go-ethereum/core/chain_manager.go
obscuren a4b79f1dac core: moved mutex locks in insert blocks to start of function
Insert blocks will no longer allow processing of multiple chains at the
same time. The block lock has been moved to start of the function.
2015-04-29 12:51:04 +02:00

677 lines
18 KiB
Go

package core
import (
"bytes"
"fmt"
"io"
"math/big"
"sync"
"time"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/core/state"
"github.com/ethereum/go-ethereum/core/types"
"github.com/ethereum/go-ethereum/event"
"github.com/ethereum/go-ethereum/logger"
"github.com/ethereum/go-ethereum/logger/glog"
"github.com/ethereum/go-ethereum/params"
"github.com/ethereum/go-ethereum/rlp"
)
var (
chainlogger = logger.NewLogger("CHAIN")
jsonlogger = logger.NewJsonLogger()
blockHashPre = []byte("block-hash-")
blockNumPre = []byte("block-num-")
)
const (
blockCacheLimit = 10000
maxFutureBlocks = 256
)
func CalcDifficulty(block, parent *types.Header) *big.Int {
diff := new(big.Int)
adjust := new(big.Int).Div(parent.Difficulty, params.DifficultyBoundDivisor)
if big.NewInt(int64(block.Time)-int64(parent.Time)).Cmp(params.DurationLimit) < 0 {
diff.Add(parent.Difficulty, adjust)
} else {
diff.Sub(parent.Difficulty, adjust)
}
if diff.Cmp(params.MinimumDifficulty) < 0 {
return params.MinimumDifficulty
}
return diff
}
func CalculateTD(block, parent *types.Block) *big.Int {
td := new(big.Int).Add(parent.Td, block.Header().Difficulty)
return td
}
func CalcGasLimit(parent *types.Block) *big.Int {
// ((1024-1) * parent.gasLimit + (gasUsed * 6 / 5)) / 1024
previous := new(big.Int).Mul(big.NewInt(1024-1), parent.GasLimit())
current := new(big.Rat).Mul(new(big.Rat).SetInt(parent.GasUsed()), big.NewRat(6, 5))
curInt := new(big.Int).Div(current.Num(), current.Denom())
result := new(big.Int).Add(previous, curInt)
result.Div(result, big.NewInt(1024))
return common.BigMax(params.GenesisGasLimit, result)
}
type ChainManager struct {
//eth EthManager
blockDb common.Database
stateDb common.Database
processor types.BlockProcessor
eventMux *event.TypeMux
genesisBlock *types.Block
// Last known total difficulty
mu sync.RWMutex
tsmu sync.RWMutex
td *big.Int
currentBlock *types.Block
lastBlockHash common.Hash
currentGasLimit *big.Int
transState *state.StateDB
txState *state.ManagedState
cache *BlockCache
futureBlocks *BlockCache
quit chan struct{}
}
func NewChainManager(blockDb, stateDb common.Database, mux *event.TypeMux) *ChainManager {
bc := &ChainManager{
blockDb: blockDb,
stateDb: stateDb,
genesisBlock: GenesisBlock(stateDb),
eventMux: mux,
quit: make(chan struct{}),
cache: NewBlockCache(blockCacheLimit),
}
bc.setLastState()
// Check the current state of the block hashes and make sure that we do not have any of the bad blocks in our chain
for _, hash := range badHashes {
if block := bc.GetBlock(hash); block != nil {
glog.V(logger.Error).Infof("Found bad hash. Reorganising chain to state %x\n", block.ParentHash().Bytes()[:4])
block = bc.GetBlock(block.ParentHash())
if block == nil {
glog.Fatal("Unable to complete. Parent block not found. Corrupted DB?")
