# Copyright 2024-2025 The Alibaba Wan Team Authors. All rights reserved. import math import torch import torch.nn as nn from einops import repeat, rearrange from ...enhance_a_video.enhance import get_feta_scores import time from contextlib import nullcontext try: from ..radial_attention.attn_mask import RadialSpargeSageAttn, RadialSpargeSageAttnDense, MaskMap except: pass from .attention import attention import numpy as np from tqdm import tqdm import gc from ...utils import log, get_module_memory_mb from ...cache_methods.cache_methods import TeaCacheState, MagCacheState, EasyCacheState, relative_l1_distance from ...multitalk.multitalk import get_attn_map_with_target from ...echoshot.echoshot import rope_apply_z, rope_apply_c, rope_apply_echoshot from ...MTV.mtv import apply_rotary_emb class FramePackMotioner(nn.Module):#from comfy.ldm.wan.model def __init__( self, inner_dim=1024, num_heads=16, # Used to indicate the number of heads in the backbone network; unrelated to this module's design zip_frame_buckets=[1, 2, 16], # Three numbers representing the number of frames sampled for patch operations from the nearest to the farthest frames drop_mode="drop", # If not "drop", it will use "padd", meaning padding instead of deletion ): super().__init__() self.proj = nn.Conv3d(16, inner_dim, kernel_size=(1, 2, 2), stride=(1, 2, 2)) self.proj_2x = nn.Conv3d(16, inner_dim, kernel_size=(2, 4, 4), stride=(2, 4, 4)) self.proj_4x = nn.Conv3d(16, inner_dim, kernel_size=(4, 8, 8), stride=(4, 8, 8)) self.zip_frame_buckets = zip_frame_buckets self.inner_dim = inner_dim self.num_heads = num_heads self.drop_mode = drop_mode def forward(self, motion_latents, rope_embedder, add_last_motion=2): lat_height, lat_width = motion_latents.shape[3], motion_latents.shape[4] padd_lat = torch.zeros(motion_latents.shape[0], 16, sum(self.zip_frame_buckets), lat_height, lat_width).to(device=motion_latents.device, dtype=motion_latents.dtype) overlap_frame = min(padd_lat.shape[2], motion_latents.shape[2]) if overlap_frame > 0: padd_lat[:, :, -overlap_frame:] = motion_latents[:, :, -overlap_frame:] if add_last_motion < 2 and self.drop_mode != "drop": zero_end_frame = sum(self.zip_frame_buckets[:len(self.zip_frame_buckets) - add_last_motion - 1]) padd_lat[:, :, -zero_end_frame:] = 0 clean_latents_4x, clean_latents_2x, clean_latents_post = padd_lat[:, :, -sum(self.zip_frame_buckets):, :, :].split(self.zip_frame_buckets[::-1], dim=2) # 16, 2 ,1 # patchfy clean_latents_post = self.proj(clean_latents_post).flatten(2).transpose(1, 2) clean_latents_2x = self.proj_2x(clean_latents_2x) l_2x_shape = clean_latents_2x.shape clean_latents_2x = clean_latents_2x.flatten(2).transpose(1, 2) clean_latents_4x = self.proj_4x(clean_latents_4x) l_4x_shape = clean_latents_4x.shape clean_latents_4x = clean_latents_4x.flatten(2).transpose(1, 2) if add_last_motion < 2 and self.drop_mode == "drop": clean_latents_post = clean_latents_post[:, :0] if add_last_motion < 2 else clean_latents_post clean_latents_2x = clean_latents_2x[:, :0] if add_last_motion < 1 else clean_latents_2x motion_lat = torch.cat([clean_latents_post, clean_latents_2x, clean_latents_4x], dim=1) rope_post = rope_embedder.rope_encode_comfy(1, lat_height, lat_width, t_start=-1, device=motion_latents.device, dtype=motion_latents.dtype) rope_2x = rope_embedder.rope_encode_comfy(1, lat_height, lat_width, t_start=-3, steps_h=l_2x_shape[-2], steps_w=l_2x_shape[-1], device=motion_latents.device, dtype=motion_latents.dtype) rope_4x = rope_embedder.rope_encode_comfy(4, lat_height, lat_width, t_start=-19, steps_h=l_4x_shape[-2], steps_w=l_4x_shape[-1], device=motion_latents.device, dtype=motion_latents.dtype) rope = torch.cat([rope_post, rope_2x, rope_4x], dim=1) return motion_lat, rope from diffusers.models.attention import AdaLayerNorm __all__ = ['WanModel'] from comfy import model_management as mm def zero_module(module): """ Zero out the parameters of a module and return it. """ for p in module.parameters(): p.detach().zero_() return module def torch_dfs(model: nn.Module, parent_name='root'): module_names, modules = [], [] current_name = parent_name if parent_name else 'root' module_names.append(current_name) modules.append(model) for name, child in model.named_children(): if parent_name: child_name = f'{parent_name}.{name}' else: child_name = name child_modules, child_names = torch_dfs(child, child_name) module_names += child_names modules += child_modules return modules, module_names #from comfy.ldm.flux.math import apply_rope as apply_rope_comfy def apply_rope_comfy(xq, xk, freqs_cis): xq_ = xq.to(dtype=freqs_cis.dtype).reshape(*xq.shape[:-1], -1, 1, 2) xk_ = xk.to(dtype=freqs_cis.dtype).reshape(*xk.shape[:-1], -1, 1, 2) xq_out = freqs_cis[..., 0] * xq_[..., 0] + freqs_cis[..., 1] * xq_[..., 1] xk_out = freqs_cis[..., 0] * xk_[..., 0] + freqs_cis[..., 1] * xk_[..., 1] return xq_out.reshape(*xq.shape).type_as(xq), xk_out.reshape(*xk.shape).type_as(xk) def apply_rope_comfy_chunked(xq, xk, freqs_cis, num_chunks=4): seq_dim = 1 # Initialize output tensors xq_out = torch.empty_like(xq) xk_out = torch.empty_like(xk) # Calculate chunks seq_len = xq.shape[seq_dim] chunk_sizes = [seq_len // num_chunks + (1 if i < seq_len % num_chunks else 0) for i in range(num_chunks)] # First pass: process xq completely start_idx = 0 for size in chunk_sizes: end_idx = start_idx + size slices = [slice(None)] * len(xq.shape) slices[seq_dim] = slice(start_idx, end_idx) freq_slices = [slice(None)] * len(freqs_cis.shape) if seq_dim < len(freqs_cis.shape): freq_slices[seq_dim] = slice(start_idx, end_idx) freqs_chunk = freqs_cis[tuple(freq_slices)] xq_chunk = xq[tuple(slices)] xq_chunk_ = xq_chunk.to(dtype=freqs_cis.dtype).reshape(*xq_chunk.shape[:-1], -1, 1, 2) xq_out[tuple(slices)] = (freqs_chunk[..., 0] * xq_chunk_[..., 0] + freqs_chunk[..., 1] * xq_chunk_[..., 1]).reshape(*xq_chunk.shape).type_as(xq) del xq_chunk, xq_chunk_, freqs_chunk start_idx = end_idx # Second pass: process xk completely start_idx = 0 for size in chunk_sizes: end_idx = start_idx + size slices = [slice(None)] * len(xk.shape) slices[seq_dim] = slice(start_idx, end_idx) freq_slices = [slice(None)] * len(freqs_cis.shape) if seq_dim < len(freqs_cis.shape): freq_slices[seq_dim] = slice(start_idx, end_idx) freqs_chunk = freqs_cis[tuple(freq_slices)] xk_chunk = xk[tuple(slices)] xk_chunk_ = xk_chunk.to(dtype=freqs_cis.dtype).reshape(*xk_chunk.shape[:-1], -1, 1, 2) xk_out[tuple(slices)] = (freqs_chunk[..., 0] * xk_chunk_[..., 0] + freqs_chunk[..., 1] * xk_chunk_[..., 1]).reshape(*xk_chunk.shape).type_as(xk) del xk_chunk, xk_chunk_, freqs_chunk start_idx = end_idx return xq_out, xk_out def rope_riflex(pos, dim, i, theta, L_test, k, ntk_factor=1.0): assert dim % 2 == 0 if mm.is_device_mps(pos.device) or mm.is_intel_xpu() or mm.is_directml_enabled(): device = torch.device("cpu") else: device = pos.device if ntk_factor != 1.0: theta *= ntk_factor scale = torch.linspace(0, (dim - 2) / dim, steps=dim//2, dtype=torch.float64, device=device) omega = 1.0 / (theta**scale) # RIFLEX modification - adjust last frequency component if L_test and k are provided if i==0 and k > 0 and L_test: omega[k-1] = 0.9 * 2 * torch.pi / L_test out = torch.einsum("...n,d->...nd", pos.to(dtype=torch.float32, device=device), omega) out = torch.stack([torch.cos(out), -torch.sin(out), torch.sin(out), torch.cos(out)], dim=-1) out = rearrange(out, "b n d (i j) -> b n d i j", i=2, j=2) return out.to(dtype=torch.float32, device=pos.device) class EmbedND_RifleX(nn.Module): def __init__(self, dim, theta, axes_dim, num_frames, k): super().__init__() self.dim = dim self.theta = theta self.axes_dim = axes_dim self.num_frames = num_frames self.k = k def forward(self, ids, ntk_factor=[1.0,1.0,1.0]): n_axes = ids.shape[-1] emb = torch.cat( [rope_riflex( ids[..., i], self.axes_dim[i], i, #f h w self.theta, self.num_frames, self.k, ntk_factor[i]) for i in range(n_axes)], dim=-3, ) return emb.unsqueeze(1) def poly1d(coefficients, x): result = torch.zeros_like(x) for i, coeff in enumerate(coefficients): result += coeff * (x ** (len(coefficients) - 1 - i)) return result.abs() def sinusoidal_embedding_1d(dim, position): # preprocess assert dim % 2 == 0 half = dim // 2 position = position.type(torch.float32) # calculation sinusoid = torch.outer( position, torch.pow(10000, -torch.arange(half).to(position).div(half))) x = torch.cat([torch.cos(sinusoid), torch.sin(sinusoid)], dim=1) return x def rope_params(max_seq_len, dim, theta=10000, L_test=25, k=0): assert dim % 2 == 0 exponents = torch.arange(0, dim, 2, dtype=torch.float64).div(dim) inv_theta_pow = 1.0 / torch.pow(theta, exponents) if k > 0: print(f"RifleX: Using {k}th freq") inv_theta_pow[k-1] = 0.9 * 2 * torch.pi / L_test freqs = torch.outer(torch.arange(max_seq_len), inv_theta_pow) freqs = torch.polar(torch.ones_like(freqs), freqs) return freqs @torch.autocast(device_type=mm.get_autocast_device(mm.get_torch_device()), enabled=False) @torch.compiler.disable() def rope_apply(x, grid_sizes, freqs, reverse_time=False): n, c = x.size(2), x.size(3) // 2 # split freqs freqs = freqs.split([c - 2 * (c // 3), c // 3, c // 3], dim=1) # loop over samples output = [] for i, (f, h, w) in enumerate(grid_sizes.tolist()): seq_len = f * h * w # precompute multipliers x_i = torch.view_as_complex(x[i, :seq_len].to(torch.float64).reshape( seq_len, n, -1, 2)) if reverse_time: time_freqs = freqs[0][:f].view(f, 1, 1, -1) time_freqs = torch.flip(time_freqs, dims=[0]) time_freqs = time_freqs.expand(f, h, w, -1) spatial_freqs = torch.cat([ freqs[1][:h].view(1, h, 1, -1).expand(f, h, w, -1), freqs[2][:w].view(1, 1, w, -1).expand(f, h, w, -1) ], dim=-1) freqs_i = torch.cat([time_freqs, spatial_freqs], dim=-1).reshape(seq_len, 1, -1) else: freqs_i = torch.cat([ freqs[0][:f].view(f, 1, 1, -1).expand(f, h, w, -1), freqs[1][:h].view(1, h, 1, -1).expand(f, h, w, -1), freqs[2][:w].view(1, 1, w, -1).expand(f, h, w, -1) ], dim=-1).reshape(seq_len, 1, -1) # apply rotary embedding x_i = torch.view_as_real(x_i * freqs_i).flatten(2) x_i = torch.cat([x_i, x[i, seq_len:]]) # append to collection output.append(x_i) return torch.stack(output).to(x.dtype) class WanRMSNorm(nn.Module): def __init__(self, dim, eps=1e-5): super().__init__() self.dim = dim self.eps = eps self.weight = nn.Parameter(torch.ones(dim)) def forward(self, x, num_chunks=1): r""" Args: x(Tensor): Shape [B, L, C] """ use_chunked = num_chunks > 1 if use_chunked: return self.forward_chunked(x, num_chunks) else: return self._norm(x) * self.weight def _norm(self, x): return x * torch.rsqrt(x.pow(2).mean(dim=-1, keepdim=True) + self.eps).to(x.dtype) def forward_chunked(self, x, num_chunks=4): output = torch.empty_like(x) chunk_sizes = [x.shape[1] // num_chunks + (1 if i < x.shape[1] % num_chunks else 0) for i in range(num_chunks)] start_idx = 0 for size in chunk_sizes: end_idx = start_idx + size chunk = x[:, start_idx:end_idx, :] norm_factor = torch.rsqrt(chunk.pow(2).mean(dim=-1, keepdim=True) + self.eps) output[:, start_idx:end_idx, :] = chunk * norm_factor.to(chunk.dtype) * self.weight start_idx = end_idx return output class WanFusedRMSNorm(nn.RMSNorm): def forward(self, x, num_chunks=1): use_chunked = num_chunks > 1 if use_chunked: return self.forward_chunked(x, num_chunks) else: return super().forward(x) def forward_chunked(self, x, num_chunks=4): output = torch.empty_like(x) chunk_sizes = [x.shape[1] // num_chunks + (1 if i < x.shape[1] % num_chunks else 0) for i in range(num_chunks)] start_idx = 0 for size in chunk_sizes: end_idx = start_idx + size chunk = x[:, start_idx:end_idx, :] output[:, start_idx:end_idx, :] = super().forward(chunk) start_idx = end_idx return output class WanLayerNorm(nn.LayerNorm): def __init__(self, dim, eps=1e-6, elementwise_affine=False): super().__init__(dim, elementwise_affine=elementwise_affine, eps=eps) def forward(self, x): r""" Args: x(Tensor): Shape [B, L, C] """ return super().forward(x) class WanSelfAttention(nn.Module): def __init__(self, in_features, out_features, num_heads, qk_norm=True, eps=1e-6, attention_mode="sdpa", rms_norm_function="default", kv_dim=None): assert out_features % num_heads == 0 super().