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	# Copyright 2024-2025 The Alibaba Wan Team Authors. All rights reserved.
	import logging
	from mmgp import offload
	import torch
	import torch.cuda.amp as amp
	import torch.nn as nn
	import torch.nn.functional as F
	from einops import rearrange

	__all__ = [
	'WanVAE',
	]

	CACHE_T = 2


	class CausalConv3d(nn.Conv3d):
	"""
	Causal 3d convolusion.
	"""

	def __init__(self, args, *kwargs):
	super().__init__(args, *kwargs)
	self._padding = (self.padding[2], self.padding[2], self.padding[1],
	self.padding[1], 2 * self.padding[0], 0)
	self.padding = (0, 0, 0)

	def forward(self, x, cache_x=None):
	padding = list(self._padding)
	if cache_x is not None and self._padding[4] > 0:
	cache_x = cache_x.to(x.device)
	x = torch.cat([cache_x, x], dim=2)
	padding[4] -= cache_x.shape[2]
	cache_x = None
	x = F.pad(x, padding)
	try:
	out = super().forward(x)
	return out
	except RuntimeError as e:
	if "miopenStatus" in str(e):
	print("⚠️ MIOpen fallback: AMD gets upset when trying to work with large areas, and so CPU will be "
	"used for this decoding (which is very slow). Consider using tiled VAE Decoding.")
	x_cpu = x.float().cpu()
	weight_cpu = self.weight.float().cpu()
	bias_cpu = self.bias.float().cpu() if self.bias is not None else None
	print(f"[Fallback] x shape: {x_cpu.shape}, weight shape: {weight_cpu.shape}")
	out = F.conv3d(x_cpu, weight_cpu, bias_cpu,
	self.stride, (0, 0, 0), # avoid double padding here
	self.dilation, self.groups)
	out = out.to(x.device)
	if x.dtype in (torch.float16, torch.bfloat16):
	out = out.half()
	if x.dtype != out.dtype:
	out = out.to(x.dtype)
	return out
	raise


	class RMS_norm(nn.Module):

	def __init__(self, dim, channel_first=True, images=True, bias=False):
	super().__init__()
	broadcastable_dims = (1, 1, 1) if not images else (1, 1)
	shape = (dim, *broadcastable_dims) if channel_first else (dim,)

	self.channel_first = channel_first
	self.scale = dim**0.5
	self.gamma = nn.Parameter(torch.ones(shape))
	self.bias = nn.Parameter(torch.zeros(shape)) if bias else 0.

	def forward(self, x):
	dtype = x.dtype
	x = F.normalize(
	x, dim=(1 if self.channel_first else
	-1)) * self.scale * self.gamma + self.bias
	x = x.to(dtype)
	return x

	class Upsample(nn.Upsample):

	def forward(self, x):
	"""
	Fix bfloat16 support for nearest neighbor interpolation.
	"""
	return super().forward(x.float()).type_as(x)


	class Resample(nn.Module):

	def __init__(self, dim, mode):
	assert mode in ('none', 'upsample2d', 'upsample3d', 'downsample2d',
	'downsample3d')
	super().__init__()
	self.dim = dim
	self.mode = mode

	# layers
	if mode == 'upsample2d':
	self.resample = nn.Sequential(
	Upsample(scale_factor=(2., 2.), mode='nearest-exact'),
	nn.Conv2d(dim, dim // 2, 3, padding=1))
	elif mode == 'upsample3d':
	self.resample = nn.Sequential(
	Upsample(scale_factor=(2., 2.), mode='nearest-exact'),
	nn.Conv2d(dim, dim // 2, 3, padding=1))
	self.time_conv = CausalConv3d(
	dim, dim * 2, (3, 1, 1), padding=(1, 0, 0))

