def test_add_many_pairs(self):
for a_low in range(0, 6):
for a_high in range(0, 6):
if a_low > a_high:
continue
a_ranges = [
Range.closed(a_low, a_high),
Range.open_closed(a_low, a_high),
Range.closed_open(a_low, a_high),
]
if a_low != a_high:
a_ranges.append(Range.open(a_low, a_high))
for b_low in range(0, 6):
for b_high in range(0, 6):
if b_low > b_high:
continue
b_ranges = [
Range.closed(b_low, b_high),
Range.open_closed(b_low, b_high),
Range.closed_open(b_low, b_high),
]
if b_low != b_high:
b_ranges.append(Range.open(b_low, b_high))
for a_range in a_ranges:
for b_range in b_ranges:
self._pair_test(a_range, b_range)
def test_check_usable_in_set(self) -> None:
range_set = ImmutableSet.of([
Range.open_closed(0, 1),
Range.open_closed(0, 1),
Range.at_most(1),
Range.at_most(1),
])
self.assertEqual(2, len(range_set))
def test_intersection_general(self):
rng = Range.closed(4, 8)
# separate
with self.assertRaises(ValueError):
rng.intersection(Range.closed(0, 2))
# adjacent below
self.assertEqual(Range.closed_open(4, 4),
rng.intersection(Range.closed_open(2, 4)))
# overlap below
self.assertEqual(Range.closed(4, 6),
rng.intersection(Range.closed(2, 6)))
# enclosed with same start
self.assertEqual(Range.closed(4, 6),
rng.intersection(Range.closed(4, 6)))
# enclosed, interior
self.assertEqual(Range.closed(5, 7),
rng.intersection(Range.closed(5, 7)))
# enclosed with same end
self.assertEqual(Range.closed(6, 8),
rng.intersection(Range.closed(6, 8)))
# equal
self.assertEqual(rng, rng.intersection(rng))
# enclosing with same start
self.assertEqual(rng, rng.intersection(Range.closed(4, 10)))
# enclosing with same end
self.assertEqual(rng, rng.intersection(Range.closed(2, 8)))
# enclosing, exterior
self.assertEqual(rng, rng.intersection(Range.closed(2, 10)))
# overlap above
self.assertEqual(Range.closed(6, 8),
rng.intersection(Range.closed(6, 10)))
# adjacent above
self.assertEqual(Range.open_closed(8, 8),
rng.intersection(Range.open_closed(8, 10)))
with self.assertRaises(ValueError):
rng.intersection(Range.closed(10, 12))
def test_range_enclosing_range(self) -> None:
range_set: MutableRangeSet[int] = RangeSet.create_mutable()
range_set.add_all(
[Range.at_most(2),
Range.open_closed(5, 8),
Range.at_least(10)])
self.assertEqual(None,
range_set.range_enclosing_range(Range.closed(2, 3)))
self.assertEqual(Range.at_most(2),
range_set.range_enclosing_range(Range.open(-1, 0)))
self.assertEqual(
Range.open_closed(5, 8),
range_set.range_enclosing_range(Range.closed_open(6, 7)),
)
self.assertEqual(None,
range_set.range_enclosing_range(Range.closed(5, 8)))
def test_intersection_de_facto_empty(self):
rng = Range.open(3, 4)
self.assertEqual(rng, rng.intersection(rng))
self.assertEqual(Range.open_closed(3, 3),
rng.intersection(Range.at_most(3)))
self.assertEqual(Range.closed_open(4, 4),
rng.intersection(Range.at_least(4)))
with self.assertRaises(ValueError):
rng.intersection(Range.less_than(3))
with self.assertRaises(ValueError):
rng.intersection(Range.greater_than(4))
rng2 = Range.closed(3, 4)
self.assertEqual(Range.open_closed(4, 4),
rng2.intersection(Range.greater_than(4)))
def test_range_clear(self) -> None:
