/*------------------------------------------------------------------------- * * bootstrap.c * routines to support running postgres in 'bootstrap' mode * bootstrap mode is used to create the initial template database * * Portions Copyright (c) 1996-2023, PostgreSQL Global Development Group * Portions Copyright (c) 1994, Regents of the University of California * * IDENTIFICATION * src/backend/bootstrap/bootstrap.c * *------------------------------------------------------------------------- */ #include "postgres.h" #include #include #include "access/genam.h" #include "access/heapam.h" #include "access/htup_details.h" #include "access/tableam.h" #include "access/toast_compression.h" #include "access/xact.h" #include "access/xlog_internal.h" #include "bootstrap/bootstrap.h" #include "catalog/index.h" #include "catalog/pg_collation.h" #include "catalog/pg_type.h" #include "common/link-canary.h" #include "libpq/pqsignal.h" #include "miscadmin.h" #include "nodes/makefuncs.h" #include "pg_getopt.h" #include "storage/bufmgr.h" #include "storage/bufpage.h" #include "storage/condition_variable.h" #include "storage/ipc.h" #include "storage/proc.h" #include "tcop/tcopprot.h" #include "utils/builtins.h" #include "utils/fmgroids.h" #include "utils/memutils.h" #include "utils/rel.h" #include "utils/relmapper.h" uint32 bootstrap_data_checksum_version = 0; /* No checksum */ static void CheckerModeMain(void); static void bootstrap_signals(void); static Form_pg_attribute AllocateAttribute(void); static void populate_typ_list(void); static Oid gettype(char *type); static void cleanup(void); /* ---------------- * global variables * ---------------- */ Relation boot_reldesc; /* current relation descriptor */ Form_pg_attribute attrtypes[MAXATTR]; /* points to attribute info */ int numattr; /* number of attributes for cur. rel */ /* * Basic information associated with each type. This is used before * pg_type is filled, so it has to cover the datatypes used as column types * in the core "bootstrapped" catalogs. * * XXX several of these input/output functions do catalog scans * (e.g., F_REGPROCIN scans pg_proc). this obviously creates some * order dependencies in the catalog creation process. */ struct typinfo { char name[NAMEDATALEN]; Oid oid; Oid elem; int16 len; bool byval; char align; char storage; Oid collation; Oid inproc; Oid outproc; }; static const struct typinfo TypInfo[] = { {"bool", BOOLOID, 0, 1, true, TYPALIGN_CHAR, TYPSTORAGE_PLAIN, InvalidOid, F_BOOLIN, F_BOOLOUT}, {"bytea", BYTEAOID, 0, -1, false, TYPALIGN_INT, TYPSTORAGE_EXTENDED, InvalidOid, F_BYTEAIN, F_BYTEAOUT}, {"char", CHAROID, 0, 1, true, TYPALIGN_CHAR, TYPSTORAGE_PLAIN, InvalidOid, F_CHARIN, F_CHAROUT}, {"int2", INT2OID, 0, 2, true, TYPALIGN_SHORT, TYPSTORAGE_PLAIN, InvalidOid, F_INT2IN, F_INT2OUT}, {"int4", INT4OID, 0, 4, true, TYPALIGN_INT, TYPSTORAGE_PLAIN, InvalidOid, F_INT4IN, F_INT4OUT}, {"float4", FLOAT4OID, 0, 4, true, TYPALIGN_INT, TYPSTORAGE_PLAIN, InvalidOid, F_FLOAT4IN, F_FLOAT4OUT}, {"name", NAMEOID, CHAROID, NAMEDATALEN, false, TYPALIGN_CHAR, TYPSTORAGE_PLAIN, C_COLLATION_OID, F_NAMEIN, F_NAMEOUT}, {"regclass", REGCLASSOID, 0, 4, true, TYPALIGN_INT, TYPSTORAGE_PLAIN, InvalidOid, F_REGCLASSIN, F_REGCLASSOUT}, {"regproc", REGPROCOID, 0, 4, true, TYPALIGN_INT, TYPSTORAGE_PLAIN, InvalidOid, F_REGPROCIN, F_REGPROCOUT}, {"regtype", REGTYPEOID, 0, 4, true, TYPALIGN_INT, TYPSTORAGE_PLAIN, InvalidOid, F_REGTYPEIN, F_REGTYPEOUT}, {"regrole", REGROLEOID, 0, 