syncthing/lib/db/meta.go

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// Copyright (C) 2017 The Syncthing Authors.
//
// This Source Code Form is subject to the terms of the Mozilla Public
// License, v. 2.0. If a copy of the MPL was not distributed with this file,
// You can obtain one at https://mozilla.org/MPL/2.0/.
package db
import (
"bytes"
"errors"
"fmt"
"math/bits"
"time"
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"github.com/syncthing/syncthing/lib/db/backend"
"github.com/syncthing/syncthing/lib/events"
"github.com/syncthing/syncthing/lib/protocol"
"github.com/syncthing/syncthing/lib/sync"
)
var errMetaInconsistent = errors.New("inconsistent counts detected")
type countsMap struct {
counts CountsSet
indexes map[metaKey]int // device ID + local flags -> index in counts
}
// metadataTracker keeps metadata on a per device, per local flag basis.
type metadataTracker struct {
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keyer keyer
countsMap
mut sync.RWMutex
dirty bool
evLogger events.Logger
}
type metaKey struct {
dev protocol.DeviceID
flag uint32
}
const needFlag uint32 = 1 << 31 // Last bit, as early ones are local flags
func newMetadataTracker(keyer keyer, evLogger events.Logger) *metadataTracker {
return &metadataTracker{
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keyer: keyer,
mut: sync.NewRWMutex(),
countsMap: countsMap{
indexes: make(map[metaKey]int),
},
evLogger: evLogger,
}
}
// Unmarshal loads a metadataTracker from the corresponding protobuf
// representation
func (m *metadataTracker) Unmarshal(bs []byte) error {
if err := m.counts.Unmarshal(bs); err != nil {
return err
}
// Initialize the index map
for i, c := range m.counts.Counts {
dev, err := protocol.DeviceIDFromBytes(c.DeviceID)
if err != nil {
return err
}
m.indexes[metaKey{dev, c.LocalFlags}] = i
}
return nil
}
// Marshal returns the protobuf representation of the metadataTracker
func (m *metadataTracker) Marshal() ([]byte, error) {
return m.counts.Marshal()
}
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func (m *metadataTracker) CommitHook(folder []byte) backend.CommitHook {
return func(t backend.WriteTransaction) error {
return m.toDB(t, folder)
}
}
// toDB saves the marshalled metadataTracker to the given db, under the key
// corresponding to the given folder
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func (m *metadataTracker) toDB(t backend.WriteTransaction, folder []byte) error {
key, err := m.keyer.GenerateFolderMetaKey(nil, folder)
if err != nil {
return err
}
m.mut.RLock()
defer m.mut.RUnlock()
if !m.dirty {
return nil
}
bs, err := m.Marshal()
if err != nil {
return err
}
err = t.Put(key, bs)
if err == nil {
m.dirty = false
}
return err
}
// fromDB initializes the metadataTracker from the marshalled data found in
// the database under the key corresponding to the given folder
func (m *metadataTracker) fromDB(db *Lowlevel, folder []byte) error {
key, err := db.keyer.GenerateFolderMetaKey(nil, folder)
if err != nil {
return err
}
bs, err := db.Get(key)
if err != nil {
return err
}
if err = m.Unmarshal(bs); err != nil {
return err
}
if m.counts.Created == 0 {
return errMetaInconsistent
}
return nil
}
// countsPtr returns a pointer to the corresponding Counts struct, if
// necessary allocating one in the process
func (m *metadataTracker) countsPtr(dev protocol.DeviceID, flag uint32) *Counts {
// must be called with the mutex held
if bits.OnesCount32(flag) > 1 {
panic("incorrect usage: set at most one bit in flag")
}
key := metaKey{dev, flag}
idx, ok := m.indexes[key]
if !ok {
idx = len(m.counts.Counts)
m.counts.Counts = append(m.counts.Counts, Counts{DeviceID: dev[:], LocalFlags: flag})
m.indexes[key] = idx
// Need bucket must be initialized when a device first occurs in
// the metadatatracker, even if there's no change to the need
// bucket itself.
nkey := metaKey{dev, needFlag}
if _, ok := m.indexes[nkey]; !ok {
// Initially a new device needs everything, except deletes
nidx := len(m.counts.Counts)
m.counts.Counts = append(m.counts.Counts, m.allNeededCounts(dev))
m.indexes[nkey] = nidx
}
}
return &m.counts.Counts[idx]
}
// allNeeded makes sure there is a counts in case the device needs everything.
