/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2014 by Michael Sevakis * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include "config.h" #include "debug.h" #include "system.h" #include "linked_list.h" #include "disk_cache.h" #include "fs_defines.h" #include "bitarray.h" /* Cache: LRU cache with separately-chained hashtable * * Each entry of the map is the mapped location of the hashed sector value * where each bit in each map entry indicates which corresponding cache * entries are occupied by sector values that collide in that map entry. * * Each volume is given its own bit map. * * To probe for a specific key, each bit in the map entry must be examined, * its position used as an index into the cache_entry array and the actual * sector information compared for that cache entry. If the search exhausts * all bits, the sector is not cached. * * To avoid long chains, the map entry count should be much greater than the * number of cache entries. Since the cache is an LRU design, no buffer entry * in the array is intrinsically associated with any particular sector number * or volume. * * Example 6-sector cache with 8-entry map: * cache entry 543210 * cache map 100000 <- sector number hashes into map * 000000 * 000100 * 000000 * 010000 * 000000 * 001001 <- collision * 000000 * volume map 111101 <- entry usage by the volume (OR of all map entries) */ enum dce_flags /* flags for each cache entry */ { DCE_INUSE = 0x01, /* entry in use and valid */ DCE_DIRTY = 0x02, /* entry is dirty in need of writeback */ DCE_BUF = 0x04, /* entry is being used as a general buffer */ }; struct disk_cache_entry { struct lldc_node node; /* LRU list links */ unsigned char flags; /* entry flags */ #ifdef HAVE_MULTIVOLUME unsigned char volume; /* volume of sector */ #endif unsigned long sector; /* cached disk sector number */ }; BITARRAY_TYPE_DECLARE(cache_map_entry_t, cache_map, DC_NUM_ENTRIES) static inline unsigned int map_sector(unsigned long sector) { /* keep sector hash simple for now */ return sector % DC_MAP_NUM_ENTRIES; } static struct lldc_head cache_lru; /* LRU cache list (head = LRU item) */ static struct disk_cache_entry cache_entry[DC_NUM_ENTRIES]; static cache_map_entry_t cache_map_entry[NUM_VOLUMES][DC_MAP_NUM_ENTRIES]; static cache_map_entry_t cache_vol_map[NUM_VOLUMES] IBSS_ATTR; static uint8_t cache_buffer[DC_NUM_ENTRIES][DC_CACHE_BUFSIZE] CACHEALIGN_ATTR; struct mutex disk_cache_mutex SHAREDBSS_ATTR; #define CACHE_MAP_ENTRY(volume, mapnum) \ cache_map_entry[IF_MV_VOL(volume)][mapnum] #define CACHE_VOL_MAP(volume) \ cache_vol_map[IF_MV_VOL(volume)] #define DCE_LRU() ((struct disk_cache_entry *)cache_lru.head) #define DCE_NEXT(fce) ((struct disk_cache_entry *)(fce)->node.next) #define NODE_DCE(node) ((struct disk_cache_entry *)(node)) /* get the cache index from a pointer to a buffer */ #define DCIDX_FROM_BUF(buf) \ ((uint8_t (*)[DC_CACHE_BUFSIZE])(buf) - cache_buffer) #define DCIDX_FROM_DCE(dce) \ ((dce) - cache_entry) /* set the in-use bit in the map */ static inline void cache_bitmap_set_bit(int volume, unsigned int mapnum, unsigned int bitnum) { cache_map_set_bit(&CACHE_MAP_ENTRY(volume, mapnum), bitnum); cache_map_set_bit(&CACHE_VOL_MAP(volume), bitnum); (void)volume; } /* clear the in-use bit in the map */ static inline void cache_bitmap_clear_bit(int volume, unsigned int mapnum, unsigned int bitnum) { cache_map_clear_bit(&CACHE_MAP_ENTRY(volume, mapnum), bitnum); cache_map_clear_bit(&CACHE_VOL_MAP(volume), bitnum); (void)volume; } /* make entry MRU by moving it to the list tail */ static inline void touch_cache_entry(struct disk_cache_entry *which) { struct lldc_node *lru = cache_lru.head; struct lldc_node *node = &which->node; if (node == lru->prev) /* already MRU */ ; /**/ else if (node == lru) /* is the LRU? just rotate list */ cache_lru.head = lru->next; else /* somewhere else; move it */ { lldc_remove(&cache_lru, node); lldc_insert_last(&cache_lru, node); } } /* remove LRU entry from the cache list to use as a buffer */ static struct disk_cache_entry * cache_remove_lru_entry(void) { struct lldc_node *lru = cache_lru.head; /* at least one is reserved for client */ if (lru == lru->next) return NULL; /* remove it; next-LRU becomes the LRU */ lldc_remove(&cache_lru, lru); return NODE_DCE(lru); } /* return entry to the cache list and set it LRU */ static void cache_return_lru_entry(struct disk_cache_entry *fce) { lldc_insert_first(&cache_lru, &fce->node); } /* discard the entry's data and mark it unused */ static inline void cache_discard_entry(struct disk_cache_entry *dce, unsigned int index) { cache_bitmap_clear_bit(IF_MV_VOL(dce->volume), map_sector(dce->sector), index); dce->flags = 0; } /* search the cache for the specified sector, returning a buffer, either to the specified sector, if it exists, or a new/evicted entry that must be filled */ void * dc_cache_probe(IF_MV(int volume,) unsigned long sector, unsigned int *flagsp) { unsigned int mapnum = map_sector(sector); FOR_EACH_BITARRAY_SET_BIT(&CACHE_MAP_ENTRY(volume, mapnum), index) { struct disk_cache_entry *dce = &cache_entry[index]; if (dce->sector == sector) { *flagsp = DCE_INUSE; touch_cache_entry(dce); return cache_buffer[index]; } } /* sector not found so the LRU is the victim */ struct disk_cache_entry *dce = DCE_LRU(); cache_lru.head = dce->node.next; unsigned int index = DCIDX_FROM_DCE(dce); void *buf = cache_buffer[index]; unsigned int old_flags = dce->flags; if (old_flags) { int old_volume = IF_MV_VOL(dce->volume); unsigned long sector = dce->sector; unsigned int old_mapnum = map_sector(sector); if (old_flags & DCE_DIRTY) dc_writeback_callback(IF_MV(old_volume,) sector, buf); if (mapnum == old_mapnum IF_MV( && volume == old_volume )) goto finish_setup; cache_bitmap_clear_bit(old_volume, old_mapnum, index); } cache_bitmap_set_bit(IF_MV_VOL(volume), mapnum, index); finish_setup: dce->flags = DCE_INUSE; #ifdef HAVE_MULTIVOLUME dce->volume = volume; #endif dce->sector = sector; *flagsp = 0; return buf; } /* mark in-use cache entry as dirty by buffer */ void dc_dirty_buf(void *buf) { unsigned int index = DCIDX_FROM_BUF(buf); if (index >= DC_NUM_ENTRIES) return; /* dirt remains, sticky until flushed */ struct disk_cache_entry *fce = &cache_entry[index]; if (fce->flags & DCE_INUSE) fce->flags |= DCE_DIRTY; } /* discard in-use cache entry by buffer */ void dc_discard_buf(void *buf) { unsigned int index = DCIDX_FROM_BUF(buf); if (index >= DC_NUM_ENTRIES) return; struct disk_cache_entry *dce = &cache_entry[index]; if (dce->flags & DCE_INUSE) cache_discard_entry(dce, index); } /* commit all dirty cache entries to storage for a specified volume */ void dc_commit_all(IF_MV_NONVOID(int volume)) { DEBUGF("dc_commit_all()\n"); FOR_EACH_BITARRAY_SET_BIT(&CACHE_VOL_MAP(volume), index) { struct disk_cache_entry *dce = &cache_entry[index]; unsigned int flags = dce->flags; if (flags & DCE_DIRTY) { dc_writeback_callback(IF_MV(volume,) dce->sector, cache_buffer[index]); dce->flags = flags & ~DCE_DIRTY; } } } /* discard all cache entries from the specified volume */ void dc_discard_all(IF_MV_NONVOID(int volume)) { DEBUGF("dc_discard_all()\n"); FOR_EACH_BITARRAY_SET_BIT(&CACHE_VOL_MAP(volume), index) cache_discard_entry(&cache_entry[index], index); } /* expropriate a buffer from the cache */ void * dc_get_buffer(void) { dc_lock_cache(); void *buf = NULL; struct disk_cache_entry *dce = cache_remove_lru_entry(); if (dce) { unsigned int index = DCIDX_FROM_DCE(dce); unsigned int flags = dce->flags; buf = cache_buffer[index]; if (flags) { /* must first commit this sector if dirty */ if (flags & DCE_DIRTY) dc_writeback_callback(IF_MV(dce->volume,) dce->sector, buf); cache_discard_entry(dce, index); } dce->flags = DCE_BUF; } /* cache is out of buffers */ dc_unlock_cache(); return buf; } /* return buffer to the cache by buffer */ void dc_release_buffer(void *buf) { unsigned int index = DCIDX_FROM_BUF(buf); if (index >= DC_NUM_ENTRIES) return; dc_lock_cache(); struct disk_cache_entry *dce = &cache_entry[index]; if (dce->flags & DCE_BUF) { dce->flags = 0; cache_return_lru_entry(dce); } dc_unlock_cache(); } /* one-time init at startup */ void dc_init(void) { mutex_init(&disk_cache_mutex); lldc_init(&cache_lru); for (unsigned int i = 0; i < DC_NUM_ENTRIES; i++) lldc_insert_last(&cache_lru, &cache_entry[i].node); }