lib/Evaluate/host.h - llvm-project/flang - Git at Google

 //===-- lib/Evaluate/host.h -------------------------------------*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #ifndef FORTRAN_EVALUATE_HOST_H_
 #define FORTRAN_EVALUATE_HOST_H_

 // Define a compile-time mapping between Fortran intrinsic types and host
 // hardware types if possible. The purpose is to avoid having to do any kind of
 // assumption on whether a "float" matches the Scalar<Type<TypeCategory::Real,
 // 4>> outside of this header. The main tools are HostTypeExists<T> and
 // HostType<T>. HostTypeExists<T>() will return true if and only if a host
 // hardware type maps to Fortran intrinsic type T. Then HostType<T> can be used
 // to safely refer to this hardware type.

 #include "flang/Evaluate/type.h"
 #include <cfenv>
 #include <complex>
 #include <cstdint>
 #include <limits>
 #include <string>
 #include <type_traits>

 namespace Fortran::evaluate {
 namespace host {

 // Helper class to handle host runtime traps, status flag and errno
 class HostFloatingPointEnvironment {
 public:
   void SetUpHostFloatingPointEnvironment(FoldingContext &);
   void CheckAndRestoreFloatingPointEnvironment(FoldingContext &);
   bool hasSubnormalFlushingHardwareControl() const {
     return hasSubnormalFlushingHardwareControl_;
   }
   void SetFlag(RealFlag flag) { flags_.set(flag); }
   bool hardwareFlagsAreReliable() const { return hardwareFlagsAreReliable_; }

 private:
   std::fenv_t originalFenv_;
 #if __x86_64__
   unsigned int originalMxcsr;
 #endif
   RealFlags flags_;
   bool hasSubnormalFlushingHardwareControl_{false};
   bool hardwareFlagsAreReliable_{true};
 };

 // Type mapping from F18 types to host types
 struct UnsupportedType {}; // There is no host type for the F18 type

 template <typename FTN_T> struct HostTypeHelper {
   using Type = UnsupportedType;
 };
 template <typename FTN_T> using HostType = typename HostTypeHelper<FTN_T>::Type;

 template <typename... T> constexpr inline bool HostTypeExists() {
   return (... && (!std::is_same_v<HostType<T>, UnsupportedType>));
 }

 // Type mapping from host types to F18 types FortranType<HOST_T> is defined
 // after all HosTypeHelper definition because it reverses them to avoid
 // duplication.

 // Scalar conversion utilities from host scalars to F18 scalars
 template <typename FTN_T>
 inline constexpr Scalar<FTN_T> CastHostToFortran(const HostType<FTN_T> &x) {
   static_assert(HostTypeExists<FTN_T>());
   if constexpr (FTN_T::category == TypeCategory::Complex &&
       sizeof(Scalar<FTN_T>) != sizeof(HostType<FTN_T>)) {
     // X87 is usually padded to 12 or 16bytes. Need to cast piecewise for
     // complex
     return Scalar<FTN_T>{CastHostToFortran<typename FTN_T::Part>(std::real(x)),
         CastHostToFortran<typename FTN_T::Part>(std::imag(x))};
   } else {
     return *reinterpret_cast<const Scalar<FTN_T> *>(&x);
   }
 }

 // Scalar conversion utilities from  F18 scalars to host scalars
 template <typename FTN_T>
 inline constexpr HostType<FTN_T> CastFortranToHost(const Scalar<FTN_T> &x) {
   static_assert(HostTypeExists<FTN_T>());
   if constexpr (FTN_T::category == TypeCategory::Complex &&
       sizeof(Scalar<FTN_T>) != sizeof(HostType<FTN_T>)) {
     // X87 is usually padded to 12 or 16bytes. Need to cast piecewise for
     // complex
     return HostType<FTN_T>{CastFortranToHost<typename FTN_T::Part>(x.REAL()),
         CastFortranToHost<typename FTN_T::Part>(x.AIMAG())};
   } else {
     return *reinterpret_cast<const HostType<FTN_T> *>(&x);
   }
 }

