src/libcore/tuple.rs - third_party/rust - Git at Google

 // NB: transitionary, de-mode-ing.
 #[forbid(deprecated_mode)];
 #[forbid(deprecated_pattern)];

 //! Operations on tuples

 use cmp::{Eq, Ord};

 pub trait CopyableTuple<T, U> {
     pure fn first() -> T;
     pure fn second() -> U;
     pure fn swap() -> (U, T);
 }

 impl<T: Copy, U: Copy> (T, U): CopyableTuple<T, U> {

     /// Return the first element of self
     pure fn first() -> T {
         let (t, _) = self;
         return t;
     }

     /// Return the second element of self
     pure fn second() -> U {
         let (_, u) = self;
         return u;
     }

     /// Return the results of swapping the two elements of self
     pure fn swap() -> (U, T) {
         let (t, u) = self;
         return (u, t);
     }

 }

 pub trait ImmutableTuple<T, U> {
     pure fn first_ref(&self) -> &self/T;
     pure fn second_ref(&self) -> &self/U;
 }

 impl<T, U> (T, U): ImmutableTuple<T, U> {
     pure fn first_ref(&self) -> &self/T {
         match *self {
             (ref t, _) => t,
         }
     }
     pure fn second_ref(&self) -> &self/U {
         match *self {
             (_, ref u) => u,
         }
     }
 }

 pub trait ExtendedTupleOps<A,B> {
     fn zip(&self) -> ~[(A, B)];
     fn map<C>(&self, f: &fn(a: &A, b: &B) -> C) -> ~[C];
 }

 impl<A: Copy, B: Copy> (&[A], &[B]): ExtendedTupleOps<A,B> {
     fn zip(&self) -> ~[(A, B)] {
         match *self {
             (ref a, ref b) => {
                 vec::zip_slice(*a, *b)
             }
         }
     }

     fn map<C>(&self, f: &fn(a: &A, b: &B) -> C) -> ~[C] {
         match *self {
             (ref a, ref b) => {
                 vec::map2(*a, *b, f)
             }
         }
     }
 }

 impl<A: Copy, B: Copy> (~[A], ~[B]): ExtendedTupleOps<A,B> {

     fn zip(&self) -> ~[(A, B)] {
         match *self {
             (ref a, ref b) => {
                 vec::zip_slice(*a, *b)
             }
         }
     }

     fn map<C>(&self, f: &fn(a: &A, b: &B) -> C) -> ~[C] {
         match *self {
             (ref a, ref b) => {
                 vec::map2(*a, *b, f)
             }
         }
     }
 }

 impl<A: Eq, B: Eq> (A, B) : Eq {
     pure fn eq(other: &(A, B)) -> bool {
         match self {
             (ref self_a, ref self_b) => match other {
                 &(ref other_a, ref other_b) => {
                     (*self_a).eq(other_a) && (*self_b).eq(other_b)
                 }
             }
         }
     }
     pure fn ne(other: &(A, B)) -> bool { !self.eq(other) }
 }

 impl<A: Ord, B: Ord> (A, B) : Ord {
     pure fn lt(other: &(A, B)) -> bool {
         match self {
             (ref self_a, ref self_b) => {
                 match (*other) {
                     (ref other_a, ref other_b) => {
                         if (*self_a).lt(other_a) { return true; }
                         if (*other_a).lt(self_a) { return false; }
                         if (*self_b).lt(other_b) { return true; }
                         return false;
                     }
                 }
             }
         }
     }
     pure fn le(other: &(A, B)) -> bool { !(*other).lt(&self) }
     pure fn ge(other: &(A, B)) -> bool { !self.lt(other) }
     pure fn gt(other: &(A, B)) -> bool { (*other).lt(&self)  }
 }

 impl<A: Eq, B: Eq, C: Eq> (A, B, C) : Eq {
     pure fn eq(other: &(A, B, C)) -> bool {
         match self {
             (ref self_a, ref self_b, ref self_c) => match other {
                 &(ref other_a, ref other_b, ref other_c) => {
                     (*self_a).eq(other_a) && (*self_b).eq(other_b)
                         && (*self_c).eq(other_c)
                 }
             }
         }
     }
     pure fn ne(other: &(A, B, C)) -> bool { !self.eq(other) }
 }

 impl<A: Ord, B: Ord, C: Ord> (A, B, C) : Ord {
     pure fn lt(other: &(A, B, C)) -> bool {
         match self {
             (ref self_a, ref self_b, ref self_c) => {
                 match (*other) {
                     (ref other_a, ref other_b, ref other_c) => {
                         if (*self_a).lt(other_a) { return true; }
                         if (*other_a).lt(self_a) { return false; }
                         if (*self_b).lt(other_b) { return true; }
                         if (*other_b).lt(self_b) { return false; }
                         if (*self_c).lt(other_c) { return true; }
                         return false;
                     }
                 }
             }
         }
     }
     pure fn le(other: &(A, B, C)) -> bool { !(*other).lt(&self) }
     pure fn ge(other: &(A, B, C)) -> bool { !self.lt(other) }
     pure fn gt(other: &(A, B, C)) -> bool { (*other).lt(&self)  }
 }

 #[test]
 fn test_tuple_ref() {
     let x = (~"foo", ~"bar");
     assert x.first_ref() == &~"foo";
     assert x.second_ref() == &~"bar";
 }

