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// Copyright 2010 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package tls
import (
"bytes"
"crypto/ecdsa"
"crypto/rsa"
"crypto/x509"
"encoding/pem"
"fmt"
"io"
"net"
"os"
"os/exec"
"path/filepath"
"strconv"
"testing"
"time"
)
// Note: see comment in handshake_test.go for details of how the reference
// tests work.
// blockingSource is an io.Reader that blocks a Read call until it's closed.
type blockingSource chan bool
func (b blockingSource) Read([]byte) (n int, err error) {
<-b
return 0, io.EOF
}
// clientTest represents a test of the TLS client handshake against a reference
// implementation.
type clientTest struct {
// name is a freeform string identifying the test and the file in which
// the expected results will be stored.
name string
// command, if not empty, contains a series of arguments for the
// command to run for the reference server.
command []string
// config, if not nil, contains a custom Config to use for this test.
config *Config
// cert, if not empty, contains a DER-encoded certificate for the
// reference server.
cert []byte
// key, if not nil, contains either a *rsa.PrivateKey or
// *ecdsa.PrivateKey which is the private key for the reference server.
key interface{}
}
var defaultServerCommand = []string{"openssl", "s_server"}
// connFromCommand starts the reference server process, connects to it and
// returns a recordingConn for the connection. The stdin return value is a
// blockingSource for the stdin of the child process. It must be closed before
// Waiting for child.
func (test *clientTest) connFromCommand() (conn *recordingConn, child *exec.Cmd, stdin blockingSource, err error) {
cert := testRSACertificate
if len(test.cert) > 0 {
cert = test.cert
}
certPath := tempFile(string(cert))
defer os.Remove(certPath)
var key interface{} = testRSAPrivateKey
if test.key != nil {
key = test.key
}
var pemType string
var derBytes []byte
switch key := key.(type) {
case *rsa.PrivateKey:
pemType = "RSA"
derBytes = x509.MarshalPKCS1PrivateKey(key)
case *ecdsa.PrivateKey:
pemType = "EC"
var err error
derBytes, err = x509.MarshalECPrivateKey(key)
if err != nil {
panic(err)
}
default:
panic("unknown key type")
}
var pemOut bytes.Buffer
pem.Encode(&pemOut, &pem.Block{Type: pemType + " PRIVATE KEY", Bytes: derBytes})
keyPath := tempFile(string(pemOut.Bytes()))
defer os.Remove(keyPath)
var command []string
if len(test.command) > 0 {
command = append(command, test.command...)
} else {
command = append(command, defaultServerCommand...)
}
command = append(command, "-cert", certPath, "-certform", "DER", "-key", keyPath)
// serverPort contains the port that OpenSSL will listen on. OpenSSL
// can't take "0" as an argument here so we have to pick a number and
// hope that it's not in use on the machine. Since this only occurs
// when -update is given and thus when there's a human watching the
// test, this isn't too bad.
const serverPort = 24323
command = append(command, "-accept", strconv.Itoa(serverPort))
cmd := exec.Command(command[0], command[1:]...)
stdin = blockingSource(make(chan bool))
cmd.Stdin = stdin
var out bytes.Buffer
cmd.Stdout = &out
cmd.Stderr = &out
if err := cmd.Start(); err != nil {
return nil, nil, nil, err
}
// OpenSSL does print an "ACCEPT" banner, but it does so *before*
// opening the listening socket, so we can't use that to wait until it
// has started listening. Thus we are forced to poll until we get a
// connection.
