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f0651511
编写于
5月 21, 2018
作者:
Y
yuyang18
浏览文件
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电子邮件补丁
差异文件
Extract tests from test_parallel_executor
上级
cd64de76
变更
10
显示空白变更内容
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Showing
10 changed file
with
1020 addition
and
913 deletion
+1020
-913
python/paddle/fluid/tests/unittests/CMakeLists.txt
python/paddle/fluid/tests/unittests/CMakeLists.txt
+0
-2
python/paddle/fluid/tests/unittests/parallel_executor_test_base.py
...ddle/fluid/tests/unittests/parallel_executor_test_base.py
+96
-0
python/paddle/fluid/tests/unittests/test_dist_train.py
python/paddle/fluid/tests/unittests/test_dist_train.py
+5
-6
python/paddle/fluid/tests/unittests/test_parallel_executor.py
...on/paddle/fluid/tests/unittests/test_parallel_executor.py
+0
-905
python/paddle/fluid/tests/unittests/test_parallel_executor_crf.py
...addle/fluid/tests/unittests/test_parallel_executor_crf.py
+197
-0
python/paddle/fluid/tests/unittests/test_parallel_executor_fetch_feed.py
...luid/tests/unittests/test_parallel_executor_fetch_feed.py
+132
-0
python/paddle/fluid/tests/unittests/test_parallel_executor_mnist.py
...dle/fluid/tests/unittests/test_parallel_executor_mnist.py
+171
-0
python/paddle/fluid/tests/unittests/test_parallel_executor_seresnext.py
...fluid/tests/unittests/test_parallel_executor_seresnext.py
+152
-0
python/paddle/fluid/tests/unittests/test_parallel_executor_test_while_train.py
...ests/unittests/test_parallel_executor_test_while_train.py
+93
-0
python/paddle/fluid/tests/unittests/test_parallel_executor_transformer.py
...uid/tests/unittests/test_parallel_executor_transformer.py
+174
-0
未找到文件。
python/paddle/fluid/tests/unittests/CMakeLists.txt
浏览文件 @
f0651511
...
@@ -40,7 +40,6 @@ endfunction()
...
@@ -40,7 +40,6 @@ endfunction()
list
(
REMOVE_ITEM TEST_OPS test_sequence_expand
)
list
(
REMOVE_ITEM TEST_OPS test_sequence_expand
)
# test time consuming OPs in a separate process for expliot parallism
# test time consuming OPs in a separate process for expliot parallism
list
(
REMOVE_ITEM TEST_OPS test_parallel_executor
)
list
(
REMOVE_ITEM TEST_OPS test_warpctc_op
)
list
(
REMOVE_ITEM TEST_OPS test_warpctc_op
)
list
(
REMOVE_ITEM TEST_OPS test_dyn_rnn
)
list
(
REMOVE_ITEM TEST_OPS test_dyn_rnn
)
list
(
REMOVE_ITEM TEST_OPS test_mul_op
)
list
(
REMOVE_ITEM TEST_OPS test_mul_op
)
...
@@ -80,7 +79,6 @@ endif(WITH_FAST_BUNDLE_TEST)
...
@@ -80,7 +79,6 @@ endif(WITH_FAST_BUNDLE_TEST)
#
#
py_test_modules
(
test_sequence_expand MODULES test_sequence_expand
)
py_test_modules
(
test_sequence_expand MODULES test_sequence_expand
)
# tests with high overhead
# tests with high overhead
py_test_modules
(
test_parallel_executor MODULES test_parallel_executor
)
py_test_modules
(
test_warpctc_op MODULES test_warpctc_op ENVS FLAGS_warpctc_dir=
${
WARPCTC_LIB_DIR
}
)
py_test_modules
(
test_warpctc_op MODULES test_warpctc_op ENVS FLAGS_warpctc_dir=
${
WARPCTC_LIB_DIR
}
)
py_test_modules
(
test_train_dyn_rnn MODULES test_dyn_rnn
)
py_test_modules
(
test_train_dyn_rnn MODULES test_dyn_rnn
)
py_test_modules
(
test_mul_op MODULES test_mul_op
)
py_test_modules
(
test_mul_op MODULES test_mul_op
)
...
...
python/paddle/fluid/tests/unittests/parallel_executor_test_base.py
0 → 100644
浏览文件 @
f0651511
# Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import
unittest
import
paddle.fluid
as
fluid
import
time
import
numpy
as
np
__all__
=
[
'TestParallelExecutorBase'
]
class
TestParallelExecutorBase
(
unittest
.
TestCase
):
def
check_network_convergence
(
self
,
method
,
memory_opt
=
True
,
iter
=
50
,
batch_size
=
None
,
allow_op_delay
=
False
,
feed_dict
=
None
,
seed
=
None
,
use_parallel_executor
=
True
,
balance_parameter_opt_between_cards
=
False
):
def
run_executor
(
exe
,
feed
,
fetch_list
,
program
=
None
):
if
isinstance
(
exe
,
fluid
.
ParallelExecutor
):
res
=
exe
.
run
(
fetch_list
=
fetch_list
,
feed
=
feed
)
elif
isinstance
(
exe
,
fluid
.
Executor
):
if
program
is
None
:
program
=
fluid
.
default_main_program
()
res
=
exe
.
run
(
program
=
program
,
feed
=
feed
,
fetch_list
=
fetch_list
)
else
:
raise
ValueError
(
'Unkown type exe'
)
return
res
main
=
fluid
.
Program
()
startup
=
fluid
.
Program
()
startup
.
random_seed
=
1
# Fix random seed
with
fluid
.
program_guard
(
main
,
startup
):
if
seed
is
not
None
:
startup
.
random_seed
=
seed
loss
=
method
(
use_feed
=
feed_dict
is
not
None
)
adam
=
fluid
.
optimizer
.
Adam
()
adam
.
minimize
(
loss
)
if
memory_opt
:
fluid
.
memory_optimize
(
main
)
place
=
fluid
.
CUDAPlace
(
0
)
startup_exe
=
fluid
.
Executor
(
place
)
startup_exe
.
run
(
startup
)
exec_strategy
=
fluid
.
ExecutionStrategy
()
exec_strategy
.
allow_op_delay
=
allow_op_delay
build_strategy
=
fluid
.
BuildStrategy
()
build_strategy
.
reduce_strategy
=
fluid
.
BuildStrategy
.
ReduceStrategy
.
Reduce
if
balance_parameter_opt_between_cards
else
fluid
.
BuildStrategy
.
ReduceStrategy
.
AllReduce
if
use_parallel_executor
:
exe
=
fluid
.
ParallelExecutor
(
True
,
loss_name
=
loss
.
name
,
exec_strategy
=
exec_strategy
,
build_strategy
=
build_strategy
)
else
:
exe
=
fluid
.
Executor
(
place
=
place
)
if
batch_size
is
not
None
:
batch_size
*=
fluid
.
core
.
get_cuda_device_count
()
begin
=
time
.
time
()
first_loss
,
=
run_executor
(
exe
=
exe
,
feed
=
feed_dict
,
fetch_list
=
[
loss
.
name
])
first_loss
=
np
.
array
(
first_loss
)
for
i
in
xrange
(
iter
):
run_executor
(
exe
=
exe
,
feed
=
feed_dict
,
fetch_list
=
[])
last_loss
,
=
run_executor
(
exe
=
exe
,
feed
=
feed_dict
,
fetch_list
=
[
loss
.
name
])
end
=
time
.
time
()
if
batch_size
is
not
None
:
print
"%.4f Instance per second"
%
(
(
batch_size
*
iter
+
2
)
/
(
end
-
begin
))
last_loss
=
np
.
array
(
last_loss
)
print
first_loss
,
last_loss
# self.assertGreater(first_loss[0], last_loss[0])
return
first_loss
,
last_loss
python/paddle/fluid/tests/unittests/test_dist_train.py
浏览文件 @
f0651511
...
@@ -12,16 +12,15 @@
...
@@ -12,16 +12,15 @@
# See the License for the specific language governing permissions and
# See the License for the specific language governing permissions and
# limitations under the License.
# limitations under the License.
import
os
import
time
import
unittest
import
unittest
from
multiprocessing
import
Process
import
numpy
import
paddle.fluid
as
fluid
import
paddle.fluid
as
fluid
import
paddle.fluid.core
as
core
import
paddle.fluid.layers
as
layers
import
paddle.fluid.layers
as
layers
import
numpy
from
multiprocessing
import
Process
from
threading
import
Thread
import
os
,
sys
import
time
class
TestSendOp
(
unittest
.
TestCase
):
class
TestSendOp
(
unittest
.
TestCase
):
...
...
python/paddle/fluid/tests/unittests/test_parallel_executor.py
已删除
100644 → 0
浏览文件 @
cd64de76
# Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import
numpy
as
np
import
unittest
import
paddle.fluid
as
fluid
import
paddle
import
paddle.dataset.mnist
as
mnist
import
paddle.dataset.wmt16
as
wmt16
MNIST_RECORDIO_FILE
=
"./mnist_test_pe.recordio"
WMT16_RECORDIO_FILE
=
"./wmt16_test_pe.recordio"
def
simple_fc_net
(
use_feed
):
if
use_feed
:
img
=
fluid
.
layers
.
data
(
name
=
'image'
,
shape
=
[
784
],
dtype
=
'float32'
)
label
=
fluid
.
layers
.
data
(
name
=
'label'
,
shape
=
[
1
],
dtype
=
'int64'
)
else
:
reader
=
fluid
.
layers
.
open_files
(
filenames
=
[
MNIST_RECORDIO_FILE
],
shapes
=
[[
-
1
,
784
],
[
-
1
,
1
]],
lod_levels
=
[
0
,
0
],
dtypes
=
[
'float32'
,
'int64'
],
thread_num
=
1
,
for_parallel
=
True
)
reader
=
fluid
.
layers
.
io
.
double_buffer
(
reader
)
img
,
label
=
fluid
.
layers
.
read_file
(
reader
)
hidden
=
img
for
_
in
xrange
(
4
):
hidden
=
fluid
.
layers
.
fc
(
hidden
,
size
=
200
,
act
=
'tanh'
,
bias_attr
=
fluid
.
ParamAttr
(
initializer
=
fluid
.
initializer
.
