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refactor-for-testability #3

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johnnylee merged 26 commits from refactor-for-testability into main 2025-03-01 20:02:27 +00:00
Conversation 0 Commits 26 Files Changed 68 +2808 -85
37 changed files with 2808 additions and 85 deletions
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Showing only changes of commit 1a6503bbda - Show all commits

5
node/README.md
View File

@@ -2,11 +2,10 @@
## Refactoring for Testability
* [ ] connWriter
* [ ] Separate send/relay calls
* [x] connWriter
* [x] mcWriter
* [x] ifWriter
* [ ] ifReader
* [ ] ifReader (testing)
* [ ] connReader
* [ ] mcReader
* [ ] hubPoller

40
node/connwriter.go
View File

@@ -68,18 +68,18 @@ func newConnWriter(conn udpAddrPortWriter, localIP byte) *connWriter {
// Not safe for concurrent use. Should only be called by supervisor.
func (w *connWriter) SendControlPacket(pkt marshaller, route *peerRoute) {
buf := pkt.Marshal(w.cBuf1)
h := header{
StreamID: controlStreamID,
Counter: atomic.AddUint64(&w.counters[route.IP], 1),
SourceIP: w.localIP,
DestIP: route.IP,
}
buf = route.ControlCipher.Encrypt(h, buf, w.cBuf2)
buf := w.encryptControlPacket(pkt, route)
w.writeTo(buf, route.RemoteAddr)
}
// Relay control packet. Routes must not be nil.
func (w *connWriter) RelayControlPacket(pkt marshaller, route, relay *peerRoute) {
buf := w.encryptControlPacket(pkt, route)
w.relayPacket(buf, w.cBuf1, route, relay)
}
// Encrypted packet will occupy cBuf2.
func (w *connWriter) encryptControlPacket(pkt marshaller, route *peerRoute) []byte {
buf := pkt.Marshal(w.cBuf1)
h := header{
StreamID: controlStreamID,
@@ -87,12 +87,11 @@ func (w *connWriter) RelayControlPacket(pkt marshaller, route, relay *peerRoute)
SourceIP: w.localIP,
DestIP: route.IP,
}
buf = route.ControlCipher.Encrypt(h, buf, w.cBuf2)
w.relayPacket(buf, w.cBuf1, route, relay)
return route.ControlCipher.Encrypt(h, buf, w.cBuf2)
}
// Not safe for concurrent use. Should only be called by ifReader.
func (w *connWriter) SendDataPacket(pkt []byte, route, relay *peerRoute) {
func (w *connWriter) SendDataPacket(pkt []byte, route *peerRoute) {
h := header{
StreamID: dataStreamID,
Counter: atomic.AddUint64(&w.counters[route.IP], 1),
@@ -101,17 +100,22 @@ func (w *connWriter) SendDataPacket(pkt []byte, route, relay *peerRoute) {
}
enc := route.DataCipher.Encrypt(h, pkt, w.dBuf1)
if route.Direct {
w.writeTo(enc, route.RemoteAddr)
return
}
// Relay a data packet. Routes must not be nil.
func (w *connWriter) RelayDataPacket(pkt []byte, route, relay *peerRoute) {
h := header{
StreamID: dataStreamID,
Counter: atomic.AddUint64(&w.counters[route.IP], 1),
SourceIP: w.localIP,
DestIP: route.IP,
}
enc := route.DataCipher.Encrypt(h, pkt, w.dBuf1)
w.relayPacket(enc, w.dBuf2, route, relay)
}
// TODO: RelayDataPacket
// Safe for concurrent use. Should only be called by connReader.
//
// This function will send pkt to the peer directly. This is used when a peer
@@ -122,10 +126,6 @@ func (w *connWriter) SendEncryptedDataPacket(pkt []byte, route *peerRoute) {
}
func (w *connWriter) relayPacket(data, buf []byte, route, relay *peerRoute) {
if relay == nil || !relay.Up {
return
}
h := header{
StreamID: dataStreamID,
Counter: atomic.AddUint64(&w.counters[relay.IP], 1),

69
node/connwriter_test.go
View File

@@ -126,7 +126,7 @@ func TestConnWriter_SendControlPacket_direct(t *testing.T) {
}
// Testing if we can relay a packet via an intermediary.
func TestConnWriter_SendControlPacket_relay(t *testing.T) {
func TestConnWriter_RelayControlPacket_relay(t *testing.T) {
route, rRoute, relay, rRelay := testConnWriter_getTestRoutes()
writer := &testUDPAddrPortWriter{}
@@ -159,40 +159,6 @@ func TestConnWriter_SendControlPacket_relay(t *testing.T) {
}
}
// Testing that a nil relay doesn't cause an issue.
func TestConnWriter_SendControlPacket_relay_relayNil(t *testing.T) {
route, rRoute, _, _ := testConnWriter_getTestRoutes()
writer := &testUDPAddrPortWriter{}
w := newConnWriter(writer, rRoute.IP)
in := testPacket("hello world!")
w.RelayControlPacket(in, route, nil)
out := writer.Written()
if len(out) != 0 {
t.Fatal(out)
}
}
// Testing that we don't send anything if the relay isn't up.
func TestConnWriter_SendControlPacket_relay_relayNotUp(t *testing.T) {
route, rRoute, relay, _ := testConnWriter_getTestRoutes()
relay.Up = false
writer := &testUDPAddrPortWriter{}
w := newConnWriter(writer, rRoute.IP)
in := testPacket("hello world!")
w.RelayControlPacket(in, route, relay)
out := writer.Written()
if len(out) != 0 {
t.Fatal(out)
}
}
// Testing that we can send a data packet directly to a remote route.
func TestConnWriter_SendDataPacket_direct(t *testing.T) {
route, rRoute, _, _ := testConnWriter_getTestRoutes()
@@ -202,7 +168,7 @@ func TestConnWriter_SendDataPacket_direct(t *testing.T) {
w := newConnWriter(writer, rRoute.IP)
in := []byte("hello world!")
w.SendDataPacket(in, route, nil)
w.SendDataPacket(in, route)
out := writer.Written()
if len(out) != 1 {
@@ -224,14 +190,14 @@ func TestConnWriter_SendDataPacket_direct(t *testing.T) {
}
// Testing that we can relay a data packet via a relay.
func TestConnWriter_SendDataPacket_relay(t *testing.T) {
func TestConnWriter_RelayDataPacket_relay(t *testing.T) {
route, rRoute, relay, rRelay := testConnWriter_getTestRoutes()
writer := &testUDPAddrPortWriter{}
w := newConnWriter(writer, rRoute.IP)
in := []byte("Hello world!")
w.SendDataPacket(in, route, relay)
w.RelayDataPacket(in, route, relay)
out := writer.Written()
if len(out) != 1 {
@@ -257,35 +223,26 @@ func TestConnWriter_SendDataPacket_relay(t *testing.T) {
}
}
// Testing that we don't attempt to relay if the relay is nil.
func TestConnWriter_SendDataPacket_relay_relayNil(t *testing.T) {
// Testing that we can send an already encrypted packet.
func TestConnWriter_SendEncryptedDataPacket(t *testing.T) {
route, rRoute, _, _ := testConnWriter_getTestRoutes()
writer := &testUDPAddrPortWriter{}
w := newConnWriter(writer, rRoute.IP)
in := []byte("Hello world!")
w.SendDataPacket(in, route, nil)
w.SendEncryptedDataPacket(in, route)
out := writer.Written()
if len(out) != 0 {
if len(out) != 1 {
t.Fatal(out)
}
if out[0].Addr != route.RemoteAddr {
t.Fatal(out[0])
}
// Testing that we don't attempt to relay if the relay isn't up.
func TestConnWriter_SendDataPacket_relay_relayNotUp(t *testing.T) {
route, rRoute, relay, _ := testConnWriter_getTestRoutes()
relay.Up = false
writer := &testUDPAddrPortWriter{}
w := newConnWriter(writer, rRoute.IP)
in := []byte("Hello world!")
w.SendDataPacket(in, route, relay)
out := writer.Written()
if len(out) != 0 {
t.Fatal(out)
if !bytes.Equal(out[0].Data, in) {
t.Fatal(out[0])
}
}

4
node/dupcheck.go
View File

@@ -38,14 +38,14 @@ func (dc *dupCheck) IsDup(counter uint64) bool {
delta := counter - dc.tailCounter
// Full clear.
if delta >= bitSetSize {
if delta >= bitSetSize-1 {
dc.ClearAll()
dc.Set(0)
dc.tail = 1
dc.head = 2
dc.tailCounter = counter + 1
dc.headCounter = dc.tailCounter - bitSetSize
dc.headCounter = dc.tailCounter - bitSetSize + 1
return false
}

12
node/header.go
View File

@@ -20,6 +20,18 @@ type header struct {
Counter uint64 // Init with time.Now().Unix << 30 to ensure monotonic.
}
func parseHeader(b []byte) (h header, ok bool) {
if len(b) < headerSize {
return
}
h.Version = b[0]
h.StreamID = b[1]
h.SourceIP = b[2]
h.DestIP = b[3]
h.Counter = *(*uint64)(unsafe.Pointer(&b[4]))
return h, true
}
func (h *header) Parse(b []byte) {
h.Version = b[0]
h.StreamID = b[1]

2
node/ifreader.go
View File

@@ -57,7 +57,7 @@ func (r *ifReader) sendPacket(pkt []byte, remoteIP byte) {
return
}
if relay := r.relay.Load(); relay != nil {
if relay := r.relay.Load(); relay != nil && relay.Up {
r.relayDataPacket(pkt, route, relay)
}
}

21
peer/bitset.go Normal file
View File

@@ -0,0 +1,21 @@
package peer
const bitSetSize = 512 // Multiple of 64.
type bitSet [bitSetSize / 64]uint64
func (bs *bitSet) Set(i int) {
bs[i/64] |= 1 << (i % 64)
}
func (bs *bitSet) Clear(i int) {
bs[i/64] &= ^(1 << (i % 64))
}
func (bs *bitSet) ClearAll() {
clear(bs[:])
}
func (bs *bitSet) Get(i int) bool {
return bs[i/64]&(1<<(i%64)) != 0
}

