flang/runtime/descriptor.cpp - llvm-project - Git at Google

 //===-- runtime/descriptor.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/descriptor.h"
 #include "derived.h"
 #include "memory.h"
 #include "stat.h"
 #include "terminator.h"
 #include "type-info.h"
 #include <cassert>
 #include <cstdlib>
 #include <cstring>

 namespace Fortran::runtime {

 Descriptor::Descriptor(const Descriptor &that) { *this = that; }

 Descriptor &Descriptor::operator=(const Descriptor &that) {
   std::memcpy(this, &that, that.SizeInBytes());
   return *this;
 }

 void Descriptor::Establish(TypeCode t, std::size_t elementBytes, void *p,
     int rank, const SubscriptValue *extent, ISO::CFI_attribute_t attribute,
     bool addendum) {
   Terminator terminator{__FILE__, __LINE__};
   // Subtle: the standard CFI_establish() function doesn't allow a zero
   // elem_len argument in cases where elem_len is not ignored; and when it
   // returns an error code (CFI_INVALID_ELEM_LEN in this case), it must not
   // modify the descriptor.  That design makes sense, maybe, for actual
   // C interoperability, but we need to work around it here.  A zero
   // incoming element length is replaced by 4 so that it will be valid
   // for all CHARACTER kinds.
   std::size_t workaroundElemLen{elementBytes ? elementBytes : 4};
   int cfiStatus{ISO::CFI_establish(
       &raw_, p, attribute, t.raw(), workaroundElemLen, rank, extent)};
   if (cfiStatus != CFI_SUCCESS) {
     terminator.Crash(
         "Descriptor::Establish: CFI_establish returned %d", cfiStatus, t.raw());
   }
   if (elementBytes == 0) {
     raw_.elem_len = 0;
     for (int j{0}; j < rank; ++j) {
       GetDimension(j).SetByteStride(0);
     }
   }
   raw_.f18Addendum = addendum;
   DescriptorAddendum *a{Addendum()};
   RUNTIME_CHECK(terminator, addendum == (a != nullptr));
   if (a) {
     new (a) DescriptorAddendum{};
   }
 }

 void Descriptor::Establish(TypeCategory c, int kind, void *p, int rank,
     const SubscriptValue *extent, ISO::CFI_attribute_t attribute,
     bool addendum) {
   Establish(TypeCode(c, kind), BytesFor(c, kind), p, rank, extent, attribute,
       addendum);
 }

 void Descriptor::Establish(int characterKind, std::size_t characters, void *p,
     int rank, const SubscriptValue *extent, ISO::CFI_attribute_t attribute,
     bool addendum) {
   Establish(TypeCode{TypeCategory::Character, characterKind},
       characterKind * characters, p, rank, extent, attribute, addendum);
 }

 void Descriptor::Establish(const typeInfo::DerivedType &dt, void *p, int rank,
     const SubscriptValue *extent, ISO::CFI_attribute_t attribute) {
   Establish(TypeCode{TypeCategory::Derived, 0}, dt.sizeInBytes(), p, rank,
       extent, attribute, true);
   DescriptorAddendum *a{Addendum()};
   Terminator terminator{__FILE__, __LINE__};
   RUNTIME_CHECK(terminator, a != nullptr);
   new (a) DescriptorAddendum{&dt};
 }

 OwningPtr<Descriptor> Descriptor::Create(TypeCode t, std::size_t elementBytes,
     void *p, int rank, const SubscriptValue *extent,
     ISO::CFI_attribute_t attribute, int derivedTypeLenParameters) {
   std::size_t bytes{SizeInBytes(rank, true, derivedTypeLenParameters)};
   Terminator terminator{__FILE__, __LINE__};
   Descriptor *result{
       reinterpret_cast<Descriptor *>(AllocateMemoryOrCrash(terminator, bytes))};
   result->Establish(t, elementBytes, p, rank, extent, attribute, true);
   return OwningPtr<Descriptor>{result};
 }

 OwningPtr<Descriptor> Descriptor::Create(TypeCategory c, int kind, void *p,
     int rank, const SubscriptValue *extent, ISO::CFI_attribute_t attribute) {
   return Create(
       TypeCode(c, kind), BytesFor(c, kind), p, rank, extent, attribute);
 }

