/*
EQ2Emulator: Everquest II Server Emulator
Copyright (C) 2007 EQ2EMulator Development Team (http://www.eq2emulator.net)
This file is part of EQ2Emulator.
EQ2Emulator 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.
EQ2Emulator 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.
You should have received a copy of the GNU General Public License
along with EQ2Emulator. If not, see .
*/
#ifdef WIN32
#include
#include
#endif
#include "debug.h"
#include
#include
#include
#include
#include
#include
#ifdef WIN32
#include
#else
#include
#include
#include
#include
#include
#include
#include
#endif
#include "EQPacket.h"
#include "EQStream.h"
#include "EQStreamFactory.h"
#include "misc.h"
#include "Mutex.h"
#include "op_codes.h"
#include "CRC16.h"
#include "packet_dump.h"
#ifdef LOGIN
#include "../LoginServer/login_structs.h"
#endif
#include "EQ2_Common_Structs.h"
#include "Log.h"
uint16 EQStream::MaxWindowSize=2048;
void EQStream::init(bool resetSession) {
if (resetSession)
{
streamactive = false;
sessionAttempts = 0;
}
timeout_delays = 0;
MInUse.lock();
active_users = 0;
MInUse.unlock();
Session=0;
Key=0;
MaxLen=0;
NextInSeq=0;
NextOutSeq=0;
CombinedAppPacket=NULL;
MAcks.lock();
MaxAckReceived = -1;
NextAckToSend = -1;
LastAckSent = -1;
MAcks.unlock();
LastSeqSent=-1;
MaxSends=5;
LastPacket=Timer::GetCurrentTime2();
oversize_buffer=NULL;
oversize_length=0;
oversize_offset=0;
Factory = NULL;
MRate.lock();
RateThreshold=RATEBASE/250;
DecayRate=DECAYBASE/250;
MRate.unlock();
BytesWritten=0;
SequencedBase = 0;
AverageDelta = 500;
crypto->setRC4Key(0);
retransmittimer = Timer::GetCurrentTime2();
retransmittimeout = 500 * RETRANSMIT_TIMEOUT_MULT;
if (uint16(SequencedBase + SequencedQueue.size()) != NextOutSeq) {
LogWrite(PACKET__DEBUG, 9, "Packet", "init Invalid Sequenced queue: BS %u + SQ %u != NOS %u", SequencedBase, SequencedQueue.size(), NextOutSeq);
}
}
EQStream::EQStream(sockaddr_in addr){
crypto = new Crypto();
resend_que_timer = new Timer(1000);
combine_timer = new Timer(250); //250 milliseconds
combine_timer->Start();
resend_que_timer->Start();
init();
remote_ip=addr.sin_addr.s_addr;
remote_port=addr.sin_port;
State=CLOSED;
StreamType=UnknownStream;
compressed=true;
encoded=false;
app_opcode_size=2;
#ifdef WIN32
ZeroMemory(&stream, sizeof(z_stream));
#else
bzero(&stream, sizeof(z_stream));
#endif
stream.zalloc = (alloc_func)0;
stream.zfree = (free_func)0;
stream.opaque = (voidpf)0;
deflateInit2(&stream, 9, Z_DEFLATED, 13, 9, Z_DEFAULT_STRATEGY);
//deflateInit(&stream, 5);
compressed_offset = 0;
client_version = 0;
received_packets = 0;
sent_packets = 0;
#ifdef WRITE_PACKETS
write_packets = 0;
char write_packets_filename[64];
snprintf(write_packets_filename, sizeof(write_packets_filename), "PacketLog%i.log", Timer::GetCurrentTime2());
write_packets = fopen(write_packets_filename, "w+");
#endif
}
EQProtocolPacket* EQStream::ProcessEncryptedData(uchar* data, int32 size, int16 opcode){
//cout << "B4:\n";
//DumpPacket(data, size);
/*if(size >= 2 && data[0] == 0 && data[1] == 0){
cout << "Attempting to fix packet!\n";
//Have to fix bad packet from client or it will screw up encryption :P
size--;
data++;
}*/
crypto->RC4Decrypt(data,size);
int8 offset = 0;
if(data[0] == 0xFF && size > 2){
offset = 3;
memcpy(&opcode, data+sizeof(int8), sizeof(int16));
}
else{
offset = 1;
memcpy(&opcode, data, sizeof(int8));
}
//cout << "After:\n";
//DumpPacket(data, size);
return new EQProtocolPacket(opcode, data+offset, size - offset);
}
EQProtocolPacket* EQStream::ProcessEncryptedPacket(EQProtocolPacket *p){
EQProtocolPacket* ret = NULL;
if(p->opcode == OP_Packet && p->size > 2)
ret = ProcessEncryptedData(p->pBuffer+2, p->size-2, p->opcode);
else
ret = ProcessEncryptedData(p->pBuffer, p->size, p->opcode);
return ret;
}
bool EQStream::HandleEmbeddedPacket(EQProtocolPacket *p, int16 offset, int16 length){
if(p && p->size >= ((uint32)(offset+2))){
if(p->pBuffer[offset] == 0 && p->pBuffer[offset+1] == 0x19){
if(length == 0)
length = p->size-2-offset;
else
length-=2;
#ifdef LE_DEBUG
printf( "Creating OP_AppCombined Packet!\n");
#endif
EQProtocolPacket *subp=new EQProtocolPacket(OP_AppCombined, p->pBuffer+2+offset, length);
subp->copyInfo(p);
ProcessPacket(subp, p);
safe_delete(subp);
return true;
}
else if (p->pBuffer[offset] == 0 && p->pBuffer[offset + 1] == 0) {
if (length == 0)
length = p->size - 1 - offset;
else
length--;
#ifdef LE_DEBUG
LogWrite(PACKET__DEBUG, 0, "Packet", "Creating Opcode 0 Packet!");
DumpPacket(p->pBuffer + 1 + offset, length);
#endif
EQProtocolPacket* newpacket = ProcessEncryptedData(p->pBuffer + 1 + offset, length, OP_Packet);
if (newpacket) {
#ifdef LE_DEBUG
LogWrite(PACKET__DEBUG, 0, "Packet", "Result: ");
DumpPacket(newpacket);
#endif
EQApplicationPacket* ap = newpacket->MakeApplicationPacket(2);
if (ap->version == 0)
ap->version = client_version;
InboundQueuePush(ap);
#ifdef WRITE_PACKETS
WritePackets(ap->GetOpcodeName(), p->pBuffer + 1 + offset, length, false);
#endif
safe_delete(newpacket);
}
else
LogWrite(PACKET__ERROR, 0, "Packet", "No Packet!");
return true;
}
}
return false;
}
void EQStream::ProcessPacket(EQProtocolPacket *p, EQProtocolPacket* lastp)
{
uint32 processed=0,subpacket_length=0;
if (p) {
if (p->opcode!=OP_SessionRequest && p->opcode!=OP_SessionResponse && !Session) {
#ifdef EQN_DEBUG
LogWrite(PACKET__ERROR, 0, "Packet", "*** Session not initialized, packet ignored ");
//p->DumpRaw();
#endif
return;
}
//cout << "Received " << (int)p->opcode << ":\n";
//DumpPacket(p->pBuffer, p->size);
switch (p->opcode) {
case OP_Combined: {
processed=0;
int8 offset = 0;
int count = 0;
#ifdef LE_DEBUG
printf( "OP_Combined:\n");
DumpPacket(p);
#endif
while(processedsize) {
if ((subpacket_length=(unsigned char)*(p->pBuffer+processed))==0xff) {
subpacket_length = ntohs(*(uint16*)(p->pBuffer + processed + 1));
offset = 3;
}
else
offset = 1;
count++;
#ifdef LE_DEBUG
printf( "OP_Combined Packet %i (%u) (%u):\n", count, subpacket_length, processed);
#endif
bool isSubPacket = EQProtocolPacket::IsProtocolPacket(p->pBuffer + processed + offset, subpacket_length, false);
if (isSubPacket) {
EQProtocolPacket* subp = new EQProtocolPacket(p->pBuffer + processed + offset, subpacket_length);
subp->copyInfo(p);
//I've seen some garbage packets get sent with wrong protocol opcodes but the rest of the combine is still correct
//So don't break if GetProtocolPacket fails
#ifdef LE_DEBUG
printf( "Opcode %i:\n", subp->opcode);
DumpPacket(subp);
#endif
ProcessPacket(subp, p);
#ifdef LE_DEBUG
DumpPacket(subp);
#endif
delete subp;
}
else if (ntohs(*reinterpret_cast(p->pBuffer + processed + offset)) > 0x1e) {
//Garbage packet?
