提交 adee3cf1 编写于 作者: C caoying03

refine comments of DSSM.

上级 f3b1bb5a
此差异已折叠。
......@@ -65,10 +65,11 @@ In below, we describe how to train DSSM model in PaddlePaddle. All the codes are
### Create a word vector table for the text
```python
def create_embedding(self, input, prefix=''):
'''
Create an embedding table whose name has a `prefix`.
'''
logger.info("create embedding table [%s] which dimention is %d" %
"""
Create word embedding. The `prefix` is added in front of the name of
embedding"s learnable parameter.
"""
logger.info("Create embedding table [%s] whose dimention is %d" %
(prefix, self.dnn_dims[0]))
emb = paddle.layer.embedding(
input=input,
......@@ -82,14 +83,15 @@ Since the input (embedding table) is a list of the IDs of the words correspondin
### CNN implementation
```python
def create_cnn(self, emb, prefix=''):
'''
"""
A multi-layer CNN.
:param emb: The word embedding.
:type emb: paddle.layer
:param prefix: The prefix will be added to of layers' names.
:type prefix: str
"""
@emb: paddle.layer
output of the embedding layer
@prefix: str
prefix of layers' names, used to share parameters between more than one `cnn` parts.
'''
def create_conv(context_len, hidden_size, prefix):
key = "%s_%d_%d" % (prefix, context_len, hidden_size)
conv = paddle.networks.sequence_conv_pool(
......@@ -97,15 +99,13 @@ def create_cnn(self, emb, prefix=''):
context_len=context_len,
hidden_size=hidden_size,
# set parameter attr for parameter sharing
context_proj_param_attr=ParamAttr(name=key + 'contex_proj.w'),
fc_param_attr=ParamAttr(name=key + '_fc.w'),
fc_bias_attr=ParamAttr(name=key + '_fc.b'),
pool_bias_attr=ParamAttr(name=key + '_pool.b'))
context_proj_param_attr=ParamAttr(name=key + "contex_proj.w"),
fc_param_attr=ParamAttr(name=key + "_fc.w"),
fc_bias_attr=ParamAttr(name=key + "_fc.b"),
pool_bias_attr=ParamAttr(name=key + "_pool.b"))
return conv
logger.info('create a sequence_conv_pool which context width is 3')
conv_3 = create_conv(3, self.dnn_dims[1], "cnn")
logger.info('create a sequence_conv_pool which context width is 4')
conv_4 = create_conv(4, self.dnn_dims[1], "cnn")
return conv_3, conv_4
```
......@@ -118,9 +118,9 @@ RNN is suitable for learning variable length of the information
```python
def create_rnn(self, emb, prefix=''):
'''
"""
A GRU sentence vector learner.
'''
"""
gru = paddle.networks.simple_gru(
input=emb,
size=self.dnn_dims[1],
......@@ -136,14 +136,15 @@ def create_rnn(self, emb, prefix=''):
```python
def create_fc(self, emb, prefix=''):
'''
"""
A multi-layer fully connected neural networks.
:param emb: The output of the embedding layer
:type emb: paddle.layer
:param prefix: A prefix will be added to the layers' names.
:type prefix: str
"""
@emb: paddle.layer
output of the embedding layer
@prefix: str
prefix of layers' names, used to share parameters between more than one `fc` parts.
'''
_input_layer = paddle.layer.pooling(
input=emb, pooling_type=paddle.pooling.Max())
fc = paddle.layer.fc(
......@@ -160,13 +161,10 @@ In the construction of FC, we use `paddle.layer.pooling` for the maximum pooling
```python
def create_dnn(self, sent_vec, prefix):
# if more than three layers exists, a fc layer will be added.
if len(self.dnn_dims) > 1:
_input_layer = sent_vec
for id, dim in enumerate(self.dnn_dims[1:]):
name = "%s_fc_%d_%d" % (prefix, id, dim)
logger.info("create fc layer [%s] which dimention is %d" %
(name, dim))
fc = paddle.layer.fc(
input=_input_layer,
size=dim,
......@@ -180,117 +178,12 @@ def create_dnn(self, sent_vec, prefix):
### Classification / Regression
The structure of classification and regression is similar. Below function can be used for both tasks.
```python
def _build_classification_or_regression_model(self, is_classification):
'''
Build a classification/regression model, and the cost is returned.
