boringssl/ssl/test/runner/handshake_server.go

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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 runner
import (
"bytes"
"crypto"
"crypto/ecdsa"
"crypto/elliptic"
"crypto/rsa"
"crypto/subtle"
"crypto/x509"
"errors"
"fmt"
"io"
"math/big"
)
// serverHandshakeState contains details of a server handshake in progress.
// It's discarded once the handshake has completed.
type serverHandshakeState struct {
c *Conn
clientHello *clientHelloMsg
hello *serverHelloMsg
suite *cipherSuite
ellipticOk bool
ecdsaOk bool
sessionState *sessionState
finishedHash finishedHash
masterSecret []byte
certsFromClient [][]byte
cert *Certificate
Add DTLS timeout and retransmit tests. This extends the packet adaptor protocol to send three commands: type command = | Packet of []byte | Timeout of time.Duration | TimeoutAck When the shim processes a Timeout in BIO_read, it sends TimeoutAck, fails the BIO_read, returns out of the SSL stack, advances the clock, calls DTLSv1_handle_timeout, and continues. If the Go side sends Timeout right between sending handshake flight N and reading flight N+1, the shim won't read the Timeout until it has sent flight N+1 (it only processes packet commands in BIO_read), so the TimeoutAck comes after N+1. Go then drops all packets before the TimeoutAck, thus dropping one transmit of flight N+1 without having to actually process the packets to determine the end of the flight. The shim then sees the updated clock, calls DTLSv1_handle_timeout, and re-sends flight N+1 for Go to process for real. When dropping packets, Go checks the epoch and increments sequence numbers so that we can continue to be strict here. This requires tracking the initial sequence number of the next epoch. The final Finished message takes an additional special-case to test. DTLS triggers retransmits on either a timeout or seeing a stale flight. OpenSSL only implements the former which should be sufficient (and is necessary) EXCEPT for the final Finished message. If the peer's final Finished message is lost, it won't be waiting for a message from us, so it won't time out anything. That retransmit must be triggered on stale message, so we retransmit the Finished message in Go. Change-Id: I3ffbdb1de525beb2ee831b304670a3387877634c Reviewed-on: https://boringssl-review.googlesource.com/3212 Reviewed-by: Adam Langley <agl@google.com>
2015-01-27 06:09:43 +00:00
finishedBytes []byte
}
// serverHandshake performs a TLS handshake as a server.
func (c *Conn) serverHandshake() error {
config := c.config
// If this is the first server handshake, we generate a random key to
// encrypt the tickets with.
config.serverInitOnce.Do(config.serverInit)
c.sendHandshakeSeq = 0
c.recvHandshakeSeq = 0
hs := serverHandshakeState{
c: c,
}
if err := hs.readClientHello(); err != nil {
return err
}
if c.vers >= VersionTLS13 {
if err := hs.doTLS13Handshake(); err != nil {
return err
}
} else {
isResume, err := hs.processClientHello()
if err != nil {
return err
}
// For an overview of TLS handshaking, see https://tools.ietf.org/html/rfc5246#section-7.3
if isResume {
// The client has included a session ticket and so we do an abbreviated handshake.
if err := hs.doResumeHandshake(); err != nil {
return err
}
if err := hs.establishKeys(); err != nil {
return err
}
if c.config.Bugs.RenewTicketOnResume {
if err := hs.sendSessionTicket(); err != nil {
return err
}
}
if err := hs.sendFinished(c.firstFinished[:]); err != nil {
return err
}
// Most retransmits are triggered by a timeout, but the final
// leg of the handshake is retransmited upon re-receiving a
// Finished.
if err := c.simulatePacketLoss(func() {
c.writeRecord(recordTypeHandshake, hs.finishedBytes)
c.flushHandshake()
}); err != nil {
return err
}
if err := hs.readFinished(nil, isResume); err != nil {
return err
}
c.didResume = true
} else {
// The client didn't include a session ticket, or it wasn't
// valid so we do a full handshake.
if err := hs.doFullHandshake(); err != nil {
return err
}
if err := hs.establishKeys(); err != nil {
return err
}
if err := hs.readFinished(c.firstFinished[:], isResume); err != nil {
return err
}
if c.config.Bugs.AlertBeforeFalseStartTest != 0 {
c.sendAlert(c.config.Bugs.AlertBeforeFalseStartTest)
}
if c.config.Bugs.ExpectFalseStart {
if err := c.readRecord(recordTypeApplicationData); err != nil {
return fmt.Errorf("tls: peer did not false start: %s", err)
}
}
if err := hs.sendSessionTicket(); err != nil {
return err
}
if err := hs.sendFinished(nil); err != nil {
return err
}
}
c.exporterSecret = hs.masterSecret
}
c.handshakeComplete = true
copy(c.clientRandom[:], hs.clientHello.random)
copy(c.serverRandom[:], hs.hello.random)
return nil
}
// readClientHello reads a ClientHello message from the client and determines
// the protocol version.
func (hs *serverHandshakeState) readClientHello() error {
config := hs.c.config
c := hs.c
Add DTLS timeout and retransmit tests. This extends the packet adaptor protocol to send three commands: type command = | Packet of []byte | Timeout of time.Duration | TimeoutAck When the shim processes a Timeout in BIO_read, it sends TimeoutAck, fails the BIO_read, returns out of the SSL stack, advances the clock, calls DTLSv1_handle_timeout, and continues. If the Go side sends Timeout right between sending handshake flight N and reading flight N+1, the shim won't read the Timeout until it has sent flight N+1 (it only processes packet commands in BIO_read), so the TimeoutAck comes after N+1. Go then drops all packets before the TimeoutAck, thus dropping one transmit of flight N+1 without having to actually process the packets to determine the end of the flight. The shim then sees the updated clock, calls DTLSv1_handle_timeout, and re-sends flight N+1 for Go to process for real. When dropping packets, Go checks the epoch and increments sequence numbers so that we can continue to be strict here. This requires tracking the initial sequence number of the next epoch. The final Finished message takes an additional special-case to test. DTLS triggers retransmits on either a timeout or seeing a stale flight. OpenSSL only implements the former which should be sufficient (and is necessary) EXCEPT for the final Finished message. If the peer's final Finished message is lost, it won't be waiting for a message from us, so it won't time out anything. That retransmit must be triggered on stale message, so we retransmit the Finished message in Go. Change-Id: I3ffbdb1de525beb2ee831b304670a3387877634c Reviewed-on: https://boringssl-review.googlesource.com/3212 Reviewed-by: Adam Langley <agl@google.com>
2015-01-27 06:09:43 +00:00
if err := c.simulatePacketLoss(nil); err != nil {
return err
Add DTLS timeout and retransmit tests. This extends the packet adaptor protocol to send three commands: type command = | Packet of []byte | Timeout of time.Duration | TimeoutAck When the shim processes a Timeout in BIO_read, it sends TimeoutAck, fails the BIO_read, returns out of the SSL stack, advances the clock, calls DTLSv1_handle_timeout, and continues. If the Go side sends Timeout right between sending handshake flight N and reading flight N+1, the shim won't read the Timeout until it has sent flight N+1 (it only processes packet commands in BIO_read), so the TimeoutAck comes after N+1. Go then drops all packets before the TimeoutAck, thus dropping one transmit of flight N+1 without having to actually process the packets to determine the end of the flight. The shim then sees the updated clock, calls DTLSv1_handle_timeout, and re-sends flight N+1 for Go to process for real. When dropping packets, Go checks the epoch and increments sequence numbers so that we can continue to be strict here. This requires tracking the initial sequence number of the next epoch. The final Finished message takes an additional special-case to test. DTLS triggers retransmits on either a timeout or seeing a stale flight. OpenSSL only implements the former which should be sufficient (and is necessary) EXCEPT for the final Finished message. If the peer's final Finished message is lost, it won't be waiting for a message from us, so it won't time out anything. That retransmit must be triggered on stale message, so we retransmit the Finished message in Go. Change-Id: I3ffbdb1de525beb2ee831b304670a3387877634c Reviewed-on: https://boringssl-review.googlesource.com/3212 Reviewed-by: Adam Langley <agl@google.com>
