[flang-commits] [flang] [flang] Separate definition of class `FirConverter` into header file (PR #74864)
Krzysztof Parzyszek via flang-commits
flang-commits at lists.llvm.org
Fri Dec 8 09:10:18 PST 2023
https://github.com/kparzysz updated https://github.com/llvm/llvm-project/pull/74864
>From 9eb6840a1d0d0d0ed36d6380217f348f19a90646 Mon Sep 17 00:00:00 2001
From: Krzysztof Parzyszek <Krzysztof.Parzyszek at amd.com>
Date: Thu, 7 Dec 2023 10:20:53 -0600
Subject: [PATCH 1/3] [flang] Separate definition of class FirConverter into
header file
The order of functions has been preserved, the order in the cpp file
matches the order in the header. This was meant to limit the visual
differences between the old and the new files.
Small functions and templates have their definitions in the header
(except `genFIR`).
All `genFIR` functions (except those explicitly listed as no-ops)
are defined in the cpp file.
The semantic changes are
- `FirCoverter` is defined in namespace `Fortran::lower` (was in
anonymous namespace before).
- Helper classes `IncrementLoopInfo', `ConstructContext`, and
`TypeInfoConverter` are now nested inside of `FirConverter` (were
in anonymous namespace before).
---
flang/lib/Lower/Bridge.cpp | 8633 +++++++++++++++-----------------
flang/lib/Lower/FirConverter.h | 1066 ++++
2 files changed, 5079 insertions(+), 4620 deletions(-)
create mode 100644 flang/lib/Lower/FirConverter.h
diff --git a/flang/lib/Lower/Bridge.cpp b/flang/lib/Lower/Bridge.cpp
index 7e64adc3c144c..bb705d1cf4da7 100644
--- a/flang/lib/Lower/Bridge.cpp
+++ b/flang/lib/Lower/Bridge.cpp
@@ -10,8 +10,9 @@
//
//===----------------------------------------------------------------------===//
-#include "flang/Lower/Bridge.h"
+#include "FirConverter.h"
#include "flang/Lower/Allocatable.h"
+#include "flang/Lower/Bridge.h"
#include "flang/Lower/CallInterface.h"
#include "flang/Lower/Coarray.h"
#include "flang/Lower/ConvertCall.h"
@@ -76,4985 +77,4377 @@ static llvm::cl::opt<bool> forceLoopToExecuteOnce(
"always-execute-loop-body", llvm::cl::init(false),
llvm::cl::desc("force the body of a loop to execute at least once"));
-namespace {
-/// Information for generating a structured or unstructured increment loop.
-struct IncrementLoopInfo {
- template <typename T>
- explicit IncrementLoopInfo(Fortran::semantics::Symbol &sym, const T &lower,
- const T &upper, const std::optional<T> &step,
- bool isUnordered = false)
- : loopVariableSym{&sym}, lowerExpr{Fortran::semantics::GetExpr(lower)},
- upperExpr{Fortran::semantics::GetExpr(upper)},
- stepExpr{Fortran::semantics::GetExpr(step)}, isUnordered{isUnordered} {}
-
- IncrementLoopInfo(IncrementLoopInfo &&) = default;
- IncrementLoopInfo &operator=(IncrementLoopInfo &&x) = default;
-
- bool isStructured() const { return !headerBlock; }
-
- mlir::Type getLoopVariableType() const {
- assert(loopVariable && "must be set");
- return fir::unwrapRefType(loopVariable.getType());
- }
+namespace Fortran::lower {
+
+//===----------------------------------------------------------------------===//
+// FirConverter
+//===----------------------------------------------------------------------===//
- bool hasLocalitySpecs() const {
- return !localSymList.empty() || !localInitSymList.empty() ||
- !sharedSymList.empty();
+/// Convert the PFT to FIR.
+void FirConverter::run(Fortran::lower::pft::Program &pft) {
+ // Preliminary translation pass.
+
+ // Lower common blocks, taking into account initialization and the largest
+ // size of all instances of each common block. This is done before lowering
+ // since the global definition may differ from any one local definition.
+ lowerCommonBlocks(pft.getCommonBlocks());
+
+ // - Declare all functions that have definitions so that definition
+ // signatures prevail over call site signatures.
+ // - Define module variables and OpenMP/OpenACC declarative constructs so
+ // they are available before lowering any function that may use them.
+ bool hasMainProgram = false;
+ const Fortran::semantics::Symbol *globalOmpRequiresSymbol = nullptr;
+ for (Fortran::lower::pft::Program::Units &u : pft.getUnits()) {
+ std::visit(Fortran::common::visitors{
+ [&](Fortran::lower::pft::FunctionLikeUnit &f) {
+ if (f.isMainProgram())
+ hasMainProgram = true;
+ declareFunction(f);
+ if (!globalOmpRequiresSymbol)
+ globalOmpRequiresSymbol = f.getScope().symbol();
+ },
+ [&](Fortran::lower::pft::ModuleLikeUnit &m) {
+ lowerModuleDeclScope(m);
+ for (Fortran::lower::pft::FunctionLikeUnit &f :
+ m.nestedFunctions)
+ declareFunction(f);
+ },
+ [&](Fortran::lower::pft::BlockDataUnit &b) {
+ if (!globalOmpRequiresSymbol)
+ globalOmpRequiresSymbol = b.symTab.symbol();
+ },
+ [&](Fortran::lower::pft::CompilerDirectiveUnit &d) {},
+ [&](Fortran::lower::pft::OpenACCDirectiveUnit &d) {},
+ },
+ u);
}
- // Data members common to both structured and unstructured loops.
- const Fortran::semantics::Symbol *loopVariableSym;
- const Fortran::lower::SomeExpr *lowerExpr;
- const Fortran::lower::SomeExpr *upperExpr;
- const Fortran::lower::SomeExpr *stepExpr;
- const Fortran::lower::SomeExpr *maskExpr = nullptr;
- bool isUnordered; // do concurrent, forall
- llvm::SmallVector<const Fortran::semantics::Symbol *> localSymList;
- llvm::SmallVector<const Fortran::semantics::Symbol *> localInitSymList;
- llvm::SmallVector<const Fortran::semantics::Symbol *> sharedSymList;
- mlir::Value loopVariable = nullptr;
-
- // Data members for structured loops.
- fir::DoLoopOp doLoop = nullptr;
-
- // Data members for unstructured loops.
- bool hasRealControl = false;
- mlir::Value tripVariable = nullptr;
- mlir::Value stepVariable = nullptr;
- mlir::Block *headerBlock = nullptr; // loop entry and test block
- mlir::Block *maskBlock = nullptr; // concurrent loop mask block
- mlir::Block *bodyBlock = nullptr; // first loop body block
- mlir::Block *exitBlock = nullptr; // loop exit target block
-};
-
-/// Information to support stack management, object deallocation, and
-/// object finalization at early and normal construct exits.
-struct ConstructContext {
- explicit ConstructContext(Fortran::lower::pft::Evaluation &eval,
- Fortran::lower::StatementContext &stmtCtx)
- : eval{eval}, stmtCtx{stmtCtx} {}
-
- Fortran::lower::pft::Evaluation &eval; // construct eval
- Fortran::lower::StatementContext &stmtCtx; // construct exit code
-};
-
-/// Helper class to generate the runtime type info global data and the
-/// fir.type_info operations that contain the dipatch tables (if any).
-/// The type info global data is required to describe the derived type to the
-/// runtime so that it can operate over it.
-/// It must be ensured these operations will be generated for every derived type
-/// lowered in the current translated unit. However, these operations
-/// cannot be generated before FuncOp have been created for functions since the
-/// initializers may take their address (e.g for type bound procedures). This
-/// class allows registering all the required type info while it is not
-/// possible to create GlobalOp/TypeInfoOp, and to generate this data afte
-/// function lowering.
-class TypeInfoConverter {
- /// Store the location and symbols of derived type info to be generated.
- /// The location of the derived type instantiation is also stored because
- /// runtime type descriptor symbols are compiler generated and cannot be
- /// mapped to user code on their own.
- struct TypeInfo {
- Fortran::semantics::SymbolRef symbol;
- const Fortran::semantics::DerivedTypeSpec &typeSpec;
- fir::RecordType type;
- mlir::Location loc;
- };
+ // Create definitions of intrinsic module constants.
+ createGlobalOutsideOfFunctionLowering(
+ [&]() { createIntrinsicModuleDefinitions(pft); });
-public:
- void registerTypeInfo(Fortran::lower::AbstractConverter &converter,
- mlir::Location loc,
- Fortran::semantics::SymbolRef typeInfoSym,
- const Fortran::semantics::DerivedTypeSpec &typeSpec,
- fir::RecordType type) {
- if (seen.contains(typeInfoSym))
- return;
- seen.insert(typeInfoSym);
- if (!skipRegistration) {
- registeredTypeInfo.emplace_back(
- TypeInfo{typeInfoSym, typeSpec, type, loc});
- return;
- }
- // Once the registration is closed, symbols cannot be added to the
- // registeredTypeInfoSymbols list because it may be iterated over.
- // However, after registration is closed, it is safe to directly generate
- // the globals because all FuncOps whose addresses may be required by the
- // initializers have been generated.
- createTypeInfoOpAndGlobal(converter,
- TypeInfo{typeInfoSym, typeSpec, type, loc});
+ // Primary translation pass.
+ for (Fortran::lower::pft::Program::Units &u : pft.getUnits()) {
+ std::visit(
+ Fortran::common::visitors{
+ [&](Fortran::lower::pft::FunctionLikeUnit &f) { lowerFunc(f); },
+ [&](Fortran::lower::pft::ModuleLikeUnit &m) { lowerMod(m); },
+ [&](Fortran::lower::pft::BlockDataUnit &b) {},
+ [&](Fortran::lower::pft::CompilerDirectiveUnit &d) {},
+ [&](Fortran::lower::pft::OpenACCDirectiveUnit &d) {
+ builder = new fir::FirOpBuilder(bridge.getModule(),
+ bridge.getKindMap());
+ Fortran::lower::genOpenACCRoutineConstruct(
+ *this, bridge.getSemanticsContext(), bridge.getModule(),
+ d.routine, accRoutineInfos);
+ builder = nullptr;
+ },
+ },
+ u);
}
- void createTypeInfo(Fortran::lower::AbstractConverter &converter) {
- skipRegistration = true;
- for (const TypeInfo &info : registeredTypeInfo)
- createTypeInfoOpAndGlobal(converter, info);
- registeredTypeInfo.clear();
- }
+ // Once all the code has been translated, create global runtime type info
+ // data structures for the derived types that have been processed, as well
+ // as fir.type_info operations for the dispatch tables.
+ createGlobalOutsideOfFunctionLowering(
+ [&]() { typeInfoConverter.createTypeInfo(*this); });
-private:
- void createTypeInfoOpAndGlobal(Fortran::lower::AbstractConverter &converter,
- const TypeInfo &info) {
- Fortran::lower::createRuntimeTypeInfoGlobal(converter, info.symbol.get());
- createTypeInfoOp(converter, info);
- }
+ // Create the list of any environment defaults for the runtime to set. The
+ // runtime default list is only created if there is a main program to ensure
+ // it only happens once and to provide consistent results if multiple files
+ // are compiled separately.
+ if (hasMainProgram)
+ createGlobalOutsideOfFunctionLowering([&]() {
+ // FIXME: Ideally, this would create a call to a runtime function
+ // accepting the list of environment defaults. That way, we would not
+ // need to add an extern pointer to the runtime and said pointer would
+ // not need to be generated even if no defaults are specified.
+ // However, generating main or changing when the runtime reads
+ // environment variables is required to do so.
+ fir::runtime::genEnvironmentDefaults(*builder, toLocation(),
+ bridge.getEnvironmentDefaults());
+ });
- void createTypeInfoOp(Fortran::lower::AbstractConverter &converter,
- const TypeInfo &info) {
- fir::RecordType parentType{};
- if (const Fortran::semantics::DerivedTypeSpec *parent =
- Fortran::evaluate::GetParentTypeSpec(info.typeSpec))
- parentType = mlir::cast<fir::RecordType>(converter.genType(*parent));
-
- fir::FirOpBuilder &builder = converter.getFirOpBuilder();
- mlir::ModuleOp module = builder.getModule();
- fir::TypeInfoOp dt =
- module.lookupSymbol<fir::TypeInfoOp>(info.type.getName());
- if (dt)
- return; // Already created.
- auto insertPt = builder.saveInsertionPoint();
- builder.setInsertionPoint(module.getBody(), module.getBody()->end());
- dt = builder.create<fir::TypeInfoOp>(info.loc, info.type, parentType);
-
- if (!info.typeSpec.HasDefaultInitialization(/*ignoreAllocatable=*/false,
- /*ignorePointer=*/false))
- dt->setAttr(dt.getNoInitAttrName(), builder.getUnitAttr());
- if (!info.typeSpec.HasDestruction())
- dt->setAttr(dt.getNoDestroyAttrName(), builder.getUnitAttr());
- if (!Fortran::semantics::MayRequireFinalization(info.typeSpec))
- dt->setAttr(dt.getNoFinalAttrName(), builder.getUnitAttr());
-
- const Fortran::semantics::Scope *scope = info.typeSpec.scope();
- if (!scope)
- scope = info.typeSpec.typeSymbol().scope();
- assert(scope && "failed to find type scope");
-
- Fortran::semantics::SymbolVector bindings =
- Fortran::semantics::CollectBindings(*scope);
- if (!bindings.empty()) {
- builder.createBlock(&dt.getDispatchTable());
- for (const Fortran::semantics::SymbolRef &binding : bindings) {
- const auto &details =
- binding.get().get<Fortran::semantics::ProcBindingDetails>();
- std::string tbpName = binding.get().name().ToString();
- if (details.numPrivatesNotOverridden() > 0)
- tbpName += "."s + std::to_string(details.numPrivatesNotOverridden());
- std::string bindingName = converter.mangleName(details.symbol());
- builder.create<fir::DTEntryOp>(
- info.loc, mlir::StringAttr::get(builder.getContext(), tbpName),
- mlir::SymbolRefAttr::get(builder.getContext(), bindingName));
- }
- builder.create<fir::FirEndOp>(info.loc);
- }
- builder.restoreInsertionPoint(insertPt);
- }
+ finalizeOpenACCLowering();
+ finalizeOpenMPLowering(globalOmpRequiresSymbol);
+}
- /// Store the front-end data that will be required to generate the type info
- /// for the derived types that have been converted to fir.type<>.
- llvm::SmallVector<TypeInfo> registeredTypeInfo;
- /// Create derived type info immediately without storing the
- /// symbol in registeredTypeInfo.
- bool skipRegistration = false;
- /// Track symbols symbols processed during and after the registration
- /// to avoid infinite loops between type conversions and global variable
- /// creation.
- llvm::SmallSetVector<Fortran::semantics::SymbolRef, 32> seen;
-};
-
-using IncrementLoopNestInfo = llvm::SmallVector<IncrementLoopInfo, 8>;
-} // namespace
+/// Declare a function.
+void FirConverter::declareFunction(
+ Fortran::lower::pft::FunctionLikeUnit &funit) {
+ setCurrentPosition(funit.getStartingSourceLoc());
+ for (int entryIndex = 0, last = funit.entryPointList.size();
+ entryIndex < last; ++entryIndex) {
+ funit.setActiveEntry(entryIndex);
+ // Calling CalleeInterface ctor will build a declaration
+ // mlir::func::FuncOp with no other side effects.
+ // TODO: when doing some compiler profiling on real apps, it may be worth
+ // to check it's better to save the CalleeInterface instead of recomputing
+ // it later when lowering the body. CalleeInterface ctor should be linear
+ // with the number of arguments, so it is not awful to do it that way for
+ // now, but the linear coefficient might be non negligible. Until
+ // measured, stick to the solution that impacts the code less.
+ Fortran::lower::CalleeInterface{funit, *this};
+ }
+ funit.setActiveEntry(0);
+
+ // Compute the set of host associated entities from the nested functions.
+ llvm::SetVector<const Fortran::semantics::Symbol *> escapeHost;
+ for (Fortran::lower::pft::FunctionLikeUnit &f : funit.nestedFunctions)
+ collectHostAssociatedVariables(f, escapeHost);
+ funit.setHostAssociatedSymbols(escapeHost);
+
+ // Declare internal procedures
+ for (Fortran::lower::pft::FunctionLikeUnit &f : funit.nestedFunctions)
+ declareFunction(f);
+}
-//===----------------------------------------------------------------------===//
-// FirConverter
-//===----------------------------------------------------------------------===//
+/// Get the scope that is defining or using \p sym. The returned scope is not
+/// the ultimate scope, since this helper does not traverse use association.
+/// This allows capturing module variables that are referenced in an internal
+/// procedure but whose use statement is inside the host program.
+const Fortran::semantics::Scope &
+FirConverter::getSymbolHostScope(const Fortran::semantics::Symbol &sym) {
+ const Fortran::semantics::Symbol *hostSymbol = &sym;
+ while (const auto *details =
+ hostSymbol->detailsIf<Fortran::semantics::HostAssocDetails>())
+ hostSymbol = &details->symbol();
+ return hostSymbol->owner();
+}
-namespace {
-
-/// Traverse the pre-FIR tree (PFT) to generate the FIR dialect of MLIR.
-class FirConverter : public Fortran::lower::AbstractConverter {
-public:
- explicit FirConverter(Fortran::lower::LoweringBridge &bridge)
- : Fortran::lower::AbstractConverter(bridge.getLoweringOptions()),
- bridge{bridge}, foldingContext{bridge.createFoldingContext()} {}
- virtual ~FirConverter() = default;
-
- /// Convert the PFT to FIR.
- void run(Fortran::lower::pft::Program &pft) {
- // Preliminary translation pass.
-
- // Lower common blocks, taking into account initialization and the largest
- // size of all instances of each common block. This is done before lowering
- // since the global definition may differ from any one local definition.
- lowerCommonBlocks(pft.getCommonBlocks());
-
- // - Declare all functions that have definitions so that definition
- // signatures prevail over call site signatures.
- // - Define module variables and OpenMP/OpenACC declarative constructs so
- // they are available before lowering any function that may use them.
- bool hasMainProgram = false;
- const Fortran::semantics::Symbol *globalOmpRequiresSymbol = nullptr;
- for (Fortran::lower::pft::Program::Units &u : pft.getUnits()) {
- std::visit(Fortran::common::visitors{
- [&](Fortran::lower::pft::FunctionLikeUnit &f) {
- if (f.isMainProgram())
- hasMainProgram = true;
- declareFunction(f);
- if (!globalOmpRequiresSymbol)
- globalOmpRequiresSymbol = f.getScope().symbol();
- },
- [&](Fortran::lower::pft::ModuleLikeUnit &m) {
- lowerModuleDeclScope(m);
- for (Fortran::lower::pft::FunctionLikeUnit &f :
- m.nestedFunctions)
- declareFunction(f);
- },
- [&](Fortran::lower::pft::BlockDataUnit &b) {
- if (!globalOmpRequiresSymbol)
- globalOmpRequiresSymbol = b.symTab.symbol();
- },
- [&](Fortran::lower::pft::CompilerDirectiveUnit &d) {},
- [&](Fortran::lower::pft::OpenACCDirectiveUnit &d) {},
- },
- u);
+/// Collects the canonical list of all host associated symbols. These bindings
+/// must be aggregated into a tuple which can then be added to each of the
+/// internal procedure declarations and passed at each call site.
+void FirConverter::collectHostAssociatedVariables(
+ Fortran::lower::pft::FunctionLikeUnit &funit,
+ llvm::SetVector<const Fortran::semantics::Symbol *> &escapees) {
+ const Fortran::semantics::Scope *internalScope =
+ funit.getSubprogramSymbol().scope();
+ assert(internalScope && "internal procedures symbol must create a scope");
+ auto addToListIfEscapee = [&](const Fortran::semantics::Symbol &sym) {
+ const Fortran::semantics::Symbol &ultimate = sym.GetUltimate();
+ const auto *namelistDetails =
+ ultimate.detailsIf<Fortran::semantics::NamelistDetails>();
+ if (ultimate.has<Fortran::semantics::ObjectEntityDetails>() ||
+ Fortran::semantics::IsProcedurePointer(ultimate) ||
+ Fortran::semantics::IsDummy(sym) || namelistDetails) {
+ const Fortran::semantics::Scope &symbolScope = getSymbolHostScope(sym);
+ if (symbolScope.kind() == Fortran::semantics::Scope::Kind::MainProgram ||
+ symbolScope.kind() == Fortran::semantics::Scope::Kind::Subprogram)
+ if (symbolScope != *internalScope &&
+ symbolScope.Contains(*internalScope)) {
+ if (namelistDetails) {
+ // So far, namelist symbols are processed on the fly in IO and
+ // the related namelist data structure is not added to the symbol
+ // map, so it cannot be passed to the internal procedures.
+ // Instead, all the symbols of the host namelist used in the
+ // internal procedure must be considered as host associated so
+ // that IO lowering can find them when needed.
+ for (const auto &namelistObject : namelistDetails->objects())
+ escapees.insert(&*namelistObject);
+ } else {
+ escapees.insert(&ultimate);
+ }
+ }
}
+ };
+ Fortran::lower::pft::visitAllSymbols(funit, addToListIfEscapee);
+}
- // Create definitions of intrinsic module constants.
- createGlobalOutsideOfFunctionLowering(
- [&]() { createIntrinsicModuleDefinitions(pft); });
-
- // Primary translation pass.
- for (Fortran::lower::pft::Program::Units &u : pft.getUnits()) {
- std::visit(
- Fortran::common::visitors{
- [&](Fortran::lower::pft::FunctionLikeUnit &f) { lowerFunc(f); },
- [&](Fortran::lower::pft::ModuleLikeUnit &m) { lowerMod(m); },
- [&](Fortran::lower::pft::BlockDataUnit &b) {},
- [&](Fortran::lower::pft::CompilerDirectiveUnit &d) {},
- [&](Fortran::lower::pft::OpenACCDirectiveUnit &d) {
- builder = new fir::FirOpBuilder(bridge.getModule(),
- bridge.getKindMap());
- Fortran::lower::genOpenACCRoutineConstruct(
- *this, bridge.getSemanticsContext(), bridge.getModule(),
- d.routine, accRoutineInfos);
- builder = nullptr;
- },
- },
- u);
- }
+//===--------------------------------------------------------------------===//
+// AbstractConverter overrides
+//===--------------------------------------------------------------------===//
+
+fir::ExtendedValue
+FirConverter::symBoxToExtendedValue(const Fortran::lower::SymbolBox &symBox) {
+ return symBox.match(
+ [](const Fortran::lower::SymbolBox::Intrinsic &box)
+ -> fir::ExtendedValue { return box.getAddr(); },
+ [](const Fortran::lower::SymbolBox::None &) -> fir::ExtendedValue {
+ llvm::report_fatal_error("symbol not mapped");
+ },
+ [&](const fir::FortranVariableOpInterface &x) -> fir::ExtendedValue {
+ return hlfir::translateToExtendedValue(getCurrentLocation(),
+ getFirOpBuilder(), x);
+ },
+ [](const auto &box) -> fir::ExtendedValue { return box; });
+}
- // Once all the code has been translated, create global runtime type info
- // data structures for the derived types that have been processed, as well
- // as fir.type_info operations for the dispatch tables.
- createGlobalOutsideOfFunctionLowering(
- [&]() { typeInfoConverter.createTypeInfo(*this); });
-
- // Create the list of any environment defaults for the runtime to set. The
- // runtime default list is only created if there is a main program to ensure
- // it only happens once and to provide consistent results if multiple files
- // are compiled separately.
- if (hasMainProgram)
- createGlobalOutsideOfFunctionLowering([&]() {
- // FIXME: Ideally, this would create a call to a runtime function
- // accepting the list of environment defaults. That way, we would not
- // need to add an extern pointer to the runtime and said pointer would
- // not need to be generated even if no defaults are specified.
- // However, generating main or changing when the runtime reads
- // environment variables is required to do so.
- fir::runtime::genEnvironmentDefaults(*builder, toLocation(),
- bridge.getEnvironmentDefaults());
- });
+fir::ExtendedValue
+FirConverter::getSymbolExtendedValue(const Fortran::semantics::Symbol &sym,
+ Fortran::lower::SymMap *symMap) {
+ Fortran::lower::SymbolBox sb = lookupSymbol(sym, symMap);
+ if (!sb) {
+ LLVM_DEBUG(llvm::dbgs() << "unknown symbol: " << sym << "\nmap: "
+ << (symMap ? *symMap : localSymbols) << '\n');
+ fir::emitFatalError(getCurrentLocation(),
+ "symbol is not mapped to any IR value");
+ }
+ return symBoxToExtendedValue(sb);
+}
- finalizeOpenACCLowering();
- finalizeOpenMPLowering(globalOmpRequiresSymbol);
- }
+mlir::Value FirConverter::impliedDoBinding(llvm::StringRef name) {
+ mlir::Value val = localSymbols.lookupImpliedDo(name);
+ if (!val)
+ fir::emitFatalError(toLocation(), "ac-do-variable has no binding");
+ return val;
+}
- /// Declare a function.
- void declareFunction(Fortran::lower::pft::FunctionLikeUnit &funit) {
- setCurrentPosition(funit.getStartingSourceLoc());
- for (int entryIndex = 0, last = funit.entryPointList.size();
- entryIndex < last; ++entryIndex) {
- funit.setActiveEntry(entryIndex);
- // Calling CalleeInterface ctor will build a declaration
- // mlir::func::FuncOp with no other side effects.
- // TODO: when doing some compiler profiling on real apps, it may be worth
- // to check it's better to save the CalleeInterface instead of recomputing
- // it later when lowering the body. CalleeInterface ctor should be linear
- // with the number of arguments, so it is not awful to do it that way for
- // now, but the linear coefficient might be non negligible. Until
- // measured, stick to the solution that impacts the code less.
- Fortran::lower::CalleeInterface{funit, *this};
- }
- funit.setActiveEntry(0);
+/// Add the symbol binding to the inner-most level of the symbol map and
+/// return true if it is not already present. Otherwise, return false.
+bool FirConverter::bindIfNewSymbol(Fortran::lower::SymbolRef sym,
+ const fir::ExtendedValue &exval) {
+ if (shallowLookupSymbol(sym))
+ return false;
+ bindSymbol(sym, exval);
+ return true;
+}
- // Compute the set of host associated entities from the nested functions.
- llvm::SetVector<const Fortran::semantics::Symbol *> escapeHost;
- for (Fortran::lower::pft::FunctionLikeUnit &f : funit.nestedFunctions)
- collectHostAssociatedVariables(f, escapeHost);
- funit.setHostAssociatedSymbols(escapeHost);
+bool FirConverter::lookupLabelSet(Fortran::lower::SymbolRef sym,
+ Fortran::lower::pft::LabelSet &labelSet) {
+ Fortran::lower::pft::FunctionLikeUnit &owningProc =
+ *getEval().getOwningProcedure();
+ auto iter = owningProc.assignSymbolLabelMap.find(sym);
+ if (iter == owningProc.assignSymbolLabelMap.end())
+ return false;
+ labelSet = iter->second;
+ return true;
+}
- // Declare internal procedures
- for (Fortran::lower::pft::FunctionLikeUnit &f : funit.nestedFunctions)
- declareFunction(f);
- }
+fir::ExtendedValue
+FirConverter::genExprAddr(const Fortran::lower::SomeExpr &expr,
+ Fortran::lower::StatementContext &context,
+ mlir::Location *locPtr) {
+ mlir::Location loc = locPtr ? *locPtr : toLocation();
+ if (lowerToHighLevelFIR())
+ return Fortran::lower::convertExprToAddress(loc, *this, expr, localSymbols,
+ context);
+ return Fortran::lower::createSomeExtendedAddress(loc, *this, expr,
+ localSymbols, context);
+}
- /// Get the scope that is defining or using \p sym. The returned scope is not
- /// the ultimate scope, since this helper does not traverse use association.
- /// This allows capturing module variables that are referenced in an internal
- /// procedure but whose use statement is inside the host program.
- const Fortran::semantics::Scope &
- getSymbolHostScope(const Fortran::semantics::Symbol &sym) {
- const Fortran::semantics::Symbol *hostSymbol = &sym;
- while (const auto *details =
- hostSymbol->detailsIf<Fortran::semantics::HostAssocDetails>())
- hostSymbol = &details->symbol();
- return hostSymbol->owner();
- }
+fir::ExtendedValue
+FirConverter::genExprValue(const Fortran::lower::SomeExpr &expr,
+ Fortran::lower::StatementContext &context,
+ mlir::Location *locPtr) {
+ mlir::Location loc = locPtr ? *locPtr : toLocation();
+ if (lowerToHighLevelFIR())
+ return Fortran::lower::convertExprToValue(loc, *this, expr, localSymbols,
+ context);
+ return Fortran::lower::createSomeExtendedExpression(loc, *this, expr,
+ localSymbols, context);
+}
- /// Collects the canonical list of all host associated symbols. These bindings
- /// must be aggregated into a tuple which can then be added to each of the
- /// internal procedure declarations and passed at each call site.
- void collectHostAssociatedVariables(
- Fortran::lower::pft::FunctionLikeUnit &funit,
- llvm::SetVector<const Fortran::semantics::Symbol *> &escapees) {
- const Fortran::semantics::Scope *internalScope =
- funit.getSubprogramSymbol().scope();
- assert(internalScope && "internal procedures symbol must create a scope");
- auto addToListIfEscapee = [&](const Fortran::semantics::Symbol &sym) {
- const Fortran::semantics::Symbol &ultimate = sym.GetUltimate();
- const auto *namelistDetails =
- ultimate.detailsIf<Fortran::semantics::NamelistDetails>();
- if (ultimate.has<Fortran::semantics::ObjectEntityDetails>() ||
- Fortran::semantics::IsProcedurePointer(ultimate) ||
- Fortran::semantics::IsDummy(sym) || namelistDetails) {
- const Fortran::semantics::Scope &symbolScope = getSymbolHostScope(sym);
- if (symbolScope.kind() ==
- Fortran::semantics::Scope::Kind::MainProgram ||
- symbolScope.kind() == Fortran::semantics::Scope::Kind::Subprogram)
- if (symbolScope != *internalScope &&
- symbolScope.Contains(*internalScope)) {
- if (namelistDetails) {
- // So far, namelist symbols are processed on the fly in IO and
- // the related namelist data structure is not added to the symbol
- // map, so it cannot be passed to the internal procedures.
- // Instead, all the symbols of the host namelist used in the
- // internal procedure must be considered as host associated so
- // that IO lowering can find them when needed.
- for (const auto &namelistObject : namelistDetails->objects())
- escapees.insert(&*namelistObject);
+fir::ExtendedValue
+FirConverter::genExprBox(mlir::Location loc,
+ const Fortran::lower::SomeExpr &expr,
+ Fortran::lower::StatementContext &stmtCtx) {
+ if (lowerToHighLevelFIR())
+ return Fortran::lower::convertExprToBox(loc, *this, expr, localSymbols,
+ stmtCtx);
+ return Fortran::lower::createBoxValue(loc, *this, expr, localSymbols,
+ stmtCtx);
+}
+
+bool FirConverter::createHostAssociateVarClone(
+ const Fortran::semantics::Symbol &sym) {
+ mlir::Location loc = genLocation(sym.name());
+ mlir::Type symType = genType(sym);
+ const auto *details = sym.detailsIf<Fortran::semantics::HostAssocDetails>();
+ assert(details && "No host-association found");
+ const Fortran::semantics::Symbol &hsym = details->symbol();
+ mlir::Type hSymType = genType(hsym);
+ Fortran::lower::SymbolBox hsb = lookupSymbol(hsym);
+
+ auto allocate = [&](llvm::ArrayRef<mlir::Value> shape,
+ llvm::ArrayRef<mlir::Value> typeParams) -> mlir::Value {
+ mlir::Value allocVal = builder->allocateLocal(
+ loc,
+ Fortran::semantics::IsAllocatableOrObjectPointer(&hsym.GetUltimate())
+ ? hSymType
+ : symType,
+ mangleName(sym), toStringRef(sym.GetUltimate().name()),
+ /*pinned=*/true, shape, typeParams,
+ sym.GetUltimate().attrs().test(Fortran::semantics::Attr::TARGET));
+ return allocVal;
+ };
+
+ fir::ExtendedValue hexv = symBoxToExtendedValue(hsb);
+ fir::ExtendedValue exv = hexv.match(
+ [&](const fir::BoxValue &box) -> fir::ExtendedValue {
+ const Fortran::semantics::DeclTypeSpec *type = sym.GetType();
+ if (type && type->IsPolymorphic())
+ TODO(loc, "create polymorphic host associated copy");
+ // Create a contiguous temp with the same shape and length as
+ // the original variable described by a fir.box.
+ llvm::SmallVector<mlir::Value> extents =
+ fir::factory::getExtents(loc, *builder, hexv);
+ if (box.isDerivedWithLenParameters())
+ TODO(loc, "get length parameters from derived type BoxValue");
+ if (box.isCharacter()) {
+ mlir::Value len = fir::factory::readCharLen(*builder, loc, box);
+ mlir::Value temp = allocate(extents, {len});
+ return fir::CharArrayBoxValue{temp, len, extents};
+ }
+ return fir::ArrayBoxValue{allocate(extents, {}), extents};
+ },
+ [&](const fir::MutableBoxValue &box) -> fir::ExtendedValue {
+ // Allocate storage for a pointer/allocatble descriptor.
+ // No shape/lengths to be passed to the alloca.
+ return fir::MutableBoxValue(allocate({}, {}), {}, {});
+ },
+ [&](const auto &) -> fir::ExtendedValue {
+ mlir::Value temp =
+ allocate(fir::factory::getExtents(loc, *builder, hexv),
+ fir::factory::getTypeParams(loc, *builder, hexv));
+ return fir::substBase(hexv, temp);
+ });
+
+ // Initialise cloned allocatable
+ hexv.match(
+ [&](const fir::MutableBoxValue &box) -> void {
+ // Do not process pointers
+ if (Fortran::semantics::IsPointer(sym.GetUltimate())) {
+ return;
+ }
+ // Allocate storage for a pointer/allocatble descriptor.
+ // No shape/lengths to be passed to the alloca.
+ const auto new_box = exv.getBoxOf<fir::MutableBoxValue>();
+
+ // allocate if allocated
+ mlir::Value isAllocated =
+ fir::factory::genIsAllocatedOrAssociatedTest(*builder, loc, box);
+ auto if_builder = builder->genIfThenElse(loc, isAllocated);
+ if_builder.genThen([&]() {
+ std::string name = mangleName(sym) + ".alloc";
+ if (auto seqTy = symType.dyn_cast<fir::SequenceType>()) {
+ fir::ExtendedValue read = fir::factory::genMutableBoxRead(
+ *builder, loc, box, /*mayBePolymorphic=*/false);
+ if (auto read_arr_box = read.getBoxOf<fir::ArrayBoxValue>()) {
+ fir::factory::genInlinedAllocation(
+ *builder, loc, *new_box, read_arr_box->getLBounds(),
+ read_arr_box->getExtents(),
+ /*lenParams=*/std::nullopt, name,
+ /*mustBeHeap=*/true);
+ } else if (auto read_char_arr_box =
+ read.getBoxOf<fir::CharArrayBoxValue>()) {
+ fir::factory::genInlinedAllocation(
+ *builder, loc, *new_box, read_char_arr_box->getLBounds(),
+ read_char_arr_box->getExtents(), read_char_arr_box->getLen(),
+ name,
+ /*mustBeHeap=*/true);
} else {
- escapees.insert(&ultimate);
+ TODO(loc, "Unhandled allocatable box type");
}
+ } else {
+ fir::factory::genInlinedAllocation(
+ *builder, loc, *new_box, box.getMutableProperties().lbounds,
+ box.getMutableProperties().extents, box.nonDeferredLenParams(),
+ name,
+ /*mustBeHeap=*/true);
}
- }
- };
- Fortran::lower::pft::visitAllSymbols(funit, addToListIfEscapee);
- }
+ });
+ if_builder.genElse([&]() {
+ // nullify box
+ auto empty = fir::factory::createUnallocatedBox(
+ *builder, loc, new_box->getBoxTy(),
+ new_box->nonDeferredLenParams(), {});
+ builder->create<fir::StoreOp>(loc, empty, new_box->getAddr());
+ });
+ if_builder.end();
+ },
+ [&](const auto &) -> void {
+ // Do nothing
+ });
- //===--------------------------------------------------------------------===//
- // AbstractConverter overrides
- //===--------------------------------------------------------------------===//
+ return bindIfNewSymbol(sym, exv);
+}
- mlir::Value getSymbolAddress(Fortran::lower::SymbolRef sym) override final {
- return lookupSymbol(sym).getAddr();
- }
+void FirConverter::createHostAssociateVarCloneDealloc(
+ const Fortran::semantics::Symbol &sym) {
+ mlir::Location loc = genLocation(sym.name());
+ Fortran::lower::SymbolBox hsb = lookupSymbol(sym);
- fir::ExtendedValue
- symBoxToExtendedValue(const Fortran::lower::SymbolBox &symBox) {
- return symBox.match(
- [](const Fortran::lower::SymbolBox::Intrinsic &box)
- -> fir::ExtendedValue { return box.getAddr(); },
- [](const Fortran::lower::SymbolBox::None &) -> fir::ExtendedValue {
- llvm::report_fatal_error("symbol not mapped");
- },
- [&](const fir::FortranVariableOpInterface &x) -> fir::ExtendedValue {
- return hlfir::translateToExtendedValue(getCurrentLocation(),
- getFirOpBuilder(), x);
- },
- [](const auto &box) -> fir::ExtendedValue { return box; });
- }
+ fir::ExtendedValue hexv = symBoxToExtendedValue(hsb);
+ hexv.match(
+ [&](const fir::MutableBoxValue &new_box) -> void {
+ // Do not process pointers
+ if (Fortran::semantics::IsPointer(sym.GetUltimate())) {
+ return;
+ }
+ // deallocate allocated in createHostAssociateVarClone value
+ Fortran::lower::genDeallocateIfAllocated(*this, new_box, loc);
+ },
+ [&](const auto &) -> void {
+ // Do nothing
+ });
+}
- fir::ExtendedValue
- getSymbolExtendedValue(const Fortran::semantics::Symbol &sym,
- Fortran::lower::SymMap *symMap) override final {
- Fortran::lower::SymbolBox sb = lookupSymbol(sym, symMap);
- if (!sb) {
- LLVM_DEBUG(llvm::dbgs() << "unknown symbol: " << sym << "\nmap: "
- << (symMap ? *symMap : localSymbols) << '\n');
- fir::emitFatalError(getCurrentLocation(),
- "symbol is not mapped to any IR value");
+void FirConverter::copyHostAssociateVar(
+ const Fortran::semantics::Symbol &sym,
+ mlir::OpBuilder::InsertPoint *copyAssignIP) {
+ // 1) Fetch the original copy of the variable.
+ assert(sym.has<Fortran::semantics::HostAssocDetails>() &&
+ "No host-association found");
+ const Fortran::semantics::Symbol &hsym = sym.GetUltimate();
+ Fortran::lower::SymbolBox hsb = lookupOneLevelUpSymbol(hsym);
+ assert(hsb && "Host symbol box not found");
+
+ // 2) Fetch the copied one that will mask the original.
+ Fortran::lower::SymbolBox sb = shallowLookupSymbol(sym);
+ assert(sb && "Host-associated symbol box not found");
+ assert(hsb.getAddr() != sb.getAddr() &&
+ "Host and associated symbol boxes are the same");
+
+ // 3) Perform the assignment.
+ mlir::OpBuilder::InsertPoint insPt = builder->saveInsertionPoint();
+ if (copyAssignIP && copyAssignIP->isSet())
+ builder->restoreInsertionPoint(*copyAssignIP);
+ else
+ builder->setInsertionPointAfter(sb.getAddr().getDefiningOp());
+
+ Fortran::lower::SymbolBox *lhs_sb, *rhs_sb;
+ if (copyAssignIP && copyAssignIP->isSet() &&
+ sym.test(Fortran::semantics::Symbol::Flag::OmpLastPrivate)) {
+ // lastprivate case
+ lhs_sb = &hsb;
+ rhs_sb = &sb;
+ } else {
+ lhs_sb = &sb;
+ rhs_sb = &hsb;
+ }
+
+ mlir::Location loc = genLocation(sym.name());
+
+ if (lowerToHighLevelFIR()) {
+ hlfir::Entity lhs{lhs_sb->getAddr()};
+ hlfir::Entity rhs{rhs_sb->getAddr()};
+ // Temporary_lhs is set to true in hlfir.assign below to avoid
+ // user assignment to be used and finalization to be called on
+ // the LHS. This may or may not be correct but mimics the current behaviour
+ // without HLFIR.
+ auto copyData = [&](hlfir::Entity l, hlfir::Entity r) {
+ // Dereference RHS and load it if trivial scalar.
+ r = hlfir::loadTrivialScalar(loc, *builder, r);
+ builder->create<hlfir::AssignOp>(
+ loc, r, l,
+ /*isWholeAllocatableAssignment=*/false,
+ /*keepLhsLengthInAllocatableAssignment=*/false,
+ /*temporary_lhs=*/true);
+ };
+ if (lhs.isAllocatable()) {
+ // Deep copy allocatable if it is allocated.
+ // Note that when allocated, the RHS is already allocated with the LHS
+ // shape for copy on entry in createHostAssociateVarClone.
+ // For lastprivate, this assumes that the RHS was not reallocated in
+ // the OpenMP region.
+ lhs = hlfir::derefPointersAndAllocatables(loc, *builder, lhs);
+ mlir::Value addr = hlfir::genVariableRawAddress(loc, *builder, lhs);
+ mlir::Value isAllocated = builder->genIsNotNullAddr(loc, addr);
+ builder->genIfThen(loc, isAllocated)
+ .genThen([&]() {
+ // Copy the DATA, not the descriptors.
+ copyData(lhs, rhs);
+ })
+ .end();
+ } else if (lhs.isPointer()) {
+ // Set LHS target to the target of RHS (do not copy the RHS
+ // target data into the LHS target storage).
+ auto loadVal = builder->create<fir::LoadOp>(loc, rhs);
+ builder->create<fir::StoreOp>(loc, loadVal, lhs);
+ } else {
+ // Non ALLOCATABLE/POINTER variable. Simple DATA copy.
+ copyData(lhs, rhs);
+ }
+ } else {
+ fir::ExtendedValue lhs = symBoxToExtendedValue(*lhs_sb);
+ fir::ExtendedValue rhs = symBoxToExtendedValue(*rhs_sb);
+ mlir::Type symType = genType(sym);
+ if (auto seqTy = symType.dyn_cast<fir::SequenceType>()) {
+ Fortran::lower::StatementContext stmtCtx;
+ Fortran::lower::createSomeArrayAssignment(*this, lhs, rhs, localSymbols,
+ stmtCtx);
+ stmtCtx.finalizeAndReset();
+ } else if (lhs.getBoxOf<fir::CharBoxValue>()) {
+ fir::factory::CharacterExprHelper{*builder, loc}.createAssign(lhs, rhs);
+ } else {
+ auto loadVal = builder->create<fir::LoadOp>(loc, fir::getBase(rhs));
+ builder->create<fir::StoreOp>(loc, loadVal, fir::getBase(lhs));
}
- return symBoxToExtendedValue(sb);
}
- mlir::Value impliedDoBinding(llvm::StringRef name) override final {
- mlir::Value val = localSymbols.lookupImpliedDo(name);
- if (!val)
- fir::emitFatalError(toLocation(), "ac-do-variable has no binding");
- return val;
+ if (copyAssignIP && copyAssignIP->isSet() &&
+ sym.test(Fortran::semantics::Symbol::Flag::OmpLastPrivate)) {
+ builder->restoreInsertionPoint(insPt);
}
+}
- void copySymbolBinding(Fortran::lower::SymbolRef src,
- Fortran::lower::SymbolRef target) override final {
- localSymbols.copySymbolBinding(src, target);
- }
+//===--------------------------------------------------------------------===//
+// Utility methods
+//===--------------------------------------------------------------------===//
+
+void FirConverter::collectSymbolSet(
+ Fortran::lower::pft::Evaluation &eval,
+ llvm::SetVector<const Fortran::semantics::Symbol *> &symbolSet,
+ Fortran::semantics::Symbol::Flag flag, bool collectSymbols,
+ bool checkHostAssociatedSymbols) {
+ auto addToList = [&](const Fortran::semantics::Symbol &sym) {
+ std::function<void(const Fortran::semantics::Symbol &, bool)>
+ insertSymbols = [&](const Fortran::semantics::Symbol &oriSymbol,
+ bool collectSymbol) {
+ if (collectSymbol && oriSymbol.test(flag))
+ symbolSet.insert(&oriSymbol);
+ if (checkHostAssociatedSymbols)
+ if (const auto *details{
+ oriSymbol
+ .detailsIf<Fortran::semantics::HostAssocDetails>()})
+ insertSymbols(details->symbol(), true);
+ };
+ insertSymbols(sym, collectSymbols);
+ };
+ Fortran::lower::pft::visitAllSymbols(eval, addToList);
+}
- /// Add the symbol binding to the inner-most level of the symbol map and
- /// return true if it is not already present. Otherwise, return false.
