xlxd/src/cysfpayload.cpp

/*
*    Copyright (C) 2016,2017 Jonathan Naylor, G4KLX
*    Copyright (C) 2016 Mathias Weyland, HB9FRV
*
*    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 "cysfconvolution.h"
#include "cysfpayload.h"
#include "ysfdefines.h"
#include "cutils.h"
#include "ccrc.h"


#include <cstdio>
#include <cassert>
#include <cstring>
#include <cstdint>

const unsigned int INTERLEAVE_TABLE_9_20[] = {
    0U, 40U,  80U, 120U, 160U, 200U, 240U, 280U, 320U,
    2U, 42U,  82U, 122U, 162U, 202U, 242U, 282U, 322U,
    4U, 44U,  84U, 124U, 164U, 204U, 244U, 284U, 324U,
    6U, 46U,  86U, 126U, 166U, 206U, 246U, 286U, 326U,
    8U, 48U,  88U, 128U, 168U, 208U, 248U, 288U, 328U,
    10U, 50U,  90U, 130U, 170U, 210U, 250U, 290U, 330U,
    12U, 52U,  92U, 132U, 172U, 212U, 252U, 292U, 332U,
    14U, 54U,  94U, 134U, 174U, 214U, 254U, 294U, 334U,
    16U, 56U,  96U, 136U, 176U, 216U, 256U, 296U, 336U,
    18U, 58U,  98U, 138U, 178U, 218U, 258U, 298U, 338U,
    20U, 60U, 100U, 140U, 180U, 220U, 260U, 300U, 340U,
    22U, 62U, 102U, 142U, 182U, 222U, 262U, 302U, 342U,
    24U, 64U, 104U, 144U, 184U, 224U, 264U, 304U, 344U,
    26U, 66U, 106U, 146U, 186U, 226U, 266U, 306U, 346U,
    28U, 68U, 108U, 148U, 188U, 228U, 268U, 308U, 348U,
    30U, 70U, 110U, 150U, 190U, 230U, 270U, 310U, 350U,
    32U, 72U, 112U, 152U, 192U, 232U, 272U, 312U, 352U,
    34U, 74U, 114U, 154U, 194U, 234U, 274U, 314U, 354U,
    36U, 76U, 116U, 156U, 196U, 236U, 276U, 316U, 356U,
    38U, 78U, 118U, 158U, 198U, 238U, 278U, 318U, 358U};

const unsigned int INTERLEAVE_TABLE_5_20[] = {
    0U, 40U,  80U, 120U, 160U,
    2U, 42U,  82U, 122U, 162U,
    4U, 44U,  84U, 124U, 164U,
    6U, 46U,  86U, 126U, 166U,
    8U, 48U,  88U, 128U, 168U,
    10U, 50U,  90U, 130U, 170U,
    12U, 52U,  92U, 132U, 172U,
    14U, 54U,  94U, 134U, 174U,
    16U, 56U,  96U, 136U, 176U,
    18U, 58U,  98U, 138U, 178U,
    20U, 60U, 100U, 140U, 180U,
    22U, 62U, 102U, 142U, 182U,
    24U, 64U, 104U, 144U, 184U,
    26U, 66U, 106U, 146U, 186U,
    28U, 68U, 108U, 148U, 188U,
    30U, 70U, 110U, 150U, 190U,
    32U, 72U, 112U, 152U, 192U,
    34U, 74U, 114U, 154U, 194U,
    36U, 76U, 116U, 156U, 196U,
    38U, 78U, 118U, 158U, 198U};

// This one differs from the others in that it interleaves bits and not dibits
const unsigned char WHITENING_DATA[] = {0x93U, 0xD7U, 0x51U, 0x21U, 0x9CU, 0x2FU, 0x6CU, 0xD0U, 0xEFU, 0x0FU,
    0xF8U, 0x3DU, 0xF1U, 0x73U, 0x20U, 0x94U, 0xEDU, 0x1EU, 0x7CU, 0xD8U};

const unsigned char BIT_MASK_TABLE[] = {0x80U, 0x40U, 0x20U, 0x10U, 0x08U, 0x04U, 0x02U, 0x01U};

#define WRITE_BIT1(p,i,b) p[(i)>>3] = (b) ? (p[(i)>>3] | BIT_MASK_TABLE[(i)&7]) : (p[(i)>>3] & ~BIT_MASK_TABLE[(i)&7])
#define READ_BIT1(p,i)    (p[(i)>>3] & BIT_MASK_TABLE[(i)&7])