}
bc.SetHead(block)
glog.V(logger.Error).Infoln("Chain reorg was successfull. Resuming normal operation")
}
}
bc.transState = bc.State().Copy()
// Take ownership of this particular state
bc.txState = state.ManageState(bc.State().Copy())
bc.futureBlocks = NewBlockCache(maxFutureBlocks)
bc.makeCache()
go bc.update()
return bc
}
func (bc *ChainManager) SetHead(head *types.Block) {
bc.mu.Lock()
defer bc.mu.Unlock()
for block := bc.currentBlock; block != nil && block.Hash() != head.Hash(); block = bc.GetBlock(block.Header().ParentHash) {
bc.removeBlock(block)
}
bc.cache = NewBlockCache(blockCacheLimit)
bc.currentBlock = head
bc.makeCache()
statedb := state.New(head.Root(), bc.stateDb)
bc.txState = state.ManageState(statedb)
bc.transState = statedb.Copy()
bc.setTotalDifficulty(head.Td)
bc.insert(head)
bc.setLastState()
}
func (self *ChainManager) Td() *big.Int {
self.mu.RLock()
defer self.mu.RUnlock()
return self.td
}
func (self *ChainManager) GasLimit() *big.Int {
return self.currentGasLimit
}
func (self *ChainManager) LastBlockHash() common.Hash {
self.mu.RLock()
defer self.mu.RUnlock()
return self.lastBlockHash
}
func (self *ChainManager) CurrentBlock() *types.Block {
self.mu.RLock()
defer self.mu.RUnlock()
return self.currentBlock
}
func (self *ChainManager) Status() (td *big.Int, currentBlock common.Hash, genesisBlock common.Hash) {
self.mu.RLock()
defer self.mu.RUnlock()
return self.td, self.currentBlock.Hash(), self.genesisBlock.Hash()
}
func (self *ChainManager) SetProcessor(proc types.BlockProcessor) {
self.processor = proc
}
func (self *ChainManager) State() *state.StateDB {
return state.New(self.CurrentBlock().Root(), self.stateDb)
}
func (self *ChainManager) TransState() *state.StateDB {
self.tsmu.RLock()
defer self.tsmu.RUnlock()
return self.transState
}
func (self *ChainManager) TxState() *state.ManagedState {
self.tsmu.RLock()
defer self.tsmu.RUnlock()
return self.txState
}
func (self *ChainManager) setTxState(statedb *state.StateDB) {
self.tsmu.Lock()
defer self.tsmu.Unlock()
self.txState = state.ManageState(statedb)
}
func (self *ChainManager) setTransState(statedb *state.StateDB) {
self.transState = statedb
}
func (bc *ChainManager) setLastState() {
data, _ := bc.blockDb.Get([]byte("LastBlock"))
if len(data) != 0 {
block := bc.GetBlock(common.BytesToHash(data))
bc.currentBlock = block
bc.lastBlockHash = block.Hash()
// Set the last know difficulty (might be 0x0 as initial value, Genesis)
bc.td = common.BigD(bc.blockDb.LastKnownTD())
} else {
bc.Reset()
}
bc.currentGasLimit = CalcGasLimit(bc.currentBlock)
if glog.V(logger.Info) {
glog.Infof("Last block (#%v) %x TD=%v\n", bc.currentBlock.Number(), bc.currentBlock.Hash(), bc.td)
}
}
func (bc *ChainManager) makeCache() {
if bc.cache == nil {
bc.cache = NewBlockCache(blockCacheLimit)
}
// load in last `blockCacheLimit` - 1 blocks. Last block is the current.
ancestors := bc.GetAncestors(bc.currentBlock, blockCacheLimit-1)
ancestors = append(ancestors, bc.currentBlock)
for _, block := range ancestors {
bc.cache.Push(block)
}
}
// Block creation & chain handling
func (bc *ChainManager) NewBlock(coinbase common.Address) *types.Block {
bc.mu.RLock()
defer bc.mu.RUnlock()
var (
root common.Hash
parentHash common.Hash
)
if bc.currentBlock != nil {
root = bc.currentBlock.Header().Root
parentHash = bc.lastBlockHash
}
block := types.NewBlock(
parentHash,
coinbase,
root,
common.BigPow(2, 32),
0,
nil)
block.SetUncles(nil)
block.SetTransactions(nil)
block.SetReceipts(nil)
parent := bc.currentBlock
if parent != nil {
header := block.Header()
header.Difficulty = CalcDifficulty(block.Header(), parent.Header())
header.Number = new(big.Int).Add(parent.Header().Number, common.Big1)
header.GasLimit = CalcGasLimit(parent)
}
return block
}
func (bc *ChainManager) Reset() {
bc.mu.Lock()
defer bc.mu.Unlock()
for block := bc.currentBlock; block != nil; block = bc.GetBlock(block.Header().ParentHash) {
bc.removeBlock(block)
}
if bc.cache == nil {
bc.cache = NewBlockCache(blockCacheLimit)
}
// Prepare the genesis block
bc.write(bc.genesisBlock)
bc.insert(bc.genesisBlock)
bc.currentBlock = bc.genesisBlock
bc.makeCache()
bc.setTotalDifficulty(common.Big("0"))
}
func (bc *ChainManager) removeBlock(block *types.Block) {
bc.blockDb.Delete(append(blockHashPre, block.Hash().Bytes()...))
