The assertAlmostEqual(x, y) method in Python's unit testing framework tests whether x and y are approximately equal assuming they are floats.

The problem with assertAlmostEqual() is that it only works on floats. I'm looking for a method like assertAlmostEqual() which works on lists of floats, sets of floats, dictionaries of floats, tuples of floats, lists of tuples of floats, sets of lists of floats, etc.

For instance, let x = 0.1234567890, y = 0.1234567891. x and y are almost equal because they agree on each and every digit except for the last one. Therefore self.assertAlmostEqual(x, y) is True because assertAlmostEqual() works for floats.

I'm looking for a more generic assertAlmostEquals() which also evaluates the following calls to True:

  • self.assertAlmostEqual_generic([x, x, x], [y, y, y]).
  • self.assertAlmostEqual_generic({1: x, 2: x, 3: x}, {1: y, 2: y, 3: y}).
  • self.assertAlmostEqual_generic([(x,x)], [(y,y)]).

Is there such a method or do I have to implement it myself?


  • assertAlmostEquals() has an optional parameter named places and the numbers are compared by computing the difference rounded to number of decimal places. By default places=7, hence self.assertAlmostEqual(0.5, 0.4) is False while self.assertAlmostEqual(0.12345678, 0.12345679) is True. My speculative assertAlmostEqual_generic() should have the same functionality.

  • Two lists are considered almost equal if they have almost equal numbers in exactly the same order. formally, for i in range(n): self.assertAlmostEqual(list1[i], list2[i]).

  • Similarly, two sets are considered almost equal if they can be converted to almost equal lists (by assigning an order to each set).

  • Similarly, two dictionaries are considered almost equal if the key set of each dictionary is almost equal to the key set of the other dictionary, and for each such almost equal key pair there's a corresponding almost equal value.

  • In general: I consider two collections almost equal if they're equal except for some corresponding floats which are just almost equal to each other. In other words, I would like to really compare objects but with a low (customized) precision when comparing floats along the way.

  • What's the point of using float keys in the dictionary? Since you can't be sure to get precisely the same float, you'll never find your items using lookup. And if you're not using lookup, why not just use a list of tuples instead of dictionary? The same argument applies to sets. – max Jan 15 '19 at 4:16
  • Just a link to the source for assertAlmostEqual. – djvg Nov 6 '19 at 10:05

if you don't mind using NumPy (which comes with your Python(x,y)), you may want to look at the np.testing module which defines, among others, a assert_almost_equal function.

The signature is np.testing.assert_almost_equal(actual, desired, decimal=7, err_msg='', verbose=True)

>>> x = 1.000001
>>> y = 1.000002
>>> np.testing.assert_almost_equal(x, y)
Arrays are not almost equal to 7 decimals
ACTUAL: 1.000001
DESIRED: 1.000002
>>> np.testing.assert_almost_equal(x, y, 5)
>>> np.testing.assert_almost_equal([x, x, x], [y, y, y], 5)
>>> np.testing.assert_almost_equal((x, x, x), (y, y, y), 5)
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  • 3
    That's close, but numpy.testing almost-equal methods work only on numbers, arrays, tuples and lists. They do not work on dictionaries, sets and collections of collections. – snakile Aug 27 '12 at 10:31
  • Indeed, but that's a start. Besides, you have access to the source code that you can modify to allow the comparison of dictionaries, collections and so forth. np.testing.assert_equal does recognize dictionaries as arguments, for example (even if the comparison is done by a == which won't work for you). – Pierre GM Aug 27 '12 at 10:46
  • Of course, you'll still run into troubles when comparing sets, as @BrenBarn mentioned. – Pierre GM Aug 27 '12 at 10:47
  • Note that the current documentation of assert_array_almost_equal recommends using assert_allclose, assert_array_almost_equal_nulp or assert_array_max_ulp instead. – phunehehe Nov 10 '19 at 3:04

Here's how I've implemented a generic is_almost_equal(first, second) function:

First, duplicate the objects you need to compare (first and second), but don't make an exact copy: cut the insignificant decimal digits of any float you encounter inside the object.

Now that you have copies of first and second for which the insignificant decimal digits are gone, just compare first and second using the == operator.

