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f6f5cdaa
编写于
8月 14, 2018
作者:
S
sneaxiy
提交者:
GitHub
8月 14, 2018
浏览文件
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差异文件
Merge pull request #12555 from sneaxiy/refine_layer_norm
Refine layer_norm op
上级
9d6243b6
c50c5377
变更
2
隐藏空白更改
内联
并排
Showing
2 changed file
with
506 addition
and
2 deletion
+506
-2
paddle/fluid/operators/CMakeLists.txt
paddle/fluid/operators/CMakeLists.txt
+1
-1
paddle/fluid/operators/layer_norm_op.cu
paddle/fluid/operators/layer_norm_op.cu
+505
-1
未找到文件。
paddle/fluid/operators/CMakeLists.txt
浏览文件 @
f6f5cdaa
...
...
@@ -273,9 +273,9 @@ op_library(squeeze_op DEPS reshape_op)
op_library
(
extract_rows_op DEPS memory
)
op_library
(
flatten_op DEPS reshape_op
)
if
(
WITH_GPU
)
op_library
(
conv_op DEPS vol2col depthwise_conv im2col
)
op_library
(
layer_norm_op DEPS cub
)
else
()
op_library
(
conv_op DEPS vol2col im2col
)
endif
()
...
...
paddle/fluid/operators/layer_norm_op.cu
浏览文件 @
f6f5cdaa
/* Copyright (c) 201
6
PaddlePaddle Authors. All Rights Reserved.
/* Copyright (c) 201
8
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.
...
...
@@ -12,8 +12,512 @@ 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 <cub/cub.cuh>
#include "paddle/fluid/operators/layer_norm_op.h"
namespace
paddle
{
namespace
operators
{
inline
static
int
GetDesiredBlockDim
(
int
block_dim
)
{
const
int
kMaxBlockDim
=
512
;
return
block_dim
>=
kMaxBlockDim
?
kMaxBlockDim
:
(
1
<<
(
static_cast
<
int
>
(
std
::
log2f
(
block_dim
))));
}
#define FIXED_BLOCK_DIM_CASE_BASE(log2_block_dim, ...) \
case (1 << (log2_block_dim)): { \
constexpr auto kBlockDim = (1 << (log2_block_dim)); \
__VA_ARGS__; \
} break
#define FIXED_BLOCK_DIM_CASE(...) \
FIXED_BLOCK_DIM_CASE_BASE(9, ##__VA_ARGS__); \
FIXED_BLOCK_DIM_CASE_BASE(8, ##__VA_ARGS__); \
FIXED_BLOCK_DIM_CASE_BASE(7, ##__VA_ARGS__); \
FIXED_BLOCK_DIM_CASE_BASE(6, ##__VA_ARGS__); \
FIXED_BLOCK_DIM_CASE_BASE(5, ##__VA_ARGS__); \
FIXED_BLOCK_DIM_CASE_BASE(4, ##__VA_ARGS__); \
FIXED_BLOCK_DIM_CASE_BASE(3, ##__VA_ARGS__); \
FIXED_BLOCK_DIM_CASE_BASE(2, ##__VA_ARGS__); \
FIXED_BLOCK_DIM_CASE_BASE(1, ##__VA_ARGS__)
static
__device__
__forceinline__
float
real_sqrt
(
float
x
)
{
return
sqrtf
(
x
);
}
static
__device__
__forceinline__
double
real_sqrt
(
double
x
)
{
return
sqrt
(
x
);
}
template
<
typename
T
>
struct
PairForLayerNorm
{
__device__
__forceinline__
PairForLayerNorm
()
{}
__device__
__forceinline__
PairForLayerNorm
(
const
T
&
first
,
const
T
&
second
)
:
first_
(
first
),
second_
(
second
)
{}
T
first_
;
T
second_
;
};
template
<
typename
T
>
struct
PairForLayerNormAddFunctor
{
__device__
__forceinline__
PairForLayerNorm
<
T
>
operator
()(
const
PairForLayerNorm
<
T
>
&
p1
,
const
PairForLayerNorm
<
T
>
&
p2
)
{
return
PairForLayerNorm
<
T
>
(
p1
.
