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Filename :
collections.pyx
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# cyextension/collections.pyx # Copyright (C) 2005-2024 the SQLAlchemy authors and contributors # <see AUTHORS file> # # This module is part of SQLAlchemy and is released under # the MIT License: https://www.opensource.org/licenses/mit-license.php cimport cython from cpython.long cimport PyLong_FromLongLong from cpython.set cimport PySet_Add from collections.abc import Collection from itertools import filterfalse cdef bint add_not_present(set seen, object item, hashfunc): hash_value = hashfunc(item) if hash_value not in seen: PySet_Add(seen, hash_value) return True else: return False cdef list cunique_list(seq, hashfunc=None): cdef set seen = set() if not hashfunc: return [x for x in seq if x not in seen and not PySet_Add(seen, x)] else: return [x for x in seq if add_not_present(seen, x, hashfunc)] def unique_list(seq, hashfunc=None): return cunique_list(seq, hashfunc) cdef class OrderedSet(set): cdef list _list @classmethod def __class_getitem__(cls, key): return cls def __init__(self, d=None): set.__init__(self) if d is not None: self._list = cunique_list(d) set.update(self, self._list) else: self._list = [] cpdef OrderedSet copy(self): cdef OrderedSet cp = OrderedSet.__new__(OrderedSet) cp._list = list(self._list) set.update(cp, cp._list) return cp @cython.final cdef OrderedSet _from_list(self, list new_list): cdef OrderedSet new = OrderedSet.__new__(OrderedSet) new._list = new_list set.update(new, new_list) return new def add(self, element): if element not in self: self._list.append(element) PySet_Add(self, element) def remove(self, element): # set.remove will raise if element is not in self set.remove(self, element) self._list.remove(element) def pop(self): try: value = self._list.pop() except IndexError: raise KeyError("pop from an empty set") from None set.remove(self, value) return value def insert(self, Py_ssize_t pos, element): if element not in self: self._list.insert(pos, element) PySet_Add(self, element) def discard(self, element): if element in self: set.remove(self, element) self._list.remove(element) def clear(self): set.clear(self) self._list = [] def __getitem__(self, key): return self._list[key] def __iter__(self): return iter(self._list) def __add__(self, other): return self.union(other) def __repr__(self): return "%s(%r)" % (self.__class__.__name__, self._list) __str__ = __repr__ def update(self, *iterables): for iterable in iterables: for e in iterable: if e not in self: self._list.append(e) set.add(self, e) def __ior__(self, iterable): self.update(iterable) return self def union(self, *other): result = self.copy() result.update(*other) return result def __or__(self, other): return self.union(other) def intersection(self, *other): cdef set other_set = set.intersection(self, *other) return self._from_list([a for a in self._list if a in other_set]) def __and__(self, other): return self.intersection(other) def symmetric_difference(self, other): cdef set other_set if isinstance(other, set): other_set = <set> other collection = other_set elif isinstance(other, Collection): collection = other other_set = set(other) else: collection = list(other) other_set = set(collection) result = self._from_list([a for a in self._list if a not in other_set]) result.update(a for a in collection if a not in self) return result def __xor__(self, other): return self.symmetric_difference(other) def difference(self, *other): cdef set other_set = set.difference(self, *other) return self._from_list([a for a in self._list if a in other_set]) def __sub__(self, other): return self.difference(other) def intersection_update(self, *other): set.intersection_update(self, *other) self._list = [a for a in self._list if a in self] def __iand__(self, other): self.intersection_update(other) return self cpdef symmetric_difference_update(self, other): collection = other if isinstance(other, Collection) else list(other) set.symmetric_difference_update(self, collection) self._list = [a for a in self._list if a in self] self._list += [a for a in collection if a in self] def __ixor__(self, other): self.symmetric_difference_update(other) return self def difference_update(self, *other): set.difference_update(self, *other) self._list = [a for a in self._list if a in self] def __isub__(self, other): self.difference_update(other) return self cdef object cy_id(object item): return PyLong_FromLongLong(<long long> (<void *>item)) # NOTE: cython 0.x will call __add__, __sub__, etc with the parameter swapped # instead of the __rmeth__, so they need to check that also self is of the # correct type. This is fixed in cython 3.x. See: # https://docs.cython.org/en/latest/src/userguide/special_methods.html#arithmetic-methods cdef class IdentitySet: """A set that considers only object id() for uniqueness. This strategy has edge cases for builtin types- it's possible to have two 'foo' strings in one of these sets, for example. Use sparingly. """ cdef dict _members def __init__(self, iterable=None): self._members = {} if iterable: self.update(iterable) def add(self, value): self._members[cy_id(value)] = value def __contains__(self, value): return cy_id(value) in self._members cpdef remove(self, value): del self._members[cy_id(value)] def discard(self, value): try: self.remove(value) except KeyError: pass def pop(self): cdef tuple pair try: pair = self._members.popitem() return pair[1] except KeyError: raise KeyError("pop from an empty set") def clear(self): self._members.clear() def __eq__(self, other): cdef IdentitySet other_ if isinstance(other, IdentitySet): other_ = other return self._members == other_._members else: return False def __ne__(self, other): cdef IdentitySet other_ if isinstance(other, IdentitySet): other_ = other return self._members != other_._members else: return True cpdef issubset(self, iterable): cdef IdentitySet other if isinstance(iterable, self.__class__): other = iterable else: other = self.__class__(iterable) if len(self) > len(other): return False for m in filterfalse(other._members.__contains__, self._members): return False return True def __le__(self, other): if not isinstance(other, IdentitySet): return NotImplemented return self.issubset(other) def __lt__(self, other): if not isinstance(other, IdentitySet): return NotImplemented return len(self) < len(other) and self.issubset(other) cpdef issuperset(self, iterable): cdef IdentitySet other if isinstance(iterable, self.__class__): other = iterable else: other = self.__class__(iterable) if len(self) < len(other): return False for m in filterfalse(self._members.__contains__, other._members): return False return True def __ge__(self, other): if not isinstance(other, IdentitySet): return NotImplemented return self.issuperset(other) def __gt__(self, other): if not isinstance(other, IdentitySet): return NotImplemented return len(self) > len(other) and self.issuperset(other) cpdef IdentitySet union(self, iterable): cdef IdentitySet result = self.__class__() result._members.update(self._members) result.update(iterable) return result def __or__(self, other): if not isinstance(other, IdentitySet) or not isinstance(self, IdentitySet): return NotImplemented return self.union(other) cpdef update(self, iterable): for obj in iterable: self._members[cy_id(obj)] = obj def __ior__(self, other): if not isinstance(other, IdentitySet): return NotImplemented self.update(other) return self cpdef IdentitySet difference(self, iterable): cdef IdentitySet result = self.__new__(self.__class__) if isinstance(iterable, self.__class__): other = (<IdentitySet>iterable)._members else: other = {cy_id(obj) for obj in iterable} result._members = {k:v for k, v in self._members.items() if k not in other} return result def __sub__(self, other): if not isinstance(other, IdentitySet) or not isinstance(self, IdentitySet): return NotImplemented return self.difference(other) cpdef difference_update(self, iterable): cdef IdentitySet other = self.difference(iterable) self._members = other._members def __isub__(self, other): if not isinstance(other, IdentitySet): return NotImplemented self.difference_update(other) return self cpdef IdentitySet intersection(self, iterable): cdef IdentitySet result = self.__new__(self.__class__) if isinstance(iterable, self.__class__): other = (<IdentitySet>iterable)._members else: other = {cy_id(obj) for obj in iterable} result._members = {k: v for k, v in self._members.items() if k in other} return result def __and__(self, other): if not isinstance(other, IdentitySet) or not isinstance(self, IdentitySet): return NotImplemented return self.intersection(other) cpdef intersection_update(self, iterable): cdef IdentitySet other = self.intersection(iterable) self._members = other._members def __iand__(self, other): if not isinstance(other, IdentitySet): return NotImplemented self.intersection_update(other) return self cpdef IdentitySet symmetric_difference(self, iterable): cdef IdentitySet result = self.__new__(self.__class__) cdef dict other if isinstance(iterable, self.__class__): other = (<IdentitySet>iterable)._members else: other = {cy_id(obj): obj for obj in iterable} result._members = {k: v for k, v in self._members.items() if k not in other} result._members.update( [(k, v) for k, v in other.items() if k not in self._members] ) return result def __xor__(self, other): if not isinstance(other, IdentitySet) or not isinstance(self, IdentitySet): return NotImplemented return self.symmetric_difference(other) cpdef symmetric_difference_update(self, iterable): cdef IdentitySet other = self.symmetric_difference(iterable) self._members = other._members def __ixor__(self, other): if not isinstance(other, IdentitySet): return NotImplemented self.symmetric_difference(other) return self cpdef IdentitySet copy(self): cdef IdentitySet cp = self.__new__(self.__class__) cp._members = self._members.copy() return cp def __copy__(self): return self.copy() def __len__(self): return len(self._members) def __iter__(self): return iter(self._members.values()) def __hash__(self): raise TypeError("set objects are unhashable") def __repr__(self): return "%s(%r)" % (type(self).__name__, list(self._members.values()))