// Copyright 2016 The go-ethereum Authors
// This file is part of the go-ethereum library.
//
// The go-ethereum library is free software: you can redistribute it and/or modify
// it under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// The go-ethereum library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
// disk storage layer for the package bzz
// DbStore implements the ChunkStore interface and is used by the FileStore as
// persistent storage of chunks
// it implements purging based on access count allowing for external control of
// max capacity
package storage
import (
"archive/tar"
"bytes"
"context"
"encoding/binary"
"encoding/hex"
"errors"
"fmt"
"io"
"io/ioutil"
"sync"
"github.com/ethereum/go-ethereum/metrics"
"github.com/ethereum/go-ethereum/rlp"
"github.com/ethereum/go-ethereum/swarm/log"
"github.com/ethereum/go-ethereum/swarm/storage/mock"
"github.com/syndtr/goleveldb/leveldb"
)
const (
defaultGCRatio = 10
defaultMaxGCRound = 10000
defaultMaxGCBatch = 5000
wEntryCnt = 1 << 0
wIndexCnt = 1 << 1
wAccessCnt = 1 << 2
)
var (
dbEntryCount = metrics . NewRegisteredCounter ( "ldbstore.entryCnt" , nil )
)
var (
keyIndex = byte ( 0 )
keyAccessCnt = [ ] byte { 2 }
keyEntryCnt = [ ] byte { 3 }
keyDataIdx = [ ] byte { 4 }
keyData = byte ( 6 )
keyDistanceCnt = byte ( 7 )
keySchema = [ ] byte { 8 }
keyGCIdx = byte ( 9 ) // access to chunk data index, used by garbage collection in ascending order from first entry
)
var (
ErrDBClosed = errors . New ( "LDBStore closed" )
)
type LDBStoreParams struct {
* StoreParams
Path string
Po func ( Address ) uint8
}
// NewLDBStoreParams constructs LDBStoreParams with the specified values.
func NewLDBStoreParams ( storeparams * StoreParams , path string ) * LDBStoreParams {
return & LDBStoreParams {
StoreParams : storeparams ,
Path : path ,
Po : func ( k Address ) ( ret uint8 ) { return uint8 ( Proximity ( storeparams . BaseKey , k [ : ] ) ) } ,
}
}
type garbage struct {
maxRound int // maximum number of chunks to delete in one garbage collection round
maxBatch int // maximum number of chunks to delete in one db request batch
ratio int // 1/x ratio to calculate the number of chunks to gc on a low capacity db
count int // number of chunks deleted in running round
target int // number of chunks to delete in running round
batch * dbBatch // the delete batch
runC chan struct { } // struct in chan means gc is NOT running
}
type LDBStore struct {
db * LDBDatabase
// this should be stored in db, accessed transactionally
entryCnt uint64 // number of items in the LevelDB
accessCnt uint64 // ever-accumulating number increased every time we read/access an entry
dataIdx uint64 // similar to entryCnt, but we only increment it
capacity uint64
bucketCnt [ ] uint64
hashfunc SwarmHasher
po func ( Address ) uint8
batchesC chan struct { }
closed bool
batch * dbBatch
lock sync . RWMutex
quit chan struct { }
gc * garbage
// Functions encodeDataFunc is used to bypass
// the default functionality of DbStore with
// mock.NodeStore for testing purposes.
encodeDataFunc func ( chunk Chunk ) [ ] byte
// If getDataFunc is defined, it will be used for
// retrieving the chunk data instead from the local
// LevelDB database.
getDataFunc func ( key Address ) ( data [ ] byte , err error )
}
type dbBatch struct {
* leveldb . Batch
err error
c chan struct { }
}
func newBatch ( ) * dbBatch {
return & dbBatch { Batch : new ( leveldb . Batch ) , c : make ( chan struct { } ) }
}
// TODO: Instead of passing the distance function, just pass the address from which distances are calculated
// to avoid the appearance of a pluggable distance metric and opportunities of bugs associated with providing
// a function different from the one that is actually used.
