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5d5ed8ae
编写于
8月 07, 2019
作者:
C
channingss
浏览文件
操作
浏览文件
下载
电子邮件补丁
差异文件
update
上级
d4c8f5f6
变更
5
隐藏空白更改
内联
并排
Showing
5 changed file
with
1416 addition
and
7 deletion
+1416
-7
x2paddle/convert.py
x2paddle/convert.py
+30
-7
x2paddle/decoder/onnx_decoder.py
x2paddle/decoder/onnx_decoder.py
+480
-0
x2paddle/op_mapper/onnx_directly_map.py
x2paddle/op_mapper/onnx_directly_map.py
+38
-0
x2paddle/op_mapper/onnx_op_mapper.py
x2paddle/op_mapper/onnx_op_mapper.py
+775
-0
x2paddle/optimizer/onnx_optimizer.py
x2paddle/optimizer/onnx_optimizer.py
+93
-0
未找到文件。
x2paddle/convert.py
浏览文件 @
5d5ed8ae
...
...
@@ -15,7 +15,6 @@
from
six
import
text_type
as
_text_type
import
argparse
import
sys
import
x2paddle
def
arg_parser
():
...
...
@@ -93,8 +92,8 @@ def tf2paddle(model_path, save_dir):
def
caffe2paddle
(
proto
,
weight
,
save_dir
,
caffe_proto
):
if
caffe_proto
is
not
None
:
import
os
if
caffe_proto
is
not
None
and
not
os
.
path
.
isfile
(
caffe_proto
):
print
(
"The
.py file compiled by caffe.proto
is not exist."
)
if
not
os
.
path
.
isfile
(
caffe_proto
+
'caffe_pb2.py'
):
print
(
"The
file that resolve caffe
is not exist."
)
return
else
:
try
:
...
...
@@ -118,9 +117,32 @@ def caffe2paddle(proto, weight, save_dir, caffe_proto):
mapper
.
save_inference_model
(
save_dir
)
def
onnx2paddle
(
model_path
,
save_dir
):
# check onnx installation and version
try
:
import
onnx
version
=
onnx
.
version
.
version
if
version
!=
'1.5.0'
:
print
(
"onnx==1.5.0 is required"
)
return
except
:
print
(
"onnx is not installed, use
\"
pip install onnx==1.5.0
\"
."
)
return
from
x2paddle.decoder.onnx_decoder
import
ONNXDecoder
from
x2paddle.op_mapper.onnx_op_mapper
import
ONNXOpMapper
from
x2paddle.optimizer.onnx_optimizer
import
ONNXOptimizer
print
(
"Now translating model from onnx to paddle."
)
model
=
ONNXDecoder
(
model_path
)
mapper
=
ONNXOpMapper
(
model
)
optimizer
=
ONNXOptimizer
(
mapper
)
optimizer
.
delete_redundance_code
()
mapper
.
save_inference_model
(
save_dir
)
def
main
():
if
len
(
sys
.
argv
)
<
2
:
print
(
"Use
\"
x2paddle -h
\"
to print the help information
\n
"
)
print
(
"Use
\"
x2paddle -h
\"
to print the help information"
)
return
parser
=
arg_parser
()
...
...
@@ -138,7 +160,6 @@ def main():
return
except
:
print
(
"paddlepaddle not installed, use
\"
pip install paddlepaddle
\"
"
)
assert
args
.
framework
is
not
None
,
"--from is not defined(tensorflow/caffe)"
assert
args
.
save_dir
is
not
None
,
"--save_dir is not defined"
...
...
@@ -150,9 +171,11 @@ def main():
assert
args
.
prototxt
is
not
None
and
args
.
weight
is
not
None
,
"--prototxt and --weight should be defined while translating caffe model"
caffe2paddle
(
args
.
prototxt
,
args
.
weight
,
args
.
save_dir
,
args
.
caffe_proto
)
elif
args
.
framework
==
"onnx"
:
assert
args
.
model
is
not
None
,
"--model should be defined while translating onnx model"
onnx2paddle
(
args
.
model
,
args
.
save_dir
)
else
:
raise
Exception
(
"--framework only support tensorflow/caffe now"
)
raise
Exception
(
"--framework only support tensorflow/caffe
/onnx
now"
)
if
__name__
==
"__main__"
:
...
...
x2paddle/decoder/onnx_decoder.py
0 → 100644
浏览文件 @
5d5ed8ae
# Copyright (c) 2019 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
x2paddle.core.graph
import
GraphNode
,
Graph
from
x2paddle.core.fluid_code
import
FluidCode
from
onnx.checker
import
ValidationError
from
onnx.checker
import
check_model
from
onnx.utils
import
polish_model
from
onnx.version_converter
import
convert_version
from
onnx
import
helper
from
onnx.helper
import
get_attribute_value
,
make_attribute
from
onnx.shape_inference
import
infer_shapes
from
onnx.mapping
import
TENSOR_TYPE_TO_NP_TYPE
from
onnx.numpy_helper
import
to_array
from
collections
import
OrderedDict
as
Dict
import
onnx
import
numpy
as
np
from
copy
import
deepcopy
default_op_domain
=
'ai.onnx'
class
ONNXGraphNode
(
GraphNode
):
def
__init__
(
self
,
layer
,
layer_name
=
None
):
if
layer_name
is
None
:
super
(
ONNXGraphNode
,
self
).
__init__
(
layer
,
layer
.
name
)
else
:
super
(
ONNXGraphNode
,
self
).
__init__
(
layer
,
layer_name
)
self
.
layer_type
=
layer
.
op_type
self
.
fluid_code
=
FluidCode
()
self
.
attr_map
=
self
.
get_attr_map
()
self
.
dtype_map
=
{
1
:
"float32"
,
3
:
"int32"
,
9
:
"int64"
}
self
.
weight_inputs
=
list
()
self
.
out_shapes
=
None
self
.
dtype
=
None
def
get_attr_map
(
self
):
"""
convert ONNX node attributes to dict
"""
return
{
attr
.
name
:
self
.
get_attribute_value2
(
attr
)
for
attr
in
self
.
layer
.
attribute
}
@
property
def
value
(
self
):
assert
'Constant'
in
self
.
layer_type
,
"Only Constant node has value."
attr
=
self
.
layer
.
attr
[
'value'
]
if
'value'
in
self
.
attr_map
:
return
default
return
self
.
attr_map
[
name
]
def
get_attribute_value2
(
self
,
attr
):
"""
get_attribute_value enhanced
"""
if
attr
.
type
==
onnx
.
AttributeProto
.
TENSOR
:
dtype
=
np
.
dtype
(
TENSOR_TYPE_TO_NP_TYPE
[
attr
.
t
.
data_type
])
data
=
attr
.
t
.
raw_data
value
=
np
.
frombuffer
(
data
,
dtype
=
dtype
,
count
=
(
len
(
data
)
//
dtype
.
itemsize
))
elif
attr
.
type
==
onnx
.
AttributeProto
.
STRING
:
value
=
attr
.
s
value
=
value
.
decode
()
if
isinstance
(
value
,
bytes
)
else
value
else
:
value
=
get_attribute_value
(
attr
)
return
value
def
get_attr
(
self
,
name
,
default
=
None
):
"""
get_attribute_value from attr_map
"""
if
name
not
in
self
.
attr_map
:
return
default
return
self
.
attr_map
[
name
]
class
ONNXGraphDataNode
(
GraphNode
):
def
__init__
(
self
,
layer
,
layer_name
=
None
,
is_global_input
=
False
):
if
layer_name
is
None
:
super
(
ONNXGraphDataNode
,
self
).
