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seanyen
seanyen / tensorflow python
Repository URL to install this package:
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Version:
1.14.0 ▾
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# Copyright 2015 The TensorFlow 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.
# ==============================================================================
# pylint: disable=invalid-name
"""Built-in optimizer classes."""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
import six
from six.moves import zip # pylint: disable=redefined-builtin
from tensorflow.python.distribute import distribution_strategy_context
from tensorflow.python.framework import ops
from tensorflow.python.keras import backend as K
from tensorflow.python.keras.optimizer_v2 import adadelta as adadelta_v2
from tensorflow.python.keras.optimizer_v2 import adagrad as adagrad_v2
from tensorflow.python.keras.optimizer_v2 import adam as adam_v2
from tensorflow.python.keras.optimizer_v2 import adamax as adamax_v2
from tensorflow.python.keras.optimizer_v2 import ftrl
from tensorflow.python.keras.optimizer_v2 import gradient_descent as gradient_descent_v2
from tensorflow.python.keras.optimizer_v2 import nadam as nadam_v2
from tensorflow.python.keras.optimizer_v2 import optimizer_v2
from tensorflow.python.keras.optimizer_v2 import rmsprop as rmsprop_v2
from tensorflow.python.keras.utils.generic_utils import deserialize_keras_object
from tensorflow.python.keras.utils.generic_utils import serialize_keras_object
from tensorflow.python.ops import clip_ops
from tensorflow.python.ops import math_ops
from tensorflow.python.ops import state_ops
from tensorflow.python.training import optimizer as tf_optimizer_module
from tensorflow.python.training import training_util
from tensorflow.python.training.tracking import base as trackable
from tensorflow.python.util.tf_export import keras_export
class Optimizer(object):
"""Abstract optimizer base class.
Note: this is the parent class of all optimizers, not an actual optimizer
that can be used for training models.
All Keras optimizers support the following keyword arguments:
clipnorm: float >= 0. Gradients will be clipped
when their L2 norm exceeds this value.
clipvalue: float >= 0. Gradients will be clipped
when their absolute value exceeds this value.
"""
def __init__(self, **kwargs):
allowed_kwargs = {'clipnorm', 'clipvalue'}
for k in kwargs:
if k not in allowed_kwargs:
raise TypeError('Unexpected keyword argument '
'passed to optimizer: ' + str(k))
# checks that clipnorm >= 0 and clipvalue >= 0
if kwargs[k] < 0:
raise ValueError('Expected {} >= 0, received: {}'.format(k, kwargs[k]))
self.__dict__.update(kwargs)
self.updates = []
self.weights = []
def get_updates(self, loss, params):
raise NotImplementedError
def get_gradients(self, loss, params):
"""Returns gradients of `loss` with respect to `params`.
Arguments:
loss: Loss tensor.
params: List of variables.
Returns:
List of gradient tensors.
Raises:
ValueError: In case any gradient cannot be computed (e.g. if gradient
function not implemented).
"""
grads = K.gradients(loss, params)
if None in grads:
raise ValueError('An operation has `None` for gradient. '
'Please make sure that all of your ops have a '
'gradient defined (i.e. are differentiable). '
'Common ops without gradient: '
'K.argmax, K.round, K.eval.')
if hasattr(self, 'clipnorm'):
grads = [clip_ops.clip_by_norm(g, self.clipnorm) for g in grads]
if hasattr(self, 'clipvalue'):
grads = [
clip_ops.clip_by_value(g, -self.clipvalue, self.clipvalue)
for g in grads
]
return grads
def set_weights(self, weights):
"""Sets the weights of the optimizer, from Numpy arrays.
Should only be called after computing the gradients
(otherwise the optimizer has no weights).
Arguments:
weights: a list of Numpy arrays. The number of arrays and their shape
must match number of the dimensions of the weights of the optimizer
(i.e. it should match the output of `get_weights`).
Raises:
ValueError: in case of incompatible weight shapes.
