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9dd5a177
编写于
9月 05, 2018
作者:
T
tensor-tang
浏览文件
操作
浏览文件
下载
电子邮件补丁
差异文件
refine batch mode and peephole
上级
f10710b0
变更
1
隐藏空白更改
内联
并排
Showing
1 changed file
with
179 addition
and
228 deletion
+179
-228
paddle/fluid/operators/fusion_lstm_op.cc
paddle/fluid/operators/fusion_lstm_op.cc
+179
-228
未找到文件。
paddle/fluid/operators/fusion_lstm_op.cc
浏览文件 @
9dd5a177
...
...
@@ -252,154 +252,162 @@ class FuisonLSTMKernel : public framework::OpKernel<T> {
const int D3 = D * 3; \
const int D4 = wh_dims[1];
#define INIT_BASE_INPUT_DATAS \
const T* x_data = x->data<T>(); \
const T* wx_data = wx->data<T>(); \
const T* wh_data = wh->data<T>(); \
/* diagonal weight*/
\
const T* wc_data = bias->data<T>() + D4; \
/* for peephole only*/
\
Tensor checked_cell; \
T* checked_cell_data = nullptr; \
auto place = ctx.GetPlace(); \
if (use_peepholes) { \
/* w_ic * Ct-1, w_fc * Ct-1 ; w_oc * Ct => ih*/
\
checked_cell_data = checked_cell.mutable_data<T>({2, D}, place); \
}
/// Compute LSTM
#define GEMM_WH_ADDON(bs, prev, out) \
blas.GEMM(CblasNoTrans, CblasNoTrans, bs, D4, D, static_cast<T>(1), prev, D, \
wh_data, D4, static_cast<T>(1), out, D4)
// gates: W_ch, W_ih, W_fh, W_oh
#define GET_Ct(ct_1, gates, ct) \
/* C_t = C_t-1 * fgated + cand_gated * igated*/
\
act_cand(D, gates, gates); \
blas.VMUL(D, gates, gates + D, gates + D); \
blas.VMUL(D, ct_1, gates + D2, gates + D2); \
blas.VADD(D, gates + D, gates + D2, ct)
#define GET_Ht(ct, gates, ht) \
/* H_t = act_cell(C_t) * ogated */
\
act_cell(D, ct, gates + D2); \
blas.VMUL(D, gates + D2, gates + D3, ht)
#define COMPUTE_CtHt_WITHOUT_H0C0(gates, ct, ht) \
act_gate(D, gates + D, gates + D); \
act_cand(D, gates, gates); \
/* C_t = igated * cgated*/
\
blas.VMUL(D, gates, gates + D, ct); \
/* get outgated*/
\
if (use_peepholes) { \
/* put W_oc * C_t on igated */
\
blas.VMUL(D, wc_data + D2, ct, gates + D); \
blas.VADD(D, gates + D, gates + D3, gates + D3); \
} \
act_gate(D, gates + D3, gates + D3); \
GET_Ht(ct, gates, ht)
#define COMPUTE_CtHt(gates, ct_1, ct, ht) \
act_gate(D3, gates + D, gates + D); \
GET_Ct(ct_1, gates, ct); \
GET_Ht(ct, gates, ht)
#define COMPUTE_CtHt_PEEPHOLE(gates, ct_1, ct, ht) \
/* get fgated and igated*/
\
blas.VMUL(D, wc_data, ct_1, checked_cell_data); \
blas.VMUL(D, wc_data + D, ct_1, checked_cell_data + D); \
blas.VADD(D2, checked_cell_data, gates + D, gates + D); \
act_gate(D2, gates + D, gates + D); \
GET_Ct(ct_1, gates, ct); \
/* get ogated*/
\
blas.VMUL(D, wc_data + D2, ct, gates + D); \
blas.VADD(D, gates + D, gates + D3, gates + D3); \
act_gate(D, gates + D3, gates + D3); \
GET_Ht(ct, gates, ht)
void
SeqCompute
(
const
framework
::
ExecutionContext
&
ctx
)
const
{
using
DeviceContext
=
paddle
::
platform
::
CPUDeviceContext
;
INIT_BASE_INPUT_OUTPUT
INIT_BASE_SIZES
INIT_VEC_FUNC
INIT_BASE_INPUT_DATAS
auto
x_lod
=
x
->
lod
();
const
int
total_T
=
x_dims
[
0
];
const
int
N
=
x_lod
[
0
].
