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 # Copyright 2024-2025 The Alibaba Wan Team Authors. All rights reserved.
##### Enjoy this spagheti VRAM optimizations done by DeepBeepMeep !
# I am sure you are a nice person and as you copy this code, you will give me officially proper credits:
# Please link to https://github.com/deepbeepmeep/Wan2GP and @deepbeepmeep on twitter
import math
from einops import rearrange
import torch
import torch.cuda.amp as amp
import torch.nn as nn
from diffusers.configuration_utils import ConfigMixin, register_to_config
from diffusers.models.modeling_utils import ModelMixin
import numpy as np
from typing import Union,Optional
from mmgp import offload
import mmgp.offload as off
def get_cache():
return off.last_offload_obj
def clear_caches():
if off.last_offload_obj is not None and hasattr(off.last_offload_obj, "clear"):
off.last_offload_obj.clear()
from shared.attention import pay_attention
from torch.backends.cuda import sdp_kernel
from ..multitalk.multitalk_utils import get_attn_map_with_target
__all__ = ['WanModel']
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 reshape_latent(latent, latent_frames):
return latent.reshape(latent.shape[0], latent_frames, -1, latent.shape[-1] )
def restore_latent_shape(latent):
return latent.reshape(latent.shape[0], -1, latent.shape[-1] )
def identify_k( b: float, d: int, N: int):
"""
This function identifies the index of the intrinsic frequency component in a RoPE-based pre-trained diffusion transformer.
Args:
b (`float`): The base frequency for RoPE.
d (`int`): Dimension of the frequency tensor
N (`int`): the first observed repetition frame in latent space
Returns:
k (`int`): the index of intrinsic frequency component
N_k (`int`): the period of intrinsic frequency component in latent space
Example:
In HunyuanVideo, b=256 and d=16, the repetition occurs approximately 8s (N=48 in latent space).
k, N_k = identify_k(b=256, d=16, N=48)
In this case, the intrinsic frequency index k is 4, and the period N_k is 50.
"""
# Compute the period of each frequency in RoPE according to Eq.(4)
periods = []
for j in range(1, d // 2 + 1):
theta_j = 1.0 / (b ** (2 * (j - 1) / d))
N_j = round(2 * torch.pi / theta_j)
periods.append(N_j)
# Identify the intrinsic frequency whose period is closed to N(see Eq.(7))
diffs = [abs(N_j - N) for N_j in periods]
k = diffs.index(min(diffs)) + 1
N_k = periods[k-1]
return k, N_k
def rope_params_riflex(max_seq_len, dim, theta=10000, L_test=30, k=6):
assert dim % 2 == 0
exponents = torch.arange(0, dim, 2, dtype=torch.float64).div(dim)
inv_theta_pow = 1.0 / torch.pow(theta, exponents)
inv_theta_pow[k-1] = 0.9 * 2 * torch.pi / L_test
freqs = torch.outer(torch.arange(max_seq_len), inv_theta_pow)
if True:
freqs_cos = freqs.cos().repeat_interleave(2, dim=1).float() # [S, D]
freqs_sin = freqs.sin().repeat_interleave(2, dim=1).float() # [S, D]
return (freqs_cos, freqs_sin)
else:
freqs = torch.polar(torch.ones_like(freqs), freqs) # complex64 # [S, D/2]
return freqs
def relative_l1_distance(last_tensor, current_tensor):
l1_distance = torch.abs(last_tensor - current_tensor).mean()
norm = torch.abs(last_tensor).mean()
relative_l1_distance = l1_distance / norm
return relative_l1_distance.to(torch.float32)
class LoRALinearLayer(nn.Module):
def __init__(
self,
in_features: int,
out_features: int,
rank: int = 128,
dtype: Optional[torch.dtype] = torch.float32,
):
super().__init__()
self.down = nn.Linear(in_features, rank, bias=False, dtype=dtype)
self.up = nn.Linear(rank, out_features, bias=False, dtype=dtype)
self.rank = rank
self.out_features = out_features
self.in_features = in_features
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)
return up_hidden_states.to(orig_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):
r"""
Args:
x(Tensor): Shape [B, L, C]
"""
y = x.float()
y.pow_(2)
y = y.mean(dim=-1, keepdim=True)
y += self.eps
y.rsqrt_()
x *= y
x *= self.weight
return x
# return self._norm(x).type_as(x) * self.weight
def _norm(self, x):
return x * torch.rsqrt(x.pow(2).mean(dim=-1, keepdim=True) + self.eps)
def my_LayerNorm(norm, x):
y = x.float()
y_m = y.mean(dim=-1, keepdim=True)
y -= y_m
del y_m
y.pow_(2)
y = y.mean(dim=-1, keepdim=True)
y += norm.eps
y.rsqrt_()
x = x * y
return x
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 F.layer_norm(
# input, self.normalized_shape, self.weight, self.bias, self.eps
# )
y = super().forward(x)
x = y.type_as(x)
return x
# return super().forward(x).type_as(x)
from .posemb_layers import apply_rotary_emb
class WanSelfAttention(nn.Module):
def __init__(self,
dim,
num_heads,
window_size=(-1, -1),
qk_norm=True,
eps=1e-6,
block_no=0):
assert dim % num_heads == 0
super().__init__()
self.dim = dim
self.num_heads = num_heads
self.head_dim = dim // num_heads
self.window_size = window_size
self.qk_norm = qk_norm
self.eps = eps
self.block_no = block_no
# layers
self.q = nn.Linear(dim, dim)
self.k = nn.Linear(dim, dim)
self.v = nn.Linear(dim, dim)
self.o = nn.Linear(dim, dim)
self.norm_q = WanRMSNorm(dim, eps=eps) if qk_norm else nn.Identity()
self.norm_k = WanRMSNorm(dim, eps=eps) if qk_norm else nn.Identity()
def text_cross_attention(self, xlist, context, return_q = False):
x = xlist[0]
xlist.clear()
b, n, d = x.size(0), self.num_heads, self.head_dim
nag_scale = offload.shared_state.get("_nag_scale",0)
# compute query, key, value
q = self.q(x)
del x
self.norm_q(q)
q= q.view(b, -1, n, d)
k = self.k(context)