__init__() self.dim = out_features self.num_heads = num_heads self.head_dim = out_features // num_heads self.qk_norm = qk_norm self.eps = eps self.attention_mode = attention_mode #radial attention self.mask_map = None self.decay_factor = 0.2 self.cond_size = None self.ref_adapter = None # layers self.q = nn.Linear(in_features, out_features) if kv_dim is not None: self.k = nn.Linear(kv_dim, out_features) self.v = nn.Linear(kv_dim, out_features) else: self.k = nn.Linear(in_features, out_features) self.v = nn.Linear(in_features, out_features) self.o = nn.Linear(in_features, out_features) if rms_norm_function=="pytorch": self.norm_q = WanFusedRMSNorm(out_features, eps=eps) if qk_norm else nn.Identity() self.norm_k = WanFusedRMSNorm(out_features, eps=eps) if qk_norm else nn.Identity() else: self.norm_q = WanRMSNorm(out_features, eps=eps) if qk_norm else nn.Identity() self.norm_k = WanRMSNorm(out_features, eps=eps) if qk_norm else nn.Identity() def qkv_fn(self, x): b, s, n, d = *x.shape[:2], self.num_heads, self.head_dim q = self.norm_q(self.q(x)).view(b, s, n, d) k = self.norm_k(self.k(x)).view(b, s, n, d) v = self.v(x).view(b, s, n, d) return q, k, v def qkv_fn_ip(self, x): b, s, n, d = *x.shape[:2], self.num_heads, self.head_dim q = self.norm_q(self.q(x) + self.q_loras(x)).view(b, s, n, d) k = self.norm_k(self.k(x) + self.k_loras(x)).view(b, s, n, d) v = (self.v(x) + self.v_loras(x)).view(b, s, n, d) return q, k, v def forward(self, q, k, v, seq_lens, lynx_ref_feature=None, lynx_ref_scale=1.0, attention_mode_override=None): r""" Args: x(Tensor): Shape [B, L, num_heads, C / num_heads] seq_lens(Tensor): Shape [B] grid_sizes(Tensor): Shape [B, 3], the second dimension contains (F, H, W) freqs(Tensor): Rope freqs, shape [1024, C / num_heads / 2] """ attention_mode = self.attention_mode if attention_mode_override is not None: attention_mode = attention_mode_override if self.ref_adapter is not None and lynx_ref_feature is not None: ref_x = self.ref_adapter(self, q, lynx_ref_feature) x = attention(q, k, v, k_lens=seq_lens, attention_mode=attention_mode) if self.ref_adapter is not None and lynx_ref_feature is not None: x = x.add(ref_x, alpha=lynx_ref_scale) # output return self.o(x.flatten(2)) def forward_ip(self, q, k, v, q_ip, k_ip, v_ip, seq_lens, attention_mode_override=None): attention_mode = self.attention_mode if attention_mode_override is not None: attention_mode = attention_mode_override # Concatenate main and IP keys/values for main attention full_k = torch.cat([k, k_ip], dim=1) full_v = torch.cat([v, v_ip], dim=1) main_out = attention(q, full_k, full_v, k_lens=seq_lens, attention_mode=attention_mode) cond_out = attention(q_ip, k_ip, v_ip, k_lens=seq_lens, attention_mode=attention_mode) x = torch.cat([main_out, cond_out], dim=1) return self.o(x.flatten(2)) def forward_radial(self, q, k, v, dense_step=False): if dense_step: x = RadialSpargeSageAttnDense(q, k, v, self.mask_map) else: x = RadialSpargeSageAttn(q, k, v, self.mask_map, decay_factor=self.decay_factor) return self.o(x.flatten(2)) def forward_multitalk(self, q, k, v, seq_lens, grid_sizes, ref_target_masks): x = attention( q, k, v, k_lens=seq_lens, attention_mode=self.attention_mode ) # output x = x.flatten(2) x = self.o(x) x_ref_attn_map = get_attn_map_with_target(q.type_as(x), k.type_as(x), grid_sizes[0], ref_target_masks=ref_target_masks) return x, x_ref_attn_map def forward_split(self, q, k, v, seq_lens, grid_sizes, freqs, seq_chunks=1,current_step=0, video_attention_split_steps = []): r""" Args: x(Tensor): Shape [B, L, num_heads, C / num_heads] seq_lens(Tensor): Shape [B] grid_sizes(Tensor): Shape [B, 3], the second dimension contains (F, H, W) freqs(Tensor): Rope freqs, shape [1024, C / num_heads / 2] """ # Split by frames if multiple prompts are provided if seq_chunks > 1 and current_step in video_attention_split_steps: outputs = [] # Extract frame, height, width from grid_sizes frames = grid_sizes[0][0] height = grid_sizes[0][1] width = grid_sizes[0][2] tokens_per_frame = height * width actual_chunks = torch.min(torch.tensor(seq_chunks, device=frames.device), frames) base_frames_per_chunk = frames // actual_chunks extra_frames = frames % actual_chunks # Calculate all chunk boundaries chunk_indices = torch.arange(actual_chunks, device=frames.device) chunk_sizes = base_frames_per_chunk + (chunk_indices < extra_frames).long() chunk_starts = torch.cumsum(torch.cat([torch.zeros(1, device=frames.device), chunk_sizes[:-1]]), dim=0).long() chunk_ends = chunk_starts + chunk_sizes # Process each chunk using tensor indexing for i in range(actual_chunks.item()): start_frame = chunk_starts[i] end_frame = chunk_ends[i] # Convert to token indices using tensor operations start_idx = start_frame * tokens_per_frame end_idx = end_frame * tokens_per_frame chunk_q = q[:, start_idx:end_idx, :, :] chunk_k = k[:, start_idx:end_idx, :, :] chunk_v = v[:, start_idx:end_idx, :, :] chunk_out = attention( q=chunk_q, k=chunk_k, v=chunk_v, k_lens=seq_lens, attention_mode=self.attention_mode) outputs.append(chunk_out) # Concatenate outputs along the sequence dimension x = torch.cat(outputs, dim=1) else: # Original attention computation x = attention( q=q, k=k, v=v, k_lens=seq_lens, attention_mode=self.attention_mode) # output x = x.flatten(2) x = self.o(x) return x def normalized_attention_guidance(self, b, n, d, q, context, nag_context=None, nag_params={}): # NAG text attention context_positive = context context_negative = nag_context nag_scale = nag_params['nag_scale'] nag_alpha = nag_params['nag_alpha'] nag_tau = nag_params['nag_tau'] k_positive = self.norm_k(self.k(context_positive)).view(b, -1, n, d) v_positive = self.v(context_positive).view(b, -1, n, d) k_negative = self.norm_k(self.k(context_negative)).view(b, -1, n, d) v_negative = self.v(context_negative).view(b, -1, n, d) x_positive = attention(q, k_positive, v_positive, attention_mode=self.attention_mode) x_positive = x_positive.flatten(2) x_negative = attention(q, k_negative, v_negative, attention_mode=self.attention_mode) x_negative = x_negative.flatten(2) nag_guidance = x_positive * nag_scale - x_negative * (nag_scale - 1) norm_positive = torch.norm(x_positive, p=1, dim=-1, keepdim=True) norm_guidance = torch.norm(nag_guidance, p=1, dim=-1, keepdim=True) scale = norm_guidance / norm_positive scale = torch.nan_to_num(scale, nan=10.0) mask = scale > nag_tau adjustment = (norm_positive * nag_tau) / (norm_guidance + 1e-7) nag_guidance = torch.where(mask, nag_guidance * adjustment, nag_guidance) del mask, adjustment return nag_guidance * nag_alpha + x_positive * (1 - nag_alpha) class LoRALinearLayer(nn.Module): def __init__( self, in_features: int, out_features: int, rank: int = 128, device=torch.device("cuda"), dtype=torch.float32, strength: float = 1.0 ): super().__init__() self.down = nn.Linear(in_features, rank, bias=False, device=device, dtype=dtype) self.up = nn.Linear(rank, out_features, bias=False, device=device, dtype=dtype) self.rank = rank self.out_features = out_features self.in_features = in_features self.strength = strength nn.init.normal_(self.down.weight, std=1 / rank) nn.init.zeros_(self.up.weight) def forward(self, hidden_states: torch.Tensor) -> torch.Tensor: orig_dtype = hidden_states.dtype dtype = self.down.weight.dtype down_hidden_states = self.down(hidden_states.to(dtype)) up_hidden_states = self.up(down_hidden_states) * self.strength return up_hidden_states.to(orig_dtype) #region crossattn class WanT2VCrossAttention(WanSelfAttention): def __init__(self, in_features, out_features, num_heads, kv_dim=None, qk_norm=True, eps=1e-6, attention_mode='sdpa', rms_norm_function="default"): super().__init__(in_features, out_features, num_heads, qk_norm, eps, kv_dim=kv_dim, rms_norm_function=rms_norm_function) self.attention_mode = attention_mode self.ip_adapter = None def forward(self, x, context, grid_sizes=None, clip_embed=None, audio_proj=None, audio_scale=1.0, num_latent_frames=21, nag_params={}, nag_context=None, is_uncond=False, rope_func="comfy", inner_t=None, inner_c=None, cross_freqs=None, adapter_proj=None, adapter_attn_mask=None, ip_scale=1.0, orig_seq_len=None, lynx_x_ip=None, lynx_ip_scale=1.0, **kwargs): b, n, d = x.size(0), self.num_heads, self.head_dim # compute query q = self.norm_q(self.q(x),num_chunks=2 if rope_func == "comfy_chunked" else 1).view(b, -1, n, d) if nag_context is not None and not is_uncond: x = self.normalized_attention_guidance(b, n, d, q, context, nag_context, nag_params) else: k = self.norm_k(self.k(context)).view(b, -1, n, d) v = self.v(context).view(b, -1, n, d) #EchoShot rope if inner_t is not None and cross_freqs is not None and not is_uncond: q = rope_apply_z(q, grid_sizes, cross_freqs, inner_t).to(q) k = rope_apply_c(k, cross_freqs, inner_c).to(q) x = attention(q, k, v, attention_mode=self.attention_mode).flatten(2) if lynx_x_ip is not None and self.ip_adapter is not None and ip_scale !=0: lynx_x_ip = self.ip_adapter(self, q, lynx_x_ip) x = x.add(lynx_x_ip, alpha=lynx_ip_scale) # FantasyTalking audio attention if audio_proj is not None: if len(audio_proj.shape) == 4: audio_q = q.view(b * num_latent_frames, -1, n, d) ip_key = self.k_proj(audio_proj).view(b * num_latent_frames, -1, n, d) ip_value = self.v_proj(audio_proj).view(b * num_latent_frames, -1, n, d) audio_x = attention(audio_q, ip_key, ip_value, attention_mode=self.attention_mode) audio_x = audio_x.view(b, q.size(1), n, d).flatten(2) elif len(audio_proj.shape) == 3: ip_key = self.k_proj(audio_proj).view(b, -1, n, d) ip_value = self.v_proj(audio_proj).view(b, -1, n, d) audio_x = attention(q, ip_key, ip_value, attention_mode=self.attention_mode).flatten(2) x = x + audio_x * audio_scale # FantasyPortrait adapter attention if adapter_proj is not None: if len(adapter_proj.shape) == 4: q_in = q[:, :orig_seq_len] adapter_q = q_in.view(b * num_latent_frames, -1, n, d) ip_key = self.ip_adapter_single_stream_k_proj(adapter_proj).view(b * num_latent_frames, -1, n, d) ip_value = self.ip_adapter_single_stream_v_proj(adapter_proj).view(b * num_latent_frames, -1, n, d) adapter_x = attention(adapter_q, ip_key, ip_value, attention_mode=self.attention_mode) adapter_x = adapter_x.view(b, q_in.size(1), n, d) adapter_x = adapter_x.flatten(2) elif len(adapter_proj.shape) == 3: ip_key = self.ip_adapter_single_stream_k_proj(adapter_proj).view(b, -1, n, d) ip_value = self.ip_adapter_single_stream_v_proj(adapter_proj).view(b, -1, n, d) adapter_x = attention(q_in, ip_key, ip_value, attention_mode=self.attention_mode) adapter_x = adapter_x.flatten(2) x[:, :orig_seq_len] = x[:, :orig_seq_len] + adapter_x * ip_scale return self.o(x) class WanI2VCrossAttention(WanSelfAttention): def __init__(self, in_features, out_features, num_heads, qk_norm=True, eps=1e-6, attention_mode='sdpa', rms_norm_function="default"): super().