%global _empty_manifest_terminate_build 0 Name: python-methoddispatch Version: 3.0.2 Release: 1 Summary: singledispatch decorator for class methods. License: BSD URL: https://github.com/seequent/methoddispatch Source0: https://mirrors.nju.edu.cn/pypi/web/packages/6d/df/8cf2717fd7b13a8619e1dd491ed779a70d38b9912a43bfe9db5cffe616cc/methoddispatch-3.0.2.tar.gz BuildArch: noarch %description |Build Status| Python 3.4 added the ``singledispatch`` decorator to the ``functools`` standard library module. This library adds this functionality to instance methods. **Deprecation Warning** ``methoddispatch`` 2 and earlier worked on standard functions too, and could be used in place of ``functools.singledispatch``. Version 3 no longer supports this functionality as it breaks the Zen of Python "There should be only one way to do something". Doing this also paved the way to support a better API and deprecate the ``methoddispatch.register`` function. To define a generic method , decorate it with the ``@singledispatch`` decorator. Note that the dispatch happens on the type of the first argument, create your function accordingly. To add overloaded implementations to the function, use the ``register()`` attribute of the generic function. It is a decorator, taking a type parameter and decorating a function implementing the operation for that type. The ``register()`` attribute returns the undecorated function which enables decorator stacking, pickling, as well as creating unit tests for each variant independently >>> from methoddispatch import singledispatch, register, SingleDispatch >>> from decimal import Decimal >>> class MyClass(SingleDispatch): The ``register()`` attribute only works inside a class statement, relying on ``SingleDispatch.__init_subclass__`` to create the actual dispatch table. This also means that (unlike functools.singledispatch) two methods with the same name cannot be registered as only the last one will be in the class dictionary. Functions not defined in the class can be registered using the ``add_overload`` attribute. >>> def nothing(obj, arg, verbose=False): >>> MyClass.fun.add_overload(type(None), nothing) When called, the generic function dispatches on the type of the first argument >>> a = MyClass() >>> a.fun("Hello, world.") Hello, world. >>> a.fun("test.", verbose=True) Let me just say, test. >>> a.fun(42, verbose=True) Strength in numbers, eh? 42 >>> a.fun(['spam', 'spam', 'eggs', 'spam'], verbose=True) Enumerate this: 0 spam 1 spam 2 eggs 3 spam >>> a.fun(None) Nothing. >>> a.fun(1.23) 0.615 Where there is no registered implementation for a specific type, its method resolution order is used to find a more generic implementation. The original function decorated with ``@singledispatch`` is registered for the base ``object`` type, which means it is used if no better implementation is found. To check which implementation will the generic function choose for a given type, use the ``dispatch()`` attribute >>> a.fun.dispatch(float) >>> a.fun.dispatch(dict) # note: default implementation To access all registered implementations, use the read-only ``registry`` attribute >>> a.fun.registry.keys() dict_keys([, , , , , ]) >>> a.fun.registry[float] >>> a.fun.registry[object] Subclasses can extend the type registry of the function on the base class with their own overrides. The ``SingleDispatch`` mixin class ensures that each subclass has it's own independant copy of the dispatch registry >>> class SubClass(MyClass): >>> s = SubClass() >>> s.fun('hello') str >>> b = MyClass() >>> b.fun('hello') hello Method overrides do not need to provide the ``register`` decorator again to be used in the dispatch of ``fun`` >>> class SubClass2(MyClass): >>> s = SubClass2() >>> s.fun(1) subclass int However, providing the register decorator with the same type will also work. Decorating a method override with a different type (not a good idea) will register the different type and leave the base-class handler in place for the orginal type. Method overrides can be specified on individual instances if necessary >>> def fun_str(obj, arg, verbose=False): >>> b = MyClass() >>> b.fun.register(str, fun_str) >>> b.fun('hello') str >>> b2 = MyClass() >>> b2.fun('hello') hello In Python 3.6 and later, for functions annotated with types, the decorator will infer the type of the first argument automatically as shown below >>> class MyClassAnno(SingleDispatch): >>> class SubClassAnno(MyClassAnno): In Python 3.5 and earlier, the ``SingleDispatch`` class uses a meta-class ``SingleDispatchMeta`` to manage the dispatch registries. However in Python 3.6 and later the ``__init_subclass__`` method is used instead. If your class also inherits from an ABC interface you can use the ``SingleDispatchABCMeta`` metaclass in Python 3.5 and earlier. Finally, accessing the method ``fun`` via a class will use the dispatch registry for that class >>> SubClass2.fun(s, 1) subclass int >>> MyClass.fun(s, 1) 1 """ %package -n python3-methoddispatch Summary: singledispatch decorator for class methods. Provides: python-methoddispatch BuildRequires: python3-devel BuildRequires: python3-setuptools BuildRequires: python3-pip %description -n python3-methoddispatch |Build Status| Python 3.4 added the ``singledispatch`` decorator to the ``functools`` standard library module. This library adds this functionality to instance methods. **Deprecation Warning** ``methoddispatch`` 2 and earlier worked on standard functions too, and could be used in place of ``functools.singledispatch``. Version 3 no longer supports this functionality as it breaks the Zen of Python "There should be only one way to do something". Doing this also paved the way to support a better API and deprecate the ``methoddispatch.register`` function. To define a generic method , decorate it with the ``@singledispatch`` decorator. Note that the dispatch happens on the type of the first argument, create your function accordingly. To add overloaded implementations to the function, use the ``register()`` attribute of the generic function. It is a decorator, taking a type parameter and decorating a function implementing the operation for that type. The ``register()`` attribute returns the undecorated function which enables decorator stacking, pickling, as well as creating unit tests for each variant independently >>> from methoddispatch import singledispatch, register, SingleDispatch >>> from decimal import Decimal >>> class MyClass(SingleDispatch): The ``register()`` attribute only works inside a class statement, relying on ``SingleDispatch.__init_subclass__`` to create the actual dispatch table. This also means that (unlike functools.singledispatch) two methods with the same name cannot be registered as only the last one will be in the class dictionary. Functions not defined in the class can be registered using the ``add_overload`` attribute. >>> def nothing(obj, arg, verbose=False): >>> MyClass.fun.add_overload(type(None), nothing) When called, the generic function dispatches on the type of the first argument >>> a = MyClass() >>> a.fun("Hello, world.") Hello, world. >>> a.fun("test.", verbose=True) Let me just say, test. >>> a.fun(42, verbose=True) Strength in numbers, eh? 42 >>> a.fun(['spam', 'spam', 'eggs', 'spam'], verbose=True) Enumerate this: 0 spam 1 spam 2 eggs 3 spam >>> a.fun(None) Nothing. >>> a.fun(1.23) 0.615 Where there is no registered implementation for a specific type, its method resolution order is used to find a more generic implementation. The original function decorated with ``@singledispatch`` is registered for the base ``object`` type, which means it is used if no better implementation is found. To check which implementation will the generic function choose for a given type, use the ``dispatch()`` attribute >>> a.fun.dispatch(float) >>> a.fun.dispatch(dict) # note: default implementation To access all registered implementations, use the read-only ``registry`` attribute >>> a.fun.registry.keys() dict_keys([, , , , , ]) >>> a.fun.registry[float] >>> a.fun.registry[object] Subclasses can extend the type registry of the function on the base class with their own overrides. The ``SingleDispatch`` mixin class ensures that each subclass has it's own independant copy of the dispatch registry >>> class SubClass(MyClass): >>> s = SubClass() >>> s.fun('hello') str >>> b = MyClass() >>> b.fun('hello') hello Method overrides do not need to provide the ``register`` decorator again to be used in the dispatch of ``fun`` >>> class SubClass2(MyClass): >>> s = SubClass2() >>> s.fun(1) subclass int However, providing the register decorator with the same type will also work. Decorating a method override with a different type (not a good idea) will register the different type and leave the base-class handler in place for the orginal type. Method overrides can be specified on individual instances if necessary >>> def fun_str(obj, arg, verbose=False): >>> b = MyClass() >>> b.fun.register(str, fun_str) >>> b.fun('hello') str >>> b2 = MyClass() >>> b2.fun('hello') hello In Python 3.6 and later, for functions annotated with types, the decorator will infer the type of the first argument automatically as shown below >>> class MyClassAnno(SingleDispatch): >>> class SubClassAnno(MyClassAnno): In Python 3.5 and earlier, the ``SingleDispatch`` class uses a meta-class ``SingleDispatchMeta`` to manage the dispatch registries. However in Python 3.6 and later the ``__init_subclass__`` method is used instead. If your class also inherits from an ABC interface you can use the ``SingleDispatchABCMeta`` metaclass in Python 3.5 and earlier. Finally, accessing the method ``fun`` via a class will use the dispatch registry for that class >>> SubClass2.fun(s, 1) subclass int >>> MyClass.fun(s, 1) 1 """ %package help Summary: Development documents and examples for methoddispatch Provides: python3-methoddispatch-doc %description help |Build Status| Python 3.4 added the ``singledispatch`` decorator to the ``functools`` standard library module. This library adds this functionality to instance methods. **Deprecation Warning** ``methoddispatch`` 2 and earlier worked on standard functions too, and could be used in place of ``functools.singledispatch``. Version 3 no longer supports this functionality as it breaks the Zen of Python "There should be only one way to do something". Doing this also paved the way to support a