dist_transformer.py 61.8 KB
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#   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.

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from __future__ import print_function

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import numpy as np
import argparse
import time
import math
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import os
import sys
import six
import argparse
import ast
import multiprocessing
import time
from functools import partial
from os.path import expanduser
import glob
import random
import tarfile
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import paddle
import paddle.fluid as fluid
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import paddle.fluid.layers as layers
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from paddle.fluid import core
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from test_dist_base import TestDistRunnerBase, runtime_main, RUN_STEP
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import paddle.compat as cpt
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from paddle.compat import long_type

import hashlib

const_para_attr = fluid.ParamAttr(initializer=fluid.initializer.Constant(0.001))
const_bias_attr = const_para_attr
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# Fix seed for test
fluid.default_startup_program().random_seed = 1
fluid.default_main_program().random_seed = 1


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#from transformer_config import ModelHyperParams, TrainTaskConfig, merge_cfg_from_list
class TrainTaskConfig(object):
    # only support GPU currently
    use_gpu = True
    # the epoch number to train.
    pass_num = 1
    # the number of sequences contained in a mini-batch.
    # deprecated, set batch_size in args.
    batch_size = 20
    # the hyper parameters for Adam optimizer.
    # This static learning_rate will be multiplied to the LearningRateScheduler
    # derived learning rate the to get the final learning rate.
    learning_rate = 1
    beta1 = 0.9
    beta2 = 0.98
    eps = 1e-9
    # the parameters for learning rate scheduling.
    warmup_steps = 4000
    # the weight used to mix up the ground-truth distribution and the fixed
    # uniform distribution in label smoothing when training.
    # Set this as zero if label smoothing is not wanted.
    label_smooth_eps = 0.1
    # the directory for saving trained models.
    model_dir = "trained_models"
    # the directory for saving checkpoints.
    ckpt_dir = "trained_ckpts"
    # the directory for loading checkpoint.
    # If provided, continue training from the checkpoint.
    ckpt_path = None
    # the parameter to initialize the learning rate scheduler.
    # It should be provided if use checkpoints, since the checkpoint doesn't
    # include the training step counter currently.
    start_step = 0
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    check_acc = True
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    data_path = expanduser("~") + (
        "/.cache/paddle/dataset/test_dist_transformer/")
    src_vocab_fpath = data_path + "vocab.bpe.32000"
    trg_vocab_fpath = data_path + "vocab.bpe.32000"
    train_file_pattern = data_path + "train.tok.clean.bpe.32000.en-de"
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    val_file_pattern = data_path + "newstest2013.tok.bpe.32000.en-de.cut"
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    pool_size = 2000
    sort_type = None
    local = True
    shuffle = False
    shuffle_batch = False
    special_token = ['<s>', '<e>', '<unk>']
    token_delimiter = ' '
    use_token_batch = False
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class InferTaskConfig(object):
    use_gpu = True
    # the number of examples in one run for sequence generation.
    batch_size = 10
    # the parameters for beam search.
    beam_size = 5
    max_out_len = 256
    # the number of decoded sentences to output.
    n_best = 1
    # the flags indicating whether to output the special tokens.
    output_bos = False
    output_eos = False
    output_unk = True
    # the directory for loading the trained model.
    model_path = "trained_models/pass_1.infer.model"
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class ModelHyperParams(object):
    # These following five vocabularies related configurations will be set
    # automatically according to the passed vocabulary path and special tokens.
    # size of source word dictionary.
    src_vocab_size = 10000
    # size of target word dictionay
    trg_vocab_size = 10000
    # index for <bos> token
    bos_idx = 0
    # index for <eos> token
    eos_idx = 1
    # index for <unk> token
    unk_idx = 2
    # max length of sequences deciding the size of position encoding table.
    # Start from 1 and count start and end tokens in.
    max_length = 256
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    # the dimension for word embeddings, which is also the last dimension of
    # the input and output of multi-head attention, position-wise feed-forward
    # networks, encoder and decoder.
    d_model = 512
    # size of the hidden layer in position-wise feed-forward networks.
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    d_inner_hid = 2048
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    # the dimension that keys are projected to for dot-product attention.
    d_key = 64
    # the dimension that values are projected to for dot-product attention.
    d_value = 64
    # number of head used in multi-head attention.
    n_head = 8
    # number of sub-layers to be stacked in the encoder and decoder.
    n_layer = 6
    # dropout rate used by all dropout layers.
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    dropout = 0.0  # no random
    # random seed used in dropout for CE.
    dropout_seed = None
    # the flag indicating whether to share embedding and softmax weights.
    # vocabularies in source and target should be same for weight sharing.
    weight_sharing = True
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def merge_cfg_from_list(cfg_list, g_cfgs):
    """
    Set the above global configurations using the cfg_list.
    """
    assert len(cfg_list) % 2 == 0
    for key, value in zip(cfg_list[0::2], cfg_list[1::2]):
        for g_cfg in g_cfgs:
            if hasattr(g_cfg, key):
                try:
                    value = eval(value)
                except Exception:  # for file path
                    pass
                setattr(g_cfg, key, value)
                break


# The placeholder for batch_size in compile time. Must be -1 currently to be
# consistent with some ops' infer-shape output in compile time, such as the
# sequence_expand op used in beamsearch decoder.
batch_size = -1
# The placeholder for squence length in compile time.
seq_len = ModelHyperParams.max_length
# Here list the data shapes and data types of all inputs.
# The shapes here act as placeholder and are set to pass the infer-shape in
# compile time.
input_descs = {
    # The actual data shape of src_word is:
    # [batch_size * max_src_len_in_batch, 1]
    "src_word": [(batch_size, seq_len, long_type(1)), "int64", 2],
    # The actual data shape of src_pos is:
    # [batch_size * max_src_len_in_batch, 1]
    "src_pos": [(batch_size, seq_len, long_type(1)), "int64"],
    # This input is used to remove attention weights on paddings in the
    # encoder.
    # The actual data shape of src_slf_attn_bias is:
    # [batch_size, n_head, max_src_len_in_batch, max_src_len_in_batch]
    "src_slf_attn_bias": [(batch_size, ModelHyperParams.n_head, seq_len,
                           seq_len), "float32"],
    # The actual data shape of trg_word is:
    # [batch_size * max_trg_len_in_batch, 1]
    "trg_word": [(batch_size, seq_len, long_type(1)), "int64",
                 2],  # lod_level is only used in fast decoder.
    # The actual data shape of trg_pos is:
    # [batch_size * max_trg_len_in_batch, 1]
    "trg_pos": [(batch_size, seq_len, long_type(1)), "int64"],
    # This input is used to remove attention weights on paddings and
    # subsequent words in the decoder.
    # The actual data shape of trg_slf_attn_bias is:
    # [batch_size, n_head, max_trg_len_in_batch, max_trg_len_in_batch]
    "trg_slf_attn_bias": [(batch_size, ModelHyperParams.n_head, seq_len,
                           seq_len), "float32"],
    # This input is used to remove attention weights on paddings of the source
    # input in the encoder-decoder attention.
    # The actual data shape of trg_src_attn_bias is:
    # [batch_size, n_head, max_trg_len_in_batch, max_src_len_in_batch]
    "trg_src_attn_bias": [(batch_size, ModelHyperParams.n_head, seq_len,
                           seq_len), "float32"],
    # This input is used in independent decoder program for inference.
    # The actual data shape of enc_output is:
    # [batch_size, max_src_len_in_batch, d_model]
    "enc_output": [(batch_size, seq_len, ModelHyperParams.d_model), "float32"],
    # The actual data shape of label_word is:
    # [batch_size * max_trg_len_in_batch, 1]
    "lbl_word": [(batch_size * seq_len, long_type(1)), "int64"],
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    # This input is used to mask out the loss of padding tokens.
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    # The actual data shape of label_weight is:
    # [batch_size * max_trg_len_in_batch, 1]
    "lbl_weight": [(batch_size * seq_len, long_type(1)), "float32"],
    # These inputs are used to change the shape tensor in beam-search decoder.
    "trg_slf_attn_pre_softmax_shape_delta": [(long_type(2), ), "int32"],
    "trg_slf_attn_post_softmax_shape_delta": [(long_type(4), ), "int32"],
    "init_score": [(batch_size, long_type(1)), "float32"],
}

