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0260d322
编写于
10月 14, 2019
作者:
J
juncaipeng
提交者:
GitHub
10月 14, 2019
浏览文件
操作
浏览文件
下载
电子邮件补丁
差异文件
Optimize quant_dequant_fuse_pass (#2169)
* optimize quant_dequant_fuse_pass, test=develop
上级
9aa795ca
变更
5
隐藏空白更改
内联
并排
Showing
5 changed file
with
159 addition
and
165 deletion
+159
-165
lite/api/mobilenetv1_int8_test.cc
lite/api/mobilenetv1_int8_test.cc
+15
-0
lite/core/mir/fusion/quant_dequant_fuse_pass.cc
lite/core/mir/fusion/quant_dequant_fuse_pass.cc
+51
-7
lite/core/mir/fusion/quant_dequant_op_fuser.cc
lite/core/mir/fusion/quant_dequant_op_fuser.cc
+88
-150
lite/core/mir/fusion/quant_dequant_op_fuser.h
lite/core/mir/fusion/quant_dequant_op_fuser.h
+3
-7
lite/operators/op_params.h
lite/operators/op_params.h
+2
-1
未找到文件。
lite/api/mobilenetv1_int8_test.cc
浏览文件 @
0260d322
...
@@ -74,6 +74,21 @@ void TestModel(const std::vector<Place>& valid_places,
...
@@ -74,6 +74,21 @@ void TestModel(const std::vector<Place>& valid_places,
1e-6
);
1e-6
);
}
}
}
}
auto
*
out_data
=
out
->
data
<
float
>
();
LOG
(
INFO
)
<<
"output data:"
;
for
(
int
i
=
0
;
i
<
out
->
numel
();
i
+=
step
)
{
LOG
(
INFO
)
<<
out_data
[
i
];
}
float
max_val
=
out_data
[
0
];
int
max_val_arg
=
0
;
for
(
int
i
=
1
;
i
<
out
->
numel
();
i
++
)
{
if
(
max_val
<
out_data
[
i
])
{
max_val
=
out_data
[
i
];
max_val_arg
=
i
;
}
}
LOG
(
INFO
)
<<
"max val:"
<<
max_val
<<
", max_val_arg:"
<<
max_val_arg
;
}
}
TEST
(
MobileNetV1
,
test_arm
)
{
TEST
(
MobileNetV1
,
test_arm
)
{
...
...
lite/core/mir/fusion/quant_dequant_fuse_pass.cc
浏览文件 @
0260d322
...
@@ -13,7 +13,9 @@
...
@@ -13,7 +13,9 @@
// limitations under the License.
// limitations under the License.
#include "lite/core/mir/fusion/quant_dequant_fuse_pass.h"
#include "lite/core/mir/fusion/quant_dequant_fuse_pass.h"
#include <list>
#include <memory>
#include <memory>
#include <unordered_set>
#include <vector>
#include <vector>
#include "lite/api/paddle_place.h"
#include "lite/api/paddle_place.h"
#include "lite/core/mir/fusion/quant_dequant_op_fuser.h"
#include "lite/core/mir/fusion/quant_dequant_op_fuser.h"
...
@@ -24,18 +26,60 @@ namespace lite {
...
@@ -24,18 +26,60 @@ namespace lite {
namespace
mir
{
namespace
mir
{
void
QuantDequantFusePass
::
Apply
(
const
std
::
unique_ptr
<
SSAGraph
>&
graph
)
{
void
QuantDequantFusePass
::
Apply
(
const
std
::
unique_ptr
<
SSAGraph
>&
graph
)
{
// obtain useful values and save to quantized_node, remove quant_nodes and
// releated nodes
std
::
unordered_set
<
std
::
string
>
quant_types
=
{
std
::
unordered_set
<
std
::
string
>
quant_types
=
{
"fake_quantize_range_abs_max"
,
"fake_quantize_moving_average_abs_max"
};
"fake_quantize_range_abs_max"
,
"fake_quantize_moving_average_abs_max"
};
std
::
unordered_set
<
std
::
string
>
quantized_op_types
=
{
for
(
auto
&
cur_node
:
graph
->
mutable_nodes
())
{
"conv2d"
,
"mul"
,
"depthwise_conv2d"
};
if
(
cur_node
.
