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/*
* Copyright 2015 Ben Manes. All Rights Reserved.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package com.github.benmanes.caffeine.cache;
import static com.github.benmanes.caffeine.cache.Caffeine.requireArgument;
import org.checkerframework.checker.index.qual.NonNegative;
/**
* A probabilistic multiset for estimating the popularity of an element within a time window. The
* maximum frequency of an element is limited to 15 (4-bits) and an aging process periodically
* halves the popularity of all elements.
*
* @author [email protected] (Ben Manes)
*/
final class FrequencySketch {
/*
* This class maintains a 4-bit CountMinSketch [1] with periodic aging to provide the popularity
* history for the TinyLfu admission policy [2]. The time and space efficiency of the sketch
* allows it to cheaply estimate the frequency of an entry in a stream of cache access events.
*
* The counter matrix is represented as a single-dimensional array holding 16 counters per slot. A
* fixed depth of four balances the accuracy and cost, resulting in a width of four times the
* length of the array. To retain an accurate estimation, the array's length equals the maximum
* number of entries in the cache, increased to the closest power-of-two to exploit more efficient
* bit masking. This configuration results in a confidence of 93.75% and an error bound of
* e / width.
*
* To improve hardware efficiency, an item's counters are constrained to a 64-byte block, which is
* the size of an L1 cache line. This differs from the theoretical ideal where counters are
* uniformly distributed to minimize collisions. In that configuration, the memory accesses are
* not predictable and lack spatial locality, which may cause the pipeline to need to wait for
* four memory loads. Instead, the items are uniformly distributed to blocks, and each counter is
* uniformly selected from a distinct 16-byte segment. While the runtime memory layout may result
* in the blocks not being cache-aligned, the L2 spatial prefetcher tries to load aligned pairs of
* cache lines, so the typical cost is only one memory access.
*
* The frequency of all entries is aged periodically using a sampling window based on the maximum
* number of entries in the cache. This is referred to as the reset operation by TinyLfu and keeps
* the sketch fresh by dividing all counters by two and subtracting based on the number of odd
* counters found. The O(n) cost of aging is amortized, ideal for hardware prefetching, and uses
* inexpensive bit manipulations per array location.
*
* [1] An Improved Data Stream Summary: The Count-Min Sketch and its Applications
* http://dimacs.rutgers.edu/~graham/pubs/papers/cm-full.pdf
* [2] TinyLFU: A Highly Efficient Cache Admission Policy
* https://dl.acm.org/citation.cfm?id=3149371
* [3] Hash Function Prospector: Three round functions
* https://github.com/skeeto/hash-prospector#three-round-functions
*/
static final long RESET_MASK = 0x7777777777777777L;
static final long ONE_MASK = 0x1111111111111111L;
int sampleSize;
int blockMask;
long[] table;
int size;
/**
* Creates a lazily initialized frequency sketch, requiring {@link #ensureCapacity} be called
* when the maximum size of the cache has been determined.
*/
@SuppressWarnings("NullAway.Init")
public FrequencySketch() {}
/**
* Initializes and increases the capacity of this FrequencySketch instance, if necessary,
* to ensure that it can accurately estimate the popularity of elements given the maximum size of
* the cache. This operation forgets all previous counts when resizing.
*
* @param maximumSize the maximum size of the cache
*/
public void ensureCapacity(@NonNegative long maximumSize) {
requireArgument(maximumSize >= 0);
int maximum = (int) Math.min(maximumSize, Integer.MAX_VALUE >>> 1);
if ((table != null) && (table.length >= maximum)) {
return;
}
table = new long[Math.max(Caffeine.ceilingPowerOfTwo(maximum), 8)];
sampleSize = (maximumSize == 0) ? 10 : (10 * maximum);
blockMask = (table.length >>> 3) - 1;
if (sampleSize <= 0) {
sampleSize = Integer.MAX_VALUE;
}
size = 0;
}
/**
* Returns if the sketch has not yet been initialized, requiring that {@link #ensureCapacity} is
* called before it begins to track frequencies.
*/
public boolean isNotInitialized() {
return (table == null);
}
/**
* Returns the estimated number of occurrences of an element, up to the maximum (15).
*
* @param e the element to count occurrences of
* @return the estimated number of occurrences of the element; possibly zero but never negative
*/
@NonNegative
public int frequency(E e) {
if (isNotInitialized()) {
return 0;
}
int[] count = new int[4];
int blockHash = spread(e.hashCode());
int counterHash = rehash(blockHash);
int block = (blockHash & blockMask) << 3;
for (int i = 0; i < 4; i++) {
int h = counterHash >>> (i << 3);
int index = (h >>> 1) & 15;
int offset = h & 1;
count[i] = (int) ((table[block + offset + (i << 1)] >>> (index << 2)) & 0xfL);
}
return Math.min(Math.min(count[0], count[1]), Math.min(count[2], count[3]));
}
/**
* Increments the popularity of the element if it does not exceed the maximum (15). The popularity
* of all elements will be periodically down sampled when the observed events exceed a threshold.
* This process provides a frequency aging to allow expired long term entries to fade away.
*
* @param e the element to add
*/
@SuppressWarnings("ShortCircuitBoolean")
public void increment(E e) {
if (isNotInitialized()) {
return;
}
int[] index = new int[8];
int blockHash = spread(e.hashCode());
int counterHash = rehash(blockHash);
int block = (blockHash & blockMask) << 3;
for (int i = 0; i < 4; i++) {
int h = counterHash >>> (i << 3);
index[i] = (h >>> 1) & 15;
int offset = h & 1;
index[i + 4] = block + offset + (i << 1);
}
boolean added =
incrementAt(index[4], index[0])
| incrementAt(index[5], index[1])
| incrementAt(index[6], index[2])
| incrementAt(index[7], index[3]);
if (added && (++size == sampleSize)) {
reset();
}
}
/** Applies a supplemental hash functions to defends against poor quality hash. */
static int spread(int x) {
x ^= x >>> 17;
x *= 0xed5ad4bb;
x ^= x >>> 11;
x *= 0xac4c1b51;
x ^= x >>> 15;
return x;
}
/** Applies another round of hashing for additional randomization. */
static int rehash(int x) {
x *= 0x31848bab;
x ^= x >>> 14;
return x;
}
/**
* Increments the specified counter by 1 if it is not already at the maximum value (15).
*
* @param i the table index (16 counters)
* @param j the counter to increment
* @return if incremented
*/
boolean incrementAt(int i, int j) {
int offset = j << 2;
long mask = (0xfL << offset);
if ((table[i] & mask) != mask) {
table[i] += (1L << offset);
return true;
}
return false;
}
/** Reduces every counter by half of its original value. */
void reset() {
int count = 0;
for (int i = 0; i < table.length; i++) {
count += Long.bitCount(table[i] & ONE_MASK);
table[i] = (table[i] >>> 1) & RESET_MASK;
}
size = (size - (count >>> 2)) >>> 1;
}
}
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