ADC/device/adc_device_attribute.h

#pragma once

/*

 ABSTRACT DEVICE COMPONENTS LIBRARY

 */

#include <system_error>
#include <unordered_map>

#include "../common/adc_traits.h"
#include "../common/adc_utils.h"

// #include "../common/adc_value.h"


namespace adc
{

namespace constants
{

static constexpr std::tuple<bool,
                            char,
                            short,
                            int,
                            long,
                            long long,
                            unsigned char,
                            unsigned short,
                            unsigned int,
                            unsigned long,
                            unsigned long long,
                            float,
                            double,
                            long double>
    AdcDefaultTrivialConvTypes{};

}  // namespace constants

namespace traits
{

/*    concepts    */

// attribute setter concept
template <typename T>
concept adc_attr_getter_c = std::is_null_pointer_v<T> ||
                            (traits::adc_func_traits<T>::arity == 0 && !std::same_as<traits::adc_retval_t<T>, void>);


// attribute setter concept
template <typename T>
concept adc_attr_setter_c = std::is_null_pointer_v<T> || (traits::adc_func_traits<T>::arity == 1);


// internal-to-user and user-to-internal type conversional function concept
template <typename T>
concept adc_attr_convfunc_c = std::is_null_pointer_v<T> ||
                              (traits::adc_func_traits<T>::arity == 1 && !std::same_as<traits::adc_retval_t<T>, void>);


// deduce attribute type from getter and setter functions signatures
template <adc_attr_getter_c GT, adc_attr_setter_c ST>
using attr_value_t =
    std::conditional_t<std::is_null_pointer_v<GT>,
                       std::conditional_t<std::is_null_pointer_v<ST>, std::nullptr_t, traits::adc_func_arg1_t<ST>>,
                       traits::adc_retval_t<GT>>;



// deduce attribute internal type from conversional functions signatures
template <adc_attr_convfunc_c FromFuncT, adc_attr_convfunc_c ToFuncT>
using attr_internal_t = std::conditional_t<
    std::is_null_pointer_v<ToFuncT>,
    std::conditional_t<std::is_null_pointer_v<FromFuncT>, std::nullptr_t, traits::adc_retval_t<FromFuncT>>,
    traits::adc_retval_t<ToFuncT>>;


// deduce user-defined type from conversional functions signatures
template <adc_attr_convfunc_c FromFuncT, adc_attr_convfunc_c ToFuncT>
using attr_user_t = std::conditional_t<
    std::is_null_pointer_v<FromFuncT>,
    std::conditional_t<std::is_null_pointer_v<ToFuncT>, std::nullptr_t, traits::adc_retval_t<ToFuncT>>,
    traits::adc_retval_t<FromFuncT>>;


// attribute serializer function concept
template <typename T, typename VT>
concept adc_serializer_c = std::invocable<T, const VT&> && !std::same_as<void, traits::adc_retval_t<T>>;


// attribute deserializer function concept
template <typename T, typename ST>
concept adc_deserializer_c = std::invocable<T, const ST&> && !std::same_as<void, traits::adc_retval_t<T>>;


// a callable and it has exactly one argument
template <typename T>
concept adc_is_setter = adc_func_traits<T>::arity == 1;

// a callable with exactly one argument of type VT
template <typename T, typename VT>
concept adc_is_setter_arg = (adc_func_traits<T>::arity == 1) && std::same_as<VT, adc_func_arg1_t<T>>;


// a callable with exactly one argument of type VT and it returns a value of type ST
template <typename T, typename ST, typename VT>
concept adc_is_serializer =
    (adc_func_traits<T>::arity == 1) && std::same_as<VT, adc_func_arg1_t<T>> && std::same_as<ST, adc_retval_t<T>>;

}  // namespace traits

// error codes
enum class AdcDeviceAttributeErrorCode : int {
    ERROR_OK,
    ERROR_NO_CONV_FUNC,
    ERROR_INTERNAL_TYPE_MISMATCH,
    ERROR_READ_ONLY,
    ERROR_WRITE_ONLY,
    ERROR_INVALID_SERIALIZED_TYPE
};

}  // namespace adc


namespace std
{

template <>
class is_error_code_enum<adc::AdcDeviceAttributeErrorCode> : public true_type
{
};