IsStmt
()
&&
quant_types
.
count
(
cur_node
.
stmt
()
->
op_type
()))
{
for
(
auto
&
quant_type
:
quant_types
)
{
// find input nodes and output nodes
for
(
auto
&
op_type
:
quantized_op_types
)
{
std
::
list
<
Node
*>
input_nodes
=
cur_node
.
inlinks
;
for
(
int
i
=
6
;
i
>=
1
;
i
--
)
{
std
::
list
<
Node
*>
output_nodes
=
cur_node
.
outlinks
;
fusion
::
QuantDequantOpFuser
fuser
(
op_type
,
quant_type
,
i
);
CHECK_EQ
(
input_nodes
.
size
(),
2
);
fuser
(
graph
.
get
());
CHECK_EQ
(
output_nodes
.
size
(),
2
);
bool
front_is_scale
=
input_nodes
.
front
()
->
arg
()
->
is_weight
;
Node
*
input_scale_node
=
front_is_scale
?
input_nodes
.
front
()
:
input_nodes
.
back
();
Node
*
input_act_node
=
front_is_scale
?
input_nodes
.
back
()
:
input_nodes
.
front
();
front_is_scale
=
output_nodes
.
front
()
->
arg
()
->
is_weight
;
Node
*
output_scale_node
=
front_is_scale
?
output_nodes
.
front
()
:
output_nodes
.
back
();
Node
*
output_act_node
=
front_is_scale
?
output_nodes
.
back
()
:
output_nodes
.
front
();
// relink nodes and save value to quantized_node
int
bit_length
=
cur_node
.
stmt
()
->
op_info
()
->
GetAttr
<
int
>
(
"bit_length"
);
int
range
=
((
1
<<
(
bit_length
-
1
))
-
1
);
auto
*
scope
=
cur_node
.
stmt
()
->
op
()
->
scope
();
auto
scale_tensor
=
scope
->
FindVar
(
output_scale_node
->
arg
()
->
name
)
->
GetMutable
<
lite
::
Tensor
>
();
float
scale_value
=
scale_tensor
->
data
<
float
>
()[
0
]
/
range
;
for
(
auto
*
quantized_node_ptr
:
output_act_node
->
outlinks
)
{
quantized_node_ptr
->
stmt
()
->
mutable_op_info
()
->
SetAttr
<
int
>
(
"bit_length"
,
bit_length
);
quantized_node_ptr
->
stmt
()
->
mutable_op_info
()
->
SetAttr
<
float
>
(
"input_scale"
,
scale_value
);
IR_NODE_LINK_TO
(
input_act_node
,
quantized_node_ptr
)
RemoveDirectedLink
(
output_act_node
,
quantized_node_ptr
);
}
}
// delete nodes and edges
std
::
unordered_set
<
const
Node
*>
nodes2rm
=
{
input_scale_node
,
&
cur_node
,
output_scale_node
,
output_act_node
};
GraphSafeRemoveNodes
(
graph
.
get
(),
nodes2rm
);
}
}
}
}
// fuse quantized node and dequant node
std
::
unordered_set
<
std
::
string
>
quantized_op_types
=
{
"conv2d"
,
"mul"
,
"depthwise_conv2d"
};
for
(
auto
&
op_type
:
quantized_op_types
)
{
fusion
::
QuantDequantOpFuser
fuser
(
op_type
);
fuser
(
graph
.
get
());
}
}
}
}
// namespace mir
}
// namespace mir
...
...
lite/core/mir/fusion/quant_dequant_op_fuser.cc
浏览文件 @
0260d322
...
@@ -23,170 +23,108 @@ namespace mir {
...
