use super::*; #[bench] #[cfg_attr(miri, ignore)] // isolated Miri does not support benchmarks fn bench_push_back_100(b: &mut test::Bencher) { let mut deq = VecDeque::with_capacity(101); b.iter(|| { for i in 0..100 { deq.push_back(i); } deq.head = 0; deq.tail = 0; }) } #[bench] #[cfg_attr(miri, ignore)] // isolated Miri does not support benchmarks fn bench_push_front_100(b: &mut test::Bencher) { let mut deq = VecDeque::with_capacity(101); b.iter(|| { for i in 0..100 { deq.push_front(i); } deq.head = 0; deq.tail = 0; }) } #[bench] #[cfg_attr(miri, ignore)] // isolated Miri does not support benchmarks fn bench_pop_back_100(b: &mut test::Bencher) { let mut deq = VecDeque::::with_capacity(101); b.iter(|| { deq.head = 100; deq.tail = 0; while !deq.is_empty() { test::black_box(deq.pop_back()); } }) } #[bench] #[cfg_attr(miri, ignore)] // isolated Miri does not support benchmarks fn bench_pop_front_100(b: &mut test::Bencher) { let mut deq = VecDeque::::with_capacity(101); b.iter(|| { deq.head = 100; deq.tail = 0; while !deq.is_empty() { test::black_box(deq.pop_front()); } }) } #[test] fn test_swap_front_back_remove() { fn test(back: bool) { // This test checks that every single combination of tail position and length is tested. // Capacity 15 should be large enough to cover every case. let mut tester = VecDeque::with_capacity(15); let usable_cap = tester.capacity(); let final_len = usable_cap / 2; for len in 0..final_len { let expected: VecDeque<_> = if back { (0..len).collect() } else { (0..len).rev().collect() }; for tail_pos in 0..usable_cap { tester.tail = tail_pos; tester.head = tail_pos; if back { for i in 0..len * 2 { tester.push_front(i); } for i in 0..len { assert_eq!(tester.swap_remove_back(i), Some(len * 2 - 1 - i)); } } else { for i in 0..len * 2 { tester.push_back(i); } for i in 0..len { let idx = tester.len() - 1 - i; assert_eq!(tester.swap_remove_front(idx), Some(len * 2 - 1 - i)); } } assert!(tester.tail < tester.cap()); assert!(tester.head < tester.cap()); assert_eq!(tester, expected); } } } test(true); test(false); } #[test] fn test_insert() { // This test checks that every single combination of tail position, length, and // insertion position is tested. Capacity 15 should be large enough to cover every case. let mut tester = VecDeque::with_capacity(15); // can't guarantee we got 15, so have to get what we got. // 15 would be great, but we will definitely get 2^k - 1, for k >= 4, or else // this test isn't covering what it wants to let cap = tester.capacity(); // len is the length *after* insertion let minlen = if cfg!(miri) { cap - 1 } else { 1 }; // Miri is too slow for len in minlen..cap { // 0, 1, 2, .., len - 1 let expected = (0..).take(len).collect::>(); for tail_pos in 0..cap { for to_insert in 0..len { tester.tail = tail_pos; tester.head = tail_pos; for i in 0..len { if i != to_insert { tester.push_back(i); } } tester.insert(to_insert, to_insert); assert!(tester.tail < tester.cap()); assert!(tester.head < tester.cap()); assert_eq!(tester, expected); } } } } #[test] fn make_contiguous_big_tail() { let mut tester = VecDeque::with_capacity(15); for i in 0..3 { tester.push_back(i); } for i in 3..10 { tester.push_front(i); } // 012......9876543 assert_eq!(tester.capacity(), 15); assert_eq!((&[9, 8, 7, 6, 5, 4, 3] as &[_], &[0, 1, 2] as &[_]), tester.as_slices()); let expected_start = tester.head; tester.make_contiguous(); assert_eq!(tester.tail, expected_start); assert_eq!((&[9, 8, 7, 6, 5, 4, 3, 0, 1, 2] as &[_], &[] as &[_]), tester.as_slices()); } #[test] fn make_contiguous_big_head() { let mut tester = VecDeque::with_capacity(15); for i in 0..8 { tester.push_back(i); } for i in 8..10 { tester.push_front(i); } // 01234567......98 let expected_start = 0; tester.make_contiguous(); assert_eq!(tester.tail, expected_start); assert_eq!