__init__(in_features, out_features, num_heads, qk_norm, eps, rms_norm_function=rms_norm_function) self.k_img = nn.Linear(in_features, out_features) self.v_img = nn.Linear(in_features, out_features) self.norm_k_img = WanRMSNorm(out_features, eps=eps) if qk_norm else nn.Identity() self.attention_mode = attention_mode def forward(self, x, context, grid_sizes=None, clip_embed=None, audio_proj=None, audio_scale=1.0, num_latent_frames=21, nag_params={}, nag_context=None, is_uncond=False, rope_func="comfy", adapter_proj=None, adapter_attn_mask=None, ip_scale=1.0, orig_seq_len=None, **kwargs): r""" Args: x(Tensor): Shape [B, L1, C] context(Tensor): Shape [B, L2, C] """ b, n, d = x.size(0), self.num_heads, self.head_dim # compute query q = self.norm_q(self.q(x),num_chunks=2 if rope_func == "comfy_chunked" else 1).view(b, -1, n, d) if nag_context is not None and not is_uncond: x_text = self.normalized_attention_guidance(b, n, d, q, context, nag_context, nag_params) else: # text attention k = self.norm_k(self.k(context)).view(b, -1, n, d) v = self.v(context).view(b, -1, n, d) x_text = attention(q, k, v, attention_mode=self.attention_mode).flatten(2) #img attention if clip_embed is not None: k_img = self.norm_k_img(self.k_img(clip_embed)).view(b, -1, n, d) v_img = self.v_img(clip_embed).view(b, -1, n, d) img_x = attention(q, k_img, v_img, attention_mode=self.attention_mode).flatten(2) x = x_text + img_x else: x = x_text # FantasyTalking audio attention if audio_proj is not None: if len(audio_proj.shape) == 4: audio_q = q.view(b * num_latent_frames, -1, n, d) ip_key = self.k_proj(audio_proj).view(b * num_latent_frames, -1, n, d) ip_value = self.v_proj(audio_proj).view(b * num_latent_frames, -1, n, d) audio_x = attention(audio_q, ip_key, ip_value, attention_mode=self.attention_mode) audio_x = audio_x.view(b, q.size(1), n, d).flatten(2) elif len(audio_proj.shape) == 3: ip_key = self.k_proj(audio_proj).view(b, -1, n, d) ip_value = self.v_proj(audio_proj).view(b, -1, n, d) audio_x = attention(q, ip_key, ip_value, attention_mode=self.attention_mode).flatten(2) x = x + audio_x * audio_scale # FantasyPortrait adapter attention if adapter_proj is not None: if len(adapter_proj.shape) == 4: adapter_q = q.view(b * num_latent_frames, -1, n, d) ip_key = self.ip_adapter_single_stream_k_proj(adapter_proj).view(b * num_latent_frames, -1, n, d) ip_value = self.ip_adapter_single_stream_v_proj(adapter_proj).view(b * num_latent_frames, -1, n, d) adapter_x = attention(adapter_q, ip_key, ip_value, attention_mode=self.attention_mode) adapter_x = adapter_x.view(b, q.size(1), n, d) adapter_x = adapter_x.flatten(2) elif len(adapter_proj.shape) == 3: ip_key = self.ip_adapter_single_stream_k_proj(adapter_proj).view(b, -1, n, d) ip_value = self.ip_adapter_single_stream_v_proj(adapter_proj).view(b, -1, n, d) adapter_x = attention(q, ip_key, ip_value, attention_mode=self.attention_mode) adapter_x = adapter_x.flatten(2) x = x + adapter_x * ip_scale return self.o(x) class WanHuMoCrossAttention(WanSelfAttention): def __init__(self, in_features, out_features, num_heads, kv_dim=None, qk_norm=True, eps=1e-6, attention_mode='sdpa', rms_norm_function="default"): super().__init__(in_features, out_features, num_heads, qk_norm, eps, kv_dim=kv_dim, rms_norm_function=rms_norm_function) self.attention_mode = attention_mode def forward(self, x, context, grid_sizes, **kwargs): b, n, d = x.size(0), self.num_heads, self.head_dim q = self.norm_q(self.q(x)).view(b, -1, n, d) k = self.norm_k(self.k(context)).view(b, -1, n, d) v = self.v(context).view(b, -1, n, d) # Handle video spatial structure hlen_wlen = grid_sizes[0][1] * grid_sizes[0][2] q = q.reshape(-1, hlen_wlen, n, d) # Handle audio temporal structure (16 tokens per frame) k = k.reshape(-1, 16, n, d) v = v.reshape(-1, 16, n, d) x_text = attention(q, k, v, attention_mode=self.attention_mode) x_text = x_text.view(b, -1, n, d).flatten(2) x = x_text return self.o(x) class AudioCrossAttentionWrapper(nn.Module): def __init__(self, in_features, out_features, num_heads, qk_norm=True, eps=1e-6, kv_dim=None): super().__init__() self.audio_cross_attn = WanHuMoCrossAttention(in_features, out_features, num_heads, kv_dim=kv_dim) self.norm1_audio = WanLayerNorm(out_features, eps, elementwise_affine=True) def forward(self, x, audio, grid_sizes, humo_audio_scale=1.0): x = x + self.audio_cross_attn(self.norm1_audio(x), audio, grid_sizes) * humo_audio_scale return x class MTVCrafterMotionAttention(WanSelfAttention): def forward(self, x, mo, pe, grid_sizes, freqs): r""" Args: x(Tensor): Shape [B, L1, C] mo: Motion tokens pe: 4D RoPE """ b, n, d = x.size(0), self.num_heads, self.head_dim # compute query, key, value q = self.norm_q(self.q(x)).view(b, -1, n, d) k = self.norm_k(self.k(mo)).view(b, n, -1, d) v = self.v(mo).view(b, -1, n, d) # compute attention x = attention( q=rope_apply(q, grid_sizes, freqs), k=apply_rotary_emb(k, pe).transpose(1, 2), v=v ) return self.o(x.flatten(2)) WAN_CROSSATTENTION_CLASSES = { 't2v_cross_attn': WanT2VCrossAttention, 'i2v_cross_attn': WanI2VCrossAttention, } class WanAttentionBlock(nn.Module): def __init__(self, cross_attn_type, in_features, out_features, ffn_dim, ffn2_dim, num_heads, qk_norm=True, cross_attn_norm=False, eps=1e-6, attention_mode="sdpa", rope_func="comfy", rms_norm_function="default", use_motion_attn=False, use_humo_audio_attn=False, face_fuser_block=False, lynx_ip_layers=None, lynx_ref_layers=None, block_idx=0 ): super().__init__() self.dim = out_features self.ffn_dim = ffn_dim self.num_heads = num_heads self.qk_norm = qk_norm self.cross_attn_norm = cross_attn_norm self.eps = eps self.attention_mode = attention_mode self.rope_func = rope_func #radial attn self.dense_timesteps = 10 self.dense_block = False self.dense_attention_mode = "sageattn" self.block_idx = block_idx self.kv_cache = None self.use_motion_attn = use_motion_attn self.has_face_fuser_block = face_fuser_block # layers self.norm1 = WanLayerNorm(out_features, eps) self.self_attn = WanSelfAttention(in_features, out_features, num_heads, qk_norm, eps, self.attention_mode, rms_norm_function=rms_norm_function) # MTV Crafter motion attn if self.use_motion_attn: self.norm4 = WanLayerNorm(out_features, eps, elementwise_affine=True) if cross_attn_norm else nn.Identity() self.motion_attn = MTVCrafterMotionAttention(in_features, out_features, num_heads, qk_norm, eps, self.attention_mode) if cross_attn_type != "no_cross_attn": self.norm3 = WanLayerNorm(out_features, eps, elementwise_affine=True) if cross_attn_norm else nn.Identity() self.cross_attn = WAN_CROSSATTENTION_CLASSES[cross_attn_type](in_features, out_features, num_heads, qk_norm, eps, rms_norm_function=rms_norm_function) self.norm2 = WanLayerNorm(out_features, eps) self.ffn = nn.Sequential( nn.Linear(in_features, ffn_dim), nn.GELU(approximate='tanh'), nn.Linear(ffn2_dim, out_features)) # modulation self.modulation = nn.Parameter(torch.randn(1, 6, out_features) / in_features**0.5) self.seg_idx = None # HuMo audio cross-attn if use_humo_audio_attn: self.audio_cross_attn_wrapper = AudioCrossAttentionWrapper(in_features, out_features, num_heads, qk_norm, eps, kv_dim=1536) if face_fuser_block: from .wananimate.face_blocks import FaceBlock self.fuser_block = FaceBlock(self.dim, num_heads) # Lynx self.ref_adapter = None if lynx_ref_layers == "full": from ...lynx.modules import WanLynxRefAttention self.self_attn.ref_adapter = WanLynxRefAttention(dim=self.dim) if lynx_ip_layers == "full": from ...lynx.modules import WanLynxIPCrossAttention self.cross_attn.ip_adapter = WanLynxIPCrossAttention(cross_attention_dim=self.dim, dim=self.dim, n_registers=16) elif lynx_ip_layers == "lite": from ...lynx.modules import WanLynxIPCrossAttention if self.block_idx % 2 == 0: self.cross_attn.ip_adapter = WanLynxIPCrossAttention(cross_attention_dim=2048, dim=self.dim, n_registers=0, bias=False) #@torch.compiler.disable() def get_mod(self, e): if e.dim() == 3: return (self.modulation + e).chunk(6, dim=1) # 1, 6, dim elif e.dim() == 4: e_mod = self.modulation.unsqueeze(2) + e return [ei.squeeze(1) for ei in e_mod.unbind(dim=1)] def modulate(self, x, shift_msa, scale_msa, seg_idx=None): """ Modulate x with shift and scale. If seg_idx is provided, apply segmented modulation. """ norm_x = self.norm1(x) if seg_idx is not None: parts = [] for i in range(2): part = torch.addcmul( shift_msa[:, i:i + 1], norm_x[:, seg_idx[i]:seg_idx[i + 1]], 1 + scale_msa[:, i:i + 1] ) parts.append(part) norm_x = torch.cat(parts, dim=1) return norm_x else: return torch.addcmul(shift_msa, norm_x, 1 + scale_msa) def ffn_chunked(self, x, shift_mlp, scale_mlp, num_chunks=4): modulated_input = torch.addcmul(shift_mlp, self.norm2(x), 1 + scale_mlp) result = torch.empty_like(x) seq_len = modulated_input.shape[1] chunk_sizes = [seq_len // num_chunks + (1 if i < seq_len % num_chunks else 0) for i in range(num_chunks)] start_idx = 0 for size in chunk_sizes: end_idx = start_idx + size chunk = modulated_input[:, start_idx:end_idx, :] result[:, start_idx:end_idx, :] = self.ffn(chunk) start_idx = end_idx return result #region attention forward def forward( self, x, e, seq_lens, grid_sizes, freqs, context, current_step, last_step=False, video_attention_split_steps=[], clip_embed=None, camera_embed=None, #ReCamMaster audio_proj=None, audio_scale=1.0, #fantasytalking num_latent_frames=21, original_seq_len=None, enhance_enabled=False, #feta nag_params={}, nag_context=None, #normalized attention guidance is_uncond=False, multitalk_audio_embedding=None, ref_target_masks=None, human_num=0, #multitalk inner_t=None, inner_c=None, cross_freqs=None, #echoshot x_ip=None, e_ip=None, freqs_ip=None, ip_scale=1.0, #stand-in adapter_proj=None, #fantasyportrait reverse_time=False, mtv_motion_tokens=None, mtv_motion_rotary_emb=None, mtv_strength=1.0, mtv_freqs=None, #mtv crafter humo_audio_input=None, humo_audio_scale=1.0, #humo audio lynx_x_ip=None, lynx_ref_feature=None, lynx_ip_scale=1.0, lynx_ref_scale=1.0, #lynx ): r""" Args: x(Tensor): Shape [B, L, C] e(Tensor): Shape [B, 6, C] seq_lens(Tensor): Shape [B], length of each sequence in batch grid_sizes(Tensor): Shape [B, 3], the second dimension contains (F, H, W) freqs(Tensor): Rope freqs, shape [1024, C / num_heads / 2] """ self.original_seq_len = original_seq_len self.zero_timestep = len(e) == 2 if self.zero_timestep: #s2v zero timestep self.seg_idx = e[1] self.seg_idx = min(max(0, self.seg_idx), x.size(1)) self.seg_idx = [0, self.seg_idx, x.size(1)] e = e[0] shift_msa, scale_msa, gate_msa, shift_mlp, scale_mlp, gate_mlp = self.get_mod(e.to(x.device)) del e input_x = self.modulate(x, shift_msa, scale_msa, seg_idx=self.seg_idx) del shift_msa, scale_msa if x_ip is not None: shift_msa_ip, scale_msa_ip, gate_msa_ip, shift_mlp_ip, scale_mlp_ip, gate_mlp_ip = self.get_mod(e_ip.to(x.device)) input_x_ip = self.modulate(x_ip, shift_msa_ip, scale_msa_ip) self.cond_size = input_x_ip.shape[1] input_x = torch.concat([input_x, input_x_ip], dim=1) self.kv_cache = None if camera_embed is not None: # encode ReCamMaster camera camera_embed = self.cam_encoder(camera_embed.to(x)) camera_embed = camera_embed.repeat(1, 2, 1) camera_embed = camera_embed.unsqueeze(2).unsqueeze(3).repeat(1, 1, grid_sizes[0][1], grid_sizes[0][2], 1) camera_embed = rearrange(camera_embed, 'b f h w d -> b (f h w) d') input_x += camera_embed # self-attention x_ref_attn_map = None # self-attention variables q_ip = k_ip = v_ip = None #RoPE and QKV computation if inner_t is not None: #query, key, value q, k, v = self.self_attn.qkv_fn(input_x) q=rope_apply_echoshot(q, grid_sizes, freqs, inner_t).to(q) k=rope_apply_echoshot(k, grid_sizes, freqs, inner_t).to(k) elif x_ip is not None and self.kv_cache is None: # First pass - separate main and IP components x_main, x_ip_input = input_x[:, : -self.cond_size], input_x[:, -self.cond_size :] # Compute QKV for main content q, k, v = self.self_attn.qkv_fn(x_main) if self.rope_func == "comfy": q, k = apply_rope_comfy(q, k, freqs) elif self.rope_func == "comfy_chunked": q, k = apply_rope_comfy_chunked(q, k, freqs) # Compute QKV for IP content q_ip, k_ip, v_ip = self.self_attn.qkv_fn_ip(x_ip_input) if self.rope_func == "comfy": q_ip, k_ip = apply_rope_comfy(q_ip, k_ip, freqs_ip) elif self.rope_func == "comfy_chunked": q_ip, k_ip = apply_rope_comfy_chunked(q_ip, k_ip, freqs_ip) else: q, k, v = self.self_attn.qkv_fn(input_x) if self.rope_func == "comfy": q, k = apply_rope_comfy(q, k, freqs) elif self.rope_func == "comfy_chunked": q, k = apply_rope_comfy_chunked(q, k, freqs) else: q=rope_apply(q, grid_sizes, freqs, reverse_time=reverse_time) k=rope_apply(k, grid_sizes, freqs, reverse_time=reverse_time) # FETA if enhance_enabled: feta_scores = get_feta_scores(q, k) #self-attention split_attn = (context is not None and (context.shape[0] > 1 or (clip_embed is not None and clip_embed.shape[0] > 1)) and x.shape[0] == 1 and inner_t is None and x_ip is None # Don't split when using IP-Adapter ) if split_attn: y = self.self_attn.forward_split( q, k, v, seq_lens, grid_sizes, freqs, seq_chunks=max(context.shape[0], clip_embed.shape[0] if clip_embed is not None else 0), current_step=current_step, video_attention_split_steps=video_attention_split_steps ) elif ref_target_masks is not None: y, x_ref_attn_map = self.self_attn.forward_multitalk(q, k, v, seq_lens, grid_sizes, ref_target_masks) elif self.attention_mode == "radial_sage_attention": if self.dense_block or self.dense_timesteps is not None and current_step < self.dense_timesteps: if self.dense_attention_mode == "sparse_sage_attn": y = self.self_attn.forward_radial(q, k, v, dense_step=True) else: y = self.self_attn.forward(q, k, v, seq_lens) else: y = self.self_attn.forward_radial(q, k, v, dense_step=False) elif self.attention_mode == "sageattn_3": if current_step != 0 and not last_step: y = self.self_attn.forward(q, k, v, seq_lens, attention_mode_override="sageattn_3") else: y = self.self_attn.forward(q, k, v, seq_lens, attention_mode_override="sageattn") elif x_ip is not None and self.kv_cache is None: # First pass: cache IP keys/values and compute attention self.kv_cache = {"k_ip": k_ip.detach(), "v_ip": v_ip.detach()} y = self.self_attn.forward_ip(q, k, v, q_ip, k_ip, v_ip, seq_lens) elif self.kv_cache is not None: # Subsequent passes: use cached IP keys/values k_ip = self.kv_cache["k_ip"] v_ip = self.kv_cache["v_ip"] full_k = torch.cat([k, k_ip], dim=1) full_v = torch.cat([v, v_ip], dim=1) y = self.self_attn.forward(q, full_k, full_v, seq_lens) else: y = self.self_attn.forward(q, k, v, seq_lens, lynx_ref_feature=lynx_ref_feature, lynx_ref_scale=lynx_ref_scale) if lynx_ref_feature is None and self.self_attn.ref_adapter is not None: lynx_ref_feature = input_x # FETA if enhance_enabled: y.mul_(feta_scores) #ReCamMaster if camera_embed is not None: y = self.projector(y) if x_ip is not None: y, y_ip = ( y[:, : -self.cond_size], y[:, -self.cond_size :], ) if self.zero_timestep: z = [] for i in range(2): z.append(y[:, self.seg_idx[i]:self.seg_idx[i + 1]] * gate_msa[:, i:i + 1]) y = torch.cat(z, dim=1) x = x.add(y) else: x = x.addcmul(y, gate_msa) del y, gate_msa # cross-attention & ffn function if context is not None: if split_attn: if nag_context is not None: raise NotImplementedError("nag_context is not supported in split_cross_attn_ffn") x = self.split_cross_attn_ffn(x, context, shift_mlp, scale_mlp, gate_mlp, clip_embed, grid_sizes) else: x = self.cross_attn_ffn(x, context, grid_sizes, shift_mlp, scale_mlp, gate_mlp, clip_embed, audio_proj, audio_scale, num_latent_frames, nag_params, nag_context, is_uncond, multitalk_audio_embedding, x_ref_attn_map, human_num, inner_t, inner_c, cross_freqs, adapter_proj=adapter_proj, ip_scale=ip_scale, mtv_freqs=mtv_freqs, mtv_motion_tokens=mtv_motion_tokens, mtv_motion_rotary_emb=mtv_motion_rotary_emb, mtv_strength=mtv_strength, humo_audio_input=humo_audio_input, humo_audio_scale=humo_audio_scale, lynx_x_ip=lynx_x_ip, lynx_ip_scale=lynx_ip_scale ) else: if self.rope_func == "comfy_chunked": y = self.ffn_chunked(x, shift_mlp, scale_mlp) else: y = self.ffn(torch.addcmul(shift_mlp, self.norm2(x), 1 + scale_mlp)) x = x.addcmul(y, gate_mlp) del gate_mlp if x_ip is not None: x_ip = x_ip.addcmul(y_ip, gate_msa_ip) y_ip = self.ffn(torch.addcmul(shift_mlp_ip, self.norm2(x_ip), 1 + scale_mlp_ip)) x_ip = x_ip.addcmul(y_ip, gate_mlp_ip) return x, x_ip, lynx_ref_feature def cross_attn_ffn(self, x, context, grid_sizes, shift_mlp, scale_mlp, gate_mlp, clip_embed, audio_proj, audio_scale, num_latent_frames, nag_params, nag_context, is_uncond, multitalk_audio_embedding, x_ref_attn_map, human_num, inner_t, inner_c, cross_freqs, adapter_proj, ip_scale, mtv_freqs, mtv_motion_tokens, mtv_motion_rotary_emb, mtv_strength, humo_audio_input, humo_audio_scale, lynx_x_ip, lynx_ip_scale): x = x + self.cross_attn(self.norm3(x), context, grid_sizes, clip_embed=clip_embed, audio_proj=audio_proj, audio_scale=audio_scale, num_latent_frames=num_latent_frames, nag_params=nag_params, nag_context=nag_context, is_uncond=is_uncond, rope_func=self.rope_func, inner_t=inner_t, inner_c=inner_c, cross_freqs=cross_freqs, adapter_proj=adapter_proj, ip_scale=ip_scale, orig_seq_len=self.original_seq_len, lynx_x_ip=lynx_x_ip, lynx_ip_scale=lynx_ip_scale) # MultiTalk if multitalk_audio_embedding is not None and not isinstance(self, VaceWanAttentionBlock): x_audio = self.audio_cross_attn(self.norm_x(x), encoder_hidden_states=multitalk_audio_embedding, shape=grid_sizes[0], x_ref_attn_map=x_ref_attn_map, human_num=human_num) x = x + x_audio * audio_scale # MTV-Crafter Motion Attention if self.use_motion_attn and mtv_motion_tokens is not None and mtv_motion_rotary_emb is not None: x_motion = self.motion_attn(self.norm4(x), mtv_motion_tokens, mtv_motion_rotary_emb, grid_sizes, mtv_freqs) x = x + x_motion * mtv_strength # HuMo Audio Cross-Attention if humo_audio_input is not None: x = self.audio_cross_attn_wrapper(x, humo_audio_input, grid_sizes, humo_audio_scale) if self.rope_func == "comfy_chunked" and not self.zero_timestep: y = self.ffn_chunked(x, shift_mlp, scale_mlp) else: norm2_x = self.norm2(x) if self.zero_timestep: parts = [] for i in range(2): parts.append(norm2_x[:, self.seg_idx[i]:self.seg_idx[i + 1]] * (1 + scale_mlp[:, i:i + 1]) + shift_mlp[:, i:i + 1]) norm2_x = torch.cat(parts, dim=1) y = self.ffn(norm2_x) else: input_x = torch.addcmul(shift_mlp, norm2_x, 1 + scale_mlp) del shift_mlp, scale_mlp, norm2_x y = self.ffn(input_x) if self.zero_timestep: z = [] for i in range(2): z.append(y[:, self.seg_idx[i]:self.seg_idx[i + 1]] * gate_mlp[:, i:i + 1]) y = torch.cat(z, dim=1) x = x.add(y) else: x = x.addcmul(y, gate_mlp) return x @torch.compiler.disable() def split_cross_attn_ffn(self, x, context, shift_mlp, scale_mlp, gate_mlp, clip_embed=None, grid_sizes=None): # Get number of prompts num_prompts = context.shape[0] num_clip_embeds = 0 if clip_embed is None else clip_embed.shape[0] num_segments = max(num_prompts, num_clip_embeds) # Extract spatial dimensions frames, height, width = grid_sizes[0] # Assuming batch size 1 tokens_per_frame = height * width # Distribute frames across prompts frames_per_segment = max(1, frames // num_segments) # Process each prompt segment x_combined = torch.zeros_like(x) for i in range(num_segments): # Calculate frame boundaries for this segment start_frame = i * frames_per_segment end_frame = min((i+1) * frames_per_segment, frames) if i < num_segments-1 else frames # Convert frame indices to token indices start_idx = start_frame * tokens_per_frame end_idx = end_frame * tokens_per_frame segment_indices = torch.arange(start_idx, end_idx, device=x.device, dtype=torch.long) # Get prompt segment (cycle through available prompts if needed) prompt_idx = i % num_prompts segment_context = context[prompt_idx:prompt_idx+1] # Handle clip_embed for this segment (cycle through available embeddings) segment_clip_embed = None if clip_embed is not None: clip_idx = i % num_clip_embeds segment_clip_embed = clip_embed[clip_idx:clip_idx+1] # Get tensor segment x_segment = x[:, segment_indices, :] # Process segment with its prompt and clip embedding processed_segment = self.cross_attn(self.norm3(x_segment), segment_context, clip_embed=segment_clip_embed) processed_segment = processed_segment.to(x.dtype) # Add to combined result x_combined[:, segment_indices, :] = processed_segment # Continue with FFN x = x + x_combined y = self.ffn_chunked(x, shift_mlp, scale_mlp) x = x.addcmul(y, gate_mlp) return x class VaceWanAttentionBlock(WanAttentionBlock): def __init__( self, cross_attn_type, in_features, out_features, ffn_dim, ffn2_dim, num_heads, qk_norm=True, cross_attn_norm=False, eps=1e-6, block_id=0, attention_mode='sdpa', rope_func="comfy", rms_norm_function="default" ): super().__init__(cross_attn_type, in_features, out_features, ffn_dim, ffn2_dim, num_heads, qk_norm, cross_attn_norm, eps, attention_mode, rope_func, rms_norm_function=rms_norm_function) self.block_id = block_id if block_id == 0: self.before_proj = nn.Linear(in_features, out_features) self.after_proj = nn.Linear(in_features, out_features) def forward(self, c, **kwargs): return super().forward(c, **kwargs) class BaseWanAttentionBlock(WanAttentionBlock): def __init__( self, cross_attn_type, in_features, out_features, ffn_dim, ffn2_dim, num_heads, qk_norm=True, cross_attn_norm=False, eps=1e-6, block_id=None, block_idx=0, attention_mode='sdpa', rope_func="comfy", rms_norm_function="default", lynx_ip_layers=None, lynx_ref_layers=None, ): super().__init__(cross_attn_type, in_features, out_features, ffn_dim, ffn2_dim, num_heads, qk_norm, cross_attn_norm, eps, attention_mode, rope_func, rms_norm_function=rms_norm_function, block_idx=block_idx, lynx_ip_layers=lynx_ip_layers, lynx_ref_layers=lynx_ref_layers) self.block_id = block_id def forward(self, x, vace_hints=None, vace_context_scale=[1.0], **kwargs): x, x_ip, lynx_ref_feature = super().forward(x, **kwargs) if vace_hints is None: return x, x_ip, lynx_ref_feature if self.block_id is not None: for i in range(len(vace_hints)): x.add_(vace_hints[i][self.block_id].to(x.device), alpha=vace_context_scale[i]) return x, x_ip, lynx_ref_feature class Head(nn.Module): def __init__(self, dim, out_dim, patch_size, eps=1e-6): super().__init__() self.dim = dim self.out_dim = out_dim self.patch_size = patch_size self.eps = eps # layers out_dim = math.prod(patch_size) * out_dim self.norm = WanLayerNorm(dim, eps) self.head = nn.Linear(dim, out_dim) # modulation self.modulation = nn.Parameter(torch.randn(1, 2, dim) / dim**0.5) def get_mod(self, e): if e.dim() == 2: return (self.modulation + e.unsqueeze(1)).chunk(2, dim=1) elif e.dim() == 3: e = (self.modulation.unsqueeze(2) + e.unsqueeze(1)).chunk(2, dim=1) return [ei.squeeze(1) for ei in e] def forward(self, x, e): r""" Args: x(Tensor): Shape [B, L1, C] e(Tensor): Shape [B, C] """ e = self.get_mod(e.to(x.device)) x = self.head(self.norm(x).mul_(1 + e[1]).add_(e[0])) return x class MLPProj(torch.nn.Module): def __init__(self, in_dim, out_dim, fl_pos_emb=False): super().__init__() self.proj = torch.nn.Sequential( torch.nn.LayerNorm(in_dim), torch.nn.Linear(in_dim, in_dim), torch.nn.GELU(), torch.nn.Linear(in_dim, out_dim), torch.nn.LayerNorm(out_dim)) if fl_pos_emb: # NOTE: we only use this for `fl2v` self.emb_pos = nn.Parameter(torch.zeros(1, 257 * 2, 1280)) def forward(self, image_embeds): if hasattr(self, 'emb_pos'): image_embeds = image_embeds + self.emb_pos.to(image_embeds.device) clip_extra_context_tokens = self.proj(image_embeds) return clip_extra_context_tokens from .s2v.auxi_blocks import MotionEncoder_tc class CausalAudioEncoder(nn.Module): def __init__(self, dim=5120, num_layers=25, out_dim=2048, video_rate=8, num_token=4, need_global=False): super().__init__() self.encoder = MotionEncoder_tc( in_dim=dim, hidden_dim=out_dim, num_heads=num_token, need_global=need_global) weight = torch.ones((1, num_layers, 1, 1)) * 0.01 self.weights = torch.nn.Parameter(weight) self.act = torch.nn.SiLU() def forward(self, features): # features B * num_layers * dim * video_length weights = self.act(self.weights) weights_sum = weights.sum(dim=1, keepdims=True) weighted_feat = ((features * weights) / weights_sum).sum( dim=1) # b dim f weighted_feat = weighted_feat.permute(0, 2, 1) # b f dim res = self.encoder(weighted_feat) # b f n dim return res # b f n dim class AudioCrossAttention(WanT2VCrossAttention): def __init__(self, *args, **kwargs): super().__init__(*args, **kwargs) class AudioInjector_WAN(nn.Module): def __init__(self, all_modules, all_modules_names, dim=2048, num_heads=32, inject_layer=[0, 27], root_net=None, enable_adain=False, adain_dim=2048, need_adain_ont=False, attention_mode='sdpa'): super().__init__() self.injected_block_id = {} audio_injector_id = 0 for mod_name, mod in zip(all_modules_names, all_modules): if isinstance(mod, WanAttentionBlock): for inject_id in inject_layer: if f'transformer_blocks.