}  // namespace std



namespace adc
{

// error category
struct AdcDeviceAttributeErrorCategory : public std::error_category {
    AdcDeviceAttributeErrorCategory() : std::error_category() {}

    const char* name() const noexcept { return "ADC_DEVICE_ATTRIBUTE_CATEGORY"; }

    std::string message(int ec) const
    {
        AdcDeviceAttributeErrorCode err = static_cast<AdcDeviceAttributeErrorCode>(ec);

        switch (err) {
            case AdcDeviceAttributeErrorCode::ERROR_OK:
                return "OK";
            case AdcDeviceAttributeErrorCode::ERROR_NO_CONV_FUNC:
                return "conversion function is not defined";
            case AdcDeviceAttributeErrorCode::ERROR_INTERNAL_TYPE_MISMATCH:
                return "try to setup default conversion function for invalid type (internal type mismatch)";
            case AdcDeviceAttributeErrorCode::ERROR_READ_ONLY:
                return "device attribute is read-only";
            case AdcDeviceAttributeErrorCode::ERROR_WRITE_ONLY:
                return "device attribute is write-only";
            case AdcDeviceAttributeErrorCode::ERROR_INVALID_SERIALIZED_TYPE:
                return "invalid user-passed serialized type";
            default:
                return "UNKNOWN";
        }
    }

    static const AdcDeviceAttributeErrorCategory& get()
    {
        static const AdcDeviceAttributeErrorCategory constInst;
        return constInst;
    }
};


inline std::error_code make_error_code(AdcDeviceAttributeErrorCode ec)
{
    return std::error_code(static_cast<int>(ec), AdcDeviceAttributeErrorCategory::get());
}



template <typename IdentT>
class AdcDeviceAttribute
{
protected:
    template <typename T>
    using ret_value_t = std::decay_t<traits::adc_retval_t<T>>;

    template <typename VT>
    inline static std::unordered_map<const AdcDeviceAttribute*, std::function<VT()>> _getterFunc{};

    template <typename VT>
    inline static std::unordered_map<const AdcDeviceAttribute*, std::function<void(const VT&)>> _setterFunc{};

    template <typename SerializedT>
    inline static std::unordered_map<const AdcDeviceAttribute*, std::function<SerializedT()>> _serializerFunc{};

    template <typename SerializedT>
    inline static std::unordered_map<const AdcDeviceAttribute*, std::function<void(const SerializedT&)>>
        _deserializerFunc{};

    std::function<void()> _clearFunc;

    std::function<void(AdcDeviceAttribute*)> _copyFunc;
    std::function<void(AdcDeviceAttribute*)> _moveFunc;


public:
    typedef IdentT ident_t;

    typedef std::string default_serialized_t;

    enum AccessType { ReadOnly, WriteOnly, ReadWrite };

    template <typename T>
    constexpr static T DummyGetter()
    {
        return T();
    }


    template <typename T>
    constexpr static void DummySetter(const T&)
    {
    }

    template <typename T, typename SerializedT = default_serialized_t>
    constexpr static SerializedT DummySerializer(const T&)
    {
        return SerializedT();
    }

    template <typename T, typename SerializedT = default_serialized_t>
    constexpr static T DummyDeserializer(const SerializedT&)
    {
        return T();
    }


    /*  CONSTRUCTORS AND DESTRUCTOR  */

    template <std::invocable<> GT,
              typename ValueT = ret_value_t<GT>,
              std::invocable<const ValueT&> ST,
              std::invocable<const ValueT&> SRT =
                  decltype(utils::AdcDefaultValueConverter<>::serialize<default_serialized_t, ValueT>),
              typename SerializedT = ret_value_t<SRT>,
              std::invocable<const SerializedT&> DSRT =
                  decltype(utils::AdcDefaultValueConverter<>::deserialize<ValueT, SerializedT>)>
    AdcDeviceAttribute(GT&& getter,
                       ST&& setter,
                       SRT&& serializer = utils::AdcDefaultValueConverter<>::serialize<default_serialized_t, ValueT>,
                       DSRT&& deserializer = utils::AdcDefaultValueConverter<>::deserialize<ValueT, SerializedT>)
    {
        _getterFunc<ValueT>.emplace(this, std::forward<GT>(getter));
        _setterFunc<ValueT>.emplace(this, std::forward<ST>(setter));


        _serializerFunc<SerializedT>[this] = [wrapper = traits::adc_pf_wrapper(std::forward<SRT>(serializer)), this]() {
            auto& serializer = std::get<0>(wrapper);


            auto val = _getterFunc<ValueT>[this]();

            return serializer(val);
        };