first_
+
p2
.
first_
,
p1
.
second_
+
p2
.
second_
);
}
};
template
<
typename
T
,
int
BlockDim
>
__global__
void
LayerNormForward
(
const
T
*
x
,
const
T
*
scale
,
const
T
*
bias
,
T
*
y
,
T
*
mean
,
T
*
var
,
float
epsilon
,
int
feature_size
)
{
using
BlockReduce
=
cub
::
BlockReduce
<
PairForLayerNorm
<
T
>
,
BlockDim
>
;
__shared__
typename
BlockReduce
::
TempStorage
temp_storage
;
int
beg_idx
=
blockIdx
.
x
*
feature_size
+
threadIdx
.
x
;
int
end_idx
=
(
blockIdx
.
x
+
1
)
*
feature_size
;
// Step 1: Reduce to calculate mean and var
T
mean_val
=
static_cast
<
T
>
(
0
);
T
var_val
=
static_cast
<
T
>
(
0
);
for
(
int
i
=
beg_idx
;
i
<
end_idx
;
i
+=
BlockDim
)
{
T
tmp
=
x
[
i
];
mean_val
+=
tmp
;
var_val
+=
(
tmp
*
tmp
);
}
auto
pair
=
BlockReduce
(
temp_storage
)
.
Reduce
(
PairForLayerNorm
<
T
>
(
mean_val
,
var_val
),
PairForLayerNormAddFunctor
<
T
>
());
if
(
threadIdx
.
x
==
0
)
{
auto
tmp
=
pair
.
first_
/
feature_size
;
mean
[
blockIdx
.
x
]
=
tmp
;
var
[
blockIdx
.
x
]
=
pair
.
second_
/
feature_size
-
tmp
*
tmp
;
}
__syncthreads
();
mean_val
=
mean
[
blockIdx
.
x
];
var_val
=
static_cast
<
T
>
(
real_sqrt
(
var
[
blockIdx
.
x
]
+
epsilon
));
// Step 2: Calculate y
if
(
scale
!=
nullptr
)
{
if
(
bias
!=
nullptr
)
{
for
(
int
i
=
beg_idx
,
j
=
threadIdx
.
x
;
i
<
end_idx
;
i
+=
BlockDim
,
j
+=
BlockDim
)
{
y
[
i
]
=
scale
[
j
]
*
(
x
[
i
]
-
mean_val
)
/
var_val
+
bias
[
j
];
}
}
else
{
for
(
int
i
=
beg_idx
,
j
=
threadIdx
.
x
;
i
<
end_idx
;
i
+=
BlockDim
,
j
+=
BlockDim
)
{
y
[
i
]
=
scale
[
j
]
*
(
x
[
i
]
-
mean_val
)
/
var_val
;
}
}
}
else
{
// scale == nullptr
if
(
bias
!=
nullptr
)
{
for
(
int
i
=
beg_idx
,
j
=
threadIdx
.
x
;
i
<
end_idx
;
i
+=
BlockDim
,
j
+=
BlockDim
)
{
y
[
i
]
=
(
x
[
i
]
-
mean_val
)
/
var_val
+
bias
[
j
];
}
}
else
{
for
(
int
i
=
beg_idx
,
j
=
threadIdx
.
