mountcontrol/asibfm700/asibfm700_configfile.h

#pragma once

/**/

#include <expected>
#include <filesystem>
#include <fstream>

#include <mcc_angle.h>
#include <mcc_moving_model_common.h>
#include <mcc_pcm.h>
#include <mcc_utils.h>

#include "asibfm700_common.h"
#include "asibfm700_servocontroller.h"

namespace asibfm700
{


/*    A SIMPLE "KEYWORD - VALUE" HOLDER CLASS SUITABLE TO STORE SOME APPLICATION CONFIGURATION    */


// to follow std::variant requirements (not references, not array, not void)
template <typename T>
concept config_record_valid_type_c = requires { !std::is_array_v<T> && !std::is_void_v<T> && !std::is_reference_v<T>; };

// simple minimal-requirement configuration record class
template <config_record_valid_type_c T>
struct simple_config_record_t {
    std::string_view key;
    T value;
};


/*    ASTOROSIB FM700 MOUNT CONFIGURATION CLASS    */

// configuration description and its defaults
static auto Asibfm700MountConfigDefaults = std::make_tuple(
    // main cycle period in millisecs
    simple_config_record_t{"hardwarePollingPeriod", std::chrono::milliseconds{100}},

    /*    geographic coordinates of the observation site    */

    // site latitude in degrees
    simple_config_record_t{"siteLatitude", mcc::MccAngle(43.646711_degs)},

    // site longitude  in degrees
    simple_config_record_t{"siteLongitude", mcc::MccAngle(41.440732_degs)},

    // site elevation in meters
    simple_config_record_t{"siteElevation", 2070.0},

    /*    celestial coordinate transformation    */

    //  wavelength at which refraction is calculated (in mkm)
    simple_config_record_t{"refractWavelength", 0.55},

    // an empty filename means default precompiled string
    simple_config_record_t{"leapSecondFilename", std::string()},

    // an empty filename means default precompiled string
    simple_config_record_t{"bulletinAFilename", std::string()},

    /*    pointing correction model    */

    // PCM default type
    simple_config_record_t{"pcmType", mcc::MccDefaultPCMType::PCM_TYPE_GEOMETRY},

    // PCM geometrical coefficients
    simple_config_record_t{"pcmGeomCoeffs", std::vector<double>{0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0}},

    // PCM B-spline degrees
    simple_config_record_t{"pcmBsplineDegree", std::vector<size_t>{3, 3}},

    // PCM B-spline knots along X-axis (HA-angle or azimuth). By default from 0 to 2*PI radians
    // NOTE: The first and last values are interpretated as border knots!!!
    //       Thus the array length must be equal to or greater than 2!
    simple_config_record_t{"pcmBsplineXknots",
                           std::vector<double>{0.0, 0.6981317, 1.3962634, 2.0943951, 2.7925268, 3.4906585, 4.1887902,
                                               4.88692191, 5.58505361, 6.28318531}},

    // PCM B-spline knots along Y-axis (declination or zenithal distance). By default from -PI/6 to PI/2 radians
    // NOTE: The first and last values are interpretated as border knots!!!
    //       Thus the array length must be equal to or greater than 2!
    simple_config_record_t{"pcmBsplineYknots",
                           std::vector<double>{-0.52359878, -0.29088821, -0.05817764, 0.17453293, 0.40724349,
                                               0.63995406, 0.87266463, 1.10537519, 1.33808576, 1.57079633}},

    // PCM B-spline coeffs for along X-axis (HA-angle or azimuth)
    simple_config_record_t{"pcmBsplineXcoeffs", std::vector<double>{}},

    // PCM B-spline coeffs for along Y-axis (declination or zenithal distance)
    simple_config_record_t{"pcmBsplineYcoeffs", std::vector<double>{}},


    /*    slewing and tracking parameters    */

    // // arcseconds per second
    // simple_config_record_t{"sideralRate", 15.0410686},

