//===-- runtime/allocatable.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 // //===----------------------------------------------------------------------===// #include "flang/Runtime/allocatable.h" #include "derived.h" #include "stat.h" #include "terminator.h" #include "type-info.h" #include "flang/Runtime/assign.h" namespace Fortran::runtime { extern "C" { void RTNAME(AllocatableInitIntrinsic)(Descriptor &descriptor, TypeCategory category, int kind, int rank, int corank) { INTERNAL_CHECK(corank == 0); descriptor.Establish(TypeCode{category, kind}, Descriptor::BytesFor(category, kind), nullptr, rank, nullptr, CFI_attribute_allocatable); } void RTNAME(AllocatableInitCharacter)(Descriptor &descriptor, SubscriptValue length, int kind, int rank, int corank) { INTERNAL_CHECK(corank == 0); descriptor.Establish( kind, length, nullptr, rank, nullptr, CFI_attribute_allocatable); } void RTNAME(AllocatableInitDerived)(Descriptor &descriptor, const typeInfo::DerivedType &derivedType, int rank, int corank) { INTERNAL_CHECK(corank == 0); descriptor.Establish( derivedType, nullptr, rank, nullptr, CFI_attribute_allocatable); } int RTNAME(MoveAlloc)(Descriptor &to, const Descriptor & /*from*/, bool /*hasStat*/, const Descriptor * /*errMsg*/, const char * /*sourceFile*/, int /*sourceLine*/) { INTERNAL_CHECK(false); // TODO: MoveAlloc is not yet implemented return StatOk; } void RTNAME(AllocatableSetBounds)(Descriptor &descriptor, int zeroBasedDim, SubscriptValue lower, SubscriptValue upper) { INTERNAL_CHECK(zeroBasedDim >= 0 && zeroBasedDim < descriptor.rank()); descriptor.GetDimension(zeroBasedDim).SetBounds(lower, upper); // The byte strides are computed when the object is allocated. } void RTNAME(AllocatableSetDerivedLength)( Descriptor &descriptor, int which, SubscriptValue x) { DescriptorAddendum *addendum{descriptor.Addendum()}; INTERNAL_CHECK(addendum != nullptr); addendum->SetLenParameterValue(which, x); } void RTNAME(AllocatableApplyMold)( Descriptor &descriptor, const Descriptor &mold) { descriptor = mold; descriptor.set_base_addr(nullptr); descriptor.raw().attribute = CFI_attribute_allocatable; } int RTNAME(AllocatableAllocate)(Descriptor &descriptor, bool hasStat, const Descriptor *errMsg, const char *sourceFile, int sourceLine) { Terminator terminator{sourceFile, sourceLine}; if (!descriptor.IsAllocatable()) { return ReturnError(terminator, StatInvalidDescriptor, errMsg, hasStat); } if (descriptor.IsAllocated()) { return ReturnError(terminator, StatBaseNotNull, errMsg, hasStat); } int stat{ReturnError(terminator, descriptor.Allocate(), errMsg, hasStat)}; if (stat == StatOk) { if (const DescriptorAddendum * addendum{descriptor.Addendum()}) { if (const auto *derived{addendum->derivedType()}) { if (!derived->noInitializationNeeded()) { stat = Initialize(descriptor, *derived, terminator, hasStat, errMsg); } } } } return stat; } int RTNAME(AllocatableDeallocate)(Descriptor &descriptor, bool hasStat, const Descriptor *errMsg, const char *sourceFile, int sourceLine) { Terminator terminator{sourceFile, sourceLine}; if (!descriptor.IsAllocatable()) { return ReturnError(terminator, StatInvalidDescriptor, errMsg, hasStat); } if (!descriptor.IsAllocated()) { return ReturnError(terminator, StatBaseNull, errMsg, hasStat); } return ReturnError(terminator, descriptor.Destroy(true), errMsg, hasStat); } void RTNAME(AllocatableDeallocateNoFinal)( Descriptor &descriptor, const char *sourceFile, int sourceLine) { Terminator terminator{sourceFile, sourceLine}; if (!descriptor.IsAllocatable()) { ReturnError(terminator, StatInvalidDescriptor); } else if (!descriptor.IsAllocated()) { ReturnError(terminator, StatBaseNull); } else { ReturnError(terminator, descriptor.Destroy(false)); } } // TODO: AllocatableCheckLengthParameter, AllocatableAllocateSource } } // namespace Fortran::runtime