((&[9, 8, 0, 1, 2, 3, 4, 5, 6, 7] as &[_], &[] as &[_]), tester.as_slices()); } #[test] fn make_contiguous_small_free() { let mut tester = VecDeque::with_capacity(15); for i in 'A' as u8..'I' as u8 { tester.push_back(i as char); } for i in 'I' as u8..'N' as u8 { tester.push_front(i as char); } // ABCDEFGH...MLKJI let expected_start = 0; tester.make_contiguous(); assert_eq!(tester.tail, expected_start); assert_eq!( (&['M', 'L', 'K', 'J', 'I', 'A', 'B', 'C', 'D', 'E', 'F', 'G', 'H'] as &[_], &[] as &[_]), tester.as_slices() ); tester.clear(); for i in 'I' as u8..'N' as u8 { tester.push_back(i as char); } for i in 'A' as u8..'I' as u8 { tester.push_front(i as char); } // IJKLM...HGFEDCBA let expected_start = 0; tester.make_contiguous(); assert_eq!(tester.tail, expected_start); assert_eq!( (&['H', 'G', 'F', 'E', 'D', 'C', 'B', 'A', 'I', 'J', 'K', 'L', 'M'] as &[_], &[] as &[_]), tester.as_slices() ); } #[test] fn make_contiguous_head_to_end() { let mut dq = VecDeque::with_capacity(3); dq.push_front('B'); dq.push_front('A'); dq.push_back('C'); dq.make_contiguous(); let expected_tail = 0; let expected_head = 3; assert_eq!(expected_tail, dq.tail); assert_eq!(expected_head, dq.head); assert_eq!((&['A', 'B', 'C'] as &[_], &[] as &[_]), dq.as_slices()); } #[test] fn make_contiguous_head_to_end_2() { // Another test case for #79808, taken from #80293. let mut dq = VecDeque::from_iter(0..6); dq.pop_front(); dq.pop_front(); dq.push_back(6); dq.push_back(7); dq.push_back(8); dq.make_contiguous(); let collected: Vec<_> = dq.iter().copied().collect(); assert_eq!(dq.as_slices(), (&collected[..], &[] as &[_])); } #[test] fn test_remove() { // This test checks that every single combination of tail position, length, and // removal position is tested. Capacity 15 should be large enough to cover every case. let mut tester = VecDeque::with_capacity(15); // can't guarantee we got 15, so have to get what we got. // 15 would be great, but we will definitely get 2^k - 1, for k >= 4, or else // this test isn't covering what it wants to let cap = tester.capacity(); // len is the length *after* removal let minlen = if cfg!(miri) { cap - 2 } else { 0 }; // Miri is too slow for len in minlen..cap - 1 { // 0, 1, 2, .., len - 1 let expected = (0..).take(len).collect::>(); for tail_pos in 0..cap { for to_remove in 0..=len { tester.tail = tail_pos; tester.head = tail_pos; for i in 0..len { if i == to_remove { tester.push_back(1234); } tester.push_back(i); } if to_remove == len { tester.push_back(1234); } tester.remove(to_remove); assert!(tester.tail < tester.cap()); assert!(tester.head < tester.cap()); assert_eq!(tester, expected); } } } } #[test] fn test_range() { let mut tester: VecDeque = VecDeque::with_capacity(7); let cap = tester.capacity(); let minlen = if cfg!(miri) { cap - 1 } else { 0 }; // Miri is too slow for len in minlen..=cap { for tail in 0..=cap { for start in 0..=len { for end in start..=len { tester.tail = tail; tester.head = tail; for i in 0..len { tester.push_back(i); } // Check that we iterate over the correct values let range: VecDeque<_> = tester.range(start..end).copied().collect(); let expected: VecDeque<_> = (start..end).collect(); assert_eq!(range, expected); } } } } } #[test] fn test_range_mut() { let mut tester: VecDeque = VecDeque::with_capacity(7); let cap = tester.capacity(); for len in 0..=cap { for tail in 0..=cap { for start in 0..=len { for end in start..=len { tester.tail = tail; tester.head = tail; for i in 0..len { tester.push_back(i); } let head_was = tester.head; let tail_was = tester.tail; // Check that we iterate over the correct values let range: VecDeque<_> = tester.range_mut(start..end).map(|v| *v).collect(); let expected: VecDeque<_> = (start..end).collect(); assert_eq!(range, expected); // We shouldn't have changed the capacity or made the // head or tail out of bounds assert_eq!(tester.capacity(), cap); assert_eq!(tester.tail, tail_was); assert_eq!(tester.head, head_was); } } } } } #[test] fn test_drain() { let mut tester: VecDeque = VecDeque::with_capacity(7); let cap = tester.capacity(); for len in 0..