/// A macro for defining #[cfg] if-else statements. /// /// This is similar to the `if/elif` C preprocessor macro by allowing definition /// of a cascade of `#[cfg]` cases, emitting the implementation which matches /// first. /// /// This allows you to conveniently provide a long list #[cfg]'d blocks of code /// without having to rewrite each clause multiple times. macro_rules! cfg_if { // match if/else chains with a final `else` ($( if #[cfg($($meta:meta),*)] { $($it:item)* } ) else * else { $($it2:item)* }) => { cfg_if! { @__items () ; $( ( ($($meta),*) ($($it)*) ), )* ( () ($($it2)*) ), } }; // match if/else chains lacking a final `else` ( if #[cfg($($i_met:meta),*)] { $($i_it:item)* } $( else if #[cfg($($e_met:meta),*)] { $($e_it:item)* } )* ) => { cfg_if! { @__items () ; ( ($($i_met),*) ($($i_it)*) ), $( ( ($($e_met),*) ($($e_it)*) ), )* ( () () ), } }; // Internal and recursive macro to emit all the items // // Collects all the negated `cfg`s in a list at the beginning and after the // semicolon is all the remaining items (@__items ($($not:meta,)*) ; ) => {}; (@__items ($($not:meta,)*) ; ( ($($m:meta),*) ($($it:item)*) ), $($rest:tt)*) => { // Emit all items within one block, applying an appropriate #[cfg]. The // #[cfg] will require all `$m` matchers specified and must also negate // all previous matchers. cfg_if! { @__apply cfg(all($($m,)* not(any($($not),*)))), $($it)* } // Recurse to emit all other items in `$rest`, and when we do so add all // our `$m` matchers to the list of `$not` matchers as future emissions // will have to negate everything we just matched as well. cfg_if! { @__items ($($not,)* $($m,)*) ; $($rest)* } }; // Internal macro to Apply a cfg attribute to a list of items (@__apply $m:meta, $($it:item)*) => { $(#[$m] $it)* }; } /// Create an internal crate prelude with `core` reexports and common types. macro_rules! prelude { () => { mod types; /// Frequently-used types that are available on all platforms /// /// We need to reexport the core types so this works with `rust-dep-of-std`. mod prelude { // Exports from `core` #[allow(unused_imports)] pub(crate) use core::clone::Clone; #[allow(unused_imports)] pub(crate) use core::default::Default; #[allow(unused_imports)] pub(crate) use core::marker::{ Copy, Send, Sync, }; #[allow(unused_imports)] pub(crate) use core::option::Option; #[allow(unused_imports)] pub(crate) use core::prelude::v1::derive; #[allow(unused_imports)] pub(crate) use core::{ cfg, fmt, hash, iter, mem, ptr, }; #[allow(unused_imports)] pub(crate) use fmt::Debug; #[allow(unused_imports)] pub(crate) use mem::{ align_of, align_of_val, size_of, size_of_val, }; #[allow(unused_imports)] pub(crate) use crate::types::{ CEnumRepr, Padding, }; // Commonly used types defined in this crate #[allow(unused_imports)] pub(crate) use crate::{ c_char, c_double, c_float, c_int, c_long, c_longlong, c_short, c_uchar, c_uint, c_ulong, c_ulonglong, c_ushort, c_void, intptr_t, size_t, ssize_t, uintptr_t, }; } }; } /// Implement `Clone`, `Copy`, and `Debug` for one or more structs, as well as `PartialEq`, `Eq`, /// and `Hash` if the `extra_traits` feature is enabled. /// /// Also mark the type with `repr(C)`. /// /// Use [`s_no_extra_traits`] for structs where the `extra_traits` feature does not /// make sense, and for unions. macro_rules! s { ($( $(#[$attr:meta])* $pub:vis $t:ident $i:ident { $($field:tt)* } )*) => ($( s!