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[amule.git] / src / EncryptedDatagramSocket.cpp
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1 //
2 // This file is part of the aMule Project.
3 //
4 // Copyright (c) 2003-2008 aMule Team ( admin@amule.org / http://www.amule.org )
5 // Copyright (c) 2002-2008 Merkur ( devs@emule-project.net / http://www.emule-project.net )
6 //
7 // Any parts of this program derived from the xMule, lMule or eMule project,
8 // or contributed by third-party developers are copyrighted by their
9 // respective authors.
11 // This program is free software; you can redistribute it and/or modify
12 // it under the terms of the GNU General Public License as published by
13 // the Free Software Foundation; either version 2 of the License, or
14 // (at your option) any later version.
16 // This program is distributed in the hope that it will be useful,
17 // but WITHOUT ANY WARRANTY; without even the implied warranty of
18 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
19 // GNU General Public License for more details.
20 //
21 // You should have received a copy of the GNU General Public License
22 // along with this program; if not, write to the Free Software
23 // Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA
26 /* Basic Obfuscated Handshake Protocol UDP:
27 see EncryptedStreamSocket.h
29 ****************************** ED2K Packets
31 - Keycreation Client <-> Client:
32 - Client A (Outgoing connection):
33 Sendkey: Md5(<UserHashClientB 16><IPClientA 4><MagicValue91 1><RandomKeyPartClientA 2>) 23
34 - Client B (Incoming connection):
35 Receivekey: Md5(<UserHashClientB 16><IPClientA 4><MagicValue91 1><RandomKeyPartClientA 2>) 23
36 - Note: The first 1024 Bytes will be _NOT_ discarded for UDP keys to save CPU time
38 - Handshake
39 -> The handshake is encrypted - except otherwise noted - by the Keys created above
40 -> Padding is currently not used for UDP meaning that PaddingLen will be 0, using PaddingLens up to 16 Bytes is acceptable however
41 Client A: <SemiRandomNotProtocolMarker 7 Bits[Unencrypted]><ED2K Marker 1Bit = 1><RandomKeyPart 2[Unencrypted]><MagicValue 4><PaddingLen 1><RandomBytes PaddingLen%16>
43 - Additional Comments:
44 - For obvious reasons the UDP handshake is actually no handshake. If a different Encryption method (or better a different Key) is to be used this has to be negotiated in a TCP connection
45 - SemiRandomNotProtocolMarker is a Byte which has a value unequal any Protocol header byte. This is a compromise, turning in complete randomness (and nice design) but gaining a lower CPU usage
46 - Kad/Ed2k Marker are only indicators, which possibility could be tried first, and should not be trusted
48 ****************************** Server Packets
50 - Keycreation Client <-> Server:
51 - Client A (Outgoing connection client -> server):
52 Sendkey: Md5(<BaseKey 4><MagicValueClientServer 1><RandomKeyPartClientA 2>) 7
53 - Client B (Incoming connection):
54 Receivekey: Md5(<BaseKey 4><MagicValueServerClient 1><RandomKeyPartClientA 2>) 7
55 - Note: The first 1024 Bytes will be _NOT_ discarded for UDP keys to save CPU time
57 - Handshake
58 -> The handshake is encrypted - except otherwise noted - by the Keys created above
59 -> Padding is currently not used for UDP meaning that PaddingLen will be 0, using PaddingLens up to 16 Bytes is acceptable however
