Sam Chaudry

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	import pytest

	import numpy as np

	from scipy.optimize._bracket import _ELIMITS
	from scipy.optimize.elementwise import bracket_root, bracket_minimum
	import scipy._lib._elementwise_iterative_method as eim
	from scipy import stats
	from scipy._lib._array_api_no_0d import (xp_assert_close, xp_assert_equal,
	xp_assert_less, array_namespace)
	from scipy._lib._array_api import xp_ravel
	from scipy.conftest import array_api_compatible


	# These tests were originally written for the private `optimize._bracket`
	# interfaces, but now we want the tests to check the behavior of the public
	# `optimize.elementwise` interfaces. Therefore, rather than importing
	# `_bracket_root`/`_bracket_minimum` from `_bracket.py`, we import
	# `bracket_root`/`bracket_minimum` from `optimize.elementwise` and wrap those
	# functions to conform to the private interface. This may look a little strange,
	# since it effectively just inverts the interface transformation done within the
	# `bracket_root`/`bracket_minimum` functions, but it allows us to run the original,
	# unmodified tests on the public interfaces, simplifying the PR that adds
	# the public interfaces. We'll refactor this when we want to @parametrize the
	# tests over multiple `method`s.
	def _bracket_root(args, *kwargs):
	res = bracket_root(args, *kwargs)
	res.xl, res.xr = res.bracket
	res.fl, res.fr = res.f_bracket
	del res.bracket
	del res.f_bracket
	return res


	def _bracket_minimum(args, *kwargs):
	res = bracket_minimum(args, *kwargs)
	res.xl, res.xm, res.xr = res.bracket
	res.fl, res.fm, res.fr = res.f_bracket
	del res.bracket
	del res.f_bracket
	return res


	array_api_strict_skip_reason = 'Array API does not support fancy indexing assignment.'
	jax_skip_reason = 'JAX arrays do not support item assignment.'

	@pytest.mark.skip_xp_backends('array_api_strict', reason=array_api_strict_skip_reason)
	@pytest.mark.skip_xp_backends('jax.numpy', reason=jax_skip_reason)
	@array_api_compatible
	@pytest.mark.usefixtures("skip_xp_backends")
	class TestBracketRoot:
	@pytest.mark.parametrize("seed", (615655101, 3141866013, 238075752))
	@pytest.mark.parametrize("use_xmin", (False, True))
	@pytest.mark.parametrize("other_side", (False, True))
	@pytest.mark.parametrize("fix_one_side", (False, True))
	def test_nfev_expected(self, seed, use_xmin, other_side, fix_one_side, xp):
	# Property-based test to confirm that _bracket_root is behaving as
	# expected. The basic case is when root < a < b.
	# The number of times bracket expands (per side) can be found by
	# setting the expression for the left endpoint of the bracket to the
	# root of f (x=0), solving for i, and rounding up. The corresponding
	# lower and upper ends of the bracket are found by plugging this back
	# into the expression for the ends of the bracket.
	# `other_side=True` is the case that a < b < root
	# Special cases like a < root < b are tested separately
	rng = np.random.default_rng(seed)
	xl0, d, factor = xp.asarray(rng.random(size=3) * [1e5, 10, 5])
	factor = 1 + factor # factor must be greater than 1
	xr0 = xl0 + d # xr0 must be greater than a in basic case

	def f(x):
	f.count += 1
	return x # root is 0

	if use_xmin:
	xmin = xp.asarray(-rng.random())
	n = xp.ceil(xp.log(-(xl0 - xmin) / xmin) / xp.log(factor))
	l, u = xmin + (xl0 - xmin)factor-n, xmin + (xl0 - xmin)factor**-(n - 1)
	kwargs = dict(xl0=xl0, xr0=xr0, factor=factor, xmin=xmin)
	else:
	n = xp.ceil(xp.log(xr0/d) / xp.log(factor))
	l, u = xr0 - dfactorn, xr0 - dfactor**(n-1)
	kwargs = dict(xl0=xl0, xr0=xr0, factor=factor)

	if other_side:
	kwargs['xl0'], kwargs['xr0'] = -kwargs['xr0'], -kwargs['xl0']
	l, u = -u, -l
	if 'xmin' in kwargs:
	kwargs['xmax'] = -kwargs.pop('xmin')

	if fix_one_side:
	if other_side:
	kwargs['xmin'] = -xr0
	else:
	kwargs['xmax'] = xr0

	f.count = 0
	res = _bracket_root(f, **kwargs)

