# Build iwasm iwasm is the executable binary built with WAMR VMcore supports WASI and command line interface. Refer to [**how to build wamr vmcore**](../doc/build_wamr.md) for all the supported CMAKE compilation variables. If you are building for ARM architecture on a X86 development machine, you can use the `CMAKE_TOOLCHAIN_FILE` to set the toolchain file for cross compling. ``` cmake .. -DCMAKE_TOOLCHAIN_FILE=$TOOL_CHAIN_FILE \ -DWAMR_BUILD_PLATFORM=linux \ -DWAMR_BUILD_TARGET=ARM ``` Refer to toolchain sample file [`wamr-app-framework/samples/simple/profiles/arm-interp/toolchain.cmake`](https://github.com/bytecodealliance/wamr-app-framework/blob/main/samples/simple/profiles/arm-interp/toolchain.cmake) for how to build mini product for ARM target architecture. If you compile for ESP-IDF, make sure to set the right toolchain file for the chip you're using (e.g. `$IDF_PATH/tools/cmake/toolchain-esp32c3.cmake`). Note that all ESP-IDF toolchain files live under `$IDF_PATH/tools/cmake/`. ## Linux First of all please install the dependent packages. Run command below in Ubuntu-22.04: ``` Bash sudo apt install build-essential cmake g++-multilib libgcc-11-dev lib32gcc-11-dev ccache ``` Or in Ubuntu-20.04 ``` Bash sudo apt install build-essential cmake g++-multilib libgcc-9-dev lib32gcc-9-dev ccache ``` Or in Ubuntu-18.04: ``` Bash sudo apt install build-essential cmake g++-multilib libgcc-8-dev lib32gcc-8-dev ccache ``` Or in Fedora: ``` Bash sudo dnf install glibc-devel.i686 ``` After installing dependencies, build the source code: ``` Bash cd product-mini/platforms/linux/ mkdir build && cd build cmake .. make # iwasm is generated under current directory ``` By default in Linux, the `fast interpreter`, `AOT` and `Libc WASI` are enabled, and JIT is disabled. And the build target is set to X86_64 or X86_32 depending on the platform's bitwidth. There are total 6 running modes supported: fast interpreter, classi interpreter, AOT, LLVM JIT, Fast JIT and Multi-tier JIT. (1) To run a wasm file with `fast interpreter` mode - build iwasm with default build and then: ```Bash iwasm ``` Or ```Bash mkdir build && cd build cmake .. -DWAMR_BUILD_INTERP=1 make ``` (2) To disable `fast interpreter` and enable `classic interpreter` instead: ``` Bash mkdir build && cd build cmake .. -DWAMR_BUILD_FAST_INTERP=0 make ``` (3) To run an AOT file, firstly please refer to [Build wamrc AOT compiler](../wamr-compiler/README.md) to build wamrc, and then: ```Bash wamrc -o iwasm ``` (4) To enable the `LLVM JIT` mode, firstly we should build the LLVM library: ``` Bash cd product-mini/platforms/linux/ ./build_llvm.sh (The llvm source code is cloned under /core/deps/llvm and auto built) ``` Then pass argument `-DWAMR_BUILD_JIT=1` to cmake to enable LLVM JIT: ``` Bash mkdir build && cd build cmake .. -DWAMR_BUILD_JIT=1 make ``` Note: By default, the LLVM Orc JIT with Lazy compilation is enabled to speedup the lanuching process and reduce the JIT compilation time by creating backend threads to compile the WASM functions parallely, and for the main thread, the functions in the module will not be compiled until they are firstly called and haven't been compiled by the compilation threads. If developer wants to disable the Lazy compilation, we can: ``` Bash mkdir build && cd build cmake .. -DWAMR_BUILD_JIT=1 -DWAMR_BUILD_LAZY_JIT=0 make ``` In which all the WASM functions will be previously compiled before main thread starts to run the wasm module. (5) To enable the `Fast JIT` mode: ``` Bash mkdir build && cd build cmake .. -DWAMR_BUILD_FAST_JIT=1 make ``` The Fast JIT is a lightweight JIT engine with quick startup, small footprint and good portability, and gains ~50% performance of AOT. (6) To enable the `Multi-tier JIT` mode: ``` Bash mkdir build && cd build cmake .. -DWAMR_BUILD_FAST_JTI=1 -DWAMR_BUILD_JIT=1 make ``` The Multi-tier JIT is a two level JIT tier-up engine, which launchs Fast JIT to run the wasm module as soon as possible and creates backend threads to compile the LLVM JIT functions at the same time, and when the LLVM JIT functions are compiled, the runtime will switch the extecution from the Fast JIT jitted code to LLVM JIT jitted code gradually, so as to gain the best performance. ## Linux SGX (Intel Software Guard Extension) Please see [Build and Port WAMR vmcore for Linux SGX](../doc/linux_sgx.md) for the details. ## MacOS Make sure to install Xcode from App Store firstly, and install cmake. If you use Homebrew, install cmake from the command line: ``` Bash brew install cmake ``` Then build the source codes: ``` Bash cd product-mini/platforms/darwin/ mkdir build cd build cmake .. make # iwasm is generated under current directory ``` By default in MacOS, the `fast interpreter`, `AOT` and `Libc WASI` are enabled, and JIT is disabled. And the build target is set to X86_64 or X86_32 depending on the platform's bitwidth. To run a wasm file with interpreter mode: ```Bash iwasm ``` To run an AOT file, firstly please refer to [Build wamrc AOT compiler](../wamr-compiler/README.md) to build wamrc, and then: ```Bash wamrc -o iwasm ``` Note: For how to build the `JIT` mode and `classic interpreter` mode, please refer to [Build iwasm on Linux](../doc/build_wamr.md#linux). WAMR provides some features which can be easily configured by passing options to cmake, please see [WAMR vmcore cmake building configurations](../doc/build_wamr.md#wamr-vmcore-cmake-building-configurations) for details. Currently in MacOS, interpreter, AOT, and builtin libc are enabled by default. ## Windows Make sure `MSVC` and `cmake` are installed and available in the command line environment Then build the source codes: ``` Bash cd product-mini/platforms/windows/ mkdir build cd build cmake .. cmake --build . --config Release # ./Release/iwasm.exe is generated ``` By default in Windows, the `fast interpreter`, `AOT` and `Libc WASI` are enabled, and JIT is disabled. To run a wasm file with interpreter mode: ```Bash iwasm.exe ``` To run an AOT file, firstly please refer to [Build wamrc AOT compiler](../wamr-compiler/README.md) to build wamrc, and then: ```Bash wamrc.exe -o iwasm.exe ``` Note: For how to build the `JIT` mode and `classic interpreter` mode, please refer to [Build iwasm on Linux](../doc/build_wamr.md#linux). WAMR provides some features which can be easily configured by passing options to cmake, please see [WAMR vmcore cmake building configurations](../doc/build_wamr.md#wamr-vmcore-cmake-building-configurations) for details. Currently in Windows, interpreter, AOT, and builtin libc are enabled by default. ## MinGW First make sure the correct CMake package is installed; the following commands are valid for the MSYS2 build environment: ```Bash pacman -R cmake pacman -S mingw-w64-x86_64-cmake pacman -S mingw-w64-x86_64-gcc pacman -S make git ``` Then follow the build instructions for Windows above, and add the following arguments for cmake: ```Bash cmake .. -G"Unix Makefiles" \ -DWAMR_DISABLE_HW_BOUND_CHECK=1 ```` Note that WASI will be disabled until further work is done towards full MinGW support. - Since memory access boundary check with hardware trap feature is disabled, when generating the AOT file with `wamrc`, the `--bounds-checks=1` flag should be added to generate the memory access boundary check instructions to ensure the sandbox security: ```bash wamrc --bounds-checks=1 -o ``` - Compiler complaining about missing `UnwindInfoAddress` field in `RUNTIME_FUNCTION` struct (winnt.h). ## VxWorks VxWorks 7 SR0620 release is