size
()
-
1
;
const
T
*
x_data
=
x
->
data
<
T
>
();
const
T
*
h0_data
=
h0
?
h0
->
data
<
T
>
()
:
nullptr
;
const
T
*
c0_data
=
c0
?
c0
->
data
<
T
>
()
:
nullptr
;
const
T
*
wx_data
=
wx
->
data
<
T
>
();
const
T
*
wh_data
=
wh
->
data
<
T
>
();
const
T
*
wc_data
=
bias
->
data
<
T
>
()
+
D4
;
// diagonal weight
auto
place
=
ctx
.
GetPlace
();
T
*
xx_data
=
xx
->
mutable_data
<
T
>
(
place
);
T
*
hidden_out_data
=
hidden_out
->
mutable_data
<
T
>
(
place
);
T
*
cell_out_data
=
cell_out
->
mutable_data
<
T
>
(
place
);
T
*
h_out_data
=
hidden_out
->
mutable_data
<
T
>
(
place
);
T
*
c_out_data
=
cell_out
->
mutable_data
<
T
>
(
place
);
auto
blas
=
math
::
GetBlas
<
DeviceContext
,
T
>
(
ctx
);
math
::
FCCompute
<
DeviceContext
,
T
>
(
blas
,
total_T
,
D4
,
M
,
x_data
,
wx_data
,
xx_data
,
bias
->
data
<
T
>
());
// for peephole only
Tensor
checked_cell
;
T
*
checked_cell_data
=
nullptr
;
if
(
use_peepholes
)
{
// w_ic * Ct-1, w_fc * Ct-1 // , w_oc * Ct => ih
checked_cell_data
=
checked_cell
.
mutable_data
<
T
>
({
2
,
D
},
place
);
}
int
xx_offset
=
D4
;
int
gate_offset
=
D
;
if
(
is_reverse
)
{
const
int
offset
=
(
total_T
-
1
)
*
D
;
xx_data
=
xx_data
+
offset
*
4
;
h
idden_out_data
=
hidden
_out_data
+
offset
;
c
ell_out_data
=
cell
_out_data
+
offset
;
h
_out_data
=
h
_out_data
+
offset
;
c
_out_data
=
c
_out_data
+
offset
;
xx_offset
=
-
D4
;
gate_offset
=
-
D
;
}
auto
move_step
=
[
&
]()
{
xx_data
=
xx_data
+
xx_offset
;
hidden_out_data
=
hidden_out_data
+
gate_offset
;
cell_out_data
=
cell_out_data
+
gate_offset
;
};
#define GEMM_WH_ADDON \
blas.GEMM(CblasNoTrans, CblasNoTrans, 1, D4, D, static_cast<T>(1), \
prev_h_data, D, wh_data, D4, static_cast<T>(1), xx_data, D4)
#define GET_Ct \
/* C_t = C_t-1 * fgated + cand_gated * igated*/
\
act_cand(D, xx_data, xx_data); \
blas.VMUL(D, xx_data, xx_data + D, xx_data + D); \
blas.VMUL(D, prev_c_data, xx_data + D2, xx_data + D2); \
blas.VADD(D, xx_data + D, xx_data + D2, cell_out_data)
#define GET_Ht_AND_MOVE \
/* H_t = act_cell(C_t) * ogated */
\
act_cell(D, cell_out_data, xx_data + D2); \
blas.VMUL(D, xx_data + D2, xx_data + D3, hidden_out_data); \
/* get prev and move*/
\
prev_h_data = hidden_out_data; \
prev_c_data = cell_out_data; \
move_step()
for
(
int
i
=
0
;
i
<
N
;
++
i
)
{
int
bid
=
is_reverse
?