4, true, TYPALIGN_INT, TYPSTORAGE_PLAIN, InvalidOid, F_REGROLEIN, F_REGROLEOUT}, {"regnamespace", REGNAMESPACEOID, 0, 4, true, TYPALIGN_INT, TYPSTORAGE_PLAIN, InvalidOid, F_REGNAMESPACEIN, F_REGNAMESPACEOUT}, {"text", TEXTOID, 0, -1, false, TYPALIGN_INT, TYPSTORAGE_EXTENDED, DEFAULT_COLLATION_OID, F_TEXTIN, F_TEXTOUT}, {"oid", OIDOID, 0, 4, true, TYPALIGN_INT, TYPSTORAGE_PLAIN, InvalidOid, F_OIDIN, F_OIDOUT}, {"tid", TIDOID, 0, 6, false, TYPALIGN_SHORT, TYPSTORAGE_PLAIN, InvalidOid, F_TIDIN, F_TIDOUT}, {"xid", XIDOID, 0, 4, true, TYPALIGN_INT, TYPSTORAGE_PLAIN, InvalidOid, F_XIDIN, F_XIDOUT}, {"cid", CIDOID, 0, 4, true, TYPALIGN_INT, TYPSTORAGE_PLAIN, InvalidOid, F_CIDIN, F_CIDOUT}, {"pg_node_tree", PG_NODE_TREEOID, 0, -1, false, TYPALIGN_INT, TYPSTORAGE_EXTENDED, DEFAULT_COLLATION_OID, F_PG_NODE_TREE_IN, F_PG_NODE_TREE_OUT}, {"int2vector", INT2VECTOROID, INT2OID, -1, false, TYPALIGN_INT, TYPSTORAGE_PLAIN, InvalidOid, F_INT2VECTORIN, F_INT2VECTOROUT}, {"oidvector", OIDVECTOROID, OIDOID, -1, false, TYPALIGN_INT, TYPSTORAGE_PLAIN, InvalidOid, F_OIDVECTORIN, F_OIDVECTOROUT}, {"_int4", INT4ARRAYOID, INT4OID, -1, false, TYPALIGN_INT, TYPSTORAGE_EXTENDED, InvalidOid, F_ARRAY_IN, F_ARRAY_OUT}, {"_text", 1009, TEXTOID, -1, false, TYPALIGN_INT, TYPSTORAGE_EXTENDED, DEFAULT_COLLATION_OID, F_ARRAY_IN, F_ARRAY_OUT}, {"_oid", 1028, OIDOID, -1, false, TYPALIGN_INT, TYPSTORAGE_EXTENDED, InvalidOid, F_ARRAY_IN, F_ARRAY_OUT}, {"_char", 1002, CHAROID, -1, false, TYPALIGN_INT, TYPSTORAGE_EXTENDED, InvalidOid, F_ARRAY_IN, F_ARRAY_OUT}, {"_aclitem", 1034, ACLITEMOID, -1, false, TYPALIGN_INT, TYPSTORAGE_EXTENDED, InvalidOid, F_ARRAY_IN, F_ARRAY_OUT} }; static const int n_types = sizeof(TypInfo) / sizeof(struct typinfo); struct typmap { /* a hack */ Oid am_oid; FormData_pg_type am_typ; }; static List *Typ = NIL; /* List of struct typmap* */ static struct typmap *Ap = NULL; static Datum values[MAXATTR]; /* current row's attribute values */ static bool Nulls[MAXATTR]; static MemoryContext nogc = NULL; /* special no-gc mem context */ /* * At bootstrap time, we first declare all the indices to be built, and * then build them. The IndexList structure stores enough information * to allow us to build the indices after they've been declared. */ typedef struct _IndexList { Oid il_heap; Oid il_ind; IndexInfo *il_info; struct _IndexList *il_next; } IndexList; static IndexList *ILHead = NULL; /* * In shared memory checker mode, all we really want to do is create shared * memory and semaphores (just to prove we can do it with the current GUC * settings). Since, in fact, that was already done by * CreateSharedMemoryAndSemaphores(), we have nothing more to do here. */ static void CheckerModeMain(void) { proc_exit(0); } /* * The main entry point for running the backend in bootstrap mode * * The bootstrap mode is used to initialize the template database. * The bootstrap backend doesn't speak SQL, but instead expects * commands in a special bootstrap language. * * When check_only is true, startup is done only far enough to verify that * the current configuration, particularly the passed in options pertaining * to shared memory sizing, options work (or at least do not cause an error * up to shared memory creation). */ void BootstrapModeMain(int argc, char *argv[], bool check_only) { int i; char *progname = argv[0]; int flag; char *userDoption = NULL; Assert(!IsUnderPostmaster); InitStandaloneProcess(argv[0]); /* Set defaults, to be overridden by