// Load the most recent state from "state" db,
// or create a new one (and save) from genesis.
func getState(config cfg.Config, stateDB dbm.DB) *sm.State {
state := sm.LoadState(stateDB)
if state == nil {
state = sm.MakeGenesisStateFromFile(stateDB, config.GetString("genesis_file"))
state.Save()
}
return state
}
// Load the most recent state from "state" db,
// or create a new one (and save) from genesis.
func getState() *sm.State {
stateDB := dbm.GetDB("state")
state := sm.LoadState(stateDB)
if state == nil {
state = sm.MakeGenesisStateFromFile(stateDB, config.GetString("genesis_file"))
state.Save()
}
return state
}
func gen_tx() {
// Get State, which may be nil.
stateDB := dbm.GetDB("state")
state := sm.LoadState(stateDB)
// Get source pubkey
srcPubKeyBytes := getByteSliceFromHex("Enter source pubkey: ")
r, n, err := bytes.NewReader(srcPubKeyBytes), new(int64), new(error)
srcPubKey := binary.ReadBinary(struct{ account.PubKey }{}, r, n, err).(struct{ account.PubKey }).PubKey
if *err != nil {
Exit(Fmt("Invalid PubKey. Error: %v", err))
}
// Get the state of the account.
var srcAccount *account.Account
var srcAccountAddress = srcPubKey.Address()
var srcAccountBalanceStr = "unknown"
var srcAccountSequenceStr = "unknown"
srcAddress := srcPubKey.Address()
if state != nil {
srcAccount = state.GetAccount(srcAddress)
srcAccountBalanceStr = Fmt("%v", srcAccount.Balance)
srcAccountSequenceStr = Fmt("%v", srcAccount.Sequence+1)
}
// Get the amount to send from src account
srcSendAmount := getUint64(Fmt("Enter amount to send from %X (total: %v): ", srcAccountAddress, srcAccountBalanceStr))
// Get the next sequence of src account
srcSendSequence := uint(getUint64(Fmt("Enter next sequence for %X (guess: %v): ", srcAccountAddress, srcAccountSequenceStr)))
// Get dest address
dstAddress := getByteSliceFromHex("Enter destination address: ")
// Get the amount to send to dst account
dstSendAmount := getUint64(Fmt("Enter amount to send to %X: ", dstAddress))
// Construct SendTx
tx := &types.SendTx{
Inputs: []*types.TxInput{
&types.TxInput{
Address: srcAddress,
Amount: srcSendAmount,
Sequence: srcSendSequence,
Signature: account.SignatureEd25519{},
PubKey: srcPubKey,
},
},
Outputs: []*types.TxOutput{
&types.TxOutput{
Address: dstAddress,
Amount: dstSendAmount,
},
},
}
// Show the intermediate form.
fmt.Printf("Generated tx: %X\n", binary.BinaryBytes(tx))
// Get source privkey (for signing)
srcPrivKeyBytes := getByteSliceFromHex("Enter source privkey (for signing): ")
r, n, err = bytes.NewReader(srcPrivKeyBytes), new(int64), new(error)
srcPrivKey := binary.ReadBinary(struct{ account.PrivKey }{}, r, n, err).(struct{ account.PrivKey }).PrivKey
if *err != nil {
Exit(Fmt("Invalid PrivKey. Error: %v", err))
}
// Sign
tx.Inputs[0].Signature = srcPrivKey.Sign(account.SignBytes(tx))
fmt.Printf("Signed tx: %X\n", binary.BinaryBytes(tx))
}
// Handle messages from the poolReactor telling the reactor what to do.
func (bcR *BlockchainReactor) poolRoutine() {
trySyncTicker := time.NewTicker(trySyncIntervalMS * time.Millisecond)
statusUpdateTicker := time.NewTicker(statusUpdateIntervalSeconds * time.Second)
switchToConsensusTicker := time.NewTicker(switchToConsensusIntervalSeconds * time.Second)
FOR_LOOP:
for {
select {
case request := <-bcR.requestsCh: // chan BlockRequest
peer := bcR.sw.Peers().Get(request.PeerId)
if peer == nil {
// We can't fulfill the request.
continue FOR_LOOP
}
msg := &bcBlockRequestMessage{request.Height}
queued := peer.TrySend(BlockchainChannel, msg)
if !queued {
// We couldn't queue the request.
time.Sleep(defaultSleepIntervalMS * time.Millisecond)
continue FOR_LOOP
}
case peerId := <-bcR.timeoutsCh: // chan string
// Peer timed out.