48
peer/bitset_test.go Normal file
View File

@@ -0,0 +1,48 @@
package peer
import (
"math/rand"
"testing"
)
func TestBitSet(t *testing.T) {
state := make([]bool, bitSetSize)
for i := range state {
state[i] = rand.Float32() > 0.5
}
bs := bitSet{}
for i := range state {
if state[i] {
bs.Set(i)
}
}
for i := range state {
if bs.Get(i) != state[i] {
t.Fatal(i, state[i], bs.Get(i))
}
}
for i := range state {
if rand.Float32() > 0.5 {
state[i] = false
bs.Clear(i)
}
}
for i := range state {
if bs.Get(i) != state[i] {
t.Fatal(i, state[i], bs.Get(i))
}
}
bs.ClearAll()
for i := range state {
if bs.Get(i) {
t.Fatal(i, bs.Get(i))
}
}
}

26
peer/cipher-control.go Normal file
View File

@@ -0,0 +1,26 @@
package peer
import "golang.org/x/crypto/nacl/box"
type controlCipher struct {
sharedKey [32]byte
}
func newControlCipher(privKey, pubKey []byte) *controlCipher {
shared := [32]byte{}
box.Precompute(&shared, (*[32]byte)(pubKey), (*[32]byte)(privKey))
return &controlCipher{shared}
}
func (cc *controlCipher) Encrypt(h header, data, out []byte) []byte {
const s = controlHeaderSize
out = out[:s+controlCipherOverhead+len(data)]
h.Marshal(out[:s])
box.SealAfterPrecomputation(out[s:s], data, (*[24]byte)(out[:s]), &cc.sharedKey)
return out
}
func (cc *controlCipher) Decrypt(encrypted, out []byte) (data []byte, ok bool) {
const s = controlHeaderSize
return box.OpenAfterPrecomputation(out[:0], encrypted[s:], (*[24]byte)(encrypted[:s]), &cc.sharedKey)
}

122
peer/cipher-control_test.go Normal file
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@@ -0,0 +1,122 @@
package peer
import (
"bytes"
"crypto/rand"
"reflect"
"testing"
"golang.org/x/crypto/nacl/box"
)
func newControlCipherForTesting() (c1, c2 *controlCipher) {
pubKey1, privKey1, err := box.GenerateKey(rand.Reader)
if err != nil {
panic(err)
}
pubKey2, privKey2, err := box.GenerateKey(rand.Reader)
if err != nil {
panic(err)
}
return newControlCipher(privKey1[:], pubKey2[:]),
newControlCipher(privKey2[:], pubKey1[:])
}
func TestControlCipher(t *testing.T) {
c1, c2 := newControlCipherForTesting()
maxSizePlaintext := make([]byte, bufferSize-controlHeaderSize-controlCipherOverhead)
rand.Read(maxSizePlaintext)
testCases := [][]byte{
make([]byte, 0),
{1},
{255},
{1, 2, 3, 4, 5},
[]byte("Hello world"),
maxSizePlaintext,
}
for _, plaintext := range testCases {
h1 := header{
StreamID: controlStreamID,
Counter: 235153,
SourceIP: 4,
DestIP: 88,
}
encrypted := make([]byte, bufferSize)
encrypted = c1.Encrypt(h1, plaintext, encrypted)
h2 := header{}
h2.Parse(encrypted)
if !reflect.DeepEqual(h1, h2) {
t.Fatal(h1, h2)
}
decrypted, ok := c2.Decrypt(encrypted, make([]byte, bufferSize))
if !ok {
t.Fatal(ok)
}
if !bytes.Equal(decrypted, plaintext) {
t.Fatal("not equal")
}
}
}
func TestControlCipher_ShortCiphertext(t *testing.T) {
c1, _ := newControlCipherForTesting()
shortText := make([]byte, controlHeaderSize+controlCipherOverhead-1)
rand.Read(shortText)
_, ok := c1.Decrypt(shortText, make([]byte, bufferSize))
if ok {
t.Fatal(ok)
}
}
func BenchmarkControlCipher_Encrypt(b *testing.B) {
c1, _ := newControlCipherForTesting()
h1 := header{
Counter: 235153,
SourceIP: 4,
DestIP: 88,
}
plaintext := make([]byte, bufferSize-controlHeaderSize-controlCipherOverhead)
rand.Read(plaintext)
encrypted := make([]byte, bufferSize)
b.ResetTimer()
for i := 0; i < b.N; i++ {
encrypted = c1.Encrypt(h1, plaintext, encrypted)
}
}
func BenchmarkControlCipher_Decrypt(b *testing.B) {
c1, c2 := newControlCipherForTesting()
h1 := header{
Counter: 235153,
SourceIP: 4,
DestIP: 88,
}
plaintext := make([]byte, bufferSize-controlHeaderSize-controlCipherOverhead)
rand.Read(plaintext)
encrypted := make([]byte, bufferSize)
encrypted = c1.Encrypt(h1, plaintext, encrypted)
decrypted := make([]byte, bufferSize)
b.ResetTimer()
for i := 0; i < b.N; i++ {
decrypted, _ = c2.Decrypt(encrypted, decrypted)
}
}

61
peer/cipher-data.go Normal file
View File

@@ -0,0 +1,61 @@
package peer
import (
"crypto/aes"
"crypto/cipher"
"crypto/rand"
"log"
)
type dataCipher struct {
key [32]byte
aead cipher.AEAD
}
func newDataCipher() *dataCipher {
key := [32]byte{}
if _, err := rand.Read(key[:]); err != nil {
log.Fatalf("Failed to read random data: %v", err)
}
return newDataCipherFromKey(key)
}
func newDataCipherFromKey(key [32]byte) *dataCipher {
block, err := aes.NewCipher(key[:])
if err != nil {
log.Fatalf("Failed to create new cipher: %v", err)
}
aead, err := cipher.NewGCM(block)
if err != nil {
log.Fatalf("Failed to create new GCM: %v", err)
}
return &dataCipher{key: key, aead: aead}
}
func (sc *dataCipher) Key() [32]byte {
return sc.key
}
func (sc *dataCipher) Encrypt(h header, data, out []byte) []byte {
const s = dataHeaderSize
out = out[:s+dataCipherOverhead+len(data)]
h.Marshal(out[:s])
sc.aead.Seal(out[s:s], out[:s], data, nil)
return out
}
func (sc *dataCipher) Decrypt(encrypted, out []byte) (data []byte, ok bool) {
const s = dataHeaderSize
if len(encrypted) < s+dataCipherOverhead {
ok = false
return
}
var err error
data, err = sc.aead.Open(out[:0], encrypted[:s], encrypted[s:], nil)
ok = err == nil
return
}

141
peer/cipher-data_test.go Normal file
View File

@@ -0,0 +1,141 @@
package peer
import (
"bytes"
"crypto/rand"
mrand "math/rand/v2"
"reflect"
"testing"
)
func TestDataCipher(t *testing.T) {
maxSizePlaintext := make([]byte, bufferSize-dataHeaderSize-dataCipherOverhead)
rand.Read(maxSizePlaintext)
testCases := [][]byte{
make([]byte, 0),
{1},
{255},
{1, 2, 3, 4, 5},
[]byte("Hello world"),
maxSizePlaintext,
}
for _, plaintext := range testCases {
h1 := header{
StreamID: dataStreamID,
Counter: 235153,
SourceIP: 4,
DestIP: 88,
}
encrypted := make([]byte, bufferSize)
dc1 := newDataCipher()
encrypted = dc1.Encrypt(h1, plaintext, encrypted)
h2 := header{}
h2.Parse(encrypted)
dc2 := newDataCipherFromKey(dc1.Key())
decrypted, ok := dc2.Decrypt(encrypted, make([]byte, bufferSize-dataHeaderSize))
if !ok {
t.Fatal(ok)
}
if !bytes.Equal(plaintext, decrypted) {
t.Fatal("not equal")
}
if !reflect.DeepEqual(h1, h2) {
t.Fatalf("%v != %v", h1, h2)
}
}
}
func TestDataCipher_ModifyCiphertext(t *testing.T) {
maxSizePlaintext := make([]byte, bufferSize-dataHeaderSize-dataCipherOverhead)
rand.Read(maxSizePlaintext)
testCases := [][]byte{
make([]byte, 0),
{1},
{255},
{1, 2, 3, 4, 5},
[]byte("Hello world"),
maxSizePlaintext,
}
for _, plaintext := range testCases {
h1 := header{
Counter: 235153,
SourceIP: 4,
DestIP: 88,
}
encrypted := make([]byte, bufferSize)
dc1 := newDataCipher()
encrypted = dc1.Encrypt(h1, plaintext, encrypted)
encrypted[mrand.IntN(len(encrypted))]++
dc2 := newDataCipherFromKey(dc1.Key())
_, ok := dc2.Decrypt(encrypted, make([]byte, bufferSize-dataHeaderSize))
if ok {
t.Fatal(ok)
}
}
}
func TestDataCipher_ShortCiphertext(t *testing.T) {
dc1 := newDataCipher()
shortText := make([]byte, dataHeaderSize+dataCipherOverhead-1)
rand.Read(shortText)
_, ok := dc1.Decrypt(shortText, make([]byte, bufferSize))
if ok {
t.Fatal(ok)
}
}
func BenchmarkDataCipher_Encrypt(b *testing.B) {
h1 := header{
Counter: 235153,
SourceIP: 4,
DestIP: 88,
}
plaintext := make([]byte, bufferSize-dataHeaderSize-dataCipherOverhead)
rand.Read(plaintext)
encrypted := make([]byte, bufferSize)
dc1 := newDataCipher()
b.ResetTimer()
for i := 0; i < b.N; i++ {
encrypted = dc1.Encrypt(h1, plaintext, encrypted)
}
}
func BenchmarkDataCipher_Decrypt(b *testing.B) {
h1 := header{
Counter: 235153,
SourceIP: 4,
DestIP: 88,
}
plaintext := make([]byte, bufferSize-dataHeaderSize-dataCipherOverhead)
rand.Read(plaintext)
encrypted := make([]byte, bufferSize)
dc1 := newDataCipher()
encrypted = dc1.Encrypt(h1, plaintext, encrypted)
decrypted := make([]byte, bufferSize)
b.ResetTimer()
for i := 0; i < b.N; i++ {
decrypted, _ = dc1.Decrypt(encrypted, decrypted)
}
}