self.norm_k(k)
k = k.view(context.shape[0], -1, n, d)
v = self.v(context).view(context.shape[0], -1, n, d)
if nag_scale <= 1 or len(k)==1:
qvl_list=[q, k, v]
if not return_q: del q
del k, v
x = pay_attention(qvl_list, cross_attn= True)
x = x.flatten(2, 3)
else:
nag_tau = offload.shared_state["_nag_tau"]
nag_alpha = offload.shared_state["_nag_alpha"]
qvl_list=[q, k[:1], v[:1]]
x_pos = pay_attention(qvl_list, cross_attn= True)
qvl_list=[q, k[1:], v[1:]]
if not return_q: del q
del k, v
x_neg = pay_attention(qvl_list, cross_attn= True)
x_pos = x_pos.flatten(2, 3)
x_neg = x_neg.flatten(2, 3)
# Behold DeepBeepMeep as the NAG Butcher !: reduce highly VRAM consumption while at the same time turn the source in gibberish
x_neg.mul_(1-nag_scale)
x_neg.add_(x_pos, alpha= nag_scale)
x_guidance = x_neg
del x_neg
norm_positive = torch.norm(x_pos, p=1, dim=-1, keepdim=True)
norm_guidance = torch.norm(x_guidance, p=1, dim=-1, keepdim=True)
scale = norm_guidance / norm_positive
scale = torch.nan_to_num(scale, 10)
factor = 1 / (norm_guidance + 1e-7) * norm_positive * nag_tau
x_guidance = torch.where(scale > nag_tau, x_guidance * factor, x_guidance )
del norm_positive, norm_guidance
x_pos.mul_(1 - nag_alpha)
x_guidance.mul_(nag_alpha)
x_guidance.add_(x_pos)
x = x_guidance
# x_guidance = x_pos * nag_scale - x_neg * (nag_scale - 1)
# norm_positive = torch.norm(x_pos, p=1, dim=-1, keepdim=True).expand(*x_pos.shape)
# norm_guidance = torch.norm(x_guidance, p=1, dim=-1, keepdim=True).expand(*x_guidance.shape)
# scale = norm_guidance / norm_positive
# scale = torch.nan_to_num(scale, 10)
# x_guidance[scale > nag_tau] = x_guidance[scale > nag_tau] / (norm_guidance[scale > nag_tau] + 1e-7) * norm_positive[scale > nag_tau] * nag_tau
# x = x_guidance * nag_alpha + x_pos * (1 - nag_alpha)
if return_q:
return x, q
else:
return x, None
def forward(self, xlist, grid_sizes, freqs, block_mask = None, ref_target_masks = None, ref_images_count = 0, standin_phase =-1):
r"""
Args:
x(Tensor): Shape [B, L, num_heads, C / num_heads]
grid_sizes(Tensor): Shape [B, 3], the second dimension contains (F, H, W)
freqs(Tensor): Rope freqs, shape [1024, C / num_heads / 2]
"""
x = xlist[0]
xlist.clear()
b, s, n, d = *x.shape[:2], self.num_heads, self.head_dim
# query, key, value function
q, k, v = self.q(x), self.k(x), self.v(x)
if standin_phase == 1:
q += self.q_loras(x)
k += self.k_loras(x)
v += self.v_loras(x)
self.norm_q(q)
self.norm_k(k)
q,k,v = q.view(b, s, n, d), k.view(b, s, n, d), v.view(b, s, n, d)
del x
qklist = [q,k]
del q,k
q,k = apply_rotary_emb(qklist, freqs, head_first=False)
if standin_phase >= 1:
standin_cache = get_cache("standin")
if standin_phase == 1:
standin_cache[self.block_no] = (k,v)
elif standin_phase == 2:
k_ip, v_ip = standin_cache[self.block_no]
k, v = torch.concat([k, k_ip], dim=1), torch.concat([v, v_ip], dim=1)
del k_ip, v_ip
if ref_target_masks != None:
x_ref_attn_map = get_attn_map_with_target(q, k , grid_sizes, ref_target_masks=ref_target_masks, ref_images_count = ref_images_count)
else:
x_ref_attn_map = None
chipmunk = offload.shared_state.get("_chipmunk", False)
if chipmunk and self.__class__ == WanSelfAttention:
q = q.transpose(1,2)
k = k.transpose(1,2)
v = v.transpose(1,2)
attn_layers = offload.shared_state["_chipmunk_layers"]
x = attn_layers[self.block_no](q, k, v)
x = x.transpose(1,2)
elif block_mask == None:
qkv_list = [q,k,v]
del q,k,v
x = pay_attention(
qkv_list,
window_size=self.window_size)
else:
with sdp_kernel(enable_flash=True, enable_math=False, enable_mem_efficient=False):
x = (
torch.nn.functional.scaled_dot_product_attention(
q.transpose(1, 2), k.transpose(1, 2), v.transpose(1, 2), attn_mask=block_mask
)
.transpose(1, 2)
.contiguous()
)
del q,k,v
x = x.flatten(2)
x = self.o(x)
return x, x_ref_attn_map
class WanT2VCrossAttention(WanSelfAttention):
def forward(self, xlist, context, grid_sizes, *args, **kwargs):
r"""
Args:
x(Tensor): Shape [B, L1, C]
context(Tensor): Shape [B, L2, C]
"""
x, _ = self.text_cross_attention( xlist, context)
x = self.o(x)
return x
class WanI2VCrossAttention(WanSelfAttention):
def __init__(self,
dim,
num_heads,
window_size=(-1, -1),
qk_norm=True,
eps=1e-6,
block_no=0):
super().__init__(dim, num_heads, window_size, qk_norm, eps, block_no)
self.k_img = nn.Linear(dim, dim)
self.v_img = nn.Linear(dim, dim)
# self.alpha = nn.Parameter(torch.zeros((1, )))
self.norm_k_img = WanRMSNorm(dim, eps=eps) if qk_norm else nn.Identity()
def forward(self, xlist, context, grid_sizes, audio_proj, audio_scale, audio_context_lens ):
r"""
Args:
x(Tensor): Shape [B, L1, C]
context(Tensor): Shape [B, L2, C]
"""
context_img = context[:, :257]
context = context[:, 257:]
x, q = self.text_cross_attention( xlist, context, return_q = True)
if len(q) != len(context_img):
context_img = context_img[:len(q)]
b, s, n, d = *x.shape[:2], self.num_heads, self.head_dim
if audio_scale != None:
audio_x = self.processor(q, audio_proj, grid_sizes[0], audio_context_lens)
k_img = self.k_img(context_img)
self.norm_k_img(k_img)
k_img = k_img.view(b, -1, n, d)
v_img = self.v_img(context_img).view(b, -1, n, d)
qkv_list = [q, k_img, v_img]
del q, k_img, v_img
img_x = pay_attention(qkv_list)
img_x = img_x.flatten(2)
# output
x += img_x
del img_x
if audio_scale != None:
x.add_(audio_x, alpha= audio_scale)
x = self.o(x)
return x
WAN_CROSSATTENTION_CLASSES = {
't2v_cross_attn': WanT2VCrossAttention,
'i2v_cross_attn': WanI2VCrossAttention,
}
