package miner
import (
"fmt"
"math/big"
"sort"
"sync"
"sync/atomic"
"github.com/ethereum/go-ethereum/accounts"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/core"
"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/pow"
"gopkg.in/fatih/set.v0"
)
var jsonlogger = logger . NewJsonLogger ( )
// Work holds the current work
type Work struct {
Number uint64
Nonce uint64
MixDigest [ ] byte
SeedHash [ ] byte
}
// Agent can register themself with the worker
type Agent interface {
Work ( ) chan <- * types . Block
SetReturnCh ( chan <- * types . Block )
Stop ( )
Start ( )
GetHashRate ( ) int64
}
const miningLogAtDepth = 5
type uint64RingBuffer struct {
ints [ ] uint64 //array of all integers in buffer
next int //where is the next insertion? assert 0 <= next < len(ints)
}
// environment is the workers current environment and holds
// all of the current state information
type environment struct {
totalUsedGas * big . Int // total gas usage in the cycle
state * state . StateDB // apply state changes here
coinbase * state . StateObject // the miner's account
block * types . Block // the new block
ancestors * set . Set // ancestor set (used for checking uncle parent validity)
family * set . Set // family set (used for checking uncle invalidity)
uncles * set . Set // uncle set
remove * set . Set // tx which will be removed
tcount int // tx count in cycle
ignoredTransactors * set . Set
lowGasTransactors * set . Set
ownedAccounts * set . Set
lowGasTxs types . Transactions
localMinedBlocks * uint64RingBuffer // the most recent block numbers that were mined locally (used to check block inclusion)
}
// env returns a new environment for the current cycle
func env ( block * types . Block , eth core . Backend ) * environment {
state := state . New ( block . Root ( ) , eth . StateDb ( ) )
env := & environment {
totalUsedGas : new ( big . Int ) ,
state : state ,
block : block ,
ancestors : set . New ( ) ,
family : set . New ( ) ,
uncles : set . New ( ) ,
coinbase : state . GetOrNewStateObject ( block . Coinbase ( ) ) ,
}
return env
}
// worker is the main object which takes care of applying messages to the new state
type worker struct {
mu sync . Mutex
agents [ ] Agent
recv chan * types . Block
mux * event . TypeMux
quit chan struct { }
pow pow . PoW
eth core . Backend
chain * core . ChainManager
proc * core . BlockProcessor
coinbase common . Address
gasPrice * big . Int
extra [ ] byte
currentMu sync . Mutex
current * environment
uncleMu sync . Mutex
possibleUncles map [ common . Hash ] * types . Block
txQueueMu sync . Mutex
txQueue map [ common . Hash ] * types . Transaction
// atomic status counters
mining int32
atWork int32
}
func newWorker ( coinbase common . Address , eth core . Backend ) * worker {
worker := & worker {
eth : eth ,
mux : eth . EventMux ( ) ,
recv : make ( chan * types . Block ) ,
gasPrice : new ( big . Int ) ,
chain : eth . ChainManager ( ) ,
proc : eth . BlockProcessor ( ) ,
possibleUncles : make ( map [ common . Hash ] * types . Block ) ,
coinbase : coinbase ,
txQueue : make ( map [ common . Hash ] * types . Transaction ) ,
quit : make ( chan struct { } ) ,
}
go worker . update ( )
go worker . wait ( )
worker . commitNewWork ( )
return worker
}
func ( self * worker ) pendingState ( ) * state . StateDB {
self . currentMu . Lock ( )
defer self . currentMu . Unlock ( )
return self . current . state
}
func ( self * worker ) pendingBlock ( ) * types . Block {
self . currentMu . Lock ( )
defer self . currentMu . Unlock ( )
return self . current . block
}
func ( self * worker ) start ( ) {
self . mu . Lock ( )
defer self . mu . Unlock ( )
atomic . StoreInt32 ( & self . mining , 1 )
// spin up agents
for _ , agent := range self . agents {
agent . Start ( )
}
}
func ( self * worker ) stop ( ) {
self . mu . Lock ( )
defer self . mu . Unlock ( )
if atomic . LoadInt32 ( & self . mining ) == 1 {
var keep [ ] Agent
// stop all agents
for _ , agent := range self . agents {
agent . Stop ( )
// keep all that's not a cpu agent
if _ , ok := agent . ( * CpuAgent ) ; ! ok {
keep = append ( keep , agent )
}
}
self . agents = keep
}
atomic . StoreInt32 ( & self . mining , 0 )
atomic . StoreInt32 ( & self . atWork , 0 )
}
func ( self * worker ) register ( agent Agent ) {
self . mu . Lock ( )
defer self . mu . Unlock ( )
self . agents = append ( self . agents , agent )
