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new_physical_plan_builder.go
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new_physical_plan_builder.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"
log "github.com/Sirupsen/logrus"
"github.com/juju/errors"
"github.com/pingcap/tidb/ast"
"github.com/pingcap/tidb/context"
"github.com/pingcap/tidb/expression"
"github.com/pingcap/tidb/expression/aggregation"
"github.com/pingcap/tidb/infoschema"
"github.com/pingcap/tidb/kv"
"github.com/pingcap/tidb/model"
"github.com/pingcap/tidb/mysql"
"github.com/pingcap/tidb/util/ranger"
"github.com/pingcap/tidb/util/types"
)
// wholeTaskTypes records all possible kinds of task that a plan can return. For Agg, TopN and Limit, we will try to get
// these tasks one by one.
var wholeTaskTypes = [...]taskType{copSingleReadTaskType, copDoubleReadTaskType, rootTaskType}
var invalidTask = &rootTask{cst: math.MaxFloat64}
func (p *requiredProp) enforceProperty(task task, ctx context.Context, allocator *idAllocator) task {
if p.isEmpty() {
return task
}
// If task is invalid, keep it remained.
if task.plan() == nil {
return task
}
task = finishCopTask(task, ctx, allocator)
sort := Sort{ByItems: make([]*ByItems, 0, len(p.cols))}.init(allocator, ctx)
for _, col := range p.cols {
sort.ByItems = append(sort.ByItems, &ByItems{col, p.desc})
}
sort.SetSchema(task.plan().Schema())
sort.profile = task.plan().statsProfile()
return sort.attach2Task(task)
}
// getChildrenPossibleProps will check if this sort property can be pushed or not.
// When a sort column will be replaced by scalar function, we refuse it.
// When a sort column will be replaced by a constant, we just remove it.
func (p *Projection) getChildrenPossibleProps(prop *requiredProp) [][]*requiredProp {
p.expectedCnt = prop.expectedCnt
newProp := &requiredProp{taskTp: rootTaskType, expectedCnt: prop.expectedCnt}
newCols := make([]*expression.Column, 0, len(prop.cols))
for _, col := range prop.cols {
idx := p.schema.ColumnIndex(col)
if idx == -1 {
return nil
}
switch expr := p.Exprs[idx].(type) {
case *expression.Column:
newCols = append(newCols, expr)
case *expression.ScalarFunction:
return nil
}
}
newProp.cols = newCols
newProp.desc = prop.desc
return [][]*requiredProp{{newProp}}
}
// joinKeysMatchIndex checks if all keys match columns in index.
func joinKeysMatchIndex(keys []*expression.Column, index *model.IndexInfo) []int {
if len(index.Columns) < len(keys) {
return nil
}
matchOffsets := make([]int, len(keys))
for i, idxCol := range index.Columns {
if idxCol.Length != types.UnspecifiedLength {
return nil
}
found := false
for j, key := range keys {
if idxCol.Name.L == key.ColName.L {
matchOffsets[i] = j
found = true
break
}
}
if !found {
return nil
}
if i+1 == len(keys) {
break
}
}
return matchOffsets
}
func (p *LogicalJoin) constructIndexJoin(innerJoinKeys, outerJoinKeys []*expression.Column, outerIdx int, innerPlan PhysicalPlan) []PhysicalPlan {
var rightConds, leftConds expression.CNFExprs
if outerIdx == 0 {
rightConds = p.RightConditions.Clone()
leftConds = p.LeftConditions.Clone()
} else {
rightConds = p.LeftConditions.Clone()
leftConds = p.RightConditions.Clone()
}
join := PhysicalIndexJoin{
outerIndex: outerIdx,
LeftConditions: leftConds,
RightConditions: rightConds,
OtherConditions: p.OtherConditions,
Outer: p.JoinType != InnerJoin,
OuterJoinKeys: outerJoinKeys,
InnerJoinKeys: innerJoinKeys,
DefaultValues: p.DefaultValues,
outerSchema: p.children[outerIdx].Schema(),
innerPlan: innerPlan,
}.init(p.allocator, p.ctx, p.children[outerIdx], p.children[1-outerIdx])
join.SetSchema(expression.MergeSchema(p.children[outerIdx].Schema(), p.children[1-outerIdx].Schema()))
join.profile = p.profile
orderJoin := join.Copy().(*PhysicalIndexJoin)
orderJoin.KeepOrder = true
return []PhysicalPlan{join, orderJoin}
}
// getIndexJoinByOuterIdx will generate index join by outerIndex. OuterIdx points out the outer child,
// because we will swap the children of join when the right child is outer child.