peer := bcR.sw.Peers().Get(peerId)
if peer != nil {
bcR.sw.StopPeerForError(peer, errors.New("BlockchainReactor Timeout"))
}
case _ = <-statusUpdateTicker.C:
// ask for status updates
go bcR.BroadcastStatusRequest()
case _ = <-switchToConsensusTicker.C:
// not thread safe access for peerless and numPending but should be fine
log.Debug("Consensus ticker", "peerless", bcR.pool.peerless, "pending", bcR.pool.numPending, "total", bcR.pool.numTotal)
// NOTE: this condition is very strict right now. may need to weaken
// if the max amount of requests are pending and peerless
// and we have some peers (say > 5), then we're caught up
maxPending := bcR.pool.numPending == maxPendingRequests
maxPeerless := bcR.pool.peerless == bcR.pool.numPending
o, i, _ := bcR.sw.NumPeers()
enoughPeers := o+i >= 5
if maxPending && maxPeerless && enoughPeers {
log.Warn("Time to switch to consensus reactor!", "height", bcR.pool.height)
bcR.pool.Stop()
stateDB := dbm.GetDB("state")
state := sm.LoadState(stateDB)
bcR.sw.Reactor("CONSENSUS").(consensusReactor).ResetToState(state)
bcR.sw.Reactor("CONSENSUS").(consensusReactor).SetSyncing(false)
break FOR_LOOP
}
case _ = <-trySyncTicker.C: // chan time
//var lastValidatedBlock *types.Block
SYNC_LOOP:
for i := 0; i < 10; i++ {
// See if there are any blocks to sync.
first, second := bcR.pool.PeekTwoBlocks()
//log.Debug("TrySync peeked", "first", first, "second", second)
if first == nil || second == nil {
// We need both to sync the first block.
break SYNC_LOOP
}
firstParts := first.MakePartSet()
firstPartsHeader := firstParts.Header()
// Finally, verify the first block using the second's validation.
err := bcR.state.BondedValidators.VerifyValidation(
first.Hash(), firstPartsHeader, first.Height, second.Validation)
if err != nil {
log.Debug("error in validation", "error", err)
bcR.pool.RedoRequest(first.Height)
break SYNC_LOOP
} else {
bcR.pool.PopRequest()
err := sm.ExecBlock(bcR.state, first, firstPartsHeader)
if err != nil {
// TODO This is bad, are we zombie?
panic(Fmt("Failed to process committed block: %v", err))
}
bcR.store.SaveBlock(first, firstParts, second.Validation)
bcR.state.Save()
//lastValidatedBlock = first
}
}
/*
// We're done syncing for now (will do again shortly)
// See if we want to stop syncing and turn on the
// consensus reactor.
// TODO: use other heuristics too besides blocktime.
// It's not a security concern, as it only needs to happen
// upon node sync, and there's also a second (slower)
// this peer failed us
// method of syncing in the consensus reactor.
if lastValidatedBlock != nil && time.Now().Sub(lastValidatedBlock.Time) < stopSyncingDurationMinutes*time.Minute {
go func() {
log.Info("Stopping blockpool syncing, turning on consensus...")
trySyncTicker.Stop() // Just stop the block requests. Still serve blocks to others.
conR := bcR.sw.Reactor("CONSENSUS")
conR.(stateResetter).ResetToState(bcR.state)
conR.Start(bcR.sw)
for _, peer := range bcR.sw.Peers().List() {
conR.AddPeer(peer)
}
}()
break FOR_LOOP
}
*/
continue FOR_LOOP
case <-bcR.quit:
break FOR_LOOP
}
}
}
func NewNode() *Node {
// Get BlockStore
blockStoreDB := dbm.GetDB("blockstore")
blockStore := bc.NewBlockStore(blockStoreDB)
// Get State
stateDB := dbm.GetDB("state")
state := sm.LoadState(stateDB)
if state == nil {
state = sm.MakeGenesisStateFromFile(stateDB, config.GetString("genesis_file"))
state.Save()
}
// Get PrivValidator
var privValidator *sm.PrivValidator
privValidatorFile := config.GetString("priv_validator_file")
if _, err := os.Stat(privValidatorFile); err == nil {
privValidator = sm.LoadPrivValidator(privValidatorFile)
log.Info("Loaded PrivValidator",
"file", privValidatorFile, "privValidator", privValidator)
} else {
privValidator = sm.GenPrivValidator()
privValidator.SetFile(privValidatorFile)
privValidator.Save()
log.Info("Generated PrivValidator", "file", privValidatorFile)
}
eventSwitch := new(events.EventSwitch)
eventSwitch.Start()
// Get PEXReactor
book := p2p.NewAddrBook(config.GetString("addrbook_file"))
