rnn.py 156.1 KB
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# Copyright (c) 2019 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.
# You may obtain a copy of the License at
#
#     http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# 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.

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import sys
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from functools import partial, reduce
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import warnings
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import paddle
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from paddle.utils import deprecated
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from . import nn
from . import tensor
from . import control_flow
from . import utils
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from . import sequence_lod
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from .utils import *
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from .. import core
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from ..framework import default_main_program
from ..data_feeder import convert_dtype
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from ..layer_helper import LayerHelper
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from ..framework import _non_static_mode
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from ..param_attr import ParamAttr
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from ..data_feeder import check_variable_and_dtype, check_type, check_dtype
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from collections.abc import Sequence
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__all__ = [
    'RNNCell',
    'GRUCell',
    'LSTMCell',
    'Decoder',
    'BeamSearchDecoder',
    'rnn',
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    'birnn',
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    'dynamic_decode',
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    'DecodeHelper',
    'TrainingHelper',
    'GreedyEmbeddingHelper',
    'SampleEmbeddingHelper',
    'BasicDecoder',
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    'dynamic_lstm',
    'dynamic_lstmp',
    'dynamic_gru',
    'gru_unit',
    'lstm_unit',
    'lstm',
    'beam_search',
    'beam_search_decode',
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]


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class RNNCell:
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    """
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        :api_attr: Static Graph
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    RNNCell is the base class for abstraction representing the calculations
    mapping the input and state to the output and new state. It is suitable to
    and mostly used in RNN.
    """

    def call(self, inputs, states, **kwargs):
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        r"""
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        Every cell must implement this method to do the calculations mapping the
        inputs and states to the output and new states.

        To be more flexible, both inputs and states can be a tensor variable or
        a nested structure (list|tuple|namedtuple|dict) of tensor variable, that
        is, a (possibly nested structure of) tensor variable[s].

        Parameters:
            inputs: A (possibly nested structure of) tensor variable[s].
            states: A (possibly nested structure of) tensor variable[s].
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            **kwargs: Additional keyword arguments, provided by the caller.

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        Returns:
            tuple: outputs and new_states pair. outputs and new_states both \
                can be nested structure of tensor variables. new_states must \
                have the same structure with states.

        """
        raise NotImplementedError("RNNCell must implent the call function.")

    def __call__(self, inputs, states, **kwargs):
        return self.call(inputs, states, **kwargs)

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    def get_initial_states(
        self,
        batch_ref,
        shape=None,
        dtype='float32',
        init_value=0,
        batch_dim_idx=0,
    ):
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        r"""
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        Generate initialized states according to provided shape, data type and
        value.

        Parameters:
            batch_ref: A (possibly nested structure of) tensor variable[s].
                The first dimension of the tensor will be used as batch size to
                initialize states.
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            shape: A (possibly nested structure of) shape[s], where a shape is
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                represented as a list/tuple of integer). -1(for batch size) will
                beautomatically inserted if shape is not started with it. If None,
                property `state_shape` will be used. The default value is None.
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            dtype: A (possibly nested structure of) data type[s]. The structure
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                must be same as that of `shape`, except when all tensors' in states
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                has the same data type, a single data type can be used. If
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                property `cell.state_shape` is not available, float32 will be used
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                as the data type. The default value is float32.
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            init_value: A float value used to initialize states.
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            batch_dim_idx: An integer indicating which dimension of the tensor in
                inputs represents batch size.  The default value is 0.
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        Returns:
            Variable: tensor variable[s] packed in the same structure provided \
                by shape, representing the initialized states.
        """
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        check_variable_and_dtype(
            batch_ref,
            'batch_ref',
            ['float32', 'float64', 'int32', 'int64'],
            'RNNCell',
        )
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        check_type(shape, 'shape', (list, tuple, type(None), int), 'RNNCell')
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        if isinstance(shape, (list, tuple)):
            shapes = map_structure(lambda x: x, shape)
            if isinstance(shape, list):
                for i, _shape in enumerate(shapes):
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                    check_type(_shape, 'shapes[' + str(i) + ']', int, 'RNNCell')
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            else:
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                check_type(shapes, 'shapes', int, 'RNNCell')
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        check_dtype(dtype, 'dtype', ['float32', 'float64'], 'RNNCell')

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        # TODO: use inputs and batch_size
        batch_ref = flatten(batch_ref)[0]

        def _is_shape_sequence(seq):
            """For shape, list/tuple of integer is the finest-grained objection"""
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            if isinstance(seq, list) or isinstance(seq, tuple):
                if reduce(
                    lambda flag, x: isinstance(x, int) and flag, seq, True
                ):
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                    return False
            # TODO: Add check for the illegal
            if isinstance(seq, dict):
                return True
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            return isinstance(seq, Sequence) and not isinstance(seq, str)
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        class Shape:
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            def __init__(self, shape):
                self.shape = shape if shape[0] == -1 else ([-1] + list(shape))

        # nested structure of shapes
        states_shapes = self.state_shape if shape is None else shape
        is_sequence_ori = utils.is_sequence
        utils.is_sequence = _is_shape_sequence
        states_shapes = map_structure(lambda shape: Shape(shape), states_shapes)
        utils.is_sequence = is_sequence_ori

        # nested structure of dtypes
        try:
            states_dtypes = self.state_dtype if dtype is None else dtype
        except NotImplementedError:  # use fp32 as default
            states_dtypes = "float32"
        if len(flatten(states_dtypes)) == 1:
            dtype = flatten(states_dtypes)[0]
            states_dtypes = map_structure(lambda shape: dtype, states_shapes)

        init_states = map_structure(
            lambda shape, dtype: tensor.fill_constant_batch_size_like(
                input=batch_ref,
                shape=shape.shape,
                dtype=dtype,
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                value=init_value,
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                input_dim_idx=batch_dim_idx,
            ),
            states_shapes,
            states_dtypes,
        )
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        return init_states

    @property
    def state_shape(self):
        """
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        Abstract method (property).
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        Used to initialize states.
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        A (possibly nested structure of) shape[s], where a shape is represented
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        as a list/tuple of integers (-1 for batch size would be automatically
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        inserted into a shape if shape is not started with it).
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        Not necessary to be implemented if states are not initialized by
        `get_initial_states` or the `shape` argument is provided when using
        `get_initial_states`.
        """
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        raise NotImplementedError(
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            "Please add implementaion for `state_shape` in the used cell."
        )
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    @property
    def state_dtype(self):
        """
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        Abstract method (property).
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        Used to initialize states.
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        A (possibly nested structure of) data types[s]. The structure must be
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        same as that of `shape`, except when all tensors' in states has the same
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        data type, a single data type can be used.
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        Not necessary to be implemented if states are not initialized
        by `get_initial_states` or the `dtype` argument is provided when using
        `get_initial_states`.
        """
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        raise NotImplementedError(
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            "Please add implementaion for `state_dtype` in the used cell."
        )
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class GRUCell(RNNCell):
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    r"""
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        :api_attr: Static Graph
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    Gated Recurrent Unit cell. It is a wrapper for
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    `fluid.contrib.layers.rnn_impl.BasicGRUUnit` to make it adapt to RNNCell.

    The formula used is as follow:

    .. math::

        u_t & = act_g(W_{ux}x_{t} + W_{uh}h_{t-1} + b_u)

        r_t & = act_g(W_{rx}x_{t} + W_{rh}h_{t-1} + b_r)

        \\tilde{h_t} & = act_c(W_{cx}x_{t} + W_{ch}(r_t \odot h_{t-1}) + b_c)

        h_t & = u_t \odot h_{t-1} + (1-u_t) \odot \\tilde{h_t}

    For more details, please refer to  `Learning Phrase Representations using
    RNN Encoder Decoder for Statistical Machine Translation <https://arxiv.org/pdf/1406.1078.pdf>`_

    Examples:

        .. code-block:: python

            import paddle.fluid.layers as layers
            cell = layers.GRUCell(hidden_size=256)
    """

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    def __init__(
        self,
        hidden_size,
        param_attr=None,
        bias_attr=None,
        gate_activation=None,
        activation=None,
        dtype="float32",
        name="GRUCell",
    ):
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        """
        Constructor of GRUCell.

        Parameters:
            hidden_size (int): The hidden size in the GRU cell.
            param_attr(ParamAttr, optional): The parameter attribute for the learnable
                weight matrix. Default: None.
            bias_attr (ParamAttr, optional): The parameter attribute for the bias
                of GRU. Default: None.
            gate_activation (function, optional): The activation function for :math:`act_g`.
                Default: `fluid.layers.sigmoid`.
            activation (function, optional): The activation function for :math:`act_c`.
                Default: `fluid.layers.tanh`.
            dtype(string, optional): The data type used in this cell. Default float32.
            name(string, optional) : The name scope used to identify parameters and biases.
        """
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        check_type(hidden_size, 'hidden_size', (int), 'GRUCell')
        check_dtype(dtype, 'dtype', ['float32', 'float64'], 'GRUCell')
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        self.hidden_size = hidden_size
        from .. import contrib  # TODO: resolve recurrent import
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        self.gru_unit = contrib.layers.rnn_impl.BasicGRUUnit(
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            name,
            hidden_size,
            param_attr,
            bias_attr,
            gate_activation,
            activation,
            dtype,
        )
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    def call(self, inputs, states):
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        r"""
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        Perform calculations of GRU.

        Parameters:
            inputs(Variable): A tensor with shape `[batch_size, input_size]`,
                corresponding to :math:`x_t` in the formula. The data type
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                should be float32 or float64.
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            states(Variable): A tensor with shape `[batch_size, hidden_size]`.
                corresponding to :math:`h_{t-1}` in the formula. The data type
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                should be float32 or float64.
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        Returns:
            tuple: A tuple( :code:`(outputs, new_states)` ), where `outputs` and \
                `new_states` is the same tensor shaped `[batch_size, hidden_size]`, \
                corresponding to :math:`h_t` in the formula. The data type of the \
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                tensor is same as that of `states`.
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        """
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        check_variable_and_dtype(
            inputs, 'inputs', ['float32', 'float64'], 'GRUCell'
        )
        check_variable_and_dtype(
            states, 'states', ['float32', 'float64'], 'GRUCell'
        )
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        new_hidden = self.gru_unit(inputs, states)
        return new_hidden, new_hidden

    @property
    def state_shape(self):
        """
        The `state_shape` of GRUCell is a shape `[hidden_size]` (-1 for batch
        size would be automatically inserted into shape). The shape corresponds
        to :math:`h_{t-1}`.
        """
        return [self.hidden_size]


class LSTMCell(RNNCell):
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    r"""
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        :api_attr: Static Graph
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    Long-Short Term Memory cell. It is a wrapper for
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    `fluid.contrib.layers.rnn_impl.BasicLSTMUnit` to make it adapt to RNNCell.

    The formula used is as follow:

    .. math::

        i_{t} & = act_g(W_{x_{i}}x_{t} + W_{h_{i}}h_{t-1} + b_{i})

        f_{t} & = act_g(W_{x_{f}}x_{t} + W_{h_{f}}h_{t-1} + b_{f} + forget\\_bias)

        c_{t} & = f_{t}c_{t-1} + i_{t} act_c (W_{x_{c}}x_{t} + W_{h_{c}}h_{t-1} + b_{c})

        o_{t} & = act_g(W_{x_{o}}x_{t} + W_{h_{o}}h_{t-1} + b_{o})

        h_{t} & = o_{t} act_c (c_{t})
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    For more details, please refer to `RECURRENT NEURAL NETWORK REGULARIZATION <http://arxiv.org/abs/1409.2329>`_

    Examples:

        .. code-block:: python

            import paddle.fluid.layers as layers
            cell = layers.LSTMCell(hidden_size=256)
    """

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    def __init__(
        self,
        hidden_size,
        param_attr=None,
        bias_attr=None,
        gate_activation=None,
        activation=None,
        forget_bias=1.0,
        dtype="float32",
        name="LSTMCell",
    ):
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        """
        Constructor of LSTMCell.

        Parameters:
            hidden_size (int): The hidden size in the LSTM cell.
            param_attr(ParamAttr, optional): The parameter attribute for the learnable
                weight matrix. Default: None.
            bias_attr (ParamAttr, optional): The parameter attribute for the bias
                of LSTM. Default: None.
            gate_activation (function, optional): The activation function for :math:`act_g`.
                Default: 'fluid.layers.sigmoid'.
            activation (function, optional): The activation function for :math:`act_h`.
                Default: 'fluid.layers.tanh'.
            forget_bias(float, optional): forget bias used when computing forget gate.
                Default 1.0
            dtype(string, optional): The data type used in this cell. Default float32.
            name(string, optional) : The name scope used to identify parameters and biases.
        """
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        check_type(hidden_size, 'hidden_size', (int), 'LSTMCell')
        check_dtype(dtype, 'dtype', ['float32', 'float64'], 'LSTMCell')
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        self.hidden_size = hidden_size
        from .. import contrib  # TODO: resolve recurrent import
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        self.lstm_unit = contrib.layers.rnn_impl.BasicLSTMUnit(
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            name,
            hidden_size,
            param_attr,
            bias_attr,
            gate_activation,
            activation,
            forget_bias,
            dtype,
        )
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    def call(self, inputs, states):
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        r"""
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        Perform calculations of LSTM.

        Parameters:
            inputs(Variable): A tensor with shape `[batch_size, input_size]`,
                corresponding to :math:`x_t` in the formula. The data type
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                should be float32 or float64.
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            states(Variable): A list of containing two tensors, each shaped
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                `[batch_size, hidden_size]`, corresponding to :math:`h_{t-1}, c_{t-1}`
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                in the formula. The data type should be float32 or float64.
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        Returns:
            tuple: A tuple( :code:`(outputs, new_states)` ), where `outputs` is \
                a tensor with shape `[batch_size, hidden_size]`, corresponding \
                to :math:`h_{t}` in the formula; `new_states` is a list containing \
                two tenser variables shaped `[batch_size, hidden_size]`, corresponding \
                to :math:`h_{t}, c_{t}` in the formula. The data type of these \
                tensors all is same as that of `states`.
        """
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        check_variable_and_dtype(
            inputs, 'inputs', ['float32', 'float64'], 'LSTMCell'
        )
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        check_type(states, 'states', list, 'LSTMCell')
        if isinstance(states, list):
            for i, state in enumerate(states):
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                check_variable_and_dtype(
                    state,
                    'state[' + str(i) + ']',
                    ['float32', 'float64'],
                    'LSTMCell',
                )
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        pre_hidden, pre_cell = states
        new_hidden, new_cell = self.lstm_unit(inputs, pre_hidden, pre_cell)
        return new_hidden, [new_hidden, new_cell]

    @property
    def state_shape(self):
        """
        The `state_shape` of LSTMCell is a list with two shapes: `[[hidden_size], [hidden_size]]`
        (-1 for batch size would be automatically inserted into shape). These two
        shapes correspond to :math:`h_{t-1}` and :math:`c_{t-1}` separately.
        """
        return [[self.hidden_size], [self.hidden_size]]


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def rnn(
    cell,
    inputs,
    initial_states=None,
    sequence_length=None,
    time_major=False,
    is_reverse=False,
    **kwargs
):
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    """
    rnn creates a recurrent neural network specified by RNNCell `cell`,
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    which performs :code:`cell.call()` (for dygraph mode :code:`cell.forward`)
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    repeatedly until reaches to the maximum length of `inputs`.

    Arguments:
        cell(RNNCellBase): An instance of `RNNCellBase`.
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        inputs(Tensor): the input sequences.
            If time_major is True, the shape is
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            `[time_steps, batch_size, input_size]`
            else the shape is `[batch_size, time_steps, input_size]`.
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        initial_states(Tensor|tuple|list, optional): the initial state of the
            rnn cell. Tensor or a possibly nested structure of tensors. If not
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            provided, `cell.get_initial_states` would be called to produce
            the initial state. Defaults to None.
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        sequence_length (Tensor, optional): shape `[batch_size]`, dtype: int64
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            or int32. The valid lengths of input sequences. Defaults to None.
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            If `sequence_length` is not None, the inputs are treated as
            padded sequences. In each input sequence, elements whose time step
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            index are not less than the valid length are treated as paddings.
        time_major (bool): Whether the first dimension of the input means the
            time steps. Defaults to False.
        is_reverse (bool, optional): Indicate whether to calculate in the reverse
            order of input sequences. Defaults to False.
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        **kwargs: Additional keyword arguments to pass to `forward` of the cell.
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    Returns:
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        (outputs, final_states)
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        outputs (Tensor|list|tuple): the output sequence. Tensor or nested
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            structure of Tensors.
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            If `time_major` is True, the shape of each tensor in outpus is
            `[time_steps, batch_size, hidden_size]`, else
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            `[batch_size, time_steps, hidden_size]`.
        final_states (Tensor|list|tuple): final states. A (possibly nested structure of)
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            tensor[s], representing the final state for RNN. It has the same
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            structure of intial state. Each tensor in final states has the same
            shape and dtype as the corresponding tensor in initial states.
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    Examples:

        .. code-block:: python

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            import paddle
            paddle.disable_static()

            cell = paddle.nn.SimpleRNNCell(16, 32)

            inputs = paddle.rand((4, 23, 16))
            prev_h = paddle.randn((4, 32))
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            outputs, final_states = paddle.fluid.layers.rnn(cell, inputs, prev_h)
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    """
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    if _non_static_mode():
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        return _rnn_dynamic_graph(
            cell,
            inputs,
            initial_states,
            sequence_length,
            time_major,
            is_reverse,
            **kwargs
        )
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    else:
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        return _rnn_static_graph(
            cell,
            inputs,
            initial_states,
            sequence_length,
            time_major,
            is_reverse,
            **kwargs
        )
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class ArrayWrapper:
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    def __init__(self, x):
        self.array = [x]

    def append(self, x):
        self.array.append(x)
        return self

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    def __getitem__(self, item):
        return self.array.__getitem__(item)

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def _maybe_copy(state, new_state, step_mask):
    """update rnn state or just pass the old state through"""
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    new_state = nn.elementwise_mul(
        new_state, step_mask, axis=0
    ) + nn.elementwise_mul(state, (1 - step_mask), axis=0)
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    return new_state


def _transpose_batch_time(x):
    perm = [1, 0] + list(range(2, len(x.shape)))
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    return paddle.transpose(x, perm)
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def _rnn_dynamic_graph(
    cell,
    inputs,
    initial_states=None,
    sequence_length=None,
    time_major=False,
    is_reverse=False,
    **kwargs
):
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    time_step_index = 0 if time_major else 1
    flat_inputs = flatten(inputs)
    time_steps = flat_inputs[0].shape[time_step_index]

