aoc-2022/venv/Lib/site-packages/pandas/tests/libs/test_hashtable.py

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from contextlib import contextmanager
import struct
import tracemalloc
import numpy as np
import pytest
from pandas._libs import hashtable as ht
import pandas as pd
import pandas._testing as tm
from pandas.core.algorithms import isin
@contextmanager
def activated_tracemalloc():
tracemalloc.start()
try:
yield
finally:
tracemalloc.stop()
def get_allocated_khash_memory():
snapshot = tracemalloc.take_snapshot()
snapshot = snapshot.filter_traces(
(tracemalloc.DomainFilter(True, ht.get_hashtable_trace_domain()),)
)
return sum(map(lambda x: x.size, snapshot.traces))
@pytest.mark.parametrize(
"table_type, dtype",
[
(ht.PyObjectHashTable, np.object_),
(ht.Complex128HashTable, np.complex128),
(ht.Int64HashTable, np.int64),
(ht.UInt64HashTable, np.uint64),
(ht.Float64HashTable, np.float64),
(ht.Complex64HashTable, np.complex64),
(ht.Int32HashTable, np.int32),
(ht.UInt32HashTable, np.uint32),
(ht.Float32HashTable, np.float32),
(ht.Int16HashTable, np.int16),
(ht.UInt16HashTable, np.uint16),
(ht.Int8HashTable, np.int8),
(ht.UInt8HashTable, np.uint8),
(ht.IntpHashTable, np.intp),
],
)
class TestHashTable:
def test_get_set_contains_len(self, table_type, dtype):
index = 5
table = table_type(55)
assert len(table) == 0
assert index not in table
table.set_item(index, 42)
assert len(table) == 1
assert index in table
assert table.get_item(index) == 42
table.set_item(index + 1, 41)
assert index in table
assert index + 1 in table
assert len(table) == 2
assert table.get_item(index) == 42
assert table.get_item(index + 1) == 41
table.set_item(index, 21)
assert index in table
assert index + 1 in table
assert len(table) == 2
assert table.get_item(index) == 21
assert table.get_item(index + 1) == 41
assert index + 2 not in table
with pytest.raises(KeyError, match=str(index + 2)):
table.get_item(index + 2)
def test_map_keys_to_values(self, table_type, dtype, writable):
# only Int64HashTable has this method
if table_type == ht.Int64HashTable:
N = 77
table = table_type()
keys = np.arange(N).astype(dtype)
vals = np.arange(N).astype(np.int64) + N
keys.flags.writeable = writable
vals.flags.writeable = writable
table.map_keys_to_values(keys, vals)
for i in range(N):
assert table.get_item(keys[i]) == i + N
def test_map_locations(self, table_type, dtype, writable):
N = 8
table = table_type()
keys = (np.arange(N) + N).astype(dtype)
keys.flags.writeable = writable
table.map_locations(keys)
for i in range(N):
assert table.get_item(keys[i]) == i
def test_lookup(self, table_type, dtype, writable):
N = 3
table = table_type()
keys = (np.arange(N) + N).astype(dtype)
keys.flags.writeable = writable
table.map_locations(keys)
result = table.lookup(keys)
expected = np.arange(N)
tm.assert_numpy_array_equal(result.astype(np.int64), expected.astype(np.int64))
def test_lookup_wrong(self, table_type, dtype):
if dtype in (np.int8, np.uint8):
N = 100
else:
N = 512
table = table_type()
keys = (np.arange(N) + N).astype(dtype)
table.map_locations(keys)
wrong_keys = np.arange(N).astype(dtype)
result = table.lookup(wrong_keys)
assert np.all(result == -1)
def test_unique(self, table_type, dtype, writable):
if dtype in (np.int8, np.uint8):
N = 88
else:
N = 1000
table = table_type()
expected = (np.arange(N) + N).astype(dtype)
keys = np.repeat(expected, 5)
keys.flags.writeable = writable
unique = table.unique(keys)
tm.assert_numpy_array_equal(unique, expected)
def test_tracemalloc_works(self, table_type, dtype):
if dtype in (np.int8, np.uint8):
N = 256
else:
N = 30000
keys = np.arange(N).astype(dtype)
with activated_tracemalloc():
table = table_type()
table.map_locations(keys)
used = get_allocated_khash_memory()
my_size = table.sizeof()
assert used == my_size
del table
assert get_allocated_khash_memory() == 0
def test_tracemalloc_for_empty(self, table_type, dtype):
with activated_tracemalloc():
table = table_type()
used = get_allocated_khash_memory()
my_size = table.sizeof()
assert used == my_size
del table