        _deserializerFunc<SerializedT>[this] = [wrapper = traits::adc_pf_wrapper(std::forward<DSRT>(deserializer)),
                                                this](const SerializedT& sval) {
            auto& deserializer = std::get<0>(wrapper);

            ValueT val = deserializer(sval);

            _setterFunc<ValueT>[this](val);
        };

        _clearFunc = [this]() {
            _getterFunc<ValueT>.erase(this);
            _setterFunc<ValueT>.erase(this);

            _serializerFunc<SerializedT>.erase(this);
            _deserializerFunc<SerializedT>.erase(this);
        };


        // copy TO other
        _copyFunc = [this](AdcDeviceAttribute* other) {
            _getterFunc<ValueT>.emplace(other, _getterFunc<ValueT>[this]);
            _setterFunc<ValueT>.emplace(other, _setterFunc<ValueT>[this]);

            _serializerFunc<SerializedT>.emplace(other, _serializerFunc<SerializedT>[this]);
            _deserializerFunc<SerializedT>.emplace(other, _deserializerFunc<SerializedT>[this]);
        };


        // move TO other
        _moveFunc = [this](AdcDeviceAttribute* other) {
            _getterFunc<ValueT>.emplace(other, std::move(_getterFunc<ValueT>[this]));
            _setterFunc<ValueT>.emplace(other, std::move(_setterFunc<ValueT>[this]));

            _serializerFunc<SerializedT>.emplace(other, std::move(_serializerFunc<SerializedT>[this]));
            _deserializerFunc<SerializedT>.emplace(other, std::move(_deserializerFunc<SerializedT>[this]));
        };
    }


    template <traits::adc_tuple_like<> TupleT,
              std::invocable<> GT,
              typename ValueT = ret_value_t<GT>,
              std::invocable<const ValueT&> ST,
              std::invocable<const ValueT&> SRT =
                  decltype(utils::AdcDefaultValueConverter<>::serialize<default_serialized_t, ValueT>),
              typename SerializedT = ret_value_t<SRT>,
              std::invocable<const SerializedT&> DSRT =
                  decltype(utils::AdcDefaultValueConverter<>::deserialize<ValueT, SerializedT>)>
    AdcDeviceAttribute(TupleT&&,
                       GT&& getter,
                       ST&& setter,
                       SRT&& serializer = utils::AdcDefaultValueConverter<>::serialize<default_serialized_t, ValueT>,
                       DSRT&& deserializer = utils::AdcDefaultValueConverter<>::deserialize<ValueT, SerializedT>)
        : AdcDeviceAttribute(std::forward<GT>(getter),
                             std::forward<ST>(setter),
                             std::forward<SRT>(serializer),
                             std::forward<DSRT>(deserializer))
    {
        AdcDeviceAttribute::setupTrivialConvertFunc<ValueT, std::decay_t<TupleT>>();
    }



    // read-only attribute constructor
    template <std::invocable<> GT,
              typename ValueT = ret_value_t<GT>,
              std::invocable<const ValueT&> SRT =
                  decltype(utils::AdcDefaultValueConverter<>::serialize<default_serialized_t, ValueT>),
              typename SerializedT = ret_value_t<SRT>>
    AdcDeviceAttribute(const IdentT& ident,
                       GT&& getter,
                       SRT&& serializer = utils::AdcDefaultValueConverter<>::serialize<default_serialized_t, ValueT>)
        : AdcDeviceAttribute(ident,
                             std::forward<GT>(getter),
                             AdcDeviceAttribute::DummySetter<ValueT>,
                             std::forward<SRT>(serializer),
                             AdcDeviceAttribute::DummyDeserializer<ValueT, SerializedT>)
    {
        _accessType = ReadOnly;
    }


    template <traits::adc_tuple_like<> TupleT,
              std::invocable<> GT,
              typename ValueT = ret_value_t<GT>,
              std::invocable<const ValueT&> SRT =
                  decltype(utils::AdcDefaultValueConverter<>::serialize<default_serialized_t, ValueT>),
              typename SerializedT = ret_value_t<SRT>>
    AdcDeviceAttribute(const IdentT& ident,
                       TupleT&&,
                       GT&& getter,
                       SRT&& serializer = utils::AdcDefaultValueConverter<>::serialize<default_serialized_t, ValueT>)
        : AdcDeviceAttribute(ident,
                             TupleT{},
                             std::forward<GT>(getter),
                             AdcDeviceAttribute::DummySetter<ValueT>,
                             std::forward<SRT>(serializer),
                             AdcDeviceAttribute::DummyDeserializer<ValueT, SerializedT>)
    {
        _accessType = ReadOnly;
    }


