| public RemoveData ( int len, int skip ) : byte[] | ||
| len | int | |
| skip | int | |
| return | byte[] | |
public override int Read(byte[] buf, int off, int len)
{
int bytesToRead = System.Math.Min(buffer.Available, len);
buffer.RemoveData(buf, off, bytesToRead, 0);
return(bytesToRead);
}
public override int Read(byte[] buf, int off, int len)
{
int num = Math.Min(buffer.Available, len);
buffer.RemoveData(buf, off, num, 0);
return(num);
}
private int ReceiveRecord(byte[] buf, int off, int len, int waitMillis)
{
if (mRecordQueue.Available > 0)
{
int length = 0;
if (mRecordQueue.Available >= RECORD_HEADER_LENGTH)
{
byte[] lengthBytes = new byte[2];
mRecordQueue.Read(lengthBytes, 0, 2, 11);
length = TlsUtilities.ReadUint16(lengthBytes, 0);
}
int received = System.Math.Min(mRecordQueue.Available, RECORD_HEADER_LENGTH + length);
mRecordQueue.RemoveData(buf, off, received, 0);
return(received);
}
{
int received = mTransport.Receive(buf, off, len, waitMillis);
if (received >= RECORD_HEADER_LENGTH)
{
int fragmentLength = TlsUtilities.ReadUint16(buf, off + 11);
int recordLength = RECORD_HEADER_LENGTH + fragmentLength;
if (received > recordLength)
{
mRecordQueue.AddData(buf, off + recordLength, received - recordLength);
received = recordLength;
}
}
return(received);
}
}
/**
* This method is called, when a change cipher spec message is received.
*
* @throws IOException If the message has an invalid content or the
* handshake is not in the correct state.
*/
private void ProcessChangeCipherSpec()
{
while (changeCipherSpecQueue.Available > 0)
{
/*
* A change cipher spec message is only one byte with the value 1.
*/
byte[] b = new byte[1];
changeCipherSpecQueue.Read(b, 0, 1, 0);
changeCipherSpecQueue.RemoveData(1);
if (b[0] != 1)
{
/*
* This should never happen.
*/
this.FailWithError(AL_fatal, AP_unexpected_message);
}
/*
* Check if we are in the correct connection state.
*/
if (this.connection_state != CS_CLIENT_FINISHED_SEND)
{
this.FailWithError(AL_fatal, AP_handshake_failure);
}
rs.ServerClientSpecReceived();
this.connection_state = CS_SERVER_CHANGE_CIPHER_SPEC_RECEIVED;
}
}
private void ProcessHandshake()
{
bool read;
do
{
read = false;
/*
* We need the first 4 bytes, they contain type and length of
* the message.
*/
if (handshakeQueue.Available >= 4)
{
byte[] beginning = new byte[4];
handshakeQueue.Read(beginning, 0, 4, 0);
MemoryStream bis = new MemoryStream(beginning, false);
short type = TlsUtilities.ReadUint8(bis);
int len = TlsUtilities.ReadUint24(bis);
/*
* Check if we have enough bytes in the buffer to read
* the full message.
*/
if (handshakeQueue.Available >= (len + 4))
{
/*
* Read the message.
*/
byte[] buf = new byte[len];
handshakeQueue.Read(buf, 0, len, 4);
handshakeQueue.RemoveData(len + 4);
/*
* RFC 2246 7.4.9. "The value handshake_messages includes all
* handshake messages starting at client hello up to, but not
* including, this finished message. [..] Note: [Also,] Hello Request
* messages are omitted from handshake hashes."
*/
switch (type)
{
case HP_HELLO_REQUEST:
case HP_FINISHED:
break;
default:
rs.UpdateHandshakeData(beginning, 0, 4);
rs.UpdateHandshakeData(buf, 0, len);
break;
}
/*
* Now, parse the message.
*/
ProcessHandshakeMessage(type, buf);
read = true;
}
}
}while (read);
}
/**
* Read data from the network. The method will return immediately, if there is
* still some data left in the buffer, or block until some application
* data has been read from the network.
*
* @param buf The buffer where the data will be copied to.
* @param offset The position where the data will be placed in the buffer.
* @param len The maximum number of bytes to read.
* @return The number of bytes read.
* @throws IOException If something goes wrong during reading data.
*/
internal int ReadApplicationData(byte[] buf, int offset, int len)
{
while (applicationDataQueue.Available == 0)
{
if (this.closed)
{
/*
* We need to read some data.
*/
if (this.failedWithError)
{
/*
* Something went terribly wrong, we should throw an IOException
*/
throw new IOException(TLS_ERROR_MESSAGE);
}
/*
* Connection has been closed, there is no more data to read.