A Classification has 3 inputs:
- source sentence
- target sentence
- classification label
'''
# prepare inputs.
assert self.class_num
source = paddle.layer.data(
name='source_input',
type=paddle.data_type.integer_value_sequence(self.vocab_sizes[0]))
target = paddle.layer.data(
name='target_input',
type=paddle.data_type.integer_value_sequence(self.vocab_sizes[1]))
label = paddle.layer.data(
name='label_input',
type=paddle.data_type.integer_value(self.class_num)
if is_classification else paddle.data_type.dense_input)
prefixs = '_ _'.split(
) if self.share_semantic_generator else 'source target'.split()
embed_prefixs = '_ _'.split(
) if self.share_embed else 'source target'.split()
word_vecs = []
for id, input in enumerate([source, target]):
x = self.create_embedding(input, prefix=embed_prefixs[id])
word_vecs.append(x)
semantics = []
for id, input in enumerate(word_vecs):
x = self.model_arch_creater(input, prefix=prefixs[id])
semantics.append(x)
if is_classification:
concated_vector = paddle.layer.concat(semantics)
prediction = paddle.layer.fc(
input=concated_vector,
size=self.class_num,
act=paddle.activation.Softmax())
cost = paddle.layer.classification_cost(
input=prediction, label=label)
else:
prediction = paddle.layer.cos_sim(*semantics)
cost = paddle.layer.square_error_cost(prediction, label)
if not self.is_infer:
return cost, prediction, label
return prediction
```
Please check the function `_build_classification_or_regression_model` in [network_conf.py]( https://github.com/PaddlePaddle/models/blob/develop/dssm/network_conf.py) for detail implementation.
### Pairwise Rank
Please check the function `_build_rank_model` in [network_conf.py]( https://github.com/PaddlePaddle/models/blob/develop/dssm/network_conf.py) for implementation.
```python
def _build_rank_model(self):
'''
Build a pairwise rank model, and the cost is returned.
A pairwise rank model has 3 inputs:
- source sentence
- left_target sentence
- right_target sentence
- label, 1 if left_target should be sorted in front of right_target, otherwise 0.
'''
source = paddle.layer.data(
name='source_input',
type=paddle.data_type.integer_value_sequence(self.vocab_sizes[0]))
left_target = paddle.layer.data(
name='left_target_input',
type=paddle.data_type.integer_value_sequence(self.vocab_sizes[1]))
right_target = paddle.layer.data(
name='right_target_input',
type=paddle.data_type.integer_value_sequence(self.vocab_sizes[1]))
label = paddle.layer.data(
name='label_input', type=paddle.data_type.integer_value(1))
prefixs = '_ _ _'.split(
) if self.share_semantic_generator else 'source target target'.split()
embed_prefixs = '_ _'.split(
) if self.share_embed else 'source target target'.split()
word_vecs = []
for id, input in enumerate([source, left_target, right_target]):
x = self.create_embedding(input, prefix=embed_prefixs[id])
word_vecs.append(x)
semantics = []
for id, input in enumerate(word_vecs):
x = self.model_arch_creater(input, prefix=prefixs[id])
semantics.append(x)
# cossim score of source and left_target
left_score = paddle.layer.cos_sim(semantics[0], semantics[1])
# cossim score of source and right target
right_score = paddle.layer.cos_sim(semantics[0], semantics[2])
# rank cost
cost = paddle.layer.rank_cost(left_score, right_score, label=label)
# prediction = left_score - right_score
# but this operator is not supported currently.
# so AUC will not used.
return cost, None, None
```
## Data Format
Below is a simple example for the data in `./data`
......@@ -347,67 +240,7 @@ The example of this format is as follows.
## Training
We use `python train.py -y 0 --model_arch 0` with the data in `./data/classification` to train a DSSM model for classification.
```
usage: train.py [-h] [-i TRAIN_DATA_PATH] [-t TEST_DATA_PATH]
[-s SOURCE_DIC_PATH] [--target_dic_path TARGET_DIC_PATH]
[-b BATCH_SIZE] [-p NUM_PASSES] -y MODEL_TYPE -a MODEL_ARCH
[--share_network_between_source_target SHARE_NETWORK_BETWEEN_SOURCE_TARGET]
[--share_embed SHARE_EMBED] [--dnn_dims DNN_DIMS]
[--num_workers NUM_WORKERS] [--use_gpu USE_GPU] [-c CLASS_NUM]
[--model_output_prefix MODEL_OUTPUT_PREFIX]
[-g NUM_BATCHES_TO_LOG] [-e NUM_BATCHES_TO_TEST]
[-z NUM_BATCHES_TO_SAVE_MODEL]
PaddlePaddle DSSM example
optional arguments:
-h, --help show this help message and exit
-i TRAIN_DATA_PATH, --train_data_path TRAIN_DATA_PATH
path of training dataset
-t TEST_DATA_PATH, --test_data_path TEST_DATA_PATH
path of testing dataset
-s SOURCE_DIC_PATH, --source_dic_path SOURCE_DIC_PATH
path of the source's word dic
--target_dic_path TARGET_DIC_PATH
path of the target's word dic, if not set, the
`source_dic_path` will be used
-b BATCH_SIZE, --batch_size BATCH_SIZE
size of mini-batch (default:32)
-p NUM_PASSES, --num_passes NUM_PASSES
number of passes to run(default:10)
-y MODEL_TYPE, --model_type MODEL_TYPE
model type, 0 for classification, 1 for pairwise rank,
2 for regression (default: classification)
-a MODEL_ARCH, --model_arch MODEL_ARCH
model architecture, 1 for CNN, 0 for FC, 2 for RNN
--share_network_between_source_target SHARE_NETWORK_BETWEEN_SOURCE_TARGET
whether to share network parameters between source and
target
--share_embed SHARE_EMBED
whether to share word embedding between source and
target
--dnn_dims DNN_DIMS dimentions of dnn layers, default is '256,128,64,32',
which means create a 4-layer dnn, demention of each
layer is 256, 128, 64 and 32
--num_workers NUM_WORKERS
num worker threads, default 1
--use_gpu USE_GPU whether to use GPU devices (default: False)
-c CLASS_NUM, --class_num CLASS_NUM
number of categories for classification task.
