eval_venv / venv /lib /python3.10 /site-packages /_pytest /python_api.py

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	# mypy: allow-untyped-defs
	from __future__ import annotations

	from collections.abc import Collection
	from collections.abc import Mapping
	from collections.abc import Sequence
	from collections.abc import Sized
	from decimal import Decimal
	import math
	from numbers import Complex
	import pprint
	import sys
	from typing import Any
	from typing import TYPE_CHECKING


	if TYPE_CHECKING:
	from numpy import ndarray


	def _compare_approx(
	full_object: object,
	message_data: Sequence[tuple[str, str, str]],
	number_of_elements: int,
	different_ids: Sequence[object],
	max_abs_diff: float,
	max_rel_diff: float,
	) -> list[str]:
	message_list = list(message_data)
	message_list.insert(0, ("Index", "Obtained", "Expected"))
	max_sizes = [0, 0, 0]
	for index, obtained, expected in message_list:
	max_sizes[0] = max(max_sizes[0], len(index))
	max_sizes[1] = max(max_sizes[1], len(obtained))
	max_sizes[2] = max(max_sizes[2], len(expected))
	explanation = [
	f"comparison failed. Mismatched elements: {len(different_ids)} / {number_of_elements}:",
	f"Max absolute difference: {max_abs_diff}",
	f"Max relative difference: {max_rel_diff}",
	] + [
	f"{indexes:<{max_sizes[0]}} \| {obtained:<{max_sizes[1]}} \| {expected:<{max_sizes[2]}}"
	for indexes, obtained, expected in message_list
	]
	return explanation


	# builtin pytest.approx helper


	class ApproxBase:
	"""Provide shared utilities for making approximate comparisons between
	numbers or sequences of numbers."""

	# Tell numpy to use our `__eq__` operator instead of its.
	__array_ufunc__ = None
	__array_priority__ = 100

	def __init__(self, expected, rel=None, abs=None, nan_ok: bool = False) -> None:
	__tracebackhide__ = True
	self.expected = expected
	self.abs = abs
	self.rel = rel
	self.nan_ok = nan_ok
	self._check_type()

	def __repr__(self) -> str:
	raise NotImplementedError

	def _repr_compare(self, other_side: Any) -> list[str]:
	return [
	"comparison failed",
	f"Obtained: {other_side}",
	f"Expected: {self}",
	]

	def __eq__(self, actual) -> bool:
	return all(
	a == self._approx_scalar(x) for a, x in self._yield_comparisons(actual)
	)

	def __bool__(self):
	__tracebackhide__ = True
	raise AssertionError(
	"approx() is not supported in a boolean context.\nDid you mean: `assert a == approx(b)`?"
	)

	# Ignore type because of https://github.com/python/mypy/issues/4266.
	__hash__ = None # type: ignore

	def __ne__(self, actual) -> bool:
	return not (actual == self)

	def _approx_scalar(self, x) -> ApproxScalar:
	if isinstance(x, Decimal):
	return ApproxDecimal(x, rel=self.rel, abs=self.abs, nan_ok=self.nan_ok)
	return ApproxScalar(x, rel=self.rel, abs=self.abs, nan_ok=self.nan_ok)

	def _yield_comparisons(self, actual):
	"""Yield all the pairs of numbers to be compared.

	This is used to implement the `__eq__` method.
	"""
	raise NotImplementedError

	def _check_type(self) -> None:
	"""Raise a TypeError if the expected value is not a valid type."""
	# This is only a concern if the expected value is a sequence. In every
	# other case, the approx() function ensures that the expected value has
	# a numeric type. For this reason, the default is to do nothing. The
	# classes that deal with sequences should reimplement this method to
	# raise if there are any non-numeric elements in the sequence.


	def _recursive_sequence_map(f, x):
	"""Recursively map a function over a sequence of arbitrary depth"""
	if isinstance(x, (list, tuple)):
	seq_type = type(x)
	return seq_type(_recursive_sequence_map(f, xi) for xi in x)
	elif _is_sequence_like(x):
	return [_recursive_sequence_map(f, xi) for xi in x]
	else:
	return f(x)


	class ApproxNumpy(ApproxBase):
	"""Perform approximate comparisons where the expected value is numpy array."""