func (m *countsMap) allNeededCounts(dev protocol.DeviceID) Counts {
counts := Counts{}
if idx, ok := m.indexes[metaKey{protocol.GlobalDeviceID, 0}]; ok {
counts = m.counts.Counts[idx]
counts.Deleted = 0 // Don't need deletes if having nothing
}
counts.DeviceID = dev[:]
counts.LocalFlags = needFlag
return counts
}
// addFile adds a file to the counts, adjusting the sequence number as
// appropriate
func (m *metadataTracker) addFile(dev protocol.DeviceID, f protocol.FileIntf) {
m.mut.Lock()
defer m.mut.Unlock()
m.updateSeqLocked(dev, f)
m.updateFileLocked(dev, f, m.addFileLocked)
}
func (m *metadataTracker) updateFileLocked(dev protocol.DeviceID, f protocol.FileIntf, fn func(protocol.DeviceID, uint32, protocol.FileIntf)) {
m.dirty = true
if f.IsInvalid() && (f.FileLocalFlags() == 0 || dev == protocol.GlobalDeviceID) {
// This is a remote invalid file or concern the global state.
// In either case invalid files are not accounted.
return
}
if flags := f.FileLocalFlags(); flags == 0 {
// Account regular files in the zero-flags bucket.
fn(dev, 0, f)
} else {
// Account in flag specific buckets.
eachFlagBit(flags, func(flag uint32) {
fn(dev, flag, f)
})
}
}
// emptyNeeded ensures that there is a need count for the given device and that it is empty.
func (m *metadataTracker) emptyNeeded(dev protocol.DeviceID) {
m.mut.Lock()
defer m.mut.Unlock()
m.dirty = true
empty := Counts{
DeviceID: dev[:],
LocalFlags: needFlag,
}
key := metaKey{dev, needFlag}
if idx, ok := m.indexes[key]; ok {
m.counts.Counts[idx] = empty
return
}
m.indexes[key] = len(m.counts.Counts)
m.counts.Counts = append(m.counts.Counts, empty)
}
// addNeeded adds a file to the needed counts
func (m *metadataTracker) addNeeded(dev protocol.DeviceID, f protocol.FileIntf) {
m.mut.Lock()
defer m.mut.Unlock()
m.dirty = true
m.addFileLocked(dev, needFlag, f)
}
func (m *metadataTracker) Sequence(dev protocol.DeviceID) int64 {
m.mut.Lock()
defer m.mut.Unlock()
return m.countsPtr(dev, 0).Sequence
}
func (m *metadataTracker) updateSeqLocked(dev protocol.DeviceID, f protocol.FileIntf) {
if dev == protocol.GlobalDeviceID {
return
}
if cp := m.countsPtr(dev, 0); f.SequenceNo() > cp.Sequence {
cp.Sequence = f.SequenceNo()
}
}
func (m *metadataTracker) addFileLocked(dev protocol.DeviceID, flag uint32, f protocol.FileIntf) {
cp := m.countsPtr(dev, flag)
switch {
case f.IsDeleted():
cp.Deleted++
case f.IsDirectory() && !f.IsSymlink():
cp.Directories++
case f.IsSymlink():
cp.Symlinks++
default:
cp.Files++
}
cp.Bytes += f.FileSize()
}
// removeFile removes a file from the counts
func (m *metadataTracker) removeFile(dev protocol.DeviceID, f protocol.FileIntf) {
m.mut.Lock()
defer m.mut.Unlock()
m.updateFileLocked(dev, f, m.removeFileLocked)
}
// removeNeeded removes a file from the needed counts
func (m *metadataTracker) removeNeeded(dev protocol.DeviceID, f protocol.FileIntf) {
m.mut.Lock()
defer m.mut.Unlock()
m.dirty = true
m.removeFileLocked(dev, needFlag, f)
}
func (m *metadataTracker) removeFileLocked(dev protocol.DeviceID, flag uint32, f protocol.FileIntf) {
cp := m.countsPtr(dev, flag)
switch {
case f.IsDeleted():
cp.Deleted--
case f.IsDirectory() && !f.IsSymlink():
cp.Directories--
case f.IsSymlink():
cp.Symlinks--
default:
cp.Files--
}
cp.Bytes -= f.FileSize()
// If we've run into an impossible situation, correct it for now and set
// the created timestamp to zero. Next time we start up the metadata
// will be seen as infinitely old and recalculated from scratch.
