lbcd/peer.go
Dave Collins 83407ade61 Rework block fetching code.
This commit significantly reworks the fetching code to interop better with
bitcoind.  In particular, when an inventory message is sent, and the
remote peer requests the final block, the remote peer sends the current
end of the main chain to signal that there are more blocks to get.

Previously this code was automatically requesting more blocks when the
number of in-flight blocks was under a certain threshold.  The original
approach does help alleviate delays in the "request final, wait for
orphan, request more" round trip, but due to the aforementioned mechanism,
it leads to double requests and other subtle issues.
2013-08-30 13:04:50 -05:00

916 lines
26 KiB
Go

// Copyright (c) 2013 Conformal Systems LLC.
// Use of this source code is governed by an ISC
// license that can be found in the LICENSE file.
package main
import (
"bytes"
"container/list"
"errors"
"fmt"
"github.com/conformal/btcchain"
"github.com/conformal/btcdb"
"github.com/conformal/btcutil"
"github.com/conformal/btcwire"
"github.com/conformal/go-socks"
"github.com/davecgh/go-spew/spew"
"net"
"strconv"
"sync"
"time"
)
const outputBufferSize = 50
// userAgent is the user agent string used to identify ourselves to other
// bitcoin peers.
var userAgent = fmt.Sprintf("/btcd:%d.%d.%d/", appMajor, appMinor, appPatch)
// zeroHash is the zero value hash (all zeros). It is defined as a convenience.
var zeroHash btcwire.ShaHash
// minUint32 is a helper function to return the minimum of two uint32s.
// This avoids a math import and the need to cast to floats.
func minUint32(a, b uint32) uint32 {
if a < b {
return a
}
return b
}
// newNetAddress attempts to extract the IP address and port from the passed
// net.Addr interface and create a bitcoin NetAddress structure using that
// information.
func newNetAddress(addr net.Addr, services btcwire.ServiceFlag) (*btcwire.NetAddress, error) {
// addr will be a net.TCPAddr when not using a proxy.
if tcpAddr, ok := addr.(*net.TCPAddr); ok {
ip := tcpAddr.IP
port := uint16(tcpAddr.Port)
na := btcwire.NewNetAddressIPPort(ip, port, services)
return na, nil
}
// addr will be a socks.ProxiedAddr when using a proxy.
if proxiedAddr, ok := addr.(*socks.ProxiedAddr); ok {
ip := net.ParseIP(proxiedAddr.Host)
if ip == nil {
ip = net.ParseIP("0.0.0.0")
}
port := uint16(proxiedAddr.Port)
na := btcwire.NewNetAddressIPPort(ip, port, services)
return na, nil
}
// For the most part, addr should be one of the two above cases, but
// to be safe, fall back to trying to parse the information from the
// address string as a last resort.
host, portStr, err := net.SplitHostPort(addr.String())
if err != nil {
return nil, err
}
ip := net.ParseIP(host)
port, err := strconv.ParseUint(portStr, 10, 16)
if err != nil {
return nil, err
}
na := btcwire.NewNetAddressIPPort(ip, uint16(port), services)
return na, nil
}
// peer provides a bitcoin peer for handling bitcoin communications.
type peer struct {
server *server
protocolVersion uint32
btcnet btcwire.BitcoinNet
services btcwire.ServiceFlag
started bool
conn net.Conn
timeConnected time.Time
inbound bool
disconnect bool
persistent bool
versionKnown bool
knownAddresses map[string]bool
lastBlock int32
requestQueue *list.List
wg sync.WaitGroup
outputQueue chan btcwire.Message
blockProcessed chan bool
quit chan bool
}
// pushVersionMsg sends a version message to the connected peer using the
// current state.
func (p *peer) pushVersionMsg() error {
_, blockNum, err := p.server.db.NewestSha()
if err != nil {
return err
}
// Create a NetAddress for the local IP. Don't assume any services
// until we know otherwise.
naMe, err := newNetAddress(p.conn.LocalAddr(), 0)
if err != nil {
return err
}
// Create a NetAddress for the remote IP. Don't assume any services
// until we know otherwise.
naYou, err := newNetAddress(p.conn.RemoteAddr(), 0)
if err != nil {
return err
}
// Version message.
msg := btcwire.NewMsgVersion(naMe, naYou, p.server.nonce, userAgent,
int32(blockNum))
// XXX: bitcoind appears to always enable the full node services flag
// of the remote peer netaddress field in the version message regardless
// of whether it knows it supports it or not. Also, bitcoind sets
// the services field of the local peer to 0 regardless of support.