Constant
(
value
=
1.0
)))
prediction
=
fluid
.
layers
.
fc
(
hidden
,
size
=
10
,
act
=
'softmax'
)
loss
=
fluid
.
layers
.
cross_entropy
(
input
=
prediction
,
label
=
label
)
loss
=
fluid
.
layers
.
mean
(
loss
)
return
loss
def
fc_with_batchnorm
(
use_feed
):
if
use_feed
:
img
=
fluid
.
layers
.
data
(
name
=
'image'
,
shape
=
[
784
],
dtype
=
'float32'
)
label
=
fluid
.
layers
.
data
(
name
=
'label'
,
shape
=
[
1
],
dtype
=
'int64'
)
else
:
reader
=
fluid
.
layers
.
open_files
(
filenames
=
[
MNIST_RECORDIO_FILE
],
shapes
=
[[
-
1
,
784
],
[
-
1
,
1
]],
lod_levels
=
[
0
,
0
],
dtypes
=
[
'float32'
,
'int64'
],
thread_num
=
1
,
for_parallel
=
True
)
reader
=
fluid
.
layers
.
io
.
double_buffer
(
reader
)
img
,
label
=
fluid
.
layers
.
read_file
(
reader
)
hidden
=
img
for
_
in
xrange
(
1
):
hidden
=
fluid
.
layers
.
fc
(
hidden
,
size
=
200
,
act
=
'tanh'
,
bias_attr
=
fluid
.
ParamAttr
(
initializer
=
fluid
.
initializer
.
Constant
(
value
=
1.0
)))
hidden
=
fluid
.
layers
.
batch_norm
(
input
=
hidden
)
prediction
=
fluid
.
layers
.
fc
(
hidden
,
size
=
10
,
act
=
'softmax'
)
loss
=
fluid
.
layers
.
cross_entropy
(
input
=
prediction
,
label
=
label
)
loss
=
fluid
.
layers
.
mean
(
loss
)
return
loss
def
squeeze_excitation
(
input
,
num_channels
,
reduction_ratio
):
# pool = fluid.layers.pool2d(
# input=input, pool_size=0, pool_type='avg', global_pooling=True)
conv
=
input
shape
=
conv
.
shape
reshape
=
fluid
.
layers
.
reshape
(
x
=
conv
,
shape
=
[
-
1
,
shape
[
1
],
shape
[
2
]
*
shape
[
3
]])
pool
=
fluid
.
layers
.
reduce_mean
(
input
=
reshape
,
dim
=
2
)
squeeze
=
fluid
.
layers
.
fc
(
input
=
pool
,
size
=
num_channels
/
reduction_ratio
,
act
=
'relu'
)
excitation
=
fluid
.
layers
.
fc
(
input
=
squeeze
,
size
=
num_channels
,
act
=
'sigmoid'
)
scale
=
fluid
.
layers
.
elementwise_mul
(
x
=
input
,
y
=
excitation
,
axis
=
0
)
return
scale
def
conv_bn_layer
(
input
,
num_filters
,
filter_size
,
stride
=
1
,
groups
=
1
,
act
=
None
):
conv
=
fluid
.
layers
.
conv2d
(
input
=
input
,
num_filters
=
num_filters
,
filter_size
=
filter_size
,
stride
=
stride
,
padding
=
(
filter_size
-
1
)
/
2
,
groups
=
groups
,
act
=
None
,
bias_attr
=
False
)
return
fluid
.
layers
.
batch_norm
(
input
=
conv
,
act
=
act
,
momentum
=
0.1
)
def
shortcut
(
input
,
ch_out
,
stride
):
ch_in
=
input
.
shape
[
1
]
if
ch_in
!=
ch_out
:
if
stride
==
1
:
filter_size
=
1
else
:
filter_size
=
3
return
conv_bn_layer
(
input
,
ch_out
,
filter_size
,
stride
)
else
:
return
input
def
bottleneck_block
(
input
,
num_filters
,
stride
,
cardinality
,
reduction_ratio
):
# The number of first 1x1 convolutional channels for each bottleneck build block
# was halved to reduce the compution cost.
conv0
=
conv_bn_layer
(
input
=
input
,
num_filters
=
num_filters
,
filter_size
=
1
,
act
=
'relu'
)
conv1
=
conv_bn_layer
(
input
=
conv0
,
num_filters
=
num_filters
*
2
,
filter_size
=
3
,
stride
=
stride
,
groups
=
cardinality
,
act
=
'relu'
)
conv2
=
conv_bn_layer
(
input
=
conv1
,
num_filters
=
num_filters
*
2
,
filter_size
=
1
,
act
=
None
)
scale
=
squeeze_excitation
(
input
=
conv2
,
num_channels
=
num_filters
*
2
,
reduction_ratio
=
reduction_ratio
)
short
=
shortcut
(
input
,
num_filters
*
2
,
stride
)
return
fluid
.
layers
.
elementwise_add
(
x
=
short
,
y
=
scale
,
act
=
'relu'
)
def
SE_ResNeXt50Small
(
batch_size
=
2
,
use_feed
=
False
):
assert
not
use_feed
,
"SE_ResNeXt doesn't support feed yet"
img
=
fluid
.
layers
.
fill_constant
(
shape
=
[
batch_size
,
3
,
224
,
224
],
dtype
=
'float32'
,
value
=
0.0
)
label
=
fluid
.
layers
.
fill_constant
(
shape
=
[
batch_size
,
1
],
dtype
=
'int64'
,
value
=
0.0
)
conv
=
conv_bn_layer
(
input
=
img
,
num_filters
=
16
,
filter_size
=
3
,
stride
=
2
,
act
=
'relu'
)
conv
=
conv_bn_layer
(
input
=
conv
,
num_filters
=
16
,
filter_size
=
3
,
stride
=
1
,
act
=
'relu'
)
conv
=
conv_bn_layer
(
input
=
conv
,
num_filters
=
16
,
filter_size
=
3
,
stride
=
1
,
act
=
'relu'
)
conv
=
fluid
.
layers
.
pool2d
(
input
=
conv
,
pool_size
=
3
,
pool_stride
=
2
,
pool_padding
=
1
,
pool_type
=
'max'
)
cardinality
=
32
reduction_ratio
=
16
depth
=
[
3
,
4
,
6
,
3
]
num_filters
=
[
128
,
256
,
512
,
1024
]
for
block
in
range
(
len
(
depth
)):
for
i
in
range
(
depth
[
block
]):
conv
=
bottleneck_block
(
input
=
conv
,
num_filters
=
num_filters
[
block
],
stride
=
2
if
i
==
0
and
block
!=
0
else
1
,
cardinality
=
cardinality
,
reduction_ratio
=
reduction_ratio
)
shape
=
conv
.
shape
reshape
=
fluid
.
layers
.
reshape
(
x
=
conv
,
shape
=
[
-
1
,
shape
[
1
],
shape
[
2
]
*
shape
[
3
]])
pool
=
fluid
.
layers
.
reduce_mean
(
input
=
reshape
,
dim
=
2
)
dropout
=
fluid
.
layers
.
dropout
(
x
=
pool
,
dropout_prob
=
0.2
)
# Classifier layer:
prediction
=
fluid
.
layers
.
fc
(
input
=
dropout
,
size
=
1000
,
act
=
'softmax'
)
loss
=
fluid
.
layers
.
cross_entropy
(
input
=
prediction
,
label
=
label
)
loss
=
fluid
.
layers
.
mean
(
loss
)
return
loss
import
time
class
TestParallelExecutorBase
(
unittest
.
TestCase
):
def
check_network_convergence
(
self
,
method
,
memory_opt
=
True
,
iter
=
50
,
batch_size
=
None
,
allow_op_delay
=
False
,
feed_dict
=
None
,
seed
=
None
,
use_parallel_executor
=
True
,
balance_parameter_opt_between_cards
=
False
):
def
run_executor
(
exe
,
feed
,
fetch_list
,
program
=
None
):
if
isinstance
(
exe
,
fluid
.
ParallelExecutor
):
res
=
exe
.
run
(
fetch_list
=
fetch_list
,
feed
=
feed
)
elif
isinstance
(
exe
,
fluid
.
Executor
):
if
program
is
None
:
program
=
fluid
.
default_main_program
()
res
=
exe
.
run
(
program
=
program
,
feed
=
feed
,
fetch_list
=
fetch_list
)
else
:
raise
ValueError
(
'Unkown type exe'
)
return
res
main
=
fluid
.
Program
()
startup
=
fluid
.
Program
()
startup
.
random_seed
=
1
# Fix random seed
with
fluid
.
program_guard
(
main
,
startup
):
if
seed
is
not
None
:
startup
.
random_seed
=
seed
loss
=
method
(
use_feed
=
feed_dict
is
not
None
)
adam
=
fluid
.
optimizer
.
Adam
()
adam
.
minimize
(
loss
)
if
memory_opt
:
fluid
.
memory_optimize
(
main
)
place
=
fluid
.
CUDAPlace
(
0
)
startup_exe
=
fluid
.
Executor
(
place
)
startup_exe
.
run
(
startup
)
exec_strategy
=
fluid
.
ExecutionStrategy
()
exec_strategy
.
allow_op_delay
=
allow_op_delay
build_strategy
=
fluid
.
BuildStrategy
()
build_strategy
.
reduce_strategy
=
fluid
.
BuildStrategy
.
ReduceStrategy
.
Reduce
if
balance_parameter_opt_between_cards
else
fluid
.
BuildStrategy
.
ReduceStrategy
.
AllReduce
if
use_parallel_executor
:
exe
=
fluid
.
ParallelExecutor
(
True
,
loss_name
=
loss
.
name
,
exec_strategy
=
exec_strategy
,
build_strategy
=
build_strategy
)
else
:
exe
=
fluid
.
Executor
(
place
=
place
)
if
batch_size
is
not
None
:
batch_size
*=
fluid
.
core
.
get_cuda_device_count
()
begin
=
time
.
time
()
first_loss
,
=
run_executor
(
exe
=
exe
,
feed
=
feed_dict
,
fetch_list
=
[
loss
.
name
])
first_loss
=
np
.
array
(
first_loss
)
for
i
in
xrange
(
iter
):
run_executor
(
exe
=
exe
,
feed
=
feed_dict
,
fetch_list
=
[])
last_loss
,
=
run_executor
(
exe
=
exe
,
feed
=
feed_dict
,
fetch_list
=
[
loss
.
name
])
end
=
time
.
time
()
if
batch_size
is
not
None
:
print
"%.4f Instance per second"
%
(
(
batch_size
*
iter
+
2
)
/
(
end
-
begin
))
last_loss
=
np
.
array
(
last_loss
)
print
first_loss
,
last_loss
# self.assertGreater(first_loss[0], last_loss[0])
return
first_loss
,
last_loss
class
TestMNIST
(
TestParallelExecutorBase
):
@
classmethod
def
setUpClass
(
cls
):
# Convert mnist to recordio file
with
fluid
.
program_guard
(
fluid
.