2015-01-27 06:09:43 +00:00
}
msg, err := c.readHandshake()
if err != nil {
return err
}
var ok bool
hs.clientHello, ok = msg.(*clientHelloMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(hs.clientHello, msg)
}
if size := config.Bugs.RequireClientHelloSize; size != 0 && len(hs.clientHello.raw) != size {
return fmt.Errorf("tls: ClientHello record size is %d, but expected %d", len(hs.clientHello.raw), size)
}
if c.isDTLS && !config.Bugs.SkipHelloVerifyRequest {
// Per RFC 6347, the version field in HelloVerifyRequest SHOULD
// be always DTLS 1.0
helloVerifyRequest := &helloVerifyRequestMsg{
vers: VersionTLS10,
cookie: make([]byte, 32),
}
if _, err := io.ReadFull(c.config.rand(), helloVerifyRequest.cookie); err != nil {
c.sendAlert(alertInternalError)
return errors.New("dtls: short read from Rand: " + err.Error())
}
c.writeRecord(recordTypeHandshake, helloVerifyRequest.marshal())
c.flushHandshake()
Add DTLS timeout and retransmit tests. This extends the packet adaptor protocol to send three commands: type command = | Packet of []byte | Timeout of time.Duration | TimeoutAck When the shim processes a Timeout in BIO_read, it sends TimeoutAck, fails the BIO_read, returns out of the SSL stack, advances the clock, calls DTLSv1_handle_timeout, and continues. If the Go side sends Timeout right between sending handshake flight N and reading flight N+1, the shim won't read the Timeout until it has sent flight N+1 (it only processes packet commands in BIO_read), so the TimeoutAck comes after N+1. Go then drops all packets before the TimeoutAck, thus dropping one transmit of flight N+1 without having to actually process the packets to determine the end of the flight. The shim then sees the updated clock, calls DTLSv1_handle_timeout, and re-sends flight N+1 for Go to process for real. When dropping packets, Go checks the epoch and increments sequence numbers so that we can continue to be strict here. This requires tracking the initial sequence number of the next epoch. The final Finished message takes an additional special-case to test. DTLS triggers retransmits on either a timeout or seeing a stale flight. OpenSSL only implements the former which should be sufficient (and is necessary) EXCEPT for the final Finished message. If the peer's final Finished message is lost, it won't be waiting for a message from us, so it won't time out anything. That retransmit must be triggered on stale message, so we retransmit the Finished message in Go. Change-Id: I3ffbdb1de525beb2ee831b304670a3387877634c Reviewed-on: https://boringssl-review.googlesource.com/3212 Reviewed-by: Adam Langley <agl@google.com>
2015-01-27 06:09:43 +00:00
if err := c.simulatePacketLoss(nil); err != nil {
return err
Add DTLS timeout and retransmit tests. This extends the packet adaptor protocol to send three commands: type command = | Packet of []byte | Timeout of time.Duration | TimeoutAck When the shim processes a Timeout in BIO_read, it sends TimeoutAck, fails the BIO_read, returns out of the SSL stack, advances the clock, calls DTLSv1_handle_timeout, and continues. If the Go side sends Timeout right between sending handshake flight N and reading flight N+1, the shim won't read the Timeout until it has sent flight N+1 (it only processes packet commands in BIO_read), so the TimeoutAck comes after N+1. Go then drops all packets before the TimeoutAck, thus dropping one transmit of flight N+1 without having to actually process the packets to determine the end of the flight. The shim then sees the updated clock, calls DTLSv1_handle_timeout, and re-sends flight N+1 for Go to process for real. When dropping packets, Go checks the epoch and increments sequence numbers so that we can continue to be strict here. This requires tracking the initial sequence number of the next epoch. The final Finished message takes an additional special-case to test. DTLS triggers retransmits on either a timeout or seeing a stale flight. OpenSSL only implements the former which should be sufficient (and is necessary) EXCEPT for the final Finished message. If the peer's final Finished message is lost, it won't be waiting for a message from us, so it won't time out anything. That retransmit must be triggered on stale message, so we retransmit the Finished message in Go. Change-Id: I3ffbdb1de525beb2ee831b304670a3387877634c Reviewed-on: https://boringssl-review.googlesource.com/3212 Reviewed-by: Adam Langley <agl@google.com>
2015-01-27 06:09:43 +00:00
}
msg, err := c.readHandshake()
if err != nil {
return err
}
newClientHello, ok := msg.(*clientHelloMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(hs.clientHello, msg)
}
if !bytes.Equal(newClientHello.cookie, helloVerifyRequest.cookie) {
return errors.New("dtls: invalid cookie")
}
// Apart from the cookie, the two ClientHellos must
// match. Note that clientHello.equal compares the
// serialization, so we make a copy.
oldClientHelloCopy := *hs.clientHello
oldClientHelloCopy.raw = nil
oldClientHelloCopy.cookie = nil
newClientHelloCopy := *newClientHello
newClientHelloCopy.raw = nil
newClientHelloCopy.cookie = nil
if !oldClientHelloCopy.equal(&newClientHelloCopy) {
return errors.New("dtls: retransmitted ClientHello does not match")
}
hs.clientHello = newClientHello
}
if config.Bugs.RequireSameRenegoClientVersion && c.clientVersion != 0 {
if c.clientVersion != hs.clientHello.vers {
return fmt.Errorf("tls: client offered different version on renego")
}
}
c.clientVersion = hs.clientHello.vers
// Reject < 1.2 ClientHellos with signature_algorithms.
if c.clientVersion < VersionTLS12 && len(hs.clientHello.signatureAlgorithms) > 0 {
return fmt.Errorf("tls: client included signature_algorithms before TLS 1.2")
}
// Check the client cipher list is consistent with the version.
if hs.clientHello.vers < VersionTLS12 {
for _, id := range hs.clientHello.cipherSuites {
if isTLS12Cipher(id) {
return fmt.Errorf("tls: client offered TLS 1.2 cipher before TLS 1.2")
}
}
}
if config.Bugs.NegotiateVersion != 0 {
c.vers = config.Bugs.NegotiateVersion
} else {
c.vers, ok = config.mutualVersion(hs.clientHello.vers, c.isDTLS)
if !ok {
c.sendAlert(alertProtocolVersion)
return fmt.Errorf("tls: client offered an unsupported, maximum protocol version of %x", hs.clientHello.vers)
}
}
c.haveVers = true
var scsvFound bool
for _, cipherSuite := range hs.clientHello.cipherSuites {
if cipherSuite == fallbackSCSV {
scsvFound = true
break
}
}
if !scsvFound && config.Bugs.FailIfNotFallbackSCSV {
return errors.New("tls: no fallback SCSV found when expected")
} else if scsvFound && !config.Bugs.FailIfNotFallbackSCSV {
return errors.New("tls: fallback SCSV found when not expected")
}
if config.Bugs.IgnorePeerSignatureAlgorithmPreferences {
hs.clientHello.signatureAlgorithms = config.signSignatureAlgorithms()
}
if config.Bugs.IgnorePeerCurvePreferences {
hs.clientHello.supportedCurves = config.curvePreferences()
}
if config.Bugs.IgnorePeerCipherPreferences {
hs.clientHello.cipherSuites = config.cipherSuites()
}
return nil
}
func (hs *serverHandshakeState) doTLS13Handshake() error {
c := hs.c
config := c.config
hs.hello = &serverHelloMsg{
isDTLS: c.isDTLS,
vers: c.vers,
}
hs.hello.random = make([]byte, 32)
if _, err := io.ReadFull(config.rand(), hs.hello.random); err != nil {
c.sendAlert(alertInternalError)
return err
}
// TLS 1.3 forbids clients from advertising any non-null compression.