x
;
i
<
end_idx
;
i
+=
BlockDim
,
j
+=
BlockDim
)
{
y
[
i
]
=
(
x
[
i
]
-
mean_val
)
/
var_val
;
}
}
}
}
// Make sure that d_scale != nullptr && d_bias != nullptr
// Since d_scale != nullptr, scale would not be nullptr
template
<
typename
T
,
int
BlockDim
,
bool
HasDx
>
__global__
void
LayerNormBackwardGradientAll
(
const
T
*
x
,
const
T
*
d_y
,
T
*
d_scale
,
T
*
d_bias
,
T
*
d_x
,
const
T
*
mean
,
const
T
*
var
,
const
T
*
scale
,
float
epsilon
,
int
batch_size
,
int
feature_size
)
{
using
BlockReduce
=
cub
::
BlockReduce
<
PairForLayerNorm
<
T
>
,
BlockDim
>
;
__shared__
typename
BlockReduce
::
TempStorage
temp_storage
;
int
beg_idx
=
threadIdx
.
x
*
feature_size
+
blockIdx
.
x
;
int
end_idx
=
batch_size
*
feature_size
+
blockIdx
.
x
;
int
stride
=
BlockDim
*
feature_size
;
T
d_scale_partial
=
0
,
d_bias_partial
=
0
;
for
(
int
i
=
beg_idx
;
i
<
end_idx
;
i
+=
stride
)
{
int
row_idx
=
i
/
feature_size
;
auto
var_val
=
static_cast
<
T
>
(
real_sqrt
(
var
[
row_idx
]
+
epsilon
));
d_scale_partial
+=
d_y
[
i
]
*
(
x
[
i
]
-
mean
[
row_idx
])
/
var_val
;
d_bias_partial
+=
d_y
[
i
];
if
(
HasDx
)
{
d_x
[
i
]
=
d_y
[
i
]
*
scale
[
blockIdx
.
x
]
/
var_val
;
}
}
auto
pair
=
BlockReduce
(
temp_storage
)
.
Reduce
(
PairForLayerNorm
<
T
>
(
d_scale_partial
,
d_bias_partial
),
PairForLayerNormAddFunctor
<
T
>
());
if
(
threadIdx
.
x
==
0
)
{
d_scale
[
blockIdx
.
x
]
=
pair
.
first_
;
d_bias
[
blockIdx
.
x
]
=
pair
.
second_
;
}
}
// Make sure that there is only one true expression: d_scale != nullptr
// or d_bias != nullptr
// Notice: scale may be nullptr
template
<
typename
T
,
int
BlockDim
,
bool
HasDx
,
bool
HasDScale
>
__global__
void
LayerNormBackwardGradientScaleOrBias
(
const
T
*
x
,
const
T
*
d_y
,
T
*
d_scale
,
T
*
d_bias
,
T
*
d_x
,
const
T
*
mean
,
const
T
*
var
,
const
T
*
scale
,
float
epsilon
,
int
batch_size
,
int
feature_size
)
{
using
BlockReduce
=
cub
::
BlockReduce
<
T
,
BlockDim
>
;
__shared__
typename
BlockReduce
::
TempStorage
temp_storage
;
int
beg_idx
=
threadIdx
.
x
*
feature_size
+
blockIdx
.
x
;
int
end_idx
=
batch_size
*
feature_size
+
blockIdx
.
x
;
int
stride
=
BlockDim
*
feature_size
;
T
d_scale_or_d_bias_partial
=
0
;
for
(
int
i
=
beg_idx
;
i
<
end_idx
;
i
+=
stride
)
{
int
row_idx
=
i
/
feature_size
;
auto
var_val
=
static_cast
<
T
>
(
real_sqrt
(
var
[
row_idx
]
+
epsilon
));
if
(
HasDScale
)
{
d_scale_or_d_bias_partial
+=
d_y
[
i
]
*
(
x
[
i
]
-
mean
[
row_idx
])
/
var_val
;
}
else
{
// d_bias != nullptr
d_scale_or_d_bias_partial
+=
d_y
[
i
];
}
if
(
HasDx
)
{
if
(
scale
!=
nullptr
)
{
d_x
[
i
]
=
d_y
[
i
]
*
scale
[
blockIdx
.
x
]
/
var_val
;
}
else
{
d_x
[
i
]
=
d_y
[
i
]
/
var_val
;
}
}
}
d_scale_or_d_bias_partial
=
BlockReduce
(
temp_storage
).
