use std::collections::btree_map::Entry::{Occupied, Vacant}; use std::collections::BTreeMap; use std::convert::TryFrom; use std::fmt::Debug; use std::iter::FromIterator; use std::mem; use std::ops::Bound::{self, Excluded, Included, Unbounded}; use std::ops::RangeBounds; use std::panic::{catch_unwind, AssertUnwindSafe}; use std::rc::Rc; use std::sync::atomic::{AtomicUsize, Ordering}; use super::DeterministicRng; // Value of node::CAPACITY, thus capacity of a tree with a single level, // i.e. a tree who's root is a leaf node at height 0. const NODE_CAPACITY: usize = 11; // Minimum number of elements to insert in order to guarantee a tree with 2 levels, // i.e. a tree who's root is an internal node at height 1, with edges to leaf nodes. // It's not the minimum size: removing an element from such a tree does not always reduce height. const MIN_INSERTS_HEIGHT_1: usize = NODE_CAPACITY + 1; // Minimum number of elements to insert in order to guarantee a tree with 3 levels, // i.e. a tree who's root is an internal node at height 2, with edges to more internal nodes. // It's not the minimum size: removing an element from such a tree does not always reduce height. const MIN_INSERTS_HEIGHT_2: usize = NODE_CAPACITY + (NODE_CAPACITY + 1) * NODE_CAPACITY + 1; // Gather all references from a mutable iterator and make sure Miri notices if // using them is dangerous. fn test_all_refs<'a, T: 'a>(dummy: &mut T, iter: impl Iterator) { // Gather all those references. let mut refs: Vec<&mut T> = iter.collect(); // Use them all. Twice, to be sure we got all interleavings. for r in refs.iter_mut() { mem::swap(dummy, r); } for r in refs { mem::swap(dummy, r); } } #[test] fn test_basic_large() { let mut map = BTreeMap::new(); // Miri is too slow let size = if cfg!(miri) { MIN_INSERTS_HEIGHT_2 } else { 10000 }; assert_eq!(map.len(), 0); for i in 0..size { assert_eq!(map.insert(i, 10 * i), None); assert_eq!(map.len(), i + 1); } assert_eq!(map.first_key_value(), Some((&0, &0))); assert_eq!(map.last_key_value(), Some((&(size - 1), &(10 * (size - 1))))); assert_eq!(map.first_entry().unwrap().key(), &0); assert_eq!(map.last_entry().unwrap().key(), &(size - 1)); for i in 0..size { assert_eq!(map.get(&i).unwrap(), &(i * 10)); } for i in size..size * 2 { assert_eq!(map.get(&i), None); } for i in 0..size { assert_eq!(map.insert(i, 100 * i), Some(10 * i)); assert_eq!(map.len(), size); } for i in 0..size { assert_eq!(map.get(&i).unwrap(), &(i * 100)); } for i in 0..size / 2 { assert_eq!(map.remove(&(i * 2)), Some(i * 200)); assert_eq!(map.len(), size - i - 1); } for i in 0..size / 2 { assert_eq!(map.get(&(2 * i)), None); assert_eq!(map.get(&(2 * i + 1)).unwrap(), &(i * 200 + 100)); } for i in 0..size / 2 { assert_eq!(map.remove(&(2 * i)), None); assert_eq!(map.remove(&(2 * i + 1)), Some(i * 200 + 100)); assert_eq!(map.len(), size / 2 - i - 1); } } #[test] fn test_basic_small() { let mut map = BTreeMap::new(); // Empty, root is absent (None): assert_eq!(map.remove(&1), None); assert_eq!(map.len(), 0); assert_eq!(map.get(&1), None); assert_eq!(map.get_mut(&1), None); assert_eq!(map.first_key_value(), None); assert_eq!(map.last_key_value(), None); assert_eq!(map.keys().count(), 0); assert_eq!(map.values().count(), 0); assert_eq!(map.range(..).next(), None); assert_eq!(map.range(..1).next(), None); assert_eq!(map.range(1..).next(), None); assert_eq!(map.range(1..=1).next(), None); assert_eq!(map.range(1..2).next(), None); assert_eq!(map.insert(1, 1), None); // 1 key-value pair: assert_eq!(map.len(), 1); assert_eq!(map.get(&1), Some(&1)); assert_eq!(map.get_mut(&1), Some(&mut 1)); assert_eq!(map.first_key_value(), Some((&1, &1))); assert_eq!(map.last_key_value(), Some((&1, &1))); assert_eq!(map.keys().collect::>(), vec![&1]); assert_eq!(map.values().collect::>(), vec![&1]); assert_eq!(map.insert(1, 2), Some(1)); assert_eq!(map.len(), 1); assert_eq!(map.get(&1), Some(&2)); assert_eq!(map.get_mut(&1), Some(&mut 2)); assert_eq!(map.first_key_value(), Some((&1, &2))); assert_eq!(map.last_key_value(), Some((&1, &2))); assert_eq!(map.keys().collect::>(), vec![&1]); assert_eq!(map.values().collect::>(), vec![&2]); assert_eq!(map.insert(2, 4), None); // 2 key-value pairs: assert_eq!(map.len(), 2); assert_eq!(map.get(&2), Some(&4)); assert_eq!(map.get_mut(&2), Some(&mut 4)); assert_eq!(map.first_key_value(), Some((&1, &2))); assert_eq!(map.last_key_value(), Some((&2, &4))); assert_eq!(map.keys().collect::>(), vec![&1, &2]); assert_eq!(map.values().collect::>(), vec![&2, &4]); assert_eq!(map.remove(&1), Some(2)); // 1 key-value pair: assert_eq!(map.len(), 1); assert_eq!(map.get(&1), None); assert_eq!(map.get_mut(&1), None); assert_eq!(map.get(&2), Some(&4)); assert_eq!(map.get_mut(&2), Some(&mut 4)); assert_eq!(map.first_key_value(), Some((&2, &4))); assert_eq!(map.last_key_value(), Some((&2, &4))); assert_eq!(map.keys().collect::>(), vec![&2]); assert_eq!(map.values().collect::>(), vec![&4]); assert_eq!(map.remove(&2), Some(4)); // Empty but root is owned (Some(...)): assert_eq!(map.len(), 0); assert_eq!(map.get(&1), None); assert_eq!(map.get_mut(&1), None); assert_eq!(map.first_key_value(), None); assert_eq!(map.last_key_value(), None); assert_eq!(map.keys().count(), 0); assert_eq!(map.values().count(), 0); assert_eq!(map.range(..).next(), None); assert_eq!(map.range(..1).next(), None); assert_eq!(map.range(1..).next(), None); assert_eq!(map.range(1..