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|
// Copyright 2018 The dexon-consensus Authors
// This file is part of the dexon-consensus library.
//
// The dexon-consensus library is free software: you can redistribute it
// and/or modify it under the terms of the GNU Lesser General Public License as
// published by the Free Software Foundation, either version 3 of the License,
// or (at your option) any later version.
//
// The dexon-consensus library is distributed in the hope that it will be
// useful, but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser
// General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with the dexon-consensus library. If not, see
// <http://www.gnu.org/licenses/>.
// Copyright 2015 The go-ethereum Authors
// This file is part of the go-ethereum library.
//
// The go-ethereum library is free software: you can redistribute it and/or modify
// it under the terms of the GNU Lesser General Public License as published by
// the Free Software Foundation, either version 3 of the License, or
// (at your option) any later version.
//
// The go-ethereum library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public License
// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
package dex
import (
"encoding/hex"
"errors"
"fmt"
"sync"
"time"
mapset "github.com/deckarep/golang-set"
coreCommon "github.com/dexon-foundation/dexon-consensus/common"
coreTypes "github.com/dexon-foundation/dexon-consensus/core/types"
dkgTypes "github.com/dexon-foundation/dexon-consensus/core/types/dkg"
"github.com/dexon-foundation/dexon/common"
"github.com/dexon-foundation/dexon/core/types"
"github.com/dexon-foundation/dexon/crypto"
"github.com/dexon-foundation/dexon/log"
"github.com/dexon-foundation/dexon/p2p"
"github.com/dexon-foundation/dexon/p2p/enode"
"github.com/dexon-foundation/dexon/p2p/enr"
"github.com/dexon-foundation/dexon/rlp"
)
var (
errClosed = errors.New("peer set is closed")
errAlreadyRegistered = errors.New("peer is already registered")
errNotRegistered = errors.New("peer is not registered")
)
const (
maxKnownTxs = 32768 // Maximum transactions hashes to keep in the known list (prevent DOS)
maxKnownRecords = 32768 // Maximum records hashes to keep in the known list (prevent DOS)
maxKnownBlocks = 1024 // Maximum block hashes to keep in the known list (prevent DOS)
maxKnownAgreements = 10240
maxKnownDKGPrivateShares = 1024 // this related to DKG Size
// maxQueuedTxs is the maximum number of transaction lists to queue up before
// dropping broadcasts. This is a sensitive number as a transaction list might
// contain a single transaction, or thousands.
maxQueuedTxs = 1024
maxQueuedRecords = 512
// maxQueuedProps is the maximum number of block propagations to queue up before
// dropping broadcasts. There's not much point in queueing stale blocks, so a few
// that might cover uncles should be enough.
maxQueuedProps = 4
// maxQueuedAnns is the maximum number of block announcements to queue up before
// dropping broadcasts. Similarly to block propagations, there's no point to queue
// above some healthy uncle limit, so use that.
maxQueuedAnns = 4
maxQueuedCoreBlocks = 16
maxQueuedVotes = 128
maxQueuedAgreements = 16
maxQueuedDKGPrivateShare = 16
maxQueuedDKGParitialSignature = 16
maxQueuedPullBlocks = 128
maxQueuedPullVotes = 128
maxQueuedPullRandomness = 128
handshakeTimeout = 5 * time.Second
groupConnNum = 3
groupConnTimeout = 3 * time.Minute
)
// PeerInfo represents a short summary of the Ethereum sub-protocol metadata known
// about a connected peer.
