use std::{mem, ptr}; use rand::distributions::{Alphanumeric, Standard}; use rand::Rng; use test::{black_box, Bencher}; #[bench] fn iterator(b: &mut Bencher) { // peculiar numbers to stop LLVM from optimising the summation // out. let v: Vec<_> = (0..100).map(|i| i ^ (i << 1) ^ (i >> 1)).collect(); b.iter(|| { let mut sum = 0; for x in &v { sum += *x; } // sum == 11806, to stop dead code elimination. if sum == 0 { panic!() } }) } #[bench] fn mut_iterator(b: &mut Bencher) { let mut v = vec![0; 100]; b.iter(|| { let mut i = 0; for x in &mut v { *x = i; i += 1; } }) } #[bench] fn concat(b: &mut Bencher) { let xss: Vec> = (0..100).map(|i| (0..i).collect()).collect(); b.iter(|| { xss.concat(); }); } #[bench] fn join(b: &mut Bencher) { let xss: Vec> = (0..100).map(|i| (0..i).collect()).collect(); b.iter(|| xss.join(&0)); } #[bench] fn push(b: &mut Bencher) { let mut vec = Vec::::new(); b.iter(|| { vec.push(0); black_box(&vec); }); } #[bench] fn starts_with_same_vector(b: &mut Bencher) { let vec: Vec<_> = (0..100).collect(); b.iter(|| vec.starts_with(&vec)) } #[bench] fn starts_with_single_element(b: &mut Bencher) { let vec: Vec<_> = vec![0]; b.iter(|| vec.starts_with(&vec)) } #[bench] fn starts_with_diff_one_element_at_end(b: &mut Bencher) { let vec: Vec<_> = (0..100).collect(); let mut match_vec: Vec<_> = (0..99).collect(); match_vec.push(0); b.iter(|| vec.starts_with(&match_vec)) } #[bench] fn ends_with_same_vector(b: &mut Bencher) { let vec: Vec<_> = (0..100).collect(); b.iter(|| vec.ends_with(&vec)) } #[bench] fn ends_with_single_element(b: &mut Bencher) { let vec: Vec<_> = vec![0]; b.iter(|| vec.ends_with(&vec)) } #[bench] fn ends_with_diff_one_element_at_beginning(b: &mut Bencher) { let vec: Vec<_> = (0..100).collect(); let mut match_vec: Vec<_> = (0..100).collect(); match_vec[0] = 200; b.iter(|| vec.starts_with(&match_vec)) } #[bench] fn contains_last_element(b: &mut Bencher) { let vec: Vec<_> = (0..100).collect(); b.iter(|| vec.contains(&99)) } #[bench] fn zero_1kb_from_elem(b: &mut Bencher) { b.iter(|| vec![0u8; 1024]); } #[bench] fn zero_1kb_set_memory(b: &mut Bencher) { b.iter(|| { let mut v = Vec::::with_capacity(1024); unsafe { let vp = v.as_mut_ptr(); ptr::write_bytes(vp, 0, 1024); v.set_len(1024); } v }); } #[bench] fn zero_1kb_loop_set(b: &mut Bencher) { b.iter(|| { let mut v = Vec::::with_capacity(1024); unsafe { v.set_len(1024); } for i in 0..1024 { v[i] = 0; } }); } #[bench] fn zero_1kb_mut_iter(b: &mut Bencher) { b.iter(|| { let mut v = Vec::::with_capacity(1024); unsafe { v.set_len(1024); } for x in &mut v { *x = 0; } v }); } #[bench] fn random_inserts(b: &mut Bencher) { let mut rng = crate::bench_rng(); b.iter(|| { let mut v = vec![(0, 0); 30]; for _ in 0..100 { let l = v.len(); v.insert(rng.gen::() % (l + 1), (1, 1)); } }) } #[bench] fn random_removes(b: &mut Bencher) { let mut rng = crate::bench_rng(); b.iter(|| { let mut v = vec![(0, 0); 130]; for _ in 0..100 { let l = v.len(); v.remove(rng.gen::() % l); } }) } fn gen_ascending(len: usize) -> Vec { (0..len as u64).collect() } fn gen_descending(len: usize) -> Vec { (0..len as u64).rev().collect() } fn gen_random(len: usize) -> Vec { let mut rng = crate::bench_rng(); (&mut rng).sample_iter(&Standard).take(len).collect() } fn gen_random_bytes(len: usize) -> Vec { let mut rng = crate::bench_rng(); (&mut rng).sample_iter(&Standard).take(len).collect() } fn gen_mostly_ascending(len: usize) -> Vec { let mut rng = crate::bench_rng(); let mut v = gen_ascending(len); for _ in (0usize..).take_while(|x| x * x <= len) { let x = rng.gen::() % len; let y = rng.gen::() % len; v.swap(x, y); } v } fn gen_mostly_descending(len: usize) -> Vec { let mut rng = crate::bench_rng(); let mut v = gen_descending(len); for _ in (0usize..).take_while(|x| x * x <= len) { let x = rng.gen::() % len; let y = rng.gen::() % len; v.swap(x, y); } v } fn gen_strings(len: usize) -> Vec { let mut rng = crate::bench_rng(); let mut v = vec![]; for _ in 0..len { let n = rng.gen::() % 20 + 1; v.push((&mut rng).sample_iter(&Alphanumeric).take(n).collect()); } v } fn gen_big_random(len: usize) -> Vec<[u64; 16]> { let mut rng = crate::bench_rng(); (&mut rng).sample_iter(&Standard).map(|x| [x; 16]).take(len).collect() } macro_rules! sort { ($f:ident, $name:ident, $gen:expr, $len:expr) => { #[bench] fn $name(b: &mut Bencher) { let v = $gen($len); b.iter(|| v.clone().$f()); b.bytes = $len * mem::size_of_val(&$gen(1)[0]) as u64; } }; } macro_rules! sort_strings { ($f:ident, $name:ident, $gen:expr, $len:expr) => { #[bench] fn $name(b: &mut Bencher) { let v = $gen($len); let v = v.iter().map(|s| &**s).collect::>(); b.iter(|| v.clone().$f()); b.bytes = $len * mem::size_of::<&str>() as u64; } }; } macro_rules! sort_expensive { ($f:ident, $name:ident, $gen:expr, $len:expr) => { #[bench] fn $name(b: &mut Bencher) { let v = $gen($len); b.iter(|| { let mut v = v.clone(); let mut count = 0; v.$f(|a: &u64, b: &u64| { count += 1; if count % 1_000_000_000 == 0 { panic!("should not happen"); } (*a as f64).cos().partial_cmp(&(*b as f64).cos()).unwrap() }); black_box(count); }); b.bytes = $len * mem::size_of_val(&$gen(1)[0]) as u64; } }; } macro_rules! sort_lexicographic { ($f:ident, $name:ident, $gen:expr, $len:expr) => { #[bench] fn $name(b: &mut Bencher) { let v = $gen($len); b.iter(|| v.clone().$f(|x| x.to_string())); b.bytes = $len * mem::size_of_val(&$gen(1)[0]) as u64; } }; } sort!(sort, sort_small_ascending, gen_ascending, 10); sort!(sort, sort_small_descending, gen_descending, 10); sort!(sort, sort_small_random, gen_random, 10); sort!(sort, sort_small_big, gen_big_random, 10); sort!(sort, sort_medium_random, gen_random, 100); sort!(sort, sort_large_ascending, gen_ascending, 10000); sort!(sort, sort_large_descending, gen_descending, 10000); sort!(sort, sort_large_mostly_ascending, gen_mostly_ascending, 10000); sort!(sort, sort_large_mostly_descending, gen_mostly_descending, 10000); sort!(sort, sort_large_random, gen_random, 10000); sort!(sort, sort_large_big, gen_big_random, 10000); sort_strings!(sort, sort_large_strings, gen_strings, 10000); sort_expensive!(sort_by, sort_large_expensive, gen_random, 10000); sort!(sort_unstable, sort_unstable_small_ascending, gen_ascending, 10); sort!(sort_unstable, sort_unstable_small_descending, gen_descending, 10); sort!(sort_unstable, sort_unstable_small_random, gen_random, 10); sort!(sort_unstable, sort_unstable_small_big, gen_big_random, 10); sort!(sort_unstable, sort_unstable_medium_random, gen_random, 100); sort!(sort_unstable, sort_unstable_large_ascending, gen_ascending, 10000); sort!