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documents-restoration / data /MBD /stn_model /tps_spatial_transformer.py

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	from __future__ import absolute_import

	import numpy as np
	import itertools

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

	def grid_sample(input, grid, canvas = None):
	output = F.grid_sample(input, grid)
	if canvas is None:
	return output
	else:
	input_mask = input.data.new(input.size()).fill_(1)
	output_mask = F.grid_sample(input_mask, grid)
	padded_output = output * output_mask + canvas * (1 - output_mask)
	return padded_output


	# phi(x1, x2) = r^2 * log(r), where r = \|\|x1 - x2\|\|_2
	def compute_partial_repr(input_points, control_points):
	N = input_points.size(0)
	M = control_points.size(0)
	pairwise_diff = input_points.view(N, 1, 2) - control_points.view(1, M, 2)
	# original implementation, very slow
	# pairwise_dist = torch.sum(pairwise_diff ** 2, dim = 2) # square of distance
	pairwise_diff_square = pairwise_diff * pairwise_diff
	pairwise_dist = pairwise_diff_square[:, :, 0] + pairwise_diff_square[:, :, 1]
	repr_matrix = 0.5 * pairwise_dist * torch.log(pairwise_dist)
	# fix numerical error for 0 * log(0), substitute all nan with 0
	mask = repr_matrix != repr_matrix
	repr_matrix.masked_fill_(mask, 0)
	return repr_matrix


	# # output_ctrl_pts are specified, according to our task.
	# def build_output_control_points(num_control_points, margins):
	# margin_x, margin_y = margins
	# margin_x, margin_y = 0,0
	# num_ctrl_pts_per_side = num_control_points // 2
	# ctrl_pts_x = np.linspace(margin_x, 1.0 - margin_x, num_ctrl_pts_per_side)
	# ctrl_pts_y_top = np.ones(num_ctrl_pts_per_side) * margin_y
	# ctrl_pts_y_bottom = np.ones(num_ctrl_pts_per_side) * (1.0 - margin_y)
	# ctrl_pts_top = np.stack([ctrl_pts_x, ctrl_pts_y_top], axis=1)
	# ctrl_pts_bottom = np.stack([ctrl_pts_x, ctrl_pts_y_bottom], axis=1)
	# # ctrl_pts_top = ctrl_pts_top[1:-1,:]
	# # ctrl_pts_bottom = ctrl_pts_bottom[1:-1,:]
	# output_ctrl_pts_arr = np.concatenate([ctrl_pts_top, ctrl_pts_bottom], axis=0)
	# output_ctrl_pts = torch.Tensor(output_ctrl_pts_arr)
	# return output_ctrl_pts

	# output_ctrl_pts are specified, according to our task.
	def build_output_control_points(num_control_points, margins):
	margin_x, margin_y = margins
	# margin_x, margin_y = 0,0
	num_ctrl_pts_per_side = (num_control_points-4) // 4 +2
	ctrl_pts_x = np.linspace(margin_x, 1.0 - margin_x, num_ctrl_pts_per_side)
	ctrl_pts_y_top = np.ones(num_ctrl_pts_per_side) * margin_y
	ctrl_pts_y_bottom = np.ones(num_ctrl_pts_per_side) * (1.0 - margin_y)
	ctrl_pts_top = np.stack([ctrl_pts_x, ctrl_pts_y_top], axis=1)
	ctrl_pts_bottom = np.stack([ctrl_pts_x, ctrl_pts_y_bottom], axis=1)

	ctrl_pts_x_left = np.ones(num_ctrl_pts_per_side) * margin_x
	ctrl_pts_x_right = np.ones(num_ctrl_pts_per_side) * (1.0-margin_x)
	ctrl_pts_left = np.stack([ctrl_pts_x_left[1:-1], ctrl_pts_x[1:-1]], axis=1)
	ctrl_pts_right = np.stack([ctrl_pts_x_right[1:-1], ctrl_pts_x[1:-1]], axis=1)

	output_ctrl_pts_arr = np.concatenate([ctrl_pts_top, ctrl_pts_bottom, ctrl_pts_left, ctrl_pts_right], axis=0)
	output_ctrl_pts = torch.Tensor(output_ctrl_pts_arr)
	return output_ctrl_pts

