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coprocessor.go
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coprocessor.go
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// Copyright 2016 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 tikv
import (
"bytes"
"fmt"
"io"
"sort"
"strings"
"sync"
"sync/atomic"
"time"
"github.com/juju/errors"
"github.com/opentracing/opentracing-go"
"github.com/pingcap/kvproto/pkg/coprocessor"
"github.com/pingcap/kvproto/pkg/kvrpcpb"
"github.com/pingcap/tidb/kv"
"github.com/pingcap/tidb/metrics"
"github.com/pingcap/tidb/store/tikv/tikvrpc"
"github.com/pingcap/tidb/util/goroutine_pool"
tipb "github.com/pingcap/tipb/go-tipb"
log "github.com/sirupsen/logrus"
"golang.org/x/net/context"
)
var copIteratorGP = gp.New(time.Minute)
// CopClient is coprocessor client.
type CopClient struct {
store *tikvStore
}
// IsRequestTypeSupported checks whether reqType is supported.
func (c *CopClient) IsRequestTypeSupported(reqType, subType int64) bool {
switch reqType {
case kv.ReqTypeSelect, kv.ReqTypeIndex:
switch subType {
case kv.ReqSubTypeGroupBy, kv.ReqSubTypeBasic, kv.ReqSubTypeTopN:
return true
default:
return c.supportExpr(tipb.ExprType(subType))
}
case kv.ReqTypeDAG:
return c.supportExpr(tipb.ExprType(subType))
case kv.ReqTypeAnalyze:
return true
}
return false
}
func (c *CopClient) supportExpr(exprType tipb.ExprType) bool {
switch exprType {
case tipb.ExprType_Null, tipb.ExprType_Int64, tipb.ExprType_Uint64, tipb.ExprType_String, tipb.ExprType_Bytes,
tipb.ExprType_MysqlDuration, tipb.ExprType_MysqlTime, tipb.ExprType_MysqlDecimal,
tipb.ExprType_Float32, tipb.ExprType_Float64, tipb.ExprType_ColumnRef:
return true
// logic operators.
case tipb.ExprType_And, tipb.ExprType_Or, tipb.ExprType_Not:
return true
// compare operators.
case tipb.ExprType_LT, tipb.ExprType_LE, tipb.ExprType_EQ, tipb.ExprType_NE,
tipb.ExprType_GE, tipb.ExprType_GT, tipb.ExprType_NullEQ,
tipb.ExprType_In, tipb.ExprType_ValueList, tipb.ExprType_IsNull,
tipb.ExprType_Like:
return true
// arithmetic operators.
case tipb.ExprType_Plus, tipb.ExprType_Div, tipb.ExprType_Minus, tipb.ExprType_Mul:
return true
// control functions
case tipb.ExprType_Case, tipb.ExprType_If, tipb.ExprType_IfNull, tipb.ExprType_Coalesce:
return true
// aggregate functions.
case tipb.ExprType_Count, tipb.ExprType_First, tipb.ExprType_Max, tipb.ExprType_Min, tipb.ExprType_Sum, tipb.ExprType_Avg,
tipb.ExprType_Agg_BitXor, tipb.ExprType_Agg_BitAnd, tipb.ExprType_Agg_BitOr:
return true
// json functions.
case tipb.ExprType_JsonType, tipb.ExprType_JsonExtract, tipb.ExprType_JsonUnquote,
tipb.ExprType_JsonObject, tipb.ExprType_JsonArray, tipb.ExprType_JsonMerge,
tipb.ExprType_JsonSet, tipb.ExprType_JsonInsert, tipb.ExprType_JsonReplace, tipb.ExprType_JsonRemove:
return true
// date functions.
case tipb.ExprType_DateFormat:
return true
case kv.ReqSubTypeDesc:
return true
case kv.ReqSubTypeSignature:
return true
default:
return false
}
}
// Send builds the request and gets the coprocessor iterator response.
func (c *CopClient) Send(ctx context.Context, req *kv.Request) kv.Response {
metrics.TiKVCoprocessorCounter.WithLabelValues("send").Inc()
bo := NewBackoffer(ctx, copBuildTaskMaxBackoff)
tasks, err := buildCopTasks(bo, c.store.regionCache, &copRanges{mid: req.KeyRanges}, req.Desc, req.Streaming)
if err != nil {
return copErrorResponse{err}
}
it := &copIterator{
store: c.store,
req: req,
concurrency: req.Concurrency,
finishCh: make(chan struct{}),
}
it.tasks = tasks
if it.concurrency > len(tasks) {
it.concurrency = len(tasks)
}
if it.concurrency < 1 {
// Make sure that there is at least one worker.
