# Copyright 2025 Alibaba Z-Image Team and The HuggingFace Team. All rights reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. import math from typing import Dict, List, Optional, Tuple, Union import torch import torch.nn as nn import torch.nn.functional as F from torch.nn.utils.rnn import pad_sequence from diffusers.configuration_utils import ConfigMixin, register_to_config from diffusers.loaders import FromOriginalModelMixin, PeftAdapterMixin from diffusers.models.attention_processor import Attention from diffusers.models.modeling_utils import ModelMixin from diffusers.models.normalization import RMSNorm from diffusers.utils.torch_utils import maybe_allow_in_graph try: from diffusers.models.attention_dispatch import dispatch_attention_fn _HAS_DISPATCH_ATTENTION = True except ImportError: _HAS_DISPATCH_ATTENTION = False from diffusers.models.modeling_outputs import Transformer2DModelOutput from flash_attn import flash_attn_func ADALN_EMBED_DIM = 256 SEQ_MULTI_OF = 32 X_PAD_DIM = 64 class TimestepEmbedder(nn.Module): def __init__(self, out_size, mid_size=None, frequency_embedding_size=256): super().__init__() if mid_size is None: mid_size = out_size self.mlp = nn.Sequential( nn.Linear(frequency_embedding_size, mid_size, bias=True), nn.SiLU(), nn.Linear(mid_size, out_size, bias=True), ) self.frequency_embedding_size = frequency_embedding_size @staticmethod def timestep_embedding(t, dim, max_period=10000): with torch.amp.autocast("cuda", enabled=False): half = dim // 2 freqs = torch.exp( -math.log(max_period) * torch.arange(start=0, end=half, dtype=torch.float32, device=t.device) / half ) args = t[:, None].float() * freqs[None] embedding = torch.cat([torch.cos(args), torch.sin(args)], dim=-1) if dim % 2: embedding = torch.cat([embedding, torch.zeros_like(embedding[:, :1])], dim=-1) return embedding def forward(self, t): t_freq = self.timestep_embedding(t, self.frequency_embedding_size) weight_dtype = self.mlp[0].weight.dtype compute_dtype = getattr(self.mlp[0], "compute_dtype", None) if weight_dtype.is_floating_point: t_freq = t_freq.to(weight_dtype) elif compute_dtype is not None: t_freq = t_freq.to(compute_dtype) t_emb = self.mlp(t_freq) return t_emb class ZSingleStreamAttnProcessor: """ Processor for Z-Image single stream attention that adapts the existing Attention class to match the behavior of the original Z-ImageAttention module. """ _attention_backend = None _parallel_config = None def __init__(self): if not hasattr(F, "scaled_dot_product_attention"): raise ImportError( "ZSingleStreamAttnProcessor requires PyTorch 2.0. To use it, please upgrade PyTorch to version 2.0 or higher." ) def __call__( self, attn: Attention, hidden_states: torch.Tensor, encoder_hidden_states: Optional[torch.Tensor] = None, attention_mask: Optional[torch.Tensor] = None, freqs_cis: Optional[torch.Tensor] = None, ) -> torch.Tensor: query = attn.to_q(hidden_states) key = attn.to_k(hidden_states) value = attn.to_v(hidden_states) query = query.unflatten(-1, (attn.heads, -1)) key = key.unflatten(-1, (attn.heads, -1)) value = value.unflatten(-1, (attn.heads, -1)) # Apply Norms if attn.norm_q is not None: query = attn.norm_q(query) if attn.norm_k is not None: key = attn.norm_k(key) # Apply RoPE def apply_rotary_emb(x_in: torch.Tensor, freqs_cis: torch.Tensor) -> torch.Tensor: with torch.amp.autocast("cuda", enabled=False): x = torch.view_as_complex(x_in.float().reshape(*x_in.shape[:-1], -1, 2)) freqs_cis = freqs_cis.unsqueeze(2) x_out = torch.view_as_real(x * freqs_cis).flatten(3) return x_out.type_as(x_in) # todo if freqs_cis is not None: query = apply_rotary_emb(query, freqs_cis) key = apply_rotary_emb(key, freqs_cis) # Cast to correct dtype dtype = query.dtype query, key = query.to(dtype), key.to(dtype) # From [batch, seq_len] to appropriate mask format if attention_mask is not None and attention_mask.ndim == 2: if _HAS_DISPATCH_ATTENTION: # dispatch_attention_fn expects 4D mask: [batch, 1, 1, seq_len] attention_mask = attention_mask[:, None, None, :] else: # flash_attn: mask out inputs directly mask_expanded = attention_mask.unsqueeze(-1).unsqueeze(-1) # (B, S, 1, 1) query = query * mask_expanded key = key * mask_expanded value = value * mask_expanded # Compute joint attention if _HAS_DISPATCH_ATTENTION: hidden_states = dispatch_attention_fn( query, key, value, attn_mask=attention_mask, dropout_p=0.0, is_causal=False, backend=self._attention_backend, parallel_config=self._parallel_config, ) else: hidden_states = flash_attn_func( query, key, value, dropout_p=0.0, causal=False, ) # Reshape back hidden_states = hidden_states.flatten(2, 3) hidden_states = hidden_states.to(dtype) output = attn.to_out[0](hidden_states) if len(attn.to_out) > 1: # dropout output = attn.to_out[1](output) return output def select_per_token( value_noisy: torch.Tensor, value_clean: torch.Tensor, noise_mask: torch.Tensor, seq_len: int, ) -> torch.Tensor: noise_mask_expanded = noise_mask.unsqueeze(-1) # (batch, seq_len, 1) return torch.where( noise_mask_expanded == 1, value_noisy.unsqueeze(1).expand(-1, seq_len, -1), value_clean.unsqueeze(1).expand(-1, seq_len, -1), ) class FeedForward(nn.Module): def __init__(self, dim: int, hidden_dim: int): super().__init__() self.w1 = nn.Linear(dim, hidden_dim, bias=False) self.w2 = nn.Linear(hidden_dim, dim, bias=False) self.w3 = nn.Linear(dim, hidden_dim, bias=False) def _forward_silu_gating(self, x1, x3): return F.silu(x1) * x3 def forward(self, x): return self.w2(self._forward_silu_gating(self.w1(x), self.w3(x))) @maybe_allow_in_graph class ZImageTransformerBlock(nn.Module): def __init__( self, layer_id: int, dim: int, n_heads: int, n_kv_heads: int, norm_eps: float, qk_norm: bool, modulation=True, ): super().__init__() self.dim = dim self.head_dim = dim // n_heads # Refactored to use diffusers Attention with custom processor # Original Z-Image params: dim, n_heads, n_kv_heads, qk_norm self.attention = Attention( query_dim=dim, cross_attention_dim=None, dim_head=dim // n_heads, heads=n_heads, qk_norm="rms_norm" if qk_norm else None, eps=1e-5, bias=False, out_bias=False, processor=ZSingleStreamAttnProcessor(), ) self.feed_forward = FeedForward(dim=dim, hidden_dim=int(dim / 3 * 8)) self.layer_id = layer_id self.attention_norm1 = RMSNorm(dim, eps=norm_eps) self.ffn_norm1 = RMSNorm(dim, eps=norm_eps) self.attention_norm2 = RMSNorm(dim, eps=norm_eps) self.ffn_norm2 = RMSNorm(dim, eps=norm_eps) self.modulation = modulation if modulation: self.adaLN_modulation = nn.Sequential(nn.Linear(min(dim, ADALN_EMBED_DIM), 4 * dim, bias=True)) def forward( self, x: torch.Tensor, attn_mask: torch.Tensor, freqs_cis: torch.Tensor, adaln_input: Optional[torch.Tensor] = None, noise_mask: Optional[torch.Tensor] = None, adaln_noisy: Optional[torch.Tensor] = None, adaln_clean: Optional[torch.Tensor] = None, ): if self.modulation: seq_len = x.shape[1] if noise_mask is not None: # Per-token modulation: different modulation for noisy/clean tokens mod_noisy = self.adaLN_modulation(adaln_noisy) mod_clean = self.adaLN_modulation(adaln_clean) scale_msa_noisy, gate_msa_noisy, scale_mlp_noisy, gate_mlp_noisy = mod_noisy.chunk(4, dim=1) scale_msa_clean, gate_msa_clean, scale_mlp_clean, gate_mlp_clean = mod_clean.chunk(4, dim=1) gate_msa_noisy, gate_mlp_noisy = gate_msa_noisy.tanh(), gate_mlp_noisy.tanh() gate_msa_clean, gate_mlp_clean = gate_msa_clean.tanh(), gate_mlp_clean.tanh() scale_msa_noisy, scale_mlp_noisy = 1.0 + scale_msa_noisy, 1.0 + scale_mlp_noisy scale_msa_clean, scale_mlp_clean = 1.0 + scale_msa_clean, 1.0 + scale_mlp_clean scale_msa = select_per_token(scale_msa_noisy, scale_msa_clean, noise_mask, seq_len) scale_mlp = select_per_token(scale_mlp_noisy, scale_mlp_clean, noise_mask, seq_len) gate_msa = select_per_token(gate_msa_noisy, gate_msa_clean, noise_mask, seq_len) gate_mlp = select_per_token(gate_mlp_noisy, gate_mlp_clean, noise_mask, seq_len) else: # Global modulation: same modulation for all tokens (avoid double select) mod = self.adaLN_modulation(adaln_input) scale_msa, gate_msa, scale_mlp, gate_mlp = mod.unsqueeze(1).chunk(4, dim=2) gate_msa, gate_mlp = gate_msa.tanh(), gate_mlp.tanh() scale_msa, scale_mlp = 1.0 + scale_msa, 1.0 + scale_mlp # Attention block attn_out = self.attention( self.attention_norm1(x) * scale_msa, attention_mask=attn_mask, freqs_cis=freqs_cis ) x = x + gate_msa * self.attention_norm2(attn_out) # FFN block x = x + gate_mlp * self.ffn_norm2(self.feed_forward(self.ffn_norm1(x) * scale_mlp)) else: # Attention block attn_out = self.attention(self.attention_norm1(x), attention_mask=attn_mask, freqs_cis=freqs_cis) x = x + self.attention_norm2(attn_out) # FFN block x = x + self.ffn_norm2(self.feed_forward(self.ffn_norm1(x))) return x class FinalLayer(nn.Module): def __init__(self, hidden_size, out_channels): super().__init__() self.norm_final = nn.LayerNorm(hidden_size, elementwise_affine=False, eps=1e-6) self.linear = nn.Linear(hidden_size, out_channels, bias=True) self.adaLN_modulation = nn.Sequential( nn.SiLU(), nn.Linear(min(hidden_size, ADALN_EMBED_DIM), hidden_size, bias=True), ) def forward(self, x, c=None, noise_mask=None, c_noisy=None, c_clean=None): seq_len = x.shape[1] if noise_mask is not None: # Per-token modulation scale_noisy = 1.0 + self.adaLN_modulation(c_noisy) scale_clean = 1.0 + self.adaLN_modulation(c_clean) scale = select_per_token(scale_noisy, scale_clean, noise_mask, seq_len) else: # Original global modulation assert c is not None, "Either c or (c_noisy, c_clean) must be provided" scale = 1.0 + self.adaLN_modulation(c) scale = scale.unsqueeze(1) x = self.norm_final(x) * scale x = self.linear(x) return x class RopeEmbedder: def __init__( self, theta: float = 256.0, axes_dims: List[int] = (16, 56, 56), axes_lens: List[int] = (64, 128, 128), ): self.theta = theta self.axes_dims = axes_dims self.axes_lens = axes_lens assert len(axes_dims) == len(axes_lens), "axes_dims and axes_lens must have the same length" self.freqs_cis = None @staticmethod def precompute_freqs_cis(dim: List[int], end: List[int], theta: float = 256.0): with torch.device("cpu"): freqs_cis = [] for i, (d, e) in enumerate(zip(dim, end)): freqs = 1.0 / (theta ** (torch.arange(0, d, 2, dtype=torch.float64, device="cpu") / d)) timestep = torch.arange(e, device=freqs.device, dtype=torch.float64) freqs = torch.outer(timestep, freqs).float() freqs_cis_i = torch.polar(torch.ones_like(freqs), freqs).to(torch.complex64) # complex64 freqs_cis.append(freqs_cis_i) return freqs_cis def __call__(self, ids: torch.Tensor): assert ids.ndim == 2 assert ids.shape[-1] == len(self.axes_dims) device = ids.device if self.freqs_cis is None: self.freqs_cis = self.precompute_freqs_cis(self.axes_dims, self.axes_lens, theta=self.theta) self.freqs_cis = [freqs_cis.to(device) for freqs_cis in self.freqs_cis] else: # Ensure freqs_cis are on the same device as ids if self.freqs_cis[0].device != device: self.freqs_cis = [freqs_cis.to(device) for freqs_cis in self.freqs_cis] result = [] for i in range(len(self.axes_dims)): index = ids[:, i] result.append(self.freqs_cis[i][index]) return torch.cat(result, dim=-1) class ZImageTransformer2DModel(ModelMixin, ConfigMixin, PeftAdapterMixin, FromOriginalModelMixin): _supports_gradient_checkpointing = True _no_split_modules = ["ZImageTransformerBlock"] _repeated_blocks = ["ZImageTransformerBlock"] _skip_layerwise_casting_patterns = ["t_embedder", "cap_embedder"] # precision sensitive layers @register_to_config def __init__( self, all_patch_size=(2,), all_f_patch_size=(1,), in_channels=16, dim=3840, n_layers=30, n_refiner_layers=2, n_heads=30, n_kv_heads=30, norm_eps=1e-5, qk_norm=True, cap_feat_dim=2560, siglip_feat_dim=None, # Optional: set to enable SigLIP support for Omni rope_theta=256.0, t_scale=1000.0, axes_dims=[32, 48, 48], axes_lens=[1024, 512, 512], ) -> None: super().