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    if initial_states is None:
        initial_states = cell.get_initial_states(
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            batch_ref=inputs, batch_dim_idx=1 if time_major else 0
        )
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    if not time_major:
        inputs = map_structure(_transpose_batch_time, inputs)

    if sequence_length is not None:
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        mask = sequence_lod.sequence_mask(
            sequence_length, maxlen=time_steps, dtype=inputs.dtype
        )
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        mask = paddle.transpose(mask, [1, 0])
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    if is_reverse:
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        inputs = map_structure(lambda x: paddle.reverse(x, axis=[0]), inputs)
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        mask = (
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            paddle.reverse(mask, axis=[0])
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            if sequence_length is not None
            else None
        )
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    states = initial_states
    outputs = []
    for i in range(time_steps):
        step_inputs = map_structure(lambda x: x[i], inputs)
        step_outputs, new_states = cell(step_inputs, states, **kwargs)
        if sequence_length is not None:
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            new_states = map_structure(
                partial(_maybe_copy, step_mask=mask[i]), states, new_states
            )
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        states = new_states
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        outputs = (
            map_structure(lambda x: ArrayWrapper(x), step_outputs)
            if i == 0
            else map_structure(
                lambda x, x_array: x_array.append(x), step_outputs, outputs
            )
        )
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    final_outputs = map_structure(
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        lambda x: paddle.stack(x.array, axis=time_step_index), outputs
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    )
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    if is_reverse:
        final_outputs = map_structure(
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            lambda x: paddle.reverse(x, axis=time_step_index), final_outputs
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        )
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    final_states = new_states
    return final_outputs, final_states


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def _rnn_static_graph(
    cell,
    inputs,
    initial_states=None,
    sequence_length=None,
    time_major=False,
    is_reverse=False,
    **kwargs
):
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    check_type(inputs, 'inputs', (Variable, list, tuple), 'rnn')
    if isinstance(inputs, (list, tuple)):
        for i, input_x in enumerate(inputs):
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            check_variable_and_dtype(
                input_x, 'inputs[' + str(i) + ']', ['float32', 'float64'], 'rnn'
            )
    check_type(
        initial_states,
        'initial_states',
        (Variable, list, tuple, type(None)),
        'rnn',
    )
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    check_type(
        sequence_length, 'sequence_length', (Variable, type(None)), 'rnn'
    )
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    def _switch_grad(x, stop=False):
        x.stop_gradient = stop
        return x

    if initial_states is None:
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        initial_states = cell.get_initial_states(
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            batch_ref=inputs, batch_dim_idx=1 if time_major else 0
        )
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    initial_states = map_structure(_switch_grad, initial_states)

    if not time_major:
        inputs = map_structure(_transpose_batch_time, inputs)

    if sequence_length:
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        max_seq_len = paddle.shape(flatten(inputs)[0])[0]
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        mask = sequence_lod.sequence_mask(
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            sequence_length,
            maxlen=max_seq_len,
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            dtype=flatten(initial_states)[0].dtype,
        )
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        mask = paddle.transpose(mask, [1, 0])
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    if is_reverse:
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        inputs = map_structure(lambda x: paddle.reverse(x, axis=[0]), inputs)
        mask = paddle.reverse(mask, axis=[0]) if sequence_length else None
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    # StaticRNN
    rnn = control_flow.StaticRNN()
    with rnn.step():
        inputs = map_structure(rnn.step_input, inputs)
        states = map_structure(rnn.memory, initial_states)
        copy_states = map_structure(lambda x: x, states)
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        outputs, new_states = cell(inputs, copy_states, **kwargs)
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        assert_same_structure(states, new_states)
        if sequence_length:
            step_mask = rnn.step_input(mask)
            new_states = map_structure(
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                partial(_maybe_copy, step_mask=step_mask), states, new_states
            )
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        map_structure(rnn.update_memory, states, new_states)
        flat_outputs = flatten(outputs)
        map_structure(rnn.step_output, outputs)
        map_structure(rnn.step_output, new_states)

    rnn_out = rnn()
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    final_outputs = rnn_out[: len(flat_outputs)]
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    final_outputs = pack_sequence_as(outputs, final_outputs)
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    final_states = map_structure(lambda x: x[-1], rnn_out[len(flat_outputs) :])
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    final_states = pack_sequence_as(new_states, final_states)

    if is_reverse:
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        final_outputs = map_structure(
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            lambda x: paddle.reverse(x, axis=[0]), final_outputs
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        )
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    if not time_major:
        final_outputs = map_structure(_transpose_batch_time, final_outputs)

    return (final_outputs, final_states)


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def birnn(
    cell_fw,
    cell_bw,
    inputs,
    initial_states=None,
    sequence_length=None,
    time_major=False,
    **kwargs
):
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    """
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    birnn creates a bidirectional recurrent neural network specified by
    RNNCell `cell_fw` and `cell_bw`, which performs :code:`cell.call()`
    (for dygraph mode :code:`cell.forward`) repeatedly until reaches to
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    the maximum length of `inputs` and then concat the outputs for both RNNs
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    along the last axis.

    Arguments:
        cell_fw(RNNCellBase): An instance of `RNNCellBase`.
        cell_bw(RNNCellBase): An instance of `RNNCellBase`.
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        inputs(Tensor): the input sequences.
            If time_major is True, the shape is
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            `[time_steps, batch_size, input_size]`
            else the shape is `[batch_size, time_steps, input_size]`.
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        initial_states(tuple, optional): A tuple of initial states of
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            `cell_fw` and `cell_bw`.
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            If not provided, `cell.get_initial_states` would be called to
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            produce initial state for each cell. Defaults to None.
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        sequence_length (Tensor, optional): shape `[batch_size]`, dtype: int64
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            or int32. The valid lengths of input sequences. Defaults to None.
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            If `sequence_length` is not None, the inputs are treated as
            padded sequences. In each input sequence, elements whose time step
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            index are not less than the valid length are treated as paddings.
        time_major (bool): Whether the first dimension of the input means the
            time steps. Defaults to False.
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        **kwargs: Additional keyword arguments to pass to `forward` of each cell.
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    Returns:
        (outputs, final_states)
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        outputs (Tensor): the outputs of the bidirectional RNN. It is the
            concatenation of the outputs from the forward RNN and backward
            RNN along the last axis.
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            If time major is True, the shape is `[time_steps, batch_size, size]`,
            else the shape is `[batch_size, time_steps, size]`, where size is
            `cell_fw.hidden_size + cell_bw.hidden_size`.
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        final_states (tuple): A tuple of the final states of the forward
            cell and backward cell.
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    Examples:

        .. code-block:: python
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            import paddle
            paddle.disable_static()

            cell_fw = paddle.nn.LSTMCell(16, 32)
            cell_bw = paddle.nn.LSTMCell(16, 32)

            inputs = paddle.rand((4, 23, 16))
            hf, cf = paddle.rand((4, 32)), paddle.rand((4, 32))
            hb, cb = paddle.rand((4, 32)), paddle.rand((4, 32))
            initial_states = ((hf, cf), (hb, cb))
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            outputs, final_states = paddle.fluid.layers.birnn(
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                cell_fw, cell_bw, inputs, initial_states)
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    """
    if initial_states is None:
        states_fw = cell_fw.get_initial_states(
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            batch_ref=inputs, batch_dim_idx=1 if time_major else 0
        )
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        states_bw = cell_fw.get_initial_states(
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            batch_ref=inputs, batch_dim_idx=1 if time_major else 0
        )
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    else:
        states_fw, states_bw = initial_states
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    outputs_fw, states_fw = rnn(
        cell_fw,
        inputs,
        states_fw,
        sequence_length,
        time_major=time_major,
        **kwargs
    )

    outputs_bw, states_bw = rnn(
        cell_bw,
        inputs,
        states_bw,
        sequence_length,
        time_major=time_major,
        is_reverse=True,
        **kwargs
    )

    outputs = map_structure(
        lambda x, y: tensor.concat([x, y], -1), outputs_fw, outputs_bw
    )
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    final_states = (states_fw, states_bw)
    return outputs, final_states


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class Decoder:
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    """
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        :api_attr: Static Graph
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    Decoder is the base class for any decoder instance used in `dynamic_decode`.
    It provides interface for output generation for one time step, which can be
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    used to generate sequences.
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    The key abstraction provided by Decoder is:

    1. :code:`(initial_input, initial_state, finished) = initialize(inits)` ,
    which generates the input and state for the first decoding step, and gives the
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    initial status telling whether each sequence in the batch is finished.
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    It would be called once before the decoding iterations.

    2. :code:`(output, next_state, next_input, finished) = step(time, input, state)` ,
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    which transforms the input and state to the output and new state, generates
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    input for the next decoding step, and emits the flag indicating finished status.
    It is the main part for each decoding iteration.

    3. :code:`(final_outputs, final_state) = finalize(outputs, final_state, sequence_lengths)` ,
    which revises the outputs(stack of all time steps' output) and final state(state from the
    last decoding step) to get the counterpart for special usage.
    Not necessary to be implemented if no need to revise the stacked outputs and
    state from the last decoding step. If implemented, it would be called after
    the decoding iterations.

    Decoder is more general compared to RNNCell, since the returned `next_input`
    and `finished` make it can determine the input and when to finish by itself
    when used in dynamic decoding. Decoder always wraps a RNNCell instance though
    not necessary.
    """

    def initialize(self, inits):
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        r"""
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        Called once before the decoding iterations.

        Parameters:
            inits: Argument provided by the caller.

        Returns:
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            tuple: A tuple( :code:`(initial_inputs, initial_states, finished)` ). \
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                `initial_inputs` and `initial_states` both are a (possibly nested \
                structure of) tensor variable[s], and `finished` is a tensor with \
                bool data type.
        """
        raise NotImplementedError

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    def step(self, time, inputs, states, **kwargs):
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        r"""
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        Called per step of decoding.
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        Parameters:
            time(Variable): A Tensor with shape :math:`[1]` provided by the caller.
                The data type is int64.
            inputs(Variable): A (possibly nested structure of) tensor variable[s].
            states(Variable): A (possibly nested structure of) tensor variable[s].
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            **kwargs: Additional keyword arguments, provided by the caller.
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        Returns:
            tuple: A tuple( :code:(outputs, next_states, next_inputs, finished)` ). \
                `next_inputs` and `next_states` both are a (possibly nested \
                structure of) tensor variable[s], and the structure, shape and \
                data type must be same as the counterpart from input arguments. \
                `outputs` is a (possibly nested structure of) tensor variable[s]. \
                `finished` is a Tensor with bool data type.
        """
        raise NotImplementedError

    def finalize(self, outputs, final_states, sequence_lengths):
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        r"""
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        Called once after the decoding iterations if implemented.

        Parameters:
            outputs(Variable): A (possibly nested structure of) tensor variable[s].
                The structure and data type is same as `output_dtype`.
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                The tensor stacks all time steps' output thus has shape
                :math:`[time\_step, batch\_size, ...]` , which is done by the caller.
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            final_states(Variable): A (possibly nested structure of) tensor variable[s].
                It is the `next_states` returned by `decoder.step` at last decoding step,
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                thus has the same structure, shape and data type with states at any time
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                step.

        Returns:
            tuple: A tuple( :code:`(final_outputs, final_states)` ). \
                `final_outputs` and `final_states` both are a (possibly nested \
                structure of) tensor variable[s].
        """
        raise NotImplementedError

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    @property
    def tracks_own_finished(self):
        """
        Describes whether the Decoder keeps track of finished states by itself.

        `decoder.step()` would emit a bool `finished` value at each decoding
        step. The emited `finished` can be used to determine whether every
        batch entries is finished directly, or it can be combined with the
        finished tracker keeped in `dynamic_decode` by performing a logical OR
        to take the already finished into account.

        If `False`, the latter would be took when performing `dynamic_decode`,
        which is the default. Otherwise, the former would be took, which uses
        the finished value emited by the decoder as all batch entry finished
        status directly, and it is the case when batch entries might be
        reordered such as beams in BeamSearchDecoder.

        Returns:
            bool: A python bool `False`.
        """
        return False

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class BeamSearchDecoder(Decoder):
    """
    Decoder with beam search decoding strategy. It wraps a cell to get probabilities,
    and follows a beam search step to calculate scores and select candidate
    token ids for each decoding step.

    Please refer to `Beam search <https://en.wikipedia.org/wiki/Beam_search>`_
    for more details.

    **NOTE** When decoding with beam search, the `inputs` and `states` of cell
    would be tiled to `beam_size` (unsqueeze and tile), resulting to shapes like
    `[batch_size * beam_size, ...]` , which is built into `BeamSearchDecoder` and
    done automatically. Thus any other tensor with shape `[batch_size, ...]` used
    in `cell.call` needs to be tiled manually first, which can be completed by using
    :code:`BeamSearchDecoder.tile_beam_merge_with_batch` . The most common case
    for this is the encoder output in attention mechanism.

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    Returns:
        BeamSearchDecoder: An instance of decoder which can be used in \
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            `paddle.nn.dynamic_decode` to implement decoding.
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    Examples:

        .. code-block:: python
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            import numpy as np
            import paddle
            from paddle.nn import BeamSearchDecoder, dynamic_decode
            from paddle.nn import GRUCell, Linear, Embedding
            trg_embeder = Embedding(100, 32)
            output_layer = Linear(32, 32)
            decoder_cell = GRUCell(input_size=32, hidden_size=32)
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            decoder = BeamSearchDecoder(decoder_cell,
                                        start_token=0,
                                        end_token=1,
                                        beam_size=4,
                                        embedding_fn=trg_embeder,
                                        output_fn=output_layer)
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    """

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    def __init__(
        self,
        cell,
        start_token,
        end_token,
        beam_size,
        embedding_fn=None,
        output_fn=None,
    ):
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        """
        Constructor of BeamSearchDecoder.

        Parameters:
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            cell(RNNCellBase): An instance of `RNNCellBase` or object with the same interface.
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            start_token(int): The start token id.
            end_token(int): The end token id.
            beam_size(int): The beam width used in beam search.
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            embedding_fn(optional): A callable to apply to selected candidate ids.
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                Mostly it is an embedding layer to transform ids to embeddings,
                and the returned value acts as the `input` argument for `cell.call`.
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                If not provided, the id to embedding transformation must be built into
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                `cell.call`. Default None.
            output_fn(optional): A callable to apply to the cell's output prior to
                calculate scores and select candidate token ids. Default None.
        """
        self.cell = cell
        self.embedding_fn = embedding_fn
        self.output_fn = output_fn
        self.start_token = start_token
        self.end_token = end_token
        self.beam_size = beam_size

    @staticmethod
    def tile_beam_merge_with_batch(x, beam_size):
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        r"""
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        Tile the batch dimension of a tensor. Specifically, this function takes
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        a tensor t shaped `[batch_size, s0, s1, ...]` composed of minibatch
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        entries `t[0], ..., t[batch_size - 1]` and tiles it to have a shape
        `[batch_size * beam_size, s0, s1, ...]` composed of minibatch entries
        `t[0], t[0], ..., t[1], t[1], ...` where each minibatch entry is repeated
        `beam_size` times.

        Parameters:
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            x(Variable): A tensor with shape `[batch_size, ...]`. The data type
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                should be float32, float64, int32, int64 or bool.
            beam_size(int): The beam width used in beam search.

        Returns:
            Variable: A tensor with shape `[batch_size * beam_size, ...]`, whose \
                data type is same as `x`.
        """
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        check_type(
            x, 'x', (Variable), 'BeamSearchDecoder.tile_beam_merge_with_batch'
        )
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        x = nn.unsqueeze(x, [1])  # [batch_size, 1, ...]
        expand_times = [1] * len(x.shape)
        expand_times[1] = beam_size
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        x = paddle.tile(x, expand_times)  # [batch_size, beam_size, ...]
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        x = paddle.transpose(
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            x, list(range(2, len(x.shape))) + [0, 1]
        )  # [..., batch_size, beam_size]
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        # use 0 to copy to avoid wrong shape
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        x = paddle.reshape(
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            x, shape=[0] * (len(x.shape) - 2) + [-1]
        )  # [..., batch_size * beam_size]
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        x = paddle.transpose(
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            x, [len(x.shape) - 1] + list(range(0, len(x.shape) - 1))
        )  # [batch_size * beam_size, ...]
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        return x

    def _split_batch_beams(self, x):
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        r"""
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        Reshape a tensor with shape `[batch_size * beam_size, ...]` to a new
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        tensor with shape `[batch_size, beam_size, ...]`.
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        Parameters:
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            x(Variable): A tensor with shape `[batch_size * beam_size, ...]`. The
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                data type should be float32, float64, int32, int64 or bool.

        Returns:
            Variable: A tensor with shape `[batch_size, beam_size, ...]`, whose \
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                data type is same as `x`.
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        """
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        check_type(x, 'x', (Variable), 'BeamSearchDecoder._split_batch_beams')
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        # TODO: avoid fake shape in compile-time like tile_beam_merge_with_batch
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        return paddle.reshape(x, shape=[-1, self.beam_size] + list(x.shape[1:]))
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    def _merge_batch_beams(self, x):
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        r"""
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        Reshape a tensor with shape `[batch_size, beam_size, ...]` to a new
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        tensor with shape `[batch_size * beam_size, ...]`.
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        Parameters:
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            x(Variable): A tensor with shape `[batch_size, beam_size, ...]`. The
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                data type should be float32, float64, int32, int64 or bool.

        Returns:
            Variable: A tensor with shape `[batch_size * beam_size, ...]`, whose \
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                data type is same as `x`.
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        """
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        check_type(x, 'x', (Variable), 'BeamSearchDecoder._merge_batch_beams')
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        # TODO: avoid fake shape in compile-time like tile_beam_merge_with_batch
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        return paddle.reshape(x, shape=[-1] + list(x.shape[2:]))
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    def _expand_to_beam_size(self, x):
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        r"""
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        This function takes a tensor t shaped `[batch_size, s0, s1, ...]` composed
        of minibatch entries `t[0], ..., t[batch_size - 1]` and tiles it to have a
        shape `[batch_size, beam_size, s0, s1, ...]` composed of minibatch entries
        `t[0], t[0], ..., t[1], t[1], ...` where each minibatch entry is repeated
        `beam_size` times.

        Parameters:
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            x(Variable): A tensor with shape `[batch_size, ...]`, The data type
                should be float32, float64, int32, int64 or bool.
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        Returns:
            Variable: A tensor with shape `[batch_size, beam_size, ...]`, whose \
                data type is same as `x`.
        """
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        check_type(x, 'x', (Variable), 'BeamSearchDecoder._expand_to_beam_size')
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        x = nn.unsqueeze(x, [1])
        expand_times = [1] * len(x.shape)
        expand_times[1] = self.beam_size
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        x = paddle.tile(x, expand_times)
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        return x

    def _mask_probs(self, probs, finished):
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        r"""
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        Mask log probabilities. It forces finished beams to allocate all probability
        mass to eos and unfinished beams to remain unchanged.

        Parameters:
            probs(Variable): A tensor with shape `[batch_size, beam_size, vocab_size]`,
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                representing the log probabilities. Its data type should be float32 or float64.
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            finished(Variable): A tensor with shape `[batch_size, beam_size]`,
                representing the finished status for all beams. Its data type
                should be bool.

