plancache.c

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/*-------------------------------------------------------------------------
 *
 * plancache.c
 *    Plan cache management.
 *
 * The plan cache manager has two principal responsibilities: deciding when
 * to use a generic plan versus a custom (parameter-value-specific) plan,
 * and tracking whether cached plans need to be invalidated because of schema
 * changes in the objects they depend on.
 *
 * The logic for choosing generic or custom plans is in choose_custom_plan,
 * which see for comments.
 *
 * Cache invalidation is driven off sinval events.  Any CachedPlanSource
 * that matches the event is marked invalid, as is its generic CachedPlan
 * if it has one.  When (and if) the next demand for a cached plan occurs,
 * parse analysis and/or rewrite is repeated to build a new valid query tree,
 * and then planning is performed as normal.  We also force re-analysis and
 * re-planning if the active search_path is different from the previous time
 * or, if RLS is involved, if the user changes or the RLS environment changes.
 *
 * Note that if the sinval was a result of user DDL actions, parse analysis
 * could throw an error, for example if a column referenced by the query is
 * no longer present.  Another possibility is for the query's output tupdesc
 * to change (for instance "SELECT *" might expand differently than before).
 * The creator of a cached plan can specify whether it is allowable for the
 * query to change output tupdesc on replan --- if so, it's up to the
 * caller to notice changes and cope with them.
 *
 * Currently, we track exactly the dependencies of plans on relations,
 * user-defined functions, and domains.  On relcache invalidation events or
 * pg_proc or pg_type syscache invalidation events, we invalidate just those
 * plans that depend on the particular object being modified.  (Note: this
 * scheme assumes that any table modification that requires replanning will
 * generate a relcache inval event.)  We also watch for inval events on
 * certain other system catalogs, such as pg_namespace; but for them, our
 * response is just to invalidate all plans.  We expect updates on those
 * catalogs to be infrequent enough that more-detailed tracking is not worth
 * the effort.
 *
 * In addition to full-fledged query plans, we provide a facility for
 * detecting invalidations of simple scalar expressions.  This is fairly
 * bare-bones; it's the caller's responsibility to build a new expression
 * if the old one gets invalidated.
 *
 *
 * Portions Copyright (c) 1996-2026, PostgreSQL Global Development Group
 * Portions Copyright (c) 1994, Regents of the University of California
 *
 * IDENTIFICATION
 *    src/backend/utils/cache/plancache.c
 *
 *-------------------------------------------------------------------------
 */
#include "postgres.h"
 
#include <limits.h>
 
#include "access/transam.h"
#include "catalog/namespace.h"
#include "executor/executor.h"
#include "miscadmin.h"
#include "nodes/nodeFuncs.h"
#include "optimizer/optimizer.h"
#include "parser/analyze.h"
#include "rewrite/rewriteHandler.h"
#include "storage/lmgr.h"
#include "tcop/pquery.h"
#include "tcop/utility.h"
#include "utils/inval.h"
#include "utils/memutils.h"
#include "utils/resowner.h"
#include "utils/rls.h"
#include "utils/snapmgr.h"
#include "utils/syscache.h"
 
 
/*
 * This is the head of the backend's list of "saved" CachedPlanSources (i.e.,
 * those that are in long-lived storage and are examined for sinval events).
 * We use a dlist instead of separate List cells so that we can guarantee
 * to save a CachedPlanSource without error.
 */
static dlist_head saved_plan_list = DLIST_STATIC_INIT(saved_plan_list);
 
/*
 * This is the head of the backend's list of CachedExpressions.
 */
static dlist_head cached_expression_list = DLIST_STATIC_INIT(cached_expression_list);
 
static void ReleaseGenericPlan(CachedPlanSource *plansource);
static bool StmtPlanRequiresRevalidation(CachedPlanSource *plansource);
static bool BuildingPlanRequiresSnapshot(CachedPlanSource *plansource);
static List *RevalidateCachedQuery(CachedPlanSource *plansource,
                                   QueryEnvironment *queryEnv);
static bool CheckCachedPlan(CachedPlanSource *plansource);
static CachedPlan *BuildCachedPlan(CachedPlanSource *plansource, List *qlist,
                                   ParamListInfo boundParams, QueryEnvironment *queryEnv);
static bool choose_custom_plan(CachedPlanSource *plansource,
                               ParamListInfo boundParams);
static double cached_plan_cost(CachedPlan *plan, bool include_planner);
static Query *QueryListGetPrimaryStmt(List *stmts);
static void AcquireExecutorLocks(List *stmt_list, bool acquire);
static void AcquirePlannerLocks(List *stmt_list, bool acquire);
static void ScanQueryForLocks(Query *parsetree, bool acquire);
static bool ScanQueryWalker(Node *node, bool *acquire);
static TupleDesc PlanCacheComputeResultDesc(List *stmt_list);
static void PlanCacheRelCallback(Datum arg, Oid relid);
static void PlanCacheObjectCallback(Datum arg, SysCacheIdentifier cacheid,
                                    uint32 hashvalue);
static void PlanCacheSysCallback(Datum arg, SysCacheIdentifier cacheid,
                                 uint32 hashvalue);
 
/* ResourceOwner callbacks to track plancache references */
static void ResOwnerReleaseCachedPlan(Datum res);
 
static const ResourceOwnerDesc planref_resowner_desc =
{
    .name = "plancache reference",
    .release_phase = RESOURCE_RELEASE_AFTER_LOCKS,
    .release_priority = RELEASE_PRIO_PLANCACHE_REFS,
    .ReleaseResource = ResOwnerReleaseCachedPlan,
    .DebugPrint = NULL          /* the default message is fine */
};
 
/* Convenience wrappers over ResourceOwnerRemember/Forget */
static inline void
ResourceOwnerRememberPlanCacheRef(ResourceOwner owner, CachedPlan *plan)
{
    ResourceOwnerRemember(owner, PointerGetDatum(plan), &planref_resowner_desc);
}
static inline void
ResourceOwnerForgetPlanCacheRef(ResourceOwner owner, CachedPlan *plan)
{
    ResourceOwnerForget(owner, PointerGetDatum(plan), &planref_resowner_desc);
}
 
 
/* GUC parameter */
int         plan_cache_mode = PLAN_CACHE_MODE_AUTO;
 
/*
 * InitPlanCache: initialize module during InitPostgres.
 *
 * All we need to do is hook into inval.c's callback lists.
 */
void
InitPlanCache(void)
{
    CacheRegisterRelcacheCallback(PlanCacheRelCallback, (Datum) 0);
    CacheRegisterSyscacheCallback(PROCOID, PlanCacheObjectCallback, (Datum) 0);
    CacheRegisterSyscacheCallback(TYPEOID, PlanCacheObjectCallback, (Datum) 0);
    CacheRegisterSyscacheCallback(NAMESPACEOID, PlanCacheSysCallback, (Datum) 0);
    CacheRegisterSyscacheCallback(OPEROID, PlanCacheSysCallback, (Datum) 0);
    CacheRegisterSyscacheCallback(AMOPOPID, PlanCacheSysCallback, (Datum) 0);
    CacheRegisterSyscacheCallback(FOREIGNSERVEROID, PlanCacheSysCallback, (Datum) 0);
    CacheRegisterSyscacheCallback(FOREIGNDATAWRAPPEROID, PlanCacheSysCallback, (Datum) 0);
}
 
/*
 * CreateCachedPlan: initially create a plan cache entry for a raw parse tree.
 *
 * Creation of a cached plan is divided into two steps, CreateCachedPlan and
 * CompleteCachedPlan.  CreateCachedPlan should be called after running the
 * query through raw_parser, but before doing parse analysis and rewrite;
 * CompleteCachedPlan is called after that.  The reason for this arrangement
 * is that it can save one round of copying of the raw parse tree, since
 * the parser will normally scribble on the raw parse tree.  Callers would
 * otherwise need to make an extra copy of the parse tree to ensure they
 * still had a clean copy to present at plan cache creation time.
 *
 * All arguments presented to CreateCachedPlan are copied into a memory
 * context created as a child of the call-time CurrentMemoryContext, which
 * should be a reasonably short-lived working context that will go away in
 * event of an error.  This ensures that the cached plan data structure will
 * likewise disappear if an error occurs before we have fully constructed it.
 * Once constructed, the cached plan can be made longer-lived, if needed,
 * by calling SaveCachedPlan.
 *
 * raw_parse_tree: output of raw_parser(), or NULL if empty query
 * query_string: original query text
 * commandTag: command tag for query, or UNKNOWN if empty query
 */
CachedPlanSource *
CreateCachedPlan(RawStmt *raw_parse_tree,
                 const char *query_string,
                 CommandTag commandTag)
{
    CachedPlanSource *plansource;
    MemoryContext source_context;
    MemoryContext oldcxt;
 
    Assert(query_string != NULL);   /* required as of 8.4 */
 
    /*
     * Make a dedicated memory context for the CachedPlanSource and its
     * permanent subsidiary data.  It's probably not going to be large, but
     * just in case, allow it to grow large.  Initially it's a child of the
     * caller's context (which we assume to be transient), so that it will be
     * cleaned up on error.
     */
    source_context = AllocSetContextCreate(CurrentMemoryContext,
                                           "CachedPlanSource",
                                           ALLOCSET_START_SMALL_SIZES);
 
    /*
     * Create and fill the CachedPlanSource struct within the new context.
     * Most fields are just left empty for the moment.
     */
    oldcxt = MemoryContextSwitchTo(source_context);
 
    plansource = palloc0_object(CachedPlanSource);
    plansource->magic = CACHEDPLANSOURCE_MAGIC;
    plansource->raw_parse_tree = copyObject(raw_parse_tree);
    plansource->analyzed_parse_tree = NULL;
    plansource->query_string = pstrdup(query_string);
    MemoryContextSetIdentifier(source_context, plansource->query_string);
    plansource->commandTag = commandTag;
    plansource->param_types = NULL;
    plansource->num_params = 0;
    plansource->parserSetup = NULL;
    plansource->parserSetupArg = NULL;
    plansource->postRewrite = NULL;
    plansource->postRewriteArg = NULL;
    plansource->cursor_options = 0;
    plansource->fixed_result = false;
    plansource->resultDesc = NULL;
    plansource->context = source_context;
    plansource->query_list = NIL;
    plansource->relationOids = NIL;
    plansource->invalItems = NIL;
    plansource->search_path = NULL;
    plansource->query_context = NULL;
    plansource->rewriteRoleId = InvalidOid;
    plansource->rewriteRowSecurity = false;
    plansource->dependsOnRLS = false;
    plansource->gplan = NULL;
    plansource->is_oneshot = false;
    plansource->is_complete = false;
    plansource->is_saved = false;
    plansource->is_valid = false;
    plansource->generation = 0;
    plansource->generic_cost = -1;
    plansource->total_custom_cost = 0;
    plansource->num_generic_plans = 0;
    plansource->num_custom_plans = 0;
 
