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EDICT / my_diffusers /models /unet_2d_condition.py

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	from dataclasses import dataclass
	from typing import Optional, Tuple, Union

	import torch
	import torch.nn as nn

	from ..configuration_utils import ConfigMixin, register_to_config
	from ..modeling_utils import ModelMixin
	from ..utils import BaseOutput
	from .embeddings import TimestepEmbedding, Timesteps
	from .unet_blocks import UNetMidBlock2DCrossAttn, get_down_block, get_up_block


	@dataclass
	class UNet2DConditionOutput(BaseOutput):
	"""
	Args:
	sample (`torch.FloatTensor` of shape `(batch_size, num_channels, height, width)`):
	Hidden states conditioned on `encoder_hidden_states` input. Output of last layer of model.
	"""

	sample: torch.FloatTensor


	class UNet2DConditionModel(ModelMixin, ConfigMixin):
	r"""
	UNet2DConditionModel is a conditional 2D UNet model that takes in a noisy sample, conditional state, and a timestep
	and returns sample shaped output.

	This model inherits from [`ModelMixin`]. Check the superclass documentation for the generic methods the library
	implements for all the model (such as downloading or saving, etc.)

	Parameters:
	sample_size (`int`, optional): The size of the input sample.
	in_channels (`int`, optional, defaults to 4): The number of channels in the input sample.
	out_channels (`int`, optional, defaults to 4): The number of channels in the output.
	center_input_sample (`bool`, optional, defaults to `False`): Whether to center the input sample.
	flip_sin_to_cos (`bool`, optional, defaults to `False`):
	Whether to flip the sin to cos in the time embedding.
	freq_shift (`int`, optional, defaults to 0): The frequency shift to apply to the time embedding.
	down_block_types (`Tuple[str]`, optional, defaults to `("CrossAttnDownBlock2D", "CrossAttnDownBlock2D", "CrossAttnDownBlock2D", "DownBlock2D")`):
	The tuple of downsample blocks to use.
	up_block_types (`Tuple[str]`, optional, defaults to `("UpBlock2D", "CrossAttnUpBlock2D", "CrossAttnUpBlock2D", "CrossAttnUpBlock2D",)`):
	The tuple of upsample blocks to use.
	block_out_channels (`Tuple[int]`, optional, defaults to `(320, 640, 1280, 1280)`):
	The tuple of output channels for each block.
	layers_per_block (`int`, optional, defaults to 2): The number of layers per block.
	downsample_padding (`int`, optional, defaults to 1): The padding to use for the downsampling convolution.
	mid_block_scale_factor (`float`, optional, defaults to 1.0): The scale factor to use for the mid block.
	act_fn (`str`, optional, defaults to `"silu"`): The activation function to use.
	norm_num_groups (`int`, optional, defaults to 32): The number of groups to use for the normalization.
	norm_eps (`float`, optional, defaults to 1e-5): The epsilon to use for the normalization.
	cross_attention_dim (`int`, optional, defaults to 1280): The dimension of the cross attention features.
	attention_head_dim (`int`, optional, defaults to 8): The dimension of the attention heads.
	"""

	@register_to_config
	def __init__(
	self,
	sample_size: Optional[int] = None,
	in_channels: int = 4,
	out_channels: int = 4,
	center_input_sample: bool = False,
	flip_sin_to_cos: bool = True,
	freq_shift: int = 0,
	down_block_types: Tuple[str] = (
	"CrossAttnDownBlock2D",
	"CrossAttnDownBlock2D",
	"CrossAttnDownBlock2D",
	"DownBlock2D",
	),
	up_block_types: Tuple[str] = ("UpBlock2D", "CrossAttnUpBlock2D", "CrossAttnUpBlock2D", "CrossAttnUpBlock2D"),
	block_out_channels: Tuple[int] = (320, 640, 1280, 1280),
	layers_per_block: int = 2,
	downsample_padding: int = 1,
	mid_block_scale_factor: float = 1,
	act_fn: str = "silu",
	norm_num_groups: int = 32,
	norm_eps: float = 1e-5,
	cross_attention_dim: int = 1280,
	attention_head_dim: int = 8,
	):
	super().__init__()