range_set: MutableRangeSet[int] = RangeSet.create_mutable()
range_set.add_all(
[Range.at_most(2),
Range.open_closed(5, 8),
Range.at_least(10)])
range_set.clear()
self.assertEqual(0, len(range_set.as_ranges()))
def test_leftmost_containing_or_above(self):
range_set = RangeSet.create_mutable().add_all((
Range.closed(-2, -1),
Range.closed_open(0, 2),
# we don't do [0, 2), [2.1, 3] because they will coalesce
# ditto for (4, 5] and (5.1, 7)
Range.closed(2.1, 3),
Range.open_closed(4, 5),
Range.open(5.1, 7),
))
# probe value is in the middle of a set
# [2.1 ... *2.5* ... 3]
self.assertEqual(Range.closed(2.1, 3.0),
range_set.leftmost_containing_or_above(2.5))
# probe value is at a closed upper limit
# [2.1 .... *3*]
self.assertEqual(Range.closed(2.1, 3.0),
range_set.leftmost_containing_or_above(3.0))
# probe value is at a closed lower limit
# [*2.1* .... 3]
self.assertEqual(Range.closed(2.1, 3.0),
range_set.leftmost_containing_or_above(2.1))
# probe value is at an open lower limit
# [2 ... 3], (*4* ... 5]
self.assertEqual(Range.open_closed(4.0, 5.0),
range_set.leftmost_containing_or_above(4.0))
# probe value is at an open upper limit
# [0 ... *2*) [2.1, 3.0]
self.assertEqual(Range.closed(2.1, 3.0),
range_set.leftmost_containing_or_above(2.0))
# probe value falls into a gap
# [-2, -1] ... *-0.5* ... [0, 2)
self.assertEqual(Range.closed_open(0, 2),
range_set.leftmost_containing_or_above(-0.5))
# no range above
# (5.1 ... 7) ... *8*
self.assertIsNone(range_set.leftmost_containing_or_above(8))
# empty rangeset
self.assertIsNone(RangeSet.create_mutable().add(Range.closed(
1.0, 2.0)).leftmost_containing_or_above(3.0))
# higher range has open upper bound
# (1,*2*)
self.assertIsNone(RangeSet.create_mutable().add(Range.open(
1.0, 2.0)).leftmost_containing_or_above(2.0))
def test_add_all(self):
range_set = RangeSet.create_mutable()
range_set.add(Range.closed(3, 10))
range_set.add_all(
[Range.open(1, 3),
Range.closed(5, 8),
Range.closed(9, 11)])
self.assertEqual(tuple(range_set.as_ranges()),
tuple([Range.open_closed(1, 11)]))
def test_lookup(self):
range_map = (ImmutableRangeMap.builder().put(Range.closed(
0, 2), "foo").put(Range.open_closed(6, 8), "bar").build())
self.assertEqual("foo", range_map[0])
self.assertEqual("foo", range_map[1])
self.assertEqual("foo", range_map[2])
self.assertEqual(None, range_map[6])
self.assertEqual("bar", range_map[7])
self.assertEqual("bar", range_map[8])
self.assertEqual(None, range_map[9])
def test_open_closed(self):
rng = Range.open_closed(4, 7)
self.check_contains(rng)
self.assertTrue(rng.has_lower_bound())
self.assertEqual(4, rng.lower_endpoint)
self.assertEqual(BoundType.open(), rng.lower_bound_type)
self.assertTrue(rng.has_upper_bound())
self.assertEqual(7, rng.upper_endpoint)
self.assertEqual(BoundType.closed(), rng.upper_bound_type)
self.assertFalse(rng.is_empty())
self.assertEqual("(4..7]", str(rng))
def test_empty_2(self):
rng = Range.open_closed(4, 4)
self.assertFalse(3 in rng)
self.assertFalse(4 in rng)
self.assertFalse(5 in rng)
self.assertTrue(rng.has_lower_bound())
self.assertEqual(4, rng.lower_endpoint)
