utils.py

import numpy
import cPickle
import gzip
import os
import sys
import time
import scipy.io
import theano
import theano.tensor as T
from PIL 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 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:`PIL.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 save_data(layer_no, learning_rate, corruption_level, epoch, W, b, training_time, model_type="mSdA", training_type="pre-training"):

    image_folder =  '/output/'+model_type+'/layer_images/' + training_type
    if not os.path.isdir(image_folder):
        os.makedirs(image_folder)

    weights_folder = '/output/'+model_type+'/weights/'+training_type + '/layer_' + str(layer_no)
    if not os.path.isdir(weights_folder):
        os.makedirs(weights_folder)

    print '... Model Checkpoint: Saving weights and corresponding image representations.'

    #Saving learned weights
    weight_filename = 'lrate='+str(learning_rate)+',noise='+str(corruption_level)+',epoch='+str(epoch)+'.mat'       
    scipy.io.savemat(os.path.join(weights_folder, weight_filename), {'W': W, 'b':b})
    
    # Saving image representations of learned weights (only for the first layer)
    if layer_no == 1:
        image_filename = 'lrate='+str(learning_rate)+',noise='+str(corruption_level)+',epoch='+str(epoch)+'.png'  
        w_part = W.T
        w_part = w_part[0:600, :]
        image = Image.fromarray(
                        tile_raster_images(w_part,
                        img_shape=(28, 28), tile_shape=(20, 30),
                        tile_spacing=(1, 1)))
        image.save(os.path.join(image_folder, image_filename))

    print 'Model Checkpoint saved. Running time = %.2fm' % ((training_time) / 60.)

def load_data(dataset):
    ''' Loads the dataset

    :type dataset: string
    :param dataset: the path to the dataset (here MNIST)
    '''

    # LOAD DATA #

    # Download the MNIST dataset if it is not present
    data_dir, data_file = os.path.split(dataset)
    if data_dir == "" and not os.path.isfile(dataset):
        # Check if dataset is in the data directory.
        new_path = os.path.join(os.path.split(__file__)[0], "..", "data", dataset)
        if os.path.isfile(new_path) or data_file == 'mnist.pkl.gz':
            dataset = new_path

    if (not os.path.isfile(dataset)) and data_file == 'mnist.pkl.gz':
        import urllib
        origin = 'http://www.iro.umontreal.ca/~lisa/deep/data/mnist/mnist.pkl.gz'
        print 'Downloading data from %s' % origin
        urllib.urlretrieve(origin, dataset)

    print '... loading data'

    # Load the dataset
    f = gzip.open(dataset, 'rb')
    train_set, valid_set, test_set = cPickle.load(f)
    f.close()
    #train_set, valid_set, test_set format: tuple(input, target)
    #input is an numpy.ndarray of 2 dimensions (a matrix)
    #witch row's correspond to an example. target is a
    #numpy.ndarray of 1 dimensions (vector)) that have the same length as
    #the number of rows in the input. It should give the target
    #target to the example with the same index in the input.
    def shared_dataset(data_xy, borrow=True):
        """ Function that loads the dataset into shared variables

        The reason we store our dataset in shared variables is to allow
        Theano to copy it into the GPU memory (when code is run on GPU).
        Since copying data into the GPU is slow, copying a minibatch everytime
        is needed (the default behaviour if the data is not in a shared
        variable) would lead to a large decrease in performance.
        """
        data_x, data_y = data_xy
        shared_x = theano.shared(numpy.asarray(data_x,
                                               dtype=theano.config.floatX),
                                 borrow=borrow)
        shared_y = theano.shared(numpy.asarray(data_y,
                                               dtype=theano.config.floatX),
                                 borrow=borrow)
        # When storing data on the GPU it has to be stored as floats
        # therefore we will store the labels as ``floatX`` as well
        # (``shared_y`` does exactly that). But during our computations
        # we need them as ints (we use labels as index, and if they are
        # floats it doesn't make sense) therefore instead of returning
        # ``shared_y`` we will have to cast it to int. This little hack
        # lets ous get around this issue
        return shared_x, T.cast(shared_y, 'int32')

    test_set_x, test_set_y = shared_dataset(test_set)
    valid_set_x, valid_set_y = shared_dataset(valid_set)
    train_set_x, train_set_y = shared_dataset(train_set)

    rval = [(train_set_x, train_set_y), (valid_set_x, valid_set_y),
            (test_set_x, test_set_y)]
    return rval