// Copyright (c) 2017 Gilad Naaman // // Permission is hereby granted, free of charge, to any person obtaining a copy // of this software and associated documentation files (the "Software"), to deal // in the Software without restriction, including without limitation the rights // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell // copies of the Software, and to permit persons to whom the Software is // furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in all // copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE // SOFTWARE. /// Macro to create a local `base_ptr` raw pointer of the given type, avoiding UB as /// much as is possible currently. #[cfg(maybe_uninit)] #[macro_export] #[doc(hidden)] macro_rules! _memoffset__let_base_ptr { ($name:ident, $type:ty) => { // No UB here, and the pointer does not dangle, either. // But we have to make sure that `uninit` lives long enough, // so it has to be in the same scope as `$name`. That's why // `let_base_ptr` declares a variable (several, actually) // instead of returning one. let uninit = $crate::__priv::mem::MaybeUninit::<$type>::uninit(); let $name: *const $type = uninit.as_ptr(); }; } #[cfg(not(maybe_uninit))] #[macro_export] #[doc(hidden)] macro_rules! _memoffset__let_base_ptr { ($name:ident, $type:ty) => { // No UB right here, but we will later dereference this pointer to // offset into a field, and that is UB because the pointer is dangling. let $name = $crate::__priv::mem::align_of::<$type>() as *const $type; }; } /// Macro to compute the distance between two pointers. #[cfg(any(feature = "unstable_const", stable_const))] #[macro_export] #[doc(hidden)] macro_rules! _memoffset_offset_from_unsafe { ($field:expr, $base:expr) => {{ let field = $field; // evaluate $field outside the `unsafe` block let base = $base; // evaluate $base outside the `unsafe` block // Compute offset, with unstable `offset_from` for const-compatibility. // (Requires the pointers to not dangle, but we already need that for `raw_field!` anyway.) unsafe { (field as *const u8).offset_from(base as *const u8) as usize } }}; } #[cfg(not(any(feature = "unstable_const", stable_const)))] #[macro_export] #[doc(hidden)] macro_rules! _memoffset_offset_from_unsafe { ($field:expr, $base:expr) => { // Compute offset. ($field as usize) - ($base as usize) }; } /// Calculates the offset of the specified field from the start of the named struct. /// /// ## Examples /// ``` /// use memoffset::offset_of; /// /// #[repr(C, packed)] /// struct Foo { /// a: u32, /// b: u64, /// c: [u8; 5] /// } /// /// fn main() { /// assert_eq!(offset_of!(Foo, a), 0); /// assert_eq!(offset_of!(Foo, b), 4); /// } /// ``` /// /// ## Notes /// Rust's ABI is unstable, and [type layout can be changed with each /// compilation](https://doc.rust-lang.org/reference/type-layout.html). /// /// Using `offset_of!` with a `repr(Rust)` struct will return the correct offset of the /// specified `field` for a particular compilation, but the exact value may change /// based on the compiler version, concrete struct type, time of day, or rustc's mood. /// /// As a result, the value should not be retained and used between different compilations. #[macro_export(local_inner_macros)] macro_rules! offset_of { ($parent:path, $field:tt) => {{ // Get a base pointer (non-dangling if rustc supports `MaybeUninit`). _memoffset__let_base_ptr!(base_ptr, $parent); // Get field pointer. let field_ptr = raw_field!(base_ptr, $parent, $field); // Compute offset. _memoffset_offset_from_unsafe!(field_ptr, base_ptr) }}; } /// Calculates the offset of the specified field from the start of the tuple. /// /// ## Examples /// ``` /// use memoffset::offset_of_tuple; /// /// fn main() { /// assert!(offset_of_tuple!((u8, u32), 1) >= 0, "Tuples do not have a defined layout"); /// } /// ``` #[cfg(tuple_ty)] #[macro_export(local_inner_macros)] macro_rules! offset_of_tuple { ($parent:ty, $field:tt) => {{ // Get a base pointer (non-dangling if rustc supports `MaybeUninit`). _memoffset__let_base_ptr!(base_ptr, $parent); // Get field pointer. let field_ptr = raw_field_tuple!(base_ptr, $parent, $field); // Compute offset. _memoffset_offset_from_unsafe!