rclone/fs/accounting/stats.go
Jacob Hands cf5457c2cd fs: Fix transferTime not being set in JSON logs
This was unintentionally broken in 04aa696
2023-08-17 11:19:35 +01:00

894 lines
23 KiB
Go

package accounting
import (
"bytes"
"context"
"errors"
"fmt"
"sort"
"strings"
"sync"
"time"
"github.com/rclone/rclone/fs"
"github.com/rclone/rclone/fs/fserrors"
"github.com/rclone/rclone/fs/rc"
"github.com/rclone/rclone/lib/terminal"
)
const (
averagePeriodLength = time.Second
averageStopAfter = time.Minute
)
// MaxCompletedTransfers specifies maximum number of completed transfers in startedTransfers list
var MaxCompletedTransfers = 100
// StatsInfo accounts all transfers
// N.B.: if this struct is modified, please remember to also update sum() function in stats_groups
// to correctly count the updated fields
type StatsInfo struct {
mu sync.RWMutex
ctx context.Context
ci *fs.ConfigInfo
bytes int64
errors int64
lastError error
fatalError bool
retryError bool
retryAfter time.Time
checks int64
checking *transferMap
checkQueue int
checkQueueSize int64
transfers int64
transferring *transferMap
transferQueue int
transferQueueSize int64
renames int64
renameQueue int
renameQueueSize int64
deletes int64
deletesSize int64
deletedDirs int64
inProgress *inProgress
startedTransfers []*Transfer // currently active transfers
oldTimeRanges timeRanges // a merged list of time ranges for the transfers
oldDuration time.Duration // duration of transfers we have culled
group string
startTime time.Time // the moment these stats were initialized or reset
average averageValues
serverSideCopies int64
serverSideCopyBytes int64
serverSideMoves int64
serverSideMoveBytes int64
}
type averageValues struct {
mu sync.Mutex
lpBytes int64
lpTime time.Time
speed float64
stop chan bool
stopped sync.WaitGroup
startOnce sync.Once
stopOnce sync.Once
}
// NewStats creates an initialised StatsInfo
func NewStats(ctx context.Context) *StatsInfo {
ci := fs.GetConfig(ctx)
return &StatsInfo{
ctx: ctx,
ci: ci,
checking: newTransferMap(ci.Checkers, "checking"),
transferring: newTransferMap(ci.Transfers, "transferring"),
inProgress: newInProgress(ctx),
startTime: time.Now(),
average: averageValues{stop: make(chan bool)},
}
}
// RemoteStats returns stats for rc
func (s *StatsInfo) RemoteStats() (out rc.Params, err error) {
// NB if adding values here - make sure you update the docs in
// stats_groups.go
out = make(rc.Params)
ts := s.calculateTransferStats()
out["totalChecks"] = ts.totalChecks
out["totalTransfers"] = ts.totalTransfers
out["totalBytes"] = ts.totalBytes
out["transferTime"] = ts.transferTime
out["speed"] = ts.speed
s.mu.RLock()
out["bytes"] = s.bytes
out["errors"] = s.errors
out["fatalError"] = s.fatalError
out["retryError"] = s.retryError
out["checks"] = s.checks
out["transfers"] = s.transfers
out["deletes"] = s.deletes
out["deletedDirs"] = s.deletedDirs
out["renames"] = s.renames
out["elapsedTime"] = time.Since(s.startTime).Seconds()
out["serverSideCopies"] = s.serverSideCopies
out["serverSideCopyBytes"] = s.serverSideCopyBytes
out["serverSideMoves"] = s.serverSideMoves
out["serverSideMoveBytes"] = s.serverSideMoveBytes
eta, etaOK := eta(s.bytes, ts.totalBytes, ts.speed)
if etaOK {
out["eta"] = eta.Seconds()
} else {
out["eta"] = nil
}
s.mu.RUnlock()
if !s.checking.empty() {
out["checking"] = s.checking.remotes()
}
if !s.transferring.empty() {
out["transferring"] = s.transferring.rcStats(s.inProgress)
}
if s.errors > 0 {
out["lastError"] = s.lastError.Error()
}
return out, nil
}
// speed returns the average speed of the transfer in bytes/second
//
// Call with lock held
func (s *StatsInfo) speed() float64 {
return s.average.speed
}
// timeRange is a start and end time of a transfer
type timeRange struct {
start time.Time
end time.Time
}
// timeRanges is a list of non-overlapping start and end times for
// transfers
type timeRanges []timeRange
// merge all the overlapping time ranges
func (trs *timeRanges) merge() {
Trs := *trs
// Sort by the starting time.