 // Defining the actual mapping
 template <> struct HostTypeHelper<Type<TypeCategory::Integer, 1>> {
   using Type = std::int8_t;
 };

 template <> struct HostTypeHelper<Type<TypeCategory::Integer, 2>> {
   using Type = std::int16_t;
 };

 template <> struct HostTypeHelper<Type<TypeCategory::Integer, 4>> {
   using Type = std::int32_t;
 };

 template <> struct HostTypeHelper<Type<TypeCategory::Integer, 8>> {
   using Type = std::int64_t;
 };

 template <> struct HostTypeHelper<Type<TypeCategory::Integer, 16>> {
 #if (defined(__GNUC__) || defined(__clang__)) && defined(__SIZEOF_INT128__)
   using Type = __int128_t;
 #else
   using Type = UnsupportedType;
 #endif
 };

 // TODO no mapping to host types are defined currently for 16bits float
 // It should be defined when gcc/clang have a better support for it.

 template <>
 struct HostTypeHelper<
     Type<TypeCategory::Real, common::RealKindForPrecision(24)>> {
   // IEEE 754 32bits
   using Type = std::conditional_t<sizeof(float) == 4 &&
           std::numeric_limits<float>::is_iec559,
       float, UnsupportedType>;
 };

 template <>
 struct HostTypeHelper<
     Type<TypeCategory::Real, common::RealKindForPrecision(53)>> {
   // IEEE 754 64bits
   using Type = std::conditional_t<sizeof(double) == 8 &&
           std::numeric_limits<double>::is_iec559,
       double, UnsupportedType>;
 };

 template <>
 struct HostTypeHelper<
     Type<TypeCategory::Real, common::RealKindForPrecision(64)>> {
   // X87 80bits
   using Type = std::conditional_t<sizeof(long double) >= 10 &&
           std::numeric_limits<long double>::digits == 64 &&
           std::numeric_limits<long double>::max_exponent == 16384,
       long double, UnsupportedType>;
 };

 template <>
 struct HostTypeHelper<
     Type<TypeCategory::Real, common::RealKindForPrecision(113)>> {
   // IEEE 754 128bits
   using Type = std::conditional_t<sizeof(long double) == 16 &&
           std::numeric_limits<long double>::digits == 113 &&
           std::numeric_limits<long double>::max_exponent == 16384,
       long double, UnsupportedType>;
 };

 template <int KIND> struct HostTypeHelper<Type<TypeCategory::Complex, KIND>> {
   using RealT = Fortran::evaluate::Type<TypeCategory::Real, KIND>;
   using Type = std::conditional_t<HostTypeExists<RealT>(),
       std::complex<HostType<RealT>>, UnsupportedType>;
 };

 template <int KIND> struct HostTypeHelper<Type<TypeCategory::Logical, KIND>> {
   using Type = std::conditional_t<KIND <= 8, std::uint8_t, UnsupportedType>;
 };

 template <int KIND> struct HostTypeHelper<Type<TypeCategory::Character, KIND>> {
   using Type =
       Scalar<typename Fortran::evaluate::Type<TypeCategory::Character, KIND>>;
 };

 // Type mapping from host types to F18 types. This need to be placed after all
 // HostTypeHelper specializations.
 template <typename T, typename... TT> struct IndexInTupleHelper {};
 template <typename T, typename... TT>
 struct IndexInTupleHelper<T, std::tuple<TT...>> {
   static constexpr int value{common::TypeIndex<T, TT...>};
 };
 struct UnknownType {}; // the host type does not match any F18 types
 template <typename HOST_T> struct FortranTypeHelper {
   using HostTypeMapping =
       common::MapTemplate<HostType, AllIntrinsicTypes, std::tuple>;
   static constexpr int index{
       IndexInTupleHelper<HOST_T, HostTypeMapping>::value};
   // Both conditional types are "instantiated", so a valid type must be
   // created for invalid index even if not used.
   using Type = std::conditional_t<index >= 0,
       std::tuple_element_t<(index >= 0) ? index : 0, AllIntrinsicTypes>,
       UnknownType>;
 };

 template <typename HOST_T>
 using FortranType = typename FortranTypeHelper<HOST_T>::Type;

 template <typename... HT> constexpr inline bool FortranTypeExists() {
   return (... && (!std::is_same_v<FortranType<HT>, UnknownType>));
 }