Program
(),
fluid
.
Program
()):
reader
=
paddle
.
batch
(
mnist
.
train
(),
batch_size
=
4
)
feeder
=
fluid
.
DataFeeder
(
feed_list
=
[
# order is image and label
fluid
.
layers
.
data
(
name
=
'image'
,
shape
=
[
784
]),
fluid
.
layers
.
data
(
name
=
'label'
,
shape
=
[
1
],
dtype
=
'int64'
),
],
place
=
fluid
.
CPUPlace
())
fluid
.
recordio_writer
.
convert_reader_to_recordio_file
(
MNIST_RECORDIO_FILE
,
reader
,
feeder
)
def
check_simple_fc_convergence
(
self
,
balance_parameter_opt_between_cards
):
self
.
check_network_convergence
(
simple_fc_net
)
self
.
check_network_convergence
(
simple_fc_net
,
allow_op_delay
=
True
)
img
=
np
.
zeros
(
shape
=
[
32
,
784
],
dtype
=
'float32'
)
label
=
np
.
ones
(
shape
=
[
32
,
1
],
dtype
=
'int64'
)
self
.
check_network_convergence
(
simple_fc_net
,
feed_dict
=
{
"image"
:
img
,
"label"
:
label
},
balance_parameter_opt_between_cards
=
balance_parameter_opt_between_cards
)
def
test_simple_fc
(
self
):
self
.
check_simple_fc_convergence
(
False
)
def
test_simple_fc_with_new_strategy
(
self
):
self
.
check_simple_fc_convergence
(
True
)
def
check_simple_fc_parallel_accuracy
(
self
,
balance_parameter_opt_between_cards
):
img
=
np
.
zeros
(
shape
=
[
32
,
784
],
dtype
=
'float32'
)
label
=
np
.
ones
(
shape
=
[
32
,
1
],
dtype
=
'int64'
)
single_first_loss
,
single_last_loss
=
self
.
check_network_convergence
(
method
=
simple_fc_net
,
seed
=
1000
,
feed_dict
=
{
"image"
:
img
,
"label"
:
label
},
use_parallel_executor
=
False
)
parallel_first_loss
,
parallel_last_loss
=
self
.
check_network_convergence
(
method
=
simple_fc_net
,
seed
=
1000
,
feed_dict
=
{
"image"
:
img
,
"label"
:
label
},
use_parallel_executor
=
True
,
balance_parameter_opt_between_cards
=
balance_parameter_opt_between_cards
)
for
p_f
in
parallel_first_loss
:
self
.
assertAlmostEquals
(
p_f
,
single_first_loss
[
0
],
delta
=
1e-6
)
for
p_l
in
parallel_last_loss
:
self
.
assertAlmostEquals
(
p_l
,
single_last_loss
[
0
],
delta
=
1e-6
)
def
test_simple_fc_parallel_accuracy
(
self
):
self
.
check_simple_fc_parallel_accuracy
(
False
)
def
test_simple_fc_parallel_accuracy_with_new_strategy
(
self
):
self
.
check_simple_fc_parallel_accuracy
(
True
)
def
check_batchnorm_fc_convergence
(
self
,
balance_parameter_opt_between_cards
):
self
.
check_network_convergence
(
fc_with_batchnorm
)
img
=
np
.
zeros
(
shape
=
[
32
,
784
],
dtype
=
'float32'
)
label
=
np
.
ones
(
shape
=
[
32
,
1
],
dtype
=
'int64'
)
self
.
check_network_convergence
(
fc_with_batchnorm
,
feed_dict
=
{
"image"
:
img
,
"label"
:
label
},
balance_parameter_opt_between_cards
=
balance_parameter_opt_between_cards
)
def
test_batchnorm_fc
(
self
):
self
.
check_batchnorm_fc_convergence
(
False
)
def
test_batchnorm_fc_with_new_strategy
(
self
):
self
.
check_batchnorm_fc_convergence
(
True
)
class
TestResnet
(
TestParallelExecutorBase
):
# @classmethod
# def setUpClass(cls):
# # import os
# # if os.path.exists('./flowers.recordio'):
# # return
# with fluid.program_guard(fluid.Program(), fluid.Program()):
# reader = paddle.batch(flowers.train(), batch_size=4)
# feeder = fluid.DataFeeder(
# feed_list=[
# fluid.layers.data(
# name='image', shape=[3, 224, 224]),
# fluid.layers.data(
# name='label', shape=[1], dtype='int64'),
# ],
# place=fluid.CPUPlace())
# fluid.recordio_writer.convert_reader_to_recordio_file(
# "./flowers.recordio", reader, feeder, compressor=fluid.core.RecordIOWriter.Compressor.NoCompress)
def
check_resnet_convergence
(
self
,
balance_parameter_opt_between_cards
):
import
functools
batch_size
=
2
self
.
check_network_convergence
(
functools
.
partial
(
SE_ResNeXt50Small
,
batch_size
=
batch_size
),
iter
=
20
,
batch_size
=
batch_size
,
balance_parameter_opt_between_cards
=
balance_parameter_opt_between_cards
)
def
test_resnet
(
self
):
self
.
check_resnet_convergence
(
False
)
def
test_resnet_with_new_strategy
(
self
):
self
.
check_resnet_convergence
(
True
)
class
ModelHyperParams
(
object
):
# Dictionary size for source and target language. This model directly uses
# paddle.dataset.wmt16 in which <bos>, <eos> and <unk> token has
# alreay been added, but the <pad> token is not added. Transformer requires
# sequences in a mini-batch are padded to have the same length. A <pad> token is
# added into the original dictionary in paddle.dateset.wmt16.
# size of source word dictionary.
src_vocab_size
=
10000
# index for <pad> token in source language.
src_pad_idx
=
src_vocab_size
# size of target word dictionay
trg_vocab_size
=
10000
# index for <pad> token in target language.
trg_pad_idx
=
trg_vocab_size
# position value corresponding to the <pad> token.
pos_pad_idx
=
0
# max length of sequences. It should plus 1 to include position
# padding token for position encoding.
max_length
=
50
# 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.
d_inner_hid
=
1024
# 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.
dropout
=
0.1
def
prepare_batch_input
(
insts
,
src_pad_idx
,
trg_pad_idx
,
n_head
):
"""
Pad the instances to the max sequence length in batch, and generate the
corresponding position data and attention bias. Then, convert the numpy
data to tensors and return a dict mapping names to tensors.
"""
def
__pad_batch_data
(
insts
,
pad_idx
,
is_target
=
False
,
return_pos
=
True
,
return_attn_bias
=
True
,
return_max_len
=
True
):
"""
Pad the instances to the max sequence length in batch, and generate the
corresponding position data and attention bias.
"""
return_list
=
[]
max_len
=
max
(
len
(
inst
)
for
inst
in
insts
)
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
return_pos
:
inst_pos
=
np
.
array
([[
pos_i
+
1
if
w_i
!=
pad_idx
else
0
for
pos_i
,
w_i
in
enumerate
(
inst
)
]
for
inst
in
inst_data
])
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
]
return
return_list
if
len
(
return_list
)
>
1
else
return_list
[
0
]
def
data_to_tensor
(
data_list
,
name_list
,
input_dict
,
place
):
assert
len
(
data_list
)
==
len
(
name_list
)
for
i
in
range
(
len
(
name_list
)):
tensor
=
fluid
.
LoDTensor
()
tensor
.
set
(
data_list
[
i
],
place
)
input_dict
[
name_list
[
i
]]
=
tensor
src_word
,
src_pos
,
src_slf_attn_bias
,
src_max_len
=
__pad_batch_data
(
[
inst
[
0
]
for
inst
in
insts
],
src_pad_idx
,
is_target
=
False
)
trg_word
,
trg_pos
,
trg_slf_attn_bias
,
trg_max_len
=
__pad_batch_data
(
[
inst
[
1
]
for
inst
in
insts
],
trg_pad_idx
,
is_target
=
True
)
trg_src_attn_bias
=
np
.
tile
(
src_slf_attn_bias
[:,
:,
::
src_max_len
,
:],
[
1
,
1
,
trg_max_len
,
1
]).
astype
(
"float32"
)
lbl_word
=
__pad_batch_data
([
inst
[
2
]
for
inst
in
insts
],
trg_pad_idx
,
False
,
False
,
False
,
False
)
lbl_weight
=
(
lbl_word
!=
trg_pad_idx
).
astype
(
"float32"
).
reshape
([
-
1
,
1
])
return
[
src_word
,
src_pos
,
trg_word
,
trg_pos
,
src_slf_attn_bias
,
trg_slf_attn_bias
,
trg_src_attn_bias
,
lbl_word
,
lbl_weight
]
import
transformer_model
def
transformer
(
use_feed
):
assert
not
use_feed
,
"transfomer doesn't support feed yet"
return
transformer_model
.
transformer
(
ModelHyperParams
.
src_vocab_size
+
1
,
ModelHyperParams
.
trg_vocab_size
+
1
,
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
.
src_pad_idx
,
ModelHyperParams
.
trg_pad_idx
,
ModelHyperParams
.
pos_pad_idx
)
class
TestTransformer
(
TestParallelExecutorBase
):
@
classmethod
def
setUpClass
(
cls
):
reader
=
paddle
.
batch
(
wmt16
.
train
(
ModelHyperParams
.
src_vocab_size
,
ModelHyperParams
.
trg_vocab_size
),
batch_size
=
transformer_model
.
batch_size
)
with
fluid
.
recordio_writer
.
create_recordio_writer
(
WMT16_RECORDIO_FILE
)
as
writer
:
for
batch
in
reader
():
for
tensor
in
prepare_batch_input
(
batch
,
ModelHyperParams
.
src_pad_idx
,
ModelHyperParams
.
trg_pad_idx
,
ModelHyperParams
.
n_head
):
t
=
fluid
.
LoDTensor
()
t
.
set
(
tensor
,
fluid
.
CPUPlace
())
writer
.
append_tensor
(
t
)
writer
.
complete_append_tensor
()
@
unittest
.
skip
(
"transformer is buggy in multi gpu"
)
def
test_main
(
self
):
self
.
check_network_convergence
(
transformer
)
class
ParallelExecutorTestingDuringTraining
(
unittest
.
TestCase
):
def
check_network_convergence
(
self
,
build_strategy
=
None
):
main
=
fluid
.
Program
()
startup
=
fluid
.
Program
()
with
fluid
.
program_guard
(
main
,
startup
):
loss
=
simple_fc_net
(
True
)
test_program
=
main
.
clone
(
for_test
=
True
)
opt
=
fluid
.
optimizer
.