	def __repr__(self) -> str:
	list_scalars = _recursive_sequence_map(
	self._approx_scalar, self.expected.tolist()
	)
	return f"approx({list_scalars!r})"

	def _repr_compare(self, other_side: ndarray \| list[Any]) -> list[str]:
	import itertools
	import math

	def get_value_from_nested_list(
	nested_list: list[Any], nd_index: tuple[Any, ...]
	) -> Any:
	"""
	Helper function to get the value out of a nested list, given an n-dimensional index.
	This mimics numpy's indexing, but for raw nested python lists.
	"""
	value: Any = nested_list
	for i in nd_index:
	value = value[i]
	return value

	np_array_shape = self.expected.shape
	approx_side_as_seq = _recursive_sequence_map(
	self._approx_scalar, self.expected.tolist()
	)

	# convert other_side to numpy array to ensure shape attribute is available
	other_side_as_array = _as_numpy_array(other_side)
	assert other_side_as_array is not None

	if np_array_shape != other_side_as_array.shape:
	return [
	"Impossible to compare arrays with different shapes.",
	f"Shapes: {np_array_shape} and {other_side_as_array.shape}",
	]

	number_of_elements = self.expected.size
	max_abs_diff = -math.inf
	max_rel_diff = -math.inf
	different_ids = []
	for index in itertools.product(*(range(i) for i in np_array_shape)):
	approx_value = get_value_from_nested_list(approx_side_as_seq, index)
	other_value = get_value_from_nested_list(other_side_as_array, index)
	if approx_value != other_value:
	abs_diff = abs(approx_value.expected - other_value)
	max_abs_diff = max(max_abs_diff, abs_diff)
	if other_value == 0.0:
	max_rel_diff = math.inf
	else:
	max_rel_diff = max(max_rel_diff, abs_diff / abs(other_value))
	different_ids.append(index)

	message_data = [
	(
	str(index),
	str(get_value_from_nested_list(other_side_as_array, index)),
	str(get_value_from_nested_list(approx_side_as_seq, index)),
	)
	for index in different_ids
	]
	return _compare_approx(
	self.expected,
	message_data,
	number_of_elements,
	different_ids,
	max_abs_diff,
	max_rel_diff,
	)

	def __eq__(self, actual) -> bool:
	import numpy as np

	# self.expected is supposed to always be an array here.

	if not np.isscalar(actual):
	try:
	actual = np.asarray(actual)
	except Exception as e:
	raise TypeError(f"cannot compare '{actual}' to numpy.ndarray") from e

	if not np.isscalar(actual) and actual.shape != self.expected.shape:
	return False

	return super().__eq__(actual)

	def _yield_comparisons(self, actual):
	import numpy as np

	# `actual` can either be a numpy array or a scalar, it is treated in
	# `__eq__` before being passed to `ApproxBase.__eq__`, which is the
	# only method that calls this one.

	if np.isscalar(actual):
	for i in np.ndindex(self.expected.shape):
	yield actual, self.expected[i].item()
	else:
	for i in np.ndindex(self.expected.shape):
	yield actual[i].item(), self.expected[i].item()


	class ApproxMapping(ApproxBase):
	"""Perform approximate comparisons where the expected value is a mapping
	with numeric values (the keys can be anything)."""

	def __repr__(self) -> str:
	return f"approx({ ({k: self._approx_scalar(v) for k, v in self.expected.items()})!r})"

	def _repr_compare(self, other_side: Mapping[object, float]) -> list[str]:
	import math

	approx_side_as_map = {
	k: self._approx_scalar(v) for k, v in self.expected.items()
	}

