lr.py 57.1 KB
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# Copyright (c) 2020 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.

import math
import numpy
import warnings
from paddle import Tensor

__all__ = [
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    'LRScheduler', 'NoamDecay', 'PiecewiseDecay', 'NaturalExpDecay',
    'InverseTimeDecay', 'PolynomialDecay', 'LinearWarmup', 'ExponentialDecay',
    'MultiStepDecay', 'StepDecay', 'LambdaDecay', 'ReduceOnPlateau',
    'CosineAnnealingDecay'
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]


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class LRScheduler(object):
    """

    LRScheduler Base class. Define the common interface of a learning rate scheduler.

    User can import it by ``form paddle.optimizer.lr import LRScheduler`` ,

    then overload it for your subclass and have a custom implementation of ``get_lr()`` .

    Otherwise, an ``NotImplementedError`` exception will be thrown.

    Args:
        learning_rate (float): The initial learning rate. It is a python float number.
        last_epoch (int, optional):  The index of last epoch. Can be set to restart training. Default: -1, means initial learning rate.
        verbose (bool, optional): If ``True``, prints a message to stdout for each update. Default: ``False`` .

    Returns:
        instance to schedule learning rate.

    Examples:
        Here is an example of a simple ``StepDecay`` implementation. 
        
        .. code-block:: python
            
            import paddle
            form paddle.optimizer.lr import LRScheduler

            class StepDecay(LRScheduler):
                def __init__(self,
                            learning_rate,
                            step_size,
                            gamma=0.1,
                            last_epoch=-1,
                            verbose=False):
                    if not isinstance(step_size, int):
                        raise TypeError(
                            "The type of 'step_size' must be 'int', but received %s." %
                            type(step_size))
                    if gamma >= 1.0:
                        raise ValueError('gamma should be < 1.0.')

                    self.step_size = step_size
                    self.gamma = gamma
                    super(StepDecay, self).__init__(learning_rate, last_epoch, verbose)

                def get_lr(self):
                    i = self.last_epoch // self.step_size
                    return self.base_lr * (self.gamma**i)
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    """

    def __init__(self, learning_rate=0.1, last_epoch=-1, verbose=False):
        if not isinstance(learning_rate, (float, int)):
            raise TypeError(
                "The type of learning rate must be float, but received {}".
                format(type(learning_rate)))
        self.base_lr = float(learning_rate)
        self.last_lr = float(learning_rate)
        self.last_epoch = last_epoch
        self.verbose = verbose
        self._var_name = None

        self.step()

    def __call__(self):
        """ 
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        Return lastest computed learning rate on current epoch.
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        """
        return self.last_lr

    def step(self, epoch=None):
        """
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        ``step`` should be called after ``optimizer.step`` . It will update the learning rate in optimizer according to current ``epoch`` .  
        The new learning rate will take effect on next ``optimizer.step`` .
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        Args:
            epoch (int, None): specify current epoch. Default: None. Auto-increment from last_epoch=-1.

        Returns:
            None
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        """
        if epoch is None:
            self.last_epoch += 1
            self.last_lr = self.get_lr()
        else:
            self.last_epoch = epoch
            if hasattr(self, "_get_closed_form_lr"):
                self.last_lr = self._get_closed_form_lr()
            else:
                self.last_lr = self.get_lr()

        if self.verbose:
            print('Epoch {}: {} set learning rate to {}.'.format(
                self.last_epoch, self.__class__.__name__, self.last_lr))

    def state_dict(self):
        """
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        Returns the state of the scheduler as a :class:`dict`.

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        It is a subset of ``self.__dict__`` .
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        """
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        self.state_keys()
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        state_dict = {}
        for key in self.keys:
            if key not in self.__dict__:
                continue
            value = self.__dict__[key]
            if isinstance(value, Tensor):
                assert value.shape == [
                    1
                ], "shape of Tensor in state_dict must be [1] {}".format(
                    value.shape)
                value = value.numpy()[0]
            state_dict[key] = value

        return state_dict

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    # For those subclass who overload LRScheduler, "last_epoch, last_lr" will be saved by default.
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    # (Note): you can change it for your subclass.
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    def state_keys(self):
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        """
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        For those subclass who overload ``LRScheduler`` (Base Class). Acquiescently, "last_epoch, last_lr" will be saved by ``self.keys = ['last_epoch', 'last_lr']`` .

        ``last_epoch`` is the current epoch num, and ``last_lr`` is the current learning rate.

        If you want to change the default behavior, you should have a custom implementation of ``_state_keys()`` to redefine ``self.keys`` .

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        """
        self.keys = ['last_epoch', 'last_lr']

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    def set_state_dict(self, state_dict):
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        """
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        Loads the schedulers state.
        """
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        self.state_keys()
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        for key in self.keys:
            if key in state_dict:
                self.__dict__[key] = state_dict[key]
            else:
                raise RuntimeError(
                    "Please check whether state_dict is correct for optimizer. Can't find [ {} ] in state_dict".
                    format(key))
        if len(state_dict) > len(self.keys):
            warnings.warn(
                "There are some unused values in state_dict. Maybe the optimizer have different 'LearningRateDecay' when invoking state_dict and set_dict"
            )

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    # alias for set_state_dict
    set_dict = set_state_dict
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    def get_lr(self):
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        """
        
        For those subclass who overload ``LRScheduler`` (Base Class), User should have a custom implementation of ``get_lr()`` .

        Otherwise, an ``NotImplementedError`` exception will be thrown.
        """
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        # calculate by python float
        raise NotImplementedError


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class NoamDecay(LRScheduler):
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    """

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    Applies Noam Decay to the initial learning rate. 
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    The algorithm can be described as following.

    .. math::

        new\_learning\_rate = learning\_rate * d_{model}^{-0.5} * min(epoch^{-0.5}, epoch * warmup\_steps^{-1.5})

    Please reference `attention is all you need <https://arxiv.org/pdf/1706.03762.pdf>`_ 


    Args:
        d$_{model}$(int): The dimensionality of input and output feature vector of model. It is a python int number.
        warmup_steps(int): The number of warmup steps. A super parameter. It is a python int number
        learning_rate (float): The initial learning rate. It is a python float number. Default: 1.0.
        last_epoch (int, optional):  The index of last epoch. Can be set to restart training. Default: -1, means initial learning rate.
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        verbose (bool, optional): If ``True``, prints a message to stdout for each update. Default: ``False`` .
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    Returns:
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        ``NoamDecay`` instance to schedule learning rate.
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    Examples:
        .. code-block:: python

            import paddle
            import numpy as np

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            # train on default dynamic graph mode
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            linear = paddle.nn.Linear(10, 10)
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            scheduler = paddle.optimizer.lr.NoamDecay(d_model=0.01, warmup_steps=100, verbose=True)
            sgd = paddle.optimizer.SGD(learning_rate=scheduler, parameters=linear.parameters())
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            for epoch in range(20):
                for batch_id in range(2):
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                    x = paddle.uniform([10, 10])
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                    out = linear(x)
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                    loss = paddle.mean(out)
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                    loss.backward()
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                    sgd.step()
                    sgd.clear_gradients()
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                scheduler.step()