assert get_allocated_khash_memory() == 0
def test_get_state(self, table_type, dtype):
table = table_type(1000)
state = table.get_state()
assert state["size"] == 0
assert state["n_occupied"] == 0
assert "n_buckets" in state
assert "upper_bound" in state
@pytest.mark.parametrize("N", range(1, 110))
def test_no_reallocation(self, table_type, dtype, N):
keys = np.arange(N).astype(dtype)
preallocated_table = table_type(N)
n_buckets_start = preallocated_table.get_state()["n_buckets"]
preallocated_table.map_locations(keys)
n_buckets_end = preallocated_table.get_state()["n_buckets"]
# original number of buckets was enough:
assert n_buckets_start == n_buckets_end
# check with clean table (not too much preallocated)
clean_table = table_type()
clean_table.map_locations(keys)
assert n_buckets_start == clean_table.get_state()["n_buckets"]
class TestHashTableUnsorted:
# TODO: moved from test_algos; may be redundancies with other tests
def test_string_hashtable_set_item_signature(self):
# GH#30419 fix typing in StringHashTable.set_item to prevent segfault
tbl = ht.StringHashTable()
tbl.set_item("key", 1)
assert tbl.get_item("key") == 1
with pytest.raises(TypeError, match="'key' has incorrect type"):
# key arg typed as string, not object
tbl.set_item(4, 6)
with pytest.raises(TypeError, match="'val' has incorrect type"):
tbl.get_item(4)
def test_lookup_nan(self, writable):
# GH#21688 ensure we can deal with readonly memory views
xs = np.array([2.718, 3.14, np.nan, -7, 5, 2, 3])
xs.setflags(write=writable)
m = ht.Float64HashTable()
m.map_locations(xs)
tm.assert_numpy_array_equal(m.lookup(xs), np.arange(len(xs), dtype=np.intp))
def test_add_signed_zeros(self):
# GH#21866 inconsistent hash-function for float64
# default hash-function would lead to different hash-buckets
# for 0.0 and -0.0 if there are more than 2^30 hash-buckets
# but this would mean 16GB
N = 4 # 12 * 10**8 would trigger the error, if you have enough memory
m = ht.Float64HashTable(N)
m.set_item(0.0, 0)
m.set_item(-0.0, 0)
assert len(m) == 1 # 0.0 and -0.0 are equivalent
def test_add_different_nans(self):
# GH#21866 inconsistent hash-function for float64
# create different nans from bit-patterns:
NAN1 = struct.unpack("d", struct.pack("=Q", 0x7FF8000000000000))[0]
NAN2 = struct.unpack("d", struct.pack("=Q", 0x7FF8000000000001))[0]
assert NAN1 != NAN1
assert NAN2 != NAN2
# default hash function would lead to different hash-buckets
# for NAN1 and NAN2 even if there are only 4 buckets:
m = ht.Float64HashTable()
m.set_item(NAN1, 0)
m.set_item(NAN2, 0)
assert len(m) == 1 # NAN1 and NAN2 are equivalent
def test_lookup_overflow(self, writable):
xs = np.array([1, 2, 2**63], dtype=np.uint64)
# GH 21688 ensure we can deal with readonly memory views
xs.setflags(write=writable)
m = ht.UInt64HashTable()
m.map_locations(xs)
tm.assert_numpy_array_equal(m.lookup(xs), np.arange(len(xs), dtype=np.intp))
@pytest.mark.parametrize("nvals", [0, 10]) # resizing to 0 is special case
@pytest.mark.parametrize(
"htable, uniques, dtype, safely_resizes",
[
(ht.PyObjectHashTable, ht.ObjectVector, "object", False),
(ht.StringHashTable, ht.ObjectVector, "object", True),
(ht.Float64HashTable, ht.Float64Vector, "float64", False),
(ht.Int64HashTable, ht.Int64Vector, "int64", False),
(ht.Int32HashTable, ht.Int32Vector, "int32", False),
(ht.UInt64HashTable, ht.UInt64Vector, "uint64", False),
],
)
def test_vector_resize(
self, writable, htable, uniques, dtype, safely_resizes, nvals
):
# Test for memory errors after internal vector
# reallocations (GH 7157)
# Changed from using np.random.rand to range
# which could cause flaky CI failures when safely_resizes=False
vals = np.array(range(1000), dtype=dtype)
# GH 21688 ensures we can deal with read-only memory views
vals.setflags(write=writable)
# initialise instances; cannot initialise in parametrization,
# as otherwise external views would be held on the array (which is
# one of the things this test is checking)
htable = htable()
uniques = uniques()
# get_labels may append to uniques
htable.get_labels(vals[:nvals], uniques, 0, -1)