explicit options below */ InitializeGUCOptions(); /* an initial --boot or --check should be present */ Assert(argc > 1 && (strcmp(argv[1], "--boot") == 0 || strcmp(argv[1], "--check") == 0)); argv++; argc--; while ((flag = getopt(argc, argv, "B:c:d:D:Fkr:X:-:")) != -1) { switch (flag) { case 'B': SetConfigOption("shared_buffers", optarg, PGC_POSTMASTER, PGC_S_ARGV); break; case 'c': case '-': { char *name, *value; ParseLongOption(optarg, &name, &value); if (!value) { if (flag == '-') ereport(ERROR, (errcode(ERRCODE_SYNTAX_ERROR), errmsg("--%s requires a value", optarg))); else ereport(ERROR, (errcode(ERRCODE_SYNTAX_ERROR), errmsg("-c %s requires a value", optarg))); } SetConfigOption(name, value, PGC_POSTMASTER, PGC_S_ARGV); pfree(name); pfree(value); break; } case 'D': userDoption = pstrdup(optarg); break; case 'd': { /* Turn on debugging for the bootstrap process. */ char *debugstr; debugstr = psprintf("debug%s", optarg); SetConfigOption("log_min_messages", debugstr, PGC_POSTMASTER, PGC_S_ARGV); SetConfigOption("client_min_messages", debugstr, PGC_POSTMASTER, PGC_S_ARGV); pfree(debugstr); } break; case 'F': SetConfigOption("fsync", "false", PGC_POSTMASTER, PGC_S_ARGV); break; case 'k': bootstrap_data_checksum_version = PG_DATA_CHECKSUM_VERSION; break; case 'r': strlcpy(OutputFileName, optarg, MAXPGPATH); break; case 'X': { int WalSegSz = strtoul(optarg, NULL, 0); if (!IsValidWalSegSize(WalSegSz)) ereport(ERROR, (errcode(ERRCODE_INVALID_PARAMETER_VALUE), errmsg("-X requires a power of two value between 1 MB and 1 GB"))); SetConfigOption("wal_segment_size", optarg, PGC_INTERNAL, PGC_S_DYNAMIC_DEFAULT); } break; default: write_stderr("Try \"%s --help\" for more information.\n", progname); proc_exit(1); break; } } if (argc != optind) { write_stderr("%s: invalid command-line arguments\n", progname); proc_exit(1); } /* Acquire configuration parameters */ if (!SelectConfigFiles(userDoption, progname)) proc_exit(1); /* * Validate we have been given a reasonable-looking DataDir and change * into it */ checkDataDir(); ChangeToDataDir(); CreateDataDirLockFile(false); SetProcessingMode(BootstrapProcessing); IgnoreSystemIndexes = true; InitializeMaxBackends(); CreateSharedMemoryAndSemaphores(); /* * XXX: It might make sense to move this into its own function at some * point. Right now it seems like it'd cause more code duplication than * it's worth. */ if (check_only) { SetProcessingMode(NormalProcessing); CheckerModeMain(); abort(); } /* * Do backend-like initialization for bootstrap mode */ InitProcess(); BaseInit(); bootstrap_signals(); BootStrapXLOG(); /* * To ensure that src/common/link-canary.c is linked into the backend, we * must call it from somewhere. Here is as good as anywhere. */ if (pg_link_canary_is_frontend()) elog(ERROR, "backend is incorrectly linked to frontend functions"); InitPostgres(NULL, InvalidOid, NULL, InvalidOid, false, false, NULL); /* Initialize stuff for bootstrap-file processing */ for (i = 0; i < MAXATTR; i++) { attrtypes[i] = NULL; Nulls[i] = false; } /* * Process bootstrap input. */ StartTransactionCommand(); boot_yyparse(); CommitTransactionCommand(); /* * We should now know about all mapped relations, so it's okay to write * out the initial relation mapping files. */ RelationMapFinishBootstrap(); /* Clean up and exit */ cleanup(); proc_exit(0); } /* ---------------------------------------------------------------- * misc functions * ---------------------------------------------------------------- */ /* * Set up signal handling for a bootstrap process */ static void bootstrap_signals(void) { Assert(!IsUnderPostmaster); /* * We don't actually need any non-default signal handling in bootstrap * mode; "curl up and die" is a sufficient response for all these cases. * Let's set that handling explicitly, as documentation if nothing else. */ pqsignal(SIGHUP, SIG_DFL); pqsignal(SIGINT, SIG_DFL); pqsignal(SIGTERM, SIG_DFL); pqsignal(SIGQUIT, SIG_DFL); } /* ---------------------------------------------------------------- * MANUAL BACKEND INTERACTIVE INTERFACE COMMANDS * ---------------------------------------------------------------- */ /* ---------------- * boot_openrel * * Execute BKI OPEN command. * ---------------- */ void boot_openrel(char *relname) { int i; if (strlen(relname) >= NAMEDATALEN) relname[NAMEDATALEN - 1] = '\0'; /* * pg_type must be filled before any OPEN command is executed, hence we * can now populate Typ if we haven't yet. */ if (Typ == NIL) populate_typ_list(); if (boot_reldesc != NULL) closerel(NULL); elog(DEBUG4, "open relation %s, attrsize %d", relname, (int) ATTRIBUTE_FIXED_PART_SIZE); boot_reldesc = table_openrv(makeRangeVar(NULL, relname, -1), NoLock); numattr = RelationGetNumberOfAttributes(boot_reldesc); for (i = 0; i < numattr; i++) { if (attrtypes[i] == NULL) attrtypes[i] = AllocateAttribute(); memmove((char *) attrtypes[i], (char *) TupleDescAttr(boot_reldesc->rd_att, i), ATTRIBUTE_FIXED_PART_SIZE); { Form_pg_attribute at = attrtypes[i]; elog(DEBUG4, "create attribute %d name %s len %d num %d type %u", i, NameStr(at->attname), at->attlen, at->attnum, at->atttypid); } } } /* ---------------- * closerel * ---------------- */ void closerel(char *relname) { if (relname) { if (boot_reldesc) { if (strcmp(RelationGetRelationName(boot_reldesc), relname) != 0) elog(ERROR, "close of %s when %s was expected", relname, RelationGetRelationName(boot_reldesc)); } else elog(ERROR, "close of %s before any relation was opened", relname); } if (boot_reldesc == NULL) elog(ERROR, "no open relation to close"); else { elog(DEBUG4, "close relation %s", RelationGetRelationName(boot_reldesc)); table_close(boot_reldesc, NoLock); boot_reldesc = NULL; } } /* ---------------- * DEFINEATTR() * * define a pair * if there are n fields in a relation to be created, this routine * will be called n times * ---------------- */ void DefineAttr(char *name, char *type, int attnum, int nullness) { Oid typeoid; if (boot_reldesc != NULL) { elog(WARNING, "no open relations allowed with CREATE command"); closerel(NULL); } if (attrtypes[attnum] == NULL) attrtypes[attnum] = AllocateAttribute(); MemSet(attrtypes[attnum], 0, ATTRIBUTE_FIXED_PART_SIZE); namestrcpy(&attrtypes[attnum]->attname, name); elog(DEBUG4, "column %s %s", NameStr(attrtypes[attnum]->attname), type); attrtypes[attnum]->attnum = attnum + 1; typeoid = gettype(type); if (Typ != NIL) { attrtypes[attnum]->atttypid = Ap->am_oid; attrtypes[attnum]->attlen = Ap->am_typ.typlen; attrtypes[attnum]->attbyval = Ap->am_typ.typbyval; attrtypes[attnum]->attalign = Ap->am_typ.typalign; attrtypes[attnum]->attstorage = Ap->am_typ.typstorage; attrtypes[attnum]->attcompression = InvalidCompressionMethod; attrtypes[attnum]->attcollation = Ap->am_typ.typcollation; /* if an array type, assume 1-dimensional attribute */ if (Ap->am_typ.typelem != InvalidOid && Ap->am_typ.typlen < 0) attrtypes[attnum]->attndims = 1; else attrtypes[attnum]->attndims = 0; } else { attrtypes[attnum]->atttypid = TypInfo[typeoid].oid; attrtypes[attnum]->attlen = TypInfo[typeoid].len; attrtypes[attnum]->attbyval = TypInfo[typeoid].byval; attrtypes[attnum]->attalign = TypInfo[typeoid].align; attrtypes[attnum]->attstorage = TypInfo[typeoid].storage; attrtypes[attnum]->attcompression = InvalidCompressionMethod; attrtypes[attnum]->attcollation = TypInfo[typeoid].collation; /* if an array type, assume 1-dimensional attribute */ if (TypInfo[typeoid].elem != InvalidOid && attrtypes[attnum]->attlen < 0) attrtypes[attnum]->attndims = 1; else attrtypes[attnum]->attndims = 0; } /* * If a system catalog column is collation-aware, force it to use C * collation, so that its behavior is independent of the database's * collation. This is essential to allow template0 to be cloned with a * different database collation. */ if (OidIsValid(attrtypes[attnum]->attcollation)) attrtypes[attnum]->attcollation = C_COLLATION_OID; attrtypes[attnum]->attstattarget = -1; attrtypes[attnum]->attcacheoff = -1; attrtypes[attnum]->atttypmod = -1; attrtypes[attnum]->attislocal = true; if (nullness == BOOTCOL_NULL_FORCE_NOT_NULL) { attrtypes[attnum]->attnotnull = true; } else if (nullness == BOOTCOL_NULL_FORCE_NULL) { attrtypes[attnum]->attnotnull = false; } else { Assert(nullness == BOOTCOL_NULL_AUTO); /* * Mark as "not null" if type is fixed-width and prior columns are * likewise fixed-width and not-null. This corresponds to case where * column can be accessed directly via C struct declaration. */ if (attrtypes[attnum]->attlen > 0) { int i; /* check earlier attributes */ for (i = 0; i < attnum; i++) { if (attrtypes[i]->attlen <= 0 || !attrtypes[i]->attnotnull) break; } if (i == attnum) attrtypes[attnum]->attnotnull = true; } } } /* ---------------- * InsertOneTuple * * If objectid is not zero, it is a specific OID to assign to the tuple. * Otherwise, an OID will be assigned (if necessary) by heap_insert. * ---------------- */ void InsertOneTuple(void) { HeapTuple tuple; TupleDesc tupDesc; int i; elog(DEBUG4, "inserting row with %d columns", numattr); tupDesc = CreateTupleDesc(numattr, attrtypes); tuple = heap_form_tuple(tupDesc, values, Nulls); pfree(tupDesc); /* just free's tupDesc, not the attrtypes */ simple_heap_insert(boot_reldesc, tuple); heap_freetuple(tuple); elog(DEBUG4, "row inserted"); /* * Reset null markers for next tuple */ for (i = 0; i < numattr; i++) Nulls[i] = false; } /* ---------------- * InsertOneValue * ---------------- */ void InsertOneValue(char *value, int i) { Oid typoid; int16 typlen; bool typbyval; char typalign; char typdelim; Oid typioparam; Oid typinput; Oid typoutput; Assert(i >= 0 && i < MAXATTR); elog(DEBUG4, "inserting column %d value \"%s\"", i, value); typoid = TupleDescAttr(boot_reldesc->rd_att, i)->atttypid; boot_get_type_io_data(typoid, &typlen, &typbyval, &typalign, &typdelim, &typioparam, &typinput, &typoutput); values[i] = OidInputFunctionCall(typinput, value, typioparam, -1); /* * We use ereport not elog here so that parameters aren't evaluated unless * the message is going to be printed, which generally it isn't */ ereport(DEBUG4, (errmsg_internal("inserted -> %s", OidOutputFunctionCall(typoutput, values[i])))); } /* ---------------- * InsertOneNull * ---------------- */ void InsertOneNull(int i) { elog(DEBUG4, "inserting column %d NULL", i); Assert(i >= 0 && i < MAXATTR); if (TupleDescAttr(boot_reldesc->rd_att, i)->attnotnull) elog(ERROR, "NULL value specified for not-null column \"%s\" of