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提交 f12deac8 编写于 作者: Y yangyaming
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Add comments for data reader and adapt the model according to parallel 

reader.
上级 ee1a4aa6
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Showing with 327 addition and 531 deletion
fluid/DeepASR/data_utils/data_reader.py
浏览文件 @ f12deac8
"""This model read the sample from disk.
use multiprocessing to reading samples
push samples from one block to multiprocessing queue
Todos:
1. multiprocess read block from disk
"""This module contains data processing related logic.
"""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
import random
import Queue
import numpy as np
import struct
import data_utils.augmentor.trans_mean_variance_norm as trans_mean_variance_norm
import data_utils.augmentor.trans_add_delta as trans_add_delta
class OneBlock(object):
""" struct for one block :
contain label, label desc, feature, feature_desc
Attributes:
label(str) : label path of one block
label_desc(str) : label description path of one block
feature(str) : feature path of on block
feature_desc(str) : feature description path of on block
from multiprocessing import Manager, Process
from threading import Thread
import time
class SampleInfo(object):
"""SampleInfo holds the necessary information to load an example from disk.
Args:
feature_bin_path (str): File containing the feature data.
feature_start (int): Start position of the sample's feature data.
feature_size (int): Byte count of the sample's feature data.
feature_frame_num (int): Time length of the sample.
feature_dim (int): Feature dimension of one frame.
label_bin_path (str): File containing the label data.
label_size (int): Byte count of the sample's label data.
label_frame_num (int): Label number of the sample.
"""
def __init__(self):
"""the constructor."""
self.label = "label"
self.label_desc = "label_desc"
self.feature = "feature"
self.feature_desc = "feature_desc"
class DataRead(object):
def __init__(self, feature_bin_path, feature_start, feature_size,
feature_frame_num, feature_dim, label_bin_path, label_start,
label_size, label_frame_num):
self.feature_bin_path = feature_bin_path
self.feature_start = feature_start
self.feature_size = feature_size
self.feature_frame_num = feature_frame_num
self.feature_dim = feature_dim
self.label_bin_path = label_bin_path
self.label_start = label_start
self.label_size = label_size
self.label_frame_num = label_frame_num
class SampleInfoBucket(object):
"""SampleInfoBucket contains paths of several description files. Feature
description file contains necessary information to access samples' feature
data and label description file contains necessary information to
access samples' label data. SampleInfoBucket is the minimum unit to do
shuffle.
Args:
feature_bin_paths (list|tuple): Files containing the binary feature
data.
feature_desc_paths (list|tuple): Files containing the description of
samples' feature data.
label_bin_paths (list|tuple): Files containing the binary label data.
label_desc_paths (list|tuple): Files containing the description of
samples' label data.
"""
Attributes:
_lblock(obj:`OneBlock`) : the list of OneBlock
_ndrop_sentence_len(int): dropout the sentence which's frame_num large than _ndrop_sentence_len
_que_sample(obj:`Queue`): sample buffer
_nframe_dim(int): the batch sample frame_dim(todo remove)
_nstart_block_idx(int): the start block id
_nload_block_num(int): the block num
def __init__(self, feature_bin_paths, feature_desc_paths, label_bin_paths,
label_desc_paths):
block_num = len(label_bin_paths)
assert len(label_desc_paths) == block_num
assert len(feature_bin_paths) == block_num
assert len(feature_desc_paths) == block_num
self._block_num = block_num
self._feature_bin_paths = feature_bin_paths
self._feature_desc_paths = feature_desc_paths
self._label_bin_paths = label_bin_paths
self._label_desc_paths = label_desc_paths
def generate_sample_info_list(self):
sample_info_list = []
for block_idx in xrange(self._block_num):
label_bin_path = self._label_bin_paths[block_idx]
label_desc_path = self._label_desc_paths[block_idx]
feature_bin_path = self._feature_bin_paths[block_idx]
feature_desc_path = self._feature_desc_paths[block_idx]
label_desc_lines = open(label_desc_path).readlines()
feature_desc_lines = open(feature_desc_path).readlines()
sample_num = int(label_desc_lines[0].split()[1])
assert sample_num == int(feature_desc_lines[0].split()[1])
for i in xrange(sample_num):
feature_desc_split = feature_desc_lines[i + 1].split()
feature_start = int(feature_desc_split[2])
feature_size = int(feature_desc_split[3])
feature_frame_num = int(feature_desc_split[4])
feature_dim = int(feature_desc_split[5])
label_desc_split = label_desc_lines[i + 1].split()
label_start = int(label_desc_split[2])
label_size = int(label_desc_split[3])
label_frame_num = int(label_desc_split[4])
sample_info_list.append(
SampleInfo(feature_bin_path, feature_start, feature_size,
feature_frame_num, feature_dim, label_bin_path,
label_start, label_size, label_frame_num))
return sample_info_list
class EpochEndSignal():
pass
class DataReader(object):
"""DataReader provides basic audio sample preprocessing pipeline including
I/O and augmentation transformation.
