"types" --- Dynamic type creation and names for built-in types
**************************************************************

**Source code:** Lib/types.py

======================================================================

此模块定义了一些工具函数，用于协助动态创建新的类型。

It also defines names for some object types that are used by the
standard Python interpreter, but not exposed as builtins like "int" or
"str" are.

Finally, it provides some additional type-related utility classes and
functions that are not fundamental enough to be builtins.


Dynamic Type Creation
=====================

types.new_class(name, bases=(), kwds=None, exec_body=None)

   Creates a class object dynamically using the appropriate metaclass.

   The first three arguments are the components that make up a class
   definition header: the class name, the base classes (in order), the
   keyword arguments (such as "metaclass").

   The *exec_body* argument is a callback that is used to populate the
   freshly created class namespace. It should accept the class
   namespace as its sole argument and update the namespace directly
   with the class contents. If no callback is provided, it has the
   same effect as passing in "lambda ns: ns".

   3.3 版新加入.

types.prepare_class(name, bases=(), kwds=None)

   Calculates the appropriate metaclass and creates the class
   namespace.

   The arguments are the components that make up a class definition
   header: the class name, the base classes (in order) and the keyword
   arguments (such as "metaclass").

   The return value is a 3-tuple: "metaclass, namespace, kwds"

   *metaclass* is the appropriate metaclass, *namespace* is the
   prepared class namespace and *kwds* is an updated copy of the
   passed in *kwds* argument with any "'metaclass'" entry removed. If
   no *kwds* argument is passed in, this will be an empty dict.

   3.3 版新加入.

   3.6 版更變: The default value for the "namespace" element of the
   returned tuple has changed.  Now an insertion-order-preserving
   mapping is used when the metaclass does not have a "__prepare__"
   method.

也參考:

  Metaclasses
     Full details of the class creation process supported by these
     functions

  **PEP 3115** - Metaclasses in Python 3000
     Introduced the "__prepare__" namespace hook

types.resolve_bases(bases)

   Resolve MRO entries dynamically as specified by **PEP 560**.

   This function looks for items in *bases* that are not instances of
   "type", and returns a tuple where each such object that has an
   "__mro_entries__" method is replaced with an unpacked result of
   calling this method.  If a *bases* item is an instance of "type",
   or it doesn't have an "__mro_entries__" method, then it is included
   in the return tuple unchanged.

   3.7 版新加入.

也參考: **PEP 560** - Core support for typing module and generic
  types


Standard Interpreter Types
==========================

This module provides names for many of the types that are required to
implement a Python interpreter. It deliberately avoids including some
of the types that arise only incidentally during processing such as
the "listiterator" type.

Typical use of these names is for "isinstance()" or "issubclass()"
checks.

如果你要实例化这些类型中的任何一种，请注意其签名在不同 Python 版本之间
可能出现变化。

Standard names are defined for the following types:

types.FunctionType
types.LambdaType

   The type of user-defined functions and functions created by
   "lambda"  expressions.

types.GeneratorType

   The type of *generator*-iterator objects, created by generator
   functions.

types.CoroutineType

   The type of *coroutine* objects, created by "async def" functions.

   3.5 版新加入.

types.AsyncGeneratorType

   The type of *asynchronous generator*-iterator objects, created by
   asynchronous generator functions.

   3.6 版新加入.

types.CodeType

   The type for code objects such as returned by "compile()".

types.CellType

   单元对象的类型：这种对象被用作函数中自由变量的容器。

   3.8 版新加入.

types.MethodType

   The type of methods of user-defined class instances.

types.BuiltinFunctionType
types.BuiltinMethodType

   The type of built-in functions like "len()" or "sys.exit()", and
   methods of built-in classes.  (Here, the term "built-in" means
   "written in C".)

types.WrapperDescriptorType

   The type of methods of some built-in data types and base classes
   such as "object.__init__()" or "object.__lt__()".

   3.7 版新加入.

types.MethodWrapperType

   The type of *bound* methods of some built-in data types and base
   classes. For example it is the type of "object().__str__".

   3.7 版新加入.

types.MethodDescriptorType

   The type of methods of some built-in data types such as
   "str.join()".

   3.7 版新加入.

types.ClassMethodDescriptorType

   The type of *unbound* class methods of some built-in data types
   such as "dict.__dict__['fromkeys']".

   3.7 版新加入.

class types.ModuleType(name, doc=None)

   The type of *modules*. Constructor takes the name of the module to
   be created and optionally its *docstring*.

   備註: Use "importlib.util.module_from_spec()" to create a new
     module if you wish to set the various import-controlled
     attributes.

   __doc__

      The *docstring* of the module. Defaults to "None".

   __loader__

      The *loader* which loaded the module. Defaults to "None".