# Names of word embedding table which might be reused for weight sharing.
word_emb_param_names = (
    "src_word_emb_table",
    "trg_word_emb_table", )
# Names of position encoding table which will be initialized externally.
pos_enc_param_names = (
    "src_pos_enc_table",
    "trg_pos_enc_table", )
# separated inputs for different usages.
encoder_data_input_fields = (
    "src_word",
    "src_pos",
    "src_slf_attn_bias", )
decoder_data_input_fields = (
    "trg_word",
    "trg_pos",
    "trg_slf_attn_bias",
    "trg_src_attn_bias",
    "enc_output", )
label_data_input_fields = (
    "lbl_word",
    "lbl_weight", )
# In fast decoder, trg_pos (only containing the current time step) is generated
# by ops and trg_slf_attn_bias is not needed.
fast_decoder_data_input_fields = (
    "trg_word",
    "init_score",
    "trg_src_attn_bias", )

# fast_decoder_util_input_fields = (
#     "trg_slf_attn_pre_softmax_shape_delta",
#     "trg_slf_attn_post_softmax_shape_delta", )


#from optim import LearningRateScheduler
class LearningRateScheduler(object):
    """
    Wrapper for learning rate scheduling as described in the Transformer paper.
    LearningRateScheduler adapts the learning rate externally and the adapted
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    learning rate will be fed into the main_program as input data.
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    """

    def __init__(self,
                 d_model,
                 warmup_steps,
                 learning_rate=0.001,
                 current_steps=0,
                 name="learning_rate"):
        self.current_steps = current_steps
        self.warmup_steps = warmup_steps
        self.d_model = d_model
        self.static_lr = learning_rate
        self.learning_rate = layers.create_global_var(
            name=name,
            shape=[1],
            value=float(learning_rate),
            dtype="float32",
            persistable=True)

    def update_learning_rate(self):
        self.current_steps += 1
        lr_value = np.power(self.d_model, -0.5) * np.min([
            np.power(self.current_steps, -0.5),
            np.power(self.warmup_steps, -1.5) * self.current_steps
        ]) * self.static_lr
        return np.array([lr_value], dtype="float32")


#from transformer_train import train_loop
def pad_batch_data(insts,
                   pad_idx,
                   n_head,
                   is_target=False,
                   is_label=False,
                   return_attn_bias=True,
                   return_max_len=True,
                   return_num_token=False):
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    """
    Pad the instances to the max sequence length in batch, and generate the
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    corresponding position data and attention bias.
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    """
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    return_list = []
    max_len = max(len(inst) for inst in insts)
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    num_token = six.moves.reduce(
        lambda x, y: x + y,
        [len(inst) for inst in insts]) if return_num_token else 0
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    # Any token included in dict can be used to pad, since the paddings' loss
    # will be masked out by weights and make no effect on parameter gradients.
    inst_data = np.array(
        [inst + [pad_idx] * (max_len - len(inst)) for inst in insts])
    return_list += [inst_data.astype("int64").reshape([-1, 1])]
    if is_label:  # label weight
        inst_weight = np.array(
            [[1.] * len(inst) + [0.] * (max_len - len(inst)) for inst in insts])
        return_list += [inst_weight.astype("float32").reshape([-1, 1])]
    else:  # position data
        inst_pos = np.array([
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            list(range(1, len(inst) + 1)) + [0] * (max_len - len(inst))
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            for inst in insts
        ])
        return_list += [inst_pos.astype("int64").reshape([-1, 1])]
    if return_attn_bias:
        if is_target:
            # This is used to avoid attention on paddings and subsequent
            # words.
            slf_attn_bias_data = np.ones((inst_data.shape[0], max_len, max_len))
            slf_attn_bias_data = np.triu(slf_attn_bias_data,
                                         1).reshape([-1, 1, max_len, max_len])
            slf_attn_bias_data = np.tile(slf_attn_bias_data,
                                         [1, n_head, 1, 1]) * [-1e9]
        else:
            # This is used to avoid attention on paddings.
            slf_attn_bias_data = np.array([[0] * len(inst) + [-1e9] *
                                           (max_len - len(inst))
                                           for inst in insts])
            slf_attn_bias_data = np.tile(
                slf_attn_bias_data.reshape([-1, 1, 1, max_len]),
                [1, n_head, max_len, 1])
        return_list += [slf_attn_bias_data.astype("float32")]
    if return_max_len:
        return_list += [max_len]
    if return_num_token:
        return_list += [num_token]
    return return_list if len(return_list) > 1 else return_list[0]


def prepare_batch_input(insts, data_input_names, src_pad_idx, trg_pad_idx,
                        n_head, d_model):
    """
    Put all padded data needed by training into a dict.
    """
    src_word, src_pos, src_slf_attn_bias, src_max_len = pad_batch_data(
        [inst[0] for inst in insts], src_pad_idx, n_head, is_target=False)
    src_word = src_word.reshape(-1, src_max_len, 1)
    src_pos = src_pos.reshape(-1, src_max_len, 1)
    trg_word, trg_pos, trg_slf_attn_bias, trg_max_len = pad_batch_data(
        [inst[1] for inst in insts], trg_pad_idx, n_head, is_target=True)
    trg_word = trg_word.reshape(-1, trg_max_len, 1)
    trg_pos = trg_pos.reshape(-1, trg_max_len, 1)
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    trg_src_attn_bias = np.tile(src_slf_attn_bias[:, :, ::src_max_len, :],
                                [1, 1, trg_max_len, 1]).astype("float32")

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    lbl_word, lbl_weight, num_token = pad_batch_data(
        [inst[2] for inst in insts],
        trg_pad_idx,
        n_head,
        is_target=False,
        is_label=True,
        return_attn_bias=False,
        return_max_len=False,
        return_num_token=True)

    data_input_dict = dict(
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        list(
            zip(data_input_names, [
                src_word, src_pos, src_slf_attn_bias, trg_word, trg_pos,
                trg_slf_attn_bias, trg_src_attn_bias, lbl_word, lbl_weight
            ])))
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    return data_input_dict, np.asarray([num_token], dtype="float32")


def read_multiple(reader, count, clip_last=True):
    """
    Stack data from reader for multi-devices.
    """

    def __impl__():
        res = []
        for item in reader():
            res.append(item)
            if len(res) == count:
                yield res
                res = []
        if len(res) == count:
            yield res
        elif not clip_last:
            data = []
            for item in res:
                data += item
            if len(data) > count:
                inst_num_per_part = len(data) // count
                yield [
                    data[inst_num_per_part * i:inst_num_per_part * (i + 1)]
                    for i in range(count)
                ]

    return __impl__


def split_data(data, num_part):
    """
    Split data for each device.
    """
    if len(data) == num_part:
        return data
    data = data[0]
    inst_num_per_part = len(data) // num_part
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    return [
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        data[inst_num_per_part * i:inst_num_per_part * (i + 1)]
        for i in range(num_part)
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    ]