it.concurrency = 1
}
if !it.req.KeepOrder {
it.respChan = make(chan copResponse, it.concurrency)
}
it.open(ctx)
return it
}
// copTask contains a related Region and KeyRange for a kv.Request.
type copTask struct {
region RegionVerID
ranges *copRanges
respChan chan copResponse
storeAddr string
cmdType tikvrpc.CmdType
}
func (r *copTask) String() string {
return fmt.Sprintf("region(%d %d %d) ranges(%d) store(%s)",
r.region.id, r.region.confVer, r.region.ver, r.ranges.len(), r.storeAddr)
}
// copRanges is like []kv.KeyRange, but may has extra elements at head/tail.
// It's for avoiding alloc big slice during build copTask.
type copRanges struct {
first *kv.KeyRange
mid []kv.KeyRange
last *kv.KeyRange
}
func (r *copRanges) String() string {
var s string
r.do(func(ran *kv.KeyRange) {
s += fmt.Sprintf("[%q, %q]", ran.StartKey, ran.EndKey)
})
return s
}
func (r *copRanges) len() int {
var l int
if r.first != nil {
l++
}
l += len(r.mid)
if r.last != nil {
l++
}
return l
}
func (r *copRanges) at(i int) kv.KeyRange {
if r.first != nil {
if i == 0 {
return *r.first
}
i--
}
if i < len(r.mid) {
return r.mid[i]
}
return *r.last
}
func (r *copRanges) slice(from, to int) *copRanges {
var ran copRanges
if r.first != nil {
if from == 0 && to > 0 {
ran.first = r.first
}
if from > 0 {
from--
}
if to > 0 {
to--
}
}
if to <= len(r.mid) {
ran.mid = r.mid[from:to]
} else {
if from <= len(r.mid) {
ran.mid = r.mid[from:]
}
if from < to {
ran.last = r.last
}
}
return &ran
}
func (r *copRanges) do(f func(ran *kv.KeyRange)) {
if r.first != nil {
f(r.first)
}
for _, ran := range r.mid {
f(&ran)
}
if r.last != nil {
f(r.last)
}
}
func (r *copRanges) toPBRanges() []*coprocessor.KeyRange {
ranges := make([]*coprocessor.KeyRange, 0, r.len())
r.do(func(ran *kv.KeyRange) {
ranges = append(ranges, &coprocessor.KeyRange{
Start: ran.StartKey,
End: ran.EndKey,
})
})
return ranges
}
// Split ranges into (left, right) by key.
func (r *copRanges) split(key []byte) (*copRanges, *copRanges) {
n := sort.Search(r.len(), func(i int) bool {
cur := r.at(i)
return len(cur.EndKey) == 0 || bytes.Compare(cur.EndKey, key) > 0
})
// If a range p contains the key, it will split to 2 parts.
if n < r.len() {
p := r.at(n)
if bytes.Compare(key, p.StartKey) > 0 {
left := r.slice(0, n)
left.last = &kv.KeyRange{StartKey: p.StartKey, EndKey: key}
right := r.slice(n+1, r.len())
right.first = &kv.KeyRange{StartKey: key, EndKey: p.EndKey}
return left, right
}
}
return r.slice(0, n), r.slice(n, r.len())
}
func buildCopTasks(bo *Backoffer, cache *RegionCache, ranges *copRanges, desc bool, streaming bool) ([]*copTask, error) {
metrics.TiKVCoprocessorCounter.WithLabelValues("build_task").Inc()
start := time.Now()
rangesLen := ranges.len()
cmdType := tikvrpc.CmdCop
if streaming {
cmdType = tikvrpc.CmdCopStream
}
var tasks []*copTask
appendTask := func(region RegionVerID, ranges *copRanges) {
tasks = append(tasks, &copTask{
region: region,
ranges: ranges,
respChan: make(chan copResponse, 1),
cmdType: cmdType,
})
}
err := splitRanges(bo, cache, ranges, appendTask)
if err != nil {
return nil, errors.Trace(err)
}
if desc {
reverseTasks(tasks)
}
if elapsed := time.Since(start); elapsed > time.Millisecond*500 {
log.Warnf("buildCopTasks takes too much time (%v), range len %v, task len %v", elapsed, rangesLen, len(tasks))
}
metrics.TiKVTxnRegionsNumHistogram.WithLabelValues("coprocessor").Observe(float64(len(tasks)))
return tasks, nil
}
func splitRanges(bo *Backoffer, cache *RegionCache, ranges *copRanges, fn func(region RegionVerID, ranges *copRanges)) error {
for ranges.len() > 0 {
loc, err := cache.LocateKey(bo, ranges.at(0).StartKey)
if err != nil {
return errors.Trace(err)
}
// Iterate to the first range that is not complete in the region.