 } // namespace host
 } // namespace Fortran::evaluate

 #endif // FORTRAN_EVALUATE_HOST_H_
	//===-- lib/Evaluate/host.h -------------------------------------- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#ifndef FORTRAN_EVALUATE_HOST_H_
	#define FORTRAN_EVALUATE_HOST_H_

	// Define a compile-time mapping between Fortran intrinsic types and host
	// hardware types if possible. The purpose is to avoid having to do any kind of
	// assumption on whether a "float" matches the Scalar<Type<TypeCategory::Real,
	// 4>> outside of this header. The main tools are HostTypeExists<T> and
	// HostType<T>. HostTypeExists<T>() will return true if and only if a host
	// hardware type maps to Fortran intrinsic type T. Then HostType<T> can be used
	// to safely refer to this hardware type.

	#include "flang/Evaluate/type.h"
	#include <cfenv>
	#include <complex>
	#include <cstdint>
	#include <limits>
	#include <string>
	#include <type_traits>

	namespace Fortran::evaluate {
	namespace host {

	// Helper class to handle host runtime traps, status flag and errno
	class HostFloatingPointEnvironment {
	public:
	void SetUpHostFloatingPointEnvironment(FoldingContext &);
	void CheckAndRestoreFloatingPointEnvironment(FoldingContext &);
	bool hasSubnormalFlushingHardwareControl() const {
	return hasSubnormalFlushingHardwareControl_;
	}
	void SetFlag(RealFlag flag) { flags_.set(flag); }
	bool hardwareFlagsAreReliable() const { return hardwareFlagsAreReliable_; }

	private:
	std::fenv_t originalFenv_;
	#if __x86_64__
	unsigned int originalMxcsr;
	#endif
	RealFlags flags_;
	bool hasSubnormalFlushingHardwareControl_{false};
	bool hardwareFlagsAreReliable_{true};
	};

	// Type mapping from F18 types to host types
	struct UnsupportedType {}; // There is no host type for the F18 type

	template <typename FTN_T> struct HostTypeHelper {
	using Type = UnsupportedType;
	};
	template <typename FTN_T> using HostType = typename HostTypeHelper<FTN_T>::Type;

	template <typename... T> constexpr inline bool HostTypeExists() {
	return (... && (!std::is_same_v<HostType<T>, UnsupportedType>));
	}

	// Type mapping from host types to F18 types FortranType<HOST_T> is defined
	// after all HosTypeHelper definition because it reverses them to avoid
	// duplication.

	// Scalar conversion utilities from host scalars to F18 scalars
	template <typename FTN_T>
	inline constexpr Scalar<FTN_T> CastHostToFortran(const HostType<FTN_T> &x) {
	static_assert(HostTypeExists<FTN_T>());
	if constexpr (FTN_T::category == TypeCategory::Complex &&
	sizeof(Scalar<FTN_T>) != sizeof(HostType<FTN_T>)) {
	// X87 is usually padded to 12 or 16bytes. Need to cast piecewise for
	// complex
	return Scalar<FTN_T>{CastHostToFortran<typename FTN_T::Part>(std::real(x)),
	CastHostToFortran<typename FTN_T::Part>(std::imag(x))};
	} else {
	return reinterpret_cast<const Scalar<FTN_T> >(&x);
	}
	}

	// Scalar conversion utilities from F18 scalars to host scalars
	template <typename FTN_T>
	inline constexpr HostType<FTN_T> CastFortranToHost(const Scalar<FTN_T> &x) {
	static_assert(HostTypeExists<FTN_T>());
	if constexpr (FTN_T::category == TypeCategory::Complex &&
	sizeof(Scalar<FTN_T>) != sizeof(HostType<FTN_T>)) {
	// X87 is usually padded to 12 or 16bytes. Need to cast piecewise for
	// complex
	return HostType<FTN_T>{CastFortranToHost<typename FTN_T::Part>(x.REAL()),
	CastFortranToHost<typename FTN_T::Part>(x.AIMAG())};
	} else {
	return reinterpret_cast<const HostType<FTN_T> >(&x);
	}
	}