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            # train on static graph mode
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            paddle.enable_static()
            main_prog = paddle.static.Program()
            start_prog = paddle.static.Program()
            with paddle.static.program_guard(main_prog, start_prog):
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                x = paddle.static.data(name='x', shape=[None, 4, 5])
                y = paddle.static.data(name='y', shape=[None, 4, 5])
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                z = paddle.static.nn.fc(x, 100)
                loss = paddle.mean(z)
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                scheduler = paddle.optimizer.lr.NoamDecay(d_model=0.01, warmup_steps=100, verbose=True)
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                sgd = paddle.optimizer.SGD(learning_rate=scheduler)
                sgd.minimize(loss)

            exe = paddle.static.Executor()
            exe.run(start_prog)
            for epoch in range(20):
                for batch_id in range(2):
                    out = exe.run(
                        main_prog,
                        feed={
                            'x': np.random.randn(3, 4, 5).astype('float32'),
                            'y': np.random.randn(3, 4, 5).astype('float32')
                        },
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                        fetch_list=loss.name)
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                scheduler.step()

    """

    def __init__(self,
                 d_model,
                 warmup_steps,
                 learning_rate=1.0,
                 last_epoch=-1,
                 verbose=False):
        self.d_model = d_model
        self.warmup_steps = warmup_steps
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        super(NoamDecay, self).__init__(learning_rate, last_epoch, verbose)
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    def get_lr(self):
        if self.last_epoch == 0:
            a = 1
        else:
            a = self.last_epoch**-0.5
        b = self.warmup_steps**-1.5 * self.last_epoch
        return self.base_lr * (self.d_model**-0.5) * min(a, b)


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class PiecewiseDecay(LRScheduler):
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    """

    Piecewise learning rate scheduler.

    The algorithm can be described as the code below:

    .. code-block:: text

        boundaries = [100, 200]
        values = [1.0, 0.5, 0.1]
        if epoch < 100:
            learning_rate = 1.0
        elif 100 <= global_step < 200:
            learning_rate = 0.5
        else:
            learning_rate = 0.1

    Args:
        boundaries(list): A list of steps numbers. The type of element in the list is python int. 
        values(list): A list of learning rate values that will be picked during different epoch boundaries. 
            The type of element in the list is python float.
        last_epoch (int, optional):  The index of last epoch. Can be set to restart training. Default: -1, means initial learning rate.
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        verbose (bool, optional): If ``True``, prints a message to stdout for each update. Default: ``False`` .
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    Returns:
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        ``PiecewiseDecay`` instance to schedule learning rate.
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    Examples:
        
        .. code-block:: python

            import paddle
            import numpy as np

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            # train on default dynamic graph mode
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            linear = paddle.nn.Linear(10, 10)
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            scheduler = paddle.optimizer.lr.PiecewiseDecay(boundaries=[3, 6, 9], values=[0.1, 0.2, 0.3, 0.4], verbose=True)
            sgd = paddle.optimizer.SGD(learning_rate=scheduler, parameters=linear.parameters())
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            for epoch in range(20):
                for batch_id in range(2):
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                    x = paddle.uniform([10, 10])
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                    out = linear(x)
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                    loss = paddle.mean(out)
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                    loss.backward()
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                    sgd.step()
                    sgd.clear_gradients()
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                scheduler.step()

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            # train on static graph mode
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            paddle.enable_static()
            main_prog = paddle.static.Program()
            start_prog = paddle.static.Program()
            with paddle.static.program_guard(main_prog, start_prog):
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                x = paddle.static.data(name='x', shape=[None, 4, 5])
                y = paddle.static.data(name='y', shape=[None, 4, 5])
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                z = paddle.static.nn.fc(x, 100)
                loss = paddle.mean(z)
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                scheduler = paddle.optimizer.lr.PiecewiseDecay(boundaries=[3, 6, 9], values=[0.1, 0.2, 0.3, 0.4], verbose=True)
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                sgd = paddle.optimizer.SGD(learning_rate=scheduler)
                sgd.minimize(loss)

            exe = paddle.static.Executor()
            exe.run(start_prog)
            for epoch in range(20):
                for batch_id in range(2):
                    out = exe.run(
                        main_prog,
                        feed={
                            'x': np.random.randn(3, 4, 5).astype('float32'),
                            'y': np.random.randn(3, 4, 5).astype('float32')
                        },
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                        fetch_list=loss.name)
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                scheduler.step()
    """

    def __init__(self, boundaries, values, last_epoch=-1, verbose=False):
        self.boundaries = boundaries
        self.values = values
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        super(PiecewiseDecay, self).__init__(
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            last_epoch=last_epoch, verbose=verbose)

    def get_lr(self):

        for i in range(len(self.boundaries)):
            if self.last_epoch < self.boundaries[i]:
                return self.values[i]
        return self.values[len(self.values) - 1]


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class NaturalExpDecay(LRScheduler):
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    """

    Applies natural exponential decay to the initial learning rate.
    
    The algorithm can be described as following:

    .. math::

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        new\_learning\_rate = learning\_rate * e^{- gamma * epoch}
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    Args:
        learning_rate (float): The initial learning rate. It is a python float number.
        gamma (float, optional): A Ratio to update the learning rate. Default: 0.1.
        last_epoch (int, optional):  The index of last epoch. Can be set to restart training. Default: -1, means initial learning rate.
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        verbose (bool, optional): If ``True``, prints a message to stdout for each update. Default: ``False`` .
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    Returns:
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        ``NaturalExpDecay`` instance to schedule learning rate.
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    Examples:
        
        .. code-block:: python

            import paddle
            import numpy as np

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            # train on default dynamic graph mode
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            linear = paddle.nn.Linear(10, 10)
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            scheduler = paddle.optimizer.lr.NaturalExpDecay(learning_rate=0.5, gamma=0.1, verbose=True)
            sgd = paddle.optimizer.SGD(learning_rate=scheduler, parameters=linear.parameters())
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            for epoch in range(20):
                for batch_id in range(2):
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                    x = paddle.uniform([10, 10])
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                    out = linear(x)
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                    loss = paddle.mean(out)
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                    loss.backward()
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                    sgd.step()
                    sgd.clear_gradients()
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                scheduler.step()