        Returns:
            Variable: A tensor with the same shape and data type as `x`, \
                where unfinished beams stay unchanged and finished beams are \
                replaced with a tensor with all probability on the EOS token.
        """
1122
        check_type(probs, 'probs', (Variable), 'BeamSearchDecoder._mask_probs')
1123 1124 1125
        check_type(
            finished, 'finished', (Variable), 'BeamSearchDecoder._mask_probs'
        )
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        # TODO: use where_op
        finished = tensor.cast(finished, dtype=probs.dtype)
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        probs = paddle.multiply(
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            paddle.tile(nn.unsqueeze(finished, [2]), [1, 1, self.vocab_size]),
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            self.noend_mask_tensor,
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        ) - nn.elementwise_mul(probs, (finished - 1), axis=0)
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        return probs

    def _gather(self, x, indices, batch_size):
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        r"""
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        Gather from the tensor `x` using `indices`.

        Parameters:
            x(Variable): A tensor with shape `[batch_size, beam_size, ...]`.
            indices(Variable): A `int64` tensor with shape `[batch_size, beam_size]`,
                representing the indices that we use to gather.
            batch_size(Variable): A tensor with shape `[1]`. Its data type should
                be int32 or int64.

        Returns:
            Variable: A tensor with the same shape and data type as `x`, \
                representing the gathered tensor.
        """
1149 1150
        check_type(x, 'x', (Variable), 'BeamSearchDecoder._gather')
        check_type(indices, 'indices', (Variable), 'BeamSearchDecoder._gather')
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        check_type(
            batch_size, 'batch_size', (Variable), 'BeamSearchDecoder._gather'
        )
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        # TODO: compatibility of int32 and int64
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        batch_size = (
            tensor.cast(batch_size, indices.dtype)
            if batch_size.dtype != indices.dtype
            else batch_size
        )
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        batch_size.stop_gradient = True  # TODO: remove this
1161
        batch_pos = paddle.tile(
1162
            nn.unsqueeze(
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                paddle.arange(0, batch_size, 1, dtype=indices.dtype), [1]
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            ),
            [1, self.beam_size],
        )
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        topk_coordinates = paddle.stack([batch_pos, indices], axis=2)
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        topk_coordinates.stop_gradient = True
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        return paddle.gather_nd(x, topk_coordinates)
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    class OutputWrapper(
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        collections.namedtuple(
            "OutputWrapper", ("scores", "predicted_ids", "parent_ids")
        )
    ):
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        """
        The structure for the returned value `outputs` of `decoder.step`.
        A namedtuple includes scores, predicted_ids, parent_ids as fields.
        """
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        pass

    class StateWrapper(
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        collections.namedtuple(
            "StateWrapper", ("cell_states", "log_probs", "finished", "lengths")
        )
    ):
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        """
        The structure for the argument `states` of `decoder.step`.
        A namedtuple includes cell_states, log_probs, finished, lengths as fields.
        """
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        pass

    def initialize(self, initial_cell_states):
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        r"""
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        Initialize the BeamSearchDecoder.

        Parameters:
            initial_cell_states(Variable): A (possibly nested structure of)
                tensor variable[s]. An argument provided by the caller.

        Returns:
            tuple: A tuple( :code:`(initial_inputs, initial_states, finished)` ). \
                `initial_inputs` is a tensor t filled by `start_token` with shape \
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                `[batch_size, beam_size]` when `embedding_fn` is None, or the \
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                returned value of `embedding_fn(t)` when `embedding_fn` is provided. \
                `initial_states` is a nested structure(namedtuple including cell_states, \
                log_probs, finished, lengths as fields) of tensor variables, where \
                `log_probs, finished, lengths` all has a tensor value shaped \
                `[batch_size, beam_size]` with data type `float32, bool, int64`. \
                cell_states has a value with the same structure as the input \
                argument `initial_cell_states` but with tiled shape `[batch_size, beam_size, ...]`. \
                `finished` is a `bool` tensor filled by False with shape `[batch_size, beam_size]`.
        """
        self.kinf = 1e9
        state = flatten(initial_cell_states)[0]
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        self.batch_size = paddle.shape(state)[0]
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        self.start_token_tensor = tensor.fill_constant(
            shape=[1], dtype="int64", value=self.start_token
        )
        self.end_token_tensor = tensor.fill_constant(
            shape=[1], dtype="int64", value=self.end_token
        )

        init_cell_states = map_structure(
            self._expand_to_beam_size, initial_cell_states
        )
        init_inputs = paddle.full(
            shape=[self.batch_size, self.beam_size],
            fill_value=self.start_token_tensor,
            dtype=self.start_token_tensor.dtype,
        )
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        log_probs = paddle.tile(
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            tensor.assign(
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                np.array(
                    [[0.0] + [-self.kinf] * (self.beam_size - 1)],
                    dtype="float32",
                )
            ),
            [self.batch_size, 1],
        )
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        if paddle.get_default_dtype() == "float64":
            log_probs = tensor.cast(log_probs, "float64")
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        # TODO: remove the restriction of force_cpu
        init_finished = tensor.fill_constant_batch_size_like(
            input=state,
            shape=[-1, self.beam_size],
            dtype="bool",
            value=False,
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            force_cpu=True,
        )
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        init_lengths = paddle.zeros_like(init_inputs)
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        init_inputs = (
            self.embedding_fn(init_inputs) if self.embedding_fn else init_inputs
        )
        return (
            init_inputs,
            self.StateWrapper(
                init_cell_states, log_probs, init_finished, init_lengths
            ),
            init_finished,
        )
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    def _beam_search_step(self, time, logits, next_cell_states, beam_state):
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        r"""
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        Calculate scores and select candidate token ids.

        Parameters:
            time(Variable): An `int64` tensor with shape `[1]` provided by the caller,
                representing the current time step number of decoding.
            logits(Variable): A tensor with shape `[batch_size, beam_size, vocab_size]`,
                representing the logits at the current time step. Its data type is float32.
            next_cell_states(Variable): A (possibly nested structure of) tensor variable[s].
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                It has the same structure, shape and data type as the `cell_states` of
                `initial_states` returned by `initialize()`. It represents the next state
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                from the cell.
            beam_state(Variable): A structure of tensor variables.
                It is same as the `initial_states` returned by `initialize()` for
                the first decoding step and `beam_search_state` returned by
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                `step()` for the others.
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        Returns:
            tuple: A tuple( :code:`(beam_search_output, beam_search_state)` ). \
                `beam_search_output` is a namedtuple(including scores, predicted_ids, \
                parent_ids as fields) of tensor variables, where \
                `scores, predicted_ids, parent_ids` all has a tensor value shaped \
                `[batch_size, beam_size]` with data type `float32, int64, int64`.
                `beam_search_state` has the same structure, shape and data type \
                as the input argument `beam_state`.

        """
        self.vocab_size = logits.shape[-1]
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        self.vocab_size_tensor = tensor.fill_constant(
            shape=[1], dtype="int64", value=self.vocab_size
        )
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        noend_array = [-self.kinf] * self.vocab_size
        noend_array[self.end_token] = 0
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        self.noend_mask_tensor = tensor.assign(np.array(noend_array, "float32"))
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        if paddle.get_default_dtype() == "float64":
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            self.noend_mask_tensor = tensor.cast(
                self.noend_mask_tensor, "float64"
            )
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        step_log_probs = paddle.log(paddle.nn.functional.softmax(logits))
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        step_log_probs = self._mask_probs(step_log_probs, beam_state.finished)
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        log_probs = nn.elementwise_add(
            x=step_log_probs, y=beam_state.log_probs, axis=0
        )
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        # TODO: length penalty
        scores = log_probs
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        scores = paddle.reshape(scores, [-1, self.beam_size * self.vocab_size])
1315
        # TODO: add grad for topk then this beam search can be used to train
1316
        topk_scores, topk_indices = paddle.topk(x=scores, k=self.beam_size)
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        beam_indices = paddle.floor_divide(topk_indices, self.vocab_size_tensor)
        token_indices = paddle.remainder(topk_indices, self.vocab_size_tensor)
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        next_log_probs = self._gather(
1320
            paddle.reshape(log_probs, [-1, self.beam_size * self.vocab_size]),
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            topk_indices,
            self.batch_size,
        )
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        next_cell_states = map_structure(
            lambda x: self._gather(x, beam_indices, self.batch_size),
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            next_cell_states,
        )
        next_finished = self._gather(
            beam_state.finished, beam_indices, self.batch_size
        )
        next_lengths = self._gather(
            beam_state.lengths, beam_indices, self.batch_size
        )
        next_lengths = next_lengths + tensor.cast(
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            paddle.logical_not(next_finished), beam_state.lengths.dtype
1336
        )
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        next_finished = paddle.logical_or(
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            next_finished,
1339
            paddle.equal(token_indices, self.end_token_tensor),
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        )

        beam_search_output = self.OutputWrapper(
            topk_scores, token_indices, beam_indices
        )
        beam_search_state = self.StateWrapper(
            next_cell_states, next_log_probs, next_finished, next_lengths
        )
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        return beam_search_output, beam_search_state

    def step(self, time, inputs, states, **kwargs):
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        r"""
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        Perform a beam search decoding step, which uses `cell` to get probabilities,
        and follows a beam search step to calculate scores and select candidate
        token ids.

        Parameters:
            time(Variable): An `int64` tensor with shape `[1]` provided by the caller,
                representing the current time step number of decoding.
            inputs(Variable): A tensor variable. It is same as `initial_inputs`
                returned by `initialize()` for the first decoding step and
                `next_inputs` returned by `step()` for the others.
            states(Variable): A structure of tensor variables.
                It is same as the `initial_states` returned by `initialize()` for
                the first decoding step and `beam_search_state` returned by
                `step()` for the others.
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            **kwargs: Additional keyword arguments, provided by the caller.

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        Returns:
            tuple: A tuple( :code:`(beam_search_output, beam_search_state, next_inputs, finished)` ). \
                `beam_search_state` and `next_inputs` have the same structure, \
                shape and data type as the input arguments `states` and `inputs` separately. \
                `beam_search_output` is a namedtuple(including scores, predicted_ids, \
                parent_ids as fields) of tensor variables, where \
                `scores, predicted_ids, parent_ids` all has a tensor value shaped \
                `[batch_size, beam_size]` with data type `float32, int64, int64`. \
                `finished` is a `bool` tensor with shape `[batch_size, beam_size]`.
        """
        inputs = map_structure(self._merge_batch_beams, inputs)
        cell_states = map_structure(self._merge_batch_beams, states.cell_states)
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        cell_outputs, next_cell_states = self.cell(
            inputs, cell_states, **kwargs
        )
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        cell_outputs = map_structure(self._split_batch_beams, cell_outputs)
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        next_cell_states = map_structure(
            self._split_batch_beams, next_cell_states
        )
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        if self.output_fn is not None:
            cell_outputs = self.output_fn(cell_outputs)

        beam_search_output, beam_search_state = self._beam_search_step(
            time=time,
            logits=cell_outputs,
            next_cell_states=next_cell_states,
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            beam_state=states,
        )
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        finished = beam_search_state.finished
        sample_ids = beam_search_output.predicted_ids
1399
        sample_ids.stop_gradient = True
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        next_inputs = (
            self.embedding_fn(sample_ids) if self.embedding_fn else sample_ids
        )
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        return (beam_search_output, beam_search_state, next_inputs, finished)

    def finalize(self, outputs, final_states, sequence_lengths):
1407
        r"""
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        Use `gather_tree` to backtrace along the beam search tree and construct
        the full predicted sequences.

        Parameters:
            outputs(Variable): A structure(namedtuple) of tensor variables,
                The structure and data type is same as `output_dtype`.
1414 1415
                The tensor stacks all time steps' output thus has shape
                `[time_step, batch_size, ...]`, which is done by the caller.
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            final_states(Variable): A structure(namedtuple) of tensor variables.
                It is the `next_states` returned by `decoder.step` at last
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                decoding step, thus has the same structure, shape and data type
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                with states at any time step.
            sequence_lengths(Variable): An `int64` tensor shaped `[batch_size, beam_size]`.
                It contains sequence lengths for each beam determined during
                decoding.

        Returns:
            tuple: A tuple( :code:`(predicted_ids, final_states)` ). \
                `predicted_ids` is an `int64` tensor shaped \
                `[time_step, batch_size, beam_size]`. `final_states` is the same \
                as the input argument `final_states`.
        """
1430
        predicted_ids = paddle.nn.functional.gather_tree(
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            outputs.predicted_ids, outputs.parent_ids
        )
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        # TODO: use FinalBeamSearchDecoderOutput as output
        return predicted_ids, final_states

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    @property
    def tracks_own_finished(self):
        """
        BeamSearchDecoder reorders its beams and their finished state. Thus it
        conflicts with `dynamic_decode` function's tracking of finished states.
        Setting this property to true to avoid early stopping of decoding due
        to mismanagement of the finished state.

        Returns:
            bool: A python bool `True`.
        """
        return True

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def _dynamic_decode_imperative(
    decoder,
    inits=None,
    max_step_num=None,
    output_time_major=False,
    impute_finished=False,
    is_test=False,
    return_length=False,
    **kwargs
):
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    def _maybe_copy(state, new_state, step_mask):
        # TODO: use where_op
        state_dtype = state.dtype
        if convert_dtype(state_dtype) in ["bool"]:
            state = tensor.cast(state, dtype="float32")
            new_state = tensor.cast(new_state, dtype="float32")
        if step_mask.dtype != state.dtype:
            step_mask = tensor.cast(step_mask, dtype=state.dtype)
            # otherwise, renamed bool gradients of would be summed up leading
            # to sum(bool) error.
            step_mask.stop_gradient = True
        new_state = nn.elementwise_mul(
1472 1473
            state, step_mask, axis=0
        ) - nn.elementwise_mul(new_state, (step_mask - 1), axis=0)
1474 1475 1476
        if convert_dtype(state_dtype) in ["bool"]:
            new_state = tensor.cast(new_state, dtype=state_dtype)
        return new_state
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    initial_inputs, initial_states, initial_finished = decoder.initialize(inits)
1479 1480 1481 1482 1483
    inputs, states, finished = (
        initial_inputs,
        initial_states,
        initial_finished,
    )
1484
    cond = paddle.logical_not((paddle.all(initial_finished)))
1485
    sequence_lengths = tensor.cast(paddle.zeros_like(initial_finished), "int64")
1486 1487 1488
    outputs = None

    step_idx = 0
1489 1490 1491
    step_idx_tensor = tensor.fill_constant(
        shape=[1], dtype="int64", value=step_idx
    )
1492
    while cond.numpy():
1493 1494 1495
        (step_outputs, next_states, next_inputs, next_finished) = decoder.step(
            step_idx_tensor, inputs, states, **kwargs
        )
1496 1497 1498 1499 1500
        if not decoder.tracks_own_finished:
            # BeamSearchDecoder would track it own finished, since
            # beams would be reordered and the finished status of each
            # entry might change. Otherwise, perform logical OR which
            # would not change the already finished.
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            next_finished = paddle.logical_or(next_finished, finished)
1502 1503 1504
            # To confirm states.finished/finished be consistent with
            # next_finished.
            tensor.assign(next_finished, finished)
1505
            next_sequence_lengths = paddle.add(
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                sequence_lengths,
1507
                tensor.cast(
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                    paddle.logical_not(finished), sequence_lengths.dtype
1509 1510
                ),
            )
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            if impute_finished:  # rectify the states for the finished.
                next_states = map_structure(
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                    lambda x, y: _maybe_copy(x, y, finished),
                    states,
                    next_states,
                )
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        else:
            warnings.warn(
                "`next_states` has no `lengths` attribute, the returned `sequence_lengths` would be all zeros."
            ) if not hasattr(next_states, "lengths") else None
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            next_sequence_lengths = getattr(
                next_states, "lengths", sequence_lengths
            )

        outputs = (
            map_structure(lambda x: ArrayWrapper(x), step_outputs)
            if step_idx == 0
            else map_structure(
                lambda x, x_array: x_array.append(x), step_outputs, outputs
            )
        )
        inputs, states, finished, sequence_lengths = (
            next_inputs,
            next_states,
            next_finished,
            next_sequence_lengths,
        )
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        control_flow.increment(x=step_idx_tensor, value=1.0, in_place=True)
        step_idx += 1
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1542
        cond = paddle.logical_not(paddle.all(finished))
1543 1544
        if max_step_num is not None and step_idx > max_step_num:
            break
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    final_outputs = map_structure(
        lambda x: paddle.stack(x.array, axis=0), outputs
    )
1549
    final_states = states
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1551
    try:
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        final_outputs, final_states = decoder.finalize(
            final_outputs, final_states, sequence_lengths
        )
1555 1556
    except NotImplementedError:
        pass
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1558 1559
    if not output_time_major:
        final_outputs = map_structure(
1560 1561 1562
            lambda x: paddle.transpose(
                x, [1, 0] + list(range(2, len(x.shape)))
            ),
1563 1564
            final_outputs,
        )
1565

1566 1567 1568 1569 1570
    return (
        (final_outputs, final_states, sequence_lengths)
        if return_length
        else (final_outputs, final_states)
    )
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1573 1574 1575 1576 1577 1578 1579 1580 1581 1582
def _dynamic_decode_declarative(
    decoder,
    inits=None,
    max_step_num=None,
    output_time_major=False,
    impute_finished=False,
    is_test=False,
    return_length=False,
    **kwargs
):
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    initial_inputs, initial_states, initial_finished = decoder.initialize(inits)
1584 1585 1586 1587 1588
    global_inputs, global_states, global_finished = (
        initial_inputs,
        initial_states,
        initial_finished,
    )
1589
    global_finished.stop_gradient = True
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    step_idx = tensor.fill_constant(shape=[1], dtype="int64", value=0)
1591