Let's assume we have a cut_insignificant_digits_recursively(obj, places) function which duplicates obj but leaves only the places most significant decimal digits of each float in the original obj. Here's a working implementation of is_almost_equals(first, second, places):

from insignificant_digit_cutter import cut_insignificant_digits_recursively

def is_almost_equal(first, second, places):
    '''returns True if first and second equal. 
    returns true if first and second aren't equal but have exactly the same
    structure and values except for a bunch of floats which are just almost
    equal (floats are almost equal if they're equal when we consider only the
    [places] most significant digits of each).'''
    if first == second: return True
    cut_first = cut_insignificant_digits_recursively(first, places)
    cut_second = cut_insignificant_digits_recursively(second, places)
    return cut_first == cut_second

And here's a working implementation of cut_insignificant_digits_recursively(obj, places):

def cut_insignificant_digits(number, places):
    '''cut the least significant decimal digits of a number, 
    leave only [places] decimal digits'''
    if  type(number) != float: return number
    number_as_str = str(number)
    end_of_number = number_as_str.find('.')+places+1
    if end_of_number > len(number_as_str): return number
    return float(number_as_str[:end_of_number])

def cut_insignificant_digits_lazy(iterable, places):
    for obj in iterable:
        yield cut_insignificant_digits_recursively(obj, places)

def cut_insignificant_digits_recursively(obj, places):
    '''return a copy of obj except that every float loses its least significant 
    decimal digits remaining only [places] decimal digits'''
    t = type(obj)
    if t == float: return cut_insignificant_digits(obj, places)
    if t in (list, tuple, set):
        return t(cut_insignificant_digits_lazy(obj, places))
    if t == dict:
        return {cut_insignificant_digits_recursively(key, places):
                cut_insignificant_digits_recursively(val, places)
                for key,val in obj.items()}
    return obj

The code and its unit tests are available here: https://github.com/snakile/approximate_comparator. I welcome any improvement and bug fix.

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  • Instead of comparing floats, you're comparing strings? OK... But then, wouldn't it be easier to set a common format? Like fmt="{{0:{0}f}}".format(decimals), and use this fmt format to "stringify" your floats? – Pierre GM Aug 27 '12 at 15:04
  • 1
    This looks nice, but a small point: places gives the number of decimal places, not the number of significant figures. For example, comparing 1024.123 and 1023.999 to 3 significant should return equal, but to 3 decimal places they're not. – Rodney Richardson Dec 17 '14 at 17:23
  • 1
    @pir, the license is indeed undefined. See snalile's answer in this issue in which he says he doesn't have time to choose/add a license, but grants use/modification permissions. Thanks for sharing this, BTW. – Jérôme Feb 27 '17 at 14:32
  • 1
    @RodneyRichardson, yes this is decimal places, like in assertAlmostEqual: "Note that these methods round the values to the given number of decimal places (i.e. like the round() function) and not significant digits." – Jérôme Feb 27 '17 at 14:40
  • 2
    @Jérôme, thanks for the comment. I've just added an MIT license. – snakile Feb 27 '17 at 14:55

As of python 3.5 you may compare using

math.isclose(a, b, rel_tol=1e-9, abs_tol=0.0)

As described in pep-0485. The implementation should be equivalent to

abs(a-b) <= max( rel_tol * max(abs(a), abs(b)), abs_tol )
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  • 7
    How does this helps compare containers with floats, which the question was asking about? – max Jan 15 '19 at 4:14

If you don't mind using the numpy package then numpy.testing has the assert_array_almost_equal method.

This works for array_like objects, so it is fine for arrays, lists and tuples of floats, but does it not work for sets and dictionaries.

The documentation is here.

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There is no such method, you'd have to do it yourself.

For lists and tuples the definition is obvious, but note that the other cases you mention aren't obvious, so it's no wonder such a function isn't provided. For instance, is {1.00001: 1.00002} almost equal to {1.00002: 1.00001}? Handling such cases requires making a choice about whether closeness depends on keys or values or both. For sets you are unlikely to find a meaningful definition, since sets are unordered, so there is no notion of "corresponding" elements.

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  • BrenBarn: I've added clarifications to the question. The answer to your question is that {1.00001: 1.00002} almost equals {1.00002: 1.00001} if and only if 1.00001 almost equals 1.00002. By default they do not almost equal (because the default precision is 7 decimal places) but for a small enough value for places they do almost equal. – snakile Aug 27 '12 at 6:49
  • 1
    @BrenBarn: IMO, the use of keys of type float in dict should be discouraged (and maybe even disallowed) for obvious reasons. Approximate equality of dict should be based on values only; the test framework need not worry about the incorrect usage of float for keys. For sets, they can be sorted before comparison, and sorted lists can be compared. – max Jan 15 '19 at 4:10

You may have to implement it yourself, while its true that list and sets can be iterated the same way, dictionaries are a different story, you iterate their keys not values, and the third example seems a bit ambiguous to me, do you mean to compare each value within the set, or each value from each set.

