storj/satellite/repair/repairer/segments.go

// 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"

	"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/orders"
	"storj.io/storj/satellite/overlay"
	"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

	// 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)
}

// 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,
	repairOverrides checker.RepairOverrides,
	timeout time.Duration, excessOptimalThreshold float64,
) *SegmentRepairer {

	if excessOptimalThreshold < 0 {
		excessOptimalThreshold = 0
	}

	return &SegmentRepairer{
		log:                        log,
		statsCollector:             newStatsCollector(),
		metabase:                   metabase,
		orders:                     orders,
		overlay:                    overlay,
		ec:                         ecRepairer,
		timeout:                    timeout,
		multiplierOptimalThreshold: 1 + excessOptimalThreshold,
		repairOverrides:            repairOverrides.GetMap(),
		reporter:                   reporter,

		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))

	var excludeNodeIDs storj.NodeIDList
	pieces := segment.Pieces
	missingPieces, err := repairer.overlay.GetMissingPieces(ctx, pieces)
	if err != nil {
		return false, overlayQueryError.New("error identifying missing pieces: %w", err)
	}

	numHealthy := len(pieces) - len(missingPieces)
	// irreparable segment
	if numHealthy < 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", numHealthy),
			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) {
		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))
		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 := sliceToSet(missingPieces)

	var healthyPieces, unhealthyPieces metabase.Pieces
	// Populate healthyPieces with all pieces from the segment except those correlating to indices in lostPieces
	for _, piece := range pieces {
		excludeNodeIDs = append(excludeNodeIDs, piece.StorageNode)
		if !lostPiecesSet[piece.Number] {
			healthyPieces = append(healthyPieces, piece)
		} else {
			unhealthyPieces = append(unhealthyPieces, piece)
		}
	}

	// Create the order limits for the GET_REPAIR action
	getOrderLimits, getPrivateKey, cachedNodesInfo, err := repairer.orders.CreateGetRepairOrderLimits(ctx, metabase.BucketLocation{}, segment, healthyPieces)
	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(healthyPieces)),
				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 healthy pieces which became unhealthy inside CreateGetRepairOrderLimits
	// Remove them from healthyPieces and add them to unhealthyPieces
	var newHealthyPieces metabase.Pieces
	for _, piece := range healthyPieces {
		if getOrderLimits[piece.Number] == nil {
			unhealthyPieces = append(unhealthyPieces, piece)
		} else {
			newHealthyPieces = append(newHealthyPieces, piece)
		}
	}
	healthyPieces = newHealthyPieces

	var requestCount int
	var minSuccessfulNeeded int
	{
		totalNeeded := math.Ceil(float64(redundancy.OptimalThreshold()) * repairer.multiplierOptimalThreshold)
		requestCount = int(totalNeeded) - len(healthyPieces) + numHealthyInExcludedCountries
		minSuccessfulNeeded = redundancy.OptimalThreshold() - len(healthyPieces) + numHealthyInExcludedCountries
	}

	// Request Overlay for n-h new storage nodes
	request := overlay.FindStorageNodesRequest{
		RequestedCount: requestCount,
		ExcludedIDs:    excludeNodeIDs,
	}
	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, metabase.BucketLocation{}, segment, getOrderLimits, 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 healthy 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{
		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, outcome.Piece.StorageNode)
	}
	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)
	}
	_, reportErr := repairer.reporter.RecordAudits(ctx, report)
	if reportErr != nil {
		// failed updates should not affect repair, therefore we will not return the error
		repairer.log.Debug("failed to record audit", zap.Error(reportErr))
	}

	// 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 := len(healthyPieces) + 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
		toRemove = unhealthyPieces
	} else {
		// if partial repair, leave unrepaired unhealthy pieces in the pointer
		for _, piece := range unhealthyPieces {
			if repairedMap[piece.Number] {
				// add only repaired pieces in the slice, unrepaired
				// unhealthy pieces are not removed from the pointer
				toRemove = append(toRemove, piece)
			}
		}
	}

	// 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)

	return true, 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")
	}

	redundancy, err := eestream.NewRedundancyStrategyFromStorj(seg.Redundancy)
	if err != nil {
		return nil, errs.New("invalid redundancy strategy: %w", err)
	}

	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, metabase.BucketLocation{}, *seg, seg.Pieces)
	if err != nil {
		return nil, errs.New("could not create order limits: %w", err)
	}

	pieceSize := eestream.CalcPieceSize(int64(seg.EncryptedSize), redundancy)

	pieceInfos = make([]AdminFetchInfo, len(getOrderLimits))
	limiter := sync2.NewLimiter(redundancy.RequiredCount())

	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
}

// sliceToSet converts the given slice to a set.
func sliceToSet(slice []uint16) map[uint16]bool {
	set := make(map[uint16]bool, len(slice))
	for _, value := range slice {
		set[value] = true
	}
	return set
}

// commaSeparatedArray concatenates an array into a comma-separated string,
// lazily.
type commaSeparatedArray []string

func (c commaSeparatedArray) String() string {
	return strings.Join(c, ", ")
}