The accepted answer is very good, and the one I recommend whenever possible. Unfortunately, such an abstraction layer is tedious to implement and it doesn't solve the whole problem.
- You have to use the pimpl idiom religiously to keep any and all WinAPI types out of the abstraction layer's header files. The Windows headers should be included only in implementation (
.cpp) files and never in headers.
- In practice, you end up having to make a lot of your own classes that capture essentially the same information as an underlying WinAPI type (e.g., a LOGFONT) because the client of the abstraction interface needs to pass and receive it. You end up needing a lot of boilerplate code to translate between your abstraction layer types and the WinAPI types.
- The big refactoring necessary to introduce the abstraction layer can be a lot of work in a legacy codebase, especially if that code is shared among many projects.
The implementation of the abstraction layer requires including windows headers. Suppose one of the platform-independent types you introduced to enable an abstraction layer has a method called
GetFont. The platform-independent code that relies on it will see
GetFont because there will be no mention of
<windows.h> in that translation unit. But the implementation file (the
.cpp file) that implements the abstraction layer on Windows will have a conflict with the
GetFont preprocessor macro because it must include
<windows.h>. So using pimpl limits the scope of the problem, but it does not solve it completely.
What I've started doing, both in newer code which uses good abstraction layers as well as older code that wasn't good about preventing platform-specific leaks into the namespace, is to create wrappers for the WinAPI headers. I replace all the
#include <windows.h> lines in the code I control with
#include "apiwrappers/windows.h", which is a reference to a file that looks roughly like this:
// Prevents Windows headers from defining macros called min and max, which
// conflict with identifiers in the C++ standard library.
// Distinguishes between different types of handles so that we get better
// error checking at compile time.
#include <windows.h> // the "real" <windows.h>
// Lowercase far and near are perfectly reasonable names for local variables
// and parameters, so we don't want redefinitions of them.
// But lots of other Win32 headers use FAR and NEAR, which are typically
// defined to far and near. We need them to be empty.
// Windows defines macros to select between the "ANSI" and "wide" versions
// of many API functions (e.g., GetMessage macro expands to GetMessageA or
// GetMessageW). We undefine many of these here to avoid naming collisions.
// Call the specific -W functions explicitly instead of relying on these
I'm growing the list of
#undefs as I resolve collisions. I don't have a comprehensive one to offer.
For other WinAPI headers, I do something similar, but the rest of them are much simpler.