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220e45bf325b061b8dbd7451f87cedc07da61706
postgres/src/backend/optimizer/prep/prepqual.c
Tom Lane 220e45bf32 Improve the planner's simplification of NOT constructs. 
This patch merges the responsibility for NOT-flattening into
eval_const_expressions' processing.  It wasn't done that way originally
because prepqual.c is far older than eval_const_expressions.  But putting
this work into eval_const_expressions saves one pass over the qual trees,
and in fact saves even more than that because we can exploit the knowledge
that the subexpressions have already been recursively simplified.  Doing it
this way also lets us do it uniformly over all expressions, whereas
prepqual.c formerly just did it at top level to save cycles.  That should
improve the planner's ability to recognize logically-equivalent constructs.

While at it, also add the ability to fold a NOT into BooleanTest and
NullTest constructs (the latter only for the scalar-datatype case).

Per discussion of bug #5702.
2010-10-10 23:19:50 -04:00

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/*-------------------------------------------------------------------------
*
* prepqual.c
* Routines for preprocessing qualification expressions
*
*
* The parser regards AND and OR as purely binary operators, so a qual like
* (A = 1) OR (A = 2) OR (A = 3) ...
* will produce a nested parsetree
* (OR (A = 1) (OR (A = 2) (OR (A = 3) ...)))
* In reality, the optimizer and executor regard AND and OR as N-argument
* operators, so this tree can be flattened to
* (OR (A = 1) (A = 2) (A = 3) ...)
*
* Formerly, this module was responsible for doing the initial flattening,
* but now we leave it to eval_const_expressions to do that since it has to
* make a complete pass over the expression tree anyway. Instead, we just
* have to ensure that our manipulations preserve AND/OR flatness.
* pull_ands() and pull_ors() are used to maintain flatness of the AND/OR
* tree after local transformations that might introduce nested AND/ORs.
*
*
* Portions Copyright (c) 1996-2010, PostgreSQL Global Development Group
* Portions Copyright (c) 1994, Regents of the University of California
*
*
* IDENTIFICATION
* src/backend/optimizer/prep/prepqual.c
*
*-------------------------------------------------------------------------
*/
#include "postgres.h"
#include "nodes/makefuncs.h"
#include "optimizer/clauses.h"
#include "optimizer/prep.h"
#include "utils/lsyscache.h"
static List *pull_ands(List *andlist);
static List *pull_ors(List *orlist);
static Expr *find_duplicate_ors(Expr *qual);
static Expr *process_duplicate_ors(List *orlist);
/*
* negate_clause
* Negate a Boolean expression.
*
* Input is a clause to be negated (e.g., the argument of a NOT clause).
* Returns a new clause equivalent to the negation of the given clause.
*
* Although this can be invoked on its own, it's mainly intended as a helper
* for eval_const_expressions(), and that context drives several design
* decisions. In particular, if the input is already AND/OR flat, we must
* preserve that property. We also don't bother to recurse in situations
* where we can assume that lower-level executions of eval_const_expressions
* would already have simplified sub-clauses of the input.
*
* The difference between this and a simple make_notclause() is that this
* tries to get rid of the NOT node by logical simplification. It's clearly
* always a win if the NOT node can be eliminated altogether. However, our
* use of DeMorgan's laws could result in having more NOT nodes rather than
* fewer. We do that unconditionally anyway, because in WHERE clauses it's
* important to expose as much top-level AND/OR structure as possible.
* Also, eliminating an intermediate NOT may allow us to flatten two levels
* of AND or OR together that we couldn't have otherwise. Finally, one of
* the motivations for doing this is to ensure that logically equivalent
* expressions will be seen as physically equal(), so we should always apply
* the same transformations.
