src/tools/clippy/tests/ui/swap.fixed - toolchain/rustc - Git at Google

 //@run-rustfix
 //@aux-build: macro_rules.rs

 #![warn(clippy::all)]
 #![allow(
     clippy::disallowed_names,
     clippy::no_effect,
     clippy::redundant_clone,
     redundant_semicolons,
     dead_code,
     unused_assignments,
     unused_variables,
     clippy::let_and_return,
     clippy::useless_vec,
     clippy::redundant_locals
 )]

 struct Foo(u32);

 #[derive(Clone)]
 struct Bar {
     a: u32,
     b: u32,
 }

 fn field() {
     let mut bar = Bar { a: 1, b: 2 };

     std::mem::swap(&mut bar.a, &mut bar.b);

     let mut baz = vec![bar.clone(), bar.clone()];
     let temp = baz[0].a;
     baz[0].a = baz[1].a;
     baz[1].a = temp;
 }

 fn array() {
     let mut foo = [1, 2];
     foo.swap(0, 1);

     foo.swap(0, 1);
 }

 fn slice() {
     let foo = &mut [1, 2];
     foo.swap(0, 1);

     foo.swap(0, 1);
 }

 fn unswappable_slice() {
     let foo = &mut [vec![1, 2], vec![3, 4]];
     let temp = foo[0][1];
     foo[0][1] = foo[1][0];
     foo[1][0] = temp;

     // swap(foo[0][1], foo[1][0]) would fail
     // this could use split_at_mut and mem::swap, but that is not much simpler.
 }

 fn vec() {
     let mut foo = vec![1, 2];
     foo.swap(0, 1);

     foo.swap(0, 1);
 }

 fn xor_swap_locals() {
     // This is an xor-based swap of local variables.
     let mut a = 0;
     let mut b = 1;
     std::mem::swap(&mut a, &mut b);
 }

 fn xor_field_swap() {
     // This is an xor-based swap of fields in a struct.
     let mut bar = Bar { a: 0, b: 1 };
     std::mem::swap(&mut bar.a, &mut bar.b);
 }

 fn xor_slice_swap() {
     // This is an xor-based swap of a slice
     let foo = &mut [1, 2];
     foo.swap(0, 1);
 }

 fn xor_no_swap() {
     // This is a sequence of xor-assignment statements that doesn't result in a swap.
     let mut a = 0;
     let mut b = 1;
     let mut c = 2;
     a ^= b;
     b ^= c;
     a ^= c;
     c ^= a;
 }

 fn xor_unswappable_slice() {
     let foo = &mut [vec![1, 2], vec![3, 4]];
     foo[0][1] ^= foo[1][0];
     foo[1][0] ^= foo[0][0];
     foo[0][1] ^= foo[1][0];

     // swap(foo[0][1], foo[1][0]) would fail
     // this could use split_at_mut and mem::swap, but that is not much simpler.
 }

 fn distinct_slice() {
     let foo = &mut [vec![1, 2], vec![3, 4]];
     let bar = &mut [vec![1, 2], vec![3, 4]];
     std::mem::swap(&mut foo[0][1], &mut bar[1][0]);
 }

 #[rustfmt::skip]
 fn main() {

     let mut a = 42;
     let mut b = 1337;

     std::mem::swap(&mut a, &mut b);

     ; std::mem::swap(&mut a, &mut b);

     let mut c = Foo(42);

     std::mem::swap(&mut c.0, &mut a);

     ; std::mem::swap(&mut c.0, &mut a);

     std::mem::swap(&mut a, &mut b);

     let mut c = 1;
     let mut d = 2;
     std::mem::swap(&mut d, &mut c);

     let mut b = 1;
     std::mem::swap(&mut a, &mut b);

     let b = 1;
     let a = 2;

     let t = b;
     let b = a;
     let a = t;

     let mut b = 1;
     let mut a = 2;

     std::mem::swap(&mut b, &mut a);
 }

 fn issue_8154() {
     struct S1 {
         x: i32,
         y: i32,
     }
     struct S2(S1);
     struct S3<'a, 'b>(&'a mut &'b mut S1);

     impl std::ops::Deref for S2 {
         type Target = S1;
         fn deref(&self) -> &Self::Target {
             &self.0
         }
     }
     impl std::ops::DerefMut for S2 {
         fn deref_mut(&mut self) -> &mut Self::Target {
             &mut self.0
         }
     }

     // Don't lint. `s.0` is mutably borrowed by `s.x` and `s.y` via the deref impl.
     let mut s = S2(S1 { x: 0, y: 0 });
     let t = s.x;
     s.x = s.y;
     s.y = t;

     // Accessing through a mutable reference is fine
     let mut s = S1 { x: 0, y: 0 };
     let mut s = &mut s;
     let s = S3(&mut s);
     std::mem::swap(&mut s.0.x, &mut s.0.y);
 }

 const fn issue_9864(mut u: u32) -> u32 {
     let mut v = 10;

     let temp = u;
     u = v;
     v = temp;
     u + v
 }

 #[macro_use]
 extern crate macro_rules;

 const fn issue_10421(x: u32) -> u32 {
     issue_10421!();
     let a = x;
     let a = a;
     let a = a;
     a
 }
	//@run-rustfix
	//@aux-build: macro_rules.rs