better API and deprecate the ``methoddispatch.register`` function. To define a generic method , decorate it with the ``@singledispatch`` decorator. Note that the dispatch happens on the type of the first argument, create your function accordingly. To add overloaded implementations to the function, use the ``register()`` attribute of the generic function. It is a decorator, taking a type parameter and decorating a function implementing the operation for that type. The ``register()`` attribute returns the undecorated function which enables decorator stacking, pickling, as well as creating unit tests for each variant independently >>> from methoddispatch import singledispatch, register, SingleDispatch >>> from decimal import Decimal >>> class MyClass(SingleDispatch): The ``register()`` attribute only works inside a class statement, relying on ``SingleDispatch.__init_subclass__`` to create the actual dispatch table. This also means that (unlike functools.singledispatch) two methods with the same name cannot be registered as only the last one will be in the class dictionary. Functions not defined in the class can be registered using the ``add_overload`` attribute. >>> def nothing(obj, arg, verbose=False): >>> MyClass.fun.add_overload(type(None), nothing) When called, the generic function dispatches on the type of the first argument >>> a = MyClass() >>> a.fun("Hello, world.") Hello, world. >>> a.fun("test.", verbose=True) Let me just say, test. >>> a.fun(42, verbose=True) Strength in numbers, eh? 42 >>> a.fun(['spam', 'spam', 'eggs', 'spam'], verbose=True) Enumerate this: 0 spam 1 spam 2 eggs 3 spam >>> a.fun(None) Nothing. >>> a.fun(1.23) 0.615 Where there is no registered implementation for a specific type, its method resolution order is used to find a more generic implementation. The original function decorated with ``@singledispatch`` is registered for the base ``object`` type, which means it is used if no better implementation is found. To check which implementation will the generic function choose for a given type, use the ``dispatch()`` attribute >>> a.fun.dispatch(float) >>> a.fun.dispatch(dict) # note: default implementation To access all registered implementations, use the read-only ``registry`` attribute >>> a.fun.registry.keys() dict_keys([, , , , , ]) >>> a.fun.registry[float] >>> a.fun.registry[object] Subclasses can extend the type registry of the function on the base class with their own overrides. The ``SingleDispatch`` mixin class ensures that each subclass has it's own independant copy of the dispatch registry >>> class SubClass(MyClass): >>> s = SubClass() >>> s.fun('hello') str >>> b = MyClass() >>> b.fun('hello') hello Method overrides do not need to provide the ``register`` decorator again to be used in the dispatch of ``fun`` >>> class SubClass2(MyClass): >>> s = SubClass2() >>> s.fun(1) subclass int However, providing the register decorator with the same type will also work. Decorating a method override with a different type (not a good idea) will register the different type and leave the base-class handler in place for the orginal type. Method overrides can be specified on individual instances if necessary >>> def fun_str(obj, arg, verbose=False): >>> b = MyClass() >>> b.fun.register(str, fun_str) >>> b.fun('hello') str >>> b2 = MyClass() >>> b2.fun('hello') hello In Python 3.6 and later, for functions annotated with types, the decorator will infer the type of the first argument automatically as shown below >>> class MyClassAnno(SingleDispatch): >>> class SubClassAnno(MyClassAnno): In Python 3.5 and earlier, the ``SingleDispatch`` class uses a meta-class ``SingleDispatchMeta`` to manage the dispatch registries. However in Python 3.6 and later the ``__init_subclass__`` method is used instead. If your class also inherits from an ABC interface you can use the ``SingleDispatchABCMeta`` metaclass in Python 3.5 and earlier. Finally, accessing the method ``fun`` via a class will use the dispatch registry for that class >>> SubClass2.fun(s, 1) subclass int >>> MyClass.fun(s, 1) 1 """ %prep %autosetup -n methoddispatch-3.0.2 %build %py3_build %install %py3_install install -d -m755 %{buildroot}/%{_pkgdocdir} if [ -d doc ]; then cp -arf doc %{buildroot}/%{_pkgdocdir}; fi if [ -d docs ]; then cp -arf docs %{buildroot}/%{_pkgdocdir}; fi if [ -d example ]; then cp -arf example %{buildroot}/%{_pkgdocdir}; fi if [ -d examples ]; then cp -arf examples %{buildroot}/%{_pkgdocdir}; fi pushd %{buildroot} if [ -d usr/lib ]; then find usr/lib -type f -printf "/%h/%f\n" >> filelist.lst fi if [ -d usr/lib64 ]; then find usr/lib64 -type f -printf "/%h/%f\n" >> filelist.lst fi if [ -d usr/bin ]; then find usr/bin -type f -printf "/%h/%f\n" >> filelist.lst fi if [ -d usr/sbin ]; then find usr/sbin -type f -printf "/%h/%f\n" >> filelist.lst fi touch doclist.lst if [ -d usr/share/man ]; then find usr/share/man -type f -printf "/%h/%f.gz\n" >> doclist.lst fi popd mv %{buildroot}/filelist.lst . mv %{buildroot}/doclist.lst . %files -n python3-methoddispatch -f filelist.lst %dir %{python3_sitelib}/* %files help -f doclist.lst %{_docdir}/* %changelog * Fri May 05 2023 Python_Bot - 3.0.2-1 - Package Spec generated