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8d428bd9
编写于
12月 04, 2017
作者:
R
ranqiu
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电子邮件补丁
差异文件
Update annotations of layers.py
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85e6906f
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66 addition
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55 deletion
+66
-55
python/paddle/trainer_config_helpers/layers.py
python/paddle/trainer_config_helpers/layers.py
+66
-55
未找到文件。
python/paddle/trainer_config_helpers/layers.py
浏览文件 @
8d428bd9
...
...
@@ -1516,34 +1516,33 @@ def lstmemory(input,
NOTE: This is a low level user interface. You can use network.simple_lstm
to config a simple plain lstm layer.
Please refer to **Generating Sequences With Recurrent Neural Networks** for
more details about LSTM.
Link_ goes as below.
.. _Link: http://arxiv.org/abs/1308.0850
Reference:
`Generating Sequences With Recurrent Neural Networks
<https://arxiv.org/pdf/1308.0850.pdf>`_
:param name: The
lstmemory layer name
.
:param name: The
name of this layer. It is optional
.
:type name: basestring
:param size: DEPRECATED.
size of the lstm cell
:param size: DEPRECATED.
The dimension of the lstm cell.
:type size: int
:param input: The input of this layer.
:type input: LayerOutput
:param reverse:
is sequence process reversed or not
.
:param reverse:
Whether the input sequence is processed in a reverse order
.
:type reverse: bool
:param act: Activation type. TanhActivation is the default activation.
:type act: BaseActivation
:param gate_act: gate activation type, SigmoidActivation by default.
:param gate_act: Activation type of this layer's gates. SigmoidActivation is the
default activation.
:type gate_act: BaseActivation
:param state_act:
state activation type, TanhActivation by default
.
:param state_act:
Activation type of the state. TanhActivation is the default activation
.
:type state_act: BaseActivation
:param bias_attr: The bias attribute. If the parameter is set to False or an object
whose type is not ParameterAttribute, no bias is defined. If the
parameter is set to True, the bias is initialized to zero.
:type bias_attr: ParameterAttribute | None | bool | Any
:param param_attr: Parameter Attribute.
:type param_attr: ParameterAttribute | None | False
:param layer_attr: Extra Layer attribute
:param param_attr: The parameter attribute. See ParameterAttribute for details.
:type param_attr: ParameterAttribute
:param layer_attr: The extra layer attribute. See ExtraLayerAttribute for
details.
:type layer_attr: ExtraLayerAttribute | None
:return: LayerOutput object.
:rtype: LayerOutput
...
...
@@ -1632,14 +1631,14 @@ def grumemory(input,
h_t = (1 - z_t) h_{t-1} + z_t {
\\
tilde{h_t}}
NOTE: In PaddlePaddle's implementation, the multiplication operations
:math:`W_{r}x_{t}`, :math:`W_{z}x_{t}` and :math:`W x_t` are not
computed in
gate_recurrent layer. Consequently, an additional mixed_layer with
:math:`W_{r}x_{t}`, :math:`W_{z}x_{t}` and :math:`W x_t` are not
performed
in
gate_recurrent layer. Consequently, an additional mixed_layer with
full_matrix_projection or a fc_layer must be included before grumemory
is called.
More details can be found by referring to `Empirical Evaluation of Gated
Recurrent Neural Networks on Sequence Modeling.
<https://arxiv.org/abs/1412.3555>`_
Reference:
`Empirical Evaluation of Gated Recurrent Neural Networks on Sequence Modeling
<https://arxiv.org/abs/1412.3555>`_
The simple usage is:
...
...
@@ -1647,28 +1646,29 @@ def grumemory(input,
gru = grumemory(input)
:param name: The
gru layer name
.
:type name:
None |
basestring
:param name: The
name of this layer. It is optional
.
:type name: basestring
:param input: The input of this layer.
:type input: LayerOutput.
:param size: DEPRECATED.
size of the gru cell
:param size: DEPRECATED.
