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llvm / llvm-project / 37d72991c136244fe53be02f5af0ad643247a1e6 / . / flang / runtime / type-info.cpp
blob: 37c3c1f5ab861b3738158586b0d4f2c5486b8624 [file] [log] [blame]
//===-- runtime/type-info.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 "type-info.h"
#include "terminator.h"
#include <cstdio>
namespace Fortran::runtime::typeInfo {
std::optional<TypeParameterValue> Value::GetValue(
const Descriptor *descriptor) const {
switch (genre_) {
case Genre::Explicit:
return value_;
case Genre::LenParameter:
if (descriptor) {
if (const auto *addendum{descriptor->Addendum()}) {
return addendum->LenParameterValue(value_);
}
}
return std::nullopt;
default:
return std::nullopt;
}
}
std::size_t Component::GetElementByteSize(const Descriptor &instance) const {
switch (category()) {
case TypeCategory::Integer:
case TypeCategory::Real:
case TypeCategory::Logical:
return kind_;
case TypeCategory::Complex:
return 2 * kind_;
case TypeCategory::Character:
if (auto value{characterLen_.GetValue(&instance)}) {
return kind_ * *value;
}
break;
case TypeCategory::Derived:
if (const auto *type{derivedType()}) {
return type->sizeInBytes();
}
break;
}
return 0;
}
std::size_t Component::GetElements(const Descriptor &instance) const {
std::size_t elements{1};
if (int rank{rank_}) {
if (const Value * boundValues{bounds()}) {
for (int j{0}; j < rank; ++j) {
TypeParameterValue lb{
boundValues[2 * j].GetValue(&instance).value_or(0)};
TypeParameterValue ub{
boundValues[2 * j + 1].GetValue(&instance).value_or(0)};
if (ub >= lb) {
elements *= ub - lb + 1;
} else {
return 0;
}
}
} else {
return 0;
}
}
return elements;
}
std::size_t Component::SizeInBytes(const Descriptor &instance) const {
if (genre() == Genre::Data) {
return GetElementByteSize(instance) * GetElements(instance);
} else if (category() == TypeCategory::Derived) {
const DerivedType *type{derivedType()};
return Descriptor::SizeInBytes(
rank_, true, type ? type->LenParameters() : 0);
} else {
return Descriptor::SizeInBytes(rank_);
}
}
void Component::EstablishDescriptor(Descriptor &descriptor,
const Descriptor &container, Terminator &terminator) const {
TypeCategory cat{category()};
if (cat == TypeCategory::Character) {
auto length{characterLen_.GetValue(&container)};
RUNTIME_CHECK(terminator, length.has_value());
descriptor.Establish(kind_, *length / kind_, nullptr, rank_);
} else if (cat == TypeCategory::Derived) {
const DerivedType *type{derivedType()};
RUNTIME_CHECK(terminator, type != nullptr);
descriptor.Establish(*type, nullptr, rank_);
} else {
descriptor.Establish(cat, kind_, nullptr, rank_);
}
if (rank_ && genre_ != Genre::Allocatable) {
const typeInfo::Value *boundValues{bounds()};
RUNTIME_CHECK(terminator, boundValues != nullptr);
auto byteStride{static_cast<SubscriptValue>(descriptor.ElementBytes())};
for (int j{0}; j < rank_; ++j) {
auto lb{boundValues++->GetValue(&container)};
auto ub{boundValues++->GetValue(&container)};
RUNTIME_CHECK(terminator, lb.has_value() && ub.has_value());
Dimension &dim{descriptor.GetDimension(j)};
dim.SetBounds(*lb, *ub);
dim.SetByteStride(byteStride);
byteStride *= dim.Extent();
}
}
}