- bool bindIfNewSymbol(Fortran::lower::SymbolRef sym,
- const fir::ExtendedValue &exval) {
- if (shallowLookupSymbol(sym))
- return false;
- bindSymbol(sym, exval);
- return true;
+/// Generate a `Location` from the `CharBlock`.
+mlir::Location
+FirConverter::genLocation(const Fortran::parser::CharBlock &block) {
+ if (const Fortran::parser::AllCookedSources *cooked =
+ bridge.getCookedSource()) {
+ if (std::optional<Fortran::parser::ProvenanceRange> provenance =
+ cooked->GetProvenanceRange(block)) {
+ if (std::optional<Fortran::parser::SourcePosition> filePos =
+ cooked->allSources().GetSourcePosition(provenance->start())) {
+ llvm::SmallString<256> filePath(*filePos->path);
+ llvm::sys::fs::make_absolute(filePath);
+ llvm::sys::path::remove_dots(filePath);
+ return mlir::FileLineColLoc::get(&getMLIRContext(), filePath.str(),
+ filePos->line, filePos->column);
+ }
+ }
}
+ return genUnknownLocation();
+}
- void bindSymbol(Fortran::lower::SymbolRef sym,
- const fir::ExtendedValue &exval) override final {
- addSymbol(sym, exval, /*forced=*/true);
- }
+/// Return the current function context, which may be a nested BLOCK context
+/// or a full subprogram context.
+Fortran::lower::StatementContext &FirConverter::getFctCtx() {
+ if (!activeConstructStack.empty() &&
+ activeConstructStack.back().eval.isA<Fortran::parser::BlockConstruct>())
+ return activeConstructStack.back().stmtCtx;
+ return bridge.fctCtx();
+}
- void
- overrideExprValues(const Fortran::lower::ExprToValueMap *map) override final {
- exprValueOverrides = map;
+llvm::StringRef
+FirConverter::getUniqueLitName(mlir::Location loc,
+ std::unique_ptr<Fortran::lower::SomeExpr> expr,
+ mlir::Type eleTy) {
+ std::string namePrefix = getConstantExprManglePrefix(loc, *expr.get(), eleTy);
+ auto [it, inserted] = literalNamesMap.try_emplace(
+ expr.get(), namePrefix + std::to_string(uniqueLitId));
+ const auto &name = it->second;
+ if (inserted) {
+ // Keep ownership of the expr key.
+ literalExprsStorage.push_back(std::move(expr));
+
+ // If we've just added a new name, we have to make sure
+ // there is no global object with the same name in the module.
+ fir::GlobalOp global = builder->getNamedGlobal(name);
+ if (global)
+ fir::emitFatalError(loc, llvm::Twine("global object with name '") +
+ llvm::Twine(name) +
+ llvm::Twine("' already exists"));
+ ++uniqueLitId;
+ return name;
}
- const Fortran::lower::ExprToValueMap *getExprOverrides() override final {
- return exprValueOverrides;
- }
+ // The name already exists. Verify that the prefix is the same.
+ if (!llvm::StringRef(name).starts_with(namePrefix))
+ fir::emitFatalError(loc, llvm::Twine("conflicting prefixes: '") +
+ llvm::Twine(name) +
+ llvm::Twine("' does not start with '") +
+ llvm::Twine(namePrefix) + llvm::Twine("'"));
- bool lookupLabelSet(Fortran::lower::SymbolRef sym,
- Fortran::lower::pft::LabelSet &labelSet) override final {
- Fortran::lower::pft::FunctionLikeUnit &owningProc =
- *getEval().getOwningProcedure();
- auto iter = owningProc.assignSymbolLabelMap.find(sym);
- if (iter == owningProc.assignSymbolLabelMap.end())
- return false;
- labelSet = iter->second;
- return true;
- }
+ return name;
+}
- Fortran::lower::pft::Evaluation *
- lookupLabel(Fortran::lower::pft::Label label) override final {
- Fortran::lower::pft::FunctionLikeUnit &owningProc =
- *getEval().getOwningProcedure();
- return owningProc.labelEvaluationMap.lookup(label);
- }
+void FirConverter::TypeInfoConverter::registerTypeInfo(
+ Fortran::lower::AbstractConverter &converter, mlir::Location loc,
+ Fortran::semantics::SymbolRef typeInfoSym,
+ const Fortran::semantics::DerivedTypeSpec &typeSpec, fir::RecordType type) {
+ if (seen.contains(typeInfoSym))
+ return;
+ seen.insert(typeInfoSym);
+ if (!skipRegistration) {
+ registeredTypeInfo.emplace_back(TypeInfo{typeInfoSym, typeSpec, type, loc});
+ return;
+ }
+ // Once the registration is closed, symbols cannot be added to the
+ // registeredTypeInfoSymbols list because it may be iterated over.
+ // However, after registration is closed, it is safe to directly generate
+ // the globals because all FuncOps whose addresses may be required by the
+ // initializers have been generated.
+ createTypeInfoOpAndGlobal(converter,
+ TypeInfo{typeInfoSym, typeSpec, type, loc});
+}
- fir::ExtendedValue
- genExprAddr(const Fortran::lower::SomeExpr &expr,
- Fortran::lower::StatementContext &context,
- mlir::Location *locPtr = nullptr) override final {
- mlir::Location loc = locPtr ? *locPtr : toLocation();
- if (lowerToHighLevelFIR())
- return Fortran::lower::convertExprToAddress(loc, *this, expr,
- localSymbols, context);
- return Fortran::lower::createSomeExtendedAddress(loc, *this, expr,
- localSymbols, context);
- }
+void FirConverter::TypeInfoConverter::createTypeInfo(
+ Fortran::lower::AbstractConverter &converter) {
+ skipRegistration = true;
+ for (const TypeInfo &info : registeredTypeInfo)
+ createTypeInfoOpAndGlobal(converter, info);
+ registeredTypeInfo.clear();
+}
- fir::ExtendedValue
- genExprValue(const Fortran::lower::SomeExpr &expr,
- Fortran::lower::StatementContext &context,
- mlir::Location *locPtr = nullptr) override final {
- mlir::Location loc = locPtr ? *locPtr : toLocation();
- if (lowerToHighLevelFIR())
- return Fortran::lower::convertExprToValue(loc, *this, expr, localSymbols,
- context);
- return Fortran::lower::createSomeExtendedExpression(loc, *this, expr,
- localSymbols, context);
- }
+void FirConverter::TypeInfoConverter::createTypeInfoOpAndGlobal(
+ Fortran::lower::AbstractConverter &converter, const TypeInfo &info) {
+ Fortran::lower::createRuntimeTypeInfoGlobal(converter, info.symbol.get());
+ createTypeInfoOp(converter, info);
+}
- fir::ExtendedValue
- genExprBox(mlir::Location loc, const Fortran::lower::SomeExpr &expr,
- Fortran::lower::StatementContext &stmtCtx) override final {
- if (lowerToHighLevelFIR())
- return Fortran::lower::convertExprToBox(loc, *this, expr, localSymbols,
- stmtCtx);
- return Fortran::lower::createBoxValue(loc, *this, expr, localSymbols,
- stmtCtx);
+void FirConverter::TypeInfoConverter::createTypeInfoOp(
+ Fortran::lower::AbstractConverter &converter, const TypeInfo &info) {
+ fir::RecordType parentType{};
+ if (const Fortran::semantics::DerivedTypeSpec *parent =
+ Fortran::evaluate::GetParentTypeSpec(info.typeSpec))
+ parentType = mlir::cast<fir::RecordType>(converter.genType(*parent));
+
+ fir::FirOpBuilder &builder = converter.getFirOpBuilder();
+ mlir::ModuleOp module = builder.getModule();
+ fir::TypeInfoOp dt =
+ module.lookupSymbol<fir::TypeInfoOp>(info.type.getName());
+ if (dt)
+ return; // Already created.
+ auto insertPt = builder.saveInsertionPoint();
+ builder.setInsertionPoint(module.getBody(), module.getBody()->end());
+ dt = builder.create<fir::TypeInfoOp>(info.loc, info.type, parentType);
+
+ if (!info.typeSpec.HasDefaultInitialization(/*ignoreAllocatable=*/false,
+ /*ignorePointer=*/false))
+ dt->setAttr(dt.getNoInitAttrName(), builder.getUnitAttr());
+ if (!info.typeSpec.HasDestruction())
+ dt->setAttr(dt.getNoDestroyAttrName(), builder.getUnitAttr());
+ if (!Fortran::semantics::MayRequireFinalization(info.typeSpec))
+ dt->setAttr(dt.getNoFinalAttrName(), builder.getUnitAttr());
+
+ const Fortran::semantics::Scope *scope = info.typeSpec.scope();
+ if (!scope)
+ scope = info.typeSpec.typeSymbol().scope();
+ assert(scope && "failed to find type scope");
+
+ Fortran::semantics::SymbolVector bindings =
+ Fortran::semantics::CollectBindings(*scope);
+ if (!bindings.empty()) {
+ builder.createBlock(&dt.getDispatchTable());
+ for (const Fortran::semantics::SymbolRef &binding : bindings) {
+ const auto &details =
+ binding.get().get<Fortran::semantics::ProcBindingDetails>();
+ std::string tbpName = binding.get().name().ToString();
+ if (details.numPrivatesNotOverridden() > 0)
+ tbpName += "."s + std::to_string(details.numPrivatesNotOverridden());
+ std::string bindingName = converter.mangleName(details.symbol());
+ builder.create<fir::DTEntryOp>(
+ info.loc, mlir::StringAttr::get(builder.getContext(), tbpName),
+ mlir::SymbolRefAttr::get(builder.getContext(), bindingName));
+ }
+ builder.create<fir::FirEndOp>(info.loc);
}
+ builder.restoreInsertionPoint(insertPt);
+}
- Fortran::evaluate::FoldingContext &getFoldingContext() override final {
- return foldingContext;
- }
+//===--------------------------------------------------------------------===//
+// Helper member functions
+//===--------------------------------------------------------------------===//
+
+/// Find the symbol in the local map or return null.
+Fortran::lower::SymbolBox
+FirConverter::lookupSymbol(const Fortran::semantics::Symbol &sym,
+ Fortran::lower::SymMap *symMap) {
+ symMap = symMap ? symMap : &localSymbols;
+ if (lowerToHighLevelFIR()) {
+ if (std::optional<fir::FortranVariableOpInterface> var =
+ symMap->lookupVariableDefinition(sym)) {
+ auto exv = hlfir::translateToExtendedValue(toLocation(), *builder, *var);
+ return exv.match(
+ [](mlir::Value x) -> Fortran::lower::SymbolBox {
+ return Fortran::lower::SymbolBox::Intrinsic{x};
+ },
+ [](auto x) -> Fortran::lower::SymbolBox { return x; });
+ }
- mlir::Type genType(const Fortran::lower::SomeExpr &expr) override final {
- return Fortran::lower::translateSomeExprToFIRType(*this, expr);
- }
- mlir::Type genType(const Fortran::lower::pft::Variable &var) override final {
- return Fortran::lower::translateVariableToFIRType(*this, var);
- }
- mlir::Type genType(Fortran::lower::SymbolRef sym) override final {
- return Fortran::lower::translateSymbolToFIRType(*this, sym);
- }
- mlir::Type
- genType(Fortran::common::TypeCategory tc, int kind,
- llvm::ArrayRef<std::int64_t> lenParameters) override final {
- return Fortran::lower::getFIRType(&getMLIRContext(), tc, kind,
- lenParameters);
- }
- mlir::Type
- genType(const Fortran::semantics::DerivedTypeSpec &tySpec) override final {
- return Fortran::lower::translateDerivedTypeToFIRType(*this, tySpec);
+ // Entry character result represented as an argument pair
+ // needs to be represented in the symbol table even before
+ // we can create DeclareOp for it. The temporary mapping
+ // is EmboxCharOp that conveys the address and length information.
+ // After mapSymbolAttributes is done, the mapping is replaced
+ // with the new DeclareOp, and the following table lookups
+ // do not reach here.
+ if (sym.IsFuncResult())
+ if (const Fortran::semantics::DeclTypeSpec *declTy = sym.GetType())
+ if (declTy->category() ==
+ Fortran::semantics::DeclTypeSpec::Category::Character)
+ return symMap->lookupSymbol(sym);
+
+ // Procedure dummies are not mapped with an hlfir.declare because
+ // they are not "variable" (cannot be assigned to), and it would
+ // make hlfir.declare more complex than it needs to to allow this.
+ // Do a regular lookup.
+ if (Fortran::semantics::IsProcedure(sym))
+ return symMap->lookupSymbol(sym);
+
+ // Commonblock names are not variables, but in some lowerings (like
+ // OpenMP) it is useful to maintain the address of the commonblock in an
+ // MLIR value and query it. hlfir.declare need not be created for these.
+ if (sym.detailsIf<Fortran::semantics::CommonBlockDetails>())
+ return symMap->lookupSymbol(sym);
+
+ return {};
}
- mlir::Type genType(Fortran::common::TypeCategory tc) override final {
- return Fortran::lower::getFIRType(
- &getMLIRContext(), tc, bridge.getDefaultKinds().GetDefaultKind(tc),
- std::nullopt);
+ if (Fortran::lower::SymbolBox v = symMap->lookupSymbol(sym))
+ return v;
+ return {};
+}
+
+/// Add the symbol to the local map and return `true`. If the symbol is
+/// already in the map and \p forced is `false`, the map is not updated.
+/// Instead the value `false` is returned.
+bool FirConverter::addSymbol(const Fortran::semantics::SymbolRef sym,
+ fir::ExtendedValue val, bool forced) {
+ if (!forced && lookupSymbol(sym))
+ return false;
+ if (lowerToHighLevelFIR()) {
+ Fortran::lower::genDeclareSymbol(*this, localSymbols, sym, val,
+ fir::FortranVariableFlagsEnum::None,
+ forced);
+ } else {
+ localSymbols.addSymbol(sym, val, forced);
}
+ return true;
+}
+
+/// Map a block argument to a result or dummy symbol. This is not the
+/// definitive mapping. The specification expression have not been lowered
+/// yet. The final mapping will be done using this pre-mapping in
+/// Fortran::lower::mapSymbolAttributes.
+bool FirConverter::mapBlockArgToDummyOrResult(
+ const Fortran::semantics::SymbolRef sym, mlir::Value val, bool forced) {
+ if (!forced && lookupSymbol(sym))
+ return false;
+ localSymbols.addSymbol(sym, val, forced);
+ return true;
+}
- bool isPresentShallowLookup(Fortran::semantics::Symbol &sym) override final {
- return bool(shallowLookupSymbol(sym));
+/// Generate the address of loop variable \p sym.
+/// If \p sym is not mapped yet, allocate local storage for it.
+mlir::Value
+FirConverter::genLoopVariableAddress(mlir::Location loc,
+ const Fortran::semantics::Symbol &sym,
+ bool isUnordered) {
+ if (isUnordered || sym.has<Fortran::semantics::HostAssocDetails>() ||
+ sym.has<Fortran::semantics::UseDetails>()) {
+ if (!shallowLookupSymbol(sym)) {
+ // Do concurrent loop variables are not mapped yet since they are local
+ // to the Do concurrent scope (same for OpenMP loops).
+ mlir::OpBuilder::InsertPoint insPt = builder->saveInsertionPoint();
+ builder->setInsertionPointToStart(builder->getAllocaBlock());
+ mlir::Type tempTy = genType(sym);
+ mlir::Value temp =
+ builder->createTemporaryAlloc(loc, tempTy, toStringRef(sym.name()));
+ bindIfNewSymbol(sym, temp);
+ builder->restoreInsertionPoint(insPt);
+ }
}
+ auto entry = lookupSymbol(sym);
+ (void)entry;
+ assert(entry && "loop control variable must already be in map");
+ Fortran::lower::StatementContext stmtCtx;
+ return fir::getBase(
+ genExprAddr(Fortran::evaluate::AsGenericExpr(sym).value(), stmtCtx));
+}
- bool createHostAssociateVarClone(
- const Fortran::semantics::Symbol &sym) override final {
- mlir::Location loc = genLocation(sym.name());
- mlir::Type symType = genType(sym);
- const auto *details = sym.detailsIf<Fortran::semantics::HostAssocDetails>();
- assert(details && "No host-association found");
- const Fortran::semantics::Symbol &hsym = details->symbol();
- mlir::Type hSymType = genType(hsym);
- Fortran::lower::SymbolBox hsb = lookupSymbol(hsym);
-
- auto allocate = [&](llvm::ArrayRef<mlir::Value> shape,
- llvm::ArrayRef<mlir::Value> typeParams) -> mlir::Value {
- mlir::Value allocVal = builder->allocateLocal(
- loc,
- Fortran::semantics::IsAllocatableOrObjectPointer(&hsym.GetUltimate())
- ? hSymType
- : symType,
- mangleName(sym), toStringRef(sym.GetUltimate().name()),
- /*pinned=*/true, shape, typeParams,
- sym.GetUltimate().attrs().test(Fortran::semantics::Attr::TARGET));
- return allocVal;
- };
+/// Insert a new block before \p block. Leave the insertion point unchanged.
+mlir::Block *FirConverter::insertBlock(mlir::Block *block) {
+ mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
+ mlir::Block *newBlock = builder->createBlock(block);
+ builder->restoreInsertionPoint(insertPt);
+ return newBlock;
+}
- fir::ExtendedValue hexv = symBoxToExtendedValue(hsb);
- fir::ExtendedValue exv = hexv.match(
- [&](const fir::BoxValue &box) -> fir::ExtendedValue {
- const Fortran::semantics::DeclTypeSpec *type = sym.GetType();
- if (type && type->IsPolymorphic())
- TODO(loc, "create polymorphic host associated copy");
- // Create a contiguous temp with the same shape and length as
- // the original variable described by a fir.box.
- llvm::SmallVector<mlir::Value> extents =
- fir::factory::getExtents(loc, *builder, hexv);
- if (box.isDerivedWithLenParameters())
- TODO(loc, "get length parameters from derived type BoxValue");
- if (box.isCharacter()) {
- mlir::Value len = fir::factory::readCharLen(*builder, loc, box);
- mlir::Value temp = allocate(extents, {len});
- return fir::CharArrayBoxValue{temp, len, extents};
- }
- return fir::ArrayBoxValue{allocate(extents, {}), extents};
- },
- [&](const fir::MutableBoxValue &box) -> fir::ExtendedValue {
- // Allocate storage for a pointer/allocatble descriptor.
- // No shape/lengths to be passed to the alloca.
- return fir::MutableBoxValue(allocate({}, {}), {}, {});
- },
- [&](const auto &) -> fir::ExtendedValue {
- mlir::Value temp =
- allocate(fir::factory::getExtents(loc, *builder, hexv),
- fir::factory::getTypeParams(loc, *builder, hexv));
- return fir::substBase(hexv, temp);
- });
+Fortran::lower::pft::Evaluation &
+FirConverter::evalOfLabel(Fortran::parser::Label label) {
+ const Fortran::lower::pft::LabelEvalMap &labelEvaluationMap =
+ getEval().getOwningProcedure()->labelEvaluationMap;
+ const auto iter = labelEvaluationMap.find(label);
+ assert(iter != labelEvaluationMap.end() && "label missing from map");
+ return *iter->second;
+}
- // Initialise cloned allocatable
- hexv.match(
- [&](const fir::MutableBoxValue &box) -> void {
- // Do not process pointers
- if (Fortran::semantics::IsPointer(sym.GetUltimate())) {
- return;
- }
- // Allocate storage for a pointer/allocatble descriptor.
- // No shape/lengths to be passed to the alloca.
- const auto new_box = exv.getBoxOf<fir::MutableBoxValue>();
-
- // allocate if allocated
- mlir::Value isAllocated =
- fir::factory::genIsAllocatedOrAssociatedTest(*builder, loc, box);
- auto if_builder = builder->genIfThenElse(loc, isAllocated);
- if_builder.genThen([&]() {
- std::string name = mangleName(sym) + ".alloc";
- if (auto seqTy = symType.dyn_cast<fir::SequenceType>()) {
- fir::ExtendedValue read = fir::factory::genMutableBoxRead(
- *builder, loc, box, /*mayBePolymorphic=*/false);
- if (auto read_arr_box = read.getBoxOf<fir::ArrayBoxValue>()) {
- fir::factory::genInlinedAllocation(
- *builder, loc, *new_box, read_arr_box->getLBounds(),
- read_arr_box->getExtents(),
- /*lenParams=*/std::nullopt, name,
- /*mustBeHeap=*/true);
- } else if (auto read_char_arr_box =
- read.getBoxOf<fir::CharArrayBoxValue>()) {
- fir::factory::genInlinedAllocation(
- *builder, loc, *new_box, read_char_arr_box->getLBounds(),
- read_char_arr_box->getExtents(),
- read_char_arr_box->getLen(), name,
- /*mustBeHeap=*/true);
- } else {
- TODO(loc, "Unhandled allocatable box type");
- }
- } else {
- fir::factory::genInlinedAllocation(
- *builder, loc, *new_box, box.getMutableProperties().lbounds,
- box.getMutableProperties().extents,
- box.nonDeferredLenParams(), name,
- /*mustBeHeap=*/true);
- }
- });
- if_builder.genElse([&]() {
- // nullify box
- auto empty = fir::factory::createUnallocatedBox(
- *builder, loc, new_box->getBoxTy(),
- new_box->nonDeferredLenParams(), {});
- builder->create<fir::StoreOp>(loc, empty, new_box->getAddr());
- });
- if_builder.end();
- },
- [&](const auto &) -> void {
- // Do nothing
- });
+void FirConverter::genConditionalBranch(mlir::Value cond,
+ mlir::Block *trueTarget,
+ mlir::Block *falseTarget) {
+ assert(trueTarget && "missing conditional branch true block");
+ assert(falseTarget && "missing conditional branch false block");
+ mlir::Location loc = toLocation();
+ mlir::Value bcc = builder->createConvert(loc, builder->getI1Type(), cond);
+ builder->create<mlir::cf::CondBranchOp>(loc, bcc, trueTarget, std::nullopt,
+ falseTarget, std::nullopt);
+}
- return bindIfNewSymbol(sym, exv);
- }
+void FirConverter::genConditionalBranch(
+ const Fortran::parser::ScalarLogicalExpr &expr, mlir::Block *trueTarget,
+ mlir::Block *falseTarget) {
+ Fortran::lower::StatementContext stmtCtx;
+ mlir::Value cond =
+ createFIRExpr(toLocation(), Fortran::semantics::GetExpr(expr), stmtCtx);
+ stmtCtx.finalizeAndReset();
+ genConditionalBranch(cond, trueTarget, falseTarget);
+}
- void createHostAssociateVarCloneDealloc(
- const Fortran::semantics::Symbol &sym) override final {
- mlir::Location loc = genLocation(sym.name());
- Fortran::lower::SymbolBox hsb = lookupSymbol(sym);
-
- fir::ExtendedValue hexv = symBoxToExtendedValue(hsb);
- hexv.match(
- [&](const fir::MutableBoxValue &new_box) -> void {
- // Do not process pointers
- if (Fortran::semantics::IsPointer(sym.GetUltimate())) {
- return;
- }
- // deallocate allocated in createHostAssociateVarClone value
- Fortran::lower::genDeallocateIfAllocated(*this, new_box, loc);
- },
- [&](const auto &) -> void {
- // Do nothing
- });
+void FirConverter::genConditionalBranch(
+ const Fortran::parser::ScalarLogicalExpr &expr,
+ Fortran::lower::pft::Evaluation *trueTarget,
+ Fortran::lower::pft::Evaluation *falseTarget) {
+ Fortran::lower::StatementContext stmtCtx;
+ mlir::Value cond =
+ createFIRExpr(toLocation(), Fortran::semantics::GetExpr(expr), stmtCtx);
+ stmtCtx.finalizeAndReset();
+ genConditionalBranch(cond, trueTarget->block, falseTarget->block);
+}
+
+/// Return the nearest active ancestor construct of \p eval, or nullptr.
+Fortran::lower::pft::Evaluation *
+FirConverter::getActiveAncestor(const Fortran::lower::pft::Evaluation &eval) {
+ Fortran::lower::pft::Evaluation *ancestor = eval.parentConstruct;
+ for (; ancestor; ancestor = ancestor->parentConstruct)
+ if (ancestor->activeConstruct)
+ break;
+ return ancestor;
+}
+
+/// Return the predicate: "a branch to \p targetEval has exit code".
+bool FirConverter::hasExitCode(
+ const Fortran::lower::pft::Evaluation &targetEval) {
+ Fortran::lower::pft::Evaluation *activeAncestor =
+ getActiveAncestor(targetEval);
+ for (auto it = activeConstructStack.rbegin(),
+ rend = activeConstructStack.rend();
+ it != rend; ++it) {
+ if (&it->eval == activeAncestor)
+ break;
+ if (it->stmtCtx.hasCode())
+ return true;
}
+ return false;
+}
- void copyHostAssociateVar(
- const Fortran::semantics::Symbol &sym,
- mlir::OpBuilder::InsertPoint *copyAssignIP = nullptr) override final {
- // 1) Fetch the original copy of the variable.
- assert(sym.has<Fortran::semantics::HostAssocDetails>() &&
- "No host-association found");
- const Fortran::semantics::Symbol &hsym = sym.GetUltimate();
- Fortran::lower::SymbolBox hsb = lookupOneLevelUpSymbol(hsym);
- assert(hsb && "Host symbol box not found");
-
- // 2) Fetch the copied one that will mask the original.
- Fortran::lower::SymbolBox sb = shallowLookupSymbol(sym);
- assert(sb && "Host-associated symbol box not found");
- assert(hsb.getAddr() != sb.getAddr() &&
- "Host and associated symbol boxes are the same");
-
- // 3) Perform the assignment.
- mlir::OpBuilder::InsertPoint insPt = builder->saveInsertionPoint();
- if (copyAssignIP && copyAssignIP->isSet())
- builder->restoreInsertionPoint(*copyAssignIP);
- else
- builder->setInsertionPointAfter(sb.getAddr().getDefiningOp());
-
- Fortran::lower::SymbolBox *lhs_sb, *rhs_sb;
- if (copyAssignIP && copyAssignIP->isSet() &&
- sym.test(Fortran::semantics::Symbol::Flag::OmpLastPrivate)) {
- // lastprivate case
- lhs_sb = &hsb;
- rhs_sb = &sb;
- } else {
- lhs_sb = &sb;
- rhs_sb = &hsb;
- }
+/// Generate a branch to \p targetEval after generating on-exit code for
+/// any enclosing construct scopes that are exited by taking the branch.
+void FirConverter::genConstructExitBranch(
+ const Fortran::lower::pft::Evaluation &targetEval) {
+ Fortran::lower::pft::Evaluation *activeAncestor =
+ getActiveAncestor(targetEval);
+ for (auto it = activeConstructStack.rbegin(),
+ rend = activeConstructStack.rend();
+ it != rend; ++it) {
+ if (&it->eval == activeAncestor)
+ break;
+ it->stmtCtx.finalizeAndKeep();
+ }
+ genBranch(targetEval.block);
+}
- mlir::Location loc = genLocation(sym.name());
-
- if (lowerToHighLevelFIR()) {
- hlfir::Entity lhs{lhs_sb->getAddr()};
- hlfir::Entity rhs{rhs_sb->getAddr()};
- // Temporary_lhs is set to true in hlfir.assign below to avoid user
- // assignment to be used and finalization to be called on the LHS.
- // This may or may not be correct but mimics the current behaviour
- // without HLFIR.
- auto copyData = [&](hlfir::Entity l, hlfir::Entity r) {
- // Dereference RHS and load it if trivial scalar.
- r = hlfir::loadTrivialScalar(loc, *builder, r);
- builder->create<hlfir::AssignOp>(
- loc, r, l,
- /*isWholeAllocatableAssignment=*/false,
- /*keepLhsLengthInAllocatableAssignment=*/false,
- /*temporary_lhs=*/true);
- };
- if (lhs.isAllocatable()) {
- // Deep copy allocatable if it is allocated.
- // Note that when allocated, the RHS is already allocated with the LHS
- // shape for copy on entry in createHostAssociateVarClone.
- // For lastprivate, this assumes that the RHS was not reallocated in
- // the OpenMP region.
- lhs = hlfir::derefPointersAndAllocatables(loc, *builder, lhs);
- mlir::Value addr = hlfir::genVariableRawAddress(loc, *builder, lhs);
- mlir::Value isAllocated = builder->genIsNotNullAddr(loc, addr);
- builder->genIfThen(loc, isAllocated)
- .genThen([&]() {
- // Copy the DATA, not the descriptors.
- copyData(lhs, rhs);
- })
- .end();
- } else if (lhs.isPointer()) {
- // Set LHS target to the target of RHS (do not copy the RHS
- // target data into the LHS target storage).
- auto loadVal = builder->create<fir::LoadOp>(loc, rhs);
- builder->create<fir::StoreOp>(loc, loadVal, lhs);
- } else {
- // Non ALLOCATABLE/POINTER variable. Simple DATA copy.
- copyData(lhs, rhs);
+/// Generate a SelectOp or branch sequence that compares \p selector against
+/// values in \p valueList and targets corresponding labels in \p labelList.
+/// If no value matches the selector, branch to \p defaultEval.
+///
+/// Three cases require special processing.
+///
+/// An empty \p valueList indicates an ArithmeticIfStmt context that requires
+/// two comparisons against 0 or 0.0. The selector may have either INTEGER
+/// or REAL type.
+///
+/// A nonpositive \p valuelist value indicates an IO statement context
+/// (0 for ERR, -1 for END, -2 for EOR). An ERR branch must be taken for
+/// any positive (IOSTAT) value. A missing (zero) label requires a branch
+/// to \p defaultEval for that value.
+///
+/// A non-null \p errorBlock indicates an AssignedGotoStmt context that
+/// must always branch to an explicit target. There is no valid defaultEval
+/// in this case. Generate a branch to \p errorBlock for an AssignedGotoStmt
+/// that violates this program requirement.
+///
+/// If this is not an ArithmeticIfStmt and no targets have exit code,
+/// generate a SelectOp. Otherwise, for each target, if it has exit code,
+/// branch to a new block, insert exit code, and then branch to the target.
+/// Otherwise, branch directly to the target.
+void FirConverter::genMultiwayBranch(
+ mlir::Value selector, llvm::SmallVector<int64_t> valueList,
+ llvm::SmallVector<Fortran::parser::Label> labelList,
+ const Fortran::lower::pft::Evaluation &defaultEval,
+ mlir::Block *errorBlock) {
+ bool inArithmeticIfContext = valueList.empty();
+ assert(((inArithmeticIfContext && labelList.size() == 2) ||
+ (valueList.size() && labelList.size() == valueList.size())) &&
+ "mismatched multiway branch targets");
+ mlir::Block *defaultBlock = errorBlock ? errorBlock : defaultEval.block;
+ bool defaultHasExitCode = !errorBlock && hasExitCode(defaultEval);
+ bool hasAnyExitCode = defaultHasExitCode;
+ if (!hasAnyExitCode)
+ for (auto label : labelList)
+ if (label && hasExitCode(evalOfLabel(label))) {
+ hasAnyExitCode = true;
+ break;
}
+ mlir::Location loc = toLocation();
+ size_t branchCount = labelList.size();
+ if (!inArithmeticIfContext && !hasAnyExitCode &&
+ !getEval().forceAsUnstructured()) { // from -no-structured-fir option
+ // Generate a SelectOp.
+ llvm::SmallVector<mlir::Block *> blockList;
+ for (auto label : labelList) {
+ mlir::Block *block = label ? evalOfLabel(label).block : defaultEval.block;
+ assert(block && "missing multiway branch block");
+ blockList.push_back(block);
+ }
+ blockList.push_back(defaultBlock);
+ if (valueList[branchCount - 1] == 0) // Swap IO ERR and default blocks.
+ std::swap(blockList[branchCount - 1], blockList[branchCount]);
+ builder->create<fir::SelectOp>(loc, selector, valueList, blockList);
+ return;
+ }
+ mlir::Type selectorType = selector.getType();
+ bool realSelector = selectorType.isa<mlir::FloatType>();
+ assert((inArithmeticIfContext || !realSelector) && "invalid selector type");
+ mlir::Value zero;
+ if (inArithmeticIfContext)
+ zero = realSelector ? builder->create<mlir::arith::ConstantOp>(
+ loc, selectorType,
+ builder->getFloatAttr(selectorType, 0.0))
+ : builder->createIntegerConstant(loc, selectorType, 0);
+ for (auto label : llvm::enumerate(labelList)) {
+ mlir::Value cond;
+ if (realSelector) // inArithmeticIfContext
+ cond = builder->create<mlir::arith::CmpFOp>(
+ loc,
+ label.index() == 0 ? mlir::arith::CmpFPredicate::OLT
+ : mlir::arith::CmpFPredicate::OGT,
+ selector, zero);
+ else if (inArithmeticIfContext) // INTEGER selector
+ cond = builder->create<mlir::arith::CmpIOp>(
+ loc,
+ label.index() == 0 ? mlir::arith::CmpIPredicate::slt
+ : mlir::arith::CmpIPredicate::sgt,
+ selector, zero);
+ else // A value of 0 is an IO ERR branch: invert comparison.
+ cond = builder->create<mlir::arith::CmpIOp>(
+ loc,
+ valueList[label.index()] == 0 ? mlir::arith::CmpIPredicate::ne
+ : mlir::arith::CmpIPredicate::eq,
+ selector,
+ builder->createIntegerConstant(loc, selectorType,
+ valueList[label.index()]));
+ // Branch to a new block with exit code and then to the target, or branch
+ // directly to the target. defaultBlock is the "else" target.
+ bool lastBranch = label.index() == branchCount - 1;
+ mlir::Block *nextBlock =
+ lastBranch && !defaultHasExitCode
+ ? defaultBlock
+ : builder->getBlock()->splitBlock(builder->getInsertionPoint());
+ const Fortran::lower::pft::Evaluation &targetEval =
+ label.value() ? evalOfLabel(label.value()) : defaultEval;
+ if (hasExitCode(targetEval)) {
+ mlir::Block *jumpBlock =
+ builder->getBlock()->splitBlock(builder->getInsertionPoint());
+ genConditionalBranch(cond, jumpBlock, nextBlock);
+ startBlock(jumpBlock);
+ genConstructExitBranch(targetEval);
} else {
- fir::ExtendedValue lhs = symBoxToExtendedValue(*lhs_sb);
- fir::ExtendedValue rhs = symBoxToExtendedValue(*rhs_sb);
- mlir::Type symType = genType(sym);
- if (auto seqTy = symType.dyn_cast<fir::SequenceType>()) {
- Fortran::lower::StatementContext stmtCtx;
- Fortran::lower::createSomeArrayAssignment(*this, lhs, rhs, localSymbols,
- stmtCtx);
- stmtCtx.finalizeAndReset();
- } else if (lhs.getBoxOf<fir::CharBoxValue>()) {
- fir::factory::CharacterExprHelper{*builder, loc}.createAssign(lhs, rhs);
- } else {
- auto loadVal = builder->create<fir::LoadOp>(loc, fir::getBase(rhs));
- builder->create<fir::StoreOp>(loc, loadVal, fir::getBase(lhs));
- }
+ genConditionalBranch(cond, targetEval.block, nextBlock);
}
-
- if (copyAssignIP && copyAssignIP->isSet() &&
- sym.test(Fortran::semantics::Symbol::Flag::OmpLastPrivate)) {
- builder->restoreInsertionPoint(insPt);
+ if (!lastBranch) {
+ startBlock(nextBlock);
+ } else if (defaultHasExitCode) {
+ startBlock(nextBlock);
+ genConstructExitBranch(defaultEval);
}
}
+}
- //===--------------------------------------------------------------------===//
- // Utility methods
- //===--------------------------------------------------------------------===//
-
- void collectSymbolSet(
- Fortran::lower::pft::Evaluation &eval,
- llvm::SetVector<const Fortran::semantics::Symbol *> &symbolSet,
- Fortran::semantics::Symbol::Flag flag, bool collectSymbols,
- bool checkHostAssociatedSymbols) override final {
- auto addToList = [&](const Fortran::semantics::Symbol &sym) {
- std::function<void(const Fortran::semantics::Symbol &, bool)>
- insertSymbols = [&](const Fortran::semantics::Symbol &oriSymbol,
- bool collectSymbol) {
- if (collectSymbol && oriSymbol.test(flag))
- symbolSet.insert(&oriSymbol);
- if (checkHostAssociatedSymbols)
- if (const auto *details{
- oriSymbol
- .detailsIf<Fortran::semantics::HostAssocDetails>()})
- insertSymbols(details->symbol(), true);
- };
- insertSymbols(sym, collectSymbols);
- };
- Fortran::lower::pft::visitAllSymbols(eval, addToList);
+//===--------------------------------------------------------------------===//
+// Termination of symbolically referenced execution units
+//===--------------------------------------------------------------------===//
+
+/// END of procedure-like constructs
+///
+/// Generate the cleanup block before the procedure exits
+void FirConverter::genReturnSymbol(
+ const Fortran::semantics::Symbol &functionSymbol) {
+ const Fortran::semantics::Symbol &resultSym =
+ functionSymbol.get<Fortran::semantics::SubprogramDetails>().result();
+ Fortran::lower::SymbolBox resultSymBox = lookupSymbol(resultSym);
+ mlir::Location loc = toLocation();
+ if (!resultSymBox) {
+ mlir::emitError(loc, "internal error when processing function return");
+ return;
+ }
+ mlir::Value resultVal = resultSymBox.match(
+ [&](const fir::CharBoxValue &x) -> mlir::Value {
+ if (Fortran::semantics::IsBindCProcedure(functionSymbol))
+ return builder->create<fir::LoadOp>(loc, x.getBuffer());
+ return fir::factory::CharacterExprHelper{*builder, loc}.createEmboxChar(
+ x.getBuffer(), x.getLen());
+ },
+ [&](const fir::MutableBoxValue &x) -> mlir::Value {
+ mlir::Value resultRef = resultSymBox.getAddr();
+ mlir::Value load = builder->create<fir::LoadOp>(loc, resultRef);
+ unsigned rank = x.rank();
+ if (x.isAllocatable() && rank > 0) {
+ // ALLOCATABLE array result must have default lower bounds.
+ // At the call site the result box of a function reference
+ // might be considered having default lower bounds, but
+ // the runtime box should probably comply with this assumption
+ // as well. If the result box has proper lbounds in runtime,
+ // this may improve the debugging experience of Fortran apps.
+ // We may consider removing this, if the overhead of setting
+ // default lower bounds is too big.
+ mlir::Value one =
+ builder->createIntegerConstant(loc, builder->getIndexType(), 1);
+ llvm::SmallVector<mlir::Value> lbounds{rank, one};
+ auto shiftTy = fir::ShiftType::get(builder->getContext(), rank);
+ mlir::Value shiftOp =
+ builder->create<fir::ShiftOp>(loc, shiftTy, lbounds);
+ load = builder->create<fir::ReboxOp>(
+ loc, load.getType(), load, shiftOp, /*slice=*/mlir::Value{});
+ }
+ return load;
+ },
+ [&](const auto &) -> mlir::Value {
+ mlir::Value resultRef = resultSymBox.getAddr();
+ mlir::Type resultType = genType(resultSym);
+ mlir::Type resultRefType = builder->getRefType(resultType);
+ // A function with multiple entry points returning different types
+ // tags all result variables with one of the largest types to allow
+ // them to share the same storage. Convert this to the actual type.
+ if (resultRef.getType() != resultRefType)
+ resultRef = builder->createConvert(loc, resultRefType, resultRef);
+ return builder->create<fir::LoadOp>(loc, resultRef);
+ });
+ bridge.openAccCtx().finalizeAndPop();
+ bridge.fctCtx().finalizeAndPop();
+ builder->create<mlir::func::ReturnOp>(loc, resultVal);
+}
+
+void FirConverter::genFIRProcedureExit(
+ Fortran::lower::pft::FunctionLikeUnit &funit,
+ const Fortran::semantics::Symbol &symbol) {
+ if (mlir::Block *finalBlock = funit.finalBlock) {
+ // The current block must end with a terminator.
+ if (blockIsUnterminated())
+ builder->create<mlir::cf::BranchOp>(toLocation(), finalBlock);
+ // Set insertion point to final block.
+ builder->setInsertionPoint(finalBlock, finalBlock->end());
+ }
+ if (Fortran::semantics::IsFunction(symbol)) {
+ genReturnSymbol(symbol);
+ } else if (Fortran::semantics::HasAlternateReturns(symbol)) {
+ mlir::Value retval =
+ builder->create<fir::LoadOp>(toLocation(), getAltReturnResult(symbol));
+ bridge.openAccCtx().finalizeAndPop();
+ bridge.fctCtx().finalizeAndPop();
+ builder->create<mlir::func::ReturnOp>(toLocation(), retval);
+ } else {
+ bridge.openAccCtx().finalizeAndPop();
+ bridge.fctCtx().finalizeAndPop();
+ genExitRoutine();
}
+}
- mlir::Location getCurrentLocation() override final { return toLocation(); }
+//
+// Statements that have control-flow semantics
+//
- /// Generate a dummy location.
- mlir::Location genUnknownLocation() override final {
- // Note: builder may not be instantiated yet
- return mlir::UnknownLoc::get(&getMLIRContext());
+mlir::func::FuncOp FirConverter::getFunc(llvm::StringRef name,
+ mlir::FunctionType ty) {
+ if (mlir::func::FuncOp func = builder->getNamedFunction(name)) {
+ assert(func.getFunctionType() == ty);
+ return func;
}
+ return builder->createFunction(toLocation(), name, ty);
+}
- /// Generate a `Location` from the `CharBlock`.
- mlir::Location
- genLocation(const Fortran::parser::CharBlock &block) override final {
- if (const Fortran::parser::AllCookedSources *cooked =
- bridge.getCookedSource()) {
- if (std::optional<Fortran::parser::ProvenanceRange> provenance =
- cooked->GetProvenanceRange(block)) {
- if (std::optional<Fortran::parser::SourcePosition> filePos =
- cooked->allSources().GetSourcePosition(provenance->start())) {
- llvm::SmallString<256> filePath(*filePos->path);
- llvm::sys::fs::make_absolute(filePath);
- llvm::sys::path::remove_dots(filePath);
- return mlir::FileLineColLoc::get(&getMLIRContext(), filePath.str(),
- filePos->line, filePos->column);
- }
- }
+/// Lowering of CALL statement
+void FirConverter::genFIR(const Fortran::parser::CallStmt &stmt) {
+ Fortran::lower::StatementContext stmtCtx;
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ setCurrentPosition(stmt.source);
+ assert(stmt.typedCall && "Call was not analyzed");
+ mlir::Value res{};
+ if (lowerToHighLevelFIR()) {
+ std::optional<mlir::Type> resultType;
+ if (stmt.typedCall->hasAlternateReturns())
+ resultType = builder->getIndexType();
+ auto hlfirRes =
+ Fortran::lower::convertCallToHLFIR(toLocation(), *this, *stmt.typedCall,
+ resultType, localSymbols, stmtCtx);
+ if (hlfirRes)
+ res = *hlfirRes;
+ } else {
+ // Call statement lowering shares code with function call lowering.
+ res = Fortran::lower::createSubroutineCall(
+ *this, *stmt.typedCall, explicitIterSpace, implicitIterSpace,
+ localSymbols, stmtCtx, /*isUserDefAssignment=*/false);
+ }
+ stmtCtx.finalizeAndReset();
+ if (!res)
+ return; // "Normal" subroutine call.
+ // Call with alternate return specifiers.
+ // The call returns an index that selects an alternate return branch target.