if cp.Deleted < 0 {
m.evLogger.Log(events.Failure, fmt.Sprintf("meta deleted count for flag 0x%x dropped below zero", flag))
cp.Deleted = 0
m.counts.Created = 0
}
if cp.Files < 0 {
m.evLogger.Log(events.Failure, fmt.Sprintf("meta files count for flag 0x%x dropped below zero", flag))
cp.Files = 0
m.counts.Created = 0
}
if cp.Directories < 0 {
m.evLogger.Log(events.Failure, fmt.Sprintf("meta directories count for flag 0x%x dropped below zero", flag))
cp.Directories = 0
m.counts.Created = 0
}
if cp.Symlinks < 0 {
m.evLogger.Log(events.Failure, fmt.Sprintf("meta deleted count for flag 0x%x dropped below zero", flag))
cp.Symlinks = 0
m.counts.Created = 0
}
}
// resetAll resets all metadata for the given device
func (m *metadataTracker) resetAll(dev protocol.DeviceID) {
m.mut.Lock()
m.dirty = true
for i, c := range m.counts.Counts {
if bytes.Equal(c.DeviceID, dev[:]) {
if c.LocalFlags != needFlag {
m.counts.Counts[i] = Counts{
DeviceID: c.DeviceID,
LocalFlags: c.LocalFlags,
}
} else {
m.counts.Counts[i] = m.allNeededCounts(dev)
}
}
}
m.mut.Unlock()
}
// resetCounts resets the file, dir, etc. counters, while retaining the
// sequence number
func (m *metadataTracker) resetCounts(dev protocol.DeviceID) {
m.mut.Lock()
m.dirty = true
for i, c := range m.counts.Counts {
if bytes.Equal(c.DeviceID, dev[:]) {
m.counts.Counts[i] = Counts{
DeviceID: c.DeviceID,
Sequence: c.Sequence,
LocalFlags: c.LocalFlags,
}
}
}
m.mut.Unlock()
}
func (m *countsMap) Counts(dev protocol.DeviceID, flag uint32) Counts {
if bits.OnesCount32(flag) > 1 {
panic("incorrect usage: set at most one bit in flag")
}
idx, ok := m.indexes[metaKey{dev, flag}]
if !ok {
if flag == needFlag {
// If there's nothing about a device in the index yet,
// it needs everything.
return m.allNeededCounts(dev)
}
return Counts{}
}
return m.counts.Counts[idx]
}
// Snapshot returns a copy of the metadata for reading.
func (m *metadataTracker) Snapshot() *countsMap {
m.mut.RLock()
defer m.mut.RUnlock()
c := &countsMap{
counts: CountsSet{
Counts: make([]Counts, len(m.counts.Counts)),
Created: m.counts.Created,
},
indexes: make(map[metaKey]int, len(m.indexes)),
}
for k, v := range m.indexes {
c.indexes[k] = v
}
for i := range m.counts.Counts {
c.counts.Counts[i] = m.counts.Counts[i]
}
return c
}
// nextLocalSeq allocates a new local sequence number
func (m *metadataTracker) nextLocalSeq() int64 {
m.mut.Lock()
defer m.mut.Unlock()
c := m.countsPtr(protocol.LocalDeviceID, 0)
c.Sequence++
return c.Sequence
}
// devices returns the list of devices tracked, excluding the local device
// (which we don't know the ID of)
func (m *metadataTracker) devices() []protocol.DeviceID {
m.mut.RLock()
defer m.mut.RUnlock()
return m.countsMap.devices()
}
func (m *countsMap) devices() []protocol.DeviceID {
devs := make([]protocol.DeviceID, 0, len(m.counts.Counts))
for _, dev := range m.counts.Counts {
if dev.Sequence > 0 {
id, err := protocol.DeviceIDFromBytes(dev.DeviceID)
if err != nil {
panic(err)
}
if id == protocol.GlobalDeviceID || id == protocol.LocalDeviceID {
continue
}
devs = append(devs, id)
}
}
return devs
}
func (m *metadataTracker) Created() time.Time {
m.mut.RLock()
defer m.mut.RUnlock()
return time.Unix(0, m.counts.Created)
}
func (m *metadataTracker) SetCreated() {
m.mut.Lock()
m.counts.Created = time.Now().UnixNano()
m.dirty = true
m.mut.Unlock()
}
// eachFlagBit calls the function once for every bit that is set in flags
func eachFlagBit(flags uint32, fn func(flag uint32)) {
// Test each bit from the right, as long as there are bits left in the
// flag set. Clear any bits found and stop testing as soon as there are
// no more bits set.
currentBit := uint32(1 << 0)
for flags != 0 {
if flags&currentBit != 0 {
fn(currentBit)
flags &^= currentBit
}
currentBit <<= 1
}
}