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            # train on static graph mode
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            paddle.enable_static()
            main_prog = paddle.static.Program()
            start_prog = paddle.static.Program()
            with paddle.static.program_guard(main_prog, start_prog):
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                x = paddle.static.data(name='x', shape=[None, 4, 5])
                y = paddle.static.data(name='y', shape=[None, 4, 5])
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                z = paddle.static.nn.fc(x, 100)
                loss = paddle.mean(z)
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                scheduler = paddle.optimizer.lr.NaturalExpDecay(learning_rate=0.5, gamma=0.1, verbose=True)
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                sgd = paddle.optimizer.SGD(learning_rate=scheduler)
                sgd.minimize(loss)

            exe = paddle.static.Executor()
            exe.run(start_prog)
            for epoch in range(20):
                for batch_id in range(2):
                    out = exe.run(
                        main_prog,
                        feed={
                            'x': np.random.randn(3, 4, 5).astype('float32'),
                            'y': np.random.randn(3, 4, 5).astype('float32')
                        },
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                        fetch_list=loss.name)
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                scheduler.step()
    """

    def __init__(self, learning_rate, gamma, last_epoch=-1, verbose=False):
        self.gamma = gamma
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        super(NaturalExpDecay, self).__init__(learning_rate, last_epoch,
                                              verbose)
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    def get_lr(self):
        return self.base_lr * math.exp(-1 * self.gamma * self.last_epoch)


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class InverseTimeDecay(LRScheduler):
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    """

    Applies inverse time decay to the initial learning rate.

    The algorithm can be described as following:

    .. math::

        new\_learning\_rate = \\frac{learning\_rate}{1 + gamma * epoch}

    Args:
        learning_rate (float): The initial learning rate. It is a python float number.
        gamma (float, optional): The Ratio that the learning rate will be reduced. ``new_lr = origin_lr * gamma`` . 
            It should be less than 1.0. Default: 0.1.
        last_epoch (int, optional):  The index of last epoch. Can be set to restart training. Default: -1, means initial learning rate.
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        verbose (bool, optional): If ``True``, prints a message to stdout for each update. Default: ``False`` .
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    Returns:
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        ``InverseTimeDecay`` instance to schedule learning rate.
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    Examples:
        
        .. code-block:: python

            import paddle
            import numpy as np

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            # train on default dynamic graph mode
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            linear = paddle.nn.Linear(10, 10)
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            scheduler = paddle.optimizer.lr.InverseTimeDecay(learning_rate=0.5, gamma=0.1, verbose=True)
            sgd = paddle.optimizer.SGD(learning_rate=scheduler, parameters=linear.parameters())
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            for epoch in range(20):
                for batch_id in range(2):
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                    x = paddle.uniform([10, 10])
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                    out = linear(x)
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                    loss = paddle.mean(out)
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                    loss.backward()
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                    sgd.step()
                    sgd.clear_gradients()
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                scheduler.step()

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            # train on static graph mode
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            paddle.enable_static()
            main_prog = paddle.static.Program()
            start_prog = paddle.static.Program()
            with paddle.static.program_guard(main_prog, start_prog):
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                x = paddle.static.data(name='x', shape=[None, 4, 5])
                y = paddle.static.data(name='y', shape=[None, 4, 5])
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                z = paddle.static.nn.fc(x, 100)
                loss = paddle.mean(z)
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                scheduler = paddle.optimizer.lr.InverseTimeDecay(learning_rate=0.5, gamma=0.1, verbose=True)
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                sgd = paddle.optimizer.SGD(learning_rate=scheduler)
                sgd.minimize(loss)

            exe = paddle.static.Executor()
            exe.run(start_prog)
            for epoch in range(20):
                for batch_id in range(2):
                    out = exe.run(
                        main_prog,
                        feed={
                            'x': np.random.randn(3, 4, 5).astype('float32'),
                            'y': np.random.randn(3, 4, 5).astype('float32')
                        },
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                        fetch_list=loss.name)
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                scheduler.step()

    """

    def __init__(self, learning_rate, gamma, last_epoch=-1, verbose=False):
        self.gamma = gamma
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        super(InverseTimeDecay, self).__init__(learning_rate, last_epoch,
                                               verbose)
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    def get_lr(self):
        return self.base_lr / (1 + self.gamma * self.last_epoch)


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class PolynomialDecay(LRScheduler):
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    """

    Applies polynomial decay to the initial learning rate.

    The algorithm can be described as following.

    If cycle is set to True, then:

    .. math::

        decay\_steps & = decay\_steps * math.ceil(\\frac{epoch}{decay\_steps}) 

        new\_learning\_rate & = (learning\_rate-end\_lr)*(1-\\frac{epoch}{decay\_steps})^{power}+end\_lr

    If cycle is set to False, then:

    .. math::

        epoch & = min(epoch, decay\_steps) 

        new\_learning\_rate & = (learning\_rate-end\_lr)*(1-\\frac{epoch}{decay\_steps})^{power}+end\_lr


    Args:
        learning_rate (float): The initial learning rate. It is a python float number.
        decay_steps(int): The decay step size. It determines the decay cycle.
        end_lr(float, optional): The minimum final learning rate. Default: 0.0001.
        power(float, optional): Power of polynomial. Default: 1.0.
        cycle(bool, optional): Whether the learning rate rises again. If True, then the learning rate will rise when it decrease 
            to ``end_lr`` .  If False, the learning rate is monotone decreasing. Default: False.
        last_epoch (int, optional):  The index of last epoch. Can be set to restart training. Default: -1, means initial learning rate.
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        verbose (bool, optional): If ``True``, prints a message to stdout for each update. Default: ``False`` .
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    Returns:
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        ``PolynomialDecay`` instance to schedule learning rate.
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    Examples:
        
        .. code-block:: python

            import paddle
            import numpy as np

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            # train on default dynamic graph mode
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            linear = paddle.nn.Linear(10, 10)
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            scheduler = paddle.optimizer.lr.PolynomialDecay(learning_rate=0.5, decay_steps=20, verbose=True)
            sgd = paddle.optimizer.SGD(learning_rate=scheduler, parameters=linear.parameters())
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            for epoch in range(20):
                for batch_id in range(2):
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                    x = paddle.uniform([10, 10])
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                    out = linear(x)
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                    loss = paddle.mean(out)
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                    loss.backward()
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                    sgd.step()
                    sgd.clear_gradients()
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                scheduler.step()