type PeerInfo struct {
Version int `json:"version"` // Ethereum protocol version negotiated
Number uint64 `json:"number"` // Number the peer's blockchain
Head string `json:"head"` // SHA3 hash of the peer's best owned block
}
type setType uint32
const (
notaryset = iota
)
type peerLabel struct {
set setType
round uint64
}
func (p peerLabel) String() string {
var t string
switch p.set {
case notaryset:
t = fmt.Sprintf("NotarySet round: %d", p.round)
}
return t
}
type peer struct {
id string
*p2p.Peer
rw p2p.MsgReadWriter
version int // Protocol version negotiated
head common.Hash
number uint64
lock sync.RWMutex
knownTxs mapset.Set // Set of transaction hashes known to be known by this peer
knownRecords mapset.Set // Set of node record known to be known by this peer
knownBlocks mapset.Set // Set of block hashes known to be known by this peer
knownAgreements mapset.Set
knownDKGPrivateShares mapset.Set
queuedTxs chan []*types.Transaction // Queue of transactions to broadcast to the peer
queuedRecords chan []*enr.Record // Queue of node records to broadcast to the peer
queuedProps chan *types.Block // Queue of blocks to broadcast to the peer
queuedAnns chan *types.Block // Queue of blocks to announce to the peer
queuedCoreBlocks chan []*coreTypes.Block
queuedVotes chan []*coreTypes.Vote
queuedAgreements chan *coreTypes.AgreementResult
queuedDKGPrivateShares chan *dkgTypes.PrivateShare
queuedDKGPartialSignatures chan *dkgTypes.PartialSignature
queuedPullBlocks chan coreCommon.Hashes
queuedPullVotes chan coreTypes.Position
queuedPullRandomness chan coreCommon.Hashes
term chan struct{} // Termination channel to stop the broadcaster
}
func newPeer(version int, p *p2p.Peer, rw p2p.MsgReadWriter) *peer {
return &peer{
Peer: p,
rw: rw,
version: version,
id: p.ID().String(),
knownTxs: mapset.NewSet(),
knownRecords: mapset.NewSet(),
knownBlocks: mapset.NewSet(),
knownAgreements: mapset.NewSet(),
knownDKGPrivateShares: mapset.NewSet(),
queuedTxs: make(chan []*types.Transaction, maxQueuedTxs),
queuedRecords: make(chan []*enr.Record, maxQueuedRecords),
queuedProps: make(chan *types.Block, maxQueuedProps),
queuedAnns: make(chan *types.Block, maxQueuedAnns),
queuedCoreBlocks: make(chan []*coreTypes.Block, maxQueuedCoreBlocks),
queuedVotes: make(chan []*coreTypes.Vote, maxQueuedVotes),
queuedAgreements: make(chan *coreTypes.AgreementResult, maxQueuedAgreements),
queuedDKGPrivateShares: make(chan *dkgTypes.PrivateShare, maxQueuedDKGPrivateShare),
queuedDKGPartialSignatures: make(chan *dkgTypes.PartialSignature, maxQueuedDKGParitialSignature),
queuedPullBlocks: make(chan coreCommon.Hashes, maxQueuedPullBlocks),
queuedPullVotes: make(chan coreTypes.Position, maxQueuedPullVotes),
queuedPullRandomness: make(chan coreCommon.Hashes, maxQueuedPullRandomness),
term: make(chan struct{}),
}
}
// broadcast is a write loop that multiplexes block propagations, announcements,
// transaction and notary node records broadcasts into the remote peer.
// The goal is to have an async writer that does not lock up node internals.
func (p *peer) broadcast() {
queuedVotes := make([]*coreTypes.Vote, 0, maxQueuedVotes)
for {
PriorityBroadcastVote:
for {
select {
case votes := <-p.queuedVotes:
queuedVotes = append(queuedVotes, votes...)
default:
break PriorityBroadcastVote
}
}
if len(queuedVotes) != 0 {
if err := p.SendVotes(queuedVotes); err != nil {
return
}
p.Log().Trace("Broadcast votes", "count", len(queuedVotes))
queuedVotes = queuedVotes[:0]
}
select {
case records := <-p.queuedRecords:
if err := p.SendNodeRecords(records); err != nil {
return
}
p.Log().Trace("Broadcast node records", "count", len(records))
case block := <-p.queuedProps:
if err := p.SendNewBlock(block); err != nil {
return
}
p.Log().Trace("Propagated block", "number", block.Number(), "hash", block.Hash())
case block := <-p.queuedAnns:
if err := p.SendNewBlockHashes([]common.Hash{block.Hash()}, []uint64{block.NumberU64()}); err != nil {
return
}
p.Log().Trace("Announced block", "number", block.Number(), "hash", block.Hash())
case blocks := <-p.queuedCoreBlocks:
if err := p.SendCoreBlocks(blocks); err != nil {
return
}
p.Log().Trace("Broadcast core blocks", "count", len(blocks))
case votes := <-p.queuedVotes:
if err := p.SendVotes(votes); err != nil {
return
}
p.Log().Trace("Broadcast votes", "count", len(votes))
case agreement := <-p.queuedAgreements:
if err := p.SendAgreement(agreement); err != nil {
return
}
p.Log().Trace("Broadcast agreement")
case privateShare := <-p.queuedDKGPrivateShares:
if err := p.SendDKGPrivateShare(privateShare); err != nil {
return
}
p.Log().Trace("Broadcast DKG private share")
case psig := <-p.queuedDKGPartialSignatures:
if err := p.SendDKGPartialSignature(psig); err != nil {
return
}
p.Log().Trace("Broadcast DKG partial signature")
case hashes := <-p.queuedPullBlocks:
if err := p.SendPullBlocks(hashes); err != nil {
return
}
p.Log().Trace("Pulling Blocks", "hashes", hashes)
case pos := <-p.queuedPullVotes:
if err := p.SendPullVotes(pos); err != nil {
return
}
p.Log().Trace("Pulling Votes", "position", pos)
case <-p.term:
return
case <-time.After(100 * time.Millisecond):
}
select {
case txs := <-p.queuedTxs:
if err := p.SendTransactions(txs); err != nil {
return
}
p.Log().Trace("Broadcast transactions", "count", len(txs))
default:
}
}
}
// close signals the broadcast goroutine to terminate.
