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// Copyright 2018 The go-ethereum Authors
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// 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/>.
package trie
import (
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"errors"
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"fmt"
"io"
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"reflect"
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"sync"
"time"
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"github.com/VictoriaMetrics/fastcache"
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"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/ethdb"
"github.com/ethereum/go-ethereum/log"
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"github.com/ethereum/go-ethereum/metrics"
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"github.com/ethereum/go-ethereum/rlp"
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)
var (
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memcacheCleanHitMeter = metrics . NewRegisteredMeter ( "trie/memcache/clean/hit" , nil )
memcacheCleanMissMeter = metrics . NewRegisteredMeter ( "trie/memcache/clean/miss" , nil )
memcacheCleanReadMeter = metrics . NewRegisteredMeter ( "trie/memcache/clean/read" , nil )
memcacheCleanWriteMeter = metrics . NewRegisteredMeter ( "trie/memcache/clean/write" , nil )
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memcacheDirtyHitMeter = metrics . NewRegisteredMeter ( "trie/memcache/dirty/hit" , nil )
memcacheDirtyMissMeter = metrics . NewRegisteredMeter ( "trie/memcache/dirty/miss" , nil )
memcacheDirtyReadMeter = metrics . NewRegisteredMeter ( "trie/memcache/dirty/read" , nil )
memcacheDirtyWriteMeter = metrics . NewRegisteredMeter ( "trie/memcache/dirty/write" , nil )
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memcacheFlushTimeTimer = metrics . NewRegisteredResettingTimer ( "trie/memcache/flush/time" , nil )
memcacheFlushNodesMeter = metrics . NewRegisteredMeter ( "trie/memcache/flush/nodes" , nil )
memcacheFlushSizeMeter = metrics . NewRegisteredMeter ( "trie/memcache/flush/size" , nil )
memcacheGCTimeTimer = metrics . NewRegisteredResettingTimer ( "trie/memcache/gc/time" , nil )
memcacheGCNodesMeter = metrics . NewRegisteredMeter ( "trie/memcache/gc/nodes" , nil )
memcacheGCSizeMeter = metrics . NewRegisteredMeter ( "trie/memcache/gc/size" , nil )
memcacheCommitTimeTimer = metrics . NewRegisteredResettingTimer ( "trie/memcache/commit/time" , nil )
memcacheCommitNodesMeter = metrics . NewRegisteredMeter ( "trie/memcache/commit/nodes" , nil )
memcacheCommitSizeMeter = metrics . NewRegisteredMeter ( "trie/memcache/commit/size" , nil )
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)
// secureKeyPrefix is the database key prefix used to store trie node preimages.
var secureKeyPrefix = [ ] byte ( "secure-key-" )
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// secureKeyPrefixLength is the length of the above prefix
const secureKeyPrefixLength = 11
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// secureKeyLength is the length of the above prefix + 32byte hash.
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const secureKeyLength = secureKeyPrefixLength + 32
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// Database is an intermediate write layer between the trie data structures and
// the disk database. The aim is to accumulate trie writes in-memory and only
// periodically flush a couple tries to disk, garbage collecting the remainder.
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//
// Note, the trie Database is **not** thread safe in its mutations, but it **is**
// thread safe in providing individual, independent node access. The rationale
// behind this split design is to provide read access to RPC handlers and sync
// servers even while the trie is executing expensive garbage collection.
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type Database struct {
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diskdb ethdb . KeyValueStore // Persistent storage for matured trie nodes
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cleans * fastcache . Cache // GC friendly memory cache of clean node RLPs
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dirties map [ common . Hash ] * cachedNode // Data and references relationships of dirty nodes
oldest common . Hash // Oldest tracked node, flush-list head
newest common . Hash // Newest tracked node, flush-list tail
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preimages map [ common . Hash ] [ ] byte // Preimages of nodes from the secure trie
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gctime time . Duration // Time spent on garbage collection since last commit
gcnodes uint64 // Nodes garbage collected since last commit
gcsize common . StorageSize // Data storage garbage collected since last commit
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flushtime time . Duration // Time spent on data flushing since last commit
flushnodes uint64 // Nodes flushed since last commit
flushsize common . StorageSize // Data storage flushed since last commit
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dirtiesSize common . StorageSize // Storage size of the dirty node cache (exc. metadata)
childrenSize common . StorageSize // Storage size of the external children tracking
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preimagesSize common . StorageSize // Storage size of the preimages cache
lock sync . RWMutex
}
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// rawNode is a simple binary blob used to differentiate between collapsed trie
// nodes and already encoded RLP binary blobs (while at the same time store them
// in the same cache fields).
