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data_feeder.py
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data_feeder.py
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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.
from __future__ import print_function
from . import core
import numpy
import os
import six
from six.moves import zip, range, xrange
import multiprocessing
from .framework import Variable, default_main_program
__all__ = ['DataFeeder']
class DataToLoDTensorConverter(object):
def __init__(self, place, lod_level, shape, dtype):
self.place = place
self.lod_level = lod_level
self.shape = shape
negtive_count = 0
for s in self.shape:
if s < 0:
negtive_count += 1
if negtive_count > 1:
self.shape = None
break
if dtype == core.VarDesc.VarType.FP32:
self.dtype = 'float32'
elif dtype == core.VarDesc.VarType.INT64:
self.dtype = 'int64'
elif dtype == core.VarDesc.VarType.FP64:
self.dtype = 'float64'
elif dtype == core.VarDesc.VarType.FP16:
self.dtype = 'float16'
elif dtype == core.VarDesc.VarType.INT32:
self.dtype = 'int32'
elif dtype == core.VarDesc.VarType.UINT8:
self.dtype = 'uint8'
else:
raise ValueError("dtype must be any of [int32, float32, int64, "
"float64, uint8]")
self.data = []
self.lod = []
for i in six.moves.range(lod_level):
self.lod.append([])
def feed(self, data):
self._feed_impl_(data, self.lod, self.lod_level)
def _feed_impl_(self, data, lod, lod_level):
if lod_level == 0:
self.data.append(data)
else:
lod[0].append(len(data))
for each_data in data:
self._feed_impl_(each_data, lod[1:], lod_level - 1)
def _check_shape(self, shape):
for s1, s2 in zip(self.shape, shape):
if s1 != s2 and s1 >= 0 and s2 >= 0:
raise ValueError(
"Shape not match. What is defined in data layer is {}, but receive {}".
format(self.shape, shape))
def done(self):
arr = numpy.array(self.data, dtype=self.dtype)
if self.shape:
if len(arr.shape) != len(self.shape):
try:
arr = arr.reshape(self.shape)
except ValueError:
raise ValueError(
"Reshape error. What is defined in data layer is {}, but receive {}"
.format(self.shape, arr.shape))
#else:
# self._check_shape(arr.shape)
t = core.LoDTensor()
t.set(arr, self.place)
if self.lod_level > 0:
t.set_recursive_sequence_lengths(self.lod)
return t
class DataFeeder(object):
"""
DataFeeder converts the data that returned by a reader into a data
structure that can feed into Executor and ParallelExecutor. The reader
usually returns a list of mini-batch data entries. Each data entry in
the list is one sample. Each sample is a list or a tuple with one
feature or multiple features.
The simple usage shows below:
.. code-block:: python
place = fluid.CPUPlace()
img = fluid.layers.data(name='image', shape=[1, 28, 28])
label = fluid.layers.data(name='label', shape=[1], dtype='int64')
feeder = fluid.DataFeeder([img, label], fluid.CPUPlace())
result = feeder.feed([([0] * 784, [9]), ([1] * 784, [1])])
If you want to feed data into GPU side separately in advance when you
use multi-GPU to train a model, you can use `decorate_reader` function.
.. code-block:: python
place=fluid.CUDAPlace(0)
feeder = fluid.DataFeeder(place=place, feed_list=[data, label])
reader = feeder.decorate_reader(
paddle.batch(flowers.train(), batch_size=16))
Args:
feed_list(list): The Variables or Variables'name that will
feed into model.
place(Place): place indicates feed data into CPU or GPU, if you want to
feed data into GPU, please using `fluid.CUDAPlace(i)` (`i` represents
the GPU id), or if you want to feed data into CPU, please using
`fluid.CPUPlace()`.
program(Program): The Program that will feed data into, if program
is None, it will use default_main_program(). Default None.
Raises:
ValueError: If some Variable is not in this Program.
