def test_upper_bound_is_none(self):
im = IntervalMetadata(None)
# should not raise error
im.add([(0, 1000000000)])
self.assertIsNone(im.upper_bound)
with self.assertRaisesRegex(TypeError, 'upper bound is `None`'):
im._reverse()
with self.assertRaisesRegex(TypeError, 'upper bound is `None`'):
IntervalMetadata.concat([self.im_1, im])
def test_upper_bound_is_none(self):
im = IntervalMetadata(None)
# should not raise error
im.add([(0, 1000000000)])
self.assertIsNone(im.upper_bound)
with self.assertRaisesRegex(
TypeError, r'upper bound is `None`'):
im._reverse()
with self.assertRaisesRegex(
TypeError, r'upper bound is `None`'):
IntervalMetadata.concat([self.im_1, im])
class TestIntervalMetadata(unittest.TestCase, ReallyEqualMixin):
def setUp(self):
self.upper_bound = 10
self.im_empty = IntervalMetadata(self.upper_bound)
self.im_1 = IntervalMetadata(self.upper_bound)
self.im_1_1 = Interval(interval_metadata=self.im_1,
bounds=[(1, 2), (4, self.upper_bound)],
metadata={
'gene': 'sagA',
'bound': 0
})
self.im_2 = IntervalMetadata(self.upper_bound)
self.im_2_1 = Interval(interval_metadata=self.im_2,
bounds=[(1, 2), (4, self.upper_bound)],
metadata={
'gene': 'sagA',
'bound': 0
})
self.im_2_2 = Interval(interval_metadata=self.im_2,
bounds=[(3, 5)],
metadata={
'gene': 'sagB',
'bound': 0,
'spam': [0]
})
def test_copy_empty(self):
obs = copy(self.im_empty)
self.assertEqual(obs, self.im_empty)
self.assertIsNot(obs._intervals, self.im_empty._intervals)
self.assertIsNot(obs._interval_tree, self.im_empty._interval_tree)
def test_copy(self):
obs = copy(self.im_2)
self.assertEqual(obs, self.im_2)
self.assertIsNot(obs._intervals, self.im_2._intervals)
self.assertIsNot(obs._interval_tree, self.im_2._interval_tree)
for i in range(self.im_2.num_interval_features):
i1, i2 = obs._intervals[i], self.im_2._intervals[i]
self.assertIsNot(i1, i2)
self.assertIsNot(i1.bounds, i2.bounds)
self.assertIsNot(i1.fuzzy, i2.fuzzy)
self.assertIsNot(i1._interval_metadata, i2._interval_metadata)
self.assertIsNot(i1.metadata, i2.metadata)
for k in i1.metadata:
self.assertIs(i1.metadata[k], i2.metadata[k])
def test_deepcopy(self):
obs = deepcopy(self.im_2)
self.assertEqual(obs, self.im_2)
self.assertIsNot(obs._intervals, self.im_2._intervals)
self.assertIsNot(obs._interval_tree, self.im_2._interval_tree)
for i in range(self.im_2.num_interval_features):
i1, i2 = obs._intervals[i], self.im_2._intervals[i]
self.assertIsNot(i1, i2)
self.assertIsNot(i1.bounds, i2.bounds)
self.assertIsNot(i1.fuzzy, i2.fuzzy)
self.assertIsNot(i1.metadata, i2.metadata)
i2.metadata['spam'].append(1)
self.assertEqual(i2.metadata, {
'gene': 'sagB',
'bound': 0,
'spam': [0, 1]
})
self.assertEqual(i1.metadata, {
'gene': 'sagB',
'bound': 0,
'spam': [0]
})
def test_deepcopy_memo_is_respected(self):
memo = {}
deepcopy(self.im_1, memo)
self.assertGreater(len(memo), 2)
def test_init(self):
self.assertFalse(self.im_empty._is_stale_tree)
self.assertEqual(self.im_empty._intervals, [])
def test_init_upper_bound_lt_lower_bound(self):
# test that no exception is raised
IntervalMetadata(0)
with self.assertRaises(ValueError):
IntervalMetadata(-1)
def test_upper_bound_is_none(self):
im = IntervalMetadata(None)
# should not raise error
im.add([(0, 1000000000)])
self.assertIsNone(im.upper_bound)
with self.assertRaisesRegex(TypeError, 'upper bound is `None`'):
im._reverse()
with self.assertRaisesRegex(TypeError, 'upper bound is `None`'):
IntervalMetadata.concat([self.im_1, im])
def test_init_copy_from(self):
for i in [None, 99, 999]:
obs = IntervalMetadata(i, self.im_1)
exp = IntervalMetadata(i)
exp.add(bounds=[(1, 2), (4, self.upper_bound)],
metadata={
'gene': 'sagA',
'bound': 0
})
self.assertEqual(obs, exp)
def test_init_copy_from_empty(self):
for i in [None, 0, 9, 99, 999]:
obs = IntervalMetadata(i, self.im_empty)
exp = IntervalMetadata(i)
self.assertEqual(obs, exp)
# test it is shallow copy
self.assertIsNot(obs._intervals, self.im_empty._intervals)
self.assertIsNot(obs._interval_tree, self.im_empty._interval_tree)
def test_init_copy_from_shallow_copy(self):
obs = IntervalMetadata(self.upper_bound, self.im_2)
self.assertEqual(self.im_2, obs)
# test it is shallow copy
self.assertIsNot(obs._intervals, self.im_2._intervals)
self.assertIsNot(obs._interval_tree, self.im_2._interval_tree)
for i in range(self.im_2.num_interval_features):
i1, i2 = obs._intervals[i], self.im_2._intervals[i]
self.assertIsNot(i1, i2)
self.assertIsNot(i1.bounds, i2.bounds)
self.assertIsNot(i1.fuzzy, i2.fuzzy)
self.assertIsNot(i1._interval_metadata, i2._interval_metadata)
self.assertIsNot(i1.metadata, i2.metadata)
for k in i1.metadata:
self.assertIs(i1.metadata[k], i2.metadata[k])
def test_init_copy_from_error(self):
i = self.upper_bound - 1
with self.assertRaisesRegex(ValueError,
r'larger than upper bound \(%r\)' % i):
IntervalMetadata(i, self.im_2)
def test_num_interval_features(self):
self.assertEqual(self.im_empty.num_interval_features, 0)
self.assertEqual(self.im_1.num_interval_features, 1)
self.assertEqual(self.im_2.num_interval_features, 2)
def test_duplicate(self):
'''Test query and drop methods on duplicate Intervals.'''