	number_of_elements = len(approx_side_as_map)
	max_abs_diff = -math.inf
	max_rel_diff = -math.inf
	different_ids = []
	for (approx_key, approx_value), other_value in zip(
	approx_side_as_map.items(), other_side.values()
	):
	if approx_value != other_value:
	if approx_value.expected is not None and other_value is not None:
	try:
	max_abs_diff = max(
	max_abs_diff, abs(approx_value.expected - other_value)
	)
	if approx_value.expected == 0.0:
	max_rel_diff = math.inf
	else:
	max_rel_diff = max(
	max_rel_diff,
	abs(
	(approx_value.expected - other_value)
	/ approx_value.expected
	),
	)
	except ZeroDivisionError:
	pass
	different_ids.append(approx_key)

	message_data = [
	(str(key), str(other_side[key]), str(approx_side_as_map[key]))
	for key in different_ids
	]

	return _compare_approx(
	self.expected,
	message_data,
	number_of_elements,
	different_ids,
	max_abs_diff,
	max_rel_diff,
	)

	def __eq__(self, actual) -> bool:
	try:
	if set(actual.keys()) != set(self.expected.keys()):
	return False
	except AttributeError:
	return False

	return super().__eq__(actual)

	def _yield_comparisons(self, actual):
	for k in self.expected.keys():
	yield actual[k], self.expected[k]

	def _check_type(self) -> None:
	__tracebackhide__ = True
	for key, value in self.expected.items():
	if isinstance(value, type(self.expected)):
	msg = "pytest.approx() does not support nested dictionaries: key={!r} value={!r}\n full mapping={}"
	raise TypeError(msg.format(key, value, pprint.pformat(self.expected)))


	class ApproxSequenceLike(ApproxBase):
	"""Perform approximate comparisons where the expected value is a sequence of numbers."""

	def __repr__(self) -> str:
	seq_type = type(self.expected)
	if seq_type not in (tuple, list):
	seq_type = list
	return f"approx({seq_type(self._approx_scalar(x) for x in self.expected)!r})"

	def _repr_compare(self, other_side: Sequence[float]) -> list[str]:
	import math

	if len(self.expected) != len(other_side):
	return [
	"Impossible to compare lists with different sizes.",
	f"Lengths: {len(self.expected)} and {len(other_side)}",
	]

	approx_side_as_map = _recursive_sequence_map(self._approx_scalar, self.expected)

	number_of_elements = len(approx_side_as_map)
	max_abs_diff = -math.inf
	max_rel_diff = -math.inf
	different_ids = []
	for i, (approx_value, other_value) in enumerate(
	zip(approx_side_as_map, other_side)
	):
	if approx_value != other_value:
	try:
	abs_diff = abs(approx_value.expected - other_value)
	max_abs_diff = max(max_abs_diff, abs_diff)
	# Ignore non-numbers for the diff calculations (#13012).
	except TypeError:
	pass
	else:
	if other_value == 0.0:
	max_rel_diff = math.inf
	else:
	max_rel_diff = max(max_rel_diff, abs_diff / abs(other_value))
	different_ids.append(i)
	message_data = [
	(str(i), str(other_side[i]), str(approx_side_as_map[i]))
	for i in different_ids
	]

	return _compare_approx(
	self.expected,
	message_data,
	number_of_elements,
	different_ids,
	max_abs_diff,
	max_rel_diff,
	)

	def __eq__(self, actual) -> bool:
	try:
	if len(actual) != len(self.expected):
	return False
	except TypeError:
	return False
	return super().__eq__(actual)

	def _yield_comparisons(self, actual):
	return zip(actual, self.expected)

	def _check_type(self) -> None:
	__tracebackhide__ = True
	for index, x in enumerate(self.expected):
	if isinstance(x, type(self.expected)):
	msg = "pytest.approx() does not support nested data structures: {!r} at index {}\n full sequence: {}"
	raise TypeError(msg.format(x, index, pprint.pformat(self.expected)))


	class ApproxScalar(ApproxBase):
	"""Perform approximate comparisons where the expected value is a single number."""

	# Using Real should be better than this Union, but not possible yet:
	# https://github.com/python/typeshed/pull/3108
	DEFAULT_ABSOLUTE_TOLERANCE: float \| Decimal = 1e-12
	DEFAULT_RELATIVE_TOLERANCE: float \| Decimal = 1e-6

	def __repr__(self) -> str:
	"""Return a string communicating both the expected value and the
	tolerance for the comparison being made.

