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# Copyright (c) 2018 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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"""
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All layers just related to the neural network.
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"""

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from __future__ import print_function

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import numpy as np
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import warnings
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import six
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import os
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import inspect
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from ..layer_helper import LayerHelper
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from ..initializer import Normal, Constant, NumpyArrayInitializer
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from ..framework import Variable, OpProtoHolder, in_dygraph_mode, dygraph_only, _dygraph_tracer, default_main_program
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from ..dygraph import base
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from ..dygraph import dygraph_utils
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from ..param_attr import ParamAttr
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from .layer_function_generator import autodoc, templatedoc, _generate_doc_string_
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from .tensor import concat, assign, fill_constant, zeros
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from . import utils
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from .. import unique_name
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from functools import reduce
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from .. import core
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from ..dygraph import layers
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from ..data_feeder import convert_dtype, check_type_and_dtype, check_type, check_dtype
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__all__ = [
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    'fc',
    'embedding',
    'linear_chain_crf',
    'crf_decoding',
    'cos_sim',
    'chunk_eval',
    'conv2d',
    'conv3d',
    'softmax',
    'pool2d',
    'pool3d',
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    'adaptive_pool2d',
    'adaptive_pool3d',
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    'batch_norm',
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    'instance_norm',
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    'data_norm',
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    'conv2d_transpose',
    'conv3d_transpose',
    'reduce_sum',
    'reduce_mean',
    'reduce_max',
    'reduce_min',
    'reduce_prod',
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    'reduce_all',
    'reduce_any',
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    'dropout',
    'split',
    'ctc_greedy_decoder',
    'l2_normalize',
    'matmul',
    'topk',
    'transpose',
    'im2sequence',
    'row_conv',
    'multiplex',
    'layer_norm',
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    'group_norm',
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    'spectral_norm',
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    'smooth_l1',
    'one_hot',
    'autoincreased_step_counter',
    'reshape',
    'squeeze',
    'unsqueeze',
    'lod_reset',
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    'lod_append',
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    'lrn',
    'pad',
    'pad_constant_like',
    'label_smooth',
    'roi_pool',
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    'roi_align',
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    'dice_loss',
    'image_resize',
    'image_resize_short',
    'resize_bilinear',
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    'resize_trilinear',
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    'resize_nearest',
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    'gather',
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    'gather_nd',
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    'scatter',
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    'scatter_nd_add',
    'scatter_nd',
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    'random_crop',
    'mean_iou',
    'relu',
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    'selu',
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    'log',
    'crop',
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    'crop_tensor',
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    'elu',
    'relu6',
    'pow',
    'stanh',
    'hard_sigmoid',
    'swish',
    'prelu',
    'brelu',
    'leaky_relu',
    'soft_relu',
    'flatten',
    'stack',
    'pad2d',
    'unstack',
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    'unique',
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    'unique_with_counts',
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    'expand',
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    'expand_as',
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    'scale',
    'elementwise_add',
    'elementwise_div',
    'elementwise_sub',
    'elementwise_mul',
    'elementwise_max',
    'elementwise_min',
    'elementwise_pow',
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    'elementwise_mod',
    'elementwise_floordiv',
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    'uniform_random_batch_size_like',
    'gaussian_random',
    'sampling_id',
    'gaussian_random_batch_size_like',
    'sum',
    'slice',
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    'strided_slice',
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    'shape',
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    'rank',
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    'size',
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    'logical_and',
    'logical_or',
    'logical_xor',
    'logical_not',
    'clip',
    'clip_by_norm',
    'mean',
    'mul',
    'maxout',
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    'space_to_depth',
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    'affine_grid',
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    'affine_channel',
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    'similarity_focus',
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    'hash',
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    'grid_sampler',
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    'log_loss',
    'add_position_encoding',
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    'bilinear_tensor_product',
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    'merge_selected_rows',
    'get_tensor_from_selected_rows',
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    'shuffle_channel',
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    'temporal_shift',
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    'py_func',
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    'psroi_pool',
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    'prroi_pool',
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    'pixel_shuffle',
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    'fsp_matrix',
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    'continuous_value_model',
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    'where',
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    'sign',
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    'deformable_conv',
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    'unfold',
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    'deformable_roi_pooling',
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    'filter_by_instag',
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    'shard_index',
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    'hard_swish',
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    'gather_tree',
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    'uniform_random',
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]


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@dygraph_only
def _elementwise_op_in_dygraph(x,
                               y,
                               axis=-1,
                               act=None,
                               use_mkldnn=False,
                               op_name=None):
    attrs = {'axis': axis, 'use_mkldnn': use_mkldnn}
    inputs = {'X': [x], 'Y': [y]}
    op = getattr(core.ops, op_name)
    outs = op(inputs, attrs)
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    out = outs['Out'][0]
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    return dygraph_utils._append_activation_in_dygraph(
        out, act, use_mkldnn=use_mkldnn)
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def fc(input,
       size,
       num_flatten_dims=1,
       param_attr=None,
       bias_attr=None,
       act=None,
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       name=None):
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    """
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    **Fully Connected Layer**
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    This operator creates a fully connected layer in the network. It can take
    a Tensor(or LoDTensor) or a list of Tensor(or LoDTensor) as its inputs(see
    Args in detail). It creates a variable called weight for each input Tensor,
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    which represents a fully connected weight matrix from each input unit to
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    each output unit. The fully connected layer multiplies each input Tensor
    with its corresponding weight to produce an output Tensor with shape :math:`[M, size]` ,
    where M is batch size. If a list of Tensor is given, the results of
    multiple output Tensors with shape :math:`[M, size]` will be summed up. If :attr:`bias_attr`
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    is not None, a bias variable will be created and added to the output.
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    Finally, if :attr:`act` is not None, it will be applied to the output as well.
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    When the input is a single Tensor(or LoDTensor):
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    .. math::

        Out = Act({XW + b})

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    When the input is a list of Tensor(or LoDTensor):
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    .. math::

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        Out = Act({\sum_{i=0}^{N-1}X_iW_i + b})
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    In the above equation:

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    * :math:`N`: Number of the input. N equals to len(input) if input is list of Variable.
    * :math:`X_i`: The i-th input tensor.
    * :math:`W_i`: The i-th weights matrix corresponding i-th input tensor.
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    * :math:`b`: The bias parameter created by this layer (if needed).
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    * :math:`Act`: The activation function.
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    * :math:`Out`: The output Tensor.
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    .. code-block:: text

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        Case 1:
        Given a single Tensor data_1, and num_flatten_dims = 2:
            data_1.data = [[[0.1, 0.2],
                            [0.3, 0.4]]]
            data_1.shape = (1, 2, 2) # 1 is batch_size

            out = fluid.layers.fc(input=data_1, size=1, num_flatten_dims=2)

        Then output is:
            out.data = [[0.83234344], [0.34936576]]
            out.shape = (1, 2, 1)

        Case 2:
        Given a list of Tensor:
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            data_1.data = [[[0.1, 0.2],
                           [0.3, 0.4]]]
            data_1.shape = (1, 2, 2) # 1 is batch_size

            data_2 = [[[0.1, 0.2, 0.3]]]
            data_2.shape = (1, 1, 3)

            out = fluid.layers.fc(input=[data_1, data_2], size=2)

        Then:
            out.data = [[0.18669507, 0.1893476]]
            out.shape = (1, 2)

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    Args:
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        input (Variable|list of Variable): A Tensor(or LoDTensor) with shape :math:`[N_1, N_2,..., N_k]` or
            a list of Tensor(or LoDTensor). The dimensions of the input Tensor is at least 2 and the data
            type should be float32 or float64.
        size(int): The number of output units in this layer, which also means the feature size of ouput
            Tensor(or LoDTensor).
        num_flatten_dims (int): The fc layer can accept an input Tensor with more than
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            two dimensions. If this happens, the multidimensional tensor will first be flattened
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            into a 2-D matrix. The parameter :attr:`num_flatten_dims` determines how the input
            Tensor is flattened: the first :attr:`num_flatten_dims` (inclusive, index starts from 1)
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            dimensions will be flatten to form the first dimension of the final matrix (height of
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            the matrix), and the rest :math:`rank(X) - num\_flatten\_dims` dimensions are flattened to
            form the second dimension of the final matrix (width of the matrix). For example, assuming that
            X is a 5-dimensional Tensor with a shape [2, 3, 4, 5, 6], and :attr:`num_flatten_dims` = 3.
            Then, the flattened matrix will have a shape [2 x 3 x 4, 5 x 6] = [24, 30]. Default: 1.
        param_attr (ParamAttr): 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): 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` .
        act (str): Activation to be applied to the output of this layer, such as tanh, softmax,
            sigmoid, relu. For more information, please refer to :ref:`api_guide_activations_en` . Default: None.
        name (str, optional): The default value is None.  Normally there is no need for user to set this property.
            For more information, please refer to :ref:`api_guide_Name` .

    Returns:
        Variable: Tensor or LoDTensor calculated by fc layer. The data type is same with input.
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    Raises:
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        ValueError: If dimensions of the input Tensor is less than 2.
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    Examples:
        .. code-block:: python

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          import paddle.fluid as fluid
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          # when input is single tensor
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          data = fluid.data(name="data", shape=[-1, 32], dtype="float32")
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          fc = fluid.layers.fc(input=data, size=1000, act="tanh")
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          # when input are multiple tensors
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          data_1 = fluid.data(name="data_1", shape=[-1, 32], dtype="float32")
          data_2 = fluid.data(name="data_2", shape=[-1, 36], dtype="float32")
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          fc = fluid.layers.fc(input=[data_1, data_2], size=1000, act="tanh")
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    """
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    helper = LayerHelper("fc", **locals())
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    check_type(input, 'input', (list, tuple, Variable), 'fc')
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    if isinstance(input, (list, tuple)):
        for i, input_x in enumerate(input):
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            check_type(input_x, 'input[' + str(i) + ']', Variable, 'fc')
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    dtype = helper.input_dtype()
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    check_dtype(dtype, 'input', ['float16', 'float32', 'float64'], 'fc')
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    mul_results = []
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    for input_var, param_attr in helper.iter_inputs_and_params():
        input_shape = input_var.shape
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        param_shape = [
            reduce(lambda a, b: a * b, input_shape[num_flatten_dims:], 1)
        ] + [size]
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        w = helper.create_parameter(
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            attr=param_attr, shape=param_shape, dtype=dtype, is_bias=False)
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        tmp = helper.create_variable_for_type_inference(dtype)
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        helper.append_op(
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            type="mul",
            inputs={"X": input_var,
                    "Y": w},
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            outputs={"Out": tmp},
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            attrs={"x_num_col_dims": num_flatten_dims,
                   "y_num_col_dims": 1})
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        mul_results.append(tmp)

    if len(mul_results) == 1:
        pre_bias = mul_results[0]
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    else:
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        pre_bias = helper.create_variable_for_type_inference(dtype)
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        helper.append_op(
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            type="sum",
            inputs={"X": mul_results},
            outputs={"Out": pre_bias},
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            attrs={"use_mkldnn": False})
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    # add bias
    pre_activation = helper.append_bias_op(pre_bias, dim_start=num_flatten_dims)
    # add activation
    return helper.append_activation(pre_activation)
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def embedding(input,
              size,
              is_sparse=False,
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              is_distributed=False,
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              padding_idx=None,
              param_attr=None,
              dtype='float32'):
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    """
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    **WARING:** This OP will be deprecated in a future release. This OP requires the
    last dimension of Tensor shape must be equal to 1. It is recommended to use
    fluid. :ref:`api_fluid_embedding` .

    The operator is used to lookup embeddings vector of ids provided by :attr:`input` .
    It automatically constructs a 2D embedding matrix based on the
    input :attr:`size` (vocab_size, emb_size) and :attr:`dtype` .

    This OP requires the last dimension of Tensor shape must be equal to 1. The shape
    of output Tensor is generated by replacing the last dimension of the input Tensor shape
    with emb_size.

    **Note:** The id in :attr:`input` must satisfy :math:`0 =< id < size[0]` , 
    otherwise the program will throw an exception and exit.

    .. code-block:: text

        Case 1:

        input is a Tensor. padding_idx = -1
            input.data = [[[1], [3]], [[2], [4]], [[4], [127]]]
            input.shape = [3, 2, 1]
        Given size = [128, 16]
        output is a Tensor:
            out.shape = [3, 2, 16]
            out.data = [[[0.129435295, 0.244512452, ..., 0.436322452],
                        [0.345421456, 0.524563927, ..., 0.144534654]],

                        [[0.345249859, 0.124939536, ..., 0.194353745],
                        [0.945345345, 0.435394634, ..., 0.435345365]],
                        
                        [[0.945345345, 0.435394634, ..., 0.435345365],
                        [0.0,         0.0,         ..., 0.0        ]]]  # padding data
        The input padding_idx is less than 0, it is automatically converted to padding_idx = -1 + 128 = 127
        It will pad all-zero data when ids is 127.
        
        Case 2:
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        input is a LoDTensor with 1-level LoD. padding_idx = 0
            input.lod = [[2, 3]]
            input.data = [[1], [3], [2], [4], [0]]
            input.shape = [5, 1]
        Given size = [128, 16]
        output is a LoDTensor:
            out.lod = [[2, 3]]
            out.shape = [5, 16]
            out.data = [[0.129435295, 0.244512452, ..., 0.436322452],
                        [0.345421456, 0.524563927, ..., 0.144534654],
                        [0.345249859, 0.124939536, ..., 0.194353745],
                        [0.945345345, 0.435394634, ..., 0.435345365],
                        [0.0,         0.0,         ..., 0.0        ]]  # padding data
        It will pad all-zero data when ids is 0.
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    Args:
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        input(Variable): A Tensor or LoDTensor with type int64, which contains the id information.
            The last dimension of Tensor shape must be equal to 1. The value of the input id should
            satisfy :math:`0<= id < size[0]` .
        size(tuple|list): The shape of lookup table parameter. It should have two elements which
            indicates the size of the dictionary of embeddings and the size of each embedding vector respectively.
        is_sparse(bool): The flag indicating whether to use sparse update. This parameter only
            affects the performance of the backwards gradient update. It is recommended to set 
            True because sparse update is faster. But some optimizer does not support sparse update,
            such as :ref:`api_fluid_optimizer_AdadeltaOptimizer` , :ref:`api_fluid_optimizer_AdamaxOptimizer` , 
            :ref:`api_fluid_optimizer_DecayedAdagradOptimizer` , :ref:`api_fluid_optimizer_FtrlOptimizer` ,
            :ref:`api_fluid_optimizer_LambOptimizer` and :ref:`api_fluid_optimizer_LarsMomentumOptimizer` .
            In these case, is_sparse must be False. Default: False.
        is_distributed(bool): Whether to store the embedding matrix in a distributed manner. Only used
            in multi-machine distributed CPU training. Default: False.
        padding_idx(int|long|None): padding_idx needs to be in the interval [-vocab_size, vocab_size). 
            If :math:`padding\_idx < 0`, the :math:`padding\_idx` will automatically be converted
            to :math:`vocab\_size + padding\_idx` . It will output all-zero padding data whenever lookup
            encounters :math:`padding\_idx` in id. And the padding data will not be updated while training.
            If set None, it makes no effect to output. Default: None.
        param_attr(ParamAttr): 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` . In addition,
            user-defined or pre-trained word vectors can be loaded with the :attr:`param_attr` parameter. 
            The local word vector needs to be transformed into numpy format, and the shape of local word
            vector shoud be consistent with :attr:`size` . Then :ref:`api_fluid_initializer_NumpyArrayInitializer`
            is used to load custom or pre-trained word vectors. See code example 2 for details.
        dtype(str|core.VarDesc.VarType): It refers to the data type of output Tensor.
            It must be float32 or float64. Default: float32.
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    Returns:
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        Variable: Embedding Tensor or LoDTensor mapped by input. The data type is the same as :attr:`dtype` .
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    Examples:
        .. code-block:: python
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          import paddle.fluid as fluid
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          import numpy as np
          data = fluid.data(name='x', shape=[None, 1], dtype='int64')

          # exampel 1
          emb_1 = fluid.embedding(input=data, size=[128, 64])

          # example 2: load custom or pre-trained word vectors
          weight_data = np.random.random(size=(128, 100))  # word vectors with numpy format
          w_param_attrs = fluid.ParamAttr(
              name="emb_weight",
              learning_rate=0.5,
              initializer=fluid.initializer.NumpyArrayInitializer(weight_data),
              trainable=True)
          emb_2 = fluid.layers.embedding(input=data, size=(128, 100), param_attr=w_param_attrs, dtype='float32')   
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    """

    helper = LayerHelper('embedding', **locals())
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    check_type_and_dtype(input, 'input', Variable, ['int64'],
                         'fluid.layers.embedding')
    check_dtype(dtype, 'dtype', ['float16', 'float32', 'float64'],
                'fluid.layers.embedding')
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    remote_prefetch = is_sparse and (not is_distributed)
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    if remote_prefetch:
        assert is_sparse is True and is_distributed is False
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    w = helper.create_parameter(
        attr=helper.param_attr, shape=size, dtype=dtype, is_bias=False)
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    tmp = helper.create_variable_for_type_inference(dtype)
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    padding_idx = -1 if padding_idx is None else padding_idx if padding_idx >= 0 else (
        size[0] + padding_idx)
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    helper.append_op(
        type='lookup_table',
        inputs={'Ids': input,
                'W': w},
        outputs={'Out': tmp},
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        attrs={
            'is_sparse': is_sparse,
            'is_distributed': is_distributed,
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            'remote_prefetch': remote_prefetch,
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            'padding_idx': padding_idx
        })
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    return tmp


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def _pull_box_sparse(input, size, dtype='float32'):
    """
    **Pull Box Sparse Layer**

    This layer is used to lookup embeddings of IDs, provided by :attr:`input`, in
    BoxPS lookup table. The result of this lookup is the embedding of each ID in the
    :attr:`input`.

    Args:
        input(Variable|list of Variable): Input is a Tensor<int64> Variable, which 
            contains the IDs information.
        size(int): The embedding size parameter, which indicates the size of 
            each embedding vector respectively.
        dtype(str): The dtype refers to the data type of output tensor. Only supports 
	    float32 now.

    Returns:
        Variable|list of Variable: The tensor variable storing the embeddings of the \
                  supplied inputs.

    Examples:
        .. code-block:: python

          import paddle.fluid as fluid
          data = fluid.layers.data(name='sequence', shape=[1], dtype='int64', lod_level=1)
          emb = fluid.layers.pull_box_sparse(input=data, size=[11])    
    """
    helper = LayerHelper('pull_box_sparse', **locals())
    if dtype != 'float32':
        raise ValueError(
            "BoxPS only support float type embedding now, and your type is: " +
            dtype)
    helper.input_dtype()
    inputs = helper.multiple_input()
    outs = [
        helper.create_variable_for_type_inference(dtype)
        for i in range(len(inputs))
    ]
    helper.append_op(
        type='pull_box_sparse',
        inputs={'Ids': inputs},
        outputs={'Out': outs},
        attrs={'size': size})
    if len(outs) == 1:
        return outs[0]
    return outs


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@templatedoc()
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def linear_chain_crf(input, label, param_attr=None, length=None):
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    """
    Linear Chain CRF.

    ${comment}

    Args:
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        input(${emission_type}): ${emission_comment} 
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        label(${label_type}): ${label_comment}
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        Length(${length_type}): ${length_comment}
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        param_attr(ParamAttr): The attribute of the learnable parameter for transition parameter.
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    Returns:
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        output(${emission_exps_type}): ${emission_exps_comment} \n
        output(${transition_exps_type}): ${transition_exps_comment} \n
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        output(${log_likelihood_type}): ${log_likelihood_comment} \n
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    Examples:
        .. code-block:: python

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            import paddle.fluid as fluid
            import numpy as np

            #define net structure, using LodTensor
            train_program = fluid.Program()
            startup_program = fluid.Program()
            with fluid.program_guard(train_program, startup_program):
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                input_data = fluid.data(name='input_data', shape=[-1,10], dtype='float32')
                label = fluid.data(name='label', shape=[-1,1], dtype='int')
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                emission= fluid.layers.fc(input=input_data, size=10, act="tanh")
                crf_cost = fluid.layers.linear_chain_crf(
                    input=emission,
                    label=label,
                    param_attr=fluid.ParamAttr(
                    name='crfw',
                    learning_rate=0.01)) 
            use_cuda = False
            place = fluid.CUDAPlace(0) if use_cuda else fluid.CPUPlace()
            exe = fluid.Executor(place)
            exe.run(startup_program)    
            #define data, using LoDTensor
            a = fluid.create_lod_tensor(np.random.rand(12,10).astype('float32'), [[3,3,4,2]], place)
            b = fluid.create_lod_tensor(np.array([[1],[1],[2],[3],[1],[1],[1],[3],[1],[1],[1],[1]]),[[3,3,4,2]] , place)
            feed1 = {'input_data':a,'label':b}
            loss= exe.run(train_program,feed=feed1, fetch_list=[crf_cost])
            print(loss) 

            #define net structure, using padding
            train_program = fluid.Program()
            startup_program = fluid.Program()
            with fluid.program_guard(train_program, startup_program):
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                input_data2 = fluid.data(name='input_data2', shape=[-1,10,10], dtype='float32')
                label2 = fluid.data(name='label2', shape=[-1,10,1], dtype='int')
                label_length = fluid.data(name='length', shape=[-1,1], dtype='int')
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                emission2= fluid.layers.fc(input=input_data2, size=10, act="tanh", num_flatten_dims=2)
                crf_cost2 = fluid.layers.linear_chain_crf(
                    input=emission2,
                    label=label2,
                    length=label_length,
                    param_attr=fluid.ParamAttr(
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                     name='crfw',
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                     learning_rate=0.01))

            use_cuda = False
            place = fluid.CUDAPlace(0) if use_cuda else fluid.CPUPlace()
            exe = fluid.Executor(place)
            exe.run(startup_program)
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            #define data, using padding
            cc=np.random.rand(4,10,10).astype('float32')
            dd=np.random.rand(4,10,1).astype('int64')
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            ll=np.array([[3],[3],[4],[2]])
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            feed2 = {'input_data2':cc,'label2':dd,'length':ll}
            loss2= exe.run(train_program,feed=feed2, fetch_list=[crf_cost2])
            print(loss2) 
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            #[array([[ 7.8902354],
            #        [ 7.3602567],
            #        [ 10.004011],
            #        [ 5.86721  ]], dtype=float32)]

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            #you can use find_var to get transition parameter.
            transition=np.array(fluid.global_scope().find_var('crfw').get_tensor())
            print(transition)
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    """
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    helper = LayerHelper('linear_chain_crf', **locals())
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    size = input.shape[2] if length else input.shape[1]
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    transition = helper.create_parameter(
        attr=helper.param_attr,
        shape=[size + 2, size],
        dtype=helper.input_dtype())
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    alpha = helper.create_variable_for_type_inference(
        dtype=helper.input_dtype())
    emission_exps = helper.create_variable_for_type_inference(
        dtype=helper.input_dtype())
    transition_exps = helper.create_variable_for_type_inference(
        dtype=helper.input_dtype())
    log_likelihood = helper.create_variable_for_type_inference(
        dtype=helper.input_dtype())
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    this_inputs = {
        "Emission": [input],
        "Transition": transition,
        "Label": [label]
    }
    if length:
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        this_inputs['Length'] = [length]
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    helper.append_op(
        type='linear_chain_crf',
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        inputs=this_inputs,
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        outputs={
            "Alpha": [alpha],
            "EmissionExps": [emission_exps],
            "TransitionExps": transition_exps,
            "LogLikelihood": log_likelihood
        })

    return log_likelihood


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@templatedoc()
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def crf_decoding(input, param_attr, label=None, length=None):
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    """
    ${comment}
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    Args:
        input(${emission_type}): ${emission_comment}
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        param_attr (ParamAttr|None): To specify the weight parameter attribute. 
            Default: None, which means the default weight parameter property is 
            used. See usage for details in :ref:`api_fluid_ParamAttr` .
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        label(${label_type}, optional): ${label_comment}
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        length(${length_type}, optional): ${length_comment}
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    Returns:
        Variable: ${viterbi_path_comment}
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    Examples:
        .. code-block:: python
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           import paddle.fluid as fluid
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           # LoDTensor-based example
           num_labels = 10
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           feature = fluid.data(name='word_emb', shape=[-1, 784], dtype='float32', lod_level=1)
           label = fluid.data(name='label', shape=[-1, 1], dtype='int64', lod_level=1)
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           emission = fluid.layers.fc(input=feature, size=num_labels)
           
           crf_cost = fluid.layers.linear_chain_crf(input=emission, label=label, 
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                     param_attr=fluid.ParamAttr(name="crfw"))
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           crf_decode = fluid.layers.crf_decoding(input=emission, 
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                     param_attr=fluid.ParamAttr(name="crfw"))
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           # Common tensor example
           num_labels, max_len = 10, 20
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           feature = fluid.data(name='word_emb_pad', shape=[-1, max_len, 784], dtype='float32')
           label = fluid.data(name='label_pad', shape=[-1, max_len, 1], dtype='int64')
           length = fluid.data(name='length', shape=[-1, 1], dtype='int64')
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           emission = fluid.layers.fc(input=feature, size=num_labels,
                                      num_flatten_dims=2)
           
           crf_cost = fluid.layers.linear_chain_crf(input=emission, label=label, length=length, 
                     param_attr=fluid.ParamAttr(name="crfw_pad"))
           crf_decode = fluid.layers.crf_decoding(input=emission, length=length,
                     param_attr=fluid.ParamAttr(name="crfw_pad"))
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    """
    helper = LayerHelper('crf_decoding', **locals())
    transition = helper.get_parameter(param_attr.name)
    viterbi_path = helper.create_variable_for_type_inference(
        dtype=helper.input_dtype())
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    inputs = {"Emission": [input], "Transition": transition, "Label": label}
    if length:
        inputs['Length'] = length
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    helper.append_op(
        type='crf_decoding',
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        inputs=inputs,
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        outputs={"ViterbiPath": [viterbi_path]})
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    return viterbi_path
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@templatedoc()
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def cos_sim(X, Y):
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    """
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    ${comment}

    Args:
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        X (Variable): ${x_comment}.
        Y (Variable): ${y_comment}.
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    Returns:
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        A Variable holding LoDTensor representing the output of cosine(X, Y).
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    Examples:
        .. code-block:: python

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            import paddle.fluid as fluid
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            x = fluid.data(name='x', shape=[3, 7], dtype='float32')
            y = fluid.data(name='y', shape=[1, 7], dtype='float32')
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            out = fluid.layers.cos_sim(x, y)
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    """
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    helper = LayerHelper('cos_sim', **locals())
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    out = helper.create_variable_for_type_inference(dtype=X.dtype)
    xnorm = helper.create_variable_for_type_inference(dtype=X.dtype)
    ynorm = helper.create_variable_for_type_inference(dtype=X.dtype)
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    helper.append_op(
        type='cos_sim',
        inputs={'X': [X],
                'Y': [Y]},
        outputs={'Out': [out],
                 'XNorm': [xnorm],
                 'YNorm': [ynorm]})
    return out


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def dropout(x,
            dropout_prob,
            is_test=False,
            seed=None,
            name=None,
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            dropout_implementation="downgrade_in_infer"):
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    """
    Computes dropout.

    Drop or keep each element of `x` independently. Dropout is a regularization
    technique for reducing overfitting by preventing neuron co-adaption during
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    training. The dropout operator randomly sets (according to the given dropout
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    probability) the outputs of some units to zero, while others are remain
    unchanged.

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    dropout op can be removed from the program to make the program more efficient.

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    Args:
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        x (Variable): The input tensor variable. The data type is float16 or float32 or float64.
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        dropout_prob (float): Probability of setting units to zero.
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        is_test (bool): A flag indicating whether it is in test phrase or not.
        seed (int): A Python integer used to create random seeds. If this
                    parameter is set to None, a random seed is used.
                    NOTE: If an integer seed is given, always the same output
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                    units will be dropped. DO NOT use a fixed seed in training.Default: None.
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        name (str|None): A name for this layer(optional). If set None, the layer
                         will be named automatically.
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        dropout_implementation(string): ['downgrade_in_infer'(default)|'upscale_in_train']

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                                        1. downgrade_in_infer(default), downgrade the outcome at inference
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                                           - train: out = input * mask
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                                           - inference: out = input * (1.0 - dropout_prob)
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                                           (mask is a tensor same shape with input, value is 0 or 1
                                           ratio of 0 is dropout_prob)
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                                        2. upscale_in_train, upscale the outcome at training time
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                                           - train: out = input * mask / ( 1.0 - dropout_prob )
                                           - inference: out = input
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                                           (mask is a tensor same shape with input, value is 0 or 1
                                           ratio of 0 is dropout_prob)
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    Returns:
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        A Variable holding Tensor representing the dropout, has same shape and data type with `x`.
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    Examples:
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        .. code-block:: python

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            import paddle.fluid as fluid
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            x = fluid.data(name="data", shape=[None, 32, 32], dtype="float32")
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            droped = fluid.layers.dropout(x, dropout_prob=0.5)
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    """

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    def get_attrs(prog, dropout_prob, is_test, seed):
        if (seed is None or seed == 0) and prog.random_seed != 0:
            seed = prog.random_seed
        attrs = {
            'dropout_prob': dropout_prob,
            'is_test': is_test,
            'fix_seed': seed is not None,
            'seed': seed if seed is not None else 0,
            'dropout_implementation': dropout_implementation,
        }
        return attrs

    if in_dygraph_mode():
        attrs = get_attrs(default_main_program(), dropout_prob, is_test, seed)
        attrs['is_test'] = not _dygraph_tracer()._train_mode
        inputs = {'X': [x]}
        outs = core.ops.dropout(inputs, attrs)
        return outs['Out'][0]

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    helper = LayerHelper('dropout', **locals())
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    check_type_and_dtype(x, 'x', Variable, ['float16', 'float32', 'float64'],
                         'dropout')
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    out = helper.create_variable_for_type_inference(dtype=x.dtype)
    mask = helper.create_variable_for_type_inference(
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        dtype=core.VarDesc.VarType.UINT8, stop_gradient=True)
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    attrs = get_attrs(helper.main_program, dropout_prob, is_test, seed)
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    helper.append_op(
        type='dropout',
        inputs={'X': [x]},
        outputs={'Out': [out],
                 'Mask': [mask]},
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        attrs=attrs)
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    return out


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@templatedoc()
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def chunk_eval(input,
               label,
               chunk_scheme,
               num_chunk_types,
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               excluded_chunk_types=None,
               seq_length=None):
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    """
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    This operator computes the precision, recall and F1-score for chunk detection.
    It is often used in sequence tagging tasks, such as Named Entity Recognition(NER).
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    For some basics of chunking, please refer to
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    `Chunking with Support Vector Machines <https://aclanthology.info/pdf/N/N01/N01-1025.pdf>`_ .
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    This operator supports IOB, IOE, IOBES and IO (also known as plain) tagging schemes.
    Here is a NER example for the usage of these tagging schemes:
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    .. code-block:: python
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       ====== ====== ======  =====  ==  ============   =====  ===== =====  ==  =========
              Li     Ming    works  at  Agricultural   Bank   of    China  in  Beijing.
       ====== ====== ======  =====  ==  ============   =====  ===== =====  ==  =========
       IO     I-PER  I-PER   O      O   I-ORG          I-ORG  I-ORG I-ORG  O   I-LOC
       IOB    B-PER  I-PER   O      O   B-ORG          I-ORG  I-ORG I-ORG  O   B-LOC
       IOE    I-PER  E-PER   O      O   I-ORG          I-ORG  I-ORG E-ORG  O   E-LOC
       IOBES  B-PER  E-PER   O      O   I-ORG          I-ORG  I-ORG E-ORG  O   S-LOC
       ====== ====== ======  =====  ==  ============   =====  ===== =====  ==  =========

    There are three chunk types(named entity types) including PER(person), ORG(organization)
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    and LOC(location), and we can see that the labels have the form `<tag type>-<chunk type>` .
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    Since the implementation of this operator actually uses label ids rather than
    label strings, to make it work, there should be a way to map label ids to
    tag types and chunk types. This operator uses the following way to do mapping:
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    .. code-block:: python

       tag_type = label % num_tag_type
       chunk_type = label / num_tag_type

    where `num_tag_type` is the num of tag types in the tagging scheme, `num_chunk_type`
    is the num of chunk types, and `tag_type` get its value from the following table.

    .. code-block:: python
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       Scheme Begin Inside End   Single
        plain   0     -      -     -
        IOB     0     1      -     -
        IOE     -     0      1     -
        IOBES   0     1      2     3

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    Accordingly, in the above NER example, if the tagging scheme is IOB and chunk
    types are ORG, PER and LOC, then the label ids would be as follows:
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    .. code-block:: python

       B-ORG  0
       I-ORG  1
       B-PER  2
       I-PER  3
       B-LOC  4
       I-LOC  5
       O      6

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    With which we can map each label id to the corresponding tag type and chunk
    type correctly.
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    Args:
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        input (Variable): A Tensor or LoDTensor, representing the predicted labels
            from the network. When it is a Tensor, its shape would be `[N, M, 1]`,
            where `N` stands for batch size, `M` for sequence length; When it is
            a LoDTensor, its shape would be `[N, 1]` where `N` stands for the total
            sequence lengths in this mini-batch. The data type should be int64.
        label (Variable): A Tensor or LoDTensor representing the ground-truth labels.
            It shoud have the same shape, lod and data type as ``input`` .
        chunk_scheme (str): Indicate the tagging schemes used here. The value must
            be IOB, IOE, IOBES or plain.
        num_chunk_types (int): The number of chunk types.
        excluded_chunk_types (list, optional): Indicate the chunk types shouldn't
            be taken into account. It should be a list of chunk type ids(integer).
            Default None.
        seq_length(Variable, optional): A 1D Tensor containing the length of each
            sequence when ``input`` and ``label`` are Tensor. It needn't be
            provided if ``input`` and ``label`` are LoDTensor. Default None.
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    Returns:
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        tuple: A tuple including precision, recall, F1-score, chunk number detected, \
            chunk number in ground-truth, chunk number correctly detected. Each \
            is a Tensor with shape `[1]`. The data type of precision, recall and \
            F1-score all is float32, and the others' data type all is int64.
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    Examples:
        .. code-block:: python

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            import paddle.fluid as fluid

            dict_size = 10000
            label_dict_len = 7
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            sequence = fluid.data(
                name='id', shape=[-1, 1], lod_level=1, dtype='int64')
            embedding = fluid.embedding(
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                input=sequence, size=[dict_size, 512])
            hidden = fluid.layers.fc(input=embedding, size=512)
            label = fluid.layers.data(
                name='label', shape=[1], lod_level=1, dtype='int32')
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            crf = fluid.layers.linear_chain_crf(
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                input=hidden, label=label, param_attr=fluid.ParamAttr(name="crfw"))
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            crf_decode = fluid.layers.crf_decoding(
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                input=hidden, param_attr=fluid.ParamAttr(name="crfw"))
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            fluid.layers.chunk_eval(
                input=crf_decode,
                label=label,
                chunk_scheme="IOB",
                num_chunk_types=(label_dict_len - 1) / 2)
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    """
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    helper = LayerHelper("chunk_eval", **locals())
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    # prepare output
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    precision = helper.create_variable_for_type_inference(dtype="float32")
    recall = helper.create_variable_for_type_inference(dtype="float32")
    f1_score = helper.create_variable_for_type_inference(dtype="float32")
    num_infer_chunks = helper.create_variable_for_type_inference(dtype="int64")
    num_label_chunks = helper.create_variable_for_type_inference(dtype="int64")
    num_correct_chunks = helper.create_variable_for_type_inference(
        dtype="int64")
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    this_input = {"Inference": [input], "Label": [label]}

    if seq_length:
        this_input["SeqLength"] = [seq_length]

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    helper.append_op(
        type="chunk_eval",
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        inputs=this_input,
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        outputs={
            "Precision": [precision],
            "Recall": [recall],
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            "F1-Score": [f1_score],
            "NumInferChunks": [num_infer_chunks],
            "NumLabelChunks": [num_label_chunks],
            "NumCorrectChunks": [num_correct_chunks]
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        },
        attrs={
            "num_chunk_types": num_chunk_types,
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            "chunk_scheme": chunk_scheme,
            "excluded_chunk_types": excluded_chunk_types or []
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        })
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    return (precision, recall, f1_score, num_infer_chunks, num_label_chunks,
            num_correct_chunks)
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def softmax(input, use_cudnn=False, name=None, axis=-1):
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    """
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    This operator implements the softmax layer. The calculation process is as follows:
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    1. The dimension :attr:`axis` of the ``input`` will be permuted to the last.
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    2. Then the input tensor will be logically flattened to a 2-D matrix. The matrix's
    second dimension(row length) is the same as the dimension :attr:`axis` of the input
    tensor, and the first dimension(column length) is the product of all other
    dimensions of the input tensor. For each row of the matrix, the softmax operator
    squashes the K-dimensional(K is the width of the matrix, which is also the size
    of the input tensor's dimension :attr:`axis`) vector of arbitrary real values to a
    K-dimensional vector of real values in the range [0, 1] that add up to 1.
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    3. After the softmax operation is completed, the inverse operations of steps 1 and 2 
    are performed to restore the two-dimensional matrix to the same dimension as the ``input``.
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    It computes the exponential of the given dimension and the sum of exponential
    values of all the other dimensions in the K-dimensional vector input.
    Then the ratio of the exponential of the given dimension and the sum of
    exponential values of all the other dimensions is the output of the softmax
    operator.
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    For each row :math:`i` and each column :math:`j` in the matrix, we have:
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    .. math::
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        Out[i, j] = \\frac{\exp(X[i, j])}{\sum_j(exp(X[i, j])}
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    Example:
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    .. code-block:: text

        Case 1:
          Input:
            X.shape = [2, 3, 4]
            X.data = [[[2.0, 3.0, 4.0, 5.0],
                       [3.0, 4.0, 5.0, 6.0],
                       [7.0, 8.0, 8.0, 9.0]],
                      [[1.0, 2.0, 3.0, 4.0],
                       [5.0, 6.0, 7.0, 8.0],
                       [6.0, 7.0, 8.0, 9.0]]]

          Attrs:
            axis = -1

          Output:
            Out.shape = [2, 3, 4]
            Out.data = [[[0.0320586 , 0.08714432, 0.23688282, 0.64391426],
                         [0.0320586 , 0.08714432, 0.23688282, 0.64391426],
                         [0.07232949, 0.19661193, 0.19661193, 0.53444665]],
                        [[0.0320586 , 0.08714432, 0.23688282, 0.64391426],
                         [0.0320586 , 0.08714432, 0.23688282, 0.64391426],
                         [0.0320586 , 0.08714432, 0.23688282, 0.64391426]]]

        Case 2:
          Input:
            X.shape = [2, 3, 4]
            X.data = [[[2.0, 3.0, 4.0, 5.0],
                       [3.0, 4.0, 5.0, 6.0],
                       [7.0, 8.0, 8.0, 9.0]],
                      [[1.0, 2.0, 3.0, 4.0],
                       [5.0, 6.0, 7.0, 8.0],
                       [6.0, 7.0, 8.0, 9.0]]]
          Attrs:
            axis = 1

          Output:
            Out.shape = [2, 3, 4]
            Out.data = [[[0.00657326, 0.00657326, 0.01714783, 0.01714783],
                         [0.01786798, 0.01786798, 0.04661262, 0.04661262],
                         [0.97555875, 0.97555875, 0.93623955, 0.93623955]],
                        [[0.00490169, 0.00490169, 0.00490169, 0.00490169],
                         [0.26762315, 0.26762315, 0.26762315, 0.26762315],
                         [0.72747516, 0.72747516, 0.72747516, 0.72747516]]] 

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    Args:
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        input (Variable): The input variable. A multi-dimension ``Tensor`` with type float32 or float64.
        use_cudnn (bool, optional): Use cudnn kernel or not, it is valid only when the cudnn \
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            library is installed. To improve numerical stablity, set use_cudnn to \
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            False by default.
        name (str, optional): The default value is None. Normally there is no need for user to set this property. For more information, please refer to :ref:`api_guide_Name` . Default: None.
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            will be named automatically. Default: None.
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        axis (int, optional): The index of dimension to perform softmax calculations, it should
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            be in range :math:`[-1, rank - 1]`, while :math:`rank` is the rank of
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            input variable. Default: -1. -1 means the last dimension.
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    Returns:
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        Variable: ``Tensor`` indicates the output of softmax. The data type and shape are the same as ``input`` .
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    Examples:

        .. code-block:: python

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            import paddle.fluid as fluid
            import numpy as np
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            data = fluid.data(name="input", shape=[-1, 3],dtype="float32")
            result = fluid.layers.softmax(data,axis=1)
            place = fluid.CPUPlace()
            exe = fluid.Executor(place)
            exe.run(fluid.default_startup_program())
            x = np.random.rand(3, 3).astype("float32")
            output= exe.run(feed={"input": x},
                             fetch_list=[result[0]])
            print(output)
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    """
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    helper = LayerHelper('softmax', **locals())
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    check_type_and_dtype(input, 'input', Variable,
                         ['float16', 'float32', 'float64'], 'softmax')
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    dtype = helper.input_dtype()
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    softmax_out = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
        type="softmax",
        inputs={"X": input},
        outputs={"Out": softmax_out},
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        attrs={"axis": axis,
               "use_cudnn": use_cudnn})
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    return softmax_out


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def conv2d(input,
           num_filters,
           filter_size,
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           stride=1,
           padding=0,
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           dilation=1,
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           groups=None,
           param_attr=None,
           bias_attr=None,
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           use_cudnn=True,
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           act=None,
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           name=None,
           data_format="NCHW"):
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    """
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    The convolution2D layer calculates the output based on the input, filter
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    and strides, paddings, dilations, groups parameters. Input and
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    Output are in NCHW or NHWC format, where N is batch size, C is the number of
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    channels, H is the height of the feature, and W is the width of the feature.
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    Filter is in MCHW format, where M is the number of output image channels,
    C is the number of input image channels, H is the height of the filter,
    and W is the width of the filter. If the groups is greater than 1,
    C will equal the number of input image channels divided by the groups.
    Please refer to UFLDL's `convolution
    <http://ufldl.stanford.edu/tutorial/supervised/FeatureExtractionUsingConvolution/>`_
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    for more details.
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    If bias attribution and activation type are provided, bias is added to the
    output of the convolution, and the corresponding activation function is
    applied to the final result.
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    For each input :math:`X`, the equation is:
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    .. math::

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        Out = \sigma (W \\ast X + b)
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    Where:
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    * :math:`X`: Input value, a tensor with NCHW or NHWC format.
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    * :math:`W`: Filter value, a tensor with MCHW format.
    * :math:`\\ast`: Convolution operation.
    * :math:`b`: Bias value, a 2-D tensor with shape [M, 1].
    * :math:`\\sigma`: Activation function.
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    * :math:`Out`: Output value, the shape of :math:`Out` and :math:`X` may be different.
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    Example:

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        - Input:

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          Input shape: :math:`(N, C_{in}, H_{in}, W_{in})`
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          Filter shape: :math:`(C_{out}, C_{in}, H_f, W_f)`
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        - Output:
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          Output shape: :math:`(N, C_{out}, H_{out}, W_{out})`
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        Where
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        .. math::
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            H_{out}&= \\frac{(H_{in} + 2 * paddings[0] - (dilations[0] * (H_f - 1) + 1))}{strides[0]} + 1 \\\\
            W_{out}&= \\frac{(W_{in} + 2 * paddings[1] - (dilations[1] * (W_f - 1) + 1))}{strides[1]} + 1
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    Args:
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        input (Variable): The input is 4-D Tensor with shape [N, C, H, W], the data type 
            of input is float16 or float32 or float64.
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        num_filters(int): The number of filter. It is as same as the output
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            image channel.
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        filter_size (int|tuple): The filter size. If filter_size 
            is a tuple, it must contain two integers, (filter_size_height, 
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            filter_size_width). Otherwise, filter_size_height = filter_size_width =\
            filter_size.
        stride (int|tuple): The stride size. It means the stride in convolution. 
            If stride is a tuple, it must contain two integers, (stride_height, stride_width). 
            Otherwise, stride_height = stride_width = stride. Default: stride = 1.
        padding (string|int|list|tuple): The padding size. It means the number of zero-paddings
            on both sides for each dimention.If `padding` is a string, either 'VALID' or
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            'SAME' which is the padding algorithm. If padding size is a tuple or list,
            it could be in three forms: `[pad_height, pad_width]` or
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            `[pad_height_top, pad_height_bottom, pad_width_left, pad_width_right]`, and when 
            `data_format` is `"NCHW"`, `padding` can be in the form `[[0,0], [0,0], 
            [pad_height_top, pad_height_bottom], [pad_width_left, pad_width_right]]`.
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            when `data_format` is `"NHWC"`, `pool_padding` can be in the form
            `[[0,0], [pad_height_top, pad_height_bottom], [pad_width_left, pad_width_right], [0,0]]`.
            Default: padding = 0.
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        dilation (int|tuple): The dilation size. It means the spacing between the kernel
            points. If dilation is a tuple, it must contain two integers, (dilation_height, 
            dilation_width). Otherwise, dilation_height = dilation_width = dilation. 
            Default: dilation = 1.
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        groups (int): The groups number of the Conv2d Layer. According to grouped
            convolution in Alex Krizhevsky's Deep CNN paper: when group=2,
            the first half of the filters is only connected to the first half
            of the input channels, while the second half of the filters is only
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            connected to the second half of the input channels. Default: groups=1.
        param_attr (ParamAttr|None): The parameter attribute for learnable parameters/weights
            of conv2d. If it is set to None or one attribute of ParamAttr, conv2d
            will create ParamAttr as param_attr. If the Initializer of the param_attr
            is not set, the parameter is initialized with :math:`Normal(0.0, std)`,
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            and the :math:`std` is :math:`(\\frac{2.0 }{filter\_elem\_num})^{0.5}`. Default: None.
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        bias_attr (ParamAttr|bool|None): The parameter attribute for the bias of conv2d.
            If it is set to False, no bias will be added to the output units.
            If it is set to None or one attribute of ParamAttr, conv2d
            will create ParamAttr as bias_attr. If the Initializer of the bias_attr
            is not set, the bias is initialized zero. Default: None.
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        use_cudnn (bool): Use cudnn kernel or not, it is valid only when the cudnn
            library is installed. Default: True
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        act (str): Activation type, if it is set to None, activation is not appended.
            Default: None
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        name(str|None): For detailed information, please refer 
           to :ref:`api_guide_Name`. Usually name is no need to set and 
           None by default.
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        data_format (str, optional): Specify the data format of the input, and the data format of the output 
            will be consistent with that of the input. An optional string from: `"NCHW"`, `"NHWC"`.
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            The default is `"NCHW"`. When it is `"NCHW"`, the data is stored in the order of:
            `[batch_size, input_channels, input_height, input_width]`.
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    Returns:
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        A Variable holding Tensor representing the conv2d, whose data type is the 
        same with input. If act is None, the tensor variable storing the convolution 
        result, and if act is not None, the tensor variable storing convolution 
        and non-linearity activation result.
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    Raises:
        ValueError: If the type of `use_cudnn` is not bool.
        ValueError: If `data_format` is not "NCHW" or "NHWC".
        ValueError: If the channel dimmention of the input is less than or equal to zero.
        ValueError: If `padding` is a string, but not "SAME" or "VALID".
        ValueError: If `padding` is a tuple, but the element corresponding to the input's batch size is not 0 
            or the element corresponding to the input's channel is not 0.
        ShapeError: If the input is not 4-D Tensor.
        ShapeError: If the input's dimension size and filter's dimension size not equal.
        ShapeError: If the dimension size of input minus the size of `stride` is not 2.
        ShapeError: If the number of input channels is not equal to filter's channels * groups.
        ShapeError: If the number of output channels is not be divided by groups.

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    Examples:
        .. code-block:: python

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          import paddle.fluid as fluid
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          data = fluid.data(name='data', shape=[None, 3, 32, 32], dtype='float32')
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          conv2d = fluid.layers.conv2d(input=data, num_filters=2, filter_size=3, act="relu")
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    """

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    check_type_and_dtype(input, 'input', Variable,
                         ['float16', 'float32', 'float64'], 'conv2d')
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    num_channels = input.shape[1]
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    if not isinstance(use_cudnn, bool):
        raise ValueError("Attr(use_cudnn) should be True or False. Received "
                         "Attr(use_cudnn): %s. " % str(use_cudnn))

    if data_format not in ["NCHW", "NHWC"]:
        raise ValueError(
            "Attr(data_format) should be 'NCHW' or 'NHWC'. Received "
            "Attr(data_format): %s." % str(data_format))

    channel_last = (data_format == "NHWC")
    num_channels = input.shape[3] if channel_last else input.shape[1]
    if num_channels < 0:
        raise ValueError(
            "The channel dimmention of the input(%s) should be defined. "
            "Received: %s." % (str(input.shape), str(num_channels)))
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    assert param_attr is not False, "param_attr should not be False here."
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    l_type = 'conv2d'
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    if (num_channels == groups and num_filters % num_channels == 0 and
            not use_cudnn):
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        l_type = 'depthwise_conv2d'
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    helper = LayerHelper(l_type, **locals())
    dtype = helper.input_dtype()

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    if groups is None:
        num_filter_channels = num_channels
    else:
        if num_channels % groups != 0:
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            raise ValueError(
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                "the channel of input must be divisible by groups,"
                "received: the channel of input is {}, the shape of input is {}"
                ", the groups is {}".format(num_channels, input.shape, groups))
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        num_filter_channels = num_channels // groups
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    filter_size = utils.convert_to_list(filter_size, 2, 'filter_size')
    stride = utils.convert_to_list(stride, 2, 'stride')
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    dilation = utils.convert_to_list(dilation, 2, 'dilation')
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    # padding
    def _update_padding(padding, data_format):
        def is_list_or_tuple(ele):
            if isinstance(ele, list) or isinstance(ele, tuple):
                return True
            return False

        if is_list_or_tuple(padding) and len(padding) == 4:
            if is_list_or_tuple(padding[0]) and (data_format == "NCHW"):
                if not (padding[0] == [0, 0] and padding[1] == [0, 0]):
                    raise ValueError(
                        "Non-zero padding(%s) in the batch or channel dimensions "
                        "is not supported." % str(padding))
                padding = padding[2:4]
                padding = [ele for a_list in padding for ele in a_list]
            elif is_list_or_tuple(padding[0]) and (data_format == "NHWC"):
                if not (padding[0] == [0, 0] and padding[3] == [0, 0]):
                    raise ValueError(
                        "Non-zero padding(%s) in the batch or channel dimensions "
                        "is not supported." % str(padding))
                padding = padding[1:3]
                padding = [ele for a_list in padding for ele in a_list]
            padding = utils.convert_to_list(padding, 4, 'padding')
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            if utils._is_symmetric_padding(padding, 2):
                padding = [padding[0], padding[2]]

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        else:
            padding = utils.convert_to_list(padding, 2, 'padding')

        return padding

    padding_algorithm = "EXPLICIT"
    if isinstance(padding, str):
        padding = padding.upper()
        if padding not in ["SAME", "VALID"]:
            raise ValueError(
                "Unknown padding: '%s'. It can only be 'SAME' or 'VALID'." %
                str(padding))
        if padding == "VALID":
            padding_algorithm = "VALID"
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            padding = [0, 0]
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        elif padding == "SAME":
            padding_algorithm = "SAME"
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            padding = [0, 0]
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    padding = _update_padding(padding, data_format)
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    filter_shape = [num_filters, int(num_filter_channels)] + filter_size
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    def _get_default_param_initializer():
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        filter_elem_num = filter_size[0] * filter_size[1] * num_channels
        std = (2.0 / filter_elem_num)**0.5
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        return Normal(0.0, std, 0)

    filter_param = helper.create_parameter(
        attr=helper.param_attr,
        shape=filter_shape,
        dtype=dtype,
        default_initializer=_get_default_param_initializer())

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    pre_bias = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
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        type=l_type,
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        inputs={
            'Input': input,
            'Filter': filter_param,
        },
        outputs={"Output": pre_bias},
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        attrs={
            'strides': stride,
            'paddings': padding,
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            'dilations': dilation,
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            'groups': groups,
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            'use_cudnn': use_cudnn,
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            'use_mkldnn': False,
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            'fuse_relu_before_depthwise_conv': False,
            "padding_algorithm": padding_algorithm,
            "data_format": data_format,
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        })
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    if data_format == 'NCHW':
        pre_act = helper.append_bias_op(pre_bias, dim_start=1, dim_end=2)
    else:
        pre_act = helper.append_bias_op(pre_bias, dim_start=3, dim_end=4)
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    return helper.append_activation(pre_act)


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def conv3d(input,
           num_filters,
           filter_size,
           stride=1,
           padding=0,
           dilation=1,
           groups=None,
           param_attr=None,
           bias_attr=None,
           use_cudnn=True,
           act=None,
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           name=None,
           data_format="NCDHW"):
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    """
    The convolution3D layer calculates the output based on the input, filter
    and strides, paddings, dilations, groups parameters. Input(Input) and
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    Output(Output) are in NCDHW or NDHWC format. Where N is batch size C is the number of
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    channels, D is the depth of the feature, H is the height of the feature,
    and W is the width of the feature. Convlution3D is similar with Convlution2D
    but adds one dimension(depth). If bias attribution and activation type are
    provided, bias is added to the output of the convolution, and the
    corresponding activation function is applied to the final result.
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    For each input :math:`X`, the equation is:

    .. math::

        Out = \sigma (W \\ast X + b)

    In the above equation:

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    * :math:`X`: Input value, a tensor with NCDHW or NDHWC format.
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    * :math:`W`: Filter value, a tensor with MCDHW format.
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    * :math:`\\ast`: Convolution operation.
    * :math:`b`: Bias value, a 2-D tensor with shape [M, 1].
    * :math:`\\sigma`: Activation function.
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    * :math:`Out`: Output value, the shape of :math:`Out` and :math:`X` may be different.
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    Example:

        - Input:

          Input shape: :math:`(N, C_{in}, D_{in}, H_{in}, W_{in})`

          Filter shape: :math:`(C_{out}, C_{in}, D_f, H_f, W_f)`

        - Output:
          Output shape: :math:`(N, C_{out}, D_{out}, H_{out}, W_{out})`

        Where

        .. math::

            D_{out}&= \\frac{(D_{in} + 2 * paddings[0] - (dilations[0] * (D_f - 1) + 1))}{strides[0]} + 1 \\\\
            H_{out}&= \\frac{(H_{in} + 2 * paddings[1] - (dilations[1] * (H_f - 1) + 1))}{strides[1]} + 1 \\\\
            W_{out}&= \\frac{(W_{in} + 2 * paddings[2] - (dilations[2] * (W_f - 1) + 1))}{strides[2]} + 1

    Args:
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        input (Variable): The input is 5-D Tensor with shape [N, C, D, H, W], the data 
            type of input is float16 or float32 or float64.
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        num_filters(int): The number of filter. It is as same as the output
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            image channel.
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        filter_size (int|tuple): The filter size. If filter_size is a tuple,
            it must contain three integers, (filter_size_depth, filter_size_height, 
            filter_size_width). Otherwise, filter_size_depth = filter_size_height = \
            filter_size_width = filter_size.
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        stride (int|tuple): The stride size. It means the stride in convolution. If stride is a 
            tuple, it must contain three integers, (stride_depth, stride_height, stride_width). 
            Otherwise, stride_depth = stride_height = stride_width = stride. Default: stride = 1.
        padding (string|int|list|tuple): The padding size. It means the number of zero-paddings 
            on both sides for each dimention. If `padding` is a string, either 'VALID' or
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            'SAME' which is the padding algorithm. If padding size is a tuple or list,
            it could be in three forms: `[pad_depth, pad_height, pad_width]` or
            `[pad_depth_front, pad_depth_back, pad_height_top, pad_height_bottom, pad_width_left, pad_width_right]`,
            and when `data_format` is `"NCDHW"`, `pool_padding` can be in the form
            `[[0,0], [0,0], [pad_depth_front, pad_depth_back], [pad_height_top, pad_height_bottom], [pad_width_left, pad_width_right]]`.
            when `data_format` is `"NDHWC"`, `pool_padding` can be in the form
            `[[0,0], [pad_depth_front, pad_depth_back], [pad_height_top, pad_height_bottom], [pad_width_left, pad_width_right], [0,0]]`.
            Default: padding = 0.
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        dilation (int|tuple): The dilation size. It means the spacing between the kernel points. 
            If dilation is a tuple, it must contain three integers, (dilation_depth, dilation_height,
            dilation_width). Otherwise, dilation_depth = dilation_height = dilation_width = dilation. 
            Default: dilation = 1.
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        groups (int): The groups number of the Conv3d Layer. According to grouped
            convolution in Alex Krizhevsky's Deep CNN paper: when group=2,
            the first half of the filters is only connected to the first half
            of the input channels, while the second half of the filters is only
            connected to the second half of the input channels. Default: groups=1
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        param_attr (ParamAttr|None): The parameter attribute for learnable parameters/weights
            of conv3d. If it is set to None or one attribute of ParamAttr, conv3d
            will create ParamAttr as param_attr. If it is set to None, the parameter
            is initialized with :math:`Normal(0.0, std)`, and the :math:`std` is
            :math:`(\\frac{2.0 }{filter\_elem\_num})^{0.5}`. Default: None.
        bias_attr (ParamAttr|bool|None): The parameter attribute for the bias of conv3d.
            If it is set to False, no bias will be added to the output units.
            If it is set to None or one attribute of ParamAttr, conv3d
            will create ParamAttr as bias_attr. If the Initializer of the bias_attr
            is not set, the bias is initialized zero. Default: None.
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        use_cudnn (bool): Use cudnn kernel or not, it is valid only when the cudnn
            library is installed. Default: True
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        act (str): Activation type, if it is set to None, activation is not appended.
            Default: None.
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        name(str|None): For detailed information, please refer 
           to :ref:`api_guide_Name`. Usually name is no need to set and 
           None by default.
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        data_format (str, optional): Specify the data format of the input, and the data format of the output 
            will be consistent with that of the input. An optional string from: `"NCHW"`, `"NHWC"`.
            The default is `"NCHW"`. When it is `"NCHW"`, the data is stored in the order of:
            `[batch_size, input_channels, input_height, input_width]`.
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    Returns:
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        A Variable holding Tensor representing the conv3d, whose data type is 
        the same with input. If act is None, the tensor variable storing the 
        convolution result, and if act is not None, the tensor variable storing 
        convolution and non-linearity activation result.
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    Raises:
        ValueError: If the type of `use_cudnn` is not bool.
        ValueError: If `data_format` is not "NCDHW" or "NDHWC".
        ValueError: If the channel dimmention of the input is less than or equal to zero.
        ValueError: If `padding` is a string, but not "SAME" or "VALID".
        ValueError: If `padding` is a tuple, but the element corresponding to the input's batch size is not 0 
            or the element corresponding to the input's channel is not 0.
        ShapeError: If the input is not 5-D Tensor.
        ShapeError: If the input's dimension size and filter's dimension size not equal.
        ShapeError: If the dimension size of input minus the size of `stride` is not 2.
        ShapeError: If the number of input channels is not equal to filter's channels * groups.
        ShapeError: If the number of output channels is not be divided by groups.

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    Examples:
        .. code-block:: python

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          import paddle.fluid as fluid
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          data = fluid.data(name='data', shape=[None, 3, 12, 32, 32], dtype='float32')
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          conv3d = fluid.layers.conv3d(input=data, num_filters=2, filter_size=3, act="relu")
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    """

    l_type = 'conv3d'
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    assert param_attr is not False, "param_attr should not be False here."
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    helper = LayerHelper(l_type, **locals())
    dtype = helper.input_dtype()

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    if not isinstance(use_cudnn, bool):
        raise ValueError("Attr(use_cudnn) should be True or False. Received "
                         "Attr(use_cudnn): %s. " % str(use_cudnn))

    if data_format not in ["NCDHW", "NDHWC"]:
        raise ValueError(
            "Attr(data_format) should be 'NCDHW' or 'NDHWC'. Received "
            "Attr(data_format): %s." % str(data_format))

    channel_last = (data_format == "NDHWC")
    num_channels = input.shape[4] if channel_last else input.shape[1]
    if num_channels < 0:
        raise ValueError(
            "The channel dimmention of the input(%s) should be defined. "
            "Received: %s." % (str(input.shape), str(num_channels)))
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    if groups is None:
        num_filter_channels = num_channels
    else:
        if num_channels % groups != 0:
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            raise ValueError(
                "The number of input channels must be divisible by Attr(groups). "
                "Received: number of channels(%s), groups(%s)." %
                (str(num_channels), str(groups)))
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        num_filter_channels = num_channels // groups
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    filter_size = utils.convert_to_list(filter_size, 3, 'filter_size')
    stride = utils.convert_to_list(stride, 3, 'stride')
    dilation = utils.convert_to_list(dilation, 3, 'dilation')

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    def _update_padding(padding, data_format):
        def is_list_or_tuple(ele):
            if isinstance(ele, list) or isinstance(ele, tuple):
                return True
            return False

        if is_list_or_tuple(padding) and len(padding) == 5:
            if is_list_or_tuple(padding[0]) and (data_format == "NCDHW"):
                if not (padding[0] == [0, 0] and padding[1] == [0, 0]):
                    raise ValueError(
                        "Non-zero padding(%s) in the batch or channel dimensions "
                        "is not supported." % str(padding))
                padding = padding[2:5]
                padding = [ele for a_list in padding for ele in a_list]
            elif is_list_or_tuple(padding[0]) and (data_format == "NDHWC"):
                if not (padding[0] == [0, 0] and padding[4] == [0, 0]):
                    raise ValueError(
                        "Non-zero padding(%s) in the batch or channel dimensions "
                        "is not supported." % str(padding))
                padding = padding[1:4]
                padding = [ele for a_list in padding for ele in a_list]
            padding = utils.convert_to_list(padding, 6, 'padding')
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            if utils._is_symmetric_padding(padding, 3):
                padding = [padding[0], padding[2], padding[4]]
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        elif is_list_or_tuple(padding) and len(padding) == 6:
            padding = utils.convert_to_list(padding, 6, 'padding')
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            if utils._is_symmetric_padding(padding, 3):
                padding = [padding[0], padding[2], padding[4]]
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        else:
            padding = utils.convert_to_list(padding, 3, 'padding')

        return padding

    padding_algorithm = "EXPLICIT"
    if isinstance(padding, str):
        padding = padding.upper()
        if padding not in ["SAME", "VALID"]:
            raise ValueError(
                "Unknown padding: '%s'. It can only be 'SAME' or 'VALID'." %
                str(padding))
        if padding == "VALID":
            padding_algorithm = "VALID"
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            padding = [0, 0, 0]
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        elif padding == "SAME":
            padding_algorithm = "SAME"
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            padding = [0, 0, 0]
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    padding = _update_padding(padding, data_format)
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    input_shape = input.shape
    filter_shape = [num_filters, num_filter_channels] + filter_size

    def _get_default_param_initializer():
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        filter_elem_num = filter_size[0] * filter_size[1] * filter_size[
            2] * num_channels
        std = (2.0 / filter_elem_num)**0.5
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        return Normal(0.0, std, 0)

    filter_param = helper.create_parameter(
        attr=helper.param_attr,
        shape=filter_shape,
        dtype=dtype,
        default_initializer=_get_default_param_initializer())

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    pre_bias = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
        type=l_type,
        inputs={
            'Input': input,
            'Filter': filter_param,
        },
        outputs={"Output": pre_bias},
        attrs={
            'strides': stride,
            'paddings': padding,
            'dilations': dilation,
            'groups': groups,
            'use_cudnn': use_cudnn,
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            'use_mkldnn': False,
            "padding_algorithm": padding_algorithm,
            "data_format": data_format,
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        })

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    if data_format == 'NCDHW':
        pre_act = helper.append_bias_op(pre_bias, dim_start=1, dim_end=2)
    else:
        pre_act = helper.append_bias_op(pre_bias, dim_start=4, dim_end=5)
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    return helper.append_activation(pre_act)


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@templatedoc()
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def pool2d(input,
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           pool_size=-1,
           pool_type="max",
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           pool_stride=1,
           pool_padding=0,
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           global_pooling=False,
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           use_cudnn=True,
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           ceil_mode=False,
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           name=None,
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           exclusive=True,
           data_format="NCHW"):
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    """
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    ${comment}
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    Args:
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        input (Variable): The input tensor of pooling operator which is a 4-D tensor with
                          shape [N, C, H, W]. The format of input tensor is `"NCHW"` or
                          `"NHWC"`, where `N` is batch size, `C` is the number of channels,
                          `H` is the height of the feature, and `W` is the width of the
                          feature. The data type if float32 or float64.
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        pool_size (int|list|tuple): The pool kernel size. If pool kernel size is a tuple or list,
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            it must contain two integers, (pool_size_Height, pool_size_Width).
            Otherwise, the pool kernel size will be a square of an int.
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        pool_type: ${pooling_type_comment}
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        pool_stride (int|list|tuple): The pool stride size. If pool stride size is a tuple or list,
            it must contain two integers, (pool_stride_Height, pool_stride_Width).
            Otherwise, the pool stride size will be a square of an int.
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        pool_padding (string|int|list|tuple): The pool padding. If `pool_padding` is a string, either 'VALID' or
            'SAME' which is the padding algorithm. If pool padding size is a tuple or list,
            it could be in three forms: `[pad_height, pad_width]` or
            `[pad_height_top, pad_height_bottom, pad_width_left, pad_width_right]`, and when `data_format` is `"NCHW"`,
            `pool_padding` can be in the form `[[0,0], [0,0], [pad_height_top, pad_height_bottom], [pad_width_left, pad_width_right]]`.
            when `data_format` is `"NHWC"`, `pool_padding` can be in the form
            `[[0,0], [pad_height_top, pad_height_bottom], [pad_width_left, pad_width_right], [0,0]]`.
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            Otherwise, the pool padding size will be a square of an int.
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        global_pooling (bool): ${global_pooling_comment}
        use_cudnn (bool): ${use_cudnn_comment}
        ceil_mode (bool): ${ceil_mode_comment}
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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
                             None by default.
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        exclusive (bool): Whether to exclude padding points in average pooling
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                          mode, default is `true`.
        data_format (string): The data format of the input and output data. An optional string from: `"NCHW"`, `"NDHW"`.
                The default is `"NCHW"`. When it is `"NCHW"`, the data is stored in the order of:
                `[batch_size, input_channels, input_height, input_width]`.
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    Returns:
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        Variable: The output tensor of pooling result. The data type is same as input tensor.
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    Raises:
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        ValueError: If `pool_type` is not "max" nor "avg".
        ValueError: If `global_pooling` is False and `pool_size` is -1.
        TypeError: If `use_cudnn` is not a bool value.
        ValueError: If `data_format` is not "NCHW" or "NHWC".
        ValueError: If `pool_padding` is a string, but not "SAME" or "VALID".
        ValueError: If `pool_padding` is "VALID", but `ceil_mode` is True.
        ValueError: If `pool_padding` is a list or tuple, but the elements in the batch or channel dimensions are non-zero.
        ShapeError: If the input is not a 4-D or 5-D Tensor.
        ShapeError: If the dimension of input minus the size of `pool_stride` is not 2.
        ShapeError: If the size of `pool_size` and `pool_stride` is not equal.
        ShapeError: If the output's shape calculated is not greater than 0.