SGD
(
learning_rate
=
0.001
)
opt
.
minimize
(
loss
)
batch_size
=
32
image
=
np
.
random
.
normal
(
size
=
(
batch_size
,
784
)).
astype
(
'float32'
)
label
=
np
.
random
.
randint
(
0
,
10
,
(
batch_size
,
1
),
dtype
=
"int64"
)
place
=
fluid
.
CUDAPlace
(
0
)
exe
=
fluid
.
Executor
(
place
)
exe
.
run
(
startup
)
feed_dict
=
{
'image'
:
image
,
'label'
:
label
}
train_exe
=
fluid
.
ParallelExecutor
(
use_cuda
=
True
,
loss_name
=
loss
.
name
,
main_program
=
main
,
build_strategy
=
build_strategy
)
test_exe
=
fluid
.
ParallelExecutor
(
use_cuda
=
True
,
main_program
=
test_program
,
share_vars_from
=
train_exe
,
build_strategy
=
build_strategy
)
for
i
in
xrange
(
5
):
test_loss
,
=
test_exe
.
run
([
loss
.
name
],
feed
=
feed_dict
)
test_loss
=
np
.
array
(
test_loss
)
train_loss
,
=
train_exe
.
run
([
loss
.
name
],
feed
=
feed_dict
)
train_loss
=
np
.
array
(
train_loss
)
self
.
assertTrue
(
np
.
allclose
(
train_loss
,
test_loss
,
atol
=
1e-8
),
"Train loss: "
+
str
(
train_loss
)
+
"
\n
Test loss:"
+
str
(
test_loss
))
def
test_parallel_testing
(
self
):
build_strategy
=
fluid
.
BuildStrategy
()
build_strategy
.
reduce_strategy
=
fluid
.
BuildStrategy
.
ReduceStrategy
.
AllReduce
self
.
check_network_convergence
(
build_strategy
)
def
test_parallel_testing_with_new_strategy
(
self
):
build_strategy
=
fluid
.
BuildStrategy
()
build_strategy
.
reduce_strategy
=
fluid
.
BuildStrategy
.
ReduceStrategy
.
Reduce
self
.
check_network_convergence
(
build_strategy
)
import
paddle.dataset.conll05
as
conll05
import
paddle.fluid
as
fluid
word_dict
,
verb_dict
,
label_dict
=
conll05
.
get_dict
()
word_dict_len
=
len
(
word_dict
)
label_dict_len
=
len
(
label_dict
)
pred_dict_len
=
len
(
verb_dict
)
mark_dict_len
=
2
word_dim
=
32
mark_dim
=
5
hidden_dim
=
512
depth
=
8
mix_hidden_lr
=
1e-3
embedding_name
=
'emb'
def
db_lstm
(
word
,
predicate
,
ctx_n2
,
ctx_n1
,
ctx_0
,
ctx_p1
,
ctx_p2
,
mark
,
is_sparse
,
**
ignored
):
# 8 features
predicate_embedding
=
fluid
.
layers
.
embedding
(
input
=
predicate
,
is_sparse
=
is_sparse
,
size
=
[
pred_dict_len
,
word_dim
],
dtype
=
'float32'
,
param_attr
=
'vemb'
)
mark_embedding
=
fluid
.
layers
.
embedding
(
input
=
mark
,
is_sparse
=
is_sparse
,
size
=
[
mark_dict_len
,
mark_dim
],
dtype
=
'float32'
)
word_input
=
[
word
,
ctx_n2
,
ctx_n1
,
ctx_0
,
ctx_p1
,
ctx_p2
]
emb_layers
=
[
fluid
.
layers
.
embedding
(
size
=
[
word_dict_len
,
word_dim
],
is_sparse
=
is_sparse
,
input
=
x
,
param_attr
=
fluid
.
ParamAttr
(
name
=
embedding_name
,
trainable
=
False
))
for
x
in
word_input
]
emb_layers
.
append
(
predicate_embedding
)
emb_layers
.
append
(
mark_embedding
)
hidden_0_layers
=
[
fluid
.
layers
.
fc
(
input
=
emb
,
size
=
hidden_dim
,
act
=
'tanh'
)
for
emb
in
emb_layers
]
hidden_0
=
fluid
.
layers
.
sums
(
input
=
hidden_0_layers
)
lstm_0
=
fluid
.
layers
.
dynamic_lstm
(
input
=
hidden_0
,
size
=
hidden_dim
,
candidate_activation
=
'relu'
,
gate_activation
=
'sigmoid'
,
cell_activation
=
'sigmoid'
)
# stack L-LSTM and R-LSTM with direct edges
input_tmp
=
[
hidden_0
,
lstm_0
]
for
i
in
range
(
1
,
depth
):
mix_hidden
=
fluid
.
layers
.
sums
(
input
=
[
fluid
.
layers
.
fc
(
input
=
input_tmp
[
0
],
size
=
hidden_dim
,
act
=
'tanh'
),
fluid
.
layers
.
fc
(
input
=
input_tmp
[
1
],
size
=
hidden_dim
,
act
=
'tanh'
)
])
lstm
=
fluid
.
layers
.
dynamic_lstm
(
input
=
mix_hidden
,
size
=
hidden_dim
,
candidate_activation
=
'relu'
,
gate_activation
=
'sigmoid'
,
cell_activation
=
'sigmoid'
,
is_reverse
=
((
i
%
2
)
==
1
))
input_tmp
=
[
mix_hidden
,
lstm
]
feature_out
=
fluid
.
layers
.
sums
(
input
=
[
fluid
.
layers
.
fc
(
input
=
input_tmp
[
0
],
size
=
label_dict_len
,
act
=
'tanh'
),
fluid
.
layers
.
fc
(
input
=
input_tmp
[
1
],
size
=
label_dict_len
,
act
=
'tanh'
)
])
return
feature_out
class
TestCRFModel
(
unittest
.
TestCase
):
def
check_network_convergence
(
self
,
is_sparse
,
build_strategy
=
None
):
main
=
fluid
.
Program
()
startup
=
fluid
.
Program
()
with
fluid
.
program_guard
(
main
,
startup
):
word
=
fluid
.
layers
.
data
(
name
=
'word_data'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
predicate
=
fluid
.
layers
.
data
(
name
=
'verb_data'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
ctx_n2
=
fluid
.
layers
.
data
(
name
=
'ctx_n2_data'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
ctx_n1
=
fluid
.
layers
.
data
(
name
=
'ctx_n1_data'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
ctx_0
=
fluid
.
layers
.
data
(
name
=
'ctx_0_data'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
ctx_p1
=
fluid
.
layers
.
data
(
name
=
'ctx_p1_data'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
ctx_p2
=
fluid
.
layers
.
data
(
name
=
'ctx_p2_data'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
mark
=
fluid
.
layers
.
data
(
name
=
'mark_data'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
feature_out
=
db_lstm
(
**
locals
())
target
=
fluid
.
layers
.
data
(
name
=
'target'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
crf_cost
=
fluid
.
layers
.
linear_chain_crf
(
input
=
feature_out
,
label
=
target
,
param_attr
=
fluid
.
ParamAttr
(
name
=
'crfw'
,
learning_rate
=
1e-1
))
avg_cost
=
fluid
.
layers
.
mean
(
crf_cost
)
sgd_optimizer
=
fluid
.
optimizer
.
SGD
(
learning_rate
=
fluid
.
layers
.
exponential_decay
(
learning_rate
=
0.01
,
decay_steps
=
100000
,
decay_rate
=
0.5
,
staircase
=
True
))
sgd_optimizer
.
minimize
(
avg_cost
)
train_data
=
paddle
.
batch
(
paddle
.
reader
.
shuffle
(
paddle
.
dataset
.
conll05
.
test
(),
buf_size
=
8192
),
batch_size
=
16
)
place
=
fluid
.
CUDAPlace
(
0
)
exe
=
fluid
.
Executor
(
place
)
exe
.
run
(
startup
)
pe
=
fluid
.
ParallelExecutor
(
use_cuda
=
True
,
loss_name
=
avg_cost
.
name
,
build_strategy
=
build_strategy
)
feeder
=
fluid
.
DataFeeder
(
feed_list
=
[
word
,
ctx_n2
,
ctx_n1
,
ctx_0
,
ctx_p1
,
ctx_p2
,
predicate
,
mark
,
target
],
place
=
fluid
.
CPUPlace
())
data
=
train_data
()
for
i
in
xrange
(
10
):
cur_batch
=
next
(
data
)
print
map
(
np
.
array
,
pe
.
run
(
feed
=
feeder
.
feed
(
cur_batch
),
fetch_list
=
[
avg_cost
.
name
]))[
0
]
def
test_update_sparse_parameter_all_reduce
(
self
):
build_strategy
=
fluid
.
BuildStrategy
()
build_strategy
.
reduce_strategy
=
fluid
.
BuildStrategy
.
ReduceStrategy
.
AllReduce
self
.
check_network_convergence
(
is_sparse
=
True
,
build_strategy
=
build_strategy
)
def
test_update_dense_parameter_all_reduce
(
self
):
build_strategy
=
fluid
.
BuildStrategy
()
build_strategy
.
reduce_strategy
=
fluid
.
BuildStrategy
.
ReduceStrategy
.
AllReduce
self
.
check_network_convergence
(
is_sparse
=
False
,
build_strategy
=
build_strategy
)
def
test_update_sparse_parameter_reduce
(
self
):
build_strategy
=
fluid
.
BuildStrategy
()
build_strategy
.
reduce_strategy
=
fluid
.
BuildStrategy
.
ReduceStrategy
.
Reduce
self
.
check_network_convergence
(
is_sparse
=
True
,
build_strategy
=
build_strategy
)
def
test_update_dense_parameter_reduce
(
self
):
build_strategy
=
fluid
.
BuildStrategy
()
build_strategy
.
reduce_strategy
=
fluid
.
BuildStrategy
.
ReduceStrategy
.
Reduce
self
.
check_network_convergence
(
is_sparse
=
False
,
build_strategy
=
build_strategy
)
# test fetch all the variables of global_block
import
paddle.dataset.flowers
as
flowers
import
math
def
Lenet
(
data
,
class_dim
):
conv1
=
fluid
.
layers
.
conv2d
(
data
,
32
,
5
,
1
,
act
=
None
)
bn1
=
fluid
.
layers
.
batch_norm
(
conv1
,
act
=
'relu'
)
pool1
=
fluid
.
layers
.
pool2d
(
bn1
,
2
,
'max'
,
2
)
conv2
=
fluid
.
layers
.
conv2d
(
pool1
,
50
,
5
,
1
,
act
=
None
)
bn2
=
fluid
.
layers
.
batch_norm
(
conv2
,
act
=
'relu'
)
pool2
=
fluid
.
layers
.
pool2d
(
bn2
,
2
,
'max'
,
2
)
fc1
=
fluid
.
layers
.
fc
(
pool2
,
size
=
500
,
act
=
'relu'
)
fc2
=
fluid
.
layers
.
fc
(
fc1
,
size
=
class_dim
,
act
=
'softmax'
)
return
fc2
class
TestFetchOp
(
unittest
.
