package eth
import (
"bytes"
"container/list"
"fmt"
"net"
"strconv"
"strings"
"sync/atomic"
"time"
"github.com/ethereum/eth-go/ethchain"
"github.com/ethereum/eth-go/ethlog"
"github.com/ethereum/eth-go/ethutil"
"github.com/ethereum/eth-go/ethwire"
)
var peerlogger = ethlog . NewLogger ( "PEER" )
const (
// The size of the output buffer for writing messages
outputBufferSize = 50
// Current protocol version
ProtocolVersion = 25
// Interval for ping/pong message
pingPongTimer = 2 * time . Second
)
type DiscReason byte
const (
// Values are given explicitly instead of by iota because these values are
// defined by the wire protocol spec; it is easier for humans to ensure
// correctness when values are explicit.
DiscReRequested = 0x00
DiscReTcpSysErr = 0x01
DiscBadProto = 0x02
DiscBadPeer = 0x03
DiscTooManyPeers = 0x04
DiscConnDup = 0x05
DiscGenesisErr = 0x06
DiscProtoErr = 0x07
DiscQuitting = 0x08
)
var discReasonToString = [ ] string {
"requested" ,
"TCP sys error" ,
"bad protocol" ,
"useless peer" ,
"too many peers" ,
"already connected" ,
"wrong genesis block" ,
"incompatible network" ,
"quitting" ,
}
func ( d DiscReason ) String ( ) string {
if len ( discReasonToString ) < int ( d ) {
return "Unknown"
}
return discReasonToString [ d ]
}
// Peer capabilities
type Caps byte
const (
CapPeerDiscTy = 1 << iota
CapTxTy
CapChainTy
CapDefault = CapChainTy | CapTxTy | CapPeerDiscTy
)
var capsToString = map [ Caps ] string {
CapPeerDiscTy : "Peer discovery" ,
CapTxTy : "Transaction relaying" ,
CapChainTy : "Block chain relaying" ,
}
func ( c Caps ) IsCap ( cap Caps ) bool {
return c & cap > 0
}
func ( c Caps ) String ( ) string {
var caps [ ] string
if c . IsCap ( CapPeerDiscTy ) {
caps = append ( caps , capsToString [ CapPeerDiscTy ] )
}
if c . IsCap ( CapChainTy ) {
caps = append ( caps , capsToString [ CapChainTy ] )
}
if c . IsCap ( CapTxTy ) {
caps = append ( caps , capsToString [ CapTxTy ] )
}
return strings . Join ( caps , " | " )
}
type Peer struct {
// Ethereum interface
ethereum * Ethereum
// Net connection
conn net . Conn
// Output queue which is used to communicate and handle messages
outputQueue chan * ethwire . Msg
// Quit channel
quit chan bool
// Determines whether it's an inbound or outbound peer
inbound bool
// Flag for checking the peer's connectivity state
connected int32
disconnect int32
// Last known message send
lastSend time . Time
// Indicated whether a verack has been send or not
// This flag is used by writeMessage to check if messages are allowed
// to be send or not. If no version is known all messages are ignored.
versionKnown bool
// Last received pong message
lastPong int64
lastBlockReceived time . Time
host [ ] byte
port uint16
caps Caps
// This peer's public key
pubkey [ ] byte
// Indicated whether the node is catching up or not
catchingUp bool
diverted bool
blocksRequested int
version string
// We use this to give some kind of pingtime to a node, not very accurate, could be improved.