=1).next(), None); assert_eq!(map.range(1..2).next(), None); assert_eq!(map.remove(&1), None); } #[test] fn test_iter() { // Miri is too slow let size = if cfg!(miri) { 200 } else { 10000 }; let mut map: BTreeMap<_, _> = (0..size).map(|i| (i, i)).collect(); fn test(size: usize, mut iter: T) where T: Iterator, { for i in 0..size { assert_eq!(iter.size_hint(), (size - i, Some(size - i))); assert_eq!(iter.next().unwrap(), (i, i)); } assert_eq!(iter.size_hint(), (0, Some(0))); assert_eq!(iter.next(), None); } test(size, map.iter().map(|(&k, &v)| (k, v))); test(size, map.iter_mut().map(|(&k, &mut v)| (k, v))); test(size, map.into_iter()); } #[test] fn test_iter_rev() { // Miri is too slow let size = if cfg!(miri) { 200 } else { 10000 }; let mut map: BTreeMap<_, _> = (0..size).map(|i| (i, i)).collect(); fn test(size: usize, mut iter: T) where T: Iterator, { for i in 0..size { assert_eq!(iter.size_hint(), (size - i, Some(size - i))); assert_eq!(iter.next().unwrap(), (size - i - 1, size - i - 1)); } assert_eq!(iter.size_hint(), (0, Some(0))); assert_eq!(iter.next(), None); } test(size, map.iter().rev().map(|(&k, &v)| (k, v))); test(size, map.iter_mut().rev().map(|(&k, &mut v)| (k, v))); test(size, map.into_iter().rev()); } /// Specifically tests iter_mut's ability to mutate the value of pairs in-line fn do_test_iter_mut_mutation(size: usize) where T: Copy + Debug + Ord + TryFrom, >::Error: std::fmt::Debug, { let zero = T::try_from(0).unwrap(); let mut map: BTreeMap = (0..size).map(|i| (T::try_from(i).unwrap(), zero)).collect(); // Forward and backward iteration sees enough pairs (also tested elsewhere) assert_eq!(map.iter_mut().count(), size); assert_eq!(map.iter_mut().rev().count(), size); // Iterate forwards, trying to mutate to unique values for (i, (k, v)) in map.iter_mut().enumerate() { assert_eq!(*k, T::try_from(i).unwrap()); assert_eq!(*v, zero); *v = T::try_from(i + 1).unwrap(); } // Iterate backwards, checking that mutations succeeded and trying to mutate again for (i, (k, v)) in map.iter_mut().rev().enumerate() { assert_eq!(*k, T::try_from(size - i - 1).unwrap()); assert_eq!(*v, T::try_from(size - i).unwrap()); *v = T::try_from(2 * size - i).unwrap(); } // Check that backward mutations succeeded for (i, (k, v)) in map.iter_mut().enumerate() { assert_eq!(*k, T::try_from(i).unwrap()); assert_eq!(*v, T::try_from(size + i + 1).unwrap()); } } #[derive(Clone, Copy, Debug, Eq, PartialEq, PartialOrd, Ord)] #[repr(align(32))] struct Align32(usize); impl TryFrom for Align32 { type Error = (); fn try_from(s: usize) -> Result { Ok(Align32(s)) } } #[test] fn test_iter_mut_mutation() { // Check many alignments and trees with roots at various heights. do_test_iter_mut_mutation::(0); do_test_iter_mut_mutation::(1); do_test_iter_mut_mutation::(MIN_INSERTS_HEIGHT_1); do_test_iter_mut_mutation::(127); // not enough unique values to test MIN_INSERTS_HEIGHT_2 do_test_iter_mut_mutation::(1); do_test_iter_mut_mutation::(MIN_INSERTS_HEIGHT_1); do_test_iter_mut_mutation::(MIN_INSERTS_HEIGHT_2); do_test_iter_mut_mutation::(1); do_test_iter_mut_mutation::(MIN_INSERTS_HEIGHT_1); do_test_iter_mut_mutation::(MIN_INSERTS_HEIGHT_2); do_test_iter_mut_mutation::(1); do_test_iter_mut_mutation::(MIN_INSERTS_HEIGHT_1); do_test_iter_mut_mutation::(MIN_INSERTS_HEIGHT_2); do_test_iter_mut_mutation::(1); do_test_iter_mut_mutation::(MIN_INSERTS_HEIGHT_1); do_test_iter_mut_mutation::(MIN_INSERTS_HEIGHT_2); do_test_iter_mut_mutation::(1); do_test_iter_mut_mutation::(MIN_INSERTS_HEIGHT_1); do_test_iter_mut_mutation::(MIN_INSERTS_HEIGHT_2); } #[test] #[cfg_attr(miri, ignore)] // FIXME: fails in Miri fn test_values_mut() { let mut a: BTreeMap<_, _> = (0..MIN_INSERTS_HEIGHT_2).map(|i| (i, i)).collect(); test_all_refs(&mut 13, a.values_mut()); } #[test] fn test_values_mut_mutation() { let mut a = BTreeMap::new(); a.insert(1, String::from("hello")); a.insert(2, String::from("goodbye")); for value in a.values_mut() { value.push_str("!"); } let values: Vec = a.values().cloned().collect(); assert_eq!(values, [String::from("hello!"), String::from("goodbye!")]); } #[test] #[cfg_attr(miri, ignore)] // FIXME: fails in Miri fn test_iter_entering_root_twice() { let mut map: BTreeMap<_, _> = (0..2).map(|i| (i, i)).collect(); let mut it = map.iter_mut(); let front = it.next().unwrap(); let back = it.next_back().unwrap(); assert_eq!(front, (&0, &mut 0)); assert_eq!(back, (&1, &mut 1)); *front.1 = 24; *back.1 = 42; assert_eq!(front, (&0, &mut 24)); assert_eq!(back, (&1, &mut 42)); } #[test] #[cfg_attr(miri, ignore)] // FIXME: fails in Miri fn test_iter_descending_to_same_node_twice() { let mut map: BTreeMap<_, _> = (0..MIN_INSERTS_HEIGHT_1).map(|i| (i, i)).collect(); let mut it = map.iter_mut(); // Descend into first child. let front = it.next().unwrap(); // Descend into first child again, after running through second child. while it.next_back().is_some() {} // Check immutable access. assert_eq!(front, (&0, &mut 0)); // Perform mutable access. *front.1 = 42; } #[test] fn test_iter_mixed() { // Miri is too slow let size = if cfg!(miri) { 200 } else { 10000 }; let mut map: BTreeMap<_, _> = (0..size).map(|i| (i, i)).collect(); fn test(size: usize, mut iter: T) where T: Iterator + DoubleEndedIterator, { for i in 0..size / 4 { assert_eq!(iter.size_hint(), (size - i * 2, Some(size - i * 2))); assert_eq!(iter.next().unwrap(), (i, i)); assert_eq!