Intelegentny_Pszczelarz/.venv/Lib/site-packages/scipy/stats/_rvs_sampling.py

# -*- coding: utf-8 -*-
import numpy as np
from scipy._lib._util import check_random_state


def rvs_ratio_uniforms(pdf, umax, vmin, vmax, size=1, c=0, random_state=None):
    """
    Generate random samples from a probability density function using the
    ratio-of-uniforms method.

    Parameters
    ----------
    pdf : callable
        A function with signature `pdf(x)` that is proportional to the
        probability density function of the distribution.
    umax : float
        The upper bound of the bounding rectangle in the u-direction.
    vmin : float
        The lower bound of the bounding rectangle in the v-direction.
    vmax : float
        The upper bound of the bounding rectangle in the v-direction.
    size : int or tuple of ints, optional
        Defining number of random variates (default is 1).
    c : float, optional.
        Shift parameter of ratio-of-uniforms method, see Notes. Default is 0.
    random_state : {None, int, `numpy.random.Generator`,
                    `numpy.random.RandomState`}, optional

        If `seed` is None (or `np.random`), the `numpy.random.RandomState`
        singleton is used.
        If `seed` is an int, a new ``RandomState`` instance is used,
        seeded with `seed`.
        If `seed` is already a ``Generator`` or ``RandomState`` instance then
        that instance is used.

    Returns
    -------
    rvs : ndarray
        The random variates distributed according to the probability
        distribution defined by the pdf.

    Notes
    -----
    Given a univariate probability density function `pdf` and a constant `c`,
    define the set ``A = {(u, v) : 0 < u <= sqrt(pdf(v/u + c))}``.
    If `(U, V)` is a random vector uniformly distributed over `A`,
    then `V/U + c` follows a distribution according to `pdf`.

    The above result (see [1]_, [2]_) can be used to sample random variables
    using only the pdf, i.e. no inversion of the cdf is required. Typical
    choices of `c` are zero or the mode of `pdf`. The set `A` is a subset of
    the rectangle ``R = [0, umax] x [vmin, vmax]`` where

    - ``umax = sup sqrt(pdf(x))``
    - ``vmin = inf (x - c) sqrt(pdf(x))``
    - ``vmax = sup (x - c) sqrt(pdf(x))``

    In particular, these values are finite if `pdf` is bounded and
    ``x**2 * pdf(x)`` is bounded (i.e. subquadratic tails).
    One can generate `(U, V)` uniformly on `R` and return
    `V/U + c` if `(U, V)` are also in `A` which can be directly
    verified.

    The algorithm is not changed if one replaces `pdf` by k * `pdf` for any
    constant k > 0. Thus, it is often convenient to work with a function
    that is proportional to the probability density function by dropping
    unneccessary normalization factors.

    Intuitively, the method works well if `A` fills up most of the
    enclosing rectangle such that the probability is high that `(U, V)`
    lies in `A` whenever it lies in `R` as the number of required
    iterations becomes too large otherwise. To be more precise, note that
    the expected number of iterations to draw `(U, V)` uniformly
    distributed on `R` such that `(U, V)` is also in `A` is given by
    the ratio ``area(R) / area(A) = 2 * umax * (vmax - vmin) / area(pdf)``,
    where `area(pdf)` is the integral of `pdf` (which is equal to one if the
    probability density function is used but can take on other values if a
    function proportional to the density is used). The equality holds since
    the area of `A` is equal to 0.5 * area(pdf) (Theorem 7.1 in [1]_).
    If the sampling fails to generate a single random variate after 50000
    iterations (i.e. not a single draw is in `A`), an exception is raised.

    If the bounding rectangle is not correctly specified (i.e. if it does not
    contain `A`), the algorithm samples from a distribution different from
    the one given by `pdf`. It is therefore recommended to perform a
    test such as `~scipy.stats.kstest` as a check.

    References
    ----------
    .. [1] L. Devroye, "Non-Uniform Random Variate Generation",
       Springer-Verlag, 1986.

    .. [2] W. Hoermann and J. Leydold, "Generating generalized inverse Gaussian
       random variates", Statistics and Computing, 24(4), p. 547--557, 2014.

    .. [3] A.J. Kinderman and J.F. Monahan, "Computer Generation of Random
       Variables Using the Ratio of Uniform Deviates",
       ACM Transactions on Mathematical Software, 3(3), p. 257--260, 1977.

    Examples
    --------
    >>> import numpy as np
    >>> from scipy import stats
    >>> rng = np.random.default_rng()

    Simulate normally distributed random variables. It is easy to compute the
    bounding rectangle explicitly in that case. For simplicity, we drop the
    normalization factor of the density.