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            # train on static graph mode
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            paddle.enable_static()
            main_prog = paddle.static.Program()
            start_prog = paddle.static.Program()
            with paddle.static.program_guard(main_prog, start_prog):
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                x = paddle.static.data(name='x', shape=[None, 4, 5])
                y = paddle.static.data(name='y', shape=[None, 4, 5])
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                z = paddle.static.nn.fc(x, 100)
                loss = paddle.mean(z)
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                scheduler = paddle.optimizer.lr.PolynomialDecay(learning_rate=0.5, decay_steps=20, verbose=True)
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                sgd = paddle.optimizer.SGD(learning_rate=scheduler)
                sgd.minimize(loss)

            exe = paddle.static.Executor()
            exe.run(start_prog)
            for epoch in range(20):
                for batch_id in range(2):
                    out = exe.run(
                        main_prog,
                        feed={
                            'x': np.random.randn(3, 4, 5).astype('float32'),
                            'y': np.random.randn(3, 4, 5).astype('float32')
                        },
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                        fetch_list=loss.name)
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                scheduler.step()
    """

    def __init__(self,
                 learning_rate,
                 decay_steps,
                 end_lr=0.0001,
                 power=1.0,
                 cycle=False,
                 last_epoch=-1,
                 verbose=False):
        self.decay_steps = decay_steps
        self.end_lr = end_lr
        self.power = power
        self.cycle = cycle
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        super(PolynomialDecay, self).__init__(learning_rate, last_epoch,
                                              verbose)
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    def get_lr(self):
        tmp_epoch_num = self.last_epoch
        tmp_decay_steps = self.decay_steps
        if self.cycle:
            div_res = math.ceil(
                float(self.last_epoch) / float(self.decay_steps))

            if self.last_epoch == 0:
                div_res = 1
            tmp_decay_steps = self.decay_steps * div_res
        else:
            tmp_epoch_num = min(self.last_epoch, self.decay_steps)

        return (self.base_lr - self.end_lr) * (
            (1 - float(tmp_epoch_num) / float(tmp_decay_steps)
             )**self.power) + self.end_lr


649
class LinearWarmup(LRScheduler):
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    """

    Linear learning rate warm up strategy. Update the learning rate preliminarily before the normal learning rate scheduler.
    For more information, please refer to `Bag of Tricks for Image Classification with Convolutional Neural Networks <https://arxiv.org/abs/1812.01187>`_
    
    When epoch < warmup_steps, learning rate is updated as:
    
657
    .. math::
658
    
659
            lr = start\_lr + (end\_lr - start\_lr) * \\frac{epoch}{warmup\_steps}
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    where start_lr is the initial learning rate, and end_lr is the final learning rate;
    
    When epoch >= warmup_steps, learning rate is updated as:
    
665
    .. math::
666 667 668
    
            lr = learning_rate
    
669
    where ``learning_rate`` is float or any subclass of ``LRScheduler`` .
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    Args:
672
        learning_rate (float|LRScheduler): The learning rate after warm-up. It is a python float number or any subclass of ``LRScheduler`` .
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        warmup_steps (int): total steps of warm up.
        start_lr (float): Initial learning rate of warm up.
        end_lr (float): Final learning rate of warm up.
        last_epoch (int, optional):  The index of last epoch. Can be set to restart training. Default: -1, means initial learning rate.
677
        verbose (bool, optional): If ``True``, prints a message to stdout for each update. Default: ``False`` .
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    Returns:
680
        ``LinearWarmup`` instance to schedule learning rate.
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    Examples:
        
        .. code-block:: python

            import paddle
            import numpy as np

689
            # train on default dynamic graph mode
690
            linear = paddle.nn.Linear(10, 10)
691
            scheduler = paddle.optimizer.lr.LinearWarmup(
692
                    learning_rate=0.5, warmup_steps=20, start_lr=0, end_lr=0.5, verbose=True)
693
            sgd = paddle.optimizer.SGD(learning_rate=scheduler, parameters=linear.parameters())
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            for epoch in range(20):
                for batch_id in range(2):
696
                    x = paddle.uniform([10, 10])
697
                    out = linear(x)
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                    loss = paddle.mean(out)
699
                    loss.backward()
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                    sgd.step()
                    sgd.clear_gradients()
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                scheduler.step()

704
            # train on static graph mode
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            paddle.enable_static()
            main_prog = paddle.static.Program()
            start_prog = paddle.static.Program()
            with paddle.static.program_guard(main_prog, start_prog):
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                x = paddle.static.data(name='x', shape=[None, 4, 5])
                y = paddle.static.data(name='y', shape=[None, 4, 5])
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                z = paddle.static.nn.fc(x, 100)
                loss = paddle.mean(z)
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                scheduler = paddle.optimizer.lr.LinearWarmup(
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                    learning_rate=0.5, warmup_steps=20, start_lr=0, end_lr=0.5, verbose=True)
                sgd = paddle.optimizer.SGD(learning_rate=scheduler)
                sgd.minimize(loss)

            exe = paddle.static.Executor()
            exe.run(start_prog)
            for epoch in range(20):
                for batch_id in range(2):
                    out = exe.run(
                        main_prog,
                        feed={
                            'x': np.random.randn(3, 4, 5).astype('float32'),
                            'y': np.random.randn(3, 4, 5).astype('float32')
                        },
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                        fetch_list=loss.name)
729
                scheduler.step()
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    """

    def __init__(self,
                 learning_rate,
                 warmup_steps,
                 start_lr,
                 end_lr,
                 last_epoch=-1,
                 verbose=False):
        type_check = isinstance(learning_rate, float) or isinstance(
740
            learning_rate, int) or isinstance(learning_rate, LRScheduler)
741 742
        if not type_check:
            raise TypeError(
743
                "the type of learning_rate should be [int, float or LRScheduler], the current type is {}".
744 745 746 747 748 749 750
                format(learning_rate))
        self.learning_rate = learning_rate
        self.warmup_steps = warmup_steps
        self.start_lr = start_lr
        self.end_lr = end_lr
        assert end_lr > start_lr, "end_lr {} must be greater than start_lr {}".format(
            end_lr, start_lr)
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        super(LinearWarmup, self).__init__(start_lr, last_epoch, verbose)
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    def get_lr(self):
        if self.last_epoch < self.warmup_steps:
            return (self.end_lr - self.start_lr) * float(
                self.last_epoch) / float(self.warmup_steps) + self.start_lr
        else:
758
            if isinstance(self.learning_rate, LRScheduler):
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                self.learning_rate.step()
                return self.learning_rate()

            return self.learning_rate


765
class ExponentialDecay(LRScheduler):
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    """

768
    Update learning rate by `gamma` each epoch.
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    The algorithm can be described as following.
    
    .. math::

        new\_learning\_rate = last\_learning\_rate * gamma

    Args:
        learning_rate (float): The initial learning rate. It is a python float number.
778 779
        gamma (float): The Ratio that the learning rate will be reduced. ``new_lr = origin_lr * gamma`` . 
            It should be less than 1.0.
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        last_epoch (int, optional):  The index of last epoch. Can be set to restart training. Default: -1, means initial learning rate.
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        verbose (bool, optional): If ``True``, prints a message to stdout for each update. Default: ``False`` .
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    Returns:
784
        ``ExponentialDecay`` instance to schedule learning rate.
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    Examples:
        
        .. code-block:: python

            import paddle
            import numpy as np

793
            # train on default dynamic graph mode
794
            linear = paddle.nn.Linear(10, 10)
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            scheduler = paddle.optimizer.lr.ExponentialDecay(learning_rate=0.5, gamma=0.9, verbose=True)
            sgd = paddle.optimizer.SGD(learning_rate=scheduler, parameters=linear.parameters())
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            for epoch in range(20):
                for batch_id in range(2):
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                    x = paddle.uniform([10, 10])
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                    out = linear(x)
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                    loss = paddle.mean(out)
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                    loss.backward()
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                    sgd.step()
                    sgd.clear_gradients()
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                scheduler.step()