sort.Slice(Trs, func(i, j int) bool {
return Trs[i].start.Before(Trs[j].start)
})
// Merge overlaps and add distinctive ranges together
var (
newTrs = Trs[:0]
i, j = 0, 1
)
for i < len(Trs) {
if j < len(Trs) {
if !Trs[i].end.Before(Trs[j].start) {
if Trs[i].end.Before(Trs[j].end) {
Trs[i].end = Trs[j].end
}
j++
continue
}
}
newTrs = append(newTrs, Trs[i])
i = j
j++
}
*trs = newTrs
}
// cull remove any ranges whose start and end are before cutoff
// returning their duration sum
func (trs *timeRanges) cull(cutoff time.Time) (d time.Duration) {
var newTrs = (*trs)[:0]
for _, tr := range *trs {
if cutoff.Before(tr.start) || cutoff.Before(tr.end) {
newTrs = append(newTrs, tr)
} else {
d += tr.end.Sub(tr.start)
}
}
*trs = newTrs
return d
}
// total the time out of the time ranges
func (trs timeRanges) total() (total time.Duration) {
for _, tr := range trs {
total += tr.end.Sub(tr.start)
}
return total
}
// Total duration is union of durations of all transfers belonging to this
// object.
// Needs to be protected by mutex.
func (s *StatsInfo) totalDuration() time.Duration {
// copy of s.oldTimeRanges with extra room for the current transfers
timeRanges := make(timeRanges, len(s.oldTimeRanges), len(s.oldTimeRanges)+len(s.startedTransfers))
copy(timeRanges, s.oldTimeRanges)
// Extract time ranges of all transfers.
now := time.Now()
for i := range s.startedTransfers {
start, end := s.startedTransfers[i].TimeRange()
if end.IsZero() {
end = now
}
timeRanges = append(timeRanges, timeRange{start, end})
}
timeRanges.merge()
return s.oldDuration + timeRanges.total()
}
const (
etaMaxSeconds = (1<<63 - 1) / int64(time.Second) // Largest possible ETA as number of seconds
etaMax = time.Duration(etaMaxSeconds) * time.Second // Largest possible ETA, which is in second precision, representing "292y24w3d23h47m16s"
)
// eta returns the ETA of the current operation,
// rounded to full seconds.
// If the ETA cannot be determined 'ok' returns false.
func eta(size, total int64, rate float64) (eta time.Duration, ok bool) {
if total <= 0 || size < 0 || rate <= 0 {
return 0, false
}
remaining := total - size
if remaining < 0 {
return 0, false
}
seconds := int64(float64(remaining) / rate)
if seconds < 0 {
// Got Int64 overflow
eta = etaMax
} else if seconds >= etaMaxSeconds {
// Would get Int64 overflow if converting from seconds to Duration (nanoseconds)
eta = etaMax
} else {
eta = time.Duration(seconds) * time.Second
}
return eta, true
}
// etaString returns the ETA of the current operation,
// rounded to full seconds.