60 Client A: <SemiRandomNotProtocolMarker 1[Unencrypted]><RandomKeyPart 2[Unencrypted]><MagicValue 4><PaddingLen 1><RandomBytes PaddingLen%16>
62 - Overhead: 8 Bytes per UDP Packet
64 - Security for Basic Obfuscation:
65 - Random looking packets, very limited protection against passive eavesdropping single packets
67 - Additional Comments:
68 - For obvious reasons the UDP handshake is actually no handshake. If a different Encryption method (or better a different Key) is to be used this has to be negotiated in a TCP connection
69 - SemiRandomNotProtocolMarker is a Byte which has a value unequal any Protocol header byte. This is a compromise, turning in complete randomness (and nice design) but gaining a lower CPU usage
71 ****************************** KAD Packets
73 - Keycreation Client <-> Client:
74 - Client A (Outgoing connection):
75 Sendkey: Md5(<KadID 16><RandomKeyPartClientA 2>) 18
76 - Client B (Incoming connection):
77 Receivekey: Md5(<KadID 16><RandomKeyPartClientA 2>) 18
78 - Note: The first 1024 Bytes will be _NOT_ discarded for UDP keys to save CPU time
80 - Handshake
81 -> The handshake is encrypted - except otherwise noted - by the Keys created above
82 -> Padding is currently not used for UDP meaning that PaddingLen will be 0, using PaddingLens up to 16 Bytes is acceptable however
83 Client A: <SemiRandomNotProtocolMarker 7 Bits[Unencrypted]><Kad Marker 1Bit = 0><RandomKeyPart 2[Unencrypted]><MagicValue 4><PaddingLen 1><RandomBytes PaddingLen%16><ReceiverVerifyKey 2><SenderVerifyKey 2>
85 - Overhead: 12 Bytes per UDP Packet
87 - Additional Comments:
88 - For obvious reasons the UDP handshake is actually no handshake. If a different Encryption method (or better a different Key) is to be used this has to be negotiated in a TCP connection
89 - SemiRandomNotProtocolMarker is a Byte which has a value unequal any Protocol header byte. This is a compromise, turning in complete randomness (and nice design) but gaining a lower CPU usage
90 - Kad/Ed2k Marker are only indicators, which possibility could be tried first, and should not be trusted
93 #include "EncryptedDatagramSocket.h"
94 #include "amule.h"
95 #include "Logger.h"
96 #include "Preferences.h"
97 #include "RC4Encrypt.h"
98 #include "./kademlia/kademlia/Prefs.h"
99 #include "./kademlia/kademlia/Kademlia.h"
100 #include "RandomFunctions.h"
101 #include "Statistics.h"
103 #include <protocol/Protocols.h>
104 #include <common/MD5Sum.h>
106 // random generator
107 #include "CryptoPP_Inc.h" // Needed for Crypto functions
109 #define CRYPT_HEADER_WITHOUTPADDING 8
110 #define MAGICVALUE_UDP 91
111 #define MAGICVALUE_UDP_SYNC_CLIENT 0x395F2EC1
112 #define MAGICVALUE_UDP_SYNC_SERVER 0x13EF24D5
113 #define MAGICVALUE_UDP_SERVERCLIENT 0xA5
114 #define MAGICVALUE_UDP_CLIENTSERVER 0x6B
116 CEncryptedDatagramSocket::CEncryptedDatagramSocket(wxIPaddress &address, wxSocketFlags flags, const CProxyData *proxyData)
117 : CDatagramSocketProxy(address, flags, proxyData)
120 CEncryptedDatagramSocket::~CEncryptedDatagramSocket()
123 int CEncryptedDatagramSocket::DecryptReceivedClient(uint8_t *bufIn, int bufLen, uint8_t **bufOut, uint32_t ip, uint32_t *receiverVerifyKey, uint32_t *senderVerifyKey)
125 int result = bufLen;
126 *bufOut = bufIn;
128 if (receiverVerifyKey == NULL || senderVerifyKey == NULL) {
129 wxFAIL;
130 return result;