(sort_unstable, sort_unstable_large_descending, gen_descending, 10000); sort!(sort_unstable, sort_unstable_large_mostly_ascending, gen_mostly_ascending, 10000); sort!(sort_unstable, sort_unstable_large_mostly_descending, gen_mostly_descending, 10000); sort!(sort_unstable, sort_unstable_large_random, gen_random, 10000); sort!(sort_unstable, sort_unstable_large_big, gen_big_random, 10000); sort_strings!(sort_unstable, sort_unstable_large_strings, gen_strings, 10000); sort_expensive!(sort_unstable_by, sort_unstable_large_expensive, gen_random, 10000); sort_lexicographic!(sort_by_key, sort_by_key_lexicographic, gen_random, 10000); sort_lexicographic!(sort_unstable_by_key, sort_unstable_by_key_lexicographic, gen_random, 10000); sort_lexicographic!(sort_by_cached_key, sort_by_cached_key_lexicographic, gen_random, 10000); macro_rules! reverse { ($name:ident, $ty:ty, $f:expr) => { #[bench] fn $name(b: &mut Bencher) { // odd length and offset by 1 to be as unaligned as possible let n = 0xFFFFF; let mut v: Vec<_> = (0..1 + (n / mem::size_of::<$ty>() as u64)).map($f).collect(); b.iter(|| black_box(&mut v[1..]).reverse()); b.bytes = n; } }; } reverse!(reverse_u8, u8, |x| x as u8); reverse!(reverse_u16, u16, |x| x as u16); reverse!(reverse_u8x3, [u8; 3], |x| [x as u8, (x >> 8) as u8, (x >> 16) as u8]); reverse!(reverse_u32, u32, |x| x as u32); reverse!(reverse_u64, u64, |x| x as u64); reverse!(reverse_u128, u128, |x| x as u128); #[repr(simd)] struct F64x4(f64, f64, f64, f64); reverse!(reverse_simd_f64x4, F64x4, |x| { let x = x as f64; F64x4(x, x, x, x) }); macro_rules! rotate { ($name:ident, $gen:expr, $len:expr, $mid:expr) => { #[bench] fn $name(b: &mut Bencher) { let size = mem::size_of_val(&$gen(1)[0]); let mut v = $gen($len * 8 / size); b.iter(|| black_box(&mut v).rotate_left(($mid * 8 + size - 1) / size)); b.bytes = (v.len() * size) as u64; } }; } rotate!(rotate_tiny_by1, gen_random, 16, 1); rotate!(rotate_tiny_half, gen_random, 16, 16 / 2); rotate!(rotate_tiny_half_plus_one, gen_random, 16, 16 / 2 + 1); rotate!(rotate_medium_by1, gen_random, 9158, 1); rotate!(rotate_medium_by727_u64, gen_random, 9158, 727); rotate!(rotate_medium_by727_bytes, gen_random_bytes, 9158, 727); rotate!(rotate_medium_by727_strings, gen_strings, 9158, 727); rotate!(rotate_medium_half, gen_random, 9158, 9158 / 2); rotate!(rotate_medium_half_plus_one, gen_random, 9158, 9158 / 2 + 1); // Intended to use more RAM than the machine has cache rotate!(rotate_huge_by1, gen_random, 5 * 1024 * 1024, 1); rotate!(rotate_huge_by9199_u64, gen_random, 5 * 1024 * 1024, 9199); rotate!(rotate_huge_by9199_bytes, gen_random_bytes, 5 * 1024 * 1024, 9199); rotate!(rotate_huge_by9199_strings, gen_strings, 5 * 1024 * 1024, 9199); rotate!(rotate_huge_by9199_big, gen_big_random, 5 * 1024 * 1024, 9199); rotate!(rotate_huge_by1234577_u64, gen_random, 5 * 1024 * 1024, 1234577); rotate!(rotate_huge_by1234577_bytes, gen_random_bytes, 5 * 1024 * 1024, 1234577); rotate!(rotate_huge_by1234577_strings, gen_strings, 5 * 1024 * 1024, 1234577); rotate!(rotate_huge_by1234577_big, gen_big_random, 5 * 1024 * 1024, 1234577); rotate!(rotate_huge_half, gen_random, 5 * 1024 * 1024, 5 * 1024 * 1024 / 2); rotate!(rotate_huge_half_plus_one, gen_random, 5 * 1024 * 1024, 5 * 1024 * 1024 / 2 + 1);