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OFA-OCR / fairseq /examples /adaptive_span /adaptive_span_model.py

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	# Copyright (c) Facebook, Inc. and its 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 math

	import torch
	import torch.nn as nn
	import torch.nn.functional as F

	from fairseq.modules.layer_norm import LayerNorm

	from .adaptive_span_attention import AdaptiveSpan

	# Size notations:
	# B = batch_size, H = d_model, M = block_size, L = attn_span


	def _skew(X, pad_value):
	"""shift every row 1 step to right"""
	# X = B x M x L
	B, M, L = X.size()
	X = F.pad(X, (0, M + 1), value=pad_value) # B x M x (L+M+1)
	X = X.view(B, -1) # B x ML+MM+M
	X = X[:, :-M] # B x ML+MM
	X = X.view(B, M, M + L) # B x M x L+M
	return X


	def _unskew(X):
	"""reverse _skew operation"""
	# X = B x M x L+M
	B, M, L = X.size()
	L -= M
	X = X.view(B, -1) # B x ML+MM
	X = F.pad(X, (0, M)) # B x ML+MM+M
	X = X.view(B, M, M + L + 1) # B x M x L+M+1
	X = X[:, :, :L] # B x M x L
	return X


	class SeqAttention(nn.Module):
	"""Sequential self-attention layer.
	Each token will attend to its previous fixed number of steps.
	Note that attention doesn't include the current step itself.
	"""

	def __init__(self, d_model, n_head, attn_span, dropout, adapt_span_layer, **kargs):
	nn.Module.__init__(self)
	self.dropout = nn.Dropout(dropout)
	self.d_model = d_model # size of a single head
	self.attn_span = attn_span
	self.adaptive_span = AdaptiveSpan(
	attn_span=attn_span,
	n_head=n_head,
	adapt_span_layer=adapt_span_layer,
	**kargs
	)

	def forward(self, query, key, value, key_pe):
	# query size = B x M x H
	# key, value sizes = B x (M+L) x H

	key, value, key_pe = self.adaptive_span.trim_memory(query, key, value, key_pe)

	# compute attention from context
	# B x M (dest) x (M+L) (src)
	attn_cont = torch.matmul(query, key.transpose(-1, -2))
	attn_cont = _unskew(attn_cont) # B x M x L

	# compute the effect of position embedding
	attn_pos = torch.matmul(query, key_pe) # B x M x L_pos
	attn = attn_cont + attn_pos

	attn = attn / math.sqrt(self.d_model) # B x M X L_pos

	attn = F.softmax(attn.float(), dim=-1).type_as(attn)

	# trim attention lengths according to the learned span
	attn = self.adaptive_span(attn)

	attn = self.dropout(attn) # B x M X L_pos

	attn_cont = _skew(attn, 0) # B x M X (L+M)
	out = torch.matmul(attn_cont, value) # B x M x H
	return out

	def get_cache_size(self):
	return self.adaptive_span.get_cache_size()


	class MultiHeadSeqAttention(nn.Module):
	def __init__(self, d_model, n_head, **kargs):
	nn.Module.__init__(self)
	assert d_model % n_head == 0
	self.n_head = n_head
	self.head_dim = d_model // n_head
	self.attn = SeqAttention(d_model=self.head_dim, n_head=n_head, **kargs)
	self.proj_query = nn.Linear(d_model, d_model, bias=False)
	nn.init.xavier_normal_(self.proj_query.weight)
	self.proj_out = nn.Linear(d_model, d_model, bias=False)
	nn.init.xavier_normal_(self.proj_out.weight)
	self.proj_val = nn.Linear(d_model, d_model, bias=False)
	nn.init.xavier_normal_(self.proj_val.weight)
	self.proj_key = nn.Linear(d_model, d_model, bias=False)
	nn.init.xavier_normal_(self.proj_key.weight)

	def head_reshape(self, x):
	K = self.n_head
	D = self.head_dim
	x = x.view(x.size()[:-1] + (K, D)) # B x (M+L) x K x D
	x = x.transpose(1, 2).contiguous() # B x K x (M+L) x D
	x = x.view(-1, x.size(-2), x.size(-1)) # B_K x (M+L) x D
	return x

	def forward(self, query, key, value, key_pe):
	B = query.size(0)
	K = self.n_head
	D = self.head_dim
	M = query.size(1)

	query = self.proj_query(query)
	query = self.head_reshape(query)
	value = self.proj_val(value)
	value = self.head_reshape(value)
	key = self.proj_key(key)
	key = self.head_reshape(key)

