/** * @file lltemplatemessagebuilder.cpp * @brief LLTemplateMessageBuilder class implementation. * * $LicenseInfo:firstyear=2007&license=viewergpl$ * * Copyright (c) 2007-2008, 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://secondlifegrid.net/programs/open_source/licensing/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://secondlifegrid.net/programs/open_source/licensing/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 "lltemplatemessagebuilder.h" #include "llmessagetemplate.h" #include "llquaternion.h" #include "u64.h" #include "v3dmath.h" #include "v3math.h" #include "v4math.h" LLTemplateMessageBuilder::LLTemplateMessageBuilder(message_template_name_map_t& name_template_map) : mCurrentSMessageData(NULL), mCurrentSMessageTemplate(NULL), mCurrentSDataBlock(NULL), mCurrentSMessageName(NULL), mCurrentSBlockName(NULL), mbSBuilt(FALSE), mbSClear(TRUE), mCurrentSendTotal(0), mMessageTemplates(name_template_map) { } //virtual LLTemplateMessageBuilder::~LLTemplateMessageBuilder() { delete mCurrentSMessageData; mCurrentSMessageData = NULL; } // virtual void LLTemplateMessageBuilder::newMessage(const char *name) { mbSBuilt = FALSE; mbSClear = FALSE; mCurrentSendTotal = 0; delete mCurrentSMessageData; mCurrentSMessageData = NULL; char* namep = (char*)name; if (mMessageTemplates.count(namep) > 0) { mCurrentSMessageTemplate = mMessageTemplates[namep]; mCurrentSMessageData = new LLMsgData(namep); mCurrentSMessageName = namep; mCurrentSDataBlock = NULL; mCurrentSBlockName = NULL; // add at one of each block const LLMessageTemplate* msg_template = mMessageTemplates[namep]; if (msg_template->getDeprecation() != MD_NOTDEPRECATED) { llwarns << "Sending deprecated message " << namep << llendl; } LLMessageTemplate::message_block_map_t::const_iterator iter; for(iter = msg_template->mMemberBlocks.begin(); iter != msg_template->mMemberBlocks.end(); ++iter) { LLMessageBlock* ci = *iter; LLMsgBlkData* tblockp = new LLMsgBlkData(ci->mName, 0); mCurrentSMessageData->addBlock(tblockp); } } else { llerrs << "newMessage - Message " << name << " not registered" << llendl; } } // virtual void LLTemplateMessageBuilder::clearMessage() { mbSBuilt = FALSE; mbSClear = TRUE; mCurrentSendTotal = 0; mCurrentSMessageTemplate = NULL; delete mCurrentSMessageData; mCurrentSMessageData = NULL; mCurrentSMessageName = NULL; mCurrentSDataBlock = NULL; mCurrentSBlockName = NULL; } // virtual void LLTemplateMessageBuilder::nextBlock(const char* blockname) { char *bnamep = (char *)blockname; if (!mCurrentSMessageTemplate) { llerrs << "newMessage not called prior to setBlock" << llendl; return; } // now, does this block exist? const LLMessageBlock* template_data = mCurrentSMessageTemplate->getBlock(bnamep); if (!template_data) { llerrs << "LLTemplateMessageBuilder::nextBlock " << bnamep << " not a block in " << mCurrentSMessageTemplate->mName << llendl; return; } // ok, have we already set this block? LLMsgBlkData* block_data = mCurrentSMessageData->mMemberBlocks[bnamep]; if (block_data->mBlockNumber == 0) { // nope! set this as the current block block_data->mBlockNumber = 1; mCurrentSDataBlock = block_data; mCurrentSBlockName = bnamep; // add placeholders for each of the variables for (LLMessageBlock::message_variable_map_t::const_iterator iter = template_data->mMemberVariables.begin(); iter != template_data->mMemberVariables.end(); iter++) { LLMessageVariable& ci = **iter; mCurrentSDataBlock->addVariable(ci.getName(), ci.getType()); } return; } else { // already have this block. . . // are we supposed to have a new one? // if the block is type MBT_SINGLE this is bad! if (template_data->mType == MBT_SINGLE) { llerrs << "LLTemplateMessageBuilder::nextBlock called multiple times" << " for " << bnamep << " but is type MBT_SINGLE" << llendl; return; } // if the block is type MBT_MULTIPLE then we need a known number, // make sure that we're not exceeding it if ( (template_data->mType == MBT_MULTIPLE) &&(mCurrentSDataBlock->mBlockNumber == template_data->mNumber)) { llerrs << "LLTemplateMessageBuilder::nextBlock called " << mCurrentSDataBlock->mBlockNumber << " times for " << bnamep << " exceeding " << template_data->mNumber << " specified in type MBT_MULTIPLE." << llendl; return; } // ok, we can make a new one // modify the name to avoid name collision by adding number to end S32 count = block_data->mBlockNumber; // incrememt base name's count block_data->mBlockNumber++; if (block_data->mBlockNumber > MAX_BLOCKS) { llerrs << "Trying to pack too many blocks into MBT_VARIABLE type " << "(limited to " << MAX_BLOCKS << ")" << llendl; } // create new name // Nota Bene: if things are working correctly, // mCurrentMessageData->mMemberBlocks[blockname]->mBlockNumber == // mCurrentDataBlock->mBlockNumber + 1 char *nbnamep = bnamep + count; mCurrentSDataBlock = new LLMsgBlkData(bnamep, count); mCurrentSDataBlock->mName = nbnamep; mCurrentSMessageData->mMemberBlocks[nbnamep] = mCurrentSDataBlock; // add placeholders for each of the variables for (LLMessageBlock::message_variable_map_t::const_iterator iter = template_data->mMemberVariables.begin(), end = template_data->mMemberVariables.end(); iter != end; iter++) { LLMessageVariable& ci = **iter; mCurrentSDataBlock->addVariable(ci.getName(), ci.getType()); } return; } } // TODO: Remove this horror... BOOL LLTemplateMessageBuilder::removeLastBlock() { if (mCurrentSBlockName) { if ( (mCurrentSMessageData) &&(mCurrentSMessageTemplate)) { if (mCurrentSMessageData->mMemberBlocks[mCurrentSBlockName]->mBlockNumber >= 1) { // At least one block for the current block name. // Store the current block name for future reference. char *block_name = mCurrentSBlockName; // Decrement the sent total by the size of the // data in the message block that we're currently building. const LLMessageBlock* template_data = mCurrentSMessageTemplate->getBlock(mCurrentSBlockName); for (LLMessageBlock::message_variable_map_t::const_iterator iter = template_data->mMemberVariables.begin(); iter != template_data->mMemberVariables.end(); iter++) { LLMessageVariable& ci = **iter; mCurrentSendTotal -= ci.getSize(); } // Now we want to find the block that we're blowing away. // Get the number of blocks. LLMsgBlkData* block_data = mCurrentSMessageData->mMemberBlocks[block_name]; S32 num_blocks = block_data->mBlockNumber; // Use the same (suspect?) algorithm that's used to generate // the names in the nextBlock method to find it. char *block_getting_whacked = block_name + num_blocks - 1; LLMsgBlkData* whacked_data = mCurrentSMessageData->mMemberBlocks[block_getting_whacked]; delete whacked_data; mCurrentSMessageData->mMemberBlocks.erase(block_getting_whacked); if (num_blocks <= 1) { // we just blew away the last one, so return FALSE llwarns << "not blowing away the only block of message " << mCurrentSMessageName << ". Block: " << block_name << ". Number: " << num_blocks << llendl; return FALSE; } else { // Decrement the counter. block_data->mBlockNumber--; return TRUE; } } } } return FALSE; } // add data to variable in current block void LLTemplateMessageBuilder::addData(const char *varname, const void *data, EMsgVariableType type, S32 size) { char *vnamep = (char *)varname; // do we have a current message? if (!mCurrentSMessageTemplate) { llerrs << "newMessage