	# Compare reported number of function evaluations `nfev` against
	# reported `nit`, actual function call count `f.count`, and theoretical
	# number of expansions `n`.
	# When both sides are free, these get multiplied by 2 because function
	# is evaluated on the left and the right each iteration.
	# When one side is fixed, however, we add one: on the right side, the
	# function gets evaluated once at b.
	# Add 1 to `n` and `res.nit` because function evaluations occur at
	# iterations 0, 1, ..., `n`. Subtract 1 from `f.count` because
	# function is called separately for left and right in iteration 0.
	if not fix_one_side:
	assert res.nfev == 2(res.nit+1) == 2(f.count-1) == 2*(n + 1)
	else:
	assert res.nfev == (res.nit+1)+1 == (f.count-1)+1 == (n+1)+1

	# Compare reported bracket to theoretical bracket and reported function
	# values to function evaluated at bracket.
	bracket = xp.asarray([res.xl, res.xr])
	xp_assert_close(bracket, xp.asarray([l, u]))
	f_bracket = xp.asarray([res.fl, res.fr])
	xp_assert_close(f_bracket, f(bracket))

	# Check that bracket is valid and that status and success are correct
	assert res.xr > res.xl
	signs = xp.sign(f_bracket)
	assert signs[0] == -signs[1]
	assert res.status == 0
	assert res.success

	def f(self, q, p):
	return stats._stats_py._SimpleNormal().cdf(q) - p

	@pytest.mark.parametrize('p', [0.6, np.linspace(0.05, 0.95, 10)])
	@pytest.mark.parametrize('xmin', [-5, None])
	@pytest.mark.parametrize('xmax', [5, None])
	@pytest.mark.parametrize('factor', [1.2, 2])
	def test_basic(self, p, xmin, xmax, factor, xp):
	# Test basic functionality to bracket root (distribution PPF)
	res = _bracket_root(self.f, xp.asarray(-0.01), 0.01, xmin=xmin, xmax=xmax,
	factor=factor, args=(xp.asarray(p),))
	xp_assert_equal(-xp.sign(res.fl), xp.sign(res.fr))

	@pytest.mark.parametrize('shape', [tuple(), (12,), (3, 4), (3, 2, 2)])
	def test_vectorization(self, shape, xp):
	# Test for correct functionality, output shapes, and dtypes for various
	# input shapes.
	p = np.linspace(-0.05, 1.05, 12).reshape(shape) if shape else np.float64(0.6)
	args = (p,)
	maxiter = 10

	@np.vectorize
	def bracket_root_single(xl0, xr0, xmin, xmax, factor, p):
	return _bracket_root(self.f, xl0, xr0, xmin=xmin, xmax=xmax,
	factor=factor, args=(p,),
	maxiter=maxiter)

	def f(args, *kwargs):
	f.f_evals += 1
	return self.f(args, *kwargs)
	f.f_evals = 0

	rng = np.random.default_rng(2348234)
	xl0 = -rng.random(size=shape)
	xr0 = rng.random(size=shape)
	xmin, xmax = 1e3xl0, 1e3xr0
	if shape: # make some elements un
	i = rng.random(size=shape) > 0.5
	xmin[i], xmax[i] = -np.inf, np.inf
	factor = rng.random(size=shape) + 1.5
	refs = bracket_root_single(xl0, xr0, xmin, xmax, factor, p).ravel()
	xl0, xr0, xmin, xmax, factor = (xp.asarray(xl0), xp.asarray(xr0),
	xp.asarray(xmin), xp.asarray(xmax),
	xp.asarray(factor))
	args = tuple(map(xp.asarray, args))
	res = _bracket_root(f, xl0, xr0, xmin=xmin, xmax=xmax, factor=factor,
	args=args, maxiter=maxiter)

	attrs = ['xl', 'xr', 'fl', 'fr', 'success', 'nfev', 'nit']
	for attr in attrs:
	ref_attr = [xp.asarray(getattr(ref, attr)) for ref in refs]
	res_attr = getattr(res, attr)
	xp_assert_close(xp_ravel(res_attr, xp=xp), xp.stack(ref_attr))
	xp_assert_equal(res_attr.shape, shape)

	xp_test = array_namespace(xp.asarray(1.))
	assert res.success.dtype == xp_test.bool
	if shape:
	assert xp.all(res.success[1:-1])
	assert res.status.dtype == xp.int32
	assert res.nfev.dtype == xp.int32
	assert res.nit.dtype == xp.int32
	assert xp.max(res.nit) == f.f_evals - 2
	xp_assert_less(res.xl, res.xr)
	xp_assert_close(res.fl, xp.asarray(self.f(res.xl, *args)))
	xp_assert_close(res.fr, xp.asarray(self.f(res.xr, *args)))