133 *receiverVerifyKey = 0;
134 *senderVerifyKey = 0;
136 if (result <= CRYPT_HEADER_WITHOUTPADDING /*|| !thePrefs.IsClientCryptLayerSupported()*/) {
137 return result;
140 switch (bufIn[0]) {
141 case OP_EMULEPROT:
142 case OP_KADEMLIAPACKEDPROT:
143 case OP_KADEMLIAHEADER:
144 case OP_UDPRESERVEDPROT1:
145 case OP_UDPRESERVEDPROT2:
146 case OP_PACKEDPROT:
147 return result; // no encrypted packet (see description on top)
148 default:
152 // might be an encrypted packet, try to decrypt
153 CRC4EncryptableBuffer receivebuffer;
154 uint32_t value = 0;
155 // check the marker bit which type this packet could be and which key to test first, this is only an indicator since old clients have it set random
156 // see the header for marker bits explanation
157 uint8_t currentTry = ((bufIn[0] & 0x03) == 3) ? 1 : (bufIn[0] & 0x03);
158 uint8_t tries;
159 if (Kademlia::CKademlia::GetPrefs() == NULL) {
160 // if kad never run, no point in checking anything except for ed2k encryption
161 tries = 1;
162 currentTry = 1;
163 } else {
164 tries = 3;
166 bool kadRecvKeyUsed = false;
167 bool kad = false;
168 do {
169 receivebuffer.FullReset();
170 tries--;
171 MD5Sum md5;
173 if (currentTry == 0) {
174 // kad packet with NodeID as key
175 kad = true;
176 kadRecvKeyUsed = false;
177 if (Kademlia::CKademlia::GetPrefs()) {
178 uint8_t keyData[18];
179 Kademlia::CKademlia::GetPrefs()->GetKadID().StoreCryptValue((uint8_t *)&keyData);
180 memcpy(keyData + 16, bufIn + 1, 2); // random key part sent from remote client
181 md5.Calculate(keyData, sizeof(keyData));
183 } else if (currentTry == 1) {
184 // ed2k packet
185 kad = false;
186 kadRecvKeyUsed = false;
187 uint8_t keyData[23];
188 md4cpy(keyData, thePrefs::GetUserHash().GetHash());
189 keyData[20] = MAGICVALUE_UDP;
190 PokeUInt32(keyData + 16, ip);
191 memcpy(keyData + 21, bufIn + 1, 2); // random key part sent from remote client
192 md5.Calculate(keyData, sizeof(keyData));
193 } else if (currentTry == 2) {
194 // kad packet with ReceiverKey as key
195 kad = true;
196 kadRecvKeyUsed = true;
197 if (Kademlia::CKademlia::GetPrefs()) {
198 uint8_t keyData[6];
199 PokeUInt32(keyData, Kademlia::CPrefs::GetUDPVerifyKey(ip));
200 memcpy(keyData + 4, bufIn + 1, 2); // random key part sent from remote client
201 md5.Calculate(keyData, sizeof(keyData));
203 } else {
204 wxFAIL;
207 receivebuffer.SetKey(md5, true);
208 receivebuffer.RC4Crypt(bufIn + 3, (uint8_t*)&value, sizeof(value));
209 ENDIAN_SWAP_I_32(value);
211 currentTry = (currentTry + 1) % 3;
212 } while (value != MAGICVALUE_UDP_SYNC_CLIENT && tries > 0); // try to decrypt as ed2k as well as kad packet if needed (max 3 rounds)
214 if (value == MAGICVALUE_UDP_SYNC_CLIENT) {
215 // yup this is an encrypted packet
216 // // debugoutput notices
217 // // the following cases are "allowed" but shouldn't happen given that there is only our implementation yet
218 // if (bKad && (pbyBufIn[0] & 0x01) != 0)
219 // DebugLog(_T("Received obfuscated UDP packet from clientIP: %s with wrong key marker bits (kad packet, ed2k bit)"), ipstr(dwIP));
220 // else if (bKad && !bKadRecvKeyUsed && (pbyBufIn[0] & 0x02) != 0)
221 // DebugLog(_T("Received obfuscated UDP packet from clientIP: %s with wrong key marker bits (kad packet, nodeid key, recvkey bit)"), ipstr(dwIP));
222 // else if (bKad && bKadRecvKeyUsed && (pbyBufIn[0] & 0x02) == 0)
