// See core/src/primitive_docs.rs for documentation. use crate::cmp::Ordering::{self, *}; use crate::marker::ConstParamTy; use crate::marker::{StructuralEq, StructuralPartialEq}; // Recursive macro for implementing n-ary tuple functions and operations // // Also provides implementations for tuples with lesser arity. For example, tuple_impls!(A B C) // will implement everything for (A, B, C), (A, B) and (A,). macro_rules! tuple_impls { // Stopping criteria (1-ary tuple) ($T:ident) => { tuple_impls!(@impl $T); }; // Running criteria (n-ary tuple, with n >= 2) ($T:ident $( $U:ident )+) => { tuple_impls!($( $U )+); tuple_impls!(@impl $T $( $U )+); }; // "Private" internal implementation (@impl $( $T:ident )+) => { maybe_tuple_doc! { $($T)+ @ #[stable(feature = "rust1", since = "1.0.0")] impl<$($T: PartialEq),+> PartialEq for ($($T,)+) where last_type!($($T,)+): ?Sized { #[inline] fn eq(&self, other: &($($T,)+)) -> bool { $( ${ignore(T)} self.${index()} == other.${index()} )&&+ } #[inline] fn ne(&self, other: &($($T,)+)) -> bool { $( ${ignore(T)} self.${index()} != other.${index()} )||+ } } } maybe_tuple_doc! { $($T)+ @ #[stable(feature = "rust1", since = "1.0.0")] impl<$($T: Eq),+> Eq for ($($T,)+) where last_type!($($T,)+): ?Sized {} } maybe_tuple_doc! { $($T)+ @ #[unstable(feature = "structural_match", issue = "31434")] impl<$($T: ConstParamTy),+> ConstParamTy for ($($T,)+) {} } maybe_tuple_doc! { $($T)+ @ #[unstable(feature = "structural_match", issue = "31434")] impl<$($T),+> StructuralPartialEq for ($($T,)+) {} } maybe_tuple_doc! { $($T)+ @ #[unstable(feature = "structural_match", issue = "31434")] impl<$($T),+> StructuralEq for ($($T,)+) {} } maybe_tuple_doc! { $($T)+ @ #[stable(feature = "rust1", since = "1.0.0")] impl<$($T: PartialOrd),+> PartialOrd for ($($T,)+) where last_type!($($T,)+): ?Sized { #[inline] fn partial_cmp(&self, other: &($($T,)+)) -> Option { lexical_partial_cmp!($( ${ignore(T)} self.${index()}, other.${index()} ),+) } #[inline] fn lt(&self, other: &($($T,)+)) -> bool { lexical_ord!(lt, Less, $( ${ignore(T)} self.${index()}, other.${index()} ),+) } #[inline] fn le(&self, other: &($($T,)+)) -> bool { lexical_ord!(le, Less, $( ${ignore(T)} self.${index()}, other.${index()} ),+) } #[inline] fn ge(&self, other: &($($T,)+)) -> bool { lexical_ord!(ge, Greater, $( ${ignore(T)} self.${index()}, other.${index()} ),+) } #[inline] fn gt(&self, other: &($($T,)+)) -> bool { lexical_ord!(gt, Greater, $( ${ignore(T)} self.${index()}, other.${index()} ),+) } } } maybe_tuple_doc! { $($T)+ @ #[stable(feature = "rust1", since = "1.0.0")] impl<$($T: Ord),+> Ord for ($($T,)+) where last_type!($($T,)+): ?Sized { #[inline] fn cmp(&self, other: &($($T,)+)) -> Ordering { lexical_cmp!($( ${ignore(T)} self.${index()}, other.${index()} ),+) } } } maybe_tuple_doc! { $($T)+ @ #[stable(feature = "rust1", since = "1.0.0")] impl<$($T: Default),+> Default for ($($T,)+) { #[inline] fn default() -> ($($T,)+) { ($({ let x: $T = Default::default(); x},)+) } } } #[stable(feature = "array_tuple_conv", since = "1.71.0")] impl From<[T; ${count(T)}]> for ($(${ignore(T)} T,)+) { #[inline] #[allow(non_snake_case)] fn from(array: [T; ${count(T)}]) -> Self { let [$($T,)+] = array; ($($T,)+) } } #[stable(feature = "array_tuple_conv", since = "1.71.0")] impl From<($(${ignore(T)} T,)+)> for [T; ${count(T)}] { #[inline] #[allow(non_snake_case)] fn from(tuple: ($(${ignore(T)} T,)+)) -> Self { let ($($T,)+) = tuple; [$($T,)+] } } } } // If this is a unary tuple, it adds a doc comment. // Otherwise, it hides the docs entirely. macro_rules! maybe_tuple_doc { ($a:ident @ #[$meta:meta] $item:item) => { #[doc(fake_variadic)] #[doc = "This trait is implemented for tuples up to twelve items long."] #[$meta] $item }; ($a:ident $($rest_a:ident)+ @ #[$meta:meta] $item:item) => { #[doc(hidden)] #[$meta] $item }; } #[inline] const fn ordering_is_some(c: Option, x: Ordering) -> bool { // FIXME: Just use `==` once that's const-stable on `Option`s. // This is mapping `None` to 2 and then doing the comparison afterwards // because it optimizes better (`None::` is represented as 2). x as i8 == match c { Some(c) => c as i8, None => 2, } } // Constructs an expression that performs a lexical ordering using method `$rel`. // The values are interleaved, so the macro invocation for // `(a1, a2, a3) < (b1, b2, b3)` would be `lexical_ord!(lt, opt_is_lt, a1, b1, // a2, b2, a3, b3)` (and similarly for `lexical_cmp`) // // `$ne_rel` is only used to determine the result after checking that they're // not equal, so `lt` and `le` can both just use `Less`. macro_rules! lexical_ord { ($rel: ident, $ne_rel: ident, $a:expr, $b:expr, $($rest_a:expr, $rest_b:expr),+) => {{ let c = PartialOrd::partial_cmp(&$a, &$b); if !ordering_is_some(c, Equal) { ordering_is_some(c, $ne_rel) } else { lexical_ord!($rel, $ne_rel, $($rest_a, $rest_b),+) } }}; ($rel: ident, $ne_rel: ident, $a:expr, $b:expr) => { // Use the specific method for the last element PartialOrd::$rel(&$a, &$b) }; } macro_rules! lexical_partial_cmp { ($a:expr, $b:expr, $($rest_a:expr, $rest_b:expr),+) => { match ($a).partial_cmp(&$b) { Some(Equal) => lexical_partial_cmp!($($rest_a, $rest_b),+), ordering => ordering } }; ($a:expr, $b:expr) => { ($a).partial_cmp(&$b) }; } macro_rules! lexical_cmp { ($a:expr, $b:expr, $($rest_a:expr, $rest_b:expr),+) => { match ($a).cmp(&$b) { Equal => lexical_cmp!($($rest_a, $rest_b),+), ordering => ordering } }; ($a:expr, $b:expr) => { ($a).cmp(&$b) }; } macro_rules! last_type { ($a:ident,) => { $a }; ($a:ident, $($rest_a:ident,)+) => { last_type!($($rest_a,)+) }; } tuple_impls!(E D C B A Z Y X W V U T);