CYSFPayload::CYSFPayload() :
m_uplink(NULL),
m_downlink(NULL),
m_source(NULL),
m_dest(NULL)
{
}

CYSFPayload::~CYSFPayload()
{
    delete[] m_uplink;
    delete[] m_downlink;
    delete[] m_source;
    delete[] m_dest;
}

bool CYSFPayload::processHeaderData(unsigned char* data)
{
    assert(data != NULL);
    
    data += YSF_SYNC_LENGTH_BYTES + YSF_FICH_LENGTH_BYTES;
    
    unsigned char dch[45U];
    
    unsigned char* p1 = data;
    unsigned char* p2 = dch;
    for (unsigned int i = 0U; i < 5U; i++) {
        ::memcpy(p2, p1, 9U);
        p1 += 18U; p2 += 9U;
    }
    
    CYSFConvolution conv;
    conv.start();
    
    for (unsigned int i = 0U; i < 180U; i++) {
        unsigned int n = INTERLEAVE_TABLE_9_20[i];
        uint8_t s0 = READ_BIT1(dch, n) ? 1U : 0U;
        
        n++;
        uint8_t s1 = READ_BIT1(dch, n) ? 1U : 0U;
        
        conv.decode(s0, s1);
    }
    
    unsigned char output[23U];
    conv.chainback(output, 176U);
    
    bool valid1 = CCRC::checkCCITT162(output, 22U);
    if (valid1) {
        for (unsigned int i = 0U; i < 20U; i++)
            output[i] ^= WHITENING_DATA[i];
        
        if (m_dest == NULL) {
            m_dest = new unsigned char[YSF_CALLSIGN_LENGTH];
            ::memcpy(m_dest, output + 0U, YSF_CALLSIGN_LENGTH);
        }
        
        if (m_source == NULL) {
            m_source = new unsigned char[YSF_CALLSIGN_LENGTH];
            ::memcpy(m_source, output + YSF_CALLSIGN_LENGTH, YSF_CALLSIGN_LENGTH);
        }
        
        for (unsigned int i = 0U; i < 20U; i++)
            output[i] ^= WHITENING_DATA[i];
        
        CCRC::addCCITT162(output, 22U);
        output[22U] = 0x00U;
        
        unsigned char convolved[45U];
        conv.encode(output, convolved, 180U);
        
        unsigned char bytes[45U];
        unsigned int j = 0U;
        for (unsigned int i = 0U; i < 180U; i++) {
            unsigned int n = INTERLEAVE_TABLE_9_20[i];
            
            bool s0 = READ_BIT1(convolved, j) != 0U;
            j++;
            
            bool s1 = READ_BIT1(convolved, j) != 0U;
            j++;
            
            WRITE_BIT1(bytes, n, s0);
            
            n++;
            WRITE_BIT1(bytes, n, s1);
        }
        
        p1 = data;
        p2 = bytes;
        for (unsigned int i = 0U; i < 5U; i++) {
            ::memcpy(p1, p2, 9U);
            p1 += 18U; p2 += 9U;
        }
    }
    
    p1 = data + 9U;
    p2 = dch;
    for (unsigned int i = 0U; i < 5U; i++) {
        ::memcpy(p2, p1, 9U);
        p1 += 18U; p2 += 9U;
    }
    
    conv.start();
    
    for (unsigned int i = 0U; i < 180U; i++) {
        unsigned int n = INTERLEAVE_TABLE_9_20[i];
        uint8_t s0 = READ_BIT1(dch, n) ? 1U : 0U;
        
        n++;
        uint8_t s1 = READ_BIT1(dch, n) ? 1U : 0U;
        
        conv.decode(s0, s1);
    }
    
    conv.chainback(output, 176U);
    
    bool valid2 = CCRC::checkCCITT162(output, 22U);
    if (valid2) {
        for (unsigned int i = 0U; i < 20U; i++)
            output[i] ^= WHITENING_DATA[i];
        
        if (m_downlink != NULL)
            ::memcpy(output + 0U, m_downlink, YSF_CALLSIGN_LENGTH);
        
        if (m_uplink != NULL)
            ::memcpy(output + YSF_CALLSIGN_LENGTH, m_uplink, YSF_CALLSIGN_LENGTH);
        
        for (unsigned int i = 0U; i < 20U; i++)
            output[i] ^= WHITENING_DATA[i];
        