}
func (bc *ChainManager) ResetWithGenesisBlock(gb *types.Block) {
bc.mu.Lock()
defer bc.mu.Unlock()
for block := bc.currentBlock; block != nil; block = bc.GetBlock(block.Header().ParentHash) {
bc.removeBlock(block)
}
// Prepare the genesis block
bc.genesisBlock = gb
bc.write(bc.genesisBlock)
bc.insert(bc.genesisBlock)
bc.currentBlock = bc.genesisBlock
bc.makeCache()
}
// Export writes the active chain to the given writer.
func (self *ChainManager) Export(w io.Writer) error {
self.mu.RLock()
defer self.mu.RUnlock()
glog.V(logger.Info).Infof("exporting %v blocks...\n", self.currentBlock.Header().Number)
last := self.currentBlock.NumberU64()
for nr := uint64(0); nr <= last; nr++ {
block := self.GetBlockByNumber(nr)
if block == nil {
return fmt.Errorf("export failed on #%d: not found", nr)
}
if err := block.EncodeRLP(w); err != nil {
return err
}
}
return nil
}
func (bc *ChainManager) insert(block *types.Block) {
key := append(blockNumPre, block.Number().Bytes()...)
bc.blockDb.Put(key, block.Hash().Bytes())
// Push block to cache
bc.cache.Push(block)
bc.blockDb.Put([]byte("LastBlock"), block.Hash().Bytes())
bc.currentBlock = block
bc.lastBlockHash = block.Hash()
}
func (bc *ChainManager) write(block *types.Block) {
enc, _ := rlp.EncodeToBytes((*types.StorageBlock)(block))
key := append(blockHashPre, block.Hash().Bytes()...)
bc.blockDb.Put(key, enc)
}
// Accessors
func (bc *ChainManager) Genesis() *types.Block {
return bc.genesisBlock
}
// Block fetching methods
func (bc *ChainManager) HasBlock(hash common.Hash) bool {
data, _ := bc.blockDb.Get(append(blockHashPre, hash[:]...))
return len(data) != 0
}
func (self *ChainManager) GetBlockHashesFromHash(hash common.Hash, max uint64) (chain []common.Hash) {
block := self.GetBlock(hash)
if block == nil {
return
}
// XXX Could be optimised by using a different database which only holds hashes (i.e., linked list)
for i := uint64(0); i < max; i++ {
block = self.GetBlock(block.ParentHash())
if block == nil {
break
}
chain = append(chain, block.Hash())
if block.Number().Cmp(common.Big0) <= 0 {
break
}
}
return
}
func (self *ChainManager) GetBlock(hash common.Hash) *types.Block {
if block := self.cache.Get(hash); block != nil {
return block
}
data, _ := self.blockDb.Get(append(blockHashPre, hash[:]...))
if len(data) == 0 {
return nil
}
var block types.StorageBlock
if err := rlp.Decode(bytes.NewReader(data), &block); err != nil {
glog.V(logger.Error).Infof("invalid block RLP for hash %x: %v", hash, err)
return nil
}
return (*types.Block)(&block)
}
func (self *ChainManager) GetBlockByNumber(num uint64) *types.Block {
self.mu.RLock()
defer self.mu.RUnlock()
return self.getBlockByNumber(num)
}
// non blocking version
func (self *ChainManager) getBlockByNumber(num uint64) *types.Block {
key, _ := self.blockDb.Get(append(blockNumPre, big.NewInt(int64(num)).Bytes()...))