TestCase
):
def
parallel_exe
(
self
,
train_inputs
,
seed
):
main
=
fluid
.
Program
()
startup
=
fluid
.
Program
()
startup
.
random_seed
=
seed
with
fluid
.
program_guard
(
main
,
startup
):
data
=
fluid
.
layers
.
data
(
name
=
'image'
,
shape
=
[
3
,
224
,
224
],
dtype
=
'float32'
)
label
=
fluid
.
layers
.
data
(
name
=
'label'
,
shape
=
[
1
],
dtype
=
'int64'
)
out
=
Lenet
(
data
,
class_dim
=
102
)
loss
=
fluid
.
layers
.
cross_entropy
(
input
=
out
,
label
=
label
)
loss
=
fluid
.
layers
.
mean
(
loss
)
opt
=
fluid
.
optimizer
.
Momentum
(
learning_rate
=
0.1
,
momentum
=
0.9
,
regularization
=
fluid
.
regularizer
.
L2Decay
(
1e-4
))
opt
.
minimize
(
loss
)
# TODO(zcd): I found that onece the memory optimizer is open,
# parallel_exe doesn't fetch some variable, such as conv2d_0.b_0@GRAD,
# conv2d_1.b_0@GRAD. Those variables should not be pruned.
# fluid.memory_optimize(main)
place
=
fluid
.
CUDAPlace
(
0
)
exe
=
fluid
.
Executor
(
place
)
exe
.
run
(
startup
)
feeder
=
fluid
.
DataFeeder
(
place
=
place
,
feed_list
=
[
data
,
label
])
pe
=
fluid
.
ParallelExecutor
(
use_cuda
=
True
,
loss_name
=
loss
.
name
,
main_program
=
main
)
fetch_list
=
[]
all_vars
=
main
.
global_block
().
vars
for
k
,
v
in
all_vars
.
iteritems
():
if
'tmp'
not
in
k
and
k
[
0
]
is
not
'_'
or
v
.
persistable
:
fetch_list
.
append
(
k
)
for
data
in
train_inputs
:
ret
=
pe
.
run
(
fetch_list
,
feed
=
feeder
.
feed
(
data
))
for
i
in
range
(
len
(
fetch_list
)):
assert
not
math
.
isnan
(
np
.
sum
(
ret
[
i
]))
and
\
not
math
.
isinf
(
np
.
sum
(
ret
[
i
]))
def
test_fetch_op
(
self
):
tst_reader
=
paddle
.
batch
(
flowers
.
test
(
use_xmap
=
False
),
batch_size
=
16
)
tst_reader_iter
=
tst_reader
()
iters
=
3
train_inputs
=
[]
for
i
in
range
(
iters
):
train_inputs
.
append
(
tst_reader_iter
.
next
())
self
.
parallel_exe
(
train_inputs
,
seed
=
1
)
class
TestFeedParallel
(
unittest
.
TestCase
):
def
test_main
(
self
):
main
=
fluid
.
Program
()
startup
=
fluid
.
Program
()
startup
.
random_seed
=
1
with
fluid
.
scope_guard
(
fluid
.
core
.
Scope
()):
with
fluid
.
program_guard
(
main
,
startup
):
data
=
fluid
.
layers
.
data
(
name
=
'image'
,
shape
=
[
3
,
224
,
224
],
dtype
=
'float32'
)
label
=
fluid
.
layers
.
data
(
name
=
'label'
,
shape
=
[
1
],
dtype
=
'int64'
)
out
=
Lenet
(
data
,
class_dim
=
102
)
loss
=
fluid
.
layers
.
cross_entropy
(
input
=
out
,
label
=
label
)
loss
=
fluid
.
layers
.
mean
(
loss
)
opt
=
fluid
.
optimizer
.
Momentum
(
learning_rate
=
0.1
,
momentum
=
0.9
,
regularization
=
fluid
.
regularizer
.
L2Decay
(
1e-4
))
opt
.
minimize
(
loss
)
place
=
fluid
.
CUDAPlace
(
0
)
feeder
=
fluid
.
DataFeeder
(
place
=
place
,
feed_list
=
[
data
,
label
])
reader
=
feeder
.
decorate_reader
(
paddle
.
batch
(
flowers
.
train
(),
batch_size
=
16
),
multi_devices
=
True
)
exe
=
fluid
.
Executor
(
place
)
exe
.
run
(
startup
)
pe
=
fluid
.
ParallelExecutor
(
use_cuda
=
True
,
loss_name
=
loss
.
name
,
main_program
=
main
)
for
batch_id
,
data
in
enumerate
(
reader
()):
loss_np
=
np
.
array
(
pe
.
run
(
feed
=
data
,
fetch_list
=
[
loss
.
name
])[
0
])
print
batch_id
,
loss_np
if
batch_id
==
2
:
break
if
__name__
==
'__main__'
:
unittest
.
main
()
python/paddle/fluid/tests/unittests/test_parallel_executor_crf.py
0 → 100644
浏览文件 @
f0651511
# Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import
paddle.dataset.conll05
as
conll05
import
paddle.fluid
as
fluid
import
unittest
import
paddle
import
numpy
as
np
word_dict
,
verb_dict
,
label_dict
=
conll05
.
get_dict
()
word_dict_len
=
len
(
word_dict
)
label_dict_len
=
len
(
label_dict
)
pred_dict_len
=
len
(
verb_dict
)
mark_dict_len
=
2
word_dim
=
32
mark_dim
=
5
hidden_dim
=
512
depth
=
8
mix_hidden_lr
=
1e-3
embedding_name
=
'emb'
def
db_lstm
(
word
,
predicate
,
ctx_n2
,
ctx_n1
,
ctx_0
,
ctx_p1
,
ctx_p2
,
mark
,
is_sparse
,
**
ignored
):
# 8 features
predicate_embedding
=
fluid
.
layers
.
embedding
(
input
=
predicate
,
is_sparse
=
is_sparse
,
size
=
[
pred_dict_len
,
word_dim
],
dtype
=
'float32'
,
param_attr
=
'vemb'
)
mark_embedding
=
fluid
.
layers
.
embedding
(
input
=
mark
,
is_sparse
=
is_sparse
,
size
=
[
mark_dict_len
,
mark_dim
],
dtype
=
'float32'
)
word_input
=
[
word
,
ctx_n2
,
ctx_n1
,
ctx_0
,
ctx_p1
,
ctx_p2
]
emb_layers
=
[
fluid
.
layers
.
embedding
(
size
=
[
word_dict_len
,
word_dim
],
is_sparse
=
is_sparse
,
input
=
x
,
param_attr
=
fluid
.
ParamAttr
(
name
=
embedding_name
,
trainable
=
False
))
for
x
in
word_input
]
emb_layers
.
append
(
predicate_embedding
)
emb_layers
.
append
(
mark_embedding
)
hidden_0_layers
=
[
fluid
.
layers
.
fc
(
input
=
emb
,
size
=
hidden_dim
,
act
=
'tanh'
)
for
emb
in
emb_layers
]
hidden_0
=
fluid
.
layers
.
sums
(
input
=
hidden_0_layers
)
lstm_0
=
fluid
.
layers
.
dynamic_lstm
(
input
=
hidden_0
,
size
=
hidden_dim
,
candidate_activation
=
'relu'
,
gate_activation
=
'sigmoid'
,
cell_activation
=
'sigmoid'
)
# stack L-LSTM and R-LSTM with direct edges
input_tmp
=
[
hidden_0
,
lstm_0
]
for
i
in
range
(
1
,
depth
):
mix_hidden
=
fluid
.
layers
.
sums
(
input
=
[
fluid
.
layers
.
fc
(
input
=
input_tmp
[
0
],
size
=
hidden_dim
,
act
=
'tanh'
),
fluid
.
layers
.
fc
(
input
=
input_tmp
[
1
],
size
=
hidden_dim
,
act
=
'tanh'
)
])
lstm
=
fluid
.
layers
.
dynamic_lstm
(
input
=
mix_hidden
,
size
=
hidden_dim
,
candidate_activation
=
'relu'
,
gate_activation
=
'sigmoid'
,
cell_activation
=
'sigmoid'
,
is_reverse
=
((
i
%
2
)
==
1
))
input_tmp
=
[
mix_hidden
,
lstm
]
feature_out
=
fluid
.
layers
.
sums
(
input
=
[
fluid
.
layers
.
fc
(
input
=
input_tmp
[
0
],
size
=
label_dict_len
,
act
=
'tanh'
),
fluid
.
layers
.
fc
(
input
=
input_tmp
[
1
],
size
=
label_dict_len
,
act
=
'tanh'
)
])
return
feature_out
class
TestCRFModel
(
unittest
.
TestCase
):
def
check_network_convergence
(
self
,
is_sparse
,
build_strategy
=
None
):
main
=
fluid
.
Program
()
startup
=
fluid
.
Program
()
with
fluid
.
program_guard
(
main
,
startup
):
word
=
fluid
.
layers
.
data
(
name
=
'word_data'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
predicate
=
fluid
.
layers
.
data
(
name
=
'verb_data'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
ctx_n2
=
fluid
.
layers
.
data
(
name
=
'ctx_n2_data'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
ctx_n1
=
fluid
.
layers
.
data
(
name
=
'ctx_n1_data'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
ctx_0
=
fluid
.
layers
.
data
(
name
=
'ctx_0_data'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
ctx_p1
=
fluid
.
layers
.
data
(
name
=
'ctx_p1_data'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
ctx_p2
=
fluid
.
layers
.
data
(
name
=
'ctx_p2_data'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
mark
=
fluid
.
layers
.
data
(
name
=
'mark_data'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
feature_out
=
db_lstm
(
**
locals
())
target
=
fluid
.
layers
.
data
(
name
=
'target'
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
crf_cost
=
fluid
.
layers
.
linear_chain_crf
(
input
=
feature_out
,
label
=
target
,
param_attr
=
fluid
.
ParamAttr
(
name
=
'crfw'
,
learning_rate
=
1e-1
))
avg_cost
=
fluid
.
layers
.
mean
(
crf_cost
)
sgd_optimizer
=
fluid
.
optimizer
.
