# Copyright (c) 2013, Mahmoud Hashemi # # Redistribution and use in source and binary forms, with or without # modification, are permitted provided that the following conditions are # met: # # * Redistributions of source code must retain the above copyright # notice, this list of conditions and the following disclaimer. # # * Redistributions in binary form must reproduce the above # copyright notice, this list of conditions and the following # disclaimer in the documentation and/or other materials provided # with the distribution. # # * The names of the contributors may not be used to endorse or # promote products derived from this software without specific # prior written permission. # # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS # "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT # LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR # A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT # OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, # SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT # LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, # DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY # THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT # (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE # OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. """Python has a very powerful mapping type at its core: the :class:`dict` type. While versatile and featureful, the :class:`dict` prioritizes simplicity and performance. As a result, it does not retain the order of item insertion [1]_, nor does it store multiple values per key. It is a fast, unordered 1:1 mapping. The :class:`OrderedMultiDict` contrasts to the built-in :class:`dict`, as a relatively maximalist, ordered 1:n subtype of :class:`dict`. Virtually every feature of :class:`dict` has been retooled to be intuitive in the face of this added complexity. Additional methods have been added, such as :class:`collections.Counter`-like functionality. A prime advantage of the :class:`OrderedMultiDict` (OMD) is its non-destructive nature. Data can be added to an :class:`OMD` without being rearranged or overwritten. The property can allow the developer to work more freely with the data, as well as make more assumptions about where input data will end up in the output, all without any extra work. One great example of this is the :meth:`OMD.inverted()` method, which returns a new OMD with the values as keys and the keys as values. All the data and the respective order is still represented in the inverted form, all from an operation which would be outright wrong and reckless with a built-in :class:`dict` or :class:`collections.OrderedDict`. The OMD has been performance tuned to be suitable for a wide range of usages, including as a basic unordered MultiDict. Special thanks to `Mark Williams`_ for all his help. .. [1] As of 2015, `basic dicts on PyPy are ordered `_, and as of December 2017, `basic dicts in CPython 3 are now ordered `_, as well. .. _Mark Williams: https://github.com/markrwilliams """ from collections.abc import KeysView, ValuesView, ItemsView from itertools import zip_longest try: from .typeutils import make_sentinel _MISSING = make_sentinel(var_name='_MISSING') except ImportError: _MISSING = object() PREV, NEXT, KEY, VALUE, SPREV, SNEXT = range(6) __all__ = ['MultiDict', 'OMD', 'OrderedMultiDict', 'OneToOne', 'ManyToMany', 'subdict', 'FrozenDict'] class OrderedMultiDict(dict): """A MultiDict is a dictionary that can have multiple values per key and the OrderedMultiDict (OMD) is a MultiDict that retains original insertion order. Common use cases include: * handling query strings parsed from URLs * inverting a dictionary to create a reverse index (values to keys) * stacking data from multiple dictionaries in a non-destructive way The OrderedMultiDict constructor is identical to the built-in :class:`dict`, and overall the API constitutes an intuitive superset of the built-in type: >>> omd = OrderedMultiDict() >>> omd['a'] = 1 >>> omd['b'] = 2 >>> omd.add('a', 3) >>> omd.get('a') 3 >>> omd.getlist('a') [1, 3] Some non-:class:`dict`-like behaviors also make an appearance, such as support for :func:`reversed`: >>> list(reversed(omd)) ['b', 