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go-ethereum/p2p/discover/table_test.go
Felix Lange bc6569462d
p2p: use netip.Addr where possible (#29891) 
enode.Node was recently changed to store a cache of endpoint information. The IP address in the cache is a netip.Addr. I chose that type over net.IP because it is just better. netip.Addr is meant to be used as a value type. Copying it does not allocate, it can be compared with ==, and can be used as a map key.

This PR changes most uses of Node.IP() into Node.IPAddr(), which returns the cached value directly without allocating.
While there are still some public APIs left where net.IP is used, I have converted all code used internally by p2p/discover to the new types. So this does change some public Go API, but hopefully not APIs any external code actually uses.

There weren't supposed to be any semantic differences resulting from this refactoring, however it does introduce one: In package p2p/netutil we treated the 0.0.0.0/8 network (addresses 0.x.y.z) as LAN, but netip.Addr.IsPrivate() doesn't. The treatment of this particular IP address range is controversial, with some software supporting it and others not. IANA lists it as special-purpose and invalid as a destination for a long time, so I don't know why I put it into the LAN list. It has now been marked as special in p2p/netutil as well.
2024-06-05 19:31:04 +02:00

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// 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 discover
import (
"crypto/ecdsa"
"fmt"
"math/rand"
"net"
"reflect"
"slices"
"testing"
"testing/quick"
"time"
"github.com/ethereum/go-ethereum/common/mclock"
"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/p2p/enr"
"github.com/ethereum/go-ethereum/p2p/netutil"
)
func TestTable_pingReplace(t *testing.T) {
run := func(newNodeResponding, lastInBucketResponding bool) {
name := fmt.Sprintf("newNodeResponding=%t/lastInBucketResponding=%t", newNodeResponding, lastInBucketResponding)
t.Run(name, func(t *testing.T) {
t.Parallel()
testPingReplace(t, newNodeResponding, lastInBucketResponding)
})
}
run(true, true)
run(false, true)
run(true, false)
run(false, false)
}
func testPingReplace(t *testing.T, newNodeIsResponding, lastInBucketIsResponding bool) {
simclock := new(mclock.Simulated)
transport := newPingRecorder()
tab, db := newTestTable(transport, Config{
Clock: simclock,
Log: testlog.Logger(t, log.LevelTrace),
})
defer db.Close()
defer tab.close()
<-tab.initDone
// Fill up the sender's bucket.
replacementNodeKey, _ := crypto.HexToECDSA("45a915e4d060149eb4365960e6a7a45f334393093061116b197e3240065ff2d8")
replacementNode := enode.NewV4(&replacementNodeKey.PublicKey, net.IP{127, 0, 0, 1}, 99, 99)
last := fillBucket(tab, replacementNode.ID())
tab.mutex.Lock()
nodeEvents := newNodeEventRecorder(128)
tab.nodeAddedHook = nodeEvents.nodeAdded
tab.nodeRemovedHook = nodeEvents.nodeRemoved
tab.mutex.Unlock()
// The revalidation process should replace
// this node in the bucket if it is unresponsive.
transport.dead[last.ID()] = !lastInBucketIsResponding
transport.dead[replacementNode.ID()] = !newNodeIsResponding
// Add replacement node to table.
tab.addFoundNode(replacementNode, false)
t.Log("last:", last.ID())
t.Log("replacement:", replacementNode.ID())
// Wait until the last node was pinged.
waitForRevalidationPing(t, transport, tab, last.ID())
if !lastInBucketIsResponding {
if !nodeEvents.waitNodeAbsent(last.ID(), 2*time.Second) {
t.Error("last node was not removed")
}
if !nodeEvents.waitNodePresent(replacementNode.ID(), 2*time.Second) {
t.Error("replacement node was not added")
}
// If a replacement is expected, we also need to wait until the replacement node
// was pinged and added/removed.
waitForRevalidationPing(t, transport, tab, replacementNode.ID())
if !newNodeIsResponding {
if !nodeEvents.waitNodeAbsent(replacementNode.ID(), 2*time.Second) {
t.Error("replacement node was not removed")
}
}
}
// Check bucket content.