class WanAttentionBlock(nn.Module):
def __init__(self,
cross_attn_type,
dim,
ffn_dim,
num_heads,
window_size=(-1, -1),
qk_norm=True,
cross_attn_norm=False,
eps=1e-6,
block_id=None,
block_no = 0,
output_dim=0,
norm_input_visual=True,
class_range=24,
class_interval=4,
):
super().__init__()
self.dim = dim
self.ffn_dim = ffn_dim
self.num_heads = num_heads
self.window_size = window_size
self.qk_norm = qk_norm
self.cross_attn_norm = cross_attn_norm
self.eps = eps
self.block_no = block_no
# layers
self.norm1 = WanLayerNorm(dim, eps)
self.self_attn = WanSelfAttention(dim, num_heads, window_size, qk_norm,
eps, block_no= block_no)
self.norm3 = WanLayerNorm(
dim, eps,
elementwise_affine=True) if cross_attn_norm else nn.Identity()
self.cross_attn = WAN_CROSSATTENTION_CLASSES[cross_attn_type](dim,
num_heads,
(-1, -1),
qk_norm,
eps,
block_no)
self.norm2 = WanLayerNorm(dim, eps)
self.ffn = nn.Sequential(
nn.Linear(dim, ffn_dim), nn.GELU(approximate='tanh'),
nn.Linear(ffn_dim, dim))
# modulation
self.modulation = nn.Parameter(torch.randn(1, 6, dim) / dim**0.5)
self.block_id = block_id
if output_dim > 0:
from ..multitalk.attention import SingleStreamMutiAttention
# init audio module
self.audio_cross_attn = SingleStreamMutiAttention(
dim=dim,
encoder_hidden_states_dim=output_dim,
num_heads=num_heads,
qk_norm=False,
qkv_bias=True,
eps=eps,
norm_layer=WanRMSNorm,
class_range=class_range,
class_interval=class_interval
)
self.norm_x = WanLayerNorm(dim, eps, elementwise_affine=True) if norm_input_visual else nn.Identity()
def forward(
self,
x,
e,
grid_sizes,
freqs,
context,
hints= None,
context_scale=[1.0],
cam_emb= None,
block_mask = None,
audio_proj= None,
audio_context_lens= None,
audio_scale=None,
multitalk_audio=None,
multitalk_masks=None,
ref_images_count=0,
standin_phase=-1,
):
r"""
Args:
x(Tensor): Shape [B, L, C]
e(Tensor): Shape [B, 6, C]
grid_sizes(Tensor): Shape [B, 3], the second dimension contains (F, H, W)
freqs(Tensor): Rope freqs, shape [1024, C / num_heads / 2]
"""
hints_processed = None
attention_dtype = self.self_attn.q.weight.dtype
dtype = x.dtype
if self.block_id is not None and hints is not None:
kwargs = {
"grid_sizes" : grid_sizes,
"freqs" :freqs,
"context" : context,
"e" : e,
}
hints_processed= []
for scale, hint in zip(context_scale, hints):
if scale == 0:
hints_processed.append(None)
else:
hints_processed.append(self.vace(hint, x, **kwargs) if self.block_id == 0 else self.vace(hint, None, **kwargs))
latent_frames = e.shape[0]
e = (self.modulation + e).chunk(6, dim=1)
# self-attention
x_mod = self.norm1(x)
x_mod = reshape_latent(x_mod , latent_frames)
x_mod *= 1 + e[1]
x_mod += e[0]
x_mod = restore_latent_shape(x_mod)
if cam_emb != None:
cam_emb = self.cam_encoder(cam_emb)
cam_emb = cam_emb.repeat(1, 2, 1)
cam_emb = cam_emb.unsqueeze(2).unsqueeze(3).repeat(1, 1, grid_sizes[1], grid_sizes[2], 1)
cam_emb = rearrange(cam_emb, 'b f h w d -> b (f h w) d')
x_mod += cam_emb
xlist = [x_mod.to(attention_dtype)]
del x_mod
y, x_ref_attn_map = self.self_attn( xlist, grid_sizes, freqs, block_mask = block_mask, ref_target_masks = multitalk_masks, ref_images_count = ref_images_count, standin_phase= standin_phase, )
y = y.to(dtype)
if cam_emb != None: y = self.projector(y)
x, y = reshape_latent(x , latent_frames), reshape_latent(y , latent_frames)
x.addcmul_(y, e[2])
x, y = restore_latent_shape(x), restore_latent_shape(y)
del y
if context is not None:
y = self.norm3(x)
y = y.to(attention_dtype)
ylist= [y]
del y
x += self.cross_attn(ylist, context, grid_sizes, audio_proj, audio_scale, audio_context_lens).to(dtype)
if multitalk_audio != None:
# cross attn of multitalk audio
y = self.norm_x(x)
y = y.to(attention_dtype)
if ref_images_count == 0:
ylist= [y]
del y
x += self.audio_cross_attn(ylist, encoder_hidden_states=multitalk_audio, shape=grid_sizes, x_ref_attn_map=x_ref_attn_map)
else:
y_shape = y.shape
y = y.reshape(y_shape[0], grid_sizes[0], -1)
y = y[:, ref_images_count:]
y = y.reshape(y_shape[0], -1, y_shape[-1])
grid_sizes_alt = [grid_sizes[0]-ref_images_count, *grid_sizes[1:]]
ylist= [y]
y = None
y = self.audio_cross_attn(ylist, encoder_hidden_states=multitalk_audio, shape=grid_sizes_alt, x_ref_attn_map=x_ref_attn_map)
y = y.reshape(y_shape[0], grid_sizes[0]-ref_images_count, -1)
x = x.reshape(y_shape[0], grid_sizes[0], -1)
x[:, ref_images_count:] += y
x = x.reshape(y_shape[0], -1, y_shape[-1])
del y
y = self.norm2(x)
y = reshape_latent(y , latent_frames)
y *= 1 + e[4]
y += e[3]
y = restore_latent_shape(y)
y = y.to(attention_dtype)
ffn = self.ffn[0]
gelu = self.ffn[1]
ffn2= self.ffn[2]
y_shape = y.shape
y = y.view(-1, y_shape[-1])
chunk_size = int(y.shape[0]/2.7)
chunks =torch.split(y, chunk_size)
for y_chunk in chunks:
mlp_chunk = ffn(y_chunk)
mlp_chunk = gelu(mlp_chunk)
y_chunk[...] = ffn2(mlp_chunk)
del mlp_chunk
y = y.view(y_shape)
y = y.to(dtype)
x, y = reshape_latent(x , latent_frames), reshape_latent(y , latent_frames)
x.addcmul_(y, e[5])
x, y = restore_latent_shape(x), restore_latent_shape(y)
if hints_processed is not None:
for hint, scale in zip(hints_processed, context_scale):
if scale != 0:
if scale == 1:
x.add_(hint)
else:
x.add_(hint, alpha= scale)
return x
class AudioProjModel(ModelMixin, ConfigMixin):
def __init__(
self,
seq_len=5,
seq_len_vf=12,
blocks=12,
channels=768,
intermediate_dim=512,
output_dim=768,
context_tokens=32,
norm_output_audio=False,
):
super().__init__()
self.seq_len = seq_len
self.blocks = blocks
self.channels = channels
