PaddleSpeech/tools/tune.py

"""Beam search parameters tuning for DeepSpeech2 model."""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function

import sys
import os
import numpy as np
import argparse
import functools
import gzip
import logging
import paddle.fluid as fluid
import _init_paths
from data_utils.data import DataGenerator
from model_utils.model import DeepSpeech2Model
from utils.error_rate import char_errors, word_errors
from utils.utility import add_arguments, print_arguments

parser = argparse.ArgumentParser(description=__doc__)
add_arg = functools.partial(add_arguments, argparser=parser)
# yapf: disable
add_arg('num_batches',      int,    -1,     "# of batches tuning on. "
                                            "Default -1, on whole dev set.")
add_arg('batch_size',       int,    256,    "# of samples per batch.")
add_arg('trainer_count',    int,    8,      "# of Trainers (CPUs or GPUs).")
add_arg('beam_size',        int,    500,    "Beam search width.")
add_arg('num_proc_bsearch', int,    8,     "# of CPUs for beam search.")
add_arg('num_conv_layers',  int,    2,      "# of convolution layers.")
add_arg('num_rnn_layers',   int,    3,      "# of recurrent layers.")
add_arg('rnn_layer_size',   int,    2048,   "# of recurrent cells per layer.")
add_arg('num_alphas',       int,    45,     "# of alpha candidates for tuning.")
add_arg('num_betas',        int,    8,      "# of beta candidates for tuning.")
add_arg('alpha_from',       float,  1.0,    "Where alpha starts tuning from.")
add_arg('alpha_to',         float,  3.2,    "Where alpha ends tuning with.")
add_arg('beta_from',        float,  0.1,    "Where beta starts tuning from.")
add_arg('beta_to',          float,  0.45,   "Where beta ends tuning with.")
add_arg('cutoff_prob',      float,  1.0,    "Cutoff probability for pruning.")
add_arg('cutoff_top_n',     int,    40,     "Cutoff number for pruning.")
add_arg('use_gru',          bool,   False,  "Use GRUs instead of simple RNNs.")
add_arg('use_gpu',          bool,   True,   "Use GPU or not.")
add_arg('share_rnn_weights',bool,   True,   "Share input-hidden weights across "
                                            "bi-directional RNNs. Not for GRU.")
add_arg('tune_manifest',    str,
        'data/librispeech/manifest.dev-clean',
        "Filepath of manifest to tune.")
add_arg('mean_std_path',    str,
        'data/librispeech/mean_std.npz',
        "Filepath of normalizer's mean & std.")
add_arg('vocab_path',       str,
        'data/librispeech/vocab.txt',
        "Filepath of vocabulary.")
add_arg('lang_model_path',  str,
        'models/lm/common_crawl_00.prune01111.trie.klm',
        "Filepath for language model.")
add_arg('model_path',       str,
        './checkpoints/libri/params.latest.tar.gz',
        "If None, the training starts from scratch, "
        "otherwise, it resumes from the pre-trained model.")
add_arg('error_rate_type',  str,
        'wer',
        "Error rate type for evaluation.",
        choices=['wer', 'cer'])
add_arg('specgram_type',    str,
        'linear',
        "Audio feature type. Options: linear, mfcc.",
        choices=['linear', 'mfcc'])
# yapf: disable
args = parser.parse_args()


def tune():
    """Tune parameters alpha and beta incrementally."""
    if not args.num_alphas >= 0:
        raise ValueError("num_alphas must be non-negative!")
    if not args.num_betas >= 0:
        raise ValueError("num_betas must be non-negative!")