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def test_context(test_program, avg_cost, train_exe, dev_count, data_input_names,
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                 sum_cost, token_num):
    val_data = DataReader(
        src_vocab_fpath=TrainTaskConfig.src_vocab_fpath,
        trg_vocab_fpath=TrainTaskConfig.trg_vocab_fpath,
        fpattern=TrainTaskConfig.val_file_pattern,
        token_delimiter=TrainTaskConfig.token_delimiter,
        use_token_batch=TrainTaskConfig.use_token_batch,
        batch_size=TrainTaskConfig.batch_size *
        (1 if TrainTaskConfig.use_token_batch else dev_count),
        pool_size=TrainTaskConfig.pool_size,
        sort_type=TrainTaskConfig.sort_type,
        start_mark=TrainTaskConfig.special_token[0],
        end_mark=TrainTaskConfig.special_token[1],
        unk_mark=TrainTaskConfig.special_token[2],
        # count start and end tokens out
        max_length=ModelHyperParams.max_length - 2,
        clip_last_batch=False,
        shuffle=False,
        shuffle_batch=False)

    build_strategy = fluid.BuildStrategy()

    strategy = fluid.ExecutionStrategy()
    strategy.num_threads = 1

    test_exe = fluid.ParallelExecutor(
        use_cuda=TrainTaskConfig.use_gpu,
        main_program=test_program,
        share_vars_from=train_exe,
        build_strategy=build_strategy,
        exec_strategy=strategy)

    def test(exe=test_exe):
        test_total_cost = 0
        test_total_token = 0
        test_data = read_multiple(
            reader=val_data.batch_generator,
            count=dev_count if TrainTaskConfig.use_token_batch else 1)
        for batch_id, data in enumerate(test_data()):
            feed_list = []
            for place_id, data_buffer in enumerate(
                    split_data(
                        data, num_part=dev_count)):
                data_input_dict, _ = prepare_batch_input(
                    data_buffer, data_input_names, ModelHyperParams.eos_idx,
                    ModelHyperParams.eos_idx, ModelHyperParams.n_head,
                    ModelHyperParams.d_model)
                feed_list.append(data_input_dict)

            outs = exe.run(feed=feed_list,
                           fetch_list=[sum_cost.name, token_num.name])
            sum_cost_val, token_num_val = np.array(outs[0]), np.array(outs[1])
            test_total_cost += sum_cost_val.sum()
            test_total_token += token_num_val.sum()
        test_avg_cost = test_total_cost / test_total_token
        test_ppl = np.exp([min(test_avg_cost, 100)])
        return test_avg_cost, test_ppl

    return test


def train_loop(exe, train_progm, dev_count, sum_cost, avg_cost, lr_scheduler,
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               token_num, predict, test_program):
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    # Initialize the parameters.
    if TrainTaskConfig.ckpt_path:
        lr_scheduler.current_steps = TrainTaskConfig.start_step
    else:
        exe.run(fluid.framework.default_startup_program())

    train_data = DataReader(
        src_vocab_fpath=TrainTaskConfig.src_vocab_fpath,
        trg_vocab_fpath=TrainTaskConfig.trg_vocab_fpath,
        fpattern=TrainTaskConfig.train_file_pattern,
        token_delimiter=TrainTaskConfig.token_delimiter,
        use_token_batch=TrainTaskConfig.use_token_batch,
        batch_size=TrainTaskConfig.batch_size *
        (1 if TrainTaskConfig.use_token_batch else dev_count),
        pool_size=TrainTaskConfig.pool_size,
        sort_type=TrainTaskConfig.sort_type,
        shuffle=TrainTaskConfig.shuffle,
        shuffle_batch=TrainTaskConfig.shuffle_batch,
        start_mark=TrainTaskConfig.special_token[0],
        end_mark=TrainTaskConfig.special_token[1],
        unk_mark=TrainTaskConfig.special_token[2],
        # count start and end tokens out
        max_length=ModelHyperParams.max_length - 2,
        clip_last_batch=False)
    train_data = read_multiple(
        reader=train_data.batch_generator,
        count=dev_count if TrainTaskConfig.use_token_batch else 1)

    build_strategy = fluid.BuildStrategy()
    # Since the token number differs among devices, customize gradient scale to
    # use token average cost among multi-devices. and the gradient scale is
    # `1 / token_number` for average cost.
    build_strategy.gradient_scale_strategy = fluid.BuildStrategy.GradientScaleStrategy.Customized

    strategy = fluid.ExecutionStrategy()
    strategy.num_threads = 1

    train_exe = fluid.ParallelExecutor(
        use_cuda=TrainTaskConfig.use_gpu,
        loss_name=sum_cost.name,
        main_program=train_progm,
        build_strategy=build_strategy,
        exec_strategy=strategy)

    data_input_names = encoder_data_input_fields + decoder_data_input_fields[:
                                                                             -1] + label_data_input_fields

    if TrainTaskConfig.val_file_pattern is not None:
550
        test = test_context(test_program, avg_cost, train_exe, dev_count,
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                            data_input_names, sum_cost, token_num)

    # the best cross-entropy value with label smoothing
    loss_normalizer = -((1. - TrainTaskConfig.label_smooth_eps) * np.log(
        (1. - TrainTaskConfig.label_smooth_eps
         )) + TrainTaskConfig.label_smooth_eps *
                        np.log(TrainTaskConfig.label_smooth_eps / (
                            ModelHyperParams.trg_vocab_size - 1) + 1e-20))
    init = False
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    for pass_id in six.moves.xrange(TrainTaskConfig.pass_num):
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        pass_start_time = time.time()
        for batch_id, data in enumerate(train_data()):
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            if batch_id >= RUN_STEP:
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                break

            feed_list = []
            total_num_token = 0

            if TrainTaskConfig.local:
                lr_rate = lr_scheduler.update_learning_rate()

            for place_id, data_buffer in enumerate(
                    split_data(
                        data, num_part=dev_count)):
                data_input_dict, num_token = prepare_batch_input(
                    data_buffer, data_input_names, ModelHyperParams.eos_idx,
                    ModelHyperParams.eos_idx, ModelHyperParams.n_head,
                    ModelHyperParams.d_model)
                total_num_token += num_token
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                feed_kv_pairs = list(data_input_dict.items())
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                if TrainTaskConfig.local:
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                    feed_kv_pairs += list({
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                        lr_scheduler.learning_rate.name: lr_rate
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                    }.items())
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                feed_list.append(dict(feed_kv_pairs))

                if not init:
                    for pos_enc_param_name in pos_enc_param_names:
                        pos_enc = position_encoding_init(
                            ModelHyperParams.max_length + 1,
                            ModelHyperParams.d_model)
                        feed_list[place_id][pos_enc_param_name] = pos_enc

            if not TrainTaskConfig.check_acc:
                for feed_dict in feed_list:
                    feed_dict[sum_cost.name + "@GRAD"] = 1. / total_num_token
            else:
                b = 100 * TrainTaskConfig.batch_size
                a = np.asarray([b], dtype="float32")
                for feed_dict in feed_list:
                    feed_dict[sum_cost.name + "@GRAD"] = 1. / a

