Remove singledispatch.

2024-12-18 08:43:37 +00:00 · 2023-05-16 14:11:34 +01:00 · 2023-05-16 14:11:34 +01:00 · e08156ce61
commit e08156ce61
parent 8ac3d82c12
3 changed files with 1 additions and 389 deletions
--- a/CHANGES.md
+++ b/CHANGES.md
@ -14,6 +14,7 @@
 * Update SimpleJSON 3.18.1 (c891b95) to 3.19.1 (aeb63ee)
 * Update Tornado Web Server 6.3.0 (7186b86) to 6.3.2 (e3aa6c5)
 * Update urllib3 1.26.14 (a06c05c) to 1.26.15 (25cca389)
 * Remove singledispatch
 * Change allow rapidfuzz update from 2.x.x to 3.x.x
 * Change remove redundant py2 import futures
 * Change add jobs to centralise scheduler activities
--- a/lib/singledispatch.py
+++ b/lib/singledispatch.py
@ -1,219 +0,0 @@
 #!/usr/bin/env python
 # -*- coding: utf-8 -*-
 from __future__ import absolute_import
 from __future__ import division
 from __future__ import print_function
 from __future__ import unicode_literals
 __all__ = ['singledispatch']
 from functools import update_wrapper
 from weakref import WeakKeyDictionary
 from singledispatch_helpers import MappingProxyType, get_cache_token
 ################################################################################
 ### singledispatch() - single-dispatch generic function decorator
 ################################################################################
 def _c3_merge(sequences):
    """Merges MROs in *sequences* to a single MRO using the C3 algorithm.
    Adapted from http://www.python.org/download/releases/2.3/mro/.
    """
    result = []
    while True:
        sequences = [s for s in sequences if s]   # purge empty sequences
        if not sequences:
            return result
        for s1 in sequences:   # find merge candidates among seq heads
            candidate = s1[0]
            for s2 in sequences:
                if candidate in s2[1:]:
                    candidate = None
                    break      # reject the current head, it appears later
            else:
                break
        if not candidate:
            raise RuntimeError("Inconsistent hierarchy")
        result.append(candidate)
        # remove the chosen candidate
        for seq in sequences:
            if seq[0] == candidate:
                del seq[0]
 def _c3_mro(cls, abcs=None):
    """Computes the method resolution order using extended C3 linearization.
    If no *abcs* are given, the algorithm works exactly like the built-in C3
    linearization used for method resolution.
    If given, *abcs* is a list of abstract base classes that should be inserted
    into the resulting MRO. Unrelated ABCs are ignored and don't end up in the
    result. The algorithm inserts ABCs where their functionality is introduced,
    i.e. issubclass(cls, abc) returns True for the class itself but returns
    False for all its direct base classes. Implicit ABCs for a given class
    (either registered or inferred from the presence of a special method like
    __len__) are inserted directly after the last ABC explicitly listed in the
    MRO of said class. If two implicit ABCs end up next to each other in the
    resulting MRO, their ordering depends on the order of types in *abcs*.
    """
    for i, base in enumerate(reversed(cls.__bases__)):
        if hasattr(base, '__abstractmethods__'):
            boundary = len(cls.__bases__) - i
            break   # Bases up to the last explicit ABC are considered first.
    else:
        boundary = 0
    abcs = list(abcs) if abcs else []
    explicit_bases = list(cls.__bases__[:boundary])
    abstract_bases = []
    other_bases = list(cls.__bases__[boundary:])
    for base in abcs:
        if issubclass(cls, base) and not any(
                issubclass(b, base) for b in cls.__bases__
            ):
            # If *cls* is the class that introduces behaviour described by
            # an ABC *base*, insert said ABC to its MRO.
            abstract_bases.append(base)
    for base in abstract_bases:
        abcs.remove(base)
    explicit_c3_mros = [_c3_mro(base, abcs=abcs) for base in explicit_bases]
    abstract_c3_mros = [_c3_mro(base, abcs=abcs) for base in abstract_bases]
    other_c3_mros = [_c3_mro(base, abcs=abcs) for base in other_bases]
    return _c3_merge(
        [[cls]] +
        explicit_c3_mros + abstract_c3_mros + other_c3_mros +
        [explicit_bases] + [abstract_bases] + [other_bases]
    )
 def _compose_mro(cls, types):
    """Calculates the method resolution order for a given class *cls*.