13
peer/cipher-discovery.go Normal file
View File

@@ -0,0 +1,13 @@
package peer
/*
func signData(privKey *[64]byte, h header, data, out []byte) []byte {
out = out[:headerSize]
h.Marshal(out)
return sign.Sign(out, data, privKey)
}
func openData(pubKey *[32]byte, signed, out []byte) (data []byte, ok bool) {
return sign.Open(out[:0], signed[headerSize:], pubKey)
}
*/

141
peer/connreader.go Normal file
View File

@@ -0,0 +1,141 @@
package peer
import (
"log"
"net/netip"
"sync/atomic"
)
type connReader struct {
conn udpReader
iface ifWriter
sender encryptedPacketSender
super controlMsgHandler
localIP byte
routes [256]*atomic.Pointer[peerRoute]
buf []byte
decBuf []byte
dupChecks [256]*dupCheck
}
func newConnReader(
conn udpReader,
ifWriter ifWriter,
sender encryptedPacketSender,
super controlMsgHandler,
localIP byte,
routes [256]*atomic.Pointer[peerRoute],
) *connReader {
return &connReader{
conn: conn,
iface: ifWriter,
sender: sender,
super: super,
localIP: localIP,
routes: routes,
buf: make([]byte, bufferSize),
decBuf: make([]byte, bufferSize),
dupChecks: func() (out [256]*dupCheck) {
for i := range out {
out[i] = newDupCheck(0)
}
return
}(),
}
}
func (r *connReader) Run() {
for {
r.handleNextPacket()
}
}
func (r *connReader) logf(s string, args ...any) {
log.Printf("[ConnReader] "+s, args...)
}
func (r *connReader) handleNextPacket() {
buf := r.buf[:bufferSize]
n, remoteAddr, err := r.conn.ReadFromUDPAddrPort(buf)
if err != nil {
log.Fatalf("Failed to read from UDP port: %v", err)
}
if n < headerSize {
return
}
remoteAddr = netip.AddrPortFrom(remoteAddr.Addr().Unmap(), remoteAddr.Port())
buf = buf[:n]
h, ok := parseHeader(buf)
if !ok {
return
}
route := r.routes[h.SourceIP].Load()
switch h.StreamID {
case controlStreamID:
r.handleControlPacket(route, remoteAddr, h, buf)
case dataStreamID:
r.handleDataPacket(route, h, buf)
default:
r.logf("Unknown stream ID: %d", h.StreamID)
}
}
func (r *connReader) handleControlPacket(
route *peerRoute,
addr netip.AddrPort,
h header,
enc []byte,
) {
if route.ControlCipher == nil {
return
}
if h.DestIP != r.localIP {
r.logf("Incorrect destination IP on control packet: %d", h.DestIP)
return
}
msg, err := decryptControlPacket(route, addr, h, enc, r.decBuf)
if err != nil {
r.logf("Failed to decrypt control packet: %v", err)
return
}
r.super.HandleControlMsg(msg)
}
func (r *connReader) handleDataPacket(route *peerRoute, h header, enc []byte) {
if !route.Up {
r.logf("Not connected (recv).")
return
}
data, err := decryptDataPacket(route, h, enc, r.decBuf)
if err != nil {
r.logf("Failed to decrypt data packet: %v", err)
return
}
if h.DestIP == r.localIP {
if _, err := r.iface.Write(data); err != nil {
log.Fatalf("Failed to write to interface: %v", err)
}
return
}
destRoute := r.routes[h.DestIP].Load()
if !destRoute.Up {
r.logf("Not connected (relay): %d", destRoute.IP)
return
}
r.sender.SendEncryptedDataPacket(data, destRoute)
}

318
peer/connreader_test.go Normal file
View File

@@ -0,0 +1,318 @@
package peer
/*
type mockIfWriter struct {
Written [][]byte
}
func (w *mockIfWriter) Write(b []byte) (int, error) {
w.Written = append(w.Written, bytes.Clone(b))
return len(b), nil
}
type mockEncryptedPacket struct {
Packet []byte
Route *peerRoute
}
type mockEncryptedPacketSender struct {
Sent []mockEncryptedPacket
}
func (m *mockEncryptedPacketSender) SendEncryptedDataPacket(pkt []byte, route *peerRoute) {
m.Sent = append(m.Sent, mockEncryptedPacket{
Packet: bytes.Clone(pkt),
Route: route,
})
}
type mockControlMsgHandler struct {
Messages []any
}
func (m *mockControlMsgHandler) HandleControlMsg(pkt any) {
m.Messages = append(m.Messages, pkt)
}
type udpPipe struct {
packets chan []byte
}
func newUDPPipe() *udpPipe {
return &udpPipe{make(chan []byte, 1024)}
}
func (p *udpPipe) WriteToUDPAddrPort(b []byte, addr netip.AddrPort) (int, error) {
p.packets <- bytes.Clone(b)
return len(b), nil
}
func (p *udpPipe) ReadFromUDPAddrPort(b []byte) (n int, addr netip.AddrPort, err error) {
packet := <-p.packets
copy(b, packet)
return len(packet), netip.AddrPort{}, nil
}
type connReaderTestHarness struct {
Pipe *udpPipe
R *connReader
WRemote *connWriter
WRelayRemote *connWriter
Remote *peerRoute
RelayRemote *peerRoute
IFace *mockIfWriter
Sender *mockEncryptedPacketSender
Super *mockControlMsgHandler
}
// Peer 2 is indirect, peer 3 is direct.
func newConnReadeTestHarness() (h connReaderTestHarness) {
pipe := newUDPPipe()
routes := [256]*atomic.Pointer[peerRoute]{}
for i := range routes {
routes[i] = &atomic.Pointer[peerRoute]{}
routes[i].Store(&peerRoute{})
}
local, remote, relayLocal, relayRemote := testConnWriter_getTestRoutes()
routes[2].Store(local)
routes[3].Store(relayLocal)
h.Pipe = pipe
h.WRemote = newConnWriter(pipe, 2)
h.WRelayRemote = newConnWriter(pipe, 3)
h.Remote = remote
h.RelayRemote = relayRemote
h.IFace = &mockIfWriter{}
h.Sender = &mockEncryptedPacketSender{}
h.Super = &mockControlMsgHandler{}
h.R = newConnReader(
pipe,
h.IFace,
h.Sender,
h.Super,
1,
routes)
return h
}
// Testing that we can receive a control packet.
func TestConnReader_handleControlPacket(t *testing.T) {
h := newConnReadeTestHarness()
pkt := synPacket{TraceID: 1234}
h.WRemote.SendControlPacket(pkt, h.Remote)
h.R.handleNextPacket()
if len(h.Super.Messages) != 1 {
t.Fatal(h.Super.Messages)
}
msg := h.Super.Messages[0].(controlMsg[synPacket])
if !reflect.DeepEqual(pkt, msg.Packet) {
t.Fatal(msg.Packet)
}
}
// Testing that a short packet is ignored.
func TestConnReader_handleNextPacket_short(t *testing.T) {
h := newConnReadeTestHarness()
h.Pipe.WriteToUDPAddrPort([]byte{1, 2, 3}, netip.AddrPort{})
h.R.handleNextPacket()
if len(h.Super.Messages) != 0 {
t.Fatal(h.Super.Messages)
}
}
// Testing that a packet with an unexpected stream ID is ignored.
func TestConnReader_handleNextPacket_unknownStreamID(t *testing.T) {
h := newConnReadeTestHarness()
pkt := synPacket{TraceID: 1234}
encrypted := h.WRemote.encryptControlPacket(pkt, h.Remote)
var header header
header.Parse(encrypted)
header.StreamID = 100
header.Marshal(encrypted)
h.WRemote.writeTo(encrypted, netip.AddrPort{})
h.R.handleNextPacket()
if len(h.Super.Messages) != 0 {
t.Fatal(h.Super.Messages)
}
}
// Testing that control packet without matching control cipher is ignored.
func TestConnReader_handleControlPacket_noCipher(t *testing.T) {
h := newConnReadeTestHarness()
pkt := synPacket{TraceID: 1234}
encrypted := h.WRemote.encryptControlPacket(pkt, h.Remote)
var header header
header.Parse(encrypted)
header.SourceIP = 10
header.Marshal(encrypted)
h.WRemote.writeTo(encrypted, netip.AddrPort{})
h.R.handleNextPacket()
if len(h.Super.Messages) != 0 {
t.Fatal(h.Super.Messages)
}
}
// Testing that control packet with incrrect destination IP is ignored.
func TestConnReader_handleControlPacket_incorrectDest(t *testing.T) {
h := newConnReadeTestHarness()
pkt := synPacket{TraceID: 1234}
encrypted := h.WRemote.encryptControlPacket(pkt, h.Remote)
var header header
header.Parse(encrypted)
header.DestIP++
header.Marshal(encrypted)
h.WRemote.writeTo(encrypted, netip.AddrPort{})
h.R.handleNextPacket()
if len(h.Super.Messages) != 0 {
t.Fatal(h.Super.Messages)
}
}
// Testing that modified control packet is ignored.
func TestConnReader_handleControlPacket_modified(t *testing.T) {
h := newConnReadeTestHarness()
pkt := synPacket{TraceID: 1234}
encrypted := h.WRemote.encryptControlPacket(pkt, h.Remote)
encrypted[len(encrypted)-1]++
h.WRemote.writeTo(encrypted, netip.AddrPort{})
h.R.handleNextPacket()
if len(h.Super.Messages) != 0 {
t.Fatal(h.Super.Messages)
}
}
type emptyPacket struct{}
func (p emptyPacket) Marshal(buf []byte) []byte {
return buf[:0]
}
// Testing that an empty control packet is ignored.
func TestConnReader_handleControlPacket_empty(t *testing.T) {
h := newConnReadeTestHarness()
pkt := emptyPacket{}
encrypted := h.WRemote.encryptControlPacket(pkt, h.Remote)
h.WRemote.writeTo(encrypted, netip.AddrPort{})
h.R.handleNextPacket()
if len(h.Super.Messages) != 0 {
t.Fatal(h.Super.Messages)
}
}
// Testing that a duplicate control packet is ignored.
func TestConnReader_handleControlPacket_duplicate(t *testing.T) {
h := newConnReadeTestHarness()
pkt := synPacket{TraceID: 1234}
log.Printf("%d", h.WRemote.counters[1])
h.WRemote.SendControlPacket(pkt, h.Remote)
log.Printf("%d", h.WRemote.counters[1])
// Rewind the counter.
h.WRemote.counters[1] = h.WRemote.counters[1] - 1
log.Printf("%d", h.WRemote.counters[1])
h.WRemote.SendControlPacket(pkt, h.Remote)
h.R.handleNextPacket()
h.R.handleNextPacket()
if len(h.Super.Messages) != 1 {
t.Fatal(h.Super.Messages)
}
msg := h.Super.Messages[0].(controlMsg[synPacket])
if !reflect.DeepEqual(pkt, msg.Packet) {
t.Fatal(msg.Packet)
}
}
type invalidPacket struct {
}
func (p invalidPacket) Marshal(b []byte) []byte {
out := b[:256]
clear(out)
return out
}
// Testing that an invalid control packet is ignored (fails to parse).
func TestConnReader_handleControlPacket_cantParse(t *testing.T) {
h := newConnReadeTestHarness()
pkt := invalidPacket{}
encrypted := h.WRemote.encryptControlPacket(pkt, h.Remote)
h.WRemote.writeTo(encrypted, netip.AddrPort{})
h.R.handleNextPacket()
if len(h.Super.Messages) != 0 {
t.Fatal(h.Super.Messages)
}
}
// Testing that we can receive a data packet.
func TestConnReader_handleDataPacket(t *testing.T) {
h := newConnReadeTestHarness()
pkt := make([]byte, 1024)
rand.Read(pkt)
h.WRemote.SendDataPacket(pkt, h.Remote)
h.R.handleNextPacket()
if len(h.IFace.Written) != 1 {
t.Fatal(h.IFace.Written)
}
if !bytes.Equal(pkt, h.IFace.Written[0]) {
t.Fatal(h.IFace.Written)
}
}
// Testing that data packet is ignored if route isn't up.
func TestConnReader_handleDataPacket_routeDown(t *testing.T) {
h := newConnReadeTestHarness()
pkt := make([]byte, 1024)
rand.Read(pkt)
h.WRemote.SendDataPacket(pkt, h.Remote)
route := h.R.routes[2].Load()
route.Up = false
h.R.handleNextPacket()
if len(h.IFace.Written) != 0 {
t.Fatal(h.IFace.Written)
}
}
*/
// Testing that a duplicate data packet is ignored.
// Testing that we send a relayed data packet.
// Testing that a relayed data packet is ignored if destination isn't up.