if len(hs.clientHello.compressionMethods) != 1 || hs.clientHello.compressionMethods[0] != compressionNone {
return errors.New("tls: client sent compression method other than null for TLS 1.3")
}
// Prepare an EncryptedExtensions message, but do not send it yet.
encryptedExtensions := new(encryptedExtensionsMsg)
encryptedExtensions.empty = config.Bugs.EmptyEncryptedExtensions
if err := hs.processClientExtensions(&encryptedExtensions.extensions); err != nil {
return err
}
supportedCurve := false
var selectedCurve CurveID
preferredCurves := config.curvePreferences()
Curves:
for _, curve := range hs.clientHello.supportedCurves {
for _, supported := range preferredCurves {
if supported == curve {
supportedCurve = true
selectedCurve = curve
break Curves
}
}
}
_, ecdsaOk := hs.cert.PrivateKey.(*ecdsa.PrivateKey)
// TODO(davidben): Implement PSK support.
pskOk := false
// Select the cipher suite.
var preferenceList, supportedList []uint16
if config.PreferServerCipherSuites {
preferenceList = config.cipherSuites()
supportedList = hs.clientHello.cipherSuites
} else {
preferenceList = hs.clientHello.cipherSuites
supportedList = config.cipherSuites()
}
for _, id := range preferenceList {
if hs.suite = c.tryCipherSuite(id, supportedList, c.vers, supportedCurve, ecdsaOk, pskOk); hs.suite != nil {
break
}
}
if hs.suite == nil {
c.sendAlert(alertHandshakeFailure)
return errors.New("tls: no cipher suite supported by both client and server")
}
hs.hello.cipherSuite = hs.suite.id
if c.config.Bugs.SendCipherSuite != 0 {
hs.hello.cipherSuite = c.config.Bugs.SendCipherSuite
}
hs.finishedHash = newFinishedHash(c.vers, hs.suite)
hs.finishedHash.discardHandshakeBuffer()
hs.writeClientHash(hs.clientHello.marshal())
// Resolve PSK and compute the early secret.
// TODO(davidben): Implement PSK in TLS 1.3.
psk := hs.finishedHash.zeroSecret()
hs.finishedHash.setResumptionContext(hs.finishedHash.zeroSecret())
earlySecret := hs.finishedHash.extractKey(hs.finishedHash.zeroSecret(), psk)
// Resolve ECDHE and compute the handshake secret.
var ecdheSecret []byte
if hs.suite.flags&suiteECDHE != 0 && !config.Bugs.MissingKeyShare {
// Look for the key share corresponding to our selected curve.
var selectedKeyShare *keyShareEntry
for i := range hs.clientHello.keyShares {
if hs.clientHello.keyShares[i].group == selectedCurve {
selectedKeyShare = &hs.clientHello.keyShares[i]
break
}
}
if selectedKeyShare == nil {
// TODO(davidben,nharper): Implement HelloRetryRequest.
return errors.New("tls: HelloRetryRequest not implemented")
}
// Once a curve has been selected and a key share identified,
// the server needs to generate a public value and send it in
// the ServerHello.
curve, ok := curveForCurveID(selectedKeyShare.group)
if !ok {
panic("tls: server failed to look up curve ID")
}
var publicKey []byte
var err error
publicKey, ecdheSecret, err = curve.accept(config.rand(), selectedKeyShare.keyExchange)
if err != nil {
c.sendAlert(alertHandshakeFailure)
return err
}
hs.hello.hasKeyShare = true
curveID := selectedKeyShare.group
if c.config.Bugs.SendCurve != 0 {
curveID = config.Bugs.SendCurve
}
if c.config.Bugs.InvalidECDHPoint {
publicKey[0] ^= 0xff
}
hs.hello.keyShare = keyShareEntry{
group: curveID,
keyExchange: publicKey,
}
if config.Bugs.EncryptedExtensionsWithKeyShare {
encryptedExtensions.extensions.hasKeyShare = true
encryptedExtensions.extensions.keyShare = keyShareEntry{
group: curveID,
keyExchange: publicKey,
}
}
} else {
ecdheSecret = hs.finishedHash.zeroSecret()
}
// Send unencrypted ServerHello.
hs.writeServerHash(hs.hello.marshal())
if config.Bugs.PartialEncryptedExtensionsWithServerHello {
helloBytes := hs.hello.marshal()
toWrite := make([]byte, 0, len(helloBytes)+1)
toWrite = append(toWrite, helloBytes...)
toWrite = append(toWrite, typeEncryptedExtensions)
c.writeRecord(recordTypeHandshake, toWrite)
} else {
c.writeRecord(recordTypeHandshake, hs.hello.marshal())
}
c.flushHandshake()
// Compute the handshake secret.
handshakeSecret := hs.finishedHash.extractKey(earlySecret, ecdheSecret)
// Switch to handshake traffic keys.
handshakeTrafficSecret := hs.finishedHash.deriveSecret(handshakeSecret, handshakeTrafficLabel)
c.out.updateKeys(deriveTrafficAEAD(c.vers, hs.suite, handshakeTrafficSecret, handshakePhase, serverWrite), c.vers)
c.in.updateKeys(deriveTrafficAEAD(c.vers, hs.suite, handshakeTrafficSecret, handshakePhase, clientWrite), c.vers)
if hs.suite.flags&suitePSK != 0 {
return errors.New("tls: PSK ciphers not implemented for TLS 1.3")
} else {
if hs.clientHello.ocspStapling {
encryptedExtensions.extensions.ocspResponse = hs.cert.OCSPStaple
}
if hs.clientHello.sctListSupported {
encryptedExtensions.extensions.sctList = hs.cert.SignedCertificateTimestampList
}
}
// Send EncryptedExtensions.
hs.writeServerHash(encryptedExtensions.marshal())
if config.Bugs.PartialEncryptedExtensionsWithServerHello {
// The first byte has already been sent.
c.writeRecord(recordTypeHandshake, encryptedExtensions.marshal()[1:])
} else {
c.writeRecord(recordTypeHandshake, encryptedExtensions.marshal())
}
if hs.suite.flags&suitePSK == 0 {
if config.ClientAuth >= RequestClientCert {
// Request a client certificate
certReq := &certificateRequestMsg{
hasSignatureAlgorithm: true,
hasRequestContext: true,
}
if !config.Bugs.NoSignatureAlgorithms {
certReq.signatureAlgorithms = config.verifySignatureAlgorithms()
}
// An empty list of certificateAuthorities signals to
// the client that it may send any certificate in response
// to our request. When we know the CAs we trust, then
// we can send them down, so that the client can choose
// an appropriate certificate to give to us.
