#![warn(rust_2018_idioms)] use slab::*; use std::panic::{catch_unwind, resume_unwind, AssertUnwindSafe}; #[test] fn insert_get_remove_one() { let mut slab = Slab::new(); assert!(slab.is_empty()); let key = slab.insert(10); assert_eq!(slab[key], 10); assert_eq!(slab.get(key), Some(&10)); assert!(!slab.is_empty()); assert!(slab.contains(key)); assert_eq!(slab.remove(key), 10); assert!(!slab.contains(key)); assert!(slab.get(key).is_none()); } #[test] fn insert_get_many() { let mut slab = Slab::with_capacity(10); for i in 0..10 { let key = slab.insert(i + 10); assert_eq!(slab[key], i + 10); } assert_eq!(slab.capacity(), 10); // Storing another one grows the slab let key = slab.insert(20); assert_eq!(slab[key], 20); // Capacity grows by 2x assert_eq!(slab.capacity(), 20); } #[test] fn insert_get_remove_many() { let mut slab = Slab::with_capacity(10); let mut keys = vec![]; for i in 0..10 { for j in 0..10 { let val = (i * 10) + j; let key = slab.insert(val); keys.push((key, val)); assert_eq!(slab[key], val); } for (key, val) in keys.drain(..) { assert_eq!(val, slab.remove(key)); } } assert_eq!(10, slab.capacity()); } #[test] fn insert_with_vacant_entry() { let mut slab = Slab::with_capacity(1); let key; { let entry = slab.vacant_entry(); key = entry.key(); entry.insert(123); } assert_eq!(123, slab[key]); } #[test] fn get_vacant_entry_without_using() { let mut slab = Slab::::with_capacity(1); let key = slab.vacant_entry().key(); assert_eq!(key, slab.vacant_entry().key()); } #[test] #[should_panic(expected = "invalid key")] fn invalid_get_panics() { let slab = Slab::::with_capacity(1); let _ = &slab[0]; } #[test] #[should_panic(expected = "invalid key")] fn invalid_get_mut_panics() { let mut slab = Slab::::new(); let _ = &mut slab[0]; } #[test] #[should_panic(expected = "invalid key")] fn double_remove_panics() { let mut slab = Slab::::with_capacity(1); let key = slab.insert(123); slab.remove(key); slab.remove(key); } #[test] #[should_panic(expected = "invalid key")] fn invalid_remove_panics() { let mut slab = Slab::::with_capacity(1); slab.remove(0); } #[test] fn slab_get_mut() { let mut slab = Slab::new(); let key = slab.insert(1); slab[key] = 2; assert_eq!(slab[key], 2); *slab.get_mut(key).unwrap() = 3; assert_eq!(slab[key], 3); } #[test] fn key_of_tagged() { let mut slab = Slab::new(); slab.insert(0); assert_eq!(slab.key_of(&slab[0]), 0); } #[test] fn key_of_layout_optimizable() { // Entry<&str> doesn't need a discriminant tag because it can use the // nonzero-ness of ptr and store Vacant's next at the same offset as len let mut slab = Slab::new(); slab.insert("foo"); slab.insert("bar"); let third = slab.insert("baz"); slab.insert("quux"); assert_eq!(slab.key_of(&slab[third]), third); } #[test] fn key_of_zst() { let mut slab = Slab::new(); slab.insert(()); let second = slab.insert(()); slab.insert(()); assert_eq!(slab.key_of(&slab[second]), second); } #[test] fn reserve_does_not_allocate_if_available() { let mut slab = Slab::with_capacity(10); let mut keys = vec![]; for i in 0..6 { keys.push(slab.insert(i)); } for key in 0..4 { slab.remove(key); } assert!(slab.capacity() - slab.len() == 8); slab.reserve(8); assert_eq!(10, slab.capacity()); } #[test] fn reserve_exact_does_not_allocate_if_available() { let mut slab = Slab::with_capacity(10); let mut keys = vec![]; for i in 0..6 { keys.push(slab.insert(i)); } for key in 0..4 { slab.remove(key); } assert!(slab.capacity() - slab.len() == 8); slab.reserve_exact(8); assert_eq!