Merge pull request #19513 from fjl/p2p-discover-split-v4

p2p/discover: split out discv4 code
This commit is contained in:
Péter Szilágyi 2019-05-02 17:30:49 +03:00 committed by GitHub
commit b6c0234e0b
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8 changed files with 746 additions and 700 deletions

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@ -0,0 +1,46 @@
// Copyright 2017 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 testlog provides a log handler for unit tests.
package testlog
import (
"testing"
"github.com/ethereum/go-ethereum/log"
)
// Logger returns a logger which logs to the unit test log of t.
func Logger(t *testing.T, level log.Lvl) log.Logger {
l := log.New()
l.SetHandler(Handler(t, level))
return l
}
// Handler returns a log handler which logs to the unit test log of t.
func Handler(t *testing.T, level log.Lvl) log.Handler {
return log.LvlFilterHandler(level, &handler{t, log.TerminalFormat(false)})
}
type handler struct {
t *testing.T
fmt log.Format
}
func (h *handler) Log(r *log.Record) error {
h.t.Logf("%s", h.fmt.Format(r))
return nil
}

57
p2p/discover/common.go Normal file
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@ -0,0 +1,57 @@
// Copyright 2019 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 discover
import (
"crypto/ecdsa"
"net"
"github.com/ethereum/go-ethereum/log"
"github.com/ethereum/go-ethereum/p2p/enode"
"github.com/ethereum/go-ethereum/p2p/netutil"
)
type UDPConn interface {
ReadFromUDP(b []byte) (n int, addr *net.UDPAddr, err error)
WriteToUDP(b []byte, addr *net.UDPAddr) (n int, err error)
Close() error
LocalAddr() net.Addr
}
// Config holds Table-related settings.
type Config struct {
// These settings are required and configure the UDP listener:
PrivateKey *ecdsa.PrivateKey
// These settings are optional:
NetRestrict *netutil.Netlist // network whitelist
Bootnodes []*enode.Node // list of bootstrap nodes
Unhandled chan<- ReadPacket // unhandled packets are sent on this channel
Log log.Logger // if set, log messages go here
}
// ListenUDP starts listening for discovery packets on the given UDP socket.
func ListenUDP(c UDPConn, ln *enode.LocalNode, cfg Config) (*UDPv4, error) {
return ListenV4(c, ln, cfg)
}
// ReadPacket is a packet that couldn't be handled. Those packets are sent to the unhandled
// channel if configured.
type ReadPacket struct {
Data []byte
Addr *net.UDPAddr
}

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@ -23,7 +23,6 @@
package discover
import (
"crypto/ecdsa"
crand "crypto/rand"
"encoding/binary"
"fmt"
@ -34,7 +33,6 @@ import (
"time"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/crypto"
"github.com/ethereum/go-ethereum/log"
"github.com/ethereum/go-ethereum/p2p/enode"
"github.com/ethereum/go-ethereum/p2p/netutil"
@ -71,26 +69,23 @@ type Table struct {
rand *mrand.Rand // source of randomness, periodically reseeded
ips netutil.DistinctNetSet
log log.Logger
db *enode.DB // database of known nodes
net transport
refreshReq chan chan struct{}
initDone chan struct{}
closeOnce sync.Once
closeReq chan struct{}
closed chan struct{}
nodeAddedHook func(*node) // for testing
}
// transport is implemented by the UDP transport.
// it is an interface so we can test without opening lots of UDP
// sockets and without generating a private key.
// transport is implemented by UDP transports.
type transport interface {
self() *enode.Node
ping(enode.ID, *net.UDPAddr) error
findnode(toid enode.ID, addr *net.UDPAddr, target encPubkey) ([]*node, error)
close()
Self() *enode.Node
lookupRandom() []*enode.Node
lookupSelf() []*enode.Node
ping(*enode.Node) error
}
// bucket contains nodes, ordered by their last activity. the entry
@ -101,7 +96,7 @@ type bucket struct {
ips netutil.DistinctNetSet
}
func newTable(t transport, db *enode.DB, bootnodes []*enode.Node) (*Table, error) {
func newTable(t transport, db *enode.DB, bootnodes []*enode.Node, log log.Logger) (*Table, error) {
tab := &Table{
net: t,
db: db,
@ -111,6 +106,7 @@ func newTable(t transport, db *enode.DB, bootnodes []*enode.Node) (*Table, error
closed: make(chan struct{}),
rand: mrand.New(mrand.NewSource(0)),
ips: netutil.DistinctNetSet{Subnet: tableSubnet, Limit: tableIPLimit},
log: log,
}
if err := tab.setFallbackNodes(bootnodes); err != nil {
return nil, err
@ -128,7 +124,7 @@ func newTable(t transport, db *enode.DB, bootnodes []*enode.Node) (*Table, error
}
func (tab *Table) self() *enode.Node {
return tab.net.self()
return tab.net.Self()
}
func (tab *Table) seedRand() {
@ -180,16 +176,22 @@ func (tab *Table) ReadRandomNodes(buf []*enode.Node) (n int) {
return i + 1
}
// Close terminates the network listener and flushes the node database.
func (tab *Table) Close() {
tab.closeOnce.Do(func() {
if tab.net != nil {
tab.net.close()
// Resolve searches for a specific node with the given ID.
// It returns nil if the node could not be found.
func (tab *Table) Resolve(n *enode.Node) *enode.Node {
tab.mutex.Lock()
cl := tab.closest(n.ID(), 1, false)
tab.mutex.Unlock()
if len(cl.entries) > 0 && cl.entries[0].ID() == n.ID() {
return unwrapNode(cl.entries[0])
}
// Wait for loop to end.
return nil
}
// close terminates the network listener and flushes the node database.
func (tab *Table) close() {
close(tab.closeReq)
<-tab.closed
})
}
// setFallbackNodes sets the initial points of contact. These nodes
@ -215,124 +217,6 @@ func (tab *Table) isInitDone() bool {
}
}
// Resolve searches for a specific node with the given ID.
// It returns nil if the node could not be found.
func (tab *Table) Resolve(n *enode.Node) *enode.Node {
// If the node is present in the local table, no
// network interaction is required.
hash := n.ID()
tab.mutex.Lock()
cl := tab.closest(hash, 1)
tab.mutex.Unlock()
if len(cl.entries) > 0 && cl.entries[0].ID() == hash {
return unwrapNode(cl.entries[0])
}
// Otherwise, do a network lookup.
result := tab.lookup(encodePubkey(n.Pubkey()), true)
for _, n := range result {
if n.ID() == hash {
return unwrapNode(n)
}
}
return nil
}
// LookupRandom finds random nodes in the network.
func (tab *Table) LookupRandom() []*enode.Node {
var target encPubkey
crand.Read(target[:])
return unwrapNodes(tab.lookup(target, true))
}
// lookup performs a network search for nodes close to the given target. It approaches the
// target by querying nodes that are closer to it on each iteration. The given target does
// not need to be an actual node identifier.
func (tab *Table) lookup(targetKey encPubkey, refreshIfEmpty bool) []*node {
var (
target = enode.ID(crypto.Keccak256Hash(targetKey[:]))
asked = make(map[enode.ID]bool)
seen = make(map[enode.ID]bool)
reply = make(chan []*node, alpha)
pendingQueries = 0
result *nodesByDistance
)
// don't query further if we hit ourself.
// unlikely to happen often in practice.
asked[tab.self().ID()] = true
for {
tab.mutex.Lock()
// generate initial result set
result = tab.closest(target, bucketSize)
tab.mutex.Unlock()
if len(result.entries) > 0 || !refreshIfEmpty {
break
}
// The result set is empty, all nodes were dropped, refresh.
// We actually wait for the refresh to complete here. The very
// first query will hit this case and run the bootstrapping
// logic.
<-tab.refresh()
refreshIfEmpty = false
}
for {
// ask the alpha closest nodes that we haven't asked yet
for i := 0; i < len(result.entries) && pendingQueries < alpha; i++ {
n := result.entries[i]
if !asked[n.ID()] {
asked[n.ID()] = true
pendingQueries++
go tab.findnode(n, targetKey, reply)
}
}
if pendingQueries == 0 {
// we have asked all closest nodes, stop the search
break
}
select {
case nodes := <-reply:
for _, n := range nodes {
if n != nil && !seen[n.ID()] {
seen[n.ID()] = true
result.push(n, bucketSize)
}
}
case <-tab.closeReq:
return nil // shutdown, no need to continue.
}
pendingQueries--
}
return result.entries
}
func (tab *Table) findnode(n *node, targetKey encPubkey, reply chan<- []*node) {
fails := tab.db.FindFails(n.ID(), n.IP())
r, err := tab.net.findnode(n.ID(), n.addr(), targetKey)
if err == errClosed {
// Avoid recording failures on shutdown.
reply <- nil
return
} else if len(r) == 0 {
fails++
tab.db.UpdateFindFails(n.ID(), n.IP(), fails)
log.Trace("Findnode failed", "id", n.ID(), "failcount", fails, "err", err)
if fails >= maxFindnodeFailures {
log.Trace("Too many findnode failures, dropping", "id", n.ID(), "failcount", fails)
tab.delete(n)
}
} else if fails > 0 {
tab.db.UpdateFindFails(n.ID(), n.IP(), fails-1)
}
// Grab as many nodes as possible. Some of them might not be alive anymore, but we'll
// just remove those again during revalidation.
for _, n := range r {
tab.addSeenNode(n)
}
reply <- r
}
func (tab *Table) refresh() <-chan struct{} {
done := make(chan struct{})
select {
@ -417,11 +301,7 @@ func (tab *Table) doRefresh(done chan struct{}) {
tab.loadSeedNodes()
// Run self lookup to discover new neighbor nodes.
// We can only do this if we have a secp256k1 identity.
var key ecdsa.PublicKey
if err := tab.self().Load((*enode.Secp256k1)(&key)); err == nil {
tab.lookup(encodePubkey(&key), false)
}
tab.net.lookupSelf()
// The Kademlia paper specifies that the bucket refresh should
// perform a lookup in the least recently used bucket. We cannot
@ -430,9 +310,7 @@ func (tab *Table) doRefresh(done chan struct{}) {
// sha3 preimage that falls into a chosen bucket.
// We perform a few lookups with a random target instead.
for i := 0; i < 3; i++ {
var target encPubkey
crand.Read(target[:])
tab.lookup(target, false)
tab.net.lookupRandom()
}
}
@ -442,7 +320,7 @@ func (tab *Table) loadSeedNodes() {
for i := range seeds {
seed := seeds[i]
age := log.Lazy{Fn: func() interface{} { return time.Since(tab.db.LastPongReceived(seed.ID(), seed.IP())) }}
log.Trace("Found seed node in database", "id", seed.ID(), "addr", seed.addr(), "age", age)
tab.log.Trace("Found seed node in database", "id", seed.ID(), "addr", seed.addr(), "age", age)
tab.addSeenNode(seed)
}
}
@ -459,7 +337,7 @@ func (tab *Table) doRevalidate(done chan<- struct{}) {
}
// Ping the selected node and wait for a pong.
err := tab.net.ping(last.ID(), last.addr())
err := tab.net.ping(unwrapNode(last))
tab.mutex.Lock()
defer tab.mutex.Unlock()
@ -467,16 +345,16 @@ func (tab *Table) doRevalidate(done chan<- struct{}) {
if err == nil {
// The node responded, move it to the front.
last.livenessChecks++
log.Debug("Revalidated node", "b", bi, "id", last.ID(), "checks", last.livenessChecks)
tab.log.Debug("Revalidated node", "b", bi, "id", last.ID(), "checks", last.livenessChecks)
tab.bumpInBucket(b, last)
return
}
// No reply received, pick a replacement or delete the node if there aren't
// any replacements.
if r := tab.replace(b, last); r != nil {
log.Debug("Replaced dead node", "b", bi, "id", last.ID(), "ip", last.IP(), "checks", last.livenessChecks, "r", r.ID(), "rip", r.IP())
tab.log.Debug("Replaced dead node", "b", bi, "id", last.ID(), "ip", last.IP(), "checks", last.livenessChecks, "r", r.ID(), "rip", r.IP())
} else {
log.Debug("Removed dead node", "b", bi, "id", last.ID(), "ip", last.IP(), "checks", last.livenessChecks)
tab.log.Debug("Removed dead node", "b", bi, "id", last.ID(), "ip", last.IP(), "checks", last.livenessChecks)
}
}
@ -520,22 +398,27 @@ func (tab *Table) copyLiveNodes() {
// closest returns the n nodes in the table that are closest to the
// given id. The caller must hold tab.mutex.
func (tab *Table) closest(target enode.ID, nresults int) *nodesByDistance {
func (tab *Table) closest(target enode.ID, nresults int, checklive bool) *nodesByDistance {
// This is a very wasteful way to find the closest nodes but
// obviously correct. I believe that tree-based buckets would make
// this easier to implement efficiently.
close := &nodesByDistance{target: target}
for _, b := range &tab.buckets {
for _, n := range b.entries {
if n.livenessChecks > 0 {
close.push(n, nresults)
if checklive && n.livenessChecks == 0 {
continue
}
close.push(n, nresults)
}
}
return close
}
// len returns the number of nodes in the table.
func (tab *Table) len() (n int) {
tab.mutex.Lock()
defer tab.mutex.Unlock()
for _, b := range &tab.buckets {
n += len(b.entries)
}
@ -641,11 +524,11 @@ func (tab *Table) addIP(b *bucket, ip net.IP) bool {
return true
}
if !tab.ips.Add(ip) {
log.Debug("IP exceeds table limit", "ip", ip)
tab.log.Debug("IP exceeds table limit", "ip", ip)
return false
}
if !b.ips.Add(ip) {
log.Debug("IP exceeds bucket limit", "ip", ip)
tab.log.Debug("IP exceeds bucket limit", "ip", ip)
tab.ips.Remove(ip)
return false
}
@ -754,8 +637,7 @@ func deleteNode(list []*node, n *node) []*node {
return list
}
// nodesByDistance is a list of nodes, ordered by
// distance to target.