223 // DebugLog(_T("Received obfuscated UDP packet from clientIP: %s with wrong key marker bits (kad packet, recvkey key, nodeid bit)"), ipstr(dwIP));
225 uint8_t padLen;
226 receivebuffer.RC4Crypt(bufIn + 7, (uint8_t*)&padLen, 1);
227 result -= CRYPT_HEADER_WITHOUTPADDING;
229 if (result <= padLen) {
230 //DebugLogError(_T("Invalid obfuscated UDP packet from clientIP: %s, Paddingsize (%u) larger than received bytes"), ipstr(dwIP), byPadLen);
231 return bufLen; // pass through, let the Receivefunction do the errorhandling on this junk
234 if (padLen > 0) {
235 receivebuffer.RC4Crypt(NULL, NULL, padLen);
238 result -= padLen;
240 if (kad) {
241 if (result <= 8) {
242 //DebugLogError(_T("Obfuscated Kad packet with mismatching size (verify keys missing) received from clientIP: %s"), ipstr(dwIP));
243 return bufLen; // pass through, let the Receivefunction do the errorhandling on this junk;
245 // read the verify keys
246 receivebuffer.RC4Crypt(bufIn + CRYPT_HEADER_WITHOUTPADDING + padLen, (uint8_t*)receiverVerifyKey, 4);
247 receivebuffer.RC4Crypt(bufIn + CRYPT_HEADER_WITHOUTPADDING + padLen + 4, (uint8_t*)senderVerifyKey, 4);
248 ENDIAN_SWAP_I_32(*receiverVerifyKey);
249 ENDIAN_SWAP_I_32(*senderVerifyKey);
250 result -= 8;
253 *bufOut = bufIn + (bufLen - result);
255 receivebuffer.RC4Crypt((uint8_t*)*bufOut, (uint8_t*)*bufOut, result);
256 theStats::AddDownOverheadCrypt(bufLen - result);
257 return result; // done
258 } else {
259 //DebugLogWarning(_T("Obfuscated packet expected but magicvalue mismatch on UDP packet from clientIP: %s"), ipstr(dwIP));
260 return bufLen; // pass through, let the Receivefunction do the errorhandling on this junk
264 // Encrypt packet. Key used:
265 // clientHashOrKadID != NULL -> clientHashOrKadID
266 // clientHashOrKadID == NULL && kad && receiverVerifyKey != 0 -> receiverVerifyKey
267 // else -> ASSERT
268 int CEncryptedDatagramSocket::EncryptSendClient(uint8_t **buf, int bufLen, const uint8_t *clientHashOrKadID, bool kad, uint32_t receiverVerifyKey, uint32_t senderVerifyKey)
270 wxASSERT(theApp->GetPublicIP() != 0 || kad);
271 wxASSERT(thePrefs::IsClientCryptLayerSupported());
272 wxASSERT(clientHashOrKadID != NULL || receiverVerifyKey != 0);
273 wxASSERT((receiverVerifyKey == 0 && senderVerifyKey == 0) || kad);
275 uint8_t padLen = 0; // padding disabled for UDP currently
276 const uint32_t cryptHeaderLen = padLen + CRYPT_HEADER_WITHOUTPADDING + (kad ? 8 : 0);
277 uint32_t cryptedLen = bufLen + cryptHeaderLen;
278 uint8_t *cryptedBuffer = new uint8_t[cryptedLen];
279 bool kadRecvKeyUsed = false;
281 uint16_t randomKeyPart = GetRandomUint16();
282 CRC4EncryptableBuffer sendbuffer;
283 MD5Sum md5;
284 if (kad) {
285 if ((clientHashOrKadID == NULL || CMD4Hash(clientHashOrKadID).IsEmpty()) && receiverVerifyKey != 0) {
286 kadRecvKeyUsed = true;
287 uint8_t keyData[6];
288 PokeUInt32(keyData, receiverVerifyKey);
289 PokeUInt16(keyData+4, randomKeyPart);
290 md5.Calculate(keyData, sizeof(keyData));
291 //DEBUG_ONLY( DebugLog(_T("Creating obfuscated Kad packet encrypted by ReceiverKey (%u)"), nReceiverVerifyKey) );
293 else if (clientHashOrKadID != NULL && !CMD4Hash(clientHashOrKadID).IsEmpty()) {
294 uint8_t keyData[18];
295 md4cpy(keyData, clientHashOrKadID);
296 PokeUInt16(keyData+16, randomKeyPart);
297 md5.Calculate(keyData, sizeof(keyData));