	def test_flags(self, xp):
	# Test cases that should produce different status flags; show that all
	# can be produced simultaneously.
	def f(xs, js):
	funcs = [lambda x: x - 1.5,
	lambda x: x - 1000,
	lambda x: x - 1000,
	lambda x: x * xp.nan,
	lambda x: x]

	return [funcs[int(j)](x) for x, j in zip(xs, js)]

	args = (xp.arange(5, dtype=xp.int64),)
	res = _bracket_root(f,
	xl0=xp.asarray([-1., -1., -1., -1., 4.]),
	xr0=xp.asarray([1, 1, 1, 1, -4]),
	xmin=xp.asarray([-xp.inf, -1, -xp.inf, -xp.inf, 6]),
	xmax=xp.asarray([xp.inf, 1, xp.inf, xp.inf, 2]),
	args=args, maxiter=3)

	ref_flags = xp.asarray([eim._ECONVERGED,
	_ELIMITS,
	eim._ECONVERR,
	eim._EVALUEERR,
	eim._EINPUTERR],
	dtype=xp.int32)

	xp_assert_equal(res.status, ref_flags)

	@pytest.mark.parametrize("root", (0.622, [0.622, 0.623]))
	@pytest.mark.parametrize('xmin', [-5, None])
	@pytest.mark.parametrize('xmax', [5, None])
	@pytest.mark.parametrize("dtype", ("float16", "float32", "float64"))
	def test_dtype(self, root, xmin, xmax, dtype, xp):
	# Test that dtypes are preserved
	dtype = getattr(xp, dtype)
	xp_test = array_namespace(xp.asarray(1.))

	xmin = xmin if xmin is None else xp.asarray(xmin, dtype=dtype)
	xmax = xmax if xmax is None else xp.asarray(xmax, dtype=dtype)
	root = xp.asarray(root, dtype=dtype)
	def f(x, root):
	return xp_test.astype((x - root) ** 3, dtype)

	bracket = xp.asarray([-0.01, 0.01], dtype=dtype)
	res = _bracket_root(f, *bracket, xmin=xmin, xmax=xmax, args=(root,))
	assert xp.all(res.success)
	assert res.xl.dtype == res.xr.dtype == dtype
	assert res.fl.dtype == res.fr.dtype == dtype

	def test_input_validation(self, xp):
	# Test input validation for appropriate error messages

	message = '`func` must be callable.'
	with pytest.raises(ValueError, match=message):
	_bracket_root(None, -4, 4)

	message = '...must be numeric and real.'
	with pytest.raises(ValueError, match=message):
	_bracket_root(lambda x: x, -4+1j, 4)
	with pytest.raises(ValueError, match=message):
	_bracket_root(lambda x: x, -4, 'hello')
	with pytest.raises(ValueError, match=message):
	_bracket_root(lambda x: x, -4, 4, xmin=np)
	with pytest.raises(ValueError, match=message):
	_bracket_root(lambda x: x, -4, 4, xmax=object())
	with pytest.raises(ValueError, match=message):
	_bracket_root(lambda x: x, -4, 4, factor=sum)

	message = "All elements of `factor` must be greater than 1."
	with pytest.raises(ValueError, match=message):
	_bracket_root(lambda x: x, -4, 4, factor=0.5)

	message = "broadcast"
	# raised by `xp.broadcast, but the traceback is readable IMO
	with pytest.raises(Exception, match=message):
	_bracket_root(lambda x: x, xp.asarray([-2, -3]), xp.asarray([3, 4, 5]))
	# Consider making this give a more readable error message
	# with pytest.raises(ValueError, match=message):
	# _bracket_root(lambda x: [x[0], x[1], x[1]], [-3, -3], [5, 5])

	message = '`maxiter` must be a non-negative integer.'
	with pytest.raises(ValueError, match=message):
	_bracket_root(lambda x: x, -4, 4, maxiter=1.5)
	with pytest.raises(ValueError, match=message):
	_bracket_root(lambda x: x, -4, 4, maxiter=-1)
	with pytest.raises(ValueError, match=message):
	_bracket_root(lambda x: x, -4, 4, maxiter="shrubbery")

	def test_special_cases(self, xp):
	# Test edge cases and other special cases
	xp_test = array_namespace(xp.asarray(1.))

