// Copyright (C) 2019 Storj Labs, Inc. // See LICENSE for copying information. package repairer import ( "context" "errors" "fmt" "io" "math" "strings" "time" "github.com/zeebo/errs" "go.uber.org/zap" "golang.org/x/exp/maps" "storj.io/common/pb" "storj.io/common/storj" "storj.io/common/sync2" "storj.io/storj/satellite/audit" "storj.io/storj/satellite/metabase" "storj.io/storj/satellite/nodeselection" "storj.io/storj/satellite/orders" "storj.io/storj/satellite/overlay" "storj.io/storj/satellite/repair" "storj.io/storj/satellite/repair/checker" "storj.io/storj/satellite/repair/queue" "storj.io/uplink/private/eestream" "storj.io/uplink/private/piecestore" ) var ( metainfoGetError = errs.Class("metainfo db get") metainfoPutError = errs.Class("metainfo db put") invalidRepairError = errs.Class("invalid repair") overlayQueryError = errs.Class("overlay query failure") orderLimitFailureError = errs.Class("order limits failure") repairReconstructError = errs.Class("repair reconstruction failure") repairPutError = errs.Class("repair could not store repaired pieces") // segmentVerificationError is the errs class when the repaired segment can not be verified during repair. segmentVerificationError = errs.Class("segment verification failed") // segmentDeletedError is the errs class when the repaired segment was deleted during the repair. segmentDeletedError = errs.Class("segment deleted during repair") // segmentModifiedError is the errs class used when a segment has been changed in any way. segmentModifiedError = errs.Class("segment has been modified") ) // irreparableError identifies situations where a segment could not be repaired due to reasons // which are hopefully transient (e.g. too many pieces unavailable). The segment should be added // to the irreparableDB. type irreparableError struct { piecesAvailable int32 piecesRequired int32 } func (ie *irreparableError) Error() string { return fmt.Sprintf("%d available pieces < %d required", ie.piecesAvailable, ie.piecesRequired) } // PieceFetchResult combines a piece pointer with the error we got when we tried // to acquire that piece. type PieceFetchResult struct { Piece metabase.Piece Err error } // FetchResultReport contains a categorization of a set of pieces based on the results of // GET operations. type FetchResultReport struct { Successful []PieceFetchResult Failed []PieceFetchResult Offline []PieceFetchResult Contained []PieceFetchResult Unknown []PieceFetchResult } // SegmentRepairer for segments. type SegmentRepairer struct { log *zap.Logger statsCollector *statsCollector metabase *metabase.DB orders *orders.Service overlay *overlay.Service ec *ECRepairer timeout time.Duration reporter audit.Reporter reputationUpdateEnabled bool doDeclumping bool doPlacementCheck bool // multiplierOptimalThreshold is the value that multiplied by the optimal // threshold results in the maximum limit of number of nodes to upload // repaired pieces multiplierOptimalThreshold float64 // repairOverrides is the set of values configured by the checker to override the repair threshold for various RS schemes. repairOverrides checker.RepairOverridesMap nowFn func() time.Time OnTestingCheckSegmentAlteredHook func() OnTestingPiecesReportHook func(pieces FetchResultReport) placementRules overlay.PlacementRules } // NewSegmentRepairer creates a new instance of SegmentRepairer. // // excessPercentageOptimalThreshold is the percentage to apply over the optimal // threshould to determine the maximum limit of nodes to upload repaired pieces, // when negative, 0 is applied. func NewSegmentRepairer( log *zap.Logger, metabase *metabase.DB, orders *orders.Service, overlay *overlay.Service, reporter audit.Reporter, ecRepairer *ECRepairer, placementRules overlay.PlacementRules, repairOverrides checker.RepairOverrides, config