# SPDX-License-Identifier: MIT import copy import enum import linecache import sys import types import typing from operator import itemgetter # We need to import _compat itself in addition to the _compat members to avoid # having the thread-local in the globals here. from . import _compat, _config, setters from ._compat import PY310, PYPY, _AnnotationExtractor, set_closure_cell from .exceptions import ( DefaultAlreadySetError, FrozenInstanceError, NotAnAttrsClassError, UnannotatedAttributeError, ) # This is used at least twice, so cache it here. _obj_setattr = object.__setattr__ _init_converter_pat = "__attr_converter_%s" _init_factory_pat = "__attr_factory_%s" _classvar_prefixes = ( "typing.ClassVar", "t.ClassVar", "ClassVar", "typing_extensions.ClassVar", ) # we don't use a double-underscore prefix because that triggers # name mangling when trying to create a slot for the field # (when slots=True) _hash_cache_field = "_attrs_cached_hash" _empty_metadata_singleton = types.MappingProxyType({}) # Unique object for unequivocal getattr() defaults. _sentinel = object() _ng_default_on_setattr = setters.pipe(setters.convert, setters.validate) class _Nothing(enum.Enum): """ Sentinel to indicate the lack of a value when ``None`` is ambiguous. If extending attrs, you can use ``typing.Literal[NOTHING]`` to show that a value may be ``NOTHING``. .. versionchanged:: 21.1.0 ``bool(NOTHING)`` is now False. .. versionchanged:: 22.2.0 ``NOTHING`` is now an ``enum.Enum`` variant. """ NOTHING = enum.auto() def __repr__(self): return "NOTHING" def __bool__(self): return False NOTHING = _Nothing.NOTHING """ Sentinel to indicate the lack of a value when ``None`` is ambiguous. """ class _CacheHashWrapper(int): """ An integer subclass that pickles / copies as None This is used for non-slots classes with ``cache_hash=True``, to avoid serializing a potentially (even likely) invalid hash value. Since ``None`` is the default value for uncalculated hashes, whenever this is copied, the copy's value for the hash should automatically reset. See GH #613 for more details. """ def __reduce__(self, _none_constructor=type(None), _args=()): return _none_constructor, _args def attrib( default=NOTHING, validator=None, repr=True, cmp=None, hash=None, init=True, metadata=None, type=None, converter=None, factory=None, kw_only=False, eq=None, order=None, on_setattr=None, alias=None, ): """ Create a new attribute on a class. .. warning:: Does *not* do anything unless the class is also decorated with `attr.s`! :param default: A value that is used if an ``attrs``-generated ``__init__`` is used and no value is passed while instantiating or the attribute is excluded using ``init=False``. If the value is an instance of `attrs.Factory`, its callable will be used to construct a new value (useful for mutable data types like lists or dicts). If a default is not set (or set manually to `attrs.NOTHING`), a value *must* be supplied when instantiating; otherwise a `TypeError` will be raised. The default can also be set using decorator notation as shown below. :type default: Any value :param callable factory: Syntactic sugar for ``default=attr.Factory(factory)``. :param validator: `callable` that is called by ``attrs``-generated ``__init__`` methods after the instance has been initialized. They receive the initialized instance, the :func:`~attrs.Attribute`, and the passed value. The return value is *not* inspected so the validator has to throw an exception itself. If a `list` is passed, its items are treated as validators and must all pass. Validators can be globally disabled and re-enabled using `get_run_validators`. The validator can also be set using decorator notation as shown below. :type validator: `callable` or a `list` of `callable`\\ s. :param repr: Include this attribute in the generated ``__repr__`` method. If ``True``, include the attribute; if ``False``, omit it. By default, the built-in ``repr()`` function is used. To override how the attribute value is formatted, pass a ``callable`` that takes a single value and returns a string. Note that the resulting string is used as-is, i.e. it will be used directly *instead* of calling ``repr()`` (the default). :type repr: a `bool` or a `callable` to use a custom function. :param eq: If ``True`` (default), include this attribute in the generated ``__eq__`` and ``__ne__`` methods that check two instances for equality. To override how the attribute value is compared, pass a ``callable`` that takes a single value and returns the value to be compared. :type eq: a `bool` or a `callable`. :param order: If ``True`` (default), include this attributes in the generated ``__lt__``, ``__le__``, ``__gt__`` and ``__ge__`` methods. To override how the attribute value is ordered, pass a ``callable`` that takes a single value and returns the value to be ordered. :type order: a `bool` or a `callable`. :param cmp: Setting *cmp* is equivalent to setting *eq* and *order* to the same value. Must not be mixed with *eq* or *order*. :type cmp: a `bool` or a `callable`. :param Optional[bool] hash: Include this attribute in the generated ``__hash__`` method. If ``None`` (default), mirror *eq*'s value. This is the correct behavior according the Python spec. Setting this value to anything else than ``None`` is *discouraged*. :param bool init: Include this attribute in the generated ``__init__`` method. It is possible to set this to ``False`` and set a default value. In that case this attributed is unconditionally initialized with the specified default value or factory. :param callable converter: `callable` that is called by ``attrs``-generated ``__init__`` methods to convert attribute's value to the desired format. It is given the passed-in value, and the returned value will be used as the new value of the attribute. The value is converted before being passed to the validator, if any. :param metadata: An arbitrary mapping, to be used by third-party components. See `extending-metadata`. :param type: The type of the attribute. Nowadays, the preferred method to specify the type is using a variable annotation (see :pep:`526`). This argument is provided for backward compatibility. Regardless of the approach used, the type will be stored on ``Attribute.type``. Please note that ``attrs`` doesn't do anything with this metadata by itself. You can use it as part of your own code or for `static type checking `. :param kw_only: Make this attribute keyword-only in the generated ``__init__`` (if ``init`` is ``False``, this parameter is ignored). :param on_setattr: Allows to overwrite the *on_setattr* setting from `attr.s`. If left `None`, the *on_setattr* value from `attr.s` is used. Set to `attrs.setters.NO_OP` to run **no** `setattr` hooks for this attribute -- regardless of the setting in `attr.s`. :type on_setattr: `callable`, or a list of callables, or `None`, or `attrs.setters.NO_OP` :param Optional[str] alias: Override this attribute's parameter name in the generated ``__init__`` method. If left `None`, default to ``name`` stripped of leading underscores. See `private-attributes`. .. versionadded:: 15.2.0 *convert* .. versionadded:: 16.3.0 *metadata* .. versionchanged:: 17.1.0 *validator* can be a ``list`` now. .. versionchanged:: 17.1.0 *hash* is ``None`` and therefore mirrors *eq* by default. .. versionadded:: 17.3.0 *type* .. deprecated:: 17.4.0 *convert* .. versionadded:: 17.4.0 *converter* as a replacement for the deprecated *convert* to achieve consistency with other noun-based arguments. .. versionadded:: 18.1.0 ``factory=f`` is syntactic sugar for ``default=attr.Factory(f)``. .. versionadded:: 18.2.0 *kw_only* .. versionchanged:: 19.2.0 *convert* keyword argument removed. .. versionchanged:: 19.2.0 *repr* also accepts a custom callable. .. deprecated:: 19.2.0 *cmp* Removal on or after 2021-06-01. .. versionadded:: 19.2.0 *eq* and *order* .. versionadded:: 20.1.0 *on_setattr* .. versionchanged:: 20.3.0 *kw_only* backported to Python 2 .. versionchanged:: 21.1.0 *eq*, *order*, and *cmp* also accept a custom callable .. versionchanged:: 21.1.0 *cmp* undeprecated .. versionadded:: 22.2.0 *alias* """ eq, eq_key, order, order_key = _determine_attrib_eq_order( cmp, eq, order, True ) if hash is not None and hash is not True and hash is not False: raise TypeError( "Invalid value for hash. Must be True, False, or None." ) if factory is not None: if default is not NOTHING: raise ValueError( "The `default` and `factory` arguments are mutually " "exclusive." ) if not callable(factory): raise ValueError("The `factory` argument must be a callable.") default = Factory(factory) if metadata is None: metadata = {} # Apply syntactic sugar by auto-wrapping. if isinstance(on_setattr, (list, tuple)): on_setattr = setters.pipe(*on_setattr) if validator and isinstance(validator, (list, tuple)): validator = and_(*validator) if converter and isinstance(converter, (list, tuple)): converter = pipe(*converter) return _CountingAttr( default=default, validator=validator, repr=repr, cmp=None, hash=hash, init=init, converter=converter, metadata=metadata, type=type, kw_only=kw_only, eq=eq, eq_key=eq_key, order=order, order_key=order_key, on_setattr=on_setattr, alias=alias, ) def _compile_and_eval(script, globs, locs=None, filename=""): """ "Exec" the script with the given global (globs) and local (locs) variables. """ bytecode = compile(script, filename, "exec") eval(bytecode, globs, locs) def _make_method(name, script, filename, globs): """ Create the method with the script given and return the method object. """ locs = {} # In order of debuggers like PDB being able to step through the code, # we add a fake linecache entry. count = 1 base_filename = filename while True: linecache_tuple = ( len(script), None, script.splitlines(True), filename, ) old_val = linecache.cache.setdefault(filename, linecache_tuple) if old_val == linecache_tuple: break else: filename = f"{base_filename[:-1]}-{count}>" count += 1 _compile_and_eval(script, globs, locs, filename) return locs[name] def _make_attr_tuple_class(cls_name, attr_names): """ Create a tuple subclass to hold `Attribute`s for an `attrs` class. The subclass is a bare tuple with properties for names. class MyClassAttributes(tuple): __slots__ = () x = property(itemgetter(0)) """ attr_class_name = f"{cls_name}Attributes" attr_class_template = [ f"class {attr_class_name}(tuple):", " __slots__ = ()", ] if attr_names: for i, attr_name in enumerate(attr_names): attr_class_template.append( f" {attr_name} = _attrs_property(_attrs_itemgetter({i}))" ) else: attr_class_template.append(" pass") globs = {"_attrs_itemgetter": itemgetter, "_attrs_property": property} _compile_and_eval("\n".join(attr_class_template), globs) return globs[attr_class_name] # Tuple class for extracted attributes from a class definition. # `base_attrs` is a subset of `attrs`. _Attributes = _make_attr_tuple_class( "_Attributes", [ # all attributes to build dunder methods for "attrs", # attributes that have been inherited "base_attrs", # map inherited attributes to their originating classes "base_attrs_map", ], ) def _is_class_var(annot): """ Check whether *annot* is a typing.ClassVar. The string comparison hack is used to avoid evaluating all string annotations which would put attrs-based classes at a performance disadvantage compared to plain old classes. """ annot = str(annot) # Annotation can be quoted. if annot.startswith(("'", '"')) and annot.endswith(("'", '"')): annot = annot[1:-1] return annot.startswith(_classvar_prefixes) def _has_own_attribute(cls, attrib_name): """ Check whether *cls* defines *attrib_name* (and doesn't just inherit it). """ attr = getattr(cls, attrib_name, _sentinel) if attr is _sentinel: return False for base_cls in cls.__mro__[1:]: a = getattr(base_cls, attrib_name, None) if attr is a: return False return True def _get_annotations(cls): """ Get annotations for *cls*. """ if _has_own_attribute(cls, "__annotations__"): return cls.__annotations__ return {} def _collect_base_attrs(cls, taken_attr_names): """ Collect attr.ibs from base classes of *cls*, except *taken_attr_names*. """ base_attrs = [] base_attr_map = {} # A dictionary of base attrs to their classes. # Traverse the MRO and collect attributes. for base_cls in reversed(cls.__mro__[1:-1]): for a in getattr(base_cls, "__attrs_attrs__", []): if a.inherited or a.name in taken_attr_names: continue a = a.evolve(inherited=True) base_attrs.append(a) base_attr_map[a.name] = base_cls # For each name, only keep the freshest definition i.e. the furthest at the # back. base_attr_map is fine because it gets overwritten with every new # instance. filtered = [] seen = set() for a in reversed(base_attrs): if a.name in seen: continue filtered.insert(0, a) seen.add(a.name) return filtered, base_attr_map def _collect_base_attrs_broken(cls, taken_attr_names): """ Collect attr.ibs from base classes of *cls*, except *taken_attr_names*. N.B. *taken_attr_names* will be mutated. Adhere to the old incorrect behavior. Notably it collects from the front and considers inherited attributes which leads to the buggy behavior reported in #428. """ base_attrs = [] base_attr_map = {} # A dictionary of base attrs to their classes. # Traverse the MRO and collect attributes. for base_cls in cls.__mro__[1:-1]: for a in getattr(base_cls, "__attrs_attrs__", []): if a.name in taken_attr_names: continue a = a.evolve(inherited=True) taken_attr_names.add(a.name) base_attrs.append(a) base_attr_map[a.name] = base_cls return base_attrs, base_attr_map def _transform_attrs( cls, these, auto_attribs, kw_only, collect_by_mro, field_transformer ): """ Transform all `_CountingAttr`s on a class into `Attribute`s. If *these* is passed, use that and don't look for them on the class. *collect_by_mro* is True, collect them in the correct MRO order, otherwise use the old -- incorrect -- order. See #428. Return an `_Attributes`. """ cd = cls.__dict__ anns = _get_annotations(cls) if these is not None: ca_list = [(name, ca) for name, ca in these.items()] elif auto_attribs is True: ca_names = { name for name, attr in cd.items() if isinstance(attr, _CountingAttr) } ca_list = [] annot_names = set() for attr_name, type in anns.items(): if _is_class_var(type): continue annot_names.add(attr_name) a = cd.get(attr_name, NOTHING) if not isinstance(a, _CountingAttr): if a is NOTHING: a = attrib() else: a = attrib(default=a) ca_list.append((attr_name, a)) unannotated = ca_names - annot_names if len(unannotated) > 0: raise UnannotatedAttributeError( "The following `attr.ib`s lack a type annotation: " + ", ".join( sorted(unannotated, key=lambda n: cd.get(n).counter) ) + "." ) else: ca_list = sorted( ( (name, attr) for name, attr in cd.items() if isinstance(attr, _CountingAttr) ), key=lambda e: e[1].counter, ) own_attrs = [ Attribute.from_counting_attr( name=attr_name, ca=ca, type=anns.get(attr_name) ) for attr_name, ca in ca_list ] if collect_by_mro: base_attrs, base_attr_map = _collect_base_attrs( cls, {a.name for a in own_attrs} ) else: base_attrs, base_attr_map = _collect_base_attrs_broken( cls, {a.name for a in own_attrs} ) if kw_only: own_attrs = [a.evolve(kw_only=True) for a in own_attrs] base_attrs = [a.evolve(kw_only=True) for a in base_attrs] attrs = base_attrs + own_attrs # Mandatory vs non-mandatory attr order only matters when they are part of # the __init__ signature and when they aren't kw_only (which are moved to # the end and can be mandatory or non-mandatory in any order, as they will # be specified as keyword args anyway). Check the order of those attrs: had_default = False for a in (a for a in attrs if a.init is not False and a.kw_only is False): if had_default is True and a.default is NOTHING: raise ValueError( "No mandatory attributes allowed after an attribute with a " f"default value or factory. Attribute in question: {a!r}" ) if had_default is False and a.default is not NOTHING: had_default = True if field_transformer is not None: attrs = field_transformer(cls, attrs) # Resolve default field alias after executing field_transformer. # This allows field_transformer to differentiate between explicit vs # default aliases and supply their own defaults. attrs = [ a.evolve(alias=_default_init_alias_for(a.name)) if not a.alias else a for a in attrs ] # Create AttrsClass *after* applying the field_transformer since it may # add or remove attributes! attr_names = [a.name for a in attrs] AttrsClass = _make_attr_tuple_class(cls.__name__, attr_names) return _Attributes((AttrsClass(attrs), base_attrs, base_attr_map)) if PYPY: def _frozen_setattrs(self, name, value): """ Attached to frozen classes as __setattr__. """ if isinstance(self, BaseException) and name in ( "__cause__", "__context__", ): BaseException.__setattr__(self, name, value) return raise FrozenInstanceError() else: def _frozen_setattrs(self, name, value): """ Attached to frozen classes as __setattr__. """ raise FrozenInstanceError() def _frozen_delattrs(self, name): """ Attached to frozen classes as __delattr__. """ raise FrozenInstanceError() class _ClassBuilder: """ Iteratively build *one* class. """ __slots__ = ( "_attr_names", "_attrs", "_base_attr_map", "_base_names", "_cache_hash", "_cls", "_cls_dict", "_delete_attribs", "_frozen", "_has_pre_init", "_has_post_init", "_is_exc", "_on_setattr", "_slots", "_weakref_slot", "_wrote_own_setattr", "_has_custom_setattr", ) def __init__( self, cls, these, slots, frozen, weakref_slot, getstate_setstate, auto_attribs, kw_only, cache_hash, is_exc, collect_by_mro, on_setattr, has_custom_setattr, field_transformer, ): attrs, base_attrs, base_map = _transform_attrs( cls, these, auto_attribs, kw_only, collect_by_mro, field_transformer, ) self._cls = cls self._cls_dict = dict(cls.__dict__) if slots else {} self._attrs = attrs self._base_names = {a.name for a in base_attrs} self._base_attr_map = base_map self._attr_names = tuple(a.name for a in attrs) self._slots = slots self._frozen = frozen self._weakref_slot = weakref_slot self._cache_hash = cache_hash self._has_pre_init = bool(getattr(cls, "__attrs_pre_init__", False)) self._has_post_init = bool(getattr(cls, "__attrs_post_init__", False)) self._delete_attribs = not bool(these) self._is_exc = is_exc self._on_setattr = on_setattr self._has_custom_setattr = has_custom_setattr self._wrote_own_setattr = False self._cls_dict["__attrs_attrs__"] = self._attrs if frozen: self._cls_dict["__setattr__"] = _frozen_setattrs self._cls_dict["__delattr__"] = _frozen_delattrs self._wrote_own_setattr = True elif on_setattr in ( _ng_default_on_setattr, setters.validate, setters.convert, ): has_validator = has_converter = False for a in attrs: if a.validator is not None: has_validator = True if a.converter is not None: has_converter = True if has_validator and has_converter: break if ( ( on_setattr == _ng_default_on_setattr and not (has_validator or has_converter) ) or (on_setattr == setters.validate and not has_validator) or (on_setattr == setters.convert and not has_converter) ): # If class-level on_setattr is set to convert + validate, but # there's no field to convert or validate, pretend like there's # no on_setattr. self._on_setattr = None if getstate_setstate: ( self._cls_dict["__getstate__"], self._cls_dict["__setstate__"], ) = self._make_getstate_setstate() def __repr__(self): return f"<_ClassBuilder(cls={self._cls.