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tdesktop/Telegram/SourceFiles/mtproto/mtpConnection.cpp

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/*
This file is part of Telegram Desktop,
the official desktop version of Telegram messaging app, see https://telegram.org
Telegram Desktop is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
It is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
Full license: https://github.com/telegramdesktop/tdesktop/blob/master/LICENSE
Copyright (c) 2014 John Preston, https://desktop.telegram.org
*/
#include "stdafx.h"
#include <openssl/rand.h>
namespace {
bool parsePQ(const std::string &pqStr, std::string &pStr, std::string &qStr) {
if (pqStr.length() > 8) return false; // more than 64 bit pq
uint64 pq = 0, p, q;
const uchar *pqChars = (const uchar*)&pqStr[0];
for (uint32 i = 0, l = pqStr.length(); i < l; ++i) {
pq <<= 8;
pq |= (uint64)pqChars[i];
}
uint64 pqSqrt = (uint64)sqrtl((long double)pq), ySqr, y;
while (pqSqrt * pqSqrt > pq) --pqSqrt;
while (pqSqrt * pqSqrt < pq) ++pqSqrt;
for (ySqr = pqSqrt * pqSqrt - pq; ; ++pqSqrt, ySqr = pqSqrt * pqSqrt - pq) {
y = (uint64)sqrtl((long double)ySqr);
while (y * y > ySqr) --y;
while (y * y < ySqr) ++y;
if (!ySqr || y + pqSqrt >= pq) return false;
if (y * y == ySqr) {
p = pqSqrt + y;
q = (pqSqrt > y) ? (pqSqrt - y) : (y - pqSqrt);
break;
}
}
if (p > q) swap(p, q);
pStr.resize(4);
uchar *pChars = (uchar*)&pStr[0];
for (uint32 i = 0; i < 4; ++i) {
*(pChars + 3 - i) = (uchar)(p & 0xFF);
p >>= 8;
}
qStr.resize(4);
uchar *qChars = (uchar*)&qStr[0];
for (uint32 i = 0; i < 4; ++i) {
*(qChars + 3 - i) = (uchar)(q & 0xFF);
q >>= 8;
}
return true;
}
class _BigNumCounter {
public:
bool count(const void *power, const void *modul, uint32 g, void *gResult, const void *g_a, void *g_aResult) {
DEBUG_LOG(("BigNum Info: counting g_b = g ^ b % dh_prime and auth_key = g_a ^ b % dh_prime"));
uint32 g_be = qToBigEndian(g);
if (
!BN_bin2bn((const uchar*)power, 64 * sizeof(uint32), &bnPower) ||
!BN_bin2bn((const uchar*)modul, 64 * sizeof(uint32), &bnModul) ||
!BN_bin2bn((const uchar*)&g_be, sizeof(uint32), &bn_g) ||
!BN_bin2bn((const uchar*)g_a, 64 * sizeof(uint32), &bn_g_a)
) {
ERR_load_crypto_strings();
LOG(("BigNum Error: BN_bin2bn failed, error: %1").arg(ERR_error_string(ERR_get_error(), 0)));
DEBUG_LOG(("BigNum Error: base %1, power %2, modul %3").arg(mb(&g_be, sizeof(uint32)).str()).arg(mb(power, 64 * sizeof(uint32)).str()).arg(mb(modul, 64 * sizeof(uint32)).str()));
return false;
}
if (!BN_mod_exp(&bnResult, &bn_g, &bnPower, &bnModul, ctx)) {
ERR_load_crypto_strings();
LOG(("BigNum Error: BN_mod_exp failed, error: %1").arg(ERR_error_string(ERR_get_error(), 0)));
DEBUG_LOG(("BigNum Error: base %1, power %2, modul %3").arg(mb(&g_be, sizeof(uint32)).str()).arg(mb(power, 64 * sizeof(uint32)).str()).arg(mb(modul, 64 * sizeof(uint32)).str()));
return false;
}
uint32 resultLen = BN_num_bytes(&bnResult);
if (resultLen != 64 * sizeof(uint32)) {
DEBUG_LOG(("BigNum Error: bad gResult len (%1)").arg(resultLen));
return false;
}
resultLen = BN_bn2bin(&bnResult, (uchar*)gResult);
if (resultLen != 64 * sizeof(uint32)) {
DEBUG_LOG(("BigNum Error: bad gResult export len (%1)").arg(resultLen));
return false;
}
BN_add_word(&bnResult, 1); // check g_b < dh_prime - 1
if (BN_cmp(&bnResult, &bnModul) >= 0) {
DEBUG_LOG(("BigNum Error: bad g_b >= dh_prime - 1"));
return false;
}
if (!BN_mod_exp(&bnResult, &bn_g_a, &bnPower, &bnModul, ctx)) {
ERR_load_crypto_strings();
LOG(("BigNum Error: BN_mod_exp failed, error: %1").arg(ERR_error_string(ERR_get_error(), 0)));
DEBUG_LOG(("BigNum Error: base %1, power %2, modul %3").arg(mb(&g_be, sizeof(uint32)).str()).arg(mb(power, 64 * sizeof(uint32)).str()).arg(mb(modul, 64 * sizeof(uint32)).str()));
return false;
}
resultLen = BN_num_bytes(&bnResult);
if (resultLen != 64 * sizeof(uint32)) {
DEBUG_LOG(("BigNum Error: bad g_aResult len (%1)").arg(resultLen));
return false;
}
resultLen = BN_bn2bin(&bnResult, (uchar*)g_aResult);
if (resultLen != 64 * sizeof(uint32)) {
DEBUG_LOG(("BigNum Error: bad g_aResult export len (%1)").arg(resultLen));
return false;
}
BN_add_word(&bn_g_a, 1); // check g_a < dh_prime - 1
if (BN_cmp(&bn_g_a, &bnModul) >= 0) {
DEBUG_LOG(("BigNum Error: bad g_a >= dh_prime - 1"));
return false;
}
return true;
}
_BigNumCounter() : ctx(BN_CTX_new()) {
BN_init(&bnPower);
BN_init(&bnModul);
BN_init(&bn_g);
BN_init(&bn_g_a);
BN_init(&bnResult);
}
~_BigNumCounter() {
BN_CTX_free(ctx);
BN_clear_free(&bnPower);
BN_clear_free(&bnModul);
BN_clear_free(&bn_g);
BN_clear_free(&bn_g_a);
BN_clear_free(&bnResult);
}
private:
BIGNUM bnPower, bnModul, bn_g, bn_g_a, bnResult;
BN_CTX *ctx;
};
// Miller-Rabin primality test
class _BigNumPrimeTest {
public:
bool isPrimeAndGood(const void *pData, uint32 iterCount, int32 g) {
if (!memcmp(pData, "\xC7\x1C\xAE\xB9\xC6\xB1\xC9\x04\x8E\x6C\x52\x2F\x70\xF1\x3F\x73\x98\x0D\x40\x23\x8E\x3E\x21\xC1\x49\x34\xD0\x37\x56\x3D\x93\x0F\x48\x19\x8A\x0A\xA7\xC1\x40\x58\x22\x94\x93\xD2\x25\x30\xF4\xDB\xFA\x33\x6F\x6E\x0A\xC9\x25\x13\x95\x43\xAE\xD4\x4C\xCE\x7C\x37\x20\xFD\x51\xF6\x94\x58\x70\x5A\xC6\x8C\xD4\xFE\x6B\x6B\x13\xAB\xDC\x97\x46\x51\x29\x69\x32\x84\x54\xF1\x8F\xAF\x8C\x59\x5F\x64\x24\x77\xFE\x96\xBB\x2A\x94\x1D\x5B\xCD\x1D\x4A\xC8\xCC\x49\x88\x07\x08\xFA\x9B\x37\x8E\x3C\x4F\x3A\x90\x60\xBE\xE6\x7C\xF9\xA4\xA4\xA6\x95\x81\x10\x51\x90\x7E\x16\x27\x53\xB5\x6B\x0F\x6B\x41\x0D\xBA\x74\xD8\xA8\x4B\x2A\x14\xB3\x14\x4E\x0E\xF1\x28\x47\x54\xFD\x17\xED\x95\x0D\x59\x65\xB4\xB9\xDD\x46\x58\x2D\xB1\x17\x8D\x16\x9C\x6B\xC4\x65\xB0\xD6\xFF\x9C\xA3\x92\x8F\xEF\x5B\x9A\xE4\xE4\x18\xFC\x15\xE8\x3E\xBE\xA0\xF8\x7F\xA9\xFF\x5E\xED\x70\x05\x0D\xED\x28\x49\xF4\x7B\xF9\x59\xD9\x56\x85\x0C\xE9\x29\x85\x1F\x0D\x81\x15\xF6\x35\xB1\x05\xEE\x2E\x4E\x15\xD0\x4B\x24\x54\xBF\x6F\x4F\xAD\xF0\x34\xB1\x04\x03\x11\x9C\xD8\xE3\xB9\x2F\xCC\x5B", 256)) {
if (g == 3 || g == 4 || g == 5 || g == 7) {
return true;
}
}
if (
!BN_bin2bn((const uchar*)pData, 64 * sizeof(uint32), &bnPrime)
) {
ERR_load_crypto_strings();
LOG(("BigNum PT Error: BN_bin2bn failed, error: %1").arg(ERR_error_string(ERR_get_error(), 0)));
DEBUG_LOG(("BigNum PT Error: prime %1").arg(mb(pData, 64 * sizeof(uint32)).str()));
return false;
}
int32 numBits = BN_num_bits(&bnPrime);
if (numBits != 2048) {
LOG(("BigNum PT Error: BN_bin2bn failed, bad dh_prime num bits: %1").arg(numBits));
return false;
}
if (BN_is_prime_ex(&bnPrime, MTPMillerRabinIterCount, ctx, NULL) == 0) {
return false;
}
BN_sub_word(&bnPrime, 1); // (p - 1) / 2
BN_div_word(&bnPrime, 2);
if (BN_is_prime_ex(&bnPrime, MTPMillerRabinIterCount, ctx, NULL) == 0) {
return false;
}
switch (g) {
case 2: {
int32 mod8 = BN_mod_word(&bnPrime, 8);
if (mod8 != 7) {
LOG(("BigNum PT Error: bad g value: %1, mod8: %2").arg(g).arg(mod8));
return false;
}
} break;
case 3: {
int32 mod3 = BN_mod_word(&bnPrime, 3);
if (mod3 != 2) {
LOG(("BigNum PT Error: bad g value: %1, mod3: %2").arg(g).arg(mod3));
return false;
}
} break;
case 4: break;
case 5: {
int32 mod5 = BN_mod_word(&bnPrime, 5);
if (mod5 != 1 && mod5 != 4) {
LOG(("BigNum PT Error: bad g value: %1, mod5: %2").arg(g).arg(mod5));
return false;
}
} break;
case 6: {
int32 mod24 = BN_mod_word(&bnPrime, 24);
if (mod24 != 19 && mod24 != 23) {
LOG(("BigNum PT Error: bad g value: %1, mod24: %2").arg(g).arg(mod24));
return false;
}
} break;
case 7: {
int32 mod7 = BN_mod_word(&bnPrime, 7);
if (mod7 != 3 && mod7 != 5 && mod7 != 6) {
LOG(("BigNum PT Error: bad g value: %1, mod7: %2").arg(g).arg(mod7));
return false;
}
} break;
default:
LOG(("BigNum PT Error: bad g value: %1").arg(g));
return false;
break;
}
return true;
}
_BigNumPrimeTest() : ctx(BN_CTX_new()) {
BN_init(&bnPrime);
}
~_BigNumPrimeTest() {
BN_CTX_free(ctx);
BN_clear_free(&bnPrime);
}
private:
BIGNUM bnPrime;
BN_CTX *ctx;
};
typedef QMap<uint64, mtpPublicRSA> PublicRSAKeys;
PublicRSAKeys gPublicRSA;
MTProtoConnection gMainConnection;
bool gConfigInited = false;
void initRSAConfig() {
if (gConfigInited) return;
gConfigInited = true;
DEBUG_LOG(("MTP Info: MTP config init"));
// read all public keys
uint32 keysCnt;
const char **keys = cPublicRSAKeys(keysCnt);
for (uint32 i = 0; i < keysCnt; ++i) {
mtpPublicRSA key(keys[i]);
if (key.key()) {
gPublicRSA.insert(key.fingerPrint(), key);
} else {
LOG(("MTP Error: could not read this public RSA key:"));
LOG((keys[i]));
}
}
DEBUG_LOG(("MTP Info: read %1 public RSA keys").arg(gPublicRSA.size()));
}
}
MTPThread::MTPThread(QObject *parent) : QThread(parent) {
static uint32 gThreadId = 0;
threadId = ++gThreadId;
}
uint32 MTPThread::getThreadId() const {
return threadId;
}
MTProtoConnection::MTProtoConnection() : thread(0), data(0) {
}
int32 MTProtoConnection::start(MTPSessionData *sessionData, int32 dc) {
initRSAConfig();
if (thread) {
DEBUG_LOG(("MTP Info: MTP start called for already working connection"));
return dc;
}
thread = new MTPThread(QApplication::instance());
data = new MTProtoConnectionPrivate(thread, this, sessionData, dc);
dc = data->getDC();
if (!dc) {
delete data;
delete thread;
data = 0;
thread = 0;
return 0;
}
thread->start();
return dc;
}
void MTProtoConnection::stop() {
if (data) data->stop();
if (thread) thread->quit();
}
void MTProtoConnection::stopped() {
if (thread) thread->deleteLater();
if (data) data->deleteLater();
thread = 0;
data = 0;
delete this;
}
int32 MTProtoConnection::state() const {
if (!data) return Disconnected;
return data->getState();
}
QString MTProtoConnection::transport() const {
if (!data) return QString();
return data->transport();
}
namespace {
mtpBuffer _handleHttpResponse(QNetworkReply *reply) {
QByteArray response = reply->readAll();
TCP_LOG(("HTTP Info: read %1 bytes").arg(response.size()));
if (response.isEmpty()) return mtpBuffer();
if (response.size() & 0x03 || response.size() < 8) {
LOG(("HTTP Error: bad response size %1").arg(response.size()));
return mtpBuffer(1, -500);
}
mtpBuffer data(response.size() >> 2);
memcpy(data.data(), response.constData(), response.size());
return data;
}
bool _handleHttpError(QNetworkReply *reply) { // returnes "maybe bad key"
bool mayBeBadKey = false;
QVariant statusCode = reply->attribute(QNetworkRequest::HttpStatusCodeAttribute);
if (statusCode.isValid()) {
int status = statusCode.toInt();
mayBeBadKey = (status == 404);
if (status == 429) {
LOG(("Protocol Error: 429 flood code returned!"));
}
}
switch (reply->error()) {
case QNetworkReply::ConnectionRefusedError: LOG(("HTTP Error: connection refused - %1").arg(reply->errorString())); break;
case QNetworkReply::RemoteHostClosedError: LOG(("HTTP Error: remote host closed - %1").arg(reply->errorString())); break;
case QNetworkReply::HostNotFoundError: LOG(("HTTP Error: host not found - %2").arg(reply->error()).arg(reply->errorString())); break;
case QNetworkReply::TimeoutError: LOG(("HTTP Error: timeout - %2").arg(reply->error()).arg(reply->errorString())); break;
case QNetworkReply::OperationCanceledError: LOG(("HTTP Error: cancelled - %2").arg(reply->error()).arg(reply->errorString())); break;
case QNetworkReply::SslHandshakeFailedError:
case QNetworkReply::TemporaryNetworkFailureError:
case QNetworkReply::NetworkSessionFailedError:
case QNetworkReply::BackgroundRequestNotAllowedError:
case QNetworkReply::UnknownNetworkError: LOG(("HTTP Error: network error %1 - %2").arg(reply->error()).arg(reply->errorString())); break;
// proxy errors (101-199):
case QNetworkReply::ProxyConnectionRefusedError:
case QNetworkReply::ProxyConnectionClosedError:
case QNetworkReply::ProxyNotFoundError:
case QNetworkReply::ProxyTimeoutError:
case QNetworkReply::ProxyAuthenticationRequiredError:
case QNetworkReply::UnknownProxyError:LOG(("HTTP Error: proxy error %1 - %2").arg(reply->error()).arg(reply->errorString())); break;
// content errors (201-299):
case QNetworkReply::ContentAccessDenied:
case QNetworkReply::ContentOperationNotPermittedError:
case QNetworkReply::ContentNotFoundError:
case QNetworkReply::AuthenticationRequiredError:
case QNetworkReply::ContentReSendError:
case QNetworkReply::UnknownContentError: LOG(("HTTP Error: content error %1 - %2").arg(reply->error()).arg(reply->errorString())); break;
// protocol errors
case QNetworkReply::ProtocolUnknownError:
case QNetworkReply::ProtocolInvalidOperationError:
case QNetworkReply::ProtocolFailure: LOG(("HTTP Error: protocol error %1 - %2").arg(reply->error()).arg(reply->errorString())); break;
};
TCP_LOG(("HTTP Error %1, restarting! - %2").arg(reply->error()).arg(reply->errorString()));
return mayBeBadKey;
}
mtpBuffer _handleTcpResponse(mtpPrime *packet, uint32 size) {
if (size < 4 || size * sizeof(mtpPrime) > MTPPacketSizeMax) {
LOG(("TCP Error: bad packet size %1").arg(size * sizeof(mtpPrime)));
return mtpBuffer(1, -500);
}
if (packet[0] != int32(size * sizeof(mtpPrime))) {
LOG(("TCP Error: bad packet header"));
TCP_LOG(("TCP Error: bad packet header, packet: %1").arg(mb(packet, size * sizeof(mtpPrime)).str()));
return mtpBuffer(1, -500);
}
if (packet[size - 1] != hashCrc32(packet, (size - 1) * sizeof(mtpPrime))) {
LOG(("TCP Error: bad packet checksum"));
TCP_LOG(("TCP Error: bad packet checksum, packet: %1").arg(mb(packet, size * sizeof(mtpPrime)).str()));
return mtpBuffer(1, -500);
}
TCP_LOG(("TCP Info: packet received, num = %1, size = %2").arg(packet[1]).arg(size * sizeof(mtpPrime)));
if (size == 4) {
if (packet[2] == -429) {
LOG(("Protocol Error: -429 flood code returned!"));
} else {
LOG(("TCP Error: error packet received, code = %1").arg(packet[2]));
}
return mtpBuffer(1, packet[2]);
}
mtpBuffer data(size - 3);
memcpy(data.data(), packet + 2, (size - 3) * sizeof(mtpPrime));
return data;
}
void _handleTcpError(QAbstractSocket::SocketError e, QTcpSocket &sock) {
switch (e) {
case QAbstractSocket::ConnectionRefusedError:
LOG(("TCP Error: socket connection refused - %1").arg(sock.errorString()));
break;
case QAbstractSocket::RemoteHostClosedError:
TCP_LOG(("TCP Info: remote host closed socket connection - %1").arg(sock.errorString()));
break;
case QAbstractSocket::HostNotFoundError:
LOG(("TCP Error: host not found - %1").arg(sock.errorString()));
break;
case QAbstractSocket::SocketTimeoutError:
LOG(("TCP Error: socket timeout - %1").arg(sock.errorString()));
break;