N
-
1
-
i
:
i
;
int
seq_len
=
x_lod
[
0
][
bid
+
1
]
-
x_lod
[
0
][
bid
];
const
T
*
prev_c_data
=
nullptr
;
const
T
*
prev_h_data
=
nullptr
;
int
tstart
=
0
;
if
(
h0_data
)
{
prev_h_data
=
h0_data
+
bid
*
D
;
prev_c_data
=
c0_data
+
bid
*
D
;
}
else
{
// W_ch, W_ih, W_fh, W_oh
act_gate
(
D
,
xx_data
+
D
,
xx_data
+
D
);
act_cand
(
D
,
xx_data
,
xx_data
);
// C_t = igated * cgated
blas
.
VMUL
(
D
,
xx_data
,
xx_data
+
D
,
cell_out_data
);
// get outgated
if
(
use_peepholes
)
{
// put W_oc * C_t on igated
blas
.
VMUL
(
D
,
wc_data
+
D2
,
cell_out_data
,
xx_data
+
D
);
blas
.
VADD
(
D
,
xx_data
+
D
,
xx_data
+
D3
,
xx_data
+
D3
);
}
act_gate
(
D
,
xx_data
+
D3
,
xx_data
+
D3
);
GET_Ht_AND_MOVE
;
tstart
=
1
;
}
#define MOVE_ONE_STEP \
prev_h_data = h_out_data; \
prev_c_data = c_out_data; \
xx_data = xx_data + xx_offset; \
h_out_data = h_out_data + gate_offset; \
c_out_data = c_out_data + gate_offset
#define PROCESS_H0C0 \
int bid = is_reverse ? N - 1 - i : i; \
int seq_len = x_lod[0][bid + 1] - x_lod[0][bid]; \
const T* prev_c_data = nullptr; \
const T* prev_h_data = nullptr; \
int tstart = 0; \
if (h0_data) { \
prev_h_data = h0_data + bid * D; \
prev_c_data = c0_data + bid * D; \
} else { \
COMPUTE_CtHt_WITHOUT_H0C0(xx_data, c_out_data, h_out_data); \
MOVE_ONE_STEP; \
tstart = 1; \
}
if
(
use_peepholes
)
{
if
(
use_peepholes
)
{
for
(
int
i
=
0
;
i
<
N
;
++
i
)
{
PROCESS_H0C0
;
for
(
int
step
=
tstart
;
step
<
seq_len
;
++
step
)
{
GEMM_WH_ADDON
;
// get fgated and igated
blas
.
VMUL
(
D
,
wc_data
,
prev_c_data
,
checked_cell_data
);
blas
.
VMUL
(
D
,
wc_data
+
D
,
prev_c_data
,
checked_cell_data
+
D
);
blas
.
VADD
(
D2
,
checked_cell_data
,
xx_data
+
D
,
xx_data
+
D
);
act_gate
(
D2
,
xx_data
+
D
,
xx_data
+
D
);
GET_Ct
;
// get ogated
blas
.
VMUL
(
D
,
wc_data
+
D2
,
cell_out_data
,
xx_data
+
D
);
blas
.
