/* -*- Mode: C; tab-width: 8; indent-tabs-mode: t; c-basic-offset: 8 -*- * * Copyright (C) 2000 Ximian, Inc. * * Authors: Michael Zucchi * * This program is free software; you can redistribute it and/or * modify it under the terms of version 2 of the GNU General Public * License as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * General Public License for more details. * * You should have received a copy of the GNU General Public * License along with this program; if not, write to the * Free Software Foundation, Inc., 59 Temple Place - Suite 330, * Boston, MA 02111-1307, USA. */ /* block file/cache/utility functions */ #include #include #include #include #include #include #include #include #include "block.h" /*#define MALLOC_CHECK*/ #ifdef MALLOC_CHECK #include #endif #define d(x) /*#define DEBUG*/ int block_log; #ifdef IBEX_STATS static void init_stats(struct _memcache *index) { index->stats = g_hash_table_new(g_direct_hash, g_direct_equal); } static void dump_1_stat(int id, struct _stat_info *info, struct _memcache *index) { printf("%d %d %d %d %d\n", id, info->read, info->write, info->cache_hit, info->cache_miss); } static void dump_stats(struct _memcache *index) { printf("Block reads writes hits misses\n"); g_hash_table_foreach(index->stats, dump_1_stat, index); } static void add_read(struct _memcache *index, int id) { struct _stat_info *info; info = g_hash_table_lookup(index->stats, (void *)id); if (info == NULL) { info = g_malloc0(sizeof(*info)); g_hash_table_insert(index->stats, (void *)id, info); } info->read++; } static void add_write(struct _memcache *index, int id) { struct _stat_info *info; info = g_hash_table_lookup(index->stats, (void *)id); if (info == NULL) { info = g_malloc0(sizeof(*info)); g_hash_table_insert(index->stats, (void *)id, info); } info->write++; } static void add_hit(struct _memcache *index, int id) { struct _stat_info *info; info = g_hash_table_lookup(index->stats, (void *)id); if (info == NULL) { info = g_malloc0(sizeof(*info)); g_hash_table_insert(index->stats, (void *)id, info); } info->cache_hit++; } static void add_miss(struct _memcache *index, int id) { struct _stat_info *info; info = g_hash_table_lookup(index->stats, (void *)id); if (info == NULL) { info = g_malloc0(sizeof(*info)); g_hash_table_insert(index->stats, (void *)id, info); } info->cache_miss++; } #endif /* IBEX_STATS */ #ifdef MALLOC_CHECK static void checkmem(void *p) { if (p) { int status = mprobe(p); switch (status) { case MCHECK_HEAD: printf("Memory underrun at %p\n", p); abort(); case MCHECK_TAIL: printf("Memory overrun at %p\n", p); abort(); case MCHECK_FREE: printf("Double free %p\n", p); abort(); } } } #endif /* simple list routines (for simplified memory management of cache/lists) */ /** * ibex_list_new: * @v: * * Initialise a list header. A list header must always be initialised * before use. **/ void ibex_list_new(struct _list *v) { v->head = (struct _listnode *)&v->tail; v->tail = 0; v->tailpred = (struct _listnode *)&v->head; } /** * ibex_list_addhead: * @l: List. * @n: Node to append. * * Prepend a listnode to the head of the list @l. * * Return value: Always @n. **/ struct _listnode *ibex_list_addhead(struct _list *l, struct _listnode *n) { n->next = l->head; n->prev = (struct _listnode *)&l->head; l->head->prev = n; l->head = n; return n; } /** * ibex_list_addtail: * @l: * @n: * * Append a listnode to the end of the list @l. * * Return value: Always the same as @n. **/ struct _listnode *ibex_list_addtail(struct _list *l, struct _listnode *n) { n->next = (struct _listnode *)&l->tail; n->prev = l->tailpred; l->tailpred->next = n; l->tailpred = n; return n; } /** * ibex_list_remove: * @n: The node to remove. * * Remove a listnode from a list. * * Return value: Always the same as @n. **/ struct _listnode *ibex_list_remove(struct _listnode *n) { n->next->prev = n->prev; n->prev->next = n->next; return n; } static struct _memblock * memblock_addr(struct _block *block) { return (struct _memblock *)(((char *)block) - G_STRUCT_OFFSET(struct _memblock, data)); } /* read/sync the rootblock into the block_cache structure */ static int ibex_block_read_root(struct _memcache *block_cache) { lseek(block_cache->fd, 0, SEEK_SET); if (read(block_cache->fd, &block_cache->root, sizeof(block_cache->root)) != sizeof(block_cache->root)) { return -1; } return 0; } static int ibex_block_sync_root(struct _memcache *block_cache) { lseek(block_cache->fd, 0, SEEK_SET); if (write(block_cache->fd, &block_cache->root, sizeof(block_cache->root)) != sizeof(block_cache->root)) { return -1; } return