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MMOCR / mmocr /models /textrecog /decoders /robust_scanner_decoder.py

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	# Copyright (c) OpenMMLab. All rights reserved.
	import torch
	import torch.nn as nn
	import torch.nn.functional as F

	from mmocr.models.builder import DECODERS, build_decoder
	from mmocr.models.textrecog.layers import RobustScannerFusionLayer
	from .base_decoder import BaseDecoder


	@DECODERS.register_module()
	class RobustScannerDecoder(BaseDecoder):
	"""Decoder for RobustScanner.

	RobustScanner: `RobustScanner: Dynamically Enhancing Positional Clues for
	Robust Text Recognition <https://arxiv.org/abs/2007.07542>`_

	Args:
	num_classes (int): Number of output classes :math:`C`.
	dim_input (int): Dimension :math:`D_i` of input vector ``feat``.
	dim_model (int): Dimension :math:`D_m` of the model. Should also be the
	same as encoder output vector ``out_enc``.
	max_seq_len (int): Maximum output sequence length :math:`T`.
	start_idx (int): The index of `<SOS>`.
	mask (bool): Whether to mask input features according to
	``img_meta['valid_ratio']``.
	padding_idx (int): The index of `<PAD>`.
	encode_value (bool): Whether to use the output of encoder ``out_enc``
	as `value` of attention layer. If False, the original feature
	``feat`` will be used.
	hybrid_decoder (dict): Configuration dict for hybrid decoder.
	position_decoder (dict): Configuration dict for position decoder.
	init_cfg (dict or list[dict], optional): Initialization configs.

	Warning:
	This decoder will not predict the final class which is assumed to be
	`<PAD>`. Therefore, its output size is always :math:`C - 1`. `<PAD>`
	is also ignored by loss as specified in
	:obj:`mmocr.models.textrecog.recognizer.EncodeDecodeRecognizer`.
	"""

	def __init__(self,
	num_classes=None,
	dim_input=512,
	dim_model=128,
	max_seq_len=40,
	start_idx=0,
	mask=True,
	padding_idx=None,
	encode_value=False,
	hybrid_decoder=None,
	position_decoder=None,
	init_cfg=None):
	super().__init__(init_cfg=init_cfg)
	self.num_classes = num_classes
	self.dim_input = dim_input
	self.dim_model = dim_model
	self.max_seq_len = max_seq_len
	self.encode_value = encode_value
	self.start_idx = start_idx
	self.padding_idx = padding_idx
	self.mask = mask

	# init hybrid decoder
	hybrid_decoder.update(num_classes=self.num_classes)
	hybrid_decoder.update(dim_input=self.dim_input)
	hybrid_decoder.update(dim_model=self.dim_model)
	hybrid_decoder.update(start_idx=self.start_idx)
	hybrid_decoder.update(padding_idx=self.padding_idx)
	hybrid_decoder.update(max_seq_len=self.max_seq_len)
	hybrid_decoder.update(mask=self.mask)
	hybrid_decoder.update(encode_value=self.encode_value)
	hybrid_decoder.update(return_feature=True)

	self.hybrid_decoder = build_decoder(hybrid_decoder)

	# init position decoder
	position_decoder.update(num_classes=self.num_classes)
	position_decoder.update(dim_input=self.dim_input)
	position_decoder.update(dim_model=self.dim_model)
	position_decoder.update(max_seq_len=self.max_seq_len)
	position_decoder.update(mask=self.mask)
	position_decoder.update(encode_value=self.encode_value)
	position_decoder.update(return_feature=True)

	self.position_decoder = build_decoder(position_decoder)

	self.fusion_module = RobustScannerFusionLayer(
	self.dim_model if encode_value else dim_input)

	pred_num_classes = num_classes - 1
	self.prediction = nn.Linear(dim_model if encode_value else dim_input,
	pred_num_classes)

	def forward_train(self, feat, out_enc, targets_dict, img_metas):
	"""
	Args:
	feat (Tensor): Tensor of shape :math:`(N, D_i, H, W)`.
	out_enc (Tensor): Encoder output of shape
	:math:`(N, D_m, H, W)`.
	targets_dict (dict): A dict with the key ``padded_targets``, a
	tensor of shape :math:`(N, T)`. Each element is the index of a
	character.
	img_metas (dict): A dict that contains meta information of input
	images. Preferably with the key ``valid_ratio``.

	Returns:
	Tensor: A raw logit tensor of shape :math:`(N, T, C-1)`.
	"""
	hybrid_glimpse = self.hybrid_decoder.forward_train(
	feat, out_enc, targets_dict, img_metas)
	position_glimpse = self.position_decoder.forward_train(
	feat, out_enc, targets_dict, img_metas)

	fusion_out = self.fusion_module(hybrid_glimpse, position_glimpse)

	out = self.prediction(fusion_out)

	return out

	def forward_test(self, feat, out_enc, img_metas):
	"""
	Args:
	feat (Tensor): Tensor of shape :math:`(N, D_i, H, W)`.
	out_enc (Tensor): Encoder output of shape
	:math:`(N, D_m, H, W)`.
	img_metas (dict): A dict that contains meta information of input
	images. Preferably with the key ``valid_ratio``.

	Returns:
	Tensor: The output logit sequence tensor of shape
	:math:`(N, T, C-1)`.
	"""
	seq_len = self.max_seq_len
	batch_size = feat.size(0)

	decode_sequence = (feat.new_ones(
	(batch_size, seq_len)) * self.start_idx).long()

	position_glimpse = self.position_decoder.forward_test(
	feat, out_enc, img_metas)

	outputs = []
	for i in range(seq_len):
	hybrid_glimpse_step = self.hybrid_decoder.forward_test_step(
	feat, out_enc, decode_sequence, i, img_metas)

	fusion_out = self.fusion_module(hybrid_glimpse_step,
	position_glimpse[:, i, :])

	char_out = self.prediction(fusion_out)
	char_out = F.softmax(char_out, -1)
	outputs.append(char_out)
	_, max_idx = torch.max(char_out, dim=1, keepdim=False)
	if i < seq_len - 1:
	decode_sequence[:, i + 1] = max_idx

	outputs = torch.stack(outputs, 1)

	return outputs