frostfs-node/pkg/services/tree/sync.go

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package tree
import (
"context"
"crypto/sha256"
"errors"
"fmt"
"io"
"math"
"math/rand"
"sync"
"git.frostfs.info/TrueCloudLab/frostfs-api-go/v2/pkg/tracing"
"git.frostfs.info/TrueCloudLab/frostfs-node/internal/logs"
"git.frostfs.info/TrueCloudLab/frostfs-node/pkg/local_object_storage/pilorama"
"git.frostfs.info/TrueCloudLab/frostfs-node/pkg/morph/client/netmap"
"git.frostfs.info/TrueCloudLab/frostfs-node/pkg/network"
cid "git.frostfs.info/TrueCloudLab/frostfs-sdk-go/container/id"
netmapSDK "git.frostfs.info/TrueCloudLab/frostfs-sdk-go/netmap"
"github.com/panjf2000/ants/v2"
"go.uber.org/zap"
"golang.org/x/sync/errgroup"
"google.golang.org/grpc"
"google.golang.org/grpc/credentials/insecure"
)
// ErrNotInContainer is returned when operation could not be performed
// because the node is not included in the container.
var ErrNotInContainer = errors.New("node is not in container")
const defaultSyncWorkerCount = 20
// synchronizeAllTrees synchronizes all the trees of the container. It fetches
// tree IDs from the other container nodes. Returns ErrNotInContainer if the node
// is not included in the container.
func (s *Service) synchronizeAllTrees(ctx context.Context, cid cid.ID) error {
nodes, pos, err := s.getContainerNodes(cid)
if err != nil {
return fmt.Errorf("can't get container nodes: %w", err)
}
if pos < 0 {
return ErrNotInContainer
}
nodes = randomizeNodeOrder(nodes, pos)
if len(nodes) == 0 {
return nil
}
rawCID := make([]byte, sha256.Size)
cid.Encode(rawCID)
req := &TreeListRequest{
Body: &TreeListRequest_Body{
ContainerId: rawCID,
},
}
err = SignMessage(req, s.key)
if err != nil {
return fmt.Errorf("could not sign request: %w", err)
}
var resp *TreeListResponse
var treesToSync []string
var outErr error
err = s.forEachNode(ctx, nodes, func(c TreeServiceClient) bool {
resp, outErr = c.TreeList(ctx, req)
if outErr != nil {
return false
}
treesToSync = resp.GetBody().GetIds()
return true
})
if err != nil {
outErr = err
}
if outErr != nil {
return fmt.Errorf("could not fetch tree ID list: %w", outErr)
}
for _, tid := range treesToSync {
h, err := s.forest.TreeLastSyncHeight(ctx, cid, tid)
if err != nil && !errors.Is(err, pilorama.ErrTreeNotFound) {
s.log.Warn(logs.TreeCouldNotGetLastSynchronizedHeightForATree,
zap.Stringer("cid", cid),
zap.String("tree", tid))
continue
}
newHeight := s.synchronizeTree(ctx, cid, h, tid, nodes)
if h < newHeight {
if err := s.forest.TreeUpdateLastSyncHeight(ctx, cid, tid, newHeight); err != nil {
s.log.Warn(logs.TreeCouldNotUpdateLastSynchronizedHeightForATree,
zap.Stringer("cid", cid),
zap.String("tree", tid))
}
}
}
return nil
}
// SynchronizeTree tries to synchronize log starting from the last stored height.
func (s *Service) SynchronizeTree(ctx context.Context, cid cid.ID, treeID string) error {
nodes, pos, err := s.getContainerNodes(cid)
if err != nil {
return fmt.Errorf("can't get container nodes: %w", err)
}
if pos < 0 {
return ErrNotInContainer
}
nodes = randomizeNodeOrder(nodes, pos)
if len(nodes) == 0 {
return nil
}
s.synchronizeTree(ctx, cid, 0, treeID, nodes)
return nil
}
// mergeOperationStreams performs merge sort for node operation streams to one stream.
func mergeOperationStreams(streams []chan *pilorama.Move, merged chan<- *pilorama.Move) uint64 {
defer close(merged)
ms := make([]*pilorama.Move, len(streams))
for i := range streams {
ms[i] = <-streams[i]
}
// Merging different node streams shuffles incoming operations like that:
//
// x - operation from the stream A
// o - operation from the stream B
//
// --o---o--x--x--x--o---x--x------> t
// ^
// If all ops have been successfully applied, we must start from the last
// operation height from the stream B. This height is stored in minStreamedLastHeight.