Args:
feature_file_list (str): File containing feature data related files.
label_file_list (str): File containing label data related files.
frame_dim (int): The final feature dimension of one frame after all
augmentation applied.
drop_sentence_len (int): Lower threshold bound to filter samples having
long sentence.
process_num (int): Number of processes for processing data.
sample_buffer_size (int): Buffer size to indicate the maximum samples
cached.
sample_info_buffer_size (int): Buffer size to indicate the maximum
sample information cached.
shuffle_block_num (int): Block number indicating the minimum unit to do
shuffle.
random_seed (int): Random seed.
"""
def __init__(self, sfeature_lst, slabel_lst, ndrop_sentence_len=512):
"""
Args:
sfeature_lst(str):feature lst path
slabel_lst(str):label lst path
Returns:
None
"""
self._lblock = []
self._ndrop_sentence_len = ndrop_sentence_len
self._que_sample = Queue.Queue()
self._nframe_dim = 120 * 11
self._nstart_block_idx = 0
self._nload_block_num = 1
self._ndrop_frame_len = 256
self._load_list(sfeature_lst, slabel_lst)
def _load_list(self, sfeature_lst, slabel_lst):
""" load list and shuffle
Args:
sfeature_lst(str):feature lst path
slabel_lst(str):label lst path
Returns:
None
"""
lfeature = open(sfeature_lst).readlines()
llabel = open(slabel_lst).readlines()
assert len(llabel) == len(lfeature)
for i in range(0, len(lfeature), 2):
one_block = OneBlock()
one_block.label = llabel[i]
one_block.label_desc = llabel[i + 1]
one_block.feature = lfeature[i]
one_block.feature_desc = lfeature[i + 1]
self._lblock.append(one_block)
random.shuffle(self._lblock)
def _load_one_block(self, lsample, id):
"""read one block by id and push load sample in list lsample
Args:
lsample(list): return sample list
id(int): block id
Returns:
None
"""
if id >= len(self._lblock):
return
slabel_path = self._lblock[id].label.strip()
slabel_desc_path = self._lblock[id].label_desc.strip()
sfeature_path = self._lblock[id].feature.strip()
sfeature_desc_path = self._lblock[id].feature_desc.strip()
llabel_line = open(slabel_desc_path).readlines()
lfeature_line = open(sfeature_desc_path).readlines()
file_lable_bin = open(slabel_path, "r")
file_feature_bin = open(sfeature_path, "r")
sample_num = int(llabel_line[0].split()[1])
assert sample_num == int(lfeature_line[0].split()[1])
llabel_line = llabel_line[1:]
lfeature_line = lfeature_line[1:]
for i in range(sample_num):
# read label
llabel_split = llabel_line[i].split()
nlabel_start = int(llabel_split[2])
nlabel_size = int(llabel_split[3])
nlabel_frame_num = int(llabel_split[4])
file_lable_bin.seek(nlabel_start, 0)
label_bytes = file_lable_bin.read(nlabel_size)
assert nlabel_frame_num * 4 == len(label_bytes)
label_array = struct.unpack('I' * nlabel_frame_num, label_bytes)
label_data = np.array(label_array, dtype="int64")
label_data = label_data.reshape((nlabel_frame_num, 1))
# read feature
lfeature_split = lfeature_line[i].split()
nfeature_start = int(lfeature_split[2])
nfeature_size = int(lfeature_split[3])
nfeature_frame_num = int(lfeature_split[4])
nfeature_frame_dim = int(lfeature_split[5])
file_feature_bin.seek(nfeature_start, 0)
feature_bytes = file_feature_bin.read(nfeature_size)
assert nfeature_frame_num * nfeature_frame_dim * 4 == len(
feature_bytes)
feature_array = struct.unpack('f' * nfeature_frame_num *
nfeature_frame_dim, feature_bytes)
feature_data = np.array(feature_array, dtype="float32")
feature_data = feature_data.reshape(
(nfeature_frame_num, nfeature_frame_dim))
#drop long sentence
if self._ndrop_frame_len < feature_data.shape[0]:
def __init__(
self,
feature_file_list,
label_file_list,
frame_dim=120 * 11, # @TODO augmentor is responsible for the value