*/
Node *
negate_clause(Node *node)
{
if (node == NULL) /* should not happen */
elog(ERROR, "can't negate an empty subexpression");
switch (nodeTag(node))
{
case T_Const:
{
Const *c = (Const *) node;
/* NOT NULL is still NULL */
if (c->constisnull)
return makeBoolConst(false, true);
/* otherwise pretty easy */
return makeBoolConst(!DatumGetBool(c->constvalue), false);
}
break;
case T_OpExpr:
{
/*
* Negate operator if possible: (NOT (< A B)) => (>= A B)
*/
OpExpr *opexpr = (OpExpr *) node;
Oid negator = get_negator(opexpr->opno);
if (negator)
{
OpExpr *newopexpr = makeNode(OpExpr);
newopexpr->opno = negator;
newopexpr->opfuncid = InvalidOid;
newopexpr->opresulttype = opexpr->opresulttype;
newopexpr->opretset = opexpr->opretset;
newopexpr->args = opexpr->args;
newopexpr->location = opexpr->location;
return (Node *) newopexpr;
}
}
break;
case T_ScalarArrayOpExpr:
{
/*
* Negate a ScalarArrayOpExpr if its operator has a negator;
* for example x = ANY (list) becomes x <> ALL (list)
*/
ScalarArrayOpExpr *saopexpr = (ScalarArrayOpExpr *) node;
Oid negator = get_negator(saopexpr->opno);
if (negator)
{
ScalarArrayOpExpr *newopexpr = makeNode(ScalarArrayOpExpr);
newopexpr->opno = negator;
newopexpr->opfuncid = InvalidOid;
newopexpr->useOr = !saopexpr->useOr;
newopexpr->args = saopexpr->args;
newopexpr->location = saopexpr->location;
return (Node *) newopexpr;
}
}
break;
case T_BoolExpr:
{
BoolExpr *expr = (BoolExpr *) node;
switch (expr->boolop)
{
/*--------------------
* Apply DeMorgan's Laws:
* (NOT (AND A B)) => (OR (NOT A) (NOT B))
* (NOT (OR A B)) => (AND (NOT A) (NOT B))
* i.e., swap AND for OR and negate each subclause.
*
* If the input is already AND/OR flat and has no NOT
* directly above AND or OR, this transformation preserves
* those properties. For example, if no direct child of
* the given AND clause is an AND or a NOT-above-OR, then
* the recursive calls of negate_clause() can't return any
* OR clauses. So we needn't call pull_ors() before
* building a new OR clause. Similarly for the OR case.
*--------------------
*/
case AND_EXPR:
{
List *nargs = NIL;
ListCell *lc;
foreach(lc, expr->args)
{
nargs = lappend(nargs,
negate_clause(lfirst(lc)));
}
return (Node *) make_orclause(nargs);
}
break;
case OR_EXPR:
{
List *nargs = NIL;
ListCell *lc;
foreach(lc, expr->args)
{
nargs = lappend(nargs,
negate_clause(lfirst(lc)));
}
return (Node *) make_andclause(nargs);
}
break;
case NOT_EXPR:
/*
* NOT underneath NOT: they cancel. We assume the
* input is already simplified, so no need to recurse.
*/
return (Node *) linitial(expr->args);
default:
elog(ERROR, "unrecognized boolop: %d",
(int) expr->boolop);
break;
}
}
break;
case T_NullTest:
{
NullTest *expr = (NullTest *) node;
/*
* In the rowtype case, the two flavors of NullTest are *not*
* logical inverses, so we can't simplify. But it does work
* for scalar datatypes.
*/
if (!expr->argisrow)
{
NullTest *newexpr = makeNode(NullTest);
newexpr->arg = expr->arg;
newexpr->nulltesttype = (expr->nulltesttype == IS_NULL ?
IS_NOT_NULL : IS_NULL);
newexpr->argisrow = expr->argisrow;
return (Node *) newexpr;
}
}
break;
case T_BooleanTest:
{
BooleanTest *expr = (BooleanTest *) node;
BooleanTest *newexpr = makeNode(BooleanTest);
newexpr->arg = expr->arg;
switch (expr->booltesttype)
{
case IS_TRUE:
newexpr->booltesttype = IS_NOT_TRUE;
break;
case IS_NOT_TRUE:
newexpr->booltesttype = IS_TRUE;
break;
case IS_FALSE:
newexpr->booltesttype = IS_NOT_FALSE;
break;
case IS_NOT_FALSE:
newexpr->booltesttype = IS_FALSE;
break;
case IS_UNKNOWN:
newexpr->booltesttype = IS_NOT_UNKNOWN;
break;
case IS_NOT_UNKNOWN:
newexpr->booltesttype = IS_UNKNOWN;
break;
default:
elog(ERROR, "unrecognized booltesttype: %d",
(int) expr->booltesttype);
break;
}
return (Node *) newexpr;
}
break;
default:
/* else fall through */
break;
}
/*
* Otherwise we don't know how to simplify this, so just tack on an
* explicit NOT node.