SGD
(
learning_rate
=
fluid
.
layers
.
exponential_decay
(
learning_rate
=
0.01
,
decay_steps
=
100000
,
decay_rate
=
0.5
,
staircase
=
True
))
sgd_optimizer
.
minimize
(
avg_cost
)
train_data
=
paddle
.
batch
(
paddle
.
reader
.
shuffle
(
paddle
.
dataset
.
conll05
.
test
(),
buf_size
=
8192
),
batch_size
=
16
)
place
=
fluid
.
CUDAPlace
(
0
)
exe
=
fluid
.
Executor
(
place
)
exe
.
run
(
startup
)
pe
=
fluid
.
ParallelExecutor
(
use_cuda
=
True
,
loss_name
=
avg_cost
.
name
,
build_strategy
=
build_strategy
)
feeder
=
fluid
.
DataFeeder
(
feed_list
=
[
word
,
ctx_n2
,
ctx_n1
,
ctx_0
,
ctx_p1
,
ctx_p2
,
predicate
,
mark
,
target
],
place
=
fluid
.
CPUPlace
())
data
=
train_data
()
for
i
in
xrange
(
10
):
cur_batch
=
next
(
data
)
print
map
(
np
.
array
,
pe
.
run
(
feed
=
feeder
.
feed
(
cur_batch
),
fetch_list
=
[
avg_cost
.
name
]))[
0
]
def
test_update_sparse_parameter_all_reduce
(
self
):
build_strategy
=
fluid
.
BuildStrategy
()
build_strategy
.
reduce_strategy
=
fluid
.
BuildStrategy
.
ReduceStrategy
.
AllReduce
self
.
check_network_convergence
(
is_sparse
=
True
,
build_strategy
=
build_strategy
)
def
test_update_dense_parameter_all_reduce
(
self
):
build_strategy
=
fluid
.
BuildStrategy
()
build_strategy
.
reduce_strategy
=
fluid
.
BuildStrategy
.
ReduceStrategy
.
AllReduce
self
.
check_network_convergence
(
is_sparse
=
False
,
build_strategy
=
build_strategy
)
def
test_update_sparse_parameter_reduce
(
self
):
build_strategy
=
fluid
.
BuildStrategy
()
build_strategy
.
reduce_strategy
=
fluid
.
BuildStrategy
.
ReduceStrategy
.
Reduce
self
.
check_network_convergence
(
is_sparse
=
True
,
build_strategy
=
build_strategy
)
def
test_update_dense_parameter_reduce
(
self
):
build_strategy
=
fluid
.
BuildStrategy
()
build_strategy
.
reduce_strategy
=
fluid
.
BuildStrategy
.
ReduceStrategy
.
Reduce
self
.
check_network_convergence
(
is_sparse
=
False
,
build_strategy
=
build_strategy
)
if
__name__
==
'__main__'
:
unittest
.
main
()
python/paddle/fluid/tests/unittests/test_parallel_executor_fetch_feed.py
0 → 100644
浏览文件 @
f0651511
# Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import
paddle.dataset.flowers
as
flowers
import
math
import
paddle.fluid
as
fluid
import
unittest
import
numpy
as
np
import
paddle
def
Lenet
(
data
,
class_dim
):
conv1
=
fluid
.
layers
.
conv2d
(
data
,
32
,
5
,
1
,
act
=
None
)
bn1
=
fluid
.
layers
.
batch_norm
(
conv1
,
act
=
'relu'
)
pool1
=
fluid
.
layers
.
pool2d
(
bn1
,
2
,
'max'
,
2
)
conv2
=
fluid
.
layers
.
conv2d
(
pool1
,
50
,
5
,
1
,
act
=
None
)
bn2
=
fluid
.
layers
.
batch_norm
(
conv2
,
act
=
'relu'
)
pool2
=
fluid
.
layers
.
pool2d
(
bn2
,
2
,
'max'
,
2
)
fc1
=
fluid
.
layers
.
fc
(
pool2
,
size
=
500
,
act
=
'relu'
)
fc2
=
fluid
.
layers
.
fc
(
fc1
,
size
=
class_dim
,
act
=
'softmax'
)
return
fc2
class
TestFetchOp
(
unittest
.
TestCase
):
def
parallel_exe
(
self
,
train_inputs
,
seed
):
main
=
fluid
.
Program
()
startup
=
fluid
.
Program
()
startup
.
random_seed
=
seed
with
fluid
.
program_guard
(
main
,
startup
):
data
=
fluid
.
layers
.
data
(
name
=
'image'
,
shape
=
[
3
,
224
,
224
],
dtype
=
'float32'
)
label
=
fluid
.
layers
.
data
(
name
=
'label'
,
shape
=
[
1
],
dtype
=
'int64'
)
out
=
Lenet
(
data
,
class_dim
=
102
)
loss
=
fluid
.
layers
.
cross_entropy
(
input
=
out
,
label
=
label
)
loss
=
fluid
.
layers
.
mean
(
loss
)
opt
=
fluid
.
optimizer
.
Momentum
(
learning_rate
=
0.1
,
momentum
=
0.9
,
regularization
=
fluid
.
regularizer
.
L2Decay
(
1e-4
))
opt
.
minimize
(
loss
)
# TODO(zcd): I found that onece the memory optimizer is open,
# parallel_exe doesn't fetch some variable, such as conv2d_0.b_0@GRAD,
# conv2d_1.b_0@GRAD. Those variables should not be pruned.
# fluid.memory_optimize(main)
place
=
fluid
.
CUDAPlace
(
0
)
exe
=
fluid
.
Executor
(
place
)
exe
.
run
(
startup
)
feeder
=
fluid
.
DataFeeder
(
place
=
place
,
feed_list
=
[
data
,
label
])
pe
=
fluid
.
ParallelExecutor
(
use_cuda
=
True
,
loss_name
=
loss
.
name
,
main_program
=
main
)
fetch_list
=
[]
all_vars
=
main
.
global_block
().
vars
for
k
,
v
in
all_vars
.
iteritems
():
if
'tmp'
not
in
k
and
k
[
0
]
is
not
'_'
or
v
.
persistable
:
fetch_list
.
append
(
k
)
for
data
in
train_inputs
:
ret
=
pe
.
run
(
fetch_list
,
feed
=
feeder
.
feed
(
data
))
for
i
in
range
(
len
(
fetch_list
)):
assert
not
math
.
isnan
(
np
.
sum
(
ret
[
i
]))
and
\
not
math
.
isinf
(
np
.
sum
(
ret
[
i
]))
def
test_fetch_op
(
self
):
tst_reader
=
paddle
.
batch
(
flowers
.
test
(
use_xmap
=
False
),
batch_size
=
16
)
tst_reader_iter
=
tst_reader
()
iters
=
3
train_inputs
=
[]
for
i
in
range
(
iters
):
train_inputs
.
append
(
tst_reader_iter
.
next
())
self
.
parallel_exe
(
train_inputs
,
seed
=
1
)
class
TestFeedParallel
(
unittest
.
TestCase
):
def
test_main
(
self
):
main
=
fluid
.
Program
()
startup
=
fluid
.
Program
()
startup
.
random_seed
=
1
with
fluid
.
scope_guard
(
fluid
.
core
.
Scope
()):
with
fluid
.
program_guard
(
main
,
startup
):
data
=
fluid
.
layers
.
data
(
name
=
'image'
,
shape
=
[
3
,
224
,
224
],
dtype
=
'float32'
)
label
=
fluid
.
layers
.
data
(
name
=
'label'
,
shape
=
[
1
],
dtype
=
'int64'
)
out
=
Lenet
(
data
,
class_dim
=
102
)
loss
=
fluid
.
layers
.
cross_entropy
(
input
=
out
,
label
=
label
)
loss
=
fluid
.
layers
.
mean
(
loss
)
opt
=
fluid
.
optimizer
.
Momentum
(
learning_rate
=
0.1
,
momentum
=
0.9
,
regularization
=
fluid
.
regularizer
.
L2Decay
(
1e-4
))
opt
.
minimize
(
loss
)
place
=
fluid
.
CUDAPlace
(
0
)
feeder
=
fluid
.
DataFeeder
(
place
=
place
,
feed_list
=
[
data
,
label
])
reader
=
feeder
.
decorate_reader
(
paddle
.
batch
(
flowers
.
train
(),
batch_size
=
16
),
multi_devices
=
True
)
exe
=
fluid
.
Executor
(
place
)
exe
.
run
(
startup
)
pe
=
fluid
.
ParallelExecutor
(
use_cuda
=
True
,
loss_name
=
loss
.
name
,
main_program
=
main
)
for
batch_id
,
data
in
enumerate
(
reader
()):
loss_np
=
np
.
array
(
pe
.
run
(
feed
=
data
,
fetch_list
=
[
loss
.
name
])[
0
])
print
batch_id
,
loss_np
if
batch_id
==
2
:
break
if
__name__
==
'__main__'
:
unittest
.
main
()
python/paddle/fluid/tests/unittests/test_parallel_executor_mnist.py
0 → 100644
浏览文件 @
f0651511
# 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
parallel_executor_test_base
import
TestParallelExecutorBase
import
paddle.fluid
as
fluid
import
numpy
as
np
import
paddle
import
paddle.dataset.mnist
as
mnist
import
unittest
MNIST_RECORDIO_FILE
=
"./mnist_test_pe.recordio"
def
simple_fc_net
(
use_feed
):
if
use_feed
:
img
=
fluid
.
layers
.
data
(
name
=
'image'
,
shape
=
[
784
],
dtype
=
'float32'
)
label
=
fluid
.
layers
.
data
(
name
=
'label'
,
shape
=
[
1
],
dtype
=
'int64'
)
else
:
reader
=
fluid
.
layers
.
open_files
(
filenames
=
[
MNIST_RECORDIO_FILE
],
shapes
=
[[
-
1
,
784
],
[
-
1
,
1
]],
lod_levels
=
[
0
,
0
],
dtypes
=
[
'float32'
,
'int64'
],
thread_num
=
1
,
for_parallel
=
True
)
reader
=
fluid
.
layers
.
io
.
double_buffer
(
reader
)
img
,
label
=
fluid
.
layers
.
read_file
(
reader
)
hidden
=
img
for
_
in
xrange
(
4
):
hidden
=
fluid
.
layers
.
fc
(
hidden
,
size
=
200
,
act
=
'tanh'
,
bias_attr
=
fluid
.
ParamAttr
(
initializer
=
fluid
.
initializer
.