        CCRC::addCCITT162(output, 22U);
        output[22U] = 0x00U;
        
        unsigned char convolved[45U];
        conv.encode(output, convolved, 180U);
        
        unsigned char bytes[45U];
        unsigned int j = 0U;
        for (unsigned int i = 0U; i < 180U; i++) {
            unsigned int n = INTERLEAVE_TABLE_9_20[i];
            
            bool s0 = READ_BIT1(convolved, j) != 0U;
            j++;
            
            bool s1 = READ_BIT1(convolved, j) != 0U;
            j++;
            
            WRITE_BIT1(bytes, n, s0);
            
            n++;
            WRITE_BIT1(bytes, n, s1);
        }
        
        p1 = data + 9U;
        p2 = bytes;
        for (unsigned int i = 0U; i < 5U; i++) {
            ::memcpy(p1, p2, 9U);
            p1 += 18U; p2 += 9U;
        }
    }
    
    return valid1;
}

bool CYSFPayload::readDataFRModeData1(const unsigned char* data, unsigned char* dt)
{
    assert(data != NULL);
    assert(dt != NULL);
    
    ::memset(dt, ' ', 20U);
    
    data += YSF_SYNC_LENGTH_BYTES + YSF_FICH_LENGTH_BYTES;
    
    unsigned char dch[45U];
    
    const unsigned char* p1 = data;
    unsigned char* p2 = dch;
    for (unsigned int i = 0U; i < 5U; i++) {
        ::memcpy(p2, p1, 9U);
        p1 += 18U; p2 += 9U;
    }
    
    CYSFConvolution conv;
    conv.start();
    
    for (unsigned int i = 0U; i < 180U; i++) {
        unsigned int n = INTERLEAVE_TABLE_9_20[i];
        uint8_t s0 = READ_BIT1(dch, n) ? 1U : 0U;
        
        n++;
        uint8_t s1 = READ_BIT1(dch, n) ? 1U : 0U;
        
        conv.decode(s0, s1);
    }
    
    unsigned char output[23U];
    conv.chainback(output, 176U);
    
    bool ret = CCRC::checkCCITT162(output, 22U);
    if (ret) {
        for (unsigned int i = 0U; i < 20U; i++)
            output[i] ^= WHITENING_DATA[i];
        
        // CUtils::dump(1U, "FR Mode Data 1", output, 20U);
        
        ::memcpy(dt, output, 20U);
    }
    
    return ret;
}

bool CYSFPayload::readDataFRModeData2(const unsigned char* data, unsigned char* dt)
{
    assert(data != NULL);
    assert(dt != NULL);
    
    ::memset(dt, ' ', 20U);
    
    data += YSF_SYNC_LENGTH_BYTES + YSF_FICH_LENGTH_BYTES;
    
    unsigned char dch[45U];
    
    const unsigned char* p1 = data + 9U;
    unsigned char* p2 = dch;
    for (unsigned int i = 0U; i < 5U; i++) {
        ::memcpy(p2, p1, 9U);
        p1 += 18U; p2 += 9U;
    }
    
    CYSFConvolution conv;
    conv.start();
    
    for (unsigned int i = 0U; i < 180U; i++) {
        unsigned int n = INTERLEAVE_TABLE_9_20[i];
        uint8_t s0 = READ_BIT1(dch, n) ? 1U : 0U;
        
        n++;
        uint8_t s1 = READ_BIT1(dch, n) ? 1U : 0U;
        
        conv.decode(s0, s1);
    }
    
    unsigned char output[23U];
    conv.chainback(output, 176U);
    
    bool ret = CCRC::checkCCITT162(output, 22U);
    if (ret) {
        for (unsigned int i = 0U; i < 20U; i++)
            output[i] ^= WHITENING_DATA[i];
        
        // CUtils::dump(1U, "FR Mode Data 2", output, 20U);
        
        ::memcpy(dt, output, 20U);
    }
    
    return ret;
}

void CYSFPayload::writeVDMode2Data(unsigned char* data, const unsigned char* dt)
{
    data += YSF_SYNC_LENGTH_BYTES + YSF_FICH_LENGTH_BYTES;
    
    unsigned char dt_tmp[13];
    ::memcpy(dt_tmp, dt, YSF_CALLSIGN_LENGTH);
    
    for (unsigned int i = 0U; i < 10U; i++)
        dt_tmp[i] ^= WHITENING_DATA[i];
    