func NewLDBStore ( params * LDBStoreParams ) ( s * LDBStore , err error ) {
s = new ( LDBStore )
s . hashfunc = params . Hash
s . quit = make ( chan struct { } )
s . batchesC = make ( chan struct { } , 1 )
go s . writeBatches ( )
s . batch = newBatch ( )
// associate encodeData with default functionality
s . encodeDataFunc = encodeData
s . db , err = NewLDBDatabase ( params . Path )
if err != nil {
return nil , err
}
s . po = params . Po
s . setCapacity ( params . DbCapacity )
s . bucketCnt = make ( [ ] uint64 , 0x100 )
for i := 0 ; i < 0x100 ; i ++ {
k := make ( [ ] byte , 2 )
k [ 0 ] = keyDistanceCnt
k [ 1 ] = uint8 ( i )
cnt , _ := s . db . Get ( k )
s . bucketCnt [ i ] = BytesToU64 ( cnt )
}
data , _ := s . db . Get ( keyEntryCnt )
s . entryCnt = BytesToU64 ( data )
data , _ = s . db . Get ( keyAccessCnt )
s . accessCnt = BytesToU64 ( data )
data , _ = s . db . Get ( keyDataIdx )
s . dataIdx = BytesToU64 ( data )
// set up garbage collection
s . gc = & garbage {
maxBatch : defaultMaxGCBatch ,
maxRound : defaultMaxGCRound ,
ratio : defaultGCRatio ,
}
s . gc . runC = make ( chan struct { } , 1 )
s . gc . runC <- struct { } { }
return s , nil
}
// MarkAccessed increments the access counter as a best effort for a chunk, so
// the chunk won't get garbage collected.
func ( s * LDBStore ) MarkAccessed ( addr Address ) {
s . lock . Lock ( )
defer s . lock . Unlock ( )
if s . closed {
return
}
proximity := s . po ( addr )
s . tryAccessIdx ( addr , proximity )
}
// initialize and set values for processing of gc round
func ( s * LDBStore ) startGC ( c int ) {
s . gc . count = 0
// calculate the target number of deletions
if c >= s . gc . maxRound {
s . gc . target = s . gc . maxRound
} else {
s . gc . target = c / s . gc . ratio
}
s . gc . batch = newBatch ( )
log . Debug ( "startgc" , "requested" , c , "target" , s . gc . target )
}
// NewMockDbStore creates a new instance of DbStore with
// mockStore set to a provided value. If mockStore argument is nil,
// this function behaves exactly as NewDbStore.
func NewMockDbStore ( params * LDBStoreParams , mockStore * mock . NodeStore ) ( s * LDBStore , err error ) {
s , err = NewLDBStore ( params )
if err != nil {
return nil , err
}
// replace put and get with mock store functionality
if mockStore != nil {
s . encodeDataFunc = newMockEncodeDataFunc ( mockStore )
s . getDataFunc = newMockGetDataFunc ( mockStore )
}
return
}
type dpaDBIndex struct {
Idx uint64
Access uint64
}
func BytesToU64 ( data [ ] byte ) uint64 {
if len ( data ) < 8 {
return 0
}
return binary . BigEndian . Uint64 ( data )
}
func U64ToBytes ( val uint64 ) [ ] byte {
data := make ( [ ] byte , 8 )
binary . BigEndian . PutUint64 ( data , val )
return data
}
func getIndexKey ( hash Address ) [ ] byte {
hashSize := len ( hash )
key := make ( [ ] byte , hashSize + 1 )
key [ 0 ] = keyIndex
copy ( key [ 1 : ] , hash [ : ] )
return key
}
func getDataKey ( idx uint64 , po uint8 ) [ ] byte {
key := make ( [ ] byte , 10 )
key [ 0 ] = keyData
key [ 1 ] = po
binary . BigEndian . PutUint64 ( key [ 2 : ] , idx )
return key
}
func getGCIdxKey ( index * dpaDBIndex ) [ ] byte {
key := make ( [ ] byte , 9 )
key [ 0 ] = keyGCIdx
binary . BigEndian . PutUint64 ( key [ 1 : ] , index . Access )
return key
}
func getGCIdxValue ( index * dpaDBIndex , po uint8 , addr Address ) [ ] byte {
val := make ( [ ] byte , 41 ) // po = 1, index.Index = 8, Address = 32
val [ 0 ] = po
binary . BigEndian . PutUint64 ( val [ 1 : ] , index . Idx )
copy ( val [ 9 : ] , addr )
return val
}
func parseIdxKey ( key [ ] byte ) ( byte , [ ] byte ) {
return key [ 0 ] , key [ 1 : ]
}
func parseGCIdxEntry ( accessCnt [ ] byte , val [ ] byte ) ( index * dpaDBIndex , po uint8 , addr Address ) {
index = & dpaDBIndex {
Idx : binary . BigEndian . Uint64 ( val [ 1 : ] ) ,
Access : binary . BigEndian . Uint64 ( accessCnt ) ,
}
po = val [ 0 ]
addr = val [ 9 : ]
return
}
func encodeIndex ( index * dpaDBIndex ) [ ] byte {
data , _ := rlp . EncodeToBytes ( index )
return data
}
func encodeData ( chunk Chunk ) [ ] byte {
// Always create a new underlying array for the returned byte slice.