drop_sentence_len=512,
drop_frame_len=256,
process_num=10,
sample_buffer_size=1024,
sample_info_buffer_size=10000,
shuffle_block_num=1,
random_seed=0):
self._feature_file_list = feature_file_list
self._label_file_list = label_file_list
self._drop_sentence_len = drop_sentence_len
self._frame_dim = frame_dim
self._drop_frame_len = drop_frame_len
self._shuffle_block_num = shuffle_block_num
self._block_info_list = None
self._rng = random.Random(random_seed)
self._bucket_list = None
self.generate_bucket_list(True)
self._order_id = 0
self._manager = Manager()
self._sample_buffer_size = sample_buffer_size
self._sample_info_buffer_size = sample_info_buffer_size
self._process_num = process_num
def generate_bucket_list(self, is_shuffle):
if self._block_info_list is None:
block_feature_info_lines = open(self._feature_file_list).readlines()
block_label_info_lines = open(self._label_file_list).readlines()
assert len(block_feature_info_lines) == len(block_label_info_lines)
self._block_info_list = []
for i in xrange(0, len(block_feature_info_lines), 2):
block_info = (block_feature_info_lines[i],
block_feature_info_lines[i + 1],
block_label_info_lines[i],
block_label_info_lines[i + 1])
self._block_info_list.append(
map(lambda line: line.strip(), block_info))
if is_shuffle:
self._rng.shuffle(self._block_info_list)
self._bucket_list = []
for i in xrange(0, len(self._block_info_list), self._shuffle_block_num):
bucket_block_info = self._block_info_list[i:i +
self._shuffle_block_num]
self._bucket_list.append(
SampleInfoBucket(
map(lambda info: info[0], bucket_block_info),
map(lambda info: info[1], bucket_block_info),
map(lambda info: info[2], bucket_block_info),
map(lambda info: info[3], bucket_block_info)))
# @TODO make this configurable
def set_transformers(self, transformers):
self._transformers = transformers
def _sample_generator(self):
sample_info_queue = self._manager.Queue(self._sample_info_buffer_size)
sample_queue = self._manager.Queue(self._sample_buffer_size)
self._order_id = 0
def ordered_feeding_worker(sample_info_queue):
for sample_info_bucket in self._bucket_list:
sample_info_list = sample_info_bucket.generate_sample_info_list(
)
self._rng.shuffle(sample_info_list) # do shuffle here
for sample_info in sample_info_list:
sample_info_queue.put((sample_info, self._order_id))
self._order_id += 1
for i in xrange(self._process_num):
sample_info_queue.put(EpochEndSignal())
feeding_thread = Thread(
target=ordered_feeding_worker, args=(sample_info_queue, ))
feeding_thread.daemon = True
feeding_thread.start()
def ordered_processing_worker(sample_info_queue, sample_queue,
out_order):
def read_bytes(fpath, start, size):
f = open(fpath, 'r')
f.seek(start, 0)
binary_bytes = f.read(size)
f.close()
return binary_bytes
ins = sample_info_queue.get()
while not isinstance(ins, EpochEndSignal):
sample_info, order_id = ins
feature_bytes = read_bytes(sample_info.feature_bin_path,
sample_info.feature_start,
sample_info.feature_size)
label_bytes = read_bytes(sample_info.label_bin_path,
sample_info.label_start,
sample_info.label_size)
assert sample_info.label_frame_num * 4 == len(label_bytes)
label_array = struct.unpack('I' * sample_info.label_frame_num,
label_bytes)
label_data = np.array(
label_array, dtype='int64').reshape(
(sample_info.label_frame_num, 1))
feature_frame_num = sample_info.feature_frame_num
feature_dim = sample_info.feature_dim
assert feature_frame_num * feature_dim * 4 == len(feature_bytes)
feature_array = struct.unpack('f' * feature_frame_num *
feature_dim, feature_bytes)
feature_data = np.array(
feature_array, dtype='float32').reshape((
sample_info.feature_frame_num, sample_info.feature_dim))
sample_data = (feature_data, label_data)
