/* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* * BSD 3 Clause License * * Copyright (c) 2007, The Storage Networking Industry Association. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * - Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * - Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * * - Neither the name of The Storage Networking Industry Association (SNIA) * nor the names of its contributors may be used to endorse or promote * products derived from this software without specific prior written * permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include #include #include #include #include #include #include /* * Hash table size. */ #define BMAP_HASH_SIZE 64 /* * Maximum number of chunk that can be cached. */ #define BMAP_CHUNK_MAX 128 /* * Size of bitmap table. */ #define BMAP_MAX 256 /* * Bit_MAP Word SIZE. This should be equal to 'sizeof (int)'. */ #define BMAP_WSIZE (sizeof (int)) /* * Bit_MAP Bit Per Word. */ #define BMAP_BPW (BMAP_WSIZE * 8) #define BMAP_BPW_SHIFT 5 #define BMAP_BPW_MASK (~(~0 << BMAP_BPW_SHIFT)) /* * Chunk of bit map in each node. */ #define BMAP_CHUNK_WORDS 1024 #define BMAP_CHUNK_BYTES (BMAP_CHUNK_WORDS * BMAP_WSIZE) #define BMAP_CHUNK_BITS (BMAP_CHUNK_WORDS * BMAP_BPW) #define BMAP_CHUNK_NO(p) ((p) / BMAP_CHUNK_BITS) #define BMAP_CHUNK_OFF(p) (BMAP_CHUNK_NO(p) * BMAP_CHUNK_BITS) /* * Bitmap flags. */ #define BMAP_BINIT_ONES 0x00000001 /* initial value of bits is 1 */ #define BMAP_INUSE 0x00000002 /* slot is in use */ /* * Macros of bitmap flags. */ #define BMAP_SET_FLAGS(b, f) ((b)->bm_flags |= (f)) #define BMAP_UNSET_FLAGS(b, f) ((b)->bm_flags &= ~(f)) #define BMAP_IS_INIT_ONES(b) ((b)->bm_flags & BMAP_BINIT_ONES) #define BMAP_IS_INUSE(b) ((b)->bm_flags & BMAP_INUSE) #define HASH(p) (((p) / BMAP_CHUNK_BITS) % BMAP_HASH_SIZE) /* * Calculate the memory size in bytes needed for the specified length * of bitmap. */ #define ROUNDUP(n, d) (((n) + (d) - 1) / (d)) #define MEM_LEN(l) (ROUNDUP((l), BMAP_BPW) * BMAP_WSIZE) /* * Chunk flags. */ #define BMAP_CSET_DIRTY(cp) (cp)->c_flags |= BMAP_CDIRTY #define BMAP_CDIRTY 0x00000001 /* the chunk is dirty */ /* * Macros on chunk flags. */ #define BMAP_CIS_DIRTY(cp) ((cp)->c_flags & BMAP_CDIRTY) /* * When loading a bitmap chunk, if it is new set the bitmap * can be set according to the initial value of bits. * Otherwise, it should be loaded from the file. */ #define BMAP_NEW_CHUNK 1 #define BMAP_OLD_CHUNK 0 /* * Each chunk holds the followin information: * - A flag showing the status of the chunk, like being ditry or not. * - Its offset in bits from the beginning of the vector. * - Its length in bits. * - Its memory length in use in bytes. * - The bitmap vector. * * In addition to the above information, each chunk can be on two lists: * one the hash list, the other LRU list. The hash list is a MRU list, * meaning the MRU entry is at the head of the list. * * All the chunks are in the LRU list. When a chunk is needed and there is * no more room for allocating chunks, the first entry of this list is * reclaimed. */ typedef struct dbmap_chunk { TAILQ_ENTRY(dbmap_chunk) c_hash; TAILQ_ENTRY(dbmap_chunk) c_lru; uint_t c_flags; u_quad_t c_off; uint_t c_clen; uint_t c_mlen; uint_t *c_bmp; } dbmap_chunk_t; TAILQ_HEAD(dbmap_list, dbmap_chunk); typedef struct dbmap_list dbmap_list_t; typedef struct