//===-- runtime/ISO_Fortran_binding.cpp -----------------------------------===// // // 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 // //===----------------------------------------------------------------------===// // Implements the required interoperability API from ISO_Fortran_binding.h // as specified in section 18.5.5 of Fortran 2018. #include "../include/flang/ISO_Fortran_binding.h" #include "descriptor.h" #include namespace Fortran::ISO { extern "C" { static inline constexpr bool IsCharacterType(CFI_type_t ty) { return ty == CFI_type_char || ty == CFI_type_char16_t || ty == CFI_type_char32_t; } static inline constexpr bool IsAssumedSize(const CFI_cdesc_t *dv) { return dv->rank > 0 && dv->dim[dv->rank - 1].extent == -1; } void *CFI_address( const CFI_cdesc_t *descriptor, const CFI_index_t subscripts[]) { char *p{static_cast(descriptor->base_addr)}; const CFI_rank_t rank{descriptor->rank}; const CFI_dim_t *dim{descriptor->dim}; for (CFI_rank_t j{0}; j < rank; ++j, ++dim) { p += (subscripts[j] - dim->lower_bound) * dim->sm; } return p; } int CFI_allocate(CFI_cdesc_t *descriptor, const CFI_index_t lower_bounds[], const CFI_index_t upper_bounds[], std::size_t elem_len) { if (!descriptor) { return CFI_INVALID_DESCRIPTOR; } if (descriptor->version != CFI_VERSION) { return CFI_INVALID_DESCRIPTOR; } if (descriptor->attribute != CFI_attribute_allocatable && descriptor->attribute != CFI_attribute_pointer) { // Non-interoperable object return CFI_INVALID_ATTRIBUTE; } if (descriptor->attribute == CFI_attribute_allocatable && descriptor->base_addr) { return CFI_ERROR_BASE_ADDR_NOT_NULL; } if (descriptor->rank > CFI_MAX_RANK) { return CFI_INVALID_RANK; } if (descriptor->type < CFI_type_signed_char || descriptor->type > CFI_type_struct) { return CFI_INVALID_TYPE; } if (!IsCharacterType(descriptor->type)) { elem_len = descriptor->elem_len; if (elem_len <= 0) { return CFI_INVALID_ELEM_LEN; } } std::size_t rank{descriptor->rank}; CFI_dim_t *dim{descriptor->dim}; std::size_t byteSize{elem_len}; for (std::size_t j{0}; j < rank; ++j, ++dim) { CFI_index_t lb{lower_bounds[j]}; CFI_index_t ub{upper_bounds[j]}; CFI_index_t extent{ub >= lb ? ub - lb + 1 : 0}; dim->lower_bound = lb; dim->extent = extent; dim->sm = byteSize; byteSize *= extent; } void *p{std::malloc(byteSize)}; if (!p && byteSize) { return CFI_ERROR_MEM_ALLOCATION; } descriptor->base_addr = p; descriptor->elem_len = elem_len; return CFI_SUCCESS; } int CFI_deallocate(CFI_cdesc_t *descriptor) { if (!descriptor) { return CFI_INVALID_DESCRIPTOR; } if (descriptor->version != CFI_VERSION) { return CFI_INVALID_DESCRIPTOR; } if (descriptor->attribute != CFI_attribute_allocatable && descriptor->attribute != CFI_attribute_pointer) { // Non-interoperable object return CFI_INVALID_DESCRIPTOR; } if (!descriptor->base_addr) { return CFI_ERROR_BASE_ADDR_NULL; } std::free(descriptor->base_addr); descriptor->base_addr = nullptr; return CFI_SUCCESS; } static constexpr std::size_t MinElemLen(CFI_type_t type) { std::size_t minElemLen{0}; switch (type) { case CFI_type_signed_char: minElemLen = sizeof(signed char); break; case CFI_type_short: minElemLen = sizeof(short); break; case CFI_type_int: minElemLen = sizeof(int); break; case CFI_type_long: minElemLen = sizeof(long); break; case CFI_type_long_long: minElemLen = sizeof(long long); break; case CFI_type_size_t: minElemLen = sizeof(std::size_t); break; case CFI_type_int8_t: minElemLen = sizeof(std::int8_t); break; case CFI_type_int16_t: minElemLen = sizeof(std::int16_t); break; case CFI_type_int32_t: minElemLen = sizeof(std::int32_t); break; case CFI_type_int64_t: minElemLen = sizeof(std::int64_t); break; case CFI_type_int128_t: minElemLen = 2 * sizeof(std::int64_t); break; case CFI_type_int_least8_t: minElemLen = sizeof(std::int_least8_t); break; case CFI_type_int_least16_t: minElemLen = sizeof(std::int_least16_t); break; case CFI_type_int_least32_t: minElemLen = sizeof(std::int_least32_t); break; case CFI_type_int_least64_t: minElemLen = sizeof(std::int_least64_t); break; case CFI_type_int_least128_t: minElemLen = 2 * sizeof(std::int_least64_t); break; case CFI_type_int_fast8_t: minElemLen = sizeof(std::int_fast8_t); break; case CFI_type_int_fast16_t: minElemLen = sizeof(std::int_fast16_t); break; case CFI_type_int_fast32_t: minElemLen = sizeof(std::int_fast32_t); break; case CFI_type_int_fast64_t: minElemLen = sizeof(std::int_fast64_t); break; case CFI_type_intmax_t: minElemLen = sizeof(std::intmax_t); break; case CFI_type_intptr_t: minElemLen = sizeof(std::intptr_t); break; case CFI_type_ptrdiff_t: minElemLen = sizeof(std::ptrdiff_t); break; case CFI_type_float: minElemLen = sizeof(float); break; case CFI_type_double: minElemLen = sizeof(double); break; case CFI_type_long_double: minElemLen = sizeof(long double); break; case CFI_type_float_Complex: minElemLen = 2 * sizeof(float); break; case CFI_type_double_Complex: minElemLen = 2 * sizeof(double); break; case CFI_type_long_double_Complex: minElemLen = 2 * sizeof(long double); break; case CFI_type_Bool: minElemLen = 1; break; case CFI_type_cptr: minElemLen = sizeof(void *); break; case CFI_type_char16_t: minElemLen = sizeof(char16_t); break; case CFI_type_char32_t: minElemLen = sizeof(char32_t); break; } return minElemLen; } int CFI_establish(CFI_cdesc_t *descriptor, void *base_addr, CFI_attribute_t attribute, CFI_type_t type, std::size_t elem_len, CFI_rank_t rank, const CFI_index_t extents[]) { if (attribute != CFI_attribute_other && attribute != CFI_attribute_pointer && attribute != CFI_attribute_allocatable) { return CFI_INVALID_ATTRIBUTE; } if (rank > CFI_MAX_RANK) { return CFI_INVALID_RANK; } if (base_addr && attribute == CFI_attribute_allocatable) { return CFI_ERROR_BASE_ADDR_NOT_NULL; } if (rank > 0 && base_addr && !extents) { return CFI_INVALID_EXTENT; } if (type < CFI_type_signed_char || type > CFI_type_struct) { return CFI_INVALID_TYPE; } if (!descriptor) { return CFI_INVALID_DESCRIPTOR; } std::size_t minElemLen{MinElemLen(type)}; if (minElemLen > 0) { elem_len = minElemLen; } else if (elem_len <= 0) { return CFI_INVALID_ELEM_LEN; } descriptor->base_addr = base_addr; descriptor->elem_len = elem_len; descriptor->version = CFI_VERSION; descriptor->rank = rank; descriptor->type = type; descriptor->attribute = attribute; descriptor->f18Addendum = 0; std::size_t byteSize{elem_len}; constexpr std::size_t lower_bound{0}; if (base_addr) { for (std::size_t j{0}; j < rank; ++j) { descriptor->dim[j].lower_bound = lower_bound; descriptor->dim[j].extent = extents[j]; descriptor->dim[j].sm = byteSize; byteSize *= extents[j]; } } return CFI_SUCCESS; } int CFI_is_contiguous(const CFI_cdesc_t *descriptor) { CFI_index_t bytes = descriptor->elem_len; for (int j{0}; j < descriptor->rank; ++j) { if (bytes != descriptor->dim[j].sm) { return 0; } bytes *= descriptor->dim[j].extent; } return 1; } int CFI_section(CFI_cdesc_t *result, const CFI_cdesc_t *source, const CFI_index_t lower_bounds[], const CFI_index_t upper_bounds[], const CFI_index_t strides[]) { CFI_index_t extent[CFI_MAX_RANK]; CFI_index_t actualStride[CFI_MAX_RANK]; CFI_rank_t resRank{0}; if (!result || !source) { return CFI_INVALID_DESCRIPTOR; } if (source->rank == 0) { return CFI_INVALID_RANK; } if (IsAssumedSize(source) && !upper_bounds) { return CFI_INVALID_DESCRIPTOR; } if ((result->type != source->type) || (result->elem_len != source->elem_len)) { return CFI_INVALID_DESCRIPTOR; } if (result->attribute == CFI_attribute_allocatable) { return CFI_INVALID_ATTRIBUTE; } if (!source->base_addr) { return CFI_ERROR_BASE_ADDR_NULL; } char *shiftedBaseAddr{static_cast(source->base_addr)}; bool isZeroSized{false}; for (int j{0}; j < source->rank; ++j) { const CFI_dim_t &dim{source->dim[j]}; const CFI_index_t srcLB{dim.lower_bound}; const CFI_index_t srcUB{srcLB + dim.extent - 1}; const CFI_index_t lb{lower_bounds ? lower_bounds[j] : srcLB}; const CFI_index_t ub{upper_bounds ? upper_bounds[j] : srcUB}; const CFI_index_t stride{strides ? strides[j] : 1}; if (stride == 0 && lb != ub) { return CFI_ERROR_OUT_OF_BOUNDS; } if ((lb <= ub && stride >= 0) || (lb >= ub && stride < 0)) { if ((lb < srcLB) || (lb > srcUB) || (ub < srcLB) || (ub > srcUB)) { return CFI_ERROR_OUT_OF_BOUNDS; } shiftedBaseAddr += (lb - srcLB) * dim.sm; extent[j] = stride != 0 ? 1 + (ub - lb) / stride : 1; } else { isZeroSized = true; extent[j] = 0; } actualStride[j] = stride; resRank += (stride != 0); } if (resRank != result->rank) { return CFI_INVALID_DESCRIPTOR; } // For zero-sized arrays, base_addr is processor-dependent (see 18.5.3). // We keep it on the source base_addr result->base_addr = isZeroSized ? source->base_addr : shiftedBaseAddr; resRank = 0; for (int j{0}; j < source->rank; ++j) { if (actualStride[j] != 0) { result->dim[resRank].lower_bound = 0; result->dim[resRank].extent = extent[j]; result->dim[resRank].sm = actualStride[j] * source->dim[j].sm; ++resRank; } } return CFI_SUCCESS; } int CFI_select_part(CFI_cdesc_t *result, const CFI_cdesc_t *source, std::size_t displacement, std::size_t elem_len) { if (!result || !source) { return CFI_INVALID_DESCRIPTOR; } if (result->rank != source->rank) { return CFI_INVALID_RANK; } if (result->attribute == CFI_attribute_allocatable) { return CFI_INVALID_ATTRIBUTE; } if (!source->base_addr) { return CFI_ERROR_BASE_ADDR_NULL; } if (IsAssumedSize(source)) { return CFI_INVALID_DESCRIPTOR; } if (!IsCharacterType(result->type)) { elem_len = result->elem_len; } if (displacement + elem_len > source->elem_len) { return CFI_INVALID_ELEM_LEN; } result->base_addr = displacement + static_cast(source->base_addr); result->elem_len = elem_len; for (int j{0}; j < source->rank; ++j) { result->dim[j].lower_bound = 0; result->dim[j].extent = source->dim[j].extent; result->dim[j].sm = source->dim[j].sm; } return CFI_SUCCESS; } int CFI_setpointer(CFI_cdesc_t *result, const CFI_cdesc_t *source, const CFI_index_t lower_bounds[]) { if (!result) { return CFI_INVALID_DESCRIPTOR; } if (result->attribute != CFI_attribute_pointer) { return CFI_INVALID_ATTRIBUTE; } if (!source) { result->base_addr = nullptr; return CFI_SUCCESS; } if (source->rank != result->rank) { return CFI_INVALID_RANK; } if (source->type != result->type) { return CFI_INVALID_TYPE; } if (source->elem_len != result->elem_len) { return CFI_INVALID_ELEM_LEN; } if (!source->base_addr && source->attribute != CFI_attribute_pointer) { return CFI_ERROR_BASE_ADDR_NULL; } if (IsAssumedSize(source)) { return CFI_INVALID_DESCRIPTOR; } const bool copySrcLB{!lower_bounds}; result->base_addr = source->base_addr; if (source->base_addr) { for (int j{0}; j < result->rank; ++j) { result->dim[j].extent = source->dim[j].extent; result->dim[j].sm = source->dim[j].sm; result->dim[j].lower_bound = copySrcLB ? source->dim[j].lower_bound : lower_bounds[j]; } } return CFI_SUCCESS; } } // extern "C" } // namespace Fortran::ISO