示例#1
0
 def test_get_model(self, model_key, kernel_size,
                    n_kernels, n_layers, input_size, n_classes):
     model = get_model(model_key, kernel_size, n_kernels,
                       n_layers, input_size, n_classes)
     assert isinstance(model, tf.keras.Sequential), \
         'Assert the model type.'
     layer = model.get_layer(index=2)
     assert isinstance(
         layer, tf.keras.layers.Layer), \
         'Assert not empyt model.'
示例#2
0
def train(*,
          data,
          model_name: str,
          dest_path: str,
          sample_size: int,
          n_classes: int,
          kernel_size: int = 3,
          n_kernels: int = 16,
          n_layers: int = 1,
          lr: float = 0.005,
          batch_size: int = 150,
          epochs: int = 10,
          verbose: int = 2,
          shuffle: bool = True,
          patience: int = 3,
          seed: int = 0,
          noise: ('post', multi(min=0)),
          noise_sets: ('spost', multi(min=0)),
          noise_params: str = None):
    """
    Function for training tensorflow models given a dataset.

    :param model_name: Name of the model, it serves as a key in the
        dictionary holding all functions returning models.
    :param kernel_size: Size of ech kernel in each layer.
    :param n_kernels: Number of kernels in each layer.
    :param n_layers: Number of layers in the model.
    :param dest_path: Path to where to save the model
        under the name "model_name".
    :param sample_size: Size of the input sample.
    :param n_classes: Number of classes.
    :param lr: Learning rate for the model, i.e., regulates the size of the step
        in the gradient descent process.
    :param data: Either path to the input data or the data dict itself.
        First dimension of the dataset should be the number of samples.
    :param batch_size: Size of the batch used in training phase,
        it is the size of samples per gradient step.
    :param epochs: Number of epochs for model to train.
    :param verbose: Verbosity mode used in training, (0, 1 or 2).
    :param shuffle: Boolean indicating whether to shuffle dataset
     dataset_key each epoch.
    :param patience: Number of epochs without improvement in order to
        stop the training phase.
    :param seed: Seed for training reproducibility.
    :param noise: List containing names of used noise injection methods
        that are performed after the normalization transformations.
    :type noise: list[str]
    :param noise_sets: List of sets that are affected by
        the noise injection methods.
        For this module single element can be either "train" or "val".
    :type noise_sets: list[str]
    :param noise_params: JSON containing the parameters
        setting of injection methods.
        Exemplary value for this parameter: "{"mean": 0, "std": 1, "pa": 0.1}".
        This JSON should include all parameters for noise injection
        functions that are specified in the noise argument.
        For the accurate description of each parameter, please
        refer to the ml_intuition/data/noise.py module.
    """

    # Reproducibility
    tf.reset_default_graph()
    tf.set_random_seed(seed=seed)
    np.random.seed(seed=seed)

    if type(data) is str:
        train_dict = io.extract_set(data, enums.Dataset.TRAIN)
        val_dict = io.extract_set(data, enums.Dataset.VAL)
        min_, max_ = train_dict[enums.DataStats.MIN], \
            train_dict[enums.DataStats.MAX]
    else:
        train_dict = data[enums.Dataset.TRAIN]
        val_dict = data[enums.Dataset.VAL]
        min_, max_ = data[enums.DataStats.MIN], \
            data[enums.DataStats.MAX]

    transformations = [transforms.SpectralTransform(),
                       transforms.OneHotEncode(n_classes=n_classes),
                       transforms.MinMaxNormalize(min_=min_, max_=max_)]

    tr_transformations = transformations + get_noise_functions(noise, noise_params) \
        if enums.Dataset.TRAIN in noise_sets else transformations
    val_transformations = transformations + get_noise_functions(noise, noise_params) \
        if enums.Dataset.VAL in noise_sets else transformations

    train_dict = transforms.apply_transformations(train_dict, tr_transformations)
    val_dict = transforms.apply_transformations(val_dict, val_transformations)

    model = models.get_model(model_key=model_name, kernel_size=kernel_size,
                              n_kernels=n_kernels, n_layers=n_layers,
                              input_size=sample_size, n_classes=n_classes)
    model.summary()
    model.compile(tf.keras.optimizers.Adam(lr=lr),
                  'categorical_crossentropy',
                  metrics=['accuracy'])

