1 //===-- lib/Evaluate/host.h -------------------------------------*- C++ -*-===//
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
7 //===----------------------------------------------------------------------===//
9 #ifndef FORTRAN_EVALUATE_HOST_H_
10 #define FORTRAN_EVALUATE_HOST_H_
12 // Define a compile-time mapping between Fortran intrinsic types and host
13 // hardware types if possible. The purpose is to avoid having to do any kind of
14 // assumption on whether a "float" matches the Scalar<Type<TypeCategory::Real,
15 // 4>> outside of this header. The main tools are HostTypeExists<T> and
16 // HostType<T>. HostTypeExists<T>() will return true if and only if a host
17 // hardware type maps to Fortran intrinsic type T. Then HostType<T> can be used
18 // to safely refer to this hardware type.
22 #include "flang/Common/float128.h"
24 #include "flang/Evaluate/type.h"
30 #include <type_traits>
32 namespace Fortran::evaluate
{
35 // Helper class to handle host runtime traps, status flag and errno
36 class HostFloatingPointEnvironment
{
38 void SetUpHostFloatingPointEnvironment(FoldingContext
&);
39 void CheckAndRestoreFloatingPointEnvironment(FoldingContext
&);
40 bool hasSubnormalFlushingHardwareControl() const {
41 return hasSubnormalFlushingHardwareControl_
;
43 void SetFlag(RealFlag flag
) { flags_
.set(flag
); }
44 bool hardwareFlagsAreReliable() const { return hardwareFlagsAreReliable_
; }
47 std::fenv_t originalFenv_
;
49 unsigned int originalMxcsr
;
52 bool hasSubnormalFlushingHardwareControl_
{false};
53 bool hardwareFlagsAreReliable_
{true};
56 // Type mapping from F18 types to host types
57 struct UnsupportedType
{}; // There is no host type for the F18 type
59 template <typename FTN_T
> struct HostTypeHelper
{
60 using Type
= UnsupportedType
;
62 template <typename FTN_T
> using HostType
= typename HostTypeHelper
<FTN_T
>::Type
;
64 template <typename
... T
> constexpr inline bool HostTypeExists() {
65 return (... && (!std::is_same_v
<HostType
<T
>, UnsupportedType
>));
68 // Type mapping from host types to F18 types FortranType<HOST_T> is defined
69 // after all HosTypeHelper definition because it reverses them to avoid
72 // Scalar conversion utilities from host scalars to F18 scalars
73 template <typename FTN_T
>
74 inline constexpr Scalar
<FTN_T
> CastHostToFortran(const HostType
<FTN_T
> &x
) {
75 static_assert(HostTypeExists
<FTN_T
>());
76 if constexpr (FTN_T::category
== TypeCategory::Complex
&&
77 sizeof(Scalar
<FTN_T
>) != sizeof(HostType
<FTN_T
>)) {
78 // X87 is usually padded to 12 or 16bytes. Need to cast piecewise for
80 return Scalar
<FTN_T
>{CastHostToFortran
<typename
FTN_T::Part
>(std::real(x
)),
81 CastHostToFortran
<typename
FTN_T::Part
>(std::imag(x
))};
83 return *reinterpret_cast<const Scalar
<FTN_T
> *>(&x
);
87 // Scalar conversion utilities from F18 scalars to host scalars.
88 template <typename FTN_T
>
89 inline constexpr HostType
<FTN_T
> CastFortranToHost(const Scalar
<FTN_T
> &x
) {
90 static_assert(HostTypeExists
<FTN_T
>());
91 if constexpr (FTN_T::category
== TypeCategory::Complex
) {
92 using FortranPartType
= typename
FTN_T::Part
;
93 return HostType
<FTN_T
>{CastFortranToHost
<FortranPartType
>(x
.REAL()),
94 CastFortranToHost
<FortranPartType
>(x
.AIMAG())};
95 } else if constexpr (std::is_same_v
<FTN_T
, Type
<TypeCategory::Real
, 10>>) {
96 // x87 80-bit floating-point occupies 16 bytes as a C "long double";
97 // copy the data to avoid a legitimate (but benign due to little-endianness)
98 // warning from GCC >= 11.2.0.
