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postgres/src/backend/utils/cache/relcache.c
Tom Lane 278bd0cc22 For some reason access/tupmacs.h has been #including utils/memutils.h, 
which is neither needed by nor related to that header.  Remove the bogus
inclusion and instead include the header in those C files that actually
need it.  Also fix unnecessary inclusions and bad inclusion order in
tsearch2 files.
2005-05-06 17:24:55 +00:00

3366 lines
98 KiB
C
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/*-------------------------------------------------------------------------
*
* relcache.c
* POSTGRES relation descriptor cache code
*
* Portions Copyright (c) 1996-2005, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
*
* IDENTIFICATION
* $PostgreSQL: pgsql/src/backend/utils/cache/relcache.c,v 1.222 2005/05/06 17:24:54 tgl Exp $
*
*-------------------------------------------------------------------------
*/
/*
* INTERFACE ROUTINES
* RelationCacheInitialize - initialize relcache
* RelationCacheInitializePhase2 - finish initializing relcache
* RelationIdGetRelation - get a reldesc by relation id
* RelationIdCacheGetRelation - get a cached reldesc by relid
* RelationClose - close an open relation
*
* NOTES
* The following code contains many undocumented hacks. Please be
* careful....
*/
#include "postgres.h"
#include <sys/file.h>
#include <fcntl.h>
#include <unistd.h>
#include "access/genam.h"
#include "access/heapam.h"
#include "catalog/catalog.h"
#include "catalog/indexing.h"
#include "catalog/namespace.h"
#include "catalog/pg_amop.h"
#include "catalog/pg_amproc.h"
#include "catalog/pg_attrdef.h"
#include "catalog/pg_attribute.h"
#include "catalog/pg_constraint.h"
#include "catalog/pg_index.h"
#include "catalog/pg_namespace.h"
#include "catalog/pg_opclass.h"
#include "catalog/pg_proc.h"
#include "catalog/pg_rewrite.h"
#include "catalog/pg_type.h"
#include "commands/trigger.h"
#include "miscadmin.h"
#include "optimizer/clauses.h"
#include "optimizer/planmain.h"
#include "optimizer/prep.h"
#include "storage/fd.h"
#include "storage/smgr.h"
#include "utils/builtins.h"
#include "utils/catcache.h"
#include "utils/fmgroids.h"
#include "utils/inval.h"
#include "utils/lsyscache.h"
#include "utils/memutils.h"
#include "utils/relcache.h"
#include "utils/resowner.h"
#include "utils/syscache.h"
#include "utils/typcache.h"
/*
* name of relcache init file, used to speed up backend startup
*/
#define RELCACHE_INIT_FILENAME "pg_internal.init"
#define RELCACHE_INIT_FILEMAGIC 0x573262 /* version ID value */
/*
* hardcoded tuple descriptors. see include/catalog/pg_attribute.h
*/
static FormData_pg_attribute Desc_pg_class[Natts_pg_class] = {Schema_pg_class};
static FormData_pg_attribute Desc_pg_attribute[Natts_pg_attribute] = {Schema_pg_attribute};
static FormData_pg_attribute Desc_pg_proc[Natts_pg_proc] = {Schema_pg_proc};
static FormData_pg_attribute Desc_pg_type[Natts_pg_type] = {Schema_pg_type};
static FormData_pg_attribute Desc_pg_index[Natts_pg_index] = {Schema_pg_index};
/*
* Hash tables that index the relation cache
*
* We used to index the cache by both name and OID, but now there
* is only an index by OID.
*/
typedef struct relidcacheent
{
Oid reloid;
Relation reldesc;
} RelIdCacheEnt;
static HTAB *RelationIdCache;
/*
* This flag is false until we have prepared the critical relcache entries
* that are needed to do indexscans on the tables read by relcache building.
*/
bool criticalRelcachesBuilt = false;
/*
* This flag is set if we discover that we need to write a new relcache
* cache file at the end of startup.
*/
static bool needNewCacheFile = false;
/*
* This counter counts relcache inval events received since backend startup
* (but only for rels that are actually in cache). Presently, we use it only
* to detect whether data about to be written by write_relcache_init_file()
* might already be obsolete.
*/
static long relcacheInvalsReceived = 0L;
/*
* This list remembers the OIDs of the relations cached in the relcache
* init file.
*/
static List *initFileRelationIds = NIL;
/*
* This flag lets us optimize away work in AtEOSubXact_RelationCache().
*/
static bool need_eosubxact_work = false;
/*
* macros to manipulate the lookup hashtables
*/
#define RelationCacheInsert(RELATION) \
do { \
RelIdCacheEnt *idhentry; bool found; \
idhentry = (RelIdCacheEnt*)hash_search(RelationIdCache, \
(void *) &(RELATION->rd_id), \
HASH_ENTER, \
&found); \
if (idhentry == NULL) \
ereport(ERROR, \
(errcode(ERRCODE_OUT_OF_MEMORY), \
errmsg("out of memory"))); \
/* used to give notice if found -- now just keep quiet */ \
idhentry->reldesc = RELATION; \
} while(0)
#define RelationIdCacheLookup(ID, RELATION) \
do { \
RelIdCacheEnt *hentry; \
hentry = (RelIdCacheEnt*)hash_search(RelationIdCache, \
(void *) &(ID), HASH_FIND,NULL); \
if (hentry) \
RELATION = hentry->reldesc; \
else \
RELATION = NULL; \
} while(0)
#define RelationCacheDelete(RELATION) \
do { \
RelIdCacheEnt *idhentry; \
idhentry = (RelIdCacheEnt*)hash_search(RelationIdCache, \
(void *) &(RELATION->rd_id), \
HASH_REMOVE, NULL); \
if (idhentry == NULL) \
elog(WARNING, "trying to delete a rd_id reldesc that does not exist"); \
} while(0)
/*
* Special cache for opclass-related information
*
* Note: only default-subtype operators and support procs get cached
*/
typedef struct opclasscacheent
{
Oid opclassoid; /* lookup key: OID of opclass */
bool valid; /* set TRUE after successful fill-in */
StrategyNumber numStrats; /* max # of strategies (from pg_am) */
StrategyNumber numSupport; /* max # of support procs (from pg_am) */
Oid *operatorOids; /* strategy operators' OIDs */
RegProcedure *supportProcs; /* support procs */
} OpClassCacheEnt;
static HTAB *OpClassCache = NULL;
/* non-export function prototypes */
static void RelationClearRelation(Relation relation, bool rebuild);
static void RelationReloadClassinfo(Relation relation);
static void RelationFlushRelation(Relation relation);
static bool load_relcache_init_file(void);
static void write_relcache_init_file(void);
static void formrdesc(const char *relationName, Oid relationReltype,
bool hasoids, int natts, FormData_pg_attribute *att);
static HeapTuple ScanPgRelation(Oid targetRelId, bool indexOK);
static Relation AllocateRelationDesc(Relation relation, Form_pg_class relp);
static void RelationBuildTupleDesc(Relation relation);
static Relation RelationBuildDesc(Oid targetRelId, Relation oldrelation);
static void RelationInitPhysicalAddr(Relation relation);
static TupleDesc GetPgIndexDescriptor(void);
static void AttrDefaultFetch(Relation relation);
static void CheckConstraintFetch(Relation relation);
static List *insert_ordered_oid(List *list, Oid datum);
static void IndexSupportInitialize(oidvector *indclass,
Oid *indexOperator,
RegProcedure *indexSupport,
StrategyNumber maxStrategyNumber,
StrategyNumber maxSupportNumber,
AttrNumber maxAttributeNumber);
static OpClassCacheEnt *LookupOpclassInfo(Oid operatorClassOid,
StrategyNumber numStrats,
StrategyNumber numSupport);
/*
* ScanPgRelation
*
* this is used by RelationBuildDesc to find a pg_class
* tuple matching targetRelId.
*
* NB: the returned tuple has been copied into palloc'd storage
* and must eventually be freed with heap_freetuple.
*/
static HeapTuple
ScanPgRelation(Oid targetRelId, bool indexOK)
{
HeapTuple pg_class_tuple;
Relation pg_class_desc;
SysScanDesc pg_class_scan;
ScanKeyData key[1];
/*
* form a scan key
*/
ScanKeyInit(&key[0],
ObjectIdAttributeNumber,
BTEqualStrategyNumber, F_OIDEQ,
ObjectIdGetDatum(targetRelId));
/*
* Open pg_class and fetch a tuple. Force heap scan if we haven't yet
* built the critical relcache entries (this includes initdb and
* startup without a pg_internal.init file). The caller can also
* force a heap scan by setting indexOK == false.
*/
pg_class_desc = heap_open(RelationRelationId, AccessShareLock);
pg_class_scan = systable_beginscan(pg_class_desc, ClassOidIndexId,
indexOK && criticalRelcachesBuilt,
SnapshotNow,
1, key);
pg_class_tuple = systable_getnext(pg_class_scan);
/*
* Must copy tuple before releasing buffer.
*/
if (HeapTupleIsValid(pg_class_tuple))
pg_class_tuple = heap_copytuple(pg_class_tuple);
/* all done */
systable_endscan(pg_class_scan);
heap_close(pg_class_desc, AccessShareLock);
return pg_class_tuple;
}
/*
* AllocateRelationDesc
*
* This is used to allocate memory for a new relation descriptor
* and initialize the rd_rel field.
*
* If 'relation' is NULL, allocate a new RelationData object.
* If not, reuse the given object (that path is taken only when
* we have to rebuild a relcache entry during RelationClearRelation).
*/
static Relation
AllocateRelationDesc(Relation relation, Form_pg_class relp)
{
MemoryContext oldcxt;
Form_pg_class relationForm;
/* Relcache entries must live in CacheMemoryContext */
oldcxt = MemoryContextSwitchTo(CacheMemoryContext);
/*
* allocate space for new relation descriptor, if needed
*/
if (relation == NULL)
relation = (Relation) palloc(sizeof(RelationData));
/*
* clear all fields of reldesc
*/
MemSet((char *) relation, 0, sizeof(RelationData));
relation->rd_targblock = InvalidBlockNumber;
/* make sure relation is marked as having no open file yet */
relation->rd_smgr = NULL;
/*
* Copy the relation tuple form
*
* We only allocate space for the fixed fields, ie, CLASS_TUPLE_SIZE.
* relacl is NOT stored in the relcache --- there'd be little point in
* it, since we don't copy the tuple's nullvalues bitmap and hence
* wouldn't know if the value is valid ... bottom line is that relacl
* *cannot* be retrieved from the relcache. Get it from the syscache
* if you need it.
*/
relationForm = (Form_pg_class) palloc(CLASS_TUPLE_SIZE);
memcpy((char *) relationForm, (char *) relp, CLASS_TUPLE_SIZE);
/* initialize relation tuple form */
relation->rd_rel = relationForm;
/* and allocate attribute tuple form storage */
relation->rd_att = CreateTemplateTupleDesc(relationForm->relnatts,
relationForm->relhasoids);
MemoryContextSwitchTo(oldcxt);
return relation;
}
/*
* RelationBuildTupleDesc
*
* Form the relation's tuple descriptor from information in
* the pg_attribute, pg_attrdef & pg_constraint system catalogs.
*/
static void
RelationBuildTupleDesc(Relation relation)
{
HeapTuple pg_attribute_tuple;
Relation pg_attribute_desc;
SysScanDesc pg_attribute_scan;
ScanKeyData skey[2];
int need;
TupleConstr *constr;
AttrDefault *attrdef = NULL;
int ndef = 0;
/* copy some fields from pg_class row to rd_att */
relation->rd_att->tdtypeid = relation->rd_rel->reltype;
relation->rd_att->tdtypmod = -1; /* unnecessary, but... */
relation->rd_att->tdhasoid = relation->rd_rel->relhasoids;
constr = (TupleConstr *) MemoryContextAlloc(CacheMemoryContext,
sizeof(TupleConstr));
constr->has_not_null = false;
/*
* Form a scan key that selects only user attributes (attnum > 0).
* (Eliminating system attribute rows at the index level is lots
* faster than fetching them.)
*/
ScanKeyInit(&skey[0],
Anum_pg_attribute_attrelid,
BTEqualStrategyNumber, F_OIDEQ,
ObjectIdGetDatum(RelationGetRelid(relation)));
ScanKeyInit(&skey[1],
Anum_pg_attribute_attnum,
BTGreaterStrategyNumber, F_INT2GT,
Int16GetDatum(0));
/*
* Open pg_attribute and begin a scan. Force heap scan if we haven't
* yet built the critical relcache entries (this includes initdb and
* startup without a pg_internal.init file).