__name__})>" if PY310: import abc def build_class(self): """ Finalize class based on the accumulated configuration. Builder cannot be used after calling this method. """ if self._slots is True: return self._create_slots_class() return self.abc.update_abstractmethods( self._patch_original_class() ) else: def build_class(self): """ Finalize class based on the accumulated configuration. Builder cannot be used after calling this method. """ if self._slots is True: return self._create_slots_class() return self._patch_original_class() def _patch_original_class(self): """ Apply accumulated methods and return the class. """ cls = self._cls base_names = self._base_names # Clean class of attribute definitions (`attr.ib()`s). if self._delete_attribs: for name in self._attr_names: if ( name not in base_names and getattr(cls, name, _sentinel) is not _sentinel ): try: delattr(cls, name) except AttributeError: # This can happen if a base class defines a class # variable and we want to set an attribute with the # same name by using only a type annotation. pass # Attach our dunder methods. for name, value in self._cls_dict.items(): setattr(cls, name, value) # If we've inherited an attrs __setattr__ and don't write our own, # reset it to object's. if not self._wrote_own_setattr and getattr( cls, "__attrs_own_setattr__", False ): cls.__attrs_own_setattr__ = False if not self._has_custom_setattr: cls.__setattr__ = _obj_setattr return cls def _create_slots_class(self): """ Build and return a new class with a `__slots__` attribute. """ cd = { k: v for k, v in self._cls_dict.items() if k not in tuple(self._attr_names) + ("__dict__", "__weakref__") } # If our class doesn't have its own implementation of __setattr__ # (either from the user or by us), check the bases, if one of them has # an attrs-made __setattr__, that needs to be reset. We don't walk the # MRO because we only care about our immediate base classes. # XXX: This can be confused by subclassing a slotted attrs class with # XXX: a non-attrs class and subclass the resulting class with an attrs # XXX: class. See `test_slotted_confused` for details. For now that's # XXX: OK with us. if not self._wrote_own_setattr: cd["__attrs_own_setattr__"] = False if not self._has_custom_setattr: for base_cls in self._cls.__bases__: if base_cls.__dict__.get("__attrs_own_setattr__", False): cd["__setattr__"] = _obj_setattr break # Traverse the MRO to collect existing slots # and check for an existing __weakref__. existing_slots = dict() weakref_inherited = False for base_cls in self._cls.__mro__[1:-1]: if base_cls.__dict__.get("__weakref__", None) is not None: weakref_inherited = True existing_slots.update( { name: getattr(base_cls, name) for name in getattr(base_cls, "__slots__", []) } ) base_names = set(self._base_names) names = self._attr_names if ( self._weakref_slot and "__weakref__" not in getattr(self._cls, "__slots__", ()) and "__weakref__" not in names and not weakref_inherited ): names += ("__weakref__",) # We only add the names of attributes that aren't inherited. # Setting __slots__ to inherited attributes wastes memory. slot_names = [name for name in names if name not in base_names] # There are slots for attributes from current class # that are defined in parent classes. # As their descriptors may be overridden by a child class, # we collect them here and update the class dict reused_slots = { slot: slot_descriptor for slot, slot_descriptor in existing_slots.items() if slot in slot_names } slot_names = [name for name in slot_names if name not in reused_slots] cd.update(reused_slots) if self._cache_hash: slot_names.append(_hash_cache_field) cd["__slots__"] = tuple(slot_names) cd["__qualname__"] = self._cls.__qualname__ # Create new class based on old class and our methods. cls = type(self._cls)(self._cls.__name__, self._cls.__bases__, cd) # The following is a fix for # . # If a method mentions `__class__` or uses the no-arg super(), the # compiler will bake a reference to the class in the method itself # as `method.__closure__`. Since we replace the class with a # clone, we rewrite these references so it keeps working. for item in cls.__dict__.values(): if isinstance(item, (classmethod, staticmethod)): # Class- and staticmethods hide their functions inside. # These might need to be rewritten as well. closure_cells = getattr(item.__func__, "__closure__", None) elif isinstance(item, property): # Workaround for property `super()` shortcut (PY3-only). # There is no universal way for other descriptors. closure_cells = getattr(item.fget, "__closure__", None) else: closure_cells = getattr(item, "__closure__", None) if not closure_cells: # Catch None or the empty list. continue for cell in closure_cells: try: match = cell.cell_contents is self._cls except ValueError: # ValueError: Cell is empty pass else: if match: set_closure_cell(cell, cls) return cls def add_repr(self, ns): self._cls_dict["__repr__"] = self._add_method_dunders( _make_repr(self._attrs, ns, self._cls) ) return self def add_str(self): repr = self._cls_dict.get("__repr__") if repr is None: raise ValueError( "__str__ can only be generated if a __repr__ exists." ) def __str__(self): return self.__repr__() self._cls_dict["__str__"] = self._add_method_dunders(__str__) return self def _make_getstate_setstate(self): """ Create custom __setstate__ and __getstate__ methods. """ # __weakref__ is not writable. state_attr_names = tuple( an for an in self._attr_names if an != "__weakref__" ) def slots_getstate(self): """ Automatically created by attrs. """ return {name: getattr(self, name) for name in state_attr_names} hash_caching_enabled = self._cache_hash def slots_setstate(self, state): """ Automatically created by attrs. """ __bound_setattr = _obj_setattr.__get__(self) for name in state_attr_names: if name in state: __bound_setattr(name, state[name]) # The hash code cache is not included when the object is # serialized, but it still needs to be initialized to None to # indicate that the first call to __hash__ should be a cache # miss. if hash_caching_enabled: __bound_setattr(_hash_cache_field, None) return slots_getstate, slots_setstate def make_unhashable(self): self._cls_dict["__hash__"] = None return self def add_hash(self): self._cls_dict["__hash__"] = self._add_method_dunders( _make_hash( self._cls, self._attrs, frozen=self._frozen, cache_hash=self._cache_hash, ) ) return self def add_init(self): self._cls_dict["__init__"] = self._add_method_dunders( _make_init( self._cls, self._attrs, self._has_pre_init, self._has_post_init, self._frozen, self._slots, self._cache_hash, self._base_attr_map, self._is_exc, self._on_setattr, attrs_init=False, ) ) return self def add_match_args(self): self._cls_dict["__match_args__"] = tuple( field.name for field in self._attrs if field.init and not field.kw_only ) def add_attrs_init(self): self._cls_dict["__attrs_init__"] = self._add_method_dunders( _make_init( self._cls, self._attrs, self._has_pre_init, self._has_post_init, self._frozen, self._slots, self._cache_hash, self._base_attr_map, self._is_exc, self._on_setattr, attrs_init=True, ) ) return self def add_eq(self): cd = self._cls_dict cd["__eq__"] = self._add_method_dunders( _make_eq(self._cls, self._attrs) ) cd["__ne__"] = self._add_method_dunders(_make_ne()) return self def add_order(self): cd = self._cls_dict cd["__lt__"], cd["__le__"], cd["__gt__"], cd["__ge__"] = ( self._add_method_dunders(meth) for meth in _make_order(self._cls, self._attrs) ) return self def add_setattr(self): if self._frozen: return self sa_attrs = {} for a in self._attrs: on_setattr = a.on_setattr or self._on_setattr if on_setattr and on_setattr is not setters.NO_OP: sa_attrs[a.name] = a, on_setattr if not sa_attrs: return self if self._has_custom_setattr: # We need to write a __setattr__ but there already is one! raise ValueError( "Can't combine custom __setattr__ with on_setattr hooks." ) # docstring comes from _add_method_dunders def __setattr__(self, name, val): try: a, hook = sa_attrs[name] except KeyError: nval = val else: nval = hook(self, a, val) _obj_setattr(self, name, nval) self._cls_dict["__attrs_own_setattr__"] = True self._cls_dict["__setattr__"] = self._add_method_dunders(__setattr__) self._wrote_own_setattr = True return self def _add_method_dunders(self, method): """ Add __module__ and __qualname__ to a *method* if possible. """ try: method.__module__ = self._cls.__module__ except AttributeError: pass try: method.__qualname__ = ".".join( (self._cls.__qualname__, method.__name__) ) except AttributeError: pass try: method.__doc__ = ( "Method generated by attrs for class " f"{self._cls.