type rawNode [ ] byte
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func ( n rawNode ) cache ( ) ( hashNode , bool ) { panic ( "this should never end up in a live trie" ) }
func ( n rawNode ) fstring ( ind string ) string { panic ( "this should never end up in a live trie" ) }
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// rawFullNode represents only the useful data content of a full node, with the
// caches and flags stripped out to minimize its data storage. This type honors
// the same RLP encoding as the original parent.
type rawFullNode [ 17 ] node
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func ( n rawFullNode ) cache ( ) ( hashNode , bool ) { panic ( "this should never end up in a live trie" ) }
func ( n rawFullNode ) fstring ( ind string ) string { panic ( "this should never end up in a live trie" ) }
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func ( n rawFullNode ) EncodeRLP ( w io . Writer ) error {
var nodes [ 17 ] node
for i , child := range n {
if child != nil {
nodes [ i ] = child
} else {
nodes [ i ] = nilValueNode
}
}
return rlp . Encode ( w , nodes )
}
// rawShortNode represents only the useful data content of a short node, with the
// caches and flags stripped out to minimize its data storage. This type honors
// the same RLP encoding as the original parent.
type rawShortNode struct {
Key [ ] byte
Val node
}
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func ( n rawShortNode ) cache ( ) ( hashNode , bool ) { panic ( "this should never end up in a live trie" ) }
func ( n rawShortNode ) fstring ( ind string ) string { panic ( "this should never end up in a live trie" ) }
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// cachedNode is all the information we know about a single cached node in the
// memory database write layer.
type cachedNode struct {
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node node // Cached collapsed trie node, or raw rlp data
size uint16 // Byte size of the useful cached data
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parents uint32 // Number of live nodes referencing this one
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children map [ common . Hash ] uint16 // External children referenced by this node
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flushPrev common . Hash // Previous node in the flush-list
flushNext common . Hash // Next node in the flush-list
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}
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// cachedNodeSize is the raw size of a cachedNode data structure without any
// node data included. It's an approximate size, but should be a lot better
// than not counting them.
var cachedNodeSize = int ( reflect . TypeOf ( cachedNode { } ) . Size ( ) )
// cachedNodeChildrenSize is the raw size of an initialized but empty external
// reference map.
const cachedNodeChildrenSize = 48
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// rlp returns the raw rlp encoded blob of the cached node, either directly from
// the cache, or by regenerating it from the collapsed node.
func ( n * cachedNode ) rlp ( ) [ ] byte {
if node , ok := n . node . ( rawNode ) ; ok {
return node
}
blob , err := rlp . EncodeToBytes ( n . node )
if err != nil {
panic ( err )
}
return blob
}
// obj returns the decoded and expanded trie node, either directly from the cache,
// or by regenerating it from the rlp encoded blob.
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func ( n * cachedNode ) obj ( hash common . Hash ) node {
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if node , ok := n . node . ( rawNode ) ; ok {
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return mustDecodeNode ( hash [ : ] , node )
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}
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return expandNode ( hash [ : ] , n . node )
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}
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// forChilds invokes the callback for all the tracked children of this node,
// both the implicit ones from inside the node as well as the explicit ones
//from outside the node.
func ( n * cachedNode ) forChilds ( onChild func ( hash common . Hash ) ) {
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for child := range n . children {
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onChild ( child )
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}
if _ , ok := n . node . ( rawNode ) ; ! ok {
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forGatherChildren ( n . node , onChild )
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}
}
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// forGatherChildren traverses the node hierarchy of a collapsed storage node and
// invokes the callback for all the hashnode children.
func forGatherChildren ( n node , onChild func ( hash common . Hash ) ) {
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switch n := n . ( type ) {
case * rawShortNode :
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forGatherChildren ( n . Val , onChild )
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case rawFullNode :
for i := 0 ; i < 16 ; i ++ {
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forGatherChildren ( n [ i ] , onChild )
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}
case hashNode :
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onChild ( common . BytesToHash ( n ) )
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case valueNode , nil :
default :
panic ( fmt . Sprintf ( "unknown node type: %T" , n ) )
}
}
// simplifyNode traverses the hierarchy of an expanded memory node and discards
// all the internal caches, returning a node that only contains the raw data.