pingTime time . Duration
pingStartTime time . Time
lastRequestedBlock * ethchain . Block
}
func NewPeer ( conn net . Conn , ethereum * Ethereum , inbound bool ) * Peer {
pubkey := ethereum . KeyManager ( ) . PublicKey ( ) [ 1 : ]
return & Peer {
outputQueue : make ( chan * ethwire . Msg , outputBufferSize ) ,
quit : make ( chan bool ) ,
ethereum : ethereum ,
conn : conn ,
inbound : inbound ,
disconnect : 0 ,
connected : 1 ,
port : 30303 ,
pubkey : pubkey ,
blocksRequested : 10 ,
caps : ethereum . ServerCaps ( ) ,
version : ethereum . ClientIdentity ( ) . String ( ) ,
}
}
func NewOutboundPeer ( addr string , ethereum * Ethereum , caps Caps ) * Peer {
p := & Peer {
outputQueue : make ( chan * ethwire . Msg , outputBufferSize ) ,
quit : make ( chan bool ) ,
ethereum : ethereum ,
inbound : false ,
connected : 0 ,
disconnect : 0 ,
caps : caps ,
version : ethereum . ClientIdentity ( ) . String ( ) ,
}
// Set up the connection in another goroutine so we don't block the main thread
go func ( ) {
conn , err := p . Connect ( addr )
if err != nil {
peerlogger . Debugln ( "Connection to peer failed. Giving up." , err )
p . Stop ( )
return
}
p . conn = conn
// Atomically set the connection state
atomic . StoreInt32 ( & p . connected , 1 )
atomic . StoreInt32 ( & p . disconnect , 0 )
p . Start ( )
} ( )
return p
}
func ( self * Peer ) Connect ( addr string ) ( conn net . Conn , err error ) {
const maxTries = 3
for attempts := 0 ; attempts < maxTries ; attempts ++ {
conn , err = net . DialTimeout ( "tcp" , addr , 10 * time . Second )
if err != nil {
//peerlogger.Debugf("Peer connection failed. Retrying (%d/%d) (%s)\n", attempts+1, maxTries, addr)
time . Sleep ( time . Duration ( attempts * 20 ) * time . Second )
continue
}
// Success
return
}
return
}
// Getters
func ( p * Peer ) PingTime ( ) string {
return p . pingTime . String ( )
}
func ( p * Peer ) Inbound ( ) bool {
return p . inbound
}
func ( p * Peer ) LastSend ( ) time . Time {
return p . lastSend
}
func ( p * Peer ) LastPong ( ) int64 {
return p . lastPong
}
func ( p * Peer ) Host ( ) [ ] byte {
return p . host
}
func ( p * Peer ) Port ( ) uint16 {
return p . port
}
func ( p * Peer ) Version ( ) string {
return p . version
}
func ( p * Peer ) Connected ( ) * int32 {
return & p . connected
}
// Setters
func ( p * Peer ) SetVersion ( version string ) {
p . version = version
}
// Outputs any RLP encoded data to the peer
func ( p * Peer ) QueueMessage ( msg * ethwire . Msg ) {
if atomic . LoadInt32 ( & p . connected ) != 1 {
return
}
p . outputQueue <- msg
}
func ( p * Peer ) writeMessage ( msg * ethwire . Msg ) {
// Ignore the write if we're not connected
if atomic . LoadInt32 ( & p . connected ) != 1 {
return
}
if ! p . versionKnown {
switch msg . Type {
case ethwire . MsgHandshakeTy : // Ok
default : // Anything but ack is allowed
return
}
}
peerlogger . DebugDetailf ( "(%v) <= %v %v\n" , p . conn . RemoteAddr ( ) , msg . Type , msg . Data )
err := ethwire . WriteMessage ( p . conn , msg )
if err != nil {
peerlogger . Debugln ( " Can't send message:" , err )
// Stop the client if there was an error writing to it
p . Stop ( )
return
}
}
// Outbound message handler. Outbound messages are handled here
func ( p * Peer ) HandleOutbound ( ) {
// The ping timer. Makes sure that every 2 minutes a ping is send to the peer
pingTimer := time . NewTicker ( pingPongTimer )
serviceTimer := time . NewTicker ( 5 * time . Minute )
out :
for {
select {
// Main message queue. All outbound messages are processed through here
case msg := <- p . outputQueue :
p . writeMessage ( msg )
p . lastSend = time . Now ( )
// Ping timer
case <- pingTimer . C :
/ *
timeSince := time . Since ( time . Unix ( p . lastPong , 0 ) )
if ! p . pingStartTime . IsZero ( ) && p . lastPong != 0 && timeSince > ( pingPongTimer + 30 * time . Second ) {
peerlogger . Infof ( "Peer did not respond to latest pong fast enough, it took %s, disconnecting.\n" , timeSince )
p . Stop ( )
return
}
* /
p . writeMessage ( ethwire . NewMessage ( ethwire . MsgPingTy , "" ) )
p . pingStartTime = time . Now ( )
// Service timer takes care of peer broadcasting, transaction
// posting or block posting
case <- serviceTimer . C :
if p . caps & CapPeerDiscTy > 0 {
msg := p . peersMessage ( )
p . ethereum . BroadcastMsg ( msg )
}
case <- p . quit :
// Break out of the for loop if a quit message is posted
break out
}
}
clean :
// This loop is for draining the output queue and anybody waiting for us
for {
select {
case <- p . outputQueue :
// TODO
default :
break clean
}
}
}
// Inbound handler. Inbound messages are received here and passed to the appropriate methods
func ( p * Peer ) HandleInbound ( ) {
for atomic . LoadInt32 ( & p . disconnect ) == 0 {
// HMM?