(it: $(#[$attr])* $pub $t $i { $($field)* }); )*); (it: $(#[$attr:meta])* $pub:vis union $i:ident { $($field:tt)* }) => ( compile_error!("unions cannot derive extra traits, use s_no_extra_traits instead"); ); (it: $(#[$attr:meta])* $pub:vis struct $i:ident { $($field:tt)* }) => ( #[repr(C)] #[::core::prelude::v1::derive( ::core::clone::Clone, ::core::marker::Copy, ::core::fmt::Debug, )] #[cfg_attr( feature = "extra_traits", ::core::prelude::v1::derive(PartialEq, Eq, Hash) )] #[allow(deprecated)] $(#[$attr])* $pub struct $i { $($field)* } ); } /// Implement `Clone`, `Copy`, and `Debug` for a tuple struct, as well as `PartialEq`, `Eq`, /// and `Hash` if the `extra_traits` feature is enabled. /// /// Unlike `s!`, this does *not* mark the type with `repr(C)`. Users should provide their own /// `repr` attribute via `$attr` as necessary. macro_rules! s_paren { ($( $(#[$attr:meta])* $pub:vis struct $i:ident ( $($field:tt)* ); )*) => ($( #[::core::prelude::v1::derive( ::core::clone::Clone, ::core::marker::Copy, ::core::fmt::Debug, )] #[cfg_attr( feature = "extra_traits", ::core::prelude::v1::derive(PartialEq, Eq, Hash) )] $(#[$attr])* $pub struct $i ( $($field)* ); )*); } /// Implement `Clone`, `Copy`, and `Debug` for one or more structs/unions, but exclude `PartialEq`, /// `Eq`, and `Hash`. /// /// Also mark the type with `repr(C)`. /// /// Most structs will prefer to use [`s`]. macro_rules! s_no_extra_traits { ($( $(#[$attr:meta])* $pub:vis $t:ident $i:ident { $($field:tt)* } )*) => ($( s_no_extra_traits!(it: $(#[$attr])* $pub $t $i { $($field)* }); )*); (it: $(#[$attr:meta])* $pub:vis union $i:ident { $($field:tt)* }) => ( #[repr(C)] #[::core::prelude::v1::derive( ::core::clone::Clone, ::core::marker::Copy, )] $(#[$attr])* $pub union $i { $($field)* } impl ::core::fmt::Debug for $i { fn fmt(&self, f: &mut ::core::fmt::Formatter<'_>) -> ::core::fmt::Result { f.debug_struct(::core::stringify!($i)).finish_non_exhaustive() } } ); (it: $(#[$attr:meta])* $pub:vis struct $i:ident { $($field:tt)* }) => ( #[repr(C)] #[::core::prelude::v1::derive( ::core::clone::Clone, ::core::marker::Copy, ::core::fmt::Debug, )] $(#[$attr])* $pub struct $i { $($field)* } ); } /// Create an uninhabited type that can't be constructed. It implements `Debug`, `Clone`, /// and `Copy`, but these aren't meaningful for extern types so they should eventually /// be removed. /// /// Really what we want here is something that also can't be named without indirection (in /// ADTs or function signatures), but this doesn't exist. macro_rules! extern_ty { ($( $(#[$attr:meta])* pub enum $i:ident {} )*) => ($( $(#[$attr])* // FIXME(1.0): the type is uninhabited so these traits are unreachable and could be // removed. #[::core::prelude::v1::derive( ::core::clone::Clone, ::core::marker::Copy, ::core::fmt::Debug, )] pub enum $i { } )*); } /// Implement `Clone` and `Copy` for an enum, as well as `Debug`, `Eq`, `Hash`, and /// `PartialEq` if the `extra_traits` feature is enabled. // FIXME(#4419): Replace all uses of `e!` with `c_enum!