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/*-------------------------------------------------------------------------
*
* nodeTidrangescan.c
* Routines to support TID range scans of relations
*
* Portions Copyright (c) 1996-2022, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
*
* IDENTIFICATION
* src/backend/executor/nodeTidrangescan.c
*
*-------------------------------------------------------------------------
*/
#include "postgres.h"
#include "access/relscan.h"
#include "access/sysattr.h"
#include "access/tableam.h"
#include "catalog/pg_operator.h"
#include "executor/execdebug.h"
#include "executor/nodeTidrangescan.h"
#include "nodes/nodeFuncs.h"
#include "storage/bufmgr.h"
#include "utils/rel.h"
#define IsCTIDVar(node) \
((node) != NULL && \
IsA((node), Var) && \
((Var *) (node))->varattno == SelfItemPointerAttributeNumber && \
((Var *) (node))->varlevelsup == 0)
typedef enum
{
TIDEXPR_UPPER_BOUND,
TIDEXPR_LOWER_BOUND
} TidExprType;
/* Upper or lower range bound for scan */
typedef struct TidOpExpr
{
TidExprType exprtype; /* type of op; lower or upper */
ExprState *exprstate; /* ExprState for a TID-yielding subexpr */
bool inclusive; /* whether op is inclusive */
} TidOpExpr;
/*
* For the given 'expr', build and return an appropriate TidOpExpr taking into
* account the expr's operator and operand order.
*/
static TidOpExpr *
MakeTidOpExpr(OpExpr *expr, TidRangeScanState *tidstate)
{
Node *arg1 = get_leftop((Expr *) expr);
Node *arg2 = get_rightop((Expr *) expr);
ExprState *exprstate = NULL;
bool invert = false;
TidOpExpr *tidopexpr;
if (IsCTIDVar(arg1))
exprstate = ExecInitExpr((Expr *) arg2, &tidstate->ss.ps);
else if (IsCTIDVar(arg2))
{
exprstate = ExecInitExpr((Expr *) arg1, &tidstate->ss.ps);
invert = true;
}
else
elog(ERROR, "could not identify CTID variable");
tidopexpr = (TidOpExpr *) palloc(sizeof(TidOpExpr));
tidopexpr->inclusive = false; /* for now */
switch (expr->opno)
{
case TIDLessEqOperator:
tidopexpr->inclusive = true;
/* fall through */
case TIDLessOperator:
tidopexpr->exprtype = invert ? TIDEXPR_LOWER_BOUND : TIDEXPR_UPPER_BOUND;
break;
case TIDGreaterEqOperator:
tidopexpr->inclusive = true;
/* fall through */
case TIDGreaterOperator:
tidopexpr->exprtype = invert ? TIDEXPR_UPPER_BOUND : TIDEXPR_LOWER_BOUND;
break;
default:
elog(ERROR, "could not identify CTID operator");
}
tidopexpr->exprstate = exprstate;
return tidopexpr;
}
/*
* Extract the qual subexpressions that yield TIDs to search for,
* and compile them into ExprStates if they're ordinary expressions.
*/
static void
TidExprListCreate(TidRangeScanState *tidrangestate)
{
TidRangeScan *node = (TidRangeScan *) tidrangestate->ss.ps.plan;
List *tidexprs = NIL;
ListCell *l;
foreach(l, node->tidrangequals)
{
OpExpr *opexpr = lfirst(l);
TidOpExpr *tidopexpr;
if (!IsA(opexpr, OpExpr))
elog(ERROR, "could not identify CTID expression");
tidopexpr = MakeTidOpExpr(opexpr, tidrangestate);
tidexprs = lappend(tidexprs, tidopexpr);
}
tidrangestate->trss_tidexprs = tidexprs;
}
/* ----------------------------------------------------------------
* TidRangeEval
*
* Compute and set node's block and offset range to scan by evaluating
* the trss_tidexprs. Returns false if we detect the range cannot
* contain any tuples. Returns true if it's possible for the range to
* contain tuples.