if config.ClientCAs != nil {
certReq.certificateAuthorities = config.ClientCAs.Subjects()
}
hs.writeServerHash(certReq.marshal())
c.writeRecord(recordTypeHandshake, certReq.marshal())
}
certMsg := &certificateMsg{
hasRequestContext: true,
}
if !config.Bugs.EmptyCertificateList {
certMsg.certificates = hs.cert.Certificate
}
certMsgBytes := certMsg.marshal()
hs.writeServerHash(certMsgBytes)
c.writeRecord(recordTypeHandshake, certMsgBytes)
certVerify := &certificateVerifyMsg{
hasSignatureAlgorithm: true,
}
// Determine the hash to sign.
privKey := hs.cert.PrivateKey
var err error
certVerify.signatureAlgorithm, err = selectSignatureAlgorithm(c.vers, privKey, config, hs.clientHello.signatureAlgorithms)
if err != nil {
c.sendAlert(alertInternalError)
return err
}
input := hs.finishedHash.certificateVerifyInput(serverCertificateVerifyContextTLS13)
certVerify.signature, err = signMessage(c.vers, privKey, c.config, certVerify.signatureAlgorithm, input)
if err != nil {
c.sendAlert(alertInternalError)
return err
}
if config.Bugs.SendSignatureAlgorithm != 0 {
certVerify.signatureAlgorithm = config.Bugs.SendSignatureAlgorithm
}
hs.writeServerHash(certVerify.marshal())
c.writeRecord(recordTypeHandshake, certVerify.marshal())
}
finished := new(finishedMsg)
finished.verifyData = hs.finishedHash.serverSum(handshakeTrafficSecret)
if config.Bugs.BadFinished {
finished.verifyData[0]++
}
hs.writeServerHash(finished.marshal())
c.writeRecord(recordTypeHandshake, finished.marshal())
c.flushHandshake()
// The various secrets do not incorporate the client's final leg, so
// derive them now before updating the handshake context.
masterSecret := hs.finishedHash.extractKey(handshakeSecret, hs.finishedHash.zeroSecret())
trafficSecret := hs.finishedHash.deriveSecret(masterSecret, applicationTrafficLabel)
// Switch to application data keys on write. In particular, any alerts
// from the client certificate are sent over these keys.
c.out.updateKeys(deriveTrafficAEAD(c.vers, hs.suite, trafficSecret, applicationPhase, serverWrite), c.vers)
// If we requested a client certificate, then the client must send a
// certificate message, even if it's empty.
if config.ClientAuth >= RequestClientCert {
msg, err := c.readHandshake()
if err != nil {
return err
}
certMsg, ok := msg.(*certificateMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(certMsg, msg)
}
hs.writeClientHash(certMsg.marshal())
if len(certMsg.certificates) == 0 {
// The client didn't actually send a certificate
switch config.ClientAuth {
case RequireAnyClientCert, RequireAndVerifyClientCert:
c.sendAlert(alertBadCertificate)
return errors.New("tls: client didn't provide a certificate")
}
}
pub, err := hs.processCertsFromClient(certMsg.certificates)
if err != nil {
return err
}
if len(c.peerCertificates) > 0 {
msg, err = c.readHandshake()
if err != nil {
return err
}
certVerify, ok := msg.(*certificateVerifyMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(certVerify, msg)
}
c.peerSignatureAlgorithm = certVerify.signatureAlgorithm
input := hs.finishedHash.certificateVerifyInput(clientCertificateVerifyContextTLS13)
if err := verifyMessage(c.vers, pub, config, certVerify.signatureAlgorithm, input, certVerify.signature); err != nil {
c.sendAlert(alertBadCertificate)
return err
}
hs.writeClientHash(certVerify.marshal())
}
}
// Read the client Finished message.
msg, err := c.readHandshake()
if err != nil {
return err
}
clientFinished, ok := msg.(*finishedMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(clientFinished, msg)
}
verify := hs.finishedHash.clientSum(handshakeTrafficSecret)
if len(verify) != len(clientFinished.verifyData) ||
subtle.ConstantTimeCompare(verify, clientFinished.verifyData) != 1 {
c.sendAlert(alertHandshakeFailure)
return errors.New("tls: client's Finished message was incorrect")
}
hs.writeClientHash(clientFinished.marshal())
// Switch to application data keys on read.
c.in.updateKeys(deriveTrafficAEAD(c.vers, hs.suite, trafficSecret, applicationPhase, clientWrite), c.vers)
// TODO(davidben): Derive and save the resumption master secret for receiving tickets.
// TODO(davidben): Save the traffic secret for KeyUpdate.
c.cipherSuite = hs.suite
c.exporterSecret = hs.finishedHash.deriveSecret(masterSecret, exporterLabel)
return nil
}
// processClientHello processes the ClientHello message from the client and
// decides whether we will perform session resumption.
func (hs *serverHandshakeState) processClientHello() (isResume bool, err error) {
config := hs.c.config
c := hs.c
hs.hello = &serverHelloMsg{
isDTLS: c.isDTLS,
vers: c.vers,
compressionMethod: compressionNone,
}
hs.hello.random = make([]byte, 32)
_, err = io.ReadFull(config.rand(), hs.hello.random)
if err != nil {
c.sendAlert(alertInternalError)
return false, err
}
// Signal downgrades in the server random, per draft-ietf-tls-tls13-14,
// section 6.3.1.2.
if c.vers <= VersionTLS12 && config.maxVersion(c.isDTLS) >= VersionTLS13 {
copy(hs.hello.random[len(hs.hello.random)-8:], downgradeTLS13)
}
if c.vers <= VersionTLS11 && config.maxVersion(c.isDTLS) == VersionTLS12 {
copy(hs.hello.random[len(hs.hello.random)-8:], downgradeTLS12)
}
foundCompression := false
// We only support null compression, so check that the client offered it.
for _, compression := range hs.clientHello.compressionMethods {
if compression == compressionNone {
foundCompression = true
break
}
}
if !foundCompression {
c.sendAlert(alertHandshakeFailure)
return false, errors.New("tls: client does not support uncompressed connections")
}
if err := hs.processClientExtensions(&hs.hello.extensions); err != nil {
return false, err
}
supportedCurve := false
preferredCurves := config.curvePreferences()
Curves:
for _, curve := range hs.clientHello.supportedCurves {
for _, supported := range preferredCurves {
if supported == curve {
supportedCurve = true
break Curves
}
}
}
supportedPointFormat := false
for _, pointFormat := range hs.clientHello.supportedPoints {
if pointFormat == pointFormatUncompressed {
supportedPointFormat = true
break
}
}
hs.ellipticOk = supportedCurve && supportedPointFormat
_, hs.ecdsaOk = hs.cert.PrivateKey.(*ecdsa.PrivateKey)
// For test purposes, check that the peer never offers a session when
// renegotiating.