//
// Realistically, this should be set as follows:
// - For outgoing connections:
// - Set the local netaddress services to what the local peer
// actually supports
// - Set the remote netaddress services to 0 to indicate no services
// as they are still unknown
// - For incoming connections:
// - Set the local netaddress services to what the local peer
// actually supports
// - Set the remote netaddress services to the what was advertised by
// by the remote peer in its version message
msg.AddrYou.Services = btcwire.SFNodeNetwork
// Advertise that we're a full node.
msg.Services = btcwire.SFNodeNetwork
p.outputQueue <- msg
return nil
}
// handleVersionMsg is invoked when a peer receives a version bitcoin message
// and is used to negotiate the protocol version details as well as kick start
// the communications.
func (p *peer) handleVersionMsg(msg *btcwire.MsgVersion) {
// Detect self connections.
if msg.Nonce == p.server.nonce {
log.Debugf("[PEER] Disconnecting peer connected to self %s",
p.conn.RemoteAddr())
p.Disconnect()
return
}
// Limit to one version message per peer.
if p.versionKnown {
log.Errorf("[PEER] Only one version message per peer is allowed %s.",
p.conn.RemoteAddr())
p.Disconnect()
return
}
// Negotiate the protocol version.
p.protocolVersion = minUint32(p.protocolVersion, uint32(msg.ProtocolVersion))
p.versionKnown = true
log.Debugf("[PEER] Negotiated protocol version %d for peer %s",
p.protocolVersion, p.conn.RemoteAddr())
p.lastBlock = msg.LastBlock
// Inbound connections.
if p.inbound {
// Set the supported services for the peer to what the remote
// peer advertised.
p.services = msg.Services
// Send version.
err := p.pushVersionMsg()
if err != nil {
log.Errorf("[PEER] %v", err)
p.Disconnect()
return
}
// Add inbound peer address to the server address manager.
na, err := btcwire.NewNetAddress(p.conn.RemoteAddr(), p.services)
if err != nil {
log.Errorf("[PEER] %v", err)
p.Disconnect()
return
}
p.server.addrManager.AddAddress(na)
}
// Send verack.
p.outputQueue <- btcwire.NewMsgVerAck()
// Outbound connections.
if !p.inbound {
// TODO(davec): Only do this if not doing the initial block
// download and the local address is routable.
if !cfg.DisableListen {
// Advertise the local address.
na, err := newNetAddress(p.conn.LocalAddr(), p.services)
if err != nil {
log.Errorf("[PEER] %v", err)
p.Disconnect()
return
}
addresses := map[string]*btcwire.NetAddress{
NetAddressKey(na): na,
}
p.pushAddrMsg(addresses)
}
// Request known addresses if the server address manager needs
// more and the peer has a protocol version new enough to
// include a timestamp with addresses.
hasTimestamp := p.protocolVersion >= btcwire.NetAddressTimeVersion
if p.server.addrManager.NeedMoreAddresses() && hasTimestamp {
p.outputQueue <- btcwire.NewMsgGetAddr()
}
}
// Request latest blocks if the peer has blocks we're interested in.
_, lastBlock, err := p.server.db.NewestSha()
if err != nil {
log.Errorf("[PEER] %v", err)
p.Disconnect()
}
// If the peer has blocks we're interested in.
if p.lastBlock > int32(lastBlock) {
locator, err := p.server.blockManager.blockChain.LatestBlockLocator()
if err != nil {
log.Error("[PEER] Failed to get block locator for the "+
"latest block: %v", err)
p.Disconnect()
}
p.pushGetBlocksMsg(locator, &zeroHash)
}
// TODO: Relay alerts.