self.assertEqual(BoundType.open(), rng.lower_bound_type)
self.assertTrue(rng.has_upper_bound())
self.assertEqual(4, rng.upper_endpoint)
self.assertEqual(BoundType.closed(), rng.upper_bound_type)
self.assertTrue(rng.is_empty())
self.assertEqual("(4..4]", str(rng))
def test_get_rightmost_containing_or_below(self):
range_map = immutablerangemap((
(Range.closed(-2, -1), 0),
(Range.closed_open(0, 2), 1),
# we don't do [0, 2), [2.1, 3] because they will coalesce
# ditto for (4, 5] and (5.1, 7)
(Range.closed(2.1, 3), 2),
(Range.open_closed(4, 5), 3),
(Range.open(5.1, 7), 4),
))
# probe value is in the middle of a set
# [2.1 ... *2.5* ... 3]
self.assertEqual(2,
range_map.get_from_rightmost_containing_or_below(2.5))
# probe value is at a closed upper limit
# [2.1 .... *3*]
self.assertEqual(2,
range_map.get_from_rightmost_containing_or_below(3.0))
# probe value is at a closed lower limit
# [*2.1* .... 3]
self.assertEqual(2,
range_map.get_from_rightmost_containing_or_below(2.1))
# probe value is at an open lower limit
# [2.1 ... 3], (*4* ... 5]
self.assertEqual(2,
range_map.get_from_rightmost_containing_or_below(4.0))
# probe value is at an open upper limit
# [0 ... *2.1*)
self.assertEqual(1,
range_map.get_from_rightmost_containing_or_below(2.0))
# probe value falls into a gap
# [-2, -1] ... *-0.5* ... [0, 2)
self.assertEqual(
0, range_map.get_from_rightmost_containing_or_below(-0.5))
# no range below
# *-3* .... [-2,-1]
self.assertIsNone(
range_map.get_from_rightmost_containing_or_below(-3.0))
# empty rangeset
self.assertIsNone(
immutablerangemap(
((Range.closed(1.0, 2.0),
1), )).get_from_rightmost_containing_or_below(0.0))
# lowest range has open lower bound
# (*1*,2)
self.assertIsNone(
immutablerangemap(
((Range.open(1.0, 2.0),
1), )).get_from_rightmost_containing_or_below(1.0))
def test_encloses_closed(self):
rng = Range.closed(2, 5)
self.assertTrue(rng.encloses(rng))
self.assertTrue(rng.encloses(Range.open(2, 5)))
self.assertTrue(rng.encloses(Range.open_closed(2, 5)))
self.assertTrue(rng.encloses(Range.closed_open(2, 5)))
self.assertTrue(rng.encloses(Range.closed(3, 5)))
self.assertTrue(rng.encloses(Range.closed(2, 4)))
self.assertFalse(rng.encloses(Range.open(1, 6)))
self.assertFalse(rng.encloses(Range.greater_than(3)))
self.assertFalse(rng.encloses(Range.less_than(3)))
self.assertFalse(rng.encloses(Range.at_least(3)))
self.assertFalse(rng.encloses(Range.at_most(3)))
self.assertFalse(rng.encloses(Range.all()))
def test_enclosed(self):
range_map: ImmutableRangeMap[int,
str] = (ImmutableRangeMap.builder().put(
Range.closed(0, 2),
"foo").put(Range.open_closed(6, 8),
"bar").put(
Range.open(12, 14),
"meep").build())
self.assertEqual(
ImmutableSet.of(["foo", "bar", "meep"]),
range_map.get_enclosed_by(Range.closed(-1, 15)),
)
self.assertEqual(ImmutableSet.of(["foo"]),
range_map.get_enclosed_by(Range.closed(0, 6)))
self.assertEqual(ImmutableSet.empty(),
range_map.get_enclosed_by(Range.closed(5, 5)))
def test_intersection_singleton(self):
rng = Range.closed(3, 3)
self.assertEqual(rng, rng.intersection(rng))
self.assertEqual(rng, rng.intersection(Range.at_most(4)))
self.assertEqual(rng, rng.intersection(Range.at_most(3)))