	# demo: ~/test/models/test_tps_transformation.py
	class TPSSpatialTransformer(nn.Module):

	def __init__(self, output_image_size=None, num_control_points=None, margins=None):
	super(TPSSpatialTransformer, self).__init__()
	self.output_image_size = output_image_size
	self.num_control_points = num_control_points
	self.margins = margins

	self.target_height, self.target_width = output_image_size
	target_control_points = build_output_control_points(num_control_points, margins)
	N = num_control_points
	# N = N - 4

	# create padded kernel matrix
	forward_kernel = torch.zeros(N + 3, N + 3)
	target_control_partial_repr = compute_partial_repr(target_control_points, target_control_points)
	forward_kernel[:N, :N].copy_(target_control_partial_repr)
	forward_kernel[:N, -3].fill_(1)
	forward_kernel[-3, :N].fill_(1)
	forward_kernel[:N, -2:].copy_(target_control_points)
	forward_kernel[-2:, :N].copy_(target_control_points.transpose(0, 1))
	# compute inverse matrix
	# print(forward_kernel.shape)
	inverse_kernel = torch.inverse(forward_kernel)

	# create target cordinate matrix
	HW = self.target_height * self.target_width
	target_coordinate = list(itertools.product(range(self.target_height), range(self.target_width)))
	target_coordinate = torch.Tensor(target_coordinate) # HW x 2
	Y, X = target_coordinate.split(1, dim = 1)
	Y = Y / (self.target_height - 1)
	X = X / (self.target_width - 1)
	target_coordinate = torch.cat([X, Y], dim = 1) # convert from (y, x) to (x, y)
	target_coordinate_partial_repr = compute_partial_repr(target_coordinate, target_control_points)
	target_coordinate_repr = torch.cat([
	target_coordinate_partial_repr, torch.ones(HW, 1), target_coordinate
	], dim = 1)

	# register precomputed matrices
	self.register_buffer('inverse_kernel', inverse_kernel)
	self.register_buffer('padding_matrix', torch.zeros(3, 2))
	self.register_buffer('target_coordinate_repr', target_coordinate_repr)
	self.register_buffer('target_control_points', target_control_points)

	def forward(self, input, source_control_points,direction='dewarp'):
	if direction == 'dewarp':
	assert source_control_points.ndimension() == 3
	assert source_control_points.size(1) == self.num_control_points
	assert source_control_points.size(2) == 2
	batch_size = source_control_points.size(0)

	Y = torch.cat([source_control_points, self.padding_matrix.expand(batch_size, 3, 2)], 1)
	mapping_matrix = torch.matmul(self.inverse_kernel, Y)
	source_coordinate = torch.matmul(self.target_coordinate_repr, mapping_matrix)

	grid = source_coordinate.view(-1, self.target_height, self.target_width, 2)
	grid = torch.clamp(grid, 0, 1) # the source_control_points may be out of [0, 1].
	# the input to grid_sample is normalized [-1, 1], but what we get is [0, 1]
	grid = 2.0 * grid - 1.0
	output_maps = grid_sample(input, grid, canvas=None)
	return output_maps, source_coordinate

	# elif direction == 'warp':
	# target_control_points = source_control_points.clone()
	# source_control_points = (build_output_control_points(self.num_control_points, self.margins)).clone()
	# source_control_points = source_control_points.unsqueeze(0)
	# source_control_points = source_control_points.expand(target_control_points.size(0),self.num_control_points,2)
	# assert source_control_points.ndimension() == 3
	# assert source_control_points.size(1) == self.num_control_points
	# assert source_control_points.size(2) == 2
	# batch_size = source_control_points.size(0)

	# Y = torch.cat([source_control_points.to('cuda'), self.padding_matrix.expand(batch_size, 3, 2)], 1)
	# mapping_matrix = torch.matmul(self.inverse_kernel, Y)
	# source_coordinate = torch.matmul(self.target_coordinate_repr, mapping_matrix)

	# grid = source_coordinate.view(-1, self.target_height, self.target_width, 2)
	# grid = torch.clamp(grid, 0, 1) # the source_control_points may be out of [0, 1].
	# # the input to grid_sample is normalized [-1, 1], but what we get is [0, 1]
	# grid = 2.0 * grid - 1.0
	# output_maps = grid_sample(input, grid, canvas=None)
	# return output_maps, source_coordinate