not called prior to addData" << llendl; return; } // do we have a current block? if (!mCurrentSDataBlock) { llerrs << "setBlock not called prior to addData" << llendl; return; } // kewl, add the data if it exists const LLMessageVariable* var_data = mCurrentSMessageTemplate->getBlock(mCurrentSBlockName)->getVariable(vnamep); if (!var_data || !var_data->getName()) { llerrs << vnamep << " not a variable in block " << mCurrentSBlockName << " of " << mCurrentSMessageTemplate->mName << llendl; return; } // ok, it seems ok. . . are we the correct size? if (var_data->getType() == MVT_VARIABLE) { // Variable 1 can only store 255 bytes, make sure our data is smaller if ((var_data->getSize() == 1) && (size > 255)) { llwarns << "Field " << varname << " is a Variable 1 but program " << "attempted to stuff more than 255 bytes in " << "(" << size << "). Clamping size and truncating data." << llendl; size = 255; char *truncate = (char *)data; truncate[255] = 0; } // no correct size for MVT_VARIABLE, instead we need to tell how many bytes the size will be encoded as mCurrentSDataBlock->addData(vnamep, data, size, type, var_data->getSize()); mCurrentSendTotal += size; } else { if (size != var_data->getSize()) { llerrs << varname << " is type MVT_FIXED but request size " << size << " doesn't match template size " << var_data->getSize() << llendl; return; } // alright, smash it in mCurrentSDataBlock->addData(vnamep, data, size, type); mCurrentSendTotal += size; } } // add data to variable in current block - fails if variable isn't MVT_FIXED void LLTemplateMessageBuilder::addData(const char *varname, const void *data, EMsgVariableType type) { char *vnamep = (char *)varname; // do we have a current message? if (!mCurrentSMessageTemplate) { llerrs << "newMessage not called prior to addData" << llendl; return; } // do we have a current block? if (!mCurrentSDataBlock) { llerrs << "setBlock not called prior to addData" << llendl; return; } // kewl, add the data if it exists const LLMessageVariable* var_data = mCurrentSMessageTemplate->getBlock(mCurrentSBlockName)->getVariable(vnamep); if (!var_data->getName()) { llerrs << vnamep << " not a variable in block " << mCurrentSBlockName << " of " << mCurrentSMessageTemplate->mName << llendl; return; } // ok, it seems ok. . . are we MVT_VARIABLE? if (var_data->getType() == MVT_VARIABLE) { // nope llerrs << vnamep << " is type MVT_VARIABLE. Call using addData(name, data, size)" << llendl; return; } else { mCurrentSDataBlock->addData(vnamep, data, var_data->getSize(), type); mCurrentSendTotal += var_data->getSize(); } } void LLTemplateMessageBuilder::addBinaryData(const char *varname, const void *data, S32 size) { addData(varname, data, MVT_FIXED, size); } void LLTemplateMessageBuilder::addS8(const char *varname, S8 s) { addData(varname, &s, MVT_S8, sizeof(s)); } void LLTemplateMessageBuilder::addU8(const char *varname, U8 u) { addData(varname, &u, MVT_U8, sizeof(u)); } void LLTemplateMessageBuilder::addS16(const char *varname, S16 i) { addData(varname, &i, MVT_S16, sizeof(i)); } void LLTemplateMessageBuilder::addU16(const char *varname, U16 i) { addData(varname, &i, MVT_U16, sizeof(i)); } void LLTemplateMessageBuilder::addF32(const char *varname, F32 f) { addData(varname, &f, MVT_F32, sizeof(f)); } void LLTemplateMessageBuilder::addS32(const char *varname, S32 s) { addData(varname, &s, MVT_S32, sizeof(s)); } void LLTemplateMessageBuilder::addU32(const char *varname, U32 u) { addData(varname, &u, MVT_U32, sizeof(u)); } void LLTemplateMessageBuilder::addU64(const char *varname, U64 lu) { addData(varname, &lu, MVT_U64, sizeof(lu)); } void