*/
return(0);
}
SafeReadData();
}
len = System.Math.Min(len, applicationDataQueue.Available);
applicationDataQueue.Read(buf, offset, len, 0);
applicationDataQueue.RemoveData(len);
return(len);
}
private int ReceiveRecord(byte[] buf, int off, int len, int waitMillis)
{
if (mRecordQueue.Available > 0)
{
int num = 0;
if (mRecordQueue.Available >= 13)
{
byte[] buf2 = new byte[2];
mRecordQueue.Read(buf2, 0, 2, 11);
num = TlsUtilities.ReadUint16(buf2, 0);
}
int num2 = Math.Min(mRecordQueue.Available, 13 + num);
mRecordQueue.RemoveData(buf, off, num2, 0);
return(num2);
}
int num3 = mTransport.Receive(buf, off, len, waitMillis);
if (num3 >= 13)
{
int num4 = TlsUtilities.ReadUint16(buf, off + 11);
int num5 = 13 + num4;
if (num3 > num5)
{
mRecordQueue.AddData(buf, off + num5, num3 - num5);
num3 = num5;
}
}
return(num3);
}
private void ProcessAlert()
{
while (true)
{
if (mAlertQueue.Available < 2)
{
return;
}
byte[] array = mAlertQueue.RemoveData(2, 0);
byte b = array[0];
byte b2 = array[1];
Peer.NotifyAlertReceived(b, b2);
if (b == 2)
{
break;
}
if (b2 == 0)
{
HandleClose(user_canceled: false);
}
HandleWarningMessage(b2);
}
InvalidateSession();
mFailedWithError = true;
mClosed = true;
mRecordStream.SafeClose();
throw new IOException(TLS_ERROR_MESSAGE);
}
private void processAlert()
{
while (alertQueue.Available >= 2)
{
/*
* An alert is always 2 bytes. Read the alert.
*/
byte[] tmp = new byte[2];
alertQueue.Read(tmp, 0, 2, 0);
alertQueue.RemoveData(2);
short level = tmp[0];
short description = tmp[1];
if (level == AL_fatal)
{
/*
* This is a fatal error.
*/
this.failedWithError = true;
this.closed = true;
/*
* Now try to Close the stream, ignore errors.
*/
try
{
rs.Close();
}
catch (Exception)
{
}
throw new IOException(TLS_ERROR_MESSAGE);
}
else
{
/*
* This is just a warning.
*/
if (description == AP_close_notify)
{
/*
* Close notify
*/
this.FailWithError(AL_warning, AP_close_notify);
}
/*
* If it is just a warning, we continue.
*/
}
}
}
private void ProcessAlert()
{
while (alertQueue.Available >= 2)
{
/*
* An alert is always 2 bytes. Read the alert.
*/
byte[] tmp = alertQueue.RemoveData(2, 0);
byte level = tmp[0];
byte description = tmp[1];
if (level == (byte)AlertLevel.fatal)
{
this.failedWithError = true;
this.closed = true;
/*
* Now try to Close the stream, ignore errors.
*/
try
{
rs.Close();
}
catch (Exception)
{
}
throw new IOException(TLS_ERROR_MESSAGE);
}
else
{
if (description == (byte)AlertDescription.close_notify)
{
HandleClose(false);
}
/*
* If it is just a warning, we continue.
*/
}
}
}
private void ProcessHandshake()
{
bool flag;
do
{
flag = false;
if (mHandshakeQueue.Available >= 4)
{
byte[] array = new byte[4];
mHandshakeQueue.Read(array, 0, 4, 0);
byte b = TlsUtilities.ReadUint8(array, 0);
int num = TlsUtilities.ReadUint24(array, 1);
if (mHandshakeQueue.Available >= num + 4)
{
byte[] array2 = mHandshakeQueue.RemoveData(num, 4);
CheckReceivedChangeCipherSpec(mConnectionState == 16 || b == 20);
switch (b)
{
default:
{
TlsContext context = Context;
if (b == 20 && mExpectedVerifyData == null && context.SecurityParameters.MasterSecret != null)
{
mExpectedVerifyData = CreateVerifyData(!context.IsServer);
}
mRecordStream.UpdateHandshakeData(array, 0, 4);
mRecordStream.UpdateHandshakeData(array2, 0, num);
break;
}
case 0:
break;
}
HandleHandshakeMessage(b, array2);
flag = true;
}
}
}while (flag);
}
protected internal virtual int ReadApplicationData(byte[] buf, int offset, int len)
{
if (len < 1)
{
return(0);
}
while (mApplicationDataQueue.Available == 0)
{
if (mClosed)
{
if (mFailedWithError)
{
throw new IOException(TLS_ERROR_MESSAGE);
}
return(0);
}
SafeReadRecord();
}
len = System.Math.Min(len, mApplicationDataQueue.Available);
mApplicationDataQueue.RemoveData(buf, offset, len, 0);
return(len);
}
protected internal virtual int ReadApplicationData(byte[] buf, int offset, int len)
{
//IL_001f: Unknown result type (might be due to invalid IL or missing references)
if (len < 1)
{
return(0);
}
while (mApplicationDataQueue.Available == 0)
{
if (mClosed)
{
if (mFailedWithError)
{
throw new IOException(TLS_ERROR_MESSAGE);
}
return(0);
}
SafeReadRecord();
}
len = Math.Min(len, mApplicationDataQueue.Available);
mApplicationDataQueue.RemoveData(buf, offset, len, 0);
return(len);
}
private void ProcessAlert()
{
//IL_0051: Unknown result type (might be due to invalid IL or missing references)
while (mAlertQueue.Available >= 2)
{
byte[] array = mAlertQueue.RemoveData(2, 0);
byte b = array[0];
byte b2 = array[1];
Peer.NotifyAlertReceived(b, b2);
if (b == 2)
{
InvalidateSession();
mFailedWithError = true;
mClosed = true;
mRecordStream.SafeClose();
throw new IOException(TLS_ERROR_MESSAGE);
}
if (b2 == 0)
{
HandleClose(user_canceled: false);
}
HandleWarningMessage(b2);
}
}
private void processHandshake()
{
bool read;
do
{
read = false;
/*
* We need the first 4 bytes, they contain type and length of
* the message.
