source: Daodan/MSYS2/mingw32/include/c++/11.2.0/experimental/bits/simd_converter.h

// Generic simd conversions -*- C++ -*-

// Copyright (C) 2020-2021 Free Software Foundation, Inc.
//
// This file is part of the GNU ISO C++ Library.  This library 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, or (at your option)
// any later version.

// This library 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.

// Under Section 7 of GPL version 3, you are granted additional
// permissions described in the GCC Runtime Library Exception, version
// 3.1, as published by the Free Software Foundation.

// You should have received a copy of the GNU General Public License and
// a copy of the GCC Runtime Library Exception along with this program;
// see the files COPYING3 and COPYING.RUNTIME respectively.  If not, see
// <http://www.gnu.org/licenses/>.

#ifndef _GLIBCXX_EXPERIMENTAL_SIMD_CONVERTER_H_
#define _GLIBCXX_EXPERIMENTAL_SIMD_CONVERTER_H_

#if __cplusplus >= 201703L

_GLIBCXX_SIMD_BEGIN_NAMESPACE
// _SimdConverter scalar -> scalar {{{
template <typename _From, typename _To>
  struct _SimdConverter<_From, simd_abi::scalar, _To, simd_abi::scalar,
                        enable_if_t<!is_same_v<_From, _To>>>
  {
    _GLIBCXX_SIMD_INTRINSIC constexpr _To operator()(_From __a) const noexcept
    { return static_cast<_To>(__a); }
  };

// }}}
// _SimdConverter scalar -> "native" {{{
template <typename _From, typename _To, typename _Abi>
  struct _SimdConverter<_From, simd_abi::scalar, _To, _Abi,
                        enable_if_t<!is_same_v<_Abi, simd_abi::scalar>>>
  {
    using _Ret = typename _Abi::template __traits<_To>::_SimdMember;

    template <typename... _More>
      _GLIBCXX_SIMD_INTRINSIC constexpr _Ret
      operator()(_From __a, _More... __more) const noexcept
      {
        static_assert(sizeof...(_More) + 1 == _Abi::template _S_size<_To>);
        static_assert(conjunction_v<is_same<_From, _More>...>);
        return __make_vector<_To>(__a, __more...);
      }
  };

// }}}
// _SimdConverter "native 1" -> "native 2" {{{
template <typename _From, typename _To, typename _AFrom, typename _ATo>
  struct _SimdConverter<
    _From, _AFrom, _To, _ATo,
    enable_if_t<!disjunction_v<
      __is_fixed_size_abi<_AFrom>, __is_fixed_size_abi<_ATo>,
      is_same<_AFrom, simd_abi::scalar>, is_same<_ATo, simd_abi::scalar>,
      conjunction<is_same<_From, _To>, is_same<_AFrom, _ATo>>>>>
  {
    using _Arg = typename _AFrom::template __traits<_From>::_SimdMember;
    using _Ret = typename _ATo::template __traits<_To>::_SimdMember;
    using _V = __vector_type_t<_To, simd_size_v<_To, _ATo>>;

    template <typename... _More>
      _GLIBCXX_SIMD_INTRINSIC constexpr _Ret
      operator()(_Arg __a, _More... __more) const noexcept
      { return __vector_convert<_V>(__a, __more...); }
  };

// }}}
// _SimdConverter scalar -> fixed_size<1> {{{1
template <typename _From, typename _To>
  struct _SimdConverter<_From, simd_abi::scalar, _To, simd_abi::fixed_size<1>,
                        void>
  {
    _GLIBCXX_SIMD_INTRINSIC constexpr _SimdTuple<_To, simd_abi::scalar>
    operator()(_From __x) const noexcept
    { return {static_cast<_To>(__x)}; }
  };