case QAbstractSocket::NetworkError:
LOG(("TCP Error: network - %1").arg(sock.errorString()));
break;
case QAbstractSocket::ProxyAuthenticationRequiredError:
case QAbstractSocket::ProxyConnectionRefusedError:
case QAbstractSocket::ProxyConnectionClosedError:
case QAbstractSocket::ProxyConnectionTimeoutError:
case QAbstractSocket::ProxyNotFoundError:
case QAbstractSocket::ProxyProtocolError:
LOG(("TCP Error: proxy (%1) - %2").arg(e).arg(sock.errorString()));
break;
default:
LOG(("TCP Error: other (%1) - %2").arg(e).arg(sock.errorString()));
break;
}
TCP_LOG(("TCP Error %1, restarting! - %2").arg(e).arg(sock.errorString()));
}
mtpBuffer _preparePQFake(const MTPint128 &nonce) {
MTPReq_pq req_pq(nonce);
mtpBuffer buffer;
uint32 requestSize = req_pq.innerLength() >> 2;
buffer.resize(0);
buffer.reserve(8 + requestSize);
buffer.push_back(0); // tcp packet len
buffer.push_back(0); // tcp packet num
buffer.push_back(0);
buffer.push_back(0);
buffer.push_back(0);
buffer.push_back(unixtime());
buffer.push_back(requestSize * 4);
req_pq.write(buffer);
buffer.push_back(0); // tcp crc32 hash
return buffer;
}
MTPResPQ _readPQFakeReply(const mtpBuffer &buffer) {
const mtpPrime *answer(buffer.constData());
uint32 len = buffer.size();
if (len < 5) {
LOG(("Fake PQ Error: bad request answer, len = %1").arg(len * sizeof(mtpPrime)));
DEBUG_LOG(("Fake PQ Error: answer bytes %1").arg(mb(answer, len * sizeof(mtpPrime)).str()));
throw Exception("bad pq reply");
}
if (answer[0] != 0 || answer[1] != 0 || (((uint32)answer[2]) & 0x03) != 1/* || (unixtime() - answer[3] > 300) || (answer[3] - unixtime() > 60)*/) { // didnt sync time yet
LOG(("Fake PQ Error: bad request answer start (%1 %2 %3)").arg(answer[0]).arg(answer[1]).arg(answer[2]));
DEBUG_LOG(("Fake PQ Error: answer bytes %1").arg(mb(answer, len * sizeof(mtpPrime)).str()));
throw Exception("bad pq reply");
}
uint32 answerLen = (uint32)answer[4];
if (answerLen != (len - 5) * sizeof(mtpPrime)) {
LOG(("Fake PQ Error: bad request answer %1 <> %2").arg(answerLen).arg((len - 5) * sizeof(mtpPrime)));
DEBUG_LOG(("Fake PQ Error: answer bytes %1").arg(mb(answer, len * sizeof(mtpPrime)).str()));
throw Exception("bad pq reply");
}
const mtpPrime *from(answer + 5), *end(from + len - 5);
MTPResPQ response;
response.read(from, end);
return response;
}
}
MTPabstractTcpConnection::MTPabstractTcpConnection() :
packetNum(0), packetRead(0), packetLeft(0), readingToShort(true), currentPos((char*)shortBuffer) {
}
void MTPabstractTcpConnection::socketRead() {
if (sock.state() != QAbstractSocket::ConnectedState) {
LOG(("MTP error: socket not connected in socketRead(), state: %1").arg(sock.state()));
emit error();
return;
}
do {
char *readTo = currentPos;
uint32 toRead = packetLeft ? packetLeft : (readingToShort ? (MTPShortBufferSize * sizeof(mtpPrime)-packetRead) : 4);
if (readingToShort) {
if (currentPos + toRead > ((char*)shortBuffer) + MTPShortBufferSize * sizeof(mtpPrime)) {
longBuffer.resize(((packetRead + toRead) >> 2) + 1);
memcpy(&longBuffer[0], shortBuffer, packetRead);
readTo = ((char*)&longBuffer[0]) + packetRead;
}
} else {
if (longBuffer.size() * sizeof(mtpPrime) < packetRead + toRead) {
longBuffer.resize(((packetRead + toRead) >> 2) + 1);
readTo = ((char*)&longBuffer[0]) + packetRead;
}
}
int32 bytes = (int32)sock.read(readTo, toRead);
if (bytes > 0) {
TCP_LOG(("TCP Info: read %1 bytes").arg(bytes));
packetRead += bytes;
currentPos += bytes;
if (packetLeft) {
packetLeft -= bytes;
if (!packetLeft) {
socketPacket((mtpPrime*)(currentPos - packetRead), packetRead >> 2);
currentPos = (char*)shortBuffer;
packetRead = packetLeft = 0;
readingToShort = true;
} else {
TCP_LOG(("TCP Info: not enough %1 for packet! read %2").arg(packetLeft).arg(packetRead));
emit receivedSome();
}
} else {
bool move = false;
while (packetRead >= 4) {
uint32 packetSize = *(uint32*)(currentPos - packetRead);
if (packetSize < 16 || packetSize > MTPPacketSizeMax || (packetSize & 0x03)) {
LOG(("TCP Error: packet size = %1").arg(packetSize));
emit error();
return;
}
if (packetRead >= packetSize) {
socketPacket((mtpPrime*)(currentPos - packetRead), packetSize >> 2);
packetRead -= packetSize;
packetLeft = 0;
move = true;
} else {
packetLeft = packetSize - packetRead;
TCP_LOG(("TCP Info: not enough %1 for packet! size %2 read %3").arg(packetLeft).arg(packetSize).arg(packetRead));
emit receivedSome();
break;
}
}
if (move) {
if (!packetRead) {
currentPos = (char*)shortBuffer;
readingToShort = true;
} else if (!readingToShort && packetRead < MTPShortBufferSize * sizeof(mtpPrime)) {
memcpy(shortBuffer, currentPos - packetRead, packetRead);
currentPos = (char*)shortBuffer;
readingToShort = true;
}
}
}
} else if (bytes < 0) {
LOG(("TCP Error: socket read return -1"));
emit error();
return;
} else {
TCP_LOG(("TCP Info: no bytes read, but bytes available was true.."));
break;
}
} while (sock.state() == QAbstractSocket::ConnectedState && sock.bytesAvailable());
}
MTPautoConnection::MTPautoConnection(QThread *thread) : status(WaitingBoth),
tcpNonce(MTP::nonce<MTPint128>()), httpNonce(MTP::nonce<MTPint128>()), _tcpTimeout(MTPMinReceiveDelay) {
moveToThread(thread);
manager.moveToThread(thread);
manager.setProxy(QNetworkProxy(QNetworkProxy::DefaultProxy));
httpStartTimer.moveToThread(thread);
httpStartTimer.setSingleShot(true);
connect(&httpStartTimer, SIGNAL(timeout()), this, SLOT(onHttpStart()));
tcpTimeoutTimer.moveToThread(thread);
tcpTimeoutTimer.setSingleShot(true);
connect(&tcpTimeoutTimer, SIGNAL(timeout()), this, SLOT(onTcpTimeoutTimer()));
sock.moveToThread(thread);
sock.setProxy(QNetworkProxy(QNetworkProxy::NoProxy));
connect(&sock, SIGNAL(error(QAbstractSocket::SocketError)), this, SLOT(socketError(QAbstractSocket::SocketError)));
// connect(&sock, SIGNAL(connected()), this, SIGNAL(connected()));
// connect(&sock, SIGNAL(disconnected()), this, SIGNAL(disconnected()));
connect(&sock, SIGNAL(connected()), this, SLOT(onSocketConnected()));
connect(&sock, SIGNAL(disconnected()), this, SLOT(onSocketDisconnected()));
}
void MTPautoConnection::onHttpStart() {
if (status == HttpReady) {
DEBUG_LOG(("Connection Info: Http-transport chosen by timer"));
status = UsingHttp;
sock.disconnectFromHost();
emit connected();
}
}
void MTPautoConnection::onSocketConnected() {
if (status == HttpReady || status == WaitingBoth || status == WaitingTcp) {
mtpBuffer buffer(_preparePQFake(tcpNonce));
DEBUG_LOG(("Connection Info: sending fake req_pq through tcp transport"));
if (_tcpTimeout < 0) _tcpTimeout = -_tcpTimeout;
tcpTimeoutTimer.start(_tcpTimeout);
tcpSend(buffer);
} else if (status == WaitingHttp || status == UsingHttp) {
sock.disconnectFromHost();
}
}
void MTPautoConnection::onTcpTimeoutTimer() {
if (status == HttpReady || status == WaitingBoth || status == WaitingTcp) {
if (_tcpTimeout < MTPMaxReceiveDelay) _tcpTimeout *= 2;
_tcpTimeout = -_tcpTimeout;
QAbstractSocket::SocketState state = sock.state();
if (state == QAbstractSocket::ConnectedState || state == QAbstractSocket::ConnectingState || state == QAbstractSocket::HostLookupState) {
sock.disconnectFromHost();
} else if (state != QAbstractSocket::ClosingState) {
sock.connectToHost(QHostAddress(_addr), _port);
}
}
}
void MTPautoConnection::onSocketDisconnected() {
if (_tcpTimeout < 0) {
_tcpTimeout = -_tcpTimeout;
if (status == HttpReady || status == WaitingBoth || status == WaitingTcp) {
sock.connectToHost(QHostAddress(_addr), _port);
return;
}
}
if (status == WaitingBoth) {
status = WaitingHttp;
} else if (status == WaitingTcp || status == UsingTcp) {
emit disconnected();
} else if (status == HttpReady) {
DEBUG_LOG(("Connection Info: Http-transport chosen by socket disconnect"));
status = UsingHttp;
emit connected();
}
}
void MTPautoConnection::sendData(mtpBuffer &buffer) {
if (buffer.size() < 3) {
LOG(("TCP Error: writing bad packet, len = %1").arg(buffer.size() * sizeof(mtpPrime)));
TCP_LOG(("TCP Error: bad packet %1").arg(mb(&buffer[0], buffer.size() * sizeof(mtpPrime)).str()));
emit error();
return;
}
if (status == UsingTcp) {
tcpSend(buffer);
} else {
httpSend(buffer);
}
}
void MTPautoConnection::tcpSend(mtpBuffer &buffer) {
uint32 size = buffer.size(), len = size * 4;
buffer[0] = len;
buffer[1] = packetNum++;
buffer[size - 1] = hashCrc32(&buffer[0], len - 4);
TCP_LOG(("TCP Info: write %1 packet %2 bytes").arg(packetNum).arg(len));
sock.write((const char*)&buffer[0], len);
}
void MTPautoConnection::httpSend(mtpBuffer &buffer) {
int32 requestSize = (buffer.size() - 3) * sizeof(mtpPrime);
QNetworkRequest request(address);
request.setHeader(QNetworkRequest::ContentLengthHeader, QVariant(requestSize));
request.setHeader(QNetworkRequest::ContentTypeHeader, QVariant(qsl("application/x-www-form-urlencoded")));
TCP_LOG(("HTTP Info: sending %1 len request").arg(requestSize));
requests.insert(manager.post(request, QByteArray((const char*)(&buffer[2]), requestSize)));
}
void MTPautoConnection::disconnectFromServer() {
Requests copy = requests;
requests.clear();
for (Requests::const_iterator i = copy.cbegin(), e = copy.cend(); i != e; ++i) {
(*i)->abort();
(*i)->deleteLater();
}
disconnect(&manager, SIGNAL(finished(QNetworkReply*)), this, SLOT(requestFinished(QNetworkReply*)));
address = QUrl();
disconnect(&sock, SIGNAL(readyRead()), 0, 0);
sock.close();
httpStartTimer.stop();
status = WaitingBoth;
}
void MTPautoConnection::connectToServer(const QString &addr, int32 port) {
address = QUrl(qsl("http://%1:%2/api").arg(addr).arg(80));//not port - always 80 port for http transport
connect(&manager, SIGNAL(finished(QNetworkReply*)), this, SLOT(requestFinished(QNetworkReply*)));
_addr = addr;
_port = port;
connect(&sock, SIGNAL(readyRead()), this, SLOT(socketRead()));
sock.connectToHost(QHostAddress(_addr), _port);
mtpBuffer buffer(_preparePQFake(httpNonce));
DEBUG_LOG(("Connection Info: sending fake req_pq through http transport"));
httpSend(buffer);
}
bool MTPautoConnection::isConnected() {
return !address.isEmpty();
}
void MTPautoConnection::requestFinished(QNetworkReply *reply) {
reply->deleteLater();
if (reply->error() == QNetworkReply::NoError) {
requests.remove(reply);
mtpBuffer data = _handleHttpResponse(reply);
if (data.size() == 1) {
if (status == WaitingBoth) {
status = WaitingTcp;
} else {
emit error();
}
} else if (!data.isEmpty()) {
if (status == UsingHttp) {
receivedQueue.push_back(data);
emit receivedData();
} else if (status == WaitingBoth || status == WaitingHttp) {
try {
MTPResPQ res_pq = _readPQFakeReply(data);
const MTPDresPQ &res_pq_data(res_pq.c_resPQ());
if (res_pq_data.vnonce == httpNonce) {
if (status == WaitingBoth) {
status = HttpReady;
httpStartTimer.start(MTPTcpConnectionWaitTimeout);
} else {
DEBUG_LOG(("Connection Info: Http-transport chosen by pq-response, awaited"));
status = UsingHttp;
sock.disconnectFromHost();
emit connected();
}
}
} catch (Exception &e) {
if (status == WaitingBoth) {
status = WaitingTcp;
} else {
emit error();
}
}
} else if (status == UsingTcp) {
DEBUG_LOG(("Connection Info: already using tcp, ignoring http response"));
}
}
} else {
if (!requests.remove(reply)) {
return;
}
bool mayBeBadKey = _handleHttpError(reply) && _sentEncrypted;
if (status == WaitingBoth) {
status = WaitingTcp;
} else if (status == WaitingHttp || status == UsingHttp) {
emit error(mayBeBadKey);
} else {
LOG(("Strange Http Error: status %1").arg(status));
}
}
}
void MTPautoConnection::socketPacket(mtpPrime *packet, uint32 size) {
mtpBuffer data = _handleTcpResponse(packet, size);
if (data.size() == 1) {
if (status == WaitingBoth) {
status = WaitingHttp;
sock.disconnectFromHost();
} else if (status == HttpReady) {
DEBUG_LOG(("Connection Info: Http-transport chosen by bad tcp response, ready"));
status = UsingHttp;
sock.disconnectFromHost();
emit connected();
} else if (status == WaitingTcp || status == UsingTcp) {
bool mayBeBadKey = (data[0] == -404) && _sentEncrypted;
emit error(mayBeBadKey);
} else {
LOG(("Strange Tcp Error; status %1").arg(status));
}
} else if (status == UsingTcp) {
receivedQueue.push_back(data);
emit receivedData();
} else if (status == WaitingBoth || status == WaitingTcp || status == HttpReady) {
tcpTimeoutTimer.stop();
try {
MTPResPQ res_pq = _readPQFakeReply(data);
const MTPDresPQ &res_pq_data(res_pq.c_resPQ());
if (res_pq_data.vnonce == tcpNonce) {
DEBUG_LOG(("Connection Info: Tcp-transport chosen by pq-response"));
status = UsingTcp;
emit connected();
}
} catch (Exception &e) {
if (status == WaitingBoth) {
status = WaitingHttp;
sock.disconnectFromHost();
} else if (status == HttpReady) {
DEBUG_LOG(("Connection Info: Http-transport chosen by bad tcp response, awaited"));
status = UsingHttp;
sock.disconnectFromHost();
emit connected();
} else {
emit error();
}
}
}
}
bool MTPautoConnection::needHttpWait() {
return (status == UsingHttp) ? requests.isEmpty() : false;
}
int32 MTPautoConnection::debugState() const {
return (status == UsingHttp) ? -1 : (UsingTcp ? sock.state() : -777);
}
QString MTPautoConnection::transport() const {
if (status == UsingTcp) {
return qsl("TCP");
} else if (status == UsingHttp) {
return qsl("HTTP");
} else {
return QString();
}
}
void MTPautoConnection::socketError(QAbstractSocket::SocketError e) {
_handleTcpError(e, sock);
if (status == WaitingBoth) {
status = WaitingHttp;
} else if (status == HttpReady) {
DEBUG_LOG(("Connection Info: Http-transport chosen by tcp error, ready"));
status = UsingHttp;
emit connected();
} else if (status == WaitingTcp || status == UsingTcp) {
emit error();
} else {
LOG(("Strange Tcp Error: status %1").arg(status));
}
}
MTPtcpConnection::MTPtcpConnection(QThread *thread) {
moveToThread(thread);
sock.moveToThread(thread);
App::setProxySettings(sock);
connect(&sock, SIGNAL(error(QAbstractSocket::SocketError)), this, SLOT(socketError(QAbstractSocket::SocketError)));
connect(&sock, SIGNAL(connected()), this, SIGNAL(connected()));
connect(&sock, SIGNAL(disconnected()), this, SIGNAL(disconnected()));
}
void MTPtcpConnection::sendData(mtpBuffer &buffer) {
if (buffer.size() < 3) {
LOG(("TCP Error: writing bad packet, len = %1").arg(buffer.size() * sizeof(mtpPrime)));
TCP_LOG(("TCP Error: bad packet %1").arg(mb(&buffer[0], buffer.size() * sizeof(mtpPrime)).str()));
emit error();
return;
}