func (p *peer) close() {
close(p.term)
}
// Info gathers and returns a collection of metadata known about a peer.
func (p *peer) Info() *PeerInfo {
hash, number := p.Head()
return &PeerInfo{
Version: p.version,
Number: number,
Head: hash.Hex(),
}
}
// Head retrieves a copy of the current head hash and number of the
// peer.
func (p *peer) Head() (hash common.Hash, number uint64) {
p.lock.RLock()
defer p.lock.RUnlock()
copy(hash[:], p.head[:])
return hash, p.number
}
// SetHead updates the head hash and number of the peer.
func (p *peer) SetHead(hash common.Hash, number uint64) {
p.lock.Lock()
defer p.lock.Unlock()
copy(p.head[:], hash[:])
p.number = number
}
// MarkBlock marks a block as known for the peer, ensuring that the block will
// never be propagated to this particular peer.
func (p *peer) MarkBlock(hash common.Hash) {
// If we reached the memory allowance, drop a previously known block hash
for p.knownBlocks.Cardinality() >= maxKnownBlocks {
p.knownBlocks.Pop()
}
p.knownBlocks.Add(hash)
}
// MarkTransaction marks a transaction as known for the peer, ensuring that it
// will never be propagated to this particular peer.
func (p *peer) MarkTransaction(hash common.Hash) {
// If we reached the memory allowance, drop a previously known transaction hash
for p.knownTxs.Cardinality() >= maxKnownTxs {
p.knownTxs.Pop()
}
p.knownTxs.Add(hash)
}
func (p *peer) MarkNodeRecord(hash common.Hash) {
for p.knownRecords.Cardinality() >= maxKnownRecords {
p.knownRecords.Pop()
}
p.knownRecords.Add(hash)
}
func (p *peer) MarkAgreement(hash common.Hash) {
for p.knownAgreements.Cardinality() >= maxKnownAgreements {
p.knownAgreements.Pop()
}
p.knownAgreements.Add(hash)
}
func (p *peer) MarkDKGPrivateShares(hash common.Hash) {
for p.knownDKGPrivateShares.Cardinality() >= maxKnownDKGPrivateShares {
p.knownDKGPrivateShares.Pop()
}
p.knownDKGPrivateShares.Add(hash)
}
func (p *peer) logSend(err error, code uint64) error {
if err != nil {
p.Log().Error("Failed to send peer message", "code", code, "err", err)
}
return err
}
// SendTransactions sends transactions to the peer and includes the hashes
// in its transaction hash set for future reference.
func (p *peer) SendTransactions(txs types.Transactions) error {
for _, tx := range txs {
p.knownTxs.Add(tx.Hash())
}
return p.logSend(p2p.Send(p.rw, TxMsg, txs), TxMsg)
}
// AsyncSendTransactions queues list of transactions propagation to a remote
// peer. If the peer's broadcast queue is full, the event is silently dropped.
func (p *peer) AsyncSendTransactions(txs []*types.Transaction) {
select {
case p.queuedTxs <- txs:
for _, tx := range txs {
p.knownTxs.Add(tx.Hash())
}
default:
p.Log().Debug("Dropping transaction propagation", "count", len(txs))
}
}
// SendNodeRecords sends the records to the peer and includes the hashes
// in its records hash set for future reference.
func (p *peer) SendNodeRecords(records []*enr.Record) error {
for _, record := range records {
p.knownRecords.Add(rlpHash(record))
}
return p.logSend(p2p.Send(p.rw, RecordMsg, records), RecordMsg)
}
// AsyncSendNodeRecord queues list of notary node records propagation to a
// remote peer. If the peer's broadcast queue is full, the event is silently
// dropped.
func (p *peer) AsyncSendNodeRecords(records []*enr.Record) {
select {
case p.queuedRecords <- records:
for _, record := range records {
p.knownRecords.Add(rlpHash(record))
}
default:
p.Log().Debug("Dropping node record propagation", "count", len(records))
}
}
// SendNewBlockHashes announces the availability of a number of blocks through
// a hash notification.
