Mirrors/servo
1
0
Fork 0
mirror of https://github.com/servo/servo.git synced 2025-06-20 07:08:59 +01:00
Code Issues Projects Releases Packages Wiki Activity
servo/components/selectors/bloom.rs
Matt Wismer 288143fadf Correct bloom hash bitpacking documentation 
The two 12 bit keys add to 24 bits, which leaves 8 bits free in each word. (And 8 * 3 = 24, to pack in the fourth hash.)
2017-06-22 21:26:14 -04:00

315 lines
8.6 KiB
Rust
Raw Blame History

/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
//! Simple counting bloom filters.
use fnv::FnvHasher;
use std::hash::{Hash, Hasher};
// The top 8 bits of the 32-bit hash value are not used by the bloom filter.
// Consumers may rely on this to pack hashes more efficiently.
pub const BLOOM_HASH_MASK: u32 = 0x00ffffff;
const KEY_SIZE: usize = 12;
const ARRAY_SIZE: usize = 1 << KEY_SIZE;
const KEY_MASK: u32 = (1 << KEY_SIZE) - 1;
/// A counting Bloom filter with 8-bit counters. For now we assume
/// that having two hash functions is enough, but we may revisit that
/// decision later.
///
/// The filter uses an array with 2**KeySize entries.
///
/// Assuming a well-distributed hash function, a Bloom filter with
/// array size M containing N elements and
/// using k hash function has expected false positive rate exactly
///
/// $ (1 - (1 - 1/M)^{kN})^k $
///
/// because each array slot has a
///
/// $ (1 - 1/M)^{kN} $
///
/// chance of being 0, and the expected false positive rate is the
/// probability that all of the k hash functions will hit a nonzero
/// slot.
///
/// For reasonable assumptions (M large, kN large, which should both
/// hold if we're worried about false positives) about M and kN this
/// becomes approximately
///
/// $$ (1 - \exp(-kN/M))^k $$
///
/// For our special case of k == 2, that's $(1 - \exp(-2N/M))^2$,
/// or in other words
///
/// $$ N/M = -0.5 * \ln(1 - \sqrt(r)) $$
///
/// where r is the false positive rate. This can be used to compute
/// the desired KeySize for a given load N and false positive rate r.
///
/// If N/M is assumed small, then the false positive rate can
/// further be approximated as 4*N^2/M^2. So increasing KeySize by
/// 1, which doubles M, reduces the false positive rate by about a
/// factor of 4, and a false positive rate of 1% corresponds to
/// about M/N == 20.
///
/// What this means in practice is that for a few hundred keys using a
/// KeySize of 12 gives false positive rates on the order of 0.25-4%.
///
/// Similarly, using a KeySize of 10 would lead to a 4% false
/// positive rate for N == 100 and to quite bad false positive
/// rates for larger N.
pub struct BloomFilter {
counters: [u8; ARRAY_SIZE],
}
impl Clone for BloomFilter {
#[inline]
fn clone(&self) -> BloomFilter {
BloomFilter {
counters: self.counters,
}
}
}
impl BloomFilter {
/// Creates a new bloom filter.
#[inline]
pub fn new() -> BloomFilter {
BloomFilter {
counters: [0; ARRAY_SIZE],
}
}
#[inline]
fn first_slot(&self, hash: u32) -> &u8 {
&self.counters[hash1(hash) as usize]
}
#[inline]
fn first_mut_slot(&mut self, hash: u32) -> &mut u8 {
&mut self.counters[hash1(hash) as usize]
}
#[inline]
fn second_slot(&self, hash: u32) -> &u8 {
&self.counters[hash2(hash) as usize]
}
#[inline]
fn second_mut_slot(&mut self, hash: u32) -> &mut u8 {
&mut self.counters[hash2(hash) as usize]
}
#[inline]
pub fn clear(&mut self) {
self.counters = [0; ARRAY_SIZE]
}
// Slow linear accessor to make sure the bloom filter is zeroed. This should
// never be used in release builds.
#[cfg(debug_assertions)]
pub fn is_zeroed(&self) -> bool {
self.counters.iter().all(|x| *x == 0)
}
#[cfg(not(debug_assertions))]
pub fn is_zeroed(&self) -> bool {
unreachable!()
}
#[inline]
pub fn insert_hash(&mut self, hash: u32) {
{
let slot1 = self.first_mut_slot(hash);
if !full(slot1) {
*slot1 += 1
}
}
{
let slot2 = self.second_mut_slot(hash);
if !full(slot2) {
*slot2 += 1
}
}
}
/// Inserts an item into the bloom filter.