time . Sleep ( 50 * time . Millisecond )
// Wait for a message from the peer
msgs , err := ethwire . ReadMessages ( p . conn )
if err != nil {
peerlogger . Debugln ( err )
}
for _ , msg := range msgs {
peerlogger . DebugDetailf ( "(%v) => %v %v\n" , p . conn . RemoteAddr ( ) , msg . Type , msg . Data )
nextMsg :
switch msg . Type {
case ethwire . MsgHandshakeTy :
// Version message
p . handleHandshake ( msg )
if p . caps . IsCap ( CapPeerDiscTy ) {
p . QueueMessage ( ethwire . NewMessage ( ethwire . MsgGetPeersTy , "" ) )
}
case ethwire . MsgDiscTy :
p . Stop ( )
peerlogger . Infoln ( "Disconnect peer: " , DiscReason ( msg . Data . Get ( 0 ) . Uint ( ) ) )
case ethwire . MsgPingTy :
// Respond back with pong
p . QueueMessage ( ethwire . NewMessage ( ethwire . MsgPongTy , "" ) )
case ethwire . MsgPongTy :
// If we received a pong back from a peer we set the
// last pong so the peer handler knows this peer is still
// active.
p . lastPong = time . Now ( ) . Unix ( )
p . pingTime = time . Since ( p . pingStartTime )
case ethwire . MsgBlockTy :
// Get all blocks and process them
//var block, lastBlock *ethchain.Block
//var err error
var (
block , lastBlock * ethchain . Block
blockChain = p . ethereum . BlockChain ( )
err error
)
// Make sure we are actually receiving anything
if msg . Data . Len ( ) - 1 > 1 && p . diverted {
// We requested blocks and now we need to make sure we have a common ancestor somewhere in these blocks so we can find
// common ground to start syncing from
lastBlock = ethchain . NewBlockFromRlpValue ( msg . Data . Get ( msg . Data . Len ( ) - 1 ) )
if p . lastRequestedBlock != nil && bytes . Compare ( lastBlock . Hash ( ) , p . lastRequestedBlock . Hash ( ) ) == 0 {
p . catchingUp = false
continue
}
p . lastRequestedBlock = lastBlock
peerlogger . Infof ( "Last block: %x. Checking if we have it locally.\n" , lastBlock . Hash ( ) )
for i := msg . Data . Len ( ) - 1 ; i >= 0 ; i -- {
block = ethchain . NewBlockFromRlpValue ( msg . Data . Get ( i ) )
// Do we have this block on our chain? If so we can continue
if ! blockChain . HasBlock ( block . Hash ( ) ) {
// We don't have this block, but we do have a block with the same prevHash, diversion time!
if blockChain . HasBlockWithPrevHash ( block . PrevHash ) {
p . diverted = false
if ! blockChain . FindCanonicalChainFromMsg ( msg , block . PrevHash ) {
p . SyncWithPeerToLastKnown ( )
break nextMsg
}
break
}
}
}
if ! blockChain . HasBlock ( lastBlock . Hash ( ) ) {
// If we can't find a common ancenstor we need to request more blocks.