	elif mode == 'downsample2d':
	self.resample = nn.Sequential(
	nn.ZeroPad2d((0, 1, 0, 1)),
	nn.Conv2d(dim, dim, 3, stride=(2, 2)))
	elif mode == 'downsample3d':
	self.resample = nn.Sequential(
	nn.ZeroPad2d((0, 1, 0, 1)),
	nn.Conv2d(dim, dim, 3, stride=(2, 2)))
	self.time_conv = CausalConv3d(
	dim, dim, (3, 1, 1), stride=(2, 1, 1), padding=(0, 0, 0))

	else:
	self.resample = nn.Identity()

	def forward(self, x, feat_cache=None, feat_idx=[0]):
	b, c, t, h, w = x.size()
	if self.mode == 'upsample3d':
	if feat_cache is not None:
	idx = feat_idx[0]
	if feat_cache[idx] is None:
	feat_cache[idx] = 'Rep'
	feat_idx[0] += 1
	else:
	clone = True
	cache_x = x[:, :, -CACHE_T:, :, :]#.clone()
	if cache_x.shape[2] < 2 and feat_cache[
	idx] is not None and feat_cache[idx] != 'Rep':
	# cache last frame of last two chunk
	clone = False
	cache_x = torch.cat([
	feat_cache[idx][:, :, -1, :, :].unsqueeze(2).to(
	cache_x.device), cache_x
	],
	dim=2)
	if cache_x.shape[2] < 2 and feat_cache[
	idx] is not None and feat_cache[idx] == 'Rep':
	clone = False
	cache_x = torch.cat([
	torch.zeros_like(cache_x).to(cache_x.device),
	cache_x
	],
	dim=2)
	if clone:
	cache_x = cache_x.clone()
	if feat_cache[idx] == 'Rep':
	x = self.time_conv(x)
	else:
	x = self.time_conv(x, feat_cache[idx])
	feat_cache[idx] = cache_x
	feat_idx[0] += 1

	x = x.reshape(b, 2, c, t, h, w)
	x = torch.stack((x[:, 0, :, :, :, :], x[:, 1, :, :, :, :]),
	3)
	x = x.reshape(b, c, t * 2, h, w)
	t = x.shape[2]
	x = rearrange(x, 'b c t h w -> (b t) c h w')
	x = self.resample(x)
	x = rearrange(x, '(b t) c h w -> b c t h w', t=t)

	if self.mode == 'downsample3d':
	if feat_cache is not None:
	idx = feat_idx[0]
	if feat_cache[idx] is None:
	feat_cache[idx] = x #.to("cpu") #x.clone() yyyy
	feat_idx[0] += 1
	else:

	cache_x = x[:, :, -1:, :, :].clone()
	# if cache_x.shape[2] < 2 and feat_cache[idx] is not None and feat_cache[idx]!='Rep':
	# # cache last frame of last two chunk
	# cache_x = torch.cat([feat_cache[idx][:, :, -1, :, :].unsqueeze(2).to(cache_x.device), cache_x], dim=2)

	x = self.time_conv(
	torch.cat([feat_cache[idx][:, :, -1:, :, :], x], 2))
	feat_cache[idx] = cache_x#.to("cpu") #yyyyy
	feat_idx[0] += 1
	return x

	def init_weight(self, conv):
	conv_weight = conv.weight
	nn.init.zeros_(conv_weight)
	c1, c2, t, h, w = conv_weight.size()
	one_matrix = torch.eye(c1, c2)
	init_matrix = one_matrix
	nn.init.zeros_(conv_weight)
	#conv_weight.data[:,:,-1,1,1] = init_matrix * 0.5
	conv_weight.data[:, :, 1, 0, 0] = init_matrix #* 0.5
	conv.weight.data.copy_(conv_weight)
	nn.init.zeros_(conv.bias.data)

	def init_weight2(self, conv):
	conv_weight = conv.weight.data
	nn.init.zeros_(conv_weight)
	c1, c2, t, h, w = conv_weight.size()
	init_matrix = torch.eye(c1 // 2, c2)
	#init_matrix = repeat(init_matrix, 'o ... -> (o 2) ...').permute(1,0,2).contiguous().reshape(c1,c2)
	conv_weight[:c1 // 2, :, -1, 0, 0] = init_matrix
	conv_weight[c1 // 2:, :, -1, 0, 0] = init_matrix
	conv.weight.data.copy_(conv_weight)
	nn.init.zeros_(conv.bias.data)


	class ResidualBlock(nn.Module):

	def __init__(self, in_dim, out_dim, dropout=0.0):
	super().__init__()
	self.in_dim = in_dim
	self.out_dim = out_dim

