/** * Digital Voice Modem - Host Software * GPLv2 Open Source. Use is subject to license terms. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * @package DVM / Host Software * */ // // Based on code from the MMDVMHost project. (https://github.com/g4klx/MMDVMHost) // Licensed under the GPLv2 License (https://opensource.org/licenses/GPL-2.0) // /* * Copyright (C) 2015,2016 by Jonathan Naylor G4KLX * Copyright (C) 2019-2021 by Bryan Biedenkapp N2PLL * * 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; either version 2 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 General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include "Defines.h" #include "dmr/lc/CSBK.h" #include "edac/BPTC19696.h" #include "edac/CRC.h" #include "Log.h" #include "Utils.h" using namespace dmr::lc; using namespace dmr; #include #include // --------------------------------------------------------------------------- // Static Class Members // --------------------------------------------------------------------------- bool CSBK::m_verbose = false; SiteData CSBK::m_siteData = SiteData(); // --------------------------------------------------------------------------- // Public Class Members // --------------------------------------------------------------------------- ///

/// Initializes a copy instance of the CSBK class. ///

/// CSBK::CSBK(const CSBK& data) : CSBK() { copy(data); } ///

/// Initializes a new instance of the CSBK class. ///

CSBK::CSBK() : m_colorCode(0U), m_lastBlock(true), m_Cdef(false), m_CSBKO(CSBKO_NONE), m_FID(0x00U), m_GI(false), m_srcId(0U), m_dstId(0U), m_dataContent(false), m_CBF(0U), m_emergency(false), m_privacy(false), m_supplementData(false), m_priority(0U), m_broadcast(false), m_proxy(false), m_response(0U), m_reason(0U), m_siteOffsetTiming(false), m_logicalCh1(DMR_CHNULL), m_logicalCh2(DMR_CHNULL), m_slotNo(0U), m_siteIdenEntry(lookups::IdenTable()) { /* stub */ } ///

/// Finalizes a instance of the CSBK class. ///

CSBK::~CSBK() { /* stub */ } ///

/// Regenerate a DMR CSBK without decoding. ///

/// /// True, if TSBK was decoded, otherwise false. bool CSBK::regenerate(uint8_t* data) { uint8_t csbk[DMR_CSBK_LENGTH_BYTES]; ::memset(csbk, 0x00U, DMR_CSBK_LENGTH_BYTES); // decode BPTC (196,96) FEC edac::BPTC19696 bptc; bptc.decode(data, csbk); // validate the CRC-CCITT 16 csbk[10U] ^= CSBK_CRC_MASK[0U]; csbk[11U] ^= CSBK_CRC_MASK[1U]; bool valid = edac::CRC::checkCCITT162(csbk, DMR_CSBK_LENGTH_BYTES); if (!valid) { LogError(LOG_DMR, "CSBK::decode(), failed CRC CCITT-162 check"); return false; } // restore the checksum csbk[10U] ^= CSBK_CRC_MASK[0U]; csbk[11U] ^= CSBK_CRC_MASK[1U]; // calculate checksum csbk[10U] ^= CSBK_CRC_MASK[0U]; csbk[11U] ^= CSBK_CRC_MASK[1U]; edac::CRC::addCCITT162(csbk, 12U); csbk[10U] ^= CSBK_CRC_MASK[0U]; csbk[11U] ^= CSBK_CRC_MASK[1U]; // encode BPTC (196,96) FEC bptc.encode(csbk, data); return true; } // --------------------------------------------------------------------------- // Protected Class Members // --------------------------------------------------------------------------- ///

/// Internal helper to convert CSBK bytes to a 64-bit long value. ///

/// /// ulong64_t CSBK::toValue(const uint8_t* csbk) { ulong64_t csbkValue = 0U; // combine bytes into ulong64_t (8 byte) value csbkValue = csbk[2U]; csbkValue = (csbkValue << 8) + csbk[3U]; csbkValue = (csbkValue << 8) + csbk[4U]; csbkValue = (csbkValue << 8) + csbk[5U]; csbkValue = (csbkValue << 8) + csbk[6U]; csbkValue = (csbkValue << 8) + csbk[7U]; csbkValue = (csbkValue << 8) + csbk[8U]; csbkValue = (csbkValue << 8) + csbk[9U]; return csbkValue; } ///