agent . SetReturnCh ( self . recv )
}
func ( self * worker ) update ( ) {
events := self . mux . Subscribe ( core . ChainHeadEvent { } , core . ChainSideEvent { } , core . TxPreEvent { } )
out :
for {
select {
case event := <- events . Chan ( ) :
switch ev := event . ( type ) {
case core . ChainHeadEvent :
self . commitNewWork ( )
case core . ChainSideEvent :
self . uncleMu . Lock ( )
self . possibleUncles [ ev . Block . Hash ( ) ] = ev . Block
self . uncleMu . Unlock ( )
case core . TxPreEvent :
// Apply transaction to the pending state if we're not mining
if atomic . LoadInt32 ( & self . mining ) == 0 {
self . mu . Lock ( )
self . commitTransactions ( types . Transactions { ev . Tx } )
self . mu . Unlock ( )
}
}
case <- self . quit :
break out
}
}
events . Unsubscribe ( )
}
func newLocalMinedBlock ( blockNumber uint64 , prevMinedBlocks * uint64RingBuffer ) ( minedBlocks * uint64RingBuffer ) {
if prevMinedBlocks == nil {
minedBlocks = & uint64RingBuffer { next : 0 , ints : make ( [ ] uint64 , miningLogAtDepth + 1 ) }
} else {
minedBlocks = prevMinedBlocks
}
minedBlocks . ints [ minedBlocks . next ] = blockNumber
minedBlocks . next = ( minedBlocks . next + 1 ) % len ( minedBlocks . ints )
return minedBlocks
}
func ( self * worker ) wait ( ) {
for {
for block := range self . recv {
atomic . AddInt32 ( & self . atWork , - 1 )
if block == nil {
continue
}
if _ , err := self . chain . InsertChain ( types . Blocks { block } ) ; err == nil {
for _ , uncle := range block . Uncles ( ) {
delete ( self . possibleUncles , uncle . Hash ( ) )
}
self . mux . Post ( core . NewMinedBlockEvent { block } )
var stale , confirm string
canonBlock := self . chain . GetBlockByNumber ( block . NumberU64 ( ) )
if canonBlock != nil && canonBlock . Hash ( ) != block . Hash ( ) {
stale = "stale "
} else {
confirm = "Wait 5 blocks for confirmation"
self . current . localMinedBlocks = newLocalMinedBlock ( block . Number ( ) . Uint64 ( ) , self . current . localMinedBlocks )
}
glog . V ( logger . Info ) . Infof ( "🔨 Mined %sblock (#%v / %x). %s" , stale , block . Number ( ) , block . Hash ( ) . Bytes ( ) [ : 4 ] , confirm )
jsonlogger . LogJson ( & logger . EthMinerNewBlock {
BlockHash : block . Hash ( ) . Hex ( ) ,
BlockNumber : block . Number ( ) ,
ChainHeadHash : block . ParentHeaderHash . Hex ( ) ,
BlockPrevHash : block . ParentHeaderHash . Hex ( ) ,
} )
} else {
self . commitNewWork ( )
}
}
}
}
func ( self * worker ) push ( ) {
if atomic . LoadInt32 ( & self . mining ) == 1 {
self . current . block . Header ( ) . GasUsed = self . current . totalUsedGas
self . current . block . SetRoot ( self . current . state . Root ( ) )
// push new work to agents
for _ , agent := range self . agents {
atomic . AddInt32 ( & self . atWork , 1 )
if agent . Work ( ) != nil {
agent . Work ( ) <- self . current . block . Copy ( )
} else {
common . Report ( fmt . Sprintf ( "%v %T\n" , agent , agent ) )
}
}
}
}
func ( self * worker ) makeCurrent ( ) {
block := self . chain . NewBlock ( self . coinbase )
parent := self . chain . GetBlock ( block . ParentHash ( ) )
// TMP fix for build server ...
if parent == nil {
return
}
if block . Time ( ) <= parent . Time ( ) {
block . Header ( ) . Time = parent . Header ( ) . Time + 1
}
block . Header ( ) . Extra = self . extra
// when 08 is processed ancestors contain 07 (quick block)
current := env ( block , self . eth )
for _ , ancestor := range self . chain . GetAncestors ( block , 7 ) {
for _ , uncle := range ancestor . Uncles ( ) {
current . family . Add ( uncle . Hash ( ) )
}
current . family . Add ( ancestor . Hash ( ) )
current . ancestors . Add ( ancestor . Hash ( ) )
}
accounts , _ := self . eth . AccountManager ( ) . Accounts ( )
// Keep track of transactions which return errors so they can be removed
current . remove = set . New ( )
current . tcount = 0
current . ignoredTransactors = set . New ( )
current . lowGasTransactors = set . New ( )
current . ownedAccounts = accountAddressesSet ( accounts )
if self . current != nil {
current . localMinedBlocks = self . current . localMinedBlocks
}
current . coinbase . SetGasPool ( core . CalcGasLimit ( parent ) )
self . current = current
}
func ( w * worker ) setGasPrice ( p * big . Int ) {
w . mu . Lock ( )
defer w . mu . Unlock ( )
// calculate the minimal gas price the miner accepts when sorting out transactions.
