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plan.go
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plan.go
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// 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 (
"fmt"
"github.com/juju/errors"
"github.com/pingcap/tidb/ast"
"github.com/pingcap/tidb/expression"
"github.com/pingcap/tidb/sessionctx"
"github.com/pingcap/tidb/util/codec"
tipb "github.com/pingcap/tipb/go-tipb"
)
// Plan is the description of an execution flow.
// It is created from ast.Node first, then optimized by the optimizer,
// finally used by the executor to create a Cursor which executes the statement.
type Plan interface {
// Get the schema.
Schema() *expression.Schema
// Get the ID.
ID() int
// Get the ID in explain statement
ExplainID() string
// replaceExprColumns replace all the column reference in the plan's expression node.
replaceExprColumns(replace map[string]*expression.Column)
context() sessionctx.Context
// StatsInfo will return the StatsInfo for this plan.
StatsInfo() *StatsInfo
}
// taskType is the type of execution task.
type taskType int
const (
rootTaskType taskType = iota
copSingleReadTaskType // TableScan and IndexScan
copDoubleReadTaskType // IndexLookUp
)
// String implements fmt.Stringer interface.
func (t taskType) String() string {
switch t {
case rootTaskType:
return "rootTask"
case copSingleReadTaskType:
return "copSingleReadTask"
case copDoubleReadTaskType:
return "copDoubleReadTask"
}
return "UnknownTaskType"
}
// requiredProp stands for the required physical property by parents.
// It contains the orders, if the order is desc and the task types.
type requiredProp struct {
cols []*expression.Column
desc bool
// taskTp means the type of task that an operator requires.
// It needs to be specified because two different tasks can't be compared with cost directly.
// e.g. If a copTask takes less cost than a rootTask, we can't sure that we must choose the former one. Because the copTask
// must be finished and increase its cost in sometime, but we can't make sure the finishing time. So the best way
// to let the comparison fair is to add taskType to required property.
taskTp taskType
// expectedCnt means this operator may be closed after fetching expectedCnt records.
expectedCnt float64
// hashcode stores the hash code of a requiredProp, will be lazily calculated when function "hashCode()" being called.
hashcode []byte
}
func (p *requiredProp) allColsFromSchema(schema *expression.Schema) bool {
return schema.ColumnsIndices(p.cols) != nil
}
func (p *requiredProp) isPrefix(prop *requiredProp) bool {
if len(p.cols) > len(prop.cols) || p.desc != prop.desc {
return false
}
for i := range p.cols {
if !p.cols[i].Equal(nil, prop.cols[i]) {
return false
}
}
return true
}
// Check if this prop's columns can match by items totally.
func (p *requiredProp) matchItems(items []*ByItems) bool {
if len(items) < len(p.cols) {
return false
}
for i, col := range p.cols {
sortItem := items[i]
if sortItem.Desc != p.desc || !sortItem.Expr.Equal(nil, col) {
return false
}
}
return true
}
func (p *requiredProp) isEmpty() bool {
return len(p.cols) == 0
}
// hashCode calculates hash code for a requiredProp object.
func (p *requiredProp) hashCode() []byte {
if p.hashcode != nil {
return p.hashcode
}
hashcodeSize := 8 + 8 + 8 + 16*len(p.cols)
p.hashcode = make([]byte, 0, hashcodeSize)
if p.desc {
p.hashcode = codec.EncodeInt(p.hashcode, 1)
} else {
p.hashcode = codec.EncodeInt(p.hashcode, 0)
}
p.hashcode = codec.EncodeInt(p.hashcode, int64(p.taskTp))
p.hashcode = codec.EncodeFloat(p.hashcode, p.expectedCnt)
for i, length := 0, len(p.cols); i < length; i++ {
p.hashcode = append(p.hashcode, p.cols[i].HashCode(nil)...)