    // timeout for telemetry updating in milliseconds
    simple_config_record_t{"telemetryTimeout", std::chrono::milliseconds(3000)},

    // minimal allowed time in seconds to prohibited zone
    simple_config_record_t{"minTimeToPZone", std::chrono::seconds(10)},

    // a time interval to update prohibited zones related quantities (millisecs)
    simple_config_record_t{"updatingPZoneInterval", std::chrono::milliseconds(5000)},

    // coordinates difference in arcsecs to stop slewing
    simple_config_record_t{"slewToleranceRadius", 5.0},

    // target-mount coordinate difference in arcsecs to start adjusting of slewing
    simple_config_record_t{"adjustCoordDiff", 50.0},

    // minimum time in millisecs between two successive adjustments
    simple_config_record_t{"adjustCycleInterval", std::chrono::milliseconds(300)},

    // slew process timeout in seconds
    simple_config_record_t{"slewTimeout", std::chrono::seconds(3600)},

    // a time shift into future to compute target position in future (UT1-scale time duration, millisecs)
    simple_config_record_t{"timeShiftToTargetPoint", std::chrono::milliseconds(10000)},

    // minimum time in millisecs between two successive tracking corrections
    simple_config_record_t{"trackingCycleInterval", std::chrono::milliseconds(300)},

    // maximal valid target-to-mount distance for tracking process (arcsecs)
    // if current distance is greater than assume current mount coordinate as target point
    simple_config_record_t{"trackingMaxCoordDiff", 20.0},


    /*    prohibited zones    */

    // minimal altitude
    simple_config_record_t{"pzMinAltitude", mcc::MccAngle(10.0_degs)},

    // HA-axis limit switch minimal value
    simple_config_record_t{"pzLimitSwitchHAMin", mcc::MccAngle(-170.0_degs)},

    // HA-axis limit switch maximal value
    simple_config_record_t{"pzLimitSwitchHAMax", mcc::MccAngle(170.0_degs)},

    // DEC-axis limit switch minimal value
    simple_config_record_t{"pzLimitSwitchDecMin", mcc::MccAngle(-90.0_degs)},

    // DEC-axis limit switch maximal value
    simple_config_record_t{"pzLimitSwitchDecMax", mcc::MccAngle(90.0_degs)},


    /*    hardware-related    */

    // hardware mode: 1 - model mode, otherwise real mode
    simple_config_record_t{"RunModel", 0},

    // mount serial device paths
    simple_config_record_t{"MountDevPath", std::string("/dev/ttyUSB0")},

    // mount serial device speed
    simple_config_record_t{"MountDevSpeed", 19200},

    // motor encoders serial device path
    simple_config_record_t{"EncoderDevPath", std::string("")},

    //  X-axis encoder serial device path
    simple_config_record_t{"EncoderXDevPath", std::string("/dev/encoderX0")},

    //  Y-axis encoder serial device path
    simple_config_record_t{"EncoderYDevPath", std::string("/dev/encoderY0")},

    // encoders serial device speed
    simple_config_record_t{"EncoderDevSpeed", 153000},

    // ==1 if encoder works as separate serial device, ==2 if there's new version with two devices
    simple_config_record_t{"SepEncoder", 2},


    // mount polling interval in millisecs
    simple_config_record_t{"MountReqInterval", std::chrono::milliseconds(100)},

    // encoders polling interval in millisecs
    simple_config_record_t{"EncoderReqInterval", std::chrono::milliseconds(50)},

    // mount axes rate calculation interval in millisecs
    simple_config_record_t{"EncoderSpeedInterval", std::chrono::milliseconds(100)},

    // X-axis coordinate PID P,I,D-params
    simple_config_record_t{"XPIDC", std::vector<double>{0.8, 0.1, 0.3}},

    // X-axis rate PID P,I,D-params
    simple_config_record_t{"XPIDV", std::vector<double>{1.0, 0.01, 0.2}},