--model_output_prefix MODEL_OUTPUT_PREFIX
prefix of the path for model to store, (default: ./)
-g NUM_BATCHES_TO_LOG, --num_batches_to_log NUM_BATCHES_TO_LOG
number of batches to output train log, (default: 100)
-e NUM_BATCHES_TO_TEST, --num_batches_to_test NUM_BATCHES_TO_TEST
number of batches to test, (default: 200)
-z NUM_BATCHES_TO_SAVE_MODEL, --num_batches_to_save_model NUM_BATCHES_TO_SAVE_MODEL
number of batches to output model, (default: 400)
```
Parameter description:
We use `python train.py -y 0 --model_arch 0` with the data in `./data/classification` to train a DSSM model for classification. The paremeters to execute the script `train.py` can be found by execution `python infer.py --help`. Some important parameters are:
- `train_data_path` Training data path
- `test_data_path` Test data path, optional
......@@ -418,48 +251,8 @@ Parameter description:
- `dnn_dims` The dimension of each layer of the model is set, the default is `256,128,64,32`,with 4 layers.
## To predict using the trained model
```
usage: infer.py [-h] --model_path MODEL_PATH -i DATA_PATH -o
PREDICTION_OUTPUT_PATH -y MODEL_TYPE [-s SOURCE_DIC_PATH]
[--target_dic_path TARGET_DIC_PATH] -a MODEL_ARCH
[--share_network_between_source_target SHARE_NETWORK_BETWEEN_SOURCE_TARGET]
[--share_embed SHARE_EMBED] [--dnn_dims DNN_DIMS]
[-c CLASS_NUM]
PaddlePaddle DSSM infer
optional arguments:
-h, --help show this help message and exit
--model_path MODEL_PATH
path of model parameters file
-i DATA_PATH, --data_path DATA_PATH
path of the dataset to infer
-o PREDICTION_OUTPUT_PATH, --prediction_output_path PREDICTION_OUTPUT_PATH
path to output the prediction
-y MODEL_TYPE, --model_type MODEL_TYPE
model type, 0 for classification, 1 for pairwise rank,
2 for regression (default: classification)
-s SOURCE_DIC_PATH, --source_dic_path SOURCE_DIC_PATH
path of the source's word dic
--target_dic_path TARGET_DIC_PATH
path of the target's word dic, if not set, the
`source_dic_path` will be used
-a MODEL_ARCH, --model_arch MODEL_ARCH
model architecture, 1 for CNN, 0 for FC, 2 for RNN
--share_network_between_source_target SHARE_NETWORK_BETWEEN_SOURCE_TARGET
whether to share network parameters between source and
target
--share_embed SHARE_EMBED
whether to share word embedding between source and
target
--dnn_dims DNN_DIMS dimentions of dnn layers, default is '256,128,64,32',
which means create a 4-layer dnn, demention of each
layer is 256, 128, 64 and 32
-c CLASS_NUM, --class_num CLASS_NUM
number of categories for classification task.
```
Important parameters are
The paremeters to execute the script `infer.py` can be found by execution `python infer.py --help`. Some important parameters are:
- `data_path` Path for the data to predict
- `prediction_output_path` Prediction output path
......
......@@ -107,10 +107,11 @@ In below, we describe how to train DSSM model in PaddlePaddle. All the codes are
### Create a word vector table for the text
```python
def create_embedding(self, input, prefix=''):
'''
Create an embedding table whose name has a `prefix`.
'''
logger.info("create embedding table [%s] which dimention is %d" %
"""
Create word embedding. The `prefix` is added in front of the name of
embedding"s learnable parameter.
"""
logger.info("Create embedding table [%s] whose dimention is %d" %
(prefix, self.dnn_dims[0]))
emb = paddle.layer.embedding(
input=input,
......@@ -124,14 +125,15 @@ Since the input (embedding table) is a list of the IDs of the words correspondin
### CNN implementation
```python
def create_cnn(self, emb, prefix=''):
'''
"""
A multi-layer CNN.
:param emb: The word embedding.
:type emb: paddle.layer
:param prefix: The prefix will be added to of layers' names.
:type prefix: str
"""
@emb: paddle.layer
output of the embedding layer
@prefix: str
prefix of layers' names, used to share parameters between more than one `cnn` parts.