// nodesByDistance is a list of nodes, ordered by distance to target.
type nodesByDistance struct {
entries []*node
target enode.ID

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@ -52,7 +52,7 @@ func testPingReplace(t *testing.T, newNodeIsResponding, lastInBucketIsResponding
transport := newPingRecorder()
tab, db := newTestTable(transport)
defer db.Close()
defer tab.Close()
defer tab.close()
<-tab.initDone
@ -117,7 +117,7 @@ func TestBucket_bumpNoDuplicates(t *testing.T) {
prop := func(nodes []*node, bumps []int) (ok bool) {
tab, db := newTestTable(newPingRecorder())
defer db.Close()
defer tab.Close()
defer tab.close()
b := &bucket{entries: make([]*node, len(nodes))}
copy(b.entries, nodes)
@ -144,7 +144,7 @@ func TestTable_IPLimit(t *testing.T) {
transport := newPingRecorder()
tab, db := newTestTable(transport)
defer db.Close()
defer tab.Close()
defer tab.close()
for i := 0; i < tableIPLimit+1; i++ {
n := nodeAtDistance(tab.self().ID(), i, net.IP{172, 0, 1, byte(i)})
@ -161,7 +161,7 @@ func TestTable_BucketIPLimit(t *testing.T) {
transport := newPingRecorder()
tab, db := newTestTable(transport)
defer db.Close()
defer tab.Close()
defer tab.close()
d := 3
for i := 0; i < bucketIPLimit+1; i++ {
@ -198,11 +198,11 @@ func TestTable_closest(t *testing.T) {
transport := newPingRecorder()
tab, db := newTestTable(transport)
defer db.Close()
defer tab.Close()
defer tab.close()
fillTable(tab, test.All)
// check that closest(Target, N) returns nodes
result := tab.closest(test.Target, test.N).entries
result := tab.closest(test.Target, test.N, false).entries
if hasDuplicates(result) {
t.Errorf("result contains duplicates")
return false
@ -259,7 +259,7 @@ func TestTable_ReadRandomNodesGetAll(t *testing.T) {
transport := newPingRecorder()
tab, db := newTestTable(transport)
defer db.Close()
defer tab.Close()
defer tab.close()
<-tab.initDone
for i := 0; i < len(buf); i++ {
@ -309,7 +309,7 @@ func TestTable_addVerifiedNode(t *testing.T) {
tab, db := newTestTable(newPingRecorder())
<-tab.initDone
defer db.Close()
defer tab.Close()
defer tab.close()
// Insert two nodes.
n1 := nodeAtDistance(tab.self().ID(), 256, net.IP{88, 77, 66, 1})
@ -341,7 +341,7 @@ func TestTable_addSeenNode(t *testing.T) {
tab, db := newTestTable(newPingRecorder())
<-tab.initDone
defer db.Close()
defer tab.Close()
defer tab.close()
// Insert two nodes.
n1 := nodeAtDistance(tab.self().ID(), 256, net.IP{88, 77, 66, 1})
@ -368,298 +368,6 @@ func TestTable_addSeenNode(t *testing.T) {
checkIPLimitInvariant(t, tab)
}
func TestTable_Lookup(t *testing.T) {
tab, db := newTestTable(lookupTestnet)
defer db.Close()
defer tab.Close()
// lookup on empty table returns no nodes
if results := tab.lookup(lookupTestnet.target, false); len(results) > 0 {
t.Fatalf("lookup on empty table returned %d results: %#v", len(results), results)
}
// seed table with initial node (otherwise lookup will terminate immediately)
seedKey, _ := decodePubkey(lookupTestnet.dists[256][0])
seed := wrapNode(enode.NewV4(seedKey, net.IP{127, 0, 0, 1}, 0, 256))
seed.livenessChecks = 1
fillTable(tab, []*node{seed})
results := tab.lookup(lookupTestnet.target, true)
t.Logf("results:")
for _, e := range results {
t.Logf(" ld=%d, %x", enode.LogDist(lookupTestnet.targetSha, e.ID()), e.ID().Bytes())
}
if len(results) != bucketSize {
t.Errorf("wrong number of results: got %d, want %d", len(results), bucketSize)
}
if hasDuplicates(results) {
t.Errorf("result set contains duplicate entries")
}
if !sortedByDistanceTo(lookupTestnet.targetSha, results) {
t.Errorf("result set not sorted by distance to target")
}
// TODO: check result nodes are actually closest
}
// This is the test network for the Lookup test.
// The nodes were obtained by running testnet.mine with a random NodeID as target.
var lookupTestnet = &preminedTestnet{
target: hexEncPubkey("166aea4f556532c6d34e8b740e5d314af7e9ac0ca79833bd751d6b665f12dfd38ec563c363b32f02aef4a80b44fd3def94612d497b99cb5f17fd24de454927ec"),
targetSha: enode.HexID("5c944ee51c5ae9f72a95eccb8aed0374eecb5119d720cbea6813e8e0d6ad9261"),
dists: [257][]encPubkey{
240: {
hexEncPubkey("2001ad5e3e80c71b952161bc0186731cf5ffe942d24a79230a0555802296238e57ea7a32f5b6f18564eadc1c65389448481f8c9338df0a3dbd18f708cbc2cbcb"),
hexEncPubkey("6ba3f4f57d084b6bf94cc4555b8c657e4a8ac7b7baf23c6874efc21dd1e4f56b7eb2721e07f5242d2f1d8381fc8cae535e860197c69236798ba1ad231b105794"),
},
244: {
hexEncPubkey("696ba1f0a9d55c59246f776600542a9e6432490f0cd78f8bb55a196918df2081a9b521c3c3ba48e465a75c10768807717f8f689b0b4adce00e1c75737552a178"),
},
246: {
hexEncPubkey("d6d32178bdc38416f46ffb8b3ec9e4cb2cfff8d04dd7e4311a70e403cb62b10be1b447311b60b4f9ee221a8131fc2cbd45b96dd80deba68a949d467241facfa8"),
hexEncPubkey("3ea3d04a43a3dfb5ac11cffc2319248cf41b6279659393c2f55b8a0a5fc9d12581a9d97ef5d8ff9b5abf3321a290e8f63a4f785f450dc8a672aba3ba2ff4fdab"),
hexEncPubkey("2fc897f05ae585553e5c014effd3078f84f37f9333afacffb109f00ca8e7a3373de810a3946be971cbccdfd40249f9fe7f322118ea459ac71acca85a1ef8b7f4"),
},
247: {
hexEncPubkey("3155e1427f85f10a5c9a7755877748041af1bcd8d474ec065eb33df57a97babf54bfd2103575fa829115d224c523596b401065a97f74010610fce76382c0bf32"),
hexEncPubkey("312c55512422cf9b8a4097e9a6ad79402e87a15ae909a4bfefa22398f03d20951933beea1e4dfa6f968212385e829f04c2d314fc2d4e255e0d3bc08792b069db"),
hexEncPubkey("38643200b172dcfef857492156971f0e6aa2c538d8b74010f8e140811d53b98c765dd2d96126051913f44582e8c199ad7c6d6819e9a56483f637feaac9448aac"),
hexEncPubkey("8dcab8618c3253b558d459da53bd8fa68935a719aff8b811197101a4b2b47dd2d47295286fc00cc081bb542d760717d1bdd6bec2c37cd72eca367d6dd3b9df73"),
hexEncPubkey("8b58c6073dd98bbad4e310b97186c8f822d3a5c7d57af40e2136e88e315afd115edb27d2d0685a908cfe5aa49d0debdda6e6e63972691d6bd8c5af2d771dd2a9"),
hexEncPubkey("2cbb718b7dc682da19652e7d9eb4fefaf7b7147d82c1c2b6805edf77b85e29fde9f6da195741467ff2638dc62c8d3e014ea5686693c15ed0080b6de90354c137"),
hexEncPubkey("e84027696d3f12f2de30a9311afea8fbd313c2360daff52bb5fc8c7094d5295758bec3134e4eef24e4cdf377b40da344993284628a7a346eba94f74160998feb"),
hexEncPubkey("f1357a4f04f9d33753a57c0b65ba20a5d8777abbffd04e906014491c9103fb08590e45548d37aa4bd70965e2e81ddba94f31860348df01469eec8c1829200a68"),
hexEncPubkey("4ab0a75941b12892369b4490a1928c8ca52a9ad6d3dffbd1d8c0b907bc200fe74c022d011ec39b64808a39c0ca41f1d3254386c3e7733e7044c44259486461b6"),
hexEncPubkey("d45150a72dc74388773e68e03133a3b5f51447fe91837d566706b3c035ee4b56f160c878c6273394daee7f56cc398985269052f22f75a8057df2fe6172765354"),
},
248: {
hexEncPubkey("6aadfce366a189bab08ac84721567483202c86590642ea6d6a14f37ca78d82bdb6509eb7b8b2f6f63c78ae3ae1d8837c89509e41497d719b23ad53dd81574afa"),
hexEncPubkey("a605ecfd6069a4cf4cf7f5840e5bc0ce10d23a3ac59e2aaa70c6afd5637359d2519b4524f56fc2ca180cdbebe54262f720ccaae8c1b28fd553c485675831624d"),
hexEncPubkey("29701451cb9448ca33fc33680b44b840d815be90146eb521641efbffed0859c154e8892d3906eae9934bfacee72cd1d2fa9dd050fd18888eea49da155ab0efd2"),
hexEncPubkey("3ed426322dee7572b08592e1e079f8b6c6b30e10e6243edd144a6a48fdbdb83df73a6e41b1143722cb82604f2203a32758610b5d9544f44a1a7921ba001528c1"),
hexEncPubkey("b2e2a2b7fdd363572a3256e75435fab1da3b16f7891a8bd2015f30995dae665d7eabfd194d87d99d5df628b4bbc7b04e5b492c596422dd8272746c7a1b0b8e4f"),
hexEncPubkey("0c69c9756162c593e85615b814ce57a2a8ca2df6c690b9c4e4602731b61e1531a3bbe3f7114271554427ffabea80ad8f36fa95a49fa77b675ae182c6ccac1728"),
hexEncPubkey("8d28be21d5a97b0876442fa4f5e5387f5bf3faad0b6f13b8607b64d6e448c0991ca28dd7fe2f64eb8eadd7150bff5d5666aa6ed868b84c71311f4ba9a38569dd"),
hexEncPubkey("2c677e1c64b9c9df6359348a7f5f33dc79e22f0177042486d125f8b6ca7f0dc756b1f672aceee5f1746bcff80aaf6f92a8dc0c9fbeb259b3fa0da060de5ab7e8"),
hexEncPubkey("3994880f94a8678f0cd247a43f474a8af375d2a072128da1ad6cae84a244105ff85e94fc7d8496f639468de7ee998908a91c7e33ef7585fff92e984b210941a1"),
hexEncPubkey("b45a9153c08d002a48090d15d61a7c7dad8c2af85d4ff5bd36ce23a9a11e0709bf8d56614c7b193bc028c16cbf7f20dfbcc751328b64a924995d47b41e452422"),
hexEncPubkey("057ab3a9e53c7a84b0f3fc586117a525cdd18e313f52a67bf31798d48078e325abe5cfee3f6c2533230cb37d0549289d692a29dd400e899b8552d4b928f6f907"),
hexEncPubkey("0ddf663d308791eb92e6bd88a2f8cb45e4f4f35bb16708a0e6ff7f1362aa6a73fedd0a1b1557fb3365e38e1b79d6918e2fae2788728b70c9ab6b51a3b94a4338"),
hexEncPubkey("f637e07ff50cc1e3731735841c4798411059f2023abcf3885674f3e8032531b0edca50fd715df6feb489b6177c345374d64f4b07d257a7745de393a107b013a5"),
hexEncPubkey("e24ec7c6eec094f63c7b3239f56d311ec5a3e45bc4e622a1095a65b95eea6fe13e29f3b6b7a2cbfe40906e3989f17ac834c3102dd0cadaaa26e16ee06d782b72"),
hexEncPubkey("b76ea1a6fd6506ef6e3506a4f1f60ed6287fff8114af6141b2ff13e61242331b54082b023cfea5b3083354a4fb3f9eb8be01fb4a518f579e731a5d0707291a6b"),
hexEncPubkey("9b53a37950ca8890ee349b325032d7b672cab7eced178d3060137b24ef6b92a43977922d5bdfb4a3409a2d80128e02f795f9dae6d7d99973ad0e23a2afb8442f"),
},
249: {
hexEncPubkey("675ae65567c3c72c50c73bc0fd4f61f202ea5f93346ca57b551de3411ccc614fad61cb9035493af47615311b9d44ee7a161972ee4d77c28fe1ec029d01434e6a"),
hexEncPubkey("8eb81408389da88536ae5800392b16ef5109d7ea132c18e9a82928047ecdb502693f6e4a4cdd18b54296caf561db937185731456c456c98bfe7de0baf0eaa495"),
hexEncPubkey("2adba8b1612a541771cb93a726a38a4b88e97b18eced2593eb7daf82f05a5321ca94a72cc780c306ff21e551a932fc2c6d791e4681907b5ceab7f084c3fa2944"),
hexEncPubkey("b1b4bfbda514d9b8f35b1c28961da5d5216fe50548f4066f69af3b7666a3b2e06eac646735e963e5c8f8138a2fb95af15b13b23ff00c6986eccc0efaa8ee6fb4"),
hexEncPubkey("d2139281b289ad0e4d7b4243c4364f5c51aac8b60f4806135de06b12b5b369c9e43a6eb494eab860d115c15c6fbb8c5a1b0e382972e0e460af395b8385363de7"),
hexEncPubkey("4a693df4b8fc5bdc7cec342c3ed2e228d7c5b4ab7321ddaa6cccbeb45b05a9f1d95766b4002e6d4791c2deacb8a667aadea6a700da28a3eea810a30395701bbc"),
hexEncPubkey("ab41611195ec3c62bb8cd762ee19fb182d194fd141f4a66780efbef4b07ce916246c022b841237a3a6b512a93431157edd221e854ed2a259b72e9c5351f44d0c"),