var i int
for ; i < ranges.len(); i++ {
r := ranges.at(i)
if !(loc.Contains(r.EndKey) || bytes.Equal(loc.EndKey, r.EndKey)) {
break
}
}
// All rest ranges belong to the same region.
if i == ranges.len() {
fn(loc.Region, ranges)
break
}
r := ranges.at(i)
if loc.Contains(r.StartKey) {
// Part of r is not in the region. We need to split it.
taskRanges := ranges.slice(0, i)
taskRanges.last = &kv.KeyRange{
StartKey: r.StartKey,
EndKey: loc.EndKey,
}
fn(loc.Region, taskRanges)
ranges = ranges.slice(i+1, ranges.len())
ranges.first = &kv.KeyRange{
StartKey: loc.EndKey,
EndKey: r.EndKey,
}
} else {
// rs[i] is not in the region.
taskRanges := ranges.slice(0, i)
fn(loc.Region, taskRanges)
ranges = ranges.slice(i, ranges.len())
}
}
return nil
}
// SplitRegionRanges get the split ranges from pd region.
func SplitRegionRanges(bo *Backoffer, cache *RegionCache, keyRanges []kv.KeyRange) ([]kv.KeyRange, error) {
ranges := copRanges{mid: keyRanges}
var ret []kv.KeyRange
appendRange := func(region RegionVerID, ranges *copRanges) {
for i := 0; i < ranges.len(); i++ {
ret = append(ret, ranges.at(i))
}
}
err := splitRanges(bo, cache, &ranges, appendRange)
if err != nil {
return nil, errors.Trace(err)
}
return ret, nil
}
func reverseTasks(tasks []*copTask) {
for i := 0; i < len(tasks)/2; i++ {
j := len(tasks) - i - 1
tasks[i], tasks[j] = tasks[j], tasks[i]
}
}
type copIterator struct {
store *tikvStore
req *kv.Request
concurrency int
finishCh chan struct{}
// There are two cases we need to close the `finishCh` channel, one is when context is done, the other one is
// when the Close is called. we use atomic.CompareAndSwap `closed` to to make sure the channel is not closed twice.
closed uint32
// If keepOrder, results are stored in copTask.respChan, read them out one by one.
tasks []*copTask
curr int
// Otherwise, results are stored in respChan.
respChan chan copResponse
wg sync.WaitGroup
}
// copIteratorWorker receives tasks from copIteratorTaskSender, handles tasks and sends the copResponse to respChan.
type copIteratorWorker struct {
taskCh <-chan *copTask
wg *sync.WaitGroup
store *tikvStore
req *kv.Request
respChan chan<- copResponse
finishCh <-chan struct{}
}
// copIteratorTaskSender sends tasks to taskCh then wait for the workers to exit.
type copIteratorTaskSender struct {
taskCh chan<- *copTask
wg *sync.WaitGroup
tasks []*copTask
finishCh <-chan struct{}
respChan chan<- copResponse
}
type copResponse struct {
*coprocessor.Response
startKey kv.Key
err error
}
const minLogCopTaskTime = 300 * time.Millisecond
// run is a worker function that get a copTask from channel, handle it and
// send the result back.
func (worker *copIteratorWorker) run(ctx context.Context) {
span, ctx1 := opentracing.StartSpanFromContext(ctx, "copIteratorWorker.run")
defer span.Finish()
defer worker.wg.Done()
for task := range worker.taskCh {
respCh := worker.respChan
if respCh == nil {
respCh = task.respChan
}
bo := NewBackoffer(ctx1, copNextMaxBackoff)
worker.handleTask(bo, task, respCh)
if bo.totalSleep > 0 {
metrics.TiKVBackoffHistogram.Observe(float64(bo.totalSleep) / 1000)
}
close(task.respChan)
select {
case <-worker.finishCh:
return
default:
}
}
}
// open starts workers and sender goroutines.
func (it *copIterator) open(ctx context.Context) {
taskCh := make(chan *copTask, 1)
it.wg.Add(it.concurrency)
// Start it.concurrency number of workers to handle cop requests.
