Intelegentny_Pszczelarz/.venv/Lib/site-packages/tensorflow/python/keras/constraints.py

# 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
# pylint: disable=g-classes-have-attributes
"""Constraints: functions that impose constraints on weight values."""

from tensorflow.python.framework import tensor_shape
from tensorflow.python.keras import backend
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 array_ops
from tensorflow.python.ops import control_flow_ops
from tensorflow.python.ops import math_ops
from tensorflow.python.util.tf_export import keras_export
from tensorflow.tools.docs import doc_controls


@keras_export('keras.constraints.Constraint')
class Constraint:
  """Base class for weight constraints.

  A `Constraint` instance works like a stateless function.
  Users who subclass this
  class should override the `__call__` method, which takes a single
  weight parameter and return a projected version of that parameter
  (e.g. normalized or clipped). Constraints can be used with various Keras
  layers via the `kernel_constraint` or `bias_constraint` arguments.

  Here's a simple example of a non-negative weight constraint:

  >>> class NonNegative(tf.keras.constraints.Constraint):
  ...
  ...  def __call__(self, w):
  ...    return w * tf.cast(tf.math.greater_equal(w, 0.), w.dtype)

  >>> weight = tf.constant((-1.0, 1.0))
  >>> NonNegative()(weight)
  <tf.Tensor: shape=(2,), dtype=float32, numpy=array([0.,  1.], dtype=float32)>

  >>> tf.keras.layers.Dense(4, kernel_constraint=NonNegative())
  """

  def __call__(self, w):
    """Applies the constraint to the input weight variable.

    By default, the inputs weight variable is not modified.
    Users should override this method to implement their own projection
    function.

    Args:
      w: Input weight variable.

    Returns:
      Projected variable (by default, returns unmodified inputs).
    """
    return w

  def get_config(self):
    """Returns a Python dict of the object config.

    A constraint config is a Python dictionary (JSON-serializable) that can
    be used to reinstantiate the same object.

    Returns:
      Python dict containing the configuration of the constraint object.
    """
    return {}


@keras_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.

  Also available via the shortcut function `tf.keras.constraints.max_norm`.

  Args:
    max_value: the maximum norm value 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

  @doc_controls.do_not_generate_docs
  def __call__(self, w):
    norms = backend.sqrt(
        math_ops.reduce_sum(math_ops.square(w), axis=self.axis, keepdims=True))
    desired = backend.clip(norms, 0, self.max_value)
    return w * (desired / (backend.epsilon() + norms))

  @doc_controls.do_not_generate_docs
  def get_config(self):
    return {'max_value': self.max_value, 'axis': self.axis}


@keras_export('keras.constraints.NonNeg', 'keras.constraints.non_neg')
class NonNeg(Constraint):
  """Constrains the weights to be non-negative.

  Also available via the shortcut function `tf.keras.constraints.non_neg`.
  """

  def __call__(self, w):
    return w * math_ops.cast(math_ops.greater_equal(w, 0.), backend.floatx())


@keras_export('keras.constraints.UnitNorm', 'keras.constraints.unit_norm')
class UnitNorm(Constraint):
  """Constrains the weights incident to each hidden unit to have unit norm.

  Also available via the shortcut function `tf.keras.constraints.unit_norm`.

  Args:
    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

  @doc_controls.do_not_generate_docs
  def __call__(self, w):
    return w / (
        backend.epsilon() + backend.sqrt(
            math_ops.reduce_sum(
                math_ops.square(w), axis=self.axis, keepdims=True)))

  @doc_controls.do_not_generate_docs
  def get_config(self):
    return {'axis': self.axis}


@keras_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.

  Also available via the shortcut function `tf.keras.constraints.min_max_norm`.

  Args:
    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

  @doc_controls.do_not_generate_docs
  def __call__(self, w):
    norms = backend.sqrt(
        math_ops.reduce_sum(math_ops.square(w), axis=self.axis, keepdims=True))
    desired = (
        self.rate * backend.clip(norms, self.min_value, self.max_value) +
        (1 - self.rate) * norms)
    return w * (desired / (backend.epsilon() + norms))

  @doc_controls.do_not_generate_docs
  def get_config(self):
    return {
        'min_value': self.min_value,
        'max_value': self.max_value,
        'rate': self.rate,
        'axis': self.axis
    }


@keras_export('keras.constraints.RadialConstraint',
              'keras.constraints.radial_constraint')
class RadialConstraint(Constraint):
  """Constrains `Conv2D` kernel weights to be the same for each radius.