// The chunk.Address array may be used in the returned slice which
// may be changed later in the code or by the LevelDB, resulting
// that the Address is changed as well.
return append ( append ( [ ] byte { } , chunk . Address ( ) [ : ] ... ) , chunk . Data ( ) ... )
}
func decodeIndex ( data [ ] byte , index * dpaDBIndex ) error {
dec := rlp . NewStream ( bytes . NewReader ( data ) , 0 )
return dec . Decode ( index )
}
func decodeData ( addr Address , data [ ] byte ) ( * chunk , error ) {
return NewChunk ( addr , data [ 32 : ] ) , nil
}
func ( s * LDBStore ) collectGarbage ( ) error {
// prevent duplicate gc from starting when one is already running
select {
case <- s . gc . runC :
default :
return nil
}
s . lock . Lock ( )
entryCnt := s . entryCnt
s . lock . Unlock ( )
metrics . GetOrRegisterCounter ( "ldbstore.collectgarbage" , nil ) . Inc ( 1 )
// calculate the amount of chunks to collect and reset counter
s . startGC ( int ( entryCnt ) )
log . Debug ( "collectGarbage" , "target" , s . gc . target , "entryCnt" , entryCnt )
for s . gc . count < s . gc . target {
it := s . db . NewIterator ( )
ok := it . Seek ( [ ] byte { keyGCIdx } )
var singleIterationCount int
// every batch needs a lock so we avoid entries changing accessidx in the meantime
s . lock . Lock ( )
for ; ok && ( singleIterationCount < s . gc . maxBatch ) ; ok = it . Next ( ) {
// quit if no more access index keys
itkey := it . Key ( )
if ( itkey == nil ) || ( itkey [ 0 ] != keyGCIdx ) {
break
}
// get chunk data entry from access index
val := it . Value ( )
index , po , hash := parseGCIdxEntry ( itkey [ 1 : ] , val )
keyIdx := make ( [ ] byte , 33 )
keyIdx [ 0 ] = keyIndex
copy ( keyIdx [ 1 : ] , hash )
// add delete operation to batch
s . delete ( s . gc . batch . Batch , index , keyIdx , po )
singleIterationCount ++
s . gc . count ++
log . Trace ( "garbage collect enqueued chunk for deletion" , "key" , hash )
// break if target is not on max garbage batch boundary
if s . gc . count >= s . gc . target {
break
}
}
s . writeBatch ( s . gc . batch , wEntryCnt )
log . Trace ( "garbage collect batch done" , "batch" , singleIterationCount , "total" , s . gc . count )
s . lock . Unlock ( )
it . Release ( )
}
metrics . GetOrRegisterCounter ( "ldbstore.collectgarbage.delete" , nil ) . Inc ( int64 ( s . gc . count ) )
log . Debug ( "garbage collect done" , "c" , s . gc . count )
s . gc . runC <- struct { } { }
return nil
}
// Export writes all chunks from the store to a tar archive, returning the
// number of chunks written.
func ( s * LDBStore ) Export ( out io . Writer ) ( int64 , error ) {
tw := tar . NewWriter ( out )
defer tw . Close ( )
it := s . db . NewIterator ( )
defer it . Release ( )
var count int64
for ok := it . Seek ( [ ] byte { keyIndex } ) ; ok ; ok = it . Next ( ) {
key := it . Key ( )
if ( key == nil ) || ( key [ 0 ] != keyIndex ) {
break
}
var index dpaDBIndex
hash := key [ 1 : ]
decodeIndex ( it . Value ( ) , & index )
po := s . po ( hash )
datakey := getDataKey ( index . Idx , po )
log . Trace ( "store.export" , "dkey" , fmt . Sprintf ( "%x" , datakey ) , "dataidx" , index . Idx , "po" , po )
data , err := s . db . Get ( datakey )
if err != nil {
log . Warn ( fmt . Sprintf ( "Chunk %x found but could not be accessed: %v" , key , err ) )
continue
}
hdr := & tar . Header {
Name : hex . EncodeToString ( hash ) ,
Mode : 0644 ,
Size : int64 ( len ( data ) ) ,
}
if err := tw . WriteHeader ( hdr ) ; err != nil {
return count , err
}
if _ , err := tw . Write ( data ) ; err != nil {
return count , err
}
count ++
}
return count , nil
}
// of chunks read.
