# Using WebAssembly from Rust This document shows an example of how to embed Wasmtime using the [Rust API][apidoc] to execute a simple wasm program. Be sure to also check out the [full API documentation][apidoc] for a full listing of what the [`wasmtime` crate][wasmtime] has to offer and the [book examples for Rust](./examples-rust-embed.md) for more information. [apidoc]: https://bytecodealliance.github.io/wasmtime/api/wasmtime/ [wasmtime]: https://crates.io/crates/wasmtime ## Creating the WebAssembly to execute Creation of a WebAssembly file is generally covered by the [Writing WebAssembly chapter](./wasm.md), so we'll just assume that you've already got a wasm file on hand for the rest of this tutorial. To make things simple we'll also just assume you've got a `hello.wat` file which looks like this: ```wat (module (func (export "answer") (result i32) i32.const 42 ) ) ``` Here we're just exporting one function which returns an integer that we'll read from Rust. ## Hello, World! First up let's create a rust project ```sh $ cargo new --bin wasmtime_hello $ cd wasmtime_hello ``` Next you'll want to add `hello.wat` to the root of your project. We will be using the `wasmtime` crate to run the wasm file, so next up we need a dependency in `Cargo.toml`: ```toml [dependencies] wasmtime = "1.0.0" ``` Next up let's write the code that we need to execute this wasm file. The simplest version of this looks like so: ```rust,no_run # extern crate wasmtime; use std::error::Error; use wasmtime::*; fn main() -> Result<(), Box> { // An engine stores and configures global compilation settings like // optimization level, enabled wasm features, etc. let engine = Engine::default(); # if false { // We start off by creating a `Module` which represents a compiled form // of our input wasm module. In this case it'll be JIT-compiled after // we parse the text format. let module = Module::from_file(&engine, "hello.wat")?; # } # let module = Module::new(&engine, r#"(module (func (export "answer") (result i32) i32.const 42))"#)?; // A `Store` is what will own instances, functions, globals, etc. All wasm // items are stored within a `Store`, and it's what we'll always be using to // interact with the wasm world. Custom data can be stored in stores but for // now we just use `()`. let mut store = Store::new(&engine, ()); // With a compiled `Module` we can then instantiate it, creating // an `Instance` which we can actually poke at functions on. let instance = Instance::new(&mut store, &module, &[])?; // The `Instance` gives us access to various exported functions and items, // which we access here to pull out our `answer` exported function and // run it. let answer = instance.get_func(&mut store, "answer") .expect("`answer` was not an exported function"); // There's a few ways we can call the `answer` `Func` value. The easiest // is to statically assert its signature with `typed` (in this case // asserting it takes no arguments and returns one i32) and then call it. let answer = answer.typed::<(), i32>(&store)?; // And finally we can call our function! Note that the error propagation // with `?` is done to handle the case where the wasm function traps. let result = answer.call(&mut store, ())?; println!("Answer: {:?}", result); Ok(()) } ``` We can build and execute our example with `cargo run`. Note that by depending on `wasmtime` you're depending on a JIT compiler, so it may take a moment to build all of its dependencies: ```sh $ cargo run Compiling ... ... Finished dev [unoptimized + debuginfo] target(s) in 42.32s Running `wasmtime_hello/target/debug/wasmtime_hello` Answer: 42 ``` and there we go! We've now executed our first WebAssembly in `wasmtime` and gotten the result back. ## Importing Host Functionality What we've just seen is a pretty small example of how to call a wasm function and take a look at the result. Most interesting wasm modules, however, are going to import some functions to do something a bit more interesting. For that you'll need to provide imported functions from Rust for wasm to call! Let's take a look at a wasm module which imports a logging function as well as some simple arithmetic from the environment. ```wat (module (import "" "log" (func $log (param i32))) (import "" "double" (func $double (param i32) (result i32))) (func (export "run") i32.const 0 call $log i32.const 1 call $log i32.const 2 call $double call $log ) ) ``` This wasm module will call our `"log"` import a few times and then also call the `"double"` import. We can compile and instantiate this module with code that looks like this: ```rust,no_run # extern crate wasmtime; use std::error::Error; use wasmtime::*; struct Log { integers_logged: Vec, } fn main() -> Result<(), Box> { let engine = Engine::default(); # if false { let module = Module::from_file(&engine, "hello.wat")?; # } # let module = Module::new(&engine, r#"(module (import "" "log" (func $log (param i32))) (import "" "double" (func $double (param i32) (result i32))) (func (export "run") i32.const 0 call $log i32.const 1 call $log i32.const 2 call $double call $log))"#)?; // For host-provided functions it's recommended to use a `Linker` which does // name-based resolution of functions. let mut linker = Linker::new(&engine); // First we create our simple "double" function which will only multiply its // input by two and return it. linker.func_wrap("", "double", |param: i32| param * 2)?; // Next we define a `log` function. Note that we're using a // Wasmtime-provided `Caller` argument to access the state on the `Store`, // which allows us to record the logged information. linker.func_wrap("", "log", |mut caller: Caller<'_, Log>, param: u32| { println!("log: {}", param); caller.data_mut().integers_logged.push(param); })?; // As above, instantiation always happens within a `Store`. This means to // actually instantiate with our `Linker` we'll need to create a store. Note // that we're also initializing the store with our custom data here too. // // Afterwards we use the `linker` to create the instance. let data = Log { integers_logged: Vec::new() }; let mut store = Store::new(&engine, data); let instance = linker.instantiate(&mut store, &module)?; // Like before, we can get the run function and execute it. let run = instance.get_typed_func::<(), ()>(&mut store, "run")?; run.call(&mut store, ())?; // We can also inspect what integers were logged: println!("logged integers: {:?}", store.data().integers_logged); Ok(()) } ``` Note that there's a number of ways to define a `Func`, be sure to [consult its documentation][`Func`] for other ways to create a host-defined function. [`Func`]: https://bytecodealliance.github.io/wasmtime/api/wasmtime/struct.Func.html