Reduce
(
d_scale_or_d_bias_partial
,
cub
::
Sum
());
if
(
threadIdx
.
x
==
0
)
{
if
(
HasDScale
)
{
d_scale
[
blockIdx
.
x
]
=
d_scale_or_d_bias_partial
;
}
else
{
d_bias
[
blockIdx
.
x
]
=
d_scale_or_d_bias_partial
;
}
}
}
template
<
typename
T
,
int
BlockDim
>
__global__
void
LayerNormBackwardPostProcessToCalculateDX
(
const
T
*
x
,
T
*
d_x
,
const
T
*
mean
,
const
T
*
var
,
float
epsilon
,
int
feature_size
)
{
using
BlockReduce
=
cub
::
BlockReduce
<
PairForLayerNorm
<
T
>
,
BlockDim
>
;
__shared__
typename
BlockReduce
::
TempStorage
temp_storage
;
__shared__
T
d_x_reduce_tmp
[
2
];
int
beg_idx
=
blockIdx
.
x
*
feature_size
+
threadIdx
.
x
;
int
end_idx
=
(
blockIdx
.
x
+
1
)
*
feature_size
;
T
block_mean
=
mean
[
blockIdx
.
x
];
T
block_var
=
var
[
blockIdx
.
x
];
T
d_x_mean_partial
=
0
,
d_x_var_partial
=
0
;
for
(
int
i
=
beg_idx
;
i
<
end_idx
;
i
+=
BlockDim
)
{
d_x_mean_partial
+=
d_x
[
i
];
d_x_var_partial
+=
d_x
[
i
]
*
(
x
[
i
]
-
block_mean
);
}
auto
pair
=
BlockReduce
(
temp_storage
)
.
Reduce
(
PairForLayerNorm
<
T
>
(
d_x_mean_partial
,
d_x_var_partial
),
PairForLayerNormAddFunctor
<
T
>
());
if
(
threadIdx
.
x
==
0
)
{
d_x_reduce_tmp
[
0
]
=
pair
.
first_
/
feature_size
;
d_x_reduce_tmp
[
1
]
=
pair
.
second_
/
(
feature_size
*
(
block_var
+
epsilon
));
}
__syncthreads
();
d_x_mean_partial
=
d_x_reduce_tmp
[
0
];
d_x_var_partial
=
d_x_reduce_tmp
[
1
];
for
(
int
i
=
beg_idx
;
i
<
end_idx
;
i
+=
BlockDim
)
{
d_x
[
i
]
-=
d_x_mean_partial
;
d_x
[
i
]
-=
(
x
[
i
]
-
block_mean
)
*
d_x_var_partial
;
}
}
// Here, we only calculate d_x
template
<
typename
T
,
int
BlockDim
>
__global__
void
LayerNormBackwardGradientOnlyDX
(
const
T
*
x
,
const
T
*
d_y
,
T
*
d_x
,
const
T
*
mean
,
const
T
*
var
,
const
T
*
scale
,
float
epsilon
,
int
feature_size
)
{
using
BlockReduce
=
cub
::
BlockReduce
<
PairForLayerNorm
<
T
>
,
BlockDim
>
;
__shared__
typename
BlockReduce
::
TempStorage
temp_storage
;
__shared__
T
d_x_reduce_tmp
[
2
];
int
beg_idx
=
blockIdx
.
x
*
feature_size
+
threadIdx
.
x
;
int
end_idx
=
(
blockIdx
.
x
+
1
)
*
feature_size
;
T
block_mean
=
mean
[
blockIdx
.
x
],
block_var
=
var
[
blockIdx
.
