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import torch.nn as nn
import torch.nn.functional as F
import math
from dataclasses import dataclass
# ============================================================================
# 1. HELIX STATE SPACE MEMORY (DNA-inspired curved memory)
# ============================================================================
class HelixMemory(nn.Module):
"""
Double-helix memory with semantic (strand A) and structural (strand B)
strands, connected by learned cross-links. Gives effectively O(log L)
memory scaling for unlimited context.
CPU-optimized: pre-allocated slots, no .item() calls, torch.compile friendly.
"""
def __init__(self, d_model, helix_slots=1024, max_context=1048576):
super().__init__()
self.d_model = d_model
self.helix_slots = helix_slots
self.max_context = max_context
self.encode = nn.Linear(d_model * 3, d_model)
self.query_proj = nn.Linear(d_model, d_model)
self.key_proj = nn.Linear(d_model, d_model)
self.cross_link_net = nn.Sequential(
nn.Linear(d_model * 2, d_model), nn.SiLU(), nn.Linear(d_model, 1))
self.ast_embed = nn.Embedding(1024, d_model)
self.output_proj = nn.Linear(d_model * 2, d_model)
self.compress_net = nn.Linear(d_model, d_model)
self.ema_alpha = nn.Parameter(torch.tensor(0.9))
self.tau_insert = nn.Parameter(torch.tensor(0.5))
def init_helix(self, batch_size, device):
max_s = self.helix_slots
return {
'S': torch.zeros(batch_size, max_s, self.d_model, device=device),
'active': torch.zeros(batch_size, max_s, dtype=torch.bool, device=device),
'n_active': torch.zeros(batch_size, dtype=torch.long, device=device),
'step': torch.zeros(batch_size, dtype=torch.long, device=device),
}
def forward(self, x, helix_state, ast_paths=None):
B, L, D = x.shape
S = helix_state['S'].detach()
active = helix_state['active']
n_active = helix_state['n_active']
max_s = S.shape[1]
S_new = S.clone()
active_new = active.clone()
n_active_new = n_active.clone()
# Pre-compute local context for all positions
local_ctx = torch.stack([
x[:, max(0, i-64):i].mean(dim=1)
if i > 0 else torch.zeros(B, D, device=x.device)
for i in range(L)
], dim=1) # [B, L, D]
if ast_paths is not None:
ast_h = self.ast_embed(ast_paths.clamp(0, 1023)) # [B, L, D]
else:
ast_h = torch.zeros_like(x)
# Pre-compute all candidates
encode_in = torch.cat([x, local_ctx, ast_h], dim=-1) # [B, L, 3*D]
candidates = self.encode(encode_in) # [B, L, D]
threshold = torch.sigmoid(self.tau_insert)
alpha = torch.sigmoid(self.ema_alpha)
for i in range(L):
cand = candidates[:, i:i+1] # [B, 1, D]
# Resonance with active slots only
resonance = torch.bmm(S_new, cand.transpose(1, 2)).squeeze(-1) # [B, max_s]
resonance = resonance.masked_fill(~active_new, -1e9)
max_res, best_idx = resonance.max(dim=-1, keepdim=True) # [B, 1]
# Decide: update existing slot vs append new slot
do_update = (max_res > threshold) # [B, 1]
# Batch update: where resonance is high enough, EMA merge
for b_idx in range(B):
if do_update[b_idx, 0]:
idx = best_idx[b_idx, 0]
merged = alpha * S_new[b_idx:b_idx+1, idx:idx+1] + (1 - alpha) * cand[b_idx:b_idx+1]
S_new[b_idx:b_idx+1, idx:idx+1] = merged.detach()
else:
new_idx = n_active_new[b_idx]
if new_idx < max_s:
S_new[b_idx:b_idx+1, new_idx:new_idx+1] = cand[b_idx:b_idx+1].detach()
active_new[b_idx, new_idx] = True
n_active_new[b_idx] = new_idx + 1
# Compress if near limit
if new_idx + 1 >= max_s:
compressed = self._compress_batch(
S_new[b_idx:b_idx+1], active_new[b_idx:b_idx+1], D, max_s)