// If the ETA cannot be determined it returns "-"
func etaString(done, total int64, rate float64) string {
d, ok := eta(done, total, rate)
if !ok {
return "-"
}
if d == etaMax {
return "-"
}
return fs.Duration(d).ShortReadableString()
}
// percent returns a/b as a percentage rounded to the nearest integer
// as a string
//
// if the percentage is invalid it returns "-"
func percent(a int64, b int64) string {
if a < 0 || b <= 0 {
return "-"
}
return fmt.Sprintf("%d%%", int(float64(a)*100/float64(b)+0.5))
}
// returned from calculateTransferStats
type transferStats struct {
totalChecks int64
totalTransfers int64
totalBytes int64
transferTime float64
speed float64
}
// calculateTransferStats calculates some additional transfer stats not
// stored directly in StatsInfo
func (s *StatsInfo) calculateTransferStats() (ts transferStats) {
// checking and transferring have their own locking so read
// here before lock to prevent deadlock on GetBytes
transferring, checking := s.transferring.count(), s.checking.count()
transferringBytesDone, transferringBytesTotal := s.transferring.progress(s)
s.mu.RLock()
defer s.mu.RUnlock()
ts.totalChecks = int64(s.checkQueue) + s.checks + int64(checking)
ts.totalTransfers = int64(s.transferQueue) + s.transfers + int64(transferring)
// note that s.bytes already includes transferringBytesDone so
// we take it off here to avoid double counting
ts.totalBytes = s.transferQueueSize + s.bytes + transferringBytesTotal - transferringBytesDone
ts.speed = s.average.speed
dt := s.totalDuration()
ts.transferTime = dt.Seconds()
return ts
}
func (s *StatsInfo) averageLoop() {
var period float64
ticker := time.NewTicker(averagePeriodLength)
defer ticker.Stop()
startTime := time.Now()
a := &s.average
defer a.stopped.Done()
for {
select {
case now := <-ticker.C:
a.mu.Lock()
var elapsed float64
if a.lpTime.IsZero() {
elapsed = now.Sub(startTime).Seconds()
} else {
elapsed = now.Sub(a.lpTime).Seconds()
}
avg := 0.0
if elapsed > 0 {
avg = float64(a.lpBytes) / elapsed
}
if period < averagePeriod {
period++
}
a.speed = (avg + a.speed*(period-1)) / period
a.lpBytes = 0
a.lpTime = now
a.mu.Unlock()
case <-a.stop:
return
}
}
}
func (s *StatsInfo) startAverageLoop() {
s.average.startOnce.Do(func() {
s.average.stopped.Add(1)
go s.averageLoop()
})
}
func (s *StatsInfo) stopAverageLoop() {
s.average.stopOnce.Do(func() {
close(s.average.stop)
s.average.stopped.Wait()
})
}
// String convert the StatsInfo to a string for printing
func (s *StatsInfo) String() string {
// NB if adding more stats in here, remember to add them into
// RemoteStats() too.
