As the documentation indicates, the
OverloadAttribute is for use by languages that do not support overloading. For example, consider writing Windows Runtime code at the ABI layer using IDL and C++ (not C++/CX). In IDL, you cannot overload interface functions: each function of an interface must have a different name.
Let's take a look at an example. Here's the definition of
IUriRuntimeClassFactory from the Windows.Foundation.idl file, which you can find in the Windows 8 SDK:
interface IUriRuntimeClassFactory : IInspectable
[overload("CreateUri")] HRESULT CreateUri([in] HSTRING uri, [out] [retval] Windows.Foundation.Uri** instance);
[overload("CreateUri")] HRESULT CreateWithRelativeUri([in] HSTRING baseUri, [in] HSTRING relativeUri, [out] [retval] Windows.Foundation.Uri** instance);
The two interface functions are declared with different names in IDL. Both functions are annotated with the IDL
overload attribute. This attribute tells the IDL compiler that both of these member functions are logically overloads of
When the midlrt IDL compiler generates a WinMD file from this IDL, it will swap the overload name and the interface function name so that in metadata, both of these interface functions will have the name
CreateUri, and both functions will have the
OverloadAttribute applied to them with the original name (
CreateUri for the first, and
CreateWithRelativeUri for the second). You can observe this by taking a look at the metadata in the reference Windows.winmd using ildasm.
When you generate IDL from a WinMD, the reverse transformation happens: interface functions that are annotated with an
OverloadAttribute are named using the name provided by that attribute. This allows lossless round-tripping between IDL and WinMD.