    // Y-axis coordinate PID P, I, D-params
    simple_config_record_t{"YPIDC", std::vector<double>{0.8, 0.1, 0.3}},

    // Y-axis rate PID P,I,D-params
    simple_config_record_t{"YPIDV", std::vector<double>{0.5, 0.2, 0.5}},


    // maximal moving rate (degrees per second) along HA-axis  (Y-axis of Sidereal servo microcontroller)
    simple_config_record_t{"hwMaxRateHA", mcc::MccAngle(8.0_degs)},

    // maximal moving rate (degrees per second) along DEC-axis (X-axis of Sidereal servo microcontroller)
    simple_config_record_t{"hwMaxRateDEC", mcc::MccAngle(10.0_degs)}


);


static constexpr std::string_view Asibfm700MountDefaultConfigString =
    R"--(
#
# ASTROSIB FM-700 MOUNT DEFAULT CONFIGURATION
#
#     (created 2025-10-01T03:00:00.0)
#

# main cycle period in millisecs
hardwarePollingPeriod = 100

#    geographic coordinates of the observation site

# site latitude in degrees
siteLatitude = 43.646711

# site longitude  in degrees
siteLongitude = 41.440732

# site elevation in meters
siteElevation = 2070.0

#    celestial coordinate transformation

# wavelength at which refraction is calculated (in mkm)
refractWavelength = 0.5

# an empty filename means default precompiled string
leapSecondFilename =

# an empty filename means default precompiled string
bulletinAFilename =

#    pointing correction model

# PCM default type:
# GEOMETRY - "classic" geometry-based correction coefficients
# GEOMETRY-BSPLINE - previous one and additional 2D B-spline corrections
# BSPLINE - pure 2D B-spline corrections
pcmType = GEOMETRY

# PCM geometrical coefficients
pcmGeomCoeffs = 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0

# PCM B-spline degrees
pcmBsplineDegree = 3, 3

# PCM B-spline knots along X-axis (HA-angle). By default from 0 to 2*PI radians
pcmBsplineXknots = 0.0, 0.6981317, 1.3962634, 2.0943951, 2.7925268, 3.4906585, 4.1887902, 4.88692191, 5.58505361, 6.28318531

# PCM B-spline knots along Y-axis (declination-angle). By default from -PI/6 to PI/2 radians
pcmBsplineYknots = -0.52359878, -0.29088821, -0.05817764, 0.17453293, 0.40724349, 0.63995406, 0.87266463, 1.10537519, 1.33808576, 1.57079633

# PCM B-spline coeffs for along X-axis (HA-angle)
pcmBsplineXcoeffs =

# PCM B-spline coeffs for along Y-axis (declination-angle)
pcmBsplineYcoeffs =


#    slewing and tracking parameters

# arcseconds per second
#sideralRate = 15.0410686

# timeout for telemetry updating in milliseconds
telemetryTimeout = 3000

# minimal allowed time in seconds to prohibited zone
minTimeToPZone = 10

# a time interval to update prohibited zones related quantities (millisecs)
updatingPZoneInterval = 5000

# coordinates difference in arcsecs to stop slewing
slewToleranceRadius = 5.0

# target-mount coordinate difference in arcsecs to start adjusting of slewing
adjustCoordDiff =  50.0

# minimum time in millisecs between two successive adjustments
adjustCycleInterval = 300

# slew process timeout in seconds
slewTimeout = 3600

# a time shift into future to compute target position in future (UT1-scale time duration, millisecs)
timeShiftToTargetPoint = 10000

# minimum time in millisecs between two successive tracking corrections
trackingCycleInterval = 300

# maximal valid target-to-mount distance for tracking process (arcsecs)
# if current distance is greater than assume current mount coordinate as target point
trackingMaxCoordDiff = 20.0