VADD
(
D
,
xx_data
+
D
,
xx_data
+
D3
,
xx_data
+
D3
);
act_gate
(
D
,
xx_data
+
D3
,
xx_data
+
D3
);
GET_Ht_AND_MOVE
;
}
// for seqlen
}
else
{
GEMM_WH_ADDON
(
1
,
prev_h_data
,
xx_data
);
COMPUTE_CtHt_PEEPHOLE
(
xx_data
,
prev_c_data
,
c_out_data
,
h_out_data
);
MOVE_ONE_STEP
;
}
}
}
else
{
for
(
int
i
=
0
;
i
<
N
;
++
i
)
{
PROCESS_H0C0
;
for
(
int
step
=
tstart
;
step
<
seq_len
;
++
step
)
{
GEMM_WH_ADDON
;
// W_ch, W_ih, W_fh, W_oh
act_gate
(
D3
,
xx_data
+
D
,
xx_data
+
D
);
GET_Ct
;
GET_Ht_AND_MOVE
;
}
// for seqlen
GEMM_WH_ADDON
(
1
,
prev_h_data
,
xx_data
);
COMPUTE_CtHt
(
xx_data
,
prev_c_data
,
c_out_data
,
h_out_data
);
MOVE_ONE_STEP
;
}
}
}
// for batch
#undef GET_Ht_AND_MOVE
#undef GEMM_WH_ADDON
#undef GET_Ct
}
#undef PROCESS_H0C0
#undef MOVE_ONE_STEP
}
void
BatchCompute
(
const
framework
::
ExecutionContext
&
ctx
)
const
{
using
DeviceContext
=
platform
::
CPUDeviceContext
;
INIT_BASE_INPUT_OUTPUT
if
(
x
->
lod
()[
0
].
size
()
==
2
)
{
// batch size == 1
if
(
x
->
lod
()[
0
].
size
()
==
2
)
{
SeqCompute
(
ctx
);
return
;
}
INIT_BASE_SIZES
INIT_VEC_FUNC
INIT_BASE_INPUT_DATAS
auto
*
reordered_h0
=
ctx
.
Output
<
Tensor
>
(
"ReorderedH0"
);
auto
*
reordered_c0
=
ctx
.
Output
<
Tensor
>
(
"ReorderedC0"
);
auto
*
batched_input
=
ctx
.
Output
<
LoDTensor
>
(
"BatchedInput"
);
auto
*
batched_c_out
=
ctx
.
Output
<
LoDTensor
>
(
"BatchedCell"
);
auto
*
batched_h_out
=
ctx
.
Output
<
LoDTensor
>
(
"BatchedHidden"
);
const
T
*
x_data
=
x
->
data
<
T
>
();
const
T
*
wx_data
=
wx
->
data
<
T
>
();
const
T
*
wh_data
=
wh
->
data
<
T
>
();
const
T
*
bias_data
=
bias
->
data
<
T
>
();
const
T
*
wc_data
=
bias_data
+
D4
;
// w_ic, w_fc, w_oc
auto
place
=
ctx
.
GetPlace
();
T
*
xx_data
=
xx
->
mutable_data
<
T
>
(
place
);
T
*
batched_input_data
=
batched_input
->
mutable_data
<
T
>
(
place
);
T
*
batched_c_out_data
=
batched_c_out
->
mutable_data
<
T
>
(
place
);
...
...
@@ -407,12 +415,6 @@ class FuisonLSTMKernel : public framework::OpKernel<T> {
hidden_out
->
mutable_data
<
T
>
(
place
);
cell_out
->
mutable_data
<
T
>
(
place
);
// use local variable
framework
::
DDim
check_dims
({
3
,
D
});
Tensor
checked_cell
;
// w_ic * Ct-1, w_fc * Ct-1, w_oc * Ct
auto
checked_cell_data
=
checked_cell
.
mutable_data
<
T
>
(
check_dims
,
ctx
.
GetPlace
());
math
::
LoDTensor2BatchFunctor
<
DeviceContext
,
T
>
to_batch
;
auto
&
dev_ctx
=
ctx
.
template
device_context
<
DeviceContext
>();
auto
blas
=
math
::
GetBlas
<
DeviceContext
,
T
>
(
dev_ctx
);
...
...
