/* * (C) 2022 by sysmocom s.f.m.c. GmbH * All Rights Reserved * * Author: Eric Wild * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU Affero General Public License as published by * the Free Software Foundation; either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU Affero General Public License for more details. * * You should have received a copy of the GNU Affero General Public License * along with this program. If not, see . * */ #include #include "sigProcLib.h" #include "ms.h" #include #include #include #include // #define TXDEBUG extern "C" { #include "sch.h" #include "convolve.h" #include "convert.h" #include #include #include #include #include extern void trxc_log_init(void *tallctx); #ifdef LSANDEBUG void __lsan_do_recoverable_leak_check(); #endif } #include "ms_trxcon_if.h" #include "ms_upper.h" #include "threadsched.h" extern bool trxc_l1ctl_init(void *tallctx); struct trxcon_inst *g_trxcon; tx_queue_t txq; cmd_queue_t cmdq_to_phy; cmdr_queue_t cmdq_from_phy; #ifdef LOG #undef LOG #define LOG(...) upper_trx::dummy_log() #endif #define DBGLG(...) upper_trx::dummy_log() std::atomic g_exit_flag; void upper_trx::stop_upper_threads() { g_exit_flag = true; pthread_join(thr_control, NULL); pthread_join(thr_tx, NULL); } void upper_trx::start_threads() { DBGLG(...) << "spawning threads.." << std::endl; thr_control = spawn_worker_thread( sched_params::thread_names::U_CTL, [](void *args) -> void * { upper_trx *t = reinterpret_cast(args); #ifdef TXDEBUG struct sched_param param; int policy; pthread_getschedparam(pthread_self(), &policy, ¶m); printf("ID: %lu, CPU: %d policy = %d priority = %d\n", pthread_self(), sched_getcpu(), policy, param.sched_priority); #endif std::cerr << "started U control!" << std::endl; while (!g_exit_flag) { t->driveControl(); } std::cerr << "exit U control!" << std::endl; return 0; }, this); thr_tx = spawn_worker_thread( sched_params::thread_names::U_TX, [](void *args) -> void * { upper_trx *t = reinterpret_cast(args); #ifdef TXDEBUG struct sched_param param; int policy; pthread_getschedparam(pthread_self(), &policy, ¶m); printf("ID: %lu, CPU: %d policy = %d priority = %d\n", pthread_self(), sched_getcpu(), policy, param.sched_priority); #endif std::cerr << "started U tx!" << std::endl; while (!g_exit_flag) { t->driveTx(); } std::cerr << "exit U tx!" << std::endl; return 0; }, this); #ifdef LSANDEBUG std::thread([this] { set_name_aff_sched(sched_params::thread_names::LEAKCHECK); while (1) { std::this_thread::sleep_for(std::chrono::seconds{ 5 }); __lsan_do_recoverable_leak_check(); } }).detach(); #endif } void upper_trx::main_loop() { set_name_aff_sched(sched_params::thread_names::U_RX); set_upper_ready(true); while (!g_exit_flag) { driveReceiveFIFO(); osmo_select_main(1); trxcon_phyif_rsp r; if (cmdq_from_phy.spsc_pop(&r)) { DBGLG() << "HAVE RESP:" << r.type << std::endl; trxcon_phyif_handle_rsp(g_trxcon, &r); } } set_upper_ready(false); std::cerr << "exit U rx!" << std::endl; mOn = false; } // signalvector is owning despite claiming not to, but we can pretend, too.. static void static_free(void *wData){}; static void *static_alloc(size_t newSize) { return 0; }; bool upper_trx::pullRadioVector(GSM::Time &wTime, int &RSSI, int &timingOffset) { // float pow, avg = 1.0; const auto zero_pad_len = 40; // give