storj/satellite/repair/repairer/ec.go
paul cannon 79553059cb satellite/repair: put irreparable segments in irreparableDB
Previously, we were simply discarding rows from the repair queue when
they couldn't be repaired (either because the overlay said too many
nodes were down, or because we failed to download enough pieces).

Now, such segments will be put into the irreparableDB for further
and (hopefully) more focused attention.

This change also better differentiates some error cases from Repair()
for monitoring purposes.

Change-Id: I82a52a6da50c948ddd651048e2a39cb4b1e6df5c
2020-03-09 21:45:16 +00:00

481 lines
14 KiB
Go

// Copyright (C) 2019 Storj Labs, Inc.
// See LICENSE for copying information.
package repairer
import (
"bytes"
"context"
"io"
"io/ioutil"
"sort"
"sync"
"sync/atomic"
"time"
"github.com/vivint/infectious"
"github.com/zeebo/errs"
"go.uber.org/zap"
"storj.io/common/errs2"
"storj.io/common/pb"
"storj.io/common/pkcrypto"
"storj.io/common/rpc"
"storj.io/common/signing"
"storj.io/common/storj"
"storj.io/common/sync2"
"storj.io/uplink/private/eestream"
"storj.io/uplink/private/piecestore"
)
// ErrPieceHashVerifyFailed is the errs class when a piece hash downloaded from storagenode fails to match the original hash.
var ErrPieceHashVerifyFailed = errs.Class("piece hashes don't match")
// ECRepairer allows the repairer to download, verify, and upload pieces from storagenodes.
type ECRepairer struct {
log *zap.Logger
dialer rpc.Dialer
satelliteSignee signing.Signee
downloadTimeout time.Duration
}
// NewECRepairer creates a new repairer for interfacing with storagenodes.
func NewECRepairer(log *zap.Logger, dialer rpc.Dialer, satelliteSignee signing.Signee, downloadTimeout time.Duration) *ECRepairer {
return &ECRepairer{
log: log,
dialer: dialer,
satelliteSignee: satelliteSignee,
downloadTimeout: downloadTimeout,
}
}
func (ec *ECRepairer) dialPiecestore(ctx context.Context, n *pb.Node) (*piecestore.Client, error) {
logger := ec.log.Named(n.Id.String())
return piecestore.Dial(ctx, ec.dialer, n, logger, piecestore.DefaultConfig)
}
// Get downloads pieces from storagenodes using the provided order limits, and decodes those pieces into a segment.
// It attempts to download from the minimum required number based on the redundancy scheme.
// After downloading a piece, the ECRepairer will verify the hash and original order limit for that piece.
// If verification fails, another piece will be downloaded until we reach the minimum required or run out of order limits.
// If piece hash verification fails, it will return all failed node IDs.
func (ec *ECRepairer) Get(ctx context.Context, limits []*pb.AddressedOrderLimit, privateKey storj.PiecePrivateKey, es eestream.ErasureScheme, dataSize int64, path storj.Path) (_ io.ReadCloser, failedPieces []*pb.RemotePiece, err error) {
defer mon.Task()(&ctx)(&err)
if len(limits) != es.TotalCount() {
return nil, nil, Error.New("number of limits slice (%d) does not match total count (%d) of erasure scheme", len(limits), es.TotalCount())
}
nonNilLimits := nonNilCount(limits)
if nonNilLimits < es.RequiredCount() {
return nil, nil, Error.New("number of non-nil limits (%d) is less than required count (%d) of erasure scheme", nonNilCount(limits), es.RequiredCount())
}
pieceSize := eestream.CalcPieceSize(dataSize, es)
var successfulPieces, inProgress int
unusedLimits := nonNilLimits
pieceReaders := make(map[int]io.ReadCloser)
limiter := sync2.NewLimiter(es.RequiredCount())
cond := sync.NewCond(&sync.Mutex{})
for currentLimitIndex, limit := range limits {
if limit == nil {
continue
}
currentLimitIndex, limit := currentLimitIndex, limit
limiter.Go(ctx, func() {
cond.L.Lock()
defer cond.Signal()
defer cond.L.Unlock()
for {
if successfulPieces >= es.RequiredCount() {
// already downloaded minimum number of pieces
cond.Broadcast()
return
}
if successfulPieces+inProgress+unusedLimits < es.RequiredCount() {
// not enough available limits left to get required number of pieces
cond.Broadcast()
return
}
if successfulPieces+inProgress >= es.RequiredCount() {
cond.Wait()
continue
}
unusedLimits--
inProgress++
cond.L.Unlock()
downloadedPiece, err := ec.downloadAndVerifyPiece(ctx, limit, privateKey, pieceSize)