intvl_1 = self.im_empty.add([(1, 2)])
intvl_2 = self.im_empty.add([(1, 2)])
self.assertEqual(len(list(self.im_empty.query([(1, 2)]))), 2)
self.im_empty.drop([intvl_1])
self.assertEqual(len(self.im_empty._intervals), 1)
self.assertTrue(self.im_empty._intervals[0] is intvl_2)
def test_duplicate_bounds(self):
intvl = self.im_empty.add([(1, 2), (1, 2)])
intvls = list(self.im_empty.query([(1, 2)]))
self.assertEqual(len(intvls), 1)
self.assertTrue(intvl is intvls[0])
def test_concat_empty(self):
for i in 0, 1, 2:
obs = IntervalMetadata.concat([self.im_empty] * i)
exp = IntervalMetadata(self.upper_bound * i)
self.assertEqual(obs, exp)
obs = IntervalMetadata.concat([])
self.assertEqual(obs, IntervalMetadata(0))
def test_concat(self):
im1 = IntervalMetadata(3)
im2 = IntervalMetadata(4)
im3 = IntervalMetadata(5)
im1.add([(0, 2)], [(True, True)])
im2.add([(0, 3)], [(True, False)], {'gene': 'sagA'})
im2.add([(2, 4)], metadata={'gene': 'sagB'})
im3.add([(1, 5)], [(False, True)], {'gene': 'sagC'})
obs = IntervalMetadata.concat([im1, im2, im3])
exp = IntervalMetadata(12)
exp.add(bounds=[(0, 2)], fuzzy=[(True, True)])
exp.add(bounds=[(3, 6)],
fuzzy=[(True, False)],
metadata={'gene': 'sagA'})
exp.add(bounds=[(5, 7)], metadata={'gene': 'sagB'})
exp.add(bounds=[(8, 12)],
fuzzy=[(False, True)],
metadata={'gene': 'sagC'})
self.assertEqual(obs, exp)
def test_merge(self):
# empty + empty
im = IntervalMetadata(self.upper_bound)
self.im_empty.merge(im)
self.assertEqual(self.im_empty, im)
# empty + non-empty
self.im_empty.merge(self.im_1)
self.assertEqual(self.im_empty, self.im_1)
# non-empty + non-empty
self.im_empty.merge(self.im_2)
self.im_2.merge(self.im_1)
self.assertEqual(self.im_empty, self.im_2)
def test_merge_unequal_upper_bounds(self):
n = 3
im1 = IntervalMetadata(n)
for im in [self.im_empty, self.im_1]:
with self.assertRaisesRegex(
ValueError,
r'not equal \(%d != %d\)' % (self.upper_bound, n)):
im.merge(im1)
def test_merge_to_unbounded(self):
for im in [self.im_empty, self.im_1, IntervalMetadata(None)]:
obs = IntervalMetadata(None)
obs.merge(im)
self.assertIsNone(obs.upper_bound)
self.assertEqual(obs._intervals, im._intervals)
def test_merge_unbounded_to_bounded(self):
im = IntervalMetadata(None)
with self.assertRaisesRegex(
ValueError, 'Cannot merge an unbound IntervalMetadata object '
'to a bounded one'):
self.im_1.merge(im)
# original im is not changed
self.assertIsNone(im.upper_bound)
self.assertEqual(im._intervals, [])
def test_sort(self):
interval = Interval(self.im_2, [(1, 2), (3, 8)],
metadata={
'gene': 'sagA',
'bound': 0
})
im = deepcopy(self.im_2)
self.im_2.sort(False)
# check sorting does not have other side effects
self.assertEqual(im, self.im_2)
self.assertEqual(self.im_2._intervals,
[self.im_2_2, self.im_2_1, interval])
self.im_2.sort()
self.assertEqual(im, self.im_2)
self.assertEqual(self.im_2._intervals,
[interval, self.im_2_1, self.im_2_2])
self.im_empty.sort()
self.assertEqual(self.im_empty, IntervalMetadata(self.upper_bound))
def test_add_eq_upper_bound(self):
self.im_empty.add(bounds=[(1, 2), (4, self.upper_bound)],
metadata={
'gene': 'sagA',
'bound': 0
})
self.assertTrue(self.im_empty._is_stale_tree)
interval = self.im_empty._intervals[0]
self.assertEqual(interval.bounds, [(1, 2), (4, self.upper_bound)])
self.assertEqual(interval.metadata, {'gene': 'sagA', 'bound': 0})
self.assertTrue(isinstance(self.im_empty._interval_tree, IntervalTree))
def test_add_gt_upper_bound(self):
with self.assertRaises(ValueError):
self.im_empty.add(bounds=[(1, 2), (4, self.upper_bound + 1)],
metadata={
'gene': 'sagA',
'bound': 0
})
def test_add_eq_start_end_bound(self):
for i in 0, 1, self.upper_bound:
# test that no exception is raised
self.im_empty.add(bounds=[(i, i)],
metadata={
'gene': 'sagA',
'bound': 0
})
def test_query_attribute(self):
intervals = self.im_2._query_attribute({})
for i, j in zip(intervals, self.im_2._intervals):
self.assertEqual(i, j)
intervals = list(self.im_2._query_attribute(None))
self.assertEqual(len(intervals), 0)
for i in self.im_2._intervals:
intervals = list(self.im_2._query_attribute(i.metadata))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], i)
def test_query_interval(self):
intervals = list(self.im_2._query_interval((1, 2)))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], self.im_2_1)
intervals = list(self.im_2._query_interval((3, 4)))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], self.im_2_2)
intervals = {repr(i) for i in self.im_2._query_interval((1, 7))}
self.assertEqual(len(intervals), 2)
self.assertSetEqual(intervals, {repr(i) for i in self.im_2._intervals})
def test_query_interval_upper_bound(self):
intervals = list(
self.im_2._query_interval(
(self.upper_bound - 1, self.upper_bound)))
self.assertEqual(intervals, [self.im_2_1])
def test_query(self):
intervals = list(
self.im_2.query(bounds=[(1, 5)], metadata={'gene': 'sagA'}))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], self.im_2_1)
def test_query_empty(self):
intervals = list(self.im_1.query())
self.assertEqual(len(intervals), 0)
def test_query_no_hits(self):
intervals = list(self.im_2.query(bounds=[(self.upper_bound, 200)]))
self.assertEqual(len(intervals), 0)
intervals = list(self.im_2.query(metadata={'gene': 'sagC'}))
self.assertEqual(len(intervals), 0)
intervals = list(
self.im_2.query(bounds=[(1, 2)], metadata={'gene': 'sagC'}))
self.assertEqual(len(intervals), 0)
def test_query_interval_only(self):
for loc in [[(1, 7)], [(1, 2), (3, 4)]]:
intervals = list(self.im_2.query(bounds=loc))
self.assertEqual(len(intervals), 2)
self.assertEqual(intervals[0], self.im_2_1)
self.assertEqual(intervals[1], self.im_2_2)
def test_query_metadata_only(self):
intervals = list(self.im_2.query(metadata={'gene': 'sagB'}))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], self.im_2_2)
intervals = list(self.im_2.query(metadata={'bound': 0}))
self.assertEqual(len(intervals), 2)
self.assertEqual(intervals[0], self.im_2_1)
self.assertEqual(intervals[1], self.im_2_2)
def test_drop(self):
intvl = self.im_2._intervals[0]
self.im_2.drop([intvl])
self.assertEqual(len(self.im_2._intervals), 1)
self.assertEqual(self.im_2._intervals[0], self.im_2_2)
# test the intvl was set to dropped
self.assertTrue(intvl.dropped)
def test_drop_all(self):
self.im_2.drop(self.im_2._intervals)
self.assertEqual(self.im_2, self.im_empty)
def test_drop_negate(self):
intvl = self.im_2._intervals[0]
self.im_2.drop([intvl], negate=True)
self.assertEqual(len(self.im_2._intervals), 1)
self.assertEqual(self.im_2._intervals[0], intvl)
# test the dropped intvl was set to dropped
self.assertTrue(self.im_2_2.dropped)
def test_reverse(self):
self.im_2._reverse()
Interval(interval_metadata=self.im_empty,
bounds=[(0, 6), (8, 9)],
metadata={
'gene': 'sagA',
'bound': 0
})
Interval(interval_metadata=self.im_empty,
bounds=[(5, 7)],
metadata={
'gene': 'sagB',
'bound': 0,
'spam': [0]
})
self.assertEqual(self.im_2, self.im_empty)
def test_eq_ne(self):
im1 = IntervalMetadata(10)
im1.add(metadata={
'gene': 'sagA',
'bound': '0'
},
bounds=[(0, 2), (4, 7)])
im1.add(metadata={'gene': 'sagB', 'bound': '3'}, bounds=[(3, 5)])
# The ordering shouldn't matter
im2 = IntervalMetadata(10)
im2.add(metadata={'gene': 'sagB', 'bound': '3'}, bounds=[(3, 5)])
im2.add(metadata={
'gene': 'sagA',
'bound': '0'
},
bounds=[(0, 2), (4, 7)])
im3 = IntervalMetadata(10)
im3.add(metadata={
'gene': 'sagA',
'bound': '3'
},
bounds=[(0, 2), (4, 7)])
im3.add(metadata={'gene': 'sagB', 'bound': '3'}, bounds=[(3, 5)])
self.assertReallyEqual(im1, im2)
self.assertReallyNotEqual(im1, im3)
def test_ne_diff_bounds(self):
im1 = IntervalMetadata(10)
im2 = IntervalMetadata(9)
intvl = {'bounds': [(0, 1)], 'metadata': {'spam': 'foo'}}
im1.add(**intvl)
im2.add(**intvl)
self.assertReallyNotEqual(im1, im2)
def test_repr(self):
exp = '''0 interval features
-------------------'''
self.assertEqual(repr(self.im_empty), exp)
self.im_empty.add([(1, 2)], metadata={'gene': 'sagA'})
exp = '''1 interval feature
------------------
Interval\(interval_metadata=<[0-9]+>, bounds=\[\(1, 2\)\], \
fuzzy=\[\(False, False\)\], metadata={'gene': 'sagA'}\)'''
self.assertRegex(repr(self.im_empty), exp)
self.im_empty.add([(3, 4)], metadata={'gene': 'sagB'})
self.im_empty.add([(3, 4)], metadata={'gene': 'sagC'})
self.im_empty.add([(3, 4)], metadata={'gene': 'sagD'})
self.im_empty.add([(3, 4)], metadata={'gene': 'sagE'})
self.im_empty.add([(3, 4)], metadata={'gene': 'sagF'})
exp = '''6 interval features
-------------------
Interval\(interval_metadata=<[0-9]+>, bounds=\[\(1, 2\)\], \
fuzzy=\[\(False, False\)\], metadata={'gene': 'sagA'}\)
Interval\(interval_metadata=<[0-9]+>, bounds=\[\(3, 4\)\], \
fuzzy=\[\(False, False\)\], metadata={'gene': 'sagB'}\)
...
