githaven/vendor/github.com/pingcap/tidb/optimizer/plan/planbuilder_join.go
Thomas Boerger b6a95a8cb3 Integrate public as bindata optionally (#293)
* Dropped unused codekit config

* Integrated dynamic and static bindata for public

* Ignore public bindata

* Add a general generate make task

* Integrated flexible public assets into web command

* Updated vendoring, added all missiong govendor deps

* Made the linter happy with the bindata and dynamic code

* Moved public bindata definition to modules directory

* Ignoring the new bindata path now

* Updated to the new public modules import path

* Updated public bindata command and drop the new prefix
2016-11-30 00:26:36 +08:00

796 lines
20 KiB
Go

// Copyright 2015 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 (
"strings"
"github.com/ngaut/log"
"github.com/pingcap/tidb/ast"
"github.com/pingcap/tidb/model"
"github.com/pingcap/tidb/mysql"
"github.com/pingcap/tidb/parser/opcode"
)
// equalCond represents an equivalent join condition, like "t1.c1 = t2.c1".
type equalCond struct {
left *ast.ResultField
leftIdx bool
right *ast.ResultField
rightIdx bool
}
func newEqualCond(left, right *ast.ResultField) *equalCond {
eq := &equalCond{left: left, right: right}
eq.leftIdx = equivHasIndex(eq.left)
eq.rightIdx = equivHasIndex(eq.right)
return eq
}
func equivHasIndex(rf *ast.ResultField) bool {
if rf.Table.PKIsHandle && mysql.HasPriKeyFlag(rf.Column.Flag) {
return true
}
for _, idx := range rf.Table.Indices {
if len(idx.Columns) == 1 && idx.Columns[0].Name.L == rf.Column.Name.L {
return true
}
}
return false
}
// joinPath can be a single table path, inner join or outer join.
type joinPath struct {
// for table path
table *ast.TableName
totalFilterRate float64
// for subquery
subquery ast.Node
asName model.CIStr
neighborCount int // number of neighbor table.
idxDepCount int // number of paths this table depends on.
ordering *ast.ResultField
orderingDesc bool
// for outer join path
outer *joinPath
inner *joinPath
rightJoin bool
// for inner join path
inners []*joinPath
// common
parent *joinPath
filterRate float64
conditions []ast.ExprNode
eqConds []*equalCond
// The joinPaths that this path's index depends on.
idxDeps map[*joinPath]bool
neighbors map[*joinPath]bool
}
// newTablePath creates a new table join path.
func newTablePath(table *ast.TableName) *joinPath {
return &joinPath{
table: table,
filterRate: rateFull,
}
}
// newSubqueryPath creates a new subquery join path.
func newSubqueryPath(node ast.Node, asName model.CIStr) *joinPath {
return &joinPath{
subquery: node,
asName: asName,
filterRate: rateFull,
}
}
// newOuterJoinPath creates a new outer join path and pushes on condition to children paths.
// The returned joinPath slice has one element.
func newOuterJoinPath(isRightJoin bool, leftPath, rightPath *joinPath, on *ast.OnCondition) *joinPath {
outerJoin := &joinPath{rightJoin: isRightJoin, outer: leftPath, inner: rightPath, filterRate: 1}
leftPath.parent = outerJoin
rightPath.parent = outerJoin
if isRightJoin {
outerJoin.outer, outerJoin.inner = outerJoin.inner, outerJoin.outer
}
if on != nil {
conditions := splitWhere(on.Expr)
availablePaths := []*joinPath{outerJoin.outer}
for _, con := range conditions {
if !outerJoin.inner.attachCondition(con, availablePaths) {
log.Errorf("Inner failed to attach ON condition")
}
}
}
return outerJoin
}
// newInnerJoinPath creates inner join path and pushes on condition to children paths.
// If left path or right path is also inner join, it will be merged.
func newInnerJoinPath(leftPath, rightPath *joinPath, on *ast.OnCondition) *joinPath {
var innerJoin *joinPath
if len(leftPath.inners) != 0 {
innerJoin = leftPath
} else {
innerJoin = &joinPath{filterRate: leftPath.filterRate}
innerJoin.inners = append(innerJoin.inners, leftPath)
}
if len(rightPath.inners) != 0 {