// First of all, we will extract the join keys for p's equal conditions. If the join keys can match some of the indices or PK
// column of inner child, we can apply the index join.
func (p *LogicalJoin) getIndexJoinByOuterIdx(outerIdx int) []PhysicalPlan {
innerChild := p.children[1-outerIdx].(LogicalPlan)
var (
usedIndexInfo *model.IndexInfo
innerJoinKeys []*expression.Column
outerJoinKeys []*expression.Column
)
if outerIdx == 0 {
outerJoinKeys = p.LeftJoinKeys
innerJoinKeys = p.RightJoinKeys
} else {
innerJoinKeys = p.LeftJoinKeys
outerJoinKeys = p.RightJoinKeys
}
x, ok := innerChild.(*DataSource)
if !ok || x.unionScanSchema != nil {
return nil
}
indices, includeTableScan := availableIndices(x.indexHints, x.tableInfo)
if includeTableScan && len(innerJoinKeys) == 1 {
pkCol := x.getPKIsHandleCol()
if pkCol != nil && innerJoinKeys[0].Equal(pkCol, nil) {
innerPlan := x.forceToTableScan()
return p.constructIndexJoin(innerJoinKeys, outerJoinKeys, outerIdx, innerPlan)
}
}
for _, indexInfo := range indices {
matchedOffsets := joinKeysMatchIndex(innerJoinKeys, indexInfo)
if matchedOffsets == nil {
continue
}
usedIndexInfo = indexInfo
newOuterJoinKeys := make([]*expression.Column, len(outerJoinKeys))
newInnerJoinKeys := make([]*expression.Column, len(innerJoinKeys))
for i, offset := range matchedOffsets {
newOuterJoinKeys[i] = outerJoinKeys[offset]
newInnerJoinKeys[i] = innerJoinKeys[offset]
}
outerJoinKeys = newOuterJoinKeys
innerJoinKeys = newInnerJoinKeys
break
}
if usedIndexInfo != nil {
innerPlan := x.forceToIndexScan(usedIndexInfo)
return p.constructIndexJoin(innerJoinKeys, outerJoinKeys, outerIdx, innerPlan)
}
return nil
}
// For index join, we shouldn't require a root task which may let CBO framework select a sort operator in fact.
// We are not sure which way of index scanning we should choose, so we try both single read and double read and finally
// it will result in a best one.
func (p *PhysicalIndexJoin) getChildrenPossibleProps(prop *requiredProp) [][]*requiredProp {
p.expectedCnt = prop.expectedCnt
if !prop.isEmpty() && !p.KeepOrder {
return nil
}
for _, col := range prop.cols {
if p.outerSchema.ColumnIndex(col) == -1 {
return nil
}
}
requiredProps1 := make([]*requiredProp, 2)
requiredProps1[p.outerIndex] = &requiredProp{taskTp: rootTaskType, expectedCnt: prop.expectedCnt, cols: prop.cols, desc: prop.desc}
return [][]*requiredProp{requiredProps1}
}
func (p *PhysicalMergeJoin) getChildrenPossibleProps(prop *requiredProp) [][]*requiredProp {
p.expectedCnt = prop.expectedCnt
lProp := &requiredProp{taskTp: rootTaskType, cols: p.leftKeys, expectedCnt: math.MaxFloat64}
rProp := &requiredProp{taskTp: rootTaskType, cols: p.rightKeys, expectedCnt: math.MaxFloat64}
if !prop.isEmpty() {
if prop.desc {
return nil
}
if !prop.isPrefix(lProp) && !prop.isPrefix(rProp) {
return nil
}
if prop.isPrefix(rProp) && p.JoinType == LeftOuterJoin {
return nil
}
if prop.isPrefix(lProp) && p.JoinType == RightOuterJoin {
return nil
}
}
return [][]*requiredProp{{lProp, rProp}}
}
// tryToGetIndexJoin will get index join by hints. If we can generate a valid index join by hint, the second return value
// will be true, which means we force to choose this index join. Otherwise we will select a join algorithm with min-cost.
func (p *LogicalJoin) tryToGetIndexJoin() ([]PhysicalPlan, bool) {
if len(p.EqualConditions) == 0 {
return nil, false
}
plans := make([]PhysicalPlan, 0, 2)
leftOuter := (p.preferINLJ & preferLeftAsOuter) > 0
if leftOuter && p.JoinType != RightOuterJoin {
join := p.getIndexJoinByOuterIdx(0)
if join != nil {
plans = append(plans, join...)
