Filename: //lib//python3/dist-packages/more_itertools/tests/test_more.py

from __future__ import division, print_function, unicode_literals from decimal import Decimal from doctest import DocTestSuite from fractions import Fraction from functools import partial, reduce from heapq import merge from io import StringIO from itertools import ( chain, count, groupby, islice, permutations, product, repeat, ) from operator import add, mul, itemgetter from unittest import TestCase from six.moves import filter, map, range, zip import more_itertools as mi def load_tests(loader, tests, ignore): # Add the doctests tests.addTests(DocTestSuite('more_itertools.more')) return tests class CollateTests(TestCase): """Unit tests for ``collate()``""" # Also accidentally tests peekable, though that could use its own tests def test_default(self): """Test with the default `key` function.""" iterables = [range(4), range(7), range(3, 6)] self.assertEqual( sorted(reduce(list.__add__, [list(it) for it in iterables])), list(mi.collate(*iterables)) ) def test_key(self): """Test using a custom `key` function.""" iterables = [range(5, 0, -1), range(4, 0, -1)] actual = sorted( reduce(list.__add__, [list(it) for it in iterables]), reverse=True ) expected = list(mi.collate(*iterables, key=lambda x: -x)) self.assertEqual(actual, expected) def test_empty(self): """Be nice if passed an empty list of iterables.""" self.assertEqual([], list(mi.collate())) def test_one(self): """Work when only 1 iterable is passed.""" self.assertEqual([0, 1], list(mi.collate(range(2)))) def test_reverse(self): """Test the `reverse` kwarg.""" iterables = [range(4, 0, -1), range(7, 0, -1), range(3, 6, -1)] actual = sorted( reduce(list.__add__, [list(it) for it in iterables]), reverse=True ) expected = list(mi.collate(*iterables, reverse=True)) self.assertEqual(actual, expected) def test_alias(self): self.assertNotEqual(merge.__doc__, mi.collate.__doc__) self.assertNotEqual(partial.__doc__, mi.collate.__doc__) class ChunkedTests(TestCase): """Tests for ``chunked()``""" def test_even(self): """Test when ``n`` divides evenly into the length of the iterable.""" self.assertEqual( list(mi.chunked('ABCDEF', 3)), [['A', 'B', 'C'], ['D', 'E', 'F']] ) def test_odd(self): """Test when ``n`` does not divide evenly into the length of the iterable. """ self.assertEqual( list(mi.chunked('ABCDE', 3)), [['A', 'B', 'C'], ['D', 'E']] ) class FirstTests(TestCase): """Tests for ``first()``""" def test_many(self): """Test that it works on many-item iterables.""" # Also try it on a generator expression to make sure it works on # whatever those return, across Python versions. self.assertEqual(mi.first(x for x in range(4)), 0) def test_one(self): """Test that it doesn't raise StopIteration prematurely.""" self.assertEqual(mi.first([3]), 3) def test_empty_stop_iteration(self): """It should raise StopIteration for empty iterables.""" self.assertRaises(ValueError, lambda: mi.first([])) def test_default(self): """It should return the provided default arg for empty iterables.""" self.assertEqual(mi.first([], 'boo'), 'boo') class PeekableTests(TestCase): """Tests for ``peekable()`` behavor not incidentally covered by testing ``collate()`` """ def test_peek_default(self): """Make sure passing a default into ``peek()`` works.""" p = mi.peekable([]) self.assertEqual(p.peek(7), 7) def test_truthiness(self): """Make sure a ``peekable`` tests true iff there are items remaining in the iterable. """ p = mi.peekable([]) self.assertFalse(p) p = mi.peekable(range(3)) self.assertTrue(p) def test_simple_peeking(self): """Make sure ``next`` and ``peek`` advance and don't advance the iterator, respectively. """ p = mi.peekable(range(10)) self.assertEqual(next(p), 0) self.assertEqual(p.peek(), 1) self.assertEqual(next(p), 1) def test_indexing(self): """ Indexing into the peekable shouldn't advance the iterator. """ p = mi.peekable('abcdefghijkl') # The 0th index is what ``next()`` will return self.assertEqual(p[0], 'a') self.assertEqual(next(p), 'a') # Indexing further into the peekable shouldn't advance the itertor self.assertEqual(p[2], 'd') self.assertEqual(next(p), 'b') # The 0th index moves up with the iterator; the last index follows self.assertEqual(p[0], 'c') self.assertEqual(p[9], 'l') self.assertEqual(next(p), 'c') self.assertEqual(p[8], 'l') # Negative indexing should work too self.assertEqual(p[-2], 'k') self.assertEqual(p[-9], 'd') self.assertRaises(IndexError, lambda: p[-10]) def test_slicing(self): """Slicing the peekable shouldn't advance the iterator.""" seq = list('abcdefghijkl') p = mi.peekable(seq) # Slicing the peekable should just be like slicing a re-iterable self.assertEqual(p[1:4], seq[1:4]) # Advancing the iterator moves the slices up also self.assertEqual(next(p), 'a') self.assertEqual(p[1:4], seq[1:][1:4]) # Implicit starts and stop should work self.assertEqual(p[:5], seq[1:][:5]) self.assertEqual(p[:], seq[1:][:]) # Indexing past the end should work self.assertEqual(p[:100], seq[1:][:100]) # Steps should work, including negative self.assertEqual(p[::2], seq[1:][::2]) self.assertEqual(p[::-1], seq[1:][::-1]) def test_slicing_reset(self): """Test slicing on a fresh iterable each time""" iterable = ['0', '1', '2', '3', '4', '5'] indexes = list(range(-4, len(iterable) + 4)) + [None] steps = [1, 2, 3, 4, -1, -2, -3, 4] for slice_args in product(indexes, indexes, steps): it = iter(iterable) p = mi.peekable(it) next(p) index = slice(*slice_args) actual = p[index] expected = iterable[1:][index] self.assertEqual(actual, expected, slice_args) def test_slicing_error(self): iterable = '01234567' p = mi.peekable(iter(iterable)) # Prime the cache p.peek() old_cache = list(p._cache) # Illegal slice with self.assertRaises(ValueError): p[1:-1:0] # Neither the cache nor the iteration should be affected self.assertEqual(old_cache, list(p._cache)) self.assertEqual(list(p), list(iterable)) def test_passthrough(self): """Iterating a peekable without using ``peek()`` or ``prepend()`` should just give the underlying iterable's elements (a trivial test but useful to set a baseline in case something goes wrong)""" expected = [1, 2, 3, 4, 5] actual = list(mi.peekable(expected)) self.assertEqual(actual, expected) # prepend() behavior tests def test_prepend(self): """Tests intersperesed ``prepend()`` and ``next()`` calls""" it = mi.peekable(range(2)) actual = [] # Test prepend() before next() it.prepend(10) actual += [next(it), next(it)] # Test prepend() between next()s it.prepend(11) actual += [next(it), next(it)] # Test prepend() after source iterable is consumed it.prepend(12) actual += [next(it)] expected = [10, 0, 11, 1, 12] self.assertEqual(actual, expected) def test_multi_prepend(self): """Tests prepending multiple items and getting them in proper order""" it = mi.peekable(range(5)) actual = [next(it), next(it)] it.prepend(10, 11, 12) it.prepend(20, 21) actual += list(it) expected = [0, 1, 20, 21, 10, 11, 12, 2, 3, 4] self.assertEqual(actual, expected) def test_empty(self): """Tests prepending in front of an empty iterable""" it = mi.peekable([]) it.prepend(10) actual = list(it) expected = [10] self.assertEqual(actual, expected) def test_prepend_truthiness(self): """Tests that ``__bool__()`` or ``__nonzero__()`` works properly with ``prepend()``""" it = mi.peekable(range(5)) self.assertTrue(it) actual = list(it) self.assertFalse(it) it.prepend(10) self.assertTrue(it) actual += [next(it)] self.assertFalse(it) expected = [0, 1, 2, 3, 4, 10] self.assertEqual(actual, expected) def test_multi_prepend_peek(self): """Tests prepending multiple elements and getting them in reverse order while peeking""" it = mi.peekable(range(5)) actual = [next(it), next(it)] self.assertEqual(it.peek(), 2) it.prepend(10, 11, 12) self.assertEqual(it.peek(), 10) it.prepend(20, 21) self.assertEqual(it.peek(), 20) actual += list(it) self.assertFalse(it) expected = [0, 1, 20, 21, 10, 11, 12, 2, 3, 4] self.assertEqual(actual, expected) def test_prepend_after_stop(self): """Test resuming iteration after a previous exhaustion""" it = mi.peekable(range(3)) self.assertEqual(list(it), [0, 1, 2]) self.assertRaises(StopIteration, lambda: next(it)) it.prepend(10) self.assertEqual(next(it), 10) self.assertRaises(StopIteration, lambda: next(it)) def test_prepend_slicing(self): """Tests interaction between prepending and slicing""" seq = list(range(20)) p = mi.peekable(seq) p.prepend(30, 40, 50) pseq = [30, 40, 50] + seq # pseq for prepended_seq # adapt the specific tests from test_slicing self.assertEqual(p[0], 30) self.assertEqual(p[1:8], pseq[1:8]) self.assertEqual(p[1:], pseq[1:]) self.assertEqual(p[:5], pseq[:5]) self.assertEqual(p[:], pseq[:]) self.assertEqual(p[:100], pseq[:100]) self.assertEqual(p[::2], pseq[::2]) self.assertEqual(p[::-1], pseq[::-1]) def test_prepend_indexing(self): """Tests interaction between prepending and indexing""" seq = list(range(20)) p = mi.peekable(seq) p.prepend(30, 40, 50) self.assertEqual(p[0], 30) self.assertEqual(next(p), 30) self.assertEqual(p[2], 0) self.assertEqual(next(p), 40) self.assertEqual(p[0], 50) self.assertEqual(p[9], 8) self.assertEqual(next(p), 50) self.assertEqual(p[8], 8) self.assertEqual(p[-2], 18) self.assertEqual(p[-9], 11) self.assertRaises(IndexError, lambda: p[-21]) def test_prepend_iterable(self): """Tests prepending from an iterable""" it = mi.peekable(range(5)) # Don't directly use the range() object to avoid any range-specific # optimizations it.prepend(*(x for x in range(5))) actual = list(it) expected = list(chain(range(5), range(5))) self.assertEqual(actual, expected) def test_prepend_many(self): """Tests that prepending a huge number of elements works""" it = mi.peekable(range(5)) # Don't directly use the range() object to avoid any range-specific # optimizations it.prepend(*(x for x in range(20000))) actual = list(it) expected = list(chain(range(20000), range(5))) self.assertEqual(actual, expected) def test_prepend_reversed(self): """Tests prepending from a reversed iterable""" it = mi.peekable(range(3)) it.prepend(*reversed((10, 11, 12))) actual = list(it) expected = [12, 11, 10, 0, 1, 2] self.assertEqual(actual, expected) class ConsumerTests(TestCase): """Tests for ``consumer()``""" def test_consumer(self): @mi.consumer def eater(): while True: x = yield # noqa e = eater() e.send('hi') # without @consumer, would raise TypeError class DistinctPermutationsTests(TestCase): def test_distinct_permutations(self): """Make sure the output for ``distinct_permutations()`` is the same as set(permutations(it)). """ iterable = ['z', 'a', 'a', 'q', 'q', 'q', 'y'] test_output = sorted(mi.distinct_permutations(iterable)) ref_output = sorted(set(permutations(iterable))) self.assertEqual(test_output, ref_output) def test_other_iterables(self): """Make sure ``distinct_permutations()`` accepts a different type of iterables. """ # a generator iterable = (c for c in ['z', 'a', 'a', 'q', 'q', 'q', 'y']) test_output = sorted(mi.distinct_permutations(iterable)) # "reload" it iterable = (c for c in ['z', 'a', 'a', 'q', 'q', 'q', 'y']) ref_output = sorted(set(permutations(iterable))) self.assertEqual(test_output, ref_output) # an iterator iterable = iter(['z', 'a', 'a', 'q', 'q', 'q', 'y']) test_output = sorted(mi.distinct_permutations(iterable)) # "reload" it iterable = iter(['z', 'a', 'a', 'q', 'q', 'q', 'y']) ref_output = sorted(set(permutations(iterable))) self.assertEqual(test_output, ref_output) class IlenTests(TestCase): def test_ilen(self): """Sanity-checks for ``ilen()``.""" # Non-empty self.assertEqual( mi.ilen(filter(lambda x: x % 10 == 0, range(101))), 11 ) # Empty self.assertEqual(mi.ilen((x for x in range(0))), 0) # Iterable with __len__ self.assertEqual(mi.ilen(list(range(6))), 6) class WithIterTests(TestCase): def test_with_iter(self): s = StringIO('One fish\nTwo fish') initial_words = [line.split()[0] for line in mi.with_iter(s)] # Iterable's items should be faithfully represented self.assertEqual(initial_words, ['One', 'Two']) # The file object should be closed self.assertEqual(s.closed, True) class OneTests(TestCase): def test_basic(self): it = iter(['item']) self.assertEqual(mi.one(it), 'item') def test_too_short(self): it = iter([]) self.assertRaises(ValueError, lambda: mi.one(it)) self.assertRaises(IndexError, lambda: mi.one(it, too_short=IndexError)) def test_too_long(self): it = count() self.assertRaises(ValueError, lambda: mi.one(it)) # burn 0 and 1 self.assertEqual(next(it), 2) self.assertRaises( OverflowError, lambda: mi.one(it, too_long=OverflowError) ) class IntersperseTest(TestCase): """ Tests for intersperse() """ def test_even(self): iterable = (x for x in '01') self.assertEqual( list(mi.intersperse(None, iterable)), ['0', None, '1'] ) def test_odd(self): iterable = (x for x in '012') self.assertEqual( list(mi.intersperse(None, iterable)), ['0', None, '1', None, '2'] ) def test_nested(self): element = ('a', 'b') iterable = (x for x in '012') actual = list(mi.intersperse(element, iterable)) expected = ['0', ('a', 'b'), '1', ('a', 'b'), '2'] self.assertEqual(actual, expected) def test_not_iterable(self): self.assertRaises(TypeError, lambda: mi.intersperse('x', 1)) def test_n(self): for n, element, expected in [ (1, '_', ['0', '_', '1', '_', '2', '_', '3', '_', '4', '_', '5']), (2, '_', ['0', '1', '_', '2', '3', '_', '4', '5']), (3, '_', ['0', '1', '2', '_', '3', '4', '5']), (4, '_', ['0', '1', '2', '3', '_', '4', '5']), (5, '_', ['0', '1', '2', '3', '4', '_', '5']), (6, '_', ['0', '1', '2', '3', '4', '5']), (7, '_', ['0', '1', '2', '3', '4', '5']), (3, ['a', 'b'], ['0', '1', '2', ['a', 'b'], '3', '4', '5']), ]: iterable = (x for x in '012345') actual = list(mi.intersperse(element, iterable, n=n)) self.assertEqual(actual, expected) def test_n_zero(self): self.assertRaises( ValueError, lambda: list(mi.intersperse('x', '012', n=0)) ) class UniqueToEachTests(TestCase): """Tests for ``unique_to_each()``""" def test_all_unique(self): """When all the input iterables are unique the output should match the input.""" iterables = [[1, 2], [3, 4, 5], [6, 7, 8]] self.assertEqual(mi.unique_to_each(*iterables), iterables) def test_duplicates(self): """When there are duplicates in any of the input iterables that aren't in the rest, those duplicates should be emitted.""" iterables = ["mississippi", "missouri"] self.assertEqual( mi.unique_to_each(*iterables), [['p', 'p'], ['o', 'u', 'r']] ) def test_mixed(self): """When the input iterables contain different types the function should still behave properly""" iterables = ['x', (i for i in range(3)), [1, 2, 3], tuple()] self.assertEqual(mi.unique_to_each(*iterables), [['x'], [0], [3], []]) class WindowedTests(TestCase): """Tests for ``windowed()``""" def test_basic(self): actual = list(mi.windowed([1, 2, 3, 4, 5], 3)) expected = [(1, 2, 3), (2, 3, 4), (3, 4, 5)] self.assertEqual(actual, expected) def test_large_size(self): """ When the window size is larger than the iterable, and no fill value is given,``None`` should be filled in. """ actual = list(mi.windowed([1, 2, 3, 4, 5], 6)) expected = [(1, 2, 3, 4, 5, None)] self.assertEqual(actual, expected) def test_fillvalue(self): """ When sizes don't match evenly, the given fill value should be used. """ iterable = [1, 2, 3, 4, 5] for n, kwargs, expected in [ (6, {}, [(1, 2, 3, 4, 5, '!')]), # n > len(iterable) (3, {'step': 3}, [(1, 2, 3), (4, 5, '!')]), # using ``step`` ]: actual = list(mi.windowed(iterable, n, fillvalue='!', **kwargs)) self.assertEqual(actual, expected) def test_zero(self): """When the window size is zero, an empty tuple should be emitted.""" actual = list(mi.windowed([1, 2, 3, 4, 5], 0)) expected = [tuple()] self.assertEqual(actual, expected) def test_negative(self): """When the window size is negative, ValueError should be raised.""" with self.assertRaises(ValueError): list(mi.windowed([1, 2, 3, 4, 5], -1)) def test_step(self): """The window should advance by the number of steps provided""" iterable = [1, 2, 3, 4, 5, 6, 7] for n, step, expected in [ (3, 2, [(1, 2, 3), (3, 4, 5), (5, 6, 7)]), # n > step (3, 3, [(1, 2, 3), (4, 5, 6), (7, None, None)]), # n == step (3, 4, [(1, 2, 3), (5, 6, 7)]), # line up nicely (3, 5, [(1, 2, 3), (6, 7, None)]), # off by one (3, 6, [(1, 2, 3), (7, None, None)]), # off by two (3, 7, [(1, 2, 3)]), # step past the end (7, 8, [(1, 2, 3, 4, 5, 6, 7)]), # step > len(iterable) ]: actual = list(mi.windowed(iterable, n, step=step)) self.assertEqual(actual, expected) # Step must be greater than or equal to 1 with self.assertRaises(ValueError): list(mi.windowed(iterable, 3, step=0)) class BucketTests(TestCase): """Tests for ``bucket()``""" def test_basic(self): iterable = [10, 20, 30, 11, 21, 31, 12, 22, 23, 33] D = mi.bucket(iterable, key=lambda x: 10 * (x // 10)) # In-order access self.assertEqual(list(D[10]), [10, 11, 12]) # Out of order access self.assertEqual(list(D[30]), [30, 31, 33]) self.assertEqual(list(D[20]), [20, 21, 22, 23]) self.assertEqual(list(D[40]), []) # Nothing in here! def test_in(self): iterable = [10, 20, 30, 11, 21, 31, 12, 22, 23, 33] D = mi.bucket(iterable, key=lambda x: 10 * (x // 10)) self.assertTrue(10 in D) self.assertFalse(40 in D) self.assertTrue(20 in D) self.assertFalse(21 in D) # Checking in-ness shouldn't advance the iterator self.assertEqual(next(D[10]), 10) def test_validator(self): iterable = count(0) key = lambda x: int(str(x)[0]) # First digit of each number validator = lambda x: 0 < x < 10 # No leading zeros D = mi.bucket(iterable, key, validator=validator) self.assertEqual(mi.take(3, D[1]), [1, 10, 11]) self.assertNotIn(0, D) # Non-valid entries don't return True self.assertNotIn(0, D._cache) # Don't store non-valid entries self.assertEqual(list(D[0]), []) class SpyTests(TestCase): """Tests for ``spy()``""" def test_basic(self): original_iterable = iter('abcdefg') head, new_iterable = mi.spy(original_iterable) self.assertEqual(head, ['a']) self.assertEqual( list(new_iterable), ['a', 'b', 'c', 'd', 'e', 'f', 'g'] ) def test_unpacking(self): original_iterable = iter('abcdefg') (first, second, third), new_iterable = mi.spy(original_iterable, 3) self.assertEqual(first, 'a') self.assertEqual(second, 'b') self.assertEqual(third, 'c') self.assertEqual( list(new_iterable), ['a', 'b', 'c', 'd', 'e', 'f', 'g'] ) def test_too_many(self): original_iterable = iter('abc') head, new_iterable = mi.spy(original_iterable, 4) self.assertEqual(head, ['a', 'b', 'c']) self.assertEqual(list(new_iterable), ['a', 'b', 'c']) def test_zero(self): original_iterable = iter('abc') head, new_iterable = mi.spy(original_iterable, 0) self.assertEqual(head, []) self.assertEqual(list(new_iterable), ['a', 'b', 'c']) class InterleaveTests(TestCase): def test_even(self): actual = list(mi.interleave([1, 4, 7], [2, 5, 8], [3, 6, 9])) expected = [1, 2, 3, 4, 5, 6, 7, 8, 9] self.assertEqual(actual, expected) def test_short(self): actual = list(mi.interleave([1, 4], [2, 5, 7], [3, 6, 8])) expected = [1, 2, 3, 4, 5, 6] self.assertEqual(actual, expected) def