      3.4 版更變: Defaults to "None". Previously the attribute was
      optional.

   __name__

      The name of the module.

   __package__

      Which *package* a module belongs to. If the module is top-level
      (i.e. not a part of any specific package) then the attribute
      should be set to "''", else it should be set to the name of the
      package (which can be "__name__" if the module is a package
      itself). Defaults to "None".

      3.4 版更變: Defaults to "None". Previously the attribute was
      optional.

class types.TracebackType(tb_next, tb_frame, tb_lasti, tb_lineno)

   The type of traceback objects such as found in "sys.exc_info()[2]".

   See the language reference for details of the available attributes
   and operations, and guidance on creating tracebacks dynamically.

types.FrameType

   The type of frame objects such as found in "tb.tb_frame" if "tb" is
   a traceback object.

   See the language reference for details of the available attributes
   and operations.

types.GetSetDescriptorType

   The type of objects defined in extension modules with
   "PyGetSetDef", such as "FrameType.f_locals" or
   "array.array.typecode".  This type is used as descriptor for object
   attributes; it has the same purpose as the "property" type, but for
   classes defined in extension modules.

types.MemberDescriptorType

   The type of objects defined in extension modules with
   "PyMemberDef", such as "datetime.timedelta.days".  This type is
   used as descriptor for simple C data members which use standard
   conversion functions; it has the same purpose as the "property"
   type, but for classes defined in extension modules.

   **CPython implementation detail:** In other implementations of
   Python, this type may be identical to "GetSetDescriptorType".

class types.MappingProxyType(mapping)

   Read-only proxy of a mapping. It provides a dynamic view on the
   mapping's entries, which means that when the mapping changes, the
   view reflects these changes.

   3.3 版新加入.

   key in proxy

      Return "True" if the underlying mapping has a key *key*, else
      "False".

   proxy[key]

      Return the item of the underlying mapping with key *key*.
      Raises a "KeyError" if *key* is not in the underlying mapping.

   iter(proxy)

      Return an iterator over the keys of the underlying mapping.
      This is a shortcut for "iter(proxy.keys())".

   len(proxy)

      Return the number of items in the underlying mapping.

   copy()

      Return a shallow copy of the underlying mapping.

   get(key[, default])

      Return the value for *key* if *key* is in the underlying
      mapping, else *default*.  If *default* is not given, it defaults
      to "None", so that this method never raises a "KeyError".

   items()

      Return a new view of the underlying mapping's items ("(key,
      value)" pairs).

   keys()

      Return a new view of the underlying mapping's keys.

   values()

      Return a new view of the underlying mapping's values.


Additional Utility Classes and Functions
========================================

class types.SimpleNamespace

   A simple "object" subclass that provides attribute access to its
   namespace, as well as a meaningful repr.

   Unlike "object", with "SimpleNamespace" you can add and remove
   attributes.  If a "SimpleNamespace" object is initialized with
   keyword arguments, those are directly added to the underlying
   namespace.

   The type is roughly equivalent to the following code:

      class SimpleNamespace:
          def __init__(self, /, **kwargs):
              self.__dict__.update(kwargs)

          def __repr__(self):
              keys = sorted(self.__dict__)
              items = ("{}={!r}".format(k, self.__dict__[k]) for k in keys)
              return "{}({})".format(type(self).__name__, ", ".join(items))

          def __eq__(self, other):
              return self.__dict__ == other.__dict__

   "SimpleNamespace" may be useful as a replacement for "class NS:
   pass". However, for a structured record type use "namedtuple()"
   instead.

   3.3 版新加入.

types.DynamicClassAttribute(fget=None, fset=None, fdel=None, doc=None)

   Route attribute access on a class to __getattr__.

   This is a descriptor, used to define attributes that act
   differently when accessed through an instance and through a class.
   Instance access remains normal, but access to an attribute through
   a class will be routed to the class's __getattr__ method; this is
   done by raising AttributeError.

   This allows one to have properties active on an instance, and have
   virtual attributes on the class with the same name (see Enum for an
   example).

   3.4 版新加入.


Coroutine Utility Functions
===========================

types.coroutine(gen_func)

   This function transforms a *generator* function into a *coroutine
   function* which returns a generator-based coroutine. The generator-
   based coroutine is still a *generator iterator*, but is also
   considered to be a *coroutine* object and is *awaitable*.  However,
   it may not necessarily implement the "__await__()" method.

   If *gen_func* is a generator function, it will be modified in-
   place.

   If *gen_func* is not a generator function, it will be wrapped. If
   it returns an instance of "collections.abc.Generator", the instance
   will be wrapped in an *awaitable* proxy object.  All other types of
   objects will be returned as is.

   3.5 版新加入.