# to_array() sets an external_view_exists flag on uniques.
tmp = uniques.to_array()
oldshape = tmp.shape
# subsequent get_labels() calls can no longer append to it
# (except for StringHashTables + ObjectVector)
if safely_resizes:
htable.get_labels(vals, uniques, 0, -1)
else:
with pytest.raises(ValueError, match="external reference.*"):
htable.get_labels(vals, uniques, 0, -1)
uniques.to_array() # should not raise here
assert tmp.shape == oldshape
@pytest.mark.parametrize(
"hashtable",
[
ht.PyObjectHashTable,
ht.StringHashTable,
ht.Float64HashTable,
ht.Int64HashTable,
ht.Int32HashTable,
ht.UInt64HashTable,
],
)
def test_hashtable_large_sizehint(self, hashtable):
# GH#22729 smoketest for not raising when passing a large size_hint
size_hint = np.iinfo(np.uint32).max + 1
hashtable(size_hint=size_hint)
class TestPyObjectHashTableWithNans:
def test_nan_float(self):
nan1 = float("nan")
nan2 = float("nan")
assert nan1 is not nan2
table = ht.PyObjectHashTable()
table.set_item(nan1, 42)
assert table.get_item(nan2) == 42
def test_nan_complex_both(self):
nan1 = complex(float("nan"), float("nan"))
nan2 = complex(float("nan"), float("nan"))
assert nan1 is not nan2
table = ht.PyObjectHashTable()
table.set_item(nan1, 42)
assert table.get_item(nan2) == 42
def test_nan_complex_real(self):
nan1 = complex(float("nan"), 1)
nan2 = complex(float("nan"), 1)
other = complex(float("nan"), 2)
assert nan1 is not nan2
table = ht.PyObjectHashTable()
table.set_item(nan1, 42)
assert table.get_item(nan2) == 42
with pytest.raises(KeyError, match=None) as error:
table.get_item(other)
assert str(error.value) == str(other)
def test_nan_complex_imag(self):
nan1 = complex(1, float("nan"))
nan2 = complex(1, float("nan"))
other = complex(2, float("nan"))
assert nan1 is not nan2
table = ht.PyObjectHashTable()
table.set_item(nan1, 42)
assert table.get_item(nan2) == 42
with pytest.raises(KeyError, match=None) as error:
table.get_item(other)
assert str(error.value) == str(other)
def test_nan_in_tuple(self):
nan1 = (float("nan"),)
nan2 = (float("nan"),)
assert nan1[0] is not nan2[0]
table = ht.PyObjectHashTable()
table.set_item(nan1, 42)
assert table.get_item(nan2) == 42
def test_nan_in_nested_tuple(self):
nan1 = (1, (2, (float("nan"),)))
nan2 = (1, (2, (float("nan"),)))
other = (1, 2)
table = ht.PyObjectHashTable()
table.set_item(nan1, 42)
assert table.get_item(nan2) == 42
with pytest.raises(KeyError, match=None) as error:
table.get_item(other)
assert str(error.value) == str(other)
def test_hash_equal_tuple_with_nans():
a = (float("nan"), (float("nan"), float("nan")))
b = (float("nan"), (float("nan"), float("nan")))
assert ht.object_hash(a) == ht.object_hash(b)
assert ht.objects_are_equal(a, b)
def test_get_labels_groupby_for_Int64(writable):
table = ht.Int64HashTable()
vals = np.array([1, 2, -1, 2, 1, -1], dtype=np.int64)
vals.flags.writeable = writable
arr, unique = table.get_labels_groupby(vals)
expected_arr = np.array([0, 1, -1, 1, 0, -1], dtype=np.intp)
expected_unique = np.array([1, 2], dtype=np.int64)
tm.assert_numpy_array_equal(arr, expected_arr)
tm.assert_numpy_array_equal(unique, expected_unique)
def test_tracemalloc_works_for_StringHashTable():
N = 1000
keys = np.arange(N).astype(np.compat.unicode).astype(np.object_)
with activated_tracemalloc():
table = ht.StringHashTable()
table.map_locations(keys)
used = get_allocated_khash_memory()
my_size = table.sizeof()
assert used == my_size
del table
assert get_allocated_khash_memory() == 0
def test_tracemalloc_for_empty_StringHashTable():
with activated_tracemalloc():
table = ht.StringHashTable()