@@ -23,170 +23,108 @@ namespace mir {
namespace
fusion
{
namespace
fusion
{
void
QuantDequantOpFuser
::
BuildPattern
()
{
void
QuantDequantOpFuser
::
BuildPattern
()
{
const
int
kNumFields
=
5
;
const
int
kQuantizedWeightOffset
=
0
;
const
int
kQuantizedOpOffset
=
1
;
const
int
kQuantizedOpOutOffset
=
2
;
const
int
kDequantOpOffset
=
3
;
const
int
kDequantOpOutOffset
=
4
;
std
::
string
weight_name
=
""
;
std
::
string
weight_name
=
""
;
if
(
op_type_
==
"conv2d"
||
op_type_
==
"depthwise_conv2d"
)
{
if
(
op_type_
==
"conv2d"
||
op_type_
==
"depthwise_conv2d"
)
{
weight_name
=
"Filter"
;
weight_name
=
"Filter"
;
}
else
{
}
else
{
weight_name
=
"Y"
;
weight_name
=
"Y"
;
}
}
auto
*
quant_op_input
=
VarNode
(
"quant_op_input"
)
->
assert_is_op_input
(
quant_type_
,
"X"
)
->
AsInput
();
auto
*
quant_op_in_scale
=
VarNode
(
"quant_op_in_scale"
)
->
assert_is_op_input
(
quant_type_
,
"InScale"
)
->
AsIntermediate
();
auto
*
quant_op
=
OpNode
(
"quant_op"
,
quant_type_
)
->
assert_is_op
(
quant_type_
)
->
AsIntermediate
();
auto
*
quant_op_out_scale
=
VarNode
(
"quant_op_out_scale"
)
->
assert_is_op_output
(
quant_type_
,
"OutScale"
)
->
assert_is_op_input
(
"fake_dequantize_max_abs"
,
"Scale"
)
->
AsIntermediate
();
auto
*
quant_op_out
=
VarNode
(
"quant_op_out"
)
auto
*
quantized_op_input
=
->
assert_is_op_output
(
quant_type_
,
"Out"
)
VarNode
(
"quantized_op_input"
)
->
assert_is_op_input
(
op_type_
)
->
AsInput
();
->
assert_is_op_input
(
op_type_
)
auto
*
quantized_op_weight
=
VarNode
(
"quantized_op_weight"
)
->
assert_is_op_input
(
op_type_
,
weight_name
)
->
AsInput
();
auto
*
quantized_op
=
OpNode
(
"quantized_op"
,
op_type_
)
->
assert_is_op
(
op_type_
)
->
AsIntermediate
();
->
AsIntermediate
();
std
::
vector
<
PMNode
*>
nodes
;
auto
*
quantized_op_out
=
for
(
int
i
=
0
;
i
<
times_
;
i
++
)
{
VarNode
(
"quantized_op_out"
)
nodes
.
push_back
(
VarNode
(
string_format
(
"quantized_op_weight%d"
,
i
))
->
assert_is_op_output
(
op_type_
)
->
assert_is_op_input
(
op_type_
,
weight_name
)
->
assert_is_op_input
(
"fake_dequantize_max_abs"
,
"X"
)
->
AsInput
());
->
AsIntermediate
();
auto
*
dequant_op
=
OpNode
(
"dequant_op"
,
"fake_dequantize_max_abs"
)
nodes
.
push_back
(
OpNode
(
string_format
(
"quantized_op%d"
,
i
),
op_type_
)
->
assert_is_op
(
"fake_dequantize_max_abs"
)
->
assert_is_op
(
op_type_
)
->
AsIntermediate
();
->
AsIntermediate
());
auto
*
dequant_op_out
=
VarNode
(
"dequant_op_out"
)
nodes
.