if len(key) == 0 {
return nil
}
return self.GetBlock(common.BytesToHash(key))
}
func (self *ChainManager) GetUnclesInChain(block *types.Block, length int) (uncles []*types.Header) {
for i := 0; block != nil && i < length; i++ {
uncles = append(uncles, block.Uncles()...)
block = self.GetBlock(block.ParentHash())
}
return
}
func (self *ChainManager) GetAncestors(block *types.Block, length int) (blocks []*types.Block) {
for i := 0; i < length; i++ {
block = self.GetBlock(block.ParentHash())
if block == nil {
break
}
blocks = append(blocks, block)
}
return
}
func (bc *ChainManager) setTotalDifficulty(td *big.Int) {
bc.blockDb.Put([]byte("LTD"), td.Bytes())
bc.td = td
}
func (self *ChainManager) CalcTotalDiff(block *types.Block) (*big.Int, error) {
parent := self.GetBlock(block.Header().ParentHash)
if parent == nil {
return nil, fmt.Errorf("Unable to calculate total diff without known parent %x", block.Header().ParentHash)
}
parentTd := parent.Td
uncleDiff := new(big.Int)
for _, uncle := range block.Uncles() {
uncleDiff = uncleDiff.Add(uncleDiff, uncle.Difficulty)
}
td := new(big.Int)
td = td.Add(parentTd, uncleDiff)
td = td.Add(td, block.Header().Difficulty)
return td, nil
}
func (bc *ChainManager) Stop() {
close(bc.quit)
}
type queueEvent struct {
queue []interface{}
canonicalCount int
sideCount int
splitCount int
}
func (self *ChainManager) procFutureBlocks() {
blocks := make([]*types.Block, len(self.futureBlocks.blocks))
self.futureBlocks.Each(func(i int, block *types.Block) {
blocks[i] = block
})
types.BlockBy(types.Number).Sort(blocks)
self.InsertChain(blocks)
}
func (self *ChainManager) InsertChain(chain types.Blocks) error {
self.mu.Lock()
defer self.mu.Unlock()
// A queued approach to delivering events. This is generally faster than direct delivery and requires much less mutex acquiring.
var (
queue = make([]interface{}, len(chain))
queueEvent = queueEvent{queue: queue}
stats struct{ queued, processed int }
tstart = time.Now()
)
for i, block := range chain {
if block == nil {
continue
}
// Call in to the block processor and check for errors. It's likely that if one block fails
// all others will fail too (unless a known block is returned).
logs, err := self.processor.Process(block)
if err != nil {
if IsKnownBlockErr(err) {
continue
}
block.Td = new(big.Int)
// Do not penelise on future block. We'll need a block queue eventually that will queue
// future block for future use
if err == BlockFutureErr {
block.SetQueued(true)
self.futureBlocks.Push(block)
stats.queued++
continue
}
if IsParentErr(err) && self.futureBlocks.Has(block.ParentHash()) {
block.SetQueued(true)
self.futureBlocks.Push(block)
stats.queued++
continue
}
h := block.Header()
glog.V(logger.Error).Infof("INVALID block #%v (%x)\n", h.Number, h.Hash().Bytes())
glog.V(logger.Error).Infoln(err)
glog.V(logger.Debug).Infoln(block)
return err
}
block.Td = new(big.Int).Set(CalculateTD(block, self.GetBlock(block.ParentHash())))
cblock := self.currentBlock
// Write block to database. Eventually we'll have to improve on this and throw away blocks that are
// not in the canonical chain.
self.write(block)
// Compare the TD of the last known block in the canonical chain to make sure it's greater.