var tcpConn net.Conn
for i := uint(0); i < 5; i++ {
var err error
tcpConn, err = net.DialTCP("tcp", nil, &net.TCPAddr{
IP: net.IPv4(127, 0, 0, 1),
Port: serverPort,
})
if err == nil {
break
}
time.Sleep((1 << i) * 5 * time.Millisecond)
}
if tcpConn == nil {
close(stdin)
out.WriteTo(os.Stdout)
cmd.Process.Kill()
return nil, nil, nil, cmd.Wait()
}
record := &recordingConn{
Conn: tcpConn,
}
return record, cmd, stdin, nil
}
func (test *clientTest) dataPath() string {
return filepath.Join("testdata", "Client-"+test.name)
}
func (test *clientTest) loadData() (flows [][]byte, err error) {
in, err := os.Open(test.dataPath())
if err != nil {
return nil, err
}
defer in.Close()
return parseTestData(in)
}
func (test *clientTest) run(t *testing.T, write bool) {
var clientConn, serverConn net.Conn
var recordingConn *recordingConn
var childProcess *exec.Cmd
var stdin blockingSource
if write {
var err error
recordingConn, childProcess, stdin, err = test.connFromCommand()
if err != nil {
t.Fatalf("Failed to start subcommand: %s", err)
}
clientConn = recordingConn
} else {
clientConn, serverConn = net.Pipe()
}
config := test.config
if config == nil {
config = testConfig
}
client := Client(clientConn, config)
doneChan := make(chan bool)
go func() {
if _, err := client.Write([]byte("hello\n")); err != nil {
t.Logf("Client.Write failed: %s", err)
}
client.Close()
clientConn.Close()
doneChan <- true
}()
if !write {
flows, err := test.loadData()
if err != nil {
t.Fatalf("%s: failed to load data from %s", test.name, test.dataPath())
}
for i, b := range flows {
if i%2 == 1 {
serverConn.Write(b)
continue
}
bb := make([]byte, len(b))
_, err := io.ReadFull(serverConn, bb)
if err != nil {
t.Fatalf("%s #%d: %s", test.name, i, err)
}
if !bytes.Equal(b, bb) {
t.Fatalf("%s #%d: mismatch on read: got:%x want:%x", test.name, i, bb, b)
}
}
serverConn.Close()
}
<-doneChan
if write {
path := test.dataPath()
out, err := os.OpenFile(path, os.O_WRONLY|os.O_CREATE|os.O_TRUNC, 0644)
if err != nil {
t.Fatalf("Failed to create output file: %s", err)
}
defer out.Close()
recordingConn.Close()
close(stdin)
childProcess.Process.Kill()
childProcess.Wait()
if len(recordingConn.flows) < 3 {
childProcess.Stdout.(*bytes.Buffer).WriteTo(os.Stdout)
t.Fatalf("Client connection didn't work")
}
recordingConn.WriteTo(out)
fmt.Printf("Wrote %s\n", path)
}
}
func runClientTestForVersion(t *testing.T, template *clientTest, prefix, option string) {
test := *template
test.name = prefix + test.name
if len(test.command) == 0 {
test.command = defaultClientCommand
}
test.command = append([]string(nil), test.command...)
test.command = append(test.command, option)
test.run(t, *update)
}
func runClientTestTLS10(t *testing.T, template *clientTest) {
runClientTestForVersion(t, template, "TLSv10-", "-tls1")
}
func runClientTestTLS11(t *testing.T, template *clientTest) {
runClientTestForVersion(t, template, "TLSv11-", "-tls1_1")
}
func runClientTestTLS12(t *testing.T, template *clientTest) {
runClientTestForVersion(t, template, "TLSv12-", "-tls1_2")
}
func TestHandshakeClientRSARC4(t *testing.T) {
test := &clientTest{
name: "RSA-RC4",
command: []string{"openssl", "s_server", "-cipher", "RC4-SHA"},
}
runClientTestTLS10(t, test)
runClientTestTLS11(t, test)
runClientTestTLS12(t, test)
}
func TestHandshakeClientECDHERSAAES(t *testing.T) {
test := &clientTest{
name: "ECDHE-RSA-AES",
command: []string{"openssl", "s_server", "-cipher", "ECDHE-RSA-AES128-SHA"},
}
runClientTestTLS10(t, test)
runClientTestTLS11(t, test)
runClientTestTLS12(t, test)
}
func TestHandshakeClientECDHEECDSAAES(t *testing.T) {
test := &clientTest{
name: "ECDHE-ECDSA-AES",
command: []string{"openssl", "s_server", "-cipher", "ECDHE-ECDSA-AES128-SHA"},
cert: testECDSACertificate,
key: testECDSAPrivateKey,
}
runClientTestTLS10(t, test)
runClientTestTLS11(t, test)
runClientTestTLS12(t, test)
}
func TestHandshakeClientECDHEECDSAAESGCM(t *testing.T) {
test := &clientTest{
name: "ECDHE-ECDSA-AES-GCM",