void Component::CreatePointerDescriptor(Descriptor &descriptor,
const Descriptor &container, Terminator &terminator,
const SubscriptValue *subscripts) const {
RUNTIME_CHECK(terminator, genre_ == Genre::Data);
EstablishDescriptor(descriptor, container, terminator);
if (subscripts) {
descriptor.set_base_addr(container.Element<char>(subscripts) + offset_);
} else {
descriptor.set_base_addr(container.OffsetElement<char>() + offset_);
}
descriptor.raw().attribute = CFI_attribute_pointer;
}
const DerivedType *DerivedType::GetParentType() const {
if (hasParent_) {
const Descriptor &compDesc{component()};
const Component &component{*compDesc.OffsetElement<const Component>()};
return component.derivedType();
} else {
return nullptr;
}
}
const Component *DerivedType::FindDataComponent(
const char *compName, std::size_t compNameLen) const {
const Descriptor &compDesc{component()};
std::size_t n{compDesc.Elements()};
SubscriptValue at[maxRank];
compDesc.GetLowerBounds(at);
for (std::size_t j{0}; j < n; ++j, compDesc.IncrementSubscripts(at)) {
const Component *component{compDesc.Element<Component>(at)};
INTERNAL_CHECK(component != nullptr);
const Descriptor &nameDesc{component->name()};
if (nameDesc.ElementBytes() == compNameLen &&
std::memcmp(compName, nameDesc.OffsetElement(), compNameLen) == 0) {
return component;
}
}
const DerivedType *parent{GetParentType()};
return parent ? parent->FindDataComponent(compName, compNameLen) : nullptr;
}
static void DumpScalarCharacter(
FILE *f, const Descriptor &desc, const char *what) {
if (desc.raw().version == CFI_VERSION &&
desc.type() == TypeCode{TypeCategory::Character, 1} &&
desc.ElementBytes() > 0 && desc.rank() == 0 &&
desc.OffsetElement() != nullptr) {
std::fwrite(desc.OffsetElement(), desc.ElementBytes(), 1, f);
} else {
std::fprintf(f, "bad %s descriptor: ", what);
desc.Dump(f);
}
}
FILE *DerivedType::Dump(FILE *f) const {
std::fprintf(f, "DerivedType @ %p:\n", reinterpret_cast<const void *>(this));
const std::uint64_t *uints{reinterpret_cast<const std::uint64_t *>(this)};
for (int j{0}; j < 64; ++j) {
int offset{j * static_cast<int>(sizeof *uints)};
std::fprintf(f, " [+%3d](%p) 0x%016jx", offset,
reinterpret_cast<const void *>(&uints[j]),
static_cast<std::uintmax_t>(uints[j]));
if (offset == offsetof(DerivedType, binding_)) {
std::fputs(" <-- binding_\n", f);
} else if (offset == offsetof(DerivedType, name_)) {
std::fputs(" <-- name_\n", f);
} else if (offset == offsetof(DerivedType, sizeInBytes_)) {
std::fputs(" <-- sizeInBytes_\n", f);
} else if (offset == offsetof(DerivedType, uninstantiated_)) {
std::fputs(" <-- uninstantiated_\n", f);
} else if (offset == offsetof(DerivedType, kindParameter_)) {
std::fputs(" <-- kindParameter_\n", f);
} else if (offset == offsetof(DerivedType, lenParameterKind_)) {
std::fputs(" <-- lenParameterKind_\n", f);
} else if (offset == offsetof(DerivedType, component_)) {
std::fputs(" <-- component_\n", f);
} else if (offset == offsetof(DerivedType, procPtr_)) {
std::fputs(" <-- procPtr_\n", f);
} else if (offset == offsetof(DerivedType, special_)) {
std::fputs(" <-- special_\n", f);
} else if (offset == offsetof(DerivedType, specialBitSet_)) {
std::fputs(" <-- specialBitSet_\n", f);