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    Examples:

        .. code-block:: python

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          import paddle.fluid as fluid
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          data = fluid.data(name='data', shape=[None, 3, 32, 32], dtype='float32')

          # max pool2d
          pool2d = fluid.layers.pool2d(
            input = data,
            pool_size = 2,
            pool_type = "max",
            pool_stride = 1,
            global_pooling=False)

          # average pool2d
          pool2d = fluid.layers.pool2d(
            input = data,
            pool_size = 2,
            pool_type = "avg",
            pool_stride = 1,
            global_pooling=False)

          # global average pool2d
          pool2d = fluid.layers.pool2d(
            input = data,
            pool_size = 2,
            pool_type = "avg",
            pool_stride = 1,
            global_pooling=True)
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          # Attr(pool_padding) is a list with 4 elements, Attr(data_format) is "NCHW".
          out_1 = fluid.layers.pool2d(
            input = data,
            pool_size = 3,
            pool_type = "avg",
            pool_stride = 1,
            pool_padding = [1, 2, 1, 0],
            data_format = "NCHW")

          # Attr(pool_padding) is a string, Attr(data_format) is "NCHW".
          out_2 = fluid.layers.pool2d(
            input = data,
            pool_size = 3,
            pool_type = "avg",
            pool_stride = 1,
            pool_padding = "VALID",
            data_format = "NCHW")
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    """
    if pool_type not in ["max", "avg"]:
        raise ValueError(
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            "Unknown Attr(pool_type): '%s'. It can only be 'max' or 'avg'.",
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            str(pool_type))
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    if global_pooling is False and pool_size == -1:
        raise ValueError(
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            "When Attr(global_pooling) is False, Attr(pool_size) must be passed "
            "and be a valid value. Received pool_size: %s." % str(pool_size))

    if not isinstance(use_cudnn, bool):
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        raise TypeError("Attr(use_cudnn) should be True or False. Received "
                        "Attr(use_cudnn): %s." % str(use_cudnn))
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    if data_format not in ["NCHW", "NHWC"]:
        raise ValueError(
            "Attr(data_format) should be 'NCHW' or 'NHWC'. Received "
            "Attr(data_format): %s." % str(data_format))
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    pool_size = utils.convert_to_list(pool_size, 2, 'pool_size')
    pool_stride = utils.convert_to_list(pool_stride, 2, 'pool_stride')

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    def update_padding(padding, data_format):
        def is_list_or_tuple(ele):
            if isinstance(ele, list) or isinstance(ele, tuple):
                return True
            return False

        if is_list_or_tuple(padding) and len(padding) == 4:
            if is_list_or_tuple(padding[0]) and (data_format == "NCHW"):
                if not (padding[0] == [0, 0] and padding[1] == [0, 0]):
                    raise ValueError(
                        "Non-zero pool_padding(%s) in the batch or channel dimensions "
                        "is not supported." % str(padding))
                padding = padding[2:4]
                padding = [ele for a_list in padding for ele in a_list]
            elif is_list_or_tuple(padding[0]) and (data_format == "NHWC"):
                if not (padding[0] == [0, 0] and padding[3] == [0, 0]):
                    raise ValueError(
                        "Non-zero pool_padding(%s) in the batch or channel dimensions "
                        "is not supported." % str(padding))
                padding = padding[1:3]
                padding = [ele for a_list in padding for ele in a_list]
            padding = utils.convert_to_list(padding, 4, 'padding')
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            if utils._is_symmetric_padding(padding, 2):
                padding = [padding[0], padding[2]]
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        else:
            padding = utils.convert_to_list(padding, 2, 'padding')

        return padding

    padding_algorithm = "EXPLICIT"
    if isinstance(pool_padding, str):
        pool_padding = pool_padding.upper()
        if pool_padding not in ["SAME", "VALID"]:
            raise ValueError(
                "Unknown Attr(pool_padding): '%s'. It can only be 'SAME' or 'VALID'."
                % str(pool_padding))
        if pool_padding == "VALID":
            padding_algorithm = "VALID"
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            pool_padding = [0, 0]
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            if ceil_mode != False:
                raise ValueError(
                    "When Attr(pool_padding) is \"VALID\", Attr(ceil_mode) must be False. "
                    "Received ceil_mode: True.")
        elif pool_padding == "SAME":
            padding_algorithm = "SAME"
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            pool_padding = [0, 0]
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    pool_padding = update_padding(pool_padding, data_format)

    op_type = 'pool2d'
    helper = LayerHelper(op_type, **locals())
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    dtype = helper.input_dtype()
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    pool_out = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
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        type=op_type,
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        inputs={"X": input},
        outputs={"Out": pool_out},
        attrs={
            "pooling_type": pool_type,
            "ksize": pool_size,
            "global_pooling": global_pooling,
            "strides": pool_stride,
            "paddings": pool_padding,
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            "padding_algorithm": padding_algorithm,
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            "use_cudnn": use_cudnn,
            "ceil_mode": ceil_mode,
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            "use_mkldnn": False,
            "exclusive": exclusive,
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            "data_format": data_format,
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        })

    return pool_out


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@templatedoc()
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def pool3d(input,
           pool_size=-1,
           pool_type="max",
           pool_stride=1,
           pool_padding=0,
           global_pooling=False,
           use_cudnn=True,
           ceil_mode=False,
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           name=None,
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           exclusive=True,
           data_format="NCDHW"):
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    """
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    ${comment}
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    Args:
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        input (Variable): The input tensor of pooling operator, which is a 5-D tensor with
                          shape [N, C, D, H, W]. The format of
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                          input tensor is `"NCDHW"` or `"NDHWC"`, where `N` is batch size, `C` is
                          the number of channels, `D` is the depth of the feature,
                          `H` is the height of the feature, and `W` is the width
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                          of the feature.
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        pool_size (int|list|tuple): The pool kernel size. If pool kernel size 
            is a tuple or list, it must contain three integers, 
            (pool_size_Depth, pool_size_Height, pool_size_Width).
            Otherwise, the pool kernel size will be the cube of an int.
        pool_type (string): ${pooling_type_comment}
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        pool_stride (string|int|list|tuple)): The pool padding. If `pool_padding` is a string, either 'VALID' or
            'SAME' which is the padding algorithm. If pool stride size is a tuple or list,
            it must contain three integers, `[stride_Depth, stride_Height, stride_Width]`.
            Otherwise, the pool stride size will be a cube of an int.
        pool_padding (int|list|tuple): The pool padding size. If pool padding size is a tuple or list,
            it could be in three forms: `[pad_depth, pad_height, pad_width]` or
            `[pad_depth_front, pad_depth_back, pad_height_top, pad_height_bottom, pad_width_left, pad_width_right]`,
            and when `data_format` is `"NCDHW"`, `pool_padding` can be in the form
            `[[0,0], [0,0], [pad_depth_front, pad_depth_back], [pad_height_top, pad_height_bottom], [pad_width_left, pad_width_right]]`.
            when `data_format` is `"NDHWC"`, `pool_padding` can be in the form
            `[[0,0], [pad_depth_front, pad_depth_back], [pad_height_top, pad_height_bottom], [pad_width_left, pad_width_right], [0,0]]`.
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        global_pooling (bool): ${global_pooling_comment}
        use_cudnn (bool): ${use_cudnn_comment}
        ceil_mode (bool): ${ceil_mode_comment}
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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
                             None by default.
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        exclusive (bool): Whether to exclude padding points in average pooling
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                          mode, default is true.
        data_format (string): The data format of the input and output data. An optional string from: `"NCDHW"`, `"NDHWC"`.
                The default is `"NCDHW"`. When it is `"NCDHW"`, the data is stored in the order of:
                `[batch_size, input_channels, input_depth, input_height, input_width]`.
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    Returns:
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        Variable: The output tensor of pooling result. The data type is same as input tensor.
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    Raises:
        ValueError: If `pool_type` is not "max" nor "avg".
        ValueError: If `global_pooling` is False and `pool_size` is -1.
        TypeError: If `use_cudnn` is not a bool value.
        ValueError: If `data_format` is not "NCDHW" or "NDHWC".
        ValueError: If `pool_padding` is a string, but not "SAME" or "VALID".
        ValueError: If `pool_padding` is "VALID", but `ceil_mode` is True.
        ValueError: If `pool_padding` is a list or tuple, but the elements in the batch or channel dimensions are non-zero.
        ShapeError: If the input is not a 4-D or 5-D Tensor.
        ShapeError: If the dimension of input minus the size of `pool_stride` is not 2.
        ShapeError: If the size of `pool_size` and `pool_stride` is not equal.
        ShapeError: If the output's shape calculated is not greater than 0.

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    Examples:

        .. code-block:: python

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          import paddle.fluid as fluid
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          data = fluid.data(name='data', shape=[None, 3, 32, 32, 32], dtype='float32')

          # max pool3d
          pool3d = fluid.layers.pool3d(
            input = data,
            pool_size = 2,
            pool_type = "max",
            pool_stride = 1,
            global_pooling=False)

          # average pool3d
          pool3d = fluid.layers.pool3d(
            input = data,
            pool_size = 2,
            pool_type = "avg",
            pool_stride = 1,
            global_pooling=False)

          # global average pool3d
          pool3d = fluid.layers.pool3d(
            input = data,
            pool_size = 2,
            pool_type = "avg",
            pool_stride = 1,
            global_pooling=True)
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          # example 1:
          # Attr(pool_padding) is a list with 6 elements, Attr(data_format) is "NCDHW".
          out_1 = fluid.layers.pool3d(
            input = data,
            pool_size = 2,
            pool_type = "avg",
            pool_stride = 1,
            pool_padding = [1, 2, 1, 0, 1, 2],
            global_pooling = False,
            data_format = "NCDHW")

          # example 2:
          # Attr(pool_padding) is a string, Attr(data_format) is "NCDHW".
          out_2 = fluid.layers.pool3d(
            input = data,
            pool_size = 3,
            pool_type = "avg",
            pool_stride = 1,
            pool_padding = "VALID",
            global_pooling = False,
            data_format = "NCDHW")

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    """
    if pool_type not in ["max", "avg"]:
        raise ValueError(
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            "Unknown Attr(pool_type): '%s'. It can only be 'max' or 'avg'.",
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            str(pool_type))
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    if global_pooling is False and pool_size == -1:
        raise ValueError(
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            "When Attr(global_pooling) is False, Attr(pool_size) must be passed "
            "and be a valid value. Received Attr(pool_size): %s." %
            str(pool_size))

    if not isinstance(use_cudnn, bool):
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        raise TypeError("Attr(use_cudnn) should be True or False. Received "
                        "Attr(use_cudnn): %s. " % str(use_cudnn))
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    if data_format not in ["NCDHW", "NDHWC"]:
        raise ValueError(
            "Attr(data_format) should be 'NCDHW' or 'NDHWC'. Received "
            "Attr(data_format): %s" % str(data_format))
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    pool_size = utils.convert_to_list(pool_size, 3, 'pool_size')
    pool_stride = utils.convert_to_list(pool_stride, 3, 'pool_stride')
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    def update_padding(padding, data_format):
        def is_list_or_tuple(ele):
            if isinstance(ele, (list, tuple)):
                return True
            return False

        if is_list_or_tuple(padding) and len(padding) == 5:
            if is_list_or_tuple(padding[0]) and (data_format == "NCDHW"):
                if not (padding[0] == [0, 0] and padding[1] == [0, 0]):
                    raise ValueError(
                        "Non-zero pool_padding(%s) in the batch or channel dimensions "
                        "is not supported." % str(padding))
                padding = padding[2:5]
                padding = [ele for a_list in padding for ele in a_list]
            elif is_list_or_tuple(padding[0]) and (data_format == "NDHWC"):
                if not (padding[0] == [0, 0] and padding[4] == [0, 0]):
                    raise ValueError(
                        "Non-zero pool_padding(%s) in the batch or channel dimensions "
                        "is not supported." % str(padding))
                padding = padding[1:4]
                padding = [ele for a_list in padding for ele in a_list]
            padding = utils.convert_to_list(padding, 6, 'padding')
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            if utils._is_symmetric_padding(padding, 3):
                padding = [padding[0], padding[2], padding[4]]
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        elif is_list_or_tuple(padding) and len(padding) == 6:
            padding = utils.convert_to_list(padding, 6, 'padding')
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            if utils._is_symmetric_padding(padding, 3):
                padding = [padding[0], padding[2], padding[4]]
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        else:
            padding = utils.convert_to_list(padding, 3, 'padding')

        return padding

    padding_algorithm = "EXPLICIT"
    if isinstance(pool_padding, str):
        pool_padding = pool_padding.upper()
        if pool_padding not in ["SAME", "VALID"]:
            raise ValueError(
                "Unknown Attr(pool_padding): '%s'. It can only be 'SAME' or 'VALID'."
                % str(pool_padding))
        if pool_padding == "VALID":
            padding_algorithm = "VALID"
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            pool_padding = [0, 0, 0]
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            if ceil_mode != False:
                raise ValueError(
                    "When Attr(pool_padding) is \"VALID\", ceil_mode must be False. "
                    "Received ceil_mode: True.")
        elif pool_padding == "SAME":
            padding_algorithm = "SAME"
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            pool_padding = [0, 0, 0]
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    pool_padding = update_padding(pool_padding, data_format)

    op_type = "pool3d"
    helper = LayerHelper(op_type, **locals())
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    dtype = helper.input_dtype()
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    pool_out = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
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        type=op_type,
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        inputs={"X": input},
        outputs={"Out": pool_out},
        attrs={
            "pooling_type": pool_type,
            "ksize": pool_size,
            "global_pooling": global_pooling,
            "strides": pool_stride,
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            "paddings": pool_padding,
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            "padding_algorithm": padding_algorithm,
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            "use_cudnn": use_cudnn,
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            "ceil_mode": ceil_mode,
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            "use_mkldnn": False,
            "exclusive": exclusive,
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            "data_format": data_format,
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        })

    return pool_out


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@templatedoc(op_type="pool2d")
def adaptive_pool2d(input,
                    pool_size,
                    pool_type="max",
                    require_index=False,
                    name=None):
    """
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    This operation calculates the output based on the input, pool_size,
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    pool_type parameters. Input(X) and output(Out) are in NCHW format, where N is batch
    size, C is the number of channels, H is the height of the feature, and W is
    the width of the feature. Parameters(pool_size) should contain two elements which
    represent height and width, respectively. Also the H and W dimensions of output(Out)
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    is same as Parameter(pool_size). The output tensor shape will be [N, C, pool_size[0], pool_size[1]]
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    For average adaptive pool2d:

    ..  math::

       hstart &= floor(i * H_{in} / H_{out})

       hend &= ceil((i + 1) * H_{in} / H_{out})

       wstart &= floor(j * W_{in} / W_{out})

       wend &= ceil((j + 1) * W_{in} / W_{out})

       Output(i ,j) &= \\frac{sum(Input[hstart:hend, wstart:wend])}{(hend - hstart) * (wend - wstart)}
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    Args:
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        input (Variable): The input tensor of pooling operator, which is a 4-D tensor
                          with shape [N, C, H, W].  The format of input tensor is NCHW,
                          where N is batch size, C is the number of channels, H is the
                          height of the feature, and W is the width of the feature.
                          The data type is float32 or float64.
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        pool_size (int|list|tuple): The pool kernel size. If pool kernel size is a tuple or list,
            it must contain two integers, (pool_size_Height, pool_size_Width).
        pool_type: ${pooling_type_comment}
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        require_index (bool): If true, the index of max pooling point will be returned along
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            with outputs. It cannot be set in average pooling type. Default False.
        name(str, optional): For detailed information, please refer
                             to :ref:`api_guide_Name`. Usually name is no need to set and
                             None by default.
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    Returns:
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        Variable: The output tensor of adaptive pooling result. The data type is same 
                  as input tensor.
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    Raises:
        ValueError: 'pool_type' is not 'max' nor 'avg'.
        ValueError: invalid setting 'require_index' true when 'pool_type' is 'avg'.
        ValueError: 'pool_size' should be a list or tuple with length as 2.

    Examples:
        .. code-block:: python

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          # average adaptive pool2d
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          # suppose input data in shape of [N, C, H, W], `pool_size` is [m, n],
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          # output shape is [N, C, m, n], adaptive pool divide H and W dimentions
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          # of input data into m * n grids averagely and performs poolings in each
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          # grid to get output.
          # adaptive average pool performs calculations as follow:
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          #
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          #     for i in range(m):
          #         for j in range(n):
          #             hstart = floor(i * H / m)
          #             hend = ceil((i + 1) * H / m)
          #             wstart = floor(i * W / n)
          #             wend = ceil((i + 1) * W / n)
          #             output[:, :, i, j] = avg(input[:, :, hstart: hend, wstart: wend])
          #
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          import paddle.fluid as fluid
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          data = fluid.data(name='data', shape=[None, 3, 32, 32], dtype='float32')
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          pool_out = fluid.layers.adaptive_pool2d(
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                            input=data,
                            pool_size=[3, 3],
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                            pool_type='avg')
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          # max adaptive pool2d
          # suppose input data in shape of [N, C, H, W], `pool_size` is [m, n],
          # output shape is [N, C, m, n], adaptive pool divide H and W dimentions
          # of input data into m * n grids averagely and performs poolings in each
          # grid to get output.
          # adaptive average pool performs calculations as follow:
          #
          #     for i in range(m):
          #         for j in range(n):
          #             hstart = floor(i * H / m)
          #             hend = ceil((i + 1) * H / m)
          #             wstart = floor(i * W / n)
          #             wend = ceil((i + 1) * W / n)
          #             output[:, :, i, j] = max(input[:, :, hstart: hend, wstart: wend])
          #
          import paddle.fluid as fluid
          data = fluid.data(name='data', shape=[None, 3, 32, 32], dtype='float32')
          pool_out = fluid.layers.adaptive_pool2d(
                            input=data,
                            pool_size=[3, 3],
                            pool_type='max')
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    """
    if pool_type not in ["max", "avg"]:
        raise ValueError(
            "Unknown pool_type: '%s'. It can only be 'max' or 'avg'.",
            str(pool_type))

    if pool_type == "avg" and require_index:
        raise ValueError(
            "invalid setting 'require_index' true when 'pool_type' is 'avg'.")

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    pool_size = utils.convert_to_list(pool_size, 2, 'pool_size')
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    if pool_type == "max":
        l_type = 'max_pool2d_with_index'
    else:
        l_type = "pool2d"

    helper = LayerHelper(l_type, **locals())
    dtype = helper.input_dtype()
    pool_out = helper.create_variable_for_type_inference(dtype)

    outputs = {"Out": pool_out}
    if pool_type == "max":
        mask = helper.create_variable_for_type_inference(dtype)
        outputs["Mask"] = mask

    helper.append_op(
        type=l_type,
        inputs={"X": input},
        outputs=outputs,
        attrs={
            "pooling_type": pool_type,
            "ksize": pool_size,
            "adaptive": True,
        })

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    return (pool_out, mask) if require_index else pool_out
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@templatedoc(op_type="pool3d")
def adaptive_pool3d(input,
                    pool_size,
                    pool_type="max",
                    require_index=False,
                    name=None):
    """
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    This operation calculates the output based on the input, pool_size,
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    pool_type parameters. Input(X) and output(Out) are in NCDHW format, where N is batch
    size, C is the number of channels, D is the depth of the feature, H is the height of
    the feature, and W is the width of the feature. Parameters(pool_size) should contain
    three elements which represent height and width, respectively. Also the D, H and W
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    dimensions of output(Out) is same as Parameter(pool_size). The output tensor shape
    will be [N, C, pool_size[0], pool_size[1], pool_size[2]]
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    For average adaptive pool3d:

    ..  math::

      dstart &= floor(i * D_{in} / D_{out})

      dend &= ceil((i + 1) * D_{in} / D_{out})

      hstart &= floor(j * H_{in} / H_{out})

      hend &= ceil((j + 1) * H_{in} / H_{out})

      wstart &= floor(k * W_{in} / W_{out})

      wend &= ceil((k + 1) * W_{in} / W_{out})

      Output(i ,j, k) &= \\frac{sum(Input[dstart:dend, hstart:hend, wstart:wend])}{(dend - dstart) * (hend - hstart) * (wend - wstart)}
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    Args:
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        input (Variable): The input tensor of pooling operator, which is a 5-D tensor with 
                          shape [N, C, D, H, W]. The format of input tensor is NCDHW, where
                          N is batch size, C is the number of channels, D is the depth of the feature,
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                          H is the height of the feature, and W is the width of the feature.
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                          The data type is float32 or float64.
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        pool_size (int|list|tuple): The pool kernel size. If pool kernel size is a tuple or list,
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            it must contain three integers, (Depth, Height, Width).
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        pool_type: ${pooling_type_comment}
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        require_index (bool): If true, the index of max pooling point will be returned along
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            with outputs. It cannot be set in average pooling type. Default False.
        name(str, optional): For detailed information, please refer
                             to :ref:`api_guide_Name`. Usually name is no need to set and
                             None by default.
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    Returns:
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        Variable: The output tensor of adaptive pooling result. The data type is same as input tensor.
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    Raises:
        ValueError: 'pool_type' is not 'max' nor 'avg'.
        ValueError: invalid setting 'require_index' true when 'pool_type' is 'avg'.
        ValueError: 'pool_size' should be a list or tuple with length as 2.

    Examples:
        .. code-block:: python

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          # average adaptive pool3d
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          # suppose input data in shape of [N, C, D, H, W], `pool_size` is [l, m, n],
          # output shape is [N, C, l, m, n], adaptive pool divide D, H and W dimentions
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          # of input data into l * m * n grids averagely and performs poolings in each
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          # grid to get output.
          # adaptive average pool performs calculations as follow:
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          #
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          #     for i in range(l):
          #         for j in range(m):
          #             for k in range(n):
          #                 dstart = floor(i * D / l)
          #                 dend = ceil((i + 1) * D / l)
          #                 hstart = floor(j * H / m)
          #                 hend = ceil((j + 1) * H / m)
          #                 wstart = floor(k * W / n)
          #                 wend = ceil((k + 1) * W / n)
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          #                 output[:, :, i, j, k] =
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          #                     avg(input[:, :, dstart:dend, hstart: hend, wstart: wend])
          #
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          import paddle.fluid as fluid

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          data = fluid.data(
              name='data', shape=[None, 3, 32, 32, 32], dtype='float32')
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          pool_out = fluid.layers.adaptive_pool3d(
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                            input=data,
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                            pool_size=[3, 3, 3],
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                            pool_type='avg')
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          # max adaptive pool3d
          # suppose input data in shape of [N, C, D, H, W], `pool_size` is [l, m, n],
          # output shape is [N, C, l, m, n], adaptive pool divide D, H and W dimentions
          # of input data into l * m * n grids averagely and performs poolings in each
          # grid to get output.
          # adaptive average pool performs calculations as follow:
          #
          #     for i in range(l):
          #         for j in range(m):
          #             for k in range(n):
          #                 dstart = floor(i * D / l)
          #                 dend = ceil((i + 1) * D / l)
          #                 hstart = floor(j * H / m)
          #                 hend = ceil((j + 1) * H / m)
          #                 wstart = floor(k * W / n)
          #                 wend = ceil((k + 1) * W / n)
          #                 output[:, :, i, j, k] =
          #                     avg(input[:, :, dstart:dend, hstart: hend, wstart: wend])
          #

          import paddle.fluid as fluid

          data = fluid.data(
              name='data', shape=[None, 3, 32, 32, 32], dtype='float32')
          pool_out = fluid.layers.adaptive_pool3d(
                            input=data,
                            pool_size=[3, 3, 3],
                            pool_type='max')
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    """
    if pool_type not in ["max", "avg"]:
        raise ValueError(
            "Unknown pool_type: '%s'. It can only be 'max' or 'avg'.",
            str(pool_type))

    if pool_type == "avg" and require_index:
        raise ValueError(
            "invalid setting 'require_index' true when 'pool_type' is 'avg'.")

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    pool_size = utils.convert_to_list(pool_size, 3, 'pool_size')
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    if pool_type == "max":
        l_type = 'max_pool3d_with_index'
    else:
        l_type = "pool3d"

    helper = LayerHelper(l_type, **locals())
    dtype = helper.input_dtype()
    pool_out = helper.create_variable_for_type_inference(dtype)

    outputs = {"Out": pool_out}
    if pool_type == "max":
        mask = helper.create_variable_for_type_inference(dtype)
        outputs["Mask"] = mask

    helper.append_op(
        type=l_type,
        inputs={"X": input},
        outputs=outputs,
        attrs={
            "pooling_type": pool_type,
            "ksize": pool_size,
            "adaptive": True,
        })

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    return (pool_out, mask) if require_index else pool_out
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def batch_norm(input,
               act=None,
               is_test=False,
               momentum=0.9,
               epsilon=1e-05,
               param_attr=None,
               bias_attr=None,
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               data_layout='NCHW',
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               in_place=False,
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               name=None,
               moving_mean_name=None,
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               moving_variance_name=None,
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               do_model_average_for_mean_and_var=True,
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               use_global_stats=False):
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    """
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    **Batch Normalization Layer**

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    Can be used as a normalizer function for convolution or fully_connected operations.
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    The required data format for this layer is one of the following:
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    1. NHWC `[batch, in_height, in_width, in_channels]`
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    2. NCHW `[batch, in_channels, in_height, in_width]`

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    Refer to `Batch Normalization: Accelerating Deep Network Training by Reducing
    Internal Covariate Shift <https://arxiv.org/pdf/1502.03167.pdf>`_
    for more details.
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    :math:`input` is the input features over a mini-batch.

    ..  math::

        \\mu_{\\beta} &\\gets \\frac{1}{m} \\sum_{i=1}^{m} x_i \\qquad &//\\
        \ mini-batch\ mean \\\\
        \\sigma_{\\beta}^{2} &\\gets \\frac{1}{m} \\sum_{i=1}^{m}(x_i - \\
        \\mu_{\\beta})^2 \\qquad &//\ mini-batch\ variance \\\\
        \\hat{x_i} &\\gets \\frac{x_i - \\mu_\\beta} {\\sqrt{\\
        \\sigma_{\\beta}^{2} + \\epsilon}} \\qquad &//\ normalize \\\\
        y_i &\\gets \\gamma \\hat{x_i} + \\beta \\qquad &//\ scale\ and\ shift
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        moving\_mean = moving\_mean * momentum + mini-batch\_mean * (1. - momentum) \\\\
        moving\_var = moving\_var * momentum + mini-batch\_var * (1. - momentum) 

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    moving_mean is global mean and moving_var is global variance.
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    When use_global_stats = True, the :math:`\\mu_{\\beta}`
    and :math:`\\sigma_{\\beta}^{2}` are not the statistics of one mini-batch.
    They are global (or running) statistics. (It usually got from the
    pre-trained model.)
    The training and testing (or inference) have the same behavior:

    ..  math::

        \\hat{x_i} &\\gets \\frac{x_i - \\mu_\\beta} {\\sqrt{\\
        \\sigma_{\\beta}^{2} + \\epsilon}}  \\\\
        y_i &\\gets \\gamma \\hat{x_i} + \\beta

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    Note:
        if build_strategy.sync_batch_norm=True, the batch_norm in network will use 
        sync_batch_norm automatically.
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        `is_test = True` can only be used in test program and inference program, `is_test` CANNOT be set to True in train program, if you want to use global status from pre_train model in train program, please set `use_global_stats = True`.
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    Args:
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        input(Variable): The rank of input variable can be 2, 3, 4, 5. The data type 
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            is float16 or float32 or float64.
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        act(string, Default None): Activation type, linear|relu|prelu|...
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        is_test (bool, Default False): A flag indicating whether it is in
            test phrase or not.
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        momentum(float|Variable, Default 0.9): The value used for the moving_mean and
            moving_var computation. This should be a float number or a Variable with
            shape [1] and data type as float32. The updated formula is:
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            :math:`moving\_mean = moving\_mean * momentum + new\_mean * (1. - momentum)`
            :math:`moving\_var = moving\_var * momentum + new\_var * (1. - momentum)`
            Default is 0.9.
        epsilon(float, Default 1e-05): A value added to the denominator for
            numerical stability. Default is 1e-5.
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        param_attr(ParamAttr|None): The parameter attribute for Parameter `scale`
             of batch_norm. If it is set to None or one attribute of ParamAttr, batch_norm
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	     will create ParamAttr as param_attr, the name of scale can be set in ParamAttr.
	     If the Initializer of the param_attr is not set, the parameter is initialized 
	     with Xavier. Default: None.
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        bias_attr(ParamAttr|None): The parameter attribute for the bias of batch_norm.
             If it is set to None or one attribute of ParamAttr, batch_norm
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	     will create ParamAttr as bias_attr, the name of bias can be set in ParamAttr. 
	     If the Initializer of the bias_attr is not set, the bias is initialized zero. 
	     Default: None.
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        data_layout (str, optional): Specify the data format of the input, and the data format of the output 
            will be consistent with that of the input. An optional string from: `"NCHW"`, `"NHWC"`.
            The default is `"NCHW"`. When it is `"NCHW"`, the data is stored in the order of:
            `[batch_size, input_channels, input_height, input_width]`.
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        in_place(bool, Default False): Make the input and output of batch norm reuse memory.
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        name(str|None): For detailed information, please refer to :ref:`api_guide_Name`. 
            Usually name is no need to set and None by default. 
        moving_mean_name(str, Default None): The name of moving_mean which store the global Mean. If it 
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            is set to None, batch_norm will save global mean with a random name, otherwise, batch_norm 
            will save global mean with the string.
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        moving_variance_name(str, Default None): The name of the moving_variance which store the global Variance.
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            If it is set to None, batch_norm will save global variance with a random name, otherwise, batch_norm 
            will save global variance with the string.
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        do_model_average_for_mean_and_var(bool, Default True): Whether parameter mean and variance should do model
            average when model average is enabled.
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        use_global_stats(bool, Default False): Whether to use global mean and
            variance. In inference or test mode, set use_global_stats to true
            or is_test to true, and the behavior is equivalent.
            In train mode, when setting use_global_stats True, the global mean
            and variance are also used during train period.
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    Returns:
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        A Variable holding Tensor which is the result after applying batch normalization on the input, 
        has same shape and data type with input. 
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    Examples:

        .. code-block:: python

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            import paddle.fluid as fluid
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            x = fluid.data(name='x', shape=[3, 7, 3, 7], dtype='float32')
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            hidden1 = fluid.layers.fc(input=x, size=200, param_attr='fc1.w')
            hidden2 = fluid.layers.batch_norm(input=hidden1)
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        .. code-block:: python

            # batch_norm with momentum as Variable
            import paddle.fluid as fluid
            import paddle.fluid.layers.learning_rate_scheduler as lr_scheduler

            def get_decay_momentum(momentum_init, decay_steps, decay_rate):
                global_step = lr_scheduler._decay_step_counter()
                momentum = fluid.layers.create_global_var(
		    shape=[1],
		    value=float(momentum_init),
		    dtype='float32',
		    # set persistable for save checkpoints and resume
		    persistable=True,
		    name="momentum")
                div_res = global_step / decay_steps
                decayed_momentum = momentum_init * (decay_rate**div_res)
                fluid.layers.assign(decayed_momentum, momentum)

                return momentum

            x = fluid.data(name='x', shape=[3, 7, 3, 7], dtype='float32')
            hidden1 = fluid.layers.fc(input=x, size=200, param_attr='fc1.w')
            momentum = get_decay_momentum(0.9, 1e5, 0.9)
            hidden2 = fluid.layers.batch_norm(input=hidden1, momentum=momentum)

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    """
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    assert bias_attr is not False, "bias_attr should not be False in batch_norm."
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    helper = LayerHelper('batch_norm', **locals())

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    check_type_and_dtype(input, 'input', Variable,
                         ['float16', 'float32', 'float64'], 'batch_norm')
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    dtype = helper.input_dtype()
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    has_reserve_space = False
    if data_layout == 'NHWC':
        flag = os.environ.get('FLAGS_cudnn_batchnorm_spatial_persistent')
        if flag is not None and flag.lower() in ['true', '1']:
            has_reserve_space = True

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    # use fp32 for bn parameter
    if dtype == core.VarDesc.VarType.FP16:
        dtype = core.VarDesc.VarType.FP32

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    input_shape = input.shape
    if data_layout == 'NCHW':
        channel_num = input_shape[1]
    else:
        if data_layout == 'NHWC':
            channel_num = input_shape[-1]
        else:
            raise ValueError("unsupported data layout:" + data_layout)

    param_shape = [channel_num]

    # create parameter
    scale = helper.create_parameter(
        attr=helper.param_attr,
        shape=param_shape,
        dtype=dtype,
        default_initializer=Constant(1.0))
    bias = helper.create_parameter(
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        attr=helper.bias_attr, shape=param_shape, dtype=dtype, is_bias=True)
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    mean = helper.create_parameter(
        attr=ParamAttr(
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            name=moving_mean_name,
            initializer=Constant(0.0),
            trainable=False,
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            do_model_average=do_model_average_for_mean_and_var),
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        shape=param_shape,
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        dtype=dtype)
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    mean.stop_gradient = True

    variance = helper.create_parameter(
        attr=ParamAttr(
            name=moving_variance_name,
            initializer=Constant(1.0),
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            trainable=False,
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            do_model_average=do_model_average_for_mean_and_var),
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        shape=param_shape,
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        dtype=dtype)
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    variance.stop_gradient = True
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    # create output
    # mean and mean_out share the same memory
    mean_out = mean
    # variance and variance out share the same memory
    variance_out = variance
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    saved_mean = helper.create_variable_for_type_inference(
        dtype=dtype, stop_gradient=True)
    saved_variance = helper.create_variable_for_type_inference(
        dtype=dtype, stop_gradient=True)
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    reserve_space = None
    if has_reserve_space:
        reserve_space = helper.create_variable_for_type_inference(
            dtype=core.VarDesc.VarType.FP16, stop_gradient=True)

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    batch_norm_out = input if in_place else helper.create_variable_for_type_inference(
        dtype)
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    inputs = {
        "X": input,
        "Scale": scale,
        "Bias": bias,
        "Mean": mean,
        "Variance": variance
    }
    attrs = {
        "epsilon": epsilon,
        "is_test": is_test,
        "data_layout": data_layout,
        "use_mkldnn": False,
        "fuse_with_relu": False,
        "use_global_stats": use_global_stats
    }
    if isinstance(momentum, Variable):
        inputs['MomemtumTensor'] = momentum
    else:
        attrs['momentum'] = momentum
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    outputs = {
        "Y": batch_norm_out,
        "MeanOut": mean_out,
        "VarianceOut": variance_out,
        "SavedMean": saved_mean,
        "SavedVariance": saved_variance
    }
    if reserve_space is not None:
        outputs["ReserveSpace"] = reserve_space

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    helper.append_op(
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        type="batch_norm", inputs=inputs, outputs=outputs, attrs=attrs)
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    return helper.append_activation(batch_norm_out)


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def instance_norm(input,
                  epsilon=1e-05,
                  param_attr=None,
                  bias_attr=None,
                  name=None):
    """
    **Instance Normalization Layer**

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    Can be used as a normalizer function for convolution or fully_connected operations.
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    The required data format for this layer is one of the following:

    DataLayout: NCHW `[batch, in_channels, in_height, in_width]`

    Refer to `Instance Normalization: The Missing Ingredient for 
    Fast Stylization <https://arxiv.org/pdf/1607.08022.pdf>`_
    for more details.

    :math:`input` is the input features over a mini-batch.

    ..  math::

        \\mu_{\\beta} &\\gets \\frac{1}{HW} \\sum_{i=1}^{HW} x_i \\qquad &//\\
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        \\ mean\ of\ one\  feature\ map\ in\ mini-batch \\\\
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        \\sigma_{\\beta}^{2} &\\gets \\frac{1}{HW} \\sum_{i=1}^{HW}(x_i - \\
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        \\mu_{\\beta})^2 \\qquad &//\ variance\ of\ one\ feature\ map\ in\ mini-batch \\\\
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        \\hat{x_i} &\\gets \\frac{x_i - \\mu_\\beta} {\\sqrt{\\
        \\sigma_{\\beta}^{2} + \\epsilon}} \\qquad &//\ normalize \\\\
        y_i &\\gets \\gamma \\hat{x_i} + \\beta \\qquad &//\ scale\ and\ shift

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    Note:
        `H` means height of feature map, `W` means width of feature map.
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    Args:
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        input(variable): The rank of input variable can be 2, 3, 4, 5. 
            The data type is float32 or float64.
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        epsilon(float, Default 1e-05): A value added to the denominator for
            numerical stability. Default is 1e-5.
        param_attr(ParamAttr|None): The parameter attribute for Parameter `scale`
             of instance_norm. If it is set to None or one attribute of ParamAttr, instance_norm
	     will create ParamAttr as param_attr, the name of scale can be set in ParamAttr.
	     If the Initializer of the param_attr is not set, the parameter is initialized 
	     with Xavier. Default: None.
        bias_attr(ParamAttr|None): The parameter attribute for the bias of instance_norm.
             If it is set to None or one attribute of ParamAttr, instance_norm
	     will create ParamAttr as bias_attr, the name of bias can be set in ParamAttr. 
	     If the Initializer of the bias_attr is not set, the bias is initialized zero. 
	     Default: None.
        name(string, Default None): A name for this layer(optional). If set None, the layer
            will be named automatically.

    Returns:
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        A Variable holding Tensor which is the result after applying instance normalization on the input, 
        has same shape and data type with input. 
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    Examples:

        .. code-block:: python

            import paddle.fluid as fluid
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            x = fluid.data(name='x', shape=[3, 7, 3, 7], dtype='float32')
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            hidden1 = fluid.layers.fc(input=x, size=200, param_attr='fc1.w')
            hidden2 = fluid.layers.instance_norm(input=hidden1)
    """
    assert bias_attr is not False, "bias_attr should not be False in instance_norm."
    helper = LayerHelper('instance_norm', **locals())
    dtype = helper.input_dtype()

    # use fp32 for in parameter
    if dtype == core.VarDesc.VarType.FP16:
        dtype = core.VarDesc.VarType.FP32

    input_shape = input.shape
    channel_num = input_shape[1]

    param_shape = [channel_num]

    # create parameter
    scale = helper.create_parameter(
        attr=helper.param_attr,
        shape=param_shape,
        dtype=dtype,
        default_initializer=Constant(1.0))
    bias = helper.create_parameter(
        attr=helper.bias_attr,
        shape=param_shape,
        dtype=dtype,
        is_bias=True,
        default_initializer=Constant(0.0))

    # create output
    saved_mean = helper.create_variable_for_type_inference(
        dtype=dtype, stop_gradient=True)
    saved_variance = helper.create_variable_for_type_inference(
        dtype=dtype, stop_gradient=True)

    instance_norm_out = helper.create_variable_for_type_inference(dtype)

    helper.append_op(
        type="instance_norm",
        inputs={
            "X": input,
            "Scale": scale,
            "Bias": bias,
        },
        outputs={
            "Y": instance_norm_out,
            "SavedMean": saved_mean,
            "SavedVariance": saved_variance
        },
        attrs={"epsilon": epsilon, })

    return instance_norm_out


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def data_norm(input,
              act=None,
              epsilon=1e-05,
              param_attr=None,
              data_layout='NCHW',
              in_place=False,
              name=None,
              moving_mean_name=None,
              moving_variance_name=None,
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              do_model_average_for_mean_and_var=True,
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              slot_dim=-1,
              sync_stats=False,
              summary_decay_rate=0.9999999):
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    """
    **Data Normalization Layer**

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    This op can be used as a normalizer function for conv2d and fully_connected operations.
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    The required data format for this layer is one of the following:

    1. NHWC `[batch, in_height, in_width, in_channels]`

    2. NCHW `[batch, in_channels, in_height, in_width]`

    :math:`input` is the input features over a mini-batch.

    ..  math::

        \\mu_{\\beta} &\\gets \\frac{1}{m} \\sum_{i=1}^{m} x_i \\qquad &//\\
        \ mini-batch\ mean \\\\
        \\sigma_{\\beta}^{2} &\\gets \\frac{1}{m} \\sum_{i=1}^{m}(x_i - \\
        \\mu_{\\beta})^2 \\qquad &//\ mini-batch\ variance \\\\
        \\hat{x_i} &\\gets \\frac{x_i - \\mu_\\beta} {\\sqrt{\\
        \\sigma_{\\beta}^{2} + \\epsilon}} \\qquad &//\ normalize \\\\
        y_i &\\gets \\gamma \\hat{x_i} + \\beta \\qquad &//\ scale\ and\ shift

    Args:
        input(variable): The input variable which is a LoDTensor.
        act(string, Default None): Activation type, linear|relu|prelu|...
        epsilon(float, Default 1e-05):
        param_attr(ParamAttr): The parameter attribute for Parameter `scale`.
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        data_layout (str, optional): Specify the data format of the input, and the data format of the output 
            will be consistent with that of the input. An optional string from: `"NCHW"`, `"NHWC"`.
            The default is `"NCHW"`. When it is `"NCHW"`, the data is stored in the order of:
            `[batch_size, input_channels, input_height, input_width]`.
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        in_place(bool, Default False): Make the input and output of batch norm reuse memory.
        name(string, Default None): A name for this layer(optional). If set None, the layer
            will be named automatically.
        moving_mean_name(string, Default None): The name of moving_mean which store the global Mean.
        moving_variance_name(string, Default None): The name of the moving_variance which store the global Variance.
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        do_model_average_for_mean_and_var(bool, Default True): Whether parameter mean and variance
            should do model average when model average is enabled.
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        slot_dim(int): The embedding dimension of one slot. Slot is a set of one specific feature. In pslib mode, we 
            distinguish feature ids by slot and pull their embeddings from parameter server (pslib). The first
            place of the embedding is the historical show number (occurence time of this feature id with a label 0).
            If the input of this op is concated by slot-wise embeddings, and the show number is zero when this slot 
            is new or empty, the normalization result may be impractical. To avoid this, we add slot_dim to locate 
            the show number and judge if the show number is zero. If so, we choose to skip normalization on this
            embedding.
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        sync_stats(bool, Default False): When running with multiple GPU cards, using allreduce to sync the
            summary messages.
        summary_decay_rate(float, Default 0.9999999): The decay rate when updating summary.
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    Returns:
        Variable: A tensor variable which is the result after applying data normalization on the input.

    Examples:

        .. code-block:: python
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            import paddle.fluid as fluid
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            hidden1 = fluid.data(name="hidden1", shape=[64, 200])
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            hidden2 = fluid.layers.data_norm(name="hidden2", input=hidden1)
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    """
    helper = LayerHelper('data_norm', **locals())
    dtype = helper.input_dtype()

    input_shape = input.shape
    if data_layout == 'NCHW':
        channel_num = input_shape[1]
    else:
        if data_layout == 'NHWC':
            channel_num = input_shape[-1]
        else:
            raise ValueError("unsupported data layout:" + data_layout)

    param_shape = [channel_num]

    batch_size_default = 1e4
    batch_sum_default = 0.0
    batch_square_sum_default = 1e4

    if param_attr and isinstance(param_attr, dict):
        batch_size_default = param_attr.get("batch_size", 1e4)
        batch_sum_default = param_attr.get("batch_sum", 0.0)
        batch_square_sum_default = param_attr.get("batch_square", 1e4)

    # create parameter
    batch_size = helper.create_parameter(
        attr=ParamAttr(
            name=name + '.batch_size',
            initializer=Constant(value=float(batch_size_default)),
            trainable=True),
        shape=param_shape,
        dtype=input.dtype)

    batch_sum = helper.create_parameter(
        attr=ParamAttr(
            name=name + '.batch_sum',
            initializer=Constant(value=float(batch_sum_default)),
            trainable=True),
        shape=param_shape,
        dtype=input.dtype)

    batch_square_sum = helper.create_parameter(
        attr=ParamAttr(
            name=name + '.batch_square_sum',
            initializer=Constant(value=float(batch_square_sum_default)),
            trainable=True),
        shape=param_shape,
        dtype=input.dtype)

    means = helper.create_variable(dtype=dtype, stop_gradient=True)
    scales = helper.create_variable(dtype=dtype, stop_gradient=True)

    data_norm_out = input if in_place else helper.create_variable(dtype=dtype)

    helper.append_op(
        type="data_norm",
        inputs={
            "X": input,
            "BatchSize": batch_size,
            "BatchSum": batch_sum,
            "BatchSquareSum": batch_square_sum
        },
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        outputs={
            "Y": data_norm_out,
            "Means": means,
            "Scales": scales,
            "BatchSize": batch_size,
            "BatchSum": batch_sum,
            "BatchSquareSum": batch_square_sum
        },
        attrs={
            "epsilon": epsilon,
            "slot_dim": slot_dim,
            "sync_stats": sync_stats,
            "summary_decay_rate": summary_decay_rate
        })
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    return helper.append_activation(data_norm_out)


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@templatedoc()
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def layer_norm(input,
               scale=True,
               shift=True,
               begin_norm_axis=1,
               epsilon=1e-05,
               param_attr=None,
               bias_attr=None,
               act=None,
               name=None):
    """
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    **Layer Normalization Layer**

    The API implements the function of the Layer Normalization Layer and can be applied to mini-batch input data.
    Refer to `Layer Normalization <https://arxiv.org/pdf/1607.06450v1.pdf>`_
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    The formula is as follows:

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    ..  math::
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        \\mu & = \\frac{1}{H}\\sum_{i=1}^{H} x_i
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        \\sigma & = \\sqrt{\\frac{1}{H}\sum_{i=1}^{H}{(x_i - \\mu)^2} + \\epsilon}
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        y & = f(\\frac{g}{\\sigma}(x - \\mu) + b)
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    - :math:`x`: the vector representation of the summed inputs to the neurons in that layer.
    - :math:`H`: the number of hidden units in a layers
    - :math:`\\epsilon`: the small value added to the variance to prevent division by zero.
    - :math:`g`: the trainable scale parameter.
    - :math:`b`: the trainable bias parameter.
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    Args:
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        input(Variable): A multi-dimension ``Tensor`` , and the data type is float32 or float64.
        scale(bool, optional): Whether to learn the adaptive gain :math:`g` after
            normalization. Default: True.
        shift(bool, optional): Whether to learn the adaptive bias :math:`b` after
            normalization. Default: True.
        begin_norm_axis(int, optional): The normalization will be performed along
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            dimensions from :attr:`begin_norm_axis` to :attr:`rank(input)`.
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            Default: 1.
        epsilon(float, optional): The small value added to the variance to prevent
            division by zero. Default: 1e-05.
        param_attr(ParamAttr, optional): The parameter attribute for the learnable
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            gain :math:`g`. If :attr:`scale` is False, :attr:`param_attr` is
            omitted. If :attr:`scale` is True and :attr:`param_attr` is None,
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            a default :code:`ParamAttr` would be added as scale. The
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            :attr:`param_attr` is initialized as 1 if it is added. Default: None.
        bias_attr(ParamAttr, optional): The parameter attribute for the learnable
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            bias :math:`b`. If :attr:`shift` is False, :attr:`bias_attr` is
            omitted. If :attr:`shift` is True and :attr:`param_attr` is None,
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            a default :code:`ParamAttr` would be added as bias. The
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            :attr:`bias_attr` is initialized as 0 if it is added. Default: None.
        act(str, optional): Activation to be applied to the output of layer normalizaiton.
                  Default: None.
        name(str): The default value is None.  Normally there is no need for user to set this property.  For more information, please refer to :ref:`api_guide_Name` .
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    Returns:
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        Variable: ``Tensor``  indicating the normalized result, the data type is the same as  ``input`` , and the return dimension is the same as  ``input`` .
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    Examples:

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        .. code-block:: python

            import paddle.fluid as fluid
            import numpy as np
            x = fluid.data(name='x', shape=[-1, 32, 32], dtype='float32')
            hidden1 = fluid.layers.layer_norm(input=x, begin_norm_axis=1)
            place = fluid.CPUPlace()
            exe = fluid.Executor(place)
            exe.run(fluid.default_startup_program())
            np_x = np.random.random(size=(8, 3, 32, 32)).astype('float32')
            output = exe.run(feed={"x": np_x}, fetch_list = [hidden1])
            print(output)
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    """
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    assert in_dygraph_mode(
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    ) is not True, "please use LayerNorm instead of layer_norm in dygraph mode!"
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    helper = LayerHelper('layer_norm', **locals())
    dtype = helper.input_dtype()

    # create intput and parameters
    inputs = {'X': input}
    input_shape = input.shape
    param_shape = [reduce(lambda x, y: x * y, input_shape[begin_norm_axis:])]
    if scale:
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        assert param_attr is not False, "param_attr should not be False when using scale."
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        scale = helper.create_parameter(
            attr=helper.param_attr,
            shape=param_shape,
            dtype=dtype,
            default_initializer=Constant(1.0))
        inputs['Scale'] = scale
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    else:
        if param_attr:
            warnings.warn("param_attr is only avaliable with scale is True.")
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    if shift:
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        assert bias_attr is not False, "bias_attr should not be False when using shift."
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        bias = helper.create_parameter(
            attr=helper.bias_attr, shape=param_shape, dtype=dtype, is_bias=True)
        inputs['Bias'] = bias
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    else:
        if bias_attr:
            warnings.warn("bias_attr is only avaliable with shift is True.")
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    # create output
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    mean_out = helper.create_variable_for_type_inference(
        dtype=dtype, stop_gradient=True)
    variance_out = helper.create_variable_for_type_inference(
        dtype=dtype, stop_gradient=True)
    layer_norm_out = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
        type="layer_norm",
        inputs=inputs,
        outputs={
            "Y": layer_norm_out,
            "Mean": mean_out,
            "Variance": variance_out,
        },
        attrs={"epsilon": epsilon,
               "begin_norm_axis": begin_norm_axis})

    return helper.append_activation(layer_norm_out)


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@templatedoc()
def group_norm(input,
               groups,
               epsilon=1e-05,
               param_attr=None,
               bias_attr=None,
               act=None,
               data_layout='NCHW',
               name=None):
    """
    **Group Normalization Layer**

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    Refer to `Group Normalization <https://arxiv.org/abs/1803.08494>`_ .
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    Parameters:
        input(Variable): 4-D Tensor, the data type is float32 or float64.
        groups(int): The number of groups that divided from channels, the data type
            is int32.
        epsilon(float, optional): The small value added to the variance to prevent
            division by zero, the data type is float32. Default: 1e-05.
        param_attr(ParamAttr|bool, optional): ParamAttr object that specifies weight parameter
            attribute. If a bool type, only False is supported, which means there is no weight parameter.
            Default: None, the default weight parameter attribute is used. For more information, please
            refer to :ref:`api_guide_ParamAttr` .
        bias_attr(ParamAttr|bool, optional): ParamAttr object that specifies bias parameter
            attribute. If a bool type, only False is supported, which means there is no bias parameter.
            Default: None, the default bias parameter attribute is used. For more information, please
            refer to :ref:`api_guide_ParamAttr` .
        act(str, optional): Activation to be applied to the output of group normalizaiton.
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        data_layout(str, optional): Specify the data format of the input, and the data format of the output 
            will be consistent with that of the input. An optional string from: `"NCHW"`, `"NHWC"`.
            The default is `"NCHW"`. When it is `"NCHW"`, the data is stored in the order of:
            `[batch_size, input_channels, input_height, input_width]`.
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        name (str, optional): The default value is None. Normally there is no need for user to set this
            property. For more information, please refer to :ref:`api_guide_Name` .
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    Returns:
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        Variable: A 4-D Tensor has same data type and data format with `input`.

    Raises:
        ValueError: If `data_layout` is neither 'NCHW' nor 'NHWC'.
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        ValueError: If `groups` is greater than the number of input channels.
        ValueError: If `groups` is less than 1.
        ShapeError: If the param_attr(Scale) is not 1-D Tensor.
        ShapeError: If the param_attr(Scale)'s first dimension size is not equal to the input channels.
        ShapeError: If the bias_attr(Bias) is not 1-D Tensor.
        ShapeError: If the bias_attr(Bias)'s first dimension size is not equal to the input channels.
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    Examples:
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       .. code-block:: python
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            import paddle.fluid as fluid
            data = fluid.data(name='data', shape=[None, 8, 32, 32], dtype='float32')
            x = fluid.layers.group_norm(input=data, groups=4)
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    """
    helper = LayerHelper('group_norm', **locals())
    dtype = helper.input_dtype()

    # create intput and parameters
    inputs = {'X': input}
    input_shape = input.shape
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    if data_layout != 'NCHW' and data_layout != 'NHWC':
        raise ValueError(
            "Param(data_layout) of Op(fluid.layers.group_norm) got wrong value: received "
            + data_layout + " but only NCHW or NHWC supported.")
    channel_num = input_shape[1] if data_layout == 'NCHW' else input_shape[-1]
    param_shape = [channel_num]
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    if param_attr:
        scale = helper.create_parameter(
            attr=helper.param_attr,
            shape=param_shape,
            dtype=dtype,
            default_initializer=Constant(1.0))
        inputs['Scale'] = scale
    if bias_attr:
        bias = helper.create_parameter(
            attr=helper.bias_attr, shape=param_shape, dtype=dtype, is_bias=True)
        inputs['Bias'] = bias

    # create output
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    mean_out = helper.create_variable(dtype=dtype, stop_gradient=True)
    variance_out = helper.create_variable(dtype=dtype, stop_gradient=True)
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    group_norm_out = helper.create_variable(dtype=dtype)

    helper.append_op(
        type="group_norm",
        inputs=inputs,
        outputs={
            "Y": group_norm_out,
            "Mean": mean_out,
            "Variance": variance_out,
        },
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        attrs={
            "epsilon": epsilon,
            "groups": groups,
            "data_layout": data_layout
        })
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    return helper.append_activation(group_norm_out)


@templatedoc()
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def spectral_norm(weight, dim=0, power_iters=1, eps=1e-12, name=None):
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    """
    **Spectral Normalization Layer**

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    This operation calculates the spectral normalization value of weight parameters of
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    fc, conv1d, conv2d, conv3d layers which should be 2-D, 3-D, 4-D, 5-D
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    Parameters. Output tensor will be in same shape with input tensor.
    Calculations are showed as follows.
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    Step 1:
    Generate vector U in shape of [H], and V in shape of [W].
    While H is the :attr:`dim` th dimension of the input weights,
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    and W is the product result of remaining dimensions.
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    Step 2:
    :attr:`power_iters` shoule be a positive interger, do following
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    calculations with U and V for :attr:`power_iters` rounds. Calculations
    as follows:
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    .. math:: 

        \mathbf{v} := \\frac{\mathbf{W}^{T} \mathbf{u}}{\|\mathbf{W}^{T} \mathbf{u}\|_2}

        \mathbf{u} := \\frac{\mathbf{W}^{T} \mathbf{v}}{\|\mathbf{W}^{T} \mathbf{v}\|_2}

    Step 3:
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    Calculate :math:`\sigma(\mathbf{W})` and normalize weight values.
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    .. math::

        \sigma(\mathbf{W}) = \mathbf{u}^{T} \mathbf{W} \mathbf{v}
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        \mathbf{W} = \\frac{\mathbf{W}}{\sigma(\mathbf{W})}
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    Refer to `Spectral Normalization <https://arxiv.org/abs/1802.05957>`_ .