}
}
rightOuter := (p.preferINLJ & preferRightAsOuter) > 0
if rightOuter && p.JoinType != LeftOuterJoin {
join := p.getIndexJoinByOuterIdx(1)
if join != nil {
plans = append(plans, join...)
}
}
if len(plans) > 0 {
return plans, true
}
// We try to choose join without considering hints.
if p.JoinType != RightOuterJoin {
join := p.getIndexJoinByOuterIdx(0)
if join != nil {
plans = append(plans, join...)
}
}
if p.JoinType != LeftOuterJoin {
join := p.getIndexJoinByOuterIdx(1)
if join != nil {
plans = append(plans, join...)
}
}
return plans, false
}
func (p *LogicalJoin) generatePhysicalPlans() []PhysicalPlan {
switch p.JoinType {
case SemiJoin, LeftOuterSemiJoin:
return []PhysicalPlan{p.getSemiJoin()}
default:
mj := p.getMergeJoin()
if p.preferMergeJoin && len(mj) > 0 {
return mj
}
joins := make([]PhysicalPlan, 0, 5)
if len(p.EqualConditions) == 1 {
joins = append(joins, mj...)
}
idxJoins, forced := p.tryToGetIndexJoin()
if forced {
return idxJoins
}
joins = append(joins, idxJoins...)
if p.JoinType != RightOuterJoin {
leftJoin := p.getHashJoin(1)
joins = append(joins, leftJoin)
}
if p.JoinType != LeftOuterJoin {
rightJoin := p.getHashJoin(0)
joins = append(joins, rightJoin)
}
return joins
}
}
func getPermutation(cols1, cols2 []*expression.Column) ([]int, []*expression.Column) {
tmpSchema := expression.NewSchema(cols2...)
permutation := make([]int, 0, len(cols1))
for i, col1 := range cols1 {
offset := tmpSchema.ColumnIndex(col1)
if offset == -1 {
return permutation, cols1[:i]
}
permutation = append(permutation, offset)
}
return permutation, cols1
}
func findMaxPrefixLen(candidates [][]*expression.Column, keys []*expression.Column) int {
maxLen := 0
for _, candidateKeys := range candidates {
matchedLen := 0
for i := range keys {
if i < len(candidateKeys) && keys[i].Equal(candidateKeys[i], nil) {
matchedLen++
} else {
break
}
}
if matchedLen > maxLen {
maxLen = matchedLen
}
}
return maxLen
}
func (p *LogicalJoin) getEqAndOtherCondsByOffsets(offsets []int) ([]*expression.ScalarFunction, []expression.Expression) {
var (
eqConds = make([]*expression.ScalarFunction, 0, len(p.EqualConditions))
otherConds = make([]expression.Expression, len(p.OtherConditions))
)
copy(otherConds, p.OtherConditions)
for i, eqCond := range p.EqualConditions {
match := false
for _, offset := range offsets {
if i == offset {
match = true
break
}
}
if !match {
otherConds = append(otherConds, eqCond)
} else {
eqConds = append(eqConds, eqCond)
}
}
return eqConds, otherConds
}
func (p *LogicalJoin) getMergeJoin() []PhysicalPlan {
joins := make([]PhysicalPlan, 0, len(p.leftProperties))
for _, leftCols := range p.leftProperties {
offsets, leftKeys := getPermutation(leftCols, p.LeftJoinKeys)
if len(offsets) == 0 {
continue
}
rightKeys := expression.NewSchema(p.RightJoinKeys...).ColumnsByIndices(offsets)
prefixLen := findMaxPrefixLen(p.rightProperties, rightKeys)
if prefixLen == 0 {
continue
}
leftKeys = leftKeys[:prefixLen]
rightKeys = rightKeys[:prefixLen]
offsets = offsets[:prefixLen]
mergeJoin := PhysicalMergeJoin{
JoinType: p.JoinType,
LeftConditions: p.LeftConditions,
RightConditions: p.RightConditions,
DefaultValues: p.DefaultValues,
leftKeys: leftKeys,
rightKeys: rightKeys,
}.init(p.allocator, p.ctx)
mergeJoin.SetSchema(p.schema)
mergeJoin.profile = p.profile
mergeJoin.EqualConditions, mergeJoin.OtherConditions = p.getEqAndOtherCondsByOffsets(offsets)
joins = append(joins, mergeJoin)
}
return joins
}
func (p *LogicalJoin) getSemiJoin() PhysicalPlan {
semiJoin := PhysicalHashSemiJoin{
WithAux: LeftOuterSemiJoin == p.JoinType,
EqualConditions: p.EqualConditions,
LeftConditions: p.LeftConditions,
RightConditions: p.RightConditions,
OtherConditions: p.OtherConditions,
Anti: p.anti,
rightChOffset: p.children[0].Schema().Len(),
}.init(p.allocator, p.ctx)
semiJoin.SetSchema(p.schema)
semiJoin.profile = p.profile
return semiJoin
}
func (p *LogicalJoin) getHashJoin(smallTable int) PhysicalPlan {
hashJoin := PhysicalHashJoin{
EqualConditions: p.EqualConditions,
LeftConditions: p.LeftConditions,
RightConditions: p.RightConditions,
OtherConditions: p.OtherConditions,
JoinType: p.JoinType,
Concurrency: JoinConcurrency,
DefaultValues: p.DefaultValues,
SmallTable: smallTable,
}.init(p.allocator, p.ctx)
hashJoin.SetSchema(p.schema)
hashJoin.profile = p.profile
return hashJoin
}
// getPropByOrderByItems will check if this sort property can be pushed or not. In order to simplify the problem, we only
// consider the case that all expression are columns and all of them are asc or desc.
