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72ee737f
编写于
4月 24, 2018
作者:
W
wangyang59
提交者:
GitHub
4月 24, 2018
浏览文件
操作
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差异文件
Merge pull request #9308 from wangyang59/bilinear
Bilinear interp op
上级
2182ecfb
bf021f34
变更
4
隐藏空白更改
内联
并排
Showing
4 changed file
with
518 addition
and
0 deletion
+518
-0
paddle/fluid/operators/bilinear_interp_op.cc
paddle/fluid/operators/bilinear_interp_op.cc
+94
-0
paddle/fluid/operators/bilinear_interp_op.cu
paddle/fluid/operators/bilinear_interp_op.cu
+186
-0
paddle/fluid/operators/bilinear_interp_op.h
paddle/fluid/operators/bilinear_interp_op.h
+143
-0
python/paddle/fluid/tests/unittests/test_bilinear_interp_op.py
...n/paddle/fluid/tests/unittests/test_bilinear_interp_op.py
+95
-0
未找到文件。
paddle/fluid/operators/bilinear_interp_op.cc
0 → 100644
浏览文件 @
72ee737f
/* Copyright (c) 2016 PaddlePaddle Authors. All Rights Reserve.
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. */
#include "paddle/fluid/operators/bilinear_interp_op.h"
#include <vector>
#include "paddle/fluid/framework/op_registry.h"
namespace
paddle
{
namespace
operators
{
using
framework
::
Tensor
;
class
BilinearInterpOp
:
public
framework
::
OperatorWithKernel
{
public:
using
framework
::
OperatorWithKernel
::
OperatorWithKernel
;
protected:
void
InferShape
(
framework
::
InferShapeContext
*
ctx
)
const
override
{
PADDLE_ENFORCE
(
ctx
->
HasInput
(
"X"
),
"Input(X) of BilinearInterOp should not be null."
);
PADDLE_ENFORCE
(
ctx
->
HasOutput
(
"Out"
),
"Output(Out) of BilinearInterOp should not be null."
);
auto
dim_x
=
ctx
->
GetInputDim
(
"X"
);
// NCHW format
int
out_h
=
ctx
->
Attrs
().
Get
<
int
>
(
"out_h"
);
int
out_w
=
ctx
->
Attrs
().
Get
<
int
>
(
"out_w"
);
PADDLE_ENFORCE_EQ
(
dim_x
.
size
(),
4
,
"X's dimension must be 4"
);
std
::
vector
<
int64_t
>
dim_out
({
dim_x
[
0
],
dim_x
[
1
],
out_h
,
out_w
});
ctx
->
SetOutputDim
(
"Out"
,
framework
::
make_ddim
(
dim_out
));
}
};
class
BilinearInterpOpMaker
:
public
framework
::
OpProtoAndCheckerMaker
{
public:
BilinearInterpOpMaker
(
OpProto
*
proto
,
OpAttrChecker
*
op_checker
)
:
OpProtoAndCheckerMaker
(
proto
,
op_checker
)
{
AddInput
(
"X"
,
"(Tensor) The input tensor of bilinear interpolation, "
"This is a 4-D tensor with shape of (N x C x h x w)"
);
AddOutput
(
"Out"
,
"(Tensor) The dimension of output is (N x C x out_h x out_w]"
);
AddAttr
<
int
>
(
"out_h"
,
"(int) output height of bilinear interpolation op."
);
AddAttr
<
int
>
(
"out_w"
,
"(int) output width of bilinear interpolation op."
);
AddComment
(
R"DOC(
Bilinear interpolation is an extension of linear interpolation for
interpolating functions of two variables (e.g. H-direction and
W-direction in this op) on a rectilinear 2D grid.
The key idea is to perform linear interpolation first in one
direction, and then again in the other direction.
