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llvm / llvm-project / 746e632dafbec2277c62164b3e63da4bee1d8553 / . / flang / lib / Lower / IO.cpp
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//===-- IO.cpp -- I/O statement lowering ----------------------------------===//
//
// 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/Lower/IO.h"
#include "RTBuilder.h"
#include "flang/Lower/Bridge.h"
#include "flang/Lower/CharacterExpr.h"
#include "flang/Lower/ComplexExpr.h"
#include "flang/Lower/FIRBuilder.h"
#include "flang/Lower/PFTBuilder.h"
#include "flang/Lower/Runtime.h"
#include "flang/Lower/Utils.h"
#include "flang/Parser/parse-tree.h"
#include "flang/Runtime/io-api.h"
#include "flang/Semantics/tools.h"
#include "mlir/Dialect/StandardOps/IR/Ops.h"
#define TODO() llvm_unreachable("not yet implemented")
using namespace Fortran::runtime::io;
#define NAMIFY_HELPER(X) #X
#define NAMIFY(X) NAMIFY_HELPER(IONAME(X))
#define mkIOKey(X) mkKey(IONAME(X))
namespace Fortran::lower {
/// Static table of IO runtime calls
///
/// This logical map contains the name and type builder function for each IO
/// runtime function listed in the tuple. This table is fully constructed at
/// compile-time. Use the `mkIOKey` macro to access the table.
static constexpr std::tuple<
mkIOKey(BeginInternalArrayListOutput), mkIOKey(BeginInternalArrayListInput),
mkIOKey(BeginInternalArrayFormattedOutput),
mkIOKey(BeginInternalArrayFormattedInput), mkIOKey(BeginInternalListOutput),
mkIOKey(BeginInternalListInput), mkIOKey(BeginInternalFormattedOutput),
mkIOKey(BeginInternalFormattedInput), mkIOKey(BeginExternalListOutput),
mkIOKey(BeginExternalListInput), mkIOKey(BeginExternalFormattedOutput),
mkIOKey(BeginExternalFormattedInput), mkIOKey(BeginUnformattedOutput),
mkIOKey(BeginUnformattedInput), mkIOKey(BeginAsynchronousOutput),
mkIOKey(BeginAsynchronousInput), mkIOKey(BeginWait), mkIOKey(BeginWaitAll),
mkIOKey(BeginClose), mkIOKey(BeginFlush), mkIOKey(BeginBackspace),
mkIOKey(BeginEndfile), mkIOKey(BeginRewind), mkIOKey(BeginOpenUnit),
mkIOKey(BeginOpenNewUnit), mkIOKey(BeginInquireUnit),
mkIOKey(BeginInquireFile), mkIOKey(BeginInquireIoLength),
mkIOKey(EnableHandlers), mkIOKey(SetAdvance), mkIOKey(SetBlank),
mkIOKey(SetDecimal), mkIOKey(SetDelim), mkIOKey(SetPad), mkIOKey(SetPos),
mkIOKey(SetRec), mkIOKey(SetRound), mkIOKey(SetSign),
mkIOKey(OutputDescriptor), mkIOKey(InputDescriptor),
mkIOKey(OutputUnformattedBlock), mkIOKey(InputUnformattedBlock),
mkIOKey(OutputInteger64), mkIOKey(InputInteger), mkIOKey(OutputReal32),
mkIOKey(InputReal32), mkIOKey(OutputReal64), mkIOKey(InputReal64),
mkIOKey(OutputComplex64), mkIOKey(OutputComplex32), mkIOKey(OutputAscii),
mkIOKey(InputAscii), mkIOKey(OutputLogical), mkIOKey(InputLogical),
mkIOKey(SetAccess), mkIOKey(SetAction), mkIOKey(SetAsynchronous),
mkIOKey(SetCarriagecontrol), mkIOKey(SetEncoding), mkIOKey(SetForm),
mkIOKey(SetPosition), mkIOKey(SetRecl), mkIOKey(SetStatus),
mkIOKey(SetFile), mkIOKey(GetNewUnit), mkIOKey(GetSize),
mkIOKey(GetIoLength), mkIOKey(GetIoMsg), mkIOKey(InquireCharacter),
mkIOKey(InquireLogical), mkIOKey(InquirePendingId),
mkIOKey(InquireInteger64), mkIOKey(EndIoStatement)>
newIOTable;
} // namespace Fortran::lower
namespace {
struct ConditionSpecifierInfo {
const Fortran::semantics::SomeExpr *ioStatExpr{};
const Fortran::semantics::SomeExpr *ioMsgExpr{};
bool hasErr{};
bool hasEnd{};
bool hasEor{};
/// Check for any condition specifier that applies to specifier processing.
bool hasErrorConditionSpecifier() const {
return ioStatExpr != nullptr || hasErr;
}
/// Check for any condition specifier that applies to data transfer items
/// in a PRINT, READ, WRITE, or WAIT statement. (WAIT may be irrelevant.)
bool hasTransferConditionSpecifier() const {
return ioStatExpr != nullptr || hasErr || hasEnd || hasEor;
}
/// Check for any condition specifier, including IOMSG.
bool hasAnyConditionSpecifier() const {
return ioStatExpr != nullptr || ioMsgExpr != nullptr || hasErr || hasEnd ||
hasEor;
}
};
} // namespace
using namespace Fortran::lower;
/// Helper function to retrieve the name of the IO function given the key `A`
template <typename A>
static constexpr const char *getName() {
return std::get<A>(newIOTable).name;
}
/// Helper function to retrieve the type model signature builder of the IO
/// function as defined by the key `A`
template <typename A>
static constexpr FuncTypeBuilderFunc getTypeModel() {
return std::get<A>(newIOTable).getTypeModel();
}
inline int64_t getLength(mlir::Type argTy) {
return argTy.cast<fir::SequenceType>().getShape()[0];
}
/// Get (or generate) the MLIR FuncOp for a given IO runtime function.
template <typename E>
static mlir::FuncOp getIORuntimeFunc(mlir::Location loc,
Fortran::lower::FirOpBuilder &builder) {
auto name = getName<E>();
auto func = builder.getNamedFunction(name);
if (func)
return func;
auto funTy = getTypeModel<E>()(builder.getContext());
func = builder.createFunction(loc, name, funTy);
func->setAttr("fir.runtime", builder.getUnitAttr());
func->setAttr("fir.io", builder.getUnitAttr());
return func;
}
/// Generate calls to end an IO statement. Return the IOSTAT value, if any.
/// It is the caller's responsibility to generate branches on that value.
static mlir::Value genEndIO(Fortran::lower::AbstractConverter &converter,
mlir::Location loc, mlir::Value cookie,
const ConditionSpecifierInfo &csi) {
auto &builder = converter.getFirOpBuilder();
if (csi.ioMsgExpr) {
auto getIoMsg = getIORuntimeFunc<mkIOKey(GetIoMsg)>(loc, builder);
auto ioMsgVar =
Fortran::lower::CharacterExprHelper{builder, loc}.createUnboxChar(
converter.genExprAddr(csi.ioMsgExpr, loc));
llvm::SmallVector<mlir::Value, 3> args{
cookie,
builder.createConvert(loc, getIoMsg.getType().getInput(1),
ioMsgVar.first),
builder.createConvert(loc, getIoMsg.getType().getInput(2),
ioMsgVar.second)};
builder.create<mlir::CallOp>(loc, getIoMsg, args);
}
auto endIoStatement = getIORuntimeFunc<mkIOKey(EndIoStatement)>(loc, builder);
llvm::SmallVector<mlir::Value, 1> endArgs{cookie};
auto call = builder.create<mlir::CallOp>(loc, endIoStatement, endArgs);
if (csi.ioStatExpr) {
auto ioStatVar = converter.genExprAddr(csi.ioStatExpr, loc);
auto ioStatResult = builder.createConvert(
loc, converter.genType(*csi.ioStatExpr), call.getResult(0));
builder.create<fir::StoreOp>(loc, ioStatResult, ioStatVar);
}
return csi.hasTransferConditionSpecifier() ? call.getResult(0)
: mlir::Value{};
}
/// Make the next call in the IO statement conditional on runtime result `ok`.