	For example, ``1.0 ± 1e-6``, ``(3+4j) ± 5e-6 ∠ ±180°``.
	"""
	# Don't show a tolerance for values that aren't compared using
	# tolerances, i.e. non-numerics and infinities. Need to call abs to
	# handle complex numbers, e.g. (inf + 1j).
	if (
	isinstance(self.expected, bool)
	or (not isinstance(self.expected, (Complex, Decimal)))
	or math.isinf(abs(self.expected) or isinstance(self.expected, bool))
	):
	return str(self.expected)

	# If a sensible tolerance can't be calculated, self.tolerance will
	# raise a ValueError. In this case, display '???'.
	try:
	if 1e-3 <= self.tolerance < 1e3:
	vetted_tolerance = f"{self.tolerance:n}"
	else:
	vetted_tolerance = f"{self.tolerance:.1e}"

	if (
	isinstance(self.expected, Complex)
	and self.expected.imag
	and not math.isinf(self.tolerance)
	):
	vetted_tolerance += " ∠ ±180°"
	except ValueError:
	vetted_tolerance = "???"

	return f"{self.expected} ± {vetted_tolerance}"

	def __eq__(self, actual) -> bool:
	"""Return whether the given value is equal to the expected value
	within the pre-specified tolerance."""

	def is_bool(val: Any) -> bool:
	# Check if `val` is a native bool or numpy bool.
	if isinstance(val, bool):
	return True
	if np := sys.modules.get("numpy"):
	return isinstance(val, np.bool_)
	return False

	asarray = _as_numpy_array(actual)
	if asarray is not None:
	# Call ``__eq__()`` manually to prevent infinite-recursion with
	# numpy<1.13. See #3748.
	return all(self.__eq__(a) for a in asarray.flat)

	# Short-circuit exact equality, except for bool and np.bool_
	if is_bool(self.expected) and not is_bool(actual):
	return False
	elif actual == self.expected:
	return True

	# If either type is non-numeric, fall back to strict equality.
	# NB: we need Complex, rather than just Number, to ensure that __abs__,
	# __sub__, and __float__ are defined. Also, consider bool to be
	# non-numeric, even though it has the required arithmetic.
	if is_bool(self.expected) or not (
	isinstance(self.expected, (Complex, Decimal))
	and isinstance(actual, (Complex, Decimal))
	):
	return False

	# Allow the user to control whether NaNs are considered equal to each
	# other or not. The abs() calls are for compatibility with complex
	# numbers.
	if math.isnan(abs(self.expected)):
	return self.nan_ok and math.isnan(abs(actual))

	# Infinity shouldn't be approximately equal to anything but itself, but
	# if there's a relative tolerance, it will be infinite and infinity
	# will seem approximately equal to everything. The equal-to-itself
	# case would have been short circuited above, so here we can just
	# return false if the expected value is infinite. The abs() call is
	# for compatibility with complex numbers.
	if math.isinf(abs(self.expected)):
	return False

	# Return true if the two numbers are within the tolerance.
	result: bool = abs(self.expected - actual) <= self.tolerance
	return result

	# Ignore type because of https://github.com/python/mypy/issues/4266.
	__hash__ = None # type: ignore

	@property
	def tolerance(self):
	"""Return the tolerance for the comparison.

	This could be either an absolute tolerance or a relative tolerance,
	depending on what the user specified or which would be larger.
	"""

	def set_default(x, default):
	return x if x is not None else default

	# Figure out what the absolute tolerance should be. ``self.abs`` is
	# either None or a value specified by the user.
	absolute_tolerance = set_default(self.abs, self.DEFAULT_ABSOLUTE_TOLERANCE)

	if absolute_tolerance < 0:
	raise ValueError(
	f"absolute tolerance can't be negative: {absolute_tolerance}"
	)
	if math.isnan(absolute_tolerance):
	raise ValueError("absolute tolerance can't be NaN.")