    MemoryContextSwitchTo(oldcxt);
 
    return plansource;
}
 
/*
 * CreateCachedPlanForQuery: initially create a plan cache entry for a Query.
 *
 * This is used in the same way as CreateCachedPlan, except that the source
 * query has already been through parse analysis, and the plancache will never
 * try to re-do that step.
 *
 * Currently this is used only for new-style SQL functions, where we have a
 * Query from the function's prosqlbody, but no source text.  The query_string
 * is typically empty, but is required anyway.
 */
CachedPlanSource *
CreateCachedPlanForQuery(Query *analyzed_parse_tree,
                         const char *query_string,
                         CommandTag commandTag)
{
    CachedPlanSource *plansource;
    MemoryContext oldcxt;
 
    /* Rather than duplicating CreateCachedPlan, just do this: */
    plansource = CreateCachedPlan(NULL, query_string, commandTag);
    oldcxt = MemoryContextSwitchTo(plansource->context);
    plansource->analyzed_parse_tree = copyObject(analyzed_parse_tree);
    MemoryContextSwitchTo(oldcxt);
 
    return plansource;
}
 
/*
 * CreateOneShotCachedPlan: initially create a one-shot plan cache entry.
 *
 * This variant of CreateCachedPlan creates a plan cache entry that is meant
 * to be used only once.  No data copying occurs: all data structures remain
 * in the caller's memory context (which typically should get cleared after
 * completing execution).  The CachedPlanSource struct itself is also created
 * in that context.
 *
 * A one-shot plan cannot be saved or copied, since we make no effort to
 * preserve the raw parse tree unmodified.  There is also no support for
 * invalidation, so plan use must be completed in the current transaction,
 * and DDL that might invalidate the querytree_list must be avoided as well.
 *
 * raw_parse_tree: output of raw_parser(), or NULL if empty query
 * query_string: original query text
 * commandTag: command tag for query, or NULL if empty query
 */
CachedPlanSource *
CreateOneShotCachedPlan(RawStmt *raw_parse_tree,
                        const char *query_string,
                        CommandTag commandTag)
{
    CachedPlanSource *plansource;
 
    Assert(query_string != NULL);   /* required as of 8.4 */
 
    /*
     * Create and fill the CachedPlanSource struct within the caller's memory
     * context.  Most fields are just left empty for the moment.
     */
    plansource = palloc0_object(CachedPlanSource);
    plansource->magic = CACHEDPLANSOURCE_MAGIC;
    plansource->raw_parse_tree = raw_parse_tree;
    plansource->analyzed_parse_tree = NULL;
    plansource->query_string = query_string;
    plansource->commandTag = commandTag;
    plansource->param_types = NULL;
    plansource->num_params = 0;
    plansource->parserSetup = NULL;
    plansource->parserSetupArg = NULL;
    plansource->postRewrite = NULL;
    plansource->postRewriteArg = NULL;
    plansource->cursor_options = 0;
    plansource->fixed_result = false;
    plansource->resultDesc = NULL;
    plansource->context = CurrentMemoryContext;
    plansource->query_list = NIL;
    plansource->relationOids = NIL;
    plansource->invalItems = NIL;
    plansource->search_path = NULL;
    plansource->query_context = NULL;
    plansource->rewriteRoleId = InvalidOid;
    plansource->rewriteRowSecurity = false;
    plansource->dependsOnRLS = false;
    plansource->gplan = NULL;
    plansource->is_oneshot = true;
    plansource->is_complete = false;
    plansource->is_saved = false;
    plansource->is_valid = false;
    plansource->generation = 0;
    plansource->generic_cost = -1;
    plansource->total_custom_cost = 0;
    plansource->num_generic_plans = 0;
    plansource->num_custom_plans = 0;
 
    return plansource;
}
 
/*
 * CompleteCachedPlan: second step of creating a plan cache entry.
 *
 * Pass in the analyzed-and-rewritten form of the query, as well as the
 * required subsidiary data about parameters and such.  All passed values will
 * be copied into the CachedPlanSource's memory, except as specified below.
 * After this is called, GetCachedPlan can be called to obtain a plan, and
 * optionally the CachedPlanSource can be saved using SaveCachedPlan.
 *
 * If querytree_context is not NULL, the querytree_list must be stored in that
 * context (but the other parameters need not be).  The querytree_list is not
 * copied, rather the given context is kept as the initial query_context of
 * the CachedPlanSource.  (It should have been created as a child of the
 * caller's working memory context, but it will now be reparented to belong
 * to the CachedPlanSource.)  The querytree_context is normally the context in
 * which the caller did raw parsing and parse analysis.  This approach saves
 * one tree copying step compared to passing NULL, but leaves lots of extra
 * cruft in the query_context, namely whatever extraneous stuff parse analysis
 * created, as well as whatever went unused from the raw parse tree.  Using
 * this option is a space-for-time tradeoff that is appropriate if the
 * CachedPlanSource is not expected to survive long.
 *
 * plancache.c cannot know how to copy the data referenced by parserSetupArg,
 * and it would often be inappropriate to do so anyway.  When using that
 * option, it is caller's responsibility that the referenced data remains
 * valid for as long as the CachedPlanSource exists.
 *
 * If the CachedPlanSource is a "oneshot" plan, then no querytree copying
 * occurs at all, and querytree_context is ignored; it is caller's
 * responsibility that the passed querytree_list is sufficiently long-lived.
 *
 * plansource: structure returned by CreateCachedPlan
 * querytree_list: analyzed-and-rewritten form of query (list of Query nodes)
 * querytree_context: memory context containing querytree_list,
 *                    or NULL to copy querytree_list into a fresh context
 * param_types: array of fixed parameter type OIDs, or NULL if none
 * num_params: number of fixed parameters
 * parserSetup: alternate method for handling query parameters
 * parserSetupArg: data to pass to parserSetup
 * cursor_options: options bitmask to pass to planner
 * fixed_result: true to disallow future changes in query's result tupdesc
 */
void
CompleteCachedPlan(CachedPlanSource *plansource,
                   List *querytree_list,
                   MemoryContext querytree_context,
                   Oid *param_types,
                   int num_params,
                   ParserSetupHook parserSetup,
                   void *parserSetupArg,
                   int cursor_options,
                   bool fixed_result)
{
    MemoryContext source_context = plansource->context;
    MemoryContext oldcxt = CurrentMemoryContext;
 
    /* Assert caller is doing things in a sane order */
    Assert(plansource->magic == CACHEDPLANSOURCE_MAGIC);
    Assert(!plansource->is_complete);
 
    /*
     * If caller supplied a querytree_context, reparent it underneath the
     * CachedPlanSource's context; otherwise, create a suitable context and
     * copy the querytree_list into it.  But no data copying should be done
     * for one-shot plans; for those, assume the passed querytree_list is
     * sufficiently long-lived.
     */
    if (plansource->is_oneshot)
    {
        querytree_context = CurrentMemoryContext;
    }
    else if (querytree_context != NULL)
    {
        MemoryContextSetParent(querytree_context, source_context);
        MemoryContextSwitchTo(querytree_context);
    }
    else
    {
        /* Again, it's a good bet the querytree_context can be small */
        querytree_context = AllocSetContextCreate(source_context,
                                                  "CachedPlanQuery",
                                                  ALLOCSET_START_SMALL_SIZES);
        MemoryContextSwitchTo(querytree_context);
        querytree_list = copyObject(querytree_list);
    }
 
    plansource->query_context = querytree_context;
    plansource->query_list = querytree_list;
 
    if (!plansource->is_oneshot && StmtPlanRequiresRevalidation(plansource))
    {
        /*
         * Use the planner machinery to extract dependencies.  Data is saved
         * in query_context.  (We assume that not a lot of extra cruft is
         * created by this call.)  We can skip this for one-shot plans, and
         * plans not needing revalidation have no such dependencies anyway.
         */
        extract_query_dependencies((Node *) querytree_list,
                                   &plansource->relationOids,
                                   &plansource->invalItems,
                                   &plansource->dependsOnRLS);
 
        /* Update RLS info as well. */
        plansource->rewriteRoleId = GetUserId();
        plansource->rewriteRowSecurity = row_security;
 
        /*
         * Also save the current search_path in the query_context.  (This
         * should not generate much extra cruft either, since almost certainly
         * the path is already valid.)  Again, we don't really need this for
         * one-shot plans; and we *must* skip this for transaction control
         * commands, because this could result in catalog accesses.
         */
        plansource->search_path = GetSearchPathMatcher(querytree_context);
    }
 
    /*
     * Save the final parameter types (or other parameter specification data)
     * into the source_context, as well as our other parameters.
     */
    MemoryContextSwitchTo(source_context);
 
    if (num_params > 0)
    {
        plansource->param_types = palloc_array(Oid, num_params);
        memcpy(plansource->param_types, param_types, num_params * sizeof(Oid));
    }
    else
        plansource->param_types = NULL;
    plansource->num_params = num_params;
    plansource->parserSetup = parserSetup;
    plansource->parserSetupArg = parserSetupArg;
    plansource->cursor_options = cursor_options;
    plansource->fixed_result = fixed_result;
 
