build_wamr.md

Build WAMR vmcore

WAMR vmcore is a set of runtime libraries for loading and running Wasm modules. This document introduces how to build the WAMR vmcore.

References:

• how to build iwasm: building different target platforms such as Linux, Windows, Mac etc
• Blog: Introduction to WAMR running modes

WAMR vmcore cmake building configurations

By including the script runtime_lib.cmake under folder build-scripts in CMakeList.txt, it is easy to use vmcore to build host software with cmake.

# add this into your CMakeList.txt
include (${WAMR_ROOT_DIR}/build-scripts/runtime_lib.cmake)
add_library(vmlib ${WAMR_RUNTIME_LIB_SOURCE})

The script runtime_lib.cmake defines a number of variables for configuring the WAMR runtime features. You can set these variables in your CMakeList.txt or pass the configurations from cmake command line.

Configure platform and architecture

• WAMR_BUILD_PLATFORM: set the target platform. It can be set to any platform name (folder name) under folder core/shared/platform.

• WAMR_BUILD_TARGET: set the target CPU architecture. Current supported targets are: X86_64, X86_32, AARCH64, ARM, THUMB, XTENSA, ARC, RISCV32, RISCV64 and MIPS.

  • For ARM and THUMB, the format is <arch>[<sub-arch>][_VFP], where <sub-arch> is the ARM sub-architecture and the "_VFP" suffix means using VFP coprocessor registers s0-s15 (d0-d7) for passing arguments or returning results in standard procedure-call. Both <sub-arch> and "_VFP" are optional, e.g. ARMV7, ARMV7_VFP, THUMBV7, THUMBV7_VFP and so on.
  • For AARCH64, the format is<arch>[<sub-arch>], VFP is enabled by default. <sub-arch> is optional, e.g. AARCH64, AARCH64V8, AARCH64V8.1 and so on.
  • For RISCV64, the format is <arch>[_abi], where "_abi" is optional, currently the supported formats are RISCV64, RISCV64_LP64D and RISCV64_LP64: RISCV64 and RISCV64_LP64D are identical, using LP64D as abi (LP64 with hardware floating-point calling convention for FLEN=64). And RISCV64_LP64 uses LP64 as abi (Integer calling-convention only, and hardware floating-point calling convention is not used).
  • For RISCV32, the format is <arch>[_abi], where "_abi" is optional, currently the supported formats are RISCV32, RISCV32_ILP32D and RISCV32_ILP32: RISCV32 and RISCV32_ILP32D are identical, using ILP32D as abi (ILP32 with hardware floating-point calling convention for FLEN=64). And RISCV32_ILP32 uses ILP32 as abi (Integer calling-convention only, and hardware floating-point calling convention is not used).

cmake -DWAMR_BUILD_PLATFORM=linux -DWAMR_BUILD_TARGET=ARM

Configure interpreters

• WAMR_BUILD_INTERP=1/0: enable or disable WASM interpreter

• WAMR_BUILD_FAST_INTERP=1/0: build fast (default) or classic WASM interpreter.

  NOTE: the fast interpreter runs ~2X faster than classic interpreter, but consumes about 2X memory to hold the pre-compiled code.

Configure AOT and JITs

• WAMR_BUILD_AOT=1/0, enable AOT or not, default to enable if not set
• WAMR_BUILD_JIT=1/0, enable LLVM JIT or not, default to disable if not set
• WAMR_BUILD_FAST_JIT=1/0, enable Fast JIT or not, default to disable if not set
• WAMR_BUILD_FAST_JIT=1 and WAMR_BUILD_JIT=1, enable Multi-tier JIT, default to disable if not set

Configure LIBC

• WAMR_BUILD_LIBC_BUILTIN=1/0, build the built-in libc subset for WASM app, default to enable if not set

• WAMR_BUILD_LIBC_WASI=1/0, build the WASI libc subset for WASM app, default to enable if not set

• WAMR_BUILD_LIBC_UVWASI=1/0 (Experiment), build the WASI libc subset for WASM app based on uvwasi implementation, default to disable if not set

Note: for platform which doesn't support WAMR_BUILD_LIBC_WASI, e.g. Windows, developer can try using WAMR_BUILD_LIBC_UVWASI.

Enable Multi-Module feature

• WAMR_BUILD_MULTI_MODULE=1/0, default to disable if not set

Enable WASM mini loader

• WAMR_BUILD_MINI_LOADER=1/0, default to disable if not set

Note: the mini loader doesn't check the integrity of the WASM binary file, developer must ensure that the WASM file is well-formed.

Enable shared memory feature

• WAMR_BUILD_SHARED_MEMORY=1/0, default to disable if not set

Enable bulk memory feature

• WAMR_BUILD_BULK_MEMORY=1/0, default to disable if not set

Enable thread manager

• WAMR_BUILD_THREAD_MGR=1/0, default to disable if not set

Enable lib-pthread

• WAMR_BUILD_LIB_PTHREAD=1/0, default to disable if not set

Note: The dependent feature of lib pthread such as the shared memory and thread manager will be enabled automatically.