*/
if (handshakeQueue.Available >= 4)
{
byte[] beginning = new byte[4];
handshakeQueue.Read(beginning, 0, 4, 0);
MemoryStream bis = new MemoryStream(beginning, false);
short type = TlsUtilities.ReadUint8(bis);
int len = TlsUtilities.ReadUint24(bis);
/*
* Check if we have enough bytes in the buffer to read
* the full message.
*/
if (handshakeQueue.Available >= (len + 4))
{
/*
* Read the message.
*/
byte[] buf = new byte[len];
handshakeQueue.Read(buf, 0, len, 4);
handshakeQueue.RemoveData(len + 4);
/*
* If it is not a finished message, update our hashes
* we prepare for the finish message.
*/
if (type != HP_FINISHED)
{
rs.hash1.BlockUpdate(beginning, 0, 4);
rs.hash2.BlockUpdate(beginning, 0, 4);
rs.hash1.BlockUpdate(buf, 0, len);
rs.hash2.BlockUpdate(buf, 0, len);
}
/*
* Now, parse the message.
*/
MemoryStream inStr = new MemoryStream(buf, false);
/*
* Check the type.
*/
switch (type)
{
case HP_CERTIFICATE:
{
switch (connection_state)
{
case CS_SERVER_HELLO_RECEIVED:
{
/*
* Parse the certificates.
*/
Certificate cert = Certificate.Parse(inStr);
AssertEmpty(inStr);
X509CertificateStructure x509Cert = cert.certs[0];
SubjectPublicKeyInfo keyInfo = x509Cert.SubjectPublicKeyInfo;
try
{
this.serverPublicKey = PublicKeyFactory.CreateKey(keyInfo);
}
catch (Exception)
{
this.FailWithError(AL_fatal, AP_unsupported_certificate);
}
// Sanity check the PublicKeyFactory
if (this.serverPublicKey.IsPrivate)
{
this.FailWithError(AL_fatal, AP_internal_error);
}
/*
* Perform various checks per RFC2246 7.4.2
* TODO "Unless otherwise specified, the signing algorithm for the certificate
* must be the same as the algorithm for the certificate key."
*/
switch (this.chosenCipherSuite.KeyExchangeAlgorithm)
{
case TlsCipherSuite.KE_RSA:
if (!(this.serverPublicKey is RsaKeyParameters))
{
this.FailWithError(AL_fatal, AP_certificate_unknown);
}
validateKeyUsage(x509Cert, KeyUsage.KeyEncipherment);
break;
case TlsCipherSuite.KE_DHE_RSA:
if (!(this.serverPublicKey is RsaKeyParameters))
{
this.FailWithError(AL_fatal, AP_certificate_unknown);
}
validateKeyUsage(x509Cert, KeyUsage.DigitalSignature);
break;
case TlsCipherSuite.KE_DHE_DSS:
if (!(this.serverPublicKey is DsaPublicKeyParameters))
{
this.FailWithError(AL_fatal, AP_certificate_unknown);
}
break;
default:
this.FailWithError(AL_fatal, AP_unsupported_certificate);
break;
}
/*
* Verify them.
*/
if (!this.verifyer.IsValid(cert.GetCerts()))
{
this.FailWithError(AL_fatal, AP_user_canceled);
}
break;
}
default:
this.FailWithError(AL_fatal, AP_unexpected_message);
break;
}
connection_state = CS_SERVER_CERTIFICATE_RECEIVED;
read = true;
break;
}
case HP_FINISHED:
switch (connection_state)
{
case CS_SERVER_CHANGE_CIPHER_SPEC_RECEIVED:
/*
* Read the checksum from the finished message,
* it has always 12 bytes.