298 //DEBUG_ONLY( DebugLog(_T("Creating obfuscated Kad packet encrypted by Hash/NodeID %s"), md4str(pachClientHashOrKadID)) );
300 else {
301 wxFAIL;
302 return bufLen;
304 } else {
305 uint8_t keyData[23];
306 md4cpy(keyData, clientHashOrKadID);
307 PokeUInt32(keyData+16, theApp->GetPublicIP());
308 PokeUInt16(keyData+21, randomKeyPart);
309 keyData[20] = MAGICVALUE_UDP;
310 md5.Calculate(keyData, sizeof(keyData));
313 sendbuffer.SetKey(md5, true);
315 // create the semi random byte encryption header
316 uint8_t semiRandomNotProtocolMarker = 0;
317 int i;
318 for (i = 0; i < 128; i++) {
319 semiRandomNotProtocolMarker = GetRandomUint8();
320 semiRandomNotProtocolMarker = kad ? (semiRandomNotProtocolMarker & 0xFE) : (semiRandomNotProtocolMarker | 0x01); // set the ed2k/kad marker bit
321 if (kad) {
322 // set the ed2k/kad and nodeid/recvkey markerbit
323 semiRandomNotProtocolMarker = kadRecvKeyUsed ? ((semiRandomNotProtocolMarker & 0xFE) | 0x02) : (semiRandomNotProtocolMarker & 0xFC);
324 } else {
325 // set the ed2k/kad marker bit
326 semiRandomNotProtocolMarker = (semiRandomNotProtocolMarker | 0x01);
329 bool bOk = false;
330 switch (semiRandomNotProtocolMarker) { // not allowed values
331 case OP_EMULEPROT:
332 case OP_KADEMLIAPACKEDPROT:
333 case OP_KADEMLIAHEADER:
334 case OP_UDPRESERVEDPROT1:
335 case OP_UDPRESERVEDPROT2:
336 case OP_PACKEDPROT:
337 break;
338 default:
339 bOk = true;
342 if (bOk) {
343 break;
347 if (i >= 128) {
348 // either we have _real_ bad luck or the randomgenerator is a bit messed up
349 wxFAIL;
350 semiRandomNotProtocolMarker = 0x01;
353 cryptedBuffer[0] = semiRandomNotProtocolMarker;
354 PokeUInt16(cryptedBuffer + 1, randomKeyPart);
356 uint32_t magicValue = ENDIAN_SWAP_32(MAGICVALUE_UDP_SYNC_CLIENT);
357 sendbuffer.RC4Crypt((uint8_t*)&magicValue, cryptedBuffer + 3, 4);
358 sendbuffer.RC4Crypt((uint8_t*)&padLen, cryptedBuffer + 7, 1);
360 for (int j = 0; j < padLen; j++) {
361 uint8_t byRand = (uint8_t)rand(); // they actually don't really need to be random, but it doesn't hurt either
362 sendbuffer.RC4Crypt((uint8_t*)&byRand, cryptedBuffer + CRYPT_HEADER_WITHOUTPADDING + j, 1);
365 if (kad) {
366 ENDIAN_SWAP_I_32(receiverVerifyKey);
367 ENDIAN_SWAP_I_32(senderVerifyKey);
368 sendbuffer.RC4Crypt((uint8_t*)&receiverVerifyKey, cryptedBuffer + CRYPT_HEADER_WITHOUTPADDING + padLen, 4);
369 sendbuffer.RC4Crypt((uint8_t*)&senderVerifyKey, cryptedBuffer + CRYPT_HEADER_WITHOUTPADDING + padLen + 4, 4);
372 sendbuffer.RC4Crypt(*buf, cryptedBuffer + cryptHeaderLen, bufLen);
373 delete [] *buf;
374 *buf = cryptedBuffer;
376 theStats::AddUpOverheadCrypt(cryptedLen - bufLen);
377 return cryptedLen;
380 int CEncryptedDatagramSocket::DecryptReceivedServer(uint8_t* pbyBufIn, int nBufLen, uint8_t **ppbyBufOut, uint32_t dwBaseKey, uint32_t /*dbgIP*/)
382 int nResult = nBufLen;
383 *ppbyBufOut = pbyBufIn;
385 if (nResult <= CRYPT_HEADER_WITHOUTPADDING || !thePrefs::IsServerCryptLayerUDPEnabled() || dwBaseKey == 0) {
386 return nResult;
389 if(pbyBufIn[0] == OP_EDONKEYPROT) {
390 return nResult; // no encrypted packet (see description on top)
393 // might be an encrypted packet, try to decrypt
394 uint8_t achKeyData[7];
395 PokeUInt32(achKeyData, dwBaseKey);
396 achKeyData[4] = MAGICVALUE_UDP_SERVERCLIENT;
397 memcpy(achKeyData + 5, pbyBufIn + 1, 2); // random key part sent from remote server
399 CRC4EncryptableBuffer receivebuffer;