` macro_rules! e { ($( $(#[$attr:meta])* pub enum $i:ident { $($field:tt)* } )*) => ($( #[cfg_attr( feature = "extra_traits", ::core::prelude::v1::derive(Eq, Hash, PartialEq) )] #[::core::prelude::v1::derive( ::core::clone::Clone, ::core::marker::Copy, ::core::fmt::Debug, )] $(#[$attr])* pub enum $i { $($field)* } )*); } /// Represent a C enum as Rust constants and a type. /// /// C enums can't soundly be mapped to Rust enums since C enums are allowed to have duplicates or /// unlisted values, but this is UB in Rust. This enum doesn't implement any traits, its main /// purpose is to calculate the correct enum values. /// /// Use the magic name `#anon` if the C enum doesn't create a type. /// /// See for more. macro_rules! c_enum { // Matcher for multiple enums ($( $(#[repr($repr:ty)])? pub enum $($ty_name:ident)? $(#$anon:ident)? { $($vis:vis $variant:ident $(= $value:expr)?,)+ } )+) => { $(c_enum!(@single; $(#[repr($repr)])? pub enum $($ty_name)? $(#$anon)? { $($vis $variant $(= $value)?,)+ } );)+ }; // Matcher for a single enum (@single; $(#[repr($repr:ty)])? pub enum $ty_name:ident { $($vis:vis $variant:ident $(= $value:expr)?,)+ } ) => { pub type $ty_name = c_enum!(@ty $($repr)?); c_enum! { @variant; ty: $ty_name; default: 0; variants: [$($vis $variant $(= $value)?,)+] } }; // Matcher for a single anonymous enum (@single; $(#[repr($repr:ty)])? pub enum #anon { $($vis:vis $variant:ident $(= $value:expr)?,)+ } ) => { c_enum! { @variant; ty: c_enum!(@ty $($repr)?); default: 0; variants: [$($vis $variant $(= $value)?,)+] } }; // Matcher for variants: eats a single variant then recurses with the rest (@variant; ty: $_ty_name:ty; default: $_idx:expr; variants: []) => { /* end of the chain */ }; ( @variant; ty: $ty_name:ty; default: $default_val:expr; variants: [ $vis:vis $variant:ident $(= $value:expr)?, $($tail:tt)* ] ) => { $vis const $variant: $ty_name = { #[allow(unused_variables)] let r = $default_val; $(let r = $value;)? r }; // The next value is always one more than the previous value, unless // set explicitly. c_enum! { @variant; ty: $ty_name; default: $variant + 1; variants: [$($tail)*] } }; // Use a specific type if provided, otherwise default to `CEnumRepr` (@ty $repr:ty) => { $repr }; (@ty) => { $crate::prelude::CEnumRepr }; } /// Define a `unsafe` function. macro_rules! f { ($( $(#[$attr:meta])* // Less than ideal hack to match either `fn` or `const fn`. pub $(fn $i:ident)? $(const fn $const_i:ident)? ($($arg:ident: $argty:ty),* $(,)*) -> $ret:ty $body:block )+) => {$( #[inline] $(#[$attr])* pub $(unsafe extern "C" fn $i)? $(const unsafe extern "C" fn $const_i)? ($($arg: $argty),*) -> $ret $body )+}; } /// Define a safe function. macro_rules! safe_f { ($( $(#[$attr:meta])* // Less than ideal hack to match either `fn` or `const fn`. pub $(fn $i:ident)? $(const fn $const_i:ident)? ($($arg:ident: $argty:ty),* $(,)*) -> $ret:ty $body:block )+) => {$( #[inline] $(#[$attr])* pub $(extern "C" fn $i)? $(const extern "C" fn $const_i)? ($($arg: $argty),*) -> $ret $body )+}; } // This macro is used to deprecate items that should be accessed via the mach2 crate macro_rules! deprecated_mach { (pub const $id:ident: $ty:ty = $expr:expr;) => { #[deprecated( since = "0.2.55", note = "Use the `mach2` crate instead", )] #[allow(deprecated)] pub const $id: $ty = $expr; }; ($(pub const $id:ident: $ty:ty = $expr:expr;)*) => { $( deprecated_mach!( pub const $id: $ty = $expr; ); )* }; (pub type $id:ident = $ty:ty;) => { #[deprecated( since = "0.2.55", note = "Use the `mach2` crate instead", )] #[allow(deprecated)] pub type $id = $ty; }; ($(pub type $id:ident = $ty:ty;)*) => { $( deprecated_mach!