ts := s.calculateTransferStats()
s.mu.RLock()
var (
buf = &bytes.Buffer{}
xfrchkString = ""
dateString = ""
elapsedTime = time.Since(s.startTime)
elapsedTimeSecondsOnly = elapsedTime.Truncate(time.Second/10) % time.Minute
displaySpeedString string
)
if s.ci.DataRateUnit == "bits" {
displaySpeedString = fs.SizeSuffix(ts.speed * 8).BitRateUnit()
} else {
displaySpeedString = fs.SizeSuffix(ts.speed).ByteRateUnit()
}
if !s.ci.StatsOneLine {
_, _ = fmt.Fprintf(buf, "\nTransferred: ")
} else {
xfrchk := []string{}
if ts.totalTransfers > 0 && s.transferQueue > 0 {
xfrchk = append(xfrchk, fmt.Sprintf("xfr#%d/%d", s.transfers, ts.totalTransfers))
}
if ts.totalChecks > 0 && s.checkQueue > 0 {
xfrchk = append(xfrchk, fmt.Sprintf("chk#%d/%d", s.checks, ts.totalChecks))
}
if len(xfrchk) > 0 {
xfrchkString = fmt.Sprintf(" (%s)", strings.Join(xfrchk, ", "))
}
if s.ci.StatsOneLineDate {
t := time.Now()
dateString = t.Format(s.ci.StatsOneLineDateFormat) // Including the separator so people can customize it
}
}
_, _ = fmt.Fprintf(buf, "%s%13s / %s, %s, %s, ETA %s%s",
dateString,
fs.SizeSuffix(s.bytes).ByteUnit(),
fs.SizeSuffix(ts.totalBytes).ByteUnit(),
percent(s.bytes, ts.totalBytes),
displaySpeedString,
etaString(s.bytes, ts.totalBytes, ts.speed),
xfrchkString,
)
if s.ci.ProgressTerminalTitle {
// Writes ETA to the terminal title
terminal.WriteTerminalTitle("ETA: " + etaString(s.bytes, ts.totalBytes, ts.speed))
}
if !s.ci.StatsOneLine {
_, _ = buf.WriteRune('\n')
errorDetails := ""
switch {
case s.fatalError:
errorDetails = " (fatal error encountered)"
case s.retryError:
errorDetails = " (retrying may help)"
case s.errors != 0:
errorDetails = " (no need to retry)"
}
// Add only non zero stats
if s.errors != 0 {
_, _ = fmt.Fprintf(buf, "Errors: %10d%s\n",
s.errors, errorDetails)
}
if s.checks != 0 || ts.totalChecks != 0 {
_, _ = fmt.Fprintf(buf, "Checks: %10d / %d, %s\n",
s.checks, ts.totalChecks, percent(s.checks, ts.totalChecks))
}
if s.deletes != 0 || s.deletedDirs != 0 {
_, _ = fmt.Fprintf(buf, "Deleted: %10d (files), %d (dirs)\n", s.deletes, s.deletedDirs)
}
if s.renames != 0 {
_, _ = fmt.Fprintf(buf, "Renamed: %10d\n", s.renames)
}
if s.transfers != 0 || ts.totalTransfers != 0 {
_, _ = fmt.Fprintf(buf, "Transferred: %10d / %d, %s\n",
s.transfers, ts.totalTransfers, percent(s.transfers, ts.totalTransfers))
}
if s.serverSideCopies != 0 || s.serverSideCopyBytes != 0 {
_, _ = fmt.Fprintf(buf, "Server Side Copies:%6d @ %s\n",
s.serverSideCopies, fs.SizeSuffix(s.serverSideCopyBytes).ByteUnit(),
)
}
if s.serverSideMoves != 0 || s.serverSideMoveBytes != 0 {
_, _ = fmt.Fprintf(buf, "Server Side Moves:%7d @ %s\n",
s.serverSideMoves, fs.SizeSuffix(s.serverSideMoveBytes).ByteUnit(),
)
}
_, _ = fmt.Fprintf(buf, "Elapsed time: %10ss\n", strings.TrimRight(fs.Duration(elapsedTime.Truncate(time.Minute)).ReadableString(), "0s")+fmt.Sprintf("%.1f", elapsedTimeSecondsOnly.Seconds()))
}
// checking and transferring have their own locking so unlock
// here to prevent deadlock on GetBytes
s.mu.RUnlock()
// Add per transfer stats if required
if !s.ci.StatsOneLine {
if !s.checking.empty() {
_, _ = fmt.Fprintf(buf, "Checking:\n%s\n", s.checking.String(s.ctx, s.inProgress, s.transferring))
}
if !s.transferring.empty() {
_, _ = fmt.Fprintf(buf, "Transferring:\n%s\n", s.transferring.String(s.ctx, s.inProgress, nil))
}
}
return buf.String()
}
// Transferred returns list of all completed transfers including checked and
// failed ones.
