# Copyright (c) 2018 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. import unittest import paddle.fluid as fluid import paddle import contextlib import math import numpy as np import sys import os def convolution_net(data, label, input_dim, class_dim=2, emb_dim=32, hid_dim=32): emb = fluid.layers.embedding(input=data, size=[input_dim, emb_dim], is_sparse=True) conv_3 = fluid.nets.sequence_conv_pool(input=emb, num_filters=hid_dim, filter_size=3, act="tanh", pool_type="sqrt") conv_4 = fluid.nets.sequence_conv_pool(input=emb, num_filters=hid_dim, filter_size=4, act="tanh", pool_type="sqrt") prediction = fluid.layers.fc(input=[conv_3, conv_4], size=class_dim, act="softmax") cost = fluid.layers.cross_entropy(input=prediction, label=label) avg_cost = paddle.mean(cost) accuracy = fluid.layers.accuracy(input=prediction, label=label) return avg_cost, accuracy, prediction def dyn_rnn_lstm(data, label, input_dim, class_dim=2, emb_dim=32, lstm_size=128): emb = fluid.layers.embedding(input=data, size=[input_dim, emb_dim], is_sparse=True) sentence = fluid.layers.fc(input=emb, size=lstm_size, act='tanh') rnn = fluid.layers.DynamicRNN() with rnn.block(): word = rnn.step_input(sentence) prev_hidden = rnn.memory(value=0.0, shape=[lstm_size]) prev_cell = rnn.memory(value=0.0, shape=[lstm_size]) def gate_common(ipt, hidden, size): gate0 = fluid.layers.fc(input=ipt, size=size, bias_attr=True) gate1 = fluid.layers.fc(input=hidden, size=size, bias_attr=False) return gate0 + gate1 forget_gate = fluid.layers.sigmoid( x=gate_common(word, prev_hidden, lstm_size)) input_gate = fluid.layers.sigmoid( x=gate_common(word, prev_hidden, lstm_size)) output_gate = fluid.layers.sigmoid( x=gate_common(word, prev_hidden, lstm_size)) cell_gate = fluid.layers.sigmoid( x=gate_common(word, prev_hidden, lstm_size)) cell = forget_gate * prev_cell + input_gate * cell_gate hidden = output_gate * fluid.layers.tanh(x=cell) rnn.update_memory(prev_cell, cell) rnn.update_memory(prev_hidden, hidden) rnn.output(hidden) last = fluid.layers.sequence_last_step(rnn()) prediction = fluid.layers.fc(input=last, size=class_dim, act="softmax") cost = fluid.layers.cross_entropy(input=prediction, label=label) avg_cost = paddle.mean(cost) accuracy = fluid.layers.accuracy(input=prediction, label=label) return avg_cost, accuracy, prediction def stacked_lstm_net(data, label, input_dim, class_dim=2, emb_dim=128, hid_dim=512, stacked_num=3): assert stacked_num % 2 == 1 emb = fluid.layers.embedding(input=data, size=[input_dim, emb_dim], is_sparse=True) # add bias attr # TODO(qijun) linear act fc1 = fluid.layers.fc(input=emb, size=hid_dim) lstm1, cell1 = fluid.layers.dynamic_lstm(input=fc1, size=hid_dim) inputs = [fc1, lstm1] for i in range(2, stacked_num + 1): fc = fluid.layers.fc(input=inputs, size=hid_dim) lstm, cell = fluid.layers.dynamic_lstm(input=fc, size=hid_dim, is_reverse=(i % 2) == 0) inputs = [fc, lstm] fc_last = fluid.layers.sequence_pool(input=inputs[0], pool_type='max') lstm_last = fluid.layers.sequence_pool(input=inputs[1], pool_type='max') prediction = fluid.layers.fc(input=[fc_last, lstm_last], size=class_dim, act='softmax') cost = fluid.layers.cross_entropy(input=prediction, label=label) avg_cost = paddle.mean(cost) accuracy = fluid.layers.accuracy(input=prediction, label=label) return avg_cost, accuracy, prediction def train(word_dict, net_method, use_cuda, parallel=False, save_dirname=None, is_local=True): BATCH_SIZE = 128 PASS_NUM = 5 dict_dim = len(word_dict) class_dim = 2 data = fluid.layers.data(name="words", shape=[1], dtype="int64", lod_level=1) label = fluid.layers.data(name="label", shape=[1], dtype="int64") if not parallel: cost, acc_out, prediction = net_method(data, label, input_dim=dict_dim, class_dim=class_dim) else: raise NotImplementedError() adagrad = fluid.optimizer.Adagrad(learning_rate=0.002) adagrad.minimize(cost) train_data = paddle.batch(paddle.reader.shuffle( paddle.dataset.imdb.train(word_dict), buf_size=1000), batch_size=BATCH_SIZE) place = fluid.CUDAPlace(0) if use_cuda else fluid.CPUPlace() exe = fluid.Executor(place) feeder = fluid.DataFeeder(feed_list=[data, label], place=place) def train_loop(main_program): exe.run(fluid.default_startup_program()) for pass_id in range(PASS_NUM): for data in train_data(): cost_val, acc_val = exe.run(main_program, feed=feeder.feed(data), fetch_list=[cost, acc_out]) print("cost=" + str(cost_val) + " acc=" + str(acc_val)) if cost_val < 0.4 and acc_val > 0.8: if save_dirname is not None: fluid.io.save_inference_model(save_dirname, ["words"], prediction, exe) return if math.isnan(float(cost_val)): sys.exit("got NaN loss, training failed.") raise AssertionError("Cost is too large for {0}".format( net_method.