	# layers
	self.residual = nn.Sequential(
	RMS_norm(in_dim, images=False), nn.SiLU(),
	CausalConv3d(in_dim, out_dim, 3, padding=1),
	RMS_norm(out_dim, images=False), nn.SiLU(), nn.Dropout(dropout),
	CausalConv3d(out_dim, out_dim, 3, padding=1))
	self.shortcut = CausalConv3d(in_dim, out_dim, 1) \
	if in_dim != out_dim else nn.Identity()

	def forward(self, x, feat_cache=None, feat_idx=[0]):
	h = self.shortcut(x)
	dtype = x.dtype
	for layer in self.residual:
	if isinstance(layer, CausalConv3d) and feat_cache is not None:
	idx = feat_idx[0]
	cache_x = x[:, :, -CACHE_T:, :, :].clone()
	if cache_x.shape[2] < 2 and feat_cache[idx] is not None:
	# cache last frame of last two chunk
	cache_x = torch.cat([
	feat_cache[idx][:, :, -1, :, :].unsqueeze(2).to(
	cache_x.device), cache_x
	],
	dim=2)
	x = layer(x, feat_cache[idx]).to(dtype)
	feat_cache[idx] = cache_x#.to("cpu")
	feat_idx[0] += 1
	else:
	x = layer(x).to(dtype)
	return x + h


	class AttentionBlock(nn.Module):
	"""
	Causal self-attention with a single head.
	"""

	def __init__(self, dim):
	super().__init__()
	self.dim = dim

	# layers
	self.norm = RMS_norm(dim)
	self.to_qkv = nn.Conv2d(dim, dim * 3, 1)
	self.proj = nn.Conv2d(dim, dim, 1)

	# zero out the last layer params
	nn.init.zeros_(self.proj.weight)

	def forward(self, x):
	identity = x
	b, c, t, h, w = x.size()
	x = rearrange(x, 'b c t h w -> (b t) c h w')
	x = self.norm(x)
	# compute query, key, value
	q, k, v = self.to_qkv(x).reshape(b * t, 1, c * 3,
	-1).permute(0, 1, 3,
	2).contiguous().chunk(
	3, dim=-1)

	# apply attention
	x = F.scaled_dot_product_attention(
	q,
	k,
	v,
	)
	x = x.squeeze(1).permute(0, 2, 1).reshape(b * t, c, h, w)

	# output
	x = self.proj(x)
	x = rearrange(x, '(b t) c h w-> b c t h w', t=t)
	return x + identity


	class Encoder3d(nn.Module):

	def __init__(self,
	dim=128,
	z_dim=4,
	dim_mult=[1, 2, 4, 4],
	num_res_blocks=2,
	attn_scales=[],
	temperal_downsample=[True, True, False],
	dropout=0.0):
	super().__init__()
	self.dim = dim
	self.z_dim = z_dim
	self.dim_mult = dim_mult
	self.num_res_blocks = num_res_blocks
	self.attn_scales = attn_scales
	self.temperal_downsample = temperal_downsample

	# dimensions
	dims = [dim * u for u in [1] + dim_mult]
	scale = 1.0

	# init block
	self.conv1 = CausalConv3d(3, dims[0], 3, padding=1)

	# downsample blocks
	downsamples = []
	for i, (in_dim, out_dim) in enumerate(zip(dims[:-1], dims[1:])):
	# residual (+attention) blocks
	for _ in range(num_res_blocks):
	downsamples.append(ResidualBlock(in_dim, out_dim, dropout))
	if scale in attn_scales:
	downsamples.append(AttentionBlock(out_dim))
	in_dim = out_dim

