utils.py

import numpy
try:
    import PIL.Image as Image
except ImportError:
    import Image


def scale_to_unit_interval(ndar, eps=1e-8):
    """ Scales all values in the ndarray ndar to be between 0 and 1 """
    ndar = ndar.copy()
    ndar -= ndar.min()
    ndar *= 1.0 / (ndar.max() + eps)
    return ndar


def save_images(x, image_name='digits.png', shape=None, img_shape=(28, 28)):
    data_size = x.shape[0]
    image_data = numpy.zeros((img_shape[0]+1, (img_shape[1]+1) * data_size - 1), dtype='uint8')
    if not shape:
        shape = (1, data_size)

    image_data = tile_raster_images(
        X=x,
        img_shape=img_shape,
        tile_shape=shape,
        tile_spacing=(1, 1)
    )

    # construct image
    image = Image.fromarray(image_data)
    image.save(image_name)


def save_digit(x, name="digit.png"):
    image_data = numpy.zeros((29, 29), dtype='uint8')

    # Original images
    image_data = tile_raster_images(
        X=numpy.array([x]),
        img_shape=(28, 28),
        tile_shape=(1, 1),
        tile_spacing=(1, 1)
    )

    image = Image.fromarray(image_data)
    image.save(name)


def tile_raster_images(X, img_shape, tile_shape, tile_spacing=(0, 0),
                       scale_rows_to_unit_interval=True,
                       output_pixel_vals=True):
    """
    Transform an array with one flattened image per row, into an array in
    which images are reshaped and layed out like tiles on a floor.

    This function is useful for visualizing datasets whose rows are images,
    and also columns of matrices for transforming those rows
    (such as the first layer of a neural net).

    :type X: a 2-D ndarray or a tuple of 4 channels, elements of which can
    be 2-D ndarrays or None;
    :param X: a 2-D array in which every row is a flattened image.

    :type img_shape: tuple; (height, width)
    :param img_shape: the original shape of each image

    :type tile_shape: tuple; (rows, cols)
    :param tile_shape: the number of images to tile (rows, cols)

    :param output_pixel_vals: if output should be pixel values (i.e. int8
    values) or floats

    :param scale_rows_to_unit_interval: if the values need to be scaled before
    being plotted to [0,1] or not


    :returns: array suitable for viewing as an image.
    (See:`Image.fromarray`.)
    :rtype: a 2-d array with same dtype as X.

    """

    assert len(img_shape) == 2
    assert len(tile_shape) == 2
    assert len(tile_spacing) == 2

    # The expression below can be re-written in a more C style as
    # follows :
    #
    # out_shape    = [0,0]
    # out_shape[0] = (img_shape[0]+tile_spacing[0])*tile_shape[0] -
    #                tile_spacing[0]
    # out_shape[1] = (img_shape[1]+tile_spacing[1])*tile_shape[1] -
    #                tile_spacing[1]
    out_shape = [
        (ishp + tsp) * tshp - tsp
        for ishp, tshp, tsp in zip(img_shape, tile_shape, tile_spacing)
    ]

    if isinstance(X, tuple):
        assert len(X) == 4
        # Create an output numpy ndarray to store the image
        if output_pixel_vals:
            out_array = numpy.zeros((out_shape[0], out_shape[1], 4),
                                    dtype='uint8')
        else:
            out_array = numpy.zeros((out_shape[0], out_shape[1], 4),
                                    dtype=X.dtype)

        #colors default to 0, alpha defaults to 1 (opaque)
        if output_pixel_vals:
            channel_defaults = [0, 0, 0, 255]
        else:
            channel_defaults = [0., 0., 0., 1.]

        for i in xrange(4):
            if X[i] is None:
                # if channel is None, fill it with zeros of the correct
                # dtype
                dt = out_array.dtype
                if output_pixel_vals:
                    dt = 'uint8'
                out_array[:, :, i] = numpy.zeros(
                    out_shape,
                    dtype=dt
                ) + channel_defaults[i]
            else:
                # use a recurrent call to compute the channel and store it
                # in the output
                out_array[:, :, i] = tile_raster_images(
                    X[i], img_shape, tile_shape, tile_spacing,
                    scale_rows_to_unit_interval, output_pixel_vals)
        return out_array

    else:
        # if we are dealing with only one channel
        H, W = img_shape
        Hs, Ws = tile_spacing

        # generate a matrix to store the output
        dt = X.dtype
        if output_pixel_vals:
            dt = 'uint8'
        out_array = numpy.zeros(out_shape, dtype=dt)

        for tile_row in xrange(tile_shape[0]):
            for tile_col in xrange(tile_shape[1]):
                if tile_row * tile_shape[1] + tile_col < X.shape[0]:
                    this_x = X[tile_row * tile_shape[1] + tile_col]
                    if scale_rows_to_unit_interval:
                        # if we should scale values to be between 0 and 1
                        # do this by calling the `scale_to_unit_interval`
                        # function
                        this_img = scale_to_unit_interval(
                            this_x.reshape(img_shape))
                    else:
                        this_img = this_x.reshape(img_shape)
                    # add the slice to the corresponding position in the
                    # output array
                    c = 1
                    if output_pixel_vals:
                        c = 255
                    out_array[
                        tile_row * (H + Hs): tile_row * (H + Hs) + H,
                        tile_col * (W + Ws): tile_col * (W + Ws) + W
                    ] = this_img * c
        return out_array


def get_class_vector(c, n_classes):
    v = numpy.zeros(10)
    v[c] = 1
    return v


def isSharedType(x_in):
    type_s = str(type(x_in))
    return any(map(lambda x: x in type_s, ['Tensor', 'cuda', 'Shared']))