func getPropByOrderByItems(items []*ByItems) (*requiredProp, bool) {
desc := false
cols := make([]*expression.Column, 0, len(items))
for i, item := range items {
col, ok := item.Expr.(*expression.Column)
if !ok {
return nil, false
}
cols = append(cols, col)
desc = item.Desc
if i > 0 && item.Desc != items[i-1].Desc {
return nil, false
}
}
return &requiredProp{cols: cols, desc: desc}, true
}
func (p *TopN) generatePhysicalPlans() []PhysicalPlan {
plans := []PhysicalPlan{p.Copy()}
if prop, canPass := getPropByOrderByItems(p.ByItems); canPass {
limit := Limit{
Count: p.Count,
Offset: p.Offset,
partial: p.partial,
expectedProp: prop,
}.init(p.allocator, p.ctx)
limit.SetSchema(p.schema)
limit.profile = p.profile
plans = append(plans, limit)
}
return plans
}
// convert2NewPhysicalPlan implements PhysicalPlan interface.
// If this sort is a topN plan, we will try to push the sort down and leave the limit.
// TODO: If this is a sort plan and the coming prop is not nil, this plan is redundant and can be removed.
func (p *Sort) convert2NewPhysicalPlan(prop *requiredProp) (task, error) {
t := p.getTask(prop)
if t != nil {
return t, nil
}
if prop.taskTp != rootTaskType {
// TODO: This is a trick here, because an operator that can be pushed to Coprocessor can never be pushed across sort.
// e.g. If an aggregation want to be pushed, the SQL is always like select count(*) from t order by ...
// The Sort will on top of Aggregation. If the SQL is like select count(*) from (select * from s order by k).
// The Aggregation will also be blocked by projection. In the future we will break this restriction.
p.storeTask(prop, invalidTask)
return invalidTask, nil
}
// enforce branch
t, err := p.children[0].(LogicalPlan).convert2NewPhysicalPlan(&requiredProp{taskTp: rootTaskType, expectedCnt: math.MaxFloat64})
if err != nil {
return nil, errors.Trace(err)
}
t = p.attach2Task(t)
newProp, canPassProp := getPropByOrderByItems(p.ByItems)
if canPassProp {
newProp.expectedCnt = prop.expectedCnt
orderedTask, err := p.children[0].(LogicalPlan).convert2NewPhysicalPlan(newProp)
if err != nil {
return nil, errors.Trace(err)
}
if orderedTask.cost() < t.cost() {
t = orderedTask
}
}
t = prop.enforceProperty(t, p.ctx, p.allocator)
p.storeTask(prop, t)
return t, nil
}
// convert2NewPhysicalPlan implements LogicalPlan interface.
func (p *baseLogicalPlan) convert2NewPhysicalPlan(prop *requiredProp) (t task, err error) {
// look up the task map
t = p.getTask(prop)
if t != nil {
return t, nil
}
t = invalidTask
if prop.taskTp != rootTaskType {
// Currently all plan cannot totally push down.
p.storeTask(prop, t)
return t, nil
}
// Now we only consider rootTask.
if len(p.basePlan.children) == 0 {
// When the children length is 0, we process it specially.
t = &rootTask{p: p.basePlan.self.(PhysicalPlan)}
t = prop.enforceProperty(t, p.basePlan.ctx, p.basePlan.allocator)
p.storeTask(prop, t)
return t, nil
}
// Else we suppose it only has one child.
for _, pp := range p.basePlan.self.(LogicalPlan).generatePhysicalPlans() {
// We consider to add enforcer firstly.