the VA some runway for misaligned bursts const auto workbuf_size = zero_pad_len + ONE_TS_BURST_LEN + zero_pad_len; static complex workbuf[workbuf_size]; static int32_t meas_p, meas_rssi; static signalVector sv(workbuf, zero_pad_len, ONE_TS_BURST_LEN, static_alloc, static_free); one_burst e; auto ss = reinterpret_cast *>(&workbuf[zero_pad_len]); std::fill(workbuf, workbuf + workbuf_size, 0); // assert(sv.begin() == &workbuf[40]); while (!rxqueue.spsc_pop(&e)) { rxqueue.spsc_prep_pop(); } wTime = e.gsmts; const auto is_sch = gsm_sch_check_ts(wTime.TN(), wTime.FN()); const auto is_fcch = gsm_fcch_check_ts(wTime.TN(), wTime.FN()); trxcon_phyif_rtr_ind i = { static_cast(wTime.FN()), static_cast(wTime.TN()) }; trxcon_phyif_rtr_rsp r = {}; trxcon_phyif_handle_rtr_ind(g_trxcon, &i, &r); if (!(r.flags & TRXCON_PHYIF_RTR_F_ACTIVE)) { bladerf_get_rfic_rssi(dev, 0, &meas_p, &meas_rssi); // std::cerr << "G : \x1B[31m rx fail \033[0m @:" << meas_rssi << std::endl; return false; } if (is_fcch) { // return trash return true; } if (is_sch) { for (int i = 0; i < 148; i++) (demodded_softbits)[i] = (e.sch_bits[i]); RSSI = 10; timingOffset = 0; return true; } if (use_va) { convert_and_scale(ss, e.burst, ONE_TS_BURST_LEN * 2, 1.f / float(rxFullScale)); // pow = energyDetect(sv, 20 * 4 /*sps*/); // if (pow < -1) { // LOG(ALERT) << "Received empty burst"; // return false; // } // avg = sqrt(pow); { float ncmax; std::complex chan_imp_resp[CHAN_IMP_RESP_LENGTH * d_OSR]; auto normal_burst_start = get_norm_chan_imp_resp(ss, &chan_imp_resp[0], &ncmax, mTSC); #ifdef DBGXX float dcmax; std::complex chan_imp_resp2[CHAN_IMP_RESP_LENGTH * d_OSR]; auto dummy_burst_start = get_norm_chan_imp_resp(ss, &chan_imp_resp2[0], &dcmax, TS_DUMMY); auto is_nb = ncmax > dcmax; // DBGLG() << " U " << (is_nb ? "NB" : "DB") << "@ o nb: " << normal_burst_start // << " o db: " << dummy_burst_start << std::endl; #endif normal_burst_start = normal_burst_start < 39 ? normal_burst_start : 39; normal_burst_start = normal_burst_start > -39 ? normal_burst_start : -39; #ifdef DBGXX // fprintf(stderr, "%s %d\n", (is_nb ? "N":"D"), burst_time.FN()); // if (is_nb) #endif detect_burst_nb(ss, &chan_imp_resp[0], normal_burst_start, demodded_softbits); #ifdef DBGXX // else // detect_burst(ss, &chan_imp_resp2[0], dummy_burst_start, outbin); #endif } } else { // lower layer sch detection offset, easy to verify by just printing the detected value using both the va+sigproc code. convert_and_scale(ss + 16, e.burst, ONE_TS_BURST_LEN * 2, 15); // pow = energyDetect(sv, 20 * 4 /*sps*/); // if (pow < -1) { // LOG(ALERT) << "Received empty burst"; // return false; // } // avg = sqrt(pow); /* Detect normal or RACH bursts */ CorrType type = CorrType::TSC; struct estim_burst_params ebp; auto rc = detectAnyBurst(sv, mTSC, 3, 4, type, 48, &ebp); if (rc > 0) { type = (CorrType)rc; } if (rc < 0) { std::cerr << "UR : \x1B[31m rx fail \033[0m @ toa:" << ebp.toa << " " << e.gsmts.FN() << ":" << e.gsmts.TN() << std::endl; return false; } SoftVector *bits = demodAnyBurst(sv, type, 4, &ebp); SoftVector::const_iterator burstItr = bits->begin(); // invert and fix to +-127 sbits for (int ii = 0; ii < 148; ii++) { demodded_softbits[ii] = *burstItr++ > 0.0f ? -127 : 127; } delete bits; } RSSI = meas_rssi; // (int)floor(20.0 * log10(rxFullScale / avg)); // FIXME: properly handle offset, sch/nb alignment diff? handled by lower anyway... timingOffset = (int)round(0); return true; } void upper_trx::driveReceiveFIFO() { int RSSI; int TOA; // in 1/256 of a symbol GSM::Time burstTime; if (!mOn) return; if (pullRadioVector(burstTime, RSSI, TOA)) { trxcon_phyif_burst_ind bi; bi.fn = burstTime.FN(); bi.tn = burstTime.TN(); bi.rssi = RSSI; bi.toa256 = TOA; bi.burst = (sbit_t *)demodded_softbits; bi.burst_len = sizeof(demodded_softbits); trxcon_phyif_handle_burst_ind(g_trxcon, &bi); } burstTime.incTN(2); struct trxcon_phyif_rts_ind rts { static_cast(burstTime.FN()), static_cast(burstTime.TN()) }; trxcon_phyif_handle_rts_ind(g_trxcon, &rts); } void upper_trx::driveTx() { internal_q_tx_buf e; static BitVector newBurst(sizeof(e.buf)); while (!txq.spsc_pop(&e)) { txq.spsc_prep_pop(); } // ensure our tx cb is tickled and can exit if (g_exit_flag) { submit_burst_ts(0, 1337, 1); return; } internal_q_tx_buf *burst = &e; #ifdef TXDEBUG2 DBGLG() << "got burst!" << burst->r.fn << ":" << burst->ts << " current: " << timekeeper.gsmtime().FN() << " dff: " << (int64_t)((int64_t)timekeeper.gsmtime().FN() - (int64_t)burst->r.fn) << std::endl; #endif auto currTime = GSM::Time(burst->r.fn, burst->r.tn); int RSSI = (int)burst->r.pwr; BitVector::iterator itr = newBurst.begin(); auto *bufferItr = burst->buf; while (itr < newBurst.end()) *itr++ = *bufferItr++; auto txburst = modulateBurst(newBurst, 8 + (currTime.TN() % 4 == 0), 4); scaleVector(*txburst, txFullScale * pow(10, -RSSI / 10)); // float -> int16 blade_sample_type burst_buf[txburst->size()]; convert_and_scale(burst_buf, txburst->begin(), txburst->size() * 2, 1); #ifdef TXDEBUG2 auto check = signalVector(txburst->size(), 40); convert_and_scale(check.begin(), burst_buf, txburst->size() * 2, 1); estim_burst_params ebp; auto d = detectAnyBurst(check, 2, 4, 4, CorrType::RACH, 40, &ebp); if (d) DBGLG() << "RACH D! " << ebp.toa << std::endl; else DBGLG() << "RACH NOOOOOOOOOO D! " << ebp.toa << std::endl; // memory read --binary --outfile /tmp/mem.bin &burst_buf[0] --count 2500 --force #endif submit_burst(burst_buf, txburst->size(), currTime); delete txburst; } #ifdef TXDEBUG static const char *cmd2str(trxcon_phyif_cmd_type c) { switch (c) { case TRXCON_PHYIF_CMDT_RESET: return "TRXCON_PHYIF_CMDT_RESET"; case TRXCON_PHYIF_CMDT_POWERON: return "TRXCON_PHYIF_CMDT_POWERON"; case TRXCON_PHYIF_CMDT_POWEROFF: return "TRXCON_PHYIF_CMDT_POWEROFF"; case TRXCON_PHYIF_CMDT_MEASURE: return "TRXCON_PHYIF_CMDT_MEASURE"; case TRXCON_PHYIF_CMDT_SETFREQ_H0: return "TRXCON_PHYIF_CMDT_SETFREQ_H0"; case TRXCON_PHYIF_CMDT_SETFREQ_H1: return "TRXCON_PHYIF_CMDT_SETFREQ_H1"; case TRXCON_PHYIF_CMDT_SETSLOT: return "TRXCON_PHYIF_CMDT_SETSLOT"; case TRXCON_PHYIF_CMDT_SETTA: return "TRXCON_PHYIF_CMDT_SETTA"; default: return "UNKNOWN COMMAND!"; } } static void print_cmd(trxcon_phyif_cmd_type c) { DBGLG() << "handling " << cmd2str(c) << std::endl; } #endif bool upper_trx::driveControl() { trxcon_phyif_rsp r; trxcon_phyif_cmd cmd; while (!cmdq_to_phy.spsc_pop(&cmd)) { cmdq_to_phy.spsc_prep_pop(); if (g_exit_flag) return false; } if (g_exit_flag) return false; #ifdef TXDEBUG print_cmd(cmd.type); #endif switch (cmd.type) { case TRXCON_PHYIF_CMDT_RESET: set_ta(0); break; case