void LLTemplateMessageBuilderTestObject::test<17>() // IPPort { LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(defaultBlock(MVT_IP_PORT, 2)); U16 outValue, inValue = 80; LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addIPPort(_PREHASH_Test0, inValue); LLTemplateMessageReader* reader = setReader(messageTemplate, builder); reader->getIPPort(_PREHASH_Test0, _PREHASH_Test0, outValue); ensure_equals("Ensure IPPort", inValue, outValue); delete reader; }
void LLTemplateMessageBuilderTestObject::test<14>() // Quaternion { LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(defaultBlock(MVT_LLQuaternion, 12)); LLQuaternion outValue, inValue = LLQuaternion(1,2,3,0); LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addQuat(_PREHASH_Test0, inValue); LLTemplateMessageReader* reader = setReader(messageTemplate, builder); reader->getQuat(_PREHASH_Test0, _PREHASH_Test0, outValue); ensure_equals("Ensure LLQuaternion", inValue, outValue); delete reader; }
void LLTemplateMessageBuilderTestObject::test<10>() // F64 { LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(defaultBlock(MVT_F64, 8)); F64 outValue, inValue = 3232143.33; LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addF64(_PREHASH_Test0, inValue); LLTemplateMessageReader* reader = setReader(messageTemplate, builder); reader->getF64(_PREHASH_Test0, _PREHASH_Test0, outValue); ensure_equals("Ensure F64", inValue, outValue); delete reader; }
void LLTemplateMessageBuilderTestObject::test<13>() // Vector3d { LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(defaultBlock(MVT_LLVector3d, 24)); LLVector3d outValue, inValue = LLVector3d(1,2,3); LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addVector3d(_PREHASH_Test0, inValue); LLTemplateMessageReader* reader = setReader(messageTemplate, builder); reader->getVector3d(_PREHASH_Test0, _PREHASH_Test0, outValue); ensure_equals("Ensure LLVector3d", inValue, outValue); delete reader; }
void LLTemplateMessageBuilderTestObject::test<8>() // U32 { LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(defaultBlock(MVT_U32, 4)); U32 outValue, inValue = 88; LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addU32(_PREHASH_Test0, inValue); LLTemplateMessageReader* reader = setReader(messageTemplate, builder); reader->getU32(_PREHASH_Test0, _PREHASH_Test0, outValue); ensure_equals("Ensure U32", inValue, outValue); delete reader; }
void LLTemplateMessageBuilderTestObject::test<5>() // U16 { LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(defaultBlock(MVT_U16, 2)); U16 outValue, inValue = 3; LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addU16(_PREHASH_Test0, inValue); LLTemplateMessageReader* reader = setReader(messageTemplate, builder); reader->getU16(_PREHASH_Test0, _PREHASH_Test0, outValue); ensure_equals("Ensure U16", inValue, outValue); delete reader; }
void LLTemplateMessageBuilderTestObject::test<2>() // BOOL { LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(defaultBlock(MVT_BOOL, 1)); BOOL outValue, inValue = TRUE; LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addBOOL(_PREHASH_Test0, inValue); LLTemplateMessageReader* reader = setReader(messageTemplate, builder); reader->getBOOL(_PREHASH_Test0, _PREHASH_Test0, outValue); ensure_equals("Ensure BOOL", inValue, outValue); delete reader; }
void LLTemplateMessageBuilderTestObject::test<16>() // IPAddr { LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(defaultBlock(MVT_IP_ADDR, 4)); U32 outValue, inValue = 12344556; LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addIPAddr(_PREHASH_Test0, inValue); LLTemplateMessageReader* reader = setReader(messageTemplate, builder); reader->getIPAddr(_PREHASH_Test0, _PREHASH_Test0, outValue); ensure_equals("Ensure IPAddr", inValue, outValue); delete reader; }
void LLTemplateMessageBuilderTestObject::test<28>() // non-zero offset with S16 { LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(defaultBlock(MVT_S16, 2)); S16 outValue, inValue = 90; LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addS16(_PREHASH_Test0, inValue); LLTemplateMessageReader* reader = setReader( messageTemplate, builder, 2); reader->getS16(_PREHASH_Test0, _PREHASH_Test0, outValue); ensure_equals("Ensure S16", inValue, outValue); delete reader; }