For details, please refer to Wikipedia:
https://en.wikipedia.org/wiki/Bilinear_interpolation
)DOC"
);
}
};
class
BilinearInterpOpGrad
:
public
framework
::
OperatorWithKernel
{
public:
using
framework
::
OperatorWithKernel
::
OperatorWithKernel
;
protected:
void
InferShape
(
framework
::
InferShapeContext
*
ctx
)
const
override
{
PADDLE_ENFORCE
(
ctx
->
HasInput
(
"X"
),
"Input(X) should not be null"
);
PADDLE_ENFORCE
(
ctx
->
HasInput
(
framework
::
GradVarName
(
"Out"
)),
"Input(Out@GRAD) should not be null"
);
auto
dim_x
=
ctx
->
GetInputDim
(
"X"
);
if
(
ctx
->
HasOutput
(
framework
::
GradVarName
(
"X"
)))
{
ctx
->
SetOutputDim
(
framework
::
GradVarName
(
"X"
),
dim_x
);
}
}
};
}
// namespace operators
}
// namespace paddle
namespace
ops
=
paddle
::
operators
;
REGISTER_OPERATOR
(
bilinear_interp
,
ops
::
BilinearInterpOp
,
ops
::
BilinearInterpOpMaker
,
paddle
::
framework
::
DefaultGradOpDescMaker
<
true
>
);
REGISTER_OPERATOR
(
bilinear_interp_grad
,
ops
::
BilinearInterpOpGrad
);
REGISTER_OP_CPU_KERNEL
(
bilinear_interp
,
ops
::
BilinearInterpKernel
<
float
>
);
REGISTER_OP_CPU_KERNEL
(
bilinear_interp_grad
,
ops
::
BilinearInterpGradKernel
<
float
>
);
paddle/fluid/operators/bilinear_interp_op.cu
0 → 100644
浏览文件 @
72ee737f
/* Copyright (c) 2016 PaddlePaddle Authors. All Rights Reserve.
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. */
#include "paddle/fluid/operators/bilinear_interp_op.h"
#include "paddle/fluid/platform/cuda_helper.h"
namespace
paddle
{
namespace
operators
{
using
framework
::
Tensor
;
template
<
typename
T
>
__global__
void
KeBilinearInterpFw
(
const
T
*
in
,
const
size_t
in_img_h
,
const
size_t
in_img_w
,
const
size_t
input_h
,
const
size_t
input_w
,
T
*
out
,
const
size_t
out_img_h
,
const
size_t
out_img_w
,
const
size_t
output_h
,
const
size_t
output_w
,
const
size_t
num_channels
,
const
T
ratio_h
,
const
T
ratioW
)
{
int
nthreads
=
output_h
*
output_w
;
int
tid
=
blockIdx
.
x
*
blockDim
.
x
+
threadIdx
.
x
;
if
(
tid
<
nthreads
)
{
int
out_id_h
=
tid
/
output_w
;
int
out_id_w
=
tid
%
output_w
;
int
in_img_size
=
input_w
/
num_channels
;
int
out_img_size
=
output_w
/
num_channels
;
int
channel_id
=
out_id_w
/
out_img_size
;
int
out_img_idy
=
(
out_id_w
%
out_img_size
)
/
out_img_w
;
int
in_img_idy
=
ratio_h
*
out_img_idy
;
int
h_id
=
(
in_img_idy
<
in_img_h
-
1
)
?
1
:
0
;
T
h1lambda
=
ratio_h
*
out_img_idy
-
in_img_idy
;
T
h2lambda
=
1.
f
-
h1lambda
;
int
out_img_idx
=
tid
%
out_img_w
;
int
in_img_idx
=
ratioW
*
out_img_idx
;
int
w_id
=
(
in_img_idx
<
in_img_w
-
1
)
?