"""
params = self.weights
if len(params) != len(weights):
raise ValueError('Length of the specified weight list (' +
str(len(weights)) +
') does not match the number of weights '
'of the optimizer (' + str(len(params)) + ')')
weight_value_tuples = []
param_values = K.batch_get_value(params)
for pv, p, w in zip(param_values, params, weights):
if pv.shape != w.shape:
raise ValueError('Optimizer weight shape ' + str(pv.shape) +
' not compatible with '
'provided weight shape ' + str(w.shape))
weight_value_tuples.append((p, w))
K.batch_set_value(weight_value_tuples)
def get_weights(self):
"""Returns the current value of the weights of the optimizer.
Returns:
A list of numpy arrays.
"""
return K.batch_get_value(self.weights)
def get_config(self):
config = {}
if hasattr(self, 'clipnorm'):
config['clipnorm'] = self.clipnorm
if hasattr(self, 'clipvalue'):
config['clipvalue'] = self.clipvalue
return config
@classmethod
def from_config(cls, config):
return cls(**config)
class SGD(Optimizer):
"""Stochastic gradient descent optimizer.
Includes support for momentum,
learning rate decay, and Nesterov momentum.
Arguments:
lr: float >= 0. Learning rate.
momentum: float >= 0. Parameter that accelerates SGD in the relevant
direction and dampens oscillations.
decay: float >= 0. Learning rate decay over each update.
nesterov: boolean. Whether to apply Nesterov momentum.
"""
def __init__(self, lr=0.01, momentum=0., decay=0., nesterov=False, **kwargs):
super(SGD, self).__init__(**kwargs)
with K.name_scope(self.__class__.__name__):
self.iterations = K.variable(0, dtype='int64', name='iterations')
self.lr = K.variable(lr, name='lr')
self.momentum = K.variable(momentum, name='momentum')
self.decay = K.variable(decay, name='decay')
self.initial_decay = decay
self.nesterov = nesterov
def get_updates(self, loss, params):
grads = self.get_gradients(loss, params)
self.updates = [state_ops.assign_add(self.iterations, 1)]
lr = self.lr
if self.initial_decay > 0:
lr = lr * ( # pylint: disable=g-no-augmented-assignment
1. /
(1. +
self.decay * math_ops.cast(self.iterations, K.dtype(self.decay))))
# momentum
shapes = [K.int_shape(p) for p in params]
moments = [K.zeros(shape) for shape in shapes]
self.weights = [self.iterations] + moments
for p, g, m in zip(params, grads, moments):
v = self.momentum * m - lr * g # velocity
self.updates.append(state_ops.assign(m, v))
if self.nesterov:
new_p = p + self.momentum * v - lr * g
else:
new_p = p + v
# Apply constraints.
if getattr(p, 'constraint', None) is not None:
new_p = p.constraint(new_p)
self.updates.append(state_ops.assign(p, new_p))
return self.updates
def get_config(self):
config = {
'lr': float(K.get_value(self.lr)),
'momentum': float(K.get_value(self.momentum)),
'decay': float(K.get_value(self.decay)),
'nesterov': self.nesterov
}
base_config = super(SGD, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
class RMSprop(Optimizer):
"""RMSProp optimizer.
It is recommended to leave the parameters of this optimizer
at their default values
(except the learning rate, which can be freely tuned).
Arguments:
lr: float >= 0. Learning rate.
rho: float >= 0.
epsilon: float >= 0. Fuzz factor. If `None`, defaults to `K.epsilon()`.
decay: float >= 0. Learning rate decay over each update.
"""
def __init__(self, lr=0.001, rho=0.9, epsilon=None, decay=0., **kwargs):
super(RMSprop, self).__init__(**kwargs)
with K.name_scope(self.__class__.__name__):
self.lr = K.variable(lr, name='lr')
self.rho = K.variable(rho, name='rho')
self.decay = K.variable(decay, name='decay')
self.iterations = K.variable(0, dtype='int64', name='iterations')
if epsilon is None:
epsilon = K.epsilon()
self.epsilon = epsilon
self.initial_decay = decay
def get_updates(self, loss, params):
grads = self.get_gradients(loss, params)
accumulators = [K.zeros(K.int_shape(p), dtype=K.dtype(p)) for p in params]
self.weights = accumulators
self.updates = [state_ops.assign_add(self.iterations, 1)]
lr = self.lr
if self.initial_decay > 0:
lr = lr * ( # pylint: disable=g-no-augmented-assignment
1. /
(1. +
self.decay * math_ops.cast(self.iterations, K.dtype(self.decay))))
for p, g, a in zip(params, grads, accumulators):
# update accumulator
new_a = self.rho * a + (1. - self.rho) * math_ops.square(g)
self.updates.append(state_ops.assign(a, new_a))
new_p = p - lr * g / (K.sqrt(new_a) + self.epsilon)