80
peer/connwriter.go Normal file
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package peer
import (
"log"
"net/netip"
"sync"
)
// ----------------------------------------------------------------------------
type connWriter struct {
localIP byte
conn udpWriter
// For sending control packets.
cBuf1 []byte
cBuf2 []byte
// For sending data packets.
dBuf1 []byte
dBuf2 []byte
// Lock around for sending on UDP Conn.
wLock sync.Mutex
}
func newConnWriter(conn udpWriter, localIP byte) *connWriter {
w := &connWriter{
localIP: localIP,
conn: conn,
cBuf1: make([]byte, bufferSize),
cBuf2: make([]byte, bufferSize),
dBuf1: make([]byte, bufferSize),
dBuf2: make([]byte, bufferSize),
}
return w
}
// Not safe for concurrent use. Should only be called by supervisor.
func (w *connWriter) SendControlPacket(pkt marshaller, route *peerRoute) {
enc := encryptControlPacket(w.localIP, route, pkt, w.cBuf1, w.cBuf2)
w.writeTo(enc, route.RemoteAddr)
}
// Relay control packet. Route must not be nil.
func (w *connWriter) RelayControlPacket(pkt marshaller, route, relay *peerRoute) {
enc := encryptControlPacket(w.localIP, route, pkt, w.cBuf1, w.cBuf2)
enc = encryptDataPacket(w.localIP, route.IP, relay, enc, w.cBuf1)
w.writeTo(enc, relay.RemoteAddr)
}
// Not safe for concurrent use. Should only be called by ifReader.
func (w *connWriter) SendDataPacket(pkt []byte, route *peerRoute) {
enc := encryptDataPacket(w.localIP, route.IP, route, pkt, w.dBuf1)
w.writeTo(enc, route.RemoteAddr)
}
// Relay a data packet. Route must not be nil.
func (w *connWriter) RelayDataPacket(pkt []byte, route, relay *peerRoute) {
enc := encryptDataPacket(w.localIP, route.IP, route, pkt, w.dBuf1)
enc = encryptDataPacket(w.localIP, route.IP, relay, enc, w.dBuf2)
w.writeTo(enc, relay.RemoteAddr)
}
// Safe for concurrent use. Should only be called by connReader.
//
// This function will send pkt to the peer directly. This is used when a peer
// is acting as a relay and is forwarding already encrypted data for another
// peer.
func (w *connWriter) SendEncryptedDataPacket(pkt []byte, route *peerRoute) {
w.writeTo(pkt, route.RemoteAddr)
}
func (w *connWriter) writeTo(packet []byte, addr netip.AddrPort) {
w.wLock.Lock()
if _, err := w.conn.WriteToUDPAddrPort(packet, addr); err != nil {
log.Printf("[ConnWriter] Failed to write to UDP port: %v", err)
}
w.wLock.Unlock()
}

240
peer/connwriter_test.go Normal file
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package peer
import (
"bytes"
"net/netip"
"testing"
)
// ----------------------------------------------------------------------------
type testUDPPacket struct {
Addr netip.AddrPort
Data []byte
}
type testUDPAddrPortWriter struct {
written []testUDPPacket
}
func (w *testUDPAddrPortWriter) WriteToUDPAddrPort(b []byte, addr netip.AddrPort) (int, error) {
w.written = append(w.written, testUDPPacket{
Addr: addr,
Data: bytes.Clone(b),
})
return len(b), nil
}
func (w *testUDPAddrPortWriter) Written() []testUDPPacket {
out := w.written
w.written = []testUDPPacket{}
return out
}
// ----------------------------------------------------------------------------
type testPacket string
func (p testPacket) Marshal(b []byte) []byte {
b = b[:len(p)]
copy(b, []byte(p))
return b
}
// ----------------------------------------------------------------------------
func testConnWriter_getTestRoutes() (local, remote, relayLocal, relayRemote *peerRoute) {
localKeys := generateKeys()
remoteKeys := generateKeys()
local = newPeerRoute(2)
local.Up = true
local.Relay = false
local.PubSignKey = remoteKeys.PubSignKey
local.ControlCipher = newControlCipher(localKeys.PrivKey, remoteKeys.PubKey)
local.DataCipher = newDataCipher()
local.RemoteAddr = netip.AddrPortFrom(netip.AddrFrom4([4]byte{1, 1, 1, 2}), 100)
remote = newPeerRoute(1)
remote.Up = true
remote.Relay = false
remote.PubSignKey = localKeys.PubSignKey
remote.ControlCipher = newControlCipher(remoteKeys.PrivKey, localKeys.PubKey)
remote.DataCipher = local.DataCipher
remote.RemoteAddr = netip.AddrPortFrom(netip.AddrFrom4([4]byte{1, 1, 1, 1}), 100)
rLocalKeys := generateKeys()
rRemoteKeys := generateKeys()
relayLocal = newPeerRoute(3)
relayLocal.Up = true
relayLocal.Relay = true
relayLocal.Direct = true
relayLocal.PubSignKey = rRemoteKeys.PubSignKey
relayLocal.ControlCipher = newControlCipher(rLocalKeys.PrivKey, rRemoteKeys.PubKey)
relayLocal.DataCipher = newDataCipher()
relayLocal.RemoteAddr = netip.AddrPortFrom(netip.AddrFrom4([4]byte{1, 1, 1, 3}), 100)
relayRemote = newPeerRoute(1)
relayRemote.Up = true
relayRemote.Relay = false
relayRemote.Direct = true
relayRemote.PubSignKey = rLocalKeys.PubSignKey
relayRemote.ControlCipher = newControlCipher(rRemoteKeys.PrivKey, rLocalKeys.PubKey)
relayRemote.DataCipher = relayLocal.DataCipher
relayRemote.RemoteAddr = netip.AddrPortFrom(netip.AddrFrom4([4]byte{1, 1, 1, 1}), 100)
return
}
// ----------------------------------------------------------------------------
// Testing if we can send a control packet directly to the remote route.
func TestConnWriter_SendControlPacket_direct(t *testing.T) {
route, rRoute, _, _ := testConnWriter_getTestRoutes()
route.Direct = true
writer := &testUDPAddrPortWriter{}
w := newConnWriter(writer, rRoute.IP)
in := testPacket("hello world!")
w.SendControlPacket(in, route)
out := writer.Written()
if len(out) != 1 {
t.Fatal(out)
}
if out[0].Addr != route.RemoteAddr {
t.Fatal(out[0])
}
dec, ok := rRoute.ControlCipher.Decrypt(out[0].Data, make([]byte, 1024))
if !ok {
t.Fatal(ok)
}
if string(dec) != string(in) {
t.Fatal(dec)
}
}
// Testing if we can relay a packet via an intermediary.
func TestConnWriter_RelayControlPacket_relay(t *testing.T) {
route, rRoute, relay, rRelay := testConnWriter_getTestRoutes()
writer := &testUDPAddrPortWriter{}
w := newConnWriter(writer, rRoute.IP)
in := testPacket("hello world!")
w.RelayControlPacket(in, route, relay)
out := writer.Written()
if len(out) != 1 {
t.Fatal(out)
}
if out[0].Addr != relay.RemoteAddr {
t.Fatal(out[0])
}
dec, ok := rRelay.DataCipher.Decrypt(out[0].Data, make([]byte, 1024))
if !ok {
t.Fatal(ok)
}
dec2, ok := rRoute.ControlCipher.Decrypt(dec, make([]byte, 1024))
if !ok {
t.Fatal(ok)
}
if string(dec2) != string(in) {
t.Fatal(dec2)
}
}
// Testing that we can send a data packet directly to a remote route.
func TestConnWriter_SendDataPacket_direct(t *testing.T) {
route, rRoute, _, _ := testConnWriter_getTestRoutes()
route.Direct = true
writer := &testUDPAddrPortWriter{}
w := newConnWriter(writer, rRoute.IP)
in := []byte("hello world!")
w.SendDataPacket(in, route)
out := writer.Written()
if len(out) != 1 {
t.Fatal(out)
}
if out[0].Addr != route.RemoteAddr {
t.Fatal(out[0])
}
dec, ok := rRoute.DataCipher.Decrypt(out[0].Data, make([]byte, 1024))
if !ok {
t.Fatal(ok)
}
if !bytes.Equal(dec, in) {
t.Fatal(dec)
}
}
// Testing that we can relay a data packet via a relay.
func TestConnWriter_RelayDataPacket_relay(t *testing.T) {
route, rRoute, relay, rRelay := testConnWriter_getTestRoutes()
writer := &testUDPAddrPortWriter{}
w := newConnWriter(writer, rRoute.IP)
in := []byte("Hello world!")
w.RelayDataPacket(in, route, relay)
out := writer.Written()
if len(out) != 1 {
t.Fatal(out)
}
if out[0].Addr != relay.RemoteAddr {
t.Fatal(out[0])
}
dec, ok := rRelay.DataCipher.Decrypt(out[0].Data, make([]byte, 1024))
if !ok {
t.Fatal(ok)
}
dec2, ok := rRoute.DataCipher.Decrypt(dec, make([]byte, 1024))
if !ok {
t.Fatal(ok)
}
if !bytes.Equal(dec2, in) {
t.Fatal(dec2)
}
}
// Testing that we can send an already encrypted packet.
func TestConnWriter_SendEncryptedDataPacket(t *testing.T) {
route, rRoute, _, _ := testConnWriter_getTestRoutes()
writer := &testUDPAddrPortWriter{}
w := newConnWriter(writer, rRoute.IP)
in := []byte("Hello world!")
w.SendEncryptedDataPacket(in, route)
out := writer.Written()
if len(out) != 1 {
t.Fatal(out)
}
if out[0].Addr != route.RemoteAddr {
t.Fatal(out[0])
}
if !bytes.Equal(out[0].Data, in) {
t.Fatal(out[0])
}
}