            outs = train_exe.run(fetch_list=[sum_cost.name, token_num.name],
                                 feed=feed_list)

            sum_cost_val, token_num_val = np.array(outs[0]), np.array(outs[1])
            total_sum_cost = sum_cost_val.sum()
            total_token_num = token_num_val.sum()
            total_avg_cost = total_sum_cost / total_token_num

            init = True

            # Validate and save the model for inference.
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            if TrainTaskConfig.val_file_pattern is not None:
                val_avg_cost, val_ppl = test()
                print("[%f]" % val_avg_cost)
            else:
                assert (False)
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#import transformer_reader as reader
class SortType(object):
    GLOBAL = 'global'
    POOL = 'pool'
    NONE = "none"


class Converter(object):
    def __init__(self, vocab, beg, end, unk, delimiter):
        self._vocab = vocab
        self._beg = beg
        self._end = end
        self._unk = unk
        self._delimiter = delimiter

    def __call__(self, sentence):
        return [self._beg] + [
            self._vocab.get(w, self._unk)
            for w in sentence.split(self._delimiter)
        ] + [self._end]


class ComposedConverter(object):
    def __init__(self, converters):
        self._converters = converters

    def __call__(self, parallel_sentence):
        return [
            self._converters[i](parallel_sentence[i])
            for i in range(len(self._converters))
        ]


class SentenceBatchCreator(object):
    def __init__(self, batch_size):
        self.batch = []
        self._batch_size = batch_size

    def append(self, info):
        self.batch.append(info)
        if len(self.batch) == self._batch_size:
            tmp = self.batch
            self.batch = []
            return tmp


class TokenBatchCreator(object):
    def __init__(self, batch_size):
        self.batch = []
        self.max_len = -1
        self._batch_size = batch_size

    def append(self, info):
        cur_len = info.max_len
        max_len = max(self.max_len, cur_len)
        if max_len * (len(self.batch) + 1) > self._batch_size:
            result = self.batch
            self.batch = [info]
            self.max_len = cur_len
            return result
        else:
            self.max_len = max_len
            self.batch.append(info)


class SampleInfo(object):
    def __init__(self, i, max_len, min_len):
        self.i = i
        self.min_len = min_len
        self.max_len = max_len


class MinMaxFilter(object):
    def __init__(self, max_len, min_len, underlying_creator):
        self._min_len = min_len
        self._max_len = max_len
        self._creator = underlying_creator

    def append(self, info):
        if info.max_len > self._max_len or info.min_len < self._min_len:
            return
        else:
            return self._creator.append(info)

    @property
    def batch(self):
        return self._creator.batch


class DataReader(object):
    """
    The data reader loads all data from files and produces batches of data
    in the way corresponding to settings.

    An example of returning a generator producing data batches whose data
    is shuffled in each pass and sorted in each pool:

    ```
    train_data = DataReader(
        src_vocab_fpath='data/src_vocab_file',
        trg_vocab_fpath='data/trg_vocab_file',
        fpattern='data/part-*',
        use_token_batch=True,
        batch_size=2000,
        pool_size=10000,
        sort_type=SortType.POOL,
        shuffle=True,
        shuffle_batch=True,
        start_mark='<s>',
        end_mark='<e>',
        unk_mark='<unk>',
        clip_last_batch=False).batch_generator
    ```

    :param src_vocab_fpath: The path of vocabulary file of source language.
    :type src_vocab_fpath: basestring
    :param trg_vocab_fpath: The path of vocabulary file of target language.
    :type trg_vocab_fpath: basestring
    :param fpattern: The pattern to match data files.
    :type fpattern: basestring
    :param batch_size: The number of sequences contained in a mini-batch.
        or the maximum number of tokens (include paddings) contained in a
        mini-batch.
    :type batch_size: int
    :param pool_size: The size of pool buffer.
    :type pool_size: int
    :param sort_type: The grain to sort by length: 'global' for all
        instances; 'pool' for instances in pool; 'none' for no sort.
    :type sort_type: basestring
    :param clip_last_batch: Whether to clip the last uncompleted batch.
    :type clip_last_batch: bool
    :param tar_fname: The data file in tar if fpattern matches a tar file.
    :type tar_fname: basestring
    :param min_length: The minimum length used to filt sequences.
    :type min_length: int
    :param max_length: The maximum length used to filt sequences.
    :type max_length: int
    :param shuffle: Whether to shuffle all instances.
    :type shuffle: bool
    :param shuffle_batch: Whether to shuffle the generated batches.
    :type shuffle_batch: bool
    :param use_token_batch: Whether to produce batch data according to
        token number.
    :type use_token_batch: bool
    :param field_delimiter: The delimiter used to split source and target in
        each line of data file.
    :type field_delimiter: basestring
    :param token_delimiter: The delimiter used to split tokens in source or
        target sentences.
    :type token_delimiter: basestring
    :param start_mark: The token representing for the beginning of
        sentences in dictionary.
    :type start_mark: basestring
    :param end_mark: The token representing for the end of sentences
        in dictionary.
    :type end_mark: basestring
    :param unk_mark: The token representing for unknown word in dictionary.
    :type unk_mark: basestring
    :param seed: The seed for random.
    :type seed: int
    """

    def __init__(self,
                 src_vocab_fpath,
                 trg_vocab_fpath,
                 fpattern,
                 batch_size,
                 pool_size,
                 sort_type=SortType.GLOBAL,
                 clip_last_batch=True,
                 tar_fname=None,
                 min_length=0,
                 max_length=100,
                 shuffle=True,
                 shuffle_batch=False,
                 use_token_batch=False,
                 field_delimiter="\t",
                 token_delimiter=" ",
                 start_mark="<s>",
                 end_mark="<e>",
                 unk_mark="<unk>",
                 seed=0):
        self._src_vocab = self.load_dict(src_vocab_fpath)
        self._only_src = True
        if trg_vocab_fpath is not None:
            self._trg_vocab = self.load_dict(trg_vocab_fpath)
            self._only_src = False
        self._pool_size = pool_size
        self._batch_size = batch_size
        self._use_token_batch = use_token_batch
        self._sort_type = sort_type
        self._clip_last_batch = clip_last_batch
        self._shuffle = shuffle
        self._shuffle_batch = shuffle_batch
        self._min_length = min_length
        self._max_length = max_length
        self._field_delimiter = field_delimiter
        self._token_delimiter = token_delimiter
        self.load_src_trg_ids(end_mark, fpattern, start_mark, tar_fname,
                              unk_mark)
        self._random = random.Random(x=seed)

    def load_src_trg_ids(self, end_mark, fpattern, start_mark, tar_fname,
                         unk_mark):
        converters = [
            Converter(
                vocab=self._src_vocab,
                beg=self._src_vocab[start_mark],
                end=self._src_vocab[end_mark],
                unk=self._src_vocab[unk_mark],
                delimiter=self._token_delimiter)
        ]
        if not self._only_src:
            converters.append(
                Converter(
                    vocab=self._trg_vocab,
                    beg=self._trg_vocab[start_mark],
                    end=self._trg_vocab[end_mark],
                    unk=self._trg_vocab[unk_mark],
                    delimiter=self._token_delimiter))

        converters = ComposedConverter(converters)

        self._src_seq_ids = []
        self._trg_seq_ids = None if self._only_src else []
        self._sample_infos = []

        for i, line in enumerate(self._load_lines(fpattern, tar_fname)):
            src_trg_ids = converters(line)
            self._src_seq_ids.append(src_trg_ids[0])
            lens = [len(src_trg_ids[0])]
            if not self._only_src:
                self._trg_seq_ids.append(src_trg_ids[1])
                lens.append(len(src_trg_ids[1]))
            self._sample_infos.append(SampleInfo(i, max(lens), min(lens)))

    def _load_lines(self, fpattern, tar_fname):
        fpaths = glob.glob(fpattern)

        if len(fpaths) == 1 and tarfile.is_tarfile(fpaths[0]):
            if tar_fname is None:
                raise Exception("If tar file provided, please set tar_fname.")