}
return p.hashcode
}
// String implements fmt.Stringer interface. Just for test.
func (p *requiredProp) String() string {
return fmt.Sprintf("Prop{cols: %s, desc: %v, taskTp: %s, expectedCount: %v}", p.cols, p.desc, p.taskTp, p.expectedCnt)
}
// LogicalPlan is a tree of logical operators.
// We can do a lot of logical optimizations to it, like predicate pushdown and column pruning.
type LogicalPlan interface {
Plan
// PredicatePushDown pushes down the predicates in the where/on/having clauses as deeply as possible.
// It will accept a predicate that is an expression slice, and return the expressions that can't be pushed.
// Because it might change the root if the having clause exists, we need to return a plan that represents a new root.
PredicatePushDown([]expression.Expression) ([]expression.Expression, LogicalPlan)
// PruneColumns prunes the unused columns.
PruneColumns([]*expression.Column)
// findBestTask converts the logical plan to the physical plan. It's a new interface.
// It is called recursively from the parent to the children to create the result physical plan.
// Some logical plans will convert the children to the physical plans in different ways, and return the one
// with the lowest cost.
findBestTask(prop *requiredProp) (task, error)
// buildKeyInfo will collect the information of unique keys into schema.
buildKeyInfo()
// pushDownTopN will push down the topN or limit operator during logical optimization.
pushDownTopN(topN *LogicalTopN) LogicalPlan
// deriveStats derives statistic info between plans.
deriveStats() (*StatsInfo, error)
// preparePossibleProperties is only used for join and aggregation. Like group by a,b,c, all permutation of (a,b,c) is
// valid, but the ordered indices in leaf plan is limited. So we can get all possible order properties by a pre-walking.
// Please make sure that children's method is called though we may not need its return value,
// so we can prepare possible properties for every LogicalPlan node.
preparePossibleProperties() [][]*expression.Column
// exhaustPhysicalPlans generates all possible plans that can match the required property.
exhaustPhysicalPlans(*requiredProp) []PhysicalPlan
extractCorrelatedCols() []*expression.CorrelatedColumn
// MaxOneRow means whether this operator only returns max one row.
MaxOneRow() bool
// findColumn finds the column in basePlan's schema.
// If the column is not in the schema, returns an error.
findColumn(*ast.ColumnName) (*expression.Column, int, error)
// Get all the children.
Children() []LogicalPlan
// SetChildren sets the children for the plan.
SetChildren(...LogicalPlan)
}
// PhysicalPlan is a tree of the physical operators.
type PhysicalPlan interface {
Plan
// attach2Task makes the current physical plan as the father of task's physicalPlan and updates the cost of
// current task. If the child's task is cop task, some operator may close this task and return a new rootTask.
attach2Task(...task) task
// ToPB converts physical plan to tipb executor.
ToPB(ctx sessionctx.Context) (*tipb.Executor, error)
// ExplainInfo returns operator information to be explained.
ExplainInfo() string
// getChildReqProps gets the required property by child index.
getChildReqProps(idx int) *requiredProp
// Get all the children.
Children() []PhysicalPlan
// SetChildren sets the children for the plan.
SetChildren(...PhysicalPlan)
// ResolveIndices resolves the indices for columns. After doing this, the columns can evaluate the rows by their indices.
ResolveIndices()
}
type baseLogicalPlan struct {
basePlan
taskMap map[string]task
self LogicalPlan
maxOneRow bool
children []LogicalPlan
}
func (p *baseLogicalPlan) MaxOneRow() bool {
return p.maxOneRow
}
type basePhysicalPlan struct {
basePlan
childrenReqProps []*requiredProp
self PhysicalPlan
children []PhysicalPlan
}
func (p *basePhysicalPlan) getChildReqProps(idx int) *requiredProp {
return p.childrenReqProps[idx]
}
// ExplainInfo implements PhysicalPlan interface.
