/*- * See the file LICENSE for redistribution information. * * Copyright (c) 2000 * Sleepycat Software. All rights reserved. * * $Id: db_vrfy.c,v 1.2 2002/02/02 18:18:05 ghutchis Exp $ */ #include "htconfig.h" #ifndef lint static const char revid[] = "$Id: db_vrfy.c,v 1.2 2002/02/02 18:18:05 ghutchis Exp $"; #endif /* not lint */ #ifndef NO_SYSTEM_INCLUDES #include #include #include #endif #include "db_int.h" #include "db_page.h" #include "db_swap.h" #include "db_verify.h" #include "db_ext.h" #include "btree.h" #include "hash.h" #include "qam.h" static int __db_guesspgsize __P((DB_ENV *, DB_FH *)); static int __db_is_valid_magicno __P((u_int32_t, DBTYPE *)); static int __db_is_valid_pagetype __P((u_int32_t)); static int __db_meta2pgset __P((DB *, VRFY_DBINFO *, db_pgno_t, u_int32_t, DB *)); static int __db_salvage_subdbs __P((DB *, VRFY_DBINFO *, void *, int(*)(void *, const void *), u_int32_t, int *)); static int __db_salvage_unknowns __P((DB *, VRFY_DBINFO *, void *, int (*)(void *, const void *), u_int32_t)); static int __db_vrfy_common __P((DB *, VRFY_DBINFO *, PAGE *, db_pgno_t, u_int32_t)); static int __db_vrfy_freelist __P((DB *, VRFY_DBINFO *, db_pgno_t, u_int32_t)); static int __db_vrfy_invalid __P((DB *, VRFY_DBINFO *, PAGE *, db_pgno_t, u_int32_t)); static int __db_vrfy_orderchkonly __P((DB *, VRFY_DBINFO *, const char *, const char *, u_int32_t)); static int __db_vrfy_pagezero __P((DB *, VRFY_DBINFO *, DB_FH *, u_int32_t)); static int __db_vrfy_subdbs __P((DB *, VRFY_DBINFO *, char *, u_int32_t)); static int __db_vrfy_structure __P((DB *, VRFY_DBINFO *, char *, db_pgno_t, u_int32_t)); static int __db_vrfy_walkpages __P((DB *, VRFY_DBINFO *, void *, int (*)(void *, const void *), u_int32_t)); /* * This is the code for DB->verify, the DB database consistency checker. * For now, it checks all subdatabases in a database, and verifies * everything it knows how to (i.e. it's all-or-nothing, and one can't * check only for a subset of possible problems). */ /* * CDB___db_verify -- * Walk the entire file page-by-page, either verifying with or without * dumping in db_dump -d format, or DB_SALVAGE-ing whatever key/data * pairs can be found and dumping them in standard (db_load-ready) * dump format. * * (Salvaging isn't really a verification operation, but we put it * here anyway because it requires essentially identical top-level * code.) * * flags may be 0, DB_NOORDERCHK, DB_ORDERCHKONLY, or DB_SALVAGE * (and optionally DB_AGGRESSIVE). * * CDB___db_verify itself is simply a wrapper to CDB___db_verify_internal, * which lets us pass appropriate equivalents to FILE * in from the * non-C APIs. * * PUBLIC: int CDB___db_verify * PUBLIC: __P((DB *, const char *, const char *, FILE *, u_int32_t)); */ int CDB___db_verify(dbp, file, database, outfile, flags) DB *dbp; const char *file, *database; FILE *outfile; u_int32_t flags; { return (CDB___db_verify_internal(dbp, file, database, outfile, CDB___db_verify_callback, flags)); } /* * CDB___db_verify_callback -- * Callback function for using pr_* functions from C. * * PUBLIC: int CDB___db_verify_callback __P((void *, const void *)); */ int CDB___db_verify_callback(handle, str_arg) void *handle; const void *str_arg; { char *str; FILE *f; str = (char *)str_arg; f = (FILE *)handle; if (fprintf(f, str) != (int)strlen(str)) return (EIO); return (0); } /* * CDB___db_verify_internal -- * Inner meat of CDB___db_verify. * * PUBLIC: int CDB___db_verify_internal __P((DB *, const char *, * PUBLIC: const char *, void *, int (*)(void *, const void *), u_int32_t)); */ int CDB___db_verify_internal(dbp_orig, name, subdb, handle, callback, flags) DB *dbp_orig; const char *name, *subdb; void *handle; int (*callback) __P((void *, const void *)); u_int32_t flags; { DB *dbp; DB_ENV *dbenv; DB_FH fh, *fhp; PAGE *h; VRFY_DBINFO *vdp; db_pgno_t last; int has, ret, isbad; char *real_name; dbenv = dbp_orig->dbenv; vdp = NULL; real_name = NULL; ret = isbad = 0; memset(&fh, 0, sizeof(fh)); fhp = &fh; PANIC_CHECK(dbenv); DB_ILLEGAL_AFTER_OPEN(dbp_orig, "verify"); #define OKFLAGS (DB_AGGRESSIVE | DB_NOORDERCHK | DB_ORDERCHKONLY | DB_SALVAGE) if ((ret = CDB___db_fchk(dbenv, "DB->verify", flags, OKFLAGS)) != 0) return (ret); /* * DB_SALVAGE is mutually exclusive with the other flags except * DB_AGGRESSIVE. */ if (LF_ISSET(DB_SALVAGE) && (flags & ~DB_AGGRESSIVE) != DB_SALVAGE) return (CDB___db_ferr(dbenv, "CDB___db_verify", 1)); if (LF_ISSET(DB_ORDERCHKONLY) && flags != DB_ORDERCHKONLY) return (CDB___db_ferr(dbenv, "CDB___db_verify", 1)); if (LF_ISSET(DB_ORDERCHKONLY) && subdb == NULL) { CDB___db_err(dbenv, "DB_ORDERCHKONLY requires a database name"); return (EINVAL); } /* * Forbid working in an environment that uses transactions or * locking; we're going to be looking at the file freely, * and while we're not going to modify it, we aren't obeying * locking conventions either. */ if (TXN_ON(dbenv) || LOCKING_ON(dbenv) || LOGGING_ON(dbenv)) { dbp_orig->errx(dbp_orig, "verify may not be used with transactions, logging, or locking"); return (EINVAL); /* NOTREACHED */ } /* Create a dbp to use internally, which we can close at our leisure. */ if ((ret = CDB_db_create(&dbp, dbenv, 0)) != 0) goto err; /* Copy the supplied pagesize, which we use if the file one is bogus. */ if (dbp_orig->pgsize >= DB_MIN_PGSIZE && dbp_orig->pgsize <= DB_MAX_PGSIZE) dbp->set_pagesize(dbp, dbp_orig->pgsize); /* * We don't know how large the cache is, and if the database * in question uses a small page size--which we don't know * yet!--it may be uncomfortably small for the default page * size [#2143]. However, the things we need temporary * databases for in dbinfo are largely tiny, so using a * 1024-byte pagesize is probably not going to be a big hit, * and will make us fit better into small spaces. */ if ((ret = CDB___db_vrfy_dbinfo_create(dbenv, 1024, &vdp)) != 0) goto err; /* Find the real name of the file. */ if ((ret = CDB___db_appname(dbenv, DB_APP_DATA, NULL, name, 0, NULL, &real_name)) != 0) goto err; /* * Our first order of business is to verify page 0, which is * the metadata page for the master database of subdatabases * or of the only database in the file. We want to do this by hand * rather than just calling CDB___db_open in case it's corrupt--various * things in CDB___db_open might act funny. * * Once we know the metadata page is healthy, I believe that it's * safe to open the database normally and then use the page swapping * code, which makes life easier. */ if ((ret = CDB___os_open(dbenv, real_name, DB_OSO_RDONLY, 