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748fa6ee
编写于
2月 19, 2019
作者:
L
lujun
提交者:
GitHub
2月 19, 2019
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差异文件
Merge pull request #682 from guoshengCS/fix-nmt-style
Fix book-nmt README
上级
ffcc9428
c05f68b2
变更
2
隐藏空白更改
内联
并排
Showing
2 changed file
with
72 addition
and
58 deletion
+72
-58
08.machine_translation/README.cn.md
08.machine_translation/README.cn.md
+36
-29
08.machine_translation/index.cn.html
08.machine_translation/index.cn.html
+36
-29
未找到文件。
08.machine_translation/README.cn.md
浏览文件 @
748fa6ee
...
@@ -54,9 +54,9 @@
...
@@ -54,9 +54,9 @@
### 编码器-解码器框架
### 编码器-解码器框架
编码器-解码器(Encoder-Decoder)
\[
[
2
](
#参考文献
)
\]
框架用于解决由一个任意长度的源序列到另一个任意长度的目标序列的变换问题。即编码阶段将整个源序列编码成一个向量,解码阶段通过最大化预测序列概率,从中解码出整个目标序列。编码和解码的过程通常都使用RNN实现。
编码器-解码器(Encoder-Decoder)
\[
[
2
](
#参考文献
)
\]
框架用于解决由一个任意长度的源序列到另一个任意长度的目标序列的变换问题。即编码阶段将整个源序列编码成一个向量,解码阶段通过最大化预测序列概率,从中解码出整个目标序列。编码和解码的过程通常都使用RNN实现。
![
encoder_decoder
](
./image/encoder_decoder.png
)
<div
align=
"center"
>
<div
align=
"center"
>
<img
src =
"https://github.com/PaddlePaddle/book/blob/develop/08.machine_translation/image/encoder_decoder.png?raw=true"
width=
"
4
00"
><br/>
<img
src =
"https://github.com/PaddlePaddle/book/blob/develop/08.machine_translation/image/encoder_decoder.png?raw=true"
width=
"
7
00"
><br/>
图3. 编码器-解码器框架
图3. 编码器-解码器框架
</div>
</div>
...
@@ -82,7 +82,7 @@
...
@@ -82,7 +82,7 @@
机器翻译任务的训练过程中,解码阶段的目标是最大化下一个正确的目标语言词的概率。思路是:
机器翻译任务的训练过程中,解码阶段的目标是最大化下一个正确的目标语言词的概率。思路是:
1.
每一个时刻,根据源语言句子的编码信息(又叫上下文向量,context vector)$c$、真实目标语言序列的第$i$个词$u_i$和$i$时刻RNN的隐层状态$z_i$,计算出下一个隐层状态$z_{i+1}$。计算公式如下:
1.
每一个时刻,根据源语言句子的编码信息(又叫上下文向量,context vector)$c$、真实目标语言序列的第$i$个词$u_i$和$i$时刻RNN的隐层状态$z_i$,计算出下一个隐层状态$z_{i+1}$。计算公式如下:
$$z_{i+1}=
\p
hi_{
\t
heta '}
\l
eft ( c,u_i,z_i
\r
ight )$$
$$z_{i+1}=
\p
hi_{
\t
heta '}
\l
eft ( c,u_i,z_i
\r
ight )$$
其中$
\p
hi _{
\t
heta '}$是一个非线性激活函数;$c
=q
\m
athbf{h}
$是源语言句子的上下文向量,在不使用注意力机制时,如果
[
编码器
](
#编码器
)
的输出是源语言句子编码后的最后一个元素,则可以定义$c=h_T$;$u_i$是目标语言序列的第$i$个单词,$u_0$是目标语言序列的开始标记
`<s>`
,表示解码开始;$z_i$是$i$时刻解码RNN的隐层状态,$z_0$是一个全零的向量。
其中$
\p
hi _{
\t
heta '}$是一个非线性激活函数;$c$是源语言句子的上下文向量,在不使用注意力机制时,如果
[
编码器
](
#编码器
)
的输出是源语言句子编码后的最后一个元素,则可以定义$c=h_T$;$u_i$是目标语言序列的第$i$个单词,$u_0$是目标语言序列的开始标记
`<s>`
,表示解码开始;$z_i$是$i$时刻解码RNN的隐层状态,$z_0$是一个全零的向量。
2.