__init__() self.in_channels = in_channels self.out_channels = in_channels self.all_patch_size = all_patch_size self.all_f_patch_size = all_f_patch_size self.dim = dim self.n_heads = n_heads self.rope_theta = rope_theta self.t_scale = t_scale self.gradient_checkpointing = False assert len(all_patch_size) == len(all_f_patch_size) all_x_embedder = {} all_final_layer = {} for patch_idx, (patch_size, f_patch_size) in enumerate(zip(all_patch_size, all_f_patch_size)): x_embedder = nn.Linear(f_patch_size * patch_size * patch_size * in_channels, dim, bias=True) all_x_embedder[f"{patch_size}-{f_patch_size}"] = x_embedder final_layer = FinalLayer(dim, patch_size * patch_size * f_patch_size * self.out_channels) all_final_layer[f"{patch_size}-{f_patch_size}"] = final_layer self.all_x_embedder = nn.ModuleDict(all_x_embedder) self.all_final_layer = nn.ModuleDict(all_final_layer) self.noise_refiner = nn.ModuleList( [ ZImageTransformerBlock( 1000 + layer_id, dim, n_heads, n_kv_heads, norm_eps, qk_norm, modulation=True, ) for layer_id in range(n_refiner_layers) ] ) self.context_refiner = nn.ModuleList( [ ZImageTransformerBlock( layer_id, dim, n_heads, n_kv_heads, norm_eps, qk_norm, modulation=False, ) for layer_id in range(n_refiner_layers) ] ) self.t_embedder = TimestepEmbedder(min(dim, ADALN_EMBED_DIM), mid_size=1024) # self.cap_embedder = nn.Sequential(RMSNorm(cap_feat_dim, eps=norm_eps), nn.Linear(cap_feat_dim, dim, bias=True)) self.semantic_embedder = nn.Sequential(RMSNorm(cap_feat_dim, eps=norm_eps), nn.Linear(cap_feat_dim, dim, bias=True)) # Optional SigLIP components (for Omni variant) if siglip_feat_dim is not None: self.siglip_embedder = nn.Sequential( RMSNorm(siglip_feat_dim, eps=norm_eps), nn.Linear(siglip_feat_dim, dim, bias=True) ) self.siglip_refiner = nn.ModuleList( [ ZImageTransformerBlock( 2000 + layer_id, dim, n_heads, n_kv_heads, norm_eps, qk_norm, modulation=False, ) for layer_id in range(n_refiner_layers) ] ) self.siglip_pad_token = nn.Parameter(torch.empty((1, dim))) else: self.siglip_embedder = None self.siglip_refiner = None self.siglip_pad_token = None self.x_pad_token = nn.Parameter(torch.empty((1, dim))) self.cap_pad_token = nn.Parameter(torch.empty((1, dim))) self.layers = nn.ModuleList( [ ZImageTransformerBlock(layer_id, dim, n_heads, n_kv_heads, norm_eps, qk_norm) for layer_id in range(n_layers) ] ) head_dim = dim // n_heads assert head_dim == sum(axes_dims) self.axes_dims = axes_dims self.axes_lens = axes_lens self.rope_embedder = RopeEmbedder(theta=rope_theta, axes_dims=axes_dims, axes_lens=axes_lens) def unpatchify( self, x: List[torch.Tensor], size: List[Tuple], patch_size, f_patch_size, x_pos_offsets: Optional[List[Tuple[int, int]]] = None, ) -> List[torch.Tensor]: pH = pW = patch_size pF = f_patch_size bsz = len(x) assert len(size) == bsz if x_pos_offsets is not None: # Omni: extract target image from unified sequence (cond_images + target) result = [] for i in range(bsz): unified_x = x[i][x_pos_offsets[i][0] : x_pos_offsets[i][1]] cu_len = 0 x_item = None for j in range(len(size[i])): if size[i][j] is None: ori_len = 0 pad_len = SEQ_MULTI_OF cu_len += pad_len + ori_len else: F, H, W = size[i][j] ori_len = (F // pF) * (H // pH) * (W // pW) pad_len = (-ori_len) % SEQ_MULTI_OF x_item = ( unified_x[cu_len : cu_len + ori_len] .view(F // pF, H // pH, W // pW, pF, pH, pW, self.out_channels) .permute(6, 0, 3, 1, 4, 2, 5) .reshape(self.out_channels, F, H, W) ) cu_len += ori_len + pad_len result.append(x_item) # Return only the last (target) image return result else: # Original mode: simple unpatchify for i in range(bsz): F, H, W = size[i] ori_len = (F // pF) * (H // pH) * (W // pW) # "f h w pf ph pw c -> c (f pf) (h ph) (w pw)" x[i] = ( x[i][:ori_len] .view(F // pF, H // pH, W // pW, pF, pH, pW, self.out_channels) .permute(6, 0, 3, 1, 4, 2, 5) .reshape(self.out_channels, F, H, W) ) return x @staticmethod def create_coordinate_grid(size, start=None, device=None): if start is None: start = (0 for _ in size) axes = [torch.arange(x0, x0 + span, dtype=torch.int32, device=device) for x0, span in zip(start, size)] grids = torch.meshgrid(axes, indexing="ij") return torch.stack(grids, dim=-1) def _patchify_image(self, image: torch.Tensor, patch_size: int, f_patch_size: int): """Patchify a single image tensor: (C, F, H, W) -> (num_patches, patch_dim).""" pH, pW, pF = patch_size, patch_size, f_patch_size C, F, H, W = image.size() F_tokens, H_tokens, W_tokens = F // pF, H // pH, W // pW image = image.view(C, F_tokens, pF, H_tokens, pH, W_tokens, pW) image = image.permute(1, 3, 5, 2, 4, 6, 0).reshape(F_tokens * H_tokens * W_tokens, pF * pH * pW * C) return image, (F, H, W), (F_tokens, H_tokens, W_tokens) def _pad_with_ids( self, feat: torch.Tensor, pos_grid_size: Tuple, pos_start: Tuple, device: torch.device, noise_mask_val: Optional[int] = None, ): """Pad feature to SEQ_MULTI_OF, create position IDs and pad mask.""" ori_len = len(feat) pad_len = (-ori_len) % SEQ_MULTI_OF total_len = ori_len + pad_len # Pos IDs ori_pos_ids = self.create_coordinate_grid(size=pos_grid_size, start=pos_start, device=device).flatten(0, 2) if pad_len > 0: pad_pos_ids = ( self.create_coordinate_grid(size=(1, 1, 1), start=(0, 0, 0), device=device) .flatten(0, 2) .repeat(pad_len, 1) ) pos_ids = torch.cat([ori_pos_ids, pad_pos_ids], dim=0) padded_feat = torch.cat([feat, feat[-1:].repeat(pad_len, 1)], dim=0) pad_mask = torch.cat( [ torch.zeros(ori_len, dtype=torch.bool, device=device), torch.ones(pad_len, dtype=torch.bool, device=device), ] ) else: pos_ids = ori_pos_ids padded_feat = feat pad_mask = torch.zeros(ori_len, dtype=torch.bool, device=device) noise_mask = [noise_mask_val] * total_len if noise_mask_val is not None else None # token level return padded_feat, pos_ids, pad_mask, total_len, noise_mask def patchify_and_embed( self, all_image: List[torch.Tensor], all_cap_feats: List[torch.Tensor], patch_size: int, f_patch_size: int ): """Patchify for basic mode: single image per batch item.""" device = all_image[0].device all_img_out, all_img_size, all_img_pos_ids, all_img_pad_mask = [], [], [], [] all_cap_out, all_cap_pos_ids, all_cap_pad_mask = [], [], [] for image, cap_feat in zip(all_image, all_cap_feats): # Caption cap_out, cap_pos_ids, cap_pad_mask, cap_len, _ = self._pad_with_ids( cap_feat, (len(cap_feat) + (-len(cap_feat)) % SEQ_MULTI_OF, 1, 1), (1, 0, 0), device ) all_cap_out.append(cap_out) all_cap_pos_ids.append(cap_pos_ids) all_cap_pad_mask.append(cap_pad_mask) # Image img_patches, size, (F_t, H_t, W_t) = self._patchify_image(image, patch_size, f_patch_size) img_out, img_pos_ids, img_pad_mask, _, _ = self._pad_with_ids( img_patches, (F_t, H_t, W_t), (cap_len + 1, 0, 0), device ) all_img_out.append(img_out) all_img_size.append(size) all_img_pos_ids.append(img_pos_ids) all_img_pad_mask.append(img_pad_mask) return ( all_img_out, all_cap_out, all_img_size, all_img_pos_ids, all_cap_pos_ids, all_img_pad_mask, all_cap_pad_mask, ) def patchify_and_embed_omni( self, all_x: List[List[torch.Tensor]], all_cap_feats: List[List[torch.Tensor]], all_siglip_feats: List[List[torch.Tensor]], patch_size: int, f_patch_size: int, images_noise_mask: List[List[int]], ): """Patchify for omni mode: multiple images per batch item with noise masks.""" bsz = len(all_x) device = all_x[0][-1].device dtype = all_x[0][-1].dtype all_x_out, all_x_size, all_x_pos_ids, all_x_pad_mask, all_x_len, all_x_noise_mask = [], [], [], [], [], [] all_cap_out, all_cap_pos_ids, all_cap_pad_mask, all_cap_len, all_cap_noise_mask = [], [], [], [], [] all_sig_out, all_sig_pos_ids, all_sig_pad_mask, all_sig_len, all_sig_noise_mask = [], [], [], [], [] for i in range(bsz): num_images = len(all_x[i]) cap_feats_list, cap_pos_list, cap_mask_list, cap_lens, cap_noise = [], [], [], [], [] cap_end_pos = [] cap_cu_len = 1 # Process captions for j, cap_item in enumerate(all_cap_feats[i]): noise_val = images_noise_mask[i][j] if j < len(images_noise_mask[i]) else 1 cap_out, cap_pos, cap_mask, cap_len, cap_nm = self._pad_with_ids( cap_item, (len(cap_item) + (-len(cap_item)) % SEQ_MULTI_OF, 1, 1), (cap_cu_len, 0, 