Advanced topics

This section describes some details of dune for advanced users.

META file generation

Dune uses META files from the findlib library manager in order to interoperate with the rest of the world when installing libraries. It is able to generate them automatically. However, for the rare cases where you would need a specific META file, or to ease the transition of a project to dune, it is allowed to write/generate a specific one.

In order to do that, write or setup a rule to generate a META.<package>.template file in the same directory as the <package>.opam file. Dune will generate a META.<package> file from the META.<package>.template file by replacing lines of the form # JBUILDER_GEN by the contents of the META it would normally generate.

For instance if you want to extend the META file generated by dune you can write the folliwing META.foo.template file:

# JBUILDER_GEN
blah = "..."

Findlib integration and limitations

Dune uses META files to support external libraries. However, it doesn’t export the full power of findlib to the user, and especially it doesn’t let the user specify predicates.

The reason for this limitation is that so far they haven’t been needed, and adding full support for them would complicate things quite a lot. In particular, complex META files are often hand-written and the various features they offer are only available once the package is installed, which goes against the root ideas dune is built on.

In practice, dune interprets META files assuming the following set of predicates:

• mt: what this means is that using a library that can be used with or without threads with dune will force the threaded version
• mt_posix: forces the use of posix threads rather than VM threads. VM threads are deprecated and are likely to go away soon
• ppx_driver: when a library acts differently depending on whether it is linked as part of a driver or meant to add a -ppx argument to the compiler, choose the former behavior

Cross Compilation

Dune allows for cross compilation by defining build contexts with multiple targets. Targets are specified by adding a targets field to the definition of a build context.

targets takes a list of target name. It can be either:

• native which means using the native tools that can build binaries that run on the machine doing the build
• the name of an alternative toolchain

Note that at the moment, there is no official support for cross-compilation in OCaml. Dune supports the opam-cross-x repositories from the ocaml-cross organization on github, such as:

• opam-cross-windows
• opam-cross-android
• opam-cross-ios

In particular:

• to build Windows binaries using opam-cross-windows, write windows in the list of targets
• to build Android binaries using opam-cross-android, write android in the list of targets
• to build IOS binaries using opam-cross-ios, write ios in the list of targets

For example, the following workspace file defines three different targets for the default build context:

(context (default (targets (native windows android))))

This configuration defines three build contexts:

• default
• default.windows
• default.android

Note that the native target is always implicitly added when not present. However, when implicitly added dune build @install will skip this context, i.e. default will only be used for building executables needed by the other contexts.

With such a setup, calling dune build @install will build all the packages three times.

Note that instead of writing a dune-workspace file, you can also use the -x command line option. Passing -x foo to dune without having a dune-workspace file is the same as writing the following dune-workspace file:

(context (default (targets (foo))))

If you have a dune-workspace and pass a -x foo option, foo will be added as target of all context stanzas.

How does it work?

In such a setup, binaries that need to be built and executed in the default.windows or default.android contexts as part of the build, will no longer be executed. Instead, all the binaries that will be executed will come from the default context. One consequence of this is that all preprocessing (ppx or otherwise) will be done using binaries built in the default context.

To clarify this with an example, let’s assume that you have the following src/dune file:

(executable (name foo))
(rule (with-stdout-to blah (run ./foo.exe)))

When building _build/default/src/blah, dune will resolve ./foo.exe to _build/default/src/foo.exe as expected. However, for _build/default.windows/src/blah dune will resolve ./foo.exe to _build/default/src/foo.exe

Assuming that the right packages are installed or that your workspace has no external dependencies, dune will be able to cross-compile a given package without doing anything special.

Some packages might still have to be updated to support cross-compilation. For instance if the foo.exe program in the previous example was using Sys.os_type, it should instead take it as a command line argument:

(rule (with-stdout-to blah (run ./foo.exe -os-type %{os_type})))

Classical ppx

classical ppx refers to running ppx using the -ppx compiler option, which is composed using Findlib. Even though this is useful to run some (usually old) ppx’s which don’t support drivers, dune does not support preprocessing with ppx this way. but a workaround exists using the ppxfind tool.