The compilation part is effectively a cherry pick from master
37 KiB
Design of wasm-bindgen
This is intended to be a bit of a deep-dive into how wasm-bindgen
works today,
specifically for Rust. If you're reading this far in the future it may no longer
be up to date, but feel free to ping me and I can try to answer questions and/or
update this!
Foundation: ES Modules
The first thing to know about wasm-bindgen
is that it's fundamentally built on
the idea of ES Modules. In other words this tool takes an opinionated stance
that wasm files should be viewed as ES6 modules. This means that you can
import
from a wasm file, use its export
-ed functionality, etc, from normal
JS files.
Now unfortunately at the time of this writing the interface of wasm interop
isn't very rich. Wasm modules can only call functions or export functions that
deal exclusively with i32
, i64
, f32
, and f64
. Bummer!
That's where this project comes in. The goal of wasm-bindgen
is to enhance the
"ABI" of wasm modules with richer types like classes, JS objects, Rust structs,
strings, etc. Keep in mind, though, that everything is based on ES Modules! This
means that the compiler is actually producing a "broken" wasm file of sorts. The
wasm file emitted by rustc, for example, does not have the interface we would
like to have. Instead it requires the wasm-bindgen
tool to postprocess the
file, generating a foo.js
and foo_bg.wasm
file. The foo.js
file is the
desired interface expressed in JS (classes, types, strings, etc) and the
foo_bg.wasm
module is simply used as an implementation detail (it was
lightly modified from the original foo.wasm
file).
Foundation #2: Unintrusive in Rust
On the more Rust-y side of things the wasm-bindgen
crate is designed to
ideally have as minimal impact on a Rust crate as possible. Ideally a few
#[wasm_bindgen]
attributes are annotated in key locations and otherwise you're
off to the races, but otherwise it strives to both not invent new syntax and
work with existing idioms today.
For example the #[no_mangle]
and extern
ABI indicators are required for
annotated free functions with #[wasm_bindgen]
, because these two snippets are
actually equivalent:
#[no_mangle]
pub extern fn only_integers(a: i32) -> u32 {
// ...
}
// is equivalent to...
#[wasm_bindgen]
pub fn only_integers_with_wasm_bindgen(a: i32) -> u32 {
// ...
}
Additionally the design here with minimal intervention in Rust should allow us
to easily take advantage of the upcoming host bindings proposal. Ideally
you'd simply upgrade wasm-bindgen
-the-crate as well as your toolchain and
you're immediately getting raw access to host bindings! (this is still a bit of
a ways off though...)
Polyfill for "JS objects in wasm"
One of the main goals of wasm-bindgen
is to allow working with and passing
around JS objects in wasm. But wait, that's not allowed today! While indeed
true, that's where the polyfill comes in!
The question here is how we shoehorn JS objects into a u32
for wasm to use.
The current strategy for this approach is to maintain two module-local variables
in the generated foo.js
file: a stack and a heap.
Temporary JS objects on the stack
The stack in foo.js
is, well, a stack. JS objects are pushed on the top of the
stack, and their index in the stack is the identifier that's passed to wasm. JS
objects are then only removed from the top of the stack as well. This data
structure is mainly useful for efficiently passing a JS object into wasm without
a sort of "heap allocation". The downside of this, however, is that it only
works for when wasm doesn't hold onto a JS object (aka it only gets a
"reference" in Rust parlance).
Let's take a look at an example.
// foo.rs
#[wasm_bindgen]
pub fn foo(a: &JsValue) {
// ...
}
Here we're using the special JsValue
type from the wasm-bindgen
library
itself. Our exported function, foo
, takes a reference to an object. This
notably means that it can't persist the object past the lifetime of this
function call.
Now what we actually want to generate is a JS module that looks like (in Typescript parlance)
// foo.d.ts
export function foo(a: any);
and what we actually generate looks something like:
// foo.js
import * as wasm from './foo_bg';
let stack = [];
function addBorrowedObject(obj) {
stack.push(obj);
return stack.length - 1;
}
export function foo(arg0) {
const idx0 = addBorrowedObject(arg0);
try {
wasm.foo(idx0);
} finally {
stack.pop();
}
}
Here we can see a few notable points of action:
- The wasm file was renamed to
foo_bg.wasm
, and we can see how the JS module generated here is importing from the wasm file. - Next we can see our
stack
module variable which is used to push/pop items from the stack. - Our exported function
foo
, takes an arbitrary argument,arg0
, which is converted to an index with theaddBorrowedObject
object function. The index is then passed to wasm so wasm can operate with it. - Finally, we have a
finally
which frees the stack slot as it's no longer used, issuing apop
for what was pushed at the start of the function.
