This crate is meant to provide a quick and simple way to integrate a runtime javacript or typescript component from within rust.
It uses the v8 engine through the deno_core crate, and is meant to be as simple as possible to use without sacrificing flexibility or performance.
I also have attempted to abstract away the v8 engine details so you can for the most part operate directly on rust types.
- By default, the code being run is entirely sandboxed from the host, having no filesystem or network access.
- It can be extended to include those capabilities and more if desired - please see the 'web' feature, and the 'runtime_extensions' example
- Asynchronous JS code is supported (I suggest using the timeout option when creating your runtime)
- Loaded JS modules can import other modules
- Typescript is supported by default, and will be transpiled into JS for execution
Here is a very basic use of this crate to execute a JS module. It will:
- Create a basic runtime
- Load a javascript module,
- Call a function registered as the entrypoint
- Return the resulting value
use rustyscript::{json_args, Runtime, Module, Error};
let module = Module::new(
"test.js",
"
export default (string, integer) => {
console.log(`Hello world: string=${string}, integer=${integer}`);
return 2;
}
"
);
let value: usize = Runtime::execute_module(
&module, vec![],
Default::default(),
json_args!("test", 5)
)?;
assert_eq!(value, 2);
Modules can also be loaded from the filesystem with [Module::load] or [Module::load_dir] if you want to collect all modules in a given directory.
If all you need is the result of a single javascript expression, you can use:
let result: i64 = rustyscript::evaluate("5 + 5").expect("The expression was invalid!");
Or to just import a single module for use:
use rustyscript::{json_args, import};
let mut module = import("js/my_module.js").expect("Something went wrong!");
let value: String = module.call("exported_function_name", json_args!()).expect("Could not get a value!");
There are a few other utilities included, such as [validate] and [resolve_path]
A more detailed version of the crate's usage can be seen below, which breaks down the steps instead of using the one-liner [Runtime::execute_module]:
use rustyscript::{json_args, Runtime, RuntimeOptions, Module, Error, Undefined};
use std::time::Duration;
let module = Module::new(
"test.js",
"
let internalValue = 0;
export const load = (value) => internalValue = value;
export const getValue = () => internalValue;
"
);
// Create a new runtime
let mut runtime = Runtime::new(RuntimeOptions {
timeout: Duration::from_millis(50), // Stop execution by force after 50ms
default_entrypoint: Some("load".to_string()), // Run this as the entrypoint function if none is registered
..Default::default()
})?;
// The handle returned is used to get exported functions and values from that module.
// We then call the entrypoint function, but do not need a return value.
//Load can be called multiple times, and modules can import other loaded modules
// Using `import './filename.js'`
let module_handle = runtime.load_module(&module)?;
runtime.call_entrypoint::<Undefined>(&module_handle, json_args!(2))?;
// Functions don't need to be the entrypoint to be callable!
let internal_value: i64 = runtime.call_function(Some(&module_handle), "getValue", json_args!())?;
There are also '_async' and 'immediate' versions of most runtime functions; '_async' functions return a future that resolves to the result of the operation, while '_immediate' functions will make no attempt to wait for the event loop, making them suitable for using [crate::js_value::Promise]
Rust functions can also be registered to be called from javascript:
use rustyscript::{ Runtime, Module, serde_json::Value };
let module = Module::new("test.js", " rustyscript.functions.foo(); ");
let mut runtime = Runtime::new(Default::default())?;
runtime.register_function("foo", |args| {
if let Some(value) = args.get(0) {
println!("called with: {}", value);
}
Ok(Value::Null)
})?;
runtime.load_module(&module)?;
Asynchronous JS can be called in 2 ways;
The first is to use the 'async' keyword in JS, and then call the function using [Runtime::call_function_async]
use rustyscript::{ Runtime, Module, json_args };
let module = Module::new("test.js", "export async function foo() { return 5; }");
let mut runtime = Runtime::new(Default::default())?;
// The runtime has its own tokio runtime; you can get a handle to it with [Runtime::tokio_runtime]
// You can also build the runtime with your own tokio runtime, see [Runtime::with_tokio_runtime]
let tokio_runtime = runtime.tokio_runtime();
let result: i32 = tokio_runtime.block_on(async {
// Top-level await is supported - we can load modules asynchronously
let handle = runtime.load_module_async(&module).await?;
// Call the function asynchronously
runtime.call_function_async(Some(&handle), "foo", json_args!()).await
})?;
assert_eq!(result, 5);
The second is to use [crate::js_value::Promise]
use rustyscript::{ Runtime, Module, js_value::Promise, json_args };
let module = Module::new("test.js", "export async function foo() { return 5; }");
let mut runtime = Runtime::new(Default::default())?;
let handle = runtime.load_module(&module)?;
// We call the function without waiting for the event loop to run, or for the promise to resolve
// This way we can store it and wait for it later, without blocking the event loop or borrowing the runtime
let result: Promise<i32> = runtime.call_function_immediate(Some(&handle), "foo", json_args!())?;
// We can then wait for the promise to resolve
// We can do so asynchronously, using [crate::js_value::Promise::into_future]
// But we can also block the current thread:
let result = result.into_value(&mut runtime)?;
assert_eq!(result, 5);
- See [Runtime::register_async_function] for registering and calling async rust from JS
- See 'examples/async_javascript.rs' for a more detailed example of using async JS
For better performance calling rust code, consider using an extension instead of a module - see the 'runtime_extensions' example for details
A threaded worker can be used to run code in a separate thread, or to allow multiple concurrent runtimes.
