use veilid_hashlink::{linked_hash_map, LinkedHashMap}; #[allow(dead_code)] fn assert_covariance() { fn set<'new>(v: LinkedHashMap<&'static str, ()>) -> LinkedHashMap<&'new str, ()> { v } fn iter<'a, 'new>( v: linked_hash_map::Iter<'a, &'static str, &'static str>, ) -> linked_hash_map::Iter<'a, &'new str, &'new str> { v } fn iter_mut<'a, 'new>( v: linked_hash_map::Iter<'a, &'static str, ()>, ) -> linked_hash_map::Iter<'a, &'new str, ()> { v } fn into_iter<'new>( v: linked_hash_map::IntoIter<&'static str, &'static str>, ) -> linked_hash_map::IntoIter<&'new str, &'new str> { v } fn drain<'new>( d: linked_hash_map::Drain<'static, &'static str, &'static str>, ) -> linked_hash_map::Drain<'new, &'new str, &'new str> { d } fn raw_entry_builder<'a, 'new>( v: linked_hash_map::RawEntryBuilder<'a, &'static str, &'static str, ()>, ) -> linked_hash_map::RawEntryBuilder<'a, &'new str, &'new str, ()> { v } } #[test] fn test_index() { let mut map = LinkedHashMap::new(); map.insert(1, 10); map.insert(2, 20); assert_eq!(10, map[&1]); map[&2] = 22; assert_eq!(22, map[&2]); } #[test] fn test_insert_and_get() { let mut map = LinkedHashMap::new(); map.insert(1, 10); map.insert(2, 20); assert_eq!(map.get(&1), Some(&10)); assert_eq!(map.get(&2), Some(&20)); assert_eq!(map.len(), 2); } #[test] fn test_insert_update() { let mut map = LinkedHashMap::new(); map.insert("1".to_string(), vec![10, 10]); map.insert("1".to_string(), vec![10, 19]); assert_eq!(map.get(&"1".to_string()), Some(&vec![10, 19])); assert_eq!(map.len(), 1); } #[test] fn test_entry_insert_vacant() { let mut map = LinkedHashMap::new(); match map.entry("1".to_string()) { linked_hash_map::Entry::Vacant(e) => { assert_eq!(*e.insert(vec![10, 10]), vec![10, 10]); } _ => panic!("fail"), } assert!(map.contains_key("1")); assert_eq!(map["1"], vec![10, 10]); match map.entry("1".to_string()) { linked_hash_map::Entry::Occupied(mut e) => { assert_eq!(*e.get(), vec![10, 10]); assert_eq!(e.insert(vec![10, 16]), vec![10, 10]); } _ => panic!("fail"), } assert!(map.contains_key("1")); assert_eq!(map["1"], vec![10, 16]); match map.entry("1".to_string()) { linked_hash_map::Entry::Occupied(e) => { assert_eq!(e.remove(), vec![10, 16]); } _ => panic!("fail"), } } #[test] fn test_remove() { let mut map = LinkedHashMap::new(); map.insert(1, 10); map.insert(2, 20); map.insert(3, 30); map.insert(4, 40); map.insert(5, 50); map.remove(&3); map.remove(&4); assert!(map.get(&3).is_none()); assert!(map.get(&4).is_none()); map.insert(6, 60); map.insert(7, 70); map.insert(8, 80); assert_eq!(map.get(&6), Some(&60)); assert_eq!(map.get(&7), Some(&70)); assert_eq!(map.get(&8), Some(&80)); } #[test] fn test_pop() { let mut map = LinkedHashMap::new(); map.insert(1, 10); map.insert(2, 20); map.insert(3, 30); map.insert(4, 40); map.insert(5, 50); assert_eq!(map.pop_front(), Some((1, 10))); assert!(map.get(&1).is_none()); assert_eq!(map.pop_back(), Some((5, 50))); assert!(map.get(&5).is_none()); map.insert(6, 60); map.insert(7, 70); map.insert(8, 80); assert_eq!(map.pop_front(), Some((2, 20))); assert!(map.get(&2).is_none()); assert_eq!(map.pop_back(), Some((8, 80))); assert!