/*- * See the file LICENSE for redistribution information. * * Copyright (c) 1996, 1997, 1998 * Sleepycat Software. All rights reserved. */ /* * Copyright (c) 1990, 1993, 1994, 1995, 1996 * Keith Bostic. All rights reserved. */ /* * Copyright (c) 1990, 1993, 1994, 1995 * The Regents of the University of California. All rights reserved. * * This code is derived from software contributed to Berkeley by * Mike Olson. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. 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. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * 4. Neither the name of the University 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 REGENTS 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 REGENTS 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 "config.h" #ifndef lint static const char sccsid[] = "@(#)db_overflow.c 10.21 (Sleepycat) 9/27/98"; #endif /* not lint */ #ifndef NO_SYSTEM_INCLUDES #include #include #include #endif #include "db_int.h" #include "db_page.h" #include "db_am.h" #include "common_ext.h" /* * Big key/data code. * * Big key and data entries are stored on linked lists of pages. The initial * reference is a structure with the total length of the item and the page * number where it begins. Each entry in the linked list contains a pointer * to the next page of data, and so on. */ /* * __db_goff -- * Get an offpage item. * * PUBLIC: int __db_goff __P((DB *, DBT *, * PUBLIC: u_int32_t, db_pgno_t, void **, u_int32_t *)); */ int __db_goff(dbp, dbt, tlen, pgno, bpp, bpsz) DB *dbp; DBT *dbt; u_int32_t tlen; db_pgno_t pgno; void **bpp; u_int32_t *bpsz; { PAGE *h; db_indx_t bytes; u_int32_t curoff, needed, start; u_int8_t *p, *src; int ret; /* * Check if the buffer is big enough; if it is not and we are * allowed to malloc space, then we'll malloc it. If we are * not (DB_DBT_USERMEM), then we'll set the dbt and return * appropriately. */ if (F_ISSET(dbt, DB_DBT_PARTIAL)) { start = dbt->doff; needed = dbt->dlen; } else { start = 0; needed = tlen; } /* Allocate any necessary memory. */ if (F_ISSET(dbt, DB_DBT_USERMEM)) { if (needed > dbt->ulen) { dbt->size = needed; return (ENOMEM); } } else if (F_ISSET(dbt, DB_DBT_MALLOC)) { if ((ret = __os_malloc(needed, dbp->db_malloc, &dbt->data)) != 0) return (ret); } else if (*bpsz == 0 || *bpsz < needed) { if ((ret = __os_realloc(bpp, needed)) != 0) return (ret); *bpsz = needed; dbt->data = *bpp; } else dbt->data = *bpp; /* * Step through the linked list of pages, copying the data on each * one into the buffer. Never copy more than the total data length. */ dbt->size = needed; for (curoff = 0, p = dbt->data; pgno != P_INVALID && needed > 0;) { if ((ret = memp_fget(dbp->mpf, &pgno, 0, &h)) != 0) { (void)__db_pgerr(dbp, pgno); return (ret); } /* Check if we need any bytes from this page. */ if (curoff + OV_LEN(h) >= start) { src = (u_int8_t *)h + P_OVERHEAD; bytes = OV_LEN(h); if (start > curoff) { src += start - curoff; bytes -= start - curoff; } if (bytes > needed) bytes = needed; memcpy(p, src, bytes); p += bytes; needed -= bytes; } curoff += OV_LEN(h); pgno = h->next_pgno; memp_fput(dbp->mpf, h, 0); } return (0); } /* * __db_poff -- * Put an offpage item. * * PUBLIC: int __db_poff __P((DBC *, const DBT *, db_pgno_t *, * PUBLIC: int (*)(DBC *, u_int32_t, PAGE **))); */ int __db_poff(dbc, dbt, pgnop, newfunc) DBC *dbc; const DBT *dbt; db_pgno_t *pgnop; int (*newfunc) __P((DBC *, u_int32_t, PAGE **)); { DB *dbp; PAGE *pagep, *lastp; DB_LSN new_lsn, null_lsn; DBT tmp_dbt; db_indx_t pagespace; u_int32_t sz; u_int8_t *p; int ret; /* * Allocate pages and copy the key/data item into them. Calculate the * number of bytes we get for pages we fill completely with a single * item. */ dbp = dbc->dbp; pagespace = P_MAXSPACE(dbp->pgsize); lastp = NULL; for (p = dbt->data, sz = dbt->size; sz > 0; p += pagespace, sz -= pagespace) { /* * Reduce pagespace so we terminate the loop correctly and * don't copy too much data. */ if (sz < pagespace) pagespace = sz; /* * Allocate and initialize a new page and copy all or part of * the item onto the page. If sz is less than pagespace, we * have a partial record. */ if ((ret = newfunc(dbc, P_OVERFLOW, &pagep)) != 0) return (ret); if (DB_LOGGING(dbc)) { tmp_dbt.data = p; tmp_dbt.size = pagespace; ZERO_LSN(null_lsn); if ((ret = __db_big_log(dbp->dbenv->lg_info, dbc->txn, &new_lsn, 0, DB_ADD_BIG, dbp->log_fileid, PGNO(pagep), lastp ? PGNO(lastp) : PGNO_INVALID, PGNO_INVALID, &tmp_dbt, &LSN(pagep), lastp == NULL ? &null_lsn : &LSN(lastp), &null_lsn)) != 0) return (ret); /* Move lsn onto page. */ if (lastp) LSN(lastp) = new_lsn; LSN(pagep) = new_lsn; } P_INIT(pagep, dbp->pgsize, PGNO(pagep), PGNO_INVALID, PGNO_INVALID, 0, P_OVERFLOW); OV_LEN(pagep) = pagespace; OV_REF(pagep) = 1; memcpy((u_int8_t *)pagep + P_OVERHEAD, p, pagespace); /* * If this is the first entry, update the user's info. * Otherwise, update the entry on the last page filled * in and release that page. */ if (lastp == NULL) *pgnop = PGNO(pagep); else { lastp->next_pgno = PGNO(pagep); pagep->prev_pgno = PGNO(lastp); (void)memp_fput(dbp->mpf, lastp, DB_MPOOL_DIRTY); } lastp = pagep; } (void)memp_fput(dbp->mpf, lastp, DB_MPOOL_DIRTY); return (0); } /* * __db_ovref -- * Increment/decrement the reference count on an overflow page. * * PUBLIC: int __db_ovref __P((DBC *, db_pgno_t, int32_t)); */ int __db_ovref(dbc, pgno, adjust) DBC *dbc; db_pgno_t pgno; int32_t adjust; { DB *dbp; PAGE *h; int ret; dbp = dbc->dbp; if ((ret = memp_fget(dbp->mpf, &pgno, 0, &h)) != 0) { (void)__db_pgerr(dbp, pgno); return (ret); } if (DB_LOGGING(dbc)) if ((ret = __db_ovref_log(dbp->dbenv->lg_info, dbc->txn, &LSN(h), 0, dbp->log_fileid, h->pgno, adjust, &LSN(h))) != 0) return (ret); OV_REF(h) += adjust; (void)memp_fput(dbp->mpf, h, DB_MPOOL_DIRTY); return (0); } /* * __db_doff -- * Delete an offpage chain of overflow pages. * * PUBLIC: int __db_doff __P((DBC *, db_pgno_t, int (*)(DBC *, PAGE *))); */ int __db_doff(dbc, pgno, freefunc) DBC *dbc; db_pgno_t pgno; int (*freefunc) __P((DBC *, PAGE *)); { DB *dbp; PAGE *pagep; DB_LSN null_lsn; DBT tmp_dbt; int ret; dbp = dbc->dbp; do { if ((ret = memp_fget(dbp->mpf, &pgno, 0, &pagep)) != 0) { (void)__db_pgerr(dbp, pgno); return (ret); } /* * If it's an overflow page and it's referenced by more than * one key/data item, decrement the reference count and return. */ if (TYPE(pagep) == P_OVERFLOW && OV_REF(pagep) > 1) { (void)memp_fput(dbp->mpf, pagep, 0); return (__db_ovref(dbc, pgno, -1)); } if (DB_LOGGING(dbc)) { tmp_dbt.data = (u_int8_t *)pagep + P_OVERHEAD; tmp_dbt.size = OV_LEN(pagep); ZERO_LSN(null_lsn); if ((ret = __db_big_log(dbp->dbenv->lg_info, dbc->txn, &LSN(pagep), 0, DB_REM_BIG, dbp->log_fileid, PGNO(pagep), PREV_PGNO(pagep), NEXT_PGNO(pagep), &tmp_dbt, &LSN(pagep), &null_lsn, &null_lsn)) != 0) return (ret); } pgno = pagep->next_pgno; if ((ret = freefunc(dbc, pagep)) != 0) return (ret); } while (pgno != PGNO_INVALID); return (0); } /* * __db_moff -- * Match on overflow pages. * * Given a starting page number and a key, return <0, 0, >0 to indicate if the * key on the page is less than, equal to or greater than the key specified. * We optimize this by doing chunk at a time comparison unless the user has * specified a comparison function. In this case, we need to materialize * the entire object and call their comparison routine. * * PUBLIC: int __db_moff __P((DB *, const DBT *, db_pgno_t, u_int32_t, * PUBLIC: int (*)(const DBT *, const DBT *), int *)); */ int __db_moff(dbp, dbt, pgno, tlen, cmpfunc, cmpp) DB *dbp; const DBT *dbt; db_pgno_t pgno; u_int32_t tlen; int (*cmpfunc) __P((const DBT *, const DBT *)), *cmpp; { PAGE *pagep; DBT local_dbt; void *buf; u_int32_t bufsize, cmp_bytes, key_left; u_int8_t *p1, *p2; int ret; /* * If there is a user-specified comparison function, build a * contiguous copy of the key, and call it. */ if (cmpfunc != NULL) { memset(&local_dbt, 0, sizeof(local_dbt)); buf = NULL; bufsize = 0; if ((ret = __db_goff(dbp, &local_dbt, tlen, pgno, &buf, &bufsize)) != 0) return (ret); *cmpp = cmpfunc(&local_dbt, dbt); __os_free(buf, bufsize); return (0); } /* While there are both keys to compare. */ for (*cmpp = 0, p1 = dbt->data, key_left = dbt->size; key_left > 0 && pgno != PGNO_INVALID;) { if ((ret = memp_fget(dbp->mpf, &pgno, 0, &pagep)) != 0) return (ret); cmp_bytes = OV_LEN(pagep) < key_left ? OV_LEN(pagep) : key_left; key_left -= cmp_bytes; for (p2 = (u_int8_t *)pagep + P_OVERHEAD; cmp_bytes-- > 0; ++p1, ++p2) if (*p1 != *p2) { *cmpp = (long)*p1 - (long)*p2; break; } pgno = NEXT_PGNO(pagep); if ((ret = memp_fput(dbp->mpf, pagep, 0)) != 0) return (ret); if (*cmpp != 0) return (0); } if (key_left > 0) /* DBT is longer than page key. */ *cmpp = -1; else if (pgno != PGNO_INVALID) /* DBT is shorter than page key. */ *cmpp = 1; else *cmpp = 0; return (0); }