LLTemplateMessageBuilder::addF64(const char *varname, F64 d) { addData(varname, &d, MVT_F64, sizeof(d)); } void LLTemplateMessageBuilder::addIPAddr(const char *varname, U32 u) { addData(varname, &u, MVT_IP_ADDR, sizeof(u)); } void LLTemplateMessageBuilder::addIPPort(const char *varname, U16 u) { u = htons(u); addData(varname, &u, MVT_IP_PORT, sizeof(u)); } void LLTemplateMessageBuilder::addBOOL(const char* varname, BOOL b) { // Can't just cast a BOOL (actually a U32) to a U8. // In some cases the low order bits will be zero. U8 temp = (b != 0); addData(varname, &temp, MVT_BOOL, sizeof(temp)); } void LLTemplateMessageBuilder::addString(const char* varname, const char* s) { if (s) addData( varname, (void *)s, MVT_VARIABLE, (S32)strlen(s) + 1); /* Flawfinder: ignore */ else addData( varname, NULL, MVT_VARIABLE, 0); } void LLTemplateMessageBuilder::addString(const char* varname, const std::string& s) { if (s.size()) addData( varname, (void *)s.c_str(), MVT_VARIABLE, (S32)(s.size()) + 1); else addData( varname, NULL, MVT_VARIABLE, 0); } void LLTemplateMessageBuilder::addVector3(const char *varname, const LLVector3& vec) { addData(varname, vec.mV, MVT_LLVector3, sizeof(vec.mV)); } void LLTemplateMessageBuilder::addVector4(const char *varname, const LLVector4& vec) { addData(varname, vec.mV, MVT_LLVector4, sizeof(vec.mV)); } void LLTemplateMessageBuilder::addVector3d(const char *varname, const LLVector3d& vec) { addData(varname, vec.mdV, MVT_LLVector3d, sizeof(vec.mdV)); } void LLTemplateMessageBuilder::addQuat(const char *varname, const LLQuaternion& quat) { addData(varname, quat.packToVector3().mV, MVT_LLQuaternion, sizeof(LLVector3)); } void LLTemplateMessageBuilder::addUUID(const char *varname, const LLUUID& uuid) { addData(varname, uuid.mData, MVT_LLUUID, sizeof(uuid.mData)); } static S32 zero_code(U8 **data, U32 *data_size) { // Encoded send buffer needs to be slightly larger since the zero // coding can potentially increase the size of the send data. static U8 encodedSendBuffer[2 * MAX_BUFFER_SIZE]; S32 count = *data_size; S32 net_gain = 0; U8 num_zeroes = 0; U8 *inptr = (U8 *)*data; U8 *outptr = (U8 *)encodedSendBuffer; // skip the packet id field for (U32 ii = 0; ii < LL_PACKET_ID_SIZE ; ++ii) { count--; *outptr++ = *inptr++; } // build encoded packet, keeping track of net size gain // sequential zero bytes are encoded as 0 [U8 count] // with 0 0 [count] representing wrap (>256 zeroes) while (count--) { if (!(*inptr)) // in a zero count { if (num_zeroes) { if (++num_zeroes > 254) { *outptr++ = num_zeroes; num_zeroes = 0; } net_gain--; // subseqent zeroes save one } else { *outptr++ = 0; net_gain++; // starting a zero count adds one num_zeroes = 1; } inptr++; } else { if (num_zeroes) { *outptr++ = num_zeroes; num_zeroes = 0; } *outptr++ = *inptr++; } } if (num_zeroes) { *outptr++ = num_zeroes; } if (net_gain < 0) { // TODO: babbage: reinstate stat collecting... //mCompressedPacketsOut++; //mUncompressedBytesOut += *data_size; *data = encodedSendBuffer; *data_size += net_gain; encodedSendBuffer[0] |= LL_ZERO_CODE_FLAG; // set the head bit to indicate zero coding //mCompressedBytesOut += *data_size; } //mTotalBytesOut += *data_size; return(net_gain); } void LLTemplateMessageBuilder::compressMessage(U8*& buf_ptr, U32& buffer_length) { if(ME_ZEROCODED == mCurrentSMessageTemplate->getEncoding()) { zero_code(&buf_ptr, &buffer_length); } } BOOL LLTemplateMessageBuilder::isMessageFull(const char* blockname) const { if(mCurrentSendTotal > MTUBYTES) { return TRUE; } if(!blockname) { return FALSE; } char* bnamep = (char*)blockname; S32 max; const LLMessageBlock* template_data = mCurrentSMessageTemplate->getBlock(bnamep); switch(template_data->mType) { case MBT_SINGLE: max = 1; break; case MBT_MULTIPLE: max = template_data->mNumber; break; case MBT_VARIABLE: default: max = MAX_BLOCKS; break; } if(mCurrentSMessageData->mMemberBlocks[bnamep]->mBlockNumber >= max) { return TRUE; } return FALSE; } static S32 buildBlock(U8* buffer, S32 buffer_size, const LLMessageBlock* template_data, LLMsgData* message_data) { S32 result = 0; LLMsgData::msg_blk_data_map_t::const_iterator block_iter = message_data->mMemberBlocks.find(template_data->mName); const LLMsgBlkData* mbci = block_iter->second; // ok, if this is the first block of a repeating pack, set // block_count and, if it's type MBT_VARIABLE encode a byte // for how many there are S32 block_count = mbci->mBlockNumber; if (template_data->mType == MBT_VARIABLE) { // remember that mBlockNumber is a S32 U8 temp_block_number = (U8)mbci->mBlockNumber; if ((S32)(result + sizeof(U8)) < MAX_BUFFER_SIZE) { memcpy(&buffer[result], &temp_block_number, sizeof(U8)); result += sizeof(U8); } else { // Just reporting error is likely not enough. Need // to check how to abort or error out gracefully // from this function. XXXTBD llerrs << "buildBlock failed. Message excedding " << "sendBuffersize." << llendl; } } else if (template_data->mType == MBT_MULTIPLE) { if (block_count != template_data->mNumber) { // nope! need to fill it in all the way! llerrs << "Block " << mbci->mName << " is type MBT_MULTIPLE but only has data for " << block_count << " out of its " << template_data->mNumber << " blocks" << llendl; } } while(block_count > 0) { // now loop through the variables for (LLMsgBlkData::msg_var_data_map_t::const_iterator iter = mbci->mMemberVarData.begin(); iter != mbci->mMemberVarData.end(); iter++) { const LLMsgVarData& mvci = *iter; if (mvci.getSize() == -1) { // oops, this variable wasn't ever set! llerrs << "The variable " << mvci.getName() << " in block " << mbci->mName << " of message " << template_data->mName << " wasn't set prior to buildMessage call" << llendl; } else { S32 data_size = mvci.getDataSize(); if(data_size > 0) { // The type is MVT_VARIABLE, which means that we // need to encode a size argument. Otherwise, // there is no need. S32 size = mvci.getSize(); U8 sizeb; U16 sizeh; switch(data_size) { case 1: sizeb = size; htonmemcpy(&buffer[result], &sizeb, MVT_U8, 1); break; case 2: sizeh = size; htonmemcpy(&buffer[result], &sizeh, MVT_U16, 2); break; case 4: htonmemcpy(&buffer[result], &size, MVT_S32, 4); break; default: llerrs << "Attempting to build variable field with unknown size of " << size << llendl; break; } result += mvci.getDataSize(); } // if there is any data to pack, pack it if((mvci.getData() != NULL) && mvci.getSize()) { if(result + mvci.getSize() < buffer_size) { memcpy( &buffer[result], mvci.getData(), mvci.getSize()); result += mvci.getSize(); } else { // Just reporting error is likely not // enough. Need to check how to abort or error // out gracefully from this function. XXXTBD llerrs << "buildBlock failed. " << "Attempted to pack " << result + mvci.getSize() << " bytes into a buffer with size " << buffer_size << "." << llendl } } } } --block_count; ++block_iter; if (block_iter != message_data->mMemberBlocks.end()) { mbci = block_iter->second; } } return result; } // make sure that all the desired data is in place and then copy the data into MAX_BUFFER_SIZEd buffer U32 LLTemplateMessageBuilder::buildMessage( U8* buffer, U32 buffer_size, U8 offset_to_data) { // basic algorithm is to loop through the various pieces, building // size and offset info if we encounter a -1 for