*/
return (Node *) make_notclause((Expr *) node);
}
/*
* canonicalize_qual
* Convert a qualification expression to the most useful form.
*
* The name of this routine is a holdover from a time when it would try to
* force the expression into canonical AND-of-ORs or OR-of-ANDs form.
* Eventually, we recognized that that had more theoretical purity than
* actual usefulness, and so now the transformation doesn't involve any
* notion of reaching a canonical form.
*
* NOTE: we assume the input has already been through eval_const_expressions
* and therefore possesses AND/OR flatness. Formerly this function included
* its own flattening logic, but that requires a useless extra pass over the
* tree.
*
* Returns the modified qualification.
*/
Expr *
canonicalize_qual(Expr *qual)
{
Expr *newqual;
/* Quick exit for empty qual */
if (qual == NULL)
return NULL;
/*
* Pull up redundant subclauses in OR-of-AND trees. We do this only
* within the top-level AND/OR structure; there's no point in looking
* deeper.
*/
newqual = find_duplicate_ors(qual);
return newqual;
}
/*
* pull_ands
* Recursively flatten nested AND clauses into a single and-clause list.
*
* Input is the arglist of an AND clause.
* Returns the rebuilt arglist (note original list structure is not touched).
*/
static List *
pull_ands(List *andlist)
{
List *out_list = NIL;
ListCell *arg;
foreach(arg, andlist)
{
Node *subexpr = (Node *) lfirst(arg);
/*
* Note: we can destructively concat the subexpression's arglist
* because we know the recursive invocation of pull_ands will have
* built a new arglist not shared with any other expr. Otherwise we'd
* need a list_copy here.
*/
if (and_clause(subexpr))
out_list = list_concat(out_list,
pull_ands(((BoolExpr *) subexpr)->args));
else
out_list = lappend(out_list, subexpr);
}
return out_list;
}
/*
* pull_ors
* Recursively flatten nested OR clauses into a single or-clause list.
*
* Input is the arglist of an OR clause.
* Returns the rebuilt arglist (note original list structure is not touched).
*/
static List *
pull_ors(List *orlist)
{
List *out_list = NIL;
ListCell *arg;
foreach(arg, orlist)
{
Node *subexpr = (Node *) lfirst(arg);
/*
* Note: we can destructively concat the subexpression's arglist
* because we know the recursive invocation of pull_ors will have
* built a new arglist not shared with any other expr. Otherwise we'd
* need a list_copy here.
*/
if (or_clause(subexpr))
out_list = list_concat(out_list,
pull_ors(((BoolExpr *) subexpr)->args));
else
out_list = lappend(out_list, subexpr);
}
return out_list;
}
/*--------------------
* The following code attempts to apply the inverse OR distributive law:
* ((A AND B) OR (A AND C)) => (A AND (B OR C))
* That is, locate OR clauses in which every subclause contains an
* identical term, and pull out the duplicated terms.
*
* This may seem like a fairly useless activity, but it turns out to be
* applicable to many machine-generated queries, and there are also queries
* in some of the TPC benchmarks that need it. This was in fact almost the
* sole useful side-effect of the old prepqual code that tried to force
* the query into canonical AND-of-ORs form: the canonical equivalent of
* ((A AND B) OR (A AND C))
* is
* ((A OR A) AND (A OR C) AND (B OR A) AND (B OR C))
* which the code was able to simplify to
* (A AND (A OR C) AND (B OR A) AND (B OR C))
* thus successfully extracting the common condition A --- but at the cost
* of cluttering the qual with many redundant clauses.
*--------------------
*/
/*
* find_duplicate_ors
* Given a qualification tree with the NOTs pushed down, search for
* OR clauses to which the inverse OR distributive law might apply.
* Only the top-level AND/OR structure is searched.
*
* Returns the modified qualification. AND/OR flatness is preserved.
*/
static Expr *
find_duplicate_ors(Expr *qual)
{
if (or_clause((Node *) qual))
{
List *orlist = NIL;
ListCell *temp;
/* Recurse */
foreach(temp, ((BoolExpr *) qual)->args)
orlist = lappend(orlist, find_duplicate_ors(lfirst(temp)));
/*
* Don't need pull_ors() since this routine will never introduce an OR
* where there wasn't one before.