uint32 size = buffer.size(), len = size * 4;
buffer[0] = len;
buffer[1] = packetNum++;
buffer[size - 1] = hashCrc32(&buffer[0], len - 4);
TCP_LOG(("TCP Info: write %1 packet %2 bytes %3").arg(packetNum).arg(len).arg(mb(&buffer[0], len).str()));
sock.write((const char*)&buffer[0], len);
}
void MTPtcpConnection::disconnectFromServer() {
disconnect(&sock, SIGNAL(readyRead()), 0, 0);
sock.close();
}
void MTPtcpConnection::connectToServer(const QString &addr, int32 port) {
connect(&sock, SIGNAL(readyRead()), this, SLOT(socketRead()));
sock.connectToHost(QHostAddress(addr), port);
}
void MTPtcpConnection::socketPacket(mtpPrime *packet, uint32 size) {
mtpBuffer data = _handleTcpResponse(packet, size);
if (data.size() == 1) {
bool mayBeBadKey = (data[0] == -404) && _sentEncrypted;
emit error(mayBeBadKey);
}
receivedQueue.push_back(data);
emit receivedData();
}
bool MTPtcpConnection::isConnected() {
return sock.state() == QAbstractSocket::ConnectedState;
}
int32 MTPtcpConnection::debugState() const {
return sock.state();
}
QString MTPtcpConnection::transport() const {
return qsl("TCP");
}
void MTPtcpConnection::socketError(QAbstractSocket::SocketError e) {
_handleTcpError(e, sock);
emit error();
}
MTPhttpConnection::MTPhttpConnection(QThread *thread) {
moveToThread(thread);
manager.moveToThread(thread);
App::setProxySettings(manager);
}
void MTPhttpConnection::sendData(mtpBuffer &buffer) {
if (buffer.size() < 3) {
LOG(("TCP Error: writing bad packet, len = %1").arg(buffer.size() * sizeof(mtpPrime)));
TCP_LOG(("TCP Error: bad packet %1").arg(mb(&buffer[0], buffer.size() * sizeof(mtpPrime)).str()));
emit error();
return;
}
int32 requestSize = (buffer.size() - 3) * sizeof(mtpPrime);
QNetworkRequest request(address);
request.setHeader(QNetworkRequest::ContentLengthHeader, QVariant(requestSize));
request.setHeader(QNetworkRequest::ContentTypeHeader, QVariant(qsl("application/x-www-form-urlencoded")));
TCP_LOG(("HTTP Info: sending %1 len request %2").arg(requestSize).arg(mb(&buffer[2], requestSize).str()));
requests.insert(manager.post(request, QByteArray((const char*)(&buffer[2]), requestSize)));
}
void MTPhttpConnection::disconnectFromServer() {
Requests copy = requests;
requests.clear();
for (Requests::const_iterator i = copy.cbegin(), e = copy.cend(); i != e; ++i) {
(*i)->abort();
(*i)->deleteLater();
}
disconnect(&manager, SIGNAL(finished(QNetworkReply*)), this, SLOT(requestFinished(QNetworkReply*)));
address = QUrl();
}
void MTPhttpConnection::connectToServer(const QString &addr, int32 p) {
address = QUrl(qsl("http://%1:%2/api").arg(addr).arg(80));//not p - always 80 port for http transport
connect(&manager, SIGNAL(finished(QNetworkReply*)), this, SLOT(requestFinished(QNetworkReply*)));
emit connected();
}
bool MTPhttpConnection::isConnected() {
return !address.isEmpty();
}
void MTPhttpConnection::requestFinished(QNetworkReply *reply) {
reply->deleteLater();
if (reply->error() == QNetworkReply::NoError) {
requests.remove(reply);
mtpBuffer data = _handleHttpResponse(reply);
if (data.size() == 1) {
emit error();
} else if (!data.isEmpty()) {
receivedQueue.push_back(data);
emit receivedData();
}
} else {
if (!requests.remove(reply)) {
return;
}
bool mayBeBadKey = _handleHttpError(reply) && _sentEncrypted;
emit error(mayBeBadKey);
}
}
bool MTPhttpConnection::needHttpWait() {
return requests.isEmpty();
}
int32 MTPhttpConnection::debugState() const {
return -1;
}
QString MTPhttpConnection::transport() const {
return qsl("HTTP");
}
void MTProtoConnectionPrivate::createConn() {
if (conn) {
conn->deleteLater();
}
if (cConnectionType() == dbictAuto) {
conn = new MTPautoConnection(thread());
} else if (cConnectionType() == dbictTcpProxy) {
conn = new MTPtcpConnection(thread());
} else {
conn = new MTPhttpConnection(thread());
}
connect(conn, SIGNAL(error(bool)), this, SLOT(onError(bool)));
connect(conn, SIGNAL(receivedSome()), this, SLOT(onReceivedSome()));
firstSentAt = 0;
if (oldConnection) {
oldConnection = false;
DEBUG_LOG(("This connection marked as not old!"));
}
oldConnectionTimer.start(MTPConnectionOldTimeout);
}
MTProtoConnectionPrivate::MTProtoConnectionPrivate(QThread *thread, MTProtoConnection *owner, MTPSessionData *data, uint32 _dc)
: QObject(0)
, _state(MTProtoConnection::Disconnected)
, _needSessionReset(false)
, dc(_dc)
, _owner(owner)
, conn(0)
, retryTimeout(1)
, oldConnection(true)
, receiveDelay(MTPMinReceiveDelay)
, firstSentAt(-1)
, pingId(0)
, toSendPingId(0)
, pingMsgId(0)
, restarted(false)
, keyId(0)
, sessionData(data)
, myKeyLock(false)
, authKeyData(0)
, authKeyStrings(0) {
oldConnectionTimer.moveToThread(thread);
connCheckTimer.moveToThread(thread);
retryTimer.moveToThread(thread);
moveToThread(thread);
// createConn();
if (!dc) {
const mtpDcOptions &gDcOptions(mtpDCOptions());
if (!gDcOptions.size()) {
LOG(("MTP Error: connect failed, no DCs"));
dc = 0;
return;
}
dc = gDcOptions.cbegin().value().id;
DEBUG_LOG(("MTP Info: searching for any DC, %1 selected..").arg(dc));
}
connect(thread, SIGNAL(started()), this, SLOT(socketStart()));
connect(thread, SIGNAL(finished()), this, SLOT(doFinish()));
connect(&retryTimer, SIGNAL(timeout()), this, SLOT(retryByTimer()));
connect(&connCheckTimer, SIGNAL(timeout()), this, SLOT(onBadConnection()));
connect(&oldConnectionTimer, SIGNAL(timeout()), this, SLOT(onOldConnection()));
connect(sessionData->owner(), SIGNAL(authKeyCreated()), this, SLOT(updateAuthKey()), Qt::QueuedConnection);
connect(sessionData->owner(), SIGNAL(needToRestart()), this, SLOT(restartNow()), Qt::QueuedConnection);
connect(this, SIGNAL(needToReceive()), sessionData->owner(), SLOT(tryToReceive()), Qt::QueuedConnection);
connect(this, SIGNAL(stateChanged(qint32)), sessionData->owner(), SLOT(onConnectionStateChange(qint32)), Qt::QueuedConnection);
connect(sessionData->owner(), SIGNAL(needToSend()), this, SLOT(tryToSend()), Qt::QueuedConnection);
connect(this, SIGNAL(sessionResetDone()), sessionData->owner(), SLOT(onResetDone()), Qt::QueuedConnection);
static bool _registered = false;
if (!_registered) {
_registered = true;
qRegisterMetaType<QVector<quint64> >("QVector<quint64>");
}
connect(this, SIGNAL(needToSendAsync()), sessionData->owner(), SIGNAL(needToSend()), Qt::QueuedConnection);
connect(this, SIGNAL(sendAnythingAsync(quint64)), sessionData->owner(), SLOT(sendAnything(quint64)), Qt::QueuedConnection);
connect(this, SIGNAL(sendHttpWaitAsync()), sessionData->owner(), SLOT(sendHttpWait()), Qt::QueuedConnection);
connect(this, SIGNAL(sendPongAsync(quint64,quint64)), sessionData->owner(), SLOT(sendPong(quint64,quint64)), Qt::QueuedConnection);
connect(this, SIGNAL(sendMsgsStateInfoAsync(quint64, QByteArray)), sessionData->owner(), SLOT(sendMsgsStateInfo(quint64,QByteArray)), Qt::QueuedConnection);
connect(this, SIGNAL(resendAsync(quint64,quint64,bool,bool)), sessionData->owner(), SLOT(resend(quint64,quint64,bool,bool)), Qt::QueuedConnection);
connect(this, SIGNAL(resendManyAsync(QVector<quint64>,quint64,bool,bool)), sessionData->owner(), SLOT(resendMany(QVector<quint64>,quint64,bool,bool)), Qt::QueuedConnection);
connect(this, SIGNAL(resendAllAsync()), sessionData->owner(), SLOT(resendAll()));
}
void MTProtoConnectionPrivate::onConfigLoaded() {
socketStart(true);
}
int32 MTProtoConnectionPrivate::getDC() const {
return dc;
}
int32 MTProtoConnectionPrivate::getState() const {
QReadLocker lock(&stateMutex);
int32 result = _state;
if (_state < 0) {
if (retryTimer.isActive()) {
result = int32(getms(true) - retryWillFinish);
if (result >= 0) {
result = -1;
}
}
}
return result;
}
QString MTProtoConnectionPrivate::transport() const {
if (!conn || _state < 0) {
return QString();
}
return conn->transport();
}
bool MTProtoConnectionPrivate::setState(int32 state, int32 ifState) {
if (ifState != MTProtoConnection::UpdateAlways) {
QReadLocker lock(&stateMutex);
if (_state != ifState) return false;
}
QWriteLocker lock(&stateMutex);
if (_state == state) return false;
_state = state;
if (state < 0) {
retryTimeout = -state;
retryTimer.start(retryTimeout);
retryWillFinish = getms(true) + retryTimeout;
}
emit stateChanged(state);
return true;
}
void MTProtoConnectionPrivate::resetSession() { // recreate all msg_id and msg_seqno
_needSessionReset = false;
QWriteLocker locker1(sessionData->haveSentMutex());
QWriteLocker locker2(sessionData->toResendMutex());
QWriteLocker locker3(sessionData->toSendMutex());
QWriteLocker locker4(sessionData->wereAckedMutex());
mtpRequestMap &haveSent(sessionData->haveSentMap());
mtpRequestIdsMap &toResend(sessionData->toResendMap());
mtpPreRequestMap &toSend(sessionData->toSendMap());
mtpRequestIdsMap &wereAcked(sessionData->wereAckedMap());
mtpMsgId newId = msgid();
mtpRequestMap setSeqNumbers;
typedef QMap<mtpMsgId, mtpMsgId> Replaces;
Replaces replaces;
for (mtpRequestMap::const_iterator i = haveSent.cbegin(), e = haveSent.cend(); i != e; ++i) {
if (!mtpRequestData::isSentContainer(i.value())) {
if (!*(mtpMsgId*)(i.value()->constData() + 4)) continue;
mtpMsgId id = i.key();
if (id > newId) {
while (true) {
if (toResend.constFind(newId) == toResend.cend() && wereAcked.constFind(newId) == wereAcked.cend() && haveSent.constFind(newId) == haveSent.cend()) {
break;
}
mtpMsgId m = msgid();
if (m <= newId) break; // wtf
newId = m;
}
MTP_LOG(dc, ("Replacing msgId %1 to %2!").arg(id).arg(newId));
replaces.insert(id, newId);
id = newId;
*(mtpMsgId*)(i.value()->data() + 4) = id;
}
setSeqNumbers.insert(id, i.value());
}
}
for (mtpRequestIdsMap::const_iterator i = toResend.cbegin(), e = toResend.cend(); i != e; ++i) { // collect all non-container requests
mtpPreRequestMap::const_iterator j = toSend.constFind(i.value());
if (j == toSend.cend()) continue;
if (!mtpRequestData::isSentContainer(j.value())) {
if (!*(mtpMsgId*)(j.value()->constData() + 4)) continue;
mtpMsgId id = i.key();
if (id > newId) {
while (true) {
if (toResend.constFind(newId) == toResend.cend() && wereAcked.constFind(newId) == wereAcked.cend() && haveSent.constFind(newId) == haveSent.cend()) {
break;
}
mtpMsgId m = msgid();
if (m <= newId) break; // wtf
newId = m;
}
MTP_LOG(dc, ("Replacing msgId %1 to %2!").arg(id).arg(newId));
replaces.insert(id, newId);
id = newId;
*(mtpMsgId*)(j.value()->data() + 4) = id;
}
setSeqNumbers.insert(id, j.value());
}
}
uint64 session = MTP::nonce<uint64>();
DEBUG_LOG(("MTP Info: creating new session after bad_msg_notification, setting random server_session %1").arg(session));
sessionData->setSession(session);
for (mtpRequestMap::const_iterator i = setSeqNumbers.cbegin(), e = setSeqNumbers.cend(); i != e; ++i) { // generate new seq_numbers
bool wasNeedAck = (*(i.value()->data() + 6) & 1);
*(i.value()->data() + 6) = sessionData->nextRequestSeqNumber(wasNeedAck);
}
if (!replaces.isEmpty()) {
for (Replaces::const_iterator i = replaces.cbegin(), e = replaces.cend(); i != e; ++i) { // replace msgIds keys in all data structs
mtpRequestMap::iterator j = haveSent.find(i.key());
if (j != haveSent.cend()) {
mtpRequest req = j.value();
haveSent.erase(j);
haveSent.insert(i.value(), req);
}
mtpRequestIdsMap::iterator k = toResend.find(i.key());
if (k != toResend.cend()) {
mtpRequestId req = k.value();
toResend.erase(k);
toResend.insert(i.value(), req);
}
k = wereAcked.find(i.key());
if (k != wereAcked.cend()) {
mtpRequestId req = k.value();
wereAcked.erase(k);
wereAcked.insert(i.value(), req);
}
}
for (mtpRequestMap::const_iterator i = haveSent.cbegin(), e = haveSent.cend(); i != e; ++i) { // replace msgIds in saved containers
if (mtpRequestData::isSentContainer(i.value())) {
mtpMsgId *ids = (mtpMsgId *)(i.value()->data() + 8);
for (uint32 j = 0, l = (i.value()->size() - 8) >> 1; j < l; ++j) {
Replaces::const_iterator k = replaces.constFind(ids[j]);
if (k != replaces.cend()) {
ids[j] = k.value();
}
}
}
}
}
ackRequestData.clear();
resendRequestData.clear();
{
QWriteLocker locker5(sessionData->stateRequestMutex());
sessionData->stateRequestMap().clear();
}
emit sessionResetDone();
}
mtpMsgId MTProtoConnectionPrivate::prepareToSend(mtpRequest &request, mtpMsgId currentLastId) {
if (request->size() < 9) return 0;
mtpMsgId msgId = *(mtpMsgId*)(request->constData() + 4);
if (msgId) { // resending this request
QWriteLocker locker(sessionData->toResendMutex());
mtpRequestIdsMap &toResend(sessionData->toResendMap());
mtpRequestIdsMap::iterator i = toResend.find(msgId);
if (i != toResend.cend()) {
toResend.erase(i);
}
} else {
msgId = *(mtpMsgId*)(request->data() + 4) = currentLastId;
*(request->data() + 6) = sessionData->nextRequestSeqNumber(mtpRequestData::needAck(request));
}
return msgId;
}
mtpMsgId MTProtoConnectionPrivate::replaceMsgId(mtpRequest &request, mtpMsgId newId) {
if (request->size() < 9) return 0;
mtpMsgId oldMsgId = *(mtpMsgId*)(request->constData() + 4);
if (oldMsgId != newId) {
if (oldMsgId) {
QWriteLocker locker(sessionData->toResendMutex());
// haveSentMutex() and wereAckedMutex() were locked in tryToSend()
mtpRequestIdsMap &toResend(sessionData->toResendMap());
mtpRequestIdsMap &wereAcked(sessionData->wereAckedMap());
mtpRequestMap &haveSent(sessionData->haveSentMap());
while (true) {
if (toResend.constFind(newId) == toResend.cend() && wereAcked.constFind(newId) == wereAcked.cend() && haveSent.constFind(newId) == haveSent.cend()) {
break;
}
mtpMsgId m = msgid();
if (m <= newId) break; // wtf
newId = m;
}
mtpRequestIdsMap::iterator i = toResend.find(oldMsgId);
if (i != toResend.cend()) {
mtpRequestId req = i.value();
toResend.erase(i);
toResend.insert(newId, req);
}
mtpRequestIdsMap::iterator j = wereAcked.find(oldMsgId);
if (j != wereAcked.cend()) {
mtpRequestId req = j.value();
wereAcked.erase(j);
wereAcked.insert(newId, req);
}
mtpRequestMap::iterator k = haveSent.find(oldMsgId);
if (k != haveSent.cend()) {
mtpRequest req = k.value();
haveSent.erase(k);
haveSent.insert(newId, req);
}
for (k = haveSent.begin(); k != haveSent.cend(); ++k) {
mtpRequest req(k.value());
if (mtpRequestData::isSentContainer(req)) {
mtpMsgId *ids = (mtpMsgId *)(req->data() + 8);
for (uint32 i = 0, l = (req->size() - 8) >> 1; i < l; ++i) {
if (ids[i] == oldMsgId) {
ids[i] = newId;
}
}
}
}
} else {
*(request->data() + 6) = sessionData->nextRequestSeqNumber(mtpRequestData::needAck(request));
}
*(mtpMsgId*)(request->data() + 4) = newId;
