# 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 """Constraints: functions that impose constraints on weight values. """ from __future__ import absolute_import from __future__ import division from __future__ import print_function import six from tensorflow.python.keras import backend as K 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 math_ops from tensorflow.python.util.tf_export import tf_export @tf_export('keras.constraints.Constraint') class Constraint(object): def __call__(self, w): return w def get_config(self): return {} @tf_export('keras.constraints.MaxNorm', 'keras.constraints.max_norm') class MaxNorm(Constraint): """MaxNorm weight constraint. Constrains the weights incident to each hidden unit to have a norm less than or equal to a desired value. Arguments: m: the maximum norm for the incoming weights. axis: integer, axis along which to calculate weight norms. For instance, in a `Dense` layer the weight matrix has shape `(input_dim, output_dim)`, set `axis` to `0` to constrain each weight vector of length `(input_dim,)`. In a `Conv2D` layer with `data_format="channels_last"`, the weight tensor has shape `(rows, cols, input_depth, output_depth)`, set `axis` to `[0, 1, 2]` to constrain the weights of each filter tensor of size `(rows, cols, input_depth)`. """ def __init__(self, max_value=2, axis=0): self.max_value = max_value self.axis = axis def __call__(self, w): norms = K.sqrt( math_ops.reduce_sum(math_ops.square(w), axis=self.axis, keepdims=True)) desired = K.clip(norms, 0, self.max_value) return w * (desired / (K.epsilon() + norms)) def get_config(self): return {'max_value': self.max_value, 'axis': self.axis} @tf_export('keras.constraints.NonNeg', 'keras.constraints.non_neg') class NonNeg(Constraint): """Constrains the weights to be non-negative. """ def __call__(self, w): return w * math_ops.cast(math_ops.greater_equal(w, 0.), K.floatx()) @tf_export('keras.constraints.UnitNorm', 'keras.constraints.unit_norm') class UnitNorm(Constraint): """Constrains the weights incident to each hidden unit to have unit norm. Arguments: axis: integer, axis along which to calculate weight norms. For instance, in a `Dense` layer the weight matrix has shape `(input_dim, output_dim)`, set `axis` to `0` to constrain each weight vector of length `(input_dim,)`. In a `Conv2D` layer with `data_format="channels_last"`, the weight tensor has shape `(rows, cols, input_depth, output_depth)`, set `axis` to `[0, 1, 2]` to constrain the weights of each filter tensor of size `(rows, cols, input_depth)`. """ def __init__(self, axis=0): self.axis = axis def __call__(self, w): return w / ( K.epsilon() + K.sqrt( math_ops.reduce_sum( math_ops.square(w), axis=self.axis, keepdims=True))) def get_config(self): return {'axis': self.axis} @tf_export('keras.constraints.MinMaxNorm', 'keras.constraints.min_max_norm') class MinMaxNorm(Constraint): """MinMaxNorm weight constraint. Constrains the weights incident to each hidden unit to have the norm between a lower bound and an upper bound. Arguments: min_value: the minimum norm for the incoming weights. max_value: the maximum norm for the incoming weights. rate: rate for enforcing the constraint: weights will be rescaled to yield `(1 - rate) * norm + rate * norm.clip(min_value, max_value)`. Effectively, this means that rate=1.0 stands for strict enforcement of the constraint, while rate<1.0 means that weights will be rescaled at each step to slowly move towards a value inside the desired interval. axis: integer, axis along which to calculate weight norms. For instance, in a `Dense` layer the weight matrix has shape `(input_dim, output_dim)`, set `axis` to `0` to constrain each weight vector of length `(input_dim,)`. In a `Conv2D` layer with `data_format="channels_last"`, the weight tensor has shape `(rows, cols, input_depth, output_depth)`, set `axis` to `[0, 1, 2]` to constrain the weights of each filter tensor of size `(rows, cols, input_depth)`. """ def __init__(self, min_value=0.0, max_value=1.0, rate=1.0, axis=0): self.min_value = min_value self.max_value = max_value self.rate = rate self.axis = axis def __call__(self, w): norms = K.sqrt( math_ops.reduce_sum(math_ops.square(w), axis=self.axis, keepdims=True)) desired = ( self.rate * K.clip(norms, self.min_value, self.max_value) + (1 - self.rate) * norms) return w * (desired / (K.epsilon() + norms)) def get_config(self): return { 'min_value': self.min_value, 'max_value': self.max_value, 'rate': self.rate, 'axis': self.axis } # Aliases. max_norm = MaxNorm non_neg = NonNeg unit_norm = UnitNorm min_max_norm = MinMaxNorm # Legacy aliases. maxnorm = max_norm nonneg = non_neg unitnorm = unit_norm @tf_export('keras.constraints.serialize') def serialize(constraint): return serialize_keras_object(constraint) @tf_export('keras.constraints.deserialize') def deserialize(config, custom_objects=None): return deserialize_keras_object( config, module_objects=globals(), custom_objects=custom_objects, printable_module_name='constraint') @tf_export('keras.constraints.get') def get(identifier): if identifier is None: return None if isinstance(identifier, dict): return deserialize(identifier) elif isinstance(identifier, six.string_types): config = {'class_name': str(identifier), 'config': {}} return deserialize(config) elif callable(identifier): return identifier else: raise ValueError('Could not interpret constraint identifier: ' + str(identifier))