0444, fhp)) != 0) goto err; /* Verify the metadata page 0; set pagesize and type. */ if ((ret = __db_vrfy_pagezero(dbp, vdp, fhp, flags)) != 0) { if (ret == DB_VERIFY_BAD) isbad = 1; else goto err; } /* * We can assume at this point that dbp->pagesize and dbp->type are * set correctly, or at least as well as they can be, and that * locking, logging, and txns are not in use. Thus we can trust * the memp code not to look at the page, and thus to be safe * enough to use. * * The dbp is not open, but the file is open in the fhp, and we * cannot assume that CDB___db_open is safe. Call CDB___db_dbenv_setup, * the [safe] part of CDB___db_open that initializes the environment-- * and the mpool--manually. */ if ((ret = CDB___db_dbenv_setup(dbp, name, DB_ODDFILESIZE | DB_RDONLY)) != 0) return (ret); /* * Find out the page number of the last page in the database. * * XXX: This currently fails if the last page is of bad type, * because it calls CDB___db_pgin and that pukes. This is bad. */ if ((ret = CDB_memp_fget(dbp->mpf, &last, DB_MPOOL_LAST, &h)) != 0) goto err; if ((ret = CDB_memp_fput(dbp->mpf, h, 0)) != 0) goto err; vdp->last_pgno = last; /* * DB_ORDERCHKONLY is a special case; our file consists of * several subdatabases, which use different hash, bt_compare, * and/or dup_compare functions. Consequently, we couldn't verify * sorting and hashing simply by calling DB->verify() on the file. * DB_ORDERCHKONLY allows us to come back and check those things; it * requires a subdatabase, and assumes that everything but that * database's sorting/hashing is correct. */ if (LF_ISSET(DB_ORDERCHKONLY)) { ret = __db_vrfy_orderchkonly(dbp, vdp, name, subdb, flags); goto done; } /* * When salvaging, we use a db to keep track of whether we've seen a * given overflow or dup page in the course of traversing normal data. * If in the end we have not, we assume its key got lost and print it * with key "UNKNOWN". */ if (LF_ISSET(DB_SALVAGE)) { if ((ret = CDB___db_salvage_init(vdp)) != 0) return (ret); /* * If we're not being aggressive, attempt to crack subdbs. * "has" will indicate whether the attempt has succeeded * (even in part), meaning that we have some semblance of * subdbs; on the walkpages pass, we print out * whichever data pages we have not seen. */ has = 0; if (!LF_ISSET(DB_AGGRESSIVE) && (__db_salvage_subdbs(dbp, vdp, handle, callback, flags, &has)) != 0) isbad = 1; /* * If we have subdatabases, we need to signal that if * any keys are found that don't belong to a subdatabase, * they'll need to have an "__OTHER__" subdatabase header * printed first. Flag this. Else, print a header for * the normal, non-subdb database. */ if (has == 1) F_SET(vdp, SALVAGE_PRINTHEADER); else if ((ret = CDB___db_prheader(dbp, NULL, 0, 0, handle, callback, vdp, PGNO_BASE_MD)) != 0) goto err; } if ((ret = __db_vrfy_walkpages(dbp, vdp, handle, callback, flags)) != 0) { if (ret == DB_VERIFY_BAD) isbad = 1; else if (ret != 0) goto err; } /* If we're verifying, verify inter-page structure. */ if (!LF_ISSET(DB_SALVAGE) && isbad == 0) if ((ret = __db_vrfy_structure(dbp, vdp, real_name, 0, flags)) != 0) { if (ret == DB_VERIFY_BAD) isbad = 1; else if (ret != 0) goto err; } /* * If we're salvaging, output with key UNKNOWN any overflow or dup pages * we haven't been able to put in context. Then destroy the salvager's * state-saving database. */ if (LF_ISSET(DB_SALVAGE)) { if ((ret = __db_salvage_unknowns(dbp, vdp, handle, callback, flags)) != 0) isbad = 1; /* No return value, since there's little we can do. */ CDB___db_salvage_destroy(vdp); } if (0) { err: (void)CDB___db_err(dbenv, "%s: %s", name, CDB_db_strerror(ret)); } if (LF_ISSET(DB_SALVAGE) && (has == 0 || F_ISSET(vdp, SALVAGE_PRINTFOOTER))) (void)CDB___db_prfooter(handle, callback); done: if (F_ISSET(fhp, DB_FH_VALID)) (void)CDB___os_closehandle(fhp); if (dbp) (void)dbp->close(dbp, 0); if (vdp) (void)CDB___db_vrfy_dbinfo_destroy(vdp); if (real_name) CDB___os_freestr(real_name); if ((ret == 0 && isbad == 1) || ret == DB_VERIFY_FATAL) ret = DB_VERIFY_BAD; return (ret); } /* * __db_vrfy_pagezero -- * Verify the master metadata page. Use seek, read, and a local buffer * rather than the DB paging code, for safety. * * Must correctly (or best-guess) set dbp->type and dbp->pagesize. */ static int __db_vrfy_pagezero(dbp, vdp, fhp, flags) DB *dbp; VRFY_DBINFO *vdp; DB_FH *fhp; u_int32_t flags; { DBMETA *meta; DB_ENV *dbenv; VRFY_PAGEINFO *pip; db_pgno_t freelist; int t_ret, ret, nr, swapped; u_int8_t mbuf[DBMETASIZE]; swapped = ret = t_ret = 0; freelist = 0; dbenv = dbp->dbenv; meta = (DBMETA *)mbuf; dbp->type = DB_UNKNOWN; /* * Seek to the metadata page. * Note that if we're just starting a verification, dbp->pgsize * may be zero; this is okay, as we want page zero anyway and * 0*0 == 0. */ if ((ret = CDB___os_seek(dbenv, fhp, 0, 0, 0, 0, DB_OS_SEEK_SET)) != 0) goto err; if ((ret = CDB___os_read(dbenv, fhp, mbuf, DBMETASIZE, (size_t *)&nr)) != 0) goto err; if (nr != DBMETASIZE) { EPRINT((dbp->dbenv, "Incomplete metadata page %lu", PGNO_BASE_MD)); t_ret = DB_VERIFY_FATAL; goto err; } /* * Check all of the fields that we can. */ /* 08-11: Current page number. Must == pgno. */ /* Note that endianness doesn't matter--it's zero. */ if (meta->pgno != PGNO_BASE_MD) { EPRINT((dbp->dbenv, "Bad pgno: was %lu, should be %lu", meta->pgno, PGNO_BASE_MD)); ret = DB_VERIFY_BAD; } /* 12-15: Magic number. Must be one of valid set. */ if (__db_is_valid_magicno(meta->magic, &dbp->type)) swapped = 0; else { M_32_SWAP(meta->magic); if (__db_is_valid_magicno(meta->magic, &dbp->type)) swapped = 1; else { EPRINT((dbp->dbenv, "Bad magic no.: %lu", meta->magic)); ret = DB_VERIFY_BAD; } } /* * 16-19: Version. Must be current; for now, we * don't support verification of old versions. */ if (swapped) M_32_SWAP(meta->version); if ((dbp->type == DB_BTREE && meta->version != DB_BTREEVERSION) || (dbp->type == DB_HASH && meta->version != DB_HASHVERSION) || (dbp->type == DB_QUEUE && meta->version != DB_QAMVERSION)) { ret = DB_VERIFY_BAD; EPRINT((dbp->dbenv, "%s%s", "Old or incorrect DB ", "version; extraneous errors may result")); } /* * 20-23: Pagesize. Must be power of two, * greater than 512, and less than 64K. */ if (swapped) M_32_SWAP(meta->pagesize); if (IS_VALID_PAGESIZE(meta->pagesize)) dbp->pgsize = meta->pagesize; else { EPRINT((dbp->dbenv, "Bad page size: %lu", meta->pagesize)); ret = DB_VERIFY_BAD; /* * Now try to settle on a pagesize to use. * If the user-supplied one is reasonable, * use it; else, guess. */ if (!IS_VALID_PAGESIZE(dbp->pgsize)) dbp->pgsize = __db_guesspgsize(dbenv, fhp); } /* * 25: Page type. Must be correct for dbp->type, * which is by now set as well as it can be. */ /* Needs no swapping--only one byte! */ if ((dbp->type == DB_BTREE && meta->type != P_BTREEMETA) || (dbp->type == DB_HASH && meta->type != P_HASHMETA) || (dbp->type == DB_QUEUE && meta->type != P_QAMMETA)) { ret = DB_VERIFY_BAD; EPRINT((dbp->dbenv, "Bad page type: %lu", meta->type)); } /* * 28-31: Free list page number. * We'll verify its sensibility when we do inter-page * verification later; for now, just store it. */ if (swapped) M_32_SWAP(meta->free); freelist = meta->free; /* * Initialize vdp->pages to fit a single pageinfo structure for * this one page. We'll realloc later when we know how many * pages there are. */ if ((ret = CDB___db_vrfy_getpageinfo(vdp, PGNO_BASE_MD, &pip)) != 0) return (ret); pip->pgno = PGNO_BASE_MD; pip->type = meta->type; /* * Signal that we still have to check the info specific to * a given type of meta page. */ F_SET(pip, VRFY_INCOMPLETE); pip->free = freelist; if ((ret = CDB___db_vrfy_putpageinfo(vdp, pip)) != 0) return (ret); if (0) { err: CDB___db_err(dbenv, "%s", CDB_db_strerror(ret)); } if (swapped == 1) F_SET(dbp, DB_AM_SWAP); if (t_ret != 0) ret = t_ret; return (ret); } /* * __db_vrfy_walkpages -- * Main loop of the verifier/salvager. Walks through, * page by page, and verifies all pages and/or prints all data pages. */ static int __db_vrfy_walkpages(dbp, vdp, handle, callback, flags) DB *dbp; VRFY_DBINFO *vdp; void *handle; int (*callback) __P((void *, const void *)); u_int32_t flags; { DB_ENV *dbenv; PAGE *h; db_pgno_t i; int ret, t_ret, isbad; ret = isbad = t_ret = 0; dbenv = dbp->dbenv; if ((ret = CDB___db_fchk(dbenv, "__db_vrfy_walkpages", flags, OKFLAGS)) != 0) return (ret); for (i = 0; i <= vdp->last_pgno; i++) { /* * If DB_SALVAGE is set, we inspect our database of * completed pages, and skip any we've already printed in * the subdb pass. */ if (LF_ISSET(DB_SALVAGE) && (CDB___db_salvage_isdone(vdp, i) != 0)) continue; /* If an individual page get fails, keep going. */ if ((t_ret = CDB_memp_fget(dbp->mpf, &i, 0, &h)) != 0) { if (ret == 0) ret = t_ret; continue; } if (LF_ISSET(DB_SALVAGE)) { /* * We pretty much don't want to quit unless a * bomb hits. May as well return that something * was screwy, however. */ if ((t_ret = CDB___db_salvage(dbp, vdp, i, h, handle, callback, flags)) != 0) { if (ret == 0) ret = t_ret; isbad = 1; } } else { /* * Verify info common to all page * types. */ if (i != PGNO_BASE_MD) if ((t_ret = __db_vrfy_common(dbp, vdp, h, i, flags)) == DB_VERIFY_BAD) isbad = 1; switch (TYPE(h)) { case P_INVALID: t_ret = __db_vrfy_invalid(dbp, vdp, h, i, flags); break; case __P_DUPLICATE: isbad = 1; EPRINT((dbp->dbenv, "Old-style dup page %lu", i)); break; case P_HASH: t_ret = CDB___ham_vrfy(dbp, vdp, h, i, flags); break; case P_IBTREE: case P_IRECNO: case P_LBTREE: case P_LDUP: t_ret = CDB___bam_vrfy(dbp, vdp, h, i, flags); break; case P_LRECNO: t_ret = CDB___ram_vrfy_leaf(dbp, vdp, h, i, flags); break; case P_OVERFLOW: t_ret = CDB___db_vrfy_overflow(dbp, vdp, h, i, flags); break; case P_HASHMETA: t_ret = CDB___ham_vrfy_meta(dbp, vdp, (HMETA *)h, i, flags); break; case P_BTREEMETA: t_ret = CDB___bam_vrfy_meta(dbp, vdp, (BTMETA *)h, i, flags); break; case P_QAMMETA: t_ret = CDB___qam_vrfy_meta(dbp, vdp, (QMETA *)h, i, flags); break; case P_QAMDATA: t_ret = CDB___qam_vrfy_data(dbp, vdp, (QPAGE *)h, i, flags); break; default: EPRINT((dbp->dbenv, "Unknown page type: %lu", TYPE(h))); isbad = 1; break; } /* * Set up error return. */ if (t_ret == DB_VERIFY_BAD) isbad = 1; else if (t_ret == DB_VERIFY_FATAL) goto err; else ret = t_ret; } if ((t_ret = CDB_memp_fput(dbp->mpf, h, 0)) != 0 && ret == 0) ret = t_ret; } if (0) { err: if ((t_ret = CDB_memp_fput(dbp->mpf, h, 0)) != 0) return (ret == 0 ? t_ret : ret); return (DB_VERIFY_BAD); } return ((isbad == 1 && ret == 0) ? DB_VERIFY_BAD : ret); } /* * __db_vrfy_structure-- * After a beginning-to-end walk through the database has been * completed, put together the information that has been collected * to verify the overall database structure. * * Should only be called if we want to do a database verification, * i.e. if DB_SALVAGE is not set. */ static int __db_vrfy_structure(dbp, vdp, dbname, meta_pgno, flags) DB *dbp; VRFY_DBINFO *vdp; char *dbname; db_pgno_t meta_pgno; u_int32_t flags; { DB *pgset; DB_ENV *dbenv; VRFY_PAGEINFO *pip; db_pgno_t i; int ret, isbad, hassubs, p; isbad = 0; pip = NULL; dbenv = dbp->dbenv; pgset = vdp->pgset; if ((ret = CDB___db_fchk(dbenv, "DB->verify", flags, OKFLAGS)) != 0) return (ret); if (LF_ISSET(DB_SALVAGE)) { CDB___db_err(dbenv, "__db_vrfy_structure called with DB_SALVAGE"); return (EINVAL); } /* * Call the appropriate function to downwards-traverse the db type. */ switch(dbp->type) { case DB_BTREE: case DB_RECNO: if ((ret = CDB___bam_vrfy_structure(dbp, vdp, 0, flags)) != 0) { if (ret == DB_VERIFY_BAD) isbad = 1; else goto err; } /* * If we have subdatabases and we know that the database is, * thus far, sound, it's safe to walk the tree of subdatabases. * Do so, and verify the structure of the databases within. */ if ((ret = CDB___db_vrfy_getpageinfo(vdp, 0, &pip)) != 0) goto err; hassubs = F_ISSET(pip, VRFY_HAS_SUBDBS); if ((ret = CDB___db_vrfy_putpageinfo(vdp, pip)) != 0) goto err; if (isbad == 0 && hassubs) if ((ret = __db_vrfy_subdbs(dbp, vdp, dbname, flags)) != 0) { if (ret == DB_VERIFY_BAD) isbad = 1; else goto err; } break; case DB_HASH: if ((ret = CDB___ham_vrfy_structure(dbp, vdp, 0, flags)) != 0) { if (ret == DB_VERIFY_BAD) isbad = 1; else goto err; } break; case DB_QUEUE: if ((ret = CDB___qam_vrfy_structure(dbp, vdp, flags)) != 0) { if (ret == DB_VERIFY_BAD) isbad = 1; } /* * Queue pages may be unreferenced and totally zeroed, if * they're empty; queue doesn't have much structure, so * this is unlikely to be wrong in any troublesome sense. * Skip to "err". */ goto err; /* NOTREACHED */ default: /* This should only happen if the verifier is somehow broken. */ DB_ASSERT(0); ret = EINVAL; goto err; /* NOTREACHED */ } /* Walk free list. */ if ((ret = __db_vrfy_freelist(dbp, vdp, meta_pgno, flags)) == DB_VERIFY_BAD) isbad = 1; /* * If structure checks up until now have failed, it's likely that * checking what pages have been missed will result in oodles of * extraneous error messages being EPRINTed. Skip to the end * if this is the case; we're going to be printing at least one * error anyway, and probably all the