var minStreamedLastHeight uint64 = math.MaxUint64
for {
var minTimeMoveTime uint64 = math.MaxUint64
minTimeMoveIndex := -1
for i, m := range ms {
if m != nil && minTimeMoveTime > m.Time {
minTimeMoveTime = m.Time
minTimeMoveIndex = i
}
}
if minTimeMoveIndex == -1 {
break
}
merged <- ms[minTimeMoveIndex]
height := ms[minTimeMoveIndex].Time
if ms[minTimeMoveIndex] = <-streams[minTimeMoveIndex]; ms[minTimeMoveIndex] == nil {
if minStreamedLastHeight > height {
minStreamedLastHeight = height
}
}
}
return minStreamedLastHeight
}
func (s *Service) applyOperationStream(ctx context.Context, cid cid.ID, treeID string,
operationStream <-chan *pilorama.Move) uint64 {
errGroup, _ := errgroup.WithContext(ctx)
const workersCount = 1024
errGroup.SetLimit(workersCount)
// We run TreeApply concurrently for the operation batch. Let's consider two operations
// in the batch m1 and m2 such that m1.Time < m2.Time. The engine may apply m2 and fail
// on m1. That means the service must start sync from m1.Time in the next iteration and
// this height is stored in unappliedOperationHeight.
var unappliedOperationHeight uint64 = math.MaxUint64
var heightMtx sync.Mutex
var prev *pilorama.Move
for m := range operationStream {
m := m
// skip already applied op
if prev != nil && prev.Time == m.Time {
continue
}
prev = m
errGroup.Go(func() error {
if err := s.forest.TreeApply(ctx, cid, treeID, m, true); err != nil {
heightMtx.Lock()
if m.Time < unappliedOperationHeight {
unappliedOperationHeight = m.Time
}
heightMtx.Unlock()
return err
}
return nil
})
}
_ = errGroup.Wait()
return unappliedOperationHeight
}
func (s *Service) startStream(ctx context.Context, cid cid.ID, treeID string,
height uint64, treeClient TreeServiceClient, opsCh chan<- *pilorama.Move) (uint64, error) {
rawCID := make([]byte, sha256.Size)
cid.Encode(rawCID)
for {
newHeight := height
req := &GetOpLogRequest{
Body: &GetOpLogRequest_Body{
ContainerId: rawCID,
TreeId: treeID,
Height: newHeight,
},
}
if err := SignMessage(req, s.key); err != nil {
return 0, err
}
c, err := treeClient.GetOpLog(ctx, req)
if err != nil {
return 0, fmt.Errorf("can't initialize client: %w", err)
}
res, err := c.Recv()
for ; err == nil; res, err = c.Recv() {
lm := res.GetBody().GetOperation()
m := &pilorama.Move{
Parent: lm.ParentId,
Child: lm.ChildId,
}
if err := m.Meta.FromBytes(lm.Meta); err != nil {
return 0, err
}
opsCh <- m
}
if height == newHeight || err != nil && !errors.Is(err, io.EOF) {
return newHeight, err
}
height = newHeight
}
}
// synchronizeTree synchronizes operations getting them from different nodes.
// Each available node does stream operations to a separate stream. These streams
// are merged into one big stream ordered by operation time. This way allows to skip
// already applied operation and keep good batching.
// The method returns a height that service should start sync from in the next time.
func (s *Service) synchronizeTree(ctx context.Context, cid cid.ID, from uint64,
treeID string, nodes []netmapSDK.NodeInfo) uint64 {
s.log.Debug(logs.TreeSynchronizeTree,
zap.Stringer("cid", cid),
zap.String("tree", treeID),
zap.Uint64("from", from))
errGroup, egCtx := errgroup.WithContext(ctx)
const workersCount = 1024
errGroup.SetLimit(workersCount)
nodeOperationStreams := make([]chan *pilorama.Move, len(nodes))
for i := range nodeOperationStreams {
nodeOperationStreams[i] = make(chan *pilorama.Move)
}
merged := make(chan *pilorama.Move)
var minStreamedLastHeight uint64
errGroup.Go(func() error {
minStreamedLastHeight = mergeOperationStreams(nodeOperationStreams, merged)
return nil
})
var minUnappliedHeight uint64
errGroup.Go(func() error {
minUnappliedHeight = s.applyOperationStream(ctx, cid, treeID, merged)
return nil
})
for i, n := range nodes {
i := i
n := n
errGroup.Go(func() error {
height := from
n.IterateNetworkEndpoints(func(addr string) bool {
var a network.Address
if err := a.FromString(addr); err != nil {
return false
}
cc, err := grpc.DialContext(egCtx, a.URIAddr(),
grpc.WithChainUnaryInterceptor(
tracing.NewGRPCUnaryClientInteceptor(),
),
grpc.WithChainStreamInterceptor(
tracing.NewGRPCStreamClientInterceptor(),
),
grpc.WithTransportCredentials(insecure.NewCredentials()))
if err != nil {
// Failed to connect, try the next address.
return false
}
defer cc.Close()
treeClient := NewTreeServiceClient(cc)
for {
h, err := s.startStream(egCtx, cid, treeID, from, treeClient, nodeOperationStreams[i])
if height < h {
height = h
}
if err != nil || h <= height {
// Error with the response, try the next node.
return true
}
}
})
close(nodeOperationStreams[i])
return nil
})
}
if err := errGroup.Wait(); err != nil {
s.log.Warn(logs.TreeFailedToRunTreeSynchronizationOverAllNodes, zap.Error(err))
}
newHeight := minStreamedLastHeight
if newHeight > minUnappliedHeight {
newHeight = minUnappliedHeight
} else {
newHeight++
}
return newHeight
}
// ErrAlreadySyncing is returned when a service synchronization has already
// been started.
var ErrAlreadySyncing = errors.New("service is being synchronized")
// ErrShuttingDown is returned when the service is shitting down and could not
// accept any calls.
var ErrShuttingDown = errors.New("service is shutting down")
// SynchronizeAll forces tree service to synchronize all the trees according to
// netmap information. Must not be called before Service.Start.