            f = tarfile.open(fpaths[0], "r")
            for line in f.extractfile(tar_fname):
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                line = cpt.to_text(line)
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                fields = line.strip("\n").split(self._field_delimiter)
                if (not self._only_src and len(fields) == 2) or (
                        self._only_src and len(fields) == 1):
                    yield fields
        else:
            for fpath in fpaths:
                if not os.path.isfile(fpath):
                    raise IOError("Invalid file: %s" % fpath)

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                with open(fpath, "rb") as f:
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                    for line in f:
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                        line = cpt.to_text(line)
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                        fields = line.strip("\n").split(self._field_delimiter)
                        if (not self._only_src and len(fields) == 2) or (
                                self._only_src and len(fields) == 1):
                            yield fields

    @staticmethod
    def load_dict(dict_path, reverse=False):
        word_dict = {}
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        with open(dict_path, "rb") as fdict:
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            for idx, line in enumerate(fdict):
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                line = cpt.to_text(line)
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                if reverse:
                    word_dict[idx] = line.strip("\n")
                else:
                    word_dict[line.strip("\n")] = idx
        return word_dict

    def batch_generator(self):
        # global sort or global shuffle
        if self._sort_type == SortType.GLOBAL:
            infos = sorted(
                self._sample_infos, key=lambda x: x.max_len, reverse=True)
        else:
            if self._shuffle:
                infos = self._sample_infos
                self._random.shuffle(infos)
            else:
                infos = self._sample_infos

            if self._sort_type == SortType.POOL:
                for i in range(0, len(infos), self._pool_size):
                    infos[i:i + self._pool_size] = sorted(
                        infos[i:i + self._pool_size], key=lambda x: x.max_len)

        # concat batch
        batches = []
        batch_creator = TokenBatchCreator(
            self._batch_size
        ) if self._use_token_batch else SentenceBatchCreator(self._batch_size)
        batch_creator = MinMaxFilter(self._max_length, self._min_length,
                                     batch_creator)

        for info in infos:
            batch = batch_creator.append(info)
            if batch is not None:
                batches.append(batch)

        if not self._clip_last_batch and len(batch_creator.batch) != 0:
            batches.append(batch_creator.batch)

        if self._shuffle_batch:
            self._random.shuffle(batches)

        for batch in batches:
            batch_ids = [info.i for info in batch]

            if self._only_src:
                yield [[self._src_seq_ids[idx]] for idx in batch_ids]
            else:
                yield [(self._src_seq_ids[idx], self._trg_seq_ids[idx][:-1],
                        self._trg_seq_ids[idx][1:]) for idx in batch_ids]


#from transformer_model import transformer
def position_encoding_init(n_position, d_pos_vec):
    """
    Generate the initial values for the sinusoid position encoding table.
    """
    position_enc = np.array([[
        pos / np.power(10000, 2 * (j // 2) / d_pos_vec)
        for j in range(d_pos_vec)
    ] if pos != 0 else np.zeros(d_pos_vec) for pos in range(n_position)])
    position_enc[1:, 0::2] = np.sin(position_enc[1:, 0::2])  # dim 2i
    position_enc[1:, 1::2] = np.cos(position_enc[1:, 1::2])  # dim 2i+1
    return position_enc.astype("float32")


def multi_head_attention(queries,
                         keys,
                         values,
                         attn_bias,
                         d_key,
                         d_value,
                         d_model,
                         n_head=1,
                         dropout_rate=0.,
                         cache=None):
    """
    Multi-Head Attention. Note that attn_bias is added to the logit before
    computing softmax activiation to mask certain selected positions so that
    they will not considered in attention weights.
    """
    if not (len(queries.shape) == len(keys.shape) == len(values.shape) == 3):
        raise ValueError(
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            "Inputs: queries, keys and values should all be 3-D tensors.")
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    def __compute_qkv(queries, keys, values, n_head, d_key, d_value):
        """
        Add linear projection to queries, keys, and values.
        """
        q = layers.fc(input=queries,
                      size=d_key * n_head,
                      num_flatten_dims=2,
                      param_attr=const_para_attr,
                      bias_attr=const_bias_attr)
        k = layers.fc(input=keys,
                      size=d_key * n_head,
                      num_flatten_dims=2,
                      param_attr=const_para_attr,
                      bias_attr=const_bias_attr)
        v = layers.fc(input=values,
                      size=d_value * n_head,
                      num_flatten_dims=2,
                      param_attr=const_para_attr,
                      bias_attr=const_bias_attr)
        return q, k, v

    def __split_heads(x, n_head):
        """
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        Reshape the last dimension of input tensor x so that it becomes two
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        dimensions and then transpose. Specifically, input a tensor with shape
        [bs, max_sequence_length, n_head * hidden_dim] then output a tensor
        with shape [bs, n_head, max_sequence_length, hidden_dim].
        """
        if n_head == 1:
            return x

        hidden_size = x.shape[-1]
        # The value 0 in shape attr means copying the corresponding dimension
        # size of the input as the output dimension size.
        reshaped = layers.reshape(
            x=x, shape=[0, 0, n_head, hidden_size // n_head])

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        # permute the dimensions into:
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        # [batch_size, n_head, max_sequence_len, hidden_size_per_head]
        return layers.transpose(x=reshaped, perm=[0, 2, 1, 3])

    def __combine_heads(x):
        """
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        Transpose and then reshape the last two dimensions of input tensor x
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        so that it becomes one dimension, which is reverse to __split_heads.
        """
        if len(x.shape) == 3: return x
        if len(x.shape) != 4:
            raise ValueError("Input(x) should be a 4-D Tensor.")

        trans_x = layers.transpose(x, perm=[0, 2, 1, 3])
        # The value 0 in shape attr means copying the corresponding dimension
        # size of the input as the output dimension size.
        return layers.reshape(
            x=trans_x,
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            shape=list(map(int, [0, 0, trans_x.shape[2] * trans_x.shape[3]])))
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    def scaled_dot_product_attention(q, k, v, attn_bias, d_model, dropout_rate):
        """
        Scaled Dot-Product Attention
        """
        scaled_q = layers.scale(x=q, scale=d_model**-0.5)
        product = layers.matmul(x=scaled_q, y=k, transpose_y=True)
        if attn_bias:
            product += attn_bias
        weights = layers.softmax(product)
        if dropout_rate:
            weights = layers.dropout(
                weights,
                dropout_prob=dropout_rate,
                seed=ModelHyperParams.dropout_seed,
                is_test=False)
        out = layers.matmul(weights, v)
        return out

    q, k, v = __compute_qkv(queries, keys, values, n_head, d_key, d_value)

    if cache is not None:  # use cache and concat time steps
        k = cache["k"] = layers.concat([cache["k"], k], axis=1)
        v = cache["v"] = layers.concat([cache["v"], v], axis=1)

    q = __split_heads(q, n_head)
    k = __split_heads(k, n_head)
    v = __split_heads(v, n_head)

    ctx_multiheads = scaled_dot_product_attention(q, k, v, attn_bias, d_model,
                                                  dropout_rate)

    out = __combine_heads(ctx_multiheads)