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

    data_generator = DataGenerator(
        vocab_filepath=args.vocab_path,
        mean_std_filepath=args.mean_std_path,
        augmentation_config='{}',
        specgram_type=args.specgram_type,
        keep_transcription_text=True,
        place = place,
        is_training = False)

    batch_reader = data_generator.batch_reader_creator(
        manifest_path=args.tune_manifest,
        batch_size=args.batch_size,
        sortagrad=False,
        shuffle_method=None)

    ds2_model = DeepSpeech2Model(
        vocab_size=data_generator.vocab_size,
        num_conv_layers=args.num_conv_layers,
        num_rnn_layers=args.num_rnn_layers,
        rnn_layer_size=args.rnn_layer_size,
        use_gru=args.use_gru,
        place=place,
        init_from_pretrained_model=args.model_path,
        share_rnn_weights=args.share_rnn_weights)

    # decoders only accept string encoded in utf-8
    vocab_list = [chars.encode("utf-8") for chars in data_generator.vocab_list]
    errors_func = char_errors if args.error_rate_type == 'cer' else word_errors
    # create grid for search
    cand_alphas = np.linspace(args.alpha_from, args.alpha_to, args.num_alphas)
    cand_betas = np.linspace(args.beta_from, args.beta_to, args.num_betas)
    params_grid = [(alpha, beta) for alpha in cand_alphas
                   for beta in cand_betas]

    err_sum = [0.0 for i in range(len(params_grid))]
    err_ave = [0.0 for i in range(len(params_grid))]
    num_ins, len_refs, cur_batch = 0, 0, 0
    # initialize external scorer
    ds2_model.init_ext_scorer(args.alpha_from, args.beta_from,
                              args.lang_model_path, vocab_list)
    ## incremental tuning parameters over multiple batches
    ds2_model.logger.info("start tuning ...")
    for infer_data in batch_reader():
        if (args.num_batches >= 0) and (cur_batch >= args.num_batches):
            break
        probs_split = ds2_model.infer_batch_probs(
            infer_data=infer_data,
            feeding_dict=data_generator.feeding)
        target_transcripts = infer_data[1]

        num_ins += len(target_transcripts)
        # grid search
        for index, (alpha, beta) in enumerate(params_grid):
            result_transcripts = ds2_model.decode_batch_beam_search(
                probs_split=probs_split,
                beam_alpha=alpha,
                beam_beta=beta,
                beam_size=args.beam_size,
                cutoff_prob=args.cutoff_prob,
                cutoff_top_n=args.cutoff_top_n,
                vocab_list=vocab_list,
                num_processes=args.num_proc_bsearch)
            for target, result in zip(target_transcripts, result_transcripts):
                errors, len_ref = errors_func(target, result)
                err_sum[index] += errors
                # accumulate the length of references of every batch
                # in the first iteration
                if args.alpha_from == alpha and args.beta_from == beta:
                    len_refs += len_ref

            err_ave[index] = err_sum[index] / len_refs
            if index % 2 == 0:
                sys.stdout.write('.')
                sys.stdout.flush()

        # output on-line tuning result at the end of current batch
        err_ave_min = min(err_ave)
        min_index = err_ave.index(err_ave_min)
        print("\nBatch %d [%d/?], current opt (alpha, beta) = (%s, %s), "
              " min [%s] = %f" %(cur_batch, num_ins,
              "%.3f" % params_grid[min_index][0],
              "%.3f" % params_grid[min_index][1],
              args.error_rate_type, err_ave_min))
        cur_batch += 1

    # output WER/CER at every (alpha, beta)
    print("\nFinal %s:\n" % args.error_rate_type)
    for index in range(len(params_grid)):
        print("(alpha, beta) = (%s, %s), [%s] = %f"
             % ("%.3f" % params_grid[index][0], "%.3f" % params_grid[index][1],
             args.error_rate_type, err_ave[index]))

    err_ave_min = min(err_ave)
    min_index = err_ave.index(err_ave_min)
    print("\nFinish tuning on %d batches, final opt (alpha, beta) = (%s, %s)"
            % (cur_batch, "%.3f" % params_grid[min_index][0],
              "%.3f" % params_grid[min_index][1]))

    ds2_model.logger.info("finish tuning")


def main():
    print_arguments(args)
    tune()


if __name__ == '__main__':
    main()