(iter.next_back().unwrap(), (size - i - 1, size - i - 1)); } for i in size / 4..size * 3 / 4 { assert_eq!(iter.size_hint(), (size * 3 / 4 - i, Some(size * 3 / 4 - i))); assert_eq!(iter.next().unwrap(), (i, i)); } assert_eq!(iter.size_hint(), (0, Some(0))); assert_eq!(iter.next(), None); } test(size, map.iter().map(|(&k, &v)| (k, v))); test(size, map.iter_mut().map(|(&k, &mut v)| (k, v))); test(size, map.into_iter()); } #[test] #[cfg_attr(miri, ignore)] // FIXME: fails in Miri fn test_iter_min_max() { let mut a = BTreeMap::new(); assert_eq!(a.iter().min(), None); assert_eq!(a.iter().max(), None); assert_eq!(a.iter_mut().min(), None); assert_eq!(a.iter_mut().max(), None); assert_eq!(a.range(..).min(), None); assert_eq!(a.range(..).max(), None); assert_eq!(a.range_mut(..).min(), None); assert_eq!(a.range_mut(..).max(), None); assert_eq!(a.keys().min(), None); assert_eq!(a.keys().max(), None); assert_eq!(a.values().min(), None); assert_eq!(a.values().max(), None); assert_eq!(a.values_mut().min(), None); assert_eq!(a.values_mut().max(), None); a.insert(1, 42); a.insert(2, 24); assert_eq!(a.iter().min(), Some((&1, &42))); assert_eq!(a.iter().max(), Some((&2, &24))); assert_eq!(a.iter_mut().min(), Some((&1, &mut 42))); assert_eq!(a.iter_mut().max(), Some((&2, &mut 24))); assert_eq!(a.range(..).min(), Some((&1, &42))); assert_eq!(a.range(..).max(), Some((&2, &24))); assert_eq!(a.range_mut(..).min(), Some((&1, &mut 42))); assert_eq!(a.range_mut(..).max(), Some((&2, &mut 24))); assert_eq!(a.keys().min(), Some(&1)); assert_eq!(a.keys().max(), Some(&2)); assert_eq!(a.values().min(), Some(&24)); assert_eq!(a.values().max(), Some(&42)); assert_eq!(a.values_mut().min(), Some(&mut 24)); assert_eq!(a.values_mut().max(), Some(&mut 42)); } fn range_keys(map: &BTreeMap, range: impl RangeBounds) -> Vec { map.range(range) .map(|(&k, &v)| { assert_eq!(k, v); k }) .collect() } #[test] fn test_range_small() { let size = 4; let map: BTreeMap<_, _> = (1..=size).map(|i| (i, i)).collect(); let all: Vec<_> = (1..=size).collect(); let (first, last) = (vec![all[0]], vec![all[size as usize - 1]]); assert_eq!(range_keys(&map, (Excluded(0), Excluded(size + 1))), all); assert_eq!(range_keys(&map, (Excluded(0), Included(size + 1))), all); assert_eq!(range_keys(&map, (Excluded(0), Included(size))), all); assert_eq!(range_keys(&map, (Excluded(0), Unbounded)), all); assert_eq!(range_keys(&map, (Included(0), Excluded(size + 1))), all); assert_eq!(range_keys(&map, (Included(0), Included(size + 1))), all); assert_eq!(range_keys(&map, (Included(0), Included(size))), all); assert_eq!(range_keys(&map, (Included(0), Unbounded)), all); assert_eq!(range_keys(&map, (Included(1), Excluded(size + 1))), all); assert_eq!(range_keys(&map, (Included(1), Included(size + 1))), all); assert_eq!(range_keys(&map, (Included(1), Included(size))), all); assert_eq!(range_keys(&map, (Included(1), Unbounded)), all); assert_eq!(range_keys(&map, (Unbounded, Excluded(size + 1))), all); assert_eq!(range_keys(&map, (Unbounded, Included(size + 1))), all); assert_eq!(range_keys(&map, (Unbounded, Included(size))), all); assert_eq!(range_keys(&map, ..), all); assert_eq!(range_keys(&map, (Excluded(0), Excluded(1))), vec![]); assert_eq!(range_keys(&map, (Excluded(0), Included(0))), vec![]); assert_eq!(range_keys(&map, (Included(0), Included(0))), vec![]); assert_eq!(range_keys(&map, (Included(0), Excluded(1))), vec![]); assert_eq!(range_keys(&map, (Unbounded, Excluded(1))), vec![]); assert_eq!(range_keys(&map, (Unbounded, Included(0))), vec![]); assert_eq!(range_keys(&map, (Excluded(0), Excluded(2))), first); assert_eq!(range_keys(&map, (Excluded(0), Included(1))), first); assert_eq!(range_keys(&map, (Included(0), Excluded(2))), first); assert_eq!(range_keys(&map, (Included(0), Included(1))), first); assert_eq!(range_keys(&map, (Included(1), Excluded(2))), first); assert_eq!(range_keys(&map, (Included(1), Included(1))), first); assert_eq!(range_keys(&map, (Unbounded, Excluded(2))), first); assert_eq!(range_keys(&map, (Unbounded, Included(1))), first); assert_eq!(range_keys(&map, (Excluded(size - 1), Excluded(size + 1))), last); assert_eq!(range_keys(&map, (Excluded(size - 1), Included(size + 1))), last); assert_eq!(range_keys(&map, (Excluded(size - 1), Included(size))), last); assert_eq!(range_keys(&map, (Excluded(size - 1), Unbounded)), last); assert_eq!(range_keys(&map, (Included(size), Excluded(size + 1))), last); assert_eq!(range_keys(&map, (Included(size), Included(size + 1))), last); assert_eq!(range_keys(&map, (Included(size), Included(size))), last); assert_eq!(range_keys(&map, (Included(size), Unbounded)), last); assert_eq!(range_keys(&map, (Excluded(size), Excluded(size + 1))), vec![]); assert_eq!(range_keys(&map, (Excluded(size), Included(size))), vec![]); assert_eq!(range_keys(&map, (Excluded(size), Unbounded)), vec![]); assert_eq!(range_keys(&map, (Included(size + 1), Excluded(size + 1))), vec![]); assert_eq!(range_keys(&map, (Included(size + 1), Included(size + 1))), vec![]); assert_eq!(range_keys(&map, (Included(size + 1), Unbounded)), vec![]); assert_eq!(range_keys(&map, ..3), vec![1, 2]); assert_eq!(range_keys(&map, 3..), vec![3, 4]); assert_eq!(range_keys(&map, 2..=3), vec![2, 3]); } #[test] fn test_range_height_1() { // Tests tree with a root and 2 leaves. Depending on details we don't want or need // to rely upon, the single key at the root will be 6 or 7. let map: BTreeMap<_, _> = (1..