func (p *peer) SendNewBlockHashes(hashes []common.Hash, numbers []uint64) error {
for _, hash := range hashes {
p.knownBlocks.Add(hash)
}
request := make(newBlockHashesData, len(hashes))
for i := 0; i < len(hashes); i++ {
request[i].Hash = hashes[i]
request[i].Number = numbers[i]
}
return p.logSend(p2p.Send(p.rw, NewBlockHashesMsg, request), NewBlockHashesMsg)
}
// AsyncSendNewBlockHash queues the availability of a block for propagation to a
// remote peer. If the peer's broadcast queue is full, the event is silently
// dropped.
func (p *peer) AsyncSendNewBlockHash(block *types.Block) {
select {
case p.queuedAnns <- block:
p.knownBlocks.Add(block.Hash())
default:
p.Log().Debug("Dropping block announcement", "number", block.NumberU64(), "hash", block.Hash())
}
}
// SendNewBlock propagates an entire block to a remote peer.
func (p *peer) SendNewBlock(block *types.Block) error {
p.knownBlocks.Add(block.Hash())
return p.logSend(p2p.Send(p.rw, NewBlockMsg, block), NewBlockMsg)
}
// AsyncSendNewBlock queues an entire block for propagation to a remote peer. If
// the peer's broadcast queue is full, the event is silently dropped.
func (p *peer) AsyncSendNewBlock(block *types.Block) {
select {
case p.queuedProps <- block:
p.knownBlocks.Add(block.Hash())
default:
p.Log().Debug("Dropping block propagation", "number", block.NumberU64(), "hash", block.Hash())
}
}
func (p *peer) SendCoreBlocks(blocks []*coreTypes.Block) error {
return p.logSend(p2p.Send(p.rw, CoreBlockMsg, blocks), CoreBlockMsg)
}
func (p *peer) AsyncSendCoreBlocks(blocks []*coreTypes.Block) {
select {
case p.queuedCoreBlocks <- blocks:
default:
p.Log().Debug("Dropping core block propagation")
}
}
func (p *peer) SendVotes(votes []*coreTypes.Vote) error {
return p.logSend(p2p.Send(p.rw, VoteMsg, votes), VoteMsg)
}
func (p *peer) AsyncSendVotes(votes []*coreTypes.Vote) {
select {
case p.queuedVotes <- votes:
default:
p.Log().Debug("Dropping vote propagation")
}
}
func (p *peer) SendAgreement(agreement *coreTypes.AgreementResult) error {
p.knownAgreements.Add(rlpHash(agreement))
return p.logSend(p2p.Send(p.rw, AgreementMsg, agreement), AgreementMsg)
}
func (p *peer) AsyncSendAgreement(agreement *coreTypes.AgreementResult) {
select {
case p.queuedAgreements <- agreement:
p.knownAgreements.Add(rlpHash(agreement))
default:
p.Log().Debug("Dropping agreement result")
}
}
func (p *peer) SendDKGPrivateShare(privateShare *dkgTypes.PrivateShare) error {
p.knownDKGPrivateShares.Add(rlpHash(privateShare))
return p.logSend(p2p.Send(p.rw, DKGPrivateShareMsg, privateShare), DKGPrivateShareMsg)
}
func (p *peer) AsyncSendDKGPrivateShare(privateShare *dkgTypes.PrivateShare) {
select {
case p.queuedDKGPrivateShares <- privateShare:
p.knownDKGPrivateShares.Add(rlpHash(privateShare))
default:
p.Log().Debug("Dropping DKG private share")
}
}
func (p *peer) SendDKGPartialSignature(psig *dkgTypes.PartialSignature) error {
return p.logSend(p2p.Send(p.rw, DKGPartialSignatureMsg, psig), DKGPartialSignatureMsg)
}
func (p *peer) AsyncSendDKGPartialSignature(psig *dkgTypes.PartialSignature) {
select {
case p.queuedDKGPartialSignatures <- psig:
default:
p.Log().Debug("Dropping DKG partial signature")
}
}
func (p *peer) SendPullBlocks(hashes coreCommon.Hashes) error {
return p.logSend(p2p.Send(p.rw, PullBlocksMsg, hashes), PullBlocksMsg)
}
func (p *peer) AsyncSendPullBlocks(hashes coreCommon.Hashes) {
select {
case p.queuedPullBlocks <- hashes:
default:
p.Log().Debug("Dropping Pull Blocks")
}
}
func (p *peer) SendPullVotes(pos coreTypes.Position) error {
return p.logSend(p2p.Send(p.rw, PullVotesMsg, pos), PullVotesMsg)
}
func (p *peer) AsyncSendPullVotes(pos coreTypes.Position) {
select {
case p.queuedPullVotes <- pos:
default:
p.Log().Debug("Dropping Pull Votes")
}
}
// SendBlockHeaders sends a batch of block headers to the remote peer.