	# downsample block
	if i != len(dim_mult) - 1:
	mode = 'downsample3d' if temperal_downsample[
	i] else 'downsample2d'
	downsamples.append(Resample(out_dim, mode=mode))
	scale /= 2.0
	self.downsamples = nn.Sequential(*downsamples)

	# middle blocks
	self.middle = nn.Sequential(
	ResidualBlock(out_dim, out_dim, dropout), AttentionBlock(out_dim),
	ResidualBlock(out_dim, out_dim, dropout))

	# output blocks
	self.head = nn.Sequential(
	RMS_norm(out_dim, images=False), nn.SiLU(),
	CausalConv3d(out_dim, z_dim, 3, padding=1))

	def forward(self, x, feat_cache=None, feat_idx=[0]):
	dtype = x.dtype
	if feat_cache is not None:
	idx = feat_idx[0]
	cache_x = x[:, :, -CACHE_T:, :, :].clone()
	if cache_x.shape[2] < 2 and feat_cache[idx] is not None:
	# cache last frame of last two chunk
	cache_x = torch.cat([
	feat_cache[idx][:, :, -1, :, :].unsqueeze(2).to(
	cache_x.device), cache_x
	],
	dim=2)
	x = self.conv1(x, feat_cache[idx]).to(dtype)
	feat_cache[idx] = cache_x
	del cache_x
	feat_idx[0] += 1
	else:
	x = self.conv1(x)


	## downsamples
	for layer in self.downsamples:
	if feat_cache is not None:
	x = layer(x, feat_cache, feat_idx)
	else:
	x = layer(x)


	## middle
	for layer in self.middle:
	if isinstance(layer, ResidualBlock) and feat_cache is not None:
	x = layer(x, feat_cache, feat_idx)
	else:
	x = layer(x)


	## head
	for layer in self.head:
	if isinstance(layer, CausalConv3d) and feat_cache is not None:
	idx = feat_idx[0]
	cache_x = x[:, :, -CACHE_T:, :, :].clone()
	if cache_x.shape[2] < 2 and feat_cache[idx] is not None:
	# cache last frame of last two chunk
	cache_x = torch.cat([
	feat_cache[idx][:, :, -1, :, :].unsqueeze(2).to(
	cache_x.device), cache_x
	],
	dim=2)
	x = layer(x, feat_cache[idx])
	feat_cache[idx] = cache_x
	del cache_x
	feat_idx[0] += 1
	else:
	x = layer(x)


	return x


	class Decoder3d(nn.Module):

	def __init__(self,
	dim=128,
	z_dim=4,
	dim_mult=[1, 2, 4, 4],
	num_res_blocks=2,
	attn_scales=[],
	temperal_upsample=[False, True, True],
	dropout=0.0):
	super().__init__()
	self.dim = dim
	self.z_dim = z_dim
	self.dim_mult = dim_mult
	self.num_res_blocks = num_res_blocks
	self.attn_scales = attn_scales
	self.temperal_upsample = temperal_upsample

	# dimensions
	dims = [dim * u for u in [dim_mult[-1]] + dim_mult[::-1]]
	scale = 1.0 / 2**(len(dim_mult) - 2)

	# init block
	self.conv1 = CausalConv3d(z_dim, dims[0], 3, padding=1)

	# middle blocks
	self.middle = nn.Sequential(
	ResidualBlock(dims[0], dims[0], dropout), AttentionBlock(dims[0]),
	ResidualBlock(dims[0], dims[0], dropout))

	# upsample blocks
	upsamples = []
	for i, (in_dim, out_dim) in enumerate(zip(dims[:-1], dims[1:])):
	# residual (+attention) blocks
	if i == 1 or i == 2 or i == 3:
	in_dim = in_dim // 2
	for _ in range(num_res_blocks + 1):
	upsamples.append(ResidualBlock(in_dim, out_dim, dropout))
	if scale in attn_scales:
	upsamples.append(AttentionBlock(out_dim))
	in_dim = out_dim