*/
byte[] receivedChecksum = new byte[12];
TlsUtilities.ReadFully(receivedChecksum, inStr);
AssertEmpty(inStr);
/*
* Calculate our own checksum.
*/
byte[] checksum = new byte[12];
byte[] md5andsha1 = new byte[16 + 20];
rs.hash2.DoFinal(md5andsha1, 0);
TlsUtilities.PRF(this.ms, TlsUtilities.ToByteArray("server finished"), md5andsha1, checksum);
/*
* Compare both checksums.
*/
for (int i = 0; i < receivedChecksum.Length; i++)
{
if (receivedChecksum[i] != checksum[i])
{
/*
* Wrong checksum in the finished message.
*/
this.FailWithError(AL_fatal, AP_handshake_failure);
}
}
connection_state = CS_DONE;
/*
* We are now ready to receive application data.
*/
this.appDataReady = true;
read = true;
break;
default:
this.FailWithError(AL_fatal, AP_unexpected_message);
break;
}
break;
case HP_SERVER_HELLO:
switch (connection_state)
{
case CS_CLIENT_HELLO_SEND:
/*
* Read the server hello message
*/
TlsUtilities.CheckVersion(inStr, this);
/*
* Read the server random
*/
this.serverRandom = new byte[32];
TlsUtilities.ReadFully(this.serverRandom, inStr);
/*
* Currently, we don't support session ids
*/
short sessionIdLength = TlsUtilities.ReadUint8(inStr);
byte[] sessionId = new byte[sessionIdLength];
TlsUtilities.ReadFully(sessionId, inStr);
/*
* Find out which ciphersuite the server has
* chosen. If we don't support this ciphersuite,
* the TlsCipherSuiteManager will throw an
* exception.
*/
this.chosenCipherSuite = TlsCipherSuiteManager.GetCipherSuite(
TlsUtilities.ReadUint16(inStr), this);
/*
* We support only the null compression which
* means no compression.
*/
short compressionMethod = TlsUtilities.ReadUint8(inStr);
if (compressionMethod != 0)
{
this.FailWithError(TlsProtocolHandler.AL_fatal, TlsProtocolHandler.AP_illegal_parameter);
}
AssertEmpty(inStr);
connection_state = CS_SERVER_HELLO_RECEIVED;
read = true;
break;
default:
this.FailWithError(AL_fatal, AP_unexpected_message);
break;
}
break;
case HP_SERVER_HELLO_DONE:
switch (connection_state)
{
case CS_SERVER_CERTIFICATE_RECEIVED:
case CS_SERVER_KEY_EXCHANGE_RECEIVED:
case CS_CERTIFICATE_REQUEST_RECEIVED:
// NB: Original code used case label fall-through
if (connection_state == CS_SERVER_CERTIFICATE_RECEIVED)
{
/*
* There was no server key exchange message, check
* that we are doing RSA key exchange.
*/
if (this.chosenCipherSuite.KeyExchangeAlgorithm != TlsCipherSuite.KE_RSA)
{
this.FailWithError(AL_fatal, AP_unexpected_message);
}
}
AssertEmpty(inStr);
bool isCertReq = (connection_state == CS_CERTIFICATE_REQUEST_RECEIVED);
connection_state = CS_SERVER_HELLO_DONE_RECEIVED;
if (isCertReq)
{
sendClientCertificate();
}
/*
* Send the client key exchange message, depending
* on the key exchange we are using in our
* ciphersuite.
*/
switch (this.chosenCipherSuite.KeyExchangeAlgorithm)
{
case TlsCipherSuite.KE_RSA:
{
/*
* We are doing RSA key exchange. We will
* choose a pre master secret and send it
* rsa encrypted to the server.
*
* Prepare pre master secret.
*/
pms = new byte[48];
pms[0] = 3;
pms[1] = 1;
random.NextBytes(pms, 2, 46);
/*
* Encode the pms and send it to the server.
*
* Prepare an Pkcs1Encoding with good random
* padding.
*/
RsaBlindedEngine rsa = new RsaBlindedEngine();
Pkcs1Encoding encoding = new Pkcs1Encoding(rsa);
encoding.Init(true, new ParametersWithRandom(this.serverPublicKey, this.random));
byte[] encrypted = null;
try
{
encrypted = encoding.ProcessBlock(pms, 0, pms.Length);
}
catch (InvalidCipherTextException)
{
/*
* This should never happen, only during decryption.
*/
this.FailWithError(AL_fatal, AP_internal_error);
}
/*
* Send the encrypted pms.
*/
sendClientKeyExchange(encrypted);
break;
}
case TlsCipherSuite.KE_DHE_DSS:
case TlsCipherSuite.KE_DHE_RSA:
{
/*
* Send the Client Key Exchange message for
* DHE key exchange.