    /*
     * Also save the result tuple descriptor.  PlanCacheComputeResultDesc may
     * leak some cruft; normally we just accept that to save a copy step, but
     * in USE_VALGRIND mode be tidy by running it in the caller's context.
     */
#ifdef USE_VALGRIND
    MemoryContextSwitchTo(oldcxt);
    plansource->resultDesc = PlanCacheComputeResultDesc(querytree_list);
    if (plansource->resultDesc)
    {
        MemoryContextSwitchTo(source_context);
        plansource->resultDesc = CreateTupleDescCopy(plansource->resultDesc);
        MemoryContextSwitchTo(oldcxt);
    }
#else
    plansource->resultDesc = PlanCacheComputeResultDesc(querytree_list);
    MemoryContextSwitchTo(oldcxt);
#endif
 
    plansource->is_complete = true;
    plansource->is_valid = true;
}
 
/*
 * SetPostRewriteHook: set a hook to modify post-rewrite query trees
 *
 * Some callers have a need to modify the query trees between rewriting and
 * planning.  In the initial call to CompleteCachedPlan, it's assumed such
 * work was already done on the querytree_list.  However, if we're forced
 * to replan, it will need to be done over.  The caller can set this hook
 * to provide code to make that happen.
 *
 * postRewriteArg is just passed verbatim to the hook.  As with parserSetupArg,
 * it is caller's responsibility that the referenced data remains
 * valid for as long as the CachedPlanSource exists.
 */
void
SetPostRewriteHook(CachedPlanSource *plansource,
                   PostRewriteHook postRewrite,
                   void *postRewriteArg)
{
    Assert(plansource->magic == CACHEDPLANSOURCE_MAGIC);
    plansource->postRewrite = postRewrite;
    plansource->postRewriteArg = postRewriteArg;
}
 
/*
 * SaveCachedPlan: save a cached plan permanently
 *
 * This function moves the cached plan underneath CacheMemoryContext (making
 * it live for the life of the backend, unless explicitly dropped), and adds
 * it to the list of cached plans that are checked for invalidation when an
 * sinval event occurs.
 *
 * This is guaranteed not to throw error, except for the caller-error case
 * of trying to save a one-shot plan.  Callers typically depend on that
 * since this is called just before or just after adding a pointer to the
 * CachedPlanSource to some permanent data structure of their own.  Up until
 * this is done, a CachedPlanSource is just transient data that will go away
 * automatically on transaction abort.
 */
void
SaveCachedPlan(CachedPlanSource *plansource)
{
    /* Assert caller is doing things in a sane order */
    Assert(plansource->magic == CACHEDPLANSOURCE_MAGIC);
    Assert(plansource->is_complete);
    Assert(!plansource->is_saved);
 
    /* This seems worth a real test, though */
    if (plansource->is_oneshot)
        elog(ERROR, "cannot save one-shot cached plan");
 
    /*
     * In typical use, this function would be called before generating any
     * plans from the CachedPlanSource.  If there is a generic plan, moving it
     * into CacheMemoryContext would be pretty risky since it's unclear
     * whether the caller has taken suitable care with making references
     * long-lived.  Best thing to do seems to be to discard the plan.
     */
    ReleaseGenericPlan(plansource);
 
    /*
     * Reparent the source memory context under CacheMemoryContext so that it
     * will live indefinitely.  The query_context follows along since it's
     * already a child of the other one.
     */
    MemoryContextSetParent(plansource->context, CacheMemoryContext);
 
    /*
     * Add the entry to the global list of cached plans.
     */
    dlist_push_tail(&saved_plan_list, &plansource->node);
 
    plansource->is_saved = true;
}
 
/*
 * DropCachedPlan: destroy a cached plan.
 *
 * Actually this only destroys the CachedPlanSource: any referenced CachedPlan
 * is released, but not destroyed until its refcount goes to zero.  That
 * handles the situation where DropCachedPlan is called while the plan is
 * still in use.
 */
void
DropCachedPlan(CachedPlanSource *plansource)
{
    Assert(plansource->magic == CACHEDPLANSOURCE_MAGIC);
 
    /* If it's been saved, remove it from the list */
    if (plansource->is_saved)
    {
        dlist_delete(&plansource->node);
        plansource->is_saved = false;
    }
 
    /* Decrement generic CachedPlan's refcount and drop if no longer needed */
    ReleaseGenericPlan(plansource);
 
    /* Mark it no longer valid */
    plansource->magic = 0;
 
    /*
     * Remove the CachedPlanSource and all subsidiary data (including the
     * query_context if any).  But if it's a one-shot we can't free anything.
     */
    if (!plansource->is_oneshot)
        MemoryContextDelete(plansource->context);
}
 
/*
 * ReleaseGenericPlan: release a CachedPlanSource's generic plan, if any.
 */
static void
ReleaseGenericPlan(CachedPlanSource *plansource)
{
    /* Be paranoid about the possibility that ReleaseCachedPlan fails */
    if (plansource->gplan)
    {
        CachedPlan *plan = plansource->gplan;
 
        Assert(plan->magic == CACHEDPLAN_MAGIC);
        plansource->gplan = NULL;
        ReleaseCachedPlan(plan, NULL);
    }
}
 
/*
 * We must skip "overhead" operations that involve database access when the
 * cached plan's subject statement is a transaction control command or one
 * that requires a snapshot not to be set yet (such as SET or LOCK).  More
 * generally, statements that do not require parse analysis/rewrite/plan
 * activity never need to be revalidated, so we can treat them all like that.
 * For the convenience of postgres.c, treat empty statements that way too.
 */
static bool
StmtPlanRequiresRevalidation(CachedPlanSource *plansource)
{
    if (plansource->raw_parse_tree != NULL)
        return stmt_requires_parse_analysis(plansource->raw_parse_tree);
    else if (plansource->analyzed_parse_tree != NULL)
        return query_requires_rewrite_plan(plansource->analyzed_parse_tree);
    /* empty query never needs revalidation */
    return false;
}
 
/*
 * Determine if creating a plan for this CachedPlanSource requires a snapshot.
 * In fact this function matches StmtPlanRequiresRevalidation(), but we want
 * to preserve the distinction between stmt_requires_parse_analysis() and
 * analyze_requires_snapshot().
 */
static bool
BuildingPlanRequiresSnapshot(CachedPlanSource *plansource)
{
    if (plansource->raw_parse_tree != NULL)
        return analyze_requires_snapshot(plansource->raw_parse_tree);
    else if (plansource->analyzed_parse_tree != NULL)
        return query_requires_rewrite_plan(plansource->analyzed_parse_tree);
    /* empty query never needs a snapshot */
    return false;
}
 
/*
 * RevalidateCachedQuery: ensure validity of analyzed-and-rewritten query tree.
 *
 * What we do here is re-acquire locks and redo parse analysis if necessary.
 * On return, the query_list is valid and we have sufficient locks to begin
 * planning.
 *
 * If any parse analysis activity is required, the caller's memory context is
 * used for that work.
 *
 * The result value is the transient analyzed-and-rewritten query tree if we
 * had to do re-analysis, and NIL otherwise.  (This is returned just to save
 * a tree copying step in a subsequent BuildCachedPlan call.)
 */
static List *
RevalidateCachedQuery(CachedPlanSource *plansource,
                      QueryEnvironment *queryEnv)
{
    bool        snapshot_set;
    List       *tlist;          /* transient query-tree list */
    List       *qlist;          /* permanent query-tree list */
    TupleDesc   resultDesc;
    MemoryContext querytree_context;
    MemoryContext oldcxt;
 
    /*
     * For one-shot plans, we do not support revalidation checking; it's
     * assumed the query is parsed, planned, and executed in one transaction,
     * so that no lock re-acquisition is necessary.  Also, if the statement
     * type can't require revalidation, we needn't do anything (and we mustn't
     * risk catalog accesses when handling, eg, transaction control commands).
     */
    if (plansource->is_oneshot || !StmtPlanRequiresRevalidation(plansource))
    {
        Assert(plansource->is_valid);
        return NIL;
    }
 
    /*
     * If the query is currently valid, we should have a saved search_path ---
     * check to see if that matches the current environment.  If not, we want
     * to force replan.  (We could almost ignore this consideration when
     * working from an analyzed parse tree; but there are scenarios where
     * planning can have search_path-dependent results, for example if it
     * inlines an old-style SQL function.)
     */
    if (plansource->is_valid)
    {
        Assert(plansource->search_path != NULL);
        if (!SearchPathMatchesCurrentEnvironment(plansource->search_path))
        {
            /* Invalidate the querytree and generic plan */
            plansource->is_valid = false;
            if (plansource->gplan)
                plansource->gplan->is_valid = false;
        }
    }
 
    /*
     * If the query rewrite phase had a possible RLS dependency, we must redo
     * it if either the role or the row_security setting has changed.
     */
    if (plansource->is_valid && plansource->dependsOnRLS &&
        (plansource->rewriteRoleId != GetUserId() ||
         plansource->rewriteRowSecurity != row_security))
        plansource->is_valid = false;
 
    /*
     * If the query is currently valid, acquire locks on the referenced
     * objects; then check again.  We need to do it this way to cover the race
     * condition that an invalidation message arrives before we get the locks.
     */
    if (plansource->is_valid)
    {
        AcquirePlannerLocks(plansource->query_list, true);
 
        /*
         * By now, if any invalidation has happened, the inval callback
         * functions will have marked the query invalid.
         */
        if (plansource->is_valid)
        {
            /* Successfully revalidated and locked the query. */
            return NIL;
        }
 
        /* Oops, the race case happened.  Release useless locks. */
        AcquirePlannerLocks(plansource->query_list, false);
    }
 
    /*
     * Discard the no-longer-useful rewritten query tree.  (Note: we don't
     * want to do this any earlier, else we'd not have been able to release
     * locks correctly in the race condition case.)
     */
    plansource->is_valid = false;
    plansource->query_list = NIL;
    plansource->relationOids = NIL;
    plansource->invalItems = NIL;
    plansource->search_path = NULL;
 
    /*
     * Free the query_context.  We don't really expect MemoryContextDelete to
     * fail, but just in case, make sure the CachedPlanSource is left in a
     * reasonably sane state.  (The generic plan won't get unlinked yet, but
     * that's acceptable.)
     */
    if (plansource->query_context)
    {
        MemoryContext qcxt = plansource->query_context;
 
        plansource->query_context = NULL;
        MemoryContextDelete(qcxt);
    }
 
    /* Drop the generic plan reference if any */
    ReleaseGenericPlan(plansource);
 
    /*
     * Now re-do parse analysis and rewrite.  This not incidentally acquires
     * the locks we need to do planning safely.
     */
    Assert(plansource->is_complete);
 
    /*
     * If a snapshot is already set (the normal case), we can just use that
     * for parsing/planning.  But if it isn't, install one.  Note: no point in
     * checking whether parse analysis requires a snapshot; utility commands
     * don't have invalidatable plans, so we'd not get here for such a
     * command.
     */
    snapshot_set = false;
    if (!ActiveSnapshotSet())
    {
        PushActiveSnapshot(GetTransactionSnapshot());
        snapshot_set = true;
    }
 
