# 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 os import re import time from random import random from functools import reduce, partial import logging import numpy as np import multiprocessing import paddle import paddle.fluid as F import paddle.fluid.layers as L from propeller import log import propeller.paddle as propeller from propeller.paddle.data import Dataset from optimization import optimization import utils.data log.setLevel(logging.DEBUG) class ClassificationBowModel(propeller.train.Model): """propeller Model wraper for paddle-ERNIE """ def __init__(self, config, mode, run_config): self.config = config self.mode = mode self.run_config = run_config self._param_initializer = F.initializer.TruncatedNormal( scale=config.initializer_range) self._emb_dtype = "float32" self._word_emb_name = "word_embedding" def forward(self, features): text_ids_a, = features def bow(ids): embed = L.embedding( input=ids, size=[self.config.vocab_size, self.config.emb_size], dtype=self._emb_dtype, param_attr=F.ParamAttr( name=self._word_emb_name, initializer=self._param_initializer), is_sparse=False) zero = L.fill_constant(shape=[1], dtype='int64', value=0) pad = L.cast(L.logical_not(L.equal(ids, zero)), 'float32') sumed = L.reduce_sum(embed * pad, dim=1) sumed = L.softsign(sumed) return sumed sumed = bow(text_ids_a) fced = L.fc( input=sumed, size=self.config.emb_size, act='tanh', param_attr=F.ParamAttr( name="middle_fc.w_0", initializer=self._param_initializer), bias_attr="middle_fc.b_0") logits = L.fc( input=fced, size=self.config.num_label, act=None, param_attr=F.ParamAttr( name="pooler_fc.w_0", initializer=self._param_initializer), bias_attr="pooler_fc.b_0") if self.mode is propeller.RunMode.PREDICT: probs = L.softmax(logits) return probs else: return logits def loss(self, predictions, labels): labels = L.softmax(labels) loss = L.softmax_with_cross_entropy(predictions, labels, soft_label=True) loss = L.mean(loss) return loss def backward(self, loss): scheduled_lr, _ = optimization( loss=loss, warmup_steps=int(self.run_config.max_steps * self.config.warmup_proportion), num_train_steps=self.run_config.max_steps, learning_rate=self.config.learning_rate, train_program=F.default_main_program(), startup_prog=F.default_startup_program(), weight_decay=self.config.weight_decay, scheduler="linear_warmup_decay",) propeller.summary.scalar('lr', scheduled_lr) def metrics(self, predictions, labels): predictions = L.argmax(predictions, axis=1) labels = L.argmax(labels, axis=1) #predictions = L.unsqueeze(predictions, axes=[1]) acc = propeller.metrics.Acc(labels, predictions) #auc = propeller.metrics.Auc(labels, predictions) return {'acc': acc} if __name__ == '__main__': parser = propeller.ArgumentParser('DAN model with Paddle') parser.add_argument('--max_seqlen', type=int, default=128) parser.add_argument('--vocab_file', type=str, required=True) parser.add_argument('--unsupervise_data_dir', type=str, required=True) parser.add_argument('--data_dir', type=str) args = parser.parse_args() run_config = propeller.parse_runconfig(args) hparams = propeller.parse_hparam(args) vocab = {j.strip().split(b'\t')[0].decode('utf8'): i for i, j in enumerate(open(args.vocab_file, 'rb'))} unk_id = vocab['[UNK]'] char_tokenizer = utils.data.CharTokenizer(vocab.keys()) space_tokenizer = utils.data.SpaceTokenizer(vocab.keys()) supervise_feature_column = propeller.data.FeatureColumns([ propeller.data.TextColumn('text_a', unk_id=unk_id, vocab_dict=vocab, tokenizer=space_tokenizer), propeller.data.LabelColumn('label'), ]) def before(text_a, label): sentence_a = text_a[: args.max_seqlen] return sentence_a, label def after(sentence_a, label): batch_size = sentence_a.shape[0] onehot_label = np.zeros([batch_size, hparams.num_label], dtype=np.float32) onehot_label[np.arange(batch_size), label] = 9999. sentence_a, = utils.data.expand_dims(sentence_a) return sentence_a, onehot_label train_ds = supervise_feature_column.build_dataset('train', data_dir=os.path.join(args.data_dir, 'train'), shuffle=True, repeat=True, use_gz=False) \ .map(before) \ .padded_batch(hparams.batch_size, (0, 0)) \ .map(after) \ unsup_train_ds = supervise_feature_column.build_dataset('unsup_train', data_dir=args.unsupervise_data_dir, shuffle=True, repeat=True, use_gz=False) \ .map(before) \ .padded_batch(hparams.batch_size, (0, 0)) \ .map(after) dev_ds = supervise_feature_column.build_dataset('dev', data_dir=os.path.join(args.data_dir, 'dev'), shuffle=False, repeat=False, use_gz=False) \ .map(before) \ .padded_batch(hparams.batch_size, (0, 0)) \ .map(after) train_ds = utils.data.interleave(train_ds, unsup_train_ds) shapes = ([-1, args.max_seqlen, 1], [-1, hparams.num_label]) types = ('int64', 'float32') train_ds.data_shapes = shapes train_ds.data_types = types dev_ds.data_shapes = shapes dev_ds.data_types = types ''' from tqdm import tqdm for slots in tqdm(train_ds): pass ''' best_exporter = propeller.train.exporter.BestExporter(os.path.join(run_config.model_dir, 'best'), cmp_fn=lambda old, new: new['dev']['acc'] > old['dev']['acc']) propeller.train.train_and_eval( model_class_or_model_fn=ClassificationBowModel, params=hparams, run_config=run_config, train_dataset=train_ds, eval_dataset={'dev': dev_ds}, exporters=[best_exporter]) print('dev_acc3\t%.5f' % (best_exporter._best['dev']['acc']))