void LLTemplateMessageBuilderTestObject::test<31>() // non-zero offset with F32 { LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(defaultBlock(MVT_F32, 4)); F32 outValue, inValue = 121.44f; LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addF32(_PREHASH_Test0, inValue); LLTemplateMessageReader* reader = setReader( messageTemplate, builder, 16); reader->getF32(_PREHASH_Test0, _PREHASH_Test0, outValue); ensure_equals("Ensure F32", inValue, outValue); delete reader; }
void LLTemplateMessageBuilderTestObject::test<33>() // non-zero offset with U64 { LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(defaultBlock(MVT_U64, 8)); U64 outValue, inValue = 121; LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addU64(_PREHASH_Test0, inValue); LLTemplateMessageReader* reader = setReader( messageTemplate, builder, 32); reader->getU64(_PREHASH_Test0, _PREHASH_Test0, outValue); ensure_equals("Ensure U64", inValue, outValue); delete reader; }
void LLTemplateMessageBuilderTestObject::test<15>() // UUID { LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(defaultBlock(MVT_LLUUID, 16)); LLUUID outValue, inValue; inValue.generate(); LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addUUID(_PREHASH_Test0, inValue); LLTemplateMessageReader* reader = setReader(messageTemplate, builder); reader->getUUID(_PREHASH_Test0, _PREHASH_Test0, outValue); ensure_equals("Ensure UUID", inValue, outValue); delete reader; }
void LLTemplateMessageBuilderTestObject::test<36>() // non-zero offset with Vector4 { LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(defaultBlock(MVT_LLVector4, 16)); LLVector4 outValue, inValue = LLVector4(1,2,3,4); LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addVector4(_PREHASH_Test0, inValue); LLTemplateMessageReader* reader = setReader( messageTemplate, builder, 64); reader->getVector4(_PREHASH_Test0, _PREHASH_Test0, outValue); ensure_equals("Ensure LLVector4", inValue, outValue); delete reader; }
void LLTemplateMessageBuilderTestObject::test<27>() // non-zero offset with U8 { LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(defaultBlock(MVT_U8, 1)); U8 outValue, inValue = 2; LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addU8(_PREHASH_Test0, inValue); LLTemplateMessageReader* reader = setReader( messageTemplate, builder, 255); reader->getU8(_PREHASH_Test0, _PREHASH_Test0, outValue); ensure_equals("Ensure U8", inValue, outValue); delete reader; }
void LLTemplateMessageBuilderTestObject::test<18>() // String { LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(defaultBlock(MVT_VARIABLE, 1)); std::string outValue, inValue = "testing"; LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addString(_PREHASH_Test0, inValue.c_str()); LLTemplateMessageReader* reader = setReader(messageTemplate, builder); char buffer[MAX_STRING]; reader->getString(_PREHASH_Test0, _PREHASH_Test0, MAX_STRING, buffer); outValue = buffer; ensure_equals("Ensure String", inValue, outValue); delete reader; }
void LLTemplateMessageBuilderTestObject::test<23>() // variable repeated block name never accessed { U32 inTest = 1, outTest; LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock( createBlock(const_cast<char*>(_PREHASH_Test0), MVT_U32, 4, MBT_SINGLE)); messageTemplate.addBlock(createBlock(const_cast<char*>(_PREHASH_Test1), MVT_U32, 4)); LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addU32(_PREHASH_Test0, inTest); LLTemplateMessageReader* reader = setReader(messageTemplate, builder); reader->getU32(_PREHASH_Test0, _PREHASH_Test0, outTest); S32 blockCount = reader->getNumberOfBlocks(const_cast<char*>(_PREHASH_Test1)); ensure_equals("Ensure block count", blockCount, 0); ensure_equals("Ensure Test0", inTest, outTest); delete reader; }