// FIXME: At one point this won't scale anymore since we are not asking for an offset
// we just keep increasing the amount of blocks.
p . blocksRequested = p . blocksRequested * 2
peerlogger . Infof ( "No common ancestor found, requesting %d more blocks.\n" , p . blocksRequested )
p . FindCommonParentBlock ( )
break nextMsg
}
p . catchingUp = false
}
for i := msg . Data . Len ( ) - 1 ; i >= 0 ; i -- {
block = ethchain . NewBlockFromRlpValue ( msg . Data . Get ( i ) )
err = p . ethereum . StateManager ( ) . Process ( block , false )
if err != nil {
if ethutil . Config . Debug {
peerlogger . Infof ( "Block %x failed\n" , block . Hash ( ) )
peerlogger . Infof ( "%v\n" , err )
peerlogger . Debugln ( block )
}
break
} else {
lastBlock = block
}
p . lastBlockReceived = time . Now ( )
}
if msg . Data . Len ( ) <= 1 {
// Set catching up to false if
// the peer has nothing left to give
p . catchingUp = false
}
if err != nil {
// If the parent is unknown try to catch up with this peer
if ethchain . IsParentErr ( err ) {
b := ethchain . NewBlockFromRlpValue ( msg . Data . Get ( 0 ) )
peerlogger . Infof ( "Attempting to catch (%x). Parent unknown\n" , b . Hash ( ) )
p . catchingUp = false
p . CatchupWithPeer ( b . PrevHash )
peerlogger . Infoln ( b )
/ *
peerlogger . Infoln ( "Attempting to catch. Parent known" )
p . catchingUp = false
p . CatchupWithPeer ( p . ethereum . BlockChain ( ) . CurrentBlock . Hash ( ) )
* /
} else if ethchain . IsValidationErr ( err ) {
fmt . Println ( "Err:" , err )
p . catchingUp = false
}
} else {
// If we're catching up, try to catch up further.
if p . catchingUp && msg . Data . Len ( ) > 1 {
if lastBlock != nil {
blockInfo := lastBlock . BlockInfo ( )
peerlogger . DebugDetailf ( "Synced chain to #%d %x %x\n" , blockInfo . Number , lastBlock . Hash ( ) , blockInfo . Hash )
}
p . catchingUp = false
hash := p . ethereum . BlockChain ( ) . CurrentBlock . Hash ( )
p . CatchupWithPeer ( hash )
}
}
case ethwire . MsgTxTy :
// If the message was a transaction queue the transaction
// in the TxPool where it will undergo validation and
// processing when a new block is found
for i := 0 ; i < msg . Data . Len ( ) ; i ++ {
tx := ethchain . NewTransactionFromValue ( msg . Data . Get ( i ) )
p . ethereum . TxPool ( ) . QueueTransaction ( tx )
}
case ethwire . MsgGetPeersTy :
// Peer asked for list of connected peers
p . pushPeers ( )
case ethwire . MsgPeersTy :
// Received a list of peers (probably because MsgGetPeersTy was send)
data := msg . Data
// Create new list of possible peers for the ethereum to process
peers := make ( [ ] string , data . Len ( ) )
// Parse each possible peer
for i := 0 ; i < data . Len ( ) ; i ++ {
value := data . Get ( i )
peers [ i ] = unpackAddr ( value . Get ( 0 ) , value . Get ( 1 ) . Uint ( ) )
}
// Connect to the list of peers
p . ethereum . ProcessPeerList ( peers )
case ethwire . MsgGetChainTy :
var parent * ethchain . Block
// Length minus one since the very last element in the array is a count
l := msg . Data . Len ( ) - 1
// Ignore empty get chains
if l == 0 {
break
}
// Amount of parents in the canonical chain
//amountOfBlocks := msg.Data.Get(l).AsUint()