tab.mutex.Lock()
defer tab.mutex.Unlock()
wantSize := bucketSize
if !lastInBucketIsResponding && !newNodeIsResponding {
wantSize--
}
bucket := tab.bucket(replacementNode.ID())
if l := len(bucket.entries); l != wantSize {
t.Errorf("wrong bucket size after revalidation: got %d, want %d", l, wantSize)
}
if ok := containsID(bucket.entries, last.ID()); ok != lastInBucketIsResponding {
t.Errorf("revalidated node found: %t, want: %t", ok, lastInBucketIsResponding)
}
wantNewEntry := newNodeIsResponding && !lastInBucketIsResponding
if ok := containsID(bucket.entries, replacementNode.ID()); ok != wantNewEntry {
t.Errorf("replacement node found: %t, want: %t", ok, wantNewEntry)
}
}
// waitForRevalidationPing waits until a PING message is sent to a node with the given id.
func waitForRevalidationPing(t *testing.T, transport *pingRecorder, tab *Table, id enode.ID) *enode.Node {
t.Helper()
simclock := tab.cfg.Clock.(*mclock.Simulated)
maxAttempts := tab.len() * 8
for i := 0; i < maxAttempts; i++ {
simclock.Run(tab.cfg.PingInterval * slowRevalidationFactor)
p := transport.waitPing(2 * time.Second)
if p == nil {
t.Fatal("Table did not send revalidation ping")
}
if id == (enode.ID{}) || p.ID() == id {
return p
}
}
t.Fatalf("Table did not ping node %v (%d attempts)", id, maxAttempts)
return nil
}
// This checks that the table-wide IP limit is applied correctly.
func TestTable_IPLimit(t *testing.T) {
transport := newPingRecorder()
tab, db := newTestTable(transport, Config{})
defer db.Close()
defer tab.close()
for i := 0; i < tableIPLimit+1; i++ {
n := nodeAtDistance(tab.self().ID(), i, net.IP{172, 0, 1, byte(i)})
tab.addFoundNode(n, false)
}
if tab.len() > tableIPLimit {
t.Errorf("too many nodes in table")
}
checkIPLimitInvariant(t, tab)
}
// This checks that the per-bucket IP limit is applied correctly.
func TestTable_BucketIPLimit(t *testing.T) {
transport := newPingRecorder()
tab, db := newTestTable(transport, Config{})
defer db.Close()
defer tab.close()
d := 3
for i := 0; i < bucketIPLimit+1; i++ {
n := nodeAtDistance(tab.self().ID(), d, net.IP{172, 0, 1, byte(i)})
tab.addFoundNode(n, false)
}
if tab.len() > bucketIPLimit {
t.Errorf("too many nodes in table")
}
checkIPLimitInvariant(t, tab)
}
// checkIPLimitInvariant checks that ip limit sets contain an entry for every
// node in the table and no extra entries.
func checkIPLimitInvariant(t *testing.T, tab *Table) {
t.Helper()
tabset := netutil.DistinctNetSet{Subnet: tableSubnet, Limit: tableIPLimit}
for _, b := range tab.buckets {
for _, n := range b.entries {
tabset.AddAddr(n.IPAddr())
}
}
if tabset.String() != tab.ips.String() {
t.Errorf("table IP set is incorrect:\nhave: %v\nwant: %v", tab.ips, tabset)
}
}
func TestTable_findnodeByID(t *testing.T) {
t.Parallel()
test := func(test *closeTest) bool {
// for any node table, Target and N
transport := newPingRecorder()
tab, db := newTestTable(transport, Config{})
defer db.Close()
defer tab.close()
fillTable(tab, test.All, true)
// check that closest(Target, N) returns nodes
result := tab.findnodeByID(test.Target, test.N, false).entries
if hasDuplicates(result) {
t.Errorf("result contains duplicates")
return false
}
if !sortedByDistanceTo(test.Target, result) {
t.Errorf("result is not sorted by distance to target")
return false
}
// check that the number of results is min(N, tablen)
wantN := test.N
if tlen := tab.len(); tlen < test.N {
wantN = tlen
}
if len(result) != wantN {
t.Errorf("wrong number of nodes: got %d, want %d", len(result), wantN)
return false
} else if len(result) == 0 {
return true // no need to check distance
}
// check that the result nodes have minimum distance to target.