used = get_allocated_khash_memory()
my_size = table.sizeof()
assert used == my_size
del table
assert get_allocated_khash_memory() == 0
@pytest.mark.parametrize("N", range(1, 110))
def test_no_reallocation_StringHashTable(N):
keys = np.arange(N).astype(np.compat.unicode).astype(np.object_)
preallocated_table = ht.StringHashTable(N)
n_buckets_start = preallocated_table.get_state()["n_buckets"]
preallocated_table.map_locations(keys)
n_buckets_end = preallocated_table.get_state()["n_buckets"]
# original number of buckets was enough:
assert n_buckets_start == n_buckets_end
# check with clean table (not too much preallocated)
clean_table = ht.StringHashTable()
clean_table.map_locations(keys)
assert n_buckets_start == clean_table.get_state()["n_buckets"]
@pytest.mark.parametrize(
"table_type, dtype",
[
(ht.Float64HashTable, np.float64),
(ht.Float32HashTable, np.float32),
(ht.Complex128HashTable, np.complex128),
(ht.Complex64HashTable, np.complex64),
],
)
class TestHashTableWithNans:
def test_get_set_contains_len(self, table_type, dtype):
index = float("nan")
table = table_type()
assert index not in table
table.set_item(index, 42)
assert len(table) == 1
assert index in table
assert table.get_item(index) == 42
table.set_item(index, 41)
assert len(table) == 1
assert index in table
assert table.get_item(index) == 41
def test_map_locations(self, table_type, dtype):
N = 10
table = table_type()
keys = np.full(N, np.nan, dtype=dtype)
table.map_locations(keys)
assert len(table) == 1
assert table.get_item(np.nan) == N - 1
def test_unique(self, table_type, dtype):
N = 1020
table = table_type()
keys = np.full(N, np.nan, dtype=dtype)
unique = table.unique(keys)
assert np.all(np.isnan(unique)) and len(unique) == 1
def test_unique_for_nan_objects_floats():
table = ht.PyObjectHashTable()
keys = np.array([float("nan") for i in range(50)], dtype=np.object_)
unique = table.unique(keys)
assert len(unique) == 1
def test_unique_for_nan_objects_complex():
table = ht.PyObjectHashTable()
keys = np.array([complex(float("nan"), 1.0) for i in range(50)], dtype=np.object_)
unique = table.unique(keys)
assert len(unique) == 1
def test_unique_for_nan_objects_tuple():
table = ht.PyObjectHashTable()
keys = np.array(
[1] + [(1.0, (float("nan"), 1.0)) for i in range(50)], dtype=np.object_
)
unique = table.unique(keys)
assert len(unique) == 2
@pytest.mark.parametrize(
"dtype",
[
np.object_,
np.complex128,
np.int64,
np.uint64,
np.float64,
np.complex64,
np.int32,
np.uint32,
np.float32,
np.int16,
np.uint16,
np.int8,
np.uint8,
np.intp,
],
)
class TestHelpFunctions:
def test_value_count(self, dtype, writable):
N = 43
expected = (np.arange(N) + N).astype(dtype)
values = np.repeat(expected, 5)
values.flags.writeable = writable
keys, counts = ht.value_count(values, False)
tm.assert_numpy_array_equal(np.sort(keys), expected)
assert np.all(counts == 5)
def test_value_count_stable(self, dtype, writable):
# GH12679
values = np.array([2, 1, 5, 22, 3, -1, 8]).astype(dtype)
values.flags.writeable = writable
keys, counts = ht.value_count(values, False)
tm.assert_numpy_array_equal(keys, values)
assert np.all(counts == 1)
def test_duplicated_first(self, dtype, writable):
N = 100
values = np.repeat(np.arange(N).astype(dtype), 5)
values.flags.writeable = writable
result = ht.duplicated(values)
expected = np.ones_like(values, dtype=np.bool_)
expected[::5] = False
tm.assert_numpy_array_equal(result, expected)
def test_ismember_yes(self, dtype, writable):
N = 127
arr = np.arange(N).astype(dtype)
values = np.arange(N).astype(dtype)
arr.flags.writeable = writable