*/
byte[] YcByte = BigIntegers.AsUnsignedByteArray(this.Yc);
sendClientKeyExchange(YcByte);
break;
}
default:
/*
* Problem during handshake, we don't know
* how to handle this key exchange method.
*/
this.FailWithError(AL_fatal, AP_unexpected_message);
break;
}
connection_state = CS_CLIENT_KEY_EXCHANGE_SEND;
/*
* Now, we send change cipher state
*/
byte[] cmessage = new byte[1];
cmessage[0] = 1;
rs.WriteMessage((short)RL_CHANGE_CIPHER_SPEC, cmessage, 0, cmessage.Length);
connection_state = CS_CLIENT_CHANGE_CIPHER_SPEC_SEND;
/*
* Calculate the ms
*/
this.ms = new byte[48];
byte[] randBytes = new byte[clientRandom.Length + serverRandom.Length];
Array.Copy(clientRandom, 0, randBytes, 0, clientRandom.Length);
Array.Copy(serverRandom, 0, randBytes, clientRandom.Length, serverRandom.Length);
TlsUtilities.PRF(pms, TlsUtilities.ToByteArray("master secret"), randBytes, this.ms);
/*
* Initialize our cipher suite
*/
rs.writeSuite = this.chosenCipherSuite;
rs.writeSuite.Init(this.ms, clientRandom, serverRandom);
/*
* Send our finished message.
*/
byte[] checksum = new byte[12];
byte[] md5andsha1 = new byte[16 + 20];
rs.hash1.DoFinal(md5andsha1, 0);
TlsUtilities.PRF(this.ms, TlsUtilities.ToByteArray("client finished"), md5andsha1, checksum);
MemoryStream bos2 = new MemoryStream();
TlsUtilities.WriteUint8(HP_FINISHED, bos2);
TlsUtilities.WriteUint24(12, bos2);
bos2.Write(checksum, 0, checksum.Length);
byte[] message2 = bos2.ToArray();
rs.WriteMessage((short)RL_HANDSHAKE, message2, 0, message2.Length);
this.connection_state = CS_CLIENT_FINISHED_SEND;
read = true;
break;
default:
this.FailWithError(AL_fatal, AP_handshake_failure);
break;
}
break;
case HP_SERVER_KEY_EXCHANGE:
{
switch (connection_state)
{
case CS_SERVER_CERTIFICATE_RECEIVED:
{
/*
* Check that we are doing DHE key exchange
*/
switch (this.chosenCipherSuite.KeyExchangeAlgorithm)
{
case TlsCipherSuite.KE_DHE_RSA:
{
processDHEKeyExchange(inStr, new TlsRsaSigner());
break;
}
case TlsCipherSuite.KE_DHE_DSS:
{
processDHEKeyExchange(inStr, new TlsDssSigner());
break;
}
default:
this.FailWithError(AL_fatal, AP_unexpected_message);
break;
}
break;
}
default:
this.FailWithError(AL_fatal, AP_unexpected_message);
break;
}
this.connection_state = CS_SERVER_KEY_EXCHANGE_RECEIVED;
read = true;
break;
}
case HP_CERTIFICATE_REQUEST:
switch (connection_state)
{
case CS_SERVER_CERTIFICATE_RECEIVED:
case CS_SERVER_KEY_EXCHANGE_RECEIVED:
{
// NB: Original code used case label fall-through
if (connection_state == CS_SERVER_CERTIFICATE_RECEIVED)
{
/*
* There was no server key exchange message, check
* that we are doing RSA key exchange.
*/
if (this.chosenCipherSuite.KeyExchangeAlgorithm != TlsCipherSuite.KE_RSA)
{
this.FailWithError(AL_fatal, AP_unexpected_message);
}
}
int typesLength = TlsUtilities.ReadUint8(inStr);
byte[] types = new byte[typesLength];
TlsUtilities.ReadFully(types, inStr);
int authsLength = TlsUtilities.ReadUint16(inStr);
byte[] auths = new byte[authsLength];
TlsUtilities.ReadFully(auths, inStr);
AssertEmpty(inStr);
break;
}
default:
this.FailWithError(AL_fatal, AP_unexpected_message);
break;
}
this.connection_state = CS_CERTIFICATE_REQUEST_RECEIVED;
read = true;
break;
case HP_HELLO_REQUEST:
case HP_CLIENT_KEY_EXCHANGE:
case HP_CERTIFICATE_VERIFY:
case HP_CLIENT_HELLO:
default:
// We do not support this!
this.FailWithError(AL_fatal, AP_unexpected_message);
break;
}
}
}
}while (read);
}
private void processHandshake()
{
bool read;
do
{
read = false;
/*
* We need the first 4 bytes, they contain type and length of
* the message.