crypto->RC4Decrypt(p->pBuffer + processed + offset, subpacket_length);
LogWrite(PACKET__ERROR, 0, "Packet", "Garbage packet?!:");
printf("!!!!!!!!!Garbage Packet!!!!!!!!!!!!!:\n");
DumpPacket(p->pBuffer + processed + offset, subpacket_length);
}
processed+=subpacket_length+offset;
}
break;
}
case OP_AppCombined: {
processed=0;
EQProtocolPacket* newpacket = 0;
int8 offset = 0;
#ifdef LE_DEBUG
printf( "OP_AppCombined: \n");
DumpPacket(p);
#endif
int count = 0;
while(processedsize) {
count++;
if ((subpacket_length=(unsigned char)*(p->pBuffer+processed))==0xff) {
subpacket_length=ntohs(*(uint16 *)(p->pBuffer+processed+1));
offset = 3;
} else
offset = 1;
if(crypto->getRC4Key()==0 && p->size >= 70){
processRSAKey(p);
}
else if(crypto->isEncrypted()){
#ifdef LE_DEBUG
printf( "OP_AppCombined Packet %i (%u) (%u): \n", count, subpacket_length, processed);
DumpPacket(p->pBuffer+processed+offset, subpacket_length);
#endif
if(!HandleEmbeddedPacket(p, processed + offset, subpacket_length)){
#ifdef LE_DEBUG
printf( "OP_AppCombined Here:\n");
#endif
MCombineQueueLock.lock();
newpacket = ProcessEncryptedData(p->pBuffer+processed + offset, subpacket_length, OP_AppCombined);
MCombineQueueLock.unlock();
if(newpacket){
#ifdef LE_DEBUG
printf( "Opcode %i:\n", newpacket->opcode);
DumpPacket(newpacket);
#endif
EQApplicationPacket* ap = newpacket->MakeApplicationPacket(2);
#ifdef LE_DEBUG
printf( "OP_AppCombined Here2:\n");
DumpPacket(ap);
#endif
if (ap->version == 0)
ap->version = client_version;
#ifdef WRITE_PACKETS
WritePackets(ap->GetOpcodeName(), p->pBuffer + processed + offset, subpacket_length, false);
#endif
InboundQueuePush(ap);
safe_delete(newpacket);
}
}
}
processed+=subpacket_length+offset;
}
}
break;
case OP_Packet: {
if (!p->pBuffer || (p->Size() < 4))
{
break;
}
uint16 seq=ntohs(*(uint16 *)(p->pBuffer));
sint8 check=CompareSequence(NextInSeq,seq);
if (check == SeqFuture) {
#ifdef EQN_DEBUG
LogWrite(PACKET__DEBUG, 1, "Packet", "*** Future packet: Expecting Seq=%i, but got Seq=%i", NextInSeq, seq);
LogWrite(PACKET__DEBUG, 1, "Packet", "[Start]");
p->DumpRawHeader(seq);
LogWrite(PACKET__DEBUG, 1, "Packet", "[End]");
#endif
OutOfOrderpackets[seq] = p->Copy();
// Image (2020): Removed as this is bad contributes to infinite loop
//SendOutOfOrderAck(seq);
} else if (check == SeqPast) {
#ifdef EQN_DEBUG
LogWrite(PACKET__DEBUG, 1, "Packet", "*** Duplicate packet: Expecting Seq=%i, but got Seq=%i", NextInSeq, seq);
LogWrite(PACKET__DEBUG, 1, "Packet", "[Start]");
p->DumpRawHeader(seq);
LogWrite(PACKET__DEBUG, 1, "Packet", "[End]");
#endif
// Image (2020): Removed as this is bad contributes to infinite loop
//OutOfOrderpackets[seq] = p->Copy();
SendOutOfOrderAck(seq);
} else {
EQProtocolPacket* qp = RemoveQueue(seq);
if (qp) {
LogWrite(PACKET__DEBUG, 1, "Packet", "OP_Fragment: Removing older queued packet with sequence %i", seq);
delete qp;
}
SetNextAckToSend(seq);
NextInSeq++;
if(HandleEmbeddedPacket(p))
break;
if(crypto->getRC4Key()==0 && p && p->size >= 70){
processRSAKey(p);
}
else if(crypto->isEncrypted() && p){
MCombineQueueLock.lock();
EQProtocolPacket* newpacket = ProcessEncryptedPacket(p);
MCombineQueueLock.unlock();
if(newpacket){
EQApplicationPacket* ap = newpacket->MakeApplicationPacket(2);
if (ap->version == 0)
ap->version = client_version;
#ifdef WRITE_PACKETS
WritePackets(ap->GetOpcodeName(), p->pBuffer, p->size, false);
#endif
InboundQueuePush(ap);
safe_delete(newpacket);
}
}
}
}
break;
case OP_Fragment: {
if (!p->pBuffer || (p->Size() < 4))
{
break;
}
uint16 seq=ntohs(*(uint16 *)(p->pBuffer));
sint8 check=CompareSequence(NextInSeq,seq);
if (check == SeqFuture) {
#ifdef EQN_DEBUG
LogWrite(PACKET__DEBUG, 1, "Packet", "*** Future packet2: Expecting Seq=%i, but got Seq=%i", NextInSeq, seq);
LogWrite(PACKET__DEBUG, 1, "Packet", "[Start]");
//p->DumpRawHeader(seq);
LogWrite(PACKET__DEBUG, 1, "Packet", "[End]");
#endif
OutOfOrderpackets[seq] = p->Copy();
//SendOutOfOrderAck(seq);
} else if (check == SeqPast) {
#ifdef EQN_DEBUG
LogWrite(PACKET__DEBUG, 1, "Packet", "*** Duplicate packet2: Expecting Seq=%i, but got Seq=%i", NextInSeq, seq);
LogWrite(PACKET__DEBUG, 1, "Packet", "[Start]");
//p->DumpRawHeader(seq);
LogWrite(PACKET__DEBUG, 1, "Packet", "[End]");
#endif
//OutOfOrderpackets[seq] = p->Copy();
SendOutOfOrderAck(seq);
} else {
// In case we did queue one before as well.