	self.sample_size = sample_size
	time_embed_dim = block_out_channels[0] * 4

	# input
	self.conv_in = nn.Conv2d(in_channels, block_out_channels[0], kernel_size=3, padding=(1, 1))

	# time
	self.time_proj = Timesteps(block_out_channels[0], flip_sin_to_cos, freq_shift)
	timestep_input_dim = block_out_channels[0]

	self.time_embedding = TimestepEmbedding(timestep_input_dim, time_embed_dim)

	self.down_blocks = nn.ModuleList([])
	self.mid_block = None
	self.up_blocks = nn.ModuleList([])

	# down
	output_channel = block_out_channels[0]
	for i, down_block_type in enumerate(down_block_types):
	input_channel = output_channel
	output_channel = block_out_channels[i]
	is_final_block = i == len(block_out_channels) - 1

	down_block = get_down_block(
	down_block_type,
	num_layers=layers_per_block,
	in_channels=input_channel,
	out_channels=output_channel,
	temb_channels=time_embed_dim,
	add_downsample=not is_final_block,
	resnet_eps=norm_eps,
	resnet_act_fn=act_fn,
	cross_attention_dim=cross_attention_dim,
	attn_num_head_channels=attention_head_dim,
	downsample_padding=downsample_padding,
	)
	self.down_blocks.append(down_block)

	# mid
	self.mid_block = UNetMidBlock2DCrossAttn(
	in_channels=block_out_channels[-1],
	temb_channels=time_embed_dim,
	resnet_eps=norm_eps,
	resnet_act_fn=act_fn,
	output_scale_factor=mid_block_scale_factor,
	resnet_time_scale_shift="default",
	cross_attention_dim=cross_attention_dim,
	attn_num_head_channels=attention_head_dim,
	resnet_groups=norm_num_groups,
	)

	# up
	reversed_block_out_channels = list(reversed(block_out_channels))
	output_channel = reversed_block_out_channels[0]
	for i, up_block_type in enumerate(up_block_types):
	prev_output_channel = output_channel
	output_channel = reversed_block_out_channels[i]
	input_channel = reversed_block_out_channels[min(i + 1, len(block_out_channels) - 1)]

	is_final_block = i == len(block_out_channels) - 1

	up_block = get_up_block(
	up_block_type,
	num_layers=layers_per_block + 1,
	in_channels=input_channel,
	out_channels=output_channel,
	prev_output_channel=prev_output_channel,
	temb_channels=time_embed_dim,
	add_upsample=not is_final_block,
	resnet_eps=norm_eps,
	resnet_act_fn=act_fn,
	cross_attention_dim=cross_attention_dim,
	attn_num_head_channels=attention_head_dim,
	)
	self.up_blocks.append(up_block)
	prev_output_channel = output_channel

	# out
	self.conv_norm_out = nn.GroupNorm(num_channels=block_out_channels[0], num_groups=norm_num_groups, eps=norm_eps)
	self.conv_act = nn.SiLU()
	self.conv_out = nn.Conv2d(block_out_channels[0], out_channels, 3, padding=1)

	def set_attention_slice(self, slice_size):
	if slice_size is not None and self.config.attention_head_dim % slice_size != 0:
	raise ValueError(
	f"Make sure slice_size {slice_size} is a divisor of "
	f"the number of heads used in cross_attention {self.config.attention_head_dim}"
	)
	if slice_size is not None and slice_size > self.config.attention_head_dim:
	raise ValueError(
	f"Chunk_size {slice_size} has to be smaller or equal to "
	f"the number of heads used in cross_attention {self.config.attention_head_dim}"
	)