1592
    cond = paddle.logical_not((paddle.all(initial_finished)))
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    if max_step_num is not None:
1594 1595 1596
        max_step_num = tensor.fill_constant(
            shape=[1], dtype="int64", value=max_step_num
        )
1597
    while_op = control_flow.While(cond, is_test=is_test)
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1599
    sequence_lengths = tensor.cast(paddle.zeros_like(initial_finished), "int64")
1600 1601 1602 1603 1604 1605 1606 1607 1608
    sequence_lengths.stop_gradient = True

    if is_test:
        # for test, reuse inputs and states variables to save memory
        inputs = map_structure(lambda x: x, initial_inputs)
        states = map_structure(lambda x: x, initial_states)
    else:
        # inputs and states of all steps must be saved for backward and training
        inputs_arrays = map_structure(
1609 1610
            lambda x: control_flow.array_write(x, step_idx), initial_inputs
        )
1611
        states_arrays = map_structure(
1612 1613
            lambda x: control_flow.array_write(x, step_idx), initial_states
        )
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    def _maybe_copy(state, new_state, step_mask):
        # TODO: use where_op
1617 1618 1619 1620 1621 1622 1623 1624 1625
        state_dtype = state.dtype
        if convert_dtype(state_dtype) in ["bool"]:
            state = tensor.cast(state, dtype="float32")
            new_state = tensor.cast(new_state, dtype="float32")
        if step_mask.dtype != state.dtype:
            step_mask = tensor.cast(step_mask, dtype=state.dtype)
            # otherwise, renamed bool gradients of would be summed up leading
            # to sum(bool) error.
            step_mask.stop_gradient = True
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        new_state = nn.elementwise_mul(
1627 1628
            state, step_mask, axis=0
        ) - nn.elementwise_mul(new_state, (step_mask - 1), axis=0)
1629 1630
        if convert_dtype(state_dtype) in ["bool"]:
            new_state = tensor.cast(new_state, dtype=state_dtype)
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        return new_state

    def _transpose_batch_time(x):
1634
        return paddle.transpose(x, [1, 0] + list(range(2, len(x.shape))))
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1636 1637
    def _create_array_out_of_while(dtype):
        current_block_idx = default_main_program().current_block_idx
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        default_main_program().current_block_idx = (
            default_main_program().current_block().parent_idx
        )
1641
        tensor_array = paddle.tensor.create_array(dtype)
1642 1643 1644
        default_main_program().current_block_idx = current_block_idx
        return tensor_array

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    # While
    with while_op.block():
1647 1648 1649
        if not is_test:
            inputs = map_structure(
                lambda array: control_flow.array_read(array, step_idx),
1650 1651
                inputs_arrays,
            )
1652 1653
            states = map_structure(
                lambda array: control_flow.array_read(array, step_idx),
1654 1655 1656 1657 1658
                states_arrays,
            )
        (outputs, next_states, next_inputs, next_finished) = decoder.step(
            step_idx, inputs, states, **kwargs
        )
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        if not decoder.tracks_own_finished:
            # BeamSearchDecoder would track it own finished, since beams would
            # be reordered and the finished status of each entry might change.
            # Otherwise, perform logical OR which would not change the already
            # finished.
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            next_finished = paddle.logical_or(next_finished, global_finished)
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            next_sequence_lengths = paddle.add(
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                sequence_lengths,
1667
                tensor.cast(
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                    paddle.logical_not(global_finished),
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                    sequence_lengths.dtype,
                ),
            )
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            if impute_finished:  # rectify the states for the finished.
                next_states = map_structure(
                    lambda x, y: _maybe_copy(x, y, global_finished),
                    states,
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                    next_states,
                )
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        else:
            warnings.warn(
                "`next_states` has no `lengths` attribute, the returned `sequence_lengths` would be all zeros."
            ) if not hasattr(next_states, "lengths") else None
1682 1683 1684
            next_sequence_lengths = getattr(
                next_states, "lengths", sequence_lengths
            )
1685 1686 1687

        # create tensor array in global block after dtype[s] of outputs can be got
        outputs_arrays = map_structure(
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            lambda x: _create_array_out_of_while(x.dtype), outputs
        )
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        map_structure(
            lambda x, x_array: control_flow.array_write(
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                x, i=step_idx, array=x_array
            ),
            outputs,
            outputs_arrays,
        )
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        control_flow.increment(x=step_idx, value=1.0, in_place=True)
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        # update the global_finished first, since it might be also in states of
        # decoder, which otherwise would write a stale finished status to array
        tensor.assign(next_finished, global_finished)
        tensor.assign(next_sequence_lengths, sequence_lengths)
1703 1704 1705 1706 1707 1708
        if is_test:
            map_structure(tensor.assign, next_inputs, global_inputs)
            map_structure(tensor.assign, next_states, global_states)
        else:
            map_structure(
                lambda x, x_array: control_flow.array_write(
1709 1710 1711 1712 1713
                    x, i=step_idx, array=x_array
                ),
                next_inputs,
                inputs_arrays,
            )
1714 1715
            map_structure(
                lambda x, x_array: control_flow.array_write(
1716 1717 1718 1719 1720
                    x, i=step_idx, array=x_array
                ),
                next_states,
                states_arrays,
            )
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        if max_step_num is not None:
1722
            paddle.logical_and(
1723
                paddle.logical_not(paddle.all(global_finished)),
1724
                paddle.less_equal(step_idx, max_step_num),
1725 1726
                cond,
            )
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        else:
1728
            paddle.logical_not(paddle.all(global_finished), cond)
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    final_outputs = map_structure(
        lambda array: tensor.tensor_array_to_tensor(
1732 1733 1734 1735
            array, axis=0, use_stack=True
        )[0],
        outputs_arrays,
    )
1736 1737 1738 1739 1740
    if is_test:
        final_states = global_states
    else:
        final_states = map_structure(
            lambda array: control_flow.array_read(array, step_idx),
1741 1742
            states_arrays,
        )
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    try:
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        final_outputs, final_states = decoder.finalize(
            final_outputs, final_states, sequence_lengths
        )
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    except NotImplementedError:
        pass

    if not output_time_major:
        final_outputs = map_structure(_transpose_batch_time, final_outputs)

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    return (
        (final_outputs, final_states, sequence_lengths)
        if return_length
        else (final_outputs, final_states)
    )
1759 1760


1761 1762 1763 1764 1765 1766 1767 1768 1769 1770
def dynamic_decode(
    decoder,
    inits=None,
    max_step_num=None,
    output_time_major=False,
    impute_finished=False,
    is_test=False,
    return_length=False,
    **kwargs
):
1771
    r"""
1772 1773 1774 1775 1776 1777 1778 1779 1780 1781
    Dynamic decoding performs :code:`decoder.step()` repeatedly until the returned
    Tensor indicating finished status contains all True values or the number of
    decoding step reaches to :attr:`max_step_num`.

    :code:`decoder.initialize()` would be called once before the decoding loop.
    If the `decoder` has implemented `finalize` method, :code:`decoder.finalize()`
    would be called once after the decoding loop.

    Parameters:
        decoder(Decoder): An instance of `Decoder`.
1782
        inits(object, optional): Argument passed to `decoder.initialize`.
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            Default `None`.
        max_step_num(int, optional): The maximum number of steps. If not provided,
            decode until the decoder is fully done, or in other words, the returned
            Tensor by :code:`decoder.step()` indicating finished status contains
            all True. Default `None`.
        output_time_major(bool, optional): Indicate the data layout of Tensor included
            in the final outputs(the first returned value of this method). If
            attr:`False`, the data layout would be batch major with shape
            `[batch_size, seq_len, ...]`.  If attr:`True`, the data layout would
            be time major with shape `[seq_len, batch_size, ...]`. Default: `False`.
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        impute_finished(bool, optional): If `True` and `decoder.tracks_own_finished`
            is False, then states get copied through for batch entries which are
            marked as finished, which differs with the unfinished using the new states
            returned by :code:`decoder.step()` and ensures that the final states have
            the correct values. Otherwise, states wouldn't be copied through when
            finished. If the returned `final_states` is needed, it should be set as
            True, which causes some slowdown. Default `False`.
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        is_test(bool, optional): A flag indicating whether to use test mode. In
            test mode, it is more memory saving. Default `False`.
        return_length(bool, optional):  A flag indicating whether to return an
            extra Tensor variable in the output tuple, which stores the actual
            lengths of all decoded sequences. Default `False`.
1805
        **kwargs: Additional keyword arguments. Arguments passed to `decoder.step`.
1806 1807

    Returns:
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        - final_outputs (Tensor, nested structure of Tensor), each Tensor in :code:`final_outputs` is the stacked of all decoding steps' outputs, which might be revised
            by :code:`decoder.finalize()` if the decoder has implemented finalize.
            And :code:`final_outputs` has the same structure and data types as the :code:`outputs`
            returned by :code:`decoder.step()`

        - final_states (Tensor, nested structure of Tensor), :code:`final_states` is the counterpart at last time step of initial states \
            returned by :code:`decoder.initialize()` , thus has the same structure
            with it and has tensors with same shapes and data types.

        - sequence_lengths (Tensor), stores the actual lengths of all decoded sequences.
            sequence_lengths is provided only if :code:`return_length` is True.
1820 1821 1822 1823

    Examples:

        .. code-block:: python
1824

1825 1826 1827 1828 1829 1830 1831 1832 1833 1834 1835 1836 1837 1838 1839 1840 1841
            import paddle
            from paddle.nn import BeamSearchDecoder, dynamic_decode
            from paddle.nn import GRUCell, Linear, Embedding
            trg_embeder = Embedding(100, 32)
            output_layer = Linear(32, 32)
            decoder_cell = GRUCell(input_size=32, hidden_size=32)
            decoder = BeamSearchDecoder(decoder_cell,
                                        start_token=0,
                                        end_token=1,
                                        beam_size=4,
                                        embedding_fn=trg_embeder,
                                        output_fn=output_layer)
            encoder_output = paddle.ones((4, 8, 32), dtype=paddle.get_default_dtype())
            outputs = dynamic_decode(decoder=decoder,
                                    inits=decoder_cell.get_initial_states(encoder_output),
                                    max_step_num=10)
    """
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    if _non_static_mode():
1843 1844 1845 1846 1847 1848 1849 1850 1851 1852
        return _dynamic_decode_imperative(
            decoder,
            inits,
            max_step_num,
            output_time_major,
            impute_finished,
            is_test,
            return_length,
            **kwargs
        )
1853
    else:
1854 1855 1856 1857 1858 1859 1860 1861 1862 1863
        return _dynamic_decode_declarative(
            decoder,
            inits,
            max_step_num,
            output_time_major,
            impute_finished,
            is_test,
            return_length,
            **kwargs
        )
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1866
class DecodeHelper:
1867 1868 1869 1870 1871 1872 1873
    """
    DecodeHelper is the base class for any helper instance used in `BasicDecoder`.
    It provides interface to implement sampling and produce inputs for the next
    time step in dynamic decoding.
    """

    def initialize(self):
1874
        r"""
1875 1876 1877 1878 1879 1880 1881 1882 1883 1884 1885 1886 1887 1888 1889 1890 1891 1892 1893 1894 1895 1896 1897 1898 1899 1900 1901 1902 1903 1904 1905 1906 1907
        DecodeHelper initialization to produce inputs for the first decoding step
        and give the initial status telling whether each sequence in the batch
        is finished. It is the partial of the initialization of `BasicDecoder`.

        Returns:
            tuple: A tuple( :code:`(initial_inputs, initial_finished)` ). \
                `initial_inputs` is a (possibly nested structure of) tensor \
                variable[s], and the tensor's shape is `[batch_size, ...]`. \
                `initial_finished` is a bool tensor with shape `[batch_size]`.
        """
        pass

    def sample(self, time, outputs, states):
        """
        Perform sampling with some strategies according to `outputs`. It is the
        partial of `BasicDecoder.step`.

        Parameters:
            time(Variable): An `int64` tensor with shape `[1]` provided by the caller,
                representing the current time step number of decoding.
            outputs(Variable): A tensor variable. Usually it's data type is float32
                or float64, and it's shape is `[batch_size, vocabulary_size]`,
                representing the predicted logits of current step. It is same as
                `outputs` returned by `BasicDecoder.output_fn(BasicDecoder.cell.call())`.
            states(Variable): A (possibly nested structure of) tensor variable[s].
                It is same as `new_states` returned by `BasicDecoder.cell.call()`.

        Returns:
            Variable: An `int64` tensor representing the sampled ids.
        """
        pass

    def next_inputs(self, time, outputs, states, sample_ids):
1908
        r"""
1909 1910 1911 1912 1913 1914 1915 1916 1917 1918 1919 1920 1921 1922 1923 1924 1925 1926 1927 1928 1929 1930 1931 1932 1933 1934 1935 1936 1937 1938 1939 1940 1941 1942 1943 1944 1945
        Produce the inputs and states for next time step and give status telling
        whether each minibatch entry is finished. It is called after `sample` in
        `BasicDecoder.step`. It is the partial of `BasicDecoder.step`.

        Parameters:
            time(Variable): An `int64` tensor with shape `[1]` provided by the caller,
                representing the current time step number of decoding.
            outputs(Variable): A tensor variable. Usually it's data type is float32
                or float64, and it's shape is `[batch_size, vocabulary_size]`,
                representing the predicted logits of current step. It is same as
                `outputs` returned by `BasicDecoder.output_fn(BasicDecoder.cell.call())`.
            states(Variable): A (possibly nested structure of) tensor variable[s].
                It is same as `new_states` returned by `BasicDecoder.cell.call()`.
            sample_ids(Variable): A (possibly nested structure of) tensor variable[s].
                It is same as `sample_ids` returned by `sample()`.

        Returns:
            tuple: A tuple( :code:`(finished, next_inputs, next_states)` ). \
                `next_inputs` and `next_states` both are a (possibly nested \
                structure of) tensor variable[s], and the structure, shape and \
                data type of `next_states` must be same as the input argument \
                `states`. `finished` is a bool tensor with shape `[batch_size]`.
        """
        pass


class TrainingHelper(DecodeHelper):
    """
    TrainingHelper is a subclass of DecodeHelper. It is a decoding helper
    slicing from the full sequence inputs as the inputs for corresponding
    step. And it uses `argmax` to sample from the outputs of `cell.call()`.

    Since the needs of sequence inputs, it is used mostly for teach-forcing MLE
    (maximum likelihood) training, and the sampled would not be used.

    Examples:
        .. code-block:: python
1946

1947 1948 1949 1950 1951 1952 1953 1954 1955 1956 1957 1958 1959 1960 1961 1962 1963 1964 1965 1966 1967 1968
            import paddle.fluid as fluid
            import paddle.fluid.layers as layers
            trg_emb = fluid.data(name="trg_emb",
                                 shape=[None, None, 128],
                                 dtype="float32")
            trg_seq_length = fluid.data(name="trg_seq_length",
                                        shape=[None],
                                        dtype="int64")
            helper = layers.TrainingHelper(trg_emb, trg_seq_length)
            decoder_cell = layers.GRUCell(hidden_size=128)
            decoder = layers.BasicDecoder(decoder_cell, helper)
            outputs = layers.dynamic_decode(
                decoder,
                inits=decoder_cell.get_initial_states(trg_emb),
                is_test=False)
    """

    def __init__(self, inputs, sequence_length, time_major=False):
        """
        Constructor of TrainingHelper.

        Parameters:
1969
            inputs(Variable): A (possibly nested structure of) tensor variable[s].
1970 1971 1972 1973 1974 1975 1976 1977 1978 1979 1980 1981 1982 1983 1984 1985 1986 1987 1988 1989
                The shape of tensor should be `[batch_size, sequence_length, ...]`
                for `time_major == False` or `[sequence_length, batch_size, ...]`
                for `time_major == True`. It represents the inputs to be sliced
                from at every decoding step.
            sequence_length(Variable): A tensor with shape `[batch_size]`.
                It stores real length of each instance in `inputs`, by which we
                can label the finished status of each instance at every decoding
                step.
            time_major(bool, optional): Indicate the data layout of Tensor included
                in `inputs`. If `False`, the data layout would be batch major with
                shape `[batch_size, sequence_length, ...]`.  If `True`, the data
                layout would be time major with shape `[sequence_length, batch_size, ...]`.
                Default: `False`.
        """
        self.inputs = inputs
        self.sequence_length = sequence_length
        self.time_major = time_major
        # extend inputs to avoid to slice out of range in `next_inputs`
        # may be easier and have better performance than condition_op
        self.inputs_ = map_structure(
1990
            lambda x: paddle.nn.functional.pad(
1991
                x,
1992
                pad=([0, 1] + [0, 0] * (len(x.shape) - 1))
1993 1994 1995 1996 1997
                if time_major
                else ([0, 0, 0, 1] + [0, 0] * (len(x.shape) - 2)),
            ),
            self.inputs,
        )
1998 1999

    def initialize(self):
2000
        r"""
2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011
        TrainingHelper initialization produces inputs for the first decoding
        step by slicing at the first time step of full sequence inputs, and it
        gives initial status telling whether each sequence in the batch is
        finished. It is the partial of the initialization of `BasicDecoder`.

        Returns:
            tuple: A tuple( :code:`(initial_inputs, initial_finished)` ). \
                `initial_inputs` is a (possibly nested structure of) tensor \
                variable[s], and the tensor's shape is `[batch_size, ...]`. \
                `initial_finished` is a bool tensor with shape `[batch_size]`.
        """
2012
        init_finished = paddle.equal(
2013
            self.sequence_length,
2014 2015 2016 2017
            tensor.fill_constant(
                shape=[1], dtype=self.sequence_length.dtype, value=0
            ),
        )
2018 2019
        # TODO: support zero length
        init_inputs = map_structure(
2020 2021
            lambda x: x[0] if self.time_major else x[:, 0], self.inputs
        )
2022 2023 2024
        return init_inputs, init_finished

    def sample(self, time, outputs, states):
2025
        r"""
2026 2027 2028 2029 2030 2031 2032 2033 2034 2035
        Perform sampling by using `argmax` according to the `outputs`. Mostly
        the sampled ids would not be used since the inputs for next decoding
        step would be got by slicing.

        Parameters:
            time(Variable): An `int64` tensor with shape `[1]` provided by the
                caller, representing the current time step number of decoding.
            outputs(Variable): A tensor variable. Usually it's data type is float32
                or float64, and it's shape is `[batch_size, vocabulary_size]`,
                representing the predicted logits of current step. It is same as
2036
                `outputs` returned by `BasicDecoder.output_fn(BasicDecoder.cell.call())`.
2037 2038 2039 2040 2041 2042 2043 2044 2045 2046 2047
            states(Variable): A (possibly nested structure of) tensor variable[s].
                It is same as `new_states` returned by `BasicDecoder.cell.call()`.

        Returns:
            Variable: An `int64` tensor with shape `[batch_size]`, representing \
                the sampled ids.
        """
        sample_ids = tensor.argmax(outputs, axis=-1)
        return sample_ids

    def next_inputs(self, time, outputs, states, sample_ids):
2048
        r"""
2049 2050 2051 2052 2053 2054 2055 2056 2057 2058 2059 2060 2061 2062 2063 2064 2065 2066 2067 2068 2069 2070 2071 2072 2073 2074
        Generate inputs for the next decoding step by slicing at corresponding
        step of the full sequence inputs. Simultaneously, produce the states
        for next time step by directly using the input `states` and emit status
        telling whether each minibatch entry reaches to the corresponding length.

        Parameters:
            time(Variable): An `int64` tensor with shape `[1]` provided by the
                caller, representing the current time step number of decoding.
            outputs(Variable): A tensor variable. Usually it's data type is float32
                or float64, and it's shape is `[batch_size, vocabulary_size]`,
                representing the predicted logits of current step. It is same as
                `outputs` returned by `BasicDecoder.output_fn(BasicDecoder.cell.call())`.
            states(Variable): A (possibly nested structure of) tensor variable[s].
                It is same as `new_states` returned by `BasicDecoder.cell.call()`.
            sample_ids(Variable): An `int64` tensor variable shaped `[batch_size]`.
                It is same as `sample_ids` returned by `sample()`.