1
:
0
;
T
w1lambda
=
ratioW
*
out_img_idx
-
in_img_idx
;
T
w2lambda
=
1.
f
-
w1lambda
;
const
T
*
in_pos
=
&
in
[
out_id_h
*
input_w
+
channel_id
*
in_img_size
+
in_img_idy
*
in_img_w
+
in_img_idx
];
// bilinear interpolation
out
[
out_id_h
*
output_w
+
out_id_w
]
=
h2lambda
*
(
w2lambda
*
in_pos
[
0
]
+
w1lambda
*
in_pos
[
w_id
])
+
h1lambda
*
(
w2lambda
*
in_pos
[
h_id
*
in_img_w
]
+
w1lambda
*
in_pos
[
h_id
*
in_img_w
+
w_id
]);
}
}
template
<
typename
T
>
__global__
void
KeBilinearInterpBw
(
T
*
in
,
const
size_t
in_img_h
,
const
size_t
in_img_w
,
const
size_t
input_h
,
const
size_t
input_w
,
const
T
*
out
,
const
size_t
out_img_h
,
const
size_t
out_img_w
,
const
size_t
output_h
,
const
size_t
output_w
,
const
size_t
num_channels
,
const
T
ratio_h
,
const
T
ratioW
)
{
int
nthreads
=
output_h
*
output_w
;
int
tid
=
blockIdx
.
x
*
blockDim
.
x
+
threadIdx
.
x
;
if
(
tid
<
nthreads
)
{
int
out_id_h
=
tid
/
output_w
;
int
out_id_w
=
tid
%
output_w
;
int
in_img_size
=
input_w
/
num_channels
;
int
out_img_size
=
output_w
/
num_channels
;
int
channel_id
=
out_id_w
/
out_img_size
;
int
out_img_idy
=
(
out_id_w
%
out_img_size
)
/
out_img_w
;
int
in_img_idy
=
ratio_h
*
out_img_idy
;
int
h_id
=
(
in_img_idy
<
in_img_h
-
1
)
?
1
:
0
;
T
h1lambda
=
ratio_h
*
out_img_idy
-
in_img_idy
;
T
h2lambda
=
1.
f
-
h1lambda
;
int
out_img_idx
=
tid
%
out_img_w
;
int
in_img_idx
=
ratioW
*
out_img_idx
;
int
w_id
=
(
in_img_idx
<
in_img_w
-
1
)
?
1
:
0
;
T
w1lambda
=
ratioW
*
out_img_idx
-
in_img_idx
;
T
w2lambda
=
1.
f
-
w1lambda
;
T
*
in_pos
=
&
in
[
out_id_h
*
input_w
+
channel_id
*
in_img_size
+
in_img_idy
*
in_img_w
+
in_img_idx
];
const
T
*
out_pos
=
&
out
[
out_id_h
*
output_w
+
out_id_w
];
atomicAdd
(
&
in_pos
[
0
],
h2lambda
*
w2lambda
*
out_pos
[
0
]);
atomicAdd
(
&
in_pos
[
w_id
],
h2lambda
*
w1lambda
*
out_pos
[
0
]);
atomicAdd
(
&
in_pos
[
h_id
*
in_img_w
],
h1lambda
*
w2lambda
*
out_pos
[
0
]);
atomicAdd
(
&
in_pos
[
h_id
*
in_img_w
+
w_id
],
h1lambda
*
w1lambda
*
out_pos
[
0
]);
}
}
template
<
typename
T
>
class
BilinearInterpOpCUDAKernel
:
public
framework
::
OpKernel
<
T
>
{
public:
void
Compute
(
const
framework
::
ExecutionContext
&
ctx
)
const
override
{
PADDLE_ENFORCE
(
platform
::
is_gpu_place
(
ctx
.
GetPlace
()),
"This kernel only runs on GPU device."
);
auto
*
input_t
=
ctx
.
Input
<
Tensor
>
(
"X"
);
// float tensor
auto
*
output_t
=
ctx
.
Output
<
Tensor
>
(
"Out"
);
// float tensor
auto
*
input
=
input_t
->
data
<
T
>
();
auto
*
output
=
output_t
->
mutable_data
<
T
>
(
ctx
.
GetPlace
());
int
out_h
=
ctx
.
Attr
<
int
>
(
"out_h"
);
int
out_w
=
ctx
.