/// If a call returns `ok==false`, further suboperation calls for an I/O
/// statement will be skipped. This may generate branch heavy, deeply nested
/// conditionals for I/O statements with a large number of suboperations.
static void makeNextConditionalOn(Fortran::lower::FirOpBuilder &builder,
mlir::Location loc,
mlir::OpBuilder::InsertPoint &insertPt,
bool checkResult, mlir::Value ok,
bool inIterWhileLoop = false) {
if (!checkResult || !ok)
// Either I/O calls do not need to be checked, or the next I/O call is the
// first potentially fallable call.
return;
// A previous I/O call for a statement returned the bool `ok`. If this call
// is in a fir.iterate_while loop, the result must be propagated up to the
// loop scope. That is done in genIoLoop, but it is enabled here.
auto whereOp =
inIterWhileLoop
? builder.create<fir::IfOp>(loc, builder.getI1Type(), ok, true)
: builder.create<fir::IfOp>(loc, ok, /*withOtherwise=*/false);
if (!insertPt.isSet())
insertPt = builder.saveInsertionPoint();
builder.setInsertionPointToStart(&whereOp.thenRegion().front());
}
template <typename D>
static void genIoLoop(Fortran::lower::AbstractConverter &converter,
mlir::Value cookie, const D &ioImpliedDo,
bool checkResult, mlir::Value &ok, bool inIterWhileLoop);
/// Get the OutputXyz routine to output a value of the given type.
static mlir::FuncOp getOutputFunc(mlir::Location loc,
Fortran::lower::FirOpBuilder &builder,
mlir::Type type) {
if (auto ty = type.dyn_cast<mlir::IntegerType>())
return ty.getWidth() == 1
? getIORuntimeFunc<mkIOKey(OutputLogical)>(loc, builder)
: getIORuntimeFunc<mkIOKey(OutputInteger64)>(loc, builder);
if (auto ty = type.dyn_cast<mlir::FloatType>())
return ty.getWidth() <= 32
? getIORuntimeFunc<mkIOKey(OutputReal32)>(loc, builder)
: getIORuntimeFunc<mkIOKey(OutputReal64)>(loc, builder);
if (auto ty = type.dyn_cast<fir::ComplexType>())
return ty.getFKind() <= 4
? getIORuntimeFunc<mkIOKey(OutputComplex32)>(loc, builder)
: getIORuntimeFunc<mkIOKey(OutputComplex64)>(loc, builder);
if (type.isa<fir::LogicalType>())
return getIORuntimeFunc<mkIOKey(OutputLogical)>(loc, builder);
if (type.isa<fir::BoxType>())
return getIORuntimeFunc<mkIOKey(OutputDescriptor)>(loc, builder);
if (Fortran::lower::CharacterExprHelper::isCharacter(type))
return getIORuntimeFunc<mkIOKey(OutputAscii)>(loc, builder);
// TODO: handle arrays
mlir::emitError(loc, "output for entity type ") << type << " not implemented";
return {};
}
/// Generate a sequence of output data transfer calls.
static void
genOutputItemList(Fortran::lower::AbstractConverter &converter,
mlir::Value cookie,
const std::list<Fortran::parser::OutputItem> &items,
mlir::OpBuilder::InsertPoint &insertPt, bool checkResult,
mlir::Value &ok, bool inIterWhileLoop) {
auto &builder = converter.getFirOpBuilder();
for (auto &item : items) {
if (const auto &impliedDo = std::get_if<1>(&item.u)) {
genIoLoop(converter, cookie, impliedDo->value(), checkResult, ok,
inIterWhileLoop);
continue;
}
auto &pExpr = std::get<Fortran::parser::Expr>(item.u);
auto loc = converter.genLocation(pExpr.source);
makeNextConditionalOn(builder, loc, insertPt, checkResult, ok,
inIterWhileLoop);
auto itemValue =
converter.genExprValue(Fortran::semantics::GetExpr(pExpr), loc);
auto itemType = itemValue.getType();
auto outputFunc = getOutputFunc(loc, builder, itemType);
auto argType = outputFunc.getType().getInput(1);
llvm::SmallVector<mlir::Value, 3> outputFuncArgs = {cookie};
Fortran::lower::CharacterExprHelper helper{builder, loc};
if (helper.isCharacter(itemType)) {
auto dataLen = helper.materializeCharacter(itemValue);
outputFuncArgs.push_back(builder.createConvert(
loc, outputFunc.getType().getInput(1), dataLen.first));
outputFuncArgs.push_back(builder.createConvert(
loc, outputFunc.getType().getInput(2), dataLen.second));
} else if (fir::isa_complex(itemType)) {
auto parts = Fortran::lower::ComplexExprHelper{builder, loc}.extractParts(
itemValue);
outputFuncArgs.push_back(parts.first);
outputFuncArgs.push_back(parts.second);
} else {
itemValue = builder.createConvert(loc, argType, itemValue);
outputFuncArgs.push_back(itemValue);
}
ok = builder.create<mlir::CallOp>(loc, outputFunc, outputFuncArgs)
.getResult(0);
}
}
/// Get the InputXyz routine to input a value of the given type.
static mlir::FuncOp getInputFunc(mlir::Location loc,
Fortran::lower::FirOpBuilder &builder,
mlir::Type type) {
if (auto ty = type.dyn_cast<mlir::IntegerType>())
return ty.getWidth() == 1
? getIORuntimeFunc<mkIOKey(InputLogical)>(loc, builder)
: getIORuntimeFunc<mkIOKey(InputInteger)>(loc, builder);
if (auto ty = type.dyn_cast<mlir::FloatType>())
return ty.getWidth() <= 32
? getIORuntimeFunc<mkIOKey(InputReal32)>(loc, builder)
: getIORuntimeFunc<mkIOKey(InputReal64)>(loc, builder);
if (auto ty = type.dyn_cast<fir::ComplexType>())
return ty.getFKind() <= 4
? getIORuntimeFunc<mkIOKey(InputReal32)>(loc, builder)
: getIORuntimeFunc<mkIOKey(InputReal64)>(loc, builder);
if (type.isa<fir::LogicalType>())
return getIORuntimeFunc<mkIOKey(InputLogical)>(loc, builder);
if (type.isa<fir::BoxType>())
return getIORuntimeFunc<mkIOKey(InputDescriptor)>(loc, builder);
if (Fortran::lower::CharacterExprHelper::isCharacter(type))
return getIORuntimeFunc<mkIOKey(InputAscii)>(loc, builder);
// TODO: handle arrays
mlir::emitError(loc, "input for entity type ") << type << " not implemented";
return {};
}
/// Generate a sequence of input data transfer calls.
static void genInputItemList(Fortran::lower::AbstractConverter &converter,
mlir::Value cookie,
const std::list<Fortran::parser::InputItem> &items,
mlir::OpBuilder::InsertPoint &insertPt,
bool checkResult, mlir::Value &ok,
bool inIterWhileLoop) {
auto &builder = converter.getFirOpBuilder();
for (auto &item : items) {
if (const auto &impliedDo = std::get_if<1>(&item.u)) {
genIoLoop(converter, cookie, impliedDo->value(), checkResult, ok,
inIterWhileLoop);
continue;
}
auto &pVar = std::get<Fortran::parser::Variable>(item.u);
auto loc = converter.genLocation(pVar.GetSource());
makeNextConditionalOn(builder, loc, insertPt, checkResult, ok,
inIterWhileLoop);
auto itemAddr =
converter.genExprAddr(Fortran::semantics::GetExpr(pVar), loc);
auto itemType = itemAddr.getType().cast<fir::ReferenceType>().getEleTy();
auto inputFunc = getInputFunc(loc, builder, itemType);
auto argType = inputFunc.getType().getInput(1);
auto originalItemAddr = itemAddr;
mlir::Type complexPartType;
if (itemType.isa<fir::ComplexType>())
complexPartType = builder.getRefType(
Fortran::lower::ComplexExprHelper{builder, loc}.getComplexPartType(
itemType));
auto complexPartAddr = [&](int index) {
return builder.create<fir::CoordinateOp>(
loc, complexPartType, originalItemAddr,
llvm::SmallVector<mlir::Value, 1>{
builder.create<mlir::arith::ConstantOp>(
loc, builder.getI32IntegerAttr(index))});
};
if (complexPartType)
itemAddr = complexPartAddr(0); // real part
itemAddr = builder.createConvert(loc, argType, itemAddr);
llvm::SmallVector<mlir::Value, 3> inputFuncArgs = {cookie, itemAddr};
Fortran::lower::CharacterExprHelper helper{builder, loc};
if (helper.isCharacter(itemType)) {
auto len = helper.materializeCharacter(originalItemAddr).second;
inputFuncArgs.push_back(
builder.createConvert(loc, inputFunc.getType().getInput(2), len));
} else if (itemType.isa<mlir::IntegerType>()) {
inputFuncArgs.push_back(builder.create<mlir::arith::ConstantOp>(
loc, builder.getI32IntegerAttr(
itemType.cast<mlir::IntegerType>().getWidth() / 8)));
}
ok = builder.create<mlir::CallOp>(loc, inputFunc, inputFuncArgs)
.getResult(0);
if (complexPartType) { // imaginary part
makeNextConditionalOn(builder, loc, insertPt, checkResult, ok,
inIterWhileLoop);
inputFuncArgs = {cookie,
builder.createConvert(loc, argType, complexPartAddr(1))};
ok = builder.create<mlir::CallOp>(loc, inputFunc, inputFuncArgs)
.getResult(0);
}
}
}
/// Generate an io-implied-do loop.
