/** * @file lltemplatemessagereader.cpp * @brief LLTemplateMessageReader class implementation. * * $LicenseInfo:firstyear=2007&license=viewergpl$ * * Copyright (c) 2007, Linden Research, Inc. * * Second Life Viewer Source Code * The source code in this file ("Source Code") is provided by Linden Lab * to you under the terms of the GNU General Public License, version 2.0 * ("GPL"), unless you have obtained a separate licensing agreement * ("Other License"), formally executed by you and Linden Lab. Terms of * the GPL can be found in doc/GPL-license.txt in this distribution, or * online at http://secondlife.com/developers/opensource/gplv2 * * There are special exceptions to the terms and conditions of the GPL as * it is applied to this Source Code. View the full text of the exception * in the file doc/FLOSS-exception.txt in this software distribution, or * online at http://secondlife.com/developers/opensource/flossexception * * By copying, modifying or distributing this software, you acknowledge * that you have read and understood your obligations described above, * and agree to abide by those obligations. * * ALL LINDEN LAB SOURCE CODE IS PROVIDED "AS IS." LINDEN LAB MAKES NO * WARRANTIES, EXPRESS, IMPLIED OR OTHERWISE, REGARDING ITS ACCURACY, * COMPLETENESS OR PERFORMANCE. * $/LicenseInfo$ */ #include "linden_common.h" #include "lltemplatemessagereader.h" #include "llfasttimer.h" #include "llmessagebuilder.h" #include "llmessagetemplate.h" #include "llquaternion.h" #include "message.h" #include "u64.h" #include "v3dmath.h" #include "v3math.h" #include "v4math.h" LLTemplateMessageReader::LLTemplateMessageReader(message_template_number_map_t& number_template_map) : mReceiveSize(0), mCurrentRMessageTemplate(NULL), mCurrentRMessageData(NULL), mMessageNumbers(number_template_map) { } //virtual LLTemplateMessageReader::~LLTemplateMessageReader() { delete mCurrentRMessageData; mCurrentRMessageData = NULL; } //virtual void LLTemplateMessageReader::clearMessage() { mReceiveSize = -1; mCurrentRMessageTemplate = NULL; delete mCurrentRMessageData; mCurrentRMessageData = NULL; } void LLTemplateMessageReader::getData(const char *blockname, const char *varname, void *datap, S32 size, S32 blocknum, S32 max_size) { // is there a message ready to go? if (mReceiveSize == -1) { llerrs << "No message waiting for decode 2!" << llendl; return; } if (!mCurrentRMessageData) { llerrs << "Invalid mCurrentMessageData in getData!" << llendl; return; } char *bnamep = (char *)blockname + blocknum; // this works because it's just a hash. The bnamep is never derefference char *vnamep = (char *)varname; LLMsgData::msg_blk_data_map_t::const_iterator iter = mCurrentRMessageData->mMemberBlocks.find(bnamep); if (iter == mCurrentRMessageData->mMemberBlocks.end()) { llerrs << "Block " << blockname << " #" << blocknum << " not in message " << mCurrentRMessageData->mName << llendl; return; } LLMsgBlkData *msg_block_data = iter->second; LLMsgVarData& vardata = msg_block_data->mMemberVarData[vnamep]; if (!vardata.getName()) { llerrs << "Variable "<< vnamep << " not in message " << mCurrentRMessageData->mName<< " block " << bnamep << llendl; return; } if (size && size != vardata.getSize()) { llerrs << "Msg " << mCurrentRMessageData->mName << " variable " << vnamep << " is size " << vardata.getSize() << " but copying into buffer of size " << size << llendl; return; } const S32 vardata_size = vardata.getSize(); if( max_size >= vardata_size ) { switch( vardata_size ) { case 1: *((U8*)datap) = *((U8*)vardata.getData()); break; case 2: *((U16*)datap) = *((U16*)vardata.getData()); break; case 4: *((U32*)datap) = *((U32*)vardata.getData()); break; case 8: ((U32*)datap)[0] = ((U32*)vardata.getData())[0]; ((U32*)datap)[1] = ((U32*)vardata.getData())[1]; break; default: memcpy(datap, vardata.getData(), vardata_size); break; } } else { llwarns << "Msg " << mCurrentRMessageData->mName << " variable " << vnamep << " is size " << vardata.getSize() << " but truncated to max size of " << max_size << llendl; memcpy(datap, vardata.getData(), max_size); } } S32 LLTemplateMessageReader::getNumberOfBlocks(const char *blockname) { // is there a message ready to go? if (mReceiveSize == -1) { llerrs << "No message waiting for decode 3!" << llendl; return -1; } if (!mCurrentRMessageData) { llerrs << "Invalid mCurrentRMessageData in getData!" << llendl; return -1; } char *bnamep = (char *)blockname; LLMsgData::msg_blk_data_map_t::const_iterator iter = mCurrentRMessageData->mMemberBlocks.find(bnamep); if (iter == mCurrentRMessageData->mMemberBlocks.end()) { // sprintf(errmsg, "Block %s not in message %s", bnamep, mCurrentRMessageData->mName); // llerrs << errmsg << llendl; // return -1; return 0; } return (iter->second)->mBlockNumber; } S32 LLTemplateMessageReader::getSize(const char *blockname, const char *varname) { // is there a message ready to go? if (mReceiveSize == -1) { llerrs << "No message waiting for decode 4!" << llendl; return -1; } if (!mCurrentRMessageData) { llerrs << "Invalid mCurrentRMessageData in getData!" << llendl; return -1; } char *bnamep = (char *)blockname; LLMsgData::msg_blk_data_map_t::const_iterator iter = mCurrentRMessageData->mMemberBlocks.find(bnamep); if (iter == mCurrentRMessageData->mMemberBlocks.end()) { llerrs << "Block " << bnamep << " not in message " << mCurrentRMessageData->mName << llendl; return -1; } char *vnamep = (char *)varname; LLMsgBlkData* msg_data = iter->second; LLMsgVarData& vardata = msg_data->mMemberVarData[vnamep]; if (!vardata.getName()) { llerrs << "Variable " << varname << " not in message " << mCurrentRMessageData->mName << " block " << bnamep << llendl; return -1; } if (mCurrentRMessageTemplate->mMemberBlocks[bnamep]->mType != MBT_SINGLE) { llerrs << "Block " << bnamep << " isn't type MBT_SINGLE," " use getSize with blocknum argument!" << llendl; return -1; } return vardata.getSize(); } S32 LLTemplateMessageReader::getSize(const char *blockname, S32 blocknum, const char *varname) { // is there a message ready to go? if (mReceiveSize == -1) { llerrs << "No message waiting for decode 5!" << llendl; return -1; } if (!mCurrentRMessageData) { llerrs << "Invalid mCurrentRMessageData in getData!" << llendl; return -1; } char *bnamep = (char *)blockname + blocknum; char *vnamep = (char *)varname; LLMsgData::msg_blk_data_map_t::const_iterator iter = mCurrentRMessageData->mMemberBlocks.find(bnamep); if (iter == mCurrentRMessageData->mMemberBlocks.end()) { llerrs << "Block " << bnamep << " not in message " << mCurrentRMessageData->mName << llendl; return -1; } LLMsgBlkData* msg_data = iter->second; LLMsgVarData& vardata = msg_data->mMemberVarData[vnamep]; if (!vardata.getName()) { llerrs << "Variable " << vnamep << " not in message " << mCurrentRMessageData->mName << " block " << bnamep << llendl; return -1; } return vardata.getSize(); } void LLTemplateMessageReader::getBinaryData(const char *blockname, const char *varname, void *datap, S32 size, S32 blocknum, S32 max_size) { getData(blockname, varname, datap, size, blocknum, max_size); } void LLTemplateMessageReader::getS8(const char *block, const char *var, S8 &u, S32 blocknum) { getData(block, var, &u, sizeof(S8), blocknum); } void LLTemplateMessageReader::getU8(const char *block, const char *var, U8 &u, S32 blocknum) { getData(block, var, &u, sizeof(U8), blocknum); } void LLTemplateMessageReader::getBOOL(const char *block, const char *var, BOOL &b, S32 blocknum ) { U8 value; getData(block, var, &value, sizeof(U8), blocknum); b = (BOOL) value; } void LLTemplateMessageReader::getS16(const char *block, const char *var, S16 &d, S32 blocknum) { getData(block, var, &d, sizeof(S16), blocknum); } void LLTemplateMessageReader::getU16(const char *block, const char *var, U16 &d, S32 blocknum) { getData(block, var, &d, sizeof(U16), blocknum); } void LLTemplateMessageReader::getS32(const char *block, const char *var, S32 &d, S32 blocknum) { getData(block, var, &d, sizeof(S32), blocknum); } void LLTemplateMessageReader::getU32(const char *block, const char *var, U32 &d, S32 blocknum) { getData(block, var, &d, sizeof(U32), blocknum); } void LLTemplateMessageReader::getU64(const char *block, const char *var, U64 &d, S32 blocknum) { getData(block, var, &d, sizeof(U64), blocknum); } void LLTemplateMessageReader::getF32(const char *block, const char *var, F32 &d, S32 blocknum) { getData(block, var, &d, sizeof(F32), blocknum); if( !llfinite( d ) ) { llwarns << "non-finite in getF32Fast " << block << " " << var << llendl; d = 0; } } void LLTemplateMessageReader::getF64(const char *block, const char *var, F64 &d, S32 blocknum) { getData(block, var, &d, sizeof(F64), blocknum); if( !llfinite( d ) ) { llwarns << "non-finite in getF64Fast " << block << " " << var << llendl; d = 0; } } void LLTemplateMessageReader::getVector3(const char *block, const char *var, LLVector3 &v, S32 blocknum ) { getData(block, var, &v.mV[0], sizeof(v.mV), blocknum); if( !v.isFinite() ) { llwarns << "non-finite in getVector3Fast " << block << " " << var << llendl; v.zeroVec(); } } void LLTemplateMessageReader::getVector4(const char *block, const char *var, LLVector4 &v, S32 blocknum) { getData(block, var, &v.mV[0], sizeof(v.mV), blocknum); if( !v.isFinite() ) { llwarns << "non-finite in getVector4Fast " << block << " " << var << llendl; v.zeroVec(); } } void LLTemplateMessageReader::getVector3d(const char *block, const char *var, LLVector3d &v, S32 blocknum ) { getData(block, var, &v.mdV[0], sizeof(v.mdV), blocknum); if( !v.isFinite() ) { llwarns << "non-finite in getVector3dFast " << block << " " << var << llendl; v.zeroVec(); } } void LLTemplateMessageReader::getQuat(const char *block, const char *var, LLQuaternion &q, S32 blocknum) { LLVector3 vec; getData(block, var, &vec.mV[0], sizeof(vec.mV), blocknum); if( vec.isFinite() ) { q.unpackFromVector3( vec ); } else { llwarns << "non-finite in getQuatFast " << block << " " << var << llendl; q.loadIdentity(); } } void LLTemplateMessageReader::getUUID(const char *block, const char *var, LLUUID &u, S32 blocknum) { getData(block, var, &u.mData[0], sizeof(u.mData), blocknum); } inline void LLTemplateMessageReader::getIPAddr(const char *block, const char *var, U32 &u, S32 blocknum) { getData(block, var, &u, sizeof(U32), blocknum); } inline void LLTemplateMessageReader::getIPPort(const char *block, const char *var, U16 &u, S32 blocknum) { getData(block, var, &u, sizeof(U16), blocknum); u = ntohs(u); } inline void LLTemplateMessageReader::getString(const char *block, const char *var, S32 buffer_size, char *s, S32 blocknum ) { s[0] = '\0'; getData(block, var, s, 0, blocknum, buffer_size); s[buffer_size - 1] = '\0'; } //virtual S32 LLTemplateMessageReader::getMessageSize() const { return mReceiveSize; } // Returns template for the message contained in buffer BOOL LLTemplateMessageReader::decodeTemplate( const U8* buffer, S32 buffer_size, // inputs LLMessageTemplate** msg_template ) // outputs { const U8* header = buffer + LL_PACKET_ID_SIZE; // is there a message ready to go? if (buffer_size <= 0) { llwarns << "No message waiting for decode!" << llendl; return(FALSE); } U32 num = 0; if (header[0] != 255) { // high frequency message num = header[0]; } else if ((buffer_size >= ((S32) LL_MINIMUM_VALID_PACKET_SIZE + 1)) && (header[1] != 255)) { // medium frequency message num = (255 << 8) | header[1]; } else if ((buffer_size >= ((S32) LL_MINIMUM_VALID_PACKET_SIZE + 3)) && (header[1] == 255)) { // low frequency message U16 message_id_U16 = 0; // I think this check busts the message system. // it appears that if there is a NULL in the message #, it won't copy