 OwningPtr<Descriptor> Descriptor::Create(int characterKind,
     SubscriptValue characters, void *p, int rank, const SubscriptValue *extent,
     ISO::CFI_attribute_t attribute) {
   return Create(TypeCode{TypeCategory::Character, characterKind},
       characterKind * characters, p, rank, extent, attribute);
 }

 OwningPtr<Descriptor> Descriptor::Create(const typeInfo::DerivedType &dt,
     void *p, int rank, const SubscriptValue *extent,
     ISO::CFI_attribute_t attribute) {
   return Create(TypeCode{TypeCategory::Derived, 0}, dt.sizeInBytes(), p, rank,
       extent, attribute, dt.LenParameters());
 }

 std::size_t Descriptor::SizeInBytes() const {
   const DescriptorAddendum *addendum{Addendum()};
   return sizeof *this - sizeof(Dimension) + raw_.rank * sizeof(Dimension) +
       (addendum ? addendum->SizeInBytes() : 0);
 }

 std::size_t Descriptor::Elements() const {
   int n{rank()};
   std::size_t elements{1};
   for (int j{0}; j < n; ++j) {
     elements *= GetDimension(j).Extent();
   }
   return elements;
 }

 int Descriptor::Allocate() {
   std::size_t byteSize{Elements() * ElementBytes()};
   void *p{std::malloc(byteSize)};
   if (!p && byteSize) {
     return CFI_ERROR_MEM_ALLOCATION;
   }
   // TODO: image synchronization
   raw_.base_addr = p;
   if (int dims{rank()}) {
     std::size_t stride{ElementBytes()};
     for (int j{0}; j < dims; ++j) {
       auto &dimension{GetDimension(j)};
       dimension.SetByteStride(stride);
       stride *= dimension.Extent();
     }
   }
   return 0;
 }

 int Descriptor::Destroy(bool finalize) {
   if (raw_.attribute == CFI_attribute_pointer) {
     return StatOk;
   } else {
     if (auto *addendum{Addendum()}) {
       if (const auto *derived{addendum->derivedType()}) {
         if (!derived->noDestructionNeeded()) {
           runtime::Destroy(*this, finalize, *derived);
         }
       }
     }
     return Deallocate();
   }
 }

 int Descriptor::Deallocate() { return ISO::CFI_deallocate(&raw_); }

 bool Descriptor::DecrementSubscripts(
     SubscriptValue *subscript, const int *permutation) const {
   for (int j{raw_.rank - 1}; j >= 0; --j) {
     int k{permutation ? permutation[j] : j};
     const Dimension &dim{GetDimension(k)};
     if (--subscript[k] >= dim.LowerBound()) {
       return true;
     }
     subscript[k] = dim.UpperBound();
   }
   return false;
 }

 std::size_t Descriptor::ZeroBasedElementNumber(
     const SubscriptValue *subscript, const int *permutation) const {
   std::size_t result{0};
   std::size_t coefficient{1};
   for (int j{0}; j < raw_.rank; ++j) {
     int k{permutation ? permutation[j] : j};
     const Dimension &dim{GetDimension(k)};
     result += coefficient * (subscript[k] - dim.LowerBound());
     coefficient *= dim.Extent();
   }
   return result;
 }

 bool Descriptor::EstablishPointerSection(const Descriptor &source,
     const SubscriptValue *lower, const SubscriptValue *upper,
     const SubscriptValue *stride) {
   *this = source;
   raw_.attribute = CFI_attribute_pointer;
   int newRank{raw_.rank};
   for (int j{0}; j < raw_.rank; ++j) {
     if (!stride || stride[j] == 0) {
       if (newRank > 0) {
         --newRank;
       } else {
         return false;
       }
     }
   }
   raw_.rank = newRank;
   if (const auto *sourceAddendum = source.Addendum()) {
     if (auto *addendum{Addendum()}) {
       *addendum = *sourceAddendum;
     } else {
       return false;
     }
   }
   return CFI_section(&raw_, &source.raw_, lower, upper, stride) == CFI_SUCCESS;
 }