test_mixed_types(self): it_list = ['a', 'b', 'c', 'd'] it_str = '12345' it_inf = count() actual = list(mi.interleave(it_list, it_str, it_inf)) expected = ['a', '1', 0, 'b', '2', 1, 'c', '3', 2, 'd', '4', 3] self.assertEqual(actual, expected) class InterleaveLongestTests(TestCase): def test_even(self): actual = list(mi.interleave_longest([1, 4, 7], [2, 5, 8], [3, 6, 9])) expected = [1, 2, 3, 4, 5, 6, 7, 8, 9] self.assertEqual(actual, expected) def test_short(self): actual = list(mi.interleave_longest([1, 4], [2, 5, 7], [3, 6, 8])) expected = [1, 2, 3, 4, 5, 6, 7, 8] self.assertEqual(actual, expected) def test_mixed_types(self): it_list = ['a', 'b', 'c', 'd'] it_str = '12345' it_gen = (x for x in range(3)) actual = list(mi.interleave_longest(it_list, it_str, it_gen)) expected = ['a', '1', 0, 'b', '2', 1, 'c', '3', 2, 'd', '4', '5'] self.assertEqual(actual, expected) class TestCollapse(TestCase): """Tests for ``collapse()``""" def test_collapse(self): l = [[1], 2, [[3], 4], [[[5]]]] self.assertEqual(list(mi.collapse(l)), [1, 2, 3, 4, 5]) def test_collapse_to_string(self): l = [["s1"], "s2", [["s3"], "s4"], [[["s5"]]]] self.assertEqual(list(mi.collapse(l)), ["s1", "s2", "s3", "s4", "s5"]) def test_collapse_flatten(self): l = [[1], [2], [[3], 4], [[[5]]]] self.assertEqual(list(mi.collapse(l, levels=1)), list(mi.flatten(l))) def test_collapse_to_level(self): l = [[1], 2, [[3], 4], [[[5]]]] self.assertEqual(list(mi.collapse(l, levels=2)), [1, 2, 3, 4, [5]]) self.assertEqual( list(mi.collapse(mi.collapse(l, levels=1), levels=1)), list(mi.collapse(l, levels=2)) ) def test_collapse_to_list(self): l = (1, [2], (3, [4, (5,)], 'ab')) actual = list(mi.collapse(l, base_type=list)) expected = [1, [2], 3, [4, (5,)], 'ab'] self.assertEqual(actual, expected) class SideEffectTests(TestCase): """Tests for ``side_effect()``""" def test_individual(self): # The function increments the counter for each call counter = [0] def func(arg): counter[0] += 1 result = list(mi.side_effect(func, range(10))) self.assertEqual(result, list(range(10))) self.assertEqual(counter[0], 10) def test_chunked(self): # The function increments the counter for each call counter = [0] def func(arg): counter[0] += 1 result = list(mi.side_effect(func, range(10), 2)) self.assertEqual(result, list(range(10))) self.assertEqual(counter[0], 5) def test_before_after(self): f = StringIO() collector = [] def func(item): print(item, file=f) collector.append(f.getvalue()) def it(): yield u'a' yield u'b' raise RuntimeError('kaboom') before = lambda: print('HEADER', file=f) after = f.close try: mi.consume(mi.side_effect(func, it(), before=before, after=after)) except RuntimeError: pass # The iterable should have been written to the file self.assertEqual(collector, [u'HEADER\na\n', u'HEADER\na\nb\n']) # The file should be closed even though something bad happened self.assertTrue(f.closed) def test_before_fails(self): f = StringIO() func = lambda x: print(x, file=f) def before(): raise RuntimeError('ouch') try: mi.consume( mi.side_effect(func, u'abc', before=before, after=f.close) ) except RuntimeError: pass # The file should be closed even though something bad happened in the # before function self.assertTrue(f.closed) class SlicedTests(TestCase): """Tests for ``sliced()``""" def test_even(self): """Test when the length of the sequence is divisible by *n*""" seq = 'ABCDEFGHI' self.assertEqual(list(mi.sliced(seq, 3)), ['ABC', 'DEF', 'GHI']) def test_odd(self): """Test when the length of the sequence is not divisible by *n*""" seq = 'ABCDEFGHI' self.assertEqual(list(mi.sliced(seq, 4)), ['ABCD', 'EFGH', 'I']) def test_not_sliceable(self): seq = (x for x in 'ABCDEFGHI') with self.assertRaises(TypeError): list(mi.sliced(seq, 3)) class SplitAtTests(TestCase): """Tests for ``split()``""" def comp_with_str_split(self, str_to_split, delim): pred = lambda c: c == delim actual = list(map(''.join, mi.split_at(str_to_split, pred))) expected = str_to_split.split(delim) self.assertEqual(actual, expected) def test_seperators(self): test_strs = ['', 'abcba', 'aaabbbcccddd', 'e'] for s, delim in product(test_strs, 'abcd'): self.comp_with_str_split(s, delim) class SplitBeforeTest(TestCase): """Tests for ``split_before()``""" def test_starts_with_sep(self): actual = list(mi.split_before('xooxoo', lambda c: c == 'x')) expected = [['x', 'o', 'o'], ['x', 'o', 'o']] self.assertEqual(actual, expected) def test_ends_with_sep(self): actual = list(mi.split_before('ooxoox', lambda c: c == 'x')) expected = [['o', 'o'], ['x', 'o', 'o'], ['x']] self.assertEqual(actual, expected) def test_no_sep(self): actual = list(mi.split_before('ooo', lambda c: c == 'x')) expected = [['o', 'o', 'o']] self.assertEqual(actual, expected) class SplitAfterTest(TestCase): """Tests for ``split_after()``""" def test_starts_with_sep(self): actual = list(mi.split_after('xooxoo', lambda c: c == 'x')) expected = [['x'], ['o', 'o', 'x'], ['o', 'o']] self.assertEqual(actual, expected) def test_ends_with_sep(self): actual = list(mi.split_after('ooxoox', lambda c: c == 'x')) expected = [['o', 'o', 'x'], ['o', 'o', 'x']] self.assertEqual(actual, expected) def test_no_sep(self): actual = list(mi.split_after('ooo', lambda c: c == 'x')) expected = [['o', 'o', 'o']] self.assertEqual(actual, expected) class PaddedTest(TestCase): """Tests for ``padded()``""" def test_no_n(self): seq = [1, 2, 3] # No fillvalue self.assertEqual(mi.take(5, mi.padded(seq)), [1, 2, 3, None, None]) # With fillvalue self.assertEqual( mi.take(5, mi.padded(seq, fillvalue='')), [1, 2, 3, '', ''] ) def test_invalid_n(self): self.assertRaises(ValueError, lambda: list(mi.padded([1, 2, 3], n=-1))) self.assertRaises(ValueError, lambda: list(mi.padded([1, 2, 3], n=0))) def test_valid_n(self): seq = [1, 2, 3, 4, 5] # No need for padding: len(seq) <= n self.assertEqual(list(mi.padded(seq, n=4)), [1, 2, 3, 4, 5]) self.assertEqual(list(mi.padded(seq, n=5)), [1, 2, 3, 4, 5]) # No fillvalue self.assertEqual( list(mi.padded(seq, n=7)), [1, 2, 3, 4, 5, None, None] ) # With fillvalue self.assertEqual( list(mi.padded(seq, fillvalue='', n=7)), [1, 2, 3, 4, 5, '', ''] ) def test_next_multiple(self): seq = [1, 2, 3, 4, 5, 6] # No need for padding: len(seq) % n == 0 self.assertEqual( list(mi.padded(seq, n=3, next_multiple=True)), [1, 2, 3, 4, 5, 6] ) # Padding needed: len(seq) < n self.assertEqual( list(mi.padded(seq, n=8, next_multiple=True)), [1, 2, 3, 4, 5, 6, None, None] ) # No padding needed: len(seq) == n self.assertEqual( list(mi.padded(seq, n=6, next_multiple=True)), [1, 2, 3, 4, 5, 6] ) # Padding needed: len(seq) > n self.assertEqual( list(mi.padded(seq, n=4, next_multiple=True)), [1, 2, 3, 4, 5, 6, None, None] ) # With fillvalue self.assertEqual( list(mi.padded(seq, fillvalue='', n=4, next_multiple=True)), [1, 2, 3, 4, 5, 6, '', ''] ) class DistributeTest(TestCase): """Tests for distribute()""" def test_invalid_n(self): self.assertRaises(ValueError, lambda: mi.distribute(-1, [1, 2, 3])) self.assertRaises(ValueError, lambda: mi.distribute(0, [1, 2, 3])) def test_basic(self): iterable = [1, 2, 3, 4, 5, 6, 7, 8, 9, 10] for n, expected in [ (1, [iterable]), (2, [[1, 3, 5, 7, 9], [2, 4, 6, 8, 10]]), (3, [[1, 4, 7, 10], [2, 5, 8], [3, 6, 9]]), (10, [[n] for n in range(1, 10 + 1)]), ]: self.assertEqual( [list(x) for x in mi.distribute(n, iterable)], expected ) def test_large_n(self): iterable = [1, 2, 3, 4] self.assertEqual( [list(x) for x in mi.distribute(6, iterable)], [[1], [2], [3], [4], [], []] ) class StaggerTest(TestCase): """Tests for ``stagger()``""" def test_default(self): iterable = [0, 1, 2, 3] actual = list(mi.stagger(iterable)) expected = [(None, 0, 1), (0, 1, 2), (1, 2, 3)] self.assertEqual(actual, expected) def test_offsets(self): iterable = [0, 1, 2, 3] for offsets, expected in [ ((-2, 0, 2), [('', 0, 2), ('', 1, 3)]), ((-2, -1), [('', ''), ('', 0), (0, 1), (1, 2), (2, 3)]), ((1, 2), [(1, 2), (2, 3)]), ]: all_groups = mi.stagger(iterable, offsets=offsets, fillvalue='') self.assertEqual(list(all_groups), expected) def test_longest(self): iterable = [0, 1, 2, 3] for offsets, expected in [ ( (-1, 0, 1), [('', 0, 1), (0, 1, 2), (1, 2, 3), (2, 3, ''), (3, '', '')] ), ((-2, -1), [('', ''), ('', 0), (0, 1), (1, 2), (2, 3), (3, '')]), ((1, 2), [(1, 2), (2, 3), (3, '')]), ]: all_groups = mi.stagger( iterable, offsets=offsets, fillvalue='', longest=True ) self.assertEqual(list(all_groups), expected) class ZipOffsetTest(TestCase): """Tests for ``zip_offset()``""" def test_shortest(self): a_1 = [0, 1, 2, 3] a_2 = [0, 1, 2, 3, 4, 5] a_3 = [0, 1, 2, 3, 4, 5, 6, 7] actual = list( mi.zip_offset(a_1, a_2, a_3, offsets=(-1, 0, 1), fillvalue='') ) expected = [('', 0, 1), (0, 1, 2), (1, 2, 3), (2, 3, 4), (3, 4, 5)] self.assertEqual(actual, expected) def test_longest(self): a_1 = [0, 1, 2, 3] a_2 = [0, 1, 2, 3, 4, 5] a_3 = [0, 1, 2, 3, 4, 5, 6, 7] actual = list( mi.zip_offset(a_1, a_2, a_3, offsets=(-1, 0, 1), longest=True) ) expected = [ (None, 0, 1), (0, 1, 2), (1, 2, 3), (2, 3, 4), (3, 4, 5), (None, 5, 6), (None, None, 7), ] self.assertEqual(actual, expected) def test_mismatch(self): iterables = [0, 1, 2], [2, 3, 4] offsets = (-1, 0, 1) self.assertRaises( ValueError, lambda: list(mi.zip_offset(*iterables, offsets=offsets)) ) class SortTogetherTest(TestCase): """Tests for sort_together()""" def test_key_list(self): """tests `key_list` including default, iterables include duplicates""" iterables = [ ['GA', 'GA', 'GA', 'CT', 'CT', 'CT'], ['May', 'Aug.', 'May', 'June', 'July', 'July'], [97, 20, 100, 70, 100, 20] ] self.assertEqual( mi.sort_together(iterables), [ ('CT', 'CT', 'CT', 'GA', 'GA', 'GA'), ('June', 'July', 'July', 'May', 'Aug.', 'May'), (70, 100, 20, 97, 20, 100) ] ) self.assertEqual( mi.sort_together(iterables, key_list=(0, 1)), [ ('CT', 'CT', 'CT', 'GA', 'GA', 'GA'), ('July', 'July', 'June', 'Aug.', 'May', 'May'), (100, 20, 70, 20, 97, 100) ] ) self.assertEqual( mi.sort_together(iterables, key_list=(0, 1, 2)), [ ('CT', 'CT', 'CT', 'GA', 'GA', 'GA'), ('July', 'July', 'June', 'Aug.', 'May', 'May'), (20, 100, 70, 20, 97, 100) ] ) self.assertEqual( mi.sort_together(iterables, key_list=(2,)), [ ('GA', 'CT', 'CT', 'GA', 'GA', 'CT'), ('Aug.', 'July', 'June', 'May', 'May', 'July'), (20, 20, 70, 97, 100, 100) ] ) def test_invalid_key_list(self): """tests `key_list` for indexes not available in `iterables`""" iterables = [ ['GA', 'GA', 'GA', 'CT', 'CT', 'CT'], ['May', 'Aug.', 'May', 'June', 'July', 'July'], [97, 20, 100, 70, 100, 20] ] self.assertRaises( IndexError, lambda: mi.sort_together(iterables, key_list=(5,)) ) def test_reverse(self): """tests `reverse` to ensure a reverse sort for `key_list` iterables""" iterables = [ ['GA', 'GA', 'GA', 'CT', 'CT', 'CT'], ['May', 'Aug.', 'May', 'June', 'July', 'July'], [97, 20, 100, 70, 100, 20] ] self.assertEqual( mi.sort_together(iterables, key_list=(0, 1, 2), reverse=True), [('GA', 'GA', 'GA', 'CT', 'CT', 'CT'), ('May', 'May', 'Aug.', 'June', 'July', 'July'), (100, 97, 20, 70, 100, 20)] ) def test_uneven_iterables(self): """tests trimming of iterables to the shortest length before sorting""" iterables = [['GA', 'GA', 'GA', 'CT', 'CT', 'CT', 'MA'], ['May', 'Aug.', 'May', 'June', 'July', 'July'], [97, 20, 100, 70, 100, 20, 0]] self.assertEqual( mi.sort_together(iterables), [ ('CT', 'CT', 'CT', 'GA', 'GA', 'GA'), ('June', 'July', 'July', 'May', 'Aug.', 'May'), (70, 100, 20, 97, 20, 100) ] ) class DivideTest(TestCase): """Tests for divide()""" def test_invalid_n(self): self.assertRaises(ValueError, lambda: mi.divide(-1, [1, 2, 3])) self.assertRaises(ValueError, lambda: mi.divide(0, [1, 2, 3])) def test_basic(self): iterable = [1, 2, 3, 4, 5, 6, 7, 8, 9, 10] for n, expected in [ (1, [iterable]), (2, [[1, 2, 3, 4, 5], [6, 7, 8, 9, 10]]), (3, [[1, 2, 3, 4], [5, 6, 7], [8, 9, 10]]), (10, [[n] for n in range(1, 10 + 1)]), ]: self.assertEqual( [list(x) for x in mi.divide(n, iterable)], expected ) def test_large_n(self): iterable = [1, 2, 3, 4] self.assertEqual( [list(x) for x in mi.divide(6, iterable)], [[1], [2], [3], [4], [], []] ) class TestAlwaysIterable(TestCase): """Tests for always_iterable()""" def test_single(self): self.assertEqual(list(mi.always_iterable(1)), [1]) def test_strings(self): for obj in ['foo', b'bar', u'baz']: actual = list(mi.always_iterable(obj)) expected = [obj] self.assertEqual(actual, expected) def test_base_type(self): dict_obj = {'a': 1, 'b': 2} str_obj = '123' # Default: dicts are iterable like they normally are default_actual = list(mi.always_iterable(dict_obj)) default_expected = list(dict_obj) self.assertEqual(default_actual, default_expected) # Unitary types set: dicts are not iterable