@@ -434,27 +436,17 @@ class FuisonLSTMKernel : public framework::OpKernel<T> {
reordered_h0
->
Resize
({
max_bs
,
D
});
reordered_c0
->
Resize
({
max_bs
,
D
});
T
*
prev_batch_h_data
=
nullptr
;
T
*
prev_batch_c_data
=
nullptr
;
T
*
cur_batch_in_data
=
batched_input_data
;
T
*
cur_batch_h_out_data
=
batched_h_out_data
;
T
*
cur_batch_c_out_data
=
batched_c_out_data
;
auto
move_step
=
[
&
](
int
bs
)
{
cur_batch_in_data
+=
bs
*
D4
;
cur_batch_c_out_data
+=
bs
*
D
;
cur_batch_h_out_data
+=
bs
*
D
;
};
int
tstart
=
0
;
T
*
prev_h_data
=
nullptr
;
T
*
prev_c_data
=
nullptr
;
if
(
h0
)
{
// reorder h0, c0
T
*
reordered_h0_data
=
reordered_h0
->
mutable_data
<
T
>
(
place
);
T
*
reordered_c0_data
=
reordered_c0
->
mutable_data
<
T
>
(
place
);
const
T
*
h0_data
=
h0
->
data
<
T
>
();
const
T
*
c0_data
=
c0
->
data
<
T
>
();
prev_
batch_
h_data
=
reordered_h0_data
;
prev_
batch_
c_data
=
reordered_c0_data
;
prev_h_data
=
reordered_h0_data
;
prev_c_data
=
reordered_c0_data
;
size_t
sz
=
sizeof
(
T
)
*
D
;
for
(
int
i
=
0
;
i
<
max_bs
;
++
i
)
{
std
::
memcpy
(
reordered_h0_data
,
h0_data
+
seq_order
[
i
]
*
D
,
sz
);
...
...
@@ -463,123 +455,74 @@ class FuisonLSTMKernel : public framework::OpKernel<T> {
reordered_c0_data
+=
D
;
}
}
else
{
// Compute with no H0/C0
T
*
cur_in_data
=
cur_batch_in_data
;
T
*
cur_c_out_data
=
cur_batch_c_out_data
;
T
*
cur_h_out_data
=
cur_batch_h_out_data
;
// If step == 0 and there is no initialized hidden state, that is to say
// the H0 is zeros. Then W_h * H_t-1 can be skiped
for
(
int
i
=
0
;
i
<
max_bs
;
++
i
)
{
// iterate each data in 1st batch
// ~C_t
act_cand
(
D
,
cur_in_data
,
cur_in_data
);
if
(
use_peepholes
)
{
// I_t, F_t
act_gate
(
D2
,
cur_in_data
+
D
,
cur_in_data
+
D
);
}
else
{
// I_t, F_t, O_t
act_gate
(
D3
,
cur_in_data
+
D
,
cur_in_data
+
D
);
}
// C_t = I_t * ~C_t
blas
.
VMUL
(
D
,
cur_in_data
,
cur_in_data
+
D
,
cur_c_out_data
);
if
(
use_peepholes
)
{
// + W_oc * C_t for peephole connection
blas
.
VMUL
(
D
,
wc_data
+
D2
,
cur_c_out_data
,
checked_cell_data
+
D2
);
blas
.
VADD
(
D
,
cur_in_data
+
D3
,
checked_cell_data
+
D2
,
cur_in_data
+
D3
);
// O_t
act_gate
(
D
,
cur_in_data
+
D3
,
cur_in_data
+
D3
);
}
// hidden out= act_state(cellout) * outgate
act_cell
(
D
,
cur_c_out_data
,
cur_in_data
+
D2
);
// H_t = O_t * act_state(C_t)
blas
.