100 std::memcpy(&y
, &x
, sizeof x
);
103 static_assert(sizeof x
== sizeof(HostType
<FTN_T
>));
104 return *reinterpret_cast<const HostType
<FTN_T
> *>(&x
);
108 template <> struct HostTypeHelper
<Type
<TypeCategory::Integer
, 1>> {
109 using Type
= std::int8_t;
112 template <> struct HostTypeHelper
<Type
<TypeCategory::Integer
, 2>> {
113 using Type
= std::int16_t;
116 template <> struct HostTypeHelper
<Type
<TypeCategory::Integer
, 4>> {
117 using Type
= std::int32_t;
120 template <> struct HostTypeHelper
<Type
<TypeCategory::Integer
, 8>> {
121 using Type
= std::int64_t;
124 template <> struct HostTypeHelper
<Type
<TypeCategory::Integer
, 16>> {
125 #if (defined(__GNUC__) || defined(__clang__)) && defined(__SIZEOF_INT128__)
126 using Type
= __int128_t
;
128 using Type
= UnsupportedType
;
132 // TODO no mapping to host types are defined currently for 16bits float
133 // It should be defined when gcc/clang have a better support for it.
136 struct HostTypeHelper
<
137 Type
<TypeCategory::Real
, common::RealKindForPrecision(24)>> {
139 using Type
= std::conditional_t
<sizeof(float) == 4 &&
140 std::numeric_limits
<float>::is_iec559
,
141 float, UnsupportedType
>;
145 struct HostTypeHelper
<
146 Type
<TypeCategory::Real
, common::RealKindForPrecision(53)>> {
148 using Type
= std::conditional_t
<sizeof(double) == 8 &&
149 std::numeric_limits
<double>::is_iec559
,
150 double, UnsupportedType
>;
154 struct HostTypeHelper
<
155 Type
<TypeCategory::Real
, common::RealKindForPrecision(64)>> {
157 using Type
= std::conditional_t
<sizeof(long double) >= 10 &&
158 std::numeric_limits
<long double>::digits
== 64 &&
159 std::numeric_limits
<long double>::max_exponent
== 16384,
160 long double, UnsupportedType
>;
164 template <> struct HostTypeHelper
<Type
<TypeCategory::Real
, 16>> {
166 using Type
= __float128
;
169 template <> struct HostTypeHelper
<Type
<TypeCategory::Real
, 16>> {
171 using Type
= std::conditional_t
<sizeof(long double) == 16 &&
172 std::numeric_limits
<long double>::digits
== 113 &&
173 std::numeric_limits
<long double>::max_exponent
== 16384,
174 long double, UnsupportedType
>;
178 template <int KIND
> struct HostTypeHelper
<Type
<TypeCategory::Complex
, KIND
>> {
179 using RealT
= Fortran::evaluate::Type
<TypeCategory::Real
, KIND
>;
180 using Type
= std::conditional_t
<HostTypeExists
<RealT
>(),
181 std::complex<HostType
<RealT
>>, UnsupportedType
>;
185 template <> struct HostTypeHelper
<Type
<TypeCategory::Complex
, 16>> {
186 using RealT
= Fortran::evaluate::Type
<TypeCategory::Real
, 16>;
187 using Type
= __complex128
;
191 template <int KIND
> struct HostTypeHelper
<Type
<TypeCategory::Logical
, KIND
>> {
192 using Type
= std::conditional_t
<KIND
<= 8, std::uint8_t, UnsupportedType
>;
195 template <int KIND
> struct HostTypeHelper
<Type
<TypeCategory::Character
, KIND
>> {
197 Scalar
<typename
Fortran::evaluate::Type
<TypeCategory::Character
, KIND
>>;
200 // Type mapping from host types to F18 types. This need to be placed after all
201 // HostTypeHelper specializations.
202 template <typename T
, typename
... TT
> struct IndexInTupleHelper
{};
203 template <typename T
, typename
... TT
>
204 struct IndexInTupleHelper
<T
, std::tuple
<TT
...>> {
205 static constexpr int value
{common::TypeIndex
<T
, TT
...>};
207 struct UnknownType
{}; // the host type does not match any F18 types
208 template <typename HOST_T
> struct FortranTypeHelper
{
209 using HostTypeMapping
=
210 common::MapTemplate
<HostType
, AllIntrinsicTypes
, std::tuple
>;
211 static constexpr int index
{
212 IndexInTupleHelper
<HOST_T
, HostTypeMapping
>::value
};
213 // Both conditional types are "instantiated", so a valid type must be
214 // created for invalid index even if not used.
215 using Type
= std::conditional_t
<index
>= 0,
216 std::tuple_element_t
<(index
>= 0) ? index
: 0, AllIntrinsicTypes
>,
220 template <typename HOST_T
>
221 using FortranType
= typename FortranTypeHelper
<HOST_T
>::Type
;
223 template <typename
... HT
> constexpr inline bool FortranTypeExists() {
224 return (... && (!std::is_same_v
<FortranType
<HT
>, UnknownType
>));
228 } // namespace Fortran::evaluate
230 #endif // FORTRAN_EVALUATE_HOST_H_