push_back
(
VarNode
(
string_format
(
"quantized_op_out%d"
,
i
))
->
assert_is_op_output
(
"fake_dequantize_max_abs"
,
"Out"
)
->
assert_is_op_output
(
op_type_
)
->
AsOutput
();
->
assert_is_op_input
(
"fake_dequantize_max_abs"
,
"X"
)
->
AsIntermediate
());
quantized_op
->
LinksFrom
({
quantized_op_input
,
quantized_op_weight
});
quantized_op_out
->
LinksFrom
({
quantized_op
});
nodes
.
push_back
(
dequant_op
->
LinksFrom
({
quantized_op_out
});
OpNode
(
string_format
(
"dequant_op%d"
,
i
),
"fake_dequantize_max_abs"
)
dequant_op_out
->
LinksFrom
({
dequant_op
});
->
assert_is_op
(
"fake_dequantize_max_abs"
)
->
AsIntermediate
());
nodes
.
push_back
(
VarNode
(
string_format
(
"dequant_op_out%d"
,
i
))
->
assert_is_op_output
(
"fake_dequantize_max_abs"
,
"Out"
)
->
AsOutput
());
}
quant_op
->
LinksFrom
({
quant_op_input
,
quant_op_in_scale
});
quant_op_out
->
LinksFrom
({
quant_op
});
quant_op_out_scale
->
LinksFrom
({
quant_op
});
for
(
int
i
=
0
;
i
<
times_
;
i
++
)
{
nodes
[
i
*
kNumFields
+
kQuantizedOpOffset
]
->
LinksFrom
(
{
quant_op_out
,
nodes
[
i
*
kNumFields
+
kQuantizedWeightOffset
]});
nodes
[
i
*
kNumFields
+
kQuantizedOpOutOffset
]
->
LinksFrom
(
{
nodes
[
i
*
kNumFields
+
kQuantizedOpOffset
]});
nodes
[
i
*
kNumFields
+
kDequantOpOffset
]
->
LinksFrom
(
{
nodes
[
i
*
kNumFields
+
kQuantizedOpOutOffset
],
quant_op_out_scale
});
nodes
[
i
*
kNumFields
+
kDequantOpOutOffset
]
->
LinksFrom
(
{
nodes
[
i
*
kNumFields
+
kDequantOpOffset
]});
}
}
}
void
QuantDequantOpFuser
::
InsertNewNode
(
SSAGraph
*
graph
,
void
QuantDequantOpFuser
::
InsertNewNode
(
SSAGraph
*
graph
,
const
key2nodes_t
&
matched
)
{
const
key2nodes_t
&
matched
)
{
const
int
kNumFields
=
5
;
auto
*
quant_op_input
=
matched
.
at
(
"quantized_op_input"
);
const
int
kQuantizedWeightOffset
=
0
;
auto
*
quantized_op_weight
=
matched
.
at
(
"quantized_op_weight"
);
const
int
kQuantizedOpOffset
=
1
;
auto
*
quantized_op
=
matched
.
at
(
"quantized_op"
);
const
int
kDequantOpOffset
=
3
;
auto
*
dequant_op
=
matched
.
at
(
"dequant_op"
);
const
int
kDequantOpOutOffset
=
4
;
auto
*
dequant_op_out
=
matched
.
at
(
"dequant_op_out"
);
auto
*
quant_op_input
=
matched
.
at
(
"quant_op_input"
);
// obtain input_scale and weight_scale
auto
*
quant_op_in_scale
=
matched
.
at
(
"quant_op_in_scale"
);
auto
*
scope
=
quantized_op
->
stmt
()
->
op
()
->
scope
();
auto
*
quant_op
=
matched
.
at
(
"quant_op"
);
auto
&
valid_places
=
quantized_op
->
stmt
()
->
op
()
->
valid_places
();
int
bit_length
=
quantized_op
->
stmt
()
->
op_info
()
->
GetAttr
<
int
>
(
"bit_length"
);
std
::
vector
<
Node
*>
nodes
;
for
(
int
i
=
0
;
i
<
times_
;
i
++
)
{
nodes
.
push_back
(
matched
.