  Also available via the shortcut function
  `tf.keras.constraints.radial_constraint`.

  For example, the desired output for the following 4-by-4 kernel:

  ```
      kernel = [[v_00, v_01, v_02, v_03],
                [v_10, v_11, v_12, v_13],
                [v_20, v_21, v_22, v_23],
                [v_30, v_31, v_32, v_33]]
  ```

  is this::

  ```
      kernel = [[v_11, v_11, v_11, v_11],
                [v_11, v_33, v_33, v_11],
                [v_11, v_33, v_33, v_11],
                [v_11, v_11, v_11, v_11]]
  ```

  This constraint can be applied to any `Conv2D` layer version, including
  `Conv2DTranspose` and `SeparableConv2D`, and with either `"channels_last"` or
  `"channels_first"` data format. The method assumes the weight tensor is of
  shape `(rows, cols, input_depth, output_depth)`.
  """

  @doc_controls.do_not_generate_docs
  def __call__(self, w):
    w_shape = w.shape
    if w_shape.rank is None or w_shape.rank != 4:
      raise ValueError(
          'The weight tensor must be of rank 4, but is of shape: %s' % w_shape)

    height, width, channels, kernels = w_shape
    w = backend.reshape(w, (height, width, channels * kernels))
    # TODO(cpeter): Switch map_fn for a faster tf.vectorized_map once
    # backend.switch is supported.
    w = backend.map_fn(
        self._kernel_constraint,
        backend.stack(array_ops.unstack(w, axis=-1), axis=0))
    return backend.reshape(backend.stack(array_ops.unstack(w, axis=0), axis=-1),
                           (height, width, channels, kernels))

  def _kernel_constraint(self, kernel):
    """Radially constraints a kernel with shape (height, width, channels)."""
    padding = backend.constant([[1, 1], [1, 1]], dtype='int32')

    kernel_shape = backend.shape(kernel)[0]
    start = backend.cast(kernel_shape / 2, 'int32')

    kernel_new = backend.switch(
        backend.cast(math_ops.floormod(kernel_shape, 2), 'bool'),
        lambda: kernel[start - 1:start, start - 1:start],
        lambda: kernel[start - 1:start, start - 1:start] + backend.zeros(  # pylint: disable=g-long-lambda
            (2, 2), dtype=kernel.dtype))
    index = backend.switch(
        backend.cast(math_ops.floormod(kernel_shape, 2), 'bool'),
        lambda: backend.constant(0, dtype='int32'),
        lambda: backend.constant(1, dtype='int32'))
    while_condition = lambda index, *args: backend.less(index, start)

    def body_fn(i, array):
      return i + 1, array_ops.pad(
          array,
          padding,
          constant_values=kernel[start + i, start + i])

    _, kernel_new = control_flow_ops.while_loop(
        while_condition,
        body_fn,
        [index, kernel_new],
        shape_invariants=[index.get_shape(),
                          tensor_shape.TensorShape([None, None])])
    return kernel_new


# Aliases.

max_norm = MaxNorm
non_neg = NonNeg
unit_norm = UnitNorm
min_max_norm = MinMaxNorm
radial_constraint = RadialConstraint

# Legacy aliases.
maxnorm = max_norm
nonneg = non_neg
unitnorm = unit_norm


@keras_export('keras.constraints.serialize')
def serialize(constraint):
  return serialize_keras_object(constraint)


@keras_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')


@keras_export('keras.constraints.get')
def get(identifier):
  if identifier is None:
    return None
  if isinstance(identifier, dict):
    return deserialize(identifier)
  elif isinstance(identifier, str):
    config = {'class_name': str(identifier), 'config': {}}
    return deserialize(config)
  elif callable(identifier):
    return identifier
  else:
    raise ValueError('Could not interpret constraint identifier: ' +
                     str(identifier))
feature: "ANN commit 2" 2023-06-19 00:49:18 +02:00			`# 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`
			`# pylint: disable=g-classes-have-attributes`
			`"""Constraints: functions that impose constraints on weight values."""`

			`from tensorflow.python.framework import tensor_shape`
			`from tensorflow.python.keras import backend`
			`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 array_ops`
			`from tensorflow.python.ops import control_flow_ops`
			`from tensorflow.python.ops import math_ops`
			`from tensorflow.python.util.tf_export import keras_export`
			`from tensorflow.tools.docs import doc_controls`


			`@keras_export('keras.constraints.Constraint')`
			`class Constraint:`
			`"""Base class for weight constraints.`

			A `Constraint` instance works like a stateless function.
			`Users who subclass this`
			class should override the `__call__` method, which takes a single
			`weight parameter and return a projected version of that parameter`
			`(e.g. normalized or clipped). Constraints can be used with various Keras`
			layers via the `kernel_constraint` or `bias_constraint` arguments.

