Source code for scipy.ndimage._filters

# Copyright (C) 2003-2005 Peter J. Verveer
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from collections.abc import Iterable
import numbers
import warnings
import numpy
import operator
from numpy.core.multiarray import normalize_axis_index
from . import _ni_support
from . import _nd_image
from . import _ni_docstrings

__all__ = ['correlate1d', 'convolve1d', 'gaussian_filter1d', 'gaussian_filter',
           'prewitt', 'sobel', 'generic_laplace', 'laplace',
           'gaussian_laplace', 'generic_gradient_magnitude',
           'gaussian_gradient_magnitude', 'correlate', 'convolve',
           'uniform_filter1d', 'uniform_filter', 'minimum_filter1d',
           'maximum_filter1d', 'minimum_filter', 'maximum_filter',
           'rank_filter', 'median_filter', 'percentile_filter',
           'generic_filter1d', 'generic_filter']


def _invalid_origin(origin, lenw):
    return (origin < -(lenw // 2)) or (origin > (lenw - 1) // 2)


def _complex_via_real_components(func, input, weights, output, cval, **kwargs):
    """Complex convolution via a linear combination of real convolutions."""
    complex_input = input.dtype.kind == 'c'
    complex_weights = weights.dtype.kind == 'c'
    if complex_input and complex_weights:
        # real component of the output
        func(input.real, weights.real, output=output.real,
             cval=numpy.real(cval), **kwargs)
        output.real -= func(input.imag, weights.imag, output=None,
                            cval=numpy.imag(cval), **kwargs)
        # imaginary component of the output
        func(input.real, weights.imag, output=output.imag,
             cval=numpy.real(cval), **kwargs)
        output.imag += func(input.imag, weights.real, output=None,
                            cval=numpy.imag(cval), **kwargs)
    elif complex_input:
        func(input.real, weights, output=output.real, cval=numpy.real(cval),
             **kwargs)
        func(input.imag, weights, output=output.imag, cval=numpy.imag(cval),
             **kwargs)
    else:
        if numpy.iscomplexobj(cval):
            raise ValueError("Cannot provide a complex-valued cval when the "
                             "input is real.")
        func(input, weights.real, output=output.real, cval=cval, **kwargs)
        func(input, weights.imag, output=output.imag, cval=cval, **kwargs)
    return output


@_ni_docstrings.docfiller
def correlate1d(input, weights, axis=-1, output=None, mode="reflect",
                cval=0.0, origin=0):
    """Calculate a 1-D correlation along the given axis.

    The lines of the array along the given axis are correlated with the
    given weights.

    Parameters
    ----------
    %(input)s
    weights : array
        1-D sequence of numbers.
    %(axis)s
    %(output)s
    %(mode_reflect)s
    %(cval)s
    %(origin)s

    Examples
    --------
    >>> from scipy.ndimage import correlate1d
    >>> correlate1d([2, 8, 0, 4, 1, 9, 9, 0], weights=[1, 3])
    array([ 8, 26,  8, 12,  7, 28, 36,  9])
    """
    input = numpy.asarray(input)
    weights = numpy.asarray(weights)
    complex_input = input.dtype.kind == 'c'
    complex_weights = weights.dtype.kind == 'c'
    if complex_input or complex_weights:
        if complex_weights:
            weights = weights.conj()
            weights = weights.astype(numpy.complex128, copy=False)
        kwargs = dict(axis=axis, mode=mode, origin=origin)
        output = _ni_support._get_output(output, input, complex_output=True)
        return _complex_via_real_components(correlate1d, input, weights,
                                            output, cval, **kwargs)

    output = _ni_support._get_output(output, input)
    weights = numpy.asarray(weights, dtype=numpy.float64)
    if weights.ndim != 1 or weights.shape[0] < 1:
        raise RuntimeError('no filter weights given')
    if not weights.flags.contiguous:
        weights = weights.copy()
    axis = normalize_axis_index(axis, input.ndim)
    if _invalid_origin(origin, len(weights)):
        raise ValueError('Invalid origin; origin must satisfy '
                         '-(len(weights) // 2) <= origin <= '
                         '(len(weights)-1) // 2')
    mode = _ni_support._extend_mode_to_code(mode)
    _nd_image.correlate1d(input, weights, axis, output, mode, cval,
                          origin)
    return output


@_ni_docstrings.docfiller
def convolve1d(input, weights, axis=-1, output=None, mode="reflect",
               cval=0.0, origin=0):
    """Calculate a 1-D convolution along the given axis.

    The lines of the array along the given axis are convolved with the
    given weights.

    Parameters
    ----------
    %(input)s
    weights : ndarray
        1-D sequence of numbers.
    %(axis)s
    %(output)s
    %(mode_reflect)s
    %(cval)s
    %(origin)s

    Returns
    -------
    convolve1d : ndarray
        Convolved array with same shape as input

    Examples
    --------
    >>> from scipy.ndimage import convolve1d
    >>> convolve1d([2, 8, 0, 4, 1, 9, 9, 0], weights=[1, 3])
    array([14, 24,  4, 13, 12, 36, 27,  0])
    """
    weights = weights[::-1]
    origin = -origin
    if not len(weights) & 1:
        origin -= 1
    weights = numpy.asarray(weights)
    if weights.dtype.kind == 'c':
        # pre-conjugate here to counteract the conjugation in correlate1d
        weights = weights.conj()
    return correlate1d(input, weights, axis, output, mode, cval, origin)


def _gaussian_kernel1d(sigma, order, radius):
    """
    Computes a 1-D Gaussian convolution kernel.
    """
    if order < 0:
        raise ValueError('order must be non-negative')
    exponent_range = numpy.arange(order + 1)
    sigma2 = sigma * sigma
    x = numpy.arange(-radius, radius+1)
    phi_x = numpy.exp(-0.5 / sigma2 * x ** 2)
    phi_x = phi_x / phi_x.sum()

    if order == 0:
        return phi_x
    else:
        # f(x) = q(x) * phi(x) = q(x) * exp(p(x))
        # f'(x) = (q'(x) + q(x) * p'(x)) * phi(x)
        # p'(x) = -1 / sigma ** 2
        # Implement q'(x) + q(x) * p'(x) as a matrix operator and apply to the
        # coefficients of q(x)
        q = numpy.zeros(order + 1)
        q[0] = 1
        D = numpy.diag(exponent_range[1:], 1)  # D @ q(x) = q'(x)
        P = numpy.diag(numpy.ones(order)/-sigma2, -1)  # P @ q(x) = q(x) * p'(x)
        Q_deriv = D + P
        for _ in range(order):
            q = Q_deriv.dot(q)
        q = (x[:, None] ** exponent_range).dot(q)
        return q * phi_x


@_ni_docstrings.docfiller
def gaussian_filter1d(input, sigma, axis=-1, order=0, output=None,
                      mode="reflect", cval=0.0, truncate=4.0, *, radius=None):
    """1-D Gaussian filter.

