Chapter I: Using QUIC
In this chapter we will write together a main.go
file that
uses netxlite to establish a new QUIC connection with an UDP endpoint.
Conceptually, this program is very similar to the ones presented
in chapters 2 and 3, except that here we use QUIC.
(This file is auto-generated from the corresponding source file,
so make sure you don't edit it manually.)
The main.go file
We define main.go
file using package main
.
The beginning of the program is equal to the previous chapters,
so there is not much to say about it.
package main
import (
"context"
"crypto/tls"
"errors"
"flag"
"os"
"time"
"github.com/apex/log"
"github.com/ooni/probe-cli/v3/internal/netxlite"
"github.com/quic-go/quic-go"
)
func main() {
log.SetLevel(log.DebugLevel)
address := flag.String("address", "8.8.4.4:443", "Remote endpoint address")
sni := flag.String("sni", "dns.google", "SNI to use")
timeout := flag.Duration("timeout", 60*time.Second, "Timeout")
flag.Parse()
ctx, cancel := context.WithTimeout(context.Background(), *timeout)
defer cancel()
The main difference is that we set the ALPN correctly for
QUIC/HTTP3 by using "h3"
here.
config := &tls.Config{
ServerName: *sni,
NextProtos: []string{"h3"},
RootCAs: nil,
}
Also, where previously we called dialTLS
now we call
a function with a similar API called dialQUIC
.
qconn, state, err := dialQUIC(ctx, *address, config)
The rest of the main function is pretty much the same.
if err != nil {
fatal(err)
}
log.Infof("Connection type : %T", qconn)
log.Infof("Cipher suite : %s", netxlite.TLSCipherSuiteString(state.CipherSuite))
log.Infof("Negotiated protocol: %s", state.NegotiatedProtocol)
log.Infof("TLS version : %s", netxlite.TLSVersionString(state.Version))
qconn.CloseWithError(0, "")
}
The dialQUIC function is new. We need to create a QUIC listener
and, using it, a QUICDialer. These two steps are separated so
higher level code can wrap the QUICDialer and collect stats on
the returned connections. Also, as previously, this dialer is
not attached to a resolver, so it will fail if provided a domain
name. The rationale for doing that is similar to before: we
are focusing on step-by-step measurements where each operation
is performed independently. (That is, we assume that before
the code written in this main we have already resolved the
domain name of interest using a resolver, which we will investigate
in the next two chapters.)
func dialQUIC(ctx context.Context, address string,
config *tls.Config) (quic.EarlyConnection, tls.ConnectionState, error) {
ql := netxlite.NewQUICListener()
d := netxlite.NewQUICDialerWithoutResolver(ql, log.Log)
qconn, err := d.DialContext(ctx, address, config, &quic.Config{})
if err != nil {
return nil, tls.ConnectionState{}, err
}
The following line unwraps the connection state returned by
QUIC code to be of the same type of the ConnectionState that
we returned in the previous chapters.
return qconn, qconn.ConnectionState().TLS.ConnectionState, nil
}
The rest of the program is equal to the previous chapters.
func fatal(err error) {
var ew *netxlite.ErrWrapper
if !errors.As(err, &ew) {
log.Fatal("cannot get ErrWrapper")
}
log.Warnf("error string : %s", err.Error())
log.Warnf("OONI failure : %s", ew.Failure)
log.Warnf("failed operation: %s", ew.Operation)
log.Warnf("underlying error: %+v", ew.WrappedErr)
os.Exit(1)
}
Running the code
Vanilla run
You can now run this code as follows:
go run -race ./internal/tutorial/netxlite/chapter04
You will see debug logs describing what is happening along with timing info.
QUIC handshake timeout
go run -race ./internal/tutorial/netxlite/chapter04 -address 8.8.4.4:1
should cause a QUIC timeout error. Try lowering the timout adding, e.g.,
the -timeout 5s
flag to the command line.
SNI mismatch
go run -race ./internal/tutorial/netxlite/chapter04 -sni example.com
should give you a TLS error mentioning that the certificate is invalid.
Conclusions
We have seen how to use netxlite to establish a QUIC connection
with a remote UDP endpoint speaking QUIC.