Interval\(interval_metadata=<[0-9]+>, bounds=\[\(3, 4\)\], \
fuzzy=\[\(False, False\)\], metadata={'gene': 'sagE'}\)
Interval\(interval_metadata=<[0-9]+>, bounds=\[\(3, 4\)\], \
fuzzy=\[\(False, False\)\], metadata={'gene': 'sagF'}\)'''
self.assertRegex(repr(self.im_empty), exp)
class TestIntervalMetadata(unittest.TestCase, ReallyEqualMixin):
def setUp(self):
self.upper_bound = 10
self.im_empty = IntervalMetadata(self.upper_bound)
self.im_1 = IntervalMetadata(self.upper_bound)
self.im_1_1 = Interval(
interval_metadata=self.im_1,
bounds=[(1, 2), (4, self.upper_bound)],
metadata={'gene': 'sagA', 'bound': 0})
self.im_2 = IntervalMetadata(self.upper_bound)
self.im_2_1 = Interval(
interval_metadata=self.im_2,
bounds=[(1, 2), (4, self.upper_bound)],
metadata={'gene': 'sagA', 'bound': 0})
self.im_2_2 = Interval(
interval_metadata=self.im_2,
bounds=[(3, 5)],
metadata={'gene': 'sagB', 'bound': 0, 'spam': [0]})
def test_copy_empty(self):
obs = copy(self.im_empty)
self.assertEqual(obs, self.im_empty)
self.assertIsNot(obs._intervals, self.im_empty._intervals)
self.assertIsNot(obs._interval_tree, self.im_empty._interval_tree)
def test_copy(self):
obs = copy(self.im_2)
self.assertEqual(obs, self.im_2)
self.assertIsNot(obs._intervals, self.im_2._intervals)
self.assertIsNot(obs._interval_tree, self.im_2._interval_tree)
for i in range(self.im_2.num_interval_features):
i1, i2 = obs._intervals[i], self.im_2._intervals[i]
self.assertIsNot(i1, i2)
self.assertIsNot(i1.bounds, i2.bounds)
self.assertIsNot(i1.fuzzy, i2.fuzzy)
self.assertIsNot(i1._interval_metadata, i2._interval_metadata)
self.assertIsNot(i1.metadata, i2.metadata)
for k in i1.metadata:
self.assertIs(i1.metadata[k], i2.metadata[k])
def test_deepcopy(self):
obs = deepcopy(self.im_2)
self.assertEqual(obs, self.im_2)
self.assertIsNot(obs._intervals, self.im_2._intervals)
self.assertIsNot(obs._interval_tree, self.im_2._interval_tree)
for i in range(self.im_2.num_interval_features):
i1, i2 = obs._intervals[i], self.im_2._intervals[i]
self.assertIsNot(i1, i2)
self.assertIsNot(i1.bounds, i2.bounds)
self.assertIsNot(i1.fuzzy, i2.fuzzy)
self.assertIsNot(i1.metadata, i2.metadata)
i2.metadata['spam'].append(1)
self.assertEqual(i2.metadata,
{'gene': 'sagB', 'bound': 0, 'spam': [0, 1]})
self.assertEqual(i1.metadata,
{'gene': 'sagB', 'bound': 0, 'spam': [0]})
def test_deepcopy_memo_is_respected(self):
memo = {}
deepcopy(self.im_1, memo)
self.assertGreater(len(memo), 2)
def test_init(self):
self.assertFalse(self.im_empty._is_stale_tree)
self.assertEqual(self.im_empty._intervals, [])
def test_init_upper_bound_lt_lower_bound(self):
try:
IntervalMetadata(0)
except ValueError:
self.fail('`IntervalMetdata` raised ValueError unexpectedly')
with self.assertRaises(ValueError):
IntervalMetadata(-1)
def test_num_interval_features(self):
self.assertEqual(self.im_empty.num_interval_features, 0)
self.assertEqual(self.im_1.num_interval_features, 1)
self.assertEqual(self.im_2.num_interval_features, 2)
def test_duplicate(self):
'''Test query and drop methods on duplicate Intervals.'''