template <typename D>
static void genIoLoop(Fortran::lower::AbstractConverter &converter,
mlir::Value cookie, const D &ioImpliedDo,
bool checkResult, mlir::Value &ok, bool inIterWhileLoop) {
mlir::OpBuilder::InsertPoint insertPt;
auto &builder = converter.getFirOpBuilder();
auto loc = converter.getCurrentLocation();
makeNextConditionalOn(builder, loc, insertPt, checkResult, ok,
inIterWhileLoop);
auto parentInsertPt = builder.saveInsertionPoint();
const auto &itemList = std::get<0>(ioImpliedDo.t);
const auto &control = std::get<1>(ioImpliedDo.t);
const auto &loopSym = *control.name.thing.thing.symbol;
auto loopVar = converter.getSymbolAddress(loopSym);
auto genFIRLoopIndex = [&](const Fortran::parser::ScalarIntExpr &expr) {
return builder.createConvert(
loc, builder.getIndexType(),
converter.genExprValue(*Fortran::semantics::GetExpr(expr)));
};
auto lowerValue = genFIRLoopIndex(control.lower);
auto upperValue = genFIRLoopIndex(control.upper);
auto stepValue = control.step.has_value()
? genFIRLoopIndex(*control.step)
: builder.create<mlir::arith::ConstantIndexOp>(loc, 1);
auto genItemList = [&](const D &ioImpliedDo, bool inIterWhileLoop) {
if constexpr (std::is_same_v<D, Fortran::parser::InputImpliedDo>)
genInputItemList(converter, cookie, itemList, insertPt, checkResult, ok,
true);
else
genOutputItemList(converter, cookie, itemList, insertPt, checkResult, ok,
true);
};
if (!checkResult) {
// No I/O call result checks - the loop is a fir.do_loop op.
auto loopOp =
builder.create<fir::DoLoopOp>(loc, lowerValue, upperValue, stepValue);
builder.setInsertionPointToStart(loopOp.getBody());
auto lcv = builder.createConvert(loc, converter.genType(loopSym),
loopOp.getInductionVar());
builder.create<fir::StoreOp>(loc, lcv, loopVar);
insertPt = builder.saveInsertionPoint();
genItemList(ioImpliedDo, false);
builder.restoreInsertionPoint(parentInsertPt);
return;
}
// Check I/O call results - the loop is a fir.iterate_while op.
if (!ok)
ok = builder.createIntegerConstant(loc, builder.getI1Type(), 1);
fir::IterWhileOp iterWhileOp = builder.create<fir::IterWhileOp>(
loc, lowerValue, upperValue, stepValue, ok);
builder.setInsertionPointToStart(iterWhileOp.getBody());
auto lcv = builder.createConvert(loc, converter.genType(loopSym),
iterWhileOp.getInductionVar());
builder.create<fir::StoreOp>(loc, lcv, loopVar);
insertPt = builder.saveInsertionPoint();
ok = iterWhileOp.getIterateVar();
auto falseValue = builder.createIntegerConstant(loc, builder.getI1Type(), 0);
genItemList(ioImpliedDo, true);
// Unwind nested I/O call scopes, filling in true and false ResultOp's.
for (auto *op = builder.getBlock()->getParentOp(); isa<fir::IfOp>(op);
op = op->getBlock()->getParentOp()) {
auto whereOp = dyn_cast<fir::IfOp>(op);
auto *lastOp = &whereOp.thenRegion().front().back();
builder.setInsertionPointAfter(lastOp);
builder.create<fir::ResultOp>(loc, lastOp->getResult(0)); // runtime result
builder.setInsertionPointToStart(&whereOp.elseRegion().front());
builder.create<fir::ResultOp>(loc, falseValue); // known false result
}
builder.restoreInsertionPoint(insertPt);
builder.create<fir::ResultOp>(loc, builder.getBlock()->back().getResult(0));
ok = iterWhileOp.getResult(0);
builder.restoreInsertionPoint(parentInsertPt);
}
//===----------------------------------------------------------------------===//
// Default argument generation.
//===----------------------------------------------------------------------===//
static mlir::Value getDefaultFilename(Fortran::lower::FirOpBuilder &builder,
mlir::Location loc, mlir::Type toType) {
mlir::Value null = builder.create<mlir::arith::ConstantOp>(
loc, builder.getI64IntegerAttr(0));
return builder.createConvert(loc, toType, null);
}
static mlir::Value getDefaultLineNo(Fortran::lower::FirOpBuilder &builder,
mlir::Location loc, mlir::Type toType) {
return builder.create<mlir::arith::ConstantOp>(
loc, builder.getIntegerAttr(toType, 0));
}
static mlir::Value getDefaultScratch(Fortran::lower::FirOpBuilder &builder,
mlir::Location loc, mlir::Type toType) {
mlir::Value null = builder.create<mlir::arith::ConstantOp>(
loc, builder.getI64IntegerAttr(0));
return builder.createConvert(loc, toType, null);
}
static mlir::Value getDefaultScratchLen(Fortran::lower::FirOpBuilder &builder,
mlir::Location loc, mlir::Type toType) {
return builder.create<mlir::arith::ConstantOp>(
loc, builder.getIntegerAttr(toType, 0));
}
/// Lower a string literal. Many arguments to the runtime are conveyed as
/// Fortran CHARACTER literals.
template <typename A>
static std::tuple<mlir::Value, mlir::Value, mlir::Value>
lowerStringLit(Fortran::lower::AbstractConverter &converter, mlir::Location loc,
const A &syntax, mlir::Type strTy, mlir::Type lenTy,
mlir::Type ty2 = {}) {
auto &builder = converter.getFirOpBuilder();
auto *expr = Fortran::semantics::GetExpr(syntax);
auto str = converter.genExprValue(expr, loc);
Fortran::lower::CharacterExprHelper helper{builder, loc};
auto dataLen = helper.materializeCharacter(str);
auto buff = builder.createConvert(loc, strTy, dataLen.first);
auto len = builder.createConvert(loc, lenTy, dataLen.second);
if (ty2) {
auto kindVal = helper.getCharacterKind(str.getType());
auto kind = builder.create<mlir::arith::ConstantOp>(
loc, builder.getIntegerAttr(ty2, kindVal));
return {buff, len, kind};
}
return {buff, len, mlir::Value{}};
}
/// Pass the body of the FORMAT statement in as if it were a CHARACTER literal
/// constant. NB: This is the prescribed manner in which the front-end passes
/// this information to lowering.
static std::tuple<mlir::Value, mlir::Value, mlir::Value>
lowerSourceTextAsStringLit(Fortran::lower::AbstractConverter &converter,
mlir::Location loc, llvm::StringRef text,
mlir::Type strTy, mlir::Type lenTy) {
text = text.drop_front(text.find('('));
text = text.take_front(text.rfind(')') + 1);
auto &builder = converter.getFirOpBuilder();
auto lit = builder.createStringLit(
loc, /*FIXME*/ fir::CharacterType::get(builder.getContext(), 1, 1), text);
auto data =
Fortran::lower::CharacterExprHelper{builder, loc}.materializeCharacter(
lit);
auto buff = builder.createConvert(loc, strTy, data.first);
auto len = builder.createConvert(loc, lenTy, data.second);
return {buff, len, mlir::Value{}};
}
//===----------------------------------------------------------------------===//
// Handle I/O statement specifiers.
// These are threaded together for a single statement via the passed cookie.
//===----------------------------------------------------------------------===//
/// Generic to build an integral argument to the runtime.
template <typename A, typename B>
mlir::Value genIntIOOption(Fortran::lower::AbstractConverter &converter,
mlir::Location loc, mlir::Value cookie,
const B &spec) {
auto &builder = converter.getFirOpBuilder();
mlir::FuncOp ioFunc = getIORuntimeFunc<A>(loc, builder);
mlir::FunctionType ioFuncTy = ioFunc.getType();
auto expr = converter.genExprValue(Fortran::semantics::GetExpr(spec.v), loc);
auto val = builder.createConvert(loc, ioFuncTy.getInput(1), expr);
llvm::SmallVector<mlir::Value, 4> ioArgs = {cookie, val};
return builder.create<mlir::CallOp>(loc, ioFunc, ioArgs).getResult(0);
}
/// Generic to build a string argument to the runtime. This passes a CHARACTER
/// as a pointer to the buffer and a LEN parameter.