	# upsample block
	if i != len(dim_mult) - 1:
	mode = 'upsample3d' if temperal_upsample[i] else 'upsample2d'
	upsamples.append(Resample(out_dim, mode=mode))
	scale *= 2.0
	self.upsamples = nn.Sequential(*upsamples)

	# output blocks
	self.head = nn.Sequential(
	RMS_norm(out_dim, images=False), nn.SiLU(),
	CausalConv3d(out_dim, 3, 3, padding=1))

	def forward(self, x, feat_cache=None, feat_idx=[0]):
	## conv1
	if feat_cache is not None:
	idx = feat_idx[0]
	cache_x = x[:, :, -CACHE_T:, :, :].clone()
	if cache_x.shape[2] < 2 and feat_cache[idx] is not None:
	# cache last frame of last two chunk
	cache_x = torch.cat([
	feat_cache[idx][:, :, -1, :, :].unsqueeze(2).to(
	cache_x.device), cache_x
	],
	dim=2)
	x = self.conv1(x, feat_cache[idx])
	feat_cache[idx] = cache_x#.to("cpu")
	del cache_x
	feat_idx[0] += 1
	else:
	x = self.conv1(x)
	cache_x = None

	## middle
	for layer in self.middle:
	if isinstance(layer, ResidualBlock) and feat_cache is not None:
	x = layer(x, feat_cache, feat_idx)
	else:
	x = layer(x)

	## upsamples
	for layer in self.upsamples:
	if feat_cache is not None:
	x = layer(x, feat_cache, feat_idx)
	else:
	x = layer(x)

	## head
	for layer in self.head:
	if isinstance(layer, CausalConv3d) and feat_cache is not None:
	idx = feat_idx[0]
	cache_x = x[:, :, -CACHE_T:, :, :] .clone()
	if cache_x.shape[2] < 2 and feat_cache[idx] is not None:
	# cache last frame of last two chunk
	cache_x = torch.cat([
	feat_cache[idx][:, :, -1, :, :].unsqueeze(2).to(
	cache_x.device), cache_x
	],
	dim=2)
	x = layer(x, feat_cache[idx])
	feat_cache[idx] = cache_x#.to("cpu")
	del cache_x
	feat_idx[0] += 1
	else:
	x = layer(x)
	return x


	def count_conv3d(model):
	count = 0
	for m in model.modules():
	if isinstance(m, CausalConv3d):
	count += 1
	return count


	class WanVAE_(nn.Module):

	_offload_hooks = ['encode', 'decode']

	def __init__(self,
	dim=128,
	z_dim=4,
	dim_mult=[1, 2, 4, 4],
	num_res_blocks=2,
	attn_scales=[],
	temperal_downsample=[True, True, False],
	dropout=0.0):
	super().__init__()
	self.dim = dim
	self.z_dim = z_dim
	self.dim_mult = dim_mult
	self.num_res_blocks = num_res_blocks
	self.attn_scales = attn_scales
	self.temperal_downsample = temperal_downsample
	self.temperal_upsample = temperal_downsample[::-1]

	# modules
	self.encoder = Encoder3d(dim, z_dim * 2, dim_mult, num_res_blocks,
	attn_scales, self.temperal_downsample, dropout)
	self.conv1 = CausalConv3d(z_dim * 2, z_dim * 2, 1)
	self.conv2 = CausalConv3d(z_dim, z_dim, 1)
	self.decoder = Decoder3d(dim, z_dim, dim_mult, num_res_blocks,
	attn_scales, self.temperal_upsample, dropout)

	def forward(self, x):
	mu, log_var = self.encode(x)
	z = self.reparameterize(mu, log_var)
	x_recon = self.decode(z)
	return x_recon, mu, log_var

