crypto/tls (part 2)

R=rsc
CC=go-dev
http://go/go-review/1018028
This commit is contained in:
Adam Langley 2009-11-03 17:25:13 -08:00
rodzic 745ac15cb1
commit 24b96e2917
5 zmienionych plików z 610 dodań i 0 usunięć

236
handshake_messages.go Normal file
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// Copyright 2009 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";
)
type clientHelloMsg struct {
raw []byte;
major, minor uint8;
random []byte;
sessionId []byte;
cipherSuites []uint16;
compressionMethods []uint8;
}
func (m *clientHelloMsg) marshal() []byte {
if m.raw != nil {
return m.raw;
}
length := 2 + 32 + 1 + len(m.sessionId) + 2 + len(m.cipherSuites)*2 + 1 + len(m.compressionMethods);
x := make([]byte, 4+length);
x[0] = typeClientHello;
x[1] = uint8(length>>16);
x[2] = uint8(length>>8);
x[3] = uint8(length);
x[4] = m.major;
x[5] = m.minor;
bytes.Copy(x[6:38], m.random);
x[38] = uint8(len(m.sessionId));
bytes.Copy(x[39 : 39+len(m.sessionId)], m.sessionId);
y := x[39+len(m.sessionId) : len(x)];
y[0] = uint8(len(m.cipherSuites)>>7);
y[1] = uint8(len(m.cipherSuites)<<1);
for i, suite := range m.cipherSuites {
y[2 + i*2] = uint8(suite>>8);
y[3 + i*2] = uint8(suite);
}
z := y[2 + len(m.cipherSuites)*2 : len(y)];
z[0] = uint8(len(m.compressionMethods));
bytes.Copy(z[1:len(z)], m.compressionMethods);
m.raw = x;
return x;
}
func (m *clientHelloMsg) unmarshal(data []byte) bool {
if len(data) < 39 {
return false;
}
m.raw = data;
m.major = data[4];
m.minor = data[5];
m.random = data[6:38];
sessionIdLen := int(data[38]);
if sessionIdLen > 32 || len(data) < 39 + sessionIdLen {
return false;
}
m.sessionId = data[39 : 39 + sessionIdLen];
data = data[39 + sessionIdLen : len(data)];
if len(data) < 2 {
return false;
}
// cipherSuiteLen is the number of bytes of cipher suite numbers. Since
// they are uint16s, the number must be even.
cipherSuiteLen := int(data[0])<<8 | int(data[1]);
if cipherSuiteLen % 2 == 1 || len(data) < 2 + cipherSuiteLen {
return false;
}
numCipherSuites := cipherSuiteLen / 2;
m.cipherSuites = make([]uint16, numCipherSuites);
for i := 0; i < numCipherSuites; i++ {
m.cipherSuites[i] = uint16(data[2 + 2*i])<<8 | uint16(data[3 + 2*i]);
}
data = data[2 + cipherSuiteLen : len(data)];
if len(data) < 2 {
return false;
}
compressionMethodsLen := int(data[0]);
if len(data) < 1 + compressionMethodsLen {
return false;
}
m.compressionMethods = data[1 : 1 + compressionMethodsLen];
// A ClientHello may be following by trailing data: RFC 4346 section 7.4.1.2
return true;
}
type serverHelloMsg struct {
raw []byte;
major, minor uint8;
random []byte;
sessionId []byte;
cipherSuite uint16;
compressionMethod uint8;
}
func (m *serverHelloMsg) marshal() []byte {
if m.raw != nil {
return m.raw;
}
length := 38+len(m.sessionId);
x := make([]byte, 4+length);
x[0] = typeServerHello;
x[1] = uint8(length>>16);
x[2] = uint8(length>>8);
x[3] = uint8(length);
x[4] = m.major;
x[5] = m.minor;
bytes.Copy(x[6:38], m.random);
x[38] = uint8(len(m.sessionId));
bytes.Copy(x[39 : 39+len(m.sessionId)], m.sessionId);
z := x[39+len(m.sessionId) : len(x)];