(10, slab.capacity()); } #[test] #[should_panic(expected = "capacity overflow")] fn reserve_does_panic_with_capacity_overflow() { let mut slab = Slab::with_capacity(10); slab.insert(true); slab.reserve(std::usize::MAX); } #[test] #[should_panic(expected = "capacity overflow")] fn reserve_exact_does_panic_with_capacity_overflow() { let mut slab = Slab::with_capacity(10); slab.insert(true); slab.reserve_exact(std::usize::MAX); } #[test] fn retain() { let mut slab = Slab::with_capacity(2); let key1 = slab.insert(0); let key2 = slab.insert(1); slab.retain(|key, x| { assert_eq!(key, *x); *x % 2 == 0 }); assert_eq!(slab.len(), 1); assert_eq!(slab[key1], 0); assert!(!slab.contains(key2)); // Ensure consistency is retained let key = slab.insert(123); assert_eq!(key, key2); assert_eq!(2, slab.len()); assert_eq!(2, slab.capacity()); // Inserting another element grows let key = slab.insert(345); assert_eq!(key, 2); assert_eq!(4, slab.capacity()); } #[test] fn into_iter() { let mut slab = Slab::new(); for i in 0..8 { slab.insert(i); } slab.remove(0); slab.remove(4); slab.remove(5); slab.remove(7); let vals: Vec<_> = slab .into_iter() .inspect(|&(key, val)| assert_eq!(key, val)) .map(|(_, val)| val) .collect(); assert_eq!(vals, vec![1, 2, 3, 6]); } #[test] fn into_iter_rev() { let mut slab = Slab::new(); for i in 0..4 { slab.insert(i); } let mut iter = slab.into_iter(); assert_eq!(iter.next_back(), Some((3, 3))); assert_eq!(iter.next_back(), Some((2, 2))); assert_eq!(iter.next(), Some((0, 0))); assert_eq!(iter.next_back(), Some((1, 1))); assert_eq!(iter.next_back(), None); assert_eq!(iter.next(), None); } #[test] fn iter() { let mut slab = Slab::new(); for i in 0..4 { slab.insert(i); } let vals: Vec<_> = slab .iter() .enumerate() .map(|(i, (key, val))| { assert_eq!(i, key); *val }) .collect(); assert_eq!(vals, vec![0, 1, 2, 3]); slab.remove(1); let vals: Vec<_> = slab.iter().map(|(_, r)| *r).collect(); assert_eq!(vals, vec![0, 2, 3]); } #[test] fn iter_rev() { let mut slab = Slab::new(); for i in 0..4 { slab.insert(i); } slab.remove(0); let vals = slab.iter().rev().collect::>(); assert_eq!(vals, vec![(3, &3), (2, &2), (1, &1)]); } #[test] fn iter_mut() { let mut slab = Slab::new(); for i in 0..4 { slab.insert(i); } for (i, (key, e)) in slab.iter_mut().enumerate() { assert_eq!(i, key); *e += 1; } let vals: Vec<_> = slab.iter().map(|(_, r)| *r).collect(); assert_eq!(vals, vec![1, 2, 3, 4]); slab.remove(2); for (_, e) in slab.iter_mut() { *e += 1; } let vals: Vec<_> = slab.iter().map(|(_, r)| *r).collect(); assert_eq!(vals, vec![2, 3, 5]); } #[test] fn iter_mut_rev() { let mut slab = Slab::new(); for i in 0..4 { slab.insert(i); } slab.remove(2); { let mut iter = slab.iter_mut(); assert_eq!(iter.next(), Some((0, &mut 0))); let mut prev_key = !0; for (key, e) in iter.rev() { *e += 10; assert!(prev_key > key); prev_key = key; } } assert_eq!(slab[0], 0); assert_eq!(slab[1], 11); assert_eq!(slab[3], 13); assert!(!slab.contains(2)); } #[test] fn from_iterator_sorted() { let mut slab = (0..5).map(|i| (i, i)).collect::>(); assert_eq!(slab.len(), 5); assert_eq!(slab[0], 0); assert_eq!(slab[2], 2); assert_eq!(slab[4], 4); assert_eq!(slab.vacant_entry().key(), 5); } #[test] fn from_iterator_new_in_order() { // all new keys come in increasing order, but existing keys are overwritten let mut slab = [(0, 'a'), (1, 'a'), (1, 'b'), (0, 'b'), (9, 'a'), (0, 'c')] .iter() .cloned() .collect::>(); assert_eq!