self.input_dim = seq_len * blocks * channels
self.input_dim_vf = seq_len_vf * blocks * channels
self.intermediate_dim = intermediate_dim
self.context_tokens = context_tokens
self.output_dim = output_dim
# define multiple linear layers
self.proj1 = nn.Linear(self.input_dim, intermediate_dim)
self.proj1_vf = nn.Linear(self.input_dim_vf, intermediate_dim)
self.proj2 = nn.Linear(intermediate_dim, intermediate_dim)
self.proj3 = nn.Linear(intermediate_dim, context_tokens * output_dim)
self.norm = nn.LayerNorm(output_dim) if norm_output_audio else nn.Identity()
def forward(self, audio_embeds, audio_embeds_vf):
video_length = audio_embeds.shape[1] + audio_embeds_vf.shape[1]
B, _, _, S, C = audio_embeds.shape
# process audio of first frame
audio_embeds = rearrange(audio_embeds, "bz f w b c -> (bz f) w b c")
batch_size, window_size, blocks, channels = audio_embeds.shape
audio_embeds = audio_embeds.view(batch_size, window_size * blocks * channels)
# process audio of latter frame
audio_embeds_vf = rearrange(audio_embeds_vf, "bz f w b c -> (bz f) w b c")
batch_size_vf, window_size_vf, blocks_vf, channels_vf = audio_embeds_vf.shape
audio_embeds_vf = audio_embeds_vf.view(batch_size_vf, window_size_vf * blocks_vf * channels_vf)
# first projection
audio_embeds = torch.relu(self.proj1(audio_embeds))
audio_embeds_vf = torch.relu(self.proj1_vf(audio_embeds_vf))
audio_embeds = rearrange(audio_embeds, "(bz f) c -> bz f c", bz=B)
audio_embeds_vf = rearrange(audio_embeds_vf, "(bz f) c -> bz f c", bz=B)
audio_embeds_c = torch.concat([audio_embeds, audio_embeds_vf], dim=1)
audio_embeds_vf = audio_embeds = None
batch_size_c, N_t, C_a = audio_embeds_c.shape
audio_embeds_c = audio_embeds_c.view(batch_size_c*N_t, C_a)
# second projection
audio_embeds_c = torch.relu(self.proj2(audio_embeds_c))
context_tokens = self.proj3(audio_embeds_c).reshape(batch_size_c*N_t, self.context_tokens, self.output_dim)
audio_embeds_c = None
# normalization and reshape
context_tokens = self.norm(context_tokens)
context_tokens = rearrange(context_tokens, "(bz f) m c -> bz f m c", f=video_length)
return context_tokens
class VaceWanAttentionBlock(WanAttentionBlock):
def __init__(
self,
cross_attn_type,
dim,
ffn_dim,
num_heads,
window_size=(-1, -1),
qk_norm=True,
cross_attn_norm=False,
eps=1e-6,
block_id=0
):
super().__init__(cross_attn_type, dim, ffn_dim, num_heads, window_size, qk_norm, cross_attn_norm, eps)
self.block_id = block_id
if block_id == 0:
self.before_proj = nn.Linear(self.dim, self.dim)
nn.init.zeros_(self.before_proj.weight)
nn.init.zeros_(self.before_proj.bias)
self.after_proj = nn.Linear(self.dim, self.dim)
nn.init.zeros_(self.after_proj.weight)
nn.init.zeros_(self.after_proj.bias)
def forward(self, hints, x, **kwargs):
# behold dbm magic !
c = hints[0]
hints[0] = None
if self.block_id == 0:
c = self.before_proj(c)
bz = x.shape[0]
if bz > c.shape[0]: c = c.repeat(bz, 1, 1 )
c += x
c = super().forward(c, **kwargs)
c_skip = self.after_proj(c)
hints[0] = c
return c_skip
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 forward(self, x, e):
r"""
Args:
x(Tensor): Shape [B, L1, C]
e(Tensor): Shape [B, C]
"""
# assert e.dtype == torch.float32
dtype = x.dtype
latent_frames = e.shape[0]
e = (self.modulation + e.unsqueeze(1)).chunk(2, dim=1)
x = self.norm(x).to(dtype)
x = reshape_latent(x , latent_frames)
x *= (1 + e[1])
x += e[0]
x = restore_latent_shape(x)
x= x.to(self.head.weight.dtype)
x = self.head(x)
return x
class MLPProj(torch.nn.Module):
def __init__(self, in_dim, out_dim, flf_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 flf_pos_emb: # NOTE: we only use this for `flf2v`
FIRST_LAST_FRAME_CONTEXT_TOKEN_NUMBER = 257 * 2
self.emb_pos = nn.Parameter(
torch.zeros(1, FIRST_LAST_FRAME_CONTEXT_TOKEN_NUMBER, 1280))
def forward(self, image_embeds):
if hasattr(self, 'emb_pos'):
bs, n, d = image_embeds.shape
image_embeds = image_embeds.view(-1, 2 * n, d)
image_embeds = image_embeds + self.emb_pos
clip_extra_context_tokens = self.proj(image_embeds)
return clip_extra_context_tokens
class WanModel(ModelMixin, ConfigMixin):
def setup_chipmunk(self):
# from chipmunk.util import LayerCounter
# from chipmunk.modules import SparseDiffMlp, SparseDiffAttn
seq_shape = (21, 45, 80)
chipmunk_layers =[]
for i in range(self.num_layers):
layer_num, layer_counter = LayerCounter.build_for_layer(is_attn_sparse=True, is_mlp_sparse=False)
chipmunk_layers.append( SparseDiffAttn(layer_num, layer_counter))
offload.shared_state["_chipmunk_layers"] = chipmunk_layers
chipmunk_layers[0].initialize_static_mask(
seq_shape=seq_shape,
txt_len=0,
local_heads_num=self.num_heads,
device='cuda'
)
chipmunk_layers[0].layer_counter.reset()
def release_chipmunk(self):
offload.shared_state["_chipmunk_layers"] = None
def preprocess_loras(self, model_type, sd):
first = next(iter(sd), None)
if first == None:
return sd
new_sd = {}
# for k,v in sd.items():
# if k.endswith("modulation.diff"):
# pass
# else:
# new_sd[ k] = v
# sd = new_sd
# if first.startswith("blocks."):
# new_sd = {}
# for k,v in sd.items():
# new_sd["diffusion_model." + k] = v
# sd = new_sd
if first.startswith("lora_unet_"):
new_sd = {}
print("Converting Lora Safetensors format to Lora Diffusers format")
alphas = {}
repl_list = ["cross_attn", "self_attn", "ffn"]
src_list = ["_" + k + "_" for k in repl_list]
tgt_list = ["." + k + "." for k in repl_list]
for k,v in sd.items():
k = k.replace("lora_unet_blocks_","diffusion_model.blocks.")
