use std::any::Any; use std::cell::RefCell; use std::cmp::PartialEq; use std::iter::TrustedLen; use std::mem; use std::sync::{Arc, Weak}; #[test] fn uninhabited() { enum Void {} let mut a = Weak::::new(); a = a.clone(); assert!(a.upgrade().is_none()); let mut a: Weak = a; // Unsizing a = a.clone(); assert!(a.upgrade().is_none()); } #[test] fn slice() { let a: Arc<[u32; 3]> = Arc::new([3, 2, 1]); let a: Arc<[u32]> = a; // Unsizing let b: Arc<[u32]> = Arc::from(&[3, 2, 1][..]); // Conversion assert_eq!(a, b); // Exercise is_dangling() with a DST let mut a = Arc::downgrade(&a); a = a.clone(); assert!(a.upgrade().is_some()); } #[test] fn trait_object() { let a: Arc = Arc::new(4); let a: Arc = a; // Unsizing // Exercise is_dangling() with a DST let mut a = Arc::downgrade(&a); a = a.clone(); assert!(a.upgrade().is_some()); let mut b = Weak::::new(); b = b.clone(); assert!(b.upgrade().is_none()); let mut b: Weak = b; // Unsizing b = b.clone(); assert!(b.upgrade().is_none()); } #[test] fn float_nan_ne() { let x = Arc::new(f32::NAN); assert!(x != x); assert!(!(x == x)); } #[test] fn partial_eq() { struct TestPEq(RefCell); impl PartialEq for TestPEq { fn eq(&self, other: &TestPEq) -> bool { *self.0.borrow_mut() += 1; *other.0.borrow_mut() += 1; true } } let x = Arc::new(TestPEq(RefCell::new(0))); assert!(x == x); assert!(!(x != x)); assert_eq!(*x.0.borrow(), 4); } #[test] fn eq() { #[derive(Eq)] struct TestEq(RefCell); impl PartialEq for TestEq { fn eq(&self, other: &TestEq) -> bool { *self.0.borrow_mut() += 1; *other.0.borrow_mut() += 1; true } } let x = Arc::new(TestEq(RefCell::new(0))); assert!(x == x); assert!(!(x != x)); assert_eq!(*x.0.borrow(), 0); } // The test code below is identical to that in `rc.rs`. // For better maintainability we therefore define this type alias. type Rc = Arc; const SHARED_ITER_MAX: u16 = 100; fn assert_trusted_len(_: &I) {} #[test] fn shared_from_iter_normal() { // Exercise the base implementation for non-`TrustedLen` iterators. { // `Filter` is never `TrustedLen` since we don't // know statically how many elements will be kept: let iter = (0..SHARED_ITER_MAX).filter(|x| x % 2 == 0).map(Box::new); // Collecting into a `Vec` or `Rc<[T]>` should make no difference: let vec = iter.clone().collect::>(); let rc = iter.collect::>(); assert_eq!(&*vec, &*rc); // Clone a bit and let these get dropped. { let _rc_2 = rc.clone(); let _rc_3 = rc.clone(); let _rc_4 = Rc::downgrade(&_rc_3); } } // Drop what hasn't been here. } #[test] fn shared_from_iter_trustedlen_normal() { // Exercise the `TrustedLen` implementation under normal circumstances // where `size_hint()` matches `(_, Some(exact_len))`. { let iter = (0..SHARED_ITER_MAX).map(Box::new); assert_trusted_len(&iter); // Collecting into a `Vec` or `Rc<[T]>` should make no difference: let vec = iter.clone().collect::>(); let rc = iter.collect::>(); assert_eq!(&*vec, &*rc); assert_eq!(mem::size_of::>() * SHARED_ITER_MAX as usize, mem::size_of_val(&*rc)); // Clone a bit and let these get dropped. { let _rc_2 = rc.clone(); let _rc_3 = rc.clone(); let _rc_4 = Rc::downgrade(&_rc_3); } } // Drop what hasn't been here. // Try a ZST to make sure it is handled well. { let iter = (0..SHARED_ITER_MAX).map(drop); let vec = iter.clone().collect::>(); let rc = iter.collect::>(); assert_eq!(&*vec, &*rc); assert_eq!(0, mem::size_of_val(&*rc)); { let _rc_2 = rc.clone(); let _rc_3 = rc.clone(); let _rc_4 = Rc::downgrade(&_rc_3); } } } #[test] #[should_panic = "I've almost got 99 problems."] fn shared_from_iter_trustedlen_panic() { // Exercise the `TrustedLen` implementation when `size_hint()` matches // `(_, Some(exact_len))` but where `.next()` drops before the last iteration. let iter = (0..SHARED_ITER_MAX).map(|val| match val { 98 => panic!("I've almost got 99 problems."), _ => Box::new(val), }); assert_trusted_len(&iter); let _ = iter.collect::>(); panic!("I am unreachable."); } #[test] fn shared_from_iter_trustedlen_no_fuse() { // Exercise the `TrustedLen` implementation when `size_hint()` matches // `(_, Some(exact_len))` but where the iterator does not behave in a fused manner. struct Iter(std::vec::IntoIter>>); unsafe impl TrustedLen for Iter {} impl Iterator for Iter { fn size_hint(&self) -> (usize, Option) { (2, Some(2)) } type Item = Box; fn next(&mut self) -> Option { self.0.next().flatten() } } let vec = vec![Some(Box::new(42)), Some(Box::new(24)), None, Some(Box::new(12))]; let iter = Iter(vec.into_iter()); assert_trusted_len(&iter); assert_eq!(&[Box::new(42), Box::new(24)], &*iter.collect::>()); } #[test] fn weak_may_dangle() { fn hmm<'a>(val: &'a mut Weak<&'a str>) -> Weak<&'a str> { val.clone() } // Without #[may_dangle] we get: let mut val = Weak::new(); hmm(&mut val); // ~~~~~~~~ borrowed value does not live long enough // // `val` dropped here while still borrowed // borrow might be used here, when `val` is dropped and runs the `Drop` code for type `std::sync::Weak` }