*/
if (handshakeQueue.Available >= 4)
{
byte[] beginning = new byte[4];
handshakeQueue.Read(beginning, 0, 4, 0);
MemoryStream bis = new MemoryStream(beginning, false);
short type = TlsUtilities.ReadUint8(bis);
int len = TlsUtilities.ReadUint24(bis);
/*
* Check if we have enough bytes in the buffer to read
* the full message.
*/
if (handshakeQueue.Available >= (len + 4))
{
/*
* Read the message.
*/
byte[] buf = new byte[len];
handshakeQueue.Read(buf, 0, len, 4);
handshakeQueue.RemoveData(len + 4);
/*
* If it is not a finished message, update our hashes
* we prepare for the finish message.
*/
if (type != HP_FINISHED)
{
rs.hash1.BlockUpdate(beginning, 0, 4);
rs.hash2.BlockUpdate(beginning, 0, 4);
rs.hash1.BlockUpdate(buf, 0, len);
rs.hash2.BlockUpdate(buf, 0, len);
}
/*
* Now, parse the message.
*/
MemoryStream inStr = new MemoryStream(buf, false);
/*
* Check the type.
*/
switch (type)
{
case HP_CERTIFICATE:
switch (connection_state)
{
case CS_SERVER_HELLO_RECEIVED:
/*
* Parse the certificates.
*/
Certificate cert = Certificate.Parse(inStr);
AssertEmpty(inStr);
/*
* Verify them.
*/
if (!this.verifyer.IsValid(cert.GetCerts()))
{
this.FailWithError(AL_fatal, AP_user_canceled);
}
/*
* We only support RSA certificates. Lets hope
* this is one.
*/
RsaPublicKeyStructure rsaKey = null;
try
{
rsaKey = RsaPublicKeyStructure.GetInstance(
cert.certs[0].TbsCertificate.SubjectPublicKeyInfo.GetPublicKey());
}
catch (Exception)
{
/*
* Sorry, we have to fail ;-(
*/
this.FailWithError(AL_fatal, AP_unsupported_certificate);
}
/*
* Parse the servers public RSA key.
*/
this.serverRsaKey = new RsaKeyParameters(
false,
rsaKey.Modulus,
rsaKey.PublicExponent);
connection_state = CS_SERVER_CERTIFICATE_RECEIVED;
read = true;
break;
default:
this.FailWithError(AL_fatal, AP_unexpected_message);
break;
}
break;
case HP_FINISHED:
switch (connection_state)
{
case CS_SERVER_CHANGE_CIPHER_SPEC_RECEIVED:
/*
* Read the checksum from the finished message,
* it has always 12 bytes.
*/
byte[] receivedChecksum = new byte[12];
TlsUtilities.ReadFully(receivedChecksum, inStr);
AssertEmpty(inStr);
/*
* Calculate our owne checksum.
*/
byte[] checksum = new byte[12];
byte[] md5andsha1 = new byte[16 + 20];
rs.hash2.DoFinal(md5andsha1, 0);
TlsUtilities.PRF(this.ms, TlsUtilities.ToByteArray("server finished"), md5andsha1, checksum);
/*
* Compare both checksums.
*/
for (int i = 0; i < receivedChecksum.Length; i++)
{
if (receivedChecksum[i] != checksum[i])
{
/*
* Wrong checksum in the finished message.
*/
this.FailWithError(AL_fatal, AP_handshake_failure);
}
}
connection_state = CS_DONE;
/*
* We are now ready to receive application data.
*/
this.appDataReady = true;
read = true;
break;
default:
this.FailWithError(AL_fatal, AP_unexpected_message);
break;
}
break;
case HP_SERVER_HELLO:
switch (connection_state)
{
case CS_CLIENT_HELLO_SEND:
/*
* Read the server hello message
*/
TlsUtilities.CheckVersion(inStr, this);
/*
* Read the server random
*/
this.serverRandom = new byte[32];
TlsUtilities.ReadFully(this.serverRandom, inStr);
/*
* Currenty, we don't support session ids
*/
short sessionIdLength = TlsUtilities.ReadUint8(inStr);
byte[] sessionId = new byte[sessionIdLength];
TlsUtilities.ReadFully(sessionId, inStr);
/*
* Find out which ciphersuite the server has
* choosen. If we don't support this ciphersuite,
* the TlsCipherSuiteManager will throw an
* exception.
*/
this.choosenCipherSuite = TlsCipherSuiteManager.GetCipherSuite(
TlsUtilities.ReadUint16(inStr), this);
/*
* We support only the null compression which
* means no compression.
