=1) # [B, S+1]
# After downsample, input_embedding must match the shortened sequence length
 input_embedding = hidden_states.clone()
# Recurrent core with RDT looping
 e = hidden_states.clone()
 B, T_seq, D = hidden_states.shape
 halted = torch.zeros(B, T_seq, device=hidden_states.device, dtype=torch.bool)
 cumulative_p = torch.zeros(B, T_seq, device=hidden_states.device, dtype=hidden_states.dtype)
 h_out = torch.zeros_like(hidden_states)
 total_aux_loss = 0.0
 past_key_values = past_key_values if past_key_values is not None else [None] * len(self.recurrent_layers)
for t in range(n_loops):
 h_loop = _loop_index_embedding(hidden_states, t, self.loop_embed_dim)
 if t > 0:
 injection = self.injection(hidden_states, input_embedding)
 hidden_states = hidden_states + injection
new_past_key_values = []
 for i, layer in enumerate(self.recurrent_layers):
 hidden_states, aux_loss, past_kv = _checkpoint(
 layer, hidden_states,
 token_ids=token_ids,
 attention_mask=attention_mask,
 position_ids=position_ids,
 past_key_value=past_key_values[i] if t == 0 else None,
 use_cache=use_cache,
 )
 total_aux_loss = total_aux_loss + aux_loss
 new_past_key_values.append(past_kv)
lora_delta = self.lora_adapter(hidden_states, t)
 hidden_states = hidden_states + lora_delta
halt_prob = self.act_halting(hidden_states).squeeze(-1)
 still_running = ~halted
 remainder = (1.0 - cumulative_p).clamp(min=0)
 weight = torch.where(
 cumulative_p + halt_prob >= self.config.act_threshold,
 remainder, halt_prob,
 )
 weight = weight * still_running.to(hidden_states.dtype)
 h_out = h_out + weight.unsqueeze(-1) * hidden_states
 cumulative_p = cumulative_p + halt_prob * still_running.to(hidden_states.dtype)
 halted = halted | (cumulative_p >= self.config.act_threshold)
 if halted.all() and not self.training:
 break
never_halted = (~halted).to(hidden_states.dtype).unsqueeze(-1)
 hidden_states = h_out + never_halted * hidden_states
# FlexiToken: if hard_boundaries provided, upsample after recurrent core
 if hard_boundaries is not None:
 hidden_states_sbd = hidden_states.permute(1, 0, 2) # [S, B, D]
 hidden_states = upsample(hard_boundaries, hidden_states_sbd) # [B, L, D]
# Coda layers
 for layer in self.coda_layers:
 if self._gradient_checkpointing and torch.is_grad_enabled():
 hidden_states, _ = _checkpoint(
 layer, hidden_states,
 attention_mask=attention_mask,
 position_ids=position_ids,
 )
 else:
 hidden_states, _ = layer(
 hidden_states, attention_mask=attention_mask,
 position_ids=position_ids,
 )
hidden_states = self.norm(hidden_states)
 return hidden_states, total_aux_loss, new_past_key_values
# ============================================================================
# SpiderForConditionalGeneration
# ============================================================================
class SpiderForConditionalGeneration(nn.Module):
 """Spider model with embedding, LM head, and FlexiToken boundary prediction.