self.assertEqual(rng, rng.intersection(Range.at_least(3)))
self.assertEqual(rng, rng.intersection(Range.at_least(2)))
self.assertEqual(Range.closed_open(3, 3),
rng.intersection(Range.less_than(3)))
self.assertEqual(Range.open_closed(3, 3),
rng.intersection(Range.greater_than(3)))
with self.assertRaises(ValueError):
rng.intersection(Range.at_least(4))
with self.assertRaises(ValueError):
rng.intersection(Range.at_most(2))
def test_intersects(self):
rng = Range.closed(4, 8)
# separate
self.assertFalse(rng.intersects(Range.closed(0, 2)))
# adjacent below
self.assertTrue(rng.intersects(Range.closed_open(2, 4)))
# overlap below
self.assertTrue(rng.intersects(Range.closed(2, 6)))
# enclosed with same start
self.assertTrue(rng.intersects(Range.closed(4, 6)))
# enclosed, interior
self.assertTrue(rng.intersects(Range.closed(5, 7)))
# enclosed with same end
self.assertTrue(rng.intersects(Range.closed(6, 8)))
# equal
self.assertTrue(rng.intersects(rng))
# enclosing with same start
self.assertTrue(rng.intersects(Range.closed(4, 10)))
# enclosing with same end
self.assertTrue(rng.intersects(Range.closed(2, 8)))
# enclosing, exterior
self.assertTrue(rng.intersects(Range.closed(2, 10)))
# overlap above
self.assertTrue(rng.intersects(Range.closed(6, 10)))
# adjacent above
self.assertTrue(rng.intersects(Range.open_closed(8, 10)))
self.assertFalse(rng.intersects(Range.closed(10, 12)))
class TestRangeSet(TestCase):
"""
Tests for RangeSet
Derived from Guava's TreeRangeSet tests, which were written by Louis Wasserman and Chris Povrik
"""
MIN_BOUND = -1
MAX_BOUND = 1
BOUND_TYPES = [BoundType.open(), BoundType.closed()]
QUERY_RANGES: List[Range[int]] = [Range.all()]
for i in range(MIN_BOUND, MAX_BOUND + 1):
QUERY_RANGES.extend([
Range.at_most(i),
Range.at_least(i),
Range.less_than(i),
Range.greater_than(i),
Range.closed(i, i),
Range.open_closed(i, i),
Range.closed_open(i, i),
])
for j in range(i + 1, MAX_BOUND + 1):
QUERY_RANGES.extend([
Range.open(i, j),
Range.open_closed(i, j),
Range.closed_open(i, j),
Range.closed(i, j),
])
def test_empty_enclosing(self):
self._test_encloses(RangeSet.create_mutable())
def test_empty_intersects(self):
self._test_intersects(RangeSet.create_mutable())
def test_all_single_ranges_enclosing(self):
for query_range in TestRangeSet.QUERY_RANGES:
self._test_encloses(RangeSet.create_mutable().add(query_range))
# also test for the complement of empty once complements are implemented
def test_all_pair_ranges_enclosing(self):
for query_range_1 in TestRangeSet.QUERY_RANGES:
for query_range_2 in TestRangeSet.QUERY_RANGES:
self._test_encloses(RangeSet.create_mutable().add(
query_range_1).add(query_range_2))
def test_intersect_ranges(self):
range_set = RangeSet.create_mutable()
range_set.add_all([
Range.closed(2, 4),
Range.closed(5, 7),
Range.closed(10, 12),
Range.closed(18, 20),
])
self.assertEqual(
range_set.ranges_overlapping(Range.closed(19, 21)),
immutableset([Range.closed(18, 20)]),
)
self.assertEqual(
range_set.ranges_overlapping(Range.closed(11, 19)),
immutableset([Range.closed(10, 12),
Range.closed(18, 20)]),
)