*/
pg_attribute_desc = heap_open(AttributeRelationId, AccessShareLock);
pg_attribute_scan = systable_beginscan(pg_attribute_desc,
AttributeRelidNumIndexId,
criticalRelcachesBuilt,
SnapshotNow,
2, skey);
/*
* add attribute data to relation->rd_att
*/
need = relation->rd_rel->relnatts;
while (HeapTupleIsValid(pg_attribute_tuple = systable_getnext(pg_attribute_scan)))
{
Form_pg_attribute attp;
attp = (Form_pg_attribute) GETSTRUCT(pg_attribute_tuple);
if (attp->attnum <= 0 ||
attp->attnum > relation->rd_rel->relnatts)
elog(ERROR, "invalid attribute number %d for %s",
attp->attnum, RelationGetRelationName(relation));
memcpy(relation->rd_att->attrs[attp->attnum - 1],
attp,
ATTRIBUTE_TUPLE_SIZE);
/* Update constraint/default info */
if (attp->attnotnull)
constr->has_not_null = true;
if (attp->atthasdef)
{
if (attrdef == NULL)
attrdef = (AttrDefault *)
MemoryContextAllocZero(CacheMemoryContext,
relation->rd_rel->relnatts *
sizeof(AttrDefault));
attrdef[ndef].adnum = attp->attnum;
attrdef[ndef].adbin = NULL;
ndef++;
}
need--;
if (need == 0)
break;
}
/*
* end the scan and close the attribute relation
*/
systable_endscan(pg_attribute_scan);
heap_close(pg_attribute_desc, AccessShareLock);
if (need != 0)
elog(ERROR, "catalog is missing %d attribute(s) for relid %u",
need, RelationGetRelid(relation));
/*
* The attcacheoff values we read from pg_attribute should all be -1
* ("unknown"). Verify this if assert checking is on. They will be
* computed when and if needed during tuple access.
*/
#ifdef USE_ASSERT_CHECKING
{
int i;
for (i = 0; i < relation->rd_rel->relnatts; i++)
Assert(relation->rd_att->attrs[i]->attcacheoff == -1);
}
#endif
/*
* However, we can easily set the attcacheoff value for the first
* attribute: it must be zero. This eliminates the need for special
* cases for attnum=1 that used to exist in fastgetattr() and
* index_getattr().
*/
if (relation->rd_rel->relnatts > 0)
relation->rd_att->attrs[0]->attcacheoff = 0;
/*
* Set up constraint/default info
*/
if (constr->has_not_null || ndef > 0 || relation->rd_rel->relchecks)
{
relation->rd_att->constr = constr;
if (ndef > 0) /* DEFAULTs */
{
if (ndef < relation->rd_rel->relnatts)
constr->defval = (AttrDefault *)
repalloc(attrdef, ndef * sizeof(AttrDefault));
else
constr->defval = attrdef;
constr->num_defval = ndef;
AttrDefaultFetch(relation);
}
else
constr->num_defval = 0;
if (relation->rd_rel->relchecks > 0) /* CHECKs */
{
constr->num_check = relation->rd_rel->relchecks;
constr->check = (ConstrCheck *)
MemoryContextAllocZero(CacheMemoryContext,
constr->num_check * sizeof(ConstrCheck));
CheckConstraintFetch(relation);
}
else
constr->num_check = 0;
}
else
{
pfree(constr);
relation->rd_att->constr = NULL;
}
}
/*
* RelationBuildRuleLock
*
* Form the relation's rewrite rules from information in
* the pg_rewrite system catalog.
*
* Note: The rule parsetrees are potentially very complex node structures.
* To allow these trees to be freed when the relcache entry is flushed,
* we make a private memory context to hold the RuleLock information for
* each relcache entry that has associated rules. The context is used
* just for rule info, not for any other subsidiary data of the relcache
* entry, because that keeps the update logic in RelationClearRelation()
* manageable. The other subsidiary data structures are simple enough
* to be easy to free explicitly, anyway.
*/
static void
RelationBuildRuleLock(Relation relation)
{
MemoryContext rulescxt;
MemoryContext oldcxt;
HeapTuple rewrite_tuple;
Relation rewrite_desc;
TupleDesc rewrite_tupdesc;
SysScanDesc rewrite_scan;
ScanKeyData key;
RuleLock *rulelock;
int numlocks;
RewriteRule **rules;
int maxlocks;
/*
* Make the private context. Parameters are set on the assumption
* that it'll probably not contain much data.
*/
rulescxt = AllocSetContextCreate(CacheMemoryContext,
RelationGetRelationName(relation),
ALLOCSET_SMALL_MINSIZE,
ALLOCSET_SMALL_INITSIZE,
ALLOCSET_SMALL_MAXSIZE);
relation->rd_rulescxt = rulescxt;
/*
* allocate an array to hold the rewrite rules (the array is extended
* if necessary)
*/
maxlocks = 4;
rules = (RewriteRule **)
MemoryContextAlloc(rulescxt, sizeof(RewriteRule *) * maxlocks);
numlocks = 0;
/*
* form a scan key
*/
ScanKeyInit(&key,
Anum_pg_rewrite_ev_class,
BTEqualStrategyNumber, F_OIDEQ,
ObjectIdGetDatum(RelationGetRelid(relation)));
/*
* open pg_rewrite and begin a scan
*
* Note: since we scan the rules using RewriteRelRulenameIndexId,
* we will be reading the rules in name order, except possibly during
* emergency-recovery operations (ie, IsIgnoringSystemIndexes). This
* in turn ensures that rules will be fired in name order.
*/
rewrite_desc = heap_open(RewriteRelationId, AccessShareLock);
rewrite_tupdesc = RelationGetDescr(rewrite_desc);
rewrite_scan = systable_beginscan(rewrite_desc,
RewriteRelRulenameIndexId,
true, SnapshotNow,
1, &key);
while (HeapTupleIsValid(rewrite_tuple = systable_getnext(rewrite_scan)))
{
Form_pg_rewrite rewrite_form = (Form_pg_rewrite) GETSTRUCT(rewrite_tuple);
bool isnull;
Datum ruleaction;
Datum rule_evqual;
char *ruleaction_str;
char *rule_evqual_str;
RewriteRule *rule;
rule = (RewriteRule *) MemoryContextAlloc(rulescxt,
sizeof(RewriteRule));
rule->ruleId = HeapTupleGetOid(rewrite_tuple);
rule->event = rewrite_form->ev_type - '0';
rule->attrno = rewrite_form->ev_attr;
rule->isInstead = rewrite_form->is_instead;
/* Must use heap_getattr to fetch ev_qual and ev_action */
ruleaction = heap_getattr(rewrite_tuple,
Anum_pg_rewrite_ev_action,
rewrite_tupdesc,
&isnull);
Assert(!isnull);
ruleaction_str = DatumGetCString(DirectFunctionCall1(textout,
ruleaction));
oldcxt = MemoryContextSwitchTo(rulescxt);
rule->actions = (List *) stringToNode(ruleaction_str);
MemoryContextSwitchTo(oldcxt);
pfree(ruleaction_str);
rule_evqual = heap_getattr(rewrite_tuple,
Anum_pg_rewrite_ev_qual,
rewrite_tupdesc,
&isnull);
Assert(!isnull);
rule_evqual_str = DatumGetCString(DirectFunctionCall1(textout,
rule_evqual));
oldcxt = MemoryContextSwitchTo(rulescxt);
rule->qual = (Node *) stringToNode(rule_evqual_str);
MemoryContextSwitchTo(oldcxt);
pfree(rule_evqual_str);
if (numlocks >= maxlocks)
{
maxlocks *= 2;
rules = (RewriteRule **)
repalloc(rules, sizeof(RewriteRule *) * maxlocks);
}
rules[numlocks++] = rule;
}
/*
* end the scan and close the attribute relation
*/
systable_endscan(rewrite_scan);
heap_close(rewrite_desc, AccessShareLock);
/*
* form a RuleLock and insert into relation
*/
rulelock = (RuleLock *) MemoryContextAlloc(rulescxt, sizeof(RuleLock));
rulelock->numLocks = numlocks;
rulelock->rules = rules;
relation->rd_rules = rulelock;
}
/*
* equalRuleLocks
*
* Determine whether two RuleLocks are equivalent
*
* Probably this should be in the rules code someplace...
*/
static bool
equalRuleLocks(RuleLock *rlock1, RuleLock *rlock2)
{
int i;
/*
* As of 7.3 we assume the rule ordering is repeatable, because
* RelationBuildRuleLock should read 'em in a consistent order. So
* just compare corresponding slots.
*/
if (rlock1 != NULL)
{
if (rlock2 == NULL)
return false;
if (rlock1->numLocks != rlock2->numLocks)
return false;
for (i = 0; i < rlock1->numLocks; i++)
{
RewriteRule *rule1 = rlock1->rules[i];
RewriteRule *rule2 = rlock2->rules[i];
if (rule1->ruleId != rule2->ruleId)
return false;
if (rule1->event != rule2->event)
return false;
if (rule1->attrno != rule2->attrno)
return false;
if (rule1->isInstead != rule2->isInstead)
return false;
if (!equal(rule1->qual, rule2->qual))
return false;
if (!equal(rule1->actions, rule2->actions))
return false;
}
}
else if (rlock2 != NULL)
return false;
return true;
}
/* ----------------------------------
* RelationBuildDesc
*
* Build a relation descriptor --- either a new one, or by
* recycling the given old relation object. The latter case
* supports rebuilding a relcache entry without invalidating
* pointers to it.
* --------------------------------
*/
static Relation
RelationBuildDesc(Oid targetRelId, Relation oldrelation)
{
Relation relation;
Oid relid;
HeapTuple pg_class_tuple;
Form_pg_class relp;
MemoryContext oldcxt;
/*
* find the tuple in pg_class corresponding to the given relation id
*/
pg_class_tuple = ScanPgRelation(targetRelId, true);
/*
* if no such tuple exists, return NULL
*/
if (!HeapTupleIsValid(pg_class_tuple))
return NULL;
/*
* get information from the pg_class_tuple
*/
relid = HeapTupleGetOid(pg_class_tuple);
relp = (Form_pg_class) GETSTRUCT(pg_class_tuple);
/*
* allocate storage for the relation descriptor, and copy
* pg_class_tuple to relation->rd_rel.
*/
relation = AllocateRelationDesc(oldrelation, relp);
/*
* now we can free the memory allocated for pg_class_tuple
*/
heap_freetuple(pg_class_tuple);
/*
* initialize the relation's relation id (relation->rd_id)
*/
RelationGetRelid(relation) = relid;
/*
* normal relations are not nailed into the cache; nor can a
* pre-existing relation be new. It could be temp though. (Actually,
* it could be new too, but it's okay to forget that fact if forced to
* flush the entry.)
*/
relation->rd_refcnt = 0;
relation->rd_isnailed = false;
relation->rd_createSubid = InvalidSubTransactionId;
relation->rd_istemp = isTempNamespace(relation->rd_rel->relnamespace);
/*
* initialize the tuple descriptor (relation->rd_att).
*/
RelationBuildTupleDesc(relation);
/*
* Fetch rules and triggers that affect this relation
*/
if (relation->rd_rel->relhasrules)
RelationBuildRuleLock(relation);
else
{
relation->rd_rules = NULL;
relation->rd_rulescxt = NULL;
}
if (relation->rd_rel->reltriggers > 0)
RelationBuildTriggers(relation);
else
relation->trigdesc = NULL;
/*
* if it's an index, initialize index-related information
*/
if (OidIsValid(relation->rd_rel->relam))
RelationInitIndexAccessInfo(relation);
/*
* initialize the relation lock manager information
*/
RelationInitLockInfo(relation); /* see lmgr.c */
/*
* initialize physical addressing information for the relation
*/
RelationInitPhysicalAddr(relation);
/* make sure relation is marked as having no open file yet */
relation->rd_smgr = NULL;
/*
* Insert newly created relation into relcache hash tables.
*/
oldcxt = MemoryContextSwitchTo(CacheMemoryContext);
RelationCacheInsert(relation);
MemoryContextSwitchTo(oldcxt);
/* It's fully valid */
relation->rd_isvalid = true;
return relation;
}
/*
* Initialize the physical addressing info (RelFileNode) for a relcache entry
*/
static void
RelationInitPhysicalAddr(Relation relation)
{
if (relation->rd_rel->reltablespace)
relation->rd_node.spcNode = relation->rd_rel->reltablespace;
else
relation->rd_node.spcNode = MyDatabaseTableSpace;
if (relation->rd_rel->relisshared)
relation->rd_node.dbNode = InvalidOid;
else
relation->rd_node.dbNode = MyDatabaseId;
relation->rd_node.relNode = relation->rd_rel->relfilenode;
}
/*
* Initialize index-access-method support data for an index relation
*/
void
RelationInitIndexAccessInfo(Relation relation)
{
HeapTuple tuple;
Form_pg_am aform;
Datum indclassDatum;
bool isnull;
MemoryContext indexcxt;
MemoryContext oldcontext;
Oid *operator;
RegProcedure *support;
FmgrInfo *supportinfo;
int natts;
uint16 amstrategies;
uint16 amsupport;
/*
* Make a copy of the pg_index entry for the index. Since pg_index
* contains variable-length and possibly-null fields, we have to do
* this honestly rather than just treating it as a Form_pg_index
* struct.
