Intelegentny_Pszczelarz/.venv/Lib/site-packages/tensorflow/python/layers/utils.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.
# =============================================================================

"""Contains layer utilities for input validation and format conversion."""
from tensorflow.python.framework import smart_cond as smart_module
from tensorflow.python.ops import control_flow_ops
from tensorflow.python.ops import variables


def convert_data_format(data_format, ndim):
  if data_format == 'channels_last':
    if ndim == 3:
      return 'NWC'
    elif ndim == 4:
      return 'NHWC'
    elif ndim == 5:
      return 'NDHWC'
    else:
      raise ValueError(f'Input rank: {ndim} not supported. We only support '
                       'input rank 3, 4 or 5.')
  elif data_format == 'channels_first':
    if ndim == 3:
      return 'NCW'
    elif ndim == 4:
      return 'NCHW'
    elif ndim == 5:
      return 'NCDHW'
    else:
      raise ValueError(f'Input rank: {ndim} not supported. We only support '
                       'input rank 3, 4 or 5.')
  else:
    raise ValueError(f'Invalid data_format: {data_format}. We only support '
                     '"channels_first" or "channels_last"')


def normalize_tuple(value, n, name):
  """Transforms a single integer or iterable of integers into an integer tuple.

  Args:
    value: The value to validate and convert. Could an int, or any iterable
      of ints.
    n: The size of the tuple to be returned.
    name: The name of the argument being validated, e.g. "strides" or
      "kernel_size". This is only used to format error messages.

  Returns:
    A tuple of n integers.

  Raises:
    ValueError: If something else than an int/long or iterable thereof was
      passed.
  """
  if isinstance(value, int):
    return (value,) * n
  else:
    try:
      value_tuple = tuple(value)
    except TypeError:
      raise ValueError(f'Argument `{name}` must be a tuple of {str(n)} '
                       f'integers. Received: {str(value)}')
    if len(value_tuple) != n:
      raise ValueError(f'Argument `{name}` must be a tuple of {str(n)} '
                       f'integers. Received: {str(value)}')
    for single_value in value_tuple:
      try:
        int(single_value)
      except (ValueError, TypeError):
        raise ValueError(f'Argument `{name}` must be a tuple of {str(n)} '
                         f'integers. Received: {str(value)} including element '
                         f'{str(single_value)} of type '
                         f'{str(type(single_value))}')
    return value_tuple


def normalize_data_format(value):
  data_format = value.lower()
  if data_format not in {'channels_first', 'channels_last'}:
    raise ValueError('The `data_format` argument must be one of '
                     '"channels_first", "channels_last". Received: '
                     f'{str(value)}.')
  return data_format


def normalize_padding(value):
  padding = value.lower()
  if padding not in {'valid', 'same'}:
    raise ValueError('The `padding` argument must be one of "valid", "same". '
                     f'Received: {str(padding)}.')
  return padding


def conv_output_length(input_length, filter_size, padding, stride, dilation=1):
  """Determines output length of a convolution given input length.

  Args:
      input_length: integer.
      filter_size: integer.
      padding: one of "same", "valid", "full".
      stride: integer.
      dilation: dilation rate, integer.

  Returns:
      The output length (integer).
  """
  if input_length is None:
    return None
  assert padding in {'same', 'valid', 'full'}
  dilated_filter_size = filter_size + (filter_size - 1) * (dilation - 1)
  if padding == 'same':
    output_length = input_length
  elif padding == 'valid':
    output_length = input_length - dilated_filter_size + 1
  elif padding == 'full':
    output_length = input_length + dilated_filter_size - 1
  return (output_length + stride - 1) // stride


def conv_input_length(output_length, filter_size, padding, stride):
  """Determines input length of a convolution given output length.

  Args:
      output_length: integer.
      filter_size: integer.
      padding: one of "same", "valid", "full".
      stride: integer.

  Returns:
      The input length (integer).
  """
  if output_length is None:
    return None
  assert padding in {'same', 'valid', 'full'}
  if padding == 'same':
    pad = filter_size // 2
  elif padding == 'valid':
    pad = 0
  elif padding == 'full':
    pad = filter_size - 1
  return (output_length - 1) * stride - 2 * pad + filter_size


def deconv_output_length(input_length, filter_size, padding, stride):
  """Determines output length of a transposed convolution given input length.

  Args:
      input_length: integer.
      filter_size: integer.
      padding: one of "same", "valid", "full".
      stride: integer.