}
return newId;
}
mtpMsgId MTProtoConnectionPrivate::placeToContainer(mtpRequest &toSendRequest, mtpMsgId &bigMsgId, mtpMsgId *&haveSentArr, mtpRequest &req) {
mtpMsgId msgId = prepareToSend(req, bigMsgId);
if (msgId > bigMsgId) msgId = replaceMsgId(req, bigMsgId);
if (msgId >= bigMsgId) bigMsgId = msgid();
*(haveSentArr++) = msgId;
uint32 from = toSendRequest->size(), len = mtpRequestData::messageSize(req);
toSendRequest->resize(from + len);
memcpy(toSendRequest->data() + from, req->constData() + 4, len * sizeof(mtpPrime));
return msgId;
}
void MTProtoConnectionPrivate::tryToSend() {
QReadLocker lockFinished(&sessionDataMutex);
if (!sessionData || !conn) {
return;
}
bool needsLayer = !sessionData->layerWasInited();
bool prependOnly = false;
mtpRequest pingRequest;
if (toSendPingId) {
MTPPing ping(MTPping(MTP_long(toSendPingId)));
prependOnly = (getState() != MTProtoConnection::Connected);
DEBUG_LOG(("MTP Info: sending ping, ping_id: %1, prepend_only: %2").arg(ping.vping_id.v).arg(prependOnly ? "[TRUE]" : "[FALSE]"));
uint32 pingSize = ping.innerLength() >> 2; // copy from MTProtoSession::send
pingRequest = mtpRequestData::prepare(pingSize);
ping.write(*pingRequest);
pingRequest->msDate = getms(true); // > 0 - can send without container
pingRequest->requestId = 0; // dont add to haveSent / wereAcked maps
pingId = toSendPingId;
toSendPingId = 0;
} else {
int32 st = getState();
DEBUG_LOG(("MTP Info: dc %1 trying to send after ping, state: %2").arg(dc).arg(st));
if (st != MTProtoConnection::Connected) {
return; // just do nothing, if is not connected yet
}
}
mtpRequest ackRequest, resendRequest, stateRequest;
if (!prependOnly && !ackRequestData.isEmpty()) {
MTPMsgsAck ack(MTP_msgs_ack(MTP_vector<MTPlong>(ackRequestData)));
ackRequest = mtpRequestData::prepare(ack.innerLength() >> 2);
ack.write(*ackRequest);
ackRequest->msDate = getms(true); // > 0 - can send without container
ackRequest->requestId = 0; // dont add to haveSent / wereAcked maps
ackRequestData.clear();
}
if (!prependOnly && !resendRequestData.isEmpty()) {
MTPMsgResendReq resend(MTP_msg_resend_req(MTP_vector<MTPlong>(resendRequestData)));
resendRequest = mtpRequestData::prepare(resend.innerLength() >> 2);
resend.write(*resendRequest);
resendRequest->msDate = getms(true); // > 0 - can send without container
resendRequest->requestId = 0; // dont add to haveSent / wereAcked maps
resendRequestData.clear();
}
if (!prependOnly) {
QVector<MTPlong> stateReq;
{
QWriteLocker locker(sessionData->stateRequestMutex());
mtpMsgIdsSet &ids(sessionData->stateRequestMap());
if (!ids.isEmpty()) {
stateReq.reserve(ids.size());
for (mtpMsgIdsSet::const_iterator i = ids.cbegin(), e = ids.cend(); i != e; ++i) {
stateReq.push_back(MTP_long(i.key()));
}
}
ids.clear();
}
if (!stateReq.isEmpty()) {
MTPMsgsStateReq req(MTP_msgs_state_req(MTP_vector<MTPlong>(stateReq)));
stateRequest = mtpRequestData::prepare(req.innerLength() >> 2);
req.write(*stateRequest);
stateRequest->msDate = getms(true); // > 0 - can send without container
stateRequest->requestId = reqid();// add to haveSent / wereAcked maps, but don't add to requestMap
}
}
MTPInitConnection<mtpRequest> initWrapperImpl, *initWrapper = &initWrapperImpl;
int32 initSize = 0, initSizeInInts = 0;
if (needsLayer) {
initWrapperImpl = MTPInitConnection<mtpRequest>(MTP_int(ApiId), MTP_string(cApiDeviceModel()), MTP_string(cApiSystemVersion()), MTP_string(cApiAppVersion()), MTP_string(ApiLang), mtpRequest());
initSizeInInts = (initWrapper->innerLength() >> 2) + 2;
initSize = initSizeInInts * sizeof(mtpPrime);
}
bool needAnyResponse = false;
mtpRequest toSendRequest;
{
QWriteLocker locker1(sessionData->toSendMutex());
mtpPreRequestMap toSendDummy, &toSend(prependOnly ? toSendDummy : sessionData->toSendMap());
if (prependOnly) locker1.unlock();
uint32 toSendCount = toSend.size();
if (pingRequest) ++toSendCount;
if (ackRequest) ++toSendCount;
if (resendRequest) ++toSendCount;
if (stateRequest) ++toSendCount;
if (!toSendCount) return; // nothing to send
mtpRequest first = pingRequest ? pingRequest : (ackRequest ? ackRequest : (resendRequest ? resendRequest : (stateRequest ? stateRequest : toSend.cbegin().value())));
if (toSendCount == 1 && first->msDate > 0) { // if can send without container
toSendRequest = first;
if (!prependOnly) {
toSend.clear();
locker1.unlock();
}
mtpMsgId msgId = prepareToSend(toSendRequest, msgid());
if (pingRequest) {
pingMsgId = msgId;
needAnyResponse = true;
} else if (resendRequest || stateRequest) {
needAnyResponse = true;
}
if (toSendRequest->requestId) {
if (mtpRequestData::needAck(toSendRequest)) {
toSendRequest->msDate = mtpRequestData::isStateRequest(toSendRequest) ? 0 : getms(true);
QWriteLocker locker2(sessionData->haveSentMutex());
mtpRequestMap &haveSent(sessionData->haveSentMap());
haveSent.insert(msgId, toSendRequest);
if (needsLayer && !toSendRequest->needsLayer) needsLayer = false;
if (toSendRequest->after) {
int32 toSendSize = toSendRequest.innerLength() >> 2;
mtpRequest wrappedRequest(mtpRequestData::prepare(toSendSize, toSendSize + 3)); // cons + msg_id
wrappedRequest->resize(4);
memcpy(wrappedRequest->data(), toSendRequest->constData(), 4 * sizeof(mtpPrime));
_mtp_internal::wrapInvokeAfter(wrappedRequest, toSendRequest, haveSent);
toSendRequest = wrappedRequest;
}
if (needsLayer) {
int32 noWrapSize = (toSendRequest.innerLength() >> 2), toSendSize = noWrapSize + initSizeInInts;
mtpRequest wrappedRequest(mtpRequestData::prepare(toSendSize));
memcpy(wrappedRequest->data(), toSendRequest->constData(), 7 * sizeof(mtpPrime)); // all except length
wrappedRequest->push_back(mtpc_invokeWithLayer);
wrappedRequest->push_back(mtpCurrentLayer);
initWrapper->write(*wrappedRequest);
wrappedRequest->resize(wrappedRequest->size() + noWrapSize);
memcpy(wrappedRequest->data() + wrappedRequest->size() - noWrapSize, toSendRequest->constData() + 8, noWrapSize * sizeof(mtpPrime));
toSendRequest = wrappedRequest;
}
needAnyResponse = true;
} else {
QWriteLocker locker3(sessionData->wereAckedMutex());
sessionData->wereAckedMap().insert(msgId, toSendRequest->requestId);
}
}
} else { // send in container
bool willNeedInit = false;
uint32 containerSize = 1 + 1, idsWrapSize = (toSendCount << 1); // cons + vector size, idsWrapSize - size of "request-like" wrap for msgId vector
if (pingRequest) containerSize += mtpRequestData::messageSize(pingRequest);
if (ackRequest) containerSize += mtpRequestData::messageSize(ackRequest);
if (resendRequest) containerSize += mtpRequestData::messageSize(resendRequest);
if (stateRequest) containerSize += mtpRequestData::messageSize(stateRequest);
for (mtpPreRequestMap::iterator i = toSend.begin(), e = toSend.end(); i != e; ++i) {
containerSize += mtpRequestData::messageSize(i.value());
if (needsLayer && i.value()->needsLayer) {
containerSize += initSizeInInts;
willNeedInit = true;
}
}
mtpBuffer initSerialized;
if (willNeedInit) {
initSerialized.reserve(initSizeInInts);
initSerialized.push_back(mtpc_invokeWithLayer);
initSerialized.push_back(mtpCurrentLayer);
initWrapper->write(initSerialized);
}
toSendRequest = mtpRequestData::prepare(containerSize, containerSize + 3 * toSend.size()); // prepare container + each in invoke after
toSendRequest->push_back(mtpc_msg_container);
toSendRequest->push_back(toSendCount);
mtpMsgId bigMsgId = msgid(); // check for a valid container
QWriteLocker locker2(sessionData->haveSentMutex()); // the fact of this lock is used in replaceMsgId()
mtpRequestMap &haveSent(sessionData->haveSentMap());
QWriteLocker locker3(sessionData->wereAckedMutex()); // the fact of this lock is used in replaceMsgId()
mtpRequestIdsMap &wereAcked(sessionData->wereAckedMap());
mtpRequest haveSentIdsWrap(mtpRequestData::prepare(idsWrapSize)); // prepare "request-like" wrap for msgId vector
haveSentIdsWrap->requestId = 0;
haveSentIdsWrap->resize(haveSentIdsWrap->size() + idsWrapSize);
mtpMsgId *haveSentArr = (mtpMsgId*)(haveSentIdsWrap->data() + 8);
if (pingRequest) {
pingMsgId = placeToContainer(toSendRequest, bigMsgId, haveSentArr, pingRequest);
needAnyResponse = true;
} else if (resendRequest || stateRequest) {
needAnyResponse = true;
}
for (mtpPreRequestMap::iterator i = toSend.begin(), e = toSend.end(); i != e; ++i) {
mtpRequest &req(i.value());
mtpMsgId msgId = prepareToSend(req, bigMsgId);
if (msgId > bigMsgId) msgId = replaceMsgId(req, bigMsgId);
if (msgId >= bigMsgId) bigMsgId = msgid();
*(haveSentArr++) = msgId;
bool added = false;
if (req->requestId) {
if (mtpRequestData::needAck(req)) {
req->msDate = mtpRequestData::isStateRequest(req) ? 0 : getms(true);
int32 reqNeedsLayer = (needsLayer && req->needsLayer) ? toSendRequest->size() : 0;
if (req->after) {
_mtp_internal::wrapInvokeAfter(toSendRequest, req, haveSent, reqNeedsLayer ? initSizeInInts : 0);
if (reqNeedsLayer) {
memcpy(toSendRequest->data() + reqNeedsLayer + 4, initSerialized.constData(), initSize);
*(toSendRequest->data() + reqNeedsLayer + 3) += initSize;
}
added = true;
} else if (reqNeedsLayer) {
toSendRequest->resize(reqNeedsLayer + initSizeInInts + mtpRequestData::messageSize(req));
memcpy(toSendRequest->data() + reqNeedsLayer, req->constData() + 4, 4 * sizeof(mtpPrime));
memcpy(toSendRequest->data() + reqNeedsLayer + 4, initSerialized.constData(), initSize);
memcpy(toSendRequest->data() + reqNeedsLayer + 4 + initSizeInInts, req->constData() + 8, req.innerLength());
*(toSendRequest->data() + reqNeedsLayer + 3) += initSize;
added = true;
}
haveSent.insert(msgId, req);
needAnyResponse = true;
} else {
wereAcked.insert(msgId, req->requestId);
}
}
if (!added) {
uint32 from = toSendRequest->size(), len = mtpRequestData::messageSize(req);
toSendRequest->resize(from + len);
memcpy(toSendRequest->data() + from, req->constData() + 4, len * sizeof(mtpPrime));
}
}
if (stateRequest) {
mtpMsgId msgId = placeToContainer(toSendRequest, bigMsgId, haveSentArr, stateRequest);
stateRequest->msDate = 0; // 0 for state request, do not request state of it
haveSent.insert(msgId, stateRequest);
}
if (resendRequest) placeToContainer(toSendRequest, bigMsgId, haveSentArr, resendRequest);
if (ackRequest) placeToContainer(toSendRequest, bigMsgId, haveSentArr, ackRequest);
mtpMsgId contMsgId = prepareToSend(toSendRequest, bigMsgId);
*(mtpMsgId*)(haveSentIdsWrap->data() + 4) = contMsgId;
(*haveSentIdsWrap)[6] = 0; // for container, msDate = 0, seqNo = 0
haveSent.insert(contMsgId, haveSentIdsWrap);
toSend.clear();
}
}
mtpRequestData::padding(toSendRequest);
sendRequest(toSendRequest, needAnyResponse);
}
void MTProtoConnectionPrivate::retryByTimer() {
QReadLocker lockFinished(&sessionDataMutex);
if (!sessionData) return;
if (retryTimeout < 3) {
++retryTimeout;
} else if (retryTimeout == 3) {
retryTimeout = 1000;
} else if (retryTimeout < 64000) {
retryTimeout *= 2;
}
if (keyId == mtpAuthKey::RecreateKeyId) {
if (sessionData->getKey()) {
QWriteLocker lock(sessionData->keyMutex());
sessionData->owner()->destroyKey();
}
keyId = 0;
}
socketStart();
}
void MTProtoConnectionPrivate::restartNow() {
retryTimeout = 1;
retryTimer.stop();
restart();
}
void MTProtoConnectionPrivate::socketStart(bool afterConfig) {
if (!conn) createConn();
if (conn->isConnected()) {
onConnected();
return;
}
setState(MTProtoConnection::Connecting);
pingId = pingMsgId = toSendPingId = 0;
const mtpDcOption *dcOption = 0;
const mtpDcOptions &gDcOptions(mtpDCOptions());
mtpDcOptions::const_iterator dcIndex = gDcOptions.constFind(dc % _mtp_internal::dcShift);
DEBUG_LOG(("MTP Info: connecting to DC %1..").arg(dc));
if (dcIndex == gDcOptions.cend()) {
if (afterConfig) {
LOG(("MTP Error: DC %1 options not found right after config load!").arg(dc));
return restart();
} else {
DEBUG_LOG(("MTP Info: DC %1 options not found, waiting for config").arg(dc));
connect(mtpConfigLoader(), SIGNAL(loaded()), this, SLOT(onConfigLoaded()));
mtpConfigLoader()->load();
return;
}
}
dcOption = &dcIndex.value();
const char *ip(dcOption->ip.c_str());
uint32 port(dcOption->port);
DEBUG_LOG(("MTP Info: socket connection to %1:%2..").arg(ip).arg(port));
connect(conn, SIGNAL(connected()), this, SLOT(onConnected()));
connect(conn, SIGNAL(disconnected()), this, SLOT(restart()));
conn->connectToServer(ip, port);
}
void MTProtoConnectionPrivate::restart(bool maybeBadKey) {
QReadLocker lockFinished(&sessionDataMutex);
if (!sessionData) return;
DEBUG_LOG(("MTP Info: restarting MTProtoConnection, maybe bad key = %1").arg(logBool(maybeBadKey)));
connCheckTimer.stop();
mtpAuthKeyPtr key(sessionData->getKey());
if (key) {
if (!sessionData->isCheckedKey()) {
if (maybeBadKey) {
clearMessages();
keyId = mtpAuthKey::RecreateKeyId;
// retryTimeout = 1; // no ddos please
LOG(("MTP Info: key may be bad and was not checked - will be destroyed"));
}
} else {
sessionData->setCheckedKey(false);
}
}
doDisconnect();
if (_needSessionReset) {
resetSession();
}
restarted = true;
if (retryTimer.isActive()) return;
DEBUG_LOG(("MTP Info: restart timeout: %1ms").arg(retryTimeout));
setState(-retryTimeout);
}
void MTProtoConnectionPrivate::onSentSome(uint64 size) {
if (!connCheckTimer.isActive()) {
uint64 remain = receiveDelay;
if (!oldConnection) {
uint64 remainBySize = size * receiveDelay / 8192; // 8kb / sec, so 512 kb give 64 sec
remain = snap(remainBySize, remain, uint64(MTPMaxReceiveDelay));
if (remain != receiveDelay) {
DEBUG_LOG(("Checking connect for request with size %1 bytes, delay will be %2").arg(size).arg(remain));
}
}
if (dc >= MTP::upl[0] && dc < MTP::upl[MTPUploadSessionsCount - 1] + _mtp_internal::dcShift) {
remain *= MTPUploadSessionsCount;
} else if (dc >= MTP::dld[0] && dc < MTP::dld[MTPDownloadSessionsCount - 1] + _mtp_internal::dcShift) {
remain *= MTPDownloadSessionsCount;
}
connCheckTimer.start(remain);
}
if (!firstSentAt) firstSentAt = getms(true);
}
void MTProtoConnectionPrivate::onReceivedSome() {
if (oldConnection) {
oldConnection = false;
DEBUG_LOG(("This connection marked as not old!"));
}
oldConnectionTimer.start(MTPConnectionOldTimeout);
connCheckTimer.stop();
if (firstSentAt > 0) {
int32 ms = getms(true) - firstSentAt;
DEBUG_LOG(("MTP Info: response in %1ms, receiveDelay: %2ms").arg(ms).arg(receiveDelay));
if (ms > 0 && ms * 2 < int32(receiveDelay)) receiveDelay = qMax(ms * 2, int32(MTPMinReceiveDelay));