func simplifyNode ( n node ) node {
switch n := n . ( type ) {
case * shortNode :
// Short nodes discard the flags and cascade
return & rawShortNode { Key : n . Key , Val : simplifyNode ( n . Val ) }
case * fullNode :
// Full nodes discard the flags and cascade
node := rawFullNode ( n . Children )
for i := 0 ; i < len ( node ) ; i ++ {
if node [ i ] != nil {
node [ i ] = simplifyNode ( node [ i ] )
}
}
return node
case valueNode , hashNode , rawNode :
return n
default :
panic ( fmt . Sprintf ( "unknown node type: %T" , n ) )
}
}
// expandNode traverses the node hierarchy of a collapsed storage node and converts
// all fields and keys into expanded memory form.
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func expandNode ( hash hashNode , n node ) node {
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switch n := n . ( type ) {
case * rawShortNode :
// Short nodes need key and child expansion
return & shortNode {
Key : compactToHex ( n . Key ) ,
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Val : expandNode ( nil , n . Val ) ,
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flags : nodeFlag {
hash : hash ,
} ,
}
case rawFullNode :
// Full nodes need child expansion
node := & fullNode {
flags : nodeFlag {
hash : hash ,
} ,
}
for i := 0 ; i < len ( node . Children ) ; i ++ {
if n [ i ] != nil {
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node . Children [ i ] = expandNode ( nil , n [ i ] )
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}
}
return node
case valueNode , hashNode :
return n
default :
panic ( fmt . Sprintf ( "unknown node type: %T" , n ) )
}
}
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// NewDatabase creates a new trie database to store ephemeral trie content before
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// its written out to disk or garbage collected. No read cache is created, so all
// data retrievals will hit the underlying disk database.
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func NewDatabase ( diskdb ethdb . KeyValueStore ) * Database {
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return NewDatabaseWithCache ( diskdb , 0 )
}
// NewDatabaseWithCache creates a new trie database to store ephemeral trie content
// before its written out to disk or garbage collected. It also acts as a read cache
// for nodes loaded from disk.
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func NewDatabaseWithCache ( diskdb ethdb . KeyValueStore , cache int ) * Database {
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var cleans * fastcache . Cache
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if cache > 0 {
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cleans = fastcache . New ( cache * 1024 * 1024 )
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}
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return & Database {
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diskdb : diskdb ,
cleans : cleans ,
dirties : map [ common . Hash ] * cachedNode { { } : {
children : make ( map [ common . Hash ] uint16 ) ,
} } ,
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preimages : make ( map [ common . Hash ] [ ] byte ) ,
}
}
// DiskDB retrieves the persistent storage backing the trie database.
all: integrate the freezer with fast sync
* all: freezer style syncing
core, eth, les, light: clean up freezer relative APIs
core, eth, les, trie, ethdb, light: clean a bit
core, eth, les, light: add unit tests
core, light: rewrite setHead function
core, eth: fix downloader unit tests
core: add receipt chain insertion test
core: use constant instead of hardcoding table name
core: fix rollback
core: fix setHead
core/rawdb: remove canonical block first and then iterate side chain
core/rawdb, ethdb: add hasAncient interface
eth/downloader: calculate ancient limit via cht first
core, eth, ethdb: lots of fixes
* eth/downloader: print ancient disable log only for fast sync
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func ( db * Database ) DiskDB ( ) ethdb . KeyValueReader {
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return db . diskdb
}
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// InsertBlob writes a new reference tracked blob to the memory database if it's
// yet unknown. This method should only be used for non-trie nodes that require
// reference counting, since trie nodes are garbage collected directly through
// their embedded children.
func ( db * Database ) InsertBlob ( hash common . Hash , blob [ ] byte ) {
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db . lock . Lock ( )
defer db . lock . Unlock ( )
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db . insert ( hash , len ( blob ) , rawNode ( blob ) )
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}
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// insert inserts a collapsed trie node into the memory database. This method is
// a more generic version of InsertBlob, supporting both raw blob insertions as
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// well ex trie node insertions. The blob size must be specified to allow proper
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// size tracking.