=MIN_INSERTS_HEIGHT_1 as i32).map(|i| (i, i)).collect(); for &root in &[6, 7] { assert_eq!(range_keys(&map, (Excluded(root), Excluded(root + 1))), vec![]); assert_eq!(range_keys(&map, (Excluded(root), Included(root + 1))), vec![root + 1]); assert_eq!(range_keys(&map, (Included(root), Excluded(root + 1))), vec![root]); assert_eq!(range_keys(&map, (Included(root), Included(root + 1))), vec![root, root + 1]); assert_eq!(range_keys(&map, (Excluded(root - 1), Excluded(root))), vec![]); assert_eq!(range_keys(&map, (Included(root - 1), Excluded(root))), vec![root - 1]); assert_eq!(range_keys(&map, (Excluded(root - 1), Included(root))), vec![root]); assert_eq!(range_keys(&map, (Included(root - 1), Included(root))), vec![root - 1, root]); } } #[test] fn test_range_large() { let size = 200; let map: BTreeMap<_, _> = (1..=size).map(|i| (i, i)).collect(); let all: Vec<_> = (1..=size).collect(); let (first, last) = (vec![all[0]], vec![all[size as usize - 1]]); assert_eq!(range_keys(&map, (Excluded(0), Excluded(size + 1))), all); assert_eq!(range_keys(&map, (Excluded(0), Included(size + 1))), all); assert_eq!(range_keys(&map, (Excluded(0), Included(size))), all); assert_eq!(range_keys(&map, (Excluded(0), Unbounded)), all); assert_eq!(range_keys(&map, (Included(0), Excluded(size + 1))), all); assert_eq!(range_keys(&map, (Included(0), Included(size + 1))), all); assert_eq!(range_keys(&map, (Included(0), Included(size))), all); assert_eq!(range_keys(&map, (Included(0), Unbounded)), all); assert_eq!(range_keys(&map, (Included(1), Excluded(size + 1))), all); assert_eq!(range_keys(&map, (Included(1), Included(size + 1))), all); assert_eq!(range_keys(&map, (Included(1), Included(size))), all); assert_eq!(range_keys(&map, (Included(1), Unbounded)), all); assert_eq!(range_keys(&map, (Unbounded, Excluded(size + 1))), all); assert_eq!(range_keys(&map, (Unbounded, Included(size + 1))), all); assert_eq!(range_keys(&map, (Unbounded, Included(size))), all); assert_eq!(range_keys(&map, ..), all); assert_eq!(range_keys(&map, (Excluded(0), Excluded(1))), vec![]); assert_eq!(range_keys(&map, (Excluded(0), Included(0))), vec![]); assert_eq!(range_keys(&map, (Included(0), Included(0))), vec![]); assert_eq!(range_keys(&map, (Included(0), Excluded(1))), vec![]); assert_eq!(range_keys(&map, (Unbounded, Excluded(1))), vec![]); assert_eq!(range_keys(&map, (Unbounded, Included(0))), vec![]); assert_eq!(range_keys(&map, (Excluded(0), Excluded(2))), first); assert_eq!(range_keys(&map, (Excluded(0), Included(1))), first); assert_eq!(range_keys(&map, (Included(0), Excluded(2))), first); assert_eq!(range_keys(&map, (Included(0), Included(1))), first); assert_eq!(range_keys(&map, (Included(1), Excluded(2))), first); assert_eq!(range_keys(&map, (Included(1), Included(1))), first); assert_eq!(range_keys(&map, (Unbounded, Excluded(2))), first); assert_eq!(range_keys(&map, (Unbounded, Included(1))), first); assert_eq!(range_keys(&map, (Excluded(size - 1), Excluded(size + 1))), last); assert_eq!(range_keys(&map, (Excluded(size - 1), Included(size + 1))), last); assert_eq!(range_keys(&map, (Excluded(size - 1), Included(size))), last); assert_eq!(range_keys(&map, (Excluded(size - 1), Unbounded)), last); assert_eq!(range_keys(&map, (Included(size), Excluded(size + 1))), last); assert_eq!(range_keys(&map, (Included(size), Included(size + 1))), last); assert_eq!(range_keys(&map, (Included(size), Included(size))), last); assert_eq!(range_keys(&map, (Included(size), Unbounded)), last); assert_eq!(range_keys(&map, (Excluded(size), Excluded(size + 1))), vec![]); assert_eq!(range_keys(&map, (Excluded(size), Included(size))), vec![]); assert_eq!(range_keys(&map, (Excluded(size), Unbounded)), vec![]); assert_eq!(range_keys(&map, (Included(size + 1), Excluded(size + 1))), vec![]); assert_eq!(range_keys(&map, (Included(size + 1), Included(size + 1))), vec![]); assert_eq!(range_keys(&map, (Included(size + 1), Unbounded)), vec![]); fn check<'a, L, R>(lhs: L, rhs: R) where L: IntoIterator, R: IntoIterator, { let lhs: Vec<_> = lhs.into_iter().collect(); let rhs: Vec<_> = rhs.into_iter().collect(); assert_eq!(lhs, rhs); } check(map.range(..=100), map.range(..101)); check(map.range(5..=8), vec![(&5, &5), (&6, &6), (&7, &7), (&8, &8)]); check(map.range(-1..=2), vec![(&1, &1), (&2, &2)]); } #[test] fn test_range_inclusive_max_value() { let max = usize::MAX; let map: BTreeMap<_, _> = vec![(max, 0)].into_iter().collect(); assert_eq!(map.range(max..=max).collect::>(), &[(&max, &0)]); } #[test] fn test_range_equal_empty_cases() { let map: BTreeMap<_, _> = (0..5).map(|i| (i, i)).collect(); assert_eq!(map.range((Included(2), Excluded(2))).next(), None); assert_eq!(map.range((Excluded(2), Included(2))).next(), None); } #[test] #[should_panic] fn test_range_equal_excluded() { let map: BTreeMap<_, _> = (0..5).map(|i| (i, i)).collect(); map.range((Excluded(2), Excluded(2))); } #[test] #[should_panic] fn test_range_backwards_1() { let map: BTreeMap<_, _> = (0..5).map(|i| (i, i)).collect(); map.range((Included(3), Included(2))); } #[test] #[should_panic] fn test_range_backwards_2() { let map: BTreeMap<_, _> = (0..5).map(|i| (i, i)).collect(); map.range((Included(3), Excluded(2))); } #[test] #[should_panic] fn test_range_backwards_3() { let map: BTreeMap<_, _> = (0..5).map(|i| (i, i)).collect(); map.range((Excluded(3), Included(2))); } #[test] #[should_panic] fn test_range_backwards_4() { let map: BTreeMap<_, _> = (0..5).map(|i| (i, i)).collect(); map.range((Excluded(3), Excluded(2))); } #[test] fn test_range_1000() { // Miri is too slow let size = if cfg!