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"""
FrozenScGPTExtractor — Frozen scGPT model for on-the-fly per-gene feature extraction.

Analogous to LatentForcing's dinov2_hf.py RAE class:
- Frozen encoder (no gradients)
- Running statistics for normalization
- Variance matching to align scale with expression embeddings
"""

import sys
import os
import json
import logging
import warnings
from typing import List, Optional

import torch
import torch.nn as nn
import numpy as np
import types

# Set up scGPT imports — create minimal package stubs to avoid scgpt/__init__.py
# pulling in heavy dependencies (datasets, scbank, etc.)
_SCGPT_ROOT = os.path.normpath(os.path.join(os.path.dirname(__file__), "..", "..", "..", "..", "transfer", "code", "scGPT"))
if _SCGPT_ROOT not in sys.path:
    sys.path.insert(0, _SCGPT_ROOT)

# Create minimal package stubs
for pkg, subdir in [
    ("scgpt", "scgpt"),
    ("scgpt.model", "scgpt/model"),
    ("scgpt.utils", "scgpt/utils"),
]:
    if pkg not in sys.modules:
        mod = types.ModuleType(pkg)
        mod.__path__ = [os.path.join(_SCGPT_ROOT, subdir)]
        sys.modules[pkg] = mod

# Add logger stub
if not hasattr(sys.modules["scgpt"], "logger"):
    sys.modules["scgpt"].logger = logging.getLogger("scgpt")

from scgpt.model.dsbn import DomainSpecificBatchNorm1d  # noqa: F401 (dependency of model.py)
from scgpt.model.grad_reverse import grad_reverse  # noqa: F401 (dependency of model.py)
from scgpt.model.model import TransformerModel


def _load_pretrained_safe(model, pretrained_params, verbose=False):
    """Load pretrained weights with non-strict matching (simplified from scGPT)."""
    model_dict = model.state_dict()
    loaded = 0
    for key, val in pretrained_params.items():
        # Handle flash attention -> standard attention key mapping
        new_key = key.replace("Wqkv.", "in_proj_").replace("inner_attn.out_proj", "out_proj")
        if new_key in model_dict and model_dict[new_key].shape == val.shape:
            model_dict[new_key] = val
            loaded += 1
        elif key in model_dict and model_dict[key].shape == val.shape:
            model_dict[key] = val
            loaded += 1
    model.load_state_dict(model_dict)
    if verbose:
        print(f"Loaded {loaded}/{len(pretrained_params)} pretrained parameters")


class FrozenScGPTExtractor(nn.Module):
    """
    Wraps a frozen scGPT TransformerModel for on-the-fly per-gene feature extraction.
    Similar to LatentForcing's RAE (frozen DINO-v2 encoder).

    Given expression values for G HVG genes, extracts contextualized per-gene features
    from scGPT's transformer encoder, then scatters them back to a fixed G-length tensor.

    Output: (B, G, scgpt_d_model) normalized features.
    """

    def __init__(
        self,
        model_dir: str,
        hvg_gene_names: List[str],
        device: torch.device = torch.device("cpu"),
        max_seq_len: int = 1200,
        target_std: float = 1.0,
        warmup_batches: int = 200,
    ):
        super().__init__()
        self.device = device
        self.max_seq_len = max_seq_len
        self.target_std = target_std
        self.warmup_batches = warmup_batches
        self.n_hvg = len(hvg_gene_names)

        # Load scGPT vocab as a simple dict (avoid torchtext dependency)
        vocab_path = os.path.join(model_dir, "vocab.json")
        with open(vocab_path, "r") as f:
            self.scgpt_vocab = json.load(f)  # {gene_name: index}

        # Build HVG -> scGPT vocab ID mapping
        self.hvg_gene_names = hvg_gene_names
        hvg_to_scgpt_id = []
        missing_count = 0
        for gene in hvg_gene_names:
            if gene in self.scgpt_vocab:
                hvg_to_scgpt_id.append(self.scgpt_vocab[gene])
            else:
                hvg_to_scgpt_id.append(-1)
                missing_count += 1
        if missing_count > 0:
            warnings.warn(
                f"FrozenScGPTExtractor: {missing_count}/{len(hvg_gene_names)} HVG genes "
                f"not found in scGPT vocab, will use zero vectors."
            )
        self.register_buffer(
            "hvg_to_scgpt_id",
            torch.tensor(hvg_to_scgpt_id, dtype=torch.long),
        )