	# Test that integers are not passed to `f`
	# (otherwise this would overflow)
	def f(x):
	assert xp_test.isdtype(x.dtype, "real floating")
	return x ** 99 - 1

	res = _bracket_root(f, xp.asarray(-7.), xp.asarray(5.))
	assert res.success

	# Test maxiter = 0. Should do nothing to bracket.
	def f(x):
	return x - 10

	bracket = (xp.asarray(-3.), xp.asarray(5.))
	res = _bracket_root(f, *bracket, maxiter=0)
	assert res.xl, res.xr == bracket
	assert res.nit == 0
	assert res.nfev == 2
	assert res.status == -2

	# Test scalar `args` (not in tuple)
	def f(x, c):
	return c*x - 1

	res = _bracket_root(f, xp.asarray(-1.), xp.asarray(1.),
	args=xp.asarray(3.))
	assert res.success
	xp_assert_close(res.fl, f(res.xl, 3))

	# Test other edge cases

	def f(x):
	f.count += 1
	return x

	# 1. root lies within guess of bracket
	f.count = 0
	_bracket_root(f, xp.asarray(-10), xp.asarray(20))
	assert f.count == 2

	# 2. bracket endpoint hits root exactly
	f.count = 0
	res = _bracket_root(f, xp.asarray(5.), xp.asarray(10.),
	factor=2)

	assert res.nfev == 4
	xp_assert_close(res.xl, xp.asarray(0.), atol=1e-15)
	xp_assert_close(res.xr, xp.asarray(5.), atol=1e-15)

	# 3. bracket limit hits root exactly
	with np.errstate(over='ignore'):
	res = _bracket_root(f, xp.asarray(5.), xp.asarray(10.),
	xmin=0)
	xp_assert_close(res.xl, xp.asarray(0.), atol=1e-15)

	with np.errstate(over='ignore'):
	res = _bracket_root(f, xp.asarray(-10.), xp.asarray(-5.),
	xmax=0)
	xp_assert_close(res.xr, xp.asarray(0.), atol=1e-15)

	# 4. bracket not within min, max
	with np.errstate(over='ignore'):
	res = _bracket_root(f, xp.asarray(5.), xp.asarray(10.),
	xmin=1)
	assert not res.success


	@pytest.mark.skip_xp_backends('array_api_strict', reason=array_api_strict_skip_reason)
	@pytest.mark.skip_xp_backends('jax.numpy', reason=jax_skip_reason)
	@array_api_compatible
	@pytest.mark.usefixtures("skip_xp_backends")
	class TestBracketMinimum:
	def init_f(self):
	def f(x, a, b):
	f.count += 1
	return (x - a)**2 + b
	f.count = 0
	return f

	def assert_valid_bracket(self, result, xp):
	assert xp.all(
	(result.xl < result.xm) & (result.xm < result.xr)
	)
	assert xp.all(
	(result.fl >= result.fm) & (result.fr > result.fm)
	\| (result.fl > result.fm) & (result.fr > result.fm)
	)

	def get_kwargs(
	self, *, xl0=None, xr0=None, factor=None, xmin=None, xmax=None, args=None
	):
	names = ("xl0", "xr0", "xmin", "xmax", "factor", "args")
	return {
	name: val for name, val in zip(names, (xl0, xr0, xmin, xmax, factor, args))
	if val is not None
	}

	@pytest.mark.parametrize(
	"seed",
	(
	307448016549685229886351382450158984917,
	11650702770735516532954347931959000479,
	113767103358505514764278732330028568336,
	)
	)
	@pytest.mark.parametrize("use_xmin", (False, True))
	@pytest.mark.parametrize("other_side", (False, True))
	def test_nfev_expected(self, seed, use_xmin, other_side, xp):
	rng = np.random.default_rng(seed)
	args = (xp.asarray(0.), xp.asarray(0.)) # f(x) = x^2 with minimum at 0
	# xl0, xm0, xr0 are chosen such that the initial bracket is to
	# the right of the minimum, and the bracket will expand
	# downhill towards zero.
	xl0, d1, d2, factor = xp.asarray(rng.random(size=4) * [1e5, 10, 10, 5])
	xm0 = xl0 + d1
	xr0 = xm0 + d2
	# Factor should be greater than one.
	factor += 1

	if use_xmin:
	xmin = xp.asarray(-rng.random() * 5, dtype=xp.float64)
	n = int(xp.ceil(xp.log(-(xl0 - xmin) / xmin) / xp.log(factor)))
	lower = xmin + (xl0 - xmin)factor*-n
	middle = xmin + (xl0 - xmin)factor*-(n-1)
	upper = xmin + (xl0 - xmin)factor*-(n-2) if n > 1 else xm0
	# It may be the case the lower is below the minimum, but we still
	# don't have a valid bracket.
	if middle2 > lower2:
	n += 1
	lower, middle, upper = (
	xmin + (xl0 - xmin)factor*-n, lower, middle
	)
	else:
	xmin = None
	n = int(xp.ceil(xp.log(xl0 / d1) / xp.log(factor)))
	lower = xl0 - d1factor*n
	middle = xl0 - d1factor*(n-1) if n > 1 else xl0
	upper = xl0 - d1factor*(n-2) if n > 1 else xm0
	# It may be the case the lower is below the minimum, but we still
	# don't have a valid bracket.
	if middle2 > lower2:
	n += 1
	lower, middle, upper = (
	xl0 - d1factor*n, lower, middle
	)
	f = self.init_f()