// _SimdConverter fixed_size<1> -> scalar {{{1
template <typename _From, typename _To>
  struct _SimdConverter<_From, simd_abi::fixed_size<1>, _To, simd_abi::scalar,
                        void>
  {
    _GLIBCXX_SIMD_INTRINSIC constexpr _To
    operator()(_SimdTuple<_From, simd_abi::scalar> __x) const noexcept
    { return {static_cast<_To>(__x.first)}; }
  };

// _SimdConverter fixed_size<_Np> -> fixed_size<_Np> {{{1
template <typename _From, typename _To, int _Np>
  struct _SimdConverter<_From, simd_abi::fixed_size<_Np>, _To,
                        simd_abi::fixed_size<_Np>,
                        enable_if_t<!is_same_v<_From, _To>>>
  {
    using _Ret = __fixed_size_storage_t<_To, _Np>;
    using _Arg = __fixed_size_storage_t<_From, _Np>;

    _GLIBCXX_SIMD_INTRINSIC constexpr _Ret
    operator()(const _Arg& __x) const noexcept
    {
      if constexpr (is_same_v<_From, _To>)
        return __x;

      // special case (optimize) int signedness casts
      else if constexpr (sizeof(_From) == sizeof(_To)
                         && is_integral_v<_From> && is_integral_v<_To>)
        return __bit_cast<_Ret>(__x);

      // special case if all ABI tags in _Ret are scalar
      else if constexpr (__is_scalar_abi<typename _Ret::_FirstAbi>())
        {
          return __call_with_subscripts(
            __x, make_index_sequence<_Np>(),
            [](auto... __values) constexpr->_Ret {
              return __make_simd_tuple<_To, decltype((void) __values,
                                                     simd_abi::scalar())...>(
                static_cast<_To>(__values)...);
            });
        }

      // from one vector to one vector
      else if constexpr (_Arg::_S_first_size == _Ret::_S_first_size)
        {
          _SimdConverter<_From, typename _Arg::_FirstAbi, _To,
                         typename _Ret::_FirstAbi>
            __native_cvt;
          if constexpr (_Arg::_S_tuple_size == 1)
            return {__native_cvt(__x.first)};
          else
            {
              constexpr size_t _NRemain = _Np - _Arg::_S_first_size;
              _SimdConverter<_From, simd_abi::fixed_size<_NRemain>, _To,
                             simd_abi::fixed_size<_NRemain>>
                __remainder_cvt;
              return {__native_cvt(__x.first), __remainder_cvt(__x.second)};
            }
        }