it.... // what was the goal? //if(header[2]) memcpy(&message_id_U16, &header[2], 2); // dependant on endian-ness: // U32 temp = (255 << 24) | (255 << 16) | header[2]; // independant of endian-ness: message_id_U16 = ntohs(message_id_U16); num = 0xFFFF0000 | message_id_U16; } else // bogus packet received (too short) { llwarns << "Packet with unusable length received (too short): " << buffer_size << llendl; return(FALSE); } LLMessageTemplate* temp = get_ptr_in_map(mMessageNumbers,num); if (temp) { *msg_template = temp; } else { llwarns << "Message #" << std::hex << num << std::dec << " received but not registered!" << llendl; gMessageSystem->callExceptionFunc(MX_UNREGISTERED_MESSAGE); return(FALSE); } return(TRUE); } void LLTemplateMessageReader::logRanOffEndOfPacket( const LLHost& host, const S32 where, const S32 wanted ) { // we've run off the end of the packet! llwarns << "Ran off end of packet " << mCurrentRMessageTemplate->mName // << " with id " << mCurrentRecvPacketID << " from " << host << " trying to read " << wanted << " bytes at position " << where << " going past packet end at " << mReceiveSize << llendl; if(gMessageSystem->mVerboseLog) { llinfos << "MSG: -> " << host << "\tREAD PAST END:\t" // << mCurrentRecvPacketID << " " << getMessageName() << llendl; } gMessageSystem->callExceptionFunc(MX_RAN_OFF_END_OF_PACKET); } // decode a given message BOOL LLTemplateMessageReader::decodeData(const U8* buffer, const LLHost& sender ) { llassert( mReceiveSize >= 0 ); llassert( mCurrentRMessageTemplate); llassert( !mCurrentRMessageData ); delete mCurrentRMessageData; // just to make sure // The offset tells us how may bytes to skip after the end of the // message name. U8 offset = buffer[PHL_OFFSET]; S32 decode_pos = LL_PACKET_ID_SIZE + (S32)(mCurrentRMessageTemplate->mFrequency) + offset; // create base working data set mCurrentRMessageData = new LLMsgData(mCurrentRMessageTemplate->mName); // loop through the template building the data structure as we go LLMessageTemplate::message_block_map_t::const_iterator iter; for(iter = mCurrentRMessageTemplate->mMemberBlocks.begin(); iter != mCurrentRMessageTemplate->mMemberBlocks.end(); ++iter) { LLMessageBlock* mbci = *iter; U8 repeat_number; S32 i; // how many of this block? if (mbci->mType == MBT_SINGLE) { // just one repeat_number = 1; } else if (mbci->mType == MBT_MULTIPLE) { // a known number repeat_number = mbci->mNumber; } else if (mbci->mType == MBT_VARIABLE) { // need to read the number from the message // repeat number is a single byte if (decode_pos >= mReceiveSize) { logRanOffEndOfPacket(sender, decode_pos, 1); // default to 0 repeats repeat_number = 0; } else { repeat_number = buffer[decode_pos]; decode_pos++; } } else { llerrs << "Unknown block type" << llendl; return FALSE; } LLMsgBlkData* cur_data_block = NULL; // now loop through the block for (i = 0; i < repeat_number; i++) { if (i) { // build new name to prevent collisions // TODO: This should really change to a vector cur_data_block = new LLMsgBlkData(mbci->mName, repeat_number); cur_data_block->mName = mbci->mName + i; } else { cur_data_block = new LLMsgBlkData(mbci->mName, repeat_number); } // add the block to the message mCurrentRMessageData->addBlock(cur_data_block); // now read the variables for (LLMessageBlock::message_variable_map_t::const_iterator iter = mbci->mMemberVariables.begin(); iter != mbci->mMemberVariables.end(); iter++) { const LLMessageVariable& mvci = **iter; // ok, build out the variables // add variable block cur_data_block->addVariable(mvci.getName(), mvci.getType()); // what type of variable? if (mvci.getType() == MVT_VARIABLE) { // variable, get the number of bytes to read from the template S32 data_size = mvci.getSize(); U8 tsizeb = 0; U16 tsizeh = 0; U32 tsize = 0; if ((decode_pos + data_size) > mReceiveSize) { logRanOffEndOfPacket(sender, decode_pos, data_size); // default