    Parameters
    ----------
    %(input)s
    sigma : scalar
        standard deviation for Gaussian kernel
    %(axis)s
    order : int, optional
        An order of 0 corresponds to convolution with a Gaussian
        kernel. A positive order corresponds to convolution with
        that derivative of a Gaussian.
    %(output)s
    %(mode_reflect)s
    %(cval)s
    truncate : float, optional
        Truncate the filter at this many standard deviations.
        Default is 4.0.
    radius : None or int, optional
        Radius of the Gaussian kernel. If specified, the size of
        the kernel will be ``2*radius + 1``, and `truncate` is ignored.
        Default is None.

    Returns
    -------
    gaussian_filter1d : ndarray

    Notes
    -----
    The Gaussian kernel will have size ``2*radius + 1`` along each axis. If
    `radius` is None, a default ``radius = round(truncate * sigma)`` will be
    used.

    Examples
    --------
    >>> from scipy.ndimage import gaussian_filter1d
    >>> import numpy as np
    >>> gaussian_filter1d([1.0, 2.0, 3.0, 4.0, 5.0], 1)
    array([ 1.42704095,  2.06782203,  3.        ,  3.93217797,  4.57295905])
    >>> gaussian_filter1d([1.0, 2.0, 3.0, 4.0, 5.0], 4)
    array([ 2.91948343,  2.95023502,  3.        ,  3.04976498,  3.08051657])
    >>> import matplotlib.pyplot as plt
    >>> rng = np.random.default_rng()
    >>> x = rng.standard_normal(101).cumsum()
    >>> y3 = gaussian_filter1d(x, 3)
    >>> y6 = gaussian_filter1d(x, 6)
    >>> plt.plot(x, 'k', label='original data')
    >>> plt.plot(y3, '--', label='filtered, sigma=3')
    >>> plt.plot(y6, ':', label='filtered, sigma=6')
    >>> plt.legend()
    >>> plt.grid()
    >>> plt.show()

    """
    sd = float(sigma)
    # make the radius of the filter equal to truncate standard deviations
    lw = int(truncate * sd + 0.5)
    if radius is not None:
        lw = radius
    if not isinstance(lw, numbers.Integral) or lw < 0:
        raise ValueError('Radius must be a nonnegative integer.')
    # Since we are calling correlate, not convolve, revert the kernel
    weights = _gaussian_kernel1d(sigma, order, lw)[::-1]
    return correlate1d(input, weights, axis, output, mode, cval, 0)


@_ni_docstrings.docfiller
def gaussian_filter(input, sigma, order=0, output=None,
                    mode="reflect", cval=0.0, truncate=4.0, *, radius=None,
                    axes=None):
    """Multidimensional Gaussian filter.

    Parameters
    ----------
    %(input)s
    sigma : scalar or sequence of scalars
        Standard deviation for Gaussian kernel. The standard
        deviations of the Gaussian filter are given for each axis as a
        sequence, or as a single number, in which case it is equal for
        all axes.
    order : int or sequence of ints, optional
        The order of the filter along each axis is given as a sequence
        of integers, or as a single number. An order of 0 corresponds
        to convolution with a Gaussian kernel. A positive order
        corresponds to convolution with that derivative of a Gaussian.
    %(output)s
    %(mode_multiple)s
    %(cval)s
    truncate : float, optional
        Truncate the filter at this many standard deviations.
        Default is 4.0.
    radius : None or int or sequence of ints, optional
        Radius of the Gaussian kernel. The radius are given for each axis
        as a sequence, or as a single number, in which case it is equal
        for all axes. If specified, the size of the kernel along each axis
        will be ``2*radius + 1``, and `truncate` is ignored.
        Default is None.
    axes : tuple of int or None, optional
        If None, `input` is filtered along all axes. Otherwise,
        `input` is filtered along the specified axes. When `axes` is
        specified, any tuples used for `sigma`, `order`, `mode` and/or `radius`
        must match the length of `axes`. The ith entry in any of these tuples
        corresponds to the ith entry in `axes`.

    Returns
    -------
    gaussian_filter : ndarray
        Returned array of same shape as `input`.

    Notes
    -----
    The multidimensional filter is implemented as a sequence of
    1-D convolution filters. The intermediate arrays are
    stored in the same data type as the output. Therefore, for output
    types with a limited precision, the results may be imprecise
    because intermediate results may be stored with insufficient
    precision.

    The Gaussian kernel will have size ``2*radius + 1`` along each axis. If
    `radius` is None, the default ``radius = round(truncate * sigma)`` will be
    used.

    Examples
    --------
    >>> from scipy.ndimage import gaussian_filter
    >>> import numpy as np
    >>> a = np.arange(50, step=2).reshape((5,5))
    >>> a
    array([[ 0,  2,  4,  6,  8],
           [10, 12, 14, 16, 18],
           [20, 22, 24, 26, 28],
           [30, 32, 34, 36, 38],
           [40, 42, 44, 46, 48]])
    >>> gaussian_filter(a, sigma=1)
    array([[ 4,  6,  8,  9, 11],
           [10, 12, 14, 15, 17],
           [20, 22, 24, 25, 27],
           [29, 31, 33, 34, 36],
           [35, 37, 39, 40, 42]])

    >>> from scipy import datasets
    >>> import matplotlib.pyplot as plt
    >>> fig = plt.figure()
    >>> plt.gray()  # show the filtered result in grayscale
    >>> ax1 = fig.add_subplot(121)  # left side
    >>> ax2 = fig.add_subplot(122)  # right side
    >>> ascent = datasets.ascent()
    >>> result = gaussian_filter(ascent, sigma=5)
    >>> ax1.imshow(ascent)
    >>> ax2.imshow(result)
    >>> plt.show()
    """
    input = numpy.asarray(input)
    output = _ni_support._get_output(output, input)

    axes = _ni_support._check_axes(axes, input.ndim)
    num_axes = len(axes)
    orders = _ni_support._normalize_sequence(order, num_axes)
    sigmas = _ni_support._normalize_sequence(sigma, num_axes)
    modes = _ni_support._normalize_sequence(mode, num_axes)
    radiuses = _ni_support._normalize_sequence(radius, num_axes)
    axes = [(axes[ii], sigmas[ii], orders[ii], modes[ii], radiuses[ii])
            for ii in range(num_axes) if sigmas[ii] > 1e-15]
    if len(axes) > 0:
        for axis, sigma, order, mode, radius in axes:
            gaussian_filter1d(input, sigma, axis, order, output,
                              mode, cval, truncate, radius=radius)
            input = output
    else:
        output[...] = input[...]
    return output


@_ni_docstrings.docfiller
def prewitt(input, axis=-1, output=None, mode="reflect", cval=0.0):
    """Calculate a Prewitt filter.

    Parameters
    ----------
    %(input)s
    %(axis)s
    %(output)s
    %(mode_multiple)s
    %(cval)s

    Examples
    --------
    >>> from scipy import ndimage, datasets
    >>> import matplotlib.pyplot as plt
    >>> fig = plt.figure()
    >>> plt.gray()  # show the filtered result in grayscale
    >>> ax1 = fig.add_subplot(121)  # left side
    >>> ax2 = fig.add_subplot(122)  # right side
    >>> ascent = datasets.ascent()
    >>> result = ndimage.prewitt(ascent)
    >>> ax1.imshow(ascent)
    >>> ax2.imshow(result)
    >>> plt.show()
    """
    input = numpy.asarray(input)
    axis = normalize_axis_index(axis, input.ndim)
    output = _ni_support._get_output(output, input)
    modes = _ni_support._normalize_sequence(mode, input.ndim)
    correlate1d(input, [-1, 0, 1], axis, output, modes[axis], cval, 0)
    axes = [ii for ii in range(input.ndim) if ii != axis]
    for ii in axes:
        correlate1d(output, [1, 1, 1], ii, output, modes[ii], cval, 0,)
    return output


@_ni_docstrings.docfiller
def sobel(input, axis=-1, output=None, mode="reflect", cval=0.0):
    """Calculate a Sobel filter.