firstSentAt = -1;
}
}
void MTProtoConnectionPrivate::onOldConnection() {
oldConnection = true;
receiveDelay = MTPMinReceiveDelay;
DEBUG_LOG(("This connection marked as old! delay now %1ms").arg(receiveDelay));
}
void MTProtoConnectionPrivate::onBadConnection() {
if (cConnectionType() != dbictAuto && cConnectionType() != dbictTcpProxy) {
return;
}
DEBUG_LOG(("MTP Info: bad connection, delay: %1ms").arg(receiveDelay));
if (receiveDelay < MTPMaxReceiveDelay) {
receiveDelay *= 2;
}
doDisconnect();
restarted = true;
if (retryTimer.isActive()) return;
DEBUG_LOG(("MTP Info: immediate restart!"));
QTimer::singleShot(0, this, SLOT(socketStart()));
}
void MTProtoConnectionPrivate::doDisconnect() {
if (conn) {
disconnect(conn, SIGNAL(disconnected()), 0, 0);
disconnect(conn, SIGNAL(receivedData()), 0, 0);
disconnect(conn, SIGNAL(receivedSome()), 0, 0);
conn->disconnectFromServer();
conn->deleteLater();
conn = 0;
}
unlockKey();
clearAuthKeyData();
setState(MTProtoConnection::Disconnected);
restarted = false;
}
void MTProtoConnectionPrivate::doFinish() {
doDisconnect();
_owner->stopped();
}
void MTProtoConnectionPrivate::handleReceived() {
QReadLocker lockFinished(&sessionDataMutex);
if (!sessionData) return;
onReceivedSome();
ReadLockerAttempt lock(sessionData->keyMutex());
if (!lock) {
DEBUG_LOG(("MTP Error: auth_key for dc %1 busy, cant lock").arg(dc));
clearMessages();
keyId = 0;
return restart();
}
mtpAuthKeyPtr key(sessionData->getKey());
if (!key || key->keyId() != keyId) {
DEBUG_LOG(("MTP Error: auth_key id for dc %1 changed").arg(dc));
return restart();
}
while (conn->received().size()) {
const mtpBuffer &encryptedBuf(conn->received().front());
uint32 len = encryptedBuf.size();
const mtpPrime *encrypted(encryptedBuf.data());
if (len < 18) { // 2 auth_key_id, 4 msg_key, 2 salt, 2 session, 2 msg_id, 1 seq_no, 1 length, (1 data + 3 padding) min
LOG(("TCP Error: bad message received, len %1").arg(len * sizeof(mtpPrime)));
TCP_LOG(("TCP Error: bad message %1").arg(mb(encrypted, len * sizeof(mtpPrime)).str()));
return restart();
}
if (keyId != *(uint64*)encrypted) {
LOG(("TCP Error: bad auth_key_id %1 instead of %2 received").arg(keyId).arg(*(uint64*)encrypted));
TCP_LOG(("TCP Error: bad message %1").arg(mb(encrypted, len * sizeof(mtpPrime)).str()));
return restart();
}
QByteArray dataBuffer((len - 6) * sizeof(mtpPrime), Qt::Uninitialized);
mtpPrime *data((mtpPrime*)dataBuffer.data()), *msg = data + 8;
const mtpPrime *from(msg), *end;
MTPint128 msgKey(*(MTPint128*)(encrypted + 2));
aesDecrypt(encrypted + 6, data, dataBuffer.size(), key, msgKey);
uint64 serverSalt = *(uint64*)&data[0], session = *(uint64*)&data[2], msgId = *(uint64*)&data[4];
uint32 seqNo = *(uint32*)&data[6], msgLen = *(uint32*)&data[7];
bool needAck = (seqNo & 0x01);
if (uint32(dataBuffer.size()) < msgLen + 8 * sizeof(mtpPrime) || (msgLen & 0x03)) {
LOG(("TCP Error: bad msg_len received %1, data size: %2").arg(msgLen).arg(dataBuffer.size()));
TCP_LOG(("TCP Error: bad message %1").arg(mb(encrypted, len * sizeof(mtpPrime)).str()));
conn->received().pop_front();
return restart();
}
uchar sha1Buffer[20];
if (memcmp(&msgKey, hashSha1(data, msgLen + 8 * sizeof(mtpPrime), sha1Buffer) + 1, sizeof(msgKey))) {
LOG(("TCP Error: bad SHA1 hash after aesDecrypt in message"));
TCP_LOG(("TCP Error: bad message %1").arg(mb(encrypted, len * sizeof(mtpPrime)).str()));
conn->received().pop_front();
return restart();
}
TCP_LOG(("TCP Info: decrypted message %1,%2,%3 is %4 len").arg(msgId).arg(seqNo).arg(logBool(needAck)).arg(msgLen + 8 * sizeof(mtpPrime)));
uint64 serverSession = sessionData->getSession();
if (session != serverSession) {
LOG(("MTP Error: bad server session received"));
TCP_LOG(("MTP Error: bad server session %1 instead of %2 in message received").arg(session).arg(serverSession));
conn->received().pop_front();
return restart();
}
conn->received().pop_front();
int32 serverTime((int32)(msgId >> 32)), clientTime(unixtime());
bool isReply = ((msgId & 0x03) == 1);
if (!isReply && ((msgId & 0x03) != 3)) {
LOG(("MTP Error: bad msg_id %1 in message received").arg(msgId));
return restart();
}
bool badTime = false;
uint64 mySalt = sessionData->getSalt();
if (serverTime > clientTime + 60 || serverTime + 300 < clientTime) {
DEBUG_LOG(("MTP Info: bad server time from msg_id: %1, my time: %2").arg(serverTime).arg(clientTime));
badTime = true;
}
bool wasConnected = (getState() == MTProtoConnection::Connected);
if (serverSalt != mySalt) {
if (!badTime) {
DEBUG_LOG(("MTP Info: other salt received.. received: %1, my salt: %2, updating..").arg(serverSalt).arg(mySalt));
sessionData->setSalt(serverSalt);
if (setState(MTProtoConnection::Connected, MTProtoConnection::Connecting)) { // only connected
if (restarted) {
emit resendAllAsync();
restarted = false;
}
}
} else {
DEBUG_LOG(("MTP Info: other salt received.. received: %1, my salt: %2").arg(serverSalt).arg(mySalt));
}
} else {
serverSalt = 0; // dont pass to handle method, so not to lock in setSalt()
}
if (needAck) ackRequestData.push_back(MTP_long(msgId));
int32 res = 1; // if no need to handle, then succeed
end = data + 8 + (msgLen >> 2);
const mtpPrime *sfrom(data + 4);
MTP_LOG(dc, ("Recv: ") + mtpTextSerialize(sfrom, end));
bool needToHandle = false;
{
QWriteLocker lock(sessionData->receivedIdsMutex());
mtpMsgIdsMap &receivedIds(sessionData->receivedIdsSet());
needToHandle = receivedIds.insert(msgId, needAck);
}
if (needToHandle) {
res = handleOneReceived(from, end, msgId, serverTime, serverSalt, badTime);
}
{
QWriteLocker lock(sessionData->receivedIdsMutex());
mtpMsgIdsMap &receivedIds(sessionData->receivedIdsSet());
uint32 receivedIdsSize = receivedIds.size();
while (receivedIdsSize-- > MTPIdsBufferSize) {
receivedIds.erase(receivedIds.begin());
}
}
// send acks
uint32 toAckSize = ackRequestData.size();
if (toAckSize) {
DEBUG_LOG(("MTP Info: will send %1 acks, ids: %2").arg(toAckSize).arg(logVectorLong(ackRequestData)));
emit sendAnythingAsync(MTPAckSendWaiting);
}
bool emitSignal = false;
{
QReadLocker locker(sessionData->haveReceivedMutex());
emitSignal = !sessionData->haveReceivedMap().isEmpty();
if (emitSignal) {
DEBUG_LOG(("MTP Info: emitting needToReceive() - need to parse in another thread, haveReceivedMap.size() = %1").arg(sessionData->haveReceivedMap().size()));
}
}
if (emitSignal) {
emit needToReceive();
}
if (res < 0) {
_needSessionReset = (res < -1);
return restart();
}
if (!sessionData->isCheckedKey()) {
DEBUG_LOG(("MTP Info: marked auth key as checked"));
sessionData->setCheckedKey(true);
}
if (!wasConnected) {
if (getState() == MTProtoConnection::Connected) {
emit needToSendAsync();
}
}
}
if (conn->needHttpWait()) {
emit sendHttpWaitAsync();
}
}
int32 MTProtoConnectionPrivate::handleOneReceived(const mtpPrime *from, const mtpPrime *end, uint64 msgId, int32 serverTime, uint64 serverSalt, bool badTime) {
mtpTypeId cons = *from;
try {
switch (cons) {
case mtpc_gzip_packed: {
DEBUG_LOG(("Message Info: gzip container"));
mtpBuffer response = ungzip(++from, end);
if (!response.size()) {
return -1;
}
return handleOneReceived(response.data(), response.data() + response.size(), msgId, serverTime, serverSalt, badTime);
}
case mtpc_msg_container: {
if (++from >= end) throw mtpErrorInsufficient();
const mtpPrime *otherEnd;
uint32 msgsCount = (uint32)*(from++);
DEBUG_LOG(("Message Info: container received, count: %1").arg(msgsCount));
for (uint32 i = 0; i < msgsCount; ++i) {
if (from + 4 >= end) throw mtpErrorInsufficient();
otherEnd = from + 4;
MTPlong inMsgId(from, otherEnd);
bool isReply = ((inMsgId.v & 0x03) == 1);
if (!isReply && ((inMsgId.v & 0x03) != 3)) {
LOG(("Message Error: bad msg_id %1 in contained message received").arg(inMsgId.v));
return -1;
}
MTPint inSeqNo(from, otherEnd);
MTPint bytes(from, otherEnd);
if ((bytes.v & 0x03) || bytes.v < 4) {
LOG(("Message Error: bad length %1 of contained message received").arg(bytes.v));
return -1;
}
bool needAck = (inSeqNo.v & 0x01);
if (needAck) ackRequestData.push_back(inMsgId);
DEBUG_LOG(("Message Info: message from container, msg_id: %1, needAck: %2").arg(inMsgId.v).arg(logBool(needAck)));
otherEnd = from + (bytes.v >> 2);
if (otherEnd > end) throw mtpErrorInsufficient();
bool needToHandle = false;
{
QWriteLocker lock(sessionData->receivedIdsMutex());
mtpMsgIdsMap &receivedIds(sessionData->receivedIdsSet());
needToHandle = receivedIds.insert(inMsgId.v, needAck);
}
int32 res = 1; // if no need to handle, then succeed
if (needToHandle) {
res = handleOneReceived(from, otherEnd, inMsgId.v, serverTime, serverSalt, badTime);
badTime = false;
}
if (res <= 0) {
return res;
}
from = otherEnd;
}
} return 1;
case mtpc_msgs_ack: {
MTPMsgsAck msg(from, end);
const QVector<MTPlong> &ids(msg.c_msgs_ack().vmsg_ids.c_vector().v);
uint32 idsCount = ids.size();
DEBUG_LOG(("Message Info: acks received, ids: %1").arg(logVectorLong(ids)));
if (!idsCount) return (badTime ? 0 : 1);
if (badTime) {
if (requestsFixTimeSalt(ids, serverTime, serverSalt)) {
badTime = false;
} else {
return 0;
}
}
requestsAcked(ids);
} return 1;
case mtpc_bad_msg_notification: {
MTPBadMsgNotification msg(from, end);
const MTPDbad_msg_notification &data(msg.c_bad_msg_notification());
LOG(("Message Info: bad message notification received (error_code %3) for msg_id = %1, seq_no = %2").arg(data.vbad_msg_id.v).arg(data.vbad_msg_seqno.v).arg(data.verror_code.v));
mtpMsgId resendId = data.vbad_msg_id.v;
int32 errorCode = data.verror_code.v;
if (errorCode == 16 || errorCode == 17 || errorCode == 32 || errorCode == 33 || errorCode == 64) { // can handle
bool needResend = (errorCode == 16 || errorCode == 17); // bad msg_id
if (errorCode == 64) { // bad container!
needResend = true;
if (cDebug()) {
mtpRequest request;
{
QWriteLocker locker(sessionData->haveSentMutex());
mtpRequestMap &haveSent(sessionData->haveSentMap());
mtpRequestMap::const_iterator i = haveSent.constFind(resendId);
if (i == haveSent.cend()) {
LOG(("Message Error: Container not found!"));
} else {
request = i.value();
}
}
if (request) {
if (mtpRequestData::isSentContainer(request)) {
QStringList lst;
const mtpMsgId *ids = (const mtpMsgId *)(request->constData() + 8);
for (uint32 i = 0, l = (request->size() - 8) >> 1; i < l; ++i) {
lst.push_back(QString::number(ids[i]));
}
LOG(("Message Info: bad container received! messages: %1").arg(lst.join(',')));
} else {
LOG(("Message Error: bad container received, but request is not a container!"));
}
}
}
}
if (!wasSent(resendId)) {
DEBUG_LOG(("Message Error: such message was not sent recently %1").arg(resendId));
return (badTime ? 0 : 1);
}
if (needResend) { // bad msg_id
if (serverSalt) sessionData->setSalt(serverSalt);
unixtimeSet(serverTime, true);
DEBUG_LOG(("Message Info: unixtime updated, now %1, resending in container..").arg(serverTime));
resend(resendId, 0, true);
} else { // must create new session, because msg_id and msg_seqno are inconsistent
if (badTime) {
if (serverSalt) sessionData->setSalt(serverSalt);
unixtimeSet(serverTime, true);
badTime = false;
}
LOG(("Message Info: bad message notification received, msgId %1, error_code %2").arg(data.vbad_msg_id.v).arg(errorCode));
return -2;
}
} else { // fatal (except 48, but it must not get here)
mtpMsgId resendId = data.vbad_msg_id.v;
mtpRequestId requestId = wasSent(resendId);
if (requestId) {
LOG(("Message Error: bad message notification received, msgId %1, error_code %2, fatal: clearing callbacks").arg(data.vbad_msg_id.v).arg(errorCode));
_mtp_internal::clearCallbacksDelayed(RPCCallbackClears(1, RPCCallbackClear(requestId, -errorCode)));
} else {
DEBUG_LOG(("Message Error: such message was not sent recently %1").arg(resendId));
}
return (badTime ? 0 : 1);
}
} return 1;
case mtpc_bad_server_salt: {
MTPBadMsgNotification msg(from, end);
const MTPDbad_server_salt &data(msg.c_bad_server_salt());
DEBUG_LOG(("Message Info: bad server salt received (error_code %4) for msg_id = %1, seq_no = %2, new salt: %3").arg(data.vbad_msg_id.v).arg(data.vbad_msg_seqno.v).arg(data.vnew_server_salt.v).arg(data.verror_code.v));
mtpMsgId resendId = data.vbad_msg_id.v;
if (!wasSent(resendId)) {
DEBUG_LOG(("Message Error: such message was not sent recently %1").arg(resendId));
return (badTime ? 0 : 1);
}
uint64 serverSalt = data.vnew_server_salt.v;
sessionData->setSalt(serverSalt);
unixtimeSet(serverTime);
if (setState(MTProtoConnection::Connected, MTProtoConnection::Connecting)) { // maybe only connected
if (restarted) {
emit resendAllAsync();
restarted = false;
}
}
badTime = false;
DEBUG_LOG(("Message Info: unixtime updated, now %1, server_salt updated, now %2, resending..").arg(serverTime).arg(serverSalt));
resend(resendId);
} return 1;
case mtpc_msgs_state_req: {
if (badTime) {
DEBUG_LOG(("Message Info: skipping with bad time.."));
return 0;
}
MTPMsgsStateReq msg(from, end);
const QVector<MTPlong> ids(msg.c_msgs_state_req().vmsg_ids.c_vector().v);
uint32 idsCount = ids.size();
DEBUG_LOG(("Message Info: msgs_state_req received, ids: %1").arg(logVectorLong(ids)));
if (!idsCount) return 1;
QByteArray info(idsCount, Qt::Uninitialized);
{
QReadLocker lock(sessionData->receivedIdsMutex());
const mtpMsgIdsMap &receivedIds(sessionData->receivedIdsSet());
mtpMsgIdsMap::const_iterator receivedIdsEnd(receivedIds.cend());
uint64 minRecv = receivedIds.min(), maxRecv = receivedIds.max();
QReadLocker locker(sessionData->wereAckedMutex());
const mtpRequestIdsMap &wereAcked(sessionData->wereAckedMap());
mtpRequestIdsMap::const_iterator wereAckedEnd(wereAcked.cend());
for (uint32 i = 0, l = idsCount; i < l; ++i) {
char state = 0;
uint64 reqMsgId = ids[i].v;
if (reqMsgId < minRecv) {
state |= 0x01;
} else if (reqMsgId > maxRecv) {
state |= 0x03;
} else {
mtpMsgIdsMap::const_iterator recv = receivedIds.constFind(reqMsgId);
if (recv == receivedIdsEnd) {
state |= 0x02;
} else {
state |= 0x04;
if (wereAcked.constFind(reqMsgId) != wereAckedEnd) {
state |= 0x80; // we know, that server knows, that we received request
}
if (recv.value()) { // need ack, so we sent ack
state |= 0x08;
} else {
state |= 0x10;
}
}
}
info[i] = state;
}
}
emit sendMsgsStateInfoAsync(msgId, info);
} return 1;
case mtpc_msgs_state_info: {
MTPMsgsStateInfo msg(from, end);