__qualname__}." ) except AttributeError: pass return method def _determine_attrs_eq_order(cmp, eq, order, default_eq): """ Validate the combination of *cmp*, *eq*, and *order*. Derive the effective values of eq and order. If *eq* is None, set it to *default_eq*. """ if cmp is not None and any((eq is not None, order is not None)): raise ValueError("Don't mix `cmp` with `eq' and `order`.") # cmp takes precedence due to bw-compatibility. if cmp is not None: return cmp, cmp # If left None, equality is set to the specified default and ordering # mirrors equality. if eq is None: eq = default_eq if order is None: order = eq if eq is False and order is True: raise ValueError("`order` can only be True if `eq` is True too.") return eq, order def _determine_attrib_eq_order(cmp, eq, order, default_eq): """ Validate the combination of *cmp*, *eq*, and *order*. Derive the effective values of eq and order. If *eq* is None, set it to *default_eq*. """ if cmp is not None and any((eq is not None, order is not None)): raise ValueError("Don't mix `cmp` with `eq' and `order`.") def decide_callable_or_boolean(value): """ Decide whether a key function is used. """ if callable(value): value, key = True, value else: key = None return value, key # cmp takes precedence due to bw-compatibility. if cmp is not None: cmp, cmp_key = decide_callable_or_boolean(cmp) return cmp, cmp_key, cmp, cmp_key # If left None, equality is set to the specified default and ordering # mirrors equality. if eq is None: eq, eq_key = default_eq, None else: eq, eq_key = decide_callable_or_boolean(eq) if order is None: order, order_key = eq, eq_key else: order, order_key = decide_callable_or_boolean(order) if eq is False and order is True: raise ValueError("`order` can only be True if `eq` is True too.") return eq, eq_key, order, order_key def _determine_whether_to_implement( cls, flag, auto_detect, dunders, default=True ): """ Check whether we should implement a set of methods for *cls*. *flag* is the argument passed into @attr.s like 'init', *auto_detect* the same as passed into @attr.s and *dunders* is a tuple of attribute names whose presence signal that the user has implemented it themselves. Return *default* if no reason for either for or against is found. """ if flag is True or flag is False: return flag if flag is None and auto_detect is False: return default # Logically, flag is None and auto_detect is True here. for dunder in dunders: if _has_own_attribute(cls, dunder): return False return default def attrs( maybe_cls=None, these=None, repr_ns=None, repr=None, cmp=None, hash=None, init=None, slots=False, frozen=False, weakref_slot=True, str=False, auto_attribs=False, kw_only=False, cache_hash=False, auto_exc=False, eq=None, order=None, auto_detect=False, collect_by_mro=False, getstate_setstate=None, on_setattr=None, field_transformer=None, match_args=True, unsafe_hash=None, ): r""" A class decorator that adds :term:`dunder methods` according to the specified attributes using `attr.ib` or the *these* argument. :param these: A dictionary of name to `attr.ib` mappings. This is useful to avoid the definition of your attributes within the class body because you can't (e.g. if you want to add ``__repr__`` methods to Django models) or don't want to. If *these* is not ``None``, ``attrs`` will *not* search the class body for attributes and will *not* remove any attributes from it. The order is deduced from the order of the attributes inside *these*. :type these: `dict` of `str` to `attr.ib` :param str repr_ns: When using nested classes, there's no way in Python 2 to automatically detect that. Therefore it's possible to set the namespace explicitly for a more meaningful ``repr`` output. :param bool auto_detect: Instead of setting the *init*, *repr*, *eq*, *order*, and *hash* arguments explicitly, assume they are set to ``True`` **unless any** of the involved methods for one of the arguments is implemented in the *current* class (i.e. it is *not* inherited from some base class). So for example by implementing ``__eq__`` on a class yourself, ``attrs`` will deduce ``eq=False`` and will create *neither* ``__eq__`` *nor* ``__ne__`` (but Python classes come with a sensible ``__ne__`` by default, so it *should* be enough to only implement ``__eq__`` in most cases). .. warning:: If you prevent ``attrs`` from creating the ordering methods for you (``order=False``, e.g. by implementing ``__le__``), it becomes *your* responsibility to make sure its ordering is sound. The best way is to use the `functools.total_ordering` decorator. Passing ``True`` or ``False`` to *init*, *repr*, *eq*, *order*, *cmp*, or *hash* overrides whatever *auto_detect* would determine. :param bool repr: Create a ``__repr__`` method with a human readable representation of ``attrs`` attributes.. :param bool str: Create a ``__str__`` method that is identical to ``__repr__``. This is usually not necessary except for `Exception`\ s. :param Optional[bool] eq: If ``True`` or ``None`` (default), add ``__eq__`` and ``__ne__`` methods that check two instances for equality. They compare the instances as if they were tuples of their ``attrs`` attributes if and only if the types of both classes are *identical*! :param Optional[bool] order: If ``True``, add ``__lt__``, ``__le__``, ``__gt__``, and ``__ge__`` methods that behave like *eq* above and allow instances to be ordered. If ``None`` (default) mirror value of *eq*. :param Optional[bool] cmp: Setting *cmp* is equivalent to setting *eq* and *order* to the same value. Must not be mixed with *eq* or *order*. :param Optional[bool] unsafe_hash: If ``None`` (default), the ``__hash__`` method is generated according how *eq* and *frozen* are set. 1. If *both* are True, ``attrs`` will generate a ``__hash__`` for you. 2. If *eq* is True and *frozen* is False, ``__hash__`` will be set to None, marking it unhashable (which it is). 3. If *eq* is False, ``__hash__`` will be left untouched meaning the ``__hash__`` method of the base class will be used (if base class is ``object``, this means it will fall back to id-based hashing.). Although not recommended, you can decide for yourself and force ``attrs`` to create one (e.g. if the class is immutable even though you didn't freeze it programmatically) by passing ``True`` or not. Both of these cases are rather special and should be used carefully. See our documentation on `hashing`, Python's documentation on `object.__hash__`, and the `GitHub issue that led to the default \ behavior `_ for more details. :param Optional[bool] hash: Alias for *unsafe_hash*. *unsafe_hash* takes precedence. :param bool init: Create a ``__init__`` method that initializes the ``attrs`` attributes. Leading underscores are stripped for the argument name. If a ``__attrs_pre_init__`` method exists on the class, it will be called before the class is initialized. If a ``__attrs_post_init__`` method exists on the class, it will be called after the class is fully initialized. If ``init`` is ``False``, an ``__attrs_init__`` method will be injected instead. This allows you to define a custom ``__init__`` method that can do pre-init work such as ``super().__init__()``, and then call ``__attrs_init__()`` and ``__attrs_post_init__()``. :param bool slots: Create a :term:`slotted class ` that's more memory-efficient. Slotted classes are generally superior to the default dict classes, but have some gotchas you should know about, so we encourage you to read the :term:`glossary entry `. :param bool frozen: Make instances immutable after initialization. If someone attempts to modify a frozen instance, `attr.exceptions.FrozenInstanceError` is raised. .. note:: 1. This is achieved by installing a custom ``__setattr__`` method on your class, so you can't implement your own. 2. True immutability is impossible in Python. 3. This *does* have a minor a runtime performance `impact ` when initializing new instances. In other words: ``__init__`` is slightly slower with ``frozen=True``. 4. If a class is frozen, you cannot modify ``self`` in ``__attrs_post_init__`` or a self-written ``__init__``. You can circumvent that limitation by using ``object.__setattr__(self, "attribute_name", value)``. 5. Subclasses of a frozen class are frozen too. :param bool weakref_slot: Make instances weak-referenceable. This has no effect unless ``slots`` is also enabled. :param bool auto_attribs: If ``True``, collect :pep:`526`-annotated attributes from the class body. In this case, you **must** annotate every field. If ``attrs`` encounters a field that is set to an `attr.ib` but lacks a type annotation, an `attr.exceptions.UnannotatedAttributeError` is raised. Use ``field_name: typing.Any = attr.ib(...)