command: []string{"openssl", "s_server", "-cipher", "ECDHE-ECDSA-AES128-GCM-SHA256"},
cert: testECDSACertificate,
key: testECDSAPrivateKey,
}
runClientTestTLS12(t, test)
}
func TestHandshakeClientCertRSA(t *testing.T) {
config := *testConfig
cert, _ := X509KeyPair([]byte(clientCertificatePEM), []byte(clientKeyPEM))
config.Certificates = []Certificate{cert}
test := &clientTest{
name: "ClientCert-RSA-RSA",
command: []string{"openssl", "s_server", "-cipher", "RC4-SHA", "-verify", "1"},
config: &config,
}
runClientTestTLS10(t, test)
runClientTestTLS12(t, test)
test = &clientTest{
name: "ClientCert-RSA-ECDSA",
command: []string{"openssl", "s_server", "-cipher", "ECDHE-ECDSA-AES128-SHA", "-verify", "1"},
config: &config,
cert: testECDSACertificate,
key: testECDSAPrivateKey,
}
runClientTestTLS10(t, test)
runClientTestTLS12(t, test)
}
func TestHandshakeClientCertECDSA(t *testing.T) {
config := *testConfig
cert, _ := X509KeyPair([]byte(clientECDSACertificatePEM), []byte(clientECDSAKeyPEM))
config.Certificates = []Certificate{cert}
test := &clientTest{
name: "ClientCert-ECDSA-RSA",
command: []string{"openssl", "s_server", "-cipher", "RC4-SHA", "-verify", "1"},
config: &config,
}
runClientTestTLS10(t, test)
runClientTestTLS12(t, test)
test = &clientTest{
name: "ClientCert-ECDSA-ECDSA",
command: []string{"openssl", "s_server", "-cipher", "ECDHE-ECDSA-AES128-SHA", "-verify", "1"},
config: &config,
cert: testECDSACertificate,
key: testECDSAPrivateKey,
}
runClientTestTLS10(t, test)
runClientTestTLS12(t, test)
}
func TestClientResumption(t *testing.T) {
serverConfig := &Config{
CipherSuites: []uint16{TLS_RSA_WITH_RC4_128_SHA, TLS_ECDHE_RSA_WITH_RC4_128_SHA},
Certificates: testConfig.Certificates,
}
clientConfig := &Config{
CipherSuites: []uint16{TLS_RSA_WITH_RC4_128_SHA},
InsecureSkipVerify: true,
ClientSessionCache: NewLRUClientSessionCache(32),
}
testResumeState := func(test string, didResume bool) {
hs, err := testHandshake(clientConfig, serverConfig)
if err != nil {
t.Fatalf("%s: handshake failed: %s", test, err)
}
if hs.DidResume != didResume {
t.Fatalf("%s resumed: %v, expected: %v", test, hs.DidResume, didResume)
}
}
testResumeState("Handshake", false)
testResumeState("Resume", true)
if _, err := io.ReadFull(serverConfig.rand(), serverConfig.SessionTicketKey[:]); err != nil {
t.Fatalf("Failed to invalidate SessionTicketKey")
}
testResumeState("InvalidSessionTicketKey", false)
testResumeState("ResumeAfterInvalidSessionTicketKey", true)
clientConfig.CipherSuites = []uint16{TLS_ECDHE_RSA_WITH_RC4_128_SHA}
testResumeState("DifferentCipherSuite", false)
testResumeState("DifferentCipherSuiteRecovers", true)
clientConfig.ClientSessionCache = nil
testResumeState("WithoutSessionCache", false)
}
func TestLRUClientSessionCache(t *testing.T) {
// Initialize cache of capacity 4.
cache := NewLRUClientSessionCache(4)
cs := make([]ClientSessionState, 6)
keys := []string{"0", "1", "2", "3", "4", "5", "6"}
// Add 4 entries to the cache and look them up.
for i := 0; i < 4; i++ {
cache.Put(keys[i], &cs[i])
}
for i := 0; i < 4; i++ {
if s, ok := cache.Get(keys[i]); !ok || s != &cs[i] {
t.Fatalf("session cache failed lookup for added key: %s", keys[i])
}
}
// Add 2 more entries to the cache. First 2 should be evicted.
for i := 4; i < 6; i++ {
cache.Put(keys[i], &cs[i])
}
for i := 0; i < 2; i++ {
if s, ok := cache.Get(keys[i]); ok || s != nil {
t.Fatalf("session cache should have evicted key: %s", keys[i])
}
}
// Touch entry 2. LRU should evict 3 next.
cache.Get(keys[2])
cache.Put(keys[0], &cs[0])
if s, ok := cache.Get(keys[3]); ok || s != nil {
t.Fatalf("session cache should have evicted key 3")
}
// Update entry 0 in place.
cache.Put(keys[0], &cs[3])
if s, ok := cache.Get(keys[0]); !ok || s != &cs[3] {
t.Fatalf("session cache failed update for key 0")
}
// Adding a nil entry is valid.
cache.Put(keys[0], nil)
if s, ok := cache.Get(keys[0]); !ok || s != nil {
t.Fatalf("failed to add nil entry to cache")
}
}
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