src/test/ui/associated-const/issue-69020-assoc-const-arith-overflow.rs - third_party/rust - Git at Google

 // revisions: noopt opt opt_with_overflow_checks
 //[noopt]compile-flags: -C opt-level=0
 //[opt]compile-flags: -O
 //[opt_with_overflow_checks]compile-flags: -C overflow-checks=on -O

 #![crate_type="lib"]

 use std::i32;

 pub trait Foo {
     const NEG: i32;
     const NEG_REV: i32;

     const ADD: i32;
     const ADD_REV: i32;

     const DIV: i32;
     const DIV_REV: i32;

     const OOB: i32;
     const OOB_REV: i32;
 }

 // These constants cannot be evaluated already (they depend on `T::N`), so they can just be linted
 // like normal run-time code. But codegen works a bit different in const context, so this test
 // makes sure that we still catch overflow. Also make sure we emit the same lints if we reverse the
 // operands (so that the generic operand comes first).
 impl<T: Foo> Foo for Vec<T> {
     const NEG: i32 = -i32::MIN + T::NEG;
     //~^ ERROR arithmetic operation will overflow
     const NEG_REV: i32 = T::NEG + (-i32::MIN);
     //~^ ERROR arithmetic operation will overflow

     const ADD: i32 = (i32::MAX+1) + T::ADD;
     //~^ ERROR arithmetic operation will overflow
     const ADD_REV: i32 =  T::ADD + (i32::MAX+1);
     //~^ ERROR arithmetic operation will overflow

     const DIV: i32 = (1/0) + T::DIV;
     //~^ ERROR operation will panic
     const DIV_REV: i32 = T::DIV + (1/0);
     //~^ ERROR operation will panic

     const OOB: i32 = [1][1] + T::OOB;
     //~^ ERROR operation will panic
     const OOB_REV: i32 = T::OOB + [1][1];
     //~^ ERROR operation will panic
 }
	// revisions: noopt opt opt_with_overflow_checks
	//[noopt]compile-flags: -C opt-level=0
	//[opt]compile-flags: -O
	//[opt_with_overflow_checks]compile-flags: -C overflow-checks=on -O

	#![crate_type="lib"]

	use std::i32;

	pub trait Foo {
	const NEG: i32;
	const NEG_REV: i32;

	const ADD: i32;
	const ADD_REV: i32;

	const DIV: i32;
	const DIV_REV: i32;

	const OOB: i32;
	const OOB_REV: i32;
	}

	// These constants cannot be evaluated already (they depend on `T::N`), so they can just be linted
	// like normal run-time code. But codegen works a bit different in const context, so this test
	// makes sure that we still catch overflow. Also make sure we emit the same lints if we reverse the
	// operands (so that the generic operand comes first).
	impl<T: Foo> Foo for Vec<T> {
	const NEG: i32 = -i32::MIN + T::NEG;
	//~^ ERROR arithmetic operation will overflow
	const NEG_REV: i32 = T::NEG + (-i32::MIN);
	//~^ ERROR arithmetic operation will overflow

	const ADD: i32 = (i32::MAX+1) + T::ADD;
	//~^ ERROR arithmetic operation will overflow
	const ADD_REV: i32 = T::ADD + (i32::MAX+1);
	//~^ ERROR arithmetic operation will overflow

	const DIV: i32 = (1/0) + T::DIV;
	//~^ ERROR operation will panic
	const DIV_REV: i32 = T::DIV + (1/0);
	//~^ ERROR operation will panic

	const OOB: i32 = [1][1] + T::OOB;
	//~^ ERROR operation will panic
	const OOB_REV: i32 = T::OOB + [1][1];
	//~^ ERROR operation will panic
	}