dbitmap { char *bm_fname; int bm_fd; uint_t bm_flags; u_quad_t bm_len; /* bitmap length */ uint_t bm_cmax; /* maximum number of cached chunks */ uint_t bm_ccur; /* current number of cached chunks */ dbmap_list_t bm_hash[BMAP_HASH_SIZE]; /* MRU hash table */ dbmap_list_t bm_lru; /* LRU list */ } dbitmap_t; /* * Disk bitmap table. Upon allocating a dbitmap, one slot * of this table will be used. */ static dbitmap_t dbitmap[BMAP_MAX]; /* * Each chunk holds the followin information: * - Its offset in bits from the beginning of the vector. * - Its length in bits. * - Its memory length in use in bytes. * - The bitmap vector. * * In addition to the above information, each chunk can be on a list: * one the hash list. The hash list is a MRU list, meaning that the * MRU entry is at the head of the list. */ typedef struct bmap_chunk { TAILQ_ENTRY(bmap_chunk) c_hash; u_quad_t c_off; uint_t c_clen; uint_t c_mlen; uint_t *c_bmp; } bmap_chunk_t; TAILQ_HEAD(bmap_list, bmap_chunk); typedef struct bmap_list bmap_list_t; typedef struct bitmap { uint_t bm_flags; u_quad_t bm_len; /* bitmap length */ uint_t bm_cmax; /* maximum number of cached chunks */ uint_t bm_ccur; /* current number of cached chunks */ bmap_list_t bm_hash[BMAP_HASH_SIZE]; /* MRU hash table */ } bitmap_t; /* * Statistics gathering structure. */ typedef struct bitmap_stats { ulong_t bs_alloc_cnt; ulong_t bs_alloc_size; ulong_t bs_free_cnt; ulong_t bs_set_applied; ulong_t bs_unset_applied; ulong_t bs_cache_hit; ulong_t bs_cache_miss; ulong_t bs_chunk_new; ulong_t bs_chunk_flush; ulong_t bs_chunk_reclaim; u_quad_t bs_get; u_quad_t bs_get_bits; u_quad_t bs_set; u_quad_t bs_set_bits; u_quad_t bs_unset; u_quad_t bs_unset_bits; } bitmap_stats_t; /* * Disk bitmap table. Upon allocating a bitmap, one slot * of this table will be used. */ static bitmap_t bitmap[BMAP_MAX]; /* * Global instance of statistics variable. */ bitmap_stats_t bitmap_stats; /* * bmd2bmp * * Convert bitmap descriptor to bitmap pointer. */ static bitmap_t * bmd2bmp(int bmd) { if (bmd < 0 || bmd >= BMAP_MAX) return (NULL); return (&bitmap[bmd]); } /* * bmd_alloc * * Allocate a bitmap descriptor. Sets the INUSE flag of the slot. */ static int bmd_alloc(void) { int i; bitmap_t *bmp; bmp = bitmap; for (i = 0; i < BMAP_MAX; bmp++, i++) if (!BMAP_IS_INUSE(bmp)) { BMAP_SET_FLAGS(bmp, BMAP_INUSE); return (i); } return (-1); } /* * bmd_free * * Free a bitmap descriptor. Clears the INUSE flag of the slot. */ static void bmd_free(int bmd) { bitmap_t *bmp; bmp = bmd2bmp(bmd); if (bmp) BMAP_UNSET_FLAGS(bmp, BMAP_INUSE); } /* * bmp_set * * Generic function to set bit in a chunk. This can set or unset the * specified bit. */ static inline int bmp_set(bmap_chunk_t *cp, u_quad_t bn, uint_t *vp) { int rv; uint_t mask; uint_t *ip; uint_t v; bn -= cp->c_off; if (bn < cp->c_clen) { mask = 1 <<(bn & BMAP_BPW_MASK); ip = &cp->c_bmp[bn >> BMAP_BPW_SHIFT]; v = (*vp <<(bn & BMAP_BPW_MASK)) & mask; *ip = (*ip & ~mask) | v; rv = 0; } else rv = -ERANGE; return (rv); } /* * bmp_get * * Generic function to get bit in a chunk. */ static inline int bmp_get(bmap_chunk_t *cp, u_quad_t bn) { int rv; uint_t bit; bn -= cp->c_off; if (bn < cp->c_clen) { bit = 1 <<(bn & BMAP_BPW_MASK); rv = (cp->c_bmp[bn >> BMAP_BPW_SHIFT] & bit) != 0; } else rv = -ERANGE; return (rv); } /* * bm_chuck_setup * * Set up the properties