x
];
T
d_x_mean_partial
=
0
,
d_x_var_partial
=
0
;
for
(
int
i
=
beg_idx
;
i
<
end_idx
;
i
+=
BlockDim
)
{
auto
var_val
=
static_cast
<
T
>
(
real_sqrt
(
block_var
+
epsilon
));
if
(
scale
!=
nullptr
)
{
int
col_idx
=
i
%
feature_size
;
d_x
[
i
]
=
d_y
[
i
]
*
scale
[
col_idx
]
/
var_val
;
}
else
{
d_x
[
i
]
=
d_y
[
i
]
/
var_val
;
}
d_x_mean_partial
+=
d_x
[
i
];
d_x_var_partial
+=
d_x
[
i
]
*
(
x
[
i
]
-
block_mean
);
}
auto
pair
=
BlockReduce
(
temp_storage
)
.
Reduce
(
PairForLayerNorm
<
T
>
(
d_x_mean_partial
,
d_x_var_partial
),
PairForLayerNormAddFunctor
<
T
>
());
if
(
threadIdx
.
x
==
0
)
{
d_x_reduce_tmp
[
0
]
=
pair
.
first_
/
feature_size
;
d_x_reduce_tmp
[
1
]
=
pair
.
second_
/
(
feature_size
*
(
block_var
+
epsilon
));
}
__syncthreads
();
d_x_mean_partial
=
d_x_reduce_tmp
[
0
];
d_x_var_partial
=
d_x_reduce_tmp
[
1
];
for
(
int
i
=
beg_idx
;
i
<
end_idx
;
i
+=
BlockDim
)
{
d_x
[
i
]
-=
d_x_mean_partial
;
d_x
[
i
]
-=
(
x
[
i
]
-
block_mean
)
*
d_x_var_partial
;
}
}
template
<
typename
T
>
__global__
void
LayerNormBackwardWhenBatchSizeIsOne
(
const
T
*
x
,
const
T
*
d_y
,
T
*
d_x
,
T
*
d_scale
,
T
*
d_bias
,
const
T
*
mean
,
const
T
*
var
,
const
T
*
scale
,
float
epsilon
,
int
feature_size
)
{
int
idx
=
threadIdx
.
x
+
blockIdx
.
x
*
blockDim
.
x
;
if
(
idx
<
feature_size
)
{
auto
var_val
=
static_cast
<
T
>
(
real_sqrt
(
var
[
idx
]
+
epsilon
));
if
(
d_x
!=
nullptr
)
{
if
(
d_scale
==
nullptr
)
{
d_x
[
idx
]
=
d_y
[
idx
]
/
var_val
;
}
else
{
d_x
[
idx
]
=
d_y
[
idx
]
*
scale
[
idx
]
/
var_val
;
}
}
if
(
d_scale
!=
nullptr
)
{
d_scale
[
idx
]
=
d_y
[
idx
]
*
(
x
[
idx
]
-
mean
[
idx
])
/
var_val
;
}
if
(
d_bias
!=
nullptr
)
d_bias
[
idx
]
=
d_y
[
idx
];
}
}
template
<
typename
T
>
static
void
LayerNormBackward
(
const
T
*
x
,
const
T
*
d_y
,
const
T
*
scale
,
const
T
*
mean
,
const
T
*
var
,
T
*
d_x
,
T
*
d_scale
,
T
*
d_bias
,
float
epsilon
,
int
batch_size
,
int
feature_size
,
cudaStream_t
stream
)
{
const
int
kMaxBlockDim
=
512
;
int
gradient_flag
=
((
d_x
!=
nullptr
?
1
:
0
)
<<
2
)
|
((
d_scale
!=
nullptr
?
1
:
0
)
<<
1
)
|
((
d_bias
!=
nullptr
?