innerJoin.inners = append(innerJoin.inners, rightPath.inners...)
innerJoin.conditions = append(innerJoin.conditions, rightPath.conditions...)
} else {
innerJoin.inners = append(innerJoin.inners, rightPath)
}
innerJoin.filterRate *= rightPath.filterRate
for _, in := range innerJoin.inners {
in.parent = innerJoin
}
if on != nil {
conditions := splitWhere(on.Expr)
for _, con := range conditions {
if !innerJoin.attachCondition(con, nil) {
innerJoin.conditions = append(innerJoin.conditions, con)
}
}
}
return innerJoin
}
func (p *joinPath) resultFields() []*ast.ResultField {
if p.table != nil {
return p.table.GetResultFields()
}
if p.outer != nil {
if p.rightJoin {
return append(p.inner.resultFields(), p.outer.resultFields()...)
}
return append(p.outer.resultFields(), p.inner.resultFields()...)
}
var rfs []*ast.ResultField
for _, in := range p.inners {
rfs = append(rfs, in.resultFields()...)
}
return rfs
}
// attachCondition tries to attach a condition as deep as possible.
// availablePaths are paths join before this path.
func (p *joinPath) attachCondition(condition ast.ExprNode, availablePaths []*joinPath) (attached bool) {
filterRate := guesstimateFilterRate(condition)
// table
if p.table != nil || p.subquery != nil {
attacher := conditionAttachChecker{targetPath: p, availablePaths: availablePaths}
condition.Accept(&attacher)
if attacher.invalid {
return false
}
p.conditions = append(p.conditions, condition)
p.filterRate *= filterRate
return true
}
// inner join
if len(p.inners) > 0 {
for _, in := range p.inners {
if in.attachCondition(condition, availablePaths) {
p.filterRate *= filterRate
return true
}
}
attacher := &conditionAttachChecker{targetPath: p, availablePaths: availablePaths}
condition.Accept(attacher)
if attacher.invalid {
return false
}
p.conditions = append(p.conditions, condition)
p.filterRate *= filterRate
return true
}
// outer join
if p.outer.attachCondition(condition, availablePaths) {
p.filterRate *= filterRate
return true
}
if p.inner.attachCondition(condition, append(availablePaths, p.outer)) {
p.filterRate *= filterRate
return true
}
return false
}
func (p *joinPath) containsTable(table *ast.TableName) bool {
if p.table != nil {
return p.table == table
}
if p.subquery != nil {
return p.asName.L == table.Name.L
}
if len(p.inners) != 0 {
for _, in := range p.inners {
if in.containsTable(table) {
return true
}
}
return false
}
return p.outer.containsTable(table) || p.inner.containsTable(table)
}
// attachEqualCond tries to attach an equalCond deep into a table path if applicable.
func (p *joinPath) attachEqualCond(eqCon *equalCond, availablePaths []*joinPath) (attached bool) {
// table
if p.table != nil {
var prevTable *ast.TableName
var needSwap bool
if eqCon.left.TableName == p.table {
prevTable = eqCon.right.TableName
} else if eqCon.right.TableName == p.table {
prevTable = eqCon.left.TableName
needSwap = true
}
if prevTable != nil {
for _, prev := range availablePaths {
if prev.containsTable(prevTable) {
if needSwap {
eqCon.left, eqCon.right = eqCon.right, eqCon.left
eqCon.leftIdx, eqCon.rightIdx = eqCon.rightIdx, eqCon.leftIdx
}
p.eqConds = append(p.eqConds, eqCon)
return true
}
}
}
return false
}
// inner join
if len(p.inners) > 0 {
for _, in := range p.inners {
if in.attachEqualCond(eqCon, availablePaths) {
p.filterRate *= rateEqual
return true
}
}
return false
}
// outer join
if p.outer.attachEqualCond(eqCon, availablePaths) {
p.filterRate *= rateEqual
return true
}
if p.inner.attachEqualCond(eqCon, append(availablePaths, p.outer)) {
p.filterRate *= rateEqual
return true
}
return false
}
func (p *joinPath) extractEqualConditon() {
var equivs []*equalCond
var cons []ast.ExprNode
for _, con := range p.conditions {
eq := equivFromExpr(con)
if eq != nil {
equivs = append(equivs, eq)
if p.table != nil {
if eq.right.TableName == p.table {
eq.left, eq.right = eq.right, eq.left