        # Load scGPT model config
        args_path = os.path.join(model_dir, "args.json")
        with open(args_path, "r") as f:
            model_args = json.load(f)

        self.scgpt_d_model = model_args.get("embsize", 512)

        # Build scGPT model (using a simple Vocab-like wrapper)
        pad_token = model_args.get("pad_token", "<pad>")
        pad_value = model_args.get("pad_value", 0)
        vocab_size = len(self.scgpt_vocab)
        pad_token_id = self.scgpt_vocab.get(pad_token, 0)

        # Create a minimal vocab-like object that TransformerModel needs
        class _SimpleVocab:
            def __getitem__(self, token):
                return self._map.get(token, 0)
            def __len__(self):
                return self._size
            def __contains__(self, token):
                return token in self._map

        simple_vocab = _SimpleVocab()
        simple_vocab._map = self.scgpt_vocab
        simple_vocab._size = vocab_size

        self.scgpt_model = TransformerModel(
            ntoken=vocab_size,
            d_model=self.scgpt_d_model,
            nhead=model_args.get("nheads", 8),
            d_hid=model_args.get("d_hid", 512),
            nlayers=model_args.get("nlayers", 12),
            vocab=simple_vocab,
            dropout=0.0,
            pad_token=pad_token,
            pad_value=pad_value,
            input_emb_style="continuous",
            use_fast_transformer=False,
        )

        # Load pretrained weights
        model_file = os.path.join(model_dir, "best_model.pt")
        pretrained_params = torch.load(model_file, map_location="cpu")
        _load_pretrained_safe(self.scgpt_model, pretrained_params, verbose=True)

        # Freeze all parameters
        self.scgpt_model.eval()
        for p in self.scgpt_model.parameters():
            p.requires_grad_(False)

        # Pad/CLS token IDs
        self.pad_token_id = pad_token_id
        self.cls_token_id = self.scgpt_vocab.get("<cls>", pad_token_id)

        # Running statistics for normalization (like dinov2_hf.py)
        self.register_buffer("running_mean", torch.zeros(self.scgpt_d_model))
        self.register_buffer("running_var", torch.ones(self.scgpt_d_model))
        self.register_buffer("n_batches_seen", torch.tensor(0, dtype=torch.long))
        self._stats_frozen = False

    def _update_running_stats(self, z: torch.Tensor):
        """Update running mean/var from a batch of features. z: (total_genes, d_model)"""
        if self._stats_frozen or z.numel() == 0:
            return

        batch_mean = z.mean(dim=0)
        batch_var = z.var(dim=0, unbiased=False)
        n = self.n_batches_seen.item()

        # Exponential moving average
        momentum = 1.0 / (n + 1)
        self.running_mean.lerp_(batch_mean, momentum)
        self.running_var.lerp_(batch_var, momentum)
        self.n_batches_seen += 1

        if self.n_batches_seen.item() >= self.warmup_batches:
            self._stats_frozen = True

    @torch.no_grad()
    def extract(self, expression_values: torch.Tensor, gene_indices: Optional[torch.Tensor] = None) -> torch.Tensor:
        """
        Extract per-gene contextualized features from frozen scGPT.

        Args:
            expression_values: (B, G) expression values for G genes
            gene_indices: (G,) optional indices into the full HVG list.
                         If provided, selects the corresponding subset of
                         hvg_to_scgpt_id mapping. If None, assumes expression_values
                         covers all n_hvg genes.