more salient ones. */ if (ret != 0 || isbad == 1) goto err; /* * Make sure no page has been missed and that no page is still marked * "all zeroes" (only certain hash pages can be, and they're unmarked * in CDB___ham_vrfy_structure). */ for (i = 0; i < vdp->last_pgno + 1; i++) { if ((ret = CDB___db_vrfy_getpageinfo(vdp, i, &pip)) != 0) goto err; if ((ret = CDB___db_vrfy_pgset_get(pgset, i, &p)) != 0) goto err; if (p == 0) { EPRINT((dbp->dbenv, "Unreferenced page %lu", i)); /* isbad = 1; */ /* XXX: this is a db bug */ if (pip->type != P_LRECNO && pip->type != P_LDUP) isbad = 1; } if (F_ISSET(pip, VRFY_IS_ALLZEROES)) { EPRINT((dbp->dbenv, "Totally zeroed page %lu", i)); isbad = 1; } if ((ret = CDB___db_vrfy_putpageinfo(vdp, pip)) != 0) goto err; pip = NULL; } err: if (pip != NULL) (void)CDB___db_vrfy_putpageinfo(vdp, pip); return ((isbad == 1 && ret == 0) ? DB_VERIFY_BAD : ret); } /* * __db_is_valid_pagetype */ static int __db_is_valid_pagetype(type) u_int32_t type; { switch (type) { case P_INVALID: /* Order matches ordinal value. */ case P_HASH: case P_IBTREE: case P_IRECNO: case P_LBTREE: case P_LRECNO: case P_OVERFLOW: case P_HASHMETA: case P_BTREEMETA: case P_QAMMETA: case P_QAMDATA: case P_LDUP: return (1); } return (0); } /* * __db_is_valid_magicno */ static int __db_is_valid_magicno(magic, typep) u_int32_t magic; DBTYPE *typep; { switch (magic) { case DB_BTREEMAGIC: *typep = DB_BTREE; return (1); case DB_HASHMAGIC: *typep = DB_HASH; return (1); case DB_QAMMAGIC: *typep = DB_QUEUE; return (1); } *typep = DB_UNKNOWN; return (0); } /* * __db_vrfy_common -- * Verify info common to all page types. */ static int __db_vrfy_common(dbp, vdp, h, pgno, flags) DB *dbp; VRFY_DBINFO *vdp; PAGE *h; db_pgno_t pgno; u_int32_t flags; { VRFY_PAGEINFO *pip; int ret, t_ret; u_int8_t *p; if ((ret = CDB___db_vrfy_getpageinfo(vdp, pgno, &pip)) != 0) return (ret); pip->pgno = pgno; F_CLR(pip, VRFY_IS_ALLZEROES); /* * Hash expands the table by leaving some pages between the * old last and the new last totally zeroed. Its pgin function * should fix things, but we might not be using that (e.g. if * we're a subdatabase). */ if (pgno != 0 && PGNO(h) == 0) { for (p = (u_int8_t *)h; p < (u_int8_t *)h + dbp->pgsize; p++) if (*p != 0) { EPRINT((dbp->dbenv, "Hash page %lu should be zeroed and is not", pgno)); ret = DB_VERIFY_BAD; goto err; } /* * It's totally zeroed; mark it as a hash, and we'll * check that that makes sense structurally later. */ pip->type = P_HASH; F_SET(pip, VRFY_IS_ALLZEROES); ret = 0; goto err; /* well, not really an err. */ } if (PGNO(h) != pgno) { EPRINT((dbp->dbenv, "Bad page number: %lu should be %lu", h->pgno, pgno)); ret = DB_VERIFY_BAD; } if (!__db_is_valid_pagetype(h->type)) { EPRINT((dbp->dbenv, "Bad page type: %lu", h->type)); ret = DB_VERIFY_BAD; } pip->type = h->type; err: if ((t_ret = CDB___db_vrfy_putpageinfo(vdp, pip)) != 0 && ret == 0) ret = t_ret; return (ret); } /* * __db_vrfy_invalid -- * Verify P_INVALID page. * (Yes, there's not much to do here.) */ static int __db_vrfy_invalid(dbp, vdp, h, pgno, flags) DB *dbp; VRFY_DBINFO *vdp; PAGE *h; db_pgno_t pgno; u_int32_t flags; { VRFY_PAGEINFO *pip; int ret, t_ret; if ((ret = CDB___db_vrfy_getpageinfo(vdp, pgno, &pip)) != 0) return (ret); pip->next_pgno = pip->prev_pgno = 0; if (!IS_VALID_PGNO(NEXT_PGNO(h))) { EPRINT((dbp->dbenv, "Invalid next_pgno %lu on page %lu", NEXT_PGNO(h), pgno)); ret = DB_VERIFY_BAD; } else pip->next_pgno = NEXT_PGNO(h); if ((t_ret = CDB___db_vrfy_putpageinfo(vdp, pip)) != 0 && ret == 0) ret = t_ret; return (ret); } /* * CDB___db_vrfy_datapage -- * Verify elements common to data pages (P_HASH, P_LBTREE, * P_IBTREE, P_IRECNO, P_LRECNO, P_OVERFLOW, P_DUPLICATE)--i.e., * those defined in the PAGE structure. * * Called from each of the per-page routines, after the * all-page-type-common elements of pip have been verified and filled * in. * * PUBLIC: int CDB___db_vrfy_datapage * PUBLIC: __P((DB *, VRFY_DBINFO *, PAGE *, db_pgno_t, u_int32_t)); */ int CDB___db_vrfy_datapage(dbp, vdp, h, pgno, flags) DB *dbp; VRFY_DBINFO *vdp; PAGE *h; db_pgno_t pgno; u_int32_t flags; { VRFY_PAGEINFO *pip; int isbad, ret, t_ret; if ((ret = CDB___db_vrfy_getpageinfo(vdp, pgno, &pip)) != 0) return (ret); isbad = 0; /* * prev_pgno and next_pgno: store for inter-page checks, * verify that they point to actual pages and not to self. * * !!! * Internal btree pages do not maintain these fields (indeed, * they overload them). Skip. */ if (TYPE(h) != P_IBTREE && TYPE(h) != P_IRECNO) { if (!IS_VALID_PGNO(PREV_PGNO(h)) || PREV_PGNO(h) == pip->pgno) { isbad = 1; EPRINT((dbp->dbenv, "Page %lu: Invalid prev_pgno %lu", pip->pgno, PREV_PGNO(h))); } if (!IS_VALID_PGNO(NEXT_PGNO(h)) || NEXT_PGNO(h) == pip->pgno) { isbad = 1; EPRINT((dbp->dbenv, "Page %lu: Invalid next_pgno %lu", pip->pgno, NEXT_PGNO(h))); } pip->prev_pgno = PREV_PGNO(h); pip->next_pgno = NEXT_PGNO(h); } /* * Verify the number of entries on the page. * There is no good way to determine if this is accurate; the * best we can do is verify that it's not more than can, in theory, * fit on the page. Then, we make sure there are at least * this many valid elements in inp[], and hope that this catches * most cases. */ if (TYPE(h) != P_OVERFLOW) { if (BKEYDATA_PSIZE(0) * NUM_ENT(h) > dbp->pgsize) { isbad = 1; EPRINT((dbp->dbenv, "Page %lu: Too many entries: %lu", pgno, NUM_ENT(h))); } pip->entries = NUM_ENT(h); } /* * btree level. Should be zero unless we're a btree; * if we are a btree, should be between LEAFLEVEL and MAXBTREELEVEL, * and we need to save it off. */ switch (TYPE(h)) { case P_IBTREE: case P_IRECNO: if (LEVEL(h) < LEAFLEVEL + 1 || LEVEL(h) > MAXBTREELEVEL) { isbad = 1; EPRINT((dbp->dbenv, "Bad btree level %lu on page %lu", LEVEL(h), pgno)); } pip->bt_level = LEVEL(h); break; case P_LBTREE: case P_LDUP: case P_LRECNO: if (LEVEL(h) != LEAFLEVEL) { isbad = 1; EPRINT((dbp->dbenv, "Btree leaf page %lu has incorrect level %lu", pgno, LEVEL(h))); } break; default: if (LEVEL(h) != 0) { isbad = 1; EPRINT((dbp->dbenv, "Nonzero level %lu in non-btree database page %lu", LEVEL(h), pgno)); } break; } /* * Even though inp[] occurs in all PAGEs, we look at it in the * access-method-specific code, since btree and hash treat * item lengths very differently, and one of the most important * things we want to verify is that the data--as specified * by offset and length--cover the right part of the page * without overlaps, gaps, or violations of the page boundary. */ if ((t_ret = CDB___db_vrfy_putpageinfo(vdp, pip)) != 0 && ret == 0) ret = t_ret; return ((ret == 0 && isbad == 1) ? DB_VERIFY_BAD : ret); } /* * CDB___db_vrfy_meta-- * Verify the access-method common parts of a meta page, using * normal mpool routines. * * PUBLIC: int CDB___db_vrfy_meta * PUBLIC: __P((DB *, VRFY_DBINFO *, DBMETA *, db_pgno_t, u_int32_t)); */ int CDB___db_vrfy_meta(dbp, vdp, meta, pgno, flags) DB *dbp; VRFY_DBINFO *vdp; DBMETA *meta; db_pgno_t pgno; u_int32_t flags; { DBTYPE dbtype, magtype; VRFY_PAGEINFO *pip; int isbad, ret, t_ret; isbad = 0; if ((ret = CDB___db_vrfy_getpageinfo(vdp, pgno, &pip)) != 0) return (ret); /* type plausible for a meta page */ switch (meta->type) { case P_BTREEMETA: dbtype = DB_BTREE; break; case P_HASHMETA: dbtype = DB_HASH; break; case P_QAMMETA: dbtype = DB_QUEUE; break; default: /* The verifier should never let us get here. */ DB_ASSERT(0); ret = EINVAL; goto err; } /* magic number valid */ if (!