'''
def create_conv(context_len, hidden_size, prefix):
key = "%s_%d_%d" % (prefix, context_len, hidden_size)
conv = paddle.networks.sequence_conv_pool(
......@@ -139,15 +141,13 @@ def create_cnn(self, emb, prefix=''):
context_len=context_len,
hidden_size=hidden_size,
# set parameter attr for parameter sharing
context_proj_param_attr=ParamAttr(name=key + 'contex_proj.w'),
fc_param_attr=ParamAttr(name=key + '_fc.w'),
fc_bias_attr=ParamAttr(name=key + '_fc.b'),
pool_bias_attr=ParamAttr(name=key + '_pool.b'))
context_proj_param_attr=ParamAttr(name=key + "contex_proj.w"),
fc_param_attr=ParamAttr(name=key + "_fc.w"),
fc_bias_attr=ParamAttr(name=key + "_fc.b"),
pool_bias_attr=ParamAttr(name=key + "_pool.b"))
return conv
logger.info('create a sequence_conv_pool which context width is 3')
conv_3 = create_conv(3, self.dnn_dims[1], "cnn")
logger.info('create a sequence_conv_pool which context width is 4')
conv_4 = create_conv(4, self.dnn_dims[1], "cnn")
return conv_3, conv_4
```
......@@ -160,9 +160,9 @@ RNN is suitable for learning variable length of the information
```python
def create_rnn(self, emb, prefix=''):
'''
"""
A GRU sentence vector learner.
'''
"""
gru = paddle.networks.simple_gru(
input=emb,
size=self.dnn_dims[1],
......@@ -178,14 +178,15 @@ def create_rnn(self, emb, prefix=''):
```python
def create_fc(self, emb, prefix=''):
'''
"""
A multi-layer fully connected neural networks.
:param emb: The output of the embedding layer
:type emb: paddle.layer
:param prefix: A prefix will be added to the layers' names.
:type prefix: str
"""
@emb: paddle.layer
output of the embedding layer
@prefix: str
prefix of layers' names, used to share parameters between more than one `fc` parts.
'''
_input_layer = paddle.layer.pooling(
input=emb, pooling_type=paddle.pooling.Max())
fc = paddle.layer.fc(
......@@ -202,13 +203,10 @@ In the construction of FC, we use `paddle.layer.pooling` for the maximum pooling
```python
def create_dnn(self, sent_vec, prefix):
# if more than three layers exists, a fc layer will be added.
if len(self.dnn_dims) > 1:
_input_layer = sent_vec
for id, dim in enumerate(self.dnn_dims[1:]):
name = "%s_fc_%d_%d" % (prefix, id, dim)
logger.info("create fc layer [%s] which dimention is %d" %
(name, dim))
fc = paddle.layer.fc(
input=_input_layer,
size=dim,
......@@ -222,117 +220,12 @@ def create_dnn(self, sent_vec, prefix):
### Classification / Regression
The structure of classification and regression is similar. Below function can be used for both tasks.
```python
def _build_classification_or_regression_model(self, is_classification):
'''
Build a classification/regression model, and the cost is returned.
A Classification has 3 inputs:
- source sentence
- target sentence
- classification label
'''
# prepare inputs.
assert self.class_num
source = paddle.layer.data(
name='source_input',
type=paddle.data_type.integer_value_sequence(self.vocab_sizes[0]))
target = paddle.layer.data(
name='target_input',
type=paddle.data_type.integer_value_sequence(self.vocab_sizes[1]))
label = paddle.layer.data(
name='label_input',
type=paddle.data_type.integer_value(self.class_num)
if is_classification else paddle.data_type.dense_input)
prefixs = '_ _'.split(
) if self.share_semantic_generator else 'source target'.split()
embed_prefixs = '_ _'.split(
) if self.share_embed else 'source target'.split()
word_vecs = []
for id, input in enumerate([source, target]):
x = self.create_embedding(input, prefix=embed_prefixs[id])
word_vecs.append(x)
semantics = []
for id, input in enumerate(word_vecs):
x = self.model_arch_creater(input, prefix=prefixs[id])
semantics.append(x)
if is_classification:
concated_vector = paddle.layer.concat(semantics)
prediction = paddle.layer.fc(
input=concated_vector,
size=self.class_num,
act=paddle.activation.Softmax())
cost = paddle.layer.classification_cost(
input=prediction, label=label)
else:
prediction = paddle.layer.cos_sim(*semantics)
cost = paddle.layer.square_error_cost(prediction, label)
if not self.is_infer:
return cost, prediction, label
return prediction
```
Please check the function `_build_classification_or_regression_model` in [network_conf.py]( https://github.com/PaddlePaddle/models/blob/develop/dssm/network_conf.py) for detail implementation.
### Pairwise Rank
Please check the function `_build_rank_model` in [network_conf.py]( https://github.com/PaddlePaddle/models/blob/develop/dssm/network_conf.py) for implementation.
```python
def _build_rank_model(self):
'''
Build a pairwise rank model, and the cost is returned.
A pairwise rank model has 3 inputs:
- source sentence
- left_target sentence
- right_target sentence
- label, 1 if left_target should be sorted in front of right_target, otherwise 0.