        Returns:
            tuple: A tuple( :code:`(finished, next_inputs, next_states)` ). \
                `next_inputs` and `next_states` both are a (possibly nested \
                structure of) tensor variable[s],  and the tensor's shape is \
                `[batch_size, ...]`. `next_states` is identical to the input \
                argument `states`. `finished` is a `bool` Tensor with \
                shape `[batch_size]`.
        """
        # TODO: compatibility of int32 and int64
2075 2076 2077 2078 2079
        time = (
            tensor.cast(time, "int32")
            if convert_dtype(time.dtype) not in ["int32"]
            else time
        )
2080 2081 2082
        if self.sequence_length.dtype != time.dtype:
            self.sequence_length = tensor.cast(self.sequence_length, time.dtype)
        next_time = time + 1
2083
        finished = paddle.less_equal(self.sequence_length, next_time)
2084 2085 2086

        def _slice(x):  # TODO: use Variable.__getitem__
            axes = [0 if self.time_major else 1]
2087
            return paddle.squeeze(
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                paddle.slice(
2089 2090
                    x, axes=axes, starts=[next_time], ends=[next_time + 1]
                ),
2091
                axis=axes,
2092
            )
2093 2094 2095 2096 2097 2098 2099 2100 2101 2102 2103 2104 2105

        next_inputs = map_structure(_slice, self.inputs_)
        return finished, next_inputs, states


class GreedyEmbeddingHelper(DecodeHelper):
    """
    GreedyEmbeddingHelper is a subclass of DecodeHelper. It is a decoding helper
    uses the argmax of the output (treated as logits) and passes the results
    through an embedding layer to get inputs for the next decoding step.

    Examples:
        .. code-block:: python
2106

2107 2108 2109 2110 2111
            import paddle.fluid as fluid
            import paddle.fluid.layers as layers
            trg_emb = fluid.data(name="trg_emb",
                                 shape=[None, None, 128],
                                 dtype="float32")
2112

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            trg_embeder = lambda x: fluid.embedding(
                x, size=[10000, 128], param_attr=fluid.ParamAttr(name="trg_embedding"))
            output_layer = lambda x: layers.fc(x,
                                            size=10000,
                                            num_flatten_dims=len(x.shape) - 1,
                                            param_attr=fluid.ParamAttr(name=
                                                                    "output_w"),
                                            bias_attr=False)
            helper = layers.GreedyEmbeddingHelper(trg_embeder, start_tokens=0, end_token=1)
            decoder_cell = layers.GRUCell(hidden_size=128)
            decoder = layers.BasicDecoder(decoder_cell, helper, output_fn=output_layer)
            outputs = layers.dynamic_decode(
                decoder=decoder, inits=decoder_cell.get_initial_states(encoder_output))
    """

    def __init__(self, embedding_fn, start_tokens, end_token):
2129
        r"""
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        Constructor of GreedyEmbeddingHelper.

        Parameters:
2133
            embedding_fn(callable): A functor to apply on the argmax results.
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                Mostly it is an embedding layer to transform ids to embeddings.
                **Note that fluid.embedding should be used here rather than
                fluid.layers.embedding, since shape of ids is [batch_size].
                when using fluid.layers.embedding, must unsqueeze in embedding_fn.**
            start_tokens(Variable):  A `int64` tensor shaped `[batch_size]`,
                representing the start tokens.
            end_token(int): The end token id.

        Returns:
            tuple: A tuple( :code:`(initial_inputs, initial_states, finished)` ). \
                `initial_inputs` and `initial_states` both are a (possibly nested \
                structure of) tensor variable[s], and `finished` is a tensor with \
                bool data type.
        """
        self.embedding_fn = embedding_fn
        self.start_tokens = start_tokens
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        self.end_token = tensor.fill_constant(
            shape=[1], dtype="int64", value=end_token
        )
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    def initialize(self):
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        r"""
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        GreedyEmbeddingHelper initialization produces inputs for the first decoding
        step by using `start_tokens` of the constructor, and gives initial
2158
        status telling whether each sequence in the batch is finished.
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        It is the partial of the initialization of `BasicDecoder`.

        Returns:
            tuple: A tuple( :code:`(initial_inputs, initial_finished)` ). \
                `initial_inputs` is same as `start_tokens` of the constructor. \
                `initial_finished` is a `bool` tensor filled by False and has \
                the same shape as `start_tokens`.
        """
        # TODO: remove the restriction of force_cpu
        init_finished = tensor.fill_constant_batch_size_like(
            input=self.start_tokens,
            shape=[-1],
            dtype="bool",
            value=False,
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            force_cpu=True,
        )
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        init_inputs = self.embedding_fn(self.start_tokens)
        return init_inputs, init_finished

    def sample(self, time, outputs, states):
2179
        r"""
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        Perform sampling by using `argmax` according to the `outputs`.

        Parameters:
            time(Variable): An `int64` tensor with shape `[1]` provided by the
                caller, representing the current time step number of decoding.
            outputs(Variable): A tensor variable. Usually it's data type is float32
                or float64, and it's shape is `[batch_size, vocabulary_size]`,
                representing the predicted logits of current step. It is same as
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                `outputs` returned by `BasicDecoder.output_fn(BasicDecoder.cell.call())`.
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            states(Variable): A (possibly nested structure of) tensor variable[s].
                It is same as `new_states` returned by `BasicDecoder.cell.call()`.

        Returns:
            Variable: An `int64` tensor with shape `[batch_size]`, representing \
                the sampled ids.
        """
        sample_ids = tensor.argmax(outputs, axis=-1)
        return sample_ids

    def next_inputs(self, time, outputs, states, sample_ids):
2200
        r"""
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        Generate inputs for the next decoding step by applying `embedding_fn`
        to `sample_ids`. Simultaneously, produce the states for next time step
        by directly using the input `states` and emit status telling whether
        each minibatch entry gets an `end_token` sample.

        Parameters:
            time(Variable): An `int64` tensor with shape `[1]` provided by the
                caller, representing the current time step number of decoding.
            outputs(Variable): A tensor variable. Usually it's data type is float32
                or float64, and it's shape is `[batch_size, vocabulary_size]`,
                representing the predicted logits of current step. It is same as
                `outputs` returned by `BasicDecoder.output_fn(BasicDecoder.cell.call())`.
            states(Variable): A (possibly nested structure of) tensor variable[s].
                It is same as `new_states` returned by `BasicDecoder.cell.call()`.
            sample_ids(Variable): An `int64` tensor variable shaped `[batch_size]`.
                It is same as `sample_ids` returned by `sample()`.

        Returns:
            tuple: A tuple( :code:`(finished, next_inputs, next_states)` ). \
                `next_inputs` and `next_states` both are a (possibly nested \
                structure of) tensor variable[s],  and the tensor's shape is \
                `[batch_size, ...]`. `next_states` is identical to the input \
                argument `states`. `finished` is a `bool` Tensor with \
                shape `[batch_size]`.
        """
2226
        finished = paddle.equal(sample_ids, self.end_token)
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        next_inputs = self.embedding_fn(sample_ids)
        return finished, next_inputs, states


class SampleEmbeddingHelper(GreedyEmbeddingHelper):
    """
    SampleEmbeddingHelper is a subclass of GreedyEmbeddingHelper. It is a decoding
    helper uses sampling (from a distribution) instead of argmax of the output
    (treated as logits) and passes the results through an embedding layer to get
    inputs for the next decoding step.

    Examples:
        .. code-block:: python
2240

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            import paddle.fluid as fluid
            import paddle.fluid.layers as layers
            trg_emb = fluid.data(name="trg_emb",
                                 shape=[None, None, 128],
                                 dtype="float32")
2246

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            trg_embeder = lambda x: fluid.embedding(
                x, size=[10000, 128], param_attr=fluid.ParamAttr(name="trg_embedding"))
            output_layer = lambda x: layers.fc(x,
                                            size=10000,
                                            num_flatten_dims=len(x.shape) - 1,
                                            param_attr=fluid.ParamAttr(name=
                                                                    "output_w"),
                                            bias_attr=False)
            helper = layers.SampleEmbeddingHelper(trg_embeder, start_tokens=0, end_token=1)
            decoder_cell = layers.GRUCell(hidden_size=128)
            decoder = layers.BasicDecoder(decoder_cell, helper, output_fn=output_layer)
            outputs = layers.dynamic_decode(
                decoder=decoder, inits=decoder_cell.get_initial_states(encoder_output))
    """

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    def __init__(
        self,
        embedding_fn,
        start_tokens,
        end_token,
        softmax_temperature=None,
        seed=None,
    ):
2270
        r"""
2271 2272 2273
        Constructor of SampleEmbeddingHelper.

        Parameters:
2274
            embedding_fn(callable): A functor to apply on the argmax results.
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                Mostly it is an embedding layer to transform ids to embeddings.
                **Note that fluid.embedding should be used here rather than
                fluid.layers.embedding, since shape of ids is [batch_size].
                when using fluid.layers.embedding, must unsqueeze in embedding_fn.**
            start_tokens(Variable):  A `int64` tensor shaped `[batch_size]`,
                representing the start tokens.
            end_token(int): The end token id.
            softmax_temperature(float, optional): the value to divide the logits
                by before computing the softmax. Higher temperatures (above 1.0)
                lead to more random, while lower temperatures push the sampling
                distribution towards the argmax. It must be strictly greater than
                0. Defaults to None, meaning using a temperature valued 1.0.
            seed: (int, optional) The sampling seed. Defaults to None, meaning not
                to use fixed seed.

        Returns:
            tuple: A tuple( :code:`(initial_inputs, initial_states, finished)` ). \
                `initial_inputs` and `initial_states` both are a (possibly nested \
                structure of) tensor variable[s], and `finished` is a tensor with \
                bool data type.
        """
2296
        super().__init__(embedding_fn, start_tokens, end_token)
2297 2298 2299 2300 2301 2302 2303
        self.softmax_temperature = (
            tensor.fill_constant(
                shape=[1], dtype="float32", value=softmax_temperature
            )
            if softmax_temperature is not None
            else None
        )
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        self.seed = seed


class BasicDecoder(Decoder):
    """
    BasicDecoder is a subclass of Decoder and assembles a RNNCell and DecodeHelper
    instance as members, where the DecodeHelper helps to implement customed
    decoding strategies.. It performs one decoding step as following steps:

    1. Perform `cell_outputs, cell_states = cell.call(inputs, states)`
    to get outputs and new states from cell.

    2. Perform `sample_ids = helper.sample(time, cell_outputs, cell_states)`
    to sample ids as decoded results of the current time step.

    3. Perform `finished, next_inputs, next_states = helper.next_inputs(time,
    cell_outputs, cell_states, sample_ids)` to generate inputs, states and
    finished status for the next decoding step.

    Examples:
        .. code-block:: python
2325

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            import paddle.fluid as fluid
            import paddle.fluid.layers as layers
            trg_emb = fluid.data(name="trg_emb",
                                 shape=[None, None, 128],
                                 dtype="float32")
2331

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            trg_embeder = lambda x: fluid.embedding(
                x, size=[10000, 128], param_attr=fluid.ParamAttr(name="trg_embedding"))
            output_layer = lambda x: layers.fc(x,
                                            size=10000,
                                            num_flatten_dims=len(x.shape) - 1,
                                            param_attr=fluid.ParamAttr(name=
                                                                    "output_w"),
                                            bias_attr=False)
            helper = layers.SampleEmbeddingHelper(trg_embeder, start_tokens=0, end_token=1)
            decoder_cell = layers.GRUCell(hidden_size=128)
            decoder = layers.BasicDecoder(decoder_cell, helper, output_fn=output_layer)
            outputs = layers.dynamic_decode(
                decoder=decoder, inits=decoder_cell.get_initial_states(encoder_output))
    """

    def __init__(self, cell, helper, output_fn=None):
        """
        Constructor of BasicDecoder.

        Parameters:
            cell(RNNCell): An instance of `RNNCell` or object with the same interface.
            helper(DecodeHelper): An instance of `DecodeHelper`.
            output_fn(optional): A callable to apply to the cell's output prior to
                sampling. Default None.
        """
        self.cell = cell
        self.helper = helper
        self.output_fn = output_fn

    def initialize(self, initial_cell_states):
2362
        r"""
2363 2364 2365 2366 2367 2368 2369 2370 2371 2372 2373 2374 2375 2376 2377 2378 2379 2380 2381 2382
        BasicDecoder initialization includes helper initialization and cell
        initialization, and cell initialization uses `initial_cell_states` as
        the result directly.

        Parameters:
            initial_cell_states(Variable): A (possibly nested structure of)
                tensor variable[s]. An argument provided by the caller `dynamic_decode`.

        Returns:
            tuple: A tuple( :code:(initial_inputs, initial_cell_states, finished)` ). \
                `initial_inputs` and `initial_states` both are a (possibly nested \
                structure of) tensor variable[s], and `finished` is a tensor with \
                bool data type. `initial_inputs` and `finished` are the results \
                of `helper.initialize()`, and `initial_cell_states` is same as \
                the input argument counterpart.
        """
        (initial_inputs, initial_finished) = self.helper.initialize()
        return initial_inputs, initial_cell_states, initial_finished

    class OutputWrapper(
2383 2384
        collections.namedtuple("OutputWrapper", ("cell_outputs", "sample_ids"))
    ):
2385 2386 2387 2388
        """
        The structure for the returned value `outputs` of `decoder.step`.
        A namedtuple includes cell_outputs, sample_ids as fields.
        """
2389

2390 2391 2392
        pass

    def step(self, time, inputs, states, **kwargs):
2393
        r"""
2394 2395 2396 2397 2398 2399 2400 2401 2402 2403 2404 2405 2406 2407 2408 2409 2410 2411 2412 2413 2414 2415 2416
        Perform one decoding step as following steps:

        1. Perform `cell_outputs, cell_states = cell.call(inputs, states)`
        to get outputs and new states from cell.

        2. Perform `sample_ids = helper.sample(time, cell_outputs, cell_states)`
        to sample ids as decoded results of the current time step.

        3. Perform `finished, next_inputs, next_states = helper.next_inputs(time,
        cell_outputs, cell_states, sample_ids)` to generate inputs, states and
        finished status for the next decoding step.

        Parameters:
            time(Variable): An `int64` tensor with shape `[1]` provided by the caller,
                representing the current time step number of decoding.
            inputs(Variable): A tensor variable. It is same as `initial_inputs`
                returned by `initialize()` for the first decoding step and
                `next_inputs` returned by `step()` for the others.
            states(Variable): A structure of tensor variables.
                It is same as the `initial_cell_states` returned by `initialize()`
                for the first decoding step and `next_states` returned by
                `step()` for the others.
            **kwargs: Additional keyword arguments, provided by the caller
2417 2418
                `dynamic_decode`.

2419 2420 2421 2422 2423 2424 2425 2426 2427 2428 2429 2430
        Returns:
            tuple: A tuple( :code:`(outputs, next_states, next_inputs, finished)` ). \
                `outputs` is a namedtuple(including cell_outputs, sample_ids, \
                as fields) of tensor variables, where `cell_outputs` is the result \
                fof `cell.call()` and `sample_ids` is the result of `helper.sample()`. \
                `next_states` and `next_inputs` have the same structure, shape \
                and data type as the input arguments `states` and `inputs` separately. \
                `finished` is a `bool` tensor with shape `[batch_size]`.
        """
        cell_outputs, cell_states = self.cell(inputs, states, **kwargs)
        if self.output_fn is not None:
            cell_outputs = self.output_fn(cell_outputs)
2431 2432 2433
        sample_ids = self.helper.sample(
            time=time, outputs=cell_outputs, states=cell_states
        )
2434
        sample_ids.stop_gradient = True
2435 2436 2437 2438 2439 2440
        (finished, next_inputs, next_states) = self.helper.next_inputs(
            time=time,
            outputs=cell_outputs,
            states=cell_states,
            sample_ids=sample_ids,
        )
2441 2442
        outputs = self.OutputWrapper(cell_outputs, sample_ids)
        return (outputs, next_states, next_inputs, finished)
2443 2444


2445 2446 2447 2448 2449 2450 2451 2452 2453 2454 2455 2456 2457 2458 2459
def dynamic_lstm(
    input,
    size,
    h_0=None,
    c_0=None,
    param_attr=None,
    bias_attr=None,
    use_peepholes=True,
    is_reverse=False,
    gate_activation='sigmoid',
    cell_activation='tanh',
    candidate_activation='tanh',
    dtype='float32',
    name=None,
):
2460
    r"""
2461
	:api_attr: Static Graph
S
swtkiwi 已提交
2462

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    **Note**:
        1. This OP only supports LoDTensor as inputs. If you need to deal with Tensor, please use :ref:`api_fluid_layers_lstm` .
        2. In order to improve efficiency, users must first map the input of dimension [T, hidden_size] to input of [T, 4 * hidden_size], and then pass it to this OP.

    The implementation of this OP include diagonal/peephole connections.
    Please refer to `Gers, F. A., & Schmidhuber, J. (2000) <ftp://ftp.idsia.ch/pub/juergen/TimeCount-IJCNN2000.pdf>`_ .
    If you do not need peephole connections, please set use_peepholes to False .