    /*
     * Run parse analysis (if needed) and rule rewriting.
     */
    if (plansource->raw_parse_tree != NULL)
    {
        /* Source is raw parse tree */
        RawStmt    *rawtree;
 
        /*
         * The parser tends to scribble on its input, so we must copy the raw
         * parse tree to prevent corruption of the cache.
         */
        rawtree = copyObject(plansource->raw_parse_tree);
        if (plansource->parserSetup != NULL)
            tlist = pg_analyze_and_rewrite_withcb(rawtree,
                                                  plansource->query_string,
                                                  plansource->parserSetup,
                                                  plansource->parserSetupArg,
                                                  queryEnv);
        else
            tlist = pg_analyze_and_rewrite_fixedparams(rawtree,
                                                       plansource->query_string,
                                                       plansource->param_types,
                                                       plansource->num_params,
                                                       queryEnv);
    }
    else if (plansource->analyzed_parse_tree != NULL)
    {
        /* Source is pre-analyzed query, so we only need to rewrite */
        Query      *analyzed_tree;
 
        /* The rewriter scribbles on its input, too, so copy */
        analyzed_tree = copyObject(plansource->analyzed_parse_tree);
        /* Acquire locks needed before rewriting ... */
        AcquireRewriteLocks(analyzed_tree, true, false);
        /* ... and do it */
        tlist = pg_rewrite_query(analyzed_tree);
    }
    else
    {
        /* Empty query, nothing to do */
        tlist = NIL;
    }
 
    /* Apply post-rewrite callback if there is one */
    if (plansource->postRewrite != NULL)
        plansource->postRewrite(tlist, plansource->postRewriteArg);
 
    /* Release snapshot if we got one */
    if (snapshot_set)
        PopActiveSnapshot();
 
    /*
     * Check or update the result tupdesc.
     *
     * We assume the parameter types didn't change from the first time, so no
     * need to update that.
     */
    resultDesc = PlanCacheComputeResultDesc(tlist);
    if (resultDesc == NULL && plansource->resultDesc == NULL)
    {
        /* OK, doesn't return tuples */
    }
    else if (resultDesc == NULL || plansource->resultDesc == NULL ||
             !equalRowTypes(resultDesc, plansource->resultDesc))
    {
        /* can we give a better error message? */
        if (plansource->fixed_result)
            ereport(ERROR,
                    (errcode(ERRCODE_FEATURE_NOT_SUPPORTED),
                     errmsg("cached plan must not change result type")));
        oldcxt = MemoryContextSwitchTo(plansource->context);
        if (resultDesc)
            resultDesc = CreateTupleDescCopy(resultDesc);
        if (plansource->resultDesc)
            FreeTupleDesc(plansource->resultDesc);
        plansource->resultDesc = resultDesc;
        MemoryContextSwitchTo(oldcxt);
    }
 
    /*
     * Allocate new query_context and copy the completed querytree into it.
     * It's transient until we complete the copying and dependency extraction.
     */
    querytree_context = AllocSetContextCreate(CurrentMemoryContext,
                                              "CachedPlanQuery",
                                              ALLOCSET_START_SMALL_SIZES);
    oldcxt = MemoryContextSwitchTo(querytree_context);
 
    qlist = copyObject(tlist);
 
    /*
     * Use the planner machinery to extract dependencies.  Data is saved in
     * query_context.  (We assume that not a lot of extra cruft is created by
     * this call.)
     */
    extract_query_dependencies((Node *) qlist,
                               &plansource->relationOids,
                               &plansource->invalItems,
                               &plansource->dependsOnRLS);
 
    /* Update RLS info as well. */
    plansource->rewriteRoleId = GetUserId();
    plansource->rewriteRowSecurity = row_security;
 
    /*
     * Also save the current search_path in the query_context.  (This should
     * not generate much extra cruft either, since almost certainly the path
     * is already valid.)
     */
    plansource->search_path = GetSearchPathMatcher(querytree_context);
 
    MemoryContextSwitchTo(oldcxt);
 
    /* Now reparent the finished query_context and save the links */
    MemoryContextSetParent(querytree_context, plansource->context);
 
    plansource->query_context = querytree_context;
    plansource->query_list = qlist;
 
    /*
     * Note: we do not reset generic_cost or total_custom_cost, although we
     * could choose to do so.  If the DDL or statistics change that prompted
     * the invalidation meant a significant change in the cost estimates, it
     * would be better to reset those variables and start fresh; but often it
     * doesn't, and we're better retaining our hard-won knowledge about the
     * relative costs.
     */
 
    plansource->is_valid = true;
 
    /* Return transient copy of querytrees for possible use in planning */
    return tlist;
}
 
/*
 * CheckCachedPlan: see if the CachedPlanSource's generic plan is valid.
 *
 * Caller must have already called RevalidateCachedQuery to verify that the
 * querytree is up to date.
 *
 * On a "true" return, we have acquired the locks needed to run the plan.
 * (We must do this for the "true" result to be race-condition-free.)
 */
static bool
CheckCachedPlan(CachedPlanSource *plansource)
{
    CachedPlan *plan = plansource->gplan;
 
    /* Assert that caller checked the querytree */
    Assert(plansource->is_valid);
 
    /* If there's no generic plan, just say "false" */
    if (!plan)
        return false;
 
    Assert(plan->magic == CACHEDPLAN_MAGIC);
    /* Generic plans are never one-shot */
    Assert(!plan->is_oneshot);
 
    /*
     * If plan isn't valid for current role, we can't use it.
     */
    if (plan->is_valid && plan->dependsOnRole &&
        plan->planRoleId != GetUserId())
        plan->is_valid = false;
 
    /*
     * If it appears valid, acquire locks and recheck; this is much the same
     * logic as in RevalidateCachedQuery, but for a plan.
     */
    if (plan->is_valid)
    {
        /*
         * Plan must have positive refcount because it is referenced by
         * plansource; so no need to fear it disappears under us here.
         */
        Assert(plan->refcount > 0);
 
        AcquireExecutorLocks(plan->stmt_list, true);
 
        /*
         * If plan was transient, check to see if TransactionXmin has
         * advanced, and if so invalidate it.
         */
        if (plan->is_valid &&
            TransactionIdIsValid(plan->saved_xmin) &&
            !TransactionIdEquals(plan->saved_xmin, TransactionXmin))
            plan->is_valid = false;
 
        /*
         * By now, if any invalidation has happened, the inval callback
         * functions will have marked the plan invalid.
         */
        if (plan->is_valid)
        {
            /* Successfully revalidated and locked the query. */
            return true;
        }
 
        /* Oops, the race case happened.  Release useless locks. */
        AcquireExecutorLocks(plan->stmt_list, false);
    }
 
    /*
     * Plan has been invalidated, so unlink it from the parent and release it.
     */
    ReleaseGenericPlan(plansource);
 
    return false;
}
 
/*
 * BuildCachedPlan: construct a new CachedPlan from a CachedPlanSource.
 *
 * qlist should be the result value from a previous RevalidateCachedQuery,
 * or it can be set to NIL if we need to re-copy the plansource's query_list.
 *
 * To build a generic, parameter-value-independent plan, pass NULL for
 * boundParams.  To build a custom plan, pass the actual parameter values via
 * boundParams.  For best effect, the PARAM_FLAG_CONST flag should be set on
 * each parameter value; otherwise the planner will treat the value as a
 * hint rather than a hard constant.
 *
 * Planning work is done in the caller's memory context.  The finished plan
 * is in a child memory context, which typically should get reparented
 * (unless this is a one-shot plan, in which case we don't copy the plan).
 */
static CachedPlan *
BuildCachedPlan(CachedPlanSource *plansource, List *qlist,
                ParamListInfo boundParams, QueryEnvironment *queryEnv)
{
    CachedPlan *plan;
    List       *plist;
    bool        snapshot_set;
    bool        is_transient;
    MemoryContext plan_context;
    MemoryContext oldcxt = CurrentMemoryContext;
    ListCell   *lc;
 
    /*
     * Normally the querytree should be valid already, but if it's not,
     * rebuild it.
     *
     * NOTE: GetCachedPlan should have called RevalidateCachedQuery first, so
     * we ought to be holding sufficient locks to prevent any invalidation.
     * However, if we're building a custom plan after having built and
     * rejected a generic plan, it's possible to reach here with is_valid
     * false due to an invalidation while making the generic plan.  In theory
     * the invalidation must be a false positive, perhaps a consequence of an
     * sinval reset event or the debug_discard_caches code.  But for safety,
     * let's treat it as real and redo the RevalidateCachedQuery call.
     */
    if (!plansource->is_valid)
        qlist = RevalidateCachedQuery(plansource, queryEnv);
 
    /*
     * If we don't already have a copy of the querytree list that can be
     * scribbled on by the planner, make one.  For a one-shot plan, we assume
     * it's okay to scribble on the original query_list.
     */
    if (qlist == NIL)
    {
        if (!plansource->is_oneshot)
            qlist = copyObject(plansource->query_list);
        else
            qlist = plansource->query_list;
    }
 
    /*
     * If a snapshot is already set (the normal case), we can just use that
     * for planning.  But if it isn't, and we need one, install one.
     */
    snapshot_set = false;
    if (!ActiveSnapshotSet() &&
        BuildingPlanRequiresSnapshot(plansource))
    {
        PushActiveSnapshot(GetTransactionSnapshot());
        snapshot_set = true;
    }
 
    /*
     * Generate the plan.
     */
    plist = pg_plan_queries(qlist, plansource->query_string,
                            plansource->cursor_options, boundParams);
 
    /* Release snapshot if we got one */
    if (snapshot_set)
        PopActiveSnapshot();
 
    /*
     * Normally we make a dedicated memory context for the CachedPlan and its
     * subsidiary data.  (It's probably not going to be large, but just in
     * case, allow it to grow large.  It's transient for the moment.)  But for
     * a one-shot plan, we just leave it in the caller's memory context.
     */
    if (!plansource->is_oneshot)
    {
        plan_context = AllocSetContextCreate(CurrentMemoryContext,
                                             "CachedPlan",
                                             ALLOCSET_START_SMALL_SIZES);
        MemoryContextCopyAndSetIdentifier(plan_context, plansource->query_string);
 