+ llvm::SmallVector<int64_t> indexList;
+ llvm::SmallVector<Fortran::parser::Label> labelList;
+ int64_t index = 0;
+ for (const Fortran::parser::ActualArgSpec &arg :
+ std::get<std::list<Fortran::parser::ActualArgSpec>>(stmt.call.t)) {
+ const auto &actual = std::get<Fortran::parser::ActualArg>(arg.t);
+ if (const auto *altReturn =
+ std::get_if<Fortran::parser::AltReturnSpec>(&actual.u)) {
+ indexList.push_back(++index);
+ labelList.push_back(altReturn->v);
}
- return genUnknownLocation();
- }
-
- const Fortran::semantics::Scope &getCurrentScope() override final {
- return bridge.getSemanticsContext().FindScope(currentPosition);
}
+ genMultiwayBranch(res, indexList, labelList, eval.nonNopSuccessor());
+}
- fir::FirOpBuilder &getFirOpBuilder() override final { return *builder; }
-
- mlir::ModuleOp &getModuleOp() override final { return bridge.getModule(); }
+void FirConverter::genFIR(const Fortran::parser::ComputedGotoStmt &stmt) {
+ Fortran::lower::StatementContext stmtCtx;
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ mlir::Value selectExpr =
+ createFIRExpr(toLocation(),
+ Fortran::semantics::GetExpr(
+ std::get<Fortran::parser::ScalarIntExpr>(stmt.t)),
+ stmtCtx);
+ stmtCtx.finalizeAndReset();
+ llvm::SmallVector<int64_t> indexList;
+ llvm::SmallVector<Fortran::parser::Label> labelList;
+ int64_t index = 0;
+ for (Fortran::parser::Label label :
+ std::get<std::list<Fortran::parser::Label>>(stmt.t)) {
+ indexList.push_back(++index);
+ labelList.push_back(label);
+ }
+ genMultiwayBranch(selectExpr, indexList, labelList, eval.nonNopSuccessor());
+}
- mlir::MLIRContext &getMLIRContext() override final {
- return bridge.getMLIRContext();
- }
- std::string
- mangleName(const Fortran::semantics::Symbol &symbol) override final {
- return Fortran::lower::mangle::mangleName(
- symbol, scopeBlockIdMap, /*keepExternalInScope=*/false,
- getLoweringOptions().getUnderscoring());
- }
- std::string mangleName(
- const Fortran::semantics::DerivedTypeSpec &derivedType) override final {
- return Fortran::lower::mangle::mangleName(derivedType, scopeBlockIdMap);
- }
- std::string mangleName(std::string &name) override final {
- return Fortran::lower::mangle::mangleName(name, getCurrentScope(),
- scopeBlockIdMap);
- }
- std::string getRecordTypeFieldName(
- const Fortran::semantics::Symbol &component) override final {
- return Fortran::lower::mangle::getRecordTypeFieldName(component,
- scopeBlockIdMap);
- }
- const fir::KindMapping &getKindMap() override final {
- return bridge.getKindMap();
- }
+void FirConverter::genFIR(const Fortran::parser::ArithmeticIfStmt &stmt) {
+ Fortran::lower::StatementContext stmtCtx;
+ mlir::Value expr = createFIRExpr(
+ toLocation(),
+ Fortran::semantics::GetExpr(std::get<Fortran::parser::Expr>(stmt.t)),
+ stmtCtx);
+ stmtCtx.finalizeAndReset();
+ // Raise an exception if REAL expr is a NaN.
+ if (expr.getType().isa<mlir::FloatType>())
+ expr = builder->create<mlir::arith::AddFOp>(toLocation(), expr, expr);
+ // An empty valueList indicates to genMultiwayBranch that the branch is
+ // an ArithmeticIfStmt that has two branches on value 0 or 0.0.
+ llvm::SmallVector<int64_t> valueList;
+ llvm::SmallVector<Fortran::parser::Label> labelList;
+ labelList.push_back(std::get<1>(stmt.t));
+ labelList.push_back(std::get<3>(stmt.t));
+ const Fortran::lower::pft::LabelEvalMap &labelEvaluationMap =
+ getEval().getOwningProcedure()->labelEvaluationMap;
+ const auto iter = labelEvaluationMap.find(std::get<2>(stmt.t));
+ assert(iter != labelEvaluationMap.end() && "label missing from map");
+ genMultiwayBranch(expr, valueList, labelList, *iter->second);
+}
- /// Return the current function context, which may be a nested BLOCK context
- /// or a full subprogram context.
- Fortran::lower::StatementContext &getFctCtx() override final {
- if (!activeConstructStack.empty() &&
- activeConstructStack.back().eval.isA<Fortran::parser::BlockConstruct>())
- return activeConstructStack.back().stmtCtx;
- return bridge.fctCtx();
+void FirConverter::genFIR(const Fortran::parser::AssignedGotoStmt &stmt) {
+ // See Fortran 90 Clause 8.2.4.
+ // Relax the requirement that the GOTO variable must have a value in the
+ // label list when a list is present, and allow a branch to any non-format
+ // target that has an ASSIGN statement for the variable.
+ mlir::Location loc = toLocation();
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ Fortran::lower::pft::FunctionLikeUnit &owningProc =
+ *eval.getOwningProcedure();
+ const Fortran::lower::pft::SymbolLabelMap &symbolLabelMap =
+ owningProc.assignSymbolLabelMap;
+ const Fortran::lower::pft::LabelEvalMap &labelEvalMap =
+ owningProc.labelEvaluationMap;
+ const Fortran::semantics::Symbol &symbol =
+ *std::get<Fortran::parser::Name>(stmt.t).symbol;
+ auto labelSetIter = symbolLabelMap.find(symbol);
+ llvm::SmallVector<int64_t> valueList;
+ llvm::SmallVector<Fortran::parser::Label> labelList;
+ if (labelSetIter != symbolLabelMap.end()) {
+ for (auto &label : labelSetIter->second) {
+ const auto evalIter = labelEvalMap.find(label);
+ assert(evalIter != labelEvalMap.end() && "assigned goto label missing");
+ if (evalIter->second->block) { // non-format statement
+ valueList.push_back(label); // label as an integer
+ labelList.push_back(label);
+ }
+ }
}
+ if (!labelList.empty()) {
+ auto selectExpr =
+ builder->create<fir::LoadOp>(loc, getSymbolAddress(symbol));
+ // Add a default error target in case the goto is nonconforming.
+ mlir::Block *errorBlock =
+ builder->getBlock()->splitBlock(builder->getInsertionPoint());
+ genMultiwayBranch(selectExpr, valueList, labelList, eval.nonNopSuccessor(),
+ errorBlock);
+ startBlock(errorBlock);
+ }
+ fir::runtime::genReportFatalUserError(
+ *builder, loc,
+ "Assigned GOTO variable '" + symbol.name().ToString() +
+ "' does not have a valid target label value");
+ builder->create<fir::UnreachableOp>(loc);
+}
- mlir::Value hostAssocTupleValue() override final { return hostAssocTuple; }
+/// Collect DO CONCURRENT or FORALL loop control information.
+FirConverter::IncrementLoopNestInfo FirConverter::getConcurrentControl(
+ const Fortran::parser::ConcurrentHeader &header,
+ const std::list<Fortran::parser::LocalitySpec> &localityList) {
+ IncrementLoopNestInfo incrementLoopNestInfo;
+ for (const Fortran::parser::ConcurrentControl &control :
+ std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t))
+ incrementLoopNestInfo.emplace_back(
+ *std::get<0>(control.t).symbol, std::get<1>(control.t),
+ std::get<2>(control.t), std::get<3>(control.t), /*isUnordered=*/true);
+ IncrementLoopInfo &info = incrementLoopNestInfo.back();
+ info.maskExpr = Fortran::semantics::GetExpr(
+ std::get<std::optional<Fortran::parser::ScalarLogicalExpr>>(header.t));
+ for (const Fortran::parser::LocalitySpec &x : localityList) {
+ if (const auto *localList =
+ std::get_if<Fortran::parser::LocalitySpec::Local>(&x.u))
+ for (const Fortran::parser::Name &x : localList->v)
+ info.localSymList.push_back(x.symbol);
+ if (const auto *localInitList =
+ std::get_if<Fortran::parser::LocalitySpec::LocalInit>(&x.u))
+ for (const Fortran::parser::Name &x : localInitList->v)
+ info.localInitSymList.push_back(x.symbol);
+ if (const auto *sharedList =
+ std::get_if<Fortran::parser::LocalitySpec::Shared>(&x.u))
+ for (const Fortran::parser::Name &x : sharedList->v)
+ info.sharedSymList.push_back(x.symbol);
+ }
+ return incrementLoopNestInfo;
+}
- /// Record a binding for the ssa-value of the tuple for this function.
- void bindHostAssocTuple(mlir::Value val) override final {
- assert(!hostAssocTuple && val);
- hostAssocTuple = val;
+/// Create DO CONCURRENT construct symbol bindings and generate LOCAL_INIT
+/// assignments.
+void FirConverter::handleLocalitySpecs(const IncrementLoopInfo &info) {
+ Fortran::semantics::SemanticsContext &semanticsContext =
+ bridge.getSemanticsContext();
+ for (const Fortran::semantics::Symbol *sym : info.localSymList)
+ createHostAssociateVarClone(*sym);
+ for (const Fortran::semantics::Symbol *sym : info.localInitSymList) {
+ createHostAssociateVarClone(*sym);
+ const auto *hostDetails =
+ sym->detailsIf<Fortran::semantics::HostAssocDetails>();
+ assert(hostDetails && "missing locality spec host symbol");
+ const Fortran::semantics::Symbol *hostSym = &hostDetails->symbol();
+ Fortran::evaluate::ExpressionAnalyzer ea{semanticsContext};
+ Fortran::evaluate::Assignment assign{
+ ea.Designate(Fortran::evaluate::DataRef{*sym}).value(),
+ ea.Designate(Fortran::evaluate::DataRef{*hostSym}).value()};
+ if (Fortran::semantics::IsPointer(*sym))
+ assign.u = Fortran::evaluate::Assignment::BoundsSpec{};
+ genAssignment(assign);
+ }
+ for (const Fortran::semantics::Symbol *sym : info.sharedSymList) {
+ const auto *hostDetails =
+ sym->detailsIf<Fortran::semantics::HostAssocDetails>();
+ copySymbolBinding(hostDetails->symbol(), *sym);
}
+}
- void registerTypeInfo(mlir::Location loc,
- Fortran::lower::SymbolRef typeInfoSym,
- const Fortran::semantics::DerivedTypeSpec &typeSpec,
- fir::RecordType type) override final {
- typeInfoConverter.registerTypeInfo(*this, loc, typeInfoSym, typeSpec, type);
+/// Generate FIR for a DO construct. There are six variants:
+/// - unstructured infinite and while loops
+/// - structured and unstructured increment loops
+/// - structured and unstructured concurrent loops
+void FirConverter::genFIR(const Fortran::parser::DoConstruct &doConstruct) {
+ setCurrentPositionAt(doConstruct);
+ // Collect loop nest information.
+ // Generate begin loop code directly for infinite and while loops.
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ bool unstructuredContext = eval.lowerAsUnstructured();
+ Fortran::lower::pft::Evaluation &doStmtEval = eval.getFirstNestedEvaluation();
+ auto *doStmt = doStmtEval.getIf<Fortran::parser::NonLabelDoStmt>();
+ const auto &loopControl =
+ std::get<std::optional<Fortran::parser::LoopControl>>(doStmt->t);
+ mlir::Block *preheaderBlock = doStmtEval.block;
+ mlir::Block *beginBlock =
+ preheaderBlock ? preheaderBlock : builder->getBlock();
+ auto createNextBeginBlock = [&]() {
+ // Step beginBlock through unstructured preheader, header, and mask
+ // blocks, created in outermost to innermost order.
+ return beginBlock = beginBlock->splitBlock(beginBlock->end());
+ };
+ mlir::Block *headerBlock =
+ unstructuredContext ? createNextBeginBlock() : nullptr;
+ mlir::Block *bodyBlock = doStmtEval.lexicalSuccessor->block;
+ mlir::Block *exitBlock = doStmtEval.parentConstruct->constructExit->block;
+ IncrementLoopNestInfo incrementLoopNestInfo;
+ const Fortran::parser::ScalarLogicalExpr *whileCondition = nullptr;
+ bool infiniteLoop = !loopControl.has_value();
+ if (infiniteLoop) {
+ assert(unstructuredContext && "infinite loop must be unstructured");
+ startBlock(headerBlock);
+ } else if ((whileCondition = std::get_if<Fortran::parser::ScalarLogicalExpr>(
+ &loopControl->u))) {
+ assert(unstructuredContext && "while loop must be unstructured");
+ maybeStartBlock(preheaderBlock); // no block or empty block
+ startBlock(headerBlock);
+ genConditionalBranch(*whileCondition, bodyBlock, exitBlock);
+ } else if (const auto *bounds =
+ std::get_if<Fortran::parser::LoopControl::Bounds>(
+ &loopControl->u)) {
+ // Non-concurrent increment loop.
+ IncrementLoopInfo &info = incrementLoopNestInfo.emplace_back(
+ *bounds->name.thing.symbol, bounds->lower, bounds->upper, bounds->step);
+ if (unstructuredContext) {
+ maybeStartBlock(preheaderBlock);
+ info.hasRealControl = info.loopVariableSym->GetType()->IsNumeric(
+ Fortran::common::TypeCategory::Real);
+ info.headerBlock = headerBlock;
+ info.bodyBlock = bodyBlock;
+ info.exitBlock = exitBlock;
+ }
+ } else {
+ const auto *concurrent =
+ std::get_if<Fortran::parser::LoopControl::Concurrent>(&loopControl->u);
+ assert(concurrent && "invalid DO loop variant");
+ incrementLoopNestInfo = getConcurrentControl(
+ std::get<Fortran::parser::ConcurrentHeader>(concurrent->t),
+ std::get<std::list<Fortran::parser::LocalitySpec>>(concurrent->t));
+ if (unstructuredContext) {
+ maybeStartBlock(preheaderBlock);
+ for (IncrementLoopInfo &info : incrementLoopNestInfo) {
+ // The original loop body provides the body and latch blocks of the
+ // innermost dimension. The (first) body block of a non-innermost
+ // dimension is the preheader block of the immediately enclosed
+ // dimension. The latch block of a non-innermost dimension is the
+ // exit block of the immediately enclosed dimension.
+ auto createNextExitBlock = [&]() {
+ // Create unstructured loop exit blocks, outermost to innermost.
+ return exitBlock = insertBlock(exitBlock);
+ };
+ bool isInnermost = &info == &incrementLoopNestInfo.back();
+ bool isOutermost = &info == &incrementLoopNestInfo.front();
+ info.headerBlock = isOutermost ? headerBlock : createNextBeginBlock();
+ info.bodyBlock = isInnermost ? bodyBlock : createNextBeginBlock();
+ info.exitBlock = isOutermost ? exitBlock : createNextExitBlock();
+ if (info.maskExpr)
+ info.maskBlock = createNextBeginBlock();
+ }
+ }
}
- llvm::StringRef
- getUniqueLitName(mlir::Location loc,
- std::unique_ptr<Fortran::lower::SomeExpr> expr,
- mlir::Type eleTy) override final {
- std::string namePrefix =
- getConstantExprManglePrefix(loc, *expr.get(), eleTy);
- auto [it, inserted] = literalNamesMap.try_emplace(
- expr.get(), namePrefix + std::to_string(uniqueLitId));
- const auto &name = it->second;
- if (inserted) {
- // Keep ownership of the expr key.
- literalExprsStorage.push_back(std::move(expr));
-
- // If we've just added a new name, we have to make sure
- // there is no global object with the same name in the module.
- fir::GlobalOp global = builder->getNamedGlobal(name);
- if (global)
- fir::emitFatalError(loc, llvm::Twine("global object with name '") +
- llvm::Twine(name) +
- llvm::Twine("' already exists"));
- ++uniqueLitId;
- return name;
- }
+ // Increment loop begin code. (Infinite/while code was already generated.)
+ if (!infiniteLoop && !whileCondition)
+ genFIRIncrementLoopBegin(incrementLoopNestInfo);
- // The name already exists. Verify that the prefix is the same.
- if (!llvm::StringRef(name).starts_with(namePrefix))
- fir::emitFatalError(loc, llvm::Twine("conflicting prefixes: '") +
- llvm::Twine(name) +
- llvm::Twine("' does not start with '") +
- llvm::Twine(namePrefix) + llvm::Twine("'"));
+ // Loop body code.
+ auto iter = eval.getNestedEvaluations().begin();
+ for (auto end = --eval.getNestedEvaluations().end(); iter != end; ++iter)
+ genFIR(*iter, unstructuredContext);
- return name;
- }
+ // An EndDoStmt in unstructured code may start a new block.
+ Fortran::lower::pft::Evaluation &endDoEval = *iter;
+ assert(endDoEval.getIf<Fortran::parser::EndDoStmt>() && "no enddo stmt");
+ if (unstructuredContext)
+ maybeStartBlock(endDoEval.block);
-private:
- FirConverter() = delete;
- FirConverter(const FirConverter &) = delete;
- FirConverter &operator=(const FirConverter &) = delete;
+ // Loop end code.
+ if (infiniteLoop || whileCondition)
+ genBranch(headerBlock);
+ else
+ genFIRIncrementLoopEnd(incrementLoopNestInfo);
- //===--------------------------------------------------------------------===//
- // Helper member functions
- //===--------------------------------------------------------------------===//
+ // This call may generate a branch in some contexts.
+ genFIR(endDoEval, unstructuredContext);
+}
- mlir::Value createFIRExpr(mlir::Location loc,
- const Fortran::lower::SomeExpr *expr,
- Fortran::lower::StatementContext &stmtCtx) {
- return fir::getBase(genExprValue(*expr, stmtCtx, &loc));
+/// Generate FIR to evaluate loop control values (lower, upper and step).
+mlir::Value FirConverter::genControlValue(const Fortran::lower::SomeExpr *expr,
+ const IncrementLoopInfo &info,
+ bool *isConst) {
+ mlir::Location loc = toLocation();
+ mlir::Type controlType = info.isStructured() ? builder->getIndexType()
+ : info.getLoopVariableType();
+ Fortran::lower::StatementContext stmtCtx;
+ if (expr) {
+ if (isConst)
+ *isConst = Fortran::evaluate::IsConstantExpr(*expr);
+ return builder->createConvert(loc, controlType,
+ createFIRExpr(loc, expr, stmtCtx));
}
- /// Find the symbol in the local map or return null.
- Fortran::lower::SymbolBox
- lookupSymbol(const Fortran::semantics::Symbol &sym,
- Fortran::lower::SymMap *symMap = nullptr) {
- symMap = symMap ? symMap : &localSymbols;
- if (lowerToHighLevelFIR()) {
- if (std::optional<fir::FortranVariableOpInterface> var =
- symMap->lookupVariableDefinition(sym)) {
- auto exv =
- hlfir::translateToExtendedValue(toLocation(), *builder, *var);
- return exv.match(
- [](mlir::Value x) -> Fortran::lower::SymbolBox {
- return Fortran::lower::SymbolBox::Intrinsic{x};
- },
- [](auto x) -> Fortran::lower::SymbolBox { return x; });
- }
+ if (isConst)
+ *isConst = true;
+ if (info.hasRealControl)
+ return builder->createRealConstant(loc, controlType, 1u);
+ return builder->createIntegerConstant(loc, controlType, 1); // step
+}
- // Entry character result represented as an argument pair
- // needs to be represented in the symbol table even before
- // we can create DeclareOp for it. The temporary mapping
- // is EmboxCharOp that conveys the address and length information.
- // After mapSymbolAttributes is done, the mapping is replaced
- // with the new DeclareOp, and the following table lookups
- // do not reach here.
- if (sym.IsFuncResult())
- if (const Fortran::semantics::DeclTypeSpec *declTy = sym.GetType())
- if (declTy->category() ==
- Fortran::semantics::DeclTypeSpec::Category::Character)
- return symMap->lookupSymbol(sym);
-
- // Procedure dummies are not mapped with an hlfir.declare because
- // they are not "variable" (cannot be assigned to), and it would
- // make hlfir.declare more complex than it needs to to allow this.
- // Do a regular lookup.
- if (Fortran::semantics::IsProcedure(sym))
- return symMap->lookupSymbol(sym);
-
- // Commonblock names are not variables, but in some lowerings (like
- // OpenMP) it is useful to maintain the address of the commonblock in an
- // MLIR value and query it. hlfir.declare need not be created for these.
- if (sym.detailsIf<Fortran::semantics::CommonBlockDetails>())
- return symMap->lookupSymbol(sym);
-
- return {};
+/// Generate FIR to begin a structured or unstructured increment loop nest.
+void FirConverter::genFIRIncrementLoopBegin(
+ IncrementLoopNestInfo &incrementLoopNestInfo) {
+ assert(!incrementLoopNestInfo.empty() && "empty loop nest");
+ mlir::Location loc = toLocation();
+ for (IncrementLoopInfo &info : incrementLoopNestInfo) {
+ info.loopVariable =
+ genLoopVariableAddress(loc, *info.loopVariableSym, info.isUnordered);
+ mlir::Value lowerValue = genControlValue(info.lowerExpr, info);
+ mlir::Value upperValue = genControlValue(info.upperExpr, info);
+ bool isConst = true;
+ mlir::Value stepValue = genControlValue(
+ info.stepExpr, info, info.isStructured() ? nullptr : &isConst);
+ // Use a temp variable for unstructured loops with non-const step.
+ if (!isConst) {
+ info.stepVariable = builder->createTemporary(loc, stepValue.getType());
+ builder->create<fir::StoreOp>(loc, stepValue, info.stepVariable);
}
- if (Fortran::lower::SymbolBox v = symMap->lookupSymbol(sym))
- return v;
- return {};
- }
-
- /// Find the symbol in the inner-most level of the local map or return null.
- Fortran::lower::SymbolBox
- shallowLookupSymbol(const Fortran::semantics::Symbol &sym) {
- if (Fortran::lower::SymbolBox v = localSymbols.shallowLookupSymbol(sym))
- return v;
- return {};
- }
- /// Find the symbol in one level up of symbol map such as for host-association
- /// in OpenMP code or return null.
- Fortran::lower::SymbolBox
- lookupOneLevelUpSymbol(const Fortran::semantics::Symbol &sym) {
- if (Fortran::lower::SymbolBox v = localSymbols.lookupOneLevelUpSymbol(sym))
- return v;
- return {};
- }
-
- /// Add the symbol to the local map and return `true`. If the symbol is
- /// already in the map and \p forced is `false`, the map is not updated.
- /// Instead the value `false` is returned.
- bool addSymbol(const Fortran::semantics::SymbolRef sym,
- fir::ExtendedValue val, bool forced = false) {
- if (!forced && lookupSymbol(sym))
- return false;
- if (lowerToHighLevelFIR()) {
- Fortran::lower::genDeclareSymbol(*this, localSymbols, sym, val,
- fir::FortranVariableFlagsEnum::None,
- forced);
- } else {
- localSymbols.addSymbol(sym, val, forced);
- }
- return true;
- }
-
- /// Map a block argument to a result or dummy symbol. This is not the
- /// definitive mapping. The specification expression have not been lowered
- /// yet. The final mapping will be done using this pre-mapping in
- /// Fortran::lower::mapSymbolAttributes.
- bool mapBlockArgToDummyOrResult(const Fortran::semantics::SymbolRef sym,
- mlir::Value val, bool forced = false) {
- if (!forced && lookupSymbol(sym))
- return false;
- localSymbols.addSymbol(sym, val, forced);
- return true;
- }
-
- /// Generate the address of loop variable \p sym.
- /// If \p sym is not mapped yet, allocate local storage for it.
- mlir::Value genLoopVariableAddress(mlir::Location loc,
- const Fortran::semantics::Symbol &sym,
- bool isUnordered) {
- if (isUnordered || sym.has<Fortran::semantics::HostAssocDetails>() ||
- sym.has<Fortran::semantics::UseDetails>()) {
- if (!shallowLookupSymbol(sym)) {
- // Do concurrent loop variables are not mapped yet since they are local
- // to the Do concurrent scope (same for OpenMP loops).
- mlir::OpBuilder::InsertPoint insPt = builder->saveInsertionPoint();
- builder->setInsertionPointToStart(builder->getAllocaBlock());
- mlir::Type tempTy = genType(sym);
- mlir::Value temp =
- builder->createTemporaryAlloc(loc, tempTy, toStringRef(sym.name()));
- bindIfNewSymbol(sym, temp);
- builder->restoreInsertionPoint(insPt);
- }
- }
- auto entry = lookupSymbol(sym);
- (void)entry;
- assert(entry && "loop control variable must already be in map");
- Fortran::lower::StatementContext stmtCtx;
- return fir::getBase(
- genExprAddr(Fortran::evaluate::AsGenericExpr(sym).value(), stmtCtx));
- }
-
- static bool isNumericScalarCategory(Fortran::common::TypeCategory cat) {
- return cat == Fortran::common::TypeCategory::Integer ||
- cat == Fortran::common::TypeCategory::Real ||
- cat == Fortran::common::TypeCategory::Complex ||
- cat == Fortran::common::TypeCategory::Logical;
- }
- static bool isLogicalCategory(Fortran::common::TypeCategory cat) {
- return cat == Fortran::common::TypeCategory::Logical;
- }
- static bool isCharacterCategory(Fortran::common::TypeCategory cat) {
- return cat == Fortran::common::TypeCategory::Character;
- }
- static bool isDerivedCategory(Fortran::common::TypeCategory cat) {
- return cat == Fortran::common::TypeCategory::Derived;
- }
-
- /// Insert a new block before \p block. Leave the insertion point unchanged.
- mlir::Block *insertBlock(mlir::Block *block) {
- mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
- mlir::Block *newBlock = builder->createBlock(block);
- builder->restoreInsertionPoint(insertPt);
- return newBlock;
- }
-
- Fortran::lower::pft::Evaluation &evalOfLabel(Fortran::parser::Label label) {
- const Fortran::lower::pft::LabelEvalMap &labelEvaluationMap =
- getEval().getOwningProcedure()->labelEvaluationMap;
- const auto iter = labelEvaluationMap.find(label);
- assert(iter != labelEvaluationMap.end() && "label missing from map");
- return *iter->second;
- }
-
- void genBranch(mlir::Block *targetBlock) {
- assert(targetBlock && "missing unconditional target block");
- builder->create<mlir::cf::BranchOp>(toLocation(), targetBlock);
- }
-
- void genConditionalBranch(mlir::Value cond, mlir::Block *trueTarget,
- mlir::Block *falseTarget) {
- assert(trueTarget && "missing conditional branch true block");
- assert(falseTarget && "missing conditional branch false block");
- mlir::Location loc = toLocation();
- mlir::Value bcc = builder->createConvert(loc, builder->getI1Type(), cond);
- builder->create<mlir::cf::CondBranchOp>(loc, bcc, trueTarget, std::nullopt,
- falseTarget, std::nullopt);
- }
- void genConditionalBranch(mlir::Value cond,
- Fortran::lower::pft::Evaluation *trueTarget,
- Fortran::lower::pft::Evaluation *falseTarget) {
- genConditionalBranch(cond, trueTarget->block, falseTarget->block);
- }
- void genConditionalBranch(const Fortran::parser::ScalarLogicalExpr &expr,
- mlir::Block *trueTarget, mlir::Block *falseTarget) {
- Fortran::lower::StatementContext stmtCtx;
- mlir::Value cond =
- createFIRExpr(toLocation(), Fortran::semantics::GetExpr(expr), stmtCtx);
- stmtCtx.finalizeAndReset();
- genConditionalBranch(cond, trueTarget, falseTarget);
- }
- void genConditionalBranch(const Fortran::parser::ScalarLogicalExpr &expr,
- Fortran::lower::pft::Evaluation *trueTarget,
- Fortran::lower::pft::Evaluation *falseTarget) {
- Fortran::lower::StatementContext stmtCtx;
- mlir::Value cond =
- createFIRExpr(toLocation(), Fortran::semantics::GetExpr(expr), stmtCtx);
- stmtCtx.finalizeAndReset();
- genConditionalBranch(cond, trueTarget->block, falseTarget->block);
- }
-
- /// Return the nearest active ancestor construct of \p eval, or nullptr.
- Fortran::lower::pft::Evaluation *
- getActiveAncestor(const Fortran::lower::pft::Evaluation &eval) {
- Fortran::lower::pft::Evaluation *ancestor = eval.parentConstruct;
- for (; ancestor; ancestor = ancestor->parentConstruct)
- if (ancestor->activeConstruct)
- break;
- return ancestor;
- }
-
- /// Return the predicate: "a branch to \p targetEval has exit code".
- bool hasExitCode(const Fortran::lower::pft::Evaluation &targetEval) {
- Fortran::lower::pft::Evaluation *activeAncestor =
- getActiveAncestor(targetEval);
- for (auto it = activeConstructStack.rbegin(),
- rend = activeConstructStack.rend();
- it != rend; ++it) {
- if (&it->eval == activeAncestor)
- break;
- if (it->stmtCtx.hasCode())
- return true;
- }
- return false;
- }
-
- /// Generate a branch to \p targetEval after generating on-exit code for
- /// any enclosing construct scopes that are exited by taking the branch.
- void
- genConstructExitBranch(const Fortran::lower::pft::Evaluation &targetEval) {
- Fortran::lower::pft::Evaluation *activeAncestor =
- getActiveAncestor(targetEval);
- for (auto it = activeConstructStack.rbegin(),
- rend = activeConstructStack.rend();
- it != rend; ++it) {
- if (&it->eval == activeAncestor)
- break;
- it->stmtCtx.finalizeAndKeep();
- }
- genBranch(targetEval.block);
- }
-
- /// Generate a SelectOp or branch sequence that compares \p selector against
- /// values in \p valueList and targets corresponding labels in \p labelList.
- /// If no value matches the selector, branch to \p defaultEval.
- ///
- /// Three cases require special processing.
- ///
- /// An empty \p valueList indicates an ArithmeticIfStmt context that requires
- /// two comparisons against 0 or 0.0. The selector may have either INTEGER
- /// or REAL type.
- ///
- /// A nonpositive \p valuelist value indicates an IO statement context
- /// (0 for ERR, -1 for END, -2 for EOR). An ERR branch must be taken for
- /// any positive (IOSTAT) value. A missing (zero) label requires a branch
- /// to \p defaultEval for that value.
- ///
- /// A non-null \p errorBlock indicates an AssignedGotoStmt context that
- /// must always branch to an explicit target. There is no valid defaultEval
- /// in this case. Generate a branch to \p errorBlock for an AssignedGotoStmt
- /// that violates this program requirement.
- ///
- /// If this is not an ArithmeticIfStmt and no targets have exit code,
- /// generate a SelectOp. Otherwise, for each target, if it has exit code,
- /// branch to a new block, insert exit code, and then branch to the target.
- /// Otherwise, branch directly to the target.
- void genMultiwayBranch(mlir::Value selector,
- llvm::SmallVector<int64_t> valueList,
- llvm::SmallVector<Fortran::parser::Label> labelList,
- const Fortran::lower::pft::Evaluation &defaultEval,
- mlir::Block *errorBlock = nullptr) {
- bool inArithmeticIfContext = valueList.empty();
- assert(((inArithmeticIfContext && labelList.size() == 2) ||
- (valueList.size() && labelList.size() == valueList.size())) &&
- "mismatched multiway branch targets");
- mlir::Block *defaultBlock = errorBlock ? errorBlock : defaultEval.block;
- bool defaultHasExitCode = !errorBlock && hasExitCode(defaultEval);
- bool hasAnyExitCode = defaultHasExitCode;
- if (!hasAnyExitCode)
- for (auto label : labelList)
- if (label && hasExitCode(evalOfLabel(label))) {
- hasAnyExitCode = true;
- break;
- }
- mlir::Location loc = toLocation();
- size_t branchCount = labelList.size();
- if (!inArithmeticIfContext && !hasAnyExitCode &&
- !getEval().forceAsUnstructured()) { // from -no-structured-fir option
- // Generate a SelectOp.
- llvm::SmallVector<mlir::Block *> blockList;
- for (auto label : labelList) {
- mlir::Block *block =
- label ? evalOfLabel(label).block : defaultEval.block;
- assert(block && "missing multiway branch block");
- blockList.push_back(block);
- }
- blockList.push_back(defaultBlock);
- if (valueList[branchCount - 1] == 0) // Swap IO ERR and default blocks.
- std::swap(blockList[branchCount - 1], blockList[branchCount]);
- builder->create<fir::SelectOp>(loc, selector, valueList, blockList);
- return;
- }
- mlir::Type selectorType = selector.getType();
- bool realSelector = selectorType.isa<mlir::FloatType>();
- assert((inArithmeticIfContext || !realSelector) && "invalid selector type");
- mlir::Value zero;
- if (inArithmeticIfContext)
- zero =
- realSelector
- ? builder->create<mlir::arith::ConstantOp>(
- loc, selectorType, builder->getFloatAttr(selectorType, 0.0))
- : builder->createIntegerConstant(loc, selectorType, 0);
- for (auto label : llvm::enumerate(labelList)) {
- mlir::Value cond;
- if (realSelector) // inArithmeticIfContext
- cond = builder->create<mlir::arith::CmpFOp>(
- loc,
- label.index() == 0 ? mlir::arith::CmpFPredicate::OLT
- : mlir::arith::CmpFPredicate::OGT,
- selector, zero);
- else if (inArithmeticIfContext) // INTEGER selector
- cond = builder->create<mlir::arith::CmpIOp>(
- loc,
- label.index() == 0 ? mlir::arith::CmpIPredicate::slt
- : mlir::arith::CmpIPredicate::sgt,
- selector, zero);
- else // A value of 0 is an IO ERR branch: invert comparison.
- cond = builder->create<mlir::arith::CmpIOp>(
- loc,
- valueList[label.index()] == 0 ? mlir::arith::CmpIPredicate::ne
- : mlir::arith::CmpIPredicate::eq,
- selector,
- builder->createIntegerConstant(loc, selectorType,
- valueList[label.index()]));
- // Branch to a new block with exit code and then to the target, or branch
- // directly to the target. defaultBlock is the "else" target.
- bool lastBranch = label.index() == branchCount - 1;
- mlir::Block *nextBlock =
- lastBranch && !defaultHasExitCode
- ? defaultBlock
- : builder->getBlock()->splitBlock(builder->getInsertionPoint());
- const Fortran::lower::pft::Evaluation &targetEval =
- label.value() ? evalOfLabel(label.value()) : defaultEval;
- if (hasExitCode(targetEval)) {
- mlir::Block *jumpBlock =
- builder->getBlock()->splitBlock(builder->getInsertionPoint());
- genConditionalBranch(cond, jumpBlock, nextBlock);
- startBlock(jumpBlock);
- genConstructExitBranch(targetEval);
+ // Structured loop - generate fir.do_loop.
+ if (info.isStructured()) {
+ mlir::Type loopVarType = info.getLoopVariableType();
+ mlir::Value loopValue;
+ if (info.isUnordered) {
+ // The loop variable value is explicitly updated.
+ info.doLoop = builder->create<fir::DoLoopOp>(
+ loc, lowerValue, upperValue, stepValue, /*unordered=*/true);
+ builder->setInsertionPointToStart(info.doLoop.getBody());
+ loopValue = builder->createConvert(loc, loopVarType,
+ info.doLoop.getInductionVar());
} else {
- genConditionalBranch(cond, targetEval.block, nextBlock);
+ // The loop variable is a doLoop op argument.
+ info.doLoop = builder->create<fir::DoLoopOp>(
+ loc, lowerValue, upperValue, stepValue, /*unordered=*/false,
+ /*finalCountValue=*/true,
+ builder->createConvert(loc, loopVarType, lowerValue));
+ builder->setInsertionPointToStart(info.doLoop.getBody());
+ loopValue = info.doLoop.getRegionIterArgs()[0];
}
- if (!lastBranch) {
- startBlock(nextBlock);
- } else if (defaultHasExitCode) {
- startBlock(nextBlock);
- genConstructExitBranch(defaultEval);
+ // Update the loop variable value in case it has non-index references.
+ builder->create<fir::StoreOp>(loc, loopValue, info.loopVariable);
+ if (info.maskExpr) {
+ Fortran::lower::StatementContext stmtCtx;
+ mlir::Value maskCond = createFIRExpr(loc, info.maskExpr, stmtCtx);
+ stmtCtx.finalizeAndReset();
+ mlir::Value maskCondCast =
+ builder->createConvert(loc, builder->getI1Type(), maskCond);
+ auto ifOp = builder->create<fir::IfOp>(loc, maskCondCast,
+ /*withElseRegion=*/false);
+ builder->setInsertionPointToStart(&ifOp.getThenRegion().front());
}
+ if (info.hasLocalitySpecs())
+ handleLocalitySpecs(info);
+ continue;
}
- }
-
- void pushActiveConstruct(Fortran::lower::pft::Evaluation &eval,
- Fortran::lower::StatementContext &stmtCtx) {
- activeConstructStack.push_back(ConstructContext{eval, stmtCtx});
- eval.activeConstruct = true;
- }
- void popActiveConstruct() {
- assert(!activeConstructStack.empty() && "invalid active construct stack");
- activeConstructStack.back().eval.activeConstruct = false;
- activeConstructStack.pop_back();
- }
-
- //===--------------------------------------------------------------------===//
- // Termination of symbolically referenced execution units
- //===--------------------------------------------------------------------===//
- /// END of program
- ///
- /// Generate the cleanup block before the program exits
- void genExitRoutine() {
-
- if (blockIsUnterminated())
- builder->create<mlir::func::ReturnOp>(toLocation());
- }
-
- /// END of procedure-like constructs
- ///
- /// Generate the cleanup block before the procedure exits
- void genReturnSymbol(const Fortran::semantics::Symbol &functionSymbol) {
- const Fortran::semantics::Symbol &resultSym =
- functionSymbol.get<Fortran::semantics::SubprogramDetails>().result();
- Fortran::lower::SymbolBox resultSymBox = lookupSymbol(resultSym);
- mlir::Location loc = toLocation();
- if (!resultSymBox) {
- mlir::emitError(loc, "internal error when processing function return");
- return;
- }
- mlir::Value resultVal = resultSymBox.match(
- [&](const fir::CharBoxValue &x) -> mlir::Value {
- if (Fortran::semantics::IsBindCProcedure(functionSymbol))
- return builder->create<fir::LoadOp>(loc, x.getBuffer());
- return fir::factory::CharacterExprHelper{*builder, loc}
- .createEmboxChar(x.getBuffer(), x.getLen());
- },
- [&](const fir::MutableBoxValue &x) -> mlir::Value {
- mlir::Value resultRef = resultSymBox.getAddr();
- mlir::Value load = builder->create<fir::LoadOp>(loc, resultRef);
- unsigned rank = x.rank();
- if (x.isAllocatable() && rank > 0) {
- // ALLOCATABLE array result must have default lower bounds.
- // At the call site the result box of a function reference
- // might be considered having default lower bounds, but
- // the runtime box should probably comply with this assumption
- // as well. If the result box has proper lbounds in runtime,
- // this may improve the debugging experience of Fortran apps.
- // We may consider removing this, if the overhead of setting
- // default lower bounds is too big.
- mlir::Value one =
- builder->createIntegerConstant(loc, builder->getIndexType(), 1);
- llvm::SmallVector<mlir::Value> lbounds{rank, one};
- auto shiftTy = fir::ShiftType::get(builder->getContext(), rank);
- mlir::Value shiftOp =
- builder->create<fir::ShiftOp>(loc, shiftTy, lbounds);
- load = builder->create<fir::ReboxOp>(
- loc, load.getType(), load, shiftOp, /*slice=*/mlir::Value{});
- }
- return load;
- },
- [&](const auto &) -> mlir::Value {
- mlir::Value resultRef = resultSymBox.getAddr();
- mlir::Type resultType = genType(resultSym);
- mlir::Type resultRefType = builder->getRefType(resultType);
- // A function with multiple entry points returning different types
- // tags all result variables with one of the largest types to allow
- // them to share the same storage. Convert this to the actual type.
- if (resultRef.getType() != resultRefType)
- resultRef = builder->createConvert(loc, resultRefType, resultRef);
- return builder->create<fir::LoadOp>(loc, resultRef);
- });
- bridge.openAccCtx().finalizeAndPop();
- bridge.fctCtx().finalizeAndPop();
- builder->create<mlir::func::ReturnOp>(loc, resultVal);
- }
-
- /// Get the return value of a call to \p symbol, which is a subroutine entry
- /// point that has alternative return specifiers.
- const mlir::Value
- getAltReturnResult(const Fortran::semantics::Symbol &symbol) {
- assert(Fortran::semantics::HasAlternateReturns(symbol) &&
- "subroutine does not have alternate returns");
- return getSymbolAddress(symbol);
- }
-
- void genFIRProcedureExit(Fortran::lower::pft::FunctionLikeUnit &funit,
- const Fortran::semantics::Symbol &symbol) {
- if (mlir::Block *finalBlock = funit.finalBlock) {
- // The current block must end with a terminator.
- if (blockIsUnterminated())
- builder->create<mlir::cf::BranchOp>(toLocation(), finalBlock);
- // Set insertion point to final block.
- builder->setInsertionPoint(finalBlock, finalBlock->end());
- }
- if (Fortran::semantics::IsFunction(symbol)) {
- genReturnSymbol(symbol);
- } else if (Fortran::semantics::HasAlternateReturns(symbol)) {
- mlir::Value retval = builder->create<fir::LoadOp>(
- toLocation(), getAltReturnResult(symbol));
- bridge.openAccCtx().finalizeAndPop();
- bridge.fctCtx().finalizeAndPop();
- builder->create<mlir::func::ReturnOp>(toLocation(), retval);
+ // Unstructured loop preheader - initialize tripVariable and loopVariable.
+ mlir::Value tripCount;
+ if (info.hasRealControl) {
+ auto diff1 =
+ builder->create<mlir::arith::SubFOp>(loc, upperValue, lowerValue);
+ auto diff2 = builder->create<mlir::arith::AddFOp>(loc, diff1, stepValue);
+ tripCount = builder->create<mlir::arith::DivFOp>(loc, diff2, stepValue);
+ tripCount =
+ builder->createConvert(loc, builder->getIndexType(), tripCount);
} else {
- bridge.openAccCtx().finalizeAndPop();
- bridge.fctCtx().finalizeAndPop();
- genExitRoutine();
+ auto diff1 =
+ builder->create<mlir::arith::SubIOp>(loc, upperValue, lowerValue);
+ auto diff2 = builder->create<mlir::arith::AddIOp>(loc, diff1, stepValue);
+ tripCount = builder->create<mlir::arith::DivSIOp>(loc, diff2, stepValue);
}
- }
-
- //
- // Statements that have control-flow semantics
- //
-
- /// Generate an If[Then]Stmt condition or its negation.
- template <typename A>
- mlir::Value genIfCondition(const A *stmt, bool negate = false) {
- mlir::Location loc = toLocation();
- Fortran::lower::StatementContext stmtCtx;
- mlir::Value condExpr = createFIRExpr(
- loc,
- Fortran::semantics::GetExpr(
- std::get<Fortran::parser::ScalarLogicalExpr>(stmt->t)),
- stmtCtx);
- stmtCtx.finalizeAndReset();
- mlir::Value cond =
- builder->createConvert(loc, builder->getI1Type(), condExpr);
- if (negate)
- cond = builder->create<mlir::arith::XOrIOp>(
- loc, cond, builder->createIntegerConstant(loc, cond.getType(), 1));
- return cond;
- }
-
- mlir::func::FuncOp getFunc(llvm::StringRef name, mlir::FunctionType ty) {
- if (mlir::func::FuncOp func = builder->getNamedFunction(name)) {
- assert(func.getFunctionType() == ty);
- return func;
+ if (forceLoopToExecuteOnce) { // minimum tripCount is 1
+ mlir::Value one =
+ builder->createIntegerConstant(loc, tripCount.getType(), 1);
+ auto cond = builder->create<mlir::arith::CmpIOp>(
+ loc, mlir::arith::CmpIPredicate::slt, tripCount, one);
+ tripCount =
+ builder->create<mlir::arith::SelectOp>(loc, cond, one, tripCount);
}
- return builder->createFunction(toLocation(), name, ty);
- }
-
- /// Lowering of CALL statement
- void genFIR(const Fortran::parser::CallStmt &stmt) {
- Fortran::lower::StatementContext stmtCtx;
- Fortran::lower::pft::Evaluation &eval = getEval();
- setCurrentPosition(stmt.source);
- assert(stmt.typedCall && "Call was not analyzed");
- mlir::Value res{};
- if (lowerToHighLevelFIR()) {
- std::optional<mlir::Type> resultType;
- if (stmt.typedCall->hasAlternateReturns())
- resultType = builder->getIndexType();
- auto hlfirRes = Fortran::lower::convertCallToHLFIR(
- toLocation(), *this, *stmt.typedCall, resultType, localSymbols,
- stmtCtx);
- if (hlfirRes)
- res = *hlfirRes;
+ info.tripVariable = builder->createTemporary(loc, tripCount.getType());
+ builder->create<fir::StoreOp>(loc, tripCount, info.tripVariable);
+ builder->create<fir::StoreOp>(loc, lowerValue, info.loopVariable);
+
+ // Unstructured loop header - generate loop condition and mask.