Constant
(
value
=
1.0
)))
prediction
=
fluid
.
layers
.
fc
(
hidden
,
size
=
10
,
act
=
'softmax'
)
loss
=
fluid
.
layers
.
cross_entropy
(
input
=
prediction
,
label
=
label
)
loss
=
fluid
.
layers
.
mean
(
loss
)
return
loss
def
fc_with_batchnorm
(
use_feed
):
if
use_feed
:
img
=
fluid
.
layers
.
data
(
name
=
'image'
,
shape
=
[
784
],
dtype
=
'float32'
)
label
=
fluid
.
layers
.
data
(
name
=
'label'
,
shape
=
[
1
],
dtype
=
'int64'
)
else
:
reader
=
fluid
.
layers
.
open_files
(
filenames
=
[
MNIST_RECORDIO_FILE
],
shapes
=
[[
-
1
,
784
],
[
-
1
,
1
]],
lod_levels
=
[
0
,
0
],
dtypes
=
[
'float32'
,
'int64'
],
thread_num
=
1
,
for_parallel
=
True
)
reader
=
fluid
.
layers
.
io
.
double_buffer
(
reader
)
img
,
label
=
fluid
.
layers
.
read_file
(
reader
)
hidden
=
img
for
_
in
xrange
(
1
):
hidden
=
fluid
.
layers
.
fc
(
hidden
,
size
=
200
,
act
=
'tanh'
,
bias_attr
=
fluid
.
ParamAttr
(
initializer
=
fluid
.
initializer
.
Constant
(
value
=
1.0
)))
hidden
=
fluid
.
layers
.
batch_norm
(
input
=
hidden
)
prediction
=
fluid
.
layers
.
fc
(
hidden
,
size
=
10
,
act
=
'softmax'
)
loss
=
fluid
.
layers
.
cross_entropy
(
input
=
prediction
,
label
=
label
)
loss
=
fluid
.
layers
.
mean
(
loss
)
return
loss
class
TestMNIST
(
TestParallelExecutorBase
):
@
classmethod
def
setUpClass
(
cls
):
# Convert mnist to recordio file
with
fluid
.
program_guard
(
fluid
.
Program
(),
fluid
.
Program
()):
reader
=
paddle
.
batch
(
mnist
.
train
(),
batch_size
=
4
)
feeder
=
fluid
.
DataFeeder
(
feed_list
=
[
# order is image and label
fluid
.
layers
.
data
(
name
=
'image'
,
shape
=
[
784
]),
fluid
.
layers
.
data
(
name
=
'label'
,
shape
=
[
1
],
dtype
=
'int64'
),
],
place
=
fluid
.
CPUPlace
())
fluid
.
recordio_writer
.
convert_reader_to_recordio_file
(
MNIST_RECORDIO_FILE
,
reader
,
feeder
)
def
check_simple_fc_convergence
(
self
,
balance_parameter_opt_between_cards
):
self
.
check_network_convergence
(
simple_fc_net
)
self
.
check_network_convergence
(
simple_fc_net
,
allow_op_delay
=
True
)
img
=
np
.
zeros
(
shape
=
[
32
,
784
],
dtype
=
'float32'
)
label
=
np
.
ones
(
shape
=
[
32
,
1
],
dtype
=
'int64'
)
self
.
check_network_convergence
(
simple_fc_net
,
feed_dict
=
{
"image"
:
img
,
"label"
:
label
},
balance_parameter_opt_between_cards
=
balance_parameter_opt_between_cards
)
def
test_simple_fc
(
self
):
self
.
check_simple_fc_convergence
(
False
)
def
test_simple_fc_with_new_strategy
(
self
):
self
.
check_simple_fc_convergence
(
True
)
def
check_simple_fc_parallel_accuracy
(
self
,
balance_parameter_opt_between_cards
):
img
=
np
.
zeros
(
shape
=
[
32
,
784
],
dtype
=
'float32'
)
label
=
np
.
ones
(
shape
=
[
32
,
1
],
dtype
=
'int64'
)
single_first_loss
,
single_last_loss
=
self
.
check_network_convergence
(
method
=
simple_fc_net
,
seed
=
1000
,
feed_dict
=
{
"image"
:
img
,
"label"
:
label
},
use_parallel_executor
=
False
)
parallel_first_loss
,
parallel_last_loss
=
self
.
check_network_convergence
(
method
=
simple_fc_net
,
seed
=
1000
,
feed_dict
=
{
"image"
:
img
,
"label"
:
label
},
use_parallel_executor
=
True
,
balance_parameter_opt_between_cards
=
balance_parameter_opt_between_cards
)
for
p_f
in
parallel_first_loss
:
self
.
assertAlmostEquals
(
p_f
,
single_first_loss
[
0
],
delta
=
1e-6
)
for
p_l
in
parallel_last_loss
:
self
.
assertAlmostEquals
(
p_l
,
single_last_loss
[
0
],
delta
=
1e-6
)
def
test_simple_fc_parallel_accuracy
(
self
):
self
.
check_simple_fc_parallel_accuracy
(
False
)
def
test_simple_fc_parallel_accuracy_with_new_strategy
(
self
):
self
.
check_simple_fc_parallel_accuracy
(
True
)
def
check_batchnorm_fc_convergence
(
self
,
balance_parameter_opt_between_cards
):
self
.
check_network_convergence
(
fc_with_batchnorm
)
img
=
np
.
zeros
(
shape
=
[
32
,
784
],
dtype
=
'float32'
)
label
=
np
.
ones
(
shape
=
[
32
,
1
],
dtype
=
'int64'
)
self
.
check_network_convergence
(
fc_with_batchnorm
,
feed_dict
=
{
"image"
:
img
,
"label"
:
label
},
balance_parameter_opt_between_cards
=
balance_parameter_opt_between_cards
)
def
test_batchnorm_fc
(
self
):
self
.
check_batchnorm_fc_convergence
(
False
)
def
test_batchnorm_fc_with_new_strategy
(
self
):
self
.
check_batchnorm_fc_convergence
(
True
)
if
__name__
==
'__main__'
:
unittest
.
main
()
python/paddle/fluid/tests/unittests/test_parallel_executor_seresnext.py
0 → 100644
浏览文件 @
f0651511
# Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import
paddle.fluid
as
fluid
from
parallel_executor_test_base
import
TestParallelExecutorBase
import
unittest
def
squeeze_excitation
(
input
,
num_channels
,
reduction_ratio
):
# pool = fluid.layers.pool2d(
# input=input, pool_size=0, pool_type='avg', global_pooling=True)
conv
=
input
shape
=
conv
.
shape
reshape
=
fluid
.
layers
.
reshape
(
x
=
conv
,
shape
=
[
-
1
,
shape
[
1
],
shape
[
2
]
*
shape
[
3
]])
pool
=
fluid
.
layers
.
reduce_mean
(
input
=
reshape
,
dim
=
2
)
squeeze
=
fluid
.
layers
.
fc
(
input
=
pool
,
size
=
num_channels
/
reduction_ratio
,
act
=
'relu'
)
excitation
=
fluid
.
layers
.
fc
(
input
=
squeeze
,
size
=
num_channels
,
act
=
'sigmoid'
)
scale
=
fluid
.
layers
.
elementwise_mul
(
x
=
input
,
y
=
excitation
,
axis
=
0
)
return
scale
def
conv_bn_layer
(
input
,
num_filters
,
filter_size
,
stride
=
1
,
groups
=
1
,
act
=
None
):
conv
=
fluid
.
layers
.
conv2d
(
input
=
input
,
num_filters
=
num_filters
,
filter_size
=
filter_size
,
stride
=
stride
,
padding
=
(
filter_size
-
1
)
/
2
,
groups
=
groups
,
act
=
None
,
bias_attr
=
False
)
return
fluid
.
layers
.
batch_norm
(
input
=
conv
,
act
=
act
,
momentum
=
0.1
)
def
shortcut
(
input
,
ch_out
,
stride
):
ch_in
=
input
.
shape
[
1
]
if
ch_in
!=
ch_out
:
if
stride
==
1
:
filter_size
=
1
else
:
filter_size
=
3
return
conv_bn_layer
(
input
,
ch_out
,
filter_size
,
stride
)
else
:
return
input
def
bottleneck_block
(
input
,
num_filters
,
stride
,
cardinality
,
reduction_ratio
):
# The number of first 1x1 convolutional channels for each bottleneck build block
# was halved to reduce the compution cost.
conv0
=
conv_bn_layer
(
input
=
input
,
num_filters
=
num_filters
,
filter_size
=
1
,
act
=
'relu'
)
conv1
=
conv_bn_layer
(
input
=
conv0
,
num_filters
=
num_filters
*
2
,
filter_size
=
3
,
stride
=
stride
,
groups
=
cardinality
,
act
=
'relu'
)
conv2
=
conv_bn_layer
(
input
=
conv1
,
num_filters
=
num_filters
*
2
,
filter_size
=
1
,
act
=
None
)
scale
=
squeeze_excitation
(
input
=
conv2
,
num_channels
=
num_filters
*
2
,
reduction_ratio
=
reduction_ratio
)
short
=
shortcut
(
input
,
num_filters
*
2
,
stride
)
return
fluid
.
layers
.
elementwise_add
(
x
=
short
,
y
=
scale
,
act
=
'relu'
)
def
SE_ResNeXt50Small
(
batch_size
=
2
,
use_feed
=
False
):
assert
not
use_feed
,
"SE_ResNeXt doesn't support feed yet"
img
=
fluid
.
layers
.
fill_constant
(
shape
=
[
batch_size
,
3
,
224
,
224
],
dtype
=
'float32'
,
value
=
0.0
)
label
=
fluid
.
layers
.
fill_constant
(
shape
=
[
batch_size
,
1
],
dtype
=
'int64'
,
value
=
0.0
)
conv
=
conv_bn_layer
(
input
=
img
,
num_filters
=
16
,
filter_size
=
3
,
stride
=
2
,
act
=
'relu'
)
conv
=
conv_bn_layer
(
input
=
conv
,
num_filters
=
16
,
filter_size
=
3
,
stride
=
1
,
act
=
'relu'
)
conv
=
conv_bn_layer
(
input
=
conv
,
num_filters
=
16
,
filter_size
=
3
,
stride
=
1
,
act
=
'relu'
)
conv
=
fluid
.
layers
.
pool2d
(
input
=
conv
,
pool_size
=
3
,
pool_stride
=
2
,
pool_padding
=
1
,
pool_type
=
'max'
)
cardinality
=
32
reduction_ratio
=
16
depth
=
[
3
,
4
,
6
,
3
]
num_filters
=
[
128
,
256
,
512
,
1024
]
for
block
in
range
(
len
(
depth
)):
for
i
in
range
(
depth
[
block
]):
conv
=
bottleneck_block
(
input
=
conv
,
num_filters
=
num_filters
[
block
],
stride
=
2
if
i
==
0
and
block
!=
0
else
1
,
cardinality
=
cardinality
,
reduction_ratio
=
reduction_ratio
)
shape
=
conv
.