#    prohibited zones

# minimal altitude in degrees
pzMinAltitude = 10.0

# HA-axis limit switch minimal value in degrees
pzLimitSwitchHAMin = -170.0

# HA-axis limit switch maximal value in degrees
pzLimitSwitchHAMax = 170.0

# DEC-axis limit switch minimal value in degrees
pzLimitSwitchDecMin = -90.0

# DEC-axis limit switch maximal value in degrees
pzLimitSwitchDecMax = 90.0


#    hardware-related

# hardware mode: 1 - model mode, otherwise real mode
RunModel = 0

# mount serial device paths
MountDevPath = /dev/ttyUSB0

# mount serial device speed
MountDevSpeed =  19200

# motor encoders serial device path
EncoderDevPath =

#  X-axis encoder serial device path
EncoderXDevPath = /dev/encoderX0

#  Y-axis encoder serial device path
EncoderYDevPath = /dev/encoderY0

# encoders serial device speed
EncoderDevSpeed = 153000

# ==1 if encoder works as separate serial device, ==2 if there's new version with two devices
SepEncoder = 2

# mount polling interval in millisecs
MountReqInterval = 100

# encoders polling interval in millisecs
EncoderReqInterval = 50

# mount axes rate calculation interval in millisecs
EncoderSpeedInterval = 100

# X-axis coordinate PID P,I,D-params
XPIDC = 0.8, 0.1, 0.3

# X-axis rate PID P,I,D-params
XPIDV = 1.0, 0.01, 0.2

# Y-axis coordinate PID P,I,D-params
YPIDC = 0.8, 0.1, 0.3

# Y-axis rate PID P,I,D-params
YPIDV = 0.5, 0.2, 0.5


# maximal moving rate (degrees per second) along HA-axis  (Y-axis of Sidereal servo microcontroller)
hwMaxRateHA = 8.0

# maximal moving rate (degrees per second) along DEC-axis (X-axis of Sidereal servo microcontroller)
hwMaxRateDEC = 10.0

)--";



class Asibfm700MountConfig : public mcc::utils::KeyValueHolder<decltype(Asibfm700MountConfigDefaults)>
{
    using base_t = mcc::utils::KeyValueHolder<decltype(Asibfm700MountConfigDefaults)>;

protected:
    inline static auto deserializer = []<typename VT>(std::string_view str, VT& value) {
        std::error_code ec{};

        mcc::utils::MccSimpleDeserializer deser;
        deser.setRangeDelim(base_t::VALUE_ARRAY_DELIM);

        if constexpr (std::is_arithmetic_v<VT> || mcc::traits::mcc_output_char_range<VT> || std::ranges::range<VT> ||
                      mcc::traits::mcc_time_duration_c<VT>) {
            // ec = base_t::defaultDeserializeFunc(str, value);
            ec = deser(str, value);
        } else if constexpr (std::same_as<VT, mcc::MccAngle>) {  // assume here all angles are in degrees
            double vd;
            // ec = base_t::defaultDeserializeFunc(str, vd);
            ec = deser(str, vd);
            if (!ec) {
                value = mcc::MccAngle(vd, mcc::MccDegreeTag{});
            }
        } else if constexpr (std::same_as<VT, mcc::MccDefaultPCMType>) {
            std::string vstr;
            // ec = base_t::defaultDeserializeFunc(str, vstr);
            ec = deser(str, vstr);

            if (!ec) {
                auto s = mcc::utils::trimSpaces(vstr);

                if (s == mcc::MccDefaultPCMTypeString<mcc::MccDefaultPCMType::PCM_TYPE_GEOMETRY>) {
                    value = mcc::MccDefaultPCMType::PCM_TYPE_GEOMETRY;
                } else if (s == mcc::MccDefaultPCMTypeString<mcc::MccDefaultPCMType::PCM_TYPE_GEOMETRY_BSPLINE>) {
                    value = mcc::MccDefaultPCMType::PCM_TYPE_GEOMETRY;
                } else if (s == mcc::MccDefaultPCMTypeString<mcc::MccDefaultPCMType::PCM_TYPE_BSPLINE>) {
                    value = mcc::MccDefaultPCMType::PCM_TYPE_BSPLINE;
                } else {
                    ec = std::make_error_code(std::errc::invalid_argument);
                }
            }
        } else {
            ec = std::make_error_code(std::errc::invalid_argument);
        }