}
// pushTxMsg sends a tx message for the provided transaction hash to the
// connected peer. An error is returned if the transaction sha is not known.
func (p *peer) pushTxMsg(sha btcwire.ShaHash) error {
// We dont deal with these for now.
return errors.New("Tx fetching not implemented")
}
// pushBlockMsg sends a block message for the provided block hash to the
// connected peer. An error is returned if the block hash is not known.
func (p *peer) pushBlockMsg(sha btcwire.ShaHash) error {
// What should this function do about the rate limiting the
// number of blocks queued for this peer?
// Current thought is have a counting mutex in the peer
// such that if > N Tx/Block requests are currently in
// the tx queue, wait until the mutex clears allowing more to be
// sent. This prevents 500 1+MB blocks from being loaded into
// memory and sit around until the output queue drains.
// Actually the outputQueue has a limit of 50 in its queue
// but still 50MB to 1.6GB(50 32MB blocks) just setting
// in memory waiting to be sent is pointless.
// I would recommend a getdata request limit of about 5
// outstanding objects.
// Should the tx complete api be a mutex or channel?
blk, err := p.server.db.FetchBlockBySha(&sha)
if err != nil {
log.Tracef("[PEER] Unable to fetch requested block sha %v: %v",
&sha, err)
return err
}
p.QueueMessage(blk.MsgBlock())
return nil
}
// pushGetBlocksMsg send a getblocks message for the provided block locator
// and stop hash.
func (p *peer) pushGetBlocksMsg(locator btcchain.BlockLocator, stopHash *btcwire.ShaHash) error {
msg := btcwire.NewMsgGetBlocks(stopHash)
for _, hash := range locator {
err := msg.AddBlockLocatorHash(hash)
if err != nil {
return err
}
}
p.QueueMessage(msg)
return nil
}
// handleInvMsg is invoked when a peer receives an inv bitcoin message and is
// used to examine the inventory being advertised by the remote peer and react
// accordingly.
//
// NOTE: This will need to have tx handling added as well when they are
// supported.
func (p *peer) handleInvMsg(msg *btcwire.MsgInv) {
// Attempt to find the final block in the inventory list. There may
// not be one.
lastBlock := -1
invVects := msg.InvList
for i := len(invVects) - 1; i >= 0; i-- {
if invVects[i].Type == btcwire.InvVect_Block {
lastBlock = i
break
}
}
// Request the advertised inventory if we don't already have it. Also,
// request parent blocks of orphans if we receive one we already have.
// Finally, attempt to detect potential stalls due to long side chains
// we already have and request more blocks to prevent them.
chain := p.server.blockManager.blockChain
for i, iv := range invVects {
switch iv.Type {
case btcwire.InvVect_Block:
if !chain.HaveInventory(iv) {
// Add it to the request queue.
p.requestQueue.PushBack(iv)
continue
}
// The block is an orphan block that we already have.
// When the existing orphan was processed, it requested
// the missing parent blocks. When this scenario
// happens, it means there were more blocks missing
// than are allowed into a single inventory message. As
// a result, once this peer requested the final
// advertised block, the remote peer noticed and is now
// resending the orphan block as an available block
// to signal there are more missing blocks that need to
// be requested.
if chain.IsKnownOrphan(&iv.Hash) {
// Request blocks starting at the latest known
// up to the root of the orphan that just came
// in.
orphanRoot := chain.GetOrphanRoot(&iv.Hash)
locator, err := chain.LatestBlockLocator()
if err != nil {
log.Error("[PEER] Failed to get block "+
"locator for the latest block: "+
"%v", err)
continue
}
p.pushGetBlocksMsg(locator, orphanRoot)
continue
}
// We already have the final block advertised by this
// inventory message, so force a request for more. This
// should only really happen if we're on a really long
// side chain.
if i == lastBlock {
// Request blocks after this one up to the
// final one the remote peer knows about (zero
// stop hash).
locator := chain.BlockLocatorFromHash(&iv.Hash)
p.pushGetBlocksMsg(locator, &zeroHash)
}
// Ignore unsupported inventory types.