shape
reshape
=
fluid
.
layers
.
reshape
(
x
=
conv
,
shape
=
[
-
1
,
shape
[
1
],
shape
[
2
]
*
shape
[
3
]])
pool
=
fluid
.
layers
.
reduce_mean
(
input
=
reshape
,
dim
=
2
)
dropout
=
fluid
.
layers
.
dropout
(
x
=
pool
,
dropout_prob
=
0.2
)
# Classifier layer:
prediction
=
fluid
.
layers
.
fc
(
input
=
dropout
,
size
=
1000
,
act
=
'softmax'
)
loss
=
fluid
.
layers
.
cross_entropy
(
input
=
prediction
,
label
=
label
)
loss
=
fluid
.
layers
.
mean
(
loss
)
return
loss
class
TestResnet
(
TestParallelExecutorBase
):
def
check_resnet_convergence
(
self
,
balance_parameter_opt_between_cards
):
import
functools
batch_size
=
2
self
.
check_network_convergence
(
functools
.
partial
(
SE_ResNeXt50Small
,
batch_size
=
batch_size
),
iter
=
20
,
batch_size
=
batch_size
,
balance_parameter_opt_between_cards
=
balance_parameter_opt_between_cards
)
def
test_resnet
(
self
):
self
.
check_resnet_convergence
(
False
)
def
test_resnet_with_new_strategy
(
self
):
self
.
check_resnet_convergence
(
True
)
if
__name__
==
'__main__'
:
unittest
.
main
()
python/paddle/fluid/tests/unittests/test_parallel_executor_test_while_train.py
0 → 100644
浏览文件 @
f0651511
# Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import
paddle.fluid
as
fluid
import
numpy
as
np
import
unittest
def
simple_fc_net
():
img
=
fluid
.
layers
.
data
(
name
=
'image'
,
shape
=
[
784
],
dtype
=
'float32'
)
label
=
fluid
.
layers
.
data
(
name
=
'label'
,
shape
=
[
1
],
dtype
=
'int64'
)
hidden
=
img
for
_
in
xrange
(
4
):
hidden
=
fluid
.
layers
.
fc
(
hidden
,
size
=
200
,
act
=
'tanh'
,
bias_attr
=
fluid
.
ParamAttr
(
initializer
=
fluid
.
initializer
.
Constant
(
value
=
1.0
)))
prediction
=
fluid
.
layers
.
fc
(
hidden
,
size
=
10
,
act
=
'softmax'
)
loss
=
fluid
.
layers
.
cross_entropy
(
input
=
prediction
,
label
=
label
)
loss
=
fluid
.
layers
.
mean
(
loss
)
return
loss
class
ParallelExecutorTestingDuringTraining
(
unittest
.
TestCase
):
def
check_network_convergence
(
self
,
build_strategy
=
None
):
main
=
fluid
.
Program
()
startup
=
fluid
.
Program
()
with
fluid
.
program_guard
(
main
,
startup
):
loss
=
simple_fc_net
()
test_program
=
main
.
clone
(
for_test
=
True
)
opt
=
fluid
.
optimizer
.
SGD
(
learning_rate
=
0.001
)
opt
.
minimize
(
loss
)
batch_size
=
32
image
=
np
.
random
.
normal
(
size
=
(
batch_size
,
784
)).
astype
(
'float32'
)
label
=
np
.
random
.
randint
(
0
,
10
,
(
batch_size
,
1
),
dtype
=
"int64"
)
place
=
fluid
.
CUDAPlace
(
0
)
exe
=
fluid
.
Executor
(
place
)
exe
.
run
(
startup
)
feed_dict
=
{
'image'
:
image
,
'label'
:
label
}
train_exe
=
fluid
.
ParallelExecutor
(
use_cuda
=
True
,
loss_name
=
loss
.
name
,
main_program
=
main
,
build_strategy
=
build_strategy
)
test_exe
=
fluid
.
ParallelExecutor
(
use_cuda
=
True
,
main_program
=
test_program
,
share_vars_from
=
train_exe
,
build_strategy
=
build_strategy
)
for
i
in
xrange
(
5
):
test_loss
,
=
test_exe
.
run
([
loss
.
name
],
feed
=
feed_dict
)
test_loss
=
np
.
array
(
test_loss
)
train_loss
,
=
train_exe
.
run
([
loss
.
name
],
feed
=
feed_dict
)
train_loss
=
np
.
array
(
train_loss
)
self
.
assertTrue
(
np
.
allclose
(
train_loss
,
test_loss
,
atol
=
1e-8
),
"Train loss: "
+
str
(
train_loss
)
+
"
\n
Test loss:"
+
str
(
test_loss
))
def
test_parallel_testing
(
self
):
build_strategy
=
fluid
.
BuildStrategy
()
build_strategy
.
reduce_strategy
=
fluid
.
BuildStrategy
.
ReduceStrategy
.
AllReduce
self
.
check_network_convergence
(
build_strategy
)
def
test_parallel_testing_with_new_strategy
(
self
):
build_strategy
=
fluid
.
BuildStrategy
()
build_strategy
.
reduce_strategy
=
fluid
.
BuildStrategy
.
ReduceStrategy
.
Reduce
self
.
check_network_convergence
(
build_strategy
)
if
__name__
==
'__main__'
:
unittest
.
main
()
python/paddle/fluid/tests/unittests/test_parallel_executor_transformer.py
0 → 100644
浏览文件 @
f0651511
# Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import
paddle.fluid
as
fluid
import
transformer_model
import
numpy
as
np
from
parallel_executor_test_base
import
TestParallelExecutorBase
import
unittest
import
paddle
import
paddle.dataset.wmt16
as
wmt16
WMT16_RECORDIO_FILE
=
"./wmt16_test_pe.recordio"
class
ModelHyperParams
(
object
):
# Dictionary size for source and target language. This model directly uses
# paddle.dataset.wmt16 in which <bos>, <eos> and <unk> token has
# alreay been added, but the <pad> token is not added. Transformer requires
# sequences in a mini-batch are padded to have the same length. A <pad> token is
# added into the original dictionary in paddle.dateset.wmt16.
# size of source word dictionary.
src_vocab_size
=
10000
# index for <pad> token in source language.
src_pad_idx
=
src_vocab_size
# size of target word dictionay
trg_vocab_size
=
10000
# index for <pad> token in target language.
trg_pad_idx
=
trg_vocab_size
# position value corresponding to the <pad> token.
pos_pad_idx
=
0
# max length of sequences. It should plus 1 to include position
# padding token for position encoding.
max_length
=
50
# 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.
d_inner_hid
=
1024
# 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.
dropout
=
0.1
def
prepare_batch_input
(
insts
,
src_pad_idx
,
trg_pad_idx
,
n_head
):
"""
Pad the instances to the max sequence length in batch, and generate the
corresponding position data and attention bias. Then, convert the numpy
data to tensors and return a dict mapping names to tensors.
"""
def
__pad_batch_data
(
insts
,
pad_idx
,
is_target
=
False
,
return_pos
=
True
,
return_attn_bias
=
True
,
return_max_len
=
True
):
"""
Pad the instances to the max sequence length in batch, and generate the
corresponding position data and attention bias.
"""
return_list
=
[]
max_len
=
max
(
len
(
inst
)
for
inst
in
insts
)
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
return_pos
:
inst_pos
=
np
.
array
([[
pos_i
+
1
if
w_i
!=
pad_idx
else
0
for
pos_i
,
w_i
in
enumerate
(
inst
)
]
for
inst
in
inst_data
])
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
]
return
return_list
if
len
(
return_list
)
>
1
else
return_list
[
0
]
src_word
,
src_pos
,
src_slf_attn_bias
,
src_max_len
=
__pad_batch_data
(
[
inst
[
0
]
for
inst
in
insts
],
src_pad_idx
,
is_target
=
False
)
trg_word
,
trg_pos
,
trg_slf_attn_bias
,
trg_max_len
=
__pad_batch_data
(
[
inst
[
1
]
for
inst
in
insts
],
trg_pad_idx
,
is_target
=
True
)
trg_src_attn_bias
=
np
.
tile
(
src_slf_attn_bias
[:,
:,
::
src_max_len
,
:],
[
1
,
1
,
trg_max_len
,
1
]).
astype
(
"float32"
)
lbl_word
=
__pad_batch_data
([
inst
[
2
]
for
inst
in
insts
],
trg_pad_idx
,
False
,
False
,
False
,
False
)
lbl_weight
=
(
lbl_word
!=
trg_pad_idx
).
astype
(
"float32"
).
reshape
([
-
1
,
1
])
return
[
src_word
,
src_pos
,
trg_word
,
trg_pos
,
src_slf_attn_bias
,
trg_slf_attn_bias
,
trg_src_attn_bias
,
lbl_word
,
lbl_weight
]
def
transformer
(
use_feed
):
assert
not
use_feed
,
"transfomer doesn't support feed yet"
return
transformer_model
.
transformer
(
ModelHyperParams
.
src_vocab_size
+
1
,
ModelHyperParams
.
trg_vocab_size
+
1
,
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
.
src_pad_idx
,
ModelHyperParams
.
trg_pad_idx
,
ModelHyperParams
.
pos_pad_idx
)
class
TestTransformer
(
TestParallelExecutorBase
):
@
classmethod
def
setUpClass
(
cls
):
reader
=
paddle
.
batch
(
wmt16
.
train
(
ModelHyperParams
.
src_vocab_size
,
ModelHyperParams
.
trg_vocab_size
),
batch_size
=
transformer_model
.
batch_size
)
with
fluid
.
recordio_writer
.
create_recordio_writer
(
WMT16_RECORDIO_FILE
)
as
writer
:
for
batch
in
reader
():
for
tensor
in
prepare_batch_input
(
batch
,
ModelHyperParams
.
src_pad_idx
,
ModelHyperParams
.
trg_pad_idx
,
ModelHyperParams
.
n_head
):
t
=
fluid
.
LoDTensor
()
t
.
set
(
tensor
,
fluid
.
CPUPlace
())
writer
.
append_tensor
(
t
)
writer
.
complete_append_tensor
()
@
unittest
.
skip
(
"transformer is buggy in multi gpu"
)
def
test_main
(
self
):
self
.
check_network_convergence
(
transformer
)
if
__name__
==
'__main__'
:
unittest
.
main
()
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