400 MD5Sum md5(achKeyData, sizeof(achKeyData));
401 receivebuffer.SetKey(md5,true);
403 uint32_t dwValue;
404 receivebuffer.RC4Crypt(pbyBufIn + 3, (uint8_t*)&dwValue, sizeof(dwValue));
405 ENDIAN_SWAP_I_32(dwValue);
406 if (dwValue == MAGICVALUE_UDP_SYNC_SERVER) {
407 // yup this is an encrypted packet
408 //DEBUG_ONLY( DebugLog(_T("Received obfuscated UDP packet from ServerIP: %s"), ipstr(dbgIP)) );
409 uint8_t byPadLen;
410 receivebuffer.RC4Crypt(pbyBufIn + 7, (uint8_t*)&byPadLen, 1);
411 byPadLen &= 15;
412 nResult -= CRYPT_HEADER_WITHOUTPADDING;
414 if (nResult <= byPadLen) {
415 //DebugLogError(_T("Invalid obfuscated UDP packet from ServerIP: %s, Paddingsize (%u) larger than received bytes"), ipstr(dbgIP), byPadLen);
416 return nBufLen; // pass through, let the Receivefunction do the errorhandling on this junk
419 if (byPadLen > 0) {
420 receivebuffer.RC4Crypt(NULL, NULL, byPadLen);
423 nResult -= byPadLen;
424 *ppbyBufOut = pbyBufIn + (nBufLen - nResult);
425 receivebuffer.RC4Crypt((uint8_t*)*ppbyBufOut, (uint8_t*)*ppbyBufOut, nResult);
427 theStats::AddDownOverheadCrypt(nBufLen - nResult);
428 return nResult; // done
429 } else {
430 //DebugLogWarning(_T("Obfuscated packet expected but magicvalue mismatch on UDP packet from ServerIP: %s"), ipstr(dbgIP));
431 return nBufLen; // pass through, let the Receivefunction do the errorhandling on this junk
435 int CEncryptedDatagramSocket::EncryptSendServer(uint8_t** ppbyBuf, int nBufLen, uint32_t dwBaseKey)
437 wxASSERT( thePrefs::IsServerCryptLayerUDPEnabled() );
438 wxASSERT( dwBaseKey != 0 );
440 uint16_t nRandomKeyPart = GetRandomUint16();
442 uint8_t achKeyData[7];
443 PokeUInt32(achKeyData, dwBaseKey);
444 achKeyData[4] = MAGICVALUE_UDP_CLIENTSERVER;
445 PokeUInt16(achKeyData + 5, nRandomKeyPart);
446 MD5Sum md5(achKeyData, sizeof(achKeyData));
447 CRC4EncryptableBuffer sendbuffer;
448 sendbuffer.SetKey(md5, true);
450 // create the semi random byte encryption header
451 uint8_t bySemiRandomNotProtocolMarker = 0;
452 int i;
454 for (i = 0; i < 128; i++) {
455 bySemiRandomNotProtocolMarker = GetRandomUint8();
456 if (bySemiRandomNotProtocolMarker != OP_EDONKEYPROT) { // not allowed values
457 break;
461 if (i >= 128) {
462 // either we have _real_ bad luck or the randomgenerator is a bit messed up
463 wxFAIL;
464 bySemiRandomNotProtocolMarker = 0x01;
467 uint8_t byPadLen = 0; // padding disabled for UDP currently
468 uint32_t nCryptedLen = nBufLen + byPadLen + CRYPT_HEADER_WITHOUTPADDING;
469 uint8_t* pachCryptedBuffer = new uint8_t[nCryptedLen];
471 pachCryptedBuffer[0] = bySemiRandomNotProtocolMarker;
472 PokeUInt16(pachCryptedBuffer + 1, nRandomKeyPart);
474 uint32_t dwMagicValue = ENDIAN_SWAP_32(MAGICVALUE_UDP_SYNC_SERVER);
475 sendbuffer.RC4Crypt((uint8_t*)&dwMagicValue, pachCryptedBuffer + 3, 4);
477 sendbuffer.RC4Crypt((uint8_t*)&byPadLen, pachCryptedBuffer + 7, 1);
479 for (int j = 0; j < byPadLen; j++){
480 uint8_t byRand = (uint8_t)rand(); // they actually don't really need to be random, but it doesn't hurt either
481 sendbuffer.RC4Crypt((uint8_t*)&byRand, pachCryptedBuffer + CRYPT_HEADER_WITHOUTPADDING + j, 1);
483 sendbuffer.RC4Crypt(*ppbyBuf, pachCryptedBuffer + CRYPT_HEADER_WITHOUTPADDING + byPadLen, nBufLen);
484 delete[] *ppbyBuf;
485 *ppbyBuf = pachCryptedBuffer;
487 theStats::AddUpOverheadCrypt(nCryptedLen - nBufLen);
488 return nCryptedLen;