func (p *basePhysicalPlan) ExplainInfo() string {
return ""
}
func (p *baseLogicalPlan) getTask(prop *requiredProp) task {
key := prop.hashCode()
return p.taskMap[string(key)]
}
func (p *baseLogicalPlan) storeTask(prop *requiredProp, task task) {
key := prop.hashCode()
p.taskMap[string(key)] = task
}
func (p *baseLogicalPlan) buildKeyInfo() {
for _, child := range p.children {
child.buildKeyInfo()
}
switch p.self.(type) {
case *LogicalLock, *LogicalLimit, *LogicalSort, *LogicalSelection, *LogicalApply, *LogicalProjection:
p.maxOneRow = p.children[0].MaxOneRow()
case *LogicalMaxOneRow, *LogicalExists:
p.maxOneRow = true
}
}
// StatsInfo implements the Plan.StatsInfo interface.
func (p *DataSource) StatsInfo() *StatsInfo {
return p.statsAfterSelect
}
func newBasePlan(ctx sessionctx.Context, tp string) basePlan {
ctx.GetSessionVars().PlanID++
id := ctx.GetSessionVars().PlanID
return basePlan{
tp: tp,
id: id,
ctx: ctx,
}
}
func newBaseLogicalPlan(ctx sessionctx.Context, tp string, self LogicalPlan) baseLogicalPlan {
return baseLogicalPlan{
taskMap: make(map[string]task),
basePlan: newBasePlan(ctx, tp),
self: self,
}
}
func newBasePhysicalPlan(ctx sessionctx.Context, tp string, self PhysicalPlan) basePhysicalPlan {
return basePhysicalPlan{
basePlan: newBasePlan(ctx, tp),
self: self,
}
}
func (p *baseLogicalPlan) extractCorrelatedCols() []*expression.CorrelatedColumn {
corCols := make([]*expression.CorrelatedColumn, 0, len(p.children))
for _, child := range p.children {
corCols = append(corCols, child.extractCorrelatedCols()...)
}
return corCols
}
// PruneColumns implements LogicalPlan interface.
func (p *baseLogicalPlan) PruneColumns(parentUsedCols []*expression.Column) {
if len(p.children) == 0 {
return
}
p.children[0].PruneColumns(parentUsedCols)
}
// basePlan implements base Plan interface.
// Should be used as embedded struct in Plan implementations.
type basePlan struct {
tp string
id int
ctx sessionctx.Context
stats *StatsInfo
}
func (p *basePlan) replaceExprColumns(replace map[string]*expression.Column) {
}
// ID implements Plan ID interface.
func (p *basePlan) ID() int {
return p.id
}
func (p *basePlan) ExplainID() string {
return fmt.Sprintf("%s_%d", p.tp, p.id)
}
// Schema implements Plan Schema interface.
func (p *baseLogicalPlan) Schema() *expression.Schema {
return p.children[0].Schema()
}
// Schema implements Plan Schema interface.
func (p *basePhysicalPlan) Schema() *expression.Schema {
return p.children[0].Schema()
}
// Children implements LogicalPlan Children interface.
func (p *baseLogicalPlan) Children() []LogicalPlan {
return p.children
}
// Children implements PhysicalPlan Children interface.
func (p *basePhysicalPlan) Children() []PhysicalPlan {
return p.children
}
// SetChildren implements LogicalPlan SetChildren interface.
func (p *baseLogicalPlan) SetChildren(children ...LogicalPlan) {
p.children = children
}
// SetChildren implements PhysicalPlan SetChildren interface.
func (p *basePhysicalPlan) SetChildren(children ...PhysicalPlan) {
p.children = children
}
func (p *basePlan) context() sessionctx.Context {
return p.ctx
}
func (p *baseLogicalPlan) findColumn(column *ast.ColumnName) (*expression.Column, int, error) {
col, idx, err := p.self.Schema().FindColumnAndIndex(column)
if err == nil && col == nil {
err = errors.Errorf("column %s not found", column.Name.O)
}
return col, idx, errors.Trace(err)
}