Crate foreign_types

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Expand description

A framework for Rust wrappers over C APIs.

Ownership is as important in C as it is in Rust, but the semantics are often implicit. In particular, pointer-to-value is commonly used to pass C values both when transferring ownership or a borrow.

This crate provides a framework to define a Rust wrapper over these kinds of raw C APIs in a way that allows ownership semantics to be expressed in an ergonomic manner. The framework takes a dual-type approach similar to APIs in the standard library such as PathBuf/Path or String/ str. One type represents an owned value and references to the other represent borrowed values.

Examples

use foreign_types::{ForeignType, ForeignTypeRef, Opaque};
use std::ops::{Deref, DerefMut};

mod foo_sys {
    pub enum FOO {}

    extern {
        pub fn FOO_free(foo: *mut FOO);
    }
}

// The borrowed type is a newtype wrapper around an `Opaque` value.
//
// `FooRef` values never exist; we instead create references to `FooRef`s
// from raw C pointers.
pub struct FooRef(Opaque);

impl ForeignTypeRef for FooRef {
    type CType = foo_sys::FOO;
}

// The owned type is simply a newtype wrapper around the raw C type.
//
// It dereferences to `FooRef`, so methods that do not require ownership
// should be defined there.
pub struct Foo(*mut foo_sys::FOO);

impl Drop for Foo {
    fn drop(&mut self) {
        unsafe { foo_sys::FOO_free(self.0) }
    }
}

impl ForeignType for Foo {
    type CType = foo_sys::FOO;
    type Ref = FooRef;

    unsafe fn from_ptr(ptr: *mut foo_sys::FOO) -> Foo {
        Foo(ptr)
    }

    fn as_ptr(&self) -> *mut foo_sys::FOO {
        self.0
    }
}

impl Deref for Foo {
    type Target = FooRef;

    fn deref(&self) -> &FooRef {
        unsafe { FooRef::from_ptr(self.0) }
    }
}

impl DerefMut for Foo {
    fn deref_mut(&mut self) -> &mut FooRef {
        unsafe { FooRef::from_ptr_mut(self.0) }
    }
}

The foreign_type! macro can generate this boilerplate for you:

#[macro_use]
extern crate foreign_types;

mod foo_sys {
    pub enum FOO {}

    extern {
        pub fn FOO_free(foo: *mut FOO);
        pub fn FOO_duplicate(foo: *mut FOO) -> *mut FOO; // Optional
    }
}

foreign_type! {
    type CType = foo_sys::FOO;
    fn drop = foo_sys::FOO_free;
    fn clone = foo_sys::FOO_duplicate; // Optional
    /// A Foo.
    pub struct Foo;
    /// A borrowed Foo.
    pub struct FooRef;
}

If fn clone is specified, then it must take CType as an argument and return a copy of it as CType. It will be used to implement ToOwned and Clone.

#[derive(…)] is permitted before the lines with pub struct. #[doc(hidden)]before thetype CTypeline will hide theforeign_type!` implementations from documentation.

Say we then have a separate type in our C API that contains a FOO:

mod foo_sys {
    pub enum FOO {}
    pub enum BAR {}

    extern {
        pub fn FOO_free(foo: *mut FOO);
        pub fn BAR_free(bar: *mut BAR);
        pub fn BAR_get_foo(bar: *mut BAR) -> *mut FOO;
    }
}

The documentation for the C library states that BAR_get_foo returns a reference into the BAR passed to it, which translates into a reference in Rust. It also says that we’re allowed to modify the FOO, so we’ll define a pair of accessor methods, one immutable and one mutable:

#[macro_use]
extern crate foreign_types;

use foreign_types::ForeignTypeRef;

mod foo_sys {
    pub enum FOO {}
    pub enum BAR {}

    extern {
        pub fn FOO_free(foo: *mut FOO);
        pub fn BAR_free(bar: *mut BAR);
        pub fn BAR_get_foo(bar: *mut BAR) -> *mut FOO;
    }
}

foreign_type! {
    #[doc(hidden)]
    type CType = foo_sys::FOO;
    fn drop = foo_sys::FOO_free;
    /// A Foo.
    pub struct Foo;
    /// A borrowed Foo.
    pub struct FooRef;
}

foreign_type! {
    type CType = foo_sys::BAR;
    fn drop = foo_sys::BAR_free;
    /// A Foo.
    pub struct Bar;
    /// A borrowed Bar.
    pub struct BarRef;
}

impl BarRef {
    fn foo(&self) -> &FooRef {
        unsafe { FooRef::from_ptr(foo_sys::BAR_get_foo(self.as_ptr())) }
    }

    fn foo_mut(&mut self) -> &mut FooRef {
        unsafe { FooRef::from_ptr_mut(foo_sys::BAR_get_foo(self.as_ptr())) }
    }
}

Macros

  • A macro to easily define wrappers for foreign types.

Structs

  • An opaque type used to define ForeignTypeRef types.

Traits

  • A type implemented by wrappers over foreign types.
  • A trait implemented by types which reference borrowed foreign types.