(map.get(&8).is_none()); map.insert(3, 30); assert_eq!(map.pop_front(), Some((4, 40))); assert!(map.get(&4).is_none()); assert_eq!(map.pop_back(), Some((3, 30))); assert!(map.get(&3).is_none()); } #[test] fn test_move() { let to_back = |map: &mut LinkedHashMap<_, _>, key| match map.entry(key) { linked_hash_map::Entry::Occupied(mut occupied) => occupied.to_back(), linked_hash_map::Entry::Vacant(_) => panic!(), }; let to_front = |map: &mut LinkedHashMap<_, _>, key| match map.entry(key) { linked_hash_map::Entry::Occupied(mut occupied) => occupied.to_front(), linked_hash_map::Entry::Vacant(_) => panic!(), }; let mut map = LinkedHashMap::new(); map.insert(1, 10); map.insert(2, 20); map.insert(3, 30); map.insert(4, 40); map.insert(5, 50); to_back(&mut map, 1); assert_eq!(map.keys().copied().collect::>(), vec![2, 3, 4, 5, 1]); to_front(&mut map, 4); assert_eq!(map.keys().copied().collect::>(), vec![4, 2, 3, 5, 1]); to_back(&mut map, 3); assert_eq!(map.keys().copied().collect::>(), vec![4, 2, 5, 1, 3]); to_front(&mut map, 2); assert_eq!(map.keys().copied().collect::>(), vec![2, 4, 5, 1, 3]); to_back(&mut map, 3); assert_eq!(map.keys().copied().collect::>(), vec![2, 4, 5, 1, 3]); to_front(&mut map, 2); assert_eq!(map.keys().copied().collect::>(), vec![2, 4, 5, 1, 3]); } #[test] fn test_clear() { let mut map = LinkedHashMap::new(); map.insert(1, 10); map.insert(2, 20); map.clear(); assert!(map.get(&1).is_none()); assert!(map.get(&2).is_none()); assert!(map.is_empty()); } #[test] fn test_iter() { let mut map = LinkedHashMap::new(); // empty iter assert_eq!(None, map.iter().next()); map.insert("a", 10); map.insert("b", 20); map.insert("c", 30); // regular iter let mut iter = map.iter(); assert_eq!((&"a", &10), iter.next().unwrap()); assert_eq!((&"b", &20), iter.next().unwrap()); assert_eq!((&"c", &30), iter.next().unwrap()); assert_eq!(None, iter.next()); assert_eq!(None, iter.next()); let mut iter = map.iter(); assert_eq!((&"a", &10), iter.next().unwrap()); let mut iclone = iter.clone(); assert_eq!((&"b", &20), iter.next().unwrap()); assert_eq!((&"b", &20), iclone.next().unwrap()); assert_eq!((&"c", &30), iter.next().unwrap()); assert_eq!((&"c", &30), iclone.next().unwrap()); // reversed iter let mut rev_iter = map.iter().rev(); assert_eq!((&"c", &30), rev_iter.next().unwrap()); assert_eq!((&"b", &20), rev_iter.next().unwrap()); assert_eq!((&"a", &10), rev_iter.next().unwrap()); assert_eq!(None, rev_iter.next()); assert_eq!(None, rev_iter.next()); // mixed let mut mixed_iter = map.iter(); assert_eq!((&"a", &10), mixed_iter.next().unwrap()); assert_eq!((&"c", &30), mixed_iter.next_back().unwrap()); assert_eq!((&"b", &20), mixed_iter.next().unwrap()); assert_eq!(None, mixed_iter.next()); assert_eq!(None, mixed_iter.next_back()); } #[test] fn test_borrow() { #[derive(PartialEq, Eq, Hash)] struct Foo(Bar); #[derive(PartialEq, Eq, Hash)] struct Bar(i32); impl ::std::borrow::Borrow for Foo { fn borrow(&self) -> &Bar { &self.0 } } let mut map = LinkedHashMap::new(); map.insert(Foo(Bar(1)), "a"); map.insert(Foo(Bar(2)), "b"); assert!(map.contains_key(&Bar(1))); assert!