 Forward flow:
 1. embed_tokens(input_ids) -> hidden_states
 2. Inject modality features at sentinel positions
 3. Prelude layers
 4. BoundaryPredictor with modality_mask -> boundaries
 5. SpiderModel (downsample -> recurrent -> upsample -> coda)
 6. lm_head -> logits
 """
def __init__(self, config: SpiderConfig):
 super().__init__()
 self.config = config
 self.embed_tokens = nn.Embedding(config.vocab_size, config.hidden_size)
 self.boundary_predictor = BoundaryPredictor(config)
 self.model = SpiderModel(config)
 self.lm_head = nn.Linear(config.hidden_size, config.vocab_size, bias=False)
 if config.tie_word_embeddings:
 self.lm_head.weight = self.embed_tokens.weight
 self.apply(self._init_weights)
def gradient_checkpointing_enable(self):
 self.model.gradient_checkpointing_enable()
def gradient_checkpointing_disable(self):
 self.model.gradient_checkpointing_disable()
def enable_input_require_grads(self):
 def _make_inputs_require_grad(module, input, output):
 output.requires_grad_(True)
 self.embed_tokens.register_forward_hook(_make_inputs_require_grad)
def _init_weights(self, module):
 if isinstance(module, nn.Linear):
 if hasattr(self, 'model') and module is self.model.injection.B:
 return # LTI injection B has its own init
 module.weight.data.normal_(mean=0.0, std=self.config.initializer_range)
 if module.bias is not None:
 module.bias.data.zero_()
 elif isinstance(module, nn.Embedding):
 module.weight.data.normal_(mean=0.0, std=self.config.initializer_range)
def _inject_modality_features(
 self,
 hidden_states: torch.Tensor,
 input_ids: torch.Tensor,
 features: list,
 modality: str = 'IMG',
 ) -> torch.Tensor:
 """Replace placeholder embeddings with actual encoder features at modality regions.
 Per D-11: Modality tokens (vision, audio, video) are injected at
 sentinel-marked positions. Between sentinel pairs, the initial
 embeddings are placeholders -- this method replaces them with the
 actual encoder features.
 T-02-06 mitigation: Validates feature shape and sentinel pair count.
 """
 start_token = SENTINEL_TOKENS[f'{modality}_START']
 end_token = SENTINEL_TOKENS[f'{modality}_END']
for b in range(hidden_states.shape[0]):
 starts = (input_ids[b] == start_token).nonzero(as_tuple=True)[0]
 ends = (input_ids[b] == end_token).nonzero(as_tuple=True)[0]
if len(starts) != len(ends):
 raise ValueError(
 f"Batch {b}: mismatched {modality} sentinel pairs -- "
 f"{len(starts)} {_TOKEN_NAMES_BY_ID[start_token]}(s) vs "
 f"{len(ends)} {_TOKEN_NAMES_BY_ID[end_token]}(s)."
 )
 if len(starts) != len(features):
 raise ValueError(
 f"Batch {b}: {modality} sentinel pair count ({len(starts)}) "
 f"doesn't match feature count ({len(features)})."
 )
for s, e, feat in zip(starts, ends, features):
 num_tokens = e - s - 1
 if feat.shape[0] != num_tokens:
 raise ValueError(
 f"Batch {b}: {modality} feature has {feat.shape[0]} tokens "
 f"but sentinel region has {num_tokens} positions "
 f"(from pos {s+1} to {e-1})."
 )
 if feat.shape[1] != hidden_states.shape[-1]:
 raise ValueError(
 f"Batch {b}: {modality} feature hidden_size {feat.shape[1]} "
 f"doesn't match model hidden_size {hidden_states.shape[-1]}."