        /*
         * Copy plan into the new context.
         */
        MemoryContextSwitchTo(plan_context);
 
        plist = copyObject(plist);
    }
    else
        plan_context = CurrentMemoryContext;
 
    /*
     * Create and fill the CachedPlan struct within the new context.
     */
    plan = palloc_object(CachedPlan);
    plan->magic = CACHEDPLAN_MAGIC;
    plan->stmt_list = plist;
 
    /*
     * CachedPlan is dependent on role either if RLS affected the rewrite
     * phase or if a role dependency was injected during planning.  And it's
     * transient if any plan is marked so.
     */
    plan->planRoleId = GetUserId();
    plan->dependsOnRole = plansource->dependsOnRLS;
    is_transient = false;
    foreach(lc, plist)
    {
        PlannedStmt *plannedstmt = lfirst_node(PlannedStmt, lc);
 
        if (plannedstmt->commandType == CMD_UTILITY)
            continue;           /* Ignore utility statements */
 
        if (plannedstmt->transientPlan)
            is_transient = true;
        if (plannedstmt->dependsOnRole)
            plan->dependsOnRole = true;
    }
    if (is_transient)
    {
        Assert(TransactionIdIsNormal(TransactionXmin));
        plan->saved_xmin = TransactionXmin;
    }
    else
        plan->saved_xmin = InvalidTransactionId;
    plan->refcount = 0;
    plan->context = plan_context;
    plan->is_oneshot = plansource->is_oneshot;
    plan->is_saved = false;
    plan->is_valid = true;
 
    /* assign generation number to new plan */
    plan->generation = ++(plansource->generation);
 
    MemoryContextSwitchTo(oldcxt);
 
    return plan;
}
 
/*
 * choose_custom_plan: choose whether to use custom or generic plan
 *
 * This defines the policy followed by GetCachedPlan.
 */
static bool
choose_custom_plan(CachedPlanSource *plansource, ParamListInfo boundParams)
{
    double      avg_custom_cost;
 
    /* One-shot plans will always be considered custom */
    if (plansource->is_oneshot)
        return true;
 
    /* Otherwise, never any point in a custom plan if there's no parameters */
    if (boundParams == NULL)
        return false;
    /* ... nor when planning would be a no-op */
    if (!StmtPlanRequiresRevalidation(plansource))
        return false;
 
    /* Let settings force the decision */
    if (plan_cache_mode == PLAN_CACHE_MODE_FORCE_GENERIC_PLAN)
        return false;
    if (plan_cache_mode == PLAN_CACHE_MODE_FORCE_CUSTOM_PLAN)
        return true;
 
    /* See if caller wants to force the decision */
    if (plansource->cursor_options & CURSOR_OPT_GENERIC_PLAN)
        return false;
    if (plansource->cursor_options & CURSOR_OPT_CUSTOM_PLAN)
        return true;
 
    /* Generate custom plans until we have done at least 5 (arbitrary) */
    if (plansource->num_custom_plans < 5)
        return true;
 
    avg_custom_cost = plansource->total_custom_cost / plansource->num_custom_plans;
 
    /*
     * Prefer generic plan if it's less expensive than the average custom
     * plan.  (Because we include a charge for cost of planning in the
     * custom-plan costs, this means the generic plan only has to be less
     * expensive than the execution cost plus replan cost of the custom
     * plans.)
     *
     * Note that if generic_cost is -1 (indicating we've not yet determined
     * the generic plan cost), we'll always prefer generic at this point.
     */
    if (plansource->generic_cost < avg_custom_cost)
        return false;
 
    return true;
}
 
/*
 * cached_plan_cost: calculate estimated cost of a plan
 *
 * If include_planner is true, also include the estimated cost of constructing
 * the plan.  (We must factor that into the cost of using a custom plan, but
 * we don't count it for a generic plan.)
 */
static double
cached_plan_cost(CachedPlan *plan, bool include_planner)
{
    double      result = 0;
    ListCell   *lc;
 
    foreach(lc, plan->stmt_list)
    {
        PlannedStmt *plannedstmt = lfirst_node(PlannedStmt, lc);
 
        if (plannedstmt->commandType == CMD_UTILITY)
            continue;           /* Ignore utility statements */
 
        result += plannedstmt->planTree->total_cost;
 
        if (include_planner)
        {
            /*
             * Currently we use a very crude estimate of planning effort based
             * on the number of relations in the finished plan's rangetable.
             * Join planning effort actually scales much worse than linearly
             * in the number of relations --- but only until the join collapse
             * limits kick in.  Also, while inheritance child relations surely
             * add to planning effort, they don't make the join situation
             * worse.  So the actual shape of the planning cost curve versus
             * number of relations isn't all that obvious.  It will take
             * considerable work to arrive at a less crude estimate, and for
             * now it's not clear that's worth doing.
             *
             * The other big difficulty here is that we don't have any very
             * good model of how planning cost compares to execution costs.
             * The current multiplier of 1000 * cpu_operator_cost is probably
             * on the low side, but we'll try this for awhile before making a
             * more aggressive correction.
             *
             * If we ever do write a more complicated estimator, it should
             * probably live in src/backend/optimizer/ not here.
             */
            int         nrelations = list_length(plannedstmt->rtable);
 
            result += 1000.0 * cpu_operator_cost * (nrelations + 1);
        }
    }
 
    return result;
}
 
/*
 * GetCachedPlan: get a cached plan from a CachedPlanSource.
 *
 * This function hides the logic that decides whether to use a generic
 * plan or a custom plan for the given parameters: the caller does not know
 * which it will get.
 *
 * On return, the plan is valid and we have sufficient locks to begin
 * execution.
 *
 * On return, the refcount of the plan has been incremented; a later
 * ReleaseCachedPlan() call is expected.  If "owner" is not NULL then
 * the refcount has been reported to that ResourceOwner (note that this
 * is only supported for "saved" CachedPlanSources).
 *
 * Note: if any replanning activity is required, the caller's memory context
 * is used for that work.
 */
CachedPlan *
GetCachedPlan(CachedPlanSource *plansource, ParamListInfo boundParams,
              ResourceOwner owner, QueryEnvironment *queryEnv)
{
    CachedPlan *plan = NULL;
    List       *qlist;
    bool        customplan;
    ListCell   *lc;
 
    /* Assert caller is doing things in a sane order */
    Assert(plansource->magic == CACHEDPLANSOURCE_MAGIC);
    Assert(plansource->is_complete);
    /* This seems worth a real test, though */
    if (owner && !plansource->is_saved)
        elog(ERROR, "cannot apply ResourceOwner to non-saved cached plan");
 
    /* Make sure the querytree list is valid and we have parse-time locks */
    qlist = RevalidateCachedQuery(plansource, queryEnv);
 
    /* Decide whether to use a custom plan */
    customplan = choose_custom_plan(plansource, boundParams);
 
    if (!customplan)
    {
        if (CheckCachedPlan(plansource))
        {
            /* We want a generic plan, and we already have a valid one */
            plan = plansource->gplan;
            Assert(plan->magic == CACHEDPLAN_MAGIC);
        }
        else
        {
            /* Build a new generic plan */
            plan = BuildCachedPlan(plansource, qlist, NULL, queryEnv);
            /* Just make real sure plansource->gplan is clear */
            ReleaseGenericPlan(plansource);
            /* Link the new generic plan into the plansource */
            plansource->gplan = plan;
            plan->refcount++;
            /* Immediately reparent into appropriate context */
            if (plansource->is_saved)
            {
                /* saved plans all live under CacheMemoryContext */
                MemoryContextSetParent(plan->context, CacheMemoryContext);
                plan->is_saved = true;
            }
            else
            {
                /* otherwise, it should be a sibling of the plansource */
                MemoryContextSetParent(plan->context,
                                       MemoryContextGetParent(plansource->context));
            }
            /* Update generic_cost whenever we make a new generic plan */
            plansource->generic_cost = cached_plan_cost(plan, false);
 
            /*
             * If, based on the now-known value of generic_cost, we'd not have
             * chosen to use a generic plan, then forget it and make a custom
             * plan.  This is a bit of a wart but is necessary to avoid a
             * glitch in behavior when the custom plans are consistently big
             * winners; at some point we'll experiment with a generic plan and
             * find it's a loser, but we don't want to actually execute that
             * plan.
             */
            customplan = choose_custom_plan(plansource, boundParams);
 
            /*
             * If we choose to plan again, we need to re-copy the query_list,
             * since the planner probably scribbled on it.  We can force
             * BuildCachedPlan to do that by passing NIL.
             */
            qlist = NIL;
        }
    }
 
    if (customplan)
    {
        /* Build a custom plan */
        plan = BuildCachedPlan(plansource, qlist, boundParams, queryEnv);
        /* Accumulate total costs of custom plans */
        plansource->total_custom_cost += cached_plan_cost(plan, true);
 
        plansource->num_custom_plans++;
    }
    else
    {
        plansource->num_generic_plans++;
    }
 
    Assert(plan != NULL);
 
    /* Flag the plan as in use by caller */
    if (owner)
        ResourceOwnerEnlarge(owner);
    plan->refcount++;
    if (owner)
        ResourceOwnerRememberPlanCacheRef(owner, plan);
 
    /*
     * Saved plans should be under CacheMemoryContext so they will not go away
     * until their reference count goes to zero.  In the generic-plan cases we
     * already took care of that, but for a custom plan, do it as soon as we
     * have created a reference-counted link.
     */
    if (customplan && plansource->is_saved)
    {
        MemoryContextSetParent(plan->context, CacheMemoryContext);
        plan->is_saved = true;
    }
 
    foreach(lc, plan->stmt_list)
    {
        PlannedStmt *pstmt = (PlannedStmt *) lfirst(lc);
 
        pstmt->planOrigin = customplan ? PLAN_STMT_CACHE_CUSTOM : PLAN_STMT_CACHE_GENERIC;
    }
 
    return plan;
}
 
/*
 * ReleaseCachedPlan: release active use of a cached plan.
 *
 * This decrements the reference count, and frees the plan if the count
 * has thereby gone to zero.  If "owner" is not NULL, it is assumed that
 * the reference count is managed by that ResourceOwner.
 *
 * Note: owner == NULL is used for releasing references that are in
 * persistent data structures, such as the parent CachedPlanSource or a
 * Portal.  Transient references should be protected by a resource owner.
 */
void
ReleaseCachedPlan(CachedPlan *plan, ResourceOwner owner)
{
    Assert(plan->magic == CACHEDPLAN_MAGIC);
    if (owner)
    {
        Assert(plan->is_saved);
        ResourceOwnerForgetPlanCacheRef(owner, plan);
    }
    Assert(plan->refcount > 0);
    plan->refcount--;
    if (plan->refcount == 0)
    {
        /* Mark it no longer valid */
        plan->magic = 0;
 
