flang/lib/Optimizer/CodeGen/DescriptorModel.h - llvm-project - Git at Google

 //===-- DescriptorModel.h -- model of descriptors for codegen ---*- 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
 //
 //===----------------------------------------------------------------------===//
 // LLVM IR dialect models of C++ types.
 //
 // This supplies a set of model builders to decompose the C declaration of a
 // descriptor (as encoded in ISO_Fortran_binding.h and elsewhere) and
 // reconstruct that type in the LLVM IR dialect.
 //
 // TODO: It is understood that this is deeply incorrect as far as building a
 // portability layer for cross-compilation as these reflected types are those of
 // the build machine and not necessarily that of either the host or the target.
 // This assumption that build == host == target is actually pervasive across the
 // compiler (https://llvm.org/PR52418).
 //
 //===----------------------------------------------------------------------===//

 #ifndef OPTIMIZER_DESCRIPTOR_MODEL_H
 #define OPTIMIZER_DESCRIPTOR_MODEL_H

 #include "flang/ISO_Fortran_binding.h"
 #include "flang/Runtime/descriptor.h"
 #include "mlir/Dialect/LLVMIR/LLVMTypes.h"
 #include "llvm/Support/ErrorHandling.h"
 #include <tuple>

 namespace fir {

 using TypeBuilderFunc = mlir::Type (*)(mlir::MLIRContext *);

 /// Get the LLVM IR dialect model for building a particular C++ type, `T`.
 template <typename T>
 TypeBuilderFunc getModel();

 template <>
 TypeBuilderFunc getModel<void *>() {
   return [](mlir::MLIRContext *context) -> mlir::Type {
     return mlir::LLVM::LLVMPointerType::get(mlir::IntegerType::get(context, 8));
   };
 }
 template <>
 TypeBuilderFunc getModel<unsigned>() {
   return [](mlir::MLIRContext *context) -> mlir::Type {
     return mlir::IntegerType::get(context, sizeof(unsigned) * 8);
   };
 }
 template <>
 TypeBuilderFunc getModel<int>() {
   return [](mlir::MLIRContext *context) -> mlir::Type {
     return mlir::IntegerType::get(context, sizeof(int) * 8);
   };
 }
 template <>
 TypeBuilderFunc getModel<unsigned long>() {
   return [](mlir::MLIRContext *context) -> mlir::Type {
     return mlir::IntegerType::get(context, sizeof(unsigned long) * 8);
   };
 }
 template <>
 TypeBuilderFunc getModel<unsigned long long>() {
   return [](mlir::MLIRContext *context) -> mlir::Type {
     return mlir::IntegerType::get(context, sizeof(unsigned long long) * 8);
   };
 }
 template <>
 TypeBuilderFunc getModel<long long>() {
   return [](mlir::MLIRContext *context) -> mlir::Type {
     return mlir::IntegerType::get(context, sizeof(long long) * 8);
   };
 }
 template <>
 TypeBuilderFunc getModel<Fortran::ISO::CFI_rank_t>() {
   return [](mlir::MLIRContext *context) -> mlir::Type {
     return mlir::IntegerType::get(context,
                                   sizeof(Fortran::ISO::CFI_rank_t) * 8);
   };
 }
 template <>
 TypeBuilderFunc getModel<Fortran::ISO::CFI_type_t>() {
   return [](mlir::MLIRContext *context) -> mlir::Type {
     return mlir::IntegerType::get(context,
                                   sizeof(Fortran::ISO::CFI_type_t) * 8);
   };
 }
 template <>
 TypeBuilderFunc getModel<long>() {
   return [](mlir::MLIRContext *context) -> mlir::Type {
     return mlir::IntegerType::get(context, sizeof(long) * 8);
   };
 }
 template <>
 TypeBuilderFunc getModel<Fortran::ISO::CFI_dim_t>() {
   return [](mlir::MLIRContext *context) -> mlir::Type {
     auto indexTy = getModel<Fortran::ISO::CFI_index_t>()(context);
     return mlir::LLVM::LLVMArrayType::get(indexTy, 3);
   };
 }
 template <>
 TypeBuilderFunc
 getModel<Fortran::ISO::cfi_internal::FlexibleArray<Fortran::ISO::CFI_dim_t>>() {
   return getModel<Fortran::ISO::CFI_dim_t>();
 }

 //===----------------------------------------------------------------------===//
 // Descriptor reflection
 //===----------------------------------------------------------------------===//

 /// Get the type model of the field number `Field` in an ISO CFI descriptor.
 template <int Field>
 static constexpr TypeBuilderFunc getDescFieldTypeModel() {
   Fortran::ISO::Fortran_2018::CFI_cdesc_t dummyDesc{};
   // check that the descriptor is exactly 8 fields as specified in CFI_cdesc_t
   // in flang/include/flang/ISO_Fortran_binding.h.
   auto [a, b, c, d, e, f, g, h] = dummyDesc;
   auto tup = std::tie(a, b, c, d, e, f, g, h);
   auto field = std::get<Field>(tup);
   return getModel<decltype(field)>();
 }

 /// An extended descriptor is defined by a class in runtime/descriptor.h. The
 /// three fields in the class are hard-coded here, unlike the reflection used on
 /// the ISO parts, which are a POD.
 template <int Field>
 static constexpr TypeBuilderFunc getExtendedDescFieldTypeModel() {
   if constexpr (Field == 8) {
     return getModel<void *>();
   } else if constexpr (Field == 9) {
     return getModel<Fortran::runtime::typeInfo::TypeParameterValue>();
   } else {
     llvm_unreachable("extended ISO descriptor only has 10 fields");
   }
 }