self.assertEqual(range_set.ranges_overlapping(Range.closed(0, 1)),
immutableset())
self.assertEqual(range_set.ranges_overlapping(Range.closed(21, 23)),
immutableset())
self.assertEqual(range_set.ranges_overlapping(Range.closed(13, 15)),
immutableset())
self.assertEqual(
range_set.ranges_overlapping(Range.closed(0, 2)),
immutableset([Range.closed(2, 4)]),
)
self.assertEqual(
range_set.ranges_overlapping(Range.closed(12, 15)),
immutableset([Range.closed(10, 12)]),
)
self.assertEqual(
range_set.ranges_overlapping(Range.closed(5, 16)),
immutableset([Range.closed(5, 7),
Range.closed(10, 12)]),
)
def test_merges_connected_with_overlap(self):
range_set = RangeSet.create_mutable()
range_set.add(Range.closed(1, 4))
range_set.add(Range.open(2, 6))
self._test_invariants(range_set)
self.assertTrue(Range.closed_open(1, 6) in range_set.as_ranges())
def test_merges_connected_disjoint(self):
range_set = RangeSet.create_mutable()
range_set.add(Range.closed(1, 4))
range_set.add(Range.open(4, 6))
self._test_invariants(range_set)
self.assertTrue(Range.closed_open(1, 6) in range_set.as_ranges())
def test_ignores_smaller_sharing_no_bound(self):
range_set = RangeSet.create_mutable()
range_set.add(Range.closed(1, 6))
range_set.add(Range.open(2, 4))
self._test_invariants(range_set)
self.assertTrue(Range.closed(1, 6) in range_set.as_ranges())
def test_ignores_smaller_sharing_lower_bound(self):
range_set = RangeSet.create_mutable()
range_set.add(Range.closed(1, 6))
range_set.add(Range.closed(1, 4))
self._test_invariants(range_set)
self.assertEqual(tuple([Range.closed(1, 6)]),
tuple(range_set.as_ranges()))
def test_ignores_smaller_sharing_upper_bound(self):
range_set = RangeSet.create_mutable()
range_set.add(Range.closed(1, 6))
range_set.add(Range.closed(3, 6))
self._test_invariants(range_set)
self.assertTrue(Range.closed(1, 6) in range_set.as_ranges())
def test_ignores_equal(self):
range_set = RangeSet.create_mutable()
range_set.add(Range.closed(1, 6))
range_set.add(Range.closed(1, 6))
self._test_invariants(range_set)
self.assertTrue(Range.closed(1, 6) in range_set.as_ranges())
def test_extend_same_lower_bound(self):
range_set = RangeSet.create_mutable()
range_set.add(Range.closed(1, 4))
range_set.add(Range.closed(1, 6))
self._test_invariants(range_set)
self.assertTrue(Range.closed(1, 6) in range_set.as_ranges())
def test_extend_same_upper_bound(self):
range_set = RangeSet.create_mutable()
range_set.add(Range.closed(3, 6))
range_set.add(Range.closed(1, 6))
self._test_invariants(range_set)
self.assertTrue(Range.closed(1, 6) in range_set.as_ranges())
def test_extend_both_directions(self):
range_set = RangeSet.create_mutable()
range_set.add(Range.closed(3, 4))
range_set.add(Range.closed(1, 6))
self._test_invariants(range_set)
self.assertTrue(Range.closed(1, 6) in range_set.as_ranges())
def test_add_empty(self):
range_set = RangeSet.create_mutable()
range_set.add(Range.closed_open(3, 3))
self._test_invariants(range_set)
self.assertTrue(len(range_set.as_ranges()) == 0)
self.assertTrue(range_set.is_empty())
def test_fill_hole_exactly(self):
range_set = RangeSet.create_mutable()
range_set.add(Range.closed_open(1, 3))