将$z_{i+1}$通过
`softmax`
归一化,得到目标语言序列的第$i+1$个单词的概率分布$p_{i+1}$。概率分布公式如下:
2.
将$z_{i+1}$通过
`softmax`
归一化,得到目标语言序列的第$i+1$个单词的概率分布$p_{i+1}$。概率分布公式如下:
$$p
\l
eft ( u_{i+1}|u_{
<
i+1},
\m
athbf{x}
\r
ight )=softmax(W_sz_{i+1}+b_z)$$
$$p
\l
eft ( u_{i+1}|u_{
<
i+1},
\m
athbf{x}
\r
ight )=softmax(W_sz_{i+1}+b_z)$$
...
@@ -160,33 +160,35 @@ except ImportError:
...
@@ -160,33 +160,35 @@ except ImportError:
from
paddle.fluid.trainer
import
*
from
paddle.fluid.trainer
import
*
from
paddle.fluid.inferencer
import
*
from
paddle.fluid.inferencer
import
*
dict_size
=
30000
dict_size
=
30000
# 字典维度
source_dict_dim
=
target_dict_dim
=
dict_size
source_dict_dim
=
target_dict_dim
=
dict_size
# 源/目标语言字典维度
hidden_dim
=
32
hidden_dim
=
32
# 编码器中的隐层大小
word_dim
=
16
word_dim
=
16
# 词向量维度
batch_size
=
2
batch_size
=
2
# batch 中的样本数
max_length
=
8
max_length
=
8
# 生成句子的最大长度
topk_size
=
50
beam_size
=
2
# 柱宽度
beam_size
=
2
decoder_size
=
hidden_dim
decoder_size
=
hidden_dim
# 解码器中的隐层大小
```
```
然后如下实现编码器框架:
然后如下实现编码器框架:
```
python
```
python
def
encoder
(
is_sparse
):
def
encoder
(
is_sparse
):
# 定义源语言id序列的输入数据
src_word_id
=
pd
.
data
(
src_word_id
=
pd
.
data
(
name
=
"src_word_id"
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
name
=
"src_word_id"
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
# 将上述编码映射到低维语言空间的词向量
src_embedding
=
pd
.
embedding
(
src_embedding
=
pd
.
embedding
(
input
=
src_word_id
,
input
=
src_word_id
,
size
=
[
dict_size
,
word_dim
],
size
=
[
dict_size
,
word_dim
],
dtype
=
'float32'
,
dtype
=
'float32'
,
is_sparse
=
is_sparse
,
is_sparse
=
is_sparse
,
param_attr
=
fluid
.
ParamAttr
(
name
=
'vemb'
))
param_attr
=
fluid
.
ParamAttr
(
name
=
'vemb'
))
# LSTM层:fc + dynamic_lstm
fc1
=
pd
.
fc
(
input
=
src_embedding
,
size
=
hidden_dim
*
4
,
act
=
'tanh'
)
fc1
=
pd
.
fc
(
input
=
src_embedding
,
size
=
hidden_dim
*
4
,
act
=
'tanh'
)
lstm_hidden0
,
lstm_0
=
pd
.
dynamic_lstm
(
input
=
fc1
,
size
=
hidden_dim
*
4
)
lstm_hidden0
,
lstm_0
=
pd
.
dynamic_lstm
(
input
=
fc1
,
size
=
hidden_dim
*
4
)
# 取源语言序列编码后的最后一个状态
encoder_out
=
pd
.
sequence_last_step
(
input
=
lstm_hidden0
)
encoder_out
=
pd
.
sequence_last_step
(
input
=
lstm_hidden0
)
return
encoder_out
return
encoder_out
```
```
...
@@ -195,6 +197,7 @@ decoder_size = hidden_dim
...
