/* * Copyright (C) 1996-2018 The Squid Software Foundation and contributors * * Squid software is distributed under GPLv2+ license and includes * contributions from numerous individuals and organizations. * Please see the COPYING and CONTRIBUTORS files for details. */ /* DEBUG: section 20 Storage Manager Heap-based replacement */ /* * The code in this file is Copyrighted (C) 1999 by Hewlett Packard. * * * For a description of these cache replacement policies see -- * http://www.hpl.hp.com/techreports/1999/HPL-1999-69.html */ #include "squid.h" #include "heap.h" #include "MemObject.h" #include "SquidTime.h" #include "Store.h" #include "store_heap_replacement.h" #include /* * Key generation function to implement the LFU-DA policy (Least * Frequently Used with Dynamic Aging). Similar to classical LFU * but with aging to handle turnover of the popular document set. * Maximizes byte hit rate by keeping more currently popular objects * in cache regardless of size. Achieves lower hit rate than GDS * because there are more large objects in cache (so less room for * smaller popular objects). * * This version implements a tie-breaker based upon recency * (e->lastref): for objects that have the same reference count * the most recent object wins (gets a higher key value). * * Note: this does not properly handle when the aging factor * gets so huge that the added value is outside of the * precision of double. However, Squid has to stay up * for quite a extended period of time (number of requests) * for this to become a problem. (estimation is 10^8 cache * turnarounds) */ heap_key HeapKeyGen_StoreEntry_LFUDA(void *entry, double heap_age) { StoreEntry *e = (StoreEntry *)entry; heap_key key; double tie; if (e->lastref <= 0) tie = 0.0; else if (squid_curtime <= e->lastref) tie = 0.0; else tie = 1.0 - exp((double) (e->lastref - squid_curtime) / 86400.0); key = heap_age + (double) e->refcount - tie; debugs(81, 3, "HeapKeyGen_StoreEntry_LFUDA: " << e->getMD5Text() << " refcnt=" << e->refcount << " lastref=" << e->lastref << " heap_age=" << heap_age << " tie=" << tie << " -> " << key); if (e->mem_obj) debugs(81, 3, "storeId=" << e->mem_obj->storeId()); return (double) key; } /* * Key generation function to implement the GDS-Frequency policy. * Similar to Greedy Dual-Size Hits policy, but adds aging of * documents to prevent pollution. Maximizes object hit rate by * keeping more small, popular objects in cache. Achieves lower * byte hit rate than LFUDA because there are fewer large objects * in cache. * * This version implements a tie-breaker based upon recency * (e->lastref): for objects that have the same reference count * the most recent object wins (gets a higher key value). * * Note: this does not properly handle when the aging factor * gets so huge that the added value is outside of the * precision of double. However, Squid has to stay up * for quite a extended period of time (number of requests) * for this to become a problem. (estimation is 10^8 cache * turnarounds) */ heap_key HeapKeyGen_StoreEntry_GDSF(void *entry, double heap_age) { StoreEntry *e = (StoreEntry *)entry; heap_key key; double size = e->swap_file_sz ? (double) e->swap_file_sz : 1.0; double tie = (e->lastref > 1) ? (1.0 / e->lastref) : 1.0; key = heap_age + ((double) e->refcount / size) - tie; debugs(81, 3, "HeapKeyGen_StoreEntry_GDSF: " << e->getMD5Text() << " size=" << size << " refcnt=" << e->refcount << " lastref=" << e->lastref << " heap_age=" << heap_age << " tie=" << tie << " -> " << key); if (e->mem_obj) debugs(81, 3, "storeId=" << e->mem_obj->storeId()); return key; } /* * Key generation function to implement the LRU policy. Normally * one would not do this with a heap -- use the linked list instead. * For testing and performance characterization it was useful. * Don't use it unless you are trying to compare performance among * heap-based replacement policies... */ heap_key HeapKeyGen_StoreEntry_LRU(void *entry, double heap_age) { StoreEntry *e = (StoreEntry *)entry; debugs(81, 3, "HeapKeyGen_StoreEntry_LRU: " << e->getMD5Text() << " heap_age=" << heap_age << " lastref=" << (double) e->lastref ); if (e->mem_obj) debugs(81, 3, "storeId=" << e->mem_obj->storeId()); return (heap_key) e->lastref; }