			`Here's a simple example of a non-negative weight constraint:`

			`>>> class NonNegative(tf.keras.constraints.Constraint):`
			`...`
			`... def __call__(self, w):`
			`... return w * tf.cast(tf.math.greater_equal(w, 0.), w.dtype)`

			`>>> weight = tf.constant((-1.0, 1.0))`
			`>>> NonNegative()(weight)`
			`<tf.Tensor: shape=(2,), dtype=float32, numpy=array([0., 1.], dtype=float32)>`

			`>>> tf.keras.layers.Dense(4, kernel_constraint=NonNegative())`
			`"""`

			`def __call__(self, w):`
			`"""Applies the constraint to the input weight variable.`

			`By default, the inputs weight variable is not modified.`
			`Users should override this method to implement their own projection`
			`function.`

			`Args:`
			`w: Input weight variable.`

			`Returns:`
			`Projected variable (by default, returns unmodified inputs).`
			`"""`
			`return w`

			`def get_config(self):`
			`"""Returns a Python dict of the object config.`

			`A constraint config is a Python dictionary (JSON-serializable) that can`
			`be used to reinstantiate the same object.`

			`Returns:`
			`Python dict containing the configuration of the constraint object.`
			`"""`
			`return {}`


			`@keras_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.`

			Also available via the shortcut function `tf.keras.constraints.max_norm`.

			`Args:`
			`max_value: the maximum norm value 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`

			`@doc_controls.do_not_generate_docs`
			`def __call__(self, w):`
			`norms = backend.sqrt(`
			`math_ops.reduce_sum(math_ops.square(w), axis=self.axis, keepdims=True))`
			`desired = backend.clip(norms, 0, self.max_value)`
			`return w * (desired / (backend.epsilon() + norms))`

			`@doc_controls.do_not_generate_docs`
			`def get_config(self):`
			`return {'max_value': self.max_value, 'axis': self.axis}`


			`@keras_export('keras.constraints.NonNeg', 'keras.constraints.non_neg')`
			`class NonNeg(Constraint):`
			`"""Constrains the weights to be non-negative.`

			Also available via the shortcut function `tf.keras.constraints.non_neg`.
			`"""`

			`def __call__(self, w):`
			`return w * math_ops.cast(math_ops.greater_equal(w, 0.), backend.floatx())`


			`@keras_export('keras.constraints.UnitNorm', 'keras.constraints.unit_norm')`
			`class UnitNorm(Constraint):`
			`"""Constrains the weights incident to each hidden unit to have unit norm.`

			Also available via the shortcut function `tf.keras.constraints.unit_norm`.

			`Args:`
			`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`

			`@doc_controls.do_not_generate_docs`
			`def __call__(self, w):`
			`return w / (`
			`backend.epsilon() + backend.sqrt(`
			`math_ops.reduce_sum(`
			`math_ops.square(w), axis=self.axis, keepdims=True)))`

			`@doc_controls.do_not_generate_docs`
			`def get_config(self):`
			`return {'axis': self.axis}`


			`@keras_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.`

			Also available via the shortcut function `tf.keras.constraints.min_max_norm`.

			`Args:`
			`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`

			`@doc_controls.do_not_generate_docs`
			`def __call__(self, w):`
			`norms = backend.sqrt(`
			`math_ops.reduce_sum(math_ops.square(w), axis=self.axis, keepdims=True))`
			`desired = (`
			`self.rate * backend.clip(norms, self.min_value, self.max_value) +`
			`(1 - self.rate) * norms)`
			`return w * (desired / (backend.epsilon() + norms))`

			`@doc_controls.do_not_generate_docs`
			`def get_config(self):`
			`return {`
			`'min_value': self.min_value,`
			`'max_value': self.max_value,`
			`'rate': self.rate,`
			`'axis': self.axis`
			`}`


			`@keras_export('keras.constraints.RadialConstraint',`
			`'keras.constraints.radial_constraint')`
			`class RadialConstraint(Constraint):`
			"""Constrains `Conv2D` kernel weights to be the same for each radius.