__init__
(
layer
,
layer
.
name
)
else
:
super
(
ONNXGraphDataNode
,
self
).
__init__
(
layer
,
layer_name
)
if
is_global_input
:
self
.
layer_type
=
'place_holder'
else
:
self
.
layer_type
=
'create_parameter'
self
.
layer_name
=
layer_name
self
.
fluid_code
=
FluidCode
()
self
.
weight
=
None
self
.
embeded_as
=
None
@
property
def
out_shapes
(
self
):
values
=
self
.
layer
.
type
.
tensor_type
.
shape
.
dim
out_shapes
=
list
()
out_shapes
=
[
dim
.
dim_value
for
dim
in
values
]
return
out_shapes
@
property
def
dtype
(
self
):
dtype
=
self
.
layer
.
type
.
tensor_type
.
elem_type
return
TENSOR_TYPE_TO_NP_TYPE
[
dtype
]
class
ONNXGraph
(
Graph
):
def
__init__
(
self
,
model
):
super
(
ONNXGraph
,
self
).
__init__
(
model
)
self
.
initializer
=
{}
self
.
place_holder_nodes
=
list
()
self
.
get_place_holder_nodes
()
def
get_inner_nodes
(
self
):
"""
generate inner node of ONNX model
"""
inner_nodes
=
[]
if
not
isinstance
(
self
.
model
,
onnx
.
GraphProto
):
logger
.
error
(
'graph is not a GraphProto instance'
)
return
for
initializer
in
self
.
model
.
initializer
:
name
=
initializer
.
name
inner_nodes
.
append
(
name
)
return
inner_nodes
def
get_place_holder_nodes
(
self
):
"""
generate place_holder node of ONNX model
"""
inner_nodes
=
self
.
get_inner_nodes
()
input_nodes
=
[
value
.
name
for
value
in
self
.
model
.
input
]
for
ipt_data
in
input_nodes
:
if
ipt_data
not
in
inner_nodes
:
self
.
place_holder_nodes
.
append
(
ipt_data
)
def
is_place_holder_nodes
(
self
,
layer
):
"""
return layer is or not place_holder node
"""
if
layer
in
self
.
place_holder_nodes
:
return
True
return
False
def
build
(
self
):
"""
build topo_sort of ONNX model
"""
for
layer
in
self
.
model
.
node
:
self
.
node_map
[
layer
.
name
]
=
ONNXGraphNode
(
layer
)
#set op node's dtype and out_shapes
for
item
in
self
.
model
.
value_info
:
if
item
.
name
in
self
.
node_map
:
self
.
node_map
[
item
.
name
].
dtype
=
TENSOR_TYPE_TO_NP_TYPE
[
item
.
type
.
tensor_type
.
elem_type
]
self
.
node_map
[
item
.
name
].
out_shapes
=
[
dim
.
dim_value
for
dim
in
item
.
type
.
tensor_type
.
shape
.
dim
]
for
layer
in
self
.
model
.
input
:
if
layer
.
name
not
in
self
.
node_map
:
is_place_holder
=
self
.
is_place_holder_nodes
(
layer
.
name
)
self
.
node_map
[
layer
.
name
]
=
ONNXGraphDataNode
(
layer
,
layer_name
=
layer
.
name
,
is_global_input
=
is_place_holder
)
#set data node's weight
for
name
,
weight
in
self
.
graph_weights
(
self
.
model
):
if
name
in
self
.
node_map
:
if
isinstance
(
self
.
node_map
[
name
],
ONNXGraphDataNode
):
self
.
node_map
[
name
].
weight
=
weight
self
.
node_map
[
name
].
embeded_as
=
[]
#generate connection between nodes for topo
for
layer_name
,
node
in
self
.
node_map
.
items
():
if
isinstance
(
node
,
ONNXGraphNode
):
for
idx
,
in_node
in
enumerate
(
node
.
layer
.
input
):
if
in_node
not
in
self
.
node_map
:
raise
Exception
(
'input[{}] of node[{}] does not exist in node_map'
.
format
(
in_node
,
layer_name
))
else
:
self
.
connect
(
in_node
,
layer_name
)
#generate topo
super
(
ONNXGraph
,
self
).
build
()
self
.
input_nodes
=
self
.
place_holder_nodes
def
get_nodes
(
self
,
names
,
copy
=
False
):
"""
get nodes by more than one name
"""
nodes
=
[]
for
name
in
names
:
nodes
.
add
(
self
.
get_node
(
name
,
copy
=
copy
))
def
graph_weights
(
self
,
graph
):
"""
generator for weights
"""
if
not
isinstance
(
graph
,
onnx
.
GraphProto
):
logger
.
error
(
'graph is not a GraphProto instance'
)
return
for
initializer
in
graph
.
initializer
:
name
=
initializer
.
name
weight
=
to_array
(
initializer
)
yield
name
,
weight
class
ONNXDecoder
(
object
):
def
__init__
(
self
,
onnx_model
):
model
=
onnx
.
load
(
onnx_model
)
print
(
'model ir_version: {}, op version: {}'
.
format
(
model
.
ir_version
,
model
.
opset_import
))
check_model
(
model
)
model
=
convert_version
(
model
,
9
)
model
=
polish_model
(
model
)
model
=
self
.
optimize_model_skip_op_for_inference
(
model
)
model
=
self
.
optimize_model_strip_initializer
(
model
)
self
.
standardize_variable_name
(
model
.
graph
)
self
.
model
=
model
graph_def
=
model
.
graph
self
.
onnx_graph
=
ONNXGraph
(
graph_def
)
self
.
onnx_graph
.
build
()
def
build_value_refs
(
self
,
nodes
):
"""
build op reference of inputs and outputs
"""
input_refs
=
Dict
()
output_refs
=
Dict
()
for
idx
,
node
in
enumerate
(
nodes
):
for
val_name
in
node
.
input
:
input_refs
.
setdefault
(
val_name
,
set
()).
add
(
idx
)
for
val_name
in
node
.
output
:
output_refs
.
setdefault
(
val_name
,
set
()).
add
(
idx
)
return
input_refs
,
output_refs
def
skip_node_forward
(
self
,
nodes
,
src_output_name
,
dst_input_name
,
input_refs
):
"""
skip nodes between src_output_name -> dst_input_name and connect this pair
"""
processed
=
0
for
next_idx
in
input_refs
[
src_output_name
]:
next_node
=
nodes
[
next_idx
]
for
val_idx
,
next_input_name
in
enumerate
(
next_node
.
input
):
if
next_input_name
==
src_output_name
:
next_node
.
input
[
val_idx
]
=
dst_input_name
processed
+=
1
return
processed
def
skip_node_backward
(
self
,
nodes
,
src_input_name
,
dst_output_name
,
output_refs
):
"""
skip nodes between dst_output_name -> src_input_name and connect this pair
"""
processed
=
0
for
prev_idx
in
output_refs
[
src_input_name
]:
prev_node
=
nodes
[
prev_idx
]
for
val_idx
,
prev_output_name
in
enumerate
(
prev_node
.
output
):
if
prev_output_name
==
src_input_name
:
prev_node
.
output
[
val_idx
]
=
dst_output_name
processed
+=
1
return
processed
def
optimize_model_skip_op_for_inference
(
self
,
model
,
op_list
=
None
):
"""
skip ops can be bypassed for inference
"""
if
op_list
is
None
:
op_list
=
[
'Dropout'
]
nodes
=
model
.
graph
.
node
input_refs
,
output_refs
=
self
.
build_value_refs
(
nodes
)
ret
=
type
(
model
)()
ret
.