*/
short compressionMethod = TlsUtilities.ReadUint8(inStr);
if (compressionMethod != 0)
{
this.FailWithError(TlsProtocolHandler.AL_fatal, TlsProtocolHandler.AP_illegal_parameter);
}
AssertEmpty(inStr);
connection_state = CS_SERVER_HELLO_RECEIVED;
read = true;
break;
default:
this.FailWithError(AL_fatal, AP_unexpected_message);
break;
}
break;
case HP_SERVER_HELLO_DONE:
switch (connection_state)
{
case CS_SERVER_CERTIFICATE_RECEIVED:
case CS_SERVER_KEY_EXCHANGE_RECEIVED:
// NB: Original code used case label fall-through
if (connection_state == CS_SERVER_CERTIFICATE_RECEIVED)
{
/*
* There was no server key exchange message, check
* that we are doing RSA key exchange.
*/
if (this.choosenCipherSuite.KeyExchangeAlgorithm != TlsCipherSuite.KE_RSA)
{
this.FailWithError(AL_fatal, AP_unexpected_message);
}
}
AssertEmpty(inStr);
connection_state = CS_SERVER_HELLO_DONE_RECEIVED;
/*
* Send the client key exchange message, depending
* on the key exchange we are using in our
* ciphersuite.
*/
short ke = this.choosenCipherSuite.KeyExchangeAlgorithm;
switch (ke)
{
case TlsCipherSuite.KE_RSA:
/*
* We are doing RSA key exchange. We will
* choose a pre master secret and send it
* rsa encrypted to the server.
*
* Prepare pre master secret.
*/
pms = new byte[48];
pms[0] = 3;
pms[1] = 1;
random.NextBytes(pms, 2, 46);
/*
* Encode the pms and send it to the server.
*
* Prepare an Pkcs1Encoding with good random
* padding.
*/
RsaBlindedEngine rsa = new RsaBlindedEngine();
Pkcs1Encoding encoding = new Pkcs1Encoding(rsa);
encoding.Init(true, new ParametersWithRandom(this.serverRsaKey, this.random));
byte[] encrypted = null;
try
{
encrypted = encoding.ProcessBlock(pms, 0, pms.Length);
}
catch (InvalidCipherTextException)
{
/*
* This should never happen, only during decryption.
*/
this.FailWithError(AL_fatal, AP_internal_error);
}
/*
* Send the encrypted pms.
*/
MemoryStream bos = new MemoryStream();
TlsUtilities.WriteUint8(HP_CLIENT_KEY_EXCHANGE, bos);
TlsUtilities.WriteUint24(encrypted.Length + 2, bos);
TlsUtilities.WriteUint16(encrypted.Length, bos);
bos.Write(encrypted, 0, encrypted.Length);
byte[] message = bos.ToArray();
rs.WriteMessage((short)RL_HANDSHAKE, message, 0, message.Length);
break;
case TlsCipherSuite.KE_DHE_RSA:
/*
* Send the Client Key Exchange message for
* DHE key exchange.
*/
byte[] YcByte = this.Yc.ToByteArray();
MemoryStream DHbos = new MemoryStream();
TlsUtilities.WriteUint8(HP_CLIENT_KEY_EXCHANGE, DHbos);
TlsUtilities.WriteUint24(YcByte.Length + 2, DHbos);
TlsUtilities.WriteUint16(YcByte.Length, DHbos);
DHbos.Write(YcByte, 0, YcByte.Length);
byte[] DHmessage = DHbos.ToArray();
rs.WriteMessage((short)RL_HANDSHAKE, DHmessage, 0, DHmessage.Length);
break;
default:
/*
* Proble during handshake, we don't know
* how to thandle this key exchange method.
*/
this.FailWithError(AL_fatal, AP_unexpected_message);
break;
}
connection_state = CS_CLIENT_KEY_EXCHANGE_SEND;
/*
* Now, we send change cipher state
*/
byte[] cmessage = new byte[1];
cmessage[0] = 1;
rs.WriteMessage((short)RL_CHANGE_CIPHER_SPEC, cmessage, 0, cmessage.Length);
connection_state = CS_CLIENT_CHANGE_CIPHER_SPEC_SEND;
/*
* Calculate the ms
*/
this.ms = new byte[48];
byte[] randBytes = new byte[clientRandom.Length + serverRandom.Length];
Array.Copy(clientRandom, 0, randBytes, 0, clientRandom.Length);
Array.Copy(serverRandom, 0, randBytes, clientRandom.Length, serverRandom.Length);
TlsUtilities.PRF(pms, TlsUtilities.ToByteArray("master secret"), randBytes, this.ms);
/*
* Initialize our cipher suite
*/
rs.writeSuite = this.choosenCipherSuite;
rs.writeSuite.Init(this.ms, clientRandom, serverRandom);
/*
* Send our finished message.