    Args:
        weight(${weight_type}): ${weight_comment}
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        dim(int): ${dim_comment}
        power_iters(int): ${power_iters_comment}
        eps(float): ${eps_comment}
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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
                             None by default.
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    Returns:
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        Variable: A tensor variable of weight parameters after spectral normalization.
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                  The data type and shape is same as input tensor.
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    Examples:
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       .. code-block:: python
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            import paddle.fluid as fluid

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            weight = fluid.data(name='weight', shape=[2, 8, 32, 32], dtype='float32')
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            x = fluid.layers.spectral_norm(weight=weight, dim=1, power_iters=2)
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    """
    helper = LayerHelper('spectral_norm', **locals())
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    dtype = weight.dtype
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    # create intput and parameters
    inputs = {'Weight': weight}
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    input_shape = weight.shape
    h = input_shape[dim]
    w = np.prod(input_shape) // h

    u = helper.create_parameter(
        attr=ParamAttr(),
        shape=[h],
        dtype=dtype,
        default_initializer=Normal(0., 1.))
    u.stop_gradient = True
    inputs['U'] = u
    v = helper.create_parameter(
        attr=ParamAttr(),
        shape=[w],
        dtype=dtype,
        default_initializer=Normal(0., 1.))
    inputs['V'] = v
    v.stop_gradient = True
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    # create output
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    out = helper.create_variable(dtype=dtype)
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    helper.append_op(
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        type="spectral_norm",
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        inputs=inputs,
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        outputs={"Out": out, },
        attrs={
            "dim": dim,
            "power_iters": power_iters,
            "eps": eps,
        })
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    return out
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def conv2d_transpose(input,
                     num_filters,
                     output_size=None,
                     filter_size=None,
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                     padding=0,
                     stride=1,
                     dilation=1,
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                     groups=None,
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                     param_attr=None,
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                     bias_attr=None,
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                     use_cudnn=True,
3265
                     act=None,
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                     name=None,
                     data_format='NCHW'):
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    """
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    The convolution2D transpose layer calculates the output based on the input,
    filter, and dilations, strides, paddings. Input(Input) and output(Output)
3271
    are in NCHW or NHWC format. Where N is batch size, C is the number of channels,
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    H is the height of the feature, and W is the width of the feature.
    Parameters(dilations, strides, paddings) are two elements. These two elements
    represent height and width, respectively. The details of convolution transpose
3275
    layer, please refer to the following explanation and references
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    `therein <https://arxiv.org/pdf/1603.07285.pdf>`_.
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    If bias attribution and activation type are provided, bias is added to
    the output of the convolution, and the corresponding activation function
    is applied to the final result.
3280 3281 3282 3283 3284

    For each input :math:`X`, the equation is:

    .. math::

3285
        Out = \sigma (W \\ast X + b)
3286

3287
    Where:
3288

3289 3290
    * :math:`X`: Input value, a 4-D Tensor with NCHW or NHWC format.
    * :math:`W`: Filter value, a 4-D Tensor with MCHW format.
3291
    * :math:`\\ast`: Convolution operation.
3292
    * :math:`b`: Bias value, a 2-D Tensor with shape [M, 1].
3293
    * :math:`\\sigma`: Activation function.
3294
    * :math:`Out`: Output value, a 4-D Tensor with data format 'NCHW' or 'NHWC', the shape of :math:`Out` and :math:`X` may be different.
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    Example:

        - Input:

3300
          Input shape: :math:`(N, C_{in}, H_{in}, W_{in})`
3301

3302
          Filter shape: :math:`(C_{in}, C_{out}, H_f, W_f)`
3303 3304 3305

        - Output:

3306
          Output shape: :math:`(N, C_{out}, H_{out}, W_{out})`
3307 3308

        Where
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3310 3311
        .. math::

3312 3313
           H^\prime_{out} &= (H_{in} - 1) * strides[0] - pad_height_top - pad_height_bottom + dilations[0] * (H_f - 1) + 1 \\\\
           W^\prime_{out} &= (W_{in} - 1) * strides[1] - pad_width_left - pad_width_right + dilations[1] * (W_f - 1) + 1 \\\\
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           H_{out} &\in [ H^\prime_{out}, H^\prime_{out} + strides[0] ] \\\\
3315 3316
           W_{out} &\in [ W^\prime_{out}, W^\prime_{out} + strides[1] ]

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    Note:
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          The conv2d_transpose can be seen as the backward of the conv2d. For conv2d, 
          when stride > 1, conv2d maps multiple input shape to the same output shape, 
          so for conv2d_transpose, when stride > 1, input shape maps multiple output shape.
          If output_size is None, :math:`H_{out} = H^\prime_{out}, W_{out} = W^\prime_{out}`; 
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          else, the :math:`H_{out}` of the output size must between :math:`H^\prime_{out}` 
          and :math:`H^\prime_{out} + strides[0]`, and the :math:`W_{out}` of the output size must 
          between :math:`W^\prime_{out}` and :math:`W^\prime_{out} + strides[1]`, 
          conv2d_transpose can compute the kernel size automatically.
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    Args:
3328 3329
        input(Variable): 4-D Tensor with [N, C, H, W] or [N, H, W, C] format,
                         its data type is float32 or float64.
3330 3331
        num_filters(int): The number of the filter. It is as same as the output
            image channel.
3332
        output_size(int|tuple, optional): The output image size. If output size is a
3333
            tuple, it must contain two integers, (image_height, image_width). None if use
3334
            filter_size, padding, and stride to calculate output_size.
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            If output_size and filter_size are specified at the same time, They
            should follow the formula above. Default: None. output_size and filter_size 
            should not be None at the same time.
3338
        filter_size(int|tuple, optional): The filter size. If filter_size is a tuple,
3339 3340
            it must contain two integers, (filter_size_height, filter_size_width).
            Otherwise, filter_size_height = filter_size_width = filter_size. None if 
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            use output size to calculate filter_size. Default: None. filter_size and 
            output_size should not be None at the same time.
        stride(int|tuple, optional): The stride size. It means the stride in transposed convolution. 
            If stride is a tuple, it must contain two integers, (stride_height, stride_width). 
            Otherwise, stride_height = stride_width = stride. Default: stride = 1.
        padding(int|list|str|tuple, optional): The padding size. The padding argument effectively adds
             `dilation * (kernel - 1)` amount of zero-padding on both sides of input. If `padding` is a
3348 3349 3350 3351 3352 3353 3354 3355 3356
             string, either 'VALID' or 'SAME' supported, which is the padding algorithm.
             If `padding` is a tuple or list, it could be in three forms:
             `[pad_height, pad_width]` or
            `[pad_height_top, pad_height_bottom, pad_width_left, pad_width_right]`, and
            when `data_format` is `'NCHW'`,
            `padding` can be in the form `[[0,0], [0,0], [pad_height_top, pad_height_bottom], [pad_width_left, pad_width_right]]`.
            when `data_format` is `'NHWC'`, `padding` can be in the form
            `[[0,0], [pad_height_top, pad_height_bottom], [pad_width_left, pad_width_right], [0,0]]`.
            Default: padding = 0.
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        dilation(int|tuple, optional): The dilation size. It means the spacing between the kernel points. 
            If dilation is a tuple, it must contain two integers, (dilation_height, dilation_width). 
            Otherwise, dilation_height = dilation_width = dilation. Default: dilation = 1.
        filter_size(int|tuple, optional): The filter size. If filter_size is a tuple,
            it must contain two integers, (filter_size_height, filter_size_width).
            Otherwise, filter_size_height = filter_size_width = filter_size. None if 
            use output size to calculate filter_size. Default: None.
3364
        groups(int, optional): The groups number of the Conv2d transpose layer. Inspired by
3365 3366 3367 3368
            grouped convolution in Alex Krizhevsky's Deep CNN paper, in which
            when group=2, the first half of the filters is only connected to the
            first half of the input channels, while the second half of the
            filters is only connected to the second half of the input channels.
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            Default: groups = 1.
3370
        param_attr (ParamAttr, optional): The parameter attribute for learnable parameters/weights
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            of conv2d_transpose. If it is set to None or one attribute of ParamAttr, conv2d_transpose
            will create ParamAttr as param_attr. If the Initializer of the param_attr
            is not set, the parameter is initialized with Xavier. Default: None.
3374
        bias_attr (ParamAttr|bool, optional): The parameter attribute for the bias of conv2d_transpose.
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            If it is set to False, no bias will be added to the output units.
            If it is set to None or one attribute of ParamAttr, conv2d_transpose
            will create ParamAttr as bias_attr. If the Initializer of the bias_attr
            is not set, the bias is initialized zero. Default: None.
3379
        use_cudnn(bool, optional): Use cudnn kernel or not, it is valid only when the cudnn
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            library is installed. Default: True.
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        act (str, optional): Activation type, if it is set to None, activation is not appended.
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            Default: None.
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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 
           None by default.
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        data_format (str, optional): Specify the data format of the input, and the data format of the output 
            will be consistent with that of the input. An optional string from: `"NCHW"`, `"NHWC"`.
            The default is `"NCHW"`. When it is `"NCHW"`, the data is stored in the order of:
            `[batch_size, input_channels, input_height, input_width]`.
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    Returns:
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        A Variable holding Tensor representing the conv2d_transpose, whose 
        data type is the same with input and shape is (num_batches, channels, out_h, 
        out_w) or (num_batches, out_h, out_w, channels). If act is None, the tensor variable 
        storing the transposed convolution result, and if act is not None, the 
        tensor variable storing transposed convolution and non-linearity activation 
        result.
3398 3399

    Raises:
3400 3401 3402 3403 3404 3405 3406 3407 3408 3409 3410
        ValueError: If the type of `use_cudnn` is not bool.
        ValueError: If `data_format` is not "NCHW" or "NHWC".
        ValueError: If `padding` is a string, but not "SAME" or "VALID".
        ValueError: If `padding` is a tuple, but the element corresponding to the input's batch size is not 0 
            or the element corresponding to the input's channel is not 0.
        ValueError: If `output_size` and filter_size are None at the same time.
        ShapeError: If the input is not 4-D Tensor.
        ShapeError: If the input's dimension size and filter's dimension size not equal.
        ShapeError: If the dimension size of input minus the size of `stride` is not 2.
        ShapeError: If the number of input channels is not equal to filter's channels.
        ShapeError: If the size of `output_size` is not equal to that of `stride`.
3411 3412 3413 3414

    Examples:
       .. code-block:: python

3415
          import paddle.fluid as fluid
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          data = fluid.data(name='data', shape=[None, 3, 32, 32], dtype='float32')
3417
          conv2d_transpose = fluid.layers.conv2d_transpose(input=data, num_filters=2, filter_size=3)
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    """
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    assert param_attr is not False, "param_attr should not be False in conv2d_transpose."
3420 3421 3422 3423
    if data_format not in ['NCHW', 'NHWC']:
        raise ValueError(
            "Attr(data_format) of Op(fluid.layers.conv2d_transpose) got wrong value: received "
            + data_format + " but only NCHW or NHWC supported.")
3424

3425
    input_channel = input.shape[1] if data_format == 'NCHW' else input.shape[-1]
3426 3427 3428 3429 3430 3431
    op_type = 'conv2d_transpose'
    if (input_channel == groups and num_filters == input_channel and
            not use_cudnn):
        op_type = 'depthwise_conv2d_transpose'

    helper = LayerHelper(op_type, **locals())
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    if not isinstance(input, Variable):
        raise TypeError("Input of conv2d_transpose must be Variable")

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    stride = utils.convert_to_list(stride, 2, 'stride')
    dilation = utils.convert_to_list(dilation, 2, 'dilation')
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    if not isinstance(use_cudnn, bool):
        raise ValueError("use_cudnn should be True or False")
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    def _update_padding(padding, data_format):
        def is_list_or_tuple(ele):
            if isinstance(ele, list) or isinstance(ele, tuple):
                return True
            return False

        if is_list_or_tuple(padding) and len(padding) == 4:
            if is_list_or_tuple(padding[0]) and (data_format == "NCHW"):
                if not (padding[0] == [0, 0] and padding[1] == [0, 0]):
                    raise ValueError(
                        "Non-zero padding(%s) in the batch or channel dimensions "
                        "is not supported." % str(padding))
                padding = padding[2:4]
                padding = [ele for a_list in padding for ele in a_list]
            elif is_list_or_tuple(padding[0]) and (data_format == "NHWC"):
                if not (padding[0] == [0, 0] and padding[3] == [0, 0]):
                    raise ValueError(
                        "Non-zero padding(%s) in the batch or channel dimensions "
                        "is not supported." % str(padding))
                padding = padding[1:3]
                padding = [ele for a_list in padding for ele in a_list]
            padding = utils.convert_to_list(padding, 4, 'padding')
        else:
            padding = utils.convert_to_list(padding, 2, 'padding')
            padding = [padding[0], padding[0], padding[1], padding[1]]
        return padding

    padding_algorithm = "EXPLICIT"
    if isinstance(padding, str):
        padding = padding.upper()
        if padding not in ["SAME", "VALID"]:
            raise ValueError(
                "Unknown padding: '%s'. It can only be 'SAME' or 'VALID'." %
                str(padding))
        if padding == "VALID":
            padding_algorithm = "VALID"
            padding = [0, 0, 0, 0]
        elif padding == "SAME":
            padding_algorithm = "SAME"
            padding = [0, 0, 0, 0]

    padding = _update_padding(padding, data_format)

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    if filter_size is None:
        if output_size is None:
            raise ValueError("output_size must be set when filter_size is None")
        if isinstance(output_size, int):
            output_size = [output_size, output_size]
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3490 3491
        h_in = input.shape[2] if data_format == 'NCHW' else input.shape[1]
        w_in = input.shape[3] if data_format == 'NCHW' else input.shape[2]
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3493 3494 3495 3496
        filter_size_h = (output_size[0] - (h_in - 1) * stride[0] + padding[0] +
                         padding[1] - 1) // dilation[0] + 1
        filter_size_w = (output_size[1] - (w_in - 1) * stride[1] + padding[2] +
                         padding[3] - 1) // dilation[1] + 1
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        filter_size = [filter_size_h, filter_size_w]
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    else:
        filter_size = utils.convert_to_list(filter_size, 2,
                                            'conv2d_transpose.filter_size')
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3502 3503 3504
    if len(padding) == 4 and utils._is_symmetric_padding(padding, 2):
        padding = [padding[0], padding[2]]

3505 3506 3507 3508 3509 3510
    if output_size is None:
        output_size = []
    elif isinstance(output_size, list) or isinstance(output_size, int):
        output_size = utils.convert_to_list(output_size, 2, 'output_size')
    else:
        raise ValueError("output_size should be list or int")
3511
    groups = 1 if groups is None else groups
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    filter_shape = [input_channel, num_filters // groups] + filter_size
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    img_filter = helper.create_parameter(
        dtype=input.dtype, shape=filter_shape, attr=helper.param_attr)

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    pre_bias = helper.create_variable_for_type_inference(dtype=input.dtype)
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    helper.append_op(
3519
        type=op_type,
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        inputs={'Input': [input],
                'Filter': [img_filter]},
3522
        outputs={'Output': pre_bias},
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        attrs={
3524
            'output_size': output_size,
3525 3526
            'strides': stride,
            'paddings': padding,
3527
            'padding_algorithm': padding_algorithm,
3528 3529
            'dilations': dilation,
            'groups': groups,
3530 3531
            'use_cudnn': use_cudnn,
            'data_format': data_format
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        })

3534 3535 3536 3537
    if data_format == 'NCHW':
        pre_act = helper.append_bias_op(pre_bias, dim_start=1, dim_end=2)
    else:
        pre_act = helper.append_bias_op(pre_bias, dim_start=3, dim_end=4)
3538 3539
    out = helper.append_activation(pre_act)
    return out
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3542
def conv3d_transpose(input,
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                     num_filters,
                     output_size=None,
                     filter_size=None,
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                     padding=0,
                     stride=1,
                     dilation=1,
3549
                     groups=None,
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                     param_attr=None,
3551
                     bias_attr=None,
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                     use_cudnn=True,
3553
                     act=None,
3554 3555
                     name=None,
                     data_format='NCDHW'):
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    """
3557
    The convolution3D transpose layer calculates the output based on the input,
3558
    filter, and dilations, strides, paddings. Input(Input) and output(Output)
3559
    are in NCDHW or NDHWC format. Where N is batch size, C is the number of channels,
3560 3561 3562 3563
    D is the depth of the feature, H is the height of the feature, and W
    is the width of the feature. Parameters(dilations, strides, paddings) are
    two elements. These two elements represent height and width, respectively.
    The details of convolution transpose layer, please refer to the following
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    explanation and references `therein <https://arxiv.org/pdf/1603.07285.pdf>`_.
3565 3566 3567
    If bias attribution and activation type are provided, bias is added to
    the output of the convolution, and the corresponding activation function
    is applied to the final result.
3568 3569 3570 3571 3572

    For each input :math:`X`, the equation is:

    .. math::

3573
        Out = \sigma (W \\ast X + b)
3574 3575 3576

    In the above equation:

3577 3578
    * :math:`X`: Input value, a Tensor with NCDHW or NDHWC format.
    * :math:`W`: Filter value, a Tensor with MCDHW format.
3579
    * :math:`\\ast`: Convolution operation.
3580
    * :math:`b`: Bias value, a 2-D Tensor with shape [M, 1].
3581 3582
    * :math:`\\sigma`: Activation function.
    * :math:`Out`: Output value, the shape of :math:`Out` and :math:`X` may be different.
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3584 3585 3586 3587
    Example:

        - Input:

3588
          Input shape: :math:`(N, C_{in}, D_{in}, H_{in}, W_{in})`
3589

3590
          Filter shape: :math:`(C_{in}, C_{out}, D_f, H_f, W_f)`
3591 3592 3593

        - Output:

3594
          Output shape: :math:`(N, C_{out}, D_{out}, H_{out}, W_{out})`
3595 3596

        Where
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3598 3599
        .. math::

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           D^\prime_{out} &= (D_{in} - 1) * strides[0] - 2 * paddings[0] + dilations[0] * (D_f - 1) + 1 \\\\
           H^\prime_{out} &= (H_{in} - 1) * strides[1] - 2 * paddings[1] + dilations[1] * (H_f - 1) + 1 \\\\
           W^\prime_{out} &= (W_{in} - 1) * strides[2] - 2 * paddings[2] + dilations[2] * (W_f - 1) + 1 \\\\
           D_{out} &\in [ D^\prime_{out}, D^\prime_{out} + strides[0] ] \\\\
           H_{out} &\in [ H^\prime_{out}, H^\prime_{out} + strides[1] ] \\\\
           W_{out} &\in [ W^\prime_{out}, W^\prime_{out} + strides[2] ]
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    Note:
          The conv3d_transpose can be seen as the backward of the conv3d. For conv3d, 
          when stride > 1, conv3d maps multiple input shape to the same output shape, 
          so for conv3d_transpose, when stride > 1, input shape maps multiple output shape.
          If output_size is None, :math:`H_{out} = H^\prime_{out}, :math:`H_{out} = \
          H^\prime_{out}, W_{out} = W^\prime_{out}`; else, the :math:`D_{out}` of the output 
          size must between :math:`D^\prime_{out}` and :math:`D^\prime_{out} + strides[0]`, 
          the :math:`H_{out}` of the output size must between :math:`H^\prime_{out}` 
          and :math:`H^\prime_{out} + strides[1]`, and the :math:`W_{out}` of the output size must 
          between :math:`W^\prime_{out}` and :math:`W^\prime_{out} + strides[2]`, 
          conv3d_transpose can compute the kernel size automatically.

    Args:
        input(Variable): The input is 5-D Tensor with shape [N, C, D, H, W] or [N, D, H, W, C], the data type 
            of input is float32 or float64.
3622 3623
        num_filters(int): The number of the filter. It is as same as the output
            image channel.
3624
        output_size(int|tuple, optional): The output image size. If output size is a
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            tuple, it must contain three integers, (image_depth, image_height, image_width). This
            parameter only works when filter_size is None. If output_size and filter_size are 
            specified at the same time, They should follow the formula above. Default: None. 
            Output_size and filter_size should not be None at the same time.
3629
        filter_size(int|tuple, optional): The filter size. If filter_size is a tuple,
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            it must contain three integers, (filter_size_depth, filter_size_height,
3631 3632
            filter_size_width). Otherwise, filter_size_depth = filter_size_height = \
            filter_size_width = filter_size. None if use output size to
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            calculate filter_size. Default: None. filter_size and output_size should not be 
            None at the same time.
        padding(int|list|str|tuple, optional): The padding size. The padding argument effectively
             adds `dilation * (kernel - 1)` amount of zero-padding on both sides of input. If `padding` is a string,
3637 3638 3639 3640 3641 3642 3643 3644
             either 'VALID' or 'SAME' supported, which is the padding algorithm. If `padding`
             is a tuple or list, it could be in three forms: `[pad_depth, pad_height, pad_width]` or
            `[pad_depth_front, pad_depth_back, pad_height_top, pad_height_bottom, pad_width_left, pad_width_right]`,
            and when `data_format` is `'NCDHW'`, `padding` can be in the form
            `[[0,0], [0,0], [pad_depth_front, pad_depth_back], [pad_height_top, pad_height_bottom], [pad_width_left, pad_width_right]]`.
            when `data_format` is `'NDHWC'`, `padding` can be in the form
            `[[0,0], [pad_depth_front, pad_depth_back], [pad_height_top, pad_height_bottom], [pad_width_left, pad_width_right], [0,0]]`.
            Default: padding = 0.
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        stride(int|tuple, optional): The stride size. It means the stride in transposed convolution. 
            If stride is a tuple, it must contain three integers, (stride_depth, stride_height, 
            stride_width). Otherwise, stride_depth = stride_height = stride_width = stride. 
            Default: stride = 1.
        dilation(int|tuple, optional): The dilation size. It means the spacing between the kernel points. 
            If dilation is a tuple, it must contain three integers, (dilation_depth, dilation_height, 
            dilation_width). Otherwise, dilation_depth = dilation_height = dilation_width = dilation. 
            Default: dilation = 1.
3653
        groups(int, optional): The groups number of the Conv3d transpose layer. Inspired by
3654 3655 3656 3657 3658
            grouped convolution in Alex Krizhevsky's Deep CNN paper, in which
            when group=2, the first half of the filters is only connected to the
            first half of the input channels, while the second half of the
            filters is only connected to the second half of the input channels.
            Default: groups=1
3659
        param_attr (ParamAttr, optional): The parameter attribute for learnable parameters/weights
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            of conv3d_transpose. If it is set to None or one attribute of ParamAttr, conv3d_transpose
            will create ParamAttr as param_attr. If the Initializer of the param_attr
            is not set, the parameter is initialized with Xavier. Default: None.
3663
        bias_attr (ParamAttr|bool, optional): The parameter attribute for the bias of conv3d_transpose.
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            If it is set to False, no bias will be added to the output units.
            If it is set to None or one attribute of ParamAttr, conv3d_transpose
            will create ParamAttr as bias_attr. If the Initializer of the bias_attr
            is not set, the bias is initialized zero. Default: None.
3668
        use_cudnn(bool, optional): Use cudnn kernel or not, it is valid only when the cudnn
3669
            library is installed. Default: True
3670
        act (str, optional): Activation type, if it is set to None, activation is not appended.
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            Default: None.
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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 
           None by default.
3675 3676 3677 3678
        data_format (str, optional): Specify the data format of the input, and the data format of the output 
            will be consistent with that of the input. An optional string from: `"NCHW"`, `"NHWC"`.
            The default is `"NCHW"`. When it is `"NCHW"`, the data is stored in the order of:
            `[batch_size, input_channels, input_height, input_width]`.
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    Returns:
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        A Variable holding Tensor representing the conv3d_transpose, whose data 
        type is the same with input and shape is (num_batches, channels, out_d, out_h, 
        out_w) or (num_batches, out_d, out_h, out_w, channels). If act is None, the tensor 
        variable storing the transposed convolution result, and if act is not None, the tensor 
        variable storing transposed convolution and non-linearity activation result.
3686 3687

    Raises:
3688 3689 3690 3691 3692 3693 3694 3695 3696 3697 3698
        ValueError: If the type of `use_cudnn` is not bool.
        ValueError: If `data_format` is not "NCDHW" or "NDHWC".
        ValueError: If `padding` is a string, but not "SAME" or "VALID".
        ValueError: If `padding` is a tuple, but the element corresponding to the input's batch size is not 0 
            or the element corresponding to the input's channel is not 0.
        ValueError: If `output_size` and filter_size are None at the same time.
        ShapeError: If the input is not 5-D Tensor.
        ShapeError: If the input's dimension size and filter's dimension size not equal.
        ShapeError: If the dimension size of input minus the size of `stride` is not 2.
        ShapeError: If the number of input channels is not equal to filter's channels.
        ShapeError: If the size of `output_size` is not equal to that of `stride`.
3699 3700 3701 3702

    Examples:
       .. code-block:: python

3703
          import paddle.fluid as fluid
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          data = fluid.data(name='data', shape=[None, 3, 12, 32, 32], dtype='float32')
3705
          conv3d_transpose = fluid.layers.conv3d_transpose(input=data, num_filters=2, filter_size=3)
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    """
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    assert param_attr is not False, "param_attr should not be False in conv3d_transpose."
3708 3709 3710 3711
    if data_format not in ['NCDHW', 'NDHWC']:
        raise ValueError(
            "Param(data_format) of Op(fluid.layers.conv3d_transpose) got wrong value: received "
            + data_format + " but only NCDHW or NDHWC supported.")
3712 3713
    l_type = "conv3d_transpose"
    helper = LayerHelper(l_type, **locals())
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    if not isinstance(input, Variable):
3715
        raise TypeError("Input of conv3d_transpose must be Variable")
3716 3717
    input_channel = input.shape[1] if data_format == 'NCDHW' else input.shape[
        -1]
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3719 3720
    stride = utils.convert_to_list(stride, 3, 'stride')
    dilation = utils.convert_to_list(dilation, 3, 'dilation')
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    if not isinstance(use_cudnn, bool):
        raise ValueError("use_cudnn should be True or False")

3725 3726 3727 3728 3729 3730 3731 3732 3733 3734 3735 3736 3737 3738
    def _update_padding(padding, data_format):
        def is_list_or_tuple(ele):
            if isinstance(ele, list) or isinstance(ele, tuple):
                return True
            return False

        if is_list_or_tuple(padding) and len(padding) == 5:
            if is_list_or_tuple(padding[0]) and (data_format == "NCDHW"):
                if not (padding[0] == [0, 0] and padding[1] == [0, 0]):
                    raise ValueError(
                        "Non-zero padding(%s) in the batch or channel dimensions "
                        "is not supported." % str(padding))
                padding = padding[2:5]
                padding = [ele for a_list in padding for ele in a_list]
3739 3740 3741 3742 3743 3744 3745 3746
            elif is_list_or_tuple(padding[0]) and (data_format == "NDHWC"):
                if not (padding[0] == [0, 0] and padding[4] == [0, 0]):
                    raise ValueError(
                        "Non-zero padding(%s) in the batch or channel dimensions "
                        "is not supported." % str(padding))
                padding = padding[1:4]
                padding = [ele for a_list in padding for ele in a_list]
            padding = utils.convert_to_list(padding, 6, 'padding')
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3748 3749
        elif is_list_or_tuple(padding) and len(padding) == 6:
            padding = utils.convert_to_list(padding, 6, 'padding')
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3751 3752 3753 3754 3755 3756 3757
        else:
            padding = utils.convert_to_list(padding, 3, 'padding')
            padding = [
                padding[0], padding[0], padding[1], padding[1], padding[2],
                padding[2]
            ]
        return padding
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3759 3760 3761 3762 3763 3764 3765 3766 3767 3768 3769 3770 3771
    padding_algorithm = "EXPLICIT"
    if isinstance(padding, str):
        padding = padding.upper()
        if padding not in ["SAME", "VALID"]:
            raise ValueError(
                "Unknown padding: '%s'. It can only be 'SAME' or 'VALID'." %
                str(padding))
        if padding == "VALID":
            padding_algorithm = "VALID"
            padding = [0, 0, 0, 0, 0, 0]
        elif padding == "SAME":
            padding_algorithm = "SAME"
            padding = [0, 0, 0, 0, 0, 0]
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3773
    padding = _update_padding(padding, data_format)
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3775 3776 3777 3778 3779
    if filter_size is None:
        if output_size is None:
            raise ValueError("output_size must be set when filter_size is None")
        if isinstance(output_size, int):
            output_size = [output_size, output_size]
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3781 3782 3783
        d_in = input.shape[2] if data_format == 'NCDHW' else input.shape[1]
        h_in = input.shape[3] if data_format == 'NCDHW' else input.shape[2]
        w_in = input.shape[4] if data_format == 'NCDHW' else input.shape[3]
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3785 3786 3787 3788 3789 3790 3791 3792 3793 3794
        filter_size_d = (output_size[0] - (d_in - 1) * stride[0] + padding[0] +
                         padding[1] - 1) // dilation[0] + 1
        filter_size_h = (output_size[1] - (h_in - 1) * stride[1] + padding[2] +
                         padding[3] - 1) // dilation[1] + 1
        filter_size_w = (output_size[2] - (w_in - 1) * stride[2] + padding[4] +
                         padding[5] - 1) // dilation[2] + 1
        filter_size = [filter_size_d, filter_size_h, filter_size_w]
    else:
        filter_size = utils.convert_to_list(filter_size, 3,
                                            'conv3d_transpose.filter_size')
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3796 3797
    if len(padding) == 6 and utils._is_symmetric_padding(padding, 3):
        padding = [padding[0], padding[2], padding[4]]
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3799 3800 3801 3802
    groups = 1 if groups is None else groups
    filter_shape = [input_channel, num_filters // groups] + filter_size
    img_filter = helper.create_parameter(
        dtype=input.dtype, shape=filter_shape, attr=helper.param_attr)
3803

3804 3805 3806 3807
    if data_format == 'NCDHW':
        data_format = 'NCHW'
    if data_format == 'NDHWC':
        data_format = 'NHWC'
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3809
    pre_bias = helper.create_variable_for_type_inference(dtype=input.dtype)
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    helper.append_op(
3811 3812 3813 3814 3815 3816 3817 3818 3819 3820 3821 3822 3823
        type=l_type,
        inputs={'Input': [input],
                'Filter': [img_filter]},
        outputs={'Output': pre_bias},
        attrs={
            'strides': stride,
            'paddings': padding,
            'padding_algorithm': padding_algorithm,
            'dilations': dilation,
            'groups': groups,
            'use_cudnn': use_cudnn,
            'data_format': data_format
        })
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3825 3826 3827 3828 3829 3830
    if data_format == 'NCHW':
        pre_act = helper.append_bias_op(pre_bias, dim_start=1, dim_end=2)
    else:
        pre_act = helper.append_bias_op(pre_bias, dim_start=4, dim_end=5)
    out = helper.append_activation(pre_act)
    return out
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def reduce_sum(input, dim=None, keep_dim=False, name=None):
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    """
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    Computes the sum of tensor elements over the given dimension.
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    Args:
3838 3839 3840
        input (Variable): The input variable which is a Tensor, the data type is float32,
            float64, int32, int64.
        dim (list|int, optional): The dimensions along which the sum is performed. If
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            :attr:`None`, sum all elements of :attr:`input` and return a
            Tensor variable with a single element, otherwise must be in the
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            range :math:`[-rank(input), rank(input))`. If :math:`dim[i] < 0`,
            the dimension to reduce is :math:`rank + dim[i]`.
3845
        keep_dim (bool, optional): Whether to reserve the reduced dimension in the
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            output Tensor. The result tensor will have one fewer dimension
3847 3848 3849 3850
            than the :attr:`input` unless :attr:`keep_dim` is true, default
            value is False.
        name(str, optional): The default value is None.  Normally there is no need for
            user to set this property.  For more information, please refer to :ref:`api_guide_Name`
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    Returns:
3853 3854
        Variable: Tensor, results of summation operation on the specified dim of input tensor,
        it's data type is the same as input's Tensor.
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3856 3857 3858
    Raises:
        TypeError, if out data type is different with the input data type.
    
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    Examples:
        .. code-block:: python

3862
            import paddle.fluid as fluid
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            # x is a Tensor variable with following elements:
            #    [[0.2, 0.3, 0.5, 0.9]
            #     [0.1, 0.2, 0.6, 0.7]]
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            # Each example is followed by the corresponding output tensor.
3867
            x = fluid.data(name='x', shape=[2, 4], dtype='float32')
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            fluid.layers.reduce_sum(x)  # [3.5]
            fluid.layers.reduce_sum(x, dim=0)  # [0.3, 0.5, 1.1, 1.6]
            fluid.layers.reduce_sum(x, dim=-1)  # [1.9, 1.6]
            fluid.layers.reduce_sum(x, dim=1, keep_dim=True)  # [[1.9], [1.6]]
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3873
            # y is a Tensor variable with shape [2, 2, 2] and elements as below:
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            #      [[[1, 2], [3, 4]],
            #      [[5, 6], [7, 8]]]
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            # Each example is followed by the corresponding output tensor.
3877
            y = fluid.data(name='y', shape=[2, 2, 2], dtype='float32')
3878 3879
            fluid.layers.reduce_sum(y, dim=[1, 2]) # [10, 26]
            fluid.layers.reduce_sum(y, dim=[0, 1]) # [16, 20]
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    """
3882 3883 3884
    if dim is not None and not isinstance(dim, list):
        dim = [dim]
    attrs = {
3885
        'dim': dim if dim != None and dim != [] else [0],
3886
        'keep_dim': keep_dim,
3887
        'reduce_all': True if dim == None or dim == [] else False
3888 3889 3890 3891 3892 3893 3894
    }

    if in_dygraph_mode():
        inputs = {'X': [input]}
        outs = core.ops.reduce_sum(inputs, attrs)
        return outs['Out'][0]

3895 3896
    check_type_and_dtype(input, 'input', Variable,
                         ['float32', 'float64', 'int32', 'int64'], 'reduce_sum')
3897
    helper = LayerHelper('reduce_sum', **locals())
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    out = helper.create_variable_for_type_inference(dtype=helper.input_dtype())
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    helper.append_op(
        type='reduce_sum',
        inputs={'X': input},
        outputs={'Out': out},
3903
        attrs=attrs)
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    return out
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def reduce_mean(input, dim=None, keep_dim=False, name=None):
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    """
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    Computes the mean of the input tensor's elements along the given dimension.
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3910 3911

    Args:
3912 3913 3914
        input (Variable): The input variable which is a Tensor, the data type is float32,
            float64, int32, int64.
        dim (list|int, optional): The dimension along which the mean is computed. If
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3915 3916
            `None`, compute the mean over all elements of :attr:`input`
            and return a variable with a single element, otherwise it
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3917
            must be in the range :math:`[-rank(input), rank(input))`. If
3918
            :math:`dim[i] < 0`, the dimension to reduce is
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            :math:`rank(input) + dim[i]`.
3920
        keep_dim (bool, optional): Whether to reserve the reduced dimension in the
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            output Tensor. The result tensor will have one fewer dimension
3922 3923 3924 3925 3926
            than the :attr:`input` unless :attr:`keep_dim` is true, default 
            value is False.
        name(str, optional): The default value is None.  Normally there is no need for
            user to set this property.  For more information, please refer to :ref:`api_guide_Name`
    
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    Returns:
3928 3929 3930 3931 3932 3933
        Variable: Tensor, results of average on the specified dim of input tensor,
        it's data type is the same as input's Tensor.
    
    Raises:
        TypeError, if out data type is different with the input data type.
    
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    Examples:
        .. code-block:: python

3937
            import paddle.fluid as fluid
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3938 3939 3940 3941
            # x is a Tensor variable with following elements:
            #    [[0.2, 0.3, 0.5, 0.9]
            #     [0.1, 0.2, 0.6, 0.7]]
            # Each example is followed by the correspending output tensor.
3942
            x = fluid.data(name='x', shape=[2, 4], dtype='float32')
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            fluid.layers.reduce_mean(x)  # [0.4375]
            fluid.layers.reduce_mean(x, dim=0)  # [0.15, 0.25, 0.55, 0.8]
            fluid.layers.reduce_mean(x, dim=-1)  # [0.475, 0.4]
3946
            fluid.layers.reduce_mean(x, dim=1, keep_dim=True)  # [[0.475], [0.4]]
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3948
            # y is a Tensor variable with shape [2, 2, 2] and elements as below:
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            #      [[[1.0, 2.0], [3.0, 4.0]],
            #      [[5.0, 6.0], [7.0, 8.0]]]
            # Each example is followed by the correspending output tensor.
3952
            y = fluid.data(name='y', shape=[2, 2, 2], dtype='float32')
3953 3954
            fluid.layers.reduce_mean(y, dim=[1, 2]) # [2.5, 6.5]
            fluid.layers.reduce_mean(y, dim=[0, 1]) # [4.0, 5.0]
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    """
3956 3957 3958 3959

    if dim is not None and not isinstance(dim, list):
        dim = [dim]
    attrs = {
3960
        'dim': dim if dim != None and dim != [] else [0],
3961
        'keep_dim': keep_dim,
3962
        'reduce_all': True if dim == None or dim == [] else False
3963 3964 3965 3966 3967 3968 3969
    }

    if in_dygraph_mode():
        inputs = {'X': [input]}
        outs = core.ops.reduce_mean(inputs, attrs)
        return outs['Out'][0]

3970 3971 3972
    check_type_and_dtype(input, 'input', Variable,
                         ['float32', 'float64', 'int32', 'int64'],
                         'reduce_mean')
3973
    helper = LayerHelper('reduce_mean', **locals())
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3974
    out = helper.create_variable_for_type_inference(dtype=helper.input_dtype())
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3975 3976 3977 3978
    helper.append_op(
        type='reduce_mean',
        inputs={'X': input},
        outputs={'Out': out},
3979
        attrs=attrs)
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    return out
3981 3982


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def reduce_max(input, dim=None, keep_dim=False, name=None):
3984
    """
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3985
    Computes the maximum of tensor elements over the given dimension.
3986 3987

    Args:
3988 3989 3990
        input (Variable): The input variable which is a Tensor, the data type is float32,
            float64, int32, int64.
        dim (list|int, optional): The dimension along which the maximum is computed.
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            If :attr:`None`, compute the maximum over all elements of
            :attr:`input` and return a Tensor variable with a single element,
            otherwise must be in the range :math:`[-rank(input), rank(input))`.
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            If :math:`dim[i] < 0`, the dimension to reduce is :math:`rank + dim[i]`.
3995
        keep_dim (bool, optional): Whether to reserve the reduced dimension in the
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            output Tensor. The result tensor will have one fewer dimension
3997 3998 3999 4000
            than the :attr:`input` unless :attr:`keep_dim` is true, default
            value is False.
        name(str, optional): The default value is None.  Normally there is no need for 
            user to set this property.  For more information, please refer to :ref:`api_guide_Name`
4001 4002

    Returns:
4003 4004
        Variable: Tensor, results of maximum on the specified dim of input tensor,
        it's data type is the same as input's Tensor.
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4006 4007 4008
    Examples:
        .. code-block:: python

4009
            import paddle.fluid as fluid
4010 4011 4012 4013
            # x is a Tensor variable with following elements:
            #    [[0.2, 0.3, 0.5, 0.9]
            #     [0.1, 0.2, 0.6, 0.7]]
            # Each example is followed by the correspending output tensor.
4014
            x = fluid.data(name='x', shape=[2, 4], dtype='float32')
4015 4016 4017 4018
            fluid.layers.reduce_max(x)  # [0.9]
            fluid.layers.reduce_max(x, dim=0)  # [0.2, 0.3, 0.6, 0.9]
            fluid.layers.reduce_max(x, dim=-1)  # [0.9, 0.7]
            fluid.layers.reduce_max(x, dim=1, keep_dim=True)  # [[0.9], [0.7]]
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4020
            # y is a Tensor variable with shape [2, 2, 2] and elements as below:
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            #      [[[1.0, 2.0], [3.0, 4.0]],
            #      [[5.0, 6.0], [7.0, 8.0]]]
            # Each example is followed by the correspending output tensor.
4024
            y = fluid.data(name='y', shape=[2, 2, 2], dtype='float32')
4025 4026
            fluid.layers.reduce_max(y, dim=[1, 2]) # [4.0, 8.0]
            fluid.layers.reduce_max(y, dim=[0, 1]) # [7.0, 8.0]
4027 4028
    """
    helper = LayerHelper('reduce_max', **locals())
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    out = helper.create_variable_for_type_inference(dtype=helper.input_dtype())
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4030 4031
    if dim is not None and not isinstance(dim, list):
        dim = [dim]
4032 4033 4034 4035 4036
    helper.append_op(
        type='reduce_max',
        inputs={'X': input},
        outputs={'Out': out},
        attrs={
4037
            'dim': dim if dim != None and dim != [] else [0],
4038
            'keep_dim': keep_dim,
4039
            'reduce_all': True if dim == None or dim == [] else False
4040 4041 4042 4043
        })
    return out


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def reduce_min(input, dim=None, keep_dim=False, name=None):
4045
    """
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    Computes the minimum of tensor elements over the given dimension.
4047 4048

    Args:
4049 4050 4051
        input (Variable): The input variable which is a Tensor, the data type is float32,
            float64, int32, int64.
        dim (list|int, optional): The dimensions along which the minimum is computed.
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            If :attr:`None`, compute the minimum over all elements of
            :attr:`input` and return a Tensor variable with a single element,
            otherwise must be in the range :math:`[-rank(input), rank(input))`.
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            If :math:`dim[i] < 0`, the dimension to reduce is :math:`rank + dim[i]`.
4056
        keep_dim (bool, optional): Whether to reserve the reduced dimension in the
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            output Tensor. The result tensor will have one fewer dimension
4058 4059 4060 4061
            than the :attr:`input` unless :attr:`keep_dim` is true, default
            value is False.
        name(str, optional): The default value is None.  Normally there is no need for 
            user to set this property.  For more information, please refer to :ref:`api_guide_Name`
4062 4063

    Returns:
4064 4065
        Variable: Tensor, result of minimum on the specified dim of input tensor,
        it's data type is the same as input's Tensor.
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4067 4068 4069
    Examples:
        .. code-block:: python

4070
            import paddle.fluid as fluid
4071 4072 4073 4074
            # x is a Tensor variable with following elements:
            #    [[0.2, 0.3, 0.5, 0.9]
            #     [0.1, 0.2, 0.6, 0.7]]
            # Each example is followed by the correspending output tensor.
4075
            x = fluid.data(name='x', shape=[2, 4], dtype='float32')
4076 4077 4078 4079
            fluid.layers.reduce_min(x)  # [0.1]
            fluid.layers.reduce_min(x, dim=0)  # [0.1, 0.2, 0.5, 0.7]
            fluid.layers.reduce_min(x, dim=-1)  # [0.2, 0.1]
            fluid.layers.reduce_min(x, dim=1, keep_dim=True)  # [[0.2], [0.1]]
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4081
            # y is a Tensor variable with shape [2, 2, 2] and elements as below:
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4082 4083 4084
            #      [[[1.0, 2.0], [3.0, 4.0]],
            #      [[5.0, 6.0], [7.0, 8.0]]]
            # Each example is followed by the correspending output tensor.
4085
            y = fluid.data(name='y', shape=[2, 2, 2], dtype='float32')
4086 4087
            fluid.layers.reduce_min(y, dim=[1, 2]) # [1.0, 5.0]
            fluid.layers.reduce_min(y, dim=[0, 1]) # [1.0, 2.0]
4088 4089
    """
    helper = LayerHelper('reduce_min', **locals())
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    out = helper.create_variable_for_type_inference(dtype=helper.input_dtype())
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    if dim is not None and not isinstance(dim, list):
        dim = [dim]
4093 4094 4095 4096 4097
    helper.append_op(
        type='reduce_min',
        inputs={'X': input},
        outputs={'Out': out},
        attrs={
4098
            'dim': dim if dim != None and dim != [] else [0],
4099
            'keep_dim': keep_dim,
4100
            'reduce_all': True if dim == None or dim == [] else False
4101 4102
        })
    return out
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4103 4104


4105 4106 4107 4108 4109
def reduce_prod(input, dim=None, keep_dim=False, name=None):
    """
    Computes the product of tensor elements over the given dimension.

    Args:
4110 4111 4112
        input (Variable): The input variable which is a Tensor, the data type is float32,
            float64, int32, int64.
        dim (list|int, optional): The dimensions along which the product is performed. If
4113 4114
            :attr:`None`, multipy all elements of :attr:`input` and return a
            Tensor variable with a single element, otherwise must be in the
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            range :math:`[-rank(input), rank(input))`. If :math:`dim[i] < 0`,
            the dimension to reduce is :math:`rank + dim[i]`.
4117
        keep_dim (bool, optional): Whether to reserve the reduced dimension in the
4118
            output Tensor. The result tensor will have one fewer dimension
4119 4120 4121 4122
            than the :attr:`input` unless :attr:`keep_dim` is true, default
            value is False.
        name(str, optional): The default value is None.  Normally there is no need for 
            user to set this property.  For more information, please refer to :ref:`api_guide_Name`
4123 4124

    Returns:
4125 4126 4127
        Variable: Tensor, result of product on the specified dim of input tensor,
        it's data type is the same as input's Tensor.
    
4128 4129 4130
    Examples:
        .. code-block:: python

4131
            import paddle.fluid as fluid
4132 4133 4134 4135
            # x is a Tensor variable with following elements:
            #    [[0.2, 0.3, 0.5, 0.9]
            #     [0.1, 0.2, 0.6, 0.7]]
            # Each example is followed by the correspending output tensor.
4136
            x = fluid.data(name='x', shape=[2, 4], dtype='float32')
4137 4138 4139
            fluid.layers.reduce_prod(x)  # [0.0002268]
            fluid.layers.reduce_prod(x, dim=0)  # [0.02, 0.06, 0.3, 0.63]
            fluid.layers.reduce_prod(x, dim=-1)  # [0.027, 0.0084]
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            fluid.layers.reduce_prod(x, dim=1,
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                                     keep_dim=True)  # [[0.027], [0.0084]]
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4142

4143
            # y is a Tensor variable with shape [2, 2, 2] and elements as below:
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4144 4145 4146
            #      [[[1.0, 2.0], [3.0, 4.0]],
            #      [[5.0, 6.0], [7.0, 8.0]]]
            # Each example is followed by the correspending output tensor.
4147
            y = fluid.data(name='y', shape=[2, 2, 2], dtype='float32')
4148 4149
            fluid.layers.reduce_prod(y, dim=[1, 2]) # [24.0, 1680.0]
            fluid.layers.reduce_prod(y, dim=[0, 1]) # [105.0, 384.0]
4150 4151
    """
    helper = LayerHelper('reduce_prod', **locals())
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    out = helper.create_variable_for_type_inference(dtype=helper.input_dtype())
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    if dim is not None and not isinstance(dim, list):
        dim = [dim]
4155 4156 4157 4158 4159
    helper.append_op(
        type='reduce_prod',
        inputs={'X': input},
        outputs={'Out': out},
        attrs={
4160
            'dim': dim if dim != None and dim != [] else [0],
4161
            'keep_dim': keep_dim,
4162
            'reduce_all': True if dim == None or dim == [] else False
4163 4164 4165 4166
        })
    return out


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def reduce_all(input, dim=None, keep_dim=False, name=None):
    """
4169
    This OP computes the ``logical and`` of tensor elements over the given dimension, and output the result.
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4170 4171

    Args:
4172 4173
        input (Variable): The input variable which is a Tensor or LoDTensor, the input data type should be `bool`.
        dim (list|int|optional): The dimension along which the logical and is computed.
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            If :attr:`None`, compute the logical and over all elements of
            :attr:`input` and return a Tensor variable with a single element,
            otherwise must be in the range :math:`[-rank(input), rank(input))`.
4177
            If :math:`dim[i] < 0`, the dimension to reduce is :math:`rank + dim[i]`. The default value is None. 
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        keep_dim (bool): Whether to reserve the reduced dimension in the
            output Tensor. The result tensor will have one fewer dimension
4180
            than the :attr:`input` unless :attr:`keep_dim` is true. The default value is False.
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        name(str|None): A name for this layer(optional). If set None, the layer
4182
                       will be named automatically. The default value is None. 
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4184 4185
    Returns: 
        Variable, the output data type is bool. : The reduced tensor variable with ``logical and`` in given dims.
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    Examples:
        .. code-block:: python
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4189
        
4190
            import paddle.fluid as fluid
4191 4192 4193
            import paddle.fluid.layers as layers
            import numpy as np

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4194 4195 4196
            # x is a bool Tensor variable with following elements:
            #    [[True, False]
            #     [True, True]]
4197 4198 4199 4200 4201 4202
            x = layers.assign(np.array([[1, 0], [1, 1]], dtype='int32'))
            x = layers.cast(x, 'bool')

            out = layers.reduce_all(x)  # False 
            out = layers.reduce_all(x, dim=0)  # [True, False]
            out = layers.reduce_all(x, dim=-1)  # [False, True]
4203 4204
            # keep_dim=False, x.shape=(2,2), out.shape=(2,)

4205
            out = layers.reduce_all(x, dim=1, keep_dim=True)  # [[False], [True]]
4206
            # keep_dim=True, x.shape=(2,2), out.shape=(2,1)
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    """
    helper = LayerHelper('reduce_all', **locals())
    out = helper.create_variable_for_type_inference(dtype=helper.input_dtype())
    if dim is not None and not isinstance(dim, list):
        dim = [dim]
    helper.append_op(
        type='reduce_all',
        inputs={'X': input},
        outputs={'Out': out},
        attrs={
4218
            'dim': dim if dim != None and dim != [] else [0],
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            'keep_dim': keep_dim,
4220
            'reduce_all': True if dim == None or dim == [] else False
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        })
    return out


def reduce_any(input, dim=None, keep_dim=False, name=None):
    """
4227
    This OP computes the ``logical or`` of tensor elements over the given dimension, and output the result.
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4228 4229

    Args:
4230 4231 4232
        input (Variable): The input variable which is a Tensor or LoDTensor, the input data type should be `bool`.
        dim (list|int|optional): The dimension along which the logical and is computed.
            If :attr:`None`, compute the logical and over all elements of
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4233 4234
            :attr:`input` and return a Tensor variable with a single element,
            otherwise must be in the range :math:`[-rank(input), rank(input))`.
4235
            If :math:`dim[i] < 0`, the dimension to reduce is :math:`rank + dim[i]`. The default value is None. 
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4236 4237
        keep_dim (bool): Whether to reserve the reduced dimension in the
            output Tensor. The result tensor will have one fewer dimension
4238
            than the :attr:`input` unless :attr:`keep_dim` is true. The default value is False.
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4239 4240
        name(str|None): A name for this layer(optional). If set None, the layer

4241 4242
    Returns: 
        Variable, the output data type is bool. : The reduced tensor variable with ``logical or`` in given dims.
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    Examples:
        .. code-block:: python
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4246

4247
            import paddle.fluid as fluid
4248 4249 4250
            import paddle.fluid.layers as layers
            import numpy as np

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4251 4252 4253
            # x is a bool Tensor variable with following elements:
            #    [[True, False]
            #     [False, False]]
4254 4255 4256 4257 4258 4259
            x = layers.assign(np.array([[1, 0], [0, 0]], dtype='int32'))
            x = layers.cast(x, 'bool')

            out = layers.reduce_any(x)  # True
            out = layers.reduce_any(x, dim=0)  # [True, False]
            out = layers.reduce_any(x, dim=-1)  # [True, False]
4260 4261
            # keep_dim=False, x.shape=(2,2), out.shape=(2,)

4262
            out = layers.reduce_any(x, dim=1,
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                                     keep_dim=True)  # [[True], [False]]
4264
            # keep_dim=True, x.shape=(2,2), out.shape=(2,1)
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    """
    helper = LayerHelper('reduce_any', **locals())
    out = helper.create_variable_for_type_inference(dtype=helper.input_dtype())
    if dim is not None and not isinstance(dim, list):
        dim = [dim]
    helper.append_op(
        type='reduce_any',
        inputs={'X': input},
        outputs={'Out': out},
        attrs={
4276
            'dim': dim if dim != None and dim != [] else [0],
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            'keep_dim': keep_dim,
4278
            'reduce_all': True if dim == None or dim == [] else False
4279 4280 4281 4282
        })
    return out


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def split(input, num_or_sections, dim=-1, name=None):
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4284
    """
4285
    Split the input tensor into multiple sub-Tensors.
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4286 4287

    Args:
4288
        input (Variable): The input variable which is an N-D Tensor or LoDTensor, data type being float32, float64, int32 or int64.
4289
        num_or_sections (int|list|tuple): If :attr:`num_or_sections` is an integer,
4290 4291
            then the integer indicates the number of equal sized sub-Tensors
            that the Tensor will be divided into. If :attr:`num_or_sections`
4292 4293 4294 4295 4296
            is a list or tuple, the length of it indicates the number of
            sub-Tensors and the elements in it indicate the sizes of sub-Tensors'
            :attr:`dim` dimension orderly. The length of the list mustn't be larger than the Tensor's size of :attr:`dim` .
        dim (int32|Varible, optional): A scalar with type ``int32`` or a ``Tensor`` with shape [1] and type ``int32``. The dimension along which to split. If :math:`dim < 0`, the
            dimension to split along is :math:`rank(input) + dim`. Default is -1.
4297
        name(str, optional): The default value is None.  Normally there is no need for user to set this property.  For more information, please refer to :ref:`api_guide_Name` .
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4298 4299

    Returns:
4300
        list(Variable): The list of segmented Tensor variables.
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4302 4303 4304 4305
    Raises:
        TypeError: num_or_sections is not int, list or tuple.
        TypeError: dim is not int or Variable.

4306
    Example:
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4307 4308
        .. code-block:: python

4309 4310
            import paddle.fluid as fluid

4311 4312
            # input is a variable which shape is [3, 9, 5]
            input = fluid.data(
4313 4314
                 name="input", shape=[3, 9, 5], dtype="float32")

4315 4316 4317 4318
            x0, x1, x2 = fluid.layers.split(input, num_or_sections=3, dim=1)
            # x0.shape [3, 3, 5]
            # x1.shape [3, 3, 5]
            # x2.shape [3, 3, 5]
4319

4320 4321 4322 4323 4324 4325 4326 4327 4328
            x0, x1, x2 = fluid.layers.split(input, num_or_sections=[2, 3, 4], dim=1)
            # x0.shape [3, 2, 5]
            # x1.shape [3, 3, 5]
            # x2.shape [3, 4, 5]

            x0, x1, x2 = fluid.layers.split(input, num_or_sections=[2, 3, -1], dim=1)
            # x0.shape [3, 2, 5]
            # x1.shape [3, 3, 5]
            # x2.shape [3, 4, 5]
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    """
4330 4331 4332 4333 4334 4335 4336 4337 4338 4339 4340 4341 4342 4343 4344 4345 4346 4347 4348 4349 4350 4351 4352 4353 4354 4355 4356 4357 4358 4359 4360
    if in_dygraph_mode():
        inputs = {'X': [input]}
        attrs = {}
        if isinstance(dim, int):
            dim = (len(input.shape) + dim) if dim < 0 else dim
            attrs['axis'] = dim
        else:
            dim.stop_gradient = True
            inputs['AxisTensor'] = [dim]

        if isinstance(num_or_sections, int):
            num = num_or_sections
            attrs['num'] = num_or_sections
            res = core.ops.split(inputs, attrs, {}, {'Out': num})
            return res['Out']
        elif isinstance(num_or_sections, list):
            num = len(num_or_sections)
            attrs['sections'] = list(
                map(lambda ele: -1 if isinstance(ele, Variable) else ele,
                    num_or_sections))
            contain_var = not all(not isinstance(ele, Variable)
                                  for ele in num_or_sections)
            if contain_var:
                raise TypeError(
                    "The type of 'num_or_sections' in split must be int or list[int] in Dygraph mode, but "
                    "received %s." % ('list[Variable]'))
        else:
            raise TypeError(
                "The type of 'num_or_sections' in split must be int or list in Dygraph mode, but "
                "received %s." % (type(num_or_sections)))

4361 4362 4363 4364 4365 4366 4367 4368 4369
    if not isinstance(num_or_sections, (int, list, tuple)):
        raise TypeError(
            "The type of 'num_or_sections' in split must be int, list or "
            "tuple, but received %s." % (type(num_or_sections)))
    if not isinstance(dim, (int, Variable)):
        raise TypeError(
            "The type of 'dim' in split must be int or Variable, but "
            "received %s." % (type(dim)))

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4370 4371
    helper = LayerHelper('split', **locals())
    input_shape = input.shape
4372 4373 4374 4375 4376 4377 4378 4379 4380 4381 4382 4383 4384 4385 4386 4387 4388 4389 4390 4391 4392 4393 4394 4395 4396 4397 4398 4399 4400 4401 4402
    inputs = {'X': input}
    attrs = {'num': num_or_sections if isinstance(num_or_sections, int) else 0}

    def _get_SectionsTensorList(one_list):
        tensor_list = []
        unk_dim_idx = -1
        for idx, dim_size in enumerate(one_list):
            if isinstance(dim_size, Variable):
                dim_size.stop_gradient = True
                tensor_list.append(dim_size)
            else:
                assert (isinstance(dim_size, int))
                if dim_size == -1:
                    assert unk_dim_idx == -1, (
                        "Only one value of 'num_or_section' in split can "
                        "be -1. But received num_or_section[%d] is also -1." %
                        idx)
                    unk_dim_idx = idx
                temp_out = helper.create_variable_for_type_inference('int32')
                fill_constant(
                    [1], 'int32', dim_size, force_cpu=True, out=temp_out)
                tensor_list.append(temp_out)
        return tensor_list

    if isinstance(dim, Variable):
        dim.stop_gradient = True
        inputs['AxisTensor'] = dim
    else:
        dim = (len(input_shape) + dim) if dim < 0 else dim
        attrs['axis'] = dim

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4403 4404
    if isinstance(num_or_sections, int):
        assert num_or_sections > 1, 'num_or_sections must be more than 1.'
4405 4406 4407 4408 4409
        if isinstance(dim, int) and input_shape[dim] > 0:
            assert input_shape[dim] % num_or_sections ==0, \
                "The input's size along the split dimension " \
                "must be evenly divisible by Attr(num_or_sections). " \
                "But %d is not evenly divisible by %d. " % (num_or_sections,input_shape[dim])
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4410 4411
        num = num_or_sections
    else:
4412 4413 4414
        if isinstance(dim, int) and input_shape[dim] > 0:
            assert len(num_or_sections) <= input_shape[
                dim], 'len(num_or_sections) must not be more than input.shape[dim].'
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        num = len(num_or_sections)
4416 4417 4418 4419 4420 4421 4422 4423 4424
        attrs['sections'] = list(
            map(lambda ele: -1 if isinstance(ele, Variable) else ele,
                num_or_sections))
        contain_var = not all(not isinstance(ele, Variable)
                              for ele in num_or_sections)
        if contain_var:
            inputs['SectionsTensorList'] = _get_SectionsTensorList(
                num_or_sections)

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    outs = [
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4426
        helper.create_variable_for_type_inference(dtype=helper.input_dtype())
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4427 4428 4429
        for i in range(num)
    ]
    helper.append_op(
4430
        type='split', inputs=inputs, outputs={'Out': outs}, attrs=attrs)
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4431
    return outs
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4432 4433 4434 4435


def l2_normalize(x, axis, epsilon=1e-12, name=None):
    """
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4436
    This op normalizes `x` along dimension `axis` using an L2
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4437 4438
    norm. For a 1-D tensor (`dim` is fixed to 0), this layer computes

4439
    .. math::
4440 4441

        y = \\frac{x}{ \sqrt{\sum {x^2} + epsion }}
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4442 4443 4444 4445 4446

    For `x` with more dimensions, this layer independently normalizes each 1-D
    slice along dimension `axis`.

    Args:
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4447
        x(Variable|list): The input tensor could be N-D tensor, and the input data type could be float32 or float64.
4448
        axis(int): The axis on which to apply normalization. If `axis < 0`, \
4449 4450
            the dimension to normalization is rank(X) + axis. -1 is the
            last dimension.
4451
        epsilon(float): The epsilon value is used to avoid division by zero, \
翟飞跃 已提交
4452
            the default value is 1e-12.
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4453 4454
	name(str, optional): The default value is None.  Normally there is no need for user to set this property.  For more information, please refer to :ref:`api_guide_Name`
    
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4455
    Returns:
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        Variable: The output has the same shape and data type with `x`.
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4457 4458

    Examples:
4459

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4460
        .. code-block:: python
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4461 4462 4463 4464 4465 4466 4467 4468 4469 4470 4471 4472
	    
	    # declarative mode
	    import paddle.fluid as fluid
	    import numpy as np
	    input = fluid.data(name="input", shape=[2,3])
	    output = fluid.layers.l2_normalize(x=input,axis=0)
	    place = fluid.CPUPlace()
	    exe = fluid.Executor(place)
	    exe.run(fluid.default_startup_program())
 
	    input_data = np.random.rand(2,3).astype("float32")
	    print(input_data)
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4473

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4474 4475 4476 4477 4478 4479 4480 4481 4482 4483 4484 4485 4486 4487 4488 4489 4490 4491 4492 4493 4494 4495 4496 4497
	    # [[0.5171216  0.12704141 0.56018186]
	    # [0.93251234 0.5382788  0.81709313]]
	
	    output_data = exe.run(fluid.default_main_program(),
                feed={"input":input_data},
                fetch_list=[output],
                return_numpy=True)
 
	    print(output_data)

	    # [array([[0.48496857, 0.22970329, 0.56545246],
	    # [0.8745316 , 0.9732607 , 0.82478094]], dtype=float32)]

	    # imperative mode
	    import paddle.fluid.dygraph as dg

	    with dg.guard(place) as g:
    		input = dg.to_variable(input_data)
    		output = fluid.layers.l2_normalize(x=input, axis=-1)
    		print(output.numpy())
	    	
		# [[0.66907585 0.16437206 0.7247892 ]
		# [0.6899054  0.3982376  0.6045142 ]]
		
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4498 4499
    """

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4500 4501
    if len(x.shape) == 1:
        axis = 0
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4502 4503
    helper = LayerHelper("l2_normalize", **locals())

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4504 4505
    out = helper.create_variable_for_type_inference(dtype=x.dtype)
    norm = helper.create_variable_for_type_inference(dtype=x.dtype)
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    helper.append_op(
4507 4508 4509 4510
        type="norm",
        inputs={"X": x},
        outputs={"Out": out,
                 "Norm": norm},
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        attrs={
4512 4513
            "axis": 1 if axis is None else axis,
            "epsilon": epsilon,
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        })
    return out
4516 4517


S
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def matmul(x, y, transpose_x=False, transpose_y=False, alpha=1.0, name=None):
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4519
    """
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4520 4521 4522 4523
    Applies matrix multiplication to two tensors.

    Currently, the input tensors' rank can be any, but when the rank of any
    inputs is bigger than 3, this two inputs' rank should be equal.
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4524

C
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    The actual behavior depends on the shapes of :math:`x`, :math:`y` and the
4526
    flag values of :attr:`transpose_x`, :attr:`transpose_y`. Specifically:
G
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4527

4528 4529 4530 4531 4532
    - If a transpose flag is specified, the last two dimensions of the tensor
      are transposed. If the tensor is rank-1 of shape :math:`[D]`, then for
      :math:`x` it is treated as :math:`[1, D]` in nontransposed form and as
      :math:`[D, 1]` in transposed form, whereas for :math:`y` it is the
      opposite: It is treated as :math:`[D, 1]` in nontransposed form and as
4533
      :math:`[1, D]` in transposed form.
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4535
    - After transpose, the two tensors are 2-D or n-D and matrix multiplication
4536
      performs in the following way.
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4538
      - If both are 2-D, they are multiplied like conventional matrices.
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      - If either is n-D, it is treated as a stack of matrices residing in the
Y
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        last two dimensions and a batched matrix multiply supporting broadcast
4541
        applies on the two tensors.
G
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    Also note that if the raw tensor :math:`x` or :math:`y` is rank-1 and
    nontransposed, the prepended or appended dimension :math:`1` will be
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    removed after matrix multiplication.
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    Args:
        x (Variable): The input variable which is a Tensor or LoDTensor.
4549 4550 4551
        y (Variable): The input variable which is a Tensor or LoDTensor.
        transpose_x (bool): Whether to transpose :math:`x` before multiplication.
        transpose_y (bool): Whether to transpose :math:`y` before multiplication.
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        alpha (float): The scale of output. Default 1.0.
4553
        name(str|None): A name for this layer(optional). If set None, the layer
4554
            will be named automatically.
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    Returns:
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        Variable: The product Tensor (or LoDTensor) variable.
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4558

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4559 4560 4561
    Examples:
        .. code-block:: python

4562
            # Examples to clarify shapes of the inputs and output
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4563
            # x: [B, ..., M, K], y: [B, ..., K, N]
4564
            # fluid.layers.matmul(x, y)  # out: [B, ..., M, N]
Y
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4566
            # x: [B, M, K], y: [B, K, N]
4567
            # fluid.layers.matmul(x, y)  # out: [B, M, N]
Y
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4568

4569
            # x: [B, M, K], y: [K, N]
4570
            # fluid.layers.matmul(x, y)  # out: [B, M, N]
Y
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4571

4572
            # x: [M, K], y: [K, N]
4573
            # fluid.layers.matmul(x, y)  # out: [M, N]
Y
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4574 4575

            # x: [B, M, K], y: [K]
4576
            # fluid.layers.matmul(x, y)  # out: [B, M]
Y
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4577

4578
            # x: [K], y: [K]
4579
            # fluid.layers.matmul(x, y)  # out: [1]
4580

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4581
            # x: [M], y: [N]
4582 4583
            # fluid.layers.matmul(x, y, True, True)  # out: [M, N]

4584
            import paddle.fluid as fluid
4585 4586 4587
            x = fluid.layers.data(name='x', shape=[2, 3], dtype='float32')
            y = fluid.layers.data(name='y', shape=[3, 2], dtype='float32')
            out = fluid.layers.matmul(x, y, True, True)
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    """
4589 4590 4591 4592 4593 4594 4595 4596 4597 4598
    attrs = {
        'transpose_X': transpose_x,
        'transpose_Y': transpose_y,
        'alpha': float(alpha),
    }

    if in_dygraph_mode():
        inputs = {'X': [x], 'Y': [y]}
        outs = core.ops.matmul(inputs, attrs)
        return outs['Out'][0]
Y
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4599 4600

    def __check_input(x, y):
4601 4602
        var_names = {'x': x, 'y': y}
        for name, val in var_names.items():
4603 4604
            check_type_and_dtype(val, name, Variable,
                                 ['float16', 'float32', 'float64'], 'matmul')
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        x_shape = list(x.shape)
        y_shape = list(y.shape)
        if len(x_shape) == 1:
            x_shape = [1] + x_shape
        if len(y_shape) == 1:
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            y_shape = y_shape + [1]
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        # check the inner 2 dimensions
        if transpose_x:
            x_shape[-2], x_shape[-1] = x_shape[-1], x_shape[-2]
        if transpose_y:
            y_shape[-2], y_shape[-1] = y_shape[-1], y_shape[-2]
        if x_shape[-1] != y_shape[-2]:
4618 4619 4620 4621 4622
            assert (x_shape[-1] == -1) or (y_shape[-2] == -1),                         \
                "After performing an optional transpose, Input X's width should be "   \
                "equal to Y's width for multiplication "                               \
                "prerequisites. But received X's shape: %s, Y's shape: %s\n" %         \
                (x_shape, y_shape)
Y
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4623

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        if len(y_shape) > 2 and len(x_shape) > 2:
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            for i, dim_x in enumerate(x_shape[:-2]):
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                # don't check neg shape
                if dim_x < 0 or y_shape[i] < 0:
                    continue
Y
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4629
                if dim_x != y_shape[i]:
4630 4631 4632 4633 4634
                    raise ValueError(
                        "When the matrix is larger than 2 dimensions, the higher "
                        "dimensional values of the two matrices need to be equal. "
                        "But received x_shape[%d] != y_shape[%d]. X's shape: %s, "
                        "Y's shape: %s.\n" % (i, i, x_shape, y_shape))
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4635 4636 4637

    __check_input(x, y)

4638
    helper = LayerHelper('matmul', **locals())
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    out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    helper.append_op(
4641 4642 4643 4644
        type='matmul',
        inputs={'X': x,
                'Y': y},
        outputs={'Out': out},
4645
        attrs=attrs)
4646
    return out
4647 4648


4649
def topk(input, k, name=None):
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    """
4651
    This OP is used to find values and indices of the k largest entries
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4652 4653
    for the last dimension.

4654 4655
    If the input is a 1-D Tensor, finds the k largest entries and outputs
    their values and indices.
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4656 4657 4658 4659

    If the input is a Tensor with higher rank, this operator computes the top k
    entries along the last dimension.

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    .. code-block:: text

4662 4663 4664 4665 4666
        Case 1:

          Input:
            input.shape = [3, 4]
            input.data = [[5, 4, 2, 3],
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                     [9, 7, 10, 25],
                     [6, 2, 10, 1]]
            k = 2

4671
          Output:
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            The first output:
4673 4674
            values.shape = [3, 2]
            values.data = [[5, 4],
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                      [10, 25],
                      [6, 10]]

            The second output:
4679 4680
            indices.shape = [3, 2]
            indices.data = [[0, 1],
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                       [2, 3],
                       [0, 2]]

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    Args:
4685 4686 4687 4688
        input(Variable): The input tensor. Support data types: float32, float64.
        k(int | Variable): The number of top elements to look for along the last dimension
                           of input tensor.
        name (str, optional): Please refer to :ref:`api_guide_Name`, Default None.
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4689 4690

    Returns:
4691 4692
        Values (Variable): Input tensor's k largest elements along each last dimensional slice. The dimension is: :math:`input.shape[:-1]+[k]`.
        Indices (Variable): Indices of k largest elements alone the last dimension of input. The dimension is same as values.
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    Raises:
4695
        ValueError: If :math:`k < 1` or :math:`k > last dimension of input`.
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    Examples:
        .. code-block:: python

4700
            import paddle.fluid as fluid
4701
            import paddle.fluid.layers as layers
4702 4703 4704 4705 4706 4707 4708 4709 4710 4711 4712 4713 4714
            # set batch size=None
            input = fluid.data(name="input", shape=[None, 13, 11], dtype='float32')
            top5_values, top5_indices = layers.topk(input, k=5) # top5_values.shape[None, 13, 5], top5_indices.shape=[None, 13, 5]

            # 1D Tensor
            input1 = fluid.data(name="input1", shape=[None, 13], dtype='float32')
            top5_values, top5_indices = layers.topk(input1, k=5) #top5_values.shape=[None, 5], top5_indices.shape=[None, 5]

            # k=Variable
            input2 = fluid.data(name="input2", shape=[None, 13, 11], dtype='float32')
            vk = fluid.data(name="vk", shape=[None, 1], dtype='int32') # save k in vk.data[0]
            vk_values, vk_indices = layers.topk(input2, k=vk) #vk_values.shape=[None, 13, k], vk_indices.shape=[None, 13, k]

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    """
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    inputs = {"X": [input]}
4717
    attrs = {}
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4718
    if isinstance(k, Variable):
4719
        inputs['K'] = [k]
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4720 4721
    else:
        attrs = {'k': k}
4722 4723 4724 4725 4726 4727 4728 4729 4730 4731 4732

    if in_dygraph_mode():
        outs = core.ops.top_k(inputs, attrs)
        outs['Out'][0].stop_gradient = True
        outs['Indices'][0].stop_gradient = True
        return outs['Out'][0], outs['Indices'][0]

    helper = LayerHelper("top_k", **locals())
    values = helper.create_variable_for_type_inference(dtype=input.dtype)
    indices = helper.create_variable_for_type_inference(dtype="int64")

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    helper.append_op(
        type="top_k",
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        inputs=inputs,
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4736 4737
        outputs={"Out": [values],
                 "Indices": [indices]},
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        attrs=attrs)
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4739 4740 4741 4742 4743
    values.stop_gradient = True
    indices.stop_gradient = True
    return values, indices


4744 4745 4746 4747 4748
def ctc_greedy_decoder(input,
                       blank,
                       input_length=None,
                       padding_value=0,
                       name=None):
4749
    """
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    This op is used to decode sequences by greedy policy by the following steps:
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4752
    1. Get the indexes of maximum value for each row in input. a.k.a.
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       numpy.argmax(input, axis=0).
    2. For each sequence in result of step1, merge repeated tokens between two
       blanks and delete all blanks.
4756

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4757 4758 4759 4760
    This op is implemented in two modes: lod and padding, either of them can be used.
    The input can be either LoDTensor or Tensor, corresponding to lod and padding 
    mode respectively.