Attr
<
int
>
(
"out_w"
);
int
batch_size
=
input_t
->
dims
()[
0
];
int
channels
=
input_t
->
dims
()[
1
];
int
in_h
=
input_t
->
dims
()[
2
];
int
in_w
=
input_t
->
dims
()[
3
];
int
in_hw
=
in_h
*
in_w
;
int
out_hw
=
out_h
*
out_w
;
int
in_chw
=
channels
*
in_hw
;
int
out_chw
=
channels
*
out_hw
;
T
ratio_h
=
(
out_h
>
1
)
?
static_cast
<
T
>
(
in_h
-
1
)
/
(
out_h
-
1
)
:
0.
f
;
T
ratio_w
=
(
out_w
>
1
)
?
static_cast
<
T
>
(
in_w
-
1
)
/
(
out_w
-
1
)
:
0.
f
;
if
(
in_h
==
out_h
&&
in_w
==
out_w
)
{
memcpy
(
output
,
input
,
input_t
->
numel
()
*
sizeof
(
T
));
}
else
{
int
threadNum
=
batch_size
*
out_chw
;
int
blocks
=
(
threadNum
+
1024
-
1
)
/
1024
;
KeBilinearInterpFw
<
T
><<<
blocks
,
1024
,
0
,
ctx
.
cuda_device_context
().
stream
()
>>>
(
input
,
in_h
,
in_w
,
batch_size
,
in_chw
,
output
,
out_h
,
out_w
,
batch_size
,
out_chw
,
channels
,
ratio_h
,
ratio_w
);
}
}
};
template
<
typename
T
>
class
BilinearInterpGradOpCUDAKernel
:
public
framework
::
OpKernel
<
T
>
{
public:
void
Compute
(
const
framework
::
ExecutionContext
&
ctx
)
const
override
{
auto
*
d_input_t
=
ctx
.
Output
<
Tensor
>
(
framework
::
GradVarName
(
"X"
));
auto
*
d_output_t
=
ctx
.
Input
<
Tensor
>
(
framework
::
GradVarName
(
"Out"
));
auto
*
d_input
=
d_input_t
->
mutable_data
<
T
>
(
ctx
.
GetPlace
());
auto
*
d_output
=
d_output_t
->
data
<
T
>
();
auto
&
device_ctx
=
ctx
.
template
device_context
<
platform
::
CUDADeviceContext
>();
math
::
SetConstant
<
platform
::
CUDADeviceContext
,
T
>
zero
;
zero
(
device_ctx
,
d_input_t
,
static_cast
<
T
>
(
0.0
));
int
out_h
=
ctx
.
Attr
<
int
>
(
"out_h"
);
int
out_w
=
ctx
.
Attr
<
int
>
(
"out_w"
);
int
batch_size
=
d_input_t
->
dims
()[
0
];
int
channels
=
d_input_t
->
dims
()[
1
];
int
in_h
=
d_input_t
->
dims
()[
2
];
int
in_w
=
d_input_t
->
dims
()[
3
];
int
in_hw
=
in_h
*
in_w
;
int
out_hw
=
out_h
*
out_w
;
int
in_chw
=
channels
*
in_hw
;
int
out_chw
=
channels
*
out_hw
;
T
ratio_h
=
(
out_h
>
1
)
?
static_cast
<
T
>
(
in_h
-
1
)
/
(
out_h
-
1
)
:
0.
f
;
T
ratio_w
=
(
out_w
>
1
)
?
static_cast
<
T
>
(
in_w
-
1
)
/
(
out_w
-
1
)
:
0.
f
;
if
(
in_h
==
out_h
&&
in_w
==
out_w
)
{
memcpy
(
d_input
,
d_output
,
d_input_t
->
numel
()
*
sizeof
(
T
));
}
else
{
int
threadNum
=
batch_size
*
out_chw
;
int
blocks
=
(
threadNum
+
1024
-
1
)
/
1024
;
KeBilinearInterpBw
<
T
><<<
blocks
,
1024
,
0
,
ctx
.