template <typename A, typename B>
mlir::Value genCharIOOption(Fortran::lower::AbstractConverter &converter,
mlir::Location loc, mlir::Value cookie,
const B &spec) {
auto &builder = converter.getFirOpBuilder();
mlir::FuncOp ioFunc = getIORuntimeFunc<A>(loc, builder);
mlir::FunctionType ioFuncTy = ioFunc.getType();
auto tup = lowerStringLit(converter, loc, spec, ioFuncTy.getInput(1),
ioFuncTy.getInput(2));
llvm::SmallVector<mlir::Value, 4> ioArgs = {cookie, std::get<0>(tup),
std::get<1>(tup)};
return builder.create<mlir::CallOp>(loc, ioFunc, ioArgs).getResult(0);
}
template <typename A>
mlir::Value genIOOption(Fortran::lower::AbstractConverter &converter,
mlir::Location loc, mlir::Value cookie, const A &spec) {
// default case: do nothing
return {};
}
template <>
mlir::Value genIOOption<Fortran::parser::FileNameExpr>(
Fortran::lower::AbstractConverter &converter, mlir::Location loc,
mlir::Value cookie, const Fortran::parser::FileNameExpr &spec) {
auto &builder = converter.getFirOpBuilder();
// has an extra KIND argument
auto ioFunc = getIORuntimeFunc<mkIOKey(SetFile)>(loc, builder);
mlir::FunctionType ioFuncTy = ioFunc.getType();
auto tup = lowerStringLit(converter, loc, spec, ioFuncTy.getInput(1),
ioFuncTy.getInput(2), ioFuncTy.getInput(3));
llvm::SmallVector<mlir::Value, 4> ioArgs{cookie, std::get<0>(tup),
std::get<1>(tup), std::get<2>(tup)};
return builder.create<mlir::CallOp>(loc, ioFunc, ioArgs).getResult(0);
}
template <>
mlir::Value genIOOption<Fortran::parser::ConnectSpec::CharExpr>(
Fortran::lower::AbstractConverter &converter, mlir::Location loc,
mlir::Value cookie, const Fortran::parser::ConnectSpec::CharExpr &spec) {
auto &builder = converter.getFirOpBuilder();
mlir::FuncOp ioFunc;
switch (std::get<Fortran::parser::ConnectSpec::CharExpr::Kind>(spec.t)) {
case Fortran::parser::ConnectSpec::CharExpr::Kind::Access:
ioFunc = getIORuntimeFunc<mkIOKey(SetAccess)>(loc, builder);
break;
case Fortran::parser::ConnectSpec::CharExpr::Kind::Action:
ioFunc = getIORuntimeFunc<mkIOKey(SetAction)>(loc, builder);
break;
case Fortran::parser::ConnectSpec::CharExpr::Kind::Asynchronous:
ioFunc = getIORuntimeFunc<mkIOKey(SetAsynchronous)>(loc, builder);
break;
case Fortran::parser::ConnectSpec::CharExpr::Kind::Blank:
ioFunc = getIORuntimeFunc<mkIOKey(SetBlank)>(loc, builder);
break;
case Fortran::parser::ConnectSpec::CharExpr::Kind::Decimal:
ioFunc = getIORuntimeFunc<mkIOKey(SetDecimal)>(loc, builder);
break;
case Fortran::parser::ConnectSpec::CharExpr::Kind::Delim:
ioFunc = getIORuntimeFunc<mkIOKey(SetDelim)>(loc, builder);
break;
case Fortran::parser::ConnectSpec::CharExpr::Kind::Encoding:
ioFunc = getIORuntimeFunc<mkIOKey(SetEncoding)>(loc, builder);
break;
case Fortran::parser::ConnectSpec::CharExpr::Kind::Form:
ioFunc = getIORuntimeFunc<mkIOKey(SetForm)>(loc, builder);
break;
case Fortran::parser::ConnectSpec::CharExpr::Kind::Pad:
ioFunc = getIORuntimeFunc<mkIOKey(SetPad)>(loc, builder);
break;
case Fortran::parser::ConnectSpec::CharExpr::Kind::Position:
ioFunc = getIORuntimeFunc<mkIOKey(SetPosition)>(loc, builder);
break;
case Fortran::parser::ConnectSpec::CharExpr::Kind::Round:
ioFunc = getIORuntimeFunc<mkIOKey(SetRound)>(loc, builder);
break;
case Fortran::parser::ConnectSpec::CharExpr::Kind::Sign:
ioFunc = getIORuntimeFunc<mkIOKey(SetSign)>(loc, builder);
break;
case Fortran::parser::ConnectSpec::CharExpr::Kind::Carriagecontrol:
ioFunc = getIORuntimeFunc<mkIOKey(SetCarriagecontrol)>(loc, builder);
break;
case Fortran::parser::ConnectSpec::CharExpr::Kind::Convert:
llvm_unreachable("CONVERT not part of the runtime::io interface");
case Fortran::parser::ConnectSpec::CharExpr::Kind::Dispose:
llvm_unreachable("DISPOSE not part of the runtime::io interface");
}
mlir::FunctionType ioFuncTy = ioFunc.getType();
auto tup = lowerStringLit(
converter, loc, std::get<Fortran::parser::ScalarDefaultCharExpr>(spec.t),
ioFuncTy.getInput(1), ioFuncTy.getInput(2));
llvm::SmallVector<mlir::Value, 4> ioArgs = {cookie, std::get<0>(tup),
std::get<1>(tup)};
return builder.create<mlir::CallOp>(loc, ioFunc, ioArgs).getResult(0);
}
template <>
mlir::Value genIOOption<Fortran::parser::ConnectSpec::Recl>(
Fortran::lower::AbstractConverter &converter, mlir::Location loc,
mlir::Value cookie, const Fortran::parser::ConnectSpec::Recl &spec) {
return genIntIOOption<mkIOKey(SetRecl)>(converter, loc, cookie, spec);
}
template <>
mlir::Value genIOOption<Fortran::parser::StatusExpr>(
Fortran::lower::AbstractConverter &converter, mlir::Location loc,
mlir::Value cookie, const Fortran::parser::StatusExpr &spec) {
return genCharIOOption<mkIOKey(SetStatus)>(converter, loc, cookie, spec.v);
}
template <>
mlir::Value
genIOOption<Fortran::parser::Name>(Fortran::lower::AbstractConverter &converter,
mlir::Location loc, mlir::Value cookie,
const Fortran::parser::Name &spec) {
// namelist
llvm_unreachable("not implemented");
}
template <>
mlir::Value genIOOption<Fortran::parser::IoControlSpec::CharExpr>(
Fortran::lower::AbstractConverter &converter, mlir::Location loc,
mlir::Value cookie, const Fortran::parser::IoControlSpec::CharExpr &spec) {
auto &builder = converter.getFirOpBuilder();
mlir::FuncOp ioFunc;
switch (std::get<Fortran::parser::IoControlSpec::CharExpr::Kind>(spec.t)) {
case Fortran::parser::IoControlSpec::CharExpr::Kind::Advance:
ioFunc = getIORuntimeFunc<mkIOKey(SetAdvance)>(loc, builder);
break;
case Fortran::parser::IoControlSpec::CharExpr::Kind::Blank:
ioFunc = getIORuntimeFunc<mkIOKey(SetBlank)>(loc, builder);
break;
case Fortran::parser::IoControlSpec::CharExpr::Kind::Decimal:
ioFunc = getIORuntimeFunc<mkIOKey(SetDecimal)>(loc, builder);
break;
case Fortran::parser::IoControlSpec::CharExpr::Kind::Delim:
ioFunc = getIORuntimeFunc<mkIOKey(SetDelim)>(loc, builder);
break;
case Fortran::parser::IoControlSpec::CharExpr::Kind::Pad:
ioFunc = getIORuntimeFunc<mkIOKey(SetPad)>(loc, builder);
break;
case Fortran::parser::IoControlSpec::CharExpr::Kind::Round:
ioFunc = getIORuntimeFunc<mkIOKey(SetRound)>(loc, builder);
break;
case Fortran::parser::IoControlSpec::CharExpr::Kind::Sign:
ioFunc = getIORuntimeFunc<mkIOKey(SetSign)>(loc, builder);
break;
}
mlir::FunctionType ioFuncTy = ioFunc.getType();
auto tup = lowerStringLit(
converter, loc, std::get<Fortran::parser::ScalarDefaultCharExpr>(spec.t),
ioFuncTy.getInput(1), ioFuncTy.getInput(2));
llvm::SmallVector<mlir::Value, 4> ioArgs = {cookie, std::get<0>(tup),
std::get<1>(tup)};
return builder.create<mlir::CallOp>(loc, ioFunc, ioArgs).getResult(0);
}
template <>
mlir::Value genIOOption<Fortran::parser::IoControlSpec::Asynchronous>(
Fortran::lower::AbstractConverter &converter, mlir::Location loc,
mlir::Value cookie,
const Fortran::parser::IoControlSpec::Asynchronous &spec) {
return genCharIOOption<mkIOKey(SetAsynchronous)>(converter, loc, cookie,
spec.v);
}
template <>
mlir::Value genIOOption<Fortran::parser::IdVariable>(
Fortran::lower::AbstractConverter &converter, mlir::Location loc,
mlir::Value cookie, const Fortran::parser::IdVariable &spec) {
llvm_unreachable("asynchronous ID not implemented");
}
template <>
mlir::Value genIOOption<Fortran::parser::IoControlSpec::Pos>(
Fortran::lower::AbstractConverter &converter, mlir::Location loc,
mlir::Value cookie, const Fortran::parser::IoControlSpec::Pos &spec) {
return genIntIOOption<mkIOKey(SetPos)>(converter, loc, cookie, spec);
}
template <>
mlir::Value genIOOption<Fortran::parser::IoControlSpec::Rec>(
Fortran::lower::AbstractConverter &converter, mlir::Location loc,
mlir::Value cookie, const Fortran::parser::IoControlSpec::Rec &spec) {
return genIntIOOption<mkIOKey(SetRec)>(converter, loc, cookie, spec);
}
//===----------------------------------------------------------------------===//
// Gather I/O statement condition specifier information (if any).