    Parameters
    ----------
    %(input)s
    %(axis)s
    %(output)s
    %(mode_multiple)s
    %(cval)s

    Notes
    -----
    This function computes the axis-specific Sobel gradient.
    The horizontal edges can emphasised with the horizontal trasform (axis=0),
    the vertical edges with the vertical transform (axis=1) and so on for higher
    dimensions. These can be combined to give the magnitude.

    Examples
    --------
    >>> from scipy import ndimage, datasets
    >>> import matplotlib.pyplot as plt
    >>> import numpy as np
    >>> ascent = datasets.ascent().astype('int32')
    >>> sobel_h = ndimage.sobel(ascent, 0)  # horizontal gradient
    >>> sobel_v = ndimage.sobel(ascent, 1)  # vertical gradient
    >>> magnitude = np.sqrt(sobel_h**2 + sobel_v**2)
    >>> magnitude *= 255.0 / np.max(magnitude)  # normalization
    >>> fig, axs = plt.subplots(2, 2, figsize=(8, 8))
    >>> plt.gray()  # show the filtered result in grayscale
    >>> axs[0, 0].imshow(ascent)
    >>> axs[0, 1].imshow(sobel_h)
    >>> axs[1, 0].imshow(sobel_v)
    >>> axs[1, 1].imshow(magnitude)
    >>> titles = ["original", "horizontal", "vertical", "magnitude"]
    >>> for i, ax in enumerate(axs.ravel()):
    ...     ax.set_title(titles[i])
    ...     ax.axis("off")
    >>> plt.show()

    """
    input = numpy.asarray(input)
    axis = normalize_axis_index(axis, input.ndim)
    output = _ni_support._get_output(output, input)
    modes = _ni_support._normalize_sequence(mode, input.ndim)
    correlate1d(input, [-1, 0, 1], axis, output, modes[axis], cval, 0)
    axes = [ii for ii in range(input.ndim) if ii != axis]
    for ii in axes:
        correlate1d(output, [1, 2, 1], ii, output, modes[ii], cval, 0)
    return output


@_ni_docstrings.docfiller
def generic_laplace(input, derivative2, output=None, mode="reflect",
                    cval=0.0,
                    extra_arguments=(),
                    extra_keywords=None):
    """
    N-D Laplace filter using a provided second derivative function.

    Parameters
    ----------
    %(input)s
    derivative2 : callable
        Callable with the following signature::

            derivative2(input, axis, output, mode, cval,
                        *extra_arguments, **extra_keywords)

        See `extra_arguments`, `extra_keywords` below.
    %(output)s
    %(mode_multiple)s
    %(cval)s
    %(extra_keywords)s
    %(extra_arguments)s
    """
    if extra_keywords is None:
        extra_keywords = {}
    input = numpy.asarray(input)
    output = _ni_support._get_output(output, input)
    axes = list(range(input.ndim))
    if len(axes) > 0:
        modes = _ni_support._normalize_sequence(mode, len(axes))
        derivative2(input, axes[0], output, modes[0], cval,
                    *extra_arguments, **extra_keywords)
        for ii in range(1, len(axes)):
            tmp = derivative2(input, axes[ii], output.dtype, modes[ii], cval,
                              *extra_arguments, **extra_keywords)
            output += tmp
    else:
        output[...] = input[...]
    return output


@_ni_docstrings.docfiller
def laplace(input, output=None, mode="reflect", cval=0.0):
    """N-D Laplace filter based on approximate second derivatives.

    Parameters
    ----------
    %(input)s
    %(output)s
    %(mode_multiple)s
    %(cval)s

    Examples
    --------
    >>> from scipy import ndimage, datasets
    >>> import matplotlib.pyplot as plt
    >>> fig = plt.figure()
    >>> plt.gray()  # show the filtered result in grayscale
    >>> ax1 = fig.add_subplot(121)  # left side
    >>> ax2 = fig.add_subplot(122)  # right side
    >>> ascent = datasets.ascent()
    >>> result = ndimage.laplace(ascent)
    >>> ax1.imshow(ascent)
    >>> ax2.imshow(result)
    >>> plt.show()
    """
    def derivative2(input, axis, output, mode, cval):
        return correlate1d(input, [1, -2, 1], axis, output, mode, cval, 0)
    return generic_laplace(input, derivative2, output, mode, cval)


@_ni_docstrings.docfiller
def gaussian_laplace(input, sigma, output=None, mode="reflect",
                     cval=0.0, **kwargs):
    """Multidimensional Laplace filter using Gaussian second derivatives.

    Parameters
    ----------
    %(input)s
    sigma : scalar or sequence of scalars
        The standard deviations of the Gaussian filter are given for
        each axis as a sequence, or as a single number, in which case
        it is equal for all axes.
    %(output)s
    %(mode_multiple)s
    %(cval)s
    Extra keyword arguments will be passed to gaussian_filter().

    Examples
    --------
    >>> from scipy import ndimage, datasets
    >>> import matplotlib.pyplot as plt
    >>> ascent = datasets.ascent()

    >>> fig = plt.figure()
    >>> plt.gray()  # show the filtered result in grayscale
    >>> ax1 = fig.add_subplot(121)  # left side
    >>> ax2 = fig.add_subplot(122)  # right side

    >>> result = ndimage.gaussian_laplace(ascent, sigma=1)
    >>> ax1.imshow(result)

    >>> result = ndimage.gaussian_laplace(ascent, sigma=3)
    >>> ax2.imshow(result)
    >>> plt.show()
    """
    input = numpy.asarray(input)

    def derivative2(input, axis, output, mode, cval, sigma, **kwargs):
        order = [0] * input.ndim
        order[axis] = 2
        return gaussian_filter(input, sigma, order, output, mode, cval,
                               **kwargs)

    return generic_laplace(input, derivative2, output, mode, cval,
                           extra_arguments=(sigma,),
                           extra_keywords=kwargs)


@_ni_docstrings.docfiller
def generic_gradient_magnitude(input, derivative, output=None,
                               mode="reflect", cval=0.0,
                               extra_arguments=(), extra_keywords=None):
    """Gradient magnitude using a provided gradient function.