CopyFrom
(
model
)
ret_nodes
=
ret
.
graph
.
node
nodes_to_remove
=
[]
for
node_idx
,
node
in
enumerate
(
nodes
):
if
not
(
node
.
domain
==
default_op_domain
or
node
.
domain
==
''
):
continue
op_type
=
node
.
op_type
if
not
(
op_type
in
op_list
):
continue
if
op_type
in
[
'Dropout'
]:
input_name
=
node
.
input
[
0
]
output_name
=
node
.
output
[
0
]
elif
not
(
len
(
node
.
input
)
==
1
and
len
(
node
.
output
)
==
1
):
print
(
'currently only 1-input-1-output op supported, skip required %d: %s'
,
node_idx
,
node
.
op_type
)
continue
else
:
input_name
=
node
.
input
[
0
]
output_name
=
node
.
output
[
0
]
if
output_name
in
input_refs
:
processed
=
self
.
skip_node_forward
(
ret_nodes
,
output_name
,
input_name
,
input_refs
)
elif
input_name
in
output_refs
:
processed
=
self
.
skip_node_backward
(
ret_nodes
,
input_name
,
output_name
,
output_refs
)
else
:
processed
=
-
1
if
processed
>
0
:
nodes_to_remove
.
append
(
node_idx
)
print
(
'skip op {}: {} -> {} -> {}'
.
format
(
node_idx
,
input_name
,
node
.
op_type
,
output_name
))
elif
processed
==
0
:
print
(
'weird, no node processed'
)
else
:
print
(
'standalone op {}: {} -> {} -> {} not skipped'
.
format
(
node_idx
,
input_name
,
node
.
op_type
,
output_name
))
nodes_to_remove
.
sort
(
reverse
=
True
)
for
node_idx
in
nodes_to_remove
:
ret_nodes
.
pop
(
node_idx
)
return
ret
def
optimize_model_strip_initializer
(
self
,
model
,
keep_input_only
=
True
):
"""
strip weights for inference
"""
nodes
=
model
.
graph
.
node
input_refs
,
output_refs
=
self
.
build_value_refs
(
nodes
)
out_names
=
[
val
.
name
for
val
in
model
.
graph
.
output
]
ret
=
type
(
model
)()
ret
.
CopyFrom
(
model
)
# strip initializers
ret
.
graph
.
ClearField
(
'initializer'
)
ret_initializers
=
ret
.
graph
.
initializer
for
initializer
in
model
.
graph
.
initializer
:
name
=
initializer
.
name
if
name
in
input_refs
:
ret_initializers
.
add
().
CopyFrom
(
initializer
)
elif
not
keep_input_only
and
name
in
output_refs
:
ret_initializers
.
add
().
CopyFrom
(
initializer
)
else
:
dtype
=
TENSOR_TYPE_TO_NP_TYPE
[
initializer
.
data_type
]
# strip inputs
ret
.
graph
.
ClearField
(
'input'
)
ret_inputs
=
ret
.
graph
.
input
for
item
in
model
.
graph
.
input
:
name
=
item
.
name
if
name
in
input_refs
or
name
in
out_names
:
ret_inputs
.
add
().
CopyFrom
(
item
)
return
ret
def
make_variable_name
(
self
,
name
):
"""
make a valid code name for ParamAttr
"""
if
name
==
''
:
raise
ValueError
(
'name should not be empty'
)
for
s
in
' .*?
\\
/-:'
:
#
name
=
name
.
replace
(
s
,
'_'
)
return
'_'
+
name
def
standardize_variable_name
(
self
,
graph
):
"""
standardize variable name for paddle's code
"""
for
initializer
in
graph
.
initializer
:
initializer
.
name
=
self
.
make_variable_name
(
initializer
.
name
)
for
ipt
in
graph
.
input
:
ipt
.
name
=
self
.
make_variable_name
(
ipt
.
name
)
for
output
in
graph
.
output
:
output
.
name
=
self
.
make_variable_name
(
output
.
name
)
for
item
in
graph
.
value_info
:
item
.
name
=
self
.
make_variable_name
(
item
.
name
)
for
node
in
graph
.
node
:
if
node
.
name
==
''
:
node
.
name
=
node
.
output
[
0
]
node
.
name
=
self
.
make_variable_name
(
node
.
name
)
for
i
in
range
(
len
(
node
.
input
)):
node
.
input
[
i
]
=
self
.
make_variable_name
(
node
.
input
[
i
])
for
i
in
range
(
len
(
node
.
output
)):
node
.
output
[
i
]
=
self
.
make_variable_name
(
node
.
output
[
i
])
def
split_model
(
self
,
model
,
outputs
=
None
):
"""
Takes a model and changes its outputs.
"""
if
outputs
is
None
:
raise
RuntimeError
(
"outputs is None"
)
if
outputs
==
model
.
graph
.
output
[
0
].
name
:
return
model
nodes
=
model
.
graph
.
node
keep_nodes
=
[]
# all the nodes we need to keep.
for
node
in
nodes
:
if
outputs
in
node
.
output
:
keep_nodes
.
append
(
node
)
break
keep_nodes
.
append
(
node
)
infer_shapes
=
onnx
.
shape_inference
.
infer_shapes
(
model
)
var_out
=
[]
for
value_info
in
infer_shapes
.
graph
.
value_info
:
if
value_info
.
name
==
outputs
:
var_out
.
append
(
value_info
)
break
graph
=
helper
.
make_graph
(
keep_nodes
,
model
.
graph
.
name
,
model
.
graph
.
input
,
var_out
,
model
.
graph
.
initializer
)
onnx_model
=
helper
.
make_model
(
graph
)
onnx_model
.
ir_version
=
model
.
ir_version
onnx_model
.
producer_name
=
model
.
producer_name
onnx_model
.
producer_version
=
model
.
producer_version
onnx_model
.
domain
=
model
.
domain
onnx_model
.
model_version
=
model
.
model_version
onnx_model
.
doc_string
=
model
.
doc_string
if
len
(
onnx_model
.
graph
.
input
)
!=
len
(
model
.
graph
.
input
):
raise
RuntimeError
(
"Input mismatch {} != {}"
.
format
(
len
(
onnx_model
.
input
),
len
(
model
.
input
)))
return
onnx_model
def
get_dynamic_shape_from_caffe2
(
self
,
layer
,
input_shapes
):
"""
get dynamic shape from caffe2.backend
"""
from
caffe2.python.onnx.backend
import
prepare
shape
=
input_shapes
[
0
]
np_images
=
np
.
random
.
rand
(
shape
[
0
],
shape
[
1
],
shape
[
2
],
shape
[
3
]).
astype
(
'float32'
)
num_onnx
=
self
.
split_model
(
self
.
model
,
layer
)
prepared_backend
=
prepare
(
num_onnx
,
device
=
'CPU'
)
output
=
prepared_backend
.
run
(
inputs
=
np_images
)
return
output
[
0
].
tolist
()
def
get_dynamic_shape_from_onnx
(
self
,
layer
,
input_shapes
):
"""
get dynamic shape from onnxruntime
"""
import
onnxruntime
as
rt
from
onnxruntime.backend
import
prepare
import
numpy
as
np
num_onnx
=
self
.
split_model
(
self
.
model
,
layer
)
sess
=
prepare
(
num_onnx
)
shape
=
input_shapes
[
0
]
print
(
shape
)
np_images
=
np
.
random
.
rand
(
shape
[
0
],
shape
[
1
],
shape
[
2
],
shape
[
3
]).
astype
(
'float32'
)
output
=
sess
.
run
(
model
=
sess
,
inputs
=
np_images
)
return
output
[
0
].