	def encode(self, x, scale = None, any_end_frame = False):
	self.clear_cache()
	## cache
	t = x.shape[2]
	if any_end_frame:
	iter_ = 2 + (t - 2) // 4
	else:
	iter_ = 1 + (t - 1) // 4
	## 对encode输入的x，按时间拆分为1、4、4、4....
	out_list = []
	for i in range(iter_):
	self._enc_conv_idx = [0]
	if i == 0:
	out_list.append(self.encoder(
	x[:, :, :1, :, :],
	feat_cache=self._enc_feat_map,
	feat_idx=self._enc_conv_idx))
	elif any_end_frame and i== iter_ -1:
	out_list.append(self.encoder(
	x[:, :, -1:, :, :],
	feat_cache= None,
	feat_idx=self._enc_conv_idx))
	else:
	out_list.append(self.encoder(
	x[:, :, 1 + 4 * (i - 1):1 + 4 * i, :, :],
	feat_cache=self._enc_feat_map,
	feat_idx=self._enc_conv_idx))

	self.clear_cache()
	out = torch.cat(out_list, 2)
	out_list = None

	mu, log_var = self.conv1(out).chunk(2, dim=1)
	if scale != None:
	if isinstance(scale[0], torch.Tensor):
	mu = (mu - scale[0].view(1, self.z_dim, 1, 1, 1)) * scale[1].view(
	1, self.z_dim, 1, 1, 1)
	else:
	mu = (mu - scale[0]) * scale[1]
	return mu


	def decode(self, z, scale=None, any_end_frame = False):
	self.clear_cache()
	# z: [b,c,t,h,w]
	if scale != None:
	if isinstance(scale[0], torch.Tensor):
	z = z / scale[1].view(1, self.z_dim, 1, 1, 1) + scale[0].view(
	1, self.z_dim, 1, 1, 1)
	else:
	z = z / scale[1] + scale[0]
	iter_ = z.shape[2]
	x = self.conv2(z)
	out_list = []
	for i in range(iter_):
	self._conv_idx = [0]
	if i == 0:
	out_list.append(self.decoder(
	x[:, :, i:i + 1, :, :],
	feat_cache=self._feat_map,
	feat_idx=self._conv_idx))
	elif any_end_frame and i==iter_-1:
	out_list.append(self.decoder(
	x[:, :, -1:, :, :],
	feat_cache=None ,
	feat_idx=self._conv_idx))
	else:
	out_list.append(self.decoder(
	x[:, :, i:i + 1, :, :],
	feat_cache=self._feat_map,
	feat_idx=self._conv_idx))
	self.clear_cache()
	out = torch.cat(out_list, 2)
	return out

	def blend_v(self, a: torch.Tensor, b: torch.Tensor, blend_extent: int) -> torch.Tensor:
	blend_extent = min(a.shape[-2], b.shape[-2], blend_extent)
	for y in range(blend_extent):
	b[:, :, :, y, :] = a[:, :, :, -blend_extent + y, :] * (1 - y / blend_extent) + b[:, :, :, y, :] * (y / blend_extent)
	return b

	def blend_h(self, a: torch.Tensor, b: torch.Tensor, blend_extent: int) -> torch.Tensor:
	blend_extent = min(a.shape[-1], b.shape[-1], blend_extent)
	for x in range(blend_extent):
	b[:, :, :, :, x] = a[:, :, :, :, -blend_extent + x] * (1 - x / blend_extent) + b[:, :, :, :, x] * (x / blend_extent)
	return b

	def spatial_tiled_decode(self, z, scale, tile_size, any_end_frame= False):
	tile_sample_min_size = tile_size
	tile_latent_min_size = int(tile_sample_min_size / 8)
	tile_overlap_factor = 0.25

