llvm-project/flang/runtime/descriptor-io.h

495 lines
18 KiB
C++

//===-- runtime/descriptor-io.h ---------------------------------*- 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
//
//===----------------------------------------------------------------------===//
#ifndef FORTRAN_RUNTIME_DESCRIPTOR_IO_H_
#define FORTRAN_RUNTIME_DESCRIPTOR_IO_H_
// Implementation of I/O data list item transfers based on descriptors.
// (All I/O items come through here so that the code is exercised for test;
// some scalar I/O data transfer APIs could be changed to bypass their use
// of descriptors in the future for better efficiency.)
#include "edit-input.h"
#include "edit-output.h"
#include "io-stmt.h"
#include "terminator.h"
#include "type-info.h"
#include "unit.h"
#include "flang/Common/uint128.h"
#include "flang/Runtime/cpp-type.h"
#include "flang/Runtime/descriptor.h"
namespace Fortran::runtime::io::descr {
template <typename A>
inline A &ExtractElement(IoStatementState &io, const Descriptor &descriptor,
const SubscriptValue subscripts[]) {
A *p{descriptor.Element<A>(subscripts)};
if (!p) {
io.GetIoErrorHandler().Crash(
"ExtractElement: null base address or subscripts out of range");
}
return *p;
}
// Per-category descriptor-based I/O templates
// TODO (perhaps as a nontrivial but small starter project): implement
// automatic repetition counts, like "10*3.14159", for list-directed and
// NAMELIST array output.
template <int KIND, Direction DIR>
inline bool FormattedIntegerIO(
IoStatementState &io, const Descriptor &descriptor) {
std::size_t numElements{descriptor.Elements()};
SubscriptValue subscripts[maxRank];
descriptor.GetLowerBounds(subscripts);
using IntType = CppTypeFor<TypeCategory::Integer, KIND>;
bool anyInput{false};
for (std::size_t j{0}; j < numElements; ++j) {
if (auto edit{io.GetNextDataEdit()}) {
IntType &x{ExtractElement<IntType>(io, descriptor, subscripts)};
if constexpr (DIR == Direction::Output) {
if (!EditIntegerOutput<KIND>(io, *edit, x)) {
return false;
}
} else if (edit->descriptor != DataEdit::ListDirectedNullValue) {
if (EditIntegerInput(io, *edit, reinterpret_cast<void *>(&x), KIND)) {
anyInput = true;
} else {
return anyInput && edit->IsNamelist();
}
}
if (!descriptor.IncrementSubscripts(subscripts) && j + 1 < numElements) {
io.GetIoErrorHandler().Crash(
"FormattedIntegerIO: subscripts out of bounds");
}
} else {
return false;
}
}
return true;
}
template <int KIND, Direction DIR>
inline bool FormattedRealIO(
IoStatementState &io, const Descriptor &descriptor) {
std::size_t numElements{descriptor.Elements()};
SubscriptValue subscripts[maxRank];
descriptor.GetLowerBounds(subscripts);
using RawType = typename RealOutputEditing<KIND>::BinaryFloatingPoint;
bool anyInput{false};
for (std::size_t j{0}; j < numElements; ++j) {
if (auto edit{io.GetNextDataEdit()}) {
RawType &x{ExtractElement<RawType>(io, descriptor, subscripts)};
if constexpr (DIR == Direction::Output) {
if (!RealOutputEditing<KIND>{io, x}.Edit(*edit)) {
return false;
}
} else if (edit->descriptor != DataEdit::ListDirectedNullValue) {
if (EditRealInput<KIND>(io, *edit, reinterpret_cast<void *>(&x))) {
anyInput = true;
} else {
return anyInput && edit->IsNamelist();
}
}
if (!descriptor.IncrementSubscripts(subscripts) && j + 1 < numElements) {
io.GetIoErrorHandler().Crash(
"FormattedRealIO: subscripts out of bounds");
}
} else {
return false;
}
}
return true;
}
template <int KIND, Direction DIR>
inline bool FormattedComplexIO(
IoStatementState &io, const Descriptor &descriptor) {
std::size_t numElements{descriptor.Elements()};
SubscriptValue subscripts[maxRank];
descriptor.GetLowerBounds(subscripts);
bool isListOutput{
io.get_if<ListDirectedStatementState<Direction::Output>>() != nullptr};
using RawType = typename RealOutputEditing<KIND>::BinaryFloatingPoint;
bool anyInput{false};
for (std::size_t j{0}; j < numElements; ++j) {
RawType *x{&ExtractElement<RawType>(io, descriptor, subscripts)};
if (isListOutput) {
DataEdit rEdit, iEdit;
rEdit.descriptor = DataEdit::ListDirectedRealPart;
iEdit.descriptor = DataEdit::ListDirectedImaginaryPart;
rEdit.modes = iEdit.modes = io.mutableModes();
if (!RealOutputEditing<KIND>{io, x[0]}.Edit(rEdit) ||
!RealOutputEditing<KIND>{io, x[1]}.Edit(iEdit)) {