    Includes relevant abstract base classes (with their respective bases) from
    the *types* iterable. Uses a modified C3 linearization algorithm.
    """
    bases = set(cls.__mro__)
    # Remove entries which are already present in the __mro__ or unrelated.
    def is_related(typ):
        return (typ not in bases and hasattr(typ, '__mro__')
                                 and issubclass(cls, typ))
    types = [n for n in types if is_related(n)]
    # Remove entries which are strict bases of other entries (they will end up
    # in the MRO anyway.
    def is_strict_base(typ):
        for other in types:
            if typ != other and typ in other.__mro__:
                return True
        return False
    types = [n for n in types if not is_strict_base(n)]
    # Subclasses of the ABCs in *types* which are also implemented by
    # *cls* can be used to stabilize ABC ordering.
    type_set = set(types)
    mro = []
    for typ in types:
        found = []
        for sub in typ.__subclasses__():
            if sub not in bases and issubclass(cls, sub):
                found.append([s for s in sub.__mro__ if s in type_set])
        if not found:
            mro.append(typ)
            continue
        # Favor subclasses with the biggest number of useful bases
        found.sort(key=len, reverse=True)
        for sub in found:
            for subcls in sub:
                if subcls not in mro:
                    mro.append(subcls)
    return _c3_mro(cls, abcs=mro)
 def _find_impl(cls, registry):
    """Returns the best matching implementation from *registry* for type *cls*.
    Where there is no registered implementation for a specific type, its method
    resolution order is used to find a more generic implementation.
    Note: if *registry* does not contain an implementation for the base
    *object* type, this function may return None.
    """
    mro = _compose_mro(cls, registry.keys())
    match = None
    for t in mro:
        if match is not None:
            # If *match* is an implicit ABC but there is another unrelated,
            # equally matching implicit ABC, refuse the temptation to guess.
            if (t in registry and t not in cls.__mro__
                              and match not in cls.__mro__
                              and not issubclass(match, t)):
                raise RuntimeError("Ambiguous dispatch: {0} or {1}".format(
                    match, t))
            break
        if t in registry:
            match = t
    return registry.get(match)
 def singledispatch(func):
    """Single-dispatch generic function decorator.
    Transforms a function into a generic function, which can have different
    behaviours depending upon the type of its first argument. The decorated
    function acts as the default implementation, and additional
    implementations can be registered using the register() attribute of the
    generic function.
    """
    registry = {}
    dispatch_cache = WeakKeyDictionary()
    def ns(): pass
    ns.cache_token = None
    def dispatch(cls):
        """generic_func.dispatch(cls) -> <function implementation>
        Runs the dispatch algorithm to return the best available implementation
        for the given *cls* registered on *generic_func*.
        """
        if ns.cache_token is not None:
            current_token = get_cache_token()
            if ns.cache_token != current_token:
                dispatch_cache.clear()
                ns.cache_token = current_token
        try:
            impl = dispatch_cache[cls]
        except KeyError:
            try:
                impl = registry[cls]
            except KeyError:
                impl = _find_impl(cls, registry)
            dispatch_cache[cls] = impl
        return impl
    def register(cls, func=None):
        """generic_func.register(cls, func) -> func
        Registers a new implementation for the given *cls* on a *generic_func*.