tolist
()
x2paddle/op_mapper/onnx_directly_map.py
0 → 100644
浏览文件 @
5d5ed8ae
# Copyright (c) 2019 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
collections
import
OrderedDict
as
_dict
default_op_mapping_field_values
=
_dict
()
default_op_mapping_field_values
[
'FLUID_OP'
]
=
''
default_op_mapping_field_values
[
'FLUID_INPUT_ARGS'
]
=
None
default_op_mapping_field_values
[
'FLUID_OUTPUT_ARGS'
]
=
None
default_op_mapping_field_values
[
'ATTR_MAPPING'
]
=
dict
()
default_op_mapping_field_values
[
'DEFAULTS'
]
=
dict
()
default_op_mapping_field_values
[
'INPUT_PERM'
]
=
None
default_op_mapping_field_values
[
'OUTPUT_PERM'
]
=
None
default_op_mapping_field_values
[
'FILL_NAME_FIELD'
]
=
True
default_op_mapping
=
{
'Gather'
:
[
'gather'
,
[
'X'
],
[
'Out'
],
dict
(
axis
=
''
)],
'Shape'
:
[
'shape'
,
[
'X'
],
[
'Out'
]],
'Mul'
:
[
'elementwise_mul'
,
[
'X'
,
'Y'
],
[
'Out'
],
dict
(),
dict
(
axis
=-
1
)],
}
default_ioa_constraint
=
{
'Gather'
:
[(
lambda
i
,
o
,
a
:
a
.
get
(
'axis'
,
0
)
==
0
,
'only axis = 0 is supported'
)],
}
x2paddle/op_mapper/onnx_op_mapper.py
0 → 100644
浏览文件 @
5d5ed8ae
# Copyright (c) 2019 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
x2paddle.core.graph
import
GraphNode
from
x2paddle.core.op_mapper
import
OpMapper
from
x2paddle.core.util
import
*
from
x2paddle.core.fluid_code
import
Layer
from
x2paddle.core.fluid_code
import
FluidCode
from
x2paddle.decoder.onnx_decoder
import
ONNXGraph
,
ONNXGraphNode
,
ONNXGraphDataNode
from
x2paddle.op_mapper.onnx_directly_map
import
default_op_mapping_field_values
from
x2paddle.op_mapper.onnx_directly_map
import
default_op_mapping
from
x2paddle.op_mapper.onnx_directly_map
import
default_ioa_constraint
import
numpy
as
np
import
logging
as
_logging
from
collections
import
OrderedDict
as
_dict
_logger
=
_logging
.
getLogger
(
__name__
)
def
_const_weight_or_none
(
node
):
if
'Constant'
in
node
.
layer_name
:
return
val
.
value
if
isinstance
(
node
,
ONNXGraphDataNode
):
return
node
.
weight
return
None
class
ONNXOpMapper
(
OpMapper
):
def
__init__
(
self
,
decoder
):
super
(
ONNXOpMapper
,
self
).
__init__
()
self
.
decoder
=
decoder
self
.
graph
=
decoder
.
onnx_graph
self
.
input_shapes
=
[]
self
.
weights
=
dict
()
self
.
omit_nodes
=
list
()
if
not
self
.
op_checker
():
raise
Exception
(
"Model are not supported yet."
)
#mapping op
for
node_name
in
self
.
graph
.
topo_sort
:
node
=
self
.
graph
.
get_node
(
node_name
)
op
=
node
.
layer_type
if
hasattr
(
self
,
op
):
func
=
getattr
(
self
,
op
)
func
(
node
)
elif
op
in
default_op_mapping
:
self
.
_default
(
node
)
def
op_checker
(
self
):
unsupported_ops
=
set
()
for
node_name
in
self
.
graph
.
topo_sort
:
node
=
self
.
graph
.
get_node
(
node_name
)
op
=
node
.
layer_type
if
not
hasattr
(
self
,
op
)
and
op
not
in
default_op_mapping
:
unsupported_ops
.
add
(
op
)
if
len
(
unsupported_ops
)
==
0
:
return
True
else
:
print
(
"There are {} ops not supported yet, list as below"
.
format
(
len
(
unsupported_ops
)))
for
op
in
unsupported_ops
:
print
(
op
)
return
False
def
_default
(
self
,
node
,
*
args
,
name
=
''
,
**
kwargs
):
inputs
=
node
.
layer
.
input
outputs
=
node
.
layer
.
output
op_type
=
node
.
layer_type
attrs
=
node
.
attr_map
info
=
default_op_mapping
[
op_type
]
info
.
extend
(
list
(
default_op_mapping_field_values
.
values
())[
len
(
info
):])
(
fluid_op
,
fluid_input_args
,
fluid_output_args
,
attr_mapping
,
default_attrs
,
input_perm
,
output_perm
,
fill_name_field
,
)
=
info
if
fluid_op
in
default_ioa_constraint
:
for
predicate
,
message
in
default_ioa_constraint
[
fluid_op
]:
assert
predicate
(
inputs
,
outputs
,
attrs
),
message
mapped_attrs
=
{
attr_mapping
.
get
(
key
,
key
):
value
for
key
,
value
in
attrs
.
items
()
}
if
''
in
mapped_attrs
:
mapped_attrs
.
pop
(
''
)
if
'_'
in
mapped_attrs
:
mapped_attrs
.
pop
(
'_'
)
fluid_attrs
=
default_attrs
.
copy
()
fluid_attrs
.
update
(
mapped_attrs
)
val_inps
=
inputs
if
input_perm
is
None
else
list
(
map
(
lambda
i
:
inputs
[
i
],
input_perm
))
val_outs
=
outputs
if
output_perm
is
None
else
list
(
map
(
lambda
i
:
outputs
[
i
],
output_perm
))
attr
=
fluid_attrs
if
fluid_op
not
in
[
'shape'
,
'gather'
]:
attr
[
'name'
]
=
string
(
node
.
layer_name
)
node
.
fluid_code
.
add_layer
(
fluid_op
,
inputs
=
', '
.
join
(
val_inps
),
output
=
val_outs
[
0
],
param_attr
=
attr
)
def
place_holder
(
self
,
node
):
self
.
input_shapes
.
append
(
node
.
out_shapes
)
attr
=
{
"dtype"
:
string
(
node
.
dtype
),
"shape"
:
node
.
out_shapes
,
"name"
:
string
(
node
.
layer_name
),
"append_batch_size"
:
'False'
}
node
.
fluid_code
.
add_layer
(
"data"
,
inputs
=
None
,
output
=
node
,
param_attr
=
attr
)
def
create_parameter
(
self
,
node
,
parameter
=
None
):
if
parameter
is
not
None
:
node
=
parameter
dtype
=
node
.
dtype
shape
=
node
.
out_shapes
self
.
weights
[
node
.
layer_name
]
=
node
.
weight
attr
=
{
'dtype'
:
string
(
dtype
),
'shape'
:
shape
,
'name'
:
string
(
node
.
layer_name
),
'attr'
:
string
(
node
.
layer_name
),
'default_initializer'
:
'Constant(0.0)'
}
node
.
fluid_code
.
add_layer
(
"create_parameter"
,
inputs
=
None
,
output
=
node
,
param_attr
=
attr
)
def
_pad_if_asymmetric
(
self
,
node
,
pads
,
val_name
):
# pads: SSEE
assert
len
(
pads
)
&
1
==
0
symmetric
=
True
ndims
=
len
(
pads
)
//
2
for
idx_dim
in
range
(
ndims
):
if
pads
[
idx_dim
]
!=
pads
[
ndims
+
idx_dim
]:
symmetric
=
False
break
if
symmetric
:
return
pads
[:
ndims
],
val_name
val_padded
=
self
.