0), device, noise_val, ) cap_feats_list.append(cap_out) cap_pos_list.append(cap_pos) cap_mask_list.append(cap_mask) cap_lens.append(cap_len) cap_noise.extend(cap_nm) cap_cu_len += len(cap_item) cap_end_pos.append(cap_cu_len) cap_cu_len += 2 # for image vae and siglip tokens all_cap_out.append(torch.cat(cap_feats_list, dim=0)) all_cap_pos_ids.append(torch.cat(cap_pos_list, dim=0)) all_cap_pad_mask.append(torch.cat(cap_mask_list, dim=0)) all_cap_len.append(cap_lens) all_cap_noise_mask.append(cap_noise) # Process images x_feats_list, x_pos_list, x_mask_list, x_lens, x_size, x_noise = [], [], [], [], [], [] for j, x_item in enumerate(all_x[i]): noise_val = images_noise_mask[i][j] if x_item is not None: x_patches, size, (F_t, H_t, W_t) = self._patchify_image(x_item, patch_size, f_patch_size) x_out, x_pos, x_mask, x_len, x_nm = self._pad_with_ids( x_patches, (F_t, H_t, W_t), (cap_end_pos[j], 0, 0), device, noise_val ) x_size.append(size) else: x_len = SEQ_MULTI_OF x_out = torch.zeros((x_len, X_PAD_DIM), dtype=dtype, device=device) x_pos = self.create_coordinate_grid((1, 1, 1), (0, 0, 0), device).flatten(0, 2).repeat(x_len, 1) x_mask = torch.ones(x_len, dtype=torch.bool, device=device) x_nm = [noise_val] * x_len x_size.append(None) x_feats_list.append(x_out) x_pos_list.append(x_pos) x_mask_list.append(x_mask) x_lens.append(x_len) x_noise.extend(x_nm) all_x_out.append(torch.cat(x_feats_list, dim=0)) all_x_pos_ids.append(torch.cat(x_pos_list, dim=0)) all_x_pad_mask.append(torch.cat(x_mask_list, dim=0)) all_x_size.append(x_size) all_x_len.append(x_lens) all_x_noise_mask.append(x_noise) # Process siglip if all_siglip_feats[i] is None: all_sig_len.append([0] * num_images) all_sig_out.append(None) else: sig_feats_list, sig_pos_list, sig_mask_list, sig_lens, sig_noise = [], [], [], [], [] for j, sig_item in enumerate(all_siglip_feats[i]): noise_val = images_noise_mask[i][j] if sig_item is not None: sig_H, sig_W, sig_C = sig_item.size() sig_flat = sig_item.permute(2, 0, 1).reshape(sig_H * sig_W, sig_C) sig_out, sig_pos, sig_mask, sig_len, sig_nm = self._pad_with_ids( sig_flat, (1, sig_H, sig_W), (cap_end_pos[j] + 1, 0, 0), device, noise_val ) # Scale position IDs to match x resolution if x_size[j] is not None: sig_pos = sig_pos.float() sig_pos[..., 1] = sig_pos[..., 1] / max(sig_H - 1, 1) * (x_size[j][1] - 1) sig_pos[..., 2] = sig_pos[..., 2] / max(sig_W - 1, 1) * (x_size[j][2] - 1) sig_pos = sig_pos.to(torch.int32) else: sig_len = SEQ_MULTI_OF sig_out = torch.zeros((sig_len, self.config.siglip_feat_dim), dtype=dtype, device=device) sig_pos = ( self.create_coordinate_grid((1, 1, 1), (0, 0, 0), device).flatten(0, 2).repeat(sig_len, 1) ) sig_mask = torch.ones(sig_len, dtype=torch.bool, device=device) sig_nm = [noise_val] * sig_len sig_feats_list.append(sig_out) sig_pos_list.append(sig_pos) sig_mask_list.append(sig_mask) sig_lens.append(sig_len) sig_noise.extend(sig_nm) all_sig_out.append(torch.cat(sig_feats_list, dim=0)) all_sig_pos_ids.append(torch.cat(sig_pos_list, dim=0)) all_sig_pad_mask.append(torch.cat(sig_mask_list, dim=0)) all_sig_len.append(sig_lens) all_sig_noise_mask.append(sig_noise) # Compute x position offsets all_x_pos_offsets = [(sum(all_cap_len[i]), sum(all_cap_len[i]) + sum(all_x_len[i])) for i in range(bsz)] return ( all_x_out, all_cap_out, all_sig_out, all_x_size, all_x_pos_ids, all_cap_pos_ids, all_sig_pos_ids, all_x_pad_mask, all_cap_pad_mask, all_sig_pad_mask, all_x_pos_offsets, all_x_noise_mask, all_cap_noise_mask, all_sig_noise_mask, ) def _prepare_sequence( self, feats: List[torch.Tensor], pos_ids: List[torch.Tensor], inner_pad_mask: List[torch.Tensor], pad_token: torch.nn.Parameter, noise_mask: Optional[List[List[int]]] = None, device: torch.device = None, ): """Prepare sequence: apply pad token, RoPE embed, pad to batch, create attention mask.""" item_seqlens = [len(f) for f in feats] max_seqlen = max(item_seqlens) bsz = len(feats) # Pad token feats_cat = torch.cat(feats, dim=0) feats_cat[torch.cat(inner_pad_mask)] = pad_token feats = list(feats_cat.split(item_seqlens, dim=0)) # RoPE