@@ -195,6 +197,7 @@ decoder_size = hidden_dim
```
python
```
python
def
train_decoder
(
context
,
is_sparse
):
def
train_decoder
(
context
,
is_sparse
):
# 定义目标语言id序列的输入数据,并映射到低维语言空间的词向量
trg_language_word
=
pd
.
data
(
trg_language_word
=
pd
.
data
(
name
=
"target_language_word"
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
name
=
"target_language_word"
,
shape
=
[
1
],
dtype
=
'int64'
,
lod_level
=
1
)
trg_embedding
=
pd
.
embedding
(
trg_embedding
=
pd
.
embedding
(
...
@@ -205,17 +208,22 @@ decoder_size = hidden_dim
...
@@ -205,17 +208,22 @@ decoder_size = hidden_dim
param_attr
=
fluid
.
ParamAttr
(
name
=
'vemb'
))
param_attr
=
fluid
.
ParamAttr
(
name
=
'vemb'
))
rnn
=
pd
.
DynamicRNN
()
rnn
=
pd
.
DynamicRNN
()
with
rnn
.
block
():
with
rnn
.
block
():
# 使用 DynamicRNN 定义每一步的计算
# 获取当前步目标语言输入的词向量
current_word
=
rnn
.
step_input
(
trg_embedding
)
current_word
=
rnn
.
step_input
(
trg_embedding
)
# 获取隐层状态
pre_state
=
rnn
.
memory
(
init
=
context
)
pre_state
=
rnn
.
memory
(
init
=
context
)
# 解码器计算单元:单层前馈网络
current_state
=
pd
.
fc
(
input
=
[
current_word
,
pre_state
],
current_state
=
pd
.
fc
(
input
=
[
current_word
,
pre_state
],
size
=
decoder_size
,
size
=
decoder_size
,
act
=
'tanh'
)
act
=
'tanh'
)
# 计算归一化的单词预测概率
current_score
=
pd
.
fc
(
input
=
current_state
,
current_score
=
pd
.
fc
(
input
=
current_state
,
size
=
target_dict_dim
,
size
=
target_dict_dim
,
act
=
'softmax'
)
act
=
'softmax'
)
# 更新RNN的隐层状态
rnn
.
update_memory
(
pre_state
,
current_state
)
rnn
.
update_memory
(
pre_state
,
current_state
)
# 输出预测概率
rnn
.
output
(
current_score
)
rnn
.
output
(
current_score
)
return
rnn
()
return
rnn
()
...
@@ -226,14 +234,14 @@ decoder_size = hidden_dim
...
@@ -226,14 +234,14 @@ decoder_size = hidden_dim
```
python
```
python
def
decode
(
context
,
is_sparse
):
def
decode
(
context
,
is_sparse
):
init_state
=
context
init_state
=
context
# 定义解码过程循环计数变量
array_len
=
pd
.
fill_constant
(
shape
=
[
1
],
dtype
=
'int64'
,
value
=
max_length
)
array_len
=
pd
.
fill_constant
(
shape
=
[
1
],
dtype
=
'int64'
,
value
=
max_length
)
counter
=
pd
.
zeros
(
shape
=
[
1
],
dtype
=
'int64'
,
force_cpu
=
True
)
counter
=
pd
.
zeros
(
shape
=
[
1
],
dtype
=
'int64'
,
force_cpu
=
True
)
#
fill the first element with init_
state
#
定义 tensor array 用以保存各个时间步的内容,并写入初始id,score和
state
state_array
=
pd
.
create_array
(
'float32'
)
state_array
=
pd
.
create_array
(
'float32'
)
pd
.
array_write
(
init_state
,
array
=
state_array
,
i
=
counter
)
pd
.
array_write
(
init_state
,
array
=
state_array
,
i
=
counter
)
# ids, scores as memory
ids_array
=
pd
.
create_array
(
'int64'
)
ids_array
=
pd
.
create_array
(
'int64'
)
scores_array
=
pd
.
create_array
(
'float32'
)
scores_array
=
pd
.
create_array
(
'float32'
)
...
@@ -244,34 +252,35 @@ def decode(context, is_sparse):
...