*/
tuple = SearchSysCache(INDEXRELID,
ObjectIdGetDatum(RelationGetRelid(relation)),
0, 0, 0);
if (!HeapTupleIsValid(tuple))
elog(ERROR, "cache lookup failed for index %u",
RelationGetRelid(relation));
oldcontext = MemoryContextSwitchTo(CacheMemoryContext);
relation->rd_indextuple = heap_copytuple(tuple);
relation->rd_index = (Form_pg_index) GETSTRUCT(relation->rd_indextuple);
MemoryContextSwitchTo(oldcontext);
ReleaseSysCache(tuple);
/*
* indclass cannot be referenced directly through the C struct, because
* it is after the variable-width indkey field. Therefore we extract
* the datum the hard way and provide a direct link in the relcache.
*/
indclassDatum = fastgetattr(relation->rd_indextuple,
Anum_pg_index_indclass,
GetPgIndexDescriptor(),
&isnull);
Assert(!isnull);
relation->rd_indclass = (oidvector *) DatumGetPointer(indclassDatum);
/*
* Make a copy of the pg_am entry for the index's access method
*/
tuple = SearchSysCache(AMOID,
ObjectIdGetDatum(relation->rd_rel->relam),
0, 0, 0);
if (!HeapTupleIsValid(tuple))
elog(ERROR, "cache lookup failed for access method %u",
relation->rd_rel->relam);
aform = (Form_pg_am) MemoryContextAlloc(CacheMemoryContext, sizeof *aform);
memcpy(aform, GETSTRUCT(tuple), sizeof *aform);
ReleaseSysCache(tuple);
relation->rd_am = aform;
natts = relation->rd_rel->relnatts;
if (natts != relation->rd_index->indnatts)
elog(ERROR, "relnatts disagrees with indnatts for index %u",
RelationGetRelid(relation));
amstrategies = aform->amstrategies;
amsupport = aform->amsupport;
/*
* Make the private context to hold index access info. The reason we
* need a context, and not just a couple of pallocs, is so that we
* won't leak any subsidiary info attached to fmgr lookup records.
*
* Context parameters are set on the assumption that it'll probably not
* contain much data.
*/
indexcxt = AllocSetContextCreate(CacheMemoryContext,
RelationGetRelationName(relation),
ALLOCSET_SMALL_MINSIZE,
ALLOCSET_SMALL_INITSIZE,
ALLOCSET_SMALL_MAXSIZE);
relation->rd_indexcxt = indexcxt;
/*
* Allocate arrays to hold data
*/
if (amstrategies > 0)
operator = (Oid *)
MemoryContextAllocZero(indexcxt,
natts * amstrategies * sizeof(Oid));
else
operator = NULL;
if (amsupport > 0)
{
int nsupport = natts * amsupport;
support = (RegProcedure *)
MemoryContextAllocZero(indexcxt, nsupport * sizeof(RegProcedure));
supportinfo = (FmgrInfo *)
MemoryContextAllocZero(indexcxt, nsupport * sizeof(FmgrInfo));
}
else
{
support = NULL;
supportinfo = NULL;
}
relation->rd_operator = operator;
relation->rd_support = support;
relation->rd_supportinfo = supportinfo;
/*
* Fill the operator and support procedure OID arrays. (supportinfo is
* left as zeroes, and is filled on-the-fly when used)
*/
IndexSupportInitialize(relation->rd_indclass,
operator, support,
amstrategies, amsupport, natts);
/*
* expressions and predicate cache will be filled later
*/
relation->rd_indexprs = NIL;
relation->rd_indpred = NIL;
}
/*
* IndexSupportInitialize
* Initializes an index's cached opclass information,
* given the index's pg_index.indclass entry.
*
* Data is returned into *indexOperator and *indexSupport, which are arrays
* allocated by the caller.
*
* The caller also passes maxStrategyNumber, maxSupportNumber, and
* maxAttributeNumber, since these indicate the size of the arrays
* it has allocated --- but in practice these numbers must always match
* those obtainable from the system catalog entries for the index and
* access method.
*/
static void
IndexSupportInitialize(oidvector *indclass,
Oid *indexOperator,
RegProcedure *indexSupport,
StrategyNumber maxStrategyNumber,
StrategyNumber maxSupportNumber,
AttrNumber maxAttributeNumber)
{
int attIndex;
for (attIndex = 0; attIndex < maxAttributeNumber; attIndex++)
{
OpClassCacheEnt *opcentry;
if (!OidIsValid(indclass->values[attIndex]))
elog(ERROR, "bogus pg_index tuple");
/* look up the info for this opclass, using a cache */
opcentry = LookupOpclassInfo(indclass->values[attIndex],
maxStrategyNumber,
maxSupportNumber);
/* copy cached data into relcache entry */
if (maxStrategyNumber > 0)
memcpy(&indexOperator[attIndex * maxStrategyNumber],
opcentry->operatorOids,
maxStrategyNumber * sizeof(Oid));
if (maxSupportNumber > 0)
memcpy(&indexSupport[attIndex * maxSupportNumber],
opcentry->supportProcs,
maxSupportNumber * sizeof(RegProcedure));
}
}
/*
* LookupOpclassInfo
*
* This routine maintains a per-opclass cache of the information needed
* by IndexSupportInitialize(). This is more efficient than relying on
* the catalog cache, because we can load all the info about a particular
* opclass in a single indexscan of pg_amproc or pg_amop.
*
* The information from pg_am about expected range of strategy and support
* numbers is passed in, rather than being looked up, mainly because the
* caller will have it already.
*
* XXX There isn't any provision for flushing the cache. However, there
* isn't any provision for flushing relcache entries when opclass info
* changes, either :-(
*/
static OpClassCacheEnt *
LookupOpclassInfo(Oid operatorClassOid,
StrategyNumber numStrats,
StrategyNumber numSupport)
{
OpClassCacheEnt *opcentry;
bool found;
Relation rel;
SysScanDesc scan;
ScanKeyData skey[2];
HeapTuple htup;
bool indexOK;
if (OpClassCache == NULL)
{
/* First time through: initialize the opclass cache */
HASHCTL ctl;
if (!CacheMemoryContext)
CreateCacheMemoryContext();
MemSet(&ctl, 0, sizeof(ctl));
ctl.keysize = sizeof(Oid);
ctl.entrysize = sizeof(OpClassCacheEnt);
ctl.hash = oid_hash;
OpClassCache = hash_create("Operator class cache", 64,
&ctl, HASH_ELEM | HASH_FUNCTION);
}
opcentry = (OpClassCacheEnt *) hash_search(OpClassCache,
(void *) &operatorClassOid,
HASH_ENTER, &found);
if (opcentry == NULL)
ereport(ERROR,
(errcode(ERRCODE_OUT_OF_MEMORY),
errmsg("out of memory")));
if (found && opcentry->valid)
{
/* Already made an entry for it */
Assert(numStrats == opcentry->numStrats);
Assert(numSupport == opcentry->numSupport);
return opcentry;
}
/* Need to fill in new entry */
opcentry->valid = false; /* until known OK */
opcentry->numStrats = numStrats;
opcentry->numSupport = numSupport;
if (numStrats > 0)
opcentry->operatorOids = (Oid *)
MemoryContextAllocZero(CacheMemoryContext,
numStrats * sizeof(Oid));
else
opcentry->operatorOids = NULL;
if (numSupport > 0)
opcentry->supportProcs = (RegProcedure *)
MemoryContextAllocZero(CacheMemoryContext,
numSupport * sizeof(RegProcedure));
else
opcentry->supportProcs = NULL;
/*
* To avoid infinite recursion during startup, force heap scans if
* we're looking up info for the opclasses used by the indexes we
* would like to reference here.
*/
indexOK = criticalRelcachesBuilt ||
(operatorClassOid != OID_BTREE_OPS_OID &&
operatorClassOid != INT2_BTREE_OPS_OID);
/*
* Scan pg_amop to obtain operators for the opclass. We only fetch
* the default ones (those with subtype zero).
*/
if (numStrats > 0)
{
ScanKeyInit(&skey[0],
Anum_pg_amop_amopclaid,
BTEqualStrategyNumber, F_OIDEQ,
ObjectIdGetDatum(operatorClassOid));
ScanKeyInit(&skey[1],
Anum_pg_amop_amopsubtype,
BTEqualStrategyNumber, F_OIDEQ,
ObjectIdGetDatum(InvalidOid));
rel = heap_open(AccessMethodOperatorRelationId, AccessShareLock);
scan = systable_beginscan(rel, AccessMethodStrategyIndexId, indexOK,
SnapshotNow, 2, skey);
while (HeapTupleIsValid(htup = systable_getnext(scan)))
{
Form_pg_amop amopform = (Form_pg_amop) GETSTRUCT(htup);
if (amopform->amopstrategy <= 0 ||
(StrategyNumber) amopform->amopstrategy > numStrats)
elog(ERROR, "invalid amopstrategy number %d for opclass %u",
amopform->amopstrategy, operatorClassOid);
opcentry->operatorOids[amopform->amopstrategy - 1] =
amopform->amopopr;
}
systable_endscan(scan);
heap_close(rel, AccessShareLock);
}
/*
* Scan pg_amproc to obtain support procs for the opclass. We only
* fetch the default ones (those with subtype zero).
*/
if (numSupport > 0)
{
ScanKeyInit(&skey[0],
Anum_pg_amproc_amopclaid,
BTEqualStrategyNumber, F_OIDEQ,
ObjectIdGetDatum(operatorClassOid));
ScanKeyInit(&skey[1],
Anum_pg_amproc_amprocsubtype,
BTEqualStrategyNumber, F_OIDEQ,
ObjectIdGetDatum(InvalidOid));
rel = heap_open(AccessMethodProcedureRelationId, AccessShareLock);
scan = systable_beginscan(rel, AccessMethodProcedureIndexId, indexOK,
SnapshotNow, 2, skey);
while (HeapTupleIsValid(htup = systable_getnext(scan)))
{
Form_pg_amproc amprocform = (Form_pg_amproc) GETSTRUCT(htup);
if (amprocform->amprocnum <= 0 ||
(StrategyNumber) amprocform->amprocnum > numSupport)
elog(ERROR, "invalid amproc number %d for opclass %u",
amprocform->amprocnum, operatorClassOid);
opcentry->supportProcs[amprocform->amprocnum - 1] =
amprocform->amproc;
}
systable_endscan(scan);
heap_close(rel, AccessShareLock);
}
opcentry->valid = true;
return opcentry;
}
/*
* formrdesc
*
* This is a special cut-down version of RelationBuildDesc()
* used by RelationCacheInitialize() in initializing the relcache.
* The relation descriptor is built just from the supplied parameters,
* without actually looking at any system table entries. We cheat
* quite a lot since we only need to work for a few basic system
* catalogs.
*
* formrdesc is currently used for: pg_class, pg_attribute, pg_proc,
* and pg_type (see RelationCacheInitialize).
*
* Note that these catalogs can't have constraints (except attnotnull),
* default values, rules, or triggers, since we don't cope with any of that.
*
* NOTE: we assume we are already switched into CacheMemoryContext.
*/
static void
formrdesc(const char *relationName, Oid relationReltype,
bool hasoids, int natts, FormData_pg_attribute *att)
{
Relation relation;
int i;
bool has_not_null;
/*
* allocate new relation desc, clear all fields of reldesc
*/
relation = (Relation) palloc0(sizeof(RelationData));
relation->rd_targblock = InvalidBlockNumber;
/* make sure relation is marked as having no open file yet */
relation->rd_smgr = NULL;
/*
* initialize reference count: 1 because it is nailed in cache
*/
relation->rd_refcnt = 1;
/*
* all entries built with this routine are nailed-in-cache; none are
* for new or temp relations.
*/
relation->rd_isnailed = true;
relation->rd_createSubid = InvalidSubTransactionId;
relation->rd_istemp = false;
/*
* initialize relation tuple form
*
* The data we insert here is pretty incomplete/bogus, but it'll serve to
* get us launched. RelationCacheInitializePhase2() will read the
* real data from pg_class and replace what we've done here.
*/
relation->rd_rel = (Form_pg_class) palloc0(CLASS_TUPLE_SIZE);
namestrcpy(&relation->rd_rel->relname, relationName);
relation->rd_rel->relnamespace = PG_CATALOG_NAMESPACE;
relation->rd_rel->reltype = relationReltype;
/*
* It's important to distinguish between shared and non-shared
* relations, even at bootstrap time, to make sure we know where they
* are stored. At present, all relations that formrdesc is used for
* are not shared.
*/
relation->rd_rel->relisshared = false;
relation->rd_rel->relpages = 1;
relation->rd_rel->reltuples = 1;
relation->rd_rel->relkind = RELKIND_RELATION;
relation->rd_rel->relhasoids = hasoids;
relation->rd_rel->relnatts = (int16) natts;
/*
* initialize attribute tuple form
*
* Unlike the case with the relation tuple, this data had better be right
* because it will never be replaced. The input values must be
* correctly defined by macros in src/include/catalog/ headers.
