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Personalize-SAM / per_segment_anything /modeling /transformer.py

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	# Copyright (c) Meta Platforms, Inc. and affiliates.
	# All rights reserved.

	# This source code is licensed under the license found in the
	# LICENSE file in the root directory of this source tree.

	import torch
	from torch import Tensor, nn

	import math
	from typing import Tuple, Type

	from .common import MLPBlock


	class TwoWayTransformer(nn.Module):
	def __init__(
	self,
	depth: int,
	embedding_dim: int,
	num_heads: int,
	mlp_dim: int,
	activation: Type[nn.Module] = nn.ReLU,
	attention_downsample_rate: int = 2,
	) -> None:
	"""
	A transformer decoder that attends to an input image using
	queries whose positional embedding is supplied.

	Args:
	depth (int): number of layers in the transformer
	embedding_dim (int): the channel dimension for the input embeddings
	num_heads (int): the number of heads for multihead attention. Must
	divide embedding_dim
	mlp_dim (int): the channel dimension internal to the MLP block
	activation (nn.Module): the activation to use in the MLP block
	"""
	super().__init__()
	self.depth = depth
	self.embedding_dim = embedding_dim
	self.num_heads = num_heads
	self.mlp_dim = mlp_dim
	self.layers = nn.ModuleList()

	for i in range(depth):
	self.layers.append(
	TwoWayAttentionBlock(
	embedding_dim=embedding_dim,
	num_heads=num_heads,
	mlp_dim=mlp_dim,
	activation=activation,
	attention_downsample_rate=attention_downsample_rate,
	skip_first_layer_pe=(i == 0),
	)
	)

	self.final_attn_token_to_image = Attention(
	embedding_dim, num_heads, downsample_rate=attention_downsample_rate
	)
	self.norm_final_attn = nn.LayerNorm(embedding_dim)

	def forward(
	self,
	image_embedding: Tensor,
	image_pe: Tensor,
	point_embedding: Tensor,
	attn_sim: Tensor,
	target_embedding=None
	) -> Tuple[Tensor, Tensor]:
	"""
	Args:
	image_embedding (torch.Tensor): image to attend to. Should be shape
	B x embedding_dim x h x w for any h and w.
	image_pe (torch.Tensor): the positional encoding to add to the image. Must
	have the same shape as image_embedding.
	point_embedding (torch.Tensor): the embedding to add to the query points.
	Must have shape B x N_points x embedding_dim for any N_points.

	Returns:
	torch.Tensor: the processed point_embedding
	torch.Tensor: the processed image_embedding
	"""
	# BxCxHxW -> BxHWxC == B x N_image_tokens x C
	bs, c, h, w = image_embedding.shape
	image_embedding = image_embedding.flatten(2).permute(0, 2, 1)
	image_pe = image_pe.flatten(2).permute(0, 2, 1)

	# Prepare queries
	queries = point_embedding
	keys = image_embedding

	# Apply transformer blocks and final layernorm
	for layer in self.layers:
	if target_embedding is not None:
	queries += target_embedding
	queries, keys = layer(
	queries=queries,
	keys=keys,
	query_pe=point_embedding,
	key_pe=image_pe,
	attn_sim=attn_sim,
	)

	# Apply the final attention layer from the points to the image
	q = queries + point_embedding
	k = keys + image_pe

	if target_embedding is not None:
	q += target_embedding
	attn_out = self.final_attn_token_to_image(q=q, k=k, v=keys)
	queries = queries + attn_out
	queries = self.norm_final_attn(queries)

	return queries, keys


	class TwoWayAttentionBlock(nn.Module):
	def __init__(
	self,
	embedding_dim: int,
	num_heads: int,
	mlp_dim: int = 2048,
	activation: Type[nn.Module] = nn.ReLU,
	attention_downsample_rate: int = 2,
	skip_first_layer_pe: bool = False,
	) -> None:
	"""
	A transformer block with four layers: (1) self-attention of sparse
	inputs, (2) cross attention of sparse inputs to dense inputs, (3) mlp
	block on sparse inputs, and (4) cross attention of dense inputs to sparse
	inputs.