@@ -244,34 +252,35 @@ def decode(context, is_sparse):
pd
.
array_write
(
init_ids
,
array
=
ids_array
,
i
=
counter
)
pd
.
array_write
(
init_ids
,
array
=
ids_array
,
i
=
counter
)
pd
.
array_write
(
init_scores
,
array
=
scores_array
,
i
=
counter
)
pd
.
array_write
(
init_scores
,
array
=
scores_array
,
i
=
counter
)
# 定义循环终止条件变量
cond
=
pd
.
less_than
(
x
=
counter
,
y
=
array_len
)
cond
=
pd
.
less_than
(
x
=
counter
,
y
=
array_len
)
# 定义 while_op
while_op
=
pd
.
While
(
cond
=
cond
)
while_op
=
pd
.
While
(
cond
=
cond
)
with
while_op
.
block
():
with
while_op
.
block
():
# 定义每一步的计算
# 获取解码器在当前步的输入,包括上一步选择的id,对应的score和上一步的state
pre_ids
=
pd
.
array_read
(
array
=
ids_array
,
i
=
counter
)
pre_ids
=
pd
.
array_read
(
array
=
ids_array
,
i
=
counter
)
pre_state
=
pd
.
array_read
(
array
=
state_array
,
i
=
counter
)
pre_state
=
pd
.
array_read
(
array
=
state_array
,
i
=
counter
)
pre_score
=
pd
.
array_read
(
array
=
scores_array
,
i
=
counter
)
pre_score
=
pd
.
array_read
(
array
=
scores_array
,
i
=
counter
)
#
expand the lod of pre_state to be the same with pre_scor
e
#
更新输入的state为上一步选择id对应的stat
e
pre_state_expanded
=
pd
.
sequence_expand
(
pre_state
,
pre_score
)
pre_state_expanded
=
pd
.
sequence_expand
(
pre_state
,
pre_score
)
# 同训练模式下解码器中的计算逻辑,包括获取输入向量,解码器计算单元计算和
# 归一化单词预测概率的计算
pre_ids_emb
=
pd
.
embedding
(
pre_ids_emb
=
pd
.
embedding
(
input
=
pre_ids
,
input
=
pre_ids
,
size
=
[
dict_size
,
word_dim
],
size
=
[
dict_size
,
word_dim
],
dtype
=
'float32'
,
dtype
=
'float32'
,
is_sparse
=
is_sparse
)
is_sparse
=
is_sparse
)
# use rnn unit to update rnn
current_state
=
pd
.
fc
(
input
=
[
pre_state_expanded
,
pre_ids_emb
],
current_state
=
pd
.
fc
(
input
=
[
pre_state_expanded
,
pre_ids_emb
],
size
=
decoder_size
,
size
=
decoder_size
,
act
=
'tanh'
)
act
=
'tanh'
)
current_state_with_lod
=
pd
.
lod_reset
(
x
=
current_state
,
y
=
pre_score
)
current_state_with_lod
=
pd
.
lod_reset
(
x
=
current_state
,
y
=
pre_score
)
# use score to do beam search
current_score
=
pd
.
fc
(
input
=
current_state_with_lod
,
current_score
=
pd
.
fc
(
input
=
current_state_with_lod
,
size
=
target_dict_dim
,
size
=
target_dict_dim
,
act
=
'softmax'
)
act
=
'softmax'
)
topk_scores
,
topk_indices
=
pd
.
topk
(
current_score
,
k
=
beam_size
)
topk_scores
,
topk_indices
=
pd
.
topk
(
current_score
,
k
=
beam_size
)
# calculate accumulated scores after topk to reduce computation cost
# 计算累计得分,进行beam search
accu_scores
=
pd
.
elementwise_add
(
accu_scores
=
pd
.
elementwise_add
(
x
=
pd
.
log
(
topk_scores
),
y
=
pd
.
reshape
(
pre_score
,
shape
=
[
-
1
]),
axis
=
0
)
x
=
pd
.
log
(
topk_scores
),
y
=
pd
.
reshape
(
pre_score
,
shape
=
[
-
1
]),
axis
=
0
)
selected_ids
,
selected_scores
=
pd
.
beam_search
(
selected_ids
,
selected_scores
=
pd
.
beam_search
(
...