It's also helpful to dig into the Rust side of things to see what's going on
there! Let's take a look at the code that #[wasm_bindgen]
generates in Rust:
// what the user wrote, note that #[no_mangle] is removed
pub extern fn foo(a: &JsValue) {
// ...
}
#[export_name = "foo"]
pub extern fn __wasm_bindgen_generated_foo(arg0: u32) {
let arg0 = unsafe {
ManuallyDrop::new(JsValue::__from_idx(arg0))
};
let arg0 = &*arg0;
foo(arg0);
}
And as with the JS, the notable points here are:
- The original function,
foo
, is unmodified in the output - A generated function here (with a unique name) is the one that's actually exported from the wasm module
- Our generated function takes an integer argument (our index) and then wraps it
in a
JsValue
. There's some trickery here that's not worth going into just yet, but we'll see in a bit what's happening under the hood.
Long-lived JS objects in a slab
The above strategy is useful when JS objects are only temporarily used in Rust, for example only during one function call. Sometimes, though, objects may have a dynamic lifetime or otherwise need to be stored on Rust's heap. To cope with this there's a second half of management of JS objects, a slab.
JS Objects passed to wasm that are not references are assumed to have a dynamic lifetime inside of the wasm module. As a result the strict push/pop of the stack won't work and we need more permanent storage for the JS objects. To cope with this we build our own "slab allocator" of sorts.
A picture (or code) is worth a thousand words so let's show what happens with an example.
// foo.rs
#[wasm_bindgen]
pub fn foo(a: JsValue) {
// ...
}
Note that the &
is missing in front of the JsValue
we had before, and in
Rust parlance this means it's taking ownership of the JS value. The exported ES
module interface is the same as before, but the ownership mechanics are slightly
different. Let's see the generated JS's slab in action:
import * as wasm from './foo_bg'; // imports from wasm file
let slab = [];
let slab_next = 0;
function addHeapObject(obj) {
if (slab_next === slab.length)
slab.push(slab.length + 1);
const idx = slab_next;
const next = slab[idx];
slab_next = next;
slab[idx] = { obj, cnt: 1 };
return idx;
}
export function foo(arg0) {
const idx0 = addHeapObject(arg0);
wasm.foo(idx0);
}
export function __wbindgen_object_drop_ref(idx) {
let obj = slab[idx];
obj.cnt -= 1;
if (obj.cnt > 0)
return;
// If we hit 0 then free up our space in the slab
slab[idx] = slab_next;
slab_next = idx;
}
Unlike before we're now calling addHeapObject
on the argument to foo
rather
than addBorrowedObject
. This function will use slab
and slab_next
as a
slab allocator to acquire a slot to store the object, placing a structure there
once it's found.
Note here that a reference count is used in addition to storing the object.
That's so we can create multiple references to the JS object in Rust without
using Rc
, but it's overall not too important to worry about here.
Another curious aspect of this generated module is the
__wbindgen_object_drop_ref
function. This is one that's actually imported from
wasm rather than used in this module! This function is used to signal the end of
the lifetime of a JsValue
in Rust, or in other words when it goes out of
scope. Otherwise though this function is largely just a general "slab free"
implementation.
And finally, let's take a look at the Rust generated again too:
// what the user wrote
pub extern fn foo(a: JsValue) {
// ...
}
#[export_name = "foo"]
pub extern fn __wasm_bindgen_generated_foo(arg0: u32) {
let arg0 = unsafe {
JsValue::__from_idx(arg0)
};
foo(arg0);
}
Ah that looks much more familiar! Not much interesting is happening here, so let's move on to...