	# If the user specified an absolute tolerance but not a relative one,
	# just return the absolute tolerance.
	if self.rel is None:
	if self.abs is not None:
	return absolute_tolerance

	# Figure out what the relative tolerance should be. ``self.rel`` is
	# either None or a value specified by the user. This is done after
	# we've made sure the user didn't ask for an absolute tolerance only,
	# because we don't want to raise errors about the relative tolerance if
	# we aren't even going to use it.
	relative_tolerance = set_default(
	self.rel, self.DEFAULT_RELATIVE_TOLERANCE
	) * abs(self.expected)

	if relative_tolerance < 0:
	raise ValueError(
	f"relative tolerance can't be negative: {relative_tolerance}"
	)
	if math.isnan(relative_tolerance):
	raise ValueError("relative tolerance can't be NaN.")

	# Return the larger of the relative and absolute tolerances.
	return max(relative_tolerance, absolute_tolerance)


	class ApproxDecimal(ApproxScalar):
	"""Perform approximate comparisons where the expected value is a Decimal."""

	DEFAULT_ABSOLUTE_TOLERANCE = Decimal("1e-12")
	DEFAULT_RELATIVE_TOLERANCE = Decimal("1e-6")

	def __repr__(self) -> str:
	if isinstance(self.rel, float):
	rel = Decimal.from_float(self.rel)
	else:
	rel = self.rel

	if isinstance(self.abs, float):
	abs_ = Decimal.from_float(self.abs)
	else:
	abs_ = self.abs

	tol_str = "???"
	if rel is not None and Decimal("1e-3") <= rel <= Decimal("1e3"):
	tol_str = f"{rel:.1e}"
	elif abs_ is not None:
	tol_str = f"{abs_:.1e}"

	return f"{self.expected} ± {tol_str}"


	def approx(expected, rel=None, abs=None, nan_ok: bool = False) -> ApproxBase:
	"""Assert that two numbers (or two ordered sequences of numbers) are equal to each other
	within some tolerance.

	Due to the :doc:`python:tutorial/floatingpoint`, numbers that we
	would intuitively expect to be equal are not always so::

	>>> 0.1 + 0.2 == 0.3
	False

	This problem is commonly encountered when writing tests, e.g. when making
	sure that floating-point values are what you expect them to be. One way to
	deal with this problem is to assert that two floating-point numbers are
	equal to within some appropriate tolerance::

	>>> abs((0.1 + 0.2) - 0.3) < 1e-6
	True

	However, comparisons like this are tedious to write and difficult to
	understand. Furthermore, absolute comparisons like the one above are
	usually discouraged because there's no tolerance that works well for all
	situations. ``1e-6`` is good for numbers around ``1``, but too small for
	very big numbers and too big for very small ones. It's better to express
	the tolerance as a fraction of the expected value, but relative comparisons
	like that are even more difficult to write correctly and concisely.

	The ``approx`` class performs floating-point comparisons using a syntax
	that's as intuitive as possible::

	>>> from pytest import approx
	>>> 0.1 + 0.2 == approx(0.3)
	True

	The same syntax also works for ordered sequences of numbers::

	>>> (0.1 + 0.2, 0.2 + 0.4) == approx((0.3, 0.6))
	True

	``numpy`` arrays::

	>>> import numpy as np # doctest: +SKIP
	>>> np.array([0.1, 0.2]) + np.array([0.2, 0.4]) == approx(np.array([0.3, 0.6])) # doctest: +SKIP
	True

	And for a ``numpy`` array against a scalar::

	>>> import numpy as np # doctest: +SKIP
	>>> np.array([0.1, 0.2]) + np.array([0.2, 0.1]) == approx(0.3) # doctest: +SKIP
	True

	Only ordered sequences are supported, because ``approx`` needs
	to infer the relative position of the sequences without ambiguity. This means
	``sets`` and other unordered sequences are not supported.

	Finally, dictionary values can also be compared::

	>>> {'a': 0.1 + 0.2, 'b': 0.2 + 0.4} == approx({'a': 0.3, 'b': 0.6})
	True

	The comparison will be true if both mappings have the same keys and their
	respective values match the expected tolerances.

