def test_get_layer(self):
pixel = layer.data(name='pixel2', type=data_type.dense_vector(784))
label = layer.data(name='label2', type=data_type.integer_value(10))
hidden = layer.fc(input=pixel,
size=100,
act=conf_helps.SigmoidActivation())
inference = layer.fc(input=hidden,
size=10,
act=conf_helps.SoftmaxActivation())
cost = layer.classification_cost(input=inference, label=label)
topo = topology.Topology(cost)
pixel_layer = topo.get_layer("pixel2")
label_layer = topo.get_layer("label2")
self.assertEqual(pixel_layer, pixel)
self.assertEqual(label_layer, label)
def test_parse(self):
pixel = layer.data(name='pixel3', type=data_type.dense_vector(784))
label = layer.data(name='label3', type=data_type.integer_value(10))
hidden = layer.fc(input=pixel,
size=100,
act=conf_helps.SigmoidActivation())
inference = layer.fc(input=hidden,
size=10,
act=conf_helps.SoftmaxActivation())
maxid = layer.max_id(input=inference)
cost1 = layer.classification_cost(input=inference, label=label)
cost2 = layer.cross_entropy_cost(input=inference, label=label)
topology.Topology(cost2).proto()
topology.Topology([cost1]).proto()
topology.Topology([cost1, cost2]).proto()
topology.Topology([inference, maxid]).proto()
def test_data_type(self):
pixel = layer.data(name='pixel', type=data_type.dense_vector(784))
label = layer.data(name='label', type=data_type.integer_value(10))
hidden = layer.fc(input=pixel,
size=100,
act=conf_helps.SigmoidActivation())
inference = layer.fc(input=hidden,
size=10,
act=conf_helps.SoftmaxActivation())
cost = layer.classification_cost(input=inference, label=label)
topo = topology.Topology(cost)
data_types = topo.data_type()
self.assertEqual(len(data_types), 2)
pixel_data_type = filter(lambda type: type[0] == "pixel", data_types)
self.assertEqual(len(pixel_data_type), 1)
pixel_data_type = pixel_data_type[0]
self.assertEqual(pixel_data_type[1].type, pydp2.DataType.Dense)
self.assertEqual(pixel_data_type[1].dim, 784)
label_data_type = filter(lambda type: type[0] == "label", data_types)
self.assertEqual(len(label_data_type), 1)
label_data_type = label_data_type[0]
self.assertEqual(label_data_type[1].type, pydp2.DataType.Index)
self.assertEqual(label_data_type[1].dim, 10)
return V2LayerImpl
data = __convert_to_v2__('data_layer', None, [])
fc = __convert_to_v2__('fc_layer', name_prefix='fc', parent_names=['input'])
max_id = __convert_to_v2__('maxid_layer',
name_prefix='maxid_layer',
parent_names=['input'])
classification_cost = __convert_to_v2__('classification_cost',
name_prefix='classification_cost',
parent_names=['input', 'label'])
cross_entropy_cost = __convert_to_v2__('cross_entropy',
name_prefix='cross_entropy',
parent_names=['input', 'label'])
if __name__ == '__main__':
pixel = data(name='pixel', size=784)
label = data(name='label', size=10)
hidden = fc(input=pixel, size=100, act=conf_helps.SigmoidActivation())
inference = fc(input=hidden, size=10, act=conf_helps.SoftmaxActivation())
maxid = max_id(input=inference)
cost1 = classification_cost(input=inference, label=label)
cost2 = cross_entropy_cost(input=inference, label=label)
print parse_network(cost1)
print parse_network(cost2)
print parse_network(cost1, cost2)
print parse_network(cost2)
print parse_network(inference, maxid)
padding=1,
stride=1,
num_channels=1,
num_filters=6,
filter_size=5,
act=paddle.LinearActivation())
pool_1 = paddle.img_pool_layer(input=conv_1,
stride=2,
pool_size=2,
pool_type=paddle.MaxPooling())
conv_2 = paddle.img_conv_layer(input=pool_1,
stride=1,
num_filters=16,
filter_size=5,
act=paddle.LinearActivation())
pool_2 = paddle.img_pool_layer(input=conv_2,
stride=2,
pool_size=2,
pool_type=paddle.MaxPooling())
fc_1 = paddle.fc_layer(input=pool_2, size=500, act=paddle.SigmoidActivation())
fc_2 = paddle.fc_layer(input=fc_1, size=10, act=paddle.SoftmaxActivation())
label = paddle.data_layer(name='label', size=10)
cost = paddle.classification_cost(input=fc_2, label=label)
paddle.outputs(cost)