The dimension of the gru cell.
:type size: int
:param reverse: Whether
sequence process is reversed or not
.
:param reverse: Whether
the input sequence is processed in a reverse order
.
:type reverse: bool
:param act: Activation type, TanhActivation is the default. This activation
affects the :math:`{
\\
tilde{h_t}}`.
:type act: BaseActivation
:param gate_act:
gate activation type, SigmoidActivation by default.
This activation affects the :math:`z_t` and :math:`r_t`. It is the
:math:`
\\
sigma` in the above formula.
:param gate_act:
Activation type of this layer's two gates. SigmoidActivation is
the default activation. This activation affects the :math:`z_t`
and :math:`r_t`. It is the
:math:`
\\
sigma` in the above formula.
:type gate_act: BaseActivation
:param bias_attr: The bias attribute. If the parameter is set to False or an object
whose type is not ParameterAttribute, no bias is defined. If the
parameter is set to True, the bias is initialized to zero.
:type bias_attr: ParameterAttribute | None | bool | Any
:param param_attr: Parameter Attribute.
:type param_attr: ParameterAttribute | None | False
:param layer_attr: Extra Layer attribute
:param param_attr: The parameter attribute. See ParameterAttribute for details.
:type param_attr: ParameterAttribute
:param layer_attr: The extra layer attribute. See ExtraLayerAttribute for
details.
:type layer_attr: ExtraLayerAttribute | None
:return: LayerOutput object.
:rtype: LayerOutput
...
...
@@ -1712,10 +1712,10 @@ def last_seq(input,
"""
Get Last Timestamp Activation of a sequence.
If stride > 0, this layer
slides
a window whose size is determined by stride,
and return the last value of the
window as the output. Thus, a long sequence
will be shorten. Note that for sequence with sub-sequence, the default valu
e
of stride is -1.
If stride > 0, this layer
will slide
a window whose size is determined by stride,
and return the last value of the
sequence in the window as the output. Thus, a
long sequence will be shortened. Note that for sequence with sub-sequence, th
e
default value
of stride is -1.
The simple usage is:
...
...
@@ -1724,14 +1724,16 @@ def last_seq(input,
seq = last_seq(input=layer)
:param agg_level: Aggregated level
:type agg_level: AggregateLevel
:param name: The name of this layer. It is optional.
:type name: basestring
:param input: The input of this layer.
:type input: LayerOutput
:param stride: The step size between successive pooling regions.
:type stride: Int
:param layer_attr: extra layer attributes.
:type layer_attr: ExtraLayerAttribute.
:type stride: int
:param layer_attr: The extra layer attribute. See ExtraLayerAttribute for
details.
:type layer_attr: ExtraLayerAttribute
:return: LayerOutput object.
:rtype: LayerOutput
"""
...
...
@@ -1768,10 +1770,10 @@ def first_seq(input,
"""
Get First Timestamp Activation of a sequence.
If stride > 0, this layer
slides
a window whose size is determined by stride,
and return the first value of the
window as the output. Thus, a long sequence
will be shorten. Note that for sequence with sub-sequence, the default valu
e
of stride is -1.
If stride > 0, this layer
will slide
a window whose size is determined by stride,
and return the first value of the
sequence in the window as the output. Thus, a
long sequence will be shortened. Note that for sequence with sub-sequence, th
e
default value
of stride is -1.
The simple usage is:
...
...
@@ -1780,13 +1782,15 @@ def first_seq(input,
seq = first_seq(input=layer)
:param agg_level: aggregation level
:type agg_level: AggregateLevel
:param name: The name of this layer. It is optional.
:type name: basestring
:param input: The input of this layer.
:type input: LayerOutput
:param stride: The step size between successive pooling regions.
:type stride: Int
:param layer_attr: extra layer attributes.
:type stride: int
:param layer_attr: The extra layer attribute. See ExtraLayerAttribute for
details.
