コード例 #1
0
def _get_sorted_solutions_indexes(selected_sections_matrix, nb_journeys_to_find, idx_of_jrny_must_keep):
    """
    The entry is a 2D array where its lines are journeys, its columns are (non) chosen sections
    """
    logger = logging.getLogger(__name__)
    """
    Get a matrix which illustrate all possible non ordered combinations of t elements from n elements where n >= t with
    their indexes.

    Let's say we'd like to find all combinations of 2 elements from a set of 3.

    selected_journeys_matrix will be like:

    [[0,1]
     [0,2]
     [1,2]]
    """
    # Allocation of memory
    shape = (nCr(selected_sections_matrix.shape[0], nb_journeys_to_find), nb_journeys_to_find)
    selected_journeys_matrix = np.empty(shape, dtype=np.uint16)

    def f(pair):
        i, c = pair
        selected_journeys_matrix[i] = c

    # replace line by line
    from itertools import izip

    map(f, izip(xrange(shape[0]), gen_all_combin(selected_sections_matrix.shape[0], nb_journeys_to_find)))
    """
    We should cut out those combinations that don't contain must-keep journeys
    """

    def _contains(idx_selected_jrny):
        return set(idx_selected_jrny).issuperset(idx_of_jrny_must_keep)

    selected_journeys_matrix = selected_journeys_matrix[
        np.apply_along_axis(_contains, 1, selected_journeys_matrix)
    ]

    selection_matrix = np.zeros((selected_journeys_matrix.shape[0], selected_sections_matrix.shape[0]))

    """
    Given  selected_journeys_matrix:
    [[0,1]
     [0,2]
     [1,2]]

    selection_matrix will be like:
    [[1,1,0], -> the first one and the second are chosen, etc...
     [1,0,1],
     [0,1,1]]
    """
    # http://stackoverflow.com/questions/20103779/index-2d-numpy-array-by-a-2d-array-of-indices-without-loops
    selection_matrix[np.arange(selected_journeys_matrix.shape[0])[:, None], selected_journeys_matrix] = 1

    res_pool = np.dot(selection_matrix, selected_sections_matrix)

    """
    Get number of sections(or tranfers) for every solution
    """
    nb_sections = np.sum(res_pool, axis=1)

    """
    integrity shows at which point a solution(chosen journeys) covers sections.
    0 means a solution covers all sections
    1 means a solutions covers almost all sections but 1 is missing
    2 means 2 sections are missing
    .... etc
    """
    integrity = res_pool.shape[1] - np.array([np.count_nonzero(r) for r in res_pool])

    """
    We want to find the solutions covers as many sections as possible which has less sections(less transfer to do)
    """
    the_best_idx = np.lexsort((nb_sections, integrity))[0]  # sort by integrity then by nb_sections

    best_indexes = np.where(
        np.logical_and(nb_sections == nb_sections[the_best_idx], integrity == integrity[the_best_idx])
    )[0]

    logger.debug("Best Itegrity: {0}".format(integrity[the_best_idx]))
    logger.debug("Best Nb sections: {0}".format(nb_sections[the_best_idx]))

    return best_indexes, selection_matrix
コード例 #2
0
def _get_sorted_solutions_indexes(selected_sections_matrix, nb_journeys_to_find):
    """
    The entry is a 2D array where its lines are journeys, its columns are (non) chosen sections
    """
    logger = logging.getLogger(__name__)
    """
    Get a matrix which illustrate all possible non ordered combinations of t elements from n elements where n >= t with
    their indexes.

    Let's say we'd like to find all combinations of 2 elements from a set of 3.

    selected_journeys_matrix will be like:

    [[0,1]
     [0,2]
     [1,2]]
    """
    selected_journeys_matrix = np.array(list(gen_all_combin(selected_sections_matrix.shape[0], nb_journeys_to_find)))

    selection_matrix = np.zeros((selected_journeys_matrix.shape[0], selected_sections_matrix.shape[0]))

    """
    Given  selected_journeys_matrix:
    [[0,1]
     [0,2]
     [1,2]]

    selection_matrix will be like:
    [[1,1,0], -> the first one and the second are chosen, etc...
     [1,0,1],
     [0,1,1]]
    """
    # http://stackoverflow.com/questions/20103779/index-2d-numpy-array-by-a-2d-array-of-indices-without-loops
    selection_matrix[np.arange(selected_journeys_matrix.shape[0])[:, None], selected_journeys_matrix] = 1

    res_pool = np.dot(selection_matrix, selected_sections_matrix)

    """
    Get number of sections(or tranfers) for every solution
    """
    nb_sections = np.sum(res_pool, axis=1)

    """
    integrity shows at which point a solution(chosen journeys) covers sections.
    0 means a solution covers all sections
    1 means a solutions covers almost all sections but 1 is missing
    2 means 2 sections are missing
    .... etc
    """
    integrity = res_pool.shape[1] - np.array([np.count_nonzero(r) for r in res_pool])

    """
    We want to find the solutions covers as many sections as possible which has less sections(less transfer to do)
    """
    the_best_idx = np.lexsort((nb_sections, integrity))[0]  # sort by integrity then by nb_sections

    best_indexes = np.where(np.logical_and(nb_sections == nb_sections[the_best_idx],
                                           integrity == integrity[the_best_idx]))[0]

    logger.debug("Best Itegrity: {0}".format(integrity[the_best_idx]))
    logger.debug("Best Nb sections: {0}".format(nb_sections[the_best_idx]))

    return best_indexes, selection_matrix