of the new chunk and position it in the hash list. */ static bmap_chunk_t * bm_chunk_setup(bitmap_t *bmp, bmap_chunk_t *cp, u_quad_t bn) { int h; u_quad_t off, l; uint_t cl, ml; bmap_list_t *hp; off = BMAP_CHUNK_OFF(bn); l = bmp->bm_len - off; if (l >= BMAP_CHUNK_BITS) { cl = BMAP_CHUNK_BITS; ml = BMAP_CHUNK_BYTES; } else { cl = l; ml = MEM_LEN(l); } if (BMAP_IS_INIT_ONES(bmp)) (void) memset(cp->c_bmp, 0xff, ml); else (void) memset(cp->c_bmp, 0x00, ml); h = HASH(bn); hp = &bmp->bm_hash[h]; /* LINTED: E_CONSTANT_CONDITION */ TAILQ_INSERT_HEAD(hp, cp, c_hash); cp->c_off = off; cp->c_clen = cl; cp->c_mlen = ml; return (cp); } /* * bm_chunk_new * * Create a new chunk and keep track of memory used. */ static bmap_chunk_t * bm_chunk_new(bitmap_t *bmp, u_quad_t bn) { bmap_chunk_t *cp; bitmap_stats.bs_chunk_new++; cp = ndmp_malloc(sizeof (bmap_chunk_t)); if (cp) { cp->c_bmp = ndmp_malloc(sizeof (uint_t) * BMAP_CHUNK_WORDS); if (!cp->c_bmp) { free(cp); cp = NULL; } else { (void) bm_chunk_setup(bmp, cp, bn); bmp->bm_ccur++; } } return (cp); } /* * bm_chunk_alloc * * Allocate a chunk and return it. If the cache for the chunks is not * fully used, a new chunk is created. */ static bmap_chunk_t * bm_chunk_alloc(bitmap_t *bmp, u_quad_t bn) { bmap_chunk_t *cp; if (bmp->bm_ccur < bmp->bm_cmax) cp = bm_chunk_new(bmp, bn); else cp = NULL; return (cp); } /* * hash_free * * Free all chunks on the hash list. */ void hash_free(bmap_list_t *hp) { bmap_chunk_t *cp; if (!hp) return; while (!TAILQ_EMPTY(hp)) { cp = TAILQ_FIRST(hp); /* LINTED: E_CONSTANT_CONDITION */ TAILQ_REMOVE(hp, cp, c_hash); free(cp->c_bmp); free(cp); } } /* * bm_chunks_free * * Release the memory allocated for the chunks. */ static void bm_chunks_free(bmap_list_t *hp) { int i; for (i = 0; i < BMAP_HASH_SIZE; hp++, i++) hash_free(hp); } /* * bm_chunk_repositions * * Re-position the chunk in the MRU hash table. */ static void bm_chunk_reposition(bitmap_t *bmp, bmap_list_t *hp, bmap_chunk_t *cp) { if (!bmp || !hp || !cp) return; if (TAILQ_FIRST(hp) != cp) { /* LINTED: E_CONSTANT_CONDITION */ TAILQ_REMOVE(hp, cp, c_hash); /* LINTED: E_CONSTANT_CONDITION */ TAILQ_INSERT_HEAD(hp, cp, c_hash); } } /* * bm_chunk_find * * Find and return the chunks which holds the specified bit. Allocate * the chunk if necessary and re-position it in the hash table lists. */ static bmap_chunk_t * bm_chunk_find(bitmap_t *bmp, u_quad_t bn) { int h; bmap_chunk_t *cp; bmap_list_t *hp; if (!bmp) return (NULL); h = HASH(bn); hp = &bmp->bm_hash[h]; TAILQ_FOREACH(cp, hp, c_hash) { if (bn >= cp->c_off && bn < (cp->c_off + cp->c_clen)) { bitmap_stats.bs_cache_hit++; bm_chunk_reposition(bmp, hp, cp); return (cp); } } bitmap_stats.bs_cache_miss++; return (bm_chunk_alloc(bmp, bn)); } /* * bmp_setval * * Set a range of bits in the bitmap specified by the vector. */ static int bmp_setval(bitmap_t *bmp, bm_iovec_t *vp) { int rv; u_quad_t cl; u_quad_t bn; u_quad_t max; bmap_chunk_t *cp; bn = vp->bmv_base; max = bn + vp->bmv_len; if (bn >= bmp->bm_len || max > bmp->bm_len) return (-EINVAL); if (*vp->bmv_val) { bitmap_stats.bs_set++; bitmap_stats.bs_set_bits += vp->bmv_len; } else { bitmap_stats.bs_unset++; bitmap_stats.bs_unset_bits += vp->bmv_len; } do { cp = bm_chunk_find(bmp, bn); if (!cp) return (-ERANGE); for (cl = cp->c_off + cp->c_clen; bn < cl && bn < max; bn++) { rv = bmp_set(cp, bn, vp->bmv_val); if (rv != 0) return (rv); } } while (bn < max); return (0); } /* * bmp_getval * * Get a range of bits in the bitmap specified by the vector. */ static int bmp_getval(bitmap_t *bmp, bm_iovec_t *vp) { uint_t cnt; uint_t *ip; int rv; u_quad_t cl; u_quad_t bn; u_quad_t max; bmap_chunk_t *cp; bn = vp->bmv_base; max = bn + vp->bmv_len; if (bn >= bmp->bm_len || max > bmp->bm_len) return (-EINVAL); bitmap_stats.bs_get++; bitmap_stats.bs_get_bits += 1; cnt = 0; ip = vp->bmv_val; *ip = 0; do { cp = bm_chunk_find(bmp, bn); if (!cp) return (-ERANGE); for (cl = cp->c_off + cp->c_clen; bn < cl && bn < max; bn++) { rv = bmp_get(cp, bn); if (rv < 0) return (rv); *ip |= rv << cnt; if (++cnt >= BMAP_BPW) { *++ip = 0; cnt = 0; } } } while (bn < max); return (0); } /* * hash_init * * Initialize the hash table lists head. */ static void hash_init(bmap_list_t *hp) { int i; for (i = 0; i < BMAP_HASH_SIZE; hp++, i++) { /* LINTED: E_CONSTANT_CONDITION */ TAILQ_INIT(hp); } } /* * bm_alloc * * Allocate a bit map and return a handle to it. * * The hash table list are empty at this point. They are allocated * on demand. */ int bm_alloc(u_quad_t len, int set) { int bmd; bitmap_t *bmp; if (len == 0) return (-1); bmd = bmd_alloc(); if (bmd < 0) return (bmd); bmp = bmd2bmp(bmd); bitmap_stats.bs_alloc_cnt++; bitmap_stats.bs_alloc_size += len; if (set) BMAP_SET_FLAGS(bmp, BMAP_BINIT_ONES); else BMAP_UNSET_FLAGS(bmp, BMAP_BINIT_ONES); bmp->bm_len = len; bmp->bm_ccur = 0; bmp->bm_cmax = BMAP_CHUNK_MAX; hash_init(bmp->bm_hash); return (bmd); } /* * bm_free * * Free memory allocated for the bitmap. */ int bm_free(int bmd) { int rv; bitmap_t *bmp; bmp = bmd2bmp(bmd); if (bmp && BMAP_IS_INUSE(bmp)) { bitmap_stats.bs_free_cnt++; bm_chunks_free(bmp->bm_hash); bmd_free(bmd); rv = 0; } else rv = -1; return (rv); } /* * bm_getiov * * Get bits specified by the array of vectors. */ int bm_getiov(int bmd, bm_io_t *iop) { int i; int rv; bm_iovec_t *vp; bitmap_t *bmp; if (!iop) rv = -EINVAL; else if (!(bmp = bmd2bmp(bmd))) rv = -EINVAL; else if (iop->bmio_iovcnt <= 0) rv = -EINVAL; else { rv = 0; vp = iop->bmio_iov; for (i = 0; i < iop->bmio_iovcnt; vp++, i++) { if (!vp) return (-EINVAL); rv |= bmp_getval(bmp, vp); } } return (rv); } /* * bm_setiov * * Set bits specified by the array of vectors. */ int bm_setiov(int bmd, bm_io_t *iop) { int i; int rv; bm_iovec_t *vp; bitmap_t *bmp; if (!iop) rv = -EINVAL; else if (!(bmp = bmd2bmp(bmd))) rv = -EINVAL; else if (iop->bmio_iovcnt <= 0) rv = -EINVAL; else if (!iop->bmio_iov) rv = -EINVAL; else { rv = 0; vp = iop->bmio_iov; for (i = 0; i < iop->bmio_iovcnt; vp++, i++) rv |= bmp_setval(bmp, vp); } return (rv); } /* * bmd2dbmp * * Convert bitmap descriptor to bitmap pointer. */ static dbitmap_t * bmd2dbmp(int bmd) { if (bmd < 0 || bmd >= BMAP_MAX) return (NULL); return (&dbitmap[bmd]); } /* * dbmp2bmd * * Convert bitmap pointer to bitmap descriptor. */ static int dbmp2bmd(dbitmap_t *bmp) { int bmd; bmd = bmp - dbitmap; if (bmd < 0 || bmd >= BMAP_MAX) bmd = -1; return (bmd); } /* * dbmd_alloc * * Allocate a bitmap descriptor. * Sets the INUSE flag of the slot. */ static int dbmd_alloc(void) { int i; dbitmap_t *bmp; bmp = dbitmap; for (i = 0; i < BMAP_MAX; bmp++, i++) if (!BMAP_IS_INUSE(bmp)) { BMAP_SET_FLAGS(bmp, BMAP_INUSE); return (i); } return (-1); } /* * dbmd_free * * Free a bitmap descriptor. * Clears the INUSE flag of the slot. */ static void dbmd_free(int bmd) { dbitmap_t *bmp; bmp = bmd2dbmp(bmd); if (bmp) BMAP_UNSET_FLAGS(bmp, BMAP_INUSE); } /* * dbmp_set * * Generic function to set bit in a chunk. This can * set or unset the specified bit. */ static inline int dbmp_set(dbmap_chunk_t *cp, u_quad_t bn, uint_t *vp) { int rv; uint_t mask; uint_t *ip; uint_t v; bn -= cp->c_off; if (bn < cp->c_clen) { mask = 1 <<(bn & BMAP_BPW_MASK); ip = &cp->c_bmp[bn >> BMAP_BPW_SHIFT]; v = (*vp <<(bn & BMAP_BPW_MASK)) & mask; *ip = (*ip & ~mask) | v; BMAP_CSET_DIRTY(cp); rv = 0; } else rv = -ERANGE; return (rv); } /* * dbmp_getlen * * Get length of the bitmap. */ static u_quad_t dbmp_getlen(dbitmap_t *bmp) { return (bmp ? bmp->bm_len : 0LL); } /* * dbmp_get * * Generic function to get bit in a chunk. */ static inline int dbmp_get(dbmap_chunk_t *cp, u_quad_t bn) { int rv; uint_t bit; bn -= cp->c_off; if (bn < cp->c_clen) { bit = 1 <<(bn & BMAP_BPW_MASK); rv = (cp->c_bmp[bn >> BMAP_BPW_SHIFT] & bit) != 0; } else rv = -ERANGE; return (rv); } /* * dbm_chunk_seek * * Seek in the file where the chunk is saved or should be saved. */ static int dbm_chunk_seek(dbitmap_t *bmp, u_quad_t bn) { int rv; off_t off; if (!bmp) rv = -1; else { off = BMAP_CHUNK_NO(bn) * BMAP_CHUNK_BYTES; rv = (lseek(bmp->bm_fd, off, SEEK_SET) != off) ? -1 : 0; } return (rv); } /* * dbm_chunk_flush * * Save a chunk to file. */ static int dbm_chunk_flush(dbitmap_t *bmp, dbmap_chunk_t *cp) { int rv; bitmap_stats.bs_chunk_flush++; if (!bmp || !cp) rv = -1; else if (dbm_chunk_seek(bmp, cp->c_off) != 0) rv = -1; else if (write(bmp->bm_fd, cp->c_bmp, cp->c_mlen) != cp->c_mlen) rv = -1; else rv = 0; return (rv); } /* * dbm_chunk_load * * Load a chunk from a file. If the chunk is a new one, * instead of reading from the disk, the memory for the * chunk is set to either all zeros or to all ones. * Otherwise, if the chunk is not a new one, it's read * from the disk. * * The new chunk is positioned in the LRU and hash table * after its data is ready. */ static dbmap_chunk_t * dbm_chunk_load(dbitmap_t *bmp, dbmap_chunk_t *cp, u_quad_t bn, int new) { int h; u_quad_t off, l; uint_t cl, ml; dbmap_list_t *hp; off = BMAP_CHUNK_OFF(bn); l = bmp->bm_len - off; if (l >= BMAP_CHUNK_BITS) { cl = BMAP_CHUNK_BITS; ml = BMAP_CHUNK_BYTES; } else { cl = l; ml = MEM_LEN(l); } if (new == BMAP_NEW_CHUNK) { if (BMAP_IS_INIT_ONES(bmp)) (void) memset(cp->c_bmp, 0xff, ml); else (void) memset(cp->c_bmp, 0x00, ml); } else { /* BMAP_OLD_CHUNK */ if (dbm_chunk_seek(bmp, bn) != 0) cp = NULL; else if (read(bmp->bm_fd, cp->c_bmp, ml) != ml) cp = NULL; } if (cp) { /* LINTED: E_CONSTANT_CONDITION */ TAILQ_INSERT_TAIL(&bmp->bm_lru, cp, c_lru); h = HASH(bn); hp = &bmp->bm_hash[h]; /* LINTED: E_CONSTANT_CONDITION */ TAILQ_INSERT_HEAD(hp, cp, c_hash); cp->c_flags = 0; cp->c_off = off; cp->c_clen = cl; cp->c_mlen = ml; } return (cp); } /* * dbm_chunk_new * * Create a new chunk and keep track of memory used. */ static dbmap_chunk_t * dbm_chunk_new(dbitmap_t *bmp, u_quad_t bn) { dbmap_chunk_t *cp; bitmap_stats.bs_chunk_new++; cp = ndmp_malloc(sizeof (dbmap_chunk_t)); if (cp) { cp->c_bmp = ndmp_malloc(sizeof (uint_t) * BMAP_CHUNK_WORDS); if (!cp->c_bmp) { free(cp); cp = NULL; } else if (!dbm_chunk_load(bmp, cp, bn, BMAP_NEW_CHUNK)) { free(cp->c_bmp); free(cp); cp = NULL; } else bmp->bm_ccur++; } return (cp); } /* * dbm_chunk_alloc * * Allocate a chunk and return it. If the cache for the * chunks is not fully used, a new chunk is created. * Otherwise, the first chunk from the LRU list is reclaimed, * loaded and returned. */ static dbmap_chunk_t * dbm_chunk_alloc(dbitmap_t *bmp, u_quad_t bn) { int h; dbmap_list_t *hp; dbmap_chunk_t *cp; if (bmp->bm_ccur < bmp->bm_cmax) return (dbm_chunk_new(bmp, bn)); bitmap_stats.bs_chunk_reclaim++; cp = TAILQ_FIRST(&bmp->bm_lru); if (BMAP_CIS_DIRTY(cp)) (void) dbm_chunk_flush(bmp, cp); /* LINTED: E_CONSTANT_CONDITION */ TAILQ_REMOVE(&bmp->bm_lru, cp, c_lru); h = HASH(cp->c_off); hp = &bmp->bm_hash[h]; /* LINTED: E_CONSTANT_CONDITION */ TAILQ_REMOVE(hp, cp, c_hash); return (dbm_chunk_load(bmp, cp, bn, BMAP_OLD_CHUNK)); } /* * dbm_chunks_free * * Release the memory allocated for the chunks. */ static void dbm_chunks_free(dbitmap_t *bmp) { dbmap_list_t *headp; dbmap_chunk_t *cp; if (!bmp) return; headp = &bmp->bm_lru; if (!headp) return; while (!TAILQ_EMPTY(headp)) { cp = TAILQ_FIRST(headp); /* LINTED: E_CONSTANT_CONDITION */ TAILQ_REMOVE(headp, cp, c_lru); free(cp->c_bmp); free(cp); } } /* * dbm_chunk_reposition * * Re-position the chunk in the LRU and the hash table. */ static void dbm_chunk_reposition(dbitmap_t *bmp, dbmap_list_t *hp, dbmap_chunk_t *cp) { if (bmp && hp && cp) { /* LINTED: E_CONSTANT_CONDITION */ TAILQ_REMOVE(&bmp->bm_lru, cp, c_lru); /* LINTED: E_CONSTANT_CONDITION */ TAILQ_INSERT_TAIL(&bmp->bm_lru, cp, c_lru); if (TAILQ_FIRST(hp) != cp) { /* LINTED: E_CONSTANT_CONDITION */ TAILQ_REMOVE(hp, cp, c_hash); /* LINTED: E_CONSTANT_CONDITION */ TAILQ_INSERT_HEAD(hp, cp, c_hash); } } } /* * dbm_chunk_find * * Find and return the chunks which holds the specified bit. * Allocate the chunk if necessary and re-position it in the * LRU and hash table lists. */ static dbmap_chunk_t * dbm_chunk_find(dbitmap_t *bmp, u_quad_t bn) { int h; dbmap_chunk_t *cp; dbmap_list_t *hp; if (!bmp) return (NULL); h = HASH(bn); hp = &bmp->bm_hash[h]; TAILQ_FOREACH(cp, hp, c_hash) { if (bn >= cp->c_off && bn < (cp->c_off + cp->c_clen)) { bitmap_stats.bs_cache_hit++; dbm_chunk_reposition(bmp, hp, cp); return (cp); } } bitmap_stats.bs_cache_miss++; return (dbm_chunk_alloc(bmp, bn)); } /* * dbmp_setval * * Set a range of bits in the bitmap specified by the * vector. */ static int dbmp_setval(dbitmap_t *bmp, bm_iovec_t *vp) { int rv; u_quad_t cl; u_quad_t bn; u_quad_t max; dbmap_chunk_t *cp; bn = vp->bmv_base; max = bn + vp->bmv_len; if (bn >= bmp->bm_len || max > bmp->bm_len) return (-EINVAL); if (*vp->bmv_val) { bitmap_stats.bs_set++; bitmap_stats.bs_set_bits += vp->bmv_len; } else { bitmap_stats.bs_unset++; bitmap_stats.bs_unset_bits += vp->bmv_len; } do { cp = dbm_chunk_find(bmp, bn); if (!cp) return (-ERANGE); for (cl = cp->c_off + cp->c_clen; bn < cl && bn < max; bn++) { rv = dbmp_set(cp, bn, vp->bmv_val); if (rv != 0) return (rv); } } while (bn < max); return (0); } /* * dbmp_getval * * Get a range of bits in the bitmap specified by the * vector. */ static int dbmp_getval(dbitmap_t *bmp, bm_iovec_t *vp) { uint_t cnt; uint_t *ip; int rv; u_quad_t cl; u_quad_t bn; u_quad_t max; dbmap_chunk_t *cp; bn = vp->bmv_base; max = bn + vp->bmv_len; if (bn >= bmp->bm_len || max > bmp->bm_len) return (-EINVAL); bitmap_stats.bs_get++; bitmap_stats.bs_get_bits += 1; cnt = 0; ip = vp->bmv_val; *ip = 0; do { cp = dbm_chunk_find(bmp, bn); if (!cp) return (-ERANGE); for (cl = cp->c_off + cp->c_clen; bn < cl && bn < max; bn++) { rv = dbmp_get(cp, bn); if (rv < 0) return (rv); *ip |= rv << cnt; if (++cnt >= BMAP_BPW) { *++ip = 0; cnt = 0; } } } while (bn < max); return (0); } /* * dbyte_apply_ifset * * Apply the function on the set bits of the specified word. */ static int dbyte_apply_ifset(dbitmap_t *bmp, u_quad_t off, uint_t b, int(*fp)(), void *arg) { int bmd; int rv; u_quad_t l; rv = 0; l = dbmp_getlen(bmp); bmd = dbmp2bmd(bmp); for (; b && off < l; off++) { if (b & 1) { bitmap_stats.bs_set_applied++; if ((rv = (*fp)(bmd, off, arg))) break; } b >>= 1; } return (rv); } /* * dbm_chunk_apply_ifset * * Apply the function on the set bits of the specified chunk. */ static int dbm_chunk_apply_ifset(dbitmap_t *bmp, dbmap_chunk_t *cp, int(*fp)(), void *arg) { int rv; uint_t *bp; uint_t i, m; u_quad_t q; rv = 0; bp = cp->c_bmp; q = cp->c_off; m = cp->c_mlen / BMAP_WSIZE; for (i = 0; i < m; q += BMAP_BPW, bp++, i++) if (*bp) { rv = dbyte_apply_ifset(bmp, q, *bp, fp, arg); if (rv != 0) break; } return (rv); } /* * swfile_trunc * * Truncate the rest of the swap file. */ static int swfile_trunc(int fd) { int rv; off_t off; /* * Get the current offset and truncate whatever is * after this point. */ rv = 0; if ((off = lseek(fd, 0, SEEK_CUR)) < 0) rv = -1; else if (ftruncate(fd, off) != 0) rv = -1; return (rv); } /* * swfile_init * * Initialize the swap file. The necessary disk space is * reserved by writing to the swap file for swapping the * chunks in/out of the file. */ static int swfile_init(int fd, u_quad_t len, int set) { u_quad_t i, n; uint_t cl, ml; uint_t buf[BMAP_CHUNK_WORDS]; (void) memset(buf, set ? 0xff : 0x00, BMAP_CHUNK_BYTES); n = len / BMAP_CHUNK_BITS; for (i = 0; i < n; i++) if (write(fd, buf, BMAP_CHUNK_BYTES) != BMAP_CHUNK_BYTES) return (-1); cl = (uint_t)(len % BMAP_CHUNK_BITS); ml = MEM_LEN(cl); if (write(fd, buf, ml) != ml) return (-1); return (swfile_trunc(fd)); } /* * dbm_alloc * * Allocate a bit map and return a handle to it. * * The swap file is created if it does not exist. * The file is truncated if it exists and is larger * than needed amount. * * The hash table and LRU list are empty at this point. * They are allocated and/or loaded on-demand. */ int dbm_alloc(char *fname, u_quad_t len, int set) { int fd; int bmd; dbitmap_t *bmp; if (!fname || !*fname || !len) return (-1); /* * When allocating bitmap, make sure there is enough * disk space by allocating needed disk space, for * writing back the dirty chunks when swaping them out. */ bmd = dbmd_alloc(); if (bmd < 0) return (bmd); bmp = bmd2dbmp(bmd); if ((fd = open(fname, O_RDWR|O_CREAT, 0600)) < 0) bmd = -1; else if (swfile_init(fd, len, set) < 0) { bmd = -1; (void) close(fd); (void) unlink(fname); dbmd_free(bmd); bmd = -1; } else if (!