      // from one vector to multiple vectors
      else if constexpr (_Arg::_S_first_size > _Ret::_S_first_size)
        {
          const auto __multiple_return_chunks
            = __convert_all<__vector_type_t<_To, _Ret::_S_first_size>>(
              __x.first);
          constexpr auto __converted = __multiple_return_chunks.size()
                                       * _Ret::_FirstAbi::template _S_size<_To>;
          constexpr auto __remaining = _Np - __converted;
          if constexpr (_Arg::_S_tuple_size == 1 && __remaining == 0)
            return __to_simd_tuple<_To, _Np>(__multiple_return_chunks);
          else if constexpr (_Arg::_S_tuple_size == 1)
            { // e.g. <int, 3> -> <double, 2, 1> or <short, 7> -> <double, 4, 2,
              // 1>
              using _RetRem
                = __remove_cvref_t<decltype(__simd_tuple_pop_front<__converted>(
                  _Ret()))>;
              const auto __return_chunks2
                = __convert_all<__vector_type_t<_To, _RetRem::_S_first_size>, 0,
                                __converted>(__x.first);
              constexpr auto __converted2
                = __converted
                  + __return_chunks2.size() * _RetRem::_S_first_size;
              if constexpr (__converted2 == _Np)
                return __to_simd_tuple<_To, _Np>(__multiple_return_chunks,
                                                 __return_chunks2);
              else
                {
                  using _RetRem2 = __remove_cvref_t<
                    decltype(__simd_tuple_pop_front<__return_chunks2.size()
                                                    * _RetRem::_S_first_size>(
                      _RetRem()))>;
                  const auto __return_chunks3 = __convert_all<
                    __vector_type_t<_To, _RetRem2::_S_first_size>, 0,
                    __converted2>(__x.first);
                  constexpr auto __converted3
                    = __converted2
                      + __return_chunks3.size() * _RetRem2::_S_first_size;
                  if constexpr (__converted3 == _Np)
                    return __to_simd_tuple<_To, _Np>(__multiple_return_chunks,
                                                     __return_chunks2,
                                                     __return_chunks3);
                  else
                    {
                      using _RetRem3
                        = __remove_cvref_t<decltype(__simd_tuple_pop_front<
                                                    __return_chunks3.size()
                                                    * _RetRem2::_S_first_size>(
                          _RetRem2()))>;
                      const auto __return_chunks4 = __convert_all<
                        __vector_type_t<_To, _RetRem3::_S_first_size>, 0,
                        __converted3>(__x.first);
                      constexpr auto __converted4
                        = __converted3
                          + __return_chunks4.size() * _RetRem3::_S_first_size;
                      if constexpr (__converted4 == _Np)
                        return __to_simd_tuple<_To, _Np>(
                          __multiple_return_chunks, __return_chunks2,
                          __return_chunks3, __return_chunks4);
                      else
                        __assert_unreachable<_To>();
                    }
                }
            }
          else
            {
              constexpr size_t _NRemain = _Np - _Arg::_S_first_size;
              _SimdConverter<_From, simd_abi::fixed_size<_NRemain>, _To,
                             simd_abi::fixed_size<_NRemain>>
                __remainder_cvt;
              return __simd_tuple_concat(
                __to_simd_tuple<_To, _Arg::_S_first_size>(
                  __multiple_return_chunks),
                __remainder_cvt(__x.second));
            }
        }

      // from multiple vectors to one vector
      // _Arg::_S_first_size < _Ret::_S_first_size
      // a) heterogeneous input at the end of the tuple (possible with partial
      //    native registers in _Ret)
      else if constexpr (_Ret::_S_tuple_size == 1
                         && _Np % _Arg::_S_first_size != 0)
        {
          static_assert(_Ret::_FirstAbi::template _S_is_partial<_To>);
          return _Ret{__generate_from_n_evaluations<
            _Np, typename _VectorTraits<typename _Ret::_FirstType>::type>(
            [&](auto __i) { return static_cast<_To>(__x[__i]); })};
        }
      else
        {
          static_assert(_Arg::_S_tuple_size > 1);
          constexpr auto __n
            = __div_roundup(_Ret::_S_first_size, _Arg::_S_first_size);
          return __call_with_n_evaluations<__n>(
            [&__x](auto... __uncvted) {
              // assuming _Arg Abi tags for all __i are _Arg::_FirstAbi
              _SimdConverter<_From, typename _Arg::_FirstAbi, _To,
                             typename _Ret::_FirstAbi>
                __native_cvt;
              if constexpr (_Ret::_S_tuple_size == 1)
                return _Ret{__native_cvt(__uncvted...)};
              else
                return _Ret{
                  __native_cvt(__uncvted...),
                  _SimdConverter<
                    _From, simd_abi::fixed_size<_Np - _Ret::_S_first_size>, _To,
                    simd_abi::fixed_size<_Np - _Ret::_S_first_size>>()(
                    __simd_tuple_pop_front<_Ret::_S_first_size>(__x))};
            },
            [&__x](auto __i) { return __get_tuple_at<__i>(__x); });
        }
    }
  };

// _SimdConverter "native" -> fixed_size<_Np> {{{1
// i.e. 1 register to ? registers
template <typename _From, typename _Ap, typename _To, int _Np>
  struct _SimdConverter<_From, _Ap, _To, simd_abi::fixed_size<_Np>,
                        enable_if_t<!__is_fixed_size_abi_v<_Ap>>>
  {
    static_assert(
      _Np == simd_size_v<_From, _Ap>,
      "_SimdConverter to fixed_size only works for equal element counts");

    using _Ret = __fixed_size_storage_t<_To, _Np>;