+ // Note - Currently there is no way to tag a loop as a concurrent loop.
+ startBlock(info.headerBlock);
+ tripCount = builder->create<fir::LoadOp>(loc, info.tripVariable);
+ mlir::Value zero =
+ builder->createIntegerConstant(loc, tripCount.getType(), 0);
+ auto cond = builder->create<mlir::arith::CmpIOp>(
+ loc, mlir::arith::CmpIPredicate::sgt, tripCount, zero);
+ if (info.maskExpr) {
+ genConditionalBranch(cond, info.maskBlock, info.exitBlock);
+ startBlock(info.maskBlock);
+ mlir::Block *latchBlock = getEval().getLastNestedEvaluation().block;
+ assert(latchBlock && "missing masked concurrent loop latch block");
+ Fortran::lower::StatementContext stmtCtx;
+ mlir::Value maskCond = createFIRExpr(loc, info.maskExpr, stmtCtx);
+ stmtCtx.finalizeAndReset();
+ genConditionalBranch(maskCond, info.bodyBlock, latchBlock);
} else {
- // Call statement lowering shares code with function call lowering.
- res = Fortran::lower::createSubroutineCall(
- *this, *stmt.typedCall, explicitIterSpace, implicitIterSpace,
- localSymbols, stmtCtx, /*isUserDefAssignment=*/false);
- }
- stmtCtx.finalizeAndReset();
- if (!res)
- return; // "Normal" subroutine call.
- // Call with alternate return specifiers.
- // The call returns an index that selects an alternate return branch target.
- llvm::SmallVector<int64_t> indexList;
- llvm::SmallVector<Fortran::parser::Label> labelList;
- int64_t index = 0;
- for (const Fortran::parser::ActualArgSpec &arg :
- std::get<std::list<Fortran::parser::ActualArgSpec>>(stmt.call.t)) {
- const auto &actual = std::get<Fortran::parser::ActualArg>(arg.t);
- if (const auto *altReturn =
- std::get_if<Fortran::parser::AltReturnSpec>(&actual.u)) {
- indexList.push_back(++index);
- labelList.push_back(altReturn->v);
- }
+ genConditionalBranch(cond, info.bodyBlock, info.exitBlock);
+ if (&info != &incrementLoopNestInfo.back()) // not innermost
+ startBlock(info.bodyBlock); // preheader block of enclosed dimension
}
- genMultiwayBranch(res, indexList, labelList, eval.nonNopSuccessor());
- }
-
- void genFIR(const Fortran::parser::ComputedGotoStmt &stmt) {
- Fortran::lower::StatementContext stmtCtx;
- Fortran::lower::pft::Evaluation &eval = getEval();
- mlir::Value selectExpr =
- createFIRExpr(toLocation(),
- Fortran::semantics::GetExpr(
- std::get<Fortran::parser::ScalarIntExpr>(stmt.t)),
- stmtCtx);
- stmtCtx.finalizeAndReset();
- llvm::SmallVector<int64_t> indexList;
- llvm::SmallVector<Fortran::parser::Label> labelList;
- int64_t index = 0;
- for (Fortran::parser::Label label :
- std::get<std::list<Fortran::parser::Label>>(stmt.t)) {
- indexList.push_back(++index);
- labelList.push_back(label);
- }
- genMultiwayBranch(selectExpr, indexList, labelList, eval.nonNopSuccessor());
- }
-
- void genFIR(const Fortran::parser::ArithmeticIfStmt &stmt) {
- Fortran::lower::StatementContext stmtCtx;
- mlir::Value expr = createFIRExpr(
- toLocation(),
- Fortran::semantics::GetExpr(std::get<Fortran::parser::Expr>(stmt.t)),
- stmtCtx);
- stmtCtx.finalizeAndReset();
- // Raise an exception if REAL expr is a NaN.
- if (expr.getType().isa<mlir::FloatType>())
- expr = builder->create<mlir::arith::AddFOp>(toLocation(), expr, expr);
- // An empty valueList indicates to genMultiwayBranch that the branch is
- // an ArithmeticIfStmt that has two branches on value 0 or 0.0.
- llvm::SmallVector<int64_t> valueList;
- llvm::SmallVector<Fortran::parser::Label> labelList;
- labelList.push_back(std::get<1>(stmt.t));
- labelList.push_back(std::get<3>(stmt.t));
- const Fortran::lower::pft::LabelEvalMap &labelEvaluationMap =
- getEval().getOwningProcedure()->labelEvaluationMap;
- const auto iter = labelEvaluationMap.find(std::get<2>(stmt.t));
- assert(iter != labelEvaluationMap.end() && "label missing from map");
- genMultiwayBranch(expr, valueList, labelList, *iter->second);
- }
-
- void genFIR(const Fortran::parser::AssignedGotoStmt &stmt) {
- // See Fortran 90 Clause 8.2.4.
- // Relax the requirement that the GOTO variable must have a value in the
- // label list when a list is present, and allow a branch to any non-format
- // target that has an ASSIGN statement for the variable.
- mlir::Location loc = toLocation();
- Fortran::lower::pft::Evaluation &eval = getEval();
- Fortran::lower::pft::FunctionLikeUnit &owningProc =
- *eval.getOwningProcedure();
- const Fortran::lower::pft::SymbolLabelMap &symbolLabelMap =
- owningProc.assignSymbolLabelMap;
- const Fortran::lower::pft::LabelEvalMap &labelEvalMap =
- owningProc.labelEvaluationMap;
- const Fortran::semantics::Symbol &symbol =
- *std::get<Fortran::parser::Name>(stmt.t).symbol;
- auto labelSetIter = symbolLabelMap.find(symbol);
- llvm::SmallVector<int64_t> valueList;
- llvm::SmallVector<Fortran::parser::Label> labelList;
- if (labelSetIter != symbolLabelMap.end()) {
- for (auto &label : labelSetIter->second) {
- const auto evalIter = labelEvalMap.find(label);
- assert(evalIter != labelEvalMap.end() && "assigned goto label missing");
- if (evalIter->second->block) { // non-format statement
- valueList.push_back(label); // label as an integer
- labelList.push_back(label);
- }
- }
- }
- if (!labelList.empty()) {
- auto selectExpr =
- builder->create<fir::LoadOp>(loc, getSymbolAddress(symbol));
- // Add a default error target in case the goto is nonconforming.
- mlir::Block *errorBlock =
- builder->getBlock()->splitBlock(builder->getInsertionPoint());
- genMultiwayBranch(selectExpr, valueList, labelList,
- eval.nonNopSuccessor(), errorBlock);
- startBlock(errorBlock);
- }
- fir::runtime::genReportFatalUserError(
- *builder, loc,
- "Assigned GOTO variable '" + symbol.name().ToString() +
- "' does not have a valid target label value");
- builder->create<fir::UnreachableOp>(loc);
- }
-
- /// Collect DO CONCURRENT or FORALL loop control information.
- IncrementLoopNestInfo getConcurrentControl(
- const Fortran::parser::ConcurrentHeader &header,
- const std::list<Fortran::parser::LocalitySpec> &localityList = {}) {
- IncrementLoopNestInfo incrementLoopNestInfo;
- for (const Fortran::parser::ConcurrentControl &control :
- std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t))
- incrementLoopNestInfo.emplace_back(
- *std::get<0>(control.t).symbol, std::get<1>(control.t),
- std::get<2>(control.t), std::get<3>(control.t), /*isUnordered=*/true);
- IncrementLoopInfo &info = incrementLoopNestInfo.back();
- info.maskExpr = Fortran::semantics::GetExpr(
- std::get<std::optional<Fortran::parser::ScalarLogicalExpr>>(header.t));
- for (const Fortran::parser::LocalitySpec &x : localityList) {
- if (const auto *localList =
- std::get_if<Fortran::parser::LocalitySpec::Local>(&x.u))
- for (const Fortran::parser::Name &x : localList->v)
- info.localSymList.push_back(x.symbol);
- if (const auto *localInitList =
- std::get_if<Fortran::parser::LocalitySpec::LocalInit>(&x.u))
- for (const Fortran::parser::Name &x : localInitList->v)
- info.localInitSymList.push_back(x.symbol);
- if (const auto *sharedList =
- std::get_if<Fortran::parser::LocalitySpec::Shared>(&x.u))
- for (const Fortran::parser::Name &x : sharedList->v)
- info.sharedSymList.push_back(x.symbol);
- }
- return incrementLoopNestInfo;
- }
-
- /// Create DO CONCURRENT construct symbol bindings and generate LOCAL_INIT
- /// assignments.
- void handleLocalitySpecs(const IncrementLoopInfo &info) {
- Fortran::semantics::SemanticsContext &semanticsContext =
- bridge.getSemanticsContext();
- for (const Fortran::semantics::Symbol *sym : info.localSymList)
- createHostAssociateVarClone(*sym);
- for (const Fortran::semantics::Symbol *sym : info.localInitSymList) {
- createHostAssociateVarClone(*sym);
- const auto *hostDetails =
- sym->detailsIf<Fortran::semantics::HostAssocDetails>();
- assert(hostDetails && "missing locality spec host symbol");
- const Fortran::semantics::Symbol *hostSym = &hostDetails->symbol();
- Fortran::evaluate::ExpressionAnalyzer ea{semanticsContext};
- Fortran::evaluate::Assignment assign{
- ea.Designate(Fortran::evaluate::DataRef{*sym}).value(),
- ea.Designate(Fortran::evaluate::DataRef{*hostSym}).value()};
- if (Fortran::semantics::IsPointer(*sym))
- assign.u = Fortran::evaluate::Assignment::BoundsSpec{};
- genAssignment(assign);
- }
- for (const Fortran::semantics::Symbol *sym : info.sharedSymList) {
- const auto *hostDetails =
- sym->detailsIf<Fortran::semantics::HostAssocDetails>();
- copySymbolBinding(hostDetails->symbol(), *sym);
+ if (info.hasLocalitySpecs()) {
+ mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
+ builder->setInsertionPointToStart(info.bodyBlock);
+ handleLocalitySpecs(info);
+ builder->restoreInsertionPoint(insertPt);
}
}
+}
- /// Generate FIR for a DO construct. There are six variants:
- /// - unstructured infinite and while loops
- /// - structured and unstructured increment loops
- /// - structured and unstructured concurrent loops
- void genFIR(const Fortran::parser::DoConstruct &doConstruct) {
- setCurrentPositionAt(doConstruct);
- // Collect loop nest information.
- // Generate begin loop code directly for infinite and while loops.
- Fortran::lower::pft::Evaluation &eval = getEval();
- bool unstructuredContext = eval.lowerAsUnstructured();
- Fortran::lower::pft::Evaluation &doStmtEval =
- eval.getFirstNestedEvaluation();
- auto *doStmt = doStmtEval.getIf<Fortran::parser::NonLabelDoStmt>();
- const auto &loopControl =
- std::get<std::optional<Fortran::parser::LoopControl>>(doStmt->t);
- mlir::Block *preheaderBlock = doStmtEval.block;
- mlir::Block *beginBlock =
- preheaderBlock ? preheaderBlock : builder->getBlock();
- auto createNextBeginBlock = [&]() {
- // Step beginBlock through unstructured preheader, header, and mask
- // blocks, created in outermost to innermost order.
- return beginBlock = beginBlock->splitBlock(beginBlock->end());
- };
- mlir::Block *headerBlock =
- unstructuredContext ? createNextBeginBlock() : nullptr;
- mlir::Block *bodyBlock = doStmtEval.lexicalSuccessor->block;
- mlir::Block *exitBlock = doStmtEval.parentConstruct->constructExit->block;
- IncrementLoopNestInfo incrementLoopNestInfo;
- const Fortran::parser::ScalarLogicalExpr *whileCondition = nullptr;
- bool infiniteLoop = !loopControl.has_value();
- if (infiniteLoop) {
- assert(unstructuredContext && "infinite loop must be unstructured");
- startBlock(headerBlock);
- } else if ((whileCondition =
- std::get_if<Fortran::parser::ScalarLogicalExpr>(
- &loopControl->u))) {
- assert(unstructuredContext && "while loop must be unstructured");
- maybeStartBlock(preheaderBlock); // no block or empty block
- startBlock(headerBlock);
- genConditionalBranch(*whileCondition, bodyBlock, exitBlock);
- } else if (const auto *bounds =
- std::get_if<Fortran::parser::LoopControl::Bounds>(
- &loopControl->u)) {
- // Non-concurrent increment loop.
- IncrementLoopInfo &info = incrementLoopNestInfo.emplace_back(
- *bounds->name.thing.symbol, bounds->lower, bounds->upper,
- bounds->step);
- if (unstructuredContext) {
- maybeStartBlock(preheaderBlock);
- info.hasRealControl = info.loopVariableSym->GetType()->IsNumeric(
- Fortran::common::TypeCategory::Real);
- info.headerBlock = headerBlock;
- info.bodyBlock = bodyBlock;
- info.exitBlock = exitBlock;
- }
- } else {
- const auto *concurrent =
- std::get_if<Fortran::parser::LoopControl::Concurrent>(
- &loopControl->u);
- assert(concurrent && "invalid DO loop variant");
- incrementLoopNestInfo = getConcurrentControl(
- std::get<Fortran::parser::ConcurrentHeader>(concurrent->t),
- std::get<std::list<Fortran::parser::LocalitySpec>>(concurrent->t));
- if (unstructuredContext) {
- maybeStartBlock(preheaderBlock);
- for (IncrementLoopInfo &info : incrementLoopNestInfo) {
- // The original loop body provides the body and latch blocks of the
- // innermost dimension. The (first) body block of a non-innermost
- // dimension is the preheader block of the immediately enclosed
- // dimension. The latch block of a non-innermost dimension is the
- // exit block of the immediately enclosed dimension.
- auto createNextExitBlock = [&]() {
- // Create unstructured loop exit blocks, outermost to innermost.
- return exitBlock = insertBlock(exitBlock);
- };
- bool isInnermost = &info == &incrementLoopNestInfo.back();
- bool isOutermost = &info == &incrementLoopNestInfo.front();
- info.headerBlock = isOutermost ? headerBlock : createNextBeginBlock();
- info.bodyBlock = isInnermost ? bodyBlock : createNextBeginBlock();
- info.exitBlock = isOutermost ? exitBlock : createNextExitBlock();
- if (info.maskExpr)
- info.maskBlock = createNextBeginBlock();
- }
+/// Generate FIR to end a structured or unstructured increment loop nest.
+void FirConverter::genFIRIncrementLoopEnd(
+ IncrementLoopNestInfo &incrementLoopNestInfo) {
+ assert(!incrementLoopNestInfo.empty() && "empty loop nest");
+ mlir::Location loc = toLocation();
+ for (auto it = incrementLoopNestInfo.rbegin(),
+ rend = incrementLoopNestInfo.rend();
+ it != rend; ++it) {
+ IncrementLoopInfo &info = *it;
+ if (info.isStructured()) {
+ // End fir.do_loop.
+ if (info.isUnordered) {
+ builder->setInsertionPointAfter(info.doLoop);
+ continue;
}
+ // Decrement tripVariable.
+ builder->setInsertionPointToEnd(info.doLoop.getBody());
+ llvm::SmallVector<mlir::Value, 2> results;
+ results.push_back(builder->create<mlir::arith::AddIOp>(
+ loc, info.doLoop.getInductionVar(), info.doLoop.getStep()));
+ // Step loopVariable to help optimizations such as vectorization.
+ // Induction variable elimination will clean up as necessary.
+ mlir::Value step = builder->createConvert(loc, info.getLoopVariableType(),
+ info.doLoop.getStep());
+ mlir::Value loopVar =
+ builder->create<fir::LoadOp>(loc, info.loopVariable);
+ results.push_back(
+ builder->create<mlir::arith::AddIOp>(loc, loopVar, step));
+ builder->create<fir::ResultOp>(loc, results);
+ builder->setInsertionPointAfter(info.doLoop);
+ // The loop control variable may be used after the loop.
+ builder->create<fir::StoreOp>(loc, info.doLoop.getResult(1),
+ info.loopVariable);
+ continue;
}
- // Increment loop begin code. (Infinite/while code was already generated.)
- if (!infiniteLoop && !whileCondition)
- genFIRIncrementLoopBegin(incrementLoopNestInfo);
-
- // Loop body code.
- auto iter = eval.getNestedEvaluations().begin();
- for (auto end = --eval.getNestedEvaluations().end(); iter != end; ++iter)
- genFIR(*iter, unstructuredContext);
-
- // An EndDoStmt in unstructured code may start a new block.
- Fortran::lower::pft::Evaluation &endDoEval = *iter;
- assert(endDoEval.getIf<Fortran::parser::EndDoStmt>() && "no enddo stmt");
- if (unstructuredContext)
- maybeStartBlock(endDoEval.block);
-
- // Loop end code.
- if (infiniteLoop || whileCondition)
- genBranch(headerBlock);
+ // Unstructured loop - decrement tripVariable and step loopVariable.
+ mlir::Value tripCount =
+ builder->create<fir::LoadOp>(loc, info.tripVariable);
+ mlir::Value one =
+ builder->createIntegerConstant(loc, tripCount.getType(), 1);
+ tripCount = builder->create<mlir::arith::SubIOp>(loc, tripCount, one);
+ builder->create<fir::StoreOp>(loc, tripCount, info.tripVariable);
+ mlir::Value value = builder->create<fir::LoadOp>(loc, info.loopVariable);
+ mlir::Value step;
+ if (info.stepVariable)
+ step = builder->create<fir::LoadOp>(loc, info.stepVariable);
else
- genFIRIncrementLoopEnd(incrementLoopNestInfo);
-
- // This call may generate a branch in some contexts.
- genFIR(endDoEval, unstructuredContext);
- }
-
- /// Generate FIR to evaluate loop control values (lower, upper and step).
- mlir::Value genControlValue(const Fortran::lower::SomeExpr *expr,
- const IncrementLoopInfo &info,
- bool *isConst = nullptr) {
- mlir::Location loc = toLocation();
- mlir::Type controlType = info.isStructured() ? builder->getIndexType()
- : info.getLoopVariableType();
- Fortran::lower::StatementContext stmtCtx;
- if (expr) {
- if (isConst)
- *isConst = Fortran::evaluate::IsConstantExpr(*expr);
- return builder->createConvert(loc, controlType,
- createFIRExpr(loc, expr, stmtCtx));
- }
-
- if (isConst)
- *isConst = true;
+ step = genControlValue(info.stepExpr, info);
if (info.hasRealControl)
- return builder->createRealConstant(loc, controlType, 1u);
- return builder->createIntegerConstant(loc, controlType, 1); // step
- }
-
- /// Generate FIR to begin a structured or unstructured increment loop nest.
- void genFIRIncrementLoopBegin(IncrementLoopNestInfo &incrementLoopNestInfo) {
- assert(!incrementLoopNestInfo.empty() && "empty loop nest");
- mlir::Location loc = toLocation();
- for (IncrementLoopInfo &info : incrementLoopNestInfo) {
- info.loopVariable =
- genLoopVariableAddress(loc, *info.loopVariableSym, info.isUnordered);
- mlir::Value lowerValue = genControlValue(info.lowerExpr, info);
- mlir::Value upperValue = genControlValue(info.upperExpr, info);
- bool isConst = true;
- mlir::Value stepValue = genControlValue(
- info.stepExpr, info, info.isStructured() ? nullptr : &isConst);
- // Use a temp variable for unstructured loops with non-const step.
- if (!isConst) {
- info.stepVariable = builder->createTemporary(loc, stepValue.getType());
- builder->create<fir::StoreOp>(loc, stepValue, info.stepVariable);
- }
-
- // Structured loop - generate fir.do_loop.
- if (info.isStructured()) {
- mlir::Type loopVarType = info.getLoopVariableType();
- mlir::Value loopValue;
- if (info.isUnordered) {
- // The loop variable value is explicitly updated.
- info.doLoop = builder->create<fir::DoLoopOp>(
- loc, lowerValue, upperValue, stepValue, /*unordered=*/true);
- builder->setInsertionPointToStart(info.doLoop.getBody());
- loopValue = builder->createConvert(loc, loopVarType,
- info.doLoop.getInductionVar());
- } else {
- // The loop variable is a doLoop op argument.
- info.doLoop = builder->create<fir::DoLoopOp>(
- loc, lowerValue, upperValue, stepValue, /*unordered=*/false,
- /*finalCountValue=*/true,
- builder->createConvert(loc, loopVarType, lowerValue));
- builder->setInsertionPointToStart(info.doLoop.getBody());
- loopValue = info.doLoop.getRegionIterArgs()[0];
- }
- // Update the loop variable value in case it has non-index references.
- builder->create<fir::StoreOp>(loc, loopValue, info.loopVariable);
- if (info.maskExpr) {
- Fortran::lower::StatementContext stmtCtx;
- mlir::Value maskCond = createFIRExpr(loc, info.maskExpr, stmtCtx);
- stmtCtx.finalizeAndReset();
- mlir::Value maskCondCast =
- builder->createConvert(loc, builder->getI1Type(), maskCond);
- auto ifOp = builder->create<fir::IfOp>(loc, maskCondCast,
- /*withElseRegion=*/false);
- builder->setInsertionPointToStart(&ifOp.getThenRegion().front());
- }
- if (info.hasLocalitySpecs())
- handleLocalitySpecs(info);
- continue;
- }
-
- // Unstructured loop preheader - initialize tripVariable and loopVariable.
- mlir::Value tripCount;
- if (info.hasRealControl) {
- auto diff1 =
- builder->create<mlir::arith::SubFOp>(loc, upperValue, lowerValue);
- auto diff2 =
- builder->create<mlir::arith::AddFOp>(loc, diff1, stepValue);
- tripCount = builder->create<mlir::arith::DivFOp>(loc, diff2, stepValue);
- tripCount =
- builder->createConvert(loc, builder->getIndexType(), tripCount);
- } else {
- auto diff1 =
- builder->create<mlir::arith::SubIOp>(loc, upperValue, lowerValue);
- auto diff2 =
- builder->create<mlir::arith::AddIOp>(loc, diff1, stepValue);
- tripCount =
- builder->create<mlir::arith::DivSIOp>(loc, diff2, stepValue);
- }
- if (forceLoopToExecuteOnce) { // minimum tripCount is 1
- mlir::Value one =
- builder->createIntegerConstant(loc, tripCount.getType(), 1);
- auto cond = builder->create<mlir::arith::CmpIOp>(
- loc, mlir::arith::CmpIPredicate::slt, tripCount, one);
- tripCount =
- builder->create<mlir::arith::SelectOp>(loc, cond, one, tripCount);
- }
- info.tripVariable = builder->createTemporary(loc, tripCount.getType());
- builder->create<fir::StoreOp>(loc, tripCount, info.tripVariable);
- builder->create<fir::StoreOp>(loc, lowerValue, info.loopVariable);
-
- // Unstructured loop header - generate loop condition and mask.
- // Note - Currently there is no way to tag a loop as a concurrent loop.
- startBlock(info.headerBlock);
- tripCount = builder->create<fir::LoadOp>(loc, info.tripVariable);
- mlir::Value zero =
- builder->createIntegerConstant(loc, tripCount.getType(), 0);
- auto cond = builder->create<mlir::arith::CmpIOp>(
- loc, mlir::arith::CmpIPredicate::sgt, tripCount, zero);
- if (info.maskExpr) {
- genConditionalBranch(cond, info.maskBlock, info.exitBlock);
- startBlock(info.maskBlock);
- mlir::Block *latchBlock = getEval().getLastNestedEvaluation().block;
- assert(latchBlock && "missing masked concurrent loop latch block");
- Fortran::lower::StatementContext stmtCtx;
- mlir::Value maskCond = createFIRExpr(loc, info.maskExpr, stmtCtx);
- stmtCtx.finalizeAndReset();
- genConditionalBranch(maskCond, info.bodyBlock, latchBlock);
- } else {
- genConditionalBranch(cond, info.bodyBlock, info.exitBlock);
- if (&info != &incrementLoopNestInfo.back()) // not innermost
- startBlock(info.bodyBlock); // preheader block of enclosed dimension
- }
- if (info.hasLocalitySpecs()) {
- mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
- builder->setInsertionPointToStart(info.bodyBlock);
- handleLocalitySpecs(info);
- builder->restoreInsertionPoint(insertPt);
- }
- }
- }
-
- /// Generate FIR to end a structured or unstructured increment loop nest.
- void genFIRIncrementLoopEnd(IncrementLoopNestInfo &incrementLoopNestInfo) {
- assert(!incrementLoopNestInfo.empty() && "empty loop nest");
- mlir::Location loc = toLocation();
- for (auto it = incrementLoopNestInfo.rbegin(),
- rend = incrementLoopNestInfo.rend();
- it != rend; ++it) {
- IncrementLoopInfo &info = *it;
- if (info.isStructured()) {
- // End fir.do_loop.
- if (info.isUnordered) {
- builder->setInsertionPointAfter(info.doLoop);
- continue;
- }
- // Decrement tripVariable.
- builder->setInsertionPointToEnd(info.doLoop.getBody());
- llvm::SmallVector<mlir::Value, 2> results;
- results.push_back(builder->create<mlir::arith::AddIOp>(
- loc, info.doLoop.getInductionVar(), info.doLoop.getStep()));
- // Step loopVariable to help optimizations such as vectorization.
- // Induction variable elimination will clean up as necessary.
- mlir::Value step = builder->createConvert(
- loc, info.getLoopVariableType(), info.doLoop.getStep());
- mlir::Value loopVar =
- builder->create<fir::LoadOp>(loc, info.loopVariable);
- results.push_back(
- builder->create<mlir::arith::AddIOp>(loc, loopVar, step));
- builder->create<fir::ResultOp>(loc, results);
- builder->setInsertionPointAfter(info.doLoop);
- // The loop control variable may be used after the loop.
- builder->create<fir::StoreOp>(loc, info.doLoop.getResult(1),
- info.loopVariable);
- continue;
- }
+ value = builder->create<mlir::arith::AddFOp>(loc, value, step);
+ else
+ value = builder->create<mlir::arith::AddIOp>(loc, value, step);
+ builder->create<fir::StoreOp>(loc, value, info.loopVariable);
- // Unstructured loop - decrement tripVariable and step loopVariable.
- mlir::Value tripCount =
- builder->create<fir::LoadOp>(loc, info.tripVariable);
- mlir::Value one =
- builder->createIntegerConstant(loc, tripCount.getType(), 1);
- tripCount = builder->create<mlir::arith::SubIOp>(loc, tripCount, one);
- builder->create<fir::StoreOp>(loc, tripCount, info.tripVariable);
- mlir::Value value = builder->create<fir::LoadOp>(loc, info.loopVariable);
- mlir::Value step;
- if (info.stepVariable)
- step = builder->create<fir::LoadOp>(loc, info.stepVariable);
- else
- step = genControlValue(info.stepExpr, info);
- if (info.hasRealControl)
- value = builder->create<mlir::arith::AddFOp>(loc, value, step);
- else
- value = builder->create<mlir::arith::AddIOp>(loc, value, step);
- builder->create<fir::StoreOp>(loc, value, info.loopVariable);
-
- genBranch(info.headerBlock);
- if (&info != &incrementLoopNestInfo.front()) // not outermost
- startBlock(info.exitBlock); // latch block of enclosing dimension
- }
+ genBranch(info.headerBlock);
+ if (&info != &incrementLoopNestInfo.front()) // not outermost
+ startBlock(info.exitBlock); // latch block of enclosing dimension
}
+}
- /// Generate structured or unstructured FIR for an IF construct.
- /// The initial statement may be either an IfStmt or an IfThenStmt.
- void genFIR(const Fortran::parser::IfConstruct &) {
- mlir::Location loc = toLocation();
- Fortran::lower::pft::Evaluation &eval = getEval();
- if (eval.lowerAsStructured()) {
- // Structured fir.if nest.
- fir::IfOp topIfOp, currentIfOp;
- for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
- auto genIfOp = [&](mlir::Value cond) {
- auto ifOp = builder->create<fir::IfOp>(loc, cond, /*withElse=*/true);
- builder->setInsertionPointToStart(&ifOp.getThenRegion().front());
- return ifOp;
- };
- if (auto *s = e.getIf<Fortran::parser::IfThenStmt>()) {
- topIfOp = currentIfOp = genIfOp(genIfCondition(s, e.negateCondition));
- } else if (auto *s = e.getIf<Fortran::parser::IfStmt>()) {
- topIfOp = currentIfOp = genIfOp(genIfCondition(s, e.negateCondition));
- } else if (auto *s = e.getIf<Fortran::parser::ElseIfStmt>()) {
- builder->setInsertionPointToStart(
- ¤tIfOp.getElseRegion().front());
- currentIfOp = genIfOp(genIfCondition(s));
- } else if (e.isA<Fortran::parser::ElseStmt>()) {
- builder->setInsertionPointToStart(
- ¤tIfOp.getElseRegion().front());
- } else if (e.isA<Fortran::parser::EndIfStmt>()) {
- builder->setInsertionPointAfter(topIfOp);
- genFIR(e, /*unstructuredContext=*/false); // may generate branch
- } else {
- genFIR(e, /*unstructuredContext=*/false);
- }
- }
- return;
- }
-
- // Unstructured branch sequence.
+/// Generate structured or unstructured FIR for an IF construct.
+/// The initial statement may be either an IfStmt or an IfThenStmt.
+void FirConverter::genFIR(const Fortran::parser::IfConstruct &) {
+ mlir::Location loc = toLocation();
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ if (eval.lowerAsStructured()) {
+ // Structured fir.if nest.
+ fir::IfOp topIfOp, currentIfOp;
for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
- auto genIfBranch = [&](mlir::Value cond) {
- if (e.lexicalSuccessor == e.controlSuccessor) // empty block -> exit
- genConditionalBranch(cond, e.parentConstruct->constructExit,
- e.controlSuccessor);
- else // non-empty block
- genConditionalBranch(cond, e.lexicalSuccessor, e.controlSuccessor);
+ auto genIfOp = [&](mlir::Value cond) {
+ auto ifOp = builder->create<fir::IfOp>(loc, cond, /*withElse=*/true);
+ builder->setInsertionPointToStart(&ifOp.getThenRegion().front());
+ return ifOp;
};
if (auto *s = e.getIf<Fortran::parser::IfThenStmt>()) {
- maybeStartBlock(e.block);
- genIfBranch(genIfCondition(s, e.negateCondition));
+ topIfOp = currentIfOp = genIfOp(genIfCondition(s, e.negateCondition));
} else if (auto *s = e.getIf<Fortran::parser::IfStmt>()) {
- maybeStartBlock(e.block);
- genIfBranch(genIfCondition(s, e.negateCondition));
+ topIfOp = currentIfOp = genIfOp(genIfCondition(s, e.negateCondition));
} else if (auto *s = e.getIf<Fortran::parser::ElseIfStmt>()) {
- startBlock(e.block);
- genIfBranch(genIfCondition(s));
+ builder->setInsertionPointToStart(¤tIfOp.getElseRegion().front());
+ currentIfOp = genIfOp(genIfCondition(s));
+ } else if (e.isA<Fortran::parser::ElseStmt>()) {
+ builder->setInsertionPointToStart(¤tIfOp.getElseRegion().front());
+ } else if (e.isA<Fortran::parser::EndIfStmt>()) {
+ builder->setInsertionPointAfter(topIfOp);
+ genFIR(e, /*unstructuredContext=*/false); // may generate branch
} else {
- genFIR(e);
+ genFIR(e, /*unstructuredContext=*/false);
}
}
+ return;
}
- void genFIR(const Fortran::parser::CaseConstruct &) {
- Fortran::lower::pft::Evaluation &eval = getEval();
- Fortran::lower::StatementContext stmtCtx;
- pushActiveConstruct(eval, stmtCtx);
- for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
- if (e.getIf<Fortran::parser::EndSelectStmt>())
- maybeStartBlock(e.block);
- else
- genFIR(e);
+ // Unstructured branch sequence.
+ for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
+ auto genIfBranch = [&](mlir::Value cond) {
+ if (e.lexicalSuccessor == e.controlSuccessor) // empty block -> exit
+ genConditionalBranch(cond, e.parentConstruct->constructExit,
+ e.controlSuccessor);
+ else // non-empty block
+ genConditionalBranch(cond, e.lexicalSuccessor, e.controlSuccessor);
+ };
+ if (auto *s = e.getIf<Fortran::parser::IfThenStmt>()) {
+ maybeStartBlock(e.block);
+ genIfBranch(genIfCondition(s, e.negateCondition));
+ } else if (auto *s = e.getIf<Fortran::parser::IfStmt>()) {
+ maybeStartBlock(e.block);
+ genIfBranch(genIfCondition(s, e.negateCondition));
+ } else if (auto *s = e.getIf<Fortran::parser::ElseIfStmt>()) {
+ startBlock(e.block);
+ genIfBranch(genIfCondition(s));
+ } else {
+ genFIR(e);
}
- popActiveConstruct();
}
+}
- template <typename A>
- void genNestedStatement(const Fortran::parser::Statement<A> &stmt) {
- setCurrentPosition(stmt.source);
- genFIR(stmt.statement);
+void FirConverter::genFIR(const Fortran::parser::CaseConstruct &) {
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ Fortran::lower::StatementContext stmtCtx;
+ pushActiveConstruct(eval, stmtCtx);
+ for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
+ if (e.getIf<Fortran::parser::EndSelectStmt>())
+ maybeStartBlock(e.block);
+ else
+ genFIR(e);
}
+ popActiveConstruct();
+}
+
+/// Force the binding of an explicit symbol. This is used to bind and re-bind
+/// a concurrent control symbol to its value.
+void FirConverter::forceControlVariableBinding(
+ const Fortran::semantics::Symbol *sym, mlir::Value inducVar) {
+ mlir::Location loc = toLocation();
+ assert(sym && "There must be a symbol to bind");
+ mlir::Type toTy = genType(*sym);
+ // FIXME: this should be a "per iteration" temporary.
+ mlir::Value tmp = builder->createTemporary(
+ loc, toTy, toStringRef(sym->name()),
+ llvm::ArrayRef<mlir::NamedAttribute>{fir::getAdaptToByRefAttr(*builder)});
+ mlir::Value cast = builder->createConvert(loc, toTy, inducVar);
+ builder->create<fir::StoreOp>(loc, cast, tmp);
+ addSymbol(*sym, tmp, /*force=*/true);
+}
- /// Force the binding of an explicit symbol. This is used to bind and re-bind
- /// a concurrent control symbol to its value.
- void forceControlVariableBinding(const Fortran::semantics::Symbol *sym,
- mlir::Value inducVar) {
+/// Process a concurrent header for a FORALL. (Concurrent headers for DO
+/// CONCURRENT loops are lowered elsewhere.)
+void FirConverter::genFIR(const Fortran::parser::ConcurrentHeader &header) {
+ llvm::SmallVector<mlir::Value> lows;
+ llvm::SmallVector<mlir::Value> highs;
+ llvm::SmallVector<mlir::Value> steps;
+ if (explicitIterSpace.isOutermostForall()) {
+ // For the outermost forall, we evaluate the bounds expressions once.
+ // Contrastingly, if this forall is nested, the bounds expressions are
+ // assumed to be pure, possibly dependent on outer concurrent control
+ // variables, possibly variant with respect to arguments, and will be
+ // re-evaluated.
mlir::Location loc = toLocation();
- assert(sym && "There must be a symbol to bind");
- mlir::Type toTy = genType(*sym);
- // FIXME: this should be a "per iteration" temporary.
- mlir::Value tmp =
- builder->createTemporary(loc, toTy, toStringRef(sym->name()),
- llvm::ArrayRef<mlir::NamedAttribute>{
- fir::getAdaptToByRefAttr(*builder)});
- mlir::Value cast = builder->createConvert(loc, toTy, inducVar);
- builder->create<fir::StoreOp>(loc, cast, tmp);
- addSymbol(*sym, tmp, /*force=*/true);
+ mlir::Type idxTy = builder->getIndexType();
+ Fortran::lower::StatementContext &stmtCtx = explicitIterSpace.stmtContext();
+ auto lowerExpr = [&](auto &e) {
+ return fir::getBase(genExprValue(e, stmtCtx));
+ };
+ for (const Fortran::parser::ConcurrentControl &ctrl :
+ std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t)) {
+ const Fortran::lower::SomeExpr *lo =
+ Fortran::semantics::GetExpr(std::get<1>(ctrl.t));
+ const Fortran::lower::SomeExpr *hi =
+ Fortran::semantics::GetExpr(std::get<2>(ctrl.t));
+ auto &optStep =
+ std::get<std::optional<Fortran::parser::ScalarIntExpr>>(ctrl.t);
+ lows.push_back(builder->createConvert(loc, idxTy, lowerExpr(*lo)));
+ highs.push_back(builder->createConvert(loc, idxTy, lowerExpr(*hi)));
+ steps.push_back(
+ optStep.has_value()
+ ? builder->createConvert(
+ loc, idxTy,
+ lowerExpr(*Fortran::semantics::GetExpr(*optStep)))
+ : builder->createIntegerConstant(loc, idxTy, 1));
+ }
}
-
- /// Process a concurrent header for a FORALL. (Concurrent headers for DO
- /// CONCURRENT loops are lowered elsewhere.)
- void genFIR(const Fortran::parser::ConcurrentHeader &header) {
- llvm::SmallVector<mlir::Value> lows;
- llvm::SmallVector<mlir::Value> highs;
- llvm::SmallVector<mlir::Value> steps;
- if (explicitIterSpace.isOutermostForall()) {
- // For the outermost forall, we evaluate the bounds expressions once.
- // Contrastingly, if this forall is nested, the bounds expressions are
- // assumed to be pure, possibly dependent on outer concurrent control
- // variables, possibly variant with respect to arguments, and will be
- // re-evaluated.
- mlir::Location loc = toLocation();
- mlir::Type idxTy = builder->getIndexType();
- Fortran::lower::StatementContext &stmtCtx =
- explicitIterSpace.stmtContext();
- auto lowerExpr = [&](auto &e) {
- return fir::getBase(genExprValue(e, stmtCtx));
- };
- for (const Fortran::parser::ConcurrentControl &ctrl :
- std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t)) {
+ auto lambda = [&, lows, highs, steps]() {
+ // Create our iteration space from the header spec.
+ mlir::Location loc = toLocation();
+ mlir::Type idxTy = builder->getIndexType();
+ llvm::SmallVector<fir::DoLoopOp> loops;
+ Fortran::lower::StatementContext &stmtCtx = explicitIterSpace.stmtContext();
+ auto lowerExpr = [&](auto &e) {
+ return fir::getBase(genExprValue(e, stmtCtx));
+ };
+ const bool outermost = !lows.empty();
+ std::size_t headerIndex = 0;
+ for (const Fortran::parser::ConcurrentControl &ctrl :
+ std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t)) {
+ const Fortran::semantics::Symbol *ctrlVar =
+ std::get<Fortran::parser::Name>(ctrl.t).symbol;
+ mlir::Value lb;
+ mlir::Value ub;
+ mlir::Value by;
+ if (outermost) {
+ assert(headerIndex < lows.size());
+ if (headerIndex == 0)
+ explicitIterSpace.resetInnerArgs();
+ lb = lows[headerIndex];
+ ub = highs[headerIndex];
+ by = steps[headerIndex++];
+ } else {
const Fortran::lower::SomeExpr *lo =
Fortran::semantics::GetExpr(std::get<1>(ctrl.t));
const Fortran::lower::SomeExpr *hi =
Fortran::semantics::GetExpr(std::get<2>(ctrl.t));
auto &optStep =
std::get<std::optional<Fortran::parser::ScalarIntExpr>>(ctrl.t);
- lows.push_back(builder->createConvert(loc, idxTy, lowerExpr(*lo)));
- highs.push_back(builder->createConvert(loc, idxTy, lowerExpr(*hi)));
- steps.push_back(
- optStep.has_value()
- ? builder->createConvert(
- loc, idxTy,
- lowerExpr(*Fortran::semantics::GetExpr(*optStep)))
- : builder->createIntegerConstant(loc, idxTy, 1));
+ lb = builder->createConvert(loc, idxTy, lowerExpr(*lo));
+ ub = builder->createConvert(loc, idxTy, lowerExpr(*hi));
+ by = optStep.has_value()
+ ? builder->createConvert(
+ loc, idxTy,
+ lowerExpr(*Fortran::semantics::GetExpr(*optStep)))
+ : builder->createIntegerConstant(loc, idxTy, 1);
}
+ auto lp = builder->create<fir::DoLoopOp>(
+ loc, lb, ub, by, /*unordered=*/true,
+ /*finalCount=*/false, explicitIterSpace.getInnerArgs());
+ if ((!loops.empty() || !outermost) && !lp.getRegionIterArgs().empty())
+ builder->create<fir::ResultOp>(loc, lp.getResults());
+ explicitIterSpace.setInnerArgs(lp.getRegionIterArgs());
+ builder->setInsertionPointToStart(lp.getBody());
+ forceControlVariableBinding(ctrlVar, lp.getInductionVar());
+ loops.push_back(lp);
}
- auto lambda = [&, lows, highs, steps]() {
- // Create our iteration space from the header spec.
- mlir::Location loc = toLocation();
- mlir::Type idxTy = builder->getIndexType();
- llvm::SmallVector<fir::DoLoopOp> loops;
- Fortran::lower::StatementContext &stmtCtx =
- explicitIterSpace.stmtContext();
- auto lowerExpr = [&](auto &e) {
- return fir::getBase(genExprValue(e, stmtCtx));
- };
- const bool outermost = !lows.empty();
- std::size_t headerIndex = 0;
- for (const Fortran::parser::ConcurrentControl &ctrl :
- std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t)) {
- const Fortran::semantics::Symbol *ctrlVar =
- std::get<Fortran::parser::Name>(ctrl.t).symbol;
- mlir::Value lb;
- mlir::Value ub;
- mlir::Value by;
- if (outermost) {
- assert(headerIndex < lows.size());
- if (headerIndex == 0)
- explicitIterSpace.resetInnerArgs();
- lb = lows[headerIndex];
- ub = highs[headerIndex];
- by = steps[headerIndex++];
- } else {
- const Fortran::lower::SomeExpr *lo =
- Fortran::semantics::GetExpr(std::get<1>(ctrl.t));
- const Fortran::lower::SomeExpr *hi =
- Fortran::semantics::GetExpr(std::get<2>(ctrl.t));
- auto &optStep =
- std::get<std::optional<Fortran::parser::ScalarIntExpr>>(ctrl.t);
- lb = builder->createConvert(loc, idxTy, lowerExpr(*lo));
- ub = builder->createConvert(loc, idxTy, lowerExpr(*hi));
- by = optStep.has_value()
- ? builder->createConvert(
- loc, idxTy,
- lowerExpr(*Fortran::semantics::GetExpr(*optStep)))
- : builder->createIntegerConstant(loc, idxTy, 1);
- }
- auto lp = builder->create<fir::DoLoopOp>(
- loc, lb, ub, by, /*unordered=*/true,
- /*finalCount=*/false, explicitIterSpace.getInnerArgs());
- if ((!loops.empty() || !outermost) && !lp.getRegionIterArgs().empty())
- builder->create<fir::ResultOp>(loc, lp.getResults());
- explicitIterSpace.setInnerArgs(lp.getRegionIterArgs());
- builder->setInsertionPointToStart(lp.getBody());
- forceControlVariableBinding(ctrlVar, lp.getInductionVar());
- loops.push_back(lp);
- }
- if (outermost)
- explicitIterSpace.setOuterLoop(loops[0]);
- explicitIterSpace.appendLoops(loops);
- if (const auto &mask =
- std::get<std::optional<Fortran::parser::ScalarLogicalExpr>>(
- header.t);
- mask.has_value()) {
- mlir::Type i1Ty = builder->getI1Type();
- fir::ExtendedValue maskExv =
- genExprValue(*Fortran::semantics::GetExpr(mask.value()), stmtCtx);
- mlir::Value cond =
- builder->createConvert(loc, i1Ty, fir::getBase(maskExv));
- auto ifOp = builder->create<fir::IfOp>(
- loc, explicitIterSpace.innerArgTypes(), cond,
- /*withElseRegion=*/true);
- builder->create<fir::ResultOp>(loc, ifOp.getResults());
- builder->setInsertionPointToStart(&ifOp.getElseRegion().front());
- builder->create<fir::ResultOp>(loc, explicitIterSpace.getInnerArgs());
- builder->setInsertionPointToStart(&ifOp.getThenRegion().front());
- }
- };
- // Push the lambda to gen the loop nest context.