 #[test]
 #[allow(non_implicitly_copyable_typarams)]
 fn test_tuple() {
     assert (948, 4039.48).first() == 948;
     assert (34.5, ~"foo").second() == ~"foo";
     assert ('a', 2).swap() == (2, 'a');
 }
	// NB: transitionary, de-mode-ing.
	#[forbid(deprecated_mode)];
	#[forbid(deprecated_pattern)];

	//! Operations on tuples

	use cmp::{Eq, Ord};

	pub trait CopyableTuple<T, U> {
	pure fn first() -> T;
	pure fn second() -> U;
	pure fn swap() -> (U, T);
	}

	impl<T: Copy, U: Copy> (T, U): CopyableTuple<T, U> {

	/// Return the first element of self
	pure fn first() -> T {
	let (t, _) = self;
	return t;
	}

	/// Return the second element of self
	pure fn second() -> U {
	let (_, u) = self;
	return u;
	}

	/// Return the results of swapping the two elements of self
	pure fn swap() -> (U, T) {
	let (t, u) = self;
	return (u, t);
	}

	}

	pub trait ImmutableTuple<T, U> {
	pure fn first_ref(&self) -> &self/T;
	pure fn second_ref(&self) -> &self/U;
	}

	impl<T, U> (T, U): ImmutableTuple<T, U> {
	pure fn first_ref(&self) -> &self/T {
	match *self {
	(ref t, _) => t,
	}
	}
	pure fn second_ref(&self) -> &self/U {
	match *self {
	(_, ref u) => u,
	}
	}
	}

	pub trait ExtendedTupleOps<A,B> {
	fn zip(&self) -> ~[(A, B)];
	fn map<C>(&self, f: &fn(a: &A, b: &B) -> C) -> ~[C];
	}

	impl<A: Copy, B: Copy> (&[A], &[B]): ExtendedTupleOps<A,B> {
	fn zip(&self) -> ~[(A, B)] {
	match *self {
	(ref a, ref b) => {
	vec::zip_slice(a, b)
	}
	}
	}

	fn map<C>(&self, f: &fn(a: &A, b: &B) -> C) -> ~[C] {
	match *self {
	(ref a, ref b) => {
	vec::map2(a, b, f)
	}
	}
	}
	}

	impl<A: Copy, B: Copy> (~[A], ~[B]): ExtendedTupleOps<A,B> {

	fn zip(&self) -> ~[(A, B)] {
	match *self {
	(ref a, ref b) => {
	vec::zip_slice(a, b)
	}
	}
	}

	fn map<C>(&self, f: &fn(a: &A, b: &B) -> C) -> ~[C] {
	match *self {
	(ref a, ref b) => {
	vec::map2(a, b, f)
	}
	}
	}
	}

	impl<A: Eq, B: Eq> (A, B) : Eq {
	pure fn eq(other: &(A, B)) -> bool {
	match self {
	(ref self_a, ref self_b) => match other {
	&(ref other_a, ref other_b) => {
	(self_a).eq(other_a) && (self_b).eq(other_b)
	}
	}
	}
	}
	pure fn ne(other: &(A, B)) -> bool { !self.eq(other) }
	}

	impl<A: Ord, B: Ord> (A, B) : Ord {
	pure fn lt(other: &(A, B)) -> bool {
	match self {
	(ref self_a, ref self_b) => {
	match (*other) {
	(ref other_a, ref other_b) => {
	if (*self_a).lt(other_a) { return true; }
	if (*other_a).lt(self_a) { return false; }
	if (*self_b).lt(other_b) { return true; }
	return false;
	}
	}
	}
	}
	}
	pure fn le(other: &(A, B)) -> bool { !(*other).lt(&self) }
	pure fn ge(other: &(A, B)) -> bool { !self.lt(other) }
	pure fn gt(other: &(A, B)) -> bool { (*other).lt(&self) }
	}

	impl<A: Eq, B: Eq, C: Eq> (A, B, C) : Eq {
	pure fn eq(other: &(A, B, C)) -> bool {
	match self {
	(ref self_a, ref self_b, ref self_c) => match other {
	&(ref other_a, ref other_b, ref other_c) => {
	(self_a).eq(other_a) && (self_b).eq(other_b)
	&& (*self_c).eq(other_c)
	}
	}
	}
	}
	pure fn ne(other: &(A, B, C)) -> bool { !self.eq(other) }
	}

	impl<A: Ord, B: Ord, C: Ord> (A, B, C) : Ord {
	pure fn lt(other: &(A, B, C)) -> bool {
	match self {
	(ref self_a, ref self_b, ref self_c) => {
	match (*other) {
	(ref other_a, ref other_b, ref other_c) => {
	if (*self_a).lt(other_a) { return true; }
	if (*other_a).lt(self_a) { return false; }
	if (*self_b).lt(other_b) { return true; }
	if (*other_b).lt(self_b) { return false; }
	if (*self_c).lt(other_c) { return true; }
	return false;
	}
	}
	}
	}
	}
	pure fn le(other: &(A, B, C)) -> bool { !(*other).lt(&self) }
	pure fn ge(other: &(A, B, C)) -> bool { !self.lt(other) }
	pure fn gt(other: &(A, B, C)) -> bool { (*other).lt(&self) }
	}

	#[test]
	fn test_tuple_ref() {
	let x = (~"foo", ~"bar");
	assert x.first_ref() == &~"foo";
	assert x.second_ref() == &~"bar";
	}

	#[test]
	#[allow(non_implicitly_copyable_typarams)]
	fn test_tuple() {
	assert (948, 4039.48).first() == 948;
	assert (34.5, ~"foo").second() == ~"foo";
	assert ('a', 2).swap() == (2, 'a');
	}