 void Descriptor::Check() const {
   // TODO
 }

 void Descriptor::Dump(FILE *f) const {
   std::fprintf(f, "Descriptor @ %p:\n", reinterpret_cast<const void *>(this));
   std::fprintf(f, "  base_addr %p\n", raw_.base_addr);
   std::fprintf(f, "  elem_len  %zd\n", static_cast<std::size_t>(raw_.elem_len));
   std::fprintf(f, "  version   %d\n", static_cast<int>(raw_.version));
   std::fprintf(f, "  rank      %d\n", static_cast<int>(raw_.rank));
   std::fprintf(f, "  type      %d\n", static_cast<int>(raw_.type));
   std::fprintf(f, "  attribute %d\n", static_cast<int>(raw_.attribute));
   std::fprintf(f, "  addendum  %d\n", static_cast<int>(raw_.f18Addendum));
   for (int j{0}; j < raw_.rank; ++j) {
     std::fprintf(f, "  dim[%d] lower_bound %jd\n", j,
         static_cast<std::intmax_t>(raw_.dim[j].lower_bound));
     std::fprintf(f, "         extent      %jd\n",
         static_cast<std::intmax_t>(raw_.dim[j].extent));
     std::fprintf(f, "         sm          %jd\n",
         static_cast<std::intmax_t>(raw_.dim[j].sm));
   }
   if (const DescriptorAddendum * addendum{Addendum()}) {
     addendum->Dump(f);
   }
 }

 DescriptorAddendum &DescriptorAddendum::operator=(
     const DescriptorAddendum &that) {
   derivedType_ = that.derivedType_;
   auto lenParms{that.LenParameters()};
   for (std::size_t j{0}; j < lenParms; ++j) {
     len_[j] = that.len_[j];
   }
   return *this;
 }

 std::size_t DescriptorAddendum::SizeInBytes() const {
   return SizeInBytes(LenParameters());
 }

 std::size_t DescriptorAddendum::LenParameters() const {
   const auto *type{derivedType()};
   return type ? type->LenParameters() : 0;
 }

 void DescriptorAddendum::Dump(FILE *f) const {
   std::fprintf(
       f, "  derivedType @ %p\n", reinterpret_cast<const void *>(derivedType()));
   std::size_t lenParms{LenParameters()};
   for (std::size_t j{0}; j < lenParms; ++j) {
     std::fprintf(f, "  len[%zd] %jd\n", j, static_cast<std::intmax_t>(len_[j]));
   }
 }
 } // namespace Fortran::runtime
	//===-- runtime/descriptor.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/descriptor.h"
	#include "derived.h"
	#include "memory.h"
	#include "stat.h"
	#include "terminator.h"
	#include "type-info.h"
	#include <cassert>
	#include <cstdlib>
	#include <cstring>

	namespace Fortran::runtime {

	Descriptor::Descriptor(const Descriptor &that) { *this = that; }

	Descriptor &Descriptor::operator=(const Descriptor &that) {
	std::memcpy(this, &that, that.SizeInBytes());
	return *this;
	}

	void Descriptor::Establish(TypeCode t, std::size_t elementBytes, void *p,
	int rank, const SubscriptValue *extent, ISO::CFI_attribute_t attribute,
	bool addendum) {
	Terminator terminator{__FILE__, __LINE__};
	// Subtle: the standard CFI_establish() function doesn't allow a zero
	// elem_len argument in cases where elem_len is not ignored; and when it
	// returns an error code (CFI_INVALID_ELEM_LEN in this case), it must not
	// modify the descriptor. That design makes sense, maybe, for actual
	// C interoperability, but we need to work around it here. A zero
	// incoming element length is replaced by 4 so that it will be valid
	// for all CHARACTER kinds.
	std::size_t workaroundElemLen{elementBytes ? elementBytes : 4};
	int cfiStatus{ISO::CFI_establish(
	&raw_, p, attribute, t.raw(), workaroundElemLen, rank, extent)};
	if (cfiStatus != CFI_SUCCESS) {
	terminator.Crash(
	"Descriptor::Establish: CFI_establish returned %d", cfiStatus, t.raw());
	}
	if (elementBytes == 0) {
	raw_.elem_len = 0;
	for (int j{0}; j < rank; ++j) {
	GetDimension(j).SetByteStride(0);
	}
	}
	raw_.f18Addendum = addendum;
	DescriptorAddendum *a{Addendum()};
	RUNTIME_CHECK(terminator, addendum == (a != nullptr));
	if (a) {
	new (a) DescriptorAddendum{};
	}
	}