@@ -284,14 +293,12 @@ def decode(context, is_sparse):
...
@@ -284,14 +293,12 @@ def decode(context, is_sparse):
level
=
0
)
level
=
0
)
pd
.
increment
(
x
=
counter
,
value
=
1
,
in_place
=
True
)
pd
.
increment
(
x
=
counter
,
value
=
1
,
in_place
=
True
)
# 将 search 结果和对应的隐层状态写入 tensor array 中
# update the memories
pd
.
array_write
(
current_state
,
array
=
state_array
,
i
=
counter
)
pd
.
array_write
(
current_state
,
array
=
state_array
,
i
=
counter
)
pd
.
array_write
(
selected_ids
,
array
=
ids_array
,
i
=
counter
)
pd
.
array_write
(
selected_ids
,
array
=
ids_array
,
i
=
counter
)
pd
.
array_write
(
selected_scores
,
array
=
scores_array
,
i
=
counter
)
pd
.
array_write
(
selected_scores
,
array
=
scores_array
,
i
=
counter
)
# update the break condition: up to the max length or all candidates of
# 更新循环终止条件
# source sentences have ended.
length_cond
=
pd
.
less_than
(
x
=
counter
,
y
=
array_len
)
length_cond
=
pd
.
less_than
(
x
=
counter
,
y
=
array_len
)
finish_cond
=
pd
.
logical_not
(
pd
.
is_empty
(
x
=
selected_ids
))
finish_cond
=
pd
.
logical_not
(
pd
.
is_empty
(
x
=
selected_ids
))
pd
.
logical_and
(
x
=
length_cond
,
y
=
finish_cond
,
out
=
cond
)
pd
.
logical_and
(
x
=
length_cond
,
y
=
finish_cond
,
out
=
cond
)
...
...
08.machine_translation/index.cn.html
浏览文件 @
748fa6ee
...
@@ -96,9 +96,9 @@
...
@@ -96,9 +96,9 @@
### 编码器-解码器框架
### 编码器-解码器框架
编码器-解码器(Encoder-Decoder)\[[2](#参考文献)\]框架用于解决由一个任意长度的源序列到另一个任意长度的目标序列的变换问题。即编码阶段将整个源序列编码成一个向量,解码阶段通过最大化预测序列概率,从中解码出整个目标序列。编码和解码的过程通常都使用RNN实现。
编码器-解码器(Encoder-Decoder)\[[2](#参考文献)\]框架用于解决由一个任意长度的源序列到另一个任意长度的目标序列的变换问题。即编码阶段将整个源序列编码成一个向量,解码阶段通过最大化预测序列概率,从中解码出整个目标序列。编码和解码的过程通常都使用RNN实现。
![encoder_decoder](./image/encoder_decoder.png)
<div
align=
"center"
>
<div
align=
"center"
>
<img
src =
"https://github.com/PaddlePaddle/book/blob/develop/08.machine_translation/image/encoder_decoder.png?raw=true"
width=
"
4
00"
><br/>
<img
src =
"https://github.com/PaddlePaddle/book/blob/develop/08.machine_translation/image/encoder_decoder.png?raw=true"
width=
"
7
00"
><br/>
图3. 编码器-解码器框架
图3. 编码器-解码器框架
</div>
</div>
...
@@ -124,7 +124,7 @@
...