z[0] = uint8(m.cipherSuite >> 8);
z[1] = uint8(m.cipherSuite);
z[2] = uint8(m.compressionMethod);
m.raw = x;
return x;
}
type certificateMsg struct {
raw []byte;
certificates [][]byte;
}
func (m *certificateMsg) marshal() (x []byte) {
if m.raw != nil {
return m.raw;
}
var i int;
for _, slice := range m.certificates {
i += len(slice);
}
length := 3 + 3*len(m.certificates) + i;
x = make([]byte, 4+length);
x[0] = typeCertificate;
x[1] = uint8(length>>16);
x[2] = uint8(length>>8);
x[3] = uint8(length);
certificateOctets := length-3;
x[4] = uint8(certificateOctets >> 16);
x[5] = uint8(certificateOctets >> 8);
x[6] = uint8(certificateOctets);
y := x[7:len(x)];
for _, slice := range m.certificates {
y[0] = uint8(len(slice)>>16);
y[1] = uint8(len(slice)>>8);
y[2] = uint8(len(slice));
bytes.Copy(y[3:len(y)], slice);
y = y[3+len(slice) : len(y)];
}
m.raw = x;
return;
}
type serverHelloDoneMsg struct{}
func (m *serverHelloDoneMsg) marshal() []byte {
x := make([]byte, 4);
x[0] = typeServerHelloDone;
return x;
}
type clientKeyExchangeMsg struct {
raw []byte;
ciphertext []byte;
}
func (m *clientKeyExchangeMsg) marshal() []byte {
if m.raw != nil {
return m.raw;
}
length := len(m.ciphertext)+2;
x := make([]byte, length+4);
x[0] = typeClientKeyExchange;
x[1] = uint8(length>>16);
x[2] = uint8(length>>8);
x[3] = uint8(length);
x[4] = uint8(len(m.ciphertext)>>8);
x[5] = uint8(len(m.ciphertext));
bytes.Copy(x[6:len(x)], m.ciphertext);
m.raw = x;
return x;
}
func (m *clientKeyExchangeMsg) unmarshal(data []byte) bool {
m.raw = data;
if len(data) < 7 {
return false;
}
cipherTextLen := int(data[4])<<8 | int(data[5]);
if len(data) != 6 + cipherTextLen {
return false;
}
m.ciphertext = data[6:len(data)];
return true;
}
type finishedMsg struct {
raw []byte;
verifyData []byte;
}
func (m *finishedMsg) marshal() (x []byte) {
if m.raw != nil {
return m.raw;
}
x = make([]byte, 16);
x[0] = typeFinished;
x[3] = 12;
bytes.Copy(x[4:len(x)], m.verifyData);
m.raw = x;
return;
}
func (m *finishedMsg) unmarshal(data []byte) bool {
m.raw = data;
if len(data) != 4+12 {
return false;
}
m.verifyData = data[4:len(data)];
return true;
}

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// Copyright 2009 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 (
"rand";
"reflect";
"testing";
"testing/quick";
)
var tests = []interface{}{
&clientHelloMsg{},
&clientKeyExchangeMsg{},
&finishedMsg{},
}
type testMessage interface {
marshal() []byte;
unmarshal([]byte) bool;
}
func TestMarshalUnmarshal(t *testing.T) {
rand := rand.New(rand.NewSource(0));
for i, iface := range tests {
ty := reflect.NewValue(iface).Type();
for j := 0; j < 100; j++ {
v, ok := quick.Value(ty, rand);
if !ok {
t.Errorf("#%d: failed to create value", i);
break;
}
m1 := v.Interface().(testMessage);
marshaled := m1.marshal();
m2 := iface.(testMessage);
if !m2.unmarshal(marshaled) {
t.Errorf("#%d failed to unmarshal %#v", i, m1);
break;
}
m2.marshal(); // to fill any marshal cache in the message
if !reflect.DeepEqual(m1, m2) {
t.Errorf("#%d got:%#v want:%#v", i, m1, m2);
break;
}
// Now check that all prefixes are invalid.