        return ec;
    };


public:
    /*  the most usefull config fields  */

    template <mcc::traits::mcc_time_duration_c DT>
    DT hardwarePollingPeriod() const
    {
        return std::chrono::duration_cast<DT>(
            getValue<std::chrono::milliseconds>("hardwarePollingPeriod").value_or(std::chrono::milliseconds{}));
    };

    std::chrono::milliseconds hardwarePollingPeriod() const
    {
        return hardwarePollingPeriod<std::chrono::milliseconds>();
    };

    template <mcc::mcc_angle_c T>
    T siteLatitude() const
    {
        return static_cast<double>(getValue<mcc::MccAngle>("siteLatitude").value_or(mcc::MccAngle{}));
    };

    mcc::MccAngle siteLatitude() const
    {
        return siteLatitude<mcc::MccAngle>();
    };

    template <mcc::mcc_angle_c T>
    T siteLongitude() const
    {
        return static_cast<double>(getValue<mcc::MccAngle>("siteLongitude").value_or(mcc::MccAngle{}));
    };

    mcc::MccAngle siteLongitude() const
    {
        return siteLongitude<mcc::MccAngle>();
    };

    template <typename T>
    T siteElevation() const
        requires std::is_arithmetic_v<T>
    {
        return getValue<double>("siteElevation").value_or(0.0);
    }

    double siteElevation() const
    {
        return getValue<double>("siteElevation").value_or(0.0);
    };

    template <typename T>
    T refractWavelength() const
        requires std::is_arithmetic_v<T>
    {
        return getValue<double>("refractWavelength").value_or(0.0);
    }

    double refractWavelength() const
    {
        return getValue<double>("refractWavelength").value_or(0.0);
    };

    template <mcc::traits::mcc_view_or_output_char_range R>
    R leapSecondFilename() const
    {
        R r;
        if constexpr (std::ranges::view<R>) {
            std::string const& val = getValue<std::string>("leapSecondFilename").value_or("");
            r = R{val.begin(), val.end()};
        } else {
            std::string val = getValue<std::string>("leapSecondFilename").value_or("");
            std::ranges::copy(val, std::back_inserter(r));
        }

        return r;
    }

    std::string_view leapSecondFilename() const
    {
        return leapSecondFilename<std::string_view>();
    };

    template <mcc::traits::mcc_view_or_output_char_range R>
    R bulletinAFilename() const
    {
        R r;
        if constexpr (std::ranges::view<R>) {
            std::string const& val = getValue<std::string>("bulletinAFilename").value_or("");
            r = R{val.begin(), val.end()};
        } else {
            std::string val = getValue<std::string>("bulletinAFilename").value_or("");
            std::ranges::copy(val, std::back_inserter(r));
        }

        return r;
    }

    std::string_view bulletinAFilename() const
    {
        return bulletinAFilename<std::string_view>();
    };


    template <mcc::mcc_angle_c T>
    T pzMinAltitude() const
    {
        return static_cast<double>(getValue<mcc::MccAngle>("pzMinAltitude").value_or(mcc::MccAngle{}));
    };

    mcc::MccAngle pzMinAltitude() const
    {
        return pzMinAltitude<mcc::MccAngle>();
    };

    template <mcc::mcc_angle_c T>
    T pzLimitSwitchHAMin() const
    {
        return static_cast<double>(getValue<mcc::MccAngle>("pzLimitSwitchHAMin").value_or(mcc::MccAngle{}));
    };

    mcc::MccAngle pzLimitSwitchHAMin() const
    {
        return pzLimitSwitchHAMin<mcc::MccAngle>();
    };

    template <mcc::mcc_angle_c T>
    T pzLimitSwitchHAMax() const
    {
        return static_cast<double>(getValue<mcc::MccAngle>("pzLimitSwitchHAMax").value_or(mcc::MccAngle{}));
    };

    mcc::MccAngle pzLimitSwitchHAMax() const
    {
        return pzLimitSwitchHAMax<mcc::MccAngle>();
    };