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func ( db * Database ) insert ( hash common . Hash , size int , node node ) {
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// If the node's already cached, skip
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if _ , ok := db . dirties [ hash ] ; ok {
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return
}
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memcacheDirtyWriteMeter . Mark ( int64 ( size ) )
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// Create the cached entry for this node
entry := & cachedNode {
node : simplifyNode ( node ) ,
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size : uint16 ( size ) ,
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flushPrev : db . newest ,
}
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entry . forChilds ( func ( child common . Hash ) {
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if c := db . dirties [ child ] ; c != nil {
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c . parents ++
}
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} )
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db . dirties [ hash ] = entry
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// Update the flush-list endpoints
if db . oldest == ( common . Hash { } ) {
db . oldest , db . newest = hash , hash
} else {
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db . dirties [ db . newest ] . flushNext , db . newest = hash , hash
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}
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db . dirtiesSize += common . StorageSize ( common . HashLength + entry . size )
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}
// insertPreimage writes a new trie node pre-image to the memory database if it's
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// yet unknown. The method will NOT make a copy of the slice,
// only use if the preimage will NOT be changed later on.
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//
// Note, this method assumes that the database's lock is held!
func ( db * Database ) insertPreimage ( hash common . Hash , preimage [ ] byte ) {
if _ , ok := db . preimages [ hash ] ; ok {
return
}
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db . preimages [ hash ] = preimage
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db . preimagesSize += common . StorageSize ( common . HashLength + len ( preimage ) )
}
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// node retrieves a cached trie node from memory, or returns nil if none can be
// found in the memory cache.
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func ( db * Database ) node ( hash common . Hash ) node {
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// Retrieve the node from the clean cache if available
if db . cleans != nil {
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if enc := db . cleans . Get ( nil , hash [ : ] ) ; enc != nil {
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memcacheCleanHitMeter . Mark ( 1 )
memcacheCleanReadMeter . Mark ( int64 ( len ( enc ) ) )
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return mustDecodeNode ( hash [ : ] , enc )
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}
}
// Retrieve the node from the dirty cache if available
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db . lock . RLock ( )
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dirty := db . dirties [ hash ]
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db . lock . RUnlock ( )
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if dirty != nil {
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memcacheDirtyHitMeter . Mark ( 1 )
memcacheDirtyReadMeter . Mark ( int64 ( dirty . size ) )
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return dirty . obj ( hash )
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}
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memcacheDirtyMissMeter . Mark ( 1 )
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// Content unavailable in memory, attempt to retrieve from disk
enc , err := db . diskdb . Get ( hash [ : ] )
if err != nil || enc == nil {
return nil
}
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if db . cleans != nil {
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db . cleans . Set ( hash [ : ] , enc )
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memcacheCleanMissMeter . Mark ( 1 )
memcacheCleanWriteMeter . Mark ( int64 ( len ( enc ) ) )
}
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return mustDecodeNode ( hash [ : ] , enc )
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}
// Node retrieves an encoded cached trie node from memory. If it cannot be found
// cached, the method queries the persistent database for the content.
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func ( db * Database ) Node ( hash common . Hash ) ( [ ] byte , error ) {
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// It doesn't make sense to retrieve the metaroot
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if hash == ( common . Hash { } ) {
return nil , errors . New ( "not found" )
}
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// Retrieve the node from the clean cache if available
if db . cleans != nil {
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if enc := db . cleans . Get ( nil , hash [ : ] ) ; enc != nil {
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memcacheCleanHitMeter . Mark ( 1 )
memcacheCleanReadMeter . Mark ( int64 ( len ( enc ) ) )
return enc , nil
}
}
// Retrieve the node from the dirty cache if available
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db . lock . RLock ( )
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dirty := db . dirties [ hash ]
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db . lock . RUnlock ( )
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if dirty != nil {
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memcacheDirtyHitMeter . Mark ( 1 )
memcacheDirtyReadMeter . Mark ( int64 ( dirty . size ) )
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return dirty . rlp ( ) , nil
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}
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memcacheDirtyMissMeter . Mark ( 1 )
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// Content unavailable in memory, attempt to retrieve from disk
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enc , err := db . diskdb . Get ( hash [ : ] )
if err == nil && enc != nil {
if db . cleans != nil {
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db . cleans . Set ( hash [ : ] , enc )
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memcacheCleanMissMeter . Mark ( 1 )
memcacheCleanWriteMeter . Mark ( int64 ( len ( enc ) ) )
}
}
return enc , err
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}
// preimage retrieves a cached trie node pre-image from memory. If it cannot be
// found cached, the method queries the persistent database for the content.