@@ -124,7 +124,7 @@
机器翻译任务的训练过程中,解码阶段的目标是最大化下一个正确的目标语言词的概率。思路是:
机器翻译任务的训练过程中,解码阶段的目标是最大化下一个正确的目标语言词的概率。思路是:
1. 每一个时刻,根据源语言句子的编码信息(又叫上下文向量,context vector)$c$、真实目标语言序列的第$i$个词$u_i$和$i$时刻RNN的隐层状态$z_i$,计算出下一个隐层状态$z_{i+1}$。计算公式如下:
1. 每一个时刻,根据源语言句子的编码信息(又叫上下文向量,context vector)$c$、真实目标语言序列的第$i$个词$u_i$和$i$时刻RNN的隐层状态$z_i$,计算出下一个隐层状态$z_{i+1}$。计算公式如下:
$$z_{i+1}=\phi_{\theta '} \left ( c,u_i,z_i \right )$$
$$z_{i+1}=\phi_{\theta '} \left ( c,u_i,z_i \right )$$
其中$\phi _{\theta '}$是一个非线性激活函数;$c
=q\mathbf{h}
$是源语言句子的上下文向量,在不使用注意力机制时,如果[编码器](#编码器)的输出是源语言句子编码后的最后一个元素,则可以定义$c=h_T$;$u_i$是目标语言序列的第$i$个单词,$u_0$是目标语言序列的开始标记`
<s>
`,表示解码开始;$z_i$是$i$时刻解码RNN的隐层状态,$z_0$是一个全零的向量。
其中$\phi _{\theta '}$是一个非线性激活函数;$c$是源语言句子的上下文向量,在不使用注意力机制时,如果[编码器](#编码器)的输出是源语言句子编码后的最后一个元素,则可以定义$c=h_T$;$u_i$是目标语言序列的第$i$个单词,$u_0$是目标语言序列的开始标记`
<s>
`,表示解码开始;$z_i$是$i$时刻解码RNN的隐层状态,$z_0$是一个全零的向量。
2. 将$z_{i+1}$通过`softmax`归一化,得到目标语言序列的第$i+1$个单词的概率分布$p_{i+1}$。概率分布公式如下:
2. 将$z_{i+1}$通过`softmax`归一化,得到目标语言序列的第$i+1$个单词的概率分布$p_{i+1}$。概率分布公式如下:
$$p\left ( u_{i+1}|u_{
<
i+1},\mathbf{x} \right )=softmax(W_sz_{i+1}+b_z)$$
$$p\left ( u_{i+1}|u_{
<
i+1},\mathbf{x} \right )=softmax(W_sz_{i+1}+b_z)$$
...
@@ -202,33 +202,35 @@ except ImportError:
...
@@ -202,33 +202,35 @@ except ImportError:
from paddle.fluid.trainer import *
from paddle.fluid.trainer import *
from paddle.fluid.inferencer import *
from paddle.fluid.inferencer import *
dict_size = 30000
dict_size = 30000 # 字典维度
source_dict_dim = target_dict_dim = dict_size
source_dict_dim = target_dict_dim = dict_size # 源/目标语言字典维度
hidden_dim = 32
hidden_dim = 32 # 编码器中的隐层大小
word_dim = 16
word_dim = 16 # 词向量维度
batch_size = 2
batch_size = 2 # batch 中的样本数
max_length = 8
max_length = 8 # 生成句子的最大长度
topk_size = 50
beam_size = 2 # 柱宽度
beam_size = 2
decoder_size = hidden_dim
decoder_size = hidden_dim
# 解码器中的隐层大小
```
```
然后如下实现编码器框架:
然后如下实现编码器框架:
```python
```python
def encoder(is_sparse):
def encoder(is_sparse):
# 定义源语言id序列的输入数据
src_word_id = pd.data(
src_word_id = pd.data(
name="src_word_id", shape=[1], dtype='int64', lod_level=1)
name="src_word_id", shape=[1], dtype='int64', lod_level=1)
# 将上述编码映射到低维语言空间的词向量
src_embedding = pd.embedding(
src_embedding = pd.embedding(
input=src_word_id,
input=src_word_id,
size=[dict_size, word_dim],
size=[dict_size, word_dim],
dtype='float32',
dtype='float32',
is_sparse=is_sparse,
is_sparse=is_sparse,
param_attr=fluid.ParamAttr(name='vemb'))
param_attr=fluid.ParamAttr(name='vemb'))
# LSTM层:fc + dynamic_lstm
fc1 = pd.fc(input=src_embedding, size=hidden_dim * 4, act='tanh')
fc1 = pd.fc(input=src_embedding, size=hidden_dim * 4, act='tanh')
lstm_hidden0, lstm_0 = pd.dynamic_lstm(input=fc1, size=hidden_dim * 4)
lstm_hidden0, lstm_0 = pd.dynamic_lstm(input=fc1, size=hidden_dim * 4)
# 取源语言序列编码后的最后一个状态
encoder_out = pd.sequence_last_step(input=lstm_hidden0)
encoder_out = pd.sequence_last_step(input=lstm_hidden0)
return encoder_out
return encoder_out
```
```
...