`` if you don't want to set a type. If you assign a value to those attributes (e.g. ``x: int = 42``), that value becomes the default value like if it were passed using ``attr.ib(default=42)``. Passing an instance of `attrs.Factory` also works as expected in most cases (see warning below). Attributes annotated as `typing.ClassVar`, and attributes that are neither annotated nor set to an `attr.ib` are **ignored**. .. warning:: For features that use the attribute name to create decorators (e.g. `validators `), you still *must* assign `attr.ib` to them. Otherwise Python will either not find the name or try to use the default value to call e.g. ``validator`` on it. These errors can be quite confusing and probably the most common bug report on our bug tracker. :param bool kw_only: Make all attributes keyword-only in the generated ``__init__`` (if ``init`` is ``False``, this parameter is ignored). :param bool cache_hash: Ensure that the object's hash code is computed only once and stored on the object. If this is set to ``True``, hashing must be either explicitly or implicitly enabled for this class. If the hash code is cached, avoid any reassignments of fields involved in hash code computation or mutations of the objects those fields point to after object creation. If such changes occur, the behavior of the object's hash code is undefined. :param bool auto_exc: If the class subclasses `BaseException` (which implicitly includes any subclass of any exception), the following happens to behave like a well-behaved Python exceptions class: - the values for *eq*, *order*, and *hash* are ignored and the instances compare and hash by the instance's ids (N.B. ``attrs`` will *not* remove existing implementations of ``__hash__`` or the equality methods. It just won't add own ones.), - all attributes that are either passed into ``__init__`` or have a default value are additionally available as a tuple in the ``args`` attribute, - the value of *str* is ignored leaving ``__str__`` to base classes. :param bool collect_by_mro: Setting this to `True` fixes the way ``attrs`` collects attributes from base classes. The default behavior is incorrect in certain cases of multiple inheritance. It should be on by default but is kept off for backward-compatibility. See issue `#428 `_ for more details. :param Optional[bool] getstate_setstate: .. note:: This is usually only interesting for slotted classes and you should probably just set *auto_detect* to `True`. If `True`, ``__getstate__`` and ``__setstate__`` are generated and attached to the class. This is necessary for slotted classes to be pickleable. If left `None`, it's `True` by default for slotted classes and ``False`` for dict classes. If *auto_detect* is `True`, and *getstate_setstate* is left `None`, and **either** ``__getstate__`` or ``__setstate__`` is detected directly on the class (i.e. not inherited), it is set to `False` (this is usually what you want). :param on_setattr: A callable that is run whenever the user attempts to set an attribute (either by assignment like ``i.x = 42`` or by using `setattr` like ``setattr(i, "x", 42)``). It receives the same arguments as validators: the instance, the attribute that is being modified, and the new value. If no exception is raised, the attribute is set to the return value of the callable. If a list of callables is passed, they're automatically wrapped in an `attrs.setters.pipe`. :type on_setattr: `callable`, or a list of callables, or `None`, or `attrs.setters.NO_OP` :param Optional[callable] field_transformer: A function that is called with the original class object and all fields right before ``attrs`` finalizes the class. You can use this, e.g., to automatically add converters or validators to fields based on their types. See `transform-fields` for more details. :param bool match_args: If `True` (default), set ``__match_args__`` on the class to support :pep:`634` (Structural Pattern Matching). It is a tuple of all non-keyword-only ``__init__`` parameter names on Python 3.10 and later. Ignored on older Python versions. .. versionadded:: 16.0.0 *slots* .. versionadded:: 16.1.0 *frozen* .. versionadded:: 16.3.0 *str* .. versionadded:: 16.3.0 Support for ``__attrs_post_init__``. .. versionchanged:: 17.1.0 *hash* supports ``None`` as value which is also the default now. .. versionadded:: 17.3.0 *auto_attribs* .. versionchanged:: 18.1.0 If *these* is passed, no attributes are deleted from the class body. .. versionchanged:: 18.1.0 If *these* is ordered, the order is retained. .. versionadded:: 18.2.0 *weakref_slot* .. deprecated:: 18.2.0 ``__lt__``, ``__le__``, ``__gt__``, and ``__ge__`` now raise a `DeprecationWarning` if the classes compared are subclasses of each other. ``__eq`` and ``__ne__`` never tried to compared subclasses to each other. .. versionchanged:: 19.2.0 ``__lt__``, ``__le__``, ``__gt__``, and ``__ge__`` now do not consider subclasses comparable anymore. .. versionadded:: 18.2.0 *kw_only* .. versionadded:: 18.2.0 *cache_hash* .. versionadded:: 19.1.0 *auto_exc* .. deprecated:: 19.2.0 *cmp* Removal on or after 2021-06-01. .. versionadded:: 19.2.0 *eq* and *order* .. versionadded:: 20.1.0 *auto_detect* .. versionadded:: 20.1.0 *collect_by_mro* .. versionadded:: 20.1.0 *getstate_setstate* .. versionadded:: 20.1.0 *on_setattr* .. versionadded:: 20.3.0 *field_transformer* .. versionchanged:: 21.1.0 ``init=False`` injects ``__attrs_init__`` .. versionchanged:: 21.1.0 Support for ``__attrs_pre_init__`` .. versionchanged:: 21.1.0 *cmp* undeprecated .. versionadded:: 21.3.0 *match_args* .. versionadded:: 22.2.0 *unsafe_hash* as an alias for *hash* (for :pep:`681` compliance). """ eq_, order_ = _determine_attrs_eq_order(cmp, eq, order, None) # unsafe_hash takes precedence due to PEP 681. if unsafe_hash is not None: hash = unsafe_hash if isinstance(on_setattr, (list, tuple)): on_setattr = setters.pipe(*on_setattr) def wrap(cls): is_frozen = frozen or _has_frozen_base_class(cls) is_exc = auto_exc is True and issubclass(cls, BaseException) has_own_setattr = auto_detect and _has_own_attribute( cls, "__setattr__" ) if has_own_setattr and is_frozen: raise ValueError("Can't freeze a class with a custom __setattr__.") builder = _ClassBuilder( cls, these, slots, is_frozen, weakref_slot, _determine_whether_to_implement( cls, getstate_setstate, auto_detect, ("__getstate__", "__setstate__"), default=slots, ), auto_attribs, kw_only, cache_hash, is_exc, collect_by_mro, on_setattr, has_own_setattr, field_transformer, ) if _determine_whether_to_implement( cls, repr, auto_detect, ("__repr__",) ): builder.add_repr(repr_ns) if str is True: builder.add_str() eq = _determine_whether_to_implement( cls, eq_, auto_detect, ("__eq__", "__ne__") ) if not is_exc and eq is True: builder.add_eq() if not is_exc and _determine_whether_to_implement( cls, order_, auto_detect, ("__lt__", "__le__", "__gt__", "__ge__") ): builder.add_order() builder.add_setattr() nonlocal hash if ( hash is None and auto_detect is True and _has_own_attribute(cls, "__hash__") ): hash = False if hash is not True and hash is not False and hash is not None: # Can't use `hash in` because 1 == True for example. raise TypeError( "Invalid value for hash. Must be True, False, or None." ) elif hash is False or (hash is None and eq is False) or is_exc: # Don't do anything. Should fall back to __object__'s __hash__ # which is by id. if cache_hash: raise TypeError( "Invalid value for cache_hash. To use hash caching," " hashing must be either explicitly or implicitly " "enabled." ) elif hash is True or ( hash is None and eq is True and is_frozen is True ): # Build a __hash__ if told so, or if it's safe. builder.add_hash() else: # Raise TypeError on attempts to hash. if cache_hash: raise TypeError( "Invalid value for cache_hash. To use hash caching," " hashing must be either explicitly or implicitly " "enabled." ) builder.make_unhashable() if _determine_whether_to_implement( cls, init, auto_detect, ("__init__",) ): builder.add_init() else: builder.add_attrs_init() if cache_hash: raise TypeError( "Invalid value for cache_hash. To use hash caching," " init must be True." ) if ( PY310 and match_args and not _has_own_attribute(cls, "__match_args__") ): builder.add_match_args() return builder.build_class() # maybe_cls's type depends on the usage of the decorator. It's a class # if it's used as `@attrs` but ``None`` if used as `@attrs()`. if maybe_cls is None: return wrap else: return wrap(maybe_cls) _attrs = attrs """ Internal alias so we can use it in functions that take an argument called *attrs*. """ def _has_frozen_base_class(cls): """ Check whether *cls* has a frozen ancestor by looking at its __setattr__. """ return cls.__setattr__ is _frozen_setattrs def _generate_unique_filename(cls, func_name): """ Create a "filename" suitable for a function being generated. """ return ( f"" ) def _make_hash(cls, attrs, frozen, cache_hash): attrs = tuple( a for a in attrs if a.hash is True or (a.hash is None and a.eq is True) ) tab = " " unique_filename = _generate_unique_filename(cls, "hash") type_hash = hash(unique_filename) # If eq is custom generated, we need to include the functions in globs globs = {} hash_def = "def __hash__(self" hash_func = "hash((" closing_braces = "))" if not cache_hash: hash_def += "):" else: hash_def += ", *" hash_def += ( ", _cache_wrapper=" + "__import__('attr._make')._make._CacheHashWrapper):" ) hash_func = "_cache_wrapper(" + hash_func closing_braces += ")" method_lines = [hash_def] def append_hash_computation_lines(prefix, indent): """ Generate the code for actually computing the hash code. Below this will either be returned directly or used to compute a value which is then cached, depending on the value of cache_hash """ method_lines.extend( [ indent + prefix + hash_func, indent + f" {type_hash},", ] ) for a in attrs: if a.eq_key: cmp_name = f"_{a.name}_key" globs[cmp_name] = a.eq_key method_lines.append( indent + f" {cmp_name}(self.{a.name})," ) else: method_lines.append(indent + f" self.{a.name},") method_lines.append(indent + " " + closing_braces) if cache_hash: method_lines.append(tab + f"if self.