#!/usr/bin/env python # -*- mode:python; tab-width: 2; coding: utf-8 -*- """Partially backported python ABC classes""" from __future__ import absolute_import import sys import types if sys.version_info > (2, 6): raise ImportError("Use native ABC classes istead of this one.") # Instance of old-style class class _C: pass _InstanceType = type(_C()) def abstractmethod(funcobj): """A decorator indicating abstract methods. Requires that the metaclass is ABCMeta or derived from it. A class that has a metaclass derived from ABCMeta cannot be instantiated unless all of its abstract methods are overridden. The abstract methods can be called using any of the normal 'super' call mechanisms. Usage: class C: __metaclass__ = ABCMeta @abstractmethod def my_abstract_method(self, ...): ... """ funcobj.__isabstractmethod__ = True return funcobj class ABCMeta(type): """Metaclass for defining Abstract Base Classes (ABCs). Use this metaclass to create an ABC. An ABC can be subclassed directly, and then acts as a mix-in class. You can also register unrelated concrete classes (even built-in classes) and unrelated ABCs as 'virtual subclasses' -- these and their descendants will be considered subclasses of the registering ABC by the built-in issubclass() function, but the registering ABC won't show up in their MRO (Method Resolution Order) nor will method implementations defined by the registering ABC be callable (not even via super()). """ # A global counter that is incremented each time a class is # registered as a virtual subclass of anything. It forces the # negative cache to be cleared before its next use. _abc_invalidation_counter = 0 def __new__(mcls, name, bases, namespace): cls = super(ABCMeta, mcls).__new__(mcls, name, bases, namespace) # Compute set of abstract method names abstracts = set(name for name, value in namespace.items() if getattr(value, "__isabstractmethod__", False)) for base in bases: for name in getattr(base, "__abstractmethods__", set()): value = getattr(cls, name, None) if getattr(value, "__isabstractmethod__", False): abstracts.add(name) cls.__abstractmethods__ = frozenset(abstracts) # Set up inheritance registry cls._abc_registry = set() cls._abc_cache = set() cls._abc_negative_cache = set() cls._abc_negative_cache_version = ABCMeta._abc_invalidation_counter return cls def register(cls, subclass): """Register a virtual subclass of an ABC.""" if not isinstance(subclass, (type, types.ClassType)): raise TypeError("Can only register classes") if issubclass(subclass, cls): return # Already a subclass # Subtle: test for cycles *after* testing for "already a subclass"; # this means we allow X.register(X) and interpret it as a no-op. if issubclass(cls, subclass): # This would create a cycle, which is bad for the algorithm below raise RuntimeError("Refusing to create an inheritance cycle") cls._abc_registry.add(subclass) ABCMeta._abc_invalidation_counter += 1 # Invalidate negative cache def _dump_registry(cls, file=None): """Debug helper to print the ABC registry.""" print >> file, "Class: %s.%s" % (cls.__module__, cls.__name__) print >> file, "Inv.counter: %s" % ABCMeta._abc_invalidation_counter for name in sorted(cls.__dict__.keys()): if name.startswith("_abc_"): value = getattr(cls, name) print >> file, "%s: %r" % (name, value) def __instancecheck__(cls, instance): """Override for isinstance(instance, cls).""" # Inline the cache checking when it's simple. subclass = getattr(instance, '__class__', None) if subclass in cls._abc_cache: return True subtype = type(instance) # Old-style instances if subtype is _InstanceType: subtype = subclass if subtype is subclass or subclass is None: if (cls._abc_negative_cache_version == ABCMeta._abc_invalidation_counter and subtype in cls._abc_negative_cache): return False # Fall back to the subclass check. return cls.__subclasscheck__(subtype) return (cls.__subclasscheck__(subclass) or cls.__subclasscheck__(subtype)) def __subclasscheck__(cls, subclass): """Override for issubclass(subclass, cls).""" # Check cache if subclass in cls._abc_cache: return True # Check negative cache; may have to invalidate if cls._abc_negative_cache_version < ABCMeta._abc_invalidation_counter: # Invalidate the negative cache cls._abc_negative_cache = set() cls._abc_negative_cache_version = ABCMeta._abc_invalidation_counter elif subclass in cls._abc_negative_cache: return False # Check the subclass hook ok = cls.__subclasshook__(subclass) if ok is not NotImplemented: assert isinstance(ok, bool) if ok: cls._abc_cache.add(subclass) else: cls._abc_negative_cache.add(subclass) return ok # Check if it's a direct subclass if cls in getattr(subclass, '__mro__', ()): cls._abc_cache.add(subclass) return True # Check if it's a subclass of a registered class (recursive) for rcls in cls._abc_registry: if issubclass(subclass, rcls): cls._abc_cache.add(subclass) return True # Check if it's a subclass of a subclass (recursive) for scls in cls.__subclasses__(): if issubclass(subclass, scls): cls._abc_cache.add(subclass) return True # No dice; update negative cache cls._abc_negative_cache.add(subclass) return False def _hasattr(C, attr): try: return any(attr in B.__dict__ for B in C.