- explicitIterSpace.pushLoopNest(lambda);
- }
+ if (outermost)
+ explicitIterSpace.setOuterLoop(loops[0]);
+ explicitIterSpace.appendLoops(loops);
+ if (const auto &mask =
+ std::get<std::optional<Fortran::parser::ScalarLogicalExpr>>(
+ header.t);
+ mask.has_value()) {
+ mlir::Type i1Ty = builder->getI1Type();
+ fir::ExtendedValue maskExv =
+ genExprValue(*Fortran::semantics::GetExpr(mask.value()), stmtCtx);
+ mlir::Value cond =
+ builder->createConvert(loc, i1Ty, fir::getBase(maskExv));
+ auto ifOp = builder->create<fir::IfOp>(
+ loc, explicitIterSpace.innerArgTypes(), cond,
+ /*withElseRegion=*/true);
+ builder->create<fir::ResultOp>(loc, ifOp.getResults());
+ builder->setInsertionPointToStart(&ifOp.getElseRegion().front());
+ builder->create<fir::ResultOp>(loc, explicitIterSpace.getInnerArgs());
+ builder->setInsertionPointToStart(&ifOp.getThenRegion().front());
+ }
+ };
+ // Push the lambda to gen the loop nest context.
+ explicitIterSpace.pushLoopNest(lambda);
+}
- void genFIR(const Fortran::parser::ForallAssignmentStmt &stmt) {
- std::visit([&](const auto &x) { genFIR(x); }, stmt.u);
- }
+void FirConverter::genFIR(const Fortran::parser::ForallAssignmentStmt &stmt) {
+ std::visit([&](const auto &x) { genFIR(x); }, stmt.u);
+}
- void genFIR(const Fortran::parser::EndForallStmt &) {
- if (!lowerToHighLevelFIR())
- cleanupExplicitSpace();
- }
+void FirConverter::genFIR(const Fortran::parser::EndForallStmt &) {
+ if (!lowerToHighLevelFIR())
+ cleanupExplicitSpace();
+}
- template <typename A>
- void prepareExplicitSpace(const A &forall) {
- if (!explicitIterSpace.isActive())
- analyzeExplicitSpace(forall);
+/// Generate FIR for a FORALL statement.
+void FirConverter::genFIR(const Fortran::parser::ForallStmt &stmt) {
+ const auto &concurrentHeader =
+ std::get<Fortran::common::Indirection<Fortran::parser::ConcurrentHeader>>(
+ stmt.t)
+ .value();
+ if (lowerToHighLevelFIR()) {
+ mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
localSymbols.pushScope();
- explicitIterSpace.enter();
- }
+ genForallNest(concurrentHeader);
+ genFIR(std::get<Fortran::parser::UnlabeledStatement<
+ Fortran::parser::ForallAssignmentStmt>>(stmt.t)
+ .statement);
+ localSymbols.popScope();
+ builder->restoreInsertionPoint(insertPt);
+ return;
+ }
+ prepareExplicitSpace(stmt);
+ genFIR(concurrentHeader);
+ genFIR(std::get<Fortran::parser::UnlabeledStatement<
+ Fortran::parser::ForallAssignmentStmt>>(stmt.t)
+ .statement);
+ cleanupExplicitSpace();
+}
- /// Cleanup all the FORALL context information when we exit.
- void cleanupExplicitSpace() {
- explicitIterSpace.leave();
+/// Generate FIR for a FORALL construct.
+void FirConverter::genFIR(const Fortran::parser::ForallConstruct &forall) {
+ mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
+ if (lowerToHighLevelFIR())
+ localSymbols.pushScope();
+ else
+ prepareExplicitSpace(forall);
+ genNestedStatement(
+ std::get<
+ Fortran::parser::Statement<Fortran::parser::ForallConstructStmt>>(
+ forall.t));
+ for (const Fortran::parser::ForallBodyConstruct &s :
+ std::get<std::list<Fortran::parser::ForallBodyConstruct>>(forall.t)) {
+ std::visit(
+ Fortran::common::visitors{
+ [&](const Fortran::parser::WhereConstruct &b) { genFIR(b); },
+ [&](const Fortran::common::Indirection<
+ Fortran::parser::ForallConstruct> &b) { genFIR(b.value()); },
+ [&](const auto &b) { genNestedStatement(b); }},
+ s.u);
+ }
+ genNestedStatement(
+ std::get<Fortran::parser::Statement<Fortran::parser::EndForallStmt>>(
+ forall.t));
+ if (lowerToHighLevelFIR()) {
localSymbols.popScope();
+ builder->restoreInsertionPoint(insertPt);
}
+}
- /// Generate FIR for a FORALL statement.
- void genFIR(const Fortran::parser::ForallStmt &stmt) {
- const auto &concurrentHeader =
- std::get<
- Fortran::common::Indirection<Fortran::parser::ConcurrentHeader>>(
- stmt.t)
- .value();
- if (lowerToHighLevelFIR()) {
- mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
- localSymbols.pushScope();
- genForallNest(concurrentHeader);
- genFIR(std::get<Fortran::parser::UnlabeledStatement<
- Fortran::parser::ForallAssignmentStmt>>(stmt.t)
- .statement);
- localSymbols.popScope();
- builder->restoreInsertionPoint(insertPt);
- return;
- }
- prepareExplicitSpace(stmt);
+/// Lower the concurrent header specification.
+void FirConverter::genFIR(const Fortran::parser::ForallConstructStmt &stmt) {
+ const auto &concurrentHeader =
+ std::get<Fortran::common::Indirection<Fortran::parser::ConcurrentHeader>>(
+ stmt.t)
+ .value();
+ if (lowerToHighLevelFIR())
+ genForallNest(concurrentHeader);
+ else
genFIR(concurrentHeader);
- genFIR(std::get<Fortran::parser::UnlabeledStatement<
- Fortran::parser::ForallAssignmentStmt>>(stmt.t)
- .statement);
- cleanupExplicitSpace();
- }
+}
- /// Generate FIR for a FORALL construct.
- void genFIR(const Fortran::parser::ForallConstruct &forall) {
- mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
- if (lowerToHighLevelFIR())
- localSymbols.pushScope();
- else
- prepareExplicitSpace(forall);
- genNestedStatement(
- std::get<
- Fortran::parser::Statement<Fortran::parser::ForallConstructStmt>>(
- forall.t));
- for (const Fortran::parser::ForallBodyConstruct &s :
- std::get<std::list<Fortran::parser::ForallBodyConstruct>>(forall.t)) {
- std::visit(
- Fortran::common::visitors{
- [&](const Fortran::parser::WhereConstruct &b) { genFIR(b); },
- [&](const Fortran::common::Indirection<
- Fortran::parser::ForallConstruct> &b) { genFIR(b.value()); },
- [&](const auto &b) { genNestedStatement(b); }},
- s.u);
- }
- genNestedStatement(
- std::get<Fortran::parser::Statement<Fortran::parser::EndForallStmt>>(
- forall.t));
- if (lowerToHighLevelFIR()) {
- localSymbols.popScope();
- builder->restoreInsertionPoint(insertPt);
+/// Generate hlfir.forall and hlfir.forall_mask nest given a Forall
+/// concurrent header
+void FirConverter::genForallNest(
+ const Fortran::parser::ConcurrentHeader &header) {
+ mlir::Location loc = getCurrentLocation();
+ const bool isOutterForall = !isInsideHlfirForallOrWhere();
+ hlfir::ForallOp outerForall;
+ auto evaluateControl = [&](const auto &parserExpr, mlir::Region ®ion,
+ bool isMask = false) {
+ if (region.empty())
+ builder->createBlock(®ion);
+ Fortran::lower::StatementContext localStmtCtx;
+ const Fortran::semantics::SomeExpr *anlalyzedExpr =
+ Fortran::semantics::GetExpr(parserExpr);
+ assert(anlalyzedExpr && "expression semantics failed");
+ // Generate the controls of outer forall outside of the hlfir.forall
+ // region. They do not depend on any previous forall indices (C1123) and
+ // no assignment has been made yet that could modify their value. This
+ // will simplify hlfir.forall analysis because the SSA integer value
+ // yielded will obviously not depend on any variable modified by the
+ // forall when produced outside of it.
+ // This is not done for the mask because it may (and in usual code, does)
+ // depend on the forall indices that have just been defined as
+ // hlfir.forall block arguments.
+ mlir::OpBuilder::InsertPoint innerInsertionPoint;
+ if (outerForall && !isMask) {
+ innerInsertionPoint = builder->saveInsertionPoint();
+ builder->setInsertionPoint(outerForall);
}
+ mlir::Value exprVal =
+ fir::getBase(genExprValue(*anlalyzedExpr, localStmtCtx, &loc));
+ localStmtCtx.finalizeAndPop();
+ if (isMask)
+ exprVal = builder->createConvert(loc, builder->getI1Type(), exprVal);
+ if (innerInsertionPoint.isSet())
+ builder->restoreInsertionPoint(innerInsertionPoint);
+ builder->create<hlfir::YieldOp>(loc, exprVal);
+ };
+ for (const Fortran::parser::ConcurrentControl &control :
+ std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t)) {
+ auto forallOp = builder->create<hlfir::ForallOp>(loc);
+ if (isOutterForall && !outerForall)
+ outerForall = forallOp;
+ evaluateControl(std::get<1>(control.t), forallOp.getLbRegion());
+ evaluateControl(std::get<2>(control.t), forallOp.getUbRegion());
+ if (const auto &optionalStep =
+ std::get<std::optional<Fortran::parser::ScalarIntExpr>>(control.t))
+ evaluateControl(*optionalStep, forallOp.getStepRegion());
+ // Create block argument and map it to a symbol via an hlfir.forall_index
+ // op (symbols must be mapped to in memory values).
+ const Fortran::semantics::Symbol *controlVar =
+ std::get<Fortran::parser::Name>(control.t).symbol;
+ assert(controlVar && "symbol analysis failed");
+ mlir::Type controlVarType = genType(*controlVar);
+ mlir::Block *forallBody =
+ builder->createBlock(&forallOp.getBody(), {}, {controlVarType}, {loc});
+ auto forallIndex = builder->create<hlfir::ForallIndexOp>(
+ loc, fir::ReferenceType::get(controlVarType),
+ forallBody->getArguments()[0],
+ builder->getStringAttr(controlVar->name().ToString()));
+ localSymbols.addVariableDefinition(*controlVar, forallIndex,
+ /*force=*/true);
+ auto end = builder->create<fir::FirEndOp>(loc);
+ builder->setInsertionPoint(end);
+ }
+
+ if (const auto &maskExpr =
+ std::get<std::optional<Fortran::parser::ScalarLogicalExpr>>(
+ header.t)) {
+ // Create hlfir.forall_mask and set insertion point in its body.
+ auto forallMaskOp = builder->create<hlfir::ForallMaskOp>(loc);
+ evaluateControl(*maskExpr, forallMaskOp.getMaskRegion(), /*isMask=*/true);
+ builder->createBlock(&forallMaskOp.getBody());
+ auto end = builder->create<fir::FirEndOp>(loc);
+ builder->setInsertionPoint(end);
}
+}
- /// Lower the concurrent header specification.
- void genFIR(const Fortran::parser::ForallConstructStmt &stmt) {
- const auto &concurrentHeader =
- std::get<
- Fortran::common::Indirection<Fortran::parser::ConcurrentHeader>>(
- stmt.t)
- .value();
- if (lowerToHighLevelFIR())
- genForallNest(concurrentHeader);
- else
- genFIR(concurrentHeader);
- }
-
- /// Generate hlfir.forall and hlfir.forall_mask nest given a Forall
- /// concurrent header
- void genForallNest(const Fortran::parser::ConcurrentHeader &header) {
- mlir::Location loc = getCurrentLocation();
- const bool isOutterForall = !isInsideHlfirForallOrWhere();
- hlfir::ForallOp outerForall;
- auto evaluateControl = [&](const auto &parserExpr, mlir::Region ®ion,
- bool isMask = false) {
- if (region.empty())
- builder->createBlock(®ion);
- Fortran::lower::StatementContext localStmtCtx;
- const Fortran::semantics::SomeExpr *anlalyzedExpr =
- Fortran::semantics::GetExpr(parserExpr);
- assert(anlalyzedExpr && "expression semantics failed");
- // Generate the controls of outer forall outside of the hlfir.forall
- // region. They do not depend on any previous forall indices (C1123) and
- // no assignment has been made yet that could modify their value. This
- // will simplify hlfir.forall analysis because the SSA integer value
- // yielded will obviously not depend on any variable modified by the
- // forall when produced outside of it.
- // This is not done for the mask because it may (and in usual code, does)
- // depend on the forall indices that have just been defined as
- // hlfir.forall block arguments.
- mlir::OpBuilder::InsertPoint innerInsertionPoint;
- if (outerForall && !isMask) {
- innerInsertionPoint = builder->saveInsertionPoint();
- builder->setInsertionPoint(outerForall);
- }
- mlir::Value exprVal =
- fir::getBase(genExprValue(*anlalyzedExpr, localStmtCtx, &loc));
- localStmtCtx.finalizeAndPop();
- if (isMask)
- exprVal = builder->createConvert(loc, builder->getI1Type(), exprVal);
- if (innerInsertionPoint.isSet())
- builder->restoreInsertionPoint(innerInsertionPoint);
- builder->create<hlfir::YieldOp>(loc, exprVal);
- };
- for (const Fortran::parser::ConcurrentControl &control :
- std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t)) {
- auto forallOp = builder->create<hlfir::ForallOp>(loc);
- if (isOutterForall && !outerForall)
- outerForall = forallOp;
- evaluateControl(std::get<1>(control.t), forallOp.getLbRegion());
- evaluateControl(std::get<2>(control.t), forallOp.getUbRegion());
- if (const auto &optionalStep =
- std::get<std::optional<Fortran::parser::ScalarIntExpr>>(
- control.t))
- evaluateControl(*optionalStep, forallOp.getStepRegion());
- // Create block argument and map it to a symbol via an hlfir.forall_index
- // op (symbols must be mapped to in memory values).
- const Fortran::semantics::Symbol *controlVar =
- std::get<Fortran::parser::Name>(control.t).symbol;
- assert(controlVar && "symbol analysis failed");
- mlir::Type controlVarType = genType(*controlVar);
- mlir::Block *forallBody = builder->createBlock(&forallOp.getBody(), {},
- {controlVarType}, {loc});
- auto forallIndex = builder->create<hlfir::ForallIndexOp>(
- loc, fir::ReferenceType::get(controlVarType),
- forallBody->getArguments()[0],
- builder->getStringAttr(controlVar->name().ToString()));
- localSymbols.addVariableDefinition(*controlVar, forallIndex,
- /*force=*/true);
- auto end = builder->create<fir::FirEndOp>(loc);
- builder->setInsertionPoint(end);
- }
+void FirConverter::genFIR(const Fortran::parser::CompilerDirective &) {
+ // TODO
+}
- if (const auto &maskExpr =
- std::get<std::optional<Fortran::parser::ScalarLogicalExpr>>(
- header.t)) {
- // Create hlfir.forall_mask and set insertion point in its body.
- auto forallMaskOp = builder->create<hlfir::ForallMaskOp>(loc);
- evaluateControl(*maskExpr, forallMaskOp.getMaskRegion(), /*isMask=*/true);
- builder->createBlock(&forallMaskOp.getBody());
- auto end = builder->create<fir::FirEndOp>(loc);
- builder->setInsertionPoint(end);
- }
+void FirConverter::genFIR(const Fortran::parser::OpenACCConstruct &acc) {
+ mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
+ localSymbols.pushScope();
+ mlir::Value exitCond =
+ genOpenACCConstruct(*this, bridge.getSemanticsContext(), getEval(), acc);
+ for (Fortran::lower::pft::Evaluation &e : getEval().getNestedEvaluations())
+ genFIR(e);
+ localSymbols.popScope();
+ builder->restoreInsertionPoint(insertPt);
+
+ const Fortran::parser::OpenACCLoopConstruct *accLoop =
+ std::get_if<Fortran::parser::OpenACCLoopConstruct>(&acc.u);
+ if (accLoop && exitCond) {
+ Fortran::lower::pft::FunctionLikeUnit *funit =
+ getEval().getOwningProcedure();
+ assert(funit && "not inside main program, function or subroutine");
+ mlir::Block *continueBlock =
+ builder->getBlock()->splitBlock(builder->getBlock()->end());
+ builder->create<mlir::cf::CondBranchOp>(toLocation(), exitCond,
+ funit->finalBlock, continueBlock);
+ builder->setInsertionPointToEnd(continueBlock);
}
+}
- void genFIR(const Fortran::parser::CompilerDirective &) {
- // TODO
- }
+void FirConverter::genFIR(
+ const Fortran::parser::OpenACCDeclarativeConstruct &accDecl) {
+ genOpenACCDeclarativeConstruct(*this, bridge.getSemanticsContext(),
+ bridge.openAccCtx(), accDecl, accRoutineInfos);
+ for (Fortran::lower::pft::Evaluation &e : getEval().getNestedEvaluations())
+ genFIR(e);
+}
- void genFIR(const Fortran::parser::OpenACCConstruct &acc) {
- mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
- localSymbols.pushScope();
- mlir::Value exitCond = genOpenACCConstruct(
- *this, bridge.getSemanticsContext(), getEval(), acc);
- for (Fortran::lower::pft::Evaluation &e : getEval().getNestedEvaluations())
- genFIR(e);
- localSymbols.popScope();
- builder->restoreInsertionPoint(insertPt);
+void FirConverter::genFIR(const Fortran::parser::OpenACCRoutineConstruct &acc) {
+ // Handled by genFIR(const Fortran::parser::OpenACCDeclarativeConstruct &)
+}
- const Fortran::parser::OpenACCLoopConstruct *accLoop =
- std::get_if<Fortran::parser::OpenACCLoopConstruct>(&acc.u);
- if (accLoop && exitCond) {
- Fortran::lower::pft::FunctionLikeUnit *funit =
- getEval().getOwningProcedure();
- assert(funit && "not inside main program, function or subroutine");
- mlir::Block *continueBlock =
- builder->getBlock()->splitBlock(builder->getBlock()->end());
- builder->create<mlir::cf::CondBranchOp>(toLocation(), exitCond,
- funit->finalBlock, continueBlock);
- builder->setInsertionPointToEnd(continueBlock);
+void FirConverter::genFIR(const Fortran::parser::OpenMPConstruct &omp) {
+ mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
+ localSymbols.pushScope();
+ genOpenMPConstruct(*this, bridge.getSemanticsContext(), getEval(), omp);
+
+ const Fortran::parser::OpenMPLoopConstruct *ompLoop =
+ std::get_if<Fortran::parser::OpenMPLoopConstruct>(&omp.u);
+ const Fortran::parser::OpenMPBlockConstruct *ompBlock =
+ std::get_if<Fortran::parser::OpenMPBlockConstruct>(&omp.u);
+
+ // If loop is part of an OpenMP Construct then the OpenMP dialect
+ // workshare loop operation has already been created. Only the
+ // body needs to be created here and the do_loop can be skipped.
+ // Skip the number of collapsed loops, which is 1 when there is a
+ // no collapse requested.
+
+ Fortran::lower::pft::Evaluation *curEval = &getEval();
+ const Fortran::parser::OmpClauseList *loopOpClauseList = nullptr;
+ if (ompLoop) {
+ loopOpClauseList = &std::get<Fortran::parser::OmpClauseList>(
+ std::get<Fortran::parser::OmpBeginLoopDirective>(ompLoop->t).t);
+ int64_t collapseValue = Fortran::lower::getCollapseValue(*loopOpClauseList);
+
+ curEval = &curEval->getFirstNestedEvaluation();
+ for (int64_t i = 1; i < collapseValue; i++) {
+ curEval = &*std::next(curEval->getNestedEvaluations().begin());
}
}
- void genFIR(const Fortran::parser::OpenACCDeclarativeConstruct &accDecl) {
- genOpenACCDeclarativeConstruct(*this, bridge.getSemanticsContext(),
- bridge.openAccCtx(), accDecl,
- accRoutineInfos);
- for (Fortran::lower::pft::Evaluation &e : getEval().getNestedEvaluations())
- genFIR(e);
- }
+ for (Fortran::lower::pft::Evaluation &e : curEval->getNestedEvaluations())
+ genFIR(e);
- void genFIR(const Fortran::parser::OpenACCRoutineConstruct &acc) {
- // Handled by genFIR(const Fortran::parser::OpenACCDeclarativeConstruct &)
+ if (ompLoop) {
+ genOpenMPReduction(*this, *loopOpClauseList);
+ } else if (ompBlock) {
+ const auto &blockStart =
+ std::get<Fortran::parser::OmpBeginBlockDirective>(ompBlock->t);
+ const auto &blockClauses =
+ std::get<Fortran::parser::OmpClauseList>(blockStart.t);
+ genOpenMPReduction(*this, blockClauses);
}
- void genFIR(const Fortran::parser::OpenMPConstruct &omp) {
- mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
- localSymbols.pushScope();
- genOpenMPConstruct(*this, bridge.getSemanticsContext(), getEval(), omp);
-
- const Fortran::parser::OpenMPLoopConstruct *ompLoop =
- std::get_if<Fortran::parser::OpenMPLoopConstruct>(&omp.u);
- const Fortran::parser::OpenMPBlockConstruct *ompBlock =
- std::get_if<Fortran::parser::OpenMPBlockConstruct>(&omp.u);
-
- // If loop is part of an OpenMP Construct then the OpenMP dialect
- // workshare loop operation has already been created. Only the
- // body needs to be created here and the do_loop can be skipped.
- // Skip the number of collapsed loops, which is 1 when there is a
- // no collapse requested.
-
- Fortran::lower::pft::Evaluation *curEval = &getEval();
- const Fortran::parser::OmpClauseList *loopOpClauseList = nullptr;
- if (ompLoop) {
- loopOpClauseList = &std::get<Fortran::parser::OmpClauseList>(
- std::get<Fortran::parser::OmpBeginLoopDirective>(ompLoop->t).t);
- int64_t collapseValue =
- Fortran::lower::getCollapseValue(*loopOpClauseList);
-
- curEval = &curEval->getFirstNestedEvaluation();
- for (int64_t i = 1; i < collapseValue; i++) {
- curEval = &*std::next(curEval->getNestedEvaluations().begin());
- }
- }
-
- for (Fortran::lower::pft::Evaluation &e : curEval->getNestedEvaluations())
- genFIR(e);
+ localSymbols.popScope();
+ builder->restoreInsertionPoint(insertPt);
- if (ompLoop) {
- genOpenMPReduction(*this, *loopOpClauseList);
- } else if (ompBlock) {
- const auto &blockStart =
- std::get<Fortran::parser::OmpBeginBlockDirective>(ompBlock->t);
- const auto &blockClauses =
- std::get<Fortran::parser::OmpClauseList>(blockStart.t);
- genOpenMPReduction(*this, blockClauses);
- }
-
- localSymbols.popScope();
- builder->restoreInsertionPoint(insertPt);
-
- // Register if a target region was found
- ompDeviceCodeFound =
- ompDeviceCodeFound || Fortran::lower::isOpenMPTargetConstruct(omp);
- }
+ // Register if a target region was found
+ ompDeviceCodeFound =
+ ompDeviceCodeFound || Fortran::lower::isOpenMPTargetConstruct(omp);
+}
- void genFIR(const Fortran::parser::OpenMPDeclarativeConstruct &ompDecl) {
- mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
- // Register if a declare target construct intended for a target device was
- // found
- ompDeviceCodeFound =
- ompDeviceCodeFound ||
- Fortran::lower::isOpenMPDeviceDeclareTarget(*this, getEval(), ompDecl);
- genOpenMPDeclarativeConstruct(*this, getEval(), ompDecl);
- for (Fortran::lower::pft::Evaluation &e : getEval().getNestedEvaluations())
- genFIR(e);
- builder->restoreInsertionPoint(insertPt);
- }
+void FirConverter::genFIR(
+ const Fortran::parser::OpenMPDeclarativeConstruct &ompDecl) {
+ mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
+ // Register if a declare target construct intended for a target device was
+ // found
+ ompDeviceCodeFound =
+ ompDeviceCodeFound ||
+ Fortran::lower::isOpenMPDeviceDeclareTarget(*this, getEval(), ompDecl);
+ genOpenMPDeclarativeConstruct(*this, getEval(), ompDecl);
+ for (Fortran::lower::pft::Evaluation &e : getEval().getNestedEvaluations())
+ genFIR(e);
+ builder->restoreInsertionPoint(insertPt);
+}
- /// Generate FIR for a SELECT CASE statement.
- /// The selector may have CHARACTER, INTEGER, or LOGICAL type.
- void genFIR(const Fortran::parser::SelectCaseStmt &stmt) {
- Fortran::lower::pft::Evaluation &eval = getEval();
- Fortran::lower::pft::Evaluation *parentConstruct = eval.parentConstruct;
- assert(!activeConstructStack.empty() &&
- &activeConstructStack.back().eval == parentConstruct &&
- "select case construct is not active");
- Fortran::lower::StatementContext &stmtCtx =
- activeConstructStack.back().stmtCtx;
- const Fortran::lower::SomeExpr *expr = Fortran::semantics::GetExpr(
- std::get<Fortran::parser::Scalar<Fortran::parser::Expr>>(stmt.t));
- bool isCharSelector = isCharacterCategory(expr->GetType()->category());
- bool isLogicalSelector = isLogicalCategory(expr->GetType()->category());
- mlir::MLIRContext *context = builder->getContext();
- mlir::Location loc = toLocation();
- auto charValue = [&](const Fortran::lower::SomeExpr *expr) {
- fir::ExtendedValue exv = genExprAddr(*expr, stmtCtx, &loc);
- return exv.match(
- [&](const fir::CharBoxValue &cbv) {
- return fir::factory::CharacterExprHelper{*builder, loc}
- .createEmboxChar(cbv.getAddr(), cbv.getLen());
- },
- [&](auto) {
- fir::emitFatalError(loc, "not a character");
- return mlir::Value{};
- });
- };
- mlir::Value selector;
- if (isCharSelector) {
- selector = charValue(expr);
- } else {
- selector = createFIRExpr(loc, expr, stmtCtx);
- if (isLogicalSelector)
- selector = builder->createConvert(loc, builder->getI1Type(), selector);
+/// Generate FIR for a SELECT CASE statement.
+/// The selector may have CHARACTER, INTEGER, or LOGICAL type.
+void FirConverter::genFIR(const Fortran::parser::SelectCaseStmt &stmt) {
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ Fortran::lower::pft::Evaluation *parentConstruct = eval.parentConstruct;
+ assert(!activeConstructStack.empty() &&
+ &activeConstructStack.back().eval == parentConstruct &&
+ "select case construct is not active");
+ Fortran::lower::StatementContext &stmtCtx =
+ activeConstructStack.back().stmtCtx;
+ const Fortran::lower::SomeExpr *expr = Fortran::semantics::GetExpr(
+ std::get<Fortran::parser::Scalar<Fortran::parser::Expr>>(stmt.t));
+ bool isCharSelector = isCharacterCategory(expr->GetType()->category());
+ bool isLogicalSelector = isLogicalCategory(expr->GetType()->category());
+ mlir::MLIRContext *context = builder->getContext();
+ mlir::Location loc = toLocation();
+ auto charValue = [&](const Fortran::lower::SomeExpr *expr) {
+ fir::ExtendedValue exv = genExprAddr(*expr, stmtCtx, &loc);
+ return exv.match(
+ [&](const fir::CharBoxValue &cbv) {
+ return fir::factory::CharacterExprHelper{*builder, loc}
+ .createEmboxChar(cbv.getAddr(), cbv.getLen());
+ },
+ [&](auto) {
+ fir::emitFatalError(loc, "not a character");
+ return mlir::Value{};
+ });
+ };
+ mlir::Value selector;
+ if (isCharSelector) {
+ selector = charValue(expr);
+ } else {
+ selector = createFIRExpr(loc, expr, stmtCtx);
+ if (isLogicalSelector)
+ selector = builder->createConvert(loc, builder->getI1Type(), selector);
+ }
+ mlir::Type selectType = selector.getType();
+ llvm::SmallVector<mlir::Attribute> attrList;
+ llvm::SmallVector<mlir::Value> valueList;
+ llvm::SmallVector<mlir::Block *> blockList;
+ mlir::Block *defaultBlock = parentConstruct->constructExit->block;
+ using CaseValue = Fortran::parser::Scalar<Fortran::parser::ConstantExpr>;
+ auto addValue = [&](const CaseValue &caseValue) {
+ const Fortran::lower::SomeExpr *expr =
+ Fortran::semantics::GetExpr(caseValue.thing);
+ if (isCharSelector)
+ valueList.push_back(charValue(expr));
+ else if (isLogicalSelector)
+ valueList.push_back(builder->createConvert(
+ loc, selectType, createFIRExpr(toLocation(), expr, stmtCtx)));
+ else
+ valueList.push_back(builder->createIntegerConstant(
+ loc, selectType, *Fortran::evaluate::ToInt64(*expr)));
+ };
+ for (Fortran::lower::pft::Evaluation *e = eval.controlSuccessor; e;
+ e = e->controlSuccessor) {
+ const auto &caseStmt = e->getIf<Fortran::parser::CaseStmt>();
+ assert(e->block && "missing CaseStmt block");
+ const auto &caseSelector =
+ std::get<Fortran::parser::CaseSelector>(caseStmt->t);
+ const auto *caseValueRangeList =
+ std::get_if<std::list<Fortran::parser::CaseValueRange>>(
+ &caseSelector.u);
+ if (!caseValueRangeList) {
+ defaultBlock = e->block;
+ continue;
}
- mlir::Type selectType = selector.getType();
- llvm::SmallVector<mlir::Attribute> attrList;
- llvm::SmallVector<mlir::Value> valueList;
- llvm::SmallVector<mlir::Block *> blockList;
- mlir::Block *defaultBlock = parentConstruct->constructExit->block;
- using CaseValue = Fortran::parser::Scalar<Fortran::parser::ConstantExpr>;
- auto addValue = [&](const CaseValue &caseValue) {
- const Fortran::lower::SomeExpr *expr =
- Fortran::semantics::GetExpr(caseValue.thing);
- if (isCharSelector)
- valueList.push_back(charValue(expr));
- else if (isLogicalSelector)
- valueList.push_back(builder->createConvert(
- loc, selectType, createFIRExpr(toLocation(), expr, stmtCtx)));
- else
- valueList.push_back(builder->createIntegerConstant(
- loc, selectType, *Fortran::evaluate::ToInt64(*expr)));
- };
- for (Fortran::lower::pft::Evaluation *e = eval.controlSuccessor; e;
- e = e->controlSuccessor) {
- const auto &caseStmt = e->getIf<Fortran::parser::CaseStmt>();
- assert(e->block && "missing CaseStmt block");
- const auto &caseSelector =
- std::get<Fortran::parser::CaseSelector>(caseStmt->t);
- const auto *caseValueRangeList =
- std::get_if<std::list<Fortran::parser::CaseValueRange>>(
- &caseSelector.u);
- if (!caseValueRangeList) {
- defaultBlock = e->block;
+ for (const Fortran::parser::CaseValueRange &caseValueRange :
+ *caseValueRangeList) {
+ blockList.push_back(e->block);
+ if (const auto *caseValue = std::get_if<CaseValue>(&caseValueRange.u)) {
+ attrList.push_back(fir::PointIntervalAttr::get(context));
+ addValue(*caseValue);
continue;
}
- for (const Fortran::parser::CaseValueRange &caseValueRange :
- *caseValueRangeList) {
- blockList.push_back(e->block);
- if (const auto *caseValue = std::get_if<CaseValue>(&caseValueRange.u)) {
- attrList.push_back(fir::PointIntervalAttr::get(context));
- addValue(*caseValue);
- continue;
- }
- const auto &caseRange =
- std::get<Fortran::parser::CaseValueRange::Range>(caseValueRange.u);
- if (caseRange.lower && caseRange.upper) {
- attrList.push_back(fir::ClosedIntervalAttr::get(context));
- addValue(*caseRange.lower);
- addValue(*caseRange.upper);
- } else if (caseRange.lower) {
- attrList.push_back(fir::LowerBoundAttr::get(context));
- addValue(*caseRange.lower);
- } else {
- attrList.push_back(fir::UpperBoundAttr::get(context));
- addValue(*caseRange.upper);
- }
+ const auto &caseRange =
+ std::get<Fortran::parser::CaseValueRange::Range>(caseValueRange.u);
+ if (caseRange.lower && caseRange.upper) {
+ attrList.push_back(fir::ClosedIntervalAttr::get(context));
+ addValue(*caseRange.lower);
+ addValue(*caseRange.upper);
+ } else if (caseRange.lower) {
+ attrList.push_back(fir::LowerBoundAttr::get(context));
+ addValue(*caseRange.lower);
+ } else {
+ attrList.push_back(fir::UpperBoundAttr::get(context));
+ addValue(*caseRange.upper);
}
}
- // Skip a logical default block that can never be referenced.
- if (isLogicalSelector && attrList.size() == 2)
- defaultBlock = parentConstruct->constructExit->block;
- attrList.push_back(mlir::UnitAttr::get(context));
- blockList.push_back(defaultBlock);
+ }
+ // Skip a logical default block that can never be referenced.
+ if (isLogicalSelector && attrList.size() == 2)
+ defaultBlock = parentConstruct->constructExit->block;
+ attrList.push_back(mlir::UnitAttr::get(context));
+ blockList.push_back(defaultBlock);
+
+ // Generate a fir::SelectCaseOp. Explicit branch code is better for the
+ // LOGICAL type. The CHARACTER type does not have downstream SelectOp
+ // support. The -no-structured-fir option can be used to force generation
+ // of INTEGER type branch code.
+ if (!isLogicalSelector && !isCharSelector &&
+ !getEval().forceAsUnstructured()) {
+ // The selector is in an ssa register. Any temps that may have been
+ // generated while evaluating it can be cleaned up now.
+ stmtCtx.finalizeAndReset();
+ builder->create<fir::SelectCaseOp>(loc, selector, attrList, valueList,
+ blockList);
+ return;
+ }
- // Generate a fir::SelectCaseOp. Explicit branch code is better for the
- // LOGICAL type. The CHARACTER type does not have downstream SelectOp
- // support. The -no-structured-fir option can be used to force generation
- // of INTEGER type branch code.
- if (!isLogicalSelector && !isCharSelector &&
- !getEval().forceAsUnstructured()) {
- // The selector is in an ssa register. Any temps that may have been
- // generated while evaluating it can be cleaned up now.
- stmtCtx.finalizeAndReset();
- builder->create<fir::SelectCaseOp>(loc, selector, attrList, valueList,
- blockList);
- return;
+ // Generate a sequence of case value comparisons and branches.
+ auto caseValue = valueList.begin();
+ auto caseBlock = blockList.begin();
+ for (mlir::Attribute attr : attrList) {
+ if (attr.isa<mlir::UnitAttr>()) {
+ genBranch(*caseBlock++);
+ break;
}
-
- // Generate a sequence of case value comparisons and branches.
- auto caseValue = valueList.begin();
- auto caseBlock = blockList.begin();
- for (mlir::Attribute attr : attrList) {
- if (attr.isa<mlir::UnitAttr>()) {
- genBranch(*caseBlock++);
- break;
- }
- auto genCond = [&](mlir::Value rhs,
- mlir::arith::CmpIPredicate pred) -> mlir::Value {
- if (!isCharSelector)
- return builder->create<mlir::arith::CmpIOp>(loc, pred, selector, rhs);
- fir::factory::CharacterExprHelper charHelper{*builder, loc};
- std::pair<mlir::Value, mlir::Value> lhsVal =
- charHelper.createUnboxChar(selector);
- std::pair<mlir::Value, mlir::Value> rhsVal =
- charHelper.createUnboxChar(rhs);
- return fir::runtime::genCharCompare(*builder, loc, pred, lhsVal.first,
- lhsVal.second, rhsVal.first,
- rhsVal.second);
- };
- mlir::Block *newBlock = insertBlock(*caseBlock);
- if (attr.isa<fir::ClosedIntervalAttr>()) {
- mlir::Block *newBlock2 = insertBlock(*caseBlock);
- mlir::Value cond =
- genCond(*caseValue++, mlir::arith::CmpIPredicate::sge);
- genConditionalBranch(cond, newBlock, newBlock2);
- builder->setInsertionPointToEnd(newBlock);
- mlir::Value cond2 =
- genCond(*caseValue++, mlir::arith::CmpIPredicate::sle);
- genConditionalBranch(cond2, *caseBlock++, newBlock2);
- builder->setInsertionPointToEnd(newBlock2);
- continue;
- }
- mlir::arith::CmpIPredicate pred;
- if (attr.isa<fir::PointIntervalAttr>()) {
- pred = mlir::arith::CmpIPredicate::eq;
- } else if (attr.isa<fir::LowerBoundAttr>()) {
- pred = mlir::arith::CmpIPredicate::sge;
- } else {
- assert(attr.isa<fir::UpperBoundAttr>() && "unexpected predicate");
- pred = mlir::arith::CmpIPredicate::sle;
- }
- mlir::Value cond = genCond(*caseValue++, pred);
- genConditionalBranch(cond, *caseBlock++, newBlock);
+ auto genCond = [&](mlir::Value rhs,
+ mlir::arith::CmpIPredicate pred) -> mlir::Value {
+ if (!isCharSelector)
+ return builder->create<mlir::arith::CmpIOp>(loc, pred, selector, rhs);
+ fir::factory::CharacterExprHelper charHelper{*builder, loc};
+ std::pair<mlir::Value, mlir::Value> lhsVal =
+ charHelper.createUnboxChar(selector);
+ std::pair<mlir::Value, mlir::Value> rhsVal =
+ charHelper.createUnboxChar(rhs);
+ return fir::runtime::genCharCompare(*builder, loc, pred, lhsVal.first,
+ lhsVal.second, rhsVal.first,
+ rhsVal.second);
+ };
+ mlir::Block *newBlock = insertBlock(*caseBlock);
+ if (attr.isa<fir::ClosedIntervalAttr>()) {
+ mlir::Block *newBlock2 = insertBlock(*caseBlock);
+ mlir::Value cond = genCond(*caseValue++, mlir::arith::CmpIPredicate::sge);
+ genConditionalBranch(cond, newBlock, newBlock2);
builder->setInsertionPointToEnd(newBlock);
+ mlir::Value cond2 =
+ genCond(*caseValue++, mlir::arith::CmpIPredicate::sle);
+ genConditionalBranch(cond2, *caseBlock++, newBlock2);
+ builder->setInsertionPointToEnd(newBlock2);
+ continue;
+ }
+ mlir::arith::CmpIPredicate pred;
+ if (attr.isa<fir::PointIntervalAttr>()) {
+ pred = mlir::arith::CmpIPredicate::eq;
+ } else if (attr.isa<fir::LowerBoundAttr>()) {
+ pred = mlir::arith::CmpIPredicate::sge;
+ } else {
+ assert(attr.isa<fir::UpperBoundAttr>() && "unexpected predicate");
+ pred = mlir::arith::CmpIPredicate::sle;
}
- assert(caseValue == valueList.end() && caseBlock == blockList.end() &&
- "select case list mismatch");
+ mlir::Value cond = genCond(*caseValue++, pred);
+ genConditionalBranch(cond, *caseBlock++, newBlock);
+ builder->setInsertionPointToEnd(newBlock);
}
+ assert(caseValue == valueList.end() && caseBlock == blockList.end() &&
+ "select case list mismatch");
+}
- fir::ExtendedValue
- genAssociateSelector(const Fortran::lower::SomeExpr &selector,
- Fortran::lower::StatementContext &stmtCtx) {
- if (lowerToHighLevelFIR())
- return genExprAddr(selector, stmtCtx);
- return Fortran::lower::isArraySectionWithoutVectorSubscript(selector)
- ? Fortran::lower::createSomeArrayBox(*this, selector,
- localSymbols, stmtCtx)
- : genExprAddr(selector, stmtCtx);
- }
+fir::ExtendedValue
+FirConverter::genAssociateSelector(const Fortran::lower::SomeExpr &selector,
+ Fortran::lower::StatementContext &stmtCtx) {
+ if (lowerToHighLevelFIR())
+ return genExprAddr(selector, stmtCtx);
+ return Fortran::lower::isArraySectionWithoutVectorSubscript(selector)
+ ? Fortran::lower::createSomeArrayBox(*this, selector, localSymbols,
+ stmtCtx)
+ : genExprAddr(selector, stmtCtx);
+}
- void genFIR(const Fortran::parser::AssociateConstruct &) {
- Fortran::lower::pft::Evaluation &eval = getEval();
- Fortran::lower::StatementContext stmtCtx;
- pushActiveConstruct(eval, stmtCtx);
- for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
- if (auto *stmt = e.getIf<Fortran::parser::AssociateStmt>()) {
- if (eval.lowerAsUnstructured())
- maybeStartBlock(e.block);
- localSymbols.pushScope();
- for (const Fortran::parser::Association &assoc :
- std::get<std::list<Fortran::parser::Association>>(stmt->t)) {
- Fortran::semantics::Symbol &sym =
- *std::get<Fortran::parser::Name>(assoc.t).symbol;
- const Fortran::lower::SomeExpr &selector =
- *sym.get<Fortran::semantics::AssocEntityDetails>().expr();
- addSymbol(sym, genAssociateSelector(selector, stmtCtx));
- }
- } else if (e.getIf<Fortran::parser::EndAssociateStmt>()) {
- if (eval.lowerAsUnstructured())
- maybeStartBlock(e.block);
- localSymbols.popScope();
- } else {
- genFIR(e);
+void FirConverter::genFIR(const Fortran::parser::AssociateConstruct &) {
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ Fortran::lower::StatementContext stmtCtx;
+ pushActiveConstruct(eval, stmtCtx);
+ for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
+ if (auto *stmt = e.getIf<Fortran::parser::AssociateStmt>()) {
+ if (eval.lowerAsUnstructured())
+ maybeStartBlock(e.block);
+ localSymbols.pushScope();
+ for (const Fortran::parser::Association &assoc :
+ std::get<std::list<Fortran::parser::Association>>(stmt->t)) {
+ Fortran::semantics::Symbol &sym =
+ *std::get<Fortran::parser::Name>(assoc.t).symbol;
+ const Fortran::lower::SomeExpr &selector =
+ *sym.get<Fortran::semantics::AssocEntityDetails>().expr();
+ addSymbol(sym, genAssociateSelector(selector, stmtCtx));
}
+ } else if (e.getIf<Fortran::parser::EndAssociateStmt>()) {
+ if (eval.lowerAsUnstructured())
+ maybeStartBlock(e.block);
+ localSymbols.popScope();
+ } else {
+ genFIR(e);
}
- popActiveConstruct();
}
+ popActiveConstruct();
+}
- void genFIR(const Fortran::parser::BlockConstruct &blockConstruct) {
- Fortran::lower::pft::Evaluation &eval = getEval();
- Fortran::lower::StatementContext stmtCtx;
- pushActiveConstruct(eval, stmtCtx);
- for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
- if (e.getIf<Fortran::parser::BlockStmt>()) {
- if (eval.lowerAsUnstructured())
- maybeStartBlock(e.block);
- setCurrentPosition(e.position);
- const Fortran::parser::CharBlock &endPosition =
- eval.getLastNestedEvaluation().position;
- localSymbols.pushScope();
- mlir::func::FuncOp stackSave = fir::factory::getLlvmStackSave(*builder);
- mlir::func::FuncOp stackRestore =
- fir::factory::getLlvmStackRestore(*builder);
- mlir::Value stackPtr =
- builder->create<fir::CallOp>(toLocation(), stackSave).getResult(0);
- mlir::Location endLoc = genLocation(endPosition);
- stmtCtx.attachCleanup([=]() {
- builder->create<fir::CallOp>(endLoc, stackRestore, stackPtr);
- });
- Fortran::semantics::Scope &scope =
- bridge.getSemanticsContext().FindScope(endPosition);
- scopeBlockIdMap.try_emplace(&scope, ++blockId);
- Fortran::lower::AggregateStoreMap storeMap;
- for (const Fortran::lower::pft::Variable &var :
- Fortran::lower::pft::getScopeVariableList(scope)) {
- // Do no instantiate again variables from the block host
- // that appears in specification of block variables.