mSize at any // point that variable wasn't given data // do we have a current message? if (!mCurrentSMessageTemplate) { llerrs << "newMessage not called prior to buildMessage" << llendl; return 0; } // leave room for flags, packet sequence #, and data offset // information. buffer[PHL_OFFSET] = offset_to_data; U32 result = LL_PACKET_ID_SIZE; // encode message number and adjust total_offset if (mCurrentSMessageTemplate->mFrequency == MFT_HIGH) { // old, endian-dependant way // memcpy(&buffer[result], &mCurrentMessageTemplate->mMessageNumber, sizeof(U8)); // new, independant way buffer[result] = (U8)mCurrentSMessageTemplate->mMessageNumber; result += sizeof(U8); } else if (mCurrentSMessageTemplate->mFrequency == MFT_MEDIUM) { U8 temp = 255; memcpy(&buffer[result], &temp, sizeof(U8)); /*Flawfinder: ignore*/ result += sizeof(U8); // mask off unsightly bits temp = mCurrentSMessageTemplate->mMessageNumber & 255; memcpy(&buffer[result], &temp, sizeof(U8)); /*Flawfinder: ignore*/ result += sizeof(U8); } else if (mCurrentSMessageTemplate->mFrequency == MFT_LOW) { U8 temp = 255; U16 message_num; memcpy(&buffer[result], &temp, sizeof(U8)); /*Flawfinder: ignore*/ result += sizeof(U8); memcpy(&buffer[result], &temp, sizeof(U8)); /*Flawfinder: ignore*/ result += sizeof(U8); // mask off unsightly bits message_num = mCurrentSMessageTemplate->mMessageNumber & 0xFFFF; // convert to network byte order message_num = htons(message_num); memcpy(&buffer[result], &message_num, sizeof(U16)); /*Flawfinder: ignore*/ result += sizeof(U16); } else { llerrs << "unexpected message frequency in buildMessage" << llendl; return 0; } // fast forward through the offset and build the message result += offset_to_data; for(LLMessageTemplate::message_block_map_t::const_iterator iter = mCurrentSMessageTemplate->mMemberBlocks.begin(), end = mCurrentSMessageTemplate->mMemberBlocks.end(); iter != end; ++iter) { result += buildBlock(buffer + result, buffer_size - result, *iter, mCurrentSMessageData); } mbSBuilt = TRUE; return result; } void LLTemplateMessageBuilder::copyFromMessageData(const LLMsgData& data) { // copy the blocks // counting variables used to encode multiple block info S32 block_count = 0; char *block_name = NULL; // loop through msg blocks to loop through variables, totalling up size // data and filling the new (send) message LLMsgData::msg_blk_data_map_t::const_iterator iter = data.mMemberBlocks.begin(); LLMsgData::msg_blk_data_map_t::const_iterator end = data.mMemberBlocks.end(); for(; iter != end; ++iter) { const LLMsgBlkData* mbci = iter->second; if(!mbci) continue; // do we need to encode a block code? if (block_count == 0) { block_count = mbci->mBlockNumber; block_name = (char *)mbci->mName; } // counting down mutliple blocks block_count--; nextBlock(block_name); // now loop through the variables LLMsgBlkData::msg_var_data_map_t::const_iterator dit = mbci->mMemberVarData.begin(); LLMsgBlkData::msg_var_data_map_t::const_iterator dend = mbci->mMemberVarData.end(); for(; dit != dend; ++dit) { const LLMsgVarData& mvci = *dit; addData(mvci.getName(), mvci.getData(), mvci.getType(), mvci.getSize()); } } } //virtual void LLTemplateMessageBuilder::copyFromLLSD(const LLSD&) { // TODO } //virtual void LLTemplateMessageBuilder::setBuilt(BOOL b) { mbSBuilt = b; } //virtual BOOL LLTemplateMessageBuilder::isBuilt() const {return mbSBuilt;} //virtual BOOL LLTemplateMessageBuilder::isClear() const {return mbSClear;} //virtual S32 LLTemplateMessageBuilder::getMessageSize() {return mCurrentSendTotal;} //virtual const char* LLTemplateMessageBuilder::getMessageName() const { return mCurrentSMessageName; }