# Copyright 2019 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. # ============================================================================== """Utilities for ImageNet data preprocessing & prediction decoding.""" import json import warnings import numpy as np from tf_keras.src import activations from tf_keras.src import backend from tf_keras.src.utils import data_utils # isort: off from tensorflow.python.util.tf_export import keras_export CLASS_INDEX = None CLASS_INDEX_PATH = ( "https://storage.googleapis.com/download.tensorflow.org/" "data/imagenet_class_index.json" ) PREPROCESS_INPUT_DOC = """ Preprocesses a tensor or Numpy array encoding a batch of images. Usage example with `applications.MobileNet`: ```python i = tf.keras.layers.Input([None, None, 3], dtype = tf.uint8) x = tf.cast(i, tf.float32) x = tf.keras.applications.mobilenet.preprocess_input(x) core = tf.keras.applications.MobileNet() x = core(x) model = tf.keras.Model(inputs=[i], outputs=[x]) image = tf.image.decode_png(tf.io.read_file('file.png')) result = model(image) ``` Args: x: A floating point `numpy.array` or a `tf.Tensor`, 3D or 4D with 3 color channels, with values in the range [0, 255]. The preprocessed data are written over the input data if the data types are compatible. To avoid this behaviour, `numpy.copy(x)` can be used. data_format: Optional data format of the image tensor/array. None, means the global setting `tf.keras.backend.image_data_format()` is used (unless you changed it, it uses "channels_last").{mode} Defaults to `None`. Returns: Preprocessed `numpy.array` or a `tf.Tensor` with type `float32`. {ret} Raises: {error} """ PREPROCESS_INPUT_MODE_DOC = """ mode: One of "caffe", "tf" or "torch". - caffe: will convert the images from RGB to BGR, then will zero-center each color channel with respect to the ImageNet dataset, without scaling. - tf: will scale pixels between -1 and 1, sample-wise. - torch: will scale pixels between 0 and 1 and then will normalize each channel with respect to the ImageNet dataset. Defaults to "caffe". """ PREPROCESS_INPUT_DEFAULT_ERROR_DOC = """ ValueError: In case of unknown `mode` or `data_format` argument.""" PREPROCESS_INPUT_ERROR_DOC = """ ValueError: In case of unknown `data_format` argument.""" PREPROCESS_INPUT_RET_DOC_TF = """ The inputs pixel values are scaled between -1 and 1, sample-wise.""" PREPROCESS_INPUT_RET_DOC_TORCH = """ The input pixels values are scaled between 0 and 1 and each channel is normalized with respect to the ImageNet dataset.""" PREPROCESS_INPUT_RET_DOC_CAFFE = """ The images are converted from RGB to BGR, then each color channel is zero-centered with respect to the ImageNet dataset, without scaling.""" @keras_export("keras.applications.imagenet_utils.preprocess_input") def preprocess_input(x, data_format=None, mode="caffe"): """Preprocesses a tensor or Numpy array encoding a batch of images.""" if mode not in {"caffe", "tf", "torch"}: raise ValueError( "Expected mode to be one of `caffe`, `tf` or `torch`. " f"Received: mode={mode}" ) if data_format is None: data_format = backend.image_data_format() elif data_format not in {"channels_first", "channels_last"}: raise ValueError( "Expected data_format to be one of `channels_first` or " f"`channels_last`. Received: data_format={data_format}" ) if isinstance(x, np.ndarray): return _preprocess_numpy_input(x, data_format=data_format, mode=mode) else: return _preprocess_symbolic_input(x, data_format=data_format, mode=mode) preprocess_input.__doc__ = PREPROCESS_INPUT_DOC.format( mode=PREPROCESS_INPUT_MODE_DOC, ret="", error=PREPROCESS_INPUT_DEFAULT_ERROR_DOC, ) @keras_export("keras.applications.imagenet_utils.decode_predictions") def decode_predictions(preds, top=5): """Decodes the prediction of an ImageNet model. Args: preds: Numpy array encoding a batch of predictions. top: Integer, how many top-guesses to return. Defaults to 5. Returns: A list of lists of top class prediction tuples `(class_name, class_description, score)`. One list of tuples per sample in batch input. Raises: ValueError: In case of invalid shape of the `pred` array (must be 2D). """ global CLASS_INDEX if len(preds.shape) != 2 or preds.shape[1] != 