at
(
string_format
(
"quantized_op_weight%d"
,
i
)));
nodes
.
push_back
(
matched
.
at
(
string_format
(
"quantized_op%d"
,
i
)));
nodes
.
push_back
(
matched
.
at
(
string_format
(
"quantized_op_out%d"
,
i
)));
nodes
.
push_back
(
matched
.
at
(
string_format
(
"dequant_op%d"
,
i
)));
nodes
.
push_back
(
matched
.
at
(
string_format
(
"dequant_op_out%d"
,
i
)));
}
int
bit_length
=
quant_op
->
stmt
()
->
op_info
()
->
GetAttr
<
int
>
(
"bit_length"
);
auto
*
scope
=
quant_op
->
stmt
()
->
op
()
->
scope
();
auto
&
valid_places
=
quant_op
->
stmt
()
->
op
()
->
valid_places
();
int
range
=
((
1
<<
(
bit_length
-
1
))
-
1
);
int
range
=
((
1
<<
(
bit_length
-
1
))
-
1
);
auto
input_scale_t
=
scope
->
FindVar
(
quant_op_in_scale
->
arg
()
->
name
)
float
input_scale
=
->
GetMutable
<
lite
::
Tensor
>
();
quantized_op
->
stmt
()
->
op_info
()
->
GetAttr
<
float
>
(
"input_scale"
);
float
input_scale
=
input_scale_t
->
data
<
float
>
()[
0
]
/
range
;
float
max_range
=
dequant_op
->
stmt
()
->
op_info
()
->
GetAttr
<
float
>
(
"max_range"
);
float
whole_weight_scale
=
VLOG
(
4
)
<<
"range: "
<<
range
<<
" input_scale: "
<<
input_scale
;
static_cast
<
float
>
(
range
*
range
)
/
max_range
/
range
;
for
(
int
i
=
0
;
i
<
times_
;
i
++
)
{
// max_range = range * range / max(abs(weight))
float
max_range
=
nodes
[
i
*
kNumFields
+
kDequantOpOffset
]
// weight_scale = range * range / (range * range / max(abs(weight))) / range
->
stmt
()
// = max(abs(weight)) / range
->
op_info
()
->
GetAttr
<
float
>
(
"max_range"
);
// set op desc
// weight_scale = max(abs(weight))
cpp
::
OpDesc
op_desc
=
*
quantized_op
->
stmt
()
->
op_info
();
float
whole_weight_scale
=
auto
quantized_weight_var_name
=
quantized_op_weight
->
arg
()
->
name
;
static_cast
<
float
>
(
range
*
range
)
/
max_range
/
range
;
auto
quantized_weight_t
=
scope
->
FindVar
(
quantized_weight_var_name
)
->
GetMutable
<
lite
::
Tensor
>
();
cpp
::
OpDesc
op_desc
=
std
::
vector
<
float
>
weight_scale
;
*
nodes
[
i
*
kNumFields
+
kQuantizedOpOffset
]
->
stmt
()
->
op_info
();
int
weight_scale_size
;
if
(
op_type_
==
"conv2d"
||
op_type_
==
"depthwise_conv2d"
)
{
auto
quantized_weight_var_name
=
op_desc
.
SetInput
(
"Input"
,
{
quant_op_input
->
arg
()
->
name
});
nodes
[
i
*
kNumFields
+
kQuantizedWeightOffset
]
->
arg
()
->
name
;
op_desc
.
SetOutput
(
"Output"
,
{
dequant_op_out
->
arg
()
->
name
});
auto
quantized_weight_t
=
// Conv weight shape: Cout * Cin * kh * hw, the weight_scale_size should
scope
->
FindVar
(
quantized_weight_var_name
)
->
GetMutable
<
lite
::
Tensor
>
();
// be Cout.
std
::
vector
<
float
>
weight_scale
;
weight_scale_size
=
quantized_weight_t
->
dims
()[
0
];
int
weight_scale_size
;
}
else
if
(
op_type_
==
"mul"
)
{
op_desc
.