* ----------------------------------------------------------------
*/
static bool
TidRangeEval(TidRangeScanState *node)
{
ExprContext *econtext = node->ss.ps.ps_ExprContext;
ItemPointerData lowerBound;
ItemPointerData upperBound;
ListCell *l;
/*
* Set the upper and lower bounds to the absolute limits of the range of
* the ItemPointer type. Below we'll try to narrow this range on either
* side by looking at the TidOpExprs.
*/
ItemPointerSet(&lowerBound, 0, 0);
ItemPointerSet(&upperBound, InvalidBlockNumber, PG_UINT16_MAX);
foreach(l, node->trss_tidexprs)
{
TidOpExpr *tidopexpr = (TidOpExpr *) lfirst(l);
ItemPointer itemptr;
bool isNull;
/* Evaluate this bound. */
itemptr = (ItemPointer)
DatumGetPointer(ExecEvalExprSwitchContext(tidopexpr->exprstate,
econtext,
&isNull));
/* If the bound is NULL, *nothing* matches the qual. */
if (isNull)
return false;
if (tidopexpr->exprtype == TIDEXPR_LOWER_BOUND)
{
ItemPointerData lb;
ItemPointerCopy(itemptr, &lb);
/*
* Normalize non-inclusive ranges to become inclusive. The
* resulting ItemPointer here may not be a valid item pointer.
*/
if (!tidopexpr->inclusive)
ItemPointerInc(&lb);
/* Check if we can narrow the range using this qual */
if (ItemPointerCompare(&lb, &lowerBound) > 0)
ItemPointerCopy(&lb, &lowerBound);
}
else if (tidopexpr->exprtype == TIDEXPR_UPPER_BOUND)
{
ItemPointerData ub;
ItemPointerCopy(itemptr, &ub);
/*
* Normalize non-inclusive ranges to become inclusive. The
* resulting ItemPointer here may not be a valid item pointer.
*/
if (!tidopexpr->inclusive)
ItemPointerDec(&ub);
/* Check if we can narrow the range using this qual */
if (ItemPointerCompare(&ub, &upperBound) < 0)
ItemPointerCopy(&ub, &upperBound);
}
}
ItemPointerCopy(&lowerBound, &node->trss_mintid);
ItemPointerCopy(&upperBound, &node->trss_maxtid);
return true;
}
/* ----------------------------------------------------------------
* TidRangeNext
*
* Retrieve a tuple from the TidRangeScan node's currentRelation
* using the TIDs in the TidRangeScanState information.
*
* ----------------------------------------------------------------
*/
static TupleTableSlot *
TidRangeNext(TidRangeScanState *node)
{
TableScanDesc scandesc;
EState *estate;
ScanDirection direction;
TupleTableSlot *slot;
/*
* extract necessary information from TID scan node
*/
scandesc = node->ss.ss_currentScanDesc;
estate = node->ss.ps.state;
slot = node->ss.ss_ScanTupleSlot;
direction = estate->es_direction;
if (!node->trss_inScan)
{
/* First time through, compute TID range to scan */
if (!TidRangeEval(node))
return NULL;
if (scandesc == NULL)
{
scandesc = table_beginscan_tidrange(node->ss.ss_currentRelation,
estate->es_snapshot,
&node->trss_mintid,
&node->trss_maxtid);
node->ss.ss_currentScanDesc = scandesc;
}
else
{
/* rescan with the updated TID range */
table_rescan_tidrange(scandesc, &node->trss_mintid,
&node->trss_maxtid);
}
node->trss_inScan = true;
}
/* Fetch the next tuple. */
if (!table_scan_getnextslot_tidrange(scandesc, direction, slot))
{
node->trss_inScan = false;
ExecClearTuple(slot);
}
return slot;
}
/*
* TidRangeRecheck -- access method routine to recheck a tuple in EvalPlanQual
*/
static bool
TidRangeRecheck(TidRangeScanState *node, TupleTableSlot *slot)
{
return true;
}
/* ----------------------------------------------------------------
* ExecTidRangeScan(node)
*
* Scans the relation using tids and returns the next qualifying tuple.