807
            # train on static graph mode
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            paddle.enable_static()
            main_prog = paddle.static.Program()
            start_prog = paddle.static.Program()
            with paddle.static.program_guard(main_prog, start_prog):
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                x = paddle.static.data(name='x', shape=[None, 4, 5])
                y = paddle.static.data(name='y', shape=[None, 4, 5])
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                z = paddle.static.nn.fc(x, 100)
                loss = paddle.mean(z)
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                scheduler = paddle.optimizer.lr.ExponentialDecay(learning_rate=0.5, gamma=0.9, verbose=True)
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                sgd = paddle.optimizer.SGD(learning_rate=scheduler)
                sgd.minimize(loss)

            exe = paddle.static.Executor()
            exe.run(start_prog)
            for epoch in range(20):
                for batch_id in range(2):
                    out = exe.run(
                        main_prog,
                        feed={
                            'x': np.random.randn(3, 4, 5).astype('float32'),
                            'y': np.random.randn(3, 4, 5).astype('float32')
                        },
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                        fetch_list=loss.name)
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                scheduler.step()
    """

    def __init__(self, learning_rate, gamma, last_epoch=-1, verbose=False):
        self.gamma = gamma
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        super(ExponentialDecay, self).__init__(learning_rate, last_epoch,
                                               verbose)
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    def get_lr(self):
        return self.base_lr * (self.gamma**self.last_epoch)


843
class MultiStepDecay(LRScheduler):
844
    """
845
    Update the learning rate by ``gamma`` once ``epoch`` reaches one of the milestones.
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    The algorithm can be described as the code below. 

    .. code-block:: text

        learning_rate = 0.5
        milestones = [30, 50]
        gamma = 0.1
        if epoch < 30:
            learning_rate = 0.5
        elif epoch < 50:
            learning_rate = 0.05
        else:
            learning_rate = 0.005

    Args:
        learning_rate (float): The initial learning rate. It is a python float number.
        milestones (tuple|list): List or tuple of each boundaries. Must be increasing.
        gamma (float, optional): The Ratio that the learning rate will be reduced. ``new_lr = origin_lr * gamma`` . 
            It should be less than 1.0. Default: 0.1.
        last_epoch (int, optional):  The index of last epoch. Can be set to restart training. Default: -1, means initial learning rate.
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        verbose (bool, optional): If ``True``, prints a message to stdout for each update. Default: ``False`` .
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    Returns:
871
        ``MultiStepDecay`` instance to schedule learning rate.
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    Examples:
        
        .. code-block:: python

            import paddle
            import numpy as np

880
            # train on default dynamic graph mode
881
            linear = paddle.nn.Linear(10, 10)
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            scheduler = paddle.optimizer.lr.MultiStepDecay(learning_rate=0.5, milestones=[2, 4, 6], gamma=0.8, verbose=True)
            sgd = paddle.optimizer.SGD(learning_rate=scheduler, parameters=linear.parameters())
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            for epoch in range(20):
                for batch_id in range(2):
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                    x = paddle.uniform([10, 10])
887
                    out = linear(x)
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                    loss = paddle.mean(out)
889
                    loss.backward()
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                    sgd.step()
                    sgd.clear_gradients()
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                scheduler.step()

894
            # train on static graph mode
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            paddle.enable_static()
            main_prog = paddle.static.Program()
            start_prog = paddle.static.Program()
            with paddle.static.program_guard(main_prog, start_prog):
899 900
                x = paddle.static.data(name='x', shape=[None, 4, 5])
                y = paddle.static.data(name='y', shape=[None, 4, 5])
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                z = paddle.static.nn.fc(x, 100)
                loss = paddle.mean(z)
903
                scheduler = paddle.optimizer.lr.MultiStepDecay(learning_rate=0.5, milestones=[2, 4, 6], gamma=0.8, verbose=True)
904 905 906 907 908 909 910 911 912 913 914 915 916
                sgd = paddle.optimizer.SGD(learning_rate=scheduler)
                sgd.minimize(loss)

            exe = paddle.static.Executor()
            exe.run(start_prog)
            for epoch in range(20):
                for batch_id in range(2):
                    out = exe.run(
                        main_prog,
                        feed={
                            'x': np.random.randn(3, 4, 5).astype('float32'),
                            'y': np.random.randn(3, 4, 5).astype('float32')
                        },
917
                        fetch_list=loss.name)
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                scheduler.step()
    """

    def __init__(self,
                 learning_rate,
                 milestones,
                 gamma=0.1,
                 last_epoch=-1,
                 verbose=False):
        if not isinstance(milestones, (tuple, list)):
            raise TypeError(
                "The type of 'milestones' in 'MultiStepDecay' must be 'tuple, list', but received %s."
                % type(milestones))

        if not all([
                milestones[i] < milestones[i + 1]
                for i in range(len(milestones) - 1)
        ]):
            raise ValueError('The elements of milestones must be incremented')
        if gamma >= 1.0:
            raise ValueError('gamma should be < 1.0.')

        self.milestones = milestones
        self.gamma = gamma
942
        super(MultiStepDecay, self).__init__(learning_rate, last_epoch, verbose)
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    def get_lr(self):
        for i in range(len(self.milestones)):
            if self.last_epoch < self.milestones[i]:
                return self.base_lr * (self.gamma**i)
        return self.base_lr * (self.gamma**len(self.milestones))


951
class StepDecay(LRScheduler):
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    """
    Update the learning rate of ``optimizer`` by ``gamma`` every ``step_size`` number of epoch.

    The algorithm can be described as the code below. 

    .. code-block:: text

        learning_rate = 0.5
        step_size = 30
        gamma = 0.1

        learning_rate = 0.5     if epoch < 30
        learning_rate = 0.05    if 30 <= epoch < 60
        learning_rate = 0.005   if 60 <= epoch < 90
        ...