VMUL
(
D
,
cur_in_data
+
D2
,
cur_in_data
+
D3
,
cur_h_out_data
);
// move to next data in the same batch
// compute without h0, c0
T
*
cur_in_data
=
batched_input_data
;
T
*
cur_h_out_data
=
batched_h_out_data
;
T
*
cur_c_out_data
=
batched_c_out_data
;
for
(
int
i
=
0
;
i
<
max_bs
;
++
i
)
{
COMPUTE_CtHt_WITHOUT_H0C0
(
cur_in_data
,
cur_c_out_data
,
cur_h_out_data
);
cur_in_data
+=
D4
;
cur_c_out_data
+=
D
;
cur_h_out_data
+=
D
;
}
// move to data for next timestep
prev_batch_h_data
=
cur_batch_h_out_data
;
prev_batch_c_data
=
cur_batch_c_out_data
;
move_step
(
max_bs
);
tstart
=
1
;
prev_h_data
=
batched_h_out_data
;
prev_c_data
=
batched_c_out_data
;
}
const
auto
&
batch_starts
=
batched_lod
[
0
];
const
int
max_seq_len
=
batch_starts
.
size
()
-
1
;
for
(
int
step
=
tstart
;
step
<
max_seq_len
;
++
step
)
{
const
int
cur_bs
=
batch_starts
[
step
+
1
]
-
batch_starts
[
step
];
// + W_h * H_t-1
blas
.
GEMM
(
CblasNoTrans
,
CblasNoTrans
,
cur_bs
,
D4
,
D
,
static_cast
<
T
>
(
1
),
prev_batch_h_data
,
D
,
wh_data
,
D4
,
static_cast
<
T
>
(
1
),
cur_batch_in_data
,
D4
);
T
*
cur_in_data
=
cur_batch_in_data
;
T
*
cur_c_out_data
=
cur_batch_c_out_data
;
T
*
cur_h_out_data
=
cur_batch_h_out_data
;
T
*
prev_c_data
=
prev_batch_c_data
;
// NULL if no C0 in step0
T
*
prev_h_data
=
prev_batch_h_data
;
// NULL if no H0 in step0
auto
next_data_in_batch
=
[
&
]()
{
cur_in_data
+=
D4
;
cur_c_out_data
+=
D
;
cur_h_out_data
+=
D
;
prev_c_data
=
prev_c_data
?
prev_c_data
+
D
:
nullptr
;
prev_h_data
=
prev_h_data
?
prev_h_data
+
D
:
nullptr
;
};
for
(
int
i
=
0
;
i
<
cur_bs
;
++
i
)
{
// iterate each data in same batch
// ~C_t
act_cand
(
D
,
cur_in_data
,
cur_in_data
);
if
(
use_peepholes
)
{
// + W_ic|W_fc * C_t-1 for peephole connection
blas
.
VMUL
(
D
,
wc_data
,
prev_c_data
,
checked_cell_data
);
blas
.
VMUL
(
D
,
wc_data
+
D
,
prev_c_data
,
checked_cell_data
+
D
);
blas
.
VADD
(
D2
,
cur_in_data
+
D
,
checked_cell_data
,
cur_in_data
+
D
);
// I_t, F_t
act_gate
(
D2
,
cur_in_data
+
D
,
cur_in_data
+
D
);
}
else
{
// I_t, F_t, O_t
act_gate
(
D3
,
cur_in_data
+
D
,
cur_in_data
+
D
);
}
const
int
offset
=
tstart
*
max_bs
*
D
;
batched_input_data
=
batched_input_data
+
offset
*
4
;
batched_h_out_data
=
batched_h_out_data
+
offset
;
batched_c_out_data
=
batched_c_out_data
+
offset
;
#define DEFINE_CUR \
T* cur_in_data = batched_input_data; \
T* cur_prev_c_data = prev_c_data; \
T* cur_c_out_data = batched_c_out_data; \
T* cur_h_out_data = batched_h_out_data
#define MOVE_ONE_BATCH \
cur_in_data += D4; \
cur_prev_c_data += D; \
cur_c_out_data += D; \
cur_h_out_data += D
#define MOVE_ONE_STEP \
prev_c_data = batched_c_out_data; \
prev_h_data = batched_h_out_data; \
batched_c_out_data = cur_c_out_data; \
batched_h_out_data = cur_h_out_data; \
batched_input_data = cur_in_data
// F_t * C_t-1
blas
.