func ( s * LDBStore ) Import ( in io . Reader ) ( int64 , error ) {
tr := tar . NewReader ( in )
ctx , cancel := context . WithCancel ( context . Background ( ) )
defer cancel ( )
countC := make ( chan int64 )
errC := make ( chan error )
var count int64
go func ( ) {
for {
hdr , err := tr . Next ( )
if err == io . EOF {
break
} else if err != nil {
select {
case errC <- err :
case <- ctx . Done ( ) :
}
}
if len ( hdr . Name ) != 64 {
log . Warn ( "ignoring non-chunk file" , "name" , hdr . Name )
continue
}
keybytes , err := hex . DecodeString ( hdr . Name )
if err != nil {
log . Warn ( "ignoring invalid chunk file" , "name" , hdr . Name , "err" , err )
continue
}
data , err := ioutil . ReadAll ( tr )
if err != nil {
select {
case errC <- err :
case <- ctx . Done ( ) :
}
}
key := Address ( keybytes )
chunk := NewChunk ( key , data [ 32 : ] )
go func ( ) {
select {
case errC <- s . Put ( ctx , chunk ) :
case <- ctx . Done ( ) :
}
} ( )
count ++
}
countC <- count
} ( )
// wait for all chunks to be stored
i := int64 ( 0 )
var total int64
for {
select {
case err := <- errC :
if err != nil {
return count , err
}
i ++
case total = <- countC :
case <- ctx . Done ( ) :
return i , ctx . Err ( )
}
if total > 0 && i == total {
return total , nil
}
}
}
// Cleanup iterates over the database and deletes chunks if they pass the `f` condition
func ( s * LDBStore ) Cleanup ( f func ( * chunk ) bool ) {
var errorsFound , removed , total int
it := s . db . NewIterator ( )
defer it . Release ( )
for ok := it . Seek ( [ ] byte { keyIndex } ) ; ok ; ok = it . Next ( ) {
key := it . Key ( )
if ( key == nil ) || ( key [ 0 ] != keyIndex ) {
break
}
total ++
var index dpaDBIndex
err := decodeIndex ( it . Value ( ) , & index )
if err != nil {
log . Warn ( "Cannot decode" )
errorsFound ++
continue
}
hash := key [ 1 : ]
po := s . po ( hash )
datakey := getDataKey ( index . Idx , po )
data , err := s . db . Get ( datakey )
if err != nil {
found := false
// The highest possible proximity is 255, so exit loop upon overflow.
for po = uint8 ( 1 ) ; po != 0 ; po ++ {
datakey = getDataKey ( index . Idx , po )
data , err = s . db . Get ( datakey )
if err == nil {
found = true
break
}
}
if ! found {
log . Warn ( fmt . Sprintf ( "Chunk %x found but count not be accessed with any po" , key ) )
errorsFound ++
continue
}
}
ck := data [ : 32 ]
c , err := decodeData ( ck , data )
if err != nil {
log . Error ( "decodeData error" , "err" , err )
continue
}
cs := int64 ( binary . LittleEndian . Uint64 ( c . sdata [ : 8 ] ) )
log . Trace ( "chunk" , "key" , fmt . Sprintf ( "%x" , key ) , "ck" , fmt . Sprintf ( "%x" , ck ) , "dkey" , fmt . Sprintf ( "%x" , datakey ) , "dataidx" , index . Idx , "po" , po , "len data" , len ( data ) , "len sdata" , len ( c . sdata ) , "size" , cs )
// if chunk is to be removed
if f ( c ) {
log . Warn ( "chunk for cleanup" , "key" , fmt . Sprintf ( "%x" , key ) , "ck" , fmt . Sprintf ( "%x" , ck ) , "dkey" , fmt . Sprintf ( "%x" , datakey ) , "dataidx" , index . Idx , "po" , po , "len data" , len ( data ) , "len sdata" , len ( c . sdata ) , "size" , cs )
s . deleteNow ( & index , getIndexKey ( key [ 1 : ] ) , po )
removed ++
errorsFound ++
}
}
log . Warn ( fmt . Sprintf ( "Found %v errors out of %v entries. Removed %v chunks." , errorsFound , total , removed ) )
}
// CleanGCIndex rebuilds the garbage collector index from scratch, while
// removing inconsistent elements, e.g., indices with missing data chunks.