(bmp->bm_fname = strdup(fname))) { (void) close(fd); (void) unlink(fname); dbmd_free(bmd); bmd = -1; } else { bitmap_stats.bs_alloc_cnt++; bitmap_stats.bs_alloc_size += len; bmp->bm_fd = fd; if (set) BMAP_SET_FLAGS(bmp, BMAP_BINIT_ONES); else BMAP_UNSET_FLAGS(bmp, BMAP_BINIT_ONES); bmp->bm_len = len; bmp->bm_ccur = 0; bmp->bm_cmax = BMAP_CHUNK_MAX; /* LINTED: E_CONSTANT_CONDITION */ TAILQ_INIT(&bmp->bm_lru); hash_init((bmap_list_t *)bmp->bm_hash); } return (bmd); } /* * dbm_free * * Free memory allocated for the bitmap and remove its swap file. */ int dbm_free(int bmd) { int rv; dbitmap_t *bmp; bmp = bmd2dbmp(bmd); if (bmp && BMAP_IS_INUSE(bmp)) { bitmap_stats.bs_free_cnt++; dbm_chunks_free(bmp); (void) close(bmp->bm_fd); (void) unlink(bmp->bm_fname); free(bmp->bm_fname); dbmd_free(bmd); rv = 0; } else rv = -1; return (rv); } /* * dbm_getlen * * Return length of the bitmap. */ u_quad_t dbm_getlen(int bmd) { dbitmap_t *bmp; bmp = bmd2dbmp(bmd); return (dbmp_getlen(bmp)); } /* * dbm_set * * Set a range of bits. */ int dbm_set(int bmd, u_quad_t start, u_quad_t len, uint_t val) { bm_io_t io; bm_iovec_t iov; iov.bmv_base = start; iov.bmv_len = len; iov.bmv_val = &val; io.bmio_iovcnt = 1; io.bmio_iov = &iov; return (dbm_setiov(bmd, &io)); } /* * dbm_getiov * * Get bits specified by the array of vectors. */ int dbm_getiov(int bmd, bm_io_t *iop) { int i; int rv; bm_iovec_t *vp; dbitmap_t *bmp; if (!iop) rv = -EINVAL; else if (!(bmp = bmd2dbmp(bmd))) rv = -EINVAL; else if (iop->bmio_iovcnt <= 0) rv = -EINVAL; else { rv = 0; vp = iop->bmio_iov; for (i = 0; i < iop->bmio_iovcnt; vp++, i++) { if (!vp) return (-EINVAL); rv |= dbmp_getval(bmp, vp); } } return (rv); } /* * dbm_setiov * * Set bits specified by the array of vectors. */ int dbm_setiov(int bmd, bm_io_t *iop) { int i; int rv; bm_iovec_t *vp; dbitmap_t *bmp; if (!iop) rv = -EINVAL; else if (!(bmp = bmd2dbmp(bmd))) rv = -EINVAL; else if (iop->bmio_iovcnt <= 0) rv = -EINVAL; else if (!iop->bmio_iov) rv = -EINVAL; else { rv = 0; vp = iop->bmio_iov; for (i = 0; i < iop->bmio_iovcnt; vp++, i++) rv |= dbmp_setval(bmp, vp); } return (rv); } /* * dbm_apply_ifset * * Call the callback function for each set bit in the bitmap and * pass the 'arg' and bit number as its argument. */ int dbm_apply_ifset(int bmd, int(*fp)(), void *arg) { int rv; u_quad_t q; dbitmap_t *bmp; dbmap_chunk_t *cp; bmp = bmd2dbmp(bmd); if (!bmp || !fp) return (-EINVAL); rv = 0; for (q = 0; q < bmp->bm_len; q += BMAP_CHUNK_BITS) { cp = dbm_chunk_find(bmp, q); if (!cp) { rv = -ERANGE; break; } rv = dbm_chunk_apply_ifset(bmp, cp, fp, arg); if (rv != 0) break; } return (rv); } /* * bm_set * * Set a range of bits. */ int bm_set(int bmd, u_quad_t start, u_quad_t len, uint_t val) { bm_io_t io; bm_iovec_t iov; iov.bmv_base = start; iov.bmv_len = len; iov.bmv_val = &val; io.bmio_iovcnt = 1; io.bmio_iov = &iov; return (bm_setiov(bmd, &io)); } /* * bm_get * * Get a range of bits. */ int bm_get(int bmd, u_quad_t start, u_quad_t len, uint_t *buf) { bm_io_t io; bm_iovec_t iov; iov.bmv_base = start; iov.bmv_len = len; iov.bmv_val = buf; io.bmio_iovcnt = 1; io.bmio_iov = &iov; return (bm_getiov(bmd, &io)); } /* * bm_getone * * Get only one bit. */ int bm_getone(int bmd, u_quad_t bitnum) { uint_t i; if (bm_get(bmd, bitnum, 1, &i) == 0) return (i ? 1 : 0); return (0); } /* * dbm_get * * Get a range of bits. */ int dbm_get(int bmd, u_quad_t start, u_quad_t len, uint_t *buf) { bm_io_t io; bm_iovec_t iov; iov.bmv_base = start; iov.bmv_len = len; iov.bmv_val = buf; io.bmio_iovcnt = 1; io.bmio_iov = &iov; return (dbm_getiov(bmd, &io)); } /* * dbm_getone * * Get only one bit. */ int dbm_getone(int bmd, u_quad_t bitnum) { uint_t i; if (dbm_get(bmd, bitnum, 1, &i) == 0) return (i ? 1 : 0); return (0); }