Enable lib-pthread-semaphore

• WAMR_BUILD_LIB_PTHREAD_SEMAPHORE=1/0, default to disable if not set

Note: This feature depends on lib-pthread, it will be enabled automatically if this feature is enabled.

Enable lib wasi-threads

• WAMR_BUILD_LIB_WASI_THREADS=1/0, default to disable if not set

Note: The dependent feature of lib wasi-threads such as the shared memory and thread manager will be enabled automatically.

Enable lib wasi-nn

• WAMR_BUILD_WASI_NN=1/0, default to disable if not set

Enable lib wasi-nn GPU mode

• WASI_NN_ENABLE_GPU=1/0, default to disable if not set

Disable boundary check with hardware trap

• WAMR_DISABLE_HW_BOUND_CHECK=1/0, default to enable if not set and supported by platform

Note: by default only platform linux/darwin/android/windows/vxworks 64-bit will enable the boundary check with hardware trap feature, for 32-bit platforms it's automatically disabled even when the flag is set to 0, and the wamrc tool will generate AOT code without boundary check instructions in all 64-bit targets except SGX to improve performance. The boundary check includes linear memory access boundary and native stack access boundary, if WAMR_DISABLE_STACK_HW_BOUND_CHECK below isn't set.

Disable native stack boundary check with hardware trap

• WAMR_DISABLE_STACK_HW_BOUND_CHECK=1/0, default to enable if not set and supported by platform, same as WAMR_DISABLE_HW_BOUND_CHECK.

Note: When boundary check with hardware trap is disabled, or WAMR_DISABLE_HW_BOUND_CHECK is set to 1, the native stack boundary check with hardware trap will be disabled too, no matter what value is set to WAMR_DISABLE_STACK_HW_BOUND_CHECK. And when boundary check with hardware trap is enabled, the status of this feature is set according to the value of WAMR_DISABLE_STACK_HW_BOUND_CHECK.

Enable tail call feature

• WAMR_BUILD_TAIL_CALL=1/0, default to disable if not set

Enable 128-bit SIMD feature

• WAMR_BUILD_SIMD=1/0, default to enable if not set

Note: only supported in AOT mode x86-64 target.

Configure Debug

• WAMR_BUILD_CUSTOM_NAME_SECTION=1/0, load the function name from custom name section, default to disable if not set

Enable dump call stack feature

• WAMR_BUILD_DUMP_CALL_STACK=1/0, default to disable if not set

Note: if it is enabled, the call stack will be dumped when exception occurs.

• For interpreter mode, the function names are firstly extracted from custom name section, if this section doesn't exist or the feature is not enabled, then the name will be extracted from the import/export sections
• For AOT/JIT mode, the function names are extracted from import/export section, please export as many functions as possible (for wasi-sdk you can use -Wl,--export-all) when compiling wasm module, and add --enable-dump-call-stack option to wamrc during compiling AOT module.

Enable memory profiling (Experiment)

• WAMR_BUILD_MEMORY_PROFILING=1/0, default to disable if not set

Note: if it is enabled, developer can use API void wasm_runtime_dump_mem_consumption(wasm_exec_env_t exec_env) to dump the memory consumption info. Currently we only profile the memory consumption of module, module_instance and exec_env, the memory consumed by other components such as wasi-ctx, multi-module and thread-manager are not included.

Enable performance profiling (Experiment)

• WAMR_BUILD_PERF_PROFILING=1/0, default to disable if not set

Note: if it is enabled, developer can use API void wasm_runtime_dump_perf_profiling(wasm_module_inst_t module_inst) to dump the performance consumption info. Currently we only profile the performance consumption of each WASM function.

The function name searching sequence is the same with dump call stack feature.

Enable the global heap

• WAMR_BUILD_GLOBAL_HEAP_POOL=1/0, default to disable if not set for all iwasm applications, except for the platforms Alios and Zephyr.

WAMR_BUILD_GLOBAL_HEAP_POOL is used in the iwasm applications provided in the directory product-mini. When writing your own host application using WAMR, if you want to use a global heap and allocate memory from it, you must set the initialization argument mem_alloc_type to Alloc_With_Pool. The global heap is defined in the documentation Memory model and memory usage tunning.

Set the global heap size

• WAMR_BUILD_GLOBAL_HEAP_SIZE=n, default to 10 MB (10485760) if not set for all iwasm applications, except for the platforms Alios (256 kB), Riot (256 kB) and Zephyr (128 kB).

