/*- * See the file LICENSE for redistribution information. * * Copyright (c) 1996,2008 Oracle. 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. 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. * * $Id: db_overflow.c,v 12.26 2008/03/12 20:32:32 mbrey Exp $ */ #include "db_config.h" #include "db_int.h" #include "dbinc/db_page.h" #include "dbinc/db_am.h" #include "dbinc/mp.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 *, DB_THREAD_INFO *, DB_TXN *, DBT *, * PUBLIC: u_int32_t, db_pgno_t, void **, u_int32_t *)); */ int __db_goff(dbp, ip, txn, dbt, tlen, pgno, bpp, bpsz) DB *dbp; DB_THREAD_INFO *ip; DB_TXN *txn; DBT *dbt; u_int32_t tlen; db_pgno_t pgno; void **bpp; u_int32_t *bpsz; { DB_MPOOLFILE *mpf; ENV *env; PAGE *h; db_indx_t bytes; u_int32_t curoff, needed, start; u_int8_t *p, *src; int ret; env = dbp->env; mpf = dbp->mpf; /* * 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; if (start > tlen) needed = 0; else if (dbt->dlen > tlen - start) needed = tlen - start; else needed = dbt->dlen; } else { start = 0; needed = tlen; } if (F_ISSET(dbt, DB_DBT_USERCOPY)) goto skip_alloc; /* Allocate any necessary memory. */ if (F_ISSET(dbt, DB_DBT_USERMEM)) { if (needed > dbt->ulen) { dbt->size = needed; return (DB_BUFFER_SMALL); } } else if (F_ISSET(dbt, DB_DBT_MALLOC)) { if ((ret = __os_umalloc(env, needed, &dbt->data)) != 0) return (ret); } else if (F_ISSET(dbt, DB_DBT_REALLOC)) { if ((ret = __os_urealloc(env, needed, &dbt->data)) != 0) return (ret); } else if (bpsz != NULL && (*bpsz == 0 || *bpsz < needed)) { if ((ret = __os_realloc(env, needed, bpp)) != 0) return (ret); *bpsz = needed; dbt->data = *bpp; } else if (bpp != NULL) dbt->data = *bpp; else { DB_ASSERT(env, F_ISSET(dbt, DB_DBT_USERMEM | DB_DBT_MALLOC | DB_DBT_REALLOC) || bpsz != NULL || bpp != NULL); return (DB_BUFFER_SMALL); } skip_alloc: /* * 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 != PGNO_INVALID && needed > 0;) { if ((ret = __memp_fget(mpf, &pgno, ip, txn, 0, &h)) != 0) return (ret); DB_ASSERT(env, TYPE(h) == P_OVERFLOW); /* Check if we need any bytes from this page. */ if (curoff + OV_LEN(h) >= start) { bytes = OV_LEN(h); src = (u_int8_t *)h + P_OVERHEAD(dbp); if (start > curoff) { src += start - curoff; bytes -= start - curoff; } if (bytes > needed) bytes = needed; if (F_ISSET(dbt, DB_DBT_USERCOPY)) { /* * The offset into the DBT is the total size * less the amount of data still needed. Care * needs to be taken if doing a partial copy * beginning at an offset other than 0. */ if ((ret = env->dbt_usercopy( dbt, dbt->size - needed, src, bytes, DB_USERCOPY_SETDATA)) != 0) { (void)__memp_fput(mpf, ip, h, dbp->priority); return (ret); } } else memcpy(p, src, bytes); p += bytes; needed -= bytes; } curoff += OV_LEN(h); pgno = h->next_pgno; (void)__memp_fput(mpf, ip, h, dbp->priority); } return (0); } /* * __db_poff -- * Put an offpage item. * * PUBLIC: int __db_poff __P((DBC *, const DBT *, db_pgno_t *)); */ int __db_poff(dbc, dbt, pgnop) DBC *dbc; const DBT *dbt; db_pgno_t *pgnop; { DB *dbp; DBT tmp_dbt; DB_LSN new_lsn, null_lsn; DB_MPOOLFILE *mpf; PAGE *pagep, *lastp; db_indx_t pagespace; u_int32_t sz; u_int8_t *p; int ret, t_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; mpf = dbp->mpf; pagespace = P_MAXSPACE(dbp, dbp->pgsize); ret = 0; 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 = __db_new(dbc, P_OVERFLOW, &pagep)) != 0) break; if (DBC_LOGGING(dbc)) { tmp_dbt.data = p; tmp_dbt.size = pagespace; ZERO_LSN(null_lsn); if ((ret = __db_big_log(dbp, dbc->txn, &new_lsn, 0, DB_ADD_BIG, PGNO(pagep), lastp ? PGNO(lastp) : PGNO_INVALID, PGNO_INVALID, &tmp_dbt, &LSN(pagep), lastp == NULL ? &null_lsn : &LSN(lastp), &null_lsn)) != 0) { if (lastp != NULL) (void)__memp_fput(mpf, dbc->thread_info, lastp, dbc->priority); lastp = pagep; break; } } else LSN_NOT_LOGGED(new_lsn); /* Move LSN onto page. */ if (lastp != NULL) LSN(lastp) = new_lsn; LSN(pagep) = new_lsn; OV_LEN(pagep) = pagespace; OV_REF(pagep) = 1; memcpy((u_int8_t *)pagep + P_OVERHEAD(dbp), 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(mpf, dbc->thread_info, lastp, dbc->priority); } lastp = pagep; } if (lastp != NULL && (t_ret = __memp_fput(mpf, dbc->thread_info, lastp, dbc->priority)) != 0 && ret == 0) ret = t_ret; return (ret); } /* * __db_ovref -- * Decrement the reference count on an overflow page. * * PUBLIC: int __db_ovref __P((DBC *, db_pgno_t)); */ int __db_ovref(dbc, pgno) DBC *dbc; db_pgno_t pgno; { DB *dbp; DB_MPOOLFILE *mpf; PAGE *h; int ret; dbp = dbc->dbp; mpf = dbp->mpf; if ((ret = __memp_fget(mpf, &pgno, dbc->thread_info, dbc->txn, DB_MPOOL_DIRTY, &h)) != 0) return (ret); if (DBC_LOGGING(dbc)) { if ((ret = __db_ovref_log(dbp, dbc->txn, &LSN(h), 0, h->pgno, -1, &LSN(h))) != 0) { (void)__memp_fput(mpf, dbc->thread_info, h, dbc->priority); return (ret); } } else LSN_NOT_LOGGED(LSN(h)); /* * In BDB releases before 4.5, the overflow reference counts were * incremented when an overflow item was split onto an internal * page. There was a lock race in that code, and rather than fix * the race, we changed BDB to copy overflow items when splitting * them onto internal pages. The code to decrement reference * counts remains so databases already in the field continue to * work. */ --OV_REF(h); return (__memp_fput(mpf, dbc->thread_info, h, dbc->priority)); } /* * __db_doff -- * Delete an offpage chain of overflow pages. * * PUBLIC: int __db_doff __P((DBC *, db_pgno_t)); */ int __db_doff(dbc, pgno) DBC *dbc; db_pgno_t pgno; { DB *dbp; DBT tmp_dbt; DB_LSN null_lsn; DB_MPOOLFILE *mpf; PAGE *pagep; int ret; dbp = dbc->dbp; mpf = dbp->mpf; do { if ((ret = __memp_fget(mpf, &pgno, dbc->thread_info, dbc->txn, 0, &pagep)) != 0) return (ret); DB_ASSERT(dbp->env, TYPE(pagep) == P_OVERFLOW); /* * If it's referenced by more than one key/data item, * decrement the reference count and return. */ if (OV_REF(pagep) > 1) { (void)__memp_fput(mpf, dbc->thread_info, pagep, dbc->priority); return (__db_ovref(dbc, pgno)); } if ((ret = __memp_dirty(mpf, &pagep, dbc->thread_info, dbc->txn, dbc->priority, 