1000: raise ValueError( "`decode_predictions` expects " "a batch of predictions " "(i.e. a 2D array of shape (samples, 1000)). " "Found array with shape: " + str(preds.shape) ) if CLASS_INDEX is None: fpath = data_utils.get_file( "imagenet_class_index.json", CLASS_INDEX_PATH, cache_subdir="models", file_hash="c2c37ea517e94d9795004a39431a14cb", ) with open(fpath) as f: CLASS_INDEX = json.load(f) results = [] for pred in preds: top_indices = pred.argsort()[-top:][::-1] result = [tuple(CLASS_INDEX[str(i)]) + (pred[i],) for i in top_indices] result.sort(key=lambda x: x[2], reverse=True) results.append(result) return results def _preprocess_numpy_input(x, data_format, mode): """Preprocesses a Numpy array encoding a batch of images. Args: x: Input array, 3D or 4D. data_format: Data format of the image array. mode: One of "caffe", "tf" or "torch". - caffe: will convert the images from RGB to BGR, then will zero-center each color channel with respect to the ImageNet dataset, without scaling. - tf: will scale pixels between -1 and 1, sample-wise. - torch: will scale pixels between 0 and 1 and then will normalize each channel with respect to the ImageNet dataset. Returns: Preprocessed Numpy array. """ if not issubclass(x.dtype.type, np.floating): x = x.astype(backend.floatx(), copy=False) if mode == "tf": x /= 127.5 x -= 1.0 return x elif mode == "torch": x /= 255.0 mean = [0.485, 0.456, 0.406] std = [0.229, 0.224, 0.225] else: if data_format == "channels_first": # 'RGB'->'BGR' if x.ndim == 3: x = x[::-1, ...] else: x = x[:, ::-1, ...] else: # 'RGB'->'BGR' x = x[..., ::-1] mean = [103.939, 116.779, 123.68] std = None # Zero-center by mean pixel if data_format == "channels_first": if x.ndim == 3: x[0, :, :] -= mean[0] x[1, :, :] -= mean[1] x[2, :, :] -= mean[2] if std is not None: x[0, :, :] /= std[0] x[1, :, :] /= std[1] x[2, :, :] /= std[2] else: x[:, 0, :, :] -= mean[0] x[:, 1, :, :] -= mean[1] x[:, 2, :, :] -= mean[2] if std is not None: x[:, 0, :, :] /= std[0] x[:, 1, :, :] /= std[1] x[:, 2, :, :] /= std[2] else: x[..., 0] -= mean[0] x[..., 1] -= mean[1] x[..., 2] -= mean[2] if std is not None: x[..., 0] /= std[0] x[..., 1] /= std[1] x[..., 2] /= std[2] return x def _preprocess_symbolic_input(x, data_format, mode): """Preprocesses a tensor encoding a batch of images. Args: x: Input tensor, 3D or 4D. data_format: Data format of the image tensor. mode: One of "caffe", "tf" or "torch". - caffe: will convert the images from RGB to BGR, then will zero-center each color channel with respect to the ImageNet dataset, without scaling. - tf: will scale pixels between -1 and 1, sample-wise. - torch: will scale pixels between 0 and 1 and then will normalize each channel with respect to the ImageNet dataset. Returns: Preprocessed tensor. """ if mode == "tf": x /= 127.5 x -= 1.0 return x elif mode == "torch": x /= 255.0 mean = [0.485, 0.456, 0.406] std = [0.229, 0.224, 0.225] else: if data_format == "channels_first": # 'RGB'->'BGR' if backend.ndim(x) == 3: x = x[::-1, ...] else: x = x[:, ::-1, ...] else: # 'RGB'->'BGR' x = x[..., ::-1] mean = [103.939, 116.779, 123.68] std = None mean_tensor = backend.constant(-np.array(mean)) # Zero-center by mean pixel if backend.dtype(x) != backend.dtype(mean_tensor): x = backend.bias_add( x, backend.cast(mean_tensor, backend.dtype(x)), data_format=data_format, ) else: x = backend.bias_add(x, mean_tensor, data_format) if std is not None: std_tensor = backend.constant(np.array(std), dtype=backend.dtype(x)) if data_format == "channels_first": std_tensor = backend.reshape(std_tensor, (-1, 1, 1)) x /= std_tensor return x def obtain_input_shape( input_shape, default_size, min_size, data_format, require_flatten, weights=None, ): """Internal utility to compute/validate a model's input shape. Args: input_shape: Either None (will return the default network input shape), or a user-provided shape to be validated. default_size: Default input width/height for the model. min_size: Minimum input width/height accepted by the model. data_format: Image data format to use. require_flatten: Whether the model is expected to be linked to a classifier via a Flatten layer. weights: One of `None` (random initialization) or 