WAMR_BUILD_GLOBAL_HEAP_SIZE is used in the iwasm applications provided in the directory product-mini. When writing your own host application using WAMR, if you want to set the amount of memory dedicated to the global heap pool, you must set the initialization argument mem_alloc_option.pool with the appropriate values. The global heap is defined in the documentation Memory model and memory usage tunning. Note: if WAMR_BUILD_GLOBAL_HEAP_SIZE is not set and the flag WAMR_BUILD_SPEC_TEST is set, the global heap size is equal to 300 MB (314572800), or 100 MB (104857600) when compiled for Intel SGX (Linux).

Set maximum app thread stack size

• WAMR_APP_THREAD_STACK_SIZE_MAX=n, default to 8 MB (8388608) if not set

Note: the AOT boundary check with hardware trap mechanism might consume large stack since the OS may lazily grow the stack mapping as a guard page is hit, we may use this configuration to reduce the total stack usage, e.g. -DWAMR_APP_THREAD_STACK_SIZE_MAX=131072 (128 KB).

WAMR_BH_VPRINTF=<vprintf_callback>, default to disable if not set

Note: if the vprintf_callback function is provided by developer, the os_printf() and os_vprintf() in Linux, Darwin, Windows and VxWorks platforms, besides WASI Libc output will call the callback function instead of libc vprintf() function to redirect the stdout output. For example, developer can define the callback function like below outside runtime lib:

int my_vprintf(const char *format, va_list ap)
{
    /* output to pre-opened file stream */
    FILE *my_file = ...;
    return vfprintf(my_file, format, ap);
    /* or output to pre-opened file descriptor */
    int my_fd = ...;
    return vdprintf(my_fd, format, ap);
    /* or output to string buffer and print the string */
    char buf[128];
    vsnprintf(buf, sizeof(buf), format, ap);
    return my_printf("%s", buf);
}

and then use cmake -DWAMR_BH_VPRINTF=my_vprintf .. to pass the callback function, or add BH_VPRINTF=my_vprintf macro for the compiler, e.g. add line add_defintions(-DBH_VPRINTF=my_vprintf) in CMakeListst.txt.

Enable reference types feature

• WAMR_BUILD_REF_TYPES=1/0, default to disable if not set

Exclude WAMR application entry functions

• WAMR_DISABLE_APP_ENTRY=1/0, default to disable if not set

Note: The WAMR application entry (core/iwasm/common/wasm_application.c) encapsulate some common process to instantiate, execute the wasm functions and print the results. Some platform related APIs are used in these functions, so you can enable this flag to exclude this file if your platform doesn't support those APIs. Don't enable this flag if you are building product-mini

Enable source debugging features

• WAMR_BUILD_DEBUG_INTERP=1/0, default to 0 if not set

Note: There are some other setup required by source debugging, please refer to source_debugging.md for more details.

Enable load wasm custom sections

• WAMR_BUILD_LOAD_CUSTOM_SECTION=1/0, default to disable if not set

Note: By default, the custom sections are ignored. If the embedder wants to get custom sections from wasm_module_t, then WAMR_BUILD_LOAD_CUSTOM_SECTION should be enabled, and then wasm_runtime_get_custom_section can be used to get a custom section by name.

Note: If WAMR_BUILD_CUSTOM_NAME_SECTION is enabled, then the custom name section will be treated as a special section and consumed by the runtime, not available to the embedder.

For AoT file, must use --emit-custom-sections to specify which sections need to be emitted into AoT file, otherwise all custom sections (except custom name section) will be ignored.

Stack guard size

• WAMR_BUILD_STACK_GUARD_SIZE=n, default to N/A if not set.

Note: By default, the stack guard size is 1K (1024) or 24K (if uvwasi enabled).

**Disable the writing linear memory base address to x86 GS segment register

• WAMR_DISABLE_WRITE_GS_BASE=1/0, default to enable if not set and supported by platform

Note: by default only platform linux x86-64 will enable this feature, for 32-bit platforms it's automatically disabled even when the flag is set to 0. In linux x86-64, writing the linear memory base address to x86 GS segment register may be used to speedup the linear memory access for LLVM AOT/JIT, when --enable-segue=[<flags>] option is added for wamrc or iwasm.

Enable running PGO(Profile-Guided Optimization) instrumented AOT file

• WAMR_BUILD_STATIC_PGO=1/0, default to disable if not set

Combination of configurations:

We can combine the configurations. For example, if we want to disable interpreter, enable AOT and WASI, we can run command:

cmake .. -DWAMR_BUILD_INTERP=0 -DWAMR_BUILD_AOT=1 -DWAMR_BUILD_LIBC_WASI=0 -DWAMR_BUILD_PLATFORM=linux

Or if we want to enable interpreter, disable AOT and WASI, and build as X86_32, we can run command:

cmake .. -DWAMR_BUILD_INTERP=1 -DWAMR_BUILD_AOT=0 -DWAMR_BUILD_LIBC_WASI=0 -DWAMR_BUILD_TARGET=X86_32