default:
continue
}
}
// Request as much as possible at once. Anything that won't fit into
// the request will be requested on the next inv message.
numRequested := 0
gdmsg := btcwire.NewMsgGetData()
for e := p.requestQueue.Front(); e != nil; e = p.requestQueue.Front() {
iv := e.Value.(*btcwire.InvVect)
gdmsg.AddInvVect(iv)
p.requestQueue.Remove(e)
numRequested++
if numRequested >= btcwire.MaxInvPerMsg {
break
}
}
if len(gdmsg.InvList) > 0 {
p.QueueMessage(gdmsg)
}
}
// handleGetData is invoked when a peer receives a getdata bitcoin message and
// is used to deliver block and transaction information.
func (p *peer) handleGetDataMsg(msg *btcwire.MsgGetData) {
notFound := btcwire.NewMsgNotFound()
out:
for _, iv := range msg.InvList {
var err error
switch iv.Type {
case btcwire.InvVect_Tx:
err = p.pushTxMsg(iv.Hash)
case btcwire.InvVect_Block:
err = p.pushBlockMsg(iv.Hash)
default:
log.Warnf("[PEER] Unknown type in inventory request %d",
iv.Type)
break out
}
if err != nil {
notFound.AddInvVect(iv)
}
}
if len(notFound.InvList) != 0 {
p.QueueMessage(notFound)
}
}
// handleGetBlocksMsg is invoked when a peer receives a getdata bitcoin message.
func (p *peer) handleGetBlocksMsg(msg *btcwire.MsgGetBlocks) {
var err error
startIdx := int64(0)
endIdx := btcdb.AllShas
// Return all block hashes to the latest one (up to max per message) if
// no stop hash was specified.
// Attempt to find the ending index of the stop hash if specified.
if !msg.HashStop.IsEqual(&zeroHash) {
block, err := p.server.db.FetchBlockBySha(&msg.HashStop)
if err != nil {
// Fetch all if we dont recognize the stop hash.
endIdx = btcdb.AllShas
}
endIdx = block.Height()
}
// TODO(davec): This should have some logic to utilize the additional
// locator hashes to ensure the proper chain.
for _, hash := range msg.BlockLocatorHashes {
// TODO(drahn) does using the caching interface make sense
// on index lookups ?
block, err := p.server.db.FetchBlockBySha(hash)
if err == nil {
// Start with the next hash since we know this one.
startIdx = block.Height() + 1
break
}
}
// Don't attempt to fetch more than we can put into a single message.
if endIdx-startIdx > btcwire.MaxBlocksPerMsg {
endIdx = startIdx + btcwire.MaxBlocksPerMsg
}
// Fetch the inventory from the block database.
hashList, err := p.server.db.FetchHeightRange(startIdx, endIdx)
if err != nil {
log.Warnf(" lookup returned %v ", err)
return
}
// Nothing to send.
if len(hashList) == 0 {
return
}
// Generate inventory vectors and push the inventory message.
inv := btcwire.NewMsgInv()
for _, hash := range hashList {
iv := btcwire.InvVect{Type: btcwire.InvVect_Block, Hash: hash}
inv.AddInvVect(&iv)
}
p.QueueMessage(inv)
}
// handleGetBlocksMsg is invoked when a peer receives a getheaders bitcoin
// message.
func (p *peer) handleGetHeadersMsg(msg *btcwire.MsgGetHeaders) {
var err error
startIdx := int64(0)
endIdx := btcdb.AllShas
// Return all block hashes to the latest one (up to max per message) if
// no stop hash was specified.