Anatomy of JsValue
Currently the JsValue
struct is actually quite simple in Rust, it's:
pub struct JsValue {
idx: u32,
}
// "private" constructors
impl Drop for JsValue {
fn drop(&mut self) {
unsafe {
__wbindgen_object_drop_ref(self.idx);
}
}
}
Or in other words it's a newtype wrapper around a u32
, the index that we're
passed from wasm. The destructor here is where the __wbindgen_object_drop_ref
function is called to relinquish our reference count of the JS object, freeing
up our slot in the slab
that we saw above.
If you'll recall as well, when we took &JsValue
above we generated a wrapper
of ManuallyDrop
around the local binding, and that's because we wanted to
avoid invoking this destructor when the object comes from the stack.
Indexing both a slab and the stack
You might be thinking at this point that this system may not work! There's indexes into both the slab and the stack mixed up, but how do we differentiate? It turns out that the examples above have been simplified a bit, but otherwise the lowest bit is currently used as an indicator of whether you're a slab or a stack index.
Exporting a function to JS
Alright now that we've got a good grasp on JS objects and how they're working,
let's take a look at another feature of wasm-bindgen
: exporting functionality
with types that are richer than just numbers.
The basic idea around exporting functionality with more flavorful types is that
the wasm exports won't actually be called directly. Instead the generated
foo.js
module will have shims for all exported functions in the wasm module.
The most interesting conversion here happens with strings so let's take a look at that.
#[wasm_bindgen]
pub fn greet(a: &str) -> String {
format!("Hello, {}!", a)
}
Here we'd like to define an ES module that looks like
// foo.d.ts
export function greet(a: string): string;
To see what's going on, let's take a look at the generated shim
import * as wasm from './foo_bg';
function passStringToWasm(arg) {
const buf = new TextEncoder('utf-8').encode(arg);
const len = buf.length;
const ptr = wasm.__wbindgen_malloc(len);
let array = new Uint8Array(wasm.memory.buffer);
array.set(buf, ptr);
return [ptr, len];
}
function getStringFromWasm(ptr, len) {
const mem = new Uint8Array(wasm.memory.buffer);
const slice = mem.slice(ptr, ptr + len);
const ret = new TextDecoder('utf-8').decode(slice);
return ret;
}
export function greet(arg0) {
const [ptr0, len0] = passStringToWasm(arg0);
try {
const ret = wasm.greet(ptr0, len0);
const ptr = wasm.__wbindgen_boxed_str_ptr(ret);
const len = wasm.__wbindgen_boxed_str_len(ret);
const realRet = getStringFromWasm(ptr, len);
wasm.__wbindgen_boxed_str_free(ret);
return realRet;
} finally {
wasm.__wbindgen_free(ptr0, len0);
}
}
Phew, that's quite a lot! We can sort of see though if we look closely what's happening:
-
Strings are passed to wasm via two arguments, a pointer and a length. Right now we have to copy the string onto the wasm heap which means we'll be using
TextEncoder
to actually do the encoding. Once this is done we use an internal function inwasm-bindgen
to allocate space for the string to go, and then we'll pass that ptr/length to wasm later on. -
Returning strings from wasm is a little tricky as we need to return a ptr/len pair, but wasm currently only supports one return value (multiple return values is being standardized). To work around this in the meantime, we're actually returning a pointer to a ptr/len pair, and then using functions to access the various fields.
-
Some cleanup ends up happening in wasm. The
__wbindgen_boxed_str_free
function is used to free the return value ofgreet
after it's been decoded onto the JS heap (usingTextDecoder
). The__wbindgen_free
is then used to free the space we allocated to pass the string argument once the function call is done.
At this point it may be predictable, but let's take a look at the Rust side of things as well
pub extern fn greet(a: &str) -> String {
format!("Hello, {}!", a)
}
#[export_name = "greet"]
pub extern fn __wasm_bindgen_generated_greet(
arg0_ptr: *const u8,
arg0_len: usize,
) -> *mut String {
let arg0 = unsafe {
let slice = ::std::slice::from_raw_parts(arg0_ptr, arg0_len);
::std::str::from_utf8_unchecked(slice)
};
let _ret = greet(arg0);
Box::into_raw(Box::new(_ret))
}
Here we can see again that our greet
function is unmodified and has a wrapper
to call it. This wrapper will take the ptr/len argument and convert it to a
string slice, while the return value is boxed up into just a pointer and is
then returned up to was for reading via the __wbindgen_boxed_str_*
functions.