const MTPDmsgs_state_info &data(msg.c_msgs_state_info());
uint64 reqMsgId = data.vreq_msg_id.v;
const string &states(data.vinfo.c_string().v);
DEBUG_LOG(("Message Info: msg state received, msgId %1, reqMsgId: %2, HEX states %3").arg(msgId).arg(reqMsgId).arg(mb(states.data(), states.length()).str()));
mtpRequest requestBuffer;
{ // find this request in session-shared sent requests map
QReadLocker locker(sessionData->haveSentMutex());
const mtpRequestMap &haveSent(sessionData->haveSentMap());
mtpRequestMap::const_iterator replyTo = haveSent.constFind(reqMsgId);
if (replyTo == haveSent.cend()) { // do not look in toResend, because we do not resend msgs_state_req requests
DEBUG_LOG(("Message Error: such message was not sent recently %1").arg(reqMsgId));
return (badTime ? 0 : 1);
}
if (badTime) {
if (serverSalt) sessionData->setSalt(serverSalt); // requestsFixTimeSalt with no lookup
unixtimeSet(serverTime, true);
DEBUG_LOG(("Message Info: unixtime updated from mtpc_msgs_state_info, now %1").arg(serverTime));
badTime = false;
}
requestBuffer = replyTo.value();
}
QVector<MTPlong> toAckReq(1, MTP_long(reqMsgId)), toAck;
requestsAcked(toAck, true);
if (requestBuffer->size() < 9) {
LOG(("Message Error: bad request %1 found in requestMap, size: %2").arg(reqMsgId).arg(requestBuffer->size()));
return -1;
}
try {
const mtpPrime *rFrom = requestBuffer->constData() + 8, *rEnd = requestBuffer->constData() + requestBuffer->size();
if (mtpTypeId(*rFrom) == mtpc_msgs_state_req) {
MTPMsgsStateReq request(rFrom, rEnd);
handleMsgsStates(request.c_msgs_state_req().vmsg_ids.c_vector().v, states, toAck);
} else {
MTPMsgResendReq request(rFrom, rEnd);
handleMsgsStates(request.c_msg_resend_req().vmsg_ids.c_vector().v, states, toAck);
}
} catch(Exception &e) {
LOG(("Message Error: could not parse sent msgs_state_req"));
throw;
}
requestsAcked(toAck);
} return 1;
case mtpc_msgs_all_info: {
if (badTime) {
DEBUG_LOG(("Message Info: skipping with bad time.."));
return 0;
}
MTPMsgsAllInfo msg(from, end);
const MTPDmsgs_all_info &data(msg.c_msgs_all_info());
const QVector<MTPlong> ids(data.vmsg_ids.c_vector().v);
const string &states(data.vinfo.c_string().v);
QVector<MTPlong> toAck;
DEBUG_LOG(("Message Info: msgs all info received, msgId %1, reqMsgIds: %2, states %3").arg(msgId).arg(logVectorLong(ids)).arg(mb(states.data(), states.length()).str()));
handleMsgsStates(ids, states, toAck);
requestsAcked(toAck);
} return 1;
case mtpc_msg_detailed_info: {
MTPMsgDetailedInfo msg(from, end);
const MTPDmsg_detailed_info &data(msg.c_msg_detailed_info());
DEBUG_LOG(("Message Info: msg detailed info, sent msgId %1, answerId %2, status %3, bytes %4").arg(data.vmsg_id.v).arg(data.vanswer_msg_id.v).arg(data.vstatus.v).arg(data.vbytes.v));
QVector<MTPlong> ids(1, data.vmsg_id);
if (badTime) {
if (requestsFixTimeSalt(ids, serverTime, serverSalt)) {
badTime = false;
} else {
DEBUG_LOG(("Message Info: error, such message was not sent recently %1").arg(data.vmsg_id.v));
return 0;
}
}
requestsAcked(ids);
bool received = false;
MTPlong resMsgId = data.vanswer_msg_id;
{
QReadLocker lock(sessionData->receivedIdsMutex());
const mtpMsgIdsMap &receivedIds(sessionData->receivedIdsSet());
received = (receivedIds.find(resMsgId.v) != receivedIds.cend()) && (receivedIds.min() < resMsgId.v);
}
if (received) {
ackRequestData.push_back(resMsgId);
} else {
DEBUG_LOG(("Message Info: answer message %1 was not received, requesting..").arg(resMsgId.v));
resendRequestData.push_back(resMsgId);
}
} return 1;
case mtpc_msg_new_detailed_info: {
if (badTime) {
DEBUG_LOG(("Message Info: skipping msg_new_detailed_info with bad time.."));
return 0;
}
MTPMsgDetailedInfo msg(from, end);
const MTPDmsg_new_detailed_info &data(msg.c_msg_new_detailed_info());
DEBUG_LOG(("Message Info: msg new detailed info, answerId %2, status %3, bytes %4").arg(data.vanswer_msg_id.v).arg(data.vstatus.v).arg(data.vbytes.v));
bool received = false;
MTPlong resMsgId = data.vanswer_msg_id;
{
QReadLocker lock(sessionData->receivedIdsMutex());
const mtpMsgIdsMap &receivedIds(sessionData->receivedIdsSet());
received = (receivedIds.find(resMsgId.v) != receivedIds.cend()) && (receivedIds.min() < resMsgId.v);
}
if (received) {
ackRequestData.push_back(resMsgId);
} else {
DEBUG_LOG(("Message Info: answer message %1 was not received, requesting..").arg(resMsgId.v));
resendRequestData.push_back(resMsgId);
}
} return 1;
case mtpc_msg_resend_req: {
MTPMsgResendReq msg(from, end);
const QVector<MTPlong> &ids(msg.c_msg_resend_req().vmsg_ids.c_vector().v);
uint32 idsCount = ids.size();
DEBUG_LOG(("Message Info: resend of msgs requested, ids: %1").arg(logVectorLong(ids)));
if (!idsCount) return (badTime ? 0 : 1);
QVector<quint64> toResend(ids.size(), Qt::Uninitialized);
for (int32 i = 0, l = ids.size(); i < l; ++i) {
toResend[i] = ids.at(i).v;
}
resendMany(toResend, 0, false, true);
} return 1;
case mtpc_rpc_result: {
if (from + 3 > end) throw mtpErrorInsufficient();
mtpResponse response;
MTPlong reqMsgId(++from, end);
mtpTypeId typeId = from[0];
DEBUG_LOG(("RPC Info: response received for %1, queueing..").arg(reqMsgId.v));
QVector<MTPlong> ids(1, reqMsgId);
if (badTime) {
if (requestsFixTimeSalt(ids, serverTime, serverSalt)) {
badTime = false;
} else {
DEBUG_LOG(("Message Info: error, such message was not sent recently %1").arg(reqMsgId.v));
return 0;
}
}
requestsAcked(ids, true);
if (typeId == mtpc_gzip_packed) {
DEBUG_LOG(("RPC Info: gzip container"));
response = ungzip(++from, end);
if (!response.size()) {
return -1;
}
typeId = response[0];
} else {
response.resize(end - from);
memcpy(response.data(), from, (end - from) * sizeof(mtpPrime));
}
if (!sessionData->layerWasInited()) {
sessionData->setLayerWasInited(true);
sessionData->owner()->notifyLayerInited(true);
}
mtpRequestId requestId = wasSent(reqMsgId.v);
if (requestId && requestId != mtpRequestId(0xFFFFFFFF)) {
QWriteLocker locker(sessionData->haveReceivedMutex());
sessionData->haveReceivedMap().insert(requestId, response); // save rpc_result for processing in main mtp thread
} else {
DEBUG_LOG(("RPC Info: requestId not found for msgId %1").arg(reqMsgId.v));
}
} return 1;
case mtpc_new_session_created: {
if (badTime) return 0;
MTPNewSession msg(from, end);
const MTPDnew_session_created &data(msg.c_new_session_created());
DEBUG_LOG(("Message Info: new server session created, unique_id %1, first_msg_id %2, server_salt %3").arg(data.vunique_id.v).arg(data.vfirst_msg_id.v).arg(data.vserver_salt.v));
sessionData->setSalt(data.vserver_salt.v);
mtpMsgId firstMsgId = data.vfirst_msg_id.v;
QVector<quint64> toResend;
{
QReadLocker locker(sessionData->haveSentMutex());
const mtpRequestMap &haveSent(sessionData->haveSentMap());
toResend.reserve(haveSent.size());
for (mtpRequestMap::const_iterator i = haveSent.cbegin(), e = haveSent.cend(); i != e; ++i) {
if (i.key() >= firstMsgId) break;
if (i.value()->requestId) toResend.push_back(i.key());
}
}
resendMany(toResend, 10, true);
mtpBuffer update(end - from);
if (end > from) memcpy(update.data(), from, (end - from) * sizeof(mtpPrime));
QWriteLocker locker(sessionData->haveReceivedMutex());
mtpResponseMap &haveReceived(sessionData->haveReceivedMap());
mtpRequestId fakeRequestId = sessionData->nextFakeRequestId();
haveReceived.insert(fakeRequestId, mtpResponse(update)); // notify main process about new session - need to get difference
} return 1;
case mtpc_ping: {
if (badTime) return 0;
MTPPing msg(from, end);
DEBUG_LOG(("Message Info: ping received, ping_id: %1, sending pong..").arg(msg.vping_id.v));
emit sendPongAsync(msgId, msg.vping_id.v);
} return 1;
case mtpc_pong: {
MTPPong msg(from, end);
const MTPDpong &data(msg.c_pong());
DEBUG_LOG(("Message Info: pong received, msg_id: %1, ping_id: %2").arg(data.vmsg_id.v).arg(data.vping_id.v));
if (!wasSent(data.vmsg_id.v)) {
DEBUG_LOG(("Message Error: such msg_id %1 ping_id %2 was not sent recently").arg(data.vmsg_id.v).arg(data.vping_id.v));
return 0;
}
if (data.vping_id.v == pingId) {
pingId = 0;
} else {
DEBUG_LOG(("Message Info: just pong.."));
}
QVector<MTPlong> ids(1, data.vmsg_id);
if (badTime) {
if (requestsFixTimeSalt(ids, serverTime, serverSalt)) {
badTime = false;
} else {
return 0;
}
}
requestsAcked(ids, true);
retryTimeout = 1; // reset restart() timer
} return 1;
}
} catch (Exception &e) {
return -1;
}
if (badTime) {
DEBUG_LOG(("Message Error: bad time in updates cons"));
return -1;
}
mtpBuffer update(end - from);
if (end > from) memcpy(update.data(), from, (end - from) * sizeof(mtpPrime));
QWriteLocker locker(sessionData->haveReceivedMutex());
mtpResponseMap &haveReceived(sessionData->haveReceivedMap());
mtpRequestId fakeRequestId = sessionData->nextFakeRequestId();
haveReceived.insert(fakeRequestId, mtpResponse(update)); // notify main process about new updates
if (cons != mtpc_updatesTooLong && cons != mtpc_updateShortMessage && cons != mtpc_updateShortChatMessage && cons != mtpc_updateShort && cons != mtpc_updatesCombined && cons != mtpc_updates) {
LOG(("Message Error: unknown constructor %1").arg(cons)); // maybe new api?..
}
return 1;
}
mtpBuffer MTProtoConnectionPrivate::ungzip(const mtpPrime *from, const mtpPrime *end) const {
MTPstring packed(from, end); // read packed string as serialized mtp string type
uint32 packedLen = packed.c_string().v.size(), unpackedChunk = packedLen, unpackedLen = 0;
mtpBuffer result; // * 4 because of mtpPrime type
result.resize(0);
z_stream stream;
stream.zalloc = 0;
stream.zfree = 0;
stream.opaque = 0;
stream.avail_in = 0;
stream.next_in = 0;
int res = inflateInit2(&stream, 16 + MAX_WBITS);
if (res != Z_OK) {
LOG(("RPC Error: could not init zlib stream, code: %1").arg(res));
return result;
}
stream.avail_in = packedLen;
stream.next_in = (Bytef*)&packed._string().v[0];
stream.avail_out = 0;
while (!stream.avail_out) {
result.resize(result.size() + unpackedChunk);
stream.avail_out = unpackedChunk * sizeof(mtpPrime);
stream.next_out = (Bytef*)&result[result.size() - unpackedChunk];
int res = inflate(&stream, Z_NO_FLUSH);
if (res != Z_OK && res != Z_STREAM_END) {
inflateEnd(&stream);
LOG(("RPC Error: could not unpack gziped data, code: %1").arg(res));
DEBUG_LOG(("RPC Error: bad gzip: %1").arg(mb(&packed.c_string().v[0], packedLen).str()));
return mtpBuffer();
}
}
if (stream.avail_out & 0x03) {
uint32 badSize = result.size() * sizeof(mtpPrime) - stream.avail_out;
LOG(("RPC Error: bad length of unpacked data %1").arg(badSize));
DEBUG_LOG(("RPC Error: bad unpacked data %1").arg(mb(result.data(), badSize).str()));
return mtpBuffer();
}
result.resize(result.size() - (stream.avail_out >> 2));
inflateEnd(&stream);
if (!result.size()) {
LOG(("RPC Error: bad length of unpacked data 0"));
}
return result;
}
bool MTProtoConnectionPrivate::requestsFixTimeSalt(const QVector<MTPlong> &ids, int32 serverTime, uint64 serverSalt) {
uint32 idsCount = ids.size();
for (uint32 i = 0; i < idsCount; ++i) {
if (wasSent(ids[i].v)) {// found such msg_id in recent acked requests or in recent sent requests
if (serverSalt) sessionData->setSalt(serverSalt);
unixtimeSet(serverTime, true);
return true;
}
}
return false;
}
void MTProtoConnectionPrivate::requestsAcked(const QVector<MTPlong> &ids, bool byResponse) {
uint32 idsCount = ids.size();
DEBUG_LOG(("Message Info: requests acked, ids %1").arg(logVectorLong(ids)));
RPCCallbackClears clearedAcked;
QVector<MTPlong> toAckMore;
{
QWriteLocker locker1(sessionData->wereAckedMutex());
mtpRequestIdsMap &wereAcked(sessionData->wereAckedMap());
{
QWriteLocker locker2(sessionData->haveSentMutex());
mtpRequestMap &haveSent(sessionData->haveSentMap());
for (uint32 i = 0; i < idsCount; ++i) {
mtpMsgId msgId = ids[i].v;
mtpRequestMap::iterator req = haveSent.find(msgId);
if (req != haveSent.cend()) {
if (!req.value()->msDate) {
DEBUG_LOG(("Message Info: container ack received, msgId %1").arg(ids[i].v));
uint32 inContCount = ((*req)->size() - 8) / 2;
const mtpMsgId *inContId = (const mtpMsgId *)(req.value()->constData() + 8);
toAckMore.reserve(toAckMore.size() + inContCount);
for (uint32 j = 0; j < inContCount; ++j) {
toAckMore.push_back(MTP_long(*(inContId++)));
}
haveSent.erase(req);
} else {
mtpRequestId reqId = req.value()->requestId;
bool moveToAcked = byResponse;
if (!moveToAcked) { // ignore ACK, if we need a response (if we have a handler)
moveToAcked = !_mtp_internal::hasCallbacks(reqId);
}
if (moveToAcked) {
wereAcked.insert(msgId, reqId);
haveSent.erase(req);
} else {
DEBUG_LOG(("Message Info: ignoring ACK for msgId %1 because request %2 requires a response").arg(msgId).arg(reqId));
}
}
} else {
DEBUG_LOG(("Message Info: msgId %1 was not found in recent sent, while acking requests, searching in resend..").arg(msgId));
QWriteLocker locker3(sessionData->toResendMutex());
mtpRequestIdsMap &toResend(sessionData->toResendMap());
mtpRequestIdsMap::iterator reqIt = toResend.find(msgId);
if (reqIt != toResend.cend()) {
mtpRequestId reqId = reqIt.value();
bool moveToAcked = byResponse;
if (!moveToAcked) { // ignore ACK, if we need a response (if we have a handler)
moveToAcked = !_mtp_internal::hasCallbacks(reqId);
}
if (moveToAcked) {
QWriteLocker locker4(sessionData->toSendMutex());
mtpPreRequestMap &toSend(sessionData->toSendMap());
mtpPreRequestMap::iterator req = toSend.find(reqId);
if (req != toSend.cend()) {
wereAcked.insert(msgId, req.value()->requestId);
if (req.value()->requestId != reqId) {
DEBUG_LOG(("Message Error: for msgId %1 found resent request, requestId %2, contains requestId %3").arg(msgId).arg(reqId).arg(req.value()->requestId));
} else {
DEBUG_LOG(("Message Info: acked msgId %1 that was prepared to resend, requestId %2").arg(msgId).arg(reqId));
}
toSend.erase(req);
} else {
DEBUG_LOG(("Message Info: msgId %1 was found in recent resent, requestId %2 was not found in prepared to send").arg(msgId));
}
toResend.erase(reqIt);
} else {
DEBUG_LOG(("Message Info: ignoring ACK for msgId %1 because request %2 requires a response").arg(msgId).arg(reqId));
}
} else {
DEBUG_LOG(("Message Info: msgId %1 was not found in recent resent either").arg(msgId));
}
}
}
}
uint32 ackedCount = wereAcked.size();
if (ackedCount > MTPIdsBufferSize) {
DEBUG_LOG(("Message Info: removing some old acked sent msgIds %1").arg(ackedCount - MTPIdsBufferSize));