cuda_device_context
().
stream
()
>>>
(
d_input
,
in_h
,
in_w
,
batch_size
,
in_chw
,
d_output
,
out_h
,
out_w
,
batch_size
,
out_chw
,
channels
,
ratio_h
,
ratio_w
);
}
}
};
}
// namespace operators
}
// namespace paddle
namespace
ops
=
paddle
::
operators
;
REGISTER_OP_CUDA_KERNEL
(
bilinear_interp
,
ops
::
BilinearInterpOpCUDAKernel
<
float
>
);
REGISTER_OP_CUDA_KERNEL
(
bilinear_interp_grad
,
ops
::
BilinearInterpGradOpCUDAKernel
<
float
>
);
paddle/fluid/operators/bilinear_interp_op.h
0 → 100644
浏览文件 @
72ee737f
/* Copyright (c) 2016 PaddlePaddle Authors. All Rights Reserve.
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. */
#pragma once
#include "paddle/fluid/framework/op_registry.h"
#include "paddle/fluid/operators/math/math_function.h"
namespace
paddle
{
namespace
operators
{
using
Tensor
=
framework
::
Tensor
;
template
<
typename
T
>
class
BilinearInterpKernel
:
public
framework
::
OpKernel
<
T
>
{
public:
void
Compute
(
const
framework
::
ExecutionContext
&
ctx
)
const
override
{
auto
*
input_t
=
ctx
.
Input
<
Tensor
>
(
"X"
);
// float tensor
auto
*
output_t
=
ctx
.
Output
<
Tensor
>
(
"Out"
);
// float tensor
auto
*
input
=
input_t
->
data
<
T
>
();
auto
*
output
=
output_t
->
mutable_data
<
T
>
(
ctx
.
GetPlace
());
int
out_h
=
ctx
.
Attr
<
int
>
(
"out_h"
);
int
out_w
=
ctx
.
Attr
<
int
>
(
"out_w"
);
int
batch_size
=
input_t
->
dims
()[
0
];
int
channels
=
input_t
->
dims
()[
1
];
int
in_h
=
input_t
->
dims
()[
2
];
int
in_w
=
input_t
->
dims
()[
3
];
int
in_hw
=
in_h
*
in_w
;
int
out_hw
=
out_h
*
out_w
;
int
in_chw
=
channels
*
in_hw
;
int
out_chw
=
channels
*
out_hw
;
T
ratio_h
=
(
out_h
>
1
)
?
static_cast
<
T
>
(
in_h
-
1
)
/
(
out_h
-
1
)
:
0.
f
;
T
ratio_w
=
(
out_w
>
1
)
?
static_cast
<
T
>
(
in_w
-
1
)
/
(
out_w
-
1
)
:
0.
f
;
if
(
in_h
==
out_h
&&
in_w
==
out_w
)
{
memcpy
(
output
,
input
,
input_t
->
numel
()
*
sizeof
(
T
));
}
else
{
for
(
int
k
=
0
;
k
<
batch_size
;
++
k
)
{
// loop for batches
for
(
int
i
=
0
;
i
<
out_h
;
++
i
)
{
// loop for images
int
h
=
ratio_h
*
i
;
int
hid
=
(
h
<
in_h
-
1
)
?
1
:
0
;
T
h1lambda
=
ratio_h
*
i
-
h
;
T
h2lambda
=
1
-
h1lambda
;
for
(
int
j
=
0
;
j
<
out_w
;
++
j
)
{
int
w
=
ratio_w
*
j
;
int
wid
=
(
w
<
in_w
-
1
)
?