    CCRC::addCCITT162(dt_tmp, 12U);
    dt_tmp[12U] = 0x00U;
    
    unsigned char convolved[25U];
    CYSFConvolution conv;
    conv.start();
    conv.encode(dt_tmp, convolved, 100U);
    
    unsigned char bytes[25U];
    unsigned int j = 0U;
    for (unsigned int i = 0U; i < 100U; i++) {
        unsigned int n = INTERLEAVE_TABLE_5_20[i];
        
        bool s0 = READ_BIT1(convolved, j) != 0U;
        j++;
        
        bool s1 = READ_BIT1(convolved, j) != 0U;
        j++;
        
        WRITE_BIT1(bytes, n, s0);
        
        n++;
        WRITE_BIT1(bytes, n, s1);
    }
    
    unsigned char* p1 = data;
    unsigned char* p2 = bytes;
    for (unsigned int i = 0U; i < 5U; i++) {
        ::memcpy(p1, p2, 5U);
        p1 += 18U; p2 += 5U;
    }
}


bool CYSFPayload::readVDMode1Data(const unsigned char* data, unsigned char* dt)
{
    assert(data != NULL);
    assert(dt != NULL);
    
    data += YSF_SYNC_LENGTH_BYTES + YSF_FICH_LENGTH_BYTES;
    
    unsigned char dch[45U];
    
    const unsigned char* p1 = data;
    unsigned char* p2 = dch;
    for (unsigned int i = 0U; i < 5U; i++) {
        ::memcpy(p2, p1, 9U);
        p1 += 18U; p2 += 9U;
    }
    
    CYSFConvolution conv;
    conv.start();
    
    for (unsigned int i = 0U; i < 180U; i++) {
        unsigned int n = INTERLEAVE_TABLE_9_20[i];
        uint8_t s0 = READ_BIT1(dch, n) ? 1U : 0U;
        
        n++;
        uint8_t s1 = READ_BIT1(dch, n) ? 1U : 0U;
        
        conv.decode(s0, s1);
    }
    
    unsigned char output[23U];
    conv.chainback(output, 176U);
    
    bool ret = CCRC::checkCCITT162(output, 22U);
    if (ret) {
        for (unsigned int i = 0U; i < 20U; i++)
            output[i] ^= WHITENING_DATA[i];
        
        // CUtils::dump(1U, "V/D Mode 1 Data", output, 20U);
        
        ::memcpy(dt, output, 20U);
    }
    
    return ret;
}


bool CYSFPayload::readVDMode2Data(const unsigned char* data, unsigned char* dt)
{
    assert(data != NULL);
    assert(dt != NULL);
    
    data += YSF_SYNC_LENGTH_BYTES + YSF_FICH_LENGTH_BYTES;
    
    unsigned char dch[25U];
    
    const unsigned char* p1 = data;
    unsigned char* p2 = dch;
    for (unsigned int i = 0U; i < 5U; i++) {
        ::memcpy(p2, p1, 5U);
        p1 += 18U; p2 += 5U;
    }
    
    CYSFConvolution conv;
    conv.start();
    
    for (unsigned int i = 0U; i < 100U; i++) {
        unsigned int n = INTERLEAVE_TABLE_5_20[i];
        uint8_t s0 = READ_BIT1(dch, n) ? 1U : 0U;
        
        n++;
        uint8_t s1 = READ_BIT1(dch, n) ? 1U : 0U;
        
        conv.decode(s0, s1);
    }
    
    unsigned char output[13U];
    conv.chainback(output, 96U);
    
    bool ret = CCRC::checkCCITT162(output, 12U);
    if (ret) {
        for (unsigned int i = 0U; i < 10U; i++)
            output[i] ^= WHITENING_DATA[i];
        
        // CUtils::dump(1U, "V/D Mode 2 Data", output, YSF_CALLSIGN_LENGTH);
        