=cap { for tail in 0..=cap { for drain_start in 0..=len { for drain_end in drain_start..=len { tester.tail = tail; tester.head = tail; for i in 0..len { tester.push_back(i); } // Check that we drain the correct values let drained: VecDeque<_> = tester.drain(drain_start..drain_end).collect(); let drained_expected: VecDeque<_> = (drain_start..drain_end).collect(); assert_eq!(drained, drained_expected); // We shouldn't have changed the capacity or made the // head or tail out of bounds assert_eq!(tester.capacity(), cap); assert!(tester.tail < tester.cap()); assert!(tester.head < tester.cap()); // We should see the correct values in the VecDeque let expected: VecDeque<_> = (0..drain_start).chain(drain_end..len).collect(); assert_eq!(expected, tester); } } } } } #[test] fn test_shrink_to_fit() { // This test checks that every single combination of head and tail position, // is tested. Capacity 15 should be large enough to cover every case. let mut tester = VecDeque::with_capacity(15); // can't guarantee we got 15, so have to get what we got. // 15 would be great, but we will definitely get 2^k - 1, for k >= 4, or else // this test isn't covering what it wants to let cap = tester.capacity(); tester.reserve(63); let max_cap = tester.capacity(); for len in 0..=cap { // 0, 1, 2, .., len - 1 let expected = (0..).take(len).collect::>(); for tail_pos in 0..=max_cap { tester.tail = tail_pos; tester.head = tail_pos; tester.reserve(63); for i in 0..len { tester.push_back(i); } tester.shrink_to_fit(); assert!(tester.capacity() <= cap); assert!(tester.tail < tester.cap()); assert!(tester.head < tester.cap()); assert_eq!(tester, expected); } } } #[test] fn test_split_off() { // This test checks that every single combination of tail position, length, and // split position is tested. Capacity 15 should be large enough to cover every case. let mut tester = VecDeque::with_capacity(15); // can't guarantee we got 15, so have to get what we got. // 15 would be great, but we will definitely get 2^k - 1, for k >= 4, or else // this test isn't covering what it wants to let cap = tester.capacity(); // len is the length *before* splitting let minlen = if cfg!(miri) { cap - 1 } else { 0 }; // Miri is too slow for len in minlen..cap { // index to split at for at in 0..=len { // 0, 1, 2, .., at - 1 (may be empty) let expected_self = (0..).take(at).collect::>(); // at, at + 1, .., len - 1 (may be empty) let expected_other = (at..).take(len - at).collect::>(); for tail_pos in 0..cap { tester.tail = tail_pos; tester.head = tail_pos; for i in 0..len { tester.push_back(i); } let result = tester.split_off(at); assert!(tester.tail < tester.cap()); assert!(tester.head < tester.cap()); assert!(result.tail < result.cap()); assert!(result.head < result.cap()); assert_eq!(tester, expected_self); assert_eq!(result, expected_other); } } } } #[test] fn test_from_vec() { use crate::vec::Vec; for cap in 0..35 { for len in 0..=cap { let mut vec = Vec::with_capacity(cap); vec.extend(0..len); let vd = VecDeque::from(vec.clone()); assert!(vd.cap().is_power_of_two()); assert_eq!(vd.len(), vec.len()); assert!(vd.into_iter().eq(vec)); } } let vec = Vec::from([(); MAXIMUM_ZST_CAPACITY - 1]); let vd = VecDeque::from(vec.clone()); assert!(vd.cap().is_power_of_two()); assert_eq!(vd.len(), vec.len()); } #[test] #[should_panic = "capacity overflow"] fn test_from_vec_zst_overflow() { use crate::vec::Vec; let vec = Vec::from([(); MAXIMUM_ZST_CAPACITY]); let vd = VecDeque::from(vec.clone()); // no room for +1 assert!(vd.cap().is_power_of_two()); assert_eq!(vd.len(), vec.len()); } #[test] fn test_vec_from_vecdeque() { use crate::vec::Vec; fn create_vec_and_test_convert(capacity: usize, offset: usize, len: usize) { let mut vd = VecDeque::with_capacity(capacity); for _ in 0..offset { vd.push_back(0); vd.pop_front(); } vd.extend(0..len); let vec: Vec<_> = Vec::from(vd.clone()); assert_eq!(vec.len(), vd.len()); assert!