'''
source = paddle.layer.data(
name='source_input',
type=paddle.data_type.integer_value_sequence(self.vocab_sizes[0]))
left_target = paddle.layer.data(
name='left_target_input',
type=paddle.data_type.integer_value_sequence(self.vocab_sizes[1]))
right_target = paddle.layer.data(
name='right_target_input',
type=paddle.data_type.integer_value_sequence(self.vocab_sizes[1]))
label = paddle.layer.data(
name='label_input', type=paddle.data_type.integer_value(1))
prefixs = '_ _ _'.split(
) if self.share_semantic_generator else 'source target target'.split()
embed_prefixs = '_ _'.split(
) if self.share_embed else 'source target target'.split()
word_vecs = []
for id, input in enumerate([source, left_target, right_target]):
x = self.create_embedding(input, prefix=embed_prefixs[id])
word_vecs.append(x)
semantics = []
for id, input in enumerate(word_vecs):
x = self.model_arch_creater(input, prefix=prefixs[id])
semantics.append(x)
# cossim score of source and left_target
left_score = paddle.layer.cos_sim(semantics[0], semantics[1])
# cossim score of source and right target
right_score = paddle.layer.cos_sim(semantics[0], semantics[2])
# rank cost
cost = paddle.layer.rank_cost(left_score, right_score, label=label)
# prediction = left_score - right_score
# but this operator is not supported currently.
# so AUC will not used.
return cost, None, None
```
## Data Format
Below is a simple example for the data in `./data`
......@@ -389,67 +282,7 @@ The example of this format is as follows.
## Training
We use `python train.py -y 0 --model_arch 0` with the data in `./data/classification` to train a DSSM model for classification.
```
usage: train.py [-h] [-i TRAIN_DATA_PATH] [-t TEST_DATA_PATH]
[-s SOURCE_DIC_PATH] [--target_dic_path TARGET_DIC_PATH]
[-b BATCH_SIZE] [-p NUM_PASSES] -y MODEL_TYPE -a MODEL_ARCH
[--share_network_between_source_target SHARE_NETWORK_BETWEEN_SOURCE_TARGET]
[--share_embed SHARE_EMBED] [--dnn_dims DNN_DIMS]
[--num_workers NUM_WORKERS] [--use_gpu USE_GPU] [-c CLASS_NUM]
[--model_output_prefix MODEL_OUTPUT_PREFIX]
[-g NUM_BATCHES_TO_LOG] [-e NUM_BATCHES_TO_TEST]
[-z NUM_BATCHES_TO_SAVE_MODEL]
PaddlePaddle DSSM example
optional arguments:
-h, --help show this help message and exit
-i TRAIN_DATA_PATH, --train_data_path TRAIN_DATA_PATH
path of training dataset
-t TEST_DATA_PATH, --test_data_path TEST_DATA_PATH
path of testing dataset
-s SOURCE_DIC_PATH, --source_dic_path SOURCE_DIC_PATH
path of the source's word dic
--target_dic_path TARGET_DIC_PATH
path of the target's word dic, if not set, the
`source_dic_path` will be used
-b BATCH_SIZE, --batch_size BATCH_SIZE
size of mini-batch (default:32)
-p NUM_PASSES, --num_passes NUM_PASSES
number of passes to run(default:10)
-y MODEL_TYPE, --model_type MODEL_TYPE
model type, 0 for classification, 1 for pairwise rank,
2 for regression (default: classification)
-a MODEL_ARCH, --model_arch MODEL_ARCH
model architecture, 1 for CNN, 0 for FC, 2 for RNN
--share_network_between_source_target SHARE_NETWORK_BETWEEN_SOURCE_TARGET
whether to share network parameters between source and
target
--share_embed SHARE_EMBED
whether to share word embedding between source and
target
--dnn_dims DNN_DIMS dimentions of dnn layers, default is '256,128,64,32',
which means create a 4-layer dnn, demention of each
layer is 256, 128, 64 and 32
--num_workers NUM_WORKERS
num worker threads, default 1
--use_gpu USE_GPU whether to use GPU devices (default: False)
-c CLASS_NUM, --class_num CLASS_NUM
number of categories for classification task.
--model_output_prefix MODEL_OUTPUT_PREFIX
prefix of the path for model to store, (default: ./)
-g NUM_BATCHES_TO_LOG, --num_batches_to_log NUM_BATCHES_TO_LOG
number of batches to output train log, (default: 100)
-e NUM_BATCHES_TO_TEST, --num_batches_to_test NUM_BATCHES_TO_TEST
number of batches to test, (default: 200)
-z NUM_BATCHES_TO_SAVE_MODEL, --num_batches_to_save_model NUM_BATCHES_TO_SAVE_MODEL
number of batches to output model, (default: 400)
```
Parameter description:
We use `python train.py -y 0 --model_arch 0` with the data in `./data/classification` to train a DSSM model for classification. The paremeters to execute the script `train.py` can be found by execution `python infer.py --help`. Some important parameters are:
- `train_data_path` Training data path
- `test_data_path` Test data path, optional
......@@ -460,48 +293,8 @@ Parameter description:
- `dnn_dims` The dimension of each layer of the model is set, the default is `256,128,64,32`,with 4 layers.