 )
 hidden_states[b, s + 1:e] = feat.to(hidden_states.dtype)
return hidden_states
def forward(
 self,
 input_ids: torch.Tensor,
 attention_mask=None,
 position_ids=None,
 labels=None,
 n_loops=None,
 use_cache=False,
 vision_features=None,
 audio_features=None,
 video_features=None,
 **kwargs,
 ):
 hidden_states = self.embed_tokens(input_ids)
 model_dtype = next(self.model.parameters()).dtype
 hidden_states = hidden_states.to(model_dtype)
 input_embedding = hidden_states.clone()
# Inject modality features at sentinel positions
 if vision_features is not None:
 hidden_states = self._inject_modality_features(
 hidden_states, input_ids, vision_features, 'IMG'
 )
 if audio_features is not None:
 hidden_states = self._inject_modality_features(
 hidden_states, input_ids, audio_features, 'AUD'
 )
 if video_features is not None:
 hidden_states = self._inject_modality_features(
 hidden_states, input_ids, video_features, 'VID'
 )
# Create modality mask and predict boundaries
 modality_mask = create_modality_mask(input_ids, strict=(labels is not None))
 soft_boundaries, hard_boundaries = self.boundary_predictor(
 hidden_states, modality_mask=modality_mask
 )
# Run model with FlexiToken boundaries
 hidden_states, aux_loss, past_kv = self.model(
 hidden_states,
 input_embedding=input_embedding,
 attention_mask=None,
 position_ids=position_ids,
 use_cache=use_cache,
 n_loops=n_loops,
 token_ids=input_ids,
 hard_boundaries=hard_boundaries,
 )
logits = self.lm_head(hidden_states)
 loss = None
 if labels is not None:
 shift_logits = logits[..., :-1, :].contiguous()
 shift_labels = labels[..., 1:].contiguous()
 loss_fct = CrossEntropyLoss()
 loss = loss_fct(shift_logits.view(-1, shift_logits.size(-1)), shift_labels.view(-1))
return {
 "loss": loss,
 "logits": logits,
 "aux_loss": aux_loss,
 "past_key_values": past_kv,
 "soft_boundaries": soft_boundaries,
 "hard_boundaries": hard_boundaries,
 }
@torch.inference_mode()
 def generate(
 self,
 input_ids: torch.Tensor,
 max_new_tokens: int = 100,
 temperature: float = 1.0,
 top_k: Optional[int] = None,
 n_loops: int = 1,
 use_cache: bool = True,
 boundary_mode: str = 'adaptive',
 ) -> torch.Tensor:
 """Token-level generation with compressed-prefix KV cache per D-28.
 Strategy: Encode the prefix through prelude + BP + downsample to get
 a compressed KV cache, then autoregressively decode byte-by-byte using
 that cached prefix. The speedup comes from the prefix being shorter in
 the KV cache (~3.3x fewer entries for English text).
 Flow:
 1. Embed prefix → prelude layers → BP → downsample → recurrent core
 → collect KV cache for compressed prefix
 2. Coda + lm_head on last position → sample first new byte
 3. For each subsequent byte: embed → recurrent (with KV cache) → coda
 → lm_head → sample → append
 4. Stop at max_new_tokens or EOS
 Args:
 input_ids: Prefix token IDs [B, L] (byte values 0-255 + BOS/EOS)
 max_new_tokens: Maximum number of new bytes to generate
 temperature: Sampling temperature (0 = greedy, 1.0 = default)
 top_k: If set, only sample from top-k logits
 n_loops: Number of recurrent loops during generation
 use_cache: Use KV cache for incremental decoding
 boundary_mode: 'adaptive' (threshold) or 'fixed' (top-k) for BP
 Returns:
 Generated token IDs [B, N] where N ≤ max_new_tokens
 """
 B = input_ids.shape[0]
 device = input_ids.device
 model_dtype = next(self.model.parameters()).dtype
# --- Step 1: Encode prefix and collect KV cache ---
 hidden_states = self.embed_tokens(input_ids).to(model_dtype)
# Prelude layers (byte-level, no compression)
 for layer in self.model.prelude_layers:
 hidden_states, _ = layer(hidden_states)
# Boundary prediction on prefix (strict=False for generation)
 modality_mask = create_modality_mask(input_ids, strict=False)