    Parameters
    ----------
    %(input)s
    derivative : callable
        Callable with the following signature::

            derivative(input, axis, output, mode, cval,
                       *extra_arguments, **extra_keywords)

        See `extra_arguments`, `extra_keywords` below.
        `derivative` can assume that `input` and `output` are ndarrays.
        Note that the output from `derivative` is modified inplace;
        be careful to copy important inputs before returning them.
    %(output)s
    %(mode_multiple)s
    %(cval)s
    %(extra_keywords)s
    %(extra_arguments)s
    """
    if extra_keywords is None:
        extra_keywords = {}
    input = numpy.asarray(input)
    output = _ni_support._get_output(output, input)
    axes = list(range(input.ndim))
    if len(axes) > 0:
        modes = _ni_support._normalize_sequence(mode, len(axes))
        derivative(input, axes[0], output, modes[0], cval,
                   *extra_arguments, **extra_keywords)
        numpy.multiply(output, output, output)
        for ii in range(1, len(axes)):
            tmp = derivative(input, axes[ii], output.dtype, modes[ii], cval,
                             *extra_arguments, **extra_keywords)
            numpy.multiply(tmp, tmp, tmp)
            output += tmp
        # This allows the sqrt to work with a different default casting
        numpy.sqrt(output, output, casting='unsafe')
    else:
        output[...] = input[...]
    return output


@_ni_docstrings.docfiller
def gaussian_gradient_magnitude(input, sigma, output=None,
                                mode="reflect", cval=0.0, **kwargs):
    """Multidimensional gradient magnitude using Gaussian derivatives.

    Parameters
    ----------
    %(input)s
    sigma : scalar or sequence of scalars
        The standard deviations of the Gaussian filter are given for
        each axis as a sequence, or as a single number, in which case
        it is equal for all axes.
    %(output)s
    %(mode_multiple)s
    %(cval)s
    Extra keyword arguments will be passed to gaussian_filter().

    Returns
    -------
    gaussian_gradient_magnitude : ndarray
        Filtered array. Has the same shape as `input`.

    Examples
    --------
    >>> from scipy import ndimage, datasets
    >>> import matplotlib.pyplot as plt
    >>> fig = plt.figure()
    >>> plt.gray()  # show the filtered result in grayscale
    >>> ax1 = fig.add_subplot(121)  # left side
    >>> ax2 = fig.add_subplot(122)  # right side
    >>> ascent = datasets.ascent()
    >>> result = ndimage.gaussian_gradient_magnitude(ascent, sigma=5)
    >>> ax1.imshow(ascent)
    >>> ax2.imshow(result)
    >>> plt.show()
    """
    input = numpy.asarray(input)

    def derivative(input, axis, output, mode, cval, sigma, **kwargs):
        order = [0] * input.ndim
        order[axis] = 1
        return gaussian_filter(input, sigma, order, output, mode,
                               cval, **kwargs)

    return generic_gradient_magnitude(input, derivative, output, mode,
                                      cval, extra_arguments=(sigma,),
                                      extra_keywords=kwargs)


def _correlate_or_convolve(input, weights, output, mode, cval, origin,
                           convolution):
    input = numpy.asarray(input)
    weights = numpy.asarray(weights)
    complex_input = input.dtype.kind == 'c'
    complex_weights = weights.dtype.kind == 'c'
    if complex_input or complex_weights:
        if complex_weights and not convolution:
            # As for numpy.correlate, conjugate weights rather than input.
            weights = weights.conj()
        kwargs = dict(
            mode=mode, origin=origin, convolution=convolution
        )
        output = _ni_support._get_output(output, input, complex_output=True)

        return _complex_via_real_components(_correlate_or_convolve, input,
                                            weights, output, cval, **kwargs)

    origins = _ni_support._normalize_sequence(origin, input.ndim)
    weights = numpy.asarray(weights, dtype=numpy.float64)
    wshape = [ii for ii in weights.shape if ii > 0]
    if len(wshape) != input.ndim:
        raise RuntimeError('filter weights array has incorrect shape.')
    if convolution:
        weights = weights[tuple([slice(None, None, -1)] * weights.ndim)]
        for ii in range(len(origins)):
            origins[ii] = -origins[ii]
            if not weights.shape[ii] & 1:
                origins[ii] -= 1
    for origin, lenw in zip(origins, wshape):
        if _invalid_origin(origin, lenw):
            raise ValueError('Invalid origin; origin must satisfy '
                             '-(weights.shape[k] // 2) <= origin[k] <= '
                             '(weights.shape[k]-1) // 2')

    if not weights.flags.contiguous:
        weights = weights.copy()
    output = _ni_support._get_output(output, input)
    temp_needed = numpy.may_share_memory(input, output)
    if temp_needed:
        # input and output arrays cannot share memory
        temp = output
        output = _ni_support._get_output(output.dtype, input)
    if not isinstance(mode, str) and isinstance(mode, Iterable):
        raise RuntimeError("A sequence of modes is not supported")
    mode = _ni_support._extend_mode_to_code(mode)
    _nd_image.correlate(input, weights, output, mode, cval, origins)
    if temp_needed:
        temp[...] = output
        output = temp
    return output


@_ni_docstrings.docfiller
def correlate(input, weights, output=None, mode='reflect', cval=0.0,
              origin=0):
    """
    Multidimensional correlation.

    The array is correlated with the given kernel.

    Parameters
    ----------
    %(input)s
    weights : ndarray
        array of weights, same number of dimensions as input
    %(output)s
    %(mode_reflect)s
    %(cval)s
    %(origin_multiple)s

    Returns
    -------
    result : ndarray
        The result of correlation of `input` with `weights`.

    See Also
    --------
    convolve : Convolve an image with a kernel.

    Examples
    --------
    Correlation is the process of moving a filter mask often referred to
    as kernel over the image and computing the sum of products at each location.

    >>> from scipy.ndimage import correlate
    >>> import numpy as np
    >>> input_img = np.arange(25).reshape(5,5)
    >>> print(input_img)
    [[ 0  1  2  3  4]
    [ 5  6  7  8  9]
    [10 11 12 13 14]
    [15 16 17 18 19]
    [20 21 22 23 24]]

    Define a kernel (weights) for correlation. In this example, it is for sum of
    center and up, down, left and right next elements.

    >>> weights = [[0, 1, 0],
    ...            [1, 1, 1],
    ...            [0, 1, 0]]

    We can calculate a correlation result:
    For example, element ``[2,2]`` is ``7 + 11 + 12 + 13 + 17 = 60``.

    >>> correlate(input_img, weights)
    array([[  6,  10,  15,  20,  24],
        [ 26,  30,  35,  40,  44],
        [ 51,  55,  60,  65,  69],
        [ 76,  80,  85,  90,  94],
        [ 96, 100, 105, 110, 114]])

    """
    return _correlate_or_convolve(input, weights, output, mode, cval,
                                  origin, False)


@_ni_docstrings.docfiller
def convolve(input, weights, output=None, mode='reflect', cval=0.0,
             origin=0):
    """
    Multidimensional convolution.

    The array is convolved with the given kernel.

    Parameters
    ----------
    %(input)s
    weights : array_like
        Array of weights, same number of dimensions as input
    %(output)s
    %(mode_reflect)s
    cval : scalar, optional
        Value to fill past edges of input if `mode` is 'constant'. Default
        is 0.0
    origin : int, optional
        Controls the origin of the input signal, which is where the
        filter is centered to produce the first element of the output.
        Positive values shift the filter to the right, and negative values
        shift the filter to the left. Default is 0.

    Returns
    -------
    result : ndarray
        The result of convolution of `input` with `weights`.

    See Also
    --------
    correlate : Correlate an image with a kernel.