Pad
(
node
,
op_independent
=
False
)
return
[
0
]
*
ndims
,
val_padded
def
Pad
(
self
,
node
,
op_independent
=
True
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
pads
=
node
.
get_attr
(
'pads'
)
mode
=
node
.
get_attr
(
'mode'
,
'constant'
)
value
=
node
.
get_attr
(
'value'
,
0.
)
data_shape
=
val_x
.
out_shapes
output_shape
=
node
.
out_shapes
assume_pad2d
=
False
attr
=
{}
if
len
(
pads
)
==
4
:
assume_pad2d
|=
mode
!=
'constant'
if
data_shape
:
assume_pad2d
|=
data_shape
and
len
(
data_shape
)
==
4
# NCHW
if
output_shape
:
assume_pad2d
|=
output_shape
and
len
(
output_shape
)
==
4
# NCHW
if
assume_pad2d
:
fluid_op
=
'pad2d'
attr
[
'data_format'
]
=
string
(
'NCHW'
)
attr
[
'mode'
]
=
string
(
mode
)
else
:
attr
=
{
'pad_value'
:
value
}
assert
mode
==
'constant'
,
'mode {} is supported only in pad2d'
.
format
(
mode
)
fluid_op
=
'pad'
if
len
(
pads
)
==
4
:
paddings
=
np
.
array
(
pads
).
reshape
(
(
-
1
,
2
)).
transpose
().
flatten
().
tolist
()
# SSEE -> SESE
elif
len
(
pads
)
==
8
:
paddings
=
np
.
array
(
pads
).
reshape
(
(
-
1
,
4
)).
transpose
().
flatten
().
tolist
()
# SSEE -> SESE
attr
[
'paddings'
]
=
paddings
if
op_independent
:
attr
[
'name'
]
=
string
(
node
.
layer_name
)
node
.
fluid_code
.
add_layer
(
fluid_op
,
inputs
=
val_x
,
output
=
node
,
param_attr
=
attr
)
else
:
attr
[
'name'
]
=
string
(
node
.
layer_name
+
'_paded'
)
node
.
fluid_code
.
add_layer
(
fluid_op
,
inputs
=
val_x
,
output
=
node
.
layer_name
+
'_paded'
,
param_attr
=
attr
)
return
node
.
layer_name
+
'_paded'
def
Unsqueeze
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
axes
=
node
.
get_attr
(
'axes'
)
attr
=
{
'axes'
:
axes
,
'name'
:
string
(
node
.
layer_name
)}
node
.
fluid_code
.
add_layer
(
'unsqueeze'
,
inputs
=
val_x
,
output
=
node
,
param_attr
=
attr
)
def
Constant
(
self
,
node
):
val_output
=
self
.
graph
.
get_node
(
node
.
layer
.
output
[
0
],
copy
=
True
)
value
=
node
.
get_attr
(
'value'
)
dtype
=
np
.
dtype
(
value
.
dtype
)
output_dtype
=
val_output
.
dtype
if
output_dtype
:
assert
dtype
==
output_dtype
,
'tensor dtype unmatches storage dtype'
shape
=
node
.
get_attr
(
'shape'
,
None
)
if
shape
is
None
:
shape
=
val_output
.
out_shapes
if
shape
is
None
:
shape
=
list
(
value
.
shape
)
_logger
.
warning
(
'in (Constant -> %s): '
'attribute "shape" of %s not inferred, '
'using value as 1-D tensor may lead to fails'
,
val_output
.
layer_name
,
val_output
.
layer_name
)
value
=
value
.
tolist
()
if
len
(
value
)
==
1
:
# scalar
shape
=
[
1
]
value
=
value
[
0
]
if
dtype
.
name
==
'int64'
:
dtype
=
'int32'
attr
=
{
'shape'
:
shape
,
'dtype'
:
string
(
dtype
),
'value'
:
value
}
node
.
fluid_code
.
add_layer
(
'fill_constant'
,
inputs
=
None
,
output
=
node
,
param_attr
=
attr
)
def
Resize
(
self
,
node
):
# I/O
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
val_scales
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
1
],
copy
=
True
)
val_y
,
=
self
.
graph
.
get_node
(
node
.
layer
.
output
[
0
],
copy
=
True
)
out_shape_
=
val_y
.
out_shapes
if
out_shape_
is
not
None
:
assert
len
(
out_shape_
)
==
4
,
'only 4-D Tensor as X and Y supported'
out_shape_
=
out_shape_
[
2
:]
scales
=
_const_weight_or_none
(
val_scales
)
if
scales
is
not
None
:
assert
len
(
scales
)
==
4
,
'only 4-D Tensor as X and Y supported'
assert
scales
[
0
]
==
1
and
scales
[
1
]
==
1
,
'only scale on (NC)HW supported'
assert
scales
[
2
]
==
scales
[
3
],
'only aspect-ratio-invariant scale supported'
scale
=
scales
[
2
]
if
scales
else
None
if
scale
is
None
:
assert
out_shape_
,
'neither scales nor output shape is available'
out_shape
=
out_shape_
else
:
out_shape
=
None
if
out_shape_
is
None
:
in_shape
=
val_x
.
out_shapes
assert
in_shape
is
not
None
,
'out_shape required but not inferrable'
assert
len
(
in_shape
)
==
4
,
'only 4-D Tensor as X and Y supported'
out_shape_
=
[
in_shape
[
2
]
*
scale
,
in_shape
[
3
]
*
scale
]
mode
=
node
.
get_attr
(
'mode'
,
'nearest'
)
fluid_op
=
'resize_{}'
.
format
(
mode
)
name_attr
=
', name={}'
.
format
(
repr
(
name
))
if
name
else
''
attr
=
{
'scale'
:
scale
,
'out_shape'
:
out_shape
,
'name'
:
string
(
node
.
layer_name
)
}
node
.
fluid_code
.
add_layer
(
fluid_op
,
inputs
=
val_x
,
output
=
node
,
param_attr
=
attr
)
def
ConstantOfShape
(
self
,
node
):
val_shape
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
shape
=
_const_weight_or_none
(
val_shape
)
if
shape
is
None
:
shape
=
node
.
out_shapes
assert
shape
is
not
None
,
(
'given shape is neither const value nor deductible from output, '
'this is not supported'
)
value
=
node
.
get_attr
(
'value'
)
dtype
=
value
.
dtype
value
=
value
.
tolist
()
if
len
(
value
)
==
1
:
shape
=
[
1
]
value
=
value
[
0
]
if
dtype
.
name
==
'int64'
:
dtype
=
'int32'
attr
=
{
'shape'
:
shape
,
'dtype'
:
string
(
dtype
),
'value'
:
value
}
node
.
fluid_code
.
add_layer
(
'fill_constant'
,
inputs
=
None
,
output
=
node
,
param_attr
=
attr
)
def
Split
(
self
,
node
):
val_input
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
var_outs
=
[
val
for
val
in
node
.
layer
.
input
]
fluid_op
=
'split'
split
=
node
.
get_attr
[
'split'
]
axis
=
node
.
get_attr
(
'axis'
,
0
)
attr
=
{
'split'
:
split
,
'axis'
:
axis
,
'name'
:
string
(
node
.
layer_name
)}
# generation
node
.
fluid_code
.
add_layer
(
'split'
,
inputs
=
val_input
,
output
=
var_outs
,
param_attr
=
attr
)
def
Reshape
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
val_shape
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
1
],
copy
=
True
)
val_reshaped
=
self
.
graph
.
get_node
(
node
.
layer
.