// WARN: it's a pretty heavy, long running function.
func ( s * LDBStore ) CleanGCIndex ( ) error {
s . lock . Lock ( )
defer s . lock . Unlock ( )
batch := leveldb . Batch { }
var okEntryCount uint64
var totalEntryCount uint64
// throw out all gc indices, we will rebuild from cleaned index
it := s . db . NewIterator ( )
it . Seek ( [ ] byte { keyGCIdx } )
var gcDeletes int
for it . Valid ( ) {
rowType , _ := parseIdxKey ( it . Key ( ) )
if rowType != keyGCIdx {
break
}
batch . Delete ( it . Key ( ) )
gcDeletes ++
it . Next ( )
}
log . Debug ( "gc" , "deletes" , gcDeletes )
if err := s . db . Write ( & batch ) ; err != nil {
return err
}
batch . Reset ( )
it . Release ( )
// corrected po index pointer values
var poPtrs [ 256 ] uint64
// set to true if chunk count not on 4096 iteration boundary
var doneIterating bool
// last key index in previous iteration
lastIdxKey := [ ] byte { keyIndex }
// counter for debug output
var cleanBatchCount int
// go through all key index entries
for ! doneIterating {
cleanBatchCount ++
var idxs [ ] dpaDBIndex
var chunkHashes [ ] [ ] byte
var pos [ ] uint8
it := s . db . NewIterator ( )
it . Seek ( lastIdxKey )
// 4096 is just a nice number, don't look for any hidden meaning here...
var i int
for i = 0 ; i < 4096 ; i ++ {
// this really shouldn't happen unless database is empty
// but let's keep it to be safe
if ! it . Valid ( ) {
doneIterating = true
break
}
// if it's not keyindex anymore we're done iterating
rowType , chunkHash := parseIdxKey ( it . Key ( ) )
if rowType != keyIndex {
doneIterating = true
break
}
// decode the retrieved index
var idx dpaDBIndex
err := decodeIndex ( it . Value ( ) , & idx )
if err != nil {
return fmt . Errorf ( "corrupt index: %v" , err )
}
po := s . po ( chunkHash )
lastIdxKey = it . Key ( )
// if we don't find the data key, remove the entry
// if we find it, add to the array of new gc indices to create
dataKey := getDataKey ( idx . Idx , po )
_ , err = s . db . Get ( dataKey )
if err != nil {
log . Warn ( "deleting inconsistent index (missing data)" , "key" , chunkHash )
batch . Delete ( it . Key ( ) )
} else {
idxs = append ( idxs , idx )
chunkHashes = append ( chunkHashes , chunkHash )
pos = append ( pos , po )
okEntryCount ++
if idx . Idx > poPtrs [ po ] {
poPtrs [ po ] = idx . Idx
}
}
totalEntryCount ++
it . Next ( )
}
it . Release ( )
// flush the key index corrections
err := s . db . Write ( & batch )
if err != nil {
return err
}
batch . Reset ( )
// add correct gc indices
for i , okIdx := range idxs {
gcIdxKey := getGCIdxKey ( & okIdx )
gcIdxData := getGCIdxValue ( & okIdx , pos [ i ] , chunkHashes [ i ] )
batch . Put ( gcIdxKey , gcIdxData )
log . Trace ( "clean ok" , "key" , chunkHashes [ i ] , "gcKey" , gcIdxKey , "gcData" , gcIdxData )
}
// flush them
err = s . db . Write ( & batch )
if err != nil {
return err
}
batch . Reset ( )
log . Debug ( "clean gc index pass" , "batch" , cleanBatchCount , "checked" , i , "kept" , len ( idxs ) )
}
log . Debug ( "gc cleanup entries" , "ok" , okEntryCount , "total" , totalEntryCount , "batchlen" , batch . Len ( ) )
// lastly add updated entry count
var entryCount [ 8 ] byte
binary . BigEndian . PutUint64 ( entryCount [ : ] , okEntryCount )
batch . Put ( keyEntryCnt , entryCount [ : ] )
// and add the new po index pointers
var poKey [ 2 ] byte
poKey [ 0 ] = keyDistanceCnt
for i , poPtr := range poPtrs {
poKey [ 1 ] = uint8 ( i )
if poPtr == 0 {
batch . Delete ( poKey [ : ] )
} else {
var idxCount [ 8 ] byte
binary . BigEndian . PutUint64 ( idxCount [ : ] , poPtr )
batch . Put ( poKey [ : ] , idxCount [ : ] )
}
}
// if you made it this far your harddisk has survived. Congratulations
return s . db . Write ( & batch )
}
// Delete is removes a chunk and updates indices.
