b15f/control/src/drv/b15f.cpp.orig

#include "b15f.h"

B15F *B15F::instance = nullptr;
errorhandler_t B15F::errorhandler = nullptr;

B15F::B15F() {
    init();
}

void B15F::init() {

    std::string device = exec("bash -c 'ls /dev/ttyUSB*'");
    while (device.find(' ') != std::string::npos || device.find('\n') != std::string::npos ||
           device.find('\t') != std::string::npos)
        device.pop_back();

    if (device.length() == 0)
        abort("Adapter nicht gefunden");

    std::cout << PRE << "Verwende Adapter: " << device << std::endl;


    std::cout << PRE << "Stelle Verbindung mit Adapter her... " << std::flush;
    usart.setBaudrate(BAUDRATE);
    usart.openDevice(device);
    std::cout << "OK" << std::endl;


    std::cout << PRE << "Teste Verbindung... " << std::flush;
    uint8_t tries = 3;
    while (tries--) {
        // verwerfe Daten, die µC noch hat
        //discard();

        if (!testConnection())
            continue;

        if (!testIntConv())
            continue;

        break;
    }
    if (tries == 0)
        abort("Verbindungstest fehlgeschlagen. Neueste Version im Einsatz?");
    std::cout << "OK" << std::endl;


    // Gib board info aus
    std::vector<std::string> info = getBoardInfo();
    std::cout << PRE << "AVR Firmware Version: " << info[0] << " um " << info[1] << " Uhr (" << info[2] << ")"
              << std::endl;
}

void B15F::reconnect() {
    uint8_t tries = RECONNECT_TRIES;
    while (tries--) {
        delay_ms(RECONNECT_TIMEOUT);
        discard();

        if (testConnection())
            return;
    }

    abort("Verbindung kann nicht repariert werden");
}

void B15F::discard(void) {
    try {
        uint8_t rq[] =
                {
                        RQ_DISC
                };

        usart.clearOutputBuffer();
        for (uint8_t i = 0; i < 16; i++) {
            usart.transmit(&rq[0], 0, sizeof(rq)); // sende discard Befehl (verwerfe input)
            delay_ms(4);
        }
        usart.clearInputBuffer();
    }
    catch (std::exception &ex) {
        abort(ex);
    }
}

bool B15F::testConnection() {
    // erzeuge zufälliges Byte
    srand(time(NULL));
    uint8_t dummy = rand() % 256;

    uint8_t rq[] =
            {
                    RQ_TEST,
                    dummy
            };
    usart.transmit(&rq[0], 0, sizeof(rq));

    uint8_t aw[2];
    usart.receive(&aw[0], 0, sizeof(aw));

    return aw[0] == MSG_OK && aw[1] == dummy;
}

bool B15F::testIntConv() {
    srand(time(NULL));
    uint16_t dummy = rand() % (0xFFFF / 3);

    uint8_t rq[] =
            {
                    RQ_INT,
                    static_cast<uint8_t >(dummy & 0xFF),
                    static_cast<uint8_t >(dummy >> 8)
            };
    usart.transmit(&rq[0], 0, sizeof(rq));

    uint16_t aw;
    usart.receive(reinterpret_cast<uint8_t *>(&aw), 0, sizeof(aw));

    return aw == dummy * 3;
}


std::vector<std::string> B15F::getBoardInfo(void) {
    std::vector<std::string> info;

    uint8_t rq[] =
            {
                    RQ_INFO
            };
    usart.transmit(&rq[0], 0, sizeof(rq));

    uint8_t n;
    usart.receive(&n, 0, sizeof(n));
    while (n--) {
        uint8_t len;
        usart.receive(&len, 0, sizeof(len));

        char str[len + 1];
        str[len] = '\0';
        usart.receive(reinterpret_cast<uint8_t *>(&str[0]), 0, len);

        info.push_back(std::string(str));
    }

    uint8_t aw;
    usart.receive(&aw, 0, sizeof(aw));
    if (aw != MSG_OK)
        abort("Board Info fehlerhalft: code " + std::to_string((int) aw));