func ( db * Database ) preimage ( hash common . Hash ) ( [ ] byte , error ) {
// Retrieve the node from cache if available
db . lock . RLock ( )
preimage := db . preimages [ hash ]
db . lock . RUnlock ( )
if preimage != nil {
return preimage , nil
}
// Content unavailable in memory, attempt to retrieve from disk
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return db . diskdb . Get ( secureKey ( hash ) )
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}
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// secureKey returns the database key for the preimage of key (as a newly
// allocated byte-slice)
func secureKey ( hash common . Hash ) [ ] byte {
buf := make ( [ ] byte , secureKeyLength )
copy ( buf , secureKeyPrefix )
copy ( buf [ secureKeyPrefixLength : ] , hash [ : ] )
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return buf
}
// Nodes retrieves the hashes of all the nodes cached within the memory database.
// This method is extremely expensive and should only be used to validate internal
// states in test code.
func ( db * Database ) Nodes ( ) [ ] common . Hash {
db . lock . RLock ( )
defer db . lock . RUnlock ( )
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var hashes = make ( [ ] common . Hash , 0 , len ( db . dirties ) )
for hash := range db . dirties {
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if hash != ( common . Hash { } ) { // Special case for "root" references/nodes
hashes = append ( hashes , hash )
}
}
return hashes
}
// Reference adds a new reference from a parent node to a child node.
func ( db * Database ) Reference ( child common . Hash , parent common . Hash ) {
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db . lock . Lock ( )
defer db . lock . Unlock ( )
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db . reference ( child , parent )
}
// reference is the private locked version of Reference.
func ( db * Database ) reference ( child common . Hash , parent common . Hash ) {
// If the node does not exist, it's a node pulled from disk, skip
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node , ok := db . dirties [ child ]
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if ! ok {
return
}
// If the reference already exists, only duplicate for roots
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if db . dirties [ parent ] . children == nil {
db . dirties [ parent ] . children = make ( map [ common . Hash ] uint16 )
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db . childrenSize += cachedNodeChildrenSize
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} else if _ , ok = db . dirties [ parent ] . children [ child ] ; ok && parent != ( common . Hash { } ) {
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return
}
node . parents ++
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db . dirties [ parent ] . children [ child ] ++
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if db . dirties [ parent ] . children [ child ] == 1 {
db . childrenSize += common . HashLength + 2 // uint16 counter
}
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}
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// Dereference removes an existing reference from a root node.
func ( db * Database ) Dereference ( root common . Hash ) {
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// Sanity check to ensure that the meta-root is not removed
if root == ( common . Hash { } ) {
log . Error ( "Attempted to dereference the trie cache meta root" )
return
}
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db . lock . Lock ( )
defer db . lock . Unlock ( )
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nodes , storage , start := len ( db . dirties ) , db . dirtiesSize , time . Now ( )
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db . dereference ( root , common . Hash { } )
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db . gcnodes += uint64 ( nodes - len ( db . dirties ) )
db . gcsize += storage - db . dirtiesSize
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db . gctime += time . Since ( start )
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memcacheGCTimeTimer . Update ( time . Since ( start ) )
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memcacheGCSizeMeter . Mark ( int64 ( storage - db . dirtiesSize ) )
memcacheGCNodesMeter . Mark ( int64 ( nodes - len ( db . dirties ) ) )
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log . Debug ( "Dereferenced trie from memory database" , "nodes" , nodes - len ( db . dirties ) , "size" , storage - db . dirtiesSize , "time" , time . Since ( start ) ,
"gcnodes" , db . gcnodes , "gcsize" , db . gcsize , "gctime" , db . gctime , "livenodes" , len ( db . dirties ) , "livesize" , db . dirtiesSize )
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}
// dereference is the private locked version of Dereference.
func ( db * Database ) dereference ( child common . Hash , parent common . Hash ) {
// Dereference the parent-child
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node := db . dirties [ parent ]
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if node . children != nil && node . children [ child ] > 0 {
node . children [ child ] --
if node . children [ child ] == 0 {
delete ( node . children , child )
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db . childrenSize -= ( common . HashLength + 2 ) // uint16 counter
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}
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}
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// If the child does not exist, it's a previously committed node.