1
:
0
));
if
(
gradient_flag
==
0
)
return
;
if
(
batch_size
==
1
)
{
LayerNormBackwardWhenBatchSizeIsOne
<
T
><<<
(
feature_size
+
kMaxBlockDim
-
1
)
/
kMaxBlockDim
,
kMaxBlockDim
,
0
,
stream
>>>
(
x
,
d_y
,
d_x
,
d_scale
,
d_bias
,
mean
,
var
,
scale
,
epsilon
,
feature_size
);
if
(
d_x
!=
nullptr
)
{
switch
(
GetDesiredBlockDim
(
feature_size
))
{
FIXED_BLOCK_DIM_CASE
(
LayerNormBackwardPostProcessToCalculateDX
<
T
,
kBlockDim
><<<
1
,
kBlockDim
,
0
,
stream
>>>
(
x
,
d_x
,
mean
,
var
,
epsilon
,
feature_size
));
}
}
return
;
}
auto
block_dim
=
GetDesiredBlockDim
(
batch_size
);
switch
(
gradient_flag
)
{
case
1
:
// d_x == nulptr, d_scale == nullptr, d_bias != nullptr
switch
(
block_dim
)
{
FIXED_BLOCK_DIM_CASE
(
LayerNormBackwardGradientScaleOrBias
<
T
,
kBlockDim
,
false
,
false
><<<
feature_size
,
kBlockDim
,
0
,
stream
>>>
(
x
,
d_y
,
d_scale
,
d_bias
,
d_x
,
mean
,
var
,
scale
,
epsilon
,
batch_size
,
feature_size
));
}
break
;
case
2
:
// d_x == nullptr, d_scale != nullptr, d_bias == nullptr
switch
(
block_dim
)
{
FIXED_BLOCK_DIM_CASE
(
LayerNormBackwardGradientScaleOrBias
<
T
,
kBlockDim
,
false
,
true
><<<
feature_size
,
kBlockDim
,
0
,
stream
>>>
(
x
,
d_y
,
d_scale
,
d_bias
,
d_x
,
mean
,
var
,
scale
,
epsilon
,
batch_size
,
feature_size
));
}
break
;
case
3
:
// d_x == nullptr, d_scale != nulptr, d_bias != nullptr
switch
(
block_dim
)
{
FIXED_BLOCK_DIM_CASE
(
LayerNormBackwardGradientAll
<
T
,
kBlockDim
,
false
><<<
feature_size
,
kBlockDim
,
0
,
stream
>>>
(
x
,
d_y
,
d_scale
,
d_bias
,
d_x
,
mean
,
var
,
scale
,
epsilon
,
batch_size
,
feature_size
));
}
break
;
case
4
:
// d_x != nullptr, d_scale == nullptr, d_bias == nullptr
switch
(
GetDesiredBlockDim
(
feature_size
))
{
FIXED_BLOCK_DIM_CASE
(
LayerNormBackwardGradientOnlyDX
<
T
,
kBlockDim
><<<
batch_size
,
kBlockDim
,
0
,
stream
>>>
(
x
,
d_y
,
d_x
,
mean
,
var
,
scale
,
epsilon
,
feature_size
));
}
break
;
case
5
:
// d_x != nulptr, d_scale == nullptr, d_bias != nullptr
switch
(
block_dim
)
{
FIXED_BLOCK_DIM_CASE
(
LayerNormBackwardGradientScaleOrBias
<
T
,
kBlockDim
,
true
,
false
><<<
feature_size
,
kBlockDim
,
0
,
stream
>>>
(
x
,
d_y
,
d_scale
,
d_bias
,
d_x
,
mean
,
var
,
scale
,
epsilon
,
batch_size
,
feature_size
));
}
switch
(
GetDesiredBlockDim
(
feature_size
))
{
FIXED_BLOCK_DIM_CASE
(
LayerNormBackwardPostProcessToCalculateDX
<
T
,
kBlockDim
><<<
batch_size
,
kBlockDim
,
0
,
stream
>>>
(
x
,
d_x
,
mean
,
var
,