output
[
0
],
copy
=
True
)
shape
=
None
if
isinstance
(
val_shape
,
ONNXGraphDataNode
):
self
.
omit_nodes
.
append
(
val_shape
.
layer_name
)
# catch dynamic graph shape
if
isinstance
(
val_shape
,
ONNXGraphNode
):
shape
=
self
.
decoder
.
get_dynamic_shape_from_caffe2
(
val_shape
.
layer_name
,
self
.
input_shapes
)
if
shape
is
None
:
shape
=
val_reshaped
.
out_shapes
shape_dtype
=
val_shape
.
dtype
if
shape_dtype
is
None
:
_logger
.
warning
(
'in op %s(%s -> Reshape -> %s): '
'dtype of input "shape" not inferred, int32 assumed'
,
name
,
inputs
,
outputs
)
shape_dtype
=
_np
.
dtype
(
'int32'
)
if
shape
is
None
:
shape
=
[
1
,
-
1
]
# who knows
_logger
.
warning
(
'in %s(%s -> Reshape -> %s): '
'input "shape" not inferred, use [1, -1] as dummy value, '
'the behavior of Paddle fluid maybe undefined'
,
name
,
inputs
,
outputs
)
attr
=
{
'shape'
:
shape
,
'name'
:
string
(
node
.
layer_name
)}
node
.
fluid_code
.
add_layer
(
'reshape'
,
inputs
=
val_x
,
output
=
node
,
param_attr
=
attr
)
def
Cast
(
self
,
node
):
val_input
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
val_output
=
self
.
graph
.
get_node
(
node
.
layer
.
output
[
0
],
copy
=
True
)
dtype
=
node
.
get_attr
(
'to'
)
if
not
isinstance
(
dtype
,
np
.
dtype
):
dtype
=
TENSOR_TYPE_TO_NP_TYPE
[
dtype
]
output_dtype
=
val_output
.
dtype
if
output_dtype
:
assert
dtype
==
output_dtype
,
'dtype of to unmatches output'
attr
=
{
'dtype'
:
string
(
dtype
)}
node
.
fluid_code
.
add_layer
(
'cast'
,
inputs
=
val_input
,
output
=
node
,
param_attr
=
attr
)
def
AveragePool
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
assert
node
.
get_attr
(
'auto_pad'
,
'NOTSET'
)
==
'NOTSET'
,
'only auto_pad = NOTSET is supported'
kernel_shape
=
node
.
get_attr
(
"kernel_shape"
)
poolnd
=
len
(
kernel_shape
)
strides
=
node
.
get_attr
(
"strides"
)
pad_mode
=
node
.
get_attr
(
"pads"
)
ceil_mode
=
bool
(
node
.
get_attr
(
'ceil_mode'
,
0
))
pads
=
node
.
get_attr
(
'pads'
,
[
0
]
*
(
poolnd
*
2
))
fluid_op
=
'pool{}d'
.
format
(
poolnd
)
assert
2
<=
poolnd
<=
3
,
'only pool2d and pool3d is supported'
paddings
,
val_x
=
self
.
_pad_if_asymmetric
(
node
,
pads
,
val_x
)
attr
=
{
"pool_size"
:
kernel_shape
,
"pool_type"
:
string
(
'avg'
),
"pool_stride"
:
strides
,
"pool_padding"
:
paddings
,
"ceil_mode"
:
ceil_mode
,
"exclusive"
:
'True'
,
"name"
:
string
(
node
.
layer_name
)
}
node
.
fluid_code
.
add_layer
(
fluid_op
,
inputs
=
val_x
,
output
=
node
,
param_attr
=
attr
)
def
_roi_pool
(
self
,
node
,
fluid_op
=
None
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
val_rois
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
1
],
copy
=
True
)
val_y
=
self
.
graph
.
get_node
(
node
.
layer
.
output
[
0
],
copy
=
True
)
spatial_scale
=
node
.
get_attr
(
'spatial_scale'
)
# required
pooled_height
,
pooled_width
=
node
.
get_attr
(
'pooled_shape'
)
# required
attr
=
{
'pooled_height'
:
pooled_height
,
'spatial_scale'
:
spatial_scale
}
feature_attr
=
''
is_max_pool
=
fluid_op
==
'roi_pool'
if
'sampling_ratio'
in
node
.
attr_map
:
#
sampling_ratio
=
node
.
get_attr
[
'sampling_ratio'
]
attr
[
'sampling_ratio'
]
=
sampling_ratio
if
'output_channels'
in
node
.
attr_map
:
#
output_channels
=
node
.
get_attr
[
'output_channels'
]
attr
[
'output_channels'
]
=
output_channels
node
.
fluid_code
.
add_layer
(
fluid_op
,
inputs
=
','
.
join
([
valx
,
val_rois
]),
output
=
node
,
param_attr
=
attr
)
def
RoiAlign
(
self
,
node
):
self
.
_roi_pool
(
node
,
fluid_op
=
'roi_align'
)
def
NonMaxSuppression
(
self
,
node
):
(
val_boxes
,
val_scores
,
val_max_output_boxes_per_class
,
val_iou_threshold
,
val_score_threshold
)
=
self
.
graph
.
get_nodes
(
node
.
layer
.
input
,
copy
=
True
)
center_point_box
=
node
.
get_attr
(
'center_point_box'
,
0
)
scores
=
_const_weight_or_none
(
val_scores
)
max_output_boxes_per_class
=
_const_weight_or_none
(
val_max_output_boxes_per_class
)
iou_threshold
=
_const_weight_or_none
(
val_iou_threshold
)
score_threshold
=
_const_weight_or_none
(
val_score_threshold
)
if
center_point_box
==
1
:
pass
attr
=
{
'scores'
:
scores
,
'score_threshold'
:
score_threshold
,
'nms_threshold'
:
iou_threshold
,
'nms_top_k'
:
max_output_boxes_per_class
,
}
def
Concat
(
self
,
node
):
inputs
=
[]
for
i
in
range
(
len
(
node
.
layer
.
input
)):
ipt
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
i
],
copy
=
True
)
if
isinstance
(
ipt
,
str
):
inputs
.
append
(
ipt
)
else
:
inputs
.
append
(
ipt
.
layer_name
)
axis
=
node
.
get_attr
(
'axis'
)
attr
=
{
'axis'
:
axis
}
node
.
fluid_code
.
add_layer
(
'concat'
,
inputs
=
'['
+
', '
.
join
(
inputs
)
+
']'
,
output
=
node
,
param_attr
=
attr
)
def
Flatten
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
axis
=
node
.
get_attr
(
'axis'
,
1
)
attr
=
{
"axis"
:
str
(
axis
),
"name"
:
string
(
node
.
layer_name
)}
node
.
fluid_code
.
add_layer
(
'flatten'
,
inputs
=
val_x
,
output
=
node
,
param_attr
=
attr
)
def
Gemm
(
self
,
node
):
val_a
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
val_b
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
1
],
copy
=
True
)
val_c
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
2
],
copy
=
True
)
alpha
=
node
.
get_attr
(
'alpha'
,
1.
)
# optional
beta
=
node
.
get_attr
(
'beta'
,
1.
)
# optional
trans_a
=
bool
(
node
.
get_attr
(
'transA'
,
0
))
# optional
trans_b
=
bool
(
node
.
get_attr
(
'transB'
,
0
))
# optional
val_mm
=
node
.
layer_name
+
'_mm'
matmul_inputs
=
{
"x"
:
val_a
,
"y"
:
val_b
}
attr_matmul
=
{
"transpose_x"
:
trans_a
,
"transpose_y"
:
trans_b
,
"alpha"
:
alpha
,
"name"
:
string
(
val_mm
)
}
node
.
fluid_code
.
add_layer
(
'matmul'
,
inputs
=
matmul_inputs
,
output
=
val_mm
,
param_attr
=
attr_matmul
)
if
beta
!=
0
:
if
beta
==
1.