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node , ok := db . dirties [ child ]
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if ! ok {
return
}
// If there are no more references to the child, delete it and cascade
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if node . parents > 0 {
// This is a special cornercase where a node loaded from disk (i.e. not in the
// memcache any more) gets reinjected as a new node (short node split into full,
// then reverted into short), causing a cached node to have no parents. That is
// no problem in itself, but don't make maxint parents out of it.
node . parents --
}
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if node . parents == 0 {
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// Remove the node from the flush-list
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switch child {
case db . oldest :
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db . oldest = node . flushNext
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db . dirties [ node . flushNext ] . flushPrev = common . Hash { }
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case db . newest :
db . newest = node . flushPrev
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db . dirties [ node . flushPrev ] . flushNext = common . Hash { }
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default :
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db . dirties [ node . flushPrev ] . flushNext = node . flushNext
db . dirties [ node . flushNext ] . flushPrev = node . flushPrev
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}
// Dereference all children and delete the node
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node . forChilds ( func ( hash common . Hash ) {
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db . dereference ( hash , child )
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} )
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delete ( db . dirties , child )
db . dirtiesSize -= common . StorageSize ( common . HashLength + int ( node . size ) )
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if node . children != nil {
db . childrenSize -= cachedNodeChildrenSize
}
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}
}
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// Cap iteratively flushes old but still referenced trie nodes until the total
// memory usage goes below the given threshold.
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//
// Note, this method is a non-synchronized mutator. It is unsafe to call this
// concurrently with other mutators.
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func ( db * Database ) Cap ( limit common . StorageSize ) error {
// Create a database batch to flush persistent data out. It is important that
// outside code doesn't see an inconsistent state (referenced data removed from
// memory cache during commit but not yet in persistent storage). This is ensured
// by only uncaching existing data when the database write finalizes.
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nodes , storage , start := len ( db . dirties ) , db . dirtiesSize , time . Now ( )
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batch := db . diskdb . NewBatch ( )
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// db.dirtiesSize only contains the useful data in the cache, but when reporting
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// the total memory consumption, the maintenance metadata is also needed to be
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// counted.
size := db . dirtiesSize + common . StorageSize ( ( len ( db . dirties ) - 1 ) * cachedNodeSize )
size += db . childrenSize - common . StorageSize ( len ( db . dirties [ common . Hash { } ] . children ) * ( common . HashLength + 2 ) )
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// We reuse an ephemeral buffer for the keys. The batch Put operation
// copies it internally, so we can reuse it.
var keyBuf [ secureKeyLength ] byte
copy ( keyBuf [ : ] , secureKeyPrefix )
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// If the preimage cache got large enough, push to disk. If it's still small
// leave for later to deduplicate writes.
flushPreimages := db . preimagesSize > 4 * 1024 * 1024
if flushPreimages {
for hash , preimage := range db . preimages {
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copy ( keyBuf [ secureKeyPrefixLength : ] , hash [ : ] )
if err := batch . Put ( keyBuf [ : ] , preimage ) ; err != nil {
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log . Error ( "Failed to commit preimage from trie database" , "err" , err )
return err
}
if batch . ValueSize ( ) > ethdb . IdealBatchSize {
if err := batch . Write ( ) ; err != nil {
return err
}
batch . Reset ( )
}
}
}
// Keep committing nodes from the flush-list until we're below allowance
oldest := db . oldest
for size > limit && oldest != ( common . Hash { } ) {
// Fetch the oldest referenced node and push into the batch
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node := db . dirties [ oldest ]
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if err := batch . Put ( oldest [ : ] , node . rlp ( ) ) ; err != nil {
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return err
}
// If we exceeded the ideal batch size, commit and reset
if batch . ValueSize ( ) >= ethdb . IdealBatchSize {
if err := batch . Write ( ) ; err != nil {
log . Error ( "Failed to write flush list to disk" , "err" , err )
return err
}
batch . Reset ( )
}
// Iterate to the next flush item, or abort if the size cap was achieved. Size
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// is the total size, including the useful cached data (hash -> blob), the
// cache item metadata, as well as external children mappings.