func (p *peer) SendBlockHeaders(flag uint8, headers []*types.HeaderWithGovState) error {
return p.logSend(p2p.Send(p.rw, BlockHeadersMsg, headersData{Flag: flag, Headers: headers}), BlockHeadersMsg)
}
// SendBlockBodiesRLP sends a batch of block contents to the remote peer from
// an already RLP encoded format.
func (p *peer) SendBlockBodiesRLP(flag uint8, bodies []rlp.RawValue) error {
return p.logSend(p2p.Send(p.rw, BlockBodiesMsg, blockBodiesDataRLP{Flag: flag, Bodies: bodies}), BlockBodiesMsg)
}
// SendNodeDataRLP sends a batch of arbitrary internal data, corresponding to the
// hashes requested.
func (p *peer) SendNodeData(data [][]byte) error {
return p.logSend(p2p.Send(p.rw, NodeDataMsg, data), NodeDataMsg)
}
// SendReceiptsRLP sends a batch of transaction receipts, corresponding to the
// ones requested from an already RLP encoded format.
func (p *peer) SendReceiptsRLP(receipts []rlp.RawValue) error {
return p.logSend(p2p.Send(p.rw, ReceiptsMsg, receipts), ReceiptsMsg)
}
func (p *peer) SendGovState(govState *types.GovState) error {
return p.logSend(p2p.Send(p.rw, GovStateMsg, govState), GovStateMsg)
}
// RequestOneHeader is a wrapper around the header query functions to fetch a
// single header. It is used solely by the fetcher.
func (p *peer) RequestOneHeader(hash common.Hash) error {
p.Log().Debug("Fetching single header", "hash", hash)
return p2p.Send(p.rw, GetBlockHeadersMsg, &getBlockHeadersData{Origin: hashOrNumber{Hash: hash}, Amount: uint64(1), Skip: uint64(0), Reverse: false, WithGov: false, Flag: fetcherReq})
}
// RequestHeadersByHash fetches a batch of blocks' headers corresponding to the
// specified header query, based on the hash of an origin block.
func (p *peer) RequestHeadersByHash(origin common.Hash, amount int, skip int, reverse, withGov bool) error {
p.Log().Debug("Fetching batch of headers", "count", amount, "fromhash", origin, "skip", skip, "reverse", reverse, "withgov", withGov, "flag", downloaderReq)
return p2p.Send(p.rw, GetBlockHeadersMsg, &getBlockHeadersData{Origin: hashOrNumber{Hash: origin}, Amount: uint64(amount), Skip: uint64(skip), Reverse: reverse, WithGov: withGov, Flag: downloaderReq})
}
// RequestHeadersByNumber fetches a batch of blocks' headers corresponding to the
// specified header query, based on the number of an origin block.
func (p *peer) RequestHeadersByNumber(origin uint64, amount int, skip int, reverse, withGov bool) error {
p.Log().Debug("Fetching batch of headers", "count", amount, "fromnum", origin, "skip", skip, "reverse", reverse, "withgov", withGov, "flag", downloaderReq)
return p2p.Send(p.rw, GetBlockHeadersMsg, &getBlockHeadersData{Origin: hashOrNumber{Number: origin}, Amount: uint64(amount), Skip: uint64(skip), Reverse: reverse, WithGov: withGov, Flag: downloaderReq})
}
func (p *peer) RequestWhitelistHeader(origin uint64) error {
p.Log().Debug("Fetching whitelist header", "number", origin, "flag", whitelistReq)
return p2p.Send(p.rw, GetBlockHeadersMsg, &getBlockHeadersData{Origin: hashOrNumber{Number: origin}, Amount: 1, Skip: 0, Reverse: false, WithGov: false, Flag: whitelistReq})
}
func (p *peer) RequestGovStateByHash(hash common.Hash) error {
p.Log().Debug("Fetching one gov state", "hash", hash)
return p2p.Send(p.rw, GetGovStateMsg, hash)
}
// RequestBodies fetches a batch of blocks' bodies corresponding to the hashes
// specified.
func (p *peer) RequestBodies(flag uint8, hashes []common.Hash) error {
p.Log().Debug("Fetching batch of block bodies", "count", len(hashes), "flag", flag)
return p2p.Send(p.rw, GetBlockBodiesMsg, []interface{}{flag, hashes})
}
func (p *peer) FetchBodies(hashes []common.Hash) error {
return p.RequestBodies(fetcherReq, hashes)
}
func (p *peer) DownloadBodies(hashes []common.Hash) error {
return p.RequestBodies(downloaderReq, hashes)
}
// RequestNodeData fetches a batch of arbitrary data from a node's known state
// data, corresponding to the specified hashes.