So in general exporting a function involves a shim both in JS and in Rust with
each side translating to or from wasm arguments to the native types of each
language. The wasm-bindgen
tool manages hooking up all these shims while the
#[wasm_bindgen]
macro takes care of the Rust shim as well.
Most arguments have a relatively clear way to convert them, bit if you've got any questions just let me know!
Importing a function from JS
Now that we've exported some rich functionality to JS it's also time to import
some! The goal here is to basically implement JS import
statements in Rust,
with fancy types and all.
First up, let's say we invert the function above and instead want to generate greetings in JS but call it from Rust. We might have, for example:
#[wasm_bindgen(module = "./greet")]
extern {
fn greet(a: &str) -> String;
}
fn other_code() {
let greeting = greet("foo");
// ...
}
The basic idea of imports is the same as exports in that we'll have shims in both JS and Rust doing the necessary translation. Let's first see the JS shim in action:
import * as wasm from './foo_bg';
import { greet } from './greet';
// ...
export function __wbg_f_greet(ptr0, len0, wasmretptr) {
const [retptr, retlen] = passStringToWasm(greet(getStringFromWasm(ptr0, len0)));
(new Uint32Array(wasm.memory.buffer))[wasmretptr / 4] = retlen;
return retptr;
}
The getStringFromWasm
and passStringToWasm
are the same as we saw before,
and like with __wbindgen_object_drop_ref
far above we've got this weird export
from our module now! The __wbg_f_greet
function is what's generated by
wasm-bindgen
to actually get imported in the foo.wasm
module.
The generated foo.js
we see imports from the ./greet
module with the greet
name (was the function import in Rust said) and then the __wbg_f_greet
function is shimming that import.
There's some tricky ABI business going on here so let's take a look at the generated Rust as well:
extern fn greet(a: &str) -> String {
extern {
fn __wbg_f_greet(a_ptr: *const u8, a_len: usize, ret_len: *mut usize) -> *mut u8;
}
unsafe {
let a_ptr = a.as_ptr();
let a_len = a.len();
let mut __ret_strlen = 0;
let mut __ret_strlen_ptr = &mut __ret_strlen as *mut usize;
let _ret = __wbg_f_greet(a_ptr, a_len, __ret_strlen_ptr);
String::from_utf8_unchecked(
Vec::from_raw_parts(_ret, __ret_strlen, __ret_strlen)
)
}
}
Here we can see that the greet
function was generated but it's largely just a
shim around the __wbg_f_greet
function that we're calling. The ptr/len pair
for the argument is passed as two arguments and for the return value we're
receiving one value (the length) indirectly while directly receiving the
returned pointer.
Exporting a struct to JS
So far we've covered JS objects, importing functions, and exporting functions.
This has given us quite a rich base to build on so far, and that's great! We
sometimes, though, want to go even further and define a JS class
in Rust. Or
in other words, we want to expose an object with methods from Rust to JS rather
than just importing/exporting free functions.
The #[wasm_bindgen]
attribute can annotate both a struct
and impl
blocks
to allow:
#[wasm_bindgen]
pub struct Foo {
internal: i32,
}
#[wasm_bindgen]
impl Foo {
pub fn new(val: i32) -> Foo {
Foo { internal: val }
}
pub fn get(&self) -> i32 {
self.internal
}
pub fn set(&mut self, val: i32) {
self.internal = val;
}
}
This is a typical Rust struct
definition for a type with a constructor and a
few methods. Annotating the struct with #[wasm_bindgen]
means that we'll
generate necessary trait impls to convert this type to/from the JS boundary. The
annotated impl
block here means that the functions inside will also be made
available to JS through generated shims. If we take a look at the generated JS
code for this we'll see:
import * as wasm from './js_hello_world_bg';
export class Foo {
static __construct(ptr) {
return new Foo(ptr);
}
constructor(ptr) {
this.ptr = ptr;
}
free() {
const ptr = this.ptr;
this.ptr = 0;
wasm.__wbg_foo_free(ptr);
}
static new(arg0) {
const ret = wasm.foo_new(arg0);
return Foo.__construct(ret)
}
get() {
const ret = wasm.foo_get(this.ptr);
return ret;
}
set(arg0) {
const ret = wasm.foo_set(this.ptr, arg0);
return ret;
}
}
That's actually not much! We can see here though how we've translated from Rust to JS:
- Associated functions in Rust (those without
self
) turn intostatic
functions in JS. - Methods in Rust turn into methods in wasm.