__db_is_valid_magicno(meta->magic, &magtype)) { isbad = 1; EPRINT((dbp->dbenv, "Magic number invalid on page %lu", pgno)); } if (magtype != dbtype) { isbad = 1; EPRINT((dbp->dbenv, "Magic number does not match type of page %lu", pgno)); } /* version */ if ((dbtype == DB_BTREE && meta->version != DB_BTREEVERSION) || (dbtype == DB_HASH && meta->version != DB_HASHVERSION) || (dbtype == DB_QUEUE && meta->version != DB_QAMVERSION)) { isbad = 1; EPRINT((dbp->dbenv, "%s%s", "Old of incorrect DB ", "version; extraneous errors may result")); } /* pagesize */ if (meta->pagesize != dbp->pgsize) { isbad = 1; EPRINT((dbp->dbenv, "Invalid pagesize %lu on page %lu", meta->pagesize, pgno)); } /* free list */ /* Can correctly be PGNO_INVALID--that's just the end of the list. */ if (meta->free != PGNO_INVALID && IS_VALID_PGNO(meta->free)) pip->free = meta->free; else if (!IS_VALID_PGNO(meta->free)) { isbad = 1; EPRINT((dbp->dbenv, "Nonsensical free list pgno %lu on page %lu", meta->free, pgno)); } err: if ((t_ret = CDB___db_vrfy_putpageinfo(vdp, pip)) != 0 && ret == 0) ret = t_ret; return ((ret == 0 && isbad == 1) ? DB_VERIFY_BAD : ret); } /* * __db_vrfy_freelist -- * Walk free list, checking off pages and verifying absence of * loops. */ static int __db_vrfy_freelist(dbp, vdp, meta, flags) DB *dbp; VRFY_DBINFO *vdp; db_pgno_t meta; u_int32_t flags; { DB *pgset; VRFY_PAGEINFO *pip; db_pgno_t pgno; int p, ret, t_ret; pgset = vdp->pgset; DB_ASSERT(pgset != NULL); if ((ret = CDB___db_vrfy_getpageinfo(vdp, meta, &pip)) != 0) return (ret); for (pgno = pip->free; pgno != PGNO_INVALID; pgno = pip->next_pgno) { if ((ret = CDB___db_vrfy_putpageinfo(vdp, pip)) != 0) return (ret); /* This shouldn't happen, but just in case. */ if (!IS_VALID_PGNO(pgno)) { EPRINT((dbp->dbenv, "Invalid next_pgno on free list page %lu", pgno)); return (DB_VERIFY_BAD); } /* Detect cycles. */ if ((ret = CDB___db_vrfy_pgset_get(pgset, pgno, &p)) != 0) return (ret); if (p != 0) { EPRINT((dbp->dbenv, "Page %lu encountered a second time on free list", pgno)); return (DB_VERIFY_BAD); } if ((ret = CDB___db_vrfy_pgset_inc(pgset, pgno)) != 0) return (ret); if ((ret = CDB___db_vrfy_getpageinfo(vdp, pgno, &pip)) != 0) return (ret); if (pip->type != P_INVALID) { EPRINT((dbp->dbenv, "Non-invalid page %lu on free list", pgno, pip->type)); ret = DB_VERIFY_BAD; /* unsafe to continue */ break; } } if ((t_ret = CDB___db_vrfy_putpageinfo(vdp, pip)) != 0) ret = t_ret; return (ret); } /* * __db_vrfy_subdbs -- * Walk the known-safe master database of subdbs with a cursor, * verifying the structure of each subdatabase we encounter. */ static int __db_vrfy_subdbs(dbp, vdp, dbname, flags) DB *dbp; VRFY_DBINFO *vdp; char *dbname; u_int32_t flags; { DB *mdbp; DBC *dbc; DBT key, data; VRFY_PAGEINFO *pip; db_pgno_t meta_pgno; int ret, t_ret, isbad; u_int8_t type; isbad = 0; dbc = NULL; if ((ret = CDB___db_master_open(dbp, dbname, DB_RDONLY, 0, &mdbp)) != 0) return (ret); if ((ret = CDB___db_icursor(mdbp, NULL, DB_BTREE, PGNO_INVALID, 0, &dbc)) != 0) goto err; memset(&key, 0, sizeof(key)); memset(&data, 0, sizeof(data)); while ((ret = dbc->c_get(dbc, &key, &data, DB_NEXT)) == 0) { if (data.size != sizeof(db_pgno_t)) { EPRINT((dbp->dbenv, "Database entry of invalid size")); isbad = 1; goto err; } memcpy(&meta_pgno, data.data, data.size); /* * Subdatabase meta pgnos are stored in network byte * order for cross-endian compatibility. Swap if appropriate. */ DB_NTOHL(&meta_pgno); if (meta_pgno == PGNO_INVALID || meta_pgno > vdp->last_pgno) { EPRINT((dbp->dbenv, "Database entry references invalid page %lu", meta_pgno)); isbad = 1; goto err; } if ((ret = CDB___db_vrfy_getpageinfo(vdp, meta_pgno, &pip)) != 0) goto err; type = pip->type; if ((ret = CDB___db_vrfy_putpageinfo(vdp, pip)) != 0) goto err; switch (type) { case P_BTREEMETA: if ((ret = CDB___bam_vrfy_structure( dbp, vdp, meta_pgno, flags)) != 0) { if (ret == DB_VERIFY_BAD) isbad = 1; else goto err; } break; case P_HASHMETA: if ((ret = CDB___ham_vrfy_structure( dbp, vdp, meta_pgno, flags)) != 0) { if (ret == DB_VERIFY_BAD) isbad = 1; else goto err; } break; case P_QAMMETA: default: EPRINT((dbp->dbenv, "Database entry references page %lu of invalid type %lu", meta_pgno, type)); ret = DB_VERIFY_BAD; goto err; /* NOTREACHED */ } } if (ret == DB_NOTFOUND) ret = 0; err: if (dbc != NULL && (t_ret = CDB___db_c_close(dbc)) != 0 && ret == 0) ret = t_ret; if ((t_ret = mdbp->close(mdbp, 0)) != 0 && ret == 0) ret = t_ret; return ((ret == 0 && isbad == 1) ? DB_VERIFY_BAD : ret); } /* * __db_vrfy_orderchkonly -- * Do an sort-order/hashing check on a known-otherwise-good subdb. */ static int __db_vrfy_orderchkonly(dbp, vdp, name, subdb, flags) DB *dbp; VRFY_DBINFO *vdp; const char *name, *subdb; u_int32_t flags; { BTMETA *btmeta; DB *mdbp, *pgset; DBC *pgsc; DBT key, data; HASH *h_internal; HMETA *hmeta; PAGE *h, *currpg; db_pgno_t meta_pgno, p, pgno; u_int32_t bucket; int t_ret, ret; currpg = h = NULL; pgsc = NULL; pgset = NULL; LF_CLR(DB_NOORDERCHK); /* Open the master database and get the meta_pgno for the subdb. */ if ((ret = CDB_db_create(&mdbp, NULL, 0)) != 0) return (ret); if ((ret = CDB___db_master_open(dbp, name, DB_RDONLY, 0, &mdbp)) != 0) goto err; memset(&key, 0, sizeof(key)); key.data = (void *)subdb; memset(&data, 0, sizeof(data)); if ((ret = dbp->get(dbp, NULL, &key, &data, 0)) != 0) goto err; if (data.size != sizeof(db_pgno_t)) { EPRINT((dbp->dbenv, "Database entry of invalid size")); ret = DB_VERIFY_BAD; goto err; } memcpy(&meta_pgno, data.data, data.size); if ((ret = CDB_memp_fget(dbp->mpf, &meta_pgno, 0, &h)) != 0) goto err; if ((ret = CDB___db_vrfy_pgset(dbp->dbenv, dbp->pgsize, &pgset)) != 0) goto err; switch (TYPE(h)) { case P_BTREEMETA: btmeta = (BTMETA *)h; if (F_ISSET(&btmeta->dbmeta, BTM_RECNO)) { /* Recnos have no order to check. */ ret = 0; goto err; } if ((ret = __db_meta2pgset(dbp, vdp, meta_pgno, flags, pgset)) != 0) goto err; if ((ret = pgset->cursor(pgset, NULL, &pgsc, 0)) != 0) goto err; while ((ret = CDB___db_vrfy_pgset_next(pgsc, &p)) == 0) { if ((ret = CDB_memp_fget(dbp->mpf, &p, 0, &currpg)) != 0) goto err; if ((ret = CDB___bam_vrfy_itemorder(dbp, NULL, currpg, p, NUM_ENT(currpg), 1, F_ISSET(&btmeta->dbmeta, BTM_DUP), flags)) != 0) goto err; if ((ret = CDB_memp_fput(dbp->mpf, currpg, 0)) != 0) goto err; currpg = NULL; } if ((ret = pgsc->c_close(pgsc)) != 0) goto err; break; case P_HASHMETA: hmeta = (HMETA *)h; h_internal = (HASH *)dbp->h_internal; /* * Make sure h_charkey is right. */ if (h_internal == NULL || h_internal->h_hash == NULL) { EPRINT((dbp->dbenv, "DB_ORDERCHKONLY requires that a hash function be set")); ret = DB_VERIFY_BAD; goto err; } if (hmeta->h_charkey != h_internal->h_hash(CHARKEY, sizeof(CHARKEY))) { EPRINT((dbp->dbenv, "Incorrect hash function for database")); ret = DB_VERIFY_BAD; goto err; } /* * Foreach bucket, verify hashing on each page in the * corresponding chain of pages. */ for (bucket = 0; bucket <= hmeta->max_bucket; bucket++) { pgno = hmeta->spares[CDB___db_log2(bucket + 1)]; while (pgno != PGNO_INVALID) { if ((ret = CDB_memp_fget(dbp->mpf, &pgno, 0, &currpg)) != 0) goto err; if ((ret = CDB___ham_vrfy_hashing(dbp, NUM_ENT(currpg),hmeta, bucket, pgno, flags, h_internal->h_hash)) != 0) goto err; pgno = NEXT_PGNO(currpg); if ((ret = CDB_memp_fput(dbp->mpf, currpg, 0)) != 0) goto err; currpg = NULL; } } break; default: EPRINT((dbp->dbenv, "Database meta page %lu of bad type %lu", meta_pgno, TYPE(h))); ret = DB_VERIFY_BAD; break; } err: if (pgsc != NULL) (void)pgsc->c_close(pgsc); if (pgset != NULL) (void)pgset->close(pgset, 0); if (h != NULL && (t_ret = CDB_memp_fput(dbp->mpf, h, 0)) != 0) ret = t_ret; if (currpg != NULL && (t_ret = CDB_memp_fput(dbp->mpf, currpg, 0)) != 0) ret = t_ret; if ((t_ret = mdbp->close(mdbp, 0)) != 0) ret = t_ret; return (ret); } /* * CDB___db_salvage -- * Walk through a page, salvaging all likely or plausible (w/ * DB_AGGRESSIVE) key/data pairs. * * PUBLIC: int CDB___db_salvage __P((DB *, VRFY_DBINFO *, db_pgno_t, PAGE *, * PUBLIC: void *, int (*)(void *, const void *), u_int32_t)); */ int CDB___db_salvage(dbp, vdp, pgno, h, handle, callback, flags) DB *dbp; VRFY_DBINFO *vdp; db_pgno_t pgno; PAGE *h; void *handle; int (*callback) __P((void *, const void *)); u_int32_t flags; { DB_ASSERT(LF_ISSET(DB_SALVAGE)); /* If we got this page in the subdb pass, we can safely skip it. */ if (CDB___db_salvage_isdone(vdp, pgno)) return (0); switch (TYPE(h)) { case P_HASH: return (CDB___ham_salvage(dbp, vdp, pgno, h, handle, callback, flags)); /* NOTREACHED */ case P_LBTREE: return (CDB___bam_salvage(dbp, vdp, pgno, P_LBTREE, h, handle, callback, NULL, flags)); /* NOTREACHED */ case P_LDUP: return (CDB___db_salvage_markneeded(vdp, pgno, SALVAGE_LDUP)); /* NOTREACHED */ case P_OVERFLOW: return (CDB___db_salvage_markneeded(vdp, pgno, SALVAGE_OVERFLOW)); /* NOTREACHED */ case P_LRECNO: /* * Recnos are tricky -- they may represent dup pages, or * they may be subdatabase/regular database pages in their * own right. If the former, they need to be printed with a * key, preferably when we hit the corresponding datum in * a btree/hash page. If the latter, there is no key. * * If a database is sufficiently frotzed, we're not going * to be able to get this right, so we best-guess: just * mark it needed now, and if we're really a normal recno * database page, the "unknowns" pass will pick us up. */ return (CDB___db_salvage_markneeded(vdp, pgno, SALVAGE_LRECNO)); /* NOTREACHED */ case P_IBTREE: case P_INVALID: case P_IRECNO: case __P_DUPLICATE: default: /* XXX: Should we be more aggressive here? */ break; } return (0); } /* * __db_salvage_unknowns -- * Walk through the salvager database, printing with key "UNKNOWN" * any pages we haven't dealt with. */ static int __db_salvage_unknowns(dbp, vdp, handle, callback, flags) DB *dbp; VRFY_DBINFO *vdp; void *handle; int (*callback) __P((void *, const void *)); u_int32_t flags; { DBT unkdbt, key, *dbt; PAGE *h; db_pgno_t pgno; u_int32_t pgtype; int ret, err_ret; void *ovflbuf; memset(&unkdbt, 0, sizeof(DBT)); unkdbt.size = strlen("UNKNOWN") + 1; unkdbt.data = "UNKNOWN"; if ((ret = CDB___os_malloc(dbp->dbenv, dbp->pgsize, 0, &ovflbuf)) != 0) return (ret); err_ret = 0; while ((ret = CDB___db_salvage_getnext(vdp, &pgno, &pgtype)) == 0) { dbt = NULL; if ((ret = CDB_memp_fget(dbp->mpf, &pgno, 0, &h)) != 0) { err_ret = ret; continue; } switch (pgtype) { case SALVAGE_LDUP: case SALVAGE_LRECNODUP: dbt = &unkdbt; /* FALLTHROUGH */ case SALVAGE_LBTREE: case SALVAGE_LRECNO: if ((ret = CDB___bam_salvage(dbp, vdp, pgno, pgtype, h, handle, callback, dbt, flags)) != 0) err_ret = ret; break; case SALVAGE_OVERFLOW: /* * XXX: * This may generate multiple "UNKNOWN" keys in * a database with no dups. What to do? */ if ((ret = CDB___db_safe_goff(dbp, vdp, pgno, &key, &ovflbuf, flags)) != 0) { err_ret = ret; continue; } if ((ret = CDB___db_prdbt(&key, 0, " ", handle, callback, 0, NULL)) != 0) { err_ret = ret; continue; } if ((ret = CDB___db_prdbt(&unkdbt, 0, " ", handle, callback, 0, NULL)) != 0) err_ret = ret; break; case SALVAGE_HASH: if ((ret = CDB___ham_salvage( dbp, vdp, pgno, h, handle, callback, flags)) != 0) err_ret = ret; break; case SALVAGE_INVALID: case SALVAGE_IGNORE: default: /* * Shouldn't happen, but if it does, just do what the * nice man says. */ DB_ASSERT(0); break; } if ((ret = CDB_memp_fput(dbp->mpf, h, 0)) != 0) err_ret = ret; } CDB___os_free(ovflbuf, 0); if (err_ret != 0 && ret == 0) ret = err_ret; return (ret == DB_NOTFOUND ? 