amountOfBlocks := uint64 ( 100 )
// Check each SHA block hash from the message and determine whether
// the SHA is in the database
for i := 0 ; i < l ; i ++ {
if data := msg . Data . Get ( i ) . Bytes ( ) ; p . ethereum . StateManager ( ) . BlockChain ( ) . HasBlock ( data ) {
parent = p . ethereum . BlockChain ( ) . GetBlock ( data )
break
}
}
// If a parent is found send back a reply
if parent != nil {
peerlogger . DebugDetailf ( "Found canonical block, returning chain from: %x " , parent . Hash ( ) )
chain := p . ethereum . BlockChain ( ) . GetChainFromHash ( parent . Hash ( ) , amountOfBlocks )
if len ( chain ) > 0 {
//peerlogger.Debugf("Returning %d blocks: %x ", len(chain), parent.Hash())
p . QueueMessage ( ethwire . NewMessage ( ethwire . MsgBlockTy , chain ) )
} else {
p . QueueMessage ( ethwire . NewMessage ( ethwire . MsgBlockTy , [ ] interface { } { } ) )
}
} else {
//peerlogger.Debugf("Could not find a similar block")
// If no blocks are found we send back a reply with msg not in chain
// and the last hash from get chain
if l > 0 {
lastHash := msg . Data . Get ( l - 1 )
//log.Printf("Sending not in chain with hash %x\n", lastHash.AsRaw())
p . QueueMessage ( ethwire . NewMessage ( ethwire . MsgNotInChainTy , [ ] interface { } { lastHash . Raw ( ) } ) )
}
}
case ethwire . MsgNotInChainTy :
peerlogger . DebugDetailf ( "Not in chain: %x\n" , msg . Data . Get ( 0 ) . Bytes ( ) )
if p . diverted == true {
// If were already looking for a common parent and we get here again we need to go deeper
p . blocksRequested = p . blocksRequested * 2
}
p . diverted = true
p . catchingUp = false
p . FindCommonParentBlock ( )
case ethwire . MsgGetTxsTy :
// Get the current transactions of the pool
txs := p . ethereum . TxPool ( ) . CurrentTransactions ( )
// Get the RlpData values from the txs
txsInterface := make ( [ ] interface { } , len ( txs ) )
for i , tx := range txs {
txsInterface [ i ] = tx . RlpData ( )
}
// Broadcast it back to the peer
p . QueueMessage ( ethwire . NewMessage ( ethwire . MsgTxTy , txsInterface ) )
// Unofficial but fun nonetheless
case ethwire . MsgTalkTy :
peerlogger . Infoln ( "%v says: %s\n" , p . conn . RemoteAddr ( ) , msg . Data . Str ( ) )
}
}
}
p . Stop ( )
}
// General update method
func ( self * Peer ) update ( ) {
serviceTimer := time . NewTicker ( 5 * time . Second )
out :
for {
select {
case <- serviceTimer . C :
if time . Since ( self . lastBlockReceived ) > 10 * time . Second {
self . catchingUp = false
}
case <- self . quit :
break out
}
}
serviceTimer . Stop ( )
}
func ( p * Peer ) Start ( ) {
peerHost , peerPort , _ := net . SplitHostPort ( p . conn . LocalAddr ( ) . String ( ) )
servHost , servPort , _ := net . SplitHostPort ( p . conn . RemoteAddr ( ) . String ( ) )
if p . inbound {
p . host , p . port = packAddr ( peerHost , peerPort )
} else {
p . host , p . port = packAddr ( servHost , servPort )
}
err := p . pushHandshake ( )
if err != nil {
peerlogger . Debugln ( "Peer can't send outbound version ack" , err )
p . Stop ( )
return
}
go p . HandleOutbound ( )
// Run the inbound handler in a new goroutine
go p . HandleInbound ( )
// Run the general update handler
go p . update ( )
