--- title: Release 0.51.0 short-description: Release notes for 0.51.0 ... # New features ## (C) Preprocessor flag handling Meson previously stored `CPPFLAGS` and per-language compilation flags separately. (That latter would come from `CFLAGS`, `CXXFLAGS`, etc., along with `_args` options whether specified no the command-line interface (`-D..`), `meson.build` (`default_options`), or cross file (`[properties]`).) This was mostly unobservable, except for certain preprocessor-only checks like `check_header` would only use the preprocessor flags, leading to confusion if some `-isystem` was in `CFLAGS` but not `CPPFLAGS`. Now, they are lumped together, and `CPPFLAGS`, for the languages which are deemed to care to about, is just another source of compilation flags along with the others already listed. ## Sanity checking compilers with user flags Sanity checks previously only used user-specified flags for cross compilers, but now do in all cases. All compilers Meson might decide to use for the build are "sanity checked" before other tests are run. This usually involves building simple executable and trying to run it. Previously user flags (compilation and/or linking flags) were used for sanity checking cross compilers, but not native compilers. This is because such flags might be essential for a cross binary to succeed, but usually aren't for a native compiler. In recent releases, there has been an effort to minimize the special-casing of cross or native builds so as to make building more predictable in less-tested cases. Since this the user flags are necessary for cross, but not harmful for native, it makes more sense to use them in all sanity checks than use them in no sanity checks, so this is what we now do. ## New `sourceset` module A new module, `sourceset`, was added to help building many binaries from the same source files. Source sets associate source files and dependencies to keys in a `configuration_data` object or a dictionary; they then take multiple `configuration_data` objects or dictionaries, and compute the set of source files and dependencies for each of those configurations. ## n_debug=if-release and buildtype=plain means no asserts Previously if this combination was used then assertions were enabled, which is fairly surprising behavior. ## `target_type` in `build_targets` accepts the value 'shared_module' The `target_type` keyword argument in `build_target()` now accepts the value `'shared_module'`. The statement ```meson build_target(..., target_type: 'shared_module') ``` is equivalent to this: ```meson shared_module(...) ``` ## New modules kwarg for python.find_installation This mirrors the modules argument that some kinds of dependencies (such as qt, llvm, and cmake based dependencies) take, allowing you to check that a particular module is available when getting a python version. ```meson py = import('python').find_installation('python3', modules : ['numpy']) ``` ## Support for the Intel Compiler on Windows (ICL) Support has been added for ICL.EXE and ifort on windows. The support should be on part with ICC support on Linux/MacOS. The ICL C/C++ compiler behaves like Microsoft's CL.EXE rather than GCC/Clang like ICC does, and has a different id, `intel-cl` to differentiate it. ```meson cc = meson.get_compiler('c') if cc.get_id == 'intel-cl' add_project_argument('/Qfoobar:yes', language : 'c') endif ``` ## Added basic support for the Xtensa CPU toolchain You can now use `xt-xcc`, `xt-xc++`, `xt-nm`, etc... on your cross compilation file and Meson won't complain about an unknown toolchain. ## Dependency objects now have a get_variable method This is a generic replacement for type specific variable getters such as `ConfigToolDependency.get_configtool_variable` and `PkgConfigDependency.get_pkgconfig_variable`, and is the only way to query such variables from cmake dependencies. This method allows you to get variables without knowing the kind of dependency you have. ```meson dep = dependency('could_be_cmake_or_pkgconfig') # cmake returns 'YES', pkg-config returns 'ON' if ['YES', 'ON'].contains(dep.get_variable(pkgconfig : 'var-name', cmake : 'COP_VAR_NAME', default_value : 'NO')) error('Cannot build your project when dep is built with var-name support') endif ``` ## CMake prefix path overrides When using pkg-config as a dependency resolver we can pass `-Dpkg_config_path=$somepath` to extend or overwrite where pkg-config will search for dependencies. Now cmake can do the same, as long as the dependency uses a ${Name}Config.cmake file (not a Find{$Name}.cmake file), by passing `-Dcmake_prefix_path=list,of,paths`. It is important that point this at the prefix that the dependency is installed into, not the cmake path. If you have installed something to `/tmp/dep`, which has a layout like: ``` /tmp/dep/lib/cmake /tmp/dep/bin ``` then invoke Meson as `meson setup builddir/ -Dcmake_prefix_path=/tmp/dep` ## Tests that should fail but did not are now errors You can tag a test as needing to fail like this: ```meson test('shoulfail', exe, should_fail: true) ``` If the test passes the problem is reported in the error logs but due to a bug it was not reported in the test runner's exit code. Starting from this release the unexpected passes are properly reported in the test runner's exit code. This means that test runs that were passing in earlier versions of Meson will report failures with the current version. This is a good thing, though, since it reveals an error in your test suite that has, until now, gone unnoticed. ## New target keyword argument: `link_language` There may be situations for which the user wishes to manually specify the linking language. For example, a C++ target may link C, Fortran, etc. and perhaps the automatic detection in Meson does not pick the desired compiler. The user can manually choose the linker by language per-target like this example of a target where one wishes to link with the Fortran compiler: ```meson executable(..., link_language : 'fortran') ``` A specific case this option fixes is where for example the main program is Fortran that calls