:
add_inputs
=
{
"x"
:
val_mm
,
"y"
:
val_c
}
attr
=
{
"name"
:
string
(
node
.
layer_name
)}
node
.
fluid_code
.
add_layer
(
"elementwise_add"
,
inputs
=
add_inputs
,
output
=
node
,
param_attr
=
attr
)
else
:
pass
def
Add
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
val_y
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
1
],
copy
=
True
)
inputs
=
{
"x"
:
val_x
,
"y"
:
val_y
,
}
attr
=
{
"name"
:
string
(
node
.
layer_name
)}
node
.
fluid_code
.
add_layer
(
"elementwise_add"
,
inputs
=
inputs
,
output
=
node
,
param_attr
=
attr
)
def
Sum
(
self
,
node
):
var_inps
=
[
val
for
val
in
node
.
layer
.
input
]
node
.
fluid_code
.
add_layer
(
"sum"
,
inputs
=
'['
+
', '
.
join
(
var_inps
)
+
']'
,
output
=
node
)
def
MatMul
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
val_y
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
1
],
copy
=
True
)
inputs
=
{
"x"
:
val_x
,
"y"
:
val_y
}
attr
=
{
"name"
:
string
(
node
.
layer_name
)}
node
.
fluid_code
.
add_layer
(
"matmul"
,
inputs
=
inputs
,
output
=
node
,
param_attr
=
attr
)
def
LRN
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
size
=
node
.
get_attr
(
'size'
)
# required
alpha
=
node
.
get_attr
(
'alpha'
,
0.0001
)
# optional
beta
=
node
.
get_attr
(
'beta'
,
0.75
)
# optional
bias
=
node
.
get_attr
(
'bias'
,
1.0
)
# optional
attr
=
{
"n"
:
max
(
1
,
size
),
"k"
:
bias
,
"alpha"
:
alpha
,
'beta'
:
beta
,
"name"
:
string
(
node
.
layer_name
)
}
node
.
fluid_code
.
add_layer
(
"lrn"
,
inputs
=
val_x
,
output
=
node
,
param_attr
=
attr
)
def
BatchNormalization
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
val_scale
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
1
],
copy
=
True
)
val_b
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
2
],
copy
=
True
)
val_mean
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
3
],
copy
=
True
)
val_var
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
4
],
copy
=
True
)
self
.
omit_nodes
.
append
(
val_scale
.
layer_name
)
self
.
omit_nodes
.
append
(
val_b
.
layer_name
)
self
.
omit_nodes
.
append
(
val_mean
.
layer_name
)
self
.
omit_nodes
.
append
(
val_var
.
layer_name
)
momentum
=
node
.
get_attr
(
'momentum'
,
.
9
)
epsilon
=
node
.
get_attr
(
'epsilon'
,
1e-5
)
attr
=
{
"momentum"
:
momentum
,
"epsilon"
:
epsilon
,
"data_layout"
:
string
(
'NCHW'
),
"is_test"
:
'True'
,
"param_attr"
:
string
(
val_scale
.
layer_name
),
"bias_attr"
:
string
(
val_b
.
layer_name
),
"moving_mean_name"
:
string
(
val_mean
.
layer_name
),
"moving_variance_name"
:
string
(
val_var
.
layer_name
),
"name"
:
string
(
node
.
layer_name
)
}
node
.
fluid_code
.
add_layer
(
"batch_norm"
,
inputs
=
val_x
,
output
=
node
,
param_attr
=
attr
)
def
Softmax
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
attr
=
{
"name"
:
string
(
node
.
layer_name
)}
node
.
fluid_code
.
add_layer
(
"softmax"
,
inputs
=
val_x
,
output
=
node
,
param_attr
=
attr
)
def
Transpose
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
perm
=
node
.
get_attr
(
'perm'
)
attr
=
{
'perm'
:
perm
,
"name"
:
string
(
node
.
layer_name
)}
node
.
fluid_code
.
add_layer
(
"transpose"
,
inputs
=
val_x
,
output
=
node
,
param_attr
=
attr
)
def
Div
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
val_y
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
1
],
copy
=
True
)
inputs
=
{
'x'
:
val_x
,
'y'
:
val_y
}
attr
=
{
"name"
:
string
(
node
.
layer_name
)}
node
.
fluid_code
.
add_layer
(
"elementwise_div"
,
inputs
=
inputs
,
output
=
node
,
param_attr
=
attr
)
def
Relu
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
attr
=
{
"name"
:
string
(
node
.
layer_name
)}
node
.
fluid_code
.
add_layer
(
"relu"
,
inputs
=
val_x
,
output
=
node
,
param_attr
=
attr
)
def
PRelu
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
val_slope
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
1
],
copy
=
True
)
attr
=
{
"name"
:
string
(
node
.
layer_name
),
"mode"
:
string
(
'channel'
)}
if
isinstance
(
val_slope
,
str
):
attr
[
"param_attr"
]
=
string
(
val_slope
.
layer_name
)
else
:
attr
[
"param_attr"
]
=
string
(
val_slope
.
layer_name
)
node
.
fluid_code
.
add_layer
(
"prelu"
,
inputs
=
val_x
,
output
=
node
,
param_attr
=
attr
)
def
Squeeze
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
squeeze_dims
=
node
.
get_attr
(
'squeeze_dims'
)
attr
=
{
'axes'
:
squeeze_dims
,
"name"
:
string
(
node
.
layer_name
)}
node
.
fluid_code
.
add_layer
(
"squeeze"
,
inputs
=
val_x
,
output
=
node
,
param_attr
=
attr
)
def
Identity
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
node
.
fluid_code
.
add_layer
(
"assign"
,
inputs
=
val_x
,
output
=
node
)
def
MaxPool
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
assert
node
.
get_attr
(
'auto_pad'
,
'NOTSET'
)
==
'NOTSET'
,
'only auto_pad = NOTSET is supported'
# optional
assert
node
.
get_attr
(
"dilations"
)
is
None
,
'only dilations = 0 is supported'
# optional
kernel_shape
=
node
.
get_attr
(
"kernel_shape"
)
poolnd
=
len
(
kernel_shape
)
strides
=
node
.
get_attr
(
"strides"
)
pad_mode
=
node
.
get_attr
(
"pads"
)
ceil_mode
=
bool
(
node
.
get_attr
(
'ceil_mode'
,
0
))
# optional
pads
=
node
.
get_attr
(
'pads'
,
[
0
]
*
(
poolnd
*
2
))
# optional
fluid_op
=
'pool{}d'
.
format
(
poolnd
)
assert
2
<=
poolnd
<=
3
,
'only pool2d and pool3d is supported'
paddings
,
val_x
=
self
.
