//@ run-pass //@ compile-flags: -C debug-assertions // FIXME(static_mut_refs): Do not allow `static_mut_refs` lint #![allow(static_mut_refs)] // Check that we do *not* overflow on a number of edge cases. // (compare with test/run-fail/overflowing-{lsh,rsh}*.rs) fn main() { test_left_shift(); test_right_shift(); } pub static mut HACK: i32 = 0; // Work around constant-evaluation // The point of this test is to exercise the code generated for execution at runtime, // `id` can never be flagged as a const fn by future aggressive analyses... // due to the modification of the static #[inline(never)] fn id(x: T) -> T { unsafe { HACK += 1; } x } fn test_left_shift() { // negative rhs can panic, but values in [0,N-1] are okay for iN macro_rules! tests { ($iN:ty, $uN:ty, $max_rhs:expr, $expect_i:expr, $expect_u:expr) => { { let x = (1 as $iN) << id(0); assert_eq!(x, 1); let x = (1 as $uN) << id(0); assert_eq!(x, 1); let x = (1 as $iN) << id($max_rhs); assert_eq!(x, $expect_i); let x = (1 as $uN) << id($max_rhs); assert_eq!(x, $expect_u); // high-order bits on LHS are silently discarded without panic. let x = (3 as $iN) << id($max_rhs); assert_eq!(x, $expect_i); let x = (3 as $uN) << id($max_rhs); assert_eq!(x, $expect_u); } } } let x = 1_i8 << id(0); assert_eq!(x, 1); let x = 1_u8 << id(0); assert_eq!(x, 1); let x = 1_i8 << id(7); assert_eq!(x, i8::MIN); let x = 1_u8 << id(7); assert_eq!(x, 0x80); // high-order bits on LHS are silently discarded without panic. let x = 3_i8 << id(7); assert_eq!(x, i8::MIN); let x = 3_u8 << id(7); assert_eq!(x, 0x80); // above is (approximately) expanded from: tests!(i8, u8, 7, i8::MIN, 0x80_u8); tests!(i16, u16, 15, i16::MIN, 0x8000_u16); tests!(i32, u32, 31, i32::MIN, 0x8000_0000_u32); tests!(i64, u64, 63, i64::MIN, 0x8000_0000_0000_0000_u64); } fn test_right_shift() { // negative rhs can panic, but values in [0,N-1] are okay for iN macro_rules! tests { ($iN:ty, $uN:ty, $max_rhs:expr, $signbit_i:expr, $highbit_i:expr, $highbit_u:expr) => { { let x = (1 as $iN) >> id(0); assert_eq!(x, 1); let x = (1 as $uN) >> id(0); assert_eq!(x, 1); let x = ($highbit_i) >> id($max_rhs-1); assert_eq!(x, 1); let x = ($highbit_u) >> id($max_rhs); assert_eq!(x, 1); // sign-bit is carried by arithmetic right shift let x = ($signbit_i) >> id($max_rhs); assert_eq!(x, -1); // low-order bits on LHS are silently discarded without panic. let x = ($highbit_i + 1) >> id($max_rhs-1); assert_eq!(x, 1); let x = ($highbit_u + 1) >> id($max_rhs); assert_eq!(x, 1); let x = ($signbit_i + 1) >> id($max_rhs); assert_eq!(x, -1); } } } tests!(i8, u8, 7, i8::MIN, 0x40_i8, 0x80_u8); tests!(i16, u16, 15, i16::MIN, 0x4000_u16, 0x8000_u16); tests!(i32, u32, 31, i32::MIN, 0x4000_0000_u32, 0x8000_0000_u32); tests!(i64, u64, 63, i64::MIN, 0x4000_0000_0000_0000_u64, 0x8000_0000_0000_0000_u64); }