cond.L.Lock()
inProgress--
if err != nil {
// gather nodes where the calculated piece hash doesn't match the uplink signed piece hash
if ErrPieceHashVerifyFailed.Has(err) {
failedPieces = append(failedPieces, &pb.RemotePiece{
PieceNum: int32(currentLimitIndex),
NodeId: limit.GetLimit().StorageNodeId,
})
} else {
ec.log.Debug("Failed to download pieces for repair",
zap.Binary("Segment", []byte(path)),
zap.Error(err))
}
return
}
pieceReaders[currentLimitIndex] = ioutil.NopCloser(bytes.NewReader(downloadedPiece))
successfulPieces++
return
}
})
}
limiter.Wait()
if successfulPieces < es.RequiredCount() {
mon.Meter("download_failed_not_enough_pieces_repair").Mark(1) //locked
return nil, failedPieces, &irreparableError{
path: path,
piecesAvailable: int32(successfulPieces),
piecesRequired: int32(es.RequiredCount()),
}
}
fec, err := infectious.NewFEC(es.RequiredCount(), es.TotalCount())
if err != nil {
return nil, failedPieces, Error.Wrap(err)
}
esScheme := eestream.NewUnsafeRSScheme(fec, es.ErasureShareSize())
expectedSize := pieceSize * int64(es.RequiredCount())
ctx, cancel := context.WithCancel(ctx)
decodeReader := eestream.DecodeReaders(ctx, cancel, ec.log.Named("decode readers"), pieceReaders, esScheme, expectedSize, 0, false)
return decodeReader, failedPieces, nil
}
// downloadAndVerifyPiece downloads a piece from a storagenode,
// expects the original order limit to have the correct piece public key,
// and expects the hash of the data to match the signed hash provided by the storagenode.
func (ec *ECRepairer) downloadAndVerifyPiece(ctx context.Context, limit *pb.AddressedOrderLimit, privateKey storj.PiecePrivateKey, pieceSize int64) (data []byte, err error) {
// contact node
downloadCtx, cancel := context.WithTimeout(ctx, ec.downloadTimeout)
defer cancel()
ps, err := ec.dialPiecestore(downloadCtx, &pb.Node{
Id: limit.GetLimit().StorageNodeId,
Address: limit.GetStorageNodeAddress(),
})
if err != nil {
return nil, err
}
defer func() { err = errs.Combine(err, ps.Close()) }()
downloader, err := ps.Download(downloadCtx, limit.GetLimit(), privateKey, 0, pieceSize)
if err != nil {
return nil, err
}
defer func() { err = errs.Combine(err, downloader.Close()) }()
pieceBytes, err := ioutil.ReadAll(downloader)
if err != nil {
return nil, err
}
if int64(len(pieceBytes)) != pieceSize {
return nil, Error.New("didn't download the correct amount of data, want %d, got %d", pieceSize, len(pieceBytes))
}
// get signed piece hash and original order limit
hash, originalLimit := downloader.GetHashAndLimit()
if hash == nil {
return nil, Error.New("hash was not sent from storagenode")
}
if originalLimit == nil {
return nil, Error.New("original order limit was not sent from storagenode")
}
// verify order limit from storage node is signed by the satellite
if err := verifyOrderLimitSignature(ctx, ec.satelliteSignee, originalLimit); err != nil {
return nil, err
}
// verify the hashes from storage node
calculatedHash := pkcrypto.SHA256Hash(pieceBytes)
if err := verifyPieceHash(ctx, originalLimit, hash, calculatedHash); err != nil {
return nil, ErrPieceHashVerifyFailed.Wrap(err)
}
return pieceBytes, nil
}
func verifyPieceHash(ctx context.Context, limit *pb.OrderLimit, hash *pb.PieceHash, expectedHash []byte) (err error) {
defer mon.Task()(&ctx)(&err)
if limit == nil || hash == nil || len(expectedHash) == 0 {
return Error.New("invalid arguments")
}
if limit.PieceId != hash.PieceId {
return Error.New("piece id changed")
}
if !bytes.Equal(hash.Hash, expectedHash) {
return Error.New("hashes don't match")
}
if err := signing.VerifyUplinkPieceHashSignature(ctx, limit.UplinkPublicKey, hash); err != nil {
return Error.New("invalid piece hash signature")
}
return nil
}
func verifyOrderLimitSignature(ctx context.Context, satellite signing.Signee, limit *pb.OrderLimit) (err error) {
if err := signing.VerifyOrderLimitSignature(ctx, satellite, limit); err != nil {
return Error.New("invalid order limit signature: %v", err)
}
return nil
}
// Repair takes a provided segment, encodes it with the provided redundancy strategy,
// and uploads the pieces in need of repair to new nodes provided by order limits.