    // write-only attribute constructor
    template <traits::adc_is_setter<> ST,
              typename ValueT = std::decay_t<traits::adc_func_arg1_t<ST>>,
              typename DSRT = decltype(utils::AdcDefaultValueConverter<>::deserialize<ValueT, default_serialized_t>),
              typename SerializedT = std::decay_t<traits::adc_func_arg1_t<DSRT>>>
    AdcDeviceAttribute(const IdentT& ident,
                       ST&& setter,
                       DSRT&& deserializer = utils::AdcDefaultValueConverter<>::deserialize<ValueT, SerializedT>)
        : AdcDeviceAttribute(ident,
                             AdcDeviceAttribute::DummyGetter<ValueT>,
                             std::forward<ST>(setter),
                             AdcDeviceAttribute::DummySerializer<ValueT>,
                             std::forward<DSRT>(deserializer))
    {
        _accessType = WriteOnly;
    }


    template <traits::adc_tuple_like<> TupleT,
              traits::adc_is_setter<> ST,
              typename ValueT = std::decay_t<traits::adc_func_arg1_t<ST>>,
              typename DSRT = decltype(utils::AdcDefaultValueConverter<>::deserialize<ValueT, default_serialized_t>),
              typename SerializedT = std::decay_t<traits::adc_func_arg1_t<DSRT>>>
    AdcDeviceAttribute(const IdentT& ident,
                       TupleT&&,
                       ST&& setter,
                       DSRT&& deserializer = utils::AdcDefaultValueConverter<>::deserialize<ValueT, SerializedT>)
        : AdcDeviceAttribute(ident,
                             TupleT{},
                             AdcDeviceAttribute::DummyGetter<ValueT>,
                             std::forward<ST>(setter),
                             AdcDeviceAttribute::DummySerializer<ValueT>,
                             std::forward<DSRT>(deserializer))
    {
        _accessType = WriteOnly;
    }



    AdcDeviceAttribute(const AdcDeviceAttribute& other)
    {
        _clearFunc();

        other._copyFunc(this);

        _clearFunc = other._clearFunc;
        _copyFunc = other._copyFunc;
        _moveFunc = other._moveFunc;
    }

    AdcDeviceAttribute(AdcDeviceAttribute&& other)
    {
        _clearFunc();

        other._moveFunc(this);

        _clearFunc = std::move(other._clearFunc);
        _copyFunc = std::move(other._copyFunc);
        _moveFunc = std::move(other._moveFunc);
    }


    virtual ~AdcDeviceAttribute() { _clearFunc(); }


    /*  PUBLIC METHODS  */



    IdentT ident() const { return _ident; }

    AccessType accessType() const { return _accessType; }


    template <typename FromFuncT, typename ToFuncT>
    AdcDeviceAttribute& addConvertFunc(FromFuncT&& func_from_internal, ToFuncT&& func_to_internal)
        requires std::invocable<FromFuncT, const ret_value_t<ToFuncT>&> &&
                 std::invocable<ToFuncT, const ret_value_t<FromFuncT>&>
    {
        using value_t = ret_value_t<ToFuncT>;  // it must be internal value type
        using user_t = ret_value_t<FromFuncT>;

        _getterFunc<user_t>[this] = [wrapper = traits::adc_pf_wrapper(std::forward<FromFuncT>(func_from_internal)),
                                     this]() {
            auto& getter = _getterFunc<value_t>[this];
            if (getter) {
                auto val = getter();
                return std::get<0>(wrapper)(val);  // convert from internal type
            }
            // invalid conversion function signature
            throw std::system_error(AdcDeviceAttributeErrorCode::ERROR_INTERNAL_TYPE_MISMATCH);
        };


        _setterFunc<user_t>[this] = [wrapper = traits::adc_pf_wrapper(std::forward<ToFuncT>(func_to_internal)),
                                     this](const user_t& val) {
            value_t value = std::get<0>(wrapper)(val);  // convert to internal type
            auto& setter = _setterFunc<value_t>[this];
            if (setter) {
                setter(value);
            } else {
                // invalid conversion function signature
                throw std::system_error(AdcDeviceAttributeErrorCode::ERROR_INTERNAL_TYPE_MISMATCH);
            }
        };