Config, ) *SegmentRepairer { excessOptimalThreshold := config.MaxExcessRateOptimalThreshold if excessOptimalThreshold < 0 { excessOptimalThreshold = 0 } return &SegmentRepairer{ log: log, statsCollector: newStatsCollector(), metabase: metabase, orders: orders, overlay: overlay, ec: ecRepairer, timeout: config.Timeout, multiplierOptimalThreshold: 1 + excessOptimalThreshold, repairOverrides: repairOverrides.GetMap(), reporter: reporter, reputationUpdateEnabled: config.ReputationUpdateEnabled, doDeclumping: config.DoDeclumping, doPlacementCheck: config.DoPlacementCheck, placementRules: placementRules, nowFn: time.Now, } } // Repair retrieves an at-risk segment and repairs and stores lost pieces on new nodes // note that shouldDelete is used even in the case where err is not null // note that it will update audit status as failed for nodes that failed piece hash verification during repair downloading. func (repairer *SegmentRepairer) Repair(ctx context.Context, queueSegment *queue.InjuredSegment) (shouldDelete bool, err error) { defer mon.Task()(&ctx, queueSegment.StreamID.String(), queueSegment.Position.Encode())(&err) segment, err := repairer.metabase.GetSegmentByPosition(ctx, metabase.GetSegmentByPosition{ StreamID: queueSegment.StreamID, Position: queueSegment.Position, }) if err != nil { if metabase.ErrSegmentNotFound.Has(err) { mon.Meter("repair_unnecessary").Mark(1) //mon:locked mon.Meter("segment_deleted_before_repair").Mark(1) //mon:locked repairer.log.Debug("segment was deleted") return true, nil } return false, metainfoGetError.Wrap(err) } if segment.Inline() { return true, invalidRepairError.New("cannot repair inline segment") } // ignore segment if expired if segment.Expired(repairer.nowFn()) { mon.Meter("repair_unnecessary").Mark(1) mon.Meter("segment_expired_before_repair").Mark(1) repairer.log.Debug("segment has expired", zap.Stringer("Stream ID", segment.StreamID), zap.Uint64("Position", queueSegment.Position.Encode())) return true, nil } redundancy, err := eestream.NewRedundancyStrategyFromStorj(segment.Redundancy) if err != nil { return true, invalidRepairError.New("invalid redundancy strategy: %w", err) } stats := repairer.getStatsByRS(&pb.RedundancyScheme{ Type: pb.RedundancyScheme_SchemeType(segment.Redundancy.Algorithm), ErasureShareSize: segment.Redundancy.ShareSize, MinReq: int32(segment.Redundancy.RequiredShares), RepairThreshold: int32(segment.Redundancy.RepairShares), SuccessThreshold: int32(segment.Redundancy.OptimalShares), Total: int32(segment.Redundancy.TotalShares), }) mon.Meter("repair_attempts").Mark(1) //mon:locked stats.repairAttempts.Mark(1) mon.IntVal("repair_segment_size").Observe(int64(segment.EncryptedSize)) //mon:locked stats.repairSegmentSize.Observe(int64(segment.EncryptedSize)) piecesCheck, err := repairer.classifySegmentPieces(ctx, segment) if err != nil { return false, err } pieces := segment.Pieces numRetrievable := len(pieces) - len(piecesCheck.MissingPiecesSet) numHealthy := len(pieces) - len(piecesCheck.MissingPiecesSet) - piecesCheck.NumUnhealthyRetrievable // irreparable segment if numRetrievable < int(segment.Redundancy.RequiredShares) { mon.Counter("repairer_segments_below_min_req").Inc(1) //mon:locked stats.repairerSegmentsBelowMinReq.Inc(1) mon.Meter("repair_nodes_unavailable").Mark(1) //mon:locked stats.repairerNodesUnavailable.Mark(1) repairer.log.Warn("irreparable segment", zap.String("StreamID", queueSegment.StreamID.String()), zap.Uint64("Position", queueSegment.Position.Encode()), zap.Int("piecesAvailable", numRetrievable), zap.Int16("piecesRequired", segment.Redundancy.RequiredShares), ) return false, nil } piecesInExcludedCountries, err := repairer.overlay.GetReliablePiecesInExcludedCountries(ctx, pieces) if err != nil { return false, overlayQueryError.New("error