    return info;
}

bool B15F::activateSelfTestMode() {
    uint8_t rq[] =
            {
                    RQ_ST
            };
    usart.transmit(&rq[0], 0, sizeof(rq));

    uint8_t aw;
    usart.receive(&aw, 0, sizeof(aw));
    return aw == MSG_OK;
}

bool B15F::digitalWrite0(uint8_t port) {
    uint8_t rq[] =
            {
                    RQ_BA0,
                    port
            };
    usart.transmit(&rq[0], 0, sizeof(rq));

    uint8_t aw;
    usart.receive(&aw, 0, sizeof(aw));
    return aw == MSG_OK;
}

bool B15F::digitalWrite1(uint8_t port) {
    uint8_t rq[] =
            {
                    RQ_BA1,
                    port
            };
    usart.transmit(&rq[0], 0, sizeof(rq));

    uint8_t aw;
    usart.receive(&aw, 0, sizeof(aw));
    return aw == MSG_OK;
}

uint8_t B15F::digitalRead0() {
    usart.clearInputBuffer();
    uint8_t rq[] =
            {
                    RQ_BE0
            };
    usart.transmit(&rq[0], 0, sizeof(rq));

    uint8_t aw;
    usart.receive(&aw, 0, sizeof(aw));
    return aw;
}

uint8_t B15F::digitalRead1() {
    usart.clearInputBuffer();
    uint8_t rq[] =
            {
                    RQ_BE1
            };
    usart.transmit(&rq[0], 0, sizeof(rq));

    uint8_t aw;
    usart.receive(&aw, 0, sizeof(aw));
    return aw;
}

uint8_t B15F::readDipSwitch() {
    usart.clearInputBuffer();
    uint8_t rq[] =
            {
                    RQ_DSW
            };
    usart.transmit(&rq[0], 0, sizeof(rq));

    uint8_t aw;
    usart.receive(&aw, 0, sizeof(aw));
    return aw;
}

bool B15F::analogWrite0(uint16_t value) {
    uint8_t rq[] =
            {
                    RQ_AA0,
                    static_cast<uint8_t >(value & 0xFF),
                    static_cast<uint8_t >(value >> 8)
            };
    usart.transmit(&rq[0], 0, sizeof(rq));

    uint8_t aw;
    usart.receive(&aw, 0, sizeof(aw));
    return aw == MSG_OK;
}

bool B15F::analogWrite1(uint16_t value) {
    uint8_t rq[] =
            {
                    RQ_AA1,
                    static_cast<uint8_t >(value & 0xFF),
                    static_cast<uint8_t >(value >> 8)
            };
    usart.transmit(&rq[0], 0, sizeof(rq));

    uint8_t aw;
    usart.receive(&aw, 0, sizeof(aw));
    return aw == MSG_OK;
}

uint16_t B15F::analogRead(uint8_t channel) {
    usart.clearInputBuffer();
    if (channel > 7)
        abort("Bad ADC channel: " + std::to_string(channel));

    uint8_t rq[] =
            {
                    RQ_ADC,
                    channel
            };

    usart.transmit(&rq[0], 0, sizeof(rq));

    uint16_t aw;
    usart.receive(reinterpret_cast<uint8_t *>(&aw), 0, sizeof(aw));

    if (aw > 1023)
        abort("Bad ADC data detected (1)");
    return aw;
}

void
B15F::analogSequence(uint8_t channel_a, uint16_t *buffer_a, uint32_t offset_a, uint8_t channel_b, uint16_t *buffer_b,
                     uint32_t offset_b, uint16_t start, int16_t delta, uint16_t count) {
    // prepare pointers
    buffer_a += offset_a;
    buffer_b += offset_b;


    usart.clearInputBuffer();
    uint8_t rq[] =
            {
                    RQ_ADC_DAC_STROKE,
                    channel_a,
                    channel_b,
                    static_cast<uint8_t >(start & 0xFF),
                    static_cast<uint8_t >(start >> 8),
                    static_cast<uint8_t >(delta & 0xFF),
                    static_cast<uint8_t >(delta >> 8),
                    static_cast<uint8_t >(count & 0xFF),
                    static_cast<uint8_t >(count >> 8)
            };