- if (!var.hasSymbol() || !lookupSymbol(var.getSymbol()))
- instantiateVar(var, storeMap);
- }
- } else if (e.getIf<Fortran::parser::EndBlockStmt>()) {
- if (eval.lowerAsUnstructured())
- maybeStartBlock(e.block);
- setCurrentPosition(e.position);
- localSymbols.popScope();
- } else {
- genFIR(e);
+void FirConverter::genFIR(
+ const Fortran::parser::BlockConstruct &blockConstruct) {
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ Fortran::lower::StatementContext stmtCtx;
+ pushActiveConstruct(eval, stmtCtx);
+ for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
+ if (e.getIf<Fortran::parser::BlockStmt>()) {
+ if (eval.lowerAsUnstructured())
+ maybeStartBlock(e.block);
+ setCurrentPosition(e.position);
+ const Fortran::parser::CharBlock &endPosition =
+ eval.getLastNestedEvaluation().position;
+ localSymbols.pushScope();
+ mlir::func::FuncOp stackSave = fir::factory::getLlvmStackSave(*builder);
+ mlir::func::FuncOp stackRestore =
+ fir::factory::getLlvmStackRestore(*builder);
+ mlir::Value stackPtr =
+ builder->create<fir::CallOp>(toLocation(), stackSave).getResult(0);
+ mlir::Location endLoc = genLocation(endPosition);
+ stmtCtx.attachCleanup([=]() {
+ builder->create<fir::CallOp>(endLoc, stackRestore, stackPtr);
+ });
+ Fortran::semantics::Scope &scope =
+ bridge.getSemanticsContext().FindScope(endPosition);
+ scopeBlockIdMap.try_emplace(&scope, ++blockId);
+ Fortran::lower::AggregateStoreMap storeMap;
+ for (const Fortran::lower::pft::Variable &var :
+ Fortran::lower::pft::getScopeVariableList(scope)) {
+ // Do no instantiate again variables from the block host
+ // that appears in specification of block variables.
+ if (!var.hasSymbol() || !lookupSymbol(var.getSymbol()))
+ instantiateVar(var, storeMap);
}
+ } else if (e.getIf<Fortran::parser::EndBlockStmt>()) {
+ if (eval.lowerAsUnstructured())
+ maybeStartBlock(e.block);
+ setCurrentPosition(e.position);
+ localSymbols.popScope();
+ } else {
+ genFIR(e);
}
- popActiveConstruct();
- }
-
- void genFIR(const Fortran::parser::ChangeTeamConstruct &construct) {
- TODO(toLocation(), "coarray: ChangeTeamConstruct");
- }
- void genFIR(const Fortran::parser::ChangeTeamStmt &stmt) {
- TODO(toLocation(), "coarray: ChangeTeamStmt");
- }
- void genFIR(const Fortran::parser::EndChangeTeamStmt &stmt) {
- TODO(toLocation(), "coarray: EndChangeTeamStmt");
- }
-
- void genFIR(const Fortran::parser::CriticalConstruct &criticalConstruct) {
- setCurrentPositionAt(criticalConstruct);
- TODO(toLocation(), "coarray: CriticalConstruct");
- }
- void genFIR(const Fortran::parser::CriticalStmt &) {
- TODO(toLocation(), "coarray: CriticalStmt");
- }
- void genFIR(const Fortran::parser::EndCriticalStmt &) {
- TODO(toLocation(), "coarray: EndCriticalStmt");
}
+ popActiveConstruct();
+}
- void genFIR(const Fortran::parser::SelectRankConstruct &selectRankConstruct) {
- setCurrentPositionAt(selectRankConstruct);
- TODO(toLocation(), "coarray: SelectRankConstruct");
- }
- void genFIR(const Fortran::parser::SelectRankStmt &) {
- TODO(toLocation(), "coarray: SelectRankStmt");
- }
- void genFIR(const Fortran::parser::SelectRankCaseStmt &) {
- TODO(toLocation(), "coarray: SelectRankCaseStmt");
- }
+void FirConverter::genFIR(
+ const Fortran::parser::ChangeTeamConstruct &construct) {
+ TODO(toLocation(), "coarray: ChangeTeamConstruct");
+}
+void FirConverter::genFIR(const Fortran::parser::ChangeTeamStmt &stmt) {
+ TODO(toLocation(), "coarray: ChangeTeamStmt");
+}
+void FirConverter::genFIR(const Fortran::parser::EndChangeTeamStmt &stmt) {
+ TODO(toLocation(), "coarray: EndChangeTeamStmt");
+}
- void genFIR(const Fortran::parser::SelectTypeConstruct &selectTypeConstruct) {
- mlir::Location loc = toLocation();
- mlir::MLIRContext *context = builder->getContext();
- Fortran::lower::StatementContext stmtCtx;
- fir::ExtendedValue selector;
- llvm::SmallVector<mlir::Attribute> attrList;
- llvm::SmallVector<mlir::Block *> blockList;
- unsigned typeGuardIdx = 0;
- std::size_t defaultAttrPos = std::numeric_limits<size_t>::max();
- bool hasLocalScope = false;
- llvm::SmallVector<const Fortran::semantics::Scope *> typeCaseScopes;
-
- const auto &typeCaseList =
- std::get<std::list<Fortran::parser::SelectTypeConstruct::TypeCase>>(
- selectTypeConstruct.t);
- for (const auto &typeCase : typeCaseList) {
- const auto &stmt =
- std::get<Fortran::parser::Statement<Fortran::parser::TypeGuardStmt>>(
- typeCase.t);
- const Fortran::semantics::Scope &scope =
- bridge.getSemanticsContext().FindScope(stmt.source);
- typeCaseScopes.push_back(&scope);
- }
+void FirConverter::genFIR(
+ const Fortran::parser::CriticalConstruct &criticalConstruct) {
+ setCurrentPositionAt(criticalConstruct);
+ TODO(toLocation(), "coarray: CriticalConstruct");
+}
+void FirConverter::genFIR(const Fortran::parser::CriticalStmt &) {
+ TODO(toLocation(), "coarray: CriticalStmt");
+}
+void FirConverter::genFIR(const Fortran::parser::EndCriticalStmt &) {
+ TODO(toLocation(), "coarray: EndCriticalStmt");
+}
- pushActiveConstruct(getEval(), stmtCtx);
- for (Fortran::lower::pft::Evaluation &eval :
- getEval().getNestedEvaluations()) {
- if (auto *selectTypeStmt =
- eval.getIf<Fortran::parser::SelectTypeStmt>()) {
- // A genFIR(SelectTypeStmt) call would have unwanted side effects.
- maybeStartBlock(eval.block);
- // Retrieve the selector
- const auto &s = std::get<Fortran::parser::Selector>(selectTypeStmt->t);
- if (const auto *v = std::get_if<Fortran::parser::Variable>(&s.u))
- selector = genExprBox(loc, *Fortran::semantics::GetExpr(*v), stmtCtx);
- else if (const auto *e = std::get_if<Fortran::parser::Expr>(&s.u))
- selector = genExprBox(loc, *Fortran::semantics::GetExpr(*e), stmtCtx);
-
- // Going through the controlSuccessor first to create the
- // fir.select_type operation.
- mlir::Block *defaultBlock = eval.parentConstruct->constructExit->block;
- for (Fortran::lower::pft::Evaluation *e = eval.controlSuccessor; e;
- e = e->controlSuccessor) {
- const auto &typeGuardStmt =
- e->getIf<Fortran::parser::TypeGuardStmt>();
- const auto &guard =
- std::get<Fortran::parser::TypeGuardStmt::Guard>(typeGuardStmt->t);
- assert(e->block && "missing TypeGuardStmt block");
- // CLASS DEFAULT
- if (std::holds_alternative<Fortran::parser::Default>(guard.u)) {
- defaultBlock = e->block;
- // Keep track of the actual position of the CLASS DEFAULT type guard
- // in the SELECT TYPE construct.
- defaultAttrPos = attrList.size();
- continue;
- }
+void FirConverter::genFIR(
+ const Fortran::parser::SelectRankConstruct &selectRankConstruct) {
+ setCurrentPositionAt(selectRankConstruct);
+ TODO(toLocation(), "coarray: SelectRankConstruct");
+}
+void FirConverter::genFIR(const Fortran::parser::SelectRankStmt &) {
+ TODO(toLocation(), "coarray: SelectRankStmt");
+}
+void FirConverter::genFIR(const Fortran::parser::SelectRankCaseStmt &) {
+ TODO(toLocation(), "coarray: SelectRankCaseStmt");
+}
- blockList.push_back(e->block);
- if (const auto *typeSpec =
- std::get_if<Fortran::parser::TypeSpec>(&guard.u)) {
- // TYPE IS
- mlir::Type ty;
- if (std::holds_alternative<Fortran::parser::IntrinsicTypeSpec>(
- typeSpec->u)) {
- const Fortran::semantics::IntrinsicTypeSpec *intrinsic =
- typeSpec->declTypeSpec->AsIntrinsic();
- int kind =
- Fortran::evaluate::ToInt64(intrinsic->kind()).value_or(kind);
- llvm::SmallVector<Fortran::lower::LenParameterTy> params;
- ty = genType(intrinsic->category(), kind, params);
- } else {
- const Fortran::semantics::DerivedTypeSpec *derived =
- typeSpec->declTypeSpec->AsDerived();
- ty = genType(*derived);
- }
- attrList.push_back(fir::ExactTypeAttr::get(ty));
- } else if (const auto *derived =
- std::get_if<Fortran::parser::DerivedTypeSpec>(
- &guard.u)) {
- // CLASS IS
- assert(derived->derivedTypeSpec && "derived type spec is null");
- mlir::Type ty = genType(*(derived->derivedTypeSpec));
- attrList.push_back(fir::SubclassAttr::get(ty));
- }
- }
- attrList.push_back(mlir::UnitAttr::get(context));
- blockList.push_back(defaultBlock);
- builder->create<fir::SelectTypeOp>(loc, fir::getBase(selector),
- attrList, blockList);
-
- // If the actual position of CLASS DEFAULT type guard is not the last
- // one, it needs to be put back at its correct position for the rest of
- // the processing. TypeGuardStmt are processed in the same order they
- // appear in the Fortran code.
- if (defaultAttrPos < attrList.size() - 1) {
- auto attrIt = attrList.begin();
- attrIt = attrIt + defaultAttrPos;
- auto blockIt = blockList.begin();
- blockIt = blockIt + defaultAttrPos;
- attrList.insert(attrIt, mlir::UnitAttr::get(context));
- blockList.insert(blockIt, defaultBlock);
- attrList.pop_back();
- blockList.pop_back();
- }
- } else if (auto *typeGuardStmt =
- eval.getIf<Fortran::parser::TypeGuardStmt>()) {
- // Map the type guard local symbol for the selector to a more precise
- // typed entity in the TypeGuardStmt when necessary.
- genFIR(eval);
+void FirConverter::genFIR(
+ const Fortran::parser::SelectTypeConstruct &selectTypeConstruct) {
+ mlir::Location loc = toLocation();
+ mlir::MLIRContext *context = builder->getContext();
+ Fortran::lower::StatementContext stmtCtx;
+ fir::ExtendedValue selector;
+ llvm::SmallVector<mlir::Attribute> attrList;
+ llvm::SmallVector<mlir::Block *> blockList;
+ unsigned typeGuardIdx = 0;
+ std::size_t defaultAttrPos = std::numeric_limits<size_t>::max();
+ bool hasLocalScope = false;
+ llvm::SmallVector<const Fortran::semantics::Scope *> typeCaseScopes;
+
+ const auto &typeCaseList =
+ std::get<std::list<Fortran::parser::SelectTypeConstruct::TypeCase>>(
+ selectTypeConstruct.t);
+ for (const auto &typeCase : typeCaseList) {
+ const auto &stmt =
+ std::get<Fortran::parser::Statement<Fortran::parser::TypeGuardStmt>>(
+ typeCase.t);
+ const Fortran::semantics::Scope &scope =
+ bridge.getSemanticsContext().FindScope(stmt.source);
+ typeCaseScopes.push_back(&scope);
+ }
+
+ pushActiveConstruct(getEval(), stmtCtx);
+ for (Fortran::lower::pft::Evaluation &eval :
+ getEval().getNestedEvaluations()) {
+ if (auto *selectTypeStmt = eval.getIf<Fortran::parser::SelectTypeStmt>()) {
+ // A genFIR(SelectTypeStmt) call would have unwanted side effects.
+ maybeStartBlock(eval.block);
+ // Retrieve the selector
+ const auto &s = std::get<Fortran::parser::Selector>(selectTypeStmt->t);
+ if (const auto *v = std::get_if<Fortran::parser::Variable>(&s.u))
+ selector = genExprBox(loc, *Fortran::semantics::GetExpr(*v), stmtCtx);
+ else if (const auto *e = std::get_if<Fortran::parser::Expr>(&s.u))
+ selector = genExprBox(loc, *Fortran::semantics::GetExpr(*e), stmtCtx);
+
+ // Going through the controlSuccessor first to create the
+ // fir.select_type operation.
+ mlir::Block *defaultBlock = eval.parentConstruct->constructExit->block;
+ for (Fortran::lower::pft::Evaluation *e = eval.controlSuccessor; e;
+ e = e->controlSuccessor) {
+ const auto &typeGuardStmt = e->getIf<Fortran::parser::TypeGuardStmt>();
const auto &guard =
- std::get<Fortran::parser::TypeGuardStmt::Guard>(typeGuardStmt->t);
- if (hasLocalScope)
- localSymbols.popScope();
- localSymbols.pushScope();
- hasLocalScope = true;
- assert(attrList.size() >= typeGuardIdx &&
- "TypeGuard attribute missing");
- mlir::Attribute typeGuardAttr = attrList[typeGuardIdx];
- mlir::Block *typeGuardBlock = blockList[typeGuardIdx];
- mlir::OpBuilder::InsertPoint crtInsPt = builder->saveInsertionPoint();
- builder->setInsertionPointToStart(typeGuardBlock);
-
- auto addAssocEntitySymbol = [&](fir::ExtendedValue exv) {
- for (auto &symbol : typeCaseScopes[typeGuardIdx]->GetSymbols()) {
- if (symbol->GetUltimate()
- .detailsIf<Fortran::semantics::AssocEntityDetails>()) {
- addSymbol(symbol, exv);
- break;
- }
- }
- };
-
- mlir::Type baseTy = fir::getBase(selector).getType();
- bool isPointer = fir::isPointerType(baseTy);
- bool isAllocatable = fir::isAllocatableType(baseTy);
- bool isArray =
- fir::dyn_cast_ptrOrBoxEleTy(baseTy).isa<fir::SequenceType>();
- const fir::BoxValue *selectorBox = selector.getBoxOf<fir::BoxValue>();
+ std::get<Fortran::parser::TypeGuardStmt::Guard>(typeGuardStmt->t);
+ assert(e->block && "missing TypeGuardStmt block");
+ // CLASS DEFAULT
if (std::holds_alternative<Fortran::parser::Default>(guard.u)) {
- // CLASS DEFAULT
- addAssocEntitySymbol(selector);
- } else if (const auto *typeSpec =
- std::get_if<Fortran::parser::TypeSpec>(&guard.u)) {
+ defaultBlock = e->block;
+ // Keep track of the actual position of the CLASS DEFAULT type guard
+ // in the SELECT TYPE construct.
+ defaultAttrPos = attrList.size();
+ continue;
+ }
+
+ blockList.push_back(e->block);
+ if (const auto *typeSpec =
+ std::get_if<Fortran::parser::TypeSpec>(&guard.u)) {
// TYPE IS
- fir::ExactTypeAttr attr =
- typeGuardAttr.dyn_cast<fir::ExactTypeAttr>();
- mlir::Value exactValue;
- mlir::Type addrTy = attr.getType();
- if (isArray) {
- auto seqTy = fir::dyn_cast_ptrOrBoxEleTy(baseTy)
- .dyn_cast<fir::SequenceType>();
- addrTy = fir::SequenceType::get(seqTy.getShape(), attr.getType());
- }
- if (isPointer)
- addrTy = fir::PointerType::get(addrTy);
- if (isAllocatable)
- addrTy = fir::HeapType::get(addrTy);
+ mlir::Type ty;
if (std::holds_alternative<Fortran::parser::IntrinsicTypeSpec>(
typeSpec->u)) {
- mlir::Type refTy = fir::ReferenceType::get(addrTy);
- if (isPointer || isAllocatable)
- refTy = addrTy;
- exactValue = builder->create<fir::BoxAddrOp>(
- loc, refTy, fir::getBase(selector));
const Fortran::semantics::IntrinsicTypeSpec *intrinsic =
typeSpec->declTypeSpec->AsIntrinsic();
- if (isArray) {
- mlir::Value exact = builder->create<fir::ConvertOp>(
- loc, fir::BoxType::get(addrTy), fir::getBase(selector));
- addAssocEntitySymbol(selectorBox->clone(exact));
- } else if (intrinsic->category() ==
- Fortran::common::TypeCategory::Character) {
- auto charTy = attr.getType().dyn_cast<fir::CharacterType>();
- mlir::Value charLen =
- fir::factory::CharacterExprHelper(*builder, loc)
- .readLengthFromBox(fir::getBase(selector), charTy);
- addAssocEntitySymbol(fir::CharBoxValue(exactValue, charLen));
- } else {
- addAssocEntitySymbol(exactValue);
- }
- } else if (std::holds_alternative<Fortran::parser::DerivedTypeSpec>(
- typeSpec->u)) {
- exactValue = builder->create<fir::ConvertOp>(
- loc, fir::BoxType::get(addrTy), fir::getBase(selector));
- addAssocEntitySymbol(selectorBox->clone(exactValue));
+ int kind =
+ Fortran::evaluate::ToInt64(intrinsic->kind()).value_or(kind);
+ llvm::SmallVector<Fortran::lower::LenParameterTy> params;
+ ty = genType(intrinsic->category(), kind, params);
+ } else {
+ const Fortran::semantics::DerivedTypeSpec *derived =
+ typeSpec->declTypeSpec->AsDerived();
+ ty = genType(*derived);
}
- } else if (std::holds_alternative<Fortran::parser::DerivedTypeSpec>(
- guard.u)) {
+ attrList.push_back(fir::ExactTypeAttr::get(ty));
+ } else if (const auto *derived =
+ std::get_if<Fortran::parser::DerivedTypeSpec>(
+ &guard.u)) {
// CLASS IS
- fir::SubclassAttr attr = typeGuardAttr.dyn_cast<fir::SubclassAttr>();
- mlir::Type addrTy = attr.getType();
- if (isArray) {
- auto seqTy = fir::dyn_cast_ptrOrBoxEleTy(baseTy)
- .dyn_cast<fir::SequenceType>();
- addrTy = fir::SequenceType::get(seqTy.getShape(), attr.getType());
+ assert(derived->derivedTypeSpec && "derived type spec is null");
+ mlir::Type ty = genType(*(derived->derivedTypeSpec));
+ attrList.push_back(fir::SubclassAttr::get(ty));
+ }
+ }
+ attrList.push_back(mlir::UnitAttr::get(context));
+ blockList.push_back(defaultBlock);
+ builder->create<fir::SelectTypeOp>(loc, fir::getBase(selector), attrList,
+ blockList);
+
+ // If the actual position of CLASS DEFAULT type guard is not the last
+ // one, it needs to be put back at its correct position for the rest of
+ // the processing. TypeGuardStmt are processed in the same order they
+ // appear in the Fortran code.
+ if (defaultAttrPos < attrList.size() - 1) {
+ auto attrIt = attrList.begin();
+ attrIt = attrIt + defaultAttrPos;
+ auto blockIt = blockList.begin();
+ blockIt = blockIt + defaultAttrPos;
+ attrList.insert(attrIt, mlir::UnitAttr::get(context));
+ blockList.insert(blockIt, defaultBlock);
+ attrList.pop_back();
+ blockList.pop_back();
+ }
+ } else if (auto *typeGuardStmt =
+ eval.getIf<Fortran::parser::TypeGuardStmt>()) {
+ // Map the type guard local symbol for the selector to a more precise
+ // typed entity in the TypeGuardStmt when necessary.
+ genFIR(eval);
+ const auto &guard =
+ std::get<Fortran::parser::TypeGuardStmt::Guard>(typeGuardStmt->t);
+ if (hasLocalScope)
+ localSymbols.popScope();
+ localSymbols.pushScope();
+ hasLocalScope = true;
+ assert(attrList.size() >= typeGuardIdx && "TypeGuard attribute missing");
+ mlir::Attribute typeGuardAttr = attrList[typeGuardIdx];
+ mlir::Block *typeGuardBlock = blockList[typeGuardIdx];
+ mlir::OpBuilder::InsertPoint crtInsPt = builder->saveInsertionPoint();
+ builder->setInsertionPointToStart(typeGuardBlock);
+
+ auto addAssocEntitySymbol = [&](fir::ExtendedValue exv) {
+ for (auto &symbol : typeCaseScopes[typeGuardIdx]->GetSymbols()) {
+ if (symbol->GetUltimate()
+ .detailsIf<Fortran::semantics::AssocEntityDetails>()) {
+ addSymbol(symbol, exv);
+ break;
}
- if (isPointer)
- addrTy = fir::PointerType::get(addrTy);
- if (isAllocatable)
- addrTy = fir::HeapType::get(addrTy);
- mlir::Type classTy = fir::ClassType::get(addrTy);
- if (classTy == baseTy) {
- addAssocEntitySymbol(selector);
+ }
+ };
+
+ mlir::Type baseTy = fir::getBase(selector).getType();
+ bool isPointer = fir::isPointerType(baseTy);
+ bool isAllocatable = fir::isAllocatableType(baseTy);
+ bool isArray =
+ fir::dyn_cast_ptrOrBoxEleTy(baseTy).isa<fir::SequenceType>();
+ const fir::BoxValue *selectorBox = selector.getBoxOf<fir::BoxValue>();
+ if (std::holds_alternative<Fortran::parser::Default>(guard.u)) {
+ // CLASS DEFAULT
+ addAssocEntitySymbol(selector);
+ } else if (const auto *typeSpec =
+ std::get_if<Fortran::parser::TypeSpec>(&guard.u)) {
+ // TYPE IS
+ fir::ExactTypeAttr attr = typeGuardAttr.dyn_cast<fir::ExactTypeAttr>();
+ mlir::Value exactValue;
+ mlir::Type addrTy = attr.getType();
+ if (isArray) {
+ auto seqTy =
+ fir::dyn_cast_ptrOrBoxEleTy(baseTy).dyn_cast<fir::SequenceType>();
+ addrTy = fir::SequenceType::get(seqTy.getShape(), attr.getType());
+ }
+ if (isPointer)
+ addrTy = fir::PointerType::get(addrTy);
+ if (isAllocatable)
+ addrTy = fir::HeapType::get(addrTy);
+ if (std::holds_alternative<Fortran::parser::IntrinsicTypeSpec>(
+ typeSpec->u)) {
+ mlir::Type refTy = fir::ReferenceType::get(addrTy);
+ if (isPointer || isAllocatable)
+ refTy = addrTy;
+ exactValue = builder->create<fir::BoxAddrOp>(loc, refTy,
+ fir::getBase(selector));
+ const Fortran::semantics::IntrinsicTypeSpec *intrinsic =
+ typeSpec->declTypeSpec->AsIntrinsic();
+ if (isArray) {
+ mlir::Value exact = builder->create<fir::ConvertOp>(
+ loc, fir::BoxType::get(addrTy), fir::getBase(selector));
+ addAssocEntitySymbol(selectorBox->clone(exact));
+ } else if (intrinsic->category() ==
+ Fortran::common::TypeCategory::Character) {
+ auto charTy = attr.getType().dyn_cast<fir::CharacterType>();
+ mlir::Value charLen =
+ fir::factory::CharacterExprHelper(*builder, loc)
+ .readLengthFromBox(fir::getBase(selector), charTy);
+ addAssocEntitySymbol(fir::CharBoxValue(exactValue, charLen));
} else {
- mlir::Value derived = builder->create<fir::ConvertOp>(
- loc, classTy, fir::getBase(selector));
- addAssocEntitySymbol(selectorBox->clone(derived));
+ addAssocEntitySymbol(exactValue);
}
+ } else if (std::holds_alternative<Fortran::parser::DerivedTypeSpec>(
+ typeSpec->u)) {
+ exactValue = builder->create<fir::ConvertOp>(
+ loc, fir::BoxType::get(addrTy), fir::getBase(selector));
+ addAssocEntitySymbol(selectorBox->clone(exactValue));
+ }
+ } else if (std::holds_alternative<Fortran::parser::DerivedTypeSpec>(
+ guard.u)) {
+ // CLASS IS
+ fir::SubclassAttr attr = typeGuardAttr.dyn_cast<fir::SubclassAttr>();
+ mlir::Type addrTy = attr.getType();
+ if (isArray) {
+ auto seqTy =
+ fir::dyn_cast_ptrOrBoxEleTy(baseTy).dyn_cast<fir::SequenceType>();
+ addrTy = fir::SequenceType::get(seqTy.getShape(), attr.getType());
+ }
+ if (isPointer)
+ addrTy = fir::PointerType::get(addrTy);
+ if (isAllocatable)
+ addrTy = fir::HeapType::get(addrTy);
+ mlir::Type classTy = fir::ClassType::get(addrTy);
+ if (classTy == baseTy) {
+ addAssocEntitySymbol(selector);
+ } else {
+ mlir::Value derived = builder->create<fir::ConvertOp>(
+ loc, classTy, fir::getBase(selector));
+ addAssocEntitySymbol(selectorBox->clone(derived));
}
- builder->restoreInsertionPoint(crtInsPt);
- ++typeGuardIdx;
- } else if (eval.getIf<Fortran::parser::EndSelectStmt>()) {
- maybeStartBlock(eval.block);
- if (hasLocalScope)
- localSymbols.popScope();
- } else {
- genFIR(eval);
}
+ builder->restoreInsertionPoint(crtInsPt);
+ ++typeGuardIdx;
+ } else if (eval.getIf<Fortran::parser::EndSelectStmt>()) {
+ maybeStartBlock(eval.block);
+ if (hasLocalScope)
+ localSymbols.popScope();
+ } else {
+ genFIR(eval);
}
- popActiveConstruct();
- }
-
- //===--------------------------------------------------------------------===//
- // IO statements (see io.h)
- //===--------------------------------------------------------------------===//
-
- void genFIR(const Fortran::parser::BackspaceStmt &stmt) {
- mlir::Value iostat = genBackspaceStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.v, iostat);
- }
- void genFIR(const Fortran::parser::CloseStmt &stmt) {
- mlir::Value iostat = genCloseStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.v, iostat);
- }
- void genFIR(const Fortran::parser::EndfileStmt &stmt) {
- mlir::Value iostat = genEndfileStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.v, iostat);
- }
- void genFIR(const Fortran::parser::FlushStmt &stmt) {
- mlir::Value iostat = genFlushStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.v, iostat);
- }
- void genFIR(const Fortran::parser::InquireStmt &stmt) {
- mlir::Value iostat = genInquireStatement(*this, stmt);
- if (const auto *specs =
- std::get_if<std::list<Fortran::parser::InquireSpec>>(&stmt.u))
- genIoConditionBranches(getEval(), *specs, iostat);
- }
- void genFIR(const Fortran::parser::OpenStmt &stmt) {
- mlir::Value iostat = genOpenStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.v, iostat);
- }
- void genFIR(const Fortran::parser::PrintStmt &stmt) {
- genPrintStatement(*this, stmt);
- }
- void genFIR(const Fortran::parser::ReadStmt &stmt) {
- mlir::Value iostat = genReadStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.controls, iostat);
- }
- void genFIR(const Fortran::parser::RewindStmt &stmt) {
- mlir::Value iostat = genRewindStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.v, iostat);
- }
- void genFIR(const Fortran::parser::WaitStmt &stmt) {
- mlir::Value iostat = genWaitStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.v, iostat);
}
- void genFIR(const Fortran::parser::WriteStmt &stmt) {
- mlir::Value iostat = genWriteStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.controls, iostat);
- }
-
- template <typename A>
- void genIoConditionBranches(Fortran::lower::pft::Evaluation &eval,
- const A &specList, mlir::Value iostat) {
- if (!iostat)
- return;
+ popActiveConstruct();
+}
- Fortran::parser::Label endLabel{};
- Fortran::parser::Label eorLabel{};
- Fortran::parser::Label errLabel{};
- bool hasIostat{};
- for (const auto &spec : specList) {
- std::visit(
- Fortran::common::visitors{
- [&](const Fortran::parser::EndLabel &label) {
- endLabel = label.v;
- },
- [&](const Fortran::parser::EorLabel &label) {
- eorLabel = label.v;
- },
- [&](const Fortran::parser::ErrLabel &label) {
- errLabel = label.v;
- },
- [&](const Fortran::parser::StatVariable &) { hasIostat = true; },
- [](const auto &) {}},
- spec.u);
- }
- if (!endLabel && !eorLabel && !errLabel)
- return;
+//===--------------------------------------------------------------------===//
+// IO statements (see io.h)
+//===--------------------------------------------------------------------===//
- // An ERR specifier branch is taken on any positive error value rather than
- // some single specific value. If ERR and IOSTAT specifiers are given and
- // END and EOR specifiers are allowed, the latter two specifiers must have
- // explicit branch targets to allow the ERR branch to be implemented as a
- // default/else target. A label=0 target for an absent END or EOR specifier
- // indicates that these specifiers have a fallthrough target. END and EOR
- // specifiers may appear on READ and WAIT statements.
- bool allSpecifiersRequired = errLabel && hasIostat &&
- (eval.isA<Fortran::parser::ReadStmt>() ||
- eval.isA<Fortran::parser::WaitStmt>());
- mlir::Value selector =
- builder->createConvert(toLocation(), builder->getIndexType(), iostat);
- llvm::SmallVector<int64_t> valueList;
- llvm::SmallVector<Fortran::parser::Label> labelList;
- if (eorLabel || allSpecifiersRequired) {
- valueList.push_back(Fortran::runtime::io::IostatEor);
- labelList.push_back(eorLabel ? eorLabel : 0);
- }
- if (endLabel || allSpecifiersRequired) {
- valueList.push_back(Fortran::runtime::io::IostatEnd);
- labelList.push_back(endLabel ? endLabel : 0);
- }
- if (errLabel) {
- // Must be last. Value 0 is interpreted as any positive value, or
- // equivalently as any value other than 0, IostatEor, or IostatEnd.
- valueList.push_back(0);
- labelList.push_back(errLabel);
- }
- genMultiwayBranch(selector, valueList, labelList, eval.nonNopSuccessor());
- }
+void FirConverter::genFIR(const Fortran::parser::BackspaceStmt &stmt) {
+ mlir::Value iostat = genBackspaceStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.v, iostat);
+}
+void FirConverter::genFIR(const Fortran::parser::CloseStmt &stmt) {
+ mlir::Value iostat = genCloseStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.v, iostat);
+}
+void FirConverter::genFIR(const Fortran::parser::EndfileStmt &stmt) {
+ mlir::Value iostat = genEndfileStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.v, iostat);
+}
+void FirConverter::genFIR(const Fortran::parser::FlushStmt &stmt) {
+ mlir::Value iostat = genFlushStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.v, iostat);
+}
+void FirConverter::genFIR(const Fortran::parser::InquireStmt &stmt) {
+ mlir::Value iostat = genInquireStatement(*this, stmt);
+ if (const auto *specs =
+ std::get_if<std::list<Fortran::parser::InquireSpec>>(&stmt.u))
+ genIoConditionBranches(getEval(), *specs, iostat);
+}
+void FirConverter::genFIR(const Fortran::parser::OpenStmt &stmt) {
+ mlir::Value iostat = genOpenStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.v, iostat);
+}
+void FirConverter::genFIR(const Fortran::parser::PrintStmt &stmt) {
+ genPrintStatement(*this, stmt);
+}
+void FirConverter::genFIR(const Fortran::parser::ReadStmt &stmt) {
+ mlir::Value iostat = genReadStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.controls, iostat);
+}
+void FirConverter::genFIR(const Fortran::parser::RewindStmt &stmt) {
+ mlir::Value iostat = genRewindStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.v, iostat);
+}
+void FirConverter::genFIR(const Fortran::parser::WaitStmt &stmt) {
+ mlir::Value iostat = genWaitStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.v, iostat);
+}
+void FirConverter::genFIR(const Fortran::parser::WriteStmt &stmt) {
+ mlir::Value iostat = genWriteStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.controls, iostat);
+}
- //===--------------------------------------------------------------------===//
- // Memory allocation and deallocation
- //===--------------------------------------------------------------------===//
+//===--------------------------------------------------------------------===//
+// Memory allocation and deallocation
+//===--------------------------------------------------------------------===//
- void genFIR(const Fortran::parser::AllocateStmt &stmt) {
- Fortran::lower::genAllocateStmt(*this, stmt, toLocation());
- }
+void FirConverter::genFIR(const Fortran::parser::AllocateStmt &stmt) {
+ Fortran::lower::genAllocateStmt(*this, stmt, toLocation());
+}
- void genFIR(const Fortran::parser::DeallocateStmt &stmt) {
- Fortran::lower::genDeallocateStmt(*this, stmt, toLocation());
- }
+void FirConverter::genFIR(const Fortran::parser::DeallocateStmt &stmt) {
+ Fortran::lower::genDeallocateStmt(*this, stmt, toLocation());
+}
- /// Nullify pointer object list
- ///
- /// For each pointer object, reset the pointer to a disassociated status.
- /// We do this by setting each pointer to null.
- void genFIR(const Fortran::parser::NullifyStmt &stmt) {
- mlir::Location loc = toLocation();
- for (auto &pointerObject : stmt.v) {
- const Fortran::lower::SomeExpr *expr =
- Fortran::semantics::GetExpr(pointerObject);
- assert(expr);
- if (Fortran::evaluate::IsProcedurePointer(*expr)) {
- Fortran::lower::StatementContext stmtCtx;
- hlfir::Entity pptr = Fortran::lower::convertExprToHLFIR(
- loc, *this, *expr, localSymbols, stmtCtx);
- auto boxTy{
- Fortran::lower::getUntypedBoxProcType(builder->getContext())};
- hlfir::Entity nullBoxProc(
- fir::factory::createNullBoxProc(*builder, loc, boxTy));
- builder->createStoreWithConvert(loc, nullBoxProc, pptr);
- return;
- }
- fir::MutableBoxValue box = genExprMutableBox(loc, *expr);
- fir::factory::disassociateMutableBox(*builder, loc, box);
+/// Nullify pointer object list
+///
+/// For each pointer object, reset the pointer to a disassociated status.
+/// We do this by setting each pointer to null.
+void FirConverter::genFIR(const Fortran::parser::NullifyStmt &stmt) {
+ mlir::Location loc = toLocation();
+ for (auto &pointerObject : stmt.v) {
+ const Fortran::lower::SomeExpr *expr =
+ Fortran::semantics::GetExpr(pointerObject);
+ assert(expr);
+ if (Fortran::evaluate::IsProcedurePointer(*expr)) {
+ Fortran::lower::StatementContext stmtCtx;
+ hlfir::Entity pptr = Fortran::lower::convertExprToHLFIR(
+ loc, *this, *expr, localSymbols, stmtCtx);
+ auto boxTy{Fortran::lower::getUntypedBoxProcType(builder->getContext())};
+ hlfir::Entity nullBoxProc(
+ fir::factory::createNullBoxProc(*builder, loc, boxTy));
+ builder->createStoreWithConvert(loc, nullBoxProc, pptr);
+ return;
}
+ fir::MutableBoxValue box = genExprMutableBox(loc, *expr);
+ fir::factory::disassociateMutableBox(*builder, loc, box);
}
+}
- //===--------------------------------------------------------------------===//
-
- void genFIR(const Fortran::parser::EventPostStmt &stmt) {
- genEventPostStatement(*this, stmt);
- }
-
- void genFIR(const Fortran::parser::EventWaitStmt &stmt) {
- genEventWaitStatement(*this, stmt);
- }
-
- void genFIR(const Fortran::parser::FormTeamStmt &stmt) {
- genFormTeamStatement(*this, getEval(), stmt);
- }
-
- void genFIR(const Fortran::parser::LockStmt &stmt) {
- genLockStatement(*this, stmt);
- }
-
- fir::ExtendedValue
- genInitializerExprValue(const Fortran::lower::SomeExpr &expr,
- Fortran::lower::StatementContext &stmtCtx) {
- return Fortran::lower::createSomeInitializerExpression(
- toLocation(), *this, expr, localSymbols, stmtCtx);
- }
+//===--------------------------------------------------------------------===//
- /// Return true if the current context is a conditionalized and implied
- /// iteration space.
- bool implicitIterationSpace() { return !implicitIterSpace.empty(); }
-
- /// Return true if context is currently an explicit iteration space. A scalar
- /// assignment expression may be contextually within a user-defined iteration
- /// space, transforming it into an array expression.
- bool explicitIterationSpace() { return explicitIterSpace.isActive(); }
-
- /// Generate an array assignment.
- /// This is an assignment expression with rank > 0. The assignment may or may
- /// not be in a WHERE and/or FORALL context.
- /// In a FORALL context, the assignment may be a pointer assignment and the \p
- /// lbounds and \p ubounds parameters should only be used in such a pointer
- /// assignment case. (If both are None then the array assignment cannot be a
- /// pointer assignment.)
- void genArrayAssignment(
- const Fortran::evaluate::Assignment &assign,
- Fortran::lower::StatementContext &localStmtCtx,
- std::optional<llvm::SmallVector<mlir::Value>> lbounds = std::nullopt,
- std::optional<llvm::SmallVector<mlir::Value>> ubounds = std::nullopt) {
-
- Fortran::lower::StatementContext &stmtCtx =
- explicitIterationSpace()
- ? explicitIterSpace.stmtContext()
- : (implicitIterationSpace() ? implicitIterSpace.stmtContext()
- : localStmtCtx);
- if (Fortran::lower::isWholeAllocatable(assign.lhs)) {
- // Assignment to allocatables may require the lhs to be
- // deallocated/reallocated. See Fortran 2018 10.2.1.3 p3
- Fortran::lower::createAllocatableArrayAssignment(
- *this, assign.lhs, assign.rhs, explicitIterSpace, implicitIterSpace,
- localSymbols, stmtCtx);
- return;
- }
+void FirConverter::genFIR(const Fortran::parser::EventPostStmt &stmt) {
+ genEventPostStatement(*this, stmt);
+}
- if (lbounds) {
- // Array of POINTER entities, with elemental assignment.
- if (!Fortran::lower::isWholePointer(assign.lhs))
- fir::emitFatalError(toLocation(), "pointer assignment to non-pointer");
+void FirConverter::genFIR(const Fortran::parser::EventWaitStmt &stmt) {
+ genEventWaitStatement(*this, stmt);
+}
- Fortran::lower::createArrayOfPointerAssignment(
- *this, assign.lhs, assign.rhs, explicitIterSpace, implicitIterSpace,
- *lbounds, ubounds, localSymbols, stmtCtx);
- return;
- }
+void FirConverter::genFIR(const Fortran::parser::FormTeamStmt &stmt) {
+ genFormTeamStatement(*this, getEval(), stmt);
+}
- if (!implicitIterationSpace() && !explicitIterationSpace()) {
- // No masks and the iteration space is implied by the array, so create a
- // simple array assignment.
- Fortran::lower::createSomeArrayAssignment(*this, assign.lhs, assign.rhs,
- localSymbols, stmtCtx);
- return;
- }
+void FirConverter::genFIR(const Fortran::parser::LockStmt &stmt) {
+ genLockStatement(*this, stmt);
+}
- // If there is an explicit iteration space, generate an array assignment
- // with a user-specified iteration space and possibly with masks. These
- // assignments may *appear* to be scalar expressions, but the scalar
- // expression is evaluated at all points in the user-defined space much like
- // an ordinary array assignment. More specifically, the semantics inside the
- // FORALL much more closely resembles that of WHERE than a scalar
- // assignment.
- // Otherwise, generate a masked array assignment. The iteration space is
- // implied by the lhs array expression.
- Fortran::lower::createAnyMaskedArrayAssignment(
+/// Generate an array assignment.
+/// This is an assignment expression with rank > 0. The assignment may or may
+/// not be in a WHERE and/or FORALL context.
+/// In a FORALL context, the assignment may be a pointer assignment and the \p
+/// lbounds and \p ubounds parameters should only be used in such a pointer
+/// assignment case. (If both are None then the array assignment cannot be a
+/// pointer assignment.)
+void FirConverter::genArrayAssignment(
+ const Fortran::evaluate::Assignment &assign,
+ Fortran::lower::StatementContext &localStmtCtx,
+ std::optional<llvm::SmallVector<mlir::Value>> lbounds,
+ std::optional<llvm::SmallVector<mlir::Value>> ubounds) {
+
+ Fortran::lower::StatementContext &stmtCtx =
+ explicitIterationSpace()
+ ? explicitIterSpace.stmtContext()
+ : (implicitIterationSpace() ? implicitIterSpace.stmtContext()
+ : localStmtCtx);
+ if (Fortran::lower::isWholeAllocatable(assign.lhs)) {
+ // Assignment to allocatables may require the lhs to be
+ // deallocated/reallocated. See Fortran 2018 10.2.1.3 p3
+ Fortran::lower::createAllocatableArrayAssignment(
*this, assign.lhs, assign.rhs, explicitIterSpace, implicitIterSpace,
localSymbols, stmtCtx);
+ return;
}
-#if !defined(NDEBUG)
- static bool isFuncResultDesignator(const Fortran::lower::SomeExpr &expr) {
- const Fortran::semantics::Symbol *sym =
- Fortran::evaluate::GetFirstSymbol(expr);
- return sym && sym->IsFuncResult();
- }
-#endif
-
- inline fir::MutableBoxValue
- genExprMutableBox(mlir::Location loc,
- const Fortran::lower::SomeExpr &expr) override final {
- if (lowerToHighLevelFIR())
- return Fortran::lower::convertExprToMutableBox(loc, *this, expr,
- localSymbols);
- return Fortran::lower::createMutableBox(loc, *this, expr, localSymbols);
- }
+ if (lbounds) {
+ // Array of POINTER entities, with elemental assignment.
+ if (!Fortran::lower::isWholePointer(assign.lhs))
+ fir::emitFatalError(toLocation(), "pointer assignment to non-pointer");
- // Create the [newRank] array with the lower bounds to be passed to the
- // runtime as a descriptor.
- mlir::Value createLboundArray(llvm::ArrayRef<mlir::Value> lbounds,
- mlir::Location loc) {
- mlir::Type indexTy = builder->getIndexType();
- mlir::Type boundArrayTy = fir::SequenceType::get(
- {static_cast<int64_t>(lbounds.size())}, builder->getI64Type());
- mlir::Value boundArray = builder->create<fir::AllocaOp>(loc, boundArrayTy);
- mlir::Value array = builder->create<fir::UndefOp>(loc, boundArrayTy);
- for (unsigned i = 0; i < lbounds.size(); ++i) {
- array = builder->create<fir::InsertValueOp>(
- loc, boundArrayTy, array, lbounds[i],
- builder->getArrayAttr({builder->getIntegerAttr(
- builder->getIndexType(), static_cast<int>(i))}));
- }
- builder->create<fir::StoreOp>(loc, array, boundArray);
- mlir::Type boxTy = fir::BoxType::get(boundArrayTy);
- mlir::Value ext =
- builder->createIntegerConstant(loc, indexTy, lbounds.size());
- llvm::SmallVector<mlir::Value> shapes = {ext};
- mlir::Value shapeOp = builder->genShape(loc, shapes);
- return builder->create<fir::EmboxOp>(loc, boxTy, boundArray, shapeOp);
- }
+ Fortran::lower::createArrayOfPointerAssignment(
+ *this, assign.lhs, assign.rhs, explicitIterSpace, implicitIterSpace,
+ *lbounds, ubounds, localSymbols, stmtCtx);
+ return;
+ }
+
+ if (!implicitIterationSpace() && !explicitIterationSpace()) {
+ // No masks and the iteration space is implied by the array, so create a
+ // simple array assignment.
+ Fortran::lower::createSomeArrayAssignment(*this, assign.lhs, assign.rhs,
+ localSymbols, stmtCtx);
+ return;
+ }
+
+ // If there is an explicit iteration space, generate an array assignment
+ // with a user-specified iteration space and possibly with masks. These
+ // assignments may *appear* to be scalar expressions, but the scalar
+ // expression is evaluated at all points in the user-defined space much like
+ // an ordinary array assignment. More specifically, the semantics inside the
+ // FORALL much more closely resembles that of WHERE than a scalar
+ // assignment.
+ // Otherwise, generate a masked array assignment. The iteration space is
+ // implied by the lhs array expression.
+ Fortran::lower::createAnyMaskedArrayAssignment(
+ *this, assign.lhs, assign.rhs, explicitIterSpace, implicitIterSpace,
+ localSymbols, stmtCtx);
+}
- // Generate pointer assignment with possibly empty bounds-spec. R1035: a
- // bounds-spec is a lower bound value.