range_set.add(Range.closed_open(4, 6))
range_set.add(Range.closed_open(3, 4))
self._test_invariants(range_set)
self.assertTrue(Range.closed_open(1, 6) in range_set.as_ranges())
def test_fill_hole_with_overlap(self):
range_set = RangeSet.create_mutable()
range_set.add(Range.closed_open(1, 3))
range_set.add(Range.closed_open(4, 6))
range_set.add(Range.closed_open(2, 5))
self._test_invariants(range_set)
self.assertEqual(tuple([Range.closed_open(1, 6)]),
tuple(range_set.as_ranges()))
def test_add_many_pairs(self):
for a_low in range(0, 6):
for a_high in range(0, 6):
if a_low > a_high:
continue
a_ranges = [
Range.closed(a_low, a_high),
Range.open_closed(a_low, a_high),
Range.closed_open(a_low, a_high),
]
if a_low != a_high:
a_ranges.append(Range.open(a_low, a_high))
for b_low in range(0, 6):
for b_high in range(0, 6):
if b_low > b_high:
continue
b_ranges = [
Range.closed(b_low, b_high),
Range.open_closed(b_low, b_high),
Range.closed_open(b_low, b_high),
]
if b_low != b_high:
b_ranges.append(Range.open(b_low, b_high))
for a_range in a_ranges:
for b_range in b_ranges:
self._pair_test(a_range, b_range)
def test_range_containing1(self):
range_set = RangeSet.create_mutable()
range_set.add(Range.closed(3, 10))
self.assertEqual(Range.closed(3, 10), range_set.range_containing(5))
self.assertTrue(5 in range_set)
self.assertIsNone(range_set.range_containing(1))
self.assertFalse(1 in range_set)
def test_add_all(self):
range_set = RangeSet.create_mutable()
range_set.add(Range.closed(3, 10))
range_set.add_all(
[Range.open(1, 3),
Range.closed(5, 8),
Range.closed(9, 11)])
self.assertEqual(tuple(range_set.as_ranges()),
tuple([Range.open_closed(1, 11)]))
def test_all_single_ranges_intersecting(self):
for query in TestRangeSet.QUERY_RANGES:
self._test_intersects(RangeSet.create_mutable().add(query))
def test_all_two_ranges_intersecting(self):
for query_1 in TestRangeSet.QUERY_RANGES:
for query_2 in TestRangeSet.QUERY_RANGES:
self._test_intersects(
RangeSet.create_mutable().add(query_1).add(query_2))
# forms the basis for corresponding tests in test_range_map
def test_rightmost_containing_or_below(self):
range_set = RangeSet.create_mutable().add_all((
Range.closed(-2, -1),
Range.closed_open(0, 2),
# we don't do [0, 2), [2.1, 3] because they will coalesce
# ditto for (4, 5] and (5.1, 7)
Range.closed(2.1, 3),
Range.open_closed(4, 5),
Range.open(5.1, 7),
))
# probe value is in the middle of a set
# [2.1 ... *2.5* ... 3]
self.assertEqual(Range.closed(2.1, 3.0),
range_set.rightmost_containing_or_below(2.5))
# probe value is at a closed upper limit
# [2.1 .... *3*]
self.assertEqual(Range.closed(2.1, 3.0),
range_set.rightmost_containing_or_below(3.0))
# probe value is at a closed lower limit
# [*2.1* .... 3]
self.assertEqual(Range.closed(2.1, 3.0),
range_set.rightmost_containing_or_below(2.1))
# probe value is at an open lower limit
# [2.1 ... 3], (*4* ... 5]
self.assertEqual(Range.closed(2.1, 3.0),
range_set.rightmost_containing_or_below(4.0))
# probe value is at an open upper limit
# [0 ... *2.1*)
self.assertEqual(Range.closed_open(0.0, 2.0),
range_set.rightmost_containing_or_below(2.0))