intvl_1 = self.im_empty.add([(1, 2)])
intvl_2 = self.im_empty.add([(1, 2)])
self.assertEqual(len(list(self.im_empty.query([(1, 2)]))), 2)
self.im_empty.drop([intvl_1])
self.assertEqual(len(self.im_empty._intervals), 1)
self.assertTrue(self.im_empty._intervals[0] is intvl_2)
def test_duplicate_bounds(self):
intvl = self.im_empty.add([(1, 2), (1, 2)])
intvls = list(self.im_empty.query([(1, 2)]))
self.assertEqual(len(intvls), 1)
self.assertTrue(intvl is intvls[0])
def test_concat_empty(self):
for i in 0, 1, 2:
obs = IntervalMetadata.concat([self.im_empty] * i)
exp = IntervalMetadata(self.upper_bound * i)
self.assertEqual(obs, exp)
obs = IntervalMetadata.concat([])
self.assertEqual(obs, IntervalMetadata(0))
def test_concat(self):
im1 = IntervalMetadata(3)
im2 = IntervalMetadata(4)
im3 = IntervalMetadata(5)
im1.add([(0, 2)], [(True, True)])
im2.add([(0, 3)], [(True, False)], {'gene': 'sagA'})
im2.add([(2, 4)], metadata={'gene': 'sagB'})
im3.add([(1, 5)], [(False, True)], {'gene': 'sagC'})
obs = IntervalMetadata.concat([im1, im2, im3])
exp = IntervalMetadata(12)
exp.add(bounds=[(0, 2)], fuzzy=[(True, True)])
exp.add(bounds=[(3, 6)], fuzzy=[(True, False)],
metadata={'gene': 'sagA'})
exp.add(bounds=[(5, 7)], metadata={'gene': 'sagB'})
exp.add(bounds=[(8, 12)], fuzzy=[(False, True)],
metadata={'gene': 'sagC'})
self.assertEqual(obs, exp)
def test_sort(self):
interval = Interval(
self.im_2,
[(1, 2), (3, 8)],
metadata={'gene': 'sagA', 'bound': 0})
im = deepcopy(self.im_2)
self.im_2.sort(False)
# check sorting does not have other side effects
self.assertEqual(im, self.im_2)
self.assertEqual(self.im_2._intervals,
[self.im_2_2, self.im_2_1, interval])
self.im_2.sort()
self.assertEqual(im, self.im_2)
self.assertEqual(self.im_2._intervals,
[interval, self.im_2_1, self.im_2_2])
self.im_empty.sort()
self.assertEqual(self.im_empty, IntervalMetadata(self.upper_bound))
def test_add_eq_upper_bound(self):
self.im_empty.add(bounds=[(1, 2), (4, self.upper_bound)],
metadata={'gene': 'sagA', 'bound': 0})
self.assertTrue(self.im_empty._is_stale_tree)
interval = self.im_empty._intervals[0]
self.assertEqual(interval.bounds, [(1, 2), (4, self.upper_bound)])
self.assertEqual(interval.metadata, {'gene': 'sagA', 'bound': 0})
self.assertTrue(isinstance(self.im_empty._interval_tree, IntervalTree))
def test_add_gt_upper_bound(self):
with self.assertRaises(ValueError):
self.im_empty.add(bounds=[(1, 2), (4, self.upper_bound+1)],
metadata={'gene': 'sagA', 'bound': 0})
def test_add_eq_start_end_bound(self):
for i in 0, 1, self.upper_bound:
with self.assertRaisesRegex(ValueError, '{i}.*{i}'.format(i=i)):
self.im_empty.add(bounds=[(i, i)],
metadata={'gene': 'sagA', 'bound': 0})
def test_query_attribute(self):
intervals = self.im_2._query_attribute({})
for i, j in zip(intervals, self.im_2._intervals):
self.assertEqual(i, j)
intervals = list(self.im_2._query_attribute(None))
self.assertEqual(len(intervals), 0)
for i in self.im_2._intervals:
intervals = list(self.im_2._query_attribute(i.metadata))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], i)
def test_query_interval(self):
intervals = list(self.im_2._query_interval((1, 2)))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], self.im_2_1)
intervals = list(self.im_2._query_interval((3, 4)))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], self.im_2_2)
intervals = {repr(i) for i in self.im_2._query_interval((1, 7))}
self.assertEqual(len(intervals), 2)
self.assertSetEqual(intervals,
{repr(i) for i in self.im_2._intervals})
def test_query_interval_upper_bound(self):
intervals = list(self.im_2._query_interval((self.upper_bound-1,
self.upper_bound)))
self.assertEqual(intervals, [self.im_2_1])
def test_query(self):
intervals = list(self.im_2.query(bounds=[(1, 5)],
metadata={'gene': 'sagA'}))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], self.im_2_1)
def test_query_empty(self):
intervals = list(self.im_1.query())
self.assertEqual(len(intervals), 0)
def test_query_no_hits(self):
intervals = list(self.im_2.query(bounds=[(self.upper_bound, 200)]))
self.assertEqual(len(intervals), 0)
intervals = list(self.im_2.query(metadata={'gene': 'sagC'}))
self.assertEqual(len(intervals), 0)
intervals = list(self.im_2.query(bounds=[(1, 2)],
metadata={'gene': 'sagC'}))
self.assertEqual(len(intervals), 0)
def test_query_interval_only(self):
for loc in [[(1, 7)],
[(1, 2), (3, 4)]]:
intervals = list(self.im_2.query(bounds=loc))
self.assertEqual(len(intervals), 2)
self.assertEqual(intervals[0], self.im_2_1)
self.assertEqual(intervals[1], self.im_2_2)
def test_query_metadata_only(self):
intervals = list(self.im_2.query(metadata={'gene': 'sagB'}))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], self.im_2_2)
intervals = list(self.im_2.query(metadata={'bound': 0}))
self.assertEqual(len(intervals), 2)
self.assertEqual(intervals[0], self.im_2_1)
self.assertEqual(intervals[1], self.im_2_2)
def test_drop(self):
intvl = self.im_2._intervals[0]
self.im_2.drop([intvl])
self.assertEqual(len(self.im_2._intervals), 1)
self.assertEqual(self.im_2._intervals[0], self.im_2_2)
# test the intvl was set to dropped
self.assertTrue(intvl.dropped)
def test_drop_all(self):
self.im_2.drop(self.im_2._intervals)
self.assertEqual(self.im_2, self.im_empty)
def test_reverse(self):
self.im_2._reverse()
Interval(
interval_metadata=self.im_empty,
bounds=[(0, 6), (8, 9)],
metadata={'gene': 'sagA', 'bound': 0})
Interval(
interval_metadata=self.im_empty,
bounds=[(5, 7)],
metadata={'gene': 'sagB', 'bound': 0, 'spam': [0]})
self.assertEqual(self.im_2, self.im_empty)
def test_eq_ne(self):
im1 = IntervalMetadata(10)
im1.add(metadata={'gene': 'sagA', 'bound': '0'},
bounds=[(0, 2), (4, 7)])
im1.add(metadata={'gene': 'sagB', 'bound': '3'},
bounds=[(3, 5)])
# The ordering shouldn't matter
im2 = IntervalMetadata(10)
im2.add(metadata={'gene': 'sagB', 'bound': '3'},
bounds=[(3, 5)])
im2.add(metadata={'gene': 'sagA', 'bound': '0'},
bounds=[(0, 2), (4, 7)])
im3 = IntervalMetadata(10)
im3.add(metadata={'gene': 'sagA', 'bound': '3'},
bounds=[(0, 2), (4, 7)])
im3.add(metadata={'gene': 'sagB', 'bound': '3'},
bounds=[(3, 5)])
self.assertReallyEqual(im1, im2)
self.assertReallyNotEqual(im1, im3)
def test_ne_diff_bounds(self):
im1 = IntervalMetadata(10)
im2 = IntervalMetadata(9)
intvl = {'bounds': [(0, 1)], 'metadata': {'spam': 'foo'}}
im1.add(**intvl)
im2.add(**intvl)
self.assertReallyNotEqual(im1, im2)
def test_repr(self):
exp = '''0 interval features
-------------------'''
self.assertEqual(repr(self.im_empty), exp)
self.im_empty.add([(1, 2)], metadata={'gene': 'sagA'})
exp = '''1 interval feature
------------------
Interval\(interval_metadata=<[0-9]+>, bounds=\[\(1, 2\)\], \
fuzzy=\[\(False, False\)\], metadata={'gene': 'sagA'}\)'''
self.assertRegex(repr(self.im_empty), exp)
self.im_empty.add([(3, 4)], metadata={'gene': 'sagB'})
self.im_empty.add([(3, 4)], metadata={'gene': 'sagC'})
self.im_empty.add([(3, 4)], metadata={'gene': 'sagD'})
self.im_empty.add([(3, 4)], metadata={'gene': 'sagE'})
self.im_empty.add([(3, 4)], metadata={'gene': 'sagF'})
exp = '''6 interval features
-------------------
Interval\(interval_metadata=<[0-9]+>, bounds=\[\(1, 2\)\], \
fuzzy=\[\(False, False\)\], metadata={'gene': 'sagA'}\)
Interval\(interval_metadata=<[0-9]+>, bounds=\[\(3, 4\)\], \
fuzzy=\[\(False, False\)\], metadata={'gene': 'sagB'}\)
...