clearedAcked.reserve(ackedCount - MTPIdsBufferSize);
while (ackedCount-- > MTPIdsBufferSize) {
mtpRequestIdsMap::iterator i(wereAcked.begin());
clearedAcked.push_back(RPCCallbackClear(i.key(), RPCError::TimeoutError));
wereAcked.erase(i);
}
}
}
if (clearedAcked.size()) {
_mtp_internal::clearCallbacksDelayed(clearedAcked);
}
if (toAckMore.size()) {
requestsAcked(toAckMore);
}
}
void MTProtoConnectionPrivate::handleMsgsStates(const QVector<MTPlong> &ids, const string &states, QVector<MTPlong> &acked) {
uint32 idsCount = ids.size();
if (!idsCount) {
DEBUG_LOG(("Message Info: void ids vector in handleMsgsStates()"));
return;
}
acked.reserve(acked.size() + idsCount);
for (uint32 i = 0, count = idsCount; i < count; ++i) {
char state = states[i];
uint64 requestMsgId = ids[i].v;
{
QReadLocker locker(sessionData->haveSentMutex());
const mtpRequestMap &haveSent(sessionData->haveSentMap());
mtpRequestMap::const_iterator haveSentEnd = haveSent.cend();
if (haveSent.find(requestMsgId) == haveSentEnd) {
DEBUG_LOG(("Message Info: state was received for msgId %1, but request is not found, looking in resent requests..").arg(requestMsgId));
QWriteLocker locker2(sessionData->toResendMutex());
mtpRequestIdsMap &toResend(sessionData->toResendMap());
mtpRequestIdsMap::iterator reqIt = toResend.find(requestMsgId);
if (reqIt != toResend.cend()) {
if ((state & 0x07) != 0x04) { // was received
DEBUG_LOG(("Message Info: state was received for msgId %1, state %2, already resending in container").arg(requestMsgId).arg((int32)state));
} else {
DEBUG_LOG(("Message Info: state was received for msgId %1, state %2, ack, cancelling resend").arg(requestMsgId).arg((int32)state));
acked.push_back(MTP_long(requestMsgId)); // will remove from resend in requestsAcked
}
} else {
DEBUG_LOG(("Message Info: msgId %1 was not found in recent resent either").arg(requestMsgId));
}
continue;
}
}
if ((state & 0x07) != 0x04) { // was received
DEBUG_LOG(("Message Info: state was received for msgId %1, state %2, resending in container").arg(requestMsgId).arg((int32)state));
resend(requestMsgId, 10, true);
} else {
DEBUG_LOG(("Message Info: state was received for msgId %1, state %2, ack").arg(requestMsgId).arg((int32)state));
acked.push_back(MTP_long(requestMsgId));
}
}
}
void MTProtoConnectionPrivate::resend(quint64 msgId, quint64 msCanWait, bool forceContainer, bool sendMsgStateInfo) {
if (msgId == pingMsgId) return;
emit resendAsync(msgId, msCanWait, forceContainer, sendMsgStateInfo);
}
void MTProtoConnectionPrivate::resendMany(QVector<quint64> msgIds, quint64 msCanWait, bool forceContainer, bool sendMsgStateInfo) {
for (int32 i = 0, l = msgIds.size(); i < l; ++i) {
if (msgIds.at(i) == pingMsgId) {
msgIds.remove(i);
--l;
}
}
emit resendManyAsync(msgIds, msCanWait, forceContainer, sendMsgStateInfo);
}
void MTProtoConnectionPrivate::onConnected() {
QReadLocker lockFinished(&sessionDataMutex);
if (!sessionData) return;
disconnect(conn, SIGNAL(connected()), this, SLOT(onConnected()));
if (!conn->isConnected()) {
LOG(("Connection Error: not connected in onConnected(), state: %1").arg(conn->debugState()));
return restart();
}
TCP_LOG(("Connection Info: connection succeed."));
if (updateAuthKey()) {
DEBUG_LOG(("MTP Info: returning from socketConnected.."));
return;
}
DEBUG_LOG(("MTP Info: will be creating auth_key"));
lockKey();
const mtpAuthKeyPtr &key(sessionData->getKey());
if (key) {
if (keyId != key->keyId()) clearMessages();
keyId = key->keyId();
unlockKey();
return authKeyCreated();
}
authKeyData = new MTProtoConnectionPrivate::AuthKeyCreateData();
authKeyStrings = new MTProtoConnectionPrivate::AuthKeyCreateStrings();
authKeyData->req_num = 0;
authKeyData->nonce = MTP::nonce<MTPint128>();
MTPReq_pq req_pq;
req_pq.vnonce = authKeyData->nonce;
connect(conn, SIGNAL(receivedData()), this, SLOT(pqAnswered()));
DEBUG_LOG(("AuthKey Info: sending Req_pq.."));
sendRequestNotSecure(req_pq);
}
bool MTProtoConnectionPrivate::updateAuthKey() {
QReadLocker lockFinished(&sessionDataMutex);
if (!sessionData || !conn) return false;
DEBUG_LOG(("AuthKey Info: MTProtoConnection updating key from MTProtoSession, dc %1").arg(dc));
uint64 newKeyId = 0;
{
ReadLockerAttempt lock(sessionData->keyMutex());
if (!lock) {
DEBUG_LOG(("MTP Info: could not lock auth_key for read, waiting signal emit"));
clearMessages();
keyId = newKeyId;
return true; // some other connection is getting key
}
const mtpAuthKeyPtr &key(sessionData->getKey());
newKeyId = key ? key->keyId() : 0;
}
if (keyId != newKeyId) {
clearMessages();
keyId = newKeyId;
}
DEBUG_LOG(("AuthKey Info: MTProtoConnection update key from MTProtoSession, dc %1 result: %2").arg(dc).arg(mb(&keyId, sizeof(keyId)).str()));
if (keyId) {
authKeyCreated();
return true;
}
DEBUG_LOG(("AuthKey Info: Key update failed"));
return false;
}
void MTProtoConnectionPrivate::clearMessages() {
if (keyId && keyId != mtpAuthKey::RecreateKeyId && conn) {
conn->received().clear();
}
}
void MTProtoConnectionPrivate::pqAnswered() {
disconnect(conn, SIGNAL(receivedData()), this, SLOT(pqAnswered()));
DEBUG_LOG(("AuthKey Info: receiving Req_pq answer.."));
MTPReq_pq::ResponseType res_pq;
if (!readResponseNotSecure(res_pq)) {
return restart();
}
const MTPDresPQ &res_pq_data(res_pq.c_resPQ());
if (res_pq_data.vnonce != authKeyData->nonce) {
LOG(("AuthKey Error: received nonce <> sent nonce (in res_pq)!"));
DEBUG_LOG(("AuthKey Error: received nonce: %1, sent nonce: %2").arg(mb(&res_pq_data.vnonce, 16).str()).arg(mb(&authKeyData->nonce, 16).str()));
return restart();
}
mtpPublicRSA *rsaKey = 0;
const QVector<MTPlong> &fingerPrints(res_pq.c_resPQ().vserver_public_key_fingerprints.c_vector().v);
for (uint32 i = 0, l = fingerPrints.size(); i < l; ++i) {
uint64 print(fingerPrints[i].v);
PublicRSAKeys::iterator rsaIndex = gPublicRSA.find(print);
if (rsaIndex != gPublicRSA.end()) {
rsaKey = &rsaIndex.value();
break;
}
}
if (!rsaKey) {
QStringList suggested, my;
for (uint32 i = 0, l = fingerPrints.size(); i < l; ++i) {
suggested.push_back(QString("%1").arg(fingerPrints[i].v));
}
for (PublicRSAKeys::const_iterator i = gPublicRSA.cbegin(), e = gPublicRSA.cend(); i != e; ++i) {
my.push_back(QString("%1").arg(i.key()));
}
LOG(("AuthKey Error: could not choose public RSA key, suggested fingerprints: %1, my fingerprints: %2").arg(suggested.join(", ")).arg(my.join(", ")));
return restart();
}
authKeyData->server_nonce = res_pq_data.vserver_nonce;
MTPP_Q_inner_data p_q_inner;
MTPDp_q_inner_data &p_q_inner_data(p_q_inner._p_q_inner_data());
p_q_inner_data.vnonce = authKeyData->nonce;
p_q_inner_data.vserver_nonce = authKeyData->server_nonce;
p_q_inner_data.vpq = res_pq_data.vpq;
const string &pq(res_pq_data.vpq.c_string().v);
string &p(p_q_inner_data.vp._string().v), &q(p_q_inner_data.vq._string().v);
if (!parsePQ(pq, p, q)) {
LOG(("AuthKey Error: could not factor pq!"));
DEBUG_LOG(("AuthKey Error: problematic pq: %1").arg(mb(&pq[0], pq.length()).str()));
return restart();
}
authKeyData->new_nonce = MTP::nonce<MTPint256>();
p_q_inner_data.vnew_nonce = authKeyData->new_nonce;
MTPReq_DH_params req_DH_params;
req_DH_params.vnonce = authKeyData->nonce;
req_DH_params.vserver_nonce = authKeyData->server_nonce;
req_DH_params.vpublic_key_fingerprint = MTP_long(rsaKey->fingerPrint());
req_DH_params.vp = p_q_inner_data.vp;
req_DH_params.vq = p_q_inner_data.vq;
string &dhEncString(req_DH_params.vencrypted_data._string().v);
uint32 p_q_inner_size = p_q_inner.innerLength(), encSize = (p_q_inner_size >> 2) + 6;
if (encSize >= 65) {
mtpBuffer tmp;
tmp.reserve(encSize);
p_q_inner.write(tmp);
LOG(("AuthKey Error: too large data for RSA encrypt, size %1").arg(encSize * sizeof(mtpPrime)));
DEBUG_LOG(("AuthKey Error: bad data for RSA encrypt %1").arg(mb(&tmp[0], tmp.size() * 4).str()));
return restart(); // can't be 255-byte string
}
mtpBuffer encBuffer;
encBuffer.reserve(65); // 260 bytes
encBuffer.resize(6);
encBuffer[0] = 0;
p_q_inner.write(encBuffer);
hashSha1(&encBuffer[6], p_q_inner_size, &encBuffer[1]);
if (encSize < 65) {
encBuffer.resize(65);
memset_rand(&encBuffer[encSize], (65 - encSize) * sizeof(mtpPrime));
}
dhEncString.resize(256);
int32 res = RSA_public_encrypt(256, ((const uchar*)&encBuffer[0]) + 3, (uchar*)&dhEncString[0], rsaKey->key(), RSA_NO_PADDING);
if (res != 256) {
ERR_load_crypto_strings();
LOG(("RSA Error: RSA_public_encrypt failed, key fp: %1, result: %2, error: %3").arg(rsaKey->fingerPrint()).arg(res).arg(ERR_error_string(ERR_get_error(), 0)));
return restart();
}
connect(conn, SIGNAL(receivedData()), this, SLOT(dhParamsAnswered()));
DEBUG_LOG(("AuthKey Info: sending Req_DH_params.."));
sendRequestNotSecure(req_DH_params);
}
void MTProtoConnectionPrivate::dhParamsAnswered() {
disconnect(conn, SIGNAL(receivedData()), this, SLOT(dhParamsAnswered()));
DEBUG_LOG(("AuthKey Info: receiving Req_DH_params answer.."));
MTPReq_DH_params::ResponseType res_DH_params;
if (!readResponseNotSecure(res_DH_params)) {
return restart();
}
switch (res_DH_params.type()) {
case mtpc_server_DH_params_ok: {
const MTPDserver_DH_params_ok &encDH(res_DH_params.c_server_DH_params_ok());
if (encDH.vnonce != authKeyData->nonce) {
LOG(("AuthKey Error: received nonce <> sent nonce (in server_DH_params_ok)!"));
DEBUG_LOG(("AuthKey Error: received nonce: %1, sent nonce: %2").arg(mb(&encDH.vnonce, 16).str()).arg(mb(&authKeyData->nonce, 16).str()));
return restart();
}
if (encDH.vserver_nonce != authKeyData->server_nonce) {
LOG(("AuthKey Error: received server_nonce <> sent server_nonce (in server_DH_params_ok)!"));
DEBUG_LOG(("AuthKey Error: received server_nonce: %1, sent server_nonce: %2").arg(mb(&encDH.vserver_nonce, 16).str()).arg(mb(&authKeyData->server_nonce, 16).str()));
return restart();
}
const string &encDHStr(encDH.vencrypted_answer.c_string().v);
uint32 encDHLen = encDHStr.length(), encDHBufLen = encDHLen >> 2;
if ((encDHLen & 0x03) || encDHBufLen < 6) {
LOG(("AuthKey Error: bad encrypted data length %1 (in server_DH_params_ok)!").arg(encDHLen));
DEBUG_LOG(("AuthKey Error: received encrypted data %1").arg(mb(&encDHStr[0], encDHLen).str()));
return restart();
}
uint32 nlen = authKeyData->new_nonce.innerLength(), slen = authKeyData->server_nonce.innerLength();
uchar tmp_aes[1024], sha1ns[20], sha1sn[20], sha1nn[20];
memcpy(tmp_aes, &authKeyData->new_nonce, nlen);
memcpy(tmp_aes + nlen, &authKeyData->server_nonce, slen);
memcpy(tmp_aes + nlen + slen, &authKeyData->new_nonce, nlen);
memcpy(tmp_aes + nlen + slen + nlen, &authKeyData->new_nonce, nlen);
hashSha1(tmp_aes, nlen + slen, sha1ns);
hashSha1(tmp_aes + nlen, nlen + slen, sha1sn);
hashSha1(tmp_aes + nlen + slen, nlen + nlen, sha1nn);
mtpBuffer decBuffer;
decBuffer.resize(encDHBufLen);
memcpy(authKeyData->aesKey, sha1ns, 20);
memcpy(authKeyData->aesKey + 20, sha1sn, 12);
memcpy(authKeyData->aesIV, sha1sn + 12, 8);
memcpy(authKeyData->aesIV + 8, sha1nn, 20);
memcpy(authKeyData->aesIV + 28, &authKeyData->new_nonce, 4);
aesDecrypt(&encDHStr[0], &decBuffer[0], encDHLen, authKeyData->aesKey, authKeyData->aesIV);
const mtpPrime *from(&decBuffer[5]), *to(from), *end(from + (encDHBufLen - 5));
MTPServer_DH_inner_data dh_inner(to, end);
const MTPDserver_DH_inner_data &dh_inner_data(dh_inner.c_server_DH_inner_data());
if (dh_inner_data.vnonce != authKeyData->nonce) {
LOG(("AuthKey Error: received nonce <> sent nonce (in server_DH_inner_data)!"));
DEBUG_LOG(("AuthKey Error: received nonce: %1, sent nonce: %2").arg(mb(&dh_inner_data.vnonce, 16).str()).arg(mb(&authKeyData->nonce, 16).str()));
return restart();
}
if (dh_inner_data.vserver_nonce != authKeyData->server_nonce) {
LOG(("AuthKey Error: received server_nonce <> sent server_nonce (in server_DH_inner_data)!"));
DEBUG_LOG(("AuthKey Error: received server_nonce: %1, sent server_nonce: %2").arg(mb(&dh_inner_data.vserver_nonce, 16).str()).arg(mb(&authKeyData->server_nonce, 16).str()));
return restart();
}
uchar sha1Buffer[20];
if (memcmp(&decBuffer[0], hashSha1(&decBuffer[5], (to - from) * sizeof(mtpPrime), sha1Buffer), 20)) {
LOG(("AuthKey Error: sha1 hash of encrypted part did not match!"));
DEBUG_LOG(("AuthKey Error: sha1 did not match, server_nonce: %1, new_nonce %2, encrypted data %3").arg(mb(&authKeyData->server_nonce, 16).str()).arg(mb(&authKeyData->new_nonce, 16).str()).arg(mb(&encDHStr[0], encDHLen).str()));
return restart();
}
unixtimeSet(dh_inner_data.vserver_time.v);
const string &dhPrime(dh_inner_data.vdh_prime.c_string().v), &g_a(dh_inner_data.vg_a.c_string().v);
if (dhPrime.length() != 256 || g_a.length() != 256) {
LOG(("AuthKey Error: bad dh_prime len (%1) or g_a len (%2)").arg(dhPrime.length()).arg(g_a.length()));
DEBUG_LOG(("AuthKey Error: dh_prime %1, g_a %2").arg(mb(&dhPrime[0], dhPrime.length()).str()).arg(mb(&g_a[0], g_a.length()).str()));
return restart();
}
// check that dhPrime and (dhPrime - 1) / 2 are really prime using openssl BIGNUM methods
_BigNumPrimeTest bnPrimeTest;
if (!bnPrimeTest.isPrimeAndGood(&dhPrime[0], MTPMillerRabinIterCount, dh_inner_data.vg.v)) {
LOG(("AuthKey Error: bad dh_prime primality!").arg(dhPrime.length()).arg(g_a.length()));
DEBUG_LOG(("AuthKey Error: dh_prime %1").arg(mb(&dhPrime[0], dhPrime.length()).str()));
return restart();
}
authKeyStrings->dh_prime = QByteArray(dhPrime.data(), dhPrime.size());
authKeyData->g = dh_inner_data.vg.v;
authKeyStrings->g_a = QByteArray(g_a.data(), g_a.size());
authKeyData->retry_id = MTP_long(0);
authKeyData->retries = 0;
} return dhClientParamsSend();
case mtpc_server_DH_params_fail: {
const MTPDserver_DH_params_fail &encDH(res_DH_params.c_server_DH_params_fail());
if (encDH.vnonce != authKeyData->nonce) {
LOG(("AuthKey Error: received nonce <> sent nonce (in server_DH_params_fail)!"));
DEBUG_LOG(("AuthKey Error: received nonce: %1, sent nonce: %2").arg(mb(&encDH.vnonce, 16).str()).arg(mb(&authKeyData->nonce, 16).str()));
return restart();
}
if (encDH.vserver_nonce != authKeyData->server_nonce) {
LOG(("AuthKey Error: received server_nonce <> sent server_nonce (in server_DH_params_fail)!"));
DEBUG_LOG(("AuthKey Error: received server_nonce: %1, sent server_nonce: %2").arg(mb(&encDH.vserver_nonce, 16).str()).arg(mb(&authKeyData->server_nonce, 16).str()));
return restart();
}
