import unittest import numpy as np from gradient_checker import GradientChecker, create_op from op_test_util import OpTestMeta class TestConv2dOp(unittest.TestCase): __metaclass__ = OpTestMeta def setUp(self): self.type = "conv2d" batch_size = 2 input_channels = 3 input_height = 5 input_width = 5 output_channels = 6 filter_height = 3 filter_width = 3 stride = 1 padding = 0 output_height = (input_height - filter_height + 2 * padding ) / stride + 1 output_width = (input_width - filter_width + 2 * padding) / stride + 1 input = np.random.random((batch_size, input_channels, input_height, input_width)).astype("float32") filter = np.random.random( (output_channels, input_channels, filter_height, filter_width)).astype("float32") output = np.ndarray( (batch_size, output_channels, output_height, output_width)) for batchid in xrange(batch_size): for channelid in xrange(output_channels): for rowid in xrange(output_height): for colid in xrange(output_width): start_h = (rowid * stride) - padding start_w = (colid * stride) - padding output_value = 0.0 for inchannelid in xrange(input_channels): for frowid in xrange(filter_height): for fcolid in xrange(filter_width): input_value = 0.0 inrowid = start_h + frowid incolid = start_w + fcolid if ((inrowid >= 0 and inrowid < input_height) and (incolid >= 0 and incolid < input_width)): input_value = input[batchid][ inchannelid][inrowid][incolid] filter_value = filter[channelid][ inchannelid][frowid][fcolid] output_value += input_value * filter_value output[batchid][channelid][rowid][colid] = output_value self.inputs = {'Input': input, 'Filter': filter} self.outputs = {'Output': output} self.attrs = {'strides': [1, 1], 'paddings': [0, 0]} if __name__ == '__main__': unittest.main()