*/
byte[] checksum = new byte[12];
byte[] md5andsha1 = new byte[16 + 20];
rs.hash1.DoFinal(md5andsha1, 0);
TlsUtilities.PRF(this.ms, TlsUtilities.ToByteArray("client finished"), md5andsha1, checksum);
MemoryStream bos2 = new MemoryStream();
TlsUtilities.WriteUint8(HP_FINISHED, bos2);
TlsUtilities.WriteUint24(12, bos2);
bos2.Write(checksum, 0, checksum.Length);
byte[] message2 = bos2.ToArray();
rs.WriteMessage((short)RL_HANDSHAKE, message2, 0, message2.Length);
this.connection_state = CS_CLIENT_FINISHED_SEND;
read = true;
break;
default:
this.FailWithError(AL_fatal, AP_handshake_failure);
break;
}
break;
case HP_SERVER_KEY_EXCHANGE:
switch (connection_state)
{
case CS_SERVER_CERTIFICATE_RECEIVED:
/*
* Check that we are doing DHE key exchange
*/
if (this.choosenCipherSuite.KeyExchangeAlgorithm != TlsCipherSuite.KE_DHE_RSA)
{
this.FailWithError(AL_fatal, AP_unexpected_message);
}
/*
* Parse the Structure
*/
int pLength = TlsUtilities.ReadUint16(inStr);
byte[] pByte = new byte[pLength];
TlsUtilities.ReadFully(pByte, inStr);
int gLength = TlsUtilities.ReadUint16(inStr);
byte[] gByte = new byte[gLength];
TlsUtilities.ReadFully(gByte, inStr);
int YsLength = TlsUtilities.ReadUint16(inStr);
byte[] YsByte = new byte[YsLength];
TlsUtilities.ReadFully(YsByte, inStr);
int sigLength = TlsUtilities.ReadUint16(inStr);
byte[] sigByte = new byte[sigLength];
TlsUtilities.ReadFully(sigByte, inStr);
this.AssertEmpty(inStr);
/*
* Verify the Signature.
*
* First, calculate the hash.
*/
CombinedHash sigDigest = new CombinedHash();
MemoryStream signedData = new MemoryStream();
TlsUtilities.WriteUint16(pLength, signedData);
signedData.Write(pByte, 0, pByte.Length);
TlsUtilities.WriteUint16(gLength, signedData);
signedData.Write(gByte, 0, gByte.Length);
TlsUtilities.WriteUint16(YsLength, signedData);
signedData.Write(YsByte, 0, YsByte.Length);
byte[] signed = signedData.ToArray();
sigDigest.BlockUpdate(this.clientRandom, 0, this.clientRandom.Length);
sigDigest.BlockUpdate(this.serverRandom, 0, this.serverRandom.Length);
sigDigest.BlockUpdate(signed, 0, signed.Length);
byte[] hash = new byte[sigDigest.GetDigestSize()];
sigDigest.DoFinal(hash, 0);
/*
* Now, do the RSA operation
*/
RsaBlindedEngine rsa = new RsaBlindedEngine();
Pkcs1Encoding encoding = new Pkcs1Encoding(rsa);
encoding.Init(false, this.serverRsaKey);
/*
* The data which was signed
*/
byte[] sigHash = null;
try
{
sigHash = encoding.ProcessBlock(sigByte, 0, sigByte.Length);
}
catch (InvalidCipherTextException)
{
this.FailWithError(AL_fatal, AP_bad_certificate);
}
/*
* Check if the data which was signed is equal to
* the hash we calculated.
*/
if (sigHash.Length != hash.Length)
{
this.FailWithError(AL_fatal, AP_bad_certificate);
}
for (int i = 0; i < sigHash.Length; i++)
{
if (sigHash[i] != hash[i])
{
this.FailWithError(AL_fatal, AP_bad_certificate);
}
}
/*
* OK, Signature was correct.
*
* Do the DH calculation.
*/
BigInteger p = new BigInteger(1, pByte);
BigInteger g = new BigInteger(1, gByte);
BigInteger Ys = new BigInteger(1, YsByte);
BigInteger x = new BigInteger(p.BitLength - 1, this.random);
Yc = g.ModPow(x, p);
this.pms = (Ys.ModPow(x, p)).ToByteArray();
/*
* Remove leading zero byte, if present.
*/
if (this.pms[0] == 0)
{
byte[] tmp = new byte[this.pms.Length - 1];
Array.Copy(this.pms, 1, tmp, 0, tmp.Length);
this.pms = tmp;
}
this.connection_state = CS_SERVER_KEY_EXCHANGE_RECEIVED;
read = true;
break;
default:
this.FailWithError(AL_fatal, AP_unexpected_message);
break;
}
break;
case HP_HELLO_REQUEST:
case HP_CLIENT_KEY_EXCHANGE:
case HP_CERTIFICATE_REQUEST:
case HP_CERTIFICATE_VERIFY:
case HP_CLIENT_HELLO:
default:
// We do not support this!
this.FailWithError(AL_fatal, AP_unexpected_message);
break;
}
}
}
}while (read);
}