1
:
0
;
T
w1lambda
=
ratio_w
*
j
-
w
;
T
w2lambda
=
1
-
w1lambda
;
// calculate four position for bilinear interpolation
const
T
*
in_pos
=
&
input
[
k
*
in_chw
+
h
*
in_w
+
w
];
T
*
out_pos
=
&
output
[
k
*
out_chw
+
i
*
out_w
+
j
];
for
(
int
c
=
0
;
c
<
channels
;
++
c
)
{
// loop for channels
// bilinear interpolation
out_pos
[
0
]
=
h2lambda
*
(
w2lambda
*
in_pos
[
0
]
+
w1lambda
*
in_pos
[
wid
])
+
h1lambda
*
(
w2lambda
*
in_pos
[
hid
*
in_w
]
+
w1lambda
*
in_pos
[
hid
*
in_w
+
wid
]);
in_pos
+=
in_hw
;
out_pos
+=
out_hw
;
}
}
}
}
}
}
};
template
<
typename
T
>
class
BilinearInterpGradKernel
:
public
framework
::
OpKernel
<
T
>
{
public:
void
Compute
(
const
framework
::
ExecutionContext
&
ctx
)
const
override
{
auto
*
d_input_t
=
ctx
.
Output
<
Tensor
>
(
framework
::
GradVarName
(
"X"
));
auto
*
d_output_t
=
ctx
.
Input
<
Tensor
>
(
framework
::
GradVarName
(
"Out"
));
auto
*
d_input
=
d_input_t
->
mutable_data
<
T
>
(
ctx
.
GetPlace
());
auto
*
d_output
=
d_output_t
->
data
<
T
>
();
auto
&
device_ctx
=
ctx
.
template
device_context
<
platform
::
CPUDeviceContext
>();
math
::
SetConstant
<
platform
::
CPUDeviceContext
,
T
>
zero
;
zero
(
device_ctx
,
d_input_t
,
static_cast
<
T
>
(
0.0
));
int
out_h
=
ctx
.
Attr
<
int
>
(
"out_h"
);
int
out_w
=
ctx
.
Attr
<
int
>
(
"out_w"
);
int
batch_size
=
d_input_t
->
dims
()[
0
];
int
channels
=
d_input_t
->
dims
()[
1
];
int
in_h
=
d_input_t
->
dims
()[
2
];
int
in_w
=
d_input_t
->
dims
()[
3
];
int
in_hw
=
in_h
*
in_w
;
int
out_hw
=
out_h
*
out_w
;
int
in_chw
=
channels
*
in_hw
;
int
out_chw
=
channels
*
out_hw
;
T
ratio_h
=
(
out_h
>
1
)
?
static_cast
<
T
>
(
in_h
-
1
)
/
(
out_h
-
1
)
:
0.
f
;
T
ratio_w
=
(
out_w
>
1
)
?
static_cast
<
T
>
(
in_w
-
1
)
/
(
out_w
-
1
)
:
0.
f
;
if
(
in_h
==
out_h
&&
in_w
==
out_w
)
{
memcpy
(
d_input
,
d_output
,
d_input_t
->
numel
()
*
sizeof
(
T
));
}
else
{
for
(
int
k
=
0
;
k
<
batch_size
;
++
k
)
{
// loop for batches
for
(
int
i
=
0
;
i
<
out_h
;
++
i
)
{
// loop for images
int
h
=
ratio_h
*
i
;
int
hid
=
(
h
<
in_h
-
1
)
?
1
:
0
;
T
h1lambda
=
ratio_h
*
i
-
h
;
T
h2lambda
=
1
-
h1lambda
;
for
(
int
j
=
0
;
j
<
out_w
;
++
j
)
{
int
w
=
ratio_w
*
j
;
int
wid
=
(
w
<
in_w
-
1
)
?