// Attempt to find the ending index of the stop hash if specified.
if !msg.HashStop.IsEqual(&zeroHash) {
block, err := p.server.db.FetchBlockBySha(&msg.HashStop)
if err != nil {
// Fetch all if we dont recognize the stop hash.
endIdx = btcdb.AllShas
}
endIdx = block.Height()
}
// TODO(davec): This should have some logic to utilize the additional
// locator hashes to ensure the proper chain.
for _, hash := range msg.BlockLocatorHashes {
// TODO(drahn) does using the caching interface make sense
// on index lookups ?
block, err := p.server.db.FetchBlockBySha(hash)
if err == nil {
// Start with the next hash since we know this one.
startIdx = block.Height() + 1
break
}
}
// Don't attempt to fetch more than we can put into a single message.
if endIdx-startIdx > btcwire.MaxBlockHeadersPerMsg {
endIdx = startIdx + btcwire.MaxBlockHeadersPerMsg
}
// Fetch the inventory from the block database.
hashList, err := p.server.db.FetchHeightRange(startIdx, endIdx)
if err != nil {
log.Warnf("lookup returned %v ", err)
return
}
// Nothing to send.
if len(hashList) == 0 {
return
}
// Generate inventory vectors and push the inventory message.
headersMsg := btcwire.NewMsgHeaders()
for _, hash := range hashList {
block, err := p.server.db.FetchBlockBySha(&hash)
if err != nil {
log.Warnf("[PEER] badness %v", err)
}
hdr := block.MsgBlock().Header // copy
hdr.TxnCount = 0
headersMsg.AddBlockHeader(&hdr)
}
p.QueueMessage(headersMsg)
}
// handleGetAddrMsg is invoked when a peer receives a getaddr bitcoin message
// and is used to provide the peer with known addresses from the address
// manager.
func (p *peer) handleGetAddrMsg(msg *btcwire.MsgGetAddr) {
// Get the current known addresses from the address manager.
addrCache := p.server.addrManager.AddressCache()
// Push the addresses.
err := p.pushAddrMsg(addrCache)
if err != nil {
log.Errorf("[PEER] %v", err)
p.Disconnect()
return
}
}
// pushAddrMsg sends one, or more, addr message(s) to the connected peer using
// the provided addresses.
func (p *peer) pushAddrMsg(addresses map[string]*btcwire.NetAddress) error {
// Nothing to send.
if len(addresses) == 0 {
return nil
}
numAdded := 0
msg := btcwire.NewMsgAddr()
for _, na := range addresses {
// Filter addresses the peer already knows about.
if p.knownAddresses[NetAddressKey(na)] {
continue
}
// Add the address to the message.
err := msg.AddAddress(na)
if err != nil {
return err
}
numAdded++
// Split into multiple messages as needed.
if numAdded > 0 && numAdded%btcwire.MaxAddrPerMsg == 0 {
p.outputQueue <- msg
msg.ClearAddresses()
}
}
// Send message with remaining addresses if needed.
if numAdded%btcwire.MaxAddrPerMsg != 0 {
p.outputQueue <- msg
}
return nil
}
// handleAddrMsg is invoked when a peer receives an addr bitcoin message and
// is used to notify the server about advertised addresses.
func (p *peer) handleAddrMsg(msg *btcwire.MsgAddr) {
// Ignore old style addresses which don't include a timestamp.
if p.protocolVersion < btcwire.NetAddressTimeVersion {
return
}
// A message that has no addresses is invalid.
if len(msg.AddrList) == 0 {
log.Errorf("[PEER] Command [%s] from %s does not contain any addresses",
msg.Command(), p.conn.RemoteAddr())
p.Disconnect()
return
}
for _, na := range msg.AddrList {
// Don't add more address if we're disconnecting.
if p.disconnect {
return
}
// Set the timestamp to 5 days ago if it's more than 24 hours
// in the future so this address is one of the first to be
// removed when space is needed.
now := time.Now()
if na.Timestamp.After(now.Add(time.Minute * 10)) {
na.Timestamp = now.Add(-1 * time.Hour * 24 * 5)
}
// Add address to known addresses for this peer.
p.knownAddresses[NetAddressKey(na)] = true
}
// Add addresses to server address manager. The address manager handles
// the details of things such as preventing duplicate addresses, max
// addresses, and last seen updates.
p.server.addrManager.AddAddresses(msg.AddrList)
}
// handlePingMsg is invoked when a peer receives a ping bitcoin message. For
// recent clients (protocol version > BIP0031Version), it replies with a pong
// message. For older clients, it does nothing and anything other than failure
// is considered a successful ping.