			`Also available via the shortcut function`
			`tf.keras.constraints.radial_constraint`.

			`For example, the desired output for the following 4-by-4 kernel:`

			```
			`kernel = [[v_00, v_01, v_02, v_03],`
			`[v_10, v_11, v_12, v_13],`
			`[v_20, v_21, v_22, v_23],`
			`[v_30, v_31, v_32, v_33]]`
			```

			`is this::`

			```
			`kernel = [[v_11, v_11, v_11, v_11],`
			`[v_11, v_33, v_33, v_11],`
			`[v_11, v_33, v_33, v_11],`
			`[v_11, v_11, v_11, v_11]]`
			```

			This constraint can be applied to any `Conv2D` layer version, including
			`Conv2DTranspose` and `SeparableConv2D`, and with either `"channels_last"` or
			`"channels_first"` data format. The method assumes the weight tensor is of
			shape `(rows, cols, input_depth, output_depth)`.
			`"""`

			`@doc_controls.do_not_generate_docs`
			`def __call__(self, w):`
			`w_shape = w.shape`
			`if w_shape.rank is None or w_shape.rank != 4:`
			`raise ValueError(`
			`'The weight tensor must be of rank 4, but is of shape: %s' % w_shape)`

			`height, width, channels, kernels = w_shape`
			`w = backend.reshape(w, (height, width, channels * kernels))`
			`# TODO(cpeter): Switch map_fn for a faster tf.vectorized_map once`
			`# backend.switch is supported.`
			`w = backend.map_fn(`
			`self._kernel_constraint,`
			`backend.stack(array_ops.unstack(w, axis=-1), axis=0))`
			`return backend.reshape(backend.stack(array_ops.unstack(w, axis=0), axis=-1),`
			`(height, width, channels, kernels))`

			`def _kernel_constraint(self, kernel):`
			`"""Radially constraints a kernel with shape (height, width, channels)."""`
			`padding = backend.constant([[1, 1], [1, 1]], dtype='int32')`

			`kernel_shape = backend.shape(kernel)[0]`
			`start = backend.cast(kernel_shape / 2, 'int32')`

			`kernel_new = backend.switch(`
			`backend.cast(math_ops.floormod(kernel_shape, 2), 'bool'),`
			`lambda: kernel[start - 1:start, start - 1:start],`
			`lambda: kernel[start - 1:start, start - 1:start] + backend.zeros( # pylint: disable=g-long-lambda`
			`(2, 2), dtype=kernel.dtype))`
			`index = backend.switch(`
			`backend.cast(math_ops.floormod(kernel_shape, 2), 'bool'),`
			`lambda: backend.constant(0, dtype='int32'),`
			`lambda: backend.constant(1, dtype='int32'))`
			`while_condition = lambda index, *args: backend.less(index, start)`

			`def body_fn(i, array):`
			`return i + 1, array_ops.pad(`
			`array,`
			`padding,`
			`constant_values=kernel[start + i, start + i])`

			`_, kernel_new = control_flow_ops.while_loop(`
			`while_condition,`
			`body_fn,`
			`[index, kernel_new],`
			`shape_invariants=[index.get_shape(),`
			`tensor_shape.TensorShape([None, None])])`
			`return kernel_new`


			`# Aliases.`

			`max_norm = MaxNorm`
			`non_neg = NonNeg`
			`unit_norm = UnitNorm`
			`min_max_norm = MinMaxNorm`
			`radial_constraint = RadialConstraint`

			`# Legacy aliases.`
			`maxnorm = max_norm`
			`nonneg = non_neg`
			`unitnorm = unit_norm`


			`@keras_export('keras.constraints.serialize')`
			`def serialize(constraint):`
			`return serialize_keras_object(constraint)`


			`@keras_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')`


			`@keras_export('keras.constraints.get')`
			`def get(identifier):`
			`if identifier is None:`
			`return None`
			`if isinstance(identifier, dict):`
			`return deserialize(identifier)`
			`elif isinstance(identifier, str):`
			`config = {'class_name': str(identifier), 'config': {}}`
			`return deserialize(config)`
			`elif callable(identifier):`
			`return identifier`
			`else:`
			`raise ValueError('Could not interpret constraint identifier: ' +`
			`str(identifier))`