for i := 0; i < it.concurrency; i++ {
worker := &copIteratorWorker{
taskCh: taskCh,
wg: &it.wg,
store: it.store,
req: it.req,
respChan: it.respChan,
finishCh: it.finishCh,
}
copIteratorGP.Go(func() {
worker.run(ctx)
})
}
taskSender := &copIteratorTaskSender{
taskCh: taskCh,
wg: &it.wg,
tasks: it.tasks,
finishCh: it.finishCh,
}
taskSender.respChan = it.respChan
copIteratorGP.Go(taskSender.run)
}
func (sender *copIteratorTaskSender) run() {
// Send tasks to feed the worker goroutines.
for _, t := range sender.tasks {
exit := sender.sendToTaskCh(t)
if exit {
break
}
}
close(sender.taskCh)
// Wait for worker goroutines to exit.
sender.wg.Wait()
if sender.respChan != nil {
close(sender.respChan)
}
}
func (it *copIterator) recvFromRespCh(ctx context.Context, respCh <-chan copResponse) (resp copResponse, ok bool, exit bool) {
select {
case resp, ok = <-respCh:
case <-it.finishCh:
exit = true
case <-ctx.Done():
// We select the ctx.Done() in the thread of `Next` instead of in the worker to avoid the cost of `WithCancel`.
if atomic.CompareAndSwapUint32(&it.closed, 0, 1) {
close(it.finishCh)
}
exit = true
}
return
}
func (sender *copIteratorTaskSender) sendToTaskCh(t *copTask) (exit bool) {
select {
case sender.taskCh <- t:
case <-sender.finishCh:
exit = true
}
return
}
func (worker *copIteratorWorker) sendToRespCh(resp copResponse, respCh chan<- copResponse) (exit bool) {
select {
case respCh <- resp:
case <-worker.finishCh:
exit = true
}
return
}
// copResultSubset implements the kv.ResultSubset interface.
type copResultSubset struct {
data []byte
startKey kv.Key
}
// GetData implements the kv.ResultSubset GetData interface.
func (rs *copResultSubset) GetData() []byte {
return rs.data
}
// GetStartKey implements the kv.ResultSubset GetStartKey interface.
func (rs *copResultSubset) GetStartKey() kv.Key {
return rs.startKey
}
// Next returns next coprocessor result.
// NOTE: Use nil to indicate finish, so if the returned ResultSubset is not nil, reader should continue to call Next().
func (it *copIterator) Next(ctx context.Context) (kv.ResultSubset, error) {
metrics.TiKVCoprocessorCounter.WithLabelValues("next").Inc()
var (
resp copResponse
ok bool
closed bool
)
// If data order matters, response should be returned in the same order as copTask slice.
// Otherwise all responses are returned from a single channel.
if it.respChan != nil {
// Get next fetched resp from chan
resp, ok, closed = it.recvFromRespCh(ctx, it.respChan)
if !ok || closed {
return nil, nil
}
} else {
for {
if it.curr >= len(it.tasks) {
// Resp will be nil if iterator is finishCh.
return nil, nil
}
task := it.tasks[it.curr]
resp, ok, closed = it.recvFromRespCh(ctx, task.respChan)
if closed {
// Close() is already called, so Next() is invalid.
return nil, nil
}
if ok {
break
}
// Switch to next task.
it.tasks[it.curr] = nil
it.curr++
}
}
if resp.err != nil {
return nil, errors.Trace(resp.err)
}
err := it.store.CheckVisibility(it.req.StartTs)
if err != nil {
return nil, errors.Trace(err)
}
if resp.Data == nil {
return &copResultSubset{}, nil
}
return &copResultSubset{data: resp.Data, startKey: resp.startKey}, nil
}
// handleTask handles single copTask, sends the result to channel, retry automatically on error.
func (worker *copIteratorWorker) handleTask(bo *Backoffer, task *copTask, respCh chan<- copResponse) {
remainTasks := []*copTask{task}
for len(remainTasks) > 0 {
tasks, err := worker.handleTaskOnce(bo, remainTasks[0], respCh)
if err != nil {
resp := copResponse{err: errors.Trace(err)}
worker.sendToRespCh(resp, respCh)
return
}
if len(tasks) > 0 {
remainTasks = append(tasks, remainTasks[1:]...)
} else {
remainTasks = remainTasks[1:]
}
}
}
// handleTaskOnce handles single copTask, successful results are send to channel.