'a'] Note that unlike some other MultiDicts, this OMD gives precedence to the most recent value added. ``omd['a']`` refers to ``3``, not ``1``. >>> omd OrderedMultiDict([('a', 1), ('b', 2), ('a', 3)]) >>> omd.poplast('a') 3 >>> omd OrderedMultiDict([('a', 1), ('b', 2)]) >>> omd.pop('a') 1 >>> omd OrderedMultiDict([('b', 2)]) If you want a safe-to-modify or flat dictionary, use :meth:`OrderedMultiDict.todict()`. >>> from pprint import pprint as pp # preserve printed ordering >>> omd = OrderedMultiDict([('a', 1), ('b', 2), ('a', 3)]) >>> pp(omd.todict()) {'a': 3, 'b': 2} >>> pp(omd.todict(multi=True)) {'a': [1, 3], 'b': [2]} With ``multi=False``, items appear with the keys in to original insertion order, alongside the most-recently inserted value for that key. >>> OrderedMultiDict([('a', 1), ('b', 2), ('a', 3)]).items(multi=False) [('a', 3), ('b', 2)] .. warning:: ``dict(omd)`` changed behavior `in Python 3.7 `_ due to changes made to support the transition from :class:`collections.OrderedDict` to the built-in dictionary being ordered. Before 3.7, the result would be a new dictionary, with values that were lists, similar to ``omd.todict(multi=True)`` (but only shallow-copy; the lists were direct references to OMD internal structures). From 3.7 onward, the values became singular, like ``omd.todict(multi=False)``. For reliable cross-version behavior, just use :meth:`~OrderedMultiDict.todict()`. """ def __new__(cls, *a, **kw): ret = super().__new__(cls) ret._clear_ll() return ret def __init__(self, *args, **kwargs): if len(args) > 1: raise TypeError('%s expected at most 1 argument, got %s' % (self.__class__.__name__, len(args))) super().__init__() if args: self.update_extend(args[0]) if kwargs: self.update(kwargs) def __getstate__(self): return list(self.iteritems(multi=True)) def __setstate__(self, state): self.clear() self.update_extend(state) def _clear_ll(self): try: _map = self._map except AttributeError: _map = self._map = {} self.root = [] _map.clear() self.root[:] = [self.root, self.root, None] def _insert(self, k, v): root = self.root cells = self._map.setdefault(k, []) last = root[PREV] cell = [last, root, k, v] last[NEXT] = root[PREV] = cell cells.append(cell) def add(self, k, v): """Add a single value *v* under a key *k*. Existing values under *k* are preserved. """ values = super().setdefault(k, []) self._insert(k, v) values.append(v) def addlist(self, k, v): """Add an iterable of values underneath a specific key, preserving any values already under that key. >>> omd = OrderedMultiDict([('a', -1)]) >>> omd.addlist('a', range(3)) >>> omd OrderedMultiDict([('a', -1), ('a', 0), ('a', 1), ('a', 2)]) Called ``addlist`` for consistency with :meth:`getlist`, but tuples and other sequences and iterables work. """ if not v: return self_insert = self._insert values = super().setdefault(k, []) for subv in v: self_insert(k, subv) values.extend(v) def get(self, k, default=None): """Return the value for key *k* if present in the dictionary, else *default*. If *default* is not given, ``None`` is returned. This method never raises a :exc:`KeyError`. To get all values under a key, use :meth:`OrderedMultiDict.getlist`. """ return super().get(k, [default])[-1] def getlist(self, k, default=_MISSING): """Get all values for key *k* as a list, if *k* is in the dictionary, else *default*. The list returned is a copy and can be safely mutated. If *default* is not given, an empty :class:`list` is returned. """ try: return super().__getitem__(k)[:] except KeyError: if default is _MISSING: return [] return default def clear(self): "Empty the dictionary." super().clear() self._clear_ll() def setdefault(self, k, default=_MISSING): """If key *k* is in the dictionary, return its value. If not, insert *k* with a value of *default* and return *default*. *default* defaults to ``None``. See :meth:`dict.setdefault` for more information. """ if not super().__contains__(k): self[k] = None if default is _MISSING else default return self[k] def copy(self): "Return a shallow copy of the dictionary." return self.