    _GLIBCXX_SIMD_INTRINSIC constexpr _Ret
    operator()(typename _SimdTraits<_From, _Ap>::_SimdMember __x) const noexcept
    {
      if constexpr (_Ret::_S_tuple_size == 1)
        return {__vector_convert<typename _Ret::_FirstType::_BuiltinType>(__x)};
      else
        {
          using _FixedNp = simd_abi::fixed_size<_Np>;
          _SimdConverter<_From, _FixedNp, _To, _FixedNp> __fixed_cvt;
          using _FromFixedStorage = __fixed_size_storage_t<_From, _Np>;
          if constexpr (_FromFixedStorage::_S_tuple_size == 1)
            return __fixed_cvt(_FromFixedStorage{__x});
          else if constexpr (_FromFixedStorage::_S_tuple_size == 2)
            {
              _FromFixedStorage __tmp;
              static_assert(sizeof(__tmp) <= sizeof(__x));
              __builtin_memcpy(&__tmp.first, &__x, sizeof(__tmp.first));
              __builtin_memcpy(&__tmp.second.first,
                               reinterpret_cast<const char*>(&__x)
                                 + sizeof(__tmp.first),
                               sizeof(__tmp.second.first));
              return __fixed_cvt(__tmp);
            }
          else
            __assert_unreachable<_From>();
        }
    }
  };

// _SimdConverter fixed_size<_Np> -> "native" {{{1
// i.e. ? register to 1 registers
template <typename _From, int _Np, typename _To, typename _Ap>
  struct _SimdConverter<_From, simd_abi::fixed_size<_Np>, _To, _Ap,
                        enable_if_t<!__is_fixed_size_abi_v<_Ap>>>
  {
    static_assert(
      _Np == simd_size_v<_To, _Ap>,
      "_SimdConverter to fixed_size only works for equal element counts");

    using _Arg = __fixed_size_storage_t<_From, _Np>;

    _GLIBCXX_SIMD_INTRINSIC constexpr
      typename _SimdTraits<_To, _Ap>::_SimdMember
      operator()(_Arg __x) const noexcept
    {
      if constexpr (_Arg::_S_tuple_size == 1)
        return __vector_convert<__vector_type_t<_To, _Np>>(__x.first);
      else if constexpr (_Arg::_S_is_homogeneous)
        return __call_with_n_evaluations<_Arg::_S_tuple_size>(
          [](auto... __members) {
            if constexpr ((is_convertible_v<decltype(__members), _To> && ...))
              return __vector_type_t<_To, _Np>{static_cast<_To>(__members)...};
            else
              return __vector_convert<__vector_type_t<_To, _Np>>(__members...);
          },
          [&](auto __i) { return __get_tuple_at<__i>(__x); });
      else if constexpr (__fixed_size_storage_t<_To, _Np>::_S_tuple_size == 1)
        {
          _SimdConverter<_From, simd_abi::fixed_size<_Np>, _To,
                         simd_abi::fixed_size<_Np>>
            __fixed_cvt;
          return __fixed_cvt(__x).first;
        }
      else
        {
          const _SimdWrapper<_From, _Np> __xv
            = __generate_from_n_evaluations<_Np, __vector_type_t<_From, _Np>>(
              [&](auto __i) { return __x[__i]; });
          return __vector_convert<__vector_type_t<_To, _Np>>(__xv);
        }
    }
  };

// }}}1
_GLIBCXX_SIMD_END_NAMESPACE
#endif // __cplusplus >= 201703L
#endif // _GLIBCXX_EXPERIMENTAL_SIMD_CONVERTER_H_

// vim: foldmethod=marker sw=2 noet ts=8 sts=2 tw=80