for transformer in self._transformers:
# @TODO(pkuyym) to make transfomer only accept feature_data
sample_data = transformer.perform_trans(sample_data)
while order_id != out_order[0]:
time.sleep(0.001)
# drop long sentence
if self._drop_sentence_len >= sample_data[0].shape[0]:
sample_queue.put(sample_data)
out_order[0] += 1
ins = sample_info_queue.get()
sample_queue.put(EpochEndSignal())
out_order = self._manager.list([0])
args = (sample_info_queue, sample_queue, out_order)
workers = [
Process(
target=ordered_processing_worker, args=args)
for _ in xrange(self._process_num)
]
for w in workers:
w.daemon = True
w.start()
finished_process_num = 0
while finished_process_num < self._process_num:
sample = sample_queue.get()
if isinstance(sample, EpochEndSignal):
finished_process_num += 1
continue
lsample.append((feature_data, label_data))
def get_one_batch(self, nbatch_size):
"""construct one batch(feature, label), batch size is nbatch_size
Args:
nbatch_size(int): batch size
Returns:
None
"""
if self._que_sample.empty():
lsample = self._load_block(
range(self._nstart_block_idx, self._nstart_block_idx +
self._nload_block_num, 1))
self._move_sample(lsample)
self._nstart_block_idx += self._nload_block_num
if self._que_sample.empty():
self._nstart_block_idx = 0
return None
#cal all frame num
ncur_len = 0
yield sample
feeding_thread.join()
for w in workers:
w.join()
def batch_iterator(self, batch_size, minimum_batch_size):
batch_samples = []
lod = [0]
samples = []
bat_feature = np.zeros((nbatch_size, self._nframe_dim))
for i in range(nbatch_size):
# empty clear zero
if self._que_sample.empty():
self._nstart_block_idx = 0
# copy
else:
(one_feature, one_label) = self._que_sample.get()
samples.append((one_feature, one_label))
ncur_len += one_feature.shape[0]
lod.append(ncur_len)
bat_feature = np.zeros((ncur_len, self._nframe_dim), dtype="float32")
bat_label = np.zeros((ncur_len, 1), dtype="int64")
ncur_len = 0
for sample in samples:
one_feature = sample[0]
one_label = sample[1]
nframe_num = one_feature.shape[0]
nstart = ncur_len
nend = ncur_len + nframe_num
bat_feature[nstart:nend, :] = one_feature
bat_label[nstart:nend, :] = one_label
ncur_len += nframe_num
return (bat_feature, bat_label, lod)
def set_trans(self, ltrans):
""" set transform list
Args:
ltrans(list): data tranform list
Returns:
None
"""
self._ltrans = ltrans
def _load_block(self, lblock_id):
"""read blocks
"""
lsample = []
for id in lblock_id:
self._load_one_block(lsample, id)
# transform sample
for (nidx, sample) in enumerate(lsample):
for trans in self._ltrans:
sample = trans.perform_trans(sample)
lsample[nidx] = sample
return lsample
def load_block(self, lblock_id):
"""read blocks
Args:
lblock_id(list):the block list id
Returns:
None
"""
lsample = []
for id in lblock_id:
self._load_one_block(lsample, id)
# transform sample
for (nidx, sample) in enumerate(lsample):
for trans in self._ltrans:
sample = trans.perform_trans(sample)
lsample[nidx] = sample
return lsample
def _move_sample(self, lsample):
"""move sample to queue
Args:
lsample(list): one block of samples read from disk
Returns:
None
"""
# random
random.shuffle(lsample)
for sample in lsample:
self._que_sample.put(sample)
# check whether need parallel here
for sample in self._sample_generator():
batch_samples.append(sample)
lod.append(lod[-1] + sample[0].shape[0])
if len(batch_samples) == batch_size:
batch_feature = np.zeros(
(lod[-1], self._frame_dim), dtype="float32")
batch_label = np.zeros((lod[-1], 1), dtype="int64")
start = 0
for sample in batch_samples:
frame_num = sample[0].shape[0]
batch_feature[start:start + frame_num, :] = sample[0]
batch_label[start:start + frame_num, :] = sample[1]