# Apply constraints.
if getattr(p, 'constraint', None) is not None:
new_p = p.constraint(new_p)
self.updates.append(state_ops.assign(p, new_p))
return self.updates
def get_config(self):
config = {
'lr': float(K.get_value(self.lr)),
'rho': float(K.get_value(self.rho)),
'decay': float(K.get_value(self.decay)),
'epsilon': self.epsilon
}
base_config = super(RMSprop, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
class Adagrad(Optimizer):
"""Adagrad optimizer.
Adagrad is an optimizer with parameter-specific learning rates,
which are adapted relative to how frequently a parameter gets
updated during training. The more updates a parameter receives,
the smaller the updates.
It is recommended to leave the parameters of this optimizer
at their default values.
# Arguments
lr: float >= 0. Initial learning rate.
epsilon: float >= 0. If `None`, defaults to `K.epsilon()`.
decay: float >= 0. Learning rate decay over each update.
# References
- [Adaptive Subgradient Methods for Online Learning and Stochastic
Optimization](http://www.jmlr.org/papers/volume12/duchi11a/duchi11a.pdf)
"""
def __init__(self, lr=0.01, epsilon=None, decay=0., **kwargs):
super(Adagrad, self).__init__(**kwargs)
with K.name_scope(self.__class__.__name__):
self.lr = K.variable(lr, name='lr')
self.decay = K.variable(decay, name='decay')
self.iterations = K.variable(0, dtype='int64', name='iterations')
if epsilon is None:
epsilon = K.epsilon()
self.epsilon = epsilon
self.initial_decay = decay
def get_updates(self, loss, params):
grads = self.get_gradients(loss, params)
shapes = [K.int_shape(p) for p in params]
accumulators = [K.zeros(shape) for shape in shapes]
self.weights = accumulators
self.updates = [state_ops.assign_add(self.iterations, 1)]
lr = self.lr
if self.initial_decay > 0:
lr = lr * ( # pylint: disable=g-no-augmented-assignment
1. /
(1. +
self.decay * math_ops.cast(self.iterations, K.dtype(self.decay))))
for p, g, a in zip(params, grads, accumulators):
new_a = a + math_ops.square(g) # update accumulator
self.updates.append(state_ops.assign(a, new_a))
new_p = p - lr * g / (K.sqrt(new_a) + self.epsilon)
# Apply constraints.
if getattr(p, 'constraint', None) is not None:
new_p = p.constraint(new_p)
self.updates.append(state_ops.assign(p, new_p))
return self.updates
def get_config(self):
config = {
'lr': float(K.get_value(self.lr)),
'decay': float(K.get_value(self.decay)),
'epsilon': self.epsilon
}
base_config = super(Adagrad, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
class Adadelta(Optimizer):
"""Adadelta optimizer.
Adadelta is a more robust extension of Adagrad
that adapts learning rates based on a moving window of gradient updates,
instead of accumulating all past gradients. This way, Adadelta continues
learning even when many updates have been done. Compared to Adagrad, in the
original version of Adadelta you don't have to set an initial learning
rate. In this version, initial learning rate and decay factor can
be set, as in most other Keras optimizers.
It is recommended to leave the parameters of this optimizer
at their default values.
# Arguments
lr: float >= 0. Initial learning rate, defaults to 1.
It is recommended to leave it at the default value.
rho: float >= 0. Adadelta decay factor, corresponding to fraction of
gradient to keep at each time step.
epsilon: float >= 0. Fuzz factor. If `None`, defaults to `K.epsilon()`.
decay: float >= 0. Initial learning rate decay.