- Manual memory management is exposed in JS as well. The
free
function is required to be invoked to deallocate resources on the Rust side of things.
To be able to use new Foo()
, you'd need to annotate new
as #[wasm_bindgen(constructor)]
.
One important aspect to note here, though, is that once free
is called the JS
object is "neutered" in that its internal pointer is nulled out. This means that
future usage of this object should trigger a panic in Rust.
The real trickery with these bindings ends up happening in Rust, however, so let's take a look at that.
// original input to `#[wasm_bindgen]` omitted ...
#[export_name = "foo_new"]
pub extern fn __wasm_bindgen_generated_Foo_new(arg0: i32) -> u32
let ret = Foo::new(arg0);
Box::into_raw(Box::new(WasmRefCell::new(ret))) as u32
}
#[export_name = "foo_get"]
pub extern fn __wasm_bindgen_generated_Foo_get(me: u32) -> i32 {
let me = me as *mut WasmRefCell<Foo>;
wasm_bindgen::__rt::assert_not_null(me);
let me = unsafe { &*me };
return me.borrow().get();
}
#[export_name = "foo_set"]
pub extern fn __wasm_bindgen_generated_Foo_set(me: u32, arg1: i32) {
let me = me as *mut WasmRefCell<Foo>;
::wasm_bindgen::__rt::assert_not_null(me);
let me = unsafe { &*me };
me.borrow_mut().set(arg1);
}
#[no_mangle]
pub unsafe extern fn __wbindgen_foo_free(me: u32) {
let me = me as *mut WasmRefCell<Foo>;
wasm_bindgen::__rt::assert_not_null(me);
(*me).borrow_mut(); // ensure no active borrows
drop(Box::from_raw(me));
}
As with before this is cleaned up from the actual output but it's the same idea
as to what's going on! Here we can see a shim for each function as well as a
shim for deallocating an instance of Foo
. Recall that the only valid wasm
types today are numbers, so we're required to shoehorn all of Foo
into a
u32
, which is currently done via Box
(like std::unique_ptr
in C++).
Note, though, that there's an extra layer here, WasmRefCell
. This type is the
same as RefCell
and can be mostly glossed over.
The purpose for this type, if you're interested though, is to uphold Rust's
guarantees about aliasing in a world where aliasing is rampant (JS).
Specifically the &Foo
type means that there can be as much alaising as you'd
like, but crucially &mut Foo
means that it is the sole pointer to the data
(no other &Foo
to the same instance exists). The RefCell
type in libstd
is a way of dynamically enforcing this at runtime (as opposed to compile time
where it usually happens). Baking in WasmRefCell
is the same idea here,
adding runtime checks for aliasing which are typically happening at compile
time. This is currently a Rust-specific feature which isn't actually in the
wasm-bindgen
tool itself, it's just in the Rust-generated code (aka the
#[wasm_bindgen]
attribute).
Importing a class from JS
Just like with functions after we've started exporting we'll also want to
import! Now that we've exported a class
to JS we'll want to also be able to
import classes in Rust as well to invoke methods and such. Since JS classes are
in general just JS objects the bindings here will look pretty similar to the JS
object bindings describe above.
As usual though, let's dive into an example!