void LLTemplateMessageBuilderTestObject::test<19>() // block name !-> binary order { U8 buffer1[MAX_BUFFER_SIZE]; memset(buffer1, 0, MAX_BUFFER_SIZE); U8 buffer2[MAX_BUFFER_SIZE]; memset(buffer2, 0, MAX_BUFFER_SIZE); U32 bufferSize1, bufferSize2; // build template: Test0 before Test1 LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(createBlock(const_cast<char*>(_PREHASH_Test0), MVT_U32, 4, MBT_SINGLE)); messageTemplate.addBlock(createBlock(const_cast<char*>(_PREHASH_Test1), MVT_U32, 4, MBT_SINGLE)); // build message: 1st declared block var == 0xaaaa, 2nd declared block var == 0xbbbb LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate, const_cast<char*>(_PREHASH_Test0)); builder->addU32(_PREHASH_Test0, 0xaaaa); builder->nextBlock(_PREHASH_Test1); builder->addU32(_PREHASH_Test0, 0xbbbb); bufferSize1 = builder->buildMessage(buffer1, MAX_BUFFER_SIZE, 0); delete builder; // build template: Test1 before Test0 messageTemplate = defaultTemplate(); messageTemplate.addBlock(createBlock(const_cast<char*>(_PREHASH_Test1), MVT_U32, 4, MBT_SINGLE)); messageTemplate.addBlock(createBlock(const_cast<char*>(_PREHASH_Test0), MVT_U32, 4, MBT_SINGLE)); // build message: 1st declared block var == 0xaaaa, 2nd declared block var == 0xbbbb builder = defaultBuilder(messageTemplate, const_cast<char*>(_PREHASH_Test1)); builder->addU32(_PREHASH_Test0, 0xaaaa); builder->nextBlock(_PREHASH_Test0); builder->addU32(_PREHASH_Test0, 0xbbbb); bufferSize2 = builder->buildMessage(buffer2, MAX_BUFFER_SIZE, 0); delete builder; ensure_equals("Ensure Buffer Sizes Equal", bufferSize1, bufferSize2); ensure_equals("Ensure Buffer Contents Equal", memcmp(buffer1, buffer2, bufferSize1), 0); }
void LLTemplateMessageBuilderTestObject::test<22>() // repeated penultimate block (crashes when data in LLDynamicArrayIndexed) { U32 inTest00 = 0, inTest01 = 1, inTest1 = 2; U32 outTest00, outTest01, outTest1; LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(createBlock(const_cast<char*>(_PREHASH_Test0), MVT_U32, 4)); messageTemplate.addBlock(createBlock(const_cast<char*>(_PREHASH_Test1), MVT_U32, 4)); LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addU32(_PREHASH_Test0, inTest00); builder->nextBlock(_PREHASH_Test0); builder->addU32(_PREHASH_Test0, inTest01); builder->nextBlock(_PREHASH_Test1); builder->addU32(_PREHASH_Test0, inTest1); LLTemplateMessageReader* reader = setReader(messageTemplate, builder); reader->getU32(_PREHASH_Test0, _PREHASH_Test0, outTest00, 0); reader->getU32(_PREHASH_Test0, _PREHASH_Test0, outTest01, 1); reader->getU32(_PREHASH_Test1, _PREHASH_Test0, outTest1); ensure_equals("Ensure Test0[0]", inTest00, outTest00); ensure_equals("Ensure Test0[1]", inTest01, outTest01); ensure_equals("Ensure Test1", inTest1, outTest1); delete reader; }
void LLTemplateMessageBuilderTestObject::test<45>() // read variable length data past end of message -> 0 length { // build message with single block LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(defaultBlock(MVT_U32, 4, MBT_SINGLE)); U32 outValue, outValue2, inValue = 0xbbbbbbbb; LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addU32(_PREHASH_Test0, inValue); const U32 bufferSize = 1024; U8 buffer[bufferSize]; memset(buffer, 0xaa, bufferSize); memset(buffer, 0, LL_PACKET_ID_SIZE); U32 builtSize = builder->buildMessage(buffer, bufferSize, 0); delete builder; // add variable block to reader template messageTemplate.addBlock(createBlock(const_cast<char*>(_PREHASH_Test1), MVT_VARIABLE, 4, MBT_SINGLE)); // read message value and default string numberMap[1] = &messageTemplate; LLTemplateMessageReader* reader = new LLTemplateMessageReader(numberMap); reader->validateMessage(buffer, builtSize, LLHost()); reader->readMessage(buffer, LLHost()); reader->getU32(_PREHASH_Test0, _PREHASH_Test0, outValue); char outBuffer[bufferSize]; memset(buffer, 0xcc, bufferSize); reader->getString(_PREHASH_Test1, _PREHASH_Test0, bufferSize, outBuffer); outValue2 = reader->getNumberOfBlocks(_PREHASH_Test1); ensure_equals("Ensure present value ", outValue, inValue); ensure_equals("Ensure unchanged buffer ", strlen(outBuffer), 0); delete reader; }