t, err = p.getBestTask(t, prop, pp, true)
if err != nil {
return nil, errors.Trace(err)
}
if prop.isEmpty() {
continue
}
t, err = p.getBestTask(t, prop, pp, false)
if err != nil {
return nil, errors.Trace(err)
}
}
p.storeTask(prop, t)
return t, nil
}
func (p *baseLogicalPlan) getBestTask(bestTask task, prop *requiredProp, pp PhysicalPlan, enforced bool) (task, error) {
var newProps [][]*requiredProp
if enforced {
newProps = pp.getChildrenPossibleProps(&requiredProp{taskTp: rootTaskType, expectedCnt: math.MaxFloat64})
} else {
newProps = pp.getChildrenPossibleProps(prop)
}
for _, newProp := range newProps {
tasks := make([]task, 0, len(p.basePlan.children))
for i, child := range p.basePlan.children {
childTask, err := child.(LogicalPlan).convert2NewPhysicalPlan(newProp[i])
if err != nil {
return nil, errors.Trace(err)
}
tasks = append(tasks, childTask)
}
resultTask := pp.attach2Task(tasks...)
if enforced {
resultTask = prop.enforceProperty(resultTask, p.basePlan.ctx, p.basePlan.allocator)
}
if resultTask.cost() < bestTask.cost() {
bestTask = resultTask
}
}
return bestTask, nil
}
func addUnionScan(cop *copTask, ds *DataSource) task {
t := finishCopTask(cop, ds.ctx, ds.allocator)
us := PhysicalUnionScan{
Conditions: ds.pushedDownConds,
NeedColHandle: ds.NeedColHandle,
}.init(ds.allocator, ds.ctx)
us.SetSchema(ds.unionScanSchema)
us.profile = t.plan().statsProfile()
return us.attach2Task(t)
}
// tryToGetMemTask will check if this table is a mem table. If it is, it will produce a task and store it.
func (p *DataSource) tryToGetMemTask(prop *requiredProp) (task task, err error) {
client := p.ctx.GetClient()
memDB := infoschema.IsMemoryDB(p.DBName.L)
isDistReq := !memDB && client != nil && client.IsRequestTypeSupported(kv.ReqTypeSelect, 0)
if isDistReq {
return nil, nil
}
memTable := PhysicalMemTable{
DBName: p.DBName,
Table: p.tableInfo,
Columns: p.Columns,
TableAsName: p.TableAsName,
}.init(p.allocator, p.ctx)
memTable.SetSchema(p.schema)
memTable.Ranges = ranger.FullIntRange()
memTable.profile = p.profile
var retPlan PhysicalPlan = memTable
if len(p.pushedDownConds) > 0 {
sel := Selection{
Conditions: p.pushedDownConds,
}.init(p.allocator, p.ctx)
sel.SetSchema(p.schema)
sel.SetChildren(memTable)
sel.profile = p.profile
retPlan = sel
}
task = &rootTask{p: retPlan}
task = prop.enforceProperty(task, p.ctx, p.allocator)
return task, nil
}
// tryToGetDualTask will check if the push down predicate has false constant. If so, it will return table dual.
func (p *DataSource) tryToGetDualTask() (task, error) {
for _, cond := range p.pushedDownConds {
if _, ok := cond.(*expression.Constant); ok {
result, err := expression.EvalBool([]expression.Expression{cond}, nil, p.ctx)
if err != nil {
return nil, errors.Trace(err)
}
if !result {
dual := TableDual{}.init(p.allocator, p.ctx)
dual.SetSchema(p.schema)
dual.profile = p.profile
return &rootTask{
p: dual,
}, nil
}
}
}
return nil, nil
}
// convert2NewPhysicalPlan implements the PhysicalPlan interface.
// It will enumerate all the available indices and choose a plan with least cost.
func (p *DataSource) convert2NewPhysicalPlan(prop *requiredProp) (task, error) {
if prop == nil {
return nil, nil
}
t := p.getTask(prop)
if t != nil {
return t, nil
}
t, err := p.tryToGetDualTask()
if err != nil {
return nil, errors.Trace(err)
}
if t != nil {
p.storeTask(prop, t)
return t, nil
}
t, err = p.tryToGetMemTask(prop)
if err != nil {
return nil, errors.Trace(err)
}
if t != nil {
p.storeTask(prop, t)
return t, nil
}
// TODO: We have not checked if this table has a predicate. If not, we can only consider table scan.