for _, b := range tab.buckets {
for _, n := range b.entries {
if containsID(result, n.ID()) {
continue // don't run the check below for nodes in result
}
farthestResult := result[len(result)-1].ID()
if enode.DistCmp(test.Target, n.ID(), farthestResult) < 0 {
t.Errorf("table contains node that is closer to target but it's not in result")
t.Logf(" Target: %v", test.Target)
t.Logf(" Farthest Result: %v", farthestResult)
t.Logf(" ID: %v", n.ID())
return false
}
}
}
return true
}
if err := quick.Check(test, quickcfg()); err != nil {
t.Error(err)
}
}
type closeTest struct {
Self enode.ID
Target enode.ID
All []*enode.Node
N int
}
func (*closeTest) Generate(rand *rand.Rand, size int) reflect.Value {
t := &closeTest{
Self: gen(enode.ID{}, rand).(enode.ID),
Target: gen(enode.ID{}, rand).(enode.ID),
N: rand.Intn(bucketSize),
}
for _, id := range gen([]enode.ID{}, rand).([]enode.ID) {
r := new(enr.Record)
r.Set(enr.IPv4Addr(netutil.RandomAddr(rand, true)))
n := enode.SignNull(r, id)
t.All = append(t.All, n)
}
return reflect.ValueOf(t)
}
func TestTable_addInboundNode(t *testing.T) {
tab, db := newTestTable(newPingRecorder(), Config{})
<-tab.initDone
defer db.Close()
defer tab.close()
// Insert two nodes.
n1 := nodeAtDistance(tab.self().ID(), 256, net.IP{88, 77, 66, 1})
n2 := nodeAtDistance(tab.self().ID(), 256, net.IP{88, 77, 66, 2})
tab.addFoundNode(n1, false)
tab.addFoundNode(n2, false)
checkBucketContent(t, tab, []*enode.Node{n1, n2})
// Add a changed version of n2. The bucket should be updated.
newrec := n2.Record()
newrec.Set(enr.IP{99, 99, 99, 99})
n2v2 := enode.SignNull(newrec, n2.ID())
tab.addInboundNode(n2v2)
checkBucketContent(t, tab, []*enode.Node{n1, n2v2})
// Try updating n2 without sequence number change. The update is accepted
// because it's inbound.
newrec = n2.Record()
newrec.Set(enr.IP{100, 100, 100, 100})
newrec.SetSeq(n2.Seq())
n2v3 := enode.SignNull(newrec, n2.ID())
tab.addInboundNode(n2v3)
checkBucketContent(t, tab, []*enode.Node{n1, n2v3})
}
func TestTable_addFoundNode(t *testing.T) {
tab, db := newTestTable(newPingRecorder(), Config{})
<-tab.initDone
defer db.Close()
defer tab.close()
// Insert two nodes.
n1 := nodeAtDistance(tab.self().ID(), 256, net.IP{88, 77, 66, 1})
n2 := nodeAtDistance(tab.self().ID(), 256, net.IP{88, 77, 66, 2})
tab.addFoundNode(n1, false)
tab.addFoundNode(n2, false)
checkBucketContent(t, tab, []*enode.Node{n1, n2})
// Add a changed version of n2. The bucket should be updated.
newrec := n2.Record()
newrec.Set(enr.IP{99, 99, 99, 99})
n2v2 := enode.SignNull(newrec, n2.ID())
tab.addFoundNode(n2v2, false)
checkBucketContent(t, tab, []*enode.Node{n1, n2v2})
// Try updating n2 without a sequence number change.
// The update should not be accepted.
newrec = n2.Record()
newrec.Set(enr.IP{100, 100, 100, 100})
newrec.SetSeq(n2.Seq())
n2v3 := enode.SignNull(newrec, n2.ID())
tab.addFoundNode(n2v3, false)
checkBucketContent(t, tab, []*enode.Node{n1, n2v2})
}
// This test checks that discv4 nodes can update their own endpoint via PING.
func TestTable_addInboundNodeUpdateV4Accept(t *testing.T) {
tab, db := newTestTable(newPingRecorder(), Config{})
<-tab.initDone
defer db.Close()
defer tab.close()
// Add a v4 node.
key, _ := crypto.HexToECDSA("dd3757a8075e88d0f2b1431e7d3c5b1562e1c0aab9643707e8cbfcc8dae5cfe3")
n1 := enode.NewV4(&key.PublicKey, net.IP{88, 77, 66, 1}, 9000, 9000)
tab.addInboundNode(n1)
checkBucketContent(t, tab, []*enode.Node{n1})
// Add an updated version with changed IP.