void LLTemplateMessageBuilderTestObject::test<21>() // block appended in declaration -> data appended in binary { U8 buffer1[MAX_BUFFER_SIZE]; memset(buffer1, 0, MAX_BUFFER_SIZE); U8 buffer2[MAX_BUFFER_SIZE]; memset(buffer2, 0, MAX_BUFFER_SIZE); U32 bufferSize1, bufferSize2; // Build template: Test0 only LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(createBlock(const_cast<char*>(_PREHASH_Test0), MVT_U32, 4, MBT_SINGLE)); // Build message LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate, const_cast<char*>(_PREHASH_Test0)); builder->addU32(_PREHASH_Test0, 0xaaaa); bufferSize1 = builder->buildMessage(buffer1, MAX_BUFFER_SIZE, 0); delete builder; // Build template: Test0 before Test1 messageTemplate = defaultTemplate(); messageTemplate.addBlock(createBlock(const_cast<char*>(_PREHASH_Test0), MVT_U32, 4, MBT_SINGLE)); messageTemplate.addBlock(createBlock(const_cast<char*>(_PREHASH_Test1), MVT_U32, 4, MBT_SINGLE)); // Build message builder = defaultBuilder(messageTemplate, const_cast<char*>(_PREHASH_Test0)); builder->addU32(_PREHASH_Test0, 0xaaaa); builder->nextBlock(_PREHASH_Test1); builder->addU32(_PREHASH_Test0, 0xbbbb); bufferSize2 = builder->buildMessage(buffer2, MAX_BUFFER_SIZE, 0); delete builder; ensure_not_equals("Ensure Buffer Sizes Not Equal", bufferSize1, bufferSize2); ensure_equals("Ensure Buffer Prefix Equal", memcmp(buffer1, buffer2, bufferSize1), 0); ensure_not_equals("Ensure Buffer Contents Not Equal", memcmp(buffer1, buffer2, bufferSize2), 0); }
void LLTemplateMessageBuilderTestObject::test<24>() // forwarding message { // build template LLMessageTemplate messageTemplate = defaultTemplate(); messageTemplate.addBlock(createBlock(const_cast<char*>(_PREHASH_Test0), MVT_U32, 4)); // build message LLTemplateMessageBuilder* builder = defaultBuilder(messageTemplate); builder->addU32(_PREHASH_Test0, 42); // read message LLTemplateMessageReader* reader = setReader(messageTemplate, builder); // forward message builder = defaultBuilder(messageTemplate); builder->newMessage(_PREHASH_TestMessage); reader->copyToBuilder(*builder); U8 buffer[MAX_BUFFER_SIZE]; builder->buildMessage(buffer, MAX_BUFFER_SIZE, 0); delete builder; delete reader; }
// static LLMessageTemplate * LLTemplateParser::parseMessage(LLTemplateTokenizer & tokens) { LLMessageTemplate *templatep = NULL; if(!tokens.want("{")) { return NULL; } // name first std::string template_name = tokens.next(); // is name a legit C variable name if (!b_variable_ok(template_name.c_str())) { llerrs << "Not legit variable name: " << template_name << " at " << tokens.line() << llendl; } // ok, now get Frequency ("High", "Medium", or "Low") EMsgFrequency frequency = MFT_LOW; std::string freq_string = tokens.next(); if (freq_string == "High") { frequency = MFT_HIGH; } else if (freq_string == "Medium") { frequency = MFT_MEDIUM; } else if (freq_string == "Low" || freq_string == "Fixed") { frequency = MFT_LOW; } else { llerrs << "Expected frequency, got " << freq_string << " at " << tokens.line() << llendl; } // TODO more explicit checking here pls U32 message_number = strtoul(tokens.next().c_str(),NULL,0); switch (frequency) { case MFT_HIGH: break; case MFT_MEDIUM: message_number = (255 << 8) | message_number; break; case MFT_LOW: message_number = (255 << 24) | (255 << 16) | message_number; break; default: llerrs << "Unknown frequency enum: " << frequency << llendl; } templatep = new LLMessageTemplate( template_name.c_str(), message_number, frequency); // Now get trust ("Trusted", "NotTrusted") std::string trust = tokens.next(); if (trust == "Trusted") { templatep->setTrust(MT_TRUST); } else if (trust == "NotTrusted") { templatep->setTrust(MT_NOTRUST); } else { llerrs << "Bad trust " << trust << " at " << tokens.line() << llendl; } // get encoding std::string encoding = tokens.next(); if(encoding == "Unencoded") { templatep->setEncoding(ME_UNENCODED); } else if(encoding == "Zerocoded") { templatep->setEncoding(ME_ZEROCODED); } else { llerrs << "Bad encoding " << encoding << " at " << tokens.line() << llendl; } // get deprecation if(tokens.want("Deprecated")) { templatep->setDeprecation(MD_DEPRECATED); } else if (tokens.want("UDPDeprecated")) { templatep->setDeprecation(MD_UDPDEPRECATED); } else if (tokens.want("UDPBlackListed")) { templatep->setDeprecation(MD_UDPBLACKLISTED); } else if (tokens.want("NotDeprecated")) { // this is the default value, but it can't hurt to set it twice templatep->setDeprecation(MD_NOTDEPRECATED); } else { // It's probably a brace, let's just start block processing } while(LLMessageBlock * blockp = parseBlock(tokens)) { templatep->addBlock(blockp); } if(!tokens.want("}")) { llerrs << "Expecting closing } for message " << template_name << " at " << tokens.line() << llendl; } return templatep; }