| /*===-- flang/runtime/complex-reduction.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 |
| * |
| * ===-----------------------------------------------------------------------=== |
| */ |
| |
| /* Wraps the C++-coded complex-valued SUM and PRODUCT reductions with |
| * C-coded wrapper functions returning _Complex values, to avoid problems |
| * with C++ build compilers that don't support C's _Complex. |
| */ |
| |
| #ifndef FORTRAN_RUNTIME_COMPLEX_REDUCTION_H_ |
| #define FORTRAN_RUNTIME_COMPLEX_REDUCTION_H_ |
| |
| #include "flang/Common/float128.h" |
| #include "flang/Runtime/entry-names.h" |
| #include <complex.h> |
| |
| struct CppDescriptor; /* dummy type name for Fortran::runtime::Descriptor */ |
| |
| #if defined(_MSC_VER) && !(defined(__clang_major__) && __clang_major__ >= 12) |
| typedef _Fcomplex float_Complex_t; |
| typedef _Dcomplex double_Complex_t; |
| typedef _Lcomplex long_double_Complex_t; |
| #else |
| typedef float _Complex float_Complex_t; |
| typedef double _Complex double_Complex_t; |
| typedef long double _Complex long_double_Complex_t; |
| #endif |
| |
| #define REDUCTION_ARGS \ |
| const struct CppDescriptor *x, const char *source, int line, int dim /*=0*/, \ |
| const struct CppDescriptor *mask /*=NULL*/ |
| #define REDUCTION_ARG_NAMES x, source, line, dim, mask |
| |
| float_Complex_t RTNAME(SumComplex2)(REDUCTION_ARGS); |
| float_Complex_t RTNAME(SumComplex3)(REDUCTION_ARGS); |
| float_Complex_t RTNAME(SumComplex4)(REDUCTION_ARGS); |
| double_Complex_t RTNAME(SumComplex8)(REDUCTION_ARGS); |
| long_double_Complex_t RTNAME(SumComplex10)(REDUCTION_ARGS); |
| #if HAS_LDBL128 || HAS_FLOAT128 |
| CFloat128ComplexType RTNAME(SumComplex16)(REDUCTION_ARGS); |
| #endif |
| |
| float_Complex_t RTNAME(ProductComplex2)(REDUCTION_ARGS); |
| float_Complex_t RTNAME(ProductComplex3)(REDUCTION_ARGS); |
| float_Complex_t RTNAME(ProductComplex4)(REDUCTION_ARGS); |
| double_Complex_t RTNAME(ProductComplex8)(REDUCTION_ARGS); |
| long_double_Complex_t RTNAME(ProductComplex10)(REDUCTION_ARGS); |
| #if HAS_LDBL128 || HAS_FLOAT128 |
| CFloat128ComplexType RTNAME(ProductComplex16)(REDUCTION_ARGS); |
| #endif |
| |
| #define DOT_PRODUCT_ARGS \ |
| const struct CppDescriptor *x, const struct CppDescriptor *y, \ |
| const char *source, int line, int dim /*=0*/, \ |
| const struct CppDescriptor *mask /*=NULL*/ |
| #define DOT_PRODUCT_ARG_NAMES x, y, source, line, dim, mask |
| |
| float_Complex_t RTNAME(DotProductComplex2)(DOT_PRODUCT_ARGS); |
| float_Complex_t RTNAME(DotProductComplex3)(DOT_PRODUCT_ARGS); |
| float_Complex_t RTNAME(DotProductComplex4)(DOT_PRODUCT_ARGS); |
| double_Complex_t RTNAME(DotProductComplex8)(DOT_PRODUCT_ARGS); |
| long_double_Complex_t RTNAME(DotProductComplex10)(DOT_PRODUCT_ARGS); |
| #if HAS_LDBL128 || HAS_FLOAT128 |
| CFloat128ComplexType RTNAME(DotProductComplex16)(DOT_PRODUCT_ARGS); |
| #endif |
| |
| #define REDUCE_ARGS(T, OP) \ |
| OP operation, const struct CppDescriptor *x, const struct CppDescriptor *y, \ |
| const char *source, int line, int dim /*=0*/, \ |
| const struct CppDescriptor *mask /*=NULL*/, const T *identity /*=NULL*/, \ |
| _Bool ordered /*=true*/ |
| #define REDUCE_ARG_NAMES \ |
| operation, x, y, source, line, dim, mask, identity, ordered |
| |
| typedef float_Complex_t (*float_Complex_t_ref_op)( |
| const float_Complex_t *, const float_Complex_t *); |
| typedef float_Complex_t (*float_Complex_t_value_op)( |
| float_Complex_t, float_Complex_t); |
| typedef double_Complex_t (*double_Complex_t_ref_op)( |
| const double_Complex_t *, const double_Complex_t *); |
| typedef double_Complex_t (*double_Complex_t_value_op)( |
| double_Complex_t, double_Complex_t); |