/// Internal helper to convert a 64-bit long value to CSBK bytes. ///

/// /// std::unique_ptr CSBK::fromValue(const ulong64_t csbkValue) { __UNIQUE_BUFFER(csbk, uint8_t, DMR_CSBK_LENGTH_BYTES); // split ulong64_t (8 byte) value into bytes csbk[2U] = (uint8_t)((csbkValue >> 56) & 0xFFU); csbk[3U] = (uint8_t)((csbkValue >> 48) & 0xFFU); csbk[4U] = (uint8_t)((csbkValue >> 40) & 0xFFU); csbk[5U] = (uint8_t)((csbkValue >> 32) & 0xFFU); csbk[6U] = (uint8_t)((csbkValue >> 24) & 0xFFU); csbk[7U] = (uint8_t)((csbkValue >> 16) & 0xFFU); csbk[8U] = (uint8_t)((csbkValue >> 8) & 0xFFU); csbk[9U] = (uint8_t)((csbkValue >> 0) & 0xFFU); return csbk; } ///

/// Internal helper to decode a control signalling block. ///

/// /// /// True, if TSBK was decoded, otherwise false. bool CSBK::decode(const uint8_t* data, uint8_t* csbk) { assert(data != nullptr); assert(csbk != nullptr); // decode BPTC (196,96) FEC edac::BPTC19696 bptc; bptc.decode(data, csbk); // validate the CRC-CCITT 16 csbk[10U] ^= CSBK_CRC_MASK[0U]; csbk[11U] ^= CSBK_CRC_MASK[1U]; bool valid = edac::CRC::checkCCITT162(csbk, DMR_CSBK_LENGTH_BYTES); if (!valid) { LogError(LOG_DMR, "CSBK::decode(), failed CRC CCITT-162 check"); return false; } // restore the checksum csbk[10U] ^= CSBK_CRC_MASK[0U]; csbk[11U] ^= CSBK_CRC_MASK[1U]; if (m_verbose) { Utils::dump(2U, "Decoded CSBK", csbk, DMR_CSBK_LENGTH_BYTES); } m_CSBKO = csbk[0U] & 0x3FU; // CSBKO m_lastBlock = (csbk[0U] & 0x80U) == 0x80U; // Last Block Marker m_FID = csbk[1U]; // Feature ID m_dataContent = false; m_CBF = 0U; return true; } ///

/// Internal helper to encode a control signalling block. ///

/// /// /// /// void CSBK::encode(uint8_t* data, const uint8_t* csbk) { assert(data != nullptr); assert(csbk != nullptr); uint8_t outCsbk[DMR_CSBK_LENGTH_BYTES]; ::memset(outCsbk, 0x00U, DMR_CSBK_LENGTH_BYTES); ::memcpy(outCsbk, csbk, DMR_CSBK_LENGTH_BYTES); outCsbk[0U] = m_CSBKO; // CSBKO outCsbk[0U] |= (m_lastBlock) ? 0x80U : 0x00U; // Last Block Marker if (!m_Cdef) { outCsbk[1U] = m_FID; // Feature ID } else { outCsbk[1U] = m_colorCode & 0x0FU; // Cdef uses Color Code } outCsbk[10U] ^= CSBK_CRC_MASK[0U]; outCsbk[11U] ^= CSBK_CRC_MASK[1U]; edac::CRC::addCCITT162(outCsbk, 12U); outCsbk[10U] ^= CSBK_CRC_MASK[0U]; outCsbk[11U] ^= CSBK_CRC_MASK[1U]; if (m_verbose) { Utils::dump(2U, "Encoded CSBK", outCsbk, DMR_CSBK_LENGTH_BYTES); } // encode BPTC (196,96) FEC edac::BPTC19696 bptc; bptc.encode(outCsbk, data); } ///

/// Internal helper to copy the the class. ///

/// void CSBK::copy(const CSBK& data) { m_colorCode = data.m_colorCode; m_lastBlock = data.m_lastBlock; m_Cdef = data.m_Cdef; m_CSBKO = data.m_CSBKO; m_FID = data.m_FID; m_GI = data.m_GI; m_srcId = data.m_srcId; m_dstId = data.m_dstId; m_dataContent = data.m_dataContent; m_CBF = data.m_CBF; m_emergency = data.m_emergency; m_privacy = data.m_privacy; m_supplementData = data.m_supplementData; m_priority = data.m_priority; m_broadcast = data.m_broadcast; m_proxy = data.m_proxy; m_response = data.m_response; m_response = data.m_reason; m_siteOffsetTiming = data.m_siteOffsetTiming; m_logicalCh1 = data.m_logicalCh1; m_logicalCh2 = data.m_logicalCh2; m_slotNo = data.m_slotNo; m_siteIdenEntry = data.m_siteIdenEntry; }