use std::collections::BTreeMap; use std::iter::Iterator; use std::ops::RangeBounds; use std::vec::Vec; use rand::{seq::SliceRandom, thread_rng, Rng}; use test::{black_box, Bencher}; macro_rules! map_insert_rand_bench { ($name: ident, $n: expr, $map: ident) => { #[bench] pub fn $name(b: &mut Bencher) { let n: usize = $n; let mut map = $map::new(); // setup let mut rng = thread_rng(); for _ in 0..n { let i = rng.gen::() % n; map.insert(i, i); } // measure b.iter(|| { let k = rng.gen::() % n; map.insert(k, k); map.remove(&k); }); black_box(map); } }; } macro_rules! map_insert_seq_bench { ($name: ident, $n: expr, $map: ident) => { #[bench] pub fn $name(b: &mut Bencher) { let mut map = $map::new(); let n: usize = $n; // setup for i in 0..n { map.insert(i * 2, i * 2); } // measure let mut i = 1; b.iter(|| { map.insert(i, i); map.remove(&i); i = (i + 2) % n; }); black_box(map); } }; } macro_rules! map_find_rand_bench { ($name: ident, $n: expr, $map: ident) => { #[bench] pub fn $name(b: &mut Bencher) { let mut map = $map::new(); let n: usize = $n; // setup let mut rng = thread_rng(); let mut keys: Vec<_> = (0..n).map(|_| rng.gen::() % n).collect(); for &k in &keys { map.insert(k, k); } keys.shuffle(&mut rng); // measure let mut i = 0; b.iter(|| { let t = map.get(&keys[i]); i = (i + 1) % n; black_box(t); }) } }; } macro_rules! map_find_seq_bench { ($name: ident, $n: expr, $map: ident) => { #[bench] pub fn $name(b: &mut Bencher) { let mut map = $map::new(); let n: usize = $n; // setup for i in 0..n { map.insert(i, i); } // measure let mut i = 0; b.iter(|| { let x = map.get(&i); i = (i + 1) % n; black_box(x); }) } }; } map_insert_rand_bench! {insert_rand_100, 100, BTreeMap} map_insert_rand_bench! {insert_rand_10_000, 10_000, BTreeMap} map_insert_seq_bench! {insert_seq_100, 100, BTreeMap} map_insert_seq_bench! {insert_seq_10_000, 10_000, BTreeMap} map_find_rand_bench! {find_rand_100, 100, BTreeMap} map_find_rand_bench! {find_rand_10_000, 10_000, BTreeMap} map_find_seq_bench! {find_seq_100, 100, BTreeMap} map_find_seq_bench! {find_seq_10_000, 10_000, BTreeMap} fn bench_iteration(b: &mut Bencher, size: i32) { let mut map = BTreeMap::::new(); let mut rng = thread_rng(); for _ in 0..size { map.insert(rng.gen(), rng.gen()); } b.iter(|| { for entry in &map { black_box(entry); } }); } #[bench] pub fn iteration_20(b: &mut Bencher) { bench_iteration(b, 20); } #[bench] pub fn iteration_1000(b: &mut Bencher) { bench_iteration(b, 1000); } #[bench] pub fn iteration_100000(b: &mut Bencher) { bench_iteration(b, 100000); } fn bench_iteration_mut(b: &mut Bencher, size: i32) { let mut map = BTreeMap::::new(); let mut rng = thread_rng(); for _ in 0..size { map.insert(rng.gen(), rng.gen()); } b.iter(|| { for kv in map.iter_mut() { black_box(kv); } }); } #[bench] pub fn iteration_mut_20(b: &mut Bencher) { bench_iteration_mut(b, 20); } #[bench] pub fn iteration_mut_1000(b: &mut Bencher) { bench_iteration_mut(b, 1000); } #[bench] pub fn iteration_mut_100000(b: &mut Bencher) { bench_iteration_mut(b, 100000); } fn bench_first_and_last(b: &mut Bencher, size: i32) { let map: BTreeMap<_, _> = (0..size).map(|i| (i, i)).collect(); b.iter(|| { for _ in 0..10 { black_box(map.first_key_value()); black_box(map.last_key_value()); } }); } #[bench] pub