*/
relation->rd_att = CreateTemplateTupleDesc(natts, hasoids);
relation->rd_att->tdtypeid = relationReltype;
relation->rd_att->tdtypmod = -1; /* unnecessary, but... */
/*
* initialize tuple desc info
*/
has_not_null = false;
for (i = 0; i < natts; i++)
{
memcpy(relation->rd_att->attrs[i],
&att[i],
ATTRIBUTE_TUPLE_SIZE);
has_not_null |= att[i].attnotnull;
/* make sure attcacheoff is valid */
relation->rd_att->attrs[i]->attcacheoff = -1;
}
/* initialize first attribute's attcacheoff, cf RelationBuildTupleDesc */
relation->rd_att->attrs[0]->attcacheoff = 0;
/* mark not-null status */
if (has_not_null)
{
TupleConstr *constr = (TupleConstr *) palloc0(sizeof(TupleConstr));
constr->has_not_null = true;
relation->rd_att->constr = constr;
}
/*
* initialize relation id from info in att array (my, this is ugly)
*/
RelationGetRelid(relation) = relation->rd_att->attrs[0]->attrelid;
relation->rd_rel->relfilenode = RelationGetRelid(relation);
/*
* initialize the relation lock manager information
*/
RelationInitLockInfo(relation); /* see lmgr.c */
/*
* initialize physical addressing information for the relation
*/
RelationInitPhysicalAddr(relation);
/*
* initialize the rel-has-index flag, using hardwired knowledge
*/
if (IsBootstrapProcessingMode())
{
/* In bootstrap mode, we have no indexes */
relation->rd_rel->relhasindex = false;
}
else
{
/* Otherwise, all the rels formrdesc is used for have indexes */
relation->rd_rel->relhasindex = true;
}
/*
* add new reldesc to relcache
*/
RelationCacheInsert(relation);
/* It's fully valid */
relation->rd_isvalid = true;
}
/* ----------------------------------------------------------------
* Relation Descriptor Lookup Interface
* ----------------------------------------------------------------
*/
/*
* RelationIdCacheGetRelation
*
* Lookup an existing reldesc by OID.
*
* Only try to get the reldesc by looking in the cache,
* do not go to the disk if it's not present.
*
* NB: relation ref count is incremented if successful.
* Caller should eventually decrement count. (Usually,
* that happens by calling RelationClose().)
*/
Relation
RelationIdCacheGetRelation(Oid relationId)
{
Relation rd;
RelationIdCacheLookup(relationId, rd);
if (RelationIsValid(rd))
{
RelationIncrementReferenceCount(rd);
/* revalidate nailed index if necessary */
if (!rd->rd_isvalid)
RelationReloadClassinfo(rd);
}
return rd;
}
/*
* RelationIdGetRelation
*
* Lookup a reldesc by OID; make one if not already in cache.
*
* NB: relation ref count is incremented, or set to 1 if new entry.
* Caller should eventually decrement count. (Usually,
* that happens by calling RelationClose().)
*/
Relation
RelationIdGetRelation(Oid relationId)
{
Relation rd;
/*
* first try and get a reldesc from the cache
*/
rd = RelationIdCacheGetRelation(relationId);
if (RelationIsValid(rd))
return rd;
/*
* no reldesc in the cache, so have RelationBuildDesc() build one and
* add it.
*/
rd = RelationBuildDesc(relationId, NULL);
if (RelationIsValid(rd))
RelationIncrementReferenceCount(rd);
return rd;
}
/* ----------------------------------------------------------------
* cache invalidation support routines
* ----------------------------------------------------------------
*/
/*
* RelationIncrementReferenceCount
* Increments relation reference count.
*
* Note: bootstrap mode has its own weird ideas about relation refcount
* behavior; we ought to fix it someday, but for now, just disable
* reference count ownership tracking in bootstrap mode.
*/
void
RelationIncrementReferenceCount(Relation rel)
{
ResourceOwnerEnlargeRelationRefs(CurrentResourceOwner);
rel->rd_refcnt += 1;
if (!IsBootstrapProcessingMode())
ResourceOwnerRememberRelationRef(CurrentResourceOwner, rel);
}
/*
* RelationDecrementReferenceCount
* Decrements relation reference count.
*/
void
RelationDecrementReferenceCount(Relation rel)
{
Assert(rel->rd_refcnt > 0);
rel->rd_refcnt -= 1;
if (!IsBootstrapProcessingMode())
ResourceOwnerForgetRelationRef(CurrentResourceOwner, rel);
}
/*
* RelationClose - close an open relation
*
* Actually, we just decrement the refcount.
*
* NOTE: if compiled with -DRELCACHE_FORCE_RELEASE then relcache entries
* will be freed as soon as their refcount goes to zero. In combination
* with aset.c's CLOBBER_FREED_MEMORY option, this provides a good test
* to catch references to already-released relcache entries. It slows
* things down quite a bit, however.
*/
void
RelationClose(Relation relation)
{
/* Note: no locking manipulations needed */
RelationDecrementReferenceCount(relation);
#ifdef RELCACHE_FORCE_RELEASE
if (RelationHasReferenceCountZero(relation) &&
relation->rd_createSubid == InvalidSubTransactionId)
RelationClearRelation(relation, false);
#endif
}
/*
* RelationReloadClassinfo - reload the pg_class row (only)
*
* This function is used only for nailed indexes. Since a REINDEX can
* change the relfilenode value for a nailed index, we have to reread
* the pg_class row anytime we get an SI invalidation on a nailed index
* (without throwing away the whole relcache entry, since we'd be unable
* to rebuild it).
*
* We can't necessarily reread the pg_class row right away; we might be
* in a failed transaction when we receive the SI notification. If so,
* RelationClearRelation just marks the entry as invalid by setting
* rd_isvalid to false. This routine is called to fix the entry when it
* is next needed.
*/
static void
RelationReloadClassinfo(Relation relation)
{
bool indexOK;
HeapTuple pg_class_tuple;
Form_pg_class relp;
/* Should be called only for invalidated nailed indexes */
Assert(relation->rd_isnailed && !relation->rd_isvalid &&
relation->rd_rel->relkind == RELKIND_INDEX);
/*
* Read the pg_class row
*
* Don't try to use an indexscan of pg_class_oid_index to reload the
* info for pg_class_oid_index ...
*/
indexOK = (RelationGetRelid(relation) != ClassOidIndexId);
pg_class_tuple = ScanPgRelation(RelationGetRelid(relation), indexOK);
if (!HeapTupleIsValid(pg_class_tuple))
elog(ERROR, "could not find tuple for system relation %u",
RelationGetRelid(relation));
relp = (Form_pg_class) GETSTRUCT(pg_class_tuple);
memcpy((char *) relation->rd_rel, (char *) relp, CLASS_TUPLE_SIZE);
/* Now we can recalculate physical address */
RelationInitPhysicalAddr(relation);
heap_freetuple(pg_class_tuple);
relation->rd_targblock = InvalidBlockNumber;
/* Okay, now it's valid again */
relation->rd_isvalid = true;
}
/*
* RelationClearRelation
*
* Physically blow away a relation cache entry, or reset it and rebuild
* it from scratch (that is, from catalog entries). The latter path is
* usually used when we are notified of a change to an open relation
* (one with refcount > 0). However, this routine just does whichever
* it's told to do; callers must determine which they want.
*/
static void
RelationClearRelation(Relation relation, bool rebuild)
{
Oid old_reltype = relation->rd_rel->reltype;
MemoryContext oldcxt;
/*
* Make sure smgr and lower levels close the relation's files, if they
* weren't closed already. If the relation is not getting deleted,
* the next smgr access should reopen the files automatically. This
* ensures that the low-level file access state is updated after, say,
* a vacuum truncation.
*/
RelationCloseSmgr(relation);
/*
* Never, never ever blow away a nailed-in system relation, because
* we'd be unable to recover. However, we must reset rd_targblock, in
* case we got called because of a relation cache flush that was
* triggered by VACUUM.
*
* If it's a nailed index, then we need to re-read the pg_class row to
* see if its relfilenode changed. We can't necessarily do that here,
* because we might be in a failed transaction. We assume it's okay
* to do it if there are open references to the relcache entry (cf
* notes for AtEOXact_RelationCache). Otherwise just mark the entry
* as possibly invalid, and it'll be fixed when next opened.
*/
if (relation->rd_isnailed)
{
relation->rd_targblock = InvalidBlockNumber;
if (relation->rd_rel->relkind == RELKIND_INDEX)
{
relation->rd_isvalid = false; /* needs to be revalidated */
if (relation->rd_refcnt > 1)
RelationReloadClassinfo(relation);
}
return;
}
/*
* Remove relation from hash tables
*
* Note: we might be reinserting it momentarily, but we must not have it
* visible in the hash tables until it's valid again, so don't try to
* optimize this away...
*/
oldcxt = MemoryContextSwitchTo(CacheMemoryContext);
RelationCacheDelete(relation);
MemoryContextSwitchTo(oldcxt);
/* Clear out catcache's entries for this relation */
CatalogCacheFlushRelation(RelationGetRelid(relation));
/*
* Free all the subsidiary data structures of the relcache entry. We
* cannot free rd_att if we are trying to rebuild the entry, however,
* because pointers to it may be cached in various places. The rule
* manager might also have pointers into the rewrite rules. So to
* begin with, we can only get rid of these fields:
*/
FreeTriggerDesc(relation->trigdesc);
if (relation->rd_indextuple)
pfree(relation->rd_indextuple);
if (relation->rd_am)
pfree(relation->rd_am);
if (relation->rd_rel)
pfree(relation->rd_rel);
list_free(relation->rd_indexlist);
if (relation->rd_indexcxt)
MemoryContextDelete(relation->rd_indexcxt);
/*
* If we're really done with the relcache entry, blow it away. But if
* someone is still using it, reconstruct the whole deal without
* moving the physical RelationData record (so that the someone's
* pointer is still valid).
*/
if (!rebuild)
{
/* ok to zap remaining substructure */
flush_rowtype_cache(old_reltype);
FreeTupleDesc(relation->rd_att);
if (relation->rd_rulescxt)
MemoryContextDelete(relation->rd_rulescxt);
pfree(relation);
}
else
{
/*
* When rebuilding an open relcache entry, must preserve ref count
* and rd_createSubid state. Also attempt to preserve the
* tupledesc and rewrite-rule substructures in place.
*
* Note that this process does not touch CurrentResourceOwner; which
* is good because whatever ref counts the entry may have do not
* necessarily belong to that resource owner.
*/
Oid save_relid = RelationGetRelid(relation);
int old_refcnt = relation->rd_refcnt;
SubTransactionId old_createSubid = relation->rd_createSubid;
TupleDesc old_att = relation->rd_att;
RuleLock *old_rules = relation->rd_rules;
MemoryContext old_rulescxt = relation->rd_rulescxt;
if (RelationBuildDesc(save_relid, relation) != relation)
{
/* Should only get here if relation was deleted */
flush_rowtype_cache(old_reltype);
FreeTupleDesc(old_att);
if (old_rulescxt)
MemoryContextDelete(old_rulescxt);
pfree(relation);
elog(ERROR, "relation %u deleted while still in use", save_relid);
}
relation->rd_refcnt = old_refcnt;
relation->rd_createSubid = old_createSubid;
if (equalTupleDescs(old_att, relation->rd_att))
{
/* needn't flush typcache here */
FreeTupleDesc(relation->rd_att);
relation->rd_att = old_att;
}
else
{
flush_rowtype_cache(old_reltype);
FreeTupleDesc(old_att);
}
if (equalRuleLocks(old_rules, relation->rd_rules))
{
if (relation->rd_rulescxt)
MemoryContextDelete(relation->rd_rulescxt);
relation->rd_rules = old_rules;
relation->rd_rulescxt = old_rulescxt;
}
else
{
if (old_rulescxt)
MemoryContextDelete(old_rulescxt);
}
}
}
/*
* RelationFlushRelation
*
* Rebuild the relation if it is open (refcount > 0), else blow it away.
*/
static void
RelationFlushRelation(Relation relation)
{
bool rebuild;
if (relation->rd_createSubid != InvalidSubTransactionId)
{
/*
* New relcache entries are always rebuilt, not flushed; else we'd
* forget the "new" status of the relation, which is a useful
* optimization to have.
*/
rebuild = true;
}
else
{
/*
* Pre-existing rels can be dropped from the relcache if not open.
*/
rebuild = !RelationHasReferenceCountZero(relation);
}
RelationClearRelation(relation, rebuild);
}
/*
* RelationForgetRelation - unconditionally remove a relcache entry
*
* External interface for destroying a relcache entry when we
* drop the relation.
*/
void
RelationForgetRelation(Oid rid)
{
Relation relation;
RelationIdCacheLookup(rid, relation);
if (!PointerIsValid(relation))
return; /* not in cache, nothing to do */
if (!RelationHasReferenceCountZero(relation))
elog(ERROR, "relation %u is still open", rid);
/* Unconditionally destroy the relcache entry */
RelationClearRelation(relation, false);
}
/*
* RelationCacheInvalidateEntry
*
* This routine is invoked for SI cache flush messages.