	xmax = None
	if other_side:
	xl0, xm0, xr0 = -xr0, -xm0, -xl0
	xmin, xmax = None, -xmin if xmin is not None else None
	lower, middle, upper = -upper, -middle, -lower

	kwargs = self.get_kwargs(
	xl0=xl0, xr0=xr0, xmin=xmin, xmax=xmax, factor=factor, args=args
	)
	result = _bracket_minimum(f, xp.asarray(xm0), **kwargs)

	# Check that `nfev` and `nit` have the correct relationship
	assert result.nfev == result.nit + 3
	# Check that `nfev` reports the correct number of function evaluations.
	assert result.nfev == f.count
	# Check that the number of iterations matches the theoretical value.
	assert result.nit == n

	# Compare reported bracket to theoretical bracket and reported function
	# values to function evaluated at bracket.
	xp_assert_close(result.xl, lower)
	xp_assert_close(result.xm, middle)
	xp_assert_close(result.xr, upper)
	xp_assert_close(result.fl, f(lower, *args))
	xp_assert_close(result.fm, f(middle, *args))
	xp_assert_close(result.fr, f(upper, *args))

	self.assert_valid_bracket(result, xp)
	assert result.status == 0
	assert result.success

	def test_flags(self, xp):
	# Test cases that should produce different status flags; show that all
	# can be produced simultaneously
	def f(xs, js):
	funcs = [lambda x: (x - 1.5)**2,
	lambda x: x,
	lambda x: x,
	lambda x: xp.nan,
	lambda x: x**2]

	return [funcs[j](x) for x, j in zip(xs, js)]

	args = (xp.arange(5, dtype=xp.int64),)
	xl0 = xp.asarray([-1.0, -1.0, -1.0, -1.0, 6.0])
	xm0 = xp.asarray([0.0, 0.0, 0.0, 0.0, 4.0])
	xr0 = xp.asarray([1.0, 1.0, 1.0, 1.0, 2.0])
	xmin = xp.asarray([-xp.inf, -1.0, -xp.inf, -xp.inf, 8.0])

	result = _bracket_minimum(f, xm0, xl0=xl0, xr0=xr0, xmin=xmin,
	args=args, maxiter=3)

	reference_flags = xp.asarray([eim._ECONVERGED, _ELIMITS,
	eim._ECONVERR, eim._EVALUEERR,
	eim._EINPUTERR], dtype=xp.int32)
	xp_assert_equal(result.status, reference_flags)

	@pytest.mark.parametrize("minimum", (0.622, [0.622, 0.623]))
	@pytest.mark.parametrize("dtype", ("float16", "float32", "float64"))
	@pytest.mark.parametrize("xmin", [-5, None])
	@pytest.mark.parametrize("xmax", [5, None])
	def test_dtypes(self, minimum, xmin, xmax, dtype, xp):
	dtype = getattr(xp, dtype)
	xp_test = array_namespace(xp.asarray(1.))
	xmin = xmin if xmin is None else xp.asarray(xmin, dtype=dtype)
	xmax = xmax if xmax is None else xp.asarray(xmax, dtype=dtype)
	minimum = xp.asarray(minimum, dtype=dtype)

	def f(x, minimum):
	return xp_test.astype((x - minimum)**2, dtype)

	xl0, xm0, xr0 = [-0.01, 0.0, 0.01]
	result = _bracket_minimum(
	f, xp.asarray(xm0, dtype=dtype), xl0=xp.asarray(xl0, dtype=dtype),
	xr0=xp.asarray(xr0, dtype=dtype), xmin=xmin, xmax=xmax, args=(minimum, )
	)
	assert xp.all(result.success)
	assert result.xl.dtype == result.xm.dtype == result.xr.dtype == dtype
	assert result.fl.dtype == result.fm.dtype == result.fr.dtype == dtype