Interval\(interval_metadata=<[0-9]+>, bounds=\[\(3, 4\)\], \
fuzzy=\[\(False, False\)\], metadata={'gene': 'sagE'}\)
Interval\(interval_metadata=<[0-9]+>, bounds=\[\(3, 4\)\], \
fuzzy=\[\(False, False\)\], metadata={'gene': 'sagF'}\)'''
self.assertRegex(repr(self.im_empty), exp)
class TestIntervalMetadata(unittest.TestCase, ReallyEqualMixin):
def setUp(self):
self.upper_bound = 10
self.im_empty = IntervalMetadata(self.upper_bound)
self.im_1 = IntervalMetadata(self.upper_bound)
self.im_1_1 = Interval(
interval_metadata=self.im_1,
bounds=[(1, 2), (4, self.upper_bound)],
metadata={'gene': 'sagA', 'bound': 0})
self.im_2 = IntervalMetadata(self.upper_bound)
self.im_2_1 = Interval(
interval_metadata=self.im_2,
bounds=[(1, 2), (4, self.upper_bound)],
metadata={'gene': 'sagA', 'bound': 0})
self.im_2_2 = Interval(
interval_metadata=self.im_2,
bounds=[(3, 5)],
metadata={'gene': 'sagB', 'bound': 0, 'spam': [0]})
def test_copy_empty(self):
obs = copy(self.im_empty)
self.assertEqual(obs, self.im_empty)
self.assertIsNot(obs._intervals, self.im_empty._intervals)
self.assertIsNot(obs._interval_tree, self.im_empty._interval_tree)
def test_copy(self):
obs = copy(self.im_2)
self.assertEqual(obs, self.im_2)
self.assertIsNot(obs._intervals, self.im_2._intervals)
self.assertIsNot(obs._interval_tree, self.im_2._interval_tree)
for i in range(self.im_2.num_interval_features):
i1, i2 = obs._intervals[i], self.im_2._intervals[i]
self.assertIsNot(i1, i2)
self.assertIsNot(i1.bounds, i2.bounds)
self.assertIsNot(i1.fuzzy, i2.fuzzy)
self.assertIsNot(i1._interval_metadata, i2._interval_metadata)
self.assertIsNot(i1.metadata, i2.metadata)
for k in i1.metadata:
self.assertIs(i1.metadata[k], i2.metadata[k])
def test_deepcopy(self):
obs = deepcopy(self.im_2)
self.assertEqual(obs, self.im_2)
self.assertIsNot(obs._intervals, self.im_2._intervals)
self.assertIsNot(obs._interval_tree, self.im_2._interval_tree)
for i in range(self.im_2.num_interval_features):
i1, i2 = obs._intervals[i], self.im_2._intervals[i]
self.assertIsNot(i1, i2)
self.assertIsNot(i1.bounds, i2.bounds)
self.assertIsNot(i1.fuzzy, i2.fuzzy)
self.assertIsNot(i1.metadata, i2.metadata)
i2.metadata['spam'].append(1)
self.assertEqual(i2.metadata,
{'gene': 'sagB', 'bound': 0, 'spam': [0, 1]})
self.assertEqual(i1.metadata,
{'gene': 'sagB', 'bound': 0, 'spam': [0]})
def test_deepcopy_memo_is_respected(self):
memo = {}
deepcopy(self.im_1, memo)
self.assertGreater(len(memo), 2)
def test_init(self):
self.assertFalse(self.im_empty._is_stale_tree)
self.assertEqual(self.im_empty._intervals, [])
def test_init_upper_bound_lt_lower_bound(self):
# test that no exception is raised
IntervalMetadata(0)
with self.assertRaises(ValueError):
IntervalMetadata(-1)
def test_num_interval_features(self):
self.assertEqual(self.im_empty.num_interval_features, 0)
self.assertEqual(self.im_1.num_interval_features, 1)
self.assertEqual(self.im_2.num_interval_features, 2)
def test_duplicate(self):
'''Test query and drop methods on duplicate Intervals.'''
intvl_1 = self.im_empty.add([(1, 2)])
intvl_2 = self.im_empty.add([(1, 2)])
self.assertEqual(len(list(self.im_empty.query([(1, 2)]))), 2)
self.im_empty.drop([intvl_1])
self.assertEqual(len(self.im_empty._intervals), 1)
self.assertTrue(self.im_empty._intervals[0] is intvl_2)
def test_duplicate_bounds(self):
intvl = self.im_empty.add([(1, 2), (1, 2)])
intvls = list(self.im_empty.query([(1, 2)]))
self.assertEqual(len(intvls), 1)
self.assertTrue(intvl is intvls[0])
def test_concat_empty(self):
for i in 0, 1, 2:
obs = IntervalMetadata.concat([self.im_empty] * i)
exp = IntervalMetadata(self.upper_bound * i)
self.assertEqual(obs, exp)
obs = IntervalMetadata.concat([])
self.assertEqual(obs, IntervalMetadata(0))
def test_concat(self):
im1 = IntervalMetadata(3)
im2 = IntervalMetadata(4)
im3 = IntervalMetadata(5)
im1.add([(0, 2)], [(True, True)])
im2.add([(0, 3)], [(True, False)], {'gene': 'sagA'})
im2.add([(2, 4)], metadata={'gene': 'sagB'})
im3.add([(1, 5)], [(False, True)], {'gene': 'sagC'})
obs = IntervalMetadata.concat([im1, im2, im3])
exp = IntervalMetadata(12)
exp.add(bounds=[(0, 2)], fuzzy=[(True, True)])
exp.add(bounds=[(3, 6)], fuzzy=[(True, False)],
metadata={'gene': 'sagA'})
exp.add(bounds=[(5, 7)], metadata={'gene': 'sagB'})
exp.add(bounds=[(8, 12)], fuzzy=[(False, True)],
metadata={'gene': 'sagC'})
self.assertEqual(obs, exp)
def test_sort(self):
interval = Interval(
self.im_2,
[(1, 2), (3, 8)],
metadata={'gene': 'sagA', 'bound': 0})
im = deepcopy(self.im_2)
self.im_2.sort(False)
# check sorting does not have other side effects
self.assertEqual(im, self.im_2)
self.assertEqual(self.im_2._intervals,
[self.im_2_2, self.im_2_1, interval])
self.im_2.sort()
self.assertEqual(im, self.im_2)
self.assertEqual(self.im_2._intervals,
[interval, self.im_2_1, self.im_2_2])
self.im_empty.sort()
self.assertEqual(self.im_empty, IntervalMetadata(self.upper_bound))
def test_add_eq_upper_bound(self):
self.im_empty.add(bounds=[(1, 2), (4, self.upper_bound)],
metadata={'gene': 'sagA', 'bound': 0})
self.assertTrue(self.im_empty._is_stale_tree)
interval = self.im_empty._intervals[0]
self.assertEqual(interval.bounds, [(1, 2), (4, self.upper_bound)])