(miri) { MIN_INSERTS_HEIGHT_2 as u32 } else { 1000 }; let map: BTreeMap<_, _> = (0..size).map(|i| (i, i)).collect(); fn test(map: &BTreeMap, size: u32, min: Bound<&u32>, max: Bound<&u32>) { let mut kvs = map.range((min, max)).map(|(&k, &v)| (k, v)); let mut pairs = (0..size).map(|i| (i, i)); for (kv, pair) in kvs.by_ref().zip(pairs.by_ref()) { assert_eq!(kv, pair); } assert_eq!(kvs.next(), None); assert_eq!(pairs.next(), None); } test(&map, size, Included(&0), Excluded(&size)); test(&map, size, Unbounded, Excluded(&size)); test(&map, size, Included(&0), Included(&(size - 1))); test(&map, size, Unbounded, Included(&(size - 1))); test(&map, size, Included(&0), Unbounded); test(&map, size, Unbounded, Unbounded); } #[test] fn test_range_borrowed_key() { let mut map = BTreeMap::new(); map.insert("aardvark".to_string(), 1); map.insert("baboon".to_string(), 2); map.insert("coyote".to_string(), 3); map.insert("dingo".to_string(), 4); // NOTE: would like to use simply "b".."d" here... let mut iter = map.range::((Included("b"), Excluded("d"))); assert_eq!(iter.next(), Some((&"baboon".to_string(), &2))); assert_eq!(iter.next(), Some((&"coyote".to_string(), &3))); assert_eq!(iter.next(), None); } #[test] fn test_range() { let size = 200; // Miri is too slow let step = if cfg!(miri) { 66 } else { 1 }; let map: BTreeMap<_, _> = (0..size).map(|i| (i, i)).collect(); for i in (0..size).step_by(step) { for j in (i..size).step_by(step) { let mut kvs = map.range((Included(&i), Included(&j))).map(|(&k, &v)| (k, v)); let mut pairs = (i..=j).map(|i| (i, i)); for (kv, pair) in kvs.by_ref().zip(pairs.by_ref()) { assert_eq!(kv, pair); } assert_eq!(kvs.next(), None); assert_eq!(pairs.next(), None); } } } #[test] fn test_range_mut() { let size = 200; // Miri is too slow let step = if cfg!(miri) { 66 } else { 1 }; let mut map: BTreeMap<_, _> = (0..size).map(|i| (i, i)).collect(); for i in (0..size).step_by(step) { for j in (i..size).step_by(step) { let mut kvs = map.range_mut((Included(&i), Included(&j))).map(|(&k, &mut v)| (k, v)); let mut pairs = (i..=j).map(|i| (i, i)); for (kv, pair) in kvs.by_ref().zip(pairs.by_ref()) { assert_eq!(kv, pair); } assert_eq!(kvs.next(), None); assert_eq!(pairs.next(), None); } } } mod test_drain_filter { use super::*; #[test] fn empty() { let mut map: BTreeMap = BTreeMap::new(); map.drain_filter(|_, _| unreachable!("there's nothing to decide on")); assert!(map.is_empty()); } #[test] fn consuming_nothing() { let pairs = (0..3).map(|i| (i, i)); let mut map: BTreeMap<_, _> = pairs.collect(); assert!(map.drain_filter(|_, _| false).eq(std::iter::empty())); } #[test] fn consuming_all() { let pairs = (0..3).map(|i| (i, i)); let mut map: BTreeMap<_, _> = pairs.clone().collect(); assert!(map.drain_filter(|_, _| true).eq(pairs)); } #[test] fn mutating_and_keeping() { let pairs = (0..3).map(|i| (i, i)); let mut map: BTreeMap<_, _> = pairs.collect(); assert!( map.drain_filter(|_, v| { *v += 6; false }) .eq(std::iter::empty()) ); assert!(map.keys().copied().eq(0..3)); assert!(map.values().copied().eq(6..9)); } #[test] fn mutating_and_removing() { let pairs = (0..3).map(|i| (i, i)); let mut map: BTreeMap<_, _> = pairs.collect(); assert!( map.drain_filter(|_, v| { *v += 6; true }) .eq((0..3).map(|i| (i, i + 6))) ); assert!(map.is_empty()); } #[test] fn underfull_keeping_all() { let pairs = (0..3).map(|i| (i, i)); let mut map: BTreeMap<_, _> = pairs.collect(); map.drain_filter(|_, _| false); assert!(map.keys().copied().eq(0..3)); } #[test] fn underfull_removing_one() { let pairs = (0..3).map(|i| (i, i)); for doomed in 0..3 { let mut map: BTreeMap<_, _> = pairs.clone().collect(); map.drain_filter(|i, _| *i == doomed); assert_eq!(map.len(), 2); } } #[test] fn underfull_keeping_one() { let pairs = (0..3).map(|i| (i, i)); for sacred in 0..3 { let mut map: BTreeMap<_, _> = pairs.clone().collect(); map.drain_filter(|i, _| *i != sacred); assert!(map.keys().copied().eq(sacred..=sacred)); } } #[test] fn underfull_removing_all() { let pairs = (0..3).map(|i| (i, i)); let mut map: BTreeMap<_, _> = pairs.collect(); map.drain_filter(|_, _| true); assert!(map.is_empty()); } #[test] fn height_0_keeping_all() { let pairs = (0..NODE_CAPACITY).map(|i| (i, i)); let mut map: BTreeMap<_, _> = pairs.collect(); map.drain_filter(|_, _| false); assert!(map.keys().copied().eq(0..NODE_CAPACITY)); } #[test] fn height_0_removing_one() { let pairs = (0..NODE_CAPACITY).map(|i| (i, i)); for doomed in 0..NODE_CAPACITY { let mut map: BTreeMap<_, _> = pairs.clone().collect(); map.drain_filter(|i, _| *i == doomed); assert_eq!(map.len(), NODE_CAPACITY - 1); } } #[test] fn height_0_keeping_one() { let pairs = (0..NODE_CAPACITY).map(|i| (i, i)); for sacred in 0..NODE_CAPACITY { let mut map: BTreeMap<_, _> = pairs.clone().collect(); map.drain_filter(|i, _| *i != sacred); assert!(map.keys().copied().eq(sacred..=sacred)); } } #[test] fn height_0_removing_all() { let pairs = (0..NODE_CAPACITY).map(|i| (i, i)); let mut map: BTreeMap<_, _> = pairs.collect(); map.drain_filter(|_, _| true); assert!(map.is_empty()); } #[test] fn height_0_keeping_half() { let mut map: BTreeMap<_, _> = (0..16).map(|i| (i, i)).collect(); assert_eq!(map.drain_filter(|i, _| *i % 2 == 0).count(), 8); assert_eq!