heres a simple code snippet.

def almost_equal(value_1, value_2, accuracy = 10**-8):
    return abs(value_1 - value_2) < accuracy

x = [1,2,3,4]
y = [1,2,4,5]
assert all(almost_equal(*values) for values in zip(x, y))
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  • Thanks, the solution is correct for lists and tuples but not for other types of collections (or nested collections). See the clarifications I've added to the question. I hope my intention is clear now. Two sets are almost equal if they would have been considered equal in a world where numbers aren't measured very precisely. – snakile Aug 27 '12 at 7:04

None of these answers work for me. The following code should work for python collections, classes, dataclasses, and namedtuples. I might have forgotten something, but so far this works for me.

import unittest
from collections import namedtuple, OrderedDict
from dataclasses import dataclass
from typing import Any

def are_almost_equal(o1: Any, o2: Any, max_abs_ratio_diff: float, max_abs_diff: float) -> bool:
    Compares two objects by recursively walking them trough. Equality is as usual except for floats.
    Floats are compared according to the two measures defined below.

    :param o1: The first object.
    :param o2: The second object.
    :param max_abs_ratio_diff: The maximum allowed absolute value of the difference.
    `abs(1 - (o1 / o2)` and vice-versa if o2 == 0.0. Ignored if < 0.
    :param max_abs_diff: The maximum allowed absolute difference `abs(o1 - o2)`. Ignored if < 0.
    :return: Whether the two objects are almost equal.
    if type(o1) != type(o2):
        return False

    composite_type_passed = False

    if hasattr(o1, '__slots__'):
        if len(o1.__slots__) != len(o2.__slots__):
            return False
        if any(not are_almost_equal(getattr(o1, s1), getattr(o2, s2),
                                    max_abs_ratio_diff, max_abs_diff)
            for s1, s2 in zip(sorted(o1.__slots__), sorted(o2.__slots__))):
            return False
            composite_type_passed = True

    if hasattr(o1, '__dict__'):
        if len(o1.__dict__) != len(o2.__dict__):
            return False
        if any(not are_almost_equal(k1, k2, max_abs_ratio_diff, max_abs_diff)
            or not are_almost_equal(v1, v2, max_abs_ratio_diff, max_abs_diff)
            for ((k1, v1), (k2, v2))
            in zip(sorted(o1.__dict__.items()), sorted(o2.__dict__.items()))
            if not k1.startswith('__')):  # avoid infinite loops
            return False
            composite_type_passed = True

    if isinstance(o1, dict):
        if len(o1) != len(o2):
            return False
        if any(not are_almost_equal(k1, k2, max_abs_ratio_diff, max_abs_diff)
            or not are_almost_equal(v1, v2, max_abs_ratio_diff, max_abs_diff)
            for ((k1, v1), (k2, v2)) in zip(sorted(o1.items()), sorted(o2.items()))):
            return False

    elif any(issubclass(o1.__class__, c) for c in (list, tuple, set)):
        if len(o1) != len(o2):
            return False
        if any(not are_almost_equal(v1, v2, max_abs_ratio_diff, max_abs_diff)
            for v1, v2 in zip(o1, o2)):
            return False

    elif isinstance(o1, float):
        if o1 == o2:
            return True
            if max_abs_ratio_diff > 0:  # if max_abs_ratio_diff < 0, max_abs_ratio_diff is ignored
                if o2 != 0:
                    if abs(1.0 - (o1 / o2)) > max_abs_ratio_diff:
                        return False
                else:  # if both == 0, we already returned True
                    if abs(1.0 - (o2 / o1)) > max_abs_ratio_diff:
                        return False
            if 0 < max_abs_diff < abs(o1 - o2):  # if max_abs_diff < 0, max_abs_diff is ignored
                return False
            return True

        if not composite_type_passed:
            return o1 == o2

    return True

class EqualityTest(unittest.TestCase):

    def test_floats(self) -> None:
        o1 = ('hi', 3, 3.4)
        o2 = ('hi', 3, 3.400001)
        self.assertTrue(are_almost_equal(o1, o2, 0.0001, 0.0001))
        self.assertFalse(are_almost_equal(o1, o2, 0.00000001, 0.00000001))

    def test_ratio_only(self):
        o1 = ['hey', 10000, 123.12]
        o2 = ['hey', 10000, 123.80]
        self.assertTrue(are_almost_equal(o1, o2, 0.01, -1))
        self.assertFalse(are_almost_equal(o1, o2, 0.001, -1))