58
peer/controlmessage.go Normal file
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package peer
import (
"net/netip"
"vppn/m"
)
// ----------------------------------------------------------------------------
type controlMsg[T any] struct {
SrcIP byte
SrcAddr netip.AddrPort
// TODO: RecvdAt int64 // Unixmilli.
Packet T
}
func parseControlMsg(srcIP byte, srcAddr netip.AddrPort, buf []byte) (any, error) {
switch buf[0] {
case packetTypeSyn:
packet, err := parseSynPacket(buf)
return controlMsg[synPacket]{
SrcIP: srcIP,
SrcAddr: srcAddr,
Packet: packet,
}, err
case packetTypeAck:
packet, err := parseAckPacket(buf)
return controlMsg[ackPacket]{
SrcIP: srcIP,
SrcAddr: srcAddr,
Packet: packet,
}, err
case packetTypeProbe:
packet, err := parseProbePacket(buf)
return controlMsg[probePacket]{
SrcIP: srcIP,
SrcAddr: srcAddr,
Packet: packet,
}, err
default:
return nil, errUnknownPacketType
}
}
// ----------------------------------------------------------------------------
type peerUpdateMsg struct {
PeerIP byte
Peer *m.Peer
}
// ----------------------------------------------------------------------------
type pingTimerMsg struct{}

113
peer/crypto.go Normal file
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package peer
import (
"crypto/rand"
"log"
"net/netip"
"sync/atomic"
"golang.org/x/crypto/nacl/box"
"golang.org/x/crypto/nacl/sign"
)
type cryptoKeys struct {
PubKey []byte
PrivKey []byte
PubSignKey []byte
PrivSignKey []byte
}
func generateKeys() cryptoKeys {
pubKey, privKey, err := box.GenerateKey(rand.Reader)
if err != nil {
log.Fatalf("Failed to generate encryption keys: %v", err)
}
pubSignKey, privSignKey, err := sign.GenerateKey(rand.Reader)
if err != nil {
log.Fatalf("Failed to generate signing keys: %v", err)
}
return cryptoKeys{pubKey[:], privKey[:], pubSignKey[:], privSignKey[:]}
}
// ----------------------------------------------------------------------------
// Route must have a ControlCipher.
func encryptControlPacket(
localIP byte,
route *peerRoute,
pkt marshaller,
tmp []byte,
out []byte,
) []byte {
h := header{
StreamID: controlStreamID,
Counter: atomic.AddUint64(route.Counter, 1),
SourceIP: localIP,
DestIP: route.IP,
}
tmp = pkt.Marshal(tmp)
return route.ControlCipher.Encrypt(h, tmp, out)
}
// Returns a controlMsg[PacketType]. Route must have ControlCipher.
func decryptControlPacket(
route *peerRoute,
fromAddr netip.AddrPort,
h header,
encrypted []byte,
tmp []byte,
) (any, error) {
out, ok := route.ControlCipher.Decrypt(encrypted, tmp)
if !ok {
return nil, errDecryptionFailed
}
if route.DupCheck.IsDup(h.Counter) {
return nil, errDuplicateSeqNum
}
msg, err := parseControlMsg(h.SourceIP, fromAddr, out)
if err != nil {
return nil, err
}
return msg, nil
}
// ----------------------------------------------------------------------------
func encryptDataPacket(
localIP byte,
destIP byte,
route *peerRoute,
data []byte,
out []byte,
) []byte {
h := header{
StreamID: dataStreamID,
Counter: atomic.AddUint64(route.Counter, 1),
SourceIP: localIP,
DestIP: destIP,
}
return route.DataCipher.Encrypt(h, data, out)
}
func decryptDataPacket(
route *peerRoute,
h header,
encrypted []byte,
out []byte,
) ([]byte, error) {
dec, ok := route.DataCipher.Decrypt(encrypted, out)
if !ok {
return nil, errDecryptionFailed
}
if route.DupCheck.IsDup(h.Counter) {
return nil, errDuplicateSeqNum
}
return dec, nil
}

213
peer/crypto_test.go Normal file
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@@ -0,0 +1,213 @@
package peer
import (
"bytes"
"crypto/rand"
"errors"
"net/netip"
"reflect"
"testing"
)
func newRoutePairForTesting() (*peerRoute, *peerRoute) {
keys1 := generateKeys()
keys2 := generateKeys()
r1 := newPeerRoute(1)
r1.PubSignKey = keys1.PubSignKey
r1.ControlCipher = newControlCipher(keys1.PrivKey, keys2.PubKey)
r1.DataCipher = newDataCipher()
r2 := newPeerRoute(2)
r2.PubSignKey = keys2.PubSignKey
r2.ControlCipher = newControlCipher(keys2.PrivKey, keys1.PubKey)
r2.DataCipher = r1.DataCipher
return r1, r2
}
func TestDecryptControlPacket(t *testing.T) {
var (
r1, r2 = newRoutePairForTesting()
tmp = make([]byte, bufferSize)
out = make([]byte, bufferSize)
)
in := synPacket{
TraceID: newTraceID(),
SharedKey: r1.DataCipher.Key(),
Direct: true,
}
enc := encryptControlPacket(r1.IP, r2, in, tmp, out)
h, ok := parseHeader(enc)
if !ok {
t.Fatal(h, ok)
}
iMsg, err := decryptControlPacket(r2, netip.AddrPort{}, h, enc, tmp)
if err != nil {
t.Fatal(err)
}
msg, ok := iMsg.(controlMsg[synPacket])
if !ok {
t.Fatal(ok)
}
if !reflect.DeepEqual(msg.Packet, in) {
t.Fatal(msg)
}
}
func TestDecryptControlPacket_decryptionFailed(t *testing.T) {
var (
r1, r2 = newRoutePairForTesting()
tmp = make([]byte, bufferSize)
out = make([]byte, bufferSize)
)
in := synPacket{
TraceID: newTraceID(),
SharedKey: r1.DataCipher.Key(),
Direct: true,
}
enc := encryptControlPacket(r1.IP, r2, in, tmp, out)
h, ok := parseHeader(enc)
if !ok {
t.Fatal(h, ok)
}
for i := range enc {
x := bytes.Clone(enc)
x[i]++
_, err := decryptControlPacket(r2, netip.AddrPort{}, h, x, tmp)
if !errors.Is(err, errDecryptionFailed) {
t.Fatal(i, err)
}
}
}
func TestDecryptControlPacket_duplicate(t *testing.T) {
var (
r1, r2 = newRoutePairForTesting()
tmp = make([]byte, bufferSize)
out = make([]byte, bufferSize)
)
in := synPacket{
TraceID: newTraceID(),
SharedKey: r1.DataCipher.Key(),
Direct: true,
}
enc := encryptControlPacket(r1.IP, r2, in, tmp, out)
h, ok := parseHeader(enc)
if !ok {
t.Fatal(h, ok)
}
if _, err := decryptControlPacket(r2, netip.AddrPort{}, h, enc, tmp); err != nil {
t.Fatal(err)
}
_, err := decryptControlPacket(r2, netip.AddrPort{}, h, enc, tmp)
if !errors.Is(err, errDuplicateSeqNum) {
t.Fatal(err)
}
}
func TestDecryptControlPacket_invalidPacket(t *testing.T) {
var (
r1, r2 = newRoutePairForTesting()
tmp = make([]byte, bufferSize)
out = make([]byte, bufferSize)
)
in := testPacket("hello!")
enc := encryptControlPacket(r1.IP, r2, in, tmp, out)
h, ok := parseHeader(enc)
if !ok {
t.Fatal(h, ok)
}
_, err := decryptControlPacket(r2, netip.AddrPort{}, h, enc, tmp)
if !errors.Is(err, errUnknownPacketType) {
t.Fatal(err)
}
}
func TestDecryptDataPacket(t *testing.T) {
var (
r1, r2 = newRoutePairForTesting()
out = make([]byte, bufferSize)
data = make([]byte, 1024)
)
rand.Read(data)
enc := encryptDataPacket(r1.IP, r2.IP, r2, data, out)
h, ok := parseHeader(enc)
if !ok {
t.Fatal(h, ok)
}
out, err := decryptDataPacket(r1, h, bytes.Clone(enc), out)
if err != nil {
t.Fatal(err)
}
if !bytes.Equal(data, out) {
t.Fatal(data, out)
}
}
func TestDecryptDataPacket_incorrectCipher(t *testing.T) {
var (
r1, r2 = newRoutePairForTesting()
out = make([]byte, bufferSize)
data = make([]byte, 1024)
)
rand.Read(data)
enc := encryptDataPacket(r1.IP, r2.IP, r2, data, bytes.Clone(out))
h, ok := parseHeader(enc)
if !ok {
t.Fatal(h, ok)
}
r1.DataCipher = newDataCipher()
_, err := decryptDataPacket(r1, h, enc, bytes.Clone(out))
if !errors.Is(err, errDecryptionFailed) {
t.Fatal(err)
}
}
func TestDecryptDataPacket_duplicate(t *testing.T) {
var (
r1, r2 = newRoutePairForTesting()
out = make([]byte, bufferSize)
data = make([]byte, 1024)
)
rand.Read(data)
enc := encryptDataPacket(r1.IP, r2.IP, r2, data, bytes.Clone(out))
h, ok := parseHeader(enc)
if !ok {
t.Fatal(h, ok)
}
_, err := decryptDataPacket(r1, h, enc, bytes.Clone(out))
if err != nil {
t.Fatal(err)
}
_, err = decryptDataPacket(r1, h, enc, bytes.Clone(out))
if !errors.Is(err, errDuplicateSeqNum) {
t.Fatal(err)
}
}