0 : ret); } /* * Offset of the ith inp array entry, which we can compare to the offset * the entry stores. */ #define INP_OFFSET(h, i) \ ((db_indx_t)((u_int8_t *)(h)->inp + (i) - (u_int8_t *)(h))) /* * CDB___db_vrfy_inpitem -- * Verify that a single entry in the inp array is sane, and update * the high water mark and current item offset. (The former of these is * used for state information between calls, and is required; it must * be initialized to the pagesize before the first call.) * * Returns DB_VERIFY_FATAL if inp has collided with the data, * since verification can't continue from there; returns DB_VERIFY_BAD * if anything else is wrong. * * PUBLIC: int CDB___db_vrfy_inpitem __P((DB *, PAGE *, * PUBLIC: db_pgno_t, u_int32_t, int, u_int32_t, u_int32_t *, u_int32_t *)); */ int CDB___db_vrfy_inpitem(dbp, h, pgno, i, is_btree, flags, himarkp, offsetp) DB *dbp; PAGE *h; db_pgno_t pgno; u_int32_t i; int is_btree; u_int32_t flags, *himarkp, *offsetp; { BKEYDATA *bk; db_indx_t offset, len; DB_ASSERT(himarkp != NULL); /* * Check that the inp array, which grows from the beginning of the * page forward, has not collided with the data, which grow from the * end of the page backward. */ if ((u_int8_t *)h->inp + i >= (u_int8_t *)h + *himarkp) { /* We've collided with the data. We need to bail. */ EPRINT((dbp->dbenv, "Page %lu entries listing %lu overlaps data", pgno, i)); return (DB_VERIFY_FATAL); } offset = h->inp[i]; /* * Check that the item offset is reasonable: it points somewhere * after the inp array and before the end of the page. */ if (offset <= INP_OFFSET(h, i) || offset > dbp->pgsize) { EPRINT((dbp->dbenv, "Bad offset %lu at page %lu index %lu", offset, pgno, i)); return (DB_VERIFY_BAD); } /* Update the high-water mark (what HOFFSET should be) */ if (offset < *himarkp) *himarkp = offset; if (is_btree) { /* * Check that the item length remains on-page. */ bk = GET_BKEYDATA(h, i); len = B_TYPE(bk->type) == B_KEYDATA ? bk->len : BOVERFLOW_SIZE; if ((size_t)(offset + len) > dbp->pgsize) { EPRINT((dbp->dbenv, "Item %lu on page %lu extends past page boundary", i, pgno)); return (DB_VERIFY_BAD); } } if (offsetp != NULL) *offsetp = offset; return (0); } /* * CDB___db_vrfy_duptype-- * Given a page number and a set of flags to CDB___bam_vrfy_subtree, * verify that the dup tree type is correct--i.e., it's a recno * if DUPSORT is not set and a btree if it is. * * PUBLIC: int CDB___db_vrfy_duptype * PUBLIC: __P((DB *, VRFY_DBINFO *, db_pgno_t, u_int32_t)); */ int CDB___db_vrfy_duptype(dbp, vdp, pgno, flags) DB *dbp; VRFY_DBINFO *vdp; db_pgno_t pgno; u_int32_t flags; { VRFY_PAGEINFO *pip; int ret, isbad; isbad = 0; if ((ret = CDB___db_vrfy_getpageinfo(vdp, pgno, &pip)) != 0) return (ret); switch (pip->type) { case P_IBTREE: case P_LDUP: if (!LF_ISSET(ST_DUPSORT)) { EPRINT((dbp->dbenv, "Sorted duplicate set at page %lu in unsorted-dup database", pgno)); isbad = 1; } break; case P_IRECNO: case P_LRECNO: if (LF_ISSET(ST_DUPSORT)) { EPRINT((dbp->dbenv, "Unsorted duplicate set at page %lu in sorted-dup database", pgno)); isbad = 1; } break; default: EPRINT((dbp->dbenv, "Duplicate page %lu of inappropriate type %lu", pgno, pip->type)); isbad = 1; break; } if ((ret = CDB___db_vrfy_putpageinfo(vdp, pip)) != 0) return (ret); return (isbad == 1 ? DB_VERIFY_BAD : 0); } /* * CDB___db_salvage_duptree -- * Attempt to salvage a given duplicate tree, given its alleged root. * * The key that corresponds to this dup set has been passed to us * in DBT *key. Because data items follow keys, though, it has been * printed once already. * * The basic idea here is that pgno ought to be a P_LDUP, a P_LRECNO, a * P_IBTREE, or a P_IRECNO. If it's an internal page, use the verifier * functions to make sure it's safe; if it's not, we simply bail and the * data will have to be printed with no key later on. if it is safe, * recurse on each of its children. * * Whether or not it's safe, if it's a leaf page, CDB___bam_salvage it. * * At all times, use the DB hanging off vdp to mark and check what we've * done, so each page gets printed exactly once and we don't get caught * in any cycles. * * PUBLIC: int CDB___db_salvage_duptree __P((DB *, VRFY_DBINFO *, db_pgno_t, * PUBLIC: DBT *, void *, int (*)(void *, const void *), u_int32_t)); */ int CDB___db_salvage_duptree(dbp, vdp, pgno, key, handle, callback, flags) DB *dbp; VRFY_DBINFO *vdp; db_pgno_t pgno; DBT *key; void *handle; int (*callback) __P((void *, const void *)); u_int32_t flags; { PAGE *h; int ret, t_ret; if (pgno == PGNO_INVALID || !IS_VALID_PGNO(pgno)) return (DB_VERIFY_BAD); /* We have a plausible page. Try it. */ if ((ret = CDB_memp_fget(dbp->mpf, &pgno, 0, &h)) != 0) return (ret); switch (TYPE(h)) { case P_IBTREE: case P_IRECNO: if ((ret = __db_vrfy_common(dbp, vdp, h, pgno, flags)) != 0) goto err; if ((ret = CDB___bam_vrfy(dbp, vdp, h, pgno, flags | DB_NOORDERCHK)) != 0 || (ret = CDB___db_salvage_markdone(vdp, pgno)) != 0) goto err; /* * We have a known-healthy internal page. Walk it. */ if ((ret = CDB___bam_salvage_walkdupint(dbp, vdp, h, key, handle, callback, flags)) != 0) goto err; break; case P_LRECNO: case P_LDUP: if ((ret = CDB___bam_salvage(dbp, vdp, pgno, TYPE(h), h, handle, callback, key, flags)) != 0) goto err; break; default: ret = DB_VERIFY_BAD; goto err; /* NOTREACHED */ } err: if ((t_ret = CDB_memp_fput(dbp->mpf, h, 0)) != 0 && ret == 0) ret = t_ret; return (ret); } /* * __db_salvage_subdbs -- * Check and see if this database has subdbs; if so, try to salvage * them independently. */ static int __db_salvage_subdbs(dbp, vdp, handle, callback, flags, hassubsp) DB *dbp; VRFY_DBINFO *vdp; void *handle; int (*callback) __P((void *, const void *)); u_int32_t flags; int *hassubsp; { BTMETA *btmeta; DB *pgset; DBC *pgsc; PAGE *h; db_pgno_t p, meta_pgno; int ret, err_ret; err_ret = 0; pgsc = NULL; pgset = NULL; meta_pgno = PGNO_BASE_MD; if ((ret = CDB_memp_fget(dbp->mpf, &meta_pgno, 0, &h)) != 0) return (ret); if (TYPE(h) == P_BTREEMETA) btmeta = (BTMETA *)h; else { /* Not a btree metadata, ergo no subdbs, so just return. */ ret = 0; goto err; } /* If it's not a safe page, bail on the attempt. */ if ((ret = __db_vrfy_common(dbp, vdp, h, PGNO_BASE_MD, flags)) != 0 || (ret = CDB___bam_vrfy_meta(dbp, vdp, btmeta, PGNO_BASE_MD, flags)) != 0) goto err; if (!F_ISSET(&btmeta->dbmeta, BTM_SUBDB)) { /* No subdbs, just return. */ ret = 0; goto err; } /* We think we've got subdbs. Mark it so. */ *hassubsp = 1; if ((ret = CDB_memp_fput(dbp->mpf, h, 0)) != 0) return (ret); /* * We have subdbs. Try to crack them. * * To do so, get a set of leaf pages in the master * database, and then walk each of the valid ones, salvaging * subdbs as we go. If any prove invalid, just drop them; we'll * pick them up on a later pass. */ if ((ret = CDB___db_vrfy_pgset(dbp->dbenv, dbp->pgsize, &pgset)) != 0) return (ret); if ((ret = __db_meta2pgset(dbp, vdp, PGNO_BASE_MD, flags, pgset)) != 0) goto err; if ((ret = pgset->cursor(pgset, NULL, &pgsc, 0)) != 0) goto err; while ((ret = CDB___db_vrfy_pgset_next(pgsc, &p)) == 0) { if ((ret = CDB_memp_fget(dbp->mpf, &p, 0, &h)) != 0) { err_ret = ret; continue; } if ((ret = __db_vrfy_common(dbp, vdp, h, p, flags)) != 