uchar sha1Buffer[20];
if (encDH.vnew_nonce_hash != *(MTPint128*)(hashSha1(&authKeyData->new_nonce, 32, sha1Buffer) + 1)) {
LOG(("AuthKey Error: received new_nonce_hash did not match!"));
DEBUG_LOG(("AuthKey Error: received new_nonce_hash: %1, new_nonce: %2").arg(mb(&encDH.vnew_nonce_hash, 16).str()).arg(mb(&authKeyData->new_nonce, 32).str()));
return restart();
}
LOG(("AuthKey Error: server_DH_params_fail received!"));
} return restart();
}
LOG(("AuthKey Error: unknown server_DH_params received, typeId = %1").arg(res_DH_params.type()));
return restart();
}
void MTProtoConnectionPrivate::dhClientParamsSend() {
if (++authKeyData->retries > 5) {
LOG(("AuthKey Error: could not create auth_key for %1 retries").arg(authKeyData->retries - 1));
return restart();
}
MTPClient_DH_Inner_Data client_dh_inner;
MTPDclient_DH_inner_data &client_dh_inner_data(client_dh_inner._client_DH_inner_data());
client_dh_inner_data.vnonce = authKeyData->nonce;
client_dh_inner_data.vserver_nonce = authKeyData->server_nonce;
client_dh_inner_data.vretry_id = authKeyData->retry_id;
client_dh_inner_data.vg_b._string().v.resize(256);
// gen rand 'b'
uint32 b[64], *g_b((uint32*)&client_dh_inner_data.vg_b._string().v[0]), g_b_len;
memset_rand(b, sizeof(b));
// count g_b and auth_key using openssl BIGNUM methods
_BigNumCounter bnCounter;
if (!bnCounter.count(b, authKeyStrings->dh_prime.constData(), authKeyData->g, g_b, authKeyStrings->g_a.constData(), authKeyData->auth_key)) {
return dhClientParamsSend();
}
// count auth_key hashes - parts of sha1(auth_key)
uchar sha1Buffer[20];
int32 *auth_key_sha = hashSha1(authKeyData->auth_key, 256, sha1Buffer);
memcpy(&authKeyData->auth_key_aux_hash, auth_key_sha, 8);
memcpy(&authKeyData->auth_key_hash, auth_key_sha + 3, 8);
MTPSet_client_DH_params req_client_DH_params;
req_client_DH_params.vnonce = authKeyData->nonce;
req_client_DH_params.vserver_nonce = authKeyData->server_nonce;
string &sdhEncString(req_client_DH_params.vencrypted_data._string().v);
uint32 client_dh_inner_size = client_dh_inner.innerLength(), encSize = (client_dh_inner_size >> 2) + 5, encFullSize = encSize;
if (encSize & 0x03) {
encFullSize += 4 - (encSize & 0x03);
}
mtpBuffer encBuffer;
encBuffer.reserve(encFullSize);
encBuffer.resize(5);
client_dh_inner.write(encBuffer);
hashSha1(&encBuffer[5], client_dh_inner_size, &encBuffer[0]);
if (encSize < encFullSize) {
encBuffer.resize(encFullSize);
memset_rand(&encBuffer[encSize], (encFullSize - encSize) * sizeof(mtpPrime));
}
sdhEncString.resize(encFullSize * 4);
aesEncrypt(&encBuffer[0], &sdhEncString[0], encFullSize * sizeof(mtpPrime), authKeyData->aesKey, authKeyData->aesIV);
connect(conn, SIGNAL(receivedData()), this, SLOT(dhClientParamsAnswered()));
DEBUG_LOG(("AuthKey Info: sending Req_client_DH_params.."));
sendRequestNotSecure(req_client_DH_params);
}
void MTProtoConnectionPrivate::dhClientParamsAnswered() {
QReadLocker lockFinished(&sessionDataMutex);
if (!sessionData) return;
disconnect(conn, SIGNAL(receivedData()), this, SLOT(dhClientParamsAnswered()));
DEBUG_LOG(("AuthKey Info: receiving Req_client_DH_params answer.."));
MTPSet_client_DH_params::ResponseType res_client_DH_params;
if (!readResponseNotSecure(res_client_DH_params)) {
return restart();
}
switch (res_client_DH_params.type()) {
case mtpc_dh_gen_ok: {
const MTPDdh_gen_ok &resDH(res_client_DH_params.c_dh_gen_ok());
if (resDH.vnonce != authKeyData->nonce) {
LOG(("AuthKey Error: received nonce <> sent nonce (in dh_gen_ok)!"));
DEBUG_LOG(("AuthKey Error: received nonce: %1, sent nonce: %2").arg(mb(&resDH.vnonce, 16).str()).arg(mb(&authKeyData->nonce, 16).str()));
return restart();
}
if (resDH.vserver_nonce != authKeyData->server_nonce) {
LOG(("AuthKey Error: received server_nonce <> sent server_nonce (in dh_gen_ok)!"));
DEBUG_LOG(("AuthKey Error: received server_nonce: %1, sent server_nonce: %2").arg(mb(&resDH.vserver_nonce, 16).str()).arg(mb(&authKeyData->server_nonce, 16).str()));
return restart();
}
authKeyData->new_nonce_buf[32] = 1;
uchar sha1Buffer[20];
if (resDH.vnew_nonce_hash1 != *(MTPint128*)(hashSha1(authKeyData->new_nonce_buf, 41, sha1Buffer) + 1)) {
LOG(("AuthKey Error: received new_nonce_hash1 did not match!"));
DEBUG_LOG(("AuthKey Error: received new_nonce_hash1: %1, new_nonce_buf: %2").arg(mb(&resDH.vnew_nonce_hash1, 16).str()).arg(mb(authKeyData->new_nonce_buf, 41).str()));
return restart();
}
uint64 salt1 = authKeyData->new_nonce.l.l, salt2 = authKeyData->server_nonce.l, serverSalt = salt1 ^ salt2;
sessionData->setSalt(serverSalt);
mtpAuthKeyPtr authKey(new mtpAuthKey());
authKey->setKey(authKeyData->auth_key);
authKey->setDC(dc % _mtp_internal::dcShift);
DEBUG_LOG(("AuthKey Info: auth key gen succeed, id: %1, server salt: %2, auth key: %3").arg(authKey->keyId()).arg(serverSalt).arg(mb(authKeyData->auth_key, 256).str()));
sessionData->owner()->notifyKeyCreated(authKey); // slot will call authKeyCreated()
sessionData->clear();
unlockKey();
} return;
case mtpc_dh_gen_retry: {
const MTPDdh_gen_retry &resDH(res_client_DH_params.c_dh_gen_retry());
if (resDH.vnonce != authKeyData->nonce) {
LOG(("AuthKey Error: received nonce <> sent nonce (in dh_gen_retry)!"));
DEBUG_LOG(("AuthKey Error: received nonce: %1, sent nonce: %2").arg(mb(&resDH.vnonce, 16).str()).arg(mb(&authKeyData->nonce, 16).str()));
return restart();
}
if (resDH.vserver_nonce != authKeyData->server_nonce) {
LOG(("AuthKey Error: received server_nonce <> sent server_nonce (in dh_gen_retry)!"));
DEBUG_LOG(("AuthKey Error: received server_nonce: %1, sent server_nonce: %2").arg(mb(&resDH.vserver_nonce, 16).str()).arg(mb(&authKeyData->server_nonce, 16).str()));
return restart();
}
authKeyData->new_nonce_buf[32] = 2;
uchar sha1Buffer[20];
if (resDH.vnew_nonce_hash2 != *(MTPint128*)(hashSha1(authKeyData->new_nonce_buf, 41, sha1Buffer) + 1)) {
LOG(("AuthKey Error: received new_nonce_hash2 did not match!"));
DEBUG_LOG(("AuthKey Error: received new_nonce_hash2: %1, new_nonce_buf: %2").arg(mb(&resDH.vnew_nonce_hash2, 16).str()).arg(mb(authKeyData->new_nonce_buf, 41).str()));
return restart();
}
authKeyData->retry_id = authKeyData->auth_key_aux_hash;
} return dhClientParamsSend();
case mtpc_dh_gen_fail: {
const MTPDdh_gen_fail &resDH(res_client_DH_params.c_dh_gen_fail());
if (resDH.vnonce != authKeyData->nonce) {
LOG(("AuthKey Error: received nonce <> sent nonce (in dh_gen_fail)!"));
DEBUG_LOG(("AuthKey Error: received nonce: %1, sent nonce: %2").arg(mb(&resDH.vnonce, 16).str()).arg(mb(&authKeyData->nonce, 16).str()));
return restart();
}
if (resDH.vserver_nonce != authKeyData->server_nonce) {
LOG(("AuthKey Error: received server_nonce <> sent server_nonce (in dh_gen_fail)!"));
DEBUG_LOG(("AuthKey Error: received server_nonce: %1, sent server_nonce: %2").arg(mb(&resDH.vserver_nonce, 16).str()).arg(mb(&authKeyData->server_nonce, 16).str()));
return restart();
}
authKeyData->new_nonce_buf[32] = 3;
uchar sha1Buffer[20];
if (resDH.vnew_nonce_hash3 != *(MTPint128*)(hashSha1(authKeyData->new_nonce_buf, 41, sha1Buffer) + 1)) {
LOG(("AuthKey Error: received new_nonce_hash3 did not match!"));
DEBUG_LOG(("AuthKey Error: received new_nonce_hash3: %1, new_nonce_buf: %2").arg(mb(&resDH.vnew_nonce_hash3, 16).str()).arg(mb(authKeyData->new_nonce_buf, 41).str()));
return restart();
}
LOG(("AuthKey Error: dh_gen_fail received!"));
} return restart();
}
LOG(("AuthKey Error: unknown set_client_DH_params_answer received, typeId = %1").arg(res_client_DH_params.type()));
return restart();
}
void MTProtoConnectionPrivate::authKeyCreated() {
clearAuthKeyData();
connect(conn, SIGNAL(receivedData()), this, SLOT(handleReceived()));
if (sessionData->getSalt()) { // else receive salt in bad_server_salt first, then try to send all the requests
setState(MTProtoConnection::Connected);
if (restarted) {
emit resendAllAsync();
restarted = false;
}
}
toSendPingId = MTP::nonce<uint64>(); // get server_salt
emit needToSendAsync();
}
void MTProtoConnectionPrivate::clearAuthKeyData() {
if (authKeyData) {
#ifdef Q_OS_WIN // TODO
SecureZeroMemory(authKeyData, sizeof(AuthKeyCreateData));
if (!authKeyStrings->dh_prime.isEmpty()) SecureZeroMemory(authKeyStrings->dh_prime.data(), authKeyStrings->dh_prime.size());
if (!authKeyStrings->g_a.isEmpty()) SecureZeroMemory(authKeyStrings->g_a.data(), authKeyStrings->g_a.size());
#else
memset(authKeyData, 0, sizeof(AuthKeyCreateData));
if (!authKeyStrings->dh_prime.isEmpty()) memset(authKeyStrings->dh_prime.data(), 0, authKeyStrings->dh_prime.size());
if (!authKeyStrings->g_a.isEmpty()) memset(authKeyStrings->g_a.data(), 0, authKeyStrings->g_a.size());
#endif
delete authKeyData;
authKeyData = 0;
delete authKeyStrings;
authKeyStrings = 0;
}
}
void MTProtoConnectionPrivate::onError(bool mayBeBadKey) {
MTP_LOG(dc, ("Restarting after error, maybe bad key: %1..").arg(logBool(mayBeBadKey)));
return restart(mayBeBadKey);
}
void MTProtoConnectionPrivate::onReadyData() {
}
template <typename TRequest>
void MTProtoConnectionPrivate::sendRequestNotSecure(const TRequest &request) {
try {
mtpBuffer buffer;
uint32 requestSize = request.innerLength() >> 2;
buffer.resize(0);
buffer.reserve(8 + requestSize);
buffer.push_back(0); // tcp packet len
buffer.push_back(0); // tcp packet num
buffer.push_back(0);
buffer.push_back(0);
buffer.push_back(authKeyData->req_num);
buffer.push_back(unixtime());
buffer.push_back(requestSize * 4);
request.write(buffer);
buffer.push_back(0); // tcp crc32 hash
++authKeyData->msgs_sent;
DEBUG_LOG(("AuthKey Info: sending request, size: %1, num: %2, time: %3").arg(requestSize).arg(authKeyData->req_num).arg(buffer[5]));
conn->sendData(buffer);
onSentSome(buffer.size() * sizeof(mtpPrime));
} catch(Exception &e) {
return restart();
}
}
template <typename TResponse>
bool MTProtoConnectionPrivate::readResponseNotSecure(TResponse &response) {
onReceivedSome();
try {
if (conn->received().isEmpty()) {
LOG(("AuthKey Error: trying to read response from empty received list"));
return false;
}
mtpBuffer buffer(conn->received().front());
conn->received().pop_front();
const mtpPrime *answer(buffer.constData());
uint32 len = buffer.size();
if (len < 5) {
LOG(("AuthKey Error: bad request answer, len = %1").arg(len * sizeof(mtpPrime)));
DEBUG_LOG(("AuthKey Error: answer bytes %1").arg(mb(answer, len * sizeof(mtpPrime)).str()));
return false;
}
if (answer[0] != 0 || answer[1] != 0 || (((uint32)answer[2]) & 0x03) != 1/* || (unixtime() - answer[3] > 300) || (answer[3] - unixtime() > 60)*/) { // didnt sync time yet
LOG(("AuthKey Error: bad request answer start (%1 %2 %3)").arg(answer[0]).arg(answer[1]).arg(answer[2]));
DEBUG_LOG(("AuthKey Error: answer bytes %1").arg(mb(answer, len * sizeof(mtpPrime)).str()));
return false;
}
uint32 answerLen = (uint32)answer[4];
if (answerLen != (len - 5) * sizeof(mtpPrime)) {
LOG(("AuthKey Error: bad request answer %1 <> %2").arg(answerLen).arg((len - 5) * sizeof(mtpPrime)));
DEBUG_LOG(("AuthKey Error: answer bytes %1").arg(mb(answer, len * sizeof(mtpPrime)).str()));
return false;
}
const mtpPrime *from(answer + 5), *end(from + len - 5);
response.read(from, end);
} catch(Exception &e) {
return false;
}
return true;
}
bool MTProtoConnectionPrivate::sendRequest(mtpRequest &request, bool needAnyResponse) {
uint32 fullSize = request->size();
if (fullSize < 9) return false;
uint32 messageSize = mtpRequestData::messageSize(request);
if (messageSize < 5 || fullSize < messageSize + 4) return false;
ReadLockerAttempt lock(sessionData->keyMutex());
if (!lock) {
DEBUG_LOG(("MTP Info: could not lock key for read in sendBuffer(), dc %1, restarting..").arg(dc));
restart();
return false;
}
mtpAuthKeyPtr key(sessionData->getKey());
if (!key || key->keyId() != keyId) {
DEBUG_LOG(("MTP Error: auth_key id for dc %1 changed").arg(dc));
restart();
return false;
}
uint32 padding = fullSize - 4 - messageSize;
uint64 session(sessionData->getSession()), salt(sessionData->getSalt());
memcpy(request->data() + 0, &salt, 2 * sizeof(mtpPrime));
memcpy(request->data() + 2, &session, 2 * sizeof(mtpPrime));
const mtpPrime *from = request->constData() + 4;
MTP_LOG(dc, ("Send: ") + mtpTextSerialize(from, from + messageSize));
uchar encryptedSHA[20];
MTPint128 &msgKey(*(MTPint128*)(encryptedSHA + 4));
hashSha1(request->constData(), (fullSize - padding) * sizeof(mtpPrime), encryptedSHA);
mtpBuffer result;
result.resize(9 + fullSize);
*((uint64*)&result[2]) = keyId;
*((MTPint128*)&result[4]) = msgKey;
aesEncrypt(request->constData(), &result[8], fullSize * sizeof(mtpPrime), key, msgKey);
DEBUG_LOG(("MTP Info: sending request, size: %1, num: %2, time: %3").arg(fullSize + 6).arg((*request)[4]).arg((*request)[5]));
conn->setSentEncrypted();
conn->sendData(result);
if (needAnyResponse) {
onSentSome(result.size() * sizeof(mtpPrime));
}
return true;
}
mtpRequestId MTProtoConnectionPrivate::wasSent(mtpMsgId msgId) const {
if (msgId == pingMsgId) return mtpRequestId(0xFFFFFFFF);
{
QReadLocker locker(sessionData->haveSentMutex());
const mtpRequestMap &haveSent(sessionData->haveSentMap());
mtpRequestMap::const_iterator i = haveSent.constFind(msgId);
if (i != haveSent.cend()) return i.value()->requestId ? i.value()->requestId : mtpRequestId(0xFFFFFFFF);
}
{
QReadLocker locker(sessionData->toResendMutex());
const mtpRequestIdsMap &toResend(sessionData->toResendMap());
mtpRequestIdsMap::const_iterator i = toResend.constFind(msgId);
if (i != toResend.cend()) return i.value();
}
{
QReadLocker locker(sessionData->wereAckedMutex());
const mtpRequestIdsMap &wereAcked(sessionData->wereAckedMap());
mtpRequestIdsMap::const_iterator i = wereAcked.constFind(msgId);
if (i != wereAcked.cend()) return i.value();
}
return 0;
}
void MTProtoConnectionPrivate::lockKey() {
unlockKey();
sessionData->keyMutex()->lockForWrite();
myKeyLock = true;
}
void MTProtoConnectionPrivate::unlockKey() {
QReadLocker lockFinished(&sessionDataMutex);
if (!sessionData) return;
if (myKeyLock) {
myKeyLock = false;
sessionData->keyMutex()->unlock();
}
}
MTProtoConnectionPrivate::~MTProtoConnectionPrivate() {
doDisconnect();
}
void MTProtoConnectionPrivate::stop() {
QWriteLocker lockFinished(&sessionDataMutex);
sessionData = 0;
}
MTProtoConnection::~MTProtoConnection() {
}
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