return false;
}
} else {
for (int k{0}; k < 2; ++k, ++x) {
auto edit{io.GetNextDataEdit()};
if (!edit) {
return false;
} else if constexpr (DIR == Direction::Output) {
if (!RealOutputEditing<KIND>{io, *x}.Edit(*edit)) {
return false;
}
} else if (edit->descriptor == DataEdit::ListDirectedNullValue) {
break;
} else if (EditRealInput<KIND>(
io, *edit, reinterpret_cast<void *>(x))) {
anyInput = true;
} else {
return anyInput && edit->IsNamelist();
}
}
}
if (!descriptor.IncrementSubscripts(subscripts) && j + 1 < numElements) {
io.GetIoErrorHandler().Crash(
"FormattedComplexIO: subscripts out of bounds");
}
}
return true;
}
template <typename A, Direction DIR>
inline bool FormattedCharacterIO(
IoStatementState &io, const Descriptor &descriptor) {
std::size_t numElements{descriptor.Elements()};
SubscriptValue subscripts[maxRank];
descriptor.GetLowerBounds(subscripts);
std::size_t length{descriptor.ElementBytes() / sizeof(A)};
auto *listOutput{io.get_if<ListDirectedStatementState<Direction::Output>>()};
bool anyInput{false};
for (std::size_t j{0}; j < numElements; ++j) {
A *x{&ExtractElement<A>(io, descriptor, subscripts)};
if (listOutput) {
if (!ListDirectedCharacterOutput(io, *listOutput, x, length)) {
return false;
}
} else if (auto edit{io.GetNextDataEdit()}) {
if constexpr (DIR == Direction::Output) {
if (!EditCharacterOutput(io, *edit, x, length)) {
return false;
}
} else {
if (edit->descriptor != DataEdit::ListDirectedNullValue) {
if (EditCharacterInput(io, *edit, x, length)) {
anyInput = true;
} else {
return anyInput && edit->IsNamelist();
}
}
}
} else {
return false;
}
if (!descriptor.IncrementSubscripts(subscripts) && j + 1 < numElements) {
io.GetIoErrorHandler().Crash(
"FormattedCharacterIO: subscripts out of bounds");
}
}
return true;
}
template <int KIND, Direction DIR>
inline bool FormattedLogicalIO(
IoStatementState &io, const Descriptor &descriptor) {
std::size_t numElements{descriptor.Elements()};
SubscriptValue subscripts[maxRank];
descriptor.GetLowerBounds(subscripts);
auto *listOutput{io.get_if<ListDirectedStatementState<Direction::Output>>()};
using IntType = CppTypeFor<TypeCategory::Integer, KIND>;
bool anyInput{false};
for (std::size_t j{0}; j < numElements; ++j) {
IntType &x{ExtractElement<IntType>(io, descriptor, subscripts)};
if (listOutput) {
if (!ListDirectedLogicalOutput(io, *listOutput, x != 0)) {
return false;
}
} else if (auto edit{io.GetNextDataEdit()}) {
if constexpr (DIR == Direction::Output) {
if (!EditLogicalOutput(io, *edit, x != 0)) {
return false;
}
} else {
if (edit->descriptor != DataEdit::ListDirectedNullValue) {
bool truth{};
if (EditLogicalInput(io, *edit, truth)) {
x = truth;
anyInput = true;
} else {
return anyInput && edit->IsNamelist();
}
}
}
} else {
return false;
}
if (!descriptor.IncrementSubscripts(subscripts) && j + 1 < numElements) {
io.GetIoErrorHandler().Crash(
"FormattedLogicalIO: subscripts out of bounds");
}
}
return true;
}
template <Direction DIR>
static bool DescriptorIO(IoStatementState &, const Descriptor &);
template <Direction DIR>
static bool DefaultFormattedComponentIO(IoStatementState &io,
const typeInfo::Component &component, const Descriptor &origDescriptor,
const SubscriptValue origSubscripts[], Terminator &terminator) {
if (component.genre() == typeInfo::Component::Genre::Data) {
// Create a descriptor for the component
StaticDescriptor<maxRank, true, 16 /*?*/> statDesc;
Descriptor &desc{statDesc.descriptor()};
component.CreatePointerDescriptor(
desc, origDescriptor, terminator, origSubscripts);
return DescriptorIO<DIR>(io, desc);
} else {
// Component is itself a descriptor
char *pointer{
origDescriptor.Element<char>(origSubscripts) + component.offset()};
RUNTIME_CHECK(
terminator, component.genre() == typeInfo::Component::Genre::Automatic);
const Descriptor &compDesc{*reinterpret_cast<const Descriptor *>(pointer)};
return DescriptorIO<DIR>(io, compDesc);
}
}
std::optional<bool> DefinedFormattedIo(
IoStatementState &, const Descriptor &, const typeInfo::SpecialBinding &);
template <Direction DIR>
static bool FormattedDerivedTypeIO(
IoStatementState &io, const Descriptor &descriptor) {
IoErrorHandler &handler{io.GetIoErrorHandler()};
// Derived type information must be present for formatted I/O.