	# z: [b,c,t,h,w]

	if isinstance(scale[0], torch.Tensor):
	z = z / scale[1].view(1, self.z_dim, 1, 1, 1) + scale[0].view(
	1, self.z_dim, 1, 1, 1)
	else:
	z = z / scale[1] + scale[0]


	overlap_size = int(tile_latent_min_size * (1 - tile_overlap_factor)) #8 0.75
	blend_extent = int(tile_sample_min_size * tile_overlap_factor) #256 0.25
	row_limit = tile_sample_min_size - blend_extent

	# Split z into overlapping tiles and decode them separately.
	# The tiles have an overlap to avoid seams between tiles.
	rows = []
	for i in range(0, z.shape[-2], overlap_size):
	row = []
	for j in range(0, z.shape[-1], overlap_size):
	tile = z[:, :, :, i: i + tile_latent_min_size, j: j + tile_latent_min_size]
	decoded = self.decode(tile, any_end_frame= any_end_frame)
	row.append(decoded)
	rows.append(row)
	result_rows = []
	for i, row in enumerate(rows):
	result_row = []
	for j, tile in enumerate(row):
	# blend the above tile and the left tile
	# to the current tile and add the current tile to the result row
	if i > 0:
	tile = self.blend_v(rows[i - 1][j], tile, blend_extent)
	if j > 0:
	tile = self.blend_h(row[j - 1], tile, blend_extent)
	result_row.append(tile[:, :, :, :row_limit, :row_limit])
	result_rows.append(torch.cat(result_row, dim=-1))

	return torch.cat(result_rows, dim=-2)


	def spatial_tiled_encode(self, x, scale, tile_size, any_end_frame = False) :
	tile_sample_min_size = tile_size
	tile_latent_min_size = int(tile_sample_min_size / 8)
	tile_overlap_factor = 0.25

	overlap_size = int(tile_sample_min_size * (1 - tile_overlap_factor))
	blend_extent = int(tile_latent_min_size * tile_overlap_factor)
	row_limit = tile_latent_min_size - blend_extent

	# Split video into tiles and encode them separately.
	rows = []
	for i in range(0, x.shape[-2], overlap_size):
	row = []
	for j in range(0, x.shape[-1], overlap_size):
	tile = x[:, :, :, i: i + tile_sample_min_size, j: j + tile_sample_min_size]
	tile = self.encode(tile, any_end_frame= any_end_frame)
	row.append(tile)
	rows.append(row)
	result_rows = []
	for i, row in enumerate(rows):
	result_row = []
	for j, tile in enumerate(row):
	# blend the above tile and the left tile
	# to the current tile and add the current tile to the result row
	if i > 0:
	tile = self.blend_v(rows[i - 1][j], tile, blend_extent)
	if j > 0:
	tile = self.blend_h(row[j - 1], tile, blend_extent)
	result_row.append(tile[:, :, :, :row_limit, :row_limit])
	result_rows.append(torch.cat(result_row, dim=-1))

	mu = torch.cat(result_rows, dim=-2)

	if isinstance(scale[0], torch.Tensor):
	mu = (mu - scale[0].view(1, self.z_dim, 1, 1, 1)) * scale[1].view(
	1, self.z_dim, 1, 1, 1)
	else:
	mu = (mu - scale[0]) * scale[1]

	return mu


	def reparameterize(self, mu, log_var):
	std = torch.exp(0.5 * log_var)
	eps = torch.randn_like(std)
	return eps * std + mu

	def sample(self, imgs, deterministic=False):
	mu, log_var = self.encode(imgs)
	if deterministic:
	return mu
	std = torch.exp(0.5 * log_var.clamp(-30.0, 20.0))
	return mu + std * torch.randn_like(std)

	def clear_cache(self):
	self._conv_num = count_conv3d(self.decoder)
	self._conv_idx = [0]
	self._feat_map = [None] * self._conv_num
	#cache encode
	self._enc_conv_num = count_conv3d(self.encoder)
	self._enc_conv_idx = [0]
	self._enc_feat_map = [None] * self._enc_conv_num


	def _video_vae(pretrained_path=None, z_dim=None, device='cpu', **kwargs):
	"""
	Autoencoder3d adapted from Stable Diffusion 1.x, 2.x and XL.
	"""
	# params
	cfg = dict(
	dim=96,
	z_dim=z_dim,
	dim_mult=[1, 2, 4, 4],
	num_res_blocks=2,
	attn_scales=[],
	temperal_downsample=[False, True, True],
	dropout=0.0)
	cfg.update(**kwargs)