{inject_id}' in mod_name: self.injected_block_id[inject_id] = audio_injector_id audio_injector_id += 1 self.injector = nn.ModuleList([ AudioCrossAttention( in_features=dim, out_features=dim, num_heads=num_heads, qk_norm=True, attention_mode=attention_mode ) for _ in range(audio_injector_id) ]) self.injector_pre_norm_feat = nn.ModuleList([ nn.LayerNorm( dim, elementwise_affine=False, eps=1e-6, ) for _ in range(audio_injector_id) ]) self.injector_pre_norm_vec = nn.ModuleList([ nn.LayerNorm( dim, elementwise_affine=False, eps=1e-6, ) for _ in range(audio_injector_id) ]) if enable_adain: self.injector_adain_layers = nn.ModuleList([ AdaLayerNorm( output_dim=dim * 2, embedding_dim=adain_dim, chunk_dim=1) for _ in range(audio_injector_id) ]) if need_adain_ont: self.injector_adain_output_layers = nn.ModuleList( [nn.Linear(dim, dim) for _ in range(audio_injector_id)]) class WanModel(torch.nn.Module): def __init__(self, model_type='t2v', patch_size=(1, 2, 2), text_len=512, in_dim=16, dim=2048, in_features=5120, out_features=5120, ffn_dim=8192, ffn2_dim=8192, freq_dim=256, text_dim=4096, out_dim=16, num_heads=16, num_layers=32, qk_norm=True, cross_attn_norm=True, eps=1e-6, attention_mode='sdpa', rope_func='comfy', rms_norm_function='default', main_device=torch.device('cuda'), offload_device=torch.device('cpu'), dtype=torch.float16, teacache_coefficients=[], magcache_ratios=[], vace_layers=None, vace_in_dim=None, inject_sample_info=False, add_ref_conv=False, in_dim_ref_conv=16, add_control_adapter=False, in_dim_control_adapter=24, use_motion_attn=False, #s2v cond_dim=0, audio_dim=1024, num_audio_token=4, enable_adain=False, adain_mode="attn_norm", audio_inject_layers=[0, 4, 8, 12, 16, 20, 24, 27, 30, 33, 36, 39], zero_timestep=False, humo_audio=False, # WanAnimate is_wananimate=False, motion_encoder_dim=512, # lynx lynx_ip_layers=None, lynx_ref_layers=None, ): r""" Initialize the diffusion model backbone. Args: model_type (`str`, *optional*, defaults to 't2v'): Model variant - 't2v' (text-to-video) or 'i2v' (image-to-video) patch_size (`tuple`, *optional*, defaults to (1, 2, 2)): 3D patch dimensions for video embedding (t_patch, h_patch, w_patch) text_len (`int`, *optional*, defaults to 512): Fixed length for text embeddings in_dim (`int`, *optional*, defaults to 16): Input video channels (C_in) dim (`int`, *optional*, defaults to 2048): Hidden dimension of the transformer ffn_dim (`int`, *optional*, defaults to 8192): Intermediate dimension in feed-forward network freq_dim (`int`, *optional*, defaults to 256): Dimension for sinusoidal time embeddings text_dim (`int`, *optional*, defaults to 4096): Input dimension for text embeddings out_dim (`int`, *optional*, defaults to 16): Output video channels (C_out) num_heads (`int`, *optional*, defaults to 16): Number of attention heads num_layers (`int`, *optional*, defaults to 32): Number of transformer blocks qk_norm (`bool`, *optional*, defaults to True): Enable query/key normalization cross_attn_norm (`bool`, *optional*, defaults to False): Enable cross-attention normalization eps (`float`, *optional*, defaults to 1e-6): Epsilon value for normalization layers """ super().__init__() self.model_type = model_type self.patch_size = patch_size self.text_len = text_len self.in_dim = in_dim self.dim = dim self.in_features = in_features self.out_features = out_features self.ffn_dim = ffn_dim self.ffn2_dim = ffn2_dim self.freq_dim = freq_dim self.text_dim = text_dim self.out_dim = out_dim self.num_heads = num_heads self.num_layers = num_layers self.qk_norm = qk_norm self.cross_attn_norm = cross_attn_norm self.eps = eps self.attention_mode = attention_mode self.rope_func = rope_func self.main_device = main_device self.offload_device = offload_device self.vace_layers = vace_layers self.device = main_device self.patched_linear = False self.blocks_to_swap = -1 self.offload_txt_emb = False self.offload_img_emb = False self.vace_blocks_to_swap = -1 self.cache_device = offload_device #init TeaCache variables self.enable_teacache = False self.rel_l1_thresh = 0.15 self.teacache_start_step= 0 self.teacache_end_step = -1 self.teacache_state = TeaCacheState(cache_device=self.cache_device) self.teacache_coefficients = teacache_coefficients self.teacache_use_coefficients = False self.teacache_mode = 'e' #init MagCache variables self.enable_magcache = False self.magcache_state = MagCacheState(cache_device=self.cache_device) self.magcache_thresh = 0.24 self.magcache_K = 4 self.magcache_start_step = 0 self.magcache_end_step = -1 self.magcache_ratios = magcache_ratios #init EasyCache variables self.enable_easycache = False self.easycache_thresh = 0.1 self.easycache_start_step = 0 self.easycache_end_step = -1 self.easycache_state = EasyCacheState(cache_device=self.cache_device) self.slg_blocks = None self.slg_start_percent = 0.0 self.slg_end_percent = 1.0 self.use_non_blocking = False self.prefetch_blocks = 0 self.block_swap_debug = False self.video_attention_split_steps = [] self.lora_scheduling_enabled = False self.multitalk_model_type = "none" self.lynx_ip_layers = lynx_ip_layers self.lynx_ref_layers = lynx_ref_layers self.humo_audio = humo_audio self.motion_encoder_dim = motion_encoder_dim self.base_dtype = dtype # embeddings self.patch_embedding = nn.Conv3d( in_dim, dim, kernel_size=patch_size, stride=patch_size) self.original_patch_embedding = self.patch_embedding self.expanded_patch_embedding = self.patch_embedding if model_type != 'no_cross_attn': self.text_embedding = nn.Sequential( nn.Linear(text_dim, dim), nn.GELU(approximate='tanh'), nn.Linear(dim, dim)) self.time_embedding = nn.Sequential( nn.Linear(freq_dim, dim), nn.SiLU(), nn.Linear(dim, dim)) self.time_projection = nn.Sequential(nn.SiLU(), nn.Linear(dim, dim * 6)) if vace_layers is not None: self.vace_layers = [i for i in range(0, self.num_layers, 2)] if vace_layers is None else vace_layers self.vace_in_dim = self.in_dim if vace_in_dim is None else vace_in_dim self.vace_layers_mapping = {i: n for n, i in enumerate(self.vace_layers)} # vace blocks self.vace_blocks = nn.ModuleList([ VaceWanAttentionBlock('t2v_cross_attn', self.in_features, self.out_features, self.ffn_dim, self.ffn2_dim,self.num_heads, self.qk_norm, self.cross_attn_norm, self.eps, block_id=i, attention_mode=self.attention_mode, rope_func=self.rope_func, rms_norm_function=rms_norm_function) for i in self.vace_layers ]) # vace patch embeddings self.vace_patch_embedding = nn.Conv3d( self.vace_in_dim, self.dim, kernel_size=self.patch_size, stride=self.patch_size ) self.blocks = nn.ModuleList([ BaseWanAttentionBlock('t2v_cross_attn', self.in_features, self.out_features, ffn_dim, self.ffn2_dim, num_heads, qk_norm, cross_attn_norm, eps, attention_mode=self.attention_mode, rope_func=self.rope_func, rms_norm_function=rms_norm_function, block_id=self.vace_layers_mapping[i] if i in self.vace_layers else None, lynx_ip_layers=lynx_ip_layers, lynx_ref_layers=lynx_ref_layers, block_idx=i) for i in range(num_layers) ]) else: # blocks if model_type == 't2v' or model_type == 's2v': cross_attn_type = 't2v_cross_attn' elif model_type == 'i2v' or model_type == 'fl2v': cross_attn_type = 'i2v_cross_attn' else: cross_attn_type = 'no_cross_attn' self.blocks = nn.ModuleList([ WanAttentionBlock(cross_attn_type, self.in_features, self.out_features, ffn_dim, ffn2_dim, num_heads, qk_norm, cross_attn_norm, eps, attention_mode=self.attention_mode, rope_func=self.rope_func, rms_norm_function=rms_norm_function, use_motion_attn=(i % 4 == 0 and use_motion_attn), use_humo_audio_attn=self.humo_audio, face_fuser_block = (i % 5 == 0 and is_wananimate), lynx_ip_layers=lynx_ip_layers, lynx_ref_layers=lynx_ref_layers, block_idx=i) for i in range(num_layers) ]) #MTV Crafter if use_motion_attn: self.pad_motion_tokens = torch.zeros(1, 1, 2048) # head self.head = Head(dim, out_dim, patch_size, eps) d = self.dim // self.num_heads self.rope_embedder = EmbedND_RifleX( d, 10000.0, [d - 4 * (d // 6), 2 * (d // 6), 2 * (d // 6)], num_frames=None, k=None, ) self.cached_freqs = self.cached_shape = self.cached_cond = None # buffers (don't use register_buffer otherwise dtype will be changed in to()) assert (dim % num_heads) == 0 and (dim // num_heads) % 2 == 0 if model_type == 'i2v' or model_type == 'fl2v': self.img_emb = MLPProj(1280, dim, fl_pos_emb=model_type == 'fl2v') #skyreels v2 if inject_sample_info: self.fps_embedding = nn.Embedding(2, dim) self.fps_projection = nn.Sequential(nn.Linear(dim, dim), nn.SiLU(), nn.Linear(dim, dim * 6)) #fun 1.1 if add_ref_conv: self.ref_conv = nn.Conv2d(in_dim_ref_conv, dim, kernel_size=patch_size[1:], stride=patch_size[1:]) else: self.ref_conv = None if add_control_adapter: from .wan_camera_adapter import SimpleAdapter self.control_adapter = SimpleAdapter(in_dim_control_adapter, dim, kernel_size=patch_size[1:], stride=patch_size[1:]) else: self.control_adapter = None #S2V self.zero_timestep = self.audio_injector = self.trainable_cond_mask =None if cond_dim > 0: self.cond_encoder = nn.Conv3d( cond_dim, self.dim, kernel_size=self.patch_size, stride=self.patch_size) if self.model_type == 's2v': self.enable_adain = enable_adain self.casual_audio_encoder = CausalAudioEncoder( dim=audio_dim, out_dim=self.dim, num_token=num_audio_token, need_global=enable_adain) all_modules, all_modules_names = torch_dfs( self.blocks, parent_name="root.transformer_blocks") self.audio_injector = AudioInjector_WAN( all_modules, all_modules_names, dim=self.dim, num_heads=self.num_heads, inject_layer=audio_inject_layers, root_net=self, enable_adain=enable_adain, adain_dim=self.dim, need_adain_ont=adain_mode != "attn_norm", attention_mode=attention_mode ) self.trainable_cond_mask = nn.Embedding(3, self.dim) self.frame_packer = FramePackMotioner( inner_dim=self.dim, num_heads=self.num_heads, zip_frame_buckets=[1, 2, 16], drop_mode='padd') self.adain_mode = adain_mode self.zero_timestep = zero_timestep # HuMo Audio if self.humo_audio: from ...HuMo.audio_proj import AudioProjModel self.audio_proj = AudioProjModel(seq_len=8, blocks=5, channels=1280, intermediate_dim=512, output_dim=1536, context_tokens=16) # WanAnimate self.motion_encoder = self.pose_patch_embedding = self.face_encoder = self.face_adapter = None if is_wananimate: from .wananimate.motion_encoder import MotionExtractor from .wananimate.face_blocks import FaceEncoder self.pose_patch_embedding = nn.Conv3d(16, dim, kernel_size=patch_size, stride=patch_size) self.motion_encoder = MotionExtractor() self.face_encoder = FaceEncoder( in_dim=motion_encoder_dim, out_dim=self.dim, num_heads=4, dtype=dtype ) def block_swap(self, blocks_to_swap, offload_txt_emb=False, offload_img_emb=False, vace_blocks_to_swap=None, prefetch_blocks=0, block_swap_debug=False): # Clamp blocks_to_swap to valid range blocks_to_swap = max(0, min(blocks_to_swap, len(self.blocks))) log.info(f"Swapping {blocks_to_swap} transformer blocks") self.blocks_to_swap = blocks_to_swap self.prefetch_blocks = prefetch_blocks self.block_swap_debug = block_swap_debug self.offload_img_emb = offload_img_emb self.offload_txt_emb = offload_txt_emb total_offload_memory = 0 total_main_memory = 0 # Calculate the index where swapping starts swap_start_idx = len(self.blocks) - blocks_to_swap for b, block in tqdm(enumerate(self.blocks), total=len(self.blocks), desc="Initializing block swap"): block_memory = get_module_memory_mb(block) if b < swap_start_idx: block.to(self.main_device) total_main_memory += block_memory else: block.to(self.offload_device, non_blocking=self.use_non_blocking) total_offload_memory += block_memory if blocks_to_swap != -1 and vace_blocks_to_swap == 0: vace_blocks_to_swap = 1 if vace_blocks_to_swap > 0 and self.vace_layers is not None: # Clamp vace_blocks_to_swap to valid range vace_blocks_to_swap = max(0, min(vace_blocks_to_swap, len(self.vace_blocks))) self.vace_blocks_to_swap = vace_blocks_to_swap # Calculate the index where VACE swapping starts vace_swap_start_idx = len(self.vace_blocks) - vace_blocks_to_swap for b, block in tqdm(enumerate(self.vace_blocks), total=len(self.vace_blocks), desc="Initializing vace block swap"): block_memory = get_module_memory_mb(block) if b < vace_swap_start_idx: block.to(self.main_device) total_main_memory += block_memory else: block.to(self.offload_device, non_blocking=self.use_non_blocking) total_offload_memory += block_memory mm.soft_empty_cache() gc.collect() log.info("----------------------") log.info(f"Block swap memory summary:") log.info(f"Transformer blocks on {self.offload_device}: {total_offload_memory:.2f}MB") log.info(f"Transformer blocks on {self.main_device}: {total_main_memory:.2f}MB") log.info(f"Total memory used by transformer blocks: {(total_offload_memory + total_main_memory):.2f}MB") log.info(f"Non-blocking memory transfer: {self.use_non_blocking}") log.info("----------------------") def forward_vace( self, x, vace_context, seq_len, kwargs ): # embeddings c = [self.vace_patch_embedding(u.unsqueeze(0).float()).to(x.dtype) for