    time_history = time_metrics.TimeHistory()
    mcp_save = tf.keras.callbacks.ModelCheckpoint(
        os.path.join(dest_path, model_name), save_best_only=True,
        monitor='val_acc', mode='max')
    early_stopping = tf.keras.callbacks.EarlyStopping(monitor='val_loss',
                                                      patience=patience)
    callbacks = [time_history, mcp_save, early_stopping]
    history = model.fit(x=train_dict[enums.Dataset.DATA],
                        y=train_dict[enums.Dataset.LABELS],
                        epochs=epochs,
                        verbose=verbose,
                        shuffle=shuffle,
                        validation_data=(val_dict[enums.Dataset.DATA],
                                         val_dict[enums.Dataset.LABELS]),
                        callbacks=callbacks,
                        batch_size=batch_size)

    history.history[time_metrics.TimeHistory.__name__] = time_history.average
    io.save_metrics(dest_path=dest_path,
                    file_name='training_metrics.csv',
                    metrics=history.history)

    np.savetxt(os.path.join(dest_path, 'min-max.csv'),
               np.array([min_, max_]), delimiter=',', fmt='%f')
示例#3
0
def train(data: Dict[str, np.ndarray], model_name: str, dest_path: str,
          sample_size: int, n_classes: int, neighborhood_size: int, lr: float,
          batch_size: int, epochs: int, verbose: int, shuffle: bool,
          patience: int, endmembers_path: str, seed: int):
    """
    Function for running experiments on various unmixing models,
    given a set of hyper parameters.

    :param data: The data dictionary containing
        the subsets for training and validation.
        First dimension of the dataset should be the number of samples.
    :param model_name: Name of the model, it serves as a key in the
        dictionary holding all functions returning models.
    :param dest_path: Path to where all experiment runs will be saved as
        subdirectories in this directory.
    :param sample_size: Spectral size of the input sample.
    :param n_classes: Number of classes.
    :param neighborhood_size: Size of the spatial patch.
    :param lr: Learning rate for the model i.e., it regulates
        the size of the step in the gradient descent process.
    :param batch_size: Size of the batch used in training phase,
        it is the number of samples per gradient step.
    :param epochs: Number of epochs for the model to train.
    :param verbose: Verbosity mode used in training, (0, 1 or 2).
    :param shuffle: Boolean indicating whether to shuffle the dataset.
    :param patience: Number of epochs without improvement in order to
        stop the training phase.
    :param endmembers_path: Path to the endmembers file
        containing the average reflectances for each class
        i.e., the pure spectra. Used only when use_unmixing is set to True.
    :param seed: Seed for experiment reproducibility.
    """
    # Reproducibility:
    tf.reset_default_graph()
    tf.set_random_seed(seed=seed)
    np.random.seed(seed=seed)

    model = models.get_model(
        model_key=model_name,
        **{
            'input_size':
            sample_size,
            'n_classes':
            n_classes,
            'neighborhood_size':
            neighborhood_size,
            'endmembers':
            np.load(endmembers_path) if endmembers_path is not None else None
        })
    model.summary()
    model.compile(optimizer=tf.keras.optimizers.Adam(lr=lr),
                  loss=UNMIXING_LOSSES[model_name],
                  metrics=UNMIXING_TRAIN_METRICS[model_name])

    time_history = time_metrics.TimeHistory()

    mcp_save = tf.keras.callbacks.ModelCheckpoint(os.path.join(
        dest_path, model_name),
                                                  save_best_only=True,
                                                  monitor='val_loss',
                                                  mode='min')

    early_stopping = tf.keras.callbacks.EarlyStopping(monitor='val_loss',
                                                      patience=patience,
                                                      mode='min')

    callbacks = [time_history, mcp_save, early_stopping]

    train_dict = data[enums.Dataset.TRAIN].copy()
    val_dict = data[enums.Dataset.VAL].copy()

    min_, max_ = data[enums.DataStats.MIN], data[enums.DataStats.MAX]

    transformations = [transforms.MinMaxNormalize(min_=min_, max_=max_)]
    transformations += [
        t(**{'neighborhood_size': neighborhood_size})
        for t in UNMIXING_TRANSFORMS[model_name]
    ]

    train_dict = transforms.apply_transformations(train_dict, transformations)
    val_dict = transforms.apply_transformations(val_dict, transformations)

    history = model.fit(x=train_dict[enums.Dataset.DATA],
                        y=train_dict[enums.Dataset.LABELS],
                        epochs=epochs,
                        verbose=verbose,
                        shuffle=shuffle,
                        validation_data=(val_dict[enums.Dataset.DATA],
                                         val_dict[enums.Dataset.LABELS]),
                        callbacks=callbacks,
                        batch_size=batch_size)

    np.savetxt(os.path.join(dest_path, 'min-max.csv'),
               np.array([min_, max_]),
               delimiter=',',
               fmt='%f')

    history.history[time_metrics.TimeHistory.__name__] = time_history.average

    io.save_metrics(dest_path=dest_path,
                    file_name='training_metrics.csv',
                    metrics=history.history)