	Tolerances

	By default, ``approx`` considers numbers within a relative tolerance of
	``1e-6`` (i.e. one part in a million) of its expected value to be equal.
	This treatment would lead to surprising results if the expected value was
	``0.0``, because nothing but ``0.0`` itself is relatively close to ``0.0``.
	To handle this case less surprisingly, ``approx`` also considers numbers
	within an absolute tolerance of ``1e-12`` of its expected value to be
	equal. Infinity and NaN are special cases. Infinity is only considered
	equal to itself, regardless of the relative tolerance. NaN is not
	considered equal to anything by default, but you can make it be equal to
	itself by setting the ``nan_ok`` argument to True. (This is meant to
	facilitate comparing arrays that use NaN to mean "no data".)

	Both the relative and absolute tolerances can be changed by passing
	arguments to the ``approx`` constructor::

	>>> 1.0001 == approx(1)
	False
	>>> 1.0001 == approx(1, rel=1e-3)
	True
	>>> 1.0001 == approx(1, abs=1e-3)
	True

	If you specify ``abs`` but not ``rel``, the comparison will not consider
	the relative tolerance at all. In other words, two numbers that are within
	the default relative tolerance of ``1e-6`` will still be considered unequal
	if they exceed the specified absolute tolerance. If you specify both
	``abs`` and ``rel``, the numbers will be considered equal if either
	tolerance is met::

	>>> 1 + 1e-8 == approx(1)
	True
	>>> 1 + 1e-8 == approx(1, abs=1e-12)
	False
	>>> 1 + 1e-8 == approx(1, rel=1e-6, abs=1e-12)
	True

	Non-numeric types

	You can also use ``approx`` to compare non-numeric types, or dicts and
	sequences containing non-numeric types, in which case it falls back to
	strict equality. This can be useful for comparing dicts and sequences that
	can contain optional values::

	>>> {"required": 1.0000005, "optional": None} == approx({"required": 1, "optional": None})
	True
	>>> [None, 1.0000005] == approx([None,1])
	True
	>>> ["foo", 1.0000005] == approx([None,1])
	False

	If you're thinking about using ``approx``, then you might want to know how
	it compares to other good ways of comparing floating-point numbers. All of
	these algorithms are based on relative and absolute tolerances and should
	agree for the most part, but they do have meaningful differences:

	- ``math.isclose(a, b, rel_tol=1e-9, abs_tol=0.0)``: True if the relative
	tolerance is met w.r.t. either ``a`` or ``b`` or if the absolute
	tolerance is met. Because the relative tolerance is calculated w.r.t.
	both ``a`` and ``b``, this test is symmetric (i.e. neither ``a`` nor
	``b`` is a "reference value"). You have to specify an absolute tolerance
	if you want to compare to ``0.0`` because there is no tolerance by
	default. More information: :py:func:`math.isclose`.

	- ``numpy.isclose(a, b, rtol=1e-5, atol=1e-8)``: True if the difference
	between ``a`` and ``b`` is less that the sum of the relative tolerance
	w.r.t. ``b`` and the absolute tolerance. Because the relative tolerance
	is only calculated w.r.t. ``b``, this test is asymmetric and you can
	think of ``b`` as the reference value. Support for comparing sequences
	is provided by :py:func:`numpy.allclose`. More information:
	:std:doc:`numpy:reference/generated/numpy.isclose`.

	- ``unittest.TestCase.assertAlmostEqual(a, b)``: True if ``a`` and ``b``
	are within an absolute tolerance of ``1e-7``. No relative tolerance is
	considered , so this function is not appropriate for very large or very
	small numbers. Also, it's only available in subclasses of ``unittest.TestCase``
	and it's ugly because it doesn't follow PEP8. More information:
	:py:meth:`unittest.TestCase.assertAlmostEqual`.

	- ``a == pytest.approx(b, rel=1e-6, abs=1e-12)``: True if the relative
	tolerance is met w.r.t. ``b`` or if the absolute tolerance is met.
	Because the relative tolerance is only calculated w.r.t. ``b``, this test
	is asymmetric and you can think of ``b`` as the reference value. In the
	special case that you explicitly specify an absolute tolerance but not a
	relative tolerance, only the absolute tolerance is considered.