func (p *peer) handlePingMsg(msg *btcwire.MsgPing) {
// Only Reply with pong is message comes from a new enough client.
if p.protocolVersion > btcwire.BIP0031Version {
// Include nonce from ping so pong can be identified.
p.outputQueue <- btcwire.NewMsgPong(msg.Nonce)
}
}
// readMessage reads the next bitcoin message from the peer with logging.
func (p *peer) readMessage() (msg btcwire.Message, buf []byte, err error) {
msg, buf, err = btcwire.ReadMessage(p.conn, p.protocolVersion, p.btcnet)
if err != nil {
return
}
log.Debugf("[PEER] Received command [%v] from %s", msg.Command(),
p.conn.RemoteAddr())
// Use closures to log expensive operations so they are only run when
// the logging level requires it.
log.Tracef("%v", newLogClosure(func() string {
return "[PEER] " + spew.Sdump(msg)
}))
log.Tracef("%v", newLogClosure(func() string {
return "[PEER] " + spew.Sdump(buf)
}))
return
}
// writeMessage sends a bitcoin Message to the peer with logging.
func (p *peer) writeMessage(msg btcwire.Message) error {
log.Debugf("[PEER] Sending command [%v] to %s", msg.Command(),
p.conn.RemoteAddr())
// Use closures to log expensive operations so they are only run when the
// logging level requires it.
log.Tracef("%v", newLogClosure(func() string {
return "[PEER] msg" + spew.Sdump(msg)
}))
log.Tracef("%v", newLogClosure(func() string {
var buf bytes.Buffer
err := btcwire.WriteMessage(&buf, msg, p.protocolVersion, p.btcnet)
if err != nil {
return err.Error()
}
return "[PEER] " + spew.Sdump(buf.Bytes())
}))
// Write the message to the peer.
err := btcwire.WriteMessage(p.conn, msg, p.protocolVersion, p.btcnet)
if err != nil {
return err
}
return nil
}
// isAllowedByRegression returns whether or not the passed error is allowed by
// regression tests without disconnecting the peer. In particular, regression
// tests need to be allowed to send malformed messages without the peer being
// disconnected.
func (p *peer) isAllowedByRegression(err error) bool {
// Don't allow the error if it's not specifically a malformed message
// error.
if _, ok := err.(*btcwire.MessageError); !ok {
return false
}
// Don't allow the error if it's not coming from localhost or the
// hostname can't be determined for some reason.
host, _, err := net.SplitHostPort(p.conn.RemoteAddr().String())
if err != nil {
return false
}
if host != "127.0.0.1" && host != "localhost" {
return false
}
// Allowed if all checks passed.
return true
}
// inHandler handles all incoming messages for the peer. It must be run as a
// goroutine.
func (p *peer) inHandler() {
out:
for !p.disconnect {
rmsg, buf, err := p.readMessage()
if err != nil {
// In order to allow regression tests with malformed
// messages, don't disconnect the peer when we're in
// regression test mode and the error is one of the
// allowed errors.
if cfg.RegressionTest && p.isAllowedByRegression(err) {
log.Errorf("[PEER] %v", err)
continue
}
// Only log the error if we're not forcibly disconnecting.
if !p.disconnect {
log.Errorf("[PEER] %v", err)
}
break out
}
// Ensure version message comes first.
if _, ok := rmsg.(*btcwire.MsgVersion); !ok && !p.versionKnown {
log.Errorf("[PEER] A version message must precede all others")
break out
}
// Handle each supported message type.
switch msg := rmsg.(type) {
case *btcwire.MsgVersion:
p.handleVersionMsg(msg)
case *btcwire.MsgVerAck:
// Do nothing.
case *btcwire.MsgGetAddr:
p.handleGetAddrMsg(msg)
case *btcwire.MsgAddr:
p.handleAddrMsg(msg)
case *btcwire.MsgPing:
p.handlePingMsg(msg)
case *btcwire.MsgPong:
// Don't do anything, but could try to work out network
// timing or similar.