#[wasm_bindgen(module = "./bar")]
extern {
type Bar;
#[wasm_bindgen(constructor)]
fn new(arg: i32) -> Bar;
#[wasm_bindgen(js_namespace = Bar)]
fn another_function() -> i32;
#[wasm_bindgen(method)]
fn get(this: &Bar) -> i32;
#[wasm_bindgen(method)]
fn set(this: &Bar, val: i32);
#[wasm_bindgen(method, getter)]
fn property(this: &Bar) -> i32;
#[wasm_bindgen(method, setter)]
fn set_property(this: &Bar, val: i32);
}
fn run() {
let bar = Bar::new(Bar::another_function());
let x = bar.get();
bar.set(x + 3);
bar.set_property(bar.property() + 6);
}
Unlike our previous imports, this one's a bit more chatty! Remember that one of
the goals of wasm-bindgen
is to use native Rust syntax wherever possible, so
this is mostly intended to use the #[wasm_bindgen]
attribute to interpret
what's written down in Rust. Now there's a few attribute annotations here, so
let's go through one-by-one:
#[wasm_bindgen(module = "./bar")]
- seen before with imports this is declare where all the subsequent functionality is imported form. For example theBar
type is going to be imported from the./bar
module.type Bar
- this is a declaration of JS class as a new type in Rust. This means that a new typeBar
is generated which is "opaque" but is represented as internally containing aJsValue
. We'll see more on this later.#[wasm_bindgen(constructor)]
- this indicates that the binding's name isn't actually used in JS but rather translates tonew Bar()
. The return value of this function must be a bare type, likeBar
.#[wasm_bindgen(js_namespace = Bar)]
- this attribute indicates that the function declaration is namespaced through theBar
class in JS.#[wasm_bindgen(method)]
- and finally, this attribute indicates that a method call is going to happen. The first argument must be a JS struct, likeBar
, and the call in JS looks likeBar.prototype.set.call(...)
.
With all that in mind, let's take a look at the JS generated.
import * as wasm from './foo_bg';
import { Bar } from './bar';
// other support functions omitted...
export function __wbg_s_Bar_new() {
return addHeapObject(new Bar());
}
const another_function_shim = Bar.another_function;
export function __wbg_s_Bar_another_function() {
return another_function_shim();
}
const get_shim = Bar.prototype.get;
export function __wbg_s_Bar_get(ptr) {
return shim.call(getObject(ptr));
}
const set_shim = Bar.prototype.set;
export function __wbg_s_Bar_set(ptr, arg0) {
set_shim.call(getObject(ptr), arg0)
}
const property_shim = Object.getOwnPropertyDescriptor(Bar.prototype, 'property').get;
export function __wbg_s_Bar_property(ptr) {
return property_shim.call(getObject(ptr));
}
const set_property_shim = Object.getOwnPropertyDescriptor(Bar.prototype, 'property').set;
export function __wbg_s_Bar_set_property(ptr, arg0) {
set_property_shim.call(getObject(ptr), arg0)
}
Like when importing functions from JS we can see a bunch of shims are generated
for all the relevant functions. The new
static function has the
#[wasm_bindgen(constructor)]
attribute which means that instead of any
particular method it should actually invoke the new
constructor instead (as
we see here). The static function another_function
, however, is dispatched as
Bar.another_function
.
The get
and set
functions are methods so they go through Bar.prototype
,
and otherwise their first argument is implicitly the JS object itself which is
loaded through getObject
like we saw earlier.
Some real meat starts to show up though on the Rust side of things, so let's take a look:
pub struct Bar {
obj: JsValue,
}
impl Bar {
fn new() -> Bar {
extern {
fn __wbg_s_Bar_new() -> u32;
}
unsafe {
let ret = __wbg_s_Bar_new();
Bar { obj: JsValue::__from_idx(ret) }
}
}
fn another_function() -> i32 {
extern {
fn __wbg_s_Bar_another_function() -> i32;
}
unsafe {
__wbg_s_Bar_another_function()
}
}
fn get(&self) -> i32 {
extern {
fn __wbg_s_Bar_get(ptr: u32) -> i32;
}
unsafe {
let ptr = self.obj.__get_idx();
let ret = __wbg_s_Bar_get(ptr);
return ret
}
}
fn set(&self, val: i32) {
extern {
fn __wbg_s_Bar_set(ptr: u32, val: i32);
}
unsafe {
let ptr = self.obj.__get_idx();
__wbg_s_Bar_set(ptr, val);
}
}
fn property(&self) -> i32 {
extern {
fn __wbg_s_Bar_property(ptr: u32) -> i32;
}
unsafe {
let ptr = self.obj.__get_idx();
let ret = __wbg_s_Bar_property(ptr);
return ret
}
}
fn set_property(&self, val: i32) {
extern {
fn __wbg_s_Bar_set_property(ptr: u32, val: i32);
}
unsafe {
let ptr = self.obj.__get_idx();
__wbg_s_Bar_set_property(ptr, val);
}
}
}
impl WasmBoundary for Bar {
// ...