	void Descriptor::Establish(TypeCategory c, int kind, void *p, int rank,
	const SubscriptValue *extent, ISO::CFI_attribute_t attribute,
	bool addendum) {
	Establish(TypeCode(c, kind), BytesFor(c, kind), p, rank, extent, attribute,
	addendum);
	}

	void Descriptor::Establish(int characterKind, std::size_t characters, void *p,
	int rank, const SubscriptValue *extent, ISO::CFI_attribute_t attribute,
	bool addendum) {
	Establish(TypeCode{TypeCategory::Character, characterKind},
	characterKind * characters, p, rank, extent, attribute, addendum);
	}

	void Descriptor::Establish(const typeInfo::DerivedType &dt, void *p, int rank,
	const SubscriptValue *extent, ISO::CFI_attribute_t attribute) {
	Establish(TypeCode{TypeCategory::Derived, 0}, dt.sizeInBytes(), p, rank,
	extent, attribute, true);
	DescriptorAddendum *a{Addendum()};
	Terminator terminator{__FILE__, __LINE__};
	RUNTIME_CHECK(terminator, a != nullptr);
	new (a) DescriptorAddendum{&dt};
	}

	OwningPtr<Descriptor> Descriptor::Create(TypeCode t, std::size_t elementBytes,
	void p, int rank, const SubscriptValue extent,
	ISO::CFI_attribute_t attribute, int derivedTypeLenParameters) {
	std::size_t bytes{SizeInBytes(rank, true, derivedTypeLenParameters)};
	Terminator terminator{__FILE__, __LINE__};
	Descriptor *result{
	reinterpret_cast<Descriptor *>(AllocateMemoryOrCrash(terminator, bytes))};
	result->Establish(t, elementBytes, p, rank, extent, attribute, true);
	return OwningPtr<Descriptor>{result};
	}

	OwningPtr<Descriptor> Descriptor::Create(TypeCategory c, int kind, void *p,
	int rank, const SubscriptValue *extent, ISO::CFI_attribute_t attribute) {
	return Create(
	TypeCode(c, kind), BytesFor(c, kind), p, rank, extent, attribute);
	}

	OwningPtr<Descriptor> Descriptor::Create(int characterKind,
	SubscriptValue characters, void p, int rank, const SubscriptValue extent,
	ISO::CFI_attribute_t attribute) {
	return Create(TypeCode{TypeCategory::Character, characterKind},
	characterKind * characters, p, rank, extent, attribute);
	}

	OwningPtr<Descriptor> Descriptor::Create(const typeInfo::DerivedType &dt,
	void p, int rank, const SubscriptValue extent,
	ISO::CFI_attribute_t attribute) {
	return Create(TypeCode{TypeCategory::Derived, 0}, dt.sizeInBytes(), p, rank,
	extent, attribute, dt.LenParameters());
	}

	std::size_t Descriptor::SizeInBytes() const {
	const DescriptorAddendum *addendum{Addendum()};
	return sizeof this - sizeof(Dimension) + raw_.rank sizeof(Dimension) +
	(addendum ? addendum->SizeInBytes() : 0);
	}

	std::size_t Descriptor::Elements() const {
	int n{rank()};
	std::size_t elements{1};
	for (int j{0}; j < n; ++j) {
	elements *= GetDimension(j).Extent();
	}
	return elements;
	}

	int Descriptor::Allocate() {
	std::size_t byteSize{Elements() * ElementBytes()};
	void *p{std::malloc(byteSize)};
	if (!p && byteSize) {
	return CFI_ERROR_MEM_ALLOCATION;
	}
	// TODO: image synchronization
	raw_.base_addr = p;
	if (int dims{rank()}) {
	std::size_t stride{ElementBytes()};
	for (int j{0}; j < dims; ++j) {
	auto &dimension{GetDimension(j)};
	dimension.SetByteStride(stride);
	stride *= dimension.Extent();
	}
	}
	return 0;
	}

	int Descriptor::Destroy(bool finalize) {
	if (raw_.attribute == CFI_attribute_pointer) {
	return StatOk;
	} else {
	if (auto *addendum{Addendum()}) {
	if (const auto *derived{addendum->derivedType()}) {
	if (!derived->noDestructionNeeded()) {
	runtime::Destroy(this, finalize, derived);
	}
	}
	}
	return Deallocate();
	}
	}