size -= common . StorageSize ( common . HashLength + int ( node . size ) + cachedNodeSize )
if node . children != nil {
size -= common . StorageSize ( cachedNodeChildrenSize + len ( node . children ) * ( common . HashLength + 2 ) )
}
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oldest = node . flushNext
}
// Flush out any remainder data from the last batch
if err := batch . Write ( ) ; err != nil {
log . Error ( "Failed to write flush list to disk" , "err" , err )
return err
}
// Write successful, clear out the flushed data
db . lock . Lock ( )
defer db . lock . Unlock ( )
if flushPreimages {
db . preimages = make ( map [ common . Hash ] [ ] byte )
db . preimagesSize = 0
}
for db . oldest != oldest {
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node := db . dirties [ db . oldest ]
delete ( db . dirties , db . oldest )
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db . oldest = node . flushNext
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db . dirtiesSize -= common . StorageSize ( common . HashLength + int ( node . size ) )
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if node . children != nil {
db . childrenSize -= common . StorageSize ( cachedNodeChildrenSize + len ( node . children ) * ( common . HashLength + 2 ) )
}
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}
if db . oldest != ( common . Hash { } ) {
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db . dirties [ db . oldest ] . flushPrev = common . Hash { }
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}
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db . flushnodes += uint64 ( nodes - len ( db . dirties ) )
db . flushsize += storage - db . dirtiesSize
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db . flushtime += time . Since ( start )
memcacheFlushTimeTimer . Update ( time . Since ( start ) )
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memcacheFlushSizeMeter . Mark ( int64 ( storage - db . dirtiesSize ) )
memcacheFlushNodesMeter . Mark ( int64 ( nodes - len ( db . dirties ) ) )
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log . Debug ( "Persisted nodes from memory database" , "nodes" , nodes - len ( db . dirties ) , "size" , storage - db . dirtiesSize , "time" , time . Since ( start ) ,
"flushnodes" , db . flushnodes , "flushsize" , db . flushsize , "flushtime" , db . flushtime , "livenodes" , len ( db . dirties ) , "livesize" , db . dirtiesSize )
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return nil
}
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// Commit iterates over all the children of a particular node, writes them out
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// to disk, forcefully tearing down all references in both directions. As a side
// effect, all pre-images accumulated up to this point are also written.
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//
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// Note, this method is a non-synchronized mutator. It is unsafe to call this
// concurrently with other mutators.
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func ( db * Database ) Commit ( node common . Hash , report bool ) error {
// Create a database batch to flush persistent data out. It is important that
// outside code doesn't see an inconsistent state (referenced data removed from
// memory cache during commit but not yet in persistent storage). This is ensured
// by only uncaching existing data when the database write finalizes.
start := time . Now ( )
batch := db . diskdb . NewBatch ( )
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// We reuse an ephemeral buffer for the keys. The batch Put operation
// copies it internally, so we can reuse it.
var keyBuf [ secureKeyLength ] byte
copy ( keyBuf [ : ] , secureKeyPrefix )
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// Move all of the accumulated preimages into a write batch
for hash , preimage := range db . preimages {
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copy ( keyBuf [ secureKeyPrefixLength : ] , hash [ : ] )
if err := batch . Put ( keyBuf [ : ] , preimage ) ; err != nil {
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log . Error ( "Failed to commit preimage from trie database" , "err" , err )
return err
}
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// If the batch is too large, flush to disk
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if batch . ValueSize ( ) > ethdb . IdealBatchSize {
if err := batch . Write ( ) ; err != nil {
return err
}
batch . Reset ( )
}
}
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// Since we're going to replay trie node writes into the clean cache, flush out
// any batched pre-images before continuing.
if err := batch . Write ( ) ; err != nil {
return err
}
batch . Reset ( )
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// Move the trie itself into the batch, flushing if enough data is accumulated
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nodes , storage := len ( db . dirties ) , db . dirtiesSize
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uncacher := & cleaner { db }
if err := db . commit ( node , batch , uncacher ) ; err != nil {
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log . Error ( "Failed to commit trie from trie database" , "err" , err )
return err
}
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// Trie mostly committed to disk, flush any batch leftovers
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if err := batch . Write ( ) ; err != nil {
log . Error ( "Failed to write trie to disk" , "err" , err )
return err
}
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// Uncache any leftovers in the last batch
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db . lock . Lock ( )
defer db . lock . Unlock ( )
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batch . Replay ( uncacher )
batch . Reset ( )
// Reset the storage counters and bumpd metrics
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db . preimages = make ( map [ common . Hash ] [ ] byte )
db . preimagesSize = 0
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memcacheCommitTimeTimer . Update ( time . Since ( start ) )
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memcacheCommitSizeMeter . Mark ( int64 ( storage - db . dirtiesSize ) )
memcacheCommitNodesMeter . Mark ( int64 ( nodes - len ( db . dirties ) ) )
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logger := log . Info
if ! report {
logger = log . Debug
}
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logger ( "Persisted trie from memory database" , "nodes" , nodes - len ( db . dirties ) + int ( db . flushnodes ) , "size" , storage - db . dirtiesSize + db . flushsize , "time" , time . Since ( start ) + db . flushtime ,
"gcnodes" , db . gcnodes , "gcsize" , db . gcsize , "gctime" , db . gctime , "livenodes" , len ( db . dirties ) , "livesize" , db . dirtiesSize )
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// Reset the garbage collection statistics
db . gcnodes , db . gcsize , db . gctime = 0 , 0 , 0
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db . flushnodes , db . flushsize , db . flushtime = 0 , 0 , 0
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return nil
}
// commit is the private locked version of Commit.