}
impl ToRefWasmBoundary for Bar {
// ...
}
In Rust we're seeing that a new type, Bar
, is generated for this import of a
class. The type Bar
internally contains a JsValue
as an instance of Bar
is meant to represent a JS object stored in our module's stack/slab. This then
works mostly the same way that we saw JS objects work in the beginning.
When calling Bar::new
we'll get an index back which is wrapped up in Bar
(which is itself just a u32
in memory when stripped down). Each function then
passes the index as the first argument and otherwise forwards everything along
in Rust.
Imports and JS exceptions
By default wasm-bindgen
will take no action when wasm calls a JS function
which ends up throwing an exception. The wasm spec right now doesn't support
stack unwinding and as a result Rust code will not execute destructors. This
can unfortunately cause memory leaks in Rust right now, but as soon as wasm
implements catching exceptions we'll be sure to add support as well!
In the meantime though fear not! You can, if necessary, annotate some imports as whether they should catch an exception. For example:
#[wasm_bindgen(module = "./bar")]
extern {
#[wasm_bindgen(catch)]
fn foo() -> Result<(), JsValue>;
}
Here the import of foo
is annotated that it should catch the JS exception, if
one occurs, and return it to wasm. This is expressed in Rust with a Result
type where the T
of the result is the otherwise successful result of the
function, and the E
must be JsValue
.
Under the hood this generates shims that do a bunch of translation, but it
suffices to say that a call in wasm to foo
should always return
appropriately.
Customizing import behavior
The #[wasm_bindgen]
macro supports a good amount of configuration for
controlling precisely how imports are imported and what they map to in JS. This
section is intended to hopefully be an exhaustive reference of the
possibilities!
-
catch
- as we saw before thecatch
attribute allows catching a JS exception. This can be attached to any imported function and the function must return aResult
where theErr
payload is aJsValue
, like so:#[wasm_bindgen] extern { #[wasm_bindgen(catch)] fn foo() -> Result<(), JsValue>; }
If the imported function throws an exception then
Err
will be returned with the exception that was raised, and otherwiseOk
is returned with the result of the function. -
constructor
- this is used to indicate that the function being bound should actually translate to anew
constructor in JS. The final argument must be a type that's imported from JS, and it's what'll get used in JS:#[wasm_bindgen] extern { type Foo; #[wasm_bindgen(constructor)] fn new() -> Foo; }
This will attach the
new
function to theFoo
type (implied byconstructor
) and in JS when this function is called it will be equivalent tonew Foo()
. -
method
- this is the gateway to adding methods to imported objects or otherwise accessing properties on objects via methods and such. This should be done for doing the equivalent of expressions likefoo.bar()
in JS.#[wasm_bindgen] extern { type Foo; #[wasm_bindgen(method)] fn work(this: &Foo); }
The first argument of a
method
annotation must be a borrowed reference (not mutable, shared) to the type that the method is attached to. In this case we'll be able to call this method likefoo.work()
in JS (wherefoo
has typeFoo
).In JS this invocation will correspond to accessing
Foo.prototype.work
and then calling that when the import is called. Note thatmethod
by default implies going throughprototype
to get a function pointer. -
js_namespace
- this attribute indicates that the JS type is accessed through a particular namespace. For example theWebAssembly.Module
APIs are all accessed through theWebAssembly
namespace. Thejs_namespace
can be applied to any import and whenever the generated JS attempts to reference a name (like a class or function name) it'll be accessed through this namespace.#[wasm_bindgen] extern { #[wasm_bindgen(js_namespace = console)] fn log(s: &str); }
This is an example of how to bind
console.log(x)
in Rust. Thelog
function will be available in the Rust module and will be invoked asconsole.log
in JS. -
getter
andsetter
- these two attributes can be combined withmethod
to indicate that this is a getter or setter method. Agetter
-tagged function by default accesses the JS property with the same name as the getter function. Asetter
's function name is currently required to start with "set_" and the property it accesses is the suffix after "set_".#[wasm_bindgen] extern { type Foo; #[wasm_bindgen(method, getter)] fn property(this: &Foo) -> u32; #[wasm_bindgen(method, setter)] fn set_property(this: &Foo, val: u32); }
Here we're importing the