start += frame_num
yield (batch_feature, batch_label, lod)
batch_samples = []
lod = [0]
if len(batch_samples) >= minimum_batch_size:
batch_feature = np.zeros(
(lod[-1], self._frame_dim), dtype="float32")
batch_label = np.zeros((lod[-1], 1), dtype="int64")
start = 0
for sample in batch_samples:
frame_num = sample[0].shape[0]
batch_feature[start:start + frame_num, :] = sample[0]
batch_label[start:start + frame_num, :] = sample[1]
start += frame_num
yield (batch_feature, batch_label, lod)
fluid/DeepASR/data_utils/parallel_reader.py 已删除 100644 → 0
浏览文件 @ ee1a4aa6
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
import random
import numpy as np
import struct
import data_utils.augmentor.trans_mean_variance_norm as trans_mean_variance_norm
import data_utils.augmentor.trans_add_delta as trans_add_delta
from multiprocessing import Manager, Process
from threading import Thread
import time
class SampleInfo(object):
def __init__(self, feature_bin_path, feature_start, feature_size,
feature_frame_num, feature_dim, label_bin_path, label_start,
label_size, label_frame_num):
self.feature_bin_path = feature_bin_path
self.feature_start = feature_start
self.feature_size = feature_size
self.feature_frame_num = feature_frame_num
self.feature_dim = feature_dim
self.label_bin_path = label_bin_path
self.label_start = label_start
self.label_size = label_size
self.label_frame_num = label_frame_num
class SampleInfoBucket(object):
def __init__(self, feature_bin_paths, feature_desc_paths, label_bin_paths,
label_desc_paths):
block_num = len(label_bin_paths)
assert len(label_desc_paths) == block_num
assert len(feature_bin_paths) == block_num
assert len(feature_desc_paths) == block_num
self._block_num = block_num
self._feature_bin_paths = feature_bin_paths
self._feature_desc_paths = feature_desc_paths
self._label_bin_paths = label_bin_paths
self._label_desc_paths = label_desc_paths
def generate_sample_info_list(self):
sample_info_list = []
for block_idx in xrange(self._block_num):
label_bin_path = self._label_bin_paths[block_idx]
label_desc_path = self._label_desc_paths[block_idx]
feature_bin_path = self._feature_bin_paths[block_idx]
feature_desc_path = self._feature_desc_paths[block_idx]
label_desc_lines = open(label_desc_path).readlines()
feature_desc_lines = open(feature_desc_path).readlines()
sample_num = int(label_desc_lines[0].split()[1])
assert sample_num == int(feature_desc_lines[0].split()[1])
for i in xrange(sample_num):
feature_desc_split = feature_desc_lines[i + 1].split()
feature_start = int(feature_desc_split[2])
feature_size = int(feature_desc_split[3])
feature_frame_num = int(feature_desc_split[4])
feature_dim = int(feature_desc_split[5])
label_desc_split = label_desc_lines[i + 1].split()
label_start = int(label_desc_split[2])
label_size = int(label_desc_split[3])
label_frame_num = int(label_desc_split[4])
sample_info_list.append(
SampleInfo(feature_bin_path, feature_start, feature_size,
feature_frame_num, feature_dim, label_bin_path,
label_start, label_size, label_frame_num))
return sample_info_list
class EpochEndSignal():
pass
class DataReader(object):
def __init__(self,
feature_file_list,
label_file_list,
frame_dim=120 * 11,
drop_sentence_len=512,
drop_frame_len=256,
parallel_num=10,
sample_buffer_size=1024,
sample_info_buffer_size=10000,
shuffle_block_num=1,
random_seed=0):
self._feature_file_list = feature_file_list
self._label_file_list = label_file_list
self._drop_sentence_len = drop_sentence_len
self._frame_dim = frame_dim
self._drop_frame_len = drop_frame_len
self._shuffle_block_num = shuffle_block_num
self._block_info_list = None
self._rng = random.Random(random_seed)
self._bucket_list = None