1
:
0
;
T
w1lambda
=
ratio_w
*
j
-
w
;
T
w2lambda
=
1
-
w1lambda
;
T
*
in_pos
=
&
d_input
[
k
*
in_chw
+
h
*
in_w
+
w
];
const
T
*
out_pos
=
&
d_output
[
k
*
out_chw
+
i
*
out_w
+
j
];
for
(
int
c
=
0
;
c
<
channels
;
++
c
)
{
// loop for channels
in_pos
[
0
]
+=
h2lambda
*
w2lambda
*
out_pos
[
0
];
in_pos
[
wid
]
+=
h2lambda
*
w1lambda
*
out_pos
[
0
];
in_pos
[
hid
*
in_w
]
+=
h1lambda
*
w2lambda
*
out_pos
[
0
];
in_pos
[
hid
*
in_w
+
wid
]
+=
h1lambda
*
w1lambda
*
out_pos
[
0
];
in_pos
+=
in_hw
;
out_pos
+=
out_hw
;
}
}
}
}
}
}
};
}
// namespace operators
}
// namespace paddle
python/paddle/fluid/tests/unittests/test_bilinear_interp_op.py
0 → 100644
浏览文件 @
72ee737f
# 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
numpy
as
np
from
op_test
import
OpTest
def
bilinear_interp_np
(
input
,
out_h
,
out_w
):
batch_size
,
channel
,
in_h
,
in_w
=
input
.
shape
if
out_h
>
1
:
ratio_h
=
(
in_h
-
1.0
)
/
(
out_h
-
1.0
)
else
:
ratio_h
=
0.0
if
out_w
>
1
:
ratio_w
=
(
in_w
-
1.0
)
/
(
out_w
-
1.0
)
else
:
ratio_w
=
0.0
out
=
np
.
zeros
((
batch_size
,
channel
,
out_h
,
out_w
))
for
i
in
range
(
out_h
):
h
=
int
(
ratio_h
*
i
)
hid
=
1
if
h
<
in_h
-
1
else
0
h1lambda
=
ratio_h
*
i
-
h
h2lambda
=
1.0
-
h1lambda
for
j
in
range
(
out_w
):
w
=
int
(
ratio_w
*
j
)
wid
=
1
if
w
<
in_w
-
1
else
0
w1lambda
=
ratio_w
*
j
-
w
w2lambda
=
1.0
-
w1lambda
out
[:,
:,
i
,
j
]
=
h2lambda
*
(
w2lambda
*
input
[:,
:,
h
,
w
]
+
w1lambda
*
input
[:,
:,
h
,
w
+
wid
])
+
\
h1lambda
*
(
w2lambda
*
input
[:,
:,
h
+
hid
,
w
]
+
w1lambda
*
input
[:,
:,
h
+
hid
,
w
+
wid
])
return
out
.
astype
(
"float32"
)
class
TestBilinearInterpOp
(
OpTest
):
def
setUp
(
self
):
self
.
init_test_case
()
self
.
op_type
=
"bilinear_interp"
input_np
=
np
.
random
.
random
(
self
.
input_shape
).
astype
(
"float32"
)
output_np
=
bilinear_interp_np
(
input_np
,
self
.
out_h
,
self
.
out_w
)
self
.
inputs
=
{
'X'
:
input_np
}
self
.
attrs
=
{
'out_h'
:
self
.
out_h
,
'out_w'
:
self
.
out_w
}
self
.
outputs
=
{
'Out'
:
output_np
}
def
test_check_output
(
self
):
self
.
check_output
()
def
test_check_grad
(
self
):
self
.
check_grad
([
'X'
],
'Out'
,
in_place
=
True
)
def
init_test_case
(
self
):
self
.
input_shape
=
[
2
,
3
,
4
,
4
]
self
.
out_h
=
2
self
.
out_w
=
2
class
TestCase1
(
TestBilinearInterpOp
):
def
init_test_case
(
self
):
self
.
input_shape
=
[
4
,
1
,
7
,
8
]
self
.
out_h
=
1
self
.
out_w
=
1
class
TestCase2
(
TestBilinearInterpOp
):
def
init_test_case
(
self
):
self
.
input_shape
=
[
3
,
3
,
9
,
6
]
self
.
out_h
=
12
self
.
out_w
=
12
class
TestCase3
(
TestBilinearInterpOp
):
def
init_test_case
(
self
):
self
.
input_shape
=
[
1
,
1
,
128
,
64
]
self
.
out_h
=
64
self
.
out_w
=
128
if
__name__
==
"__main__"
:
unittest
.
main
()
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