Foo
type and defining the ability to access each object'sproperty
property. The first function here is a getter and will be available in Rust asfoo.property()
, and the latter is the setter which is accessible asfoo.set_property(2)
. Note that both functions have athis
argument as they're tagged withmethod
.Finally, you can also pass an argument to the
getter
andsetter
properties to configure what property is accessed. When the property is explicitly specified then there is no restriction on the method name. For example the below is equivalent to the above:#[wasm_bindgen] extern { type Foo; #[wasm_bindgen(method, getter = property)] fn assorted_method_name(this: &Foo) -> u32; #[wasm_bindgen(method, setter = "property")] fn some_other_method_name(this: &Foo, val: u32); }
Properties in JS are accessed through
Object.getOwnPropertyDescriptor
. Note that this typically only works for class-like-defined properties which aren't just attached properties on any old object. For accessing any old property on an object we can use... -
structural
- this is a flag tomethod
annotations which indicates that the method being accessed (or property with getters/setters) should be accessed in a structural fashion. For example methods are not accessed throughprototype
and properties are accessed on the object directly rather than throughObject.getOwnPropertyDescriptor
.#[wasm_bindgen] extern { type Foo; #[wasm_bindgen(method, structural)] fn bar(this: &Foo); #[wasm_bindgen(method, getter, structural)] fn baz(this: &Foo) -> u32; }
The type here,
Foo
, is not required to exist in JS (it's not referenced). Instead wasm-bindgen will generate shims that will access the passed in JS value'sbar
property to or thebaz
property (depending on the function). -
js_name = foo
- this can be used to bind to a different function in JS than the identifier that's defined in Rust. For example you can also define multiple signatures for a polymorphic function in JS as well:#[wasm_bindgen] extern { type Foo; #[wasm_bindgen(js_namespace = console, js_name = log)] fn log_string(s: &str); #[wasm_bindgen(js_namespace = console, js_name = log)] fn log_u32(n: u32); #[wasm_bindgen(js_namespace = console, js_name = log)] fn log_many(a: u32, b: JsValue); }
All of these functions will call
console.log
in Rust, but each identifier will have only one signature in Rust.
Closures
Closures are a particularly tricky topic in wasm-bindgen right now. They use somewhat advanced language features to currently be implemented and still the amount of functionality you can use is quite limiting.
Most of the implementation details of closures can be found in src/convert.rs
and src/closure.rs
, effectively the ToRefWasmBoundary
implementations for
closure types. Stack closures are pretty straightforward in that they pass
a function pointer and a data pointer to JS. This function pointer is accessed
via the exported WebAssembly.Table
in JS, and the data pointer is passed along
eventually when the JS closure is invoked.
Stack closures currently only support Fn
because there's no great location to
insert a RefCell
for types like FnMut
. This restriction may be lift-able
though in the future...
Long-lived closures are a bit more complicated. The general idea there is:
- First you create a
Closure
. This manufactures a JS callback and "passes it" to Rust so Rust can store it. - Next you later pass it as
&Closure<...>
to JS. This extracts the callback from Rust and passes it to JS. - Finally you eventually drop the Rust
Closure
which invalidates the JS closure.
Creation of the initial JS function is done with a bunch of
__wbindgen_cb_arityN
functions. These functions create a JS closure with the
given arity (number of arguments). This isn't really that scalable unfortunately
and also means that it's very difficult to support richer types one day. Unsure
how to solve this.
The ToRefWasmBoundary
is quite straightforward for Closure
as it just plucks
out the JS closure and passes it along. The real meat comes down to the
WasmShim
internal trait. This is implemented for all the unsized closure
types to avoid running afoul with coherence. Each trait impl defines a shim
function to be invokeable from JS as well as the ability to wrap up the sized
verion (aka transition from F: FnMut()
to FnMut()
). Impls for FnMut
also
embed the RefCell
internally.
The WasmShim
design is basically the first thing that got working today. It's
not great and will likely change in the future to hopefully be more flexible!
Wrapping up
That's currently at least what wasm-bindgen
has to offer! If you've got more
questions though please don't hesitate to ask or open an issue!