identifying pieces in excluded countries: %w", err) } numHealthyInExcludedCountries := len(piecesInExcludedCountries) // ensure we get values, even if only zero values, so that redash can have an alert based on this mon.Counter("repairer_segments_below_min_req").Inc(0) //mon:locked stats.repairerSegmentsBelowMinReq.Inc(0) repairThreshold := int32(segment.Redundancy.RepairShares) pbRedundancy := &pb.RedundancyScheme{ MinReq: int32(segment.Redundancy.RequiredShares), RepairThreshold: int32(segment.Redundancy.RepairShares), SuccessThreshold: int32(segment.Redundancy.OptimalShares), Total: int32(segment.Redundancy.TotalShares), } overrideValue := repairer.repairOverrides.GetOverrideValuePB(pbRedundancy) if overrideValue != 0 { repairThreshold = overrideValue } // repair not needed if numHealthy-numHealthyInExcludedCountries > int(repairThreshold) { // remove pieces out of placement without repairing as we are above repair threshold if len(piecesCheck.OutOfPlacementPiecesSet) > 0 { var outOfPlacementPieces metabase.Pieces for _, piece := range pieces { if _, ok := piecesCheck.OutOfPlacementPiecesSet[piece.Number]; ok { outOfPlacementPieces = append(outOfPlacementPieces, piece) } } newPieces, err := segment.Pieces.Update(nil, outOfPlacementPieces) if err != nil { return false, metainfoPutError.Wrap(err) } err = repairer.metabase.UpdateSegmentPieces(ctx, metabase.UpdateSegmentPieces{ StreamID: segment.StreamID, Position: segment.Position, OldPieces: segment.Pieces, NewRedundancy: segment.Redundancy, NewPieces: newPieces, NewRepairedAt: time.Now(), }) if err != nil { return false, metainfoPutError.Wrap(err) } mon.Meter("dropped_out_of_placement_pieces").Mark(len(piecesCheck.OutOfPlacementPiecesSet)) } mon.Meter("repair_unnecessary").Mark(1) //mon:locked stats.repairUnnecessary.Mark(1) repairer.log.Debug("segment above repair threshold", zap.Int("numHealthy", numHealthy), zap.Int32("repairThreshold", repairThreshold), zap.Int("numClumped", len(piecesCheck.ClumpedPiecesSet)), zap.Int("numOffPieces", len(piecesCheck.OutOfPlacementPiecesSet))) return true, nil } healthyRatioBeforeRepair := 0.0 if segment.Redundancy.TotalShares != 0 { healthyRatioBeforeRepair = float64(numHealthy) / float64(segment.Redundancy.TotalShares) } mon.FloatVal("healthy_ratio_before_repair").Observe(healthyRatioBeforeRepair) //mon:locked stats.healthyRatioBeforeRepair.Observe(healthyRatioBeforeRepair) lostPiecesSet := piecesCheck.MissingPiecesSet var retrievablePieces metabase.Pieces unhealthyPieces := make(map[metabase.Piece]struct{}) healthySet := make(map[int32]struct{}) // Populate retrievablePieces with all pieces from the segment except those correlating to indices in lostPieces. // Populate unhealthyPieces with all pieces in lostPieces, clumpedPieces or outOfPlacementPieces. for _, piece := range pieces { if lostPiecesSet[piece.Number] { unhealthyPieces[piece] = struct{}{} } else { retrievablePieces = append(retrievablePieces, piece) if piecesCheck.ClumpedPiecesSet[piece.Number] || piecesCheck.OutOfPlacementPiecesSet[piece.Number] { unhealthyPieces[piece] = struct{}{} } else { healthySet[int32(piece.Number)] = struct{}{} } } } // Create the order limits for the GET_REPAIR action getOrderLimits, getPrivateKey, cachedNodesInfo, err := repairer.orders.CreateGetRepairOrderLimits(ctx, segment, retrievablePieces) if err != nil { if orders.ErrDownloadFailedNotEnoughPieces.Has(err) { mon.Counter("repairer_segments_below_min_req").Inc(1) //mon:locked stats.repairerSegmentsBelowMinReq.Inc(1) mon.Meter("repair_nodes_unavailable").Mark(1) //mon:locked stats.repairerNodesUnavailable.Mark(1) repairer.log.Warn("irreparable segment: too many nodes