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decorrelate.go
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decorrelate.go
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// Copyright 2017 PingCAP, Inc.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// See the License for the specific language governing permissions and
// limitations under the License.
package plan
import (
"math"
"github.com/juju/errors"
"github.com/pingcap/tidb/ast"
"github.com/pingcap/tidb/expression"
"github.com/pingcap/tidb/expression/aggregation"
"github.com/pingcap/tidb/mysql"
"github.com/pingcap/tidb/types"
)
// extractCorColumnsBySchema only extracts the correlated columns that match the outer plan's schema.
// e.g. If the correlated columns from inner plan are [t1.a, t2.a, t3.a] and outer plan's schema is [t2.a, t2.b, t2.c],
// only [t2.a] is treated as this apply's correlated column.
func (la *LogicalApply) extractCorColumnsBySchema() {
schema := la.children[0].Schema()
corCols := la.children[1].extractCorrelatedCols()
resultCorCols := make([]*expression.CorrelatedColumn, schema.Len())
for _, corCol := range corCols {
idx := schema.ColumnIndex(&corCol.Column)
if idx != -1 {
if resultCorCols[idx] == nil {
resultCorCols[idx] = &expression.CorrelatedColumn{
Column: *schema.Columns[idx],
Data: new(types.Datum),
}
}
corCol.Data = resultCorCols[idx].Data
}
}
// Shrink slice. e.g. [col1, nil, col2, nil] will be changed to [col1, col2].
length := 0
for _, col := range resultCorCols {
if col != nil {
resultCorCols[length] = col
length++
}
}
la.corCols = resultCorCols[:length]
}
// canPullUpAgg checks if an apply can pull an aggregation up.
func (la *LogicalApply) canPullUpAgg() bool {
if la.JoinType != InnerJoin && la.JoinType != LeftOuterJoin {
return false
}
if len(la.EqualConditions)+len(la.LeftConditions)+len(la.RightConditions)+len(la.OtherConditions) > 0 {
return false
}
return len(la.children[0].Schema().Keys) > 0
}
// canPullUp checks if an aggregation can be pulled up. An aggregate function like count(*) cannot be pulled up.
func (la *LogicalAggregation) canPullUp() bool {
if len(la.GroupByItems) > 0 {
return false
}
for _, f := range la.AggFuncs {
for _, arg := range f.Args {
expr := expression.EvaluateExprWithNull(la.ctx, la.children[0].Schema(), arg)
if con, ok := expr.(*expression.Constant); !ok || !con.Value.IsNull() {
return false
}
}
}
return true
}
// deCorColFromEqExpr checks whether it's an equal condition of form `col = correlated col`. If so we will change the decorrelated
// column to normal column to make a new equal condition.
func (la *LogicalApply) deCorColFromEqExpr(expr expression.Expression) expression.Expression {
sf, ok := expr.(*expression.ScalarFunction)
if !ok || sf.FuncName.L != ast.EQ {
return nil
}
if col, lOk := sf.GetArgs()[0].(*expression.Column); lOk {
if corCol, rOk := sf.GetArgs()[1].(*expression.CorrelatedColumn); rOk {
ret := corCol.Decorrelate(la.Schema())
if _, ok := ret.(*expression.CorrelatedColumn); ok {
return nil
}
// We should make sure that the equal condition's left side is the join's left join key, right is the right key.
return expression.NewFunctionInternal(la.ctx, ast.EQ, types.NewFieldType(mysql.TypeTiny), ret, col)
}
}
if corCol, lOk := sf.GetArgs()[0].(*expression.CorrelatedColumn); lOk {
if col, rOk := sf.GetArgs()[1].(*expression.Column); rOk {
ret := corCol.Decorrelate(la.Schema())
if _, ok := ret.(*expression.CorrelatedColumn); ok {
return nil
}
// We should make sure that the equal condition's left side is the join's left join key, right is the right key.
return expression.NewFunctionInternal(la.ctx, ast.EQ, types.NewFieldType(mysql.TypeTiny), ret, col)
}
}
return nil
}
// decorrelateSolver tries to convert apply plan to join plan.
type decorrelateSolver struct{}
func (s *decorrelateSolver) aggDefaultValueMap(agg *LogicalAggregation) map[int]*expression.Constant {
defaultValueMap := make(map[int]*expression.Constant)
for i, f := range agg.AggFuncs {
switch f.Name {
case ast.AggFuncBitOr, ast.AggFuncBitXor, ast.AggFuncCount:
defaultValueMap[i] = expression.Zero.Clone().(*expression.Constant)
case ast.AggFuncBitAnd:
defaultValueMap[i] = &expression.Constant{Value: types.NewUintDatum(math.MaxUint64), RetType: types.NewFieldType(mysql.TypeLonglong)}
}
}
return defaultValueMap
}
// optimize implements logicalOptRule interface.
func (s *decorrelateSolver) optimize(p LogicalPlan) (LogicalPlan, error) {
if apply, ok := p.(*LogicalApply); ok {
outerPlan := apply.children[0]
innerPlan := apply.children[1]
apply.extractCorColumnsBySchema()
if len(apply.corCols) == 0 {
// If the inner plan is non-correlated, the apply will be simplified to join.
join := &apply.LogicalJoin
join.self = join
p = join
} else if sel, ok := innerPlan.(*LogicalSelection); ok {
// If the inner plan is a selection, we add this condition to join predicates.