- void genPointerAssignment(
- mlir::Location loc, const Fortran::evaluate::Assignment &assign,
- const Fortran::evaluate::Assignment::BoundsSpec &lbExprs) {
- Fortran::lower::StatementContext stmtCtx;
+inline fir::MutableBoxValue
+FirConverter::genExprMutableBox(mlir::Location loc,
+ const Fortran::lower::SomeExpr &expr) {
+ if (lowerToHighLevelFIR())
+ return Fortran::lower::convertExprToMutableBox(loc, *this, expr,
+ localSymbols);
+ return Fortran::lower::createMutableBox(loc, *this, expr, localSymbols);
+}
- if (!lowerToHighLevelFIR() && Fortran::evaluate::IsProcedure(assign.rhs))
- TODO(loc, "procedure pointer assignment");
- if (Fortran::evaluate::IsProcedurePointer(assign.lhs)) {
- hlfir::Entity lhs = Fortran::lower::convertExprToHLFIR(
- loc, *this, assign.lhs, localSymbols, stmtCtx);
- if (Fortran::evaluate::IsNullProcedurePointer(assign.rhs)) {
- auto boxTy{Fortran::lower::getUntypedBoxProcType(&getMLIRContext())};
- hlfir::Entity rhs(
- fir::factory::createNullBoxProc(*builder, loc, boxTy));
- builder->createStoreWithConvert(loc, rhs, lhs);
- return;
- }
- hlfir::Entity rhs(getBase(Fortran::lower::convertExprToAddress(
- loc, *this, assign.rhs, localSymbols, stmtCtx)));
- builder->createStoreWithConvert(loc, rhs, lhs);
- return;
- }
+// Create the [newRank] array with the lower bounds to be passed to the
+// runtime as a descriptor.
+mlir::Value FirConverter::createLboundArray(llvm::ArrayRef<mlir::Value> lbounds,
+ mlir::Location loc) {
+ mlir::Type indexTy = builder->getIndexType();
+ mlir::Type boundArrayTy = fir::SequenceType::get(
+ {static_cast<int64_t>(lbounds.size())}, builder->getI64Type());
+ mlir::Value boundArray = builder->create<fir::AllocaOp>(loc, boundArrayTy);
+ mlir::Value array = builder->create<fir::UndefOp>(loc, boundArrayTy);
+ for (unsigned i = 0; i < lbounds.size(); ++i) {
+ array = builder->create<fir::InsertValueOp>(
+ loc, boundArrayTy, array, lbounds[i],
+ builder->getArrayAttr({builder->getIntegerAttr(builder->getIndexType(),
+ static_cast<int>(i))}));
+ }
+ builder->create<fir::StoreOp>(loc, array, boundArray);
+ mlir::Type boxTy = fir::BoxType::get(boundArrayTy);
+ mlir::Value ext =
+ builder->createIntegerConstant(loc, indexTy, lbounds.size());
+ llvm::SmallVector<mlir::Value> shapes = {ext};
+ mlir::Value shapeOp = builder->genShape(loc, shapes);
+ return builder->create<fir::EmboxOp>(loc, boxTy, boundArray, shapeOp);
+}
- std::optional<Fortran::evaluate::DynamicType> lhsType =
- assign.lhs.GetType();
- // Delegate pointer association to unlimited polymorphic pointer
- // to the runtime. element size, type code, attribute and of
- // course base_addr might need to be updated.
- if (lhsType && lhsType->IsPolymorphic()) {
- if (!lowerToHighLevelFIR() && explicitIterationSpace())
- TODO(loc, "polymorphic pointer assignment in FORALL");
- llvm::SmallVector<mlir::Value> lbounds;
- for (const Fortran::evaluate::ExtentExpr &lbExpr : lbExprs)
- lbounds.push_back(
- fir::getBase(genExprValue(toEvExpr(lbExpr), stmtCtx)));
- fir::MutableBoxValue lhsMutableBox = genExprMutableBox(loc, assign.lhs);
- if (Fortran::evaluate::UnwrapExpr<Fortran::evaluate::NullPointer>(
- assign.rhs)) {
- fir::factory::disassociateMutableBox(*builder, loc, lhsMutableBox);
- return;
- }
- mlir::Value lhs = lhsMutableBox.getAddr();
- mlir::Value rhs = fir::getBase(genExprBox(loc, assign.rhs, stmtCtx));
- if (!lbounds.empty()) {
- mlir::Value boundsDesc = createLboundArray(lbounds, loc);
- Fortran::lower::genPointerAssociateLowerBounds(*builder, loc, lhs, rhs,
- boundsDesc);
- return;
- }
- Fortran::lower::genPointerAssociate(*builder, loc, lhs, rhs);
+// Generate pointer assignment with possibly empty bounds-spec. R1035: a
+// bounds-spec is a lower bound value.
+void FirConverter::genPointerAssignment(
+ mlir::Location loc, const Fortran::evaluate::Assignment &assign,
+ const Fortran::evaluate::Assignment::BoundsSpec &lbExprs) {
+ Fortran::lower::StatementContext stmtCtx;
+
+ if (!lowerToHighLevelFIR() && Fortran::evaluate::IsProcedure(assign.rhs))
+ TODO(loc, "procedure pointer assignment");
+ if (Fortran::evaluate::IsProcedurePointer(assign.lhs)) {
+ hlfir::Entity lhs = Fortran::lower::convertExprToHLFIR(
+ loc, *this, assign.lhs, localSymbols, stmtCtx);
+ if (Fortran::evaluate::IsNullProcedurePointer(assign.rhs)) {
+ auto boxTy{Fortran::lower::getUntypedBoxProcType(&getMLIRContext())};
+ hlfir::Entity rhs(fir::factory::createNullBoxProc(*builder, loc, boxTy));
+ builder->createStoreWithConvert(loc, rhs, lhs);
return;
}
-
+ hlfir::Entity rhs(getBase(Fortran::lower::convertExprToAddress(
+ loc, *this, assign.rhs, localSymbols, stmtCtx)));
+ builder->createStoreWithConvert(loc, rhs, lhs);
+ return;
+ }
+
+ std::optional<Fortran::evaluate::DynamicType> lhsType = assign.lhs.GetType();
+ // Delegate pointer association to unlimited polymorphic pointer
+ // to the runtime. element size, type code, attribute and of
+ // course base_addr might need to be updated.
+ if (lhsType && lhsType->IsPolymorphic()) {
+ if (!lowerToHighLevelFIR() && explicitIterationSpace())
+ TODO(loc, "polymorphic pointer assignment in FORALL");
llvm::SmallVector<mlir::Value> lbounds;
for (const Fortran::evaluate::ExtentExpr &lbExpr : lbExprs)
lbounds.push_back(fir::getBase(genExprValue(toEvExpr(lbExpr), stmtCtx)));
- if (!lowerToHighLevelFIR() && explicitIterationSpace()) {
- // Pointer assignment in FORALL context. Copy the rhs box value
- // into the lhs box variable.
- genArrayAssignment(assign, stmtCtx, lbounds);
+ fir::MutableBoxValue lhsMutableBox = genExprMutableBox(loc, assign.lhs);
+ if (Fortran::evaluate::UnwrapExpr<Fortran::evaluate::NullPointer>(
+ assign.rhs)) {
+ fir::factory::disassociateMutableBox(*builder, loc, lhsMutableBox);
return;
}
- fir::MutableBoxValue lhs = genExprMutableBox(loc, assign.lhs);
- Fortran::lower::associateMutableBox(*this, loc, lhs, assign.rhs, lbounds,
- stmtCtx);
- }
-
- // Create the 2 x newRank array with the bounds to be passed to the runtime as
- // a descriptor.
- mlir::Value createBoundArray(llvm::ArrayRef<mlir::Value> lbounds,
- llvm::ArrayRef<mlir::Value> ubounds,
- mlir::Location loc) {
- assert(lbounds.size() && ubounds.size());
- mlir::Type indexTy = builder->getIndexType();
- mlir::Type boundArrayTy = fir::SequenceType::get(
- {2, static_cast<int64_t>(lbounds.size())}, builder->getI64Type());
- mlir::Value boundArray = builder->create<fir::AllocaOp>(loc, boundArrayTy);
- mlir::Value array = builder->create<fir::UndefOp>(loc, boundArrayTy);
- for (unsigned i = 0; i < lbounds.size(); ++i) {
- array = builder->create<fir::InsertValueOp>(
- loc, boundArrayTy, array, lbounds[i],
- builder->getArrayAttr(
- {builder->getIntegerAttr(builder->getIndexType(), 0),
- builder->getIntegerAttr(builder->getIndexType(),
- static_cast<int>(i))}));
- array = builder->create<fir::InsertValueOp>(
- loc, boundArrayTy, array, ubounds[i],
- builder->getArrayAttr(
- {builder->getIntegerAttr(builder->getIndexType(), 1),
- builder->getIntegerAttr(builder->getIndexType(),
- static_cast<int>(i))}));
+ mlir::Value lhs = lhsMutableBox.getAddr();
+ mlir::Value rhs = fir::getBase(genExprBox(loc, assign.rhs, stmtCtx));
+ if (!lbounds.empty()) {
+ mlir::Value boundsDesc = createLboundArray(lbounds, loc);
+ Fortran::lower::genPointerAssociateLowerBounds(*builder, loc, lhs, rhs,
+ boundsDesc);
+ return;
}
- builder->create<fir::StoreOp>(loc, array, boundArray);
- mlir::Type boxTy = fir::BoxType::get(boundArrayTy);
- mlir::Value ext =
- builder->createIntegerConstant(loc, indexTy, lbounds.size());
- mlir::Value c2 = builder->createIntegerConstant(loc, indexTy, 2);
- llvm::SmallVector<mlir::Value> shapes = {c2, ext};
- mlir::Value shapeOp = builder->genShape(loc, shapes);
- return builder->create<fir::EmboxOp>(loc, boxTy, boundArray, shapeOp);
- }
+ Fortran::lower::genPointerAssociate(*builder, loc, lhs, rhs);
+ return;
+ }
+
+ llvm::SmallVector<mlir::Value> lbounds;
+ for (const Fortran::evaluate::ExtentExpr &lbExpr : lbExprs)
+ lbounds.push_back(fir::getBase(genExprValue(toEvExpr(lbExpr), stmtCtx)));
+ if (!lowerToHighLevelFIR() && explicitIterationSpace()) {
+ // Pointer assignment in FORALL context. Copy the rhs box value
+ // into the lhs box variable.
+ genArrayAssignment(assign, stmtCtx, lbounds);
+ return;
+ }
+ fir::MutableBoxValue lhs = genExprMutableBox(loc, assign.lhs);
+ Fortran::lower::associateMutableBox(*this, loc, lhs, assign.rhs, lbounds,
+ stmtCtx);
+}
- // Pointer assignment with bounds-remapping. R1036: a bounds-remapping is a
- // pair, lower bound and upper bound.
- void genPointerAssignment(
- mlir::Location loc, const Fortran::evaluate::Assignment &assign,
- const Fortran::evaluate::Assignment::BoundsRemapping &boundExprs) {
- Fortran::lower::StatementContext stmtCtx;
- llvm::SmallVector<mlir::Value> lbounds;
- llvm::SmallVector<mlir::Value> ubounds;
- for (const std::pair<Fortran::evaluate::ExtentExpr,
- Fortran::evaluate::ExtentExpr> &pair : boundExprs) {
- const Fortran::evaluate::ExtentExpr &lbExpr = pair.first;
- const Fortran::evaluate::ExtentExpr &ubExpr = pair.second;
- lbounds.push_back(fir::getBase(genExprValue(toEvExpr(lbExpr), stmtCtx)));
- ubounds.push_back(fir::getBase(genExprValue(toEvExpr(ubExpr), stmtCtx)));
- }
+// Create the 2 x newRank array with the bounds to be passed to the runtime as
+// a descriptor.
+mlir::Value FirConverter::createBoundArray(llvm::ArrayRef<mlir::Value> lbounds,
+ llvm::ArrayRef<mlir::Value> ubounds,
+ mlir::Location loc) {
+ assert(lbounds.size() && ubounds.size());
+ mlir::Type indexTy = builder->getIndexType();
+ mlir::Type boundArrayTy = fir::SequenceType::get(
+ {2, static_cast<int64_t>(lbounds.size())}, builder->getI64Type());
+ mlir::Value boundArray = builder->create<fir::AllocaOp>(loc, boundArrayTy);
+ mlir::Value array = builder->create<fir::UndefOp>(loc, boundArrayTy);
+ for (unsigned i = 0; i < lbounds.size(); ++i) {
+ array = builder->create<fir::InsertValueOp>(
+ loc, boundArrayTy, array, lbounds[i],
+ builder->getArrayAttr(
+ {builder->getIntegerAttr(builder->getIndexType(), 0),
+ builder->getIntegerAttr(builder->getIndexType(),
+ static_cast<int>(i))}));
+ array = builder->create<fir::InsertValueOp>(
+ loc, boundArrayTy, array, ubounds[i],
+ builder->getArrayAttr(
+ {builder->getIntegerAttr(builder->getIndexType(), 1),
+ builder->getIntegerAttr(builder->getIndexType(),
+ static_cast<int>(i))}));
+ }
+ builder->create<fir::StoreOp>(loc, array, boundArray);
+ mlir::Type boxTy = fir::BoxType::get(boundArrayTy);
+ mlir::Value ext =
+ builder->createIntegerConstant(loc, indexTy, lbounds.size());
+ mlir::Value c2 = builder->createIntegerConstant(loc, indexTy, 2);
+ llvm::SmallVector<mlir::Value> shapes = {c2, ext};
+ mlir::Value shapeOp = builder->genShape(loc, shapes);
+ return builder->create<fir::EmboxOp>(loc, boxTy, boundArray, shapeOp);
+}
- std::optional<Fortran::evaluate::DynamicType> lhsType =
- assign.lhs.GetType();
- std::optional<Fortran::evaluate::DynamicType> rhsType =
- assign.rhs.GetType();
- // Polymorphic lhs/rhs need more care. See F2018 10.2.2.3.
- if ((lhsType && lhsType->IsPolymorphic()) ||
- (rhsType && rhsType->IsPolymorphic())) {
- if (!lowerToHighLevelFIR() && explicitIterationSpace())
- TODO(loc, "polymorphic pointer assignment in FORALL");
-
- fir::MutableBoxValue lhsMutableBox = genExprMutableBox(loc, assign.lhs);
- if (Fortran::evaluate::UnwrapExpr<Fortran::evaluate::NullPointer>(
- assign.rhs)) {
- fir::factory::disassociateMutableBox(*builder, loc, lhsMutableBox);
- return;
- }
- mlir::Value lhs = lhsMutableBox.getAddr();
- mlir::Value rhs = fir::getBase(genExprBox(loc, assign.rhs, stmtCtx));
- mlir::Value boundsDesc = createBoundArray(lbounds, ubounds, loc);
- Fortran::lower::genPointerAssociateRemapping(*builder, loc, lhs, rhs,
- boundsDesc);
- return;
- }
- if (!lowerToHighLevelFIR() && explicitIterationSpace()) {
- // Pointer assignment in FORALL context. Copy the rhs box value
- // into the lhs box variable.
- genArrayAssignment(assign, stmtCtx, lbounds, ubounds);
- return;
- }
- fir::MutableBoxValue lhs = genExprMutableBox(loc, assign.lhs);
+// Pointer assignment with bounds-remapping. R1036: a bounds-remapping is a
+// pair, lower bound and upper bound.
+void FirConverter::genPointerAssignment(
+ mlir::Location loc, const Fortran::evaluate::Assignment &assign,
+ const Fortran::evaluate::Assignment::BoundsRemapping &boundExprs) {
+ Fortran::lower::StatementContext stmtCtx;
+ llvm::SmallVector<mlir::Value> lbounds;
+ llvm::SmallVector<mlir::Value> ubounds;
+ for (const std::pair<Fortran::evaluate::ExtentExpr,
+ Fortran::evaluate::ExtentExpr> &pair : boundExprs) {
+ const Fortran::evaluate::ExtentExpr &lbExpr = pair.first;
+ const Fortran::evaluate::ExtentExpr &ubExpr = pair.second;
+ lbounds.push_back(fir::getBase(genExprValue(toEvExpr(lbExpr), stmtCtx)));
+ ubounds.push_back(fir::getBase(genExprValue(toEvExpr(ubExpr), stmtCtx)));
+ }
+
+ std::optional<Fortran::evaluate::DynamicType> lhsType = assign.lhs.GetType();
+ std::optional<Fortran::evaluate::DynamicType> rhsType = assign.rhs.GetType();
+ // Polymorphic lhs/rhs need more care. See F2018 10.2.2.3.
+ if ((lhsType && lhsType->IsPolymorphic()) ||
+ (rhsType && rhsType->IsPolymorphic())) {
+ if (!lowerToHighLevelFIR() && explicitIterationSpace())
+ TODO(loc, "polymorphic pointer assignment in FORALL");
+
+ fir::MutableBoxValue lhsMutableBox = genExprMutableBox(loc, assign.lhs);
if (Fortran::evaluate::UnwrapExpr<Fortran::evaluate::NullPointer>(
assign.rhs)) {
- fir::factory::disassociateMutableBox(*builder, loc, lhs);
+ fir::factory::disassociateMutableBox(*builder, loc, lhsMutableBox);
return;
}
- // Do not generate a temp in case rhs is an array section.
- fir::ExtendedValue rhs =
- Fortran::lower::isArraySectionWithoutVectorSubscript(assign.rhs)
- ? Fortran::lower::createSomeArrayBox(*this, assign.rhs,
- localSymbols, stmtCtx)
- : genExprAddr(assign.rhs, stmtCtx);
- fir::factory::associateMutableBoxWithRemap(*builder, loc, lhs, rhs, lbounds,
- ubounds);
- if (!lowerToHighLevelFIR() && explicitIterationSpace()) {
- mlir::ValueRange inners = explicitIterSpace.getInnerArgs();
- if (!inners.empty())
- builder->create<fir::ResultOp>(loc, inners);
- }
+ mlir::Value lhs = lhsMutableBox.getAddr();
+ mlir::Value rhs = fir::getBase(genExprBox(loc, assign.rhs, stmtCtx));
+ mlir::Value boundsDesc = createBoundArray(lbounds, ubounds, loc);
+ Fortran::lower::genPointerAssociateRemapping(*builder, loc, lhs, rhs,
+ boundsDesc);
+ return;
+ }
+ if (!lowerToHighLevelFIR() && explicitIterationSpace()) {
+ // Pointer assignment in FORALL context. Copy the rhs box value
+ // into the lhs box variable.
+ genArrayAssignment(assign, stmtCtx, lbounds, ubounds);
+ return;
+ }
+ fir::MutableBoxValue lhs = genExprMutableBox(loc, assign.lhs);
+ if (Fortran::evaluate::UnwrapExpr<Fortran::evaluate::NullPointer>(
+ assign.rhs)) {
+ fir::factory::disassociateMutableBox(*builder, loc, lhs);
+ return;
+ }
+ // Do not generate a temp in case rhs is an array section.
+ fir::ExtendedValue rhs =
+ Fortran::lower::isArraySectionWithoutVectorSubscript(assign.rhs)
+ ? Fortran::lower::createSomeArrayBox(*this, assign.rhs, localSymbols,
+ stmtCtx)
+ : genExprAddr(assign.rhs, stmtCtx);
+ fir::factory::associateMutableBoxWithRemap(*builder, loc, lhs, rhs, lbounds,
+ ubounds);
+ if (!lowerToHighLevelFIR() && explicitIterationSpace()) {
+ mlir::ValueRange inners = explicitIterSpace.getInnerArgs();
+ if (!inners.empty())
+ builder->create<fir::ResultOp>(loc, inners);
}
+}
- /// Given converted LHS and RHS of the assignment, materialize any
- /// implicit conversion of the RHS to the LHS type. The front-end
- /// usually already makes those explicit, except for non-standard
- /// LOGICAL <-> INTEGER, or if the LHS is a whole allocatable
- /// (making the conversion explicit in the front-end would prevent
- /// propagation of the LHS lower bound in the reallocation).
- /// If array temporaries or values are created, the cleanups are
- /// added in the statement context.
- hlfir::Entity genImplicitConvert(const Fortran::evaluate::Assignment &assign,
- hlfir::Entity rhs, bool preserveLowerBounds,
- Fortran::lower::StatementContext &stmtCtx) {
- mlir::Location loc = toLocation();
- auto &builder = getFirOpBuilder();
- mlir::Type toType = genType(assign.lhs);
- auto valueAndPair = hlfir::genTypeAndKindConvert(loc, builder, rhs, toType,
- preserveLowerBounds);
- if (valueAndPair.second)
- stmtCtx.attachCleanup(*valueAndPair.second);
- return hlfir::Entity{valueAndPair.first};
- }
+/// Given converted LHS and RHS of the assignment, materialize any
+/// implicit conversion of the RHS to the LHS type. The front-end
+/// usually already makes those explicit, except for non-standard
+/// LOGICAL <-> INTEGER, or if the LHS is a whole allocatable
+/// (making the conversion explicit in the front-end would prevent
+/// propagation of the LHS lower bound in the reallocation).
+/// If array temporaries or values are created, the cleanups are
+/// added in the statement context.
+hlfir::Entity
+FirConverter::genImplicitConvert(const Fortran::evaluate::Assignment &assign,
+ hlfir::Entity rhs, bool preserveLowerBounds,
+ Fortran::lower::StatementContext &stmtCtx) {
+ mlir::Location loc = toLocation();
+ auto &builder = getFirOpBuilder();
+ mlir::Type toType = genType(assign.lhs);
+ auto valueAndPair = hlfir::genTypeAndKindConvert(loc, builder, rhs, toType,
+ preserveLowerBounds);
+ if (valueAndPair.second)
+ stmtCtx.attachCleanup(*valueAndPair.second);
+ return hlfir::Entity{valueAndPair.first};
+}
- static void
- genCleanUpInRegionIfAny(mlir::Location loc, fir::FirOpBuilder &builder,
- mlir::Region ®ion,
- Fortran::lower::StatementContext &context) {
- if (!context.hasCode())
- return;
- mlir::OpBuilder::InsertPoint insertPt = builder.saveInsertionPoint();
- if (region.empty())
- builder.createBlock(®ion);
- else
- builder.setInsertionPointToEnd(®ion.front());
- context.finalizeAndPop();
- hlfir::YieldOp::ensureTerminator(region, builder, loc);
- builder.restoreInsertionPoint(insertPt);
- }
+void FirConverter::genCleanUpInRegionIfAny(
+ mlir::Location loc, fir::FirOpBuilder &builder, mlir::Region ®ion,
+ Fortran::lower::StatementContext &context) {
+ if (!context.hasCode())
+ return;
+ mlir::OpBuilder::InsertPoint insertPt = builder.saveInsertionPoint();
+ if (region.empty())
+ builder.createBlock(®ion);
+ else
+ builder.setInsertionPointToEnd(®ion.front());
+ context.finalizeAndPop();
+ hlfir::YieldOp::ensureTerminator(region, builder, loc);
+ builder.restoreInsertionPoint(insertPt);
+}
- bool firstDummyIsPointerOrAllocatable(
- const Fortran::evaluate::ProcedureRef &userDefinedAssignment) {
- using DummyAttr = Fortran::evaluate::characteristics::DummyDataObject::Attr;
- if (auto procedure =
- Fortran::evaluate::characteristics::Procedure::Characterize(
- userDefinedAssignment.proc(), getFoldingContext()))
- if (!procedure->dummyArguments.empty())
- if (const auto *dataArg = std::get_if<
- Fortran::evaluate::characteristics::DummyDataObject>(
- &procedure->dummyArguments[0].u))
- return dataArg->attrs.test(DummyAttr::Pointer) ||
- dataArg->attrs.test(DummyAttr::Allocatable);
- return false;
- }
+bool FirConverter::firstDummyIsPointerOrAllocatable(
+ const Fortran::evaluate::ProcedureRef &userDefinedAssignment) {
+ using DummyAttr = Fortran::evaluate::characteristics::DummyDataObject::Attr;
+ if (auto procedure =
+ Fortran::evaluate::characteristics::Procedure::Characterize(
+ userDefinedAssignment.proc(), getFoldingContext()))
+ if (!procedure->dummyArguments.empty())
+ if (const auto *dataArg =
+ std::get_if<Fortran::evaluate::characteristics::DummyDataObject>(
+ &procedure->dummyArguments[0].u))
+ return dataArg->attrs.test(DummyAttr::Pointer) ||
+ dataArg->attrs.test(DummyAttr::Allocatable);
+ return false;
+}
- void genDataAssignment(
- const Fortran::evaluate::Assignment &assign,
- const Fortran::evaluate::ProcedureRef *userDefinedAssignment) {
- mlir::Location loc = getCurrentLocation();
- fir::FirOpBuilder &builder = getFirOpBuilder();
- // Gather some information about the assignment that will impact how it is
- // lowered.
- const bool isWholeAllocatableAssignment =
- !userDefinedAssignment && !isInsideHlfirWhere() &&
- Fortran::lower::isWholeAllocatable(assign.lhs);
- const bool isUserDefAssignToPointerOrAllocatable =
- userDefinedAssignment &&
- firstDummyIsPointerOrAllocatable(*userDefinedAssignment);
- std::optional<Fortran::evaluate::DynamicType> lhsType =
- assign.lhs.GetType();
- const bool keepLhsLengthInAllocatableAssignment =
- isWholeAllocatableAssignment && lhsType.has_value() &&
- lhsType->category() == Fortran::common::TypeCategory::Character &&
- !lhsType->HasDeferredTypeParameter();
- const bool lhsHasVectorSubscripts =
- Fortran::evaluate::HasVectorSubscript(assign.lhs);
-
- // Helper to generate the code evaluating the right-hand side.
- auto evaluateRhs = [&](Fortran::lower::StatementContext &stmtCtx) {
- hlfir::Entity rhs = Fortran::lower::convertExprToHLFIR(
- loc, *this, assign.rhs, localSymbols, stmtCtx);
- // Load trivial scalar RHS to allow the loads to be hoisted outside of
- // loops early if possible. This also dereferences pointer and
- // allocatable RHS: the target is being assigned from.
- rhs = hlfir::loadTrivialScalar(loc, builder, rhs);
- // In intrinsic assignments, the LHS type may not match the RHS type, in
- // which case an implicit conversion of the LHS must be done. The
- // front-end usually makes it explicit, unless it cannot (whole
- // allocatable LHS or Logical<->Integer assignment extension). Recognize
- // any type mismatches here and insert explicit scalar convert or
- // ElementalOp for array assignment. Preserve the RHS lower bounds on the
- // converted entity in case of assignment to whole allocatables so to
- // propagate the lower bounds to the LHS in case of reallocation.
- if (!userDefinedAssignment)
- rhs = genImplicitConvert(assign, rhs, isWholeAllocatableAssignment,
- stmtCtx);
- return rhs;
- };
+void FirConverter::genDataAssignment(
+ const Fortran::evaluate::Assignment &assign,
+ const Fortran::evaluate::ProcedureRef *userDefinedAssignment) {
+ mlir::Location loc = getCurrentLocation();
+ fir::FirOpBuilder &builder = getFirOpBuilder();
+ // Gather some information about the assignment that will impact how it is
+ // lowered.
+ const bool isWholeAllocatableAssignment =
+ !userDefinedAssignment && !isInsideHlfirWhere() &&
+ Fortran::lower::isWholeAllocatable(assign.lhs);
+ const bool isUserDefAssignToPointerOrAllocatable =
+ userDefinedAssignment &&
+ firstDummyIsPointerOrAllocatable(*userDefinedAssignment);
+ std::optional<Fortran::evaluate::DynamicType> lhsType = assign.lhs.GetType();
+ const bool keepLhsLengthInAllocatableAssignment =
+ isWholeAllocatableAssignment && lhsType.has_value() &&
+ lhsType->category() == Fortran::common::TypeCategory::Character &&
+ !lhsType->HasDeferredTypeParameter();
+ const bool lhsHasVectorSubscripts =
+ Fortran::evaluate::HasVectorSubscript(assign.lhs);
+
+ // Helper to generate the code evaluating the right-hand side.
+ auto evaluateRhs = [&](Fortran::lower::StatementContext &stmtCtx) {
+ hlfir::Entity rhs = Fortran::lower::convertExprToHLFIR(
+ loc, *this, assign.rhs, localSymbols, stmtCtx);
+ // Load trivial scalar RHS to allow the loads to be hoisted outside of
+ // loops early if possible. This also dereferences pointer and
+ // allocatable RHS: the target is being assigned from.
+ rhs = hlfir::loadTrivialScalar(loc, builder, rhs);
+ // In intrinsic assignments, the LHS type may not match the RHS type, in
+ // which case an implicit conversion of the LHS must be done. The
+ // front-end usually makes it explicit, unless it cannot (whole
+ // allocatable LHS or Logical<->Integer assignment extension). Recognize
+ // any type mismatches here and insert explicit scalar convert or
+ // ElementalOp for array assignment. Preserve the RHS lower bounds on the
+ // converted entity in case of assignment to whole allocatables so to
+ // propagate the lower bounds to the LHS in case of reallocation.
+ if (!userDefinedAssignment)
+ rhs = genImplicitConvert(assign, rhs, isWholeAllocatableAssignment,
+ stmtCtx);
+ return rhs;
+ };
- // Helper to generate the code evaluating the left-hand side.
- auto evaluateLhs = [&](Fortran::lower::StatementContext &stmtCtx) {
- hlfir::Entity lhs = Fortran::lower::convertExprToHLFIR(
- loc, *this, assign.lhs, localSymbols, stmtCtx);
- // Dereference pointer LHS: the target is being assigned to.
- // Same for allocatables outside of whole allocatable assignments.
- if (!isWholeAllocatableAssignment &&
- !isUserDefAssignToPointerOrAllocatable)
- lhs = hlfir::derefPointersAndAllocatables(loc, builder, lhs);
- return lhs;
- };
+ // Helper to generate the code evaluating the left-hand side.
+ auto evaluateLhs = [&](Fortran::lower::StatementContext &stmtCtx) {
+ hlfir::Entity lhs = Fortran::lower::convertExprToHLFIR(
+ loc, *this, assign.lhs, localSymbols, stmtCtx);
+ // Dereference pointer LHS: the target is being assigned to.
+ // Same for allocatables outside of whole allocatable assignments.
+ if (!isWholeAllocatableAssignment && !isUserDefAssignToPointerOrAllocatable)
+ lhs = hlfir::derefPointersAndAllocatables(loc, builder, lhs);
+ return lhs;
+ };
- if (!isInsideHlfirForallOrWhere() && !lhsHasVectorSubscripts &&
- !userDefinedAssignment) {
- Fortran::lower::StatementContext localStmtCtx;
- hlfir::Entity rhs = evaluateRhs(localStmtCtx);
- hlfir::Entity lhs = evaluateLhs(localStmtCtx);
- builder.create<hlfir::AssignOp>(loc, rhs, lhs,
- isWholeAllocatableAssignment,
- keepLhsLengthInAllocatableAssignment);
- return;
+ if (!isInsideHlfirForallOrWhere() && !lhsHasVectorSubscripts &&
+ !userDefinedAssignment) {
+ Fortran::lower::StatementContext localStmtCtx;
+ hlfir::Entity rhs = evaluateRhs(localStmtCtx);
+ hlfir::Entity lhs = evaluateLhs(localStmtCtx);
+ builder.create<hlfir::AssignOp>(loc, rhs, lhs, isWholeAllocatableAssignment,
+ keepLhsLengthInAllocatableAssignment);
+ return;
+ }
+ // Assignments inside Forall, Where, or assignments to a vector subscripted
+ // left-hand side requires using an hlfir.region_assign in HLFIR. The
+ // right-hand side and left-hand side must be evaluated inside the
+ // hlfir.region_assign regions.
+ auto regionAssignOp = builder.create<hlfir::RegionAssignOp>(loc);
+
+ // Lower RHS in its own region.
+ builder.createBlock(®ionAssignOp.getRhsRegion());
+ Fortran::lower::StatementContext rhsContext;
+ hlfir::Entity rhs = evaluateRhs(rhsContext);
+ auto rhsYieldOp = builder.create<hlfir::YieldOp>(loc, rhs);
+ genCleanUpInRegionIfAny(loc, builder, rhsYieldOp.getCleanup(), rhsContext);
+ // Lower LHS in its own region.
+ builder.createBlock(®ionAssignOp.getLhsRegion());
+ Fortran::lower::StatementContext lhsContext;
+ mlir::Value lhsYield = nullptr;
+ if (!lhsHasVectorSubscripts) {
+ hlfir::Entity lhs = evaluateLhs(lhsContext);
+ auto lhsYieldOp = builder.create<hlfir::YieldOp>(loc, lhs);
+ genCleanUpInRegionIfAny(loc, builder, lhsYieldOp.getCleanup(), lhsContext);
+ lhsYield = lhs;
+ } else {
+ hlfir::ElementalAddrOp elementalAddr =
+ Fortran::lower::convertVectorSubscriptedExprToElementalAddr(
+ loc, *this, assign.lhs, localSymbols, lhsContext);
+ genCleanUpInRegionIfAny(loc, builder, elementalAddr.getCleanup(),
+ lhsContext);
+ lhsYield = elementalAddr.getYieldOp().getEntity();
+ }
+ assert(lhsYield && "must have been set");
+
+ // Add "realloc" flag to hlfir.region_assign.
+ if (isWholeAllocatableAssignment)
+ TODO(loc, "assignment to a whole allocatable inside FORALL");
+
+ // Generate the hlfir.region_assign userDefinedAssignment region.
+ if (userDefinedAssignment) {
+ mlir::Type rhsType = rhs.getType();
+ mlir::Type lhsType = lhsYield.getType();
+ if (userDefinedAssignment->IsElemental()) {
+ rhsType = hlfir::getEntityElementType(rhs);
+ lhsType = hlfir::getEntityElementType(hlfir::Entity{lhsYield});
}
- // Assignments inside Forall, Where, or assignments to a vector subscripted
- // left-hand side requires using an hlfir.region_assign in HLFIR. The
- // right-hand side and left-hand side must be evaluated inside the
- // hlfir.region_assign regions.
- auto regionAssignOp = builder.create<hlfir::RegionAssignOp>(loc);
-
- // Lower RHS in its own region.
- builder.createBlock(®ionAssignOp.getRhsRegion());
- Fortran::lower::StatementContext rhsContext;
- hlfir::Entity rhs = evaluateRhs(rhsContext);
- auto rhsYieldOp = builder.create<hlfir::YieldOp>(loc, rhs);
- genCleanUpInRegionIfAny(loc, builder, rhsYieldOp.getCleanup(), rhsContext);
- // Lower LHS in its own region.
- builder.createBlock(®ionAssignOp.getLhsRegion());
- Fortran::lower::StatementContext lhsContext;
- mlir::Value lhsYield = nullptr;
- if (!lhsHasVectorSubscripts) {
- hlfir::Entity lhs = evaluateLhs(lhsContext);
- auto lhsYieldOp = builder.create<hlfir::YieldOp>(loc, lhs);
- genCleanUpInRegionIfAny(loc, builder, lhsYieldOp.getCleanup(),
- lhsContext);
- lhsYield = lhs;
- } else {
- hlfir::ElementalAddrOp elementalAddr =
- Fortran::lower::convertVectorSubscriptedExprToElementalAddr(
- loc, *this, assign.lhs, localSymbols, lhsContext);
- genCleanUpInRegionIfAny(loc, builder, elementalAddr.getCleanup(),
- lhsContext);
- lhsYield = elementalAddr.getYieldOp().getEntity();
- }
- assert(lhsYield && "must have been set");
-
- // Add "realloc" flag to hlfir.region_assign.
- if (isWholeAllocatableAssignment)
- TODO(loc, "assignment to a whole allocatable inside FORALL");
-
- // Generate the hlfir.region_assign userDefinedAssignment region.
- if (userDefinedAssignment) {
- mlir::Type rhsType = rhs.getType();
- mlir::Type lhsType = lhsYield.getType();
- if (userDefinedAssignment->IsElemental()) {
- rhsType = hlfir::getEntityElementType(rhs);
- lhsType = hlfir::getEntityElementType(hlfir::Entity{lhsYield});
- }
- builder.createBlock(®ionAssignOp.getUserDefinedAssignment(),
- mlir::Region::iterator{}, {rhsType, lhsType},
- {loc, loc});
- auto end = builder.create<fir::FirEndOp>(loc);
- builder.setInsertionPoint(end);
- hlfir::Entity lhsBlockArg{regionAssignOp.getUserAssignmentLhs()};
- hlfir::Entity rhsBlockArg{regionAssignOp.getUserAssignmentRhs()};
- Fortran::lower::convertUserDefinedAssignmentToHLFIR(
- loc, *this, *userDefinedAssignment, lhsBlockArg, rhsBlockArg,
- localSymbols);
- }
- builder.setInsertionPointAfter(regionAssignOp);
- }
+ builder.createBlock(®ionAssignOp.getUserDefinedAssignment(),
+ mlir::Region::iterator{}, {rhsType, lhsType},
+ {loc, loc});
+ auto end = builder.create<fir::FirEndOp>(loc);
+ builder.setInsertionPoint(end);
+ hlfir::Entity lhsBlockArg{regionAssignOp.getUserAssignmentLhs()};
+ hlfir::Entity rhsBlockArg{regionAssignOp.getUserAssignmentRhs()};
+ Fortran::lower::convertUserDefinedAssignmentToHLFIR(
+ loc, *this, *userDefinedAssignment, lhsBlockArg, rhsBlockArg,
+ localSymbols);
+ }
+ builder.setInsertionPointAfter(regionAssignOp);
+}
- /// Shared for both assignments and pointer assignments.
- void genAssignment(const Fortran::evaluate::Assignment &assign) {
- mlir::Location loc = toLocation();
- if (lowerToHighLevelFIR()) {
- std::visit(
- Fortran::common::visitors{
- [&](const Fortran::evaluate::Assignment::Intrinsic &) {
- genDataAssignment(assign, /*userDefinedAssignment=*/nullptr);
- },
- [&](const Fortran::evaluate::ProcedureRef &procRef) {
- genDataAssignment(assign, /*userDefinedAssignment=*/&procRef);
- },
- [&](const Fortran::evaluate::Assignment::BoundsSpec &lbExprs) {
- if (isInsideHlfirForallOrWhere())
- TODO(loc, "pointer assignment inside FORALL");
- genPointerAssignment(loc, assign, lbExprs);
- },
- [&](const Fortran::evaluate::Assignment::BoundsRemapping
- &boundExprs) {
- if (isInsideHlfirForallOrWhere())
- TODO(loc, "pointer assignment inside FORALL");
- genPointerAssignment(loc, assign, boundExprs);
- },
- },
- assign.u);
- return;
- }
- if (explicitIterationSpace()) {
- Fortran::lower::createArrayLoads(*this, explicitIterSpace, localSymbols);
- explicitIterSpace.genLoopNest();
- }
- Fortran::lower::StatementContext stmtCtx;
+/// Shared for both assignments and pointer assignments.
+void FirConverter::genAssignment(const Fortran::evaluate::Assignment &assign) {
+ mlir::Location loc = toLocation();
+ if (lowerToHighLevelFIR()) {
std::visit(
Fortran::common::visitors{
- // [1] Plain old assignment.
[&](const Fortran::evaluate::Assignment::Intrinsic &) {
- const Fortran::semantics::Symbol *sym =
- Fortran::evaluate::GetLastSymbol(assign.lhs);
-
- if (!sym)
- TODO(loc, "assignment to pointer result of function reference");
-
- std::optional<Fortran::evaluate::DynamicType> lhsType =
- assign.lhs.GetType();
- assert(lhsType && "lhs cannot be typeless");
- std::optional<Fortran::evaluate::DynamicType> rhsType =
- assign.rhs.GetType();
-
- // Assignment to/from polymorphic entities are done with the
- // runtime.
- if (lhsType->IsPolymorphic() ||
- lhsType->IsUnlimitedPolymorphic() ||
- (rhsType && (rhsType->IsPolymorphic() ||
- rhsType->IsUnlimitedPolymorphic()))) {
- mlir::Value lhs;
- if (Fortran::lower::isWholeAllocatable(assign.lhs))
- lhs = genExprMutableBox(loc, assign.lhs).getAddr();
- else
- lhs = fir::getBase(genExprBox(loc, assign.lhs, stmtCtx));
- mlir::Value rhs =
- fir::getBase(genExprBox(loc, assign.rhs, stmtCtx));
- if ((lhsType->IsPolymorphic() ||
- lhsType->IsUnlimitedPolymorphic()) &&
- Fortran::lower::isWholeAllocatable(assign.lhs))
- fir::runtime::genAssignPolymorphic(*builder, loc, lhs, rhs);
- else
- fir::runtime::genAssign(*builder, loc, lhs, rhs);
- return;
- }
-
- // Note: No ad-hoc handling for pointers is required here. The
- // target will be assigned as per 2018 10.2.1.3 p2. genExprAddr
- // on a pointer returns the target address and not the address of
- // the pointer variable.
-
- if (assign.lhs.Rank() > 0 || explicitIterationSpace()) {
- if (isDerivedCategory(lhsType->category()) &&
- Fortran::semantics::IsFinalizable(
- lhsType->GetDerivedTypeSpec()))
- TODO(loc, "derived-type finalization with array assignment");
- // Array assignment
- // See Fortran 2018 10.2.1.3 p5, p6, and p7
- genArrayAssignment(assign, stmtCtx);
- return;
- }
-
- // Scalar assignment
- const bool isNumericScalar =
- isNumericScalarCategory(lhsType->category());
- const bool isVector =
- isDerivedCategory(lhsType->category()) &&
- lhsType->GetDerivedTypeSpec().IsVectorType();
- fir::ExtendedValue rhs = (isNumericScalar || isVector)
- ? genExprValue(assign.rhs, stmtCtx)
- : genExprAddr(assign.rhs, stmtCtx);
- const bool lhsIsWholeAllocatable =
- Fortran::lower::isWholeAllocatable(assign.lhs);
- std::optional<fir::factory::MutableBoxReallocation> lhsRealloc;
- std::optional<fir::MutableBoxValue> lhsMutableBox;
-
- // Set flag to know if the LHS needs finalization. Polymorphic,
- // unlimited polymorphic assignment will be done with genAssign.
- // Assign runtime function performs the finalization.
- bool needFinalization = !lhsType->IsPolymorphic() &&
- !lhsType->IsUnlimitedPolymorphic() &&
- (isDerivedCategory(lhsType->category()) &&
- Fortran::semantics::IsFinalizable(
- lhsType->GetDerivedTypeSpec()));
-
- auto lhs = [&]() -> fir::ExtendedValue {
- if (lhsIsWholeAllocatable) {
- lhsMutableBox = genExprMutableBox(loc, assign.lhs);
- // Finalize if needed.
- if (needFinalization) {
- mlir::Value isAllocated =
- fir::factory::genIsAllocatedOrAssociatedTest(
- *builder, loc, *lhsMutableBox);
- builder->genIfThen(loc, isAllocated)
- .genThen([&]() {
- fir::runtime::genDerivedTypeDestroy(
- *builder, loc, fir::getBase(*lhsMutableBox));
- })
- .end();
- needFinalization = false;
- }
-
- llvm::SmallVector<mlir::Value> lengthParams;
- if (const fir::CharBoxValue *charBox = rhs.getCharBox())
- lengthParams.push_back(charBox->getLen());
- else if (fir::isDerivedWithLenParameters(rhs))
- TODO(loc, "assignment to derived type allocatable with "
- "LEN parameters");
- lhsRealloc = fir::factory::genReallocIfNeeded(
- *builder, loc, *lhsMutableBox,
- /*shape=*/std::nullopt, lengthParams);
- return lhsRealloc->newValue;
- }
- return genExprAddr(assign.lhs, stmtCtx);
- }();
-
- if (isNumericScalar || isVector) {
- // Fortran 2018 10.2.1.3 p8 and p9
- // Conversions should have been inserted by semantic analysis,
- // but they can be incorrect between the rhs and lhs. Correct
- // that here.
- mlir::Value addr = fir::getBase(lhs);
- mlir::Value val = fir::getBase(rhs);
- // A function with multiple entry points returning different
- // types tags all result variables with one of the largest
- // types to allow them to share the same storage. Assignment
- // to a result variable of one of the other types requires
- // conversion to the actual type.
- mlir::Type toTy = genType(assign.lhs);
-
- // If Cray pointee, need to handle the address
- // Array is handled in genCoordinateOp.