hexEncPubkey("68e8e26099030d10c3c703ae7045c0a48061fb88058d853b3e67880014c449d4311014da99d617d3150a20f1a3da5e34bf0f14f1c51fe4dd9d58afd222823176"),
hexEncPubkey("3fbcacf546fb129cd70fc48de3b593ba99d3c473798bc309292aca280320e0eacc04442c914cad5c4cf6950345ba79b0d51302df88285d4e83ee3fe41339eee7"),
hexEncPubkey("1d4a623659f7c8f80b6c3939596afdf42e78f892f682c768ad36eb7bfba402dbf97aea3a268f3badd8fe7636be216edf3d67ee1e08789ebbc7be625056bd7109"),
hexEncPubkey("a283c474ab09da02bbc96b16317241d0627646fcc427d1fe790b76a7bf1989ced90f92101a973047ae9940c92720dffbac8eff21df8cae468a50f72f9e159417"),
hexEncPubkey("dbf7e5ad7f87c3dfecae65d87c3039e14ed0bdc56caf00ce81931073e2e16719d746295512ff7937a15c3b03603e7c41a4f9df94fcd37bb200dd8f332767e9cb"),
hexEncPubkey("caaa070a26692f64fc77f30d7b5ae980d419b4393a0f442b1c821ef58c0862898b0d22f74a4f8c5d83069493e3ec0b92f17dc1fe6e4cd437c1ec25039e7ce839"),
hexEncPubkey("874cc8d1213beb65c4e0e1de38ef5d8165235893ac74ab5ea937c885eaab25c8d79dad0456e9fd3e9450626cac7e107b004478fb59842f067857f39a47cee695"),
hexEncPubkey("d94193f236105010972f5df1b7818b55846592a0445b9cdc4eaed811b8c4c0f7c27dc8cc9837a4774656d6b34682d6d329d42b6ebb55da1d475c2474dc3dfdf4"),
hexEncPubkey("edd9af6aded4094e9785637c28fccbd3980cbe28e2eb9a411048a23c2ace4bd6b0b7088a7817997b49a3dd05fc6929ca6c7abbb69438dbdabe65e971d2a794b2"),
},
250: {
hexEncPubkey("53a5bd1215d4ab709ae8fdc2ced50bba320bced78bd9c5dc92947fb402250c914891786db0978c898c058493f86fc68b1c5de8a5cb36336150ac7a88655b6c39"),
hexEncPubkey("b7f79e3ab59f79262623c9ccefc8f01d682323aee56ffbe295437487e9d5acaf556a9c92e1f1c6a9601f2b9eb6b027ae1aeaebac71d61b9b78e88676efd3e1a3"),
hexEncPubkey("d374bf7e8d7ffff69cc00bebff38ef5bc1dcb0a8d51c1a3d70e61ac6b2e2d6617109254b0ac224354dfbf79009fe4239e09020c483cc60c071e00b9238684f30"),
hexEncPubkey("1e1eac1c9add703eb252eb991594f8f5a173255d526a855fab24ae57dc277e055bc3c7a7ae0b45d437c4f47a72d97eb7b126f2ba344ba6c0e14b2c6f27d4b1e6"),
hexEncPubkey("ae28953f63d4bc4e706712a59319c111f5ff8f312584f65d7436b4cd3d14b217b958f8486bad666b4481fe879019fb1f767cf15b3e3e2711efc33b56d460448a"),
hexEncPubkey("934bb1edf9c7a318b82306aca67feb3d6b434421fa275d694f0b4927afd8b1d3935b727fd4ff6e3d012e0c82f1824385174e8c6450ade59c2a43281a4b3446b6"),
hexEncPubkey("9eef3f28f70ce19637519a0916555bf76d26de31312ac656cf9d3e379899ea44e4dd7ffcce923b4f3563f8a00489a34bd6936db0cbb4c959d32c49f017e07d05"),
hexEncPubkey("82200872e8f871c48f1fad13daec6478298099b591bb3dbc4ef6890aa28ebee5860d07d70be62f4c0af85085a90ae8179ee8f937cf37915c67ea73e704b03ee7"),
hexEncPubkey("6c75a5834a08476b7fc37ff3dc2011dc3ea3b36524bad7a6d319b18878fad813c0ba76d1f4555cacd3890c865438c21f0e0aed1f80e0a157e642124c69f43a11"),
hexEncPubkey("995b873742206cb02b736e73a88580c2aacb0bd4a3c97a647b647bcab3f5e03c0e0736520a8b3600da09edf4248991fb01091ec7ff3ec7cdc8a1beae011e7aae"),
hexEncPubkey("c773a056594b5cdef2e850d30891ff0e927c3b1b9c35cd8e8d53a1017001e237468e1ece3ae33d612ca3e6abb0a9169aa352e9dcda358e5af2ad982b577447db"),
hexEncPubkey("2b46a5f6923f475c6be99ec6d134437a6d11f6bb4b4ac6bcd94572fa1092639d1c08aeefcb51f0912f0a060f71d4f38ee4da70ecc16010b05dd4a674aab14c3a"),
hexEncPubkey("af6ab501366debbaa0d22e20e9688f32ef6b3b644440580fd78de4fe0e99e2a16eb5636bbae0d1c259df8ddda77b35b9a35cbc36137473e9c68fbc9d203ba842"),
hexEncPubkey("c9f6f2dd1a941926f03f770695bda289859e85fabaf94baaae20b93e5015dc014ba41150176a36a1884adb52f405194693e63b0c464a6891cc9cc1c80d450326"),
hexEncPubkey("5b116f0751526868a909b61a30b0c5282c37df6925cc03ddea556ef0d0602a9595fd6c14d371f8ed7d45d89918a032dcd22be4342a8793d88fdbeb3ca3d75bd7"),
hexEncPubkey("50f3222fb6b82481c7c813b2172e1daea43e2710a443b9c2a57a12bd160dd37e20f87aa968c82ad639af6972185609d47036c0d93b4b7269b74ebd7073221c10"),
},
251: {
hexEncPubkey("9b8f702a62d1bee67bedfeb102eca7f37fa1713e310f0d6651cc0c33ea7c5477575289ccd463e5a2574a00a676a1fdce05658ba447bb9d2827f0ba47b947e894"),
hexEncPubkey("b97532eb83054ed054b4abdf413bb30c00e4205545c93521554dbe77faa3cfaa5bd31ef466a107b0b34a71ec97214c0c83919720142cddac93aa7a3e928d4708"),
hexEncPubkey("2f7a5e952bfb67f2f90b8441b5fadc9ee13b1dcde3afeeb3dd64bf937f86663cc5c55d1fa83952b5422763c7df1b7f2794b751c6be316ebc0beb4942e65ab8c1"),
hexEncPubkey("42c7483781727051a0b3660f14faf39e0d33de5e643702ae933837d036508ab856ce7eec8ec89c4929a4901256e5233a3d847d5d4893f91bcf21835a9a880fee"),
hexEncPubkey("873bae27bf1dc854408fba94046a53ab0c965cebe1e4e12290806fc62b88deb1f4a47f9e18f78fc0e7913a0c6e42ac4d0fc3a20cea6bc65f0c8a0ca90b67521e"),
hexEncPubkey("a7e3a370bbd761d413f8d209e85886f68bf73d5c3089b2dc6fa42aab1ecb5162635497eed95dee2417f3c9c74a3e76319625c48ead2e963c7de877cd4551f347"),
hexEncPubkey("528597534776a40df2addaaea15b6ff832ce36b9748a265768368f657e76d58569d9f30dbb91e91cf0ae7efe8f402f17aa0ae15f5c55051ba03ba830287f4c42"),
hexEncPubkey("461d8bd4f13c3c09031fdb84f104ed737a52f630261463ce0bdb5704259bab4b737dda688285b8444dbecaecad7f50f835190b38684ced5e90c54219e5adf1bc"),
hexEncPubkey("6ec50c0be3fd232737090fc0111caaf0bb6b18f72be453428087a11a97fd6b52db0344acbf789a689bd4f5f50f79017ea784f8fd6fe723ad6ae675b9e3b13e21"),
hexEncPubkey("12fc5e2f77a83fdcc727b79d8ae7fe6a516881138d3011847ee136b400fed7cfba1f53fd7a9730253c7aa4f39abeacd04f138417ba7fcb0f36cccc3514e0dab6"),
hexEncPubkey("4fdbe75914ccd0bce02101606a1ccf3657ec963e3b3c20239d5fec87673fe446d649b4f15f1fe1a40e6cfbd446dda2d31d40bb602b1093b8fcd5f139ba0eb46a"),
hexEncPubkey("3753668a0f6281e425ea69b52cb2d17ab97afbe6eb84cf5d25425bc5e53009388857640668fadd7c110721e6047c9697803bd8a6487b43bb343bfa32ebf24039"),
hexEncPubkey("2e81b16346637dec4410fd88e527346145b9c0a849dbf2628049ac7dae016c8f4305649d5659ec77f1e8a0fac0db457b6080547226f06283598e3740ad94849a"),
hexEncPubkey("802c3cc27f91c89213223d758f8d2ecd41135b357b6d698f24d811cdf113033a81c38e0bdff574a5c005b00a8c193dc2531f8c1fa05fa60acf0ab6f2858af09f"),
hexEncPubkey("fcc9a2e1ac3667026ff16192876d1813bb75abdbf39b929a92863012fe8b1d890badea7a0de36274d5c1eb1e8f975785532c50d80fd44b1a4b692f437303393f"),
hexEncPubkey("6d8b3efb461151dd4f6de809b62726f5b89e9b38e9ba1391967f61cde844f7528fecf821b74049207cee5a527096b31f3ad623928cd3ce51d926fa345a6b2951"),
},
252: {
hexEncPubkey("f1ae93157cc48c2075dd5868fbf523e79e06caf4b8198f352f6e526680b78ff4227263de92612f7d63472bd09367bb92a636fff16fe46ccf41614f7a72495c2a"),
hexEncPubkey("587f482d111b239c27c0cb89b51dd5d574db8efd8de14a2e6a1400c54d4567e77c65f89c1da52841212080b91604104768350276b6682f2f961cdaf4039581c7"),
hexEncPubkey("e3f88274d35cefdaabdf205afe0e80e936cc982b8e3e47a84ce664c413b29016a4fb4f3a3ebae0a2f79671f8323661ed462bf4390af94c424dc8ace0c301b90f"),
hexEncPubkey("0ddc736077da9a12ba410dc5ea63cbcbe7659dd08596485b2bff3435221f82c10d263efd9af938e128464be64a178b7cd22e19f400d5802f4c9df54bf89f2619"),
hexEncPubkey("784aa34d833c6ce63fcc1279630113c3272e82c4ae8c126c5a52a88ac461b6baeed4244e607b05dc14e5b2f41c70a273c3804dea237f14f7a1e546f6d1309d14"),
hexEncPubkey("f253a2c354ee0e27cfcae786d726753d4ad24be6516b279a936195a487de4a59dbc296accf20463749ff55293263ed8c1b6365eecb248d44e75e9741c0d18205"),
hexEncPubkey("a1910b80357b3ad9b4593e0628922939614dc9056a5fbf477279c8b2c1d0b4b31d89a0c09d0d41f795271d14d3360ef08a3f821e65e7e1f56c07a36afe49c7c5"),
hexEncPubkey("f1168552c2efe541160f0909b0b4a9d6aeedcf595cdf0e9b165c97e3e197471a1ee6320e93389edfba28af6eaf10de98597ad56e7ab1b504ed762451996c3b98"),
hexEncPubkey("b0c8e5d2c8634a7930e1a6fd082e448c6cf9d2d8b7293558b59238815a4df926c286bf297d2049f14e8296a6eb3256af614ec1812c4f2bbe807673b58bf14c8c"),
hexEncPubkey("0fb346076396a38badc342df3679b55bd7f40a609ab103411fe45082c01f12ea016729e95914b2b5540e987ff5c9b133e85862648e7f36abdfd23100d248d234"),
hexEncPubkey("f736e0cc83417feaa280d9483f5d4d72d1b036cd0c6d9cbdeb8ac35ceb2604780de46dddaa32a378474e1d5ccdf79b373331c30c7911ade2ae32f98832e5de1f"),
hexEncPubkey("8b02991457602f42b38b342d3f2259ae4100c354b3843885f7e4e07bd644f64dab94bb7f38a3915f8b7f11d8e3f81c28e07a0078cf79d7397e38a7b7e0c857e2"),
hexEncPubkey("9221d9f04a8a184993d12baa91116692bb685f887671302999d69300ad103eb2d2c75a09d8979404c6dd28f12362f58a1a43619c493d9108fd47588a23ce5824"),
hexEncPubkey("652797801744dada833fff207d67484742eea6835d695925f3e618d71b68ec3c65bdd85b4302b2cdcb835ad3f94fd00d8da07e570b41bc0d2bcf69a8de1b3284"),
hexEncPubkey("d84f06fe64debc4cd0625e36d19b99014b6218375262cc2209202bdbafd7dffcc4e34ce6398e182e02fd8faeed622c3e175545864902dfd3d1ac57647cddf4c6"),
hexEncPubkey("d0ed87b294f38f1d741eb601020eeec30ac16331d05880fe27868f1e454446de367d7457b41c79e202eaf9525b029e4f1d7e17d85a55f83a557c005c68d7328a"),
},
253: {
hexEncPubkey("ad4485e386e3cc7c7310366a7c38fb810b8896c0d52e55944bfd320ca294e7912d6c53c0a0cf85e7ce226e92491d60430e86f8f15cda0161ed71893fb4a9e3a1"),
hexEncPubkey("36d0e7e5b7734f98c6183eeeb8ac5130a85e910a925311a19c4941b1290f945d4fc3996b12ef4966960b6fa0fb29b1604f83a0f81bd5fd6398d2e1a22e46af0c"),
hexEncPubkey("7d307d8acb4a561afa23bdf0bd945d35c90245e26345ec3a1f9f7df354222a7cdcb81339c9ed6744526c27a1a0c8d10857e98df942fa433602facac71ac68a31"),
hexEncPubkey("d97bf55f88c83fae36232661af115d66ca600fc4bd6d1fb35ff9bb4dad674c02cf8c8d05f317525b5522250db58bb1ecafb7157392bf5aa61b178c61f098d995"),
hexEncPubkey("7045d678f1f9eb7a4613764d17bd5698796494d0bf977b16f2dbc272b8a0f7858a60805c022fc3d1fe4f31c37e63cdaca0416c0d053ef48a815f8b19121605e0"),
hexEncPubkey("14e1f21418d445748de2a95cd9a8c3b15b506f86a0acabd8af44bb968ce39885b19c8822af61b3dd58a34d1f265baec30e3ae56149dc7d2aa4a538f7319f69c8"),
hexEncPubkey("b9453d78281b66a4eac95a1546017111eaaa5f92a65d0de10b1122940e92b319728a24edf4dec6acc412321b1c95266d39c7b3a5d265c629c3e49a65fb022c09"),
hexEncPubkey("e8a49248419e3824a00d86af422f22f7366e2d4922b304b7169937616a01d9d6fa5abf5cc01061a352dc866f48e1fa2240dbb453d872b1d7be62bdfc1d5e248c"),
hexEncPubkey("bebcff24b52362f30e0589ee573ce2d86f073d58d18e6852a592fa86ceb1a6c9b96d7fb9ec7ed1ed98a51b6743039e780279f6bb49d0a04327ac7a182d9a56f6"),
hexEncPubkey("d0835e5a4291db249b8d2fca9f503049988180c7d247bedaa2cf3a1bad0a76709360a85d4f9a1423b2cbc82bb4d94b47c0cde20afc430224834c49fe312a9ae3"),