fn first_and_last_0(b: &mut Bencher) { bench_first_and_last(b, 0); } #[bench] pub fn first_and_last_100(b: &mut Bencher) { bench_first_and_last(b, 100); } #[bench] pub fn first_and_last_10k(b: &mut Bencher) { bench_first_and_last(b, 10_000); } const BENCH_RANGE_SIZE: i32 = 145; const BENCH_RANGE_COUNT: i32 = BENCH_RANGE_SIZE * (BENCH_RANGE_SIZE - 1) / 2; fn bench_range(b: &mut Bencher, f: F) where F: Fn(i32, i32) -> R, R: RangeBounds, { let map: BTreeMap<_, _> = (0..BENCH_RANGE_SIZE).map(|i| (i, i)).collect(); b.iter(|| { let mut c = 0; for i in 0..BENCH_RANGE_SIZE { for j in i + 1..BENCH_RANGE_SIZE { black_box(map.range(f(i, j))); c += 1; } } debug_assert_eq!(c, BENCH_RANGE_COUNT); }); } #[bench] pub fn range_included_excluded(b: &mut Bencher) { bench_range(b, |i, j| i..j); } #[bench] pub fn range_included_included(b: &mut Bencher) { bench_range(b, |i, j| i..=j); } #[bench] pub fn range_included_unbounded(b: &mut Bencher) { bench_range(b, |i, _| i..); } #[bench] pub fn range_unbounded_unbounded(b: &mut Bencher) { bench_range(b, |_, _| ..); } fn bench_iter(b: &mut Bencher, repeats: i32, size: i32) { let map: BTreeMap<_, _> = (0..size).map(|i| (i, i)).collect(); b.iter(|| { for _ in 0..repeats { black_box(map.iter()); } }); } /// Contrast range_unbounded_unbounded with `iter()`. #[bench] pub fn range_unbounded_vs_iter(b: &mut Bencher) { bench_iter(b, BENCH_RANGE_COUNT, BENCH_RANGE_SIZE); } #[bench] pub fn iter_0(b: &mut Bencher) { bench_iter(b, 1_000, 0); } #[bench] pub fn iter_1(b: &mut Bencher) { bench_iter(b, 1_000, 1); } #[bench] pub fn iter_100(b: &mut Bencher) { bench_iter(b, 1_000, 100); } #[bench] pub fn iter_10k(b: &mut Bencher) { bench_iter(b, 1_000, 10_000); } #[bench] pub fn iter_1m(b: &mut Bencher) { bench_iter(b, 1_000, 1_000_000); } const FAT: usize = 256; // The returned map has small keys and values. // Benchmarks on it have a counterpart in set.rs with the same keys and no values at all. fn slim_map(n: usize) -> BTreeMap { (0..n).map(|i| (i, i)).collect::>() } // The returned map has small keys and large values. fn fat_val_map(n: usize) -> BTreeMap { (0..n).map(|i| (i, [i; FAT])).collect::>() } #[bench] pub fn clone_slim_100(b: &mut Bencher) { let src = slim_map(100); b.iter(|| src.clone()) } #[bench] pub fn clone_slim_100_and_clear(b: &mut Bencher) { let src = slim_map(100); b.iter(|| src.clone().clear()) } #[bench] pub fn clone_slim_100_and_drain_all(b: &mut Bencher) { let src = slim_map(100); b.iter(|| src.clone().drain_filter(|_, _| true).count()) } #[bench] pub fn clone_slim_100_and_drain_half(b: &mut Bencher) { let src = slim_map(100); b.iter(|| { let mut map = src.clone(); assert_eq!(map.drain_filter(|i, _| i % 2 == 0).count(), 100 / 2); assert_eq!(map.len(), 100 / 2); }) } #[bench] pub fn clone_slim_100_and_into_iter(b: &mut Bencher) { let src = slim_map(100); b.iter(|| src.clone().into_iter().count()) } #[bench] pub fn clone_slim_100_and_pop_all(b: &mut Bencher) { let src = slim_map(100); b.iter(|| { let mut map = src.clone(); while map.pop_first().is_some() {} map }); } #[bench] pub fn clone_slim_100_and_remove_all(b: &mut Bencher) { let src = slim_map(100); b.iter(|| { let mut map = src.clone(); while let Some(elt) = map.iter().map(|(&i, _)| i).next() { let v = map.remove(&elt); debug_assert!