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Edit File: scimath.cpython-38.pyc
U �p�]�9 � @ sP d Z ddlmZmZmZ ddlm mZ ddl m m Z ddlmZm Z ddlmZ ddlmZ ddd d ddd ddg Ze�d�Zdd� Zdd� Zdd� Zdd� Zdd� Zee�dd� �Zee�dd� �Zee�dd� �Zdd� Zee�d d � �Zee�d!d � �Zd"d#� Zee�d$d� �Z ee�d%d � �Z!ee�d&d� �Z"ee�d'd� �Z#dS )(aD Wrapper functions to more user-friendly calling of certain math functions whose output data-type is different than the input data-type in certain domains of the input. For example, for functions like `log` with branch cuts, the versions in this module provide the mathematically valid answers in the complex plane:: >>> import math >>> from numpy.lib import scimath >>> scimath.log(-math.exp(1)) == (1+1j*math.pi) True Similarly, `sqrt`, other base logarithms, `power` and trig functions are correctly handled. See their respective docstrings for specific examples. � )�division�absolute_import�print_functionN)�asarray�any)�array_function_dispatch)�isreal�sqrt�log�log2�logn�log10�power�arccos�arcsin�arctanhg @c C sB t | jjtjtjtjtjtjtj f�r2| � tj �S | � tj�S dS )a_ Convert its input `arr` to a complex array. The input is returned as a complex array of the smallest type that will fit the original data: types like single, byte, short, etc. become csingle, while others become cdouble. A copy of the input is always made. Parameters ---------- arr : array Returns ------- array An array with the same input data as the input but in complex form. Examples -------- First, consider an input of type short: >>> a = np.array([1,2,3],np.short) >>> ac = np.lib.scimath._tocomplex(a); ac array([1.+0.j, 2.+0.j, 3.+0.j], dtype=complex64) >>> ac.dtype dtype('complex64') If the input is of type double, the output is correspondingly of the complex double type as well: >>> b = np.array([1,2,3],np.double) >>> bc = np.lib.scimath._tocomplex(b); bc array([1.+0.j, 2.+0.j, 3.+0.j]) >>> bc.dtype dtype('complex128') Note that even if the input was complex to begin with, a copy is still made, since the astype() method always copies: >>> c = np.array([1,2,3],np.csingle) >>> cc = np.lib.scimath._tocomplex(c); cc array([1.+0.j, 2.+0.j, 3.+0.j], dtype=complex64) >>> c *= 2; c array([2.+0.j, 4.+0.j, 6.+0.j], dtype=complex64) >>> cc array([1.+0.j, 2.+0.j, 3.+0.j], dtype=complex64) N)� issubclassZdtype�type�ntZsingleZbyteZshortZubyteZushortZcsingleZastypeZcdouble)Zarr� r �3/usr/lib/python3/dist-packages/numpy/lib/scimath.py� _tocomplex$ s 8 �r c C s( t | �} tt| �| dk @ �r$t| �} | S )a� Convert `x` to complex if it has real, negative components. Otherwise, output is just the array version of the input (via asarray). Parameters ---------- x : array_like Returns ------- array Examples -------- >>> np.lib.scimath._fix_real_lt_zero([1,2]) array([1, 2]) >>> np.lib.scimath._fix_real_lt_zero([-1,2]) array([-1.+0.j, 2.+0.j]) r )r r r r ��xr r r �_fix_real_lt_zeroc s r c C s( t | �} tt| �| dk @ �r$| d } | S )a� Convert `x` to double if it has real, negative components. Otherwise, output is just the array version of the input (via asarray). Parameters ---------- x : array_like Returns ------- array Examples -------- >>> np.lib.scimath._fix_int_lt_zero([1,2]) array([1, 2]) >>> np.lib.scimath._fix_int_lt_zero([-1,2]) array([-1., 2.]) r g �?)r r r r r r r �_fix_int_lt_zero s r c C s, t | �} tt| �t| �dk@ �r(t| �} | S )a� Convert `x` to complex if it has real components x_i with abs(x_i)>1. Otherwise, output is just the array version of the input (via asarray). Parameters ---------- x : array_like Returns ------- array Examples -------- >>> np.lib.scimath._fix_real_abs_gt_1([0,1]) array([0, 1]) >>> np.lib.scimath._fix_real_abs_gt_1([0,2]) array([0.+0.j, 2.