    >>> f = lambda x: np.exp(-x**2 / 2)
    >>> v_bound = np.sqrt(f(np.sqrt(2))) * np.sqrt(2)
    >>> umax, vmin, vmax = np.sqrt(f(0)), -v_bound, v_bound
    >>> rvs = stats.rvs_ratio_uniforms(f, umax, vmin, vmax, size=2500,
    ...                                random_state=rng)

    The K-S test confirms that the random variates are indeed normally
    distributed (normality is not rejected at 5% significance level):

    >>> stats.kstest(rvs, 'norm')[1]
    0.250634764150542

    The exponential distribution provides another example where the bounding
    rectangle can be determined explicitly.

    >>> rvs = stats.rvs_ratio_uniforms(lambda x: np.exp(-x), umax=1,
    ...                                vmin=0, vmax=2*np.exp(-1), size=1000,
    ...                                random_state=rng)
    >>> stats.kstest(rvs, 'expon')[1]
    0.21121052054580314

    """
    if vmin >= vmax:
        raise ValueError("vmin must be smaller than vmax.")

    if umax <= 0:
        raise ValueError("umax must be positive.")

    size1d = tuple(np.atleast_1d(size))
    N = np.prod(size1d)  # number of rvs needed, reshape upon return

    # start sampling using ratio of uniforms method
    rng = check_random_state(random_state)
    x = np.zeros(N)
    simulated, i = 0, 1

    # loop until N rvs have been generated: expected runtime is finite.
    # to avoid infinite loop, raise exception if not a single rv has been
    # generated after 50000 tries. even if the expected numer of iterations
    # is 1000, the probability of this event is (1-1/1000)**50000
    # which is of order 10e-22
    while simulated < N:
        k = N - simulated
        # simulate uniform rvs on [0, umax] and [vmin, vmax]
        u1 = umax * rng.uniform(size=k)
        v1 = rng.uniform(vmin, vmax, size=k)
        # apply rejection method
        rvs = v1 / u1 + c
        accept = (u1**2 <= pdf(rvs))
        num_accept = np.sum(accept)
        if num_accept > 0:
            x[simulated:(simulated + num_accept)] = rvs[accept]
            simulated += num_accept

        if (simulated == 0) and (i*N >= 50000):
            msg = ("Not a single random variate could be generated in {} "
                   "attempts. The ratio of uniforms method does not appear "
                   "to work for the provided parameters. Please check the "
                   "pdf and the bounds.".format(i*N))
            raise RuntimeError(msg)
        i += 1

    return np.reshape(x, size1d)
feature: "ANN commit 2" 2023-06-19 00:49:18 +02:00			`# -- coding: utf-8 --`
			`import numpy as np`
			`from scipy._lib._util import check_random_state`


			`def rvs_ratio_uniforms(pdf, umax, vmin, vmax, size=1, c=0, random_state=None):`
			`"""`
			`Generate random samples from a probability density function using the`
			`ratio-of-uniforms method.`

			`Parameters`
			`----------`
			`pdf : callable`
			A function with signature `pdf(x)` that is proportional to the
			`probability density function of the distribution.`
			`umax : float`
			`The upper bound of the bounding rectangle in the u-direction.`
			`vmin : float`
			`The lower bound of the bounding rectangle in the v-direction.`
			`vmax : float`
			`The upper bound of the bounding rectangle in the v-direction.`
			`size : int or tuple of ints, optional`
			`Defining number of random variates (default is 1).`
			`c : float, optional.`
			`Shift parameter of ratio-of-uniforms method, see Notes. Default is 0.`
			random_state : {None, int, `numpy.random.Generator`,
			`numpy.random.RandomState`}, optional

			If `seed` is None (or `np.random`), the `numpy.random.RandomState`
			`singleton is used.`
			If `seed` is an int, a new ``RandomState`` instance is used,
			seeded with `seed`.
			If `seed` is already a ``Generator`` or ``RandomState`` instance then
			`that instance is used.`

			`Returns`
			`-------`
			`rvs : ndarray`
			`The random variates distributed according to the probability`
			`distribution defined by the pdf.`

			`Notes`
			`-----`
			Given a univariate probability density function `pdf` and a constant `c`,
			define the set ``A = {(u, v) : 0 < u <= sqrt(pdf(v/u + c))}``.
			If `(U, V)` is a random vector uniformly distributed over `A`,
			then `V/U + c` follows a distribution according to `pdf`.

			`The above result (see [1]_, [2]_) can be used to sample random variables`
			`using only the pdf, i.e. no inversion of the cdf is required. Typical`
			choices of `c` are zero or the mode of `pdf`. The set `A` is a subset of
			the rectangle ``R = [0, umax] x [vmin, vmax]`` where

			- ``umax = sup sqrt(pdf(x))``
			- ``vmin = inf (x - c) sqrt(pdf(x))``
			- ``vmax = sup (x - c) sqrt(pdf(x))``

			In particular, these values are finite if `pdf` is bounded and
			``x*2 pdf(x)`` is bounded (i.e. subquadratic tails).
			One can generate `(U, V)` uniformly on `R` and return
			`V/U + c` if `(U, V)` are also in `A` which can be directly
			`verified.`