_pad_if_asymmetric
(
node
,
pads
,
val_x
)
attr
=
{
"pool_size"
:
kernel_shape
,
"pool_type"
:
string
(
"max"
),
"pool_stride"
:
strides
,
"pool_padding"
:
paddings
,
"ceil_mode"
:
ceil_mode
,
"name"
:
string
(
node
.
layer_name
),
"exclusive"
:
False
}
node
.
fluid_code
.
add_layer
(
fluid_op
,
inputs
=
val_x
,
output
=
node
,
param_attr
=
attr
)
def
GlobalAveragePool
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
val_y
=
self
.
graph
.
get_node
(
node
.
layer
.
output
[
0
],
copy
=
True
)
input_shape
=
val_x
.
out_shapes
output_shape
=
_val_y
.
out_shapes
assert
input_shape
is
not
None
or
output_shape
is
not
None
,
'poolnd not inferred'
# N
if
input_shape
:
poolnd
=
len
(
input_shape
)
-
2
# NC...
elif
output_shape
:
poolnd
=
len
(
output_shape
)
-
2
# NC...
assert
2
<=
poolnd
<=
3
,
'only pool2d and pool3d is supported'
fluid_op
=
'pool{}d'
.
format
(
poolnd
)
attr
=
{
"pool_type"
:
string
(
"avg"
),
"global_pooling"
:
True
,
"name"
:
string
(
node
.
layer_name
)
}
node
.
fluid_code
.
add_layer
(
fluid_op
,
inputs
=
val_x
,
output
=
node
,
param_attr
=
attr
)
def
Conv
(
self
,
node
):
val_x
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
0
],
copy
=
True
)
val_w
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
1
],
copy
=
True
)
val_y
=
self
.
graph
.
get_node
(
node
.
layer
.
output
[
0
],
copy
=
True
)
self
.
omit_nodes
.
append
(
val_w
.
layer_name
)
input_shape
=
val_x
.
out_shapes
has_bias
=
len
(
node
.
layer
.
input
)
==
3
if
has_bias
:
val_b
=
self
.
graph
.
get_node
(
node
.
layer
.
input
[
2
],
copy
=
True
)
self
.
omit_nodes
.
append
(
val_b
.
layer_name
)
auto_pad
=
node
.
get_attr
(
'auto_pad'
,
'NOTSET'
)
kernel_shape
=
val_w
.
out_shapes
[
2
:]
# OI...
assert
kernel_shape
==
node
.
get_attr
(
'kernel_shape'
),
'kernel_shape in attr unmatches value_info'
# HW
convnd
=
len
(
kernel_shape
)
assert
2
<=
convnd
<=
3
,
'only conv2d and conv3d is supported'
num_out_channels
=
val_w
.
out_shapes
[
0
]
# OI...
fluid_op
=
'conv{}d'
.
format
(
convnd
)
num_groups
=
node
.
get_attr
(
'group'
,
1
)
strides
=
node
.
get_attr
(
'strides'
,
[
1
]
*
convnd
)
# optional
dilations
=
node
.
get_attr
(
'dilations'
,
[
1
]
*
convnd
)
# optional
pads
=
node
.
get_attr
(
'pads'
,
[
0
]
*
(
convnd
*
2
))
# optional
paddings
,
val_x
=
self
.
_pad_if_asymmetric
(
node
,
pads
,
val_x
)
if
auto_pad
==
"SAME_UPPER"
or
auto_pad
==
"SAME_UPPER"
:
pad_h
=
get_same_padding
(
input_shape
[
2
],
kernel_shape
[
0
],
strides
[
0
])
pad_w
=
get_same_padding
(
input_shape
[
3
],
kernel_shape
[
1
],
strides
[
1
])
attr
=
{
"paddings"
:
pad_h
+
pad_w
,
"pad_value"
:
0.0
}
attr
=
{
"num_filters"
:
num_out_channels
,
"filter_size"
:
kernel_shape
,
"stride"
:
strides
,
"padding"
:
paddings
,
"dilation"
:
dilations
,
"groups"
:
num_groups
,
'param_attr'
:
string
(
val_w
.
layer_name
),
"name"
:
string
(
node
.
layer_name
)
}
if
has_bias
:
attr
[
"bias_attr"
]
=
string
(
val_b
.
layer_name
)
else
:
attr
[
"bias_attr"
]
=
False
node
.
fluid_code
.
add_layer
(
fluid_op
,
inputs
=
val_x
,
output
=
node
,
param_attr
=
attr
)
x2paddle/optimizer/onnx_optimizer.py
0 → 100644
浏览文件 @
5d5ed8ae
# Copyright (c) 2019 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.
# TODO useless node remove
from
x2paddle.op_mapper.onnx_op_mapper
import
ONNXOpMapper
from
x2paddle.core.util
import
*
class
ONNXOptimizer
(
object
):
def
__init__
(
self
,
op_mapper
):
self
.
op_mapper
=
op_mapper
self
.
graph
=
op_mapper
.
graph
def
delete_redundance_code
(
self
):
for
node_name
in
self
.
graph
.
topo_sort
:
if
node_name
in
self
.
op_mapper
.
omit_nodes
:
node
=
self
.
graph
.
get_node
(
node_name
)
omit_freq
=
self
.
op_mapper
.
omit_nodes
.
count
(
node_name
)
if
len
(
node
.
outputs
)
<=
omit_freq
:
node
.
fluid_code
.
clear
()
# TODO activation merge
def
merge_activation
(
self
):
act_nodes
=
list
()
for
node_name
in
self
.
graph
.
topo_sort
:
node
=
self
.
graph
.
get_node
(
node_name
)
if
node
.
layer_type
in
self
.
activation_ops
:
act_nodes
.
append
(
node_name
)
for
act_node_name
in
act_nodes
:
node
=
self
.
graph
.
get_node
(
act_node_name
)
input
=
self
.
graph
.
get_node
(
node
.
inputs
[
0
])
if
input
.
layer_type
not
in
self
.
layers_with_act
:
continue
if
len
(
input
.
fluid_code
.
layers
)
==
0
:
continue
if
'act'
in
input
.
fluid_code
.
layers
[
-
1
].
param_attr
and
input
.
fluid_code
.
layers
[
-
1
].
param_attr
[
'act'
]
is
not
None
:
continue
if
len
(
input
.
outputs
)
!=
1
:
continue
input
.
fluid_code
.
layers
[
-
1
].
param_attr
[
'act'
]
=
string
(
self
.
activation_ops
[
node
.
layer_type
])
input
.
fluid_code
.
layers
[
-
1
].
output
=
node
.
fluid_code
.
layers
[
0
].
output
self
.
graph
.
remove_node
(
act_node_name
)
# TODO bias merge
def
merge_bias
(
self
):
for
node_name
in
self
.
graph
.
topo_sort
:
node
=
self
.
graph
.
get_node
(
node_name
)
if
node
.
layer_type
==
"BiasAdd"
:
input
=
self
.
graph
.
get_node
(
node
.
inputs
[
0
])
if
input
.
layer_type
not
in
self
.
layers_with_bias
:
continue
if
len
(
input
.
outputs
)
!=
1
:
continue
if
len
(
input
.
fluid_code
.
layers
)
==
0
:
continue
bias_with_act
=
False
if
'act'
in
node
.
fluid_code
.
layers
[
-
1
].
param_attr
:
bias_with_act
=
True
layer_with_act
=
False
if
'act'
in
input
.
fluid_code
.
layers
[
-
1
].
param_attr
and
input
.
fluid_code
.
layers
[
-
1
].
param_attr
[
'act'
]
is
not
None
:
layer_with_act
=
True
if
bias_with_act
and
layer_with_act
:
continue
if
not
input
.
fluid_code
.
layers
[
-
1
].
param_attr
[
'bias_attr'
]:
bias_name
=
node
.
inputs
[
1
]
input
.
fluid_code
.
layers
[
-
1
].
param_attr
[
'bias_attr'
]
=
string
(
bias_name
)
input
.
fluid_code
.
layers
[
-
1
].
output
=
node
.
fluid_code
.
layers
[
0
].
output
if
bias_with_act
:
input
.
fluid_code
.
layers
[
-
1
].
param_attr
[
'act'
]
=
node
.
fluid_code
.
layers
[
-
1
].
param_attr
[
'act'
]
node
.
fluid_code
.
clear
()
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