mod control_flow; mod from_residual; use core::ops::{ Bound, Deref, DerefMut, Range, RangeFrom, RangeFull, RangeInclusive, RangeTo, RangeToInclusive, }; // Test the Range structs and syntax. #[test] fn test_range() { let r = Range { start: 2, end: 10 }; let mut count = 0; for (i, ri) in r.enumerate() { assert_eq!(ri, i + 2); assert!(ri >= 2 && ri < 10); count += 1; } assert_eq!(count, 8); } #[test] fn test_range_from() { let r = RangeFrom { start: 2 }; let mut count = 0; for (i, ri) in r.take(10).enumerate() { assert_eq!(ri, i + 2); assert!(ri >= 2 && ri < 12); count += 1; } assert_eq!(count, 10); } #[test] fn test_range_to() { // Not much to test. let _ = RangeTo { end: 42 }; } #[test] fn test_full_range() { // Not much to test. let _ = RangeFull; } #[test] fn test_range_inclusive() { let mut r = RangeInclusive::new(1i8, 2); assert_eq!(r.next(), Some(1)); assert_eq!(r.next(), Some(2)); assert_eq!(r.next(), None); r = RangeInclusive::new(127i8, 127); assert_eq!(r.next(), Some(127)); assert_eq!(r.next(), None); r = RangeInclusive::new(-128i8, -128); assert_eq!(r.next_back(), Some(-128)); assert_eq!(r.next_back(), None); // degenerate r = RangeInclusive::new(1, -1); assert_eq!(r.size_hint(), (0, Some(0))); assert_eq!(r.next(), None); } #[test] fn test_range_to_inclusive() { // Not much to test. let _ = RangeToInclusive { end: 42 }; } #[test] fn test_range_is_empty() { assert!(!(0.0..10.0).is_empty()); assert!((-0.0..0.0).is_empty()); assert!((10.0..0.0).is_empty()); assert!(!(f32::NEG_INFINITY..f32::INFINITY).is_empty()); assert!((f32::EPSILON..f32::NAN).is_empty()); assert!((f32::NAN..f32::EPSILON).is_empty()); assert!((f32::NAN..f32::NAN).is_empty()); assert!(!(0.0..=10.0).is_empty()); assert!(!(-0.0..=0.0).is_empty()); assert!((10.0..=0.0).is_empty()); assert!(!(f32::NEG_INFINITY..=f32::INFINITY).is_empty()); assert!((f32::EPSILON..=f32::NAN).is_empty()); assert!((f32::NAN..=f32::EPSILON).is_empty()); assert!((f32::NAN..=f32::NAN).is_empty()); } #[test] fn test_bound_cloned_unbounded() { assert_eq!(Bound::<&u32>::Unbounded.cloned(), Bound::Unbounded); } #[test] fn test_bound_cloned_included() { assert_eq!(Bound::Included(&3).cloned(), Bound::Included(3)); } #[test] fn test_bound_cloned_excluded() { assert_eq!(Bound::Excluded(&3).cloned(), Bound::Excluded(3)); } #[test] #[allow(unused_comparisons)] #[allow(unused_mut)] fn test_range_syntax() { let mut count = 0; for i in 0_usize..10 { assert!(i >= 0 && i < 10); count += i; } assert_eq!(count, 45); let mut count = 0; let mut range = 0_usize..10; for i in range { assert!(i >= 0 && i < 10); count += i; } assert_eq!(count, 45); let mut count = 0; let mut rf = 3_usize..; for i in rf.take(10) { assert!(i >= 3 && i < 13); count += i; } assert_eq!(count, 75); let _ = 0_usize..4 + 4 - 3; fn foo() -> isize { 42 } let _ = 0..foo(); let _ = { &42..&100 }; // references to literals are OK let _ = ..42_usize; // Test we can use two different types with a common supertype. let x = &42; { let y = 42; let _ = x..&y; } } #[test] #[allow(dead_code)] fn test_range_syntax_in_return_statement() { fn return_range_to() -> RangeTo { return ..1; } fn return_full_range() -> RangeFull { return ..; } // Not much to test. } #[test] fn range_structural_match() { // test that all range types can be structurally matched upon const RANGE: Range = 0..1000; match RANGE { RANGE => {} _ => unreachable!(), } const RANGE_FROM: RangeFrom = 0..; match RANGE_FROM { RANGE_FROM => {} _ => unreachable!(), } const RANGE_FULL: RangeFull = ..; match RANGE_FULL { RANGE_FULL => {} } const RANGE_INCLUSIVE: RangeInclusive = 0..=999; match RANGE_INCLUSIVE { RANGE_INCLUSIVE => {} _ => unreachable!(), } const RANGE_TO: RangeTo = ..1000; match RANGE_TO { RANGE_TO => {} _ => unreachable!(), } const RANGE_TO_INCLUSIVE: RangeToInclusive = ..=999; match RANGE_TO_INCLUSIVE { RANGE_TO_INCLUSIVE => {} _ => unreachable!(), } } // Test Deref implementations #[test] fn deref_mut_on_ref() { // Test that `&mut T` implements `DerefMut` fn inc + DerefMut>(mut t: T) { *t += 1; } let mut x: isize = 5; inc(&mut x); assert_eq!(x, 6); } #[test] fn deref_on_ref() { // Test that `&T` and `&mut T` implement `Deref` fn deref>(t: T) -> U { *t } let x: isize = 3; let y = deref(&x); assert_eq!(y, 3); let mut x: isize = 4; let y = deref(&mut x); assert_eq!(y, 4); } #[test] #[allow(unreachable_code)] fn test_not_never() { if !return () {} }