Crate pin_init[][src]

Expand description

Safe pinned-initialization in Rust.

The problem

Rust’s Pin provides sufficient guarantee for C interop and self-referential structs – their address are stable once they’re pinned and the destructor is guaranteed to be called before the memory region can be deallocated.

The problem here is “once pinned”. Pin expects the type can be created without pinning, and can be pinned later before any operations. This is okay for Generators, which are created without any self references, and self references can only be created when polling the generator. For other types, e.g. pthread_mutex_t, it is expected to be pinned from the start.

For demonstration purpose, we will use this type NeedPin:

struct NeedPin {
    // Must points to itself
    address: *const NeedPin,
    _pinned: PhantomPinned,

impl NeedPin {
    fn verify(&self) {
        assert!(ptr::eq(self, self.address), "invariant not held");

impl Drop for NeedPin {
    fn drop(&mut self) {
        /* Must be called */

One could separate creating and initialization (Infallible is used as a placeholder here but in reality it can fail):

impl NeedPin {
    unsafe fn uninit() -> Self {
        Self {
            address: ptr::null(),
            _pinned: PhantomPinned,

    unsafe fn init(self: Pin<&mut Self>) -> Result<(), Infallible> {
        let this = unsafe { self.get_unchecked_mut() };
        this.address = this;

but this requires unsafe and is very difficult to use.

The ultimate goal is:

  1. Safety. We should be able to create and use such pinned type without unsafe. (Obviously the pinned type themselves are still unsafe to implement).
  2. Ergonomics. The syntax shouldn’t be too different from anormal Rust.
  3. Aggregatable. A struct containing multiple pinned types can be safely created and initialized together.
  4. No Implicit Allocation. Allocation should not be required during initialization. User should be able to dictate whether it’s initialized in a box or on the stack.
  5. Fallible. No assumption is made about success of initialization.

The solution: pin_init

This crate provides type PinUninit and InitResult as the primitives for safe pinned-initialization. Details about these types can be found in their respective documentation, but in a nutshell, instead of having a (fallible) constructor that returns Result<T, Err>, pin_init expect you to present a constructor that returns impl Init<T, Err>, where Init can be created from a closure of type for<'a> FnOnce(PinUninit<'a, T>) -> InitResult<'a, T, Err> using init_from_closure.

NeedPin::new could be define like this:

impl NeedPin {
    pub fn new() -> impl Init<Self, Infallible> {
        init_from_closure(|mut this: PinUninit<'_, Self>| -> InitResult<'_, Self, Infallible> {
            let v = this.get_mut().as_mut_ptr();
            unsafe { *ptr::addr_of_mut!((*v).address) = v };
            Ok(unsafe { this.init_ok() })

With Rust’s affine type system and borrow checker, the InitResult is essentially a certificate about whether the type is initialized or not. NeedPin can now be easily initialized:

// In a box
let p: Pin<Box<NeedPin>> = Box::pin_with(NeedPin::new()).unwrap();
// On the stack
init_stack!(p = NeedPin::new());
let p: Pin<&mut NeedPin> = p.unwrap();

For structs, if #[pin_init] when defining the struct, then init_pin! can create it very similar to the struct expression. Nested structures are also supported.

struct ManyPin {
    a: NeedPin,
    b: usize,

struct TooManyPin {
    a: NeedPin,
    b: ManyPin,
let p = Box::pin_with(init_pin!(TooManyPin {
    a: NeedPin::new(),
    b: ManyPin {
        a: NeedPin::new(),
        b: 0,

This crate also provides a UniqueRc and UniqueArc, inspired from servo_arc. They can be used to mutably initialize Rc and Arc before they are being shared. Rc::pin_with and Arc::pin_with are provided which create UniqueRc and UniqueArc internally, pin-initialize it with given constructor, and convert them to the shareable form.

This crate allows safe initialization of pinned data structure. pin-project can be used to safely access these structs. You can use both #[pin_init] and #[pin_project] together with your struct, they even share the same #[pin] field attribute!

See examples for some non-artifical examples.


Create and pin-initialize a struct.

Create and pin-initialize a new variable on the stack.


Proof that the value is not pin-initialized.

Proof that the value is pin-initialized.

A pinned, uninitialized pointer.

An uniquely owned Arc.

An uniquely owned Rc.


Initializer that can be used to safely pin-initialize T.

Types that can be constructed using init_pin.

Pointer types that can be pin-initialized.


Pointer types that can be pin-newed.


Pointer types that can be pin-newed.


Construct a Init<T, E> with a closure.

Specify an Error type if type inference cannot infer it.

Type Definitions

Result of pin-initialization.

Attribute Macros

Mark a type as being init_pin!-able.