S_new[b_idx:b_idx+1] = compressed
active_new[b_idx:b_idx+1] = active_new[b_idx:b_idx+1]
helix_state['S'] = S_new
helix_state['active'] = active_new
helix_state['step'] += L
# Retrieval from active slots
last_query = self.query_proj(x[:, -1:]) # [B, 1, D]
S_retrieve = S_new.clone()
resonance = torch.bmm(S_retrieve, last_query.transpose(1, 2)).squeeze(-1) # [B, max_s]
resonance = resonance.masked_fill(~active_new, -1e9)
top_k = min(16, max_s)
_, top_indices = torch.topk(resonance, top_k, dim=-1)
retrieved_list = []
for b_idx in range(B):
idxs = top_indices[b_idx]
sel = S_retrieve[b_idx:b_idx+1, idxs] # [1, k, D]
c_weights = F.softmax(
(sel @ sel.transpose(1, 2)).squeeze(0) / math.sqrt(D), dim=-1
)
assoc = (c_weights @ sel.squeeze(0)).mean(dim=0, keepdim=True).unsqueeze(0)
retrieved_list.append(assoc)
retrieved = torch.cat(retrieved_list, dim=0) # [B, 1, D]
enhanced = self.output_proj(torch.cat([x[:, -1:], retrieved], dim=-1))
return enhanced, helix_state
def _compress_batch(self, S_b, active_b, D, max_s):
k = active_b.sum().item()
if k <= 64 or k < 4:
return S_b
active_indices = active_b.nonzero(as_tuple=True)[0]
clusters = torch.split(active_indices, max(4, k // 16))
result = []
for cluster in clusters:
cluster_sel = S_b[0:1, cluster]
corr = (cluster_sel @ cluster_sel.transpose(1, 2)).sum(dim=-1)
weights = F.softmax(corr, dim=-1)
merged = (weights.unsqueeze(-1) * cluster_sel).sum(dim=1, keepdim=True)
result.append(merged)
S_compressed = torch.cat(result, dim=1)
n_compressed = S_compressed.shape[1]
if n_compressed < max_s:
pad = torch.zeros(1, max_s - n_compressed, D, device=S_b.device)
S_compressed = torch.cat([S_compressed, pad], dim=1)
S_b[:, :max_s] = S_compressed[:, :max_s]
return S_b
# ============================================================================
# 2. HIERARCHICAL CODE ATTENTION (HCA)
# ============================================================================
class HierarchicalCodeAttention(nn.Module):
"""
Three-tier attention: local window, AST-aware structure, global sparse.
"""
def __init__(self, d_model, n_heads, kv_heads=None, window_size=128,
local_heads=8, struct_heads=4, global_heads=4):
super().__init__()
self.d_model = d_model
self.n_heads = n_heads
self.kv_heads = kv_heads or n_heads
self.window_size = window_size
self.head_dim = d_model // n_heads
self.groups = n_heads // self.kv_heads
self.local_heads = local_heads
self.struct_heads = struct_heads
self.global_heads = global_heads
assert local_heads + struct_heads + global_heads == n_heads
self.q_proj = nn.Linear(d_model, d_model, bias=False)
self.k_proj = nn.Linear(d_model, self.kv_heads * self.head_dim, bias=False)
self.v_proj = nn.Linear(d_model, self.kv_heads * self.head_dim, bias=False)
self.o_proj = nn.Linear(d_model, d_model, bias=False)
self.struct_q = nn.Linear(d_model, struct_heads * self.head_dim, bias=False)
self.struct_k = nn.Linear(d_model * 2, struct_heads * self.head_dim, bias=False)
self.global_router = nn.Linear(d_model, global_heads * 2, bias=False)
self.top_k = 32
def forward(self, x, mask=None, ast_embeds=None):
B, L, D = x.shape
H, Hk, Hd = self.n_heads, self.kv_heads, self.head_dim
q = self.q_proj(x).view(B, L, H, Hd).transpose(1,2)
k = self.k_proj(x).view(B, L, Hk, Hd).transpose(1,2)
v = self.v_proj(x).view(B, L, Hk, Hd).transpose(1,2)
out = torch.zeros(B, H, L, Hd, device=x.device, dtype=x.dtype)
# Level 1: Local sliding window
local_q = q[:, :self.local_heads]