:type layer_attr: ExtraLayerAttribute.
:return: LayerOutput object.
:rtype: LayerOutput
...
...
@@ -1844,8 +1848,8 @@ def expand_layer(input,
expand_level
=
ExpandLevel
.
FROM_NO_SEQUENCE
,
layer_attr
=
None
):
"""
A layer for
"Expand D
ense data or (sequence data where the length of each
sequence is one) to sequence data.
"
A layer for
expanding d
ense data or (sequence data where the length of each
sequence is one) to sequence data.
The example usage is:
...
...
@@ -1857,7 +1861,9 @@ def expand_layer(input,
:param input: The input of this layer.
:type input: LayerOutput
:param expand_as: Expand as this layer's sequence info.
:param expand_as: Expand the input according to this layer's sequence infomation. And
after the operation, the input expanded will have the same number of
elememts as this layer.
:type expand_as: LayerOutput
:param name: The name of this layer. It is optional.
:type name: basestring
...
...
@@ -1865,9 +1871,10 @@ def expand_layer(input,
whose type is not ParameterAttribute, no bias is defined. If the
parameter is set to True, the bias is initialized to zero.
:type bias_attr: ParameterAttribute | None | bool | Any
:param expand_level:
whether input layer is timestep(default) or
sequence.
:param expand_level:
Whether the input layer is a sequence or the element of a
sequence.
:type expand_level: ExpandLevel
:param layer_attr: extra layer attributes.
:param layer_attr: The extra layer attribute. See ExtraLayerAttribute for
details.
:type layer_attr: ExtraLayerAttribute.
:return: LayerOutput object.
:rtype: LayerOutput
...
...
@@ -3294,7 +3301,7 @@ def row_l2_norm_layer(input, name=None, layer_attr=None):
A layer for L2-normalization in each row.
.. math::
out[i] =
\
f
rac{in[i]}{\sqrt{
\sum_{k=1}^N in[k]^{2}}}
out[i] =
\
\
frac{in[i]} {
\\
sqrt{
\
\
sum_{k=1}^N in[k]^{2}}}
where the size of :math:`in` is (batchSize x dataDim) ,
and the size of :math:`out` is a (batchSize x dataDim) .
...
...
@@ -6161,9 +6168,11 @@ def huber_regression_cost(input,
Given a prediction f(x), a label y and :math:`\delta`, the loss function
is defined as:
.. math:
loss = 0.5*\left ( y-f(x)
\r
ight )^2, \left | y-f(x)
\r
ight |\leq \delta
loss = \delta \left | y-f(x)
\r
ight |-0.5\delta ^2, otherwise
.. math::
loss = 0.5*(y-f(x))^{2}, | y-f(x) | < \delta
loss = \delta | y-f(x) | - 0.5 \delta ^2, otherwise
The example usage is:
...
...
@@ -6210,12 +6219,14 @@ def huber_classification_cost(input,
"""
For classification purposes, a variant of the Huber loss called modified Huber
is sometimes used. Given a prediction f(x) (a real-valued classifier score) and
a true binary class label :math:`y\in \
left \{-1, 1
\r
ight
\}`, the modified Huber
a true binary class label :math:`y\in \
{-1, 1
\}`, the modified Huber
loss is defined as:
.. math:
loss = \max \left ( 0, 1-yf(x)
\r
ight )^2, yf(x)\geq 1
loss = -4yf(x),
\t
ext{otherwise}
loss = \max ( 0, 1-yf(x) )^2, yf(x) \geq -1
loss = -4yf(x), otherwise
The example usage is:
...
...
@@ -6959,7 +6970,7 @@ def clip_layer(input, min, max, name=None):
.. math::
out[i] = \min
\left(\max\left(in[i],p_{1}
\r
ight),p_{2}
\r
ight
)
out[i] = \min
(\max (in[i],p_{1} ),p_{2}
)
.. code-block:: python
...
...
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