EQProtocolPacket* qp = RemoveQueue(seq);
if (qp) {
LogWrite(PACKET__DEBUG, 1, "Packet", "OP_Fragment: Removing older queued packet with sequence %i", seq);
delete qp;
}
SetNextAckToSend(seq);
NextInSeq++;
if (oversize_buffer) {
memcpy(oversize_buffer+oversize_offset,p->pBuffer+2,p->size-2);
oversize_offset+=p->size-2;
//cout << "Oversized is " << oversize_offset << "/" << oversize_length << " (" << (p->size-2) << ") Seq=" << seq << endl;
if (oversize_offset==oversize_length) {
if (*(p->pBuffer+2)==0x00 && *(p->pBuffer+3)==0x19) {
EQProtocolPacket *subp=new EQProtocolPacket(oversize_buffer,oversize_offset);
subp->copyInfo(p);
ProcessPacket(subp, p);
delete subp;
} else {
if(crypto->isEncrypted() && p && p->size > 2){
MCombineQueueLock.lock();
EQProtocolPacket* p2 = ProcessEncryptedData(oversize_buffer, oversize_offset, p->opcode);
MCombineQueueLock.unlock();
EQApplicationPacket* ap = p2->MakeApplicationPacket(2);
ap->copyInfo(p);
if (ap->version == 0)
ap->version = client_version;
#ifdef WRITE_PACKETS
WritePackets(ap->GetOpcodeName(), oversize_buffer, oversize_offset, false);
#endif
ap->copyInfo(p);
InboundQueuePush(ap);
safe_delete(p2);
}
}
delete[] oversize_buffer;
oversize_buffer=NULL;
oversize_offset=0;
}
} else if (!oversize_buffer) {
oversize_length=ntohl(*(uint32 *)(p->pBuffer+2));
oversize_buffer=new unsigned char[oversize_length];
memcpy(oversize_buffer,p->pBuffer+6,p->size-6);
oversize_offset=p->size-6;
//cout << "Oversized is " << oversize_offset << "/" << oversize_length << " (" << (p->size-6) << ") Seq=" << seq << endl;
}
}
}
break;
case OP_KeepAlive: {
#ifndef COLLECTOR
NonSequencedPush(new EQProtocolPacket(p->opcode,p->pBuffer,p->size));
#endif
}
break;
case OP_Ack: {
if (!p->pBuffer || (p->Size() < 4))
{
LogWrite(PACKET__DEBUG, 9, "Packet", "Received OP_Ack that was of malformed size");
break;
}
uint16 seq = ntohs(*(uint16*)(p->pBuffer));
AckPackets(seq);
retransmittimer = Timer::GetCurrentTime2();
}
break;
case OP_SessionRequest: {
if (p->Size() < sizeof(SessionRequest))
{
break;
}
if (GetState() == ESTABLISHED) {
//_log(NET__ERROR, _L "Received OP_SessionRequest in ESTABLISHED state (%d) streamactive (%i) attempt (%i)" __L, GetState(), streamactive, sessionAttempts);
// client seems to try a max of 4 times (initial +3 retries) then gives up, giving it a few more attempts just in case
// streamactive means we identified the opcode, we cannot re-establish this connection
if (streamactive || (sessionAttempts > 30))
{
SendDisconnect(false);
SetState(CLOSED);
break;
}
}
sessionAttempts++;
init(GetState() != ESTABLISHED);
OutboundQueueClear();
SessionRequest *Request=(SessionRequest *)p->pBuffer;
Session=ntohl(Request->Session);
SetMaxLen(ntohl(Request->MaxLength));
#ifndef COLLECTOR
NextInSeq=0;
Key=0x33624702;
SendSessionResponse();
#endif
SetState(ESTABLISHED);
}
break;
case OP_SessionResponse: {
if (p->Size() < sizeof(SessionResponse))
{
break;
}
init();
OutboundQueueClear();
SetActive(true);
SessionResponse *Response=(SessionResponse *)p->pBuffer;
SetMaxLen(ntohl(Response->MaxLength));
Key=ntohl(Response->Key);
NextInSeq=0;
SetState(ESTABLISHED);
if (!Session)
Session=ntohl(Response->Session);
compressed=(Response->Format&FLAG_COMPRESSED);
encoded=(Response->Format&FLAG_ENCODED);
// Kinda kludgy, but trie for now
if (compressed) {
if (remote_port==9000 || (remote_port==0 && p->src_port==9000))
SetStreamType(WorldStream);
else
SetStreamType(ZoneStream);
} else if (encoded)
SetStreamType(ChatOrMailStream);
else
SetStreamType(LoginStream);
}
break;
case OP_SessionDisconnect: {
//NextInSeq=0;
SendDisconnect();
//SetState(CLOSED);
}
break;
case OP_OutOfOrderAck: {
if (!p->pBuffer || (p->Size() < 4))
{
LogWrite(PACKET__DEBUG, 9, "Packet", "Received OP_OutOfOrderAck that was of malformed size");
break;
}
uint16 seq = ntohs(*(uint16*)(p->pBuffer));
MOutboundQueue.lock();
if (uint16(SequencedBase + SequencedQueue.size()) != NextOutSeq) {
LogWrite(PACKET__DEBUG, 9, "Packet", "Pre-OOA Invalid Sequenced queue: BS %u + SQ %u != NOS %u", SequencedBase, SequencedQueue.size(), NextOutSeq);
}
//if the packet they got out of order is between our last acked packet and the last sent packet, then its valid.
if (CompareSequence(SequencedBase, seq) != SeqPast && CompareSequence(NextOutSeq, seq) == SeqPast) {
uint16 sqsize = SequencedQueue.size();
uint16 index = seq - SequencedBase;
LogWrite(PACKET__DEBUG, 9, "Packet", "OP_OutOfOrderAck marking packet acked in queue (queue index = %u, queue size = %u)", index, sqsize);
if (index < sqsize) {
SequencedQueue[index]->acked = true;
// flag packets for a resend
uint16 count = 0;
uint32 timeout = AverageDelta * 2 + 100;
for (auto sitr = SequencedQueue.begin(); sitr != SequencedQueue.end() && count < index; ++sitr, ++count) {
if (!(*sitr)->acked && (*sitr)->sent_time > 0 && (((*sitr)->sent_time + timeout) < Timer::GetCurrentTime2())) {
(*sitr)->sent_time = 0;
LogWrite(PACKET__DEBUG, 9, "Packet", "OP_OutOfOrderAck Flagging packet %u for retransmission", SequencedBase + count);
}
}
}
if (RETRANSMIT_TIMEOUT_MULT) {
retransmittimer = Timer::GetCurrentTime2();
}
}
else {
LogWrite(PACKET__DEBUG, 9, "Packet", "Received OP_OutOfOrderAck for out-of-window %u. Window (%u->%u)", seq, SequencedBase, NextOutSeq);
}
if (uint16(SequencedBase + SequencedQueue.size()) != NextOutSeq) {
LogWrite(PACKET__DEBUG, 9, "Packet", "Post-OOA Invalid Sequenced queue: BS %u + SQ %u != NOS %u", SequencedBase, SequencedQueue.size(), NextOutSeq);
}
MOutboundQueue.unlock();
}
break;
case OP_ServerKeyRequest:{
if (p->Size() < sizeof(ClientSessionStats))
{
//_log(NET__ERROR, _L "Received OP_SessionStatRequest that was of malformed size" __L);
break;
}
ClientSessionStats* Stats = (ClientSessionStats*)p->pBuffer;
int16 request_id = Stats->RequestID;
AdjustRates(ntohl(Stats->average_delta));
ServerSessionStats* stats=(ServerSessionStats*)p->pBuffer;
memset(stats, 0, sizeof(ServerSessionStats));
stats->RequestID = request_id;
stats->current_time = ntohl(Timer::GetCurrentTime2());
stats->sent_packets = ntohl(sent_packets);
stats->sent_packets2 = ntohl(sent_packets);
stats->received_packets = ntohl(received_packets);
stats->received_packets2 = ntohl(received_packets);