//===----------------------------------------------------------------------===//
template <typename SEEK, typename A>
static bool hasX(const A &list) {
for (const auto &spec : list)
if (std::holds_alternative<SEEK>(spec.u))
return true;
return false;
}
template <typename SEEK, typename A>
static bool hasMem(const A &stmt) {
return hasX<SEEK>(stmt.v);
}
/// Get the sought expression from the specifier list.
template <typename SEEK, typename A>
static const Fortran::semantics::SomeExpr *getExpr(const A &stmt) {
for (const auto &spec : stmt.v)
if (auto *f = std::get_if<SEEK>(&spec.u))
return Fortran::semantics::GetExpr(f->v);
llvm_unreachable("must have a file unit");
}
/// For each specifier, build the appropriate call, threading the cookie, and
/// returning the insertion point as to the initial context. If there are no
/// specifiers, the insertion point is undefined.
template <typename A>
static mlir::OpBuilder::InsertPoint
threadSpecs(Fortran::lower::AbstractConverter &converter, mlir::Location loc,
mlir::Value cookie, const A &specList, bool checkResult,
mlir::Value &ok) {
auto &builder = converter.getFirOpBuilder();
mlir::OpBuilder::InsertPoint insertPt;
for (const auto &spec : specList) {
makeNextConditionalOn(builder, loc, insertPt, checkResult, ok);
ok = std::visit(Fortran::common::visitors{[&](const auto &x) {
return genIOOption(converter, loc, cookie, x);
}},
spec.u);
}
return insertPt;
}
template <typename A>
static void
genConditionHandlerCall(Fortran::lower::AbstractConverter &converter,
mlir::Location loc, mlir::Value cookie,
const A &specList, ConditionSpecifierInfo &csi) {
for (const auto &spec : specList) {
std::visit(
Fortran::common::visitors{
[&](const Fortran::parser::StatVariable &msgVar) {
csi.ioStatExpr = Fortran::semantics::GetExpr(msgVar);
},
[&](const Fortran::parser::MsgVariable &msgVar) {
csi.ioMsgExpr = Fortran::semantics::GetExpr(msgVar);
},
[&](const Fortran::parser::EndLabel &) { csi.hasEnd = true; },
[&](const Fortran::parser::EorLabel &) { csi.hasEor = true; },
[&](const Fortran::parser::ErrLabel &) { csi.hasErr = true; },
[](const auto &) {}},
spec.u);
}
if (!csi.hasAnyConditionSpecifier())
return;
auto &builder = converter.getFirOpBuilder();
mlir::FuncOp enableHandlers =
getIORuntimeFunc<mkIOKey(EnableHandlers)>(loc, builder);
mlir::Type boolType = enableHandlers.getType().getInput(1);
auto boolValue = [&](bool specifierIsPresent) {
return builder.create<mlir::arith::ConstantOp>(
loc, builder.getIntegerAttr(boolType, specifierIsPresent));
};
llvm::SmallVector<mlir::Value, 6> ioArgs = {
cookie,
boolValue(csi.ioStatExpr != nullptr),
boolValue(csi.hasErr),
boolValue(csi.hasEnd),
boolValue(csi.hasEor),
boolValue(csi.ioMsgExpr != nullptr)};
builder.create<mlir::CallOp>(loc, enableHandlers, ioArgs);
}
//===----------------------------------------------------------------------===//
// Data transfer helpers
//===----------------------------------------------------------------------===//
template <typename SEEK, typename A>
static bool hasIOControl(const A &stmt) {
return hasX<SEEK>(stmt.controls);
}
template <typename SEEK, typename A>
static const auto *getIOControl(const A &stmt) {
for (const auto &spec : stmt.controls)
if (const auto *result = std::get_if<SEEK>(&spec.u))
return result;
return static_cast<const SEEK *>(nullptr);
}
/// returns true iff the expression in the parse tree is not really a format but
/// rather a namelist group
template <typename A>
static bool formatIsActuallyNamelist(const A &format) {
if (auto *e = std::get_if<Fortran::parser::Expr>(&format.u)) {
auto *expr = Fortran::semantics::GetExpr(*e);
if (const Fortran::semantics::Symbol *y =
Fortran::evaluate::UnwrapWholeSymbolDataRef(*expr))
return y->has<Fortran::semantics::NamelistDetails>();
}
return false;
}
template <typename A>
static bool isDataTransferFormatted(const A &stmt) {
if (stmt.format)
return !formatIsActuallyNamelist(*stmt.format);
return hasIOControl<Fortran::parser::Format>(stmt);
}
template <>
constexpr bool isDataTransferFormatted<Fortran::parser::PrintStmt>(
const Fortran::parser::PrintStmt &) {
return true; // PRINT is always formatted
}
template <typename A>
static bool isDataTransferList(const A &stmt) {
if (stmt.format)
return std::holds_alternative<Fortran::parser::Star>(stmt.format->u);
if (auto *mem = getIOControl<Fortran::parser::Format>(stmt))
return std::holds_alternative<Fortran::parser::Star>(mem->u);
return false;
}
template <>
bool isDataTransferList<Fortran::parser::PrintStmt>(
const Fortran::parser::PrintStmt &stmt) {
return std::holds_alternative<Fortran::parser::Star>(
std::get<Fortran::parser::Format>(stmt.t).u);
}
template <typename A>
static bool isDataTransferInternal(const A &stmt) {
if (stmt.iounit.has_value())
return std::holds_alternative<Fortran::parser::Variable>(stmt.iounit->u);
if (auto *unit = getIOControl<Fortran::parser::IoUnit>(stmt))
return std::holds_alternative<Fortran::parser::Variable>(unit->u);
return false;
}
template <>
constexpr bool isDataTransferInternal<Fortran::parser::PrintStmt>(
const Fortran::parser::PrintStmt &) {
return false;
}
static bool hasNonDefaultCharKind(const Fortran::parser::Variable &var) {
// TODO
return false;
}
template <typename A>
static bool isDataTransferInternalNotDefaultKind(const A &stmt) {
// same as isDataTransferInternal, but the KIND of the expression is not the
// default KIND.
if (stmt.iounit.has_value())
if (auto *var = std::get_if<Fortran::parser::Variable>(&stmt.iounit->u))
return hasNonDefaultCharKind(*var);
if (auto *unit = getIOControl<Fortran::parser::IoUnit>(stmt))
if (auto *var = std::get_if<Fortran::parser::Variable>(&unit->u))
return hasNonDefaultCharKind(*var);
return false;
}
template <>
constexpr bool isDataTransferInternalNotDefaultKind<Fortran::parser::PrintStmt>(
const Fortran::parser::PrintStmt &) {
return false;
}
template <typename A>
static bool isDataTransferAsynchronous(const A &stmt) {
if (auto *asynch =
getIOControl<Fortran::parser::IoControlSpec::Asynchronous>(stmt)) {
// FIXME: should contain a string of YES or NO
llvm_unreachable("asynchronous transfers not implemented in runtime");
}
return false;
}
template <>
constexpr bool isDataTransferAsynchronous<Fortran::parser::PrintStmt>(
const Fortran::parser::PrintStmt &) {
return false;
}
template <typename A>
static bool isDataTransferNamelist(const A &stmt) {
if (stmt.format)
return formatIsActuallyNamelist(*stmt.format);
return hasIOControl<Fortran::parser::Name>(stmt);
}
template <>
constexpr bool isDataTransferNamelist<Fortran::parser::PrintStmt>(
const Fortran::parser::PrintStmt &) {
return false;
}
/// Generate a reference to a format string. There are four cases - a format
/// statement label, a character format expression, an integer that holds the
/// label of a format statement, and the * case. The first three are done here.