__class__(self.iteritems(multi=True)) @classmethod def fromkeys(cls, keys, default=None): """Create a dictionary from a list of keys, with all the values set to *default*, or ``None`` if *default* is not set. """ return cls([(k, default) for k in keys]) def update(self, E, **F): """Add items from a dictionary or iterable (and/or keyword arguments), overwriting values under an existing key. See :meth:`dict.update` for more details. """ # E and F are throwback names to the dict() __doc__ if E is self: return self_add = self.add if isinstance(E, OrderedMultiDict): for k in E: if k in self: del self[k] for k, v in E.iteritems(multi=True): self_add(k, v) elif callable(getattr(E, 'keys', None)): for k in E.keys(): self[k] = E[k] else: seen = set() seen_add = seen.add for k, v in E: if k not in seen and k in self: del self[k] seen_add(k) self_add(k, v) for k in F: self[k] = F[k] return def update_extend(self, E, **F): """Add items from a dictionary, iterable, and/or keyword arguments without overwriting existing items present in the dictionary. Like :meth:`update`, but adds to existing keys instead of overwriting them. """ if E is self: iterator = iter(E.items()) elif isinstance(E, OrderedMultiDict): iterator = E.iteritems(multi=True) elif hasattr(E, 'keys'): iterator = ((k, E[k]) for k in E.keys()) else: iterator = E self_add = self.add for k, v in iterator: self_add(k, v) def __setitem__(self, k, v): if super().__contains__(k): self._remove_all(k) self._insert(k, v) super().__setitem__(k, [v]) def __getitem__(self, k): return super().__getitem__(k)[-1] def __delitem__(self, k): super().__delitem__(k) self._remove_all(k) def __eq__(self, other): if self is other: return True try: if len(other) != len(self): return False except TypeError: return False if isinstance(other, OrderedMultiDict): selfi = self.iteritems(multi=True) otheri = other.iteritems(multi=True) zipped_items = zip_longest(selfi, otheri, fillvalue=(None, None)) for (selfk, selfv), (otherk, otherv) in zipped_items: if selfk != otherk or selfv != otherv: return False if not(next(selfi, _MISSING) is _MISSING and next(otheri, _MISSING) is _MISSING): # leftovers (TODO: watch for StopIteration?) return False return True elif hasattr(other, 'keys'): for selfk in self: try: other[selfk] == self[selfk] except KeyError: return False return True return False def __ne__(self, other): return not (self == other) def __ior__(self, other): self.update(other) return self def pop(self, k, default=_MISSING): """Remove all values under key *k*, returning the most-recently inserted value. Raises :exc:`KeyError` if the key is not present and no *default* is provided. """ try: return self.popall(k)[-1] except KeyError: if default is _MISSING: raise KeyError(k) return default def popall(self, k, default=_MISSING): """Remove all values under key *k*, returning them in the form of a list. Raises :exc:`KeyError` if the key is not present and no *default* is provided. """ super_self = super() if super_self.__contains__(k): self._remove_all(k) if default is _MISSING: return super_self.pop(k) return super_self.pop(k, default) def poplast(self, k=_MISSING, default=_MISSING): """Remove and return the most-recently inserted value under the key *k*, or the most-recently inserted key if *k* is not provided. If no values remain under *k*, it will be removed from the OMD. Raises :exc:`KeyError` if *k* is not present in the dictionary, or the dictionary is empty. """ if k is _MISSING: if self: k = self.root[PREV][KEY] else: if default is _MISSING: raise KeyError('empty %r' % type(self)) return default try: self._remove(k) except KeyError: if default is _MISSING: raise KeyError(k) return default values = super().__getitem__(k) v = values.pop() if not values: super().__delitem__(k) return v def _remove(self, k): values = self._map[k] cell = values.pop() cell[PREV][NEXT], cell[NEXT][PREV] = cell[NEXT], cell[PREV] if not values: del self._map[k] def _remove_all(self, k): values = self._map[k] while values: cell = values.pop() cell[PREV][NEXT], cell[NEXT][PREV] = cell[NEXT], cell[PREV] del self._map[k] def iteritems(self, multi=False): """Iterate over the OMD's items in insertion order. By default, yields only the most-recently inserted value for each key. Set *multi* to ``True`` to get all inserted items. """ root = self.root curr = root[NEXT] if multi: while curr is not root: yield curr[KEY], curr[VALUE] curr = curr[NEXT] else: for key in self.iterkeys(): yield key, self[key] def iterkeys(self, multi=False): """Iterate over the OMD's keys in insertion order. By default, yields each key once, according to the most recent insertion. Set *multi* to ``True`` to get all keys, including duplicates, in insertion order. """ root = self.root curr = root[NEXT] if multi: while curr is not root: yield curr[KEY] curr = curr[NEXT] else: yielded = set() yielded_add = yielded.add while curr is not root: k = curr[KEY] if k not in yielded: yielded_add(k) yield k curr = curr[NEXT] def itervalues(self, multi=False): """Iterate over the OMD's values in insertion order. By default, yields the most-recently inserted value per unique key. Set *multi* to ``True`` to get all values according to insertion order. """ for k, v in self.iteritems(multi=multi): yield v def todict(self, multi=False): """Gets a basic :class:`dict` of the items in this dictionary. Keys are the same as the OMD, values are the most recently inserted values for each key. Setting the *multi* arg to ``True`` is yields the same result as calling :class:`dict` on the OMD, except that all the value lists are copies that can be safely mutated. """ if multi: return {k: self.getlist(k) for k in self} return {k: self[k] for k in self} def sorted(self, key=None, reverse=False): """Similar to the built-in :func:`sorted`, except this method returns a new :class:`OrderedMultiDict` sorted by the provided key function, optionally reversed. Args: key (callable): A callable to determine the sort key of each element. The callable should expect an **item** (key-value pair tuple). reverse (bool): Set to ``True`` to reverse the ordering. >>> omd = OrderedMultiDict(zip(range(3), range(3))) >>> omd.sorted(reverse=True) OrderedMultiDict([(2, 2), (1, 1), (0, 0)]) Note that the key function receives an **item** (key-value tuple), so the recommended signature looks like: >>> omd = OrderedMultiDict(zip('hello', 'world')) >>> omd.sorted(key=lambda i: i[1]) # i[0] is the key, i[1] is the val OrderedMultiDict([('o', 'd'), ('l', 'l'), ('e', 'o'), ('l', 'r'), ('h', 'w')]) """ cls = self.__class__ return cls(sorted(self.iteritems(multi=True), key=key, reverse=reverse)) def sortedvalues(self, key=None, reverse=False): """Returns a copy of the :class:`OrderedMultiDict` with the same keys in the same order as the original OMD, but the values within each keyspace have been sorted according to *key* and *reverse*. Args: key (callable): A single-argument callable to determine the sort key of each element. The callable should expect an **item** (key-value pair tuple). reverse (bool): Set to ``True`` to reverse the ordering. >>> omd = OrderedMultiDict() >>> omd.addlist('even', [6, 2]) >>> omd.addlist('odd', [1, 5]) >>> omd.add('even', 4) >>> omd.add('odd', 3) >>> somd = omd.sortedvalues() >>> somd.getlist('even') [2, 4, 6] >>> somd.keys(multi=True) == omd.keys(multi=True) True >>> omd == somd False >>> somd OrderedMultiDict([('even', 2), ('even', 4), ('odd', 1), ('odd', 3), ('even', 6), ('odd', 5)]) As demonstrated above, contents and key order are retained. Only value order changes. """ try: superself_iteritems = super().iteritems() except AttributeError: superself_iteritems = super().items() # (not reverse) because they pop off in reverse order for reinsertion sorted_val_map = {k: sorted(v, key=key, reverse=(not reverse)) for k, v in superself_iteritems} ret = self.__class__() for k in self.iterkeys(multi=True): ret.add(k, sorted_val_map[k].pop()) return ret def inverted(self): """Returns a new :class:`OrderedMultiDict` with values and keys swapped, like creating dictionary transposition or reverse index. Insertion order is retained and all keys and values are represented in the output. >>> omd = OMD([(0, 2), (1, 2)]) >>> omd.inverted().getlist(2) [0, 1] Inverting twice yields a copy of the original: >>> omd.inverted().inverted() OrderedMultiDict([(0, 2), (1, 2)]) """ return self.__class__((v, k) for k, v in self.iteritems(multi=True)) def counts(self): """Returns a mapping from key to number of values inserted under that key. Like :py:class:`collections.Counter`, but returns a new :class:`OrderedMultiDict`. """ # Returns an OMD because Counter/OrderedDict may not be # available, and neither Counter nor dict maintain order. super_getitem = super().