*
* Any relcache entry matching the relid must be flushed. (Note: caller has
* already determined that the relid belongs to our database or is a shared
* relation.)
*
* We used to skip local relations, on the grounds that they could
* not be targets of cross-backend SI update messages; but it seems
* safer to process them, so that our *own* SI update messages will
* have the same effects during CommandCounterIncrement for both
* local and nonlocal relations.
*/
void
RelationCacheInvalidateEntry(Oid relationId)
{
Relation relation;
RelationIdCacheLookup(relationId, relation);
if (PointerIsValid(relation))
{
relcacheInvalsReceived++;
RelationFlushRelation(relation);
}
}
/*
* RelationCacheInvalidate
* Blow away cached relation descriptors that have zero reference counts,
* and rebuild those with positive reference counts. Also reset the smgr
* relation cache.
*
* This is currently used only to recover from SI message buffer overflow,
* so we do not touch new-in-transaction relations; they cannot be targets
* of cross-backend SI updates (and our own updates now go through a
* separate linked list that isn't limited by the SI message buffer size).
*
* We do this in two phases: the first pass deletes deletable items, and
* the second one rebuilds the rebuildable items. This is essential for
* safety, because hash_seq_search only copes with concurrent deletion of
* the element it is currently visiting. If a second SI overflow were to
* occur while we are walking the table, resulting in recursive entry to
* this routine, we could crash because the inner invocation blows away
* the entry next to be visited by the outer scan. But this way is OK,
* because (a) during the first pass we won't process any more SI messages,
* so hash_seq_search will complete safely; (b) during the second pass we
* only hold onto pointers to nondeletable entries.
*
* The two-phase approach also makes it easy to ensure that we process
* nailed-in-cache indexes before other nondeletable items, and that we
* process pg_class_oid_index first of all. In scenarios where a nailed
* index has been given a new relfilenode, we have to detect that update
* before the nailed index is used in reloading any other relcache entry.
*/
void
RelationCacheInvalidate(void)
{
HASH_SEQ_STATUS status;
RelIdCacheEnt *idhentry;
Relation relation;
List *rebuildFirstList = NIL;
List *rebuildList = NIL;
ListCell *l;
/* Phase 1 */
hash_seq_init(&status, RelationIdCache);
while ((idhentry = (RelIdCacheEnt *) hash_seq_search(&status)) != NULL)
{
relation = idhentry->reldesc;
/* Must close all smgr references to avoid leaving dangling ptrs */
RelationCloseSmgr(relation);
/* Ignore new relations, since they are never SI targets */
if (relation->rd_createSubid != InvalidSubTransactionId)
continue;
relcacheInvalsReceived++;
if (RelationHasReferenceCountZero(relation))
{
/* Delete this entry immediately */
Assert(!relation->rd_isnailed);
RelationClearRelation(relation, false);
}
else
{
/*
* Add this entry to list of stuff to rebuild in second pass.
* pg_class_oid_index goes on the front of rebuildFirstList,
* other nailed indexes on the back, and everything else into
* rebuildList (in no particular order).
*/
if (relation->rd_isnailed &&
relation->rd_rel->relkind == RELKIND_INDEX)
{
if (RelationGetRelid(relation) == ClassOidIndexId)
rebuildFirstList = lcons(relation, rebuildFirstList);
else
rebuildFirstList = lappend(rebuildFirstList, relation);
}
else
rebuildList = lcons(relation, rebuildList);
}
}
rebuildList = list_concat(rebuildFirstList, rebuildList);
/*
* Now zap any remaining smgr cache entries. This must happen before
* we start to rebuild entries, since that may involve catalog fetches
* which will re-open catalog files.
*/
smgrcloseall();
/* Phase 2: rebuild the items found to need rebuild in phase 1 */
foreach(l, rebuildList)
{
relation = (Relation) lfirst(l);
RelationClearRelation(relation, true);
}
list_free(rebuildList);
}
/*
* AtEOXact_RelationCache
*
* Clean up the relcache at main-transaction commit or abort.
*
* Note: this must be called *before* processing invalidation messages.
* In the case of abort, we don't want to try to rebuild any invalidated
* cache entries (since we can't safely do database accesses). Therefore
* we must reset refcnts before handling pending invalidations.
*/
void
AtEOXact_RelationCache(bool isCommit)
{
HASH_SEQ_STATUS status;
RelIdCacheEnt *idhentry;
hash_seq_init(&status, RelationIdCache);
while ((idhentry = (RelIdCacheEnt *) hash_seq_search(&status)) != NULL)
{
Relation relation = idhentry->reldesc;
int expected_refcnt;
/*
* Is it a relation created in the current transaction?
*
* During commit, reset the flag to zero, since we are now out of the
* creating transaction. During abort, simply delete the relcache
* entry --- it isn't interesting any longer. (NOTE: if we have
* forgotten the new-ness of a new relation due to a forced cache
* flush, the entry will get deleted anyway by shared-cache-inval
* processing of the aborted pg_class insertion.)
*/
if (relation->rd_createSubid != InvalidSubTransactionId)
{
if (isCommit)
relation->rd_createSubid = InvalidSubTransactionId;
else
{
RelationClearRelation(relation, false);
continue;
}
}
/*
* During transaction abort, we must also reset relcache entry ref
* counts to their normal not-in-a-transaction state. A ref count
* may be too high because some routine was exited by ereport()
* between incrementing and decrementing the count.
*
* During commit, we should not have to do this, but it's still
* useful to check that the counts are correct to catch missed
* relcache closes.
*
* In bootstrap mode, do NOT reset the refcnt nor complain that it's
* nonzero --- the bootstrap code expects relations to stay open
* across start/commit transaction calls. (That seems bogus, but
* it's not worth fixing.)
*/
expected_refcnt = relation->rd_isnailed ? 1 : 0;
if (isCommit)
{
if (relation->rd_refcnt != expected_refcnt &&
!IsBootstrapProcessingMode())
{
elog(WARNING, "relcache reference leak: relation \"%s\" has refcnt %d instead of %d",
RelationGetRelationName(relation),
relation->rd_refcnt, expected_refcnt);
relation->rd_refcnt = expected_refcnt;
}
}
else
{
/* abort case, just reset it quietly */
relation->rd_refcnt = expected_refcnt;
}
/*
* Flush any temporary index list.
*/
if (relation->rd_indexvalid == 2)
{
list_free(relation->rd_indexlist);
relation->rd_indexlist = NIL;
relation->rd_indexvalid = 0;
}
}
/* Once done with the transaction, we can reset need_eosubxact_work */
need_eosubxact_work = false;
}
/*
* AtEOSubXact_RelationCache
*
* Clean up the relcache at sub-transaction commit or abort.
*
* Note: this must be called *before* processing invalidation messages.
*/
void
AtEOSubXact_RelationCache(bool isCommit, SubTransactionId mySubid,
SubTransactionId parentSubid)
{
HASH_SEQ_STATUS status;
RelIdCacheEnt *idhentry;
/*
* In the majority of subtransactions there is not anything for this
* routine to do, and since there are usually many entries in the
* relcache, uselessly scanning the cache represents a surprisingly
* large fraction of the subtransaction entry/exit overhead. To avoid
* this, we keep a static flag that must be set whenever a condition
* is created that requires subtransaction-end work. (Currently, this
* means either a relation is created in the current xact, or an index
* list is forced.) For simplicity, the flag remains set till end of
* top-level transaction, even though we could clear it earlier in some
* cases.
*/
if (!need_eosubxact_work)
return;
hash_seq_init(&status, RelationIdCache);
while ((idhentry = (RelIdCacheEnt *) hash_seq_search(&status)) != NULL)
{
Relation relation = idhentry->reldesc;
/*
* Is it a relation created in the current subtransaction?
*
* During subcommit, mark it as belonging to the parent, instead.
* During subabort, simply delete the relcache entry.
*/
if (relation->rd_createSubid == mySubid)
{
if (isCommit)
relation->rd_createSubid = parentSubid;
else
{
Assert(RelationHasReferenceCountZero(relation));
RelationClearRelation(relation, false);
continue;
}
}
/*
* Flush any temporary index list.
*/
if (relation->rd_indexvalid == 2)
{
list_free(relation->rd_indexlist);
relation->rd_indexlist = NIL;
relation->rd_indexvalid = 0;
}
}
}
/*
* RelationBuildLocalRelation
* Build a relcache entry for an about-to-be-created relation,
* and enter it into the relcache.
*/
Relation
RelationBuildLocalRelation(const char *relname,
Oid relnamespace,
TupleDesc tupDesc,
Oid relid,
Oid reltablespace,
bool shared_relation)
{
Relation rel;
MemoryContext oldcxt;
int natts = tupDesc->natts;
int i;
bool has_not_null;
bool nailit;
AssertArg(natts >= 0);
/*
* check for creation of a rel that must be nailed in cache.
*
* XXX this list had better match RelationCacheInitialize's list.
*/
switch (relid)
{
case RelationRelationId:
case AttributeRelationId:
case ProcedureRelationId:
case TypeRelationId:
nailit = true;
break;
default:
nailit = false;
break;
}
/*
* switch to the cache context to create the relcache entry.
*/
if (!CacheMemoryContext)
CreateCacheMemoryContext();
oldcxt = MemoryContextSwitchTo(CacheMemoryContext);
/*
* allocate a new relation descriptor and fill in basic state fields.
*/
rel = (Relation) palloc0(sizeof(RelationData));
rel->rd_targblock = InvalidBlockNumber;
/* make sure relation is marked as having no open file yet */
rel->rd_smgr = NULL;
/* mark it nailed if appropriate */
rel->rd_isnailed = nailit;
rel->rd_refcnt = nailit ? 1 : 0;
/* it's being created in this transaction */
rel->rd_createSubid = GetCurrentSubTransactionId();
/* must flag that we have rels created in this transaction */
need_eosubxact_work = true;
/* is it a temporary relation? */
rel->rd_istemp = isTempNamespace(relnamespace);
/*
* create a new tuple descriptor from the one passed in. We do this
* partly to copy it into the cache context, and partly because the
* new relation can't have any defaults or constraints yet; they have
* to be added in later steps, because they require additions to
* multiple system catalogs. We can copy attnotnull constraints here,
* however.
*/
rel->rd_att = CreateTupleDescCopy(tupDesc);
has_not_null = false;
for (i = 0; i < natts; i++)
{
rel->rd_att->attrs[i]->attnotnull = tupDesc->attrs[i]->attnotnull;
has_not_null |= tupDesc->attrs[i]->attnotnull;
}
if (has_not_null)
{
TupleConstr *constr = (TupleConstr *) palloc0(sizeof(TupleConstr));
constr->has_not_null = true;
rel->rd_att->constr = constr;
}
/*
* initialize relation tuple form (caller may add/override data later)
*/
rel->rd_rel = (Form_pg_class) palloc0(CLASS_TUPLE_SIZE);
namestrcpy(&rel->rd_rel->relname, relname);
rel->rd_rel->relnamespace = relnamespace;
rel->rd_rel->relkind = RELKIND_UNCATALOGED;
rel->rd_rel->relhasoids = rel->rd_att->tdhasoid;
rel->rd_rel->relnatts = natts;
rel->rd_rel->reltype = InvalidOid;
/*
* Insert relation physical and logical identifiers (OIDs) into the
* right places. Note that the physical ID (relfilenode) is initially
* the same as the logical ID (OID).
*/
rel->rd_rel->relisshared = shared_relation;
RelationGetRelid(rel) = relid;
for (i = 0; i < natts; i++)
rel->rd_att->attrs[i]->attrelid = relid;
rel->rd_rel->relfilenode = relid;
rel->rd_rel->reltablespace = reltablespace;
RelationInitLockInfo(rel); /* see lmgr.c */
RelationInitPhysicalAddr(rel);
/*
* Okay to insert into the relcache hash tables.
*/
RelationCacheInsert(rel);
/*
* done building relcache entry.
*/
MemoryContextSwitchTo(oldcxt);
/* It's fully valid */
rel->rd_isvalid = true;
/*
* Caller expects us to pin the returned entry.
*/
RelationIncrementReferenceCount(rel);
return rel;
}
/*
* RelationCacheInitialize
*
* This initializes the relation descriptor cache. At the time
* that this is invoked, we can't do database access yet (mainly
* because the transaction subsystem is not up), so we can't get
* "real" info. However it's okay to read the pg_internal.init
* cache file, if one is available. Otherwise we make phony
* entries for the minimum set of nailed-in-cache relations.