offline", zap.String("StreamID", queueSegment.StreamID.String()), zap.Uint64("Position", queueSegment.Position.Encode()), zap.Int("piecesAvailable", len(retrievablePieces)), zap.Int16("piecesRequired", segment.Redundancy.RequiredShares), zap.Error(err), ) } return false, orderLimitFailureError.New("could not create GET_REPAIR order limits: %w", err) } // Double check for retrievable pieces which became irretrievable inside CreateGetRepairOrderLimits // Add them to unhealthyPieces. for _, piece := range retrievablePieces { if getOrderLimits[piece.Number] == nil { unhealthyPieces[piece] = struct{}{} } } numHealthy = len(healthySet) var requestCount int var minSuccessfulNeeded int { totalNeeded := math.Ceil(float64(redundancy.OptimalThreshold()) * repairer.multiplierOptimalThreshold) requestCount = int(totalNeeded) + numHealthyInExcludedCountries if requestCount > redundancy.TotalCount() { requestCount = redundancy.TotalCount() } requestCount -= numHealthy minSuccessfulNeeded = redundancy.OptimalThreshold() - numHealthy + numHealthyInExcludedCountries } // Request Overlay for n-h new storage nodes request := overlay.FindStorageNodesRequest{ RequestedCount: requestCount, ExcludedIDs: piecesCheck.ExcludeNodeIDs, Placement: segment.Placement, } newNodes, err := repairer.overlay.FindStorageNodesForUpload(ctx, request) if err != nil { return false, overlayQueryError.Wrap(err) } // Create the order limits for the PUT_REPAIR action putLimits, putPrivateKey, err := repairer.orders.CreatePutRepairOrderLimits(ctx, segment, getOrderLimits, healthySet, newNodes, repairer.multiplierOptimalThreshold, numHealthyInExcludedCountries) if err != nil { return false, orderLimitFailureError.New("could not create PUT_REPAIR order limits: %w", err) } // Download the segment using just the retrievable pieces segmentReader, piecesReport, err := repairer.ec.Get(ctx, getOrderLimits, cachedNodesInfo, getPrivateKey, redundancy, int64(segment.EncryptedSize)) // ensure we get values, even if only zero values, so that redash can have an alert based on this mon.Meter("repair_too_many_nodes_failed").Mark(0) //mon:locked mon.Meter("repair_suspected_network_problem").Mark(0) //mon:locked stats.repairTooManyNodesFailed.Mark(0) if repairer.OnTestingPiecesReportHook != nil { repairer.OnTestingPiecesReportHook(piecesReport) } // Check if segment has been altered checkSegmentError := repairer.checkIfSegmentAltered(ctx, segment) if checkSegmentError != nil { if segmentDeletedError.Has(checkSegmentError) { // mon.Meter("segment_deleted_during_repair").Mark(1) //mon:locked repairer.log.Debug("segment deleted during Repair") return true, nil } if segmentModifiedError.Has(checkSegmentError) { // mon.Meter("segment_modified_during_repair").Mark(1) //mon:locked repairer.log.Debug("segment modified during Repair") return true, nil } return false, segmentVerificationError.Wrap(checkSegmentError) } if len(piecesReport.Contained) > 0 { repairer.log.Debug("unexpected contained pieces during repair", zap.Int("count", len(piecesReport.Contained))) } if err != nil { // If the context was closed during the Get phase, it will appear here as though // we just failed to download enough pieces to reconstruct the segment. Check for // a closed context before doing any further error processing. if ctxErr := ctx.Err(); ctxErr != nil { return false, ctxErr } // If Get failed because of input validation, then it will keep failing. But if it // gave us irreparableError, then we failed to download enough pieces and must try // to wait for nodes to come back online. var irreparableErr *irreparableError if errors.As(err, &irreparableErr) { // piecesReport.Offline: // Nodes which were online recently, but which we couldn't contact for // this operation. // // piecesReport.Failed: // Nodes which we contacted successfully but which indicated they // didn't have the piece we wanted. // // piecesReport.Contained: // Nodes which we contacted successfully but timed out after we asked // for the piece. // // piecesReport.Unknown: // Something else went wrong, and we don't know what. // // In a network failure scenario, we expect more than half of the outcomes // will be in Offline or Contained. if len(piecesReport.Offline)+len(piecesReport.Contained) > len(piecesReport.Successful)+len(piecesReport.Failed)+len(piecesReport.Unknown) { mon.Meter("repair_suspected_network_problem").Mark(1) //mon:locked } else { mon.Meter("repair_too_many_nodes_failed").Mark(1) //mon:locked } stats.repairTooManyNodesFailed.Mark(1) failedNodeIDs := make([]string, 0, len(piecesReport.Failed)) offlineNodeIDs := make([]string, 0, len(piecesReport.Offline)) timedOutNodeIDs := make([]string, 0, len(piecesReport.Contained)) unknownErrs := make([]string, 0, len(piecesReport.Unknown)) for _, outcome := range piecesReport.Failed { failedNodeIDs = append(failedNodeIDs, outcome.Piece.StorageNode.String()) } for _, outcome := range piecesReport.Offline { offlineNodeIDs = append(offlineNodeIDs, outcome.Piece.StorageNode.String()) } for _, outcome := range piecesReport.Contained { timedOutNodeIDs = append(timedOutNodeIDs, outcome.Piece.StorageNode.String()) } for _, outcome := range piecesReport.Unknown { // We are purposefully using the error's string here, as opposed // to wrapping the error. It is not likely that we need the local-side // traceback of where this error was initially wrapped, and this will // keep the logs more readable. unknownErrs = append(unknownErrs, fmt.Sprintf("node ID [%s] err: %v", outcome.Piece.StorageNode, outcome.Err)) } repairer.log.Warn("irreparable segment: could not acquire enough shares", zap.String("StreamID", queueSegment.StreamID.String()), zap.Uint64("Position", queueSegment.Position.Encode()), zap.Int32("piecesAvailable", irreparableErr.piecesAvailable), zap.Int32("piecesRequired", irreparableErr.piecesRequired), zap.Int("numFailedNodes", len(failedNodeIDs)), zap.Stringer("failedNodes", commaSeparatedArray(failedNodeIDs)), zap.Int("numOfflineNodes", len(offlineNodeIDs)), zap.Stringer("offlineNodes", commaSeparatedArray(offlineNodeIDs)), zap.Int("numTimedOutNodes", len(timedOutNodeIDs)), zap.Stringer("timedOutNodes", commaSeparatedArray(timedOutNodeIDs)), zap.Stringer("unknownErrors", commaSeparatedArray(unknownErrs)), ) // repair will be attempted again if the segment remains unhealthy. return false, nil } // The segment's redundancy strategy is invalid, or else there was an internal error. return true, repairReconstructError.New("segment could not be reconstructed: %w", err) } defer func() { err = errs.Combine(err, segmentReader.Close()) }() // only report audit result when segment can be successfully downloaded cachedNodesReputation := make(map[storj.NodeID]overlay.ReputationStatus, len(cachedNodesInfo)) for id, info := range cachedNodesInfo { cachedNodesReputation[id] = info.Reputation } report := audit.Report{ Segment: &segment, NodesReputation: cachedNodesReputation, } for _, outcome := range piecesReport.Successful { report.Successes = append(report.Successes, outcome.Piece.StorageNode) } for _, outcome := range piecesReport.Failed { report.Fails = append(report.Fails, metabase.Piece{ StorageNode: outcome.Piece.StorageNode, Number: outcome.Piece.Number, }) } for _, outcome := range piecesReport.Offline { report.Offlines = append(report.Offlines, outcome.Piece.StorageNode) } for _, outcome := range piecesReport.Unknown { report.Unknown = append(report.Unknown, outcome.Piece.StorageNode) } if repairer.reputationUpdateEnabled { repairer.reporter.RecordAudits(ctx, report) } // Upload the repaired pieces successfulNodes, _, err := repairer.ec.Repair(ctx, putLimits, putPrivateKey, redundancy, segmentReader, repairer.timeout, minSuccessfulNeeded) if