    This OP computes each timestep as follows:

    .. math::
      i_t = \sigma(W_{ix}x_{t} + W_{ih}h_{t-1} + b_{x_i} + b_{h_i})
    .. math::
      f_t = \sigma(W_{fx}x_{t} + W_{fh}h_{t-1} + b_{x_f} + b_{h_f})
    .. math::
      o_t = \sigma(W_{ox}x_{t} + W_{oh}h_{t-1} + b_{x_o} + b_{h_o})
    .. math::
      \widetilde{c_t} = tanh(W_{cx}x_t + W_{ch}h_{t-1} + b{x_c} + b_{h_c})
    .. math::
      c_t = f_t \odot c_{t-1} + i_t \odot \widetilde{c_t}
    .. math::
      h_t = o_t \odot tanh(c_t)

    The symbolic meanings in the formula are as follows:

    - :math:`x_{t}` represents the input at timestep :math:`t`
    - :math:`h_{t}` represents the hidden state at timestep :math:`t`
    - :math:`h_{t-1}, c_{t-1}` represent the hidden state and cell state at timestep :math:`t-1` , respectively
    - :math:`\widetilde{c_t}` represents the candidate cell state
    - :math:`i_t` , :math:`f_t` and :math:`o_t` represent input gate, forget gate, output gate, respectively
    - :math:`W` represents weight (e.g., :math:`W_{ix}` is the weight of a linear transformation of input :math:`x_{t}` when calculating input gate :math:`i_t` )
    - :math:`b` represents bias (e.g., :math:`b_{i}` is the bias of input gate)
    - :math:`\sigma` represents nonlinear activation function for gate, default sigmoid
    - :math:`\odot` represents the Hadamard product of a matrix, i.e. multiplying the elements of the same position for two matrices with the same dimension to get another matrix with the same dimension

    Parameters:
        input ( :ref:`api_guide_Variable_en` ): LSTM input tensor, multi-dimensional LODTensor of shape :math:`[T, 4*hidden\_size]` . Data type is float32 or float64.
        size (int): must be 4 * hidden_size.
        h_0( :ref:`api_guide_Variable_en` , optional): The initial hidden state of the LSTM, multi-dimensional Tensor of shape :math:`[batch\_size, hidden\_size]` .
                       Data type is float32 or float64. If set to None, it will be a vector of all 0. Default: None.
        c_0( :ref:`api_guide_Variable_en` , optional): The initial hidden state of the LSTM, multi-dimensional Tensor of shape :math:`[batch\_size, hidden\_size]` .
                       Data type is float32 or float64. If set to None, it will be a vector of all 0. `h_0` and `c_0` can be None but only at the same time. Default: None.
        param_attr(ParamAttr, optional): Parameter attribute of weight. If it is None, the default weight parameter attribute is used. Please refer to ref:`api_fluid_ParamAttr' .
                              If the user needs to set this parameter, the dimension must be :math:`[hidden\_size, 4*hidden\_size]` . Default: None.

                              - Weights = :math:`\{ W_{cr},W_{ir},W_{fr},W_{or} \}` , the shape is [hidden_size, 4*hidden_size].

        bias_attr (ParamAttr, optional): The bias attribute for the learnable bias
                              weights, which contains two parts, input-hidden
                              bias weights and peephole connections weights if
                              setting `use_peepholes` to `True`.
                              Please refer to ref:`api_fluid_ParamAttr' . Default: None.

                              1. `use_peepholes = False`
                                 - Biases = {:math:`b_c, b_i, b_f, b_o`}.
                                 - The shape is [1, 4*hidden_size].
                              2. `use_peepholes = True`
                                 - Biases = { :math:`b_c, b_i, b_f, b_o, W_{ic}, \
                                                 W_{fc}, W_{oc}`}.
                                 - The shape is [1, 7*hidden_size].
2523

2524 2525 2526 2527 2528 2529 2530 2531 2532 2533 2534 2535 2536 2537 2538 2539 2540 2541
        use_peepholes (bool, optional): Whether to use peephole connection or not. Default: True.
        is_reverse (bool, optional): Whether to calculate reverse LSTM. Default: False.
        gate_activation (str, optional): The activation for input gate, forget gate and output gate. Default: "sigmoid".
        cell_activation (str, optional): The activation for cell output. Default: "tanh".
        candidate_activation (str, optional): The activation for candidate hidden state. Default: "tanh".
        dtype (str, optional): Data type, can be "float32" or "float64". Default: "float32".
        name (str, optional): A name for this layer. Please refer to :ref:`api_guide_Name` . Default: None.

    Returns:
        tuple ( :ref:`api_guide_Variable` , :ref:`api_guide_Variable` ) :

            The hidden state and cell state of LSTM

                - hidden: LoDTensor with shape of :math:`[T, hidden\_size]` , and its lod and dtype is the same as the input.
                - cell: LoDTensor with shape of :math:`[T, hidden\_size]` , and its lod and dtype is the same as the input.

    Examples:
        .. code-block:: python
2542

2543 2544 2545 2546
            import paddle.fluid as fluid
            emb_dim = 256
            vocab_size = 10000
            hidden_dim = 512
2547

2548 2549 2550 2551 2552 2553 2554 2555 2556 2557 2558
            data = fluid.data(name='x', shape=[None], dtype='int64', lod_level=1)
            emb = fluid.embedding(input=data, size=[vocab_size, emb_dim], is_sparse=True)

            forward_proj = fluid.layers.fc(input=emb, size=hidden_dim * 4,
                                           bias_attr=False)

            forward, cell = fluid.layers.dynamic_lstm(
                input=forward_proj, size=hidden_dim * 4, use_peepholes=False)
            forward.shape  # (-1, 512)
            cell.shape  # (-1, 512)
    """
2559 2560 2561 2562 2563 2564 2565 2566 2567 2568
    assert (
        _non_static_mode() is not True
    ), "please use lstm instead of dynamic_lstm in dygraph mode!"
    assert (
        bias_attr is not False
    ), "bias_attr should not be False in dynamic_lstm."

    check_variable_and_dtype(
        input, 'input', ['float32', 'float64'], 'dynamic_lstm'
    )
2569 2570 2571

    check_type(h_0, 'h_0', (Variable, type(None)), 'dynamic_lstm')
    if isinstance(h_0, Variable):
2572 2573 2574
        check_variable_and_dtype(
            h_0, 'h_0', ['float32', 'float64'], 'dynamic_lstm'
        )
2575 2576 2577

    check_type(c_0, 'c_0', (Variable, type(None)), 'dynamic_lstm')
    if isinstance(c_0, Variable):
2578 2579 2580
        check_variable_and_dtype(
            c_0, 'c_0', ['float32', 'float64'], 'dynamic_lstm'
        )
2581

2582 2583
    helper = LayerHelper('lstm', **locals())
    size = size // 4
2584 2585 2586
    weight = helper.create_parameter(
        attr=helper.param_attr, shape=[size, 4 * size], dtype=dtype
    )
2587 2588 2589
    bias_size = [1, 7 * size]
    if not use_peepholes:
        bias_size[1] = 4 * size
2590 2591 2592
    bias = helper.create_parameter(
        attr=helper.bias_attr, shape=bias_size, dtype=dtype, is_bias=True
    )
2593 2594 2595 2596 2597 2598 2599 2600

    hidden = helper.create_variable_for_type_inference(dtype)
    cell = helper.create_variable_for_type_inference(dtype)
    batch_gate = helper.create_variable_for_type_inference(dtype)
    batch_cell_pre_act = helper.create_variable_for_type_inference(dtype)
    inputs = {'Input': input, 'Weight': weight, 'Bias': bias}
    batch_size = input.shape[0]
    if h_0:
2601
        assert h_0.shape == (batch_size, size), (
2602
            'The shape of h0 should be (batch_size, %d)' % size
2603
        )
2604 2605
        inputs['H0'] = h_0
    if c_0:
2606
        assert c_0.shape == (batch_size, size), (
2607
            'The shape of c0 should be (batch_size, %d)' % size
2608
        )
2609 2610
        inputs['C0'] = c_0

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    helper.append_op(
        type='lstm',
        inputs=inputs,
        outputs={
            'Hidden': hidden,
            'Cell': cell,
            'BatchGate': batch_gate,
            'BatchCellPreAct': batch_cell_pre_act,
        },
        attrs={
            'use_peepholes': use_peepholes,
            'is_reverse': is_reverse,
            'gate_activation': gate_activation,
            'cell_activation': cell_activation,
            'candidate_activation': candidate_activation,
        },
    )
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    return hidden, cell


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@deprecated(
    since='2.0.0',
    update_to='paddle.nn.LSTM',
    reason="This API may occur CUDNN errors.",
)
def lstm(
    input,
    init_h,
    init_c,
    max_len,
    hidden_size,
    num_layers,
    dropout_prob=0.0,
    is_bidirec=False,
    is_test=False,
    name=None,
    default_initializer=None,
    seed=-1,
):
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    r"""
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	:api_attr: Static Graph
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    **Note**:
        This OP only supports running on GPU devices.

    This OP implements LSTM operation - `Hochreiter, S., & Schmidhuber, J. (1997) <http://deeplearning.cs.cmu.edu/pdfs/Hochreiter97_lstm.pdf>`_ .

    The implementation of this OP does not include diagonal/peephole connections.
    Please refer to `Gers, F. A., & Schmidhuber, J. (2000) <ftp://ftp.idsia.ch/pub/juergen/TimeCount-IJCNN2000.pdf>`_ .
    If you need peephole connections, please use :ref:`api_fluid_layers_dynamic_lstm` .

    This OP computes each timestep as follows:

    .. math::
      i_t = \sigma(W_{ix}x_{t} + W_{ih}h_{t-1} + b_{x_i} + b_{h_i})
    .. math::
      f_t = \sigma(W_{fx}x_{t} + W_{fh}h_{t-1} + b_{x_f} + b_{h_f})
    .. math::
      o_t = \sigma(W_{ox}x_{t} + W_{oh}h_{t-1} + b_{x_o} + b_{h_o})
    .. math::
      \widetilde{c_t} = tanh(W_{cx}x_t + W_{ch}h_{t-1} + b{x_c} + b_{h_c})
    .. math::
      c_t = f_t \odot c_{t-1} + i_t \odot \widetilde{c_t}
    .. math::
      h_t = o_t \odot tanh(c_t)

    The symbolic meanings in the formula are as follows:

    - :math:`x_{t}` represents the input at timestep :math:`t`
    - :math:`h_{t}` represents the hidden state at timestep :math:`t`
    - :math:`h_{t-1}, c_{t-1}` represent the hidden state and cell state at timestep :math:`t-1` , respectively
    - :math:`\widetilde{c_t}` represents the candidate cell state
    - :math:`i_t` , :math:`f_t` and :math:`o_t` represent input gate, forget gate, output gate, respectively
    - :math:`W` represents weight (e.g., :math:`W_{ix}` is the weight of a linear transformation of input :math:`x_{t}` when calculating input gate :math:`i_t` )
    - :math:`b` represents bias (e.g., :math:`b_{i}` is the bias of input gate)
    - :math:`\sigma` represents nonlinear activation function for gate, default sigmoid
    - :math:`\odot` represents the Hadamard product of a matrix, i.e. multiplying the elements of the same position for two matrices with the same dimension to get another matrix with the same dimension

    Parameters:
        input ( :ref:`api_guide_Variable_en` ): LSTM input tensor, 3-D Tensor of shape :math:`[batch\_size, seq\_len, input\_dim]` . Data type is float32 or float64
        init_h( :ref:`api_guide_Variable_en` ): The initial hidden state of the LSTM, 3-D Tensor of shape :math:`[num\_layers, batch\_size, hidden\_size]` .
                       If is_bidirec = True, shape should be :math:`[num\_layers*2, batch\_size, hidden\_size]` . Data type is float32 or float64.
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        max_len (int): This parameter has no effect and will be discarded.
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        init_c( :ref:`api_guide_Variable_en` ): The initial cell state of the LSTM, 3-D Tensor of shape :math:`[num\_layers, batch\_size, hidden\_size]` .
                       If is_bidirec = True, shape should be :math:`[num\_layers*2, batch\_size, hidden\_size]` . Data type is float32 or float64.
        hidden_size (int): hidden size of the LSTM.
        num_layers (int): total layers number of the LSTM.
        dropout_prob(float, optional): dropout prob, dropout ONLY work between rnn layers, NOT between time steps
                             There is NO dropout work on rnn output of the last RNN layers.
                             Default: 0.0.
        is_bidirec (bool, optional): If it is bidirectional. Default: False.
        is_test (bool, optional): If it is in test phrase. Default: False.
        name (str, optional): A name for this layer. If set None, the layer
                         will be named automatically. Default: None.
        default_initializer(Initializer, optional): Where use initializer to initialize the Weight
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                         If set None, default initializer will be used. Default: None.
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        seed(int, optional): Seed for dropout in LSTM, If it's -1, dropout will use random seed. Default: 1.


    Returns:
        tuple ( :ref:`api_guide_Variable_en` , :ref:`api_guide_Variable_en` , :ref:`api_guide_Variable_en` ) :

                        Three tensors, rnn_out, last_h, last_c:

                        - rnn_out is result of LSTM hidden, shape is :math:`[seq\_len, batch\_size, hidden\_size]` \
                          if is_bidirec set to True, shape will be :math:`[seq\_len, batch\_size, hidden\_size*2]`
                        - last_h is the hidden state of the last step of LSTM \
                          shape is :math:`[num\_layers, batch\_size, hidden\_size]` \
                          if is_bidirec set to True, shape will be :math:`[num\_layers*2, batch\_size, hidden\_size]`
                        - last_c(Tensor): the cell state of the last step of LSTM \
                          shape is :math:`[num\_layers, batch\_size, hidden\_size]` \
                          if is_bidirec set to True, shape will be :math:`[num\_layers*2, batch\_size, hidden\_size]`


    Examples:
        .. code-block:: python
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            import paddle
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            import paddle.fluid as fluid
            import paddle.fluid.layers as layers
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            paddle.enable_static()
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            emb_dim = 256
            vocab_size = 10000
            data = fluid.data(name='x', shape=[None, 100], dtype='int64')
            emb = fluid.embedding(input=data, size=[vocab_size, emb_dim], is_sparse=True)
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            batch_size = 100
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            dropout_prob = 0.2
            input_size = 100
            hidden_size = 150
            num_layers = 1
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            max_len = 12
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            init_h = layers.fill_constant( [num_layers, batch_size, hidden_size], 'float32', 0.0 )
            init_c = layers.fill_constant( [num_layers, batch_size, hidden_size], 'float32', 0.0 )
            rnn_out, last_h, last_c = layers.lstm( emb, init_h, init_c, \
                    max_len, hidden_size, num_layers, \
                    dropout_prob=dropout_prob)
            rnn_out.shape  # (-1, 100, 150)
            last_h.shape  # (1, 20, 150)
            last_c.shape  # (1, 20, 150)
    """

    helper = LayerHelper('cudnn_lstm', **locals())
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    check_variable_and_dtype(input, 'input', ['float32', 'float64'], 'lstm')
    check_variable_and_dtype(init_h, 'init_h', ['float32', 'float64'], 'lstm')
    check_variable_and_dtype(init_c, 'init_c', ['float32', 'float64'], 'lstm')
    check_type(max_len, 'max_len', (int), 'lstm')
    check_type(hidden_size, 'hidden_size', (int), 'lstm')
    check_type(num_layers, 'num_layers', (int), 'lstm')
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    dtype = input.dtype
    input_shape = list(input.shape)
    input_size = input_shape[-1]
    weight_size = 0
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    num_dirrection = 2 if is_bidirec == True else 1

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    for i in range(num_layers):
        if i == 0:
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            input_weight_size = (input_size * hidden_size) * 4 * num_dirrection
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        else:
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            input_weight_size = (hidden_size * hidden_size) * 4 * num_dirrection
        hidden_weight_size = (hidden_size * hidden_size) * 4 * num_dirrection
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        weight_size += input_weight_size + hidden_weight_size
        weight_size += hidden_size * 8 * num_dirrection
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    weight = helper.create_parameter(
        attr=helper.param_attr,
        shape=[weight_size],
        dtype=dtype,
        default_initializer=default_initializer,
    )
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    out = helper.create_variable_for_type_inference(dtype)
    last_h = helper.create_variable_for_type_inference(dtype)
    last_c = helper.create_variable_for_type_inference(dtype)
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    reserve = helper.create_variable_for_type_inference(
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        dtype=core.VarDesc.VarType.UINT8, stop_gradient=True
    )
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    state_out = helper.create_variable_for_type_inference(
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        dtype=core.VarDesc.VarType.UINT8, stop_gradient=True
    )
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    state_out.persistable = True
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    helper.append_op(
        type='cudnn_lstm',
        inputs={
            'Input': input,
            'InitH': init_h,
            'InitC': init_c,
            'W': weight,
        },
        outputs={
            'Out': out,
            'LastH': last_h,
            'LastC': last_c,
            'Reserve': reserve,
            'StateOut': state_out,
        },
        attrs={
            'is_bidirec': is_bidirec,
            'input_size': input_size,
            'hidden_size': hidden_size,
            'num_layers': num_layers,
            'is_test': is_test,
            'dropout_prob': dropout_prob,
            'seed': seed,
        },
    )
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    return out, last_h, last_c


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def dynamic_lstmp(
    input,
    size,
    proj_size,
    param_attr=None,
    bias_attr=None,
    use_peepholes=True,
    is_reverse=False,
    gate_activation='sigmoid',
    cell_activation='tanh',
    candidate_activation='tanh',
    proj_activation='tanh',
    dtype='float32',
    name=None,
    h_0=None,
    c_0=None,
    cell_clip=None,
    proj_clip=None,
):
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    r"""
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	:api_attr: Static Graph
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    **Note**:
        1. In order to improve efficiency, users must first map the input of dimension [T, hidden_size] to input of [T, 4 * hidden_size], and then pass it to this OP.

    This OP implements the LSTMP (LSTM Projected) layer.
    The LSTMP layer has a separate linear mapping layer behind the LSTM layer. -- `Sak, H., Senior, A., & Beaufays, F. (2014) <https://ai.google/research/pubs/pub43905.pdf>`_ .

    Compared with the standard LSTM layer, LSTMP has an additional linear mapping layer,
    which is used to map from the original hidden state :math:`h_t` to the lower dimensional state :math:`r_t` .
    This reduces the total number of parameters and computational complexity, especially when the output unit is relatively large.

    The default implementation of the OP contains diagonal/peephole connections,
    please refer to `Gers, F. A., & Schmidhuber, J. (2000) <ftp://ftp.idsia.ch/pub/juergen/TimeCount-IJCNN2000.pdf>`_ .
    If you need to disable the peephole connections, set use_peepholes to False.

    This OP computes each timestep as follows:

    .. math::
      i_t = \sigma(W_{ix}x_{t} + W_{ir}r_{t-1} + W_{ic}c_{t-1} + b_i)
    .. math::
          f_t = \sigma(W_{fx}x_{t} + W_{fr}r_{t-1} + W_{fc}c_{t-1} + b_f)
    .. math::
          o_t = \sigma(W_{ox}x_{t} + W_{or}r_{t-1} + W_{oc}c_{t-1} + b_o)
    .. math::
          \widetilde{c_t} = act_g(W_{cx}x_t + W_{cr}r_{t-1} + b_c)
    .. math::
          c_t = f_t \odot c_{t-1} + i_t \odot \widetilde{c_t}
    .. math::
          h_t = o_t \odot act_h(c_t)
    .. math::
          r_t = \overline{act_h}(W_{rh}h_t)

    The symbolic meanings in the formula are as follows:

    - :math:`x_{t}` represents the input at timestep :math:`t`
    - :math:`h_{t}` represents the hidden state at timestep :math:`t`
    - :math:`r_{t}` : represents the state of the projected output of the hidden state :math:`h_{t}`
    - :math:`h_{t-1}, c_{t-1}, r_{t-1}` represent the hidden state, cell state and projected output at timestep :math:`t-1` , respectively
    - :math:`\widetilde{c_t}` represents the candidate cell state
    - :math:`i_t` , :math:`f_t` and :math:`o_t` represent input gate, forget gate, output gate, respectively
    - :math:`W` represents weight (e.g., :math:`W_{ix}` is the weight of a linear transformation of input :math:`x_{t}` when calculating input gate :math:`i_t` )
    - :math:`b` represents bias (e.g., :math:`b_{i}` is the bias of input gate)
    - :math:`\sigma` represents nonlinear activation function for gate, default sigmoid
    - :math:`\odot` represents the Hadamard product of a matrix, i.e. multiplying the elements of the same position for two matrices with the same dimension to get another matrix with the same dimension

    Parameters:
        input( :ref:`api_guide_Variable_en` ): The input of dynamic_lstmp layer, which supports
                         variable-time length input sequence.
                         It is a multi-dimensional LODTensor of shape :math:`[T, 4*hidden\_size]` . Data type is float32 or float64.
        size(int): must be 4 * hidden_size.
        proj_size(int): The size of projection output.
        param_attr(ParamAttr, optional): Parameter attribute of weight. If it is None, the default weight parameter attribute is used. Please refer to ref:`api_fluid_ParamAttr' .
                              If the user needs to set this parameter, the dimension must be :math:`[hidden\_size, 4*hidden\_size]` . Default: None.