indices, includeTableScan := availableIndices(p.indexHints, p.tableInfo)
t = invalidTask
if includeTableScan {
t, err = p.convertToTableScan(prop)
if err != nil {
return nil, errors.Trace(err)
}
}
if !includeTableScan || len(p.pushedDownConds) > 0 || len(prop.cols) > 0 {
for _, idx := range indices {
idxTask, err := p.convertToIndexScan(prop, idx)
if err != nil {
return nil, errors.Trace(err)
}
if idxTask.cost() < t.cost() {
t = idxTask
}
}
}
p.storeTask(prop, t)
return t, nil
}
func (p *DataSource) forceToIndexScan(idx *model.IndexInfo) PhysicalPlan {
is := PhysicalIndexScan{
Table: p.tableInfo,
TableAsName: p.TableAsName,
DBName: p.DBName,
Columns: p.Columns,
Index: idx,
dataSourceSchema: p.schema,
physicalTableSource: physicalTableSource{NeedColHandle: p.NeedColHandle},
Ranges: ranger.FullIndexRange(),
OutOfOrder: true,
}.init(p.allocator, p.ctx)
is.filterCondition = p.pushedDownConds
is.profile = p.profile
cop := &copTask{
indexPlan: is,
}
if !isCoveringIndex(is.Columns, is.Index.Columns, is.Table.PKIsHandle) {
// On this way, it's double read case.
cop.tablePlan = PhysicalTableScan{Columns: p.Columns, Table: is.Table}.init(p.allocator, p.ctx)
cop.tablePlan.SetSchema(is.dataSourceSchema)
}
is.initSchema(p.id, idx, cop.tablePlan != nil)
is.addPushedDownSelection(cop, p, math.MaxFloat64)
t := finishCopTask(cop, p.ctx, p.allocator)
return t.plan()
}
// convertToIndexScan converts the DataSource to index scan with idx.
func (p *DataSource) convertToIndexScan(prop *requiredProp, idx *model.IndexInfo) (task task, err error) {
is := PhysicalIndexScan{
Table: p.tableInfo,
TableAsName: p.TableAsName,
DBName: p.DBName,
Columns: p.Columns,
Index: idx,
dataSourceSchema: p.schema,
physicalTableSource: physicalTableSource{NeedColHandle: p.NeedColHandle || p.unionScanSchema != nil},
}.init(p.allocator, p.ctx)
statsTbl := p.statisticTable
rowCount := float64(statsTbl.Count)
sc := p.ctx.GetSessionVars().StmtCtx
idxCols, colLengths := expression.IndexInfo2Cols(p.Schema().Columns, idx)
is.Ranges = ranger.FullIndexRange()
if len(p.pushedDownConds) > 0 {
conds := make([]expression.Expression, 0, len(p.pushedDownConds))
for _, cond := range p.pushedDownConds {
conds = append(conds, cond.Clone())
}
if len(idxCols) > 0 {
var ranges []types.Range
is.AccessCondition, is.filterCondition = ranger.DetachIndexConditions(conds, idxCols, colLengths)
ranges, err = ranger.BuildRange(sc, is.AccessCondition, ranger.IndexRangeType, idxCols, colLengths)
if err != nil {
return nil, errors.Trace(err)
}
is.Ranges = ranger.Ranges2IndexRanges(ranges)
rowCount, err = statsTbl.GetRowCountByIndexRanges(sc, is.Index.ID, is.Ranges)
if err != nil {
return nil, errors.Trace(err)
}
} else {
is.filterCondition = conds
}
}
is.profile = p.getStatsProfileByFilter(p.pushedDownConds)
cop := &copTask{
indexPlan: is,
}
if !isCoveringIndex(is.Columns, is.Index.Columns, is.Table.PKIsHandle) {
// On this way, it's double read case.
cop.tablePlan = PhysicalTableScan{Columns: p.Columns, Table: is.Table}.init(p.allocator, p.ctx)
cop.tablePlan.SetSchema(is.dataSourceSchema.Clone())
// If it's parent requires single read task, return max cost.
if prop.taskTp == copSingleReadTaskType {
return &copTask{cst: math.MaxFloat64}, nil
}
} else if prop.taskTp == copDoubleReadTaskType {
// If it's parent requires double read task, return max cost.
return &copTask{cst: math.MaxFloat64}, nil
}
is.initSchema(p.id, idx, cop.tablePlan != nil)
// Check if this plan matches the property.