freqs_cis = list(self.rope_embedder(torch.cat(pos_ids, dim=0)).split([len(p) for p in pos_ids], dim=0)) # Pad to batch feats = pad_sequence(feats, batch_first=True, padding_value=0.0) freqs_cis = pad_sequence(freqs_cis, batch_first=True, padding_value=0.0)[:, : feats.shape[1]] # Attention mask attn_mask = torch.zeros((bsz, max_seqlen), dtype=torch.bool, device=device) for i, seq_len in enumerate(item_seqlens): attn_mask[i, :seq_len] = 1 # Noise mask noise_mask_tensor = None if noise_mask is not None: noise_mask_tensor = pad_sequence( [torch.tensor(m, dtype=torch.long, device=device) for m in noise_mask], batch_first=True, padding_value=0, )[:, : feats.shape[1]] return feats, freqs_cis, attn_mask, item_seqlens, noise_mask_tensor def _build_unified_sequence( self, x: torch.Tensor, x_freqs: torch.Tensor, x_seqlens: List[int], x_noise_mask: Optional[List[List[int]]], cap: torch.Tensor, cap_freqs: torch.Tensor, cap_seqlens: List[int], cap_noise_mask: Optional[List[List[int]]], siglip: Optional[torch.Tensor], siglip_freqs: Optional[torch.Tensor], siglip_seqlens: Optional[List[int]], siglip_noise_mask: Optional[List[List[int]]], omni_mode: bool, device: torch.device, ): """Build unified sequence: x, cap, and optionally siglip. Basic mode order: [x, cap]; Omni mode order: [cap, x, siglip] """ bsz = len(x_seqlens) unified = [] unified_freqs = [] unified_noise_mask = [] for i in range(bsz): x_len, cap_len = x_seqlens[i], cap_seqlens[i] if omni_mode: # Omni: [cap, x, siglip] if siglip is not None and siglip_seqlens is not None: sig_len = siglip_seqlens[i] unified.append(torch.cat([cap[i][:cap_len], x[i][:x_len], siglip[i][:sig_len]])) unified_freqs.append( torch.cat([cap_freqs[i][:cap_len], x_freqs[i][:x_len], siglip_freqs[i][:sig_len]]) ) unified_noise_mask.append( torch.tensor( cap_noise_mask[i] + x_noise_mask[i] + siglip_noise_mask[i], dtype=torch.long, device=device ) ) else: unified.append(torch.cat([cap[i][:cap_len], x[i][:x_len]])) unified_freqs.append(torch.cat([cap_freqs[i][:cap_len], x_freqs[i][:x_len]])) unified_noise_mask.append( torch.tensor(cap_noise_mask[i] + x_noise_mask[i], dtype=torch.long, device=device) ) else: # Basic: [x, cap] unified.append(torch.cat([x[i][:x_len], cap[i][:cap_len]])) unified_freqs.append(torch.cat([x_freqs[i][:x_len], cap_freqs[i][:cap_len]])) # Compute unified seqlens if omni_mode: if siglip is not None and siglip_seqlens is not None: unified_seqlens = [a + b + c for a, b, c in zip(cap_seqlens, x_seqlens, siglip_seqlens)] else: unified_seqlens = [a + b for a, b in zip(cap_seqlens, x_seqlens)] else: unified_seqlens = [a + b for a, b in zip(x_seqlens, cap_seqlens)] max_seqlen = max(unified_seqlens) # Pad to batch unified = pad_sequence(unified, batch_first=True, padding_value=0.0) unified_freqs = pad_sequence(unified_freqs, batch_first=True, padding_value=0.0) # Attention mask attn_mask = torch.zeros((bsz, max_seqlen), dtype=torch.bool, device=device) for i, seq_len in enumerate(unified_seqlens): attn_mask[i, :seq_len] = 1 # Noise mask noise_mask_tensor = None if omni_mode: noise_mask_tensor = pad_sequence(unified_noise_mask, batch_first=True, padding_value=0)[ :, : unified.shape[1] ] return unified, unified_freqs, attn_mask, noise_mask_tensor def forward( self, x: Union[List[torch.Tensor], List[List[torch.Tensor]]], t, cap_feats: Union[List[torch.Tensor], List[List[torch.Tensor]]], return_dict: bool = True, controlnet_block_samples: Optional[Dict[int, torch.Tensor]] = None, siglip_feats: Optional[List[List[torch.Tensor]]] = None, image_noise_mask: Optional[List[List[int]]] = None, patch_size: int = 2, f_patch_size: int = 1, ): """ Flow: patchify -> t_embed -> x_embed -> x_refine -> cap_embed -> cap_refine -> [siglip_embed -> siglip_refine] -> build_unified -> main_layers -> final_layer -> unpatchify """ assert patch_size in self.all_patch_size and f_patch_size in self.all_f_patch_size omni_mode = isinstance(x[0], list) device = x[0][-1].device if omni_mode else x[0].device if