0 || (ret = CDB___bam_vrfy(dbp, vdp, h, p, flags | DB_NOORDERCHK)) != 0) goto nextpg; if (TYPE(h) != P_LBTREE) goto nextpg; else if ((ret = CDB___db_salvage_subdbpg( dbp, vdp, h, handle, callback, flags)) != 0) err_ret = ret; nextpg: if ((ret = CDB_memp_fput(dbp->mpf, h, 0)) != 0) err_ret = ret; } if (ret != DB_NOTFOUND) goto err; if ((ret = pgsc->c_close(pgsc)) != 0) goto err; ret = pgset->close(pgset, 0); return ((ret == 0 && err_ret != 0) ? err_ret : ret); /* NOTREACHED */ err: if (pgsc != NULL) (void)pgsc->c_close(pgsc); if (pgset != NULL) (void)pgset->close(pgset, 0); (void)CDB_memp_fput(dbp->mpf, h, 0); return (ret); } /* * CDB___db_salvage_subdbpg -- * Given a known-good leaf page in the master database, salvage all * leaf pages corresponding to each subdb. * * PUBLIC: int CDB___db_salvage_subdbpg * PUBLIC: __P((DB *, VRFY_DBINFO *, PAGE *, void *, * PUBLIC: int (*)(void *, const void *), u_int32_t)); */ int CDB___db_salvage_subdbpg(dbp, vdp, master, handle, callback, flags) DB *dbp; VRFY_DBINFO *vdp; PAGE *master; void *handle; int (*callback) __P((void *, const void *)); u_int32_t flags; { BKEYDATA *bkkey, *bkdata; BOVERFLOW *bo; DB *pgset; DBC *pgsc; DBT key; PAGE *subpg; db_indx_t i; db_pgno_t meta_pgno, p; int ret, err_ret, t_ret; char *subdbname; ret = err_ret = 0; subdbname = NULL; if ((ret = CDB___db_vrfy_pgset(dbp->dbenv, dbp->pgsize, &pgset)) != 0) return (ret); /* * For each entry, get and salvage the set of pages * corresponding to that entry. */ for (i = 0; i < NUM_ENT(master); i += P_INDX) { bkkey = GET_BKEYDATA(master, i); bkdata = GET_BKEYDATA(master, i + O_INDX); /* Get the subdatabase name. */ if (B_TYPE(bkkey->type) == B_OVERFLOW) { /* * We can, in principle anyway, have a subdb * name so long it overflows. Ick. */ bo = (BOVERFLOW *)bkkey; if ((ret = CDB___db_safe_goff(dbp, vdp, bo->pgno, &key, (void **)&subdbname, flags)) != 0) { err_ret = DB_VERIFY_BAD; continue; } /* Nul-terminate it. */ if ((ret = CDB___os_realloc(dbp->dbenv, key.size + 1, NULL, &subdbname)) != 0) goto err; subdbname[key.size] = '\0'; } else if (B_TYPE(bkkey->type == B_KEYDATA)) { if ((ret = CDB___os_realloc(dbp->dbenv, bkkey->len + 1, NULL, &subdbname)) != 0) goto err; memcpy(subdbname, bkkey->data, bkkey->len); subdbname[bkkey->len] = '\0'; } /* Get the corresponding pgno. */ if (bkdata->len != sizeof(db_pgno_t)) { err_ret = DB_VERIFY_BAD; continue; } memcpy(&meta_pgno, bkdata->data, sizeof(db_pgno_t)); /* If we can't get the subdb meta page, just skip the subdb. */ if (!IS_VALID_PGNO(meta_pgno) || (ret = CDB_memp_fget(dbp->mpf, &meta_pgno, 0, &subpg)) != 0) { err_ret = ret; continue; } /* * Verify the subdatabase meta page. This has two functions. * First, if it's bad, we have no choice but to skip the subdb * and let the pages just get printed on a later pass. Second, * the access-method-specific meta verification routines record * the various state info (such as the presence of dups) * that we need for CDB___db_prheader(). */ if ((ret = __db_vrfy_common(dbp, vdp, subpg, meta_pgno, flags)) != 0) { err_ret = ret; (void)CDB_memp_fput(dbp->mpf, subpg, 0); continue; } switch (TYPE(subpg)) { case P_BTREEMETA: if ((ret = CDB___bam_vrfy_meta(dbp, vdp, (BTMETA *)subpg, meta_pgno, flags)) != 0) { err_ret = ret; (void)CDB_memp_fput(dbp->mpf, subpg, 0); continue; } break; case P_HASHMETA: if ((ret = CDB___ham_vrfy_meta(dbp, vdp, (HMETA *)subpg, meta_pgno, flags)) != 0) { err_ret = ret; (void)CDB_memp_fput(dbp->mpf, subpg, 0); continue; } break; default: /* This isn't an appropriate page; skip this subdb. */ err_ret = DB_VERIFY_BAD; continue; /* NOTREACHED */ } if ((ret = CDB_memp_fput(dbp->mpf, subpg, 0)) != 0) { err_ret = ret; continue; } /* Print a subdatabase header. */ if ((ret = CDB___db_prheader(dbp, subdbname, 0, 0, handle, callback, vdp, meta_pgno)) != 0) goto err; if ((ret = __db_meta2pgset(dbp, vdp, meta_pgno, flags, pgset)) != 0) { err_ret = ret; continue; } if ((ret = pgset->cursor(pgset, NULL, &pgsc, 0)) != 0) goto err; while ((ret = CDB___db_vrfy_pgset_next(pgsc, &p)) == 0) { if ((ret = CDB_memp_fget(dbp->mpf, &p, 0, &subpg)) != 0) { err_ret = ret; continue; } if ((ret = CDB___db_salvage(dbp, vdp, p, subpg, handle, callback, flags)) != 0) err_ret = ret; if ((ret = CDB_memp_fput(dbp->mpf, subpg, 0)) != 0) err_ret = ret; } if (ret != DB_NOTFOUND) goto err; if ((ret = pgsc->c_close(pgsc)) != 0) goto err; if ((ret = CDB___db_prfooter(handle, callback)) != 0) goto err; } err: if (subdbname) CDB___os_free(subdbname, 0); if ((t_ret = pgset->close(pgset, 0)) != 0) ret = t_ret; if ((t_ret = CDB___db_salvage_markdone(vdp, PGNO(master))) != 0) return (t_ret); return ((err_ret != 0) ? err_ret : ret); } /* * __db_meta2pgset -- * Given a known-safe meta page number, return the set of pages * corresponding to the database it represents. Return DB_VERIFY_BAD if * it's not a suitable meta page or is invalid. */ static int __db_meta2pgset(dbp, vdp, pgno, flags, pgset) DB *dbp; VRFY_DBINFO *vdp; db_pgno_t pgno; u_int32_t flags; DB *pgset; { PAGE *h; int ret, t_ret; if ((ret = CDB_memp_fget(dbp->mpf, &pgno, 0, &h)) != 0) return (ret); switch (TYPE(h)) { case P_BTREEMETA: ret = CDB___bam_meta2pgset(dbp, vdp, (BTMETA *)h, flags, pgset); break; case P_HASHMETA: ret = CDB___ham_meta2pgset(dbp, vdp, (HMETA *)h, flags, pgset); break; default: ret = DB_VERIFY_BAD; break; } if ((t_ret = CDB_memp_fput(dbp->mpf, h, 0)) != 0) return (t_ret); return (ret); } /* * __db_guesspgsize -- * Try to guess what the pagesize is if the one on the meta page * and the one in the db are invalid. */ static int __db_guesspgsize(dbenv, fhp) DB_ENV *dbenv; DB_FH *fhp; { db_pgno_t i; size_t nr; u_int32_t guess; u_int8_t type; int ret; for (guess = DB_MAX_PGSIZE; guess >= DB_MIN_PGSIZE; guess >>= 1) { /* * We try to read three pages ahead after the first one * and make sure we have plausible types for all of them. * If the seeks fail, continue with a smaller size; * we're probably just looking past the end of the database. * If they succeed but the types are wrong, also continue * with a size smaller; we may be looking at pages N, * 2N, and 3N for some N > 1. * * As soon as we hit an invalid type, we stop and return * our best guess; the last one was probably the page size. */ for (i = 1; i <= 3; i++) { if ((ret = CDB___os_seek(dbenv, fhp, guess, i, SSZ(DBMETA, type), 0, DB_OS_SEEK_SET)) != 0) break; if ((ret = CDB___os_read(dbenv, fhp, &type, 1, &nr)) != 0 || nr == 0) break; if (type == P_INVALID || type >= P_PAGETYPE_MAX) break; } } return (guess); }