NonSequencedPush(new EQProtocolPacket(OP_SessionStatResponse,p->pBuffer,p->size));
if(!crypto->isEncrypted())
SendKeyRequest();
}
break;
case OP_SessionStatResponse: {
LogWrite(PACKET__INFO, 0, "Packet", "OP_SessionStatResponse");
}
break;
case OP_OutOfSession: {
LogWrite(PACKET__INFO, 0, "Packet", "OP_OutOfSession");
SendDisconnect();
SetState(CLOSED);
}
break;
default:
//EQApplicationPacket *ap = p->MakeApplicationPacket(app_opcode_size);
//InboundQueuePush(ap);
EQApplicationPacket* ap = p->MakeApplicationPacket(app_opcode_size);
if (ap->version == 0)
ap->version = client_version;
#ifdef WRITE_PACKETS
WritePackets(ap->GetOpcodeName(), p->pBuffer, p->size, false);
#endif
//InboundQueuePush(ap);
LogWrite(PACKET__INFO, 0, "Packet", "Received unknown packet type, not adding to inbound queue");
safe_delete(ap);
//SendDisconnect();
break;
}
}
}
int8 EQStream::EQ2_Compress(EQ2Packet* app, int8 offset){
#ifdef LE_DEBUG
printf( "Before Compress in %s, line %i:\n", __FUNCTION__, __LINE__);
DumpPacket(app);
#endif
uchar* pDataPtr = app->pBuffer + offset;
int xpandSize = app->size * 2;
uchar* deflate_buff = new uchar[xpandSize];
MCompressData.lock();
stream.next_in = pDataPtr;
stream.avail_in = app->size - offset;
stream.next_out = deflate_buff;
stream.avail_out = xpandSize;
int ret = deflate(&stream, Z_SYNC_FLUSH);
if (ret != Z_OK)
{
printf("ZLIB COMPRESSION RETFAIL: %i, %i (Ret: %i)\n", app->size, stream.avail_out, ret);
MCompressData.unlock();
safe_delete_array(deflate_buff);
return 0;
}
int32 newsize = xpandSize - stream.avail_out;
safe_delete_array(app->pBuffer);
app->size = newsize + offset;
app->pBuffer = new uchar[app->size];
app->pBuffer[(offset - 1)] = 1;
memcpy(app->pBuffer + offset, deflate_buff, newsize);
MCompressData.unlock();
safe_delete_array(deflate_buff);
#ifdef LE_DEBUG
printf( "After Compress in %s, line %i:\n", __FUNCTION__, __LINE__);
DumpPacket(app);
#endif
return offset - 1;
}
int16 EQStream::processRSAKey(EQProtocolPacket *p){
/*int16 limit = 0;
int8 offset = 13;
int8 offset2 = 0;
if(p->pBuffer[2] == 0)
limit = p->pBuffer[9];
else{
limit = p->pBuffer[5];
offset2 = 5;
offset-=1;
}
crypto->setRC4Key(Crypto::RSADecrypt(p->pBuffer + offset + (limit-8), 8));
return (limit + offset +1) - offset2;*/
if(p->pBuffer[0] == 0)
crypto->setRC4Key(Crypto::RSADecrypt(p->pBuffer + 62, 8));
else
crypto->setRC4Key(Crypto::RSADecrypt(p->pBuffer + 61, 8));
return 0;
}
void EQStream::SendKeyRequest(){
int32 crypto_key_size = 60;
int16 size = sizeof(KeyGen_Struct) + sizeof(KeyGen_End_Struct) + crypto_key_size;
EQ2Packet *outapp=new EQ2Packet(OP_WSLoginRequestMsg,NULL,size);
memcpy(&outapp->pBuffer[0], &crypto_key_size, sizeof(int32));
memset(&outapp->pBuffer[4], 0xFF, crypto_key_size);
memset(&outapp->pBuffer[size-5], 1, 1);
memset(&outapp->pBuffer[size-1], 1, 1);
EQ2QueuePacket(outapp);
}
void EQStream::EncryptPacket(EQ2Packet* app, int8 compress_offset, int8 offset){
if(app->size>2 && crypto->isEncrypted()){
app->packet_encrypted = true;
uchar* crypt_buff = app->pBuffer;
if(app->eq2_compressed)
crypto->RC4Encrypt(crypt_buff + compress_offset, app->size - compress_offset);
else
crypto->RC4Encrypt(crypt_buff + 2 + offset, app->size - 2 - offset);
}
}
void EQStream::EQ2QueuePacket(EQ2Packet* app, bool attempted_combine){
if(CheckActive()){
if(!attempted_combine){
MCombineQueueLock.lock();
combine_queue.push_back(app);
MCombineQueueLock.unlock();
}
else{
MCombineQueueLock.lock();
PreparePacket(app);
MCombineQueueLock.unlock();
#ifdef LE_DEBUG
printf( "After B in %s, line %i:\n", __FUNCTION__, __LINE__);
DumpPacket(app);
#endif
SendPacket(app);
}
}
}
void EQStream::UnPreparePacket(EQ2Packet* app){
if(app->pBuffer[2] == 0 && app->pBuffer[3] == 19){
uchar* new_buffer = new uchar[app->size-3];
memcpy(new_buffer+2, app->pBuffer+5, app->size-3);
delete[] app->pBuffer;
app->size-=3;
app->pBuffer = new_buffer;
}
}
#ifdef WRITE_PACKETS
char EQStream::GetChar(uchar in)
{
if (in < ' ' || in > '~')
return '.';
return (char)in;
}
void EQStream::WriteToFile(char* pFormat, ...) {
va_list args;
va_start(args, pFormat);
vfprintf(write_packets, pFormat, args);
va_end(args);
}
void EQStream::WritePackets(const char* opcodeName, uchar* data, int32 size, bool outgoing) {
MWritePackets.lock();
struct in_addr ip_addr;
ip_addr.s_addr = remote_ip;
char timebuffer[80];
time_t rawtime;
struct tm* timeinfo;
time(&rawtime);
timeinfo = localtime(&rawtime);
strftime(timebuffer, 80, "%m/%d/%Y %H:%M:%S", timeinfo);
if (outgoing)
WriteToFile("-- %s --\n%s\nSERVER -> %s\n", opcodeName, timebuffer, inet_ntoa(ip_addr));
else
WriteToFile("-- %s --\n%s\n%s -> SERVER\n", opcodeName, timebuffer, inet_ntoa(ip_addr));
int i;
int nLines = size / 16;
int nExtra = size % 16;
uchar* pPtr = data;
for (i = 0; i < nLines; i++)
{
WriteToFile("%4.4X:\t%2.2X %2.2X %2.2X %2.2X %2.2X %2.2X %2.2X %2.2X %2.2X %2.2X %2.2X %2.2X %2.2X %2.2X %2.2X %2.2X %c%c%c%c%c%c%c%c%c%c%c%c%c%c%c%c\n", i * 16, pPtr[0], pPtr[1], pPtr[2], pPtr[3], pPtr[4], pPtr[5], pPtr[6], pPtr[7], pPtr[8], pPtr[9], pPtr[10], pPtr[11], pPtr[12], pPtr[13], pPtr[14], pPtr[15], GetChar(pPtr[0]), GetChar(pPtr[1]), GetChar(pPtr[2]), GetChar(pPtr[3]), GetChar(pPtr[4]), GetChar(pPtr[5]), GetChar(pPtr[6]), GetChar(pPtr[7]), GetChar(pPtr[8]), GetChar(pPtr[9]), GetChar(pPtr[10]), GetChar(pPtr[11]), GetChar(pPtr[12]), GetChar(pPtr[13]), GetChar(pPtr[14]), GetChar(pPtr[15]));
pPtr += 16;
}
if (nExtra)
{
WriteToFile("%4.4X\t", nLines * 16);
for (i = 0; i < nExtra; i++)
{
WriteToFile("%2.2X ", pPtr[i]);
}
for (i; i < 16; i++)
WriteToFile(" ");
for (i = 0; i < nExtra; i++)
{
WriteToFile("%c", GetChar(pPtr[i]));
}
WriteToFile("\n");
}
WriteToFile("\n\n");
fflush(write_packets);
MWritePackets.unlock();
}
void EQStream::WritePackets(EQ2Packet* app, bool outgoing) {
if (app->version == 0)
app->version = client_version;
WritePackets(app->GetOpcodeName(), app->pBuffer, app->size, outgoing);
}
#endif
void EQStream::PreparePacket(EQ2Packet* app, int8 offset){
app->setVersion(client_version);
compressed_offset = 0;
#ifdef LE_DEBUG
printf( "Before A in %s, line %i:\n", __FUNCTION__, __LINE__);
DumpPacket(app);
#endif
if(!app->packet_prepared){