/// The * case is done elsewhere.
static std::tuple<mlir::Value, mlir::Value, mlir::Value>
genFormat(Fortran::lower::AbstractConverter &converter, mlir::Location loc,
const Fortran::parser::Format &format, mlir::Type strTy,
mlir::Type lenTy, Fortran::lower::pft::LabelEvalMap &labelMap,
Fortran::lower::pft::SymbolLabelMap &assignMap) {
if (const auto *label = std::get_if<Fortran::parser::Label>(&format.u)) {
// format statement label
auto iter = labelMap.find(*label);
assert(iter != labelMap.end() && "FORMAT not found in PROCEDURE");
return lowerSourceTextAsStringLit(
converter, loc, toStringRef(iter->second->position), strTy, lenTy);
}
const auto *pExpr = std::get_if<Fortran::parser::Expr>(&format.u);
assert(pExpr && "missing format expression");
auto e = Fortran::semantics::GetExpr(*pExpr);
if (Fortran::semantics::ExprHasTypeCategory(
*e, Fortran::common::TypeCategory::Character))
// character expression
return lowerStringLit(converter, loc, *pExpr, strTy, lenTy);
// integer variable containing an ASSIGN label
assert(Fortran::semantics::ExprHasTypeCategory(
*e, Fortran::common::TypeCategory::Integer));
// TODO - implement this
llvm::report_fatal_error(
"using a variable to reference a FORMAT statement; not implemented yet");
}
template <typename A>
std::tuple<mlir::Value, mlir::Value, mlir::Value>
getFormat(Fortran::lower::AbstractConverter &converter, mlir::Location loc,
const A &stmt, mlir::Type strTy, mlir::Type lenTy,
Fortran::lower::pft::LabelEvalMap &labelMap,
Fortran::lower::pft::SymbolLabelMap &assignMap) {
if (stmt.format && !formatIsActuallyNamelist(*stmt.format))
return genFormat(converter, loc, *stmt.format, strTy, lenTy, labelMap,
assignMap);
return genFormat(converter, loc, *getIOControl<Fortran::parser::Format>(stmt),
strTy, lenTy, labelMap, assignMap);
}
template <>
std::tuple<mlir::Value, mlir::Value, mlir::Value>
getFormat<Fortran::parser::PrintStmt>(
Fortran::lower::AbstractConverter &converter, mlir::Location loc,
const Fortran::parser::PrintStmt &stmt, mlir::Type strTy, mlir::Type lenTy,
Fortran::lower::pft::LabelEvalMap &labelMap,
Fortran::lower::pft::SymbolLabelMap &assignMap) {
return genFormat(converter, loc, std::get<Fortran::parser::Format>(stmt.t),
strTy, lenTy, labelMap, assignMap);
}
static std::tuple<mlir::Value, mlir::Value, mlir::Value>
genBuffer(Fortran::lower::AbstractConverter &converter, mlir::Location loc,
const Fortran::parser::IoUnit &iounit, mlir::Type strTy,
mlir::Type lenTy) {
[[maybe_unused]] auto &var = std::get<Fortran::parser::Variable>(iounit.u);
TODO();
}
template <typename A>
std::tuple<mlir::Value, mlir::Value, mlir::Value>
getBuffer(Fortran::lower::AbstractConverter &converter, mlir::Location loc,
const A &stmt, mlir::Type strTy, mlir::Type lenTy) {
if (stmt.iounit)
return genBuffer(converter, loc, *stmt.iounit, strTy, lenTy);
return genBuffer(converter, loc, *getIOControl<Fortran::parser::IoUnit>(stmt),
strTy, lenTy);
}
template <typename A>
mlir::Value getDescriptor(Fortran::lower::AbstractConverter &converter,
mlir::Location loc, const A &stmt,
mlir::Type toType) {
TODO();
}
static mlir::Value genIOUnit(Fortran::lower::AbstractConverter &converter,
mlir::Location loc,
const Fortran::parser::IoUnit &iounit,
mlir::Type ty) {
auto &builder = converter.getFirOpBuilder();
if (auto *e = std::get_if<Fortran::parser::FileUnitNumber>(&iounit.u)) {
auto ex = converter.genExprValue(Fortran::semantics::GetExpr(*e), loc);
return builder.createConvert(loc, ty, ex);
}
return builder.create<mlir::arith::ConstantOp>(
loc, builder.getIntegerAttr(ty, Fortran::runtime::io::DefaultUnit));
}
template <typename A>
mlir::Value getIOUnit(Fortran::lower::AbstractConverter &converter,
mlir::Location loc, const A &stmt, mlir::Type ty) {
if (stmt.iounit)
return genIOUnit(converter, loc, *stmt.iounit, ty);
return genIOUnit(converter, loc, *getIOControl<Fortran::parser::IoUnit>(stmt),
ty);
}
//===----------------------------------------------------------------------===//
// Generators for each I/O statement type.
//===----------------------------------------------------------------------===//
template <typename K, typename S>
static mlir::Value genBasicIOStmt(Fortran::lower::AbstractConverter &converter,
const S &stmt) {
auto &builder = converter.getFirOpBuilder();
auto loc = converter.getCurrentLocation();
auto beginFunc = getIORuntimeFunc<K>(loc, builder);
mlir::FunctionType beginFuncTy = beginFunc.getType();
auto unit = converter.genExprValue(
getExpr<Fortran::parser::FileUnitNumber>(stmt), loc);
auto un = builder.createConvert(loc, beginFuncTy.getInput(0), unit);
auto file = getDefaultFilename(builder, loc, beginFuncTy.getInput(1));
auto line = getDefaultLineNo(builder, loc, beginFuncTy.getInput(2));
llvm::SmallVector<mlir::Value, 4> args{un, file, line};
auto cookie = builder.create<mlir::CallOp>(loc, beginFunc, args).getResult(0);
ConditionSpecifierInfo csi{};
genConditionHandlerCall(converter, loc, cookie, stmt.v, csi);
mlir::Value ok{};
auto insertPt = threadSpecs(converter, loc, cookie, stmt.v,
csi.hasErrorConditionSpecifier(), ok);
if (insertPt.isSet())
builder.restoreInsertionPoint(insertPt);
return genEndIO(converter, converter.getCurrentLocation(), cookie, csi);
}
mlir::Value Fortran::lower::genBackspaceStatement(
Fortran::lower::AbstractConverter &converter,
const Fortran::parser::BackspaceStmt &stmt) {
return genBasicIOStmt<mkIOKey(BeginBackspace)>(converter, stmt);
}
mlir::Value Fortran::lower::genEndfileStatement(
Fortran::lower::AbstractConverter &converter,
const Fortran::parser::EndfileStmt &stmt) {
return genBasicIOStmt<mkIOKey(BeginEndfile)>(converter, stmt);
}
mlir::Value
Fortran::lower::genFlushStatement(Fortran::lower::AbstractConverter &converter,
const Fortran::parser::FlushStmt &stmt) {
return genBasicIOStmt<mkIOKey(BeginFlush)>(converter, stmt);
}
mlir::Value
Fortran::lower::genRewindStatement(Fortran::lower::AbstractConverter &converter,
const Fortran::parser::RewindStmt &stmt) {
return genBasicIOStmt<mkIOKey(BeginRewind)>(converter, stmt);
}
mlir::Value
Fortran::lower::genOpenStatement(Fortran::lower::AbstractConverter &converter,
const Fortran::parser::OpenStmt &stmt) {
auto &builder = converter.getFirOpBuilder();
mlir::FuncOp beginFunc;
llvm::SmallVector<mlir::Value, 4> beginArgs;
auto loc = converter.getCurrentLocation();
if (hasMem<Fortran::parser::FileUnitNumber>(stmt)) {
beginFunc = getIORuntimeFunc<mkIOKey(BeginOpenUnit)>(loc, builder);
mlir::FunctionType beginFuncTy = beginFunc.getType();
auto unit = converter.genExprValue(
getExpr<Fortran::parser::FileUnitNumber>(stmt), loc);
beginArgs.push_back(
builder.createConvert(loc, beginFuncTy.getInput(0), unit));
beginArgs.push_back(
getDefaultFilename(builder, loc, beginFuncTy.getInput(1)));
beginArgs.push_back(
getDefaultLineNo(builder, loc, beginFuncTy.getInput(2)));
} else {
assert(hasMem<Fortran::parser::ConnectSpec::Newunit>(stmt));
beginFunc = getIORuntimeFunc<mkIOKey(BeginOpenNewUnit)>(loc, builder);
mlir::FunctionType beginFuncTy = beginFunc.getType();
beginArgs.push_back(
getDefaultFilename(builder, loc, beginFuncTy.getInput(0)));
beginArgs.push_back(
getDefaultLineNo(builder, loc, beginFuncTy.getInput(1)));
}
auto cookie =
builder.create<mlir::CallOp>(loc, beginFunc, beginArgs).getResult(0);
ConditionSpecifierInfo csi{};
genConditionHandlerCall(converter, loc, cookie, stmt.v, csi);
mlir::Value ok{};
auto insertPt = threadSpecs(converter, loc, cookie, stmt.v,
csi.hasErrorConditionSpecifier(), ok);
if (insertPt.isSet())
builder.restoreInsertionPoint(insertPt);
return genEndIO(converter, loc, cookie, csi);
}
mlir::Value
Fortran::lower::genCloseStatement(Fortran::lower::AbstractConverter &converter,
const Fortran::parser::CloseStmt &stmt) {
return genBasicIOStmt<mkIOKey(BeginClose)>(converter, stmt);
}
mlir::Value
Fortran::lower::genWaitStatement(Fortran::lower::AbstractConverter &converter,
const Fortran::parser::WaitStmt &stmt) {
auto &builder = converter.getFirOpBuilder();
auto loc = converter.getCurrentLocation();
bool hasId = hasMem<Fortran::parser::IdExpr>(stmt);
mlir::FuncOp beginFunc =
hasId ? getIORuntimeFunc<mkIOKey(BeginWait)>(loc, builder)
: getIORuntimeFunc<mkIOKey(BeginWaitAll)>(loc, builder);
mlir::FunctionType beginFuncTy = beginFunc.getType();
auto unit = converter.genExprValue(
getExpr<Fortran::parser::FileUnitNumber>(stmt), loc);
auto un = builder.createConvert(loc, beginFuncTy.getInput(0), unit);
llvm::SmallVector<mlir::Value, 4> args{un};
if (hasId) {
auto id =
converter.genExprValue(getExpr<Fortran::parser::IdExpr>(stmt), loc);
args.push_back(builder.createConvert(loc, beginFuncTy.getInput(1), id));
}
auto cookie = builder.create<mlir::CallOp>(loc, beginFunc, args).getResult(0);
ConditionSpecifierInfo csi{};
genConditionHandlerCall(converter, loc, cookie, stmt.v, csi);
return genEndIO(converter, converter.getCurrentLocation(), cookie, csi);
}
//===----------------------------------------------------------------------===//
// Data transfer statements.