    # Project back to the model size.
    proj_out = layers.fc(input=out,
                         size=d_model,
                         num_flatten_dims=2,
                         param_attr=const_para_attr,
                         bias_attr=const_bias_attr)
    return proj_out


def positionwise_feed_forward(x, d_inner_hid, d_hid):
    """
    Position-wise Feed-Forward Networks.
    This module consists of two linear transformations with a ReLU activation
    in between, which is applied to each position separately and identically.
    """
    hidden = layers.fc(input=x,
                       size=d_inner_hid,
                       num_flatten_dims=2,
                       act="relu",
                       param_attr=const_para_attr,
                       bias_attr=const_bias_attr)
    out = layers.fc(input=hidden,
                    size=d_hid,
                    num_flatten_dims=2,
                    param_attr=const_para_attr,
                    bias_attr=const_bias_attr)
    return out


def pre_post_process_layer(prev_out, out, process_cmd, dropout_rate=0.):
    """
    Add residual connection, layer normalization and droput to the out tensor
    optionally according to the value of process_cmd.
    This will be used before or after multi-head attention and position-wise
    feed-forward networks.
    """
    for cmd in process_cmd:
        if cmd == "a":  # add residual connection
            out = out + prev_out if prev_out else out
        elif cmd == "n":  # add layer normalization
            out = layers.layer_norm(
                out,
                begin_norm_axis=len(out.shape) - 1,
                param_attr=fluid.initializer.Constant(1.),
                bias_attr=fluid.initializer.Constant(0.))
        elif cmd == "d":  # add dropout
            if dropout_rate:
                out = layers.dropout(
                    out,
                    dropout_prob=dropout_rate,
                    seed=ModelHyperParams.dropout_seed,
                    is_test=False)
    return out


pre_process_layer = partial(pre_post_process_layer, None)
post_process_layer = pre_post_process_layer


def prepare_encoder(src_word,
                    src_pos,
                    src_vocab_size,
                    src_emb_dim,
                    src_max_len,
                    dropout_rate=0.,
                    word_emb_param_name=None,
                    pos_enc_param_name=None):
    """Add word embeddings and position encodings.
    The output tensor has a shape of:
    [batch_size, max_src_length_in_batch, d_model].
    This module is used at the bottom of the encoder stacks.
    """
    if TrainTaskConfig.check_acc:
        src_word_emb = layers.embedding(
            src_word,
            size=[src_vocab_size, src_emb_dim],
            param_attr=fluid.ParamAttr(
                name=word_emb_param_name,
                initializer=fluid.initializer.ConstantInitializer(0.001)))
    else:
        src_word_emb = layers.embedding(
            src_word,
            size=[src_vocab_size, src_emb_dim],
            param_attr=fluid.ParamAttr(
                name=word_emb_param_name,
                initializer=fluid.initializer.Normal(0., src_emb_dim**-0.5)))

    src_word_emb = layers.scale(x=src_word_emb, scale=src_emb_dim**0.5)
    src_pos_enc = layers.embedding(
        src_pos,
        size=[src_max_len, src_emb_dim],
        param_attr=fluid.ParamAttr(
            name=pos_enc_param_name,
            trainable=False,
            initializer=fluid.initializer.ConstantInitializer(0.001)))
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    src_pos_enc.stop_gradient = True
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    enc_input = src_word_emb + src_pos_enc
    return layers.dropout(
        enc_input,
        dropout_prob=dropout_rate,
        seed=ModelHyperParams.dropout_seed,
        is_test=False) if dropout_rate else enc_input


prepare_encoder = partial(
    prepare_encoder, pos_enc_param_name=pos_enc_param_names[0])
prepare_decoder = partial(
    prepare_encoder, pos_enc_param_name=pos_enc_param_names[1])


def encoder_layer(enc_input,
                  attn_bias,
                  n_head,
                  d_key,
                  d_value,
                  d_model,
                  d_inner_hid,
                  dropout_rate=0.):
    """The encoder layers that can be stacked to form a deep encoder.
    This module consits of a multi-head (self) attention followed by
    position-wise feed-forward networks and both the two components companied
    with the post_process_layer to add residual connection, layer normalization
    and droput.
    """
    attn_output = multi_head_attention(enc_input, enc_input, enc_input,
                                       attn_bias, d_key, d_value, d_model,
                                       n_head, dropout_rate)
    attn_output = post_process_layer(enc_input, attn_output, "dan",
                                     dropout_rate)
    ffd_output = positionwise_feed_forward(attn_output, d_inner_hid, d_model)
    return post_process_layer(attn_output, ffd_output, "dan", dropout_rate)


def encoder(enc_input,
            attn_bias,
            n_layer,
            n_head,
            d_key,
            d_value,
            d_model,
            d_inner_hid,
            dropout_rate=0.):
    """
    The encoder is composed of a stack of identical layers returned by calling
    encoder_layer.
    """
    for i in range(n_layer):
        enc_output = encoder_layer(enc_input, attn_bias, n_head, d_key, d_value,
                                   d_model, d_inner_hid, dropout_rate)
        enc_input = enc_output
    return enc_output


def decoder_layer(dec_input,
                  enc_output,
                  slf_attn_bias,
                  dec_enc_attn_bias,
                  n_head,
                  d_key,
                  d_value,
                  d_model,
                  d_inner_hid,
                  dropout_rate=0.,
                  cache=None):
    """ The layer to be stacked in decoder part.
    The structure of this module is similar to that in the encoder part except
    a multi-head attention is added to implement encoder-decoder attention.
    """
    slf_attn_output = multi_head_attention(
        dec_input,
        dec_input,
        dec_input,
        slf_attn_bias,
        d_key,
        d_value,
        d_model,
        n_head,
        dropout_rate,
        cache, )
    slf_attn_output = post_process_layer(
        dec_input,
        slf_attn_output,
        "dan",  # residual connection + dropout + layer normalization
        dropout_rate, )
    enc_attn_output = multi_head_attention(
        slf_attn_output,
        enc_output,
        enc_output,
        dec_enc_attn_bias,
        d_key,
        d_value,
        d_model,
        n_head,
        dropout_rate, )
    enc_attn_output = post_process_layer(
        slf_attn_output,
        enc_attn_output,
        "dan",  # residual connection + dropout + layer normalization
        dropout_rate, )
    ffd_output = positionwise_feed_forward(
        enc_attn_output,
        d_inner_hid,
        d_model, )
    dec_output = post_process_layer(
        enc_attn_output,
        ffd_output,
        "dan",  # residual connection + dropout + layer normalization
        dropout_rate, )
    return dec_output
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def decoder(dec_input,
            enc_output,
            dec_slf_attn_bias,
            dec_enc_attn_bias,
            n_layer,
            n_head,
            d_key,
            d_value,
            d_model,
            d_inner_hid,
            dropout_rate=0.,
            caches=None):
    """
    The decoder is composed of a stack of identical decoder_layer layers.
    """
    for i in range(n_layer):
        cache = None
        if caches is not None:
            cache = caches[i]