validated. First you need to build a VSB. Make sure *UTILS_UNIX* layer is added in the VSB. After the VSB is built, export the VxWorks toolchain path by: ```bash export /host/vx-compiler/bin:$PATH ``` Now switch to iwasm source tree to build the source code: ```bash cd product-mini/platforms/vxworks/ mkdir build cd build cmake .. make ``` Create a VIP based on the VSB. Make sure the following components are added: * INCLUDE_POSIX_PTHREADS * INCLUDE_POSIX_PTHREAD_SCHEDULER * INCLUDE_SHARED_DATA * INCLUDE_SHL Copy the generated iwasm executable, the test WASM binary as well as the needed shared libraries (libc.so.1, libllvm.so.1 or libgnu.so.1 depending on the VSB, libunix.so.1) to a supported file system (eg: romfs). Note: WAMR provides some features which can be easily configured by passing options to cmake, please see [WAMR vmcore cmake building configurations](../doc/build_wamr.md#wamr-vmcore-cmake-building-configurations) for details. Currently in VxWorks, interpreter and builtin libc are enabled by default. ## Zephyr Please refer to this [README](./platforms/zephyr/simple/README.md) under the Zephyr sample directory for details. Note: WAMR provides some features which can be easily configured by passing options to cmake, please see [WAMR vmcore cmake building configurations](../doc/build_wamr.md#wamr-vmcore-cmake-building-configurations) for details. Currently in Zephyr, interpreter, AOT and builtin libc are enabled by default. ## RT-Thread 1. Get rt-thread [system codes](https://github.com/RT-Thread/rt-thread). 2. Enable WAMR software package with menuconfig tool which provided by RT-Thread. * Environment in Linux, run command below: ```bash scons --menuconfig ``` * Environment in Windows ConEmu, run command below: ```bash menuconfig ``` Select and enable `WAMR` in: * RT-Thread online packages * tools packages * WebAssembly Micro Runtime (WAMR) 3. Configure `WAMR` with menuconfig tool. you can choice features of iwasm below: * Enable testing parameters of iwasm * Enable interpreter Mode / Fast interpreter Mode * Use built-libc * Enable AOT 4. Exit menuconfig tool and save configure, update and download package. ```bash pkgs --update ``` 5. build project and download the binary to boards. ```bash scons ``` or build project with 8-thread by using command below: ```bash scons -j8 ``` after project building, you can got an binary file named `rtthread.bin`, then you can download this file to the MCU board. ## Android Able to generate a shared library support Android platform. - need an [android SDK](https://developer.android.com/studio). Go and get the "Command line tools only" - look for a command named *sdkmanager* and download below components. version numbers might need to check and pick others - "build-tools;29.0.3" - "cmake;3.10.2.4988404" - "ndk;latest" - "patcher;v4" - "platform-tools" - "platforms;android-29" - add bin/ of the downloaded cmake to $PATH - export ANDROID_HOME=/the/path/of/downloaded/sdk/ - export ANDROID_NDK_LATEST_HOME=/the/path/of/downloaded/sdk/ndk/2x.xxx/ - ready to go Use such commands, you are able to compile with default configurations. ``` shell $ cd product-mini/platforms/android/ $ mkdir build $ cd build $ cmake .. $ make $ # check output in distribution/wasm $ # include/ includes all necesary head files $ # lib includes libiwasm.so ``` To change the target architecture and ABI, you can define `WAMR_BUILD_TARGET` or `ANDROID_ABI` respectively. To build for [supported Android ABIs](https://developer.android.com/ndk/guides/abis#sa): ```shell $ cmake .. -DWAMR_BUILD_TARGET=X86_32 -DANDROID_ABI=x86 # 32-bit Intel CPU $ cmake .. -DWAMR_BUILD_TARGET=X86_64 -DANDROID_ABI=x86_64 # 64-bit Intel CPU $ cmake .. -DWAMR_BUILD_TARGET=ARMV7A -DANDROID_ABI=armeabi-v7a # 32-bit ARM CPU $ cmake .. -DWAMR_BUILD_TARGET=AARCH64 -DANDROID_ABI=arm64-v8a # 64-bit ARM CPU ``` ## NuttX WAMR is intergrated with NuttX, just enable the WAMR in Kconfig option (Application Configuration/Interpreters). ## ESP-IDF WAMR integrates with ESP-IDF both for the XTENSA and RISC-V chips (esp32x and esp32c3 respectively). In order to use this, you need at least version 4.3.1 of ESP-IDF. If you don't have it installed, follow the instructions [here](https://docs.espressif.com/projects/esp-idf/en/latest/esp32/get-started/#get-started-get-prerequisites). ESP-IDF also installs the toolchains needed for compiling WAMR and ESP-IDF. A small demonstration of how to use WAMR and ESP-IDF can be found under [product_mini](./platforms/esp-idf). The demo builds WAMR for ESP-IDF and runs a small wasm program. In order to run it for your specific Espressif chip, edit the [build_and_run.sh](./platforms/esp-idf/build_and_run.sh) file and put the correct toolchain file (see #Cross-compilation) and `IDF_TARGET`. Before compiling it is also necessary to call ESP-IDF's `export.sh` script to bring all compile time relevant information in scope. ## Docker [Docker](https://www.docker.com/) will download all the dependencies and build WAMR Core on your behalf. Make sure you have Docker installed on your machine: [macOS](https://docs.docker.com/docker-for-mac/install/), [Windows](https://docs.docker.com/docker-for-windows/install/) or [Linux](https://docs.docker.com/install/linux/docker-ce/ubuntu/). Build *iwasm* with the Docker image: ``` Bash $ cd ci $ ./build_wamr.sh $ ls ../build_out/ ``` *build_wamr.sh* will generate *linux* compatible libraries ( libiwasm.so and libvmlib.a ) and an executable binary (*iwasm*) and copy *iwasm* to *build_out*. All original generated files are still under *product-mini/platforms/linux/build*. ## FreeBSD First, install the dependent packages: ```shell sudo pkg install gcc cmake wget ``` Then you can run the following commands to build iwasm with default configurations: ```shell cd product-mini/platforms/freebsd mkdir build && cd build cmake .. make ``` ## AliOS-Things 1. a developerkit board id needed for testing 2. download the AliOS-Things code ``` Bash git clone https://github.com/alibaba/AliOS-Things.git ``` 3. copy /product-mini/platforms/alios-things directory to AliOS-Things/middleware, and rename it as iwasm ``` Bash cp -a /product-mini/platforms/alios-things middleware/iwasm ``` 4. create a link to in middleware/iwasm/ and rename it to wamr ``` Bash ln -s middleware/iwasm/wamr ``` 5. modify file app/example/helloworld/helloworld.c, patch as: ``` C #include #include extern bool iwasm_init(); int application_start(int argc, char *argv[]) { int count = 0; iwasm_init(); ... } ``` 6. modify file app/example/helloworld/aos.mk ``` C $(NAME)_COMPONENTS := osal_aos iwasm ``` 7. build source code and run For linux host: ``` Bash aos make helloworld@linuxhost -c config aos make ./out/helloworld@linuxhost/binary/helloworld@linuxhost.elf ``` For developerkit: Modify file middleware/iwasm/aos.mk, patch as: ``` C WAMR_BUILD_TARGET := THUMBV7M ``` ``` Bash aos make helloworld@developerkit -c config aos make ``` download the binary to developerkit board, check the output from serial port ## Cosmopolitan Libc Currently, only x86_64 architecture with interpreter modes is supported. Setup `cosmocc` as described in [Getting Started](https://github.com/jart/cosmopolitan/#getting-started) being sure to get its `bin` directory into `PATH`. Build iwasm ``` Bash export CC=x86_64-unknown-cosmo-cc export CXX=x86_64-unknown-cosmo-c++ rm -rf build mkdir build cmake -DWAMR_BUILD_INTERP=1 -DWAMR_BUILD_FAST_INTERP=1 -B build cmake --build build -j ``` Run like ``` Bash ./build/iwasm.com ```