    Args:
        learning_rate (float): The initial learning rate. It is a python float number.
        step_size (int): the interval to update.
        gamma (float, optional): The Ratio that the learning rate will be reduced. ``new_lr = origin_lr * gamma`` . 
            It should be less than 1.0. Default: 0.1.
        last_epoch (int, optional):  The index of last epoch. Can be set to restart training. Default: -1, means initial learning rate.
974
        verbose (bool, optional): If ``True``, prints a message to stdout for each update. Default: ``False`` .
975 976

    Returns:
977
        ``StepDecay`` instance to schedule learning rate.
978 979 980 981 982 983 984 985 986


    Examples:
        
        .. code-block:: python

            import paddle
            import numpy as np

987
            # train on default dynamic graph mode
988
            linear = paddle.nn.Linear(10, 10)
989 990
            scheduler = paddle.optimizer.lr.StepDecay(learning_rate=0.5, step_size=5, gamma=0.8, verbose=True)
            sgd = paddle.optimizer.SGD(learning_rate=scheduler, parameters=linear.parameters())
991 992
            for epoch in range(20):
                for batch_id in range(2):
993
                    x = paddle.uniform([10, 10])
994
                    out = linear(x)
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                    loss = paddle.mean(out)
996
                    loss.backward()
997 998
                    sgd.step()
                    sgd.clear_gradients()
999 1000
                scheduler.step()

1001
            # train on static graph mode
1002 1003 1004 1005
            paddle.enable_static()
            main_prog = paddle.static.Program()
            start_prog = paddle.static.Program()
            with paddle.static.program_guard(main_prog, start_prog):
1006 1007
                x = paddle.static.data(name='x', shape=[None, 4, 5])
                y = paddle.static.data(name='y', shape=[None, 4, 5])
1008 1009
                z = paddle.static.nn.fc(x, 100)
                loss = paddle.mean(z)
1010
                scheduler = paddle.optimizer.lr.StepDecay(learning_rate=0.5, step_size=5, gamma=0.8, verbose=True)
1011 1012 1013 1014 1015 1016 1017 1018 1019 1020 1021 1022 1023
                sgd = paddle.optimizer.SGD(learning_rate=scheduler)
                sgd.minimize(loss)

            exe = paddle.static.Executor()
            exe.run(start_prog)
            for epoch in range(20):
                for batch_id in range(2):
                    out = exe.run(
                        main_prog,
                        feed={
                            'x': np.random.randn(3, 4, 5).astype('float32'),
                            'y': np.random.randn(3, 4, 5).astype('float32')
                        },
1024
                        fetch_list=loss.name)
1025 1026 1027 1028 1029 1030 1031 1032 1033 1034 1035 1036 1037 1038 1039 1040 1041 1042
                scheduler.step()
    """

    def __init__(self,
                 learning_rate,
                 step_size,
                 gamma=0.1,
                 last_epoch=-1,
                 verbose=False):
        if not isinstance(step_size, int):
            raise TypeError(
                "The type of 'step_size' must be 'int', but received %s." %
                type(step_size))
        if gamma >= 1.0:
            raise ValueError('gamma should be < 1.0.')

        self.step_size = step_size
        self.gamma = gamma
1043
        super(StepDecay, self).__init__(learning_rate, last_epoch, verbose)
1044 1045 1046 1047 1048 1049

    def get_lr(self):
        i = self.last_epoch // self.step_size
        return self.base_lr * (self.gamma**i)


1050
class LambdaDecay(LRScheduler):
1051 1052 1053 1054 1055 1056 1057 1058 1059 1060
    """
    Sets the learning rate of ``optimizer`` by function ``lr_lambda`` . ``lr_lambda`` is funciton which receives ``epoch`` .

    The algorithm can be described as the code below. 

    .. code-block:: text

        learning_rate = 0.5        # init learning_rate
        lr_lambda = lambda epoch: 0.95 ** epoch

1061 1062 1063
        learning_rate = 0.5        # epoch 0, 0.5*0.95**0
        learning_rate = 0.475      # epoch 1, 0.5*0.95**1
        learning_rate = 0.45125    # epoch 2, 0.5*0.95**2
1064 1065 1066 1067 1068

    Args:
        learning_rate (float): The initial learning rate. It is a python float number.
        lr_lambda (function): A function which computes a factor by ``epoch`` , and then multiply the initial learning rate by this factor.
        last_epoch (int, optional):  The index of last epoch. Can be set to restart training. Default: -1, means initial learning rate.
1069
        verbose (bool, optional): If ``True``, prints a message to stdout for each update. Default: ``False`` .
1070 1071
    
    Returns:
1072
        ``LambdaDecay`` instance to schedule learning rate.
1073 1074 1075 1076 1077 1078 1079 1080

    Examples:
        
        .. code-block:: python

            import paddle
            import numpy as np

1081
            # train on default dynamic graph mode
1082
            linear = paddle.nn.Linear(10, 10)
1083 1084
            scheduler = paddle.optimizer.lr.LambdaDecay(learning_rate=0.5, lr_lambda=lambda x:0.95**x, verbose=True)
            sgd = paddle.optimizer.SGD(learning_rate=scheduler, parameters=linear.parameters())
1085 1086
            for epoch in range(20):
                for batch_id in range(2):
1087
                    x = paddle.uniform([10, 10])
1088
                    out = linear(x)
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                    loss = paddle.mean(out)
1090
                    loss.backward()
1091 1092
                    sgd.step()
                    sgd.clear_gradients()
1093 1094
                scheduler.step()

1095
            # train on static graph mode
1096 1097 1098 1099
            paddle.enable_static()
            main_prog = paddle.static.Program()
            start_prog = paddle.static.Program()
            with paddle.static.program_guard(main_prog, start_prog):
1100 1101
                x = paddle.static.data(name='x', shape=[None, 4, 5])
                y = paddle.static.data(name='y', shape=[None, 4, 5])
1102 1103
                z = paddle.static.nn.fc(x, 100)
                loss = paddle.mean(z)
1104
                scheduler = paddle.optimizer.lr.LambdaDecay(learning_rate=0.5, lr_lambda=lambda x:0.95**x, verbose=True)
1105 1106 1107 1108 1109 1110 1111 1112 1113 1114 1115 1116 1117
                sgd = paddle.optimizer.SGD(learning_rate=scheduler)
                sgd.minimize(loss)

            exe = paddle.static.Executor()
            exe.run(start_prog)
            for epoch in range(20):
                for batch_id in range(2):
                    out = exe.run(
                        main_prog,
                        feed={
                            'x': np.random.randn(3, 4, 5).astype('float32'),
                            'y': np.random.randn(3, 4, 5).astype('float32')
                        },
1118
                        fetch_list=loss.name)
1119 1120 1121 1122 1123 1124 1125
                scheduler.step()

    """

    def __init__(self, learning_rate, lr_lambda, last_epoch=-1, verbose=False):
        if not callable(lr_lambda):
            raise TypeError(
1126
                "The type of 'lr_lambda' in 'LambdaDecay' must be 'function', but received %s."
1127 1128 1129
                % type(lr_lambda))

        self.lr_lambda = lr_lambda
1130
        super(LambdaDecay, self).__init__(learning_rate, last_epoch, verbose)
1131 1132 1133 1134 1135

    def get_lr(self):
        return self.base_lr * self.lr_lambda(self.last_epoch)


1136
class ReduceOnPlateau(LRScheduler):
1137 1138 1139 1140 1141 1142 1143 1144 1145 1146 1147 1148 1149 1150 1151 1152 1153 1154 1155 1156 1157 1158 1159 1160 1161 1162 1163
    """
    Reduce learning rate when ``metrics`` has stopped descending. Models often benefit from reducing the learning rate 
    by 2 to 10 times once model performance has no longer improvement.