custom_actual = list(mi.always_iterable(dict_obj, base_type=dict)) custom_expected = [dict_obj] self.assertEqual(custom_actual, custom_expected) # With unitary types set, strings are iterable str_actual = list(mi.always_iterable(str_obj, base_type=None)) str_expected = list(str_obj) self.assertEqual(str_actual, str_expected) def test_iterables(self): self.assertEqual(list(mi.always_iterable([0, 1])), [0, 1]) self.assertEqual( list(mi.always_iterable([0, 1], base_type=list)), [[0, 1]] ) self.assertEqual( list(mi.always_iterable(iter('foo'))), ['f', 'o', 'o'] ) self.assertEqual(list(mi.always_iterable([])), []) def test_none(self): self.assertEqual(list(mi.always_iterable(None)), []) def test_generator(self): def _gen(): yield 0 yield 1 self.assertEqual(list(mi.always_iterable(_gen())), [0, 1]) class AdjacentTests(TestCase): def test_typical(self): actual = list(mi.adjacent(lambda x: x % 5 == 0, range(10))) expected = [(True, 0), (True, 1), (False, 2), (False, 3), (True, 4), (True, 5), (True, 6), (False, 7), (False, 8), (False, 9)] self.assertEqual(actual, expected) def test_empty_iterable(self): actual = list(mi.adjacent(lambda x: x % 5 == 0, [])) expected = [] self.assertEqual(actual, expected) def test_length_one(self): actual = list(mi.adjacent(lambda x: x % 5 == 0, [0])) expected = [(True, 0)] self.assertEqual(actual, expected) actual = list(mi.adjacent(lambda x: x % 5 == 0, [1])) expected = [(False, 1)] self.assertEqual(actual, expected) def test_consecutive_true(self): """Test that when the predicate matches multiple consecutive elements it doesn't repeat elements in the output""" actual = list(mi.adjacent(lambda x: x % 5 < 2, range(10))) expected = [(True, 0), (True, 1), (True, 2), (False, 3), (True, 4), (True, 5), (True, 6), (True, 7), (False, 8), (False, 9)] self.assertEqual(actual, expected) def test_distance(self): actual = list(mi.adjacent(lambda x: x % 5 == 0, range(10), distance=2)) expected = [(True, 0), (True, 1), (True, 2), (True, 3), (True, 4), (True, 5), (True, 6), (True, 7), (False, 8), (False, 9)] self.assertEqual(actual, expected) actual = list(mi.adjacent(lambda x: x % 5 == 0, range(10), distance=3)) expected = [(True, 0), (True, 1), (True, 2), (True, 3), (True, 4), (True, 5), (True, 6), (True, 7), (True, 8), (False, 9)] self.assertEqual(actual, expected) def test_large_distance(self): """Test distance larger than the length of the iterable""" iterable = range(10) actual = list(mi.adjacent(lambda x: x % 5 == 4, iterable, distance=20)) expected = list(zip(repeat(True), iterable)) self.assertEqual(actual, expected) actual = list(mi.adjacent(lambda x: False, iterable, distance=20)) expected = list(zip(repeat(False), iterable)) self.assertEqual(actual, expected) def test_zero_distance(self): """Test that adjacent() reduces to zip+map when distance is 0""" iterable = range(1000) predicate = lambda x: x % 4 == 2 actual = mi.adjacent(predicate, iterable, 0) expected = zip(map(predicate, iterable), iterable) self.assertTrue(all(a == e for a, e in zip(actual, expected))) def test_negative_distance(self): """Test that adjacent() raises an error with negative distance""" pred = lambda x: x self.assertRaises( ValueError, lambda: mi.adjacent(pred, range(1000), -1) ) self.assertRaises( ValueError, lambda: mi.adjacent(pred, range(10), -10) ) def test_grouping(self): """Test interaction of adjacent() with groupby_transform()""" iterable = mi.adjacent(lambda x: x % 5 == 0, range(10)) grouper = mi.groupby_transform(iterable, itemgetter(0), itemgetter(1)) actual = [(k, list(g)) for k, g in grouper] expected = [ (True, [0, 1]), (False, [2, 3]), (True, [4, 5, 6]), (False, [7, 8, 9]), ] self.assertEqual(actual, expected) def test_call_once(self): """Test that the predicate is only called once per item.""" already_seen = set() iterable = range(10) def predicate(item): self.assertNotIn(item, already_seen) already_seen.add(item) return True actual = list(mi.adjacent(predicate, iterable)) expected = [(True, x) for x in iterable] self.assertEqual(actual, expected) class GroupByTransformTests(TestCase): def assertAllGroupsEqual(self, groupby1, groupby2): """Compare two groupby objects for equality, both keys and groups.""" for a, b in zip(groupby1, groupby2): key1, group1 = a key2, group2 = b self.assertEqual(key1, key2) self.assertListEqual(list(group1), list(group2)) self.assertRaises(StopIteration, lambda: next(groupby1)) self.assertRaises(StopIteration, lambda: next(groupby2)) def test_default_funcs(self): """Test that groupby_transform() with default args mimics groupby()""" iterable = [(x // 5, x) for x in range(1000)] actual = mi.groupby_transform(iterable) expected = groupby(iterable) self.assertAllGroupsEqual(actual, expected) def test_valuefunc(self): iterable = [(int(x / 5), int(x / 3), x) for x in range(10)] # Test the standard usage of grouping one iterable using another's keys grouper = mi.groupby_transform( iterable, keyfunc=itemgetter(0), valuefunc=itemgetter(-1) ) actual = [(k, list(g)) for k, g in grouper] expected = [(0, [0, 1, 2, 3, 4]), (1, [5, 6, 7, 8, 9])] self.assertEqual(actual, expected) grouper = mi.groupby_transform( iterable, keyfunc=itemgetter(1), valuefunc=itemgetter(-1) ) actual = [(k, list(g)) for k, g in grouper] expected = [(0, [0, 1, 2]), (1, [3, 4, 5]), (2, [6, 7, 8]), (3, [9])] self.assertEqual(actual, expected) # and now for something a little different d = dict(zip(range(10), 'abcdefghij')) grouper = mi.groupby_transform( range(10), keyfunc=lambda x: x // 5, valuefunc=d.get ) actual = [(k, ''.join(g)) for k, g in grouper] expected = [(0, 'abcde'), (1, 'fghij')] self.assertEqual(actual, expected) def test_no_valuefunc(self): iterable = range(1000) def key(x): return x // 5 actual = mi.groupby_transform(iterable, key, valuefunc=None) expected = groupby(iterable, key) self.assertAllGroupsEqual(actual, expected) actual = mi.groupby_transform(iterable, key) # default valuefunc expected = groupby(iterable, key) self.assertAllGroupsEqual(actual, expected) class NumericRangeTests(TestCase): def test_basic(self): for args, expected in [ ((4,), [0, 1, 2, 3]), ((4.0,), [0.0, 1.0, 2.0, 3.0]), ((1.0, 4), [1.0, 2.0, 3.0]), ((1, 4.0), [1, 2, 3]), ((1.0, 5), [1.0, 2.0, 3.0, 4.0]), ((0, 20, 5), [0, 5, 10, 15]), ((0, 20, 5.0), [0.0, 5.0, 10.0, 15.0]), ((0, 10, 3), [0, 3, 6, 9]), ((0, 10, 