{_hash_cache_field} is None:") if frozen: append_hash_computation_lines( f"object.__setattr__(self, '{_hash_cache_field}', ", tab * 2 ) method_lines.append(tab * 2 + ")") # close __setattr__ else: append_hash_computation_lines( f"self.{_hash_cache_field} = ", tab * 2 ) method_lines.append(tab + f"return self.{_hash_cache_field}") else: append_hash_computation_lines("return ", tab) script = "\n".join(method_lines) return _make_method("__hash__", script, unique_filename, globs) def _add_hash(cls, attrs): """ Add a hash method to *cls*. """ cls.__hash__ = _make_hash(cls, attrs, frozen=False, cache_hash=False) return cls def _make_ne(): """ Create __ne__ method. """ def __ne__(self, other): """ Check equality and either forward a NotImplemented or return the result negated. """ result = self.__eq__(other) if result is NotImplemented: return NotImplemented return not result return __ne__ def _make_eq(cls, attrs): """ Create __eq__ method for *cls* with *attrs*. """ attrs = [a for a in attrs if a.eq] unique_filename = _generate_unique_filename(cls, "eq") lines = [ "def __eq__(self, other):", " if other.__class__ is not self.__class__:", " return NotImplemented", ] # We can't just do a big self.x = other.x and... clause due to # irregularities like nan == nan is false but (nan,) == (nan,) is true. globs = {} if attrs: lines.append(" return (") others = [" ) == ("] for a in attrs: if a.eq_key: cmp_name = f"_{a.name}_key" # Add the key function to the global namespace # of the evaluated function. globs[cmp_name] = a.eq_key lines.append(f" {cmp_name}(self.{a.name}),") others.append(f" {cmp_name}(other.{a.name}),") else: lines.append(f" self.{a.name},") others.append(f" other.{a.name},") lines += others + [" )"] else: lines.append(" return True") script = "\n".join(lines) return _make_method("__eq__", script, unique_filename, globs) def _make_order(cls, attrs): """ Create ordering methods for *cls* with *attrs*. """ attrs = [a for a in attrs if a.order] def attrs_to_tuple(obj): """ Save us some typing. """ return tuple( key(value) if key else value for value, key in ( (getattr(obj, a.name), a.order_key) for a in attrs ) ) def __lt__(self, other): """ Automatically created by attrs. """ if other.__class__ is self.__class__: return attrs_to_tuple(self) < attrs_to_tuple(other) return NotImplemented def __le__(self, other): """ Automatically created by attrs. """ if other.__class__ is self.__class__: return attrs_to_tuple(self) <= attrs_to_tuple(other) return NotImplemented def __gt__(self, other): """ Automatically created by attrs. """ if other.__class__ is self.__class__: return attrs_to_tuple(self) > attrs_to_tuple(other) return NotImplemented def __ge__(self, other): """ Automatically created by attrs. """ if other.__class__ is self.__class__: return attrs_to_tuple(self) >= attrs_to_tuple(other) return NotImplemented return __lt__, __le__, __gt__, __ge__ def _add_eq(cls, attrs=None): """ Add equality methods to *cls* with *attrs*. """ if attrs is None: attrs = cls.__attrs_attrs__ cls.__eq__ = _make_eq(cls, attrs) cls.__ne__ = _make_ne() return cls def _make_repr(attrs, ns, cls): unique_filename = _generate_unique_filename(cls, "repr") # Figure out which attributes to include, and which function to use to # format them. The a.repr value can be either bool or a custom # callable. attr_names_with_reprs = tuple( (a.name, (repr if a.repr is True else a.repr), a.init) for a in attrs if a.repr is not False ) globs = { name + "_repr": r for name, r, _ in attr_names_with_reprs if r != repr } globs["_compat"] = _compat globs["AttributeError"] = AttributeError globs["NOTHING"] = NOTHING attribute_fragments = [] for name, r, i in attr_names_with_reprs: accessor = ( "self." + name if i else 'getattr(self, "' + name + '", NOTHING)' ) fragment = ( "%s={%s!r}" % (name, accessor) if r == repr else "%s={%s_repr(%s)}" % (name, name, accessor) ) attribute_fragments.append(fragment) repr_fragment = ", ".join(attribute_fragments) if ns is None: cls_name_fragment = '{self.__class__.__qualname__.rsplit(">.", 1)[-1]}' else: cls_name_fragment = ns + ".{self.__class__.__name__}" lines = [ "def __repr__(self):", " try:", " already_repring = _compat.repr_context.already_repring", " except AttributeError:", " already_repring = {id(self),}", " _compat.repr_context.already_repring = already_repring", " else:", " if id(self) in already_repring:", " return '...'", " else:", " already_repring.add(id(self))", " try:", f" return f'{cls_name_fragment}({repr_fragment})'", " finally:", " already_repring.remove(id(self))", ] return _make_method( "__repr__", "\n".join(lines), unique_filename, globs=globs ) def _add_repr(cls, ns=None, attrs=None): """ Add a repr method to *cls*. """ if attrs is None: attrs = cls.__attrs_attrs__ cls.__repr__ = _make_repr(attrs, ns, cls) return cls def fields(cls): """ Return the tuple of ``attrs`` attributes for a class. The tuple also allows accessing the fields by their names (see below for examples). :param type cls: Class to introspect. :raise TypeError: If *cls* is not a class. :raise attr.exceptions.NotAnAttrsClassError: If *cls* is not an ``attrs`` class. :rtype: tuple (with name accessors) of `attrs.Attribute` .. versionchanged:: 16.2.0 Returned tuple allows accessing the fields by name. """ if not isinstance(cls, type): raise TypeError("Passed object must be a class.") attrs = getattr(cls, "__attrs_attrs__", None) if attrs is None: raise NotAnAttrsClassError(f"{cls!r} is not an attrs-decorated class.") return attrs def fields_dict(cls): """ Return an ordered dictionary of ``attrs`` attributes for a class, whose keys are the attribute names. :param type cls: Class to introspect. :raise TypeError: If *cls* is not a class. :raise attr.exceptions.NotAnAttrsClassError: If *cls* is not an ``attrs`` class. :rtype: dict .. versionadded:: 18.1.0 """ if not isinstance(cls, type): raise TypeError("Passed object must be a class.") attrs = getattr(cls, "__attrs_attrs__", None) if attrs is None: raise NotAnAttrsClassError(f"{cls!r} is not an attrs-decorated class.") return {a.name: a for a in attrs} def validate(inst): """ Validate all attributes on *inst* that have a validator. Leaves all exceptions through. :param inst: Instance of a class with ``attrs`` attributes. """ if _config._run_validators is False: return for a in fields(inst.__class__): v = a.validator if v is not None: v(inst, a, getattr(inst, a.name)) def _is_slot_cls(cls): return "__slots__" in cls.__dict__ def _is_slot_attr(a_name, base_attr_map): """ Check if the attribute name comes from a slot class. """ return a_name in base_attr_map and _is_slot_cls(base_attr_map[a_name]) def _make_init( cls, attrs, pre_init, post_init, frozen, slots, cache_hash, base_attr_map, is_exc, cls_on_setattr, attrs_init, ): has_cls_on_setattr = ( cls_on_setattr is not None and cls_on_setattr is not setters.NO_OP ) if frozen and has_cls_on_setattr: raise ValueError("Frozen classes can't use on_setattr.") needs_cached_setattr = cache_hash or frozen filtered_attrs = [] attr_dict = {} for a in attrs: if not a.init and a.default is NOTHING: continue filtered_attrs.append(a) attr_dict[a.name] = a if a.on_setattr is not None: if frozen is True: raise ValueError("Frozen classes can't use on_setattr.") needs_cached_setattr = True elif has_cls_on_setattr and a.on_setattr is not setters.NO_OP: needs_cached_setattr = True unique_filename = _generate_unique_filename(cls, "init") script, globs, annotations = _attrs_to_init_script( filtered_attrs, frozen, slots, pre_init, post_init, cache_hash, base_attr_map, is_exc, needs_cached_setattr, has_cls_on_setattr, attrs_init, ) if cls.__module__ in sys.modules: # This makes typing.get_type_hints(CLS.__init__) resolve string types. globs.update(sys.modules[cls.__module__].__dict__) globs.update({"NOTHING": NOTHING, "attr_dict": attr_dict}) if needs_cached_setattr: # Save the lookup overhead in __init__ if we need to circumvent # setattr hooks. globs["_cached_setattr_get"] = _obj_setattr.__get__ init = _make_method( "__attrs_init__" if attrs_init else "__init__", script, unique_filename, globs, ) init.__annotations__ = annotations return init def _setattr(attr_name, value_var, has_on_setattr): """ Use the cached object.setattr to set *attr_name* to *value_var*. """ return f"_setattr('{attr_name}', {value_var})" def _setattr_with_converter(attr_name, value_var, has_on_setattr): """ Use the cached object.setattr to set *attr_name* to *value_var*, but run its converter first. """ return "_setattr('%s', %s(%s))" % ( attr_name, _init_converter_pat % (attr_name,), value_var, ) def _assign(attr_name, value, has_on_setattr): """ Unless *attr_name* has an on_setattr hook, use normal assignment. Otherwise relegate to _setattr. """ if has_on_setattr: return _setattr(attr_name, value, True) return f"self.{attr_name} = {value}" def _assign_with_converter(attr_name, value_var, has_on_setattr): """ Unless *attr_name* has an on_setattr hook, use normal assignment after conversion. Otherwise relegate to _setattr_with_converter. """ if has_on_setattr: return _setattr_with_converter(attr_name, value_var, True) return "self.