if(app->PreparePacket(MaxLen) == 255) //invalid version
return;
}
#ifdef LE_DEBUG
printf( "After Prepare in %s, line %i:\n", __FUNCTION__, __LINE__);
DumpPacket(app);
#endif
#ifdef WRITE_PACKETS
if (!app->eq2_compressed && !app->packet_encrypted)
WritePackets(app, true);
#endif
if(!app->eq2_compressed && app->size>128){
compressed_offset = EQ2_Compress(app);
if (compressed_offset)
app->eq2_compressed = true;
}
if(!app->packet_encrypted){
EncryptPacket(app, compressed_offset, offset);
if(app->size > 2 && app->pBuffer[2] == 0){
uchar* new_buffer = new uchar[app->size+1];
new_buffer[2] = 0;
memcpy(new_buffer+3, app->pBuffer+2, app->size-2);
delete[] app->pBuffer;
app->pBuffer = new_buffer;
app->size++;
}
}
#ifdef LE_DEBUG
printf( "After A in %s, line %i:\n", __FUNCTION__, __LINE__);
DumpPacket(app);
#endif
}
void EQStream::SendPacket(EQProtocolPacket *p)
{
uint32 chunksize,used;
uint32 length;
// Convert the EQApplicationPacket to 1 or more EQProtocolPackets
if (p->size>( MaxLen-8)) { // proto-op(2), seq(2), app-op(2) ... data ... crc(2)
uchar* tmpbuff=p->pBuffer;
length=p->size - 2;
EQProtocolPacket *out=new EQProtocolPacket(OP_Fragment,NULL,MaxLen-4);
*(uint32 *)(out->pBuffer+2)=htonl(length);
used=MaxLen-10;
memcpy(out->pBuffer+6,tmpbuff+2,used);
#ifdef LE_DEBUG
printf("(%s, %i) New Fragment:\n ", __FUNCTION__, __LINE__);
DumpPacket(out);
#endif
SequencedPush(out);
while (usedpBuffer+2,tmpbuff,1);
memcpy(out->pBuffer+2,tmpbuff+used+2,chunksize);
#ifdef LE_DEBUG
printf("Chunk: \n");
DumpPacket(out);
#endif
SequencedPush(out);
used+=chunksize;
}
#ifdef LE_DEBUG
printf( "ChunkDelete: \n");
DumpPacket(out);
//cerr << "1: Deleting 0x" << hex << (uint32)(p) << dec << endl;
#endif
delete p;
} else {
SequencedPush(p);
}
}
void EQStream::SendPacket(EQApplicationPacket *p)
{
uint32 chunksize,used;
uint32 length;
// Convert the EQApplicationPacket to 1 or more EQProtocolPackets
if (p->size>(MaxLen-8)) { // proto-op(2), seq(2), app-op(2) ... data ... crc(2)
//cout << "Making oversized packet for: " << endl;
//cout << p->size << endl;
//p->DumpRawHeader();
//dump_message(p->pBuffer,p->size,timestamp());
//cout << p->size << endl;
unsigned char *tmpbuff=new unsigned char[p->size+2];
//cout << hex << (int)tmpbuff << dec << endl;
length=p->serialize(tmpbuff);
EQProtocolPacket *out=new EQProtocolPacket(OP_Fragment,NULL,MaxLen-4);
*(uint32 *)(out->pBuffer+2)=htonl(p->Size());
memcpy(out->pBuffer+6,tmpbuff,MaxLen-10);
used=MaxLen-10;
SequencedPush(out);
//cout << "Chunk #" << ++i << " size=" << used << ", length-used=" << (length-used) << endl;
while (usedpBuffer+2,tmpbuff+used,chunksize);
out->size=chunksize+2;
SequencedPush(out);
used+=chunksize;
//cout << "Chunk #"<< ++i << " size=" << chunksize << ", length-used=" << (length-used) << endl;
}
//cerr << "1: Deleting 0x" << hex << (uint32)(p) << dec << endl;
delete p;
delete[] tmpbuff;
} else {
EQProtocolPacket *out=new EQProtocolPacket(OP_Packet,NULL,p->Size()+2);
p->serialize(out->pBuffer+2);
SequencedPush(out);
//cerr << "2: Deleting 0x" << hex << (uint32)(p) << dec << endl;
delete p;
}
}
void EQStream::SequencedPush(EQProtocolPacket *p)
{
p->setVersion(client_version);
MOutboundQueue.lock();
*(uint16 *)(p->pBuffer)=htons(NextOutSeq);
SequencedQueue.push_back(p);
p->sequence = NextOutSeq;
NextOutSeq++;
MOutboundQueue.unlock();
}
void EQStream::NonSequencedPush(EQProtocolPacket *p)
{
p->setVersion(client_version);
MOutboundQueue.lock();
NonSequencedQueue.push(p);
MOutboundQueue.unlock();
}
void EQStream::SendAck(uint16 seq)
{
uint16 Seq=htons(seq);
SetLastAckSent(seq);
NonSequencedPush(new EQProtocolPacket(OP_Ack,(unsigned char *)&Seq,sizeof(uint16)));
}
void EQStream::SendOutOfOrderAck(uint16 seq)
{
uint16 Seq=htons(seq);
NonSequencedPush(new EQProtocolPacket(OP_OutOfOrderAck,(unsigned char *)&Seq,sizeof(uint16)));
}
bool EQStream::CheckCombineQueue(){
bool ret = true; //processed all packets
MCombineQueueLock.lock();
if(combine_queue.size() > 0){
EQ2Packet* first = combine_queue.front();
combine_queue.pop_front();
if(combine_queue.size() == 0){ //nothing to combine this with
EQ2QueuePacket(first, true);
}
else{
PreparePacket(first);
EQ2Packet* second = 0;
bool combine_worked = false;
int16 count = 0;
while(combine_queue.size()){
count++;
second = combine_queue.front();
combine_queue.pop_front();
PreparePacket(second);
/*if(first->GetRawOpcode() != OP_AppCombined && first->pBuffer[2] == 0){
EQ2Packet* tmp = second;
second = first;
first = tmp;
}*/
if(!first->AppCombine(second)){
first->SetProtocolOpcode(OP_Packet);
if(combine_worked){
SequencedPush(first);
}
else{
EQ2QueuePacket(first, true);
}
first = second;
combine_worked = false;
}
else{
combine_worked = true;
//DumpPacket(first);
}
if(count >= 60 || first->size > 4000){ //other clients need packets too
ret = false;
break;
}
}
if(first){
first->SetProtocolOpcode(OP_Packet);
if(combine_worked){
SequencedPush(first);
}
else{
EQ2QueuePacket(first, true);
}
}
}
}
MCombineQueueLock.unlock();
return ret;
}
void EQStream::CheckResend(int eq_fd){
int32 curr = Timer::GetCurrentTime2();
EQProtocolPacket* packet = 0;
deque::iterator itr;
MResendQue.lock();
for(itr=resend_que.begin();itr!=resend_que.end();itr++){
packet = *itr;
if(packet->attempt_count >= 5){//tried to resend this packet 5 times, client must already have it but didnt ack it
safe_delete(packet);
itr = resend_que.erase(itr);
if(itr == resend_que.end())
break;
}
else{
if((curr - packet->sent_time) < 1000)
continue;
packet->sent_time -=1000;
packet->attempt_count++;
WritePacket(eq_fd, packet);
}
}
MResendQue.unlock();
}
//returns SeqFuture if `seq` is later than `expected_seq`
EQStream::SeqOrder EQStream::CompareSequence(uint16 expected_seq, uint16 seq)
{
if (expected_seq == seq) {
// Curent
return SeqInOrder;
}
else if ((seq > expected_seq && (uint32)seq < ((uint32)expected_seq + EQStream::MaxWindowSize)) || seq < (expected_seq - EQStream::MaxWindowSize)) {
// Future
return SeqFuture;
}
else {
// Past
return SeqPast;
}
}
void EQStream::AckPackets(uint16 seq)
{
std::deque::iterator itr, tmp;
MOutboundQueue.lock();
SeqOrder ord = CompareSequence(SequencedBase, seq);
if (ord == SeqInOrder) {
//they are not acking anything new...