# probe value falls into a gap
# [-2, -1] ... *-0.5* ... [0, 2)
self.assertEqual(Range.closed(-2.0, -1.0),
range_set.rightmost_containing_or_below(-0.5))
# no range below
# *-3* .... [-2,-1]
self.assertIsNone(range_set.rightmost_containing_or_below(-3.0))
# empty rangeset
self.assertIsNone(RangeSet.create_mutable().add(Range.closed(
1.0, 2.0)).rightmost_containing_or_below(0.0))
# lowest range has open lower bound
# (*1*,2)
self.assertIsNone(RangeSet.create_mutable().add(Range.open(
1.0, 2.0)).rightmost_containing_or_below(1.0))
# forms the basis for corresponding tests in test_range_set
def test_leftmost_containing_or_above(self):
range_set = RangeSet.create_mutable().add_all((
Range.closed(-2, -1),
Range.closed_open(0, 2),
# we don't do [0, 2), [2.1, 3] because they will coalesce
# ditto for (4, 5] and (5.1, 7)
Range.closed(2.1, 3),
Range.open_closed(4, 5),
Range.open(5.1, 7),
))
# probe value is in the middle of a set
# [2.1 ... *2.5* ... 3]
self.assertEqual(Range.closed(2.1, 3.0),
range_set.leftmost_containing_or_above(2.5))
# probe value is at a closed upper limit
# [2.1 .... *3*]
self.assertEqual(Range.closed(2.1, 3.0),
range_set.leftmost_containing_or_above(3.0))
# probe value is at a closed lower limit
# [*2.1* .... 3]
self.assertEqual(Range.closed(2.1, 3.0),
range_set.leftmost_containing_or_above(2.1))
# probe value is at an open lower limit
# [2 ... 3], (*4* ... 5]
self.assertEqual(Range.open_closed(4.0, 5.0),
range_set.leftmost_containing_or_above(4.0))
# probe value is at an open upper limit
# [0 ... *2*) [2.1, 3.0]
self.assertEqual(Range.closed(2.1, 3.0),
range_set.leftmost_containing_or_above(2.0))
# probe value falls into a gap
# [-2, -1] ... *-0.5* ... [0, 2)
self.assertEqual(Range.closed_open(0, 2),
range_set.leftmost_containing_or_above(-0.5))
# no range above
# (5.1 ... 7) ... *8*
self.assertIsNone(range_set.leftmost_containing_or_above(8))
# empty rangeset
self.assertIsNone(RangeSet.create_mutable().add(Range.closed(
1.0, 2.0)).leftmost_containing_or_above(3.0))
# higher range has open upper bound
# (1,*2*)
self.assertIsNone(RangeSet.create_mutable().add(Range.open(
1.0, 2.0)).leftmost_containing_or_above(2.0))
def test_len(self):
self.assertEqual(0, len(RangeSet.create_mutable()))
self.assertEqual(
1, len(RangeSet.create_mutable().add(Range.closed(1, 2))))
self.assertEqual(
2,
len(RangeSet.create_mutable().add(Range.closed(1, 2)).add(
Range.open(3, 4))),
)
# support methods
def _pair_test(self, a: Range[int], b: Range[int]) -> None:
range_set: MutableRangeSet[int] = RangeSet.create_mutable()
range_set.add(a)
range_set.add(b)
if a.is_empty() and b.is_empty():
self.assertTrue(range_set.is_empty())
self.assertFalse(range_set.as_ranges())
elif a.is_empty():
self.assertTrue(b in range_set.as_ranges())
elif b.is_empty():
self.assertTrue(a in range_set.as_ranges())
elif a.is_connected(b):
self.assertEqual(tuple(range_set.as_ranges()), tuple([a.span(b)]))
else:
if a.lower_endpoint < b.lower_endpoint:
self.assertEqual(tuple(range_set.as_ranges()), tuple([a, b]))
else:
self.assertEqual(ImmutableSet.of([a, b]),
ImmutableSet.of(range_set.as_ranges()))