(map.len(), 8); } #[test] fn height_1_removing_all() { let pairs = (0..MIN_INSERTS_HEIGHT_1).map(|i| (i, i)); let mut map: BTreeMap<_, _> = pairs.collect(); map.drain_filter(|_, _| true); assert!(map.is_empty()); } #[test] fn height_1_removing_one() { let pairs = (0..MIN_INSERTS_HEIGHT_1).map(|i| (i, i)); for doomed in 0..MIN_INSERTS_HEIGHT_1 { let mut map: BTreeMap<_, _> = pairs.clone().collect(); map.drain_filter(|i, _| *i == doomed); assert_eq!(map.len(), MIN_INSERTS_HEIGHT_1 - 1); } } #[test] fn height_1_keeping_one() { let pairs = (0..MIN_INSERTS_HEIGHT_1).map(|i| (i, i)); for sacred in 0..MIN_INSERTS_HEIGHT_1 { let mut map: BTreeMap<_, _> = pairs.clone().collect(); map.drain_filter(|i, _| *i != sacred); assert!(map.keys().copied().eq(sacred..=sacred)); } } #[cfg(not(miri))] // Miri is too slow #[test] fn height_2_removing_one() { let pairs = (0..MIN_INSERTS_HEIGHT_2).map(|i| (i, i)); for doomed in (0..MIN_INSERTS_HEIGHT_2).step_by(12) { let mut map: BTreeMap<_, _> = pairs.clone().collect(); map.drain_filter(|i, _| *i == doomed); assert_eq!(map.len(), MIN_INSERTS_HEIGHT_2 - 1); } } #[cfg(not(miri))] // Miri is too slow #[test] fn height_2_keeping_one() { let pairs = (0..MIN_INSERTS_HEIGHT_2).map(|i| (i, i)); for sacred in (0..MIN_INSERTS_HEIGHT_2).step_by(12) { let mut map: BTreeMap<_, _> = pairs.clone().collect(); map.drain_filter(|i, _| *i != sacred); assert!(map.keys().copied().eq(sacred..=sacred)); } } #[test] fn height_2_removing_all() { let pairs = (0..MIN_INSERTS_HEIGHT_2).map(|i| (i, i)); let mut map: BTreeMap<_, _> = pairs.collect(); map.drain_filter(|_, _| true); assert!(map.is_empty()); } #[test] fn drop_panic_leak() { static PREDS: AtomicUsize = AtomicUsize::new(0); static DROPS: AtomicUsize = AtomicUsize::new(0); struct D; impl Drop for D { fn drop(&mut self) { if DROPS.fetch_add(1, Ordering::SeqCst) == 1 { panic!("panic in `drop`"); } } } // Keys are multiples of 4, so that each key is counted by a hexadecimal digit. let mut map = (0..3).map(|i| (i * 4, D)).collect::>(); catch_unwind(move || { drop(map.drain_filter(|i, _| { PREDS.fetch_add(1usize << i, Ordering::SeqCst); true })) }) .unwrap_err(); assert_eq!(PREDS.load(Ordering::SeqCst), 0x011); assert_eq!(DROPS.load(Ordering::SeqCst), 3); } #[test] fn pred_panic_leak() { static PREDS: AtomicUsize = AtomicUsize::new(0); static DROPS: AtomicUsize = AtomicUsize::new(0); struct D; impl Drop for D { fn drop(&mut self) { DROPS.fetch_add(1, Ordering::SeqCst); } } // Keys are multiples of 4, so that each key is counted by a hexadecimal digit. let mut map = (0..3).map(|i| (i * 4, D)).collect::>(); catch_unwind(AssertUnwindSafe(|| { drop(map.drain_filter(|i, _| { PREDS.fetch_add(1usize << i, Ordering::SeqCst); match i { 0 => true, _ => panic!(), } })) })) .unwrap_err(); assert_eq!(PREDS.load(Ordering::SeqCst), 0x011); assert_eq!(DROPS.load(Ordering::SeqCst), 1); assert_eq!(map.len(), 2); assert_eq!(map.first_entry().unwrap().key(), &4); assert_eq!(map.last_entry().unwrap().key(), &8); } // Same as above, but attempt to use the iterator again after the panic in the predicate #[test] fn pred_panic_reuse() { static PREDS: AtomicUsize = AtomicUsize::new(0); static DROPS: AtomicUsize = AtomicUsize::new(0); struct D; impl Drop for D { fn drop(&mut self) { DROPS.fetch_add(1, Ordering::SeqCst); } } // Keys are multiples of 4, so that each key is counted by a hexadecimal digit. let mut map = (0..3).map(|i| (i * 4, D)).collect::>(); { let mut it = map.drain_filter(|i, _| { PREDS.fetch_add(1usize << i, Ordering::SeqCst); match i { 0 => true, _ => panic!(), } }); catch_unwind(AssertUnwindSafe(|| while it.next().is_some() {})).unwrap_err(); // Iterator behaviour after a panic is explicitly unspecified, // so this is just the current implementation: let result = catch_unwind(AssertUnwindSafe(|| it.next())); assert!(matches!(result, Ok(None))); } assert_eq!(PREDS.load(Ordering::SeqCst), 0x011); assert_eq!(DROPS.load(Ordering::SeqCst), 1); assert_eq!(map.len(), 2); assert_eq!(map.first_entry().unwrap().key(), &4); assert_eq!(map.last_entry().unwrap().key(), &8); } } #[test] fn test_borrow() { // make sure these compile -- using the Borrow trait { let mut map = BTreeMap::new(); map.insert("0".to_string(), 1); assert_eq!(map["0"], 1); } { let mut map = BTreeMap::new(); map.insert(Box::new(0), 1); assert_eq!(map[&0], 1); } { let mut map = BTreeMap::new(); map.insert(Box::new([0, 1]) as Box<[i32]>, 1); assert_eq!(map[&[0, 1][..]], 1); } { let mut map = BTreeMap::new(); map.insert(Rc::new(0), 1); assert_eq!(map[&0], 1); } } #[test] fn test_entry() { let xs = [(1, 10), (2, 20), (3, 30), (4, 40), (5, 50), (6, 60)]; let mut map: BTreeMap<_, _> = xs.iter().cloned().collect(); // Existing key (insert) match map.entry(1) { Vacant(_) => unreachable!(), Occupied(mut view) => { assert_eq!(view.get(), &10); assert_eq!(view.insert(100), 10); } } assert_eq!(map.get(&1).unwrap(), &100); assert_eq!(map.len(), 6); // Existing key (update) match map.entry(2) { Vacant(_) => unreachable!(), Occupied(mut view) => { let v = view.get_mut(); *v *= 10; } } assert_eq!(map.get(&2).unwrap(), &200); assert_eq!(map.len(), 6); // Existing key (take) match map.entry(3) { Vacant(_) => unreachable!(), Occupied(view) => { assert_eq!(view.remove(), 30); } } assert_eq!(map.get(&3), None); assert_eq!(map.len(), 5); // Inexistent key (insert) match map.entry(10) { Occupied(_) => unreachable!(), Vacant(view) => { assert_eq!