    The ``metrics`` is the one which has been pass into ``step`` , it must be 1-D Tensor with shape [1]. When ``metrics`` 
    stop descending for a ``patience`` number of epochs, the learning rate will be reduced to ``learning_rate * factor`` . 
    (Specially, ``mode`` can also be set to ``'max`` , in this case, when ``metrics`` stop ascending for a ``patience`` 
    number of epochs, the learning rate will be reduced.)

    In addition, After each reduction, it will wait a ``cooldown`` number of epochs before resuming above operation.

    Args:
        learning_rate (float): The initial learning rate. It is a python float number.
        mode (str, optional): ``'min'`` or ``'max'`` can be selected. Normally, it is ``'min'`` , which means that the 
            learning rate will reduce when ``loss`` stops descending. Specially, if it's set to ``'max'`` ,  the learning 
            rate will reduce when ``loss`` stops ascending. Default: ``'min'`` .
        factor (float, optional): The Ratio that the learning rate will be reduced. ``new_lr = origin_lr * factor`` . 
            It should be less than 1.0. Default: 0.1.
        patience (int, optional): When ``loss`` doesn't improve for this number of epochs, learing rate will be reduced. 
            Default: 10.
        threshold (float, optional): ``threshold`` and ``threshold_mode`` will determine the minimum change of ``loss`` . 
            This make tiny changes of ``loss`` will be ignored. Default: 1e-4.
        threshold_mode (str, optional): ``'rel'`` or ``'abs'`` can be selected. In ``'rel'`` mode, the minimum change of ``loss``
            is ``last_loss * threshold`` , where ``last_loss`` is ``loss`` in last epoch. In ``'abs'`` mode, the minimum 
            change of ``loss`` is ``threshold`` . Default: ``'rel'`` .
        cooldown (int, optional): The number of epochs to wait before resuming normal operation. Default: 0.
        min_lr (float, optional): The lower bound of the learning rate after reduction. Default: 0.
1164 1165
        epsilon (float, optional): Minimal decay applied to lr. If the difference between new and old lr is smaller than epsilon, 
            the update is ignored. Default: 1e-8.
1166 1167 1168 1169
        verbose (bool, optional): If ``True``, prints a message to stdout for each update. Default: ``False``.

    
    Returns:
1170
        ``ReduceOnPlateau`` instance to schedule learning rate.
1171 1172 1173 1174 1175 1176 1177 1178


    Examples:
        .. code-block:: python

            import paddle
            import numpy as np

1179
            # train on default dynamic graph mode
1180
            linear = paddle.nn.Linear(10, 10)
1181 1182
            scheduler = paddle.optimizer.lr.ReduceOnPlateau(learning_rate=1.0, factor=0.5, patience=5, verbose=True)
            sgd = paddle.optimizer.SGD(learning_rate=scheduler, parameters=linear.parameters())
1183 1184
            for epoch in range(20):
                for batch_id in range(2):
1185
                    x = paddle.uniform([10, 10])
1186
                    out = linear(x)
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                    loss = paddle.mean(out)
1188
                    loss.backward()
1189 1190
                    sgd.step()
                    sgd.clear_gradients()
1191 1192
                scheduler.step(loss)

1193
            # train on static graph mode
1194 1195 1196 1197
            paddle.enable_static()
            main_prog = paddle.static.Program()
            start_prog = paddle.static.Program()
            with paddle.static.program_guard(main_prog, start_prog):
1198 1199
                x = paddle.static.data(name='x', shape=[None, 4, 5])
                y = paddle.static.data(name='y', shape=[None, 4, 5])
1200 1201
                z = paddle.static.nn.fc(x, 100)
                loss = paddle.mean(z)
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                scheduler = paddle.optimizer.lr.ReduceOnPlateau(learning_rate=1.0, factor=0.5, patience=5, verbose=True)
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                sgd = paddle.optimizer.SGD(learning_rate=scheduler)
                sgd.minimize(loss)

            exe = paddle.static.Executor()
            exe.run(start_prog)
            for epoch in range(20):
                for batch_id in range(2):
                    out = exe.run(
                        main_prog,
                        feed={
                            'x': np.random.randn(3, 4, 5).astype('float32'),
                            'y': np.random.randn(3, 4, 5).astype('float32')
                        },
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                        fetch_list=loss.name)
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                scheduler.step(out[0])

    """

    def __init__(self,
                 learning_rate,
                 mode='min',
                 factor=0.1,
                 patience=10,
                 threshold=1e-4,
                 threshold_mode='rel',
                 cooldown=0,
                 min_lr=0,
                 epsilon=1e-8,
                 verbose=False):
        mode = mode.lower()
        if mode not in ['min', 'max']:
            raise ValueError('mode: ' + mode + ' is unknown!')
        self.mode = mode

        if factor >= 1.0:
            raise ValueError(
                'new_lr = origin_lr * gamma and gamma should be < 1.0.')
        self.factor = factor

        threshold_mode = threshold_mode.lower()
        if threshold_mode not in ['rel', 'abs']:
            raise ValueError('threshold mode: ' + threshold_mode +
                             ' is unknown!')
        self.threshold_mode = threshold_mode
        if not isinstance(learning_rate, (float, int)):
            raise TypeError(
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                "The type of 'learning_rate' in 'ReduceOnPlateau' must be 'float', but received %s."
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                % type(learning_rate))

        self.verbose = verbose
        self.patience = patience
        self.threshold = threshold
        self.threshold_mode = threshold_mode
        self.cooldown = cooldown
        self.min_lr = min_lr
        self.epsilon = epsilon

        self.cooldown_counter = 0
        self.best = None
        self.num_bad_epochs = 0

        # Can not call Parent __init__, so implement here.
        self.base_lr = float(learning_rate)
        self.last_lr = float(learning_rate)
        self.last_epoch = 0
        self.verbose = verbose
        self._var_name = None

    # "cooldown_counter / best / num_bad_epochs / last_epoch / last_lr" will be stored.
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    def state_keys(self):
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        self.keys = [
            'cooldown_counter', 'best', 'num_bad_epochs', 'last_epoch',
            'last_lr'
        ]

    def step(self, metrics, epoch=None):
        """
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        step should be called after `optimizer.step()` . It will update the learning rate in optimizer according to ``metrics`` .  
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        The new learning rate will take effect on next epoch.

        Args:
            metrics (Tensor|numpy.ndarray|float): Which will be monitored to determine whether the learning rate will reduce. 
                If it stop descending for a ``patience`` number of epochs, the learning rate will reduce. If it's 'Tensor' or
                'numpy.ndarray', its shape must be [1].
            epoch (int, None): specify current epoch. Default: None. Auto-increment from last_epoch=-1.