'imagenet' (pre-training on ImageNet). If weights='imagenet' input channels must be equal to 3. Returns: An integer shape tuple (may include None entries). Raises: ValueError: In case of invalid argument values. """ if weights != "imagenet" and input_shape and len(input_shape) == 3: if data_format == "channels_first": if input_shape[0] not in {1, 3}: warnings.warn( "This model usually expects 1 or 3 input channels. " "However, it was passed an input_shape with " + str(input_shape[0]) + " input channels.", stacklevel=2, ) default_shape = (input_shape[0], default_size, default_size) else: if input_shape[-1] not in {1, 3}: warnings.warn( "This model usually expects 1 or 3 input channels. " "However, it was passed an input_shape with " + str(input_shape[-1]) + " input channels.", stacklevel=2, ) default_shape = (default_size, default_size, input_shape[-1]) else: if data_format == "channels_first": default_shape = (3, default_size, default_size) else: default_shape = (default_size, default_size, 3) if weights == "imagenet" and require_flatten: if input_shape is not None: if input_shape != default_shape: raise ValueError( "When setting `include_top=True` " "and loading `imagenet` weights, " f"`input_shape` should be {default_shape}. " f"Received: input_shape={input_shape}" ) return default_shape if input_shape: if data_format == "channels_first": if input_shape is not None: if len(input_shape) != 3: raise ValueError( "`input_shape` must be a tuple of three integers." ) if input_shape[0] != 3 and weights == "imagenet": raise ValueError( "The input must have 3 channels; Received " f"`input_shape={input_shape}`" ) if ( input_shape[1] is not None and input_shape[1] < min_size ) or (input_shape[2] is not None and input_shape[2] < min_size): raise ValueError( f"Input size must be at least {min_size}" f"x{min_size}; Received: " f"input_shape={input_shape}" ) else: if input_shape is not None: if len(input_shape) != 3: raise ValueError( "`input_shape` must be a tuple of three integers." ) if input_shape[-1] != 3 and weights == "imagenet": raise ValueError( "The input must have 3 channels; Received " f"`input_shape={input_shape}`" ) if ( input_shape[0] is not None and input_shape[0] < min_size ) or (input_shape[1] is not None and input_shape[1] < min_size): raise ValueError( "Input size must be at least " f"{min_size}x{min_size}; Received: " f"input_shape={input_shape}" ) else: if require_flatten: input_shape = default_shape else: if data_format == "channels_first": input_shape = (3, None, None) else: input_shape = (None, None, 3) if require_flatten: if None in input_shape: raise ValueError( "If `include_top` is True, " "you should specify a static `input_shape`. " f"Received: input_shape={input_shape}" ) return input_shape def correct_pad(inputs, kernel_size): """Returns a tuple for zero-padding for 2D convolution with downsampling. Args: inputs: Input tensor. kernel_size: An integer or tuple/list of 2 integers. Returns: A tuple. """ img_dim = 2 if backend.image_data_format() == "channels_first" else 1 input_size = backend.int_shape(inputs)[img_dim : (img_dim + 2)] if isinstance(kernel_size, int): kernel_size = (kernel_size, kernel_size) if input_size[0] is None: adjust = (1, 1) else: adjust = (1 - input_size[0] % 2, 1 - input_size[1] % 2) correct = (kernel_size[0] // 2, kernel_size[1] // 2) return ( (correct[0] - adjust[0], correct[0]), (correct[1] - adjust[1], correct[1]), ) def validate_activation(classifier_activation, weights): """validates that the classifer_activation is compatible with the weights. Args: classifier_activation: str or callable activation function weights: The pretrained weights to load. Raises: ValueError: if an activation other than `None` or `softmax` are used with pretrained weights. """ if weights is None: return classifier_activation = activations.get(classifier_activation) if classifier_activation not in { activations.get("softmax"), activations.get(None), }: raise ValueError( "Only `None` and `softmax` activations are allowed " "for the `classifier_activation` argument when using " "pretrained weights, with `include_top=True`; Received: " f"classifier_activation={classifier_activation}" )