	@pytest.mark.skip_xp_backends(np_only=True, reason="str/object arrays")
	def test_input_validation(self, xp):
	# Test input validation for appropriate error messages

	message = '`func` must be callable.'
	with pytest.raises(ValueError, match=message):
	_bracket_minimum(None, -4, xl0=4)

	message = '...must be numeric and real.'
	with pytest.raises(ValueError, match=message):
	_bracket_minimum(lambda x: x**2, xp.asarray(4+1j))
	with pytest.raises(ValueError, match=message):
	_bracket_minimum(lambda x: x**2, xp.asarray(-4), xl0='hello')
	with pytest.raises(ValueError, match=message):
	_bracket_minimum(lambda x: x**2, xp.asarray(-4),
	xr0='farcical aquatic ceremony')
	with pytest.raises(ValueError, match=message):
	_bracket_minimum(lambda x: x**2, xp.asarray(-4), xmin=np)
	with pytest.raises(ValueError, match=message):
	_bracket_minimum(lambda x: x**2, xp.asarray(-4), xmax=object())
	with pytest.raises(ValueError, match=message):
	_bracket_minimum(lambda x: x**2, xp.asarray(-4), factor=sum)

	message = "All elements of `factor` must be greater than 1."
	with pytest.raises(ValueError, match=message):
	_bracket_minimum(lambda x: x, xp.asarray(-4), factor=0.5)

	message = "shape mismatch: objects cannot be broadcast"
	# raised by `xp.broadcast, but the traceback is readable IMO
	with pytest.raises(ValueError, match=message):
	_bracket_minimum(lambda x: x**2, xp.asarray([-2, -3]), xl0=[-3, -4, -5])

	message = '`maxiter` must be a non-negative integer.'
	with pytest.raises(ValueError, match=message):
	_bracket_minimum(lambda x: x**2, xp.asarray(-4), xr0=4, maxiter=1.5)
	with pytest.raises(ValueError, match=message):
	_bracket_minimum(lambda x: x**2, xp.asarray(-4), xr0=4, maxiter=-1)
	with pytest.raises(ValueError, match=message):
	_bracket_minimum(lambda x: x**2, xp.asarray(-4), xr0=4, maxiter="ekki")

	@pytest.mark.parametrize("xl0", [0.0, None])
	@pytest.mark.parametrize("xm0", (0.05, 0.1, 0.15))
	@pytest.mark.parametrize("xr0", (0.2, 0.4, 0.6, None))
	# Minimum is ``a`` for each tuple ``(a, b)`` below. Tests cases where minimum
	# is within, or at varying distances to the left or right of the initial
	# bracket.
	@pytest.mark.parametrize(
	"args",
	(
	(1.2, 0), (-0.5, 0), (0.1, 0), (0.2, 0), (3.6, 0), (21.4, 0),
	(121.6, 0), (5764.1, 0), (-6.4, 0), (-12.9, 0), (-146.2, 0)
	)
	)
	def test_scalar_no_limits(self, xl0, xm0, xr0, args, xp):
	f = self.init_f()
	kwargs = self.get_kwargs(xl0=xl0, xr0=xr0, args=tuple(map(xp.asarray, args)))
	result = _bracket_minimum(f, xp.asarray(xm0, dtype=xp.float64), **kwargs)
	self.assert_valid_bracket(result, xp)
	assert result.status == 0
	assert result.success
	assert result.nfev == f.count

	@pytest.mark.parametrize(
	# xmin is set at 0.0 in all cases.
	"xl0,xm0,xr0,xmin",
	(
	# Initial bracket at varying distances from the xmin.
	(0.5, 0.75, 1.0, 0.0),
	(1.0, 2.5, 4.0, 0.0),
	(2.0, 4.0, 6.0, 0.0),
	(12.0, 16.0, 20.0, 0.0),
	# Test default initial left endpoint selection. It should not
	# be below xmin.
	(None, 0.75, 1.0, 0.0),
	(None, 2.5, 4.0, 0.0),
	(None, 4.0, 6.0, 0.0),
	(None, 16.0, 20.0, 0.0),
	)
	)
	@pytest.mark.parametrize(
	"args", (
	(0.0, 0.0), # Minimum is directly at xmin.
	(1e-300, 0.0), # Minimum is extremely close to xmin.
	(1e-20, 0.0), # Minimum is very close to xmin.
	# Minimum at varying distances from xmin.
	(0.1, 0.0),
	(0.2, 0.0),
	(0.4, 0.0)
	)
	)
	def test_scalar_with_limit_left(self, xl0, xm0, xr0, xmin, args, xp):
	f = self.init_f()
	kwargs = self.get_kwargs(xl0=xl0, xr0=xr0, xmin=xmin,
	args=tuple(map(xp.asarray, args)))
	result = _bracket_minimum(f, xp.asarray(xm0), **kwargs)
	self.assert_valid_bracket(result, xp)
	assert result.status == 0
	assert result.success
	assert result.nfev == f.count