matchProperty := false
if !prop.isEmpty() {
for i, col := range idx.Columns {
// not matched
if col.Name.L == prop.cols[0].ColName.L {
matchProperty = matchIndicesProp(idx.Columns[i:], prop.cols)
break
} else if i >= len(is.AccessCondition) {
break
} else if sf, ok := is.AccessCondition[i].(*expression.ScalarFunction); !ok || sf.FuncName.L != ast.EQ {
break
}
}
}
if matchProperty && prop.expectedCnt < math.MaxFloat64 {
selectivity, err := p.statisticTable.Selectivity(p.ctx, is.filterCondition)
if err != nil {
log.Warnf("An error happened: %v, we have to use the default selectivity", err.Error())
selectivity = selectionFactor
}
rowCount = math.Min(prop.expectedCnt/selectivity, rowCount)
}
is.expectedCnt = rowCount
cop.cst = rowCount * scanFactor
task = cop
if matchProperty {
if prop.desc {
is.Desc = true
cop.cst = rowCount * descScanFactor
}
if !is.NeedColHandle && cop.tablePlan != nil {
tblPlan := cop.tablePlan.(*PhysicalTableScan)
tblPlan.Columns = append(tblPlan.Columns, &model.ColumnInfo{
ID: model.ExtraHandleID,
Name: model.NewCIStr("_rowid"),
})
}
cop.keepOrder = true
is.addPushedDownSelection(cop, p, prop.expectedCnt)
if p.unionScanSchema != nil {
task = addUnionScan(cop, p)
}
} else {
is.OutOfOrder = true
expectedCnt := math.MaxFloat64
if prop.isEmpty() {
expectedCnt = prop.expectedCnt
}
is.addPushedDownSelection(cop, p, expectedCnt)
if p.unionScanSchema != nil {
task = addUnionScan(cop, p)
}
task = prop.enforceProperty(task, p.ctx, p.allocator)
}
if prop.taskTp == rootTaskType {
task = finishCopTask(task, p.ctx, p.allocator)
} else if _, ok := task.(*rootTask); ok {
return invalidTask, nil
}
return task, nil
}
func (is *PhysicalIndexScan) initSchema(id int, idx *model.IndexInfo, isDoubleRead bool) {
var indexCols []*expression.Column
for _, col := range idx.Columns {
indexCols = append(indexCols, &expression.Column{FromID: id, Position: col.Offset})
}
setHandle := false
for _, col := range is.Columns {
if (mysql.HasPriKeyFlag(col.Flag) && is.Table.PKIsHandle) || col.ID == model.ExtraHandleID {
indexCols = append(indexCols, &expression.Column{FromID: id, ID: col.ID, Position: col.Offset})
setHandle = true
break
}
}
// If it's double read case, the first index must return handle. So we should add extra handle column
// if there isn't a handle column.
if isDoubleRead && !setHandle {
indexCols = append(indexCols, &expression.Column{FromID: id, ID: model.ExtraHandleID, Position: -1})
}
is.SetSchema(expression.NewSchema(indexCols...))
}
func (is *PhysicalIndexScan) addPushedDownSelection(copTask *copTask, p *DataSource, expectedCnt float64) {
// Add filter condition to table plan now.
if len(is.filterCondition) > 0 {
var indexConds, tableConds []expression.Expression
if copTask.tablePlan != nil {
indexConds, tableConds = ranger.DetachIndexFilterConditions(is.filterCondition, is.Index.Columns, is.Table)
} else {
indexConds = is.filterCondition
}
if indexConds != nil {
condsClone := make([]expression.Expression, 0, len(indexConds))
for _, cond := range indexConds {
condsClone = append(condsClone, cond.Clone())
}
indexSel := Selection{Conditions: condsClone}.init(is.allocator, is.ctx)
indexSel.SetSchema(is.schema)
indexSel.SetChildren(is)
indexSel.profile = p.getStatsProfileByFilter(append(is.AccessCondition, indexConds...))
// FIXME: It is not precise.
indexSel.expectedCnt = expectedCnt
copTask.indexPlan = indexSel
copTask.cst += copTask.count() * cpuFactor
}
if tableConds != nil {
copTask.finishIndexPlan()
tableSel := Selection{Conditions: tableConds}.init(is.allocator, is.ctx)
tableSel.SetSchema(copTask.tablePlan.Schema())
tableSel.SetChildren(copTask.tablePlan)
tableSel.profile = p.profile
tableSel.expectedCnt = expectedCnt
copTask.tablePlan = tableSel
copTask.cst += copTask.count() * cpuFactor
}
}
}
func matchIndicesProp(idxCols []*model.IndexColumn, propCols []*expression.Column) bool {
if len(idxCols) < len(propCols) {
return false
}
for i, col := range propCols {
if idxCols[i].Length != types.UnspecifiedLength || col.ColName.L != idxCols[i].Name.L {
return false
}
}
return true
}
func (p *DataSource) forceToTableScan() PhysicalPlan {
ts := PhysicalTableScan{
Table: p.tableInfo,
Columns: p.Columns,
TableAsName: p.TableAsName,
DBName: p.DBName,
physicalTableSource: physicalTableSource{NeedColHandle: p.NeedColHandle},
Ranges: ranger.FullIntRange(),
}.init(p.allocator, p.ctx)
ts.SetSchema(p.schema)
ts.profile = p.profile
ts.filterCondition = p.pushedDownConds
copTask := &copTask{
tablePlan: ts,
indexPlanFinished: true,
}
ts.addPushedDownSelection(copTask, p.profile, math.MaxFloat64)
t := finishCopTask(copTask, p.ctx, p.allocator)
return t.plan()
}
// convertToTableScan converts the DataSource to table scan.