LogWrite(PACKET__DEBUG, 9, "Packet", "Received an ack with no window advancement (seq %u)", seq);
}
else if (ord == SeqPast) {
//they are nacking blocks going back before our buffer, wtf?
LogWrite(PACKET__DEBUG, 9, "Packet", "Received an ack with backward window advancement (they gave %u, our window starts at %u). This is bad" , seq, SequencedBase);
}
else {
LogWrite(PACKET__DEBUG, 9, "Packet", "Received an ack up through sequence %u. Our base is %u", seq, SequencedBase);
//this is a good ack, we get to ack some blocks.
seq++; //we stop at the block right after their ack, counting on the wrap of both numbers.
while (SequencedBase != seq) {
if (SequencedQueue.empty()) {
LogWrite(PACKET__DEBUG, 9, "Packet", "OUT OF PACKETS acked packet with sequence %u. Next send is %u before this", (unsigned long)SequencedBase, SequencedQueue.size());
SequencedBase = NextOutSeq;
break;
}
LogWrite(PACKET__DEBUG, 9, "Packet", "Removing acked packet with sequence %u", (unsigned long)SequencedBase);
//clean out the acked packet
delete SequencedQueue.front();
SequencedQueue.pop_front();
//advance the base sequence number to the seq of the block after the one we just got rid of.
SequencedBase++;
}
if (uint16(SequencedBase + SequencedQueue.size()) != NextOutSeq) {
LogWrite(PACKET__DEBUG, 9, "Packet", "Post-Ack on %u Invalid Sequenced queue: BS %u + SQ %u != NOS %u", seq, SequencedBase, SequencedQueue.size(), NextOutSeq);
}
}
MOutboundQueue.unlock();
}
void EQStream::Write(int eq_fd)
{
queue ReadyToSend;
long maxack;
// Check our rate to make sure we can send more
MRate.lock();
sint32 threshold=RateThreshold;
MRate.unlock();
if (BytesWritten > threshold) {
//cout << "Over threshold: " << BytesWritten << " > " << threshold << endl;
return;
}
MCombinedAppPacket.lock();
EQApplicationPacket *CombPack=CombinedAppPacket;
CombinedAppPacket=NULL;
MCombinedAppPacket.unlock();
if (CombPack) {
SendPacket(CombPack);
}
// If we got more packets to we need to ack, send an ack on the highest one
MAcks.lock();
maxack=MaxAckReceived;
// Added from peaks findings
if (NextAckToSend>LastAckSent || LastAckSent == 0x0000ffff)
SendAck(NextAckToSend);
MAcks.unlock();
// Lock the outbound queues while we process
MOutboundQueue.lock();
// Adjust where we start sending in case we get a late ack
//if (maxack>LastSeqSent)
// LastSeqSent=maxack;
// Place to hold the base packet t combine into
EQProtocolPacket *p=NULL;
std::deque::iterator sitr;
// Find the next sequenced packet to send from the "queue"
sitr = SequencedQueue.begin();
uint16 count = 0;
// get to start of packets
while (sitr != SequencedQueue.end() && (*sitr)->sent_time > 0) {
++sitr;
++count;
}
bool SeqEmpty = false, NonSeqEmpty = false;
// Loop until both are empty or MaxSends is reached
while (!SeqEmpty || !NonSeqEmpty) {
// See if there are more non-sequenced packets left
if (!NonSequencedQueue.empty()) {
if (!p) {
// If we don't have a packet to try to combine into, use this one as the base
// And remove it form the queue
p = NonSequencedQueue.front();
LogWrite(PACKET__DEBUG, 9, "Packet", "Starting combined packet with non-seq packet of len %u",p->size);
NonSequencedQueue.pop();
}
else if (!p->combine(NonSequencedQueue.front())) {
// Trying to combine this packet with the base didn't work (too big maybe)
// So just send the base packet (we'll try this packet again later)
LogWrite(PACKET__DEBUG, 9, "Packet", "Combined packet full at len %u, next non-seq packet is len %u", p->size, (NonSequencedQueue.front())->size);
ReadyToSend.push(p);
BytesWritten += p->size;
p = nullptr;
if (BytesWritten > threshold) {
// Sent enough this round, lets stop to be fair
LogWrite(PACKET__DEBUG, 9, "Packet", "Exceeded write threshold in nonseq (%u > %u)", BytesWritten, threshold);
break;
}
}
else {
// Combine worked, so just remove this packet and it's spot in the queue
LogWrite(PACKET__DEBUG, 9, "Packet", "Combined non-seq packet of len %u, yeilding %u combined", (NonSequencedQueue.front())->size, p->size);
delete NonSequencedQueue.front();
NonSequencedQueue.pop();
}
}
else {
// No more non-sequenced packets
NonSeqEmpty = true;
}
if (sitr != SequencedQueue.end()) {
uint16 seq_send = SequencedBase + count; //just for logging...