hexEncPubkey("6b087fe2a2da5e4f0b0f4777598a4a7fb66bf77dbd5bfc44e8a7eaa432ab585a6e226891f56a7d4f5ed11a7c57b90f1661bba1059590ca4267a35801c2802913"),
hexEncPubkey("d901e5bde52d1a0f4ddf010a686a53974cdae4ebe5c6551b3c37d6b6d635d38d5b0e5f80bc0186a2c7809dbf3a42870dd09643e68d32db896c6da8ba734579e7"),
hexEncPubkey("96419fb80efae4b674402bb969ebaab86c1274f29a83a311e24516d36cdf148fe21754d46c97688cdd7468f24c08b13e4727c29263393638a3b37b99ff60ebca"),
hexEncPubkey("7b9c1889ae916a5d5abcdfb0aaedcc9c6f9eb1c1a4f68d0c2d034fe79ac610ce917c3abc670744150fa891bfcd8ab14fed6983fca964de920aa393fa7b326748"),
hexEncPubkey("7a369b2b8962cc4c65900be046482fbf7c14f98a135bbbae25152c82ad168fb2097b3d1429197cf46d3ce9fdeb64808f908a489cc6019725db040060fdfe5405"),
hexEncPubkey("47bcae48288da5ecc7f5058dfa07cf14d89d06d6e449cb946e237aa6652ea050d9f5a24a65efdc0013ccf232bf88670979eddef249b054f63f38da9d7796dbd8"),
},
254: {
hexEncPubkey("099739d7abc8abd38ecc7a816c521a1168a4dbd359fa7212a5123ab583ffa1cf485a5fed219575d6475dbcdd541638b2d3631a6c7fce7474e7fe3cba1d4d5853"),
hexEncPubkey("c2b01603b088a7182d0cf7ef29fb2b04c70acb320fccf78526bf9472e10c74ee70b3fcfa6f4b11d167bd7d3bc4d936b660f2c9bff934793d97cb21750e7c3d31"),
hexEncPubkey("20e4d8f45f2f863e94b45548c1ef22a11f7d36f263e4f8623761e05a64c4572379b000a52211751e2561b0f14f4fc92dd4130410c8ccc71eb4f0e95a700d4ca9"),
hexEncPubkey("27f4a16cc085e72d86e25c98bd2eca173eaaee7565c78ec5a52e9e12b2211f35de81b5b45e9195de2ebfe29106742c59112b951a04eb7ae48822911fc1f9389e"),
hexEncPubkey("55db5ee7d98e7f0b1c3b9d5be6f2bc619a1b86c3cdd513160ad4dcf267037a5fffad527ac15d50aeb32c59c13d1d4c1e567ebbf4de0d25236130c8361f9aac63"),
hexEncPubkey("883df308b0130fc928a8559fe50667a0fff80493bc09685d18213b2db241a3ad11310ed86b0ef662b3ce21fc3d9aa7f3fc24b8d9afe17c7407e9afd3345ae548"),
hexEncPubkey("c7af968cc9bc8200c3ee1a387405f7563be1dce6710a3439f42ea40657d0eae9d2b3c16c42d779605351fcdece4da637b9804e60ca08cfb89aec32c197beffa6"),
hexEncPubkey("3e66f2b788e3ff1d04106b80597915cd7afa06c405a7ae026556b6e583dca8e05cfbab5039bb9a1b5d06083ffe8de5780b1775550e7218f5e98624bf7af9a0a8"),
hexEncPubkey("4fc7f53764de3337fdaec0a711d35d3a923e72fa65025444d12230b3552ed43d9b2d1ad08ccb11f2d50c58809e6dd74dde910e195294fca3b47ae5a3967cc479"),
hexEncPubkey("bafdfdcf6ccaa989436752fa97c77477b6baa7deb374b16c095492c529eb133e8e2f99e1977012b64767b9d34b2cf6d2048ed489bd822b5139b523f6a423167b"),
hexEncPubkey("7f5d78008a4312fe059104ce80202c82b8915c2eb4411c6b812b16f7642e57c00f2c9425121f5cbac4257fe0b3e81ef5dea97ea2dbaa98f6a8b6fd4d1e5980bb"),
hexEncPubkey("598c37fe78f922751a052f463aeb0cb0bc7f52b7c2a4cf2da72ec0931c7c32175d4165d0f8998f7320e87324ac3311c03f9382a5385c55f0407b7a66b2acd864"),
hexEncPubkey("f758c4136e1c148777a7f3275a76e2db0b2b04066fd738554ec398c1c6cc9fb47e14a3b4c87bd47deaeab3ffd2110514c3855685a374794daff87b605b27ee2e"),
hexEncPubkey("0307bb9e4fd865a49dcf1fe4333d1b944547db650ab580af0b33e53c4fef6c789531110fac801bbcbce21fc4d6f61b6d5b24abdf5b22e3030646d579f6dca9c2"),
hexEncPubkey("82504b6eb49bb2c0f91a7006ce9cefdbaf6df38706198502c2e06601091fc9dc91e4f15db3410d45c6af355bc270b0f268d3dff560f956985c7332d4b10bd1ed"),
hexEncPubkey("b39b5b677b45944ceebe76e76d1f051de2f2a0ec7b0d650da52135743e66a9a5dba45f638258f9a7545d9a790c7fe6d3fdf82c25425c7887323e45d27d06c057"),
},
255: {
hexEncPubkey("5c4d58d46e055dd1f093f81ee60a675e1f02f54da6206720adee4dccef9b67a31efc5c2a2949c31a04ee31beadc79aba10da31440a1f9ff2a24093c63c36d784"),
hexEncPubkey("ea72161ffdd4b1e124c7b93b0684805f4c4b58d617ed498b37a145c670dbc2e04976f8785583d9c805ffbf343c31d492d79f841652bbbd01b61ed85640b23495"),
hexEncPubkey("51caa1d93352d47a8e531692a3612adac1e8ac68d0a200d086c1c57ae1e1a91aa285ab242e8c52ef9d7afe374c9485b122ae815f1707b875569d0433c1c3ce85"),
hexEncPubkey("c08397d5751b47bd3da044b908be0fb0e510d3149574dff7aeab33749b023bb171b5769990fe17469dbebc100bc150e798aeda426a2dcc766699a225fddd75c6"),
hexEncPubkey("0222c1c194b749736e593f937fad67ee348ac57287a15c7e42877aa38a9b87732a408bca370f812efd0eedbff13e6d5b854bf3ba1dec431a796ed47f32552b09"),
hexEncPubkey("03d859cd46ef02d9bfad5268461a6955426845eef4126de6be0fa4e8d7e0727ba2385b78f1a883a8239e95ebb814f2af8379632c7d5b100688eebc5841209582"),
hexEncPubkey("64d5004b7e043c39ff0bd10cb20094c287721d5251715884c280a612b494b3e9e1c64ba6f67614994c7d969a0d0c0295d107d53fc225d47c44c4b82852d6f960"),
hexEncPubkey("b0a5eefb2dab6f786670f35bf9641eefe6dd87fd3f1362bcab4aaa792903500ab23d88fae68411372e0813b057535a601d46e454323745a948017f6063a47b1f"),
hexEncPubkey("0cc6df0a3433d448b5684d2a3ffa9d1a825388177a18f44ad0008c7bd7702f1ec0fc38b83506f7de689c3b6ecb552599927e29699eed6bb867ff08f80068b287"),
hexEncPubkey("50772f7b8c03a4e153355fbbf79c8a80cf32af656ff0c7873c99911099d04a0dae0674706c357e0145ad017a0ade65e6052cb1b0d574fcd6f67da3eee0ace66b"),
hexEncPubkey("1ae37829c9ef41f8b508b82259ebac76b1ed900d7a45c08b7970f25d2d48ddd1829e2f11423a18749940b6dab8598c6e416cef0efd47e46e51f29a0bc65b37cd"),
hexEncPubkey("ba973cab31c2af091fc1644a93527d62b2394999e2b6ccbf158dd5ab9796a43d408786f1803ef4e29debfeb62fce2b6caa5ab2b24d1549c822a11c40c2856665"),
hexEncPubkey("bc413ad270dd6ea25bddba78f3298b03b8ba6f8608ac03d06007d4116fa78ef5a0cfe8c80155089382fc7a193243ee5500082660cb5d7793f60f2d7d18650964"),
hexEncPubkey("5a6a9ef07634d9eec3baa87c997b529b92652afa11473dfee41ef7037d5c06e0ddb9fe842364462d79dd31cff8a59a1b8d5bc2b810dea1d4cbbd3beb80ecec83"),
hexEncPubkey("f492c6ee2696d5f682f7f537757e52744c2ae560f1090a07024609e903d334e9e174fc01609c5a229ddbcac36c9d21adaf6457dab38a25bfd44f2f0ee4277998"),
hexEncPubkey("459e4db99298cb0467a90acee6888b08bb857450deac11015cced5104853be5adce5b69c740968bc7f931495d671a70cad9f48546d7cd203357fe9af0e8d2164"),
},
256: {
hexEncPubkey("a8593af8a4aef7b806b5197612017951bac8845a1917ca9a6a15dd6086d608505144990b245785c4cd2d67a295701c7aac2aa18823fb0033987284b019656268"),
hexEncPubkey("d2eebef914928c3aad77fc1b2a495f52d2294acf5edaa7d8a530b540f094b861a68fe8348a46a7c302f08ab609d85912a4968eacfea0740847b29421b4795d9e"),
hexEncPubkey("b14bfcb31495f32b650b63cf7d08492e3e29071fdc73cf2da0da48d4b191a70ba1a65f42ad8c343206101f00f8a48e8db4b08bf3f622c0853e7323b250835b91"),
hexEncPubkey("7feaee0d818c03eb30e4e0bf03ade0f3c21ca38e938a761aa1781cf70bda8cc5cd631a6cc53dd44f1d4a6d3e2dae6513c6c66ee50cb2f0e9ad6f7e319b309fd9"),
hexEncPubkey("4ca3b657b139311db8d583c25dd5963005e46689e1317620496cc64129c7f3e52870820e0ec7941d28809311df6db8a2867bbd4f235b4248af24d7a9c22d1232"),
hexEncPubkey("1181defb1d16851d42dd951d84424d6bd1479137f587fa184d5a8152be6b6b16ed08bcdb2c2ed8539bcde98c80c432875f9f724737c316a2bd385a39d3cab1d8"),
hexEncPubkey("d9dd818769fa0c3ec9f553c759b92476f082817252a04a47dc1777740b1731d280058c66f982812f173a294acf4944a85ba08346e2de153ba3ba41ce8a62cb64"),
hexEncPubkey("bd7c4f8a9e770aa915c771b15e107ca123d838762da0d3ffc53aa6b53e9cd076cffc534ec4d2e4c334c683f1f5ea72e0e123f6c261915ed5b58ac1b59f003d88"),
hexEncPubkey("3dd5739c73649d510456a70e9d6b46a855864a4a3f744e088fd8c8da11b18e4c9b5f2d7da50b1c147b2bae5ca9609ae01f7a3cdea9dce34f80a91d29cd82f918"),
hexEncPubkey("f0d7df1efc439b4bcc0b762118c1cfa99b2a6143a9f4b10e3c9465125f4c9fca4ab88a2504169bbcad65492cf2f50da9dd5d077c39574a944f94d8246529066b"),
hexEncPubkey("dd598b9ba441448e5fb1a6ec6c5f5aa9605bad6e223297c729b1705d11d05f6bfd3d41988b694681ae69bb03b9a08bff4beab5596503d12a39bffb5cd6e94c7c"),
hexEncPubkey("3fce284ac97e567aebae681b15b7a2b6df9d873945536335883e4bbc26460c064370537f323fd1ada828ea43154992d14ac0cec0940a2bd2a3f42ec156d60c83"),
hexEncPubkey("7c8dfa8c1311cb14fb29a8ac11bca23ecc115e56d9fcf7b7ac1db9066aa4eb39f8b1dabf46e192a65be95ebfb4e839b5ab4533fef414921825e996b210dd53bd"),
hexEncPubkey("cafa6934f82120456620573d7f801390ed5e16ed619613a37e409e44ab355ef755e83565a913b48a9466db786f8d4fbd590bfec474c2524d4a2608d4eafd6abd"),
hexEncPubkey("9d16600d0dd310d77045769fed2cb427f32db88cd57d86e49390c2ba8a9698cfa856f775be2013237226e7bf47b248871cf865d23015937d1edeb20db5e3e760"),
hexEncPubkey("17be6b6ba54199b1d80eff866d348ea11d8a4b341d63ad9a6681d3ef8a43853ac564d153eb2a8737f0afc9ab320f6f95c55aa11aaa13bbb1ff422fd16bdf8188"),
},
},
}
type preminedTestnet struct {
target encPubkey
targetSha enode.ID // sha3(target)
dists [hashBits + 1][]encPubkey
}
func (tn *preminedTestnet) self() *enode.Node {
return nullNode
}
func (tn *preminedTestnet) findnode(toid enode.ID, toaddr *net.UDPAddr, target encPubkey) ([]*node, error) {
// current log distance is encoded in port number
// fmt.Println("findnode query at dist", toaddr.Port)
if toaddr.Port == 0 {
panic("query to node at distance 0")
}
next := toaddr.Port - 1
var result []*node
for i, ekey := range tn.dists[toaddr.Port] {
key, _ := decodePubkey(ekey)
node := wrapNode(enode.NewV4(key, net.ParseIP("127.0.0.1"), i, next))
result = append(result, node)
}
return result, nil
}
func (*preminedTestnet) close() {}
func (*preminedTestnet) ping(toid enode.ID, toaddr *net.UDPAddr) error { return nil }
var _ = (*preminedTestnet).mine // avoid linter warning about mine being dead code.
// mine generates a testnet struct literal with nodes at
// various distances to the given target.
func (tn *preminedTestnet) mine(target encPubkey) {
tn.target = target
tn.targetSha = tn.target.id()
found := 0
for found < bucketSize*10 {
k := newkey()
key := encodePubkey(&k.PublicKey)
ld := enode.LogDist(tn.targetSha, key.id())
if len(tn.dists[ld]) < bucketSize {
tn.dists[ld] = append(tn.dists[ld], key)
fmt.Println("found ID with ld", ld)
found++
}
}
fmt.Println("&preminedTestnet{")
fmt.Printf(" target: %#v,\n", tn.target)
fmt.Printf(" targetSha: %#v,\n", tn.targetSha)
fmt.Printf(" dists: [%d][]encPubkey{\n", len(tn.dists))
for ld, ns := range tn.dists {
if len(ns) == 0 {
continue
}
fmt.Printf(" %d: []encPubkey{\n", ld)
for _, n := range ns {
fmt.Printf(" hexEncPubkey(\"%x\"),\n", n[:])
}
fmt.Println(" },")
}
fmt.Println(" },")
fmt.Println("}")
}
// gen wraps quick.Value so it's easier to use.