	out = self.attn(query, key, value, key_pe) # B_K x M x D
	out = out.view(B, K, M, D) # B x K x M x D
	out = out.transpose(1, 2).contiguous() # B x M x K x D
	out = out.view(B, M, -1) # B x M x K_D
	out = self.proj_out(out)
	return out


	class FeedForwardLayer(nn.Module):
	def __init__(self, d_model, d_inner, dropout, **kargs):
	nn.Module.__init__(self)
	self.fc1 = nn.Linear(d_model, d_inner)
	self.fc2 = nn.Linear(d_inner, d_model)
	nn.init.xavier_uniform_(self.fc1.weight)
	nn.init.xavier_uniform_(self.fc2.weight)
	self.dropout = nn.Dropout(dropout)

	def forward(self, h):
	h1 = F.relu(self.fc1(h))
	h1 = self.dropout(h1)
	h2 = self.fc2(h1)
	return h2


	class TransformerSeqLayer(nn.Module):
	def __init__(self, d_model, **kargs):
	nn.Module.__init__(self)
	self.attn = MultiHeadSeqAttention(d_model=d_model, **kargs)
	self.norm1 = LayerNorm(d_model)
	self.ff = FeedForwardLayer(d_model=d_model, **kargs)
	self.norm2 = LayerNorm(d_model)

	def forward(self, h, h_cache, key_pe):
	# h = B x M x H
	# h_cache = B x L x H
	h_all = torch.cat([h_cache, h], dim=1) # B x (M+L) x H
	attn_out = self.attn(h, h_all, h_all, key_pe)
	h = self.norm1(h + attn_out) # B x M x H
	if self.ff is not None:
	ff_out = self.ff(h)
	out = self.norm2(h + ff_out) # B x M x H
	else:
	out = h
	return out

	def get_cache_size(self):
	return self.attn.attn.get_cache_size()


	class TransformerSeq(nn.Module):
	def __init__(
	self,
	vocab_size,
	d_model,
	n_head,
	n_layer,
	attn_span,
	emb_dropout,
	aux_loss_scaler,
	adapt_span_layer,
	**kargs
	):
	nn.Module.__init__(self)
	# token embeddings
	self.in_emb = nn.Embedding(vocab_size, d_model)
	nn.init.normal_(self.in_emb.weight, mean=0, std=d_model ** -0.5)
	self.out_emb = nn.Linear(d_model, vocab_size)
	self.aux_loss_scaler = aux_loss_scaler
	if emb_dropout > 0:
	self.emb_dropout = nn.Dropout(emb_dropout)
	else:
	self.emb_dropout = None
	# position embeddings
	self.key_pe = nn.Parameter(torch.randn(1, d_model // n_head, attn_span))

	self.layers = nn.ModuleList()
	self.layers.extend(
	TransformerSeqLayer(
	d_model=d_model,
	n_head=n_head,
	attn_span=attn_span,
	adapt_span_layer=adapt_span_layer,
	**kargs
	)
	for _ in range(n_layer)
	)

	def forward(self, x, h_cache, target=None):
	# x size = B x M
	block_size = x.size(1)
	h = self.in_emb(x) # B x M x H
	if self.emb_dropout is not None:
	h = self.emb_dropout(h)

	h_cache_next = []
	for l, layer in enumerate(self.layers):
	cache_size = layer.attn.attn.get_cache_size()
	if cache_size > block_size:
	h_cache_next_l = torch.cat(
	[h_cache[l][:, -cache_size + block_size :, :], h], dim=1
	).detach()
	else:
	h_cache_next_l = h[:, -cache_size:, :].detach()
	h_cache_next.append(h_cache_next_l)
	h = layer(h, h_cache[l], self.key_pe) # B x M x H

	if self.emb_dropout is not None:
	h = self.emb_dropout(h)

	out = F.log_softmax(self.out_emb(h).float(), dim=-1).type_as(h)
	dummy_loss = None

	return out, h_cache_next, dummy_loss

	def get_aux_loss(self):
	loss = 0.0
	for layer in self.layers:
	loss += layer.attn.attn.adaptive_span.get_loss()
	return self.aux_loss_scaler * loss

	def get_current_max_span(self):
	max_span = 0.0
	for layer in self.layers:
	max_span = max(
	max_span, layer.attn.attn.adaptive_span.get_current_max_span()
	)
	return max_span

	def get_current_avg_span(self):
	avg_span = 0.0
	for layer in self.layers:
	avg_span += layer.attn.attn.adaptive_span.get_current_avg_span()
	return avg_span / len(self.layers)