// Notice that no matter what kind of join is, it's always right.
newConds := make([]expression.Expression, 0, len(sel.Conditions))
for _, cond := range sel.Conditions {
newConds = append(newConds, cond.Decorrelate(outerPlan.Schema()))
}
apply.attachOnConds(newConds)
innerPlan = sel.children[0]
apply.SetChildren(outerPlan, innerPlan)
return s.optimize(p)
} else if m, ok := innerPlan.(*LogicalMaxOneRow); ok {
if m.children[0].MaxOneRow() {
innerPlan = m.children[0]
apply.SetChildren(outerPlan, innerPlan)
return s.optimize(p)
}
} else if proj, ok := innerPlan.(*LogicalProjection); ok {
for i, expr := range proj.Exprs {
proj.Exprs[i] = expr.Decorrelate(outerPlan.Schema())
}
apply.columnSubstitute(proj.Schema(), proj.Exprs)
innerPlan = proj.children[0]
apply.SetChildren(outerPlan, innerPlan)
if apply.JoinType != SemiJoin && apply.JoinType != LeftOuterSemiJoin && apply.JoinType != AntiSemiJoin && apply.JoinType != AntiLeftOuterSemiJoin {
proj.SetSchema(apply.Schema())
proj.Exprs = append(expression.Column2Exprs(outerPlan.Schema().Clone().Columns), proj.Exprs...)
apply.SetSchema(expression.MergeSchema(outerPlan.Schema(), innerPlan.Schema()))
np, err := s.optimize(p)
if err != nil {
return nil, errors.Trace(err)
}
proj.SetChildren(np)
return proj, nil
}
return s.optimize(p)
} else if agg, ok := innerPlan.(*LogicalAggregation); ok {
if apply.canPullUpAgg() && agg.canPullUp() {
innerPlan = agg.children[0]
apply.JoinType = LeftOuterJoin
apply.SetChildren(outerPlan, innerPlan)
agg.SetSchema(apply.Schema())
agg.GroupByItems = expression.Column2Exprs(outerPlan.Schema().Keys[0])
newAggFuncs := make([]*aggregation.AggFuncDesc, 0, apply.Schema().Len())
for _, col := range outerPlan.Schema().Columns {
first := aggregation.NewAggFuncDesc(agg.ctx, ast.AggFuncFirstRow, []expression.Expression{col}, false)
newAggFuncs = append(newAggFuncs, first)
}
newAggFuncs = append(newAggFuncs, agg.AggFuncs...)
agg.AggFuncs = newAggFuncs
apply.SetSchema(expression.MergeSchema(outerPlan.Schema(), innerPlan.Schema()))
np, err := s.optimize(p)
if err != nil {
return nil, errors.Trace(err)
}
agg.SetChildren(np)
// TODO: Add a Projection if any argument of aggregate funcs or group by items are scalar functions.
// agg.buildProjectionIfNecessary()
agg.collectGroupByColumns()
return agg, nil
}
// We can pull up the equal conditions below the aggregation as the join key of the apply, if only
// the equal conditions contain the correlated column of this apply.
if sel, ok := agg.children[0].(*LogicalSelection); ok && apply.JoinType == LeftOuterJoin {
var (
eqCondWithCorCol []*expression.ScalarFunction
remainedExpr []expression.Expression
)
// Extract the equal condition.
for _, cond := range sel.Conditions {
if expr := apply.deCorColFromEqExpr(cond); expr != nil {
eqCondWithCorCol = append(eqCondWithCorCol, expr.(*expression.ScalarFunction))
} else {
remainedExpr = append(remainedExpr, cond)
}
}
if len(eqCondWithCorCol) > 0 {
originalExpr := sel.Conditions
sel.Conditions = remainedExpr
apply.extractCorColumnsBySchema()
// There's no other correlated column.
if len(apply.corCols) == 0 {
join := &apply.LogicalJoin
join.EqualConditions = append(join.EqualConditions, eqCondWithCorCol...)
for _, eqCond := range eqCondWithCorCol {
clonedCol := eqCond.GetArgs()[1].Clone()
// If the join key is not in the aggregation's schema, add first row function.
if agg.schema.ColumnIndex(eqCond.GetArgs()[1].(*expression.Column)) == -1 {
newFunc := aggregation.NewAggFuncDesc(apply.ctx, ast.AggFuncFirstRow, []expression.Expression{clonedCol}, false)
agg.AggFuncs = append(agg.AggFuncs, newFunc)
agg.schema.Append(clonedCol.(*expression.Column))
}
// If group by cols don't contain the join key, add it into this.
if agg.getGbyColIndex(eqCond.GetArgs()[1].(*expression.Column)) == -1 {
agg.GroupByItems = append(agg.GroupByItems, clonedCol)
}
}
agg.collectGroupByColumns()
// The selection may be useless, check and remove it.
if len(sel.Conditions) == 0 {
agg.SetChildren(sel.children[0])
}
defaultValueMap := s.aggDefaultValueMap(agg)
// We should use it directly, rather than building a projection.
if len(defaultValueMap) > 0 {
proj := LogicalProjection{}.init(agg.ctx)
proj.SetSchema(apply.schema)
proj.Exprs = expression.Column2Exprs(apply.schema.Columns)
for i, val := range defaultValueMap {
pos := proj.schema.ColumnIndex(agg.schema.Columns[i])
ifNullFunc := expression.NewFunctionInternal(agg.ctx, ast.Ifnull, types.NewFieldType(mysql.TypeLonglong), agg.schema.Columns[i], val)
proj.Exprs[pos] = ifNullFunc
}
proj.SetChildren(apply)
p = proj
}
return s.optimize(p)
}
sel.Conditions = originalExpr
apply.extractCorColumnsBySchema()
}
}
}
}
newChildren := make([]LogicalPlan, 0, len(p.Children()))
for _, child := range p.Children() {
np, err := s.optimize(child)
if err != nil {
return nil, errors.Trace(err)
}
newChildren = append(newChildren, np)
}
p.SetChildren(newChildren...)
return p, nil
}