Examples:
.. code-block:: python
# ...
place = fluid.CPUPlace()
feed_list = [
main_program.global_block().var(var_name) for var_name in feed_vars_name
] # feed_vars_name is a list of variables' name.
feeder = fluid.DataFeeder(feed_list, place)
for data in reader():
outs = exe.run(program=main_program,
feed=feeder.feed(data))
"""
def __init__(self, feed_list, place, program=None):
self.feed_dtypes = []
self.feed_names = []
self.feed_shapes = []
self.feed_lod_level = []
if program is None:
program = default_main_program()
for each_var in feed_list:
if isinstance(each_var, six.string_types):
each_var = program.block(0).var(each_var)
if not isinstance(each_var, Variable):
raise TypeError("Feed list should contain a list of variable")
self.feed_dtypes.append(each_var.dtype)
self.feed_names.append(each_var.name)
self.feed_lod_level.append(each_var.lod_level)
self.feed_shapes.append(each_var.shape)
self.place = place
def feed(self, iterable):
"""
According to feed_list and iterable, converters the input into
a data structure that can feed into Executor and ParallelExecutor.
Args:
iterable(list|tuple): the input data.
Returns:
dict: the result of conversion.
"""
converter = []
for lod_level, shape, dtype in six.moves.zip(
self.feed_lod_level, self.feed_shapes, self.feed_dtypes):
converter.append(
DataToLoDTensorConverter(
place=self.place,
lod_level=lod_level,
shape=shape,
dtype=dtype))
for each_sample in iterable:
assert len(each_sample) == len(converter), (
"The number of fields in data (%s) does not match " +
"len(feed_list) (%s)") % (len(each_sample), len(converter))
for each_converter, each_slot in six.moves.zip(converter,
each_sample):
each_converter.feed(each_slot)
ret_dict = {}
for each_name, each_converter in six.moves.zip(self.feed_names,
converter):
ret_dict[each_name] = each_converter.done()
return ret_dict
def feed_parallel(self, iterable, num_places=None):
"""
Takes multiple mini-batches. Each mini-batch will be feed on each
device in advance.
Args:
iterable(list|tuple): the input data.
num_places(int): the number of devices. Default None.
Returns:
dict: the result of conversion.
Notes:
The number of devices and number of mini-batches must be same.
"""
if isinstance(self.place, core.CUDAPlace):
places = [
core.CUDAPlace(i)
for i in six.moves.xrange(
self._get_number_of_places_(num_places))
]
else:
places = [
core.CPUPlace()
for _ in six.moves.xrange(
self._get_number_of_places_(num_places))
]
if len(iterable) != len(places):
raise ValueError("feed_parallel takes multiple mini-batches. Each "
"mini-batch will be feed on each device. The "
"number of devices and number of mini-batches "
"must be same.")
place = self.place
for p, batch in six.moves.zip(places, iterable):
self.place = p
yield self.feed(batch)
self.place = place
def _get_number_of_places_(self, num_places):
if num_places is not None:
return int(num_places)
elif isinstance(self.place, core.CUDAPlace):
return core.get_cuda_device_count()
else:
cpu_num = int(
os.environ.get('CPU_NUM', multiprocessing.cpu_count()))
return cpu_num
def decorate_reader(self,
reader,
multi_devices,
num_places=None,
drop_last=True):
"""
Converter the input data into a data that returned by reader into
multiple mini-batches. Each mini-batch will be feed on each device.
Args:
reader(function): the reader is the function which can generate data.
multi_devices(bool): whether to use multiple devices or not.
num_places(int): if the multi_devices is True, you can specify the number
of GPU to use, if 'num_places' is None, the function will use all the
GPU of the current machine. Default None.
drop_last(bool): whether to drop the last batch if the
size of the last batch is less than batch_size. Default True.
Returns:
dict: the result of conversion.
Raises:
ValueError: If drop_last is False and the data batch which cannot fit for devices.
"""
def __reader_creator__():
if not multi_devices:
for item in reader():
yield self.feed(item)
else:
num = self._get_number_of_places_(num_places)
item = []
for batch in reader():
item.append(batch)
if len(item) == num:
yield list(self.feed_parallel(item, num))
item = []
if not drop_last and len(item) != 0:
raise ValueError(
"The data batch which cannot fit for devices will be "
"dropped is not implementation. Other strategies are "
"not implemented")
return __reader_creator__