(*view.insert(1000), 1000); } } assert_eq!(map.get(&10).unwrap(), &1000); assert_eq!(map.len(), 6); } #[test] fn test_extend_ref() { let mut a = BTreeMap::new(); a.insert(1, "one"); let mut b = BTreeMap::new(); b.insert(2, "two"); b.insert(3, "three"); a.extend(&b); assert_eq!(a.len(), 3); assert_eq!(a[&1], "one"); assert_eq!(a[&2], "two"); assert_eq!(a[&3], "three"); } #[test] fn test_zst() { let mut m = BTreeMap::new(); assert_eq!(m.len(), 0); assert_eq!(m.insert((), ()), None); assert_eq!(m.len(), 1); assert_eq!(m.insert((), ()), Some(())); assert_eq!(m.len(), 1); assert_eq!(m.iter().count(), 1); m.clear(); assert_eq!(m.len(), 0); for _ in 0..100 { m.insert((), ()); } assert_eq!(m.len(), 1); assert_eq!(m.iter().count(), 1); } // This test's only purpose is to ensure that zero-sized keys with nonsensical orderings // do not cause segfaults when used with zero-sized values. All other map behavior is // undefined. #[test] fn test_bad_zst() { use std::cmp::Ordering; struct Bad; impl PartialEq for Bad { fn eq(&self, _: &Self) -> bool { false } } impl Eq for Bad {} impl PartialOrd for Bad { fn partial_cmp(&self, _: &Self) -> Option { Some(Ordering::Less) } } impl Ord for Bad { fn cmp(&self, _: &Self) -> Ordering { Ordering::Less } } let mut m = BTreeMap::new(); for _ in 0..100 { m.insert(Bad, Bad); } } #[test] fn test_clone() { let mut map = BTreeMap::new(); let size = MIN_INSERTS_HEIGHT_1; assert_eq!(map.len(), 0); for i in 0..size { assert_eq!(map.insert(i, 10 * i), None); assert_eq!(map.len(), i + 1); assert_eq!(map, map.clone()); } for i in 0..size { assert_eq!(map.insert(i, 100 * i), Some(10 * i)); assert_eq!(map.len(), size); assert_eq!(map, map.clone()); } for i in 0..size / 2 { assert_eq!(map.remove(&(i * 2)), Some(i * 200)); assert_eq!(map.len(), size - i - 1); assert_eq!(map, map.clone()); } for i in 0..size / 2 { assert_eq!(map.remove(&(2 * i)), None); assert_eq!(map.remove(&(2 * i + 1)), Some(i * 200 + 100)); assert_eq!(map.len(), size / 2 - i - 1); assert_eq!(map, map.clone()); } // Test a tree with 2 chock-full levels and a tree with 3 levels. map = (1..MIN_INSERTS_HEIGHT_2).map(|i| (i, i)).collect(); assert_eq!(map.len(), MIN_INSERTS_HEIGHT_2 - 1); assert_eq!(map, map.clone()); map.insert(0, 0); assert_eq!(map.len(), MIN_INSERTS_HEIGHT_2); assert_eq!(map, map.clone()); } #[test] fn test_clone_from() { let mut map1 = BTreeMap::new(); let max_size = MIN_INSERTS_HEIGHT_1; // Range to max_size inclusive, because i is the size of map1 being tested. for i in 0..=max_size { let mut map2 = BTreeMap::new(); for j in 0..i { let mut map1_copy = map2.clone(); map1_copy.clone_from(&map1); // small cloned from large assert_eq!(map1_copy, map1); let mut map2_copy = map1.clone(); map2_copy.clone_from(&map2); // large cloned from small assert_eq!(map2_copy, map2); map2.insert(100 * j + 1, 2 * j + 1); } map2.clone_from(&map1); // same length assert_eq!(map2, map1); map1.insert(i, 10 * i); } } #[test] #[allow(dead_code)] fn test_variance() { use std::collections::btree_map::{IntoIter, Iter, Keys, Range, Values}; fn map_key<'new>(v: BTreeMap<&'static str, ()>) -> BTreeMap<&'new str, ()> { v } fn map_val<'new>(v: BTreeMap<(), &'static str>) -> BTreeMap<(), &'new str> { v } fn iter_key<'a, 'new>(v: Iter<'a, &'static str, ()>) -> Iter<'a, &'new str, ()> { v } fn iter_val<'a, 'new>(v: Iter<'a, (), &'static str>) -> Iter<'a, (), &'new str> { v } fn into_iter_key<'new>(v: IntoIter<&'static str, ()>) -> IntoIter<&'new str, ()> { v } fn into_iter_val<'new>(v: IntoIter<(), &'static str>) -> IntoIter<(), &'new str> { v } fn range_key<'a, 'new>(v: Range<'a, &'static str, ()>) -> Range<'a, &'new str, ()> { v } fn range_val<'a, 'new>(v: Range<'a, (), &'static str>) -> Range<'a, (), &'new str> { v } fn keys<'a, 'new>(v: Keys<'a, &'static str, ()>) -> Keys<'a, &'new str, ()> { v } fn vals<'a, 'new>(v: Values<'a, (), &'static str>) -> Values<'a, (), &'new str> { v } } #[test] fn test_occupied_entry_key() { let mut a = BTreeMap::new(); let key = "hello there"; let value = "value goes here"; assert!(a.is_empty()); a.insert(key.clone(), value.clone()); assert_eq!(a.len(), 1); assert_eq!(a[key], value); match a.entry(key.clone()) { Vacant(_) => panic!(), Occupied(e) => assert_eq!(key, *e.key()), } assert_eq!(a.len(), 1); assert_eq!(a[key], value); } #[test] fn test_vacant_entry_key() { let mut a = BTreeMap::new(); let key = "hello there"; let value = "value goes here"; assert!(a.is_empty()); match a.entry(key.clone()) { Occupied(_) => panic!(), Vacant(e) => { assert_eq!(key, *e.key()); e.insert(value.clone()); } } assert_eq!(a.len(), 1); assert_eq!(a[key], value); } #[test] fn test_first_last_entry() { let mut a = BTreeMap::new(); assert!(a.first_entry().is_none()); assert!(a.last_entry().is_none()); a.insert(1, 42); assert_eq!(a.first_entry().unwrap().key(), &1); assert_eq!(a.last_entry().unwrap().key(), &1); a.insert(2, 24); assert_eq!(a.first_entry().unwrap().key(), &1); assert_eq!(a.last_entry().unwrap().key(), &2); a.insert(0, 6); assert_eq!(a.first_entry().unwrap().key(), &0); assert_eq!(a.last_entry().unwrap().key(), &2); let (k1, v1) = a.first_entry().unwrap().remove_entry(); assert_eq!(k1, 0); assert_eq!(v1, 6); let (k2, v2) = a.last_entry().unwrap().remove_entry(); assert_eq!(k2, 2); assert_eq!(v2, 24); assert_eq!(a.first_entry().unwrap().key(), &1); assert_eq!