    AsibFM700ServoController::hardware_config_t servoControllerConfig() const
    {
        AsibFM700ServoController::hardware_config_t hw_cfg;

        hw_cfg.hwConfig = {};

        hw_cfg.MountDevPath = getValue<std::string>("MountDevPath").value_or({});
        hw_cfg.EncoderDevPath = getValue<std::string>("EncoderDevPath").value_or({});
        hw_cfg.EncoderXDevPath = getValue<std::string>("EncoderXDevPath").value_or({});
        hw_cfg.EncoderYDevPath = getValue<std::string>("EncoderYDevPath").value_or({});

        hw_cfg.devConfig.MountDevPath = hw_cfg.MountDevPath.data();
        hw_cfg.devConfig.EncoderDevPath = hw_cfg.EncoderDevPath.data();
        hw_cfg.devConfig.EncoderXDevPath = hw_cfg.EncoderXDevPath.data();
        hw_cfg.devConfig.EncoderYDevPath = hw_cfg.EncoderYDevPath.data();

        hw_cfg.devConfig.RunModel = getValue<int>("RunModel").value_or({});
        hw_cfg.devConfig.MountDevSpeed = getValue<int>("MountDevSpeed").value_or({});
        hw_cfg.devConfig.EncoderDevSpeed = getValue<int>("EncoderDevSpeed").value_or({});
        hw_cfg.devConfig.SepEncoder = getValue<int>("SepEncoder").value_or({});

        std::chrono::duration<double> secs;  // seconds as floating-point

        secs = getValue<std::chrono::milliseconds>("MountReqInterval").value_or({});
        hw_cfg.devConfig.MountReqInterval = secs.count();

        secs = getValue<std::chrono::milliseconds>("EncoderReqInterval").value_or({});
        hw_cfg.devConfig.EncoderReqInterval = secs.count();

        secs = getValue<std::chrono::milliseconds>("EncoderSpeedInterval").value_or({});
        hw_cfg.devConfig.EncoderSpeedInterval = secs.count();

        std::vector<double> pid = getValue<std::vector<double>>("XPIDC").value_or({});
        if (pid.size() > 2) {
            hw_cfg.devConfig.XPIDC.P = pid[0];
            hw_cfg.devConfig.XPIDC.I = pid[1];
            hw_cfg.devConfig.XPIDC.D = pid[2];
        }

        pid = getValue<std::vector<double>>("XPIDV").value_or({});
        if (pid.size() > 2) {
            hw_cfg.devConfig.XPIDV.P = pid[0];
            hw_cfg.devConfig.XPIDV.I = pid[1];
            hw_cfg.devConfig.XPIDV.D = pid[2];
        }

        pid = getValue<std::vector<double>>("YPIDC").value_or({});
        if (pid.size() > 2) {
            hw_cfg.devConfig.YPIDC.P = pid[0];
            hw_cfg.devConfig.YPIDC.I = pid[1];
            hw_cfg.devConfig.YPIDC.D = pid[2];
        }

        pid = getValue<std::vector<double>>("YPIDV").value_or({});
        if (pid.size() > 2) {
            hw_cfg.devConfig.YPIDV.P = pid[0];
            hw_cfg.devConfig.YPIDV.I = pid[1];
            hw_cfg.devConfig.YPIDV.D = pid[2];
        }