3.0), [0.0, 3.0, 6.0, 9.0]), ((0, -5, -1), [0, -1, -2, -3, -4]), ((0.0, -5, -1), [0.0, -1.0, -2.0, -3.0, -4.0]), ((1, 2, Fraction(1, 2)), [Fraction(1, 1), Fraction(3, 2)]), ((0,), []), ((0.0,), []), ((1, 0), []), ((1.0, 0.0), []), ((Fraction(2, 1),), [Fraction(0, 1), Fraction(1, 1)]), ((Decimal('2.0'),), [Decimal('0.0'), Decimal('1.0')]), ]: actual = list(mi.numeric_range(*args)) self.assertEqual(actual, expected) self.assertTrue( all(type(a) == type(e) for a, e in zip(actual, expected)) ) def test_arg_count(self): self.assertRaises(TypeError, lambda: list(mi.numeric_range())) self.assertRaises( TypeError, lambda: list(mi.numeric_range(0, 1, 2, 3)) ) def test_zero_step(self): self.assertRaises( ValueError, lambda: list(mi.numeric_range(1, 2, 0)) ) class CountCycleTests(TestCase): def test_basic(self): expected = [ (0, 'a'), (0, 'b'), (0, 'c'), (1, 'a'), (1, 'b'), (1, 'c'), (2, 'a'), (2, 'b'), (2, 'c'), ] for actual in [ mi.take(9, mi.count_cycle('abc')), # n=None list(mi.count_cycle('abc', 3)), # n=3 ]: self.assertEqual(actual, expected) def test_empty(self): self.assertEqual(list(mi.count_cycle('')), []) self.assertEqual(list(mi.count_cycle('', 2)), []) def test_negative(self): self.assertEqual(list(mi.count_cycle('abc', -3)), []) class LocateTests(TestCase): def test_default_pred(self): iterable = [0, 1, 1, 0, 1, 0, 0] actual = list(mi.locate(iterable)) expected = [1, 2, 4] self.assertEqual(actual, expected) def test_no_matches(self): iterable = [0, 0, 0] actual = list(mi.locate(iterable)) expected = [] self.assertEqual(actual, expected) def test_custom_pred(self): iterable = ['0', 1, 1, '0', 1, '0', '0'] pred = lambda x: x == '0' actual = list(mi.locate(iterable, pred)) expected = [0, 3, 5, 6] self.assertEqual(actual, expected) class StripFunctionTests(TestCase): def test_hashable(self): iterable = list('www.example.com') pred = lambda x: x in set('cmowz.') self.assertEqual(list(mi.lstrip(iterable, pred)), list('example.com')) self.assertEqual(list(mi.rstrip(iterable, pred)), list('www.example')) self.assertEqual(list(mi.strip(iterable, pred)), list('example')) def test_not_hashable(self): iterable = [ list('http://'), list('www'), list('.example'), list('.com') ] pred = lambda x: x in [list('http://'), list('www'), list('.com')] self.assertEqual(list(mi.lstrip(iterable, pred)), iterable[2:]) self.assertEqual(list(mi.rstrip(iterable, pred)), iterable[:3]) self.assertEqual(list(mi.strip(iterable, pred)), iterable[2: 3]) def test_math(self): iterable = [0, 1, 2, 3, 0, 1, 2, 3, 0, 1, 2] pred = lambda x: x <= 2 self.assertEqual(list(mi.lstrip(iterable, pred)), iterable[3:]) self.assertEqual(list(mi.rstrip(iterable, pred)), iterable[:-3]) self.assertEqual(list(mi.strip(iterable, pred)), iterable[3:-3]) class IsliceExtendedTests(TestCase): def test_all(self): iterable = ['0', '1', '2', '3', '4', '5'] indexes = list(range(-4, len(iterable) + 4)) + [None] steps = [1, 2, 3, 4, -1, -2, -3, 4] for slice_args in product(indexes, indexes, steps): try: actual = list(mi.islice_extended(iterable, *slice_args)) except Exception as e: self.fail((slice_args, e)) expected = iterable[slice(*slice_args)] self.assertEqual(actual, expected, slice_args) def test_zero_step(self): with self.assertRaises(ValueError): list(mi.islice_extended([1, 2, 3], 0, 1, 0)) class ConsecutiveGroupsTest(TestCase): def test_numbers(self): iterable = [-10, -8, -7, -6, 1, 2, 4, 5, -1, 7] actual = [list(g) for g in mi.consecutive_groups(iterable)] expected = [[-10], [-8, -7, -6], [1, 2], [4, 5], [-1], [7]] self.assertEqual(actual, expected) def test_custom_ordering(self): iterable = ['1', '10', '11', '20', '21', '22', '30', '31'] ordering = lambda x: int(x) actual = [list(g) for g in mi.consecutive_groups(iterable, ordering)] expected = [['1'], ['10', '11'], ['20', '21', '22'], ['30', '31']] self.assertEqual(actual, expected) def test_exotic_ordering(self): iterable = [ ('a', 'b', 'c', 'd'), ('a', 'c', 'b', 'd'), ('a', 'c', 'd', 'b'), ('a', 'd', 'b', 'c'), ('d', 'b', 'c', 'a'), ('d', 'c', 'a', 'b'), ] ordering = list(permutations('abcd')).index actual = [list(g) for g in mi.consecutive_groups(iterable, ordering)] expected = [ [('a', 'b', 'c', 'd')], [('a', 'c', 'b', 'd'), ('a', 'c', 'd', 'b'), ('a', 'd', 'b', 'c')], [('d', 'b', 'c', 'a'), ('d', 'c', 'a', 'b')], ] self.assertEqual(actual, expected) class DifferenceTest(TestCase): def test_normal(self): iterable = [10, 20, 30, 40, 50] actual = list(mi.difference(iterable)) expected = [10, 10, 10, 10, 10] self.assertEqual(actual, expected) def test_custom(self): iterable = [10, 20, 30, 40, 50] actual = list(mi.difference(iterable, add)) expected = [10, 30, 50, 70, 90] self.assertEqual(actual, expected) def test_roundtrip(self): original = list(range(100)) accumulated = mi.accumulate(original) actual = list(mi.difference(accumulated)) self.assertEqual(actual, original) def test_one(self): self.assertEqual(list(mi.difference([0])), [0]) def test_empty(self): self.assertEqual(list(mi.difference([])), []) class SeekableTest(TestCase): def test_exhaustion_reset(self): iterable = [str(n) for n in range(10)] s = mi.seekable(iterable) self.assertEqual(list(s), iterable) # Normal iteration self.assertEqual(list(s), []) # Iterable is exhausted s.seek(0) self.assertEqual(list(s), iterable) # Back in action def test_partial_reset(self): iterable = [str(n) for n in range(10)] s = mi.seekable(iterable) self.assertEqual(mi.take(5, s), iterable[:5]) # Normal iteration s.seek(1) self.assertEqual(list(s), iterable[1:]) # Get the rest of the iterable def test_forward(self): iterable = [str(n) for n in range(10)] s = mi.seekable(iterable) self.assertEqual(mi.take(1, s), iterable[:1]) # Normal iteration s.seek(3) # Skip over index 2 self.assertEqual(list(s), iterable[3:]) # Result is similar to slicing s.seek(0) # Back to 0 self.assertEqual(list(s), iterable) # No difference in result def test_past_end(self): iterable = [str(n) for n in range(10)] s = mi.seekable(iterable) self.assertEqual(mi.take(1, s), iterable[:1]) # Normal iteration s.seek(20) self.assertEqual(list(s), []) # Iterable is exhausted s.seek(0) # Back to 0 self.assertEqual(list(s), iterable) # No difference in result def test_elements(self): iterable = map(str, count()) s = mi.seekable(iterable) mi.take(10, s) elements = s.elements() self.assertEqual( [elements[i] for