//
// There are several dimensions to the API with regard to data transfer
// statements that need to be considered.
//
// - input (READ) vs. output (WRITE, PRINT)
// - formatted vs. list vs. unformatted
// - synchronous vs. asynchronous
// - namelist vs. list
// - external vs. internal + default KIND vs. internal + other KIND
//===----------------------------------------------------------------------===//
// Determine the correct BeginXyz{In|Out}put api to invoke.
template <bool isInput>
mlir::FuncOp getBeginDataTransfer(mlir::Location loc, FirOpBuilder &builder,
bool isFormatted, bool isList, bool isIntern,
bool isOtherIntern, bool isAsynch,
bool isNml) {
if constexpr (isInput) {
if (isAsynch)
return getIORuntimeFunc<mkIOKey(BeginAsynchronousInput)>(loc, builder);
if (isFormatted) {
if (isIntern) {
if (isOtherIntern) {
if (isList || isNml)
return getIORuntimeFunc<mkIOKey(BeginInternalArrayListInput)>(
loc, builder);
return getIORuntimeFunc<mkIOKey(BeginInternalArrayFormattedInput)>(
loc, builder);
}
if (isList || isNml)
return getIORuntimeFunc<mkIOKey(BeginInternalListInput)>(loc,
builder);
return getIORuntimeFunc<mkIOKey(BeginInternalFormattedInput)>(loc,
builder);
}
if (isList || isNml)
return getIORuntimeFunc<mkIOKey(BeginExternalListInput)>(loc, builder);
return getIORuntimeFunc<mkIOKey(BeginExternalFormattedInput)>(loc,
builder);
}
return getIORuntimeFunc<mkIOKey(BeginUnformattedInput)>(loc, builder);
} else {
if (isAsynch)
return getIORuntimeFunc<mkIOKey(BeginAsynchronousOutput)>(loc, builder);
if (isFormatted) {
if (isIntern) {
if (isOtherIntern) {
if (isList || isNml)
return getIORuntimeFunc<mkIOKey(BeginInternalArrayListOutput)>(
loc, builder);
return getIORuntimeFunc<mkIOKey(BeginInternalArrayFormattedOutput)>(
loc, builder);
}
if (isList || isNml)
return getIORuntimeFunc<mkIOKey(BeginInternalListOutput)>(loc,
builder);
return getIORuntimeFunc<mkIOKey(BeginInternalFormattedOutput)>(loc,
builder);
}
if (isList || isNml)
return getIORuntimeFunc<mkIOKey(BeginExternalListOutput)>(loc, builder);
return getIORuntimeFunc<mkIOKey(BeginExternalFormattedOutput)>(loc,
builder);
}
return getIORuntimeFunc<mkIOKey(BeginUnformattedOutput)>(loc, builder);
}
}
/// Generate the arguments of a BeginXyz call.
template <bool hasIOCtrl, typename A>
void genBeginCallArguments(llvm::SmallVector<mlir::Value, 8> &ioArgs,
Fortran::lower::AbstractConverter &converter,
mlir::Location loc, const A &stmt,
mlir::FunctionType ioFuncTy, bool isFormatted,
bool isList, bool isIntern, bool isOtherIntern,
bool isAsynch, bool isNml,
Fortran::lower::pft::LabelEvalMap &labelMap,
Fortran::lower::pft::SymbolLabelMap &assignMap) {
auto &builder = converter.getFirOpBuilder();
if constexpr (hasIOCtrl) {
// READ/WRITE cases have a wide variety of argument permutations
if (isAsynch || !isFormatted) {
// unit (always first), ...
ioArgs.push_back(
getIOUnit(converter, loc, stmt, ioFuncTy.getInput(ioArgs.size())));
if (isAsynch) {
// unknown-thingy, [buff, LEN]
llvm_unreachable("not implemented");
}
return;
}
assert(isFormatted && "formatted data transfer");
if (!isIntern) {
if (isNml) {
// namelist group, ...
llvm_unreachable("not implemented");
} else if (!isList) {
// | [format, LEN], ...
auto pair = getFormat(
converter, loc, stmt, ioFuncTy.getInput(ioArgs.size()),
ioFuncTy.getInput(ioArgs.size() + 1), labelMap, assignMap);
ioArgs.push_back(std::get<0>(pair));
ioArgs.push_back(std::get<1>(pair));
}
// unit (always last)
ioArgs.push_back(
getIOUnit(converter, loc, stmt, ioFuncTy.getInput(ioArgs.size())));
return;
}
assert(isIntern && "internal data transfer");
if (isNml || isOtherIntern) {
// descriptor, ...
ioArgs.push_back(getDescriptor(converter, loc, stmt,
ioFuncTy.getInput(ioArgs.size())));
if (isNml) {
// namelist group, ...
llvm_unreachable("not implemented");
} else if (isOtherIntern && !isList) {
// | [format, LEN], ...
auto pair = getFormat(
converter, loc, stmt, ioFuncTy.getInput(ioArgs.size()),
ioFuncTy.getInput(ioArgs.size() + 1), labelMap, assignMap);
ioArgs.push_back(std::get<0>(pair));
ioArgs.push_back(std::get<1>(pair));
}
} else {
// | [buff, LEN], ...
auto pair =
getBuffer(converter, loc, stmt, ioFuncTy.getInput(ioArgs.size()),
ioFuncTy.getInput(ioArgs.size() + 1));
ioArgs.push_back(std::get<0>(pair));
ioArgs.push_back(std::get<1>(pair));
if (!isList) {
// [format, LEN], ...
auto pair = getFormat(
converter, loc, stmt, ioFuncTy.getInput(ioArgs.size()),
ioFuncTy.getInput(ioArgs.size() + 1), labelMap, assignMap);
ioArgs.push_back(std::get<0>(pair));
ioArgs.push_back(std::get<1>(pair));
}
}
// [scratch, LEN] (always last)
ioArgs.push_back(
getDefaultScratch(builder, loc, ioFuncTy.getInput(ioArgs.size())));
ioArgs.push_back(
getDefaultScratchLen(builder, loc, ioFuncTy.getInput(ioArgs.size())));
} else {
if (!isList) {
// [format, LEN], ...