        return hw_cfg;
    }


    mcc::MccSimpleMovingModelParams movingModelParams() const
    {
        static constexpr double arcsecs2rad = std::numbers::pi / 180.0 / 3600.0;  // arcseconds to radians

        mcc::MccSimpleMovingModelParams pars;

        pars.telemetryTimeout =
            getValue<decltype(pars.telemetryTimeout)>("telemetryTimeout").value_or(pars.telemetryTimeout);

        pars.minTimeToPZone = getValue<decltype(pars.minTimeToPZone)>("minTimeToPZone").value_or(pars.minTimeToPZone);

        pars.updatingPZoneInterval = getValue<decltype(pars.updatingPZoneInterval)>("updatingPZoneInterval")
                                         .value_or(pars.updatingPZoneInterval);

        pars.slewToleranceRadius =
            getValue<decltype(pars.slewToleranceRadius)>("slewToleranceRadius").value_or(pars.slewToleranceRadius) *
            arcsecs2rad;

        pars.adjustCoordDiff =
            getValue<decltype(pars.adjustCoordDiff)>("adjustCoordDiff").value_or(pars.adjustCoordDiff) * arcsecs2rad;

        pars.adjustCycleInterval =
            getValue<decltype(pars.adjustCycleInterval)>("adjustCycleInterval").value_or(pars.adjustCycleInterval);

        pars.slewTimeout = getValue<decltype(pars.slewTimeout)>("slewTimeout").value_or(pars.slewTimeout);

        pars.timeShiftToTargetPoint = getValue<decltype(pars.timeShiftToTargetPoint)>("timeShiftToTargetPoint")
                                          .value_or(pars.timeShiftToTargetPoint);

        pars.trackingCycleInterval = getValue<decltype(pars.trackingCycleInterval)>("trackingCycleInterval")
                                         .value_or(pars.trackingCycleInterval);

        pars.trackingMaxCoordDiff =
            getValue<decltype(pars.trackingMaxCoordDiff)>("trackingMaxCoordDiff").value_or(pars.trackingMaxCoordDiff) *
            arcsecs2rad;

        return pars;
    }

    Asibfm700PCM::pcm_data_t pcmData() const
    {
        Asibfm700PCM::pcm_data_t pcm_data;

        std::vector<double> empty_vec;

        pcm_data.type = getValue<decltype(pcm_data.type)>("pcmType").value_or(pcm_data.type);

        pcm_data.siteLatitude = getValue<mcc::MccAngle>("siteLatitude").value_or(pcm_data.siteLatitude);

        std::vector<double> vec = getValue<std::vector<double>>("pcmGeomCoeffs").value_or(empty_vec);
        if (vec.size() >= 9) {  // must be 9 coefficients
            pcm_data.geomCoefficients = {.zeroPointX = vec[0],
                                         .zeroPointY = vec[1],
                                         .collimationErr = vec[2],
                                         .nonperpendErr = vec[3],
                                         .misalignErr1 = vec[4],
                                         .misalignErr2 = vec[5],
                                         .tubeFlexure = vec[6],
                                         .forkFlexure = vec[7],
                                         .DECaxisFlexure = vec[8]};
        }

        std::vector<size_t> dd = getValue<decltype(dd)>("pcmBsplineDegree").value_or(dd);
        if (dd.size() >= 2) {
            pcm_data.bspline.bsplDegreeX = dd[0] > 0 ? dd[0] : 3;
            pcm_data.bspline.bsplDegreeY = dd[1] > 0 ? dd[1] : 3;
        }

        vec = getValue<std::vector<double>>("pcmBsplineXknots").value_or(empty_vec);
        // pid must contains interior and border (single point for each border) knots so minimal length must be 2
        if (vec.size() >= 2) {
            // generate full knots array (with border knots)
            size_t Nknots = vec.size() + pcm_data.bspline.bsplDegreeX * 2 - 2;
            pcm_data.bspline.knotsX.resize(Nknots);

