How to create UnsafeCell<c_void> safely?

Question

The UnsafeCell documentation says

The UnsafeCell<T> type is the only legal way to obtain aliasable data that is considered mutable.

The only construction method is:

pub const fn new(value: T) -> UnsafeCell<T>

However, it is not possible to create a c_void, we can only create *mut c_void or *const c_void.

Is it possible to create UnsafeCell<c_void> from a *mut c_void? With this, we can let the compiler know that the pointer can point to something mutable.

Or is this not necessary? Can we always use *mut c_void even we know some FFI call will mutate the data it points to and we have multiple references to it?

A use case would be:

struct FFIStruct { v: UnsafeCell<c_void>, other_fields: ... }
impl FFIStruct {
    // We don't want to require &mut self, as we 
    // are sure private call_ffi() will always be called 
    // sequentially, and we don't want to stop
    // status() being callable during the call
    fn call_ffi(&self){ ffi_function(self.v.get()) }
    pub fn status(&self) -> FFIStatus { ... }
}

Now how do we create FFIStruct? Or just use *mut c_void would be OK?

Example code to create &Cell<c_void>

Requires #![feature(as_cell)]:

unsafe fn get_cell<'a>(p: *mut c_void) -> &'a Cell<c_void> {
    Cell::from_mut(&mut *p)
}

Answer 1

TL;DR: Just use *mut Foo. Cells of any kind are not needed here.

---

Disclaimer: there is no formal Rust memory model, yet.

You cannot create this type, period, because you cannot¹ create an instance of c_void.

The thing is, you don't need to create such a type. Aliasing is not spatial but temporal. You can have multiple *mut T pointing to the same place and it doesn't matter until you try to access one. This essentially converts it to a reference and the aliasing requirements need to be upheld while that reference is around.

raw pointers fall outside of Rust's safe memory model.

— The Rustonomicon

Different from references and smart pointers, raw pointers:

• Are allowed to ignore the borrowing rules by having both immutable and mutable pointers or multiple mutable pointers to the same location
• Aren’t guaranteed to point to valid memory
• Are allowed to be null
• Don’t implement any automatic cleanup

¸— The Rust Programming Language

See also:

• Why does modifying a mutable reference's value through a raw pointer not violate Rust's aliasing rules?
• What's the Rust idiom to define a field pointing to a C opaque pointer?
• Is it undefined behavior to do runtime borrow management with the help of raw pointers in Rust?
• Can an FFI function modify a variable that wasn't declared mutable?

¹ You technically can, but that's only because of an implementation and backwards compatibility limitation.

Answer 2

I think I understand some of the confusion occurring in this conversation, so I'm going to address some points that I think you aren't clear on. Tell me if I'm misinterpreting things.

UnsafeCell stores data in place

You do not want to have a UnsafeCell<*mut c_void> because UnsafeCell is accessed through a pointer, so you are conceiving this construction as a pointer to a pointer. UnsafeCell is accessed through a pointer, but the UnsafeCell itself is not a pointer. The UnsafeCell<T> stores T in-place. Wrapping a T in an UnsafeCell<T> does not at all change the representation in memory.

UnsafeCell::<T>::get(&self) -> *mut T simply serves as a way to begin an access to the inner data in a way that is semantically consistent with the existing language mechanism of pointers.

After all, a pointer is just a memory address, and all data is accessed with memory addresses.

Raw pointers only allow exceptions to Rust's lifetime rules

Raw pointers do not serve as a mechanism for interior mutability. They are simply a pointer type, just like references or the Box, which allows the user to unsafely take control of managing the data lifetime, often to build safe abstractions like Rc and Vec.

Raw pointers are still expected to follow Rust's borrowing rules

Both references and raw pointers in Rust follow the expectation that, at a given time, there can only be one mutable reference to a particular piece of data.

Consider this code:

unsafe {
    let pointer: *mut i32 = unimplemented!();
    *pointer = 7;
    let integer: i32 = *pointer;
}

The compiler is not required to actually write and then read to the pointed-at memory address. Since the compiler, with optimizations enabled, can trivially deduce that integer will have the value 7, it can choose to optimize the write and read out of existence. It does not have to consider the possibility that another thread could write to it.

UnsafeCell allows exceptions to Rust's borrowing rules

UnsafeCell is the foundation of abstractions for interior mutability. When you call UnsafeCell.get(), to create a pointer to the wrapped data, the compiler is not allowed to perform caching optimizations on the inner data. It has to assume that some other thread may have mutated that data.

If we adapted the previous example into this:

unsafe {
    let cell: *mut UnsafeCell<i32> = unimplemented!();
    let pointer: *mut i32 = (&*cell).get();
    *pointer = 7;
    let pointer: *mut i32 = (&*cell).get();
    let integer: i32 = *pointer;
}

The compiler would actually have to write then read the pointer, because each time we call UnsafeCell.get(), the compiler cannot cache the cell's contents.

You want an UnsafeCell<*mut c_void>

From what you're describing, it sounds like you want an UnsafeCell<*mut c_void>. That will be a mutable pointer to data of an unknown type which leaves you in charge of maintaining a valid lifetime and reference rules.

unsafe {
    // as an example, it can hold a 1 byte heap allocation
    let pointer: UnsafeCell<*mut c_void> = UnsafeCell::new(Box::into_raw(Box::new(0u8)) as *mut u8 as *mut c_void);

    // write 
    *(*pointer.get() as *mut u8) = 42u8;

    // read
    let b: u8 = *(*pointer.get() as *mut u8);
    println!("{}", b);
}

Answer 3

After some internal discussion in the Rust forum and a discussion on RFC 1861, I realize c_void is just a common workaround and other options exists like struct Opaque<UnsafeCell<()>>.

So I concluded what I needed here is *const UnsafeCell<c_void>. From its type we know:

• This is a raw pointer, so it is suitable to send to FFI immediately;
• The raw pointer assumes const, means any casting to *mut T will UB and programmer should avoid it. This protects the memory it points to being modified within Rust (unless through UnsafeCell, of cause);
• It contains UnsafeCell, so it implies interior mutability. This justifies the FFI function being able to mutate it;
• It is not possible to create a c_void, so as for UnsafeCell<c_void>. They can only be created by FFI.

Demostrate:

use std::cell::UnsafeCell;
use std::os::raw::c_void;

//Let's say all those functions are in an FFI module,
//with the exact same behaviour
fn ffi_create() -> *mut c_void {
    Box::into_raw(Box::new(0u8)) as *mut c_void
}
unsafe fn ffi_write_u8(p: *mut c_void, v:u8) {
    *(p as *mut u8) = v;
}
unsafe fn ffi_read_u8(p: *mut c_void) -> u8 {
    *(p as *mut u8)
}

fn main() {
    unsafe {
        //let's ignore ffi_destroy() for now
        let pointer = ffi_create() as *const UnsafeCell<c_void>;
        let ref_pointer = &pointer;        
        ffi_write_u8((&*pointer).get(), 7);
        let integer = ffi_read_u8((&**ref_pointer).get());
        assert_eq!(integer, 7);
    }
}

It is interesting how easy and ergonomic (yet expressive) to convert between *mut c_void and *const UnsafeCell<c_void>.