(map.contains_key(&Bar(2))); assert!(map.contains_key(&Foo(Bar(1)))); assert!(map.contains_key(&Foo(Bar(2)))); assert_eq!(map.get(&Bar(1)), Some(&"a")); assert_eq!(map.get(&Bar(2)), Some(&"b")); assert_eq!(map.get(&Foo(Bar(1))), Some(&"a")); assert_eq!(map.get(&Foo(Bar(2))), Some(&"b")); assert_eq!(map.get_mut(&Bar(1)), Some(&mut "a")); assert_eq!(map.get_mut(&Bar(2)), Some(&mut "b")); assert_eq!(map.get_mut(&Foo(Bar(1))), Some(&mut "a")); assert_eq!(map.get_mut(&Foo(Bar(2))), Some(&mut "b")); assert_eq!(map[&Bar(1)], "a"); assert_eq!(map[&Bar(2)], "b"); assert_eq!(map[&Foo(Bar(1))], "a"); assert_eq!(map[&Foo(Bar(2))], "b"); assert_eq!(map.remove(&Bar(1)), Some("a")); assert_eq!(map.remove(&Bar(2)), Some("b")); assert_eq!(map.remove(&Foo(Bar(1))), None); assert_eq!(map.remove(&Foo(Bar(2))), None); } #[test] fn test_iter_mut() { let mut map = LinkedHashMap::new(); map.insert("a", 10); map.insert("c", 30); map.insert("b", 20); { let mut iter = map.iter_mut(); let entry = iter.next().unwrap(); assert_eq!("a", *entry.0); *entry.1 = 17; assert_eq!(format!("{:?}", iter), "[(\"c\", 30), (\"b\", 20)]"); // reverse iterator let mut iter = iter.rev(); let entry = iter.next().unwrap(); assert_eq!("b", *entry.0); *entry.1 = 23; let entry = iter.next().unwrap(); assert_eq!("c", *entry.0); assert_eq!(None, iter.next()); assert_eq!(None, iter.next()); } assert_eq!(17, map[&"a"]); assert_eq!(23, map[&"b"]); } #[test] fn test_consuming_iter() { let map = { let mut map = LinkedHashMap::new(); map.insert("a", 10); map.insert("c", 30); map.insert("b", 20); map }; let mut iter = map.into_iter(); assert_eq!(Some(("a", 10)), iter.next()); assert_eq!(Some(("b", 20)), iter.next_back()); assert_eq!(iter.len(), 1); assert_eq!(format!("{:?}", iter), "[(\"c\", 30)]"); assert_eq!(Some(("c", 30)), iter.next()); assert_eq!(None, iter.next()); } #[test] fn test_consuming_iter_empty() { let map = LinkedHashMap::<&str, i32>::new(); let mut iter = map.into_iter(); assert_eq!(None, iter.next()); } #[test] fn test_consuming_iter_with_free_list() { let mut map = LinkedHashMap::new(); map.insert("a", 10); map.insert("c", 30); map.insert("b", 20); map.remove("a"); map.remove("b"); let mut iter = map.into_iter(); assert_eq!(Some(("c", 30)), iter.next()); assert_eq!(None, iter.next()); } #[test] fn test_into_iter_drop() { struct Counter<'a>(&'a mut usize); impl<'a> Drop for Counter<'a> { fn drop(&mut self) { *self.0 += 1; } } let mut a = 0; let mut b = 0; let mut c = 0; { let mut map = LinkedHashMap::new(); map.insert("a", Counter(&mut a)); map.insert("b", Counter(&mut b)); map.insert("c", Counter(&mut c)); let mut iter = map.into_iter(); assert_eq!(iter.next().map(|p| p.0), Some("a")); assert_eq!(iter.next_back().map(|p| p.0), Some("c")); } assert_eq!(a, 1); assert_eq!(b, 1); assert_eq!(c, 1); } #[test] fn test_drain() { use std::{cell::Cell, rc::Rc}; struct Counter(Rc>); impl Drop for Counter { fn drop(&mut self) { self.0.set(self.0.get() + 1); } } let mut map = LinkedHashMap::new(); let a = Rc::new(Cell::new(0)); let b = Rc::new(Cell::new(0)); let c = Rc::new(Cell::new(0)); map.insert("a", Counter(a.clone())); map.insert("b", Counter(b.clone())); map.insert("c", Counter(c.clone())); let mut iter = map.drain(); assert_eq!