func (s *StatsInfo) Transferred() []TransferSnapshot {
s.mu.RLock()
defer s.mu.RUnlock()
ts := make([]TransferSnapshot, 0, len(s.startedTransfers))
for _, tr := range s.startedTransfers {
if tr.IsDone() {
ts = append(ts, tr.Snapshot())
}
}
return ts
}
// Log outputs the StatsInfo to the log
func (s *StatsInfo) Log() {
if s.ci.UseJSONLog {
out, _ := s.RemoteStats()
fs.LogLevelPrintf(s.ci.StatsLogLevel, nil, "%v%v\n", s, fs.LogValueHide("stats", out))
} else {
fs.LogLevelPrintf(s.ci.StatsLogLevel, nil, "%v\n", s)
}
}
// Bytes updates the stats for bytes bytes
func (s *StatsInfo) Bytes(bytes int64) {
s.average.mu.Lock()
s.average.lpBytes += bytes
s.average.mu.Unlock()
s.mu.Lock()
defer s.mu.Unlock()
s.bytes += bytes
}
// GetBytes returns the number of bytes transferred so far
func (s *StatsInfo) GetBytes() int64 {
s.mu.RLock()
defer s.mu.RUnlock()
return s.bytes
}
// GetBytesWithPending returns the number of bytes transferred and remaining transfers
func (s *StatsInfo) GetBytesWithPending() int64 {
s.mu.RLock()
defer s.mu.RUnlock()
pending := int64(0)
for _, tr := range s.startedTransfers {
if tr.acc != nil {
bytes, size := tr.acc.progress()
if bytes < size {
pending += size - bytes
}
}
}
return s.bytes + pending
}
// Errors updates the stats for errors
func (s *StatsInfo) Errors(errors int64) {
s.mu.Lock()
defer s.mu.Unlock()
s.errors += errors
}
// GetErrors reads the number of errors
func (s *StatsInfo) GetErrors() int64 {
s.mu.RLock()
defer s.mu.RUnlock()
return s.errors
}
// GetLastError returns the lastError
func (s *StatsInfo) GetLastError() error {
s.mu.RLock()
defer s.mu.RUnlock()
return s.lastError
}
// GetChecks returns the number of checks
func (s *StatsInfo) GetChecks() int64 {
s.mu.RLock()
defer s.mu.RUnlock()
return s.checks
}
// FatalError sets the fatalError flag
func (s *StatsInfo) FatalError() {
s.mu.Lock()
defer s.mu.Unlock()
s.fatalError = true
}
// HadFatalError returns whether there has been at least one FatalError
func (s *StatsInfo) HadFatalError() bool {
s.mu.RLock()
defer s.mu.RUnlock()
return s.fatalError
}
// RetryError sets the retryError flag
func (s *StatsInfo) RetryError() {
s.mu.Lock()
defer s.mu.Unlock()
s.retryError = true
}
// HadRetryError returns whether there has been at least one non-NoRetryError
func (s *StatsInfo) HadRetryError() bool {
s.mu.RLock()
defer s.mu.RUnlock()
return s.retryError
}
var (
errMaxDelete = fserrors.FatalError(errors.New("--max-delete threshold reached"))
errMaxDeleteSize = fserrors.FatalError(errors.New("--max-delete-size threshold reached"))
)
// DeleteFile updates the stats for deleting a file
//
// It may return fatal errors if the threshold for --max-delete or
// --max-delete-size have been reached.