def _test_encloses(self, range_set: RangeSet[int]):
self.assertTrue(range_set.encloses_all(ImmutableSet.empty()))
for query_range in TestRangeSet.QUERY_RANGES:
expected_to_enclose = any(
x.encloses(query_range) for x in range_set.as_ranges())
self.assertEqual(expected_to_enclose,
range_set.encloses(query_range))
self.assertEqual(expected_to_enclose,
range_set.encloses_all([query_range]))
def _test_intersects(self, range_set: RangeSet[int]):
for query in TestRangeSet.QUERY_RANGES:
expect_intersects = any(
r.is_connected(query) and not r.intersection(query).is_empty()
for r in range_set.as_ranges())
self.assertEqual(expect_intersects, range_set.intersects(query))
def _test_invariants(self, range_set: RangeSet[int]):
self.assertEqual(len(range_set.as_ranges()) == 0, range_set.is_empty())
as_ranges: Sequence[Range[int]] = tuple(range_set.as_ranges())
# test that connected ranges are coalesced
for (range_1, range_2) in tile_with_pairs(as_ranges):
self.assertFalse(range_1.is_connected(range_2))
for rng in as_ranges:
self.assertFalse(rng.is_empty())
# test that the RangeSet's span is the span of all the ranges
if as_ranges:
self.assertEqual(Range.create_spanning(range_set.as_ranges()),
range_set.span)
else:
with self.assertRaises(ValueError):
# pylint: disable=pointless-statement
# noinspection PyStatementEffect
range_set.span
# test internal utility functions
def test_entry_above_below(self):
sorted_dict = SortedDict({1: 1, 3: 3, 5: 5, 7: 7, 9: 9})
value_at_or_below_reference = (
(0, None),
(1, 1),
(2, 1),
(3, 3),
(4, 3),
(5, 5),
(6, 5),
(7, 7),
(8, 7),
(9, 9),
(10, 9),
(200, 9),
)
for (key, ref) in value_at_or_below_reference:
self.assertEqual(_value_at_or_below(sorted_dict, key), ref)
value_below_reference = (
(0, None),
(1, None),
(2, 1),
(3, 1),
(4, 3),
(5, 3),
(6, 5),
(7, 5),
(8, 7),
(9, 7),
(10, 9),
(200, 9),
)
for (key, ref) in value_below_reference:
self.assertEqual(_value_below(sorted_dict, key), ref)
value_at_or_above_reference = (
(0, 1),
(1, 1),
(2, 3),
(3, 3),
(4, 5),
(5, 5),
(6, 7),
(7, 7),
(8, 9),
(9, 9),
(10, None),
(200, None),
)
for (key, ref) in value_at_or_above_reference:
self.assertEqual(_value_at_or_above(sorted_dict, key), ref)
def test_pickling(self):
empty_mutable_rangeset = MutableRangeSet.create_mutable()
empty_immutable_rangeset = ImmutableRangeSet.builder().build()
ranges = (Range.closed(0, 2), Range.closed(5,
29), Range.closed(35, 39))
mutable_rangeset = MutableRangeSet.create_mutable().add_all(ranges)
immutable_rangeset = ImmutableRangeSet.builder().add_all(
ranges).build()
self.assertEqual(empty_mutable_rangeset,
pickle.loads(pickle.dumps(empty_mutable_rangeset)))
self.assertEqual(empty_immutable_rangeset,
pickle.loads(pickle.dumps(empty_immutable_rangeset)))
self.assertEqual(mutable_rangeset,
pickle.loads(pickle.dumps(mutable_rangeset)))
self.assertEqual(immutable_rangeset,
pickle.loads(pickle.dumps(immutable_rangeset)))
self.assertEqual(empty_mutable_rangeset.__getstate__(), ())
self.assertEqual(empty_immutable_rangeset.__getstate__(), ())
self.assertEqual(mutable_rangeset.__getstate__(), ranges)
self.assertEqual(immutable_rangeset.__getstate__(), ranges)