self.generate_bucket_list(True)
self._order_id = 0
self._manager = Manager()
self._sample_buffer_size = sample_buffer_size
self._sample_info_buffer_size = sample_info_buffer_size
self._process_num = parallel_num
def generate_bucket_list(self, is_shuffle):
if self._block_info_list is None:
block_feature_info_lines = open(self._feature_file_list).readlines()
block_label_info_lines = open(self._label_file_list).readlines()
assert len(block_feature_info_lines) == len(block_label_info_lines)
self._block_info_list = []
for i in xrange(0, len(block_feature_info_lines), 2):
block_info = (block_feature_info_lines[i],
block_feature_info_lines[i + 1],
block_label_info_lines[i],
block_label_info_lines[i + 1])
self._block_info_list.append(
map(lambda line: line.strip(), block_info))
if is_shuffle:
self._rng.shuffle(self._block_info_list)
self._bucket_list = []
for i in xrange(0, len(self._block_info_list), self._shuffle_block_num):
bucket_block_info = self._block_info_list[i:i +
self._shuffle_block_num]
self._bucket_list.append(
SampleInfoBucket(
map(lambda info: info[0], bucket_block_info),
map(lambda info: info[1], bucket_block_info),
map(lambda info: info[2], bucket_block_info),
map(lambda info: info[3], bucket_block_info)))
# @TODO make this configurable
def set_transformers(self, transformers):
self._transformers = transformers
def _sample_generator(self):
sample_info_queue = self._manager.Queue(self._sample_info_buffer_size)
sample_queue = self._manager.Queue(self._sample_buffer_size)
self._order_id = 0
def ordered_feeding_worker(sample_info_queue):
for sample_info_bucket in self._bucket_list:
sample_info_list = sample_info_bucket.generate_sample_info_list(
)
self._rng.shuffle(sample_info_list) # do shuffle here
for sample_info in sample_info_list:
sample_info_queue.put((sample_info, self._order_id))
self._order_id += 1
for i in xrange(self._process_num):
sample_info_queue.put(EpochEndSignal())
feeding_thread = Thread(
target=ordered_feeding_worker, args=(sample_info_queue, ))
feeding_thread.daemon = True
feeding_thread.start()
def ordered_processing_worker(sample_info_queue, sample_queue,
out_order):
def read_bytes(fpath, start, size):
f = open(fpath, 'r')
f.seek(start, 0)
binary_bytes = f.read(size)
f.close()
return binary_bytes
ins = sample_info_queue.get()
while not isinstance(ins, EpochEndSignal):
sample_info, order_id = ins
feature_bytes = read_bytes(sample_info.feature_bin_path,
sample_info.feature_start,
sample_info.feature_size)
label_bytes = read_bytes(sample_info.label_bin_path,
sample_info.label_start,
sample_info.label_size)
assert sample_info.label_frame_num * 4 == len(label_bytes)
label_array = struct.unpack('I' * sample_info.label_frame_num,
label_bytes)
label_data = np.array(
label_array, dtype='int64').reshape(
(sample_info.label_frame_num, 1))
feature_frame_num = sample_info.feature_frame_num
feature_dim = sample_info.feature_dim
assert feature_frame_num * feature_dim * 4 == len(feature_bytes)
feature_array = struct.unpack('f' * feature_frame_num *
feature_dim, feature_bytes)
feature_data = np.array(
feature_array, dtype='float32').reshape((
sample_info.feature_frame_num, sample_info.feature_dim))
sample_data = (feature_data, label_data)
for transformer in self._transformers:
# @TODO(pkuyym) to make transfomer only accept feature_data
sample_data = transformer.perform_trans(sample_data)
while order_id != out_order[0]:
time.sleep(0.001)
# drop long sentence
if self._drop_sentence_len >= sample_data[0].shape[0]:
sample_queue.put(sample_data)
out_order[0] += 1
ins = sample_info_queue.get()
sample_queue.put(EpochEndSignal())
out_order = self._manager.list([0])
args = (sample_info_queue, sample_queue, out_order)