(slab.len(), 3); assert_eq!(slab[0], 'c'); assert_eq!(slab[1], 'b'); assert_eq!(slab[9], 'a'); assert_eq!(slab.get(5), None); assert_eq!(slab.vacant_entry().key(), 8); } #[test] fn from_iterator_unordered() { let mut slab = vec![(1, "one"), (50, "fifty"), (3, "three"), (20, "twenty")] .into_iter() .collect::>(); assert_eq!(slab.len(), 4); assert_eq!(slab.vacant_entry().key(), 0); let mut iter = slab.iter(); assert_eq!(iter.next(), Some((1, &"one"))); assert_eq!(iter.next(), Some((3, &"three"))); assert_eq!(iter.next(), Some((20, &"twenty"))); assert_eq!(iter.next(), Some((50, &"fifty"))); assert_eq!(iter.next(), None); } // https://github.com/tokio-rs/slab/issues/100 #[test] fn from_iterator_issue_100() { let mut slab: slab::Slab<()> = vec![(1, ())].into_iter().collect(); assert_eq!(slab.len(), 1); assert_eq!(slab.insert(()), 0); assert_eq!(slab.insert(()), 2); assert_eq!(slab.insert(()), 3); let mut slab: slab::Slab<()> = vec![(1, ()), (2, ())].into_iter().collect(); assert_eq!(slab.len(), 2); assert_eq!(slab.insert(()), 0); assert_eq!(slab.insert(()), 3); assert_eq!(slab.insert(()), 4); let mut slab: slab::Slab<()> = vec![(1, ()), (3, ())].into_iter().collect(); assert_eq!(slab.len(), 2); assert_eq!(slab.insert(()), 2); assert_eq!(slab.insert(()), 0); assert_eq!(slab.insert(()), 4); let mut slab: slab::Slab<()> = vec![(0, ()), (2, ()), (3, ()), (5, ())] .into_iter() .collect(); assert_eq!(slab.len(), 4); assert_eq!(slab.insert(()), 4); assert_eq!(slab.insert(()), 1); assert_eq!(slab.insert(()), 6); } #[test] fn clear() { let mut slab = Slab::new(); for i in 0..4 { slab.insert(i); } // clear full slab.clear(); assert!(slab.is_empty()); assert_eq!(0, slab.len()); assert_eq!(4, slab.capacity()); for i in 0..2 { slab.insert(i); } let vals: Vec<_> = slab.iter().map(|(_, r)| *r).collect(); assert_eq!(vals, vec![0, 1]); // clear half-filled slab.clear(); assert!(slab.is_empty()); } #[test] fn shrink_to_fit_empty() { let mut slab = Slab::::with_capacity(20); slab.shrink_to_fit(); assert_eq!(slab.capacity(), 0); } #[test] fn shrink_to_fit_no_vacant() { let mut slab = Slab::with_capacity(20); slab.insert(String::new()); slab.shrink_to_fit(); assert!(slab.capacity() < 10); } #[test] fn shrink_to_fit_doesnt_move() { let mut slab = Slab::with_capacity(8); slab.insert("foo"); let bar = slab.insert("bar"); slab.insert("baz"); let quux = slab.insert("quux"); slab.remove(quux); slab.remove(bar); slab.shrink_to_fit(); assert_eq!(slab.len(), 2); assert!(slab.capacity() >= 3); assert_eq!(slab.get(0), Some(&"foo")); assert_eq!(slab.get(2), Some(&"baz")); assert_eq!(slab.vacant_entry().key(), bar); } #[test] fn shrink_to_fit_doesnt_recreate_list_when_nothing_can_be_done() { let mut slab = Slab::with_capacity(16); for i in 0..4 { slab.insert(Box::new(i)); } slab.remove(0); slab.remove(2); slab.remove(1); assert_eq!(slab.vacant_entry().key(), 1); slab.shrink_to_fit(); assert_eq!(slab.len(), 1); assert!(slab.capacity() >= 4); assert_eq!(slab.vacant_entry().key(), 1); } #[test] fn compact_empty() { let mut slab = Slab::new(); slab.compact(|_, _, _| panic!()); assert_eq!(slab.len(), 0); assert_eq!(slab.capacity(), 0); slab.reserve(20); slab.compact(|_, _, _| panic!()); assert_eq!(slab.len(), 0); assert_eq!(slab.capacity(), 0); slab.insert(0); slab.insert(1); slab.insert(2); slab.remove(1); slab.remove(2); slab.remove(0); slab.compact(|_, _, _| panic!()); assert_eq!(slab.len(), 0); assert_eq!