} else if (offset == offsetof(DerivedType, hasParent_)) {
std::fputs(" <-- (flags)\n", f);
} else {
std::fputc('\n', f);
}
}
std::fputs(" name: ", f);
DumpScalarCharacter(f, name(), "DerivedType::name");
const Descriptor &bindingDesc{binding()};
std::fprintf(
f, "\n binding descriptor (byteSize 0x%zx): ", binding_.byteSize);
bindingDesc.Dump(f);
const Descriptor &compDesc{component()};
std::fputs("\n components:\n", f);
if (compDesc.raw().version == CFI_VERSION &&
compDesc.type() == TypeCode{TypeCategory::Derived, 0} &&
compDesc.ElementBytes() == sizeof(Component) && compDesc.rank() == 1) {
std::size_t n{compDesc.Elements()};
for (std::size_t j{0}; j < n; ++j) {
const Component &comp{*compDesc.ZeroBasedIndexedElement<Component>(j)};
std::fprintf(f, " [%3zd] ", j);
comp.Dump(f);
}
} else {
std::fputs(" bad descriptor: ", f);
compDesc.Dump(f);
}
const Descriptor &specialDesc{special()};
std::fprintf(
f, "\n special descriptor (byteSize 0x%zx): ", special_.byteSize);
specialDesc.Dump(f);
std::size_t specials{specialDesc.Elements()};
for (std::size_t j{0}; j < specials; ++j) {
std::fprintf(f, " [%3zd] ", j);
specialDesc.ZeroBasedIndexedElement<SpecialBinding>(j)->Dump(f);
}
return f;
}
FILE *Component::Dump(FILE *f) const {
std::fprintf(f, "Component @ %p:\n", reinterpret_cast<const void *>(this));
std::fputs(" name: ", f);
DumpScalarCharacter(f, name(), "Component::name");
if (genre_ == Genre::Data) {
std::fputs(" Data ", f);
} else if (genre_ == Genre::Pointer) {
std::fputs(" Pointer ", f);
} else if (genre_ == Genre::Allocatable) {
std::fputs(" Allocatable", f);
} else if (genre_ == Genre::Automatic) {
std::fputs(" Automatic ", f);
} else {
std::fprintf(f, " (bad genre 0x%x)", static_cast<int>(genre_));
}
std::fprintf(f, " category %d kind %d rank %d offset 0x%zx\n", category_,
kind_, rank_, static_cast<std::size_t>(offset_));
if (initialization_) {
std::fprintf(f, " initialization @ %p:\n",
reinterpret_cast<const void *>(initialization_));
for (int j{0}; j < 128; j += sizeof(std::uint64_t)) {
std::fprintf(f, " [%3d] 0x%016jx\n", j,
static_cast<std::uintmax_t>(
*reinterpret_cast<const std::uint64_t *>(initialization_ + j)));
}
}
return f;
}
FILE *SpecialBinding::Dump(FILE *f) const {
std::fprintf(
f, "SpecialBinding @ %p:\n", reinterpret_cast<const void *>(this));
switch (which_) {
case Which::ScalarAssignment:
std::fputs(" ScalarAssignment", f);
break;
case Which::ElementalAssignment:
std::fputs(" ElementalAssignment", f);
break;
case Which::ReadFormatted:
std::fputs(" ReadFormatted", f);
break;
case Which::ReadUnformatted:
std::fputs(" ReadUnformatted", f);
break;
case Which::WriteFormatted:
std::fputs(" WriteFormatted", f);
break;
case Which::WriteUnformatted:
std::fputs(" WriteUnformatted", f);
break;
case Which::ElementalFinal:
std::fputs(" ElementalFinal", f);
break;
case Which::AssumedRankFinal:
std::fputs(" AssumedRankFinal", f);
break;
default:
std::fprintf(f, " rank-%d final:",
static_cast<int>(which_) - static_cast<int>(Which::ScalarFinal));
break;
}
std::fprintf(f, " isArgDescriptorSet: 0x%x\n", isArgDescriptorSet_);
std::fprintf(f, " proc: %p\n", reinterpret_cast<void *>(proc_));
return f;
}
} // namespace Fortran::runtime::typeInfo