## To predict using the trained model
```
usage: infer.py [-h] --model_path MODEL_PATH -i DATA_PATH -o
PREDICTION_OUTPUT_PATH -y MODEL_TYPE [-s SOURCE_DIC_PATH]
[--target_dic_path TARGET_DIC_PATH] -a MODEL_ARCH
[--share_network_between_source_target SHARE_NETWORK_BETWEEN_SOURCE_TARGET]
[--share_embed SHARE_EMBED] [--dnn_dims DNN_DIMS]
[-c CLASS_NUM]
PaddlePaddle DSSM infer
optional arguments:
-h, --help show this help message and exit
--model_path MODEL_PATH
path of model parameters file
-i DATA_PATH, --data_path DATA_PATH
path of the dataset to infer
-o PREDICTION_OUTPUT_PATH, --prediction_output_path PREDICTION_OUTPUT_PATH
path to output the prediction
-y MODEL_TYPE, --model_type MODEL_TYPE
model type, 0 for classification, 1 for pairwise rank,
2 for regression (default: classification)
-s SOURCE_DIC_PATH, --source_dic_path SOURCE_DIC_PATH
path of the source's word dic
--target_dic_path TARGET_DIC_PATH
path of the target's word dic, if not set, the
`source_dic_path` will be used
-a MODEL_ARCH, --model_arch MODEL_ARCH
model architecture, 1 for CNN, 0 for FC, 2 for RNN
--share_network_between_source_target SHARE_NETWORK_BETWEEN_SOURCE_TARGET
whether to share network parameters between source and
target
--share_embed SHARE_EMBED
whether to share word embedding between source and
target
--dnn_dims DNN_DIMS dimentions of dnn layers, default is '256,128,64,32',
which means create a 4-layer dnn, demention of each
layer is 256, 128, 64 and 32
-c CLASS_NUM, --class_num CLASS_NUM
number of categories for classification task.
```
Important parameters are
The paremeters to execute the script `infer.py` can be found by execution `python infer.py --help`. Some important parameters are:
- `data_path` Path for the data to predict
- `prediction_output_path` Prediction output path
......
......@@ -9,30 +9,27 @@ from utils import logger, ModelType, ModelArch, load_dic
parser = argparse.ArgumentParser(description="PaddlePaddle DSSM infer")
parser.add_argument(
"--model_path",
type=str,
required=True,
help="path of model parameters file")
"--model_path", type=str, required=True, help="The path of trained model.")
parser.add_argument(
"-i",
"--data_path",
type=str,
required=True,
help="path of the dataset to infer")
help="The path of the data for inferring.")
parser.add_argument(
"-o",
"--prediction_output_path",
type=str,
required=True,
help="path to output the prediction")
help="The path to save the predictions.")
parser.add_argument(
"-y",
"--model_type",
type=int,
required=True,
default=ModelType.CLASSIFICATION_MODE,
help=("model type, %d for classification, %d for pairwise rank, "
"%d for regression (default: classification)") %
help=("The model type: %d for classification, %d for pairwise rank, "
"%d for regression (default: classification).") %
(ModelType.CLASSIFICATION_MODE, ModelType.RANK_MODE,
ModelType.REGRESSION_MODE))
parser.add_argument(
......@@ -40,13 +37,13 @@ parser.add_argument(
"--source_dic_path",
type=str,
required=False,
help="path of the source's word dic")
help="The path of the source's word dictionary.")
parser.add_argument(
"--target_dic_path",
type=str,
required=False,
help=("path of the target's word dictionary, "
"if not set, the `source_dic_path` will be used"))
help=("The path of the target's word dictionary, "
"if this parameter is not set, the `source_dic_path` will be used."))
parser.add_argument(
"-a",
"--model_arch",
......@@ -69,15 +66,15 @@ parser.add_argument(
"--dnn_dims",
type=str,
default="256,128,64,32",
help=("dimentions of dnn layers, default is `256,128,64,32`, "
"which means create a 4-layer dnn, "
"demention of each layer is 256, 128, 64 and 32"))
help=("The dimentions of dnn layers, default is `256,128,64,32`, "
"which means a dnn with 4 layers with "
"dmentions 256, 128, 64 and 32 will be created."))
parser.add_argument(
"-c",
"--class_num",
type=int,
default=0,
help="number of categories for classification task.")
help="The number of categories for classification task.")
args = parser.parse_args()
args.model_type = ModelType(args.model_type)
......