4761 4762 4763 4764 4765
    A simple example as below:

    .. code-block:: text

        Given:
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4766
        (1) for lod mode:
4767 4768 4769 4770 4771 4772 4773 4774 4775 4776 4777

        input.data = [[0.6, 0.1, 0.3, 0.1],
                      [0.3, 0.2, 0.4, 0.1],
                      [0.1, 0.5, 0.1, 0.3],
                      [0.5, 0.1, 0.3, 0.1],

                      [0.5, 0.1, 0.3, 0.1],
                      [0.2, 0.2, 0.2, 0.4],
                      [0.2, 0.2, 0.1, 0.5],
                      [0.5, 0.1, 0.3, 0.1]]

4778
        input.lod = [[4, 4]]
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W
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4780
        Computation:
4781

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4782 4783 4784 4785 4786 4787
        step1: Apply argmax to first input sequence which is input.data[0:4]. Then we get:
               [[0], [2], [1], [0]]
        step2: merge repeated tokens and remove blank which is 0. Then we get first output sequence:
               [[2], [1]]

        Finally:
4788 4789 4790 4791 4792

        output.data = [[2],
                       [1],
                       [3]]

4793
        output.lod = [[2, 1]]
4794

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4795
        (2) for padding mode:
4796 4797 4798 4799 4800 4801 4802 4803 4804 4805 4806 4807 4808 4809 4810 4811 4812 4813 4814 4815 4816 4817 4818 4819 4820 4821

         input.data = [[[0.6, 0.1, 0.3, 0.1],
                        [0.3, 0.2, 0.4, 0.1],
                        [0.1, 0.5, 0.1, 0.3],
                        [0.5, 0.1, 0.3, 0.1]],

                       [[0.5, 0.1, 0.3, 0.1],
                        [0.2, 0.2, 0.2, 0.4],
                        [0.2, 0.2, 0.1, 0.5],
                        [0.5, 0.1, 0.3, 0.1]]]

        input_length.data = [[4], [4]]
        input.shape = [2, 4, 4]

        step1: Apply argmax to first input sequence which is input.data[0:4]. Then we get:
               [[0], [2], [1], [0]], for input.data[4:8] is [[0], [3], [3], [0]], shape is [2,4,1]
        step2: Change the argmax result to use padding mode, then argmax result is 
                [[0, 2, 1, 0], [0, 3, 3, 0]], shape is [2, 4], lod is [], input_length is [[4], [4]]
        step3: Apply ctc_align to padding argmax result, padding_value is 0

        Finally:
        output.data = [[2, 1, 0, 0],
                       [3, 0, 0, 0]]
        output_length.data = [[2], [1]]


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4822
    Parameters:
4823

S
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4824 4825
        input(Variable): the probabilities of variable-length sequences. When in lod mode, 
                         it is a 2-D LoDTensor with LoD information. It's shape is [Lp, num_classes + 1] 
Y
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4826
                         where Lp is the sum of all input sequences' length and
4827 4828
                         num_classes is the true number of classes. When in padding mode,
                         it is a 3-D Tensor with padding, It's shape is [batch_size, N, num_classes + 1].
S
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4829
                         (not including the blank label). The data type can be float32 or float64.
Y
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4830
        blank(int): the blank label index of Connectionist Temporal
S
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4831
                    Classification (CTC) loss, which is in the half-opened
Y
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4832
                    interval [0, num_classes + 1).
S
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4833 4834
        input_length(Variable, optional): 2-D LoDTensor, shape is [batch_size, 1], data type is int64.
                                 It is used for padding mode. In lod mode, input_length is None.
4835
        padding_value(int): padding value.
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4836 4837 4838
        name(str, optional): The default value is None.  
                             Normally there is no need for user to set this property.  
                             For more information, please refer to :ref:`api_guide_Name` 
4839 4840

    Returns:
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4841 4842 4843 4844 4845 4846 4847 4848 4849 4850 4851 4852 4853 4854 4855 4856 4857
        For lod mode, returns the result of CTC greedy decoder, 2-D LoDTensor, shape is [Lp, 1], \
        data type is int64. 'Lp' is the sum of all output sequences' length. If all the sequences \
        in result were empty, the result LoDTensor will be [-1] with  empty \
        LoD [[]].

        For padding mode, returns a tuple of (output, output_length), which was describled as below: 

        output, 2-D Tensor, shape is [batch_size, N], data type is int64.

        output_length, 2-D Tensor, shape is [batch_size, 1], data type is int64. It is the length of \
                           each sequence of output for padding mode.

    Return type:
        For lod mode: Variable

        For padding mode: tuple of two Variables (output, output_length).

4858 4859 4860 4861

    Examples:
        .. code-block:: python

4862
            # for lod mode
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4863
            import paddle.fluid as fluid
S
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4864
            x = fluid.data(name='x', shape=[None, 8], dtype='float32', lod_level=1)
4865
            cost = fluid.layers.ctc_greedy_decoder(input=x, blank=0)
4866 4867

            # for padding mode
S
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4868 4869
            x_pad = fluid.data(name='x_pad', shape=[10, 4, 8], dtype='float32')
            x_pad_len = fluid.data(name='x_pad_len', shape=[10, 1], dtype='int64')
4870 4871 4872
            out, out_len = fluid.layers.ctc_greedy_decoder(input=x_pad, blank=0,
                            input_length=x_pad_len)

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4873
    """
4874
    helper = LayerHelper("ctc_greedy_decoder", **locals())
Q
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4875
    _, topk_indices = topk(input, k=1)
4876 4877

    # ctc align op
X
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4878
    ctc_out = helper.create_variable_for_type_inference(dtype="int64")
4879 4880 4881 4882 4883 4884 4885 4886 4887 4888 4889 4890 4891 4892 4893 4894 4895 4896 4897 4898 4899 4900 4901 4902 4903

    if input_length is None:
        helper.append_op(
            type="ctc_align",
            inputs={"Input": [topk_indices]},
            outputs={"Output": [ctc_out]},
            attrs={"merge_repeated": True,
                   "blank": blank})
        return ctc_out
    else:
        ctc_out_len = helper.create_variable_for_type_inference(dtype="int64")
        ctc_input = squeeze(topk_indices, [2])

        helper.append_op(
            type="ctc_align",
            inputs={"Input": [ctc_input],
                    "InputLength": [input_length]},
            outputs={"Output": [ctc_out],
                     "OutputLength": [ctc_out_len]},
            attrs={
                "merge_repeated": True,
                "blank": blank,
                "padding_value": padding_value
            })
        return ctc_out, ctc_out_len
4904 4905


Y
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4906
def transpose(x, perm, name=None):
Y
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4907
    """
4908
    Permute the data dimensions of `input` according to `perm`.
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4909 4910 4911 4912 4913

    The `i`-th dimension  of the returned tensor will correspond to the
    perm[i]-th dimension of `input`.

    Args:
4914 4915
        x (Variable): The input Tensor. It is a N-D Tensor of data types float32, float64, int32.
        perm (list): Permute the input accoring to the data of perm.
4916
        name (str): The name of this layer. It is optional.
Y
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4917 4918

    Returns:
4919 4920 4921 4922 4923 4924 4925 4926 4927 4928 4929 4930 4931 4932 4933 4934 4935 4936 4937 4938 4939 4940 4941 4942
        Variable: A transposed n-D Tensor, with data type being float32, float64, int32, int64.

    For Example:

        .. code-block:: text

         x = [[[ 1  2  3  4] [ 5  6  7  8] [ 9 10 11 12]]
             [[13 14 15 16] [17 18 19 20] [21 22 23 24]]]
         shape(x) =  [2,3,4]

         # Example 1
         perm0 = [1,0,2]
         y_perm0 = [[[ 1  2  3  4] [13 14 15 16]]
                   [[ 5  6  7  8]  [17 18 19 20]]
                   [[ 9 10 11 12]  [21 22 23 24]]]
         shape(y_perm0) = [3,2,4]

         # Example 2
         perm1 = [2,1,0]
         y_perm1 = [[[ 1 13] [ 5 17] [ 9 21]]
                   [[ 2 14] [ 6 18] [10 22]]
                   [[ 3 15]  [ 7 19]  [11 23]]
                   [[ 4 16]  [ 8 20]  [12 24]]]
         shape(y_perm1) = [4,3,2]
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4943 4944

    Examples:
4945

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4946 4947
        .. code-block:: python

4948
            # use append_batch_size=False to avoid prepending extra
4949
            # batch size in shape
4950
            import paddle.fluid as fluid
4951
            x = fluid.layers.data(name='x', shape=[2, 3, 4],
4952
                            dtype='float32', append_batch_size=False)
4953
            x_transposed = fluid.layers.transpose(x, perm=[1, 0, 2])
4954 4955
            print x_transposed.shape
            #(3L, 2L, 4L)
Y
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4956

4957
    """
4958 4959 4960 4961 4962 4963
    if in_dygraph_mode():
        attrs = {'axis': perm}
        inputs = {'X': [x]}
        outs = core.ops.transpose2(inputs, attrs)
        return outs['Out'][0]

4964 4965 4966 4967
    check_type_and_dtype(x, 'x', Variable,
                         ['float16', 'float32', 'float64', 'int32', 'int64'],
                         'transpose')
    check_type(perm, 'perm', list, 'transpose')
4968

Y
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ying 已提交
4969
    if len(perm) != len(x.shape):
Y
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4970
        raise ValueError(
4971 4972 4973 4974
            "Input(perm) is the permutation of dimensions of Input(x), "
            "its length should be equal to dimensions of Input(x), "
            "but received dimension of Input(x) is %s, "
            "the length of Input(perm) is %s." % (len(x.shape), len(perm)))
Y
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4975 4976 4977
    for idx, dim in enumerate(perm):
        if dim >= len(x.shape):
            raise ValueError(
4978 4979 4980
                "Each element in Input(perm) should be less than Input(x)'s dimension, "
                "but %d-th element in Input(perm) is %d which exceeds Input(x)'s "
                "dimension %d." % (idx, perm[idx], len(x.shape)))
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4981 4982

    helper = LayerHelper('transpose', **locals())
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4983 4984
    out = helper.create_variable_for_type_inference(x.dtype)
    x_shape = helper.create_variable_for_type_inference(x.dtype)
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    helper.append_op(
4986
        type='transpose2',
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        inputs={'X': [x]},
4988 4989
        outputs={'Out': [out],
                 'XShape': [x_shape]},
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        attrs={'axis': perm})
    return out
4992 4993


4994 4995 4996 4997 4998 4999 5000
def im2sequence(input,
                filter_size=1,
                stride=1,
                padding=0,
                input_image_size=None,
                out_stride=1,
                name=None):
5001
    """
5002
    Extracts image patches from the input tensor to form a tensor of shape
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    {input.batch_size * output_height * output_width, filter_size_height *
    filter_size_width * input.channels}. This op use filter to scan images
    and convert these images to sequences. After expanding, the number of time step are
5006 5007
    output_height * output_width for an image, in which output_height and
    output_width are calculated by below equation:
5008 5009 5010

    .. math::

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5011 5012 5013 5014
        output\_height  = 1 + \
            (padding\_up + padding\_down + input\_height  - filter\_size\_height  + stride\_height - 1) / stride\_height \\\\
        output\_width  = 1 + \
            (padding\_left + padding\_right + input\_width  - filter\_size\_width  + stride\_width - 1) / stride\_width
5015

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5016
    And the dimension of each time step is filter_size_height * filter_size_width * input.channels.
5017

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5018 5019
    Parameters:
        input (Variable): The input should be a 4-D Tensor in :math:`NCHW` format. The data type is float32.
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        filter_size(int32 | List[int32]): The filter size. If filter_size is a List,
            it must contain two integers, :math:`[filter\_size\_height, filter\_size\_width]` .
            Otherwise, the filter size will be a square :math:`[filter\_size, filter\_size]` . Default is 1.
5024

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        stride(int32 | List[int32]): The stride size. If stride is a List, it must
            contain two integers, :math:`[stride\_height, stride\_width]` . Otherwise, the stride size will be a square :math:`[stride\_size, stride\_size]` . Default is 1.
5027

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        padding(int32 | List[int32]): The padding size. If padding is a List, it can
            contain four integers like :math:`[padding\_up, padding\_left, padding\_down, padding\_right]` to indicate
            paddings of four direction.  Or it can contain two integers :math:`[padding\_height, padding\_width]` which means
            padding_up = padding_down = padding_height and
            padding_left = padding_right = padding_width. Otherwise, a scalar padding means
            padding_up = padding_down = padding_left = padding_right = padding. 
            Default is 0.
5035

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        input_image_size(Variable, optional): the input contains image real size.It's dim
            is :math:`[batchsize, 2]` . It is just for batch inference when not None. Default is None.

        out_stride(int32 | List[int32]): The scaling of image through CNN. It is valid only when input_image_size is not None.
            If out_stride is List,  it must contain two intergers,
            :math:`[out\_stride\_height, out\_stride\_W]` . Otherwise,
            the out_stride_height = out_stride_width = out_stride. Default is 1.

        name (str, optional): The default value is None.  Normally there is no need for
                    user to set this property.  For more information, please refer to :ref:`api_guide_Name` .
    
    Returns: 
            The output is a 2-D LoDTensor with shape {input.batch\_size * output\_height * output\_width, \ 
            filter\_size\_height * filter\_size\_width * input.channels}. The data type is float32.

    Return Type: Variable
5052 5053 5054 5055 5056 5057 5058 5059 5060 5061 5062 5063 5064 5065 5066 5067 5068 5069 5070 5071 5072 5073 5074 5075 5076 5077 5078

    Examples:

        .. code-block:: text

            Given:

            x = [[[[ 6.  2.  1.]
                   [ 8.  3.  5.]
                   [ 0.  2.  6.]]

                  [[ 2.  4.  4.]
                   [ 6.  3.  0.]
                   [ 6.  4.  7.]]]

                 [[[ 6.  7.  1.]
                   [ 5.  7.  9.]
                   [ 2.  4.  8.]]

                  [[ 1.  2.  1.]
                   [ 1.  3.  5.]
                   [ 9.  0.  8.]]]]

            x.dims = {2, 2, 3, 3}

            And:

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            filter = [2, 2]
            stride = [1, 1]
            padding = [0, 0]
5082 5083 5084 5085 5086 5087 5088 5089 5090 5091 5092 5093

            Then:

            output.data = [[ 6.  2.  8.  3.  2.  4.  6.  3.]
                           [ 2.  1.  3.  5.  4.  4.  3.  0.]
                           [ 8.  3.  0.  2.  6.  3.  6.  4.]
                           [ 3.  5.  2.  6.  3.  0.  4.  7.]
                           [ 6.  7.  5.  7.  1.  2.  1.  3.]
                           [ 7.  1.  7.  9.  2.  1.  3.  5.]
                           [ 5.  7.  2.  4.  1.  3.  9.  0.]
                           [ 7.  9.  4.  8.  3.  5.  0.  8.]]

5094
            output.dims = {8, 8}
5095

5096
            output.lod = [[4, 4]]
5097

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    Examples:
5099 5100 5101

        .. code-block:: python

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            import paddle.fluid as fluid
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            data = fluid.data(name='data', shape=[None, 3, 32, 32],
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                                     dtype='float32')
5105
            output = fluid.layers.im2sequence(
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                input=data, stride=[1, 1], filter_size=[2, 2])

5108 5109

    """
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    assert not in_dygraph_mode(), (
5111
        "sequence layer is not supported in dygraph mode yet.")
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    if isinstance(filter_size, int):
        filter_size = [filter_size, filter_size]
    if isinstance(stride, int):
        stride = [stride, stride]
    if isinstance(padding, int):
        padding = [padding, padding]
    if len(padding) == 2:
        padding.append(padding[0])
        padding.append(padding[1])
5122
    inputs = {"X": input}
5123
    attrs = {"kernels": filter_size, "strides": stride, "paddings": padding}
5124 5125 5126 5127 5128
    if input_image_size:
        if isinstance(out_stride, int):
            out_stride = [out_stride, out_stride]
        inputs["Y"] = input_image_size
        attrs["out_stride"] = out_stride
5129
    helper = LayerHelper('im2sequence', **locals())
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    out = helper.create_variable_for_type_inference(dtype=helper.input_dtype())
5131
    helper.append_op(
5132
        type='im2sequence', inputs=inputs, outputs={'Out': out}, attrs=attrs)
5133
    return out
5134 5135


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@templatedoc()
5137
def row_conv(input, future_context_size, param_attr=None, act=None):
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5138 5139
    """
    ${comment}
5140 5141

    Args:
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        input (${x_type}): ${x_comment}.
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        future_context_size (int): Future context size. Please note, the shape
            of convolution kernel is [future_context_size + 1, D].
5145 5146 5147 5148 5149
        param_attr (ParamAttr): Attributes of parameters, including
            name, initializer etc.
        act (str): Non-linear activation to be applied to output variable.

    Returns:
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        ${out_comment}.
5151 5152

    Examples:
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        >>>  # for LodTensor inputs
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        >>> import paddle.fluid as fluid
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        >>> x = fluid.data(name='x', shape=[9, 16],
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        >>>                        dtype='float32', lod_level=1)
        >>> out = fluid.layers.row_conv(input=x, future_context_size=2)
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        >>> # for Tensor inputs
        >>> x = fluid.data(name='x', shape=[9, 4, 16], dtype='float32')
        >>> out = fluid.layers.row_conv(input=x, future_context_size=2)
5161 5162 5163 5164 5165 5166
    """
    helper = LayerHelper('row_conv', **locals())
    dtype = helper.input_dtype()
    filter_shape = [future_context_size + 1, input.shape[1]]
    filter_param = helper.create_parameter(
        attr=helper.param_attr, shape=filter_shape, dtype=dtype)
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    out = helper.create_variable_for_type_inference(dtype)
5168 5169 5170 5171 5172
    helper.append_op(
        type='row_conv',
        inputs={'X': [input],
                'Filter': [filter_param]},
        outputs={'Out': [out]})
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    return helper.append_activation(out)
5174 5175


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5176
@templatedoc()
5177 5178
def multiplex(inputs, index):
    """
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5179

5180
    Based on the given index parameter, the OP selects a specific row from each input Tensor to construct the output Tensor.
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5182
    If the input of this OP contains :math:`m` Tensors, where :math:`I_{i}` means the i-th input Tensor, :math:`i` between :math:`[0,m)` .
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5184
    And :math:`O` means the output, where :math:`O[i]` means the i-th row of the output, then the output satisfies that :math:`O[i] = I_{index[i]}[i]` .
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5185

5186
    For Example:
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5187

5188
            .. code-block:: text
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5189

5190
                Given:
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5191

5192 5193 5194 5195
                inputs = [[[0,0,3,4], [0,1,3,4], [0,2,4,4], [0,3,3,4]],
                          [[1,0,3,4], [1,1,7,8], [1,2,4,2], [1,3,3,4]],
                          [[2,0,3,4], [2,1,7,8], [2,2,4,2], [2,3,3,4]],
                          [[3,0,3,4], [3,1,7,8], [3,2,4,2], [3,3,3,4]]]
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5196

5197
                index = [[3],[0],[1],[2]]
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5199 5200 5201 5202
                out = [[3,0,3,4],    # out[0] = inputs[index[0]][0] = inputs[3][0] = [3,0,3,4]
                       [0,1,3,4],    # out[1] = inputs[index[1]][1] = inputs[0][1] = [0,1,3,4]
                       [1,2,4,2],    # out[2] = inputs[index[2]][2] = inputs[1][2] = [1,2,4,2]
                       [2,3,3,4]]    # out[3] = inputs[index[3]][3] = inputs[2][3] = [2,3,3,4]
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5205 5206 5207
    Args:
       inputs (list): The input Tensor list. The list elements are N-D Tensors of data types float32, float64, int32, int64. All input Tensor shapes should be the same and rank must be at least 2.
       index (Variable): Used to select some rows in the input Tensor to construct an index of the output Tensor. It is a 2-D Tensor with data type int32 or int64 and shape [M, 1], where M is the number of input Tensors.
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5208

5209
    Returns:
5210
        Variable(Tensor): Output of multiplex OP, with data type being float32, float64, int32, int64.
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5211 5212

    Examples:
5213

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5214 5215
        .. code-block:: python

5216
            import paddle.fluid as fluid
5217
            import numpy as np
5218

5219 5220 5221 5222
            x1 = fluid.data(name='x1', shape=[None, 2], dtype='float32')
            x2 = fluid.data(name='x2', shape=[None, 2], dtype='float32')
            index = fluid.data(name='index', shape=[None, 1], dtype='int32')
            out = fluid.layers.multiplex(inputs=[x1, x2], index=index)
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5224 5225 5226 5227 5228 5229 5230 5231 5232
            exe = fluid.Executor(fluid.CPUPlace())
            exe.run(fluid.default_startup_program())

            img1 = np.array([[1, 2], [3, 4]]).astype(np.float32)
            img2 = np.array([[5, 6], [7, 8]]).astype(np.float32)
            index = np.array([[1], [0]]).astype(np.int32)

            res = exe.run(fluid.default_main_program(), feed={'x1':img1, 'x2':img2, 'index':index}, fetch_list=[out])
            print(res) # [array([[5., 6.], [3., 4.]], dtype=float32)]
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5234 5235 5236 5237 5238 5239 5240 5241
    """
    helper = LayerHelper('multiplex', **locals())

    if not isinstance(inputs, list) and len(inputs) < 2:
        raise ValueError("inputs should be a list object and contains at least "
                         "2 elements.")

    out = helper.create_variable_for_type_inference(inputs[0].dtype)
5242
    helper.append_op(
5243 5244 5245 5246 5247
        type='multiplex',
        inputs={'X': inputs,
                'Ids': index},
        outputs={'Out': [out]})
    return out
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5248 5249


5250 5251
def smooth_l1(x, y, inside_weight=None, outside_weight=None, sigma=None):
    """
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5252 5253
    This layer computes the smooth L1 loss for Variable :attr:`x` and :attr:`y`.
    It takes the first dimension of :attr:`x` and :attr:`y` as batch size.
Q
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5254
    For each instance, it computes the smooth L1 loss element by element first
5255
    and then sums all the losses. So the shape of ouput Variable is
5256
    [batch_size, 1].
5257

5258 5259
    Args:
        x (Variable): A tensor with rank at least 2. The input value of smooth
Q
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5260
            L1 loss op with shape [batch_size, dim1, ..., dimN].
5261
            A LoDTensor or Tensor with type float32.
5262
        y (Variable): A tensor with rank at least 2. The target value of smooth
Y
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5263
            L1 loss op with same shape as :attr:`x`.
5264
            A LoDTensor or Tensor with type float32.
5265
        inside_weight (Variable|None):  A tensor with rank at least 2. This
5266 5267
            input is optional and should have same shape with :attr:`x`. If
            provided, the result of (:attr:`x` - :attr:`y`) will be multiplied
Y
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5268
            by this tensor element by element.
5269
            A Tensor with type float32.
5270
        outside_weight (Variable|None): A tensor with rank at least 2. This
5271 5272
            input is optional and should have same shape with :attr:`x`. If
            provided, the out smooth L1 loss will be multiplied by this tensor
Y
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5273
            element by element.
5274
            A Tensor with type float32.
5275
        sigma (float|None): Hyper parameter of smooth L1 loss layer. A float
5276 5277
           scalar with default value 1.0.

5278
    Returns:
5279
        Variable: The output smooth L1 loss with shape [batch_size, 1].  A Tensor with type float32.
5280 5281 5282 5283

    Examples:
        .. code-block:: python

5284
            import paddle.fluid as fluid
5285 5286 5287 5288 5289 5290 5291 5292 5293 5294 5295 5296 5297 5298 5299 5300 5301
            import numpy as np
            data = fluid.data(name="x", shape=[-1, 3], dtype="float32")
            label = fluid.data(name="y", shape=[-1, 3], dtype="float32")
            result = fluid.layers.smooth_l1(data,label)
            place = fluid.CPUPlace()
            exe = fluid.Executor(place)
            exe.run(fluid.default_startup_program())
            x = np.random.rand(3,3).astype("float32")
            y = np.random.rand(3,3).astype("float32")
            output= exe.run(feed={"x":x, "y":y},
                             fetch_list=[result])
            print(output)
        
            #[array([[0.08220536],
            #       [0.36652038],
            #      [0.20541131]], dtype=float32)]

5302
    """
5303

5304
    helper = LayerHelper('smooth_l1_loss', **locals())
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5305 5306
    diff = helper.create_variable_for_type_inference(dtype=x.dtype)
    loss = helper.create_variable_for_type_inference(dtype=x.dtype)
5307 5308 5309 5310 5311 5312 5313 5314 5315 5316
    helper.append_op(
        type='smooth_l1_loss',
        inputs={
            'X': x,
            'Y': y,
            'InsideWeight': inside_weight,
            'OutsideWeight': outside_weight
        },
        outputs={'Diff': diff,
                 'Out': loss},
5317
        attrs={'sigma': sigma if sigma is not None else 1.0})
5318
    return loss
5319 5320


5321
def one_hot(input, depth, allow_out_of_range=False):
5322
    """
5323 5324 5325 5326 5327 5328 5329 5330 5331 5332 5333 5334 5335 5336 5337 5338 5339 5340 5341 5342 5343 5344 5345 5346 5347 5348 5349 5350 5351 5352 5353 5354 5355 5356 5357 5358 5359 5360 5361 5362 5363 5364 5365 5366 5367 5368 5369 5370 5371 5372 5373 5374 5375 5376

    **WARING:** This OP requires the last dimension of Tensor shape must be equal to 1.
    This OP will be deprecated in a future release. It is recommended to use fluid. :ref:`api_fluid_one_hot` .

    The operator converts each id in the input to an one-hot vector with a
    :attr:`depth` length. The value in the vector dimension corresponding to the id
    is 1, and the value in the remaining dimension is 0.

    The shape of output Tensor or LoDTensor is generated by adding :attr:`depth` dimension
    behind the last dimension of the input shape.

    .. code-block:: text

        Example 1 (allow_out_of_range=False):

        input:
            X.shape = [4, 1]
            X.data = [[1], [1], [3], [0]]
            depth = 4

        output:
            Out.shape = [4, 4]
            Out.data = [[0., 1., 0., 0.],
                        [0., 1., 0., 0.],
                        [0., 0., 0., 1.],
                        [1., 0., 0., 0.]]

        Example 2 (allow_out_of_range=True):

        input:
            X.shape = [4, 1]
            X.data = [[1], [1], [5], [0]]
            depth = 4
            allow_out_of_range = True

        output:
            Out.shape = [4, 4]
            Out.data = [[0., 1., 0., 0.],
                        [0., 1., 0., 0.], 
                        [0., 0., 0., 0.], # This id is 5, which goes beyond depth, so set it all-zeros data.
                        [1., 0., 0., 0.]]

        Example 3 (allow_out_of_range=False):

        input:
            X.shape = [4, 1]
            X.data = [[1], [1], [5], [0]]
            depth = 4
            allow_out_of_range = False

        output: Throw an exception for Illegal value
            The second dimension in X is 5, which is greater than depth.  
            Allow_out_of_range =False means that does not allow the word id to exceed depth,
            so it throws an exception.
5377 5378

    Args:
5379 5380 5381 5382 5383
        input(Variable): Tensor or LoDTensor with shape :math:`[N_1, N_2, ..., N_k, 1]` ,
            which contains at least one dimension and the last dimension must be 1.
            The data type is int32 or int64.
        depth(scalar): An integer defining the :attr:`depth` of the one hot dimension. If input 
            is word id, depth is generally the dictionary size.
5384
        allow_out_of_range(bool): A bool value indicating whether the input
5385 5386 5387 5388
            indices could be out of range :math:`[0, depth)` . When input indices are
            out of range, exceptions :code:`Illegal value` is raised if :attr:`allow_out_of_range`
            is False, or zero-filling representations is created if it is set True.
            Default: False.
5389 5390

    Returns:
5391
        Variable: The one-hot representations of input. A Tensor or LoDTensor with type float32.
5392 5393

    Examples:
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5394
        .. code-block:: python
5395

5396
            import paddle.fluid as fluid
5397 5398 5399
            # Correspond to the first example above, where label.shape is [4, 1] and one_hot_label.shape is [4, 4].
            label = fluid.data(name="label", shape=[4, 1], dtype="int64")
            one_hot_label = fluid.layers.one_hot(input=label, depth=4)
5400 5401
    """
    helper = LayerHelper("one_hot", **locals())
5402

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5403
    one_hot_out = helper.create_variable_for_type_inference(dtype='float32')
5404 5405 5406

    if in_dygraph_mode():
        inputs = {'X': input}
Y
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5407
        attrs = {'depth': depth, 'allow_out_of_range': allow_out_of_range}
5408 5409
    else:
        if not isinstance(depth, Variable):
G
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5410
            # user attribute
5411
            inputs = {'X': input}
Y
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5412
            attrs = {'depth': depth, 'allow_out_of_range': allow_out_of_range}
5413
        else:
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5414
            depth.stop_gradient = True
5415
            inputs = {'X': input, 'depth_tensor': depth}
Y
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5416
            attrs = {'allow_out_of_range': allow_out_of_range}
5417 5418
    helper.append_op(
        type="one_hot",
5419 5420
        inputs=inputs,
        attrs=attrs,
5421 5422
        outputs={'Out': one_hot_out})
    one_hot_out.stop_gradient = True
5423
    return one_hot_out
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5424 5425


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5426
def autoincreased_step_counter(counter_name=None, begin=1, step=1):
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5427
    """
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5428 5429 5430
    Create an auto-increase variable. which will be automatically increased 
    by 1 in every iteration. By default, the first return of this counter is 1, 
    and the step size is 1.
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5431 5432

    Args:
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5433 5434 5435
        counter_name(str, optional): The counter name. Default '@STEP_COUNTER@'.
        begin(int, optional): The first return value of this counter. Default 1.
        step(int, optional): The step size. Default 1.
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5436

5437
    Returns:
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5438
        Variable: The auto-increased Variable with data type int64.
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5439 5440 5441 5442

    Examples:
        .. code-block:: python

5443
           import paddle.fluid as fluid
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           global_step = fluid.layers.autoincreased_step_counter(
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               counter_name='@LR_DECAY_COUNTER@', begin=0, step=1)
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    """
    helper = LayerHelper('global_step_counter')
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    if counter_name is None:
        counter_name = '@STEP_COUNTER@'
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    counter, is_new_var = helper.create_or_get_global_variable(
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        name=counter_name,
        dtype='int64',
        shape=[1],
        persistable=True,
        belong_to_optimizer=True)
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    if is_new_var:
        helper.set_variable_initializer(
            counter, initializer=Constant(
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                value=begin - 1, force_cpu=True))
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        helper.main_program.global_block()._prepend_op(
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            type='increment',
            inputs={'X': [counter]},
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            outputs={'Out': [counter]},
5464
            attrs={'step': float(step)})
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        counter.stop_gradient = True

    return counter
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5470
def reshape(x, shape, actual_shape=None, act=None, inplace=False, name=None):
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    """
5472
    This operator changes the shape of ``x`` without changing its data.
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5473

5474 5475 5476 5477
    The target shape can be given by ``shape`` or ``actual_shape``.
    When ``shape`` and ``actual_shape`` are set at the same time,
    ``actual_shape`` has a higher priority than ``shape``
    but at this time ``shape`` can only be an integer list or tuple, and ``shape`` still should be set correctly to
5478
    gurantee shape inference in compile-time.
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5480
    Some tricks exist when specifying the target shape.
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5482 5483 5484 5485
    1. -1 means the value of this dimension is inferred from the total element
    number of x and remaining dimensions. Thus one and only one dimension can
    be set -1.

5486
    2. 0 means the actual dimension value is going to be copied from the
5487
    corresponding dimension of x. The indice of 0s in shape can not exceed
5488
    the dimension of x.
5489 5490

    Here are some examples to explain it.
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    1. Given a 3-D tensor x with a shape [2, 4, 6], and the target shape
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    is [6, 8], the reshape operator will transform x into a 2-D tensor with
5494
    shape [6, 8] and leaving x's data unchanged.
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5496
    2. Given a 3-D tensor x with a shape [2, 4, 6], and the target shape
5497 5498
    specified is [2, 3, -1, 2], the reshape operator will transform x into a
    4-D tensor with shape [2, 3, 4, 2] and leaving x's data unchanged. In this
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    case, one dimension of the target shape is set to -1, the value of this
    dimension is inferred from the total element number of x and remaining
5501
    dimensions.
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5503
    3. Given a 3-D tensor x with a shape [2, 4, 6], and the target shape
5504 5505 5506 5507
    is [-1, 0, 3, 2], the reshape operator will transform x into a 4-D tensor
    with shape [2, 4, 3, 2] and leaving x's data unchanged. In this case,
    besides -1, 0 means the actual dimension value is going to be copied from
    the corresponding dimension of x.
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5509 5510
    **Note**:
        The parameter ``actual_shape`` will be deprecated in the future and only use ``shape`` instead to represent the target shape.
5511

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    Args:
5513 5514 5515 5516 5517 5518 5519 5520 5521 5522 5523 5524 5525 5526 5527 5528 5529
        x(Variable): A ``Tensor`` or ``LoDTensor`` . The data type is ``float32``, ``float64``, ``int32`` or ``int64``.
        shape(list|tuple|Variable): Define the target shape. At most one dimension of the target shape can be -1.
                        The data type is ``int32`` . If ``shape`` is a list or tuple, the elements of it should be integers or Tensors with shape [1].
                        If ``shape`` is an Variable, it should be an 1-D Tensor .
        actual_shape(variable, optional): An 1-D ``Tensor`` or ``LoDTensor`` . The data type is ``int32`` . If provided, reshape
                                according to this given shape rather than ``shape`` specifying shape.
                                That is to say ``actual_shape`` has a higher priority
                                than ``shape(list|tuple)`` but not ``shape(Variable)``. \
                                This argument ``actual_shape`` will be removed in a future version. \
                                Instructions for updating: ``actual_shape`` will be removed in future versions and replaced by ``shape``.
        act (str, optional): The non-linear activation to be applied to the reshaped input. Default None.
        inplace(bool, optional): If ``inplace`` is True, the input and output of ``layers.reshape``
                       are the same variable. Otherwise, the input and output of
                       ``layers.reshape`` are different variable. Default False. Note that if ``x``
                       is more than one OPs' input, ``inplace`` must be False.
        name(str, optional): The default value is None. Normally there is no need for user to set this property.
                            For more information, please refer to :ref:`api_guide_Name` .
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5531
    Returns:
5532
        Variable: A ``Tensor`` or ``LoDTensor``. The data type is same as ``x``. It is a new tensor variable if ``inplace`` is ``False``, otherwise it is ``x``. If ``act`` is None, return the reshaped tensor variable, otherwise return the activated tensor variable.
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    Raises:
5535 5536 5537 5538
        TypeError: If actual_shape is neither Variable nor None.
        ValueError: If more than one elements of ``shape`` is -1.
        ValueError: If the element of ``shape`` is 0, the corresponding dimension should be less than or equal to the dimension of ``x``.
        ValueError: If the elements in ``shape`` is negative except -1.
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    Examples:
        .. code-block:: python
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5543
            import paddle.fluid as fluid
5544 5545 5546

            # example 1:
            # attr shape is a list which doesn't contain tensor Variable.
5547 5548
            data_1 = fluid.data(
              name='data_1', shape=[2, 4, 6], dtype='float32')
5549
            reshaped_1 = fluid.layers.reshape(
5550 5551
              x=data_1, shape=[-1, 0, 3, 2], inplace=True)
            # the shape of reshaped_1 is [2,4,3,2].
5552 5553 5554 5555 5556 5557

            # example 2:
            # attr shape is a list which contains tensor Variable.
            data_2 = fluid.layers.fill_constant([2,25], "int32", 3)
            dim = fluid.layers.fill_constant([1], "int32", 5)
            reshaped_2 = fluid.layers.reshape(data_2, shape=[dim, 10])
5558
            # the shape of reshaped_2 is [5,10].
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    """
5560 5561 5562 5563 5564 5565 5566 5567 5568 5569 5570 5571 5572 5573 5574 5575 5576 5577 5578 5579 5580 5581
    if in_dygraph_mode():
        #TODO(zhiqiu): open inplace if we can.
        if inplace:
            warnings.warn(
                "Inplace on reshape is not allowed and will be discarded in dygraph mode currently."
            )
        attrs = {}
        if isinstance(shape, (list, tuple)):
            contain_var = not all(not isinstance(ele, Variable)
                                  for ele in shape)
            if contain_var:
                raise TypeError(
                    "The type of 'shape' in reshape must be list[int] or tuple(int) in Dygraph mode, but "
                    "received %s, which contains Variable." % type(shape))
            attrs['shape'] = shape
        else:
            raise TypeError(
                "The type of 'shape' in reshape must be list[int] or tuple(int) in Dygraph mode, but "
                "received %s." % type(shape))

        inputs = {'X': [x]}
        outs = core.ops.reshape2(inputs, attrs)
5582 5583
        out = outs['Out'][0]
        return dygraph_utils._append_activation_in_dygraph(out, act)
5584

5585 5586 5587 5588 5589
    check_type_and_dtype(x, 'x', Variable,
                         ['float16', 'float32', 'float64', 'int32', 'int64'],
                         'reshape')
    check_type(shape, 'shape', (list, tuple, Variable), 'reshape')
    check_type(actual_shape, 'actual_shape', (Variable, type(None)), 'reshape')
5590

5591
    helper = LayerHelper("reshape2", **locals())
5592 5593 5594 5595 5596 5597 5598 5599 5600 5601 5602 5603 5604 5605 5606 5607 5608 5609 5610 5611 5612 5613 5614 5615 5616 5617 5618 5619 5620 5621

    def contain_var(one_list):
        for ele in one_list:
            if isinstance(ele, Variable):
                return True
        return False

    def get_new_shape_tensor(list_shape):
        new_shape_tensor = []
        for dim in list_shape:
            if isinstance(dim, Variable):
                dim.stop_gradient = True
                new_shape_tensor.append(dim)
            else:
                assert (isinstance(dim, int))
                temp_out = helper.create_variable_for_type_inference('int32')
                fill_constant([1], 'int32', dim, force_cpu=True, out=temp_out)
                new_shape_tensor.append(temp_out)
        return new_shape_tensor

    def get_attr_shape(list_shape):
        unk_dim_idx = -1
        attrs_shape = []
        for dim_idx, dim_size in enumerate(list_shape):
            if isinstance(dim_size, Variable):
                attrs_shape.append(-1)
            else:
                attrs_shape.append(dim_size)
                if dim_size == -1:
                    assert unk_dim_idx == -1, (
5622 5623
                        "Only one dimension value of 'shape' in reshape can "
                        "be -1. But received shape[%d] is also -1." % dim_idx)
5624 5625 5626
                    unk_dim_idx = dim_idx
                elif dim_size == 0:
                    assert dim_idx < len(x.shape), (
5627 5628 5629 5630
                        "The index of 0 in `shape` must be less than "
                        "the input tensor X's dimensions. "
                        "But received shape[%d] = 0, X's dimensions = %d." %
                        (dim_idx, len(x.shape)))
5631 5632
                else:
                    assert dim_size > 0, (
5633 5634 5635 5636
                        "Each dimension value of 'shape' in reshape must not "
                        "be negtive except one unknown dimension. "
                        "But received shape[%d] = %s." %
                        (dim_idx, str(dim_size)))
5637 5638
        return attrs_shape

5639 5640 5641 5642 5643 5644 5645 5646 5647 5648 5649 5650 5651 5652 5653 5654 5655
    inputs = {"X": x}
    attrs = {}
    if isinstance(shape, Variable):
        shape.stop_gradient = True
        inputs["Shape"] = shape
    elif isinstance(shape, (list, tuple)):
        assert len(shape) > 0, ("The size of 'shape' in reshape can't be zero, "
                                "but received %s." % len(shape))
        attrs["shape"] = get_attr_shape(shape)
        if contain_var(shape):
            inputs['ShapeTensor'] = get_new_shape_tensor(shape)
        elif isinstance(actual_shape, Variable):
            actual_shape.stop_gradient = True
            inputs["Shape"] = actual_shape

    out = x if inplace else helper.create_variable_for_type_inference(
        dtype=x.dtype)
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    x_shape = helper.create_variable_for_type_inference(dtype=x.dtype)
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5657
    helper.append_op(
5658
        type="reshape2",
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        inputs=inputs,
5660
        attrs=attrs,
5661 5662
        outputs={"Out": out,
                 "XShape": x_shape})
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    return helper.append_activation(out)
5665

5666

5667
def squeeze(input, axes, name=None):
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    """
5669 5670 5671
    This OP will squeeze single-dimensional entries of input tensor's shape. If axes is provided, will
    remove the dims by axes, the dims selected by axes should be one. If not provide axes, all dims equal
    to one will be deleted.
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5673

5674
    .. code-block:: text 
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5675

5676
        Case1:
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5677

5678
          Input:
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5679 5680
            X.shape = (1, 3, 1, 5)
            axes = [0]
5681
          Output:
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5682 5683
            Out.shape = (3, 1, 5)

5684
        Case2:
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5685

5686
          Input:
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5687 5688
            X.shape = (1, 3, 1, 5)
            axes = []
5689
          Output:
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5690
            Out.shape = (3, 5)
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5692 5693 5694 5695 5696 5697 5698 5699
        Case3:

          Input:
            X.shape = [1,3,1,5]
            axes = [-2]
          Output:
            Out.shape = [1,3,5]

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    Args:
5701 5702 5703 5704 5705
        input (Variable): The input Tensor. Support data type: float32, float64, int8, int32, int64.
                          axes (list): One integer or List of integers, indicating the dimensions to be squeezed.
                          Axes range is :math:`[-rank(input), rank(input))`.
                          If axes is negative, :math:`axes=axes+rank(input)`.
        name (str, optional): Please refer to :ref:`api_guide_Name`, Default None.
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5706 5707

    Returns:
5708
        Variable: Output squeezed Tensor. Data type is same as input Tensor.
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    Examples:
        .. code-block:: python

5713
            import paddle.fluid as fluid
5714
            import paddle.fluid.layers as layers
5715 5716 5717 5718
            # set batch size=None
            x = fluid.data(name='x', shape=[None, 5, 1, 10])
            y = layers.squeeze(input=x, axes=[2]) # y.shape=[None, 5, 10]

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5719 5720
    """
    helper = LayerHelper("squeeze", **locals())
5721 5722 5723 5724
    check_type_and_dtype(input, 'input', Variable,
                         ['float32', 'float64', 'int8', 'int32', 'int64'],
                         'squeeze')
    check_type(axes, 'axes', list, 'squeeze')
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5725 5726
    out = helper.create_variable_for_type_inference(dtype=input.dtype)
    x_shape = helper.create_variable_for_type_inference(dtype=input.dtype)
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5727
    helper.append_op(
5728
        type="squeeze2",
5729
        inputs={"X": input},
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5730
        attrs={"axes": axes},
5731 5732
        outputs={"Out": out,
                 "XShape": x_shape})
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5733

5734 5735 5736
    return out


5737
def unsqueeze(input, axes, name=None):
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5738
    """
5739
    Insert single-dimensional entries to the shape of a Tensor. Takes one
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5740 5741
    required argument axes, a list of dimensions that will be inserted.
    Dimension indices in axes are as seen in the output tensor.
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5743
    For example:
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5744 5745 5746

    .. code-block:: text

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5747
      Given a tensor such that tensor with shape [3, 4, 5],
Y
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5748
      then Unsqueezed tensor with axes=[0, 4] has shape [1, 3, 4, 5, 1].
M
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5749

Y
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5750
    Args:
5751
        input (Variable): The input Tensor to be unsqueezed. It is a N-D Tensor of data types float32, float64, int32.
5752
        axes (int|list|tuple|Variable): Indicates the dimensions to be inserted. The data type is ``int32`` . If ``axes`` is a list or tuple, the elements of it should be integers or Tensors with shape [1]. If ``axes`` is an Variable, it should be an 1-D Tensor .
5753
        name (str|None): Name for this layer.
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5754 5755

    Returns:
5756
        Variable: Output unsqueezed Tensor, with data type being float32, float64, int32, int64.
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5757 5758 5759 5760

    Examples:
        .. code-block:: python

5761 5762 5763
            import paddle.fluid as fluid
            x = fluid.layers.data(name='x', shape=[5, 10])
            y = fluid.layers.unsqueeze(input=x, axes=[1])
5764

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5765
    """
5766 5767 5768 5769 5770 5771 5772 5773 5774 5775 5776 5777 5778 5779 5780 5781 5782 5783 5784 5785 5786 5787 5788 5789 5790 5791 5792 5793 5794 5795 5796 5797 5798
    if not isinstance(axes, (int, list, tuple, Variable)):
        raise TypeError(
            "The type of 'axes' in unsqueeze must be int, list, tuple or Variable, but "
            "received %s." % (type(axes)))
    helper = LayerHelper("unsqueeze2", **locals())
    inputs = {"X": input}
    attrs = {}

    def _to_Variable_list(one_list):
        Variable_list = []
        for ele in one_list:
            if isinstance(ele, Variable):
                ele.stop_gradient = True
                Variable_list.append(ele)
            else:
                assert (isinstance(ele, int))
                temp_out = helper.create_variable_for_type_inference('int32')
                fill_constant([1], 'int32', ele, force_cpu=True, out=temp_out)
                Variable_list.append(temp_out)
        return Variable_list

    if isinstance(axes, int):
        axes = [axes]
    if isinstance(axes, Variable):
        axes.stop_gradient = True
        inputs["AxesTensor"] = axes
    elif isinstance(axes, (list, tuple)):
        contain_var = not all(not isinstance(ele, Variable) for ele in axes)
        if contain_var:
            inputs["AxesTensorList"] = _to_Variable_list(axes)
        else:
            attrs["axes"] = axes

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    out = helper.create_variable_for_type_inference(dtype=input.dtype)
    x_shape = helper.create_variable_for_type_inference(dtype=input.dtype)
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5801
    helper.append_op(
5802
        type="unsqueeze2",
5803 5804
        inputs=inputs,
        attrs=attrs,
5805 5806
        outputs={"Out": out,
                 "XShape": x_shape})
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5807

5808 5809
    return out

5810

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5811
def lod_reset(x, y=None, target_lod=None):
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5812
    """
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5813
    Set LoD of :attr:`x` to a new one specified by :attr:`y` or
5814 5815 5816 5817
    :attr:`target_lod`. When :attr:`y` provided, :attr:`y.lod` would be
    considered as target LoD first, otherwise :attr:`y.data` would be
    considered as target LoD. If :attr:`y` is not provided, target LoD should
    be specified by :attr:`target_lod`. If target LoD is specified by
5818
    :attr:`y.data` or :attr:`target_lod`, only one level LoD is supported.
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5819 5820 5821 5822 5823 5824

    .. code-block:: text

        * Example 1:

            Given a 1-level LoDTensor x:
5825
                x.lod =  [[ 2,           3,                   1 ]]
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5826 5827 5828
                x.data = [[1.0], [2.0], [3.0], [4.0], [5.0], [6.0]]
                x.dims = [6, 1]

5829
            target_lod: [4, 2]
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5830 5831

            then we get a 1-level LoDTensor:
5832
                out.lod =  [[4,                          2]]
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5833 5834 5835 5836 5837 5838
                out.data = [[1.0], [2.0], [3.0], [4.0], [5.0], [6.0]]
                out.dims = [6, 1]

        * Example 2:

            Given a 1-level LoDTensor x:
5839
                x.lod =  [[2,            3,                   1]]
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5840 5841 5842 5843
                x.data = [[1.0], [2.0], [3.0], [4.0], [5.0], [6.0]]
                x.dims = [6, 1]

            y is a Tensor:
5844
                y.data = [[2, 4]]
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5845 5846 5847
                y.dims = [1, 3]

            then we get a 1-level LoDTensor:
5848
                out.lod =  [[2,            4]]
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5849 5850 5851 5852 5853 5854
                out.data = [[1.0], [2.0], [3.0], [4.0], [5.0], [6.0]]
                out.dims = [6, 1]

        * Example 3:

            Given a 1-level LoDTensor x:
5855
                x.lod =  [[2,            3,                   1]]
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5856 5857 5858 5859
                x.data = [[1.0], [2.0], [3.0], [4.0], [5.0], [6.0]]
                x.dims = [6, 1]

            y is a 2-level LoDTensor:
5860
                y.lod =  [[2, 2], [2, 2, 1, 1]]
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5861 5862 5863 5864
                y.data = [[1.1], [2.1], [3.1], [4.1], [5.1], [6.1]]
                y.dims = [6, 1]

            then we get a 2-level LoDTensor:
5865
                out.lod =  [[2, 2], [2, 2, 1, 1]]
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5866 5867 5868 5869
                out.data = [[1.0], [2.0], [3.0], [4.0], [5.0], [6.0]]
                out.dims = [6, 1]

    Args:
5870
        x (Variable): Input variable which could be a Tensor or LoDTensor.
5871
        y (Variable|None): If provided, output's LoD would be derived
Y
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5872
                           from :attr:`y`.
Y
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5873
        target_lod (list|tuple|None): One level LoD which should be considered
Y
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5874
                                      as target LoD when :attr:`y` not provided.
Y
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5875 5876

    Returns:
Y
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5877
        Variable: Output variable with LoD specified by this layer.
Y
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5878 5879

    Raises:
Y
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5880
        ValueError: If :attr:`y` and :attr:`target_lod` are both None.
Y
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5881 5882 5883 5884

    Examples:
        .. code-block:: python

5885
            import paddle.fluid as fluid
5886 5887 5888
            x = fluid.layers.data(name='x', shape=[10])
            y = fluid.layers.data(name='y', shape=[10, 20], lod_level=2)
            out = fluid.layers.lod_reset(x=x, y=y)
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5889 5890
    """
    helper = LayerHelper("lod_reset", **locals())
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5891
    out = helper.create_variable_for_type_inference(dtype=x.dtype)
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5892 5893 5894 5895 5896 5897 5898 5899 5900 5901 5902
    if y is not None:
        helper.append_op(
            type="lod_reset", inputs={'X': x,
                                      'Y': y}, outputs={'Out': out})
    elif target_lod is not None:
        helper.append_op(
            type="lod_reset",
            inputs={'X': x},
            attrs={'target_lod': target_lod},
            outputs={'Out': out})
    else:
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        raise ValueError("y and target_lod should not be both none.")
    return out


def lod_append(x, level):
    """
    Append level to LoD of :attr:`x`.

    .. code-block:: text

        * Example 1:

            given a 1-level LoDTensor x:
                x.lod =  [[ 2,           3,                   1 ]]
                x.data = [[1.0], [2.0], [3.0], [4.0], [5.0], [6.0]]
                x.dims = [6, 1]

            level: [1, 1, 1, 1, 1, 1, 1]

            then we get a 2-level LoDTensor:
                x.lod =  [[ 2, 3, 1 ], [1, 1, 1, 1, 1, 1]]
                x.data = [[1.0], [2.0], [3.0], [4.0], [5.0], [6.0]]
                x.dims = [6, 1]

    Args:
        x (Variable): Input variable which could be a tensor or LoDTensor.
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        level (list|tuple|Variable): The LoD level to be appended into LoD of x.
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    Returns:
        Variable: Output variable with new LoD level.

    Raises:
        ValueError: If :attr:`y` is None or and :attr:`level` is not Iterator.
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    Examples:
        .. code-block:: python

            import paddle.fluid as fluid
            x = fluid.layers.data(name='x', shape=[6, 10], lod_level=1)
            out = fluid.layers.lod_append(x, [1,1,1,1,1,1])
    """
    from collections import Iterable
    if x is None:
        raise ValueError("Input(x) can't be None.")
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    if (not isinstance(level, Iterable)) and (not isinstance(level, Variable)):
        raise ValueError("Input(level) must be list, tuple or Variable.")

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    helper = LayerHelper("lod_append", **locals())
    out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    inputs = {'X': x}
    attrs = {'append': True}

    if isinstance(level, Variable):
        inputs['Y'] = level
    else:
        attrs['target_lod'] = level
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    helper.append_op(
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        type="lod_reset", inputs=inputs, attrs=attrs, outputs={'Out': out})
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    return out
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def lrn(input, n=5, k=1.0, alpha=1e-4, beta=0.75, name=None,
        data_format='NCHW'):
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    """
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    This operator implements the Local Response Normalization Layer.
    This layer performs a type of "lateral inhibition" by normalizing over local input regions.
    For more information, please refer to `ImageNet Classification with Deep Convolutional Neural Networks <https://papers.nips.cc/paper/4824-imagenet-classification-with-deep-convolutional-neural-networks.pdf>`_
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    The formula is as follows:

    .. math::

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        Output(i, x, y) = Input(i, x, y) / \\left(k + \\alpha \\sum\\limits^{\\min(C-1, i + n/2)}_{j = \\max(0, i - n/2)}(Input(j, x, y))^2\\right)^{\\beta}
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    In the above equation:

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    - :math:`n` : The number of channels to sum over.
    - :math:`k` : The offset (avoid being divided by 0).
    - :math:`\\alpha` : The scaling parameter.
    - :math:`\\beta` : The exponent parameter.
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    Args:
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        input (Variable): Input feature, 4D-Tensor with the shape of [N,C,H,W] or [N, H, W, C], 
            where N is the batch size, C is the input channel, H is Height, W is weight. The data 
            type is float32. The rank of this tensor must be 4, otherwise it will raise ValueError.
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        n (int, optional): The number of channels to sum over. Default: 5
        k (float, optional): An offset, positive. Default: 1.0
        alpha (float, optional): The scaling parameter, positive. Default:1e-4
        beta (float, optional): The exponent, positive. Default:0.75
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        name (str, optional): The default value is None. Normally there is no need for user to set 
            this property. For more information, please refer to :ref:`api_guide_Name` 
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        data_format (str, optional): Specify the data format of the input, and the data format of the output 
            will be consistent with that of the input. An optional string from: `"NCHW"`, `"NHWC"`.
            The default is `"NCHW"`. When it is `"NCHW"`, the data is stored in the order of:
            `[batch_size, input_channels, input_height, input_width]`.
        
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    Returns:
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        Variable: A tensor variable storing the transformation result with the same shape and data type as input.

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    Examples:

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    .. code-block:: python

        import paddle.fluid as fluid
        data = fluid.data(
            name="data", shape=[None, 3, 112, 112], dtype="float32")
        lrn = fluid.layers.lrn(input=data)
        print(lrn.shape)  # [-1, 3, 112, 112]
        print(lrn.dtype)  # float32
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    """
    helper = LayerHelper('lrn', **locals())
    dtype = helper.input_dtype()
    input_shape = input.shape
    dims = len(input_shape)

    if dims != 4:
        raise ValueError(
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            "Input's dimension size of Op(lrn) must be 4, but received %d." %
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            (dims))
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    if data_format not in ['NCHW', 'NHWC']:
        raise ValueError(
            "Attr(data_format) of Op(lrn) got wrong value: received " +
            data_format + " but only NCHW or NHWC supported.")
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    mid_out = helper.create_variable_for_type_inference(
        dtype=dtype, stop_gradient=True)
    lrn_out = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
        type="lrn",
        inputs={"X": input},
        outputs={
            "Out": lrn_out,
            "MidOut": mid_out,
        },
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        attrs={
            "n": n,
            "k": k,
            "alpha": alpha,
            "beta": beta,
            "data_format": data_format
        })
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    return lrn_out
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def pad(x, paddings, pad_value=0., name=None):
    """
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    This op will pad a tensor with a constant value given by :attr:`pad_value`, and the
    padded shape is specified by :attr:`paddings`.
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    Specifically, the number of values padded before the elements of :attr:`x`
    in dimension :attr:`i` is indicated by :attr:`paddings[2*i]`, and the number
    of values padded after the elements of :attr:`x` in dimension :attr:`i` is
    indicated by :attr:`paddings[2*i+1]`.
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    See below for an example.

    .. code-block:: text

        Given:
            x = [[1, 2], [3, 4]]

            paddings = [0, 1, 1, 2]

            pad_value = 0

        Return:

            out = [[0, 1, 2, 0, 0]
                   [0, 3, 4, 0, 0]
                   [0, 0, 0, 0, 0]]

    Args:
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        x (Variable): Tensor, data type is float32.
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        paddings (list): A list of integers. Its elements specify the padded
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                         width before and after each dimension in turn.
                         The length of :attr:`paddings` must be equal to 
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                         :math:`rank(x) \\times 2`.
        pad_value (float): The constant value used to pad.
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        name(str, optional): The default value is None.  
                             Normally there is no need for user to set this property.  
                             For more information, please refer to :ref:`api_guide_Name`
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    Returns:
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        The padded tensor, with the same data type and rank as :attr:`x`

    Return Type:
        Variable
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    Examples:
        .. code-block:: python
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            # x is a rank 2 tensor variable with shape [100, 224].
            # out will be a tensor of shape [101, 227] 
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            import paddle.fluid as fluid
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            x = fluid.data(name='data', shape=[100, 224], dtype='float32')
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            out = fluid.layers.pad(
                x=x, paddings=[0, 1, 1, 2], pad_value=0.)
    """
    helper = LayerHelper('pad', input=x, **locals())
    dtype = helper.input_dtype()
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    out = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
        type='pad',
        inputs={'X': x},
        outputs={'Out': out},
        attrs={'paddings': paddings,
               'pad_value': float(pad_value)})
    return out
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def pad_constant_like(x, y, pad_value=0., name=None):
    """
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    Pad :attr:`y` with :attr:`pad_value`, the number of values padded to
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    the edges of each axis is specified by the difference of the shape
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    of :attr:`x` and :attr:`y` . ((0, shape_x_0 - shape_y_0), ... (0, shape_x_n - shape_y_n))
    specify padding widths for each axis. The input should be a k-D tensor(k > 0 and k < 7).
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    See below for an example.

    .. code-block:: text

        Given:
            X = [[[[ 0,  1,  2],
                   [ 3,  4,  5]],
                  [[ 6,  7,  8],
                   [ 9, 10, 11]],
                  [[12, 13, 14],
                   [15, 16, 17]]],
                 [[[18, 19, 20],
                   [21, 22, 23]],
                  [[24, 25, 26],
                   [27, 28, 29]],
                  [[30, 31, 32],
                   [33, 34, 35]]]]
            X.shape = (2, 3, 2, 3)

            Y = [[[[35, 36, 37]],
                  [[38, 39, 40]],
                  [[41, 42, 43]]]]
            Y.shape = (1, 3, 1, 3)
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		And
            pad_value = -1,
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        Return:
            Out = [[[[35, 36, 37],
                     [-1, -1, -1]],
                    [[38, 39, 40],
                     [-1, -1, -1]],
                    [[41, 42, 43],
                     [-1, -1, -1]]],
                  [[[-1, -1, -1],
                    [-1, -1, -1]],
                   [[-1, -1, -1],
                    [-1, -1, -1]],
                   [[-1, -1, -1],
                    [-1, -1, -1]]]]
            Out.shape = (2, 3, 2, 3)
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    Args:
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        x (Variable): Tensor, its shape spicifies the shape of output.
        y (Variable): Tensor, its rank is the same with :attr:`x`, and for each dimension :math:`i` , 
                      :math:`y\_shape[i] <= x\_shape[i]` . The data type can be float32 or float64.
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        pad_value (float): The constant value used to pad.
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        name(str, optional): The default value is None.  
                             Normally there is no need for user to set this property.  
                             For more information, please refer to :ref:`api_guide_Name`
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    Returns:
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        The padded tensor, with the same shape as :attr:`x` and the same data type as :attr:`y`

    Return Type:
        Variable
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    Examples:
        .. code-block:: python

            # x is a rank 4 tensor variable, x.shape = (2, 3, 2, 3)
            # y is a rank 4 tensor variable, y.shape = (1, 3, 1, 3)
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            import paddle.fluid as fluid
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            x = fluid.data(name='x', shape=[2,3,2,3], dtype='float32')
            y = fluid.data(name='y', shape=[1,3,1,3], dtype='float32')
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            out = fluid.layers.pad_constant_like(x=x, y=y, pad_value=0.)
            # out is a rank 4 tensor variable, and out.shape = [2, 3 ,2 , 3]
    """
    helper = LayerHelper('pad_constant_like', input=x, **locals())
    dtype = helper.input_dtype()
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    out = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
        type='pad_constant_like',
        inputs={'X': x,
                'Y': y},
        outputs={'Out': out},
        attrs={'pad_value': float(pad_value)})
    return out


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def label_smooth(label,
                 prior_dist=None,
                 epsilon=0.1,
                 dtype="float32",
                 name=None):
    """
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    Label smoothing is a mechanism to regularize the classifier layer and is called 
    label-smoothing regularization (LSR). 
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    Label smoothing is proposed to encourage the model to be less confident,
    since optimizing the log-likelihood of the correct label directly may
    cause overfitting and reduce the ability of the model to adapt. Label
    smoothing replaces the ground-truth label :math:`y` with the weighted sum
    of itself and some fixed distribution :math:`\mu`. For class :math:`k`,
    i.e.

    .. math::

        \\tilde{y_k} = (1 - \epsilon) * y_k + \epsilon * \mu_k,

    where :math:`1 - \epsilon` and :math:`\epsilon` are the weights
    respectively, and :math:`\\tilde{y}_k` is the smoothed label. Usually
    uniform distribution is used for :math:`\mu`.

    See more details about label smoothing in https://arxiv.org/abs/1512.00567.

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    Parameters:
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        label(Variable): The input variable containing the label data. The
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                        label data should use one-hot representation. It's 
                        a multidimensional tensor with a shape of 
                        :math:`[N_1, ..., Depth]`, where Depth is class number.
        prior_dist(Variable, optional): The prior distribution to be used to smooth
                        labels. If not provided, an uniform distribution
                        is used. It's a multidimensional tensor with a shape of
                        :math:`[1, class\_num]` . The default value is None.
        epsilon(float, optional): The weight used to mix up the original ground-truth
                        distribution and the fixed distribution. The default value is 
                        0.1.
        dtype(np.dtype|core.VarDesc.VarType|str, optional): The data type can be set
                        as 'float32', 'float64'. The default value is 'float32'.
        name(str, optional): The default value is None. Normally there is no need for user 
                        to set this property. For more information, please refer to 
                        :ref:`api_guide_Name`.
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    Returns:
        Variable: The tensor variable containing the smoothed labels.

    Examples:
        .. code-block:: python
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6253
            import paddle.fluid as fluid
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            import paddle.fluid.layers as layers
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            label = layers.data(name="label", shape=[1], dtype="float32")
            one_hot_label = layers.one_hot(input=label, depth=10)
            smooth_label = layers.label_smooth(
                label=one_hot_label, epsilon=0.1, dtype="float32")
    """
    if epsilon > 1. or epsilon < 0.:
        raise ValueError("The value of epsilon must be between 0 and 1.")
    helper = LayerHelper("label_smooth", **locals())
    label.stop_gradient = True
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    smooth_label = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
        type="label_smooth",
        inputs={"X": label,
                "PriorDist": prior_dist} if prior_dist else {"X": label},
        outputs={"Out": smooth_label},
        attrs={"epsilon": float(epsilon)})
    return smooth_label
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@templatedoc()
def roi_pool(input, rois, pooled_height=1, pooled_width=1, spatial_scale=1.0):
    """
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    This operator implements the roi_pooling layer. 
    Region of interest pooling (also known as RoI pooling) is to perform max pooling on inputs of nonuniform sizes to obtain fixed-size feature maps (e.g. 7*7).
    
    The operator has three steps:
    
        1. Dividing each region proposal into equal-sized sections with the pooled_width and pooled_height;
        2. Finding the largest value in each section;
        3. Copying these max values to the output buffer.
    
    For more information, please refer to https://stackoverflow.com/questions/43430056/what-is-roi-layer-in-fast-rcnn
    
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    Args:
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        input (Variable): Input feature, 4D-Tensor with the shape of [N,C,H,W], where N is the batch size, C is the input channel, H is Height, W is weight. The data type is float32 or float64.
        rois (Variable): ROIs (Regions of Interest) to pool over. 2D-LoDTensor with the shape of [num_rois,4], the lod level is 1. Given as [[x1, y1, x2, y2], ...], (x1, y1) is the top left coordinates, and (x2, y2) is the bottom right coordinates.
        pooled_height (int, optional): The pooled output height, data type is int32. Default: 1
        pooled_width (int, optional): The pooled output height, data type is int32. Default: 1
        spatial_scale (float, optional): Multiplicative spatial scale factor to translate ROI coords from their input scale to the scale used when pooling. Default: 1.0
    
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    Returns:
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        Variable: The pooled feature, 4D-Tensor with the shape of [num_rois, C, pooled_height, pooled_width].
    
    
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    Examples:
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    ..  code-block:: python
    
        import paddle.fluid as fluid
        import numpy as np
    
        DATATYPE='float32'
    
        place = fluid.CPUPlace()
        #place = fluid.CUDAPlace(0)
    
        input_data = np.array([i for i in range(1,17)]).reshape(1,1,4,4).astype(DATATYPE)
        roi_data =fluid.create_lod_tensor(np.array([[1., 1., 2., 2.], [1.5, 1.5, 3., 3.]]).astype(DATATYPE),[[2]], place)
    
        x = fluid.data(name='input', shape=[None,1,4,4], dtype=DATATYPE)
        rois = fluid.data(name='roi', shape=[None,4], dtype=DATATYPE)
    
        pool_out = fluid.layers.roi_pool(
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                input=x,
                rois=rois,
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                pooled_height=1,
                pooled_width=1,
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                spatial_scale=1.0)
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        exe = fluid.Executor(place)
        out, = exe.run(feed={'input':input_data ,'roi':roi_data}, fetch_list=[pool_out.name])
        print(out)   #array([[[[11.]]], [[[16.]]]], dtype=float32)
        print(np.array(out).shape)  # (2, 1, 1, 1)
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    """
    helper = LayerHelper('roi_pool', **locals())
    dtype = helper.input_dtype()
    pool_out = helper.create_variable_for_type_inference(dtype)
    argmaxes = helper.create_variable_for_type_inference(dtype='int32')
    helper.append_op(
        type="roi_pool",
        inputs={"X": input,
                "ROIs": rois},
        outputs={"Out": pool_out,
                 "Argmax": argmaxes},
        attrs={
            "pooled_height": pooled_height,
            "pooled_width": pooled_width,
            "spatial_scale": spatial_scale
        })
    return pool_out
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@templatedoc()
def roi_align(input,
              rois,
              pooled_height=1,
              pooled_width=1,
              spatial_scale=1.0,
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              sampling_ratio=-1,
              name=None):
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    """
    ${comment}

    Args:
        input (Variable): ${x_comment}
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        rois (Variable): ROIs (Regions of Interest) to pool over.It should be
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            a 2-D LoDTensor of shape (num_rois, 4), the lod level is 1. The 
            data type is float32 or float64. Given as [[x1, y1, x2, y2], ...], 
            (x1, y1) is the top left coordinates, and (x2, y2) is the bottom
            right coordinates. 
        pooled_height (int32, optional): ${pooled_height_comment} Default: 1
        pooled_width (int32, optional): ${pooled_width_comment} Default: 1
        spatial_scale (float32, optional): ${spatial_scale_comment} Default: 1.0
        sampling_ratio(int32, optional): ${sampling_ratio_comment} Default: -1
        name(str, optional): For detailed information, please refer 
            to :ref:`api_guide_Name`. Usually name is no need to set and 
            None by default. 
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    Returns:
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        Variable:

        Output: ${out_comment}.