	#![warn(clippy::all)]
	#![allow(
	clippy::disallowed_names,
	clippy::no_effect,
	clippy::redundant_clone,
	redundant_semicolons,
	dead_code,
	unused_assignments,
	unused_variables,
	clippy::let_and_return,
	clippy::useless_vec,
	clippy::redundant_locals
	)]

	struct Foo(u32);

	#[derive(Clone)]
	struct Bar {
	a: u32,
	b: u32,
	}

	fn field() {
	let mut bar = Bar { a: 1, b: 2 };

	std::mem::swap(&mut bar.a, &mut bar.b);

	let mut baz = vec![bar.clone(), bar.clone()];
	let temp = baz[0].a;
	baz[0].a = baz[1].a;
	baz[1].a = temp;
	}

	fn array() {
	let mut foo = [1, 2];
	foo.swap(0, 1);

	foo.swap(0, 1);
	}

	fn slice() {
	let foo = &mut [1, 2];
	foo.swap(0, 1);

	foo.swap(0, 1);
	}

	fn unswappable_slice() {
	let foo = &mut [vec![1, 2], vec![3, 4]];
	let temp = foo[0][1];
	foo[0][1] = foo[1][0];
	foo[1][0] = temp;

	// swap(foo[0][1], foo[1][0]) would fail
	// this could use split_at_mut and mem::swap, but that is not much simpler.
	}

	fn vec() {
	let mut foo = vec![1, 2];
	foo.swap(0, 1);

	foo.swap(0, 1);
	}

	fn xor_swap_locals() {
	// This is an xor-based swap of local variables.
	let mut a = 0;
	let mut b = 1;
	std::mem::swap(&mut a, &mut b);
	}

	fn xor_field_swap() {
	// This is an xor-based swap of fields in a struct.
	let mut bar = Bar { a: 0, b: 1 };
	std::mem::swap(&mut bar.a, &mut bar.b);
	}

	fn xor_slice_swap() {
	// This is an xor-based swap of a slice
	let foo = &mut [1, 2];
	foo.swap(0, 1);
	}

	fn xor_no_swap() {
	// This is a sequence of xor-assignment statements that doesn't result in a swap.
	let mut a = 0;
	let mut b = 1;
	let mut c = 2;
	a ^= b;
	b ^= c;
	a ^= c;
	c ^= a;
	}

	fn xor_unswappable_slice() {
	let foo = &mut [vec![1, 2], vec![3, 4]];
	foo[0][1] ^= foo[1][0];
	foo[1][0] ^= foo[0][0];
	foo[0][1] ^= foo[1][0];

	// swap(foo[0][1], foo[1][0]) would fail
	// this could use split_at_mut and mem::swap, but that is not much simpler.
	}

	fn distinct_slice() {
	let foo = &mut [vec![1, 2], vec![3, 4]];
	let bar = &mut [vec![1, 2], vec![3, 4]];
	std::mem::swap(&mut foo[0][1], &mut bar[1][0]);
	}

	#[rustfmt::skip]
	fn main() {

	let mut a = 42;
	let mut b = 1337;

	std::mem::swap(&mut a, &mut b);

	; std::mem::swap(&mut a, &mut b);

	let mut c = Foo(42);

	std::mem::swap(&mut c.0, &mut a);

	; std::mem::swap(&mut c.0, &mut a);

	std::mem::swap(&mut a, &mut b);

	let mut c = 1;
	let mut d = 2;
	std::mem::swap(&mut d, &mut c);

	let mut b = 1;
	std::mem::swap(&mut a, &mut b);

	let b = 1;
	let a = 2;

	let t = b;
	let b = a;
	let a = t;

	let mut b = 1;
	let mut a = 2;

	std::mem::swap(&mut b, &mut a);
	}

	fn issue_8154() {
	struct S1 {
	x: i32,
	y: i32,
	}
	struct S2(S1);
	struct S3<'a, 'b>(&'a mut &'b mut S1);

	impl std::ops::Deref for S2 {
	type Target = S1;
	fn deref(&self) -> &Self::Target {
	&self.0
	}
	}
	impl std::ops::DerefMut for S2 {
	fn deref_mut(&mut self) -> &mut Self::Target {
	&mut self.0
	}
	}

	// Don't lint. `s.0` is mutably borrowed by `s.x` and `s.y` via the deref impl.
	let mut s = S2(S1 { x: 0, y: 0 });
	let t = s.x;
	s.x = s.y;
	s.y = t;

	// Accessing through a mutable reference is fine
	let mut s = S1 { x: 0, y: 0 };
	let mut s = &mut s;
	let s = S3(&mut s);
	std::mem::swap(&mut s.0.x, &mut s.0.y);
	}

	const fn issue_9864(mut u: u32) -> u32 {
	let mut v = 10;

	let temp = u;
	u = v;
	v = temp;
	u + v
	}

	#[macro_use]
	extern crate macro_rules;

	const fn issue_10421(x: u32) -> u32 {
	issue_10421!();
	let a = x;
	let a = a;
	let a = a;
	a
	}