    def test_diff_only(self):
        o1 = ['hey', 10000, 1234567890.12]
        o2 = ['hey', 10000, 1234567890.80]
        self.assertTrue(are_almost_equal(o1, o2, -1, 1))
        self.assertFalse(are_almost_equal(o1, o2, -1, 0.1))

    def test_both_ignored(self):
        o1 = ['hey', 10000, 1234567890.12]
        o2 = ['hey', 10000, 0.80]
        o3 = ['hi', 10000, 0.80]
        self.assertTrue(are_almost_equal(o1, o2, -1, -1))
        self.assertFalse(are_almost_equal(o1, o3, -1, -1))

    def test_different_lengths(self):
        o1 = ['hey', 1234567890.12, 10000]
        o2 = ['hey', 1234567890.80]
        self.assertFalse(are_almost_equal(o1, o2, 1, 1))

    def test_classes(self):
        class A:
            d = 12.3

            def __init__(self, a, b, c):
                self.a = a
                self.b = b
                self.c = c

        o1 = A(2.34, 'str', {1: 'hey', 345.23: [123, 'hi', 890.12]})
        o2 = A(2.34, 'str', {1: 'hey', 345.231: [123, 'hi', 890.121]})
        self.assertTrue(are_almost_equal(o1, o2, 0.1, 0.1))
        self.assertFalse(are_almost_equal(o1, o2, 0.0001, 0.0001))

        o2.hello = 'hello'
        self.assertFalse(are_almost_equal(o1, o2, -1, -1))

    def test_namedtuples(self):
        B = namedtuple('B', ['x', 'y'])
        o1 = B(3.3, 4.4)
        o2 = B(3.4, 4.5)
        self.assertTrue(are_almost_equal(o1, o2, 0.2, 0.2))
        self.assertFalse(are_almost_equal(o1, o2, 0.001, 0.001))

    def test_classes_with_slots(self):
        class C(object):
            __slots__ = ['a', 'b']

            def __init__(self, a, b):
                self.a = a
                self.b = b

        o1 = C(3.3, 4.4)
        o2 = C(3.4, 4.5)
        self.assertTrue(are_almost_equal(o1, o2, 0.3, 0.3))
        self.assertFalse(are_almost_equal(o1, o2, -1, 0.01))

    def test_dataclasses(self):
        class D:
            s: str
            i: int
            f: float

        class E:
            f2: float
            f4: str
            d: D

        o1 = E(12.3, 'hi', D('hello', 34, 20.01))
        o2 = E(12.1, 'hi', D('hello', 34, 20.0))
        self.assertTrue(are_almost_equal(o1, o2, -1, 0.4))
        self.assertFalse(are_almost_equal(o1, o2, -1, 0.001))

        o3 = E(12.1, 'hi', D('ciao', 34, 20.0))
        self.assertFalse(are_almost_equal(o2, o3, -1, -1))

    def test_ordereddict(self):
        o1 = OrderedDict({1: 'hey', 345.23: [123, 'hi', 890.12]})
        o2 = OrderedDict({1: 'hey', 345.23: [123, 'hi', 890.0]})
        self.assertTrue(are_almost_equal(o1, o2, 0.01, -1))
        self.assertFalse(are_almost_equal(o1, o2, 0.0001, -1))
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I would still use self.assertEqual() for it stays the most informative when shit hits the fan. You can do that by rounding, eg.

self.assertEqual(round_tuple((13.949999999999999, 1.121212), 2), (13.95, 1.12))

where round_tuple is

def round_tuple(t: tuple, ndigits: int) -> tuple:
    return tuple(round(e, ndigits=ndigits) for e in t)

def round_list(l: list, ndigits: int) -> list:
    return [round(e, ndigits=ndigits) for e in l]

According to the python docs (see https://stackoverflow.com/a/41407651/1031191) you can get away with rounding issues like 13.94999999, because 13.94999999 == 13.95 is True.

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An alternative approach is to convert your data into a comparable form by e.g turning each float into a string with fixed precision.

def comparable(data):
    """Converts `data` to a comparable structure by converting any floats to a string with fixed precision."""
    if isinstance(data, (int, str)):
        return data
    if isinstance(data, float):
        return '{:.4f}'.format(data)
    if isinstance(data, list):
        return [comparable(el) for el in data]
    if isinstance(data, tuple):
        return tuple([comparable(el) for el in data])
    if isinstance(data, dict):
        return {k: comparable(v) for k, v in data.items()}

Then you can:

self.assertEquals(comparable(value1), comparable(value2))
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