if c.cipherSuite != nil && len(hs.clientHello.sessionId) > 0 && c.config.Bugs.FailIfResumeOnRenego {
return false, errors.New("tls: offered resumption on renegotiation")
}
if c.config.Bugs.FailIfSessionOffered && (len(hs.clientHello.sessionTicket) > 0 || len(hs.clientHello.sessionId) > 0) {
return false, errors.New("tls: client offered a session ticket or ID")
}
if hs.checkForResumption() {
return true, nil
}
var preferenceList, supportedList []uint16
if c.config.PreferServerCipherSuites {
preferenceList = c.config.cipherSuites()
supportedList = hs.clientHello.cipherSuites
} else {
preferenceList = hs.clientHello.cipherSuites
supportedList = c.config.cipherSuites()
}
for _, id := range preferenceList {
if hs.suite = c.tryCipherSuite(id, supportedList, c.vers, hs.ellipticOk, hs.ecdsaOk, true); hs.suite != nil {
break
}
}
if hs.suite == nil {
c.sendAlert(alertHandshakeFailure)
return false, errors.New("tls: no cipher suite supported by both client and server")
}
return false, nil
}
// processClientExtensions processes all ClientHello extensions not directly
// related to cipher suite negotiation and writes responses in serverExtensions.
func (hs *serverHandshakeState) processClientExtensions(serverExtensions *serverExtensions) error {
config := hs.c.config
c := hs.c
if c.vers < VersionTLS13 || config.Bugs.NegotiateRenegotiationInfoAtAllVersions {
if !bytes.Equal(c.clientVerify, hs.clientHello.secureRenegotiation) {
c.sendAlert(alertHandshakeFailure)
return errors.New("tls: renegotiation mismatch")
}
if len(c.clientVerify) > 0 && !c.config.Bugs.EmptyRenegotiationInfo {
serverExtensions.secureRenegotiation = append(serverExtensions.secureRenegotiation, c.clientVerify...)
serverExtensions.secureRenegotiation = append(serverExtensions.secureRenegotiation, c.serverVerify...)
if c.config.Bugs.BadRenegotiationInfo {
serverExtensions.secureRenegotiation[0] ^= 0x80
}
} else {
serverExtensions.secureRenegotiation = hs.clientHello.secureRenegotiation
}
if c.noRenegotiationInfo() {
serverExtensions.secureRenegotiation = nil
}
}
serverExtensions.duplicateExtension = c.config.Bugs.DuplicateExtension
if len(hs.clientHello.serverName) > 0 {
c.serverName = hs.clientHello.serverName
}
if len(config.Certificates) == 0 {
c.sendAlert(alertInternalError)
return errors.New("tls: no certificates configured")
}
hs.cert = &config.Certificates[0]
if len(hs.clientHello.serverName) > 0 {
hs.cert = config.getCertificateForName(hs.clientHello.serverName)
}
if expected := c.config.Bugs.ExpectServerName; expected != "" && expected != hs.clientHello.serverName {
return errors.New("tls: unexpected server name")
}
if len(hs.clientHello.alpnProtocols) > 0 {
if proto := c.config.Bugs.ALPNProtocol; proto != nil {
serverExtensions.alpnProtocol = *proto
serverExtensions.alpnProtocolEmpty = len(*proto) == 0
c.clientProtocol = *proto
c.usedALPN = true
} else if selectedProto, fallback := mutualProtocol(hs.clientHello.alpnProtocols, c.config.NextProtos); !fallback {
serverExtensions.alpnProtocol = selectedProto
c.clientProtocol = selectedProto
c.usedALPN = true
}
}
if c.vers < VersionTLS13 || config.Bugs.NegotiateNPNAtAllVersions {
if len(hs.clientHello.alpnProtocols) == 0 || c.config.Bugs.NegotiateALPNAndNPN {
// Although sending an empty NPN extension is reasonable, Firefox has
// had a bug around this. Best to send nothing at all if
// config.NextProtos is empty. See
// https://code.google.com/p/go/issues/detail?id=5445.
if hs.clientHello.nextProtoNeg && len(config.NextProtos) > 0 {
serverExtensions.nextProtoNeg = true
serverExtensions.nextProtos = config.NextProtos
serverExtensions.npnLast = config.Bugs.SwapNPNAndALPN
}
}
}
if c.vers < VersionTLS13 || config.Bugs.NegotiateEMSAtAllVersions {
serverExtensions.extendedMasterSecret = c.vers >= VersionTLS10 && hs.clientHello.extendedMasterSecret && !c.config.Bugs.NoExtendedMasterSecret
}
if c.vers < VersionTLS13 || config.Bugs.NegotiateChannelIDAtAllVersions {
if hs.clientHello.channelIDSupported && config.RequestChannelID {
serverExtensions.channelIDRequested = true
}
}
if hs.clientHello.srtpProtectionProfiles != nil {
SRTPLoop:
for _, p1 := range c.config.SRTPProtectionProfiles {
for _, p2 := range hs.clientHello.srtpProtectionProfiles {
if p1 == p2 {
serverExtensions.srtpProtectionProfile = p1
c.srtpProtectionProfile = p1
break SRTPLoop
}
}
}
}
if c.config.Bugs.SendSRTPProtectionProfile != 0 {
serverExtensions.srtpProtectionProfile = c.config.Bugs.SendSRTPProtectionProfile
}
if expected := c.config.Bugs.ExpectedCustomExtension; expected != nil {
if hs.clientHello.customExtension != *expected {
return fmt.Errorf("tls: bad custom extension contents %q", hs.clientHello.customExtension)
}
}
serverExtensions.customExtension = config.Bugs.CustomExtension
if c.config.Bugs.AdvertiseTicketExtension {
serverExtensions.ticketSupported = true
}
return nil
}
// checkForResumption returns true if we should perform resumption on this connection.
func (hs *serverHandshakeState) checkForResumption() bool {
c := hs.c
if len(hs.clientHello.sessionTicket) > 0 {
if c.config.SessionTicketsDisabled {
return false
}
var ok bool
if hs.sessionState, ok = c.decryptTicket(hs.clientHello.sessionTicket); !ok {
return false
}
} else {
if c.config.ServerSessionCache == nil {
return false
}
var ok bool
sessionId := string(hs.clientHello.sessionId)
if hs.sessionState, ok = c.config.ServerSessionCache.Get(sessionId); !ok {
return false
}
}
// Never resume a session for a different SSL version.
if !c.config.Bugs.AllowSessionVersionMismatch && c.vers != hs.sessionState.vers {
return false
}
cipherSuiteOk := false
// Check that the client is still offering the ciphersuite in the session.
for _, id := range hs.clientHello.cipherSuites {
if id == hs.sessionState.cipherSuite {
cipherSuiteOk = true
break
}
}
if !cipherSuiteOk {
return false
}
// Check that we also support the ciphersuite from the session.
hs.suite = c.tryCipherSuite(hs.sessionState.cipherSuite, c.config.cipherSuites(), hs.sessionState.vers, hs.ellipticOk, hs.ecdsaOk, true)
if hs.suite == nil {
return false
}
sessionHasClientCerts := len(hs.sessionState.certificates) != 0
needClientCerts := c.config.ClientAuth == RequireAnyClientCert || c.config.ClientAuth == RequireAndVerifyClientCert
if needClientCerts && !sessionHasClientCerts {
return false
}
if sessionHasClientCerts && c.config.ClientAuth == NoClientCert {
return false
}
return true
}
func (hs *serverHandshakeState) doResumeHandshake() error {
c := hs.c
hs.hello.cipherSuite = hs.suite.id
if c.config.Bugs.SendCipherSuite != 0 {
hs.hello.cipherSuite = c.config.Bugs.SendCipherSuite
}
// We echo the client's session ID in the ServerHello to let it know
// that we're doing a resumption.