k = k.replace("lora_unet__blocks_","diffusion_model.blocks.")
for s,t in zip(src_list, tgt_list):
k = k.replace(s,t)
k = k.replace("lora_up","lora_B")
k = k.replace("lora_down","lora_A")
new_sd[k] = v
sd = new_sd
from wgp import test_class_i2v
if not test_class_i2v(model_type) or model_type in ["i2v_2_2"]:
new_sd = {}
# convert loras for i2v to t2v
for k,v in sd.items():
if any(layer in k for layer in ["cross_attn.k_img", "cross_attn.v_img", "img_emb."]):
continue
new_sd[k] = v
sd = new_sd
return sd
r"""
Wan diffusion backbone supporting both text-to-video and image-to-video.
"""
ignore_for_config = [
'patch_size', 'cross_attn_norm', 'qk_norm', 'text_dim', 'window_size'
]
_no_split_modules = ['WanAttentionBlock']
@register_to_config
def __init__(self,
vace_layers=None,
vace_in_dim=None,
model_type='t2v',
patch_size=(1, 2, 2),
text_len=512,
in_dim=16,
dim=2048,
ffn_dim=8192,
freq_dim=256,
text_dim=4096,
out_dim=16,
num_heads=16,
num_layers=32,
window_size=(-1, -1),
qk_norm=True,
cross_attn_norm=True,
eps=1e-6,
flf = False,
recammaster = False,
inject_sample_info = False,
fantasytalking_dim = 0,
multitalk_output_dim = 0,
audio_window=5,
intermediate_dim=512,
context_tokens=32,
vae_scale=4, # vae timedownsample scale
norm_input_visual=True,
norm_output_audio=True,
standin= False,
):
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.ffn_dim = ffn_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.window_size = window_size
self.qk_norm = qk_norm
self.cross_attn_norm = cross_attn_norm
self.eps = eps
self.num_frame_per_block = 1
self.flag_causal_attention = False
self.block_mask = None
self.inject_sample_info = inject_sample_info
self.norm_output_audio = norm_output_audio
self.audio_window = audio_window
self.intermediate_dim = intermediate_dim
self.vae_scale = vae_scale
multitalk = multitalk_output_dim > 0
self.multitalk = multitalk
# embeddings
self.patch_embedding = nn.Conv3d(
in_dim, dim, kernel_size=patch_size, stride=patch_size)
self.text_embedding = nn.Sequential(
nn.Linear(text_dim, dim), nn.GELU(approximate='tanh'),
nn.Linear(dim, dim))
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))
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))
# blocks
if vace_layers == None:
cross_attn_type = 't2v_cross_attn' if model_type in ['t2v','i2v2_2', 'ti2v2_2'] else 'i2v_cross_attn'
self.blocks = nn.ModuleList([
WanAttentionBlock(cross_attn_type, dim, ffn_dim, num_heads,
window_size, qk_norm, cross_attn_norm, eps, block_no =i, output_dim=multitalk_output_dim, norm_input_visual=norm_input_visual)
for i in range(num_layers)
])
# head
self.head = Head(dim, out_dim, patch_size, eps)
# buffers (don't use register_buffer otherwise dtype will be changed in to())
if model_type == 'i2v':
self.img_emb = MLPProj(1280, dim, flf_pos_emb = flf)
if multitalk :
# init audio adapter
self.audio_proj = AudioProjModel(
seq_len=audio_window,
seq_len_vf=audio_window+vae_scale-1,
intermediate_dim=intermediate_dim,
output_dim=multitalk_output_dim,
context_tokens=context_tokens,
norm_output_audio=norm_output_audio,
)
# initialize weights
self.init_weights()
if vace_layers != 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
assert 0 in self.vace_layers
self.vace_layers_mapping = {i: n for n, i in enumerate(self.vace_layers)}
# blocks
self.blocks = nn.ModuleList([
WanAttentionBlock('t2v_cross_attn', self.dim, self.ffn_dim, self.num_heads, self.window_size, self.qk_norm,
self.cross_attn_norm, self.eps, block_no =i,
block_id=self.vace_layers_mapping[i] if i in self.vace_layers else None,
output_dim=multitalk_output_dim,
norm_input_visual=norm_input_visual,
)
for i in range(self.num_layers)
])
# vace blocks
self.vace_blocks = nn.ModuleList([
VaceWanAttentionBlock('t2v_cross_attn', self.dim, self.ffn_dim, self.num_heads, self.window_size, self.qk_norm,
self.cross_attn_norm, self.eps, block_id=i)
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
)
if recammaster :
dim=self.blocks[0].self_attn.q.weight.shape[0]
for block in self.blocks:
block.cam_encoder = nn.Linear(12, dim)
block.projector = nn.Linear(dim, dim)
block.cam_encoder.weight.data.zero_()
block.cam_encoder.bias.data.zero_()
block.projector.weight = nn.Parameter(torch.eye(dim))
block.projector.bias = nn.Parameter(torch.zeros(dim))
if fantasytalking_dim > 0:
from ..fantasytalking.model import WanCrossAttentionProcessor
for block in self.blocks:
block.cross_attn.processor = WanCrossAttentionProcessor(fantasytalking_dim, dim)
if standin:
for block in self.blocks:
block.self_attn.q_loras = LoRALinearLayer(dim, dim, rank=128)
block.self_attn.k_loras = LoRALinearLayer(dim, dim, rank=128)
block.self_attn.v_loras = LoRALinearLayer(dim, dim, rank=128)
def lock_layers_dtypes(self, hybrid_dtype = None, dtype = torch.float32):
layer_list = [self.head, self.head.head, self.patch_embedding]
target_dype= dtype
layer_list2 = [ self.time_embedding, self.time_embedding[0], self.time_embedding[2],
self.time_projection, self.time_projection[1]] #, self.text_embedding, self.text_embedding[0], self.text_embedding[2] ]
for block in self.blocks:
layer_list2 += [block.norm3]
if hasattr(self, "audio_proj"):
for block in self.blocks:
layer_list2 += [block.norm_x]
if hasattr(self, "fps_embedding"):
layer_list2 += [self.fps_embedding, self.fps_projection, self.fps_projection[0], self.fps_projection[2]]
if hasattr(self, "vace_patch_embedding"):
layer_list2 += [self.vace_patch_embedding]
layer_list2 += [self.vace_blocks[0].before_proj]
for block in self.vace_blocks:
layer_list2 += [block.after_proj, block.norm3]