*/
#define INITRELCACHESIZE 400
void
RelationCacheInitialize(void)
{
MemoryContext oldcxt;
HASHCTL ctl;
/*
* switch to cache memory context
*/
if (!CacheMemoryContext)
CreateCacheMemoryContext();
oldcxt = MemoryContextSwitchTo(CacheMemoryContext);
/*
* create hashtables that index the relcache
*/
MemSet(&ctl, 0, sizeof(ctl));
ctl.keysize = sizeof(Oid);
ctl.entrysize = sizeof(RelIdCacheEnt);
ctl.hash = oid_hash;
RelationIdCache = hash_create("Relcache by OID", INITRELCACHESIZE,
&ctl, HASH_ELEM | HASH_FUNCTION);
/*
* Try to load the relcache cache file. If successful, we're done for
* now. Otherwise, initialize the cache with pre-made descriptors for
* the critical "nailed-in" system catalogs.
*/
if (IsBootstrapProcessingMode() ||
!load_relcache_init_file())
{
formrdesc("pg_class", PG_CLASS_RELTYPE_OID,
true, Natts_pg_class, Desc_pg_class);
formrdesc("pg_attribute", PG_ATTRIBUTE_RELTYPE_OID,
false, Natts_pg_attribute, Desc_pg_attribute);
formrdesc("pg_proc", PG_PROC_RELTYPE_OID,
true, Natts_pg_proc, Desc_pg_proc);
formrdesc("pg_type", PG_TYPE_RELTYPE_OID,
true, Natts_pg_type, Desc_pg_type);
#define NUM_CRITICAL_RELS 4 /* fix if you change list above */
}
MemoryContextSwitchTo(oldcxt);
}
/*
* RelationCacheInitializePhase2
*
* This is called as soon as the catcache and transaction system
* are functional. At this point we can actually read data from
* the system catalogs. Update the relcache entries made during
* RelationCacheInitialize, and make sure we have entries for the
* critical system indexes.
*/
void
RelationCacheInitializePhase2(void)
{
HASH_SEQ_STATUS status;
RelIdCacheEnt *idhentry;
if (IsBootstrapProcessingMode())
return;
/*
* If we didn't get the critical system indexes loaded into relcache,
* do so now. These are critical because the catcache depends on them
* for catcache fetches that are done during relcache load. Thus, we
* have an infinite-recursion problem. We can break the recursion by
* doing heapscans instead of indexscans at certain key spots. To
* avoid hobbling performance, we only want to do that until we have
* the critical indexes loaded into relcache. Thus, the flag
* criticalRelcachesBuilt is used to decide whether to do heapscan or
* indexscan at the key spots, and we set it true after we've loaded
* the critical indexes.
*
* The critical indexes are marked as "nailed in cache", partly to make
* it easy for load_relcache_init_file to count them, but mainly
* because we cannot flush and rebuild them once we've set
* criticalRelcachesBuilt to true. (NOTE: perhaps it would be
* possible to reload them by temporarily setting
* criticalRelcachesBuilt to false again. For now, though, we just
* nail 'em in.)
*/
if (!criticalRelcachesBuilt)
{
Relation ird;
#define LOAD_CRIT_INDEX(indexoid) \
do { \
ird = RelationBuildDesc((indexoid), NULL); \
ird->rd_isnailed = true; \
ird->rd_refcnt = 1; \
} while (0)
LOAD_CRIT_INDEX(ClassOidIndexId);
LOAD_CRIT_INDEX(AttributeRelidNumIndexId);
LOAD_CRIT_INDEX(IndexRelidIndexId);
LOAD_CRIT_INDEX(AccessMethodStrategyIndexId);
LOAD_CRIT_INDEX(AccessMethodProcedureIndexId);
LOAD_CRIT_INDEX(OperatorOidIndexId);
#define NUM_CRITICAL_INDEXES 6 /* fix if you change list above */
criticalRelcachesBuilt = true;
}
/*
* Now, scan all the relcache entries and update anything that might
* be wrong in the results from formrdesc or the relcache cache file.
* If we faked up relcache entries using formrdesc, then read the real
* pg_class rows and replace the fake entries with them. Also, if any
* of the relcache entries have rules or triggers, load that info the
* hard way since it isn't recorded in the cache file.
*/
hash_seq_init(&status, RelationIdCache);
while ((idhentry = (RelIdCacheEnt *) hash_seq_search(&status)) != NULL)
{
Relation relation = idhentry->reldesc;
/*
* If it's a faked-up entry, read the real pg_class tuple.
*/
if (needNewCacheFile && relation->rd_isnailed)
{
HeapTuple htup;
Form_pg_class relp;
htup = SearchSysCache(RELOID,
ObjectIdGetDatum(RelationGetRelid(relation)),
0, 0, 0);
if (!HeapTupleIsValid(htup))
elog(FATAL, "cache lookup failed for relation %u",
RelationGetRelid(relation));
relp = (Form_pg_class) GETSTRUCT(htup);
/*
* Copy tuple to relation->rd_rel. (See notes in
* AllocateRelationDesc())
*/
Assert(relation->rd_rel != NULL);
memcpy((char *) relation->rd_rel, (char *) relp, CLASS_TUPLE_SIZE);
/*
* Also update the derived fields in rd_att.
*/
relation->rd_att->tdtypeid = relp->reltype;
relation->rd_att->tdtypmod = -1; /* unnecessary, but... */
relation->rd_att->tdhasoid = relp->relhasoids;
ReleaseSysCache(htup);
}
/*
* Fix data that isn't saved in relcache cache file.
*/
if (relation->rd_rel->relhasrules && relation->rd_rules == NULL)
RelationBuildRuleLock(relation);
if (relation->rd_rel->reltriggers > 0 && relation->trigdesc == NULL)
RelationBuildTriggers(relation);
}
}
/*
* RelationCacheInitializePhase3
*
* Final step of relcache initialization: write out a new relcache
* cache file if one is needed.
*/
void
RelationCacheInitializePhase3(void)
{
if (IsBootstrapProcessingMode())
return;
if (needNewCacheFile)
{
/*
* Force all the catcaches to finish initializing and thereby open
* the catalogs and indexes they use. This will preload the
* relcache with entries for all the most important system
* catalogs and indexes, so that the init file will be most useful
* for future backends.
*/
InitCatalogCachePhase2();
/* now write the file */
write_relcache_init_file();
}
}
/*
* GetPgIndexDescriptor -- get a predefined tuple descriptor for pg_index
*
* We need this kluge because we have to be able to access non-fixed-width
* fields of pg_index before we have the standard catalog caches available.
* We use predefined data that's set up in just the same way as the
* bootstrapped reldescs used by formrdesc(). The resulting tupdesc is
* not 100% kosher: it does not have the correct rowtype OID in tdtypeid,
* nor does it have a TupleConstr field. But it's good enough for the
* purpose of extracting fields.
*/
static TupleDesc
GetPgIndexDescriptor(void)
{
static TupleDesc pgindexdesc = NULL;
MemoryContext oldcxt;
int i;
/* Already done? */
if (pgindexdesc)
return pgindexdesc;
oldcxt = MemoryContextSwitchTo(CacheMemoryContext);
pgindexdesc = CreateTemplateTupleDesc(Natts_pg_index, false);
pgindexdesc->tdtypeid = RECORDOID; /* not right, but we don't care */
pgindexdesc->tdtypmod = -1;
for (i = 0; i < Natts_pg_index; i++)
{
memcpy(pgindexdesc->attrs[i],
&Desc_pg_index[i],
ATTRIBUTE_TUPLE_SIZE);
/* make sure attcacheoff is valid */
pgindexdesc->attrs[i]->attcacheoff = -1;
}
/* initialize first attribute's attcacheoff, cf RelationBuildTupleDesc */
pgindexdesc->attrs[0]->attcacheoff = 0;
/* Note: we don't bother to set up a TupleConstr entry */
MemoryContextSwitchTo(oldcxt);
return pgindexdesc;
}
static void
AttrDefaultFetch(Relation relation)
{
AttrDefault *attrdef = relation->rd_att->constr->defval;
int ndef = relation->rd_att->constr->num_defval;
Relation adrel;
SysScanDesc adscan;
ScanKeyData skey;
HeapTuple htup;
Datum val;
bool isnull;
int found;
int i;
ScanKeyInit(&skey,
Anum_pg_attrdef_adrelid,
BTEqualStrategyNumber, F_OIDEQ,
ObjectIdGetDatum(RelationGetRelid(relation)));
adrel = heap_open(AttrDefaultRelationId, AccessShareLock);
adscan = systable_beginscan(adrel, AttrDefaultIndexId, true,
SnapshotNow, 1, &skey);
found = 0;
while (HeapTupleIsValid(htup = systable_getnext(adscan)))
{
Form_pg_attrdef adform = (Form_pg_attrdef) GETSTRUCT(htup);
for (i = 0; i < ndef; i++)
{
if (adform->adnum != attrdef[i].adnum)
continue;
if (attrdef[i].adbin != NULL)
elog(WARNING, "multiple attrdef records found for attr %s of rel %s",
NameStr(relation->rd_att->attrs[adform->adnum - 1]->attname),
RelationGetRelationName(relation));
else
found++;
val = fastgetattr(htup,
Anum_pg_attrdef_adbin,
adrel->rd_att, &isnull);
if (isnull)
elog(WARNING, "null adbin for attr %s of rel %s",
NameStr(relation->rd_att->attrs[adform->adnum - 1]->attname),
RelationGetRelationName(relation));
else
attrdef[i].adbin = MemoryContextStrdup(CacheMemoryContext,
DatumGetCString(DirectFunctionCall1(textout,
val)));
break;
}
if (i >= ndef)
elog(WARNING, "unexpected attrdef record found for attr %d of rel %s",
adform->adnum, RelationGetRelationName(relation));
}
systable_endscan(adscan);
heap_close(adrel, AccessShareLock);
if (found != ndef)
elog(WARNING, "%d attrdef record(s) missing for rel %s",
ndef - found, RelationGetRelationName(relation));
}
static void
CheckConstraintFetch(Relation relation)
{
ConstrCheck *check = relation->rd_att->constr->check;
int ncheck = relation->rd_att->constr->num_check;
Relation conrel;
SysScanDesc conscan;
ScanKeyData skey[1];
HeapTuple htup;
Datum val;
bool isnull;
int found = 0;
ScanKeyInit(&skey[0],
Anum_pg_constraint_conrelid,
BTEqualStrategyNumber, F_OIDEQ,
ObjectIdGetDatum(RelationGetRelid(relation)));
conrel = heap_open(ConstraintRelationId, AccessShareLock);
conscan = systable_beginscan(conrel, ConstraintRelidIndexId, true,
SnapshotNow, 1, skey);
while (HeapTupleIsValid(htup = systable_getnext(conscan)))
{
Form_pg_constraint conform = (Form_pg_constraint) GETSTRUCT(htup);
/* We want check constraints only */
if (conform->contype != CONSTRAINT_CHECK)
continue;
if (found >= ncheck)
elog(ERROR, "unexpected constraint record found for rel %s",
RelationGetRelationName(relation));
check[found].ccname = MemoryContextStrdup(CacheMemoryContext,
NameStr(conform->conname));
/* Grab and test conbin is actually set */
val = fastgetattr(htup,
Anum_pg_constraint_conbin,
conrel->rd_att, &isnull);
if (isnull)
elog(ERROR, "null conbin for rel %s",
RelationGetRelationName(relation));
check[found].ccbin = MemoryContextStrdup(CacheMemoryContext,
DatumGetCString(DirectFunctionCall1(textout,
val)));
found++;
}
systable_endscan(conscan);
heap_close(conrel, AccessShareLock);
if (found != ncheck)
elog(ERROR, "%d constraint record(s) missing for rel %s",
ncheck - found, RelationGetRelationName(relation));
}
/*
* RelationGetIndexList -- get a list of OIDs of indexes on this relation
*
* The index list is created only if someone requests it. We scan pg_index
* to find relevant indexes, and add the list to the relcache entry so that
* we won't have to compute it again. Note that shared cache inval of a
* relcache entry will delete the old list and set rd_indexvalid to 0,
* so that we must recompute the index list on next request. This handles
* creation or deletion of an index.
*
* The returned list is guaranteed to be sorted in order by OID. This is
* needed by the executor, since for index types that we obtain exclusive
* locks on when updating the index, all backends must lock the indexes in
* the same order or we will get deadlocks (see ExecOpenIndices()). Any
* consistent ordering would do, but ordering by OID is easy.
*
* Since shared cache inval causes the relcache's copy of the list to go away,
* we return a copy of the list palloc'd in the caller's context. The caller
* may freeList() the returned list after scanning it. This is necessary
* since the caller will typically be doing syscache lookups on the relevant
* indexes, and syscache lookup could cause SI messages to be processed!
*/
List *
RelationGetIndexList(Relation relation)
{
Relation indrel;
SysScanDesc indscan;
ScanKeyData skey;
HeapTuple htup;
List *result;
MemoryContext oldcxt;
/* Quick exit if we already computed the list. */
if (relation->rd_indexvalid != 0)
return list_copy(relation->rd_indexlist);
/*
* We build the list we intend to return (in the caller's context)
* while doing the scan. After successfully completing the scan, we
* copy that list into the relcache entry. This avoids cache-context
* memory leakage if we get some sort of error partway through.