# References
- [Adadelta - an adaptive learning rate
method](http://arxiv.org/abs/1212.5701)
"""
def __init__(self, lr=1.0, rho=0.95, epsilon=None, decay=0., **kwargs):
super(Adadelta, self).__init__(**kwargs)
with K.name_scope(self.__class__.__name__):
self.lr = K.variable(lr, name='lr')
self.decay = K.variable(decay, name='decay')
self.iterations = K.variable(0, dtype='int64', name='iterations')
if epsilon is None:
epsilon = K.epsilon()
self.rho = rho
self.epsilon = epsilon
self.initial_decay = decay
def get_updates(self, loss, params):
grads = self.get_gradients(loss, params)
shapes = [K.int_shape(p) for p in params]
accumulators = [K.zeros(shape) for shape in shapes]
delta_accumulators = [K.zeros(shape) for shape in shapes]
self.weights = accumulators + delta_accumulators
self.updates = [state_ops.assign_add(self.iterations, 1)]
lr = self.lr
if self.initial_decay > 0:
lr = lr * ( # pylint: disable=g-no-augmented-assignment
1. /
(1. +
self.decay * math_ops.cast(self.iterations, K.dtype(self.decay))))
for p, g, a, d_a in zip(params, grads, accumulators, delta_accumulators):
# update accumulator
new_a = self.rho * a + (1. - self.rho) * math_ops.square(g)
self.updates.append(state_ops.assign(a, new_a))
# use the new accumulator and the *old* delta_accumulator
update = g * K.sqrt(d_a + self.epsilon) / K.sqrt(new_a + self.epsilon)
new_p = p - lr * update
# Apply constraints.
if getattr(p, 'constraint', None) is not None:
new_p = p.constraint(new_p)
self.updates.append(state_ops.assign(p, new_p))
# update delta_accumulator
new_d_a = self.rho * d_a + (1 - self.rho) * math_ops.square(update)
self.updates.append(state_ops.assign(d_a, new_d_a))
return self.updates
def get_config(self):
config = {
'lr': float(K.get_value(self.lr)),
'rho': self.rho,
'decay': float(K.get_value(self.decay)),
'epsilon': self.epsilon
}
base_config = super(Adadelta, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
class Adam(Optimizer):
"""Adam optimizer.
Default parameters follow those provided in the original paper.
Arguments:
lr: float >= 0. Learning rate.
beta_1: float, 0 < beta < 1. Generally close to 1.
beta_2: float, 0 < beta < 1. Generally close to 1.
epsilon: float >= 0. Fuzz factor. If `None`, defaults to `K.epsilon()`.
decay: float >= 0. Learning rate decay over each update.
amsgrad: boolean. Whether to apply the AMSGrad variant of this algorithm
from the paper "On the Convergence of Adam and Beyond".
"""
def __init__(self,
lr=0.001,
beta_1=0.9,
beta_2=0.999,
epsilon=None,
decay=0.,
amsgrad=False,
**kwargs):
super(Adam, self).__init__(**kwargs)
with K.name_scope(self.__class__.__name__):
self.iterations = K.variable(0, dtype='int64', name='iterations')
self.lr = K.variable(lr, name='lr')
self.beta_1 = K.variable(beta_1, name='beta_1')
self.beta_2 = K.variable(beta_2, name='beta_2')
self.decay = K.variable(decay, name='decay')
if epsilon is None:
epsilon = K.epsilon()
self.epsilon = epsilon
self.initial_decay = decay
self.amsgrad = amsgrad
def get_updates(self, loss, params):
grads = self.get_gradients(loss, params)
self.updates = []
lr = self.lr
if self.initial_decay > 0:
lr = lr * ( # pylint: disable=g-no-augmented-assignment
1. /
(1. +
self.decay * math_ops.cast(self.iterations, K.dtype(self.decay))))
with ops.control_dependencies([state_ops.assign_add(self.iterations, 1)]):
t = math_ops.cast(self.iterations, K.floatx())
lr_t = lr * (
K.sqrt(1. - math_ops.pow(self.beta_2, t)) /
(1. - math_ops.pow(self.beta_1, t)))
ms = [K.zeros(K.int_shape(p), dtype=K.dtype(p)) for p in params]
vs = [K.zeros(K.int_shape(p), dtype=K.dtype(p)) for p in params]
if self.amsgrad:
vhats = [K.zeros(K.int_shape(p), dtype=K.dtype(p)) for p in params]
else:
vhats = [K.zeros(1) for _ in params]
self.weights = [self.iterations] + ms + vs + vhats
for p, g, m, v, vhat in zip(params, grads, ms, vs, vhats):
m_t = (self.beta_1 * m) + (1. - self.beta_1) * g
v_t = (self.beta_2 * v) + (1. - self.beta_2) * math_ops.square(g)
if self.amsgrad:
vhat_t = math_ops.maximum(vhat, v_t)
p_t = p - lr_t * m_t / (K.sqrt(vhat_t) + self.epsilon)
self.updates.append(state_ops.assign(vhat, vhat_t))
else:
p_t = p - lr_t * m_t / (K.sqrt(v_t) + self.epsilon)
self.updates.append(state_ops.assign(m, m_t))
self.updates.append(state_ops.assign(v, v_t))