	Arguments:
	embedding_dim (int): the channel dimension of the embeddings
	num_heads (int): the number of heads in the attention layers
	mlp_dim (int): the hidden dimension of the mlp block
	activation (nn.Module): the activation of the mlp block
	skip_first_layer_pe (bool): skip the PE on the first layer
	"""
	super().__init__()
	self.self_attn = Attention(embedding_dim, num_heads)
	self.norm1 = nn.LayerNorm(embedding_dim)

	self.cross_attn_token_to_image = Attention(
	embedding_dim, num_heads, downsample_rate=attention_downsample_rate
	)
	self.norm2 = nn.LayerNorm(embedding_dim)

	self.mlp = MLPBlock(embedding_dim, mlp_dim, activation)
	self.norm3 = nn.LayerNorm(embedding_dim)

	self.norm4 = nn.LayerNorm(embedding_dim)
	self.cross_attn_image_to_token = Attention(
	embedding_dim, num_heads, downsample_rate=attention_downsample_rate
	)

	self.skip_first_layer_pe = skip_first_layer_pe

	def forward(
	self, queries: Tensor, keys: Tensor, query_pe: Tensor, key_pe: Tensor, attn_sim: Tensor
	) -> Tuple[Tensor, Tensor]:
	# Self attention block
	if self.skip_first_layer_pe:
	queries = self.self_attn(q=queries, k=queries, v=queries)
	else:
	q = queries + query_pe
	attn_out = self.self_attn(q=q, k=q, v=queries)
	queries = queries + attn_out
	queries = self.norm1(queries)

	# Cross attention block, tokens attending to image embedding
	q = queries + query_pe
	k = keys + key_pe
	attn_out = self.cross_attn_token_to_image(q=q, k=k, v=keys, attn_sim=attn_sim)
	queries = queries + attn_out
	queries = self.norm2(queries)

	# MLP block
	mlp_out = self.mlp(queries)
	queries = queries + mlp_out
	queries = self.norm3(queries)

	# Cross attention block, image embedding attending to tokens
	q = queries + query_pe
	k = keys + key_pe
	attn_out = self.cross_attn_image_to_token(q=k, k=q, v=queries)
	keys = keys + attn_out
	keys = self.norm4(keys)

	return queries, keys


	class Attention(nn.Module):
	"""
	An attention layer that allows for downscaling the size of the embedding
	after projection to queries, keys, and values.
	"""

	def __init__(
	self,
	embedding_dim: int,
	num_heads: int,
	downsample_rate: int = 1,
	) -> None:
	super().__init__()
	self.embedding_dim = embedding_dim
	self.internal_dim = embedding_dim // downsample_rate
	self.num_heads = num_heads
	assert self.internal_dim % num_heads == 0, "num_heads must divide embedding_dim."

	self.q_proj = nn.Linear(embedding_dim, self.internal_dim)
	self.k_proj = nn.Linear(embedding_dim, self.internal_dim)
	self.v_proj = nn.Linear(embedding_dim, self.internal_dim)
	self.out_proj = nn.Linear(self.internal_dim, embedding_dim)

	def _separate_heads(self, x: Tensor, num_heads: int) -> Tensor:
	b, n, c = x.shape
	x = x.reshape(b, n, num_heads, c // num_heads)
	return x.transpose(1, 2) # B x N_heads x N_tokens x C_per_head

	def _recombine_heads(self, x: Tensor) -> Tensor:
	b, n_heads, n_tokens, c_per_head = x.shape
	x = x.transpose(1, 2)
	return x.reshape(b, n_tokens, n_heads * c_per_head) # B x N_tokens x C

	def forward(self, q: Tensor, k: Tensor, v: Tensor, attn_sim: Tensor = None) -> Tensor:
	# Input projections
	q = self.q_proj(q)
	k = self.k_proj(k)
	v = self.v_proj(v)

	# Separate into heads
	q = self._separate_heads(q, self.num_heads)
	k = self._separate_heads(k, self.num_heads)
	v = self._separate_heads(v, self.num_heads)

	# Attention
	_, _, _, c_per_head = q.shape
	attn = q @ k.permute(0, 1, 3, 2) # B x N_heads x N_tokens x N_tokens
	attn = attn / math.sqrt(c_per_head)
	attn = torch.softmax(attn, dim=-1)

	if attn_sim is not None:
	attn = attn + attn_sim
	attn = torch.softmax(attn, dim=-1)

	# Get output
	out = attn @ v
	out = self._recombine_heads(out)
	out = self.out_proj(out)

	return out