76
peer/dupcheck.go Normal file
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package peer
type dupCheck struct {
bitSet
head int
tail int
headCounter uint64
tailCounter uint64 // Also next expected counter value.
}
func newDupCheck(headCounter uint64) *dupCheck {
return &dupCheck{
headCounter: headCounter,
tailCounter: headCounter + 1,
tail: 1,
}
}
func (dc *dupCheck) IsDup(counter uint64) bool {
// Before head => it's late, say it's a dup.
if counter < dc.headCounter {
return true
}
// It's within the counter bounds.
if counter < dc.tailCounter {
index := (int(counter-dc.headCounter) + dc.head) % bitSetSize
if dc.Get(index) {
return true
}
dc.Set(index)
return false
}
// It's more than 1 beyond the tail.
delta := counter - dc.tailCounter
// Full clear.
if delta >= bitSetSize-1 {
dc.ClearAll()
dc.Set(0)
dc.tail = 1
dc.head = 2
dc.tailCounter = counter + 1
dc.headCounter = dc.tailCounter - bitSetSize + 1
return false
}
// Clear if necessary.
for i := 0; i < int(delta); i++ {
dc.put(false)
}
dc.put(true)
return false
}
func (dc *dupCheck) put(set bool) {
if set {
dc.Set(dc.tail)
} else {
dc.Clear(dc.tail)
}
dc.tail = (dc.tail + 1) % bitSetSize
dc.tailCounter++
if dc.head == dc.tail {
dc.head = (dc.head + 1) % bitSetSize
dc.headCounter++
}
}

57
peer/dupcheck_test.go Normal file
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package peer
import (
"testing"
)
func TestDupCheck(t *testing.T) {
dc := newDupCheck(0)
for i := range bitSetSize {
if dc.IsDup(uint64(i)) {
t.Fatal("!")
}
}
type TestCase struct {
Counter uint64
Dup bool
}
testCases := []TestCase{
{511, true},
{0, true},
{1, true},
{2, true},
{3, true},
{63, true},
{256, true},
{510, true},
{511, true},
{512, false},
{0, true},
{512, true},
{513, false},
{517, false},
{512, true},
{513, true},
{514, false},
{515, false},
{516, false},
{517, true},
{2512, false},
{2512, true},
{2001, true},
{2002, false},
{2002, true},
{4000, false},
{4000 - 511, true}, // Too old.
{4000 - 510, false}, // Just in the window.
}
for i, tc := range testCases {
if ok := dc.IsDup(tc.Counter); ok != tc.Dup {
t.Fatal(i, ok, tc)
}
}
}

10
peer/errors.go Normal file
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package peer
import "errors"
var (
errDecryptionFailed = errors.New("decryption failed")
errDuplicateSeqNum = errors.New("duplicate sequence number")
errMalformedPacket = errors.New("malformed packet")
errUnknownPacketType = errors.New("unknown packet type")
)

19
peer/globals.go Normal file
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package peer
import (
"net"
"net/netip"
)
const (
bufferSize = 1536
if_mtu = 1200
if_queue_len = 2048
controlCipherOverhead = 16
dataCipherOverhead = 16
signOverhead = 64
)
var multicastAddr = net.UDPAddrFromAddrPort(netip.AddrPortFrom(
netip.AddrFrom4([4]byte{224, 0, 0, 157}),
4560))

49
peer/header.go Normal file
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package peer
import "unsafe"
// ----------------------------------------------------------------------------
const (
headerSize = 12
controlStreamID = 2
controlHeaderSize = 24
dataStreamID = 1
dataHeaderSize = 12
)
type header struct {
Version byte
StreamID byte
SourceIP byte
DestIP byte
Counter uint64 // Init with time.Now().Unix << 30 to ensure monotonic.
}
func parseHeader(b []byte) (h header, ok bool) {
if len(b) < headerSize {
return
}
h.Version = b[0]
h.StreamID = b[1]
h.SourceIP = b[2]
h.DestIP = b[3]
h.Counter = *(*uint64)(unsafe.Pointer(&b[4]))
return h, true
}
func (h *header) Parse(b []byte) {
h.Version = b[0]
h.StreamID = b[1]
h.SourceIP = b[2]
h.DestIP = b[3]
h.Counter = *(*uint64)(unsafe.Pointer(&b[4]))
}
func (h *header) Marshal(buf []byte) {
buf[0] = h.Version
buf[1] = h.StreamID
buf[2] = h.SourceIP
buf[3] = h.DestIP
*(*uint64)(unsafe.Pointer(&buf[4])) = h.Counter
}

21
peer/header_test.go Normal file
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@@ -0,0 +1,21 @@
package peer
import "testing"
func TestHeaderMarshalParse(t *testing.T) {
nIn := header{
StreamID: 23,
Counter: 3212,
SourceIP: 34,
DestIP: 200,
}
buf := make([]byte, headerSize)
nIn.Marshal(buf)
nOut := header{}
nOut.Parse(buf)
if nIn != nOut {
t.Fatal(nIn, nOut)
}
}

100
peer/ifreader.go Normal file
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package peer
import (
"io"
"log"
"sync/atomic"
)
type ifReader struct {
iface io.Reader
routes [256]*atomic.Pointer[peerRoute]
relay *atomic.Pointer[peerRoute]
sender dataPacketSender
}
func newIFReader(
iface io.Reader,
routes [256]*atomic.Pointer[peerRoute],
relay *atomic.Pointer[peerRoute],
sender dataPacketSender,
) *ifReader {
return &ifReader{
iface: iface,
routes: routes,
relay: relay,
sender: sender,
}
}
func (r *ifReader) Run() {
var (
packet = make([]byte, bufferSize)
remoteIP byte
ok bool
)
for {
packet = r.readNextPacket(packet)
if remoteIP, ok = r.parsePacket(packet); ok {
r.sendPacket(packet, remoteIP)
}
}
}
func (r *ifReader) sendPacket(pkt []byte, remoteIP byte) {
route := r.routes[remoteIP].Load()
if !route.Up {
log.Printf("Route not connected: %d", remoteIP)
return
}
// Direct path => early return.
if route.Direct {
r.sender.SendDataPacket(pkt, route)
return
}
if relay := r.relay.Load(); relay != nil && relay.Up {
r.sender.RelayDataPacket(pkt, route, relay)
}
}
// Get next packet, returning packet, and destination ip.
func (r *ifReader) readNextPacket(buf []byte) []byte {
n, err := r.iface.Read(buf[:cap(buf)])
if err != nil {
log.Fatalf("Failed to read from interface: %v", err)
}
return buf[:n]
}
func (r *ifReader) parsePacket(buf []byte) (byte, bool) {
n := len(buf)
if n == 0 {
return 0, false
}
version := buf[0] >> 4
switch version {
case 4:
if n < 20 {
log.Printf("Short IPv4 packet: %d", len(buf))
return 0, false
}
return buf[19], true
case 6:
if len(buf) < 40 {
log.Printf("Short IPv6 packet: %d", len(buf))
return 0, false
}
return buf[39], true
default:
log.Printf("Invalid IP packet version: %v", version)
return 0, false
}
}