__name__)) if is_local: train_loop(fluid.default_main_program()) else: port = os.getenv("PADDLE_PSERVER_PORT", "6174") pserver_ips = os.getenv("PADDLE_PSERVER_IPS") # ip,ip... eplist = [] for ip in pserver_ips.split(","): eplist.append(':'.join([ip, port])) pserver_endpoints = ",".join(eplist) # ip:port,ip:port... trainers = int(os.getenv("PADDLE_TRAINERS")) current_endpoint = os.getenv("POD_IP") + ":" + port trainer_id = int(os.getenv("PADDLE_TRAINER_ID")) training_role = os.getenv("PADDLE_TRAINING_ROLE", "TRAINER") t = fluid.DistributeTranspiler() t.transpile(trainer_id, pservers=pserver_endpoints, trainers=trainers) if training_role == "PSERVER": pserver_prog = t.get_pserver_program(current_endpoint) pserver_startup = t.get_startup_program(current_endpoint, pserver_prog) exe.run(pserver_startup) exe.run(pserver_prog) elif training_role == "TRAINER": train_loop(t.get_trainer_program()) def infer(word_dict, use_cuda, save_dirname=None): if save_dirname is None: return place = fluid.CUDAPlace(0) if use_cuda else fluid.CPUPlace() exe = fluid.Executor(place) inference_scope = fluid.core.Scope() with fluid.scope_guard(inference_scope): # Use fluid.io.load_inference_model to obtain the inference program desc, # the feed_target_names (the names of variables that will be fed # data using feed operators), and the fetch_targets (variables that # we want to obtain data from using fetch operators). [inference_program, feed_target_names, fetch_targets] = fluid.io.load_inference_model(save_dirname, exe) word_dict_len = len(word_dict) # Setup input by creating LoDTensor to represent sequence of words. # Here each word is the basic element of the LoDTensor and the shape of # each word (base_shape) should be [1] since it is simply an index to # look up for the corresponding word vector. # Suppose the recursive_sequence_lengths info is set to [[3, 4, 2]], # which has only one level of detail. Then the created LoDTensor will have only # one higher level structure (sequence of words, or sentence) than the basic # element (word). Hence the LoDTensor will hold data for three sentences of # length 3, 4 and 2, respectively. # Note that recursive_sequence_lengths should be a list of lists. recursive_seq_lens = [[3, 4, 2]] base_shape = [1] # The range of random integers is [low, high] tensor_words = fluid.create_random_int_lodtensor(recursive_seq_lens, base_shape, place, low=0, high=word_dict_len - 1) # Construct feed as a dictionary of {feed_target_name: feed_target_data} # and results will contain a list of data corresponding to fetch_targets. assert feed_target_names[0] == "words" results = exe.run(inference_program, feed={feed_target_names[0]: tensor_words}, fetch_list=fetch_targets, return_numpy=False) print(results[0].recursive_sequence_lengths()) np_data = np.array(results[0]) print("Inference Shape: ", np_data.shape) print("Inference results: ", np_data) def main(word_dict, net_method, use_cuda, parallel=False, save_dirname=None): if use_cuda and not fluid.core.is_compiled_with_cuda(): return train(word_dict, net_method, use_cuda, parallel=parallel, save_dirname=save_dirname) infer(word_dict, use_cuda, save_dirname) class TestUnderstandSentiment(unittest.TestCase): @classmethod def setUpClass(cls): cls.word_dict = paddle.dataset.imdb.word_dict() @contextlib.contextmanager def new_program_scope(self): prog = fluid.Program() startup_prog = fluid.Program() scope = fluid.core.Scope() with fluid.scope_guard(scope): with fluid.program_guard(prog, startup_prog): yield def test_conv_cpu(self): with self.new_program_scope(): main(self.word_dict, net_method=convolution_net, use_cuda=False, save_dirname="understand_sentiment_conv.inference.model") def test_conv_cpu_parallel(self): with self.new_program_scope(): main(self.word_dict, net_method=convolution_net, use_cuda=False, parallel=True) @unittest.skip(reason="make CI faster") def test_stacked_lstm_cpu(self): with self.new_program_scope(): main( self.word_dict, net_method=stacked_lstm_net, use_cuda=False, save_dirname="understand_sentiment_stacked_lstm.inference.model" ) def test_stacked_lstm_cpu_parallel(self): with self.new_program_scope(): main(self.word_dict, net_method=stacked_lstm_net, use_cuda=False, parallel=True) def test_conv_gpu(self): with self.new_program_scope(): main(self.word_dict, net_method=convolution_net, use_cuda=True, save_dirname="understand_sentiment_conv.inference.model") def test_conv_gpu_parallel(self): with self.new_program_scope(): main(self.word_dict, net_method=convolution_net, use_cuda=True, parallel=True) @unittest.skip(reason="make CI faster") def test_stacked_lstm_gpu(self): with self.new_program_scope(): main( self.word_dict, net_method=stacked_lstm_net, use_cuda=True, save_dirname="understand_sentiment_stacked_lstm.inference.model" ) def test_stacked_lstm_gpu_parallel(self): with self.new_program_scope(): main(self.word_dict, net_method=stacked_lstm_net, use_cuda=True, parallel=True) @unittest.skip(reason='make CI faster') def test_dynrnn_lstm_gpu(self): with self.new_program_scope(): main(self.word_dict, net_method=dyn_rnn_lstm, use_cuda=True, parallel=False) def test_dynrnn_lstm_gpu_parallel(self): with self.new_program_scope(): main(self.word_dict, net_method=dyn_rnn_lstm, use_cuda=True, parallel=True) if __name__ == '__main__': unittest.main()