// The update will be accepted because it is inbound.
n1v2 := enode.NewV4(&key.PublicKey, net.IP{99, 99, 99, 99}, 9000, 9000)
tab.addInboundNode(n1v2)
checkBucketContent(t, tab, []*enode.Node{n1v2})
}
// This test checks that discv4 node entries will NOT be updated when a
// changed record is found.
func TestTable_addFoundNodeV4UpdateReject(t *testing.T) {
tab, db := newTestTable(newPingRecorder(), Config{})
<-tab.initDone
defer db.Close()
defer tab.close()
// Add a v4 node.
key, _ := crypto.HexToECDSA("dd3757a8075e88d0f2b1431e7d3c5b1562e1c0aab9643707e8cbfcc8dae5cfe3")
n1 := enode.NewV4(&key.PublicKey, net.IP{88, 77, 66, 1}, 9000, 9000)
tab.addFoundNode(n1, false)
checkBucketContent(t, tab, []*enode.Node{n1})
// Add an updated version with changed IP.
// The update won't be accepted because it isn't inbound.
n1v2 := enode.NewV4(&key.PublicKey, net.IP{99, 99, 99, 99}, 9000, 9000)
tab.addFoundNode(n1v2, false)
checkBucketContent(t, tab, []*enode.Node{n1})
}
func checkBucketContent(t *testing.T, tab *Table, nodes []*enode.Node) {
t.Helper()
b := tab.bucket(nodes[0].ID())
if reflect.DeepEqual(unwrapNodes(b.entries), nodes) {
return
}
t.Log("wrong bucket content. have nodes:")
for _, n := range b.entries {
t.Logf(" %v (seq=%v, ip=%v)", n.ID(), n.Seq(), n.IPAddr())
}
t.Log("want nodes:")
for _, n := range nodes {
t.Logf(" %v (seq=%v, ip=%v)", n.ID(), n.Seq(), n.IPAddr())
}
t.FailNow()
// Also check IP limits.
checkIPLimitInvariant(t, tab)
}
// This test checks that ENR updates happen during revalidation. If a node in the table
// announces a new sequence number, the new record should be pulled.
func TestTable_revalidateSyncRecord(t *testing.T) {
transport := newPingRecorder()
tab, db := newTestTable(transport, Config{
Clock: new(mclock.Simulated),
Log: testlog.Logger(t, log.LevelTrace),
})
<-tab.initDone
defer db.Close()
defer tab.close()
// Insert a node.
var r enr.Record
r.Set(enr.IP(net.IP{127, 0, 0, 1}))
id := enode.ID{1}
n1 := enode.SignNull(&r, id)
tab.addFoundNode(n1, false)
// Update the node record.
r.Set(enr.WithEntry("foo", "bar"))
n2 := enode.SignNull(&r, id)
transport.updateRecord(n2)
// Wait for revalidation. We wait for the node to be revalidated two times
// in order to synchronize with the update in the table.
waitForRevalidationPing(t, transport, tab, n2.ID())
waitForRevalidationPing(t, transport, tab, n2.ID())
intable := tab.getNode(id)
if !reflect.DeepEqual(intable, n2) {
t.Fatalf("table contains old record with seq %d, want seq %d", intable.Seq(), n2.Seq())
}
}
func TestNodesPush(t *testing.T) {
var target enode.ID
n1 := nodeAtDistance(target, 255, intIP(1))
n2 := nodeAtDistance(target, 254, intIP(2))
n3 := nodeAtDistance(target, 253, intIP(3))
perm := [][]*enode.Node{
{n3, n2, n1},
{n3, n1, n2},
{n2, n3, n1},
{n2, n1, n3},
{n1, n3, n2},
{n1, n2, n3},
}
// Insert all permutations into lists with size limit 3.
for _, nodes := range perm {
list := nodesByDistance{target: target}
for _, n := range nodes {
list.push(n, 3)
}
if !slices.EqualFunc(list.entries, perm[0], nodeIDEqual) {
t.Fatal("not equal")
}
}
// Insert all permutations into lists with size limit 2.
for _, nodes := range perm {
list := nodesByDistance{target: target}
for _, n := range nodes {
list.push(n, 2)
}
if !slices.EqualFunc(list.entries, perm[0][:2], nodeIDEqual) {
t.Fatal("not equal")
}
}
}
func nodeIDEqual[N nodeType](n1, n2 N) bool {
return n1.ID() == n2.ID()
}
// 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{} {
v, ok := quick.Value(reflect.TypeOf(typ), rand)
if !ok {
panic(fmt.Sprintf("couldn't generate random value of type %T", typ))
}
return v.Interface()
}
func quickcfg() *quick.Config {
return &quick.Config{
MaxCount: 5000,
Rand: rand.New(rand.NewSource(time.Now().Unix())),
}
}
func newkey() *ecdsa.PrivateKey {
key, err := crypto.GenerateKey()
if err != nil {
panic("couldn't generate key: " + err.Error())
}
return key
}
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