* We call the ExecScan() routine and pass it the appropriate
* access method functions.
*
* Conditions:
* -- the "cursor" maintained by the AMI is positioned at the tuple
* returned previously.
*
* Initial States:
* -- the relation indicated is opened for TID range scanning.
* ----------------------------------------------------------------
*/
static TupleTableSlot *
ExecTidRangeScan(PlanState *pstate)
{
TidRangeScanState *node = castNode(TidRangeScanState, pstate);
return ExecScan(&node->ss,
(ExecScanAccessMtd) TidRangeNext,
(ExecScanRecheckMtd) TidRangeRecheck);
}
/* ----------------------------------------------------------------
* ExecReScanTidRangeScan(node)
* ----------------------------------------------------------------
*/
void
ExecReScanTidRangeScan(TidRangeScanState *node)
{
/* mark scan as not in progress, and tid range list as not computed yet */
node->trss_inScan = false;
/*
* We must wait until TidRangeNext before calling table_rescan_tidrange.
*/
ExecScanReScan(&node->ss);
}
/* ----------------------------------------------------------------
* ExecEndTidRangeScan
*
* Releases any storage allocated through C routines.
* Returns nothing.
* ----------------------------------------------------------------
*/
void
ExecEndTidRangeScan(TidRangeScanState *node)
{
TableScanDesc scan = node->ss.ss_currentScanDesc;
if (scan != NULL)
table_endscan(scan);
/*
* Free the exprcontext
*/
ExecFreeExprContext(&node->ss.ps);
/*
* clear out tuple table slots
*/
if (node->ss.ps.ps_ResultTupleSlot)
ExecClearTuple(node->ss.ps.ps_ResultTupleSlot);
ExecClearTuple(node->ss.ss_ScanTupleSlot);
}
/* ----------------------------------------------------------------
* ExecInitTidRangeScan
*
* Initializes the tid range scan's state information, creates
* scan keys, and opens the scan relation.
*
* Parameters:
* node: TidRangeScan node produced by the planner.
* estate: the execution state initialized in InitPlan.
* ----------------------------------------------------------------
*/
TidRangeScanState *
ExecInitTidRangeScan(TidRangeScan *node, EState *estate, int eflags)
{
TidRangeScanState *tidrangestate;
Relation currentRelation;
/*
* create state structure
*/
tidrangestate = makeNode(TidRangeScanState);
tidrangestate->ss.ps.plan = (Plan *) node;
tidrangestate->ss.ps.state = estate;
tidrangestate->ss.ps.ExecProcNode = ExecTidRangeScan;
/*
* Miscellaneous initialization
*
* create expression context for node
*/
ExecAssignExprContext(estate, &tidrangestate->ss.ps);
/*
* mark scan as not in progress, and TID range as not computed yet
*/
tidrangestate->trss_inScan = false;
/*
* open the scan relation
*/
currentRelation = ExecOpenScanRelation(estate, node->scan.scanrelid, eflags);
tidrangestate->ss.ss_currentRelation = currentRelation;
tidrangestate->ss.ss_currentScanDesc = NULL; /* no table scan here */
/*
* get the scan type from the relation descriptor.
*/
ExecInitScanTupleSlot(estate, &tidrangestate->ss,
RelationGetDescr(currentRelation),
table_slot_callbacks(currentRelation));
/*
* Initialize result type and projection.
*/
ExecInitResultTypeTL(&tidrangestate->ss.ps);
ExecAssignScanProjectionInfo(&tidrangestate->ss);
/*
* initialize child expressions
*/
tidrangestate->ss.ps.qual =
ExecInitQual(node->scan.plan.qual, (PlanState *) tidrangestate);
TidExprListCreate(tidrangestate);
/*
* all done.
*/
return tidrangestate;
}
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