......@@ -9,120 +9,129 @@ from utils import TaskType, load_dic, logger, ModelType, ModelArch, display_args
parser = argparse.ArgumentParser(description="PaddlePaddle DSSM example")
parser.add_argument(
'-i',
'--train_data_path',
"-i",
"--train_data_path",
type=str,
required=False,
help="path of training dataset")
help="The path of training data.")
parser.add_argument(
'-t',
'--test_data_path',
"-t",
"--test_data_path",
type=str,
required=False,
help="path of testing dataset")
help="The path of testing data.")
parser.add_argument(
'-s',
'--source_dic_path',
"-s",
"--source_dic_path",
type=str,
required=False,
help="path of the source's word dic")
help="The path of the source's word dictionary.")
parser.add_argument(
'--target_dic_path',
"--target_dic_path",
type=str,
required=False,
help=("path of the target's word dictionary, "
"if not set, the `source_dic_path` will be used"))
help=("The path of the target's word dictionary, "
"if this parameter is not set, the `source_dic_path` will be used"))
parser.add_argument(
'-b',
'--batch_size',
"-b",
"--batch_size",
type=int,
default=32,
help="size of mini-batch (default:32)")
help="The size of mini-batch (default:32).")
parser.add_argument(
'-p',
'--num_passes',
"-p",
"--num_passes",
type=int,
default=10,
help="number of passes to run(default:10)")
help="The number of passes to run(default:10).")
parser.add_argument(
'-y',
'--model_type',
"-y",
"--model_type",
type=int,
required=True,
default=ModelType.CLASSIFICATION_MODE,
help="model type, %d for classification, %d for pairwise rank, %d for regression (default: classification)"
% (ModelType.CLASSIFICATION_MODE, ModelType.RANK_MODE,
help=("model type, %d for classification, %d for pairwise rank, "
"%d for regression (default: classification).") %
(ModelType.CLASSIFICATION_MODE, ModelType.RANK_MODE,
ModelType.REGRESSION_MODE))
parser.add_argument(
'-a',
'--model_arch',
"-a",
"--model_arch",
type=int,
required=True,
default=ModelArch.CNN_MODE,
help="model architecture, %d for CNN, %d for FC, %d for RNN" %
help="The model architecture, %d for CNN, %d for FC, %d for RNN." %
(ModelArch.CNN_MODE, ModelArch.FC_MODE, ModelArch.RNN_MODE))
parser.add_argument(
'--share_network_between_source_target',
"--share_network_between_source_target",
type=distutils.util.strtobool,
default=False,
help="whether to share network parameters between source and target")
help="Whether to share network parameters between source and target.")
parser.add_argument(
'--share_embed',
"--share_embed",
type=distutils.util.strtobool,
default=False,
help="whether to share word embedding between source and target")
help="Whether to share word embedding between source and target.")
parser.add_argument(
'--dnn_dims',
"--dnn_dims",
type=str,
default='256,128,64,32',
help="dimentions of dnn layers, default is '256,128,64,32', which means create a 4-layer dnn, demention of each layer is 256, 128, 64 and 32"
)
default="256,128,64,32",
help=("The dimentions of dnn layers, default is '256,128,64,32', "
"which means create a 4-layer dnn. The dimention of each layer is "
"'256, 128, 64 and 32'."))
parser.add_argument(
'--num_workers', type=int, default=1, help="num worker threads, default 1")
"--num_workers",
type=int,
default=1,
help="The number of worker threads, default 1.")
parser.add_argument(
'--use_gpu',
"--use_gpu",
type=distutils.util.strtobool,
default=False,
help="whether to use GPU devices (default: False)")
help="Whether to use GPU devices (default: False)")
parser.add_argument(
'-c',
'--class_num',
"-c",
"--class_num",
type=int,
default=0,
help="number of categories for classification task.")
help="The number of categories for classification task.")
parser.add_argument(
'--model_output_prefix',
"--model_output_prefix",
type=str,
default="./",
help="prefix of the path for model to store, (default: ./)")
help="The prefix of the path to store the trained models (default: ./).")
parser.add_argument(
'-g',
'--num_batches_to_log',
"-g",
"--num_batches_to_log",
type=int,
default=100,
help="number of batches to output train log, (default: 100)")
help=("The log period. Every num_batches_to_test batches, "
"a training log will be printed. (default: 100)"))
parser.add_argument(
'-e',
'--num_batches_to_test',
"-e",
"--num_batches_to_test",
type=int,
default=200,
help="number of batches to test, (default: 200)")
help=("The test period. Every num_batches_to_save_model batches, "
"the specified test sample will be test (default: 200)."))
parser.add_argument(
'-z',
'--num_batches_to_save_model',
"-z",
"--num_batches_to_save_model",
type=int,
default=400,
help="number of batches to output model, (default: 400)")
help=("Every num_batches_to_save_model batches, "
"a trained model will be saved (default: 400)."))
# arguments check.
args = parser.parse_args()
args.model_type = ModelType(args.model_type)
args.model_arch = ModelArch(args.model_arch)
if args.model_type.is_classification():
assert args.class_num > 1, "--class_num should be set in classification task."
assert args.class_num > 1, ("The parameter class_num should be set in "
"classification task.")
layer_dims = [int(i) for i in args.dnn_dims.split(',')]
args.target_dic_path = args.source_dic_path if not args.target_dic_path else args.target_dic_path
layer_dims = [int(i) for i in args.dnn_dims.split(",")]
args.target_dic_path = args.source_dic_path if not \
args.target_dic_path else args.target_dic_path
def train(train_data_path=None,
......@@ -138,15 +147,15 @@ def train(train_data_path=None,
class_num=None,
num_workers=1,
use_gpu=False):
'''
"""
Train the DSSM.