hs.hello.sessionId = hs.clientHello.sessionId
hs.hello.extensions.ticketSupported = c.config.Bugs.RenewTicketOnResume
if c.config.Bugs.SendSCTListOnResume != nil {
hs.hello.extensions.sctList = c.config.Bugs.SendSCTListOnResume
}
hs.finishedHash = newFinishedHash(c.vers, hs.suite)
hs.finishedHash.discardHandshakeBuffer()
hs.writeClientHash(hs.clientHello.marshal())
hs.writeServerHash(hs.hello.marshal())
c.writeRecord(recordTypeHandshake, hs.hello.marshal())
if len(hs.sessionState.certificates) > 0 {
if _, err := hs.processCertsFromClient(hs.sessionState.certificates); err != nil {
return err
}
}
hs.masterSecret = hs.sessionState.masterSecret
c.extendedMasterSecret = hs.sessionState.extendedMasterSecret
return nil
}
func (hs *serverHandshakeState) doFullHandshake() error {
config := hs.c.config
c := hs.c
isPSK := hs.suite.flags&suitePSK != 0
if !isPSK && hs.clientHello.ocspStapling && len(hs.cert.OCSPStaple) > 0 {
hs.hello.extensions.ocspStapling = true
}
if hs.clientHello.sctListSupported && len(hs.cert.SignedCertificateTimestampList) > 0 {
hs.hello.extensions.sctList = hs.cert.SignedCertificateTimestampList
}
hs.hello.extensions.ticketSupported = hs.clientHello.ticketSupported && !config.SessionTicketsDisabled && c.vers > VersionSSL30
hs.hello.cipherSuite = hs.suite.id
if config.Bugs.SendCipherSuite != 0 {
hs.hello.cipherSuite = config.Bugs.SendCipherSuite
}
c.extendedMasterSecret = hs.hello.extensions.extendedMasterSecret
// Generate a session ID if we're to save the session.
if !hs.hello.extensions.ticketSupported && config.ServerSessionCache != nil {
hs.hello.sessionId = make([]byte, 32)
if _, err := io.ReadFull(config.rand(), hs.hello.sessionId); err != nil {
c.sendAlert(alertInternalError)
return errors.New("tls: short read from Rand: " + err.Error())
}
}
hs.finishedHash = newFinishedHash(c.vers, hs.suite)
hs.writeClientHash(hs.clientHello.marshal())
hs.writeServerHash(hs.hello.marshal())
c.writeRecord(recordTypeHandshake, hs.hello.marshal())
if !isPSK {
certMsg := new(certificateMsg)
if !config.Bugs.EmptyCertificateList {
certMsg.certificates = hs.cert.Certificate
}
if !config.Bugs.UnauthenticatedECDH {
certMsgBytes := certMsg.marshal()
hs.writeServerHash(certMsgBytes)
c.writeRecord(recordTypeHandshake, certMsgBytes)
}
}
if hs.hello.extensions.ocspStapling && !c.config.Bugs.SkipCertificateStatus {
certStatus := new(certificateStatusMsg)
certStatus.statusType = statusTypeOCSP
certStatus.response = hs.cert.OCSPStaple
hs.writeServerHash(certStatus.marshal())
c.writeRecord(recordTypeHandshake, certStatus.marshal())
}
keyAgreement := hs.suite.ka(c.vers)
skx, err := keyAgreement.generateServerKeyExchange(config, hs.cert, hs.clientHello, hs.hello)
if err != nil {
c.sendAlert(alertHandshakeFailure)
return err
}
if skx != nil && !config.Bugs.SkipServerKeyExchange {
hs.writeServerHash(skx.marshal())
c.writeRecord(recordTypeHandshake, skx.marshal())
}
if config.ClientAuth >= RequestClientCert {
// Request a client certificate
certReq := &certificateRequestMsg{
certificateTypes: config.ClientCertificateTypes,
}
if certReq.certificateTypes == nil {
certReq.certificateTypes = []byte{
byte(CertTypeRSASign),
byte(CertTypeECDSASign),
}
}
if c.vers >= VersionTLS12 {
certReq.hasSignatureAlgorithm = true
if !config.Bugs.NoSignatureAlgorithms {
certReq.signatureAlgorithms = config.verifySignatureAlgorithms()
}
}
// An empty list of certificateAuthorities signals to
// the client that it may send any certificate in response
// to our request. When we know the CAs we trust, then
// we can send them down, so that the client can choose
// an appropriate certificate to give to us.
if config.ClientCAs != nil {
certReq.certificateAuthorities = config.ClientCAs.Subjects()
}
hs.writeServerHash(certReq.marshal())
c.writeRecord(recordTypeHandshake, certReq.marshal())
}
helloDone := new(serverHelloDoneMsg)
hs.writeServerHash(helloDone.marshal())
c.writeRecord(recordTypeHandshake, helloDone.marshal())
c.flushHandshake()
var pub crypto.PublicKey // public key for client auth, if any
Add DTLS timeout and retransmit tests. This extends the packet adaptor protocol to send three commands: type command = | Packet of []byte | Timeout of time.Duration | TimeoutAck When the shim processes a Timeout in BIO_read, it sends TimeoutAck, fails the BIO_read, returns out of the SSL stack, advances the clock, calls DTLSv1_handle_timeout, and continues. If the Go side sends Timeout right between sending handshake flight N and reading flight N+1, the shim won't read the Timeout until it has sent flight N+1 (it only processes packet commands in BIO_read), so the TimeoutAck comes after N+1. Go then drops all packets before the TimeoutAck, thus dropping one transmit of flight N+1 without having to actually process the packets to determine the end of the flight. The shim then sees the updated clock, calls DTLSv1_handle_timeout, and re-sends flight N+1 for Go to process for real. When dropping packets, Go checks the epoch and increments sequence numbers so that we can continue to be strict here. This requires tracking the initial sequence number of the next epoch. The final Finished message takes an additional special-case to test. DTLS triggers retransmits on either a timeout or seeing a stale flight. OpenSSL only implements the former which should be sufficient (and is necessary) EXCEPT for the final Finished message. If the peer's final Finished message is lost, it won't be waiting for a message from us, so it won't time out anything. That retransmit must be triggered on stale message, so we retransmit the Finished message in Go. Change-Id: I3ffbdb1de525beb2ee831b304670a3387877634c Reviewed-on: https://boringssl-review.googlesource.com/3212 Reviewed-by: Adam Langley <agl@google.com>
2015-01-27 06:09:43 +00:00
if err := c.simulatePacketLoss(nil); err != nil {
return err
}
msg, err := c.readHandshake()
if err != nil {
return err
}
var ok bool
// If we requested a client certificate, then the client must send a
// certificate message, even if it's empty.
if config.ClientAuth >= RequestClientCert {
var certMsg *certificateMsg
var certificates [][]byte
if certMsg, ok = msg.(*certificateMsg); ok {
if c.vers == VersionSSL30 && len(certMsg.certificates) == 0 {
return errors.New("tls: empty certificate message in SSL 3.0")
}
hs.writeClientHash(certMsg.marshal())
certificates = certMsg.certificates
} else if c.vers != VersionSSL30 {
// In TLS, the Certificate message is required. In SSL
// 3.0, the peer skips it when sending no certificates.