const DescriptorAddendum *addendum{descriptor.Addendum()};
RUNTIME_CHECK(handler, addendum != nullptr);
const typeInfo::DerivedType *type{addendum->derivedType()};
RUNTIME_CHECK(handler, type != nullptr);
if (const typeInfo::SpecialBinding *
special{type->FindSpecialBinding(DIR == Direction::Input
? typeInfo::SpecialBinding::Which::ReadFormatted
: typeInfo::SpecialBinding::Which::WriteFormatted)}) {
if (std::optional<bool> wasDefined{
DefinedFormattedIo(io, descriptor, *special)}) {
return *wasDefined; // user-defined I/O was applied
}
}
// Default componentwise derived type formatting
const Descriptor &compArray{type->component()};
RUNTIME_CHECK(handler, compArray.rank() == 1);
std::size_t numComponents{compArray.Elements()};
std::size_t numElements{descriptor.Elements()};
SubscriptValue subscripts[maxRank];
descriptor.GetLowerBounds(subscripts);
for (std::size_t j{0}; j < numElements;
++j, descriptor.IncrementSubscripts(subscripts)) {
SubscriptValue at[maxRank];
compArray.GetLowerBounds(at);
for (std::size_t k{0}; k < numComponents;
++k, compArray.IncrementSubscripts(at)) {
const typeInfo::Component &component{
*compArray.Element<typeInfo::Component>(at)};
if (!DefaultFormattedComponentIO<DIR>(
io, component, descriptor, subscripts, handler)) {
return false;
}
}
}
return true;
}
bool DefinedUnformattedIo(
IoStatementState &, const Descriptor &, const typeInfo::SpecialBinding &);
// Unformatted I/O
template <Direction DIR>
static bool UnformattedDescriptorIO(
IoStatementState &io, const Descriptor &descriptor) {
IoErrorHandler &handler{io.GetIoErrorHandler()};
const DescriptorAddendum *addendum{descriptor.Addendum()};
const typeInfo::DerivedType *type{
addendum ? addendum->derivedType() : nullptr};
if (const typeInfo::SpecialBinding *
special{type
? type->FindSpecialBinding(DIR == Direction::Input
? typeInfo::SpecialBinding::Which::ReadUnformatted
: typeInfo::SpecialBinding::Which::WriteUnformatted)
: nullptr}) {
// User-defined derived type unformatted I/O
return DefinedUnformattedIo(io, descriptor, *special);
} else {
// Regular derived type unformatted I/O, not user-defined
auto *externalUnf{io.get_if<ExternalUnformattedIoStatementState<DIR>>()};
auto *childUnf{io.get_if<ChildUnformattedIoStatementState<DIR>>()};
auto *inq{
DIR == Direction::Output ? io.get_if<InquireIOLengthState>() : nullptr};
RUNTIME_CHECK(handler, externalUnf || childUnf || inq);
std::size_t elementBytes{descriptor.ElementBytes()};
std::size_t numElements{descriptor.Elements()};
SubscriptValue subscripts[maxRank];
descriptor.GetLowerBounds(subscripts);
using CharType =
std::conditional_t<DIR == Direction::Output, const char, char>;
auto Transfer{[=](CharType &x, std::size_t totalBytes,
std::size_t elementBytes) -> bool {
if constexpr (DIR == Direction::Output) {
return externalUnf ? externalUnf->Emit(&x, totalBytes, elementBytes)
: childUnf ? childUnf->Emit(&x, totalBytes, elementBytes)
: inq->Emit(&x, totalBytes, elementBytes);
} else {
return externalUnf ? externalUnf->Receive(&x, totalBytes, elementBytes)
: childUnf->Receive(&x, totalBytes, elementBytes);
}
}};
if (descriptor.IsContiguous()) { // contiguous unformatted I/O
char &x{ExtractElement<char>(io, descriptor, subscripts)};
return Transfer(x, numElements * elementBytes, elementBytes);
} else { // non-contiguous unformatted I/O
for (std::size_t j{0}; j < numElements; ++j) {
char &x{ExtractElement<char>(io, descriptor, subscripts)};