C and/or C++ code. The automatic language detection of Meson prioritizes C/C++, and so an compile-time error results like `undefined reference to main`, because the linker is C or C++ instead of Fortran, which is fixed by this per-target override. ## New module to parse kconfig output files The new module `unstable-kconfig` adds the ability to parse and use kconfig output files from `meson.build`. ## Add new `meson subprojects foreach` command `meson subprojects` has learned a new `foreach` command which accepts a command with arguments and executes it in each subproject directory. For example this can be useful to check the status of subprojects (e.g. with `git status` or `git diff`) before performing other actions on them. ## Added c17 and c18 as c_std values for recent GCC and Clang Versions For gcc version 8.0 and later, the values c17, c18, gnu17, and gnu18 were added to the accepted values for built-in compiler option c_std. For Clang version 10.0 and later on Apple OSX (Darwin), and for version 7.0 and later on other platforms, the values c17 and gnu17 were added as c_std values. ## gpgme dependency now supports gpgme-config Previously, we could only detect GPGME with custom invocations of `gpgme-config` or when the GPGME version was recent enough (>=1.13.0) to install pkg-config files. Now we added support to Meson allowing us to use `dependency('gpgme')` and fall back on `gpgme-config` parsing. ## Can link against custom targets The output of `custom_target` and `custom_target[i]` can be used in `link_with` and `link_whole` keyword arguments. This is useful for integrating custom code generator steps, but note that there are many limitations: - Meson can not know about link dependencies of the custom target. If the target requires further link libraries, you need to add them manually - The user is responsible for ensuring that the code produced by different toolchains are compatible. - `custom_target` may only be used when it has a single output file. Use `custom_target[i]` when dealing with multiple output files. - The output file must have the correct file name extension. ## Removed the deprecated `--target-files` API The `--target-files` introspection API is now no longer available. The same information can be queried with the `--targets` API introduced in 0.50.0. ## Generators have a new `depends` keyword argument Generators can now specify extra dependencies with the `depends` keyword argument. It matches the behaviour of the same argument in other functions and specifies that the given targets must be built before the generator can be run. This is used in cases such as this one where you need to tell a generator to indirectly invoke a different program. ```meson exe = executable(...) cg = generator(program_runner, output: ['@BASENAME@.c'], arguments: ['--use-tool=' + exe.full_path(), '@INPUT@', '@OUTPUT@'], depends: exe) ``` ## Specifying options per mer machine Previously, no cross builds were controllable from the command line. Machine-specific options like the pkg-config path and compiler options only affected native targets, that is to say all targets in native builds, and `native: true` targets in cross builds. Now, prefix the option with `build.` to affect build machine targets, and leave it unprefixed to affect host machine targets. For those trying to ensure native and cross builds to the same platform produced the same result, the old way was frustrating because very different invocations were needed to affect the same targets, if it was possible at all. Now, the same command line arguments affect the same targets everywhere --- Meson is closer to ignoring whether the "overall" build is native or cross, and just caring about whether individual targets are for the build or host machines. ## subproject.get_variable() now accepts a `fallback` argument Similar to `get_variable`, a fallback argument can now be passed to `subproject.get_variable()`, it will be returned if the requested variable name did not exist. ``` meson var = subproject.get_variable('does-not-exist', 'fallback-value') ``` ## Add keyword `static` to `find_library` `find_library` has learned the `static` keyword. They keyword must be a boolean, where `true` only searches for static libraries and `false` only searches for dynamic/shared. Leaving the keyword unset will keep the old behavior of first searching for dynamic and then falling back to static. ## Fortran `include` statements recursively parsed While non-standard and generally not recommended, some legacy Fortran programs use `include` directives to inject code inline. Since v0.51, Meson can handle Fortran `include` directives recursively. DO NOT list `include` files as sources for a target, as in general their syntax is not correct as a standalone target. In general `include` files are meant to be injected inline as if they were copy and pasted into the source file. `include` was never standard and was superseded by Fortran 90 `module`. The `include` file is only recognized by Meson if it has a Fortran file suffix, such as `.f` `.F` `.f90` `.F90` or similar. This is to avoid deeply nested scanning of large external legacy C libraries that only interface to Fortran by `include biglib.h` or similar. ## CMake subprojects Meson can now directly consume CMake based subprojects with the CMake module. Using CMake subprojects is similar to using the "normal" Meson subprojects. They also have to be located in the `subprojects` directory. Example: ```cmake add_library(cm_lib SHARED ${SOURCES}) ``` ```meson cmake = import('cmake') # Configure the CMake project sub_proj = cmake.subproject('libsimple_cmake') # Fetch the dependency object cm_lib = sub_proj.dependency('cm_lib') executable(exe1, ['sources'], dependencies: [cm_lib]) ``` It should be noted that not all projects are guaranteed to work. The safest approach would still be to create a `meson.build` for the subprojects in question. ## Multiple cross files can be specified `--cross-file` can be passed multiple times, with the configuration files overlaying the same way as `--native-file`.