(iter.next().map(|p| p.0), Some("a")); assert_eq!(iter.next_back().map(|p| p.0), Some("c")); assert_eq!(iter.next_back().map(|p| p.0), Some("b")); assert!(iter.next().is_none()); assert!(iter.next_back().is_none()); drop(iter); assert_eq!(map.len(), 0); assert_eq!(a.get(), 1); assert_eq!(b.get(), 1); assert_eq!(c.get(), 1); map.insert("a", Counter(a.clone())); map.insert("b", Counter(b.clone())); map.insert("c", Counter(c.clone())); let mut iter = map.drain(); assert_eq!(iter.next().map(|p| p.0), Some("a")); assert_eq!(iter.next().map(|p| p.0), Some("b")); assert_eq!(iter.next_back().map(|p| p.0), Some("c")); assert!(iter.next().is_none()); assert!(iter.next_back().is_none()); drop(iter); assert_eq!(map.len(), 0); assert_eq!(a.get(), 2); assert_eq!(b.get(), 2); assert_eq!(c.get(), 2); map.insert("a", Counter(a.clone())); map.insert("b", Counter(b.clone())); map.insert("c", Counter(c.clone())); map.drain(); assert_eq!(map.len(), 0); assert_eq!(a.get(), 3); assert_eq!(b.get(), 3); assert_eq!(c.get(), 3); } #[test] fn test_send_sync() { fn is_send_sync() {} is_send_sync::>(); is_send_sync::>(); is_send_sync::>(); is_send_sync::>(); is_send_sync::>(); is_send_sync::>(); is_send_sync::>(); is_send_sync::>(); is_send_sync::>(); is_send_sync::>(); } #[test] fn test_retain() { use std::{cell::Cell, rc::Rc}; let xs = [1, 2, 3, 4, 5, 6]; let mut map: LinkedHashMap = xs.iter().map(|i| (i.to_string(), *i)).collect(); map.retain(|_, v| *v % 2 == 0); assert_eq!(map.len(), 3); assert!(map.contains_key("2")); assert!(map.contains_key("4")); assert!(map.contains_key("6")); struct Counter(Rc>); impl Drop for Counter { fn drop(&mut self) { self.0.set(self.0.get() + 1); } } let c = Rc::new(Cell::new(0)); let mut map = LinkedHashMap::new(); map.insert(1, Counter(Rc::clone(&c))); map.insert(2, Counter(Rc::clone(&c))); map.insert(3, Counter(Rc::clone(&c))); map.insert(4, Counter(Rc::clone(&c))); map.retain(|k, _| *k % 2 == 0); assert!(c.get() == 2); drop(map); assert!(c.get() == 4); } #[test] fn test_order_equality() { let xs = [1, 2, 3, 4, 5, 6]; let mut map1: LinkedHashMap = xs.iter().map(|i| (i.to_string(), *i)).collect(); let mut map2: LinkedHashMap = xs.iter().map(|i| (i.to_string(), *i)).collect(); assert_eq!(map1, map2); map1.to_front("4"); assert_ne!(map1, map2); map2.to_front("4"); assert_eq!(map1, map2); } #[test] fn test_replace() { let mut map = LinkedHashMap::new(); map.insert(1, 1); map.insert(2, 2); map.insert(3, 3); map.insert(4, 4); assert!(map .iter() .map(|(k, v)| (*k, *v)) .eq([(1, 1), (2, 2), (3, 3), (4, 4)].iter().copied())); map.insert(3, 5); assert!(map .iter() .map(|(k, v)| (*k, *v)) .eq([(1, 1), (2, 2), (4, 4), (3, 5)].iter().copied())); map.replace(2, 6); assert!(map .iter() .map(|(k, v)| (*k, *v)) .eq([(1, 1), (2, 6), (4, 4), (3, 5)].iter().copied())); } #[test] fn test_reserve() { let mut map = LinkedHashMap::new(); map.insert(1, 1); map.insert(2, 2); map.insert(3, 3); map.insert(4, 4); assert!