SetInput
(
"X"
,
{
quant_op_input
->
arg
()
->
name
});
if
(
op_type_
==
"conv2d"
||
op_type_
==
"depthwise_conv2d"
)
{
op_desc
.
SetOutput
(
"Out"
,
{
dequant_op_out
->
arg
()
->
name
});
op_desc
.
SetInput
(
"Input"
,
{
matched
.
at
(
"quant_op_input"
)
->
arg
()
->
name
});
// Fc weight: Cin * Cout, the weight_scale_size should be Cout.
op_desc
.
SetOutput
(
weight_scale_size
=
quantized_weight_t
->
dims
()[
1
];
"Output"
,
{
nodes
[
i
*
kNumFields
+
kDequantOpOutOffset
]
->
arg
()
->
name
});
}
// Conv weight shape: Cout * Cin * kh * hw, the weight_scale_size should
for
(
int
i
=
0
;
i
<
weight_scale_size
;
i
++
)
{
// be Cout.
weight_scale
.
push_back
(
whole_weight_scale
);
weight_scale_size
=
quantized_weight_t
->
dims
()[
0
];
}
}
else
if
(
op_type_
==
"mul"
)
{
op_desc
.
SetAttr
(
"enable_int8"
,
true
);
op_desc
.
SetInput
(
"X"
,
{
matched
.
at
(
"quant_op_input"
)
->
arg
()
->
name
});
op_desc
.
SetAttr
(
"input_scale"
,
input_scale
);
op_desc
.
SetOutput
(
op_desc
.
SetAttr
(
"weight_scale"
,
weight_scale
);
"Out"
,
{
nodes
[
i
*
kNumFields
+
kDequantOpOutOffset
]
->
arg
()
->
name
});
// Fc weight: Cin * Cout, the weight_scale_size should be Cout.
// change the weight from the float type to int8 type.
weight_scale_size
=
quantized_weight_t
->
dims
()[
1
];
Tensor
temp_tensor
;
}
temp_tensor
.
CopyDataFrom
(
*
quantized_weight_t
);
for
(
int
i
=
0
;
i
<
weight_scale_size
;
i
++
)
{
float
*
temp_data
=
temp_tensor
.
mutable_data
<
float
>
();
weight_scale
.
push_back
(
whole_weight_scale
);
size_t
weight_num
=
quantized_weight_t
->
data_size
();
}
int8_t
*
quantized_weight_data
=
quantized_weight_t
->
mutable_data
<
int8_t
>
();
op_desc
.
SetAttr
(
"enable_int8"
,
true
);
for
(
size_t
i
=
0
;
i
<
weight_num
;
i
++
)
{
op_desc
.
SetAttr
(
"input_scale"
,
input_scale
);
quantized_weight_data
[
i
]
=
static_cast
<
int8_t
>
(
temp_data
[
i
]);
op_desc
.
SetAttr
(
"weight_scale"
,
weight_scale
);
Tensor
temp_tensor
;
temp_tensor
.
CopyDataFrom
(
*
quantized_weight_t
);
float
*
temp_data
=
temp_tensor
.
mutable_data
<
float
>
();
size_t
weight_num
=
quantized_weight_t
->
data_size
();
int8_t
*
quantized_weight_data
=
quantized_weight_t
->
mutable_data
<
int8_t
>
();
// change the weight from the float type to int8 type.
for
(
size_t
i
=
0
;
i
<
weight_num
;
i
++
)
{
quantized_weight_data
[
i
]
=
static_cast
<
int8_t
>
(
temp_data
[
i
]);
}
quantized_weight_t
->
set_persistable
(
true
);
quantized_weight_t
->
set_precision
(
PRECISION
(
kInt8
));
auto
quantized_op
=
LiteOpRegistry
::
Global
().