// Is thread safe
func ( s * LDBStore ) Delete ( addr Address ) error {
s . lock . Lock ( )
defer s . lock . Unlock ( )
ikey := getIndexKey ( addr )
idata , err := s . db . Get ( ikey )
if err != nil {
return err
}
var idx dpaDBIndex
decodeIndex ( idata , & idx )
proximity := s . po ( addr )
return s . deleteNow ( & idx , ikey , proximity )
}
// executes one delete operation immediately
// see *LDBStore.delete
func ( s * LDBStore ) deleteNow ( idx * dpaDBIndex , idxKey [ ] byte , po uint8 ) error {
batch := new ( leveldb . Batch )
s . delete ( batch , idx , idxKey , po )
return s . db . Write ( batch )
}
// adds a delete chunk operation to the provided batch
// if called directly, decrements entrycount regardless if the chunk exists upon deletion. Risk of wrap to max uint64
func ( s * LDBStore ) delete ( batch * leveldb . Batch , idx * dpaDBIndex , idxKey [ ] byte , po uint8 ) {
metrics . GetOrRegisterCounter ( "ldbstore.delete" , nil ) . Inc ( 1 )
gcIdxKey := getGCIdxKey ( idx )
batch . Delete ( gcIdxKey )
dataKey := getDataKey ( idx . Idx , po )
batch . Delete ( dataKey )
batch . Delete ( idxKey )
s . entryCnt --
dbEntryCount . Dec ( 1 )
cntKey := make ( [ ] byte , 2 )
cntKey [ 0 ] = keyDistanceCnt
cntKey [ 1 ] = po
batch . Put ( keyEntryCnt , U64ToBytes ( s . entryCnt ) )
batch . Put ( cntKey , U64ToBytes ( s . bucketCnt [ po ] ) )
}
func ( s * LDBStore ) BinIndex ( po uint8 ) uint64 {
s . lock . RLock ( )
defer s . lock . RUnlock ( )
return s . bucketCnt [ po ]
}
// Put adds a chunk to the database, adding indices and incrementing global counters.
// If it already exists, it merely increments the access count of the existing entry.
// Is thread safe
func ( s * LDBStore ) Put ( ctx context . Context , chunk Chunk ) error {
metrics . GetOrRegisterCounter ( "ldbstore.put" , nil ) . Inc ( 1 )
log . Trace ( "ldbstore.put" , "key" , chunk . Address ( ) )
ikey := getIndexKey ( chunk . Address ( ) )
var index dpaDBIndex
po := s . po ( chunk . Address ( ) )
s . lock . Lock ( )
if s . closed {
s . lock . Unlock ( )
return ErrDBClosed
}
batch := s . batch
log . Trace ( "ldbstore.put: s.db.Get" , "key" , chunk . Address ( ) , "ikey" , fmt . Sprintf ( "%x" , ikey ) )
_ , err := s . db . Get ( ikey )
if err != nil {
s . doPut ( chunk , & index , po )
}
idata := encodeIndex ( & index )
s . batch . Put ( ikey , idata )
// add the access-chunkindex index for garbage collection
gcIdxKey := getGCIdxKey ( & index )
gcIdxData := getGCIdxValue ( & index , po , chunk . Address ( ) )
s . batch . Put ( gcIdxKey , gcIdxData )
s . lock . Unlock ( )
select {
case s . batchesC <- struct { } { } :
default :
}
select {
case <- batch . c :
return batch . err
case <- ctx . Done ( ) :
return ctx . Err ( )
}
}
// force putting into db, does not check or update necessary indices
func ( s * LDBStore ) doPut ( chunk Chunk , index * dpaDBIndex , po uint8 ) {
data := s . encodeDataFunc ( chunk )
dkey := getDataKey ( s . dataIdx , po )
s . batch . Put ( dkey , data )
index . Idx = s . dataIdx
s . bucketCnt [ po ] = s . dataIdx
s . entryCnt ++
dbEntryCount . Inc ( 1 )
s . dataIdx ++
index . Access = s . accessCnt
s . accessCnt ++
cntKey := make ( [ ] byte , 2 )
cntKey [ 0 ] = keyDistanceCnt
cntKey [ 1 ] = po
s . batch . Put ( cntKey , U64ToBytes ( s . bucketCnt [ po ] ) )
}
func ( s * LDBStore ) writeBatches ( ) {
for {
select {