const pct = int64 ( 90 )
w . gasPrice = gasprice ( p , pct )
w . mux . Post ( core . GasPriceChanged { w . gasPrice } )
}
func ( self * worker ) isBlockLocallyMined ( deepBlockNum uint64 ) bool {
//Did this instance mine a block at {deepBlockNum} ?
var isLocal = false
for idx , blockNum := range self . current . localMinedBlocks . ints {
if deepBlockNum == blockNum {
isLocal = true
self . current . localMinedBlocks . ints [ idx ] = 0 //prevent showing duplicate logs
break
}
}
//Short-circuit on false, because the previous and following tests must both be true
if ! isLocal {
return false
}
//Does the block at {deepBlockNum} send earnings to my coinbase?
var block = self . chain . GetBlockByNumber ( deepBlockNum )
return block . Header ( ) . Coinbase == self . coinbase
}
func ( self * worker ) logLocalMinedBlocks ( previous * environment ) {
if previous != nil && self . current . localMinedBlocks != nil {
nextBlockNum := self . current . block . Number ( ) . Uint64 ( )
for checkBlockNum := previous . block . Number ( ) . Uint64 ( ) ; checkBlockNum < nextBlockNum ; checkBlockNum ++ {
inspectBlockNum := checkBlockNum - miningLogAtDepth
if self . isBlockLocallyMined ( inspectBlockNum ) {
glog . V ( logger . Info ) . Infof ( "🔨 🔗 Mined %d blocks back: block #%v" , miningLogAtDepth , inspectBlockNum )
}
}
}
}
func ( self * worker ) commitNewWork ( ) {
self . mu . Lock ( )
defer self . mu . Unlock ( )
self . uncleMu . Lock ( )
defer self . uncleMu . Unlock ( )
self . currentMu . Lock ( )
defer self . currentMu . Unlock ( )
previous := self . current
self . makeCurrent ( )
current := self . current
transactions := self . eth . TxPool ( ) . GetTransactions ( )
sort . Sort ( types . TxByNonce { transactions } )
// commit transactions for this run
self . commitTransactions ( transactions )
self . eth . TxPool ( ) . RemoveTransactions ( current . lowGasTxs )
var (
uncles [ ] * types . Header
badUncles [ ] common . Hash
)
for hash , uncle := range self . possibleUncles {
if len ( uncles ) == 2 {
break
}
if err := self . commitUncle ( uncle . Header ( ) ) ; err != nil {
if glog . V ( logger . Ridiculousness ) {
glog . V ( logger . Detail ) . Infof ( "Bad uncle found and will be removed (%x)\n" , hash [ : 4 ] )
glog . V ( logger . Detail ) . Infoln ( uncle )
}
badUncles = append ( badUncles , hash )
} else {
glog . V ( logger . Debug ) . Infof ( "commiting %x as uncle\n" , hash [ : 4 ] )
uncles = append ( uncles , uncle . Header ( ) )
}
}
// We only care about logging if we're actually mining
if atomic . LoadInt32 ( & self . mining ) == 1 {
glog . V ( logger . Info ) . Infof ( "commit new work on block %v with %d txs & %d uncles\n" , current . block . Number ( ) , current . tcount , len ( uncles ) )
self . logLocalMinedBlocks ( previous )
}
for _ , hash := range badUncles {
delete ( self . possibleUncles , hash )
}
self . current . block . SetUncles ( uncles )
core . AccumulateRewards ( self . current . state , self . current . block )
self . current . state . Update ( )
self . push ( )
}
var (
inclusionReward = new ( big . Int ) . Div ( core . BlockReward , big . NewInt ( 32 ) )
_uncleReward = new ( big . Int ) . Mul ( core . BlockReward , big . NewInt ( 15 ) )
uncleReward = new ( big . Int ) . Div ( _uncleReward , big . NewInt ( 16 ) )
)
func ( self * worker ) commitUncle ( uncle * types . Header ) error {
if self . current . uncles . Has ( uncle . Hash ( ) ) {
// Error not unique
return core . UncleError ( "Uncle not unique" )
}
self . current . uncles . Add ( uncle . Hash ( ) )
if ! self . current . ancestors . Has ( uncle . ParentHash ) {
return core . UncleError ( fmt . Sprintf ( "Uncle's parent unknown (%x)" , uncle . ParentHash [ 0 : 4 ] ) )
}
if self . current . family . Has ( uncle . Hash ( ) ) {
return core . UncleError ( fmt . Sprintf ( "Uncle already in family (%x)" , uncle . Hash ( ) ) )
}
return nil
}
func ( self * worker ) commitTransactions ( transactions types . Transactions ) {
current := self . current
for _ , tx := range transactions {
// We can skip err. It has already been validated in the tx pool
from , _ := tx . From ( )
// Check if it falls within margin. Txs from owned accounts are always processed.