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(certMsg, msg)
}
if len(certificates) == 0 {
// The client didn't actually send a certificate
switch config.ClientAuth {
case RequireAnyClientCert, RequireAndVerifyClientCert:
c.sendAlert(alertBadCertificate)
return errors.New("tls: client didn't provide a certificate")
}
}
pub, err = hs.processCertsFromClient(certificates)
if err != nil {
return err
}
if ok {
msg, err = c.readHandshake()
if err != nil {
return err
}
}
}
// Get client key exchange
ckx, ok := msg.(*clientKeyExchangeMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(ckx, msg)
}
hs.writeClientHash(ckx.marshal())
preMasterSecret, err := keyAgreement.processClientKeyExchange(config, hs.cert, ckx, c.vers)
if err != nil {
c.sendAlert(alertHandshakeFailure)
return err
}
if c.extendedMasterSecret {
hs.masterSecret = extendedMasterFromPreMasterSecret(c.vers, hs.suite, preMasterSecret, hs.finishedHash)
} else {
if c.config.Bugs.RequireExtendedMasterSecret {
return errors.New("tls: extended master secret required but not supported by peer")
}
hs.masterSecret = masterFromPreMasterSecret(c.vers, hs.suite, preMasterSecret, hs.clientHello.random, hs.hello.random)
}
// If we received a client cert in response to our certificate request message,
// the client will send us a certificateVerifyMsg immediately after the
// clientKeyExchangeMsg. This message is a digest of all preceding
// handshake-layer messages that is signed using the private key corresponding
// to the client's certificate. This allows us to verify that the client is in
// possession of the private key of the certificate.
if len(c.peerCertificates) > 0 {
msg, err = c.readHandshake()
if err != nil {
return err
}
certVerify, ok := msg.(*certificateVerifyMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(certVerify, msg)
}
// Determine the signature type.
var sigAlg signatureAlgorithm
if certVerify.hasSignatureAlgorithm {
sigAlg = certVerify.signatureAlgorithm
c.peerSignatureAlgorithm = sigAlg
}
if c.vers > VersionSSL30 {
err = verifyMessage(c.vers, pub, c.config, sigAlg, hs.finishedHash.buffer, certVerify.signature)
} else {
// SSL 3.0's client certificate construction is
// incompatible with signatureAlgorithm.
rsaPub, ok := pub.(*rsa.PublicKey)
if !ok {
err = errors.New("unsupported key type for client certificate")
} else {
digest := hs.finishedHash.hashForClientCertificateSSL3(hs.masterSecret)
err = rsa.VerifyPKCS1v15(rsaPub, crypto.MD5SHA1, digest, certVerify.signature)
}
}
if err != nil {
c.sendAlert(alertBadCertificate)
return errors.New("could not validate signature of connection nonces: " + err.Error())
}
hs.writeClientHash(certVerify.marshal())
}
hs.finishedHash.discardHandshakeBuffer()
return nil
}
func (hs *serverHandshakeState) establishKeys() error {
c := hs.c
clientMAC, serverMAC, clientKey, serverKey, clientIV, serverIV :=
keysFromMasterSecret(c.vers, hs.suite, hs.masterSecret, hs.clientHello.random, hs.hello.random, hs.suite.macLen, hs.suite.keyLen, hs.suite.ivLen(c.vers))
var clientCipher, serverCipher interface{}
var clientHash, serverHash macFunction
if hs.suite.aead == nil {
clientCipher = hs.suite.cipher(clientKey, clientIV, true /* for reading */)
clientHash = hs.suite.mac(c.vers, clientMAC)
serverCipher = hs.suite.cipher(serverKey, serverIV, false /* not for reading */)
serverHash = hs.suite.mac(c.vers, serverMAC)
} else {
clientCipher = hs.suite.aead(c.vers, clientKey, clientIV)
serverCipher = hs.suite.aead(c.vers, serverKey, serverIV)
}
c.in.prepareCipherSpec(c.vers, clientCipher, clientHash)
c.out.prepareCipherSpec(c.vers, serverCipher, serverHash)
return nil
}
func (hs *serverHandshakeState) readFinished(out []byte, isResume bool) error {
c := hs.c
c.readRecord(recordTypeChangeCipherSpec)
if err := c.in.error(); err != nil {
return err
}
if hs.hello.extensions.nextProtoNeg {
msg, err := c.readHandshake()
if err != nil {
return err
}
nextProto, ok := msg.(*nextProtoMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(nextProto, msg)
}
hs.writeClientHash(nextProto.marshal())
c.clientProtocol = nextProto.proto
}
if hs.hello.extensions.channelIDRequested {
msg, err := c.readHandshake()
if err != nil {
return err
}
channelIDMsg, ok := msg.(*channelIDMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(channelIDMsg, msg)
}
x := new(big.Int).SetBytes(channelIDMsg.channelID[0:32])
y := new(big.Int).SetBytes(channelIDMsg.channelID[32:64])
r := new(big.Int).SetBytes(channelIDMsg.channelID[64:96])
s := new(big.Int).SetBytes(channelIDMsg.channelID[96:128])
if !elliptic.P256().IsOnCurve(x, y) {
return errors.New("tls: invalid channel ID public key")
}
channelID := &ecdsa.PublicKey{elliptic.P256(), x, y}
var resumeHash []byte
if isResume {
resumeHash = hs.sessionState.handshakeHash
}
if !ecdsa.Verify(channelID, hs.finishedHash.hashForChannelID(resumeHash), r, s) {
return errors.New("tls: invalid channel ID signature")
}
c.channelID = channelID
hs.writeClientHash(channelIDMsg.marshal())
}
msg, err := c.readHandshake()
if err != nil {
return err
}
clientFinished, ok := msg.(*finishedMsg)
if !ok {
c.sendAlert(alertUnexpectedMessage)
return unexpectedMessageError(clientFinished, msg)
}
verify := hs.finishedHash.clientSum(hs.masterSecret)
if len(verify) != len(clientFinished.verifyData) ||
subtle.ConstantTimeCompare(verify, clientFinished.verifyData) != 1 {
c.sendAlert(alertHandshakeFailure)
return errors.New("tls: client's Finished message is incorrect")
}
c.clientVerify = append(c.clientVerify[:0], clientFinished.verifyData...)
copy(out, clientFinished.verifyData)
hs.writeClientHash(clientFinished.marshal())
return nil
}
func (hs *serverHandshakeState) sendSessionTicket() error {
c := hs.c
state := sessionState{
vers: c.vers,
cipherSuite: hs.suite.id,
masterSecret: hs.masterSecret,
certificates: hs.certsFromClient,
handshakeHash: hs.finishedHash.server.Sum(nil),
}
if !hs.hello.extensions.ticketSupported || hs.c.config.Bugs.SkipNewSessionTicket {
if c.config.ServerSessionCache != nil && len(hs.hello.sessionId) != 0 {
c.config.ServerSessionCache.Put(string(hs.hello.sessionId), &state)
}
return nil
}
m := new(newSessionTicketMsg)
if !c.config.Bugs.SendEmptySessionTicket {
var err error
m.ticket, err = c.encryptTicket(&state)
if err != nil {
return err
}
}
hs.writeServerHash(m.marshal())
c.writeRecord(recordTypeHandshake, m.marshal())
return nil
}
func (hs *serverHandshakeState) sendFinished(out []byte) error {
c := hs.c
finished := new(finishedMsg)
finished.verifyData = hs.finishedHash.serverSum(hs.masterSecret)
copy(out, finished.verifyData)
if c.config.Bugs.BadFinished {
finished.verifyData[0]++
}
c.serverVerify = append(c.serverVerify[:0], finished.verifyData...)
