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1 /* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
2 /* vim: set ts=8 sts=2 et sw=2 tw=80: */
3 /* This Source Code Form is subject to the terms of the Mozilla Public
4 * License, v. 2.0. If a copy of the MPL was not distributed with this
5 * file, You can obtain one at http://mozilla.org/MPL/2.0/. */
7 /*
8 * A counting Bloom filter implementation. This allows consumers to
9 * do fast probabilistic "is item X in set Y?" testing which will
10 * never answer "no" when the correct answer is "yes" (but might
11 * incorrectly answer "yes" when the correct answer is "no").
12 */
14 #ifndef mozilla_BloomFilter_h
15 #define mozilla_BloomFilter_h
20 #include <stdint.h>
21 #include <string.h>
25 /*
26 * This class implements a classic Bloom filter as described at
27 * <http://en.wikipedia.org/wiki/Bloom_filter>. This allows quick
28 * probabilistic answers to the question "is object X in set Y?" where the
29 * contents of Y might not be time-invariant. The probabilistic nature of the
30 * test means that sometimes the answer will be "yes" when it should be "no".
31 * If the answer is "no", then X is guaranteed not to be in Y.
32 *
33 * The filter is parametrized on KeySize, which is the size of the key
34 * generated by each of hash functions used by the filter, in bits,
35 * and the type of object T being added and removed. T must implement
36 * a |uint32_t hash() const| method which returns a uint32_t hash key
37 * that will be used to generate the two separate hash functions for
38 * the Bloom filter. This hash key MUST be well-distributed for good
39 * results! KeySize is not allowed to be larger than 16.
40 *
41 * The filter uses exactly 2**KeySize bit (2**(KeySize-3) bytes) of memory.
42 * From now on we will refer to the memory used by the filter as M.
43 *
44 * The expected rate of incorrect "yes" answers depends on M and on
45 * the number N of objects in set Y. As long as N is small compared
46 * to M, the rate of such answers is expected to be approximately
47 * 4*(N/M)**2 for this filter. In practice, if Y has a few hundred
48 * elements then using a KeySize of 12 gives a reasonably low
49 * incorrect answer rate. A KeySize of 12 has the additional benefit
50 * of using exactly one page for the filter in typical hardware
51 * configurations.
52 */
55 /*
56 * A counting Bloom filter with 8-bit counters. For now we assume
57 * that having two hash functions is enough, but we may revisit that
58 * decision later.
59 *
60 * The filter uses an array with 2**KeySize entries.
61 *
62 * Assuming a well-distributed hash function, a Bloom filter with
63 * array size M containing N elements and
64 * using k hash function has expected false positive rate exactly
65 *
66 * $ (1 - (1 - 1/M)^{kN})^k $
67 *
68 * because each array slot has a
69 *
70 * $ (1 - 1/M)^{kN} $
71 *
72 * chance of being 0, and the expected false positive rate is the
73 * probability that all of the k hash functions will hit a nonzero
74 * slot.
75 *
76 * For reasonable assumptions (M large, kN large, which should both
77 * hold if we're worried about false positives) about M and kN this
78 * becomes approximately
79 *
80 * $$ (1 - \exp(-kN/M))^k $$
81 *
82 * For our special case of k == 2, that's $(1 - \exp(-2N/M))^2$,
83 * or in other words
84 *
85 * $$ N/M = -0.5 * \ln(1 - \sqrt(r)) $$
86 *
87 * where r is the false positive rate. This can be used to compute
88 * the desired KeySize for a given load N and false positive rate r.
89 *
90 * If N/M is assumed small, then the false positive rate can
91 * further be approximated as 4*N^2/M^2. So increasing KeySize by
92 * 1, which doubles M, reduces the false positive rate by about a
93 * factor of 4, and a false positive rate of 1% corresponds to
94 * about M/N == 20.
95 *
96 * What this means in practice is that for a few hundred keys using a
97 * KeySize of 12 gives false positive rates on the order of 0.25-4%.
98 *
99 * Similarly, using a KeySize of 10 would lead to a 4% false
100 * positive rate for N == 100 and to quite bad false positive
101 * rates for larger N.
102 */
108 // XXX: Should we have a custom operator new using calloc instead and
109 // require that we're allocated via the operator?
111 }
113 /*
114 * Clear the filter. This should be done before reusing it.
115 */
118 /*
119 * Add an item to the filter.
120 */
123 /*
124 * Check whether the filter might contain an item. This can
125 * sometimes return true even if the item is not in the filter,
126 * but will never return false for items that are actually in the
127 * filter.
128 */
131 /*
132 * Methods for add/contain when we already have a hash computed
133 */
145 }
152 }
159 }
168 };
173 }
179 }
185 }
190 // Check that all the slots for this hash contain something
192 }
199 }
201 /*
202 * This class implements a counting Bloom filter as described at
203 * <http://en.wikipedia.org/wiki/Bloom_filter#Counting_filters>, with
204 * 8-bit counters.
205 *
206 * Compared to `BitBloomFilter`, this class supports 'remove' operation.
207 *
208 * The filter uses exactly 2**KeySize bytes of memory.
209 *
210 * Other characteristics are the same as BitBloomFilter.
211 */
219 }
221 /*
222 * Clear the filter. This should be done before reusing it, because
223 * just removing all items doesn't clear counters that hit the upper
224 * bound.
225 */
228 /*
229 * Add an item to the filter.
230 */
233 /*
234 * Remove an item from the filter.
235 */
238 /*
239 * Check whether the filter might contain an item. This can
240 * sometimes return true even if the item is not in the filter,
241 * but will never return false for items that are actually in the
242 * filter.
243 */
246 /*
247 * Methods for add/remove/contain when we already have a hash computed
248 */
261 }
268 }
271 }
276 };
281 }
288 }
292 }
293 }
299 }
303 // If the slots are full, we don't know whether we bumped them to be
304 // there when we added or not, so just leave them full.
308 }
312 }
313 }
320 }
325 // Check that all the slots for this hash contain something
327 }
334 }