values.flags.writeable = writable
result = ht.ismember(arr, values)
expected = np.ones_like(values, dtype=np.bool_)
tm.assert_numpy_array_equal(result, expected)
def test_ismember_no(self, dtype):
N = 17
arr = np.arange(N).astype(dtype)
values = (np.arange(N) + N).astype(dtype)
result = ht.ismember(arr, values)
expected = np.zeros_like(values, dtype=np.bool_)
tm.assert_numpy_array_equal(result, expected)
def test_mode(self, dtype, writable):
if dtype in (np.int8, np.uint8):
N = 53
else:
N = 11111
values = np.repeat(np.arange(N).astype(dtype), 5)
values[0] = 42
values.flags.writeable = writable
result = ht.mode(values, False)
assert result == 42
def test_mode_stable(self, dtype, writable):
values = np.array([2, 1, 5, 22, 3, -1, 8]).astype(dtype)
values.flags.writeable = writable
keys = ht.mode(values, False)
tm.assert_numpy_array_equal(keys, values)
def test_modes_with_nans():
# GH42688, nans aren't mangled
nulls = [pd.NA, np.nan, pd.NaT, None]
values = np.array([True] + nulls * 2, dtype=np.object_)
modes = ht.mode(values, False)
assert modes.size == len(nulls)
def test_unique_label_indices_intp(writable):
keys = np.array([1, 2, 2, 2, 1, 3], dtype=np.intp)
keys.flags.writeable = writable
result = ht.unique_label_indices(keys)
expected = np.array([0, 1, 5], dtype=np.intp)
tm.assert_numpy_array_equal(result, expected)
def test_unique_label_indices():
a = np.random.randint(1, 1 << 10, 1 << 15).astype(np.intp)
left = ht.unique_label_indices(a)
right = np.unique(a, return_index=True)[1]
tm.assert_numpy_array_equal(left, right, check_dtype=False)
a[np.random.choice(len(a), 10)] = -1
left = ht.unique_label_indices(a)
right = np.unique(a, return_index=True)[1][1:]
tm.assert_numpy_array_equal(left, right, check_dtype=False)
@pytest.mark.parametrize(
"dtype",
[
np.float64,
np.float32,
np.complex128,
np.complex64,
],
)
class TestHelpFunctionsWithNans:
def test_value_count(self, dtype):
values = np.array([np.nan, np.nan, np.nan], dtype=dtype)
keys, counts = ht.value_count(values, True)
assert len(keys) == 0
keys, counts = ht.value_count(values, False)
assert len(keys) == 1 and np.all(np.isnan(keys))
assert counts[0] == 3
def test_duplicated_first(self, dtype):
values = np.array([np.nan, np.nan, np.nan], dtype=dtype)
result = ht.duplicated(values)
expected = np.array([False, True, True])
tm.assert_numpy_array_equal(result, expected)
def test_ismember_yes(self, dtype):
arr = np.array([np.nan, np.nan, np.nan], dtype=dtype)
values = np.array([np.nan, np.nan], dtype=dtype)
result = ht.ismember(arr, values)
expected = np.array([True, True, True], dtype=np.bool_)
tm.assert_numpy_array_equal(result, expected)
def test_ismember_no(self, dtype):
arr = np.array([np.nan, np.nan, np.nan], dtype=dtype)
values = np.array([1], dtype=dtype)
result = ht.ismember(arr, values)
expected = np.array([False, False, False], dtype=np.bool_)
tm.assert_numpy_array_equal(result, expected)
def test_mode(self, dtype):
values = np.array([42, np.nan, np.nan, np.nan], dtype=dtype)
assert ht.mode(values, True) == 42
assert np.isnan(ht.mode(values, False))
def test_ismember_tuple_with_nans():
# GH-41836
values = [("a", float("nan")), ("b", 1)]
comps = [("a", float("nan"))]
result = isin(values, comps)
expected = np.array([True, False], dtype=np.bool_)
tm.assert_numpy_array_equal(result, expected)
def test_float_complex_int_are_equal_as_objects():
values = ["a", 5, 5.0, 5.0 + 0j]
comps = list(range(129))
result = isin(values, comps)
expected = np.array([False, True, True, True], dtype=np.bool_)
tm.assert_numpy_array_equal(result, expected)