if tx . GasPrice ( ) . Cmp ( self . gasPrice ) < 0 && ! current . ownedAccounts . Has ( from ) {
// ignore the transaction and transactor. We ignore the transactor
// because nonce will fail after ignoring this transaction so there's
// no point
current . lowGasTransactors . Add ( from )
glog . V ( logger . Info ) . Infof ( "transaction(%x) below gas price (tx=%v ask=%v). All sequential txs from this address(%x) will be ignored\n" , tx . Hash ( ) . Bytes ( ) [ : 4 ] , common . CurrencyToString ( tx . GasPrice ( ) ) , common . CurrencyToString ( self . gasPrice ) , from [ : 4 ] )
}
// Continue with the next transaction if the transaction sender is included in
// the low gas tx set. This will also remove the tx and all sequential transaction
// from this transactor
if current . lowGasTransactors . Has ( from ) {
// add tx to the low gas set. This will be removed at the end of the run
// owned accounts are ignored
if ! current . ownedAccounts . Has ( from ) {
current . lowGasTxs = append ( current . lowGasTxs , tx )
}
continue
}
// Move on to the next transaction when the transactor is in ignored transactions set
// This may occur when a transaction hits the gas limit. When a gas limit is hit and
// the transaction is processed (that could potentially be included in the block) it
// will throw a nonce error because the previous transaction hasn't been processed.
// Therefor we need to ignore any transaction after the ignored one.
if current . ignoredTransactors . Has ( from ) {
continue
}
self . current . state . StartRecord ( tx . Hash ( ) , common . Hash { } , 0 )
err := self . commitTransaction ( tx )
switch {
case core . IsNonceErr ( err ) || core . IsInvalidTxErr ( err ) :
// Remove invalid transactions
from , _ := tx . From ( )
self . chain . TxState ( ) . RemoveNonce ( from , tx . Nonce ( ) )
current . remove . Add ( tx . Hash ( ) )
if glog . V ( logger . Detail ) {
glog . Infof ( "TX (%x) failed, will be removed: %v\n" , tx . Hash ( ) . Bytes ( ) [ : 4 ] , err )
}
case state . IsGasLimitErr ( err ) :
from , _ := tx . From ( )
// ignore the transactor so no nonce errors will be thrown for this account
// next time the worker is run, they'll be picked up again.
current . ignoredTransactors . Add ( from )
glog . V ( logger . Detail ) . Infof ( "Gas limit reached for (%x) in this block. Continue to try smaller txs\n" , from [ : 4 ] )
default :
current . tcount ++
}
}
}
func ( self * worker ) commitTransaction ( tx * types . Transaction ) error {
snap := self . current . state . Copy ( )
receipt , _ , err := self . proc . ApplyTransaction ( self . current . coinbase , self . current . state , self . current . block , tx , self . current . totalUsedGas , true )
if err != nil && ( core . IsNonceErr ( err ) || state . IsGasLimitErr ( err ) || core . IsInvalidTxErr ( err ) ) {
self . current . state . Set ( snap )
return err
}
self . current . block . AddTransaction ( tx )
self . current . block . AddReceipt ( receipt )
return nil
}
// TODO: remove or use
func ( self * worker ) HashRate ( ) int64 {
return 0
}
// gasprice calculates a reduced gas price based on the pct
// XXX Use big.Rat?
func gasprice ( price * big . Int , pct int64 ) * big . Int {
p := new ( big . Int ) . Set ( price )
p . Div ( p , big . NewInt ( 100 ) )
p . Mul ( p , big . NewInt ( pct ) )
return p
}
func accountAddressesSet ( accounts [ ] accounts . Account ) * set . Set {
accountSet := set . New ( )
for _ , account := range accounts {
accountSet . Add ( account . Address )
}
return accountSet
}