self.assertEqual(interval.metadata, {'gene': 'sagA', 'bound': 0})
self.assertTrue(isinstance(self.im_empty._interval_tree, IntervalTree))
def test_add_gt_upper_bound(self):
with self.assertRaises(ValueError):
self.im_empty.add(bounds=[(1, 2), (4, self.upper_bound+1)],
metadata={'gene': 'sagA', 'bound': 0})
def test_add_eq_start_end_bound(self):
for i in 0, 1, self.upper_bound:
# test that no exception is raised
self.im_empty.add(bounds=[(i, i)],
metadata={'gene': 'sagA', 'bound': 0})
def test_query_attribute(self):
intervals = self.im_2._query_attribute({})
for i, j in zip(intervals, self.im_2._intervals):
self.assertEqual(i, j)
intervals = list(self.im_2._query_attribute(None))
self.assertEqual(len(intervals), 0)
for i in self.im_2._intervals:
intervals = list(self.im_2._query_attribute(i.metadata))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], i)
def test_query_interval(self):
intervals = list(self.im_2._query_interval((1, 2)))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], self.im_2_1)
intervals = list(self.im_2._query_interval((3, 4)))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], self.im_2_2)
intervals = {repr(i) for i in self.im_2._query_interval((1, 7))}
self.assertEqual(len(intervals), 2)
self.assertSetEqual(intervals,
{repr(i) for i in self.im_2._intervals})
def test_query_interval_upper_bound(self):
intervals = list(self.im_2._query_interval((self.upper_bound-1,
self.upper_bound)))
self.assertEqual(intervals, [self.im_2_1])
def test_query(self):
intervals = list(self.im_2.query(bounds=[(1, 5)],
metadata={'gene': 'sagA'}))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], self.im_2_1)
def test_query_empty(self):
intervals = list(self.im_1.query())
self.assertEqual(len(intervals), 0)
def test_query_no_hits(self):
intervals = list(self.im_2.query(bounds=[(self.upper_bound, 200)]))
self.assertEqual(len(intervals), 0)
intervals = list(self.im_2.query(metadata={'gene': 'sagC'}))
self.assertEqual(len(intervals), 0)
intervals = list(self.im_2.query(bounds=[(1, 2)],
metadata={'gene': 'sagC'}))
self.assertEqual(len(intervals), 0)
def test_query_interval_only(self):
for loc in [[(1, 7)],
[(1, 2), (3, 4)]]:
intervals = list(self.im_2.query(bounds=loc))
self.assertEqual(len(intervals), 2)
self.assertEqual(intervals[0], self.im_2_1)
self.assertEqual(intervals[1], self.im_2_2)
def test_query_metadata_only(self):
intervals = list(self.im_2.query(metadata={'gene': 'sagB'}))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], self.im_2_2)
intervals = list(self.im_2.query(metadata={'bound': 0}))
self.assertEqual(len(intervals), 2)
self.assertEqual(intervals[0], self.im_2_1)
self.assertEqual(intervals[1], self.im_2_2)
def test_drop(self):
intvl = self.im_2._intervals[0]
self.im_2.drop([intvl])
self.assertEqual(len(self.im_2._intervals), 1)
self.assertEqual(self.im_2._intervals[0], self.im_2_2)
# test the intvl was set to dropped
self.assertTrue(intvl.dropped)
def test_drop_all(self):
self.im_2.drop(self.im_2._intervals)
self.assertEqual(self.im_2, self.im_empty)
def test_reverse(self):
self.im_2._reverse()
Interval(
interval_metadata=self.im_empty,
bounds=[(0, 6), (8, 9)],
metadata={'gene': 'sagA', 'bound': 0})
Interval(
interval_metadata=self.im_empty,
bounds=[(5, 7)],
metadata={'gene': 'sagB', 'bound': 0, 'spam': [0]})
self.assertEqual(self.im_2, self.im_empty)
def test_eq_ne(self):
im1 = IntervalMetadata(10)
im1.add(metadata={'gene': 'sagA', 'bound': '0'},
bounds=[(0, 2), (4, 7)])
im1.add(metadata={'gene': 'sagB', 'bound': '3'},
bounds=[(3, 5)])
# The ordering shouldn't matter
im2 = IntervalMetadata(10)
im2.add(metadata={'gene': 'sagB', 'bound': '3'},
bounds=[(3, 5)])
im2.add(metadata={'gene': 'sagA', 'bound': '0'},
bounds=[(0, 2), (4, 7)])
im3 = IntervalMetadata(10)
im3.add(metadata={'gene': 'sagA', 'bound': '3'},
bounds=[(0, 2), (4, 7)])
im3.add(metadata={'gene': 'sagB', 'bound': '3'},
bounds=[(3, 5)])
self.assertReallyEqual(im1, im2)
self.assertReallyNotEqual(im1, im3)
def test_ne_diff_bounds(self):
im1 = IntervalMetadata(10)
im2 = IntervalMetadata(9)
intvl = {'bounds': [(0, 1)], 'metadata': {'spam': 'foo'}}
im1.add(**intvl)
im2.add(**intvl)
self.assertReallyNotEqual(im1, im2)
def test_repr(self):
exp = '''0 interval features
-------------------'''
self.assertEqual(repr(self.im_empty), exp)
self.im_empty.add([(1, 2)], metadata={'gene': 'sagA'})
exp = '''1 interval feature
------------------
Interval\(interval_metadata=<[0-9]+>, bounds=\[\(1, 2\)\], \
fuzzy=\[\(False, False\)\], metadata={'gene': 'sagA'}\)'''
self.assertRegex(repr(self.im_empty), exp)
self.im_empty.add([(3, 4)], metadata={'gene': 'sagB'})
self.im_empty.add([(3, 4)], metadata={'gene': 'sagC'})
self.im_empty.add([(3, 4)], metadata={'gene': 'sagD'})
self.im_empty.add([(3, 4)], metadata={'gene': 'sagE'})
self.im_empty.add([(3, 4)], metadata={'gene': 'sagF'})
exp = '''6 interval features
-------------------
Interval\(interval_metadata=<[0-9]+>, bounds=\[\(1, 2\)\], \
fuzzy=\[\(False, False\)\], metadata={'gene': 'sagA'}\)
Interval\(interval_metadata=<[0-9]+>, bounds=\[\(3, 4\)\], \
fuzzy=\[\(False, False\)\], metadata={'gene': 'sagB'}\)
...