232
peer/ifreader_test.go Normal file
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package peer
import (
"bytes"
"net"
"reflect"
"sync/atomic"
"testing"
)
// Test that we parse IPv4 packets correctly.
func TestIFReader_parsePacket_ipv4(t *testing.T) {
r := newIFReader(nil, [256]*atomic.Pointer[peerRoute]{}, nil, nil)
pkt := make([]byte, 1234)
pkt[0] = 4 << 4
pkt[19] = 128
if ip, ok := r.parsePacket(pkt); !ok || ip != 128 {
t.Fatal(ip, ok)
}
}
// Test that we parse IPv6 packets correctly.
func TestIFReader_parsePacket_ipv6(t *testing.T) {
r := newIFReader(nil, [256]*atomic.Pointer[peerRoute]{}, nil, nil)
pkt := make([]byte, 1234)
pkt[0] = 6 << 4
pkt[39] = 42
if ip, ok := r.parsePacket(pkt); !ok || ip != 42 {
t.Fatal(ip, ok)
}
}
// Test that empty packets work as expected.
func TestIFReader_parsePacket_emptyPacket(t *testing.T) {
r := newIFReader(nil, [256]*atomic.Pointer[peerRoute]{}, nil, nil)
pkt := make([]byte, 0)
if ip, ok := r.parsePacket(pkt); ok {
t.Fatal(ip, ok)
}
}
// Test that invalid IP versions fail.
func TestIFReader_parsePacket_invalidIPVersion(t *testing.T) {
r := newIFReader(nil, [256]*atomic.Pointer[peerRoute]{}, nil, nil)
for i := byte(1); i < 16; i++ {
if i == 4 || i == 6 {
continue
}
pkt := make([]byte, 1234)
pkt[0] = i << 4
if ip, ok := r.parsePacket(pkt); ok {
t.Fatal(i, ip, ok)
}
}
}
// Test that short IPv4 packets fail.
func TestIFReader_parsePacket_shortIPv4(t *testing.T) {
r := newIFReader(nil, [256]*atomic.Pointer[peerRoute]{}, nil, nil)
pkt := make([]byte, 19)
pkt[0] = 4 << 4
if ip, ok := r.parsePacket(pkt); ok {
t.Fatal(ip, ok)
}
}
// Test that short IPv6 packets fail.
func TestIFReader_parsePacket_shortIPv6(t *testing.T) {
r := newIFReader(nil, [256]*atomic.Pointer[peerRoute]{}, nil, nil)
pkt := make([]byte, 39)
pkt[0] = 6 << 4
if ip, ok := r.parsePacket(pkt); ok {
t.Fatal(ip, ok)
}
}
// Test that we can read a packet.
func TestIFReader_readNextpacket(t *testing.T) {
in, out := net.Pipe()
r := newIFReader(out, [256]*atomic.Pointer[peerRoute]{}, nil, nil)
defer in.Close()
defer out.Close()
go in.Write([]byte("hello world!"))
pkt := r.readNextPacket(make([]byte, bufferSize))
if !bytes.Equal(pkt, []byte("hello world!")) {
t.Fatalf("%s", pkt)
}
}
// ----------------------------------------------------------------------------
type sentPacket struct {
Relayed bool
Packet []byte
Route peerRoute
Relay peerRoute
}
type sendPacketTestHarness struct {
Packets []sentPacket
}
func (h *sendPacketTestHarness) SendDataPacket(pkt []byte, route *peerRoute) {
h.Packets = append(h.Packets, sentPacket{
Packet: bytes.Clone(pkt),
Route: *route,
})
}
func (h *sendPacketTestHarness) RelayDataPacket(pkt []byte, route, relay *peerRoute) {
h.Packets = append(h.Packets, sentPacket{
Relayed: true,
Packet: bytes.Clone(pkt),
Route: *route,
Relay: *relay,
})
}
func newIFReaderForSendPacketTesting() (*ifReader, *sendPacketTestHarness) {
h := &sendPacketTestHarness{}
routes := [256]*atomic.Pointer[peerRoute]{}
for i := range routes {
routes[i] = &atomic.Pointer[peerRoute]{}
routes[i].Store(&peerRoute{})
}
relay := &atomic.Pointer[peerRoute]{}
r := newIFReader(nil, routes, relay, h)
return r, h
}
// Testing that we can send a packet directly.
func TestIFReader_sendPacket_direct(t *testing.T) {
r, h := newIFReaderForSendPacketTesting()
route := r.routes[2].Load()
route.Up = true
route.Direct = true
in := []byte("hello world")
r.sendPacket(in, 2)
if len(h.Packets) != 1 {
t.Fatal(h.Packets)
}
expected := sentPacket{
Relayed: false,
Packet: in,
Route: *route,
}
if !reflect.DeepEqual(h.Packets[0], expected) {
t.Fatal(h.Packets[0])
}
}
// Testing that we don't send a packet if route isn't up.
func TestIFReader_sendPacket_directNotUp(t *testing.T) {
r, h := newIFReaderForSendPacketTesting()
route := r.routes[2].Load()
route.Direct = true
in := []byte("hello world")
r.sendPacket(in, 2)
if len(h.Packets) != 0 {
t.Fatal(h.Packets)
}
}
// Testing that we can send a packet via a relay.
func TestIFReader_sendPacket_relayed(t *testing.T) {
r, h := newIFReaderForSendPacketTesting()
route := r.routes[2].Load()
route.Up = true
route.Direct = false
relay := r.routes[3].Load()
r.relay.Store(relay)
relay.Up = true
relay.Direct = true
in := []byte("hello world")
r.sendPacket(in, 2)
if len(h.Packets) != 1 {
t.Fatal(h.Packets)
}
expected := sentPacket{
Relayed: true,
Packet: in,
Route: *route,
Relay: *relay,
}
if !reflect.DeepEqual(h.Packets[0], expected) {
t.Fatal(h.Packets[0])
}
}
// Testing that we don't try to send on a nil relay IP.
func TestIFReader_sendPacket_nilRealy(t *testing.T) {
r, h := newIFReaderForSendPacketTesting()
route := r.routes[2].Load()
route.Up = true
route.Direct = false
in := []byte("hello world")
r.sendPacket(in, 2)
if len(h.Packets) != 0 {
t.Fatal(h.Packets)
}
}

5
peer/ifwriter.go Normal file
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@@ -0,0 +1,5 @@
package peer
import "io"
type ifWriter io.Writer

28
peer/interfaces.go Normal file
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@@ -0,0 +1,28 @@
package peer
import "net/netip"
type udpReader interface {
ReadFromUDPAddrPort(b []byte) (n int, addr netip.AddrPort, err error)
}
type udpWriter interface {
WriteToUDPAddrPort([]byte, netip.AddrPort) (int, error)
}
type marshaller interface {
Marshal([]byte) []byte
}
type dataPacketSender interface {
SendDataPacket(pkt []byte, route *peerRoute)
RelayDataPacket(pkt []byte, route, relay *peerRoute)
}
type encryptedPacketSender interface {
SendEncryptedDataPacket(pkt []byte, route *peerRoute)
}
type controlMsgHandler interface {
HandleControlMsg(pkt any)
}

62
peer/mcwriter.go Normal file
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@@ -0,0 +1,62 @@
package peer
import (
"log"
"net"
"golang.org/x/crypto/nacl/sign"
)
// ----------------------------------------------------------------------------
type mcUDPWriter interface {
WriteToUDP([]byte, *net.UDPAddr) (int, error)
}
// ----------------------------------------------------------------------------
func createLocalDiscoveryPacket(localIP byte, signingKey []byte) []byte {
h := header{
SourceIP: localIP,
DestIP: 255,
}
buf := make([]byte, headerSize)
h.Marshal(buf)
out := make([]byte, headerSize+signOverhead)
return sign.Sign(out[:0], buf, (*[64]byte)(signingKey))
}
func headerFromLocalDiscoveryPacket(pkt []byte) (h header, ok bool) {
if len(pkt) != headerSize+signOverhead {
return
}
h.Parse(pkt[signOverhead:])
ok = true
return
}
func verifyLocalDiscoveryPacket(pkt, buf []byte, pubSignKey []byte) bool {
_, ok := sign.Open(buf[:0], pkt, (*[32]byte)(pubSignKey))
return ok
}
// ----------------------------------------------------------------------------
type mcWriter struct {
conn mcUDPWriter
discoveryPacket []byte
}
func newMCWriter(conn mcUDPWriter, localIP byte, signingKey []byte) *mcWriter {
return &mcWriter{
conn: conn,
discoveryPacket: createLocalDiscoveryPacket(localIP, signingKey),
}
}
func (w *mcWriter) SendLocalDiscovery() {
if _, err := w.conn.WriteToUDP(w.discoveryPacket, multicastAddr); err != nil {
log.Printf("[MCWriter] Failed to write multicast UDP packet: %v", err)
}
}

102
peer/mcwriter_test.go Normal file
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package peer
import (
"bytes"
"net"
"testing"
)
// ----------------------------------------------------------------------------
// Testing that we can create and verify a local discovery packet.
func TestVerifyLocalDiscoveryPacket_valid(t *testing.T) {
keys := generateKeys()
created := createLocalDiscoveryPacket(55, keys.PrivSignKey)
header, ok := headerFromLocalDiscoveryPacket(created)
if !ok {
t.Fatal(ok)
}
if header.SourceIP != 55 || header.DestIP != 255 {
t.Fatal(header)
}
if !verifyLocalDiscoveryPacket(created, make([]byte, 1024), keys.PubSignKey) {
t.Fatal("Not valid")
}
}
// Testing that we don't try to parse short packets.
func TestVerifyLocalDiscoveryPacket_tooShort(t *testing.T) {
keys := generateKeys()
created := createLocalDiscoveryPacket(55, keys.PrivSignKey)
_, ok := headerFromLocalDiscoveryPacket(created[:len(created)-1])
if ok {
t.Fatal(ok)
}
}
// Testing that modifying a packet makes it invalid.
func TestVerifyLocalDiscoveryPacket_invalid(t *testing.T) {
keys := generateKeys()
created := createLocalDiscoveryPacket(55, keys.PrivSignKey)
buf := make([]byte, 1024)
for i := range created {
modified := bytes.Clone(created)
modified[i]++
if verifyLocalDiscoveryPacket(modified, buf, keys.PubSignKey) {
t.Fatal("Verification should have failed.")
}
}
}
// ----------------------------------------------------------------------------
type testUDPWriter struct {
written [][]byte
}
func (w *testUDPWriter) WriteToUDP(b []byte, addr *net.UDPAddr) (int, error) {
w.written = append(w.written, bytes.Clone(b))
return len(b), nil
}
func (w *testUDPWriter) Written() [][]byte {
out := w.written
w.written = [][]byte{}
return out
}
// ----------------------------------------------------------------------------
// Testing that the mcWriter sends local discovery packets as expected.
func TestMCWriter_SendLocalDiscovery(t *testing.T) {
keys := generateKeys()
writer := &testUDPWriter{}
mcw := newMCWriter(writer, 42, keys.PrivSignKey)
mcw.SendLocalDiscovery()
out := writer.Written()
if len(out) != 1 {
t.Fatal(out)
}
pkt := out[0]
header, ok := headerFromLocalDiscoveryPacket(pkt)
if !ok {
t.Fatal(ok)
}
if header.SourceIP != 42 || header.DestIP != 255 {
t.Fatal(header)
}
if !verifyLocalDiscoveryPacket(pkt, make([]byte, 1024), keys.PubSignKey) {
t.Fatal("Verification should succeed.")
}
}