// Returns ErrAlreadySyncing if synchronization has been started and blocked
// by another routine.
// Note: non-blocking operation.
func (s *Service) SynchronizeAll() error {
select {
case <-s.closeCh:
return ErrShuttingDown
default:
}
select {
case s.syncChan <- struct{}{}:
return nil
default:
return ErrAlreadySyncing
}
}
func (s *Service) syncLoop(ctx context.Context) {
for {
select {
case <-s.closeCh:
return
case <-ctx.Done():
return
case <-s.syncChan:
ctx, span := tracing.StartSpanFromContext(ctx, "TreeService.sync")
s.log.Debug(logs.TreeSyncingTrees)
cnrs, err := s.cfg.cnrSource.List()
if err != nil {
s.log.Error(logs.TreeCouldNotFetchContainers, zap.Error(err))
span.End()
continue
}
newMap, cnrsToSync := s.containersToSync(cnrs)
s.syncContainers(ctx, cnrsToSync)
s.removeContainers(ctx, newMap)
s.log.Debug(logs.TreeTreesHaveBeenSynchronized)
span.End()
}
}
}
func (s *Service) syncContainers(ctx context.Context, cnrs []cid.ID) {
ctx, span := tracing.StartSpanFromContext(ctx, "TreeService.syncContainers")
defer span.End()
// sync new containers
var wg sync.WaitGroup
for _, cnr := range cnrs {
wg.Add(1)
cnr := cnr
err := s.syncPool.Submit(func() {
defer wg.Done()
s.log.Debug(logs.TreeSyncingContainerTrees, zap.Stringer("cid", cnr))
err := s.synchronizeAllTrees(ctx, cnr)
if err != nil {
s.log.Error(logs.TreeCouldNotSyncTrees, zap.Stringer("cid", cnr), zap.Error(err))
return
}
s.log.Debug(logs.TreeContainerTreesHaveBeenSynced, zap.Stringer("cid", cnr))
})
if err != nil {
wg.Done()
s.log.Error(logs.TreeCouldNotQueryTreesForSynchronization,
zap.Stringer("cid", cnr),
zap.Error(err))
if errors.Is(err, ants.ErrPoolClosed) {
return
}
}
}
wg.Wait()
}
func (s *Service) removeContainers(ctx context.Context, newContainers map[cid.ID]struct{}) {
ctx, span := tracing.StartSpanFromContext(ctx, "TreeService.removeContainers")
defer span.End()
s.cnrMapMtx.Lock()
defer s.cnrMapMtx.Unlock()
var removed []cid.ID
for cnr := range s.cnrMap {
if _, ok := newContainers[cnr]; ok {
continue
}
removed = append(removed, cnr)
}
for i := range removed {
delete(s.cnrMap, removed[i])
}
for _, cnr := range removed {
s.log.Debug(logs.TreeRemovingRedundantTrees, zap.Stringer("cid", cnr))
err := s.DropTree(ctx, cnr, "")
if err != nil {
s.log.Error(logs.TreeCouldNotRemoveRedundantTree,
zap.Stringer("cid", cnr),
zap.Error(err))
}
}
}
func (s *Service) containersToSync(cnrs []cid.ID) (map[cid.ID]struct{}, []cid.ID) {
newMap := make(map[cid.ID]struct{}, len(s.cnrMap))
cnrsToSync := make([]cid.ID, 0, len(cnrs))
for _, cnr := range cnrs {
_, pos, err := s.getContainerNodes(cnr)
if err != nil {
s.log.Error(logs.TreeCouldNotCalculateContainerNodes,
zap.Stringer("cid", cnr),
zap.Error(err))
continue
}
if pos < 0 {
// node is not included in the container.
continue
}
newMap[cnr] = struct{}{}
cnrsToSync = append(cnrsToSync, cnr)
}
return newMap, cnrsToSync
}
// randomizeNodeOrder shuffles nodes and removes not a `pos` index.
// It is assumed that 0 <= pos < len(nodes).
func randomizeNodeOrder(cnrNodes []netmap.NodeInfo, pos int) []netmap.NodeInfo {
if len(cnrNodes) == 1 {
return nil
}
nodes := make([]netmap.NodeInfo, len(cnrNodes)-1)
n := copy(nodes, cnrNodes[:pos])
copy(nodes[n:], cnrNodes[pos+1:])
rand.Shuffle(len(nodes), func(i, j int) {
nodes[i], nodes[j] = nodes[j], nodes[i]
})
return nodes
}