        Returns:
            (B, G, scgpt_d_model) normalized per-gene features
        """
        B, G = expression_values.shape
        device = expression_values.device

        # Select the appropriate scGPT ID mapping
        if gene_indices is not None:
            hvg_ids = self.hvg_to_scgpt_id[gene_indices]  # (G,)
        else:
            hvg_ids = self.hvg_to_scgpt_id  # (n_hvg,)

        # Valid mask: genes that have a scGPT vocab mapping
        valid_mask = hvg_ids >= 0  # (G,)
        valid_scgpt_ids = hvg_ids[valid_mask]  # (G_valid,)
        n_valid = valid_scgpt_ids.shape[0]

        # Get expression values for valid genes only
        expr_valid = expression_values[:, valid_mask]  # (B, G_valid)

        # Limit sequence length
        if n_valid + 1 > self.max_seq_len:  # +1 for CLS
            perm = torch.randperm(n_valid, device=device)[:self.max_seq_len - 1]
            perm, _ = perm.sort()
            selected_scgpt_ids = valid_scgpt_ids[perm]
            selected_expr = expr_valid[:, perm]
            seq_len = self.max_seq_len
            selected_valid_idx = torch.where(valid_mask)[0][perm]
        else:
            selected_scgpt_ids = valid_scgpt_ids
            selected_expr = expr_valid
            seq_len = n_valid + 1
            selected_valid_idx = torch.where(valid_mask)[0]

        # Build input: prepend CLS token
        cls_ids = torch.full((B, 1), self.cls_token_id, dtype=torch.long, device=device)
        gene_ids = selected_scgpt_ids.unsqueeze(0).expand(B, -1)
        src = torch.cat([cls_ids, gene_ids], dim=1)  # (B, seq_len)

        cls_val = torch.zeros(B, 1, device=device)
        values = torch.cat([cls_val, selected_expr], dim=1)  # (B, seq_len)

        # Padding mask
        src_key_padding_mask = torch.zeros(B, seq_len, dtype=torch.bool, device=device)

        # Run frozen scGPT encoder
        encoder_out = self.scgpt_model._encode(
            src, values, src_key_padding_mask
        )  # (B, seq_len, d_model)

        # Skip CLS token, get per-gene features
        gene_features = encoder_out[:, 1:, :]  # (B, seq-1, d_model)

        # Scatter back to fixed G positions
        output = torch.zeros(B, G, self.scgpt_d_model, device=device, dtype=gene_features.dtype)
        idx = selected_valid_idx.unsqueeze(0).unsqueeze(-1).expand(B, -1, self.scgpt_d_model)
        output.scatter_(1, idx, gene_features)

        # Update running statistics (only during training warmup)
        if self.training and not self._stats_frozen:
            nonzero_mask = output.abs().sum(-1) > 0
            if nonzero_mask.any():
                nonzero_feats = output[nonzero_mask]
                self._update_running_stats(nonzero_feats)

        # Normalize: zero mean, unit variance, then scale
        eps = 1e-6
        output = (output - self.running_mean) / (self.running_var.sqrt() + eps)
        output = output * self.target_std

        # Zero out missing gene positions (normalization shifted them from 0)
        output[:, self.get_missing_gene_mask(gene_indices), :] = 0.0

        return output

    def get_missing_gene_mask(self, gene_indices=None):
        """Return (G,) bool tensor, True = gene not in scGPT vocab."""
        hvg_ids = self.hvg_to_scgpt_id[gene_indices] if gene_indices is not None else self.hvg_to_scgpt_id
        return hvg_ids < 0

    def _prepare_gene_selection(self, gene_indices, device):
        """Shared gene subset logic for extract and attention-delta."""
        if gene_indices is not None:
            hvg_ids = self.hvg_to_scgpt_id[gene_indices]
        else:
            hvg_ids = self.hvg_to_scgpt_id

        valid_mask = hvg_ids >= 0
        valid_scgpt_ids = hvg_ids[valid_mask]
        n_valid = valid_scgpt_ids.shape[0]

        if n_valid + 1 > self.max_seq_len:
            perm = torch.randperm(n_valid, device=device)[:self.max_seq_len - 1]
            perm, _ = perm.sort()
            selected_scgpt_ids = valid_scgpt_ids[perm]
            selected_valid_idx = torch.where(valid_mask)[0][perm]
        else:
            selected_scgpt_ids = valid_scgpt_ids
            selected_valid_idx = torch.where(valid_mask)[0]

        return valid_mask, selected_scgpt_ids, selected_valid_idx

    def _forward_to_layer(self, src, values, mask, target_layer):
        """
        Run scGPT encoder up to (but not including) target_layer.
        Returns hidden states (B, seq_len, d_model) after layer (target_layer - 1).
        """
        model = self.scgpt_model
        # Embedding
        src_embs = model.encoder(src)
        val_embs = model.value_encoder(values)
        total_embs = src_embs + val_embs
        # Positional encoding if available
        if hasattr(model, 'pos_encoder') and model.pos_encoder is not None:
            total_embs = model.pos_encoder(total_embs)