n_local_kv = max(1, self.local_heads // self.groups)
local_k = k[:, :n_local_kv]
local_v = v[:, :n_local_kv]
for i in range(L):
start = max(0, i - self.window_size)
w_k = local_k[:, :, start:i+1]
w_v = local_v[:, :, start:i+1]
q_i = local_q[:, :, i] # [B, local_h, Hd]
scores = torch.matmul(q_i.unsqueeze(2), w_k.transpose(-2,-1)).squeeze(2) / math.sqrt(Hd)
if mask is not None:
m = mask[:, 0, 0, start:i+1] # [B, W]
scores = scores.masked_fill(~m.unsqueeze(1).expand(-1, self.local_heads, -1), -1e9)
attn = F.softmax(scores, dim=-1)
out[:, :self.local_heads, i] = torch.matmul(attn.unsqueeze(2), w_v).squeeze(2)
# Level 2: AST-aware structure heads
if ast_embeds is not None and self.struct_heads > 0:
s_q = self.struct_q(x).view(B, L, self.struct_heads, Hd).transpose(1,2)
s_input = torch.cat([x, ast_embeds], dim=-1)
s_k = self.struct_k(s_input).view(B, L, self.struct_heads, Hd).transpose(1,2)
n_s_kv = max(1, self.struct_heads // self.groups)
s_v = v[:, :n_s_kv]
scores = torch.matmul(s_q, s_k.transpose(-2,-1)) / math.sqrt(Hd)
if mask is not None:
scores = scores.masked_fill(~mask[:, :, :, :L], -1e9)
attn = F.softmax(scores, dim=-1)
start = self.local_heads
end = self.local_heads + self.struct_heads
out[:, start:end] = torch.matmul(attn, s_v)
# Level 3: Global attention
if self.global_heads > 0:
n_g_kv = max(1, self.global_heads // self.groups)
q_g = q[:, -self.global_heads:] # [B, g_h, L, Hd]
k_g = k[:, :n_g_kv] # [B, n_g_kv, L, Hd]
v_g = v[:, :n_g_kv] # [B, n_g_kv, L, Hd]
scores = torch.matmul(q_g, k_g.transpose(-2,-1)) / math.sqrt(Hd)
if mask is not None:
scores = scores.masked_fill(~mask[:, :, :, :L], -1e9)
attn = F.softmax(scores, dim=-1)
g_out = torch.matmul(attn, v_g)
if g_out.shape[1] != self.global_heads:
g_out = g_out[:, :self.global_heads]
out[:, -self.global_heads:] = g_out
out = out.transpose(1,2).contiguous().view(B, L, D)
out = self.o_proj(out)
return out
# ============================================================================
# 3. EXECUTION-AUGMENTED FFN (EA-FFN)
# ============================================================================
class ExecutionAugmentedFFN(nn.Module):
"""
Two-stream FFN: standard SwiGLU + execution trace stream.
"""
def __init__(self, d_model, d_ff=None, trace_dim=256):
super().__init__()
d_ff = d_ff or d_model * 4
self.trace_dim = trace_dim
# Stream A: Standard SwiGLU
self.gate_proj = nn.Linear(d_model, d_ff, bias=False)
self.up_proj = nn.Linear(d_model, d_ff, bias=False)
self.down_proj = nn.Linear(d_ff, d_model, bias=False)
# Stream B: Execution trace
self.trace_proj = nn.Linear(d_model + trace_dim, d_ff, bias=False)
self.trace_down = nn.Linear(d_ff, d_model, bias=False)
# Gate
self.gate_net = nn.Linear(d_model, d_model)
def forward(self, x, trace=None):
# Stream A
a = F.silu(self.gate_proj(x)) * self.up_proj(x)
a = self.down_proj(a)
# Stream B (with execution trace if available)
b = 0
if trace is not None:
b_input = torch.cat([x, trace], dim=-1)
b = F.silu(self.trace_proj(b_input))
b = self.trace_down(b)
# Learned gating
gate = torch.sigmoid(self.gate_net(x))
return gate * a + (1 - gate) * b
# ============================================================================
# 4. ROPE WITH STRUCTURAL BIAS (RoPE-S)
# ============================================================================
class RoPEWithStructuralBias(nn.Module):
"""
Rotary position encoding with structural bias terms for AST depth,
scope, and control flow nesting.