  Returns:
      The output length (integer).
  """
  if input_length is None:
    return None
  input_length *= stride
  if padding == 'valid':
    input_length += max(filter_size - stride, 0)
  elif padding == 'full':
    input_length -= (stride + filter_size - 2)
  return input_length


def smart_cond(pred, true_fn=None, false_fn=None, name=None):
  """Return either `true_fn()` if predicate `pred` is true else `false_fn()`.

  If `pred` is a bool or has a constant value, we return either `true_fn()`
  or `false_fn()`, otherwise we use `tf.cond` to dynamically route to both.

  Args:
    pred: A scalar determining whether to return the result of `true_fn` or
      `false_fn`.
    true_fn: The callable to be performed if pred is true.
    false_fn: The callable to be performed if pred is false.
    name: Optional name prefix when using `tf.cond`.

  Returns:
    Tensors returned by the call to either `true_fn` or `false_fn`.

  Raises:
    TypeError: If `true_fn` or `false_fn` is not callable.
  """
  if isinstance(pred, variables.Variable):
    return control_flow_ops.cond(
        pred, true_fn=true_fn, false_fn=false_fn, name=name)
  return smart_module.smart_cond(
      pred, true_fn=true_fn, false_fn=false_fn, name=name)


def constant_value(pred):
  """Return the bool value for `pred`, or None if `pred` had a dynamic value.

    Args:
      pred: A scalar, either a Python bool or a TensorFlow boolean variable
        or tensor, or the Python integer 1 or 0.

    Returns:
      True or False if `pred` has a constant boolean value, None otherwise.

    Raises:
      TypeError: If `pred` is not a Variable, Tensor or bool, or Python
        integer 1 or 0.
    """
  # Allow integer booleans.
  if isinstance(pred, int):
    if pred == 1:
      pred = True
    elif pred == 0:
      pred = False

  if isinstance(pred, variables.Variable):
    return None
  return smart_module.smart_constant_value(pred)
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.`
			`# =============================================================================`

			`"""Contains layer utilities for input validation and format conversion."""`
			`from tensorflow.python.framework import smart_cond as smart_module`
			`from tensorflow.python.ops import control_flow_ops`
			`from tensorflow.python.ops import variables`


			`def convert_data_format(data_format, ndim):`
			`if data_format == 'channels_last':`
			`if ndim == 3:`
			`return 'NWC'`
			`elif ndim == 4:`
			`return 'NHWC'`
			`elif ndim == 5:`
			`return 'NDHWC'`
			`else:`
			`raise ValueError(f'Input rank: {ndim} not supported. We only support '`
			`'input rank 3, 4 or 5.')`
			`elif data_format == 'channels_first':`
			`if ndim == 3:`
			`return 'NCW'`
			`elif ndim == 4:`
			`return 'NCHW'`
			`elif ndim == 5:`
			`return 'NCDHW'`
			`else:`
			`raise ValueError(f'Input rank: {ndim} not supported. We only support '`
			`'input rank 3, 4 or 5.')`
			`else:`
			`raise ValueError(f'Invalid data_format: {data_format}. We only support '`
			`'"channels_first" or "channels_last"')`


			`def normalize_tuple(value, n, name):`
			`"""Transforms a single integer or iterable of integers into an integer tuple.`

			`Args:`
			`value: The value to validate and convert. Could an int, or any iterable`
			`of ints.`
			`n: The size of the tuple to be returned.`
			`name: The name of the argument being validated, e.g. "strides" or`
			`"kernel_size". This is only used to format error messages.`

			`Returns:`
			`A tuple of n integers.`

			`Raises:`
			`ValueError: If something else than an int/long or iterable thereof was`
			`passed.`
			`"""`
			`if isinstance(value, int):`
			`return (value,) * n`
			`else:`
			`try:`
			`value_tuple = tuple(value)`
			`except TypeError:`
			raise ValueError(f'Argument `{name}` must be a tuple of {str(n)} '
			`f'integers. Received: {str(value)}')`
			`if len(value_tuple) != n:`
			raise ValueError(f'Argument `{name}` must be a tuple of {str(n)} '
			`f'integers. Received: {str(value)}')`
			`for single_value in value_tuple:`
			`try:`
			`int(single_value)`
			`except (ValueError, TypeError):`
			raise ValueError(f'Argument `{name}` must be a tuple of {str(n)} '
			`f'integers. Received: {str(value)} including element '`
			`f'{str(single_value)} of type '`
			`f'{str(type(single_value))}')`
			`return value_tuple`