(field_ptr, base_ptr) }}; } /// Calculates the offset of the specified union member from the start of the union. /// /// ## Examples /// ``` /// use memoffset::offset_of_union; /// /// #[repr(C, packed)] /// union Foo { /// foo32: i32, /// foo64: i64, /// } /// /// fn main() { /// assert!(offset_of_union!(Foo, foo64) == 0); /// } /// ``` /// /// ## Note /// Due to macro_rules limitations, this macro will accept structs with a single field as well as unions. /// This is not a stable guarantee, and future versions of this crate might fail /// on any use of this macro with a struct, without a semver bump. #[macro_export(local_inner_macros)] macro_rules! offset_of_union { ($parent:path, $field:tt) => {{ // Get a base pointer (non-dangling if rustc supports `MaybeUninit`). _memoffset__let_base_ptr!(base_ptr, $parent); // Get field pointer. let field_ptr = raw_field_union!(base_ptr, $parent, $field); // Compute offset. _memoffset_offset_from_unsafe!(field_ptr, base_ptr) }}; } #[cfg(test)] mod tests { #[test] fn offset_simple() { #[repr(C)] struct Foo { a: u32, b: [u8; 2], c: i64, } assert_eq!(offset_of!(Foo, a), 0); assert_eq!(offset_of!(Foo, b), 4); assert_eq!(offset_of!(Foo, c), 8); } #[test] #[cfg_attr(miri, ignore)] // this creates unaligned references fn offset_simple_packed() { #[repr(C, packed)] struct Foo { a: u32, b: [u8; 2], c: i64, } assert_eq!(offset_of!(Foo, a), 0); assert_eq!(offset_of!(Foo, b), 4); assert_eq!(offset_of!(Foo, c), 6); } #[test] fn tuple_struct() { #[repr(C)] struct Tup(i32, i32); assert_eq!(offset_of!(Tup, 0), 0); assert_eq!(offset_of!(Tup, 1), 4); } #[test] fn offset_union() { // Since we're specifying repr(C), all fields are supposed to be at offset 0 #[repr(C)] union Foo { a: u32, b: [u8; 2], c: i64, } assert_eq!(offset_of_union!(Foo, a), 0); assert_eq!(offset_of_union!(Foo, b), 0); assert_eq!(offset_of_union!(Foo, c), 0); } #[test] fn path() { mod sub { #[repr(C)] pub struct Foo { pub x: u32, } } assert_eq!(offset_of!(sub::Foo, x), 0); } #[test] fn inside_generic_method() { struct Pair(T, U); fn foo(_: Pair) -> usize { offset_of!(Pair, 1) } assert_eq!(foo(Pair(0, 0)), 4); } #[cfg(tuple_ty)] #[test] fn test_tuple_offset() { let f = (0i32, 0.0f32, 0u8); let f_ptr = &f as *const _; let f1_ptr = &f.1 as *const _; assert_eq!( f1_ptr as usize - f_ptr as usize, offset_of_tuple!((i32, f32, u8), 1) ); } #[test] fn test_raw_field() { #[repr(C)] struct Foo { a: u32, b: [u8; 2], c: i64, } let f: Foo = Foo { a: 0, b: [0, 0], c: 0, }; let f_ptr = &f as *const _; assert_eq!(f_ptr as usize + 0, raw_field!(f_ptr, Foo, a) as usize); assert_eq!(f_ptr as usize + 4, raw_field!(f_ptr, Foo, b) as usize); assert_eq!(f_ptr as usize + 8, raw_field!(f_ptr, Foo, c) as usize); } #[cfg(tuple_ty)] #[test] fn test_raw_field_tuple() { let t = (0u32, 0u8, false); let t_ptr = &t as *const _; let t_addr = t_ptr as usize; assert_eq!( &t.0 as *const _ as usize - t_addr, raw_field_tuple!(t_ptr, (u32, u8, bool), 0) as usize - t_addr ); assert_eq!( &t.1 as *const _ as usize - t_addr, raw_field_tuple!(t_ptr, (u32, u8, bool), 1) as usize - t_addr ); assert_eq!( &t.2 as *const _ as usize - t_addr, raw_field_tuple!(t_ptr, (u32, u8, bool), 2) as usize - t_addr ); } #[test] fn test_raw_field_union() { #[repr(C)] union Foo { a: u32, b: [u8; 2], c: i64, } let f = Foo { a: 0 }; let f_ptr = &f as *const _; assert_eq!(f_ptr as usize + 0, raw_field_union!(f_ptr, Foo, a) as usize); assert_eq!(f_ptr as usize + 0, raw_field_union!(f_ptr, Foo, b) as usize); assert_eq!(f_ptr as usize + 0, raw_field_union!(f_ptr, Foo, c) as usize); } #[cfg(any(feature = "unstable_const", stable_const))] #[test] fn const_offset() { #[repr(C)] struct Foo { a: u32, b: [u8; 2], c: i64, } assert_eq!([0; offset_of!(Foo, b)].len(), 4); } #[cfg(feature = "unstable_const")] #[test] fn const_offset_interior_mutable() { #[repr(C)] struct Foo { a: u32, b: core::cell::Cell, } assert_eq!([0; offset_of!(Foo, b)].len(), 4); } #[cfg(any(feature = "unstable_const", stable_const))] #[test] fn const_fn_offset() { const fn test_fn() -> usize { #[repr(C)] struct Foo { a: u32, b: [u8; 2], c: i64, } offset_of!(Foo, b) } assert_eq!([0; test_fn()].len(), 4); } }