 soft_boundaries, hard_boundaries = self.boundary_predictor(
 hidden_states, modality_mask=modality_mask
 )
# Apply boundary mode
 if boundary_mode == 'adaptive':
 hard_boundaries = (soft_boundaries > 0.5).float()
 hard_boundaries = hard_boundaries - soft_boundaries.detach() + soft_boundaries
 elif boundary_mode == 'fixed':
 k = max(1, int(soft_boundaries.shape[-1] / 3.3))
 topk_vals, topk_idx = soft_boundaries.topk(k, dim=-1)
 hard_boundaries = torch.zeros_like(soft_boundaries)
 hard_boundaries.scatter_(-1, topk_idx, 1.0)
 hard_boundaries = hard_boundaries - soft_boundaries.detach() + soft_boundaries
# Downsample prefix for compressed KV cache
 hidden_normed = self.model.norm(hidden_states)
 null_group = torch.zeros(
 1, B, hidden_states.shape[-1], device=device, dtype=hidden_states.dtype
 )
 shortened = downsample(hard_boundaries, hidden_normed, null_group)
 hidden_states = shortened.permute(1, 0, 2) # [B, S, D]
 input_embedding = hidden_states.clone()
# Run through recurrent core + coda (hard_boundaries=None skips downsample/upsample)
 hidden_states, _, past_key_values = self.model(
 hidden_states,
 input_embedding=input_embedding,
 use_cache=use_cache,
 n_loops=n_loops,
 hard_boundaries=None,
 )
# Get logits for last position of prefix (norm + lm_head only, coda already applied)
 logits = self.lm_head(hidden_states[:, -1:, :]) # [B, 1, vocab]
 next_token = self._sample_token(logits, temperature, top_k) # [B, 1]
generated = [next_token]
# --- Step 2: Autoregressive byte-level decoding with KV cache ---
 for _ in range(max_new_tokens - 1):
 # Check EOS
 if (next_token == SENTINEL_TOKENS['EOS']).all():
 break
# Embed the last generated token
 hidden_states = self.embed_tokens(next_token).to(model_dtype) # [B, 1, D]
 input_embedding = hidden_states.clone()
if use_cache:
 # Incremental forward: 1 new token, cached prefix in past_key_values
 hidden_states, _, past_key_values = self.model(
 hidden_states,
 input_embedding=input_embedding,
 past_key_values=past_key_values,
 use_cache=True,
 n_loops=n_loops,
 hard_boundaries=None,
 )
 else:
 # Naive: re-run full forward from scratch (no KV cache)
 all_ids = torch.cat([input_ids, torch.cat(generated, dim=1)], dim=1)
 output = self.forward(
 all_ids, n_loops=n_loops, use_cache=False,
 )
 logits_full = output['logits']
 next_logits = logits_full[:, -1, :] / max(temperature, 1e-8)
 if top_k is not None and top_k > 0:
 v, _ = torch.topk(next_logits, min(top_k, next_logits.size(-1)))
 next_logits = next_logits.masked_fill(next_logits < v[:, [-1]], float('-inf'))
 if temperature < 1e-8:
 next_token = next_logits.argmax(dim=-1, keepdim=True)
 else:
 probs = torch.softmax(next_logits, dim=-1)
 next_token = torch.multinomial(probs, num_samples=1)
 generated.append(next_token)
 continue
# lm_head on last position (coda + norm already applied by self.model)
 logits = self.lm_head(hidden_states[:, -1:, :]) # [B, 1, vocab]
 next_token = self._sample_token(logits, temperature, top_k)
 generated.append(next_token)
return torch.cat(generated, dim=1) # [B, N]
@staticmethod
 def _sample_token(logits: torch.Tensor, temperature: float, top_k: Optional[int]) -> torch.Tensor:
 """Sample next token from logits with temperature and top-k."""
 logits = logits.squeeze(1) # [B, vocab]
 if temperature < 1e-8:
 return logits.argmax(dim=-1, keepdim=True) # greedy
 logits = logits / temperature
 if top_k is not None and top_k > 0:
 v, _ = torch.topk(logits, min(top_k, logits.size(-1)))
 logits = logits.masked_fill(logits < v[:, [-1]], float('-inf'))
 probs = torch.softmax(logits, dim=-1)
 return torch.multinomial(probs, num_samples=1) # [B, 1]
def get_num_params(self):
 total = sum(p.numel() for p in self.parameters())
 return {"total": total, "trainable": total}