// Wait a few seconds for startup and then ask for an initial ping
time . Sleep ( 2 * time . Second )
p . writeMessage ( ethwire . NewMessage ( ethwire . MsgPingTy , "" ) )
p . pingStartTime = time . Now ( )
}
func ( p * Peer ) Stop ( ) {
if atomic . AddInt32 ( & p . disconnect , 1 ) != 1 {
return
}
close ( p . quit )
if atomic . LoadInt32 ( & p . connected ) != 0 {
p . writeMessage ( ethwire . NewMessage ( ethwire . MsgDiscTy , "" ) )
p . conn . Close ( )
}
// Pre-emptively remove the peer; don't wait for reaping. We already know it's dead if we are here
p . ethereum . RemovePeer ( p )
}
func ( p * Peer ) pushHandshake ( ) error {
pubkey := p . ethereum . KeyManager ( ) . PublicKey ( )
msg := ethwire . NewMessage ( ethwire . MsgHandshakeTy , [ ] interface { } {
uint32 ( ProtocolVersion ) , uint32 ( 0 ) , [ ] byte ( p . version ) , byte ( p . caps ) , p . port , pubkey [ 1 : ] ,
} )
p . QueueMessage ( msg )
return nil
}
func ( p * Peer ) peersMessage ( ) * ethwire . Msg {
outPeers := make ( [ ] interface { } , len ( p . ethereum . InOutPeers ( ) ) )
// Serialise each peer
for i , peer := range p . ethereum . InOutPeers ( ) {
// Don't return localhost as valid peer
if ! net . ParseIP ( peer . conn . RemoteAddr ( ) . String ( ) ) . IsLoopback ( ) {
outPeers [ i ] = peer . RlpData ( )
}
}
// Return the message to the peer with the known list of connected clients
return ethwire . NewMessage ( ethwire . MsgPeersTy , outPeers )
}
// Pushes the list of outbound peers to the client when requested
func ( p * Peer ) pushPeers ( ) {
p . QueueMessage ( p . peersMessage ( ) )
}
func ( p * Peer ) handleHandshake ( msg * ethwire . Msg ) {
c := msg . Data
// Set pubkey
p . pubkey = c . Get ( 5 ) . Bytes ( )
if p . pubkey == nil {
peerlogger . Warnln ( "Pubkey required, not supplied in handshake." )
p . Stop ( )
return
}
usedPub := 0
// This peer is already added to the peerlist so we expect to find a double pubkey at least once
eachPeer ( p . ethereum . Peers ( ) , func ( peer * Peer , e * list . Element ) {
if bytes . Compare ( p . pubkey , peer . pubkey ) == 0 {
usedPub ++
}
} )
if usedPub > 0 {
peerlogger . Debugf ( "Pubkey %x found more then once. Already connected to client." , p . pubkey )
p . Stop ( )
return
}
if c . Get ( 0 ) . Uint ( ) != ProtocolVersion {
peerlogger . Debugf ( "Invalid peer version. Require protocol: %d. Received: %d\n" , ProtocolVersion , c . Get ( 0 ) . Uint ( ) )
p . Stop ( )
return
}
// [PROTOCOL_VERSION, NETWORK_ID, CLIENT_ID, CAPS, PORT, PUBKEY]
p . versionKnown = true
// If this is an inbound connection send an ack back
if p . inbound {
p . port = uint16 ( c . Get ( 4 ) . Uint ( ) )
// Self connect detection
pubkey := p . ethereum . KeyManager ( ) . PublicKey ( )
if bytes . Compare ( pubkey , p . pubkey ) == 0 {
p . Stop ( )
return
}
}
// Set the peer's caps
p . caps = Caps ( c . Get ( 3 ) . Byte ( ) )
// Get a reference to the peers version
versionString := c . Get ( 2 ) . Str ( )
if len ( versionString ) > 0 {
p . SetVersion ( c . Get ( 2 ) . Str ( ) )
}
p . ethereum . PushPeer ( p )
p . ethereum . reactor . Post ( "peerList" , p . ethereum . Peers ( ) )