			The algorithm is not changed if one replaces `pdf` by k * `pdf` for any
			`constant k > 0. Thus, it is often convenient to work with a function`
			`that is proportional to the probability density function by dropping`
			`unneccessary normalization factors.`

			Intuitively, the method works well if `A` fills up most of the
			enclosing rectangle such that the probability is high that `(U, V)`
			lies in `A` whenever it lies in `R` as the number of required
			`iterations becomes too large otherwise. To be more precise, note that`
			the expected number of iterations to draw `(U, V)` uniformly
			distributed on `R` such that `(U, V)` is also in `A` is given by
			the ratio ``area(R) / area(A) = 2 * umax * (vmax - vmin) / area(pdf)``,
			where `area(pdf)` is the integral of `pdf` (which is equal to one if the
			`probability density function is used but can take on other values if a`
			`function proportional to the density is used). The equality holds since`
			the area of `A` is equal to 0.5 * area(pdf) (Theorem 7.1 in [1]_).
			`If the sampling fails to generate a single random variate after 50000`
			iterations (i.e. not a single draw is in `A`), an exception is raised.

			`If the bounding rectangle is not correctly specified (i.e. if it does not`
			contain `A`), the algorithm samples from a distribution different from
			the one given by `pdf`. It is therefore recommended to perform a
			test such as `~scipy.stats.kstest` as a check.

			`References`
			`----------`
			`.. [1] L. Devroye, "Non-Uniform Random Variate Generation",`
			`Springer-Verlag, 1986.`

			`.. [2] W. Hoermann and J. Leydold, "Generating generalized inverse Gaussian`
			`random variates", Statistics and Computing, 24(4), p. 547--557, 2014.`

			`.. [3] A.J. Kinderman and J.F. Monahan, "Computer Generation of Random`
			`Variables Using the Ratio of Uniform Deviates",`
			`ACM Transactions on Mathematical Software, 3(3), p. 257--260, 1977.`

			`Examples`
			`--------`
			`>>> import numpy as np`
			`>>> from scipy import stats`
			`>>> rng = np.random.default_rng()`

			`Simulate normally distributed random variables. It is easy to compute the`
			`bounding rectangle explicitly in that case. For simplicity, we drop the`
			`normalization factor of the density.`

			`>>> f = lambda x: np.exp(-x**2 / 2)`
			`>>> v_bound = np.sqrt(f(np.sqrt(2))) * np.sqrt(2)`
			`>>> umax, vmin, vmax = np.sqrt(f(0)), -v_bound, v_bound`
			`>>> rvs = stats.rvs_ratio_uniforms(f, umax, vmin, vmax, size=2500,`
			`... random_state=rng)`

			`The K-S test confirms that the random variates are indeed normally`
			`distributed (normality is not rejected at 5% significance level):`

			`>>> stats.kstest(rvs, 'norm')[1]`
			`0.250634764150542`

			`The exponential distribution provides another example where the bounding`
			`rectangle can be determined explicitly.`

			`>>> rvs = stats.rvs_ratio_uniforms(lambda x: np.exp(-x), umax=1,`
			`... vmin=0, vmax=2*np.exp(-1), size=1000,`
			`... random_state=rng)`
			`>>> stats.kstest(rvs, 'expon')[1]`
			`0.21121052054580314`

			`"""`
			`if vmin >= vmax:`
			`raise ValueError("vmin must be smaller than vmax.")`

			`if umax <= 0:`
			`raise ValueError("umax must be positive.")`

			`size1d = tuple(np.atleast_1d(size))`
			`N = np.prod(size1d) # number of rvs needed, reshape upon return`

			`# start sampling using ratio of uniforms method`
			`rng = check_random_state(random_state)`
			`x = np.zeros(N)`
			`simulated, i = 0, 1`

			`# loop until N rvs have been generated: expected runtime is finite.`
			`# to avoid infinite loop, raise exception if not a single rv has been`
			`# generated after 50000 tries. even if the expected numer of iterations`
			`# is 1000, the probability of this event is (1-1/1000)**50000`
			`# which is of order 10e-22`
			`while simulated < N:`
			`k = N - simulated`
			`# simulate uniform rvs on [0, umax] and [vmin, vmax]`
			`u1 = umax * rng.uniform(size=k)`
			`v1 = rng.uniform(vmin, vmax, size=k)`
			`# apply rejection method`
			`rvs = v1 / u1 + c`
			`accept = (u1**2 <= pdf(rvs))`
			`num_accept = np.sum(accept)`
			`if num_accept > 0:`
			`x[simulated:(simulated + num_accept)] = rvs[accept]`
			`simulated += num_accept`

			`if (simulated == 0) and (i*N >= 50000):`
			`msg = ("Not a single random variate could be generated in {} "`
			`"attempts. The ratio of uniforms method does not appear "`
			`"to work for the provided parameters. Please check the "`
			`"pdf and the bounds.".format(i*N))`
			`raise RuntimeError(msg)`
			`i += 1`

			`return np.reshape(x, size1d)`