        ::memcpy(dt, output, YSF_CALLSIGN_LENGTH);
    }
    
    return ret;
}

void CYSFPayload::writeHeader(unsigned char* data, const unsigned char* csd1, const unsigned char* csd2)
{
    assert(data != NULL);
    assert(csd1 != NULL);
    assert(csd2 != NULL);
    
    writeDataFRModeData1(csd1, data);
    
    writeDataFRModeData2(csd2, data);
}

void CYSFPayload::writeDataFRModeData1(const unsigned char* dt, unsigned char* data)
{
    assert(dt != NULL);
    assert(data != NULL);
    
    data += YSF_SYNC_LENGTH_BYTES + YSF_FICH_LENGTH_BYTES;
    
    unsigned char output[25U];
    for (unsigned int i = 0U; i < 20U; i++)
        output[i] = dt[i] ^ WHITENING_DATA[i];
    
    CCRC::addCCITT162(output, 22U);
    output[22U] = 0x00U;
    
    unsigned char convolved[45U];
    
    CYSFConvolution conv;
    conv.encode(output, convolved, 180U);
    
    unsigned char bytes[45U];
    unsigned int j = 0U;
    for (unsigned int i = 0U; i < 180U; i++) {
        unsigned int n = INTERLEAVE_TABLE_9_20[i];
        
        bool s0 = READ_BIT1(convolved, j) != 0U;
        j++;
        
        bool s1 = READ_BIT1(convolved, j) != 0U;
        j++;
        
        WRITE_BIT1(bytes, n, s0);
        
        n++;
        WRITE_BIT1(bytes, n, s1);
    }
    
    unsigned char* p1 = data;
    unsigned char* p2 = bytes;
    for (unsigned int i = 0U; i < 5U; i++) {
        ::memcpy(p1, p2, 9U);
        p1 += 18U; p2 += 9U;
    }
}

void CYSFPayload::writeDataFRModeData2(const unsigned char* dt, unsigned char* data)
{
    assert(dt != NULL);
    assert(data != NULL);
    
    data += YSF_SYNC_LENGTH_BYTES + YSF_FICH_LENGTH_BYTES;
    
    unsigned char output[25U];
    for (unsigned int i = 0U; i < 20U; i++)
        output[i] = dt[i] ^ WHITENING_DATA[i];
    
    CCRC::addCCITT162(output, 22U);
    output[22U] = 0x00U;
    
    unsigned char convolved[45U];
    
    CYSFConvolution conv;
    conv.encode(output, convolved, 180U);
    
    unsigned char bytes[45U];
    unsigned int j = 0U;
    for (unsigned int i = 0U; i < 180U; i++) {
        unsigned int n = INTERLEAVE_TABLE_9_20[i];
        
        bool s0 = READ_BIT1(convolved, j) != 0U;
        j++;
        
        bool s1 = READ_BIT1(convolved, j) != 0U;
        j++;
        
        WRITE_BIT1(bytes, n, s0);
        
        n++;
        WRITE_BIT1(bytes, n, s1);
    }
    
    unsigned char* p1 = data + 9U;
    unsigned char* p2 = bytes;
    for (unsigned int i = 0U; i < 5U; i++) {
        ::memcpy(p1, p2, 9U);
        p1 += 18U; p2 += 9U;
    }
}

void CYSFPayload::setUplink(const std::string& callsign)
{
    m_uplink = new unsigned char[YSF_CALLSIGN_LENGTH];
    
    std::string uplink = callsign;
    uplink.resize(YSF_CALLSIGN_LENGTH, ' ');
    
    for (unsigned int i = 0U; i < YSF_CALLSIGN_LENGTH; i++)
        m_uplink[i] = uplink.at(i);
}

void CYSFPayload::setDownlink(const std::string& callsign)
{
    m_downlink = new unsigned char[YSF_CALLSIGN_LENGTH];
    
    std::string downlink = callsign;
    downlink.resize(YSF_CALLSIGN_LENGTH, ' ');
    
    for (unsigned int i = 0U; i < YSF_CALLSIGN_LENGTH; i++)
        m_downlink[i] = downlink.at(i);
}

std::string CYSFPayload::getSource()
{
    std::string tmp;
    
    if (m_dest)
        tmp.assign((const char *)m_source, YSF_CALLSIGN_LENGTH);
    else
        tmp = "";
    
    return tmp;
}

std::string CYSFPayload::getDest()
{
    std::string tmp;
    
    if (m_dest)
        tmp.assign((const char *)m_dest, YSF_CALLSIGN_LENGTH);
    else
        tmp = "";
    
    return tmp;
}

void CYSFPayload::reset()
{
    delete[] m_source;
    delete[] m_dest;
    
    m_source = NULL;
    m_dest = NULL;
}