			`def normalize_data_format(value):`
			`data_format = value.lower()`
			`if data_format not in {'channels_first', 'channels_last'}:`
			raise ValueError('The `data_format` argument must be one of '
			`'"channels_first", "channels_last". Received: '`
			`f'{str(value)}.')`
			`return data_format`


			`def normalize_padding(value):`
			`padding = value.lower()`
			`if padding not in {'valid', 'same'}:`
			raise ValueError('The `padding` argument must be one of "valid", "same". '
			`f'Received: {str(padding)}.')`
			`return padding`


			`def conv_output_length(input_length, filter_size, padding, stride, dilation=1):`
			`"""Determines output length of a convolution given input length.`

			`Args:`
			`input_length: integer.`
			`filter_size: integer.`
			`padding: one of "same", "valid", "full".`
			`stride: integer.`
			`dilation: dilation rate, integer.`

			`Returns:`
			`The output length (integer).`
			`"""`
			`if input_length is None:`
			`return None`
			`assert padding in {'same', 'valid', 'full'}`
			`dilated_filter_size = filter_size + (filter_size - 1) * (dilation - 1)`
			`if padding == 'same':`
			`output_length = input_length`
			`elif padding == 'valid':`
			`output_length = input_length - dilated_filter_size + 1`
			`elif padding == 'full':`
			`output_length = input_length + dilated_filter_size - 1`
			`return (output_length + stride - 1) // stride`


			`def conv_input_length(output_length, filter_size, padding, stride):`
			`"""Determines input length of a convolution given output length.`

			`Args:`
			`output_length: integer.`
			`filter_size: integer.`
			`padding: one of "same", "valid", "full".`
			`stride: integer.`

			`Returns:`
			`The input length (integer).`
			`"""`
			`if output_length is None:`
			`return None`
			`assert padding in {'same', 'valid', 'full'}`
			`if padding == 'same':`
			`pad = filter_size // 2`
			`elif padding == 'valid':`
			`pad = 0`
			`elif padding == 'full':`
			`pad = filter_size - 1`
			`return (output_length - 1) * stride - 2 * pad + filter_size`


			`def deconv_output_length(input_length, filter_size, padding, stride):`
			`"""Determines output length of a transposed convolution given input length.`

			`Args:`
			`input_length: integer.`
			`filter_size: integer.`
			`padding: one of "same", "valid", "full".`
			`stride: integer.`

			`Returns:`
			`The output length (integer).`
			`"""`
			`if input_length is None:`
			`return None`
			`input_length *= stride`
			`if padding == 'valid':`
			`input_length += max(filter_size - stride, 0)`
			`elif padding == 'full':`
			`input_length -= (stride + filter_size - 2)`
			`return input_length`


			`def smart_cond(pred, true_fn=None, false_fn=None, name=None):`
			"""Return either `true_fn()` if predicate `pred` is true else `false_fn()`.

			If `pred` is a bool or has a constant value, we return either `true_fn()`
			or `false_fn()`, otherwise we use `tf.cond` to dynamically route to both.

			`Args:`
			pred: A scalar determining whether to return the result of `true_fn` or
			`false_fn`.
			`true_fn: The callable to be performed if pred is true.`
			`false_fn: The callable to be performed if pred is false.`
			name: Optional name prefix when using `tf.cond`.

			`Returns:`
			Tensors returned by the call to either `true_fn` or `false_fn`.

			`Raises:`
			TypeError: If `true_fn` or `false_fn` is not callable.
			`"""`
			`if isinstance(pred, variables.Variable):`
			`return control_flow_ops.cond(`
			`pred, true_fn=true_fn, false_fn=false_fn, name=name)`
			`return smart_module.smart_cond(`
			`pred, true_fn=true_fn, false_fn=false_fn, name=name)`


			`def constant_value(pred):`
			"""Return the bool value for `pred`, or None if `pred` had a dynamic value.

			`Args:`
			`pred: A scalar, either a Python bool or a TensorFlow boolean variable`
			`or tensor, or the Python integer 1 or 0.`

			`Returns:`
			True or False if `pred` has a constant boolean value, None otherwise.

			`Raises:`
			TypeError: If `pred` is not a Variable, Tensor or bool, or Python
			`integer 1 or 0.`
			`"""`
			`# Allow integer booleans.`
			`if isinstance(pred, int):`
			`if pred == 1:`
			`pred = True`
			`elif pred == 0:`
			`pred = False`

			`if isinstance(pred, variables.Variable):`
			`return None`
			`return smart_module.smart_constant_value(pred)`