relation \"%s\"", NameStr(TupleDescAttr(boot_reldesc->rd_att, i)->attname), RelationGetRelationName(boot_reldesc)); values[i] = PointerGetDatum(NULL); Nulls[i] = true; } /* ---------------- * cleanup * ---------------- */ static void cleanup(void) { if (boot_reldesc != NULL) closerel(NULL); } /* ---------------- * populate_typ_list * * Load the Typ list by reading pg_type. * ---------------- */ static void populate_typ_list(void) { Relation rel; TableScanDesc scan; HeapTuple tup; MemoryContext old; Assert(Typ == NIL); rel = table_open(TypeRelationId, NoLock); scan = table_beginscan_catalog(rel, 0, NULL); old = MemoryContextSwitchTo(TopMemoryContext); while ((tup = heap_getnext(scan, ForwardScanDirection)) != NULL) { Form_pg_type typForm = (Form_pg_type) GETSTRUCT(tup); struct typmap *newtyp; newtyp = (struct typmap *) palloc(sizeof(struct typmap)); Typ = lappend(Typ, newtyp); newtyp->am_oid = typForm->oid; memcpy(&newtyp->am_typ, typForm, sizeof(newtyp->am_typ)); } MemoryContextSwitchTo(old); table_endscan(scan); table_close(rel, NoLock); } /* ---------------- * gettype * * NB: this is really ugly; it will return an integer index into TypInfo[], * and not an OID at all, until the first reference to a type not known in * TypInfo[]. At that point it will read and cache pg_type in Typ, * and subsequently return a real OID (and set the global pointer Ap to * point at the found row in Typ). So caller must check whether Typ is * still NIL to determine what the return value is! * ---------------- */ static Oid gettype(char *type) { if (Typ != NIL) { ListCell *lc; foreach(lc, Typ) { struct typmap *app = lfirst(lc); if (strncmp(NameStr(app->am_typ.typname), type, NAMEDATALEN) == 0) { Ap = app; return app->am_oid; } } /* * The type wasn't known; reload the pg_type contents and check again * to handle composite types, added since last populating the list. */ list_free_deep(Typ); Typ = NIL; populate_typ_list(); /* * Calling gettype would result in infinite recursion for types * missing in pg_type, so just repeat the lookup. */ foreach(lc, Typ) { struct typmap *app = lfirst(lc); if (strncmp(NameStr(app->am_typ.typname), type, NAMEDATALEN) == 0) { Ap = app; return app->am_oid; } } } else { int i; for (i = 0; i < n_types; i++) { if (strncmp(type, TypInfo[i].name, NAMEDATALEN) == 0) return i; } /* Not in TypInfo, so we'd better be able to read pg_type now */ elog(DEBUG4, "external type: %s", type); populate_typ_list(); return gettype(type); } elog(ERROR, "unrecognized type \"%s\"", type); /* not reached, here to make compiler happy */ return 0; } /* ---------------- * boot_get_type_io_data * * Obtain type I/O information at bootstrap time. This intentionally has * almost the same API as lsyscache.c's get_type_io_data, except that * we only support obtaining the typinput and typoutput routines, not * the binary I/O routines. It is exported so that array_in and array_out * can be made to work during early bootstrap. * ---------------- */ void boot_get_type_io_data(Oid typid, int16 *typlen, bool *typbyval, char *typalign, char *typdelim, Oid *typioparam, Oid *typinput, Oid *typoutput) { if (Typ != NIL) { /* We have the boot-time contents of pg_type, so use it */ struct typmap *ap = NULL; ListCell *lc; foreach(lc, Typ) { ap = lfirst(lc); if (ap->am_oid == typid) break; } if (!ap || ap->am_oid != typid) elog(ERROR, "type OID %u not found in Typ list", typid); *typlen = ap->am_typ.typlen; *typbyval = ap->am_typ.typbyval; *typalign = ap->am_typ.typalign; *typdelim = ap->am_typ.typdelim; /* XXX this logic must match getTypeIOParam() */ if (OidIsValid(ap->am_typ.typelem)) *typioparam = ap->am_typ.typelem; else *typioparam = typid; *typinput = ap->am_typ.typinput; *typoutput = ap->am_typ.typoutput; } else { /* We don't have pg_type yet, so use the hard-wired TypInfo array */ int typeindex; for (typeindex = 0; typeindex < n_types; typeindex++) { if (TypInfo[typeindex].oid == typid) break; } if (typeindex >= n_types) elog(ERROR, "type OID %u not found in TypInfo", typid); *typlen = TypInfo[typeindex].len; *typbyval = TypInfo[typeindex].byval; *typalign = TypInfo[typeindex].align; /* We assume typdelim is ',' for all boot-time types */ *typdelim = ','; /* XXX this logic must match getTypeIOParam() */ if (OidIsValid(TypInfo[typeindex].elem)) *typioparam = TypInfo[typeindex].elem; else *typioparam = typid; *typinput = TypInfo[typeindex].inproc; *typoutput = TypInfo[typeindex].outproc; } } /* ---------------- * AllocateAttribute * * Note: bootstrap never sets any per-column ACLs, so we only need * ATTRIBUTE_FIXED_PART_SIZE space per attribute. * ---------------- */ static Form_pg_attribute AllocateAttribute(void) { return (Form_pg_attribute) MemoryContextAllocZero(TopMemoryContext, ATTRIBUTE_FIXED_PART_SIZE); } /* * index_register() -- record an index that has been set up for building * later. * * At bootstrap time, we define a bunch of indexes on system catalogs. * We postpone actually building the indexes until just before we're * finished with initialization, however. This is because the indexes * themselves have catalog entries, and those have to be included in the * indexes on those catalogs. Doing it in two phases is the simplest * way of making sure the indexes have the right contents at the end. */ void index_register(Oid heap, Oid ind, const IndexInfo *indexInfo) { IndexList *newind; MemoryContext oldcxt; /* * XXX mao 10/31/92 -- don't gc index reldescs, associated info at * bootstrap time. we'll declare the indexes now, but want to create them * later. */ if (nogc == NULL) nogc = AllocSetContextCreate(NULL, "BootstrapNoGC", ALLOCSET_DEFAULT_SIZES); oldcxt = MemoryContextSwitchTo(nogc); newind = (IndexList *) palloc(sizeof(IndexList)); newind->il_heap = heap; newind->il_ind = ind; newind->il_info = (IndexInfo *) palloc(sizeof(IndexInfo)); memcpy(newind->il_info, indexInfo, sizeof(IndexInfo)); /* expressions will likely be null, but may as well copy it */ newind->il_info->ii_Expressions = copyObject(indexInfo->ii_Expressions); newind->il_info->ii_ExpressionsState = NIL; /* predicate will likely be null, but may as well copy it */ newind->il_info->ii_Predicate = copyObject(indexInfo->ii_Predicate); newind->il_info->ii_PredicateState = NULL; /* no exclusion constraints at bootstrap time, so no need to copy */ Assert(indexInfo->ii_ExclusionOps == NULL); Assert(indexInfo->ii_ExclusionProcs == NULL); Assert(indexInfo->ii_ExclusionStrats == NULL); newind->il_next = ILHead; ILHead = newind; MemoryContextSwitchTo(oldcxt); } /* * build_indices -- fill in all the indexes registered earlier */ void build_indices(void) { for (; ILHead != NULL; ILHead = ILHead->il_next) { Relation heap; Relation ind; /* need not bother with locks during bootstrap */ heap = table_open(ILHead->il_heap, NoLock); ind = index_open(ILHead->il_ind, NoLock); index_build(heap, ind, ILHead->il_info, false, false); index_close(ind, NoLock); table_close(heap, NoLock); } }