@@ -237,6 +239,7 @@ decoder_size = hidden_dim
...
@@ -237,6 +239,7 @@ decoder_size = hidden_dim
```python
```python
def train_decoder(context, is_sparse):
def train_decoder(context, is_sparse):
# 定义目标语言id序列的输入数据,并映射到低维语言空间的词向量
trg_language_word = pd.data(
trg_language_word = pd.data(
name="target_language_word", shape=[1], dtype='int64', lod_level=1)
name="target_language_word", shape=[1], dtype='int64', lod_level=1)
trg_embedding = pd.embedding(
trg_embedding = pd.embedding(
...
@@ -247,17 +250,22 @@ decoder_size = hidden_dim
...
@@ -247,17 +250,22 @@ decoder_size = hidden_dim
param_attr=fluid.ParamAttr(name='vemb'))
param_attr=fluid.ParamAttr(name='vemb'))
rnn = pd.DynamicRNN()
rnn = pd.DynamicRNN()
with rnn.block():
with rnn.block(): # 使用 DynamicRNN 定义每一步的计算
# 获取当前步目标语言输入的词向量
current_word = rnn.step_input(trg_embedding)
current_word = rnn.step_input(trg_embedding)
# 获取隐层状态
pre_state = rnn.memory(init=context)
pre_state = rnn.memory(init=context)
# 解码器计算单元:单层前馈网络
current_state = pd.fc(input=[current_word, pre_state],
current_state = pd.fc(input=[current_word, pre_state],
size=decoder_size,
size=decoder_size,
act='tanh')
act='tanh')
# 计算归一化的单词预测概率
current_score = pd.fc(input=current_state,
current_score = pd.fc(input=current_state,
size=target_dict_dim,
size=target_dict_dim,
act='softmax')
act='softmax')
# 更新RNN的隐层状态
rnn.update_memory(pre_state, current_state)
rnn.update_memory(pre_state, current_state)
# 输出预测概率
rnn.output(current_score)
rnn.output(current_score)
return rnn()
return rnn()
...
@@ -268,14 +276,14 @@ decoder_size = hidden_dim
...
@@ -268,14 +276,14 @@ decoder_size = hidden_dim
```python
```python
def decode(context, is_sparse):
def decode(context, is_sparse):
init_state = context
init_state = context
# 定义解码过程循环计数变量
array_len = pd.fill_constant(shape=[1], dtype='int64', value=max_length)
array_len = pd.fill_constant(shape=[1], dtype='int64', value=max_length)
counter = pd.zeros(shape=[1], dtype='int64', force_cpu=True)
counter = pd.zeros(shape=[1], dtype='int64', force_cpu=True)
#
fill the first element with init_
state
#
定义 tensor array 用以保存各个时间步的内容,并写入初始id,score和
state
state_array = pd.create_array('float32')
state_array = pd.create_array('float32')
pd.array_write(init_state, array=state_array, i=counter)
pd.array_write(init_state, array=state_array, i=counter)
# ids, scores as memory
ids_array = pd.create_array('int64')
ids_array = pd.create_array('int64')
scores_array = pd.create_array('float32')
scores_array = pd.create_array('float32')
...
@@ -286,34 +294,35 @@ def decode(context, is_sparse):
...