%s = %s(%s)" % ( attr_name, _init_converter_pat % (attr_name,), value_var, ) def _attrs_to_init_script( attrs, frozen, slots, pre_init, post_init, cache_hash, base_attr_map, is_exc, needs_cached_setattr, has_cls_on_setattr, attrs_init, ): """ Return a script of an initializer for *attrs* and a dict of globals. The globals are expected by the generated script. If *frozen* is True, we cannot set the attributes directly so we use a cached ``object.__setattr__``. """ lines = [] if pre_init: lines.append("self.__attrs_pre_init__()") if needs_cached_setattr: lines.append( # Circumvent the __setattr__ descriptor to save one lookup per # assignment. # Note _setattr will be used again below if cache_hash is True "_setattr = _cached_setattr_get(self)" ) if frozen is True: if slots is True: fmt_setter = _setattr fmt_setter_with_converter = _setattr_with_converter else: # Dict frozen classes assign directly to __dict__. # But only if the attribute doesn't come from an ancestor slot # class. # Note _inst_dict will be used again below if cache_hash is True lines.append("_inst_dict = self.__dict__") def fmt_setter(attr_name, value_var, has_on_setattr): if _is_slot_attr(attr_name, base_attr_map): return _setattr(attr_name, value_var, has_on_setattr) return f"_inst_dict['{attr_name}'] = {value_var}" def fmt_setter_with_converter( attr_name, value_var, has_on_setattr ): if has_on_setattr or _is_slot_attr(attr_name, base_attr_map): return _setattr_with_converter( attr_name, value_var, has_on_setattr ) return "_inst_dict['%s'] = %s(%s)" % ( attr_name, _init_converter_pat % (attr_name,), value_var, ) else: # Not frozen. fmt_setter = _assign fmt_setter_with_converter = _assign_with_converter args = [] kw_only_args = [] attrs_to_validate = [] # This is a dictionary of names to validator and converter callables. # Injecting this into __init__ globals lets us avoid lookups. names_for_globals = {} annotations = {"return": None} for a in attrs: if a.validator: attrs_to_validate.append(a) attr_name = a.name has_on_setattr = a.on_setattr is not None or ( a.on_setattr is not setters.NO_OP and has_cls_on_setattr ) # a.alias is set to maybe-mangled attr_name in _ClassBuilder if not # explicitly provided arg_name = a.alias has_factory = isinstance(a.default, Factory) if has_factory and a.default.takes_self: maybe_self = "self" else: maybe_self = "" if a.init is False: if has_factory: init_factory_name = _init_factory_pat % (a.name,) if a.converter is not None: lines.append( fmt_setter_with_converter( attr_name, init_factory_name + f"({maybe_self})", has_on_setattr, ) ) conv_name = _init_converter_pat % (a.name,) names_for_globals[conv_name] = a.converter else: lines.append( fmt_setter( attr_name, init_factory_name + f"({maybe_self})", has_on_setattr, ) ) names_for_globals[init_factory_name] = a.default.factory else: if a.converter is not None: lines.append( fmt_setter_with_converter( attr_name, f"attr_dict['{attr_name}'].default", has_on_setattr, ) ) conv_name = _init_converter_pat % (a.name,) names_for_globals[conv_name] = a.converter else: lines.append( fmt_setter( attr_name, f"attr_dict['{attr_name}'].default", has_on_setattr, ) ) elif a.default is not NOTHING and not has_factory: arg = f"{arg_name}=attr_dict['{attr_name}'].default" if a.kw_only: kw_only_args.append(arg) else: args.append(arg) if a.converter is not None: lines.append( fmt_setter_with_converter( attr_name, arg_name, has_on_setattr ) ) names_for_globals[ _init_converter_pat % (a.name,) ] = a.converter else: lines.append(fmt_setter(attr_name, arg_name, has_on_setattr)) elif has_factory: arg = f"{arg_name}=NOTHING" if a.kw_only: kw_only_args.append(arg) else: args.append(arg) lines.append(f"if {arg_name} is not NOTHING:") init_factory_name = _init_factory_pat % (a.name,) if a.converter is not None: lines.append( " " + fmt_setter_with_converter( attr_name, arg_name, has_on_setattr ) ) lines.append("else:") lines.append( " " + fmt_setter_with_converter( attr_name, init_factory_name + "(" + maybe_self + ")", has_on_setattr, ) ) names_for_globals[ _init_converter_pat % (a.name,) ] = a.converter else: lines.append( " " + fmt_setter(attr_name, arg_name, has_on_setattr) ) lines.append("else:") lines.append( " " + fmt_setter( attr_name, init_factory_name + "(" + maybe_self + ")", has_on_setattr, ) ) names_for_globals[init_factory_name] = a.default.factory else: if a.kw_only: kw_only_args.append(arg_name) else: args.append(arg_name) if a.converter is not None: lines.append( fmt_setter_with_converter( attr_name, arg_name, has_on_setattr ) ) names_for_globals[ _init_converter_pat % (a.name,) ] = a.converter else: lines.append(fmt_setter(attr_name, arg_name, has_on_setattr)) if a.init is True: if a.type is not None and a.converter is None: annotations[arg_name] = a.type elif a.converter is not None: # Try to get the type from the converter. t = _AnnotationExtractor(a.converter).get_first_param_type() if t: annotations[arg_name] = t if attrs_to_validate: # we can skip this if there are no validators. names_for_globals["_config"] = _config lines.append("if _config._run_validators is True:") for a in attrs_to_validate: val_name = "__attr_validator_" + a.name attr_name = "__attr_" + a.name lines.append(f" {val_name}(self, {attr_name}, self.{a.name})") names_for_globals[val_name] = a.validator names_for_globals[attr_name] = a if post_init: lines.append("self.__attrs_post_init__()") # because this is set only after __attrs_post_init__ is called, a crash # will result if post-init tries to access the hash code. This seemed # preferable to setting this beforehand, in which case alteration to # field values during post-init combined with post-init accessing the # hash code would result in silent bugs. if cache_hash: if frozen: if slots: # if frozen and slots, then _setattr defined above init_hash_cache = "_setattr('%s', %s)" else: # if frozen and not slots, then _inst_dict defined above init_hash_cache = "_inst_dict['%s'] = %s" else: init_hash_cache = "self.%s = %s" lines.append(init_hash_cache % (_hash_cache_field, "None")) # For exceptions we rely on BaseException.__init__ for proper # initialization. if is_exc: vals = ",".join(f"self.{a.name}" for a in attrs if a.init) lines.append(f"BaseException.__init__(self, {vals})") args = ", ".join(args) if kw_only_args: args += "%s*, %s" % ( ", " if args else "", # leading comma ", ".join(kw_only_args), # kw_only args ) return ( "def %s(self, %s):\n %s\n" % ( ("__attrs_init__" if attrs_init else "__init__"), args, "\n ".join(lines) if lines else "pass", ), names_for_globals, annotations, ) def _default_init_alias_for(name: str) -> str: """ The default __init__ parameter name for a field. This performs private-name adjustment via leading-unscore stripping, and is the default value of Attribute.alias if not provided. """ return name.lstrip("_") class Attribute: """ *Read-only* representation of an attribute. The class has *all* arguments of `attr.ib` (except for ``factory`` which is only syntactic sugar for ``default=Factory(...)`` plus the following: - ``name`` (`str`): The name of the attribute. - ``alias`` (`str`): The __init__ parameter name of the attribute, after any explicit overrides and default private-attribute-name handling. - ``inherited`` (`bool`): Whether or not that attribute has been inherited from a base class. - ``eq_key`` and ``order_key`` (`typing.Callable` or `None`): The callables that are used for comparing and ordering objects by this attribute, respectively. These are set by passing a callable to `attr.ib`'s ``eq``, ``order``, or ``cmp`` arguments. See also :ref:`comparison customization `. Instances of this class are frequently used for introspection purposes like: - `fields` returns a tuple of them. - Validators get them passed as the first argument. - The :ref:`field transformer ` hook receives a list of them. - The ``alias`` property exposes the __init__ parameter name of the field, with any overrides and default private-attribute handling applied. .. versionadded:: 20.1.0 *inherited* .. versionadded:: 20.1.0 *on_setattr* .. versionchanged:: 20.2.0 *inherited* is not taken into account for equality checks and hashing anymore. .. versionadded:: 21.1.0 *eq_key* and *order_key* .. versionadded:: 22.2.0 *alias* For the full version history of the fields, see `attr.ib`. """ __slots__ = ( "name", "default", "validator", "repr", "eq", "eq_key", "order", "order_key", "hash", "init", "metadata", "type", "converter", "kw_only", "inherited", "on_setattr", "alias", ) def __init__( self, name, default, validator, repr, cmp, # XXX: unused, remove along with other cmp code. hash, init, inherited, metadata=None, type=None, converter=None, kw_only=False, eq=None, eq_key=None, order=None, order_key=None, on_setattr=None, alias=None, ): eq, eq_key, order, order_key = _determine_attrib_eq_order( cmp, eq_key or eq, order_key or order, True ) # Cache this descriptor here to speed things up later. bound_setattr = _obj_setattr.__get__(self) # Despite the big red warning, people *do* instantiate `Attribute` # themselves. bound_setattr("name", name) bound_setattr("default", default) bound_setattr("validator", validator) bound_setattr("repr", repr) bound_setattr("eq", eq) bound_setattr("eq_key", eq_key) bound_setattr("order", order) bound_setattr("order_key", order_key) bound_setattr("hash", hash) bound_setattr("init", init) bound_setattr("converter", converter) bound_setattr( "metadata", ( types.MappingProxyType(dict(metadata)) # Shallow copy if metadata else _empty_metadata_singleton ), ) bound_setattr("type", type) bound_setattr("kw_only", kw_only) bound_setattr("inherited", inherited) bound_setattr("on_setattr", on_setattr) bound_setattr("alias", alias) def __setattr__(self, name, value): raise FrozenInstanceError() @classmethod def from_counting_attr(cls, name, ca, type=None): # type holds the annotated value. deal with conflicts: if type is None: type = ca.type elif ca.type is not None: raise ValueError( "Type annotation and type argument cannot both be present" ) inst_dict = { k: getattr(ca, k) for k in Attribute.