// it generates a random value of the given value's type.
func gen(typ interface{}, rand *rand.Rand) interface{} {

View File

@ -17,12 +17,16 @@
package discover
import (
"crypto/ecdsa"
"encoding/hex"
"fmt"
"math/rand"
"net"
"sort"
"sync"
"github.com/ethereum/go-ethereum/crypto"
"github.com/ethereum/go-ethereum/log"
"github.com/ethereum/go-ethereum/p2p/enode"
"github.com/ethereum/go-ethereum/p2p/enr"
)
@ -37,7 +41,7 @@ func init() {
func newTestTable(t transport) (*Table, *enode.DB) {
db, _ := enode.OpenDB("")
tab, _ := newTable(t, db, nil)
tab, _ := newTable(t, db, nil, log.Root())
return tab, db
}
@ -108,26 +112,30 @@ func newPingRecorder() *pingRecorder {
}
}
func (t *pingRecorder) self() *enode.Node {
func (t *pingRecorder) Self() *enode.Node {
return nullNode
}
func (t *pingRecorder) findnode(toid enode.ID, toaddr *net.UDPAddr, target encPubkey) ([]*node, error) {
return nil, nil
}
func (t *pingRecorder) ping(toid enode.ID, toaddr *net.UDPAddr) error {
func (t *pingRecorder) ping(n *enode.Node) error {
t.mu.Lock()
defer t.mu.Unlock()
t.pinged[toid] = true
if t.dead[toid] {
t.pinged[n.ID()] = true
if t.dead[n.ID()] {
return errTimeout
} else {
return nil
}
}
func (t *pingRecorder) lookupSelf() []*enode.Node {
return nil
}
func (t *pingRecorder) lookupRandom() []*enode.Node {
return nil
}
func (t *pingRecorder) close() {}
func hasDuplicates(slice []*node) bool {
@ -145,14 +153,21 @@ func hasDuplicates(slice []*node) bool {
}
func sortedByDistanceTo(distbase enode.ID, slice []*node) bool {
var last enode.ID
for i, e := range slice {
if i > 0 && enode.DistCmp(distbase, e.ID(), last) < 0 {
return false
return sort.SliceIsSorted(slice, func(i, j int) bool {
return enode.DistCmp(distbase, slice[i].ID(), slice[j].ID()) < 0
})
}
last = e.ID()
func hexEncPrivkey(h string) *ecdsa.PrivateKey {
b, err := hex.DecodeString(h)
if err != nil {
panic(err)
}
return true
key, err := crypto.ToECDSA(b)
if err != nil {
panic(err)
}
return key
}
func hexEncPubkey(h string) (ret encPubkey) {

View File

@ -20,8 +20,10 @@ import (
"bytes"
"container/list"
"crypto/ecdsa"
crand "crypto/rand"
"errors"
"fmt"
"io"
"net"
"sync"
"time"
@ -63,15 +65,15 @@ const (
// RPC packet types
const (
pingPacket = iota + 1 // zero is 'reserved'
pongPacket
findnodePacket
neighborsPacket
p_pingV4 = iota + 1 // zero is 'reserved'
p_pongV4
p_findnodeV4
p_neighborsV4
)
// RPC request structures
type (
ping struct {
pingV4 struct {
senderKey *ecdsa.PublicKey // filled in by preverify
Version uint
@ -81,8 +83,8 @@ type (
Rest []rlp.RawValue `rlp:"tail"`
}
// pong is the reply to ping.
pong struct {
// pongV4 is the reply to pingV4.
pongV4 struct {
// This field should mirror the UDP envelope address
// of the ping packet, which provides a way to discover the
// the external address (after NAT).
@ -94,16 +96,16 @@ type (
Rest []rlp.RawValue `rlp:"tail"`
}
// findnode is a query for nodes close to the given target.
findnode struct {
// findnodeV4 is a query for nodes close to the given target.
findnodeV4 struct {
Target encPubkey
Expiration uint64
// Ignore additional fields (for forward compatibility).
Rest []rlp.RawValue `rlp:"tail"`
}
// reply to findnode
neighbors struct {
// neighborsV4 is the reply to findnodeV4.
neighborsV4 struct {
Nodes []rpcNode
Expiration uint64
// Ignore additional fields (for forward compatibility).
@ -124,6 +126,16 @@ type (
}
)
// packet is implemented by all v4 protocol messages.
type packetV4 interface {
// preverify checks whether the packet is valid and should be handled at all.
preverify(t *UDPv4, from *net.UDPAddr, fromID enode.ID, fromKey encPubkey) error
// handle handles the packet.
handle(t *UDPv4, from *net.UDPAddr, fromID enode.ID, mac []byte)
// name returns the name of the packet for logging purposes.
name() string
}
func makeEndpoint(addr *net.UDPAddr, tcpPort uint16) rpcEndpoint {
ip := net.IP{}
if ip4 := addr.IP.To4(); ip4 != nil {
@ -134,7 +146,7 @@ func makeEndpoint(addr *net.UDPAddr, tcpPort uint16) rpcEndpoint {
return rpcEndpoint{IP: ip, UDP: uint16(addr.Port), TCP: tcpPort}
}
func (t *udp) nodeFromRPC(sender *net.UDPAddr, rn rpcNode) (*node, error) {
func (t *UDPv4) nodeFromRPC(sender *net.UDPAddr, rn rpcNode) (*node, error) {
if rn.UDP <= 1024 {
return nil, errors.New("low port")
}
@ -162,31 +174,16 @@ func nodeToRPC(n *node) rpcNode {
return rpcNode{ID: ekey, IP: n.IP(), UDP: uint16(n.UDP()), TCP: uint16(n.TCP())}
}
// packet is implemented by all protocol messages.
type packet interface {
// preverify checks whether the packet is valid and should be handled at all.
preverify(t *udp, from *net.UDPAddr, fromID enode.ID, fromKey encPubkey) error
// handle handles the packet.
handle(t *udp, from *net.UDPAddr, fromID enode.ID, mac []byte)
// name returns the name of the packet for logging purposes.
name() string
}
type conn interface {
ReadFromUDP(b []byte) (n int, addr *net.UDPAddr, err error)
WriteToUDP(b []byte, addr *net.UDPAddr) (n int, err error)
Close() error
LocalAddr() net.Addr
}
// udp implements the discovery v4 UDP wire protocol.
type udp struct {
conn conn
// UDPv4 implements the v4 wire protocol.
type UDPv4 struct {
conn UDPConn
log log.Logger
netrestrict *netutil.Netlist
priv *ecdsa.PrivateKey
localNode *enode.LocalNode
db *enode.DB
tab *Table
closeOnce sync.Once
wg sync.WaitGroup
addReplyMatcher chan *replyMatcher
@ -229,41 +226,15 @@ type reply struct {
from enode.ID
ip net.IP
ptype byte
data packet
data packetV4
// loop indicates whether there was
// a matching request by sending on this channel.
matched chan<- bool
}
// ReadPacket is sent to the unhandled channel when it could not be processed
type ReadPacket struct {
Data []byte
Addr *net.UDPAddr
}
// Config holds Table-related settings.
type Config struct {
// These settings are required and configure the UDP listener:
PrivateKey *ecdsa.PrivateKey
// These settings are optional:
NetRestrict *netutil.Netlist // network whitelist
Bootnodes []*enode.Node // list of bootstrap nodes
Unhandled chan<- ReadPacket // unhandled packets are sent on this channel
}
// ListenUDP returns a new table that listens for UDP packets on laddr.
func ListenUDP(c conn, ln *enode.LocalNode, cfg Config) (*Table, error) {
tab, _, err := newUDP(c, ln, cfg)
if err != nil {
return nil, err
}
return tab, nil
}
func newUDP(c conn, ln *enode.LocalNode, cfg Config) (*Table, *udp, error) {
udp := &udp{
func ListenV4(c UDPConn, ln *enode.LocalNode, cfg Config) (*UDPv4, error) {
t := &UDPv4{
conn: c,
priv: cfg.PrivateKey,
netrestrict: cfg.NetRestrict,
@ -272,50 +243,190 @@ func newUDP(c conn, ln *enode.LocalNode, cfg Config) (*Table, *udp, error) {
closing: make(chan struct{}),
gotreply: make(chan reply),
addReplyMatcher: make(chan *replyMatcher),
log: cfg.Log,
}
tab, err := newTable(udp, ln.Database(), cfg.Bootnodes)
if t.log == nil {
t.log = log.Root()
}
tab, err := newTable(t, ln.Database(), cfg.Bootnodes, t.log)
if err != nil {
return nil, nil, err
return nil, err
}
udp.tab = tab
t.tab = tab
udp.wg.Add(2)
go udp.loop()
go udp.readLoop(cfg.Unhandled)
return udp.tab, udp, nil
t.wg.Add(2)
go t.loop()
go t.readLoop(cfg.Unhandled)
return t, nil
}
func (t *udp) self() *enode.Node {
// Self returns the local node.
func (t *UDPv4) Self() *enode.Node {
return t.localNode.Node()
}
func (t *udp) close() {
// Close shuts down the socket and aborts any running queries.
func (t *UDPv4) Close() {
t.closeOnce.Do(func() {
close(t.closing)
t.conn.Close()
t.wg.Wait()
t.tab.close()
})
}
func (t *udp) ourEndpoint() rpcEndpoint {
n := t.self()
// ReadRandomNodes reads random nodes from the local table.
func (t *UDPv4) ReadRandomNodes(buf []*enode.Node) int {
return t.tab.ReadRandomNodes(buf)
}
// LookupRandom finds random nodes in the network.
func (t *UDPv4) LookupRandom() []*enode.Node {
if t.tab.len() == 0 {
// All nodes were dropped, refresh. The very first query will hit this
// case and run the bootstrapping logic.
<-t.tab.refresh()
}
return t.lookupRandom()
}
func (t *UDPv4) LookupPubkey(key *ecdsa.PublicKey) []*enode.Node {
if t.tab.len() == 0 {
// All nodes were dropped, refresh. The very first query will hit this
// case and run the bootstrapping logic.
<-t.tab.refresh()
}
return unwrapNodes(t.lookup(encodePubkey(key)))
}
func (t *UDPv4) lookupRandom() []*enode.Node {
var target encPubkey
crand.Read(target[:])
return unwrapNodes(t.lookup(target))
}
func (t *UDPv4) lookupSelf() []*enode.Node {
return unwrapNodes(t.lookup(encodePubkey(&t.priv.PublicKey)))
}
// lookup performs a network search for nodes close to the given target. It approaches the
// target by querying nodes that are closer to it on each iteration. The given target does
// not need to be an actual node identifier.
func (t *UDPv4) lookup(targetKey encPubkey) []*node {
var (
target = enode.ID(crypto.Keccak256Hash(targetKey[:]))
asked = make(map[enode.ID]bool)
seen = make(map[enode.ID]bool)
reply = make(chan []*node, alpha)
pendingQueries = 0
result *nodesByDistance
)
// Don't query further if we hit ourself.
// Unlikely to happen often in practice.
asked[t.Self().ID()] = true
// Generate the initial result set.
t.tab.mutex.Lock()
result = t.tab.closest(target, bucketSize, false)
t.tab.mutex.Unlock()
for {
// ask the alpha closest nodes that we haven't asked yet
for i := 0; i < len(result.entries) && pendingQueries < alpha; i++ {
n := result.entries[i]
if !asked[n.ID()] {
asked[n.ID()] = true
pendingQueries++
go t.lookupWorker(n, targetKey, reply)
}
}
if pendingQueries == 0 {
// we have asked all closest nodes, stop the search
break
}
select {
case nodes := <-reply:
for _, n := range nodes {
if n != nil && !seen[n.ID()] {
seen[n.ID()] = true
result.push(n, bucketSize)
}
}
case <-t.tab.closeReq:
return nil // shutdown, no need to continue.
}
pendingQueries--
}
return result.entries
}
func (t *UDPv4) lookupWorker(n *node, targetKey encPubkey, reply chan<- []*node) {
fails := t.db.FindFails(n.ID(), n.IP())
r, err := t.findnode(n.ID(), n.addr(), targetKey)
if err == errClosed {
// Avoid recording failures on shutdown.
reply <- nil
return
} else if len(r) == 0 {
fails++
t.db.UpdateFindFails(n.ID(), n.IP(), fails)
t.log.Trace("Findnode failed", "id", n.ID(), "failcount", fails, "err", err)
if fails >= maxFindnodeFailures {
t.log.Trace("Too many findnode failures, dropping", "id", n.ID(), "failcount", fails)
t.tab.delete(n)
}
} else if fails > 0 {
t.db.UpdateFindFails(n.ID(), n.IP(), fails-1)
}
// Grab as many nodes as possible. Some of them might not be alive anymore, but we'll
// just remove those again during revalidation.
for _, n := range r {
t.tab.addSeenNode(n)
}
reply <- r
}
// Resolve searches for a specific node with the given ID.
// It returns nil if the node could not be found.
func (t *UDPv4) Resolve(n *enode.Node) *enode.Node {
// If the node is present in the local table, no
// network interaction is required.
if intab := t.tab.Resolve(n); intab != nil {
return intab
}
// Otherwise, do a network lookup.
hash := n.ID()
result := t.LookupPubkey(n.Pubkey())
for _, n := range result {
if n.ID() == hash {
return n
}
}
return nil
}
func (t *UDPv4) ourEndpoint() rpcEndpoint {
n := t.Self()
a := &net.UDPAddr{IP: n.IP(), Port: n.UDP()}
return makeEndpoint(a, uint16(n.TCP()))
}
// ping sends a ping message to the given node and waits for a reply.
func (t *udp) ping(toid enode.ID, toaddr *net.UDPAddr) error {
return <-t.sendPing(toid, toaddr, nil)
func (t *UDPv4) ping(n *enode.Node) error {
return <-t.sendPing(n.ID(), &net.UDPAddr{IP: n.IP(), Port: n.UDP()}, nil)
}
// sendPing sends a ping message to the given node and invokes the callback
// when the reply arrives.
func (t *udp) sendPing(toid enode.ID, toaddr *net.UDPAddr, callback func()) <-chan error {
req := &ping{
func (t *UDPv4) sendPing(toid enode.ID, toaddr *net.UDPAddr, callback func()) <-chan error {
req := &pingV4{
Version: 4,
From: t.ourEndpoint(),
To: makeEndpoint(toaddr, 0), // TODO: maybe use known TCP port from DB
Expiration: uint64(time.Now().Add(expiration).Unix()),
}
packet, hash, err := encodePacket(t.priv, pingPacket, req)
packet, hash, err := t.encode(t.priv, p_pingV4, req)
if err != nil {
errc := make(chan error, 1)
errc <- err
@ -323,8 +434,8 @@ func (t *udp) sendPing(toid enode.ID, toaddr *net.UDPAddr, callback func()) <-ch
}
// Add a matcher for the reply to the pending reply queue. Pongs are matched if they
// reference the ping we're about to send.
errc := t.pending(toid, toaddr.IP, pongPacket, func(p interface{}) (matched bool, requestDone bool) {
matched = bytes.Equal(p.(*pong).ReplyTok, hash)
errc := t.pending(toid, toaddr.IP, p_pongV4, func(p interface{}) (matched bool, requestDone bool) {
matched = bytes.Equal(p.(*pongV4).ReplyTok, hash)
if matched && callback != nil {
callback()
}
@ -338,11 +449,11 @@ func (t *udp) sendPing(toid enode.ID, toaddr *net.UDPAddr, callback func()) <-ch
// findnode sends a findnode request to the given node and waits until
// the node has sent up to k neighbors.
func (t *udp) findnode(toid enode.ID, toaddr *net.UDPAddr, target encPubkey) ([]*node, error) {
func (t *UDPv4) findnode(toid enode.ID, toaddr *net.UDPAddr, target encPubkey) ([]*node, error) {
// If we haven't seen a ping from the destination node for a while, it won't remember
// our endpoint proof and reject findnode. Solicit a ping first.
if time.Since(t.db.LastPingReceived(toid, toaddr.IP)) > bondExpiration {
t.ping(toid, toaddr)
<-t.sendPing(toid, toaddr, nil)
// Wait for them to ping back and process our pong.
time.Sleep(respTimeout)
}
@ -351,20 +462,20 @@ func (t *udp) findnode(toid enode.ID, toaddr *net.UDPAddr, target encPubkey) ([]
// active until enough nodes have been received.
nodes := make([]*node, 0, bucketSize)
nreceived := 0
errc := t.pending(toid, toaddr.IP, neighborsPacket, func(r interface{}) (matched bool, requestDone bool) {
reply := r.(*neighbors)
errc := t.pending(toid, toaddr.IP, p_neighborsV4, func(r interface{}) (matched bool, requestDone bool) {
reply := r.(*neighborsV4)
for _, rn := range reply.Nodes {
nreceived++
n, err := t.nodeFromRPC(toaddr, rn)
if err != nil {
log.Trace("Invalid neighbor node received", "ip", rn.IP, "addr", toaddr, "err", err)
t.log.Trace("Invalid neighbor node received", "ip", rn.IP, "addr", toaddr, "err", err)
continue
}
nodes = append(nodes, n)
}
return true, nreceived >= bucketSize
})
t.send(toaddr, toid, findnodePacket, &findnode{
t.send(toaddr, toid, p_findnodeV4, &findnodeV4{
Target: target,
Expiration: uint64(time.Now().Add(expiration).Unix()),
})
@ -373,7 +484,7 @@ func (t *udp) findnode(toid enode.ID, toaddr *net.UDPAddr, target encPubkey) ([]
// pending adds a reply matcher to the pending reply queue.