	// Defining the actual mapping
	template <> struct HostTypeHelper<Type<TypeCategory::Integer, 1>> {
	using Type = std::int8_t;
	};

	template <> struct HostTypeHelper<Type<TypeCategory::Integer, 2>> {
	using Type = std::int16_t;
	};

	template <> struct HostTypeHelper<Type<TypeCategory::Integer, 4>> {
	using Type = std::int32_t;
	};

	template <> struct HostTypeHelper<Type<TypeCategory::Integer, 8>> {
	using Type = std::int64_t;
	};

	template <> struct HostTypeHelper<Type<TypeCategory::Integer, 16>> {
	#if (defined(__GNUC__) \|\| defined(__clang__)) && defined(__SIZEOF_INT128__)
	using Type = __int128_t;
	#else
	using Type = UnsupportedType;
	#endif
	};

	// TODO no mapping to host types are defined currently for 16bits float
	// It should be defined when gcc/clang have a better support for it.

	template <>
	struct HostTypeHelper<
	Type<TypeCategory::Real, common::RealKindForPrecision(24)>> {
	// IEEE 754 32bits
	using Type = std::conditional_t<sizeof(float) == 4 &&
	std::numeric_limits<float>::is_iec559,
	float, UnsupportedType>;
	};

	template <>
	struct HostTypeHelper<
	Type<TypeCategory::Real, common::RealKindForPrecision(53)>> {
	// IEEE 754 64bits
	using Type = std::conditional_t<sizeof(double) == 8 &&
	std::numeric_limits<double>::is_iec559,
	double, UnsupportedType>;
	};

	template <>
	struct HostTypeHelper<
	Type<TypeCategory::Real, common::RealKindForPrecision(64)>> {
	// X87 80bits
	using Type = std::conditional_t<sizeof(long double) >= 10 &&
	std::numeric_limits<long double>::digits == 64 &&
	std::numeric_limits<long double>::max_exponent == 16384,
	long double, UnsupportedType>;
	};

	template <>
	struct HostTypeHelper<
	Type<TypeCategory::Real, common::RealKindForPrecision(113)>> {
	// IEEE 754 128bits
	using Type = std::conditional_t<sizeof(long double) == 16 &&
	std::numeric_limits<long double>::digits == 113 &&
	std::numeric_limits<long double>::max_exponent == 16384,
	long double, UnsupportedType>;
	};

	template <int KIND> struct HostTypeHelper<Type<TypeCategory::Complex, KIND>> {
	using RealT = Fortran::evaluate::Type<TypeCategory::Real, KIND>;
	using Type = std::conditional_t<HostTypeExists<RealT>(),
	std::complex<HostType<RealT>>, UnsupportedType>;
	};

	template <int KIND> struct HostTypeHelper<Type<TypeCategory::Logical, KIND>> {
	using Type = std::conditional_t<KIND <= 8, std::uint8_t, UnsupportedType>;
	};

	template <int KIND> struct HostTypeHelper<Type<TypeCategory::Character, KIND>> {
	using Type =
	Scalar<typename Fortran::evaluate::Type<TypeCategory::Character, KIND>>;
	};

	// Type mapping from host types to F18 types. This need to be placed after all
	// HostTypeHelper specializations.
	template <typename T, typename... TT> struct IndexInTupleHelper {};
	template <typename T, typename... TT>
	struct IndexInTupleHelper<T, std::tuple<TT...>> {
	static constexpr int value{common::TypeIndex<T, TT...>};
	};
	struct UnknownType {}; // the host type does not match any F18 types
	template <typename HOST_T> struct FortranTypeHelper {
	using HostTypeMapping =
	common::MapTemplate<HostType, AllIntrinsicTypes, std::tuple>;
	static constexpr int index{
	IndexInTupleHelper<HOST_T, HostTypeMapping>::value};
	// Both conditional types are "instantiated", so a valid type must be
	// created for invalid index even if not used.
	using Type = std::conditional_t<index >= 0,
	std::tuple_element_t<(index >= 0) ? index : 0, AllIntrinsicTypes>,
	UnknownType>;
	};

	template <typename HOST_T>
	using FortranType = typename FortranTypeHelper<HOST_T>::Type;

	template <typename... HT> constexpr inline bool FortranTypeExists() {
	return (... && (!std::is_same_v<FortranType<HT>, UnknownType>));
	}

	} // namespace host
	} // namespace Fortran::evaluate

	#endif // FORTRAN_EVALUATE_HOST_H_