for j := 0; j < len(marshaled); j++ {
if m2.unmarshal(marshaled[0:j]) {
t.Errorf("#%d unmarshaled a prefix of length %d of %#v", i, j, m1);
break;
}
}
}
}
}
func randomBytes(n int, rand *rand.Rand) []byte {
r := make([]byte, n);
for i := 0; i < n; i++ {
r[i] = byte(rand.Int31());
}
return r;
}
func (*clientHelloMsg) Generate(rand *rand.Rand, size int) reflect.Value {
m := &clientHelloMsg{};
m.major = uint8(rand.Intn(256));
m.minor = uint8(rand.Intn(256));
m.random = randomBytes(32, rand);
m.sessionId = randomBytes(rand.Intn(32), rand);
m.cipherSuites = make([]uint16, rand.Intn(63) + 1);
for i := 0; i < len(m.cipherSuites); i++ {
m.cipherSuites[i] = uint16(rand.Int31());
}
m.compressionMethods = randomBytes(rand.Intn(63) + 1, rand);
return reflect.NewValue(m);
}
func (*clientKeyExchangeMsg) Generate(rand *rand.Rand, size int) reflect.Value {
m := &clientKeyExchangeMsg{};
m.ciphertext = randomBytes(rand.Intn(1000), rand);
return reflect.NewValue(m);
}
func (*finishedMsg) Generate(rand *rand.Rand, size int) reflect.Value {
m := &finishedMsg{};
m.verifyData = randomBytes(12, rand);
return reflect.NewValue(m);
}

42
record_read.go Normal file
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// Copyright 2009 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
// The record reader handles reading from the connection and reassembling TLS
// record structures. It loops forever doing this and writes the TLS records to
// it's outbound channel. On error, it closes its outbound channel.
import (
"io";
"bufio";
)
// recordReader loops, reading TLS records from source and writing them to the
// given channel. The channel is closed on EOF or on error.
func recordReader(c chan<- *record, source io.Reader) {
defer close(c);
buf := bufio.NewReader(source);
for {
var header [5]byte;
n, _ := buf.Read(header[0:len(header)]);
if n != 5 {
return;
}
recordLength := int(header[3])<<8 | int(header[4]);
if recordLength > maxTLSCiphertext {
return;
}
payload := make([]byte, recordLength);
n, _ = buf.Read(payload);
if n != recordLength {
return;
}
c <- &record{recordType(header[0]), header[1], header[2], payload};
}
}

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record_read_test.go Normal file
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// Copyright 2009 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";
"testing";
"testing/iotest";
)
func matchRecord(r1, r2 *record) bool {
if (r1 == nil) != (r2 == nil) {
return false;
}
if r1 == nil {
return true;
}
return r1.contentType == r2.contentType &&
r1.major == r2.major &&
r1.minor == r2.minor &&
bytes.Compare(r1.payload, r2.payload) == 0;
}
type recordReaderTest struct {
in []byte;
out []*record;
}
var recordReaderTests = []recordReaderTest{
recordReaderTest{nil, nil},
recordReaderTest{fromHex("01"), nil},
recordReaderTest{fromHex("0102"), nil},
recordReaderTest{fromHex("010203"), nil},
recordReaderTest{fromHex("01020300"), nil},
recordReaderTest{fromHex("0102030000"), []*record{&record{1, 2, 3, nil}}},
recordReaderTest{fromHex("01020300000102030000"), []*record{&record{1, 2, 3, nil}, &record{1, 2, 3, nil}}},
recordReaderTest{fromHex("0102030001fe0102030002feff"), []*record{&record{1, 2, 3, []byte{0xfe}}, &record{1, 2, 3, []byte{0xfe, 0xff}}}},
recordReaderTest{fromHex("010203000001020300"), []*record{&record{1, 2, 3, nil}}},
}
func TestRecordReader(t *testing.T) {
for i, test := range recordReaderTests {
buf := bytes.NewBuffer(test.in);
c := make(chan *record);
go recordReader(c, buf);
matchRecordReaderOutput(t, i, test, c);
buf = bytes.NewBuffer(test.in);
buf2 := iotest.OneByteReader(buf);
c = make(chan *record);
go recordReader(c, buf2);
matchRecordReaderOutput(t, i*2, test, c);
}
}
func matchRecordReaderOutput(t *testing.T, i int, test recordReaderTest, c <-chan *record) {
for j, r1 := range test.out {
r2 := <-c;
if r2 == nil {
t.Errorf("#%d truncated after %d values", i, j);
break;
}
if !matchRecord(r1, r2) {
t.Errorf("#%d (%d) got:%#v want:%#v", i, j, r2, r1);
}
}
<-c;
if !closed(c) {
t.Errorf("#%d: channel didn't close", i);
}
}

164
record_write.go Normal file
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// Copyright 2009 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 (
"fmt";
"hash";
"io";
)
// writerEnableApplicationData is a message which instructs recordWriter to
// start reading and transmitting data from the application data channel.
type writerEnableApplicationData struct{}
// writerChangeCipherSpec updates the encryption and MAC functions and resets
// the sequence count.