(a.last_entry().unwrap().key(), &1); } macro_rules! create_append_test { ($name:ident, $len:expr) => { #[test] fn $name() { let mut a = BTreeMap::new(); for i in 0..8 { a.insert(i, i); } let mut b = BTreeMap::new(); for i in 5..$len { b.insert(i, 2 * i); } a.append(&mut b); assert_eq!(a.len(), $len); assert_eq!(b.len(), 0); for i in 0..$len { if i < 5 { assert_eq!(a[&i], i); } else { assert_eq!(a[&i], 2 * i); } } assert_eq!(a.remove(&($len - 1)), Some(2 * ($len - 1))); assert_eq!(a.insert($len - 1, 20), None); } }; } // These are mostly for testing the algorithm that "fixes" the right edge after insertion. // Single node. create_append_test!(test_append_9, 9); // Two leafs that don't need fixing. create_append_test!(test_append_17, 17); // Two leafs where the second one ends up underfull and needs stealing at the end. create_append_test!(test_append_14, 14); // Two leafs where the second one ends up empty because the insertion finished at the root. create_append_test!(test_append_12, 12); // Three levels; insertion finished at the root. create_append_test!(test_append_144, 144); // Three levels; insertion finished at leaf while there is an empty node on the second level. create_append_test!(test_append_145, 145); // Tests for several randomly chosen sizes. create_append_test!(test_append_170, 170); create_append_test!(test_append_181, 181); #[cfg(not(miri))] // Miri is too slow create_append_test!(test_append_239, 239); #[cfg(not(miri))] // Miri is too slow create_append_test!(test_append_1700, 1700); fn rand_data(len: usize) -> Vec<(u32, u32)> { let mut rng = DeterministicRng::new(); Vec::from_iter((0..len).map(|_| (rng.next(), rng.next()))) } #[test] fn test_split_off_empty_right() { let mut data = rand_data(173); let mut map = BTreeMap::from_iter(data.clone()); let right = map.split_off(&(data.iter().max().unwrap().0 + 1)); data.sort(); assert!(map.into_iter().eq(data)); assert!(right.into_iter().eq(None)); } #[test] fn test_split_off_empty_left() { let mut data = rand_data(314); let mut map = BTreeMap::from_iter(data.clone()); let right = map.split_off(&data.iter().min().unwrap().0); data.sort(); assert!(map.into_iter().eq(None)); assert!(right.into_iter().eq(data)); } // In a tree with 3 levels, if all but a part of the first leaf node is split off, // make sure fix_top eliminates both top levels. #[test] fn test_split_off_tiny_left_height_2() { let pairs = (0..MIN_INSERTS_HEIGHT_2).map(|i| (i, i)); let mut left: BTreeMap<_, _> = pairs.clone().collect(); let right = left.split_off(&1); assert_eq!(left.len(), 1); assert_eq!(right.len(), MIN_INSERTS_HEIGHT_2 - 1); assert_eq!(*left.first_key_value().unwrap().0, 0); assert_eq!(*right.first_key_value().unwrap().0, 1); } // In a tree with 3 levels, if only part of the last leaf node is split off, // make sure fix_top eliminates both top levels. #[test] fn test_split_off_tiny_right_height_2() { let pairs = (0..MIN_INSERTS_HEIGHT_2).map(|i| (i, i)); let last = MIN_INSERTS_HEIGHT_2 - 1; let mut left: BTreeMap<_, _> = pairs.clone().collect(); assert_eq!(*left.last_key_value().unwrap().0, last); let right = left.split_off(&last); assert_eq!(left.len(), MIN_INSERTS_HEIGHT_2 - 1); assert_eq!(right.len(), 1); assert_eq!(*left.last_key_value().unwrap().0, last - 1); assert_eq!(*right.last_key_value().unwrap().0, last); } #[test] fn test_split_off_large_random_sorted() { // Miri is too slow let mut data = if cfg!(miri) { rand_data(529) } else { rand_data(1529) }; // special case with maximum height. data.sort(); let mut map = BTreeMap::from_iter(data.clone()); let key = data[data.len() / 2].0; let right = map.split_off(&key); assert!(map.into_iter().eq(data.clone().into_iter().filter(|x| x.0 < key))); assert!(right.into_iter().eq(data.into_iter().filter(|x| x.0 >= key))); } #[test] fn test_into_iter_drop_leak_height_0() { static DROPS: AtomicUsize = AtomicUsize::new(0); struct D; impl Drop for D { fn drop(&mut self) { if DROPS.fetch_add(1, Ordering::SeqCst) == 3 { panic!("panic in `drop`"); } } } let mut map = BTreeMap::new(); map.insert("a", D); map.insert("b", D); map.insert("c", D); map.insert("d", D); map.insert("e", D); catch_unwind(move || drop(map.into_iter())).unwrap_err(); assert_eq!(DROPS.load(Ordering::SeqCst), 5); } #[test] fn test_into_iter_drop_leak_height_1() { let size = MIN_INSERTS_HEIGHT_1; static DROPS: AtomicUsize = AtomicUsize::new(0); static PANIC_POINT: AtomicUsize = AtomicUsize::new(0); struct D; impl Drop for D { fn drop(&mut self) { if DROPS.fetch_add(1, Ordering::SeqCst) == PANIC_POINT.load(Ordering::SeqCst) { panic!("panic in `drop`"); } } } for panic_point in vec![0, 1, size - 2, size - 1] { DROPS.store(0, Ordering::SeqCst); PANIC_POINT.store(panic_point, Ordering::SeqCst); let map: BTreeMap<_, _> = (0..size).map(|i| (i, D)).collect(); catch_unwind(move || drop(map.into_iter())).unwrap_err(); assert_eq!(DROPS.load(Ordering::SeqCst), size); } } #[test] fn test_into_keys() { let vec = vec![(1, 'a'), (2, 'b'), (3, 'c')]; let map: BTreeMap<_, _> = vec.into_iter().collect(); let keys: Vec<_> = map.into_keys().collect(); assert_eq!(keys.len(), 3); assert!(keys.contains(&1)); assert!(keys.contains(&2)); assert!(keys.contains(&3)); } #[test] fn test_into_values() { let vec = vec![(1, 'a'), (2, 'b'), (3, 'c')]; let map: BTreeMap<_, _> = vec.into_iter().collect(); let values: Vec<_> = map.into_values().collect(); assert_eq!(values.len(), 3); assert!(values.contains(&'a')); assert!(values.contains(&'b')); assert!(values.contains(&'c')); }