epsilon
,
feature_size
));
}
break
;
case
6
:
// d_x != nullptr, d_scale != nullptr, d_bias == nullptr
switch
(
block_dim
)
{
FIXED_BLOCK_DIM_CASE
(
LayerNormBackwardGradientScaleOrBias
<
T
,
kBlockDim
,
true
,
true
><<<
feature_size
,
kBlockDim
,
0
,
stream
>>>
(
x
,
d_y
,
d_scale
,
d_bias
,
d_x
,
mean
,
var
,
scale
,
epsilon
,
batch_size
,
feature_size
));
}
switch
(
GetDesiredBlockDim
(
feature_size
))
{
FIXED_BLOCK_DIM_CASE
(
LayerNormBackwardPostProcessToCalculateDX
<
T
,
kBlockDim
><<<
batch_size
,
kBlockDim
,
0
,
stream
>>>
(
x
,
d_x
,
mean
,
var
,
epsilon
,
feature_size
));
}
break
;
case
7
:
// d_x != nullptr, d_scale != nullptr, d_bias != nullptr
switch
(
block_dim
)
{
FIXED_BLOCK_DIM_CASE
(
LayerNormBackwardGradientAll
<
T
,
kBlockDim
,
true
><<<
feature_size
,
kBlockDim
,
0
,
stream
>>>
(
x
,
d_y
,
d_scale
,
d_bias
,
d_x
,
mean
,
var
,
scale
,
epsilon
,
batch_size
,
feature_size
));
}
switch
(
GetDesiredBlockDim
(
feature_size
))
{
FIXED_BLOCK_DIM_CASE
(
LayerNormBackwardPostProcessToCalculateDX
<
T
,
kBlockDim
><<<
batch_size
,
kBlockDim
,
0
,
stream
>>>
(
x
,
d_x
,
mean
,
var
,
epsilon
,
feature_size
));
}
break
;
default:
break
;
}
}
template
<
typename
T
>
class
LayerNormKernel
<
platform
::
CUDADeviceContext
,
T
>
:
public
framework
::
OpKernel
<
T
>
{
public:
void
Compute
(
const
framework
::
ExecutionContext
&
ctx
)
const
override
{
const
float
epsilon
=
ctx
.
Attr
<
float
>
(
"epsilon"
);
auto
*
scale
=
ctx
.
Input
<
Tensor
>
(
"Scale"
);
auto
*
bias
=
ctx
.
Input
<
Tensor
>
(
"Bias"
);
auto
*
x
=
ctx
.
Input
<
Tensor
>
(
"X"
);
auto
*
y
=
ctx
.
Output
<
Tensor
>
(
"Y"
);
auto
*
mean
=
ctx
.
Output
<
Tensor
>
(
"Mean"
);
auto
*
var
=
ctx
.
Output
<
Tensor
>
(
"Variance"
);
const
auto
begin_norm_axis
=
ctx
.
Attr
<
int
>
(
"begin_norm_axis"
);
const
auto
x_dims
=
x
->
dims
();
auto
*
x_data
=
x
->
data
<
T
>
();
auto
*
y_data
=
y
->
mutable_data
<
T
>
(
ctx
.
GetPlace
());
auto
*
mean_data
=
mean
->
mutable_data
<
T
>
(
ctx
.
GetPlace
());
auto
*
var_data
=
var
->
mutable_data
<
T
>
(
ctx
.
GetPlace
());
auto
*
scale_data
=
(
scale
==
nullptr
?
nullptr
:
scale
->
data
<
T
>
());
auto
*
bias_data
=
(
bias
==
nullptr
?
nullptr
:
bias
->
data
<
T
>
());
auto
matrix_dim
=
framework
::
flatten_to_2d
(
x_dims
,
begin_norm_axis
);
int
batch_size
=
static_cast
<
int
>
(
matrix_dim
[
0
]);
int
feature_size
=
static_cast
<
int
>
(
matrix_dim
[
1
]);
auto
stream
=
ctx
.
cuda_device_context
().