                              - Weights = :math:`\{ W_{cr},W_{ir},W_{fr},W_{or} \}` , the shape is [P, 4*hidden_size] , where P is the projection size.
                              - Projection weight  = :math:`\{ W_{rh} \}` , the shape is [hidden_size, P].

        bias_attr (ParamAttr, optional): The bias attribute for the learnable bias
                              weights, which contains two parts, input-hidden
                              bias weights and peephole connections weights if
                              setting `use_peepholes` to `True`.
                              Please refer to ref:`api_fluid_ParamAttr' . Default: None.

                              1. `use_peepholes = False`
                                 - Biases = {:math:`b_c, b_i, b_f, b_o`}.
                                 - The shape is [1, 4*hidden_size].
                              2. `use_peepholes = True`
                                 - Biases = { :math:`b_c, b_i, b_f, b_o, W_{ic}, \
                                                 W_{fc}, W_{oc}`}.
                                 - The shape is [1, 7*hidden_size].

        use_peepholes (bool, optional): Whether to use peephole connection or not. Default True.
        is_reverse (bool, optional): Whether to calculate reverse LSTM. Default False.
        gate_activation (str, optional): The activation for input gate, forget gate and output gate. Default "sigmoid".
        cell_activation (str, optional): The activation for cell output. Default "tanh".
        candidate_activation (str, optional): The activation for candidate hidden state. Default "tanh".
        proj_activation(str, optional): The activation for projection output. Default "tanh".
        dtype (str, optional): Data type, can be "float32" or "float64". Default "float32".
        name (str, optional): A name for this layer. Please refer to :ref:`api_guide_Name` . Default: None.
        h_0( :ref:`api_guide_Variable` , optional): The initial hidden state is an optional input, default is zero.
                       This is a tensor with shape :math:`[batch\_size, P]` , where P is the projection size. Default: None.
        c_0( :ref:`api_guide_Variable` , optional): The initial cell state is an optional input, default is zero.
                       This is a tensor with shape :math:`[batch\_size, P]` , where P is the projection size.
                       `h_0` and `c_0` can be None but only at the same time. Default: None.
        cell_clip(float, optional): If not None, the cell state is clipped
                             by this value prior to the cell output activation. Default: None.
        proj_clip(float, optional): If `num_proj > 0` and `proj_clip` is
                            provided, then the projected values are clipped elementwise to within
                            `[-proj_clip, proj_clip]`. Default: None.

    Returns:
        tuple ( :ref:`api_guide_Variable` , :ref:`api_guide_Variable` ) :

                The hidden state and cell state of LSTMP

                - hidden: LoDTensor with shape of :math:`[T, P]` , and its lod and dtype is the same as the input.
                - cell: LoDTensor with shape of :math:`[T, hidden\_size]` , and its lod and dtype is the same as the input.

    Examples:

        .. code-block:: python

            import paddle.fluid as fluid
            dict_dim, emb_dim = 128, 64
            data = fluid.data(name='sequence', shape=[None], dtype='int64', lod_level=1)
            emb = fluid.embedding(input=data, size=[dict_dim, emb_dim])
            hidden_dim, proj_dim = 512, 256
            fc_out = fluid.layers.fc(input=emb, size=hidden_dim * 4,
                                    act=None, bias_attr=None)
            proj_out, last_c = fluid.layers.dynamic_lstmp(input=fc_out,
                                                    size=hidden_dim * 4,
                                                    proj_size=proj_dim,
                                                    use_peepholes=False,
                                                    is_reverse=True,
                                                    cell_activation="tanh",
                                                    proj_activation="tanh")
            proj_out.shape  # (-1, 256)
            last_c.shape  # (-1, 512)
    """

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    assert (
        _non_static_mode() is not True
    ), "please use lstm instead of dynamic_lstmp in dygraph mode!"
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    assert (
        bias_attr is not False
    ), "bias_attr should not be False in dynamic_lstmp."
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    check_variable_and_dtype(
        input, 'input', ['float32', 'float64'], 'dynamic_lstmp'
    )
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    check_type(h_0, 'h_0', (Variable, type(None)), 'dynamic_lstmp')
    if isinstance(h_0, Variable):
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        check_variable_and_dtype(
            h_0, 'h_0', ['float32', 'float64'], 'dynamic_lstmp'
        )
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    check_type(c_0, 'c_0', (Variable, type(None)), 'dynamic_lstmp')
    if isinstance(c_0, Variable):
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        check_variable_and_dtype(
            c_0, 'c_0', ['float32', 'float64'], 'dynamic_lstmp'
        )
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    helper = LayerHelper('lstmp', **locals())
    size = size // 4
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    weight = helper.create_parameter(
        attr=helper.param_attr, shape=[proj_size, 4 * size], dtype=dtype
    )
    proj_weight = helper.create_parameter(
        attr=helper.param_attr, shape=[size, proj_size], dtype=dtype
    )
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    bias_size = [1, 7 * size]
    if not use_peepholes:
        bias_size[1] = 4 * size
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    bias = helper.create_parameter(
        attr=helper.bias_attr, shape=bias_size, dtype=dtype, is_bias=True
    )
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    projection = helper.create_variable_for_type_inference(dtype)
    cell = helper.create_variable_for_type_inference(dtype)
    ordered_proj0 = helper.create_variable_for_type_inference(dtype)
    batch_hidden = helper.create_variable_for_type_inference(dtype)
    batch_gate = helper.create_variable_for_type_inference(dtype)
    batch_cell_pre_act = helper.create_variable_for_type_inference(dtype)
    inputs = {
        'Input': input,
        'Weight': weight,
        'ProjWeight': proj_weight,
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        'Bias': bias,
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    }
    batch_size = input.shape[0]
    if h_0:
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        assert h_0.shape == (batch_size, proj_size), (
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            'The shape of h0 should be (batch_size, %d)' % proj_size
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        )
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        inputs['H0'] = h_0
    if c_0:
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        assert c_0.shape == (batch_size, size), (
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            'The shape of c0 should be (batch_size, %d)' % size
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        )
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        inputs['C0'] = c_0

    if cell_clip:
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        assert cell_clip >= 0, "cell_clip should not be negative."
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    if proj_clip:
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        assert proj_clip >= 0, "proj_clip should not be negative."
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    helper.append_op(
        type='lstmp',
        inputs=inputs,
        outputs={
            'Projection': projection,
            'Cell': cell,
            'BatchHidden': batch_hidden,
            'BatchGate': batch_gate,
            'BatchCellPreAct': batch_cell_pre_act,
        },
        attrs={
            'use_peepholes': use_peepholes,
            'cell_clip': cell_clip,
            'proj_clip': proj_clip,
            'is_reverse': is_reverse,
            'gate_activation': gate_activation,
            'cell_activation': cell_activation,
            'candidate_activation': candidate_activation,
            'proj_activation': proj_activation,
        },
    )
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    return projection, cell


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def dynamic_gru(
    input,
    size,
    param_attr=None,
    bias_attr=None,
    is_reverse=False,
    gate_activation='sigmoid',
    candidate_activation='tanh',
    h_0=None,
    origin_mode=False,
):
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    r"""
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	:api_attr: Static Graph
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    **Note: The input type of this must be LoDTensor. If the input type to be
    processed is Tensor, use** :ref:`api_fluid_layers_StaticRNN` .

    This operator is used to perform the calculations for a single layer of
    Gated Recurrent Unit (GRU) on full sequences step by step. The calculations
    in one time step support these two modes:

    If ``origin_mode`` is True, then the formula used is from paper
    `Learning Phrase Representations using RNN Encoder Decoder for Statistical
    Machine Translation <https://arxiv.org/pdf/1406.1078.pdf>`_ .

    .. math::

        u_t & = act_g(W_{ux}x_{t} + W_{uh}h_{t-1} + b_u)

        r_t & = act_g(W_{rx}x_{t} + W_{rh}h_{t-1} + b_r)

        \\tilde{h_t} & = act_c(W_{cx}x_{t} + W_{ch}(r_t \odot h_{t-1}) + b_c)

        h_t & = u_t \odot h_{t-1} + (1-u_t) \odot \\tilde{h_t}


    if ``origin_mode`` is False, then the formula used is from paper
    `Empirical Evaluation of Gated Recurrent Neural Networks on Sequence
    Modeling  <https://arxiv.org/pdf/1412.3555.pdf>`_

    .. math::

        u_t & = act_g(W_{ux}x_{t} + W_{uh}h_{t-1} + b_u)

        r_t & = act_g(W_{rx}x_{t} + W_{rh}h_{t-1} + b_r)

        \\tilde{h_t} & = act_c(W_{cx}x_{t} + W_{ch}(r_t \odot h_{t-1}) + b_c)

        h_t & = (1-u_t) \odot h_{t-1} + u_t \odot \\tilde{h_t}

    :math:`x_t` is the input of current time step, but it is not from ``input`` .
    This operator does not include the calculations :math:`W_{ux}x_{t}, W_{rx}x_{t}, W_{cx}x_{t}` ,
    **Note** thus a fully-connect layer whose size is 3 times of ``size`` should
    be used before this operator, and the output should be used as ``input`` here.
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    :math:`h_{t-1}` is the hidden state from previous time step.
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    :math:`u_t` , :math:`r_t` , :math:`\\tilde{h_t}` and :math:`h_t` stand for
    update gate, reset gate, candidate hidden and hidden output separately.
    :math:`W_{uh}, b_u` , :math:`W_{rh}, b_r` and :math:`W_{ch}, b_c` stand for
    the weight matrix and bias used in update gate, reset gate, candidate hidden
    calculations. For implementation, the three weight matrix are merged into a
    tensor shaped :math:`[D, D \\times 3]` , the three bias are concatenated as
    a tensor shaped :math:`[1, D \\times 3]` , where :math:`D` stands for the
    hidden size; The data layout of weight tensor is: :math:`W_{uh}` and :math:`W_{rh}`
    are concatenated with shape :math:`[D, D  \\times 2]` lying on the first part,
    and :math:`W_{ch}` lying on the latter part with shape :math:`[D, D]` .


    Args:
        input(Variable): A LoDTensor whose lod level is 1, representing the input
            after linear projection. Its shape should be :math:`[T, D \\times 3]` ,
            where :math:`T` stands for the total sequence lengths in this mini-batch,
            :math:`D` for the hidden size. The data type should be float32 or float64.
        size(int): Indicate the hidden size.
        param_attr(ParamAttr, optional):  To specify the weight parameter property.
            Default: None, which means the default weight parameter property is used.
            See usage for details in :ref:`api_fluid_ParamAttr` .
        bias_attr (ParamAttr, optional): To specify the bias parameter property.
            Default: None, which means the default bias parameter property is used.
            See usage for details in :ref:`api_fluid_ParamAttr` .
        is_reverse(bool, optional): Whether to compute in the reversed order of
            input sequences. Default False.
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        gate_activation(str, optional): The activation function corresponding to
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            :math:`act_g` in the formula. "sigmoid", "tanh", "relu" and "identity"
            are supported. Default "sigmoid".
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        candidate_activation(str, optional): The activation function corresponding to
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            :math:`act_c` in the formula. "sigmoid", "tanh", "relu" and "identity"
            are supported. Default "tanh".
        h_0 (Variable, optional): A Tensor representing the initial hidden state.
            It not provided, the default initial hidden state is 0. The shape is
            :math:`[N, D]` , where :math:`N` is the number of sequences in the
            mini-batch, :math:`D` for the hidden size. The data type should be
            same as ``input`` . Default None.

    Returns:
        Variable: A LoDTensor whose lod level is 1 and shape is :math:`[T, D]` , \
            where :math:`T` stands for the total sequence lengths in this mini-batch \
            :math:`D` for the hidden size. It represents GRU transformed sequence output, \
            and has the same lod and data type with ``input`` .

    Examples:

        .. code-block:: python

            import paddle.fluid as fluid

            dict_dim, emb_dim = 128, 64
            data = fluid.data(name='sequence',
                      shape=[None],
                      dtype='int64',
                      lod_level=1)
            emb = fluid.embedding(input=data, size=[dict_dim, emb_dim])
            hidden_dim = 512
            x = fluid.layers.fc(input=emb, size=hidden_dim * 3)
            hidden = fluid.layers.dynamic_gru(input=x, size=hidden_dim)
    """

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    assert (
        _non_static_mode() is not True
    ), "please use gru instead of dynamic_gru in dygraph mode!"
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    check_variable_and_dtype(
        input, 'input', ['float32', 'float64'], 'dynamic_gru'
    )
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    check_type(h_0, 'h_0', (Variable, type(None)), 'dynamic_gru')
    if isinstance(h_0, Variable):
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        check_variable_and_dtype(
            h_0, 'h_0', ['float32', 'float64'], 'dynamic_gru'
        )
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    helper = LayerHelper('gru', **locals())
    dtype = helper.input_dtype()

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    weight = helper.create_parameter(
        attr=helper.param_attr, shape=[size, 3 * size], dtype=dtype
    )
    bias = helper.create_parameter(
        attr=helper.bias_attr, shape=[1, 3 * size], dtype=dtype, is_bias=True
    )
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    batch_size = input.shape[0]
    inputs = {'Input': input, 'Weight': weight, 'Bias': bias}
    if h_0:
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        assert h_0.shape == (batch_size, size), (
            'The shape of h0 should be(batch_size, %d)' % size
        )
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        inputs['H0'] = h_0

    hidden = helper.create_variable_for_type_inference(dtype)
    batch_gate = helper.create_variable_for_type_inference(dtype)
    batch_reset_hidden_prev = helper.create_variable_for_type_inference(dtype)
    batch_hidden = helper.create_variable_for_type_inference(dtype)

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    helper.append_op(
        type='gru',
        inputs=inputs,
        outputs={
            'Hidden': hidden,
            'BatchGate': batch_gate,
            'BatchResetHiddenPrev': batch_reset_hidden_prev,
            'BatchHidden': batch_hidden,
        },
        attrs={
            'is_reverse': is_reverse,
            'gate_activation': gate_activation,
            'activation': candidate_activation,
            'origin_mode': origin_mode,
        },
    )
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    return hidden


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def gru_unit(
    input,
    hidden,
    size,
    param_attr=None,
    bias_attr=None,
    activation='tanh',
    gate_activation='sigmoid',
    origin_mode=False,
):
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    r"""
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	:api_attr: Static Graph
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    Gated Recurrent Unit (GRU) RNN cell. This operator performs GRU calculations for
    one time step and it supports these two modes:

    If ``origin_mode`` is True, then the formula used is from paper
    `Learning Phrase Representations using RNN Encoder Decoder for Statistical
    Machine Translation <https://arxiv.org/pdf/1406.1078.pdf>`_ .

    .. math::

        u_t & = act_g(W_{ux}x_{t} + W_{uh}h_{t-1} + b_u)

        r_t & = act_g(W_{rx}x_{t} + W_{rh}h_{t-1} + b_r)

        \\tilde{h_t} & = act_c(W_{cx}x_{t} + W_{ch}(r_t \odot h_{t-1}) + b_c)

        h_t & = u_t \odot h_{t-1} + (1-u_t) \odot \\tilde{h_t}


    if ``origin_mode`` is False, then the formula used is from paper
    `Empirical Evaluation of Gated Recurrent Neural Networks on Sequence
    Modeling  <https://arxiv.org/pdf/1412.3555.pdf>`_

    .. math::

        u_t & = act_g(W_{ux}x_{t} + W_{uh}h_{t-1} + b_u)

        r_t & = act_g(W_{rx}x_{t} + W_{rh}h_{t-1} + b_r)

        \\tilde{h_t} & = act_c(W_{cx}x_{t} + W_{ch}(r_t \odot h_{t-1}) + b_c)

        h_t & = (1-u_t) \odot h_{t-1} + u_t \odot \\tilde{h_t}

    :math:`x_t` is the input of current time step, but it is not ``input`` .
    This operator does not include the calculations :math:`W_{ux}x_{t}, W_{rx}x_{t}, W_{cx}x_{t}` ,
    **Note** thus a fully-connect layer whose size is 3 times of GRU hidden size should
    be used before this operator, and the output should be used as ``input`` here.
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    :math:`h_{t-1}` is the hidden state from previous time step.
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    :math:`u_t` , :math:`r_t` , :math:`\\tilde{h_t}` and :math:`h_t` stand for
    update gate, reset gate, candidate hidden and hidden output separately.
    :math:`W_{uh}, b_u` , :math:`W_{rh}, b_r` and :math:`W_{ch}, b_c` stand for
    the weight matrix and bias used in update gate, reset gate, candidate hidden
    calculations. For implementation, the three weight matrix are merged into a
    tensor shaped :math:`[D, D \\times 3]` , the three bias are concatenated as
    a tensor shaped :math:`[1, D \\times 3]` , where :math:`D` stands for the
    hidden size; The data layout of weight tensor is: :math:`W_{uh}` and :math:`W_{rh}`
    are concatenated with shape :math:`[D, D  \\times 2]` lying on the first part,
    and :math:`W_{ch}` lying on the latter part with shape :math:`[D, D]` .


    Args:
        input(Variable): A 2D Tensor representing the input after linear projection
            after linear projection. Its shape should be :math:`[N, D \\times 3]` ,
            where :math:`N` stands for batch size, :math:`D` for the hidden size.
            The data type should be float32 or float64.
        hidden(Variable): A 2D Tensor representing the hidden state from previous step.
            Its shape should be :math:`[N, D]` , where :math:`N` stands for batch size,
            :math:`D` for the hidden size. The data type should be same as ``input`` .
        size(int): Indicate the hidden size.
        param_attr(ParamAttr, optional):  To specify the weight parameter property.
            Default: None, which means the default weight parameter property is used.
            See usage for details in :ref:`api_fluid_ParamAttr` .
        bias_attr (ParamAttr, optional): To specify the bias parameter property.
            Default: None, which means the default bias parameter property is used.
            See usage for details in :ref:`api_fluid_ParamAttr` .
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        activation(str, optional): The activation function corresponding to
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            :math:`act_c` in the formula. "sigmoid", "tanh", "relu" and "identity"
            are supported. Default "tanh".
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        gate_activation(str, optional): The activation function corresponding to
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            :math:`act_g` in the formula. "sigmoid", "tanh", "relu" and "identity"
            are supported. Default "sigmoid".