fsync(block_cache->fd); } /** * ibex_block_dirty: * @block: * * Dirty a block. This will cause it to be written to disk on * a cache sync, or when the block is flushed from the cache. **/ void ibex_block_dirty(struct _block *block) { memblock_addr(block)->flags |= BLOCK_DIRTY; } static void sync_block(struct _memcache *block_cache, struct _memblock *memblock) { if (block_log) printf("writing block %d\n", memblock->block); lseek(block_cache->fd, memblock->block, SEEK_SET); if (write(block_cache->fd, &memblock->data, sizeof(memblock->data)) != -1) { memblock->flags &= ~BLOCK_DIRTY; } #ifdef IBEX_STATS add_write(block_cache, memblock->block); #endif } /** * ibex_block_cache_sync: * @block_cache: * * Ensure the block cache is fully synced to disk. **/ void ibex_block_cache_sync(struct _memcache *block_cache) { struct _memblock *memblock; if (block_cache->failed) return; memblock = (struct _memblock *)block_cache->nodes.head; while (memblock->next) { #ifdef MALLOC_CHECK checkmem(memblock); #endif if (memblock->flags & BLOCK_DIRTY) { sync_block(block_cache, memblock); } memblock = memblock->next; } block_cache->root.flags |= IBEX_ROOT_SYNCF; if (ibex_block_sync_root(block_cache) != 0) { block_cache->root.flags &= ~IBEX_ROOT_SYNCF; } #ifdef IBEX_STATS dump_stats(block_cache); #endif } #ifdef MALLOC_CHECK static void check_cache(struct _memcache *block_cache) { struct _memblock *mw, *mn; checkmem(block_cache); checkmem(block_cache->index); mw = (struct _memblock *)block_cache->nodes.head; mn = mw->next; while (mn) { checkmem(mw); mw = mn; mn = mn->next; } } #endif /** * ibex_block_cache_flush: * @block_cache: * * Ensure the block cache is fully synced to disk, and then flush * its contents from memory. **/ void ibex_block_cache_flush(struct _memcache *block_cache) { struct _memblock *mw, *mn; ibex_block_cache_sync(block_cache); mw = (struct _memblock *)block_cache->nodes.head; mn = mw->next; while (mn) { g_hash_table_remove(block_cache->index, (void *)mw->block); g_free(mw); mw = mn; mn = mn->next; } ibex_list_new(&block_cache->nodes); } /** * ibex_block_read: * @block_cache: * @blockid: * * Read the data of a block by blockid. The data contents is backed by * the block cache, and should be considered static. * * TODO; should this return a NULL block on error? * * Return value: The address of the block data (which may be cached). **/ struct _block * ibex_block_read(struct _memcache *block_cache, blockid_t blockid) { struct _memblock *memblock; #ifdef MALLOC_CHECK check_cache(block_cache); #endif /* nothing can read the root block directly */ ibex_block_cache_assert(block_cache, blockid != 0); ibex_block_cache_assert(block_cache, blockid < block_cache->root.roof); memblock = g_hash_table_lookup(block_cache->index, (void *)blockid); #ifdef MALLOC_CHECK check_cache(block_cache); #endif if (memblock) { d(printf("foudn blockid in cache %d = %p\n", blockid, &memblock->data)); /* 'access' page */ ibex_list_remove((struct _listnode *)memblock); ibex_list_addtail(&block_cache->nodes, (struct _listnode *)memblock); #ifdef MALLOC_CHECK check_cache(block_cache); #endif #ifdef IBEX_STATS add_hit(block_cache, memblock->block); #endif #ifdef MALLOC_CHECK check_cache(block_cache); #endif return &memblock->data; } #ifdef IBEX_STATS add_miss(block_cache, blockid); add_read(block_cache, blockid); #endif if (block_log) printf("miss block %d\n", blockid); d(printf("loading blockid from disk %d\n", blockid)); memblock = g_malloc(sizeof(*memblock)); memblock->block = blockid; memblock->flags = 0; lseek(block_cache->fd, blockid, SEEK_SET); memset(&memblock->data, 0, sizeof(memblock->data)); read(block_cache->fd, &memblock->data, sizeof(memblock->data)); ibex_list_addtail(&block_cache->nodes, (struct _listnode *)memblock); g_hash_table_insert(block_cache->index, (void *)blockid, memblock); if (block_cache->count >= CACHE_SIZE) { struct _memblock *old = (struct _memblock *)block_cache->nodes.head; d(printf("discaring cache block %d\n", old->block)); g_hash_table_remove(block_cache->index, (void *)old->block); ibex_list_remove((struct _listnode *)old); if (old->flags & BLOCK_DIRTY) { /* are we about to un-sync the file? update root and sync it */ if (block_cache->root.flags & IBEX_ROOT_SYNCF) { d(printf("Unsyncing root block\n")); block_cache->root.flags &= ~IBEX_ROOT_SYNCF; if (ibex_block_sync_root(block_cache) != 0) { /* what do we do? i dont know! */ g_warning("Could not sync root block of index: %s", strerror(errno)); } } sync_block(block_cache, old); } g_free(old); } else { block_cache->count++; } d(printf(" --- cached blocks : %d\n", block_cache->count)); #ifdef MALLOC_CHECK check_cache(block_cache); #endif return &memblock->data; } void ibex_block_cache_fail(struct _memcache *block_cache, char *where, int line, char *why) { block_cache->failed = TRUE; block_cache->root.flags &= ~IBEX_ROOT_SYNCF; /* and blow it away, we can do nothing better yet */ ftruncate(block_cache->fd, 0); g_warning("%s(%d): Integrity assertion failed: '%s' on file '%s'", where, line, why, block_cache->name); longjmp(block_cache->failenv, 1); } /** * ibex_block_cache_open: * @name: * @flags: Flags as to open(2), should use O_RDWR and optionally O_CREAT. * @mode: Mose as to open(2) * * Open a block file. * * FIXME; this currently also initialises the word and name indexes * because their pointers are stored in the root block. Should be * upto the caller to manage these pointers/data. * * Return value: NULL if the backing file could not be opened. **/ struct _memcache * ibex_block_cache_open(const char *name, int flags, int mode) { struct _memcache *block_cache = g_malloc0(sizeof(*block_cache)); d(printf("opening ibex file: %s", name)); /* setup cache */ ibex_list_new(&block_cache->nodes); block_cache->count = 0; block_cache->index = g_hash_table_new(g_direct_hash, g_direct_equal); block_cache->fd = open(name, flags, mode); block_cache->failed = FALSE; block_cache->name = g_strdup(name); if (block_cache->fd == -1) { g_hash_table_destroy(block_cache->index); g_free(block_cache); return NULL; } if (ibex_block_cache_setjmp(block_cache) != 0) { close(block_cache->fd); g_hash_table_destroy(block_cache->index); g_free(block_cache); return NULL; } ibex_block_read_root(block_cache); if (block_cache->root.roof == 0 || memcmp(block_cache->root.version, IBEX_VERSION, 4) || ((block_cache->root.flags & IBEX_ROOT_SYNCF) == 0)) { d(printf("Initialising superblock\n")); /* reset root data */ memcpy(block_cache->root.version, IBEX_VERSION, 4); block_cache->root.roof = 1024; block_cache->root.free = 0; block_cache->root.words = 0; block_cache->root.names = 0; block_cache->root.tail = 0; /* list of tail blocks */ block_cache->root.flags = 0; ibex_block_sync_root(block_cache); /* reset the file contents */ ftruncate(block_cache->fd, 1024); } else { d(printf("superblock already initialised:\n" " roof = %d\n free = %d\n words = %d\n names = %d\n tail = %d\n", block_cache->root.roof, block_cache->root.free, block_cache->root.words, block_cache->root.names, block_cache->root.tail)); } /* FIXME: this should be moved higher up in the object tree */ { struct _IBEXWord *ibex_create_word_index_mem(struct _memcache *bc, blockid_t *wordroot, blockid_t *nameroot); block_cache->words = ibex_create_word_index_mem(block_cache, &block_cache->root.words,&block_cache->root.names); } #ifdef IBEX_STATS init_stats(block_cache); #endif return block_cache; } /** * ibex_block_cache_close: * @block_cache: * * Close the block file, sync any remaining cached data * to disk, and free all resources. **/ void ibex_block_cache_close(struct _memcache *block_cache) { struct _memblock *mw, *mn; ibex_block_cache_sync(block_cache); close(block_cache->fd); g_free(block_cache->name); mw = (struct _memblock *)block_cache->nodes.head; mn = mw->next; while (mn) { g_free(mw); mw = mn; mn = mw->next; } g_hash_table_destroy(block_cache->index); g_free(block_cache); } /** * ibex_block_free: * @block_cache: * @blockid: * * Return a block to the free pool. **/ void ibex_block_free(struct _memcache *block_cache, blockid_t blockid) { struct _block *block = ibex_block_read(block_cache, blockid); block->next = block_number(block_cache->root.free); block_cache->root.free = blockid; ibex_block_dirty((struct _block *)block); } /** * ibex_block_get: * @block_cache: * * Allocate a new block, or access a previously freed block and return * its block id. The block will have zeroed contents. * * Return value: 0 if there are no blocks left (disk full/read only * file, etc). **/ blockid_t ibex_block_get(struct _memcache *block_cache) { struct _block *block; blockid_t head; if (block_cache->root.free) { head = block_cache->root.free; block = ibex_block_read(block_cache, head); block_cache->root.free = block_location(block->next); } else { /* TODO: check the block will fit first */ /* TODO: no need to read this block, can allocate it manually (saves a syscall/read) */ head = block_cache->root.roof; block_cache->root.roof += BLOCK_SIZE; block = ibex_block_read(block_cache, head); } ibex_block_cache_assert(block_cache, head != 0); d(printf("new block = %d\n", head)); block->next = 0; block->used = 0; ibex_block_dirty(block); return head; }