(map.capacity() - map.len() < 100); map.reserve(100); assert!(map.capacity() - map.len() >= 100); } #[test] fn test_shrink_to_fit_resize() { let mut map = LinkedHashMap::new(); map.shrink_to_fit(); for i in 0..100 { map.insert(i, i); } map.shrink_to_fit(); for _ in 0..50 { map.pop_front(); map.shrink_to_fit(); } assert_eq!(map.len(), 50); for i in 50..100 { assert_eq!(map.get(&i).unwrap(), &i); } } #[test] fn test_cursor_mut_current() { let mut map = LinkedHashMap::new(); map.insert(3, 3); if let linked_hash_map::Entry::Occupied(entry) = map.entry(3) { let mut cursor = entry.cursor_mut(); let value = cursor.current().unwrap(); assert_eq!(value, (&3, &mut 3)); *value.1 = 5; let value = cursor.current().unwrap(); assert_eq!(value, (&3, &mut 5)); } } #[test] fn test_cursor_mut_move_next() { let mut map = LinkedHashMap::new(); map.insert(3, 3); map.insert(4, 4); map.insert(5, 5); map.insert(6, 6); if let linked_hash_map::Entry::Occupied(entry) = map.entry(3) { let mut cursor = entry.cursor_mut(); let value = cursor.current(); assert!(&value.is_some()); assert_eq!(value.unwrap().1, &mut 3); cursor.move_next(); let value = cursor.current(); assert!(&value.is_some()); assert_eq!(value.unwrap().1, &mut 4); cursor.move_next(); let value = cursor.current(); assert!(&value.is_some()); assert_eq!(value.unwrap().1, &mut 5); cursor.move_next(); let value = cursor.current(); assert!(&value.is_some()); assert_eq!(value.unwrap().1, &mut 6); cursor.move_next(); let value = cursor.current(); assert!(value.is_none()); cursor.move_next(); let value = cursor.current(); assert!(value.is_some()); assert_eq!(value.unwrap().1, &mut 3); cursor.move_next(); let value = cursor.current(); assert!(&value.is_some()); assert_eq!(value.unwrap().1, &mut 4); } } #[test] fn test_cursor_mut_move_prev() { let mut map = LinkedHashMap::new(); map.insert(3, 3); if let linked_hash_map::Entry::Occupied(entry) = map.entry(3) { let mut cursor = entry.cursor_mut(); cursor.move_prev(); let value = cursor.current(); assert!(value.is_none()); cursor.move_prev(); let value = cursor.current(); assert!(&value.is_some()); assert_eq!(value.unwrap().1, &mut 3); } } #[test] fn test_cursor_mut_pick_next() { let mut map = LinkedHashMap::new(); map.insert(3, 3); map.insert(4, 4); if let linked_hash_map::Entry::Occupied(entry) = map.entry(3) { let mut cursor = entry.cursor_mut(); let next = cursor.peek_next(); assert!(&next.is_some()); assert_eq!(next.unwrap().1, &mut 4); cursor.move_next(); let next = cursor.peek_next(); assert!(&next.is_none()); cursor.move_next(); let next = cursor.peek_next(); assert!(&next.is_some()); let value = next.as_ref().unwrap().to_owned(); assert_eq!(*value.1, 3); *next.unwrap().1 = 5; let next = cursor.peek_next(); assert!(&next.is_some()); assert_eq!(next.unwrap().1, &mut 5); } } #[test] fn test_cursor_mut_pick_prev() { let mut map = LinkedHashMap::new(); map.insert(3, 3); map.insert(4, 4); if let linked_hash_map::Entry::Occupied(entry) = map.entry(3) { let mut cursor = entry.cursor_mut(); let next = cursor.peek_prev(); assert!(&next.is_none()); cursor.move_prev(); let next = cursor.peek_prev(); assert!