eq.leftIdx, eq.rightIdx = eq.rightIdx, eq.leftIdx
}
}
} else {
cons = append(cons, con)
}
}
p.eqConds = equivs
p.conditions = cons
for _, in := range p.inners {
in.extractEqualConditon()
}
if p.outer != nil {
p.outer.extractEqualConditon()
p.inner.extractEqualConditon()
}
}
func (p *joinPath) addIndexDependency() {
if p.outer != nil {
p.outer.addIndexDependency()
p.inner.addIndexDependency()
return
}
if p.table != nil {
return
}
for _, eq := range p.eqConds {
if !eq.leftIdx && !eq.rightIdx {
continue
}
pathLeft := p.findInnerContains(eq.left.TableName)
if pathLeft == nil {
continue
}
pathRight := p.findInnerContains(eq.right.TableName)
if pathRight == nil {
continue
}
if eq.leftIdx && eq.rightIdx {
pathLeft.addNeighbor(pathRight)
pathRight.addNeighbor(pathLeft)
} else if eq.leftIdx {
if !pathLeft.hasOuterIdxEqualCond() {
pathLeft.addIndexDep(pathRight)
}
} else if eq.rightIdx {
if !pathRight.hasOuterIdxEqualCond() {
pathRight.addIndexDep(pathLeft)
}
}
}
for _, in := range p.inners {
in.removeIndexDepCycle(in)
in.addIndexDependency()
}
}
func (p *joinPath) hasOuterIdxEqualCond() bool {
if p.table != nil {
for _, eq := range p.eqConds {
if eq.leftIdx {
return true
}
}
return false
}
if p.outer != nil {
return p.outer.hasOuterIdxEqualCond()
}
for _, in := range p.inners {
if in.hasOuterIdxEqualCond() {
return true
}
}
return false
}
func (p *joinPath) findInnerContains(table *ast.TableName) *joinPath {
for _, in := range p.inners {
if in.containsTable(table) {
return in
}
}
return nil
}
func (p *joinPath) addNeighbor(neighbor *joinPath) {
if p.neighbors == nil {
p.neighbors = map[*joinPath]bool{}
}
p.neighbors[neighbor] = true
p.neighborCount++
}
func (p *joinPath) addIndexDep(dep *joinPath) {
if p.idxDeps == nil {
p.idxDeps = map[*joinPath]bool{}
}
p.idxDeps[dep] = true
p.idxDepCount++
}
func (p *joinPath) removeIndexDepCycle(origin *joinPath) {
if p.idxDeps == nil {
return
}
for dep := range p.idxDeps {
if dep == origin {
delete(p.idxDeps, origin)
continue
}
dep.removeIndexDepCycle(origin)
}
}
func (p *joinPath) score() float64 {
return 1 / p.filterRate
}
func (p *joinPath) String() string {
if p.table != nil {
return p.table.TableInfo.Name.L
}
if p.outer != nil {
return "outer{" + p.outer.String() + "," + p.inner.String() + "}"
}
var innerStrs []string
for _, in := range p.inners {
innerStrs = append(innerStrs, in.String())
}
return "inner{" + strings.Join(innerStrs, ",") + "}"
}
func (p *joinPath) optimizeJoinOrder(availablePaths []*joinPath) {
if p.table != nil {
return
}
if p.outer != nil {
p.outer.optimizeJoinOrder(availablePaths)
p.inner.optimizeJoinOrder(append(availablePaths, p.outer))
return
}
var ordered []*joinPath
pathMap := map[*joinPath]bool{}
for _, in := range p.inners {
pathMap[in] = true
}
for len(pathMap) > 0 {
next := p.nextPath(pathMap, availablePaths)
next.optimizeJoinOrder(availablePaths)
ordered = append(ordered, next)
delete(pathMap, next)
availablePaths = append(availablePaths, next)
for path := range pathMap {
if path.idxDeps != nil {
delete(path.idxDeps, next)
}
if path.neighbors != nil {
delete(path.neighbors, next)
}
}
p.reattach(pathMap, availablePaths)
}
p.inners = ordered
}
// reattach is called by inner joinPath to retry attach conditions to inner paths
// after an inner path has been added to available paths.
func (p *joinPath) reattach(pathMap map[*joinPath]bool, availablePaths []*joinPath) {
if len(p.conditions) != 0 {
remainedConds := make([]ast.ExprNode, 0, len(p.conditions))
for _, con := range p.conditions {
var attached bool
for path := range pathMap {
if path.attachCondition(con, availablePaths) {
attached = true
break
}
}
if !attached {
remainedConds = append(remainedConds, con)
}
}
p.conditions = remainedConds
}
if len(p.eqConds) != 0 {
remainedEqConds := make([]*equalCond, 0, len(p.eqConds))