Add DTLS timeout and retransmit tests. This extends the packet adaptor protocol to send three commands: type command = | Packet of []byte | Timeout of time.Duration | TimeoutAck When the shim processes a Timeout in BIO_read, it sends TimeoutAck, fails the BIO_read, returns out of the SSL stack, advances the clock, calls DTLSv1_handle_timeout, and continues. If the Go side sends Timeout right between sending handshake flight N and reading flight N+1, the shim won't read the Timeout until it has sent flight N+1 (it only processes packet commands in BIO_read), so the TimeoutAck comes after N+1. Go then drops all packets before the TimeoutAck, thus dropping one transmit of flight N+1 without having to actually process the packets to determine the end of the flight. The shim then sees the updated clock, calls DTLSv1_handle_timeout, and re-sends flight N+1 for Go to process for real. When dropping packets, Go checks the epoch and increments sequence numbers so that we can continue to be strict here. This requires tracking the initial sequence number of the next epoch. The final Finished message takes an additional special-case to test. DTLS triggers retransmits on either a timeout or seeing a stale flight. OpenSSL only implements the former which should be sufficient (and is necessary) EXCEPT for the final Finished message. If the peer's final Finished message is lost, it won't be waiting for a message from us, so it won't time out anything. That retransmit must be triggered on stale message, so we retransmit the Finished message in Go. Change-Id: I3ffbdb1de525beb2ee831b304670a3387877634c Reviewed-on: https://boringssl-review.googlesource.com/3212 Reviewed-by: Adam Langley <agl@google.com>
2015-01-27 06:09:43 +00:00
hs.finishedBytes = finished.marshal()
hs.writeServerHash(hs.finishedBytes)
postCCSBytes := hs.finishedBytes
if c.config.Bugs.FragmentAcrossChangeCipherSpec {
c.writeRecord(recordTypeHandshake, postCCSBytes[:5])
postCCSBytes = postCCSBytes[5:]
} else if c.config.Bugs.SendUnencryptedFinished {
c.writeRecord(recordTypeHandshake, postCCSBytes)
postCCSBytes = nil
}
c.flushHandshake()
if !c.config.Bugs.SkipChangeCipherSpec {
ccs := []byte{1}
if c.config.Bugs.BadChangeCipherSpec != nil {
ccs = c.config.Bugs.BadChangeCipherSpec
}
c.writeRecord(recordTypeChangeCipherSpec, ccs)
}
if c.config.Bugs.AppDataAfterChangeCipherSpec != nil {
c.writeRecord(recordTypeApplicationData, c.config.Bugs.AppDataAfterChangeCipherSpec)
}
if c.config.Bugs.AlertAfterChangeCipherSpec != 0 {
c.sendAlert(c.config.Bugs.AlertAfterChangeCipherSpec)
return errors.New("tls: simulating post-CCS alert")
}
if !c.config.Bugs.SkipFinished && len(postCCSBytes) > 0 {
c.writeRecord(recordTypeHandshake, postCCSBytes)
c.flushHandshake()
}
c.cipherSuite = hs.suite
return nil
}
// processCertsFromClient takes a chain of client certificates either from a
// Certificates message or from a sessionState and verifies them. It returns
// the public key of the leaf certificate.
func (hs *serverHandshakeState) processCertsFromClient(certificates [][]byte) (crypto.PublicKey, error) {
c := hs.c
hs.certsFromClient = certificates
certs := make([]*x509.Certificate, len(certificates))
var err error
for i, asn1Data := range certificates {
if certs[i], err = x509.ParseCertificate(asn1Data); err != nil {
c.sendAlert(alertBadCertificate)
return nil, errors.New("tls: failed to parse client certificate: " + err.Error())
}
}
if c.config.ClientAuth >= VerifyClientCertIfGiven && len(certs) > 0 {
opts := x509.VerifyOptions{
Roots: c.config.ClientCAs,
CurrentTime: c.config.time(),
Intermediates: x509.NewCertPool(),
KeyUsages: []x509.ExtKeyUsage{x509.ExtKeyUsageClientAuth},
}
for _, cert := range certs[1:] {
opts.Intermediates.AddCert(cert)
}
chains, err := certs[0].Verify(opts)
if err != nil {
c.sendAlert(alertBadCertificate)
return nil, errors.New("tls: failed to verify client's certificate: " + err.Error())
}
ok := false
for _, ku := range certs[0].ExtKeyUsage {
if ku == x509.ExtKeyUsageClientAuth {
ok = true
break
}
}
if !ok {
c.sendAlert(alertHandshakeFailure)
return nil, errors.New("tls: client's certificate's extended key usage doesn't permit it to be used for client authentication")
}
c.verifiedChains = chains
}
if len(certs) > 0 {
var pub crypto.PublicKey
switch key := certs[0].PublicKey.(type) {
case *ecdsa.PublicKey, *rsa.PublicKey:
pub = key
default:
c.sendAlert(alertUnsupportedCertificate)
return nil, fmt.Errorf("tls: client's certificate contains an unsupported public key of type %T", certs[0].PublicKey)
}
c.peerCertificates = certs
return pub, nil
}
return nil, nil
}
func (hs *serverHandshakeState) writeServerHash(msg []byte) {
// writeServerHash is called before writeRecord.
hs.writeHash(msg, hs.c.sendHandshakeSeq)
}
func (hs *serverHandshakeState) writeClientHash(msg []byte) {
// writeClientHash is called after readHandshake.
hs.writeHash(msg, hs.c.recvHandshakeSeq-1)
}
func (hs *serverHandshakeState) writeHash(msg []byte, seqno uint16) {
if hs.c.isDTLS {
// This is somewhat hacky. DTLS hashes a slightly different format.
// First, the TLS header.
hs.finishedHash.Write(msg[:4])
// Then the sequence number and reassembled fragment offset (always 0).
hs.finishedHash.Write([]byte{byte(seqno >> 8), byte(seqno), 0, 0, 0})
// Then the reassembled fragment (always equal to the message length).
hs.finishedHash.Write(msg[1:4])
// And then the message body.
hs.finishedHash.Write(msg[4:])
} else {
hs.finishedHash.Write(msg)
}
}
// tryCipherSuite returns a cipherSuite with the given id if that cipher suite
// is acceptable to use.
func (c *Conn) tryCipherSuite(id uint16, supportedCipherSuites []uint16, version uint16, ellipticOk, ecdsaOk, pskOk bool) *cipherSuite {
for _, supported := range supportedCipherSuites {
if id == supported {
var candidate *cipherSuite
for _, s := range cipherSuites {
if s.id == id {
candidate = s
break
}
}
if candidate == nil {
continue
}
// Don't select a ciphersuite which we can't
// support for this client.
if !c.config.Bugs.EnableAllCiphers {
if (candidate.flags&suitePSK != 0) && !pskOk {
continue
}
if (candidate.flags&suiteECDHE != 0) && !ellipticOk {
continue
}
if (candidate.flags&suiteECDSA != 0) != ecdsaOk {
continue
}
if version < VersionTLS12 && candidate.flags&suiteTLS12 != 0 {
continue
}
if version >= VersionTLS13 && candidate.flags&suiteTLS13 == 0 {
continue
}
if c.isDTLS && candidate.flags&suiteNoDTLS != 0 {
continue
}
}
return candidate
}
}
return nil
}
func isTLS12Cipher(id uint16) bool {
for _, cipher := range cipherSuites {
if cipher.id != id {
continue
}
return cipher.flags&suiteTLS12 != 0
}
// Unknown cipher.
return false
}