    Notes
    -----
    Each value in result is :math:`C_i = \\sum_j{I_{i+k-j} W_j}`, where
    W is the `weights` kernel,
    j is the N-D spatial index over :math:`W`,
    I is the `input` and k is the coordinate of the center of
    W, specified by `origin` in the input parameters.

    Examples
    --------
    Perhaps the simplest case to understand is ``mode='constant', cval=0.0``,
    because in this case borders (i.e., where the `weights` kernel, centered
    on any one value, extends beyond an edge of `input`) are treated as zeros.

    >>> import numpy as np
    >>> a = np.array([[1, 2, 0, 0],
    ...               [5, 3, 0, 4],
    ...               [0, 0, 0, 7],
    ...               [9, 3, 0, 0]])
    >>> k = np.array([[1,1,1],[1,1,0],[1,0,0]])
    >>> from scipy import ndimage
    >>> ndimage.convolve(a, k, mode='constant', cval=0.0)
    array([[11, 10,  7,  4],
           [10,  3, 11, 11],
           [15, 12, 14,  7],
           [12,  3,  7,  0]])

    Setting ``cval=1.0`` is equivalent to padding the outer edge of `input`
    with 1.0's (and then extracting only the original region of the result).

    >>> ndimage.convolve(a, k, mode='constant', cval=1.0)
    array([[13, 11,  8,  7],
           [11,  3, 11, 14],
           [16, 12, 14, 10],
           [15,  6, 10,  5]])

    With ``mode='reflect'`` (the default), outer values are reflected at the
    edge of `input` to fill in missing values.

    >>> b = np.array([[2, 0, 0],
    ...               [1, 0, 0],
    ...               [0, 0, 0]])
    >>> k = np.array([[0,1,0], [0,1,0], [0,1,0]])
    >>> ndimage.convolve(b, k, mode='reflect')
    array([[5, 0, 0],
           [3, 0, 0],
           [1, 0, 0]])

    This includes diagonally at the corners.

    >>> k = np.array([[1,0,0],[0,1,0],[0,0,1]])
    >>> ndimage.convolve(b, k)
    array([[4, 2, 0],
           [3, 2, 0],
           [1, 1, 0]])

    With ``mode='nearest'``, the single nearest value in to an edge in
    `input` is repeated as many times as needed to match the overlapping
    `weights`.

    >>> c = np.array([[2, 0, 1],
    ...               [1, 0, 0],
    ...               [0, 0, 0]])
    >>> k = np.array([[0, 1, 0],
    ...               [0, 1, 0],
    ...               [0, 1, 0],
    ...               [0, 1, 0],
    ...               [0, 1, 0]])
    >>> ndimage.convolve(c, k, mode='nearest')
    array([[7, 0, 3],
           [5, 0, 2],
           [3, 0, 1]])

    """
    return _correlate_or_convolve(input, weights, output, mode, cval,
                                  origin, True)