// If error happened, returns error. If region split or meet lock, returns the remain tasks.
func (worker *copIteratorWorker) handleTaskOnce(bo *Backoffer, task *copTask, ch chan<- copResponse) ([]*copTask, error) {
// gofail: var handleTaskOnceError bool
// if handleTaskOnceError {
// return nil, errors.New("mock handleTaskOnce error")
// }
sender := NewRegionRequestSender(worker.store.regionCache, worker.store.client)
req := &tikvrpc.Request{
Type: task.cmdType,
Cop: &coprocessor.Request{
Tp: worker.req.Tp,
Data: worker.req.Data,
Ranges: task.ranges.toPBRanges(),
},
Context: kvrpcpb.Context{
IsolationLevel: pbIsolationLevel(worker.req.IsolationLevel),
Priority: kvPriorityToCommandPri(worker.req.Priority),
NotFillCache: worker.req.NotFillCache,
HandleTime: true,
},
}
startTime := time.Now()
resp, err := sender.SendReq(bo, req, task.region, ReadTimeoutMedium)
if err != nil {
return nil, errors.Trace(err)
}
// Set task.storeAddr field so its task.String() method have the store address information.
task.storeAddr = sender.storeAddr
costTime := time.Since(startTime)
if costTime > minLogCopTaskTime {
worker.logTimeCopTask(costTime, task, bo, resp)
}
metrics.TiKVCoprocessorCounter.WithLabelValues("handle_task").Inc()
metrics.TiKVCoprocessorHistogram.Observe(costTime.Seconds())
if task.cmdType == tikvrpc.CmdCopStream {
return worker.handleCopStreamResult(bo, resp.CopStream, task, ch)
}
// Handles the response for non-streaming copTask.
return worker.handleCopResponse(bo, resp.Cop, task, ch, nil)
}
const (
minLogBackoffTime = 100
minLogKVProcessTime = 100
minLogKVWaitTime = 200
)
func (worker *copIteratorWorker) logTimeCopTask(costTime time.Duration, task *copTask, bo *Backoffer, resp *tikvrpc.Response) {
logStr := fmt.Sprintf("[TIME_COP_PROCESS] resp_time:%s txn_start_ts:%d region_id:%d store_addr:%s", costTime, worker.req.StartTs, task.region.id, task.storeAddr)
if bo.totalSleep > minLogBackoffTime {
backoffTypes := strings.Replace(fmt.Sprintf("%v", bo.types), " ", ",", -1)
logStr += fmt.Sprintf(" backoff_ms:%d backoff_types:%s", bo.totalSleep, backoffTypes)
}
var detail *kvrpcpb.ExecDetails
if resp.Cop != nil {
detail = resp.Cop.ExecDetails
} else if resp.CopStream != nil {
detail = resp.CopStream.ExecDetails
}
if detail != nil && detail.HandleTime != nil {
processMs := detail.HandleTime.ProcessMs
waitMs := detail.HandleTime.WaitMs
if processMs > minLogKVProcessTime {
logStr += fmt.Sprintf(" kv_process_ms:%d", processMs)
if detail.ScanDetail != nil {
logStr = appendScanDetail(logStr, "write", detail.ScanDetail.Write)
logStr = appendScanDetail(logStr, "data", detail.ScanDetail.Data)
logStr = appendScanDetail(logStr, "lock", detail.ScanDetail.Lock)
}
}
if waitMs > minLogKVWaitTime {
logStr += fmt.Sprintf(" kv_wait_ms:%d", waitMs)
if processMs <= minLogKVProcessTime {
logStr = strings.Replace(logStr, "TIME_COP_PROCESS", "TIME_COP_WAIT", 1)
}
}
}
log.Info(logStr)
}
func appendScanDetail(logStr string, columnFamily string, scanInfo *kvrpcpb.ScanInfo) string {
if scanInfo != nil {
logStr += fmt.Sprintf(" scan_total_%s:%d", columnFamily, scanInfo.Total)
logStr += fmt.Sprintf(" scan_processed_%s:%d", columnFamily, scanInfo.Processed)
}
return logStr
}
func (worker *copIteratorWorker) handleCopStreamResult(bo *Backoffer, stream *tikvrpc.CopStreamResponse, task *copTask, ch chan<- copResponse) ([]*copTask, error) {
defer stream.Close()
var resp *coprocessor.Response
var lastRange *coprocessor.KeyRange
resp = stream.Response
if resp == nil {
// streaming request returns io.EOF, so the first Response is nil.