to 0 length variable blocks tsize = 0; } else { switch(data_size) { case 1: htonmemcpy(&tsizeb, &buffer[decode_pos], MVT_U8, 1); tsize = tsizeb; break; case 2: htonmemcpy(&tsizeh, &buffer[decode_pos], MVT_U16, 2); tsize = tsizeh; break; case 4: htonmemcpy(&tsize, &buffer[decode_pos], MVT_U32, 4); break; default: llerrs << "Attempting to read variable field with unknown size of " << data_size << llendl; break; } } decode_pos += data_size; cur_data_block->addData(mvci.getName(), &buffer[decode_pos], tsize, mvci.getType()); decode_pos += tsize; } else { // fixed! // so, copy data pointer and set data size to fixed size if ((decode_pos + mvci.getSize()) > mReceiveSize) { logRanOffEndOfPacket(sender, decode_pos, mvci.getSize()); // default to 0s. U32 size = mvci.getSize(); std::vector data(size); memset(&(data[0]), 0, size); cur_data_block->addData(mvci.getName(), &(data[0]), size, mvci.getType()); } else { cur_data_block->addData(mvci.getName(), &buffer[decode_pos], mvci.getSize(), mvci.getType()); } decode_pos += mvci.getSize(); } } } } if (mCurrentRMessageData->mMemberBlocks.empty() && !mCurrentRMessageTemplate->mMemberBlocks.empty()) { lldebugs << "Empty message '" << mCurrentRMessageTemplate->mName << "' (no blocks)" << llendl; return FALSE; } { static LLTimer decode_timer; if(LLMessageReader::getTimeDecodes() || gMessageSystem->getTimingCallback()) { decode_timer.reset(); } { LLFastTimer t(LLFastTimer::FTM_PROCESS_MESSAGES); if( !mCurrentRMessageTemplate->callHandlerFunc(gMessageSystem) ) { llwarns << "Message from " << sender << " with no handler function received: " << mCurrentRMessageTemplate->mName << llendl; } } if(LLMessageReader::getTimeDecodes() || gMessageSystem->getTimingCallback()) { F32 decode_time = decode_timer.getElapsedTimeF32(); if (gMessageSystem->getTimingCallback()) { (gMessageSystem->getTimingCallback())(mCurrentRMessageTemplate->mName, decode_time, gMessageSystem->getTimingCallbackData()); } if (LLMessageReader::getTimeDecodes()) { mCurrentRMessageTemplate->mDecodeTimeThisFrame += decode_time; mCurrentRMessageTemplate->mTotalDecoded++; mCurrentRMessageTemplate->mTotalDecodeTime += decode_time; if( mCurrentRMessageTemplate->mMaxDecodeTimePerMsg < decode_time ) { mCurrentRMessageTemplate->mMaxDecodeTimePerMsg = decode_time; } if(decode_time > LLMessageReader::getTimeDecodesSpamThreshold()) { lldebugs << "--------- Message " << mCurrentRMessageTemplate->mName << " decode took " << decode_time << " seconds. (" << mCurrentRMessageTemplate->mMaxDecodeTimePerMsg << " max, " << (mCurrentRMessageTemplate->mTotalDecodeTime / mCurrentRMessageTemplate->mTotalDecoded) << " avg)" << llendl; } } } } return TRUE; } BOOL LLTemplateMessageReader::validateMessage(const U8* buffer, S32 buffer_size, const LLHost& sender) { mReceiveSize = buffer_size; BOOL result = decodeTemplate(buffer, buffer_size, &mCurrentRMessageTemplate ); if(result) { mCurrentRMessageTemplate->mReceiveCount++; lldebugst(LLERR_MESSAGE) << "MessageRecvd:" << mCurrentRMessageTemplate->mName << " from " << sender << llendl; } return result; } BOOL LLTemplateMessageReader::readMessage(const U8* buffer, const LLHost& sender) { return decodeData(buffer, sender); } //virtual const char* LLTemplateMessageReader::getMessageName() const { if (!mCurrentRMessageTemplate) { llwarns << "no mCurrentRMessageTemplate" << llendl; return ""; } return mCurrentRMessageTemplate->mName; } //virtual bool LLTemplateMessageReader::isTrusted() const { return mCurrentRMessageTemplate->getTrust() == MT_TRUST; } //virtual bool LLTemplateMessageReader::isBanned(bool trustedSource) const { return mCurrentRMessageTemplate->isBanned(trustedSource); } //virtual void LLTemplateMessageReader::copyToBuilder(LLMessageBuilder& builder) const { if(NULL == mCurrentRMessageTemplate) { return; } builder.copyFromMessageData(*mCurrentRMessageData); }