u in vace_context] c = [u.flatten(2).transpose(1, 2) for u in c] c = torch.cat([ torch.cat([u, u.new_zeros(1, seq_len - u.size(1), u.size(2))], dim=1) for u in c ]) if x.shape[1] > c.shape[1]: c = torch.cat([c.new_zeros(x.shape[0], x.shape[1] - c.shape[1], c.shape[2]), c], dim=1) if c.shape[1] > x.shape[1]: c = c[:, :x.shape[1]] hints = [] current_c = c vace_swap_start_idx = len(self.vace_blocks) - self.vace_blocks_to_swap if self.vace_blocks_to_swap > 0 else len(self.vace_blocks) for b, block in enumerate(self.vace_blocks): if b >= vace_swap_start_idx and self.vace_blocks_to_swap > 0: block.to(self.main_device) if b == 0: c_processed = block.before_proj(current_c) + x else: c_processed = current_c c_processed = block.forward(c_processed, **kwargs)[0] # Store skip connection c_skip = block.after_proj(c_processed) hints.append(c_skip.to( self.offload_device if self.vace_blocks_to_swap > 0 else self.main_device, non_blocking=self.use_non_blocking )) current_c = c_processed if b >= vace_swap_start_idx and self.vace_blocks_to_swap > 0: block.to(self.offload_device, non_blocking=self.use_non_blocking) return hints def audio_injector_forward(self, block_idx, x, audio_emb, scale=1.0): if block_idx in self.audio_injector.injected_block_id.keys(): audio_attn_id = self.audio_injector.injected_block_id[block_idx] num_frames = audio_emb.shape[1]# b f n c input_x = x[:, :self.original_seq_len].clone() # b (f h w) c input_x = rearrange(input_x, "b (t n) c -> (b t) n c", t=num_frames) if self.enable_adain and self.adain_mode == "attn_norm": audio_emb_global = self.audio_emb_global audio_emb_global = rearrange(audio_emb_global,"b t n c -> (b t) n c") attn_x = self.audio_injector.injector_adain_layers[audio_attn_id](input_x, temb=audio_emb_global[:, 0]) else: attn_x = self.audio_injector.injector_pre_norm_feat[audio_attn_id](input_x) attn_audio_emb = rearrange(audio_emb, "b t n c -> (b t) n c", t=num_frames) residual_out = self.audio_injector.injector[audio_attn_id]( x=attn_x , context=attn_audio_emb * scale, ) residual_out = rearrange(residual_out, "(b t) n c -> b (t n) c", t=num_frames) x[:, :self.original_seq_len].add_(residual_out) return x def wananimate_pose_embedding(self, x, pose_latents, strength=1.0): pose_latents = [self.pose_patch_embedding(u.unsqueeze(0).to(torch.float32)).to(x[0].dtype) for u in pose_latents] for x_, pose_latents_ in zip(x, pose_latents): x_[:, :, 1:].add_(pose_latents_, alpha=strength) return x def wananimate_face_embedding(self, face_pixel_values): b,c,T,h,w = face_pixel_values.shape face_pixel_values = rearrange(face_pixel_values, "b c t h w -> (b t) c h w") encode_bs = 8 face_pixel_values_tmp = [] self.motion_encoder.to(self.main_device) for i in range(math.ceil(face_pixel_values.shape[0]/encode_bs)): face_pixel_values_tmp.append(self.motion_encoder(face_pixel_values[i*encode_bs:(i+1)*encode_bs])) del face_pixel_values self.motion_encoder.to(self.offload_device) motion_vec = rearrange(torch.cat(face_pixel_values_tmp), "(b t) c -> b t c", t=T) del face_pixel_values_tmp self.face_encoder.to(self.main_device) motion_vec = self.face_encoder(motion_vec.to(self.face_encoder.dtype)) self.face_encoder.to(self.offload_device) B, L, H, C = motion_vec.shape pad_face = torch.zeros(B, 1, H, C, device=motion_vec.device, dtype=motion_vec.dtype) return torch.cat([pad_face, motion_vec], dim=1) def wananimate_forward(self, block, x, motion_vec, strength=1.0, motion_masks=None): adapter_args = [x, motion_vec, motion_masks] residual_out = block.fuser_block(*adapter_args) return x.add(residual_out, alpha=strength) def rope_encode_comfy(self, t, h, w, freq_offset=0, t_start=0, attn_cond_shape=None, steps_t=None, steps_h=None, steps_w=None, ntk_alphas=[1,1,1], device=None, dtype=None): patch_size = self.patch_size t_len = ((t + (patch_size[0] // 2)) // patch_size[0]) h_len = ((h + (patch_size[1] // 2)) // patch_size[1]) w_len = ((w + (patch_size[2] // 2)) // patch_size[2]) if steps_t is None: steps_t = t_len if steps_h is None: steps_h = h_len if steps_w is None: steps_w = w_len img_ids = torch.zeros((steps_t, steps_h, steps_w, 3), device=device, dtype=dtype) img_ids[:, :, :, 0] = img_ids[:, :, :, 0] + torch.linspace(t_start+freq_offset, t_start + (t_len - 1), steps=steps_t, device=device, dtype=dtype).reshape(-1, 1, 1) img_ids[:, :, :, 1] = img_ids[:, :, :, 1] + torch.linspace(freq_offset, h_len - 1, steps=steps_h, device=device, dtype=dtype).reshape(1, -1, 1) img_ids[:, :, :, 2] = img_ids[:, :, :, 2] + torch.linspace(freq_offset, w_len - 1, steps=steps_w, device=device, dtype=dtype).reshape(1, 1, -1) img_ids = img_ids.reshape(1, -1, img_ids.shape[-1]) if attn_cond_shape is not None: F_cond, H_cond, W_cond = attn_cond_shape[2], attn_cond_shape[3], attn_cond_shape[4] cond_f_len = ((F_cond + (self.patch_size[0] // 2)) // self.patch_size[0]) cond_h_len = ((H_cond + (self.patch_size[1] // 2)) // self.patch_size[1]) cond_w_len = ((W_cond + (self.patch_size[2] // 2)) // self.patch_size[2]) cond_img_ids = torch.zeros((cond_f_len, cond_h_len, cond_w_len, 3), device=device, dtype=dtype) #shift shift_f_size = 81 # Default value shift_f = False if shift_f: cond_img_ids[:, :, :, 0] = cond_img_ids[:, :, :, 0] + torch.linspace(shift_f_size, shift_f_size + cond_f_len - 1,steps=cond_f_len, device=device, dtype=dtype).reshape(-1, 1, 1) else: cond_img_ids[:, :, :, 0] = cond_img_ids[:, :, :, 0] + torch.linspace(0, cond_f_len - 1, steps=cond_f_len, device=device, dtype=dtype).reshape(-1, 1, 1) cond_img_ids[:, :, :, 1] = cond_img_ids[:, :, :, 1] + torch.linspace(h_len, h_len + cond_h_len - 1, steps=cond_h_len, device=device, dtype=dtype).reshape(1, -1, 1) cond_img_ids[:, :, :, 2] = cond_img_ids[:, :, :, 2] + torch.linspace(w_len, w_len + cond_w_len - 1, steps=cond_w_len, device=device, dtype=dtype).reshape(1, 1, -1) # Combine original and conditional position ids #img_ids = repeat(img_ids, "t h w c -> b (t h w) c", b=1) #cond_img_ids = repeat(cond_img_ids, "t h w c -> b (t h w) c", b=1) cond_img_ids = cond_img_ids.reshape(1, -1, cond_img_ids.shape[-1]) combined_img_ids = torch.cat([img_ids, cond_img_ids], dim=1) # Generate RoPE frequencies for the combined positions freqs = self.rope_embedder(combined_img_ids, ntk_alphas).movedim(1, 2) else: freqs = self.rope_embedder(img_ids, ntk_alphas).movedim(1, 2) return freqs def forward( self, x, t, context, seq_len, is_uncond=False, current_step_percentage=0.0, current_step=0, last_step=0, total_steps=50, clip_fea=None, y=None, device=torch.device('cuda'), freqs=None, enhance_enabled=False, pred_id=None, control_lora_enabled=False, vace_data=None, camera_embed=None, unianim_data=None, fps_embeds=None, fun_ref=None, fun_camera=None, audio_proj=None, audio_scale=1.0, uni3c_data=None, controlnet=None, add_cond=None, attn_cond=None, nag_params={}, nag_context=None, multitalk_audio=None, ref_target_masks=None, inner_t=None, standin_input=None, fantasy_portrait_input=None, phantom_ref=None, reverse_time=False, ntk_alphas = [1.0, 1.0, 1.0], mtv_motion_tokens=None, mtv_motion_rotary_emb=None, mtv_freqs=None, mtv_strength=1.0, s2v_audio_input=None, s2v_ref_latent=None, s2v_audio_scale=1.0, s2v_ref_motion=None, s2v_pose=None, s2v_motion_frames=[1, 0], humo_audio=None, humo_audio_scale=1.0, wananim_pose_latents=None, wananim_face_pixel_values=None, wananim_pose_strength=1.0, wananim_face_strength=1.0, lynx_embeds=None, ): r""" Forward pass through the diffusion model Args: x (List[Tensor]): List of input video tensors, each with shape [C_in, F, H, W] t (Tensor): Diffusion timesteps tensor of shape [B] context (List[Tensor]): List of text embeddings each with shape [L, C] seq_len (`int`): Maximum sequence length for positional encoding clip_fea (Tensor, *optional*): CLIP image features for image-to-video mode y (List[Tensor], *optional*): Conditional video inputs for image-to-video mode, same shape as x Returns: List[Tensor]: List of denoised video tensors with original input shapes [C_out, F, H / 8, W / 8] """ # Stand-In only used on first positive pass, then cached in kv_cache if is_uncond or current_step > 0: standin_input = None # MTV Crafter motion projection if mtv_motion_tokens is not None: bs, motion_seq_len = mtv_motion_tokens.shape[0], mtv_motion_tokens.shape[1] mtv_motion_tokens = torch.cat([mtv_motion_tokens, self.pad_motion_tokens.to(mtv_motion_tokens).expand(bs, motion_seq_len, -1)], dim=-1) # Fantasy Portrait adapter_proj = ip_scale = None if fantasy_portrait_input is not None: if fantasy_portrait_input['start_percent'] <= current_step_percentage <= fantasy_portrait_input['end_percent']: adapter_proj = fantasy_portrait_input.get("adapter_proj", None) ip_scale = fantasy_portrait_input.get("strength", 1.0) if self.lora_scheduling_enabled: for name, submodule in self.named_modules(): if isinstance(submodule, nn.Linear): if hasattr(submodule, 'step'): submodule.step = current_step # lynx lynx_x_ip = lynx_ref_feature = lynx_ref_buffer = lynx_ref_feature_extractor = None lynx_ip_scale = lynx_ref_scale = 1.0 if lynx_embeds is not None: lynx_ref_feature_extractor = lynx_embeds.get("ref_feature_extractor", False) lynx_ref_blocks_to_use = lynx_embeds.get("ref_blocks_to_use", None) if lynx_ref_blocks_to_use is None: lynx_ref_blocks_to_use = list(range(len(self.blocks))) if (lynx_embeds['start_percent'] <= current_step_percentage <= lynx_embeds['end_percent']) and not lynx_ref_feature_extractor: if not is_uncond: lynx_x_ip = lynx_embeds.get("ip_x", None) lynx_ref_buffer = lynx_embeds.get("ref_buffer", None) else: lynx_x_ip = lynx_embeds.get("ip_x_uncond", None) lynx_ref_buffer = lynx_embeds.get("ref_buffer_uncond", None) lynx_x_ip = lynx_x_ip.to(self.main_device) if lynx_x_ip is not None else None lynx_ip_scale = lynx_embeds.get("ip_scale", 1.0) lynx_ref_scale = lynx_embeds.get("ref_scale", 1.0) #s2v if self.model_type == 's2v' and s2v_audio_input is not None: if is_uncond: s2v_audio_input = s2v_audio_input * 0 # to match original code s2v_audio_input = torch.cat([s2v_audio_input[..., 0:1].repeat(1, 1, 1, s2v_motion_frames[0]), s2v_audio_input], dim=-1) audio_emb_res = self.casual_audio_encoder(s2v_audio_input) if self.enable_adain: audio_emb_global, audio_emb = audio_emb_res self.audio_emb_global = audio_emb_global[:, s2v_motion_frames[1]:].clone() else: audio_emb = audio_emb_res merged_audio_emb = audio_emb[:, s2v_motion_frames[1]:, :] # params device = self.patch_embedding.weight.device if freqs is not None and freqs.device != device: freqs = freqs.to(device) _, F, H, W = x[0].shape if y is not None: if hasattr(self, "randomref_embedding_pose") and unianim_data is not None: if unianim_data['start_percent'] <= current_step_percentage <= unianim_data['end_percent']: random_ref_emb = unianim_data["random_ref"] if random_ref_emb is not None: y[0].add_(random_ref_emb, alpha=unianim_data["strength"]) x = [torch.cat([u, v], dim=0) for u, v in zip(x, y)] #uni3c controlnet if uni3c_data is not None: render_latent = uni3c_data["render_latent"].to(self.base_dtype) hidden_states = x[0].unsqueeze(0).clone().float() if hidden_states.shape[1] == 16: #T2V work around hidden_states = torch.cat([hidden_states, torch.zeros_like(hidden_states[:, :4])], dim=1) render_latent = torch.cat([hidden_states[:, :20], render_latent], dim=1) # patch embed if control_lora_enabled: self.expanded_patch_embedding.to(device) x = [ self.expanded_patch_embedding(u.unsqueeze(0).to(torch.float32)).to(x[0].dtype) for u in x ] else: self.original_patch_embedding.to(self.main_device) x = [ self.original_patch_embedding(u.unsqueeze(0).to(torch.float32)).to(x[0].dtype) for u in x ] # WanAnimate motion_vec = None if wananim_face_pixel_values is not None: motion_vec = self.wananimate_face_embedding(wananim_face_pixel_values).to(self.base_dtype) if wananim_pose_latents is not None: x = self.wananimate_pose_embedding(x, wananim_pose_latents, strength=wananim_pose_strength) # s2v pose embedding if s2v_pose is not None: x[0] = x[0] + self.cond_encoder(s2v_pose.to(self.cond_encoder.weight.dtype)).to(self.base_dtype) # Fun camera if self.control_adapter is not None and fun_camera is not None: fun_camera = self.control_adapter(fun_camera) x = [u + v for u, v in zip(x, fun_camera)] grid_sizes = torch.stack([torch.tensor(u.shape[2:], device=device, dtype=torch.long) for u in x]) original_grid_sizes = grid_sizes.clone() x = [u.flatten(2).transpose(1, 2) for u in x] seq_lens = torch.tensor([u.size(1) for u in x], dtype=torch.int32) assert seq_lens.max() <= seq_len cond_mask_weight = None if self.trainable_cond_mask is not None: cond_mask_weight = self.trainable_cond_mask.weight.to(x[0]).unsqueeze(1).unsqueeze(1) self.original_seq_len = x[0].shape[1] if add_cond is not None: add_cond = self.add_conv_in(add_cond.to(self.add_conv_in.weight.dtype)).to(x[0].dtype) add_cond = add_cond.flatten(2).transpose(1, 2) x[0] = x[0] + self.add_proj(add_cond) attn_cond_shape = None if attn_cond is not None: attn_cond_shape = attn_cond.shape grid_sizes = torch.stack([torch.tensor([u[0] + 1, u[1], u[2]]) for u in grid_sizes]).to(grid_sizes.device) attn_cond = self.attn_conv_in(attn_cond.to(self.attn_conv_in.weight.dtype)).to(x[0].dtype) attn_cond = attn_cond.flatten(2).transpose(1, 2) x[0] = torch.cat([x[0], attn_cond], dim=1) seq_len += attn_cond.size(1) for block in self.blocks: block.self_attn.mask_map = MaskMap(video_token_num=seq_len, num_frame=F+1) if self.ref_conv is not None and fun_ref is not None: fun_ref = self.ref_conv(fun_ref).flatten(2).transpose(1, 2) grid_sizes = torch.stack([torch.tensor([u[0] + 1, u[1], u[2]]) for u in grid_sizes]).to(grid_sizes.device) seq_len += fun_ref.size(1) F += 1 x = [torch.cat([_fun_ref.unsqueeze(0), u], dim=1) for _fun_ref, u in zip(fun_ref, x)] end_ref_latent=None if s2v_ref_latent is not None: end_ref_latent = s2v_ref_latent.squeeze(0) elif phantom_ref is not None: end_ref_latent = phantom_ref F += end_ref_latent.size(1) if end_ref_latent is not None: end_ref_latent_frames = end_ref_latent.size(1) end_ref_latent = self.original_patch_embedding(end_ref_latent.unsqueeze(0).to(torch.float32)).to(x[0].dtype) end_ref_latent = end_ref_latent.flatten(2).transpose(1, 2) if cond_mask_weight is not None: end_ref_latent = end_ref_latent + cond_mask_weight[1] grid_sizes = torch.stack([torch.tensor([u[0] + end_ref_latent_frames, u[1], u[2]]) for u in grid_sizes]).to(grid_sizes.device) end_ref_latent_seq_len = end_ref_latent.size(1) seq_len += end_ref_latent_seq_len x = [torch.cat([u, end_ref_latent.unsqueeze(0)], dim=1) for end_ref_latent, u in zip(end_ref_latent, x)] x = torch.cat([ torch.cat([u, u.new_zeros(1, seq_len - u.size(1), u.size(2))], dim=1) for u in x ]) if self.trainable_cond_mask is not None: x = x + cond_mask_weight[0] # StandIn LoRA input x_ip = None freq_offset = 0 if standin_input is not None: ip_image = standin_input["ip_image_latent"] if ip_image.dim() == 6 and ip_image.shape[3] == 1: ip_image = ip_image.squeeze(1) ip_image_patch = self.original_patch_embedding(ip_image.float()).to(self.base_dtype) f_ip, h_ip, w_ip = ip_image_patch.shape[2:] x_ip = ip_image_patch.flatten(2).transpose(1, 2) # [B, N, D] freq_offset = standin_input["freq_offset"] if freqs is None: #comfy rope current_shape = (F, H, W) has_cond = attn_cond is not None if (self.cached_freqs is not None and self.cached_shape == current_shape and self.cached_cond == has_cond and self.cached_rope_k == self.rope_embedder.k and self.cached_ntk_alphas == ntk_alphas ): freqs = self.cached_freqs else: freqs = self.rope_encode_comfy(F, H, W, freq_offset=freq_offset, ntk_alphas=ntk_alphas, attn_cond_shape=attn_cond_shape, device=x.device, dtype=x.dtype) if s2v_ref_latent is not None: freqs_ref = self.rope_encode_comfy( s2v_ref_latent.shape[2], s2v_ref_latent.shape[3], s2v_ref_latent.shape[4], t_start=max(30, F + 9), device=x.device, dtype=x.dtype) freqs = torch.cat([freqs, freqs_ref], dim=1) self.cached_freqs = freqs self.cached_shape = current_shape self.cached_cond = has_cond self.cached_rope_k = self.rope_embedder.k self.cached_ntk_alphas = ntk_alphas # Stand-In RoPE frequencies if x_ip is not None: # Generate RoPE frequencies for x_ip h_len = (H + 1) // 2 w_len = (W + 1) // 2 ip_img_ids = torch.zeros((f_ip, h_ip, w_ip, 3), device=x.device, dtype=x.dtype) ip_img_ids[:, :, :, 0] = ip_img_ids[:, :, :, 0] + torch.linspace(0, f_ip - 1, steps=f_ip, device=x.device, dtype=x.dtype).reshape(-1, 1, 1) ip_img_ids[:, :, :, 1] = ip_img_ids[:, :, :, 1] + torch.linspace(h_len + freq_offset, h_len + freq_offset + h_ip - 1, steps=h_ip, device=x.device, dtype=x.dtype).reshape(1, -1, 1) ip_img_ids[:, :, :, 2] = ip_img_ids[:, :, :, 2] + torch.linspace(w_len + freq_offset, w_len + freq_offset + w_ip - 1, steps=w_ip, device=x.device, dtype=x.dtype).reshape(1, 1, -1) ip_img_ids = repeat(ip_img_ids, "t h w c -> b (t h w) c", b=1) freqs_ip = self.rope_embedder(ip_img_ids).movedim(1, 2) # EchoShot cross attn freqs inner_c = None if inner_t is not None: d = self.dim // self.num_heads self.cross_freqs = rope_params(100, d).to(device=x.device) if s2v_ref_motion is not None: motion_encoded, freqs_motion = self.frame_packer(s2v_ref_motion, self) motion_encoded = motion_encoded + cond_mask_weight[2] x = torch.cat([x, motion_encoded], dim=1) freqs = torch.cat([freqs, freqs_motion], dim=1) # time embeddings if t.dim() == 2: b, f = t.shape expanded_timesteps = True else: expanded_timesteps = False if self.zero_timestep: t = torch.cat([t, torch.zeros([1], dtype=t.dtype, device=t.device)]) time_embed_dtype = self.time_embedding[0].weight.dtype if time_embed_dtype not in [torch.float16, torch.bfloat16, torch.float32]: time_embed_dtype = self.base_dtype e = self.time_embedding(sinusoidal_embedding_1d(self.freq_dim, t.flatten()).to(time_embed_dtype)) # b, dim e0 = self.time_projection(e).unflatten(1, (6, self.dim)) # b, 6, dim #S2V zero timestep if self.zero_timestep: e = e[:-1] zero_e0 = e0[-1:] e0 = e0[:-1] e0 = torch.cat([ e0.unsqueeze(2), zero_e0.unsqueeze(2).repeat(e0.size(0), 1, 1, 1) ], dim=2) e0 = [e0, self.original_seq_len] if x_ip is not None: timestep_ip = torch.zeros_like(t) # [B] with 0s t_ip = self.time_embedding(sinusoidal_embedding_1d(self.freq_dim, timestep_ip.flatten()).to(time_embed_dtype)) # b, dim ) e0_ip = self.time_projection(t_ip).unflatten(1, (6, self.dim)) if fps_embeds is not None: fps_embeds = torch.tensor(fps_embeds, dtype=torch.long, device=device) fps_emb = self.fps_embedding(fps_embeds).to(e0.dtype) if expanded_timesteps: e0 = e0 + self.fps_projection(fps_emb).unflatten(1, (6, self.dim)).repeat(t.shape[1], 1, 1) else: e0 = e0 + self.fps_projection(fps_emb).unflatten(1, (6, self.dim)) if expanded_timesteps: e = e.view(b, f, 1, 1, self.dim).expand(b, f, grid_sizes[0][1], grid_sizes[0][2], self.dim) e0 = e0.view(b, f, 1, 1, 6, self.dim).expand(b, f, grid_sizes[0][1], grid_sizes[0][2], 6, self.dim) e = e.flatten(1, 3) e0 = e0.flatten(1, 3) e0 = e0.transpose(1, 2) if not e0.is_contiguous(): e0 = e0.contiguous() e = e.to(self.offload_device, non_blocking=self.use_non_blocking) #context (text embedding) if hasattr(self, "text_embedding") and context != []: text_embed_dtype = self.text_embedding[0].weight.dtype if text_embed_dtype not in [torch.float16, torch.bfloat16, torch.float32]: text_embed_dtype = self.base_dtype if self.offload_txt_emb: self.text_embedding.to(self.main_device) if inner_t is not None: if nag_context is not None: raise NotImplementedError("nag_context is not supported with EchoShot") inner_c = [[u.shape[0] for u in context]] context = self.text_embedding( torch.stack([ torch.cat( [u, u.new_zeros(self.text_len - u.size(0), u.size(1))]) for u in context ]).to(text_embed_dtype)) # NAG if nag_context is not None: nag_context = self.text_embedding( torch.stack([ torch.cat( [u, u.new_zeros(self.text_len - u.size(0), u.size(1))]) for u in nag_context ]).to(text_embed_dtype)) if self.offload_txt_emb: self.text_embedding.to(self.offload_device, non_blocking=self.use_non_blocking) else: context = None clip_embed = None if clip_fea is not None and hasattr(self, "img_emb"): clip_fea = clip_fea.to(self.main_device) if self.offload_img_emb: self.img_emb.to(self.main_device) clip_embed = self.img_emb(clip_fea) # bs x 257 x dim #context = torch.concat([context_clip, context], dim=1) if self.offload_img_emb: self.img_emb.to(self.offload_device, non_blocking=self.use_non_blocking) # MultiTalk if multitalk_audio is not None: self.multitalk_audio_proj.to(self.main_device) audio_cond = multitalk_audio.to(device=x.device, dtype=self.base_dtype) first_frame_audio_emb_s = audio_cond[:, :1, ...] latter_frame_audio_emb = audio_cond[:, 1:, ...] latter_frame_audio_emb = rearrange(latter_frame_audio_emb, "b (n_t n) w s c -> b n_t n w s c", n=4) middle_index = self.multitalk_audio_proj.seq_len // 2 latter_first_frame_audio_emb = latter_frame_audio_emb[:, :, :1, :middle_index+1, ...] latter_first_frame_audio_emb = rearrange(latter_first_frame_audio_emb, "b n_t n w s c -> b n_t (n w) s c") latter_last_frame_audio_emb = latter_frame_audio_emb[:, :, -1:, middle_index:, ...] latter_last_frame_audio_emb = rearrange(latter_last_frame_audio_emb, "b n_t n w s c -> b n_t (n w) s c") latter_middle_frame_audio_emb = latter_frame_audio_emb[:, :, 1:-1, middle_index:middle_index+1, ...] latter_middle_frame_audio_emb = rearrange(latter_middle_frame_audio_emb, "b n_t n w s c -> b n_t (n w) s c") latter_frame_audio_emb_s = torch.concat([latter_first_frame_audio_emb, latter_middle_frame_audio_emb, latter_last_frame_audio_emb], dim=2) multitalk_audio_embedding = self.multitalk_audio_proj(first_frame_audio_emb_s, latter_frame_audio_emb_s) human_num = len(multitalk_audio_embedding) multitalk_audio_embedding = torch.concat(multitalk_audio_embedding.split(1), dim=2).to(self.base_dtype) self.multitalk_audio_proj.to(self.offload_device) # convert ref_target_masks to token_ref_target_masks token_ref_target_masks = None if ref_target_masks is not None: ref_target_masks = ref_target_masks.unsqueeze(0).to(torch.float32) token_ref_target_masks = nn.functional.interpolate(ref_target_masks, size=(H // 2, W // 2), mode='nearest') token_ref_target_masks = token_ref_target_masks.squeeze(0) token_ref_target_masks = (token_ref_target_masks > 0) token_ref_target_masks = token_ref_target_masks.view(token_ref_target_masks.shape[0], -1) token_ref_target_masks = token_ref_target_masks.to(device, self.base_dtype) humo_audio_input = None if humo_audio is not None: humo_audio_input = self.audio_proj(humo_audio.unsqueeze(0)).permute(0, 3, 1, 2) humo_audio_seq_len = torch.tensor(humo_audio.shape[2] * humo_audio_input.shape[3], device=device) humo_audio_input = humo_audio_input.flatten(2).transpose(1, 2) # 1, t*32, 1536 pad_len = int(humo_audio_seq_len - humo_audio_input.size(1)) if pad_len > 0: humo_audio_input = torch.nn.functional.pad(humo_audio_input, (0, 0, 0, pad_len)) should_calc = True #TeaCache if self.enable_teacache and self.teacache_start_step <= current_step <= self.teacache_end_step: accumulated_rel_l1_distance = torch.tensor(0.0, dtype=torch.float32, device=device) if pred_id is None: pred_id = self.teacache_state.new_prediction(cache_device=self.cache_device) should_calc = True else: previous_modulated_input = self.teacache_state.get(pred_id)['previous_modulated_input'] previous_modulated_input = previous_modulated_input.to(device) previous_residual = self.teacache_state.get(pred_id)['previous_residual'] accumulated_rel_l1_distance = self.teacache_state.get(pred_id)['accumulated_rel_l1_distance'] if self.teacache_use_coefficients: rescale_func = np.poly1d(self.teacache_coefficients[self.teacache_mode]) temb = e if self.teacache_mode == 'e' else e0 accumulated_rel_l1_distance += rescale_func(( (temb.to(device) - previous_modulated_input).abs().mean() / previous_modulated_input.abs().mean() ).cpu().item()) del temb else: temb_relative_l1 = relative_l1_distance(previous_modulated_input, e0) accumulated_rel_l1_distance = accumulated_rel_l1_distance.to(e0.device) + temb_relative_l1 del temb_relative_l1 if accumulated_rel_l1_distance < self.rel_l1_thresh: should_calc = False else: should_calc = True accumulated_rel_l1_distance = torch.tensor(0.0, dtype=torch.float32, device=device) accumulated_rel_l1_distance = accumulated_rel_l1_distance.to(self.cache_device) previous_modulated_input = e.to(self.cache_device).clone() if (self.teacache_use_coefficients and self.teacache_mode == 'e') else e0.to(self.cache_device).clone() if not should_calc: x = x.to(previous_residual.dtype) + previous_residual.to(x.device) self.teacache_state.update( pred_id, accumulated_rel_l1_distance=accumulated_rel_l1_distance, ) self.teacache_state.get(pred_id)['skipped_steps'].append(current_step) # MagCache if self.enable_magcache and self.magcache_start_step <= current_step <= self.magcache_end_step: if pred_id is None: pred_id = self.magcache_state.new_prediction(cache_device=self.cache_device) should_calc = True else: accumulated_ratio = self.magcache_state.get(pred_id)['accumulated_ratio'] accumulated_err = self.magcache_state.get(pred_id)['accumulated_err'] accumulated_steps = self.magcache_state.get(pred_id)['accumulated_steps'] calibration_len = len(self.magcache_ratios) // 2 cur_mag_ratio = self.magcache_ratios[int((current_step*(calibration_len/total_steps)))] accumulated_ratio *= cur_mag_ratio accumulated_err += np.abs(1-accumulated_ratio) accumulated_steps += 1 self.magcache_state.update( pred_id, accumulated_ratio=accumulated_ratio, accumulated_steps=accumulated_steps, accumulated_err=accumulated_err ) if accumulated_err<=self.magcache_thresh and accumulated_steps<=self.magcache_K: should_calc = False x += self.magcache_state.get(pred_id)['residual_cache'].to(x.device) self.magcache_state.get(pred_id)['skipped_steps'].append(current_step) else: should_calc = True self.magcache_state.update( pred_id, accumulated_ratio=1.0, accumulated_steps=0, accumulated_err=0 ) # EasyCache if self.enable_easycache and self.easycache_start_step <= current_step <= self.easycache_end_step: if pred_id is None: pred_id = self.easycache_state.new_prediction(cache_device=self.cache_device) should_calc = True else: state = self.easycache_state.get(pred_id) previous_raw_input = state.get('previous_raw_input') previous_raw_output = state.get('previous_raw_output') cache = state.get('cache') accumulated_error = state.get('accumulated_error') k = state.get('k', 1) if previous_raw_input is not None and previous_raw_output is not None: raw_input = x.clone() # Calculate input change raw_input_change = (raw_input - previous_raw_input.to(raw_input.device)).abs().mean() output_norm = (previous_raw_output.to(x.device)).abs().mean() combined_pred_change = (raw_input_change / output_norm) * k accumulated_error += combined_pred_change # Predict output change if accumulated_error < self.easycache_thresh: should_calc = False x = raw_input + cache.to(x.device) state['skipped_steps'].append(current_step) else: should_calc = True else: should_calc = True x = x.to(self.base_dtype) if isinstance(e0, list): e0 = [item.to(self.base_dtype) if torch.is_tensor(item) else item for item in e0] else: e0 = e0.to(self.base_dtype) if self.enable_easycache: original_x = x.clone().to(self.cache_device) if should_calc: if self.enable_teacache or self.enable_magcache: original_x = x.clone().to(self.cache_device) if hasattr(self, "dwpose_embedding") and unianim_data is not None: if unianim_data['start_percent'] <= current_step_percentage <= unianim_data['end_percent']: dwpose_emb = rearrange(unianim_data['dwpose'], 'b c f h w -> b (f h w) c').contiguous() x.add_(dwpose_emb, alpha=unianim_data['strength']) # arguments kwargs = dict( e=e0, seq_lens=seq_lens, grid_sizes=grid_sizes, freqs=freqs, context=context, clip_embed=clip_embed, current_step=current_step, last_step=last_step, video_attention_split_steps=self.video_attention_split_steps, camera_embed=camera_embed, audio_proj=audio_proj, num_latent_frames = F, original_seq_len=self.original_seq_len, enhance_enabled=enhance_enabled, audio_scale=audio_scale, nag_params=nag_params, nag_context=nag_context, is_uncond = is_uncond, multitalk_audio_embedding=multitalk_audio_embedding if multitalk_audio is not None else None, ref_target_masks=token_ref_target_masks if multitalk_audio is not None else None, human_num=human_num if multitalk_audio is not None else 0, inner_t=inner_t, inner_c=inner_c, cross_freqs=self.cross_freqs if inner_t is not None else None, freqs_ip=freqs_ip if x_ip is not None else None, e_ip=e0_ip if x_ip is not None else None, adapter_proj=adapter_proj, ip_scale=ip_scale, reverse_time=reverse_time, mtv_motion_tokens=mtv_motion_tokens, mtv_motion_rotary_emb=mtv_motion_rotary_emb, mtv_strength=mtv_strength, mtv_freqs=mtv_freqs, humo_audio_input=humo_audio_input, humo_audio_scale=humo_audio_scale, lynx_x_ip=lynx_x_ip, lynx_ip_scale=lynx_ip_scale, lynx_ref_scale=lynx_ref_scale, ) if vace_data is not None: vace_hint_list = [] vace_scale_list = [] if isinstance(vace_data[0], dict): for data in vace_data: if (data["start"] <= current_step_percentage <= data["end"]) or \ (data["end"] > 0 and current_step == 0 and current_step_percentage >= data["start"]): vace_hints = self.forward_vace(x, data["context"], data["seq_len"], kwargs) vace_hint_list.append(vace_hints) vace_scale_list.append(data["scale"][current_step]) else: vace_hints = self.forward_vace(x, vace_data, seq_len, kwargs) vace_hint_list.append(vace_hints) vace_scale_list.append(1.0) kwargs['vace_hints'] = vace_hint_list kwargs['vace_context_scale'] = vace_scale_list #uni3c controlnet uni3c_controlnet_states = None if uni3c_data is not None: if (uni3c_data["start"] <= current_step_percentage <= uni3c_data["end"]) or \ (uni3c_data["end"] > 0 and current_step == 0 and current_step_percentage >= uni3c_data["start"]): self.controlnet.to(self.main_device) with torch.autocast(device_type=mm.get_autocast_device(device), dtype=self.base_dtype, enabled=True): uni3c_controlnet_states = self.controlnet( render_latent=render_latent.to(self.main_device, self.controlnet.dtype), render_mask=uni3c_data["render_mask"], camera_embedding=uni3c_data["camera_embedding"], temb=e.to(self.main_device), device=self.offload_device) self.controlnet.to(self.offload_device) # Asynchronous block offloading with CUDA streams and events if torch.cuda.is_available(): cuda_stream = None #torch.cuda.Stream(device=device, priority=0) # todo causes issues on some systems events = [torch.cuda.Event() for _ in self.blocks] swap_start_idx = len(self.blocks) - self.blocks_to_swap if self.blocks_to_swap > 0 else len(self.blocks) else: cuda_stream = None events = None swap_start_idx = len(self.blocks) # lynx ref if lynx_ref_buffer is None and lynx_ref_feature_extractor: lynx_ref_buffer = {} for b, block in enumerate(self.blocks): block_idx = f"{b:02d}" if lynx_ref_buffer is not None and not lynx_ref_feature_extractor: lynx_ref_feature = lynx_ref_buffer.get(block_idx, None) else: lynx_ref_feature = None # Prefetch blocks if enabled if self.prefetch_blocks > 0: for prefetch_offset in range(1, self.prefetch_blocks + 1): prefetch_idx = b + prefetch_offset if prefetch_idx < len(self.blocks) and self.blocks_to_swap > 0 and prefetch_idx >= swap_start_idx: context_mgr = torch.cuda.stream(cuda_stream) if torch.cuda.is_available() else nullcontext() with context_mgr: self.blocks[prefetch_idx].to(self.main_device, non_blocking=self.use_non_blocking) if events is not None: events[prefetch_idx].record(cuda_stream) if self.block_swap_debug: transfer_start = time.perf_counter() # Wait for block to be ready if b >= swap_start_idx and self.blocks_to_swap > 0: if self.prefetch_blocks > 0 and events is not None: if not events[b].query(): events[b].synchronize() block.to(self.main_device) if self.block_swap_debug: transfer_end = time.perf_counter() transfer_time = transfer_end - transfer_start compute_start = time.perf_counter() #skip layer guidance if self.slg_blocks is not None: if b in self.slg_blocks and is_uncond: if self.slg_start_percent <= current_step_percentage <= self.slg_end_percent: continue x, x_ip, lynx_ref_feature = block(x, x_ip=x_ip, lynx_ref_feature=lynx_ref_feature, **kwargs) #run block if self.audio_injector is not None and s2v_audio_input is not None: x = self.audio_injector_forward(b, x, merged_audio_emb, scale=s2v_audio_scale) #s2v if block.has_face_fuser_block and motion_vec is not None: x = self.wananimate_forward(block, x, motion_vec, strength=wananim_face_strength) if self.block_swap_debug: compute_end = time.perf_counter() compute_time = compute_end - compute_start to_cpu_transfer_start = time.perf_counter() if b >= swap_start_idx and self.blocks_to_swap > 0: block.to(self.offload_device, non_blocking=self.use_non_blocking) if self.block_swap_debug: to_cpu_transfer_end = time.perf_counter() to_cpu_transfer_time = to_cpu_transfer_end - to_cpu_transfer_start log.info(f"Block {b}: transfer_time={transfer_time:.4f}s, compute_time={compute_time:.4f}s, to_cpu_transfer_time={to_cpu_transfer_time:.4f}s") # lynx ref if lynx_ref_feature_extractor: if b in lynx_ref_blocks_to_use: log.info(f"storing to lynx ref buffer for block {block_idx}") lynx_ref_buffer[block_idx] = lynx_ref_feature #uni3c controlnet if uni3c_controlnet_states is not None and b < len(uni3c_controlnet_states): x[:, :self.original_seq_len] += uni3c_controlnet_states[b].to(x) * uni3c_data["controlnet_weight"] #controlnet if (controlnet is not None) and (b % controlnet["controlnet_stride"] == 0) and (b // controlnet["controlnet_stride"] < len(controlnet["controlnet_states"])): x[:, :self.original_seq_len] += controlnet["controlnet_states"][b // controlnet["controlnet_stride"]].to(x) * controlnet["controlnet_weight"] if lynx_ref_feature_extractor: return lynx_ref_buffer if self.enable_teacache and (self.teacache_start_step <= current_step <= self.teacache_end_step) and pred_id is not None: self.teacache_state.update( pred_id, previous_residual=(x.to(original_x.device) - original_x), accumulated_rel_l1_distance=accumulated_rel_l1_distance, previous_modulated_input=previous_modulated_input ) elif self.enable_magcache and (self.magcache_start_step <= current_step <= self.magcache_end_step) and pred_id is not None: self.magcache_state.update( pred_id, residual_cache=(x.to(original_x.device) - original_x) ) elif self.enable_easycache and (self.easycache_start_step <= current_step <= self.easycache_end_step) and pred_id is not None: x_out = x.clone().to(original_x.device) output_change = (x_out - original_x).abs().mean() input_change = (original_x - x_out).abs().mean() self.easycache_state.update( pred_id, previous_raw_input=original_x, previous_raw_output=x_out, cache=x.to(original_x.device) - original_x, k = output_change / input_change, accumulated_error = 0.0 ) if self.enable_easycache and (self.easycache_start_step <= current_step <= self.easycache_end_step) and pred_id is not None: self.easycache_state.update( pred_id, previous_raw_output=x.clone(), ) if self.ref_conv is not None and fun_ref is not None: fun_ref_length = fun_ref.size(1) x = x[:, fun_ref_length:] grid_sizes = torch.stack([torch.tensor([u[0] - 1, u[1], u[2]]) for u in grid_sizes]).to(grid_sizes.device) if end_ref_latent is not None: end_ref_latent_length = end_ref_latent.size(1) x = x[:, :-end_ref_latent_length] grid_sizes = torch.stack([torch.tensor([u[0] - end_ref_latent_frames, u[1], u[2]]) for u in grid_sizes]).to(grid_sizes.device) if attn_cond is not None: x = x[:, :self.original_seq_len] grid_sizes = torch.stack([torch.tensor([u[0] - 1, u[1], u[2]]) for u in grid_sizes]).to(grid_sizes.device) x = x[:, :self.original_seq_len] x = self.head(x, e.to(x.device)) x = self.unpatchify(x, original_grid_sizes) # type: ignore[arg-type] x = [u.float() for u in x] return (x, pred_id) if pred_id is not None else (x, None) def unpatchify(self, x, grid_sizes): r""" Reconstruct video tensors from patch embeddings. Args: x (List[Tensor]): List of patchified features, each with shape [L, C_out * prod(patch_size)] grid_sizes (Tensor): Original spatial-temporal grid dimensions before patching, shape [B, 3] (3 dimensions correspond to F_patches, H_patches, W_patches) Returns: List[Tensor]: Reconstructed video tensors with shape [C_out, F, H / 8, W / 8] """ c = self.out_dim out = [] for u, v in zip(x, grid_sizes.tolist()): u = u[: math.prod(v)].view(*v, *self.patch_size, c) u = torch.einsum("fhwpqrc->cfphqwr", u) u = u.reshape(c, *[i * j for i, j in zip(v, self.patch_size)]) out.append(u) return out