/* * Copyright (C) 2015,2016 Jonathan Naylor, G4KLX * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; version 2 of the License. * * 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 General Public License for more details. */ #include "YSFControl.h" #include "YSFFICH.h" #include "Utils.h" #include "Sync.h" #include "Log.h" #include #include #include #include // #define DUMP_YSF CYSFControl::CYSFControl(const std::string& callsign, CDisplay* display, unsigned int timeout, bool duplex) : m_display(display), m_duplex(duplex), m_queue(5000U, "YSF Control"), m_state(RS_RF_LISTENING), m_timeoutTimer(1000U, timeout), m_interval(), m_frames(0U), m_errs(0U), m_bits(0U), m_source(NULL), m_dest(NULL), m_payload(), m_fp(NULL) { assert(display != NULL); m_payload.setUplink(callsign); m_payload.setDownlink(callsign); m_interval.start(); } CYSFControl::~CYSFControl() { } bool CYSFControl::writeModem(unsigned char *data) { assert(data != NULL); unsigned char type = data[0U]; if (type == TAG_LOST && m_state == RS_RF_AUDIO) { LogMessage("YSF, transmission lost, %.1f seconds, BER: %.1f%%", float(m_frames) / 10.0F, float(m_errs * 100U) / float(m_bits)); // if (m_parrot != NULL) // m_parrot->end(); writeEndOfTransmission(); return false; } if (type == TAG_LOST) return false; CYSFFICH fich; bool valid = fich.decode(data + 2U); if (valid && m_state == RS_RF_LISTENING) { unsigned char fi = fich.getFI(); if (fi == YSF_FI_TERMINATOR) return false; m_frames = 0U; m_errs = 0U; m_bits = 1U; m_timeoutTimer.start(); m_payload.reset(); m_state = RS_RF_AUDIO; #if defined(DUMP_YSF) openFile(); #endif } if (m_state != RS_RF_AUDIO) return false; unsigned char fi = fich.getFI(); if (valid && fi == YSF_FI_HEADER) { CSync::addYSFSync(data + 2U); m_frames++; valid = m_payload.processHeaderData(data + 2U); if (m_duplex) { fich.setMR(YSF_MR_BUSY); fich.encode(data + 2U); data[0U] = TAG_DATA; data[1U] = 0x00U; writeQueue(data); } // if (m_parrot != NULL) { // fich.setMR(YSF_MR_NOT_BUSY); // fich.encode(data + 2U); // // data[0U] = TAG_DATA; // data[1U] = 0x00U; // writeParrot(data); // } if (valid) m_source = m_payload.getSource(); unsigned char cm = fich.getCM(); if (cm == YSF_CM_GROUP) { m_dest = (unsigned char*)"ALL "; } else { if (valid) m_dest = m_payload.getDest(); } #if defined(DUMP_YSF) writeFile(data + 2U); #endif if (m_source != NULL && m_dest != NULL) LogMessage("YSF, received header from %10.10s to %10.10s", m_source, m_dest); else if (m_source == NULL && m_dest != NULL) LogMessage("YSF, received header from ?????????? to %10.10s", m_dest); else if (m_source != NULL && m_dest == NULL) LogMessage("YSF, received header from %10.10s to ??????????", m_source); else LogMessage("YSF, received header from ?????????? to ??????????"); } else if (valid && fi == YSF_FI_TERMINATOR) { CSync::addYSFSync(data + 2U); m_frames++; m_payload.processHeaderData(data + 2U); if (m_duplex) { fich.setMR(YSF_MR_BUSY); fich.encode(data + 2U); data[0U] = TAG_EOT; data[1U] = 0x00U; writeQueue(data); } // if (m_parrot != NULL) { // fich.setMR(YSF_MR_NOT_BUSY); // fich.encode(data + 2U); // // data[0U] = TAG_EOT; // data[1U] = 0x00U; // writeParrot(data); // } #if defined(DUMP_YSF) writeFile(data + 2U); #endif LogMessage("YSF, received RF end of transmission, %.1f seconds, BER: %.1f%%", float(m_frames) / 10.0F, float(m_errs * 100U) / float(m_bits)); writeEndOfTransmission(); return false; } else if (valid) { CSync::addYSFSync(data + 2U); unsigned char fn = fich.getFN(); unsigned char ft = fich.getFT(); unsigned char dt = fich.getDT(); m_frames++; switch (dt) { case YSF_DT_VD_MODE1: valid = m_payload.processVDMode1Data(data + 2U, fn); m_errs += m_payload.processVDMode1Audio(data + 2U); m_bits += 235U; break; case YSF_DT_VD_MODE2: valid = m_payload.processVDMode2Data(data + 2U, fn); m_errs += m_payload.processVDMode2Audio(data + 2U); m_bits += 135U; break; case YSF_DT_DATA_FR_MODE: valid = m_payload.processDataFRModeData(data + 2U, fn); break; case YSF_DT_VOICE_FR_MODE: if (fn != 0U || ft != 1U) { // The first packet after the header is odd, don't try and regenerate it m_errs += m_payload.processVoiceFRModeAudio(data + 2U); m_bits += 720U; } valid = false; break; default: break; } bool change = false; if (m_dest == NULL) { unsigned char cm = fich.getCM(); if (cm == YSF_CM_GROUP) { m_dest = (unsigned char*)"ALL "; change = true; } else if (valid) { m_dest = m_payload.getDest(); if (m_dest != NULL) change = true; } } if (valid && m_source == NULL) { m_source = m_payload.getSource(); if (m_source != NULL) change = true; } if (change) { if (m_source != NULL && m_dest != NULL) { m_display->writeFusion((char*)m_source, (char*)m_dest); LogMessage("YSF, received transmission from %10.10s to %10.10s", m_source, m_dest); } if (m_source != NULL && m_dest == NULL) { m_display->writeFusion((char*)m_source, "??????????"); LogMessage("YSF, received transmission from %10.10s to ??????????", m_source); } if (m_source == NULL && m_dest != NULL) { m_display->writeFusion("??????????", (char*)m_dest); LogMessage("YSF, received transmission from ?????????? to %10.10s", m_dest); } } if (m_duplex) { fich.setMR(YSF_MR_BUSY); fich.encode(data + 2U); data[0U] = TAG_DATA; data[1U] = 0x00U; writeQueue(data); } // if (m_parrot != NULL) { // fich.setMR(YSF_MR_NOT_BUSY); // fich.encode(data + 2U); // // data[0U] = TAG_DATA; // data[1U] = 0x00U; // writeParrot(data); // } #if defined(DUMP_YSF) writeFile(data + 2U); #endif } else { CSync::addYSFSync(data + 2U); m_frames++; if (m_duplex) { data[0U] = TAG_DATA; data[1U] = 0x00U; writeQueue(data); } // if (m_parrot != NULL) { // data[0U] = TAG_DATA; // data[1U] = 0x00U; // writeParrot(data); // } #if defined(DUMP_YSF) writeFile(data + 2U); #endif } return true; } unsigned int CYSFControl::readModem(unsigned char* data) { assert(data != NULL); if (m_queue.isEmpty()) return 0U; unsigned char len = 0U; m_queue.getData(&len, 1U); m_queue.getData(data, len); return len; } void CYSFControl::writeEndOfTransmission() { m_state = RS_RF_LISTENING; m_timeoutTimer.stop(); m_payload.reset(); m_display->clearFusion(); // These variables are free'd by YSFPayload m_source = NULL; m_dest = NULL; #if defined(DUMP_YSF) closeFile(); #endif } void CYSFControl::clock() { unsigned int ms = m_interval.elapsed(); m_interval.start(); m_timeoutTimer.clock(ms); // if (m_parrot != NULL) { // m_parrot->clock(ms); // // unsigned int space = m_queue.freeSpace(); // bool hasData = m_parrot->hasData(); // // if (space > (YSF_FRAME_LENGTH_BYTES + 2U) && hasData) { // unsigned char data[YSF_FRAME_LENGTH_BYTES + 2U]; // m_parrot->read(data); // writeQueue(data); // } // } } void CYSFControl::writeQueue(const unsigned char *data) { assert(data != NULL); if (m_timeoutTimer.isRunning() && m_timeoutTimer.hasExpired()) return; unsigned char len = YSF_FRAME_LENGTH_BYTES + 2U; unsigned int space = m_queue.freeSpace(); if (space < (len + 1U)) { LogError("YSF, overflow in the System Fusion RF queue"); return; } m_queue.addData(&len, 1U); m_queue.addData(data, len); } // void CYSFControl::writeParrot(const unsigned char *data) // { // assert(data != NULL); // // if (m_timeoutTimer.isRunning() && m_timeoutTimer.hasExpired()) // return; // // m_parrot->write(data); // // if (data[0U] == TAG_EOT) // m_parrot->end(); // } bool CYSFControl::openFile() { if (m_fp != NULL) return true; time_t t; ::time(&t); struct tm* tm = ::localtime(&t); char name[100U]; ::sprintf(name, "YSF_%04d%02d%02d_%02d%02d%02d.ambe", tm->tm_year + 1900, tm->tm_mon + 1, tm->tm_mday, tm->tm_hour, tm->tm_min, tm->tm_sec); m_fp = ::fopen(name, "wb"); if (m_fp == NULL) return false; ::fwrite("YSF", 1U, 3U, m_fp); return true; } bool CYSFControl::writeFile(const unsigned char* data) { if (m_fp == NULL) return false; ::fwrite(data, 1U, YSF_FRAME_LENGTH_BYTES, m_fp); return true; } void CYSFControl::closeFile() { if (m_fp != NULL) { ::fclose(m_fp); m_fp = NULL; } }