VMUL
(
D
,
cur_in_data
+
D2
,
prev_c_data
,
cur_in_data
+
D2
);
// I_t * ~C_t
blas
.
VMUL
(
D
,
cur_in_data
,
cur_in_data
+
D
,
cur_in_data
+
D
);
// C_t = F_t * C_t-1 + I_t * ~C_t
blas
.
VADD
(
D
,
cur_in_data
+
D
,
cur_in_data
+
D2
,
cur_c_out_data
);
if
(
use_peepholes
)
{
// + W_oc * C_t for peephole connection
blas
.
VMUL
(
D
,
wc_data
+
D2
,
cur_c_out_data
,
checked_cell_data
+
D2
);
blas
.
VADD
(
D
,
cur_in_data
+
D3
,
checked_cell_data
+
D2
,
cur_in_data
+
D3
);
// O_t
act_gate
(
D
,
cur_in_data
+
D3
,
cur_in_data
+
D3
);
if
(
use_peepholes
)
{
for
(
int
step
=
tstart
;
step
<
max_seq_len
;
++
step
)
{
const
int
cur_bs
=
batch_starts
[
step
+
1
]
-
batch_starts
[
step
];
GEMM_WH_ADDON
(
cur_bs
,
prev_h_data
,
batched_input_data
);
DEFINE_CUR
;
for
(
int
i
=
0
;
i
<
cur_bs
;
++
i
)
{
COMPUTE_CtHt_PEEPHOLE
(
cur_in_data
,
cur_prev_c_data
,
cur_c_out_data
,
cur_h_out_data
);
MOVE_ONE_BATCH
;
}
// hidden out= act_state(cellout) * outgate
act_cell
(
D
,
cur_c_out_data
,
cur_in_data
+
D2
);
// H_t = O_t * act_state(C_t)
blas
.
VMUL
(
D
,
cur_in_data
+
D2
,
cur_in_data
+
D3
,
cur_h_out_data
);
// move to next data in same batch
next_data_in_batch
();
MOVE_ONE_STEP
;
}
}
else
{
for
(
int
step
=
tstart
;
step
<
max_seq_len
;
++
step
)
{
const
int
cur_bs
=
batch_starts
[
step
+
1
]
-
batch_starts
[
step
];
GEMM_WH_ADDON
(
cur_bs
,
prev_h_data
,
batched_input_data
);
DEFINE_CUR
;
for
(
int
i
=
0
;
i
<
cur_bs
;
++
i
)
{
COMPUTE_CtHt
(
cur_in_data
,
cur_prev_c_data
,
cur_c_out_data
,
cur_h_out_data
);
MOVE_ONE_BATCH
;
}
MOVE_ONE_STEP
;
}
// move to data for next timestep
prev_batch_h_data
=
cur_batch_h_out_data
;
prev_batch_c_data
=
cur_batch_c_out_data
;
move_step
(
cur_bs
);
}
#undef MOVE_ONE_STEP
#undef MOVE_ONE_BATCH
#undef DEFINE_CUR
math
::
Batch2LoDTensorFunctor
<
DeviceContext
,
T
>
to_seq
;
batched_h_out
->
set_lod
(
batched_lod
);
...
...
@@ -595,6 +538,14 @@ class FuisonLSTMKernel : public framework::OpKernel<T> {
BatchCompute
(
ctx
);
}
}
#undef COMPUTE_CtHt_PEEPHOLE
#undef COMPUTE_CtHt
#undef COMPUTE_CtHt_WITHOUT_H0C0
#undef GET_Ht
#undef GET_Ct
#undef GEMM_WH_ADDON
#undef INIT_BASE_INPUT_DATAS
#undef INIT_BASE_SIZES
#undef INIT_BASE_INPUT_OUTPUT
#undef INIT_VEC_FUNC
...
...
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