/*
	This file is part of Fennix Kernel.

	Fennix Kernel 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 3 of
	the License, or (at your option) any later version.

	Fennix Kernel 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 Fennix Kernel. If not, see <https://www.gnu.org/licenses/>.
*/

#pragma once

#include <type_traits>

namespace std
{
	namespace detail
	{
		template <intmax_t A, intmax_t B>
		struct GCD
		{
			static constexpr intmax_t value = GCD<B, A % B>::value;
		};

		template <intmax_t A>
		struct GCD<A, 0>
		{
			static constexpr intmax_t value = A;
		};
	}

	template <intmax_t Num, intmax_t Denom = 1>
	class ratio
	{
	private:
		static_assert(Denom != 0, "Denominator cannot be zero");
		static_assert(Num >= -__INTMAX_MAX__ && Denom >= -__INTMAX_MAX__, "Overflow");

	private:
		static constexpr intmax_t __first = Num < 0 ? -Num : Num;
		static constexpr intmax_t __second = Denom < 0 ? -Denom : Denom;
		static constexpr intmax_t __gcd = detail::GCD<__first, __second>::value;

	public:
		typedef ratio<Num, Denom> type;
		static constexpr intmax_t num = Denom < 0 ? -Num / __gcd : Num / __gcd;
		static constexpr intmax_t den = Denom < 0 ? -Denom / __gcd : Denom / __gcd;
	};

	namespace detail
	{
		template <typename _Tp>
		constexpr bool __ta_is_ratio = false;

		template <intmax_t _Num, intmax_t _Den>
		constexpr bool __ta_is_ratio<ratio<_Num, _Den>> = true;

		template <class R1, class R2>
		constexpr bool __is_equal()
		{
			return R1::num == R2::num && R1::den == R2::den;
		}

		template <class R1, class R2>
		constexpr bool __is_less()
		{
			return R1::num * R2::den < R2::num * R1::den;
		}

		template <class R1, class R2>
		constexpr bool __is_less_or_equal()
		{
			return R1::num * R2::den <= R2::num * R1::den;
		}

		template <class R1, class R2>
		constexpr bool __is_greater()
		{
			return R1::num * R2::den > R2::num * R1::den;
		}

		template <class R1, class R2>
		constexpr bool __is_greater_or_equal()
		{
			return R1::num * R2::den >= R2::num * R1::den;
		}
	};

	template <class R1, class R2>
	struct ratio_add
	{
		static_assert(detail::__ta_is_ratio<R1> && detail::__ta_is_ratio<R2>, "Both template arguments must be std::ratio");

		static constexpr intmax_t num = R1::num * R2::den + R2::num * R1::den;
		static constexpr intmax_t den = R1::den * R2::den;

		using type = ratio<num, den>;
	};

	template <class R1, class R2>
	struct ratio_subtract
	{
		static_assert(detail::__ta_is_ratio<R1> && detail::__ta_is_ratio<R2>, "Both template arguments must be std::ratio");

		static constexpr intmax_t num = R1::num * R2::den - R2::num * R1::den;
		static constexpr intmax_t den = R1::den * R2::den;

		using type = ratio<num, den>;
	};

	template <class R1, class R2>
	struct ratio_multiply
	{
		static_assert(detail::__ta_is_ratio<R1> && detail::__ta_is_ratio<R2>, "Both templates must be ratios");

		static constexpr intmax_t num = R1::num * R2::num;
		static constexpr intmax_t den = R1::den * R2::den;

		using type = ratio<num, den>;
	};

	template <class R1, class R2>
	struct ratio_divide
	{
		static_assert(R2::num != 0, "Divide by zero");

		static constexpr intmax_t num = R1::num * R2::den;
		static constexpr intmax_t den = R1::den * R2::num;

		using type = ratio<num, den>;
	};

	template <class R1, class R2>
	struct ratio_equal : public std::integral_constant<bool, detail::__is_equal<R1, R2>()>
	{
	};

	template <class R1, class R2>
	struct ratio_not_equal : public std::integral_constant<bool, !detail::__is_equal<R1, R2>()>
	{
	};

	template <class R1, class R2>
	struct ratio_less : public std::integral_constant<bool, detail::__is_less<R1, R2>()>
	{
	};

	template <class R1, class R2>
	struct ratio_less_equal : public std::integral_constant<bool, detail::__is_less_or_equal<R1, R2>()>
	{
	};

	template <class R1, class R2>
	struct ratio_greater : public std::integral_constant<bool, detail::__is_greater<R1, R2>()>
	{
	};

	template <class R1, class R2>
	struct ratio_greater_equal : public std::integral_constant<bool, detail::__is_greater_or_equal<R1, R2>()>
	{
	};

	template <class R1, class R2>
	constexpr bool ratio_equal_v = ratio_equal<R1, R2>::value;

	template <class R1, class R2>
	constexpr bool ratio_not_equal_v = ratio_not_equal<R1, R2>::value;

	template <class R1, class R2>
	constexpr bool ratio_less_v = ratio_less<R1, R2>::value;

	template <class R1, class R2>
	constexpr bool ratio_less_equal_v = ratio_less_equal<R1, R2>::value;

	template <class R1, class R2>
	constexpr bool ratio_greater_v = ratio_greater<R1, R2>::value;

	template <class R1, class R2>
	constexpr bool ratio_greater_equal_v = ratio_greater_equal<R1, R2>::value;

	// typedef ratio<1, 1000000000000000000000000000000> quecto;
	// typedef ratio<1, 1000000000000000000000000000> ronto;
	// typedef ratio<1, 1000000000000000000000000> yocto;
	// typedef ratio<1, 1000000000000000000000> zepto;
	typedef ratio<1, 1000000000000000000> atto;
	typedef ratio<1, 1000000000000000> femto;
	typedef ratio<1, 1000000000000> pico;
	typedef ratio<1, 1000000000> nano;
	typedef ratio<1, 1000000> micro;
	typedef ratio<1, 1000> milli;
	typedef ratio<1, 100> centi;
	typedef ratio<1, 10> deci;
	typedef ratio<10, 1> deca;
	typedef ratio<100, 1> hecto;
	typedef ratio<1000, 1> kilo;
	typedef ratio<1000000, 1> mega;
	typedef ratio<1000000000, 1> giga;
	typedef ratio<1000000000000, 1> tera;
	typedef ratio<1000000000000000, 1> peta;
	typedef ratio<1000000000000000000, 1> exa;
	// typedef ratio<1000000000000000000000, 1> zetta;
	// typedef ratio<1000000000000000000000000, 1> yotta;
	// typedef ratio<1000000000000000000000000000, 1> ronna;
	// typedef ratio<1000000000000000000000000000000, 1> quetta;
}