new_p = p_t
# Apply constraints.
if getattr(p, 'constraint', None) is not None:
new_p = p.constraint(new_p)
self.updates.append(state_ops.assign(p, new_p))
return self.updates
def get_config(self):
config = {
'lr': float(K.get_value(self.lr)),
'beta_1': float(K.get_value(self.beta_1)),
'beta_2': float(K.get_value(self.beta_2)),
'decay': float(K.get_value(self.decay)),
'epsilon': self.epsilon,
'amsgrad': self.amsgrad
}
base_config = super(Adam, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
class Adamax(Optimizer):
"""Adamax optimizer from Adam paper's Section 7.
It is a variant of Adam based on the infinity norm.
Default parameters follow those provided in the paper.
Arguments:
lr: float >= 0. Learning rate.
beta_1/beta_2: floats, 0 < beta < 1. Generally close to 1.
epsilon: float >= 0. Fuzz factor. If `None`, defaults to `K.epsilon()`.
decay: float >= 0. Learning rate decay over each update.
"""
def __init__(self,
lr=0.002,
beta_1=0.9,
beta_2=0.999,
epsilon=None,
decay=0.,
**kwargs):
super(Adamax, self).__init__(**kwargs)
with K.name_scope(self.__class__.__name__):
self.iterations = K.variable(0, dtype='int64', name='iterations')
self.lr = K.variable(lr, name='lr')
self.beta_1 = K.variable(beta_1, name='beta_1')
self.beta_2 = K.variable(beta_2, name='beta_2')
self.decay = K.variable(decay, name='decay')
if epsilon is None:
epsilon = K.epsilon()
self.epsilon = epsilon
self.initial_decay = decay
def get_updates(self, loss, params):
grads = self.get_gradients(loss, params)
self.updates = []
lr = self.lr
if self.initial_decay > 0:
lr = lr * ( # pylint: disable=g-no-augmented-assignment
1. /
(1. +
self.decay * math_ops.cast(self.iterations, K.dtype(self.decay))))
with ops.control_dependencies([state_ops.assign_add(self.iterations, 1)]):
t = math_ops.cast(self.iterations, K.floatx())
lr_t = lr / (1. - math_ops.pow(self.beta_1, t))
shapes = [K.int_shape(p) for p in params]
# zero init of 1st moment
ms = [K.zeros(shape) for shape in shapes]
# zero init of exponentially weighted infinity norm
us = [K.zeros(shape) for shape in shapes]
self.weights = [self.iterations] + ms + us
for p, g, m, u in zip(params, grads, ms, us):
m_t = (self.beta_1 * m) + (1. - self.beta_1) * g
u_t = math_ops.maximum(self.beta_2 * u, math_ops.abs(g))
p_t = p - lr_t * m_t / (u_t + self.epsilon)
self.updates.append(state_ops.assign(m, m_t))
self.updates.append(state_ops.assign(u, u_t))
new_p = p_t
# Apply constraints.
if getattr(p, 'constraint', None) is not None:
new_p = p.constraint(new_p)
self.updates.append(state_ops.assign(p, new_p))
return self.updates
def get_config(self):
config = {
'lr': float(K.get_value(self.lr)),
'beta_1': float(K.get_value(self.beta_1)),
'beta_2': float(K.get_value(self.beta_2)),
'decay': float(K.get_value(self.decay)),
'epsilon': self.epsilon
}
base_config = super(Adamax, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
class Nadam(Optimizer):
"""Nesterov Adam optimizer.