func (s *StatsInfo) DeleteFile(ctx context.Context, size int64) error {
ci := fs.GetConfig(ctx)
s.mu.Lock()
defer s.mu.Unlock()
if size < 0 {
size = 0
}
if ci.MaxDelete >= 0 && s.deletes+1 > ci.MaxDelete {
return errMaxDelete
}
if ci.MaxDeleteSize >= 0 && s.deletesSize+size > int64(ci.MaxDeleteSize) {
return errMaxDeleteSize
}
s.deletes++
s.deletesSize += size
return nil
}
// GetDeletes returns the number of deletes
func (s *StatsInfo) GetDeletes() int64 {
s.mu.Lock()
defer s.mu.Unlock()
return s.deletes
}
// DeletedDirs updates the stats for deletedDirs
func (s *StatsInfo) DeletedDirs(deletedDirs int64) int64 {
s.mu.Lock()
defer s.mu.Unlock()
s.deletedDirs += deletedDirs
return s.deletedDirs
}
// Renames updates the stats for renames
func (s *StatsInfo) Renames(renames int64) int64 {
s.mu.Lock()
defer s.mu.Unlock()
s.renames += renames
return s.renames
}
// ResetCounters sets the counters (bytes, checks, errors, transfers, deletes, renames) to 0 and resets lastError, fatalError and retryError
func (s *StatsInfo) ResetCounters() {
s.mu.Lock()
defer s.mu.Unlock()
s.bytes = 0
s.errors = 0
s.lastError = nil
s.fatalError = false
s.retryError = false
s.retryAfter = time.Time{}
s.checks = 0
s.transfers = 0
s.deletes = 0
s.deletesSize = 0
s.deletedDirs = 0
s.renames = 0
s.startedTransfers = nil
s.oldDuration = 0
s.stopAverageLoop()
s.average = averageValues{stop: make(chan bool)}
}
// ResetErrors sets the errors count to 0 and resets lastError, fatalError and retryError
func (s *StatsInfo) ResetErrors() {
s.mu.Lock()
defer s.mu.Unlock()
s.errors = 0
s.lastError = nil
s.fatalError = false
s.retryError = false
s.retryAfter = time.Time{}
}
// Errored returns whether there have been any errors
func (s *StatsInfo) Errored() bool {
s.mu.RLock()
defer s.mu.RUnlock()
return s.errors != 0
}
// Error adds a single error into the stats, assigns lastError and eventually sets fatalError or retryError
func (s *StatsInfo) Error(err error) error {
if err == nil || fserrors.IsCounted(err) {
return err
}
s.mu.Lock()
defer s.mu.Unlock()
s.errors++
s.lastError = err
err = fserrors.FsError(err)
fserrors.Count(err)
switch {
case fserrors.IsFatalError(err):
s.fatalError = true
case fserrors.IsRetryAfterError(err):
retryAfter := fserrors.RetryAfterErrorTime(err)
if s.retryAfter.IsZero() || retryAfter.Sub(s.retryAfter) > 0 {
s.retryAfter = retryAfter
}
s.retryError = true
case !fserrors.IsNoRetryError(err):
s.retryError = true
}
return err
}
// RetryAfter returns the time to retry after if it is set. It will
// be Zero if it isn't set.
func (s *StatsInfo) RetryAfter() time.Time {
s.mu.Lock()
defer s.mu.Unlock()
return s.retryAfter
}
// NewCheckingTransfer adds a checking transfer to the stats, from the object.
func (s *StatsInfo) NewCheckingTransfer(obj fs.DirEntry, what string) *Transfer {
tr := newCheckingTransfer(s, obj, what)
s.checking.add(tr)
return tr
}
// DoneChecking removes a check from the stats
func (s *StatsInfo) DoneChecking(remote string) {
s.checking.del(remote)
s.mu.Lock()
s.checks++
s.mu.Unlock()
}
// GetTransfers reads the number of transfers
func (s *StatsInfo) GetTransfers() int64 {
s.mu.RLock()
defer s.mu.RUnlock()
return s.transfers
}
// NewTransfer adds a transfer to the stats from the object.
func (s *StatsInfo) NewTransfer(obj fs.DirEntry) *Transfer {
tr := newTransfer(s, obj)
s.transferring.add(tr)
s.startAverageLoop()
return tr
}
// NewTransferRemoteSize adds a transfer to the stats based on remote and size.