Interval\(interval_metadata=<[0-9]+>, bounds=\[\(3, 4\)\], \
fuzzy=\[\(False, False\)\], metadata={'gene': 'sagE'}\)
Interval\(interval_metadata=<[0-9]+>, bounds=\[\(3, 4\)\], \
fuzzy=\[\(False, False\)\], metadata={'gene': 'sagF'}\)'''
self.assertRegex(repr(self.im_empty), exp)
class TestIntervalMetadata(unittest.TestCase, ReallyEqualMixin):
def setUp(self):
self.upper_bound = 10
self.im_empty = IntervalMetadata(self.upper_bound)
self.im_1 = IntervalMetadata(self.upper_bound)
self.im_1_1 = Interval(
interval_metadata=self.im_1,
bounds=[(1, 2), (4, self.upper_bound)],
metadata={'gene': 'sagA', 'bound': 0})
self.im_2 = IntervalMetadata(self.upper_bound)
self.im_2_1 = Interval(
interval_metadata=self.im_2,
bounds=[(1, 2), (4, self.upper_bound)],
metadata={'gene': 'sagA', 'bound': 0})
self.im_2_2 = Interval(
interval_metadata=self.im_2,
bounds=[(3, 5)],
metadata={'gene': 'sagB', 'bound': 0, 'spam': [0]})
def test_copy_empty(self):
obs = copy(self.im_empty)
self.assertEqual(obs, self.im_empty)
self.assertIsNot(obs._intervals, self.im_empty._intervals)
self.assertIsNot(obs._interval_tree, self.im_empty._interval_tree)
def test_copy(self):
obs = copy(self.im_2)
self.assertEqual(obs, self.im_2)
self.assertIsNot(obs._intervals, self.im_2._intervals)
self.assertIsNot(obs._interval_tree, self.im_2._interval_tree)
for i in range(self.im_2.num_interval_features):
i1, i2 = obs._intervals[i], self.im_2._intervals[i]
self.assertIsNot(i1, i2)
self.assertIsNot(i1.bounds, i2.bounds)
self.assertIsNot(i1.fuzzy, i2.fuzzy)
self.assertIsNot(i1._interval_metadata, i2._interval_metadata)
self.assertIsNot(i1.metadata, i2.metadata)
for k in i1.metadata:
self.assertIs(i1.metadata[k], i2.metadata[k])
def test_deepcopy(self):
obs = deepcopy(self.im_2)
self.assertEqual(obs, self.im_2)
self.assertIsNot(obs._intervals, self.im_2._intervals)
self.assertIsNot(obs._interval_tree, self.im_2._interval_tree)
for i in range(self.im_2.num_interval_features):
i1, i2 = obs._intervals[i], self.im_2._intervals[i]
self.assertIsNot(i1, i2)
self.assertIsNot(i1.bounds, i2.bounds)
self.assertIsNot(i1.fuzzy, i2.fuzzy)
self.assertIsNot(i1.metadata, i2.metadata)
i2.metadata['spam'].append(1)
self.assertEqual(i2.metadata,
{'gene': 'sagB', 'bound': 0, 'spam': [0, 1]})
self.assertEqual(i1.metadata,
{'gene': 'sagB', 'bound': 0, 'spam': [0]})
def test_deepcopy_memo_is_respected(self):
memo = {}
deepcopy(self.im_1, memo)
self.assertGreater(len(memo), 2)
def test_init(self):
self.assertFalse(self.im_empty._is_stale_tree)
self.assertEqual(self.im_empty._intervals, [])
def test_init_upper_bound_lt_lower_bound(self):
# test that no exception is raised
IntervalMetadata(0)
with self.assertRaises(ValueError):
IntervalMetadata(-1)
def test_upper_bound_is_none(self):
im = IntervalMetadata(None)
# should not raise error
im.add([(0, 1000000000)])
self.assertIsNone(im.upper_bound)
with self.assertRaisesRegex(
TypeError, r'upper bound is `None`'):
im._reverse()
with self.assertRaisesRegex(
TypeError, r'upper bound is `None`'):
IntervalMetadata.concat([self.im_1, im])
def test_init_copy_from(self):
for i in [None, 99, 999]:
obs = IntervalMetadata(i, self.im_1)
exp = IntervalMetadata(i)
exp.add(bounds=[(1, 2), (4, self.upper_bound)],
metadata={'gene': 'sagA', 'bound': 0})
self.assertEqual(obs, exp)
def test_init_copy_from_empty(self):
for i in [None, 0, 9, 99, 999]:
obs = IntervalMetadata(i, self.im_empty)
exp = IntervalMetadata(i)
self.assertEqual(obs, exp)
# test it is shallow copy
self.assertIsNot(obs._intervals, self.im_empty._intervals)
self.assertIsNot(obs._interval_tree, self.im_empty._interval_tree)
def test_init_copy_from_shallow_copy(self):
obs = IntervalMetadata(self.upper_bound, self.im_2)
self.assertEqual(self.im_2, obs)
# test it is shallow copy
self.assertIsNot(obs._intervals, self.im_2._intervals)
self.assertIsNot(obs._interval_tree, self.im_2._interval_tree)
for i in range(self.im_2.num_interval_features):
i1, i2 = obs._intervals[i], self.im_2._intervals[i]
self.assertIsNot(i1, i2)
self.assertIsNot(i1.bounds, i2.bounds)
self.assertIsNot(i1.fuzzy, i2.fuzzy)
self.assertIsNot(i1._interval_metadata, i2._interval_metadata)
self.assertIsNot(i1.metadata, i2.metadata)
for k in i1.metadata:
self.assertIs(i1.metadata[k], i2.metadata[k])
def test_init_copy_from_error(self):
i = self.upper_bound - 1
with self.assertRaisesRegex(
ValueError, r'larger than upper bound \(%r\)' % i):
IntervalMetadata(i, self.im_2)
def test_num_interval_features(self):
self.assertEqual(self.im_empty.num_interval_features, 0)
self.assertEqual(self.im_1.num_interval_features, 1)
self.assertEqual(self.im_2.num_interval_features, 2)
def test_duplicate(self):
'''Test query and drop methods on duplicate Intervals.'''
intvl_1 = self.im_empty.add([(1, 2)])
intvl_2 = self.im_empty.add([(1, 2)])
self.assertEqual(len(list(self.im_empty.query([(1, 2)]))), 2)
self.im_empty.drop([intvl_1])
self.assertEqual(len(self.im_empty._intervals), 1)
self.assertTrue(self.im_empty._intervals[0] is intvl_2)
def test_duplicate_bounds(self):
intvl = self.im_empty.add([(1, 2), (1, 2)])
intvls = list(self.im_empty.query([(1, 2)]))
self.assertEqual(len(intvls), 1)
self.assertTrue(intvl is intvls[0])
def test_concat_empty(self):
for i in 0, 1, 2:
obs = IntervalMetadata.concat([self.im_empty] * i)
exp = IntervalMetadata(self.upper_bound * i)
self.assertEqual(obs, exp)
obs = IntervalMetadata.concat([])
self.assertEqual(obs, IntervalMetadata(0))
def test_concat(self):
im1 = IntervalMetadata(3)
im2 = IntervalMetadata(4)
im3 = IntervalMetadata(5)
im1.add([(0, 2)], [(True, True)])
im2.add([(0, 3)], [(True, False)], {'gene': 'sagA'})
im2.add([(2, 4)], metadata={'gene': 'sagB'})
im3.add([(1, 5)], [(False, True)], {'gene': 'sagC'})
obs = IntervalMetadata.concat([im1, im2, im3])
exp = IntervalMetadata(12)
exp.add(bounds=[(0, 2)], fuzzy=[(True, True)])
exp.add(bounds=[(3, 6)], fuzzy=[(True, False)],
metadata={'gene': 'sagA'})
exp.add(bounds=[(5, 7)], metadata={'gene': 'sagB'})
exp.add(bounds=[(8, 12)], fuzzy=[(False, True)],
metadata={'gene': 'sagC'})
self.assertEqual(obs, exp)
def test_merge(self):
# empty + empty
im = IntervalMetadata(self.upper_bound)
self.im_empty.merge(im)
self.assertEqual(self.im_empty, im)
# empty + non-empty
self.im_empty.merge(self.im_1)
self.assertEqual(self.im_empty, self.im_1)
# non-empty + non-empty
self.im_empty.merge(self.im_2)
self.im_2.merge(self.im_1)
self.assertEqual(self.im_empty, self.im_2)
def test_merge_unequal_upper_bounds(self):
n = 3
im1 = IntervalMetadata(n)
for im in [self.im_empty, self.im_1]:
with self.assertRaisesRegex(
ValueError,
r'not equal \(%d != %d\)' % (self.upper_bound, n)):
im.merge(im1)
def test_merge_to_unbounded(self):
for im in [self.im_empty, self.im_1, IntervalMetadata(None)]:
obs = IntervalMetadata(None)
obs.merge(im)
self.assertIsNone(obs.upper_bound)
self.assertEqual(obs._intervals, im._intervals)