func (ec *ECRepairer) Repair(ctx context.Context, limits []*pb.AddressedOrderLimit, privateKey storj.PiecePrivateKey, rs eestream.RedundancyStrategy, data io.Reader, timeout time.Duration, path storj.Path) (successfulNodes []*pb.Node, successfulHashes []*pb.PieceHash, err error) {
defer mon.Task()(&ctx)(&err)
pieceCount := len(limits)
if pieceCount != rs.TotalCount() {
return nil, nil, Error.New("size of limits slice (%d) does not match total count (%d) of erasure scheme", pieceCount, rs.TotalCount())
}
if !unique(limits) {
return nil, nil, Error.New("duplicated nodes are not allowed")
}
readers, err := eestream.EncodeReader(ctx, ec.log, ioutil.NopCloser(data), rs)
if err != nil {
return nil, nil, err
}
// info contains data about a single piece transfer
type info struct {
i int
err error
hash *pb.PieceHash
}
// this channel is used to synchronize concurrently uploaded pieces with the overall repair
infos := make(chan info, pieceCount)
psCtx, cancel := context.WithCancel(ctx)
defer cancel()
for i, addressedLimit := range limits {
go func(i int, addressedLimit *pb.AddressedOrderLimit) {
hash, err := ec.putPiece(psCtx, ctx, addressedLimit, privateKey, readers[i], path)
infos <- info{i: i, err: err, hash: hash}
}(i, addressedLimit)
}
ec.log.Info("Starting a timer for repair so that the number of pieces will be closer to the success threshold",
zap.Binary("Segment", []byte(path)),
zap.Duration("Timer", timeout),
zap.Int("Node Count", nonNilCount(limits)),
zap.Int("Optimal Threshold", rs.OptimalThreshold()),
)
var successfulCount, failureCount, cancellationCount int32
timer := time.AfterFunc(timeout, func() {
if ctx.Err() != context.Canceled {
ec.log.Info("Timer expired. Canceling the long tail...",
zap.Binary("Segment", []byte(path)),
zap.Int32("Successfully repaired", atomic.LoadInt32(&successfulCount)),
)
cancel()
}
})
successfulNodes = make([]*pb.Node, pieceCount)
successfulHashes = make([]*pb.PieceHash, pieceCount)
for range limits {
info := <-infos
if limits[info.i] == nil {
continue
}
if info.err != nil {
if !errs2.IsCanceled(info.err) {
failureCount++
} else {
cancellationCount++
}
ec.log.Debug("Repair to storage node failed",
zap.Binary("Segment", []byte(path)),
zap.Stringer("Node ID", limits[info.i].GetLimit().StorageNodeId),
zap.Error(info.err),
)
continue
}
successfulNodes[info.i] = &pb.Node{
Id: limits[info.i].GetLimit().StorageNodeId,
Address: limits[info.i].GetStorageNodeAddress(),
}
successfulHashes[info.i] = info.hash
successfulCount++
}
// Ensure timer is stopped
_ = timer.Stop()
// TODO: clean up the partially uploaded segment's pieces
defer func() {
select {
case <-ctx.Done():
err = Error.New("repair cancelled")
default:
}
}()
if successfulCount == 0 {
return nil, nil, Error.New("repair to all nodes failed")
}
ec.log.Info("Successfully repaired",
zap.Binary("Segment", []byte(path)),
zap.Int32("Success Count", atomic.LoadInt32(&successfulCount)),
)
mon.IntVal("repair_segment_pieces_total").Observe(int64(pieceCount)) //locked
mon.IntVal("repair_segment_pieces_successful").Observe(int64(successfulCount)) //locked
mon.IntVal("repair_segment_pieces_failed").Observe(int64(failureCount)) //locked
