// Copyright 2019 AT&T Intellectual Property // Copyright 2019 Nokia // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // This source code is part of the near-RT RIC (RAN Intelligent Controller) // platform project (RICP). // TODO: High-level file comment. #include <3rdparty/oranE2/RANfunctions-List.h> #include "sctpThread.h" #include "BuildRunName.h" #include "3rdparty/oranE2SM/E2SM-gNB-NRT-RANfunction-Definition.h" #include "BuildXml.h" #include "pugixml/src/pugixml.hpp" // #include // #include // #include // #include // #include // #include // #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include using namespace std; //using namespace std::placeholders; using namespace boost::filesystem; using namespace rapidjson; //#ifdef __cplusplus //extern "C" //{ //#endif int sendMessageSocket(const int dest_port); int parseMessageData(ReportingMessages_t &message, char *data, char *host, uint16_t &port); // need to expose without the include of gcov extern "C" void __gcov_flush(void); static void catch_function(int signal) { __gcov_flush(); exit(signal); } BOOST_LOG_INLINE_GLOBAL_LOGGER_DEFAULT(my_logger, src::logger_mt) boost::shared_ptr> boostLogger; double cpuClock = 0.0; bool jsonTrace = true; void init_log() { mdclog_attr_t *attr; mdclog_attr_init(&attr); mdclog_attr_set_ident(attr, "E2Terminator"); mdclog_init(attr); mdclog_attr_destroy(attr); } auto start_time = std::chrono::high_resolution_clock::now(); typedef std::chrono::duration> seconds_t; double age() { return seconds_t(std::chrono::high_resolution_clock::now() - start_time).count(); } double approx_CPU_MHz(unsigned sleeptime) { using namespace std::chrono_literals; uint32_t aux = 0; uint64_t cycles_start = rdtscp(aux); double time_start = age(); std::this_thread::sleep_for(sleeptime * 1ms); uint64_t elapsed_cycles = rdtscp(aux) - cycles_start; double elapsed_time = age() - time_start; return elapsed_cycles / elapsed_time; } //std::atomic rmrCounter{0}; std::atomic num_of_messages{0}; std::atomic num_of_XAPP_messages{0}; static long transactionCounter = 0; int buildListeningPort(sctp_params_t &sctpParams) { sctpParams.listenFD = socket (AF_INET6, SOCK_STREAM, IPPROTO_SCTP); struct sockaddr_in6 servaddr {}; servaddr.sin6_family = AF_INET6; servaddr.sin6_addr = in6addr_any; servaddr.sin6_port = htons(sctpParams.sctpPort); if (bind(sctpParams.listenFD, (SA *)&servaddr, sizeof(servaddr)) < 0 ) { mdclog_write(MDCLOG_ERR, "Error binding. %s\n", strerror(errno)); return -1; } if (setSocketNoBlocking(sctpParams.listenFD) == -1) { //mdclog_write(MDCLOG_ERR, "Error binding. %s", strerror(errno)); return -1; } if (mdclog_level_get() >= MDCLOG_DEBUG) { struct sockaddr_in6 cliaddr {}; socklen_t len = sizeof(cliaddr); getsockname(sctpParams.listenFD, (SA *)&cliaddr, &len); char buff[1024] {}; inet_ntop(AF_INET6, &cliaddr.sin6_addr, buff, sizeof(buff)); mdclog_write(MDCLOG_DEBUG, "My address: %s, port %d\n", buff, htons(cliaddr.sin6_port)); } if (listen(sctpParams.listenFD, SOMAXCONN) < 0) { mdclog_write(MDCLOG_ERR, "Error listening. %s\n", strerror(errno)); return -1; } struct epoll_event event {}; event.events = EPOLLIN | EPOLLET; event.data.fd = sctpParams.listenFD; // add listening port to epoll if (epoll_ctl(sctpParams.epoll_fd, EPOLL_CTL_ADD, sctpParams.listenFD, &event)) { printf("Failed to add descriptor to epoll\n"); mdclog_write(MDCLOG_ERR, "Failed to add descriptor to epoll. %s\n", strerror(errno)); return -1; } return 0; } int buildConfiguration(sctp_params_t &sctpParams) { path p = (sctpParams.configFilePath + "/" + sctpParams.configFileName).c_str(); if (exists(p)) { const int size = 2048; auto fileSize = file_size(p); if (fileSize > size) { mdclog_write(MDCLOG_ERR, "File %s larger than %d", p.string().c_str(), size); return -1; } } else { mdclog_write(MDCLOG_ERR, "Configuration File %s not exists", p.string().c_str()); return -1; } ReadConfigFile conf; if (conf.openConfigFile(p.string()) == -1) { mdclog_write(MDCLOG_ERR, "Filed to open config file %s, %s", p.string().c_str(), strerror(errno)); return -1; } int rmrPort = conf.getIntValue("nano"); if (rmrPort == -1) { mdclog_write(MDCLOG_ERR, "illigal RMR port "); return -1; } sctpParams.rmrPort = (uint16_t)rmrPort; snprintf(sctpParams.rmrAddress, sizeof(sctpParams.rmrAddress), "%d", (int) (sctpParams.rmrPort)); auto tmpStr = conf.getStringValue("loglevel"); if (tmpStr.length() == 0) { mdclog_write(MDCLOG_ERR, "illigal loglevel. Set loglevel to MDCLOG_INFO"); tmpStr = "info"; } transform(tmpStr.begin(), tmpStr.end(), tmpStr.begin(), ::tolower); if ((tmpStr.compare("debug")) == 0) { sctpParams.logLevel = MDCLOG_DEBUG; } else if ((tmpStr.compare("info")) == 0) { sctpParams.logLevel = MDCLOG_INFO; } else if ((tmpStr.compare("warning")) == 0) { sctpParams.logLevel = MDCLOG_WARN; } else if ((tmpStr.compare("error")) == 0) { sctpParams.logLevel = MDCLOG_ERR; } else { mdclog_write(MDCLOG_ERR, "illigal loglevel = %s. Set loglevel to MDCLOG_INFO", tmpStr.c_str()); sctpParams.logLevel = MDCLOG_INFO; } mdclog_level_set(sctpParams.logLevel); tmpStr = conf.getStringValue("volume"); if (tmpStr.length() == 0) { mdclog_write(MDCLOG_ERR, "illigal volume."); return -1; } char tmpLogFilespec[VOLUME_URL_SIZE]; tmpLogFilespec[0] = 0; sctpParams.volume[0] = 0; snprintf(sctpParams.volume, VOLUME_URL_SIZE, "%s", tmpStr.c_str()); // copy the name to temp file as well snprintf(tmpLogFilespec, VOLUME_URL_SIZE, "%s", tmpStr.c_str()); // define the file name in the tmp directory under the volume strcat(tmpLogFilespec,"/tmp/E2Term_%Y-%m-%d_%H-%M-%S.%N.tmpStr"); sctpParams.myIP = conf.getStringValue("local-ip"); if (sctpParams.myIP.length() == 0) { mdclog_write(MDCLOG_ERR, "illigal local-ip."); return -1; } int sctpPort = conf.getIntValue("sctp-port"); if (sctpPort == -1) { mdclog_write(MDCLOG_ERR, "illigal SCTP port "); return -1; } sctpParams.sctpPort = (uint16_t)sctpPort; sctpParams.fqdn = conf.getStringValue("external-fqdn"); if (sctpParams.fqdn.length() == 0) { mdclog_write(MDCLOG_ERR, "illigal external-fqdn"); return -1; } std::string pod = conf.getStringValue("pod_name"); if (pod.length() == 0) { mdclog_write(MDCLOG_ERR, "illigal pod_name in config file"); return -1; } auto *podName = getenv(pod.c_str()); if (podName == nullptr) { mdclog_write(MDCLOG_ERR, "illigal pod_name or environment varible not exists : %s", pod.c_str()); return -1; } else { sctpParams.podName.assign(podName); if (sctpParams.podName.length() == 0) { mdclog_write(MDCLOG_ERR, "illigal pod_name"); return -1; } } tmpStr = conf.getStringValue("trace"); transform(tmpStr.begin(), tmpStr.end(), tmpStr.begin(), ::tolower); if ((tmpStr.compare("start")) == 0) { mdclog_write(MDCLOG_INFO, "Trace set to: start"); sctpParams.trace = true; } else if ((tmpStr.compare("stop")) == 0) { mdclog_write(MDCLOG_INFO, "Trace set to: stop"); sctpParams.trace = false; } jsonTrace = sctpParams.trace; sctpParams.ka_message_length = snprintf(sctpParams.ka_message, KA_MESSAGE_SIZE, "{\"address\": \"%s:%d\"," "\"fqdn\": \"%s\"," "\"pod_name\": \"%s\"}", (const char *)sctpParams.myIP.c_str(), sctpParams.rmrPort, sctpParams.fqdn.c_str(), sctpParams.podName.c_str()); if (mdclog_level_get() >= MDCLOG_INFO) { mdclog_mdc_add("RMR Port", to_string(sctpParams.rmrPort).c_str()); mdclog_mdc_add("LogLevel", to_string(sctpParams.logLevel).c_str()); mdclog_mdc_add("volume", sctpParams.volume); mdclog_mdc_add("tmpLogFilespec", tmpLogFilespec); mdclog_mdc_add("my ip", sctpParams.myIP.c_str()); mdclog_mdc_add("pod name", sctpParams.podName.c_str()); mdclog_write(MDCLOG_INFO, "running parameters for instance : %s", sctpParams.ka_message); } mdclog_mdc_clean(); // Files written to the current working directory boostLogger = logging::add_file_log( keywords::file_name = tmpLogFilespec, // to temp directory keywords::rotation_size = 10 * 1024 * 1024, keywords::time_based_rotation = sinks::file::rotation_at_time_interval(posix_time::hours(1)), keywords::format = "%Message%" //keywords::format = "[%TimeStamp%]: %Message%" // use each tmpStr with time stamp ); // Setup a destination folder for collecting rotated (closed) files --since the same volumn can use rename() boostLogger->locked_backend()->set_file_collector(sinks::file::make_collector( keywords::target = sctpParams.volume )); // Upon restart, scan the directory for files matching the file_name pattern boostLogger->locked_backend()->scan_for_files(); // Enable auto-flushing after each tmpStr record written if (mdclog_level_get() >= MDCLOG_DEBUG) { boostLogger->locked_backend()->auto_flush(true); } return 0; } int main(const int argc, const char **argv) { sctp_params_t sctpParams; { std::random_device device{}; std::mt19937 generator(device()); std::uniform_int_distribution distribution(1, (long) 1e12); transactionCounter = distribution(generator); } // uint64_t st = 0; // uint32_t aux1 = 0; // st = rdtscp(aux1); unsigned num_cpus = std::thread::hardware_concurrency(); init_log(); mdclog_level_set(MDCLOG_INFO); if (std::signal(SIGINT, catch_function) == SIG_ERR) { mdclog_write(MDCLOG_ERR, "Error initializing SIGINT"); exit(1); } if (std::signal(SIGABRT, catch_function)== SIG_ERR) { mdclog_write(MDCLOG_ERR, "Error initializing SIGABRT"); exit(1); } if (std::signal(SIGTERM, catch_function)== SIG_ERR) { mdclog_write(MDCLOG_ERR, "Error initializing SIGTERM"); exit(1); } cpuClock = approx_CPU_MHz(100); mdclog_write(MDCLOG_DEBUG, "CPU speed %11.11f", cpuClock); auto result = parse(argc, argv, sctpParams); if (buildConfiguration(sctpParams) != 0) { exit(-1); } // start epoll sctpParams.epoll_fd = epoll_create1(0); if (sctpParams.epoll_fd == -1) { mdclog_write(MDCLOG_ERR, "failed to open epoll descriptor"); exit(-1); } getRmrContext(sctpParams); if (sctpParams.rmrCtx == nullptr) { close(sctpParams.epoll_fd); exit(-1); } if (buildInotify(sctpParams) == -1) { close(sctpParams.rmrListenFd); rmr_close(sctpParams.rmrCtx); close(sctpParams.epoll_fd); exit(-1); } if (buildListeningPort(sctpParams) != 0) { close(sctpParams.rmrListenFd); rmr_close(sctpParams.rmrCtx); close(sctpParams.epoll_fd); exit(-1); } sctpParams.sctpMap = new mapWrapper(); std::vector threads(num_cpus); // std::vector threads; num_cpus = 1; for (unsigned int i = 0; i < num_cpus; i++) { threads[i] = std::thread(listener, &sctpParams); cpu_set_t cpuset; CPU_ZERO(&cpuset); CPU_SET(i, &cpuset); int rc = pthread_setaffinity_np(threads[i].native_handle(), sizeof(cpu_set_t), &cpuset); if (rc != 0) { mdclog_write(MDCLOG_ERR, "Error calling pthread_setaffinity_np: %d", rc); } } auto statFlag = false; auto statThread = std::thread(statColectorThread, (void *)&statFlag); //loop over term_init until first message from xApp handleTermInit(sctpParams); for (auto &t : threads) { t.join(); } statFlag = true; statThread.join(); return 0; } void handleTermInit(sctp_params_t &sctpParams) { sendTermInit(sctpParams); //send to e2 manager init of e2 term //E2_TERM_INIT int count = 0; while (true) { auto xappMessages = num_of_XAPP_messages.load(std::memory_order_acquire); if (xappMessages > 0) { if (mdclog_level_get() >= MDCLOG_INFO) { mdclog_write(MDCLOG_INFO, "Got a message from some appliction, stop sending E2_TERM_INIT"); } return; } usleep(100000); count++; if (count % 1000 == 0) { mdclog_write(MDCLOG_ERR, "GOT No messages from any xApp"); sendTermInit(sctpParams); } } } void sendTermInit(sctp_params_t &sctpParams) { rmr_mbuf_t *msg = rmr_alloc_msg(sctpParams.rmrCtx, sctpParams.ka_message_length); auto count = 0; while (true) { msg->mtype = E2_TERM_INIT; msg->state = 0; rmr_bytes2payload(msg, (unsigned char *)sctpParams.ka_message, sctpParams.ka_message_length); static unsigned char tx[32]; auto txLen = snprintf((char *) tx, sizeof tx, "%15ld", transactionCounter++); rmr_bytes2xact(msg, tx, txLen); msg = rmr_send_msg(sctpParams.rmrCtx, msg); if (msg == nullptr) { msg = rmr_alloc_msg(sctpParams.rmrCtx, sctpParams.ka_message_length); } else if (msg->state == 0) { rmr_free_msg(msg); if (mdclog_level_get() >= MDCLOG_INFO) { mdclog_write(MDCLOG_INFO, "E2_TERM_INIT succsesfuly sent "); } return; } else { if (count % 100 == 0) { mdclog_write(MDCLOG_ERR, "Error sending E2_TERM_INIT cause : %s ", translateRmrErrorMessages(msg->state).c_str()); } sleep(1); } count++; } } /** * * @param argc * @param argv * @param sctpParams * @return */ cxxopts::ParseResult parse(int argc, const char *argv[], sctp_params_t &sctpParams) { cxxopts::Options options(argv[0], "e2 term help"); options.positional_help("[optional args]").show_positional_help(); options.allow_unrecognised_options().add_options() ("p,path", "config file path", cxxopts::value(sctpParams.configFilePath)->default_value("config")) ("f,file", "config file name", cxxopts::value(sctpParams.configFileName)->default_value("config.conf")) ("h,help", "Print help"); auto result = options.parse(argc, argv); if (result.count("help")) { std::cout << options.help({""}) << std::endl; exit(0); } return result; } /** * * @param sctpParams * @return -1 failed 0 success */ int buildInotify(sctp_params_t &sctpParams) { sctpParams.inotifyFD = inotify_init1(IN_NONBLOCK); if (sctpParams.inotifyFD == -1) { mdclog_write(MDCLOG_ERR, "Failed to init inotify (inotify_init1) %s", strerror(errno)); close(sctpParams.rmrListenFd); rmr_close(sctpParams.rmrCtx); close(sctpParams.epoll_fd); return -1; } sctpParams.inotifyWD = inotify_add_watch(sctpParams.inotifyFD, (const char *)sctpParams.configFilePath.c_str(), (unsigned)IN_OPEN | (unsigned)IN_CLOSE_WRITE | (unsigned)IN_CLOSE_NOWRITE); //IN_CLOSE = (IN_CLOSE_WRITE | IN_CLOSE_NOWRITE) if (sctpParams.inotifyWD == -1) { mdclog_write(MDCLOG_ERR, "Failed to add directory : %s to inotify (inotify_add_watch) %s", sctpParams.configFilePath.c_str(), strerror(errno)); close(sctpParams.inotifyFD); return -1; } struct epoll_event event{}; event.events = (EPOLLIN); event.data.fd = sctpParams.inotifyFD; // add listening RMR FD to epoll if (epoll_ctl(sctpParams.epoll_fd, EPOLL_CTL_ADD, sctpParams.inotifyFD, &event)) { mdclog_write(MDCLOG_ERR, "Failed to add inotify FD to epoll"); close(sctpParams.inotifyFD); return -1; } return 0; } /** * * @param args * @return */ void listener(sctp_params_t *params) { int num_of_SCTP_messages = 0; auto totalTime = 0.0; mdclog_mdc_clean(); mdclog_level_set(params->logLevel); std::thread::id this_id = std::this_thread::get_id(); //save cout streambuf *oldCout = cout.rdbuf(); ostringstream memCout; // create new cout cout.rdbuf(memCout.rdbuf()); cout << this_id; //return to the normal cout cout.rdbuf(oldCout); char tid[32]; memcpy(tid, memCout.str().c_str(), memCout.str().length() < 32 ? memCout.str().length() : 31); tid[memCout.str().length()] = 0; mdclog_mdc_add("thread id", tid); if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "started thread number %s", tid); } RmrMessagesBuffer_t rmrMessageBuffer{}; //create and init RMR rmrMessageBuffer.rmrCtx = params->rmrCtx; auto *events = (struct epoll_event *) calloc(MAXEVENTS, sizeof(struct epoll_event)); struct timespec end{0, 0}; struct timespec start{0, 0}; rmrMessageBuffer.rcvMessage = rmr_alloc_msg(rmrMessageBuffer.rmrCtx, RECEIVE_XAPP_BUFFER_SIZE); rmrMessageBuffer.sendMessage = rmr_alloc_msg(rmrMessageBuffer.rmrCtx, RECEIVE_XAPP_BUFFER_SIZE); memcpy(rmrMessageBuffer.ka_message, params->ka_message, params->ka_message_length); rmrMessageBuffer.ka_message_len = params->ka_message_length; rmrMessageBuffer.ka_message[rmrMessageBuffer.ka_message_len] = 0; if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "keep alive message is : %s", rmrMessageBuffer.ka_message); } ReportingMessages_t message {}; // for (int i = 0; i < MAX_RMR_BUFF_ARRY; i++) { // rmrMessageBuffer.rcvBufferedMessages[i] = rmr_alloc_msg(rmrMessageBuffer.rmrCtx, RECEIVE_XAPP_BUFFER_SIZE); // rmrMessageBuffer.sendBufferedMessages[i] = rmr_alloc_msg(rmrMessageBuffer.rmrCtx, RECEIVE_XAPP_BUFFER_SIZE); // } message.statCollector = StatCollector::GetInstance(); while (true) { if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Start EPOLL Wait"); } auto numOfEvents = epoll_wait(params->epoll_fd, events, MAXEVENTS, -1); if (numOfEvents < 0 && errno == EINTR) { if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "got EINTR : %s", strerror(errno)); } continue; } if (numOfEvents < 0) { mdclog_write(MDCLOG_ERR, "Epoll wait failed, errno = %s", strerror(errno)); return; } for (auto i = 0; i < numOfEvents; i++) { if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "handling epoll event %d out of %d", i + 1, numOfEvents); } clock_gettime(CLOCK_MONOTONIC, &message.message.time); start.tv_sec = message.message.time.tv_sec; start.tv_nsec = message.message.time.tv_nsec; if ((events[i].events & EPOLLERR) || (events[i].events & EPOLLHUP)) { handlepoll_error(events[i], message, rmrMessageBuffer, params); } else if (events[i].events & EPOLLOUT) { handleEinprogressMessages(events[i], message, rmrMessageBuffer, params); } else if (params->listenFD == events[i].data.fd) { if (mdclog_level_get() >= MDCLOG_INFO) { mdclog_write(MDCLOG_INFO, "New connection request from sctp network\n"); } // new connection is requested from RAN start build connection while (true) { struct sockaddr in_addr {}; socklen_t in_len; char hostBuff[NI_MAXHOST]; char portBuff[NI_MAXSERV]; in_len = sizeof(in_addr); auto *peerInfo = (ConnectedCU_t *)calloc(1, sizeof(ConnectedCU_t)); peerInfo->sctpParams = params; peerInfo->fileDescriptor = accept(params->listenFD, &in_addr, &in_len); if (peerInfo->fileDescriptor == -1) { if ((errno == EAGAIN) || (errno == EWOULDBLOCK)) { /* We have processed all incoming connections. */ break; } else { mdclog_write(MDCLOG_ERR, "Accept error, errno = %s", strerror(errno)); break; } } if (setSocketNoBlocking(peerInfo->fileDescriptor) == -1) { mdclog_write(MDCLOG_ERR, "setSocketNoBlocking failed to set new connection %s on port %s\n", hostBuff, portBuff); close(peerInfo->fileDescriptor); break; } auto ans = getnameinfo(&in_addr, in_len, peerInfo->hostName, NI_MAXHOST, peerInfo->portNumber, NI_MAXSERV, (unsigned )((unsigned int)NI_NUMERICHOST | (unsigned int)NI_NUMERICSERV)); if (ans < 0) { mdclog_write(MDCLOG_ERR, "Failed to get info on connection request. %s\n", strerror(errno)); close(peerInfo->fileDescriptor); break; } if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Accepted connection on descriptor %d (host=%s, port=%s)\n", peerInfo->fileDescriptor, peerInfo->hostName, peerInfo->portNumber); } peerInfo->isConnected = false; peerInfo->gotSetup = false; if (addToEpoll(params->epoll_fd, peerInfo, (EPOLLIN | EPOLLET), params->sctpMap, nullptr, 0) != 0) { break; } break; } } else if (params->rmrListenFd == events[i].data.fd) { // got message from XAPP num_of_XAPP_messages.fetch_add(1, std::memory_order_release); num_of_messages.fetch_add(1, std::memory_order_release); if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "new message from RMR"); } if (receiveXappMessages(params->sctpMap, rmrMessageBuffer, message.message.time) != 0) { mdclog_write(MDCLOG_ERR, "Error handling Xapp message"); } } else if (params->inotifyFD == events[i].data.fd) { mdclog_write(MDCLOG_INFO, "Got event from inotify (configuration update)"); handleConfigChange(params); } else { /* We RMR_ERR_RETRY have data on the fd waiting to be read. Read and display it. * We must read whatever data is available completely, as we are running * in edge-triggered mode and won't get a notification again for the same data. */ num_of_messages.fetch_add(1, std::memory_order_release); if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "new message from SCTP, epoll flags are : %0x", events[i].events); } receiveDataFromSctp(&events[i], params->sctpMap, num_of_SCTP_messages, rmrMessageBuffer, message.message.time); } clock_gettime(CLOCK_MONOTONIC, &end); if (mdclog_level_get() >= MDCLOG_INFO) { totalTime += ((end.tv_sec + 1.0e-9 * end.tv_nsec) - ((double) start.tv_sec + 1.0e-9 * start.tv_nsec)); } if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "message handling is %ld seconds %ld nanoseconds", end.tv_sec - start.tv_sec, end.tv_nsec - start.tv_nsec); } } } } /** * * @param sctpParams */ void handleConfigChange(sctp_params_t *sctpParams) { char buf[4096] __attribute__ ((aligned(__alignof__(struct inotify_event)))); const struct inotify_event *event; char *ptr; path p = (sctpParams->configFilePath + "/" + sctpParams->configFileName).c_str(); auto endlessLoop = true; while (endlessLoop) { auto len = read(sctpParams->inotifyFD, buf, sizeof buf); if (len == -1) { if (errno != EAGAIN) { mdclog_write(MDCLOG_ERR, "read %s ", strerror(errno)); endlessLoop = false; continue; } else { endlessLoop = false; continue; } } for (ptr = buf; ptr < buf + len; ptr += sizeof(struct inotify_event) + event->len) { event = (const struct inotify_event *)ptr; if (event->mask & (uint32_t)IN_ISDIR) { continue; } // the directory name if (sctpParams->inotifyWD == event->wd) { // not the directory } if (event->len) { auto retVal = strcmp(sctpParams->configFileName.c_str(), event->name); if (retVal != 0) { continue; } } // only the file we want if (event->mask & (uint32_t)IN_CLOSE_WRITE) { if (mdclog_level_get() >= MDCLOG_INFO) { mdclog_write(MDCLOG_INFO, "Configuration file changed"); } if (exists(p)) { const int size = 2048; auto fileSize = file_size(p); if (fileSize > size) { mdclog_write(MDCLOG_ERR, "File %s larger than %d", p.string().c_str(), size); return; } } else { mdclog_write(MDCLOG_ERR, "Configuration File %s not exists", p.string().c_str()); return; } ReadConfigFile conf; if (conf.openConfigFile(p.string()) == -1) { mdclog_write(MDCLOG_ERR, "Filed to open config file %s, %s", p.string().c_str(), strerror(errno)); return; } auto tmpStr = conf.getStringValue("loglevel"); if (tmpStr.length() == 0) { mdclog_write(MDCLOG_ERR, "illigal loglevel. Set loglevel to MDCLOG_INFO"); tmpStr = "info"; } transform(tmpStr.begin(), tmpStr.end(), tmpStr.begin(), ::tolower); if ((tmpStr.compare("debug")) == 0) { mdclog_write(MDCLOG_INFO, "Log level set to MDCLOG_DEBUG"); sctpParams->logLevel = MDCLOG_DEBUG; } else if ((tmpStr.compare("info")) == 0) { mdclog_write(MDCLOG_INFO, "Log level set to MDCLOG_INFO"); sctpParams->logLevel = MDCLOG_INFO; } else if ((tmpStr.compare("warning")) == 0) { mdclog_write(MDCLOG_INFO, "Log level set to MDCLOG_WARN"); sctpParams->logLevel = MDCLOG_WARN; } else if ((tmpStr.compare("error")) == 0) { mdclog_write(MDCLOG_INFO, "Log level set to MDCLOG_ERR"); sctpParams->logLevel = MDCLOG_ERR; } else { mdclog_write(MDCLOG_ERR, "illigal loglevel = %s. Set loglevel to MDCLOG_INFO", tmpStr.c_str()); sctpParams->logLevel = MDCLOG_INFO; } mdclog_level_set(sctpParams->logLevel); tmpStr = conf.getStringValue("trace"); if (tmpStr.length() == 0) { mdclog_write(MDCLOG_ERR, "illigal trace. Set trace to stop"); tmpStr = "stop"; } transform(tmpStr.begin(), tmpStr.end(), tmpStr.begin(), ::tolower); if ((tmpStr.compare("start")) == 0) { mdclog_write(MDCLOG_INFO, "Trace set to: start"); sctpParams->trace = true; } else if ((tmpStr.compare("stop")) == 0) { mdclog_write(MDCLOG_INFO, "Trace set to: stop"); sctpParams->trace = false; } else { mdclog_write(MDCLOG_ERR, "Trace was set to wrong value %s, set to stop", tmpStr.c_str()); sctpParams->trace = false; } jsonTrace = sctpParams->trace; endlessLoop = false; } } } } /** * * @param event * @param message * @param rmrMessageBuffer * @param params */ void handleEinprogressMessages(struct epoll_event &event, ReportingMessages_t &message, RmrMessagesBuffer_t &rmrMessageBuffer, sctp_params_t *params) { auto *peerInfo = (ConnectedCU_t *)event.data.ptr; memcpy(message.message.enodbName, peerInfo->enodbName, sizeof(peerInfo->enodbName)); mdclog_write(MDCLOG_INFO, "file descriptor %d got EPOLLOUT", peerInfo->fileDescriptor); auto retVal = 0; socklen_t retValLen = 0; auto rc = getsockopt(peerInfo->fileDescriptor, SOL_SOCKET, SO_ERROR, &retVal, &retValLen); if (rc != 0 || retVal != 0) { if (rc != 0) { rmrMessageBuffer.sendMessage->len = snprintf((char *)rmrMessageBuffer.sendMessage->payload, 256, "%s|Failed SCTP Connection, after EINPROGRESS the getsockopt%s", peerInfo->enodbName, strerror(errno)); } else if (retVal != 0) { rmrMessageBuffer.sendMessage->len = snprintf((char *)rmrMessageBuffer.sendMessage->payload, 256, "%s|Failed SCTP Connection after EINPROGRESS, SO_ERROR", peerInfo->enodbName); } message.message.asndata = rmrMessageBuffer.sendMessage->payload; message.message.asnLength = rmrMessageBuffer.sendMessage->len; mdclog_write(MDCLOG_ERR, "%s", rmrMessageBuffer.sendMessage->payload); message.message.direction = 'N'; if (sendRequestToXapp(message, RIC_SCTP_CONNECTION_FAILURE, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "SCTP_CONNECTION_FAIL message failed to send to xAPP"); } memset(peerInfo->asnData, 0, peerInfo->asnLength); peerInfo->asnLength = 0; peerInfo->mtype = 0; return; } peerInfo->isConnected = true; if (modifyToEpoll(params->epoll_fd, peerInfo, (EPOLLIN | EPOLLET), params->sctpMap, peerInfo->enodbName, peerInfo->mtype) != 0) { mdclog_write(MDCLOG_ERR, "epoll_ctl EPOLL_CTL_MOD"); return; } message.message.asndata = (unsigned char *)peerInfo->asnData; message.message.asnLength = peerInfo->asnLength; message.message.messageType = peerInfo->mtype; memcpy(message.message.enodbName, peerInfo->enodbName, sizeof(peerInfo->enodbName)); num_of_messages.fetch_add(1, std::memory_order_release); if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "send the delayed SETUP/ENDC SETUP to sctp for %s", message.message.enodbName); } if (sendSctpMsg(peerInfo, message, params->sctpMap) != 0) { if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Error write to SCTP %s %d", __func__, __LINE__); } return; } memset(peerInfo->asnData, 0, peerInfo->asnLength); peerInfo->asnLength = 0; peerInfo->mtype = 0; } void handlepoll_error(struct epoll_event &event, ReportingMessages_t &message, RmrMessagesBuffer_t &rmrMessageBuffer, sctp_params_t *params) { if (event.data.fd != params->rmrListenFd) { auto *peerInfo = (ConnectedCU_t *)event.data.ptr; mdclog_write(MDCLOG_ERR, "epoll error, events %0x on fd %d, RAN NAME : %s", event.events, peerInfo->fileDescriptor, peerInfo->enodbName); rmrMessageBuffer.sendMessage->len = snprintf((char *)rmrMessageBuffer.sendMessage->payload, 256, "%s|Failed SCTP Connection", peerInfo->enodbName); message.message.asndata = rmrMessageBuffer.sendMessage->payload; message.message.asnLength = rmrMessageBuffer.sendMessage->len; memcpy(message.message.enodbName, peerInfo->enodbName, sizeof(peerInfo->enodbName)); message.message.direction = 'N'; if (sendRequestToXapp(message, RIC_SCTP_CONNECTION_FAILURE, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "SCTP_CONNECTION_FAIL message failed to send to xAPP"); } close(peerInfo->fileDescriptor); params->sctpMap->erase(peerInfo->enodbName); cleanHashEntry((ConnectedCU_t *) event.data.ptr, params->sctpMap); } else { mdclog_write(MDCLOG_ERR, "epoll error, events %0x on RMR FD", event.events); } } /** * * @param socket * @return */ int setSocketNoBlocking(int socket) { auto flags = fcntl(socket, F_GETFL, 0); if (flags == -1) { mdclog_mdc_add("func", "fcntl"); mdclog_write(MDCLOG_ERR, "%s, %s", __FUNCTION__, strerror(errno)); mdclog_mdc_clean(); return -1; } flags = (unsigned) flags | (unsigned) O_NONBLOCK; if (fcntl(socket, F_SETFL, flags) == -1) { mdclog_mdc_add("func", "fcntl"); mdclog_write(MDCLOG_ERR, "%s, %s", __FUNCTION__, strerror(errno)); mdclog_mdc_clean(); return -1; } return 0; } /** * * @param val * @param m */ void cleanHashEntry(ConnectedCU_t *val, Sctp_Map_t *m) { char *dummy; auto port = (uint16_t) strtol(val->portNumber, &dummy, 10); char searchBuff[2048]{}; snprintf(searchBuff, sizeof searchBuff, "host:%s:%d", val->hostName, port); m->erase(searchBuff); m->erase(val->enodbName); free(val); } /** * * @param fd file discriptor * @param data the asn data to send * @param len length of the data * @param enodbName the enodbName as in the map for printing purpose * @param m map host information * @param mtype message number * @return 0 success, anegative number on fail */ int sendSctpMsg(ConnectedCU_t *peerInfo, ReportingMessages_t &message, Sctp_Map_t *m) { auto loglevel = mdclog_level_get(); int fd = peerInfo->fileDescriptor; if (loglevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Send SCTP message for CU %s, %s", message.message.enodbName, __FUNCTION__); } while (true) { if (send(fd,message.message.asndata, message.message.asnLength,MSG_NOSIGNAL) < 0) { if (errno == EINTR) { continue; } mdclog_write(MDCLOG_ERR, "error writing to CU a message, %s ", strerror(errno)); if (!peerInfo->isConnected) { mdclog_write(MDCLOG_ERR, "connection to CU %s is still in progress.", message.message.enodbName); return -1; } cleanHashEntry(peerInfo, m); close(fd); char key[MAX_ENODB_NAME_SIZE * 2]; snprintf(key, MAX_ENODB_NAME_SIZE * 2, "msg:%s|%d", message.message.enodbName, message.message.messageType); if (loglevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "remove key = %s from %s at line %d", key, __FUNCTION__, __LINE__); } auto tmp = m->find(key); if (tmp) { free(tmp); } m->erase(key); return -1; } // TODO remove stat update //message.statCollector->incSentMessage(string(message.message.enodbName)); message.message.direction = 'D'; // send report.buffer of size buildJsonMessage(message); if (loglevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "SCTP message for CU %s sent from %s", message.message.enodbName, __FUNCTION__); } return 0; } } /** * * @param message * @param rmrMessageBuffer */ void getRequestMetaData(ReportingMessages_t &message, RmrMessagesBuffer_t &rmrMessageBuffer) { rmr_get_meid(rmrMessageBuffer.rcvMessage, (unsigned char *) (message.message.enodbName)); message.message.asndata = rmrMessageBuffer.rcvMessage->payload; message.message.asnLength = rmrMessageBuffer.rcvMessage->len; if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Message from Xapp RAN name = %s message length = %ld", message.message.enodbName, (unsigned long) message.message.asnLength); } } /** * 09/11/2020 - Leo: parse json message * * @param metaData all the data strip to structure * @param data the data recived from xAPP * @return 0 success all other values are fault */ int parseMessageData(ReportingMessages_t &message, char *data, char *host, uint16_t &port) { auto loglevel = mdclog_level_get(); Document document; document.Parse(data); const char* ran_ip; if (document.HasMember("ranIp")) { ran_ip = document["ranIp"].GetString(); std::cout << "ranIP: " << ran_ip << ", length: " << strlen(ran_ip) << std::endl; memcpy(host, ran_ip, strlen(ran_ip)); } else { mdclog_write(MDCLOG_ERR, "ranIp not provided"); return -1; } int ran_port; if (document.HasMember("ranPort")) { ran_port = document["ranPort"].GetInt(); std::cout << "ranPort: " << ran_port << std::endl; port = (uint16_t) ran_port; } else { mdclog_write(MDCLOG_ERR, "ranPort not provided"); return -2; } const char* ran_name; if (document.HasMember("ranName")) { ran_name = document["ranName"].GetString(); std::cout << "ranName: " << ran_name << ", length: " << strlen(ran_name) << std::endl; memcpy(message.message.enodbName, ran_name, strlen(ran_name)); } else { mdclog_write(MDCLOG_ERR, "ranName not provided"); return -3; } const char* message_payload; if (document.HasMember("payload")) { message_payload = document["payload"].GetString(); std::cout << "payload: " << message_payload << ", length: " << strlen(message_payload) << std::endl; message.message.asndata = (unsigned char *) message_payload; std::cout << "message.message.asndata: " << message.message.asndata << std::endl; message.message.asnLength = (uint16_t) strlen(message_payload); std::cout << "message.message.asnLength: " << message.message.asnLength << std::endl; } else { mdclog_write(MDCLOG_ERR, "Payload not provided"); return -4; } std::cout << "Step 1" << std::endl; // val = strtok_r(nullptr, delimiter, &tmp); // if (val != nullptr) { // mdclog_write(MDCLOG_DEBUG, "ASN length parameter from message = %s", val); // if (mdclog_level_get() >= MDCLOG_DEBUG) { // mdclog_write(MDCLOG_DEBUG, "ASN length parameter from message = %s", val); // } // char *dummy; // message.message.asnLength = (uint16_t) strtol(val, &dummy, 10); // } else { // mdclog_write(MDCLOG_ERR, "wrong ASN length for setup request %s", data); // return -4; // } // // message.message.asndata = (unsigned char *)tmp; // tmp is local but point to the location in data if (loglevel >= MDCLOG_INFO) { mdclog_write(MDCLOG_INFO, "Message from Xapp RAN name = %s host address = %s port = %d", message.message.enodbName, host, port); } std::cout << "Step 2" << std::endl; return 0; } /** * * @param events * @param sctpMap * @param numOfMessages * @param rmrMessageBuffer * @param ts * @return */ int receiveDataFromSctp(struct epoll_event *events, Sctp_Map_t *sctpMap, int &numOfMessages, RmrMessagesBuffer_t &rmrMessageBuffer, struct timespec &ts) { /* We have data on the fd waiting to be read. Read and display it. * We must read whatever data is available completely, as we are running * in edge-triggered mode and won't get a notification again for the same data. */ ReportingMessages_t message {}; auto done = 0; auto loglevel = mdclog_level_get(); // get the identity of the interface message.peerInfo = (ConnectedCU_t *)events->data.ptr; message.statCollector = StatCollector::GetInstance(); struct timespec start{0, 0}; struct timespec decodestart{0, 0}; struct timespec end{0, 0}; E2AP_PDU_t *pdu = nullptr; while (true) { if (loglevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Start Read from SCTP %d fd", message.peerInfo->fileDescriptor); clock_gettime(CLOCK_MONOTONIC, &start); } // read the buffer directly to rmr payload message.message.asndata = rmrMessageBuffer.sendMessage->payload; message.message.asnLength = rmrMessageBuffer.sendMessage->len = read(message.peerInfo->fileDescriptor, rmrMessageBuffer.sendMessage->payload, RECEIVE_SCTP_BUFFER_SIZE); if (loglevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Finish Read from SCTP %d fd message length = %ld", message.peerInfo->fileDescriptor, message.message.asnLength); } memcpy(message.message.enodbName, message.peerInfo->enodbName, sizeof(message.peerInfo->enodbName)); message.statCollector->incRecvMessage(string(message.message.enodbName)); message.message.direction = 'U'; message.message.time.tv_nsec = ts.tv_nsec; message.message.time.tv_sec = ts.tv_sec; if (message.message.asnLength < 0) { if (errno == EINTR) { continue; } /* If errno == EAGAIN, that means we have read all data. So goReportingMessages_t back to the main loop. */ if (errno != EAGAIN) { mdclog_write(MDCLOG_ERR, "Read error, %s ", strerror(errno)); done = 1; } else if (loglevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "EAGAIN - descriptor = %d", message.peerInfo->fileDescriptor); } break; } else if (message.message.asnLength == 0) { /* End of file. The remote has closed the connection. */ if (loglevel >= MDCLOG_INFO) { mdclog_write(MDCLOG_INFO, "END of File Closed connection - descriptor = %d", message.peerInfo->fileDescriptor); } done = 1; break; } if (loglevel >= MDCLOG_DEBUG) { char printBuffer[4096]{}; char *tmp = printBuffer; for (size_t i = 0; i < (size_t)message.message.asnLength; ++i) { snprintf(tmp, 3, "%02x", message.message.asndata[i]); tmp += 2; } printBuffer[message.message.asnLength] = 0; clock_gettime(CLOCK_MONOTONIC, &end); mdclog_write(MDCLOG_DEBUG, "Before Encoding E2AP PDU for : %s, Read time is : %ld seconds, %ld nanoseconds", message.peerInfo->enodbName, end.tv_sec - start.tv_sec, end.tv_nsec - start.tv_nsec); mdclog_write(MDCLOG_DEBUG, "PDU buffer length = %ld, data = : %s", message.message.asnLength, printBuffer); clock_gettime(CLOCK_MONOTONIC, &decodestart); } auto rval = asn_decode(nullptr, ATS_ALIGNED_BASIC_PER, &asn_DEF_E2AP_PDU, (void **) &pdu, message.message.asndata, message.message.asnLength); if (rval.code != RC_OK) { mdclog_write(MDCLOG_ERR, "Error %d Decoding (unpack) E2AP PDU from RAN : %s", rval.code, message.peerInfo->enodbName); //todo may need reset to pdu break; } if (loglevel >= MDCLOG_DEBUG) { clock_gettime(CLOCK_MONOTONIC, &end); mdclog_write(MDCLOG_DEBUG, "After Encoding E2AP PDU for : %s, Read time is : %ld seconds, %ld nanoseconds", message.peerInfo->enodbName, end.tv_sec - decodestart.tv_sec, end.tv_nsec - decodestart.tv_nsec); char *printBuffer; size_t size; FILE *stream = open_memstream(&printBuffer, &size); asn_fprint(stream, &asn_DEF_E2AP_PDU, pdu); mdclog_write(MDCLOG_DEBUG, "Encoding E2AP PDU past : %s", printBuffer); clock_gettime(CLOCK_MONOTONIC, &decodestart); } switch (pdu->present) { case E2AP_PDU_PR_initiatingMessage: {//initiating message asnInitiatingRequest(pdu, sctpMap,message, rmrMessageBuffer); break; } case E2AP_PDU_PR_successfulOutcome: { //successful outcome asnSuccsesfulMsg(pdu, sctpMap, message, rmrMessageBuffer); break; } case E2AP_PDU_PR_unsuccessfulOutcome: { //Unsuccessful Outcome asnUnSuccsesfulMsg(pdu, sctpMap, message, rmrMessageBuffer); break; } default: mdclog_write(MDCLOG_ERR, "Unknown index %d in E2AP PDU", pdu->present); break; } if (loglevel >= MDCLOG_DEBUG) { clock_gettime(CLOCK_MONOTONIC, &end); mdclog_write(MDCLOG_DEBUG, "After processing message and sent to rmr for : %s, Read time is : %ld seconds, %ld nanoseconds", message.peerInfo->enodbName, end.tv_sec - decodestart.tv_sec, end.tv_nsec - decodestart.tv_nsec); } numOfMessages++; if (pdu != nullptr) { ASN_STRUCT_RESET(asn_DEF_E2AP_PDU, pdu); //ASN_STRUCT_FREE(asn_DEF_E2AP_PDU, pdu); //pdu = nullptr; } } if (done) { if (loglevel >= MDCLOG_INFO) { mdclog_write(MDCLOG_INFO, "Closed connection - descriptor = %d", message.peerInfo->fileDescriptor); } message.message.asnLength = rmrMessageBuffer.sendMessage->len = snprintf((char *)rmrMessageBuffer.sendMessage->payload, 256, "%s|CU disconnected unexpectedly", message.peerInfo->enodbName); message.message.asndata = rmrMessageBuffer.sendMessage->payload; if (sendRequestToXapp(message, RIC_SCTP_CONNECTION_FAILURE, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "SCTP_CONNECTION_FAIL message failed to send to xAPP"); } /* Closing descriptor make epoll remove it from the set of descriptors which are monitored. */ close(message.peerInfo->fileDescriptor); cleanHashEntry((ConnectedCU_t *) events->data.ptr, sctpMap); } if (loglevel >= MDCLOG_DEBUG) { clock_gettime(CLOCK_MONOTONIC, &end); mdclog_write(MDCLOG_DEBUG, "from receive SCTP to send RMR time is %ld seconds and %ld nanoseconds", end.tv_sec - start.tv_sec, end.tv_nsec - start.tv_nsec); } return 0; } static void buildAndsendSetupRequest(ReportingMessages_t &message, RmrMessagesBuffer_t &rmrMessageBuffer, E2AP_PDU_t *pdu, vector &repValues) { auto logLevel = mdclog_level_get(); // now we can send the data to e2Mgr auto buffer_size = RECEIVE_SCTP_BUFFER_SIZE * 2; unsigned char buffer[RECEIVE_SCTP_BUFFER_SIZE * 2]; auto *rmrMsg = rmr_alloc_msg(rmrMessageBuffer.rmrCtx, buffer_size); // encode to xml auto er = asn_encode_to_buffer(nullptr, ATS_BASIC_XER, &asn_DEF_E2AP_PDU, pdu, buffer, buffer_size); if (er.encoded == -1) { mdclog_write(MDCLOG_ERR, "encoding of %s failed, %s", asn_DEF_E2AP_PDU.name, strerror(errno)); } else if (er.encoded > (ssize_t) buffer_size) { mdclog_write(MDCLOG_ERR, "Buffer of size %d is to small for %s, at %s line %d", (int) buffer_size, asn_DEF_E2AP_PDU.name, __func__, __LINE__); } else { string messageType("E2setupRequest"); string ieName("E2setupRequestIEs"); buffer[er.encoded] = '\0'; buildXmlData(messageType, ieName, repValues, buffer, (size_t)er.encoded); // string xmlStr = (char *)buffer; // auto removeSpaces = [] (string str) -> string { // str.erase(remove(str.begin(), str.end(), ' '), str.end()); // str.erase(remove(str.begin(), str.end(), '\t'), str.end()); // return str; // }; // // xmlStr = removeSpaces(xmlStr); // // we have the XML // rmrMsg->len = snprintf((char *)rmrMsg->payload, RECEIVE_SCTP_BUFFER_SIZE * 2, "%s:%d|%s", // message.peerInfo->sctpParams->myIP.c_str(), // message.peerInfo->sctpParams->rmrPort, // xmlStr.c_str()); rmrMsg->len = snprintf((char *)rmrMsg->payload, RECEIVE_SCTP_BUFFER_SIZE * 2, "%s:%d|%s", message.peerInfo->sctpParams->myIP.c_str(), message.peerInfo->sctpParams->rmrPort, buffer); if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Setup request of size %d :\n %s\n", rmrMsg->len, rmrMsg->payload); } // send to RMR message.message.messageType = rmrMsg->mtype = RIC_E2_SETUP_REQ; rmrMsg->state = 0; rmr_bytes2meid(rmrMsg, (unsigned char *) message.message.enodbName, strlen(message.message.enodbName)); static unsigned char tx[32]; snprintf((char *) tx, sizeof tx, "%15ld", transactionCounter++); rmr_bytes2xact(rmrMsg, tx, strlen((const char *) tx)); rmrMsg = rmr_send_msg(rmrMessageBuffer.rmrCtx, rmrMsg); if (rmrMsg == nullptr) { mdclog_write(MDCLOG_ERR, "RMR failed to send returned nullptr"); } else if (rmrMsg->state != 0) { char meid[RMR_MAX_MEID]{}; if (rmrMsg->state == RMR_ERR_RETRY) { usleep(5); rmrMsg->state = 0; mdclog_write(MDCLOG_INFO, "RETRY sending Message %d to Xapp from %s", rmrMsg->mtype, rmr_get_meid(rmrMsg, (unsigned char *) meid)); rmrMsg = rmr_send_msg(rmrMessageBuffer.rmrCtx, rmrMsg); if (rmrMsg == nullptr) { mdclog_write(MDCLOG_ERR, "RMR failed send returned nullptr"); } else if (rmrMsg->state != 0) { mdclog_write(MDCLOG_ERR, "RMR Retry failed %s sending request %d to Xapp from %s", translateRmrErrorMessages(rmrMsg->state).c_str(), rmrMsg->mtype, rmr_get_meid(rmrMsg, (unsigned char *) meid)); } } else { mdclog_write(MDCLOG_ERR, "RMR failed: %s. sending request %d to Xapp from %s", translateRmrErrorMessages(rmrMsg->state).c_str(), rmrMsg->mtype, rmr_get_meid(rmrMsg, (unsigned char *) meid)); } } message.peerInfo->gotSetup = true; buildJsonMessage(message); if (rmrMsg != nullptr) { rmr_free_msg(rmrMsg); } } } int RAN_Function_list_To_Vector(RANfunctions_List_t& list, vector &runFunXML_v) { auto index = 0; runFunXML_v.clear(); for (auto j = 0; j < list.list.count; j++) { auto *raNfunctionItemIEs = (RANfunction_ItemIEs_t *)list.list.array[j]; if (raNfunctionItemIEs->id == ProtocolIE_ID_id_RANfunction_Item && (raNfunctionItemIEs->value.present == RANfunction_ItemIEs__value_PR_RANfunction_Item)) { // encode to xml E2SM_gNB_NRT_RANfunction_Definition_t *ranFunDef = nullptr; auto rval = asn_decode(nullptr, ATS_ALIGNED_BASIC_PER, &asn_DEF_E2SM_gNB_NRT_RANfunction_Definition, (void **)&ranFunDef, raNfunctionItemIEs->value.choice.RANfunction_Item.ranFunctionDefinition.buf, raNfunctionItemIEs->value.choice.RANfunction_Item.ranFunctionDefinition.size); if (rval.code != RC_OK) { mdclog_write(MDCLOG_ERR, "Error %d Decoding (unpack) E2SM message from : %s", rval.code, asn_DEF_E2SM_gNB_NRT_RANfunction_Definition.name); return -1; } // if (mdclog_level_get() >= MDCLOG_DEBUG) { // char *printBuffer; // size_t size; // FILE *stream = open_memstream(&printBuffer, &size); // asn_fprint(stream, &asn_DEF_E2SM_gNB_NRT_RANfunction_Definition, ranFunDef); // mdclog_write(MDCLOG_DEBUG, "Encoding E2SM %s PDU past : %s", // asn_DEF_E2SM_gNB_NRT_RANfunction_Definition.name, // printBuffer); // } auto xml_buffer_size = RECEIVE_SCTP_BUFFER_SIZE * 2; unsigned char xml_buffer[RECEIVE_SCTP_BUFFER_SIZE * 2]; // encode to xml auto er = asn_encode_to_buffer(nullptr, ATS_BASIC_XER, &asn_DEF_E2SM_gNB_NRT_RANfunction_Definition, ranFunDef, xml_buffer, xml_buffer_size); if (er.encoded == -1) { mdclog_write(MDCLOG_ERR, "encoding of %s failed, %s", asn_DEF_E2SM_gNB_NRT_RANfunction_Definition.name, strerror(errno)); } else if (er.encoded > (ssize_t)xml_buffer_size) { mdclog_write(MDCLOG_ERR, "Buffer of size %d is to small for %s, at %s line %d", (int) xml_buffer_size, asn_DEF_E2SM_gNB_NRT_RANfunction_Definition.name, __func__, __LINE__); } else { if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Encoding E2SM %s PDU number %d : %s", asn_DEF_E2SM_gNB_NRT_RANfunction_Definition.name, index++, xml_buffer); } string runFuncs = (char *)(xml_buffer); runFunXML_v.emplace_back(runFuncs); } } } return 0; } int collectSetupAndServiceUpdate_RequestData(E2AP_PDU_t *pdu, Sctp_Map_t *sctpMap, ReportingMessages_t &message, vector &RANfunctionsAdded_v, vector &RANfunctionsModified_v) { memset(message.peerInfo->enodbName, 0 , MAX_ENODB_NAME_SIZE); for (auto i = 0; i < pdu->choice.initiatingMessage->value.choice.E2setupRequest.protocolIEs.list.count; i++) { auto *ie = pdu->choice.initiatingMessage->value.choice.E2setupRequest.protocolIEs.list.array[i]; if (ie->id == ProtocolIE_ID_id_GlobalE2node_ID) { // get the ran name for meid if (ie->value.present == E2setupRequestIEs__value_PR_GlobalE2node_ID) { if (buildRanName(message.peerInfo->enodbName, ie) < 0) { mdclog_write(MDCLOG_ERR, "Bad param in E2setupRequestIEs GlobalE2node_ID.\n"); // no mesage will be sent return -1; } memcpy(message.message.enodbName, message.peerInfo->enodbName, strlen(message.peerInfo->enodbName)); sctpMap->setkey(message.message.enodbName, message.peerInfo); } } else if (ie->id == ProtocolIE_ID_id_RANfunctionsAdded) { if (ie->value.present == E2setupRequestIEs__value_PR_RANfunctions_List) { if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Run function list have %d entries", ie->value.choice.RANfunctions_List.list.count); } if (RAN_Function_list_To_Vector(ie->value.choice.RANfunctions_List, RANfunctionsAdded_v) != 0 ) { return -1; } } } else if (ie->id == ProtocolIE_ID_id_RANfunctionsModified) { if (ie->value.present == E2setupRequestIEs__value_PR_RANfunctions_List) { if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Run function list have %d entries", ie->value.choice.RANfunctions_List.list.count); } if (RAN_Function_list_To_Vector(ie->value.choice.RANfunctions_List, RANfunctionsModified_v) != 0 ) { return -1; } } } } if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Run function vector have %ld entries", RANfunctionsAdded_v.size()); } return 0; } /** * * @param pdu * @param message * @param rmrMessageBuffer */ void asnInitiatingRequest(E2AP_PDU_t *pdu, Sctp_Map_t *sctpMap, ReportingMessages_t &message, RmrMessagesBuffer_t &rmrMessageBuffer) { auto logLevel = mdclog_level_get(); auto procedureCode = ((InitiatingMessage_t *) pdu->choice.initiatingMessage)->procedureCode; if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Initiating message %ld\n", procedureCode); } switch (procedureCode) { case ProcedureCode_id_E2setup: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got E2setup"); } // first get the message as XML buffer auto setup_xml_buffer_size = RECEIVE_SCTP_BUFFER_SIZE * 2; unsigned char setup_xml_buffer[RECEIVE_SCTP_BUFFER_SIZE * 2]; auto er = asn_encode_to_buffer(nullptr, ATS_BASIC_XER, &asn_DEF_E2AP_PDU, pdu, setup_xml_buffer, setup_xml_buffer_size); if (er.encoded == -1) { mdclog_write(MDCLOG_ERR, "encoding of %s failed, %s", asn_DEF_E2AP_PDU.name, strerror(errno)); break; } else if (er.encoded > (ssize_t) setup_xml_buffer_size) { mdclog_write(MDCLOG_ERR, "Buffer of size %d is to small for %s, at %s line %d", (int)setup_xml_buffer_size, asn_DEF_E2AP_PDU.name, __func__, __LINE__); break; } std::string xmlString(setup_xml_buffer_size, setup_xml_buffer_size + er.encoded); vector RANfunctionsAdded_v; vector RANfunctionsModified_v; RANfunctionsAdded_v.clear(); RANfunctionsModified_v.clear(); if (collectSetupAndServiceUpdate_RequestData(pdu, sctpMap, message, RANfunctionsAdded_v, RANfunctionsModified_v) != 0) { break; } buildAndsendSetupRequest(message, rmrMessageBuffer, pdu, RANfunctionsAdded_v); break; } case ProcedureCode_id_RICserviceUpdate: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICserviceUpdate %s", message.message.enodbName); } if (sendRequestToXapp(message, RIC_SERVICE_UPDATE, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "RIC_SERVICE_UPDATE message failed to send to xAPP"); } break; } case ProcedureCode_id_ErrorIndication: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got ErrorIndication %s", message.message.enodbName); } if (sendRequestToXapp(message, RIC_ERROR_INDICATION, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "RIC_ERROR_INDICATION failed to send to xAPP"); } break; } case ProcedureCode_id_Reset: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got Reset %s", message.message.enodbName); } if (sendRequestToXapp(message, RIC_X2_RESET, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "RIC_X2_RESET message failed to send to xAPP"); } break; } case ProcedureCode_id_RICcontrol: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICcontrol %s", message.message.enodbName); } break; } case ProcedureCode_id_RICindication: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICindication - initiating %s", message.message.enodbName); } for (auto i = 0; i < pdu->choice.initiatingMessage->value.choice.RICindication.protocolIEs.list.count; i++) { auto messageSent = false; RICindication_IEs_t *ie = pdu->choice.initiatingMessage->value.choice.RICindication.protocolIEs.list.array[i]; if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "ie type (ProtocolIE_ID) = %ld", ie->id); } if (ie->id == ProtocolIE_ID_id_RICrequestID) { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RIC requestId entry, ie type (ProtocolIE_ID) = %ld", ie->id); } if (ie->value.present == RICindication_IEs__value_PR_RICrequestID) { static unsigned char tx[32]; message.message.messageType = rmrMessageBuffer.sendMessage->mtype = RIC_INDICATION; snprintf((char *) tx, sizeof tx, "%15ld", transactionCounter++); rmr_bytes2xact(rmrMessageBuffer.sendMessage, tx, strlen((const char *) tx)); int exit_status = rmr_bytes2meid(rmrMessageBuffer.sendMessage, (unsigned char *)message.message.enodbName, strlen(message.message.enodbName)); rmrMessageBuffer.sendMessage->state = 0; // set sub_id to ricRequestorID for future lookup in rmr routing table. // it was set to ricInstanceID before rmrMessageBuffer.sendMessage->sub_id = ie->value.choice.RICrequestID.ricRequestorID; // rmrMessageBuffer.sendMessage->sub_id = (int)ie->value.choice.RICrequestID.ricInstanceID; unsigned char *me_id; unsigned char* me_id_ptr = rmr_get_meid(rmrMessageBuffer.sendMessage, me_id); mdclog_write(MDCLOG_DEBUG, "Received MEID: %s, exit_status %d, ptr %s", me_id, exit_status, me_id_ptr); //ie->value.choice.RICrequestID.ricInstanceID; if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "sub id = %d, mtype = %d, ric instance id %ld, requestor id = %ld", rmrMessageBuffer.sendMessage->sub_id, rmrMessageBuffer.sendMessage->mtype, ie->value.choice.RICrequestID.ricInstanceID, ie->value.choice.RICrequestID.ricRequestorID); } sendRmrMessage(rmrMessageBuffer, message); messageSent = true; } else { mdclog_write(MDCLOG_ERR, "RIC request id missing illigal request"); } } if (messageSent) { break; } } break; } case ProcedureCode_id_RICserviceQuery: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICserviceQuery %s", message.message.enodbName); } break; } case ProcedureCode_id_RICsubscription: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICsubscription %s", message.message.enodbName); } break; } case ProcedureCode_id_RICsubscriptionDelete: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICsubscriptionDelete %s", message.message.enodbName); } break; } default: { mdclog_write(MDCLOG_ERR, "Undefined or not supported message = %ld", procedureCode); message.message.messageType = 0; // no RMR message type yet buildJsonMessage(message); break; } } } /** * * @param pdu * @param message * @param rmrMessageBuffer */ void asnSuccsesfulMsg(E2AP_PDU_t *pdu, Sctp_Map_t *sctpMap, ReportingMessages_t &message, RmrMessagesBuffer_t &rmrMessageBuffer) { auto procedureCode = pdu->choice.successfulOutcome->procedureCode; auto logLevel = mdclog_level_get(); if (logLevel >= MDCLOG_INFO) { mdclog_write(MDCLOG_INFO, "Successful Outcome %ld", procedureCode); } switch (procedureCode) { case ProcedureCode_id_E2setup: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got E2setup\n"); } break; } case ProcedureCode_id_ErrorIndication: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got ErrorIndication %s", message.message.enodbName); } if (sendRequestToXapp(message, RIC_ERROR_INDICATION, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "RIC_ERROR_INDICATION failed to send to xAPP"); } break; } case ProcedureCode_id_Reset: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got Reset %s", message.message.enodbName); } if (sendRequestToXapp(message, RIC_X2_RESET, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "RIC_X2_RESET message failed to send to xAPP"); } break; } case ProcedureCode_id_RICcontrol: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICcontrol %s", message.message.enodbName); } for (auto i = 0; i < pdu->choice.successfulOutcome->value.choice.RICcontrolAcknowledge.protocolIEs.list.count; i++) { auto messageSent = false; RICcontrolAcknowledge_IEs_t *ie = pdu->choice.successfulOutcome->value.choice.RICcontrolAcknowledge.protocolIEs.list.array[i]; if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "ie type (ProtocolIE_ID) = %ld", ie->id); } if (ie->id == ProtocolIE_ID_id_RICrequestID) { if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RIC requestId entry, ie type (ProtocolIE_ID) = %ld", ie->id); } if (ie->value.present == RICcontrolAcknowledge_IEs__value_PR_RICrequestID) { message.message.messageType = rmrMessageBuffer.sendMessage->mtype = RIC_CONTROL_ACK; rmrMessageBuffer.sendMessage->state = 0; // rmrMessageBuffer.sendMessage->sub_id = (int) ie->value.choice.RICrequestID.ricRequestorID; rmrMessageBuffer.sendMessage->sub_id = (int)ie->value.choice.RICrequestID.ricInstanceID; static unsigned char tx[32]; snprintf((char *) tx, sizeof tx, "%15ld", transactionCounter++); rmr_bytes2xact(rmrMessageBuffer.sendMessage, tx, strlen((const char *) tx)); rmr_bytes2meid(rmrMessageBuffer.sendMessage, (unsigned char *)message.message.enodbName, strlen(message.message.enodbName)); sendRmrMessage(rmrMessageBuffer, message); messageSent = true; } else { mdclog_write(MDCLOG_ERR, "RIC request id missing illigal request"); } } if (messageSent) { break; } } break; } case ProcedureCode_id_RICindication: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICindication %s", message.message.enodbName); } for (auto i = 0; i < pdu->choice.initiatingMessage->value.choice.RICindication.protocolIEs.list.count; i++) { auto messageSent = false; RICindication_IEs_t *ie = pdu->choice.initiatingMessage->value.choice.RICindication.protocolIEs.list.array[i]; if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "ie type (ProtocolIE_ID) = %ld", ie->id); } if (ie->id == ProtocolIE_ID_id_RICrequestID) { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RIC requestId entry, ie type (ProtocolIE_ID) = %ld", ie->id); } if (ie->value.present == RICindication_IEs__value_PR_RICrequestID) { static unsigned char tx[32]; message.message.messageType = rmrMessageBuffer.sendMessage->mtype = RIC_INDICATION; snprintf((char *) tx, sizeof tx, "%15ld", transactionCounter++); rmr_bytes2xact(rmrMessageBuffer.sendMessage, tx, strlen((const char *) tx)); rmr_bytes2meid(rmrMessageBuffer.sendMessage, (unsigned char *)message.message.enodbName, strlen(message.message.enodbName)); rmrMessageBuffer.sendMessage->state = 0; rmrMessageBuffer.sendMessage->sub_id = (int)ie->value.choice.RICrequestID.ricInstanceID; if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "RIC sub id = %d, message type = %d", rmrMessageBuffer.sendMessage->sub_id, rmrMessageBuffer.sendMessage->mtype); } sendRmrMessage(rmrMessageBuffer, message); messageSent = true; } else { mdclog_write(MDCLOG_ERR, "RIC request id missing illigal request"); } } if (messageSent) { break; } } break; } case ProcedureCode_id_RICserviceQuery: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICserviceQuery %s", message.message.enodbName); } break; } case ProcedureCode_id_RICserviceUpdate: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICserviceUpdate %s", message.message.enodbName); } if (sendRequestToXapp(message, RIC_SERVICE_UPDATE, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "RIC_SERVICE_UPDATE message failed to send to xAPP"); } break; } case ProcedureCode_id_RICsubscription: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICsubscription %s", message.message.enodbName); } if (sendRequestToXapp(message, RIC_SUB_RESP, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "Subscription successful message failed to send to xAPP"); } break; } case ProcedureCode_id_RICsubscriptionDelete: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICsubscriptionDelete %s", message.message.enodbName); } if (sendRequestToXapp(message, RIC_SUB_DEL_RESP, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "Subscription delete successful message failed to send to xAPP"); } break; } default: { mdclog_write(MDCLOG_WARN, "Undefined or not supported message = %ld", procedureCode); message.message.messageType = 0; // no RMR message type yet buildJsonMessage(message); break; } } } /** * * @param pdu * @param message * @param rmrMessageBuffer */ void asnUnSuccsesfulMsg(E2AP_PDU_t *pdu, Sctp_Map_t *sctpMap, ReportingMessages_t &message, RmrMessagesBuffer_t &rmrMessageBuffer) { auto procedureCode = pdu->choice.unsuccessfulOutcome->procedureCode; auto logLevel = mdclog_level_get(); if (logLevel >= MDCLOG_INFO) { mdclog_write(MDCLOG_INFO, "Unsuccessful Outcome %ld", procedureCode); } switch (procedureCode) { case ProcedureCode_id_E2setup: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got E2setup\n"); } break; } case ProcedureCode_id_ErrorIndication: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got ErrorIndication %s", message.message.enodbName); } if (sendRequestToXapp(message, RIC_ERROR_INDICATION, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "RIC_ERROR_INDICATION failed to send to xAPP"); } break; } case ProcedureCode_id_Reset: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got Reset %s", message.message.enodbName); } if (sendRequestToXapp(message, RIC_X2_RESET, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "RIC_X2_RESET message failed to send to xAPP"); } break; } case ProcedureCode_id_RICcontrol: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICcontrol %s", message.message.enodbName); } for (int i = 0; i < pdu->choice.unsuccessfulOutcome->value.choice.RICcontrolFailure.protocolIEs.list.count; i++) { auto messageSent = false; RICcontrolFailure_IEs_t *ie = pdu->choice.unsuccessfulOutcome->value.choice.RICcontrolFailure.protocolIEs.list.array[i]; if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "ie type (ProtocolIE_ID) = %ld", ie->id); } if (ie->id == ProtocolIE_ID_id_RICrequestID) { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RIC requestId entry, ie type (ProtocolIE_ID) = %ld", ie->id); } if (ie->value.present == RICcontrolFailure_IEs__value_PR_RICrequestID) { message.message.messageType = rmrMessageBuffer.sendMessage->mtype = RIC_CONTROL_FAILURE; rmrMessageBuffer.sendMessage->state = 0; // rmrMessageBuffer.sendMessage->sub_id = (int)ie->value.choice.RICrequestID.ricRequestorID; rmrMessageBuffer.sendMessage->sub_id = (int)ie->value.choice.RICrequestID.ricInstanceID; static unsigned char tx[32]; snprintf((char *) tx, sizeof tx, "%15ld", transactionCounter++); rmr_bytes2xact(rmrMessageBuffer.sendMessage, tx, strlen((const char *) tx)); rmr_bytes2meid(rmrMessageBuffer.sendMessage, (unsigned char *) message.message.enodbName, strlen(message.message.enodbName)); sendRmrMessage(rmrMessageBuffer, message); messageSent = true; } else { mdclog_write(MDCLOG_ERR, "RIC request id missing illigal request"); } } if (messageSent) { break; } } break; } case ProcedureCode_id_RICindication: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICindication %s", message.message.enodbName); } for (auto i = 0; i < pdu->choice.initiatingMessage->value.choice.RICindication.protocolIEs.list.count; i++) { auto messageSent = false; RICindication_IEs_t *ie = pdu->choice.initiatingMessage->value.choice.RICindication.protocolIEs.list.array[i]; if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "ie type (ProtocolIE_ID) = %ld", ie->id); } if (ie->id == ProtocolIE_ID_id_RICrequestID) { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RIC requestId entry, ie type (ProtocolIE_ID) = %ld", ie->id); } if (ie->value.present == RICindication_IEs__value_PR_RICrequestID) { static unsigned char tx[32]; message.message.messageType = rmrMessageBuffer.sendMessage->mtype = RIC_INDICATION; snprintf((char *) tx, sizeof tx, "%15ld", transactionCounter++); rmr_bytes2xact(rmrMessageBuffer.sendMessage, tx, strlen((const char *) tx)); rmr_bytes2meid(rmrMessageBuffer.sendMessage, (unsigned char *)message.message.enodbName, strlen(message.message.enodbName)); rmrMessageBuffer.sendMessage->state = 0; // rmrMessageBuffer.sendMessage->sub_id = (int)ie->value.choice.RICrequestID.ricRequestorID; rmrMessageBuffer.sendMessage->sub_id = (int)ie->value.choice.RICrequestID.ricInstanceID; if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "RIC sub id = %d, message type = %d", rmrMessageBuffer.sendMessage->sub_id, rmrMessageBuffer.sendMessage->mtype); } sendRmrMessage(rmrMessageBuffer, message); messageSent = true; } else { mdclog_write(MDCLOG_ERR, "RIC request id missing illigal request"); } } if (messageSent) { break; } } break; } case ProcedureCode_id_RICserviceQuery: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICserviceQuery %s", message.message.enodbName); } break; } case ProcedureCode_id_RICserviceUpdate: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICserviceUpdate %s", message.message.enodbName); } if (sendRequestToXapp(message, RIC_SERVICE_UPDATE, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "RIC_SERVICE_UPDATE message failed to send to xAPP"); } break; } case ProcedureCode_id_RICsubscription: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICsubscription %s", message.message.enodbName); } if (sendRequestToXapp(message, RIC_SUB_FAILURE, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "Subscription unsuccessful message failed to send to xAPP"); } break; } case ProcedureCode_id_RICsubscriptionDelete: { if (logLevel >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got RICsubscriptionDelete %s", message.message.enodbName); } if (sendRequestToXapp(message, RIC_SUB_DEL_FAILURE, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "Subscription Delete unsuccessful message failed to send to xAPP"); } break; } default: { mdclog_write(MDCLOG_WARN, "Undefined or not supported message = %ld", procedureCode); message.message.messageType = 0; // no RMR message type yet buildJsonMessage(message); break; } } } /** * * @param message * @param requestId * @param rmrMmessageBuffer * @return */ int sendRequestToXapp(ReportingMessages_t &message, int requestId, RmrMessagesBuffer_t &rmrMmessageBuffer) { rmr_bytes2meid(rmrMmessageBuffer.sendMessage, (unsigned char *)message.message.enodbName, strlen(message.message.enodbName)); message.message.messageType = rmrMmessageBuffer.sendMessage->mtype = requestId; rmrMmessageBuffer.sendMessage->state = 0; static unsigned char tx[32]; snprintf((char *) tx, sizeof tx, "%15ld", transactionCounter++); rmr_bytes2xact(rmrMmessageBuffer.sendMessage, tx, strlen((const char *) tx)); auto rc = sendRmrMessage(rmrMmessageBuffer, message); return rc; } void getRmrContext(sctp_params_t &pSctpParams) { pSctpParams.rmrCtx = nullptr; pSctpParams.rmrCtx = rmr_init(pSctpParams.rmrAddress, RECEIVE_XAPP_BUFFER_SIZE, RMRFL_NONE); if (pSctpParams.rmrCtx == nullptr) { mdclog_write(MDCLOG_ERR, "Failed to initialize RMR"); return; } rmr_set_stimeout(pSctpParams.rmrCtx, 0); // disable retries for any send operation // we