Tor Lillqvist Hans Breuer Note that this document is not really maintained in a serious fashion. Lots of information here might be misleading or outdated. You have been warned. General ======= For prebuilt binaries (DLLs and EXEs) and developer packages (headers, import libraries) of GLib, Pango, GTK+ etc for Windows, go to http://www.gtk.org/download-windows.html . They are for "native" Windows meaning they use the Win32 API and Microsoft C runtime library only. No POSIX (Unix) emulation layer like Cygwin in involved. To build GLib on Win32, you can use either gcc ("mingw") or the Microsoft compiler and tools. For the latter, MSVC6 and later have been used successfully. Also the Digital Mars C/C++ compiler has reportedly been used. You can also cross-compile GLib for Windows from Linux using the cross-compiling mingw packages for your distro. Note that to just *use* GLib on Windows, there is no need to build it yourself. On Windows setting up a correct build environment can be quite a task, especially if you are used to just typing `meson; ninja` on Linux, and expect things to work as smoothly on Windows. The following preprocessor macros are to be used for conditional compilation related to Win32 in GLib-using code: - G_OS_WIN32 is defined when compiling for native Win32, without any POSIX emulation, other than to the extent provided by the bundled Microsoft C library (msvcr*.dll). - G_WITH_CYGWIN is defined if compiling for the Cygwin environment. Note that G_OS_WIN32 is *not* defined in that case, as Cygwin is supposed to behave like Unix. G_OS_UNIX *is* defined by a GLib for Cygwin. - G_PLATFORM_WIN32 is defined when either G_OS_WIN32 or G_WITH_CYGWIN is defined. These macros are defined in glibconfig.h, and are thus available in all source files that include . Additionally, there are the compiler-specific macros: - __GNUC__ is defined when using gcc - _MSC_VER is defined when using the Microsoft compiler - __DMC__ is defined when using the Digital Mars C/C++ compiler G_OS_WIN32 implies using the Microsoft C runtime, normally msvcrt.dll. GLib is not known to work with the older crtdll.dll runtime, or the static Microsoft C runtime libraries libc.lib and libcmt.lib. It apparently does work with the debugging version of msvcrt.dll, msvcrtd.dll. If compiled with Microsoft compilers newer than MSVC6, it also works with their compiler-specific runtimes, like msvcr70.dll or msvcr80.dll. Please note that it's non totally clear if you would be allowed by the license to distrubute a GLib linked to msvcr70.dll or msvcr80.dll, as those are not part of the operating system, but of the MSVC product. msvcrt.dll is part of Windows. For people using Visual Studio 2005 or later: If you are building GLib-based libraries or applications, or GLib itself and you see a C4819 error (or warning, before C4819 is treated as an error in msvc_recommended_pragmas.h), please be advised that this error/warning should not be disregarded, as this likely means portions of the build is not being done correctly, as this is an issue of Visual Studio running on CJK (East Asian) locales. This is an issue that also affects builds of other projects, such as QT, Firefox, LibreOffice/OpenOffice, Pango and GTK+, along with many other projects. To overcome this problem, please set your system's locale setting for non-Unicode to English (United States), reboot, and restart the build, and the code should build normally. See also this GNOME Wiki page [1] that gives a bit further info on this. In Visual Studio 2015 and later, the /utf-8 option is provided, which is set by the latest Meson releases when building GLib, and can be used in other project files that uses GLib to avoid the need of setting your system's locale setting for non-Unicode and the subsequent requirement to restart the system. Building software that use GLib or GTK+ ======================================= Building software that just *uses* GLib or GTK+ also require to have the right compiler set up the right way. If you intend to use gcc, follow the relevant instructions below in that case, too. Tor uses gcc with the -mms-bitfields flag which means that in order to use the prebuilt DLLs (especially of GTK+), if you compile your code with gcc, you *must* also use that flag. This flag means that the struct layout rules are identical to those used by MSVC. This is essential if the same DLLs are to be usable both from gcc- and MSVC-compiled code. Such compatibility is desirable. When using the prebuilt GLib DLLs that use msvcrt.dll from code that uses other C runtimes like