__getitem__ return self.__class__((k, len(super_getitem(k))) for k in self) def keys(self, multi=False): """Returns a list containing the output of :meth:`iterkeys`. See that method's docs for more details. """ return list(self.iterkeys(multi=multi)) def values(self, multi=False): """Returns a list containing the output of :meth:`itervalues`. See that method's docs for more details. """ return list(self.itervalues(multi=multi)) def items(self, multi=False): """Returns a list containing the output of :meth:`iteritems`. See that method's docs for more details. """ return list(self.iteritems(multi=multi)) def __iter__(self): return self.iterkeys() def __reversed__(self): root = self.root curr = root[PREV] lengths = {} lengths_sd = lengths.setdefault get_values = super().__getitem__ while curr is not root: k = curr[KEY] vals = get_values(k) if lengths_sd(k, 1) == len(vals): yield k lengths[k] += 1 curr = curr[PREV] def __repr__(self): cn = self.__class__.__name__ kvs = ', '.join([repr((k, v)) for k, v in self.iteritems(multi=True)]) return f'{cn}([{kvs}])' def viewkeys(self): "OMD.viewkeys() -> a set-like object providing a view on OMD's keys" return KeysView(self) def viewvalues(self): "OMD.viewvalues() -> an object providing a view on OMD's values" return ValuesView(self) def viewitems(self): "OMD.viewitems() -> a set-like object providing a view on OMD's items" return ItemsView(self) # A couple of convenient aliases OMD = OrderedMultiDict MultiDict = OrderedMultiDict class FastIterOrderedMultiDict(OrderedMultiDict): """An OrderedMultiDict backed by a skip list. Iteration over keys is faster and uses constant memory but adding duplicate key-value pairs is slower. Brainchild of Mark Williams. """ def _clear_ll(self): # TODO: always reset objects? (i.e., no else block below) try: _map = self._map except AttributeError: _map = self._map = {} self.root = [] _map.clear() self.root[:] = [self.root, self.root, None, None, self.root, self.root] def _insert(self, k, v): root = self.root empty = [] cells = self._map.setdefault(k, empty) last = root[PREV] if cells is empty: cell = [last, root, k, v, last, root] # was the last one skipped? if last[SPREV][SNEXT] is root: last[SPREV][SNEXT] = cell last[NEXT] = last[SNEXT] = root[PREV] = root[SPREV] = cell cells.append(cell) else: # if the previous was skipped, go back to the cell that # skipped it sprev = last[SPREV] if (last[SPREV][SNEXT] is not last) else last cell = [last, root, k, v, sprev, root] # skip me last[SNEXT] = root last[NEXT] = root[PREV] = root[SPREV] = cell cells.append(cell) def _remove(self, k): cells = self._map[k] cell = cells.pop() if not cells: del self._map[k] cell[PREV][SNEXT] = cell[SNEXT] if cell[PREV][SPREV][SNEXT] is cell: cell[PREV][SPREV][SNEXT] = cell[NEXT] elif cell[SNEXT] is cell[NEXT]: cell[SPREV][SNEXT], cell[SNEXT][SPREV] = cell[SNEXT], cell[SPREV] cell[PREV][NEXT], cell[NEXT][PREV] = cell[NEXT], cell[PREV] def _remove_all(self, k): cells = self._map.pop(k) while cells: cell = cells.pop() if cell[PREV][SPREV][SNEXT] is cell: cell[PREV][SPREV][SNEXT] = cell[NEXT] elif cell[SNEXT] is cell[NEXT]: cell[SPREV][SNEXT], cell[SNEXT][SPREV] = cell[SNEXT], cell[SPREV] cell[PREV][NEXT], cell[NEXT][PREV] = cell[NEXT], cell[PREV] cell[PREV][SNEXT] = cell[SNEXT] def iteritems(self, multi=False): next_link = NEXT if multi else SNEXT root = self.root curr = root[next_link] while curr is not root: yield curr[KEY], curr[VALUE] curr = curr[next_link] def iterkeys(self, multi=False): next_link = NEXT if multi else SNEXT root = self.root curr = root[next_link] while curr is not root: yield curr[KEY] curr = curr[next_link] def __reversed__(self): root = self.root curr = root[PREV] while curr is not root: if curr[SPREV][SNEXT] is not curr: curr = curr[SPREV] if curr is root: break yield curr[KEY] curr = curr[PREV] _OTO_INV_MARKER = object() _OTO_UNIQUE_MARKER = object() class OneToOne(dict): """Implements a one-to-one mapping dictionary. In addition to inheriting from and behaving exactly like the builtin :class:`dict`, all values are automatically added as keys on a reverse mapping, available as the `inv` attribute. This arrangement keeps key and value namespaces distinct. Basic operations are intuitive: >>> oto = OneToOne({'a': 1, 'b': 2}) >>> print(oto['a']) 1 >>> print(oto.inv[1]) a >>> len(oto) 2 Overwrites happens in both directions: >>> oto.inv[1] = 'c' >>> print(oto.get('a')) None >>> len(oto) 2 For a very similar project, with even more one-to-one functionality, check out `bidict `_. """ __slots__ = ('inv',) def __init__(self, *a, **kw): raise_on_dupe = False if a: if a[0] is _OTO_INV_MARKER: self.inv = a[1] dict.