target_dype2 = hybrid_dtype if hybrid_dtype != None else dtype
# cam master
if hasattr(self.blocks[0], "projector"):
for block in self.blocks:
layer_list2 += [block.projector]
for current_layer_list, current_dtype in zip([layer_list, layer_list2], [target_dype, target_dype2]):
for layer in current_layer_list:
layer._lock_dtype = dtype
if hasattr(layer, "weight") and layer.weight.dtype != current_dtype :
layer.weight.data = layer.weight.data.to(current_dtype)
if hasattr(layer, "bias"):
layer.bias.data = layer.bias.data.to(current_dtype)
self._lock_dtype = dtype
def compute_magcache_threshold(self, start_step, timesteps = None, speed_factor =0):
skips_step_cache = self.cache
def nearest_interp(src_array, target_length):
src_length = len(src_array)
if target_length == 1: return np.array([src_array[-1]])
scale = (src_length - 1) / (target_length - 1)
mapped_indices = np.round(np.arange(target_length) * scale).astype(int)
return src_array[mapped_indices]
num_inference_steps = len(timesteps)
def_mag_ratios = np.array([1.0]*2+ skips_step_cache.def_mag_ratios)
if len(def_mag_ratios) != num_inference_steps*2:
mag_ratio_con = nearest_interp(def_mag_ratios[0::2], num_inference_steps)
mag_ratio_ucon = nearest_interp(def_mag_ratios[1::2], num_inference_steps)
interpolated_mag_ratios = np.concatenate([mag_ratio_con.reshape(-1, 1), mag_ratio_ucon.reshape(-1, 1)], axis=1).reshape(-1)
skips_step_cache.mag_ratios = interpolated_mag_ratios
else:
skips_step_cache.mag_ratios = def_mag_ratios
best_deltas = None
best_threshold = 0.01
best_diff = 1000
best_signed_diff = 1000
target_nb_steps= int(len(timesteps) / speed_factor)
threshold = 0.01
x_id_max = 1
while threshold <= 0.6:
nb_steps = 0
diff = 1000
accumulated_err, accumulated_steps, accumulated_ratio = [0] * x_id_max , [0] * x_id_max, [1.0] * x_id_max
for i, t in enumerate(timesteps):
if i<=start_step:
skip = False
x_should_calc = [True] * x_id_max
else:
x_should_calc = []
for cur_x_id in range(x_id_max):
cur_mag_ratio = skips_step_cache.mag_ratios[i * 2 + cur_x_id] # conditional and unconditional in one list
accumulated_ratio[cur_x_id] *= cur_mag_ratio # magnitude ratio between current step and the cached step
accumulated_steps[cur_x_id] += 1 # skip steps plus 1
cur_skip_err = np.abs(1-accumulated_ratio[cur_x_id]) # skip error of current steps
accumulated_err[cur_x_id] += cur_skip_err # accumulated error of multiple steps
if accumulated_err[cur_x_id]<threshold and accumulated_steps[cur_x_id]<=skips_step_cache.magcache_K:
skip = True
else:
skip = False
accumulated_err[cur_x_id], accumulated_steps[cur_x_id], accumulated_ratio[cur_x_id] = 0, 0, 1.0
x_should_calc.append(not skip)
if not skip:
nb_steps += 1
signed_diff = target_nb_steps - nb_steps
diff = abs(signed_diff)
if diff < best_diff:
best_threshold = threshold
best_diff = diff
best_signed_diff = signed_diff
elif diff > best_diff:
break
threshold += 0.01
skips_step_cache.magcache_thresh = best_threshold
print(f"Mag Cache, best threshold found:{best_threshold:0.2f} with gain x{len(timesteps)/(target_nb_steps - best_signed_diff):0.2f} for a target of x{speed_factor}")
return best_threshold
def compute_teacache_threshold(self, start_step, timesteps = None, speed_factor =0):
skips_step_cache = self.cache
modulation_dtype = self.time_projection[1].weight.dtype
rescale_func = np.poly1d(skips_step_cache.coefficients)
e_list = []
for t in timesteps:
t = torch.stack([t])
time_emb = self.time_embedding( sinusoidal_embedding_1d(self.freq_dim, t.flatten()).to(modulation_dtype) ) # b, dim
e_list.append(time_emb)
best_deltas = None
best_threshold = 0.01
best_diff = 1000
best_signed_diff = 1000
target_nb_steps= int(len(timesteps) / speed_factor)
threshold = 0.01
while threshold <= 0.6:
accumulated_rel_l1_distance =0
nb_steps = 0
diff = 1000
deltas = []
for i, t in enumerate(timesteps):
skip = False
if not (i<=start_step or i== len(timesteps)-1):
delta = abs(rescale_func(((e_list[i]-e_list[i-1]).abs().mean() / e_list[i-1].abs().mean()).cpu().item()))
# deltas.append(delta)
accumulated_rel_l1_distance += delta
if accumulated_rel_l1_distance < threshold:
skip = True
# deltas.append("SKIP")
else:
accumulated_rel_l1_distance = 0
if not skip:
nb_steps += 1
signed_diff = target_nb_steps - nb_steps
diff = abs(signed_diff)
if diff < best_diff:
best_threshold = threshold
best_deltas = deltas
best_diff = diff
best_signed_diff = signed_diff
elif diff > best_diff:
break
threshold += 0.01
skips_step_cache.rel_l1_thresh = best_threshold
print(f"Tea Cache, best threshold found:{best_threshold:0.2f} with gain x{len(timesteps)/(target_nb_steps - best_signed_diff):0.2f} for a target of x{speed_factor}")
# print(f"deltas:{best_deltas}")
return best_threshold
def forward(
self,
x,
t,
context,
vace_context = None,
vace_context_scale=[1.0],
clip_fea=None,
y=None,
freqs = None,
pipeline = None,
current_step = 0,
x_id= 0,
max_steps = 0,
slg_layers=None,
callback = None,
cam_emb: torch.Tensor = None,
fps = None,
causal_block_size = 1,
causal_attention = False,
audio_proj=None,
audio_context_lens=None,
audio_scale=None,
multitalk_audio = None,
multitalk_masks = None,
ref_images_count = 0,
standin_freqs = None,
standin_ref = None,
):
# patch_dtype = self.patch_embedding.weight.dtype
modulation_dtype = self.time_projection[1].weight.dtype
if self.model_type == 'i2v':
assert clip_fea is not None and y is not None
# params
device = self.patch_embedding.weight.device
if torch.is_tensor(freqs) and freqs.device != device:
freqs = freqs.to(device)
chipmunk = offload.shared_state.get("_chipmunk", False)