"""
def __init__(self, d_model, max_len=131072, base=10000.0):
super().__init__()
self.d_model = d_model
self.max_len = max_len
inv_freq = 1.0 / (base ** (torch.arange(0, d_model, 2).float() / d_model))
self.register_buffer('inv_freq', inv_freq)
self.struct_bias = nn.Linear(4, d_model // 2, bias=False)
def forward(self, x, positions, ast_depth=None, scope_id=None,
ctrl_flow=None, branch_id=None):
B, L, D = x.shape
# positions: [B, L] or [L] - handle both
if positions.dim() == 2:
pos = positions.float() # [B, L]
freqs = pos.unsqueeze(-1) * self.inv_freq.unsqueeze(0).unsqueeze(0) # [B, L, D/2]
else:
pos = positions.float()
freqs = torch.outer(pos, self.inv_freq) # [L, D/2]
emb = torch.cat([freqs.sin(), freqs.cos()], dim=-1) # [B, L, D] or [L, D]
if emb.dim() == 2:
emb = emb.unsqueeze(0).expand(B, -1, -1)
if ast_depth is not None:
ast_h = ast_depth.float() / 32.0
sc_h = (scope_id.float() / 256.0) if scope_id is not None else pos / 256.0
cf_h = (ctrl_flow.float() / 16.0) if ctrl_flow is not None else pos / 16.0
br_h = (branch_id.float() / 8.0) if branch_id is not None else pos / 8.0
struct_feats = torch.stack([ast_h, sc_h, cf_h, br_h], dim=-1)
struct_bias = self.struct_bias(struct_feats)
emb = emb + torch.cat([struct_bias, struct_bias], dim=-1)
# Apply rotary: x * cos + rotate_half(x) * sin
x_rot = x * emb.cos() + torch.stack([-x[..., 1::2], x[..., ::2]], dim=-1).reshape(x.shape) * emb.sin()
return x_rot
# ============================================================================
# 5. PREFIX-PRESERVING NORMALIZATION (PPN)
# ============================================================================
class PrefixPreservingNorm(nn.Module):
"""
Block-diagonal normalization that preserves prefix subspaces.
Enables exact KV-cache sharing across prefix lengths.
"""
def __init__(self, d_model, n_groups=4, eps=1e-5):
super().__init__()
self.n_groups = n_groups
self.eps = eps
self.weight = nn.Parameter(torch.ones(d_model))
self.bias = nn.Parameter(torch.zeros(d_model))
self.group_size = d_model // n_groups
def forward(self, x):
B, L, D = x.shape
x = x.view(B, L, self.n_groups, self.group_size)
var = x.var(dim=-1, keepdim=True, unbiased=False)
x = x / torch.sqrt(var + self.eps)
x = x.view(B, L, D)
return x * self.weight + self.bias
# ============================================================================
# 6. MIXTURE-OF-DEPTH (MoD) ROUTER
# ============================================================================
class MixtureOfDepth(nn.Module):
"""
Per-token depth routing. Each token chooses how many layers to execute.
"""
def __init__(self, d_model, n_layers, n_buckets=4):
super().__init__()
self.n_layers = n_layers
self.n_buckets = n_buckets
self.bucket_sizes = [n_layers // 2 ** i for i in range(n_buckets)]
self.bucket_sizes[0] = max(1, n_layers // 4)
self.router = nn.Sequential(
nn.Linear(d_model + 8, d_model), nn.SiLU(),
nn.Linear(d_model, n_buckets))
def forward(self, x, depth_features=None):
B, L, D = x.shape
features = depth_features if depth_features is not None else x.new_zeros(B, L, 8)
logits = self.router(torch.cat([x, features], dim=-1))
probs = F.softmax(logits, dim=-1)
bucket = probs.argmax(dim=-1)
depths = torch.tensor([self.bucket_sizes[b.item()] for b in bucket[0]],
device=x.device, dtype=torch.long)
aux_loss = -torch.mean(probs * torch.log(probs + 1e-8)) # entropy regularization
return depths, probs, aux_loss
# ============================================================================
# 7. FSI_EDGE TRANSFORMER BLOCK
# ============================================================================
class FSIEdgeBlock(nn.Module):
def __init__(self, layer_id, config):
super().__init__()
self.layer_id = layer_id
self.config = config
self.helix = HelixMemory(config.d_model, config.helix_slots)
self.hca = HierarchicalCodeAttention(
config.d_model, config.n_heads, config.kv_heads,
config.window_size, config.local_heads,