func (p *DataSource) convertToTableScan(prop *requiredProp) (task task, err error) {
if prop.taskTp == copDoubleReadTaskType {
return &copTask{cst: math.MaxFloat64}, nil
}
ts := PhysicalTableScan{
Table: p.tableInfo,
Columns: p.Columns,
TableAsName: p.TableAsName,
DBName: p.DBName,
physicalTableSource: physicalTableSource{NeedColHandle: p.NeedColHandle || p.unionScanSchema != nil},
}.init(p.allocator, p.ctx)
ts.SetSchema(p.schema)
sc := p.ctx.GetSessionVars().StmtCtx
ts.Ranges = ranger.FullIntRange()
var pkCol *expression.Column
if ts.Table.PKIsHandle {
if pkColInfo := ts.Table.GetPkColInfo(); pkColInfo != nil {
pkCol = expression.ColInfo2Col(ts.schema.Columns, pkColInfo)
}
}
if len(p.pushedDownConds) > 0 {
conds := make([]expression.Expression, 0, len(p.pushedDownConds))
for _, cond := range p.pushedDownConds {
conds = append(conds, cond.Clone())
}
if pkCol != nil {
var ranges []types.Range
ts.AccessCondition, ts.filterCondition = ranger.DetachColumnConditions(conds, pkCol.ColName)
ranges, err = ranger.BuildRange(sc, ts.AccessCondition, ranger.IntRangeType, []*expression.Column{pkCol}, nil)
ts.Ranges = ranger.Ranges2IntRanges(ranges)
if err != nil {
return nil, errors.Trace(err)
}
} else {
ts.filterCondition = conds
}
}
ts.profile = p.getStatsProfileByFilter(p.pushedDownConds)
statsTbl := p.statisticTable
rowCount := float64(statsTbl.Count)
if pkCol != nil {
// TODO: We can use p.getStatsProfileByFilter(accessConditions).
rowCount, err = statsTbl.GetRowCountByIntColumnRanges(sc, pkCol.ID, ts.Ranges)
if err != nil {
return nil, errors.Trace(err)
}
}
copTask := &copTask{
tablePlan: ts,
indexPlanFinished: true,
}
task = copTask
matchProperty := len(prop.cols) == 1 && pkCol != nil && prop.cols[0].Equal(pkCol, nil)
if matchProperty && prop.expectedCnt < math.MaxFloat64 {
selectivity, err := p.statisticTable.Selectivity(p.ctx, ts.filterCondition)
if err != nil {
log.Warnf("An error happened: %v, we have to use the default selectivity", err.Error())
selectivity = selectionFactor
}
rowCount = math.Min(prop.expectedCnt/selectivity, rowCount)
}
ts.expectedCnt = rowCount
copTask.cst = rowCount * scanFactor
if matchProperty {
if prop.desc {
ts.Desc = true
copTask.cst = rowCount * descScanFactor
}
ts.KeepOrder = true
copTask.keepOrder = true
ts.addPushedDownSelection(copTask, p.profile, prop.expectedCnt)
if p.unionScanSchema != nil {
task = addUnionScan(copTask, p)
}
} else {
expectedCnt := math.MaxFloat64
if prop.isEmpty() {
expectedCnt = prop.expectedCnt
}
ts.addPushedDownSelection(copTask, p.profile, expectedCnt)
if p.unionScanSchema != nil {
task = addUnionScan(copTask, p)
}
task = prop.enforceProperty(task, p.ctx, p.allocator)
}
if prop.taskTp == rootTaskType {
task = finishCopTask(task, p.ctx, p.allocator)
} else if _, ok := task.(*rootTask); ok {
return invalidTask, nil
}
return task, nil
}
func (ts *PhysicalTableScan) addPushedDownSelection(copTask *copTask, profile *statsProfile, expectedCnt float64) {