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func ( db * Database ) commit ( hash common . Hash , batch ethdb . Batch , uncacher * cleaner ) error {
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// If the node does not exist, it's a previously committed node
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node , ok := db . dirties [ hash ]
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if ! ok {
return nil
}
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var err error
node . forChilds ( func ( child common . Hash ) {
if err == nil {
err = db . commit ( child , batch , uncacher )
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}
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} )
if err != nil {
return err
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}
2018-06-21 12:28:05 +03:00
if err := batch . Put ( hash [ : ] , node . rlp ( ) ) ; err != nil {
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return err
}
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// If we've reached an optimal batch size, commit and start over
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if batch . ValueSize ( ) >= ethdb . IdealBatchSize {
if err := batch . Write ( ) ; err != nil {
return err
}
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db . lock . Lock ( )
batch . Replay ( uncacher )
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batch . Reset ( )
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db . lock . Unlock ( )
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}
return nil
}
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// cleaner is a database batch replayer that takes a batch of write operations
// and cleans up the trie database from anything written to disk.
type cleaner struct {
db * Database
}
// Put reacts to database writes and implements dirty data uncaching. This is the
// post-processing step of a commit operation where the already persisted trie is
// removed from the dirty cache and moved into the clean cache. The reason behind
// the two-phase commit is to ensure ensure data availability while moving from
// memory to disk.
func ( c * cleaner ) Put ( key [ ] byte , rlp [ ] byte ) error {
hash := common . BytesToHash ( key )
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// If the node does not exist, we're done on this path
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node , ok := c . db . dirties [ hash ]
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if ! ok {
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return nil
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}
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// Node still exists, remove it from the flush-list
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switch hash {
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case c . db . oldest :
c . db . oldest = node . flushNext
c . db . dirties [ node . flushNext ] . flushPrev = common . Hash { }
case c . db . newest :
c . db . newest = node . flushPrev
c . db . dirties [ node . flushPrev ] . flushNext = common . Hash { }
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default :
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c . db . dirties [ node . flushPrev ] . flushNext = node . flushNext
c . db . dirties [ node . flushNext ] . flushPrev = node . flushPrev
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}
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// Remove the node from the dirty cache
delete ( c . db . dirties , hash )
c . db . dirtiesSize -= common . StorageSize ( common . HashLength + int ( node . size ) )
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if node . children != nil {
c . db . dirtiesSize -= common . StorageSize ( cachedNodeChildrenSize + len ( node . children ) * ( common . HashLength + 2 ) )
}
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// Move the flushed node into the clean cache to prevent insta-reloads
if c . db . cleans != nil {
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c . db . cleans . Set ( hash [ : ] , rlp )
2019-12-02 13:14:44 +03:00
memcacheCleanWriteMeter . Mark ( int64 ( len ( rlp ) ) )
2018-02-05 19:40:32 +03:00
}
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return nil
}
func ( c * cleaner ) Delete ( key [ ] byte ) error {
2019-11-22 18:24:48 +03:00
panic ( "not implemented" )
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}
// Size returns the current storage size of the memory cache in front of the
// persistent database layer.
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func ( db * Database ) Size ( ) ( common . StorageSize , common . StorageSize ) {
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db . lock . RLock ( )
defer db . lock . RUnlock ( )
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// db.dirtiesSize only contains the useful data in the cache, but when reporting
2018-06-04 10:47:43 +03:00
// the total memory consumption, the maintenance metadata is also needed to be
2018-11-22 15:09:04 +03:00
// counted.
var metadataSize = common . StorageSize ( ( len ( db . dirties ) - 1 ) * cachedNodeSize )
var metarootRefs = common . StorageSize ( len ( db . dirties [ common . Hash { } ] . children ) * ( common . HashLength + 2 ) )
return db . dirtiesSize + db . childrenSize + metadataSize - metarootRefs , db . preimagesSize
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}