(&next.is_some()); assert_eq!(next.unwrap(), (&4, &mut 4)); } } #[test] fn test_cursor_mut_insert_before() { let mut map = LinkedHashMap::new(); map.insert(3, 3); map.insert(4, 4); // Insert new element in the middle if let linked_hash_map::Entry::Occupied(entry) = map.entry(4) { entry.cursor_mut().insert_before(5, 5); assert!(map .iter() .map(|(k, v)| (*k, *v)) .eq([(3, 3), (5, 5), (4, 4)].iter().copied())); } // Insert new element at the very end of the list if let linked_hash_map::Entry::Occupied(entry) = map.entry(3) { let mut cursor = entry.cursor_mut(); cursor.move_prev(); cursor.insert_before(6, 6); assert!(map .iter() .map(|(k, v)| (*k, *v)) .eq([(3, 3), (5, 5), (4, 4), (6, 6)].iter().copied())); } // Relocate element and override value if let linked_hash_map::Entry::Occupied(entry) = map.entry(5) { entry.cursor_mut().insert_before(4, 42); assert!(map .iter() .map(|(k, v)| (*k, *v)) .eq([(3, 3), (4, 42), (5, 5), (6, 6)].iter().copied())); } } #[test] fn test_cursor_mut_insert_after() { let mut map = LinkedHashMap::new(); map.insert(3, 3); map.insert(4, 4); // Insert new element in the middle. if let linked_hash_map::Entry::Occupied(entry) = map.entry(3) { entry.cursor_mut().insert_after(5, 5); assert!(map .iter() .map(|(k, v)| (*k, *v)) .eq([(3, 3), (5, 5), (4, 4)].iter().copied())); } // Insert new element as the first one. if let linked_hash_map::Entry::Occupied(entry) = map.entry(4) { let mut cursor = entry.cursor_mut(); cursor.move_next(); cursor.insert_after(6, 6); assert!(map .iter() .map(|(k, v)| (*k, *v)) .eq([(6, 6), (3, 3), (5, 5), (4, 4)].iter().copied())); } } #[test] fn test_cursor_mut_insert_before_itself() { let mut map = LinkedHashMap::new(); map.insert(2, 2); map.insert(3, 3); map.insert(4, 4); // Insert a new value before its key. This is a corner case that needs to be // handled explicitly. if let linked_hash_map::Entry::Occupied(entry) = map.entry(3) { entry.cursor_mut().insert_before(3, 5); assert!(map .iter() .map(|(k, v)| (*k, *v)) .eq([(2, 2), (3, 5), (4, 4)].iter().copied())); } } #[test] fn test_cursor_front_mut() { let mut map: LinkedHashMap = LinkedHashMap::new(); // The `CursorMut`` in an empty LinkedHashMap will always return `None` as its // current element, regardless of any move in any direction. let mut cursor = map.cursor_front_mut(); assert!(cursor.current().is_none()); cursor.move_next(); assert!(cursor.current().is_none()); cursor.insert_after(1, 1); cursor.move_next(); assert!(cursor.current().is_some()); assert_eq!(cursor.current().unwrap().1, &mut 1); cursor.move_next(); assert!(cursor.current().is_none()); assert!(map .iter() .map(|(k, v)| (*k, *v)) .eq([(1, 1)].iter().copied())); map.insert(2, 2); map.insert(3, 3); let mut cursor = map.cursor_front_mut(); assert!(cursor.current().is_some()); assert_eq!(cursor.current().unwrap().1, &mut 1); } #[test] fn test_cursor_back_mut() { let mut map: LinkedHashMap = LinkedHashMap::new(); map.insert(1, 1); map.insert(2, 2); map.insert(3, 3); let mut cursor = map.cursor_back_mut(); assert!(cursor.current().is_some()); assert_eq!(cursor.current().unwrap().1, &mut 3); }