the [worker] module provides a simple interface to create and interact with workers. The [worker::InnerWorker] trait can be implemented to provide custom worker behavior.
It also provides a default worker implementation that can be used without any additional setup:
use rustyscript::{Error, worker::{Worker, DefaultWorker, DefaultWorkerOptions}};
use std::time::Duration;
fn main() -> Result<(), Error> {
let worker = DefaultWorker::new(DefaultWorkerOptions {
default_entrypoint: None,
timeout: Duration::from_secs(5),
})?;
let result: i32 = worker.eval("5 + 5".to_string())?;
assert_eq!(result, 10);
Ok(())
}
These functions provide simple one-liner access to common features of this crate:
- evaluate; Evaluate a single JS expression and return the resulting value
- import; Get a handle to a JS module from which you can get exported values and functions
- resolve_path; Resolve a relative path to the current working dir
- validate; Validate the syntax of a JS expression
- init_platform; Initialize the V8 platform for multi-threaded applications
The table below lists the available features for this crate. Features marked at Preserves Sandbox: NO
break isolation between loaded JS modules and the host system.
Use with caution.
More details on the features can be found in Cargo.toml
Please note that the 'web' feature will also enable fs_import and url_import, allowing arbitrary filesystem and network access for import statements
- This is because the deno_web crate allows both fetch and FS reads already
Feature | Description | Preserves Sandbox | Dependencies |
---|---|---|---|
cache | Implements the Cache API for Deno | NO | deno_cache, deno_webidl, deno_web, deno_crypto, deno_fetch, deno_url, deno_net |
console | Provides console.* functionality from JS |
yes | deno_console |
crypto | Provides crypto.* functionality from JS |
yes | deno_crypto, deno_webidl |
url | Provides the URL, and URLPattern APIs from within JS | yes | deno_webidl, deno_url |
io | Provides IO primitives such as stdio streams and abstraction over File System files. | NO | deno_io, rustyline, winapi, nix, libc, once_cell |
web | Provides the Event, TextEncoder, TextDecoder, File, Web Cryptography, and fetch APIs from within JS | NO | deno_webidl, deno_web, deno_crypto, deno_fetch, deno_url, deno_net |
webstorage | Provides the WebStorage API | NO | deno_webidl, deno_webstorage |
webidl | Provides the webidl API | yes | deno_webidl |
default | Provides only those extensions that preserve sandboxing | yes | deno_console, deno_crypto, deno_webidl, deno_url |
no_extensions | Disables all extensions to the JS runtime - you can still add your own extensions in this mode | yes | None |
all | Provides all available functionality | NO | deno_console, deno_webidl, deno_web, deno_net, deno_crypto, deno_fetch, deno_url |
fs_import | Enables importing arbitrary code from the filesystem through JS | NO | None |
url_import | Enables importing arbitrary code from network locations through JS | NO | reqwest |
worker | Enables access to the threaded worker API [worker] | yes | None |
snapshot_builder | Enables access to [SnapshotBuilder], a runtime for creating snapshots that can improve start-times | yes | None |
web_stub | Enables a subset of web features that do not break sandboxing |
yes | deno_webidl |
Please also check out @Bromeon/js_sandbox, another great crate in this niche