TRXCON_PHYIF_CMDT_POWERON: if (!mOn) { mOn = true; start_lower_ms(); } break; case TRXCON_PHYIF_CMDT_POWEROFF: break; case TRXCON_PHYIF_CMDT_MEASURE: r.type = trxcon_phyif_cmd_type::TRXCON_PHYIF_CMDT_MEASURE; r.param.measure.band_arfcn = cmd.param.measure.band_arfcn; // FIXME: do we want to measure anything, considering the transceiver just syncs by.. syncing? r.param.measure.dbm = -80; // tuneRx(gsm_arfcn2freq10(cmd.param.measure.band_arfcn, 0) * 1000 * 100); // tuneTx(gsm_arfcn2freq10(cmd.param.measure.band_arfcn, 1) * 1000 * 100); cmdq_from_phy.spsc_push(&r); break; case TRXCON_PHYIF_CMDT_SETFREQ_H0: // tuneRx(gsm_arfcn2freq10(cmd.param.setfreq_h0.band_arfcn, 0) * 1000 * 100); // tuneTx(gsm_arfcn2freq10(cmd.param.setfreq_h0.band_arfcn, 1) * 1000 * 100); break; case TRXCON_PHYIF_CMDT_SETFREQ_H1: break; case TRXCON_PHYIF_CMDT_SETSLOT: break; case TRXCON_PHYIF_CMDT_SETTA: set_ta(cmd.param.setta.ta); break; } return false; } void sighandler(int sigset) { // we might get a sigpipe in case the l1ctl ud socket disconnects because mobile quits if (sigset == SIGPIPE || sigset == SIGINT) { g_exit_flag = true; // we know the flag is atomic and it prevents the trxcon cb handlers from writing // to the queues, so submit some trash to unblock the threads & exit trxcon_phyif_cmd cmd = {}; internal_q_tx_buf b = {}; txq.spsc_push(&b); cmdq_to_phy.spsc_push(&cmd); msleep(200); return; } } extern "C" { #include #include #include "mssdr_vty.h" } int main(int argc, char *argv[]) { auto tall_trxcon_ctx = talloc_init("trxcon context"); signal(SIGPIPE, sighandler); signal(SIGINT, sighandler); msgb_talloc_ctx_init(tall_trxcon_ctx, 0); trxc_log_init(tall_trxcon_ctx); /* Configure pretty logging */ log_set_print_extended_timestamp(osmo_stderr_target, 1); log_set_print_category_hex(osmo_stderr_target, 0); log_set_print_category(osmo_stderr_target, 1); log_set_print_level(osmo_stderr_target, 1); log_set_print_filename2(osmo_stderr_target, LOG_FILENAME_BASENAME); log_set_print_filename_pos(osmo_stderr_target, LOG_FILENAME_POS_LINE_END); osmo_fsm_log_timeouts(true); auto g_mssdr_ctx = vty_mssdr_ctx_alloc(tall_trxcon_ctx); vty_init(&g_mssdr_vty_info); logging_vty_add_cmds(); mssdr_vty_init(g_mssdr_ctx); const char *home_dir = getenv("HOME"); if (!home_dir) home_dir = "~"; auto config_file = talloc_asprintf(tall_trxcon_ctx, "%s/%s", home_dir, ".osmocom/bb/mssdr.cfg"); int rc = vty_read_config_file(config_file, NULL); if (rc < 0) { fprintf(stderr, "Failed to parse config file: '%s'\n", config_file); exit(2); } g_trxcon = trxcon_inst_alloc(tall_trxcon_ctx, 0); g_trxcon->gsmtap = nullptr; g_trxcon->phyif = nullptr; g_trxcon->phy_quirks.fbsb_extend_fns = 866; // 4 seconds, known to work. convolve_init(); convert_init(); sigProcLibSetup(); initvita(); int status = 0; auto trx = new upper_trx(&g_mssdr_ctx->cfg); status = trx->init_dev_and_streams(); if (status < 0) { std::cerr << "Error initializing hardware, quitting.." << std::endl; return -1; } set_name_aff_sched(sched_params::thread_names::MAIN); if (!trxc_l1ctl_init(tall_trxcon_ctx)) { std::cerr << "Error initializing l1ctl, quitting.." << std::endl; return -1; } // blocking, will return when global exit is requested trx->start_threads(); trx->main_loop(); trx->stop_threads(); trx->stop_upper_threads(); return status; }