for _, eq := range p.eqConds {
var attached bool
for path := range pathMap {
if path.attachEqualCond(eq, availablePaths) {
attached = true
break
}
}
if !attached {
remainedEqConds = append(remainedEqConds, eq)
}
}
p.eqConds = remainedEqConds
}
}
func (p *joinPath) nextPath(pathMap map[*joinPath]bool, availablePaths []*joinPath) *joinPath {
cans := p.candidates(pathMap)
if len(cans) == 0 {
var v *joinPath
for v = range pathMap {
log.Errorf("index dep %v, prevs %v\n", v.idxDeps, len(availablePaths))
}
return v
}
indexPath := p.nextIndexPath(cans)
if indexPath != nil {
return indexPath
}
return p.pickPath(cans)
}
func (p *joinPath) candidates(pathMap map[*joinPath]bool) []*joinPath {
var cans []*joinPath
for t := range pathMap {
if len(t.idxDeps) > 0 {
continue
}
cans = append(cans, t)
}
return cans
}
func (p *joinPath) nextIndexPath(candidates []*joinPath) *joinPath {
var best *joinPath
for _, can := range candidates {
// Since we may not have equal conditions attached on the path, we
// need to check neighborCount and idxDepCount to see if this path
// can be joined with index.
neighborIsAvailable := len(can.neighbors) < can.neighborCount
idxDepIsAvailable := can.idxDepCount > 0
if can.hasOuterIdxEqualCond() || neighborIsAvailable || idxDepIsAvailable {
if best == nil {
best = can
}
if can.score() > best.score() {
best = can
}
}
}
return best
}
func (p *joinPath) pickPath(candidates []*joinPath) *joinPath {
var best *joinPath
for _, path := range candidates {
if best == nil {
best = path
}
if path.score() > best.score() {
best = path
}
}
return best
}
// conditionAttachChecker checks if an expression is valid to
// attach to a path. attach is valid only if all the referenced tables in the
// expression are available.
type conditionAttachChecker struct {
targetPath *joinPath
availablePaths []*joinPath
invalid bool
}
func (c *conditionAttachChecker) Enter(in ast.Node) (ast.Node, bool) {
switch x := in.(type) {
case *ast.ColumnNameExpr:
table := x.Refer.TableName
if c.targetPath.containsTable(table) {
return in, false
}
c.invalid = true
for _, path := range c.availablePaths {
if path.containsTable(table) {
c.invalid = false
return in, false
}
}
}
return in, false
}
func (c *conditionAttachChecker) Leave(in ast.Node) (ast.Node, bool) {
return in, !c.invalid
}
func (b *planBuilder) buildJoin(sel *ast.SelectStmt) Plan {
nrfinder := &nullRejectFinder{nullRejectTables: map[*ast.TableName]bool{}}
if sel.Where != nil {
sel.Where.Accept(nrfinder)
}
path := b.buildBasicJoinPath(sel.From.TableRefs, nrfinder.nullRejectTables)
rfs := path.resultFields()
whereConditions := splitWhere(sel.Where)
for _, whereCond := range whereConditions {
if !path.attachCondition(whereCond, nil) {
// TODO: Find a better way to handle this condition.
path.conditions = append(path.conditions, whereCond)
log.Errorf("Failed to attach where condtion.")
}
}
path.extractEqualConditon()
path.addIndexDependency()
path.optimizeJoinOrder(nil)
p := b.buildPlanFromJoinPath(path)
p.SetFields(rfs)
return p
}
type nullRejectFinder struct {
nullRejectTables map[*ast.TableName]bool
}
func (n *nullRejectFinder) Enter(in ast.Node) (ast.Node, bool) {
switch x := in.(type) {
case *ast.BinaryOperationExpr:
if x.Op == opcode.NullEQ || x.Op == opcode.OrOr {
return in, true
}
case *ast.IsNullExpr:
if !x.Not {
return in, true
}
case *ast.IsTruthExpr:
if x.Not {
return in, true
}
}
return in, false
}
func (n *nullRejectFinder) Leave(in ast.Node) (ast.Node, bool) {
switch x := in.(type) {
case *ast.ColumnNameExpr:
n.nullRejectTables[x.Refer.TableName] = true
}
return in, true
}
func (b *planBuilder) buildBasicJoinPath(node ast.ResultSetNode, nullRejectTables map[*ast.TableName]bool) *joinPath {
switch x := node.(type) {
case nil:
return nil
case *ast.Join:
leftPath := b.buildBasicJoinPath(x.Left, nullRejectTables)
if x.Right == nil {
return leftPath