        /* One-shot plans do not own their context, so we can't free them */
        if (!plan->is_oneshot)
            MemoryContextDelete(plan->context);
    }
}
 
/*
 * CachedPlanAllowsSimpleValidityCheck: can we use CachedPlanIsSimplyValid?
 *
 * This function, together with CachedPlanIsSimplyValid, provides a fast path
 * for revalidating "simple" generic plans.  The core requirement to be simple
 * is that the plan must not require taking any locks, which translates to
 * not touching any tables; this happens to match up well with an important
 * use-case in PL/pgSQL.  This function tests whether that's true, along
 * with checking some other corner cases that we'd rather not bother with
 * handling in the fast path.  (Note that it's still possible for such a plan
 * to be invalidated, for example due to a change in a function that was
 * inlined into the plan.)
 *
 * If the plan is simply valid, and "owner" is not NULL, record a refcount on
 * the plan in that resowner before returning.  It is caller's responsibility
 * to be sure that a refcount is held on any plan that's being actively used.
 *
 * This must only be called on known-valid generic plans (eg, ones just
 * returned by GetCachedPlan).  If it returns true, the caller may re-use
 * the cached plan as long as CachedPlanIsSimplyValid returns true; that
 * check is much cheaper than the full revalidation done by GetCachedPlan.
 * Nonetheless, no required checks are omitted.
 */
bool
CachedPlanAllowsSimpleValidityCheck(CachedPlanSource *plansource,
                                    CachedPlan *plan, ResourceOwner owner)
{
    ListCell   *lc;
 
    /*
     * Sanity-check that the caller gave us a validated generic plan.  Notice
     * that we *don't* assert plansource->is_valid as you might expect; that's
     * because it's possible that that's already false when GetCachedPlan
     * returns, e.g. because ResetPlanCache happened partway through.  We
     * should accept the plan as long as plan->is_valid is true, and expect to
     * replan after the next CachedPlanIsSimplyValid call.
     */
    Assert(plansource->magic == CACHEDPLANSOURCE_MAGIC);
    Assert(plan->magic == CACHEDPLAN_MAGIC);
    Assert(plan->is_valid);
    Assert(plan == plansource->gplan);
    Assert(plansource->search_path != NULL);
    Assert(SearchPathMatchesCurrentEnvironment(plansource->search_path));
 
    /* We don't support oneshot plans here. */
    if (plansource->is_oneshot)
        return false;
    Assert(!plan->is_oneshot);
 
    /*
     * If the plan is dependent on RLS considerations, or it's transient,
     * reject.  These things probably can't ever happen for table-free
     * queries, but for safety's sake let's check.
     */
    if (plansource->dependsOnRLS)
        return false;
    if (plan->dependsOnRole)
        return false;
    if (TransactionIdIsValid(plan->saved_xmin))
        return false;
 
    /*
     * Reject if AcquirePlannerLocks would have anything to do.  This is
     * simplistic, but there's no need to inquire any more carefully; indeed,
     * for current callers it shouldn't even be possible to hit any of these
     * checks.
     */
    foreach(lc, plansource->query_list)
    {
        Query      *query = lfirst_node(Query, lc);
 
        if (query->commandType == CMD_UTILITY)
            return false;
        if (query->rtable || query->cteList || query->hasSubLinks)
            return false;
    }
 
    /*
     * Reject if AcquireExecutorLocks would have anything to do.  This is
     * probably unnecessary given the previous check, but let's be safe.
     */
    foreach(lc, plan->stmt_list)
    {
        PlannedStmt *plannedstmt = lfirst_node(PlannedStmt, lc);
        ListCell   *lc2;
 
        if (plannedstmt->commandType == CMD_UTILITY)
            return false;
 
        /*
         * We have to grovel through the rtable because it's likely to contain
         * an RTE_RESULT relation, rather than being totally empty.
         */
        foreach(lc2, plannedstmt->rtable)
        {
            RangeTblEntry *rte = (RangeTblEntry *) lfirst(lc2);
 
            if (rte->rtekind == RTE_RELATION)
                return false;
        }
    }
 
    /*
     * Okay, it's simple.  Note that what we've primarily established here is
     * that no locks need be taken before checking the plan's is_valid flag.
     */
 
    /* Bump refcount if requested. */
    if (owner)
    {
        ResourceOwnerEnlarge(owner);
        plan->refcount++;
        ResourceOwnerRememberPlanCacheRef(owner, plan);
    }
 
    return true;
}
 
/*
 * CachedPlanIsSimplyValid: quick check for plan still being valid
 *
 * This function must not be used unless CachedPlanAllowsSimpleValidityCheck
 * previously said it was OK.
 *
 * If the plan is valid, and "owner" is not NULL, record a refcount on
 * the plan in that resowner before returning.  It is caller's responsibility
 * to be sure that a refcount is held on any plan that's being actively used.
 *
 * The code here is unconditionally safe as long as the only use of this
 * CachedPlanSource is in connection with the particular CachedPlan pointer
 * that's passed in.  If the plansource were being used for other purposes,
 * it's possible that its generic plan could be invalidated and regenerated
 * while the current caller wasn't looking, and then there could be a chance
 * collision of address between this caller's now-stale plan pointer and the
 * actual address of the new generic plan.  For current uses, that scenario
 * can't happen; but with a plansource shared across multiple uses, it'd be
 * advisable to also save plan->generation and verify that that still matches.
 */
bool
CachedPlanIsSimplyValid(CachedPlanSource *plansource, CachedPlan *plan,
                        ResourceOwner owner)
{
    /*
     * Careful here: since the caller doesn't necessarily hold a refcount on
     * the plan to start with, it's possible that "plan" is a dangling
     * pointer.  Don't dereference it until we've verified that it still
     * matches the plansource's gplan (which is either valid or NULL).
     */
    Assert(plansource->magic == CACHEDPLANSOURCE_MAGIC);
 
    /*
     * Has cache invalidation fired on this plan?  We can check this right
     * away since there are no locks that we'd need to acquire first.  Note
     * that here we *do* check plansource->is_valid, so as to force plan
     * rebuild if that's become false.
     */
    if (!plansource->is_valid ||
        plan == NULL || plan != plansource->gplan ||
        !plan->is_valid)
        return false;
 
    Assert(plan->magic == CACHEDPLAN_MAGIC);
 
    /* Is the search_path still the same as when we made it? */
    Assert(plansource->search_path != NULL);
    if (!SearchPathMatchesCurrentEnvironment(plansource->search_path))
        return false;
 
    /* It's still good.  Bump refcount if requested. */
    if (owner)
    {
        ResourceOwnerEnlarge(owner);
        plan->refcount++;
        ResourceOwnerRememberPlanCacheRef(owner, plan);
    }
 
    return true;
}
 
/*
 * CachedPlanSetParentContext: move a CachedPlanSource to a new memory context
 *
 * This can only be applied to unsaved plans; once saved, a plan always
 * lives underneath CacheMemoryContext.
 */
void
CachedPlanSetParentContext(CachedPlanSource *plansource,
                           MemoryContext newcontext)
{
    /* Assert caller is doing things in a sane order */
    Assert(plansource->magic == CACHEDPLANSOURCE_MAGIC);
    Assert(plansource->is_complete);
 
    /* These seem worth real tests, though */
    if (plansource->is_saved)
        elog(ERROR, "cannot move a saved cached plan to another context");
    if (plansource->is_oneshot)
        elog(ERROR, "cannot move a one-shot cached plan to another context");
 
    /* OK, let the caller keep the plan where he wishes */
    MemoryContextSetParent(plansource->context, newcontext);
 
    /*
     * The query_context needs no special handling, since it's a child of
     * plansource->context.  But if there's a generic plan, it should be
     * maintained as a sibling of plansource->context.
     */
    if (plansource->gplan)
    {
        Assert(plansource->gplan->magic == CACHEDPLAN_MAGIC);
        MemoryContextSetParent(plansource->gplan->context, newcontext);
    }
}
 
/*
 * CopyCachedPlan: make a copy of a CachedPlanSource
 *
 * This is a convenience routine that does the equivalent of
 * CreateCachedPlan + CompleteCachedPlan, using the data stored in the
 * input CachedPlanSource.  The result is therefore "unsaved" (regardless
 * of the state of the source), and we don't copy any generic plan either.
 * The result will be currently valid, or not, the same as the source.
 */
CachedPlanSource *
CopyCachedPlan(CachedPlanSource *plansource)
{
    CachedPlanSource *newsource;
    MemoryContext source_context;
    MemoryContext querytree_context;
    MemoryContext oldcxt;
 
    Assert(plansource->magic == CACHEDPLANSOURCE_MAGIC);
    Assert(plansource->is_complete);
 