func (p *peer) RequestNodeData(hashes []common.Hash) error {
p.Log().Debug("Fetching batch of state data", "count", len(hashes))
return p2p.Send(p.rw, GetNodeDataMsg, hashes)
}
// RequestReceipts fetches a batch of transaction receipts from a remote node.
func (p *peer) RequestReceipts(hashes []common.Hash) error {
p.Log().Debug("Fetching batch of receipts", "count", len(hashes))
return p2p.Send(p.rw, GetReceiptsMsg, hashes)
}
// Handshake executes the eth protocol handshake, negotiating version number,
// network IDs, difficulties, head and genesis blocks.
func (p *peer) Handshake(network uint64, number uint64, head common.Hash, genesis common.Hash) error {
// Send out own handshake in a new thread
errc := make(chan error, 2)
var status statusData // safe to read after two values have been received from errc
go func() {
errc <- p2p.Send(p.rw, StatusMsg, &statusData{
ProtocolVersion: uint32(p.version),
NetworkId: network,
Number: number,
CurrentBlock: head,
GenesisBlock: genesis,
})
}()
go func() {
errc <- p.readStatus(network, &status, genesis)
}()
timeout := time.NewTimer(handshakeTimeout)
defer timeout.Stop()
for i := 0; i < 2; i++ {
select {
case err := <-errc:
if err != nil {
return err
}
case <-timeout.C:
return p2p.DiscReadTimeout
}
}
p.number, p.head = status.Number, status.CurrentBlock
return nil
}
func (p *peer) readStatus(network uint64, status *statusData, genesis common.Hash) (err error) {
msg, err := p.rw.ReadMsg()
if err != nil {
return err
}
if msg.Code != StatusMsg {
return errResp(ErrNoStatusMsg, "first msg has code %x (!= %x)", msg.Code, StatusMsg)
}
if msg.Size > ProtocolMaxMsgSize {
return errResp(ErrMsgTooLarge, "%v > %v", msg.Size, ProtocolMaxMsgSize)
}
// Decode the handshake and make sure everything matches
if err := msg.Decode(&status); err != nil {
return errResp(ErrDecode, "msg %v: %v", msg, err)
}
if status.GenesisBlock != genesis {
return errResp(ErrGenesisBlockMismatch, "%x (!= %x)", status.GenesisBlock[:8], genesis[:8])
}
if status.NetworkId != network {
return errResp(ErrNetworkIdMismatch, "%d (!= %d)", status.NetworkId, network)
}
if int(status.ProtocolVersion) != p.version {
return errResp(ErrProtocolVersionMismatch, "%d (!= %d)", status.ProtocolVersion, p.version)
}
return nil
}
// String implements fmt.Stringer.
func (p *peer) String() string {
return fmt.Sprintf("Peer %s [%s]", p.id,
fmt.Sprintf("dex/%2d", p.version),
)
}
// peerSet represents the collection of active peers currently participating in
// the Ethereum sub-protocol.
type peerSet struct {
peers map[string]*peer
lock sync.RWMutex
closed bool
tab *nodeTable
selfPK string
srvr p2pServer
gov governance
label2Nodes map[peerLabel]map[string]*enode.Node
directConn map[peerLabel]struct{}
groupConnPeers map[peerLabel]map[string]time.Time
allDirectPeers map[string]map[peerLabel]struct{}
}
// newPeerSet creates a new peer set to track the active participants.
func newPeerSet(gov governance, srvr p2pServer, tab *nodeTable) *peerSet {
return &peerSet{
peers: make(map[string]*peer),
gov: gov,
srvr: srvr,
tab: tab,
selfPK: hex.EncodeToString(crypto.FromECDSAPub(&srvr.GetPrivateKey().PublicKey)),
label2Nodes: make(map[peerLabel]map[string]*enode.Node),
directConn: make(map[peerLabel]struct{}),
groupConnPeers: make(map[peerLabel]map[string]time.Time),
allDirectPeers: make(map[string]map[peerLabel]struct{}),
}
}
// Register injects a new peer into the working set, or returns an error if the
// peer is already known. If a new peer it registered, its broadcast loop is also
// started.
func (ps *peerSet) Register(p *peer) error {
ps.lock.Lock()
defer ps.lock.Unlock()
if ps.closed {
return errClosed
}
if _, ok := ps.peers[p.id]; ok {
return errAlreadyRegistered
}
ps.peers[p.id] = p
go p.broadcast()
return nil
}
// Unregister removes a remote peer from the active set, disabling any further
// actions to/from that particular entity.
func (ps *peerSet) Unregister(id string) error {
ps.lock.Lock()
defer ps.lock.Unlock()
p, ok := ps.peers[id]
if !ok {
return errNotRegistered
}
delete(ps.peers, id)
p.close()
return nil
}
// Peer retrieves the registered peer with the given id.