190
peer/packets-util.go Normal file
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package peer
import (
"net/netip"
"sync/atomic"
"time"
"unsafe"
)
var traceIDCounter uint64 = uint64(time.Now().Unix()<<30) + 1
func newTraceID() uint64 {
return atomic.AddUint64(&traceIDCounter, 1)
}
// ----------------------------------------------------------------------------
type binWriter struct {
b []byte
i int
}
func newBinWriter(buf []byte) *binWriter {
buf = buf[:cap(buf)]
return &binWriter{buf, 0}
}
func (w *binWriter) Bool(b bool) *binWriter {
if b {
return w.Byte(1)
}
return w.Byte(0)
}
func (w *binWriter) Byte(b byte) *binWriter {
w.b[w.i] = b
w.i++
return w
}
func (w *binWriter) SharedKey(key [32]byte) *binWriter {
copy(w.b[w.i:w.i+32], key[:])
w.i += 32
return w
}
func (w *binWriter) Uint16(x uint16) *binWriter {
*(*uint16)(unsafe.Pointer(&w.b[w.i])) = x
w.i += 2
return w
}
func (w *binWriter) Uint64(x uint64) *binWriter {
*(*uint64)(unsafe.Pointer(&w.b[w.i])) = x
w.i += 8
return w
}
func (w *binWriter) Int64(x int64) *binWriter {
*(*int64)(unsafe.Pointer(&w.b[w.i])) = x
w.i += 8
return w
}
func (w *binWriter) AddrPort(addrPort netip.AddrPort) *binWriter {
w.Bool(addrPort.IsValid())
addr := addrPort.Addr().As16()
copy(w.b[w.i:w.i+16], addr[:])
w.i += 16
return w.Uint16(addrPort.Port())
}
func (w *binWriter) AddrPortArray(l [8]netip.AddrPort) *binWriter {
for _, addrPort := range l {
w.AddrPort(addrPort)
}
return w
}
func (w *binWriter) Build() []byte {
return w.b[:w.i]
}
// ----------------------------------------------------------------------------
type binReader struct {
b []byte
i int
err error
}
func newBinReader(buf []byte) *binReader {
return &binReader{b: buf}
}
func (r *binReader) hasBytes(n int) bool {
if r.err != nil || (len(r.b)-r.i) < n {
r.err = errMalformedPacket
return false
}
return true
}
func (r *binReader) Bool(b *bool) *binReader {
var bb byte
r.Byte(&bb)
*b = bb != 0
return r
}
func (r *binReader) Byte(b *byte) *binReader {
if !r.hasBytes(1) {
return r
}
*b = r.b[r.i]
r.i++
return r
}
func (r *binReader) SharedKey(x *[32]byte) *binReader {
if !r.hasBytes(32) {
return r
}
*x = ([32]byte)(r.b[r.i : r.i+32])
r.i += 32
return r
}
func (r *binReader) Uint16(x *uint16) *binReader {
if !r.hasBytes(2) {
return r
}
*x = *(*uint16)(unsafe.Pointer(&r.b[r.i]))
r.i += 2
return r
}
func (r *binReader) Uint64(x *uint64) *binReader {
if !r.hasBytes(8) {
return r
}
*x = *(*uint64)(unsafe.Pointer(&r.b[r.i]))
r.i += 8
return r
}
func (r *binReader) Int64(x *int64) *binReader {
if !r.hasBytes(8) {
return r
}
*x = *(*int64)(unsafe.Pointer(&r.b[r.i]))
r.i += 8
return r
}
func (r *binReader) AddrPort(x *netip.AddrPort) *binReader {
if !r.hasBytes(19) {
return r
}
var (
valid bool
port uint16
)
r.Bool(&valid)
addr := netip.AddrFrom16(([16]byte)(r.b[r.i : r.i+16])).Unmap()
r.i += 16
r.Uint16(&port)
if valid {
*x = netip.AddrPortFrom(addr, port)
} else {
*x = netip.AddrPort{}
}
return r
}
func (r *binReader) AddrPortArray(x *[8]netip.AddrPort) *binReader {
for i := range x {
r.AddrPort(&x[i])
}
return r
}
func (r *binReader) Error() error {
return r.err
}

56
peer/packets-util_test.go Normal file
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@@ -0,0 +1,56 @@
package peer
import (
"net/netip"
"reflect"
"testing"
)
func TestBinWriteRead(t *testing.T) {
buf := make([]byte, 1024)
type Item struct {
Type byte
TraceID uint64
Addrs [8]netip.AddrPort
DestAddr netip.AddrPort
}
in := Item{
1,
2,
[8]netip.AddrPort{},
netip.AddrPortFrom(netip.AddrFrom4([4]byte{1, 2, 3, 4}), 22),
}
in.Addrs[0] = netip.AddrPortFrom(netip.AddrFrom4([4]byte{0, 1, 2, 3}), 20)
in.Addrs[2] = netip.AddrPortFrom(netip.AddrFrom4([4]byte{2, 3, 4, 5}), 22)
in.Addrs[3] = netip.AddrPortFrom(netip.AddrFrom4([4]byte{2, 3, 4, 3}), 23)
in.Addrs[4] = netip.AddrPortFrom(netip.AddrFrom4([4]byte{2, 3, 4, 4}), 24)
in.Addrs[5] = netip.AddrPortFrom(netip.AddrFrom4([4]byte{2, 3, 4, 5}), 25)
in.Addrs[6] = netip.AddrPortFrom(netip.AddrFrom4([4]byte{2, 3, 4, 6}), 26)
in.Addrs[7] = netip.AddrPortFrom(netip.AddrFrom4([4]byte{7, 8, 9, 7}), 27)
buf = newBinWriter(buf).
Byte(in.Type).
Uint64(in.TraceID).
AddrPort(in.DestAddr).
AddrPortArray(in.Addrs).
Build()
out := Item{}
err := newBinReader(buf).
Byte(&out.Type).
Uint64(&out.TraceID).
AddrPort(&out.DestAddr).
AddrPortArray(&out.Addrs).
Error()
if err != nil {
t.Fatal(err)
}
if !reflect.DeepEqual(in, out) {
t.Fatal(in, out)
}
}

123
peer/packets.go Normal file
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@@ -0,0 +1,123 @@
package peer
import (
"net/netip"
)
const (
packetTypeSyn = iota + 1
packetTypeSynAck
packetTypeAck
packetTypeProbe
packetTypeAddrDiscovery
)
// ----------------------------------------------------------------------------
type synPacket struct {
TraceID uint64 // TraceID to match response w/ request.
// TODO: SentAt int64 // Unixmilli.
SharedKey [32]byte // Our shared key.
Direct bool
PossibleAddrs [8]netip.AddrPort // Possible public addresses of the sender.
}
func (p synPacket) Marshal(buf []byte) []byte {
return newBinWriter(buf).
Byte(packetTypeSyn).
Uint64(p.TraceID).
SharedKey(p.SharedKey).
Bool(p.Direct).
AddrPort(p.PossibleAddrs[0]).
AddrPort(p.PossibleAddrs[1]).
AddrPort(p.PossibleAddrs[2]).
AddrPort(p.PossibleAddrs[3]).
AddrPort(p.PossibleAddrs[4]).
AddrPort(p.PossibleAddrs[5]).
AddrPort(p.PossibleAddrs[6]).
AddrPort(p.PossibleAddrs[7]).
Build()
}
func parseSynPacket(buf []byte) (p synPacket, err error) {
err = newBinReader(buf[1:]).
Uint64(&p.TraceID).
SharedKey(&p.SharedKey).
Bool(&p.Direct).
AddrPort(&p.PossibleAddrs[0]).
AddrPort(&p.PossibleAddrs[1]).
AddrPort(&p.PossibleAddrs[2]).
AddrPort(&p.PossibleAddrs[3]).
AddrPort(&p.PossibleAddrs[4]).
AddrPort(&p.PossibleAddrs[5]).
AddrPort(&p.PossibleAddrs[6]).
AddrPort(&p.PossibleAddrs[7]).
Error()
return
}
// ----------------------------------------------------------------------------
type ackPacket struct {
TraceID uint64
ToAddr netip.AddrPort
PossibleAddrs [8]netip.AddrPort // Possible public addresses of the sender.
}
func (p ackPacket) Marshal(buf []byte) []byte {
return newBinWriter(buf).
Byte(packetTypeAck).
Uint64(p.TraceID).
AddrPort(p.ToAddr).
AddrPort(p.PossibleAddrs[0]).
AddrPort(p.PossibleAddrs[1]).
AddrPort(p.PossibleAddrs[2]).
AddrPort(p.PossibleAddrs[3]).
AddrPort(p.PossibleAddrs[4]).
AddrPort(p.PossibleAddrs[5]).
AddrPort(p.PossibleAddrs[6]).
AddrPort(p.PossibleAddrs[7]).
Build()
}
func parseAckPacket(buf []byte) (p ackPacket, err error) {
err = newBinReader(buf[1:]).
Uint64(&p.TraceID).
AddrPort(&p.ToAddr).
AddrPort(&p.PossibleAddrs[0]).
AddrPort(&p.PossibleAddrs[1]).
AddrPort(&p.PossibleAddrs[2]).
AddrPort(&p.PossibleAddrs[3]).
AddrPort(&p.PossibleAddrs[4]).
AddrPort(&p.PossibleAddrs[5]).
AddrPort(&p.PossibleAddrs[6]).
AddrPort(&p.PossibleAddrs[7]).
Error()
return
}
// ----------------------------------------------------------------------------
// A probeReqPacket is sent from a client to a server to determine if direct
// UDP communication can be used.
type probePacket struct {
TraceID uint64
}
func (p probePacket) Marshal(buf []byte) []byte {
return newBinWriter(buf).
Byte(packetTypeProbe).
Uint64(p.TraceID).
Build()
}
func parseProbePacket(buf []byte) (p probePacket, err error) {
err = newBinReader(buf[1:]).
Uint64(&p.TraceID).
Error()
return
}
// ----------------------------------------------------------------------------
type localDiscoveryPacket struct{}

1
peer/packets_test.go Normal file
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@@ -0,0 +1 @@
package peer

29
peer/state.go Normal file
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@@ -0,0 +1,29 @@
package peer
import (
"net/netip"
"time"
)
type peerRoute struct {
IP byte // VPN IP of peer (last byte).
Up bool // True if data can be sent on the route.
Relay bool // True if the peer is a relay.
Direct bool // True if this is a direct connection.
PubSignKey []byte
ControlCipher *controlCipher
DataCipher *dataCipher
RemoteAddr netip.AddrPort // Remote address if directly connected.
Counter *uint64 // For sending to. Atomic access only.
DupCheck *dupCheck // For receiving from. Not safe for concurrent use.
}
func newPeerRoute(ip byte) *peerRoute {
counter := uint64(time.Now().Unix()<<30 + 1)
return &peerRoute{
IP: ip,
Counter: &counter,
DupCheck: newDupCheck(0),
}
}