( pub type $id = $ty; ); )* } } /// Polyfill for std's `offset_of`. // FIXME(msrv): stabilized in std in 1.77 macro_rules! offset_of { ($Ty:path, $field:ident) => {{ // Taken from bytemuck, avoids accidentally calling on deref #[allow(clippy::unneeded_field_pattern)] let $Ty { $field: _, .. }; let data = core::mem::MaybeUninit::<$Ty>::uninit(); let ptr = data.as_ptr(); // nested unsafe, see f! #[allow(unused_unsafe)] // SAFETY: computed address is inbounds since we have a stack alloc for T let fptr = unsafe { core::ptr::addr_of!((*ptr).$field) }; let off = (fptr as usize).checked_sub(ptr as usize).unwrap(); core::assert!(off <= core::mem::size_of::<$Ty>()); off }}; } #[cfg(test)] mod tests { use core::any::TypeId; use crate::types::CEnumRepr; #[test] fn c_enum_basic() { // By default, variants get sequential values. c_enum! { pub enum e { VAR0, VAR1, VAR2, } // Also check enums that don't create a type. pub enum #anon { ANON0, ANON1, ANON2, } } assert_eq!(TypeId::of::(), TypeId::of::()); assert_eq!(VAR0, 0 as CEnumRepr); assert_eq!(VAR1, 1 as CEnumRepr); assert_eq!(VAR2, 2 as CEnumRepr); assert_eq!(type_id_of_val(&ANON0), TypeId::of::()); assert_eq!(ANON0, 0 as CEnumRepr); assert_eq!(ANON1, 1 as CEnumRepr); assert_eq!(ANON2, 2 as CEnumRepr); } #[test] fn c_enum_repr() { // Check specifying the integer representation c_enum! { #[repr(u16)] pub enum e { VAR0, } #[repr(u16)] pub enum #anon { ANON0, } } assert_eq!(TypeId::of::(), TypeId::of::()); assert_eq!(VAR0, 0_u16); assert_eq!(type_id_of_val(&ANON0), TypeId::of::()); assert_eq!(ANON0, 0_u16); } #[test] fn c_enum_set_value() { // Setting an explicit value resets the count. c_enum! { pub enum e { VAR2 = 2, VAR3, VAR4, } } assert_eq!(VAR2, 2 as CEnumRepr); assert_eq!(VAR3, 3 as CEnumRepr); assert_eq!(VAR4, 4 as CEnumRepr); } #[test] fn c_enum_multiple_set_value() { // C enums always take one more than the previous value, unless set to a specific // value. Duplicates are allowed. c_enum! { pub enum e { VAR0, VAR2_0 = 2, VAR3_0, VAR4_0, VAR2_1 = 2, VAR3_1, VAR4_1, } } assert_eq!(VAR0, 0 as CEnumRepr); assert_eq!(VAR2_0, 2 as CEnumRepr); assert_eq!(VAR3_0, 3 as CEnumRepr); assert_eq!(VAR4_0, 4 as CEnumRepr); assert_eq!(VAR2_1, 2 as CEnumRepr); assert_eq!(VAR3_1, 3 as CEnumRepr); assert_eq!(VAR4_1, 4 as CEnumRepr); } #[test] fn c_enum_vis() { mod priv1 { c_enum! { #[repr(u8)] pub enum e1 { PRIV_ON_1 = 10, // Variant should still be usable within its visibility pub PUB1 = PRIV_ON_1 * 2, } } } mod priv2 { c_enum! { #[repr(u16)] pub enum e2 { pub PRIV_ON_1 = 42, pub PUB2 = PRIV_ON_1 * 2, } } } use priv1::*; use priv2::*; assert_eq!(TypeId::of::(), TypeId::of::()); assert_eq!(TypeId::of::(), TypeId::of::()); assert_eq!(PUB1, 10u8 * 2); assert_eq!(PUB2, 42u16 * 2); // Verify that the default is private. If `PRIV_ON_1` was actually public in `priv1`, this // would be an ambiguous import and/or type mismatch error. assert_eq!(PRIV_ON_1, 42u16); } fn type_id_of_val(_: &T) -> TypeId { TypeId::of::() } #[test] fn test_offset_of() { #[repr(C)] struct Off1 { a: u8, b: u32, c: Off2, d: u64, } #[repr(C)] #[repr(align(128))] struct Off2 {} assert_eq!(core::mem::offset_of!(Off1, a), offset_of!(Off1, a)); assert_eq!(core::mem::offset_of!(Off1, b), offset_of!(Off1, b)); assert_eq!(core::mem::offset_of!(Off1, c), offset_of!(Off1, c)); assert_eq!(core::mem::offset_of!(Off1, d), offset_of!(Off1, d)); } } #[cfg(test)] #[allow(unused)] mod macro_checks { s! { pub struct S1 { pub a: u32, b: u32, } struct S1Priv { pub a: u32, b: u32, } } s_no_extra_traits! { pub struct S2 { pub a: u32, b: u32, } struct S2Priv { pub a: u32, b: u32, } pub union U2 { pub a: u32, b: f32, } union U2Priv { pub a: u32, b: f32, } } }