Extending
=========

Each ``attrs``-decorated class has a ``__attrs_attrs__`` class attribute.
It is a tuple of `attr.Attribute` carrying meta-data about each attribute.

So it is fairly simple to build your own decorators on top of ``attrs``:

.. doctest::

   >>> import attr
   >>> def print_attrs(cls):
   ...     print(cls.__attrs_attrs__)
   ...     return cls
   >>> @print_attrs
   ... @attr.s
   ... class C(object):
   ...     a = attr.ib()
   (Attribute(name='a', default=NOTHING, validator=None, repr=True, eq=True, order=True, hash=None, init=True, metadata=mappingproxy({}), type=None, converter=None, kw_only=False),)


.. warning::

   The `attr.s` decorator **must** be applied first because it puts ``__attrs_attrs__`` in place!
   That means that is has to come *after* your decorator because::

      @a
      @b
      def f():
         pass

   is just `syntactic sugar <https://en.wikipedia.org/wiki/Syntactic_sugar>`_ for::

      def original_f():
         pass

      f = a(b(original_f))


Wrapping the Decorator
----------------------

A more elegant way can be to wrap ``attrs`` altogether and build a class `DSL <https://en.wikipedia.org/wiki/Domain-specific_language>`_ on top of it.

An example for that is the package `environ-config <https://github.com/hynek/environ-config>`_ that uses ``attrs`` under the hood to define environment-based configurations declaratively without exposing ``attrs`` APIs at all.


Types
-----

``attrs`` offers two ways of attaching type information to attributes:

- `PEP 526 <https://www.python.org/dev/peps/pep-0526/>`_ annotations on Python 3.6 and later,
- and the *type* argument to `attr.ib`.

This information is available to you:

.. doctest::

   >>> import attr
   >>> @attr.s
   ... class C(object):
   ...     x: int = attr.ib()
   ...     y = attr.ib(type=str)
   >>> attr.fields(C).x.type
   <class 'int'>
   >>> attr.fields(C).y.type
   <class 'str'>

Currently, ``attrs`` doesn't do anything with this information but it's very useful if you'd like to write your own validators or serializers!


.. _extending_metadata:

Metadata
--------

If you're the author of a third-party library with ``attrs`` integration, you may want to take advantage of attribute metadata.

Here are some tips for effective use of metadata:

- Try making your metadata keys and values immutable.
  This keeps the entire ``Attribute`` instances immutable too.

- To avoid metadata key collisions, consider exposing your metadata keys from your modules.::

    from mylib import MY_METADATA_KEY

    @attr.s
    class C(object):
      x = attr.ib(metadata={MY_METADATA_KEY: 1})

  Metadata should be composable, so consider supporting this approach even if you decide implementing your metadata in one of the following ways.

- Expose ``attr.ib`` wrappers for your specific metadata.
  This is a more graceful approach if your users don't require metadata from other libraries.

  .. doctest::

    >>> MY_TYPE_METADATA = '__my_type_metadata'
    >>>
    >>> def typed(
    ...     cls, default=attr.NOTHING, validator=None, repr=True,
    ...     eq=True, order=None, hash=None, init=True, metadata={},
    ...     type=None, converter=None
    ... ):
    ...     metadata = dict() if not metadata else metadata
    ...     metadata[MY_TYPE_METADATA] = cls
    ...     return attr.ib(
    ...         default=default, validator=validator, repr=repr,
    ...         eq=eq, order=order, hash=hash, init=init,
    ...         metadata=metadata, type=type, converter=converter
    ...     )
    >>>
    >>> @attr.s
    ... class C(object):
    ...     x = typed(int, default=1, init=False)
    >>> attr.fields(C).x.metadata[MY_TYPE_METADATA]
    <class 'int'>
