netbird/relay/testec2/main.go

259 lines
6.1 KiB
Go
Raw Normal View History

//go:build linux || darwin
package main
import (
"crypto/rand"
"flag"
"fmt"
"net"
"os"
"sync"
"time"
log "github.com/sirupsen/logrus"
"github.com/netbirdio/netbird/util"
)
const (
errMsgFailedReadTCP = "failed to read from tcp: %s"
)
var (
dataSize = 1024 * 1024 * 50 // 50MB
pairs = []int{1, 5, 10, 20, 30, 40, 50, 60, 70, 80, 90, 100}
signalListenAddress = ":8081"
relaySrvAddress string
turnSrvAddress string
signalURL string
udpListener string // used for TURN test
)
type testResult struct {
numOfPairs int
duration time.Duration
speed float64
}
func (tr testResult) Speed() string {
speed := tr.speed
var unit string
switch {
case speed < 1024:
unit = "B/s"
case speed < 1048576:
speed /= 1024
unit = "KB/s"
case speed < 1073741824:
speed /= 1048576
unit = "MB/s"
default:
speed /= 1073741824
unit = "GB/s"
}
return fmt.Sprintf("%.2f %s", speed, unit)
}
func seedRandomData(size int) ([]byte, error) {
token := make([]byte, size)
_, err := rand.Read(token)
if err != nil {
return nil, err
}
return token, nil
}
func avg(transferDuration []time.Duration) (time.Duration, float64) {
var totalDuration time.Duration
for _, d := range transferDuration {
totalDuration += d
}
avgDuration := totalDuration / time.Duration(len(transferDuration))
bps := float64(dataSize) / avgDuration.Seconds()
return avgDuration, bps
}
func RelayReceiverMain() []testResult {
testResults := make([]testResult, 0, len(pairs))
for _, p := range pairs {
tr := testResult{numOfPairs: p}
td := relayReceive(relaySrvAddress, p)
tr.duration, tr.speed = avg(td)
testResults = append(testResults, tr)
}
return testResults
}
func RelaySenderMain() {
log.Infof("starting sender")
log.Infof("starting seed phase")
testData, err := seedRandomData(dataSize)
if err != nil {
log.Fatalf("failed to seed random data: %s", err)
}
log.Infof("data size: %d", len(testData))
for n, p := range pairs {
log.Infof("running test with %d pairs", p)
relayTransfer(relaySrvAddress, testData, p)
// grant time to prepare new receivers
if n < len(pairs)-1 {
time.Sleep(3 * time.Second)
}
}
}
// TRUNSenderMain is the sender
// - allocate turn clients
// - send relayed addresses to signal server in batch
// - wait for signal server to send back addresses in a map
// - send test data to each address in parallel
func TRUNSenderMain() {
log.Infof("starting TURN sender test")
log.Infof("starting seed random data: %d", dataSize)
testData, err := seedRandomData(dataSize)
if err != nil {
log.Fatalf("failed to seed random data: %s", err)
}
ss := SignalClient{signalURL}
for _, p := range pairs {
log.Infof("running test with %d pairs", p)
turnSender := &TurnSender{}
createTurnConns(p, turnSender)
log.Infof("send addresses via signal server: %d", len(turnSender.addresses))
clientAddresses, err := ss.SendAddress(turnSender.addresses)
if err != nil {
log.Fatalf("failed to send address: %s", err)
}
log.Infof("received addresses: %v", clientAddresses.Address)
createSenderDevices(turnSender, clientAddresses)
log.Infof("waiting for tcpListeners to be ready")
time.Sleep(2 * time.Second)
tcpConns := make([]net.Conn, 0, len(turnSender.devices))
for i := range turnSender.devices {
addr := fmt.Sprintf("10.0.%d.2:9999", i)
log.Infof("dialing: %s", addr)
tcpConn, err := net.Dial("tcp", addr)
if err != nil {
log.Fatalf("failed to dial tcp: %s", err)
}
tcpConns = append(tcpConns, tcpConn)
}
log.Infof("start test data transfer for %d pairs", p)
testDataLen := len(testData)
wg := sync.WaitGroup{}
wg.Add(len(tcpConns))
for i, tcpConn := range tcpConns {
log.Infof("sending test data to device: %d", i)
go runTurnWriting(tcpConn, testData, testDataLen, &wg)
}
wg.Wait()
for _, d := range turnSender.devices {
_ = d.Close()
}
log.Infof("test finished with %d pairs", p)
}
}
func TURNReaderMain() []testResult {
log.Infof("starting TURN receiver test")
si := NewSignalService()
go func() {
log.Infof("starting signal server")
err := si.Listen(signalListenAddress)
if err != nil {
log.Errorf("failed to listen: %s", err)
}
}()
testResults := make([]testResult, 0, len(pairs))
for range pairs {
addresses := <-si.AddressesChan
instanceNumber := len(addresses)
log.Infof("received addresses: %d", instanceNumber)
turnReceiver := &TurnReceiver{}
err := createDevices(addresses, turnReceiver)
if err != nil {
log.Fatalf("%s", err)
}
// send client addresses back via signal server
si.ClientAddressChan <- turnReceiver.clientAddresses
durations := make(chan time.Duration, instanceNumber)
for _, device := range turnReceiver.devices {
go runTurnReading(device, durations)
}
durationsList := make([]time.Duration, 0, instanceNumber)
for d := range durations {
durationsList = append(durationsList, d)
if len(durationsList) == instanceNumber {
close(durations)
}
}
avgDuration, avgSpeed := avg(durationsList)
ts := testResult{
numOfPairs: len(durationsList),
duration: avgDuration,
speed: avgSpeed,
}
testResults = append(testResults, ts)
for _, d := range turnReceiver.devices {
_ = d.Close()
}
}
return testResults
}
func main() {
var mode string
_ = util.InitLog("debug", "console")
flag.StringVar(&mode, "mode", "sender", "sender or receiver mode")
flag.Parse()
relaySrvAddress = os.Getenv("TEST_RELAY_SERVER") // rel://ip:port
turnSrvAddress = os.Getenv("TEST_TURN_SERVER") // ip:3478
signalURL = os.Getenv("TEST_SIGNAL_URL") // http://receiver_ip:8081
udpListener = os.Getenv("TEST_UDP_LISTENER") // IP:0
if mode == "receiver" {
relayResult := RelayReceiverMain()
turnResults := TURNReaderMain()
for i := 0; i < len(turnResults); i++ {
log.Infof("pairs: %d,\tRelay speed:\t%s,\trelay duration:\t%s", relayResult[i].numOfPairs, relayResult[i].Speed(), relayResult[i].duration)
log.Infof("pairs: %d,\tTURN speed:\t%s,\tturn duration:\t%s", turnResults[i].numOfPairs, turnResults[i].Speed(), turnResults[i].duration)
}
} else {
RelaySenderMain()
// grant time for receiver to start
time.Sleep(3 * time.Second)
TRUNSenderMain()
}
}