	@pytest.mark.parametrize(
	#xmax is set to 1.0 in all cases.
	"xl0,xm0,xr0,xmax",
	(
	# Bracket at varying distances from xmax.
	(0.2, 0.3, 0.4, 1.0),
	(0.05, 0.075, 0.1, 1.0),
	(-0.2, -0.1, 0.0, 1.0),
	(-21.2, -17.7, -14.2, 1.0),
	# Test default right endpoint selection. It should not exceed xmax.
	(0.2, 0.3, None, 1.0),
	(0.05, 0.075, None, 1.0),
	(-0.2, -0.1, None, 1.0),
	(-21.2, -17.7, None, 1.0),
	)
	)
	@pytest.mark.parametrize(
	"args", (
	(0.9999999999999999, 0.0), # Minimum very close to xmax.
	# Minimum at varying distances from xmax.
	(0.9, 0.0),
	(0.7, 0.0),
	(0.5, 0.0)
	)
	)
	def test_scalar_with_limit_right(self, xl0, xm0, xr0, xmax, args, xp):
	f = self.init_f()
	args = tuple(xp.asarray(arg, dtype=xp.float64) for arg in args)
	kwargs = self.get_kwargs(xl0=xl0, xr0=xr0, xmax=xmax, args=args)
	result = _bracket_minimum(f, xp.asarray(xm0, dtype=xp.float64), **kwargs)
	self.assert_valid_bracket(result, xp)
	assert result.status == 0
	assert result.success
	assert result.nfev == f.count

	@pytest.mark.parametrize(
	"xl0,xm0,xr0,xmin,xmax,args",
	(
	( # Case 1:
	# Initial bracket.
	0.2,
	0.3,
	0.4,
	# Function slopes down to the right from the bracket to a minimum
	# at 1.0. xmax is also at 1.0
	None,
	1.0,
	(1.0, 0.0)
	),
	( # Case 2:
	# Initial bracket.
	1.4,
	1.95,
	2.5,
	# Function slopes down to the left from the bracket to a minimum at
	# 0.3 with xmin set to 0.3.
	0.3,
	None,
	(0.3, 0.0)
	),
	(
	# Case 3:
	# Initial bracket.
	2.6,
	3.25,
	3.9,
	# Function slopes down and to the right to a minimum at 99.4 with xmax
	# at 99.4. Tests case where minimum is at xmax relatively further from
	# the bracket.
	None,
	99.4,
	(99.4, 0)
	),
	(
	# Case 4:
	# Initial bracket.
	4,
	4.5,
	5,
	# Function slopes down and to the left away from the bracket with a
	# minimum at -26.3 with xmin set to -26.3. Tests case where minimum is
	# at xmin relatively far from the bracket.
	-26.3,
	None,
	(-26.3, 0)
	),
	(
	# Case 5:
	# Similar to Case 1 above, but tests default values of xl0 and xr0.
	None,
	0.3,
	None,
	None,
	1.0,
	(1.0, 0.0)
	),
	( # Case 6:
	# Similar to Case 2 above, but tests default values of xl0 and xr0.
	None,
	1.95,
	None,
	0.3,
	None,
	(0.3, 0.0)
	),
	(
	# Case 7:
	# Similar to Case 3 above, but tests default values of xl0 and xr0.
	None,
	3.25,
	None,
	None,
	99.4,
	(99.4, 0)
	),
	(
	# Case 8:
	# Similar to Case 4 above, but tests default values of xl0 and xr0.
	None,
	4.5,
	None,
	-26.3,
	None,
	(-26.3, 0)
	),
	)
	)
	def test_minimum_at_boundary_point(self, xl0, xm0, xr0, xmin, xmax, args, xp):
	f = self.init_f()
	kwargs = self.get_kwargs(xr0=xr0, xmin=xmin, xmax=xmax,
	args=tuple(map(xp.asarray, args)))
	result = _bracket_minimum(f, xp.asarray(xm0), **kwargs)
	assert result.status == -1
	assert args[0] in (result.xl, result.xr)
	assert result.nfev == f.count

	@pytest.mark.parametrize('shape', [tuple(), (12, ), (3, 4), (3, 2, 2)])
	def test_vectorization(self, shape, xp):
	# Test for correct functionality, output shapes, and dtypes for
	# various input shapes.
	a = np.linspace(-0.05, 1.05, 12).reshape(shape) if shape else 0.6
	args = (a, 0.)
	maxiter = 10