// see the documentation of type replyMatcher for a detailed explanation.
func (t *udp) pending(id enode.ID, ip net.IP, ptype byte, callback replyMatchFunc) <-chan error {
func (t *UDPv4) pending(id enode.ID, ip net.IP, ptype byte, callback replyMatchFunc) <-chan error {
ch := make(chan error, 1)
p := &replyMatcher{from: id, ip: ip, ptype: ptype, callback: callback, errc: ch}
select {
@ -387,7 +498,7 @@ func (t *udp) pending(id enode.ID, ip net.IP, ptype byte, callback replyMatchFun
// handleReply dispatches a reply packet, invoking reply matchers. It returns
// whether any matcher considered the packet acceptable.
func (t *udp) handleReply(from enode.ID, fromIP net.IP, ptype byte, req packet) bool {
func (t *UDPv4) handleReply(from enode.ID, fromIP net.IP, ptype byte, req packetV4) bool {
matched := make(chan bool, 1)
select {
case t.gotreply <- reply{from, fromIP, ptype, req, matched}:
@ -400,7 +511,7 @@ func (t *udp) handleReply(from enode.ID, fromIP net.IP, ptype byte, req packet)
// loop runs in its own goroutine. it keeps track of
// the refresh timer and the pending reply queue.
func (t *udp) loop() {
func (t *UDPv4) loop() {
defer t.wg.Done()
var (
@ -507,7 +618,7 @@ var (
)
func init() {
p := neighbors{Expiration: ^uint64(0)}
p := neighborsV4{Expiration: ^uint64(0)}
maxSizeNode := rpcNode{IP: make(net.IP, 16), UDP: ^uint16(0), TCP: ^uint16(0)}
for n := 0; ; n++ {
p.Nodes = append(p.Nodes, maxSizeNode)
@ -523,32 +634,32 @@ func init() {
}
}
func (t *udp) send(toaddr *net.UDPAddr, toid enode.ID, ptype byte, req packet) ([]byte, error) {
packet, hash, err := encodePacket(t.priv, ptype, req)
func (t *UDPv4) send(toaddr *net.UDPAddr, toid enode.ID, ptype byte, req packetV4) ([]byte, error) {
packet, hash, err := t.encode(t.priv, ptype, req)
if err != nil {
return hash, err
}
return hash, t.write(toaddr, toid, req.name(), packet)
}
func (t *udp) write(toaddr *net.UDPAddr, toid enode.ID, what string, packet []byte) error {
func (t *UDPv4) write(toaddr *net.UDPAddr, toid enode.ID, what string, packet []byte) error {
_, err := t.conn.WriteToUDP(packet, toaddr)
log.Trace(">> "+what, "id", toid, "addr", toaddr, "err", err)
t.log.Trace(">> "+what, "id", toid, "addr", toaddr, "err", err)
return err
}
func encodePacket(priv *ecdsa.PrivateKey, ptype byte, req interface{}) (packet, hash []byte, err error) {
func (t *UDPv4) encode(priv *ecdsa.PrivateKey, ptype byte, req interface{}) (packet, hash []byte, err error) {
b := new(bytes.Buffer)
b.Write(headSpace)
b.WriteByte(ptype)
if err := rlp.Encode(b, req); err != nil {
log.Error("Can't encode discv4 packet", "err", err)
t.log.Error("Can't encode discv4 packet", "err", err)
return nil, nil, err
}
packet = b.Bytes()
sig, err := crypto.Sign(crypto.Keccak256(packet[headSize:]), priv)
if err != nil {
log.Error("Can't sign discv4 packet", "err", err)
t.log.Error("Can't sign discv4 packet", "err", err)
return nil, nil, err
}
copy(packet[macSize:], sig)
@ -561,7 +672,7 @@ func encodePacket(priv *ecdsa.PrivateKey, ptype byte, req interface{}) (packet,
}
// readLoop runs in its own goroutine. it handles incoming UDP packets.
func (t *udp) readLoop(unhandled chan<- ReadPacket) {
func (t *UDPv4) readLoop(unhandled chan<- ReadPacket) {
defer t.wg.Done()
if unhandled != nil {
defer close(unhandled)
@ -572,11 +683,13 @@ func (t *udp) readLoop(unhandled chan<- ReadPacket) {
nbytes, from, err := t.conn.ReadFromUDP(buf)
if netutil.IsTemporaryError(err) {
// Ignore temporary read errors.
log.Debug("Temporary UDP read error", "err", err)
t.log.Debug("Temporary UDP read error", "err", err)
continue
} else if err != nil {
// Shut down the loop for permament errors.
log.Debug("UDP read error", "err", err)
if err != io.EOF {
t.log.Debug("UDP read error", "err", err)
}
return
}
if t.handlePacket(from, buf[:nbytes]) != nil && unhandled != nil {
@ -588,24 +701,24 @@ func (t *udp) readLoop(unhandled chan<- ReadPacket) {
}
}
func (t *udp) handlePacket(from *net.UDPAddr, buf []byte) error {
packet, fromKey, hash, err := decodePacket(buf)
func (t *UDPv4) handlePacket(from *net.UDPAddr, buf []byte) error {
packet, fromKey, hash, err := decodeV4(buf)
if err != nil {
log.Debug("Bad discv4 packet", "addr", from, "err", err)
t.log.Debug("Bad discv4 packet", "addr", from, "err", err)
return err
}
fromID := fromKey.id()
if err == nil {
err = packet.preverify(t, from, fromID, fromKey)
}
log.Trace("<< "+packet.name(), "id", fromID, "addr", from, "err", err)
t.log.Trace("<< "+packet.name(), "id", fromID, "addr", from, "err", err)
if err == nil {
packet.handle(t, from, fromID, hash)
}
return err
}
func decodePacket(buf []byte) (packet, encPubkey, []byte, error) {
func decodeV4(buf []byte) (packetV4, encPubkey, []byte, error) {
if len(buf) < headSize+1 {
return nil, encPubkey{}, nil, errPacketTooSmall
}
@ -619,16 +732,16 @@ func decodePacket(buf []byte) (packet, encPubkey, []byte, error) {
return nil, fromKey, hash, err
}
var req packet
var req packetV4
switch ptype := sigdata[0]; ptype {
case pingPacket:
req = new(ping)
case pongPacket:
req = new(pong)
case findnodePacket:
req = new(findnode)
case neighborsPacket:
req = new(neighbors)
case p_pingV4:
req = new(pingV4)
case p_pongV4:
req = new(pongV4)
case p_findnodeV4:
req = new(findnodeV4)
case p_neighborsV4:
req = new(neighborsV4)
default:
return nil, fromKey, hash, fmt.Errorf("unknown type: %d", ptype)
}
@ -639,7 +752,7 @@ func decodePacket(buf []byte) (packet, encPubkey, []byte, error) {
// Packet Handlers
func (req *ping) preverify(t *udp, from *net.UDPAddr, fromID enode.ID, fromKey encPubkey) error {
func (req *pingV4) preverify(t *UDPv4, from *net.UDPAddr, fromID enode.ID, fromKey encPubkey) error {
if expired(req.Expiration) {
return errExpired
}
@ -651,9 +764,9 @@ func (req *ping) preverify(t *udp, from *net.UDPAddr, fromID enode.ID, fromKey e
return nil
}
func (req *ping) handle(t *udp, from *net.UDPAddr, fromID enode.ID, mac []byte) {
func (req *pingV4) handle(t *UDPv4, from *net.UDPAddr, fromID enode.ID, mac []byte) {
// Reply.
t.send(from, fromID, pongPacket, &pong{
t.send(from, fromID, p_pongV4, &pongV4{
To: makeEndpoint(from, req.From.TCP),
ReplyTok: mac,
Expiration: uint64(time.Now().Add(expiration).Unix()),
@ -674,26 +787,26 @@ func (req *ping) handle(t *udp, from *net.UDPAddr, fromID enode.ID, mac []byte)
t.localNode.UDPEndpointStatement(from, &net.UDPAddr{IP: req.To.IP, Port: int(req.To.UDP)})
}
func (req *ping) name() string { return "PING/v4" }
func (req *pingV4) name() string { return "PING/v4" }
func (req *pong) preverify(t *udp, from *net.UDPAddr, fromID enode.ID, fromKey encPubkey) error {
func (req *pongV4) preverify(t *UDPv4, from *net.UDPAddr, fromID enode.ID, fromKey encPubkey) error {
if expired(req.Expiration) {
return errExpired
}
if !t.handleReply(fromID, from.IP, pongPacket, req) {
if !t.handleReply(fromID, from.IP, p_pongV4, req) {
return errUnsolicitedReply
}
return nil
}
func (req *pong) handle(t *udp, from *net.UDPAddr, fromID enode.ID, mac []byte) {
func (req *pongV4) handle(t *UDPv4, from *net.UDPAddr, fromID enode.ID, mac []byte) {
t.localNode.UDPEndpointStatement(from, &net.UDPAddr{IP: req.To.IP, Port: int(req.To.UDP)})
t.db.UpdateLastPongReceived(fromID, from.IP, time.Now())
}
func (req *pong) name() string { return "PONG/v4" }
func (req *pongV4) name() string { return "PONG/v4" }
func (req *findnode) preverify(t *udp, from *net.UDPAddr, fromID enode.ID, fromKey encPubkey) error {
func (req *findnodeV4) preverify(t *UDPv4, from *net.UDPAddr, fromID enode.ID, fromKey encPubkey) error {
if expired(req.Expiration) {
return errExpired
}
@ -709,48 +822,48 @@ func (req *findnode) preverify(t *udp, from *net.UDPAddr, fromID enode.ID, fromK
return nil
}
func (req *findnode) handle(t *udp, from *net.UDPAddr, fromID enode.ID, mac []byte) {
func (req *findnodeV4) handle(t *UDPv4, from *net.UDPAddr, fromID enode.ID, mac []byte) {
// Determine closest nodes.
target := enode.ID(crypto.Keccak256Hash(req.Target[:]))
t.tab.mutex.Lock()
closest := t.tab.closest(target, bucketSize).entries
closest := t.tab.closest(target, bucketSize, true).entries
t.tab.mutex.Unlock()
// Send neighbors in chunks with at most maxNeighbors per packet
// to stay below the packet size limit.
p := neighbors{Expiration: uint64(time.Now().Add(expiration).Unix())}
p := neighborsV4{Expiration: uint64(time.Now().Add(expiration).Unix())}
var sent bool
for _, n := range closest {
if netutil.CheckRelayIP(from.IP, n.IP()) == nil {
p.Nodes = append(p.Nodes, nodeToRPC(n))
}
if len(p.Nodes) == maxNeighbors {
t.send(from, fromID, neighborsPacket, &p)
t.send(from, fromID, p_neighborsV4, &p)
p.Nodes = p.Nodes[:0]
sent = true
}
}
if len(p.Nodes) > 0 || !sent {
t.send(from, fromID, neighborsPacket, &p)
t.send(from, fromID, p_neighborsV4, &p)
}
}
func (req *findnode) name() string { return "FINDNODE/v4" }
func (req *findnodeV4) name() string { return "FINDNODE/v4" }
func (req *neighbors) preverify(t *udp, from *net.UDPAddr, fromID enode.ID, fromKey encPubkey) error {
func (req *neighborsV4) preverify(t *UDPv4, from *net.UDPAddr, fromID enode.ID, fromKey encPubkey) error {
if expired(req.Expiration) {
return errExpired
}
if !t.handleReply(fromID, from.IP, neighborsPacket, req) {
if !t.handleReply(fromID, from.IP, p_neighborsV4, req) {
return errUnsolicitedReply
}
return nil
}
func (req *neighbors) handle(t *udp, from *net.UDPAddr, fromID enode.ID, mac []byte) {
func (req *neighborsV4) handle(t *UDPv4, from *net.UDPAddr, fromID enode.ID, mac []byte) {
}
func (req *neighbors) name() string { return "NEIGHBORS/v4" }
func (req *neighborsV4) name() string { return "NEIGHBORS/v4" }
func expired(ts uint64) bool {
return time.Unix(int64(ts), 0).Before(time.Now())

View File

@ -0,0 +1,220 @@
// Copyright 2019 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 discover
import (
"crypto/ecdsa"
"fmt"
"net"
"reflect"
"sort"
"testing"
"github.com/ethereum/go-ethereum/crypto"
"github.com/ethereum/go-ethereum/p2p/enode"
)
func TestUDPv4_Lookup(t *testing.T) {
t.Parallel()
test := newUDPTest(t)
// Lookup on empty table returns no nodes.
targetKey, _ := decodePubkey(lookupTestnet.target)
if results := test.udp.LookupPubkey(targetKey); len(results) > 0 {
t.Fatalf("lookup on empty table returned %d results: %#v", len(results), results)
}
// Seed table with initial node.
fillTable(test.table, []*node{wrapNode(lookupTestnet.node(256, 0))})
// Start the lookup.
resultC := make(chan []*enode.Node, 1)
go func() {
resultC <- test.udp.LookupPubkey(targetKey)
test.close()
}()
// Answer lookup packets.
for done := false; !done; {
done = test.waitPacketOut(func(p packetV4, to *net.UDPAddr, hash []byte) {
n, key := lookupTestnet.nodeByAddr(to)
switch p.(type) {
case *pingV4:
test.packetInFrom(nil, key, to, p_pongV4, &pongV4{Expiration: futureExp, ReplyTok: hash})
case *findnodeV4:
dist := enode.LogDist(n.ID(), lookupTestnet.target.id())
nodes := lookupTestnet.nodesAtDistance(dist - 1)
test.packetInFrom(nil, key, to, p_neighborsV4, &neighborsV4{Expiration: futureExp, Nodes: nodes})
}
})
}
// Verify result nodes.
results := <-resultC
t.Logf("results:")
for _, e := range results {
t.Logf(" ld=%d, %x", enode.LogDist(lookupTestnet.target.id(), e.ID()), e.ID().Bytes())
}
if len(results) != bucketSize {
t.Errorf("wrong number of results: got %d, want %d", len(results), bucketSize)
}
if hasDuplicates(wrapNodes(results)) {
t.Errorf("result set contains duplicate entries")
}
if !sortedByDistanceTo(lookupTestnet.target.id(), wrapNodes(results)) {
t.Errorf("result set not sorted by distance to target")
}
if !reflect.DeepEqual(results, lookupTestnet.closest(bucketSize)) {
t.Errorf("results aren't the closest %d nodes", bucketSize)
}
}
// This is the test network for the Lookup test.