	int Descriptor::Deallocate() { return ISO::CFI_deallocate(&raw_); }

	bool Descriptor::DecrementSubscripts(
	SubscriptValue subscript, const int permutation) const {
	for (int j{raw_.rank - 1}; j >= 0; --j) {
	int k{permutation ? permutation[j] : j};
	const Dimension &dim{GetDimension(k)};
	if (--subscript[k] >= dim.LowerBound()) {
	return true;
	}
	subscript[k] = dim.UpperBound();
	}
	return false;
	}

	std::size_t Descriptor::ZeroBasedElementNumber(
	const SubscriptValue subscript, const int permutation) const {
	std::size_t result{0};
	std::size_t coefficient{1};
	for (int j{0}; j < raw_.rank; ++j) {
	int k{permutation ? permutation[j] : j};
	const Dimension &dim{GetDimension(k)};
	result += coefficient * (subscript[k] - dim.LowerBound());
	coefficient *= dim.Extent();
	}
	return result;
	}

	bool Descriptor::EstablishPointerSection(const Descriptor &source,
	const SubscriptValue lower, const SubscriptValue upper,
	const SubscriptValue *stride) {
	*this = source;
	raw_.attribute = CFI_attribute_pointer;
	int newRank{raw_.rank};
	for (int j{0}; j < raw_.rank; ++j) {
	if (!stride \|\| stride[j] == 0) {
	if (newRank > 0) {
	--newRank;
	} else {
	return false;
	}
	}
	}
	raw_.rank = newRank;
	if (const auto *sourceAddendum = source.Addendum()) {
	if (auto *addendum{Addendum()}) {
	addendum = sourceAddendum;
	} else {
	return false;
	}
	}
	return CFI_section(&raw_, &source.raw_, lower, upper, stride) == CFI_SUCCESS;
	}

	void Descriptor::Check() const {
	// TODO
	}

	void Descriptor::Dump(FILE *f) const {
	std::fprintf(f, "Descriptor @ %p:\n", reinterpret_cast<const void *>(this));
	std::fprintf(f, " base_addr %p\n", raw_.base_addr);
	std::fprintf(f, " elem_len %zd\n", static_cast<std::size_t>(raw_.elem_len));
	std::fprintf(f, " version %d\n", static_cast<int>(raw_.version));
	std::fprintf(f, " rank %d\n", static_cast<int>(raw_.rank));
	std::fprintf(f, " type %d\n", static_cast<int>(raw_.type));
	std::fprintf(f, " attribute %d\n", static_cast<int>(raw_.attribute));
	std::fprintf(f, " addendum %d\n", static_cast<int>(raw_.f18Addendum));
	for (int j{0}; j < raw_.rank; ++j) {
	std::fprintf(f, " dim[%d] lower_bound %jd\n", j,
	static_cast<std::intmax_t>(raw_.dim[j].lower_bound));
	std::fprintf(f, " extent %jd\n",
	static_cast<std::intmax_t>(raw_.dim[j].extent));
	std::fprintf(f, " sm %jd\n",
	static_cast<std::intmax_t>(raw_.dim[j].sm));
	}
	if (const DescriptorAddendum * addendum{Addendum()}) {
	addendum->Dump(f);
	}
	}

	DescriptorAddendum &DescriptorAddendum::operator=(
	const DescriptorAddendum &that) {
	derivedType_ = that.derivedType_;
	auto lenParms{that.LenParameters()};
	for (std::size_t j{0}; j < lenParms; ++j) {
	len_[j] = that.len_[j];
	}
	return *this;
	}

	std::size_t DescriptorAddendum::SizeInBytes() const {
	return SizeInBytes(LenParameters());
	}

	std::size_t DescriptorAddendum::LenParameters() const {
	const auto *type{derivedType()};
	return type ? type->LenParameters() : 0;
	}

	void DescriptorAddendum::Dump(FILE *f) const {
	std::fprintf(
	f, " derivedType @ %p\n", reinterpret_cast<const void *>(derivedType()));
	std::size_t lenParms{LenParameters()};
	for (std::size_t j{0}; j < lenParms; ++j) {
	std::fprintf(f, " len[%zd] %jd\n", j, static_cast<std::intmax_t>(len_[j]));
	}
	}
	} // namespace Fortran::runtime