case <- s . quit :
log . Debug ( "DbStore: quit batch write loop" )
return
case <- s . batchesC :
err := s . writeCurrentBatch ( )
if err != nil {
log . Debug ( "DbStore: quit batch write loop" , "err" , err . Error ( ) )
return
}
}
}
}
func ( s * LDBStore ) writeCurrentBatch ( ) error {
s . lock . Lock ( )
defer s . lock . Unlock ( )
b := s . batch
l := b . Len ( )
if l == 0 {
return nil
}
s . batch = newBatch ( )
b . err = s . writeBatch ( b , wEntryCnt | wAccessCnt | wIndexCnt )
close ( b . c )
if s . entryCnt >= s . capacity {
go s . collectGarbage ( )
}
return nil
}
// must be called non concurrently
func ( s * LDBStore ) writeBatch ( b * dbBatch , wFlag uint8 ) error {
if wFlag & wEntryCnt > 0 {
b . Put ( keyEntryCnt , U64ToBytes ( s . entryCnt ) )
}
if wFlag & wIndexCnt > 0 {
b . Put ( keyDataIdx , U64ToBytes ( s . dataIdx ) )
}
if wFlag & wAccessCnt > 0 {
b . Put ( keyAccessCnt , U64ToBytes ( s . accessCnt ) )
}
l := b . Len ( )
if err := s . db . Write ( b . Batch ) ; err != nil {
return fmt . Errorf ( "unable to write batch: %v" , err )
}
log . Trace ( fmt . Sprintf ( "batch write (%d entries)" , l ) )
return nil
}
// newMockEncodeDataFunc returns a function that stores the chunk data
// to a mock store to bypass the default functionality encodeData.
// The constructed function always returns the nil data, as DbStore does
// not need to store the data, but still need to create the index.
func newMockEncodeDataFunc ( mockStore * mock . NodeStore ) func ( chunk Chunk ) [ ] byte {
return func ( chunk Chunk ) [ ] byte {
if err := mockStore . Put ( chunk . Address ( ) , encodeData ( chunk ) ) ; err != nil {
log . Error ( fmt . Sprintf ( "%T: Chunk %v put: %v" , mockStore , chunk . Address ( ) . Log ( ) , err ) )
}
return chunk . Address ( ) [ : ]
}
}
// tryAccessIdx tries to find index entry. If found then increments the access
// count for garbage collection and returns the index entry and true for found,
// otherwise returns nil and false.
func ( s * LDBStore ) tryAccessIdx ( addr Address , po uint8 ) ( * dpaDBIndex , bool ) {
ikey := getIndexKey ( addr )
idata , err := s . db . Get ( ikey )
if err != nil {
return nil , false
}
index := new ( dpaDBIndex )
decodeIndex ( idata , index )
oldGCIdxKey := getGCIdxKey ( index )
s . batch . Put ( keyAccessCnt , U64ToBytes ( s . accessCnt ) )
index . Access = s . accessCnt
idata = encodeIndex ( index )
s . accessCnt ++
s . batch . Put ( ikey , idata )
newGCIdxKey := getGCIdxKey ( index )
newGCIdxData := getGCIdxValue ( index , po , ikey [ 1 : ] )
s . batch . Delete ( oldGCIdxKey )
s . batch . Put ( newGCIdxKey , newGCIdxData )
select {
case s . batchesC <- struct { } { } :
default :
}
return index , true
}
// GetSchema is returning the current named schema of the datastore as read from LevelDB
func ( s * LDBStore ) GetSchema ( ) ( string , error ) {
s . lock . Lock ( )
defer s . lock . Unlock ( )
data , err := s . db . Get ( keySchema )
if err != nil {
if err == leveldb . ErrNotFound {
return DbSchemaNone , nil
}
return "" , err
}
return string ( data ) , nil
}
// PutSchema is saving a named schema to the LevelDB datastore
func ( s * LDBStore ) PutSchema ( schema string ) error {
s . lock . Lock ( )
defer s . lock . Unlock ( )
return s . db . Put ( keySchema , [ ] byte ( schema ) )
}
// Get retrieves the chunk matching the provided key from the database.