        dec_output = decoder_layer(
            dec_input,
            enc_output,
            dec_slf_attn_bias,
            dec_enc_attn_bias,
            n_head,
            d_key,
            d_value,
            d_model,
            d_inner_hid,
            dropout_rate,
            cache=cache)
        dec_input = dec_output
    return dec_output


def make_all_inputs(input_fields):
    """
    Define the input data layers for the transformer model.
    """
    inputs = []
    for input_field in input_fields:
        input_var = layers.data(
            name=input_field,
            shape=input_descs[input_field][0],
            dtype=input_descs[input_field][1],
            lod_level=input_descs[input_field][2]
            if len(input_descs[input_field]) == 3 else 0,
            append_batch_size=False)
        inputs.append(input_var)
    return inputs


def transformer(
        src_vocab_size,
        trg_vocab_size,
        max_length,
        n_layer,
        n_head,
        d_key,
        d_value,
        d_model,
        d_inner_hid,
        dropout_rate,
        weight_sharing,
        label_smooth_eps, ):
    if weight_sharing:
        assert src_vocab_size == src_vocab_size, (
            "Vocabularies in source and target should be same for weight sharing."
        )
    enc_inputs = make_all_inputs(encoder_data_input_fields)

    enc_output = wrap_encoder(
        src_vocab_size,
        max_length,
        n_layer,
        n_head,
        d_key,
        d_value,
        d_model,
        d_inner_hid,
        dropout_rate,
        weight_sharing,
        enc_inputs, )

    dec_inputs = make_all_inputs(decoder_data_input_fields[:-1])

    predict = wrap_decoder(
        trg_vocab_size,
        max_length,
        n_layer,
        n_head,
        d_key,
        d_value,
        d_model,
        d_inner_hid,
        dropout_rate,
        weight_sharing,
        dec_inputs,
        enc_output, )

    # Padding index do not contribute to the total loss. The weights is used to
    # cancel padding index in calculating the loss.
    label, weights = make_all_inputs(label_data_input_fields)
    if label_smooth_eps:
        label = layers.label_smooth(
            label=layers.one_hot(
                input=label, depth=trg_vocab_size),
            epsilon=label_smooth_eps)

    cost = layers.softmax_with_cross_entropy(
        logits=layers.reshape(
            predict, shape=[-1, trg_vocab_size]),
        label=label,
        soft_label=True if label_smooth_eps else False)
    weighted_cost = cost * weights
    sum_cost = layers.reduce_sum(weighted_cost)
    token_num = layers.reduce_sum(weights)
    avg_cost = sum_cost / token_num
    avg_cost.stop_gradient = True
    return sum_cost, avg_cost, predict, token_num


def wrap_encoder(src_vocab_size,
                 max_length,
                 n_layer,
                 n_head,
                 d_key,
                 d_value,
                 d_model,
                 d_inner_hid,
                 dropout_rate,
                 weight_sharing,
                 enc_inputs=None):
    """
    The wrapper assembles together all needed layers for the encoder.
    """
    if enc_inputs is None:
        # This is used to implement independent encoder program in inference.
        src_word, src_pos, src_slf_attn_bias = \
            make_all_inputs(encoder_data_input_fields)
    else:
        src_word, src_pos, src_slf_attn_bias = \
            enc_inputs
    enc_input = prepare_encoder(
        src_word,
        src_pos,
        src_vocab_size,
        d_model,
        max_length,
        dropout_rate,
        word_emb_param_name=word_emb_param_names[0])
    enc_output = encoder(enc_input, src_slf_attn_bias, n_layer, n_head, d_key,
                         d_value, d_model, d_inner_hid, dropout_rate)
    return enc_output


def wrap_decoder(trg_vocab_size,
                 max_length,
                 n_layer,
                 n_head,
                 d_key,
                 d_value,
                 d_model,
                 d_inner_hid,
                 dropout_rate,
                 weight_sharing,
                 dec_inputs=None,
                 enc_output=None,
                 caches=None):
    """
    The wrapper assembles together all needed layers for the decoder.
    """
    if dec_inputs is None:
        # This is used to implement independent decoder program in inference.
        trg_word, trg_pos, trg_slf_attn_bias, trg_src_attn_bias, \
        enc_output = make_all_inputs(
            decoder_data_input_fields + decoder_util_input_fields)
    else:
        trg_word, trg_pos, trg_slf_attn_bias, trg_src_attn_bias = dec_inputs

    dec_input = prepare_decoder(
        trg_word,
        trg_pos,
        trg_vocab_size,
        d_model,
        max_length,
        dropout_rate,
        word_emb_param_name=word_emb_param_names[0]
        if weight_sharing else word_emb_param_names[1])
    dec_output = decoder(
        dec_input,
        enc_output,
        trg_slf_attn_bias,
        trg_src_attn_bias,
        n_layer,
        n_head,
        d_key,
        d_value,
        d_model,
        d_inner_hid,
        dropout_rate,
        caches=caches)
    # Return logits for training and probs for inference.
    if weight_sharing:
        predict = layers.matmul(
            x=dec_output,
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            y=fluid.framework._get_var(word_emb_param_names[0]),
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            transpose_y=True)
    else:
        predict = layers.fc(input=dec_output,
                            size=trg_vocab_size,
                            num_flatten_dims=2,
                            param_attr=const_para_attr,
                            bias_attr=const_bias_attr)
    if dec_inputs is None:
        predict = layers.softmax(predict)
    return predict


def fast_decode(
        src_vocab_size,
        trg_vocab_size,
        max_in_len,
        n_layer,
        n_head,
        d_key,
        d_value,
        d_model,
        d_inner_hid,
        dropout_rate,
        weight_sharing,
        beam_size,
        max_out_len,
        eos_idx, ):
    """
    Use beam search to decode. Caches will be used to store states of history
    steps which can make the decoding faster.
    """
    enc_output = wrap_encoder(src_vocab_size, max_in_len, n_layer, n_head,
                              d_key, d_value, d_model, d_inner_hid,
                              dropout_rate, weight_sharing)
    start_tokens, init_scores, trg_src_attn_bias = \
        make_all_inputs(fast_decoder_data_input_fields )