    /*
     * One-shot plans can't be copied, because we haven't taken care that
     * parsing/planning didn't scribble on the raw parse tree or querytrees.
     */
    if (plansource->is_oneshot)
        elog(ERROR, "cannot copy a one-shot cached plan");
 
    source_context = AllocSetContextCreate(CurrentMemoryContext,
                                           "CachedPlanSource",
                                           ALLOCSET_START_SMALL_SIZES);
 
    oldcxt = MemoryContextSwitchTo(source_context);
 
    newsource = palloc0_object(CachedPlanSource);
    newsource->magic = CACHEDPLANSOURCE_MAGIC;
    newsource->raw_parse_tree = copyObject(plansource->raw_parse_tree);
    newsource->analyzed_parse_tree = copyObject(plansource->analyzed_parse_tree);
    newsource->query_string = pstrdup(plansource->query_string);
    MemoryContextSetIdentifier(source_context, newsource->query_string);
    newsource->commandTag = plansource->commandTag;
    if (plansource->num_params > 0)
    {
        newsource->param_types = palloc_array(Oid, plansource->num_params);
        memcpy(newsource->param_types, plansource->param_types,
               plansource->num_params * sizeof(Oid));
    }
    else
        newsource->param_types = NULL;
    newsource->num_params = plansource->num_params;
    newsource->parserSetup = plansource->parserSetup;
    newsource->parserSetupArg = plansource->parserSetupArg;
    newsource->postRewrite = plansource->postRewrite;
    newsource->postRewriteArg = plansource->postRewriteArg;
    newsource->cursor_options = plansource->cursor_options;
    newsource->fixed_result = plansource->fixed_result;
    if (plansource->resultDesc)
        newsource->resultDesc = CreateTupleDescCopy(plansource->resultDesc);
    else
        newsource->resultDesc = NULL;
    newsource->context = source_context;
 
    querytree_context = AllocSetContextCreate(source_context,
                                              "CachedPlanQuery",
                                              ALLOCSET_START_SMALL_SIZES);
    MemoryContextSwitchTo(querytree_context);
    newsource->query_list = copyObject(plansource->query_list);
    newsource->relationOids = copyObject(plansource->relationOids);
    newsource->invalItems = copyObject(plansource->invalItems);
    if (plansource->search_path)
        newsource->search_path = CopySearchPathMatcher(plansource->search_path);
    newsource->query_context = querytree_context;
    newsource->rewriteRoleId = plansource->rewriteRoleId;
    newsource->rewriteRowSecurity = plansource->rewriteRowSecurity;
    newsource->dependsOnRLS = plansource->dependsOnRLS;
 
    newsource->gplan = NULL;
 
    newsource->is_oneshot = false;
    newsource->is_complete = true;
    newsource->is_saved = false;
    newsource->is_valid = plansource->is_valid;
    newsource->generation = plansource->generation;
 
    /* We may as well copy any acquired cost knowledge */
    newsource->generic_cost = plansource->generic_cost;
    newsource->total_custom_cost = plansource->total_custom_cost;
    newsource->num_generic_plans = plansource->num_generic_plans;
    newsource->num_custom_plans = plansource->num_custom_plans;
 
    MemoryContextSwitchTo(oldcxt);
 
    return newsource;
}
 
/*
 * CachedPlanIsValid: test whether the rewritten querytree within a
 * CachedPlanSource is currently valid (that is, not marked as being in need
 * of revalidation).
 *
 * This result is only trustworthy (ie, free from race conditions) if
 * the caller has acquired locks on all the relations used in the plan.
 */
bool
CachedPlanIsValid(CachedPlanSource *plansource)
{
    Assert(plansource->magic == CACHEDPLANSOURCE_MAGIC);
    return plansource->is_valid;
}
 
/*
 * CachedPlanGetTargetList: return tlist, if any, describing plan's output
 *
 * The result is guaranteed up-to-date.  However, it is local storage
 * within the cached plan, and may disappear next time the plan is updated.
 */
List *
CachedPlanGetTargetList(CachedPlanSource *plansource,
                        QueryEnvironment *queryEnv)
{
    Query      *pstmt;
 
    /* Assert caller is doing things in a sane order */
    Assert(plansource->magic == CACHEDPLANSOURCE_MAGIC);
    Assert(plansource->is_complete);
 
    /*
     * No work needed if statement doesn't return tuples (we assume this
     * feature cannot be changed by an invalidation)
     */
    if (plansource->resultDesc == NULL)
        return NIL;
 
    /* Make sure the querytree list is valid and we have parse-time locks */
    RevalidateCachedQuery(plansource, queryEnv);
 
    /* Get the primary statement and find out what it returns */
    pstmt = QueryListGetPrimaryStmt(plansource->query_list);
 
    return FetchStatementTargetList((Node *) pstmt);
}
 
/*
 * GetCachedExpression: construct a CachedExpression for an expression.
 *
 * This performs the same transformations on the expression as
 * expression_planner(), ie, convert an expression as emitted by parse
 * analysis to be ready to pass to the executor.
 *
 * The result is stashed in a private, long-lived memory context.
 * (Note that this might leak a good deal of memory in the caller's
 * context before that.)  The passed-in expr tree is not modified.
 */
CachedExpression *
GetCachedExpression(Node *expr)
{
    CachedExpression *cexpr;
    List       *relationOids;
    List       *invalItems;
    MemoryContext cexpr_context;
    MemoryContext oldcxt;
 
    /*
     * Pass the expression through the planner, and collect dependencies.
     * Everything built here is leaked in the caller's context; that's
     * intentional to minimize the size of the permanent data structure.
     */
    expr = (Node *) expression_planner_with_deps((Expr *) expr,
                                                 &relationOids,
                                                 &invalItems);
 
    /*
     * Make a private memory context, and copy what we need into that.  To
     * avoid leaking a long-lived context if we fail while copying data, we
     * initially make the context under the caller's context.
     */
    cexpr_context = AllocSetContextCreate(CurrentMemoryContext,
                                          "CachedExpression",
                                          ALLOCSET_SMALL_SIZES);
 
    oldcxt = MemoryContextSwitchTo(cexpr_context);
 
    cexpr = palloc_object(CachedExpression);
    cexpr->magic = CACHEDEXPR_MAGIC;
    cexpr->expr = copyObject(expr);
    cexpr->is_valid = true;
    cexpr->relationOids = copyObject(relationOids);
    cexpr->invalItems = copyObject(invalItems);
    cexpr->context = cexpr_context;
 
    MemoryContextSwitchTo(oldcxt);
 
    /*
     * Reparent the expr's memory context under CacheMemoryContext so that it
     * will live indefinitely.
     */
    MemoryContextSetParent(cexpr_context, CacheMemoryContext);
 
    /*
     * Add the entry to the global list of cached expressions.
     */
    dlist_push_tail(&cached_expression_list, &cexpr->node);
 
    return cexpr;
}
 
/*
 * FreeCachedExpression
 *      Delete a CachedExpression.
 */
void
FreeCachedExpression(CachedExpression *cexpr)
{
    /* Sanity check */
    Assert(cexpr->magic == CACHEDEXPR_MAGIC);
    /* Unlink from global list */
    dlist_delete(&cexpr->node);
    /* Free all storage associated with CachedExpression */
    MemoryContextDelete(cexpr->context);
}
 
/*
 * QueryListGetPrimaryStmt
 *      Get the "primary" stmt within a list, ie, the one marked canSetTag.
 *
 * Returns NULL if no such stmt.  If multiple queries within the list are
 * marked canSetTag, returns the first one.  Neither of these cases should
 * occur in present usages of this function.
 */
static Query *
QueryListGetPrimaryStmt(List *stmts)
{
    ListCell   *lc;
 
    foreach(lc, stmts)
    {
        Query      *stmt = lfirst_node(Query, lc);
 
        if (stmt->canSetTag)
            return stmt;
    }
    return NULL;
}
 
/*
 * AcquireExecutorLocks: acquire locks needed for execution of a cached plan;
 * or release them if acquire is false.
 */
static void
AcquireExecutorLocks(List *stmt_list, bool acquire)
{
    ListCell   *lc1;
 
    foreach(lc1, stmt_list)
    {
        PlannedStmt *plannedstmt = lfirst_node(PlannedStmt, lc1);
        ListCell   *lc2;
 
        if (plannedstmt->commandType == CMD_UTILITY)
        {
            /*
             * Ignore utility statements, except those (such as EXPLAIN) that
             * contain a parsed-but-not-planned query.  Note: it's okay to use
             * ScanQueryForLocks, even though the query hasn't been through
             * rule rewriting, because rewriting doesn't change the query
             * representation.
             */
            Query      *query = UtilityContainsQuery(plannedstmt->utilityStmt);
 
            if (query)
                ScanQueryForLocks(query, acquire);
            continue;
        }
 
        foreach(lc2, plannedstmt->rtable)
        {
            RangeTblEntry *rte = (RangeTblEntry *) lfirst(lc2);
 
            if (!(rte->rtekind == RTE_RELATION ||
                  (rte->rtekind == RTE_SUBQUERY && OidIsValid(rte->relid))))
                continue;
 
            /*
             * Acquire the appropriate type of lock on each relation OID. Note
             * that we don't actually try to open the rel, and hence will not
             * fail if it's been dropped entirely --- we'll just transiently
             * acquire a non-conflicting lock.
             */
            if (acquire)
                LockRelationOid(rte->relid, rte->rellockmode);
            else
                UnlockRelationOid(rte->relid, rte->rellockmode);
        }
    }
}
 
/*
 * AcquirePlannerLocks: acquire locks needed for planning of a querytree list;
 * or release them if acquire is false.
 *
 * Note that we don't actually try to open the relations, and hence will not
 * fail if one has been dropped entirely --- we'll just transiently acquire
 * a non-conflicting lock.
 */
static void
AcquirePlannerLocks(List *stmt_list, bool acquire)
{
    ListCell   *lc;
 
    foreach(lc, stmt_list)
    {
        Query      *query = lfirst_node(Query, lc);
 
        if (query->commandType == CMD_UTILITY)
        {
            /* Ignore utility statements, unless they contain a Query */
            query = UtilityContainsQuery(query->utilityStmt);
            if (query)
                ScanQueryForLocks(query, acquire);
            continue;
        }
 
        ScanQueryForLocks(query, acquire);
    }
}
 
/*
 * ScanQueryForLocks: recursively scan one Query for AcquirePlannerLocks.
 */
static void
ScanQueryForLocks(Query *parsetree, bool acquire)
{
    ListCell   *lc;
 
    /* Shouldn't get called on utility commands */
    Assert(parsetree->commandType != CMD_UTILITY);
 
    /*
     * First, process RTEs of the current query level.
     */
    foreach(lc, parsetree->rtable)
    {
        RangeTblEntry *rte = (RangeTblEntry *) lfirst(lc);
 
        switch (rte->rtekind)
        {
            case RTE_RELATION:
                /* Acquire or release the appropriate type of lock */
                if (acquire)
                    LockRelationOid(rte->relid, rte->rellockmode);
                else
                    UnlockRelationOid(rte->relid, rte->rellockmode);
                break;
 
            case RTE_SUBQUERY:
                /* If this was a view, must lock/unlock the view */
                if (OidIsValid(rte->relid))
                {
                    if (acquire)
                        LockRelationOid(rte->relid, rte->rellockmode);
                    else
                        UnlockRelationOid(rte->relid, rte->rellockmode);
                }
                /* Recurse into subquery-in-FROM */
                ScanQueryForLocks(rte->subquery, acquire);
                break;
 
            default:
                /* ignore other types of RTEs */
                break;
        }
    }
 