need to find that routing table exist and we can run if (mdclog_level_get() >= MDCLOG_INFO) { mdclog_write(MDCLOG_INFO, "We are after RMR INIT wait for RMR_Ready"); } int rmrReady = 0; int count = 0; while (!rmrReady) { if ((rmrReady = rmr_ready(pSctpParams.rmrCtx)) == 0) { sleep(1); } count++; if (count % 60 == 0) { mdclog_write(MDCLOG_INFO, "waiting to RMR ready state for %d seconds", count); } } if (mdclog_level_get() >= MDCLOG_INFO) { mdclog_write(MDCLOG_INFO, "RMR running"); } rmr_init_trace(pSctpParams.rmrCtx, 200); // get the RMR fd for the epoll pSctpParams.rmrListenFd = rmr_get_rcvfd(pSctpParams.rmrCtx); struct epoll_event event{}; // add RMR fd to epoll event.events = (EPOLLIN); event.data.fd = pSctpParams.rmrListenFd; // add listening RMR FD to epoll if (epoll_ctl(pSctpParams.epoll_fd, EPOLL_CTL_ADD, pSctpParams.rmrListenFd, &event)) { mdclog_write(MDCLOG_ERR, "Failed to add RMR descriptor to epoll"); close(pSctpParams.rmrListenFd); rmr_close(pSctpParams.rmrCtx); pSctpParams.rmrCtx = nullptr; } } int PER_FromXML(ReportingMessages_t &message, RmrMessagesBuffer_t &rmrMessageBuffer) { E2AP_PDU_t *pdu = nullptr; if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "got xml setup response of size %d is:%s", rmrMessageBuffer.rcvMessage->len, rmrMessageBuffer.rcvMessage->payload); } auto rval = asn_decode(nullptr, ATS_BASIC_XER, &asn_DEF_E2AP_PDU, (void **) &pdu, rmrMessageBuffer.rcvMessage->payload, rmrMessageBuffer.rcvMessage->len); if (rval.code != RC_OK) { mdclog_write(MDCLOG_ERR, "Error %d Decoding (unpack) setup response from E2MGR : %s", rval.code, message.message.enodbName); return -1; } int buff_size = RECEIVE_XAPP_BUFFER_SIZE; auto er = asn_encode_to_buffer(nullptr, ATS_ALIGNED_BASIC_PER, &asn_DEF_E2AP_PDU, pdu, rmrMessageBuffer.rcvMessage->payload, buff_size); if (er.encoded == -1) { mdclog_write(MDCLOG_ERR, "encoding of %s failed, %s", asn_DEF_E2AP_PDU.name, strerror(errno)); return -1; } else if (er.encoded > (ssize_t)buff_size) { mdclog_write(MDCLOG_ERR, "Buffer of size %d is to small for %s, at %s line %d", (int)rmrMessageBuffer.rcvMessage->len, asn_DEF_E2AP_PDU.name, __func__, __LINE__); return -1; } rmrMessageBuffer.rcvMessage->len = er.encoded; return 0; } /** * * @param sctpMap * @param rmrMessageBuffer * @param ts * @return */ int receiveXappMessages(Sctp_Map_t *sctpMap, RmrMessagesBuffer_t &rmrMessageBuffer, struct timespec &ts) { if (rmrMessageBuffer.rcvMessage == nullptr) { //we have error mdclog_write(MDCLOG_ERR, "RMR Allocation message, %s", strerror(errno)); return -1; } if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Call to rmr_rcv_msg"); } rmrMessageBuffer.rcvMessage = rmr_rcv_msg(rmrMessageBuffer.rmrCtx, rmrMessageBuffer.rcvMessage); if (rmrMessageBuffer.rcvMessage == nullptr) { mdclog_write(MDCLOG_ERR, "RMR Receving message with null pointer, Realloc rmr mesage buffer"); rmrMessageBuffer.rcvMessage = rmr_alloc_msg(rmrMessageBuffer.rmrCtx, RECEIVE_XAPP_BUFFER_SIZE); return -2; } ReportingMessages_t message; message.message.direction = 'D'; message.message.time.tv_nsec = ts.tv_nsec; message.message.time.tv_sec = ts.tv_sec; // get message payload //auto msgData = msg->payload; if (rmrMessageBuffer.rcvMessage->state != 0) { mdclog_write(MDCLOG_ERR, "RMR Receving message with stat = %d", rmrMessageBuffer.rcvMessage->state); return -1; } rmr_get_meid(rmrMessageBuffer.rcvMessage, (unsigned char *)message.message.enodbName); switch (rmrMessageBuffer.rcvMessage->mtype) { case RIC_E2_SETUP_RESP : { if (PER_FromXML(message, rmrMessageBuffer) != 0) { break; } if (sendDirectionalSctpMsg(rmrMessageBuffer, message, 0, sctpMap) != 0) { mdclog_write(MDCLOG_ERR, "Failed to send RIC_E2_SETUP_RESP"); return -6; } break; } case RIC_E2_SETUP_FAILURE : { if (PER_FromXML(message, rmrMessageBuffer) != 0) { break; } if (sendDirectionalSctpMsg(rmrMessageBuffer, message, 0, sctpMap) != 0) { mdclog_write(MDCLOG_ERR, "Failed to send RIC_E2_SETUP_FAILURE"); return -6; } break; } case RIC_ERROR_INDICATION: { if (sendDirectionalSctpMsg(rmrMessageBuffer, message, 0, sctpMap) != 0) { mdclog_write(MDCLOG_ERR, "Failed to send RIC_ERROR_INDICATION"); return -6; } break; } case RIC_SUB_REQ: { if (sendDirectionalSctpMsg(rmrMessageBuffer, message, 0, sctpMap) != 0) { mdclog_write(MDCLOG_ERR, "Failed to send RIC_SUB_REQ"); return -6; } break; } case RIC_SUB_DEL_REQ: { if (sendDirectionalSctpMsg(rmrMessageBuffer, message, 0, sctpMap) != 0) { mdclog_write(MDCLOG_ERR, "Failed to send RIC_SUB_DEL_REQ"); return -6; } break; } case RIC_CONTROL_REQ: { if (sendDirectionalSctpMsg(rmrMessageBuffer, message, 0, sctpMap) != 0) { mdclog_write(MDCLOG_ERR, "Failed to send RIC_CONTROL_REQ"); return -6; } break; } case RIC_SERVICE_QUERY: { if (PER_FromXML(message, rmrMessageBuffer) != 0) { break; } if (sendDirectionalSctpMsg(rmrMessageBuffer, message, 0, sctpMap) != 0) { mdclog_write(MDCLOG_ERR, "Failed to send RIC_SERVICE_QUERY"); return -6; } break; } case RIC_SERVICE_UPDATE_ACK: { if (PER_FromXML(message, rmrMessageBuffer) != 0) { break; } if (sendDirectionalSctpMsg(rmrMessageBuffer, message, 0, sctpMap) != 0) { mdclog_write(MDCLOG_ERR, "Failed to send RIC_SERVICE_UPDATE_ACK"); return -6; } break; } case RIC_SERVICE_UPDATE_FAILURE: { if (PER_FromXML(message, rmrMessageBuffer) != 0) { break; } if (sendDirectionalSctpMsg(rmrMessageBuffer, message, 0, sctpMap) != 0) { mdclog_write(MDCLOG_ERR, "Failed to send RIC_SERVICE_UPDATE_FAILURE"); return -6; } break; } case RIC_X2_RESET: { if (sendDirectionalSctpMsg(rmrMessageBuffer, message, 0, sctpMap) != 0) { mdclog_write(MDCLOG_ERR, "Failed to send RIC_X2_RESET"); return -6; } break; } case RIC_X2_RESET_RESP: { if (sendDirectionalSctpMsg(rmrMessageBuffer, message, 0, sctpMap) != 0) { mdclog_write(MDCLOG_ERR, "Failed to send RIC_X2_RESET_RESP"); return -6; } break; } case RIC_SCTP_CLEAR_ALL: { mdclog_write(MDCLOG_INFO, "RIC_SCTP_CLEAR_ALL"); // loop on all keys and close socket and then erase all map. vector v; sctpMap->getKeys(v); for (auto const &iter : v) { //}; iter != sctpMap.end(); iter++) { if (!boost::starts_with((string) (iter), "host:") && !boost::starts_with((string) (iter), "msg:")) { auto *peerInfo = (ConnectedCU_t *) sctpMap->find(iter); if (peerInfo == nullptr) { continue; } close(peerInfo->fileDescriptor); memcpy(message.message.enodbName, peerInfo->enodbName, sizeof(peerInfo->enodbName)); message.message.direction = 'D'; message.message.time.tv_nsec = ts.tv_nsec; message.message.time.tv_sec = ts.tv_sec; message.message.asnLength = rmrMessageBuffer.sendMessage->len = snprintf((char *)rmrMessageBuffer.sendMessage->payload, 256, "%s|RIC_SCTP_CLEAR_ALL", peerInfo->enodbName); message.message.asndata = rmrMessageBuffer.sendMessage->payload; mdclog_write(MDCLOG_INFO, "%s", message.message.asndata); if (sendRequestToXapp(message, RIC_SCTP_CONNECTION_FAILURE, rmrMessageBuffer) != 0) { mdclog_write(MDCLOG_ERR, "SCTP_CONNECTION_FAIL message failed to send to xAPP"); } free(peerInfo); } } sleep(1); sctpMap->clear(); break; } case E2_TERM_KEEP_ALIVE_REQ: { // send message back rmr_bytes2payload(rmrMessageBuffer.sendMessage, (unsigned char *)rmrMessageBuffer.ka_message, rmrMessageBuffer.ka_message_len); rmrMessageBuffer.sendMessage->mtype = E2_TERM_KEEP_ALIVE_RESP; rmrMessageBuffer.sendMessage->state = 0; static unsigned char tx[32]; auto txLen = snprintf((char *) tx, sizeof tx, "%15ld", transactionCounter++); rmr_bytes2xact(rmrMessageBuffer.sendMessage, tx, txLen); rmrMessageBuffer.sendMessage = rmr_send_msg(rmrMessageBuffer.rmrCtx, rmrMessageBuffer.sendMessage); if (rmrMessageBuffer.sendMessage == nullptr) { rmrMessageBuffer.sendMessage = rmr_alloc_msg(rmrMessageBuffer.rmrCtx, RECEIVE_XAPP_BUFFER_SIZE); mdclog_write(MDCLOG_ERR, "Failed to send E2_TERM_KEEP_ALIVE_RESP RMR message returned NULL"); } else if (rmrMessageBuffer.sendMessage->state != 0) { mdclog_write(MDCLOG_ERR, "Failed to send E2_TERM_KEEP_ALIVE_RESP, on RMR state = %d ( %s)", rmrMessageBuffer.sendMessage->state, translateRmrErrorMessages(rmrMessageBuffer.sendMessage->state).c_str()); } else if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Got Keep Alive Request send : %s", rmrMessageBuffer.ka_message); } break; } case 42000: { mdclog_write(MDCLOG_INFO, "Received message 42000"); // sendMessageSocket(1234); break; } default: mdclog_write(MDCLOG_WARN, "Message Type : %d is not seported", rmrMessageBuffer.rcvMessage->mtype); message.message.asndata = rmrMessageBuffer.rcvMessage->payload; message.message.asnLength = rmrMessageBuffer.rcvMessage->len; message.message.time.tv_nsec = ts.tv_nsec; message.message.time.tv_sec = ts.tv_sec; message.message.messageType = rmrMessageBuffer.rcvMessage->mtype; buildJsonMessage(message); return -7; } if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "EXIT OK from %s", __FUNCTION__); } return 0; } int sendMessageSocket(const int dest_port) { const char* dest_ip = "10.0.2.100"; int sckfd = socket(AF_INET, SOCK_STREAM, IPPROTO_SCTP); if (sckfd < 0) { mdclog_write(MDCLOG_ERR, "ERROR: OPEN SOCKET"); close(sckfd); return -1; } // SET SOCKET OPTIONS TO RELEASE THE SOCKET ADDRESS IMMEDIATELY AFTER // THE SOCKET IS CLOSED int option(1); setsockopt(sckfd, SOL_SOCKET, SO_REUSEADDR, (char*)&option, sizeof(option)); struct sockaddr_in dest_addr = {0}; dest_addr.sin_family = AF_INET; dest_addr.sin_port = htons(dest_port); // convert dest_ip from char* to network address if (inet_pton(AF_INET, dest_ip, &dest_addr.sin_addr) <= 0) { mdclog_write(MDCLOG_ERR, "ERROR CONVERTING IP TO INTERNET ADDR"); close(sckfd); // if conversion fail, close the socket and return error -2 return -2; } if (connect(sckfd, (struct sockaddr *) &dest_addr, sizeof(dest_addr)) < 0) { mdclog_write(MDCLOG_ERR, "ERROR: CONNECT"); close(sckfd); return -3; } // TRANSMIT DATA const size_t max_size = 512; char buf[max_size] = "Hello, Server!"; // store the data in a buffer size_t data_size = 14; int sent_size = sctp_sendmsg(sckfd, buf, data_size, NULL, 0, 0, 0, 0, 0, 0 ); // int sent_size = sctp_sendmsg(sckfd, (void *) msg, strlen(msg) + 1, NULL, 0, 0, 0, 0, 0, 0 ); if(sent_size < 0) { // the send returns a size of -1 in case of errors mdclog_write(MDCLOG_ERR, "ERROR: SEND"); close(sckfd); // if error close the socket and exit return -4; } else { mdclog_write(MDCLOG_INFO, "Message sent"); } close(sckfd); return 0; // // open a SOCK_STREAM (TCP) socket // int sckfd = socket(AF_INET, SOCK_STREAM, 0); // if (sckfd < 0){ // mdclog_write(MDCLOG_ERR, "ERROR: OPEN SOCKET"); // close(sckfd); // return -1; // } // // // SET SOCKET OPTIONS TO RELEASE THE SOCKET ADDRESS IMMEDIATELY AFTER // // THE SOCKET IS CLOSED // int option(1); // setsockopt(sckfd, SOL_SOCKET, SO_REUSEADDR, (char*)&option, sizeof(option)); // // //SET SERVER DESTINATION ADDRESS // struct sockaddr_in dest_addr = {0}; // set all elements of the struct to 0 // dest_addr.sin_family = AF_INET; // address family is AF_INET (IPV4) // // // convert dest_port to network number format // dest_addr.sin_port = htons(dest_port); // // convert dest_ip from char* to network address // if (inet_pton(AF_INET, dest_ip, &dest_addr.sin_addr) <= 0) { // mdclog_write(MDCLOG_ERR, "ERROR CONVERTING IP TO INTERNET ADDR"); // close(sckfd); // if conversion fail, close the socket and return error -2 // return -2; // } // // //CONNECT THE SOCKET TO THE SERVER IP:PORT SPECIFIED INTO DEST_ADDR // if (connect(sckfd, (struct sockaddr*) &dest_addr, sizeof(dest_addr)) < 0) { // mdclog_write(MDCLOG_ERR, "ERROR: CONNECT"); // close(sckfd); // if connection failed return // return -3; // } // // //TRANSMIT DATA // const size_t max_size = 512; // char buf[max_size] = "Hello from e2term"; // store the data in a buffer // size_t data_size = 10; // int sent_size = send(sckfd,buf,data_size,0); // send the data through sckfd // // if(sent_size < 0) { // the send returns a size of -1 in case of errors // mdclog_write(MDCLOG_ERR, "ERROR: SEND"); // close(sckfd); // if error close the socket and exit // return -4; // } // else { // mdclog_write(MDCLOG_INFO, "Message sent"); // } // // memset(buf, 0, max_size); // set buffer to zero for next read // // //CLOSE THE SOCKET // close(sckfd); } /** * Send message to the CU that is not expecting for successful or unsuccessful results * @param messageBuffer * @param message * @param failedMsgId * @param sctpMap * @return */ int sendDirectionalSctpMsg(RmrMessagesBuffer_t &messageBuffer, ReportingMessages_t &message, int failedMsgId, Sctp_Map_t *sctpMap) { getRequestMetaData(message, messageBuffer); if (mdclog_level_get() >= MDCLOG_INFO) { mdclog_write(MDCLOG_INFO, "send message to %s address", message.message.enodbName); } auto rc = sendMessagetoCu(sctpMap, messageBuffer, message, failedMsgId); return rc; } /** * * @param sctpMap * @param messageBuffer * @param message * @param failedMesgId * @return */ int sendMessagetoCu(Sctp_Map_t *sctpMap, RmrMessagesBuffer_t &messageBuffer, ReportingMessages_t &message, int failedMesgId) { auto *peerInfo = (ConnectedCU_t *) sctpMap->find(message.message.enodbName); if (peerInfo == nullptr) { if (failedMesgId != 0) { sendFailedSendingMessagetoXapp(messageBuffer, message, failedMesgId); } else { mdclog_write(MDCLOG_ERR, "Failed to send message no CU entry %s", message.message.enodbName); } return -1; } // get the FD message.message.messageType = messageBuffer.rcvMessage->mtype; auto rc = sendSctpMsg(peerInfo, message, sctpMap); return rc; } /** * * @param rmrCtx the rmr context to send and receive * @param msg the msg we got fromxApp * @param metaData data from xApp in ordered struct * @param failedMesgId the return message type error */ void sendFailedSendingMessagetoXapp(RmrMessagesBuffer_t &rmrMessageBuffer, ReportingMessages_t &message, int failedMesgId) { rmr_mbuf_t *msg = rmrMessageBuffer.sendMessage; msg->len = snprintf((char *) msg->payload, 200, "the gNb/eNode name %s not found", message.message.enodbName); if (mdclog_level_get() >= MDCLOG_INFO) { mdclog_write(MDCLOG_INFO, "%s", msg->payload); } msg->mtype = failedMesgId; msg->state = 0; static unsigned char tx[32]; snprintf((char *) tx, sizeof tx, "%15ld", transactionCounter++); rmr_bytes2xact(msg, tx, strlen((const char *) tx)); sendRmrMessage(rmrMessageBuffer, message); } /** * * @param epoll_fd * @param peerInfo * @param events * @param sctpMap * @param enodbName * @param msgType * @return */ int addToEpoll(int epoll_fd, ConnectedCU_t *peerInfo, uint32_t events, Sctp_Map_t *sctpMap, char *enodbName, int msgType) { // Add to Epol struct epoll_event event{}; event.data.ptr = peerInfo; event.events = events; if (epoll_ctl(epoll_fd, EPOLL_CTL_ADD, peerInfo->fileDescriptor, &event) < 0) { if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "epoll_ctl EPOLL_CTL_ADD (may chack not to quit here), %s, %s %d", strerror(errno), __func__, __LINE__); } close(peerInfo->fileDescriptor); if (enodbName != nullptr) { cleanHashEntry(peerInfo, sctpMap); char key[MAX_ENODB_NAME_SIZE * 2]; snprintf(key, MAX_ENODB_NAME_SIZE * 2, "msg:%s|%d", enodbName, msgType); if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "remove key = %s from %s at line %d", key, __FUNCTION__, __LINE__); } auto tmp = sctpMap->find(key); if (tmp) { free(tmp); sctpMap->erase(key); } } else { peerInfo->enodbName[0] = 0; } mdclog_write(MDCLOG_ERR, "epoll_ctl EPOLL_CTL_ADD (may chack not to quit here)"); return -1; } return 0; } /** * * @param epoll_fd * @param peerInfo * @param events * @param sctpMap * @param enodbName * @param msgType * @return */ int modifyToEpoll(int epoll_fd, ConnectedCU_t *peerInfo, uint32_t events, Sctp_Map_t *sctpMap, char *enodbName, int msgType) { // Add to Epol struct epoll_event event{}; event.data.ptr = peerInfo; event.events = events; if (epoll_ctl(epoll_fd, EPOLL_CTL_MOD, peerInfo->fileDescriptor, &event) < 0) { if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "epoll_ctl EPOLL_CTL_MOD (may chack not to quit here), %s, %s %d", strerror(errno), __func__, __LINE__); } close(peerInfo->fileDescriptor); cleanHashEntry(peerInfo, sctpMap); char key[MAX_ENODB_NAME_SIZE * 2]; snprintf(key, MAX_ENODB_NAME_SIZE * 2, "msg:%s|%d", enodbName, msgType); if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "remove key = %s from %s at line %d", key, __FUNCTION__, __LINE__); } auto tmp = sctpMap->find(key); if (tmp) { free(tmp); } sctpMap->erase(key); mdclog_write(MDCLOG_ERR, "epoll_ctl EPOLL_CTL_ADD (may chack not to quit here)"); return -1; } return 0; } int sendRmrMessage(RmrMessagesBuffer_t &rmrMessageBuffer, ReportingMessages_t &message) { buildJsonMessage(message); rmrMessageBuffer.sendMessage = rmr_send_msg(rmrMessageBuffer.rmrCtx, rmrMessageBuffer.sendMessage); if (rmrMessageBuffer.sendMessage == nullptr) { rmrMessageBuffer.sendMessage = rmr_alloc_msg(rmrMessageBuffer.rmrCtx, RECEIVE_XAPP_BUFFER_SIZE); mdclog_write(MDCLOG_ERR, "RMR failed send message returned with NULL pointer"); return -1; } if (rmrMessageBuffer.sendMessage->state != 0) { char meid[RMR_MAX_MEID]{}; if (rmrMessageBuffer.sendMessage->state == RMR_ERR_RETRY) { usleep(5); rmrMessageBuffer.sendMessage->state = 0; mdclog_write(MDCLOG_INFO, "RETRY sending Message type %d to Xapp from %s", rmrMessageBuffer.sendMessage->mtype, rmr_get_meid(rmrMessageBuffer.sendMessage, (unsigned char *)meid)); rmrMessageBuffer.sendMessage = rmr_send_msg(rmrMessageBuffer.rmrCtx, rmrMessageBuffer.sendMessage); if (rmrMessageBuffer.sendMessage == nullptr) { mdclog_write(MDCLOG_ERR, "RMR failed send message returned with NULL pointer"); rmrMessageBuffer.sendMessage = rmr_alloc_msg(rmrMessageBuffer.rmrCtx, RECEIVE_XAPP_BUFFER_SIZE); return -1; } else if (rmrMessageBuffer.sendMessage->state != 0) { mdclog_write(MDCLOG_ERR, "Message state %s while sending request %d to Xapp from %s after retry of 10 microseconds", translateRmrErrorMessages(rmrMessageBuffer.sendMessage->state).c_str(), rmrMessageBuffer.sendMessage->mtype, rmr_get_meid(rmrMessageBuffer.sendMessage, (unsigned char *)meid)); auto rc = rmrMessageBuffer.sendMessage->state; return rc; } } else { mdclog_write(MDCLOG_ERR, "Message state %s while sending request %d to Xapp from %s", translateRmrErrorMessages(rmrMessageBuffer.sendMessage->state).c_str(), rmrMessageBuffer.sendMessage->mtype, rmr_get_meid(rmrMessageBuffer.sendMessage, (unsigned char *)meid)); return rmrMessageBuffer.sendMessage->state; } } return 0; } void buildJsonMessage(ReportingMessages_t &message) { if (jsonTrace) { message.outLen = sizeof(message.base64Data); base64::encode((const unsigned char *) message.message.asndata, (const int) message.message.asnLength, message.base64Data, message.outLen); if (mdclog_level_get() >= MDCLOG_DEBUG) { mdclog_write(MDCLOG_DEBUG, "Tracing: ASN length = %d, base64 message length = %d ", (int) message.message.asnLength, (int) message.outLen); } snprintf(message.buffer, sizeof(message.buffer), "{\"header\": {\"ts\": \"%ld.%09ld\"," "\"ranName\": \"%s\"," "\"messageType\": %d," "\"direction\": \"%c\"}," "\"base64Length\": %d," "\"asnBase64\": \"%s\"}", message.message.time.tv_sec, message.message.time.tv_nsec, message.message.enodbName, message.message.messageType, message.message.direction, (int) message.outLen, message.base64Data); static src::logger_mt &lg = my_logger::get(); BOOST_LOG(lg) << message.buffer; } } /** * take RMR error code to string * @param state * @return */ string translateRmrErrorMessages(int state) { string str = {}; switch (state) { case RMR_OK: str = "RMR_OK - state is good"; break; case RMR_ERR_BADARG: str = "RMR_ERR_BADARG - argument passd to function was unusable"; break; case RMR_ERR_NOENDPT: str = "RMR_ERR_NOENDPT - send//call could not find an endpoint based on msg type"; break; case RMR_ERR_EMPTY: str = "RMR_ERR_EMPTY - msg received had no payload; attempt to send an empty message"; break; case RMR_ERR_NOHDR: str = "RMR_ERR_NOHDR - message didn't contain a valid header"; break; case RMR_ERR_SENDFAILED: str = "RMR_ERR_SENDFAILED - send failed; errno has nano reason"; break; case RMR_ERR_CALLFAILED: str = "RMR_ERR_CALLFAILED - unable to send call() message"; break; case RMR_ERR_NOWHOPEN: str = "RMR_ERR_NOWHOPEN - no wormholes are open"; break; case RMR_ERR_WHID: str = "RMR_ERR_WHID - wormhole id was invalid"; break; case RMR_ERR_OVERFLOW: str = "RMR_ERR_OVERFLOW - operation would have busted through a buffer/field size"; break; case RMR_ERR_RETRY: str = "RMR_ERR_RETRY - request (send/call/rts) failed, but caller should retry (EAGAIN for wrappers)"; break; case RMR_ERR_RCVFAILED: str = "RMR_ERR_RCVFAILED - receive failed (hard error)"; break; case RMR_ERR_TIMEOUT: str = "RMR_ERR_TIMEOUT - message processing call timed out"; break; case RMR_ERR_UNSET: str = "RMR_ERR_UNSET - the message hasn't been populated with a transport buffer"; break; case RMR_ERR_TRUNC: str = "RMR_ERR_TRUNC - received message likely truncated"; break; case RMR_ERR_INITFAILED: str = "RMR_ERR_INITFAILED - initialisation of something (probably message) failed"; break; case RMR_ERR_NOTSUPP: str = "RMR_ERR_NOTSUPP - the request is not supported, or RMr was not initialised for the request"; break; default: char buf[128]{}; snprintf(buf, sizeof buf, "UNDOCUMENTED RMR_ERR : %d", state); str = buf; break; } return str; }