Much like Adam is essentially RMSprop with momentum,
Nadam is Adam RMSprop with Nesterov momentum.
Default parameters follow those provided in the paper.
It is recommended to leave the parameters of this optimizer
at their default values.
Arguments:
lr: float >= 0. Learning rate.
beta_1/beta_2: floats, 0 < beta < 1. Generally close to 1.
epsilon: float >= 0. Fuzz factor. If `None`, defaults to `K.epsilon()`.
"""
def __init__(self,
lr=0.002,
beta_1=0.9,
beta_2=0.999,
epsilon=None,
schedule_decay=0.004,
**kwargs):
super(Nadam, self).__init__(**kwargs)
with K.name_scope(self.__class__.__name__):
self.iterations = K.variable(0, dtype='int64', name='iterations')
self.m_schedule = K.variable(1., name='m_schedule')
self.lr = K.variable(lr, name='lr')
self.beta_1 = K.variable(beta_1, name='beta_1')
self.beta_2 = K.variable(beta_2, name='beta_2')
if epsilon is None:
epsilon = K.epsilon()
self.epsilon = epsilon
self.schedule_decay = schedule_decay
def get_updates(self, loss, params):
grads = self.get_gradients(loss, params)
self.updates = []
with ops.control_dependencies([state_ops.assign_add(self.iterations, 1)]):
t = math_ops.cast(self.iterations, K.floatx())
# Due to the recommendations in [2], i.e. warming momentum schedule
momentum_cache_t = self.beta_1 * (
1. - 0.5 *
(math_ops.pow(K.cast_to_floatx(0.96), t * self.schedule_decay)))
momentum_cache_t_1 = self.beta_1 * (
1. - 0.5 *
(math_ops.pow(K.cast_to_floatx(0.96), (t + 1) * self.schedule_decay)))
m_schedule_new = self.m_schedule * momentum_cache_t
m_schedule_next = self.m_schedule * momentum_cache_t * momentum_cache_t_1
self.updates.append((self.m_schedule, m_schedule_new))
shapes = [K.int_shape(p) for p in params]
ms = [K.zeros(shape) for shape in shapes]
vs = [K.zeros(shape) for shape in shapes]
self.weights = [self.iterations, self.m_schedule] + ms + vs
for p, g, m, v in zip(params, grads, ms, vs):
# the following equations given in [1]
g_prime = g / (1. - m_schedule_new)
m_t = self.beta_1 * m + (1. - self.beta_1) * g
m_t_prime = m_t / (1. - m_schedule_next)
v_t = self.beta_2 * v + (1. - self.beta_2) * math_ops.square(g)
v_t_prime = v_t / (1. - math_ops.pow(self.beta_2, t))
m_t_bar = (1. -
momentum_cache_t) * g_prime + momentum_cache_t_1 * m_t_prime
self.updates.append(state_ops.assign(m, m_t))
self.updates.append(state_ops.assign(v, v_t))
p_t = p - self.lr * m_t_bar / (K.sqrt(v_t_prime) + self.epsilon)
new_p = p_t
# Apply constraints.
if getattr(p, 'constraint', None) is not None:
new_p = p.constraint(new_p)
self.updates.append(state_ops.assign(p, new_p))
return self.updates
def get_config(self):
config = {
'lr': float(K.get_value(self.lr)),
'beta_1': float(K.get_value(self.beta_1)),
'beta_2': float(K.get_value(self.beta_2)),
'epsilon': self.epsilon,
'schedule_decay': self.schedule_decay
}
base_config = super(Nadam, self).get_config()
return dict(list(base_config.items()) + list(config.items()))
class TFOptimizer(Optimizer, trackable.Trackable):
"""Wrapper class for native TensorFlow optimizers."""