__init__(self, [(v, k) for k, v in self.inv.items()]) return elif a[0] is _OTO_UNIQUE_MARKER: a, raise_on_dupe = a[1:], True dict.__init__(self, *a, **kw) self.inv = self.__class__(_OTO_INV_MARKER, self) if len(self) == len(self.inv): # if lengths match, that means everything's unique return if not raise_on_dupe: dict.clear(self) dict.update(self, [(v, k) for k, v in self.inv.items()]) return # generate an error message if the values aren't 1:1 val_multidict = {} for k, v in self.items(): val_multidict.setdefault(v, []).append(k) dupes = {v: k_list for v, k_list in val_multidict.items() if len(k_list) > 1} raise ValueError('expected unique values, got multiple keys for' ' the following values: %r' % dupes) @classmethod def unique(cls, *a, **kw): """This alternate constructor for OneToOne will raise an exception when input values overlap. For instance: >>> OneToOne.unique({'a': 1, 'b': 1}) Traceback (most recent call last): ... ValueError: expected unique values, got multiple keys for the following values: ... This even works across inputs: >>> a_dict = {'a': 2} >>> OneToOne.unique(a_dict, b=2) Traceback (most recent call last): ... ValueError: expected unique values, got multiple keys for the following values: ... """ return cls(_OTO_UNIQUE_MARKER, *a, **kw) def __setitem__(self, key, val): hash(val) # ensure val is a valid key if key in self: dict.__delitem__(self.inv, self[key]) if val in self.inv: del self.inv[val] dict.__setitem__(self, key, val) dict.__setitem__(self.inv, val, key) def __delitem__(self, key): dict.__delitem__(self.inv, self[key]) dict.__delitem__(self, key) def clear(self): dict.clear(self) dict.clear(self.inv) def copy(self): return self.__class__(self) def pop(self, key, default=_MISSING): if key in self: dict.__delitem__(self.inv, self[key]) return dict.pop(self, key) if default is not _MISSING: return default raise KeyError() def popitem(self): key, val = dict.popitem(self) dict.__delitem__(self.inv, val) return key, val def setdefault(self, key, default=None): if key not in self: self[key] = default return self[key] def update(self, dict_or_iterable, **kw): keys_vals = [] if isinstance(dict_or_iterable, dict): for val in dict_or_iterable.values(): hash(val) keys_vals = list(dict_or_iterable.items()) else: for key, val in dict_or_iterable: hash(key) hash(val) keys_vals = list(dict_or_iterable) for val in kw.values(): hash(val) keys_vals.extend(kw.items()) for key, val in keys_vals: self[key] = val def __repr__(self): cn = self.__class__.__name__ dict_repr = dict.__repr__(self) return f"{cn}({dict_repr})" # marker for the secret handshake used internally to set up the invert ManyToMany _PAIRING = object() class ManyToMany: """ a dict-like entity that represents a many-to-many relationship between two groups of objects behaves like a dict-of-tuples; also has .inv which is kept up to date which is a dict-of-tuples in the other direction also, can be used as a directed graph among hashable python objects """ def __init__(self, items=None): self.data = {} if type(items) is tuple and items and items[0] is _PAIRING: self.inv = items[1] else: self.inv = self.