__slots__ if k not in ( "name", "validator", "default", "type", "inherited", ) # exclude methods and deprecated alias } return cls( name=name, validator=ca._validator, default=ca._default, type=type, cmp=None, inherited=False, **inst_dict, ) # Don't use attr.evolve since fields(Attribute) doesn't work def evolve(self, **changes): """ Copy *self* and apply *changes*. This works similarly to `attr.evolve` but that function does not work with ``Attribute``. It is mainly meant to be used for `transform-fields`. .. versionadded:: 20.3.0 """ new = copy.copy(self) new._setattrs(changes.items()) return new # Don't use _add_pickle since fields(Attribute) doesn't work def __getstate__(self): """ Play nice with pickle. """ return tuple( getattr(self, name) if name != "metadata" else dict(self.metadata) for name in self.__slots__ ) def __setstate__(self, state): """ Play nice with pickle. """ self._setattrs(zip(self.__slots__, state)) def _setattrs(self, name_values_pairs): bound_setattr = _obj_setattr.__get__(self) for name, value in name_values_pairs: if name != "metadata": bound_setattr(name, value) else: bound_setattr( name, types.MappingProxyType(dict(value)) if value else _empty_metadata_singleton, ) _a = [ Attribute( name=name, default=NOTHING, validator=None, repr=True, cmp=None, eq=True, order=False, hash=(name != "metadata"), init=True, inherited=False, alias=_default_init_alias_for(name), ) for name in Attribute.__slots__ ] Attribute = _add_hash( _add_eq( _add_repr(Attribute, attrs=_a), attrs=[a for a in _a if a.name != "inherited"], ), attrs=[a for a in _a if a.hash and a.name != "inherited"], ) class _CountingAttr: """ Intermediate representation of attributes that uses a counter to preserve the order in which the attributes have been defined. *Internal* data structure of the attrs library. Running into is most likely the result of a bug like a forgotten `@attr.s` decorator. """ __slots__ = ( "counter", "_default", "repr", "eq", "eq_key", "order", "order_key", "hash", "init", "metadata", "_validator", "converter", "type", "kw_only", "on_setattr", "alias", ) __attrs_attrs__ = tuple( Attribute( name=name, alias=_default_init_alias_for(name), default=NOTHING, validator=None, repr=True, cmp=None, hash=True, init=True, kw_only=False, eq=True, eq_key=None, order=False, order_key=None, inherited=False, on_setattr=None, ) for name in ( "counter", "_default", "repr", "eq", "order", "hash", "init", "on_setattr", "alias", ) ) + ( Attribute( name="metadata", alias="metadata", default=None, validator=None, repr=True, cmp=None, hash=False, init=True, kw_only=False, eq=True, eq_key=None, order=False, order_key=None, inherited=False, on_setattr=None, ), ) cls_counter = 0 def __init__( self, default, validator, repr, cmp, hash, init, converter, metadata, type, kw_only, eq, eq_key, order, order_key, on_setattr, alias, ): _CountingAttr.cls_counter += 1 self.counter = _CountingAttr.cls_counter self._default = default self._validator = validator self.converter = converter self.repr = repr self.eq = eq self.eq_key = eq_key self.order = order self.order_key = order_key self.hash = hash self.init = init self.metadata = metadata self.type = type self.kw_only = kw_only self.on_setattr = on_setattr self.alias = alias def validator(self, meth): """ Decorator that adds *meth* to the list of validators. Returns *meth* unchanged. .. versionadded:: 17.1.0 """ if self._validator is None: self._validator = meth else: self._validator = and_(self._validator, meth) return meth def default(self, meth): """ Decorator that allows to set the default for an attribute. Returns *meth* unchanged. :raises DefaultAlreadySetError: If default has been set before. .. versionadded:: 17.1.0 """ if self._default is not NOTHING: raise DefaultAlreadySetError() self._default = Factory(meth, takes_self=True) return meth _CountingAttr = _add_eq(_add_repr(_CountingAttr)) class Factory: """ Stores a factory callable. If passed as the default value to `attrs.field`, the factory is used to generate a new value. :param callable factory: A callable that takes either none or exactly one mandatory positional argument depending on *takes_self*. :param bool takes_self: Pass the partially initialized instance that is being initialized as a positional argument. .. versionadded:: 17.1.0 *takes_self* """ __slots__ = ("factory", "takes_self") def __init__(self, factory, takes_self=False): """ `Factory` is part of the default machinery so if we want a default value here, we have to implement it ourselves. """ self.factory = factory self.takes_self = takes_self def __getstate__(self): """ Play nice with pickle. """ return tuple(getattr(self, name) for name in self.__slots__) def __setstate__(self, state): """ Play nice with pickle. """ for name, value in zip(self.__slots__, state): setattr(self, name, value) _f = [ Attribute( name=name, default=NOTHING, validator=None, repr=True, cmp=None, eq=True, order=False, hash=True, init=True, inherited=False, ) for name in Factory.__slots__ ] Factory = _add_hash(_add_eq(_add_repr(Factory, attrs=_f), attrs=_f), attrs=_f) def make_class(name, attrs, bases=(object,), **attributes_arguments): """ A quick way to create a new class called *name* with *attrs*. :param str name: The name for the new class. :param attrs: A list of names or a dictionary of mappings of names to attributes. The order is deduced from the order of the names or attributes inside *attrs*. Otherwise the order of the definition of the attributes is used. :type attrs: `list` or `dict` :param tuple bases: Classes that the new class will subclass. :param attributes_arguments: Passed unmodified to `attr.s`. :return: A new class with *attrs*. :rtype: type .. versionadded:: 17.1.0 *bases* .. versionchanged:: 18.1.0 If *attrs* is ordered, the order is retained. """ if isinstance(attrs, dict): cls_dict = attrs elif isinstance(attrs, (list, tuple)): cls_dict = {a: attrib() for a in attrs} else: raise TypeError("attrs argument must be a dict or a list.") pre_init = cls_dict.pop("__attrs_pre_init__", None) post_init = cls_dict.pop("__attrs_post_init__", None) user_init = cls_dict.pop("__init__", None) body = {} if pre_init is not None: body["__attrs_pre_init__"] = pre_init if post_init is not None: body["__attrs_post_init__"] = post_init if user_init is not None: body["__init__"] = user_init type_ = types.new_class(name, bases, {}, lambda ns: ns.update(body)) # For pickling to work, the __module__ variable needs to be set to the # frame where the class is created. Bypass this step in environments where # sys._getframe is not defined (Jython for example) or sys._getframe is not # defined for arguments greater than 0 (IronPython). try: type_.__module__ = sys._getframe(1).f_globals.get( "__name__", "__main__" ) except (AttributeError, ValueError): pass # We do it here for proper warnings with meaningful stacklevel. cmp = attributes_arguments.pop("cmp", None) ( attributes_arguments["eq"], attributes_arguments["order"], ) = _determine_attrs_eq_order( cmp, attributes_arguments.get("eq"), attributes_arguments.get("order"), True, ) return _attrs(these=cls_dict, **attributes_arguments)(type_) # These are required by within this module so we define them here and merely # import into .validators / .converters. @attrs(slots=True, hash=True) class _AndValidator: """ Compose many validators to a single one. """ _validators = attrib() def __call__(self, inst, attr, value): for v in self._validators: v(inst, attr, value) def and_(*validators): """ A validator that composes multiple validators into one. When called on a value, it runs all wrapped validators. :param callables validators: Arbitrary number of validators. .. versionadded:: 17.1.0 """ vals = [] for validator in validators: vals.extend( validator._validators if isinstance(validator, _AndValidator) else [validator] ) return _AndValidator(tuple(vals)) def pipe(*converters): """ A converter that composes multiple converters into one. When called on a value, it runs all wrapped converters, returning the *last* value. Type annotations will be inferred from the wrapped converters', if they have any. :param callables converters: Arbitrary number of converters. .. versionadded:: 20.1.0 """ def pipe_converter(val): for converter in converters: val = converter(val) return val if not converters: # If the converter list is empty, pipe_converter is the identity. A = typing.TypeVar("A") pipe_converter.__annotations__ = {"val": A, "return": A} else: # Get parameter type from first converter. t = _AnnotationExtractor(converters[0]).get_first_param_type() if t: pipe_converter.__annotations__["val"] = t # Get return type from last converter. rt = _AnnotationExtractor(converters[-1]).get_return_type() if rt: pipe_converter.__annotations__["return"] = rt return pipe_converter