        # Run through transformer layers up to target_layer
        output = total_embs
        for i in range(target_layer):
            layer = model.transformer_encoder.layers[i]
            output = layer(output, src_key_padding_mask=mask)
        return output

    def _compute_attention(self, hidden, layer_idx, use_rank_norm=True):
        """
        Compute attention weights at a given layer using Q/K from in_proj_weight.
        Returns (B, S, S) attention weights averaged over heads.
        """
        model = self.scgpt_model
        layer = model.transformer_encoder.layers[layer_idx]
        self_attn = layer.self_attn

        d_model = self.scgpt_d_model
        nhead = self_attn.num_heads
        d_k = d_model // nhead

        # Extract Q, K from in_proj_weight: [W_q; W_k; W_v] each (d_model, d_model)
        W = self_attn.in_proj_weight  # (3*d_model, d_model)
        b = self_attn.in_proj_bias    # (3*d_model,)
        W_q, W_k = W[:d_model], W[d_model:2*d_model]
        b_q, b_k = b[:d_model], b[d_model:2*d_model]

        B, S, _ = hidden.shape
        Q = torch.nn.functional.linear(hidden, W_q, b_q)  # (B, S, d_model)
        K = torch.nn.functional.linear(hidden, W_k, b_k)  # (B, S, d_model)

        # Reshape to multi-head: (B, nhead, S, d_k)
        Q = Q.view(B, S, nhead, d_k).transpose(1, 2)
        K = K.view(B, S, nhead, d_k).transpose(1, 2)

        # Attention scores: (B, nhead, S, S)
        attn = torch.matmul(Q, K.transpose(-2, -1)) / (d_k ** 0.5)

        if use_rank_norm:
            # Rank normalization: replace values with their ranks, then normalize to [0, 1]
            B_, H_, S1_, S2_ = attn.shape
            attn_flat = attn.reshape(B_ * H_, S1_ * S2_)
            ranks = attn_flat.argsort(dim=-1).argsort(dim=-1).float()
            ranks = ranks / (S1_ * S2_ - 1)  # normalize to [0, 1]
            attn = ranks.reshape(B_, H_, S1_, S2_)

        # Average over heads: (B, S, S)
        attn = attn.mean(dim=1)
        return attn

    @torch.no_grad()
    def extract_attention_delta(
        self,
        control_expr: torch.Tensor,   # (B, G)
        target_expr: torch.Tensor,    # (B, G)
        gene_indices: torch.Tensor = None,
        attn_layer: int = 11,
        use_rank_norm: bool = True,
        multi_layer: str = "",
    ) -> torch.Tensor:
        """
        Compute attention-delta features: Δ_attn @ gene_emb.

        Steps:
        1. gene_emb = scGPT.encoder(gene_ids)  → (G_sel, 512)
        2. hidden_ctrl/tgt = forward to target_layer
        3. attn_ctrl/tgt = Q @ K^T with rank norm
        4. Δ_attn = attn_tgt - attn_ctrl, remove CLS
        5. features = Δ_attn @ gene_emb → (B, G_sel, 512)
        6. scatter to G positions + normalize

        Returns: (B, G, scgpt_d_model) normalized features
        """
        B, G = control_expr.shape
        device = control_expr.device

        valid_mask, selected_scgpt_ids, selected_valid_idx = self._prepare_gene_selection(gene_indices, device)
        n_sel = selected_scgpt_ids.shape[0]

        # Expression for valid genes
        ctrl_valid = control_expr[:, valid_mask][:, :n_sel] if n_sel < valid_mask.sum() else control_expr[:, valid_mask]
        tgt_valid = target_expr[:, valid_mask][:, :n_sel] if n_sel < valid_mask.sum() else target_expr[:, valid_mask]