func (ps *peerSet) Peer(id string) *peer {
ps.lock.RLock()
defer ps.lock.RUnlock()
return ps.peers[id]
}
// Len returns if the current number of peers in the set.
func (ps *peerSet) Len() int {
ps.lock.RLock()
defer ps.lock.RUnlock()
return len(ps.peers)
}
// Peers retrieves all of the peers.
func (ps *peerSet) Peers() []*peer {
ps.lock.RLock()
defer ps.lock.RUnlock()
list := make([]*peer, 0, len(ps.peers))
for _, p := range ps.peers {
list = append(list, p)
}
return list
}
// PeersWithoutBlock retrieves a list of peers that do not have a given block in
// their set of known hashes.
func (ps *peerSet) PeersWithoutBlock(hash common.Hash) []*peer {
ps.lock.RLock()
defer ps.lock.RUnlock()
list := make([]*peer, 0, len(ps.peers))
for _, p := range ps.peers {
if !p.knownBlocks.Contains(hash) {
list = append(list, p)
}
}
return list
}
func (ps *peerSet) PeersWithLabel(label peerLabel) []*peer {
ps.lock.RLock()
defer ps.lock.RUnlock()
list := make([]*peer, 0, len(ps.label2Nodes[label]))
for id := range ps.label2Nodes[label] {
if p, ok := ps.peers[id]; ok {
list = append(list, p)
}
}
return list
}
func (ps *peerSet) PeersWithoutLabel(label peerLabel) []*peer {
ps.lock.RLock()
defer ps.lock.RUnlock()
length := len(ps.peers) - len(ps.label2Nodes[label])
if length <= 0 {
return []*peer{}
}
list := make([]*peer, 0, len(ps.peers)-len(ps.label2Nodes[label]))
peersWithLabel := ps.label2Nodes[label]
for id, p := range ps.peers {
if _, exist := peersWithLabel[id]; !exist {
list = append(list, p)
}
}
return list
}
// PeersWithoutNodeRecord retrieves a list of peers that do not have a
// given record in their set of known hashes.
func (ps *peerSet) PeersWithoutNodeRecord(hash common.Hash) []*peer {
ps.lock.RLock()
defer ps.lock.RUnlock()
list := make([]*peer, 0, len(ps.peers))
for _, p := range ps.peers {
if !p.knownRecords.Contains(hash) {
list = append(list, p)
}
}
return list
}
func (ps *peerSet) PeersWithoutAgreement(hash common.Hash) []*peer {
ps.lock.RLock()
defer ps.lock.RUnlock()
list := make([]*peer, 0, len(ps.peers))
for _, p := range ps.peers {
if !p.knownAgreements.Contains(hash) {
list = append(list, p)
}
}
return list
}
func (ps *peerSet) PeersWithoutDKGPrivateShares(hash common.Hash) []*peer {
ps.lock.RLock()
defer ps.lock.RUnlock()
list := make([]*peer, 0, len(ps.peers))
for _, p := range ps.peers {
if !p.knownDKGPrivateShares.Contains(hash) {
list = append(list, p)
}
}
return list
}
// BestPeer retrieves the known peer with the currently highest total difficulty.
func (ps *peerSet) BestPeer() *peer {
ps.lock.RLock()
defer ps.lock.RUnlock()
var (
bestPeer *peer
bestNumber uint64
)
for _, p := range ps.peers {
if _, number := p.Head(); bestPeer == nil || number > bestNumber {
bestPeer, bestNumber = p, number
}
}
return bestPeer
}
// Close disconnects all peers.
// No new peers can be registered after Close has returned.
func (ps *peerSet) Close() {
ps.lock.Lock()
defer ps.lock.Unlock()
for _, p := range ps.peers {
p.Disconnect(p2p.DiscQuitting)
}
ps.closed = true
}
func (ps *peerSet) BuildConnection(round uint64) {
ps.lock.Lock()
defer ps.lock.Unlock()
log.Info("Build connection", "round", round)
notaryLabel := peerLabel{set: notaryset, round: round}
if _, ok := ps.label2Nodes[notaryLabel]; !ok {
notaryPKs, err := ps.gov.NotarySet(round)
if err != nil {
log.Error("get notary set fail", "round", round, "err", err)
return
}
nodes := ps.pksToNodes(notaryPKs)
ps.label2Nodes[notaryLabel] = nodes
if _, exists := nodes[ps.srvr.Self().ID().String()]; exists {
ps.buildDirectConn(notaryLabel)
} else {
ps.buildGroupConn(notaryLabel)
}
}
}
func (ps *peerSet) ForgetConnection(round uint64) {
ps.lock.Lock()
defer ps.lock.Unlock()
for label := range ps.directConn {
if label.round <= round {
ps.forgetDirectConn(label)
}
}
for label := range ps.groupConnPeers {
if label.round <= round {
ps.forgetGroupConn(label)
}
}
for label := range ps.label2Nodes {
if label.round <= round {
delete(ps.label2Nodes, label)
}
}
}
func (ps *peerSet) EnsureGroupConn() {
ps.lock.Lock()
defer ps.lock.Unlock()
now := time.Now()
for label, peers := range ps.groupConnPeers {
// Remove timeout group conn peer.