    /* Recurse into subquery-in-WITH */
    foreach(lc, parsetree->cteList)
    {
        CommonTableExpr *cte = lfirst_node(CommonTableExpr, lc);
 
        ScanQueryForLocks(castNode(Query, cte->ctequery), acquire);
    }
 
    /*
     * Recurse into sublink subqueries, too.  But we already did the ones in
     * the rtable and cteList.
     */
    if (parsetree->hasSubLinks)
    {
        query_tree_walker(parsetree, ScanQueryWalker, &acquire,
                          QTW_IGNORE_RC_SUBQUERIES);
    }
}
 
/*
 * Walker to find sublink subqueries for ScanQueryForLocks
 */
static bool
ScanQueryWalker(Node *node, bool *acquire)
{
    if (node == NULL)
        return false;
    if (IsA(node, SubLink))
    {
        SubLink    *sub = (SubLink *) node;
 
        /* Do what we came for */
        ScanQueryForLocks(castNode(Query, sub->subselect), *acquire);
        /* Fall through to process lefthand args of SubLink */
    }
 
    /*
     * Do NOT recurse into Query nodes, because ScanQueryForLocks already
     * processed subselects of subselects for us.
     */
    return expression_tree_walker(node, ScanQueryWalker, acquire);
}
 
/*
 * PlanCacheComputeResultDesc: given a list of analyzed-and-rewritten Queries,
 * determine the result tupledesc it will produce.  Returns NULL if the
 * execution will not return tuples.
 *
 * Note: the result is created or copied into current memory context.
 */
static TupleDesc
PlanCacheComputeResultDesc(List *stmt_list)
{
    Query      *query;
 
    switch (ChoosePortalStrategy(stmt_list))
    {
        case PORTAL_ONE_SELECT:
        case PORTAL_ONE_MOD_WITH:
            query = linitial_node(Query, stmt_list);
            return ExecCleanTypeFromTL(query->targetList);
 
        case PORTAL_ONE_RETURNING:
            query = QueryListGetPrimaryStmt(stmt_list);
            Assert(query->returningList);
            return ExecCleanTypeFromTL(query->returningList);
 
        case PORTAL_UTIL_SELECT:
            query = linitial_node(Query, stmt_list);
            Assert(query->utilityStmt);
            return UtilityTupleDescriptor(query->utilityStmt);
 
        case PORTAL_MULTI_QUERY:
            /* will not return tuples */
            break;
    }
    return NULL;
}
 
/*
 * PlanCacheRelCallback
 *      Relcache inval callback function
 *
 * Invalidate all plans mentioning the given rel, or all plans mentioning
 * any rel at all if relid == InvalidOid.
 */
static void
PlanCacheRelCallback(Datum arg, Oid relid)
{
    dlist_iter  iter;
 
    dlist_foreach(iter, &saved_plan_list)
    {
        CachedPlanSource *plansource = dlist_container(CachedPlanSource,
                                                       node, iter.cur);
 
        Assert(plansource->magic == CACHEDPLANSOURCE_MAGIC);
 
        /* No work if it's already invalidated */
        if (!plansource->is_valid)
            continue;
 
        /* Never invalidate if parse/plan would be a no-op anyway */
        if (!StmtPlanRequiresRevalidation(plansource))
            continue;
 
        /*
         * Check the dependency list for the rewritten querytree.
         */
        if ((relid == InvalidOid) ? plansource->relationOids != NIL :
            list_member_oid(plansource->relationOids, relid))
        {
            /* Invalidate the querytree and generic plan */
            plansource->is_valid = false;
            if (plansource->gplan)
                plansource->gplan->is_valid = false;
        }
 
        /*
         * The generic plan, if any, could have more dependencies than the
         * querytree does, so we have to check it too.
         */
        if (plansource->gplan && plansource->gplan->is_valid)
        {
            ListCell   *lc;
 
            foreach(lc, plansource->gplan->stmt_list)
            {
                PlannedStmt *plannedstmt = lfirst_node(PlannedStmt, lc);
 
                if (plannedstmt->commandType == CMD_UTILITY)
                    continue;   /* Ignore utility statements */
                if ((relid == InvalidOid) ? plannedstmt->relationOids != NIL :
                    list_member_oid(plannedstmt->relationOids, relid))
                {
                    /* Invalidate the generic plan only */
                    plansource->gplan->is_valid = false;
                    break;      /* out of stmt_list scan */
                }
            }
        }
    }
 
    /* Likewise check cached expressions */
    dlist_foreach(iter, &cached_expression_list)
    {
        CachedExpression *cexpr = dlist_container(CachedExpression,
                                                  node, iter.cur);
 
        Assert(cexpr->magic == CACHEDEXPR_MAGIC);
 
        /* No work if it's already invalidated */
        if (!cexpr->is_valid)
            continue;
 
        if ((relid == InvalidOid) ? cexpr->relationOids != NIL :
            list_member_oid(cexpr->relationOids, relid))
        {
            cexpr->is_valid = false;
        }
    }
}
 
/*
 * PlanCacheObjectCallback
 *      Syscache inval callback function for PROCOID and TYPEOID caches
 *
 * Invalidate all plans mentioning the object with the specified hash value,
 * or all plans mentioning any member of this cache if hashvalue == 0.
 */
static void
PlanCacheObjectCallback(Datum arg, SysCacheIdentifier cacheid, uint32 hashvalue)
{
    dlist_iter  iter;
 
    dlist_foreach(iter, &saved_plan_list)
    {
        CachedPlanSource *plansource = dlist_container(CachedPlanSource,
                                                       node, iter.cur);
        ListCell   *lc;
 
        Assert(plansource->magic == CACHEDPLANSOURCE_MAGIC);
 
        /* No work if it's already invalidated */
        if (!plansource->is_valid)
            continue;
 
        /* Never invalidate if parse/plan would be a no-op anyway */
        if (!StmtPlanRequiresRevalidation(plansource))
            continue;
 
        /*
         * Check the dependency list for the rewritten querytree.
         */
        foreach(lc, plansource->invalItems)
        {
            PlanInvalItem *item = (PlanInvalItem *) lfirst(lc);
 
            if (item->cacheId != cacheid)
                continue;
            if (hashvalue == 0 ||
                item->hashValue == hashvalue)
            {
                /* Invalidate the querytree and generic plan */
                plansource->is_valid = false;
                if (plansource->gplan)
                    plansource->gplan->is_valid = false;
                break;
            }
        }
 
        /*
         * The generic plan, if any, could have more dependencies than the
         * querytree does, so we have to check it too.
         */
        if (plansource->gplan && plansource->gplan->is_valid)
        {
            foreach(lc, plansource->gplan->stmt_list)
            {
                PlannedStmt *plannedstmt = lfirst_node(PlannedStmt, lc);
                ListCell   *lc3;
 
                if (plannedstmt->commandType == CMD_UTILITY)
                    continue;   /* Ignore utility statements */
                foreach(lc3, plannedstmt->invalItems)
                {
                    PlanInvalItem *item = (PlanInvalItem *) lfirst(lc3);
 
                    if (item->cacheId != cacheid)
                        continue;
                    if (hashvalue == 0 ||
                        item->hashValue == hashvalue)
                    {
                        /* Invalidate the generic plan only */
                        plansource->gplan->is_valid = false;
                        break;  /* out of invalItems scan */
                    }
                }
                if (!plansource->gplan->is_valid)
                    break;      /* out of stmt_list scan */
            }
        }
    }
 
    /* Likewise check cached expressions */
    dlist_foreach(iter, &cached_expression_list)
    {
        CachedExpression *cexpr = dlist_container(CachedExpression,
                                                  node, iter.cur);
        ListCell   *lc;
 
        Assert(cexpr->magic == CACHEDEXPR_MAGIC);
 
        /* No work if it's already invalidated */
        if (!cexpr->is_valid)
            continue;
 
        foreach(lc, cexpr->invalItems)
        {
            PlanInvalItem *item = (PlanInvalItem *) lfirst(lc);
 
            if (item->cacheId != cacheid)
                continue;
            if (hashvalue == 0 ||
                item->hashValue == hashvalue)
            {
                cexpr->is_valid = false;
                break;
            }
        }
    }
}
 
/*
 * PlanCacheSysCallback
 *      Syscache inval callback function for other caches
 *
 * Just invalidate everything...
 */
static void
PlanCacheSysCallback(Datum arg, SysCacheIdentifier cacheid, uint32 hashvalue)
{
    ResetPlanCache();
}
 
/*
 * ResetPlanCache: invalidate all cached plans.
 */
void
ResetPlanCache(void)
{
    dlist_iter  iter;
 
    dlist_foreach(iter, &saved_plan_list)
    {
        CachedPlanSource *plansource = dlist_container(CachedPlanSource,
                                                       node, iter.cur);
 
        Assert(plansource->magic == CACHEDPLANSOURCE_MAGIC);
 
        /* No work if it's already invalidated */
        if (!plansource->is_valid)
            continue;
 
        /*
         * We *must not* mark transaction control statements as invalid,
         * particularly not ROLLBACK, because they may need to be executed in
         * aborted transactions when we can't revalidate them (cf bug #5269).
         * In general there's no point in invalidating statements for which a
         * new parse analysis/rewrite/plan cycle would certainly give the same
         * results.
         */
        if (!StmtPlanRequiresRevalidation(plansource))
            continue;
 
        plansource->is_valid = false;
        if (plansource->gplan)
            plansource->gplan->is_valid = false;
    }
 
    /* Likewise invalidate cached expressions */
    dlist_foreach(iter, &cached_expression_list)
    {
        CachedExpression *cexpr = dlist_container(CachedExpression,
                                                  node, iter.cur);
 
        Assert(cexpr->magic == CACHEDEXPR_MAGIC);
 
        cexpr->is_valid = false;
    }
}
 
/*
 * Release all CachedPlans remembered by 'owner'
 */
void
ReleaseAllPlanCacheRefsInOwner(ResourceOwner owner)
{
    ResourceOwnerReleaseAllOfKind(owner, &planref_resowner_desc);
}
 
/* ResourceOwner callbacks */
 
static void
ResOwnerReleaseCachedPlan(Datum res)
{
    ReleaseCachedPlan((CachedPlan *) DatumGetPointer(res), NULL);
}