*/
result = NIL;
/* Prepare to scan pg_index for entries having indrelid = this rel. */
ScanKeyInit(&skey,
Anum_pg_index_indrelid,
BTEqualStrategyNumber, F_OIDEQ,
ObjectIdGetDatum(RelationGetRelid(relation)));
indrel = heap_open(IndexRelationId, AccessShareLock);
indscan = systable_beginscan(indrel, IndexIndrelidIndexId, true,
SnapshotNow, 1, &skey);
while (HeapTupleIsValid(htup = systable_getnext(indscan)))
{
Form_pg_index index = (Form_pg_index) GETSTRUCT(htup);
result = insert_ordered_oid(result, index->indexrelid);
}
systable_endscan(indscan);
heap_close(indrel, AccessShareLock);
/* Now save a copy of the completed list in the relcache entry. */
oldcxt = MemoryContextSwitchTo(CacheMemoryContext);
relation->rd_indexlist = list_copy(result);
relation->rd_indexvalid = 1;
MemoryContextSwitchTo(oldcxt);
return result;
}
/*
* insert_ordered_oid
* Insert a new Oid into a sorted list of Oids, preserving ordering
*
* Building the ordered list this way is O(N^2), but with a pretty small
* constant, so for the number of entries we expect it will probably be
* faster than trying to apply qsort(). Most tables don't have very many
* indexes...
*/
static List *
insert_ordered_oid(List *list, Oid datum)
{
ListCell *prev;
/* Does the datum belong at the front? */
if (list == NIL || datum < linitial_oid(list))
return lcons_oid(datum, list);
/* No, so find the entry it belongs after */
prev = list_head(list);
for (;;)
{
ListCell *curr = lnext(prev);
if (curr == NULL || datum < lfirst_oid(curr))
break; /* it belongs after 'prev', before 'curr' */
prev = curr;
}
/* Insert datum into list after 'prev' */
lappend_cell_oid(list, prev, datum);
return list;
}
/*
* RelationSetIndexList -- externally force the index list contents
*
* This is used to temporarily override what we think the set of valid
* indexes is. The forcing will be valid only until transaction commit
* or abort.
*
* This should only be applied to nailed relations, because in a non-nailed
* relation the hacked index list could be lost at any time due to SI
* messages. In practice it is only used on pg_class (see REINDEX).
*
* It is up to the caller to make sure the given list is correctly ordered.
*/
void
RelationSetIndexList(Relation relation, List *indexIds)
{
MemoryContext oldcxt;
Assert(relation->rd_isnailed);
/* Copy the list into the cache context (could fail for lack of mem) */
oldcxt = MemoryContextSwitchTo(CacheMemoryContext);
indexIds = list_copy(indexIds);
MemoryContextSwitchTo(oldcxt);
/* Okay to replace old list */
list_free(relation->rd_indexlist);
relation->rd_indexlist = indexIds;
relation->rd_indexvalid = 2; /* mark list as forced */
/* must flag that we have a forced index list */
need_eosubxact_work = true;
}
/*
* RelationGetIndexExpressions -- get the index expressions for an index
*
* We cache the result of transforming pg_index.indexprs into a node tree.
* If the rel is not an index or has no expressional columns, we return NIL.
* Otherwise, the returned tree is copied into the caller's memory context.
* (We don't want to return a pointer to the relcache copy, since it could
* disappear due to relcache invalidation.)
*/
List *
RelationGetIndexExpressions(Relation relation)
{
List *result;
Datum exprsDatum;
bool isnull;
char *exprsString;
MemoryContext oldcxt;
/* Quick exit if we already computed the result. */
if (relation->rd_indexprs)
return (List *) copyObject(relation->rd_indexprs);
/* Quick exit if there is nothing to do. */
if (relation->rd_indextuple == NULL ||
heap_attisnull(relation->rd_indextuple, Anum_pg_index_indexprs))
return NIL;
/*
* We build the tree we intend to return in the caller's context.
* After successfully completing the work, we copy it into the
* relcache entry. This avoids problems if we get some sort of error
* partway through.
*/
exprsDatum = heap_getattr(relation->rd_indextuple,
Anum_pg_index_indexprs,
GetPgIndexDescriptor(),
&isnull);
Assert(!isnull);
exprsString = DatumGetCString(DirectFunctionCall1(textout, exprsDatum));
result = (List *) stringToNode(exprsString);
pfree(exprsString);
/*
* Run the expressions through eval_const_expressions. This is not just an
* optimization, but is necessary, because the planner will be comparing
* them to similarly-processed qual clauses, and may fail to detect valid
* matches without this. We don't bother with canonicalize_qual, however.
*/
result = (List *) eval_const_expressions((Node *) result);
/*
* Also mark any coercion format fields as "don't care", so that the
* planner can match to both explicit and implicit coercions.
*/
set_coercionform_dontcare((Node *) result);
/* May as well fix opfuncids too */
fix_opfuncids((Node *) result);
/* Now save a copy of the completed tree in the relcache entry. */
oldcxt = MemoryContextSwitchTo(CacheMemoryContext);
relation->rd_indexprs = (List *) copyObject(result);
MemoryContextSwitchTo(oldcxt);
return result;
}
/*
* RelationGetIndexPredicate -- get the index predicate for an index
*
* We cache the result of transforming pg_index.indpred into an implicit-AND
* node tree (suitable for ExecQual).
* If the rel is not an index or has no predicate, we return NIL.
* Otherwise, the returned tree is copied into the caller's memory context.
* (We don't want to return a pointer to the relcache copy, since it could
* disappear due to relcache invalidation.)
*/
List *
RelationGetIndexPredicate(Relation relation)
{
List *result;
Datum predDatum;
bool isnull;
char *predString;
MemoryContext oldcxt;
/* Quick exit if we already computed the result. */
if (relation->rd_indpred)
return (List *) copyObject(relation->rd_indpred);
/* Quick exit if there is nothing to do. */
if (relation->rd_indextuple == NULL ||
heap_attisnull(relation->rd_indextuple, Anum_pg_index_indpred))
return NIL;
/*
* We build the tree we intend to return in the caller's context.
* After successfully completing the work, we copy it into the
* relcache entry. This avoids problems if we get some sort of error
* partway through.
*/
predDatum = heap_getattr(relation->rd_indextuple,
Anum_pg_index_indpred,
GetPgIndexDescriptor(),
&isnull);
Assert(!isnull);
predString = DatumGetCString(DirectFunctionCall1(textout, predDatum));
result = (List *) stringToNode(predString);
pfree(predString);
/*
* Run the expression through const-simplification and canonicalization.
* This is not just an optimization, but is necessary, because the planner
* will be comparing it to similarly-processed qual clauses, and may fail
* to detect valid matches without this. This must match the processing
* done to qual clauses in preprocess_expression()! (We can skip the
* stuff involving subqueries, however, since we don't allow any in
* index predicates.)
*/
result = (List *) eval_const_expressions((Node *) result);
result = (List *) canonicalize_qual((Expr *) result);
/*
* Also mark any coercion format fields as "don't care", so that the
* planner can match to both explicit and implicit coercions.
*/
set_coercionform_dontcare((Node *) result);
/* Also convert to implicit-AND format */
result = make_ands_implicit((Expr *) result);
/* May as well fix opfuncids too */
fix_opfuncids((Node *) result);
/* Now save a copy of the completed tree in the relcache entry. */
oldcxt = MemoryContextSwitchTo(CacheMemoryContext);
relation->rd_indpred = (List *) copyObject(result);
MemoryContextSwitchTo(oldcxt);
return result;
}
/*
* load_relcache_init_file, write_relcache_init_file
*
* In late 1992, we started regularly having databases with more than
* a thousand classes in them. With this number of classes, it became
* critical to do indexed lookups on the system catalogs.
*
* Bootstrapping these lookups is very hard. We want to be able to
* use an index on pg_attribute, for example, but in order to do so,
* we must have read pg_attribute for the attributes in the index,
* which implies that we need to use the index.
*
* In order to get around the problem, we do the following:
*
* + When the database system is initialized (at initdb time), we
* don't use indexes. We do sequential scans.
*
* + When the backend is started up in normal mode, we load an image
* of the appropriate relation descriptors, in internal format,
* from an initialization file in the data/base/... directory.
*
* + If the initialization file isn't there, then we create the
* relation descriptors using sequential scans and write 'em to
* the initialization file for use by subsequent backends.
*
* We could dispense with the initialization file and just build the
* critical reldescs the hard way on every backend startup, but that
* slows down backend startup noticeably.
*
* We can in fact go further, and save more relcache entries than
* just the ones that are absolutely critical; this allows us to speed
* up backend startup by not having to build such entries the hard way.
* Presently, all the catalog and index entries that are referred to
* by catcaches are stored in the initialization file.
*
* The same mechanism that detects when catcache and relcache entries
* need to be invalidated (due to catalog updates) also arranges to
* unlink the initialization file when its contents may be out of date.
* The file will then be rebuilt during the next backend startup.
*/
/*
* load_relcache_init_file -- attempt to load cache from the init file
*
* If successful, return TRUE and set criticalRelcachesBuilt to true.
* If not successful, return FALSE and set needNewCacheFile to true.
*
* NOTE: we assume we are already switched into CacheMemoryContext.
*/
static bool
load_relcache_init_file(void)
{
FILE *fp;
char initfilename[MAXPGPATH];
Relation *rels;
int relno,
num_rels,
max_rels,
nailed_rels,
nailed_indexes,
magic;
int i;
snprintf(initfilename, sizeof(initfilename), "%s/%s",
DatabasePath, RELCACHE_INIT_FILENAME);
fp = AllocateFile(initfilename, PG_BINARY_R);
if (fp == NULL)
{
needNewCacheFile = true;
return false;
}
/*
* Read the index relcache entries from the file. Note we will not
* enter any of them into the cache if the read fails partway through;
* this helps to guard against broken init files.
*/
max_rels = 100;
rels = (Relation *) palloc(max_rels * sizeof(Relation));
num_rels = 0;
nailed_rels = nailed_indexes = 0;
initFileRelationIds = NIL;
/* check for correct magic number (compatible version) */
if (fread(&magic, 1, sizeof(magic), fp) != sizeof(magic))
goto read_failed;
if (magic != RELCACHE_INIT_FILEMAGIC)
goto read_failed;
for (relno = 0;; relno++)
{
Size len;
size_t nread;
Relation rel;
Form_pg_class relform;
bool has_not_null;
Datum indclassDatum;
bool isnull;
/* first read the relation descriptor length */
if ((nread = fread(&len, 1, sizeof(len), fp)) != sizeof(len))
{
if (nread == 0)
break; /* end of file */
goto read_failed;
}
/* safety check for incompatible relcache layout */
if (len != sizeof(RelationData))
goto read_failed;
/* allocate another relcache header */
if (num_rels >= max_rels)
{
max_rels *= 2;
rels = (Relation *) repalloc(rels, max_rels * sizeof(Relation));
}
rel = rels[num_rels++] = (Relation) palloc(len);
/* then, read the Relation structure */
if ((nread = fread(rel, 1, len, fp)) != len)
goto read_failed;
/* next read the relation tuple form */
if ((nread = fread(&len, 1, sizeof(len), fp)) != sizeof(len))
goto read_failed;
relform = (Form_pg_class) palloc(len);
if ((nread = fread(relform, 1, len, fp)) != len)
goto read_failed;
rel->rd_rel = relform;
/* initialize attribute tuple forms */
rel->rd_att = CreateTemplateTupleDesc(relform->relnatts,
relform->relhasoids);
rel->rd_att->tdtypeid = relform->reltype;
rel->rd_att->tdtypmod = -1; /* unnecessary, but... */
/* next read all the attribute tuple form data entries */
has_not_null = false;
for (i = 0; i < relform->relnatts; i++)
{
if ((nread = fread(&len, 1, sizeof(len), fp)) != sizeof(len))
goto read_failed;
if (len != ATTRIBUTE_TUPLE_SIZE)
goto read_failed;
if ((nread = fread(rel->rd_att->attrs[i], 1, len, fp)) != len)
goto read_failed;
has_not_null |= rel->rd_att->attrs[i]->attnotnull;
}
/* mark not-null status */
if (has_not_null)
{
TupleConstr *constr = (TupleConstr *) palloc0(sizeof(TupleConstr));
constr->has_not_null = true;
rel->rd_att->constr = constr;
}
/* If it's an index, there's more to do */
if (rel->rd_rel->relkind == RELKIND_INDEX)
{
Form_pg_am am;
MemoryContext indexcxt;
Oid *operator;
RegProcedure *support;
int nsupport;
/* Count nailed indexes to ensure we have 'em all */
if (rel->rd_isnailed)
nailed_indexes++;
/* next, read the pg_index tuple */
if ((nread = fread(&len, 1, sizeof(len), fp)) != sizeof(len))
goto read_failed;
rel->rd_indextuple = (HeapTuple) palloc(len);
if ((nread = fread(rel->rd_indextuple, 1, len, fp)) != len)
goto read_failed;
/* Fix up internal pointers in the tuple -- see heap_copytuple */
rel->rd_indextuple->t_datamcxt = CurrentMemoryContext;
rel->rd_indextuple->t_data = (HeapTupleHeader) ((char *) rel->rd_indextuple + HEAPTUPLESIZE);
rel->rd_index = (Form_pg_index) GETSTRUCT(rel->rd_indextuple);
/* fix up indclass pointer too */
indclassDatum = fastgetattr(rel->rd_indextuple,
Anum_pg_index_indclass,
GetPgIndexDescriptor(),
&isnull);
Assert(!isnull);
rel->rd_indclass = (oidvector *) DatumGetPointer(indclassDatum);
/* next, read the access method tuple form */
if ((nread = fread(&len, 1, sizeof(len), fp)) != sizeof(len))
goto read_failed;
am = (Form_pg_am) palloc(len);
if ((nread = fread(am, 1, len, fp)) != len)
goto read_failed;
rel->rd_am = am;
/*
* prepare index info context --- parameters should match
* RelationInitIndexAccessInfo
*/
indexcxt = AllocSetContextCreate(CacheMemoryContext,
RelationGetRelationName(rel),
ALLOCSET_SMALL_MINSIZE,
ALLOCSET_SMALL_INITSIZE,
ALLOCSET_SMALL_MAXSIZE);
rel->rd_indexcxt = indexcxt;
/* next, read the vector of operator OIDs */
if ((nread = fread(&len, 1, sizeof(len), fp)) != sizeof(len))
goto read_failed;
operator = (Oid *) MemoryContextAlloc(indexcxt, len);
if ((nread = fread(operator, 1, len, fp)) != len)
goto read_failed;
rel->rd_operator = operator;
/* finally, read the vector of support procedures */
if ((nread = fread(&len, 1, sizeof(len), fp)) != sizeof(len))
goto read_failed;
support = (RegProcedure *) MemoryContextAlloc(indexcxt, len);
if ((nread = fread(support, 1, len, fp)) != len)
goto read_failed;
rel->rd_support = support;
/* add a zeroed support-fmgr-info vector */
nsupport = relform->relnatts * am->amsupport;
rel->rd_supportinfo = (FmgrInfo *)
MemoryContextAllocZero(indexcxt, nsupport * sizeof(FmgrInfo));
}
else
{
/* Count nailed rels to ensure we have 'em all */
if (rel->rd_isnailed)
nailed_rels++;
Assert(rel->rd_index == NULL);
Assert(rel->rd_indextuple == NULL);
Assert(rel->rd_indclass == NULL);
Assert(rel->rd_am == NULL);
Assert(rel->rd_indexcxt == NULL);
Assert(rel->rd_operator == NULL);
Assert(rel->rd_support == NULL);
Assert(rel->rd_supportinfo == NULL);
}
/*
* Rules and triggers are not saved (mainly because the internal
* format is complex and subject to change). They must be rebuilt
* if needed by RelationCacheInitializePhase2. This is not
* expected to be a big performance hit since few system catalogs
* have such. Ditto for index expressions and predicates.