auto pair =
getFormat(converter, loc, stmt, ioFuncTy.getInput(ioArgs.size()),
ioFuncTy.getInput(ioArgs.size() + 1), labelMap, assignMap);
ioArgs.push_back(std::get<0>(pair));
ioArgs.push_back(std::get<1>(pair));
}
// unit (always last)
ioArgs.push_back(builder.create<mlir::arith::ConstantOp>(
loc, builder.getIntegerAttr(ioFuncTy.getInput(ioArgs.size()),
Fortran::runtime::io::DefaultUnit)));
}
}
template <bool isInput, bool hasIOCtrl = true, typename A>
static mlir::Value
genDataTransferStmt(Fortran::lower::AbstractConverter &converter, const A &stmt,
Fortran::lower::pft::LabelEvalMap &labelMap,
Fortran::lower::pft::SymbolLabelMap &assignMap) {
auto &builder = converter.getFirOpBuilder();
auto loc = converter.getCurrentLocation();
const bool isFormatted = isDataTransferFormatted(stmt);
const bool isList = isFormatted ? isDataTransferList(stmt) : false;
const bool isIntern = isDataTransferInternal(stmt);
const bool isOtherIntern =
isIntern ? isDataTransferInternalNotDefaultKind(stmt) : false;
const bool isAsynch = isDataTransferAsynchronous(stmt);
const bool isNml = isDataTransferNamelist(stmt);
// Determine which BeginXyz call to make.
mlir::FuncOp ioFunc =
getBeginDataTransfer<isInput>(loc, builder, isFormatted, isList, isIntern,
isOtherIntern, isAsynch, isNml);
mlir::FunctionType ioFuncTy = ioFunc.getType();
// Append BeginXyz call arguments. File name and line number are always last.
llvm::SmallVector<mlir::Value, 8> ioArgs;
genBeginCallArguments<hasIOCtrl>(ioArgs, converter, loc, stmt, ioFuncTy,
isFormatted, isList, isIntern, isOtherIntern,
isAsynch, isNml, labelMap, assignMap);
ioArgs.push_back(
getDefaultFilename(builder, loc, ioFuncTy.getInput(ioArgs.size())));
ioArgs.push_back(
getDefaultLineNo(builder, loc, ioFuncTy.getInput(ioArgs.size())));
// Arguments are done; call the BeginXyz function.
mlir::Value cookie =
builder.create<mlir::CallOp>(loc, ioFunc, ioArgs).getResult(0);
// Generate an EnableHandlers call and remaining specifier calls.
ConditionSpecifierInfo csi;
mlir::OpBuilder::InsertPoint insertPt;
mlir::Value ok;
if constexpr (hasIOCtrl) {
genConditionHandlerCall(converter, loc, cookie, stmt.controls, csi);
insertPt = threadSpecs(converter, loc, cookie, stmt.controls,
csi.hasErrorConditionSpecifier(), ok);
}
// Generate data transfer list calls.
if constexpr (isInput) // ReadStmt
genInputItemList(converter, cookie, stmt.items, insertPt,
csi.hasTransferConditionSpecifier(), ok, false);
else if constexpr (std::is_same_v<A, Fortran::parser::PrintStmt>)
genOutputItemList(converter, cookie, std::get<1>(stmt.t), insertPt,
csi.hasTransferConditionSpecifier(), ok, false);
else // WriteStmt
genOutputItemList(converter, cookie, stmt.items, insertPt,
csi.hasTransferConditionSpecifier(), ok, false);
// Generate end statement call/s.
if (insertPt.isSet())
builder.restoreInsertionPoint(insertPt);
return genEndIO(converter, loc, cookie, csi);
}
void Fortran::lower::genPrintStatement(
Fortran::lower::AbstractConverter &converter,
const Fortran::parser::PrintStmt &stmt,
Fortran::lower::pft::LabelEvalMap &labelMap,
Fortran::lower::pft::SymbolLabelMap &assignMap) {
// PRINT does not take an io-control-spec. It only has a format specifier, so
// it is a simplified case of WRITE.
genDataTransferStmt</*isInput=*/false, /*ioCtrl=*/false>(converter, stmt,
labelMap, assignMap);
}
mlir::Value Fortran::lower::genWriteStatement(
Fortran::lower::AbstractConverter &converter,
const Fortran::parser::WriteStmt &stmt,
Fortran::lower::pft::LabelEvalMap &labelMap,
Fortran::lower::pft::SymbolLabelMap &assignMap) {
return genDataTransferStmt</*isInput=*/false>(converter, stmt, labelMap,
assignMap);
}
mlir::Value Fortran::lower::genReadStatement(
Fortran::lower::AbstractConverter &converter,
const Fortran::parser::ReadStmt &stmt,
Fortran::lower::pft::LabelEvalMap &labelMap,
Fortran::lower::pft::SymbolLabelMap &assignMap) {
return genDataTransferStmt</*isInput=*/true>(converter, stmt, labelMap,
assignMap);
}
/// Get the file expression from the inquire spec list. Also return if the
/// expression is a file name.
static std::pair<const Fortran::semantics::SomeExpr *, bool>
getInquireFileExpr(const std::list<Fortran::parser::InquireSpec> *stmt) {
if (!stmt)
return {nullptr, false};
for (const auto &spec : *stmt) {
if (auto *f = std::get_if<Fortran::parser::FileUnitNumber>(&spec.u))
return {Fortran::semantics::GetExpr(*f), false};
if (auto *f = std::get_if<Fortran::parser::FileNameExpr>(&spec.u))
return {Fortran::semantics::GetExpr(*f), true};
}
// semantics should have already caught this condition
llvm_unreachable("inquire spec must have a file");
}
mlir::Value Fortran::lower::genInquireStatement(
Fortran::lower::AbstractConverter &converter,
const Fortran::parser::InquireStmt &stmt) {
auto &builder = converter.getFirOpBuilder();
auto loc = converter.getCurrentLocation();
mlir::FuncOp beginFunc;
mlir::Value cookie;
ConditionSpecifierInfo csi{};
const auto *list =
std::get_if<std::list<Fortran::parser::InquireSpec>>(&stmt.u);
auto exprPair = getInquireFileExpr(list);
auto inquireFileUnit = [&]() -> bool {
return exprPair.first && !exprPair.second;
};
auto inquireFileName = [&]() -> bool {
return exprPair.first && exprPair.second;
};
// Determine which BeginInquire call to make.
if (inquireFileUnit()) {
// File unit call.
beginFunc = getIORuntimeFunc<mkIOKey(BeginInquireUnit)>(loc, builder);
mlir::FunctionType beginFuncTy = beginFunc.getType();
auto unit = converter.genExprValue(exprPair.first, loc);
auto un = builder.createConvert(loc, beginFuncTy.getInput(0), unit);
auto file = getDefaultFilename(builder, loc, beginFuncTy.getInput(1));
auto line = getDefaultLineNo(builder, loc, beginFuncTy.getInput(2));
llvm::SmallVector<mlir::Value, 4> beginArgs{un, file, line};
cookie =
builder.create<mlir::CallOp>(loc, beginFunc, beginArgs).getResult(0);
// Handle remaining arguments in specifier list.
genConditionHandlerCall(converter, loc, cookie, *list, csi);
} else if (inquireFileName()) {
// Filename call.
beginFunc = getIORuntimeFunc<mkIOKey(BeginInquireFile)>(loc, builder);
mlir::FunctionType beginFuncTy = beginFunc.getType();
auto file = converter.genExprValue(exprPair.first, loc);
// Helper to query [BUFFER, LEN].
Fortran::lower::CharacterExprHelper helper(builder, loc);
auto dataLen = helper.materializeCharacter(file);
auto buff =
builder.createConvert(loc, beginFuncTy.getInput(0), dataLen.first);
auto len =
builder.createConvert(loc, beginFuncTy.getInput(1), dataLen.second);
auto kindInt = helper.getCharacterKind(file.getType());
mlir::Value kindValue =
builder.createIntegerConstant(loc, beginFuncTy.getInput(2), kindInt);
auto sourceFile = getDefaultFilename(builder, loc, beginFuncTy.getInput(3));
auto line = getDefaultLineNo(builder, loc, beginFuncTy.getInput(4));
llvm::SmallVector<mlir::Value, 5> beginArgs = {
buff, len, kindValue, sourceFile, line,
};
cookie =
builder.create<mlir::CallOp>(loc, beginFunc, beginArgs).getResult(0);
// Handle remaining arguments in specifier list.
genConditionHandlerCall(converter, loc, cookie, *list, csi);
} else {
// Io length call.
const auto *ioLength =
std::get_if<Fortran::parser::InquireStmt::Iolength>(&stmt.u);
assert(ioLength && "must have an io length");
beginFunc = getIORuntimeFunc<mkIOKey(BeginInquireIoLength)>(loc, builder);
mlir::FunctionType beginFuncTy = beginFunc.getType();
auto file = getDefaultFilename(builder, loc, beginFuncTy.getInput(0));
auto line = getDefaultLineNo(builder, loc, beginFuncTy.getInput(1));
llvm::SmallVector<mlir::Value, 4> beginArgs{file, line};
cookie =
builder.create<mlir::CallOp>(loc, beginFunc, beginArgs).getResult(0);
// Handle remaining arguments in output list.
genConditionHandlerCall(
converter, loc, cookie,
std::get<std::list<Fortran::parser::OutputItem>>(ioLength->t), csi);
}
// Generate end statement call.
return genEndIO(converter, loc, cookie, csi);
}