def __init__(self, optimizer, iterations=None): # pylint: disable=super-init-not-called
self.optimizer = optimizer
self._track_trackable(optimizer, name='optimizer')
if iterations is None:
with K.name_scope(self.__class__.__name__):
self.iterations = K.variable(0, dtype='int64', name='iterations')
else:
self.iterations = iterations
self._track_trackable(self.iterations, name='global_step')
def apply_gradients(self, grads):
self.optimizer.apply_gradients(grads, global_step=self.iterations)
def get_grads(self, loss, params):
return self.optimizer.compute_gradients(loss, params)
def get_updates(self, loss, params):
if distribution_strategy_context.has_strategy():
self.updates = []
if not params:
# After the model vars have been created, the second call to get_updates
# is called with params as an empty list. This ensures that we call
# compute_gradients with params=None.
grads = self.optimizer.compute_gradients(loss)
else:
grads = self.optimizer.compute_gradients(loss, params)
global_step = training_util.get_global_step()
opt_update = self.optimizer.apply_gradients(grads, global_step)
else:
if not params:
self.updates = [state_ops.assign_add(self.iterations, 1)]
return self.updates
# Updates list starts out empty because the iterations variable is
# incremented in optimizer.apply_gradients()
self.updates = []
grads = self.optimizer.compute_gradients(loss, params)
opt_update = self.optimizer.apply_gradients(
grads, global_step=self.iterations)
self.updates.append(opt_update)
return self.updates
@property
def weights(self):
raise NotImplementedError
def get_config(self):
raise NotImplementedError
def from_config(self, config):
raise NotImplementedError
# Aliases.
sgd = SGD
rmsprop = RMSprop
adagrad = Adagrad
adadelta = Adadelta
adam = Adam
adamax = Adamax
nadam = Nadam
@keras_export('keras.optimizers.serialize')
def serialize(optimizer):
return serialize_keras_object(optimizer)
@keras_export('keras.optimizers.deserialize')
def deserialize(config, custom_objects=None):
"""Inverse of the `serialize` function.
Arguments:
config: Optimizer configuration dictionary.
custom_objects: Optional dictionary mapping names (strings) to custom
objects (classes and functions) to be considered during deserialization.
Returns:
A Keras Optimizer instance.
"""
all_classes = {
'adadelta': adadelta_v2.Adadelta,
'adagrad': adagrad_v2.Adagrad,
'adam': adam_v2.Adam,
'adamax': adamax_v2.Adamax,
'nadam': nadam_v2.Nadam,
'rmsprop': rmsprop_v2.RMSprop,
'sgd': gradient_descent_v2.SGD,
'ftrl': ftrl.Ftrl
}
# Make deserialization case-insensitive for built-in optimizers.
if config['class_name'].lower() in all_classes:
config['class_name'] = config['class_name'].lower()
return deserialize_keras_object(
config,
module_objects=all_classes,
custom_objects=custom_objects,
printable_module_name='optimizer')
@keras_export('keras.optimizers.get')
def get(identifier):
"""Retrieves a Keras Optimizer instance.
Arguments:
identifier: Optimizer identifier, one of
- String: name of an optimizer
- Dictionary: configuration dictionary. - Keras Optimizer instance (it
will be returned unchanged). - TensorFlow Optimizer instance (it
will be wrapped as a Keras Optimizer).
Returns:
A Keras Optimizer instance.
Raises:
ValueError: If `identifier` cannot be interpreted.
"""
if isinstance(identifier, (Optimizer, optimizer_v2.OptimizerV2)):
return identifier
# Wrap TF optimizer instances
elif isinstance(identifier, tf_optimizer_module.Optimizer):
opt = TFOptimizer(identifier)
K.track_tf_optimizer(opt)
return opt
elif isinstance(identifier, dict):
return deserialize(identifier)
elif isinstance(identifier, six.string_types):
config = {'class_name': str(identifier), 'config': {}}
return deserialize(config)
else:
raise ValueError('Could not interpret optimizer identifier:', identifier)