*/
rel->rd_rules = NULL;
rel->rd_rulescxt = NULL;
rel->trigdesc = NULL;
rel->rd_indexprs = NIL;
rel->rd_indpred = NIL;
/*
* Reset transient-state fields in the relcache entry
*/
rel->rd_smgr = NULL;
rel->rd_targblock = InvalidBlockNumber;
if (rel->rd_isnailed)
rel->rd_refcnt = 1;
else
rel->rd_refcnt = 0;
rel->rd_indexvalid = 0;
rel->rd_indexlist = NIL;
rel->rd_createSubid = InvalidSubTransactionId;
MemSet(&rel->pgstat_info, 0, sizeof(rel->pgstat_info));
/*
* Recompute lock and physical addressing info. This is needed in
* case the pg_internal.init file was copied from some other
* database by CREATE DATABASE.
*/
RelationInitLockInfo(rel);
RelationInitPhysicalAddr(rel);
}
/*
* We reached the end of the init file without apparent problem. Did
* we get the right number of nailed items? (This is a useful
* crosscheck in case the set of critical rels or indexes changes.)
*/
if (nailed_rels != NUM_CRITICAL_RELS ||
nailed_indexes != NUM_CRITICAL_INDEXES)
goto read_failed;
/*
* OK, all appears well.
*
* Now insert all the new relcache entries into the cache.
*/
for (relno = 0; relno < num_rels; relno++)
{
RelationCacheInsert(rels[relno]);
/* also make a list of their OIDs, for RelationIdIsInInitFile */
initFileRelationIds = lcons_oid(RelationGetRelid(rels[relno]),
initFileRelationIds);
}
pfree(rels);
FreeFile(fp);
criticalRelcachesBuilt = true;
return true;
/*
* init file is broken, so do it the hard way. We don't bother trying
* to free the clutter we just allocated; it's not in the relcache so
* it won't hurt.
*/
read_failed:
pfree(rels);
FreeFile(fp);
needNewCacheFile = true;
return false;
}
/*
* Write out a new initialization file with the current contents
* of the relcache.
*/
static void
write_relcache_init_file(void)
{
FILE *fp;
char tempfilename[MAXPGPATH];
char finalfilename[MAXPGPATH];
int magic;
HASH_SEQ_STATUS status;
RelIdCacheEnt *idhentry;
MemoryContext oldcxt;
int i;
/*
* We must write a temporary file and rename it into place. Otherwise,
* another backend starting at about the same time might crash trying
* to read the partially-complete file.
*/
snprintf(tempfilename, sizeof(tempfilename), "%s/%s.%d",
DatabasePath, RELCACHE_INIT_FILENAME, MyProcPid);
snprintf(finalfilename, sizeof(finalfilename), "%s/%s",
DatabasePath, RELCACHE_INIT_FILENAME);
unlink(tempfilename); /* in case it exists w/wrong permissions */
fp = AllocateFile(tempfilename, PG_BINARY_W);
if (fp == NULL)
{
/*
* We used to consider this a fatal error, but we might as well
* continue with backend startup ...
*/
ereport(WARNING,
(errcode_for_file_access(),
errmsg("could not create relation-cache initialization file \"%s\": %m",
tempfilename),
errdetail("Continuing anyway, but there's something wrong.")));
return;
}
/*
* Write a magic number to serve as a file version identifier. We can
* change the magic number whenever the relcache layout changes.
*/
magic = RELCACHE_INIT_FILEMAGIC;
if (fwrite(&magic, 1, sizeof(magic), fp) != sizeof(magic))
elog(FATAL, "could not write init file");
/*
* Write all the reldescs (in no particular order).
*/
hash_seq_init(&status, RelationIdCache);
initFileRelationIds = NIL;
while ((idhentry = (RelIdCacheEnt *) hash_seq_search(&status)) != NULL)
{
Relation rel = idhentry->reldesc;
Form_pg_class relform = rel->rd_rel;
Size len;
/*
* first write the relcache entry proper
*/
len = sizeof(RelationData);
/* first, write the relation descriptor length */
if (fwrite(&len, 1, sizeof(len), fp) != sizeof(len))
elog(FATAL, "could not write init file");
/* next, write out the Relation structure */
if (fwrite(rel, 1, len, fp) != len)
elog(FATAL, "could not write init file");
/* next write the relation tuple form */
len = sizeof(FormData_pg_class);
if (fwrite(&len, 1, sizeof(len), fp) != sizeof(len))
elog(FATAL, "could not write init file");
if (fwrite(relform, 1, len, fp) != len)
elog(FATAL, "could not write init file");
/* next, do all the attribute tuple form data entries */
for (i = 0; i < relform->relnatts; i++)
{
len = ATTRIBUTE_TUPLE_SIZE;
if (fwrite(&len, 1, sizeof(len), fp) != sizeof(len))
elog(FATAL, "could not write init file");
if (fwrite(rel->rd_att->attrs[i], 1, len, fp) != len)
elog(FATAL, "could not write init file");
}
/* If it's an index, there's more to do */
if (rel->rd_rel->relkind == RELKIND_INDEX)
{
Form_pg_am am = rel->rd_am;
/* write the pg_index tuple */
/* we assume this was created by heap_copytuple! */
len = HEAPTUPLESIZE + rel->rd_indextuple->t_len;
if (fwrite(&len, 1, sizeof(len), fp) != sizeof(len))
elog(FATAL, "could not write init file");
if (fwrite(rel->rd_indextuple, 1, len, fp) != len)
elog(FATAL, "could not write init file");
/* next, write the access method tuple form */
len = sizeof(FormData_pg_am);
if (fwrite(&len, 1, sizeof(len), fp) != sizeof(len))
elog(FATAL, "could not write init file");
if (fwrite(am, 1, len, fp) != len)
elog(FATAL, "could not write init file");
/* next, write the vector of operator OIDs */
len = relform->relnatts * (am->amstrategies * sizeof(Oid));
if (fwrite(&len, 1, sizeof(len), fp) != sizeof(len))
elog(FATAL, "could not write init file");
if (fwrite(rel->rd_operator, 1, len, fp) != len)
elog(FATAL, "could not write init file");
/* finally, write the vector of support procedures */
len = relform->relnatts * (am->amsupport * sizeof(RegProcedure));
if (fwrite(&len, 1, sizeof(len), fp) != sizeof(len))
elog(FATAL, "could not write init file");
if (fwrite(rel->rd_support, 1, len, fp) != len)
elog(FATAL, "could not write init file");
}
/* also make a list of their OIDs, for RelationIdIsInInitFile */
oldcxt = MemoryContextSwitchTo(CacheMemoryContext);
initFileRelationIds = lcons_oid(RelationGetRelid(rel),
initFileRelationIds);
MemoryContextSwitchTo(oldcxt);
}
if (FreeFile(fp))
elog(FATAL, "could not write init file");
/*
* Now we have to check whether the data we've so painstakingly
* accumulated is already obsolete due to someone else's
* just-committed catalog changes. If so, we just delete the temp
* file and leave it to the next backend to try again. (Our own
* relcache entries will be updated by SI message processing, but we
* can't be sure whether what we wrote out was up-to-date.)
*
* This mustn't run concurrently with RelationCacheInitFileInvalidate, so
* grab a serialization lock for the duration.
*/
LWLockAcquire(RelCacheInitLock, LW_EXCLUSIVE);
/* Make sure we have seen all incoming SI messages */
AcceptInvalidationMessages();
/*
* If we have received any SI relcache invals since backend start,
* assume we may have written out-of-date data.
*/
if (relcacheInvalsReceived == 0L)
{
/*
* OK, rename the temp file to its final name, deleting any
* previously-existing init file.
*
* Note: a failure here is possible under Cygwin, if some other
* backend is holding open an unlinked-but-not-yet-gone init file.
* So treat this as a noncritical failure; just remove the useless
* temp file on failure.
*/
if (rename(tempfilename, finalfilename) < 0)
unlink(tempfilename);
}
else
{
/* Delete the already-obsolete temp file */
unlink(tempfilename);
}
LWLockRelease(RelCacheInitLock);
}
/*
* Detect whether a given relation (identified by OID) is one of the ones
* we store in the init file.
*
* Note that we effectively assume that all backends running in a database
* would choose to store the same set of relations in the init file;
* otherwise there are cases where we'd fail to detect the need for an init
* file invalidation. This does not seem likely to be a problem in practice.
*/
bool
RelationIdIsInInitFile(Oid relationId)
{
return list_member_oid(initFileRelationIds, relationId);
}
/*
* Invalidate (remove) the init file during commit of a transaction that
* changed one or more of the relation cache entries that are kept in the
* init file.
*
* We actually need to remove the init file twice: once just before sending
* the SI messages that include relcache inval for such relations, and once
* just after sending them. The unlink before ensures that a backend that's
* currently starting cannot read the now-obsolete init file and then miss
* the SI messages that will force it to update its relcache entries. (This
* works because the backend startup sequence gets into the PROC array before
* trying to load the init file.) The unlink after is to synchronize with a
* backend that may currently be trying to write an init file based on data
* that we've just rendered invalid. Such a backend will see the SI messages,
* but we can't leave the init file sitting around to fool later backends.
*
* Ignore any failure to unlink the file, since it might not be there if
* no backend has been started since the last removal.
*/
void
RelationCacheInitFileInvalidate(bool beforeSend)
{
char initfilename[MAXPGPATH];
snprintf(initfilename, sizeof(initfilename), "%s/%s",
DatabasePath, RELCACHE_INIT_FILENAME);
if (beforeSend)
{
/* no interlock needed here */
unlink(initfilename);
}
else
{
/*
* We need to interlock this against write_relcache_init_file, to
* guard against possibility that someone renames a new-but-
* already-obsolete init file into place just after we unlink.
* With the interlock, it's certain that write_relcache_init_file
* will notice our SI inval message before renaming into place, or
* else that we will execute second and successfully unlink the
* file.
*/
LWLockAcquire(RelCacheInitLock, LW_EXCLUSIVE);
unlink(initfilename);
LWLockRelease(RelCacheInitLock);
}
}
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