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    Examples:
        .. code-block:: python

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            import paddle.fluid as fluid
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            x = fluid.data(
                name='data', shape=[None, 256, 32, 32], dtype='float32')
            rois = fluid.data(
                name='rois', shape=[None, 4], dtype='float32')
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            align_out = fluid.layers.roi_align(input=x,
                                               rois=rois,
                                               pooled_height=7,
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                                               pooled_width=7,
                                               spatial_scale=0.5,
                                               sampling_ratio=-1)
    """
    helper = LayerHelper('roi_align', **locals())
    dtype = helper.input_dtype()
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    align_out = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
        type="roi_align",
        inputs={"X": input,
                "ROIs": rois},
        outputs={"Out": align_out},
        attrs={
            "pooled_height": pooled_height,
            "pooled_width": pooled_width,
            "spatial_scale": spatial_scale,
            "sampling_ratio": sampling_ratio
        })
    return align_out


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def dice_loss(input, label, epsilon=0.00001, name=None):
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    """
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    Dice loss for comparing the similarity between the input predictions and the label.
    This implementation is for binary classification, where the input is sigmoid
    predictions of each pixel, usually used for segmentation task. The dice loss can
    be defined as the following equation:
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    .. math::

        dice\_loss &= 1 - \\frac{2 * intersection\_area}{total\_area} \\\\
                  &= \\frac{(total\_area - intersection\_area) - intersection\_area}{total\_area} \\\\
                  &= \\frac{(union\_area - intersection\_area)}{total\_area}


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    Parameters:
        input (Variable): Tensor, rank>=2, shape is :math:`[N_1, N_2, ..., N_D]`, where :math:`N_1` is
                          the batch_size, :math:`N_D` is 1. It is usually the output predictions of sigmoid activation.
                          The data type can be float32 or float64.
        label (Variable): Tensor, the groud truth with the same rank as input, shape is :math:`[N_1, N_2, ..., N_D]`. 
                          where :math:`N_1` is the batch_size, :math:`N_D` is 1. The data type can be float32 or float64.
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        epsilon (float): The epsilon will be added to the numerator and denominator.
                         If both input and label are empty, it makes sure dice is 1.
                         Default: 0.00001
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        name(str, optional): The default value is None.  
                             Normally there is no need for user to set this property.  
                             For more information, please refer to :ref:`api_guide_Name`
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    Returns:
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        The dice loss with shape [1], data type is the same as `input` .
    Return Type:
        Varaible
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    Example:
6445 6446
        .. code-block:: python

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            import paddle.fluid as fluid
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            x = fluid.data(name='data', shape = [3, 224, 224, 1], dtype='float32')
            label = fluid.data(name='label', shape=[3, 224, 224, 1], dtype='float32')
            predictions = fluid.layers.sigmoid(x)
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            loss = fluid.layers.dice_loss(input=predictions, label=label)
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    """
    label = one_hot(label, depth=input.shape[-1])
6454
    reduce_dim = list(range(1, len(input.shape)))
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    inse = reduce_sum(input * label, dim=reduce_dim)
    dice_denominator = reduce_sum(
        input, dim=reduce_dim) + reduce_sum(
            label, dim=reduce_dim)
    dice_score = 1 - inse * 2 / (dice_denominator + epsilon)
    return reduce_mean(dice_score)
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6463 6464 6465 6466
def image_resize(input,
                 out_shape=None,
                 scale=None,
                 name=None,
6467
                 resample='BILINEAR',
6468 6469
                 actual_shape=None,
                 align_corners=True,
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                 align_mode=1,
                 data_format='NCHW'):
6472
    """
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    This op resizes a batch of images.
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    The input must be a 4-D Tensor of the shape (num_batches, channels, in_h, in_w) 
    or (num_batches, in_h, in_w, channels), or a 5-D Tensor of the shape 
    (num_batches, channels, in_d, in_h, in_w) or (num_batches, in_d, in_h, in_w, channels), 
    and the resizing only applies on the three dimensions(depth, hight and width).
6479

6480
    **Warning:** the parameter :attr:`actual_shape` will be deprecated in the
6481 6482
    future and only use :attr:`out_shape` instead.

6483
    Supporting resample methods:
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6485
        'BILINEAR' : Bilinear interpolation
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        'TRILINEAR' : Trilinear interpolation

6489
        'NEAREST' : Nearest neighbor interpolation
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    Nearest neighbor interpolation is to perform nearest neighbor interpolation
    in both the 3rd dimention(in height direction) and the 4th dimention(in width 
    direction) on input tensor.
            
    Bilinear interpolation is an extension of linear interpolation for 
    interpolating functions of two variables (e.g. H-direction and 
    W-direction in this op) on a rectilinear 2D grid. The key idea is 
    to perform linear interpolation first in one direction, and then 
    again in the other direction.

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    Trilinear interpolation is an extension of linear interpolation for 
    interpolating functions of three variables (e.g. D-direction, 
    H-direction and W-direction in this op) on a rectilinear 3D grid. 
    The linear interpolation is performed on three directions.

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    Align_corners and align_mode are optinal parameters,the calculation method 
6507 6508 6509 6510
    of interpolation can be selected by them.

    Example:

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    .. code-block:: text
6512

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        For scale:
6514
          
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            if align_corners = True && out_size > 1 :
6516

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              scale_factor = (in_size-1.0)/(out_size-1.0)
            
            else:
              
              scale_factor = float(in_size/out_size)
            
          
        Nearest neighbor interpolation:
          
          if:
              align_corners = False
6528

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              input : (N,C,H_in,W_in)
              output: (N,C,H_out,W_out) where:
6531

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              H_out = floor (H_{in} * scale_{factor})
              W_out = floor (W_{in} * scale_{factor})
6534

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          else:
              align_corners = True
6537

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              input : (N,C,H_in,W_in)
              output: (N,C,H_out,W_out) where:
6540

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              H_out = round(H_{in} * scale_{factor})
              W_out = round(W_{in} * scale_{factor})
6543

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        Bilinear interpolation:

          if:
              align_corners = False , align_mode = 0
              
              input : (N,C,H_in,W_in)
              output: (N,C,H_out,W_out) where:
              
              H_out = (H_{in}+0.5) * scale_{factor} - 0.5
              W_out = (W_{in}+0.5) * scale_{factor} - 0.5
6554

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          else:
           
              input : (N,C,H_in,W_in)
              output: (N,C,H_out,W_out) where:
6559

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              H_out = H_{in} * scale_{factor}
              W_out = W_{in} * scale_{factor}
6562

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        Trilinear interpolation:

          if:
              align_corners = False , align_mode = 0
              
              input : (N,C,D_in,H_in,W_in)
              output: (N,C,D_out,H_out,W_out) where:
              
              D_out = (D_{in}+0.5) * scale_{factor} - 0.5
              H_out = (H_{in}+0.5) * scale_{factor} - 0.5
              W_out = (W_{in}+0.5) * scale_{factor} - 0.5


          else:
           
              input : (N,C,D_in,H_in,W_in)
              output: (N,C,D_out,H_out,W_out) where:

              D_out = D_{in} * scale_{factor}
              H_out = H_{in} * scale_{factor}
              W_out = W_{in} * scale_{factor}
          
6585 6586 6587 6588 6589 6590
    For details of nearest neighbor interpolation, please refer to Wikipedia: 
    https://en.wikipedia.org/wiki/Nearest-neighbor_interpolation.

    For details of bilinear interpolation, please refer to Wikipedia: 
    https://en.wikipedia.org/wiki/Bilinear_interpolation.

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    For details of trilinear interpolation, please refer to Wikipedia: 
    https://en.wikipedia.org/wiki/Trilinear_interpolation.

6594 6595


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    Parameters:
6597 6598
        input (Variable): 4-D or 5-D Tensor, its data type is float32, float64, or uint8,
                          its data format is specified by :attr:`data_format`.
6599
        out_shape(list|tuple|Variable|None): Output shape of image resize
6600 6601 6602 6603
             layer, the shape is (out_h, out_w) when input is a 4-D Tensor and is
             (out_d, out_h, out_w) when input is a 5-D Tensor. Default: None. If 
             a list, each element can be an integer or a Tensor Variable of shape: [1].
             If a Tensor Variable, its dimensions size should be a 1.
6604 6605 6606
        scale(float|Variable|None): The multiplier for the input height or width. At
             least one of :attr:`out_shape` or :attr:`scale` must be set.
             And :attr:`out_shape` has a higher priority than :attr:`scale`.
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             Default: None.
6608 6609
        name(str|None): A name for this layer(optional). If set None, the layer
                        will be named automatically.
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        resample(str): The resample method. It supports 'BILINEAR', 'TRILINEAR'
                       and 'NEAREST' currently. Default: 'BILINEAR'
6612 6613 6614
        actual_shape(Variable): An optional input to specify output shape
                                dynamically. If provided, image resize
                                according to this given shape rather than
6615
                                :attr:`out_shape` and :attr:`scale` specifying
6616 6617
                                shape. That is to say actual_shape has the
                                highest priority. It is recommended to use
6618 6619 6620 6621 6622 6623
                                :attr:`out_shape` if you want to specify output 
                                shape dynamically, because :attr:`actual_shape` 
                                will be deprecated. When using actual_shape to 
                                specify output shape, one of :attr:`out_shape` 
                                and :attr:`scale` should also be set, otherwise 
                                errors would be occured in graph constructing stage.
6624
                                Default: None
6625 6626 6627 6628
        align_corners(bool) :  An optional bool, If True, the centers of the 4 corner pixels of the 
                               input and output tensors are aligned, preserving the values at the 
                               corner pixels.
                               Default: True
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        align_mode(int)  :  An optional for bilinear interpolation. can be \'0\' 
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                            for src_idx = scale*(dst_indx+0.5)-0.5 , can be \'1\' for 
6631
                            src_idx = scale*dst_index.
6632 6633 6634 6635 6636
        data_format (str, optional): Specify the data format of the input, and the data format of the output 
            will be consistent with that of the input. An optional string from: `"NCHW"`, `"NHWC"`, `"NCDHW"`,
            `"NDHWC"`. The default is `"NCHW"`. When it is `"NCHW"`, the data is stored in the order of:
            `[batch_size, input_channels, input_height, input_width]`. When it is `"NCHW"`, the data is stored 
            in the order of: `[batch_size, input_channels, input_depth, input_height, input_width]`.
6637 6638

    Returns:
6639 6640
        A 4-D Tensor of the shape (num_batches, channels, out_h, out_w) or (num_batches, out_h, out_w, channels),
        or 5-D Tensor of the shape (num_batches, channels, out_d, out_h, out_w) or (num_batches, out_d, out_h, out_w, channels).
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6642 6643 6644
    Raises:
        TypeError: out_shape should be a list or tuple or Variable.
        TypeError: actual_shape should either be Variable or None.
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        ValueError: The 'resample' of image_resize can only be 'BILINEAR',
                    'TRILINEAR' or 'NEAREST' currently.
        ValueError: 'BILINEAR' and 'NEAREST' only support 4-D tensor.
        ValueError: 'TRILINEAR' only support 5-D tensor.
6649
        ValueError: One of out_shape and scale must not be None.
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        ValueError: out_shape length should be 2 for input 4-D tensor.
        ValueError: out_shape length should be 3 for input 5-D tensor.
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        ValueError: scale should be greater than zero.
6653 6654
        TypeError: align_corners shoule be a bool value
        ValueError: align_mode can only be '0' or '1'
6655
        ValueError: data_format can only be 'NCHW', 'NHWC', 'NCDHW' or 'NDHWC'.
6656

6657 6658
    Examples:
        .. code-block:: python
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	    #declarative mode
	    import paddle.fluid as fluid
	    import numpy as np
	    input = fluid.data(name="input", shape=[None,3,6,10])

	    #1
	    output = fluid.layers.image_resize(input=input,out_shape=[12,12])

	    #2
	    #x = np.array([2]).astype("int32")
	    #dim1 = fluid.data(name="dim1", shape=[1], dtype="int32")
	    #fluid.layers.assign(input=x, output=dim1)
	    #output = fluid.layers.image_resize(input=input,out_shape=[12,dim1])

	    #3
	    #x = np.array([3,12]).astype("int32")
	    #shape_tensor = fluid.data(name="shape_tensor", shape=[2], dtype="int32")
	    #fluid.layers.assign(input=x, output=shape_tensor)
	    #output = fluid.layers.image_resize(input=input,out_shape=shape_tensor)

	    #4
	    #x = np.array([0.5]).astype("float32")
	    #scale_tensor = fluid.data(name="scale", shape=[1], dtype="float32")
	    #fluid.layers.assign(x,scale_tensor)
	    #output = fluid.layers.image_resize(input=input,scale=scale_tensor)

	    place = fluid.CPUPlace()
	    exe = fluid.Executor(place)
	    exe.run(fluid.default_startup_program())
 
	    input_data = np.random.rand(2,3,6,10).astype("float32")
6691

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	    output_data = exe.run(fluid.default_main_program(),
                feed={"input":input_data},
                fetch_list=[output],
                return_numpy=True)
 
	    print(output_data[0].shape)
6698

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	    #1
	    # (2, 3, 12, 12)
	    #2
	    # (2, 3, 12, 2)
	    #3
	    # (2, 3, 3, 12)
	    #4
	    # (2, 3, 3, 5)
6707

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	    #imperative mode
	    import paddle.fluid.dygraph as dg
6710

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	    with dg.guard(place) as g:
    		input = dg.to_variable(input_data)
    		output = fluid.layers.image_resize(input=input, out_shape=[12,12])
    		print(output.shape)
6715

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		# [2L, 3L, 12L, 12L]
6717

6718
    """
6719 6720
    resample_methods = {
        'BILINEAR': 'bilinear',
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        'TRILINEAR': 'trilinear',
6722 6723
        'NEAREST': 'nearest',
    }
6724 6725
    if resample not in resample_methods:
        raise ValueError(
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            "The 'resample' of image_resize can only be 'BILINEAR', 'TRILINEAR' "
            "or 'NEAREST' currently.")
6728
    resample_type = resample_methods[resample]
6729

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    if resample in ['BILINEAR', 'NEAREST'] and len(input.shape) != 4:
        raise ValueError("'BILINEAR' and 'NEAREST' only support 4-D tensor.")
    if resample == 'TRILINEAR' and len(input.shape) != 5:
        raise ValueError("'TRILINEAR'only support 5-D tensor.")

6735 6736 6737 6738 6739
    if not isinstance(align_corners, bool):
        raise TypeError("Attr align_corners should be a bool value")
    if align_mode != 0 and align_mode != 1:
        raise ValueError("align_mode can only be 0 or 1")

6740
    if out_shape is None and scale is None:
6741
        raise ValueError("One of out_shape and scale must not be None.")
6742
    helper = LayerHelper('{}_interp'.format(resample_type), **locals())
6743
    dtype = helper.input_dtype()
6744

6745 6746 6747 6748 6749 6750 6751 6752 6753
    if len(input.shape) == 4 and data_format not in ['NCHW', 'NHWC']:
        raise ValueError(
            "Got wrong value for param `data_format`: " + data_format +
            " received but only `NCHW` or `NHWC` supported for 4-D input.")
    elif len(input.shape) == 5 and data_format not in ['NCDHW', 'NDHWC']:
        raise ValueError(
            "Got wrong value for param `data_format`: " + data_format +
            " received but only `NCDHW` or `NDHWC` supported for 5-D input.")

6754 6755 6756
    def _is_list_or_turple_(data):
        return (isinstance(data, list) or isinstance(data, tuple))

6757 6758 6759 6760 6761
    if data_format == 'NCHW' or data_format == 'NCDHW':
        data_layout = 'NCHW'
    if data_format == 'NHWC' or data_format == 'NDHWC':
        data_layout = 'NHWC'

6762
    inputs = {"X": input}
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    attrs = {
6764 6765 6766
        "out_d": -1,
        "out_h": -1,
        "out_w": -1,
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        "interp_method": resample_type,
        "align_corners": align_corners,
6769 6770
        "align_mode": align_mode,
        "data_layout": data_layout
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    }

6773
    if out_shape is not None:
6774
        if isinstance(out_shape, Variable):
6775
            out_shape.stop_gradient = True
6776
            inputs['OutSize'] = out_shape
6777 6778
        else:
            if not (_is_list_or_turple_(out_shape)):
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                raise TypeError(
                    "out_shape should be a list or tuple or Variable.")
6781 6782 6783 6784 6785 6786 6787 6788 6789 6790 6791 6792 6793 6794 6795 6796 6797 6798 6799 6800 6801 6802 6803 6804 6805 6806 6807 6808
            # Validate the shape
            contain_var = False
            for dim_idx, dim_size in enumerate(out_shape):
                if isinstance(dim_size, Variable):
                    contain_var = True
                    continue
                assert dim_size > 0, (
                    "Each dimension size given in out_shape must be greater than 0."
                )

            if contain_var:
                new_size_tensor = []
                size_list = []
                for dim in out_shape:
                    if isinstance(dim, Variable):
                        dim.stop_gradient = True
                        new_size_tensor.append(dim)
                        size_list.append(-1)
                    else:
                        assert (isinstance(dim, int))
                        temp_out = helper.create_variable_for_type_inference(
                            'int32')
                        fill_constant(
                            [1], 'int32', dim, force_cpu=True, out=temp_out)
                        new_size_tensor.append(temp_out)
                        size_list.append(dim)
                inputs['SizeTensor'] = new_size_tensor

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            if len(input.shape) == 4:
                if len(out_shape) != 2:
                    raise ValueError("out_shape length should be 2 for "
                                     "input 4-D tensor.")
6813 6814 6815 6816 6817 6818 6819
                if contain_var:
                    attrs['out_h'] = size_list[0]
                    attrs['out_w'] = size_list[1]
                else:
                    out_shape = list(map(int, out_shape))
                    attrs['out_h'] = out_shape[0]
                    attrs['out_w'] = out_shape[1]
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            if len(input.shape) == 5:
                if len(out_shape) != 3:
                    raise ValueError("out_shape length should be 3 for "
                                     "input 5-D tensor.")
6824 6825 6826 6827 6828 6829 6830 6831 6832
                if contain_var:
                    attrs['out_d'] = size_list[0]
                    attrs['out_h'] = size_list[1]
                    attrs['out_w'] = size_list[2]
                else:
                    out_shape = list(map(int, out_shape))
                    attrs['out_d'] = out_shape[0]
                    attrs['out_h'] = out_shape[1]
                    attrs['out_w'] = out_shape[2]
6833

6834
    else:
6835 6836 6837
        if isinstance(scale, Variable):
            scale.stop_gradient = True
            inputs["Scale"] = scale
6838
        elif isinstance(scale, float) or isinstance(scale, int):
6839
            if scale <= 0:
6840
                raise ValueError("Attr(scale) should be greater than zero.")
6841
            attrs['scale'] = float(scale)
6842 6843 6844
        else:
            raise TypeError(
                "Attr(scale)'s type should be float, int or Variable.")
6845

6846
    if isinstance(actual_shape, Variable):
6847 6848 6849 6850 6851
        warnings.warn(
            "actual_shape will be deprecated, it is recommended to use "
            "out_shape instead of actual_shape to specify output shape dynamically."
        )
        actual_shape.stop_gradient = True
6852 6853 6854 6855
        inputs["OutSize"] = actual_shape
    elif actual_shape is not None:
        raise TypeError("actual_shape should either be Variable or None.")

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    out = helper.create_variable_for_type_inference(dtype)
6857
    helper.append_op(
6858
        type='{}_interp'.format(resample_type),
6859
        inputs=inputs,
6860
        outputs={"Out": out},
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        attrs=attrs)
6862
    return out
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@templatedoc(op_type="bilinear_interp")
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def resize_bilinear(input,
                    out_shape=None,
                    scale=None,
                    name=None,
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                    actual_shape=None,
                    align_corners=True,
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                    align_mode=1,
                    data_format='NCHW'):
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    """
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    This op resizes the input by performing bilinear interpolation based on given
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    output shape which specified by actual_shape, out_shape and scale
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    in priority order.

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    **Warning:** the parameter :attr:`actual_shape` will be deprecated in 
    the future and only use :attr:`out_shape` instead.

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    Bilinear interpolation is an extension of linear interpolation for
    interpolating functions of two variables (e.g. H-direction and
    W-direction in this op) on a rectilinear 2D grid. The key idea is
    to perform linear interpolation first in one direction, and then
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    again in the other direction.

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    For details of bilinear interpolation, please refer to Wikipedia:
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    https://en.wikipedia.org/wiki/Bilinear_interpolation
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    Align_corners and align_mode are optinal parameters,the calculation 
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    method of interpolation can be selected by them.

    Example:

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    .. code-block:: text
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        For scale:
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            if align_corners = True && out_size > 1 :
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              scale_factor = (in_size-1.0)/(out_size-1.0)
            
            else:
              
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              scale_factor = float(in_size/out_size)
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        Bilinear interpolation:

          if:
              align_corners = False , align_mode = 0
              
              input : (N,C,H_in,W_in)
              output: (N,C,H_out,W_out) where:
              
              H_out = (H_{in}+0.5) * scale_{factor} - 0.5
              W_out = (W_{in}+0.5) * scale_{factor} - 0.5
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          else:
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              input : (N,C,H_in,W_in)
              output: (N,C,H_out,W_out) where:
              H_out = H_{in} * scale_{factor}
              W_out = W_{in} * scale_{factor}
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    Parameters:
        input(Variable): 4-D Tensor(NCHW), its data type is float32, float64, or uint8,
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                          its data format is specified by :attr:`data_format`.
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        out_shape(list|tuple|Variable|None): Output shape of resize bilinear
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            layer, the shape is (out_h, out_w).Default: None. If a list, each 
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            element can be an integer or a Tensor Variable with shape: [1]. If a 
            Tensor Variable, its dimension size should be 1.
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        scale(float|Variable|None): The multiplier for the input height or width. At
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             least one of :attr:`out_shape` or :attr:`scale` must be set. 
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             And :attr:`out_shape` has a higher priority than :attr:`scale`. 
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             Default: None.
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        actual_shape(Variable): An optional input to specify output shape
                                dynamically. If provided, image resize
                                according to this given shape rather than
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                                :attr:`out_shape` and :attr:`scale` specifying
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                                shape. That is to say actual_shape has the
                                highest priority. It is recommended to use
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                                :attr:`out_shape` if you want to specify output 
                                shape dynamically, because :attr:`actual_shape` 
                                will be deprecated. When using actual_shape to 
                                specify output shape, one of :attr:`out_shape` 
                                and :attr:`scale` should also be set, otherwise 
                                errors would be occured in graph constructing stage.
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                                Default: None
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        align_corners(bool): ${align_corners_comment}
        align_mode(bool): ${align_mode_comment}
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        data_format (str, optional): Specify the data format of the input, and the data format of the output 
            will be consistent with that of the input. An optional string from: `"NCHW"`, `"NHWC"`.
            The default is `"NCHW"`. When it is `"NCHW"`, the data is stored in the order of:
            `[batch_size, input_channels, input_height, input_width]`.
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        name(str, optional): The default value is None.  Normally there is no need for user to set this property.  For more information, please refer to :ref:`api_guide_Name`
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    Returns:
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	Variable: 4-D tensor(NCHW or NHWC).
    
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    Examples:
        .. code-block:: python
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	    #declarative mode
	    import paddle.fluid as fluid
	    import numpy as np
	    input = fluid.data(name="input", shape=[None,3,6,10])

	    #1
	    output = fluid.layers.resize_bilinear(input=input,out_shape=[12,12])

	    #2
	    #x = np.array([2]).astype("int32")
	    #dim1 = fluid.data(name="dim1", shape=[1], dtype="int32")
	    #fluid.layers.assign(input=x, output=dim1)
	    #output = fluid.layers.resize_bilinear(input=input,out_shape=[12,dim1])

	    #3
	    #x = np.array([3,12]).astype("int32")
	    #shape_tensor = fluid.data(name="shape_tensor", shape=[2], dtype="int32")
	    #fluid.layers.assign(input=x, output=shape_tensor)
	    #output = fluid.layers.resize_bilinear(input=input,out_shape=shape_tensor)

	    #4
	    #x = np.array([0.5]).astype("float32")
	    #scale_tensor = fluid.data(name="scale", shape=[1], dtype="float32")
	    #fluid.layers.assign(x,scale_tensor)
	    #output = fluid.layers.resize_bilinear(input=input,scale=scale_tensor)

	    place = fluid.CPUPlace()
	    exe = fluid.Executor(place)
	    exe.run(fluid.default_startup_program())
 
	    input_data = np.random.rand(2,3,6,10).astype("float32")
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	    output_data = exe.run(fluid.default_main_program(),
                feed={"input":input_data},
                fetch_list=[output],
                return_numpy=True)
 
	    print(output_data[0].shape)
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	    #1
	    # (2, 3, 12, 12)
	    #2
	    # (2, 3, 12, 2)
	    #3
	    # (2, 3, 3, 12)
	    #4
	    # (2, 3, 3, 5)
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	    #imperative mode
	    import paddle.fluid.dygraph as dg
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	    with dg.guard(place) as g:
    		input = dg.to_variable(input_data)
    		output = fluid.layers.resize_bilinear(input=input, out_shape=[12,12])
    		print(output.shape)
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		# [2L, 3L, 12L, 12L]
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    """

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    return image_resize(input, out_shape, scale, name, 'BILINEAR', actual_shape,
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                        align_corners, align_mode, data_format)
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@templatedoc(op_type="trilinear_interp")
def resize_trilinear(input,
                     out_shape=None,
                     scale=None,
                     name=None,
                     actual_shape=None,
                     align_corners=True,
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                     align_mode=1,
                     data_format='NCDHW'):
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    """
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    This op resizes the input by performing trilinear interpolation based on given
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    output shape which specified by actual_shape, out_shape and scale
    in priority order.

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    **Warning:** the parameter :attr:`actual_shape` will be deprecated 
    in the future and only use :attr:`out_shape` instead.

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    Trilinear interpolation is an extension of linear interpolation for 
    interpolating functions of three variables (e.g. D-direction, 
    H-direction and W-direction in this op) on a rectilinear 3D grid. 
    The linear interpolation is performed on three directions.

    For details of trilinear interpolation, please refer to Wikipedia:
    https://en.wikipedia.org/wiki/Trilinear_interpolation

    Align_corners and align_mode are optinal parameters,the calculation 
    method of interpolation can be selected by them.

    Example:

    .. code-block:: text

        For scale:
          
            if align_corners = True && out_size > 1 :

              scale_factor = (in_size-1.0)/(out_size-1.0)
            
            else:
              
              scale_factor = float(in_size/out_size)     

        Bilinear interpolation:

          if:
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              align_corners = False , align_mode = 0
              
              input : (N,C,D_in,H_in,W_in)
              output: (N,C,D_out,H_out,W_out) where:
              
              D_out = (D_{in}+0.5) * scale_{factor} - 0.5
              H_out = (H_{in}+0.5) * scale_{factor} - 0.5
              W_out = (W_{in}+0.5) * scale_{factor} - 0.5

          else:

              input : (N,C,D_in,H_in,W_in)
              output: (N,C,D_out,H_out,W_out) where:

              D_out = D_{in} * scale_{factor}
              H_out = H_{in} * scale_{factor}
              W_out = W_{in} * scale_{factor}

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    Parameters:
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        input(${x_type}): 5-D Tensor, its data type is float32, float64, or uint8,
                          its data format is specified by :attr:`data_format`.
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        out_shape(list|tuple|Variable|None): The output shape of resized tensor, the shape is (out_d, out_h, out_w). Default: None. Every element should be an integer or a Tensor Variable with shape: [1] if it is a list. If it is a Tensor Variable, its dimension size should be 1.
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        scale(float|Variable|None): The multiplier for the input depth, height or width.
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             At least one of :attr:`out_shape` or :attr:`scale` must be set. 
             And :attr:`out_shape` has a higher priority than :attr:`scale`. 
             Default: None.
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        name(str, optional): The default value is None.  Normally there is no need for user to set this property.  For more information, please refer to :ref:`api_guide_Name`
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        actual_shape(Variable): An optional input to specify output shape
                                dynamically. If provided, image resize
                                according to this given shape rather than
                                :attr:`out_shape` and :attr:`scale` specifying
                                shape. That is to say actual_shape has the
                                highest priority. It is recommended to use
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                                :attr:`out_shape` if you want to specify output 
                                shape dynamically, because :attr:`actual_shape` 
                                will be deprecated. When using actual_shape to 
                                specify output shape, one of :attr:`out_shape` 
                                and :attr:`scale` should also be set, otherwise 
                                errors would be occured in graph constructing stage.
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                                Default: None
        align_corners(bool): ${align_corners_comment}
        align_mode(bool): ${align_mode_comment}
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        data_format (str, optional): Specify the data format of the input, and the data format of the output 
            will be consistent with that of the input. An optional string from: `"NCDHW"`, `"NDHWC"`.
            The default is `"NCDHW"`. When it is `"NCDHW"`, the data is stored in the order of:
            `[batch_size, input_channels, input_depth, input_height, input_width]`.
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    Returns:
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        Variable: A 5-D Tensor(NCDHW or NDHWC) 
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    Examples:
        .. code-block:: python
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	    #declarative mode
	    import paddle.fluid as fluid
	    import numpy as np
	    input = fluid.data(name="input", shape=[None,3,6,8,10])

	    #1
	    output = fluid.layers.resize_trilinear(input=input,out_shape=[12,12,12])

	    #2
	    #x = np.array([2]).astype("int32")
	    #dim1 = fluid.data(name="dim1", shape=[1], dtype="int32")
	    #fluid.layers.assign(input=x, output=dim1)
	    #output = fluid.layers.resize_trilinear(input=input,out_shape=[12,dim1,4])

	    #3
	    #x = np.array([3,12,12]).astype("int32")
	    #shape_tensor = fluid.data(name="shape_tensor", shape=[3], dtype="int32")
	    #fluid.layers.assign(input=x, output=shape_tensor)
	    #output = fluid.layers.resize_trilinear(input=input,out_shape=shape_tensor)

	    #4
	    #x = np.array([0.5]).astype("float32")
	    #scale_tensor = fluid.data(name="scale", shape=[1], dtype="float32")
	    #fluid.layers.assign(x,scale_tensor)
	    #output = fluid.layers.resize_trilinear(input=input,scale=scale_tensor)

	    place = fluid.CPUPlace()
	    exe = fluid.Executor(place)
	    exe.run(fluid.default_startup_program())
 
	    input_data = np.random.rand(2,3,6,8,10).astype("float32")
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	    output_data = exe.run(fluid.default_main_program(),
                feed={"input":input_data},
                fetch_list=[output],
                return_numpy=True)
 
	    print(output_data[0].shape)

	    #1
	    # (2, 3, 12, 12, 12)
	    #2
	    # (2, 3, 12, 2, 4)
	    #3
	    # (2, 3, 3, 12, 12)
	    #4
	    # (2, 3, 3, 4, 5)

	    #imperative mode
	    import paddle.fluid.dygraph as dg
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	    with dg.guard(place) as g:
    		input = dg.to_variable(input_data)
    		output = fluid.layers.resize_trilinear(input=input, out_shape=[12,12,12])
    		print(output.shape)
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		# [2L, 3L, 12L, 12L, 12L]
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    """

    return image_resize(input, out_shape, scale, name, 'TRILINEAR',
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                        actual_shape, align_corners, align_mode, data_format)
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7193
@templatedoc(op_type="nearest_interp")
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def resize_nearest(input,
                   out_shape=None,
                   scale=None,
                   name=None,
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                   actual_shape=None,
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                   align_corners=True,
                   data_format='NCHW'):
7201
    """
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    This op resizes the input by performing nearest neighbor interpolation in both the
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    height direction and the width direction based on given output shape 
    which is specified by actual_shape, out_shape and scale in priority order.
7205

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    **Warning:** the parameter :attr:`actual_shape` will be deprecated in the 
    future and only use :attr:`out_shape` instead.

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    Example:

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    .. code-block:: text

        For scale:
          
            if align_corners = True && out_size > 1 :
              scale_factor = (in_size-1.0)/(out_size-1.0)
            
            else:
              
              scale_factor = float(in_size/out_size)
          
        Nearest neighbor interpolation:
7223
          
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          if:
              align_corners = False
7226

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              input : (N,C,H_in,W_in)
              output: (N,C,H_out,W_out) where:
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              H_out = floor(H_{in} * scale_{factor})
              W_out = floor(W_{in} * scale_{factor})
7232

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          else:
              align_corners = True
7235

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              input : (N,C,H_in,W_in)
              output: (N,C,H_out,W_out) where:
7238

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              H_out = round(H_{in} * scale_{factor})
              W_out = round(W_{in} * scale_{factor})
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7243
    For details of nearest neighbor interpolation, please refer to Wikipedia:
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    https://en.wikipedia.org/wiki/Nearest-neighbor_interpolation
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    Parameters:
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        input(${x_type}): 4-D Tensor, its data type is float32, float64, or uint8,
                          its data format is specified by :attr:`data_format`.
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        out_shape(list|tuple|Variable|None): The output shape of resized tensor, the shape is (out_h, out_w). Default: None. Every element should be an integer or a tensor Variable with shape: [1] if it is a list. If it is a tensor Variable, its dimension size should be 1.
7250
        scale(float|Variable|None): The multiplier for the input height or width. At
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             least one of :attr:`out_shape` or :attr:`scale` must be set. 
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             And :attr:`out_shape` has a higher priority than :attr:`scale`. 
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             Default: None. 
        name(str, optional): The default value is None.  Normally there is no need for user to set this property.  For more information, please refer to :ref:`api_guide_Name`
	actual_shape(Variable): An optional input to specify output shape
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                                dynamically. If provided, image resize
                                according to this given shape rather than
7258
                                :attr:`out_shape` and :attr:`scale` specifying
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                                shape. That is to say actual_shape has the
                                highest priority. It is recommended to use
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                                :attr:`out_shape` if you want to specify output 
                                shape dynamically, because :attr:`actual_shape` 
                                will be deprecated. When using actual_shape to 
                                specify output shape, one of :attr:`out_shape` 
                                and :attr:`scale` should also be set, otherwise 
                                errors would be occured in graph constructing stage.
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                                Default: None
7268
        align_corners(bool): ${align_corners_comment}
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        data_format (str, optional): Specify the data format of the input, and the data format of the output 
            will be consistent with that of the input. An optional string from: `"NCHW"`, `"NHWC"`.
            The default is `"NCHW"`. When it is `"NCHW"`, the data is stored in the order of:
            `[batch_size, input_channels, input_height, input_width]`.
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    Returns:
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	Variable: 4-D tensor(NCHW or NHWC).
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    Examples:
        .. code-block:: python
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	    #declarative mode
	    import paddle.fluid as fluid
	    import numpy as np
	    input = fluid.data(name="input", shape=[None,3,6,10])

	    #1
	    output = fluid.layers.resize_nearest(input=input,out_shape=[12,12])

	    #2
	    #x = np.array([2]).astype("int32")
	    #dim1 = fluid.data(name="dim1", shape=[1], dtype="int32")
	    #fluid.layers.assign(input=x, output=dim1)
	    #output = fluid.layers.resize_nearest(input=input,out_shape=[12,dim1])

	    #3
	    #x = np.array([3,12]).astype("int32")
	    #shape_tensor = fluid.data(name="shape_tensor", shape=[2], dtype="int32")
	    #fluid.layers.assign(input=x, output=shape_tensor)
	    #output = fluid.layers.resize_nearest(input=input,out_shape=shape_tensor)

	    #4
	    #x = np.array([0.5]).astype("float32")
	    #scale_tensor = fluid.data(name="scale", shape=[1], dtype="float32")
	    #fluid.layers.assign(x,scale_tensor)
	    #output = fluid.layers.resize_nearest(input=input,scale=scale_tensor)

	    place = fluid.CPUPlace()
	    exe = fluid.Executor(place)
	    exe.run(fluid.default_startup_program())
 
	    input_data = np.random.rand(2,3,6,10).astype("float32")
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	    output_data = exe.run(fluid.default_main_program(),
                feed={"input":input_data},
                fetch_list=[output],
                return_numpy=True)
 
	    print(output_data[0].shape)

	    #1
	    # (2, 3, 12, 12)
	    #2
	    # (2, 3, 12, 2)
	    #3
	    # (2, 3, 3, 12)
	    #4
	    # (2, 3, 3, 5)
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	    #imperative mode
	    import paddle.fluid.dygraph as dg
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	    with dg.guard(place) as g:
    		input = dg.to_variable(input_data)
    		output = fluid.layers.resize_nearest(input=input, out_shape=[12,12])
    		print(output.shape)

		# [2L, 3L, 12L, 12L]
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    """

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    return image_resize(
        input,
        out_shape,
        scale,
        name,
        'NEAREST',
        actual_shape,
        align_corners,
        align_mode=1,
        data_format=data_format)
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def image_resize_short(input, out_short_len, resample='BILINEAR'):
    """
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    This op resizes a batch of images. The short edge of input images will be
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    resized to the given 'out_short_len'. The long edge of input images
    will be resized proportionately to make images' length-width ratio
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    constant.

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    Parameters:
        input (Variable): 4-D tensor(NCHW), The input tensor of image resize layer.
7363
        out_short_len(int): The length of output images' short edge.
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        resample (str): resample method, default: BILINEAR.
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    Returns:
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        Variable: 4-D tensor(NCHW).
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    Examples:
        .. code-block:: python

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            import paddle.fluid as fluid
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            input = fluid.data(name="input", shape=[None,3,6,9], dtype="float32")
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            out = fluid.layers.image_resize_short(input, out_short_len=3)
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    """
    in_shape = input.shape
    if len(in_shape) != 4:
        raise ValueError(
            "The rank of input must be 4 (num_batches, channels, in_h, in_w).")
    hw = in_shape[2:4]
    short_idx = hw.index(min(hw))
    long_idx = 1 - short_idx
    out_shape = list(hw)
    out_shape[short_idx] = out_short_len
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    out_shape[long_idx] = int(
        float(out_shape[long_idx]) * (float(out_short_len) / float(hw[
            short_idx])) + 0.5)
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    return image_resize(input=input, out_shape=out_shape, resample=resample)


7391
def gather(input, index, overwrite=True):
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    """
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    **Gather Layer**

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    Output is obtained by gathering entries of the outer-most dimension
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    of X indexed by `index` and concatenate them together.

    .. math::

7400
        Out = X[Index]
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    .. code-block:: text


                Given:

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                X = [[1, 2],
                     [3, 4],
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                     [5, 6]]

                Index = [1, 2]

                Then:

                Out = [[3, 4],
                       [5, 6]]

    Args:
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        input (Variable): The source input tensor with rank>=1. Supported data type is 
            int32, int64, float32, float64 and uint8 (only for CPU), 
            float16 (only for GPU).
        index (Variable): The index input tensor with rank=1. Data type is int32 or int64.
        overwrite (bool, optional): The mode that updating the grad when has same index.
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            If True, use the overwrite mode to update the grad of the same index,
	    if False, use the accumulate mode to update the grad of the same index. 
	    Default value is True.
	    

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    Returns:
        output (Variable): The output is a tensor with the same rank as input.

    Examples:
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        .. code-block:: python

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            import paddle.fluid as fluid
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            x = fluid.data(name='x', shape=[-1, 5], dtype='float32')
            index = fluid.data(name='index', shape=[-1, 1], dtype='int32')
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            output = fluid.layers.gather(x, index)
    """
    helper = LayerHelper('gather', **locals())
    dtype = helper.input_dtype()
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    out = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
        type="gather",
        inputs={"X": input,
                "Index": index},
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        outputs={"Out": out},
        attrs={'overwrite': overwrite})
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    return out


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def gather_nd(input, index, name=None):
    """
    **Gather Nd Layer**

    This function is actually a high-dimensional extension of :code:`gather` 
    and supports for simultaneous indexing by multiple axes. :attr:`index` is a 
    K-dimensional integer tensor, which is regarded as a (K-1)-dimensional 
    tensor of :attr:`index` into :attr:`input`, where each element defines 
    a slice of params:

    .. math::

        output[(i_0, ..., i_{K-2})] = input[index[(i_0, ..., i_{K-2})]]

    Obviously, :code:`index.shape[-1] <= input.rank` . And, the output tensor has
    shape :code:`index.shape[:-1] + input.shape[index.shape[-1]:]` .

    .. code-block:: text

            Given:
                input = [[[ 0,  1,  2,  3],
                          [ 4,  5,  6,  7],
                          [ 8,  9, 10, 11]],
                         [[12, 13, 14, 15],
                          [16, 17, 18, 19],
                          [20, 21, 22, 23]]]
                input.shape = (2, 3, 4)

            * Case 1:
                index = [[1]]
                
                gather_nd(input, index)  
                         = [input[1, :, :]] 
                         = [[12, 13, 14, 15],
                            [16, 17, 18, 19],
                            [20, 21, 22, 23]]

            * Case 2:
                index = [[0,2]]

                gather_nd(input, index)
                         = [input[0, 2, :]]
                         = [8, 9, 10, 11]

            * Case 3:
                index = [[1, 2, 3]]

                gather_nd(input, index)
                         = [input[1, 2, 3]]
                         = [23]

    Args:
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        input (Variable): The source input. Its dtype should be int32, int64, float32, float64.
        index (Variable): The index input with rank > 1, index.shape[-1] <= input.rank.
                          Its dtype should be int32, int64.
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        name (str|None): A name for this layer(optional). If set None, the
7511
                         layer will be named automatically.
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    Returns:
        output (Variable): A tensor with the shape index.shape[:-1] + input.shape[index.shape[-1]:]

    Examples:

        .. code-block:: python

            import paddle.fluid as fluid
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            x = fluid.data(name='x', shape=[3, 4, 5], dtype='float32')
            index = fluid.data(name='index', shape=[2, 2], dtype='int32')
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            output = fluid.layers.gather_nd(x, index)

    """
    helper = LayerHelper('gather_nd', **locals())
    dtype = helper.input_dtype()
    if name is None:
        output = helper.create_variable_for_type_inference(dtype)
    else:
        output = helper.create_variable(
            name=name, dtype=dtype, persistable=False)
    helper.append_op(
        type="gather_nd",
        inputs={"X": input,
                "Index": index},
        outputs={"Out": output})
    return output


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def scatter(input, index, updates, name=None, overwrite=True):
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    """
    **Scatter Layer**

7545
    Output is obtained by updating the input on selected indices based on updates.
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    .. code-block:: python
        import numpy as np
                
        #input:
        input = np.array([[1, 1], [2, 2], [3, 3]])
        index = np.array([2, 1, 0, 1])
        # shape of updates should be the same as input
        # shape of updates with dim > 1 should be the same as input
        updates = np.array([[1, 1], [2, 2], [3, 3], [4, 4]])
        overwrite = False

        # calculation:
        if not overwrite:
            for i in range(len(index)):
                input[index[i]] = np.zeros((2))

        for i in range(len(index)):
            if (overwrite):
                input[index[i]] = updates[i]
            else:
                input[index[i]] += updates[i]
        # output:
        out = np.array([[3, 3], [6, 6], [1, 1]])
        out.shape # [3, 2]
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    Args:
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        input (Variable): The input N-D Tensor with rank>=1. Data type can be float32.
        index (Variable): The index 1-D Tensor. Data type can be int32, int64. The length of index cannot exceed updates's length, and the value in index cannot exceed input's length.
        updates (Variable): update input with updates parameter based on index. shape should be the same as input, and dim value with dim > 1 shoule be the same as input.
        name(str, optional): The default value is None.  Normally there is no need for user to set this property.  For more information, please refer to :ref:`api_guide_Name` .
        overwrite (bool): The mode that updating the output when there are same indices.
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            If True, use the overwrite mode to update the output of the same index,
	    if False, use the accumulate mode to update the output of the same index. 
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	    Default value is True.
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    Returns:
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        Variable(Tensor|LoDTensor): The output is a Tensor with the same shape as input.
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    Examples:

        .. code-block:: python

7589
            import numpy as np
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            import paddle.fluid as fluid

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            input = fluid.layers.data(name='data', shape=[3, 2], dtype='float32', append_batch_size=False)
            index = fluid.layers.data(name='index', shape=[4], dtype='int64', append_batch_size=False)
            updates = fluid.layers.data(name='update', shape=[4, 2], dtype='float32', append_batch_size=False)
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            output = fluid.layers.scatter(input, index, updates, overwrite=False)

            exe = fluid.Executor(fluid.CPUPlace())
            exe.run(fluid.default_startup_program())

            in_data = np.array([[1, 1], [2, 2], [3, 3]]).astype(np.float32)
            index_data = np.array([2, 1, 0, 1]).astype(np.int64)
            update_data = np.array([[1, 1], [2, 2], [3, 3], [4, 4]]).astype(np.float32)

            res = exe.run(fluid.default_main_program(), feed={'data':in_data, "index":index_data, "update":update_data}, fetch_list=[output])
            print(res)
            # [array([[3., 3.],
            #   [6., 6.],
            #   [1., 1.]], dtype=float32)]
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    """
    helper = LayerHelper('scatter', **locals())
    dtype = helper.input_dtype()
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    out = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
        type="scatter",
        inputs={"X": input,
                "Ids": index,
                "Updates": updates},
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        attrs={'overwrite': overwrite},
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        outputs={"Out": out})
    return out


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def scatter_nd_add(ref, index, updates, name=None):
    """
    **Scatter_nd_add Layer**

    Output is obtained by applying sparse addition to a single value
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    or slice in a Variable. 

    :attr:`ref` is a Tensor with rank :math:`R` 
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    and :attr:`index` is a Tensor with rank :math:`K` . Thus, :attr:`index` 
    has shape :math:`[i_0, i_1, ..., i_{K-2}, Q]` where :math:`Q \leq R` . :attr:`updates` 
    is a Tensor with rank :math:`K - 1 + R - Q` and its
    shape is :math:`index.shape[:-1] + ref.shape[index.shape[-1]:]` .
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    According to the :math:`[i_0, i_1, ..., i_{K-2}]` of :attr:`index` ,
    add the corresponding :attr:`updates` slice to the :attr:`ref` slice
    which is obtained by the last one dimension of :attr:`index` .

    .. code-block:: text
        
        Given:

        * Case 1:
            ref = [0, 1, 2, 3, 4, 5]
            index = [[1], [2], [3], [1]]
            updates = [9, 10, 11, 12]

          we get:
             
            output = [0, 22, 12, 14, 4, 5]

        * Case 2:
            ref = [[65, 17], [-14, -25]]
            index = [[], []]
            updates = [[[-1, -2], [1, 2]],
                       [[3, 4], [-3, -4]]]
            ref.shape = (2, 2)
            index.shape = (2, 0)
            updates.shape = (2, 2, 2)

          we get:
             
            output = [[67, 19], [-16, -27]]

    Args:
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        ref (Variable): The ref input. Its dtype should be float32, float64.
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        index (Variable): The index input with rank > 1 and index.shape[-1] <= ref.rank.
                          Its dtype should be int32 or int64 as it is used as indexes.
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        updates (Variable): The updated value of scatter_nd_add op, and it must have the same dtype
                            as ref. It must have the shape index.shape[:-1] + ref.shape[index.shape[-1]:].
        name (str|None): The output variable name. If set None, the layer will be named automatically.
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    Returns:
7676
        output (Variable): The output is a tensor with the same shape and dtype as ref.
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    Examples:

        .. code-block:: python

            import paddle.fluid as fluid

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            ref = fluid.data(name='ref', shape=[3, 5, 9, 10], dtype='float32')
            index = fluid.data(name='index', shape=[3, 2], dtype='int32')
            updates = fluid.data(name='update', shape=[3, 9, 10], dtype='float32')
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            output = fluid.layers.scatter_nd_add(ref, index, updates)
    """
    if ref.dtype != updates.dtype:
        raise ValueError("ref and updates must have same data type.")

    helper = LayerHelper('scatter_nd_add', **locals())
7694
    dtype = helper.input_dtype(input_param_name='ref')
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    if name is None:
        output = helper.create_variable_for_type_inference(dtype)
    else:
        output = helper.create_variable(
            name=name, dtype=dtype, persistable=False)
    helper.append_op(
        type="scatter_nd_add",
        inputs={"X": ref,
                "Index": index,
                "Updates": updates},
        outputs={"Out": output})
    return output


def scatter_nd(index, updates, shape, name=None):
    """
    **Scatter_nd Layer**

    Output is obtained by scattering the :attr:`updates` in a new tensor according 
    to :attr:`index` . This op is similar to :code:`scatter_nd_add`, except the 
    tensor of :attr:`shape` is zero-initialized. Correspondingly, :code:`scatter_nd(index, updates, shape)` 
    is equal to :code:`scatter_nd_add(fluid.layers.zeros(shape, updates.dtype), index, updates)` . 
    If :attr:`index` has repeated elements, then the corresponding updates are accumulated. 
    Because of the numerical approximation issues, the different order of repeated elements 
    in :attr:`index` may cause different results. The specific calculation method can be 
    seen :code:`scatter_nd_add` . This op is the inverse of the :code:`gather_nd` op.

    Args:
        index (Variable): The index input with rank > 1 and index.shape[-1] <= len(shape).
                          Its dtype should be int32 or int64 as it is used as indexes.
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        updates (Variable): The updated value of scatter_nd op. Its dtype should be float32, float64.
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                            It must have the shape index.shape[:-1] + shape[index.shape[-1]:]
        shape(tuple|list): Shape of output tensor.
7728
        name (str|None): The output variable name. If set None, the layer will be named automatically.
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    Returns:
        output (Variable): The output is a tensor with the same type as :attr:`updates` .

    Examples:

        .. code-block:: python

            import paddle.fluid as fluid

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            index = fluid.data(name='index', shape=[3, 2], dtype='int64')
            updates = fluid.data(name='update', shape=[3, 9, 10], dtype='float32')
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            shape = [3, 5, 9, 10]

            output = fluid.layers.scatter_nd(index, updates, shape)
    """
    return scatter_nd_add(zeros(shape, updates.dtype), index, updates, name)


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@templatedoc()
def random_crop(x, shape, seed=None):
    """
    ${comment}

    Args:
        x(${x_type}): ${x_comment}
        shape(${shape_type}): ${shape_comment}
        seed(int|${seed_type}|None): ${seed_comment} By default, the seed will
            get from `random.randint(-65536, 65535)`.

    Returns:
        ${out_comment}
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    Examples:
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        .. code-block:: python

            import paddle.fluid as fluid
            img = fluid.data("img", [None, 3, 256, 256])
            # cropped_img is [-1, 3, 224, 224]
            cropped_img = fluid.layers.random_crop(img, shape=[3, 224, 224])

            # cropped_img2 shape: [-1, 2, 224, 224]
            # cropped_img2 = fluid.layers.random_crop(img, shape=[2, 224, 224])

            # cropped_img3 shape: [-1, 3, 128, 224]
            # cropped_img3 = fluid.layers.random_crop(img, shape=[128, 224])

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    """
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    helper = LayerHelper("random_crop", **locals())
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    dtype = x.dtype
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    out = helper.create_variable_for_type_inference(dtype)
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    if seed is None:
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        seed = np.random.randint(-65536, 65536)
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    op_attrs = {"shape": shape}
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    if isinstance(seed, int):
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        op_attrs["startup_seed"] = seed
        seed = helper.create_variable(
            name=unique_name.generate("random_crop_seed"),
            dtype="int64",
            persistable=True)
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    elif not isinstance(seed, Variable):
        raise ValueError("'seed' must be a Variable or an int.")
    helper.append_op(
        type="random_crop",
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        inputs={"X": x,
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                "Seed": seed},
        outputs={"Out": out,
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                 "SeedOut": seed},
        attrs=op_attrs)
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    return out
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def log(x, name=None):
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    """
    Calculates the natural log of the given input tensor, element-wise.

    .. math::

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        Out = \\ln(x)
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    Args:
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        x (Variable): Input LoDTensor or Tensor. Must be one of the following types: float32, float64.
        name (str|None): The default value is None. Normally there is no need for user to set this property. For more information, please refer to :ref:`api_guide_Name`
    
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    Returns:
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        Variable: The natural log of the input LoDTensor or Tensor computed element-wise.
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    Examples:

        .. code-block:: python

7821
            import paddle.fluid as fluid
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            import numpy as np

            # Graph Organizing
            x = fluid.layers.data(name="x", shape=[1], dtype="float32")
            res = fluid.layers.log(x)

            # Create an executor using CPU as an example
            exe = fluid.Executor(fluid.CPUPlace())

            # Execute
            x_i = np.array([[1], [2]]).astype(np.float32)
            res_val, = exe.run(fluid.default_main_program(), feed={'x':x_i}, fetch_list=[res])
            print(res_val) # [[0.], [0.6931472]]
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    """
    helper = LayerHelper('log', **locals())
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    dtype = helper.input_dtype(input_param_name='x')
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    out = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(type="log", inputs={"X": x}, outputs={"Out": out})
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    return out


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@templatedoc()
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def relu(x, name=None):
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    """
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    ${comment}
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    Args:
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        x(Variable): ${x_comment}
        name(str, optional): The default value is None. Normally there is no
            need for user to set this property. For more information, please
            refer to :ref:`api_guide_Name`.
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    Returns:
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        Variable: ${out_comment}
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    Examples:

        .. code-block:: python

7861
            import paddle.fluid as fluid
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            import numpy as np
            in1 = np.array([[-1,0],[1,2.6]])
            with fluid.dygraph.guard():
                x1 = fluid.dygraph.to_variable(in1)
                out1 = fluid.layers.relu(x1)
                print(out1.numpy())
                # [[0.  0. ]
                #  [1.  2.6]]
"""
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    helper = LayerHelper('relu', **locals())
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    dtype = helper.input_dtype(input_param_name='x')
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    out = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
        type="relu", inputs={"X": helper.input('x')}, outputs={"Out": out})
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    return out
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def selu(x, scale=None, alpha=None, name=None):
    """
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    Selu Operator.

    The equation is:
    
    .. math::
        selu= \\lambda*
        \\begin{cases}
            x                      &\\quad \\text{ if } x>0 \n
            \\alpha * e^x - \\alpha  &\\quad \\text{ if } x<=0
        \\end{cases}
    

    The input `X` can carry the LoD (Level of Details) information,
    or not. And the output shares the LoD information with input `X`.
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    Args:
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        x (Variable): The input N-D Tensor.
        scale(float, optional): lambda in selu activation function,
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            the default value is 1.0507009873554804934193349852946.
            For more information about this value, please refer
            to: https://arxiv.org/abs/1706.02515.
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        alpha(float, optional): alpha in selu activation function,
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            the default value is 1.6732632423543772848170429916717.
            For more information about this value, please refer
            to: https://arxiv.org/abs/1706.02515.
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        name(str, optional): The default value is None.  Normally there is no need for user to set this property.  For more information, please refer to :ref:`api_guide_Name` .

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    Returns:
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        Variable(Tensor|LoDTensor): The output Tensor or LoDTensor with the same shape and LoD information as input.
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    Examples:

        .. code-block:: python
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            import paddle.fluid as fluid
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            import numpy as np

            inputs = fluid.layers.data(name="x", shape=[2, 2], dtype="float32")
            output = fluid.layers.selu(inputs)

            exe = fluid.Executor(fluid.CPUPlace())
            exe.run(fluid.default_startup_program())

            img = np.array([[0, 1],[2, 3]]).astype(np.float32)

            res = exe.run(fluid.default_main_program(), feed={'x':img}, fetch_list=[output])
            print(res) # [array([[0.      , 1.050701],[2.101402, 3.152103]], dtype=float32)]
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    """
    helper = LayerHelper('selu', **locals())
    dtype = helper.input_dtype(input_param_name='x')
    out = helper.create_variable_for_type_inference(dtype)
    attrs = {}
    if scale is not None:
        attrs["scale"] = scale
    if alpha is not None:
        attrs["alpha"] = alpha

    helper.append_op(
        type="selu", inputs={"X": x}, outputs={"Out": out}, attrs=attrs)
    return out


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def mean_iou(input, label, num_classes):
    """
    Mean Intersection-Over-Union is a common evaluation metric for
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    semantic image segmentation, which first computes the IOU for each
    semantic class and then computes the average over classes.
    IOU is defined as follows:

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    .. math::
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        IOU = \\frac{true\_positive}{(true\_positive + false\_positive + false\_negative)}.
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    The predictions are accumulated in a confusion matrix and mean-IOU
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    is then calculated from it.


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    Parameters:
        input (Variable): A n-D Tensor of prediction results for semantic labels with type int32 or int64.
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        label (Variable): A Tensor of ground truth labels with type int32 or int64.
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                           Its shape should be the same as input.
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        num_classes (int32): The possible number of labels.

    Returns: 
	Three Variables.

        - mean_iou(Variable) : A 1-D Tensor representing the mean intersection-over-union with shape [1]. \
			    Data type is float32.
        - out_wrong(Variable) : A 1-D Tensor with shape [num_classes]. Data type is int32. \
			     The wrong numbers of each class.
        - out_correct(Variable): A 1-D  Tensor with shape [num_classes]. Data type is int32. The correct numbers of each class.
 
   
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    Examples:

        .. code-block:: python
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            import paddle.fluid as fluid
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            iou_shape = [None, 32, 32]
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            num_classes = 5
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            predict = fluid.data(name='predict', shape=iou_shape, dtype='int64')
            label = fluid.data(name='label', shape=iou_shape, dtype='int64')
            mean_iou, out_wrong, out_correct = fluid.layers.mean_iou(predict, label,
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                                                          num_classes)
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    """
    helper = LayerHelper('mean_iou', **locals())
    dtype = helper.input_dtype()
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    out_mean_iou = helper.create_variable_for_type_inference(dtype='float32')
    out_wrong = helper.create_variable_for_type_inference(dtype='int32')
    out_correct = helper.create_variable_for_type_inference(dtype='int32')
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    helper.append_op(
        type="mean_iou",
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        inputs={"Predictions": input,
                "Labels": label},
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        outputs={
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            "OutMeanIou": out_mean_iou,
            "OutWrong": out_wrong,
            "OutCorrect": out_correct
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        },
        attrs={"num_classes": num_classes})
    return out_mean_iou, out_wrong, out_correct
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def crop(x, shape=None, offsets=None, name=None):
    """
    Crop input into output, as specified by offsets and shape.

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    **Warning:** THIS OP IS DEPRECATED. It will be removed in the future version.
    Instructions for updating: Use :ref:`api_fluid_layers_crop_tensor` instead.
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    .. code-block:: text

        * Case 1:
            Given
                X = [[0, 1, 2, 0, 0]
                     [0, 3, 4, 0, 0]
                     [0, 0, 0, 0, 0]],
            and
                shape = [2, 2],
                offsets = [0, 1],
            output is:
                Out = [[1, 2],
                       [3, 4]].
        * Case 2:
            Given
                X = [[0, 1, 2, 5, 0]
                     [0, 3, 4, 6, 0]
                     [0, 0, 0, 0, 0]],
            and shape is tensor
                shape = [[0, 0, 0]
                         [0, 0, 0]]
            and
                offsets = [0, 1],

            output is:
                Out = [[1, 2, 5],
                       [3, 4, 6]].

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    Parameters:
        x (Variable): Tensor, data type can be float32 or float64.
        shape (Variable|list/tuple of integers): The output shape is specified
            by `shape`, which can be a Tensor or a list/tuple of integers.
            If it is a Tensor, it's rank must be the same as `x` , only 
            it's shape will be used, and the value of it will be ignored. This way
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            is suitable for the case that the output shape may be changed each
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            iteration. If it is a list/tuple of integers, it's length must be the same
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            as the rank of `x`
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        offsets (Variable|list/tuple of integers|None): Specifies the cropping
            offsets at each dimension. It can be a Tensor or a list/tuple
            of integers. If it is a Tensor, it's rank must be the same as `x`.
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            This way is suitable for the case that the offsets may be changed
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            each iteration. If it is a list/tuple of integers, it's length must be the
            same as the rank of `x`. If None, the offsets are 0 at each dimension.
        name(str, optional): For detailed information, please refer 
            to :ref:`api_guide_Name` . Usually name is no need to set and 
            None by default. 
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    Returns:
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        The cropped Tensor, which has the same rank and data type with `x`

    Return Type:
        Variable
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    Raises:
        ValueError: If shape is not a list, tuple or Variable.

    Examples:

        .. code-block:: python

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            import paddle.fluid as fluid
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            x = fluid.data(name="x", shape=[3, 3, 5], dtype="float32")
            y = fluid.data(name="y", shape=[2, 2, 3], dtype="float32")
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            crop = fluid.layers.crop(x, shape=y)

            # or
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            z = fluid.data(name="z", shape=[3, 3, 5], dtype="float32")
            crop = fluid.layers.crop(z, shape=[2, 2, 3])
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    """
    helper = LayerHelper('crop', **locals())

    if not (isinstance(shape, list) or isinstance(shape, tuple) or \
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            isinstance(shape, Variable)):
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        raise ValueError("The shape should be a list, tuple or Variable.")

    if offsets is None:
        offsets = [0] * len(x.shape)

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    out = helper.create_variable_for_type_inference(x.dtype)
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    ipts = {'X': x}
    attrs = {}
    if isinstance(shape, Variable):
        ipts['Y'] = shape
    else:
        attrs['shape'] = shape
    if isinstance(offsets, Variable):
        ipts['Offsets'] = offsets
    else:
        attrs['offsets'] = offsets

    helper.append_op(
        type='crop',
        inputs=ipts,
        outputs={'Out': out},
        attrs=None if len(attrs) == 0 else attrs)
    return out
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def crop_tensor(x, shape=None, offsets=None, name=None):
    """
    Crop input into output, as specified by offsets and shape.

    .. code-block:: text

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        * Case 1 (input is a 2-D Tensor):
            Input:
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                X.shape = [3, 5]
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                X.data = [[0, 1, 2, 0, 0],
                          [0, 3, 4, 0, 0],
                          [0, 0, 0, 0, 0]]
            Parameters:
                shape = [2, 2]
                offsets = [0, 1]
            Output:
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                Out.shape = [2, 2]
                Out.data = [[1, 2],
                            [3, 4]]
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        * Case 2 (input is a 3-D Tensor):
            Input:
                X.shape = [2, 3, 4]
                X.data =  [[[0, 1, 2, 3],
                            [0, 5, 6, 7],
                            [0, 0, 0, 0]],
                           [[0, 3, 4, 5],
                            [0, 6, 7, 8],
                            [0, 0, 0, 0]]]
            Parameters:
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                shape = [2, 2, -1]
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                offsets = [0, 0, 1]
            Output:
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                Out.shape = [2, 2, 3]
                Out.data  = [[[1, 2, 3],
                              [5, 6, 7]],
                             [[3, 4, 5],
                              [6, 7, 8]]]
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    Parameters:
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        x (Variable): 1-D to 6-D Tensor, the data type is float32, float64, int32 or int64.
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        shape (list|tuple|Variable): The output shape is specified
            by `shape`. Its data type is int32. If a list/tuple, it's length must be
            the same as the dimension size of `x`. If a Variable, it shoule be a 1-D Tensor.
            When it is a list, each element can be an integer or a Tensor of shape: [1].
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            If Variable contained, it is suitable for the case that the shape may
            be changed each iteration.
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        offsets (list|tuple|Variable, optional): Specifies the cropping
            offsets at each dimension. Its data type is int32. If a list/tuple, it's length
            must be the same as the dimension size of `x`. If a Variable, it shoule be a 1-D
            Tensor. When it is a list, each element can be an integer or a Tensor of shape: [1].
            If Variable contained, it is suitable for the case that the offsets may be changed
            each iteration. Default: None, the offsets are 0 at each dimension.
        name(str, optional): The default value is None. Normally there is no need for user to set
            this property. For more information, please refer to :ref:`api_guide_Name` .
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    Returns:
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        Variable: The cropped Tensor has same data type with `x`.
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    Raises:
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        TypeError: If the data type of `x` is not in: float32, float64, int32, int64.
        TypeError: If `shape` is not a list, tuple or Variable.
        TypeError: If the data type of `shape` is not int32.
        TypeError: If `offsets` is not None and not a list, tuple or Variable.
        TypeError: If the data type of `offsets` is not int32.
        ValueError: If the element in `offsets` is less than zero.
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    Examples:

        .. code-block:: python

            import paddle.fluid as fluid
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            x = fluid.data(name="x", shape=[None, 3, 5], dtype="float32")
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            # x.shape = [-1, 3, 5], where -1 indicates batch size, and it will get the exact value in runtime.

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            # shape is a 1-D Tensor
            crop_shape = fluid.data(name="crop_shape", shape=[3], dtype="int32")
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            crop0 = fluid.layers.crop_tensor(x, shape=crop_shape)
            # crop0.shape = [-1, -1, -1], it means crop0.shape[0] = x.shape[0] in runtime.