	for block in self.down_blocks:
	if hasattr(block, "attentions") and block.attentions is not None:
	block.set_attention_slice(slice_size)

	self.mid_block.set_attention_slice(slice_size)

	for block in self.up_blocks:
	if hasattr(block, "attentions") and block.attentions is not None:
	block.set_attention_slice(slice_size)

	def forward(
	self,
	sample: torch.FloatTensor,
	timestep: Union[torch.Tensor, float, int],
	encoder_hidden_states: torch.Tensor,
	return_dict: bool = True,
	) -> Union[UNet2DConditionOutput, Tuple]:
	"""r
	Args:
	sample (`torch.FloatTensor`): (batch, channel, height, width) noisy inputs tensor
	timestep (`torch.FloatTensor` or `float` or `int): (batch) timesteps
	encoder_hidden_states (`torch.FloatTensor`): (batch, channel, height, width) encoder hidden states
	return_dict (`bool`, optional, defaults to `True`):
	Whether or not to return a [`models.unet_2d_condition.UNet2DConditionOutput`] instead of a plain tuple.

	Returns:
	[`~models.unet_2d_condition.UNet2DConditionOutput`] or `tuple`:
	[`~models.unet_2d_condition.UNet2DConditionOutput`] if `return_dict` is True, otherwise a `tuple`. When
	returning a tuple, the first element is the sample tensor.
	"""
	# 0. center input if necessary
	if self.config.center_input_sample:
	sample = 2 * sample - 1.0

	# 1. time
	timesteps = timestep
	if not torch.is_tensor(timesteps):
	timesteps = torch.tensor([timesteps], dtype=torch.long, device=sample.device)
	elif torch.is_tensor(timesteps) and len(timesteps.shape) == 0:
	timesteps = timesteps.to(dtype=torch.float64)
	timesteps = timesteps[None].to(device=sample.device)

	# broadcast to batch dimension in a way that's compatible with ONNX/Core ML
	timesteps = timesteps.expand(sample.shape[0])

	t_emb = self.time_proj(timesteps)
	# print(t_emb.dtype)
	t_emb = t_emb.to(sample.dtype).to(sample.device)
	emb = self.time_embedding(t_emb)

	# 2. pre-process
	sample = self.conv_in(sample)

	# 3. down
	down_block_res_samples = (sample,)
	for downsample_block in self.down_blocks:
	if hasattr(downsample_block, "attentions") and downsample_block.attentions is not None:
	# print(sample.dtype, emb.dtype, encoder_hidden_states.dtype)
	sample, res_samples = downsample_block(
	hidden_states=sample, temb=emb, encoder_hidden_states=encoder_hidden_states
	)
	else:
	sample, res_samples = downsample_block(hidden_states=sample, temb=emb)

	down_block_res_samples += res_samples

	# 4. mid
	sample = self.mid_block(sample, emb, encoder_hidden_states=encoder_hidden_states)

	# 5. up
	for upsample_block in self.up_blocks:
	res_samples = down_block_res_samples[-len(upsample_block.resnets) :]
	down_block_res_samples = down_block_res_samples[: -len(upsample_block.resnets)]

	if hasattr(upsample_block, "attentions") and upsample_block.attentions is not None:
	sample = upsample_block(
	hidden_states=sample,
	temb=emb,
	res_hidden_states_tuple=res_samples,
	encoder_hidden_states=encoder_hidden_states,
	)
	else:
	sample = upsample_block(hidden_states=sample, temb=emb, res_hidden_states_tuple=res_samples)

	# 6. post-process
	# make sure hidden states is in float32
	# when running in half-precision
	sample = self.conv_norm_out(sample.double()).type(sample.dtype)
	sample = self.conv_act(sample)
	sample = self.conv_out(sample)

	if not return_dict:
	return (sample,)

	return UNet2DConditionOutput(sample=sample)