ethlogger . Infof ( "Added peer (%s) %d / %d\n" , p . conn . RemoteAddr ( ) , p . ethereum . Peers ( ) . Len ( ) , p . ethereum . MaxPeers )
/ *
// Catch up with the connected peer
if ! p . ethereum . IsUpToDate ( ) {
peerlogger . Debugln ( "Already syncing up with a peer; sleeping" )
time . Sleep ( 10 * time . Second )
}
* /
p . SyncWithPeerToLastKnown ( )
peerlogger . Debugln ( p )
}
func ( p * Peer ) String ( ) string {
var strBoundType string
if p . inbound {
strBoundType = "inbound"
} else {
strBoundType = "outbound"
}
var strConnectType string
if atomic . LoadInt32 ( & p . disconnect ) == 0 {
strConnectType = "connected"
} else {
strConnectType = "disconnected"
}
return fmt . Sprintf ( "[%s] (%s) %v %s [%s]" , strConnectType , strBoundType , p . conn . RemoteAddr ( ) , p . version , p . caps )
}
func ( p * Peer ) SyncWithPeerToLastKnown ( ) {
p . catchingUp = false
p . CatchupWithPeer ( p . ethereum . BlockChain ( ) . CurrentBlock . Hash ( ) )
}
func ( p * Peer ) FindCommonParentBlock ( ) {
if p . catchingUp {
return
}
p . catchingUp = true
if p . blocksRequested == 0 {
p . blocksRequested = 20
}
blocks := p . ethereum . BlockChain ( ) . GetChain ( p . ethereum . BlockChain ( ) . CurrentBlock . Hash ( ) , p . blocksRequested )
var hashes [ ] interface { }
for _ , block := range blocks {
hashes = append ( hashes , block . Hash ( ) )
}
msgInfo := append ( hashes , uint64 ( len ( hashes ) ) )
peerlogger . DebugDetailf ( "Asking for block from %x (%d total) from %s\n" , p . ethereum . BlockChain ( ) . CurrentBlock . Hash ( ) , len ( hashes ) , p . conn . RemoteAddr ( ) . String ( ) )
msg := ethwire . NewMessage ( ethwire . MsgGetChainTy , msgInfo )
p . QueueMessage ( msg )
}
func ( p * Peer ) CatchupWithPeer ( blockHash [ ] byte ) {
if ! p . catchingUp {
// Make sure nobody else is catching up when you want to do this
p . catchingUp = true
msg := ethwire . NewMessage ( ethwire . MsgGetChainTy , [ ] interface { } { blockHash , uint64 ( 100 ) } )
p . QueueMessage ( msg )
peerlogger . DebugDetailf ( "Requesting blockchain %x... from peer %s\n" , p . ethereum . BlockChain ( ) . CurrentBlock . Hash ( ) [ : 4 ] , p . conn . RemoteAddr ( ) )
msg = ethwire . NewMessage ( ethwire . MsgGetTxsTy , [ ] interface { } { } )
p . QueueMessage ( msg )
}
}
func ( p * Peer ) RlpData ( ) [ ] interface { } {
return [ ] interface { } { p . host , p . port , p . pubkey }
}
func packAddr ( address , port string ) ( [ ] byte , uint16 ) {
addr := strings . Split ( address , "." )
a , _ := strconv . Atoi ( addr [ 0 ] )
b , _ := strconv . Atoi ( addr [ 1 ] )
c , _ := strconv . Atoi ( addr [ 2 ] )
d , _ := strconv . Atoi ( addr [ 3 ] )
host := [ ] byte { byte ( a ) , byte ( b ) , byte ( c ) , byte ( d ) }
prt , _ := strconv . Atoi ( port )
return host , uint16 ( prt )
}
func unpackAddr ( value * ethutil . Value , p uint64 ) string {
byts := value . Bytes ( )
a := strconv . Itoa ( int ( byts [ 0 ] ) )
b := strconv . Itoa ( int ( byts [ 1 ] ) )
c := strconv . Itoa ( int ( byts [ 2 ] ) )
d := strconv . Itoa ( int ( byts [ 3 ] ) )
host := strings . Join ( [ ] string { a , b , c , d } , "." )
port := strconv . Itoa ( int ( p ) )
return net . JoinHostPort ( host , port )
}