if (SequencedQueue.empty()) {
LogWrite(PACKET__DEBUG, 9, "Packet", "Tried to write a packet with an empty queue (%u is past next out %u)", seq_send, NextOutSeq);
SeqEmpty = true;
continue;
}
if ((*sitr)->acked || (*sitr)->sent_time != 0) {
++sitr;
++count;
if (p) {
LogWrite(PACKET__DEBUG, 9, "Packet", "Final combined packet not full, len %u", p->size);
ReadyToSend.push(p);
BytesWritten += p->size;
p = nullptr;
}
LogWrite(PACKET__DEBUG, 9, "Packet", "Not retransmitting seq packet %u because already marked as acked", seq_send);
}
else if (!p) {
// If we don't have a packet to try to combine into, use this one as the base
// Copy it first as it will still live until it is acked
p = (*sitr)->Copy();
LogWrite(PACKET__DEBUG, 9, "Packet", "Starting combined packet with seq packet %u of len %u", seq_send, p->size);
(*sitr)->sent_time = Timer::GetCurrentTime2();
++sitr;
++count;
}
else if (!p->combine(*sitr)) {
// Trying to combine this packet with the base didn't work (too big maybe)
// So just send the base packet (we'll try this packet again later)
LogWrite(PACKET__DEBUG, 9, "Packet", "Combined packet full at len %u, next seq packet %u is len %u", p->size, seq_send + 1, (*sitr)->size);
ReadyToSend.push(p);
BytesWritten += p->size;
p = nullptr;
if ((*sitr)->opcode != OP_Fragment && BytesWritten > threshold) {
// Sent enough this round, lets stop to be fair
LogWrite(PACKET__DEBUG, 9, "Packet", "Exceeded write threshold in seq (%u > %u)", BytesWritten, threshold);
break;
}
}
else {
// Combine worked
LogWrite(PACKET__DEBUG, 9, "Packet", "Combined seq packet %u of len %u, yeilding %u combined", seq_send, (*sitr)->size, p->size);
(*sitr)->sent_time = Timer::GetCurrentTime2();
++sitr;
++count;
}
if (uint16(SequencedBase + SequencedQueue.size()) != NextOutSeq) {
LogWrite(PACKET__DEBUG, 9, "Packet", "Post send Invalid Sequenced queue: BS %u + SQ %u != NOS %u", SequencedBase, SequencedQueue.size(), NextOutSeq);
}
}
else {
// No more sequenced packets
SeqEmpty = true;
}
}
MOutboundQueue.unlock(); // Unlock the queue
// We have a packet still, must have run out of both seq and non-seq, so send it
if (p) {
LogWrite(PACKET__DEBUG, 9, "Packet", "Final combined packet not full, len %u", p->size);
ReadyToSend.push(p);
BytesWritten += p->size;
}
// Send all the packets we "made"
while (!ReadyToSend.empty()) {
p = ReadyToSend.front();
WritePacket(eq_fd, p);
delete p;
ReadyToSend.pop();
}
//see if we need to send our disconnect and finish our close
if (SeqEmpty && NonSeqEmpty) {
//no more data to send
if (GetState() == CLOSING) {
MOutboundQueue.lock();
if (SequencedQueue.size() > 0 )
LogWrite(PACKET__DEBUG, 9, "Packet", "All outgoing data flushed, client should be disconnecting, awaiting acknowledgement of SequencedQueue.");
else
{
LogWrite(PACKET__DEBUG, 9, "Packet", "All outgoing data flushed, disconnecting client.");
//we are waiting for the queues to empty, now we can do our disconnect.
//this packet will not actually go out until the next call to Write().
SendDisconnect();
//SetState(CLOSED);
}
MOutboundQueue.unlock();
}
}
}
void EQStream::WritePacket(int eq_fd, EQProtocolPacket *p)
{
uint32 length = 0;
sockaddr_in address;
unsigned char tmpbuffer[2048];
address.sin_family = AF_INET;
address.sin_addr.s_addr=remote_ip;
address.sin_port=remote_port;
#ifdef NOWAY
uint32 ip=address.sin_addr.s_addr;
cout << "Sending to: "
<< (int)*(unsigned char *)&ip
<< "." << (int)*((unsigned char *)&ip+1)
<< "." << (int)*((unsigned char *)&ip+2)
<< "." << (int)*((unsigned char *)&ip+3)
<< "," << (int)ntohs(address.sin_port) << "(" << p->size << ")" << endl;
p->DumpRaw();
cout << "-------------" << endl;
#endif
length=p->serialize(buffer);
if (p->opcode!=OP_SessionRequest && p->opcode!=OP_SessionResponse) {
if (compressed) {
BytesWritten -= p->size;
uint32 newlen=EQProtocolPacket::Compress(buffer,length,tmpbuffer,2048);
memcpy(buffer,tmpbuffer,newlen);
length=newlen;
BytesWritten += newlen;
}
if (encoded) {
EQProtocolPacket::ChatEncode(buffer,length,Key);
}
*(uint16 *)(buffer+length)=htons(CRC16(buffer,length,Key));
length+=2;
}
sent_packets++;
//dump_message_column(buffer,length,"Writer: ");
//cout << "Raw Data:\n";
//DumpPacket(buffer, length);
sendto(eq_fd,(char *)buffer,length,0,(sockaddr *)&address,sizeof(address));
}
EQProtocolPacket *EQStream::Read(int eq_fd, sockaddr_in *from)
{
int socklen;
int length=0;
unsigned char buffer[2048];
EQProtocolPacket *p=NULL;
char temp[15];
socklen=sizeof(sockaddr);
#ifdef WIN32
length=recvfrom(eq_fd, (char *)buffer, 2048, 0, (struct sockaddr*)from, (int *)&socklen);
#else
length=recvfrom(eq_fd, buffer, 2048, 0, (struct sockaddr*)from, (socklen_t *)&socklen);
#endif
if (length>=2) {
DumpPacket(buffer, length);
p=new EQProtocolPacket(buffer[1],&buffer[2],length-2);
uint32 ip=from->sin_addr.s_addr;
sprintf(temp,"%d.%d.%d.%d:%d",
*(unsigned char *)&ip,
*((unsigned char *)&ip+1),
*((unsigned char *)&ip+2),
*((unsigned char *)&ip+3),
ntohs(from->sin_port));
//cout << timestamp() << "Data from: " << temp << " OpCode 0x" << hex << setw(2) << setfill('0') << (int)p->opcode << dec << endl;
//dump_message(p->pBuffer,p->size,timestamp());
}
return p;
}
void EQStream::SendSessionResponse()
{
EQProtocolPacket *out=new EQProtocolPacket(OP_SessionResponse,NULL,sizeof(SessionResponse));
SessionResponse *Response=(SessionResponse *)out->pBuffer;
Response->Session=htonl(Session);
Response->MaxLength=htonl(MaxLen);
Response->UnknownA=2;
Response->Format=0;
if (compressed)
Response->Format|=FLAG_COMPRESSED;
if (encoded)
Response->Format|=FLAG_ENCODED;
Response->Key=htonl(Key);
out->size=sizeof(SessionResponse);
NonSequencedPush(out);
}
void EQStream::SendSessionRequest()
{
EQProtocolPacket *out=new EQProtocolPacket(OP_SessionRequest,NULL,sizeof(SessionRequest));
SessionRequest *Request=(SessionRequest *)out->pBuffer;
memset(Request,0,sizeof(SessionRequest));
Request->Session=htonl(time(NULL));