    Returns:
        tuple: The tuple contains three Tensor variables with the same data type \
            as ``input`` . They represent the hidden state for next time step ( :math:`h_t` ), \
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            reset previous hidden state ( :math:`r_t \odot h_{t-1}` ), and the \
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            concatenation of :math:`h_t, r_t, \\tilde{h_t}` . And they have shape \
            :math:`[N, D]` , :math:`[N, D]` , :math:`[N, D \times 3]` separately. \
            Usually only the hidden state for next time step ( :math:`h_t` ) is used \
            as output and state, the other two are intermediate results of calculations.

    Examples:

        .. code-block:: python

            import paddle.fluid as fluid

            dict_dim, emb_dim = 128, 64
            data = fluid.data(name='step_data', shape=[None], dtype='int64')
            emb = fluid.embedding(input=data, size=[dict_dim, emb_dim])
            hidden_dim = 512
            x = fluid.layers.fc(input=emb, size=hidden_dim * 3)
            pre_hidden = fluid.data(
                name='pre_hidden', shape=[None, hidden_dim], dtype='float32')
            hidden = fluid.layers.gru_unit(
                input=x, hidden=pre_hidden, size=hidden_dim * 3)

    """
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    check_variable_and_dtype(input, 'input', ['float32', 'float64'], 'gru_unit')
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    check_variable_and_dtype(
        hidden, 'hidden', ['float32', 'float64'], 'gru_unit'
    )
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    check_type(size, 'size', (int), 'gru_unit')
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    activation_dict = dict(
        identity=0,
        sigmoid=1,
        tanh=2,
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        relu=3,
    )
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    activation = activation_dict[activation]
    gate_activation = activation_dict[gate_activation]

    helper = LayerHelper('gru_unit', **locals())
    dtype = helper.input_dtype()
    size = size // 3

    # create weight
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    weight = helper.create_parameter(
        attr=helper.param_attr, shape=[size, 3 * size], dtype=dtype
    )
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    gate = helper.create_variable_for_type_inference(dtype)
    reset_hidden_pre = helper.create_variable_for_type_inference(dtype)
    updated_hidden = helper.create_variable_for_type_inference(dtype)
    inputs = {'Input': input, 'HiddenPrev': hidden, 'Weight': weight}
    # create bias
    if helper.bias_attr:
        bias_size = [1, 3 * size]
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        bias = helper.create_parameter(
            attr=helper.bias_attr, shape=bias_size, dtype=dtype, is_bias=True
        )
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        inputs['Bias'] = bias

    helper.append_op(
        type='gru_unit',
        inputs=inputs,
        outputs={
            'Gate': gate,
            'ResetHiddenPrev': reset_hidden_pre,
            'Hidden': updated_hidden,
        },
        attrs={
            'activation': 2,  # tanh
            'gate_activation': 1,  # sigmoid
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            'origin_mode': origin_mode,
        },
    )
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    return updated_hidden, reset_hidden_pre, gate


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def beam_search(
    pre_ids,
    pre_scores,
    ids,
    scores,
    beam_size,
    end_id,
    level=0,
    is_accumulated=True,
    name=None,
    return_parent_idx=False,
):
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    r"""
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    Beam search is a classical algorithm for selecting candidate words in a
    machine translation task.

    Refer to `Beam search <https://en.wikipedia.org/wiki/Beam_search>`_
    for more details.

    **This operator only supports LoDTensor.** It is used after finishing
    scores calculation to perform beam search for one time step. Specifically,
    after ``ids`` and ``scores`` have been produced, it selects the top-K
    ( `k` is ``beam_size`` ) candidate word ids of current step from ``ids``
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    according to the corresponding ``scores``. Additionally, ``pre_id`` and
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    ``pre_scores`` are the output of `beam_search` at previous step, they
    are needed for special use to handle ended candidate translations.

    Note that if ``is_accumulated`` is True, the ``scores`` passed in should
    be accumulated scores. Otherwise, the ``scores`` are
    considered as the probabilities of single step and would be transformed to
    the log field and added up with ``pre_scores`` for final scores in this
    operator. Length penalty should be done with extra operators before calculating
    the accumulated scores if needed.

    Please see the following demo for a fully beam search usage example:

        fluid/tests/book/test_machine_translation.py

    Args:
        pre_ids(Variable): A LodTensor variable (lod level is 2), representing
            the selected ids of previous step. It is the output of beam_search
            at previous step. Its shape is `[batch_size, 1]` and its lod is
            `[[0, 1, ... , batch_size], [0, 1, ..., batch_size]]` at the
            first step. The data type should be int64.
        pre_scores(Variable): A LodTensor variable has the same shape and lod
            with ``pre_ids`` , representing the accumulated scores corresponding
            to the selected ids of previous step. It is the output of
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            beam_search at previous step. The data type should be float32 or float64.
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        ids(Variable|None): A LodTensor variable containing the candidates ids.
            It has the same lod with ``pre_ids`` and its shape should be
            `[batch_size * beam_size, K]`, where `K` supposed to be greater than
            ``beam_size`` and the first dimension size (decrease as samples reach
            to the end) should be same as that of ``pre_ids`` . The data type
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            should be int64. It can be None, which use index in ``scores`` as
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            ids.
        scores(Variable): A LodTensor variable containing the accumulated
            scores corresponding to ``ids`` . Both its shape and lod are same as
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            those of ``ids`` . The data type should be float32 or float64.
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        beam_size(int): The beam width used in beam search.
        end_id(int): The id of end token.
        level(int): **It can be ignored and mustn't change currently.**
            The 2 level lod used in this operator has the following
            meaning: The first level describes how many beams each sample has,
            which would change to 0 when beams of the sample all end (batch reduce);
            The second level describes how many times each beam is selected.
            Default 0, which shouldn't be changed currently.
        is_accumulated(bool): Whether the input ``score`` is accumulated scores.
            Default True.
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        name(str, optional): For detailed information, please refer
            to :ref:`api_guide_Name`. Usually name is no need to set and
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            None by default.
        return_parent_idx(bool, optional): Whether to return an extra Tensor variable
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            in output, which stores the selected ids' parent index in
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            ``pre_ids`` and can be used to update RNN's states by gather operator.
            Default False.

    Returns:
        tuple: The tuple contains two or three LodTensor variables. The two LodTensor, \
            representing the selected ids and the corresponding accumulated scores of \
            current step, have the same shape `[batch_size, beam_size]` and lod with 2 levels, \
            and have data types int64 and float32. If ``return_parent_idx`` is True, \
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            an extra Tensor variable preserving the selected ids' parent index \
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            is included, whose shape is `[batch_size * beam_size]` and data type \
            is int64.

    Examples:
        .. code-block:: python

            import paddle.fluid as fluid
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            import paddle
            paddle.enable_static()
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            # Suppose `probs` contains predicted results from the computation
            # cell and `pre_ids` and `pre_scores` is the output of beam_search
            # at previous step.
            beam_size = 4
            end_id = 1
            pre_ids = fluid.data(
                name='pre_id', shape=[None, 1], lod_level=2, dtype='int64')
            pre_scores = fluid.data(
                name='pre_scores', shape=[None, 1], lod_level=2, dtype='float32')
            probs = fluid.data(
                name='probs', shape=[None, 10000], dtype='float32')
            topk_scores, topk_indices = fluid.layers.topk(probs, k=beam_size)
            accu_scores = fluid.layers.elementwise_add(
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                x=paddle.log(x=topk_scores),
                y=paddle.reshape(pre_scores, shape=[-1]),
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                axis=0)
            selected_ids, selected_scores = fluid.layers.beam_search(
                pre_ids=pre_ids,
                pre_scores=pre_scores,
                ids=topk_indices,
                scores=accu_scores,
                beam_size=beam_size,
                end_id=end_id)
    """
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    check_variable_and_dtype(pre_ids, 'pre_ids', ['int64'], 'beam_search')
3507 3508 3509
    check_variable_and_dtype(
        pre_scores, 'pre_scores', ['float32', 'float64'], 'beam_search'
    )
3510
    check_type(ids, 'ids', (Variable, type(None)), 'beam_search')
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    check_variable_and_dtype(
        scores, 'scores', ['float32', 'float64'], 'beam_search'
    )
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    helper = LayerHelper('beam_search', **locals())
    score_type = pre_scores.dtype
    id_type = pre_ids.dtype

    inputs = {"pre_ids": pre_ids, "pre_scores": pre_scores, "scores": scores}
    if ids is not None:
        inputs["ids"] = ids

    selected_scores = helper.create_variable_for_type_inference(
3523 3524
        dtype=score_type
    )
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    selected_ids = helper.create_variable_for_type_inference(dtype=id_type)
    # parent_idx is a tensor used to gather cell states at the next time
    # step. Though lod in selected_ids can also be used to gather by
    # sequence_expand, it is not efficient.
    # gather_op's index input only supports int32 dtype currently
    parent_idx = helper.create_variable_for_type_inference(dtype="int32")

    helper.append_op(
        type='beam_search',
        inputs=inputs,
        outputs={
            'selected_ids': selected_ids,
            'selected_scores': selected_scores,
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            'parent_idx': parent_idx,
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        },
        attrs={
            # TODO(ChunweiYan) to assure other value support
            'level': level,
            'beam_size': beam_size,
            'end_id': end_id,
            'is_accumulated': is_accumulated,
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        },
    )
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    if return_parent_idx:
        return selected_ids, selected_scores, parent_idx
    else:
        return selected_ids, selected_scores


def beam_search_decode(ids, scores, beam_size, end_id, name=None):
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    r"""
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    This operator is used after beam search has completed. It constructs the
    full predicted sequences for each sample by walking back along the search
    paths stored in lod of ``ids`` . The result sequences are stored in a
    LoDTensor, which uses the following way to parse:

    .. code-block:: text

        If lod = [[0, 3, 6], [0, 12, 24, 40, 54, 67, 82]]

        The first level of lod stands for: There are 2 samples each having 3
        (beam width) predicted sequence.

        The second level of lod stands for: The lengths of the first sample's
        3 predicted sequences are 12, 12, 16; The lengths of the second sample's
        3 predicted sequences are 14, 13, 15.


    Please see the following demo for a fully beam search usage example:
        fluid/tests/book/test_machine_translation.py

    Args:
        ids(Variable): The LoDTensorArray variable containing the selected ids
            of all steps. Each LoDTensor in it has int64 data type and 2 level
            lod which can be used to get the search paths.
        scores(Variable): The LodTensorArray variable containing the accumulated
            scores corresponding to selected ids of all steps. It has the same size
            as ``ids`` . Each LoDTensor in it has the same shape and lod as the
            counterpart in ``ids`` , and has a float32 data type.
        beam_size(int): The beam width used in beam search.
        end_id(int): The id of end token.
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        name(str, optional): For detailed information, please refer
            to :ref:`api_guide_Name`. Usually name is no need to set and
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            None by default.

    Returns:
        tuple: The tuple contains two LodTensor variables. The two LodTensor, \
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            containing the full sequences of ids and the corresponding accumulated \
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            scores, have the same shape flattened to 1D and have the same 2 level \
            lod. The lod can be used to get how many predicted sequences each sample \
            has and how many ids each predicted sequence has.

    Examples:
        .. code-block:: python

            import paddle.fluid as fluid
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            import paddle
            paddle.enable_static()
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            # Suppose `ids` and `scores` are LodTensorArray variables reserving
            # the selected ids and scores of all steps
            ids = fluid.layers.create_array(dtype='int64')
            scores = fluid.layers.create_array(dtype='float32')
            finished_ids, finished_scores = fluid.layers.beam_search_decode(
                ids, scores, beam_size=5, end_id=0)
    """
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    check_variable_and_dtype(ids, 'ids', ['int64'], 'beam_search_encode')
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    check_variable_and_dtype(
        scores, 'scores', ['float32'], 'beam_search_encode'
    )
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    helper = LayerHelper('beam_search_decode', **locals())
    sentence_ids = helper.create_variable_for_type_inference(dtype=ids.dtype)
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    sentence_scores = helper.create_variable_for_type_inference(
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        dtype=scores.dtype
    )

    helper.append_op(
        type="beam_search_decode",
        inputs={"Ids": ids, "Scores": scores},
        outputs={
            "SentenceIds": sentence_ids,
            "SentenceScores": sentence_scores,
        },
        attrs={"beam_size": beam_size, "end_id": end_id},
    )
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    return sentence_ids, sentence_scores


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def lstm_unit(
    x_t,
    hidden_t_prev,
    cell_t_prev,
    forget_bias=0.0,
    param_attr=None,
    bias_attr=None,
    name=None,
):
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    r"""
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	:api_attr: Static Graph
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    Long-Short Term Memory (LSTM) RNN cell. This operator performs LSTM calculations for
    one time step, whose implementation is based on calculations described in `RECURRENT
    NEURAL NETWORK REGULARIZATION <http://arxiv.org/abs/1409.2329>`_  .

    We add forget_bias to the biases of the forget gate in order to
    reduce the scale of forgetting. The formula is as follows:
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    .. math::

        i_{t} & = \sigma(W_{x_{i}}x_{t} + W_{h_{i}}h_{t-1} + b_{i})

        f_{t} & = \sigma(W_{x_{f}}x_{t} + W_{h_{f}}h_{t-1} + b_{f} + forget\\_bias)

        c_{t} & = f_{t}c_{t-1} + i_{t} tanh (W_{x_{c}}x_{t} + W_{h_{c}}h_{t-1} + b_{c})

        o_{t} & = \sigma(W_{x_{o}}x_{t} + W_{h_{o}}h_{t-1} + b_{o})

        h_{t} & = o_{t} tanh (c_{t})

    :math:`x_{t}` stands for ``x_t`` , corresponding to the input of current time step;
    :math:`h_{t-1}` and :math:`c_{t-1}` correspond to ``hidden_t_prev`` and ``cell_t_prev`` ,
    representing the output of from previous time step.
    :math:`i_{t}, f_{t}, c_{t}, o_{t}, h_{t}` are input gate, forget gate, cell, output gate
    and hidden calculation.

    Args:
        x_t(Variable): A 2D Tensor representing the input of current time step.
            Its shape should be :math:`[N, M]` , where :math:`N` stands for batch
            size, :math:`M` for the feature size of input. The data type should
            be float32 or float64.
        hidden_t_prev(Variable): A 2D Tensor representing the hidden value from
            previous step. Its shape should be :math:`[N, D]` , where :math:`N`
            stands for batch size, :math:`D` for the hidden size. The data type
            should be same as ``x_t`` .
        cell_t_prev(Variable): A 2D Tensor representing the cell value from
            previous step. It has the same shape and data type with ``hidden_t_prev`` .
        forget_bias (float, optional): :math:`forget\\_bias` added to the biases
            of the forget gate. Default 0.
        param_attr(ParamAttr, optional):  To specify the weight parameter property.
            Default: None, which means the default weight parameter property is used.
            See usage for details in :ref:`api_fluid_ParamAttr` .
        bias_attr (ParamAttr, optional): To specify the bias parameter property.
            Default: None, which means the default bias parameter property is used.
            See usage for details in :ref:`api_fluid_ParamAttr` .
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        name(str, optional): For detailed information, please refer
            to :ref:`api_guide_Name`. Usually name is no need to set and
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            None by default.

    Returns:
        tuple: The tuple contains two Tensor variables with the same shape and \
            data type with ``hidden_t_prev`` , representing the hidden value and \
            cell value which correspond to :math:`h_{t}` and :math:`c_{t}` in \
            the formula.

    Raises:
        ValueError: Rank of x_t must be 2.
        ValueError: Rank of hidden_t_prev must be 2.
        ValueError: Rank of cell_t_prev must be 2.
        ValueError: The 1st dimensions of x_t, hidden_t_prev and cell_t_prev must be the same.
        ValueError: The 2nd dimensions of hidden_t_prev and cell_t_prev must be the same.

    Examples:

        .. code-block:: python

            import paddle.fluid as fluid

            dict_dim, emb_dim, hidden_dim = 128, 64, 512
            data = fluid.data(name='step_data', shape=[None], dtype='int64')
            x = fluid.embedding(input=data, size=[dict_dim, emb_dim])
            pre_hidden = fluid.data(
                name='pre_hidden', shape=[None, hidden_dim], dtype='float32')
            pre_cell = fluid.data(
                name='pre_cell', shape=[None, hidden_dim], dtype='float32')
            hidden = fluid.layers.lstm_unit(
                x_t=x,
                hidden_t_prev=pre_hidden,
                cell_t_prev=pre_cell)
    """
    helper = LayerHelper('lstm_unit', **locals())
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    check_variable_and_dtype(x_t, 'x_t', ['float32', 'float64'], 'lstm_unit')
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    check_variable_and_dtype(
        hidden_t_prev, 'hidden_t_prev', ['float32', 'float64'], 'lstm_unit'
    )
    check_variable_and_dtype(
        cell_t_prev, 'cell_t_prev', ['float32', 'float64'], 'lstm_unit'
    )
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    if len(x_t.shape) != 2:
        raise ValueError("Rank of x_t must be 2.")

    if len(hidden_t_prev.shape) != 2:
        raise ValueError("Rank of hidden_t_prev must be 2.")

    if len(cell_t_prev.shape) != 2:
        raise ValueError("Rank of cell_t_prev must be 2.")

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    if (
        x_t.shape[0] != hidden_t_prev.shape[0]
        or x_t.shape[0] != cell_t_prev.shape[0]
    ):
        raise ValueError(
            "The 1st dimensions of x_t, hidden_t_prev and "
            "cell_t_prev must be the same."
        )
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    if hidden_t_prev.shape[1] != cell_t_prev.shape[1]:
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        raise ValueError(
            "The 2nd dimensions of hidden_t_prev and "
            "cell_t_prev must be the same."
        )
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    if bias_attr is None:
        bias_attr = ParamAttr()

    size = cell_t_prev.shape[1]
    concat_out = nn.concat(input=[x_t, hidden_t_prev], axis=1)
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    fc_out = nn.fc(
        input=concat_out,
        size=4 * size,
        param_attr=param_attr,
        bias_attr=bias_attr,
    )
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    dtype = x_t.dtype
    c = helper.create_variable_for_type_inference(dtype)
    h = helper.create_variable_for_type_inference(dtype)

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    helper.append_op(
        type='lstm_unit',
        inputs={"X": fc_out, "C_prev": cell_t_prev},
        outputs={"C": c, "H": h},
        attrs={"forget_bias": forget_bias},
    )
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    return h, c