// If the chunk entry does not exist, it returns an error
// Updates access count and is thread safe
func ( s * LDBStore ) Get ( _ context . Context , addr Address ) ( chunk Chunk , err error ) {
metrics . GetOrRegisterCounter ( "ldbstore.get" , nil ) . Inc ( 1 )
log . Trace ( "ldbstore.get" , "key" , addr )
s . lock . Lock ( )
defer s . lock . Unlock ( )
return s . get ( addr )
}
// Has queries the underlying DB if a chunk with the given address is stored
// Returns true if the chunk is found, false if not
func ( s * LDBStore ) Has ( _ context . Context , addr Address ) bool {
s . lock . RLock ( )
defer s . lock . RUnlock ( )
ikey := getIndexKey ( addr )
_ , err := s . db . Get ( ikey )
return err == nil
}
// TODO: To conform with other private methods of this object indices should not be updated
func ( s * LDBStore ) get ( addr Address ) ( chunk * chunk , err error ) {
if s . closed {
return nil , ErrDBClosed
}
proximity := s . po ( addr )
index , found := s . tryAccessIdx ( addr , proximity )
if found {
var data [ ] byte
if s . getDataFunc != nil {
// if getDataFunc is defined, use it to retrieve the chunk data
log . Trace ( "ldbstore.get retrieve with getDataFunc" , "key" , addr )
data , err = s . getDataFunc ( addr )
if err != nil {
return
}
} else {
// default DbStore functionality to retrieve chunk data
datakey := getDataKey ( index . Idx , proximity )
data , err = s . db . Get ( datakey )
log . Trace ( "ldbstore.get retrieve" , "key" , addr , "indexkey" , index . Idx , "datakey" , fmt . Sprintf ( "%x" , datakey ) , "proximity" , proximity )
if err != nil {
log . Trace ( "ldbstore.get chunk found but could not be accessed" , "key" , addr , "err" , err )
s . deleteNow ( index , getIndexKey ( addr ) , s . po ( addr ) )
return
}
}
return decodeData ( addr , data )
} else {
err = ErrChunkNotFound
}
return
}
// newMockGetFunc returns a function that reads chunk data from
// the mock database, which is used as the value for DbStore.getFunc
// to bypass the default functionality of DbStore with a mock store.
func newMockGetDataFunc ( mockStore * mock . NodeStore ) func ( addr Address ) ( data [ ] byte , err error ) {
return func ( addr Address ) ( data [ ] byte , err error ) {
data , err = mockStore . Get ( addr )
if err == mock . ErrNotFound {
// preserve ErrChunkNotFound error
err = ErrChunkNotFound
}
return data , err
}
}
func ( s * LDBStore ) setCapacity ( c uint64 ) {
s . lock . Lock ( )
defer s . lock . Unlock ( )
s . capacity = c
for s . entryCnt > c {
s . collectGarbage ( )
}
}
func ( s * LDBStore ) Close ( ) {
close ( s . quit )
s . lock . Lock ( )
s . closed = true
s . lock . Unlock ( )
// force writing out current batch
s . writeCurrentBatch ( )
s . db . Close ( )
}
// SyncIterator(start, stop, po, f) calls f on each hash of a bin po from start to stop
func ( s * LDBStore ) SyncIterator ( since uint64 , until uint64 , po uint8 , f func ( Address , uint64 ) bool ) error {
metrics . GetOrRegisterCounter ( "ldbstore.synciterator" , nil ) . Inc ( 1 )
sincekey := getDataKey ( since , po )
untilkey := getDataKey ( until , po )
it := s . db . NewIterator ( )
defer it . Release ( )
for ok := it . Seek ( sincekey ) ; ok ; ok = it . Next ( ) {
metrics . GetOrRegisterCounter ( "ldbstore.synciterator.seek" , nil ) . Inc ( 1 )
dbkey := it . Key ( )
if dbkey [ 0 ] != keyData || dbkey [ 1 ] != po || bytes . Compare ( untilkey , dbkey ) < 0 {
break
}
key := make ( [ ] byte , 32 )
val := it . Value ( )
copy ( key , val [ : 32 ] )
if ! f ( Address ( key ) , binary . BigEndian . Uint64 ( dbkey [ 2 : ] ) ) {
break
}
}
return it . Error ( )
}