i in range(10)], [str(n) for n in range(10)] ) self.assertEqual(len(elements), 10) mi.take(10, s) self.assertEqual(list(elements), [str(n) for n in range(20)]) class SequenceViewTests(TestCase): def test_init(self): view = mi.SequenceView((1, 2, 3)) self.assertEqual(repr(view), "SequenceView((1, 2, 3))") self.assertRaises(TypeError, lambda: mi.SequenceView({})) def test_update(self): seq = [1, 2, 3] view = mi.SequenceView(seq) self.assertEqual(len(view), 3) self.assertEqual(repr(view), "SequenceView([1, 2, 3])") seq.pop() self.assertEqual(len(view), 2) self.assertEqual(repr(view), "SequenceView([1, 2])") def test_indexing(self): seq = ('a', 'b', 'c', 'd', 'e', 'f') view = mi.SequenceView(seq) for i in range(-len(seq), len(seq)): self.assertEqual(view[i], seq[i]) def test_slicing(self): seq = ('a', 'b', 'c', 'd', 'e', 'f') view = mi.SequenceView(seq) n = len(seq) indexes = list(range(-n - 1, n + 1)) + [None] steps = list(range(-n, n + 1)) steps.remove(0) for slice_args in product(indexes, indexes, steps): i = slice(*slice_args) self.assertEqual(view[i], seq[i]) def test_abc_methods(self): # collections.Sequence should provide all of this functionality seq = ('a', 'b', 'c', 'd', 'e', 'f', 'f') view = mi.SequenceView(seq) # __contains__ self.assertIn('b', view) self.assertNotIn('g', view) # __iter__ self.assertEqual(list(iter(view)), list(seq)) # __reversed__ self.assertEqual(list(reversed(view)), list(reversed(seq))) # index self.assertEqual(view.index('b'), 1) # count self.assertEqual(seq.count('f'), 2) class RunLengthTest(TestCase): def test_encode(self): iterable = (int(str(n)[0]) for n in count(800)) actual = mi.take(4, mi.run_length.encode(iterable)) expected = [(8, 100), (9, 100), (1, 1000), (2, 1000)] self.assertEqual(actual, expected) def test_decode(self): iterable = [('d', 4), ('c', 3), ('b', 2), ('a', 1)] actual = ''.join(mi.run_length.decode(iterable)) expected = 'ddddcccbba' self.assertEqual(actual, expected) class ExactlyNTests(TestCase): """Tests for ``exactly_n()``""" def test_true(self): """Iterable has ``n`` ``True`` elements""" self.assertTrue(mi.exactly_n([True, False, True], 2)) self.assertTrue(mi.exactly_n([1, 1, 1, 0], 3)) self.assertTrue(mi.exactly_n([False, False], 0)) self.assertTrue(mi.exactly_n(range(100), 10, lambda x: x < 10)) def test_false(self): """Iterable does not have ``n`` ``True`` elements""" self.assertFalse(mi.exactly_n([True, False, False], 2)) self.assertFalse(mi.exactly_n([True, True, False], 1)) self.assertFalse(mi.exactly_n([False], 1)) self.assertFalse(mi.exactly_n([True], -1)) self.assertFalse(mi.exactly_n(repeat(True), 100)) def test_empty(self): """Return ``True`` if the iterable is empty and ``n`` is 0""" self.assertTrue(mi.exactly_n([], 0)) self.assertFalse(mi.exactly_n([], 1)) class AlwaysReversibleTests(TestCase): """Tests for ``always_reversible()``""" def test_regular_reversed(self): self.assertEqual(list(reversed(range(10))), list(mi.always_reversible(range(10)))) self.assertEqual(list(reversed([1, 2, 3])), list(mi.always_reversible([1, 2, 3]))) self.assertEqual(reversed([1, 2, 3]).__class__, mi.always_reversible([1, 2, 3]).__class__) def test_nonseq_reversed(self): # Create a non-reversible generator from a sequence with self.assertRaises(TypeError): reversed(x for x in range(10)) self.assertEqual(list(reversed(range(10))), list(mi.always_reversible(x for x in range(10)))) self.assertEqual(list(reversed([1, 2, 3])), list(mi.always_reversible(x for x in [1, 2, 3]))) self.assertNotEqual(reversed((1, 2)).__class__, mi.always_reversible(x for x in (1, 2)).__class__) class CircularShiftsTests(TestCase): def test_empty(self): # empty iterable -> empty list self.assertEqual(list(mi.circular_shifts([])), []) def test_simple_circular_shifts(self): # test the a simple iterator case self.assertEqual( mi.circular_shifts(range(4)), [(0, 1, 2, 3), (1, 2, 3, 0), (2, 3, 0, 1), (3, 0, 1, 2)] ) def test_duplicates(self): # test non-distinct entries self.assertEqual( mi.circular_shifts([0, 1, 0, 1]), [(0, 1, 0, 1), (1, 0, 1, 0), (0, 1, 0, 1), (1, 0, 1, 0)] ) class MakeDecoratorTests(TestCase): def test_basic(self): slicer = mi.make_decorator(islice) @slicer(1, 10, 2) def user_function(arg_1, arg_2, kwarg_1=None): self.assertEqual(arg_1, 'arg_1') self.assertEqual(arg_2, 'arg_2') self.assertEqual(kwarg_1, 'kwarg_1') return map(str, count()) it = user_function('arg_1', 'arg_2', kwarg_1='kwarg_1') actual = list(it) expected = ['1', '3', '5', '7', '9'] self.assertEqual(actual, expected) def test_result_index(self): def stringify(*args, **kwargs): self.assertEqual(args[0], 'arg_0') iterable = args[1] self.assertEqual(args[2], 'arg_2') self.assertEqual(kwargs['kwarg_1'], 'kwarg_1') return map(str, iterable) stringifier = mi.make_decorator(stringify, result_index=1) @stringifier('arg_0', 'arg_2', kwarg_1='kwarg_1') def user_function(n): return count(n) it = user_function(1) actual = mi.take(5, it) expected = ['1', '2', '3', '4', '5'] self.assertEqual(actual, expected) def test_wrap_class(self): seeker = mi.make_decorator(mi.seekable) @seeker() def user_function(n): return map(str, range(n)) it = user_function(5) self.assertEqual(list(it), ['0', '1', '2', '3', '4']) it.seek(0) self.assertEqual(list(it), ['0', '1', '2', '3', '4']) class MapReduceTests(TestCase): def test_default(self): iterable = (str(x) for x in range(5)) keyfunc = lambda x: int(x) // 2 actual = sorted(mi.map_reduce(iterable, keyfunc).items()) expected = [(0, ['0', '1']), (1, ['2', '3']), (2, ['4'])] self.assertEqual(actual, expected) def test_valuefunc(self): iterable = (str(x) for x in range(5)) keyfunc = lambda x: int(x) // 2 valuefunc = int actual = sorted(mi.map_reduce(iterable, keyfunc, valuefunc).items()) expected = [(0, [0, 1]), (1, [2, 3]), (2, [4])] self.assertEqual(actual, expected) def test_reducefunc(self): iterable = (str(x) for x in range(5)) keyfunc = lambda x: int(x) // 2 valuefunc = int reducefunc = lambda value_list: reduce(mul, value_list, 1) actual = sorted( mi.map_reduce(iterable, keyfunc, valuefunc, reducefunc).items() ) expected = [(0, 0), (1, 6), (2, 4)] self.assertEqual(actual, expected) def test_ret(self): d = mi.map_reduce([1, 0, 2, 0, 1, 0], bool) self.assertEqual(d, {False: [0, 0, 0], True: [1, 2, 1]}) self.assertRaises(KeyError, lambda: d[None].append(1))

./Ninja\.