func (s *StatsInfo) NewTransferRemoteSize(remote string, size int64) *Transfer {
tr := newTransferRemoteSize(s, remote, size, false, "")
s.transferring.add(tr)
s.startAverageLoop()
return tr
}
// DoneTransferring removes a transfer from the stats
//
// if ok is true and it was in the transfermap (to avoid incrementing in case of nested calls, #6213) then it increments the transfers count
func (s *StatsInfo) DoneTransferring(remote string, ok bool) {
existed := s.transferring.del(remote)
if ok && existed {
s.mu.Lock()
s.transfers++
s.mu.Unlock()
}
if s.transferring.empty() && s.checking.empty() {
time.AfterFunc(averageStopAfter, s.stopAverageLoop)
}
}
// SetCheckQueue sets the number of queued checks
func (s *StatsInfo) SetCheckQueue(n int, size int64) {
s.mu.Lock()
s.checkQueue = n
s.checkQueueSize = size
s.mu.Unlock()
}
// SetTransferQueue sets the number of queued transfers
func (s *StatsInfo) SetTransferQueue(n int, size int64) {
s.mu.Lock()
s.transferQueue = n
s.transferQueueSize = size
s.mu.Unlock()
}
// SetRenameQueue sets the number of queued transfers
func (s *StatsInfo) SetRenameQueue(n int, size int64) {
s.mu.Lock()
s.renameQueue = n
s.renameQueueSize = size
s.mu.Unlock()
}
// AddTransfer adds reference to the started transfer.
func (s *StatsInfo) AddTransfer(transfer *Transfer) {
s.mu.Lock()
s.startedTransfers = append(s.startedTransfers, transfer)
s.mu.Unlock()
}
// removeTransfer removes a reference to the started transfer in
// position i.
//
// Must be called with the lock held
func (s *StatsInfo) removeTransfer(transfer *Transfer, i int) {
now := time.Now()
// add finished transfer onto old time ranges
start, end := transfer.TimeRange()
if end.IsZero() {
end = now
}
s.oldTimeRanges = append(s.oldTimeRanges, timeRange{start, end})
s.oldTimeRanges.merge()
// remove the found entry
s.startedTransfers = append(s.startedTransfers[:i], s.startedTransfers[i+1:]...)
// Find youngest active transfer
oldestStart := now
for i := range s.startedTransfers {
start, _ := s.startedTransfers[i].TimeRange()
if start.Before(oldestStart) {
oldestStart = start
}
}
// remove old entries older than that
s.oldDuration += s.oldTimeRanges.cull(oldestStart)
}
// RemoveTransfer removes a reference to the started transfer.
func (s *StatsInfo) RemoveTransfer(transfer *Transfer) {
s.mu.Lock()
for i, tr := range s.startedTransfers {
if tr == transfer {
s.removeTransfer(tr, i)
break
}
}
s.mu.Unlock()
}
// PruneTransfers makes sure there aren't too many old transfers by removing
// single finished transfer.
func (s *StatsInfo) PruneTransfers() {
if MaxCompletedTransfers < 0 {
return
}
s.mu.Lock()
// remove a transfer from the start if we are over quota
if len(s.startedTransfers) > MaxCompletedTransfers+s.ci.Transfers {
for i, tr := range s.startedTransfers {
if tr.IsDone() {
s.removeTransfer(tr, i)
break
}
}
}
s.mu.Unlock()
}
// AddServerSideMove counts a server side move
func (s *StatsInfo) AddServerSideMove(n int64) {
s.mu.Lock()
s.serverSideMoves += 1
s.serverSideMoveBytes += n
s.mu.Unlock()
}
// AddServerSideCopy counts a server side copy
func (s *StatsInfo) AddServerSideCopy(n int64) {
s.mu.Lock()
s.serverSideCopies += 1
s.serverSideCopyBytes += n
s.mu.Unlock()
}