# Shipping prebuilt binaries as wraps A common dependency case, especially on Windows, is the need to provide dependencies as prebuilt binaries rather than Meson projects that you build from scratch. Common reasons include not having access to source code, not having the time and effort to rewrite a legacy system's build definitions to Meson or just the fact that compiling the dependency projects takes too long. Packaging a project is straightforward. As an example let's look at a case where the project consists of one static library called `bob` and some headers. To create a binary dependency project we put the static library at the top level and headers in a subdirectory called `include`. The Meson build definition would look like the following. ```meson project('bob', 'c') # Do some sanity checking so that meson can fail early instead of at final link time if not (host_machine.system() == 'windows' or host_machine.cpu_family() == 'x86_64') error('This wrap of libbob is a binary wrap for x64_64 Windows, and will not work on your system') endif cc = meson.get_compiler('c') bob_dep = declare_dependency( dependencies : cc.find_library('bob', dirs : meson.current_source_dir()), include_directories : include_directories('include')) meson.override_dependency('bob', bob_dep) ``` Now you can use this subproject as if it was a Meson project: ```meson project('using dep', 'c') bob_dep = dependency('bob') executable('prog', 'prog.c', dependencies : bob_dep) ``` Note that often libraries compiled with different compilers (or even compiler flags) might not be compatible. If you do this, then you are responsible for verifying that your libraries are compatible, Meson will not check things for you. ## Using a wrap file To make this all work automatically, a project will need a [wrap file](Wrap-dependency-system-manual.md#wrap-format), as well as the meson.build definition from above. For this example our dependency is called `bob`. The wrap ini (subprojects/bob.wrap): ```ini [wrap-file] directory = libbob-1.0 source_url = https://libbob.example.com/libbob-1.0.zip source_filename = libbob-1.0.zip source_hash = 5ebeea0dfb75d090ea0e7ff84799b2a7a1550db3fe61eb5f6f61c2e971e57663 patch_directory = libbob [provide] dependency_names = bob ``` Then create `subprojects/packagefiles/libbob/`, and place the `meson.build` from above in that directory. With these in place a call to `dependency('bob')` will first try standard discovery methods for your system (such as pkg-config, cmake, and any built-in meson find methods), and then fall back to using the binary wrap if it cannot find the dependency on the system. Meson provides the `--force-fallback-for=bob` command line option to force the use of the fallback. ## Note for Linux libraries A precompiled linux shared library (.so) requires a soname field to be properly installed. If the soname field is missing, binaries referencing the library will require a hard link to the location of the library at install time (`/path/to/your/project/subprojects/precompiledlibrary/lib.so` instead of `$INSTALL_PREFIX/lib/lib.so`) after installation. You should change the compilation options for the precompiled library to avoid this issue. If recompiling is not an option, you can use the [patchelf](https://github.com/NixOS/patchelf) tool with the command `patchelf --set-soname libfoo.so libfoo.so` to edit the precompiled library after the fact. Meson generally guarantees any library it compiles has a soname. One notable exception is libraries built with the [[shared_module]] function.