        """
        if func is None:
            return lambda f: register(cls, f)
        registry[cls] = func
        if ns.cache_token is None and hasattr(cls, '__abstractmethods__'):
            ns.cache_token = get_cache_token()
        dispatch_cache.clear()
        return func
    def wrapper(*args, **kw):
        return dispatch(args[0].__class__)(*args, **kw)
    registry[object] = func
    wrapper.register = register
    wrapper.dispatch = dispatch
    wrapper.registry = MappingProxyType(registry)
    wrapper._clear_cache = dispatch_cache.clear
    update_wrapper(wrapper, func)
    return wrapper
--- a/lib/singledispatch_helpers.py
+++ b/lib/singledispatch_helpers.py
@ -1,170 +0,0 @@
 #!/usr/bin/env python
 # -*- coding: utf-8 -*-
 from __future__ import absolute_import
 from __future__ import division
 from __future__ import print_function
 from __future__ import unicode_literals
 from abc import ABCMeta
 from collections import MutableMapping
 import sys
 try:
    from collections import UserDict
 except ImportError:
    from UserDict import UserDict
 try:
    from collections import OrderedDict
 except ImportError:
    from ordereddict import OrderedDict
 try:
    from thread import get_ident
 except ImportError:
    try:
        from _thread import get_ident
    except ImportError:
        from _dummy_thread import get_ident
 def recursive_repr(fillvalue='...'):
    'Decorator to make a repr function return fillvalue for a recursive call'
    def decorating_function(user_function):
        repr_running = set()
        def wrapper(self):
            key = id(self), get_ident()
            if key in repr_running:
                return fillvalue
            repr_running.add(key)
            try:
                result = user_function(self)
            finally:
                repr_running.discard(key)
            return result
        # Can't use functools.wraps() here because of bootstrap issues
        wrapper.__module__ = getattr(user_function, '__module__')
        wrapper.__doc__ = getattr(user_function, '__doc__')
        wrapper.__name__ = getattr(user_function, '__name__')
        wrapper.__annotations__ = getattr(user_function, '__annotations__', {})
        return wrapper
    return decorating_function
 class ChainMap(MutableMapping):
    ''' A ChainMap groups multiple dicts (or other mappings) together
    to create a single, updateable view.
    The underlying mappings are stored in a list.  That list is public and can
    accessed or updated using the *maps* attribute.  There is no other state.
    Lookups search the underlying mappings successively until a key is found.
    In contrast, writes, updates, and deletions only operate on the first
    mapping.
    '''
    def __init__(self, *maps):
        '''Initialize a ChainMap by setting *maps* to the given mappings.
        If no mappings are provided, a single empty dictionary is used.
        '''
        self.maps = list(maps) or [{}]          # always at least one map
    def __missing__(self, key):
        raise KeyError(key)
    def __getitem__(self, key):
        for mapping in self.maps:
            try:
                return mapping[key]             # can't use 'key in mapping' with defaultdict
            except KeyError:
                pass
        return self.__missing__(key)            # support subclasses that define __missing__
    def get(self, key, default=None):
        return self[key] if key in self else default
    def __len__(self):
        return len(set().union(*self.maps))     # reuses stored hash values if possible
    def __iter__(self):
        return iter(set().union(*self.maps))
    def __contains__(self, key):
        return any(key in m for m in self.maps)
    @recursive_repr()
    def __repr__(self):
        return '{0.__class__.__name__}({1})'.format(
            self, ', '.join(map(repr, self.maps)))
    @classmethod
    def fromkeys(cls, iterable, *args):
        'Create a ChainMap with a single dict created from the iterable.'
        return cls(dict.fromkeys(iterable, *args))
    def copy(self):
        'New ChainMap or subclass with a new copy of maps[0] and refs to maps[1:]'
        return self.__class__(self.maps[0].copy(), *self.maps[1:])
    __copy__ = copy
    def new_child(self):                        # like Django's Context.push()
        'New ChainMap with a new dict followed by all previous maps.'
        return self.__class__({}, *self.maps)
    @property
    def parents(self):                          # like Django's Context.pop()
        'New ChainMap from maps[1:].'
        return self.__class__(*self.maps[1:])
    def __setitem__(self, key, value):
        self.maps[0][key] = value
    def __delitem__(self, key):
        try:
            del self.maps[0][key]
        except KeyError:
            raise KeyError('Key not found in the first mapping: {!r}'.format(key))
    def popitem(self):
        'Remove and return an item pair from maps[0]. Raise KeyError is maps[0] is empty.'
        try:
            return self.maps[0].popitem()
        except KeyError:
            raise KeyError('No keys found in the first mapping.')
    def pop(self, key, *args):
        'Remove *key* from maps[0] and return its value. Raise KeyError if *key* not in maps[0].'
        try:
            return self.maps[0].pop(key, *args)
        except KeyError:
            raise KeyError('Key not found in the first mapping: {!r}'.format(key))
    def clear(self):
        'Clear maps[0], leaving maps[1:] intact.'
        self.maps[0].clear()
 class MappingProxyType(UserDict):
    def __init__(self, data):
        UserDict.__init__(self)
        self.data = data
 def get_cache_token():
    return ABCMeta._abc_invalidation_counter
 class Support(object):
    def dummy(self):
        pass
    def cpython_only(self, func):
        if 'PyPy' in sys.version:
            return self.dummy
        return func