| typedef long_double_Complex_t (*long_double_Complex_t_ref_op)( |
| const long_double_Complex_t *, const long_double_Complex_t *); |
| typedef long_double_Complex_t (*long_double_Complex_t_value_op)( |
| long_double_Complex_t, long_double_Complex_t); |
| |
| float_Complex_t RTNAME(ReduceComplex2Ref)( |
| REDUCE_ARGS(float_Complex_t, float_Complex_t_ref_op)); |
| float_Complex_t RTNAME(ReduceComplex2Value)( |
| REDUCE_ARGS(float_Complex_t, float_Complex_t_value_op)); |
| float_Complex_t RTNAME(ReduceComplex3Ref)( |
| REDUCE_ARGS(float_Complex_t, float_Complex_t_ref_op)); |
| float_Complex_t RTNAME(ReduceComplex3Value)( |
| REDUCE_ARGS(float_Complex_t, float_Complex_t_value_op)); |
| float_Complex_t RTNAME(ReduceComplex4Ref)( |
| REDUCE_ARGS(float_Complex_t, float_Complex_t_ref_op)); |
| float_Complex_t RTNAME(ReduceComplex4Value)( |
| REDUCE_ARGS(float_Complex_t, float_Complex_t_value_op)); |
| double_Complex_t RTNAME(ReduceComplex8Ref)( |
| REDUCE_ARGS(double_Complex_t, double_Complex_t_ref_op)); |
| double_Complex_t RTNAME(ReduceComplex8Value)( |
| REDUCE_ARGS(double_Complex_t, double_Complex_t_value_op)); |
| long_double_Complex_t RTNAME(ReduceComplex10Ref)( |
| REDUCE_ARGS(long_double_Complex_t, long_double_Complex_t_ref_op)); |
| long_double_Complex_t RTNAME(ReduceComplex10Value)( |
| REDUCE_ARGS(long_double_Complex_t, long_double_Complex_t_value_op)); |
| #if HAS_LDBL128 || HAS_FLOAT128 |
| typedef CFloat128ComplexType (*CFloat128ComplexType_ref_op)( |
| const CFloat128ComplexType *, const CFloat128ComplexType *); |
| typedef CFloat128ComplexType (*CFloat128ComplexType_value_op)( |
| CFloat128ComplexType, CFloat128ComplexType); |
| CFloat128ComplexType RTNAME(ReduceComplex16Ref)( |
| REDUCE_ARGS(CFloat128ComplexType, CFloat128ComplexType_ref_op)); |
| CFloat128ComplexType RTNAME(ReduceComplex16Value)( |
| REDUCE_ARGS(CFloat128ComplexType, CFloat128ComplexType_value_op)); |
| #endif |
| |
| #define REDUCE_DIM_ARGS(T, OP) \ |
| struct CppDescriptor *result, OP operation, const struct CppDescriptor *x, \ |
| const struct CppDescriptor *y, const char *source, int line, int dim, \ |
| const struct CppDescriptor *mask /*=NULL*/, const T *identity /*=NULL*/, \ |
| _Bool ordered /*=true*/ |
| #define REDUCE_DIM_ARG_NAMES \ |
| result, operation, x, y, source, line, dim, mask, identity, ordered |
| |
| void RTNAME(ReduceComplex2DimRef)( |
| REDUCE_DIM_ARGS(float_Complex_t, float_Complex_t_ref_op)); |
| void RTNAME(ReduceComplex2DimValue)( |
| REDUCE_DIM_ARGS(float_Complex_t, float_Complex_t_value_op)); |
| void RTNAME(ReduceComplex3DimRef)( |
| REDUCE_DIM_ARGS(float_Complex_t, float_Complex_t_ref_op)); |
| void RTNAME(ReduceComplex3DimValue)( |
| REDUCE_DIM_ARGS(float_Complex_t, float_Complex_t_value_op)); |
| void RTNAME(ReduceComplex4DimRef)( |
| REDUCE_DIM_ARGS(float_Complex_t, float_Complex_t_ref_op)); |
| void RTNAME(ReduceComplex4DimValue)( |
| REDUCE_DIM_ARGS(float_Complex_t, float_Complex_t_value_op)); |
| void RTNAME(ReduceComplex8DimRef)( |
| REDUCE_DIM_ARGS(double_Complex_t, double_Complex_t_ref_op)); |
| void RTNAME(ReduceComplex8DimValue)( |
| REDUCE_DIM_ARGS(double_Complex_t, double_Complex_t_value_op)); |
| void RTNAME(ReduceComplex10DimRef)( |
| REDUCE_DIM_ARGS(long_double_Complex_t, long_double_Complex_t_ref_op)); |
| void RTNAME(ReduceComplex10DimValue)( |
| REDUCE_DIM_ARGS(long_double_Complex_t, long_double_Complex_t_value_op)); |
| #if HAS_LDBL128 || HAS_FLOAT128 |
| void RTNAME(ReduceComplex16DimRef)( |
| REDUCE_DIM_ARGS(CFloat128ComplexType, CFloat128ComplexType_ref_op)); |
| void RTNAME(ReduceComplex16DimValue)( |
| REDUCE_DIM_ARGS(CFloat128ComplexType, CFloat128ComplexType_value_op)); |
| #endif |
| |
| #endif // FORTRAN_RUNTIME_COMPLEX_REDUCTION_H_ |