if chipmunk:
# from chipmunk.ops.voxel import voxel_chunk_no_padding, reverse_voxel_chunk_no_padding
voxel_shape = (4, 6, 8)
x_list = x
joint_pass = len(x_list) > 1
is_source_x = [ x.data_ptr() == x_list[0].data_ptr() and i > 0 for i, x in enumerate(x_list) ]
last_x_idx = 0
for i, (is_source, x) in enumerate(zip(is_source_x, x_list)):
if is_source:
x_list[i] = x_list[0].clone()
last_x_idx = i
else:
# image source
bz = len(x)
if y is not None:
y = y.unsqueeze(0)
if bz > 1: y = y.expand(bz, -1, -1, -1, -1)
x = torch.cat([x, y], dim=1)
# embeddings
# x = self.patch_embedding(x.unsqueeze(0)).to(modulation_dtype)
x = self.patch_embedding(x).to(modulation_dtype)
grid_sizes = x.shape[2:]
if chipmunk:
x = x.unsqueeze(-1)
x_og_shape = x.shape
x = voxel_chunk_no_padding(x, voxel_shape).squeeze(-1).transpose(1, 2)
else:
x = x.flatten(2).transpose(1, 2)
x_list[i] = x
x, y = None, None
block_mask = None
if causal_attention and causal_block_size > 0 and False: # NEVER WORKED
frame_num = grid_sizes[0]
height = grid_sizes[1]
width = grid_sizes[2]
block_num = frame_num // causal_block_size
range_tensor = torch.arange(block_num).view(-1, 1)
range_tensor = range_tensor.repeat(1, causal_block_size).flatten()
causal_mask = range_tensor.unsqueeze(0) <= range_tensor.unsqueeze(1) # f, f
causal_mask = causal_mask.view(frame_num, 1, 1, frame_num, 1, 1).to(x[0].device)
causal_mask = causal_mask.repeat(1, height, width, 1, height, width)
causal_mask = causal_mask.reshape(frame_num * height * width, frame_num * height * width)
block_mask = causal_mask.unsqueeze(0).unsqueeze(0)
del causal_mask
offload.shared_state["embed_sizes"] = grid_sizes
offload.shared_state["step_no"] = current_step
offload.shared_state["max_steps"] = max_steps
if current_step == 0 and x_id == 0: clear_caches()
# arguments
kwargs = dict(
grid_sizes=grid_sizes,
freqs=freqs,
cam_emb = cam_emb,
block_mask = block_mask,
audio_proj=audio_proj,
audio_context_lens=audio_context_lens,
ref_images_count=ref_images_count,
)
_flag_df = t.dim() == 2
e = self.time_embedding(
sinusoidal_embedding_1d(self.freq_dim, t.flatten()).to(modulation_dtype) # self.patch_embedding.weight.dtype)
) # b, dim
e0 = self.time_projection(e).unflatten(1, (6, self.dim)).to(e.dtype)
standin_x = None
if standin_ref is not None:
standin_cache_enabled = False
kwargs["standin_phase"] = 2
if current_step == 0 or not standin_cache_enabled :
standin_x = self.patch_embedding(standin_ref).to(modulation_dtype).flatten(2).transpose(1, 2)
standin_e = self.time_embedding( sinusoidal_embedding_1d(self.freq_dim, torch.zeros_like(t)).to(modulation_dtype) )
standin_e0 = self.time_projection(standin_e).unflatten(1, (6, self.dim)).to(e.dtype)
standin_e = standin_ref = None
if self.inject_sample_info and fps!=None:
fps = torch.tensor(fps, dtype=torch.long, device=device)
fps_emb = self.fps_embedding(fps).to(e.dtype)
if _flag_df:
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))
# context
context = [self.text_embedding( u ) for u in context ]
if clip_fea is not None:
context_clip = self.img_emb(clip_fea) # bs x 257 x dim
context_list = []
for one_context in context:
if len(one_context) != len(context_clip):
context_list.append( torch.cat( [context_clip.repeat(len(one_context), 1, 1), one_context ], dim=1 ))
else:
context_list.append( torch.cat( [context_clip, one_context ], dim=1 ))
else:
context_list = context
if multitalk_audio != None:
multitalk_audio_list = []
for audio in multitalk_audio:
if audio is not None:
audio = self.audio_proj(*audio)
audio = torch.concat(audio.split(1), dim=2).to(context[0])
multitalk_audio_list.append(audio)
audio = None
else:
multitalk_audio_list = [None] * len(x_list)
if multitalk_masks != None:
multitalk_masks_list = multitalk_masks
else:
multitalk_masks_list = [None] * len(x_list)
if audio_scale != None:
audio_scale_list = audio_scale
else:
audio_scale_list = [None] * len(x_list)
if vace_context == None:
hints_list = [None ] *len(x_list)
else:
# Vace embeddings
c = [self.vace_patch_embedding(u.to(self.vace_patch_embedding.weight.dtype).unsqueeze(0)) for u in vace_context]
c = [u.flatten(2).transpose(1, 2) for u in c]
kwargs['context_scale'] = vace_context_scale
hints_list = [ [ [sub_c] for sub_c in c] for _ in range(len(x_list)) ]
del c
should_calc = True
x_should_calc = None
skips_steps_cache = self.cache
if skips_steps_cache != None:
if skips_steps_cache.cache_type == "mag":
if current_step <= skips_steps_cache.start_step:
should_calc = True
elif skips_steps_cache.one_for_all and x_id != 0: # not joint pass, not main pas, one for all
assert len(x_list) == 1
should_calc = skips_steps_cache.should_calc
else:
x_should_calc = []
for i in range(1 if skips_steps_cache.one_for_all else len(x_list)):
cur_x_id = i if joint_pass else x_id
cur_mag_ratio = skips_steps_cache.mag_ratios[current_step * 2 + cur_x_id] # conditional and unconditional in one list
skips_steps_cache.accumulated_ratio[cur_x_id] *= cur_mag_ratio # magnitude ratio between current step and the cached step
skips_steps_cache.accumulated_steps[cur_x_id] += 1 # skip steps plus 1
cur_skip_err = np.abs(1-skips_steps_cache.accumulated_ratio[cur_x_id]) # skip error of current steps
skips_steps_cache.accumulated_err[cur_x_id] += cur_skip_err # accumulated error of multiple steps
if skips_steps_cache.accumulated_err[cur_x_id]<skips_steps_cache.magcache_thresh and skips_steps_cache.accumulated_steps[cur_x_id]<=skips_steps_cache.magcache_K:
skip_forward = True
if i == 0 and x_id == 0: skips_steps_cache.skipped_steps += 1