__mro__) except AttributeError: # Old-style class return hasattr(C, attr) class Sized: __metaclass__ = ABCMeta @abstractmethod def __len__(self): return 0 @classmethod def __subclasshook__(cls, C): if cls is Sized: if _hasattr(C, "__len__"): return True return NotImplemented class Container: __metaclass__ = ABCMeta @abstractmethod def __contains__(self, x): return False @classmethod def __subclasshook__(cls, C): if cls is Container: if _hasattr(C, "__contains__"): return True return NotImplemented class Iterable: __metaclass__ = ABCMeta @abstractmethod def __iter__(self): while False: yield None @classmethod def __subclasshook__(cls, C): if cls is Iterable: if _hasattr(C, "__iter__"): return True return NotImplemented Iterable.register(str) class Set(Sized, Iterable, Container): """A set is a finite, iterable container. This class provides concrete generic implementations of all methods except for __contains__, __iter__ and __len__. To override the comparisons (presumably for speed, as the semantics are fixed), all you have to do is redefine __le__ and then the other operations will automatically follow suit. """ def __le__(self, other): if not isinstance(other, Set): return NotImplemented if len(self) > len(other): return False for elem in self: if elem not in other: return False return True def __lt__(self, other): if not isinstance(other, Set): return NotImplemented return len(self) < len(other) and self.__le__(other) def __gt__(self, other): if not isinstance(other, Set): return NotImplemented return other < self def __ge__(self, other): if not isinstance(other, Set): return NotImplemented return other <= self def __eq__(self, other): if not isinstance(other, Set): return NotImplemented return len(self) == len(other) and self.__le__(other) def __ne__(self, other): return not (self == other) @classmethod def _from_iterable(cls, it): '''Construct an instance of the class from any iterable input. Must override this method if the class constructor signature does not accept an iterable for an input. ''' return cls(it) def __and__(self, other): if not isinstance(other, Iterable): return NotImplemented return self._from_iterable(value for value in other if value in self) def isdisjoint(self, other): for value in other: if value in self: return False return True def __or__(self, other): if not isinstance(other, Iterable): return NotImplemented chain = (e for s in (self, other) for e in s) return self._from_iterable(chain) def __sub__(self, other): if not isinstance(other, Set): if not isinstance(other, Iterable): return NotImplemented other = self._from_iterable(other) return self._from_iterable(value for value in self if value not in other) def __xor__(self, other): if not isinstance(other, Set): if not isinstance(other, Iterable): return NotImplemented other = self._from_iterable(other) return (self - other) | (other - self) # Sets are not hashable by default, but subclasses can change this __hash__ = None def _hash(self): """Compute the hash value of a set. Note that we don't define __hash__: not all sets are hashable. But if you define a hashable set type, its __hash__ should call this function. This must be compatible __eq__. All sets ought to compare equal if they contain the same elements, regardless of how they are implemented, and regardless of the order of the elements; so there's not much freedom for __eq__ or __hash__. We match the algorithm used by the built-in frozenset type. """ MAX = sys.maxint MASK = 2 * MAX + 1 n = len(self) h = 1927868237 * (n + 1) h &= MASK for x in self: hx = hash(x) h ^= (hx ^ (hx << 16) ^ 89869747) * 3644798167 h &= MASK h = h * 69069 + 907133923 h &= MASK if h > MAX: h -= MASK + 1 if h == -1: h = 590923713 return h Set.register(frozenset) class MutableSet(Set): @abstractmethod def add(self, value): """Add an element.""" raise NotImplementedError @abstractmethod def discard(self, value): """Remove an element. Do not raise an exception if absent.""" raise NotImplementedError def remove(self, value): """Remove an element. If not a member, raise a KeyError.""" if value not in self: raise KeyError(value) self.discard(value) def pop(self): """Return the popped value. Raise KeyError if empty.""" it = iter(self) try: value = it.next() except StopIteration: raise KeyError self.discard(value) return value def clear(self): """This is slow (creates N new iterators!) but effective.""" try: while True: self.pop() except KeyError: pass def __ior__(self, it): for value in it: self.add(value) return self def __iand__(self, it): for value in (self - it): self.discard(value) return self def __ixor__(self, it): if not isinstance(it, Set): it = self._from_iterable(it) for value in it: if value in self: self.discard(value) else: self.add(value) return self def __isub__(self, it): for value in it: self.discard(value) return self MutableSet.register(set) class OrderedSet(MutableSet): def __init__(self, iterable=None): self.end = end = [] end += [None, end, end] # sentinel node for doubly linked list self.map = {} # key --> [key, prev, next] if iterable is not None: self |= iterable def __len__(self): return len(self.map) def __contains__(self, key): return key in self.map def __getitem__(self, key): return list(self)[key] def add(self, key): if key not in self.map: end = self.end curr = end[PREV] curr[NEXT] = end[PREV] = self.map[key] = [key, curr, end] def discard(self, key): if key in self.map: key, prev, next = self.map.pop(key) prev[NEXT] = next next[PREV] = prev def __iter__(self): end = self.end curr = end[NEXT] while curr is not end: yield curr[KEY] curr = curr[NEXT] def __reversed__(self): end = self.end curr = end[PREV] while curr is not end: yield curr[KEY] curr = curr[PREV] def pop(self, last=True): if not self: raise KeyError('set is empty') key = reversed(self).next() if last else iter(self).next() self.discard(key) return key def __repr__(self): if not self: return '%s()' % (self.__class__.__name__,) return '%s(%r)' % (self.__class__.__name__, list(self)) def __eq__(self, other): if isinstance(other, OrderedSet): return len(self) == len(other) and list(self) == list(other) return set(self) == set(other) def __del__(self): self.clear() # remove circular references if __name__ == '__main__': print(OrderedSet('abracadaba')) print(OrderedSet('simsalabim'))