[docs] @_ni_docstrings.docfiller def uniform_filter1d(input, size, axis=-1, output=None, mode="reflect", cval=0.0, origin=0): """Calculate a 1-D uniform filter along the given axis. The lines of the array along the given axis are filtered with a uniform filter of given size. Parameters ---------- %(input)s size : int length of uniform filter %(axis)s %(output)s %(mode_reflect)s %(cval)s %(origin)s Examples -------- >>> from scipy.ndimage import uniform_filter1d >>> uniform_filter1d([2, 8, 0, 4, 1, 9, 9, 0], size=3) array([4, 3, 4, 1, 4, 6, 6, 3]) """ input = numpy.asarray(input) axis = normalize_axis_index(axis, input.ndim) if size < 1: raise RuntimeError('incorrect filter size') complex_output = input.dtype.kind == 'c' output = _ni_support._get_output(output, input, complex_output=complex_output) if (size // 2 + origin < 0) or (size // 2 + origin >= size): raise ValueError('invalid origin') mode = _ni_support._extend_mode_to_code(mode) if not complex_output: _nd_image.uniform_filter1d(input, size, axis, output, mode, cval, origin) else: _nd_image.uniform_filter1d(input.real, size, axis, output.real, mode, numpy.real(cval), origin) _nd_image.uniform_filter1d(input.imag, size, axis, output.imag, mode, numpy.imag(cval), origin) return output
[docs] @_ni_docstrings.docfiller def uniform_filter(input, size=3, output=None, mode="reflect", cval=0.0, origin=0, *, axes=None): """Multidimensional uniform filter. Parameters ---------- %(input)s size : int or sequence of ints, optional The sizes of the uniform filter are given for each axis as a sequence, or as a single number, in which case the size is equal for all axes. %(output)s %(mode_multiple)s %(cval)s %(origin_multiple)s axes : tuple of int or None, optional If None, `input` is filtered along all axes. Otherwise, `input` is filtered along the specified axes. When `axes` is specified, any tuples used for `size`, `origin`, and/or `mode` must match the length of `axes`. The ith entry in any of these tuples corresponds to the ith entry in `axes`. Returns ------- uniform_filter : ndarray Filtered array. Has the same shape as `input`. Notes ----- The multidimensional filter is implemented as a sequence of 1-D uniform filters. The intermediate arrays are stored in the same data type as the output. Therefore, for output types with a limited precision, the results may be imprecise because intermediate results may be stored with insufficient precision. Examples -------- >>> from scipy import ndimage, datasets >>> import matplotlib.pyplot as plt >>> fig = plt.figure() >>> plt.gray() # show the filtered result in grayscale >>> ax1 = fig.add_subplot(121) # left side >>> ax2 = fig.add_subplot(122) # right side >>> ascent = datasets.ascent() >>> result = ndimage.uniform_filter(ascent, size=20) >>> ax1.imshow(ascent) >>> ax2.imshow(result) >>> plt.show() """ input = numpy.asarray(input) output = _ni_support._get_output(output, input, complex_output=input.dtype.kind == 'c') axes = _ni_support._check_axes(axes, input.ndim) num_axes = len(axes) sizes = _ni_support._normalize_sequence(size, num_axes) origins = _ni_support._normalize_sequence(origin, num_axes) modes = _ni_support._normalize_sequence(mode, num_axes) axes = [(axes[ii], sizes[ii], origins[ii], modes[ii]) for ii in range(num_axes) if sizes[ii] > 1] if len(axes) > 0: for axis, size, origin, mode in axes: uniform_filter1d(input, int(size), axis, output, mode, cval, origin) input = output else: output[...] = input[...] return output
@_ni_docstrings.docfiller def minimum_filter1d(input, size, axis=-1, output=None, mode="reflect", cval=0.0, origin=0): """Calculate a 1-D minimum filter along the given axis. The lines of the array along the given axis are filtered with a minimum filter of given size. Parameters ---------- %(input)s size : int length along which to calculate 1D minimum %(axis)s %(output)s %(mode_reflect)s %(cval)s %(origin)s Notes ----- This function implements the MINLIST algorithm [1]_, as described by Richard Harter [2]_, and has a guaranteed O(n) performance, `n` being the `input` length, regardless of filter size. References ---------- .. [1] http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.42.2777 .. [2] http://www.richardhartersworld.com/cri/2001/slidingmin.html Examples -------- >>> from scipy.ndimage import minimum_filter1d >>> minimum_filter1d([2, 8, 0, 4, 1, 9, 9, 0], size=3) array([2, 0, 0, 0, 1, 1, 0, 0]) """ input = numpy.asarray(input) if numpy.iscomplexobj(input): raise TypeError('Complex type not supported') axis = normalize_axis_index(axis, input.ndim) if size < 1: raise RuntimeError('incorrect filter size') output = _ni_support._get_output(output, input) if (size // 2 + origin < 0) or (size // 2 + origin >= size): raise ValueError('invalid origin') mode = _ni_support._extend_mode_to_code(mode) _nd_image.min_or_max_filter1d(input, size, axis, output, mode, cval, origin, 1) return output @_ni_docstrings.docfiller def maximum_filter1d(input, size, axis=-1, output=None, mode="reflect", cval=0.0, origin=0): """Calculate a 1-D maximum filter along the given axis. The lines of the array along the given axis are filtered with a maximum filter of given size. Parameters ---------- %(input)s size : int Length along which to calculate the 1-D maximum. %(axis)s %(output)s %(mode_reflect)s %(cval)s %(origin)s Returns ------- maximum1d : ndarray, None Maximum-filtered array with same shape as input. None if `output` is not None Notes ----- This function implements the MAXLIST algorithm [1]_, as described by Richard Harter [2]_, and has a guaranteed O(n) performance, `n` being the `input` length, regardless of filter size. References ---------- .. [1] http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.42.2777 .. [2] http://www.richardhartersworld.com/cri/2001/slidingmin.html Examples -------- >>> from scipy.ndimage import maximum_filter1d >>> maximum_filter1d([2, 8, 0, 4, 1, 9, 9, 0], size=3) array([8, 8, 8, 4, 9, 9, 9, 9]) """ input = numpy.asarray(input) if numpy.iscomplexobj(input): raise TypeError('Complex type not supported') axis = normalize_axis_index(axis, input.ndim) if size < 1: raise RuntimeError('incorrect filter size') output = _ni_support._get_output(output, input) if (size // 2 + origin < 0) or (size // 2 + origin >= size): raise ValueError('invalid origin') mode = _ni_support._extend_mode_to_code(mode) _nd_image.min_or_max_filter1d(input, size, axis, output, mode, cval, origin, 0) return output def _min_or_max_filter(input, size, footprint, structure, output, mode, cval, origin, minimum, axes=None): if (size is not None) and (footprint is not None): warnings.warn("ignoring size because footprint is set", UserWarning, stacklevel=3) if structure is None: if footprint is None: if size is None: raise RuntimeError("no footprint provided") separable = True else: footprint = numpy.asarray(footprint, dtype=bool) if not footprint.any(): raise ValueError("All-zero footprint is not supported.") if footprint.all(): size = footprint.shape footprint = None separable = True else: separable = False else: structure = numpy.asarray(structure, dtype=numpy.float64) separable = False if footprint is None: footprint = numpy.ones(structure.shape, bool) else: footprint = numpy.asarray(footprint, dtype=bool) input = numpy.asarray(input) if numpy.iscomplexobj(input): raise TypeError('Complex type not supported') output = _ni_support._get_output(output, input) temp_needed = numpy.may_share_memory(input, output) if temp_needed: # input and output arrays cannot share memory temp = output output = _ni_support._get_output(output.dtype, input) axes = _ni_support._check_axes(axes, input.ndim) num_axes = len(axes) if separable: origins = _ni_support._normalize_sequence(origin, num_axes) sizes = _ni_support._normalize_sequence(size, num_axes) modes = _ni_support._normalize_sequence(mode, num_axes) axes = [(axes[ii], sizes[ii], origins[ii], modes[ii]) for ii in range(len(axes)) if sizes[ii] > 1] if minimum: filter_ = minimum_filter1d else: filter_ = maximum_filter1d if len(axes) > 0: for axis, size, origin, mode in axes: filter_(input, int(size), axis, output, mode, cval, origin) input = output else: output[...] = input[...] else: origins = _ni_support._normalize_sequence(origin, input.ndim) if num_axes < input.ndim: if footprint.ndim != num_axes: raise RuntimeError("footprint array has incorrect shape") footprint = numpy.expand_dims( footprint, tuple(ax for ax in range(input.ndim) if ax not in axes) ) fshape = [ii for ii in footprint.shape if ii > 0] if len(fshape) != input.ndim: raise RuntimeError('footprint array has incorrect shape.') for origin, lenf in zip(origins, fshape): if (lenf // 2 + origin < 0) or (lenf // 2 + origin >= lenf): raise ValueError('invalid origin') if not footprint.flags.contiguous: footprint = footprint.copy() if structure is not None: if len(structure.shape) != input.ndim: raise RuntimeError('structure array has incorrect shape') if num_axes != structure.ndim: structure = numpy.expand_dims( structure, tuple(ax for ax in range(structure.ndim) if ax not in axes) ) if not structure.flags.contiguous: structure = structure.copy() if not isinstance(mode, str) and isinstance(mode, Iterable): raise RuntimeError( "A sequence of modes is not supported for non-separable " "footprints") mode = _ni_support._extend_mode_to_code(mode) _nd_image.min_or_max_filter(input, footprint, structure, output, mode, cval, origins, minimum) if temp_needed: temp[...] = output output = temp return output @_ni_docstrings.docfiller def minimum_filter(input, size=None, footprint=None, output=None, mode="reflect", cval=0.0, origin=0, *, axes=None): """Calculate a multidimensional minimum filter. Parameters ---------- %(input)s %(size_foot)s %(output)s %(mode_multiple)s %(cval)s %(origin_multiple)s axes : tuple of int or None, optional If None, `input` is filtered along all axes. Otherwise, `input` is filtered along the specified axes. When `axes` is specified, any tuples used for `size`, `origin`, and/or `mode` must match the length of `axes`. The ith entry in any of these tuples corresponds to the ith entry in `axes`. Returns ------- minimum_filter : ndarray Filtered array. Has the same shape as `input`. Notes ----- A sequence of modes (one per axis) is only supported when the footprint is separable. Otherwise, a single mode string must be provided. Examples -------- >>> from scipy import ndimage, datasets >>> import matplotlib.pyplot as plt >>> fig = plt.figure() >>> plt.gray() # show the filtered result in grayscale >>> ax1 = fig.add_subplot(121) # left side >>> ax2 = fig.add_subplot(122) # right side >>> ascent = datasets.ascent() >>> result = ndimage.minimum_filter(ascent, size=20) >>> ax1.imshow(ascent) >>> ax2.imshow(result) >>> plt.show() """ return _min_or_max_filter(input, size, footprint, None, output, mode, cval, origin, 1, axes) @_ni_docstrings.docfiller def maximum_filter(input, size=None, footprint=None, output=None, mode="reflect", cval=0.0, origin=0, *, axes=None): """Calculate a multidimensional maximum filter. Parameters ---------- %(input)s %(size_foot)s %(output)s %(mode_multiple)s %(cval)s %(origin_multiple)s axes : tuple of int or None, optional If None, `input` is filtered along all axes. Otherwise, `input` is filtered along the specified axes. When `axes` is specified, any tuples used for `size`, `origin`, and/or `mode` must match the length of `axes`. The ith entry in any of these tuples corresponds to the ith entry in `axes`. Returns ------- maximum_filter : ndarray Filtered array. Has the same shape as `input`. Notes ----- A sequence of modes (one per axis) is only supported when the footprint is separable. Otherwise, a single mode string must be provided. Examples -------- >>> from scipy import ndimage, datasets >>> import matplotlib.pyplot as plt >>> fig = plt.figure() >>> plt.gray() # show the filtered result in grayscale >>> ax1 = fig.add_subplot(121) # left side >>> ax2 = fig.add_subplot(122) # right side >>> ascent = datasets.ascent() >>> result = ndimage.maximum_filter(ascent, size=20) >>> ax1.imshow(ascent) >>> ax2.imshow(result) >>> plt.show() """ return _min_or_max_filter(input, size, footprint, None, output, mode, cval, origin, 0, axes) @_ni_docstrings.docfiller def _rank_filter(input, rank, size=None, footprint=None, output=None, mode="reflect", cval=0.0, origin=0, operation='rank', axes=None): if (size is not None) and (footprint is not None): warnings.warn("ignoring size because footprint is set", UserWarning, stacklevel=3) input = numpy.asarray(input) if numpy.iscomplexobj(input): raise TypeError('Complex type not supported') axes = _ni_support._check_axes(axes, input.ndim) num_axes = len(axes) origins = _ni_support._normalize_sequence(origin, num_axes) if footprint is None: if size is None: raise RuntimeError("no footprint or filter size provided") sizes = _ni_support._normalize_sequence(size, num_axes) footprint = numpy.ones(sizes, dtype=bool) else: footprint = numpy.asarray(footprint, dtype=bool) if num_axes < input.ndim: # set origin = 0 for any axes not being filtered origins_temp = [0,] * input.ndim for o, ax in zip(origins, axes): origins_temp[ax] = o origins = origins_temp if not isinstance(mode, str) and isinstance(mode, Iterable): # set mode = 'constant' for any axes not being filtered modes = _ni_support._normalize_sequence(mode, num_axes) modes_temp = ['constant'] * input.ndim for m, ax in zip(modes, axes): modes_temp[ax] = m mode = modes_temp # insert singleton dimension along any non-filtered axes if footprint.ndim != num_axes: raise RuntimeError("footprint array has incorrect shape") footprint = numpy.expand_dims( footprint, tuple(ax for ax in range(input.ndim) if ax not in axes) ) fshape = [ii for ii in footprint.shape if ii > 0] if len(fshape) != input.ndim: raise RuntimeError('footprint array has incorrect shape.') for origin, lenf in zip(origins, fshape): if (lenf // 2 + origin < 0) or (lenf // 2 + origin >= lenf): raise ValueError('invalid origin') if not footprint.flags.contiguous: footprint = footprint.copy() filter_size = numpy.where(footprint, 1, 0).sum() if operation == 'median': rank = filter_size // 2 elif operation == 'percentile': percentile = rank if percentile < 0.0: percentile += 100.0 if percentile < 0 or percentile > 100: raise RuntimeError('invalid percentile') if percentile == 100.0: rank = filter_size - 1 else: rank = int(float(filter_size) * percentile / 100.0) if rank < 0: rank += filter_size if rank < 0 or rank >= filter_size: raise RuntimeError('rank not within filter footprint size') if rank == 0: return minimum_filter(input, None, footprint, output, mode, cval, origins, axes=None) elif rank == filter_size - 1: return maximum_filter(input, None, footprint, output, mode, cval, origins, axes=None) else: output = _ni_support._get_output(output, input) temp_needed = numpy.may_share_memory(input, output) if temp_needed: # input and output arrays cannot share memory temp = output output = _ni_support._get_output(output.dtype, input) if not isinstance(mode, str) and isinstance(mode, Iterable): raise RuntimeError( "A sequence of modes is not supported by non-separable rank " "filters") mode = _ni_support._extend_mode_to_code(mode) _nd_image.rank_filter(input, rank, footprint, output, mode, cval, origins) if temp_needed: temp[...] = output output = temp return output @_ni_docstrings.docfiller def rank_filter(input, rank, size=None, footprint=None, output=None, mode="reflect", cval=0.0, origin=0, *, axes=None): """Calculate a multidimensional rank filter. Parameters ---------- %(input)s rank : int The rank parameter may be less than zero, i.e., rank = -1 indicates the largest element. %(size_foot)s %(output)s %(mode_reflect)s %(cval)s %(origin_multiple)s axes : tuple of int or None, optional If None, `input` is filtered along all axes. Otherwise, `input` is filtered along the specified axes. Returns ------- rank_filter : ndarray Filtered array. Has the same shape as `input`. Examples -------- >>> from scipy import ndimage, datasets >>> import matplotlib.pyplot as plt >>> fig = plt.figure() >>> plt.gray() # show the filtered result in grayscale >>> ax1 = fig.add_subplot(121) # left side >>> ax2 = fig.add_subplot(122) # right side >>> ascent = datasets.ascent() >>> result = ndimage.rank_filter(ascent, rank=42, size=20) >>> ax1.imshow(ascent) >>> ax2.imshow(result) >>> plt.show() """ rank = operator.index(rank) return _rank_filter(input, rank, size, footprint, output, mode, cval, origin, 'rank', axes=axes) @_ni_docstrings.docfiller def median_filter(input, size=None, footprint=None, output=None, mode="reflect", cval=0.0, origin=0, *, axes=None): """ Calculate a multidimensional median filter. Parameters ---------- %(input)s %(size_foot)s %(output)s %(mode_reflect)s %(cval)s %(origin_multiple)s axes : tuple of int or None, optional If None, `input` is filtered along all axes. Otherwise, `input` is filtered along the specified axes. Returns ------- median_filter : ndarray Filtered array. Has the same shape as `input`. See Also -------- scipy.signal.medfilt2d Notes ----- For 2-dimensional images with ``uint8``, ``float32`` or ``float64`` dtypes the specialised function `scipy.signal.medfilt2d` may be faster. It is however limited to constant mode with ``cval=0``. Examples -------- >>> from scipy import ndimage, datasets >>> import matplotlib.pyplot as plt >>> fig = plt.figure() >>> plt.gray() # show the filtered result in grayscale >>> ax1 = fig.add_subplot(121) # left side >>> ax2 = fig.add_subplot(122) # right side >>> ascent = datasets.ascent() >>> result = ndimage.median_filter(ascent, size=20) >>> ax1.imshow(ascent) >>> ax2.imshow(result) >>> plt.show() """ return _rank_filter(input, 0, size, footprint, output, mode, cval, origin, 'median', axes=axes) @_ni_docstrings.docfiller def percentile_filter(input, percentile, size=None, footprint=None, output=None, mode="reflect", cval=0.0, origin=0, *, axes=None): """Calculate a multidimensional percentile filter. Parameters ---------- %(input)s percentile : scalar The percentile parameter may be less than zero, i.e., percentile = -20 equals percentile = 80 %(size_foot)s %(output)s %(mode_reflect)s %(cval)s %(origin_multiple)s axes : tuple of int or None, optional If None, `input` is filtered along all axes. Otherwise, `input` is filtered along the specified axes. Returns ------- percentile_filter : ndarray Filtered array. Has the same shape as `input`. Examples -------- >>> from scipy import ndimage, datasets >>> import matplotlib.pyplot as plt >>> fig = plt.figure() >>> plt.gray() # show the filtered result in grayscale >>> ax1 = fig.add_subplot(121) # left side >>> ax2 = fig.add_subplot(122) # right side >>> ascent = datasets.ascent() >>> result = ndimage.percentile_filter(ascent, percentile=20, size=20) >>> ax1.imshow(ascent) >>> ax2.imshow(result) >>> plt.show() """ return _rank_filter(input, percentile, size, footprint, output, mode, cval, origin, 'percentile', axes=axes) @_ni_docstrings.docfiller def generic_filter1d(input, function, filter_size, axis=-1, output=None, mode="reflect", cval=0.0, origin=0, extra_arguments=(), extra_keywords=None): """Calculate a 1-D filter along the given axis. `generic_filter1d` iterates over the lines of the array, calling the given function at each line. The arguments of the line are the input line, and the output line. The input and output lines are 1-D double arrays. The input line is extended appropriately according to the filter size and origin. The output line must be modified in-place with the result. Parameters ---------- %(input)s function : {callable, scipy.LowLevelCallable} Function to apply along given axis. filter_size : scalar Length of the filter. %(axis)s %(output)s %(mode_reflect)s %(cval)s %(origin)s %(extra_arguments)s %(extra_keywords)s Notes ----- This function also accepts low-level callback functions with one of the following signatures and wrapped in `scipy.LowLevelCallable`: .. code:: c int function(double *input_line, npy_intp input_length, double *output_line, npy_intp output_length, void *user_data) int function(double *input_line, intptr_t input_length, double *output_line, intptr_t output_length, void *user_data) The calling function iterates over the lines of the input and output arrays, calling the callback function at each line. The current line is extended according to the border conditions set by the calling function, and the result is copied into the array that is passed through ``input_line``. The length of the input line (after extension) is passed through ``input_length``. The callback function should apply the filter and store the result in the array passed through ``output_line``. The length of the output line is passed through ``output_length``. ``user_data`` is the data pointer provided to `scipy.LowLevelCallable` as-is. The callback function must return an integer error status that is zero if something went wrong and one otherwise. If an error occurs, you should normally set the python error status with an informative message before returning, otherwise a default error message is set by the calling function. In addition, some other low-level function pointer specifications are accepted, but these are for backward compatibility only and should not be used in new code. """ if extra_keywords is None: extra_keywords = {} input = numpy.asarray(input) if numpy.iscomplexobj(input): raise TypeError('Complex type not supported') output = _ni_support._get_output(output, input) if filter_size < 1: raise RuntimeError('invalid filter size') axis = normalize_axis_index(axis, input.ndim) if (filter_size // 2 + origin < 0) or (filter_size // 2 + origin >= filter_size): raise ValueError('invalid origin') mode = _ni_support._extend_mode_to_code(mode) _nd_image.generic_filter1d(input, function, filter_size, axis, output, mode, cval, origin, extra_arguments, extra_keywords) return output @_ni_docstrings.docfiller def generic_filter(input, function, size=None, footprint=None, output=None, mode="reflect", cval=0.0, origin=0, extra_arguments=(), extra_keywords=None): """Calculate a multidimensional filter using the given function. At each element the provided function is called. The input values within the filter footprint at that element are passed to the function as a 1-D array of double values. Parameters ---------- %(input)s function : {callable, scipy.LowLevelCallable} Function to apply at each element. %(size_foot)s %(output)s %(mode_reflect)s %(cval)s %(origin_multiple)s %(extra_arguments)s %(extra_keywords)s Notes ----- This function also accepts low-level callback functions with one of the following signatures and wrapped in `scipy.LowLevelCallable`: .. code:: c int callback(double *buffer, npy_intp filter_size, double *return_value, void *user_data) int callback(double *buffer, intptr_t filter_size, double *return_value, void *user_data) The calling function iterates over the elements of the input and output arrays, calling the callback function at each element. The elements within the footprint of the filter at the current element are passed through the ``buffer`` parameter, and the number of elements within the footprint through ``filter_size``. The calculated value is returned in ``return_value``. ``user_data`` is the data pointer provided to `scipy.LowLevelCallable` as-is. The callback function must return an integer error status that is zero if something went wrong and one otherwise. If an error occurs, you should normally set the python error status with an informative message before returning, otherwise a default error message is set by the calling function. In addition, some other low-level function pointer specifications are accepted, but these are for backward compatibility only and should not be used in new code. Examples -------- Import the necessary modules and load the example image used for filtering. >>> import numpy as np >>> from scipy import datasets >>> from scipy.ndimage import generic_filter >>> import matplotlib.pyplot as plt >>> ascent = datasets.ascent() Compute a maximum filter with kernel size 10 by passing a simple NumPy aggregation function as argument to `function`. >>> maximum_filter_result = generic_filter(ascent, np.amax, [10, 10]) While a maximmum filter could also directly be obtained using `maximum_filter`, `generic_filter` allows generic Python function or `scipy.LowLevelCallable` to be used as a filter. Here, we compute the range between maximum and minimum value as an example for a kernel size of 5. >>> def custom_filter(image): ... return np.amax(image) - np.amin(image) >>> custom_filter_result = generic_filter(ascent, custom_filter, [5, 5]) Plot the original and filtered images. >>> fig, axes = plt.subplots(3, 1, figsize=(4, 12)) >>> plt.gray() # show the filtered result in grayscale >>> top, middle, bottom = axes >>> for ax in axes: ... ax.set_axis_off() # remove coordinate system >>> top.imshow(ascent) >>> top.set_title("Original image") >>> middle.imshow(maximum_filter_result) >>> middle.set_title("Maximum filter, Kernel: 10x10") >>> bottom.imshow(custom_filter_result) >>> bottom.set_title("Custom filter, Kernel: 5x5") >>> fig.tight_layout() """ if (size is not None) and (footprint is not None): warnings.warn("ignoring size because footprint is set", UserWarning, stacklevel=2) if extra_keywords is None: extra_keywords = {} input = numpy.asarray(input) if numpy.iscomplexobj(input): raise TypeError('Complex type not supported') origins = _ni_support._normalize_sequence(origin, input.ndim) if footprint is None: if size is None: raise RuntimeError("no footprint or filter size provided") sizes = _ni_support._normalize_sequence(size, input.ndim) footprint = numpy.ones(sizes, dtype=bool) else: footprint = numpy.asarray(footprint, dtype=bool) fshape = [ii for ii in footprint.shape if ii > 0] if len(fshape) != input.ndim: raise RuntimeError('filter footprint array has incorrect shape.') for origin, lenf in zip(origins, fshape): if (lenf // 2 + origin < 0) or (lenf // 2 + origin >= lenf): raise ValueError('invalid origin') if not footprint.flags.contiguous: footprint = footprint.copy() output = _ni_support._get_output(output, input) mode = _ni_support._extend_mode_to_code(mode) _nd_image.generic_filter(input, function, footprint, output, mode, cval, origins, extra_arguments, extra_keywords) return output