mon.IntVal("repair_segment_pieces_canceled").Observe(int64(cancellationCount)) //locked
return successfulNodes, successfulHashes, nil
}
func (ec *ECRepairer) putPiece(ctx, parent context.Context, limit *pb.AddressedOrderLimit, privateKey storj.PiecePrivateKey, data io.ReadCloser, path storj.Path) (hash *pb.PieceHash, err error) {
nodeName := "nil"
if limit != nil {
nodeName = limit.GetLimit().StorageNodeId.String()[0:8]
}
defer mon.Task()(&ctx, "node: "+nodeName)(&err)
defer func() { err = errs.Combine(err, data.Close()) }()
if limit == nil {
_, _ = io.Copy(ioutil.Discard, data)
return nil, nil
}
storageNodeID := limit.GetLimit().StorageNodeId
pieceID := limit.GetLimit().PieceId
ps, err := ec.dialPiecestore(ctx, &pb.Node{
Id: storageNodeID,
Address: limit.GetStorageNodeAddress(),
})
if err != nil {
ec.log.Debug("Failed dialing for putting piece to node",
zap.Binary("Segment", []byte(path)),
zap.Stringer("Piece ID", pieceID),
zap.Stringer("Node ID", storageNodeID),
zap.Error(err),
)
return nil, err
}
defer func() { err = errs.Combine(err, ps.Close()) }()
upload, err := ps.Upload(ctx, limit.GetLimit(), privateKey)
if err != nil {
ec.log.Debug("Failed requesting upload of pieces to node",
zap.Binary("Segment", []byte(path)),
zap.Stringer("Piece ID", pieceID),
zap.Stringer("Node ID", storageNodeID),
zap.Error(err),
)
return nil, err
}
defer func() {
if ctx.Err() != nil || err != nil {
hash = nil
err = errs.Combine(err, upload.Cancel(ctx))
return
}
h, closeErr := upload.Commit(ctx)
hash = h
err = errs.Combine(err, closeErr)
}()
_, err = sync2.Copy(ctx, upload, data)
// Canceled context means the piece upload was interrupted by user or due
// to slow connection. No error logging for this case.
if ctx.Err() == context.Canceled {
if parent.Err() == context.Canceled {
ec.log.Info("Upload to node canceled by user",
zap.Binary("Segment", []byte(path)),
zap.Stringer("Node ID", storageNodeID))
} else {
ec.log.Debug("Node cut from upload due to slow connection",
zap.Binary("Segment", []byte(path)),
zap.Stringer("Node ID", storageNodeID))
}
err = context.Canceled
} else if err != nil {
nodeAddress := "nil"
if limit.GetStorageNodeAddress() != nil {
nodeAddress = limit.GetStorageNodeAddress().GetAddress()
}
ec.log.Debug("Failed uploading piece to node",
zap.Binary("Segment", []byte(path)),
zap.Stringer("Piece ID", pieceID),
zap.Stringer("Node ID", storageNodeID),
zap.String("Node Address", nodeAddress),
zap.Error(err),
)
}
return hash, err
}
func nonNilCount(limits []*pb.AddressedOrderLimit) int {
total := 0
for _, limit := range limits {
if limit != nil {
total++
}
}
return total
}
func unique(limits []*pb.AddressedOrderLimit) bool {
if len(limits) < 2 {
return true
}
ids := make(storj.NodeIDList, len(limits))
for i, addressedLimit := range limits {
if addressedLimit != nil {
ids[i] = addressedLimit.GetLimit().StorageNodeId
}
}
// sort the ids and check for identical neighbors
sort.Sort(ids)
// sort.Slice(ids, func(i, k int) bool { return ids[i].Less(ids[k]) })
for i := 1; i < len(ids); i++ {
if ids[i] != (storj.NodeID{}) && ids[i] == ids[i-1] {
return false
}
}
return true
}