// The nodes were obtained by running lookupTestnet.mine with a random NodeID as target.
var lookupTestnet = &preminedTestnet{
target: hexEncPubkey("5d485bdcbe9bc89314a10ae9231e429d33853e3a8fa2af39f5f827370a2e4185e344ace5d16237491dad41f278f1d3785210d29ace76cd627b9147ee340b1125"),
dists: [257][]*ecdsa.PrivateKey{
251: {
hexEncPrivkey("29738ba0c1a4397d6a65f292eee07f02df8e58d41594ba2be3cf84ce0fc58169"),
hexEncPrivkey("511b1686e4e58a917f7f848e9bf5539d206a68f5ad6b54b552c2399fe7d174ae"),
hexEncPrivkey("d09e5eaeec0fd596236faed210e55ef45112409a5aa7f3276d26646080dcfaeb"),
hexEncPrivkey("c1e20dbbf0d530e50573bd0a260b32ec15eb9190032b4633d44834afc8afe578"),
hexEncPrivkey("ed5f38f5702d92d306143e5d9154fb21819777da39af325ea359f453d179e80b"),
},
252: {
hexEncPrivkey("1c9b1cafbec00848d2c174b858219914b42a7d5c9359b1ca03fd650e8239ae94"),
hexEncPrivkey("e0e1e8db4a6f13c1ffdd3e96b72fa7012293ced187c9dcdcb9ba2af37a46fa10"),
hexEncPrivkey("3d53823e0a0295cb09f3e11d16c1b44d07dd37cec6f739b8df3a590189fe9fb9"),
},
253: {
hexEncPrivkey("2d0511ae9bf590166597eeab86b6f27b1ab761761eaea8965487b162f8703847"),
hexEncPrivkey("6cfbd7b8503073fc3dbdb746a7c672571648d3bd15197ccf7f7fef3d904f53a2"),
hexEncPrivkey("a30599b12827b69120633f15b98a7f6bc9fc2e9a0fd6ae2ebb767c0e64d743ab"),
hexEncPrivkey("14a98db9b46a831d67eff29f3b85b1b485bb12ae9796aea98d91be3dc78d8a91"),
hexEncPrivkey("2369ff1fc1ff8ca7d20b17e2673adc3365c3674377f21c5d9dafaff21fe12e24"),
hexEncPrivkey("9ae91101d6b5048607f41ec0f690ef5d09507928aded2410aabd9237aa2727d7"),
hexEncPrivkey("05e3c59090a3fd1ae697c09c574a36fcf9bedd0afa8fe3946f21117319ca4973"),
hexEncPrivkey("06f31c5ea632658f718a91a1b1b9ae4b7549d7b3bc61cbc2be5f4a439039f3ad"),
},
254: {
hexEncPrivkey("dec742079ec00ff4ec1284d7905bc3de2366f67a0769431fd16f80fd68c58a7c"),
hexEncPrivkey("ff02c8861fa12fbd129d2a95ea663492ef9c1e51de19dcfbbfe1c59894a28d2b"),
hexEncPrivkey("4dded9e4eefcbce4262be4fd9e8a773670ab0b5f448f286ec97dfc8cf681444a"),
hexEncPrivkey("750d931e2a8baa2c9268cb46b7cd851f4198018bed22f4dceb09dd334a2395f6"),
hexEncPrivkey("ce1435a956a98ffec484cd11489c4f165cf1606819ab6b521cee440f0c677e9e"),
hexEncPrivkey("996e7f8d1638be92d7328b4770f47e5420fc4bafecb4324fd33b1f5d9f403a75"),
hexEncPrivkey("ebdc44e77a6cc0eb622e58cf3bb903c3da4c91ca75b447b0168505d8fc308b9c"),
hexEncPrivkey("46bd1eddcf6431bea66fc19ebc45df191c1c7d6ed552dcdc7392885009c322f0"),
},
255: {
hexEncPrivkey("da8645f90826e57228d9ea72aff84500060ad111a5d62e4af831ed8e4b5acfb8"),
hexEncPrivkey("3c944c5d9af51d4c1d43f5d0f3a1a7ef65d5e82744d669b58b5fed242941a566"),
hexEncPrivkey("5ebcde76f1d579eebf6e43b0ffe9157e65ffaa391175d5b9aa988f47df3e33da"),
hexEncPrivkey("97f78253a7d1d796e4eaabce721febcc4550dd68fb11cc818378ba807a2cb7de"),
hexEncPrivkey("a38cd7dc9b4079d1c0406afd0fdb1165c285f2c44f946eca96fc67772c988c7d"),
hexEncPrivkey("d64cbb3ffdf712c372b7a22a176308ef8f91861398d5dbaf326fd89c6eaeef1c"),
hexEncPrivkey("d269609743ef29d6446e3355ec647e38d919c82a4eb5837e442efd7f4218944f"),
hexEncPrivkey("d8f7bcc4a530efde1d143717007179e0d9ace405ddaaf151c4d863753b7fd64c"),
},
256: {
hexEncPrivkey("8c5b422155d33ea8e9d46f71d1ad3e7b24cb40051413ffa1a81cff613d243ba9"),
hexEncPrivkey("937b1af801def4e8f5a3a8bd225a8bcff1db764e41d3e177f2e9376e8dd87233"),
hexEncPrivkey("120260dce739b6f71f171da6f65bc361b5fad51db74cf02d3e973347819a6518"),
hexEncPrivkey("1fa56cf25d4b46c2bf94e82355aa631717b63190785ac6bae545a88aadc304a9"),
hexEncPrivkey("3c38c503c0376f9b4adcbe935d5f4b890391741c764f61b03cd4d0d42deae002"),
hexEncPrivkey("3a54af3e9fa162bc8623cdf3e5d9b70bf30ade1d54cc3abea8659aba6cff471f"),
hexEncPrivkey("6799a02ea1999aefdcbcc4d3ff9544478be7365a328d0d0f37c26bd95ade0cda"),
hexEncPrivkey("e24a7bc9051058f918646b0f6e3d16884b2a55a15553b89bab910d55ebc36116"),
},
},
}
type preminedTestnet struct {
target encPubkey
dists [hashBits + 1][]*ecdsa.PrivateKey
}
func (tn *preminedTestnet) node(dist, index int) *enode.Node {
key := tn.dists[dist][index]
ip := net.IP{127, byte(dist >> 8), byte(dist), byte(index)}
return enode.NewV4(&key.PublicKey, ip, 0, 5000)
}
func (tn *preminedTestnet) nodeByAddr(addr *net.UDPAddr) (*enode.Node, *ecdsa.PrivateKey) {
dist := int(addr.IP[1])<<8 + int(addr.IP[2])
index := int(addr.IP[3])
key := tn.dists[dist][index]
return tn.node(dist, index), key
}
func (tn *preminedTestnet) nodesAtDistance(dist int) []rpcNode {
result := make([]rpcNode, len(tn.dists[dist]))
for i := range result {
result[i] = nodeToRPC(wrapNode(tn.node(dist, i)))
}
return result
}
func (tn *preminedTestnet) closest(n int) (nodes []*enode.Node) {
for d := range tn.dists {
for i := range tn.dists[d] {
nodes = append(nodes, tn.node(d, i))
}
}
sort.Slice(nodes, func(i, j int) bool {
return enode.DistCmp(tn.target.id(), nodes[i].ID(), nodes[j].ID()) < 0
})
return nodes[:n]
}
var _ = (*preminedTestnet).mine // avoid linter warning about mine being dead code.
// mine generates a testnet struct literal with nodes at
// various distances to the network's target.
func (tn *preminedTestnet) mine() {
// Clear existing slices first (useful when re-mining).
for i := range tn.dists {
tn.dists[i] = nil
}
targetSha := tn.target.id()
found, need := 0, 40
for found < need {
k := newkey()
ld := enode.LogDist(targetSha, encodePubkey(&k.PublicKey).id())
if len(tn.dists[ld]) < 8 {
tn.dists[ld] = append(tn.dists[ld], k)
found++
fmt.Printf("found ID with ld %d (%d/%d)\n", ld, found, need)
}
}
fmt.Printf("&preminedTestnet{\n")
fmt.Printf(" target: hexEncPubkey(\"%x\"),\n", tn.target[:])
fmt.Printf(" dists: [%d][]*ecdsa.PrivateKey{\n", len(tn.dists))
for ld, ns := range tn.dists {
if len(ns) == 0 {
continue
}
fmt.Printf(" %d: {\n", ld)
for _, key := range ns {
fmt.Printf(" hexEncPrivkey(\"%x\"),\n", crypto.FromECDSA(key))
}
fmt.Printf(" },\n")
}
fmt.Printf(" },\n")
fmt.Printf("}\n")
}

View File

@ -23,13 +23,10 @@ import (
"encoding/binary"
"encoding/hex"
"errors"
"fmt"
"io"
"math/rand"
"net"
"path/filepath"
"reflect"
"runtime"
"sync"
"testing"
"time"
@ -37,6 +34,8 @@ import (
"github.com/davecgh/go-spew/spew"
"github.com/ethereum/go-ethereum/common"
"github.com/ethereum/go-ethereum/crypto"
"github.com/ethereum/go-ethereum/internal/testlog"
"github.com/ethereum/go-ethereum/log"
"github.com/ethereum/go-ethereum/p2p/enode"
"github.com/ethereum/go-ethereum/rlp"
)
@ -59,7 +58,7 @@ type udpTest struct {
pipe *dgramPipe
table *Table
db *enode.DB
udp *udp
udp *UDPv4
sent [][]byte
localkey, remotekey *ecdsa.PrivateKey
remoteaddr *net.UDPAddr
@ -73,91 +72,93 @@ func newUDPTest(t *testing.T) *udpTest {
remotekey: newkey(),
remoteaddr: &net.UDPAddr{IP: net.IP{10, 0, 1, 99}, Port: 30303},
}
test.db, _ = enode.OpenDB("")
ln := enode.NewLocalNode(test.db, test.localkey)
test.table, test.udp, _ = newUDP(test.pipe, ln, Config{PrivateKey: test.localkey})
test.udp, _ = ListenV4(test.pipe, ln, Config{
PrivateKey: test.localkey,
Log: testlog.Logger(t, log.LvlTrace),
})
test.table = test.udp.tab
// Wait for initial refresh so the table doesn't send unexpected findnode.
<-test.table.initDone
return test
}
func (test *udpTest) close() {
test.table.Close()
test.udp.Close()
test.db.Close()
}
// handles a packet as if it had been sent to the transport.
func (test *udpTest) packetIn(wantError error, ptype byte, data packet) error {
return test.packetInFrom(wantError, test.remotekey, test.remoteaddr, ptype, data)
func (test *udpTest) packetIn(wantError error, ptype byte, data packetV4) {
test.t.Helper()
test.packetInFrom(wantError, test.remotekey, test.remoteaddr, ptype, data)
}
// handles a packet as if it had been sent to the transport by the key/endpoint.
func (test *udpTest) packetInFrom(wantError error, key *ecdsa.PrivateKey, addr *net.UDPAddr, ptype byte, data packet) error {
enc, _, err := encodePacket(key, ptype, data)
func (test *udpTest) packetInFrom(wantError error, key *ecdsa.PrivateKey, addr *net.UDPAddr, ptype byte, data packetV4) {
test.t.Helper()
enc, _, err := test.udp.encode(key, ptype, data)
if err != nil {
return test.errorf("packet (%d) encode error: %v", ptype, err)
test.t.Errorf("packet (%d) encode error: %v", ptype, err)
}
test.sent = append(test.sent, enc)
if err = test.udp.handlePacket(addr, enc); err != wantError {
return test.errorf("error mismatch: got %q, want %q", err, wantError)
test.t.Errorf("error mismatch: got %q, want %q", err, wantError)
}
return nil
}
// waits for a packet to be sent by the transport.
// validate should have type func(*udpTest, X) error, where X is a packet type.
func (test *udpTest) waitPacketOut(validate interface{}) (*net.UDPAddr, []byte, error) {
dgram := test.pipe.waitPacketOut()
p, _, hash, err := decodePacket(dgram.data)
// validate should have type func(X, *net.UDPAddr, []byte), where X is a packet type.
func (test *udpTest) waitPacketOut(validate interface{}) (closed bool) {
test.t.Helper()
dgram, ok := test.pipe.receive()
if !ok {
return true
}
p, _, hash, err := decodeV4(dgram.data)
if err != nil {
return &dgram.to, hash, test.errorf("sent packet decode error: %v", err)
test.t.Errorf("sent packet decode error: %v", err)
return false
}
fn := reflect.ValueOf(validate)
exptype := fn.Type().In(0)
if reflect.TypeOf(p) != exptype {
return &dgram.to, hash, test.errorf("sent packet type mismatch, got: %v, want: %v", reflect.TypeOf(p), exptype)
if !reflect.TypeOf(p).AssignableTo(exptype) {
test.t.Errorf("sent packet type mismatch, got: %v, want: %v", reflect.TypeOf(p), exptype)
return false
}
fn.Call([]reflect.Value{reflect.ValueOf(p)})
return &dgram.to, hash, nil
fn.Call([]reflect.Value{reflect.ValueOf(p), reflect.ValueOf(&dgram.to), reflect.ValueOf(hash)})
return false
}
func (test *udpTest) errorf(format string, args ...interface{}) error {
_, file, line, ok := runtime.Caller(2) // errorf + waitPacketOut
if ok {
file = filepath.Base(file)
} else {
file = "???"
line = 1
}
err := fmt.Errorf(format, args...)