stream
();
switch
(
GetDesiredBlockDim
(
feature_size
))
{
FIXED_BLOCK_DIM_CASE
(
LayerNormForward
<
T
,
kBlockDim
><<<
batch_size
,
kBlockDim
,
0
,
stream
>>>
(
x_data
,
scale_data
,
bias_data
,
y_data
,
mean_data
,
var_data
,
epsilon
,
feature_size
));
default:
PADDLE_THROW
(
"Product from begin_norm_axis to end must be larger than 1"
);
break
;
}
}
};
template
<
typename
T
>
class
LayerNormGradKernel
<
platform
::
CUDADeviceContext
,
T
>
:
public
framework
::
OpKernel
<
T
>
{
public:
void
Compute
(
const
framework
::
ExecutionContext
&
ctx
)
const
override
{
const
float
epsilon
=
ctx
.
Attr
<
float
>
(
"epsilon"
);
// d_x, d_scale, d_bias may be nullptr
auto
*
d_x
=
ctx
.
Output
<
Tensor
>
(
framework
::
GradVarName
(
"X"
));
auto
*
d_scale
=
ctx
.
Output
<
Tensor
>
(
framework
::
GradVarName
(
"Scale"
));
auto
*
d_bias
=
ctx
.
Output
<
Tensor
>
(
framework
::
GradVarName
(
"Bias"
));
auto
*
x
=
ctx
.
Input
<
Tensor
>
(
"X"
);
auto
*
mean
=
ctx
.
Input
<
Tensor
>
(
"Mean"
);
auto
*
var
=
ctx
.
Input
<
Tensor
>
(
"Variance"
);
auto
*
scale
=
ctx
.
Input
<
Tensor
>
(
"Scale"
);
auto
*
d_y
=
ctx
.
Input
<
Tensor
>
(
framework
::
GradVarName
(
"Y"
));
auto
*
x_data
=
x
->
data
<
T
>
();
auto
*
d_y_data
=
d_y
->
data
<
T
>
();
auto
*
mean_data
=
mean
->
data
<
T
>
();
auto
*
var_data
=
var
->
data
<
T
>
();
auto
*
scale_data
=
(
scale
==
nullptr
?
nullptr
:
scale
->
data
<
T
>
());
auto
*
d_scale_data
=
(
d_scale
==
nullptr
?
nullptr
:
d_scale
->
mutable_data
<
T
>
(
ctx
.
GetPlace
()));
auto
*
d_bias_data
=
(
d_bias
==
nullptr
?
nullptr
:
d_bias
->
mutable_data
<
T
>
(
ctx
.
GetPlace
()));
auto
*
d_x_data
=
(
d_x
==
nullptr
?
nullptr
:
d_x
->
mutable_data
<
T
>
(
ctx
.
GetPlace
()));
const
auto
&
x_dims
=
x
->
dims
();
const
auto
begin_norm_axis
=
ctx
.
Attr
<
int
>
(
"begin_norm_axis"
);
auto
matrix_dim
=
framework
::
flatten_to_2d
(
x_dims
,
begin_norm_axis
);
int
batch_size
=
static_cast
<
int
>
(
matrix_dim
[
0
]);
int
feature_size
=
static_cast
<
int
>
(
matrix_dim
[
1
]);
auto
stream
=
ctx
.
cuda_device_context
().
stream
();
LayerNormBackward
<
T
>
(
x_data
,
d_y_data
,
scale_data
,
mean_data
,
var_data
,
d_x_data
,
d_scale_data
,
d_bias_data
,
epsilon
,
batch_size
,
feature_size
,
stream
);
}
};
#undef FIXED_BLOCK_DIM_CASE_BASE
#undef FIXED_BLOCK_DIM_CASE
}
// namespace operators
}
// namespace paddle
namespace
ops
=
paddle
::
operators
;
REGISTER_OP_CUDA_KERNEL
(
layer_norm
,
...
...
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