Request->MaxLength=htonl(512);
NonSequencedPush(out);
}
void EQStream::SendDisconnect(bool setstate)
{
try{
if(GetState() != ESTABLISHED)
return;
EQProtocolPacket *out=new EQProtocolPacket(OP_SessionDisconnect,NULL,sizeof(uint32)+sizeof(int16));
*(uint32 *)out->pBuffer=htonl(Session);
out->pBuffer[4] = 0;
out->pBuffer[5] = 6;
NonSequencedPush(out);
if(setstate)
SetState(CLOSING);
}
catch(...){}
}
void EQStream::InboundQueuePush(EQApplicationPacket *p)
{
MInboundQueue.lock();
InboundQueue.push_back(p);
MInboundQueue.unlock();
}
EQApplicationPacket *EQStream::PopPacket()
{
EQApplicationPacket *p=NULL;
MInboundQueue.lock();
if (InboundQueue.size()) {
p=InboundQueue.front();
InboundQueue.pop_front();
}
MInboundQueue.unlock();
if(p)
p->setVersion(client_version);
return p;
}
void EQStream::InboundQueueClear()
{
MInboundQueue.lock();
while(InboundQueue.size()){
delete InboundQueue.front();
InboundQueue.pop_front();
}
MInboundQueue.unlock();
}
void EQStream::EncryptPacket(uchar* data, int16 size){
if(size>6){
}
}
bool EQStream::HasOutgoingData()
{
bool flag;
//once closed, we have nothing more to say
if(CheckClosed())
return(false);
MOutboundQueue.lock();
flag=(!NonSequencedQueue.empty());
if (!flag) {
flag = (!SequencedQueue.empty());
}
MOutboundQueue.unlock();
if (!flag) {
MAcks.lock();
flag= (NextAckToSend>LastAckSent);
MAcks.unlock();
}
if (!flag) {
MCombinedAppPacket.lock();
flag=(CombinedAppPacket!=NULL);
MCombinedAppPacket.unlock();
}
return flag;
}
void EQStream::OutboundQueueClear()
{
MOutboundQueue.lock();
while(NonSequencedQueue.size()) {
delete NonSequencedQueue.front();
NonSequencedQueue.pop();
}
while(SequencedQueue.size()) {
delete SequencedQueue.front();
SequencedQueue.pop_front();
}
MOutboundQueue.unlock();
}
void EQStream::Process(const unsigned char *buffer, const uint32 length)
{
received_packets++;
static unsigned char newbuffer[2048];
uint32 newlength=0;
#ifdef LE_DEBUG
printf("ProcessBuffer:\n");
DumpPacket(buffer, length);
#endif
if (EQProtocolPacket::ValidateCRC(buffer,length,Key)) {
if (compressed) {
newlength=EQProtocolPacket::Decompress(buffer,length,newbuffer,2048);
#ifdef LE_DEBUG
printf("ProcessBufferDecompress:\n");
DumpPacket(buffer, newlength);
#endif
} else {
memcpy(newbuffer,buffer,length);
newlength=length;
if (encoded)
EQProtocolPacket::ChatDecode(newbuffer,newlength-2,Key);
}
if (buffer[1]!=0x01 && buffer[1]!=0x02 && buffer[1]!=0x1d)
newlength-=2;
#ifdef LE_DEBUG
printf("ResultProcessBuffer:\n");
DumpPacket(buffer, newlength);
#endif
EQProtocolPacket p(newbuffer,newlength);
ProcessPacket(&p);
ProcessQueue();
} else {
#ifdef EQN_DEBUG
cout << "Incoming packet failed checksum:" <(buffer),length,"CRC failed: ");
#endif
}
}
long EQStream::GetMaxAckReceived()
{
MAcks.lock();
long l=MaxAckReceived;
MAcks.unlock();
return l;
}
long EQStream::GetNextAckToSend()
{
MAcks.lock();
long l=NextAckToSend;
MAcks.unlock();
return l;
}
long EQStream::GetLastAckSent()
{
MAcks.lock();
long l=LastAckSent;
MAcks.unlock();
return l;
}
void EQStream::SetMaxAckReceived(uint32 seq)
{
deque::iterator itr;
MAcks.lock();
MaxAckReceived=seq;
MAcks.unlock();
MOutboundQueue.lock();
if (long(seq) > LastSeqSent)
LastSeqSent=seq;
MResendQue.lock();
EQProtocolPacket* packet = 0;
for(itr=resend_que.begin();itr!=resend_que.end();itr++){
packet = *itr;
if(packet && packet->sequence <= seq){
safe_delete(packet);
itr = resend_que.erase(itr);
if(itr == resend_que.end())
break;
}
}
MResendQue.unlock();
MOutboundQueue.unlock();
}
void EQStream::SetNextAckToSend(uint32 seq)
{
MAcks.lock();
NextAckToSend=seq;
MAcks.unlock();
}
void EQStream::SetLastAckSent(uint32 seq)
{
MAcks.lock();
LastAckSent=seq;
MAcks.unlock();
}
void EQStream::SetLastSeqSent(uint32 seq)
{
MOutboundQueue.lock();
LastSeqSent=seq;
MOutboundQueue.unlock();
}
void EQStream::SetStreamType(EQStreamType type)
{
StreamType=type;
switch (StreamType) {
case LoginStream:
app_opcode_size=1;
compressed=false;
encoded=false;
break;
case EQ2Stream:
app_opcode_size=2;
compressed=false;
encoded=false;
break;
case ChatOrMailStream:
case ChatStream:
case MailStream:
app_opcode_size=1;
compressed=false;
encoded=true;
break;
case ZoneStream:
case WorldStream:
default:
app_opcode_size=2;
compressed=true;
encoded=false;
break;
}
}
void EQStream::ProcessQueue()
{
if (OutOfOrderpackets.empty()) {
return;
}
EQProtocolPacket* qp = NULL;
while ((qp = RemoveQueue(NextInSeq)) != NULL) {
//_log(NET__DEBUG, _L "Processing Queued Packet: Seq=%d" __L, NextInSeq);
ProcessPacket(qp);
delete qp;
//_log(NET__APP_TRACE, _L "OP_Packet Queue size=%d" __L, PacketQueue.size());
}
}
EQProtocolPacket* EQStream::RemoveQueue(uint16 seq)
{
map::iterator itr;
EQProtocolPacket* qp = NULL;
if ((itr = OutOfOrderpackets.find(seq)) != OutOfOrderpackets.end()) {
qp = itr->second;
OutOfOrderpackets.erase(itr);
//_log(NET__APP_TRACE, _L "OP_Packet Queue size=%d" __L, PacketQueue.size());
}
return qp;
}
void EQStream::Decay()
{
MRate.lock();
uint32 rate=DecayRate;
MRate.unlock();
if (BytesWritten>0) {
BytesWritten-=rate;
if (BytesWritten<0)
BytesWritten=0;
}
int count = 0;
MOutboundQueue.lock();
for (auto sitr = SequencedQueue.begin(); sitr != SequencedQueue.end(); ++sitr, count++) {
if (!(*sitr)->acked && (*sitr)->sent_time > 0 && ((*sitr)->sent_time + retransmittimeout) < Timer::GetCurrentTime2()) {
(*sitr)->sent_time = 0;
LogWrite(PACKET__DEBUG, 9, "Packet", "Timeout exceeded for seq %u. Flagging packet for retransmission", SequencedBase + count);
}
}
MOutboundQueue.unlock();
}
void EQStream::AdjustRates(uint32 average_delta)
{
if (average_delta && (average_delta <= AVERAGE_DELTA_MAX)) {
MRate.lock();
AverageDelta = average_delta;
RateThreshold = RATEBASE / average_delta;
DecayRate = DECAYBASE / average_delta;
if (BytesWritten > RateThreshold)
BytesWritten = RateThreshold + DecayRate;
MRate.unlock();
}
else {
AverageDelta = AVERAGE_DELTA_MAX;
}
}