(slab.capacity(), 0); } #[test] fn compact_no_moves_needed() { let mut slab = Slab::new(); for i in 0..10 { slab.insert(i); } slab.remove(8); slab.remove(9); slab.remove(6); slab.remove(7); slab.compact(|_, _, _| panic!()); assert_eq!(slab.len(), 6); for ((index, &value), want) in slab.iter().zip(0..6) { assert!(index == value); assert_eq!(index, want); } assert!(slab.capacity() >= 6 && slab.capacity() < 10); } #[test] fn compact_moves_successfully() { let mut slab = Slab::with_capacity(20); for i in 0..10 { slab.insert(i); } for &i in &[0, 5, 9, 6, 3] { slab.remove(i); } let mut moved = 0; slab.compact(|&mut v, from, to| { assert!(from > to); assert!(from >= 5); assert!(to < 5); assert_eq!(from, v); moved += 1; true }); assert_eq!(slab.len(), 5); assert_eq!(moved, 2); assert_eq!(slab.vacant_entry().key(), 5); assert!(slab.capacity() >= 5 && slab.capacity() < 20); let mut iter = slab.iter(); assert_eq!(iter.next(), Some((0, &8))); assert_eq!(iter.next(), Some((1, &1))); assert_eq!(iter.next(), Some((2, &2))); assert_eq!(iter.next(), Some((3, &7))); assert_eq!(iter.next(), Some((4, &4))); assert_eq!(iter.next(), None); } #[test] fn compact_doesnt_move_if_closure_errors() { let mut slab = Slab::with_capacity(20); for i in 0..10 { slab.insert(i); } for &i in &[9, 3, 1, 4, 0] { slab.remove(i); } slab.compact(|&mut v, from, to| { assert!(from > to); assert_eq!(from, v); v != 6 }); assert_eq!(slab.len(), 5); assert!(slab.capacity() >= 7 && slab.capacity() < 20); assert_eq!(slab.vacant_entry().key(), 3); let mut iter = slab.iter(); assert_eq!(iter.next(), Some((0, &8))); assert_eq!(iter.next(), Some((1, &7))); assert_eq!(iter.next(), Some((2, &2))); assert_eq!(iter.next(), Some((5, &5))); assert_eq!(iter.next(), Some((6, &6))); assert_eq!(iter.next(), None); } #[test] fn compact_handles_closure_panic() { let mut slab = Slab::new(); for i in 0..10 { slab.insert(i); } for i in 1..6 { slab.remove(i); } let result = catch_unwind(AssertUnwindSafe(|| { slab.compact(|&mut v, from, to| { assert!(from > to); assert_eq!(from, v); if v == 7 { panic!("test"); } true }) })); match result { Err(ref payload) if payload.downcast_ref() == Some(&"test") => {} Err(bug) => resume_unwind(bug), Ok(()) => unreachable!(), } assert_eq!(slab.len(), 5 - 1); assert_eq!(slab.vacant_entry().key(), 3); let mut iter = slab.iter(); assert_eq!(iter.next(), Some((0, &0))); assert_eq!(iter.next(), Some((1, &9))); assert_eq!(iter.next(), Some((2, &8))); assert_eq!(iter.next(), Some((6, &6))); assert_eq!(iter.next(), None); } #[test] fn fully_consumed_drain() { let mut slab = Slab::new(); for i in 0..3 { slab.insert(i); } { let mut drain = slab.drain(); assert_eq!(Some(0), drain.next()); assert_eq!(Some(1), drain.next()); assert_eq!(Some(2), drain.next()); assert_eq!(None, drain.next()); } assert!(slab.is_empty()); } #[test] fn partially_consumed_drain() { let mut slab = Slab::new(); for i in 0..3 { slab.insert(i); } { let mut drain = slab.drain(); assert_eq!(Some(0), drain.next()); } assert!(slab.is_empty()) } #[test] fn drain_rev() { let mut slab = Slab::new(); for i in 0..10 { slab.insert(i); } slab.remove(9); let vals: Vec = slab.drain().rev().collect(); assert_eq!(vals, (0..9).rev().collect::>()); } #[test] fn try_remove() { let mut slab = Slab::new(); let key = slab.insert(1); assert_eq!(slab.try_remove(key), Some(1)); assert_eq!(slab.try_remove(key), None); assert_eq!(slab.get(key), None); } #[rustversion::since(1.39)] #[test] fn const_new() { static _SLAB: Slab<()> = Slab::new(); }