omni_mode: # Dual embeddings: noisy (t) and clean (t=1) t_noisy = self.t_embedder(t * self.t_scale).type_as(x[0][-1]) t_clean = self.t_embedder(torch.ones_like(t) * self.t_scale).type_as(x[0][-1]) adaln_input = None else: # Single embedding for all tokens adaln_input = self.t_embedder(t * self.t_scale).type_as(x[0]) t_noisy = t_clean = None # Patchify if omni_mode: ( x, cap_feats, siglip_feats, x_size, x_pos_ids, cap_pos_ids, siglip_pos_ids, x_pad_mask, cap_pad_mask, siglip_pad_mask, x_pos_offsets, x_noise_mask, cap_noise_mask, siglip_noise_mask, ) = self.patchify_and_embed_omni(x, cap_feats, siglip_feats, patch_size, f_patch_size, image_noise_mask) else: ( x, cap_feats, x_size, x_pos_ids, cap_pos_ids, x_pad_mask, cap_pad_mask, ) = self.patchify_and_embed(x, cap_feats, patch_size, f_patch_size) x_pos_offsets = x_noise_mask = cap_noise_mask = siglip_noise_mask = None # X embed & refine x_seqlens = [len(xi) for xi in x] x = self.all_x_embedder[f"{patch_size}-{f_patch_size}"](torch.cat(x, dim=0)) # embed x, x_freqs, x_mask, _, x_noise_tensor = self._prepare_sequence( list(x.split(x_seqlens, dim=0)), x_pos_ids, x_pad_mask, self.x_pad_token, x_noise_mask, device ) for layer in self.noise_refiner: x = ( self._gradient_checkpointing_func( layer, x, x_mask, x_freqs, adaln_input, x_noise_tensor, t_noisy, t_clean ) if torch.is_grad_enabled() and self.gradient_checkpointing else layer(x, x_mask, x_freqs, adaln_input, x_noise_tensor, t_noisy, t_clean) ) # Cap embed & refine cap_seqlens = [len(ci) for ci in cap_feats] # cap_feats = self.cap_embedder(torch.cat(cap_feats, dim=0)) # embed cap_feats = self.semantic_embedder(torch.cat(cap_feats, dim=0)) cap_feats, cap_freqs, cap_mask, _, _ = self._prepare_sequence( list(cap_feats.split(cap_seqlens, dim=0)), cap_pos_ids, cap_pad_mask, self.cap_pad_token, None, device ) for layer in self.context_refiner: cap_feats = ( self._gradient_checkpointing_func(layer, cap_feats, cap_mask, cap_freqs) if torch.is_grad_enabled() and self.gradient_checkpointing else layer(cap_feats, cap_mask, cap_freqs) ) # Siglip embed & refine siglip_seqlens = siglip_freqs = None if omni_mode and siglip_feats[0] is not None and self.siglip_embedder is not None: siglip_seqlens = [len(si) for si in siglip_feats] siglip_feats = self.siglip_embedder(torch.cat(siglip_feats, dim=0)) # embed siglip_feats, siglip_freqs, siglip_mask, _, _ = self._prepare_sequence( list(siglip_feats.split(siglip_seqlens, dim=0)), siglip_pos_ids, siglip_pad_mask, self.siglip_pad_token, None, device, ) for layer in self.siglip_refiner: siglip_feats = ( self._gradient_checkpointing_func(layer, siglip_feats, siglip_mask, siglip_freqs) if torch.is_grad_enabled() and self.gradient_checkpointing else layer(siglip_feats, siglip_mask, siglip_freqs) ) # Unified sequence unified, unified_freqs, unified_mask, unified_noise_tensor = self._build_unified_sequence( x, x_freqs, x_seqlens, x_noise_mask, cap_feats, cap_freqs, cap_seqlens, cap_noise_mask, siglip_feats, siglip_freqs, siglip_seqlens, siglip_noise_mask, omni_mode, device, ) # Main transformer layers for layer_idx, layer in enumerate(self.layers): unified = ( self._gradient_checkpointing_func( layer, unified, unified_mask, unified_freqs, adaln_input, unified_noise_tensor, t_noisy, t_clean ) if torch.is_grad_enabled() and self.gradient_checkpointing else layer(unified, unified_mask, unified_freqs, adaln_input, unified_noise_tensor, t_noisy, t_clean) ) if controlnet_block_samples is not None and layer_idx in controlnet_block_samples: unified = unified + controlnet_block_samples[layer_idx] unified = ( self.all_final_layer[f"{patch_size}-{f_patch_size}"]( unified, noise_mask=unified_noise_tensor, c_noisy=t_noisy, c_clean=t_clean ) if omni_mode else self.all_final_layer[f"{patch_size}-{f_patch_size}"](unified, c=adaln_input) ) # Unpatchify x = self.unpatchify(list(unified.unbind(dim=0)), x_size, patch_size, f_patch_size, x_pos_offsets) return (x,) if not return_dict else Transformer2DModelOutput(sample=x)