	@np.vectorize
	def bracket_minimum_single(xm0, xl0, xr0, xmin, xmax, factor, a):
	return _bracket_minimum(self.init_f(), xm0, xl0=xl0, xr0=xr0, xmin=xmin,
	xmax=xmax, factor=factor, maxiter=maxiter,
	args=(a, 0.0))

	f = self.init_f()

	rng = np.random.default_rng(2348234)
	xl0 = -rng.random(size=shape)
	xr0 = rng.random(size=shape)
	xm0 = xl0 + rng.random(size=shape) * (xr0 - xl0)
	xmin, xmax = 1e3xl0, 1e3xr0
	if shape: # make some elements un
	i = rng.random(size=shape) > 0.5
	xmin[i], xmax[i] = -np.inf, np.inf
	factor = rng.random(size=shape) + 1.5
	refs = bracket_minimum_single(xm0, xl0, xr0, xmin, xmax, factor, a).ravel()
	args = tuple(xp.asarray(arg, dtype=xp.float64) for arg in args)
	res = _bracket_minimum(f, xp.asarray(xm0), xl0=xl0, xr0=xr0, xmin=xmin,
	xmax=xmax, factor=factor, args=args, maxiter=maxiter)

	attrs = ['xl', 'xm', 'xr', 'fl', 'fm', 'fr', 'success', 'nfev', 'nit']
	for attr in attrs:
	ref_attr = [xp.asarray(getattr(ref, attr)) for ref in refs]
	res_attr = getattr(res, attr)
	xp_assert_close(xp_ravel(res_attr, xp=xp), xp.stack(ref_attr))
	xp_assert_equal(res_attr.shape, shape)

	xp_test = array_namespace(xp.asarray(1.))
	assert res.success.dtype == xp_test.bool
	if shape:
	assert xp.all(res.success[1:-1])
	assert res.status.dtype == xp.int32
	assert res.nfev.dtype == xp.int32
	assert res.nit.dtype == xp.int32
	assert xp.max(res.nit) == f.count - 3
	self.assert_valid_bracket(res, xp)
	xp_assert_close(res.fl, f(res.xl, *args))
	xp_assert_close(res.fm, f(res.xm, *args))
	xp_assert_close(res.fr, f(res.xr, *args))

	def test_special_cases(self, xp):
	# Test edge cases and other special cases.
	xp_test = array_namespace(xp.asarray(1.))

	# Test that integers are not passed to `f`
	# (otherwise this would overflow)
	def f(x):
	assert xp_test.isdtype(x.dtype, "numeric")
	return x ** 98 - 1

	result = _bracket_minimum(f, xp.asarray(-7., dtype=xp.float64), xr0=5)
	assert result.success

	# Test maxiter = 0. Should do nothing to bracket.
	def f(x):
	return x**2 - 10

	xl0, xm0, xr0 = xp.asarray(-3.), xp.asarray(-1.), xp.asarray(2.)
	result = _bracket_minimum(f, xm0, xl0=xl0, xr0=xr0, maxiter=0)
	xp_assert_equal(result.xl, xl0)
	xp_assert_equal(result.xm, xm0)
	xp_assert_equal(result.xr, xr0)

	# Test scalar `args` (not in tuple)
	def f(x, c):
	return cx*2 - 1

	result = _bracket_minimum(f, xp.asarray(-1.), args=xp.asarray(3.))
	assert result.success
	xp_assert_close(result.fl, f(result.xl, 3))

	# Initial bracket is valid.
	f = self.init_f()
	xl0, xm0, xr0 = xp.asarray(-1.0), xp.asarray(-0.2), xp.asarray(1.0)
	args = (xp.asarray(0.), xp.asarray(0.))
	result = _bracket_minimum(f, xm0, xl0=xl0, xr0=xr0, args=args)
	assert f.count == 3

	xp_assert_equal(result.xl, xl0)
	xp_assert_equal(result.xm , xm0)
	xp_assert_equal(result.xr, xr0)
	xp_assert_equal(result.fl, f(xl0, *args))
	xp_assert_equal(result.fm, f(xm0, *args))
	xp_assert_equal(result.fr, f(xr0, *args))

	def test_gh_20562_left(self, xp):
	# Regression test for https://github.com/scipy/scipy/issues/20562
	# minimum of f in [xmin, xmax] is at xmin.
	xmin, xmax = xp.asarray(0.21933608), xp.asarray(1.39713606)

	def f(x):
	log_a, log_b = xp.log(xmin), xp.log(xmax)
	return -((log_b - log_a)x)*-1

	result = _bracket_minimum(f, xp.asarray(0.5535723499480897), xmin=xmin,
	xmax=xmax)
	assert xmin == result.xl

	def test_gh_20562_right(self, xp):
	# Regression test for https://github.com/scipy/scipy/issues/20562
	# minimum of f in [xmin, xmax] is at xmax.
	xmin, xmax = xp.asarray(-1.39713606), xp.asarray(-0.21933608)

	def f(x):
	log_a, log_b = xp.log(-xmax), xp.log(-xmin)
	return ((log_b - log_a)x)*-1

	result = _bracket_minimum(f, xp.asarray(-0.5535723499480897),
	xmin=xmin, xmax=xmax)
	assert xmax == result.xr