fmt.Printf("\t%s:%d: %v\n", file, line, err)
test.t.Fail()
return err
}
func TestUDP_packetErrors(t *testing.T) {
func TestUDPv4_packetErrors(t *testing.T) {
test := newUDPTest(t)
defer test.close()
test.packetIn(errExpired, pingPacket, &ping{From: testRemote, To: testLocalAnnounced, Version: 4})
test.packetIn(errUnsolicitedReply, pongPacket, &pong{ReplyTok: []byte{}, Expiration: futureExp})
test.packetIn(errUnknownNode, findnodePacket, &findnode{Expiration: futureExp})
test.packetIn(errUnsolicitedReply, neighborsPacket, &neighbors{Expiration: futureExp})
test.packetIn(errExpired, p_pingV4, &pingV4{From: testRemote, To: testLocalAnnounced, Version: 4})
test.packetIn(errUnsolicitedReply, p_pongV4, &pongV4{ReplyTok: []byte{}, Expiration: futureExp})
test.packetIn(errUnknownNode, p_findnodeV4, &findnodeV4{Expiration: futureExp})
test.packetIn(errUnsolicitedReply, p_neighborsV4, &neighborsV4{Expiration: futureExp})
}
func TestUDP_pingTimeout(t *testing.T) {
func TestUDPv4_pingTimeout(t *testing.T) {
t.Parallel()
test := newUDPTest(t)
defer test.close()
key := newkey()
toaddr := &net.UDPAddr{IP: net.ParseIP("1.2.3.4"), Port: 2222}
toid := enode.ID{1, 2, 3, 4}
if err := test.udp.ping(toid, toaddr); err != errTimeout {
node := enode.NewV4(&key.PublicKey, toaddr.IP, 0, toaddr.Port)
if err := test.udp.ping(node); err != errTimeout {
t.Error("expected timeout error, got", err)
}
}
func TestUDP_responseTimeouts(t *testing.T) {
func TestUDPv4_responseTimeouts(t *testing.T) {
t.Parallel()
test := newUDPTest(t)
defer test.close()
@ -229,7 +230,7 @@ func TestUDP_responseTimeouts(t *testing.T) {
}
}
func TestUDP_findnodeTimeout(t *testing.T) {
func TestUDPv4_findnodeTimeout(t *testing.T) {
t.Parallel()
test := newUDPTest(t)
defer test.close()
@ -246,7 +247,7 @@ func TestUDP_findnodeTimeout(t *testing.T) {
}
}
func TestUDP_findnode(t *testing.T) {
func TestUDPv4_findnode(t *testing.T) {
test := newUDPTest(t)
defer test.close()
@ -275,10 +276,10 @@ func TestUDP_findnode(t *testing.T) {
test.table.db.UpdateLastPongReceived(remoteID, test.remoteaddr.IP, time.Now())
// check that closest neighbors are returned.
expected := test.table.closest(testTarget.id(), bucketSize)
test.packetIn(nil, findnodePacket, &findnode{Target: testTarget, Expiration: futureExp})
expected := test.table.closest(testTarget.id(), bucketSize, true)
test.packetIn(nil, p_findnodeV4, &findnodeV4{Target: testTarget, Expiration: futureExp})
waitNeighbors := func(want []*node) {
test.waitPacketOut(func(p *neighbors) {
test.waitPacketOut(func(p *neighborsV4, to *net.UDPAddr, hash []byte) {
if len(p.Nodes) != len(want) {
t.Errorf("wrong number of results: got %d, want %d", len(p.Nodes), bucketSize)
}
@ -301,7 +302,7 @@ func TestUDP_findnode(t *testing.T) {
waitNeighbors(want)
}
func TestUDP_findnodeMultiReply(t *testing.T) {
func TestUDPv4_findnodeMultiReply(t *testing.T) {
test := newUDPTest(t)
defer test.close()
@ -322,7 +323,7 @@ func TestUDP_findnodeMultiReply(t *testing.T) {
// wait for the findnode to be sent.
// after it is sent, the transport is waiting for a reply
test.waitPacketOut(func(p *findnode) {
test.waitPacketOut(func(p *findnodeV4, to *net.UDPAddr, hash []byte) {
if p.Target != testTarget {
t.Errorf("wrong target: got %v, want %v", p.Target, testTarget)
}
@ -339,8 +340,8 @@ func TestUDP_findnodeMultiReply(t *testing.T) {
for i := range list {
rpclist[i] = nodeToRPC(list[i])
}
test.packetIn(nil, neighborsPacket, &neighbors{Expiration: futureExp, Nodes: rpclist[:2]})
test.packetIn(nil, neighborsPacket, &neighbors{Expiration: futureExp, Nodes: rpclist[2:]})
test.packetIn(nil, p_neighborsV4, &neighborsV4{Expiration: futureExp, Nodes: rpclist[:2]})
test.packetIn(nil, p_neighborsV4, &neighborsV4{Expiration: futureExp, Nodes: rpclist[2:]})
// check that the sent neighbors are all returned by findnode
select {
@ -356,46 +357,47 @@ func TestUDP_findnodeMultiReply(t *testing.T) {
}
}
func TestUDP_pingMatch(t *testing.T) {
func TestUDPv4_pingMatch(t *testing.T) {
test := newUDPTest(t)
defer test.close()
randToken := make([]byte, 32)
crand.Read(randToken)
test.packetIn(nil, pingPacket, &ping{From: testRemote, To: testLocalAnnounced, Version: 4, Expiration: futureExp})
test.waitPacketOut(func(*pong) error { return nil })
test.waitPacketOut(func(*ping) error { return nil })
test.packetIn(errUnsolicitedReply, pongPacket, &pong{ReplyTok: randToken, To: testLocalAnnounced, Expiration: futureExp})
test.packetIn(nil, p_pingV4, &pingV4{From: testRemote, To: testLocalAnnounced, Version: 4, Expiration: futureExp})
test.waitPacketOut(func(*pongV4, *net.UDPAddr, []byte) {})
test.waitPacketOut(func(*pingV4, *net.UDPAddr, []byte) {})
test.packetIn(errUnsolicitedReply, p_pongV4, &pongV4{ReplyTok: randToken, To: testLocalAnnounced, Expiration: futureExp})
}
func TestUDP_pingMatchIP(t *testing.T) {
func TestUDPv4_pingMatchIP(t *testing.T) {
test := newUDPTest(t)
defer test.close()
test.packetIn(nil, pingPacket, &ping{From: testRemote, To: testLocalAnnounced, Version: 4, Expiration: futureExp})
test.waitPacketOut(func(*pong) error { return nil })
test.packetIn(nil, p_pingV4, &pingV4{From: testRemote, To: testLocalAnnounced, Version: 4, Expiration: futureExp})
test.waitPacketOut(func(*pongV4, *net.UDPAddr, []byte) {})
_, hash, _ := test.waitPacketOut(func(*ping) error { return nil })
test.waitPacketOut(func(p *pingV4, to *net.UDPAddr, hash []byte) {
wrongAddr := &net.UDPAddr{IP: net.IP{33, 44, 1, 2}, Port: 30000}
test.packetInFrom(errUnsolicitedReply, test.remotekey, wrongAddr, pongPacket, &pong{
test.packetInFrom(errUnsolicitedReply, test.remotekey, wrongAddr, p_pongV4, &pongV4{
ReplyTok: hash,
To: testLocalAnnounced,
Expiration: futureExp,
})
})
}
func TestUDP_successfulPing(t *testing.T) {
func TestUDPv4_successfulPing(t *testing.T) {
test := newUDPTest(t)
added := make(chan *node, 1)
test.table.nodeAddedHook = func(n *node) { added <- n }
defer test.close()
// The remote side sends a ping packet to initiate the exchange.
go test.packetIn(nil, pingPacket, &ping{From: testRemote, To: testLocalAnnounced, Version: 4, Expiration: futureExp})
go test.packetIn(nil, p_pingV4, &pingV4{From: testRemote, To: testLocalAnnounced, Version: 4, Expiration: futureExp})
// the ping is replied to.
test.waitPacketOut(func(p *pong) {
test.waitPacketOut(func(p *pongV4, to *net.UDPAddr, hash []byte) {
pinghash := test.sent[0][:macSize]
if !bytes.Equal(p.ReplyTok, pinghash) {
t.Errorf("got pong.ReplyTok %x, want %x", p.ReplyTok, pinghash)
@ -412,7 +414,7 @@ func TestUDP_successfulPing(t *testing.T) {
})
// remote is unknown, the table pings back.
_, hash, _ := test.waitPacketOut(func(p *ping) error {
test.waitPacketOut(func(p *pingV4, to *net.UDPAddr, hash []byte) {
if !reflect.DeepEqual(p.From, test.udp.ourEndpoint()) {
t.Errorf("got ping.From %#v, want %#v", p.From, test.udp.ourEndpoint())
}
@ -425,9 +427,8 @@ func TestUDP_successfulPing(t *testing.T) {
if !reflect.DeepEqual(p.To, wantTo) {
t.Errorf("got ping.To %v, want %v", p.To, wantTo)
}
return nil
test.packetIn(nil, p_pongV4, &pongV4{ReplyTok: hash, Expiration: futureExp})
})
test.packetIn(nil, pongPacket, &pong{ReplyTok: hash, Expiration: futureExp})
// the node should be added to the table shortly after getting the
// pong packet.
@ -457,7 +458,7 @@ var testPackets = []struct {
}{
{
input: "71dbda3a79554728d4f94411e42ee1f8b0d561c10e1e5f5893367948c6a7d70bb87b235fa28a77070271b6c164a2dce8c7e13a5739b53b5e96f2e5acb0e458a02902f5965d55ecbeb2ebb6cabb8b2b232896a36b737666c55265ad0a68412f250001ea04cb847f000001820cfa8215a8d790000000000000000000000000000000018208ae820d058443b9a355",
wantPacket: &ping{
wantPacket: &pingV4{
Version: 4,
From: rpcEndpoint{net.ParseIP("127.0.0.1").To4(), 3322, 5544},
To: rpcEndpoint{net.ParseIP("::1"), 2222, 3333},
@ -467,7 +468,7 @@ var testPackets = []struct {
},
{
input: "e9614ccfd9fc3e74360018522d30e1419a143407ffcce748de3e22116b7e8dc92ff74788c0b6663aaa3d67d641936511c8f8d6ad8698b820a7cf9e1be7155e9a241f556658c55428ec0563514365799a4be2be5a685a80971ddcfa80cb422cdd0101ec04cb847f000001820cfa8215a8d790000000000000000000000000000000018208ae820d058443b9a3550102",
wantPacket: &ping{
wantPacket: &pingV4{
Version: 4,
From: rpcEndpoint{net.ParseIP("127.0.0.1").To4(), 3322, 5544},
To: rpcEndpoint{net.ParseIP("::1"), 2222, 3333},
@ -477,7 +478,7 @@ var testPackets = []struct {
},
{
input: "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",
wantPacket: &ping{
wantPacket: &pingV4{
Version: 555,
From: rpcEndpoint{net.ParseIP("2001:db8:3c4d:15::abcd:ef12"), 3322, 5544},
To: rpcEndpoint{net.ParseIP("2001:db8:85a3:8d3:1319:8a2e:370:7348"), 2222, 33338},
@ -487,7 +488,7 @@ var testPackets = []struct {
},
{
input: "09b2428d83348d27cdf7064ad9024f526cebc19e4958f0fdad87c15eb598dd61d08423e0bf66b2069869e1724125f820d851c136684082774f870e614d95a2855d000f05d1648b2d5945470bc187c2d2216fbe870f43ed0909009882e176a46b0102f846d79020010db885a308d313198a2e037073488208ae82823aa0fbc914b16819237dcd8801d7e53f69e9719adecb3cc0e790c57e91ca4461c9548443b9a355c6010203c2040506a0c969a58f6f9095004c0177a6b47f451530cab38966a25cca5cb58f055542124e",
wantPacket: &pong{
wantPacket: &pongV4{
To: rpcEndpoint{net.ParseIP("2001:db8:85a3:8d3:1319:8a2e:370:7348"), 2222, 33338},
ReplyTok: common.Hex2Bytes("fbc914b16819237dcd8801d7e53f69e9719adecb3cc0e790c57e91ca4461c954"),
Expiration: 1136239445,
@ -496,7 +497,7 @@ var testPackets = []struct {
},
{
input: "c7c44041b9f7c7e41934417ebac9a8e1a4c6298f74553f2fcfdcae6ed6fe53163eb3d2b52e39fe91831b8a927bf4fc222c3902202027e5e9eb812195f95d20061ef5cd31d502e47ecb61183f74a504fe04c51e73df81f25c4d506b26db4517490103f84eb840ca634cae0d49acb401d8a4c6b6fe8c55b70d115bf400769cc1400f3258cd31387574077f301b421bc84df7266c44e9e6d569fc56be00812904767bf5ccd1fc7f8443b9a35582999983999999280dc62cc8255c73471e0a61da0c89acdc0e035e260add7fc0c04ad9ebf3919644c91cb247affc82b69bd2ca235c71eab8e49737c937a2c396",
wantPacket: &findnode{
wantPacket: &findnodeV4{
Target: hexEncPubkey("ca634cae0d49acb401d8a4c6b6fe8c55b70d115bf400769cc1400f3258cd31387574077f301b421bc84df7266c44e9e6d569fc56be00812904767bf5ccd1fc7f"),
Expiration: 1136239445,
Rest: []rlp.RawValue{{0x82, 0x99, 0x99}, {0x83, 0x99, 0x99, 0x99}},
@ -504,7 +505,7 @@ var testPackets = []struct {
},
{
input: "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",
wantPacket: &neighbors{
wantPacket: &neighborsV4{
Nodes: []rpcNode{
{
ID: hexEncPubkey("3155e1427f85f10a5c9a7755877748041af1bcd8d474ec065eb33df57a97babf54bfd2103575fa829115d224c523596b401065a97f74010610fce76382c0bf32"),
@ -537,7 +538,7 @@ var testPackets = []struct {
},
}
func TestForwardCompatibility(t *testing.T) {
func TestUDPv4_forwardCompatibility(t *testing.T) {
testkey, _ := crypto.HexToECDSA("b71c71a67e1177ad4e901695e1b4b9ee17ae16c6668d313eac2f96dbcda3f291")
wantNodeKey := encodePubkey(&testkey.PublicKey)
@ -546,7 +547,7 @@ func TestForwardCompatibility(t *testing.T) {
if err != nil {
t.Fatalf("invalid hex: %s", test.input)
}
packet, nodekey, _, err := decodePacket(input)
packet, nodekey, _, err := decodeV4(input)
if err != nil {
t.Errorf("did not accept packet %s\n%v", test.input, err)
continue
@ -610,6 +611,7 @@ func (c *dgramPipe) Close() error {
close(c.closing)
c.closed = true
}
c.cond.Broadcast()
return nil
}
@ -617,14 +619,17 @@ func (c *dgramPipe) LocalAddr() net.Addr {
return &net.UDPAddr{IP: testLocal.IP, Port: int(testLocal.UDP)}
}
func (c *dgramPipe) waitPacketOut() dgram {
func (c *dgramPipe) receive() (dgram, bool) {
c.mu.Lock()
defer c.mu.Unlock()
for len(c.queue) == 0 {
for len(c.queue) == 0 && !c.closed {
c.cond.Wait()
}
if c.closed {
return dgram{}, false
}
p := c.queue[0]
copy(c.queue, c.queue[1:])
c.queue = c.queue[:len(c.queue)-1]
return p
return p, true
}