        # Use the same selection as _prepare_gene_selection
        if gene_indices is not None:
            hvg_ids = self.hvg_to_scgpt_id[gene_indices]
        else:
            hvg_ids = self.hvg_to_scgpt_id
        valid_positions = torch.where(hvg_ids >= 0)[0]
        if n_sel < len(valid_positions):
            # _prepare_gene_selection applied a permutation
            perm_map = selected_valid_idx
            ctrl_valid = control_expr[:, perm_map]
            tgt_valid = target_expr[:, perm_map]
        else:
            ctrl_valid = control_expr[:, valid_positions]
            tgt_valid = target_expr[:, valid_positions]

        # Build input with CLS
        cls_ids = torch.full((B, 1), self.cls_token_id, dtype=torch.long, device=device)
        gene_ids_expanded = selected_scgpt_ids.unsqueeze(0).expand(B, -1)
        src_ctrl = torch.cat([cls_ids, gene_ids_expanded], dim=1)
        src_tgt = torch.cat([cls_ids, gene_ids_expanded], dim=1)

        cls_val = torch.zeros(B, 1, device=device)
        val_ctrl = torch.cat([cls_val, ctrl_valid], dim=1)
        val_tgt = torch.cat([cls_val, tgt_valid], dim=1)

        seq_len = n_sel + 1
        pad_mask = torch.zeros(B, seq_len, dtype=torch.bool, device=device)

        # Step 1: gene_emb (static lookup)
        gene_emb = self.scgpt_model.encoder(selected_scgpt_ids.unsqueeze(0))  # (1, G_sel, 512)
        gene_emb = gene_emb.squeeze(0)  # (G_sel, 512)

        # Parse layers
        if multi_layer:
            layers = [int(x) for x in multi_layer.split(",")]
        else:
            layers = [attn_layer]

        # Step 2-4: compute delta attention (averaged over layers if multi_layer)
        delta_attn_sum = torch.zeros(B, n_sel, n_sel, device=device)
        for layer_idx in layers:
            hidden_ctrl = self._forward_to_layer(src_ctrl, val_ctrl, pad_mask, layer_idx)
            hidden_tgt = self._forward_to_layer(src_tgt, val_tgt, pad_mask, layer_idx)

            attn_ctrl = self._compute_attention(hidden_ctrl, layer_idx, use_rank_norm)  # (B, S, S)
            attn_tgt = self._compute_attention(hidden_tgt, layer_idx, use_rank_norm)

            # Remove CLS row and column
            attn_ctrl = attn_ctrl[:, 1:, 1:]  # (B, G_sel, G_sel)
            attn_tgt = attn_tgt[:, 1:, 1:]

            delta_attn_sum = delta_attn_sum + (attn_tgt - attn_ctrl)

        delta_attn = delta_attn_sum / len(layers)

        # Step 5: features = Δ_attn @ gene_emb → (B, G_sel, 512)
        features = torch.matmul(delta_attn, gene_emb.unsqueeze(0).expand(B, -1, -1))

        # Step 6: scatter to G positions
        output = torch.zeros(B, G, self.scgpt_d_model, device=device, dtype=features.dtype)
        idx = selected_valid_idx.unsqueeze(0).unsqueeze(-1).expand(B, -1, self.scgpt_d_model)
        output.scatter_(1, idx, features)

        # Update running statistics (during training warmup)
        if self.training and not self._stats_frozen:
            nonzero_mask = output.abs().sum(-1) > 0
            if nonzero_mask.any():
                nonzero_feats = output[nonzero_mask]
                self._update_running_stats(nonzero_feats)

        # Normalize
        eps = 1e-6
        output = (output - self.running_mean) / (self.running_var.sqrt() + eps)
        output = output * self.target_std

        # Zero out missing gene positions (normalization shifted them from 0)
        output[:, self.get_missing_gene_mask(gene_indices), :] = 0.0

        return output

    def train(self, mode: bool = True):
        """Override to keep scGPT always in eval mode."""
        super().train(mode)
        self.scgpt_model.eval()
        return self