'''
default_train_path = './data/rank/train.txt'
default_test_path = './data/rank/test.txt'
default_dic_path = './data/vocab.txt'
"""
default_train_path = "./data/rank/train.txt"
default_test_path = "./data/rank/test.txt"
default_dic_path = "./data/vocab.txt"
if not model_type.is_rank():
default_train_path = './data/classification/train.txt'
default_test_path = './data/classification/test.txt'
default_train_path = "./data/classification/train.txt"
default_test_path = "./data/classification/test.txt"
use_default_data = not train_data_path
......@@ -200,19 +209,19 @@ def train(train_data_path=None,
feeding = {}
if model_type.is_classification() or model_type.is_regression():
feeding = {'source_input': 0, 'target_input': 1, 'label_input': 2}
feeding = {"source_input": 0, "target_input": 1, "label_input": 2}
else:
feeding = {
'source_input': 0,
'left_target_input': 1,
'right_target_input': 2,
'label_input': 3
"source_input": 0,
"left_target_input": 1,
"right_target_input": 2,
"label_input": 3
}
def _event_handler(event):
'''
"""
Define batch handler
'''
"""
if isinstance(event, paddle.event.EndIteration):
# output train log
if event.batch_id % args.num_batches_to_log == 0:
......@@ -249,7 +258,7 @@ def train(train_data_path=None,
logger.info("Training has finished.")
if __name__ == '__main__':
if __name__ == "__main__":
display_args(args)
train(
train_data_path=args.train_data_path,
......
......@@ -8,7 +8,7 @@ logger.setLevel(logging.INFO)
def mode_attr_name(mode):
return mode.upper() + '_MODE'
return mode.upper() + "_MODE"
def create_attrs(cls):
......@@ -17,9 +17,9 @@ def create_attrs(cls):
def make_check_method(cls):
'''
"""
create methods for classes.
'''
"""
def method(mode):
def _method(self):
......@@ -28,7 +28,7 @@ def make_check_method(cls):
return _method
for id, mode in enumerate(cls.modes):
setattr(cls, 'is_' + mode, method(mode))
setattr(cls, "is_" + mode, method(mode))
def make_create_method(cls):
......@@ -41,10 +41,10 @@ def make_create_method(cls):
return _method
for id, mode in enumerate(cls.modes):
setattr(cls, 'create_' + mode, method(mode))
setattr(cls, "create_" + mode, method(mode))
def make_str_method(cls, type_name='unk'):
def make_str_method(cls, type_name="unk"):
def _str_(self):
for mode in cls.modes:
if self.mode == getattr(cls, mode_attr_name(mode)):
......@@ -53,9 +53,9 @@ def make_str_method(cls, type_name='unk'):
def _hash_(self):
return self.mode
setattr(cls, '__str__', _str_)
setattr(cls, '__repr__', _str_)
setattr(cls, '__hash__', _hash_)
setattr(cls, "__str__", _str_)
setattr(cls, "__repr__", _str_)
setattr(cls, "__hash__", _hash_)
cls.__name__ = type_name
......@@ -65,7 +65,7 @@ def _init_(self, mode, cls):
elif isinstance(mode, cls):
self.mode = mode.mode
else:
raise Exception("wrong mode type, get type: %s, value: %s" %
raise Exception("A wrong mode type, get type: %s, value: %s." %
(type(mode), mode))
......@@ -77,21 +77,21 @@ def build_mode_class(cls):
class TaskType(object):
modes = 'train test infer'.split()
modes = "train test infer".split()
def __init__(self, mode):
_init_(self, mode, TaskType)
class ModelType:
modes = 'classification rank regression'.split()
modes = "classification rank regression".split()
def __init__(self, mode):
_init_(self, mode, ModelType)
class ModelArch:
modes = 'fc cnn rnn'.split()
modes = "fc cnn rnn".split()
def __init__(self, mode):
_init_(self, mode, ModelArch)
......@@ -103,22 +103,16 @@ build_mode_class(ModelArch)
def sent2ids(sent, vocab):
'''
"""
transform a sentence to a list of ids.
@sent: str
a sentence.
@vocab: dict
a word dic
'''
"""
return [vocab.get(w, UNK) for w in sent.split()]
def load_dic(path):
'''
word dic format:
each line is a word
'''
"""
The format of word dictionary : each line is a word.
"""
dic = {}
with open(path) as f:
for id, line in enumerate(f):
......@@ -128,13 +122,6 @@ def load_dic(path):
def display_args(args):
logger.info("arguments passed by command line:")
logger.info("The arguments passed by command line is :")
for k, v in sorted(v for v in vars(args).items()):
logger.info("{}:\t{}".format(k, v))
if __name__ == '__main__':
t = TaskType(1)
t = TaskType.create_train()
print t
print 'is', t.is_train()
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