# Building BoringSSL ## Build Prerequisites * [CMake](http://www.cmake.org/download/) 2.8.8 or later is required. * Perl 5.6.1 or later is required. On Windows, [Strawberry Perl](http://strawberryperl.com/) and MSYS Perl have both been reported to work. If not found by CMake, it may be configured explicitly by setting `PERL_EXECUTABLE`. * On Windows you currently must use [Ninja](https://martine.github.io/ninja/) to build; on other platforms, it is not required, but recommended, because it makes builds faster. * If you need to build Ninja from source, then a recent version of [Python](https://www.python.org/downloads/) is required (Python 2.7.5 works). * On Windows only, [Yasm](http://yasm.tortall.net/) is required. If not found by CMake, it may be configured explicitly by setting `CMAKE_ASM_NASM_COMPILER`. * A C compiler is required. On Windows, MSVC 12 (Visual Studio 2013) or later with Platform SDK 8.1 or later are supported. Recent versions of GCC and Clang should work on non-Windows platforms, and maybe on Windows too. * [Go](https://golang.org/dl/) is required. If not found by CMake, the go executable may be configured explicitly by setting `GO_EXECUTABLE`. * If you change crypto/chacha/chacha_vec.c, you will need the arm-linux-gnueabihf-gcc compiler: ``` $ wget https://releases.linaro.org/14.11/components/toolchain/binaries/arm-linux-gnueabihf/gcc-linaro-4.9-2014.11-x86_64_arm-linux-gnueabihf.tar.xz $ echo bc4ca2ced084d2dc12424815a4442e19cb1422db87068830305d90075feb1a3b gcc-linaro-4.9-2014.11-x86_64_arm-linux-gnueabihf.tar.xz | sha256sum -c $ tar xf gcc-linaro-4.9-2014.11-x86_64_arm-linux-gnueabihf.tar.xz $ sudo mv gcc-linaro-4.9-2014.11-x86_64_arm-linux-gnueabihf /opt/ ``` ## Building Using Ninja (note the 'N' is capitalized in the cmake invocation): mkdir build cd build cmake -GNinja .. ninja Using Make (does not work on Windows): mkdir build cd build cmake .. make You usually don't need to run `cmake` again after changing `CMakeLists.txt` files because the build scripts will detect changes to them and rebuild themselves automatically. Note that the default build flags in the top-level `CMakeLists.txt` are for debugging—optimisation isn't enabled. If you want to cross-compile then there is an example toolchain file for 32-bit Intel in `util/`. Wipe out the build directory, recreate it and run `cmake` like this: cmake -DCMAKE_TOOLCHAIN_FILE=../util/32-bit-toolchain.cmake -GNinja .. If you want to build as a shared library, pass `-DBUILD_SHARED_LIBS=1`. On Windows, where functions need to be tagged with `dllimport` when coming from a shared library, define `BORINGSSL_SHARED_LIBRARY` in any code which `#include`s the BoringSSL headers. ### Building for Android It's possible to build BoringSSL with the Android NDK using CMake. This has been tested with version 10d of the NDK. Unpack the Android NDK somewhere and export `ANDROID_NDK` to point to the directory. Clone https://github.com/taka-no-me/android-cmake into `util/`. Then make a build directory as above and run CMake *twice* like this: cmake -DANDROID_NATIVE_API_LEVEL=android-9 \ -DANDROID_ABI=armeabi-v7a \ -DCMAKE_TOOLCHAIN_FILE=../util/android-cmake/android.toolchain.cmake \ -DANDROID_NATIVE_API_LEVEL=16 \ -GNinja .. Once you've run that twice, Ninja should produce Android-compatible binaries. You can replace `armeabi-v7a` in the above with `arm64-v8a` to build aarch64 binaries. ## Known Limitations on Windows * Versions of CMake since 3.0.2 have a bug in its Ninja generator that causes yasm to output warnings yasm: warning: can open only one input file, only the last file will be processed These warnings can be safely ignored. The cmake bug is http://www.cmake.org/Bug/view.php?id=15253. * CMake can generate Visual Studio projects, but the generated project files don't have steps for assembling the assembly language source files, so they currently cannot be used to build BoringSSL. ## Embedded ARM ARM, unlike Intel, does not have an instruction that allows applications to discover the capabilities of the processor. Instead, the capability information has to be provided by the operating system somehow. BoringSSL will try to use `getauxval` to discover the capabilities and, failing that, will probe for NEON support by executing a NEON instruction and handling any illegal-instruction signal. But some environments don't support that sort of thing and, for them, it's possible to configure the CPU capabilities at compile time. If you define `OPENSSL_STATIC_ARMCAP` then you can define any of the following to enabling the corresponding ARM feature. * `OPENSSL_STATIC_ARMCAP_NEON` or `__ARM_NEON__` (note that the latter is set by compilers when NEON support is enabled). * `OPENSSL_STATIC_ARMCAP_AES` * `OPENSSL_STATIC_ARMCAP_SHA1` * `OPENSSL_STATIC_ARMCAP_SHA256` * `OPENSSL_STATIC_ARMCAP_PMULL` Note that if a feature is enabled in this way, but not actually supported at run-time, BoringSSL will likely crash. # Running tests There are two sets of tests: the C/C++ tests and the blackbox tests. For former are built by Ninja and can be run from the top-level directory with `go run util/all_tests.go`. The latter have to be run separately by running `go test` from within `ssl/test/runner`. Both sets of tests may also be run with `ninja -C build run_tests`, but CMake 3.2 or later is required to avoid Ninja's output buffering.