(v.is_some()); } map }); } #[bench] pub fn clone_slim_100_and_remove_half(b: &mut Bencher) { let src = slim_map(100); b.iter(|| { let mut map = src.clone(); for i in (0..100).step_by(2) { let v = map.remove(&i); debug_assert!(v.is_some()); } assert_eq!(map.len(), 100 / 2); map }) } #[bench] pub fn clone_slim_10k(b: &mut Bencher) { let src = slim_map(10_000); b.iter(|| src.clone()) } #[bench] pub fn clone_slim_10k_and_clear(b: &mut Bencher) { let src = slim_map(10_000); b.iter(|| src.clone().clear()) } #[bench] pub fn clone_slim_10k_and_drain_all(b: &mut Bencher) { let src = slim_map(10_000); b.iter(|| src.clone().drain_filter(|_, _| true).count()) } #[bench] pub fn clone_slim_10k_and_drain_half(b: &mut Bencher) { let src = slim_map(10_000); b.iter(|| { let mut map = src.clone(); assert_eq!(map.drain_filter(|i, _| i % 2 == 0).count(), 10_000 / 2); assert_eq!(map.len(), 10_000 / 2); }) } #[bench] pub fn clone_slim_10k_and_into_iter(b: &mut Bencher) { let src = slim_map(10_000); b.iter(|| src.clone().into_iter().count()) } #[bench] pub fn clone_slim_10k_and_pop_all(b: &mut Bencher) { let src = slim_map(10_000); b.iter(|| { let mut map = src.clone(); while map.pop_first().is_some() {} map }); } #[bench] pub fn clone_slim_10k_and_remove_all(b: &mut Bencher) { let src = slim_map(10_000); b.iter(|| { let mut map = src.clone(); while let Some(elt) = map.iter().map(|(&i, _)| i).next() { let v = map.remove(&elt); debug_assert!(v.is_some()); } map }); } #[bench] pub fn clone_slim_10k_and_remove_half(b: &mut Bencher) { let src = slim_map(10_000); b.iter(|| { let mut map = src.clone(); for i in (0..10_000).step_by(2) { let v = map.remove(&i); debug_assert!(v.is_some()); } assert_eq!(map.len(), 10_000 / 2); map }) } #[bench] pub fn clone_fat_val_100(b: &mut Bencher) { let src = fat_val_map(100); b.iter(|| src.clone()) } #[bench] pub fn clone_fat_val_100_and_clear(b: &mut Bencher) { let src = fat_val_map(100); b.iter(|| src.clone().clear()) } #[bench] pub fn clone_fat_val_100_and_drain_all(b: &mut Bencher) { let src = fat_val_map(100); b.iter(|| src.clone().drain_filter(|_, _| true).count()) } #[bench] pub fn clone_fat_val_100_and_drain_half(b: &mut Bencher) { let src = fat_val_map(100); b.iter(|| { let mut map = src.clone(); assert_eq!(map.drain_filter(|i, _| i % 2 == 0).count(), 100 / 2); assert_eq!(map.len(), 100 / 2); }) } #[bench] pub fn clone_fat_val_100_and_into_iter(b: &mut Bencher) { let src = fat_val_map(100); b.iter(|| src.clone().into_iter().count()) } #[bench] pub fn clone_fat_val_100_and_pop_all(b: &mut Bencher) { let src = fat_val_map(100); b.iter(|| { let mut map = src.clone(); while map.pop_first().is_some() {} map }); } #[bench] pub fn clone_fat_val_100_and_remove_all(b: &mut Bencher) { let src = fat_val_map(100); b.iter(|| { let mut map = src.clone(); while let Some(elt) = map.iter().map(|(&i, _)| i).next() { let v = map.remove(&elt); debug_assert!(v.is_some()); } map }); } #[bench] pub fn clone_fat_val_100_and_remove_half(b: &mut Bencher) { let src = fat_val_map(100); b.iter(|| { let mut map = src.clone(); for i in (0..100).step_by(2) { let v = map.remove(&i); debug_assert!(v.is_some()); } assert_eq!(map.len(), 100 / 2); map }) }