This repository contains an up-to-date Android toolchain featuring OCaml 4.04.0, as well as some commonly used packages.
The supported build systems are 32-bit and 64-bit x86 Linux. The supported target systems are 32-bit x86 and ARM Android.
If you need support for other platforms or versions, please open an issue.
On 64-bit Linux build systems, 32-bit libraries must be installed. On Debian derivatives they are provided in the gcc-multilib
package.
The compiled toolchain requires about 5G of disk space.
Add this repository to OPAM:
opam repository add android git://github.com/whitequark/opam-cross-android
On 64-bit build systems, switch to 32-bit compiler when compiling for 32-bit targets:
opam switch 4.04.0+32bit
eval `opam config env`
Otherwise, use a regular compiler; its version must match the version of the cross-compiler:
opam switch 4.04.0
eval `opam config env`
Pin some prerequisite packages that don't yet have fixes merged upstream:
opam pin add ocamlbuild https://github.com/ocaml/ocamlbuild.git
opam pin add topkg https://github.com/whitequark/topkg.git
Configure the compiler for ARM:
ARCH=arm SUBARCH=armv7 SYSTEM=linux_eabi \
CCARCH=arm TOOLCHAIN=arm-linux-androideabi-4.9 \
TRIPLE=arm-linux-androideabi LEVEL=24 \
STLVER=4.9 STLARCH=armeabi \
opam install conf-android
Alternatively, configure the compiler for AArch64:
ARCH=arm64 SUBARCH=arm64 SYSTEM=linux_eabi \
CCARCH=arm64 TOOLCHAIN=aarch64-linux-android-4.9 \
TRIPLE=aarch64-linux-android LEVEL=24 \
STLVER=4.9 STLARCH=arm64-v8a \
opam install conf-android
Alternatively, configure the compiler for x86:
ARCH=i386 SUBARCH=default SYSTEM=linux_elf \
CCARCH=x86 TOOLCHAIN=x86-4.9 \
TRIPLE=i686-linux-android LEVEL=24 \
STLVER=4.9 STLARCH=x86 \
opam install conf-android
Some options can be tweaked:
SUBARCH
(on ARM) specifies the ARM architecture version, e.g.armv5te
orarmv7
;SYSTEM
(on ARM) specifies the ABI:linux_eabi
for soft-float andlinux_eabihf
for hard-float;LEVEL
specifies the Android API level and defaults to latest available API.
The options above (ARCH
, SUBARCH
, SYSTEM
, LEVEL
, TOOLCHAIN
and TRIPLE
) are recorded inside the conf-android
package, so make sure to reinstall that package if you wish to switch to a different toolchain. Otherwise, it is not necessary to supply them while upgrading the ocaml-android*
packages.
If desired, request the compiler to be built with flambda optimizers:
opam install conf-flambda-android
Install the compiler:
opam install ocaml-android
Build some code:
echo 'let () = print_endline "Hello, world!"' >helloworld.ml
ocamlfind -toolchain android ocamlc -custom helloworld.ml -o helloworld.byte
ocamlfind -toolchain android ocamlopt helloworld.ml -o helloworld.native
Install some packages:
opam install re-android
Write some code using them:
let () =
let regexp = Re_pcre.regexp {|\b([a-z]+)\b|} in
let result = Re.exec regexp "Hello, world!" in
Format.printf "match: %s\n" (Re.get result 1)
Build it:
ocamlfind -toolchain android ocamlopt -package re.pcre -linkpkg test_pcre.ml -o test_pcre
Make an object file out of it and link it with your Android project (you'll need to call caml_startup(argv)
to run OCaml code; see this article):
ocamlfind -toolchain android ocamlopt -package re.pcre -linkpkg -output-complete-obj test_pcre.ml -o test_pcre.o
Make a shared object out of it:
ocamlfind -toolchain android ocamlopt -package re.pcre -linkpkg -output-obj -cclib -shared test_pcre.ml -o test_pcre.so
With opam-android, cross-compilation is easy!
OCaml packages often have components that execute at compile-time (camlp4 or ppx syntax extensions, cstubs, OASIS, ...). Thus, it is not possible to just blanketly cross-compile every package in the OPAM repository; sometimes you would even need a cross-compiled and a non-cross-compiled package at once. The package definitions also often need package-specific modification in order to work.
As a result, if you want a package to be cross-compiled, you have to copy the definition from opam-repository, rename the package to add -android
suffix while updating any dependencies it could have, and update the build script. Don't forget to add ocaml-android
as a dependency!
Findlib 1.5.4 adds a feature that makes porting packages much simpler; namely, an OCAMLFIND_TOOLCHAIN
environment variable that is equivalent to the -toolchain
command-line flag. Now it is not necessary to patch the build systems of the packages to select the Android toolchain; it is often enough to add ["env" "OCAMLFIND_TOOLCHAIN=android" make ...]
to the build command in the opam
file.
For projects using OASIS, the following steps will work:
build: [
["ocaml" "setup.ml" "-configure" "--prefix" "%{prefix}%/android-sysroot"]
["env" "OCAMLFIND_TOOLCHAIN=android" "ocaml" "setup.ml" "-build"]
]
install: [
["env" "OCAMLFIND_TOOLCHAIN=android" "ocaml" "setup.ml" "-install"]
]
remove: [["ocamlfind" "-toolchain" "android" "remove" "pkg"]]
depends: ["ocaml-android" ...]
The output of the configure
script will be entirely wrong, referring to the host configuration rather than target configuration. Thankfully, it is not actually used in the build process itself, so it doesn't matter.
For projects installing the files via OPAM's .install
files (e.g. topkg), the following steps will work:
build: [["ocaml" "pkg/pkg.ml" "build" "--pinned" "%{pinned}%" "--toolchain" "windows" ]]
install: [["opam-installer" "--prefix=%{prefix}%/android-sysroot" "pkg.install"]]
remove: [["ocamlfind" "-toolchain" "android" "remove" "pkg"]]
depends: ["ocaml-android" ...]
The aim of this repository is to build a cross-compiler while altering the original codebase in the minimal possible way. (Indeed, only about 50 lines are changed.) There are no attempts to alter the configure
script; rather, the configuration is provided directly. The resulting cross-compiler has several interesting properties:
- All paths to the Android toolchain are embedded inside
ocamlc
andocamlopt
; thus, no knowledge of the Android toolchain is required even for packages that have components in C, provided they use the OCaml driver to compile the C code. (This is usually the case.) - The build system makes several assumptions that are not strictly valid while cross-compiling, mainly the fact that the bytecode the cross-compiler has just built can be ran by the
ocamlrun
on the build system. Thus, the requirement for a 32-bit build compiler for 32-bit targets, as well as for the matching versions. - The
.opt
versions of the compiler are built using itself, which doesn't work while cross-compiling, so all provided tools are bytecode-based.
All files contained in this repository are licensed under the CC0 1.0 Universal license.
Some of the tricks in this repository were inspired by Jerome Vouillon's opam-android-repository. However, no code was reused.
See also opam-cross-windows and opam-cross-ios.