for example msvcr70.dll, one should note that one cannot use such GLib API that take or returns file descriptors. On Windows, a file descriptor (the small integer as returned by open() and handled by related functions, and included in the FILE struct) is an index into a table local to the C runtime DLL. A file descriptor in one C runtime DLL does not have the same meaning in another C runtime DLL. Building GLib ============= Again, first decide whether you really want to do this. Before building GLib you must also have a GNU gettext-runtime developer package. Get prebuilt binaries of gettext-runtime from http://www.gtk.org/download-windows.html . Building with Visual Studio =========================== Meson is now the supported method of building GLib using Visual Studio. Note that you will need a libintl implementation, zlib, and libFFI, and optionally PCRE1, which should preferably be built with the same compiler that is now being used to build GLib. Ensure that their headers, .lib's and DLLs can be found in the paths specified by the INCLUDE, LIB and PATH envvars. The Meson build process will pull in a copy of the ZLib and the libFFI sources if they cannot be found, and will build an in-source copy of PCRE1 if PCRE1 cannt be found. One can also refer to the following page for building the dependencies: https://wiki.gnome.org/Projects/GTK%2B/Win32/MSVCCompilationOfGTKStack You will also need the following items: -Python 3.6.x, you need the 32-bit version if you are building GLib as a 32-bit/x86 build, or the amd64/x64 version for building 64-bit/x86-64 builds. You will then need to install or update Meson by using pip. -The Ninja build tool, required for Visual Studio 2008, 2012 and 2013 builds, and optional for 2010, 2015 and 2017 builds, where Visual Studio projects can be generated instead of the Ninja build files. -GIT for Windows is highly recommended, in the case where some required dependencies are not found, and Meson makes use of GIT to download the sources to build in the build process. To do a build using Meson, do the following: -Open a Visual Studio (or SDK) command prompt that matches the Visual Studio version and build platform (Win32/x86, x64, etc.) that will be used in all the following steps. -Create an empty directory/folder for the build. It needs to be in the same drive as where your GLib sources are located (i.e. $(GLIB_SRCDIR)). cd into that directory/folder. -Setup your PATH envvar: set PATH=%PATH%;$(PYTHON_INSTALL_DIR);$(NINJA_DIR) where PYTHON_INSTALL_DIR is where Python 3.6.x+ is installed to, and NINJA_DIR is where your ninja executable can be found. The NINJA_DIR can be omitted if one passes --backend=vs to the Meson configuration line, for Visual Studio 2010, 2015 and 2017 builds. -Configure the build using Meson: python $(PYTHON_INSTALL_DIR)\scripts\meson.py $(GLIB_SRCDIR) --buildtype=$(build_configuration) --prefix=$(INSTALL_PREFIX) [--backend=vs] Please see the Meson docs for an explanation for --buildtype, the path passed for --prefix need not to be on the same drive as where the build is carried out, but it is recommended to use forward slashes for this path. The --backend=vs can be used if the Visual Studio project generator is preferred over using Ninja, for Visual Studio 2010, 2015 and 2017 builds. -Build, test and install the build: Run ninja (and ninja test and ninja install) or open the generated Visual Studio projects to compile, test and install the build. Note that if building the sources with Visual Studio 2008, note the following additional items: -You need to run the following lines from your build directory, to embed the manifests that are generated during the build, assuming the built binaries are installed to $(PREFIX), after a successful build/installation: for /r %f in (*.dll.manifest) do if exist $(PREFIX)\bin\%~nf mt /manifest %f $(PREFIX)\bin\%~nf;2 for /r %f in (*.exe.manifest) do if exist $(PREFIX)\bin\%~nf mt /manifest %f $(PREFIX)\bin\%~nf;1 -If building for amd64/x86_64/x64, sometimes the compilation of sources may seem to hang, which is caused by an optimization issue in the 2008 x64 compiler. You need to use Task Manager to remove all running instances of cl.exe, which will cause the build process to terminate. Update the build flags of the sources that hang on compilation by changing its "/O2" flag to "/O1" in build.ninja, and retry the build, where things should continue to build normally. At the time of writing, this is needed for compiling glib/gtestutils.c, gio/gsettings.c, gio/gsettingsschema.c and gio/tests/gsubprocess-testprog.c