// At this point it's possible that a different chain (fork) becomes the new canonical chain.
if block.Td.Cmp(self.td) > 0 {
//if block.Header().Number.Cmp(new(big.Int).Add(cblock.Header().Number, common.Big1)) < 0 {
if block.Number().Cmp(cblock.Number()) <= 0 {
chash := cblock.Hash()
hash := block.Hash()
if glog.V(logger.Info) {
glog.Infof("Split detected. New head #%v (%x) TD=%v, was #%v (%x) TD=%v\n", block.Header().Number, hash[:4], block.Td, cblock.Header().Number, chash[:4], self.td)
}
// during split we merge two different chains and create the new canonical chain
self.merge(self.getBlockByNumber(block.NumberU64()), block)
queue[i] = ChainSplitEvent{block, logs}
queueEvent.splitCount++
}
self.setTotalDifficulty(block.Td)
self.insert(block)
jsonlogger.LogJson(&logger.EthChainNewHead{
BlockHash: block.Hash().Hex(),
BlockNumber: block.Number(),
ChainHeadHash: cblock.Hash().Hex(),
BlockPrevHash: block.ParentHash().Hex(),
})
self.setTransState(state.New(block.Root(), self.stateDb))
self.txState.SetState(state.New(block.Root(), self.stateDb))
queue[i] = ChainEvent{block, logs}
queueEvent.canonicalCount++
if glog.V(logger.Debug) {
glog.Infof("inserted block #%d (%d TXs %d UNCs) (%x...)\n", block.Number(), len(block.Transactions()), len(block.Uncles()), block.Hash().Bytes()[0:4])
}
} else {
queue[i] = ChainSideEvent{block, logs}
queueEvent.sideCount++
}
stats.processed++
self.futureBlocks.Delete(block.Hash())
}
if (stats.queued > 0 || stats.processed > 0) && bool(glog.V(logger.Info)) {
tend := time.Since(tstart)
start, end := chain[0], chain[len(chain)-1]
glog.Infof("imported %d block(s) %d queued in %v. #%v [%x / %x]\n", stats.processed, stats.queued, tend, end.Number(), start.Hash().Bytes()[:4], end.Hash().Bytes()[:4])
}
go self.eventMux.Post(queueEvent)
return nil
}
// merge takes two blocks, an old chain and a new chain and will reconstruct the blocks and inserts them
// to be part of the new canonical chain.
func (self *ChainManager) merge(oldBlock, newBlock *types.Block) {
glog.V(logger.Debug).Infof("Applying diff to %x & %x\n", oldBlock.Hash().Bytes()[:4], newBlock.Hash().Bytes()[:4])
var oldChain, newChain types.Blocks
// First find the split (common ancestor) so we can perform an adequate merge
for {
oldBlock, newBlock = self.GetBlock(oldBlock.ParentHash()), self.GetBlock(newBlock.ParentHash())
if oldBlock.Hash() == newBlock.Hash() {
break
}
oldChain = append(oldChain, oldBlock)
newChain = append(newChain, newBlock)
}
// insert blocks
for _, block := range newChain {
self.insert(block)
}
if glog.V(logger.Detail) {
for i, oldBlock := range oldChain {
glog.Infof("- %.10v = %x\n", oldBlock.Number(), oldBlock.Hash())
glog.Infof("+ %.10v = %x\n", newChain[i].Number(), newChain[i].Hash())
}
}
}
func (self *ChainManager) update() {
events := self.eventMux.Subscribe(queueEvent{})
futureTimer := time.NewTicker(5 * time.Second)
out:
for {
select {
case ev := <-events.Chan():
switch ev := ev.(type) {
case queueEvent:
for i, event := range ev.queue {
switch event := event.(type) {
case ChainEvent:
// We need some control over the mining operation. Acquiring locks and waiting for the miner to create new block takes too long
// and in most cases isn't even necessary.
if i+1 == ev.canonicalCount {
self.currentGasLimit = CalcGasLimit(event.Block)
self.eventMux.Post(ChainHeadEvent{event.Block})
}
case ChainSplitEvent:
// On chain splits we need to reset the transaction state. We can't be sure whether the actual
// state of the accounts are still valid.
if i == ev.splitCount {
self.setTxState(state.New(event.Block.Root(), self.stateDb))
}
}
self.eventMux.Post(event)
}
}
case <-futureTimer.C:
self.procFutureBlocks()
case <-self.quit:
break out
}
}
}