+0.j]) � )r r r �absr r r r r �_fix_real_abs_gt_1� s r c C s | fS �Nr r r r r �_unary_dispatcher� s r c C s t | �} t�| �S )a Compute the square root of x. For negative input elements, a complex value is returned (unlike `numpy.sqrt` which returns NaN). Parameters ---------- x : array_like The input value(s). Returns ------- out : ndarray or scalar The square root of `x`. If `x` was a scalar, so is `out`, otherwise an array is returned. See Also -------- numpy.sqrt Examples -------- For real, non-negative inputs this works just like `numpy.sqrt`: >>> np.lib.scimath.sqrt(1) 1.0 >>> np.lib.scimath.sqrt([1, 4]) array([1., 2.]) But it automatically handles negative inputs: >>> np.lib.scimath.sqrt(-1) 1j >>> np.lib.scimath.sqrt([-1,4]) array([0.+1.j, 2.+0.j]) )r �nxr r r r r r � s (c C s t | �} t�| �S )a� Compute the natural logarithm of `x`. Return the "principal value" (for a description of this, see `numpy.log`) of :math:`log_e(x)`. For real `x > 0`, this is a real number (``log(0)`` returns ``-inf`` and ``log(np.inf)`` returns ``inf``). Otherwise, the complex principle value is returned. Parameters ---------- x : array_like The value(s) whose log is (are) required. Returns ------- out : ndarray or scalar The log of the `x` value(s). If `x` was a scalar, so is `out`, otherwise an array is returned. See Also -------- numpy.log Notes ----- For a log() that returns ``NAN`` when real `x < 0`, use `numpy.log` (note, however, that otherwise `numpy.log` and this `log` are identical, i.e., both return ``-inf`` for `x = 0`, ``inf`` for `x = inf`, and, notably, the complex principle value if ``x.imag != 0``). Examples -------- >>> np.emath.log(np.exp(1)) 1.0 Negative arguments are handled "correctly" (recall that ``exp(log(x)) == x`` does *not* hold for real ``x < 0``): >>> np.emath.log(-np.exp(1)) == (1 + np.pi * 1j) True �r r! r r r r r r � s ,c C s t | �} t�| �S )a� Compute the logarithm base 10 of `x`. Return the "principal value" (for a description of this, see `numpy.log10`) of :math:`log_{10}(x)`. For real `x > 0`, this is a real number (``log10(0)`` returns ``-inf`` and ``log10(np.inf)`` returns ``inf``). Otherwise, the complex principle value is returned. Parameters ---------- x : array_like or scalar The value(s) whose log base 10 is (are) required. Returns ------- out : ndarray or scalar The log base 10 of the `x` value(s). If `x` was a scalar, so is `out`, otherwise an array object is returned. See Also -------- numpy.log10 Notes ----- For a log10() that returns ``NAN`` when real `x < 0`, use `numpy.log10` (note, however, that otherwise `numpy.log10` and this `log10` are identical, i.e., both return ``-inf`` for `x = 0`, ``inf`` for `x = inf`, and, notably, the complex principle value if ``x.imag != 0``). Examples -------- (We set the printing precision so the example can be auto-tested) >>> np.set_printoptions(precision=4) >>> np.emath.log10(10**1) 1.0 >>> np.emath.log10([-10**1, -10**2, 10**2]) array([1.+1.3644j, 2.+1.3644j, 2.+0.j ]) )r r! r r r r r r s .c C s | |fS r r ��nr r r r �_logn_dispatcherG s r% c C s$ t |�}t | �} t�|�t�| � S )a� Take log base n of x. If `x` contains negative inputs, the answer is computed and returned in the complex domain. Parameters ---------- n : array_like The integer base(s) in which the log is taken. x : array_like The value(s) whose log base `n` is (are) required. Returns ------- out : ndarray or scalar The log base `n` of the `x` value(s). If `x` was a scalar, so is `out`, otherwise an array is returned. Examples -------- >>> np.set_printoptions(precision=4) >>> np.lib.scimath.logn(2, [4, 8]) array([2., 3.]) >>> np.lib.scimath.logn(2, [-4, -8, 8]) array([2.+4.5324j, 3.+4.5324j, 3.+0.j ]) r"