# print(f"skip: step={current_step} for x_id={cur_x_id}, accum error {skips_step_cache.accumulated_err[cur_x_id]}")
else:
skip_forward = False
skips_steps_cache.accumulated_err[cur_x_id], skips_steps_cache.accumulated_steps[cur_x_id], skips_steps_cache.accumulated_ratio[cur_x_id] = 0, 0, 1.0
x_should_calc.append(not skip_forward)
if skips_steps_cache.one_for_all:
should_calc = skips_steps_cache.should_calc = x_should_calc[0]
x_should_calc = None
else:
if x_id != 0:
should_calc = skips_steps_cache.should_calc
else:
if current_step <= skips_steps_cache.start_step or current_step == skips_steps_cache.num_steps-1:
should_calc = True
skips_steps_cache.accumulated_rel_l1_distance = 0
else:
rescale_func = np.poly1d(skips_steps_cache.coefficients)
delta = abs(rescale_func(((e-skips_steps_cache.previous_modulated_input).abs().mean() / skips_steps_cache.previous_modulated_input.abs().mean()).cpu().item()))
skips_steps_cache.accumulated_rel_l1_distance += delta
if skips_steps_cache.accumulated_rel_l1_distance < skips_steps_cache.rel_l1_thresh:
should_calc = False
skips_steps_cache.skipped_steps += 1
# print(f"Teacache Skipped Step no {current_step} ({skips_step_cache.cache_skipped_steps}/{current_step}), delta={delta}" )
else:
should_calc = True
skips_steps_cache.accumulated_rel_l1_distance = 0
skips_steps_cache.previous_modulated_input = e
skips_steps_cache.should_calc = should_calc
if x_should_calc == None: x_should_calc = [should_calc] * len(x_list)
if joint_pass:
for i, x in enumerate(x_list):
if not x_should_calc[i]: x += skips_steps_cache.previous_residual[i]
elif not x_should_calc[0]:
x = x_list[0]
x += skips_steps_cache.previous_residual[x_id]
x = None
if skips_steps_cache != None:
if skips_steps_cache.previous_residual == None: skips_steps_cache.previous_residual = [ None ] * len(x_list)
if joint_pass:
for i, should_calc in enumerate(x_should_calc):
if should_calc: skips_steps_cache.previous_residual[i] = None
elif x_should_calc[0]:
skips_steps_cache.previous_residual[x_id] = None
ori_hidden_states = [ None ] * len(x_list)
if all(x_should_calc):
ori_hidden_states[0] = x_list[0].clone()
for i in range(1, len(x_list)):
ori_hidden_states[i] = ori_hidden_states[0] if is_source_x[i] else x_list[i].clone()
else:
for i in range(len(x_list)):
if x_should_calc[i]: ori_hidden_states[i] = x_list[i].clone()
if any(x_should_calc):
for block_idx, block in enumerate(self.blocks):
offload.shared_state["layer"] = block_idx
if callback != None:
callback(-1, None, False, True)
if pipeline._interrupt:
return [None] * len(x_list)
if standin_x is not None:
if not standin_cache_enabled: get_cache("standin").clear()
standin_x = block(standin_x, context = None, grid_sizes = None, e= standin_e0, freqs = standin_freqs, standin_phase = 1)
if slg_layers is not None and block_idx in slg_layers:
if x_id != 0 or not x_should_calc[0]:
continue
x_list[0] = block(x_list[0], context = context_list[0], audio_scale= audio_scale_list[0], e= e0, **kwargs)
else:
for i, (x, context, hints, audio_scale, multitalk_audio, multitalk_masks, should_calc) in enumerate(zip(x_list, context_list, hints_list, audio_scale_list, multitalk_audio_list, multitalk_masks_list, x_should_calc)):
if should_calc:
x_list[i] = block(x, context = context, hints= hints, audio_scale= audio_scale, multitalk_audio = multitalk_audio, multitalk_masks =multitalk_masks, e= e0, **kwargs)
del x
context = hints = audio_embedding = None
if skips_steps_cache != None:
if joint_pass:
if all(x_should_calc):
for i, (x, ori, is_source) in enumerate(zip(x_list, ori_hidden_states, is_source_x)) :
if i == 0 or is_source and i != last_x_idx :
skips_steps_cache.previous_residual[i] = torch.sub(x, ori)
else:
skips_steps_cache.previous_residual[i] = ori
torch.sub(x, ori, out=skips_steps_cache.previous_residual[i])
ori_hidden_states[i] = None
else:
for i, (x, ori, is_source, should_calc) in enumerate(zip(x_list, ori_hidden_states, is_source_x, x_should_calc)) :
if should_calc:
skips_steps_cache.previous_residual[i] = ori
torch.sub(x, ori, out=skips_steps_cache.previous_residual[i])
ori_hidden_states[i] = None
x , ori = None, None
elif x_should_calc[0]:
residual = ori_hidden_states[0] # just to have a readable code
torch.sub(x_list[0], ori_hidden_states[0], out=residual)
skips_steps_cache.previous_residual[x_id] = residual
residual, ori_hidden_states = None, None
for i, x in enumerate(x_list):
if chipmunk:
x = reverse_voxel_chunk_no_padding(x.transpose(1, 2).unsqueeze(-1), x_og_shape, voxel_shape).squeeze(-1)
x = x.flatten(2).transpose(1, 2)
# head
x = self.head(x, e)
# unpatchify
x_list[i] = self.unpatchify(x, grid_sizes)
del x
return [x.float() for x in x_list]
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 in x:
u = u[:math.prod(grid_sizes)].view(*grid_sizes, *self.patch_size, c)
u = torch.einsum('fhwpqrc->cfphqwr', u)
u = u.reshape(c, *[i * j for i, j in zip(grid_sizes, self.patch_size)])
out.append(u)
if len(x) == 1:
return out[0].unsqueeze(0)
else:
return torch.stack(out, 0)
def init_weights(self):
r"""
Initialize model parameters using Xavier initialization.
"""
# basic init
for m in self.modules():
if isinstance(m, nn.Linear):
nn.init.xavier_uniform_(m.weight)
if m.bias is not None:
nn.init.zeros_(m.bias)
# init embeddings
nn.init.xavier_uniform_(self.patch_embedding.weight.flatten(1))
for m in self.text_embedding.modules():
if isinstance(m, nn.Linear):
nn.init.normal_(m.weight, std=.02)
for m in self.time_embedding.modules():
if isinstance(m, nn.Linear):
nn.init.normal_(m.weight, std=.02)
# init output layer
nn.init.zeros_(self.head.head.weight)