err != nil { return false, repairPutError.Wrap(err) } pieceSize := eestream.CalcPieceSize(int64(segment.EncryptedSize), redundancy) var bytesRepaired int64 // Add the successfully uploaded pieces to repairedPieces var repairedPieces metabase.Pieces repairedMap := make(map[uint16]bool) for i, node := range successfulNodes { if node == nil { continue } bytesRepaired += pieceSize piece := metabase.Piece{ Number: uint16(i), StorageNode: node.Id, } repairedPieces = append(repairedPieces, piece) repairedMap[uint16(i)] = true } mon.Meter("repair_bytes_uploaded").Mark64(bytesRepaired) //mon:locked healthyAfterRepair := numHealthy + len(repairedPieces) switch { case healthyAfterRepair <= int(segment.Redundancy.RepairShares): // Important: this indicates a failure to PUT enough pieces to the network to pass // the repair threshold, and _not_ a failure to reconstruct the segment. But we // put at least one piece, else ec.Repair() would have returned an error. So the // repair "succeeded" in that the segment is now healthier than it was, but it is // not as healthy as we want it to be. mon.Meter("repair_failed").Mark(1) //mon:locked stats.repairFailed.Mark(1) case healthyAfterRepair < int(segment.Redundancy.OptimalShares): mon.Meter("repair_partial").Mark(1) //mon:locked stats.repairPartial.Mark(1) default: mon.Meter("repair_success").Mark(1) //mon:locked stats.repairSuccess.Mark(1) } healthyRatioAfterRepair := 0.0 if segment.Redundancy.TotalShares != 0 { healthyRatioAfterRepair = float64(healthyAfterRepair) / float64(segment.Redundancy.TotalShares) } mon.FloatVal("healthy_ratio_after_repair").Observe(healthyRatioAfterRepair) //mon:locked stats.healthyRatioAfterRepair.Observe(healthyRatioAfterRepair) var toRemove metabase.Pieces if healthyAfterRepair >= int(segment.Redundancy.OptimalShares) { // if full repair, remove all unhealthy pieces for unhealthyPiece := range unhealthyPieces { toRemove = append(toRemove, unhealthyPiece) } } else { // if partial repair, leave unrepaired unhealthy pieces in the pointer for unhealthyPiece := range unhealthyPieces { if repairedMap[unhealthyPiece.Number] { // add only repaired pieces in the slice, unrepaired // unhealthy pieces are not removed from the pointer toRemove = append(toRemove, unhealthyPiece) } } } // add pieces that failed piece hashes verification to the removal list for _, outcome := range piecesReport.Failed { toRemove = append(toRemove, outcome.Piece) } newPieces, err := segment.Pieces.Update(repairedPieces, toRemove) if err != nil { return false, repairPutError.Wrap(err) } err = repairer.metabase.UpdateSegmentPieces(ctx, metabase.UpdateSegmentPieces{ StreamID: segment.StreamID, Position: segment.Position, OldPieces: segment.Pieces, NewRedundancy: segment.Redundancy, NewPieces: newPieces, NewRepairedAt: time.Now(), }) if err != nil { return false, metainfoPutError.Wrap(err) } repairedAt := time.Time{} if segment.RepairedAt != nil { repairedAt = *segment.RepairedAt } var segmentAge time.Duration if segment.CreatedAt.Before(repairedAt) { segmentAge = time.Since(repairedAt) } else { segmentAge = time.Since(segment.CreatedAt) } // TODO what to do with RepairCount var repairCount int64 // pointer.RepairCount++ mon.IntVal("segment_time_until_repair").Observe(int64(segmentAge.Seconds())) //mon:locked stats.segmentTimeUntilRepair.Observe(int64(segmentAge.Seconds())) mon.IntVal("segment_repair_count").Observe(repairCount) //mon:locked stats.segmentRepairCount.Observe(repairCount) repairer.log.Debug("repaired segment", zap.Stringer("Stream ID", segment.StreamID), zap.Uint64("Position", segment.Position.Encode()), zap.Int("clumped pieces", len(piecesCheck.ClumpedPiecesSet)), zap.Int("out of placement pieces", len(piecesCheck.OutOfPlacementPiecesSet)), zap.Int("in