*/
return process_duplicate_ors(orlist);
}
else if (and_clause((Node *) qual))
{
List *andlist = NIL;
ListCell *temp;
/* Recurse */
foreach(temp, ((BoolExpr *) qual)->args)
andlist = lappend(andlist, find_duplicate_ors(lfirst(temp)));
/* Flatten any ANDs introduced just below here */
andlist = pull_ands(andlist);
/* The AND list can't get shorter, so result is always an AND */
return make_andclause(andlist);
}
else
return qual;
}
/*
* process_duplicate_ors
* Given a list of exprs which are ORed together, try to apply
* the inverse OR distributive law.
*
* Returns the resulting expression (could be an AND clause, an OR
* clause, or maybe even a single subexpression).
*/
static Expr *
process_duplicate_ors(List *orlist)
{
List *reference = NIL;
int num_subclauses = 0;
List *winners;
List *neworlist;
ListCell *temp;
if (orlist == NIL)
return NULL; /* probably can't happen */
if (list_length(orlist) == 1) /* single-expression OR (can this
* happen?) */
return linitial(orlist);
/*
* Choose the shortest AND clause as the reference list --- obviously, any
* subclause not in this clause isn't in all the clauses. If we find a
* clause that's not an AND, we can treat it as a one-element AND clause,
* which necessarily wins as shortest.
*/
foreach(temp, orlist)
{
Expr *clause = (Expr *) lfirst(temp);
if (and_clause((Node *) clause))
{
List *subclauses = ((BoolExpr *) clause)->args;
int nclauses = list_length(subclauses);
if (reference == NIL || nclauses < num_subclauses)
{
reference = subclauses;
num_subclauses = nclauses;
}
}
else
{
reference = list_make1(clause);
break;
}
}
/*
* Just in case, eliminate any duplicates in the reference list.
*/
reference = list_union(NIL, reference);
/*
* Check each element of the reference list to see if it's in all the OR
* clauses. Build a new list of winning clauses.
*/
winners = NIL;
foreach(temp, reference)
{
Expr *refclause = (Expr *) lfirst(temp);
bool win = true;
ListCell *temp2;
foreach(temp2, orlist)
{
Expr *clause = (Expr *) lfirst(temp2);
if (and_clause((Node *) clause))
{
if (!list_member(((BoolExpr *) clause)->args, refclause))
{
win = false;
break;
}
}
else
{
if (!equal(refclause, clause))
{
win = false;
break;
}
}
}
if (win)
winners = lappend(winners, refclause);
}
/*
* If no winners, we can't transform the OR
*/
if (winners == NIL)
return make_orclause(orlist);
/*
* Generate new OR list consisting of the remaining sub-clauses.
*
* If any clause degenerates to empty, then we have a situation like (A
* AND B) OR (A), which can be reduced to just A --- that is, the
* additional conditions in other arms of the OR are irrelevant.
*
* Note that because we use list_difference, any multiple occurrences of a
* winning clause in an AND sub-clause will be removed automatically.
*/
neworlist = NIL;
foreach(temp, orlist)
{
Expr *clause = (Expr *) lfirst(temp);
if (and_clause((Node *) clause))
{
List *subclauses = ((BoolExpr *) clause)->args;
subclauses = list_difference(subclauses, winners);
if (subclauses != NIL)
{
if (list_length(subclauses) == 1)
neworlist = lappend(neworlist, linitial(subclauses));
else
neworlist = lappend(neworlist, make_andclause(subclauses));
}
else
{
neworlist = NIL; /* degenerate case, see above */
break;
}
}
else
{
if (!list_member(winners, clause))
neworlist = lappend(neworlist, clause);
else
{
neworlist = NIL; /* degenerate case, see above */
break;
}
}
}
/*
* Append reduced OR to the winners list, if it's not degenerate, handling
* the special case of one element correctly (can that really happen?).
* Also be careful to maintain AND/OR flatness in case we pulled up a
* sub-sub-OR-clause.
*/
if (neworlist != NIL)
{
if (list_length(neworlist) == 1)
winners = lappend(winners, linitial(neworlist));
else
winners = lappend(winners, make_orclause(pull_ors(neworlist)));
}
/*
* And return the constructed AND clause, again being wary of a single
* element and AND/OR flatness.
*/
if (list_length(winners) == 1)
return (Expr *) linitial(winners);
else
return make_andclause(pull_ands(winners));
}
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