 } // namespace fir

 #endif // OPTIMIZER_DESCRIPTOR_MODEL_H
	//===-- DescriptorModel.h -- model of descriptors for codegen ---- 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
	//
	//===----------------------------------------------------------------------===//
	// LLVM IR dialect models of C++ types.
	//
	// This supplies a set of model builders to decompose the C declaration of a
	// descriptor (as encoded in ISO_Fortran_binding.h and elsewhere) and
	// reconstruct that type in the LLVM IR dialect.
	//
	// TODO: It is understood that this is deeply incorrect as far as building a
	// portability layer for cross-compilation as these reflected types are those of
	// the build machine and not necessarily that of either the host or the target.
	// This assumption that build == host == target is actually pervasive across the
	// compiler (https://llvm.org/PR52418).
	//
	//===----------------------------------------------------------------------===//

	#ifndef OPTIMIZER_DESCRIPTOR_MODEL_H
	#define OPTIMIZER_DESCRIPTOR_MODEL_H

	#include "flang/ISO_Fortran_binding.h"
	#include "flang/Runtime/descriptor.h"
	#include "mlir/Dialect/LLVMIR/LLVMTypes.h"
	#include "llvm/Support/ErrorHandling.h"
	#include <tuple>

	namespace fir {

	using TypeBuilderFunc = mlir::Type ()(mlir::MLIRContext );

	/// Get the LLVM IR dialect model for building a particular C++ type, `T`.
	template <typename T>
	TypeBuilderFunc getModel();

	template <>
	TypeBuilderFunc getModel<void *>() {
	return [](mlir::MLIRContext *context) -> mlir::Type {
	return mlir::LLVM::LLVMPointerType::get(mlir::IntegerType::get(context, 8));
	};
	}
	template <>
	TypeBuilderFunc getModel<unsigned>() {
	return [](mlir::MLIRContext *context) -> mlir::Type {
	return mlir::IntegerType::get(context, sizeof(unsigned) * 8);
	};
	}
	template <>
	TypeBuilderFunc getModel<int>() {
	return [](mlir::MLIRContext *context) -> mlir::Type {
	return mlir::IntegerType::get(context, sizeof(int) * 8);
	};
	}
	template <>
	TypeBuilderFunc getModel<unsigned long>() {
	return [](mlir::MLIRContext *context) -> mlir::Type {
	return mlir::IntegerType::get(context, sizeof(unsigned long) * 8);
	};
	}
	template <>
	TypeBuilderFunc getModel<unsigned long long>() {
	return [](mlir::MLIRContext *context) -> mlir::Type {
	return mlir::IntegerType::get(context, sizeof(unsigned long long) * 8);
	};
	}
	template <>
	TypeBuilderFunc getModel<long long>() {
	return [](mlir::MLIRContext *context) -> mlir::Type {
	return mlir::IntegerType::get(context, sizeof(long long) * 8);
	};
	}
	template <>
	TypeBuilderFunc getModel<Fortran::ISO::CFI_rank_t>() {
	return [](mlir::MLIRContext *context) -> mlir::Type {
	return mlir::IntegerType::get(context,
	sizeof(Fortran::ISO::CFI_rank_t) * 8);
	};
	}
	template <>
	TypeBuilderFunc getModel<Fortran::ISO::CFI_type_t>() {
	return [](mlir::MLIRContext *context) -> mlir::Type {
	return mlir::IntegerType::get(context,
	sizeof(Fortran::ISO::CFI_type_t) * 8);
	};
	}
	template <>
	TypeBuilderFunc getModel<long>() {
	return [](mlir::MLIRContext *context) -> mlir::Type {
	return mlir::IntegerType::get(context, sizeof(long) * 8);
	};
	}
	template <>
	TypeBuilderFunc getModel<Fortran::ISO::CFI_dim_t>() {
	return [](mlir::MLIRContext *context) -> mlir::Type {
	auto indexTy = getModel<Fortran::ISO::CFI_index_t>()(context);
	return mlir::LLVM::LLVMArrayType::get(indexTy, 3);
	};
	}
	template <>
	TypeBuilderFunc
	getModel<Fortran::ISO::cfi_internal::FlexibleArray<Fortran::ISO::CFI_dim_t>>() {
	return getModel<Fortran::ISO::CFI_dim_t>();
	}

	//===----------------------------------------------------------------------===//
	// Descriptor reflection
	//===----------------------------------------------------------------------===//

	/// Get the type model of the field number `Field` in an ISO CFI descriptor.
	template <int Field>
	static constexpr TypeBuilderFunc getDescFieldTypeModel() {
	Fortran::ISO::Fortran_2018::CFI_cdesc_t dummyDesc{};
	// check that the descriptor is exactly 8 fields as specified in CFI_cdesc_t
	// in flang/include/flang/ISO_Fortran_binding.h.
	auto [a, b, c, d, e, f, g, h] = dummyDesc;
	auto tup = std::tie(a, b, c, d, e, f, g, h);
	auto field = std::get<Field>(tup);
	return getModel<decltype(field)>();
	}

	/// An extended descriptor is defined by a class in runtime/descriptor.h. The
	/// three fields in the class are hard-coded here, unlike the reflection used on
	/// the ISO parts, which are a POD.
	template <int Field>
	static constexpr TypeBuilderFunc getExtendedDescFieldTypeModel() {
	if constexpr (Field == 8) {
	return getModel<void *>();
	} else if constexpr (Field == 9) {
	return getModel<Fortran::runtime::typeInfo::TypeParameterValue>();
	} else {
	llvm_unreachable("extended ISO descriptor only has 10 fields");
	}
	}

	} // namespace fir

	#endif // OPTIMIZER_DESCRIPTOR_MODEL_H