Create
(
op_type_
);
quantized_op
->
Attach
(
op_desc
,
scope
);
auto
*
new_op_node
=
graph
->
GraphCreateInstructNode
(
quantized_op
,
valid_places
);
IR_NODE_LINK_TO
(
quant_op_input
,
new_op_node
);
IR_NODE_LINK_TO
(
nodes
[
i
*
kNumFields
+
kQuantizedWeightOffset
],
new_op_node
);
IR_NODE_LINK_TO
(
new_op_node
,
nodes
[
i
*
kNumFields
+
kDequantOpOutOffset
]);
}
}
quantized_weight_t
->
set_persistable
(
true
);
quantized_weight_t
->
set_precision
(
PRECISION
(
kInt8
));
// new op and relink nodes
auto
new_quantized_op
=
LiteOpRegistry
::
Global
().
Create
(
op_type_
);
new_quantized_op
->
Attach
(
op_desc
,
scope
);
auto
*
new_quantized_op_node
=
graph
->
GraphCreateInstructNode
(
new_quantized_op
,
valid_places
);
IR_NODE_LINK_TO
(
quant_op_input
,
new_quantized_op_node
);
IR_NODE_LINK_TO
(
quantized_op_weight
,
new_quantized_op_node
);
IR_NODE_LINK_TO
(
new_quantized_op_node
,
dequant_op_out
);
}
}
cpp
::
OpDesc
QuantDequantOpFuser
::
GenOpDesc
(
const
key2nodes_t
&
matched
)
{
cpp
::
OpDesc
QuantDequantOpFuser
::
GenOpDesc
(
const
key2nodes_t
&
matched
)
{
...
...
lite/core/mir/fusion/quant_dequant_op_fuser.h
浏览文件 @
0260d322
...
@@ -37,10 +37,8 @@ namespace fusion {
...
@@ -37,10 +37,8 @@ namespace fusion {
*/
*/
class
QuantDequantOpFuser
:
public
FuseBase
{
class
QuantDequantOpFuser
:
public
FuseBase
{
public:
public:
explicit
QuantDequantOpFuser
(
const
std
::
string
&
op_type
,
explicit
QuantDequantOpFuser
(
const
std
::
string
&
op_type
)
const
std
::
string
&
quant_type
,
:
op_type_
(
op_type
)
{}
int
times
)
:
op_type_
(
op_type
),
quant_type_
(
quant_type
),
times_
(
times
)
{}
void
BuildPattern
()
override
;
void
BuildPattern
()
override
;
void
InsertNewNode
(
SSAGraph
*
graph
,
const
key2nodes_t
&
matched
)
override
;
void
InsertNewNode
(
SSAGraph
*
graph
,
const
key2nodes_t
&
matched
)
override
;
...
@@ -48,9 +46,7 @@ class QuantDequantOpFuser : public FuseBase {
...
@@ -48,9 +46,7 @@ class QuantDequantOpFuser : public FuseBase {
cpp
::
OpDesc
GenOpDesc
(
const
key2nodes_t
&
matched
)
override
;
cpp
::
OpDesc
GenOpDesc
(
const
key2nodes_t
&
matched
)
override
;
private:
private:
std
::
string
op_type_
{
"conv2d"
};
std
::
string
op_type_
{};
std
::
string
quant_type_
;
int
times_
;
};
};
}
// namespace fusion
}
// namespace fusion
...
...
lite/operators/op_params.h
浏览文件 @
0260d322
...
@@ -35,7 +35,8 @@ using param_t = Any;
...
@@ -35,7 +35,8 @@ using param_t = Any;
bool enable_int8{false}; \
bool enable_int8{false}; \
float input_scale{1.0}; \
float input_scale{1.0}; \
std::vector<float> weight_scale{}; \
std::vector<float> weight_scale{}; \
float output_scale{1.0};
float output_scale{1.0}; \
int bit_length{8};
/// ----------------------- Functional operators ------------------------------
/// ----------------------- Functional operators ------------------------------
struct
FeedParam
{
struct
FeedParam
{
...
...
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