            for (size_t i = 0; i <= pcm_data.bspline.bsplDegreeX; ++i) {  // border knots
                pcm_data.bspline.knotsX[i] = vec[0];
                pcm_data.bspline.knotsX[Nknots - i - 1] = vec.back();
            }
            for (size_t i = 0; i < (vec.size() - 2); ++i) {  // interior knots
                pcm_data.bspline.knotsX[i + pcm_data.bspline.bsplDegreeX] = vec[1 + i];
            }
        }

        vec = getValue<std::vector<double>>("pcmBsplineYknots").value_or(empty_vec);
        // pid must contains interior and border (single point for each border) knots so minimal length must be 2
        if (vec.size() >= 2) {
            // generate full knots array (with border knots)
            size_t Nknots = vec.size() + pcm_data.bspline.bsplDegreeY * 2 - 2;
            pcm_data.bspline.knotsY.resize(Nknots);

            for (size_t i = 0; i <= pcm_data.bspline.bsplDegreeY; ++i) {  // border knots
                pcm_data.bspline.knotsY[i] = vec[0];
                pcm_data.bspline.knotsY[Nknots - i - 1] = vec.back();
            }
            for (size_t i = 0; i < (vec.size() - 2); ++i) {  // interior knots
                pcm_data.bspline.knotsY[i + pcm_data.bspline.bsplDegreeY] = vec[1 + i];
            }
        }

        // minimal allowed number of B-spline coefficients
        size_t Ncoeffs = pcm_data.type == mcc::MccDefaultPCMType::PCM_TYPE_GEOMETRY
                             ? 0
                             : (pcm_data.bspline.knotsX.size() - pcm_data.bspline.bsplDegreeX - 1) *
                                   (pcm_data.bspline.knotsY.size() - pcm_data.bspline.bsplDegreeY - 1);

        vec = getValue<std::vector<double>>("pcmBsplineXcoeffs").value_or(empty_vec);

        if (vec.size() >= Ncoeffs) {
            pcm_data.bspline.coeffsX.resize(Ncoeffs);
            for (size_t i = 0; i < Ncoeffs; ++i) {
                pcm_data.bspline.coeffsX[i] = vec[i];
            }
        }

        vec = getValue<std::vector<double>>("pcmBsplineYcoeffs").value_or(empty_vec);

        if (vec.size() >= Ncoeffs) {
            pcm_data.bspline.coeffsY.resize(Ncoeffs);
            for (size_t i = 0; i < Ncoeffs; ++i) {
                pcm_data.bspline.coeffsY[i] = vec[i];
            }
        }

        return pcm_data;
    }


    Asibfm700MountConfig() : base_t(Asibfm700MountConfigDefaults) {}

    ~Asibfm700MountConfig() = default;

    std::error_code load(const std::filesystem::path& path)
    {
        std::string buffer;

        std::error_code ec;
        auto sz = std::filesystem::file_size(path, ec);

        if (!ec && sz) {
            std::ifstream fst(path);

            try {
                buffer.resize(sz);

                fst.read(buffer.data(), sz);

                fst.close();

                ec = base_t::fromCharRange(buffer, deserializer);
            } catch (std::ios_base::failure const& ex) {
                ec = ex.code();
            } catch (std::length_error const& ex) {
                ec = std::make_error_code(std::errc::no_buffer_space);
            } catch (std::bad_alloc const& ex) {
                ec = std::make_error_code(std::errc::not_enough_memory);
            } catch (...) {
                ec = std::make_error_code(std::errc::operation_canceled);
            }
        }

        return ec;
    }

    // dump default values to file
    static bool dumpDefaults(const std::filesystem::path& path)
    {
        std::ofstream fst(path);
        if (!fst.is_open()) {
            return false;
        }

        fst << asibfm700::Asibfm700MountDefaultConfigString;
        fst.close();

        return true;
    }
};



}  // namespace asibfm700