            # or shape is a list in which each element is a constant
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            crop1 = fluid.layers.crop_tensor(x, shape=[-1, -1, 3], offsets=[0, 1, 0])
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            # crop1.shape = [-1, 2, 3]

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            # or shape is a list in which each element is a constant or Variable
            y = fluid.data(name="y", shape=[3, 8, 8], dtype="float32")
            dim1 = fluid.data(name="dim1", shape=[1], dtype="int32")
            crop2 = fluid.layers.crop_tensor(y, shape=[3, dim1, 4])
            # crop2.shape = [3, -1, 4]
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            # offsets is a 1-D Tensor
            crop_offsets = fluid.data(name="crop_offsets", shape=[3], dtype="int32")
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            crop3 = fluid.layers.crop_tensor(x, shape=[-1, 2, 3], offsets=crop_offsets)
            # crop3.shape = [-1, 2, 3]

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            # offsets is a list in which each element is a constant or Variable
            offsets_var =  fluid.data(name="dim1", shape=[1], dtype="int32")
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            crop4 = fluid.layers.crop_tensor(x, shape=[-1, 2, 3], offsets=[0, 1, offsets_var])
            # crop4.shape = [-1, 2, 3]

    """
    helper = LayerHelper('crop_tensor', **locals())
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    check_type_and_dtype(x, 'x', Variable,
                         ['float32', 'float64', 'int32', 'int64'],
                         'crop_tensor')
    check_type(shape, 'shape', (list, tuple, Variable), 'crop_tensor')
    check_type(offsets, 'offsets', (list, tuple, Variable, type(None)),
               'crop_tensor')
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    if offsets is None:
        offsets = [0] * len(x.shape)

    out = helper.create_variable_for_type_inference(x.dtype)
    ipts = {'X': x}
    attrs = {}

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    def _contain_var(input_list):
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        for ele in input_list:
            if isinstance(ele, Variable):
                return True
        return False

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    def _attr_shape_check(shape_val):
        if not isinstance(shape_val, int):
            raise TypeError(
                "Attr(shape)'s dtype of Op(crop_tensor) should be int32, but received: %s."
                % type(shape_val))
        if shape_val == 0:
            raise ValueError(
                "Attr(shape) of Op(crop_tensor) should not be zero, but received: %s."
                % str(shape_val))
        if shape_val < -1:
            raise ValueError(
                "When the element in Attr(shape) of Op(crop_tensor) is negative, only -1 is supported, but received: %s."
                % str(shape_val))

    def _attr_offsets_check(offset_val):
        if not isinstance(offset_val, int):
            raise TypeError(
                "Attr(offsets)'s dtype of Op(crop_tensor) should be int32, but received: %s."
                % type(offset_val))
        if offset_val < 0:
            raise ValueError(
                "Attr(offsets) of Op(crop_tensor) should be greater or equal to zero, but received: %s."
                % str(offset_val))

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    if isinstance(offsets, Variable):
        offsets.stop_gradient = True
        ipts['Offsets'] = offsets
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        attrs['offsets'] = [-1] * len(x.shape)
    elif _contain_var(offsets):
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        new_offsets_tensor = []
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        offsets_attr = []
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        for dim in offsets:
            if isinstance(dim, Variable):
                dim.stop_gradient = True
                new_offsets_tensor.append(dim)
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                offsets_attr.append(-1)
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            else:
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                _attr_offsets_check(dim)
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                temp_out = helper.create_variable_for_type_inference('int32')
                fill_constant([1], 'int32', dim, force_cpu=True, out=temp_out)
                new_offsets_tensor.append(temp_out)
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                offsets_attr.append(dim)
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        ipts['OffsetsTensor'] = new_offsets_tensor
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        attrs['offsets'] = offsets_attr
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    else:
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        for offset in offsets:
            _attr_offsets_check(offset)
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        attrs['offsets'] = offsets

    if isinstance(shape, Variable):
        shape.stop_gradient = True
        ipts['Shape'] = shape
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    elif _contain_var(shape):
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        new_shape_tensor = []
        shape_attr = []
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        for dim_size in shape:
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            if isinstance(dim_size, Variable):
                dim_size.stop_gradient = True
                new_shape_tensor.append(dim_size)
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                shape_attr.append(0)
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            else:
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                _attr_shape_check(dim_size)
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                temp_out = helper.create_variable_for_type_inference('int32')
                fill_constant(
                    [1], 'int32', dim_size, force_cpu=True, out=temp_out)
                new_shape_tensor.append(temp_out)
                shape_attr.append(dim_size)
        ipts['ShapeTensor'] = new_shape_tensor
        attrs['shape'] = shape_attr
    else:
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        for dim_size in shape:
            _attr_shape_check(dim_size)
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        attrs['shape'] = shape

    helper.append_op(
        type='crop_tensor',
        inputs=ipts,
        outputs={'Out': out},
        attrs=None if len(attrs) == 0 else attrs)
    return out


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def affine_grid(theta, out_shape, name=None):
    """
    It generates a grid of (x,y) coordinates using the parameters of
    the affine transformation that correspond to a set of points where
    the input feature map should be sampled to produce the transformed
    output feature map.

    Args:
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        theta (Variable) - A Tensor with shape [N, 2, 3]. It contains a batch of affine transform parameters.
                           The data type can be float32 or float64.
        out_shape (Variable | list | tuple): The shape of target output with format [batch_size, channel, height, width].
                                             ``out_shape`` can be a Tensor or a list or tuple. The data
                                             type must be int32.
        name(str|None): The default value is None.  Normally there is no need for user to set this property.  For more information, please refer to :ref:`api_guide_Name`.
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    Returns:
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        Variable: A Tensor with shape [batch_size, H, W, 2] while 'H' and 'W' are the height and width of feature map in affine transformation. The data type is the same as `theta`. 
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    Raises:
        ValueError: If the type of arguments is not supported.

    Examples:

        .. code-block:: python
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            import paddle.fluid as fluid
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            import numpy as np
            place = fluid.CPUPlace()
            theta = fluid.data(name="x", shape=[None, 2, 3], dtype="float32")
            out_shape = fluid.data(name="y", shape=[4], dtype="int32")
            grid_0 = fluid.layers.affine_grid(theta, out_shape)
            grid_1 = fluid.layers.affine_grid(theta, [5, 3, 28, 28])
            batch_size=2
            exe = fluid.Executor(place)
            exe.run(fluid.default_startup_program())
            output= exe.run(feed={"x": np.random.rand(batch_size,2,3).astype("float32"),
                                  "y": np.array([5, 3, 28, 28]).astype("int32")},
                                  fetch_list=[grid_0.name, grid_1.name])
            print(output[0])
            print(output[1])
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    """
    helper = LayerHelper('affine_grid')

    if not (isinstance(out_shape, list) or isinstance(out_shape, tuple) or \
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            isinstance(out_shape, Variable)):
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        raise ValueError("The out_shape should be a list, tuple or Variable.")

    if not isinstance(theta, Variable):
        raise ValueError("The theta should be a Variable.")

    out = helper.create_variable_for_type_inference(theta.dtype)
    ipts = {'Theta': theta}
    attrs = {}
    if isinstance(out_shape, Variable):
        ipts['OutputShape'] = out_shape
    else:
        attrs['output_shape'] = out_shape

    helper.append_op(
        type='affine_grid',
        inputs=ipts,
        outputs={'Output': out},
        attrs=None if len(attrs) == 0 else attrs)
    return out


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def pad2d(input,
          paddings=[0, 0, 0, 0],
          mode='constant',
          pad_value=0.0,
          data_format="NCHW",
          name=None):
    """
    Pad 2-d images accordding to 'paddings' and 'mode'.
    If mode is 'reflect', paddings[0] and paddings[1] must be no greater
    than height-1. And the width dimension has the same condition.

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    Parameters:
        input (Variable): The input image with [N, C, H, W] format or [N, H, W, C] format, which is a 4-D Tensor with data type float32.
        paddings (Variable | List[int32]): The padding size. If padding is a List, it must
            contain four integers, (padding_top, padding_bottom, padding_left, padding_right).
            Otherwise, it is a 1-D Tensor with shape [4]. Data type is int32.
            Default is [0, 0, 0, 0].
        mode (str): Three modes: 'constant' (default), 'reflect', 'edge' .
        	When in 'constant' mode, this op uses a constant value to pad the input tensor.
        	When in 'reflect' mode, uses reflection of the input boundaries to pad the input tensor.
        	When in 'edge' mode, uses input boundaries to pad the input tensor.
        	Default is 'constant'
        pad_value (float32): The value to fill the padded areas in 'constant' mode . Default is 0.0
        data_format (str): An string from: "NHWC", "NCHW". Specify the data format of
                           the input data.
                           Default is  "NCHW"
        name (str, optional) : The default value is None.  Normally there is no need for
                    user to set this property.  For more information, please refer to :ref:`api_guide_Name` .

    Returns: a 4-D Tensor padded accordding to paddings and mode and data type is same as input.

    Return Type: Variable


    Examples:
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        .. code-block:: text
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	      Given that X is a channel of image from input:
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	      X = [[1, 2, 3],
		   [4, 5, 6]]
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	      Case 0:
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		paddings = [0, 1, 2, 3],
		mode = 'constant'
		pad_value = 0
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		Out = [[0, 0, 1, 2, 3, 0, 0, 0]
		       [0, 0, 4, 5, 6, 0, 0, 0]
		       [0, 0, 0, 0, 0, 0, 0, 0]]
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	      Case 1:
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		paddings = [0, 1, 2, 1],
		mode = 'reflect'
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		Out = [[3, 2, 1, 2, 3, 2]
		       [6, 5, 4, 5, 6, 5]
		       [3, 2, 1, 2, 3, 2]]
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	      Case 2:
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		paddings = [0, 1, 2, 1],
		mode = 'edge'
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		Out = [[1, 1, 1, 2, 3, 3]
		       [4, 4, 4, 5, 6, 6]
		       [4, 4, 4, 5, 6, 6]]
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    Code Examples:
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        .. code-block:: python

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          import paddle.fluid as fluid
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          data = fluid.data(name='data', shape=[None, 3, 32, 32],
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                                   dtype='float32')
          result = fluid.layers.pad2d(input=data, paddings=[1, 2, 3, 4],
                                      mode='reflect')
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    """

    helper = LayerHelper('pad2d', **locals())
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    assert mode in ['reflect', 'edge', 'constant'
                    ], "mode should be one of constant, reflect, edge."

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    dtype = helper.input_dtype(input_param_name='input')
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    out = helper.create_variable_for_type_inference(dtype)
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    inputs = {'X': input}
    attrs = {'mode': mode, 'pad_value': pad_value, 'data_format': data_format}

    if isinstance(paddings, Variable):
        inputs['Paddings'] = paddings
        attrs['paddings'] = []
    else:
        attrs['paddings'] = paddings

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    helper.append_op(
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        type='pad2d', inputs=inputs, outputs={"Out": out}, attrs=attrs)
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    return out


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@templatedoc()
def elu(x, alpha=1.0, name=None):
    """
    ${comment}
    Args:
        x(${x_type}): ${x_comment}
        alpha(${alpha_type}|1.0): ${alpha_comment}
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        name(str|None): The default value is None. Normally there is no need for user to set this property. 
                        For more information, please refer to :ref:`api_guide_Name`.
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    Returns:
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        ${out_type}: ${out_comment}
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    Examples:

        .. code-block:: python

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            import paddle.fluid as fluid
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            import numpy as np
         
            input_elu = np.array([[-1,6],[1,15.6]])
            with fluid.dygraph.guard():
                x = fluid.dygraph.to_variable(input_elu)
                y = fluid.layers.elu(x, alpha=0.2)
                print(y.numpy())
                # [[-0.12642411  6.        ]
                # [ 1.          15.6       ]]
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    """
    helper = LayerHelper('elu', **locals())
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    check_type_and_dtype(x, 'x', Variable, ['float16', 'float32', 'float64'],
                         'elu')
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    out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    helper.append_op(
        type='elu',
        inputs={'X': x},
        outputs={'Out': out},
        attrs={'alpha': alpha})
    return out


@templatedoc()
def relu6(x, threshold=6.0, name=None):
    """
    ${comment}
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    Args:
        x(${x_type}): ${x_comment}
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        threshold(float, optional): ${threshold_comment}
        name(str, optional): The default value is None. Normally there is no
            need for user to set this property. For more information, please
            refer to :ref:`api_guide_Name`.
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    Returns:
        output(${out_type}): ${out_comment}
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    Examples:

        .. code-block:: python

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            import paddle.fluid as fluid
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            import numpy as np
            in1 = np.array([[-1,0],[2.5,7.8]])
            with fluid.dygraph.guard():
                x1 = fluid.dygraph.to_variable(in1)
                out1 = fluid.layers.relu6(x=x1, threshold=6.0)
                print(out1.numpy())
                # [[0.  0. ]
                #  [2.5 6. ]]
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    """
    helper = LayerHelper('relu6', **locals())
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    out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    helper.append_op(
        type='relu6',
        inputs={'X': x},
        outputs={'Out': out},
        attrs={'threshold': threshold})
    return out


@templatedoc()
def pow(x, factor=1.0, name=None):
    """
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    This is Pow Activation Operator.

    :math:`out = x^{factor}`

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    Args:
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        x(Variable): A ``Tensor`` or ``LoDTensor`` . The data type is ``float32`` or ``float64``.
        factor(float32|Variable, optional): A scalar with type ``float32`` or a ``Tensor`` with shape [1] and type ``float32``.  The exponential factor of Pow. Default 1.0.
        name(str, optional): The default value is None. Normally there is no need for user to set this property. For more information, please refer to :ref:`api_guide_Name` .
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    Returns:
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        Variable: A ``Tensor`` or ``LoDTensor``. The data type is same as ``x``.
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    Examples:

        .. code-block:: python

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            import paddle.fluid as fluid
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            x = fluid.data(name="x", shape=[32,32], dtype="float32")
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            # example 1: argument factor is float
            y_1 = fluid.layers.pow(x, factor=2.0)
8585
            # y_1 is x^{2.0}
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            # example 2: argument factor is Variable
            factor_tensor = fluid.layers.fill_constant([1], "float32", 3.0)
            y_2 = fluid.layers.pow(x, factor=factor_tensor)
8590
            # y_2 is x^{3.0}
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    """
    helper = LayerHelper('pow', **locals())
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    inputs = {'X': x}
    attrs = {}
    if isinstance(factor, Variable):
        factor.stop_gradient = True
        inputs['FactorTensor'] = factor
    else:
        attrs['factor'] = factor

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    out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    helper.append_op(
8603
        type='pow', inputs=inputs, outputs={'Out': out}, attrs=attrs)
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    return out


@templatedoc()
8608
def stanh(x, scale_a=0.67, scale_b=1.7159, name=None):
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    """
    ${comment}
    Args:
        x(${x_type}): ${x_comment}
        scale_a(${scale_a_type}|2.0 / 3.0): ${scale_a_comment}
        scale_b(${scale_b_type}|1.7159): ${scale_b_comment}
        name(str|None): A name for this layer(optional). If set None, the layer
                        will be named automatically.

    Returns:
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        output(${out_type}): ${out_comment}. 
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    Examples:

        .. code-block:: python

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            import paddle.fluid as fluid
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            import numpy as np
            data = fluid.data(name="input", shape=[-1, 3])
            result = fluid.layers.stanh(data,scale_a=0.67, scale_b=1.72)
            place = fluid.CPUPlace()
            exe = fluid.Executor(place)
            exe.run(fluid.default_startup_program())
            x = np.random.random(size=(3, 3)).astype('float32')
            output= exe.run(feed={"input": x},
                         fetch_list=[result])
            print(output)

            #[array([[0.626466  , 0.89842904, 0.7501062 ],
            #       [0.25147712, 0.7484996 , 0.22902708],
            #       [0.62705994, 0.23110689, 0.56902856]], dtype=float32)]

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    """
    helper = LayerHelper('stanh', **locals())
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    out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    helper.append_op(
        type='stanh',
        inputs={'X': x},
        outputs={'Out': out},
        attrs={'scale_a': scale_a,
               'scale_b': scale_b})
    return out


@templatedoc()
def hard_sigmoid(x, slope=0.2, offset=0.5, name=None):
    """
    ${comment}
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    Parameters:
        x (${x_type}): ${x_comment}
        slope (float, optional): ${slope_comment}
        offset (float, optional): ${offset_comment}
        name (str, optional): The default value is None. Normally there is no
            need for user to set this property. For more information, please
            refer to :ref:`api_guide_Name`
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    Returns:
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        ${out_type}: ${out_comment}
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    Examples:

        .. code-block:: python

8672
            import paddle.fluid as fluid
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            data = fluid.layers.fill_constant(shape=[3, 2], value=0.5, dtype='float32') # [[0.5, 0.5], [0.5, 0.5], [0.5, 0.5]]
            result = fluid.layers.hard_sigmoid(data) # [[0.6, 0.6], [0.6, 0.6], [0.6, 0.6]]
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    """
    helper = LayerHelper('hard_sigmoid', **locals())
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    out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    helper.append_op(
        type='hard_sigmoid',
        inputs={'X': x},
        outputs={'Out': out},
        attrs={'slope': slope,
               'offset': offset})
    return out


@templatedoc()
def swish(x, beta=1.0, name=None):
    """
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    Elementwise swish activation function. See `Searching for Activation Functions <https://arxiv.org/abs/1710.05941>`_ for more details.
    
    Equation:

    .. math::
        out = \\frac{x}{1 + e^{- beta * x}}
    
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    Args:
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        x(Variable): Tensor or LoDTensor, dtype: float32 or float64, the input of swish activation.
        
        beta(float): Constant beta of swish operator, default 1.0.
        
        name(str, optional): The default value is None. Normally there is no need for user to set this property. For more information, please refer to :ref:`api_guide_Name`.
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    Returns:
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        Variable: Output of the swish activation, Tensor or LoDTensor, with the same dtype and shape with the input x.
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    Examples:

        .. code-block:: python
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            # declarative mode
            import numpy as np
            from paddle import fluid
            
            x = fluid.data(name="x", shape=(-1, 3), dtype="float32")
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            y = fluid.layers.swish(x, beta=2.0)
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            place = fluid.CPUPlace()
            exe = fluid.Executor(place)
            start = fluid.default_startup_program()
            main = fluid.default_main_program()
            
            data = np.random.randn(2, 3).astype("float32")
            exe.run(start)
            y_np, = exe.run(main, feed={"x": data}, fetch_list=[y])
            
            data
            # array([[-1.1239197 ,  1.3391294 ,  0.03921051],
            #        [ 1.1970421 ,  0.02440812,  1.2055548 ]], dtype=float32)
            y_np
            # array([[-0.2756806 ,  1.0610548 ,  0.01998957],
            #        [ 0.9193261 ,  0.01235299,  0.9276883 ]], dtype=float32)


        .. code-block:: python

            # imperative mode
            import numpy as np
            from paddle import fluid
            import paddle.fluid.dygraph as dg
            
            data = np.random.randn(2, 3).astype("float32")
            place = fluid.CPUPlace()
            with dg.guard(place) as g:
                x = dg.to_variable(data)
                y = fluid.layers.swish(x)
                y_np = y.numpy()
            data
            # array([[-0.0816701 ,  1.1603649 , -0.88325626],
            #        [ 0.7522361 ,  1.0978601 ,  0.12987892]], dtype=float32)
            y_np
            # array([[-0.03916847,  0.8835007 , -0.25835553],
            #        [ 0.51126915,  0.82324016,  0.06915068]], dtype=float32)
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    """
    helper = LayerHelper('swish', **locals())
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    out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    helper.append_op(
        type='swish',
        inputs={'X': x},
        outputs={'Out': out},
        attrs={'slope': beta})
    return out


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def prelu(x, mode, param_attr=None, name=None):
    """
    Equation:

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    .. math::
        y = \max(0, x) + \\alpha * \min(0, x)
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    There are three modes for the activation:

    .. code-block:: text

        all: All elements share same alpha.
        channel: Elements in same channel share same alpha.
        element: All elements do not share alpha. Each element has its own alpha.

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    Args:
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        x (Variable): The input Tensor or LoDTensor with data type float32.
        mode (str): The mode for weight sharing. 
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        param_attr(ParamAttr|None): The parameter attribute for the learnable
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          weight (alpha), it can be create by ParamAttr. None by default.
          For detailed information, please refer to :ref:`api_fluid_ParamAttr`.
        name(str|None): For detailed information, please refer 
          to :ref:`api_guide_Name`. Usually name is no need to set and 
          None by default. 
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    Returns:
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        Variable:

        output(Variable): The tensor or LoDTensor with the same shape as input.
        The data type is float32.
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    Examples:

        .. code-block:: python

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            import paddle.fluid as fluid
            from paddle.fluid.param_attr import ParamAttr
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            x = fluid.data(name="x", shape=[None,5,10,10], dtype="float32")
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            mode = 'channel'
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            output = fluid.layers.prelu(
                     x,mode,param_attr=ParamAttr(name='alpha'))

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    """
    helper = LayerHelper('prelu', **locals())
    if mode not in ['all', 'channel', 'element']:
        raise ValueError('mode should be one of all, channel, element.')
    alpha_shape = [1]
    if mode == 'channel':
        alpha_shape = [1, x.shape[1], 1, 1]
    elif mode == 'element':
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        alpha_shape = [1, x.shape[1], x.shape[2], x.shape[3]]
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    dtype = helper.input_dtype(input_param_name='x')
    alpha = helper.create_parameter(
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        attr=helper.param_attr,
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        shape=alpha_shape,
        dtype='float32',
        is_bias=False,
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        default_initializer=Constant(0.25))
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    out = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
        type="prelu",
        inputs={"X": x,
                'Alpha': alpha},
        attrs={"mode": mode},
        outputs={"Out": out})
    return out


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@templatedoc()
def brelu(x, t_min=0.0, t_max=24.0, name=None):
    """
    ${comment}
    Args:
        x(${x_type}): ${x_comment}
        t_min(${t_min_type}|0.0): ${t_min_comment}
        t_max(${t_max_type}|24.0): ${t_max_comment}
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        name(str|None): The default value is None. Normally there is no need for user to set this property. 
                        For more information, please refer to :ref:`api_guide_Name`.
8844
    Returns:
8845
        ${out_type}: ${out_comment}
8846 8847 8848

    Examples:

8849
    .. code-block:: python
8850

8851
            import paddle.fluid as fluid
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            import numpy as np
            
            input_brelu = np.array([[-1,6],[1,15.6]])
            with fluid.dygraph.guard():
                x = fluid.dygraph.to_variable(input_brelu)
                y = fluid.layers.brelu(x, t_min=1.0, t_max=10.0)
                print(y.numpy())
                #[[ 1.  6.]
                #[ 1. 10.]] 
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    """
    helper = LayerHelper('brelu', **locals())
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    out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    helper.append_op(
        type='brelu',
        inputs={'X': x},
        outputs={'Out': out},
        attrs={'t_min': t_min,
               't_max': t_max})
    return out


@templatedoc()
def leaky_relu(x, alpha=0.02, name=None):
    """
    ${comment}
    Args:
        x(${x_type}): ${x_comment}
        alpha(${alpha_type}|0.02): ${alpha_comment}
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        name(str|None): The default value is None. Normally there is no need for user to set this property. For more information, please refer to :ref:`api_guide_Name`

8882
    Returns:
8883
        output(${out_type}): ${out_comment}
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    Examples:

        .. code-block:: python

8889
            import paddle.fluid as fluid
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            import numpy as np

            # Graph Organizing
            x = fluid.layers.data(name="x", shape=[2], dtype="float32")
            res = fluid.layers.leaky_relu(x, alpha=0.1)

            # Create an executor using CPU as an example
            exe = fluid.Executor(fluid.CPUPlace())

            # Execute
            x_i = np.array([[-1, 2], [3, -4]]).astype(np.float32)
            res_val, = exe.run(fluid.default_main_program(), feed={'x':x_i}, fetch_list=[res])
            print(res_val) # [[-0.1, 2], [3, -0.4]]
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    """
    helper = LayerHelper('leaky_relu', **locals())
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    out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    helper.append_op(
        type='leaky_relu',
        inputs={'X': x},
        outputs={'Out': out},
        attrs={'alpha': alpha})
    return out


def soft_relu(x, threshold=40.0, name=None):
    """
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    SoftRelu Activation Operator.

    $out = \ln(1 + \exp(\max(\min(x, threshold), -threshold)))$

8920
    Args:
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        x(Variable): Input of soft_relu operator. Data type can be float32, float64.
        threshold(float, optional): The threshold value of soft_relu, default value being 40.0.
        name(str, optional): The default value is None.  Normally there is no need for user to set this property.  For more information, please refer to :ref:`api_guide_Name` .

8925
    Returns:
8926
        Variable(Tensor|LoDTensor)): Output of soft_relu operator, shape and LoD same as input.
8927 8928 8929

    Examples:

8930 8931 8932
        .. code-block:: python 
 
            import paddle.fluid as fluid
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            import numpy as np

            inputs = fluid.layers.data(name="x", shape=[2, 2], dtype="float32")
            output = fluid.layers.soft_relu(inputs, threshold=20.0)

            exe = fluid.Executor(fluid.CPUPlace())
            exe.run(fluid.default_startup_program())

            img = np.array([[0, 1],[2, 3]]).astype(np.float32)

            res = exe.run(fluid.default_main_program(), feed={'x':img}, fetch_list=[output])
            print(res) # [array([[0.6931472, 1.3132616], [2.126928 , 3.0485873]], dtype=float32)]
8945 8946
    """
    helper = LayerHelper('soft_relu', **locals())
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    out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    helper.append_op(
        type='soft_relu',
        inputs={'X': x},
        outputs={'Out': out},
        attrs={'threshold': threshold})
    return out


8956 8957
def flatten(x, axis=1, name=None):
    """
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    **Flatten op**

    Flatten the input tensor into a 2D matrix.
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    For Example:
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    .. code-block:: text
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        Case 1:

          Given
            X.shape = (3, 100, 100, 4)

          and
            axis = 2

          We get:
            Out.shape = (3 * 100, 4 * 100)

        Case 2:

          Given
            X.shape = (3, 100, 100, 4)

          and
            axis = 0

          We get:
            Out.shape = (1, 3 * 100 * 100 * 4)
8987 8988

    Args:
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        x (Variable): A tensor of rank >= axis. A tensor with type float32,
                      float64, int8, int32, int64.
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        axis (int): Indicate up to which input dimensions (exclusive) should
                    be flattened to the outer dimension of the output.
8993
                    The value for axis must be in the range [0, R], where R
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                    is the rank of the input tensor. Default: 1.
        name(str, Optional): For details, please refer to :ref:`api_guide_Name`.
                        Generally, no setting is required. Default: None.
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    Returns:
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        Variable: A 2D tensor with the contents of the input tensor, with input \
                  dimensions up to axis flattened to the outer dimension of \
                  the output and remaining input dimensions flattened into the \
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                  inner dimension of the output. A Tensor with type same as input x.
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    Raises:
        ValueError: If x is not a variable.
9006
        ValueError: If axis is not in range [0, rank(x)].
9007 9008 9009 9010 9011

    Examples:

        .. code-block:: python

9012
            import paddle.fluid as fluid
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            x = fluid.data(name="x", shape=[4, 4, 3], dtype="float32")
9014
            # x shape is [4, 4, 3]
9015
            out = fluid.layers.flatten(x=x, axis=2)
9016
            # out shape is [16, 3]
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    """
    helper = LayerHelper('flatten', **locals())

    if not (isinstance(x, Variable)):
        raise ValueError("The input x should be a Variable")

    if not (isinstance(axis, int)) or axis > len(x.shape) or axis < 0:
        raise ValueError("The axis should be a int, and in range [0, rank(x)]")

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    out = helper.create_variable_for_type_inference(x.dtype)
    x_shape = helper.create_variable_for_type_inference(x.dtype)
9028
    helper.append_op(
9029
        type='flatten2',
9030
        inputs={"X": x},
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        outputs={'Out': out,
                 'XShape': x_shape},
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        attrs={"axis": axis})
    return out
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def stack(x, axis=0):
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    """
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    This OP stacks all the inputs :code:`x` along axis.
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    .. code-block:: text

        Case 1:
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          Input:
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            x[0].shape = [1, 2]
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            x[0].data = [ [1.0 , 2.0 ] ]
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            x[1].shape = [1, 2]
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            x[1].data = [ [3.0 , 4.0 ] ]
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            x[2].shape = [1, 2]
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            x[2].data = [ [5.0 , 6.0 ] ]

          Attrs:
            axis = 0

          Output:
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            Out.dims = [3, 1, 2]
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            Out.data =[ [ [1.0, 2.0] ],
                        [ [3.0, 4.0] ],
                        [ [5.0, 6.0] ] ]
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        Case 2:
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          Input:
            x[0].shape = [1, 2]
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            x[0].data = [ [1.0 , 2.0 ] ]
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            x[1].shape = [1, 2]
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            x[1].data = [ [3.0 , 4.0 ] ]
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            x[2].shape = [1, 2]
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            x[2].data = [ [5.0 , 6.0 ] ]
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          Attrs:
            axis = 1 or axis = -2

          Output:
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            Out.shape = [1, 3, 2]
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            Out.data =[ [ [1.0, 2.0]
                          [3.0, 4.0]
                          [5.0, 6.0] ] ]
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    Args:
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        x (Variable|list(Variable)): Input :code:`x` can be a single Tensor, a :code:`list` of Tensors.
                                     If :code:`x` is a :code:`list`, the shapes of all these Tensors
                                     must be the same. Supposing input is N dims
                                     Tensors :math:`[d_0, d_1, ..., d_{n-1}]`, the output is N+1 dims
                                     Tensor :math:`[d_0, d_1, d_{axis-1}, len(x), d_{axis}, ..., d_{n-1}]`.
                                     Support data types: float32, float64, int32, int64.
        axis (int, optional): The axis along which all inputs are stacked. ``axis`` range is :math:`[-(R+1), R+1)`.
                              R is the first tensor of inputs. If ``axis`` < 0, :math:`axis=axis+rank(x[0])+1`.
                              The default value of axis is 0.
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    Returns:
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        Variable: The stacked Tensor, has same data type with input Tensors. Output dim is :math:`rank(x[0])+1`.
9099

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    Examples:
        .. code-block:: python

9103
            import paddle.fluid as fluid
9104
            import paddle.fluid.layers as layers
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            # set batch size=None
            x1 = fluid.data(name='x1', shape=[None, 1, 2], dtype='int32')
            x2 = fluid.data(name='x2', shape=[None, 1, 2], dtype='int32')
            # stack Tensor list
            data = layers.stack([x1,x2]) # stack according to axis 0, data.shape=[2, None, 1, 2]

            data = layers.stack([x1,x2], axis=1) # stack according to axis 1, data.shape=[None, 2, 1, 2]

            # stack single Tensor
            data = layers.stack(x1)  # stack according to axis 0, data.shape=[1, None, 1, 2]
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    """

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    helper = LayerHelper('stack', **locals())
    axis = 0 if axis is None else axis

    if not isinstance(x, list) and not isinstance(x, tuple):
        x = [x]

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    out = helper.create_variable_for_type_inference(x[0].dtype)
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    helper.append_op(
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        type='stack', inputs={'X': x}, outputs={'Y': out},
        attrs={'axis': axis})
9128

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    return out
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@templatedoc(op_type="filter_by_instag")
def filter_by_instag(ins, ins_tag, filter_tag, is_lod):
    """
    **Filter By Instag Layer**
   
    This function filter a batch of ins by instag, 
    There are multiple ins, and every ins belongs to some tags. 
    We can specify some tags we want. So the ins which belongs to that tags
    remains in the output, and others removed.
 
    For example, one batch has 4 ins. Every ins has its tag list. 
     
       | Ins   |   Ins_Tag |
       |:-----:|:------:|
       |  0    |   0, 1 |
       |  1    |   1, 3 |
       |  2    |   0, 3 |
       |  3    |   2, 6 |

    And Lod is [1,1,1,1]

    And the filter tags [1]

    From the definition above, ins which has tag 1 can pass the filter
    So Ins 0 and Ins 1 can pass and be seen in the output,
    Ins 2 and 3 cannot pass because they do not has tag 1.

    Actually, if is_lod is false, it is normal tensor that equals to 
    lod_tensor with all 1, similar to the example above.

    Args:
        ins (Variable): Input Variable (LoDTensor), usually it is 2D tensor
                        And first dimension can have lod info or not.
        ins_tag (Variable): Input Variable (LoDTensor), usually it is 1D list
                        And split them by lod info
        filter_tag (Variable): Input Variable (1D Tensor/List), usually it is 
                        list that holds the tags.
        is_lod (Bool): Boolean value to indicate ins is lod tensor or not.

    Returns:
        Variable: filtered ins (LoDTensor) and loss weight (Tensor)

    Examples:
        .. code-block:: python

          import paddle.fluid.layers as layers
          ins = layers.data(name='Ins', shape=[-1,32], lod_level=0, dtype='float64')
          ins_tag = layers.data(name='Ins_tag', shape=[-1,16], lod_level=0, dtype='int64')
          filter_tag = layers.data(name='Filter_tag', shape=[-1,16], dtype='int64')
          out, loss_weight = layers.filter_by_instag(ins,  ins_tag,  filter_tag, True)
        		
    """
    helper = LayerHelper('filter_by_instag', **locals())

    out = helper.create_variable_for_type_inference(dtype=ins.dtype)
    loss_weight = helper.create_variable_for_type_inference(dtype=np.float64)
    mmap = helper.create_variable_for_type_inference(dtype=ins_tag.dtype)
    helper.append_op(
        type='filter_by_instag',
        inputs={'Ins': ins,
                'Ins_tag': ins_tag,
                'Filter_tag': filter_tag},
        outputs={'Out': out,
                 'LossWeight': loss_weight,
                 'IndexMap': mmap},
        attrs={'is_lod': is_lod})

    return [out, loss_weight]


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def unstack(x, axis=0, num=None):
    """
    **UnStack Layer**

9206
    This layer unstacks input Tensor :code:`x` into several Tensors along :code:`axis`.
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    If :code:`axis` < 0, it would be replaced with :code:`axis+rank(x)`.
    If :code:`num` is None, it would be inferred from :code:`x.shape[axis]`,
    and if :code:`x.shape[axis]` <= 0 or is unknown, :code:`ValueError` is
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    raised.
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    Args:
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        x (Variable): Input Tensor. It is a N-D Tensors of data types float32, float64, int32, int64.
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        axis (int): The axis along which the input is unstacked.
        num (int|None): The number of output variables.
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    Returns:
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        list(Variable): The unstacked Tensors list. The list elements are N-D Tensors of data types float32, float64, int32, int64.

    Raises:
        ValueError: If x.shape[axis] <= 0 or axis is not in range [-D, D).
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    Examples:
        .. code-block:: python

            import paddle.fluid as fluid
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            x = fluid.layers.data(name='x', shape=[2, 3, 5], dtype='float32')  # create a tensor with shape=[2, 3, 5]
            y = fluid.layers.unstack(x, axis=1)  # unstack with second axis, which results 3 tensors with shape=[2, 5]
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9231
    """
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    helper = LayerHelper('unstack', **locals())
    if num is None:
        if axis is None or x.shape[axis] <= 0:
            raise ValueError('unknown unstack number')
        else:
            num = x.shape[axis]

    outs = []
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    for _ in range(num):
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        outs.append(helper.create_variable_for_type_inference(x.dtype))
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    helper.append_op(
        type='unstack',
        inputs={'X': [x]},
        outputs={'Y': outs},
        attrs={'axis': axis,
               'num': num})
    return outs
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def expand(x, expand_times, name=None):
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    """
    This operation tiles ``x`` multiple times according to the parameter ``expand_times``.
    The times number for each dimension of ``x`` is set by the parameter ``expand_times``.
    The rank of ``x`` should be less than or equal to 6. Please note that size of ``expand_times`` must be the same
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    with X's rank. Following is a using case:


    .. code-block:: text

        Input(X) is a 3-D tensor with shape [2, 3, 1]:
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                [
                   [[1], [2], [3]],
                   [[4], [5], [6]]
                ]
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        Attr(expand_times):  [1, 2, 2]
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        Output(Out) is a 3-D tensor with shape [2, 6, 2]:
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                [
                    [[1, 1], [2, 2], [3, 3], [1, 1], [2, 2], [3, 3]],
                    [[4, 4], [5, 5], [6, 6], [4, 4], [5, 5], [6, 6]]
                ]
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    Args:
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        x (Variable): A ``Tensor`` or ``LoDTensor`` with dimension in [1, 6]. The data type is ``bool``, ``float32``, ``float64`` or ``int32`` .
        expand_times (list|tuple|Variable): The data type is ``int32`` . If ``expand_times`` is a list or tuple, the elements of
                it should be integers or Tensors with shape [1]. If ``expand_times`` is an Variable, it should be an 1-D Tensor.
                Expand times number for each dimension of ``x`` .
        name (str, optional): The default value is None. Normally there is no need for user to set this property. For more information, please refer to :ref:`api_guide_Name` .
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    Returns:
9286
        Variable: A ``Tensor`` or ``LoDTensor``. The data type is same as ``x``. After expanding, size of each dimension of output is equal to the size of the corresponding dimension of ``x`` multiplying the corresponding value given by ``expand_times`` .
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    Raises:
        TypeError: The type of ``expand_times`` must be list, tuple or Variable.
        ValueError: The elements of ``expand_times`` cannot be negative.
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    Examples:
        .. code-block:: python
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            import paddle.fluid as fluid
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            # example 1:
            data_1 = fluid.layers.fill_constant(shape=[2, 3, 1], dtype='int32', value=0)
            expanded_1 = fluid.layers.expand(data_1, expand_times=[1, 2, 2])
9300
            # the shape of expanded_1 is [2, 6, 2].
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            # example 2:
            data_2 = fluid.layers.fill_constant(shape=[12, 14], dtype="int32", value=3)
            expand_times = fluid.layers.fill_constant(shape=[2], dtype="int32", value=4)
            expanded_2 = fluid.layers.expand(data_2, expand_times=expand_times)
9306
            # the shape of expanded_2 is [48, 56].
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    """
9308 9309 9310 9311
    check_type_and_dtype(x, 'x', Variable,
                         ['bool', 'float32', 'float64', 'int32', 'int64'],
                         'expand')
    check_type(expand_times, 'expand_times', (list, tuple, Variable), 'expand')
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    if convert_dtype(x.dtype) == 'bool' and x.stop_gradient == True:
        raise ValueError(
            "expand op bool date type must set the stop_gradient to be False")
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    helper = LayerHelper('expand', input=x, **locals())
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    inputs = {"X": x}
    attrs = {}

    def contain_var(expand_times):
        for ele in expand_times:
            if isinstance(ele, Variable):
                return True
        return False

    def get_attr_expand_times(list_expand_times):
        attrs_expand_times = []
        for idx, times in enumerate(list_expand_times):
            if isinstance(times, Variable):
                attrs_expand_times.append(-1)
            else:
                attrs_expand_times.append(times)
                assert times > 0, (
                    "Each element given in expand_times must not be negtive.")
        return attrs_expand_times

    def get_new_expand_times_tensor(list_expand_times):
        new_expand_times_tensor = []
        for ele in list_expand_times:
            if isinstance(ele, Variable):
                ele.stop_gradient = True
                new_expand_times_tensor.append(ele)
            else:
                assert (isinstance(ele, int))
                temp_out = helper.create_variable_for_type_inference('int32')
                fill_constant([1], 'int32', ele, force_cpu=True, out=temp_out)
                new_expand_times_tensor.append(temp_out)
        return new_expand_times_tensor
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    if in_dygraph_mode():
        inputs = {'X': x}
        attrs = {'expand_times': expand_times}
    else:
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        if isinstance(expand_times, Variable):
            expand_times.stop_gradient = True
            inputs['ExpandTimes'] = expand_times
        elif isinstance(expand_times, (list, tuple)):
            attrs['expand_times'] = get_attr_expand_times(expand_times)
            if contain_var(expand_times):
                inputs['expand_times_tensor'] = get_new_expand_times_tensor(
                    expand_times)
9362

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    dtype = helper.input_dtype(input_param_name='x')
    out = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
9366
        type='expand', inputs=inputs, outputs={'Out': out}, attrs=attrs)
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    return out
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def expand_as(x, target_tensor, name=None):
    """
    expand_as operator tiles to the input by given expand tensor. You should set expand tensor
    for each dimension by providing tensor 'target_tensor'. The rank of X
    should be in [1, 6]. Please note that size of 'target_tensor' must be the same
    with X's rank. Following is a using case:


    .. code-block:: text

        Input(X) is a 3-D tensor with shape [2, 3, 1]:

                [
                   [[1], [2], [3]],
                   [[4], [5], [6]]
                ]

        target_tensor's shape:  [2, 6, 2] 

        Output(Out) is a 3-D tensor with shape [2, 6, 2]:

                [
                    [[1, 1], [2, 2], [3, 3], [1, 1], [2, 2], [3, 3]],
                    [[4, 4], [5, 5], [6, 6], [4, 4], [5, 5], [6, 6]]
                ]
                

    Args:
        x (Variable): A Tensor with dtype float64, float32, int32.
        A tensor with rank in [1, 6].
        target_tensor (Variable): A Tensor with dtype float64, float32, int32.
        target_tensor for expanding to Input(X). Only use target_tensor'shape.

    Returns:
        Variable: A Tensor with dtype float64, float32, int32. 
        After expanding, size of each dimension of Output(Out) is equal to the size 
        of the corresponding dimension of target_tensor multiplying the corresponding
        value given by target_tensor.


    Examples:
        .. code-block:: python
          
        import paddle.fluid as fluid
        import numpy as np

        data = fluid.layers.data(name="data", shape=[-1,10], dtype='float64')
        target_tensor = fluid.layers.data(
          name="target_tensor", shape=[-1,20], dtype='float64')
        result = fluid.layers.expand_as(x=data, target_tensor=target_tensor) 
        use_cuda = False
        place = fluid.CUDAPlace(0) if use_cuda else fluid.CPUPlace()
        exe = fluid.Executor(place)
        exe.run(fluid.default_startup_program())
        x = np.random.rand(3,10)
        y = np.random.rand(3,20)
        output= exe.run(feed={"data":x,"target_tensor":y},fetch_list=[result.name])
        print(output[0].shape)
        #(3,20)

    """

    helper = LayerHelper('expand_as', input=x, **locals())
    dtype = helper.input_dtype(input_param_name='x')
    out = helper.create_variable_for_type_inference(dtype)
    inputs = {'X': x, 'target_tensor': target_tensor}
    helper.append_op(type='expand_as', inputs=inputs, outputs={'Out': out})
    return out


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from paddle.fluid.framework import convert_np_dtype_to_dtype_


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@templatedoc()
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def uniform_random_batch_size_like(input,
                                   shape,
                                   dtype='float32',
                                   input_dim_idx=0,
                                   output_dim_idx=0,
                                   min=-1.0,
                                   max=1.0,
                                   seed=0):
    """
9453 9454 9455 9456 9457 9458
    This OP initializes a variable with random values sampled from a
    uniform distribution in the range [min, max). The input_dim_idx used to get the input dimension value which will be used to resize the output dimension.

    .. code-block:: text

        *Case 1:
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            Given:
                input =[[0.946741  , 0.1357001 , 0.38086128]]    # input.shape=[1,3]
                shape=[2,4]

            result.shape[output_dim_idx] = input.shape[input_dim_idx],
            output_dim_idx = 0, 
            input_dim_idx = 0,
            result.shape[0] = input.shape[0], 
            then:
                result=[[ 0.3443427 , -0.23056602,  0.3477049 ,  0.06139076]]    # result.shape=[1,4]
            
       *Case 2:
           
           Given:
               input =[[0.946741  , 0.1357001 , 0.38086128]]     # input.shape=[1,3]
               shape=[2,4]
               input_dim_idx=1
               output_dim_idx=1
         
           result.shape[output_dim_idx] = input.shape[input_dim_idx],
           output_dim_idx = 1, 
           input_dim_idx = 1,
           result.shape[1] = input.shape[1], 
           then:
               result=[[-0.23133647, -0.84195036,  0.21441269],
                       [-0.08774924,  0.25605237, -0.09403259]]    # result.shape=[2,3]
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    Args:
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        input (Variable): A Tensor. Supported data types: float32, float64.
        shape (tuple|list): A python list or python tuple. The shape of the output Tensor, the data type is int.
        input_dim_idx (int, optional): An index used to get the input dimension value which will be used to resize the output dimension. Default  0. 
        output_dim_idx (int, optional): An index used to indicate the specific dimension that will be replaced by corresponding input dimension value. Default 0.
        min (float, optional): The lower bound on the range of random values to generate, the min is included in the range. Default -1.0.
        max (float, optional): The upper bound on the range of random values to generate, the max is excluded in the range. Default 1.0.
        seed (int, optional):  Random seed used for generating samples. 0 means use a seed generated by the system.Note that if seed is not 0, this operator will always generate the same random numbers every time.
        dtype(np.dtype|core.VarDesc.VarType|str, optional): The data type of output Tensor. Supported data types: float32, float64. Default float32.
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    Returns:
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        Variable: A Tensor of the specified shape filled with uniform_random values. The shape of the Tensor is determined by the shape parameter and the specified dimension of the input Tensor.
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    Examples:
        .. code-block:: python

9501
            import paddle.fluid as fluid
9502 9503 9504 9505
            
            # example 1: 
            input = fluid.data(name="input", shape=[1, 3], dtype='float32')
            out_1 = fluid.layers.uniform_random_batch_size_like(input, [2, 4]) # out_1.shape=[1, 4]
9506

9507 9508 9509 9510
            # example 2: 
            out_2 = fluid.layers.uniform_random_batch_size_like(input, [2, 4], input_dim_idx=1, output_dim_idx=1) # out_2.shape=[2, 3]

            
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    """

    helper = LayerHelper('uniform_random_batch_size_like', **locals())
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    out = helper.create_variable_for_type_inference(dtype)
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    c_dtype = convert_np_dtype_to_dtype_(dtype)
    helper.append_op(
        type='uniform_random_batch_size_like',
        inputs={'Input': input},
        outputs={'Out': out},
        attrs={
            'shape': shape,
            'input_dim_idx': input_dim_idx,
            'output_dim_idx': output_dim_idx,
            'min': min,
            'max': max,
            'seed': seed,
            'dtype': c_dtype
        })

    return out
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@templatedoc()
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def gaussian_random(shape, mean=0.0, std=1.0, seed=0, dtype='float32'):
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    """
9536
    Generate a random tensor whose data is drawn from a Gaussian distribution.
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    Args:
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        shape (Tuple[int] | List[int]): Shape of the generated random tensor.
        
        mean (float): Mean of the random tensor, defaults to 0.0.
            
        std (float): Standard deviation of the random tensor, defaults to 1.0.
        
        seed (int): ${seed_comment}
        
        dtype(np.dtype | core.VarDesc.VarType | str): Output data type, float32 or float64.
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    Returns:
9550
        Variable: Random tensor whose data is drawn from a Gaussian distribution, dtype: flaot32 or float64 as specified.
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9552
    Examples:
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       .. code-block:: python
       
           # declarative mode 
           import numpy as np
           from paddle import fluid
   
           x = fluid.layers.gaussian_random((2, 3), std=2., seed=10)
   
           place = fluid.CPUPlace()
           exe = fluid.Executor(place)
           start = fluid.default_startup_program()
           main = fluid.default_main_program()
   
           exe.run(start)
           x_np, = exe.run(main, feed={}, fetch_list=[x])
9568

9569 9570 9571 9572 9573 9574 9575 9576 9577 9578 9579 9580 9581 9582 9583 9584 9585 9586
           x_np
           # array([[2.3060477, 2.676496 , 3.9911983],
           #        [0.9990833, 2.8675377, 2.2279181]], dtype=float32)

       .. code-block:: python

           # imperative mode
           import numpy as np
           from paddle import fluid
           import paddle.fluid.dygraph as dg
    
           place = fluid.CPUPlace()
           with dg.guard(place) as g:
               x = fluid.layers.gaussian_random((2, 4), mean=2., dtype="float32", seed=10)
               x_np = x.numpy()       
           x_np
           # array([[2.3060477 , 2.676496  , 3.9911983 , 0.9990833 ],
           #        [2.8675377 , 2.2279181 , 0.79029655, 2.8447366 ]], dtype=float32)
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    """

    helper = LayerHelper('gaussian_random', **locals())
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    out = helper.create_variable_for_type_inference(dtype)
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    c_dtype = convert_np_dtype_to_dtype_(dtype)
    helper.append_op(
        type='gaussian_random',
        outputs={'Out': out},
        attrs={
            'shape': shape,
            'mean': mean,
            'std': std,
            'seed': seed,
            'dtype': c_dtype,
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            'use_mkldnn': False
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        })

    return out


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@templatedoc()
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def sampling_id(x, min=0.0, max=1.0, seed=0, dtype='float32'):
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    """
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    This op is used for sampling id from multinomial distribution from the input, sampling one id for one sample.
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    Parameters:
        x (Variable): 2-D tensor, [batch_size, input_feature_dimensions]
        min (Float): minimum , default 0.0.
        max (Float): maximum, default 1.0.
        seed (Float): Random seed, default 0. if seed is not 0, will generate same number every time. 
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        dtype(np.dtype|core.VarDesc.VarType|str): The type of output data : float32, float_16, int etc
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    Returns:
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        Variable: sampling tensor.
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    Examples:
        .. code-block:: python

9625
            import paddle.fluid as fluid
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            x = fluid.data(
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                name="X",
                shape=[13, 11],
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                dtype='float32')
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            out = fluid.layers.sampling_id(x)
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    """

    helper = LayerHelper('sampling_id', **locals())
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    out = helper.create_variable_for_type_inference(dtype)
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    helper.append_op(
        type='sampling_id',
        inputs={'X': x},
        outputs={'Out': out},
        attrs={'min': min,
               'max': max,
               'seed': seed})

    return out


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@templatedoc()
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def gaussian_random_batch_size_like(input,
                                    shape,
                                    input_dim_idx=0,
                                    output_dim_idx=0,
                                    mean=0.0,
                                    std=1.0,
                                    seed=0,
                                    dtype='float32'):
    """
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    ${comment}
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    Args:
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        input (Variable): ${input_comment}
        shape (tuple|list): ${shape_comment}
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        input_dim_idx (int): ${input_dim_idx_comment}
        output_dim_idx (int): ${output_dim_idx_comment}
        mean (float): ${mean_comment}
        std (float): ${std_comment}
        seed (int): ${seed_comment}
        dtype(np.dtype|core.VarDesc.VarType|str): The type of output data, float32 or float_64.
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    Returns:
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        out (Variable): ${out_comment}
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    Examples:
        .. code-block:: python

9675
            import paddle.fluid as fluid
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            input = fluid.data(name="input", shape=[13, 11], dtype='float32')
9677

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            out = fluid.layers.gaussian_random_batch_size_like(
9679
                input, shape=[-1, 11], mean=1.0, std=2.0)
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    """

    helper = LayerHelper('gaussian_random_batch_size_like', **locals())
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    out = helper.create_variable_for_type_inference(dtype)
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    c_dtype = convert_np_dtype_to_dtype_(dtype)
    helper.append_op(
        type='gaussian_random_batch_size_like',
        inputs={'Input': input},
        outputs={'Out': out},
        attrs={
            'shape': shape,
            'input_dim_idx': input_dim_idx,
            'output_dim_idx': output_dim_idx,
            'mean': mean,
            'std': std,
            'seed': seed,
            'dtype': c_dtype
        })

    return out


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@templatedoc()
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def sum(x):
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    """
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    ${comment}
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    Case 1:
    ::
        Input:
            Input. Shape = [2, 3]
            Input = [[1, 2, 3],
                     [4, 5, 6]]

        Output:
            The output. Shape = [2, 3]
            Output = [[1, 2, 3],
                      [4, 5, 6]]

    Case 2:
    ::
        Input:
            First input:
            Input1. Shape = [2, 3]
            Input1 = [[1, 2, 3],
                      [4, 5, 6]]

        The second input:
            Input2. Shape = [2, 3]
            Input2 = [[7, 8, 9],
                      [10, 11, 12]]

        Output:
            The output. Shape = [2, 3]
            Output = [[8, 10, 12],
                      [14, 16, 18]]
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    Args:
9738
        x (Variable|list(Variable)): ${x_comment}
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    Returns:
9741
        Variable: ${out_comment}
9742 9743 9744 9745

    Examples:
        .. code-block:: python

9746
            import paddle.fluid as fluid
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            input0 = fluid.layers.fill_constant(shape=[2, 3], dtype='int64', value=5)
            input1 = fluid.layers.fill_constant(shape=[2, 3], dtype='int64', value=3)
            sum = fluid.layers.sum([input0, input1])

            # You can print out 'sum' via executor.
            out = fluid.layers.Print(sum, message="the sum of input0 and input1: ")
            exe = fluid.Executor(fluid.CPUPlace())
            exe.run(fluid.default_main_program())

            # The printed result is:
            # 1570701754	the sum of input0 and input1: 	The place is:CPUPlace
            # Tensor[sum_0.tmp_0]
            #    shape: [2,3,]
            #    dtype: l
            #    data: 8,8,8,8,8,8,

            # the sum of input0 and input1 is 2-D Tensor with shape [2,3].
            # dtype is the corresponding C++ data type, which may vary in different environments.
            # Eg: if the data type of tensor is int64, then the corresponding C++ data type is int64_t, 
            #       so the dtype value is typeid(int64_t).Name(), which is 'x' on MacOS, 'l' on Linux, 
            #       and '__int64' on Windows. They both represent 64-bit integer variables.
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    """

    helper = LayerHelper('sum', **locals())
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    out = helper.create_variable_for_type_inference(
        dtype=helper.input_dtype('x'))
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    helper.append_op(
        type='sum',
        inputs={'X': x},
        outputs={'Out': out},
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        attrs={'use_mkldnn': False})
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    return out


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@templatedoc()
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def slice(input, axes, starts, ends):
    """
9786
    This operator produces a slice of ``input`` along multiple axes. Similar to numpy:
9787
    https://docs.scipy.org/doc/numpy/reference/arrays.indexing.html
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    Slice uses ``axes``, ``starts`` and ``ends`` attributes to specify the start and
    end dimension for each axis in the list of axes and Slice uses this information
    to slice the input data tensor. If a negative value is passed to
    ``starts`` or ``ends`` such as :math:`-i`,  it represents the reverse position of the
    axis :math:`i-1` (here 0 is the initial position).
    If the value passed to ``starts`` or ``ends`` is greater than n
    (the number of elements in this dimension), it represents n.
9795
    For slicing to the end of a dimension with unknown size, it is recommended
9796
    to pass in INT_MAX. The size of ``axes`` must be equal to ``starts`` and ``ends``.
9797 9798 9799
    Following examples will explain how slice works:

    .. code-block:: text
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        Case1:
            Given:
                data = [ [1, 2, 3, 4], [5, 6, 7, 8], ]
                axes = [0, 1]
                starts = [1, 0]
                ends = [2, 3]
            Then:
                result = [ [5, 6, 7], ]
9809

9810 9811 9812 9813 9814
        Case2:
            Given:
                data = [ [1, 2, 3, 4], [5, 6, 7, 8], ]
                axes = [0, 1]
                starts = [0, 1]
9815
                ends = [-1, 1000]       # -1 denotes the reverse 0th position of dimension 0.
9816
            Then:
9817
                result = [ [2, 3, 4], ] # result = data[0:1, 1:4]
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    Args:
9819 9820 9821 9822 9823 9824 9825 9826 9827
        input (Variable): A ``Tensor`` or ``LoDTensor`` . The data type is ``float16``, ``float32``, ``float64``, ``int32`` or ``int64``.
        axes (list|tuple): The data type is ``int32`` . Axes that `starts` and `ends` apply to.
                            It's optional. If it is not provides, it will be treated as :math:`[0,1,...,len(starts)-1]`.
        starts (list|tuple|Variable): The data type is ``int32`` . If ``starts`` is a list or tuple, the elements of
                it should be integers or Tensors with shape [1]. If ``starts`` is an Variable, it should be an 1-D Tensor.
                It represents starting indices of corresponding axis in ``axes``.
        ends (list|tuple|Variable): The data type is ``int32`` . If ``ends`` is a list or tuple, the elements of
                it should be integers or Tensors with shape [1]. If ``ends`` is an Variable, it should be an 1-D Tensor .
                It represents ending indices of corresponding axis in ``axes``.
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    Returns:
9830 9831 9832 9833 9834
        Variable:  A ``Tensor`` or ``LoDTensor``. The data type is same as ``input``.

    Raises:
        TypeError: The type of ``starts`` must be list, tuple or Variable.
        TypeError: The type of ``ends`` must be list, tuple or Variable.
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9836 9837 9838
    Examples:
        .. code-block:: python

9839
            import paddle.fluid as fluid
9840

9841 9842
            input = fluid.data(
                name="input", shape=[4, 5, 6], dtype='float32')
9843

9844 9845 9846 9847 9848 9849
            # example 1:
            # attr starts is a list which doesn't contain tensor Variable.
            axes = [0, 1, 2]
            starts = [-3, 0, 2]
            ends = [3, 2, 4]
            sliced_1 = fluid.layers.slice(input, axes=axes, starts=starts, ends=ends)
9850
            # sliced_1 is input[0:3, 0:2, 2:4].
9851 9852 9853 9854 9855

            # example 2:
            # attr starts is a list which contain tensor Variable.
            minus_3 = fluid.layers.fill_constant([1], "int32", -3)
            sliced_2 = fluid.layers.slice(input, axes=axes, starts=[minus_3, 0, 2], ends=ends)
9856
            # sliced_2 is input[0:3, 0:2, 2:4].
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    """

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    def contain_var(one_list):
        for ele in one_list:
            if isinstance(ele, Variable):
                return True
        return False

    if in_dygraph_mode():
        infer_flags = list(1 for i in range(len(axes)))
        inputs = {'Input': [input]}

        if isinstance(starts, (list, tuple)):
            if contain_var(starts):
                raise TypeError(
                    "The type of 'starts' in slice must be list[int] or tuple(int) in Dygraph mode, but "
                    "received %s, which contains Variable." % type(shape))
        else:
            raise TypeError(
                "The type of 'starts' in slice must be list[int] or tuple(int) in Dygraph mode, but "
                "received %s." % type(shape))

        if isinstance(ends, (list, tuple)):
            if contain_var(ends):
                raise TypeError(
                    "The type of 'ends' in slice must be list[int] or tuple(int) in Dygraph mode, but "
                    "received %s, which contains Variable." % type(shape))
        else:
            raise TypeError(
                "The type of 'ends' in slice must be list[int] or tuple(int) in Dygraph mode, but "
                "received %s." % type(shape))

        attrs = {
            'axes': axes,
            'starts': starts,
            'ends': ends,
            'infer_flags': infer_flags
        }
        outs = core.ops.slice(inputs, attrs)
        return outs['Out'][0]

9898 9899 9900 9901 9902 9903 9904
    if not isinstance(starts, (list, tuple, Variable)):
        raise ValueError(
            "Input starts must be an Variable, python list or tuple.")
    if not isinstance(ends, (list, tuple, Variable)):
        raise ValueError(
            "Input ends must be an Variable, python list or tuple.")

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    helper = LayerHelper('slice', **locals())
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    def get_new_list_tensor(old_list):
        new_list_tensor = []
        for dim in old_list:
            if isinstance(dim, Variable):
                dim.stop_gradient = True
                new_list_tensor.append(dim)
            else:
                assert (isinstance(dim, int))
                temp_out = helper.create_variable_for_type_inference('int32')
                fill_constant([1], 'int32', dim, force_cpu=True, out=temp_out)
                new_list_tensor.append(temp_out)
        return new_list_tensor

    inputs = {'Input': input}
    attrs = {'axes': axes}
    infer_flags = list(1 for i in range(len(axes)))

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    # starts
    if isinstance(starts, Variable):
        starts.stop_gradient = True
        inputs['StartsTensor'] = starts
        infer_flags = list(-1 for i in range(len(axes)))
    elif isinstance(starts, (list, tuple)):
        attrs['starts'] = []
        if not contain_var(starts):
            attrs['starts'] = starts
        else:
            inputs['StartsTensorList'] = get_new_list_tensor(starts)
            for i, dim in enumerate(starts):
                if isinstance(dim, Variable):
                    attrs['starts'].append(-1)
                    infer_flags[i] = -1
                else:
                    attrs['starts'].append(dim)

    # ends
    if isinstance(ends, Variable):
        ends.stop_gradient = True
        inputs['EndsTensor'] = ends
        infer_flags = list(-1 for i in range(len(axes)))
    elif isinstance(ends, (list, tuple)):
        attrs['ends'] = []
        if not contain_var(ends):
            attrs['ends'] = ends
        else:
            inputs['EndsTensorList'] = get_new_list_tensor(ends)
            for i, dim in enumerate(ends):
                if isinstance(dim, Variable):
                    attrs['ends'].append(-1)
                    infer_flags[i] = -1
                else:
                    attrs['ends'].append(dim)
    # infer_flags
    attrs['infer_flags'] = infer_flags
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    out = helper.create_variable_for_type_inference(
        dtype=helper.input_dtype('input'))
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    helper.append_op(
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        type='slice', inputs=inputs, attrs=attrs, outputs={'Out': out})
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    return out


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@templatedoc()
def strided_slice(input, axes, starts, ends, strides):
    """
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    This operator produces a slice of ``input`` along multiple axes. Similar to numpy:
    https://docs.scipy.org/doc/numpy/reference/arrays.indexing.html
    Slice uses ``axes``, ``starts`` and ``ends`` attributes to specify the start and
    end dimension for each axis in the list of axes and Slice uses this information
    to slice the input data tensor. If a negative value is passed to
    ``starts`` or ``ends`` such as :math:`-i`,  it represents the reverse position of the
    axis :math:`i-1` th(here 0 is the initial position). The ``strides`` represents steps of
    slicing and if the ``strides`` is negative, slice operation is in the opposite direction.
    If the value passed to ``starts`` or ``ends`` is greater than n
    (the number of elements in this dimension), it represents n.
    For slicing to the end of a dimension with unknown size, it is recommended
    to pass in INT_MAX. The size of ``axes`` must be equal to ``starts`` , ``ends`` and ``strides``.
    Following examples will explain how strided_slice works:
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    .. code-block:: text

        Case1:
            Given:
                data = [ [1, 2, 3, 4], [5, 6, 7, 8], ]
                axes = [0, 1]
                starts = [1, 0]
                ends = [2, 3]
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                strides = [1, 1]
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            Then:
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                result = [ [5, 6, 7], ]
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        Case2:
            Given:
                data = [ [1, 2, 3, 4], [5, 6, 7, 8], ]
                axes = [0, 1]
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                starts = [0, 1]
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                ends = [2, 0]
                strides = [1, -1]
            Then:
                result = [ [8, 7, 6], ]
        
        Case3:
            Given:
                data = [ [1, 2, 3, 4], [5, 6, 7, 8], ]
                axes = [0, 1]
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                starts = [0, 1]
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                ends = [-1, 1000]
                strides = [1, 3]
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            Then:
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                result = [ [2], ]
    Args:
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        input (Variable): An N-D ``Tensor`` or ``LoDTensor`` . The data type is ``float32``, ``float64``, ``int32`` or ``int64``.
        axes (list|tuple): The data type is ``int32`` . Axes that `starts` and `ends` apply to.
                            It's optional. If it is not provides, it will be treated as :math:`[0,1,...,len(starts)-1]`.
        starts (list|tuple|Variable): The data type is ``int32`` . If ``starts`` is a list or tuple, the elements of
                it should be integers or Tensors with shape [1]. If ``starts`` is an Variable, it should be an 1-D Tensor.
                It represents starting indices of corresponding axis in ``axes``.
        ends (list|tuple|Variable): The data type is ``int32`` . If ``ends`` is a list or tuple, the elements of
                it should be integers or Tensors with shape [1]. If ``ends`` is an Variable, it should be an 1-D Tensor .
                It represents ending indices of corresponding axis in ``axes``.
        strides (list|tuple|Variable): The data type is ``int32`` . If ``strides`` is a list or tuple, the elements of
                it should be integers or Tensors with shape [1]. If ``strides`` is an Variable, it should be an 1-D Tensor .
                It represents slice step of corresponding axis in ``axes``.
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    Returns:
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        Variable:  A ``Tensor`` or ``LoDTensor`` with the same dimension as ``input``. The data type is same as ``input``.

    Raises:
        TypeError: The type of ``starts`` must be list, tuple or Variable.
        TypeError: The type of ``ends`` must be list, tuple or Variable.
        TypeError: The type of ``strides`` must be list, tuple or Variable.
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    Examples:
        .. code-block:: python

            import paddle.fluid as fluid

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            input = fluid.data(
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                name="input", shape=[3, 4, 5, 6], dtype='float32')

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            # example 1:
            # attr starts is a list which doesn't contain tensor Variable.
            axes = [0, 1, 2]
            starts = [-3, 0, 2]
            ends = [3, 2, 4]
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            strides_1 = [1, 1, 1]
            strides_2 = [1, 1, 2]
            sliced_1 = fluid.layers.strided_slice(input, axes=axes, starts=starts, ends=ends, strides=strides_1)
            # sliced_1 is input[:, 0:3:1, 0:2:1, 2:4:1].

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            # example 2:
            # attr starts is a list which contain tensor Variable.
            minus_3 = fluid.layers.fill_constant([1], "int32", -3)
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            sliced_2 = fluid.layers.strided_slice(input, axes=axes, starts=[minus_3, 0, 2], ends=ends, strides=strides_2)
            # sliced_2 is input[:, 0:3:1, 0:2:1, 2:4:2].
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    """
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    if not isinstance(starts, (list, tuple, Variable)):
        raise ValueError(
            "Input starts must be an Variable, python list or tuple.")
    if not isinstance(ends, (list, tuple, Variable)):
        raise ValueError(
            "Input ends must be an Variable, python list or tuple.")
    if not isinstance(strides, (list, tuple, Variable)):
        raise ValueError(
            "Input strides must be an Variable, python list or tuple.")

