WABT (we pronounce it "wabbit") is a suite of tools for WebAssembly, including:
- wat2wasm: translate from WebAssembly text format to the WebAssembly binary format
- wasm2wat: the inverse of wat2wasm, translate from the binary format back to the text format (also known as a .wat)
- wasm-objdump: print information about a wasm binary. Similiar to objdump.
- wasm-interp: decode and run a WebAssembly binary file using a stack-based interpreter
- wasm-decompile: decompile a wasm binary into readable C-like syntax.
- wat-desugar: parse .wat text form as supported by the spec interpreter (s-expressions, flat syntax, or mixed) and print "canonical" flat format
- wasm2c: convert a WebAssembly binary file to a C source and header
- wasm-strip: remove sections of a WebAssembly binary file
- wasm-validate: validate a file in the WebAssembly binary format
- wast2json: convert a file in the wasm spec test format to a JSON file and associated wasm binary files
- wasm-opcodecnt: count opcode usage for instructions
- spectest-interp: read a Spectest JSON file, and run its tests in the interpreter
These tools are intended for use in (or for development of) toolchains or other systems that want to manipulate WebAssembly files. Unlike the WebAssembly spec interpreter (which is written to be as simple, declarative and "speccy" as possible), they are written in C/C++ and designed for easier integration into other systems. Unlike Binaryen these tools do not aim to provide an optimization platform or a higher-level compiler target; instead they aim for full fidelity and compliance with the spec (e.g. 1:1 round-trips with no changes to instructions).
Wabt has been compiled to JavaScript via emscripten. Some of the functionality is available in the following demos:
- Proposal: Name and link to the WebAssembly proposal repo
- flag: Flag to pass to the tool to enable/disable support for the feature
- default: Whether the feature is enabled by default
- binary: Whether wabt can read/write the binary format
- text: Whether wabt can read/write the text format
- validate: Whether wabt can validate the syntax
- interpret: Whether wabt can execute these operations in
wasm-interp
orspectest-interp
Proposal | flag | default | binary | text | validate | interpret |
---|---|---|---|---|---|---|
exception handling | --enable-exceptions |
✓ | ✓ | ✓ | ✓ | |
mutable globals | --disable-mutable-globals |
✓ | ✓ | ✓ | ✓ | ✓ |
nontrapping float-to-int conversions | --disable-saturating-float-to-int |
✓ | ✓ | ✓ | ✓ | ✓ |
sign extension | --disable-sign-extension |
✓ | ✓ | ✓ | ✓ | ✓ |
simd | --enable-simd |
✓ | ✓ | ✓ | ✓ | |
threads | --enable-threads |
✓ | ✓ | ✓ | ✓ | |
multi-value | --disable-multi-value |
✓ | ✓ | ✓ | ✓ | ✓ |
tail-call | --enable-tail-call |
✓ | ✓ | ✓ | ✓ | |
bulk memory | --enable-bulk-memory |
✓ | ✓ | ✓ | ✓ | |
reference types | --enable-reference-types |
✓ | ✓ | ✓ | ✓ | |
annotations | --enable-annotations |
✓ | ||||
memory64 | --enable-memory64 |
Clone as normal, but don't forget to get the submodules as well:
$ git clone --recursive https://github.com/WebAssembly/wabt
$ cd wabt
This will fetch the testsuite and gtest repos, which are needed for some tests.
You'll need CMake. You can then run CMake, the normal way:
$ mkdir build
$ cd build
$ cmake ..
$ cmake --build .
This will produce build files using CMake's default build generator. Read the CMake documentation for more information.
NOTE: You must create a separate directory for the build artifacts (e.g. build
above).
Running cmake
from the repo root directory will not work since the build produces an
executable called wasm2c
which conflicts with the wasm2c
directory.
NOTE: Under the hood, this uses make
to run CMake, which then calls make
again.
On some systems (typically macOS), this doesn't build properly. If you see these errors,
you can build using CMake directly as described above.
You'll need CMake. If you just run make
, it will run CMake for you,
and put the result in bin/clang/Debug/
by default:
Note: If you are on macOS, you will need to use CMake version 3.2 or higher
$ make
This will build the default version of the tools: a debug build using the Clang compiler.
There are many make targets available for other configurations as well. They are generated from every combination of a compiler, build type and configuration.
- compilers:
gcc
,clang
,gcc-i686
,emcc
- build types:
debug
,release
- configurations: empty,
asan
,msan
,lsan
,ubsan
,fuzz
,no-tests
They are combined with dashes, for example:
$ make clang-debug
$ make gcc-i686-release
$ make clang-debug-lsan
$ make gcc-debug-no-tests
You'll need CMake. You'll also need Visual Studio (2015 or newer) or MinGW.