return nil, nil
}
for {
remainedTasks, err := worker.handleCopResponse(bo, resp, task, ch, lastRange)
if err != nil || len(remainedTasks) != 0 {
return remainedTasks, errors.Trace(err)
}
resp, err = stream.Recv()
if err != nil {
if errors.Cause(err) == io.EOF {
return nil, nil
}
if err1 := bo.Backoff(boTiKVRPC, errors.Errorf("recv stream response error: %v, task: %s", err, task)); err1 != nil {
return nil, errors.Trace(err)
}
// No coprocessor.Response for network error, rebuild task based on the last success one.
log.Info("stream recv timeout:", err)
return worker.buildCopTasksFromRemain(bo, lastRange, task)
}
lastRange = resp.Range
}
}
// handleCopResponse checks coprocessor Response for region split and lock,
// returns more tasks when that happens, or handles the response if no error.
// if we're handling streaming coprocessor response, lastRange is the range of last
// successful response, otherwise it's nil.
func (worker *copIteratorWorker) handleCopResponse(bo *Backoffer, resp *coprocessor.Response, task *copTask, ch chan<- copResponse, lastRange *coprocessor.KeyRange) ([]*copTask, error) {
if regionErr := resp.GetRegionError(); regionErr != nil {
if err := bo.Backoff(BoRegionMiss, errors.New(regionErr.String())); err != nil {
return nil, errors.Trace(err)
}
// We may meet RegionError at the first packet, but not during visiting the stream.
metrics.TiKVCoprocessorCounter.WithLabelValues("rebuild_task").Inc()
return buildCopTasks(bo, worker.store.regionCache, task.ranges, worker.req.Desc, worker.req.Streaming)
}
if lockErr := resp.GetLocked(); lockErr != nil {
log.Debugf("coprocessor encounters lock: %v", lockErr)
ok, err1 := worker.store.lockResolver.ResolveLocks(bo, []*Lock{NewLock(lockErr)})
if err1 != nil {
return nil, errors.Trace(err1)
}
if !ok {
if err := bo.Backoff(boTxnLockFast, errors.New(lockErr.String())); err != nil {
return nil, errors.Trace(err)
}
}
return worker.buildCopTasksFromRemain(bo, lastRange, task)
}
if otherErr := resp.GetOtherError(); otherErr != "" {
err := errors.Errorf("other error: %s", otherErr)
log.Warnf("coprocessor err: %v", err)
return nil, errors.Trace(err)
}
var startKey kv.Key
// When the request is using streaming API, the `Range` is not nil.
if resp.Range != nil {
startKey = resp.Range.Start
} else {
startKey = task.ranges.at(0).StartKey
}
worker.sendToRespCh(copResponse{resp, startKey, nil}, ch)
return nil, nil
}
func (worker *copIteratorWorker) buildCopTasksFromRemain(bo *Backoffer, lastRange *coprocessor.KeyRange, task *copTask) ([]*copTask, error) {
remainedRanges := task.ranges
if worker.req.Streaming && lastRange != nil {
remainedRanges = worker.calculateRemain(task.ranges, lastRange, worker.req.Desc)
}
return buildCopTasks(bo, worker.store.regionCache, remainedRanges, worker.req.Desc, worker.req.Streaming)
}
// calculateRemain splits the input ranges into two, and take one of them according to desc flag.
// It's used in streaming API, to calculate which range is consumed and what needs to be retry.
// For example:
// ranges: [r1 --> r2) [r3 --> r4)
// split: [s1 --> s2)
// In normal scan order, all data before s1 is consumed, so the remain ranges should be [s1 --> r2) [r3 --> r4)
// In reverse scan order, all data after s2 is consumed, so the remain ranges should be [r1 --> r2) [r3 --> s2)
func (worker *copIteratorWorker) calculateRemain(ranges *copRanges, split *coprocessor.KeyRange, desc bool) *copRanges {
if desc {
left, _ := ranges.split(split.End)
return left
}
_, right := ranges.split(split.Start)
return right
}
func (it *copIterator) Close() error {
if atomic.CompareAndSwapUint32(&it.closed, 0, 1) {
close(it.finishCh)
}
it.wg.Wait()
return nil
}
// copErrorResponse returns error when calling Next()
type copErrorResponse struct{ error }
func (it copErrorResponse) Next(ctx context.Context) (kv.ResultSubset, error) {
return nil, it.error
}
func (it copErrorResponse) Close() error {
return nil
}