if (!Transfer(x, elementBytes, elementBytes)) {
return false;
}
if (!descriptor.IncrementSubscripts(subscripts) &&
j + 1 < numElements) {
handler.Crash("DescriptorIO: subscripts out of bounds");
}
}
return true;
}
}
}
template <Direction DIR>
static bool DescriptorIO(IoStatementState &io, const Descriptor &descriptor) {
IoErrorHandler &handler{io.GetIoErrorHandler()};
if (handler.InError()) {
return false;
}
if (!io.get_if<IoDirectionState<DIR>>()) {
io.GetIoErrorHandler().Crash(
"DescriptorIO() called for wrong I/O direction");
return false;
}
if constexpr (DIR == Direction::Input) {
if (!io.BeginReadingRecord()) {
return false;
}
}
if (!io.get_if<FormattedIoStatementState<DIR>>()) {
return UnformattedDescriptorIO<DIR>(io, descriptor);
}
if (auto catAndKind{descriptor.type().GetCategoryAndKind()}) {
TypeCategory cat{catAndKind->first};
int kind{catAndKind->second};
switch (cat) {
case TypeCategory::Integer:
switch (kind) {
case 1:
return FormattedIntegerIO<1, DIR>(io, descriptor);
case 2:
return FormattedIntegerIO<2, DIR>(io, descriptor);
case 4:
return FormattedIntegerIO<4, DIR>(io, descriptor);
case 8:
return FormattedIntegerIO<8, DIR>(io, descriptor);
case 16:
return FormattedIntegerIO<16, DIR>(io, descriptor);
default:
handler.Crash(
"DescriptorIO: Unimplemented INTEGER kind (%d) in descriptor",
kind);
return false;
}
case TypeCategory::Real:
switch (kind) {
case 2:
return FormattedRealIO<2, DIR>(io, descriptor);
case 3:
return FormattedRealIO<3, DIR>(io, descriptor);
case 4:
return FormattedRealIO<4, DIR>(io, descriptor);
case 8:
return FormattedRealIO<8, DIR>(io, descriptor);
case 10:
return FormattedRealIO<10, DIR>(io, descriptor);
// TODO: case double/double
case 16:
return FormattedRealIO<16, DIR>(io, descriptor);
default:
handler.Crash(
"DescriptorIO: Unimplemented REAL kind (%d) in descriptor", kind);
return false;
}
case TypeCategory::Complex:
switch (kind) {
case 2:
return FormattedComplexIO<2, DIR>(io, descriptor);
case 3:
return FormattedComplexIO<3, DIR>(io, descriptor);
case 4:
return FormattedComplexIO<4, DIR>(io, descriptor);
case 8:
return FormattedComplexIO<8, DIR>(io, descriptor);
case 10:
return FormattedComplexIO<10, DIR>(io, descriptor);
// TODO: case double/double
case 16:
return FormattedComplexIO<16, DIR>(io, descriptor);
default:
handler.Crash(
"DescriptorIO: Unimplemented COMPLEX kind (%d) in descriptor",
kind);
return false;
}
case TypeCategory::Character:
switch (kind) {
case 1:
return FormattedCharacterIO<char, DIR>(io, descriptor);
case 2:
return FormattedCharacterIO<char16_t, DIR>(io, descriptor);
case 4:
return FormattedCharacterIO<char32_t, DIR>(io, descriptor);
default:
handler.Crash(
"DescriptorIO: Unimplemented CHARACTER kind (%d) in descriptor",
kind);
return false;
}
case TypeCategory::Logical:
switch (kind) {
case 1:
return FormattedLogicalIO<1, DIR>(io, descriptor);
case 2:
return FormattedLogicalIO<2, DIR>(io, descriptor);
case 4:
return FormattedLogicalIO<4, DIR>(io, descriptor);
case 8:
return FormattedLogicalIO<8, DIR>(io, descriptor);
default:
handler.Crash(
"DescriptorIO: Unimplemented LOGICAL kind (%d) in descriptor",
kind);
return false;
}
case TypeCategory::Derived:
return FormattedDerivedTypeIO<DIR>(io, descriptor);
}
}
handler.Crash("DescriptorIO: bad type code (%d) in descriptor",
static_cast<int>(descriptor.type().raw()));
return false;
}
} // namespace Fortran::runtime::io::descr
#endif // FORTRAN_RUNTIME_DESCRIPTOR_IO_H_