        _clearFunc = [prev_clear = _clearFunc, this]() {
            prev_clear();

            _getterFunc<user_t>.erase(this);
            _setterFunc<user_t>.erase(this);
        };


        // copy TO other
        _copyFunc = [prev_copy = _copyFunc, this](AdcDeviceAttribute* other) {
            prev_copy(other);

            _getterFunc<user_t>.emplace(other, _getterFunc<user_t>[this]);
            _setterFunc<user_t>.emplace(other, _setterFunc<user_t>[this]);
        };

        // move TO other
        _moveFunc = [prev_move = _moveFunc, this](AdcDeviceAttribute* other) {
            prev_move(other);

            _getterFunc<user_t>.emplace(other, std::move(_getterFunc<user_t>[this]));
            _setterFunc<user_t>.emplace(other, std::move(_setterFunc<user_t>[this]));
        };

        return *this;
    }

    template <typename UT>
    operator UT() const
    {
        if (_accessType == WriteOnly) {
            throw std::system_error(AdcDeviceAttributeErrorCode::ERROR_WRITE_ONLY);
        }

        using val_t = std::decay_t<UT>;

        auto getter = _getterFunc<val_t>[this];
        if (getter) {
            return getter();
        }

        throw std::system_error(AdcDeviceAttributeErrorCode::ERROR_NO_CONV_FUNC);
    }

    template <typename UT>
    AdcDeviceAttribute& operator=(UT&& other)
    {
        if (_accessType == ReadOnly) {
            throw std::system_error(AdcDeviceAttributeErrorCode::ERROR_READ_ONLY);
        }

        using val_t = std::decay_t<UT>;

        auto setter = _setterFunc<val_t>[this];
        if (setter) {
            setter(std::forward<UT>(other));
        } else {
            throw std::system_error(AdcDeviceAttributeErrorCode::ERROR_NO_CONV_FUNC);
        }

        return *this;
    }


    AdcDeviceAttribute& operator=(const AdcDeviceAttribute& other)
    {
        if (&other != this) {
            _clearFunc();

            other._copyFunc(this);

            _clearFunc = other._clearFunc;
            _copyFunc = other._copyFunc;
            _moveFunc = other._moveFunc;
        }

        return *this;
    }


    AdcDeviceAttribute& operator=(AdcDeviceAttribute&& other)
    {
        if (&other != this) {
            _clearFunc();

            other._moveFunc(this);

            _clearFunc = std::move(other._clearFunc);
            _copyFunc = std::move(other._copyFunc);
            _moveFunc = std::move(other._moveFunc);
        }

        return *this;
    }

    template <typename SerializedT>
    SerializedT serialize()
    {
        using s_t = std::decay_t<SerializedT>;

        auto& serializer = _serializerFunc<s_t>[this];

        if (serializer) {
            return serializer();
        }

        throw std::system_error(AdcDeviceAttributeErrorCode::ERROR_INVALID_SERIALIZED_TYPE);
    }

    template <typename SerializedT>
    void deserialize(const SerializedT& sval)
    {
        using s_t = std::decay_t<SerializedT>;

        auto& deserializer = _deserializerFunc<s_t>[this];
        if (deserializer) {
            deserializer(sval);
        } else {
            throw std::system_error(AdcDeviceAttributeErrorCode::ERROR_INVALID_SERIALIZED_TYPE);
        }
    }

protected:
    IdentT _ident;
    AccessType _accessType;


    template <typename VT, size_t I, typename TupleT>
    void setupTrivialConvertFuncImpl()
    {
        if constexpr (I < std::tuple_size_v<TupleT>) {
            using elem_t = std::tuple_element_t<I, TupleT>;

            if constexpr (!std::is_same_v<VT, elem_t>) {
                addConvertFunc([](const VT& v) { return static_cast<elem_t>(v); },
                               [](const elem_t& v) { return static_cast<VT>(v); });
            }

            setupTrivialConvertFuncImpl<VT, I + 1, TupleT>();
        }
    }

    template <typename VT, typename TupleT>
    void setupTrivialConvertFunc()
    {
        setupTrivialConvertFuncImpl<VT, 0, TupleT>();
    }
};

}  // namespace adc