// Test udp.Addr works correctly.
func TestUDPAddr(t *testing.T) {
tests.ResetLog()
defer tests.DisplayLog()
t.Log("Given the need to listen on any port and know that bound UDP address.")
{
// Create a configuration.
cfg := udp.Config{
NetType: "udp4",
Addr: ":0", // Defer port assignment to OS.
ConnHandler: udpConnHandler{},
ReqHandler: udpReqHandler{},
RespHandler: udpRespHandler{},
OptIntPool: udp.OptIntPool{
RecvMinPoolSize: func() int { return 2 },
RecvMaxPoolSize: func() int { return 1000 },
SendMinPoolSize: func() int { return 2 },
SendMaxPoolSize: func() int { return 1000 },
},
}
// Create a new UDP value.
u, err := udp.New("TEST", "TEST", cfg)
if err != nil {
t.Fatal("\tShould be able to create a new UDP listener.", tests.Failed, err)
}
t.Log("\tShould be able to create a new UDP listener.", tests.Success)
// Addr should be nil before start.
if addr := u.Addr(); addr != nil {
t.Fatalf("\tAddr() should be nil before Start; Addr() = %q. %s", addr, tests.Failed)
}
t.Log("\tAddr() should be nil before Start.", tests.Success)
// Start accepting client data.
if err := u.Start("TEST"); err != nil {
t.Fatal("\tShould be able to start the UDP listener.", tests.Failed, err)
}
defer u.Stop("TEST")
// Addr should be non-nil after Start.
addr := u.Addr()
if addr == nil {
t.Fatal("\tAddr() should be not be nil after Start.", tests.Failed)
}
t.Log("\tAddr() should be not be nil after Start.", tests.Success)
// The OS should assign a random open port, which shouldn't be 0.
_, port, err := net.SplitHostPort(addr.String())
if err != nil {
t.Fatalf("\tSplitHostPort should not fail. tests.Failed %v. %s", err, tests.Failed)
}
if port == "0" {
t.Fatalf("\tAddr port should not be %q. %s", port, tests.Failed)
}
t.Logf("\tAddr() should be not be 0 after Start (port = %q). %s", port, tests.Success)
}
}
func main() {
const context = "startup"
// Create the configuration.
cfg := udp.Config{
NetType: "udp4",
Addr: ":6000",
ConnHandler: udpConnHandler{},
ReqHandler: udpReqHandler{},
RespHandler: udpRespHandler{},
OptIntPool: udp.OptIntPool{
RecvMinPoolSize: func() int { return 2 },
RecvMaxPoolSize: func() int { return 100 },
SendMinPoolSize: func() int { return 2 },
SendMaxPoolSize: func() int { return 100 },
},
}
// Create a new UDP value.
u, err := udp.New(context, "Sample", cfg)
if err != nil {
log.Error(context, "main", err, "Creating udp")
return
}
// Start accepting client data.
if err := u.Start(context); err != nil {
log.Error(context, "main", err, "Starting udp")
return
}
// Defer the stop on shutdown.
defer u.Stop(context)
log.User(context, "main", "Waiting for data on: %s", u.Addr())
// Listen for an interrupt signal from the OS.
sigChan := make(chan os.Signal, 1)
signal.Notify(sigChan, os.Interrupt)
<-sigChan
// Use netcat to test the server.
// nc -4u localhost 6000 < test.hex
log.User(context, "main", "Shutting down")
}
// TestUDP provide a test of listening for a connection and
// echoing the data back.
func TestUDP(t *testing.T) {
tests.ResetLog()
defer tests.DisplayLog()
t.Log("Given the need to listen and process UDP data.")
{
// Create a configuration.
cfg := udp.Config{
NetType: "udp4",
Addr: ":0",
ConnHandler: udpConnHandler{},
ReqHandler: udpReqHandler{},
RespHandler: udpRespHandler{},
OptIntPool: udp.OptIntPool{
RecvMinPoolSize: func() int { return 2 },
RecvMaxPoolSize: func() int { return 1000 },
SendMinPoolSize: func() int { return 2 },
SendMaxPoolSize: func() int { return 1000 },
},
}
// Create a new UDP value.
u, err := udp.New("TEST", "TEST", cfg)
if err != nil {
t.Fatal("\tShould be able to create a new UDP listener.", tests.Failed, err)
}
t.Log("\tShould be able to create a new UDP listener.", tests.Success)
// Start accepting client data.
if err := u.Start("TEST"); err != nil {
t.Fatal("\tShould be able to start the UDP listener.", tests.Failed, err)
}
t.Log("\tShould be able to start the UDP listener.", tests.Success)
defer u.Stop("TEST")
// Let's connect back and send a UDP package
conn, err := net.Dial("udp4", u.Addr().String())
if err != nil {
t.Fatal("\tShould be able to dial a new UDP connection.", tests.Failed, err)
}
t.Log("\tShould be able to dial a new UDP connection.", tests.Success)
// Send some know data to the udp listener.
b := bytes.NewBuffer([]byte{0x01, 0x3D, 0x06, 0x00, 0x58, 0x68, 0x9b, 0x9d, 0x80, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0xFF, 0xFC, 0x00, 0x01})
b.WriteTo(conn)
// Setup a limit reader to extract the response.
lr := io.LimitReader(conn, 6)
// Let's read the response.
data := make([]byte, 6)
if _, err := lr.Read(data); err != nil {
t.Fatal("\tShould be able to read the response from the connection.", tests.Failed, err)
}
t.Log("\tShould be able to read the response from the connection.", tests.Success)
response := string(data)
if response == "GOT IT" {
t.Log("\tShould receive the string \"GOT IT\".", tests.Success)
} else {
t.Error("\tShould receive the string \"GOT IT\".", tests.Failed, response)
}
d := atomic.LoadInt64(&dur)
duration := time.Duration(d)
if duration <= 2*time.Second {
t.Log("\tShould be less that 2 seconds.", tests.Success)
} else {
t.Error("\tShould be less that 2 seconds.", tests.Failed, duration)
}
}
}