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    helper = LayerHelper('strided_slice', **locals())

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    def contain_var(one_list):
        for ele in one_list:
            if isinstance(ele, Variable):
                return True
        return False

    def get_new_list_tensor(old_list):
        new_list_tensor = []
        for dim in old_list:
            if isinstance(dim, Variable):
                dim.stop_gradient = True
                new_list_tensor.append(dim)
            else:
                assert (isinstance(dim, int))
                temp_out = helper.create_variable_for_type_inference('int32')
                fill_constant([1], 'int32', dim, force_cpu=True, out=temp_out)
                new_list_tensor.append(temp_out)
        return new_list_tensor

    inputs = {'Input': input}
    attrs = {'axes': axes}
    infer_flags = list(1 for i in range(len(axes)))

    if in_dygraph_mode():
        inputs = {'Input': input}
        attrs = {
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            'axes': axes,
            'starts': starts,
            'ends': ends,
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            'strides': strides,
            'infer_flags': infer_flags
        }
    else:
        # starts
        if isinstance(starts, Variable):
            starts.stop_gradient = True
            inputs['StartsTensor'] = starts
        elif isinstance(starts, (list, tuple)):
            attrs['starts'] = []
            if not contain_var(starts):
                attrs['starts'] = starts
            else:
                inputs['StartsTensorList'] = get_new_list_tensor(starts)
                for i, dim in enumerate(starts):
                    if isinstance(dim, Variable):
                        attrs['starts'].append(-1)
                        infer_flags[i] = -1
                    else:
                        attrs['starts'].append(dim)

        # ends
        if isinstance(ends, Variable):
            ends.stop_gradient = True
            inputs['EndsTensor'] = ends
        elif isinstance(ends, (list, tuple)):
            attrs['ends'] = []
            if not contain_var(ends):
                attrs['ends'] = ends
            else:
                inputs['EndsTensorList'] = get_new_list_tensor(ends)
                for i, dim in enumerate(ends):
                    if isinstance(dim, Variable):
                        attrs['ends'].append(-1)
                        infer_flags[i] = -1
                    else:
                        attrs['ends'].append(dim)
        # strides
        if isinstance(strides, Variable):
            strides.stop_gradient = True
            inputs['StridesTensor'] = strides
        elif isinstance(strides, (list, tuple)):
            attrs['strides'] = []
            if not contain_var(strides):
                attrs['strides'] = strides
            else:
                inputs['StridesTensorList'] = get_new_list_tensor(strides)
                for i, dim in enumerate(strides):
                    if isinstance(dim, Variable):
                        attrs['strides'].append(-1)
                        infer_flags[i] = -1
                    else:
                        attrs['strides'].append(dim)
        attrs['infer_flags'] = infer_flags
    out = helper.create_variable_for_type_inference(
        dtype=helper.input_dtype('input'))
    helper.append_op(
        type='strided_slice', inputs=inputs, attrs=attrs, outputs={'Out': out})
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    return out


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def shape(input):
    """
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    **Shape Layer**

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    Get the shape of the input.
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    Args:
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        input (Variable): The input N-D Tensor. Datatype can be float32, float64, int32, int64.
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    Returns:
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        Variable (Tensor): The shape of the input variable.
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    Examples:
        .. code-block:: python

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            import paddle.fluid as fluid
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            import numpy as np
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            inputs = fluid.layers.data(name="x", shape=[3, 100, 100], dtype="float32")
            output = fluid.layers.shape(inputs)

            exe = fluid.Executor(fluid.CPUPlace())
            exe.run(fluid.default_startup_program())

            img = np.ones((3, 100, 100)).astype(np.float32)

            res = exe.run(fluid.default_main_program(), feed={'x':img}, fetch_list=[output])
            print(res) # [array([  3, 100, 100], dtype=int32)]
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    """

    helper = LayerHelper('shape', **locals())
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    out = helper.create_variable_for_type_inference(dtype='int32')
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    helper.append_op(
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        type='shape', inputs={'Input': input}, outputs={'Out': out})
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    return out
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def rank(input):
    """
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    The OP returns the number of dimensions for a tensor, which is a 0-D int32 Tensor.
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    Args:
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        input (Variable): The input N-D tensor with shape of :math:`[N_1, N_2, ..., N_k]`, the data type is arbitrary.
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    Returns:
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        Variable, the output data type is int32.: The 0-D tensor with the dimensions of the input variable.
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    Examples:
        .. code-block:: python

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            import paddle.fluid as fluid

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            input = fluid.data(name="input", shape=[3, 100, 100], dtype="float32")
            rank = fluid.layers.rank(input) # rank=(3,)
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    """

    ndims = len(input.shape)
    out = assign(np.array(ndims, 'int32'))

    return out


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def size(input):
    """
    **Size Layer**

    Returns the number of elements for a tensor, which is a int64 Tensor with shape [1].

    Args:
        input (Variable): The input variable.

    Returns:
        Variable: The number of elements for the input variable.

    Examples:
        .. code-block:: python

            import paddle.fluid.layers as layers

            input = layers.data(
                name="input", shape=[3, 100], dtype="float32", append_batch_size=False)
            rank = layers.size(input) # 300
    """

    helper = LayerHelper('size', **locals())
    out = helper.create_variable_for_type_inference(dtype='int64')
    helper.append_op(type='size', inputs={'Input': input}, outputs={'Out': out})

    return out


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def _elementwise_op(helper):
    op_type = helper.layer_type
    x = helper.kwargs.get('x', None)
    y = helper.kwargs.get('y', None)
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    if in_dygraph_mode():
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        x = base.to_variable(x)
        y = base.to_variable(y)

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    assert x is not None, 'x cannot be None in {}'.format(op_type)
    assert y is not None, 'y cannot be None in {}'.format(op_type)
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    check_type_and_dtype(x, 'x', Variable,
                         ['float16', 'float32', 'float64', 'int32', 'int64'],
                         op_type)
    check_type_and_dtype(y, 'y', Variable,
                         ['float16', 'float32', 'float64', 'int32', 'int64'],
                         op_type)
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    axis = helper.kwargs.get('axis', -1)
    use_mkldnn = helper.kwargs.get('use_mkldnn', False)
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    name = helper.kwargs.get('name', None)
    if name is None:
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        out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    else:
        out = helper.create_variable(
            name=name, dtype=x.dtype, persistable=False)
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    helper.append_op(
        type=op_type,
        inputs={'X': x,
                'Y': y},
        outputs={'Out': out},
        attrs={'axis': axis,
               'use_mkldnn': use_mkldnn})
    return helper.append_activation(out)


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def scale(x, scale=1.0, bias=0.0, bias_after_scale=True, act=None, name=None):
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    """
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    Scale operator.

    Putting scale and bias to the input Tensor as following:

    ``bias_after_scale`` is True:

    .. math::
                            Out=scale*X+bias

    ``bias_after_scale`` is False:

    .. math::
                            Out=scale*(X+bias)
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    Args:
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        x(Variable): Input N-D Tensor of scale operator. Data type can be float32, float64, int8, int16, int32, int64, uint8.
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        scale(float|Variable): The scale factor of the input, it should be a float number or a Variable with shape [1] and data type as float32.
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        bias(float): The bias to be put on the input.
        bias_after_scale(bool): Apply bias addition after or before scaling. It is useful for numeric stability in some circumstances.
        act(str, optional): Activation applied to the output such as tanh, softmax, sigmoid, relu.
        name(str, optional): The default value is None. Normally there is no need for user to set this property.  For more information, please refer to :ref:`api_guide_Name` 
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    Returns:
10320
        Variable(Tensor|LoDTensor): Output tensor of scale operator, with shape and data type same as input.
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    Examples:
        .. code-block:: python

            import paddle.fluid as fluid
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            import numpy as np

            inputs = fluid.layers.data(name="x", shape=[2, 3], dtype='float32')
            output = fluid.layers.scale(inputs, scale = 2.0, bias = 1.0)

            exe = fluid.Executor(fluid.CPUPlace())
            exe.run(fluid.default_startup_program())

            img = np.array([[1, 2, 3], [4, 5, 6]]).astype(np.float32)
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            res = exe.run(fluid.default_main_program(), feed={'x':img}, fetch_list=[output])
            print(res) # [array([[ 3.,  5.,  7.], [ 9., 11., 13.]], dtype=float32)]
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        .. code-block:: python

            # scale with parameter scale as Variable
            import paddle.fluid as fluid
            import numpy as np

            inputs = fluid.layers.data(name="x", shape=[2, 3], dtype='float32')
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            scale = fluid.layers.data(name="scale", shape=[1], dtype='float32',
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                                      append_batch_size=False)
            output = fluid.layers.scale(inputs, scale = scale, bias = 1.0)

            exe = fluid.Executor(fluid.CPUPlace())
            exe.run(fluid.default_startup_program())

            img = np.array([[1, 2, 3], [4, 5, 6]]).astype(np.float32)
            scale_np = np.array([2.]).astype(np.float32)

            res = exe.run(fluid.default_main_program(), feed={'x':img, 'scale':scale_np}, fetch_list=[output])
            print(res) # [array([[ 3.,  5.,  7.], [ 9., 11., 13.]], dtype=float32)]

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    """

    helper = LayerHelper('scale', **locals())
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    if name is None:
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        out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    else:
        out = helper.create_variable(
            name=name, dtype=x.dtype, persistable=False)
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    inputs = {'X': x}
    attrs = {
        'bias': float(bias),
        'bias_after_scale': bias_after_scale,
    }
    if isinstance(scale, Variable):
        inputs['ScaleTensor'] = scale
    else:
        attrs['scale'] = float(scale)

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    helper.append_op(
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        type='scale', inputs=inputs, outputs={'Out': out}, attrs=attrs)
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    return helper.append_activation(out)
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def elementwise_add(x, y, axis=-1, act=None, name=None):
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    """
Examples:

    .. code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
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                "x": np.array([2, 3, 4]).astype('float32'),
                "y": np.array([1, 5, 2]).astype('float32')
10396 10397
            }

10398 10399
        x = fluid.data(name="x", shape=[3], dtype='float32')
        y = fluid.data(name="y", shape=[3], dtype='float32')
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        z = fluid.layers.elementwise_add(x, y)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)
        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])

        print(z_value) #[3., 8., 6.]


    .. code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
                "x": np.ones((2, 3, 4, 5)).astype('float32'),
                "y": np.zeros((3, 4)).astype('float32')
            }

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        x = fluid.data(name="x", shape=[2,3,4,5], dtype='float32')
        y = fluid.data(name="y", shape=[3,4], dtype='float32')
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        z = fluid.layers.elementwise_add(x, y, axis=1)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)

        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])

        print(z_value) # z.shape=[2,3,4,5]


    ..  code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
                "x": np.random.randint(1, 5, size=[2, 3, 4, 5]).astype('float32'),
                "y": np.random.randint(1, 5, size=[5]).astype('float32')
            }
        
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        x = fluid.data(name="x", shape=[2,3,4,5], dtype='float32')
        y = fluid.data(name="y", shape=[5], dtype='float32')
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        z = fluid.layers.elementwise_add(x, y, axis=3)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)

        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])
        print(z_value) # z.shape=[2,3,4,5]

    """
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    if in_dygraph_mode():
        return _elementwise_op_in_dygraph(
            x, y, axis=axis, act=act, op_name='elementwise_add')

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    return _elementwise_op(LayerHelper('elementwise_add', **locals()))


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def elementwise_div(x, y, axis=-1, act=None, name=None):
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    """
Examples:

    .. code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
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                "x": np.array([2, 3, 4]).astype('float32'),
                "y": np.array([1, 5, 2]).astype('float32')
10477 10478
            }

10479 10480
        x = fluid.data(name="x", shape=[3], dtype='float32')
        y = fluid.data(name="y", shape=[3], dtype='float32')
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        z = fluid.layers.elementwise_div(x, y)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)
        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])

        print(z_value) #[2., 0.6, 2.]


    .. code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
                "x": np.ones((2, 3, 4, 5)).astype('float32'),
                "y": np.zeros((3, 4)).astype('float32')
            }

10502 10503
        x = fluid.data(name="x", shape=[2,3,4,5], dtype='float32')
        y = fluid.data(name="y", shape=[3,4], dtype='float32')
10504 10505 10506 10507 10508 10509 10510 10511 10512 10513 10514 10515 10516 10517 10518 10519 10520 10521 10522 10523 10524 10525
        z = fluid.layers.elementwise_div(x, y, axis=1)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)

        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])

        print(z_value) # z.shape=[2,3,4,5]


    ..  code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
                "x": np.random.randint(1, 5, size=[2, 3, 4, 5]).astype('float32'),
                "y": np.random.randint(1, 5, size=[5]).astype('float32')
            }
        
10526 10527
        x = fluid.data(name="x", shape=[2,3,4,5], dtype='float32')
        y = fluid.data(name="y", shape=[5], dtype='float32')
10528 10529 10530 10531 10532 10533 10534 10535 10536 10537
        z = fluid.layers.elementwise_div(x, y, axis=3)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)
        
        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])
        print(z_value) # z.shape=[2,3,4,5]

    """
10538 10539 10540 10541
    if in_dygraph_mode():
        return _elementwise_op_in_dygraph(
            x, y, axis=axis, act=act, op_name='elementwise_div')

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    return _elementwise_op(LayerHelper('elementwise_div', **locals()))


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def elementwise_sub(x, y, axis=-1, act=None, name=None):
10546 10547 10548 10549 10550 10551 10552 10553 10554 10555
    """
Examples:

    .. code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
10556 10557
                "x": np.array([2, 3, 4]).astype('float32'),
                "y": np.array([1, 5, 2]).astype('float32')
10558 10559
            }

10560 10561
        x = fluid.data(name="x", shape=[3], dtype='float32')
        y = fluid.data(name="y", shape=[3], dtype='float32')
10562 10563 10564 10565 10566 10567 10568 10569 10570 10571 10572 10573 10574 10575 10576 10577 10578 10579 10580 10581 10582
        z = fluid.layers.elementwise_sub(x, y)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)
        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])

        print(z_value) #[1., -2., 2.]


    .. code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
                "x": np.ones((2, 3, 4, 5)).astype('float32'),
                "y": np.zeros((3, 4)).astype('float32')
            }

10583 10584
        x = fluid.data(name="x", shape=[2,3,4,5], dtype='float32')
        y = fluid.data(name="y", shape=[3,4], dtype='float32')
10585 10586 10587 10588 10589 10590 10591 10592 10593 10594 10595 10596 10597 10598 10599 10600 10601 10602 10603 10604 10605 10606
        z = fluid.layers.elementwise_sub(x, y, axis=1)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)

        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])

        print(z_value) # z.shape=[2,3,4,5]


    ..  code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
                "x": np.random.randint(1, 5, size=[2, 3, 4, 5]).astype('float32'),
                "y": np.random.randint(1, 5, size=[5]).astype('float32')
            }
        
10607 10608
        x = fluid.data(name="x", shape=[2,3,4,5], dtype='float32')
        y = fluid.data(name="y", shape=[5], dtype='float32')
10609 10610 10611 10612 10613 10614 10615 10616 10617 10618
        z = fluid.layers.elementwise_sub(x, y, axis=3)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)
        
        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])
        print(z_value) # z.shape=[2,3,4,5]

    """
10619 10620 10621 10622
    if in_dygraph_mode():
        return _elementwise_op_in_dygraph(
            x, y, axis=axis, act=act, op_name='elementwise_sub')

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    return _elementwise_op(LayerHelper('elementwise_sub', **locals()))


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def elementwise_mul(x, y, axis=-1, act=None, name=None):
10627 10628 10629 10630 10631 10632 10633 10634 10635 10636
    """
Examples:

    .. code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
10637 10638
                "x": np.array([2, 3, 4]).astype('float32'),
                "y": np.array([1, 5, 2]).astype('float32')
10639 10640
            }

10641 10642
        x = fluid.data(name="x", shape=[3], dtype='float32')
        y = fluid.data(name="y", shape=[3], dtype='float32')
10643 10644 10645 10646 10647 10648 10649 10650 10651 10652 10653 10654 10655 10656 10657 10658 10659 10660 10661 10662 10663
        z = fluid.layers.elementwise_mul(x, y)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)
        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])

        print(z_value) #[2., 15., 8.]


    .. code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
                "x": np.ones((2, 3, 4, 5)).astype('float32'),
                "y": np.zeros((3, 4)).astype('float32')
            }

10664 10665
        x = fluid.data(name="x", shape=[2,3,4,5], dtype='float32')
        y = fluid.data(name="y", shape=[3,4], dtype='float32')
10666 10667 10668 10669 10670 10671 10672 10673 10674 10675 10676 10677 10678 10679 10680 10681 10682 10683 10684 10685 10686 10687
        z = fluid.layers.elementwise_mul(x, y, axis=1)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)

        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])

        print(z_value) # z.shape=[2,3,4,5]


    ..  code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
                "x": np.random.randint(1, 5, size=[2, 3, 4, 5]).astype('float32'),
                "y": np.random.randint(1, 5, size=[5]).astype('float32')
            }
        
10688 10689
        x = fluid.data(name="x", shape=[2,3,4,5], dtype='float32')
        y = fluid.data(name="y", shape=[5], dtype='float32')
10690 10691 10692 10693 10694 10695 10696 10697 10698 10699
        z = fluid.layers.elementwise_mul(x, y, axis=3)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)
        
        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])
        print(z_value) # z.shape=[2,3,4,5]
 
    """
10700 10701 10702 10703
    if in_dygraph_mode():
        return _elementwise_op_in_dygraph(
            x, y, axis=axis, act=act, op_name='elementwise_mul')

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    return _elementwise_op(LayerHelper('elementwise_mul', **locals()))


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def elementwise_max(x, y, axis=-1, act=None, name=None):
10708 10709 10710 10711 10712 10713 10714 10715 10716 10717
    """
Examples:

    .. code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
10718 10719
                "x": np.array([2, 3, 4]).astype('float32'),
                "y": np.array([1, 5, 2]).astype('float32')
10720 10721
            }

10722 10723
        x = fluid.data(name="x", shape=[3], dtype='float32')
        y = fluid.data(name="y", shape=[3], dtype='float32')
10724 10725 10726 10727 10728 10729 10730 10731 10732 10733 10734 10735 10736 10737 10738 10739 10740 10741 10742 10743 10744
        z = fluid.layers.elementwise_max(x, y)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)
        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])

        print(z_value) #[2, 5, 4]


    .. code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
                "x": np.ones((2, 3, 4, 5)).astype('float32'),
                "y": np.zeros((3, 4)).astype('float32')
            }

10745 10746
        x = fluid.data(name="x", shape=[2,3,4,5], dtype='float32')
        y = fluid.data(name="y", shape=[3,4], dtype='float32')
10747 10748 10749 10750 10751 10752 10753 10754 10755 10756 10757
        z = fluid.layers.elementwise_max(x, y, axis=1)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)

        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])

        print(z_value)#[[[[1., 1., 1., 1., 1.] .... [1., 1., 1., 1., 1.]]]]

    """
10758 10759 10760 10761
    if in_dygraph_mode():
        return _elementwise_op_in_dygraph(
            x, y, axis=axis, act=act, op_name='elementwise_max')

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    return _elementwise_op(LayerHelper('elementwise_max', **locals()))


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def elementwise_min(x, y, axis=-1, act=None, name=None):
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    """
Examples:

    ..  code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
10776 10777
                "x": np.array([2, 3, 4]).astype('float32'),
                "y": np.array([1, 5, 2]).astype('float32')
10778 10779
            }

10780 10781
        x = fluid.data(name="x", shape=[3], dtype='float32')
        y = fluid.data(name="y", shape=[3], dtype='float32')
10782 10783 10784 10785 10786 10787 10788 10789 10790 10791 10792 10793 10794 10795 10796 10797 10798 10799 10800 10801
        z = fluid.layers.elementwise_max(x, y)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)
        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])

        print(z_value) #[1, 3, 2]

    ..  code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
                "x": np.ones((2, 3, 4, 5)).astype('float32'),
                "y": np.zeros((3, 4)).astype('float32')
            }

10802 10803
        x = fluid.data(name="x", shape=[2,3,4,5], dtype='float32')
        y = fluid.data(name="y", shape=[3,4], dtype='float32')
10804 10805 10806 10807 10808 10809 10810 10811 10812 10813 10814
        z = fluid.layers.elementwise_max(x, y, axis=1)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)

        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])

        print(z_value)#[[[[0., 0., 0., 0., 0.] .... [0., 0., 0., 0., 0.]]]]
    """

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    return _elementwise_op(LayerHelper('elementwise_min', **locals()))


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def elementwise_pow(x, y, axis=-1, act=None, name=None):
10819 10820 10821 10822 10823 10824 10825 10826 10827 10828
    """
Examples:

    ..  code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
10829 10830
                "x": np.array([2, 3, 4]).astype('float32'),
                "y": np.array([1, 5, 2]).astype('float32')
10831 10832
            }

10833 10834
        x = fluid.data(name="x", shape=[3], dtype='float32')
        y = fluid.data(name="y", shape=[3], dtype='float32')
10835 10836 10837 10838 10839 10840 10841 10842 10843
        z = fluid.layers.elementwise_pow(x, y)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)
        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])

        print(z_value) #[2, 243, 16]
    """
10844 10845 10846
    if in_dygraph_mode():
        return _elementwise_op_in_dygraph(
            x, y, axis=axis, act=act, op_name='elementwise_pow')
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    return _elementwise_op(LayerHelper('elementwise_pow', **locals()))


10850
def elementwise_mod(x, y, axis=-1, act=None, name=None):
10851 10852 10853 10854 10855 10856 10857 10858 10859 10860 10861 10862 10863 10864 10865 10866 10867 10868 10869 10870 10871 10872 10873 10874 10875
    """
Examples:

    ..  code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
                "x": np.array([10, 15, 8]).astype('int32'),
                "y": np.array([3, 6, 5]).astype('int32')
            }

        x = fluid.data(name="x", shape=[3], dtype='int32')
        y = fluid.data(name="y", shape=[3], dtype='int32')
        z = fluid.layers.elementwise_mod(x, y)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)
        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])

        print(z_value) #[1, 3, 3]
    """
10876 10877 10878 10879
    if in_dygraph_mode():
        return _elementwise_op_in_dygraph(
            x, y, axis=axis, act=act, op_name='elementwise_mod')

10880 10881 10882 10883
    return _elementwise_op(LayerHelper('elementwise_mod', **locals()))


def elementwise_floordiv(x, y, axis=-1, act=None, name=None):
10884 10885 10886 10887 10888 10889 10890 10891 10892 10893 10894 10895 10896 10897 10898 10899 10900 10901 10902 10903 10904 10905 10906 10907 10908
    """
Examples:

    ..  code-block:: python

        import paddle.fluid as fluid
        import numpy as np

        def gen_data():
            return {
                "x": np.array([10, 15, 8]).astype('int32'),
                "y": np.array([3, 7, 5]).astype('int32')
            }

        x = fluid.data(name="x", shape=[3], dtype='int32')
        y = fluid.data(name="y", shape=[3], dtype='int32')
        z = fluid.layers.elementwise_floordiv(x, y)

        place = fluid.CPUPlace()
        exe = fluid.Executor(place)
        z_value = exe.run(feed=gen_data(),
                            fetch_list=[z.name])

        print(z_value) #[3, 2, 1]
    """
10909 10910 10911 10912
    if in_dygraph_mode():
        return _elementwise_op_in_dygraph(
            x, y, axis=axis, act=act, op_name='elementwise_floordiv')

10913 10914 10915
    return _elementwise_op(LayerHelper('elementwise_floordiv', **locals()))


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for func in [
10917 10918 10919 10920
        elementwise_add,
        elementwise_div,
        elementwise_sub,
        elementwise_mul,
10921 10922
        elementwise_max,
        elementwise_pow,
10923
        elementwise_min,
10924 10925
        elementwise_mod,
        elementwise_floordiv,
10926 10927 10928 10929 10930 10931 10932 10933 10934 10935 10936 10937 10938 10939 10940 10941 10942
]:
    op_proto = OpProtoHolder.instance().get_op_proto(func.__name__)
    func.__doc__ = _generate_doc_string_(
        op_proto,
        additional_args_lines=[
            "axis (int32, optional): If X.dimension != Y.dimension, \
            Y.dimension must be a subsequence of x.dimension. \
            And axis is the start dimension index for broadcasting Y onto X. ",
            "act (string, optional): Activation applied to the output. \
            Default is None. Details: :ref:`api_guide_activations_en` ",
            "name (string, optional): Name of the output. \
            Default is None. It's used to print debug info for developers. Details: \
            :ref:`api_guide_Name` "
        ],
        skip_attrs_set={"x_data_format", "y_data_format", "axis"
                        }) + """\n""" + str(func.__doc__)

10943
for func in []:
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    op_proto = OpProtoHolder.instance().get_op_proto(func.__name__)
    func.__doc__ = _generate_doc_string_(
        op_proto,
        additional_args_lines=[
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            "act (basestring|None): Activation applied to the output.",
            "name (basestring|None): Name of the output."
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        ])
10951 10952 10953 10954 10955 10956 10957 10958 10959 10960 10961 10962 10963 10964 10965 10966 10967 10968 10969 10970 10971 10972 10973 10974 10975 10976 10977 10978 10979 10980 10981 10982 10983 10984 10985 10986 10987
    func.__doc__ = func.__doc__ + """

Examples:
  .. code-block:: python
    
    import paddle.fluid as fluid
    # example 1: shape(x) = (2, 3, 4, 5), shape(y) = (2, 3, 4, 5)
    x0 = fluid.layers.data(name="x0", shape=[2, 3, 4, 5], dtype='float32')
    y0 = fluid.layers.data(name="y0", shape=[2, 3, 4, 5], dtype='float32')
    z0 = fluid.layers.%s(x0, y0)

    # example 2: shape(X) = (2, 3, 4, 5), shape(Y) = (5)
    x1 = fluid.layers.data(name="x1", shape=[2, 3, 4, 5], dtype='float32')
    y1 = fluid.layers.data(name="y1", shape=[5], dtype='float32')
    z1 = fluid.layers.%s(x1, y1)

    # example 3: shape(X) = (2, 3, 4, 5), shape(Y) = (4, 5), with axis=-1(default) or axis=2
    x2 = fluid.layers.data(name="x2", shape=[2, 3, 4, 5], dtype='float32')
    y2 = fluid.layers.data(name="y2", shape=[4, 5], dtype='float32')
    z2 = fluid.layers.%s(x2, y2, axis=2)

    # example 4: shape(X) = (2, 3, 4, 5), shape(Y) = (3, 4), with axis=1
    x3 = fluid.layers.data(name="x3", shape=[2, 3, 4, 5], dtype='float32')
    y3 = fluid.layers.data(name="y3", shape=[3, 4], dtype='float32')
    z3 = fluid.layers.%s(x3, y3, axis=1)

    # example 5: shape(X) = (2, 3, 4, 5), shape(Y) = (2), with axis=0
    x4 = fluid.layers.data(name="x4", shape=[2, 3, 4, 5], dtype='float32')
    y4 = fluid.layers.data(name="y4", shape=[2], dtype='float32')
    z4 = fluid.layers.%s(x4, y4, axis=0)

    # example 6: shape(X) = (2, 3, 4, 5), shape(Y) = (2, 1), with axis=0
    x5 = fluid.layers.data(name="x5", shape=[2, 3, 4, 5], dtype='float32')
    y5 = fluid.layers.data(name="y5", shape=[2], dtype='float32')
    z5 = fluid.layers.%s(x5, y5, axis=0)
    """ % (func.__name__, func.__name__, func.__name__, func.__name__,
           func.__name__, func.__name__)
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10990
def _logical_op(op_name, x, y, out=None, name=None, binary_op=True):
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    helper = LayerHelper(op_name, **locals())

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    if binary_op:
        assert x.dtype == y.dtype
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    if out is None:
        if name is None:
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            out = helper.create_variable_for_type_inference(dtype=x.dtype)
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        else:
            out = helper.create_variable(
                name=name, dtype=x.dtype, persistable=False)

    if binary_op:
        helper.append_op(
            type=op_name, inputs={"X": x,
                                  "Y": y}, outputs={"Out": out})
    else:
        helper.append_op(type=op_name, inputs={"X": x}, outputs={"Out": out})

    return out


@templatedoc()
11014
def logical_and(x, y, out=None, name=None):
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    """
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    logical_and Operator

    It operates element-wise on X and Y, and returns the Out. X, Y and Out are N-dim boolean LoDTensor or Tensor.
    Each element of Out is calculated by
    
    .. math::

        Out = X \land Y
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    Args:
        x(${x_type}): ${x_comment}
        y(${y_type}): ${y_comment}
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        out(LoDTensor or Tensor): The LoDTensor or Tensor that specifies the output of the operator, which can be any Variable that has been created in the program. The default value is None, and a new Variable will be created to save the output.
        name(str|None): The default value is None. Normally there is no need for user to set this property. For more information, please refer to :ref:`api_guide_Name`
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    Returns:
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        ${out_type}: ${out_comment}
11033 11034 11035 11036

    Examples:
        .. code-block:: python

11037
            import paddle.fluid as fluid
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            import numpy as np

            # Graph organizing
            x = fluid.layers.data(name='x', shape=[2], dtype='bool')
            y = fluid.layers.data(name='y', shape=[2], dtype='bool')
            res = fluid.layers.logical_and(x=x, y=y)
            # The comment lists another available method.
            # res = fluid.layers.fill_constant(shape=[2], dtype='bool', value=0)
            # fluid.layers.logical_and(x=x, y=y, out=res)

            # Create an executor using CPU as an example
            exe = fluid.Executor(fluid.CPUPlace())

            # Execute
            x_i = np.array([[1, 0], [0, 1]]).astype(np.bool)
            y_i = np.array([[1, 1], [0, 0]]).astype(np.bool)
            res_val, = exe.run(fluid.default_main_program(), feed={'x':x_i, 'y':y_i}, fetch_list=[res])
            print(res_val) # [[True, False], [False, False]]
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    """

    return _logical_op(
        op_name="logical_and", x=x, y=y, name=name, out=out, binary_op=True)


@templatedoc()
11063
def logical_or(x, y, out=None, name=None):
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    """
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    logical_or Operator

    It operates element-wise on X and Y, and returns the Out. X, Y and Out are N-dim boolean LoDTensor or Tensor.
    Each element of Out is calculated by
    
    .. math::

        Out = X \lor Y
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    Args:
        x(${x_type}): ${x_comment}
        y(${y_type}): ${y_comment}
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        out(LoDTensor or Tensor): The LoDTensor or Tensor that specifies the output of the operator, which can be any Variable that has been created in the program. The default value is None, and a new Variable will be created to save the output.
        name(str|None): The default value is None. Normally there is no need for user to set this property. For more information, please refer to :ref:`api_guide_Name`
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    Returns:
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        ${out_type}: ${out_comment}
11082 11083 11084 11085

    Examples:
        .. code-block:: python

11086
            import paddle.fluid as fluid
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            import numpy as np

            # Graph organizing
            x = fluid.layers.data(name='x', shape=[2], dtype='bool')
            y = fluid.layers.data(name='y', shape=[2], dtype='bool')
            res = fluid.layers.logical_or(x=x, y=y)
            # The comment lists another available method.
            # res = fluid.layers.fill_constant(shape=[2], dtype='bool', value=0)
            # fluid.layers.logical_or(x=x, y=y, out=res)

            # Create an executor using CPU as an example
            exe = fluid.Executor(fluid.CPUPlace())

            # Execute
            x_i = np.array([[1, 0], [0, 1]]).astype(np.bool)
            y_i = np.array([[1, 1], [0, 0]]).astype(np.bool)
            res_val, = exe.run(fluid.default_main_program(), feed={'x':x_i, 'y':y_i}, fetch_list=[res])
            print(res_val) # [[True, True], [False, True]]
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    """

    return _logical_op(
        op_name="logical_or", x=x, y=y, name=name, out=out, binary_op=True)


@templatedoc()
11112
def logical_xor(x, y, out=None, name=None):
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    """
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    logical_xor Operator

    It operates element-wise on X and Y, and returns the Out. X, Y and Out are N-dim boolean LoDTensor or Tensor.
    Each element of Out is calculated by
    
    .. math::

        Out = (X \lor Y) \land \lnot (X \land Y)
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    Args:
        x(${x_type}): ${x_comment}
        y(${y_type}): ${y_comment}
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        out(LoDTensor or Tensor): The LoDTensor or Tensor that specifies the output of the operator, which can be any Variable that has been created in the program. The default value is None, and a new Variable will be created to save the output.
        name(str|None): The default value is None. Normally there is no need for user to set this property. For more information, please refer to :ref:`api_guide_Name`
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    Returns:
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        ${out_type}: ${out_comment}
11131 11132 11133 11134

    Examples:
        .. code-block:: python

11135
            import paddle.fluid as fluid
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            import numpy as np

            # Graph organizing
            x = fluid.layers.data(name='x', shape=[2], dtype='bool')
            y = fluid.layers.data(name='y', shape=[2], dtype='bool')
            res = fluid.layers.logical_xor(x=x, y=y)
            # The comment lists another available method.
            # res = fluid.layers.fill_constant(shape=[2], dtype='bool', value=0)
            # fluid.layers.logical_xor(x=x, y=y, out=res)

            # Create an executor using CPU as an example
            exe = fluid.Executor(fluid.CPUPlace())

            # Execute
            x_i = np.array([[1, 0], [0, 1]]).astype(np.bool)
            y_i = np.array([[1, 1], [0, 0]]).astype(np.bool)
            res_val, = exe.run(fluid.default_main_program(), feed={'x':x_i, 'y':y_i}, fetch_list=[res])
            print(res_val) # [[False, True], [False, True]]
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    """

    return _logical_op(
        op_name="logical_xor", x=x, y=y, name=name, out=out, binary_op=True)


@templatedoc()
11161
def logical_not(x, out=None, name=None):
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    """
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    logical_not Operator

    It operates element-wise on X, and returns the Out. X and Out are N-dim boolean LoDTensor or Tensor.
    Each element of Out is calculated by
    
    .. math::

        Out = \lnot X
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    Args:
        x(${x_type}): ${x_comment}
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        out(LoDTensor/Tensor): The LoDTensor/Tensor that specifies the output of the operator, which can be any Variable that has been created in the program. The default value is None, and a new Variable will be created to save the output.
        name(str|None): The default value is None. Normally there is no need for user to set this property. For more information, please refer to :ref:`api_guide_Name`
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    Returns:
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        ${out_type}: ${out_comment}
11179 11180 11181 11182

    Examples:
        .. code-block:: python

11183
            import paddle.fluid as fluid
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            import numpy as np

            # Graph organizing
            x = fluid.layers.data(name='x', shape=[2], dtype='bool')
            res = fluid.layers.logical_not(x)
            # The comment lists another availble method.
            # res = fluid.layers.fill_constant(shape=[2], dtype='bool', value=0)
            # fluid.layers.logical_not(x, out=res)

            # Create an executor using CPU as an example
            exe = fluid.Executor(fluid.CPUPlace())

            # Execute
            x_i = np.array([[1, 0]]).astype(np.bool)
            res_val, = exe.run(fluid.default_main_program(), feed={'x':x_i}, fetch_list=[res])
            print(res_val) # [[False, True]]
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    """

    return _logical_op(
        op_name="logical_not", x=x, y=None, name=name, out=out, binary_op=False)
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@templatedoc()
def clip(x, min, max, name=None):
    """
    ${comment}

    Args:
        x(${x_type}): ${x_comment}
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        min(float): ${min_comment}
        max(float): ${max_comment}
        name(str, optional): The default value is None.  
                             Normally there is no need for user to set this property.  
                             For more information, please refer to :ref:`api_guide_Name`
11218 11219

    Returns:
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        ${out_comment}

    Return Type:
        ${out_type}
11224 11225 11226 11227

    Examples:
        .. code-block:: python

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            import paddle.fluid as fluid
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            input = fluid.data(
11230 11231
                name='data', shape=[1], dtype='float32')
            reward = fluid.layers.clip(x=input, min=-1.0, max=1.0)
11232 11233 11234 11235 11236
    """

    helper = LayerHelper("clip", **locals())

    if name is None:
11237 11238
        name = unique_name.generate_with_ignorable_key(".".join(
            [helper.name, 'tmp']))
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    out = helper.create_variable(
        type=x.type, name=name, dtype=x.dtype, persistable=False)
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    helper.append_op(
        type="clip",
        inputs={"X": x},
        attrs={"min": min,
               "max": max},
        outputs={"Out": out})

    return out


@templatedoc()
def clip_by_norm(x, max_norm, name=None):
    """
    ${comment}

    Args:
        x(${x_type}): ${x_comment}
        max_norm(${max_norm_type}): ${max_norm_comment}
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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 
            None by default. 
11264 11265

    Returns:
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        Variable:

11268
        out(${out_type}): ${out_comment}
11269

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11271 11272 11273
    Examples:
        .. code-block:: python

11274
            import paddle.fluid as fluid
11275 11276
            input = fluid.data(
                name='data', shape=[None, 1], dtype='float32')
11277
            reward = fluid.layers.clip_by_norm(x=input, max_norm=1.0)
11278 11279 11280 11281 11282
    """

    helper = LayerHelper("clip_by_norm", **locals())

    if name is None:
11283 11284
        name = unique_name.generate_with_ignorable_key(".".join(
            [helper.name, 'tmp']))
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    out = helper.create_variable(
        type=x.type, name=name, dtype=x.dtype, persistable=False)
11288 11289 11290 11291 11292 11293 11294 11295

    helper.append_op(
        type="clip_by_norm",
        inputs={"X": x},
        attrs={"max_norm": max_norm},
        outputs={"Out": out})

    return out
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@templatedoc()
def mean(x, name=None):
    """
    ${comment}

    Args:
        x(${x_type}): ${x_comment}
        name(basestring|None): Name of the output.

    Returns:
        out(${out_type}): ${out_comment}
11309 11310 11311 11312

    Examples:
        .. code-block:: python

11313
            import paddle.fluid as fluid
11314 11315 11316
            input = fluid.layers.data(
                name='data', shape=[2, 3], dtype='float32')
            mean = fluid.layers.mean(input)
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    """
11318 11319 11320 11321
    if in_dygraph_mode():
        inputs = {"X": [x]}
        outs = core.ops.mean(inputs)
        return outs['Out'][0]
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    helper = LayerHelper("mean", **locals())
11324 11325
    check_type_and_dtype(x, 'x', Variable, ['float16', 'float32', 'float64'],
                         'mean')
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    if name is None:
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        out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    else:
        out = helper.create_variable(
            name=name, dtype=x.dtype, persistable=False)

    helper.append_op(
        type="mean", inputs={"X": x}, attrs={}, outputs={"Out": out})

    return out


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@templatedoc()
def merge_selected_rows(x, name=None):
    """
    ${comment}

    Args:
        x(${x_type}): ${x_comment}
        name(basestring|None): Name of the output.

    Returns:
        out(${out_type}): ${out_comment}
11349 11350 11351 11352

    Examples:
        .. code-block:: python

11353
            import paddle.fluid as fluid
11354 11355 11356 11357 11358
            b = fluid.default_main_program().global_block()
            var = b.create_var(
                name="X", dtype="float32", persistable=True,
                type=fluid.core.VarDesc.VarType.SELECTED_ROWS)
            y = fluid.layers.merge_selected_rows(var)
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    """

    helper = LayerHelper("merge_selected_rows", **locals())
    out = helper.create_variable_for_type_inference(dtype=x.dtype)
    helper.append_op(
        type="merge_selected_rows",
        inputs={"X": x},
        attrs={},
        outputs={"Out": out})
    return out


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def mul(x, y, x_num_col_dims=1, y_num_col_dims=1, name=None):
    """
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    Mul Operator.
    This operator is used to perform matrix multiplication for input $x$ and $y$.
    The equation is:

    ..  math::
        Out = x * y

    Both the input $x$ and $y$ can carry the LoD (Level of Details) information, or not. But the output only shares the LoD information with input $x$.
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    Args:
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        x (Variable): The first input Tensor/LoDTensor of mul_op.
        y (Variable): The second input Tensor/LoDTensor of mul_op.
        x_num_col_dims (int, optional): The mul_op can take tensors with more than two dimensions as its inputs. If the input $x$ is a tensor with more than two dimensions, $x$ will be flattened into a two-dimensional matrix first. The flattening rule is: the first `num_col_dims` will be flattened to form the first dimension of the final matrix (the height of the matrix), and the rest `rank(x) - num_col_dims` dimensions are flattened to form the second dimension of the final matrix (the width of the matrix). As a result, height of the flattened matrix is equal to the product of $x$'s first `x_num_col_dims` dimensions' sizes, and width of the flattened matrix is equal to the product of $x$'s last `rank(x) - num_col_dims` dimensions' size. For example, suppose $x$ is a 6-dimensional tensor with the shape [2, 3, 4, 5, 6], and `x_num_col_dims` = 3. Thus, the flattened matrix will have a shape [2 x 3 x 4, 5 x 6] = [24, 30]. Default is 1. 
        y_num_col_dims (int, optional): The mul_op can take tensors with more than two dimensions as its inputs. If the input $y$ is a tensor with more than two dimensions, $y$ will be flattened into a two-dimensional matrix first. The attribute `y_num_col_dims` determines how $y$ is flattened. See comments of `x_num_col_dims` for more details. Default is 1. 
        name (str, optional): Name of the output. Normally there is no need for user to set this property. For more information, please refer to :ref:`api_guide_Name`. Default is None. 
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    Returns:
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        Variable(Tensor/LoDTensor): The output Tensor/LoDTensor of mul op.
11391 11392

    Examples:
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        ..  code-block:: python
11394 11395 11396 11397 11398 11399 11400 11401 11402
            
            import paddle.fluid as fluid
            dataX = fluid.layers.data(name="dataX", append_batch_size = False, shape=[2, 5], dtype="float32")
            dataY = fluid.layers.data(name="dataY", append_batch_size = False, shape=[5, 3], dtype="float32")
            output = fluid.layers.mul(dataX, dataY,
                                      x_num_col_dims = 1,
                                      y_num_col_dims = 1)
            

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    """

    helper = LayerHelper("mul", **locals())
11406 11407 11408 11409
    check_type_and_dtype(x, 'x', Variable, ['float16', 'float32', 'float64'],
                         'mul')
    check_type_and_dtype(y, 'y', Variable, ['float16', 'float32', 'float64'],
                         'mul')
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    if name is None:
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        out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    else:
        out = helper.create_variable(
            name=name, dtype=x.dtype, persistable=False)

    helper.append_op(
        type="mul",
        inputs={"X": x,
                "Y": y},
        attrs={
X
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            "x_num_col_dims": x_num_col_dims,
            "y_num_col_dims": y_num_col_dims
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        },
        outputs={"Out": out})
    return out


@templatedoc()
11429
def maxout(x, groups, name=None, axis=1):
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    """
    ${comment}

    Args:
        x(${x_type}): ${x_comment}
11435 11436
        groups(int): ${groups_comment}
        axis(int, optional): ${axis_comment}
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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 
            None by default.
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11440 11441

    Returns:
11442
        Variable: ${out_comment}
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11444 11445
    Raises:
        ValueError: If `axis` is not 1, -1 or 3.
11446
        ValueError: If the number of input channels can not be divisible by `groups`.
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    Examples:
        .. code-block:: python

11451
            import paddle.fluid as fluid
11452
            input = fluid.data(
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                name='data', 
11454
                shape=[None, 256, 32, 32], 
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                dtype='float32')
            out = fluid.layers.maxout(input, groups=2)
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    """
    helper = LayerHelper("maxout", **locals())
11459 11460 11461 11462 11463 11464
    if axis not in [1, -1, 3]:
        raise ValueError(
            "Attr(axis) should be 1 when data format is NCHW, -1 or 3 when data format is NHWC. Received "
            "Attr(axis): %s." % str(axis))
    if axis == -1:
        axis = 3
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    if name is None:
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        out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    else:
        out = helper.create_variable(
            name=name, dtype=x.dtype, persistable=False)

    helper.append_op(
        type="maxout",
        inputs={"X": x},
11475 11476
        attrs={"groups": groups,
               "axis": axis},
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        outputs={"Out": out})
    return out
11479 11480


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def space_to_depth(x, blocksize, name=None):
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    """
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    Gives a blocksize to space_to_depth the input LoDtensor with Layout: [batch, channel, height, width]
11484

11485 11486 11487
    This op rearranges blocks of spatial data, into depth. More specifically, this op outputs a copy of \
        theinput LoDtensor where values from the height and width dimensions are moved to the channel \
        dimension.
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    The attr blocksize indicates the input block size.
11489

11490 11491 11492
    space_to_depth will reorgnize the elements of input with shape[batch, channel, height, width] \
        according to blocksize to construct output with shape \
        [batch, channel * blocksize * blocksize, height/blocksize, width/blocksize]:
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    - Non-overlapping blocks of size block_size x block size are rearranged into depth at each location.
    - The Y, X coordinates within each block of the input become the high order component of the output channel index
    - channel should be divisible by square of blocksize
    - height, width should be divsible by blocksize

11499 11500 11501 11502 11503 11504 11505 11506 11507 11508 11509 11510 11511 11512 11513 11514 11515
    This OP is useful for resizing the activations between convolutions \
        (but keeping all data)

    .. code-block:: text

        Given the input x with the shape [1, 1, 4, 4]:
        x.data = [[[[1,   2,  5,  6],
                    [3,   4,  7,  8],
                    [9,  10, 13, 14],
                    [11, 12, 15, 16]]]]
        blocksize = 2

        then get the output with the shape [1, 4, 2, 2]:
        out.data = [[[[1,   2],  [3,  4]],
                     [[5,   6],  [7,  8]],
                     [[9,  10], [11, 12]],
                     [[13, 14], [15, 16]]]]
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    Args:
11518 11519 11520 11521 11522 11523
        x (Variable): The input, which should be 4 dims Tensor or LodTensor, with the shape \
            [batch, channel, height, width]
        blocksize (int): The blocksize to select the element on each feature map should be > 2
        name(str, optional): For detailed information, please refer \
            to :ref:`api_guide_Name`. Usually name is no need to set and \
            None by default.
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11525 11526 11527 11528
    Returns: The output, which should be 4 dims Tensor or LodTensor, with the shape \
            [batch, channel * blocksize * blocksize, height/blocksize, width/blocksize]

    Return Type: Variable
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    Raises:
11531
        TypeError: blocksize type must be int64.
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    Examples:
        .. code-block:: python
11535
    
11536 11537
            import paddle.fluid as fluid
            import numpy as np
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11539 11540
            data = fluid.data(
                name='data', shape=[1, 4, 2, 2], dtype='float32')
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            space_to_depthed = fluid.layers.space_to_depth(
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                x=data, blocksize=2)
11543

11544
            exe = fluid.Executor(fluid.CPUPlace())
11545
            data_np = np.arange(0,16).reshape((1,4,2,2)).astype('float32')
11546 11547 11548 11549 11550 11551 11552

            print(data_np)
            #array([[[[ 0.,  1.], [ 2.,  3.]],
            #        [[ 4.,  5.], [ 6.,  7.]],
            #        [[ 8.,  9.], [10., 11.]],
            #        [[12., 13.], [14., 15.]]]], dtype=float32)

11553
            out_main = exe.run(fluid.default_main_program(),
11554 11555 11556 11557 11558 11559 11560 11561
                        feed={'data': data_np},
                        fetch_list=[space_to_depthed])

            print(out_main)
            #[array([[[[ 0.]], [[ 4.]], [[ 1.]], [[ 5.]],
            #         [[ 8.]], [[12.]], [[ 9.]], [[13.]],
            #         [[ 2.]], [[ 6.]], [[ 3.]], [[ 7.]],
            #         [[10.]], [[14.]], [[11.]], [[15.]]]], dtype=float32)]
11562

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    """

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    helper = LayerHelper("space_to_depth", **locals())
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    if not (isinstance(blocksize, int)):
        raise ValueError("blocksize must be a python Int")
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    if name is None:
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11571 11572
        out = helper.create_variable_for_type_inference(
            dtype=x.dtype)  #fix create
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    else:
        out = helper.create_variable(
            name=name, dtype=x.dtype, persistable=False)

    helper.append_op(
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        type="space_to_depth",
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        inputs={"X": x},
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        attrs={"blocksize": blocksize},
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        outputs={"Out": out})
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    return out

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11585 11586 11587 11588 11589 11590
def affine_channel(x,
                   scale=None,
                   bias=None,
                   data_layout='NCHW',
                   name=None,
                   act=None):
11591 11592 11593 11594 11595
    """
    Applies a separate affine transformation to each channel of the input.
    Useful for replacing spatial batch norm with its equivalent fixed
    transformation. The input also can be 2D tensor and applies a affine
    transformation in second dimension.
11596

11597 11598 11599
    Args:
        x (Variable): Feature map input can be a 4D tensor with order NCHW
            or NHWC. It also can be a 2D tensor and the affine transformation
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            is applied in the second dimension.The data type is float32 or float64.
11601 11602
        scale (Variable): 1D input of shape (C), the c-th element is the scale
            factor of the affine transformation for the c-th channel of
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            the input.The data type is float32 or float64.
11604 11605
        bias (Variable): 1D input of shape (C), the c-th element is the bias
            of the affine transformation for the c-th channel of the input.
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            The data type is float32 or float64.
11607 11608 11609 11610 11611
        data_layout (str, optional): Specify the data format of the input, and the data format of the output 
            will be consistent with that of the input. An optional string from: `"NCHW"`, `"NHWC"`.
            The default is `"NCHW"`. When it is `"NCHW"`, the data is stored in the order of:
            `[batch_size, input_channels, input_height, input_width]`. If input is 2D Tensor, you can ignore 
            data_layout.
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        name (str, default None): The name of this layer. For more information,
            please refer to :ref:`api_guide_Name` .
11614
        act (str, default None): Activation to be applied to the output of this layer.
11615 11616

    Returns:
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        Variable: A tensor which has the same shape, data layout and data type with x.
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    Examples:
        .. code-block:: python
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            import numpy as np
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            import paddle.fluid as fluid
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            use_gpu = False
            place = fluid.CUDAPlace(0) if use_gpu else fluid.CPUPlace()
            exe = fluid.Executor(place)

            data = fluid.data(name='data', shape=[None, 1, 2, 2], dtype='float32')
            input_scale = fluid.layers.create_parameter(shape=[1], dtype="float32",
                                    default_initializer=fluid.initializer.Constant(2.0))
            input_bias = fluid.layers.create_parameter(shape=[1],dtype="float32",
                                    default_initializer=fluid.initializer.Constant(0.5))
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            out = fluid.layers.affine_channel(data,scale=input_scale,
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                                    bias=input_bias)

            exe.run(fluid.default_startup_program())
            test_program = fluid.default_main_program().clone(for_test=True)

            [out_array] = exe.run(test_program,
                                  fetch_list=out,
                                  feed={'data': np.ones([1,1,2,2]).astype('float32')})
            # out_array is [[[[2.5, 2.5],
            #                [2.5, 2.5]]]] with shape: [1, 1, 2, 2]
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11646 11647 11648 11649
    """
    helper = LayerHelper("affine_channel", **locals())

    if name is None:
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        out = helper.create_variable_for_type_inference(dtype=x.dtype)
11651 11652 11653 11654 11655 11656 11657 11658 11659 11660 11661
    else:
        out = helper.create_variable(
            name=name, dtype=x.dtype, persistable=False)

    helper.append_op(
        type="affine_channel",
        inputs={"X": x,
                'Scale': scale,
                'Bias': bias},
        attrs={"data_layout": data_layout},
        outputs={"Out": out})
11662
    return helper.append_activation(out)
11663 11664


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def similarity_focus(input, axis, indexes, name=None):
11666
    """
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    SimilarityFocus Operator
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    Generate a similarity focus mask with the same shape of input using the following method:
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11671 11672 11673
    1. Extract the 3-D tensor(here the first dimension is BatchSize) corresponding
       to the axis according to the indexes. For example, if axis=1 and indexes=[a],
       it will get the matrix T=X[:, a, :, :]. In this case, if the shape of input X
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       is (BatchSize, A, B, C), the shape of tensor T is (BatchSize, B, C).
11675 11676 11677 11678 11679 11680 11681
    2. For each index, find the largest numbers in the tensor T, so that the same
       row and same column has at most one number(what it means is that if the
       largest number has been found in the i-th row and the j-th column, then
       the numbers in the i-th row or j-th column will be skipped. And then the
       next largest number will be selected from the remaining numbers. Obviously
       there will be min(B, C) numbers), and mark the corresponding position of the
       3-D similarity focus mask as 1, otherwise as 0. Do elementwise-or for
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       each index.
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    3. Broadcast the 3-D similarity focus mask to the same shape of input X.

    Refer to `Similarity Focus Layer <http://www.aclweb.org/anthology/N16-1108>`_

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    .. code-block:: text

        * Example :

            Given a 4-D tensor x with the shape (BatchSize, C, A, B), where C is
            the number of channels and the shape of feature map is (A, B):
                x.shape = (2, 3, 2, 2)
                x.data = [[[[0.8, 0.1],
                            [0.4, 0.5]],

                           [[0.9, 0.7],
                            [0.9, 0.9]],

                           [[0.8, 0.9],
                            [0.1, 0.2]]],


                          [[[0.2, 0.5],
                            [0.3, 0.4]],

                           [[0.9, 0.7],
                            [0.8, 0.4]],

                           [[0.0, 0.2],
                            [0.4, 0.7]]]]

            Given axis: 1 (the axis of the channel)
            Given indexes: [0]

            then we get a 4-D tensor out with the same shape of input x:
                out.shape = (2, 3, 2, 2)
                out.data = [[[[1.0, 0.0],
                              [0.0, 1.0]],

                             [[1.0, 0.0],
                              [0.0, 1.0]],

                             [[1.0, 0.0],
                              [0.0, 1.0]]],

                            [[[0.0, 1.0],
                              [1.0, 0.0]],

                             [[0.0, 1.0],
                              [1.0, 0.0]],

                             [[0.0, 1.0],
                              [1.0, 0.0]]]]

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    Args:
11737
        input(Variable): The input tensor variable(default float). It should
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            be a 4-D tensor with shape [BatchSize, A, B, C]. Data type is 
            float32 or float64.
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        axis(int): Indicating the dimension to be selected. It can only be
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            1, 2 or 3.
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        indexes(list): Indicating the indexes of the selected dimension.
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    Returns:
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        Variable: A tensor variable with the same shape and same type \
                  as the input.
11747

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    Examples:
        .. code-block:: python
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11751
            import paddle.fluid as fluid
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            data = fluid.data(
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                name='data', shape=[-1, 3, 2, 2], dtype='float32')
            fluid.layers.similarity_focus(input=data, axis=1, indexes=[0])
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    """
    helper = LayerHelper('similarity_focus', **locals())
    # check attrs
    if isinstance(axis, int) is False:
        raise TypeError("axis must be int type.")
    if isinstance(indexes, list) is False:
        raise TypeError("indexes must be list type.")
    if axis != 1 and axis != 2 and axis != 3:
        raise ValueError("axis must be 1, 2 or 3.")
    if len(indexes) == 0:
        raise ValueError("indexes can not be empty.")

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    if name is None:
        out = helper.create_variable_for_type_inference(dtype=input.dtype)
    else:
        out = helper.create_variable(
            name=name, dtype=input.dtype, persistable=False)
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    helper.append_op(
        type='similarity_focus',
        inputs={'X': input},
        outputs={'Out': out},
        attrs={"axis": axis,
               "indexes": indexes})
    return out
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def hash(input, hash_size, num_hash=1, name=None):
    """
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    This OP hash the input to an integer less than the hash_size.
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    The hash algorithm we used was xxHash - Extremely fast hash algorithm
    (https://github.com/Cyan4973/xxHash/tree/v0.6.5)
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    Args:
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        input(Variable): A **Two-Dimensional** LoDTensor with type int32, int64.
             **Only support LoDTensor**.
        num_hash(int, optional): The times of hash, default is 1.
        name(str, optional): The default value is None. Normally there is no
            need for user to set this property. For more information, please
            refer to :ref:`api_guide_Name`.
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    Returns:
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       Variable: A LoDTensor with the same data type as input.
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    Examples:
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        .. code-block:: python
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11801
            import paddle.fluid as fluid
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            import numpy as np
11803

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            place = fluid.core.CPUPlace()
11805

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            x = fluid.data(name="x", shape=[1], dtype="int32", lod_level=1)
            res = fluid.layers.hash(name="res",input=x, hash_size=1000, num_hash=4)
11808

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            exe = fluid.Executor(place)
            exe.run(fluid.default_startup_program())
            in1 = np.array([[1,2],[3,4]]).astype("int32")
            print(in1)
            x_i = fluid.core.LoDTensor()
            x_i.set(in1,place)
            x_i.set_recursive_sequence_lengths([[0,2]])
            res = exe.run(fluid.default_main_program(), feed={'x':x_i}, fetch_list=[res], return_numpy=False)
            print(np.array(res[0]))
            # [[[722]
            #   [407]
            #   [337]
            #   [395]]
            #  [[603]
            #   [590]
            #   [386]
            #   [901]]]
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    """
    helper = LayerHelper('hash', **locals())
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    out = helper.create_variable_for_type_inference(
        helper.input_dtype(), stop_gradient=True)
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    helper.append_op(
        type='hash',
        inputs={'X': input},
        outputs={'Out': out},
        attrs={'num_hash': num_hash,
               'mod_by': hash_size})
    return out
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@templatedoc()
11840 11841
def grid_sampler(x, grid, name=None):
    """
11842
    This operation samples input X by using bilinear interpolation based on
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    flow field grid, which is usually gennerated by :code:`affine_grid` . The grid of
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    shape [N, H, W, 2] is the concatenation of (x, y) coordinates
    with shape [N, H, W] each, where x is indexing the 4th dimension
    (in width dimension) of input data x and y is indexng the 3rd
11847
    dimention (in height dimension), finally results is the bilinear
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    interpolation value of 4 nearest corner points. The output tensor 
    shape will be [N, C, H, W].
11850

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    .. code-block:: text
11852

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        Step 1:
        Get (x, y) grid coordinates and scale to [0, H-1/W-1].
11855

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        .. code-block:: text

            grid_x = 0.5 * (grid[:, :, :, 0] + 1) * (W - 1)
            grid_y = 0.5 * (grid[:, :, :, 1] + 1) * (H - 1)
11860

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        Step 2:
        Indices input data X with grid (x, y) in each [H, W] area, and bilinear
        interpolate point value by 4 nearest points.
11864

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          wn ------- y_n ------- en
          |           |           |
          |          d_n          |
          |           |           |
         x_w --d_w-- grid--d_e-- x_e
          |           |           |
          |          d_s          |
          |           |           |
          ws ------- y_s ------- wn
11874

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        x_w = floor(x)              // west side x coord
        x_e = x_w + 1               // east side x coord
        y_n = floor(y)              // north side y coord
        y_s = y_s + 1               // south side y coord
11879

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        d_w = grid_x - x_w          // distance to west side
        d_e = x_e - grid_x          // distance to east side
        d_n = grid_y - y_n          // distance to north side
        d_s = y_s - grid_y          // distance to south side
11884

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        wn = X[:, :, y_n, x_w]      // north-west point value
        en = X[:, :, y_n, x_e]      // north-east point value
        ws = X[:, :, y_s, x_w]      // south-east point value
        es = X[:, :, y_s, x_w]      // north-east point value
11889

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        output = wn * d_e * d_s + en * d_w * d_s
               + ws * d_e * d_n + es * d_w * d_n
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    Args:
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        x(Variable): The input tensor, which is a 4-D tensor with shape
                     [N, C, H, W], N is the batch size, C is the channel
                     number, H and W is the feature height and width.
                     The data type is float32 or float64.
        grid(Variable): Input grid tensor of shape [N, H, W, 2]. The
                        data type is float32 or float64.
        name(str, optional): For detailed information, please refer
                             to :ref:`api_guide_Name`. Usually name is no need to set and
                             None by default.
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    Returns:
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        Variable: Output of shape [N, C, H, W] data samples input X
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                  using bilnear interpolation based on input grid.
                  The data type is same as input tensor.
11908

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    Examples:

        .. code-block:: python

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            import paddle.fluid as fluid

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            # use with affine_grid
            x = fluid.data(name='x', shape=[None, 10, 32, 32], dtype='float32')
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            theta = fluid.layers.data(name='theta', shape=[2, 3], dtype='float32')
            grid = fluid.layers.affine_grid(theta=theta, out_shape=[3, 10, 32, 32])
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            out = fluid.layers.grid_sampler(x=x, grid=grid)
11920

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    """
    helper = LayerHelper("grid_sampler", **locals())

    if not isinstance(x, Variable):
        return ValueError("The x should be a Variable")

    if not isinstance(grid, Variable):
        return ValueError("The grid should be a Variable")

11930
    out = helper.create_variable_for_type_inference(x.dtype)
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    ipts = {'X': x, 'Grid': grid}

11933
    helper.append_op(type='grid_sampler', inputs=ipts, outputs={'Output': out})
11934 11935 11936
    return out


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def log_loss(input, label, epsilon=1e-4, name=None):
    """
    **Negative Log Loss Layer**

    This layer accepts input predictions and target label and returns the
    negative log loss.

    .. math::

        Out = -label * \\log{(input + \\epsilon)}
              - (1 - label) * \\log{(1 - input + \\epsilon)}

    Args:
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        input (Variable|list):  A 2-D tensor with shape [N x 1], where N is the
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                                batch size. This input is a probability computed
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                                by the previous operator. Data type float32.
        label (Variable|list):  The ground truth which is a 2-D tensor with
                                shape [N x 1], where N is the batch size. 
                                Data type float32.
        epsilon (float, optional): A small number for numerical stability. Default 1e-4.
        name(str|None): For detailed information, please refer to 
            :ref:`api_guide_Name` . Usually name is no need to set and None by default.
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    Returns:
        Variable: A 2-D tensor with shape [N x 1], the negative log loss.

    Examples:
        .. code-block:: python

11966
          import paddle.fluid as fluid
11967 11968
          label = fluid.data(name='label', shape=[None, 1], dtype='float32')
          prob = fluid.data(name='prob', shape=[None, 1], dtype='float32')
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          cost = fluid.layers.log_loss(input=prob, label=label)
    """
    helper = LayerHelper('log_loss', **locals())

    if name is None:
        loss = helper.create_variable_for_type_inference(dtype=input.dtype)
    else:
        loss = helper.create_variable(
            name=name, dtype=input.dtype, persistable=False)

    helper.append_op(
        type='log_loss',
        inputs={'Predicted': [input],
                'Labels': [label]},
        outputs={'Loss': [loss]},
        attrs={'epsilon': epsilon})
    return loss


def add_position_encoding(input, alpha, beta, name=None):
    """
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    This operator performs weighted sum of input feature at each position
    (position in the sequence) and the corresponding position encoding.
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    For more details of position encoding, please refer to `Attention Is All You 
    Need <http://arxiv.org/pdf/1706.03762.pdf>`_ .
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    The formula is as follows:
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    .. math::
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        PE(pos, 2i) &= \\sin{(pos / 10000^{2i / P})}   \\\\
        PE(pos, 2i + 1) &= \\cos{(pos / 10000^{2i / P})}  \\\\
        Out(:, pos, i) &= \\alpha * input(:, pos, i) + \\beta * PE(pos, i)
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    Where:
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      - :math:`PE(pos, 2i)` : the value at even index `2i` for encoding of position `pos`.
      - :math:`PE(pos, 2i + 1)` : the value at odd index `2i+1` for encoding of position `pos`

    Args:
        input(Variable): A Tensor or LoDTensor (lod level is 1). If it is a
            Tensor, the shape should be `[N, M, P]`, where `N` stands for
            batch size, `M` for sequence length, `P` for the size of feature
            dimension. If it is a LoDTensor, the shape should be `[N, P]`,
            where `N` stands for the total sequence lengths in this mini-batch,
            `P` for the size of feature. The data type should be float32 or float64.
        alpha(float): Indicate the weight coefficient for `input` when performing
            weighted sum.
        beta(float): Indicate the weight coefficient for position encoding when
            performing weighted sum.
        name(str, optional): For detailed information, please refer 
            to :ref:`api_guide_Name`. Usually name is no need to set and 
            None by default.
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    Returns:
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        Variable: A Tensor or LoDTensor. It has the same shape, data type and lod as `input`.
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    Examples:
        .. code-block:: python

12028 12029
          import paddle.fluid as fluid

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          tensor = fluid.data(
12031
              name='tensor',
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              shape=[None, 64, 512],
              dtype='float32')
12034 12035
          position_tensor = fluid.layers.add_position_encoding(
              input=tensor, alpha=1.0, beta=1.0)
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    """
    helper = LayerHelper('add_position_encoding', **locals())
    dtype = helper.input_dtype()

    if name is None:
        out = helper.create_variable_for_type_inference(dtype=dtype)
    else:
        out = helper.create_variable(name=name, dtype=dtype, persistable=False)

    helper.append_op(
        type="add_position_encoding",
        inputs={"X": input},
        outputs={"Out": out},
        attrs={"alpha": alpha,
               "beta": beta})
    return out
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def bilinear_tensor_product(x,
                            y,
                            size,
                            act=None,
                            name=None,
                            param_attr=None,
                            bias_attr=None):
    """
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    **Bilinear Tensor Product Layer**
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    This layer performs bilinear tensor product on two inputs.
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    For example:

    .. math::
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       out_{i} = x * W_{i} * {y^\mathrm{T}}, i=0,1,...,size-1
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    In this formula:
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      - :math:`x`: the first input contains M elements, shape is [batch_size, M].
      - :math:`y`: the second input contains N elements, shape is [batch_size, N].
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      - :math:`W_{i}`: the i-th learned weight, shape is [M, N].
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      - :math:`out_{i}`: the i-th element of out, shape is [batch_size, size].
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      - :math:`y^\mathrm{T}`: the transpose of :math:`y_{2}`.

