Source code for colour.algebra.common

#!/usr/bin/env python
# -*- coding: utf-8 -*-

"""
Algebra Common Utilities
========================

Defines algebra common utilities objects that don"t belong to any algebra
specific category.
"""

from __future__ import division, unicode_literals

import numpy as np

__author__ = 'Colour Developers'
__copyright__ = 'Copyright (C) 2013 - 2014 - Colour Developers'
__license__ = 'New BSD License - http://opensource.org/licenses/BSD-3-Clause'
__maintainer__ = 'Colour Developers'
__email__ = 'colour-science@googlegroups.com'
__status__ = 'Production'

__all__ = ['FLOATING_POINT_NUMBER_PATTERN',
           'INTEGER_THRESHOLD',
           'steps',
           'closest',
           'to_ndarray',
           'is_uniform',
           'is_iterable',
           'is_numeric',
           'is_integer',
           'normalise']

FLOATING_POINT_NUMBER_PATTERN = '[0-9]*\.?[0-9]+([eE][-+]?[0-9]+)?'

INTEGER_THRESHOLD = 0.001
"""
Integer threshold value.

INTEGER_THRESHOLD : numeric
"""


[docs]def steps(distribution): """ Returns the steps of given distribution. Parameters ---------- distribution : array_like Distribution to retrieve the steps. Returns ------- tuple Distribution steps. Examples -------- Uniformly spaced variable: >>> y = np.array([1, 2, 3, 4, 5]) >>> steps(y) (1,) Non-uniformly spaced variable: >>> y = np.array([1, 2, 3, 4, 8]) >>> steps(y) (1, 4) """ return tuple(set([distribution[i + 1] - distribution[i] for i in range(len(distribution) - 1)]))
[docs]def closest(y, x): """ Returns closest :math:`y` variable element to reference :math:`x` variable. Parameters ---------- y : array_like Variable to search for the closest element. x : numeric Reference variable. Returns ------- numeric Closest :math:`y` variable element. Examples -------- >>> y = np.array([24.31357115, 63.62396289, 55.71528816, 62.70988028, 46.84480573, 25.40026416]) # noqa >>> closest(y, 63) 62.70988028 """ return y[(np.abs(np.array(y) - x)).argmin()]
[docs]def to_ndarray(x, data_type=np.float_): """ Converts given :math:`x` variable to *ndarray*. Parameters ---------- x : object Variable to convert. data_type : dtype *ndarray* data type. Returns ------- ndarray :math:`x` variable converted to *ndarray*. Examples -------- >>> to_ndarray(1) array([ 1.]) """ return (np.array(x, dtype=data_type) if is_iterable(x) else np.array((x,), dtype=data_type))
[docs]def is_uniform(distribution): """ Returns if given distribution is uniform. Parameters ---------- distribution : array_like Distribution to check for uniformity. Returns ------- bool Is distribution uniform. Examples -------- Uniformly spaced variable: >>> y = np.array([1, 2, 3, 4, 5]) >>> is_uniform(y) True Non-uniformly spaced variable: >>> y = np.array([1, 2, 3.1415, 4, 5]) >>> is_uniform(y) False """ return True if len(steps(distribution)) == 1 else False
[docs]def is_iterable(x): """ Returns if given :math:`x` variable is iterable. Parameters ---------- x : object Variable to check the iterability. Returns ------- bool :math:`x` variable iterability. Examples -------- >>> is_iterable([1, 2, 3]) True >>> is_iterable(1) False """ try: for _ in x: break return True except TypeError: return False
[docs]def is_numeric(x): """ Returns if given :math:`x` variable is a number. Parameters ---------- x : object Variable to check. Returns ------- bool Is :math:`x` variable a number. See Also -------- is_integer Examples -------- >>> is_numeric(1) True >>> is_numeric((1,)) False """ return isinstance(x, (int, float, complex, np.integer, np.floating, np.complex))
[docs]def is_integer(x): """ Returns if given :math:`x` variable is an integer under given threshold. Parameters ---------- x : object Variable to check. Returns ------- bool Is :math:`x` variable an integer. Notes ----- - The determination threshold is defined by the :attr:`colour.algebra.common.INTEGER_THRESHOLD` attribute. See Also -------- is_numeric Examples -------- >>> is_integer(1) True >>> is_integer(1.01) False """ return abs(x - round(x)) <= INTEGER_THRESHOLD
[docs]def normalise(x, factor=1, clip=True): """ Normalises given *array_like* :math:`x` variable values and optionally clip them between. Parameters ---------- x : array_like :math:`x` variable to normalise. factor : numeric, optional Normalization factor clip : bool, optional Clip values between in domain [0, 'factor']. Returns ------- ndarray Normalised :math:`x` variable. Examples -------- >>> x = np.array([0.48224885, 0.31651974, 0.22070513]) >>> normalise(x) # doctest: +ELLIPSIS array([ 1. , 0.6563411..., 0.4576581...]) """ x = to_ndarray(x) maximum = np.max(x) x *= (1 / maximum) * factor return np.clip(x, 0, factor) if clip else x