    usart.transmit(&rq[0], 0, sizeof(rq));

    for (uint16_t i = 0; i < count; i++) {
        if (buffer_a) {
            usart.receive(reinterpret_cast<uint8_t *>(&buffer_a[i]), 0, 2);

            if (buffer_a[i] > 1023) // check for broken usart connection
                abort("Bad ADC data detected (2)");
        } else {
            usart.drop(2);
        }

        if (buffer_b) {
            usart.receive(reinterpret_cast<uint8_t *>(&buffer_b[i]), 0, 2);

            if (buffer_b[i] > 1023) // check for broken usart connection
                abort("Bad ADC data detected (3)");
        } else {
            usart.drop(2);
        }
    }

    uint8_t aw;
    usart.receive(&aw, 0, sizeof(aw));
    if(aw != MSG_OK)
        abort("Sequenz unterbrochen");
}

uint8_t B15F::pwmSetFrequency(uint32_t freq) {
    usart.clearInputBuffer();

    uint8_t rq[] =
            {
                    RQ_PWM_SET_FREQ,
                    static_cast<uint8_t>((freq >> 0) & 0xFF),
                    static_cast<uint8_t>((freq >> 8) & 0xFF),
                    static_cast<uint8_t>((freq >> 16) & 0xFF),
                    static_cast<uint8_t>((freq >> 24) & 0xFF)
            };

    usart.transmit(&rq[0], 0, sizeof(rq));

    uint8_t aw;
    usart.receive(&aw, 0, sizeof(aw));
    return aw;
}

bool B15F::pwmSetValue(uint8_t value) {
    usart.clearInputBuffer();

    uint8_t rq[] =
            {
                    RQ_PWM_SET_VALUE,
                    value
            };

    usart.transmit(&rq[0], 0, sizeof(rq));

    uint8_t aw;
    usart.receive(&aw, 0, sizeof(aw));
    return aw == MSG_OK;
}

bool B15F::setRegister(uint8_t adr, uint8_t val) {
    usart.clearInputBuffer();

    uint8_t rq[] =
            {
                    RQ_SET_REG,
                    adr,
                    val
            };

    usart.transmit(&rq[0], 0, sizeof(rq));

    uint8_t aw;
    usart.receive(&aw, 0, sizeof(aw));
    return aw == val;
}

uint8_t B15F::getRegister(uint8_t adr) {
    usart.clearInputBuffer();

    uint8_t rq[] =
            {
                    RQ_GET_REG,
                    adr
            };

    usart.transmit(&rq[0], 0, sizeof(rq));

    uint8_t aw;
    usart.receive(&aw, 0, sizeof(aw));
    return aw;
}


void B15F::delay_ms(uint16_t ms) {
    std::this_thread::sleep_for(std::chrono::milliseconds(ms));
}

void B15F::delay_us(uint16_t us) {
    std::this_thread::sleep_for(std::chrono::microseconds(us));
}

B15F &B15F::getInstance(void) {
    if (!instance)
        instance = new B15F();

    return *instance;
}

// https://stackoverflow.com/a/478960
std::string B15F::exec(std::string cmd) {
    std::array<char, 128> buffer;
    std::string result;
    std::unique_ptr<FILE, decltype(&pclose)> pipe(popen(cmd.c_str(), "r"), pclose);
    if (!pipe) {
        throw std::runtime_error("popen() failed!");
    }
    while (fgets(buffer.data(), buffer.size(), pipe.get()) != nullptr) {
        result += buffer.data();
    }
    return result;
}

void B15F::abort(std::string msg) {
    DriverException ex(msg);
    abort(ex);
}

void B15F::abort(std::exception &ex) {
    if (errorhandler)
        errorhandler(ex);
    else {
        std::cerr << "NOTICE: B15F::errorhandler not set" << std::endl;
        std::cout << ex.what() << std::endl;
        throw DriverException(ex.what());
    }
}

void B15F::setAbortHandler(errorhandler_t func) {
    errorhandler = func;
}