    Args:
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        x (Variable): 2-D input tensor with shape [batch_size, M]. Data type 
            is float32 or float64.
        y (Variable): 2-D input tensor with shape [batch_size, N]. Data type 
            should be same as **x**.
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        size (int): The dimension of this layer.
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        act (str|None): Activation to be applied to the output of this layer. Default None.
        name(str|None): For detailed information, please refer to 
            :ref:`api_guide_Name` . Usually name is no need to set and None by default.
        param_attr (ParamAttr|None): To specify the weight parameter attribute. 
            Default: None, which means the default weight parameter property is 
            used. See usage for details in :ref:`api_fluid_ParamAttr` .
        bias_attr (ParamAttr|None): To specify the bias parameter attribute. 
            Default: None, which means the default bias parameter property is 
            used. See usage for details in :ref:`api_fluid_ParamAttr` .
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    Returns:
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        Variable: A 2-D Tensor of shape [batch_size, size]. Data type is the same as input **x**.
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    Examples:
        .. code-block:: python

12099
          import paddle.fluid as fluid
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          layer1 = fluid.data("t1", shape=[-1, 5], dtype="float32")
          layer2 = fluid.data("t2", shape=[-1, 4], dtype="float32")
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          tensor = fluid.layers.bilinear_tensor_product(x=layer1, y=layer2, size=1000)
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    """
    helper = LayerHelper('bilinear_tensor_product', **locals())
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    dtype = helper.input_dtype('x')
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    param_shape = [size, x.shape[1], y.shape[1]]

    w = helper.create_parameter(
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        attr=helper.param_attr, shape=param_shape, dtype=dtype, is_bias=False)
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    if name is None:
        out = helper.create_variable_for_type_inference(dtype=dtype)
    else:
        out = helper.create_variable(name=name, dtype=dtype, persistable=False)

    inputs = {"X": x, "Y": y, "Weight": w}
    if helper.bias_attr:
        bias_size = [1, size]
        bias = helper.create_parameter(
            attr=helper.bias_attr, shape=bias_size, dtype=dtype, is_bias=True)
        inputs["Bias"] = bias
    helper.append_op(
        type="bilinear_tensor_product", inputs=inputs, outputs={"Out": out})

    # add activation
    return helper.append_activation(out)
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@templatedoc()
def get_tensor_from_selected_rows(x, name=None):
    """
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    This operator gets tensor data from input with SelectedRows type, and outputs a LoDTensor.

    .. code-block:: text

        input x is SelectedRows:
           x.rows = [0, 5, 5, 4, 19]
           x.height = 20
           x.value = [[1, 1] [2, 2] [2, 2] [3, 3] [6, 6]]

        Ouput is LoDTensor:
           out.shape = [5, 2]
           out.data = [[1, 1],
                       [2, 2],
                       [2, 2],
                       [3, 3],
                       [6, 6]]
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    Args:
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        x(SelectedRows): Input with SelectedRows type. The data type is float32, float64, int32 or int64.
        name(str, optional): The default value is None.  Normally there is no need for user to set this property.
            For more information, please refer to :ref:`api_guide_Name` .
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    Returns:
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        Variable: LoDTensor transformed from SelectedRows. The data type is same with input.
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    Examples:
        .. code-block:: python
	    
            import paddle.fluid as fluid
            b = fluid.default_main_program().global_block()
            input = b.create_var(name="X", dtype="float32", persistable=True, type=fluid.core.VarDesc.VarType.SELECTED_ROWS)
            out = fluid.layers.get_tensor_from_selected_rows(input)
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    """

    helper = LayerHelper('get_tensor_from_selected_rows', **locals())
    out = helper.create_variable_for_type_inference(dtype=x.dtype)
    helper.append_op(
        type='get_tensor_from_selected_rows',
        inputs={'X': x},
        outputs={'Out': out},
        attrs={})
    return out
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def shuffle_channel(x, group, name=None):
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    """
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    This operator shuffles the channels of input x.
    It divide the input channels in each group into :attr:`group` subgroups,
    and obtain a new order by selecting element from every subgroup one by one.

    Please refer to the paper
    https://arxiv.org/pdf/1707.01083.pdf
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    .. code-block:: text
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        Given a 4-D tensor input with the shape (N, C, H, W):
            input.shape = (1, 4, 2, 2)
            input.data =[[[[0.1, 0.2],
                           [0.2, 0.3]],

                          [[0.3, 0.4],
                           [0.4, 0.5]],

                          [[0.5, 0.6],
                           [0.6, 0.7]],

                          [[0.7, 0.8],
                           [0.8, 0.9]]]]
            Given group: 2
            then we get a 4-D tensor out whth the same shape of input:
            out.shape = (1, 4, 2, 2)
            out.data = [[[[0.1, 0.2],
                          [0.2, 0.3]],
                          
                         [[0.5, 0.6],
                          [0.6, 0.7]],
                          
                         [[0.3, 0.4],
                          [0.4, 0.5]],
                          
                         [[0.7, 0.8],
                          [0.8, 0.9]]]]
                        
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    Args: 
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        x(Variable): The input tensor variable. It should be a 4-D tensor with shape [N, C, H, W]
        group(int): Indicating the conuts of subgroups, It should divide the number of channels.
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    Returns:
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        out(Variable): the channels shuffling result is a tensor variable with the 
        same shape and same type as the input.
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    Raises:
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        ValueError: If group is not an int type variable.
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    Examples:
        .. code-block:: python
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12230
            import paddle.fluid as fluid
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            input = fluid.data(name='input', shape=[None,4,2,2], dtype='float32')
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            out = fluid.layers.shuffle_channel(x=input, group=2)
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    """
    helper = LayerHelper("shuffle_channel", **locals())

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    out = helper.create_variable_for_type_inference(dtype=x.dtype)
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    if not isinstance(group, int):
        raise TypeError("group must be int type")

    helper.append_op(
        type="shuffle_channel",
        inputs={"X": x},
        outputs={"Out": out},
        attrs={"group": group})
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    return out
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@templatedoc()
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def temporal_shift(x, seg_num, shift_ratio=0.25, name=None):
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    """
    **Temporal Shift Operator**
    
    ${comment}
                        
    Args: 
        x(Variable): ${x_comment}
        seg_num(int): ${seg_num_comment}
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        shift_ratio(float): ${shift_ratio_comment}
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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
                             None by default.
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    Returns:
        out(Variable): The temporal shifting result is a tensor variable with the 
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        same shape and same data type as the input.
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    Raises:
        TypeError: seg_num must be int type.

    Examples:
        .. code-block:: python

12274
            import paddle.fluid as fluid
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            input = fluid.data(name='input', shape=[None,4,2,2], dtype='float32')
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            out = fluid.layers.temporal_shift(x=input, seg_num=2, shift_ratio=0.2)
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    """
    helper = LayerHelper("temporal_shift", **locals())

    out = helper.create_variable_for_type_inference(dtype=x.dtype)

    if not isinstance(seg_num, int):
        raise TypeError("seg_num must be int type.")

    helper.append_op(
        type="temporal_shift",
        inputs={"X": x},
        outputs={"Out": out},
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        attrs={"seg_num": seg_num,
               "shift_ratio": shift_ratio})
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    return out


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class PyFuncRegistry(object):
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    _register_funcs = []

    def __init__(self, func):
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        if func is None or not callable(func):
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            raise TypeError('func must be a Python function')

        self._func = func
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        # find named args using reflection
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        args = inspect.getargspec(self._func)
        if len(args[0]) == 0 and args[1] is None and args[2] is None:
            # Function with no inputs
            self._named_args = None
        else:
            self._named_args = args[0]
        self._id = core._append_python_callable_object_and_return_id(self)
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        '''
        Why record self here?

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        1. For debug usage. Users can call
           :code:`py_func.registered_func(idx)` method
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           to find the registered function corresponding
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           to :code:`idx`.
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        2. For increasing reference count of self.
           It seems that to release Python object
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           whose reference count is 1 would cause
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           segmentation fault error in C++ side.
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           May be lack of Python GC in C++ side?
        '''
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        PyFuncRegistry._register_funcs.append(self)
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    @classmethod
    def registered_func(cls, idx):
        return cls._register_funcs[idx]._func

    @classmethod
    def registered_func_num(cls):
        return len(cls._register_funcs)

    @property
    def id(self):
        return self._id

    def __call__(self, *args):
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        if self._named_args is None:
            func_ret = self._func()
        else:
            kwargs = dict()
            idx = 0
            for arg in self._named_args:
                kwargs[arg] = args[idx]
                idx += 1
            func_ret = self._func(*args[idx:], **kwargs)
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        if not isinstance(func_ret, (list, tuple)):
            func_ret = (func_ret, )
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        ret = []
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        for each_ret in func_ret:
            if each_ret is None or isinstance(each_ret, core.LoDTensor):
                ret.append(each_ret)
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                continue

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            if not isinstance(each_ret, np.ndarray):
                each_ret = np.array(each_ret)
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            tensor = core.LoDTensor()
            tensor.set(each_ret, core.CPUPlace())
            ret.append(tensor)
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        return tuple(ret)
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@templatedoc()
def py_func(func, x, out, backward_func=None, skip_vars_in_backward_input=None):
    """
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    This OP is used to register customized Python OP to Paddle Fluid. The design 
    principe of py_func is that LodTensor and numpy array can be converted to each
    other easily. So you can use Python and numpy API to register a python OP.

    The forward  function of the registered OP is ``func`` and the backward function 
    of that is  ``backward_func``. Paddle will call ``func`` at forward runtime and 
    call ``backward_func`` at backward runtime(if ``backward_func`` is not  None). 
12378
    ``x`` is the input of ``func``, whose type must be LoDTensor; ``out`` is 
12379
    the output of ``func``, whose type can be either LoDTensor or numpy array.
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    The input of the backward function ``backward_func`` is ``x``, ``out`` and 
    the gradient of ``out``. If some variables of ``out`` have no gradient, the 
    relevant input variable of ``backward_func`` is None. If some variables of 
    ``x`` do not have a gradient, the user should return None in ``backward_func``.

    The data type and shape of ``out`` should also be set correctly before this 
    API is called, and the data type and shape of the gradient of ``out`` and 
    ``x`` will be inferred automatically.

    This API can also be used to debug the neural network by setting the ``func``
    as a function that only print variables.

    Args:
        func (callable): The forward function of the registered OP. When the network
            is running, the forward output ``out`` will be calculated according to this 
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            function and the forward input ``x``. In ``func`` , it's suggested that we 
            actively convert LoDTensor into a numpy array, so that we can use Python and
            numpy API arbitrarily. If not, some operations of numpy may not be compatible.
        x (Variable|tuple(Variale)|list[Variale]): The input of the forward function ``func``. 
            It can be Variable|tuple(Variale)|list[Variale], where Variable is LoDTensor or 
            Tenosor. In addition, Multiple Variable should be passed in the form of tuple(Variale)
            or list[Variale].
        out (Variable|tuple(Variale)|list[Variale]): The output of the forward function ``func``, 
            it can be Variable|tuple(Variale)|list[Variale], where Variable can be either LoDTensor
            or numpy array. Since Paddle cannot automatically infer the shape and type of ``out``, 
            you must create ``out`` in advance.
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        backward_func (callable, optional): The backward function of the registered OP. 
            Its default value is None, which means there is no reverse calculation. If 
            it is not None, ``backward_func`` is called to calculate the gradient of 
            ``x`` when the network is at backward runtime.
        skip_vars_in_backward_input (Variable, optional): It's used to limit the input 
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            variable list of ``backward_func``, and it can be Variable|tuple(Variale)|list[Variale]. 
            It must belong to either ``x`` or ``out``. The default  value is None, which means 
            that no variables need to be removed from ``x`` and ``out``. If it is not None, 
            these variables will not be the input of ``backward_func``. This parameter is only 
            useful when ``backward_func`` is not None.
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    Returns: 
12419
        Variable|tuple(Variale)|list[Variale]: The output ``out`` of the forward function ``func``.
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    Examples:
12422
        .. code-block:: python
12423 12424
	    
            # example 1:
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            import paddle.fluid as fluid
            import six

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            # Creates a forward function, LodTensor can be input directly without
            # being converted into numpy array.
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            def tanh(x):
                return np.tanh(x)

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            # Skip x in backward function and return the gradient of x
            # LodTensor must be actively converted to numpy array, otherwise, 
            # operations such as +/- can't be used.
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            def tanh_grad(y, dy):
                return np.array(dy) * (1 - np.square(np.array(y)))
12438 12439
            
            # Creates a forward function for debugging running networks(print value)
12440 12441
            def debug_func(x):
                print(x)
12442 12443 12444 12445
            
            def create_tmp_var(name, dtype, shape):
                return fluid.default_main_program().current_block().create_var(
                    name=name, dtype=dtype, shape=shape)
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            def simple_net(img, label):
                hidden = img
                for idx in six.moves.range(4):
                    hidden = fluid.layers.fc(hidden, size=200)
                    new_hidden = create_tmp_var(name='hidden_{}'.format(idx),
                        dtype=hidden.dtype, shape=hidden.shape)

                    # User-defined forward and backward 
                    hidden = fluid.layers.py_func(func=tanh, x=hidden,
                        out=new_hidden, backward_func=tanh_grad,
                        skip_vars_in_backward_input=hidden)

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                    # User-defined debug functions that print out the input LodTensor
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                    fluid.layers.py_func(func=debug_func, x=hidden, out=None)

                prediction = fluid.layers.fc(hidden, size=10, act='softmax')
                loss = fluid.layers.cross_entropy(input=prediction, label=label)
                return fluid.layers.mean(loss)
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            # example 2: 
            # This example shows how to turn LoDTensor into numpy array and 
            # use numpy API to register an Python OP
            import paddle.fluid as fluid
            import numpy as np

            def element_wise_add(x, y): 
                # LodTensor must be actively converted to numpy array, otherwise, 
                # numpy.shape can't be used.
                x = np.array(x)    
                y = np.array(y)

                if x.shape != y.shape:
                    raise AssertionError("the shape of inputs must be the same!")

                result = np.zeros(x.shape, dtype='int32')
                for i in range(len(x)):
                    for j in range(len(x[0])):
                        result[i][j] = x[i][j] + y[i][j]

                return result

            def create_tmp_var(name, dtype, shape):
                return fluid.default_main_program().current_block().create_var(
                            name=name, dtype=dtype, shape=shape)

            def py_func_demo():
                start_program = fluid.default_startup_program()
                main_program = fluid.default_main_program()

                # Input of the forward function
                x = fluid.data(name='x', shape=[2,3], dtype='int32')
                y = fluid.data(name='y', shape=[2,3], dtype='int32')
                
                # Output of the forward function, name/dtype/shape must be specified
                output = create_tmp_var('output','int32', [3,1])

                # Multiple Variable should be passed in the form of tuple(Variale) or list[Variale]
                fluid.layers.py_func(func=element_wise_add, x=[x,y], out=output)

                exe=fluid.Executor(fluid.CPUPlace())
                exe.run(start_program)

                # Feed numpy array to main_program
                input1 = np.random.randint(1, 10, size=[2,3], dtype='int32')
                input2 = np.random.randint(1, 10, size=[2,3], dtype='int32')
                out = exe.run(main_program, 
                            feed={'x':input1, 'y':input2},
                            fetch_list=[output.name])
                print("{0} + {1} = {2}".format(input1, input2, out))

            py_func_demo()

            # Reference output:
            # [[5, 9, 9]   + [[7, 8, 4]  =  [array([[12, 17, 13]
            #  [7, 5, 2]]     [1, 3, 3]]            [8, 8, 5]], dtype=int32)]
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    """
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    helper = LayerHelper('py_func', **locals())
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    if x is None:
        x = []
    elif isinstance(x, Variable):
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        x = [x]
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    elif isinstance(x, tuple):
        x = list(x)
    elif not isinstance(x, (list, tuple, Variable)):
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        raise TypeError('Input must be Variable/list(Variable)/tuple(Variable)')
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    if out is None:
        out_list = []
    elif isinstance(out, Variable):
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        out_list = [out]
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    elif isinstance(out, tuple):
        out_list = list(out)
    elif not isinstance(x, (list, tuple, Variable)):
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        raise TypeError(
            'Output must be Variable/list(Variable)/tuple(Variable)')
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    fwd_func_id = PyFuncRegistry(func).id
    bwd_func_id = PyFuncRegistry(
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        backward_func).id if backward_func is not None else -1
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    for each_out in out_list:
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        if len(each_out.shape) == 0:
            raise ValueError(
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                'Output shapes of py_func op should be provided by users manually'
            )
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    backward_skip_vars = set()
    if backward_func is not None and skip_vars_in_backward_input is not None:
        if isinstance(skip_vars_in_backward_input, Variable):
            skip_vars_in_backward_input = [skip_vars_in_backward_input]

        fwd_in_out = [v.name for v in x]
        fwd_in_out.extend([v.name for v in out_list])
        fwd_in_out = set(fwd_in_out)
        backward_skip_vars = set()
        for v in skip_vars_in_backward_input:
            if not v.name in fwd_in_out:
                raise ValueError(
                    'Variable {} is not found in forward inputs and outputs'
                    .format(v.name))
            backward_skip_vars.add(v.name)
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    helper.append_op(
        type='py_func',
        inputs={'X': x},
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        outputs={'Out': out_list},
        attrs={
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            'forward_callable_id': fwd_func_id,
            'backward_callable_id': bwd_func_id,
            'backward_skip_vars': list(backward_skip_vars)
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        })
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    return out
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# For debug usage
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py_func.registered_func = PyFuncRegistry.registered_func
py_func.registered_func_num = PyFuncRegistry.registered_func_num


12586 12587 12588 12589 12590 12591 12592 12593 12594 12595 12596
@templatedoc()
def psroi_pool(input,
               rois,
               output_channels,
               spatial_scale,
               pooled_height,
               pooled_width,
               name=None):
    """
    ${comment}

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    Parameters:
12598
        input (Variable): ${x_comment}
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        rois (Variable): LoDTensor, ROIs (Regions of Interest) to pool over.It should be
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                         a 2-D LoDTensor of shape (num_rois, 4), the lod level
                         is 1. Given as [[x1, y1, x2, y2], ...], (x1, y1) is
                         the top left coordinates, and (x2, y2) is the bottom
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                         right coordinates. The data type is the same as `input`
        output_channels (int): ${output_channels_comment}
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        spatial_scale (float): ${spatial_scale_comment} Default: 1.0
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        pooled_height (int): ${pooled_height_comment} Default: 1
        pooled_width (int): ${pooled_width_comment} Default: 1
        name(str, optional): The default value is None.  
                             Normally there is no need for user to set this property.  
                             For more information, please refer to :ref:`api_guide_Name`
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    Returns:
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        ${out_comment}.

    Return Type:
        Variable
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    Examples:
        .. code-block:: python

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            import paddle.fluid as fluid
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            x = fluid.data(name='x', shape=[100, 490, 28, 28], dtype='float32')
            rois = fluid.data(name='rois', shape=[None, 4], lod_level=1, dtype='float32')
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            pool_out = fluid.layers.psroi_pool(x, rois, 10, 1.0, 7, 7)
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    """
    helper = LayerHelper('psroi_pool', **locals())
    # check attrs
    if not isinstance(output_channels, int):
        raise TypeError("output_channels must be int type")
    if not isinstance(spatial_scale, float):
        raise TypeError("spatial_scale must be float type")
    if not isinstance(pooled_height, int):
        raise TypeError("pooled_height must be int type")
    if not isinstance(pooled_width, int):
        raise TypeError("pooled_width must be int type")
    dtype = helper.input_dtype()
    out = helper.create_variable_for_type_inference(dtype)
    helper.append_op(
        type='psroi_pool',
        inputs={'X': input,
                'ROIs': rois},
        outputs={'Out': out},
        attrs={
            'output_channels': output_channels,
            'spatial_scale': spatial_scale,
            'pooled_height': pooled_height,
            'pooled_width': pooled_width
        })
    return out
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@templatedoc()
def prroi_pool(input,
               rois,
               spatial_scale=1.0,
               pooled_height=1,
               pooled_width=1,
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               batch_roi_nums=None,
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               name=None):
    """
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    The precise roi pooling implementation for paddle. Reference: https://arxiv.org/pdf/1807.11590.pdf
12662 12663

    Args:
12664
        input (Variable):The input of precise roi pooliing.The shape of input tensor is
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                        [N,C,H,W]. Where N is batch size,C is number of input channels,H
                        is height of the feature, and W is the width of the feature.
        rois (Variable): ROIs (Regions of Interest) to pool over.It should be
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                        a 2-D LoDTensor or Tensor of shape (num_rois, 4), the lod level
                        is 1 when it is LoDTensor. The LoD include the rois's batch index
                        information. If rois is Tensor, its batch index information should
                        be provided by batch_index.
                        Given as [[x1, y1, x2, y2], ...], (x1, y1) is
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                        the top left coordinates, and (x2, y2) is the bottom
                        right coordinates.
        spatial_scale (float): Ratio of input feature map height (or width) to raw image height (or width).
                             Equals the reciprocal of total stride in convolutional layers, Default: 1.0.
        pooled_height (integer): The pooled output height. Default: 1.
        pooled_width (integer): The pooled output width. Default: 1.
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        batch_roi_nums (Variable): The number of roi for each image in batch. It 
                         shoule be 1-D Tensor, with shape [N] and dtype int64, 
                         where N is the batch size. Default: None. Be note: The lod of input should be
                         empty when batch_roi_nums has values;
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        name (str, default None): The name of this operation.

    Returns:
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        Variable(Tensor):The shape of the returned Tensor is (N, C, pooled_height, pooled_width), with value type float32,float16. N, C denote batch_size and channels of input respectively.
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    Examples:
        .. code-block:: python

12691
            ## prroi_pool without batch_roi_num
12692
            import paddle.fluid as fluid
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            x = fluid.data(name='x', shape=[None, 490, 28, 28], dtype='float32')
            rois = fluid.data(name='rois', shape=[None, 4], lod_level=1, dtype='float32')
12695
            pool_out = fluid.layers.prroi_pool(x, rois, 1.0, 7, 7)
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            ## prroi_pool with batch_roi_num
            batchsize=4
            x2 = fluid.data(name='x2', shape=[batchsize, 490, 28, 28], dtype='float32')
            rois2 = fluid.data(name='rois2', shape=[batchsize, 4], dtype='float32')
            batch_rois_num = fluid.data(name='rois_nums', shape=[batchsize], dtype='int64')
            pool_out2 = fluid.layers.prroi_pool(x2, rois2, 1.0, 7, 7, batch_roi_nums=batch_rois_num)


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    """
    helper = LayerHelper('prroi_pool', **locals())
    # check attrs
    if not isinstance(spatial_scale, float):
        raise TypeError("spatial_scale must be float type")
    if not isinstance(pooled_height, int):
        raise TypeError("pooled_height must be int type")
    if not isinstance(pooled_width, int):
        raise TypeError("pooled_width must be int type")
    dtype = helper.input_dtype()
    out = helper.create_variable_for_type_inference(dtype)
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    inputs_op = {'X': input, 'ROIs': rois}
    if batch_roi_nums is not None:
        inputs_op['BatchRoINums'] = batch_roi_nums
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    helper.append_op(
        type='prroi_pool',
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        inputs=inputs_op,
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        outputs={'Out': out},
        attrs={
            'spatial_scale': spatial_scale,
            'pooled_height': pooled_height,
            'pooled_width': pooled_width
        })
    return out
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def pixel_shuffle(x, upscale_factor):
    """

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    This op rearranges elements in a tensor of shape [N, C, H, W]
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    to a tensor of shape [N, C/r**2, H*r, W*r].
    This is useful for implementing efficient sub-pixel convolution
    with a stride of 1/r.
    Please refer to the paper: `Real-Time Single Image and Video Super-Resolution 
    Using an Efficient Sub-Pixel Convolutional Neural Network <https://arxiv.org/abs/1609.05158v2>`_ .
    by Shi et. al (2016) for more details.

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    Parameters:
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        x(Variable): 4-D tensor, the data type should be float32 or float64.
        upscale_factor(int): factor to increase spatial resolution.
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    Returns:
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        Out(Variable): Reshaped tensor according to the new dimension.
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    Raises:
        ValueError: If the square of upscale_factor cannot divide the channels of input.

    Examples:
        .. code-block:: python

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	    # declarative mode
	    import paddle.fluid as fluid
	    import numpy as np
	    input = fluid.data(name="input", shape=[2,9,4,4])
	    output = fluid.layers.pixel_shuffle(x=input, upscale_factor=3)
	    place = fluid.CPUPlace()
	    exe = fluid.Executor(place)
	    exe.run(fluid.default_startup_program())
 
	    input_data = np.random.rand(2,9,4,4).astype("float32")
	    output_data = exe.run(fluid.default_main_program(),
                feed={"input":input_data},
                fetch_list=[output],
                return_numpy=True)
 
 	    # print(output.shape)
	    # (2L, 1L, 12L, 12L)
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    """

    helper = LayerHelper("pixel_shuffle", **locals())

    out = helper.create_variable_for_type_inference(dtype=x.dtype)

    if not isinstance(upscale_factor, int):
        raise TypeError("upscale factor must be int type")

    helper.append_op(
        type="pixel_shuffle",
        inputs={"X": x},
        outputs={"Out": out},
        attrs={"upscale_factor": upscale_factor})
    return out


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def fsp_matrix(x, y):
    """

    **FSP matrix op**

12796
    This op is used to calculate the flow of solution procedure (FSP) matrix of two 4-D Tensor feature maps.
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    Given feature map x with shape [x_channel, h, w] and feature map y with shape
    [y_channel, h, w], we can get the fsp matrix of x and y in two steps:

    1. reshape x into matrix with shape [x_channel, h * w] and reshape and
       transpose y into matrix with shape [h * w, y_channel].
    2. multiply x and y to get fsp matrix with shape [x_channel, y_channel].

    The output is a batch of fsp matrices.

    Args:

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        x (Variable): A 4-D Tensor feature map with shape [batch_size, x_channel, height, width].
                      A Tensor with type float32, float64.
        y (Variable): A 4-D Tensor feature map with shape [batch_size, y_channel, height, width].
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                      The y_channel can be different with the x_channel of Input(X)
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                      while the other dimensions must be the same with Input(X)'s. A Tensor with
                      type float32, float64.
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    Returns:

        fsp matrix (Variable): The output of FSP op with shape [batch_size, x_channel, y_channel].
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        The x_channel is the channel of x and the y_channel is the channel of y. A Tensor with
        type float32, float64.
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    Examples:

        .. code-block:: python

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            import paddle.fluid as fluid
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            data = fluid.data(name='data', shape=[None, 3, 32, 32])
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            feature_map_0 = fluid.layers.conv2d(data, num_filters=2,
                                                filter_size=3)
            feature_map_1 = fluid.layers.conv2d(feature_map_0, num_filters=2,
                                                filter_size=1)
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            loss = fluid.layers.fsp_matrix(feature_map_0, feature_map_1)

    """
    helper = LayerHelper('fsp_matrix', **locals())
    out = helper.create_variable_for_type_inference(dtype=helper.input_dtype(
        input_param_name='x'))
    helper.append_op(type='fsp', inputs={'X': x, 'Y': y}, outputs={'Out': out})
    return out
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def continuous_value_model(input, cvm, use_cvm=True):
    """
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    **continuous_value_model layers**
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    Now, this OP is used in CTR project to remove or dispose show and click value in :attr:`input`.
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    :attr:`input` is an embedding vector including show and click value, whose shape is :math:`[N, D]` (N is batch size. D is `2 + embedding dim` ).
    Show and click at first two dims of embedding vector D.
    If :attr:`use_cvm` is True, it will caculate :math:`log(show)` and :math:`log(click)` , and output shape is :math:`[N, D]` .
    If :attr:`use_cvm` is False, it will remove show and click from :attr:`input` , and output shape is :math:`[N, D - 2]` .
    :attr:`cvm` is show_click info, whose shape is :math:`[N, 2]` .
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    Args:
        input (Variable): The input variable. A 2-D LoDTensor with shape :math:`[N, D]` , where N is the batch size, D is `2 + the embedding dim` . `lod level = 1` .
        A Tensor with type float32, float64.
        cvm (Variable): Show and click variable. A 2-D Tensor with shape :math:`[N, 2]` , where N is the batch size, 2 is show and click.
        A Tensor with type float32, float64.
        use_cvm  (bool):  Use show_click or not. if use, the output dim is the same as input.
                          if not use, the output dim is `input dim - 2` (remove show and click)
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    Returns:
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        Variable: A 2-D LodTensor with shape :math:`[N, M]` . if :attr:`use_cvm` = True, M is equal to input dim D. if False, M is equal to `D - 2`. \
        A Tensor with same type as input.
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    Examples:
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        .. code-block:: python
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12871
          import paddle.fluid as fluid
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          input = fluid.data(name="input", shape=[64, 1], dtype="int64")
          label = fluid.data(name="label", shape=[64, 1], dtype="int64")
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          embed = fluid.layers.embedding(
                            input=input,
                            size=[100, 11],
                            dtype='float32')
          ones = fluid.layers.fill_constant_batch_size_like(input=label, shape=[-1, 1], dtype="int64", value=1)
          show_clk = fluid.layers.cast(fluid.layers.concat([ones, label], axis=1), dtype='float32')
          show_clk.stop_gradient = True
          input_with_cvm = fluid.layers.continuous_value_model(embed, show_clk, True)
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    """
    helper = LayerHelper('cvm', **locals())
    out = helper.create_variable(dtype=input.dtype)
    helper.append_op(
        type='cvm',
        inputs={'X': [input],
                'CVM': [cvm]},
        outputs={'Y': [out]},
        attrs={"use_cvm": use_cvm})
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    return out
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def where(condition):
    """
    Return an int64 tensor with rank 2, specifying the coordinate of true element in `condition`.

    Args:
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        condition(Variable): A bool tensor with rank at least 1, the data type is bool.
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    Returns:
12903
        Variable, the output data type is int64. : The tensor variable storing a 2-D tensor, which involves all coordinate. 
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    Examples:
        .. code-block:: python

12908
             import paddle.fluid as fluid
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             import paddle.fluid.layers as layers
             import numpy as np

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             # condition is a tensor [True, False, True]
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             condition = layers.assign(np.array([1, 0, 1], dtype='int32'))
             condition = layers.cast(condition, 'bool')
             out = layers.where(condition) # [[0], [2]]
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             # condition is a tensor [[True, False], [False, True]]
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             condition = layers.assign(np.array([[1, 0], [0, 1]], dtype='int32'))
             condition = layers.cast(condition, 'bool')
             out = layers.where(condition) # [[0, 0], [1, 1]]
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             # condition is a tensor [False, False, False]
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             condition = layers.assign(np.array([0, 0, 0], dtype='int32'))
             condition = layers.cast(condition, 'bool')
             out = layers.where(condition) # [[]]

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    """
    helper = LayerHelper("where", **locals())

    out = helper.create_variable_for_type_inference(
        dtype=core.VarDesc.VarType.INT64)

    helper.append_op(
        type='where', inputs={'Condition': condition}, outputs={'Out': [out]})
    return out
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def sign(x):
    """
12940
    This OP returns sign of every element in `x`: 1 for positive, -1 for negative and 0 for zero.
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    Args:
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        x(Variable|numpy.ndarray): The input variable could be N-D tensor or N-D numpy array, \
            the input data type is float32 or float64.
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    Returns:
12947
        Variable, the output data type is the same as input data type. : The output sign tensor with identical shape to input :attr:`x`.
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    Examples:
        .. code-block:: python

12952 12953 12954
          import paddle.fluid as fluid
          import numpy as np

12955 12956
          # [1.0, 0.0, -1.0]
          data = fluid.layers.sign(np.array([3.0, 0.0, -2.0], dtype='float32')) 
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    """

    helper = LayerHelper("sign", **locals())
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    check_type(x, 'x', (Variable, np.ndarray), 'sign')
    if isinstance(x, np.ndarray):
        x = assign(x)
    check_dtype(x.dtype, 'x', ['float16', 'float32', 'float64'], 'sign')
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    out = helper.create_variable_for_type_inference(dtype=x.dtype)

    helper.append_op(type='sign', inputs={'X': [x]}, outputs={'Out': [out]})

    return out
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def unique(x, dtype='int32'):
    """
    **unique** 

    Return a unique tensor for `x` and an index tensor pointing to this unique tensor.

    Args:
        x(Variable): A 1-D input tensor.
        dtype(np.dtype|core.VarDesc.VarType|str): The type of index tensor: int32, int64.

    Returns:
        tuple: (out, index). `out` is the unique tensor for `x`, with identical dtype to `x`, and \
            `index` is an index tensor pointing to `out`, by which user can recover the original `x` tensor.

    Examples:
        .. code-block:: python

             import numpy as np
             import paddle.fluid as fluid
             x = fluid.assign(np.array([2, 3, 3, 1, 5, 3], dtype='int32'))
             out, index = fluid.layers.unique(x) # out is [2, 3, 1, 5]; index is [0, 1, 1, 2, 3, 1]
    """

    helper = LayerHelper("unique", **locals())

    out = helper.create_variable_for_type_inference(dtype=x.dtype)

    index = helper.create_variable_for_type_inference(dtype)

    helper.append_op(
        type='unique',
        inputs={'X': x},
        attrs={'dtype': convert_np_dtype_to_dtype_(dtype)},
        outputs={'Out': [out],
                 'Index': [index]})

    return out, index


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def unique_with_counts(x, dtype='int32'):
    """
13012 13013
    This OP return a unique tensor for `x` , and count tensor that the count of unqiue result in raw input, \
    and an index tensor pointing to this unique tensor. 
13014

13015
    **NOTICE**: This op support the variable type of Tensor only.
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    Args:
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        x(Variable): A 1-D input tensor with input shape of :math:`[N]` , the input data type is float32, float64, int32, int64.
        dtype(np.dtype|core.VarDesc.VarType|str): The type of count and index tensor, it could be int32, int64. Defalut value is int32.
13020

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    Returns: 
        tuple, the variable type in tuple is Tensor, the output :attr:`out` data type is the same as input :attr:`x`, \
        and data type of output :attr:`index` and :attr:`count` will be int32 or int64.: The :attr:`out` is unique tensor for input :attr:`x`,\
        the data shape is :math:`[K]`, the `K` may be different to the `N` in shape of :attr:`x`. :attr:`index` is an index tensor pointing\
        to :attr:`out`, the data shape is :math:`[N]` , the data shape is the same as input :attr:`x`. :attr:`count` is count of unqiue element in\
        the :attr:`x`, the data shape is :math:`[K]`, the data shape is the same as output :attr:`out`.
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    Examples:
        .. code-block:: python

             import numpy as np
             import paddle.fluid as fluid
             x = fluid.layers.assign(np.array([2, 3, 3, 1, 5, 3], dtype='int32'))
             out, index, count = fluid.layers.unique_with_counts(x) # out is [2, 3, 1, 5]; index is [0, 1, 1, 2, 3, 1]
                                                        # count is [1, 3, 1, 1]
13036
            # x.shape=(6,) out.shape=(4,), index.shape=(6,), count.shape=(4,)
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    """
    if not (dtype == 'int32' or dtype == 'int64'):
        raise TypeError(
            "Op unique_with_counts, index dtype must be int32 or int64")

    if x is None or len(x.shape) != 1:
        raise ValueError(
            "Op unique_with_counts, x must not be null and size of dim must be 1"
        )

    helper = LayerHelper("unique_with_counts", **locals())

    out = helper.create_variable_for_type_inference(dtype=x.dtype)

    index = helper.create_variable_for_type_inference(dtype)

    count = helper.create_variable_for_type_inference(dtype)

    helper.append_op(
        type='unique_with_counts',
        inputs={'X': x},
        attrs={'dtype': convert_np_dtype_to_dtype_(dtype)},
        outputs={'Out': [out],
                 'Index': [index],
                 'Count': [count]})

    return out, index, count


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def deformable_conv(input,
                    offset,
                    mask,
                    num_filters,
                    filter_size,
                    stride=1,
                    padding=0,
                    dilation=1,
                    groups=None,
                    deformable_groups=None,
                    im2col_step=None,
                    param_attr=None,
                    bias_attr=None,
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                    modulated=True,
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                    name=None):
    """
13082
    **Deformable Convolution op**
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    Compute 2-D deformable convolution on 4-D input.
    Given input image x, output feature map y, the deformable convolution operation can be expressed as follow:
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    Deformable Convolution v2: 
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    .. math::

        y(p) = \sum_{k=1}^{K}{w_k * x(p + p_k + \Delta p_k) * \Delta m_k}
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    Deformable Convolution v1:
13095
    
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    .. math::

        y(p) = \sum_{k=1}^{K}{w_k * x(p + p_k + \Delta p_k)}
    
    Where :math:`\Delta p_k` and :math:`\Delta m_k` are the learnable offset and modulation scalar for the k-th location, 
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    Which :math:`\Delta m_k` is one in deformable convolution v1. Please refer to `Deformable ConvNets v2: More Deformable, Better Results
13102
    <https://arxiv.org/abs/1811.11168v2>`_ and `Deformable Convolutional Networks <https://arxiv.org/abs/1703.06211>`_.
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    Example:
        - Input:

          Input shape: :math:`(N, C_{in}, H_{in}, W_{in})`

          Filter shape: :math:`(C_{out}, C_{in}, H_f, W_f)`

          Offset shape: :math:`(N, 2 * deformable\_groups * H_f * H_w, H_{in}, W_{in})`

          Mask shape: :math:`(N, deformable\_groups * H_f * H_w, H_{in}, W_{in})`

        - Output:

          Output shape: :math:`(N, C_{out}, H_{out}, W_{out})`

        Where

        .. math::

            H_{out}&= \\frac{(H_{in} + 2 * paddings[0] - (dilations[0] * (H_f - 1) + 1))}{strides[0]} + 1 \\\\
            W_{out}&= \\frac{(W_{in} + 2 * paddings[1] - (dilations[1] * (W_f - 1) + 1))}{strides[1]} + 1

    Args:
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        input (Variable): The input image with [N, C, H, W] format. A Tensor with type
            float32, float64.
13129
        offset (Variable): The input coordinate offset of deformable convolution layer.
13130
            A Tensor with type float32, float64.
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        Mask (Variable, Optional): The input mask of deformable convolution layer.
            A Tensor with type float32, float64. It should be None when you use
            deformable convolution v1.
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        num_filters(int): The number of filter. It is as same as the output
            image channel.
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        filter_size (int|tuple): The filter size. If filter_size is a tuple,
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            it must contain two integers, (filter_size_H, filter_size_W).
            Otherwise, the filter will be a square.
        stride (int|tuple): The stride size. If stride is a tuple, it must
            contain two integers, (stride_H, stride_W). Otherwise, the
            stride_H = stride_W = stride. Default: stride = 1.
        padding (int|tuple): The padding size. If padding is a tuple, it must
            contain two integers, (padding_H, padding_W). Otherwise, the
            padding_H = padding_W = padding. Default: padding = 0.
        dilation (int|tuple): The dilation size. If dilation is a tuple, it must
            contain two integers, (dilation_H, dilation_W). Otherwise, the
            dilation_H = dilation_W = dilation. Default: dilation = 1.
        groups (int): The groups number of the deformable conv layer. According to
            grouped convolution in Alex Krizhevsky's Deep CNN paper: when group=2,
            the first half of the filters is only connected to the first half
            of the input channels, while the second half of the filters is only
            connected to the second half of the input channels. Default: groups=1.
        deformable_groups (int): The number of deformable group partitions.
            Default: deformable_groups = 1.
        im2col_step (int): Maximum number of images per im2col computation; 
            The total batch size should be divisable by this value or smaller
            than this value; if you face out of memory problem, you can try
            to use a smaller value here.
            Default: im2col_step = 64.
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        param_attr (ParamAttr, Optional): The parameter attribute for learnable parameters/weights
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            of deformable conv. If it is set to None or one attribute of ParamAttr,
            deformable conv will create ParamAttr as param_attr.
            If the Initializer of the param_attr is not set, the parameter is
            initialized with :math:`Normal(0.0, std)`, and the 
            :math:`std` is :math:`(\\frac{2.0 }{filter\_elem\_num})^{0.5}`. Default: None.
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        bias_attr (ParamAttr|bool, Optional): The parameter attribute for the bias of
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            deformable conv layer. If it is set to False, no bias will be added
            to the output units. If it is set to None or one attribute of ParamAttr, conv2d
            will create ParamAttr as bias_attr. If the Initializer of the bias_attr
            is not set, the bias is initialized zero. Default: None.
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        modulated (bool): Make sure which version should be used between v1 and v2, where v2 is \
            used while True. Default: True.
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        name(str, Optional): For details, please refer to :ref:`api_guide_Name`.
                        Generally, no setting is required. Default: None.
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    Returns:
        Variable: The tensor variable storing the deformable convolution \
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                  result. A Tensor with type float32, float64.
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    Raises:
        ValueError: If the shapes of input, filter_size, stride, padding and
                    groups mismatch.
    Examples:
        .. code-block:: python

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          #deformable conv v2:
         
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          import paddle.fluid as fluid
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          C_in, H_in, W_in = 3, 32, 32
          filter_size, deformable_groups = 3, 1
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          data = fluid.data(name='data', shape=[None, C_in, H_in, W_in], dtype='float32')
          offset = fluid.data(name='offset', shape=[None, 2*deformable_groups*filter_size**2, H_in, W_in], dtype='float32')
          mask = fluid.data(name='mask', shape=[None, deformable_groups*filter_size**2, H_in, W_in], dtype='float32')
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          out = fluid.layers.deformable_conv(input=data, offset=offset, mask=mask,
13193
                                             num_filters=2, filter_size=filter_size, padding=1, modulated=True)
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          #deformable conv v1:

          import paddle.fluid as fluid
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          C_in, H_in, W_in = 3, 32, 32
          filter_size, deformable_groups = 3, 1
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          data = fluid.data(name='data', shape=[None, C_in, H_in, W_in], dtype='float32')
          offset = fluid.data(name='offset', shape=[None, 2*deformable_groups*filter_size**2, H_in, W_in], dtype='float32')
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          out = fluid.layers.deformable_conv(input=data, offset=offset, mask=None,
13203
                                             num_filters=2, filter_size=filter_size, padding=1, modulated=False)
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    """

    num_channels = input.shape[1]
    assert param_attr is not False, "param_attr should not be False here."

    helper = LayerHelper('deformable_conv', **locals())
    dtype = helper.input_dtype()

    if not isinstance(input, Variable):
        raise TypeError("Input of deformable_conv must be Variable")
    if not isinstance(offset, Variable):
        raise TypeError("Input Offset of deformable_conv must be Variable")

    if groups is None:
        num_filter_channels = num_channels
    else:
        if num_channels % groups != 0:
            raise ValueError("num_channels must be divisible by groups.")
        num_filter_channels = num_channels // groups

    filter_size = utils.convert_to_list(filter_size, 2, 'filter_size')
    stride = utils.convert_to_list(stride, 2, 'stride')
    padding = utils.convert_to_list(padding, 2, 'padding')
    dilation = utils.convert_to_list(dilation, 2, 'dilation')

    input_shape = input.shape
    filter_shape = [num_filters, int(num_filter_channels)] + filter_size

    def _get_default_param_initializer():
        filter_elem_num = filter_size[0] * filter_size[1] * num_channels
        std = (2.0 / filter_elem_num)**0.5
        return Normal(0.0, std, 0)

    filter_param = helper.create_parameter(
        attr=helper.param_attr,
        shape=filter_shape,
        dtype=dtype,
        default_initializer=_get_default_param_initializer())

    pre_bias = helper.create_variable_for_type_inference(dtype)

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    if modulated:
        helper.append_op(
            type='deformable_conv',
            inputs={
                'Input': input,
                'Filter': filter_param,
                'Offset': offset,
                'Mask': mask,
            },
            outputs={"Output": pre_bias},
            attrs={
                'strides': stride,
                'paddings': padding,
                'dilations': dilation,
                'groups': groups,
                'deformable_groups': deformable_groups,
                'im2col_step': im2col_step,
            })

    else:
        helper.append_op(
            type='deformable_conv_v1',
            inputs={
                'Input': input,
                'Filter': filter_param,
                'Offset': offset,
            },
            outputs={"Output": pre_bias},
            attrs={
                'strides': stride,
                'paddings': padding,
                'dilations': dilation,
                'groups': groups,
                'deformable_groups': deformable_groups,
                'im2col_step': im2col_step,
            })
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    output = helper.append_bias_op(pre_bias, dim_start=1, dim_end=2)
    return output
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def unfold(x, kernel_sizes, strides=1, paddings=0, dilations=1, name=None):
    """

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    This op returns a col buffer of sliding local blocks of input x, also known
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    as im2col for batched 2D image tensors. For each block under the convolution filter,
    all element will be rearranged as a column. While the convolution filter silding over
    the input feature map, a series of such columns will be formed.

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    For each input :math:`x` with shape [N, C, H, W], the output shape [N, Cout, Lout]
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    can be calculated as following.

    .. math::

        dkernel[0] &= dilations[0] \\times (kernel\_sizes[0] - 1) + 1

        dkernel[1] &= dilations[1] \\times (kernel\_sizes[1] - 1) + 1

        hout &= \\frac{H + paddings[0] + paddings[2] - dkernel[0]}{strides[0]} + 1

        wout &= \\frac{W + paddings[1] + paddings[3] - dkernel[1]}{strides[1]} + 1

        Cout &= C \\times kernel\_sizes[0] \\times kernel\_sizes[1]

        Lout &= hout \\times wout


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    Parameters:
        x(Varaible):              4-D Tensor, input tensor of format [N, C, H, W], 
                                  data type can be float32 or float64
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        kernel_sizes(int|list):   The size of convolution kernel, should be [k_h, k_w]
                                  or an integer k treated as [k, k].
        strides(int|list):        The strides, should be [stride_h, stride_w]
                                  or an integer stride treated as [sride, stride].
                                  For default, strides will be [1, 1].
        paddings(int|list):       The paddings of each dimension, should be
                                  [padding_top, padding_left, padding_bottom, padding_right]
                                  or [padding_h, padding_w] or an integer padding.
                                  If [padding_h, padding_w] was given, it will expanded to
                                  [padding_h, padding_w, padding_h, padding_w]. If an integer
                                  padding was given, [padding, padding, padding, padding] will
                                  be used. For default, paddings will be [0, 0, 0, 0]
        dilations(int|list):      the dilations of convolution kernel, shold be
                                  [dilation_h, dilation_w], or an integer dialtion treated as
                                  [dilation, dilation]. For default, it will be [1, 1].
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        name(str, optional): The default value is None.  
                             Normally there is no need for user to set this property.  
                             For more information, please refer to :ref:`api_guide_Name`
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    Returns:
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        The tensor variable corresponding to the sliding local blocks. 
        The output shape is [N, Cout, Lout] as decribled above. 
        Cout is the  total number of values within each block, 
        and Lout is the total number of such blocks. 
        The data type of output is the same as the input :math:`x`

    Return Type:
        Variable
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    Examples:

        .. code-block:: python

            import paddle.fluid as fluid
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            x = fluid.data(name = 'data', shape = [100, 3, 224, 224], dtype = 'float32')
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            y = fluid.layers.unfold(x, [3, 3], 1, 1, 1)
    """

    helper = LayerHelper("unfold", **locals())

    assert len(x.shape) == 4, \
            "input should be the format of [N, C, H, W]"

    if isinstance(kernel_sizes, int):
        kernel_sizes = [kernel_sizes, kernel_sizes]
    else:
        assert isinstance(kernel_sizes, list) and (len(kernel_sizes) == 2), \
            "kernel_sizes should either be an integer or a list of two integers"

    if isinstance(strides, int):
        strides = [strides, strides]
    else:
        assert isinstance(strides, list) and (len(strides) == 2), \
            "strides should either be an integer or a list of two integers"

    if isinstance(dilations, int):
        dilations = [dilations, dilations]
    else:
        assert isinstance(dilations, list) and (len(dilations) == 2), \
            "dilations should either be an integer or a list of two integers"

    if isinstance(paddings, int):
        paddings = [paddings] * 4
    elif isinstance(paddings, list):
        if len(paddings) == 2:
            paddings = paddings * 2
        elif len(paddings) == 4:
            pass
        else:
            raise ValueError(
                "paddings should either be an integer or a list of 2 or 4 integers"
            )
    else:
        raise ValueError(
            "Unexpected type of paddings, it should be either an integer or a list"
            "of 2 or 4 integers")

    out = helper.create_variable_for_type_inference(dtype=x.dtype)
    helper.append_op(
        type="unfold",
        inputs={"X": x},
        outputs={"Y": out},
        attrs={
            "kernel_sizes": kernel_sizes,
            "strides": strides,
            "paddings": paddings,
            "dilations": dilations
        })
    return out
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def deformable_roi_pooling(input,
                           rois,
                           trans,
                           no_trans=False,
                           spatial_scale=1.0,
                           group_size=[1, 1],
                           pooled_height=1,
                           pooled_width=1,
                           part_size=None,
                           sample_per_part=1,
                           trans_std=0.1,
                           position_sensitive=False,
                           name=None):
    """
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    Deformable ROI Pooling Layer
  
    Performs deformable region-of-interest pooling on inputs. As described
    in `Deformable Convolutional Networks <https://arxiv.org/abs/1703.06211>`_, it will get offset for each bin after 
    roi pooling so that pooling at correct region. Batch_size will change to the number of region bounding boxes after deformable_roi_pooling.
  
    The operation has three steps:
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    1. Dividing each region proposal into equal-sized sections with the pooled_width and pooled_height.
  
    2. Add offset to pixel in ROI to get new location and the new value which are computed directly through
       bilinear interpolation with four nearest pixel.
     
    3. Sample several points in each bin to get average values as output.
  
  
    Args:
        input (Variable):The input of deformable roi pooling and it is tensor which value type is float32. The shape of input is
                         [N, C, H, W]. Where N is batch size, C is number of input channels,
                         H is height of the feature, and W is the width of the feature.
        rois (Variable): ROIs (Regions of Interest) with type float32 to pool over. It should be
                         a 2-D LoDTensor of shape (num_rois, 4), and the lod level
                         is 1. Given as [[x1, y1, x2, y2], ...], (x1, y1) is
                         the top left coordinates, and (x2, y2) is the bottom
                         right coordinates, which value type is float32.
        trans (Variable): Offset of features on ROIs while pooling which value type is float32. The format is [N, C, H, W], where 
                          N is number of ROIs, C is number of channels, which indicate the offset distance 
                          in the x and y directions, H is pooled height, and W is pooled width. 
        no_trans (bool): Whether to add offset to get new value or not while roi pooling, which value with type bool is True or False.
                         If value is True, no offset will be added in operation. Default: False.
        spatial_scale (float): Ratio of input feature map height (or width) to raw image height (or width), which value type is float32.
                         Equals the reciprocal of total stride in convolutional layers, Default: 1.0.
        group_size (list|tuple): The number of groups which input channels are divided and the input is list or tuple, which value type is int32. (eg.number of input channels 
                          is k1 * k2 * (C + 1), which k1 and k2 are group width and height and C+1 is number of output
                          chanels.) eg.(4, 6), which 4 is height of group and 6 is width of group. Default: [1, 1].
        pooled_height (int): The pooled output height which value type is int32. Default: 1.
        pooled_width (int): The pooled output width which value type is int32. Default: 1.
        part_size (list|tuple): The height and width of offset which values in list or tuple is int32, eg.(4, 6), which height is 4 and width is 6, and values always equal to pooled_height \
                         and pooled_width. Default: if None, default value is [pooled_height, pooled_width].
        sample_per_part (int): The number of samples in each bin which value type is int32. If value is bigger, it will consume more performance. Default: 1.
        trans_std (float): Coefficient of offset which value type is float32. It controls weight of offset. Default: 0.1.
        position_sensitive (bool): Whether to choose deformable psroi pooling mode or not, and value type is bool(True or False). If value is False, input dimension equals to output dimension. \
                                   If value is True, input dimension shoule be output dimension * pooled_height * pooled_width. Default: False.
        name (str|None): Name of layer. Default: None.
    Returns:
        Variable: Output of deformable roi pooling is that, if position sensitive is False, input dimension equals to output dimension. If position sensitive is True,\
                  input dimension should be the result of output dimension divided by pooled height and pooled width.
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    Examples:
      .. code-block:: python

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        # position_sensitive=True
        import paddle.fluid as fluid
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        input = fluid.data(name="input",
                           shape=[2, 192, 64, 64], 
                           dtype='float32')                   
        rois = fluid.data(name="rois",
                          shape=[-1, 4],
                          dtype='float32', 
                          lod_level=1)
        trans = fluid.data(name="trans",
                           shape=[2, 384, 64, 64], 
                           dtype='float32') 
        x = fluid.layers.deformable_roi_pooling(input=input, 
                                                rois=rois, 
                                                trans=trans, 
                                                no_trans=False,
                                                spatial_scale=1.0, 
                                                group_size=(1, 1),
                                                pooled_height=8,
                                                pooled_width=8,
                                                part_size=(8, 8),
                                                sample_per_part=4, 
                                                trans_std=0.1,
                                                position_sensitive=True)
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        # position_sensitive=False
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        import paddle.fluid as fluid
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        input = fluid.data(name="input",
                           shape=[2, 192, 64, 64], 
                           dtype='float32')                   
        rois = fluid.data(name="rois",
                          shape=[-1, 4],
                          dtype='float32', 
                          lod_level=1)
        trans = fluid.data(name="trans",
                           shape=[2, 384, 64, 64], 
                           dtype='float32') 
        x = fluid.layers.deformable_roi_pooling(input=input, 
                                                rois=rois, 
                                                trans=trans, 
                                                no_trans=False,
                                                spatial_scale=1.0, 
                                                group_size=(1, 1),
                                                pooled_height=8,
                                                pooled_width=8,
                                                part_size=(8, 8),
                                                sample_per_part=4, 
                                                trans_std=0.1,
                                                position_sensitive=False)
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    """

    input_channels = input.shape[1]
    if position_sensitive == False:
        output_channels = input_channels
    else:
        output_channels = input_channels / pooled_height / pooled_width

    if part_size is None:
        part_height = pooled_height
        part_width = pooled_width
        part_size = [part_height, part_width]
    part_size = utils.convert_to_list(part_size, 2, 'part_size')
    group_size = utils.convert_to_list(group_size, 2, 'group_size')
    helper = LayerHelper('deformable_psroi_pooling', **locals())
    dtype = helper.input_dtype()
    output = helper.create_variable_for_type_inference(dtype)
    top_count = helper.create_variable_for_type_inference(dtype='int32')
    helper.append_op(
        type="deformable_psroi_pooling",
        inputs={"Input": input,
                "ROIs": rois,
                "Trans": trans},
        outputs={"Output": output,
                 "TopCount": top_count},
        attrs={
            "no_trans": no_trans,
            "spatial_scale": spatial_scale,
            "output_dim": output_channels,
            "group_size": group_size,
            "pooled_height": pooled_height,
            "pooled_width": pooled_width,
            "part_size": part_size,
            "sample_per_part": sample_per_part,
            "trans_std": trans_std
        })
    return output
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def shard_index(input, index_num, nshards, shard_id, ignore_value=-1):
    """
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    This operator recomputes the `input` indices according to the offset of the
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    shard. The length of the indices is evenly divided into N shards, and if
    the `shard_id` matches the shard with the input index inside, the index is
    recomputed on the basis of the shard offset, elsewise it is set to
    `ignore_value`. The detail is as follows:
    :: 
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        shard_size = (index_num + nshards - 1) // nshards
        y = x % shard_size if x // shard_size == shard_id else ignore_value
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    NOTE: If the length of indices cannot be evely divided by the shard number,
    the size of the last shard will be less than the calculated `shard_size`
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    Examples:
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    ::
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        Input:
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          X.shape = [4, 1]
          X.data = [[1], [6], [12], [19]]
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          index_num = 20
          nshards = 2
          ignore_value = -1
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        if shard_id == 0, we get:
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          Out.shape = [4, 1]
          Out.data = [[1], [6], [-1], [-1]]
        
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        if shard_id == 1, we get:
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          Out.shape = [4, 1]
          Out.data = [[-1], [-1], [2], [9]]
    
    Args:
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        - **input** (Variable): Input indices, last dimension must be 1.
        - **index_num** (scalar): An interger defining the range of the index.
        - **nshards** (scalar): The number of shards
        - **shard_id** (scalar): The index of the current shard
        - **ignore_value** (scalar): An ingeter value out of sharded index range
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    Returns:
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        Variable: The sharded index of input.
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    Examples:
        .. code-block:: python

            import paddle.fluid as fluid
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            batch_size = 32
            label = fluid.data(name="label", shape=[batch_size, 1], dtype="int64")
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            shard_label = fluid.layers.shard_index(input=label,
                                                   index_num=20,
                                                   nshards=2,
                                                   shard_id=0)
    """
    op_type = 'shard_index'
    helper = LayerHelper(op_type, **locals())
    if shard_id < 0 or shard_id >= nshards:
        raise ValueError('The shard_id(%d) should be in [0, %d)' %
                         (shard_id, nshards))

    out = helper.create_variable_for_type_inference(dtype=input.dtype)
    helper.append_op(
        type=op_type,
        inputs={'X': [input]},
        outputs={'Out': out},
        attrs={
            'index_num': index_num,
            'nshards': nshards,
            'shard_id': shard_id,
            'ignore_value': ignore_value
        },
        stop_gradient=True)
    return out
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@templatedoc()
def hard_swish(x, threshold=6.0, scale=6.0, offset=3.0, name=None):
    """
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    This operator implements the hard_swish activation function.
    Hard_swish is proposed in MobileNetV3, and performs better in computational stability and efficiency compared to swish function.
    For more details please refer to: https://arxiv.org/pdf/1905.02244.pdf
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    The formula is as follows:
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    .. math::
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        out = \\frac{x * (min(max(0, x+offset), threshold))}{scale}
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    In the above equation:

    ``threshold`` and ``scale`` should be positive, ``offset`` can be positive or negative. It is recommended to use default parameters.

    Args:
        x (Variable): Input feature, multi-dimensional Tensor. The data type should be float32 or float64.
        threshold (float, optional): The threshold in Relu function. Default: 6.0
        scale (float, optional): The scale factor. Default: 6.0
        offset (float, optional): The offset factor. Default: 3.0
        name (str, optional): The default value is None. Normally there is no need for user to set this property. For more information, please refer to :ref:`api_guide_Name` 
        
    Returns:
        Variable: The output tensor with the same shape and data type as input.
    
    
    Examples:
    
    .. code-block:: python
    
        import paddle.fluid as fluid
        import numpy as np
    
        DATATYPE='float32'
    
        x_data = np.array([i for i in range(1,5)]).reshape([1,1,4]).astype(DATATYPE)
    
        x = fluid.data(name="x", shape=[None,1,4], dtype=DATATYPE)
        y = fluid.layers.hard_swish(x)
    
        place = fluid.CPUPlace()
        #place = fluid.CUDAPlace(0)
        exe = fluid.Executor(place)
        out, = exe.run(feed={'x':x_data}, fetch_list=[y.name])
        print(out)  # [[0.66666667, 1.66666667,3., 4.]]
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    """
    helper = LayerHelper('hard_swish', **locals())
    out = helper.create_variable_for_type_inference(dtype=x.dtype)
    helper.append_op(
        type='hard_swish',
        inputs={'X': x},
        outputs={'Out': out},
        attrs={'threshold': threshold,
               'scale': scale,
               'offset': offset})
    return out
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def gather_tree(ids, parents):
    """
    To be used after beam search. After beam search, we get selected ids at
    each time step and the corresponding parents in the search tree. Both ids
    and parents have the layout :attr:`[max_time, batch_size, beam_size]`. Then
    :attr:`gather_tree` is used to backtrace from the last time step and
    generate the full sequences by collecting selected ids.

    Here is an example:

    .. code-block:: text

            Given:
                ids = [[[2 2]
                        [6 1]]
                       [[3 9]
                        [6 1]]
                       [[0 1]
                        [9 0]]]
                parents = [[[0 0]
                            [1 1]]
                           [[1 0]
                            [1 0]]
                           [[0 0]
                            [0 1]]]

            Then:                
                gather_tree(ids, parents)  
                         = [[[2 2]
                             [1 6]]
                            [[3 3]
                             [6 1]]
                            [[0 1]
                             [9 0]]]

    Args:
        ids(Variable): A Tensor with shape :attr:`[length, batch_size, beam_size]`
            and data type :attr:`int32` or :attr:`int64`. It contains the selected
            ids of all time steps.
        parents(Variable): A Tensor with the same shape and data type as :attr:`ids`,
            It contains the parents corresponding to selected ids when searching
            among beams.

    Returns:
        Variable: A Tensor with the same shape and data type as :attr:`ids`. \
            It contains the full sequences. The sequences are collected from \
            :attr:`ids` by backtracing according to :attr:`parents`.

    Examples:
        .. code-block:: python

            import paddle.fluid as fluid

            ids = fluid.layers.data(name='ids',
                                    shape=[5, 2, 2],
                                    dtype='int64',
                                    append_batch_size=False)
            parents = fluid.layers.data(name='parents',
                                        shape=[5, 2, 2],
                                        dtype='int64',
                                        append_batch_size=False)
            final_sequences = fluid.layers.gather_tree(ids, parents)
    """
    helper = LayerHelper('gather_tree', **locals())
    out = helper.create_variable_for_type_inference(dtype=ids.dtype)

    helper.append_op(
        type="gather_tree",
        inputs={"Ids": ids,
                "Parents": parents},
        outputs={"Out": out})

    return out


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@templatedoc()
def uniform_random(shape, dtype='float32', min=-1.0, max=1.0, seed=0):
    """
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    This OP initializes a variable with random values sampled from a
    uniform distribution in the range [min, max).
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    Examples:
    ::
    
        Input:
          shape = [1, 2]
        
        Output:
          result=[[0.8505902, 0.8397286]]

    Args:
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        shape (list|tuple|Variable): The shape of the output Tensor,  if the shape is a list or tuple, 
                                     its elements can be an integer
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                                     or a Tensor with the shape [1], and the type of the Tensor must be int32 or int64. 
                                     If the shape is a Variable, it is a 1-D Tensor, and the type of the Tensor must be int32 or int64.
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        dtype(np.dtype|core.VarDesc.VarType|str, optional): The type of the output Tensor. Supported data types: float32, float64.
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                                                  Default: float32.
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        min (float, optional): The lower bound on the range of random values to generate, the min is included in the range. Default -1.0.
        max (float, optional): The upper bound on the range of random values to generate, the max is excluded in the range. Default 1.0.
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        seed (int, optional): Random seed used for generating samples. 0 means use a
            seed generated by the system. Note that if seed is not 0, this
            operator will always generate the same random numbers every time.
            Default 0.

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    Returns: 
        Variable: A Tensor of the specified shape filled with uniform_random values.
13801

13802
    Raises:
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        TypeError: The shape type should be list or tupple or variable.
    
    Examples:
        .. code-block:: python

            import paddle.fluid as fluid

            # example 1:
            # attr shape is a list which doesn't contain tensor Variable.
            result_1 = fluid.layers.uniform_random(shape=[3, 4])

            # example 2:
            # attr shape is a list which contains tensor Variable.
            dim_1 = fluid.layers.fill_constant([1],"int64",3)
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            dim_2 = fluid.layers.fill_constant([1],"int32",5)
            result_2 = fluid.layers.uniform_random(shape=[dim_1, dim_2])
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            # example 3:
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            # attr shape is a Variable, the data type must be int64 or int32.
13822
            var_shape = fluid.data(name='var_shape', shape=[2], dtype="int64")
13823
            result_3 = fluid.layers.uniform_random(var_shape)
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            var_shape_int32 = fluid.data(name='var_shape_int32', shape=[2], dtype="int32")
            result_4 = fluid.layers.uniform_random(var_shape_int32)
             

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    """
13830
    check_type(shape, 'shape', (list, tuple, Variable), 'uniform_random')
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    if not isinstance(dtype, core.VarDesc.VarType):
        dtype = convert_np_dtype_to_dtype_(dtype)
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    check_dtype(dtype, 'dtype', ['float32', 'float64'], 'uniform_random')
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    def contain_var(one_list):
        for ele in one_list:
            if isinstance(ele, Variable):
                return True
        return False

    def get_new_shape_tensor(list_shape):
        new_shape_tensor = []
        for dim in list_shape:
            if isinstance(dim, Variable):
                dim.stop_gradient = True
                new_shape_tensor.append(dim)
            else:
                assert (isinstance(dim, int))
                temp_out = helper.create_variable_for_type_inference('int64')
                fill_constant([1], 'int64', dim, force_cpu=True, out=temp_out)
                new_shape_tensor.append(temp_out)
        return new_shape_tensor

    def get_attr_shape(list_shape):
        unk_dim_idx = -1
        attrs_shape = []
        for dim_idx, dim_size in enumerate(list_shape):
            if isinstance(dim_size, Variable):
                attrs_shape.append(-1)
            else:
                attrs_shape.append(dim_size)
                assert dim_size > 0, (
                    "Each dimension size given in shape must not be negtive "
                    "except one unknown dimension.")
        return attrs_shape

    helper = LayerHelper("uniform_random", **locals())
    inputs = dict()
13869
    attrs = {'seed': seed, 'min': min, 'max': max}
13870
    if in_dygraph_mode():
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        attrs['shape'] = shape
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    else:
        if isinstance(shape, Variable):
            shape.stop_gradient = True
            inputs["ShapeTensor"] = shape
        elif isinstance(shape, (list, tuple)):
            assert len(shape) > 0, (
                "The size of argument(shape) can't be zero.")
            attrs["shape"] = get_attr_shape(shape)
            if contain_var(shape):
                inputs['ShapeTensorList'] = get_new_shape_tensor(shape)

    out = helper.create_variable_for_type_inference(dtype)
    helper.append_op(
        type="uniform_random", inputs=inputs, attrs=attrs,
        outputs={"Out": out})

    return helper.append_activation(out)