	.. note::

	``approx`` can handle numpy arrays, but we recommend the
	specialised test helpers in :std:doc:`numpy:reference/routines.testing`
	if you need support for comparisons, NaNs, or ULP-based tolerances.

	To match strings using regex, you can use
	`Matches <https://github.com/asottile/re-assert#re_assertmatchespattern-str-args-kwargs>`_
	from the
	`re_assert package <https://github.com/asottile/re-assert>`_.


	.. note::

	Unlike built-in equality, this function considers
	booleans unequal to numeric zero or one. For example::

	>>> 1 == approx(True)
	False

	.. warning::

	.. versionchanged:: 3.2

	In order to avoid inconsistent behavior, :py:exc:`TypeError` is
	raised for ``>``, ``>=``, ``<`` and ``<=`` comparisons.
	The example below illustrates the problem::

	assert approx(0.1) > 0.1 + 1e-10 # calls approx(0.1).__gt__(0.1 + 1e-10)
	assert 0.1 + 1e-10 > approx(0.1) # calls approx(0.1).__lt__(0.1 + 1e-10)

	In the second example one expects ``approx(0.1).__le__(0.1 + 1e-10)``
	to be called. But instead, ``approx(0.1).__lt__(0.1 + 1e-10)`` is used to
	comparison. This is because the call hierarchy of rich comparisons
	follows a fixed behavior. More information: :py:meth:`object.__ge__`

	.. versionchanged:: 3.7.1
	``approx`` raises ``TypeError`` when it encounters a dict value or
	sequence element of non-numeric type.

	.. versionchanged:: 6.1.0
	``approx`` falls back to strict equality for non-numeric types instead
	of raising ``TypeError``.
	"""
	# Delegate the comparison to a class that knows how to deal with the type
	# of the expected value (e.g. int, float, list, dict, numpy.array, etc).
	#
	# The primary responsibility of these classes is to implement ``__eq__()``
	# and ``__repr__()``. The former is used to actually check if some
	# "actual" value is equivalent to the given expected value within the
	# allowed tolerance. The latter is used to show the user the expected
	# value and tolerance, in the case that a test failed.
	#
	# The actual logic for making approximate comparisons can be found in
	# ApproxScalar, which is used to compare individual numbers. All of the
	# other Approx classes eventually delegate to this class. The ApproxBase
	# class provides some convenient methods and overloads, but isn't really
	# essential.

	__tracebackhide__ = True

	if isinstance(expected, Decimal):
	cls: type[ApproxBase] = ApproxDecimal
	elif isinstance(expected, Mapping):
	cls = ApproxMapping
	elif _is_numpy_array(expected):
	expected = _as_numpy_array(expected)
	cls = ApproxNumpy
	elif _is_sequence_like(expected):
	cls = ApproxSequenceLike
	elif isinstance(expected, Collection) and not isinstance(expected, (str, bytes)):
	msg = f"pytest.approx() only supports ordered sequences, but got: {expected!r}"
	raise TypeError(msg)
	else:
	cls = ApproxScalar

	return cls(expected, rel, abs, nan_ok)


	def _is_sequence_like(expected: object) -> bool:
	return (
	hasattr(expected, "__getitem__")
	and isinstance(expected, Sized)
	and not isinstance(expected, (str, bytes))
	)


	def _is_numpy_array(obj: object) -> bool:
	"""
	Return true if the given object is implicitly convertible to ndarray,
	and numpy is already imported.
	"""
	return _as_numpy_array(obj) is not None


	def _as_numpy_array(obj: object) -> ndarray \| None:
	"""
	Return an ndarray if the given object is implicitly convertible to ndarray,
	and numpy is already imported, otherwise None.
	"""
	np: Any = sys.modules.get("numpy")
	if np is not None:
	# avoid infinite recursion on numpy scalars, which have __array__
	if np.isscalar(obj):
	return None
	elif isinstance(obj, np.ndarray):
	return obj
	elif hasattr(obj, "__array__") or hasattr("obj", "__array_interface__"):
	return np.asarray(obj)
	return None