#[inline]
pub fn insert<T: Hash>(&mut self, elem: &T) {
self.insert_hash(hash(elem))
}
#[inline]
pub fn remove_hash(&mut self, hash: u32) {
{
let slot1 = self.first_mut_slot(hash);
if !full(slot1) {
*slot1 -= 1
}
}
{
let slot2 = self.second_mut_slot(hash);
if !full(slot2) {
*slot2 -= 1
}
}
}
/// Removes an item from the bloom filter.
#[inline]
pub fn remove<T: Hash>(&mut self, elem: &T) {
self.remove_hash(hash(elem))
}
#[inline]
pub fn might_contain_hash(&self, hash: u32) -> bool {
*self.first_slot(hash) != 0 && *self.second_slot(hash) != 0
}
/// Check whether the filter might contain an item. This can
/// sometimes return true even if the item is not in the filter,
/// but will never return false for items that are actually in the
/// filter.
#[inline]
pub fn might_contain<T: Hash>(&self, elem: &T) -> bool {
self.might_contain_hash(hash(elem))
}
}
#[inline]
fn full(slot: &u8) -> bool {
*slot == 0xff
}
fn hash<T: Hash>(elem: &T) -> u32 {
let mut hasher = FnvHasher::default();
elem.hash(&mut hasher);
let hash: u64 = hasher.finish();
(hash >> 32) as u32 ^ (hash as u32)
}
#[inline]
fn hash1(hash: u32) -> u32 {
hash & KEY_MASK
}
#[inline]
fn hash2(hash: u32) -> u32 {
(hash >> KEY_SIZE) & KEY_MASK
}
#[test]
fn create_and_insert_some_stuff() {
let mut bf = BloomFilter::new();
for i in 0_usize .. 1000 {
bf.insert(&i);
}
for i in 0_usize .. 1000 {
assert!(bf.might_contain(&i));
}
let false_positives =
(1001_usize .. 2000).filter(|i| bf.might_contain(i)).count();
assert!(false_positives < 150, "{} is not < 150", false_positives); // 15%.
for i in 0_usize .. 100 {
bf.remove(&i);
}
for i in 100_usize .. 1000 {
assert!(bf.might_contain(&i));
}
let false_positives = (0_usize .. 100).filter(|i| bf.might_contain(i)).count();
assert!(false_positives < 20, "{} is not < 20", false_positives); // 20%.
bf.clear();
for i in 0_usize .. 2000 {
assert!(!bf.might_contain(&i));
}
}
#[cfg(feature = "unstable")]
#[cfg(test)]
mod bench {
extern crate test;
use super::BloomFilter;
#[derive(Default)]
struct HashGenerator(u32);
impl HashGenerator {
fn next(&mut self) -> u32 {
// Each hash is split into two twelve-bit segments, which are used
// as an index into an array. We increment each by 64 so that we
// hit the next cache line, and then another 1 so that our wrapping
// behavior leads us to different entries each time.
//
// Trying to simulate cold caches is rather difficult with the cargo
// benchmarking setup, so it may all be moot depending on the number
// of iterations that end up being run. But we might as well.
self.0 += (65) + (65 << super::KEY_SIZE);
self.0
}
}
#[bench]
fn create_insert_1000_remove_100_lookup_100(b: &mut test::Bencher) {
b.iter(|| {
let mut gen1 = HashGenerator::default();
let mut gen2 = HashGenerator::default();
let mut bf = BloomFilter::new();
for _ in 0_usize .. 1000 {
bf.insert_hash(gen1.next());
}
for _ in 0_usize .. 100 {
bf.remove_hash(gen2.next());
}
for _ in 100_usize .. 200 {
test::black_box(bf.might_contain_hash(gen2.next()));
}
});
}
#[bench]
fn might_contain_10(b: &mut test::Bencher) {
let bf = BloomFilter::new();
let mut gen = HashGenerator::default();
b.iter(|| for _ in 0..10 {
test::black_box(bf.might_contain_hash(gen.next()));
});
}
#[bench]
fn clear(b: &mut test::Bencher) {
let mut bf = Box::new(BloomFilter::new());
b.iter(|| test::black_box(&mut bf).clear());
}
#[bench]
fn insert_10(b: &mut test::Bencher) {
let mut bf = BloomFilter::new();
let mut gen = HashGenerator::default();
b.iter(|| for _ in 0..10 {
test::black_box(bf.insert_hash(gen.next()));
});
}
#[bench]
fn remove_10(b: &mut test::Bencher) {
let mut bf = BloomFilter::new();
let mut gen = HashGenerator::default();
// Note: this will underflow, and that's ok.
b.iter(|| for _ in 0..10 {
bf.remove_hash(gen.next())
});
}
}
Reference in a new issue View git blame Copy permalink