}
righPath := b.buildBasicJoinPath(x.Right, nullRejectTables)
isOuter := b.isOuterJoin(x.Tp, leftPath, righPath, nullRejectTables)
if isOuter {
return newOuterJoinPath(x.Tp == ast.RightJoin, leftPath, righPath, x.On)
}
return newInnerJoinPath(leftPath, righPath, x.On)
case *ast.TableSource:
switch v := x.Source.(type) {
case *ast.TableName:
return newTablePath(v)
case *ast.SelectStmt, *ast.UnionStmt:
return newSubqueryPath(v, x.AsName)
default:
b.err = ErrUnsupportedType.Gen("unsupported table source type %T", x)
return nil
}
default:
b.err = ErrUnsupportedType.Gen("unsupported table source type %T", x)
return nil
}
}
func (b *planBuilder) isOuterJoin(tp ast.JoinType, leftPaths, rightPaths *joinPath,
nullRejectTables map[*ast.TableName]bool) bool {
var innerPath *joinPath
switch tp {
case ast.LeftJoin:
innerPath = rightPaths
case ast.RightJoin:
innerPath = leftPaths
default:
return false
}
for table := range nullRejectTables {
if innerPath.containsTable(table) {
return false
}
}
return true
}
func equivFromExpr(expr ast.ExprNode) *equalCond {
binop, ok := expr.(*ast.BinaryOperationExpr)
if !ok || binop.Op != opcode.EQ {
return nil
}
ln, lOK := binop.L.(*ast.ColumnNameExpr)
rn, rOK := binop.R.(*ast.ColumnNameExpr)
if !lOK || !rOK {
return nil
}
if ln.Name.Table.L == "" || rn.Name.Table.L == "" {
return nil
}
if ln.Name.Schema.L == rn.Name.Schema.L && ln.Name.Table.L == rn.Name.Table.L {
return nil
}
return newEqualCond(ln.Refer, rn.Refer)
}
func (b *planBuilder) buildPlanFromJoinPath(path *joinPath) Plan {
if path.table != nil {
return b.buildTablePlanFromJoinPath(path)
}
if path.subquery != nil {
return b.buildSubqueryJoinPath(path)
}
if path.outer != nil {
join := &JoinOuter{
Outer: b.buildPlanFromJoinPath(path.outer),
Inner: b.buildPlanFromJoinPath(path.inner),
}
if path.rightJoin {
join.SetFields(append(join.Inner.Fields(), join.Outer.Fields()...))
} else {
join.SetFields(append(join.Outer.Fields(), join.Inner.Fields()...))
}
return join
}
join := &JoinInner{}
for _, in := range path.inners {
join.Inners = append(join.Inners, b.buildPlanFromJoinPath(in))
join.fields = append(join.fields, in.resultFields()...)
}
join.Conditions = path.conditions
for _, equiv := range path.eqConds {
cond := &ast.BinaryOperationExpr{L: equiv.left.Expr, R: equiv.right.Expr, Op: opcode.EQ}
join.Conditions = append(join.Conditions, cond)
}
return join
}
func (b *planBuilder) buildTablePlanFromJoinPath(path *joinPath) Plan {
for _, equiv := range path.eqConds {
columnNameExpr := &ast.ColumnNameExpr{}
columnNameExpr.Name = &ast.ColumnName{}
columnNameExpr.Name.Name = equiv.left.Column.Name
columnNameExpr.Name.Table = equiv.left.Table.Name
columnNameExpr.Refer = equiv.left
condition := &ast.BinaryOperationExpr{L: columnNameExpr, R: equiv.right.Expr, Op: opcode.EQ}
ast.SetFlag(condition)
path.conditions = append(path.conditions, condition)
}
candidates := b.buildAllAccessMethodsPlan(path)
var p Plan
var lowestCost float64
for _, can := range candidates {
cost := EstimateCost(can)
if p == nil {
p = can
lowestCost = cost
}
if cost < lowestCost {
p = can
lowestCost = cost
}
}
return p
}
// Build subquery join path plan
func (b *planBuilder) buildSubqueryJoinPath(path *joinPath) Plan {
for _, equiv := range path.eqConds {
columnNameExpr := &ast.ColumnNameExpr{}
columnNameExpr.Name = &ast.ColumnName{}
columnNameExpr.Name.Name = equiv.left.Column.Name
columnNameExpr.Name.Table = equiv.left.Table.Name
columnNameExpr.Refer = equiv.left
condition := &ast.BinaryOperationExpr{L: columnNameExpr, R: equiv.right.Expr, Op: opcode.EQ}
ast.SetFlag(condition)
path.conditions = append(path.conditions, condition)
}
p := b.build(path.subquery)
if len(path.conditions) == 0 {
return p
}
filterPlan := &Filter{Conditions: path.conditions}
filterPlan.SetSrc(p)
filterPlan.SetFields(p.Fields())
return filterPlan
}