def test_merge_unbounded_to_bounded(self):
im = IntervalMetadata(None)
with self.assertRaisesRegex(
ValueError,
r'Cannot merge an unbound IntervalMetadata object '
'to a bounded one'):
self.im_1.merge(im)
# original im is not changed
self.assertIsNone(im.upper_bound)
self.assertEqual(im._intervals, [])
def test_sort(self):
interval = Interval(
self.im_2,
[(1, 2), (3, 8)],
metadata={'gene': 'sagA', 'bound': 0})
im = deepcopy(self.im_2)
self.im_2.sort(False)
# check sorting does not have other side effects
self.assertEqual(im, self.im_2)
self.assertEqual(self.im_2._intervals,
[self.im_2_2, self.im_2_1, interval])
self.im_2.sort()
self.assertEqual(im, self.im_2)
self.assertEqual(self.im_2._intervals,
[interval, self.im_2_1, self.im_2_2])
self.im_empty.sort()
self.assertEqual(self.im_empty, IntervalMetadata(self.upper_bound))
def test_add_eq_upper_bound(self):
self.im_empty.add(bounds=[(1, 2), (4, self.upper_bound)],
metadata={'gene': 'sagA', 'bound': 0})
self.assertTrue(self.im_empty._is_stale_tree)
interval = self.im_empty._intervals[0]
self.assertEqual(interval.bounds, [(1, 2), (4, self.upper_bound)])
self.assertEqual(interval.metadata, {'gene': 'sagA', 'bound': 0})
self.assertTrue(isinstance(self.im_empty._interval_tree, IntervalTree))
def test_add_gt_upper_bound(self):
with self.assertRaises(ValueError):
self.im_empty.add(bounds=[(1, 2), (4, self.upper_bound+1)],
metadata={'gene': 'sagA', 'bound': 0})
def test_add_eq_start_end_bound(self):
for i in 0, 1, self.upper_bound:
# test that no exception is raised
self.im_empty.add(bounds=[(i, i)],
metadata={'gene': 'sagA', 'bound': 0})
def test_query_attribute(self):
intervals = self.im_2._query_attribute({})
for i, j in zip(intervals, self.im_2._intervals):
self.assertEqual(i, j)
intervals = list(self.im_2._query_attribute(None))
self.assertEqual(len(intervals), 0)
for i in self.im_2._intervals:
intervals = list(self.im_2._query_attribute(i.metadata))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], i)
def test_query_interval(self):
intervals = list(self.im_2._query_interval((1, 2)))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], self.im_2_1)
intervals = list(self.im_2._query_interval((3, 4)))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], self.im_2_2)
intervals = {repr(i) for i in self.im_2._query_interval((1, 7))}
self.assertEqual(len(intervals), 2)
self.assertSetEqual(intervals,
{repr(i) for i in self.im_2._intervals})
def test_query_interval_upper_bound(self):
intervals = list(self.im_2._query_interval((self.upper_bound-1,
self.upper_bound)))
self.assertEqual(intervals, [self.im_2_1])
def test_query(self):
intervals = list(self.im_2.query(bounds=[(1, 5)],
metadata={'gene': 'sagA'}))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], self.im_2_1)
def test_query_empty(self):
intervals = list(self.im_1.query())
self.assertEqual(len(intervals), 0)
def test_query_no_hits(self):
intervals = list(self.im_2.query(bounds=[(self.upper_bound, 200)]))
self.assertEqual(len(intervals), 0)
intervals = list(self.im_2.query(metadata={'gene': 'sagC'}))
self.assertEqual(len(intervals), 0)
intervals = list(self.im_2.query(bounds=[(1, 2)],
metadata={'gene': 'sagC'}))
self.assertEqual(len(intervals), 0)
def test_query_interval_only(self):
for loc in [[(1, 7)],
[(1, 2), (3, 4)]]:
intervals = list(self.im_2.query(bounds=loc))
self.assertEqual(len(intervals), 2)
self.assertEqual(intervals[0], self.im_2_1)
self.assertEqual(intervals[1], self.im_2_2)
def test_query_metadata_only(self):
intervals = list(self.im_2.query(metadata={'gene': 'sagB'}))
self.assertEqual(len(intervals), 1)
self.assertEqual(intervals[0], self.im_2_2)
intervals = list(self.im_2.query(metadata={'bound': 0}))
self.assertEqual(len(intervals), 2)
self.assertEqual(intervals[0], self.im_2_1)
self.assertEqual(intervals[1], self.im_2_2)
def test_drop(self):
intvl = self.im_2._intervals[0]
self.im_2.drop([intvl])
self.assertEqual(len(self.im_2._intervals), 1)
self.assertEqual(self.im_2._intervals[0], self.im_2_2)
# test the intvl was set to dropped
self.assertTrue(intvl.dropped)
def test_drop_all(self):
self.im_2.drop(self.im_2._intervals)
self.assertEqual(self.im_2, self.im_empty)
def test_drop_negate(self):
intvl = self.im_2._intervals[0]
self.im_2.drop([intvl], negate=True)
self.assertEqual(len(self.im_2._intervals), 1)
self.assertEqual(self.im_2._intervals[0], intvl)
# test the dropped intvl was set to dropped
self.assertTrue(self.im_2_2.dropped)
def test_reverse(self):
self.im_2._reverse()
Interval(
interval_metadata=self.im_empty,
bounds=[(0, 6), (8, 9)],
metadata={'gene': 'sagA', 'bound': 0})
Interval(
interval_metadata=self.im_empty,
bounds=[(5, 7)],
metadata={'gene': 'sagB', 'bound': 0, 'spam': [0]})
self.assertEqual(self.im_2, self.im_empty)
def test_eq_ne(self):
im1 = IntervalMetadata(10)
im1.add(metadata={'gene': 'sagA', 'bound': '0'},
bounds=[(0, 2), (4, 7)])
im1.add(metadata={'gene': 'sagB', 'bound': '3'},
bounds=[(3, 5)])
# The ordering shouldn't matter
im2 = IntervalMetadata(10)
im2.add(metadata={'gene': 'sagB', 'bound': '3'},
bounds=[(3, 5)])
im2.add(metadata={'gene': 'sagA', 'bound': '0'},
bounds=[(0, 2), (4, 7)])
im3 = IntervalMetadata(10)
im3.add(metadata={'gene': 'sagA', 'bound': '3'},
bounds=[(0, 2), (4, 7)])
im3.add(metadata={'gene': 'sagB', 'bound': '3'},
bounds=[(3, 5)])
self.assertReallyEqual(im1, im2)
self.assertReallyNotEqual(im1, im3)
def test_ne_diff_bounds(self):
im1 = IntervalMetadata(10)
im2 = IntervalMetadata(9)
intvl = {'bounds': [(0, 1)], 'metadata': {'spam': 'foo'}}
im1.add(**intvl)
im2.add(**intvl)
self.assertReallyNotEqual(im1, im2)
def test_repr(self):
exp = '''0 interval features
-------------------'''
self.assertEqual(repr(self.im_empty), exp)
self.im_empty.add([(1, 2)], metadata={'gene': 'sagA'})
exp = ("1 interval feature\n"
"------------------\n"
r"Interval\(interval_metadata=<[0-9]+>, bounds=\[\(1, 2\)\], "
r"fuzzy=\[\(False, False\)\], metadata={'gene': 'sagA'}\)")
self.assertRegex(repr(self.im_empty), exp)
self.im_empty.add([(3, 4)], metadata={'gene': 'sagB'})
self.im_empty.add([(3, 4)], metadata={'gene': 'sagC'})
self.im_empty.add([(3, 4)], metadata={'gene': 'sagD'})
self.im_empty.add([(3, 4)], metadata={'gene': 'sagE'})
self.im_empty.add([(3, 4)], metadata={'gene': 'sagF'})
exp = ("6 interval features\n"
"-------------------\n"
r"Interval\(interval_metadata=<[0-9]+>, bounds=\[\(1, 2\)\], "
r"fuzzy=\[\(False, False\)\], metadata={'gene': 'sagA'}\)\n"
r"Interval\(interval_metadata=<[0-9]+>, bounds=\[\(3, 4\)\], "
r"fuzzy=\[\(False, False\)\], metadata={'gene': 'sagB'}\)\n"
r"...\n"
r"Interval\(interval_metadata=<[0-9]+>, bounds=\[\(3, 4\)\], "
r"fuzzy=\[\(False, False\)\], metadata={'gene': 'sagE'}\)\n"
r"Interval\(interval_metadata=<[0-9]+>, bounds=\[\(3, 4\)\], "
r"fuzzy=\[\(False, False\)\], metadata={'gene': 'sagF'}\)")
self.assertRegex(repr(self.im_empty), exp)