        Returns:
            None
        
        Examples:
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            Please refer to the example of current LRScheduler.
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        """
        if epoch is None:
            self.last_epoch = self.last_epoch + 1
        else:
            self.last_epoch = epoch

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        # loss must be float, numpy.ndarray or 1-D Tensor with shape [1]
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        if isinstance(metrics, (Tensor, numpy.ndarray)):
            assert len(metrics.shape) == 1 and metrics.shape[0] == 1, "the metrics.shape " \
                "should be (1L,), but the current metrics.shape is {}. Maybe that "  \
                "you should call paddle.mean to process it first.".format(loss.shape)
        elif not isinstance(metrics,
                            (int, float, numpy.float32, numpy.float64)):
            raise TypeError(
                "metrics must be 'int', 'float', 'np.float', 'numpy.ndarray' or 'paddle.Tensor', but receive {}".
                format(type(metrics)))

        if self.cooldown_counter > 0:
            self.cooldown_counter -= 1
        else:
            if self.best is None or self._is_better(metrics, self.best):
                self.best = metrics
                self.num_bad_epochs = 0
            else:
                self.num_bad_epochs += 1

            if self.num_bad_epochs > self.patience:
                self.cooldown_counter = self.cooldown
                self.num_bad_epochs = 0
                new_lr = max(self.last_lr * self.factor, self.min_lr)
                if self.last_lr - new_lr > self.epsilon:
                    self.last_lr = new_lr
                    if self.verbose:
                        print('Epoch {}: {} set learning rate to {}.'.format(
                            self.last_epoch, self.__class__.__name__,
                            self.last_lr))

    def _is_better(self, current, best):
        if self.mode == 'min' and self.threshold_mode == 'rel':
            return current < best - best * self.threshold

        elif self.mode == 'min' and self.threshold_mode == 'abs':
            return current < best - self.threshold

        elif self.mode == 'max' and self.threshold_mode == 'rel':
            return current > best + best * self.threshold

        else:
            return current > best + self.threshold


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class CosineAnnealingDecay(LRScheduler):
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    """

    Set the learning rate using a cosine annealing schedule, where :math:`\eta_{max}` is set to 
    the initial learning_rate. :math:`T_{cur}` is the number of epochs since the last restart in 
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    SGDR.
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    The algorithm can be described as following.

    .. math::
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        \\begin{aligned}
            \eta_t & = \eta_{min} + \\frac{1}{2}(\eta_{max} - \eta_{min})\left(1
            + \cos\left(\\frac{T_{cur}}{T_{max}}\pi\\right)\\right),
            & T_{cur} \\neq (2k+1)T_{max}; \\
            \eta_{t+1} & = \eta_{t} + \\frac{1}{2}(\eta_{max} - \eta_{min})
            \left(1 - \cos\left(\\frac{1}{T_{max}}\pi\\right)\\right),
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            & T_{cur} = (2k+1)T_{max}.
        \end{aligned}
    
    It has been proposed in `SGDR: Stochastic Gradient Descent with Warm Restarts <https://arxiv.org/abs/1608.03983>`_. 
    Note that this only implements the cosine annealing part of SGDR, and not the restarts.
    
    Args:
        learning_rate (float): The initial learning rate, that is :math:`\eta_{max}` . It can be set to python float or int number.
        T_max (int): Maximum number of iterations. It is half of the decay cycle of learning rate.
        eta_min (float|int, optional): Minimum learning rate, that is :math:`\eta_{min}` . Default: 0.
        last_epoch (int, optional):  The index of last epoch. Can be set to restart training. Default: -1, means initial learning rate.
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        verbose (bool, optional): If ``True``, prints a message to stdout for each update. Default: ``False`` .
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    Returns:
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        ``CosineAnnealingDecay`` instance to schedule learning rate.
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    Examples:
        
        .. code-block:: python

            import paddle
            import numpy as np

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            # train on default dynamic graph mode
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            linear = paddle.nn.Linear(10, 10)
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            scheduler = paddle.optimizer.lr.CosineAnnealingDecay(learning_rate=0.5, T_max=10, verbose=True)
            sgd = paddle.optimizer.SGD(learning_rate=scheduler, parameters=linear.parameters())
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            for epoch in range(20):
                for batch_id in range(2):
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                    x = paddle.uniform([10, 10])
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                    out = linear(x)
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chentianyu03 已提交
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                    loss = paddle.mean(out)
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                    loss.backward()
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                    sgd.step()
                    sgd.clear_gradients()
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                scheduler.step()

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            # train on static graph mode
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            paddle.enable_static()
            main_prog = paddle.static.Program()
            start_prog = paddle.static.Program()
            with paddle.static.program_guard(main_prog, start_prog):
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                x = paddle.static.data(name='x', shape=[None, 4, 5])
                y = paddle.static.data(name='y', shape=[None, 4, 5])
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                z = paddle.static.nn.fc(x, 100)
                loss = paddle.mean(z)
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                scheduler = paddle.optimizer.lr.CosineAnnealingDecay(learning_rate=0.5, T_max=10, verbose=True)
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                sgd = paddle.optimizer.SGD(learning_rate=scheduler)
                sgd.minimize(loss)

            exe = paddle.static.Executor()
            exe.run(start_prog)
            for epoch in range(20):
                for batch_id in range(2):
                    out = exe.run(
                        main_prog,
                        feed={
                            'x': np.random.randn(3, 4, 5).astype('float32'),
                            'y': np.random.randn(3, 4, 5).astype('float32')
                        },
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                        fetch_list=loss.name)
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                scheduler.step()
    """

    def __init__(self,
                 learning_rate,
                 T_max,
                 eta_min=0,
                 last_epoch=-1,
                 verbose=False):
        if not isinstance(T_max, int):
            raise TypeError(
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                "The type of 'T_max' in 'CosineAnnealingDecay' must be 'int', but received %s."
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                % type(T_max))
        if not isinstance(eta_min, (float, int)):
            raise TypeError(
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                "The type of 'eta_min' in 'CosineAnnealingDecay' must be 'float, int', but received %s."
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                % type(eta_min))
        self.T_max = T_max
        self.eta_min = float(eta_min)
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        super(CosineAnnealingDecay, self).__init__(learning_rate, last_epoch,
                                                   verbose)
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    def get_lr(self):
        if self.last_epoch == 0:
            return self.base_lr
        elif (self.last_epoch - 1 - self.T_max) % (2 * self.T_max) == 0:
            return self.last_lr + (self.base_lr - self.eta_min) * (1 - math.cos(
                math.pi / self.T_max)) / 2

        return (1 + math.cos(math.pi * self.last_epoch / self.T_max)) / (
            1 + math.cos(math.pi * (self.last_epoch - 1) / self.T_max)) * (
                self.last_lr - self.eta_min) + self.eta_min

    def _get_closed_form_lr(self):
        return self.eta_min + (self.base_lr - self.eta_min) * (1 + math.cos(
            math.pi * self.last_epoch / self.T_max)) / 2