workers = [
Process(
target=ordered_processing_worker, args=args)
for _ in xrange(self._process_num)
]
for w in workers:
w.daemon = True
w.start()
finished_process_num = 0
while finished_process_num < self._process_num:
sample = sample_queue.get()
if isinstance(sample, EpochEndSignal):
finished_process_num += 1
continue
yield sample
feeding_thread.join()
for w in workers:
w.join()
def batch_iterator(self, batch_size, minimum_batch_size):
batch_samples = []
lod = [0]
# check whether need parallel here
for sample in self._sample_generator():
batch_samples.append(sample)
lod.append(lod[-1] + sample[0].shape[0])
if len(batch_samples) == batch_size:
batch_feature = np.zeros(
(lod[-1], self._frame_dim), dtype="float32")
batch_label = np.zeros((lod[-1], 1), dtype="int64")
start = 0
for sample in batch_samples:
frame_num = sample[0].shape[0]
batch_feature[start:start + frame_num, :] = sample[0]
batch_label[start:start + frame_num, :] = sample[1]
start += frame_num
yield (batch_feature, batch_label, lod)
batch_samples = []
lod = [0]
if len(batch_samples) >= minimum_batch_size:
batch_feature = np.zeros(
(lod[-1], self._frame_dim), dtype="float32")
batch_label = np.zeros((lod[-1], 1), dtype="int64")
start = 0
for sample in batch_samples:
frame_num = sample[0].shape[0]
batch_feature[start:start + frame_num, :] = sample[0]
batch_label[start:start + frame_num, :] = sample[1]
start += frame_num
yield (batch_feature, batch_label, lod)
fluid/DeepASR/stacked_dynamic_lstm.py
浏览文件 @ f12deac8
......@@ -9,9 +9,9 @@ import time
import paddle.v2 as paddle
import paddle.v2.fluid as fluid
import paddle.v2.fluid.profiler as profiler
import data_utils.trans_mean_variance_norm as trans_mean_variance_norm
import data_utils.trans_add_delta as trans_add_delta
import data_utils.trans_splice as trans_splice
import data_utils.augmentor.trans_mean_variance_norm as trans_mean_variance_norm
import data_utils.augmentor.trans_add_delta as trans_add_delta
import data_utils.augmentor.trans_splice as trans_splice
import data_utils.data_reader as reader
......@@ -22,6 +22,12 @@ def parse_args():
type=int,
default=32,
help='The sequence number of a batch data. (default: %(default)d)')
parser.add_argument(
'--minimum_batch_size',
type=int,
default=32,
help='The minimum sequence number of a batch data. (default: %(default)d)'
)
parser.add_argument(
'--stacked_num',
type=int,
......@@ -160,14 +166,15 @@ def train(args):
exe = fluid.Executor(place)
exe.run(fluid.default_startup_program())
# @TODO datareader should take the responsibility (parsing from config file)
ltrans = [
trans_add_delta.TransAddDelta(2, 2),
trans_mean_variance_norm.TransMeanVarianceNorm(args.mean_var),
trans_splice.TransSplice()
]
data_reader = reader.DataRead(args.feature_lst, args.label_lst)
data_reader.set_trans(ltrans)
data_reader = reader.DataReader(args.feature_lst, args.label_lst)
data_reader.set_transformers(ltrans)
res_feature = fluid.LoDTensor()
res_label = fluid.LoDTensor()
......@@ -175,22 +182,15 @@ def train(args):
pass_start_time = time.time()
words_seen = 0
accuracy.reset(exe)
batch_id = 0
while True:
# load_data
one_batch = data_reader.get_one_batch(args.batch_size)
if one_batch == None:
break
(bat_feature, bat_label, lod) = one_batch
for batch_id, batch_data in enumerate(
data_reader.batch_iterator(args.batch_size,
args.minimum_batch_size)):
(bat_feature, bat_label, lod) = batch_data
res_feature.set(bat_feature, place)
res_feature.set_lod([lod])
res_label.set(bat_label, place)
res_label.set_lod([lod])
batch_id += 1
words_seen += lod[-1]
loss, acc = exe.run(
fluid.default_main_program(),
feed={"feature": res_feature,
......
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