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clang-p2996/flang/runtime/descriptor.cpp
peter klausler 4fede8bc8a [flang] Implement derived type description table encoding 
Define Fortran derived types that describe the characteristics
of derived types, and instantiations of parameterized derived
types, that are of relevance to the runtime language support
library.  Define a suite of corresponding C++ structure types
for the runtime library to use to interpret instances of the
descriptions.

Create instances of these description types in Semantics as
static initializers for compiler-created objects in the scopes
that define or instantiate user derived types.

Delete obsolete code from earlier attempts to package runtime
type information.

Differential Revision: https://reviews.llvm.org/D92802
2020-12-08 10:26:58 -08:00

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//===-- 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 "descriptor.h"
#include "derived.h"
#include "memory.h"
#include "terminator.h"
#include "type-info.h"
#include <cassert>
#include <cstdlib>
#include <cstring>
namespace Fortran::runtime {
Descriptor::Descriptor(const Descriptor &that) {
std::memcpy(this, &that, that.SizeInBytes());
}
Descriptor::~Descriptor() {
if (raw_.attribute != CFI_attribute_pointer) {
Deallocate();
}
}
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__};
RUNTIME_CHECK(terminator,
ISO::CFI_establish(&raw_, p, attribute, t.raw(), elementBytes, rank,
extent) == CFI_SUCCESS);
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(CFI_type_struct, 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{CFI_type_struct}, 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
// TODO: derived type initialization
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::Allocate(const SubscriptValue lb[], const SubscriptValue ub[]) {
int result{ISO::CFI_allocate(&raw_, lb, ub, ElementBytes())};
if (result == CFI_SUCCESS) {
// TODO: derived type initialization
}
return result;
}
int Descriptor::Deallocate(bool finalize) {
Destroy(finalize);
return ISO::CFI_deallocate(&raw_);
}
void Descriptor::Destroy(bool finalize) const {
if (const DescriptorAddendum * addendum{Addendum()}) {
if (const typeInfo::DerivedType * dt{addendum->derivedType()}) {
if (addendum->flags() & DescriptorAddendum::DoNotFinalize) {
finalize = false;
}
runtime::Destroy(*this, finalize, *dt);
}
}
}
bool Descriptor::IncrementSubscripts(
SubscriptValue *subscript, const int *permutation) const {
for (int j{0}; j < raw_.rank; ++j) {
int k{permutation ? permutation[j] : j};
const Dimension &dim{GetDimension(k)};
if (subscript[k]++ < dim.UpperBound()) {
return true;
}
subscript[k] = dim.LowerBound();
}
return false;
}
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::SubscriptsForZeroBasedElementNumber(SubscriptValue *subscript,
std::size_t elementNumber, const int *permutation) const {
std::size_t coefficient{1};
std::size_t dimCoefficient[maxRank];
for (int j{0}; j < raw_.rank; ++j) {
int k{permutation ? permutation[j] : j};
const Dimension &dim{GetDimension(k)};
dimCoefficient[j] = coefficient;
coefficient *= dim.Extent();
}
if (elementNumber >= coefficient) {
return false; // out of range
}
for (int j{raw_.rank - 1}; j >= 0; --j) {
int k{permutation ? permutation[j] : j};
const Dimension &dim{GetDimension(k)};
std::size_t quotient{j ? elementNumber / dimCoefficient[j] : 0};
subscript[k] =
dim.LowerBound() + elementNumber - dimCoefficient[j] * quotient;
elementNumber = quotient;
}
return true;
}
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);
}
}
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::fprintf(f, " flags 0x%jx\n", static_cast<std::intmax_t>(flags_));
// TODO: LEN parameter values
}
} // namespace Fortran::runtime
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