    def beam_search():
        max_len = layers.fill_constant(
            shape=[1], dtype=start_tokens.dtype, value=max_out_len)
        step_idx = layers.fill_constant(
            shape=[1], dtype=start_tokens.dtype, value=0)
        cond = layers.less_than(x=step_idx, y=max_len)
        while_op = layers.While(cond)
        # array states will be stored for each step.
        ids = layers.array_write(
            layers.reshape(start_tokens, (-1, 1)), step_idx)
        scores = layers.array_write(init_scores, step_idx)
        # cell states will be overwrited at each step.
        # caches contains states of history steps to reduce redundant
        # computation in decoder.
        caches = [{
            "k": layers.fill_constant_batch_size_like(
                input=start_tokens,
                shape=[-1, 0, d_model],
                dtype=enc_output.dtype,
                value=0),
            "v": layers.fill_constant_batch_size_like(
                input=start_tokens,
                shape=[-1, 0, d_model],
                dtype=enc_output.dtype,
                value=0)
        } for i in range(n_layer)]
        with while_op.block():
            pre_ids = layers.array_read(array=ids, i=step_idx)
            pre_ids = layers.reshape(pre_ids, (-1, 1, 1))
            pre_scores = layers.array_read(array=scores, i=step_idx)
            # sequence_expand can gather sequences according to lod thus can be
            # used in beam search to sift states corresponding to selected ids.
            pre_src_attn_bias = layers.sequence_expand(
                x=trg_src_attn_bias, y=pre_scores)
            pre_enc_output = layers.sequence_expand(x=enc_output, y=pre_scores)
            pre_caches = [{
                "k": layers.sequence_expand(
                    x=cache["k"], y=pre_scores),
                "v": layers.sequence_expand(
                    x=cache["v"], y=pre_scores),
            } for cache in caches]
            pre_pos = layers.elementwise_mul(
                x=layers.fill_constant_batch_size_like(
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                    input=pre_enc_output,  # can't use pre_ids here since it has lod
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                    value=1,
                    shape=[-1, 1, 1],
                    dtype=pre_ids.dtype),
                y=layers.increment(
                    x=step_idx, value=1.0, in_place=False),
                axis=0)
            logits = wrap_decoder(
                trg_vocab_size,
                max_in_len,
                n_layer,
                n_head,
                d_key,
                d_value,
                d_model,
                d_inner_hid,
                dropout_rate,
                weight_sharing,
                dec_inputs=(pre_ids, pre_pos, None, pre_src_attn_bias),
                enc_output=pre_enc_output,
                caches=pre_caches)
            logits = layers.reshape(logits, (-1, trg_vocab_size))

            topk_scores, topk_indices = layers.topk(
                input=layers.softmax(logits), k=beam_size)
            accu_scores = layers.elementwise_add(
                x=layers.log(topk_scores),
                y=layers.reshape(
                    pre_scores, shape=[-1]),
                axis=0)
            # beam_search op uses lod to distinguish branches.
            topk_indices = layers.lod_reset(topk_indices, pre_ids)
            selected_ids, selected_scores = layers.beam_search(
                pre_ids=pre_ids,
                pre_scores=pre_scores,
                ids=topk_indices,
                scores=accu_scores,
                beam_size=beam_size,
                end_id=eos_idx)

            layers.increment(x=step_idx, value=1.0, in_place=True)
            # update states
            layers.array_write(selected_ids, i=step_idx, array=ids)
            layers.array_write(selected_scores, i=step_idx, array=scores)
            layers.assign(pre_src_attn_bias, trg_src_attn_bias)
            layers.assign(pre_enc_output, enc_output)
            for i in range(n_layer):
                layers.assign(pre_caches[i]["k"], caches[i]["k"])
                layers.assign(pre_caches[i]["v"], caches[i]["v"])
            length_cond = layers.less_than(x=step_idx, y=max_len)
            finish_cond = layers.logical_not(layers.is_empty(x=selected_ids))
            layers.logical_and(x=length_cond, y=finish_cond, out=cond)

        finished_ids, finished_scores = layers.beam_search_decode(
            ids, scores, beam_size=beam_size, end_id=eos_idx)
        return finished_ids, finished_scores

    finished_ids, finished_scores = beam_search()
    return finished_ids, finished_scores


def get_model(is_dist, is_async):
    sum_cost, avg_cost, predict, token_num = transformer(
        ModelHyperParams.src_vocab_size, ModelHyperParams.trg_vocab_size,
        ModelHyperParams.max_length + 1, ModelHyperParams.n_layer,
        ModelHyperParams.n_head, ModelHyperParams.d_key,
        ModelHyperParams.d_value, ModelHyperParams.d_model,
        ModelHyperParams.d_inner_hid, ModelHyperParams.dropout,
        ModelHyperParams.weight_sharing, TrainTaskConfig.label_smooth_eps)

    local_lr_scheduler = LearningRateScheduler(ModelHyperParams.d_model,
                                               TrainTaskConfig.warmup_steps,
                                               TrainTaskConfig.learning_rate)
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    # Context to do validation.
    test_program = fluid.default_main_program().clone(for_test=True)
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    if not is_dist:
        optimizer = fluid.optimizer.Adam(
            learning_rate=local_lr_scheduler.learning_rate,
            beta1=TrainTaskConfig.beta1,
            beta2=TrainTaskConfig.beta2,
            epsilon=TrainTaskConfig.eps)
        optimizer.minimize(sum_cost)
    elif is_async:
        optimizer = fluid.optimizer.SGD(0.003)
        optimizer.minimize(sum_cost)
    else:
        lr_decay = fluid.layers\
         .learning_rate_scheduler\
         .noam_decay(ModelHyperParams.d_model,
            TrainTaskConfig.warmup_steps)

        optimizer = fluid.optimizer.Adam(
            learning_rate=lr_decay,
            beta1=TrainTaskConfig.beta1,
            beta2=TrainTaskConfig.beta2,
            epsilon=TrainTaskConfig.eps)
        optimizer.minimize(sum_cost)

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    return sum_cost, avg_cost, predict, token_num, local_lr_scheduler, test_program
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def update_args():
    src_dict = DataReader.load_dict(TrainTaskConfig.src_vocab_fpath)
    trg_dict = DataReader.load_dict(TrainTaskConfig.trg_vocab_fpath)
    dict_args = [
        "src_vocab_size", str(len(src_dict)), "trg_vocab_size",
        str(len(trg_dict)), "bos_idx",
        str(src_dict[TrainTaskConfig.special_token[0]]), "eos_idx",
        str(src_dict[TrainTaskConfig.special_token[1]]), "unk_idx",
        str(src_dict[TrainTaskConfig.special_token[2]])
    ]
    merge_cfg_from_list(dict_args, [TrainTaskConfig, ModelHyperParams])


class DistTransformer2x2(TestDistRunnerBase):
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    def run_pserver(self, args):
        get_model(True, not args.sync_mode)
        t = self.get_transpiler(args.trainer_id,
                                fluid.default_main_program(), args.endpoints,
                                args.trainers, args.sync_mode)
        pserver_prog = t.get_pserver_program(args.current_endpoint)
        startup_prog = t.get_startup_program(args.current_endpoint,
                                             pserver_prog)
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        place = fluid.CPUPlace()
        exe = fluid.Executor(place)
        exe.run(startup_prog)
        exe.run(pserver_prog)

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    def run_trainer(self, args):
        TrainTaskConfig.use_gpu = args.use_cuda
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        sum_cost, avg_cost, predict, token_num, local_lr_scheduler, test_program = get_model(
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            args.is_dist, not args.sync_mode)
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        if args.is_dist:
            t = self.get_transpiler(args.trainer_id,
                                    fluid.default_main_program(),
                                    args.endpoints, args.trainers,
                                    args.sync_mode)
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            trainer_prog = t.get_trainer_program()
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            TrainTaskConfig.batch_size = 10
            TrainTaskConfig.train_file_pattern = TrainTaskConfig.data_path + "train.tok.clean.bpe.32000.en-de.train_{}".format(
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                args.trainer_id)
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        else:
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            TrainTaskConfig.batch_size = 20
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            trainer_prog = fluid.default_main_program()

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        if args.use_cuda:
            place = fluid.CUDAPlace(0)
        else:
            place = fluid.CPUPlace()

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        startup_exe = fluid.Executor(place)
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        TrainTaskConfig.local = not args.is_dist
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        train_loop(startup_exe, trainer_prog, 1, sum_cost, avg_cost,
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                   local_lr_scheduler, token_num, predict, test_program)
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if __name__ == "__main__":
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    update_args()
    runtime_main(DistTransformer2x2)