	# init model
	with torch.device('meta'):
	model = WanVAE_(**cfg)

	from mmgp import offload
	# load checkpoint
	logging.info(f'loading {pretrained_path}')
	# model.load_state_dict(
	# torch.load(pretrained_path, map_location=device), assign=True)
	# offload.load_model_data(model, pretrained_path.replace(".pth", "_bf16.safetensors"), writable_tensors= False)
	offload.load_model_data(model, pretrained_path.replace(".pth", ".safetensors"), writable_tensors= False)
	return model


	class WanVAE:

	def __init__(self,
	z_dim=16,
	vae_pth='cache/vae_step_411000.pth',
	dtype=torch.float,
	device="cuda"):
	self.dtype = dtype
	self.device = device

	mean = [
	-0.7571, -0.7089, -0.9113, 0.1075, -0.1745, 0.9653, -0.1517, 1.5508,
	0.4134, -0.0715, 0.5517, -0.3632, -0.1922, -0.9497, 0.2503, -0.2921
	]
	std = [
	2.8184, 1.4541, 2.3275, 2.6558, 1.2196, 1.7708, 2.6052, 2.0743,
	3.2687, 2.1526, 2.8652, 1.5579, 1.6382, 1.1253, 2.8251, 1.9160
	]
	self.mean = torch.tensor(mean, dtype=dtype, device=device)
	self.std = torch.tensor(std, dtype=dtype, device=device)
	self.scale = [self.mean, 1.0 / self.std]

	# init model
	self.model = _video_vae(
	pretrained_path=vae_pth,
	z_dim=z_dim,
	).to(dtype).eval() #.requires_grad_(False).to(device)
	self.model._model_dtype = dtype

	@staticmethod
	def get_VAE_tile_size(vae_config, device_mem_capacity, mixed_precision):
	# VAE Tiling
	if vae_config == 0:
	if mixed_precision:
	device_mem_capacity = device_mem_capacity / 2
	if device_mem_capacity >= 24000:
	use_vae_config = 1
	elif device_mem_capacity >= 8000:
	use_vae_config = 2
	else:
	use_vae_config = 3
	else:
	use_vae_config = vae_config

	if use_vae_config == 1:
	VAE_tile_size = 0
	elif use_vae_config == 2:
	VAE_tile_size = 256
	else:
	VAE_tile_size = 128

	return VAE_tile_size

	def encode(self, videos, tile_size = 256, any_end_frame = False):
	"""
	videos: A list of videos each with shape [C, T, H, W].
	"""
	scale = [u.to(device = self.device) for u in self.scale]
	if tile_size > 0:
	return [ self.model.spatial_tiled_encode(u.to(self.dtype).unsqueeze(0), scale, tile_size, any_end_frame=any_end_frame).float().squeeze(0) for u in videos ]
	else:
	return [ self.model.encode(u.to(self.dtype).unsqueeze(0), scale, any_end_frame=any_end_frame).float().squeeze(0) for u in videos ]


	def decode(self, zs, tile_size, any_end_frame = False):
	scale = [u.to(device = self.device) for u in self.scale]
	if tile_size > 0:
	return [ self.model.spatial_tiled_decode(u.to(self.dtype).unsqueeze(0), scale, tile_size, any_end_frame=any_end_frame).clamp_(-1, 1).float().squeeze(0) for u in zs ]
	else:
	return [ self.model.decode(u.to(self.dtype).unsqueeze(0), scale, any_end_frame=any_end_frame).clamp_(-1, 1).float().squeeze(0) for u in zs ]