0)) != 0) { (void)__memp_fput(mpf, dbc->thread_info, pagep, dbc->priority); return (ret); } if (DBC_LOGGING(dbc)) { tmp_dbt.data = (u_int8_t *)pagep + P_OVERHEAD(dbp); tmp_dbt.size = OV_LEN(pagep); ZERO_LSN(null_lsn); if ((ret = __db_big_log(dbp, dbc->txn, &LSN(pagep), 0, DB_REM_BIG, PGNO(pagep), PREV_PGNO(pagep), NEXT_PGNO(pagep), &tmp_dbt, &LSN(pagep), &null_lsn, &null_lsn)) != 0) { (void)__memp_fput(mpf, dbc->thread_info, pagep, dbc->priority); return (ret); } } else LSN_NOT_LOGGED(LSN(pagep)); pgno = pagep->next_pgno; OV_LEN(pagep) = 0; if ((ret = __db_free(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. * * __db_moff and __db_coff are generic functions useful in searching and * ordering off page items. __db_moff matches an overflow DBT with an offpage * item. __db_coff compares two offpage items for lexicographic sort order. * * PUBLIC: int __db_moff __P((DB *, * PUBLIC: DB_THREAD_INFO *, DB_TXN *, const DBT *, db_pgno_t, * PUBLIC: u_int32_t, int (*)(DB *, const DBT *, const DBT *), int *)); */ int __db_moff(dbp, ip, txn, dbt, pgno, tlen, cmpfunc, cmpp) DB *dbp; DB_THREAD_INFO *ip; DB_TXN *txn; const DBT *dbt; db_pgno_t pgno; u_int32_t tlen; int (*cmpfunc) __P((DB *, const DBT *, const DBT *)), *cmpp; { DBT local_dbt; DB_MPOOLFILE *mpf; PAGE *pagep; void *buf; u_int32_t bufsize, cmp_bytes, key_left; u_int8_t *p1, *p2; int ret; mpf = dbp->mpf; /* * 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, ip, txn, &local_dbt, tlen, pgno, &buf, &bufsize)) != 0) return (ret); /* Pass the key as the first argument */ *cmpp = cmpfunc(dbp, dbt, &local_dbt); __os_free(dbp->env, buf); 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(mpf, &pgno, ip, txn, 0, &pagep)) != 0) return (ret); cmp_bytes = OV_LEN(pagep) < key_left ? OV_LEN(pagep) : key_left; tlen -= cmp_bytes; key_left -= cmp_bytes; for (p2 = (u_int8_t *)pagep + P_OVERHEAD(dbp); cmp_bytes-- > 0; ++p1, ++p2) if (*p1 != *p2) { *cmpp = (long)*p1 - (long)*p2; break; } pgno = NEXT_PGNO(pagep); if ((ret = __memp_fput(mpf, ip, pagep, dbp->priority)) != 0) return (ret); if (*cmpp != 0) return (0); } if (key_left > 0) /* DBT is longer than the page key. */ *cmpp = 1; else if (tlen > 0) /* DBT is shorter than the page key. */ *cmpp = -1; else *cmpp = 0; return (0); } /* * __db_coff -- * Match two offpage dbts. * * The DBTs must both refer to offpage items. * The match happens a chunk (page) at a time unless a user defined comparison * function exists. It is not possible to optimize this comparison away when * a lexicographic sort order is required on mismatch. * * NOTE: For now this function only works for H_OFFPAGE type items. It would * be simple to extend it for use with B_OVERFLOW type items. It would only * require extracting the total length, and page number, dependent on the * DBT type. * * PUBLIC: int __db_coff __P((DB *, DB_THREAD_INFO *, DB_TXN *, const DBT *, * PUBLIC: const DBT *, int (*)(DB *, const DBT *, const DBT *), int *)); */ int __db_coff(dbp, ip, txn, dbt, match, cmpfunc, cmpp) DB *dbp; DB_THREAD_INFO *ip; DB_TXN *txn; const DBT *dbt, *match; int (*cmpfunc) __P((DB *, const DBT *, const DBT *)), *cmpp; { DBT local_key, local_match; DB_MPOOLFILE *mpf; PAGE *dbt_pagep, *match_pagep; db_pgno_t dbt_pgno, match_pgno; u_int32_t cmp_bytes, dbt_bufsz, dbt_len, match_bufsz; u_int32_t match_len, max_data, page_sz; u_int8_t *p1, *p2; int ret; void *dbt_buf, *match_buf; mpf = dbp->mpf; page_sz = dbp->pgsize; *cmpp = 0; dbt_buf = match_buf = NULL; DB_ASSERT(dbp->env, HPAGE_PTYPE(dbt->data) == H_OFFPAGE); DB_ASSERT(dbp->env, HPAGE_PTYPE(match->data) == H_OFFPAGE); /* Extract potentially unaligned length and pgno fields from DBTs */ memcpy(&dbt_len, HOFFPAGE_TLEN(dbt->data), sizeof(u_int32_t)); memcpy(&dbt_pgno, HOFFPAGE_PGNO(dbt->data), sizeof(db_pgno_t)); memcpy(&match_len, HOFFPAGE_TLEN(match->data), sizeof(u_int32_t)); memcpy(&match_pgno, HOFFPAGE_PGNO(match->data), sizeof(db_pgno_t)); max_data = (dbt_len < match_len ? dbt_len : match_len); /* * If there is a custom comparator, fully resolve both DBTs. * Then call the users comparator. */ if (cmpfunc != NULL) { memset(&local_key, 0, sizeof(local_key)); memset(&local_match, 0, sizeof(local_match)); dbt_buf = match_buf = NULL; dbt_bufsz = match_bufsz = 0; if ((ret = __db_goff(dbp, ip, txn, &local_key, dbt_len, dbt_pgno, &dbt_buf, &dbt_bufsz)) != 0) goto err1; if ((ret = __db_goff(dbp, ip, txn, &local_match, match_len, match_pgno, &match_buf, &match_bufsz)) != 0) goto err1; /* The key needs to be the first argument for sort order */ *cmpp = cmpfunc(dbp, &local_key, &local_match); err1: if (dbt_buf != NULL) __os_free(dbp->env, dbt_buf); if (match_buf != NULL) __os_free(dbp->env, match_buf); return (ret); } /* Match the offpage DBTs a page at a time. */ while (dbt_pgno != PGNO_INVALID && match_pgno != PGNO_INVALID) { if ((ret = __memp_fget(mpf, &dbt_pgno, ip, txn, 0, &dbt_pagep)) != 0) return (ret); if ((ret = __memp_fget(mpf, &match_pgno, ip, txn, 0, &match_pagep)) != 0) { (void)__memp_fput( mpf, ip, dbt_pagep, DB_PRIORITY_UNCHANGED); return (ret); } cmp_bytes = page_sz < max_data ? page_sz : max_data; for (p1 = (u_int8_t *)dbt_pagep + P_OVERHEAD(dbp), p2 = (u_int8_t *)match_pagep + P_OVERHEAD(dbp); cmp_bytes-- > 0; ++p1, ++p2) if (*p1 != *p2) { *cmpp = (long)*p1 - (long)*p2; break; } dbt_pgno = NEXT_PGNO(dbt_pagep); match_pgno = NEXT_PGNO(match_pagep); max_data -= page_sz; if ((ret = __memp_fput(mpf, ip, dbt_pagep, DB_PRIORITY_UNCHANGED)) != 0) { (void)__memp_fput(mpf, ip, match_pagep, DB_PRIORITY_UNCHANGED); return (ret); } if ((ret = __memp_fput(mpf, ip, match_pagep, DB_PRIORITY_UNCHANGED)) != 0) return (ret); if (*cmpp != 0) return (0); } /* If a lexicographic mismatch was found, then the result has already * been returned. If the DBTs matched, consider the lengths of the * items, and return appropriately. */ if (dbt_len > match_len) /* DBT is longer than the match key. */ *cmpp = 1; else if (match_len > dbt_len) /* DBT is shorter than the match key. */ *cmpp = -1; else *cmpp = 0; return (0); }