@@ -286,34 +294,35 @@ def decode(context, is_sparse):
pd.array_write(init_ids, array=ids_array, i=counter)
pd.array_write(init_ids, array=ids_array, i=counter)
pd.array_write(init_scores, array=scores_array, i=counter)
pd.array_write(init_scores, array=scores_array, i=counter)
# 定义循环终止条件变量
cond = pd.less_than(x=counter, y=array_len)
cond = pd.less_than(x=counter, y=array_len)
# 定义 while_op
while_op = pd.While(cond=cond)
while_op = pd.While(cond=cond)
with while_op.block():
with while_op.block(): # 定义每一步的计算
# 获取解码器在当前步的输入,包括上一步选择的id,对应的score和上一步的state
pre_ids = pd.array_read(array=ids_array, i=counter)
pre_ids = pd.array_read(array=ids_array, i=counter)
pre_state = pd.array_read(array=state_array, i=counter)
pre_state = pd.array_read(array=state_array, i=counter)
pre_score = pd.array_read(array=scores_array, i=counter)
pre_score = pd.array_read(array=scores_array, i=counter)
#
expand the lod of pre_state to be the same with pre_scor
e
#
更新输入的state为上一步选择id对应的stat
e
pre_state_expanded = pd.sequence_expand(pre_state, pre_score)
pre_state_expanded = pd.sequence_expand(pre_state, pre_score)
# 同训练模式下解码器中的计算逻辑,包括获取输入向量,解码器计算单元计算和
# 归一化单词预测概率的计算
pre_ids_emb = pd.embedding(
pre_ids_emb = pd.embedding(
input=pre_ids,
input=pre_ids,
size=[dict_size, word_dim],
size=[dict_size, word_dim],
dtype='float32',
dtype='float32',
is_sparse=is_sparse)
is_sparse=is_sparse)
# use rnn unit to update rnn
current_state = pd.fc(input=[pre_state_expanded, pre_ids_emb],
current_state = pd.fc(input=[pre_state_expanded, pre_ids_emb],
size=decoder_size,
size=decoder_size,
act='tanh')
act='tanh')
current_state_with_lod = pd.lod_reset(x=current_state, y=pre_score)
current_state_with_lod = pd.lod_reset(x=current_state, y=pre_score)
# use score to do beam search
current_score = pd.fc(input=current_state_with_lod,
current_score = pd.fc(input=current_state_with_lod,
size=target_dict_dim,
size=target_dict_dim,
act='softmax')
act='softmax')
topk_scores, topk_indices = pd.topk(current_score, k=beam_size)
topk_scores, topk_indices = pd.topk(current_score, k=beam_size)
# calculate accumulated scores after topk to reduce computation cost
# 计算累计得分,进行beam search
accu_scores = pd.elementwise_add(
accu_scores = pd.elementwise_add(
x=pd.log(topk_scores), y=pd.reshape(pre_score, shape=[-1]), axis=0)
x=pd.log(topk_scores), y=pd.reshape(pre_score, shape=[-1]), axis=0)
selected_ids, selected_scores = pd.beam_search(
selected_ids, selected_scores = pd.beam_search(
...
@@ -326,14 +335,12 @@ def decode(context, is_sparse):
...
@@ -326,14 +335,12 @@ def decode(context, is_sparse):
level=0)
level=0)
pd.increment(x=counter, value=1, in_place=True)
pd.increment(x=counter, value=1, in_place=True)
# 将 search 结果和对应的隐层状态写入 tensor array 中
# update the memories
pd.array_write(current_state, array=state_array, i=counter)
pd.array_write(current_state, array=state_array, i=counter)
pd.array_write(selected_ids, array=ids_array, i=counter)
pd.array_write(selected_ids, array=ids_array, i=counter)
pd.array_write(selected_scores, array=scores_array, i=counter)
pd.array_write(selected_scores, array=scores_array, i=counter)
# update the break condition: up to the max length or all candidates of
# 更新循环终止条件
# source sentences have ended.
length_cond = pd.less_than(x=counter, y=array_len)
length_cond = pd.less_than(x=counter, y=array_len)
finish_cond = pd.logical_not(pd.is_empty(x=selected_ids))
finish_cond = pd.logical_not(pd.is_empty(x=selected_ids))
pd.logical_and(x=length_cond, y=finish_cond, out=cond)
pd.logical_and(x=length_cond, y=finish_cond, out=cond)
...
...
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