Note: Visual Studio 2017 and later come with CMake (and the Ninja build system) out of the box, and should be on your PATH if you open a Developer Command prompt. See https://aka.ms/cmake for more details.
You can run CMake from the command prompt, or use the CMake GUI tool. See Running CMake for more information.
When running from the commandline, create a new directory for the build artifacts, then run cmake from this directory:
> cd [build dir]
> cmake [wabt project root] -DCMAKE_BUILD_TYPE=[config] -DCMAKE_INSTALL_PREFIX=[install directory] -G [generator]
The [config]
parameter should be a CMake build type, typically DEBUG
or RELEASE
.
The [generator]
parameter should be the type of project you want to generate,
for example "Visual Studio 14 2015"
. You can see the list of available
generators by running cmake --help
.
To build the project, you can use Visual Studio, or you can tell CMake to do it:
> cmake --build [wabt project root] --config [config] --target install
This will build and install to the installation directory you provided above.
So, for example, if you want to build the debug configuration on Visual Studio 2015:
> mkdir build
> cd build
> cmake .. -DCMAKE_BUILD_TYPE=DEBUG -DCMAKE_INSTALL_PREFIX=..\ -G "Visual Studio 14 2015"
> cmake --build . --config DEBUG --target install
If you want to add new keywords, you'll need to install
gperf. Before you upload your PR, please
run make update-gperf
to update the prebuilt C++ sources in src/prebuilt/
.
Some examples:
# parse and typecheck test.wat
$ bin/wat2wasm test.wat
# parse test.wat and write to binary file test.wasm
$ bin/wat2wasm test.wat -o test.wasm
# parse spec-test.wast, and write verbose output to stdout (including the
# meaning of every byte)
$ bin/wat2wasm spec-test.wast -v
You can use --help
to get additional help:
$ bin/wat2wasm --help
Or try the online demo.
Some examples:
# parse binary file test.wasm and write text file test.wat
$ bin/wasm2wat test.wasm -o test.wat
# parse test.wasm and write test.wat
$ bin/wasm2wat test.wasm -o test.wat
You can use --help
to get additional help:
$ bin/wasm2wat --help
Or try the online demo.
Some examples:
# parse binary file test.wasm, and type-check it
$ bin/wasm-interp test.wasm
# parse test.wasm and run all its exported functions
$ bin/wasm-interp test.wasm --run-all-exports
# parse test.wasm, run the exported functions and trace the output
$ bin/wasm-interp test.wasm --run-all-exports --trace
# parse test.json and run the spec tests
$ bin/wasm-interp test.json --spec
# parse test.wasm and run all its exported functions, setting the value stack
# size to 100 elements
$ bin/wasm-interp test.wasm -V 100 --run-all-exports
You can use --help
to get additional help:
$ bin/wasm-interp --help
See wast2json.md.
For example:
# parse binary file test.wasm and write text file test.dcmp
$ bin/wasm-decompile test.wasm -o test.dcmp
You can use --help
to get additional help:
$ bin/wasm-decompile --help
See decompiler.md for more information on the language being generated.
See wasm2c.md
See test/README.md.
To build with the LLVM sanitizers, append the sanitizer name to the target:
$ make clang-debug-asan
$ make clang-debug-msan
$ make clang-debug-lsan
$ make clang-debug-ubsan
There are configurations for the Address Sanitizer (ASAN), Memory Sanitizer (MSAN), Leak Sanitizer (LSAN) and Undefine Behavior Sanitizer (UBSAN). You can read about the behaviors of the sanitizers in the link above, but essentially the Address Sanitizer finds invalid memory accesses (use after free, access out-of-bounds, etc.), Memory Sanitizer finds uses of uninitialized memory, the Leak Sanitizer finds memory leaks, and the Undefined Behavior Sanitizer finds undefined behavior (surprise!).
Typically, you'll just want to run all the tests for a given sanitizer:
$ make test-asan
You can also run the tests for a release build:
$ make test-clang-release-asan
...
The Travis bots run all of these tests (and more). Before you land a change,
you should run them too. One easy way is to use the test-everything
target:
$ make test-everything
To run everything the Travis bots do, you can use the following scripts:
$ CC=gcc scripts/travis-build.sh
$ CC=gcc scripts/travis-test.sh
$ CC=clang scripts/travis-build.sh
$ CC=clang scripts/travis-test.sh
To build using the LLVM fuzzer support,
append fuzz
to the target:
$ make clang-debug-fuzz
This will produce a wasm2wat_fuzz
binary. It can be used to fuzz the binary
reader, as well as reproduce fuzzer errors found by
oss-fuzz.
$ out/clang/Debug/fuzz/wasm2wat_fuzz ...
See the libFuzzer documentation for more information about how to use this tool.