config.struct_heads, config.global_heads)
self.eaffn = ExecutionAugmentedFFN(config.d_model, config.d_ff, config.trace_dim)
self.ppn1 = PrefixPreservingNorm(config.d_model, config.norm_groups)
self.ppn2 = PrefixPreservingNorm(config.d_model, config.norm_groups)
self.rope_s = RoPEWithStructuralBias(config.d_model, config.max_seq_len)
def forward(self, x, helmet_state, mask=None, positions=None,
ast_embeds=None, ast_depth=None, scope_id=None,
ctrl_flow=None, branch_id=None, trace=None):
# Pre-norm + RoPE-S
h = self.ppn1(x)
h = self.rope_s(h, positions, ast_depth, scope_id, ctrl_flow, branch_id)
# HCA + Helix memory
h = self.hca(h, mask, ast_embeds)
helix_out, helmet_state = self.helix(h, helmet_state)
x = x + h + helix_out
# EA-FFN
h = self.ppn2(x)
h = self.eaffn(h, trace)
x = x + h
return x, helmet_state
# ============================================================================
# 8. FSI_EDGE MAIN MODEL
# ============================================================================
@dataclass
class FSIEdgeConfig:
vocab_size: int = 32768
d_model: int = 1536
n_layers: int = 28
n_heads: int = 24
kv_heads: int = 6
d_ff: int = 6144
max_seq_len: int = 16384
window_size: int = 128
local_heads: int = 14
struct_heads: int = 6
global_heads: int = 4
helix_slots: int = 1024
trace_dim: int = 256
norm_groups: int = 4
rope_base: float = 10000.0
moe_n_experts: int = 1
moe_top_k: int = 1
dropout: float = 0.0
init_std: float = 0.02
def __post_init__(self):
total = self.local_heads + self.struct_heads + self.global_heads
if total != self.n_heads:
ratio = self.n_heads / total
self.local_heads = max(1, int(self.local_heads * ratio))
self.struct_heads = max(1, int(self.struct_heads * ratio))
self.global_heads = self.n_heads - self.local_heads - self.struct_heads
if self.global_heads < 1:
self.global_heads = 1
self.local_heads = self.n_heads - self.struct_heads - self.global_heads
class FSIEdgeModel(nn.Module):
def __init__(self, config):
super().__init__()
self.config = config
self.embed = nn.Embedding(config.vocab_size, config.d_model)
self.ast_type_embed = nn.Embedding(64, config.d_model)
self.layers = nn.ModuleList([
FSIEdgeBlock(i, config) for i in range(config.n_layers)
])
self.mod = MixtureOfDepth(config.d_model, config.n_layers)
self.final_norm = PrefixPreservingNorm(config.d_model, config.norm_groups)
self.lm_head = nn.Linear(config.d_model, config.vocab_size, bias=False)
self.apply(self._init_weights)
def _init_weights(self, module):
if isinstance(module, nn.Linear):
module.weight.data.normal_(mean=0.0, std=self.config.init_std)
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.init_std)
def forward(self, input_ids, ast_types=None, ast_depths=None,
scope_ids=None, ctrl_flows=None, branch_ids=None,
traces=None, attention_mask=None, labels=None):
B, L = input_ids.shape
device = input_ids.device
x = self.embed(input_ids)
if ast_types is not None:
x = x + self.ast_type_embed(ast_types)
positions = torch.arange(L, device=device).unsqueeze(0).expand(B, -1)
mask = attention_mask.unsqueeze(1).unsqueeze(2).bool() if attention_mask is not None else None
ast_embeds = None
if ast_types is not None:
ast_embeds = self.ast_type_embed(ast_types)
# Helix init at layer 0
helmet_state = self.layers[0].helix.init_helix(B, device)
for layer in self.layers:
x, helmet_state = layer(
x, helmet_state, mask, positions,
ast_embeds, ast_depths, scope_ids,
ctrl_flows, branch_ids, traces)
x = self.final_norm(x)
logits = self.lm_head(x)
loss = None
if labels is not None:
shift_logits = logits[..., :-1, :].contiguous()
shift_labels = labels[..., 1:].contiguous()
loss = F.cross_entropy(
shift_logits.view(-1, shift_logits.size(-1)),
shift_labels.view(-1),
ignore_index=0)
return FSIEdgeOutput(loss=loss, logits=logits, helmet_state=helmet_state)
@dataclass
class FSIEdgeOutput:
loss: torch.Tensor = None
logits: torch.Tensor = None
helmet_state: dict = None
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