__class__((_PAIRING, self)) if items: self.update(items) return def get(self, key, default=frozenset()): try: return self[key] except KeyError: return default def __getitem__(self, key): return frozenset(self.data[key]) def __setitem__(self, key, vals): vals = set(vals) if key in self: to_remove = self.data[key] - vals vals -= self.data[key] for val in to_remove: self.remove(key, val) for val in vals: self.add(key, val) def __delitem__(self, key): for val in self.data.pop(key): self.inv.data[val].remove(key) if not self.inv.data[val]: del self.inv.data[val] def update(self, iterable): """given an iterable of (key, val), add them all""" if type(iterable) is type(self): other = iterable for k in other.data: if k not in self.data: self.data[k] = other.data[k] else: self.data[k].update(other.data[k]) for k in other.inv.data: if k not in self.inv.data: self.inv.data[k] = other.inv.data[k] else: self.inv.data[k].update(other.inv.data[k]) elif callable(getattr(iterable, 'keys', None)): for k in iterable.keys(): self.add(k, iterable[k]) else: for key, val in iterable: self.add(key, val) return def add(self, key, val): if key not in self.data: self.data[key] = set() self.data[key].add(val) if val not in self.inv.data: self.inv.data[val] = set() self.inv.data[val].add(key) def remove(self, key, val): self.data[key].remove(val) if not self.data[key]: del self.data[key] self.inv.data[val].remove(key) if not self.inv.data[val]: del self.inv.data[val] def replace(self, key, newkey): """ replace instances of key by newkey """ if key not in self.data: return self.data[newkey] = fwdset = self.data.pop(key) for val in fwdset: revset = self.inv.data[val] revset.remove(key) revset.add(newkey) def iteritems(self): for key in self.data: for val in self.data[key]: yield key, val def keys(self): return self.data.keys() def __contains__(self, key): return key in self.data def __iter__(self): return self.data.__iter__() def __len__(self): return self.data.__len__() def __eq__(self, other): return type(self) == type(other) and self.data == other.data def __repr__(self): cn = self.__class__.__name__ return f'{cn}({list(self.iteritems())!r})' def subdict(d, keep=None, drop=None): """Compute the "subdictionary" of a dict, *d*. A subdict is to a dict what a subset is a to set. If *A* is a subdict of *B*, that means that all keys of *A* are present in *B*. Returns a new dict with any keys in *drop* removed, and any keys in *keep* still present, provided they were in the original dict. *keep* defaults to all keys, *drop* defaults to empty, so without one of these arguments, calling this function is equivalent to calling ``dict()``. >>> from pprint import pprint as pp >>> pp(subdict({'a': 1, 'b': 2})) {'a': 1, 'b': 2} >>> subdict({'a': 1, 'b': 2, 'c': 3}, drop=['b', 'c']) {'a': 1} >>> pp(subdict({'a': 1, 'b': 2, 'c': 3}, keep=['a', 'c'])) {'a': 1, 'c': 3} """ if keep is None: keep = d.keys() if drop is None: drop = [] keys = set(keep) - set(drop) return type(d)([(k, v) for k, v in d.items() if k in keys]) class FrozenHashError(TypeError): pass class FrozenDict(dict): """An immutable dict subtype that is hashable and can itself be used as a :class:`dict` key or :class:`set` entry. What :class:`frozenset` is to :class:`set`, FrozenDict is to :class:`dict`. There was once an attempt to introduce such a type to the standard library, but it was rejected: `PEP 416 `_. Because FrozenDict is a :class:`dict` subtype, it automatically works everywhere a dict would, including JSON serialization. """ __slots__ = ('_hash',) def updated(self, *a, **kw): """Make a copy and add items from a dictionary or iterable (and/or keyword arguments), overwriting values under an existing key. See :meth:`dict.update` for more details. """ data = dict(self) data.update(*a, **kw) return type(self)(data) @classmethod def fromkeys(cls, keys, value=None): # one of the lesser known and used/useful dict methods return cls(dict.fromkeys(keys, value)) def __repr__(self): cn = self.__class__.__name__ return f'{cn}({dict.__repr__(self)})' def __reduce_ex__(self, protocol): return type(self), (dict(self),) def __hash__(self): try: ret = self._hash except AttributeError: try: ret = self._hash = hash(frozenset(self.items())) except Exception as e: ret = self._hash = FrozenHashError(e) if ret.__class__ is FrozenHashError: raise ret return ret def __copy__(self): return self # immutable types don't copy, see tuple's behavior # block everything else def _raise_frozen_typeerror(self, *a, **kw): "raises a TypeError, because FrozenDicts are immutable" raise TypeError('%s object is immutable' % self.__class__.__name__) __ior__ = __setitem__ = __delitem__ = update = _raise_frozen_typeerror setdefault = pop = popitem = clear = _raise_frozen_typeerror del _raise_frozen_typeerror # end dictutils.py