(vec.into_iter().eq(vd)); } // Miri is too slow let max_pwr = if cfg!(miri) { 5 } else { 7 }; for cap_pwr in 0..max_pwr { // Make capacity as a (2^x)-1, so that the ring size is 2^x let cap = (2i32.pow(cap_pwr) - 1) as usize; // In these cases there is enough free space to solve it with copies for len in 0..((cap + 1) / 2) { // Test contiguous cases for offset in 0..(cap - len) { create_vec_and_test_convert(cap, offset, len) } // Test cases where block at end of buffer is bigger than block at start for offset in (cap - len)..(cap - (len / 2)) { create_vec_and_test_convert(cap, offset, len) } // Test cases where block at start of buffer is bigger than block at end for offset in (cap - (len / 2))..cap { create_vec_and_test_convert(cap, offset, len) } } // Now there's not (necessarily) space to straighten the ring with simple copies, // the ring will use swapping when: // (cap + 1 - offset) > (cap + 1 - len) && (len - (cap + 1 - offset)) > (cap + 1 - len)) // right block size > free space && left block size > free space for len in ((cap + 1) / 2)..cap { // Test contiguous cases for offset in 0..(cap - len) { create_vec_and_test_convert(cap, offset, len) } // Test cases where block at end of buffer is bigger than block at start for offset in (cap - len)..(cap - (len / 2)) { create_vec_and_test_convert(cap, offset, len) } // Test cases where block at start of buffer is bigger than block at end for offset in (cap - (len / 2))..cap { create_vec_and_test_convert(cap, offset, len) } } } } #[test] fn test_clone_from() { let m = vec![1; 8]; let n = vec![2; 12]; let limit = if cfg!(miri) { 4 } else { 8 }; // Miri is too slow for pfv in 0..limit { for pfu in 0..limit { for longer in 0..2 { let (vr, ur) = if longer == 0 { (&m, &n) } else { (&n, &m) }; let mut v = VecDeque::from(vr.clone()); for _ in 0..pfv { v.push_front(1); } let mut u = VecDeque::from(ur.clone()); for _ in 0..pfu { u.push_front(2); } v.clone_from(&u); assert_eq!(&v, &u); } } } } #[test] fn test_vec_deque_truncate_drop() { static mut DROPS: u32 = 0; #[derive(Clone)] struct Elem(i32); impl Drop for Elem { fn drop(&mut self) { unsafe { DROPS += 1; } } } let v = vec![Elem(1), Elem(2), Elem(3), Elem(4), Elem(5)]; for push_front in 0..=v.len() { let v = v.clone(); let mut tester = VecDeque::with_capacity(5); for (index, elem) in v.into_iter().enumerate() { if index < push_front { tester.push_front(elem); } else { tester.push_back(elem); } } assert_eq!(unsafe { DROPS }, 0); tester.truncate(3); assert_eq!(unsafe { DROPS }, 2); tester.truncate(0); assert_eq!(unsafe { DROPS }, 5); unsafe { DROPS = 0; } } } #[test] fn issue_53529() { use crate::boxed::Box; let mut dst = VecDeque::new(); dst.push_front(Box::new(1)); dst.push_front(Box::new(2)); assert_eq!(*dst.pop_back().unwrap(), 1); let mut src = VecDeque::new(); src.push_front(Box::new(2)); dst.append(&mut src); for a in dst { assert_eq!(*a, 2); } } #[test] fn issue_80303() { use core::iter; use core::num::Wrapping; // This is a valid, albeit rather bad hash function implementation. struct SimpleHasher(Wrapping); impl Hasher for SimpleHasher { fn finish(&self) -> u64 { self.0.0 } fn write(&mut self, bytes: &[u8]) { // This particular implementation hashes value 24 in addition to bytes. // Such an implementation is valid as Hasher only guarantees equivalence // for the exact same set of calls to its methods. for &v in iter::once(&24).chain(bytes) { self.0 = Wrapping(31) * self.0 + Wrapping(u64::from(v)); } } } fn hash_code(value: impl Hash) -> u64 { let mut hasher = SimpleHasher(Wrapping(1)); value.hash(&mut hasher); hasher.finish() } // This creates two deques for which values returned by as_slices // method differ. let vda: VecDeque = (0..10).collect(); let mut vdb = VecDeque::with_capacity(10); vdb.extend(5..10); (0..5).rev().for_each(|elem| vdb.push_front(elem)); assert_ne!(vda.as_slices(), vdb.as_slices()); assert_eq!(vda, vdb); assert_eq!(hash_code(vda), hash_code(vdb)); }