excluded countries", numHealthyInExcludedCountries), zap.Int("removed pieces", len(toRemove)), zap.Int("repaired pieces", len(repairedPieces)), zap.Int("healthy before repair", numHealthy), zap.Int("healthy after repair", healthyAfterRepair)) return true, nil } type piecesCheckResult struct { ExcludeNodeIDs []storj.NodeID MissingPiecesSet map[uint16]bool ClumpedPiecesSet map[uint16]bool OutOfPlacementPiecesSet map[uint16]bool NumUnhealthyRetrievable int } func (repairer *SegmentRepairer) classifySegmentPieces(ctx context.Context, segment metabase.Segment) (result piecesCheckResult, err error) { defer mon.Task()(&ctx)(&err) pieces := segment.Pieces allNodeIDs := make([]storj.NodeID, len(pieces)) nodeIDPieceMap := map[storj.NodeID]uint16{} result.MissingPiecesSet = map[uint16]bool{} for i, p := range pieces { allNodeIDs[i] = p.StorageNode nodeIDPieceMap[p.StorageNode] = p.Number result.MissingPiecesSet[p.Number] = true } result.ExcludeNodeIDs = allNodeIDs online, offline, err := repairer.overlay.KnownReliable(ctx, allNodeIDs) if err != nil { return piecesCheckResult{}, overlayQueryError.New("error identifying missing pieces: %w", err) } // remove online nodes from missing pieces for _, onlineNode := range online { pieceNum := nodeIDPieceMap[onlineNode.ID] delete(result.MissingPiecesSet, pieceNum) } if repairer.doDeclumping { // if multiple pieces are on the same last_net, keep only the first one. The rest are // to be considered retrievable but unhealthy. lastNets := make([]string, 0, len(allNodeIDs)) reliablePieces := metabase.Pieces{} collectLastNets := func(reliable []nodeselection.SelectedNode) { for _, node := range reliable { pieceNum := nodeIDPieceMap[node.ID] reliablePieces = append(reliablePieces, metabase.Piece{ Number: pieceNum, StorageNode: node.ID, }) lastNets = append(lastNets, node.LastNet) } } collectLastNets(online) collectLastNets(offline) clumpedPieces := repair.FindClumpedPieces(reliablePieces, lastNets) result.ClumpedPiecesSet = map[uint16]bool{} for _, clumpedPiece := range clumpedPieces { result.ClumpedPiecesSet[clumpedPiece.Number] = true } } if repairer.doPlacementCheck && segment.Placement != storj.EveryCountry { result.OutOfPlacementPiecesSet = map[uint16]bool{} nodeFilters := repairer.placementRules(segment.Placement) checkPlacement := func(reliable []nodeselection.SelectedNode) { for _, node := range reliable { if nodeFilters.MatchInclude(&node) { continue } result.OutOfPlacementPiecesSet[nodeIDPieceMap[node.ID]] = true } } checkPlacement(online) checkPlacement(offline) } result.NumUnhealthyRetrievable = len(result.ClumpedPiecesSet) + len(result.OutOfPlacementPiecesSet) if len(result.ClumpedPiecesSet) != 0 && len(result.OutOfPlacementPiecesSet) != 0 { // verify that some of clumped pieces and out of placement pieces are not the same unhealthyRetrievableSet := map[uint16]bool{} maps.Copy(unhealthyRetrievableSet, result.ClumpedPiecesSet) maps.Copy(unhealthyRetrievableSet, result.OutOfPlacementPiecesSet) result.NumUnhealthyRetrievable = len(unhealthyRetrievableSet) } return result, nil } // checkIfSegmentAltered checks if oldSegment has been altered since it was selected for audit. func (repairer *SegmentRepairer) checkIfSegmentAltered(ctx context.Context, oldSegment metabase.Segment) (err error) { defer mon.Task()(&ctx)(&err) if repairer.OnTestingCheckSegmentAlteredHook != nil { repairer.OnTestingCheckSegmentAlteredHook() } newSegment, err := repairer.metabase.GetSegmentByPosition(ctx, metabase.GetSegmentByPosition{ StreamID: oldSegment.StreamID, Position: oldSegment.Position, }) if err != nil { if metabase.ErrSegmentNotFound.Has(err) { return segmentDeletedError.New("StreamID: %q Position: %d", oldSegment.StreamID.String(), oldSegment.Position.Encode()) } return err } if !oldSegment.Pieces.Equal(newSegment.Pieces) { return segmentModifiedError.New("StreamID: %q Position: %d", oldSegment.StreamID.String(), oldSegment.Position.Encode()) } return nil } func (repairer *SegmentRepairer) getStatsByRS(redundancy *pb.RedundancyScheme) *stats { rsString := getRSString(repairer.loadRedundancy(redundancy)) return repairer.statsCollector.getStatsByRS(rsString) } func (repairer *SegmentRepairer) loadRedundancy(redundancy *pb.RedundancyScheme) (int, int, int, int) { repair := int(redundancy.RepairThreshold) overrideValue := repairer.repairOverrides.GetOverrideValuePB(redundancy) if overrideValue != 0 { repair = int(overrideValue) } return int(redundancy.MinReq), repair, int(redundancy.SuccessThreshold), int(redundancy.Total) } // SetNow allows tests to have the server act as if the current time is whatever they want. func (repairer *SegmentRepairer) SetNow(nowFn func() time.Time) { repairer.nowFn = nowFn } // AdminFetchInfo groups together all the information about a piece that should be retrievable // from storage nodes. type AdminFetchInfo struct { Reader io.ReadCloser Hash *pb.PieceHash GetLimit *pb.AddressedOrderLimit OriginalLimit *pb.OrderLimit FetchError error } // AdminFetchPieces retrieves raw pieces and the associated hashes and original order // limits from the storage nodes on which they are stored, and returns them intact to // the caller rather than decoding or decrypting or verifying anything. This is to be // used for debugging purposes. func (repairer *SegmentRepairer) AdminFetchPieces(ctx context.Context, seg *metabase.Segment, saveDir string) (pieceInfos []AdminFetchInfo, err error) { if seg.Inline() { return nil, errs.New("cannot download an inline segment") } if len(seg.Pieces) < int(seg.Redundancy.RequiredShares) { return nil, errs.New("segment only has %d pieces; needs %d for reconstruction", seg.Pieces, seg.Redundancy.RequiredShares) } // we treat all pieces as "healthy" for our purposes here; we want to download as many // of them as we reasonably can. Thus, we pass in seg.Pieces for 'healthy' getOrderLimits, getPrivateKey, cachedNodesInfo, err := repairer.orders.CreateGetRepairOrderLimits(ctx, *seg, seg.Pieces) if err != nil { return nil, errs.New("could not create order limits: %w", err) } pieceSize := seg.PieceSize() pieceInfos = make([]AdminFetchInfo, len(getOrderLimits)) limiter := sync2.NewLimiter(int(seg.Redundancy.RequiredShares)) for currentLimitIndex, limit := range getOrderLimits { if limit == nil { continue } pieceInfos[currentLimitIndex].GetLimit = limit currentLimitIndex, limit := currentLimitIndex, limit limiter.Go(ctx, func() { info := cachedNodesInfo[limit.GetLimit().StorageNodeId] address := limit.GetStorageNodeAddress().GetAddress() var triedLastIPPort bool if info.LastIPPort != "" && info.LastIPPort != address { address = info.LastIPPort triedLastIPPort = true } pieceReadCloser, hash, originalLimit, err := repairer.ec.downloadAndVerifyPiece(ctx, limit, address, getPrivateKey, saveDir, pieceSize) // if piecestore dial with last ip:port failed try again with node address if triedLastIPPort && piecestore.Error.Has(err) { if pieceReadCloser != nil { _ = pieceReadCloser.Close() } pieceReadCloser, hash, originalLimit, err = repairer.ec.downloadAndVerifyPiece(ctx, limit, limit.GetStorageNodeAddress().GetAddress(), getPrivateKey, saveDir, pieceSize) } pieceInfos[currentLimitIndex].Reader = pieceReadCloser pieceInfos[currentLimitIndex].Hash = hash pieceInfos[currentLimitIndex].OriginalLimit = originalLimit pieceInfos[currentLimitIndex].FetchError = err }) } limiter.Wait() return pieceInfos, nil } // commaSeparatedArray concatenates an array into a comma-separated string, // lazily. type commaSeparatedArray []string func (c commaSeparatedArray) String() string { return strings.Join(c, ", ") }