# Copyright (c) 2019 PaddlePaddle Authors. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. from __future__ import print_function import paddle.fluid as fluid import paddle.fluid.layers.ops as ops from paddle.fluid.initializer import init_on_cpu from paddle.fluid.layers.learning_rate_scheduler import _decay_step_counter from simple_nets import init_data import math import os os.environ['CPU_NUM'] = str(4) # FIXME(zcd): If the neural net has dropout_op, the output of ParallelExecutor # and Executor is different. Because, for ParallelExecutor, the dropout_op of # the neural net will be copied N copies(N is the number of device). This will # lead to the random numbers generated by ParallelExecutor and Executor are different. # So, if we compare the loss of ParallelExecutor and Executor, we should remove the # dropout_op. remove_dropout = False # FIXME(zcd): If the neural net has batch_norm, the output of ParallelExecutor # and Executor is different. remove_bn = False remove_dropout = True remove_bn = True def squeeze_excitation(input, num_channels, reduction_ratio): # pool = fluid.layers.pool2d( # input=input, pool_size=0, pool_type='avg', global_pooling=True) conv = input shape = conv.shape reshape = fluid.layers.reshape( x=conv, shape=[-1, shape[1], shape[2] * shape[3]]) pool = fluid.layers.reduce_mean(input=reshape, dim=2) squeeze = fluid.layers.fc(input=pool, size=num_channels // reduction_ratio, act='relu') excitation = fluid.layers.fc(input=squeeze, size=num_channels, act='sigmoid') scale = fluid.layers.elementwise_mul(x=input, y=excitation, axis=0) return scale def conv_bn_layer(input, num_filters, filter_size, stride=1, groups=1, act=None): conv = fluid.layers.conv2d( input=input, num_filters=num_filters, filter_size=filter_size, stride=stride, padding=(filter_size - 1) // 2, groups=groups, act=None, bias_attr=False) return conv if remove_bn else fluid.layers.batch_norm( input=conv, act=act, momentum=0.1) def shortcut(input, ch_out, stride): ch_in = input.shape[1] if ch_in != ch_out: if stride == 1: filter_size = 1 else: filter_size = 3 return conv_bn_layer(input, ch_out, filter_size, stride) else: return input def bottleneck_block(input, num_filters, stride, cardinality, reduction_ratio): # The number of first 1x1 convolutional channels for each bottleneck build block # was halved to reduce the compution cost. conv0 = conv_bn_layer( input=input, num_filters=num_filters, filter_size=1, act='relu') conv1 = conv_bn_layer( input=conv0, num_filters=num_filters * 2, filter_size=3, stride=stride, groups=cardinality, act='relu') conv2 = conv_bn_layer( input=conv1, num_filters=num_filters * 2, filter_size=1, act=None) scale = squeeze_excitation( input=conv2, num_channels=num_filters * 2, reduction_ratio=reduction_ratio) short = shortcut(input, num_filters * 2, stride) return fluid.layers.elementwise_add(x=short, y=scale, act='relu') img_shape = [3, 224, 224] def SE_ResNeXt50Small(use_feed): img = fluid.layers.data(name='image', shape=img_shape, dtype='float32') label = fluid.layers.data(name='label', shape=[1], dtype='int64') conv = conv_bn_layer( input=img, num_filters=16, filter_size=3, stride=2, act='relu') conv = conv_bn_layer( input=conv, num_filters=16, filter_size=3, stride=1, act='relu') conv = conv_bn_layer( input=conv, num_filters=16, filter_size=3, stride=1, act='relu') conv = fluid.layers.pool2d( input=conv, pool_size=3, pool_stride=2, pool_padding=1, pool_type='max') cardinality = 32 reduction_ratio = 16 depth = [3, 4, 6, 3] num_filters = [128, 256, 512, 1024] for block in range(len(depth)): for i in range(depth[block]): conv = bottleneck_block( input=conv, num_filters=num_filters[block], stride=2 if i == 0 and block != 0 else 1, cardinality=cardinality, reduction_ratio=reduction_ratio) shape = conv.shape reshape = fluid.layers.reshape( x=conv, shape=[-1, shape[1], shape[2] * shape[3]]) pool = fluid.layers.reduce_mean(input=reshape, dim=2) dropout = pool if remove_dropout else fluid.layers.dropout( x=pool, dropout_prob=0.2, seed=1) # Classifier layer: prediction = fluid.layers.fc(input=dropout, size=1000, act='softmax') loss = fluid.layers.cross_entropy(input=prediction, label=label) loss = fluid.layers.mean(loss) return loss def cosine_decay(learning_rate, step_each_epoch, epochs=120): """ Applies cosine decay to the learning rate. lr = 0.05 * (math.cos(epoch * (math.pi / 120)) + 1) """ global_step = _decay_step_counter() with init_on_cpu(): epoch = ops.floor(global_step / step_each_epoch) decayed_lr = learning_rate * \ (ops.cos(epoch * (math.pi / epochs)) + 1)/2 return decayed_lr def optimizer(learning_rate=0.01): optimizer = fluid.optimizer.Momentum( learning_rate=cosine_decay( learning_rate=learning_rate, step_each_epoch=2, epochs=1), momentum=0.9, regularization=fluid.regularizer.L2Decay(1e-4)) return optimizer model = SE_ResNeXt50Small def batch_size(): return 12 def iter(use_cuda): if use_cuda: return 10 return 2 gpu_img, gpu_label = init_data( batch_size=batch_size(), img_shape=img_shape, label_range=999) cpu_img, cpu_label = init_data( batch_size=batch_size(), img_shape=img_shape, label_range=999) feed_dict_gpu = {"image": gpu_img, "label": gpu_label} feed_dict_cpu = {"image": cpu_img, "label": cpu_label} def feed_dict(use_cuda): if use_cuda: return feed_dict_gpu return feed_dict_cpu