for id, addtime := range peers {
if ps.peers[id] == nil && time.Since(addtime) > groupConnTimeout {
ps.removeDirectPeer(id, label)
delete(ps.groupConnPeers[label], id)
}
}
// Add new group conn peer.
for id := range ps.label2Nodes[label] {
if len(ps.groupConnPeers[label]) >= groupConnNum {
break
}
ps.groupConnPeers[label][id] = now
ps.addDirectPeer(id, label)
}
}
}
func (ps *peerSet) Refresh() {
ps.lock.Lock()
defer ps.lock.Unlock()
for id := range ps.allDirectPeers {
if ps.peers[id] == nil {
if node := ps.tab.GetNode(enode.HexID(id)); node != nil {
ps.srvr.AddDirectPeer(node)
}
}
}
}
func (ps *peerSet) buildDirectConn(label peerLabel) {
ps.directConn[label] = struct{}{}
for id := range ps.label2Nodes[label] {
ps.addDirectPeer(id, label)
}
}
func (ps *peerSet) forgetDirectConn(label peerLabel) {
for id := range ps.label2Nodes[label] {
ps.removeDirectPeer(id, label)
}
delete(ps.directConn, label)
}
func (ps *peerSet) buildGroupConn(label peerLabel) {
peers := make(map[string]time.Time)
now := time.Now()
for id := range ps.label2Nodes[label] {
peers[id] = now
ps.addDirectPeer(id, label)
if len(peers) >= groupConnNum {
break
}
}
ps.groupConnPeers[label] = peers
}
func (ps *peerSet) forgetGroupConn(label peerLabel) {
for id := range ps.groupConnPeers[label] {
ps.removeDirectPeer(id, label)
}
delete(ps.groupConnPeers, label)
}
func (ps *peerSet) addDirectPeer(id string, label peerLabel) {
if len(ps.allDirectPeers[id]) > 0 {
ps.allDirectPeers[id][label] = struct{}{}
return
}
ps.allDirectPeers[id] = map[peerLabel]struct{}{label: {}}
node := ps.tab.GetNode(enode.HexID(id))
if node == nil {
node = ps.label2Nodes[label][id]
}
ps.srvr.AddDirectPeer(node)
}
func (ps *peerSet) removeDirectPeer(id string, label peerLabel) {
if len(ps.allDirectPeers[id]) == 0 {
return
}
delete(ps.allDirectPeers[id], label)
if len(ps.allDirectPeers[id]) == 0 {
ps.srvr.RemoveDirectPeer(ps.label2Nodes[label][id])
delete(ps.allDirectPeers, id)
}
}
func (ps *peerSet) pksToNodes(pks map[string]struct{}) map[string]*enode.Node {
nodes := map[string]*enode.Node{}
for pk := range pks {
n := ps.newEmptyNode(pk)
if n.ID() == ps.srvr.Self().ID() {
n = ps.srvr.Self()
}
nodes[n.ID().String()] = n
}
return nodes
}
func (ps *peerSet) newEmptyNode(pk string) *enode.Node {
b, err := hex.DecodeString(pk)
if err != nil {
panic(err)
}
pubkey, err := crypto.UnmarshalPubkey(b)
if err != nil {
panic(err)
}
return enode.NewV4(pubkey, nil, 0, 0)
}
func (ps *peerSet) Status() {
ps.lock.Lock()
defer ps.lock.Unlock()
for label := range ps.directConn {
l := label.String()
for id := range ps.label2Nodes[label] {
_, ok := ps.peers[id]
log.Debug("direct conn", "label", l, "id", id, "connected", ok)
}
}
for label, peers := range ps.groupConnPeers {
l := label.String()
for id := range peers {
_, ok := ps.peers[id]
log.Debug("group conn", "label", l, "id", id, "connected", ok)
}
}
connected := 0
for id := range ps.allDirectPeers {
if _, ok := ps.peers[id]; ok {
connected++
}
}
log.Debug("all direct peers",
"connected", connected, "all", len(ps.allDirectPeers))
}
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