pexReactor := p2p.NewPEXReactor(book)
// Get BlockchainReactor
bcReactor := bc.NewBlockchainReactor(state, blockStore, config.GetBool("fast_sync"))
// Get MempoolReactor
mempool := mempl.NewMempool(state.Copy())
mempoolReactor := mempl.NewMempoolReactor(mempool)
// Get ConsensusReactor
consensusState := consensus.NewConsensusState(state, blockStore, mempoolReactor)
consensusReactor := consensus.NewConsensusReactor(consensusState, blockStore)
if privValidator != nil {
consensusReactor.SetPrivValidator(privValidator)
}
// so the consensus reactor won't do anything until we're synced
if config.GetBool("fast_sync") {
consensusReactor.SetSyncing(true)
}
sw := p2p.NewSwitch()
sw.AddReactor("PEX", pexReactor)
sw.AddReactor("MEMPOOL", mempoolReactor)
sw.AddReactor("BLOCKCHAIN", bcReactor)
sw.AddReactor("CONSENSUS", consensusReactor)
// add the event switch to all services
// they should all satisfy events.Eventable
SetFireable(eventSwitch, pexReactor, bcReactor, mempoolReactor, consensusReactor)
return &Node{
sw: sw,
evsw: eventSwitch,
book: book,
blockStore: blockStore,
pexReactor: pexReactor,
bcReactor: bcReactor,
mempoolReactor: mempoolReactor,
consensusState: consensusState,
consensusReactor: consensusReactor,
privValidator: privValidator,
}
}
func NewNode() *Node {
// Get BlockStore
blockStoreDB := dbm.GetDB("blockstore")
blockStore := bc.NewBlockStore(blockStoreDB)
// Get State
stateDB := dbm.GetDB("state")
state := sm.LoadState(stateDB)
var genDoc *stypes.GenesisDoc
if state == nil {
genDoc, state = sm.MakeGenesisStateFromFile(stateDB, config.GetString("genesis_file"))
state.Save()
// write the gendoc to db
buf, n, err := new(bytes.Buffer), new(int64), new(error)
wire.WriteJSON(genDoc, buf, n, err)
stateDB.Set(stypes.GenDocKey, buf.Bytes())
if *err != nil {
Exit(Fmt("Unable to write gendoc to db: %v", err))
}
} else {
genDocBytes := stateDB.Get(stypes.GenDocKey)
err := new(error)
wire.ReadJSONPtr(&genDoc, genDocBytes, err)
if *err != nil {
Exit(Fmt("Unable to read gendoc from db: %v", err))
}
}
// add the chainid to the global config
config.Set("chain_id", state.ChainID)
// Get PrivValidator
privValidatorFile := config.GetString("priv_validator_file")
privValidator := types.LoadOrGenPrivValidator(privValidatorFile)
// Generate node PrivKey
privKey := acm.GenPrivKeyEd25519()
// Make event switch
eventSwitch := events.NewEventSwitch()
_, err := eventSwitch.Start()
if err != nil {
Exit(Fmt("Failed to start switch: %v", err))
}
// Make PEXReactor
book := p2p.NewAddrBook(config.GetString("addrbook_file"))
pexReactor := p2p.NewPEXReactor(book)
// Make BlockchainReactor
bcReactor := bc.NewBlockchainReactor(state.Copy(), blockStore, config.GetBool("fast_sync"))
// Make MempoolReactor
mempool := mempl.NewMempool(state.Copy())
mempoolReactor := mempl.NewMempoolReactor(mempool)
// Make ConsensusReactor
consensusState := consensus.NewConsensusState(state.Copy(), blockStore, mempoolReactor)
consensusReactor := consensus.NewConsensusReactor(consensusState, blockStore, config.GetBool("fast_sync"))
if privValidator != nil {
consensusReactor.SetPrivValidator(privValidator)
}
// Make p2p network switch
sw := p2p.NewSwitch()
sw.AddReactor("PEX", pexReactor)
sw.AddReactor("MEMPOOL", mempoolReactor)
sw.AddReactor("BLOCKCHAIN", bcReactor)
sw.AddReactor("CONSENSUS", consensusReactor)
// add the event switch to all services
// they should all satisfy events.Eventable
SetFireable(eventSwitch, pexReactor, bcReactor, mempoolReactor, consensusReactor)
// run the profile server
profileHost := config.GetString("prof_laddr")
if profileHost != "" {
go func() {
log.Warn("Profile server", "error", http.ListenAndServe(profileHost, nil))
}()
}
// set vm log level
vm.SetDebug(config.GetBool("vm_log"))
return &Node{
sw: sw,
evsw: eventSwitch,
book: book,
blockStore: blockStore,
pexReactor: pexReactor,
bcReactor: bcReactor,
mempoolReactor: mempoolReactor,
consensusState: consensusState,
consensusReactor: consensusReactor,
privValidator: privValidator,
genDoc: genDoc,
privKey: privKey,
}
}