case *btcwire.MsgAlert:
p.server.BroadcastMessage(msg, p)
case *btcwire.MsgBlock:
// Queue the block up to be handled by the block
// manager and intentionally block further receives
// until the bitcoin block is fully processed and known
// good or bad. This helps prevent a malicious peer
// from queueing up a bunch of bad blocks before
// disconnecting (or being disconnected) and wasting
// memory. Additionally, this behavior is depended on
// by at least the block acceptance test tool as the
// reference implementation processes blocks in the same
// thread and therefore blocks further messages until
// the bitcoin block has been fully processed.
block := btcutil.NewBlockFromBlockAndBytes(msg, buf)
p.server.blockManager.QueueBlock(block, p)
<-p.blockProcessed
case *btcwire.MsgInv:
p.handleInvMsg(msg)
case *btcwire.MsgGetData:
p.handleGetDataMsg(msg)
case *btcwire.MsgGetBlocks:
p.handleGetBlocksMsg(msg)
case *btcwire.MsgGetHeaders:
p.handleGetHeadersMsg(msg)
default:
log.Debugf("[PEER] Received unhandled message of type %v: Fix Me",
rmsg.Command())
}
}
// Ensure connection is closed and notify server that the peer is done.
p.Disconnect()
p.server.donePeers <- p
p.quit <- true
p.wg.Done()
log.Tracef("[PEER] Peer input handler done for %s", p.conn.RemoteAddr())
}
// outHandler handles all outgoing messages for the peer. It must be run as a
// goroutine. It uses a buffered channel to serialize output messages while
// allowing the sender to continue running asynchronously.
func (p *peer) outHandler() {
out:
for {
select {
case msg := <-p.outputQueue:
// Don't send anything if we're disconnected.
if p.disconnect {
continue
}
err := p.writeMessage(msg)
if err != nil {
p.Disconnect()
log.Errorf("[PEER] %v", err)
}
case <-p.quit:
break out
}
}
p.wg.Done()
log.Tracef("[PEER] Peer output handler done for %s", p.conn.RemoteAddr())
}
// QueueMessage adds the passed bitcoin message to the peer send queue. It
// uses a buffered channel to communicate with the output handler goroutine so
// it is automatically rate limited and safe for concurrent access.
func (p *peer) QueueMessage(msg btcwire.Message) {
p.outputQueue <- msg
}
// Start begins processing input and output messages. It also sends the initial
// version message for outbound connections to start the negotiation process.
func (p *peer) Start() error {
// Already started?
if p.started {
return nil
}
log.Tracef("[PEER] Starting peer %s", p.conn.RemoteAddr())
// Send an initial version message if this is an outbound connection.
if !p.inbound {
err := p.pushVersionMsg()
if err != nil {
log.Errorf("[PEER] %v", err)
p.conn.Close()
return err
}
}
// Start processing input and output.
go p.inHandler()
go p.outHandler()
p.wg.Add(2)
p.started = true
return nil
}
// Disconnect disconnects the peer by closing the connection. It also sets
// a flag so the impending shutdown can be detected.
func (p *peer) Disconnect() {
p.disconnect = true
p.conn.Close()
}
// Shutdown gracefully shuts down the peer by disconnecting it and waiting for
// all goroutines to finish.
func (p *peer) Shutdown() {
log.Tracef("[PEER] Shutdown peer %s", p.conn.RemoteAddr())
p.Disconnect()
p.wg.Wait()
}
// newPeer returns a new bitcoin peer for the provided server and connection.
// Use start to begin processing incoming and outgoing messages.
func newPeer(s *server, conn net.Conn, inbound bool, persistent bool) *peer {
p := peer{
server: s,
protocolVersion: btcwire.ProtocolVersion,
btcnet: s.btcnet,
services: btcwire.SFNodeNetwork,
conn: conn,
timeConnected: time.Now(),
inbound: inbound,
persistent: persistent,
knownAddresses: make(map[string]bool),
requestQueue: list.New(),
outputQueue: make(chan btcwire.Message, outputBufferSize),
blockProcessed: make(chan bool, 1),
quit: make(chan bool),
}
return &p
}