type writerChangeCipherSpec struct {
encryptor encryptor;
mac hash.Hash;
}
// writerSetVersion sets the version number bytes that we included in the
// record header for future records.
type writerSetVersion struct {
major, minor uint8;
}
// A recordWriter accepts messages from the handshake processor and
// application data. It writes them to the outgoing connection and blocks on
// writing. It doesn't read from the application data channel until the
// handshake processor has signaled that the handshake is complete.
type recordWriter struct {
writer io.Writer;
encryptor encryptor;
mac hash.Hash;
seqNum uint64;
major, minor uint8;
shutdown bool;
appChan <-chan []byte;
controlChan <-chan interface{};
header [13]byte;
}
func (w *recordWriter) loop(writer io.Writer, appChan <-chan []byte, controlChan <-chan interface{}) {
w.writer = writer;
w.encryptor = nop{};
w.mac = nop{};
w.appChan = appChan;
w.controlChan = controlChan;
for !w.shutdown {
msg := <-controlChan;
if _, ok := msg.(writerEnableApplicationData); ok {
break;
}
w.processControlMessage(msg);
}
for !w.shutdown {
// Always process control messages first.
if controlMsg, ok := <-controlChan; ok {
w.processControlMessage(controlMsg);
continue;
}
select {
case controlMsg := <-controlChan:
w.processControlMessage(controlMsg);
case appMsg := <-appChan:
w.processAppMessage(appMsg);
}
}
if !closed(appChan) {
go func() { for _ = range appChan {} }();
}
if !closed(controlChan) {
go func() { for _ = range controlChan {} }();
}
}
// fillMACHeader generates a MAC header. See RFC 4346, section 6.2.3.1.
func fillMACHeader(header *[13]byte, seqNum uint64, length int, r *record) {
header[0] = uint8(seqNum>>56);
header[1] = uint8(seqNum>>48);
header[2] = uint8(seqNum>>40);
header[3] = uint8(seqNum>>32);
header[4] = uint8(seqNum>>24);
header[5] = uint8(seqNum>>16);
header[6] = uint8(seqNum>>8);
header[7] = uint8(seqNum);
header[8] = uint8(r.contentType);
header[9] = r.major;
header[10] = r.minor;
header[11] = uint8(length>>8);
header[12] = uint8(length);
}
func (w *recordWriter) writeRecord(r *record) {
w.mac.Reset();
fillMACHeader(&w.header, w.seqNum, len(r.payload), r);
w.mac.Write(w.header[0:13]);
w.mac.Write(r.payload);
macBytes := w.mac.Sum();
w.encryptor.XORKeyStream(r.payload);
w.encryptor.XORKeyStream(macBytes);
length := len(r.payload)+len(macBytes);
w.header[11] = uint8(length>>8);
w.header[12] = uint8(length);
w.writer.Write(w.header[8:13]);
w.writer.Write(r.payload);
w.writer.Write(macBytes);
w.seqNum++;
}
func (w *recordWriter) processControlMessage(controlMsg interface{}) {
if controlMsg == nil {
w.shutdown = true;
return;
}
switch msg := controlMsg.(type) {
case writerChangeCipherSpec:
w.writeRecord(&record{recordTypeChangeCipherSpec, w.major, w.minor, []byte{0x01}});
w.encryptor = msg.encryptor;
w.mac = msg.mac;
w.seqNum = 0;
case writerSetVersion:
w.major = msg.major;
w.minor = msg.minor;
case alert:
w.writeRecord(&record{recordTypeAlert, w.major, w.minor, []byte{byte(msg.level), byte(msg.error)}});
case handshakeMessage:
// TODO(agl): marshal may return a slice too large for a single record.
w.writeRecord(&record{recordTypeHandshake, w.major, w.minor, msg.marshal()});
default:
fmt.Printf("processControlMessage: unknown %#v\n", msg);
}
}
func (w *recordWriter) processAppMessage(appMsg []byte) {
if closed(w.appChan) {
w.writeRecord(&record{recordTypeApplicationData, w.major, w.minor, []byte{byte(alertCloseNotify)}});
w.shutdown = true;
return;
}
var done int;
for done < len(appMsg) {
todo := len(appMsg);
if todo > maxTLSPlaintext {
todo = maxTLSPlaintext;
}
w.writeRecord(&record{recordTypeApplicationData, w.major, w.minor, appMsg[done : done+todo]});
done += todo;
}
}