- if (sym->test(Fortran::semantics::Symbol::Flag::CrayPointee) &&
- sym->Rank() == 0) {
- // get the corresponding Cray pointer
-
- auto ptrSym = Fortran::lower::getCrayPointer(*sym);
- fir::ExtendedValue ptr =
- getSymbolExtendedValue(ptrSym, nullptr);
- mlir::Value ptrVal = fir::getBase(ptr);
- mlir::Type ptrTy = genType(*ptrSym);
-
- fir::ExtendedValue pte =
- getSymbolExtendedValue(*sym, nullptr);
- mlir::Value pteVal = fir::getBase(pte);
- mlir::Value cnvrt = Fortran::lower::addCrayPointerInst(
- loc, *builder, ptrVal, ptrTy, pteVal.getType());
- addr = builder->create<fir::LoadOp>(loc, cnvrt);
- }
- mlir::Value cast =
- isVector ? val
- : builder->convertWithSemantics(loc, toTy, val);
- if (fir::dyn_cast_ptrEleTy(addr.getType()) != toTy) {
- assert(isFuncResultDesignator(assign.lhs) && "type mismatch");
- addr = builder->createConvert(
- toLocation(), builder->getRefType(toTy), addr);
- }
- builder->create<fir::StoreOp>(loc, cast, addr);
- } else if (isCharacterCategory(lhsType->category())) {
- // Fortran 2018 10.2.1.3 p10 and p11
- fir::factory::CharacterExprHelper{*builder, loc}.createAssign(
- lhs, rhs);
- } else if (isDerivedCategory(lhsType->category())) {
- // Handle parent component.
- if (Fortran::lower::isParentComponent(assign.lhs)) {
- if (!fir::getBase(lhs).getType().isa<fir::BaseBoxType>())
- lhs = fir::getBase(builder->createBox(loc, lhs));
- lhs = Fortran::lower::updateBoxForParentComponent(*this, lhs,
- assign.lhs);
- }
-
- // Fortran 2018 10.2.1.3 p13 and p14
- // Recursively gen an assignment on each element pair.
- fir::factory::genRecordAssignment(*builder, loc, lhs, rhs,
- needFinalization);
- } else {
- llvm_unreachable("unknown category");
- }
- if (lhsIsWholeAllocatable) {
- assert(lhsRealloc.has_value());
- fir::factory::finalizeRealloc(*builder, loc, *lhsMutableBox,
- /*lbounds=*/std::nullopt,
- /*takeLboundsIfRealloc=*/false,
- *lhsRealloc);
- }
+ genDataAssignment(assign, /*userDefinedAssignment=*/nullptr);
},
-
- // [2] User defined assignment. If the context is a scalar
- // expression then call the procedure.
[&](const Fortran::evaluate::ProcedureRef &procRef) {
- Fortran::lower::StatementContext &ctx =
- explicitIterationSpace() ? explicitIterSpace.stmtContext()
- : stmtCtx;
- Fortran::lower::createSubroutineCall(
- *this, procRef, explicitIterSpace, implicitIterSpace,
- localSymbols, ctx, /*isUserDefAssignment=*/true);
+ genDataAssignment(assign, /*userDefinedAssignment=*/&procRef);
},
-
[&](const Fortran::evaluate::Assignment::BoundsSpec &lbExprs) {
- return genPointerAssignment(loc, assign, lbExprs);
+ if (isInsideHlfirForallOrWhere())
+ TODO(loc, "pointer assignment inside FORALL");
+ genPointerAssignment(loc, assign, lbExprs);
},
[&](const Fortran::evaluate::Assignment::BoundsRemapping
&boundExprs) {
- return genPointerAssignment(loc, assign, boundExprs);
+ if (isInsideHlfirForallOrWhere())
+ TODO(loc, "pointer assignment inside FORALL");
+ genPointerAssignment(loc, assign, boundExprs);
},
},
assign.u);
- if (explicitIterationSpace())
- Fortran::lower::createArrayMergeStores(*this, explicitIterSpace);
- }
-
- // Is the insertion point of the builder directly or indirectly set
- // inside any operation of type "Op"?
- template <typename... Op>
- bool isInsideOp() const {
- mlir::Block *block = builder->getInsertionBlock();
- mlir::Operation *op = block ? block->getParentOp() : nullptr;
- while (op) {
- if (mlir::isa<Op...>(op))
- return true;
- op = op->getParentOp();
- }
- return false;
- }
- bool isInsideHlfirForallOrWhere() const {
- return isInsideOp<hlfir::ForallOp, hlfir::WhereOp>();
- }
- bool isInsideHlfirWhere() const { return isInsideOp<hlfir::WhereOp>(); }
+ return;
+ }
+ if (explicitIterationSpace()) {
+ Fortran::lower::createArrayLoads(*this, explicitIterSpace, localSymbols);
+ explicitIterSpace.genLoopNest();
+ }
+ Fortran::lower::StatementContext stmtCtx;
+ std::visit(
+ Fortran::common::visitors{
+ // [1] Plain old assignment.
+ [&](const Fortran::evaluate::Assignment::Intrinsic &) {
+ const Fortran::semantics::Symbol *sym =
+ Fortran::evaluate::GetLastSymbol(assign.lhs);
+
+ if (!sym)
+ TODO(loc, "assignment to pointer result of function reference");
+
+ std::optional<Fortran::evaluate::DynamicType> lhsType =
+ assign.lhs.GetType();
+ assert(lhsType && "lhs cannot be typeless");
+ std::optional<Fortran::evaluate::DynamicType> rhsType =
+ assign.rhs.GetType();
+
+ // Assignment to/from polymorphic entities are done with the
+ // runtime.
+ if (lhsType->IsPolymorphic() || lhsType->IsUnlimitedPolymorphic() ||
+ (rhsType && (rhsType->IsPolymorphic() ||
+ rhsType->IsUnlimitedPolymorphic()))) {
+ mlir::Value lhs;
+ if (Fortran::lower::isWholeAllocatable(assign.lhs))
+ lhs = genExprMutableBox(loc, assign.lhs).getAddr();
+ else
+ lhs = fir::getBase(genExprBox(loc, assign.lhs, stmtCtx));
+ mlir::Value rhs =
+ fir::getBase(genExprBox(loc, assign.rhs, stmtCtx));
+ if ((lhsType->IsPolymorphic() ||
+ lhsType->IsUnlimitedPolymorphic()) &&
+ Fortran::lower::isWholeAllocatable(assign.lhs))
+ fir::runtime::genAssignPolymorphic(*builder, loc, lhs, rhs);
+ else
+ fir::runtime::genAssign(*builder, loc, lhs, rhs);
+ return;
+ }
- void genFIR(const Fortran::parser::WhereConstruct &c) {
- mlir::Location loc = getCurrentLocation();
- hlfir::WhereOp whereOp;
+ // Note: No ad-hoc handling for pointers is required here. The
+ // target will be assigned as per 2018 10.2.1.3 p2. genExprAddr
+ // on a pointer returns the target address and not the address of
+ // the pointer variable.
+
+ if (assign.lhs.Rank() > 0 || explicitIterationSpace()) {
+ if (isDerivedCategory(lhsType->category()) &&
+ Fortran::semantics::IsFinalizable(
+ lhsType->GetDerivedTypeSpec()))
+ TODO(loc, "derived-type finalization with array assignment");
+ // Array assignment
+ // See Fortran 2018 10.2.1.3 p5, p6, and p7
+ genArrayAssignment(assign, stmtCtx);
+ return;
+ }
- if (!lowerToHighLevelFIR()) {
- implicitIterSpace.growStack();
- } else {
- whereOp = builder->create<hlfir::WhereOp>(loc);
- builder->createBlock(&whereOp.getMaskRegion());
- }
+ // Scalar assignment
+ const bool isNumericScalar =
+ isNumericScalarCategory(lhsType->category());
+ const bool isVector = isDerivedCategory(lhsType->category()) &&
+ lhsType->GetDerivedTypeSpec().IsVectorType();
+ fir::ExtendedValue rhs = (isNumericScalar || isVector)
+ ? genExprValue(assign.rhs, stmtCtx)
+ : genExprAddr(assign.rhs, stmtCtx);
+ const bool lhsIsWholeAllocatable =
+ Fortran::lower::isWholeAllocatable(assign.lhs);
+ std::optional<fir::factory::MutableBoxReallocation> lhsRealloc;
+ std::optional<fir::MutableBoxValue> lhsMutableBox;
+
+ // Set flag to know if the LHS needs finalization. Polymorphic,
+ // unlimited polymorphic assignment will be done with genAssign.
+ // Assign runtime function performs the finalization.
+ bool needFinalization = !lhsType->IsPolymorphic() &&
+ !lhsType->IsUnlimitedPolymorphic() &&
+ (isDerivedCategory(lhsType->category()) &&
+ Fortran::semantics::IsFinalizable(
+ lhsType->GetDerivedTypeSpec()));
+
+ auto lhs = [&]() -> fir::ExtendedValue {
+ if (lhsIsWholeAllocatable) {
+ lhsMutableBox = genExprMutableBox(loc, assign.lhs);
+ // Finalize if needed.
+ if (needFinalization) {
+ mlir::Value isAllocated =
+ fir::factory::genIsAllocatedOrAssociatedTest(
+ *builder, loc, *lhsMutableBox);
+ builder->genIfThen(loc, isAllocated)
+ .genThen([&]() {
+ fir::runtime::genDerivedTypeDestroy(
+ *builder, loc, fir::getBase(*lhsMutableBox));
+ })
+ .end();
+ needFinalization = false;
+ }
- // Lower the where mask. For HLFIR, this is done in the hlfir.where mask
- // region.
- genNestedStatement(
- std::get<
- Fortran::parser::Statement<Fortran::parser::WhereConstructStmt>>(
- c.t));
-
- // Lower WHERE body. For HLFIR, this is done in the hlfir.where body
- // region.
- if (whereOp)
- builder->createBlock(&whereOp.getBody());
-
- for (const auto &body :
- std::get<std::list<Fortran::parser::WhereBodyConstruct>>(c.t))
- genFIR(body);
- for (const auto &e :
- std::get<std::list<Fortran::parser::WhereConstruct::MaskedElsewhere>>(
- c.t))
- genFIR(e);
- if (const auto &e =
- std::get<std::optional<Fortran::parser::WhereConstruct::Elsewhere>>(
- c.t);
- e.has_value())
- genFIR(*e);
- genNestedStatement(
- std::get<Fortran::parser::Statement<Fortran::parser::EndWhereStmt>>(
- c.t));
-
- if (whereOp) {
- // For HLFIR, create fir.end terminator in the last hlfir.elsewhere, or
- // in the hlfir.where if it had no elsewhere.
- builder->create<fir::FirEndOp>(loc);
- builder->setInsertionPointAfter(whereOp);
- }
- }
- void genFIR(const Fortran::parser::WhereBodyConstruct &body) {
- std::visit(
- Fortran::common::visitors{
- [&](const Fortran::parser::Statement<
- Fortran::parser::AssignmentStmt> &stmt) {
- genNestedStatement(stmt);
- },
- [&](const Fortran::parser::Statement<Fortran::parser::WhereStmt>
- &stmt) { genNestedStatement(stmt); },
- [&](const Fortran::common::Indirection<
- Fortran::parser::WhereConstruct> &c) { genFIR(c.value()); },
- },
- body.u);
- }
+ llvm::SmallVector<mlir::Value> lengthParams;
+ if (const fir::CharBoxValue *charBox = rhs.getCharBox())
+ lengthParams.push_back(charBox->getLen());
+ else if (fir::isDerivedWithLenParameters(rhs))
+ TODO(loc, "assignment to derived type allocatable with "
+ "LEN parameters");
+ lhsRealloc = fir::factory::genReallocIfNeeded(
+ *builder, loc, *lhsMutableBox,
+ /*shape=*/std::nullopt, lengthParams);
+ return lhsRealloc->newValue;
+ }
+ return genExprAddr(assign.lhs, stmtCtx);
+ }();
+
+ if (isNumericScalar || isVector) {
+ // Fortran 2018 10.2.1.3 p8 and p9
+ // Conversions should have been inserted by semantic analysis,
+ // but they can be incorrect between the rhs and lhs. Correct
+ // that here.
+ mlir::Value addr = fir::getBase(lhs);
+ mlir::Value val = fir::getBase(rhs);
+ // A function with multiple entry points returning different
+ // types tags all result variables with one of the largest
+ // types to allow them to share the same storage. Assignment
+ // to a result variable of one of the other types requires
+ // conversion to the actual type.
+ mlir::Type toTy = genType(assign.lhs);
+
+ // If Cray pointee, need to handle the address
+ // Array is handled in genCoordinateOp.
+ if (sym->test(Fortran::semantics::Symbol::Flag::CrayPointee) &&
+ sym->Rank() == 0) {
+ // get the corresponding Cray pointer
+
+ auto ptrSym = Fortran::lower::getCrayPointer(*sym);
+ fir::ExtendedValue ptr =
+ getSymbolExtendedValue(ptrSym, nullptr);
+ mlir::Value ptrVal = fir::getBase(ptr);
+ mlir::Type ptrTy = genType(*ptrSym);
+
+ fir::ExtendedValue pte = getSymbolExtendedValue(*sym, nullptr);
+ mlir::Value pteVal = fir::getBase(pte);
+ mlir::Value cnvrt = Fortran::lower::addCrayPointerInst(
+ loc, *builder, ptrVal, ptrTy, pteVal.getType());
+ addr = builder->create<fir::LoadOp>(loc, cnvrt);
+ }
+ mlir::Value cast =
+ isVector ? val
+ : builder->convertWithSemantics(loc, toTy, val);
+ if (fir::dyn_cast_ptrEleTy(addr.getType()) != toTy) {
+ assert(isFuncResultDesignator(assign.lhs) && "type mismatch");
+ addr = builder->createConvert(toLocation(),
+ builder->getRefType(toTy), addr);
+ }
+ builder->create<fir::StoreOp>(loc, cast, addr);
+ } else if (isCharacterCategory(lhsType->category())) {
+ // Fortran 2018 10.2.1.3 p10 and p11
+ fir::factory::CharacterExprHelper{*builder, loc}.createAssign(
+ lhs, rhs);
+ } else if (isDerivedCategory(lhsType->category())) {
+ // Handle parent component.
+ if (Fortran::lower::isParentComponent(assign.lhs)) {
+ if (!fir::getBase(lhs).getType().isa<fir::BaseBoxType>())
+ lhs = fir::getBase(builder->createBox(loc, lhs));
+ lhs = Fortran::lower::updateBoxForParentComponent(*this, lhs,
+ assign.lhs);
+ }
- /// Lower a Where or Elsewhere mask into an hlfir mask region.
- void lowerWhereMaskToHlfir(mlir::Location loc,
- const Fortran::semantics::SomeExpr *maskExpr) {
- assert(maskExpr && "mask semantic analysis failed");
- Fortran::lower::StatementContext maskContext;
- hlfir::Entity mask = Fortran::lower::convertExprToHLFIR(
- loc, *this, *maskExpr, localSymbols, maskContext);
- mask = hlfir::loadTrivialScalar(loc, *builder, mask);
- auto yieldOp = builder->create<hlfir::YieldOp>(loc, mask);
- genCleanUpInRegionIfAny(loc, *builder, yieldOp.getCleanup(), maskContext);
- }
- void genFIR(const Fortran::parser::WhereConstructStmt &stmt) {
- const Fortran::semantics::SomeExpr *maskExpr = Fortran::semantics::GetExpr(
- std::get<Fortran::parser::LogicalExpr>(stmt.t));
- if (lowerToHighLevelFIR())
- lowerWhereMaskToHlfir(getCurrentLocation(), maskExpr);
- else
- implicitIterSpace.append(maskExpr);
- }
- void genFIR(const Fortran::parser::WhereConstruct::MaskedElsewhere &ew) {
- mlir::Location loc = getCurrentLocation();
- hlfir::ElseWhereOp elsewhereOp;
- if (lowerToHighLevelFIR()) {
- elsewhereOp = builder->create<hlfir::ElseWhereOp>(loc);
- // Lower mask in the mask region.
- builder->createBlock(&elsewhereOp.getMaskRegion());
- }
- genNestedStatement(
- std::get<
- Fortran::parser::Statement<Fortran::parser::MaskedElsewhereStmt>>(
- ew.t));
-
- // For HLFIR, lower the body in the hlfir.elsewhere body region.
- if (elsewhereOp)
- builder->createBlock(&elsewhereOp.getBody());
-
- for (const auto &body :
- std::get<std::list<Fortran::parser::WhereBodyConstruct>>(ew.t))
- genFIR(body);
- }
- void genFIR(const Fortran::parser::MaskedElsewhereStmt &stmt) {
- const auto *maskExpr = Fortran::semantics::GetExpr(
- std::get<Fortran::parser::LogicalExpr>(stmt.t));
- if (lowerToHighLevelFIR())
- lowerWhereMaskToHlfir(getCurrentLocation(), maskExpr);
- else
- implicitIterSpace.append(maskExpr);
- }
- void genFIR(const Fortran::parser::WhereConstruct::Elsewhere &ew) {
- if (lowerToHighLevelFIR()) {
- auto elsewhereOp =
- builder->create<hlfir::ElseWhereOp>(getCurrentLocation());
- builder->createBlock(&elsewhereOp.getBody());
- }
- genNestedStatement(
- std::get<Fortran::parser::Statement<Fortran::parser::ElsewhereStmt>>(
- ew.t));
- for (const auto &body :
- std::get<std::list<Fortran::parser::WhereBodyConstruct>>(ew.t))
- genFIR(body);
- }
- void genFIR(const Fortran::parser::ElsewhereStmt &stmt) {
- if (!lowerToHighLevelFIR())
- implicitIterSpace.append(nullptr);
- }
- void genFIR(const Fortran::parser::EndWhereStmt &) {
- if (!lowerToHighLevelFIR())
- implicitIterSpace.shrinkStack();
- }
+ // Fortran 2018 10.2.1.3 p13 and p14
+ // Recursively gen an assignment on each element pair.
+ fir::factory::genRecordAssignment(*builder, loc, lhs, rhs,
+ needFinalization);
+ } else {
+ llvm_unreachable("unknown category");
+ }
+ if (lhsIsWholeAllocatable) {
+ assert(lhsRealloc.has_value());
+ fir::factory::finalizeRealloc(*builder, loc, *lhsMutableBox,
+ /*lbounds=*/std::nullopt,
+ /*takeLboundsIfRealloc=*/false,
+ *lhsRealloc);
+ }
+ },
- void genFIR(const Fortran::parser::WhereStmt &stmt) {
- Fortran::lower::StatementContext stmtCtx;
- const auto &assign = std::get<Fortran::parser::AssignmentStmt>(stmt.t);
- const auto *mask = Fortran::semantics::GetExpr(
- std::get<Fortran::parser::LogicalExpr>(stmt.t));
- if (lowerToHighLevelFIR()) {
- mlir::Location loc = getCurrentLocation();
- auto whereOp = builder->create<hlfir::WhereOp>(loc);
- builder->createBlock(&whereOp.getMaskRegion());
- lowerWhereMaskToHlfir(loc, mask);
- builder->createBlock(&whereOp.getBody());
- genAssignment(*assign.typedAssignment->v);
- builder->create<fir::FirEndOp>(loc);
- builder->setInsertionPointAfter(whereOp);
- return;
- }
- implicitIterSpace.growStack();
- implicitIterSpace.append(mask);
- genAssignment(*assign.typedAssignment->v);
- implicitIterSpace.shrinkStack();
- }
+ // [2] User defined assignment. If the context is a scalar
+ // expression then call the procedure.
+ [&](const Fortran::evaluate::ProcedureRef &procRef) {
+ Fortran::lower::StatementContext &ctx =
+ explicitIterationSpace() ? explicitIterSpace.stmtContext()
+ : stmtCtx;
+ Fortran::lower::createSubroutineCall(
+ *this, procRef, explicitIterSpace, implicitIterSpace,
+ localSymbols, ctx, /*isUserDefAssignment=*/true);
+ },
- void genFIR(const Fortran::parser::PointerAssignmentStmt &stmt) {
- genAssignment(*stmt.typedAssignment->v);
- }
+ [&](const Fortran::evaluate::Assignment::BoundsSpec &lbExprs) {
+ return genPointerAssignment(loc, assign, lbExprs);
+ },
+ [&](const Fortran::evaluate::Assignment::BoundsRemapping
+ &boundExprs) {
+ return genPointerAssignment(loc, assign, boundExprs);
+ },
+ },
+ assign.u);
+ if (explicitIterationSpace())
+ Fortran::lower::createArrayMergeStores(*this, explicitIterSpace);
+}
- void genFIR(const Fortran::parser::AssignmentStmt &stmt) {
- genAssignment(*stmt.typedAssignment->v);
- }
+void FirConverter::genFIR(const Fortran::parser::WhereConstruct &c) {
+ mlir::Location loc = getCurrentLocation();
+ hlfir::WhereOp whereOp;
- void genFIR(const Fortran::parser::SyncAllStmt &stmt) {
- genSyncAllStatement(*this, stmt);
+ if (!lowerToHighLevelFIR()) {
+ implicitIterSpace.growStack();
+ } else {
+ whereOp = builder->create<hlfir::WhereOp>(loc);
+ builder->createBlock(&whereOp.getMaskRegion());
+ }
+
+ // Lower the where mask. For HLFIR, this is done in the hlfir.where mask
+ // region.
+ genNestedStatement(
+ std::get<Fortran::parser::Statement<Fortran::parser::WhereConstructStmt>>(
+ c.t));
+
+ // Lower WHERE body. For HLFIR, this is done in the hlfir.where body
+ // region.
+ if (whereOp)
+ builder->createBlock(&whereOp.getBody());
+
+ for (const auto &body :
+ std::get<std::list<Fortran::parser::WhereBodyConstruct>>(c.t))
+ genFIR(body);
+ for (const auto &e :
+ std::get<std::list<Fortran::parser::WhereConstruct::MaskedElsewhere>>(
+ c.t))
+ genFIR(e);
+ if (const auto &e =
+ std::get<std::optional<Fortran::parser::WhereConstruct::Elsewhere>>(
+ c.t);
+ e.has_value())
+ genFIR(*e);
+ genNestedStatement(
+ std::get<Fortran::parser::Statement<Fortran::parser::EndWhereStmt>>(c.t));
+
+ if (whereOp) {
+ // For HLFIR, create fir.end terminator in the last hlfir.elsewhere, or
+ // in the hlfir.where if it had no elsewhere.
+ builder->create<fir::FirEndOp>(loc);
+ builder->setInsertionPointAfter(whereOp);
}
+}
- void genFIR(const Fortran::parser::SyncImagesStmt &stmt) {
- genSyncImagesStatement(*this, stmt);
- }
+void FirConverter::genFIR(const Fortran::parser::WhereBodyConstruct &body) {
+ std::visit(
+ Fortran::common::visitors{
+ [&](const Fortran::parser::Statement<Fortran::parser::AssignmentStmt>
+ &stmt) { genNestedStatement(stmt); },
+ [&](const Fortran::parser::Statement<Fortran::parser::WhereStmt>
+ &stmt) { genNestedStatement(stmt); },
+ [&](const Fortran::common::Indirection<
+ Fortran::parser::WhereConstruct> &c) { genFIR(c.value()); },
+ },
+ body.u);
+}
- void genFIR(const Fortran::parser::SyncMemoryStmt &stmt) {
- genSyncMemoryStatement(*this, stmt);
- }
+/// Lower a Where or Elsewhere mask into an hlfir mask region.
+void FirConverter::lowerWhereMaskToHlfir(
+ mlir::Location loc, const Fortran::semantics::SomeExpr *maskExpr) {
+ assert(maskExpr && "mask semantic analysis failed");
+ Fortran::lower::StatementContext maskContext;
+ hlfir::Entity mask = Fortran::lower::convertExprToHLFIR(
+ loc, *this, *maskExpr, localSymbols, maskContext);
+ mask = hlfir::loadTrivialScalar(loc, *builder, mask);
+ auto yieldOp = builder->create<hlfir::YieldOp>(loc, mask);
+ genCleanUpInRegionIfAny(loc, *builder, yieldOp.getCleanup(), maskContext);
+}
- void genFIR(const Fortran::parser::SyncTeamStmt &stmt) {
- genSyncTeamStatement(*this, stmt);
- }
+void FirConverter::genFIR(const Fortran::parser::WhereConstructStmt &stmt) {
+ const Fortran::semantics::SomeExpr *maskExpr = Fortran::semantics::GetExpr(
+ std::get<Fortran::parser::LogicalExpr>(stmt.t));
+ if (lowerToHighLevelFIR())
+ lowerWhereMaskToHlfir(getCurrentLocation(), maskExpr);
+ else
+ implicitIterSpace.append(maskExpr);
+}
- void genFIR(const Fortran::parser::UnlockStmt &stmt) {
- genUnlockStatement(*this, stmt);
- }
+void FirConverter::genFIR(
+ const Fortran::parser::WhereConstruct::MaskedElsewhere &ew) {
+ mlir::Location loc = getCurrentLocation();
+ hlfir::ElseWhereOp elsewhereOp;
+ if (lowerToHighLevelFIR()) {
+ elsewhereOp = builder->create<hlfir::ElseWhereOp>(loc);
+ // Lower mask in the mask region.
+ builder->createBlock(&elsewhereOp.getMaskRegion());
+ }
+ genNestedStatement(
+ std::get<
+ Fortran::parser::Statement<Fortran::parser::MaskedElsewhereStmt>>(
+ ew.t));
+
+ // For HLFIR, lower the body in the hlfir.elsewhere body region.
+ if (elsewhereOp)
+ builder->createBlock(&elsewhereOp.getBody());
+
+ for (const auto &body :
+ std::get<std::list<Fortran::parser::WhereBodyConstruct>>(ew.t))
+ genFIR(body);
+}
- void genFIR(const Fortran::parser::AssignStmt &stmt) {
- const Fortran::semantics::Symbol &symbol =
- *std::get<Fortran::parser::Name>(stmt.t).symbol;
- mlir::Location loc = toLocation();
- mlir::Value labelValue = builder->createIntegerConstant(
- loc, genType(symbol), std::get<Fortran::parser::Label>(stmt.t));
- builder->create<fir::StoreOp>(loc, labelValue, getSymbolAddress(symbol));
- }
+void FirConverter::genFIR(const Fortran::parser::MaskedElsewhereStmt &stmt) {
+ const auto *maskExpr = Fortran::semantics::GetExpr(
+ std::get<Fortran::parser::LogicalExpr>(stmt.t));
+ if (lowerToHighLevelFIR())
+ lowerWhereMaskToHlfir(getCurrentLocation(), maskExpr);
+ else
+ implicitIterSpace.append(maskExpr);
+}
- void genFIR(const Fortran::parser::FormatStmt &) {
- // do nothing.
+void FirConverter::genFIR(
+ const Fortran::parser::WhereConstruct::Elsewhere &ew) {
+ if (lowerToHighLevelFIR()) {
+ auto elsewhereOp =
+ builder->create<hlfir::ElseWhereOp>(getCurrentLocation());
+ builder->createBlock(&elsewhereOp.getBody());
+ }
+ genNestedStatement(
+ std::get<Fortran::parser::Statement<Fortran::parser::ElsewhereStmt>>(
+ ew.t));
+ for (const auto &body :
+ std::get<std::list<Fortran::parser::WhereBodyConstruct>>(ew.t))
+ genFIR(body);
+}
- // FORMAT statements have no semantics. They may be lowered if used by a
- // data transfer statement.
- }
+void FirConverter::genFIR(const Fortran::parser::ElsewhereStmt &stmt) {
+ if (!lowerToHighLevelFIR())
+ implicitIterSpace.append(nullptr);
+}
- void genFIR(const Fortran::parser::PauseStmt &stmt) {
- genPauseStatement(*this, stmt);
- }
+void FirConverter::genFIR(const Fortran::parser::EndWhereStmt &) {
+ if (!lowerToHighLevelFIR())
+ implicitIterSpace.shrinkStack();
+}
- // call FAIL IMAGE in runtime
- void genFIR(const Fortran::parser::FailImageStmt &stmt) {
- genFailImageStatement(*this);
- }
+void FirConverter::genFIR(const Fortran::parser::WhereStmt &stmt) {
+ Fortran::lower::StatementContext stmtCtx;
+ const auto &assign = std::get<Fortran::parser::AssignmentStmt>(stmt.t);
+ const auto *mask = Fortran::semantics::GetExpr(
+ std::get<Fortran::parser::LogicalExpr>(stmt.t));
+ if (lowerToHighLevelFIR()) {
+ mlir::Location loc = getCurrentLocation();
+ auto whereOp = builder->create<hlfir::WhereOp>(loc);
+ builder->createBlock(&whereOp.getMaskRegion());
+ lowerWhereMaskToHlfir(loc, mask);
+ builder->createBlock(&whereOp.getBody());
+ genAssignment(*assign.typedAssignment->v);
+ builder->create<fir::FirEndOp>(loc);
+ builder->setInsertionPointAfter(whereOp);
+ return;
+ }
+ implicitIterSpace.growStack();
+ implicitIterSpace.append(mask);
+ genAssignment(*assign.typedAssignment->v);
+ implicitIterSpace.shrinkStack();
+}
- // call STOP, ERROR STOP in runtime
- void genFIR(const Fortran::parser::StopStmt &stmt) {
- genStopStatement(*this, stmt);
- }
+void FirConverter::genFIR(const Fortran::parser::PointerAssignmentStmt &stmt) {
+ genAssignment(*stmt.typedAssignment->v);
+}
- void genFIR(const Fortran::parser::ReturnStmt &stmt) {
- Fortran::lower::pft::FunctionLikeUnit *funit =
- getEval().getOwningProcedure();
- assert(funit && "not inside main program, function or subroutine");
- for (auto it = activeConstructStack.rbegin(),
- rend = activeConstructStack.rend();
- it != rend; ++it) {
- it->stmtCtx.finalizeAndKeep();
- }
- if (funit->isMainProgram()) {
- bridge.fctCtx().finalizeAndKeep();
- genExitRoutine();
- return;
- }
- mlir::Location loc = toLocation();
- if (stmt.v) {
- // Alternate return statement - If this is a subroutine where some
- // alternate entries have alternate returns, but the active entry point
- // does not, ignore the alternate return value. Otherwise, assign it
- // to the compiler-generated result variable.
- const Fortran::semantics::Symbol &symbol = funit->getSubprogramSymbol();
- if (Fortran::semantics::HasAlternateReturns(symbol)) {
- Fortran::lower::StatementContext stmtCtx;
- const Fortran::lower::SomeExpr *expr =
- Fortran::semantics::GetExpr(*stmt.v);
- assert(expr && "missing alternate return expression");
- mlir::Value altReturnIndex = builder->createConvert(
- loc, builder->getIndexType(), createFIRExpr(loc, expr, stmtCtx));
- builder->create<fir::StoreOp>(loc, altReturnIndex,
- getAltReturnResult(symbol));
- }
- }
- // Branch to the last block of the SUBROUTINE, which has the actual return.
- if (!funit->finalBlock) {
- mlir::OpBuilder::InsertPoint insPt = builder->saveInsertionPoint();
- Fortran::lower::setInsertionPointAfterOpenACCLoopIfInside(*builder);
- funit->finalBlock = builder->createBlock(&builder->getRegion());
- builder->restoreInsertionPoint(insPt);
- }
+void FirConverter::genFIR(const Fortran::parser::AssignmentStmt &stmt) {
+ genAssignment(*stmt.typedAssignment->v);
+}
- if (Fortran::lower::isInOpenACCLoop(*builder))
- Fortran::lower::genEarlyReturnInOpenACCLoop(*builder, loc);
- else
- builder->create<mlir::cf::BranchOp>(loc, funit->finalBlock);
- }
+void FirConverter::genFIR(const Fortran::parser::SyncAllStmt &stmt) {
+ genSyncAllStatement(*this, stmt);
+}
- void genFIR(const Fortran::parser::CycleStmt &) {
- genConstructExitBranch(*getEval().controlSuccessor);
- }
- void genFIR(const Fortran::parser::ExitStmt &) {
- genConstructExitBranch(*getEval().controlSuccessor);
- }
- void genFIR(const Fortran::parser::GotoStmt &) {
- genConstructExitBranch(*getEval().controlSuccessor);
- }
+void FirConverter::genFIR(const Fortran::parser::SyncImagesStmt &stmt) {
+ genSyncImagesStatement(*this, stmt);
+}
- // Nop statements - No code, or code is generated at the construct level.
- // But note that the genFIR call immediately below that wraps one of these
- // calls does block management, possibly starting a new block, and possibly
- // generating a branch to end a block. So these calls may still be required
- // for that functionality.
- void genFIR(const Fortran::parser::AssociateStmt &) {} // nop
- void genFIR(const Fortran::parser::BlockStmt &) {} // nop
- void genFIR(const Fortran::parser::CaseStmt &) {} // nop
- void genFIR(const Fortran::parser::ContinueStmt &) {} // nop
- void genFIR(const Fortran::parser::ElseIfStmt &) {} // nop
- void genFIR(const Fortran::parser::ElseStmt &) {} // nop
- void genFIR(const Fortran::parser::EndAssociateStmt &) {} // nop
- void genFIR(const Fortran::parser::EndBlockStmt &) {} // nop
- void genFIR(const Fortran::parser::EndDoStmt &) {} // nop
- void genFIR(const Fortran::parser::EndFunctionStmt &) {} // nop
- void genFIR(const Fortran::parser::EndIfStmt &) {} // nop
- void genFIR(const Fortran::parser::EndMpSubprogramStmt &) {} // nop
- void genFIR(const Fortran::parser::EndProgramStmt &) {} // nop
- void genFIR(const Fortran::parser::EndSelectStmt &) {} // nop
- void genFIR(const Fortran::parser::EndSubroutineStmt &) {} // nop
- void genFIR(const Fortran::parser::EntryStmt &) {} // nop
- void genFIR(const Fortran::parser::IfStmt &) {} // nop
- void genFIR(const Fortran::parser::IfThenStmt &) {} // nop
- void genFIR(const Fortran::parser::NonLabelDoStmt &) {} // nop
- void genFIR(const Fortran::parser::OmpEndLoopDirective &) {} // nop
- void genFIR(const Fortran::parser::SelectTypeStmt &) {} // nop
- void genFIR(const Fortran::parser::TypeGuardStmt &) {} // nop
-
- /// Generate FIR for Evaluation \p eval.
- void genFIR(Fortran::lower::pft::Evaluation &eval,
- bool unstructuredContext = true) {
- // Start a new unstructured block when applicable. When transitioning
- // from unstructured to structured code, unstructuredContext is true,
- // which accounts for the possibility that the structured code could be
- // a target that starts a new block.
- if (unstructuredContext)
- maybeStartBlock(eval.isConstruct() && eval.lowerAsStructured()
- ? eval.getFirstNestedEvaluation().block
- : eval.block);
-
- // Generate evaluation specific code. Even nop calls should usually reach
- // here in case they start a new block or require generation of a generic
- // end-of-block branch. An alternative is to add special case code
- // elsewhere, such as in the genFIR code for a parent construct.
- setCurrentEval(eval);
- setCurrentPosition(eval.position);
- eval.visit([&](const auto &stmt) { genFIR(stmt); });
-
- // Generate an end-of-block branch for several special cases. For
- // constructs, this can be done for either the end construct statement,
- // or for the construct itself, which will skip this code if the
- // end statement was visited first and generated a branch.
- Fortran::lower::pft::Evaluation *successor =
- eval.isConstruct() ? eval.getLastNestedEvaluation().lexicalSuccessor
- : eval.lexicalSuccessor;
- if (successor && blockIsUnterminated()) {
- if (successor->isIntermediateConstructStmt() &&
- successor->parentConstruct->lowerAsUnstructured())
- // Exit from an intermediate unstructured IF or SELECT construct block.
- genBranch(successor->parentConstruct->constructExit->block);
- else if (unstructuredContext && eval.isConstructStmt() &&
- successor == eval.controlSuccessor)
- // Exit from a degenerate, empty construct block.
- genBranch(eval.parentConstruct->constructExit->block);
- }
- }
+void FirConverter::genFIR(const Fortran::parser::SyncMemoryStmt &stmt) {
+ genSyncMemoryStatement(*this, stmt);
+}
- /// Map mlir function block arguments to the corresponding Fortran dummy
- /// variables. When the result is passed as a hidden argument, the Fortran
- /// result is also mapped. The symbol map is used to hold this mapping.
- void mapDummiesAndResults(Fortran::lower::pft::FunctionLikeUnit &funit,
- const Fortran::lower::CalleeInterface &callee) {
- assert(builder && "require a builder object at this point");
- using PassBy = Fortran::lower::CalleeInterface::PassEntityBy;
- auto mapPassedEntity = [&](const auto arg) {
- if (arg.passBy == PassBy::AddressAndLength) {
- if (callee.characterize().IsBindC())
- return;
- // TODO: now that fir call has some attributes regarding character
- // return, PassBy::AddressAndLength should be retired.
- mlir::Location loc = toLocation();
- fir::factory::CharacterExprHelper charHelp{*builder, loc};
- mlir::Value box =
- charHelp.createEmboxChar(arg.firArgument, arg.firLength);
- mapBlockArgToDummyOrResult(arg.entity->get(), box);
- } else {
- if (arg.entity.has_value()) {
- mapBlockArgToDummyOrResult(arg.entity->get(), arg.firArgument);
- } else {
- assert(funit.parentHasTupleHostAssoc() && "expect tuple argument");
- }
- }
- };
- for (const Fortran::lower::CalleeInterface::PassedEntity &arg :
- callee.getPassedArguments())
- mapPassedEntity(arg);
- if (std::optional<Fortran::lower::CalleeInterface::PassedEntity>
- passedResult = callee.getPassedResult()) {
- mapPassedEntity(*passedResult);
- // FIXME: need to make sure things are OK here. addSymbol may not be OK
- if (funit.primaryResult &&
- passedResult->entity->get() != *funit.primaryResult)
- mapBlockArgToDummyOrResult(
- *funit.primaryResult,
- getSymbolAddress(passedResult->entity->get()));
- }
- }
+void FirConverter::genFIR(const Fortran::parser::SyncTeamStmt &stmt) {
+ genSyncTeamStatement(*this, stmt);
+}
- /// Instantiate variable \p var and add it to the symbol map.
- /// See ConvertVariable.cpp.
- void instantiateVar(const Fortran::lower::pft::Variable &var,
- Fortran::lower::AggregateStoreMap &storeMap) {
- Fortran::lower::instantiateVariable(*this, var, localSymbols, storeMap);
- if (var.hasSymbol()) {
- if (var.getSymbol().test(
- Fortran::semantics::Symbol::Flag::OmpThreadprivate))
- Fortran::lower::genThreadprivateOp(*this, var);
-
- if (var.getSymbol().test(
- Fortran::semantics::Symbol::Flag::OmpDeclareTarget))
- Fortran::lower::genDeclareTargetIntGlobal(*this, var);
- }
- }
+void FirConverter::genFIR(const Fortran::parser::UnlockStmt &stmt) {
+ genUnlockStatement(*this, stmt);
+}
- /// Where applicable, save the exception state and halting and rounding
- /// modes at function entry and restore them at function exits.
- void manageFPEnvironment(Fortran::lower::pft::FunctionLikeUnit &funit) {
- mlir::Location loc = toLocation();
- mlir::Location endLoc =
- toLocation(Fortran::lower::pft::stmtSourceLoc(funit.endStmt));
- if (funit.hasIeeeAccess) {
- // Subject to F18 Clause 17.1p3, 17.3p3 states: If a flag is signaling
- // on entry to a procedure [...], the processor will set it to quiet
- // on entry and restore it to signaling on return. If a flag signals
- // during execution of a procedure, the processor shall not set it to
- // quiet on return.
- mlir::func::FuncOp testExcept = fir::factory::getFetestexcept(*builder);
- mlir::func::FuncOp clearExcept = fir::factory::getFeclearexcept(*builder);
- mlir::func::FuncOp raiseExcept = fir::factory::getFeraiseexcept(*builder);
- mlir::Value ones = builder->createIntegerConstant(
- loc, testExcept.getFunctionType().getInput(0), -1);
- mlir::Value exceptSet =
- builder->create<fir::CallOp>(loc, testExcept, ones).getResult(0);
- builder->create<fir::CallOp>(loc, clearExcept, exceptSet);
- bridge.fctCtx().attachCleanup([=]() {
- builder->create<fir::CallOp>(endLoc, raiseExcept, exceptSet);
- });
- }
- if (funit.mayModifyHaltingMode) {
- // F18 Clause 17.6p1: In a procedure [...], the processor shall not
- // change the halting mode on entry, and on return shall ensure that
- // the halting mode is the same as it was on entry.
- mlir::func::FuncOp getExcept = fir::factory::getFegetexcept(*builder);
- mlir::func::FuncOp disableExcept =
- fir::factory::getFedisableexcept(*builder);
- mlir::func::FuncOp enableExcept =
- fir::factory::getFeenableexcept(*builder);
- mlir::Value exceptSet =
- builder->create<fir::CallOp>(loc, getExcept).getResult(0);
- mlir::Value ones = builder->createIntegerConstant(
- loc, disableExcept.getFunctionType().getInput(0), -1);
- bridge.fctCtx().attachCleanup([=]() {
- builder->create<fir::CallOp>(endLoc, disableExcept, ones);
- builder->create<fir::CallOp>(endLoc, enableExcept, exceptSet);
- });
- }
- if (funit.mayModifyRoundingMode) {
- // F18 Clause 17.4.5: In a procedure [...], the processor shall not
- // change the rounding modes on entry, and on return shall ensure that
- // the rounding modes are the same as they were on entry.
- mlir::func::FuncOp getRounding =
- fir::factory::getLlvmGetRounding(*builder);
- mlir::func::FuncOp setRounding =
- fir::factory::getLlvmSetRounding(*builder);
- mlir::Value roundingMode =
- builder->create<fir::CallOp>(loc, getRounding).getResult(0);
- bridge.fctCtx().attachCleanup([=]() {
- builder->create<fir::CallOp>(endLoc, setRounding, roundingMode);
- });
- }
- }
+void FirConverter::genFIR(const Fortran::parser::AssignStmt &stmt) {
+ const Fortran::semantics::Symbol &symbol =
+ *std::get<Fortran::parser::Name>(stmt.t).symbol;
+ mlir::Location loc = toLocation();
+ mlir::Value labelValue = builder->createIntegerConstant(
+ loc, genType(symbol), std::get<Fortran::parser::Label>(stmt.t));
+ builder->create<fir::StoreOp>(loc, labelValue, getSymbolAddress(symbol));
+}
- /// Start translation of a function.
- void startNewFunction(Fortran::lower::pft::FunctionLikeUnit &funit) {
- assert(!builder && "expected nullptr");
- bridge.fctCtx().pushScope();
- bridge.openAccCtx().pushScope();
- const Fortran::semantics::Scope &scope = funit.getScope();
- LLVM_DEBUG(llvm::dbgs() << "\n[bridge - startNewFunction]";
- if (auto *sym = scope.symbol()) llvm::dbgs() << " " << *sym;
- llvm::dbgs() << "\n");
- Fortran::lower::CalleeInterface callee(funit, *this);
- mlir::func::FuncOp func = callee.addEntryBlockAndMapArguments();
- builder = new fir::FirOpBuilder(func, bridge.getKindMap());
- assert(builder && "FirOpBuilder did not instantiate");
- builder->setFastMathFlags(bridge.getLoweringOptions().getMathOptions());
- builder->setInsertionPointToStart(&func.front());
- func.setVisibility(mlir::SymbolTable::Visibility::Public);
- assert(blockId == 0 && "invalid blockId");
- assert(activeConstructStack.empty() && "invalid construct stack state");
-
- // Manage floating point exception, halting mode, and rounding mode
- // settings at function entry and exit.
- if (!funit.isMainProgram())
- manageFPEnvironment(funit);
-
- mapDummiesAndResults(funit, callee);
-
- // Map host associated symbols from parent procedure if any.
- if (funit.parentHasHostAssoc())
- funit.parentHostAssoc().internalProcedureBindings(*this, localSymbols);
-
- // Non-primary results of a function with multiple entry points.
- // These result values share storage with the primary result.
- llvm::SmallVector<Fortran::lower::pft::Variable> deferredFuncResultList;
-
- // Backup actual argument for entry character results with different
- // lengths. It needs to be added to the non-primary results symbol before
- // mapSymbolAttributes is called.
- Fortran::lower::SymbolBox resultArg;
- if (std::optional<Fortran::lower::CalleeInterface::PassedEntity>
- passedResult = callee.getPassedResult())
- resultArg = lookupSymbol(passedResult->entity->get());
+void FirConverter::genFIR(const Fortran::parser::FormatStmt &) {
+ // do nothing.
- Fortran::lower::AggregateStoreMap storeMap;
+ // FORMAT statements have no semantics. They may be lowered if used by a
+ // data transfer statement.
+}
- // Map all containing submodule and module equivalences and variables, in
- // case they are referenced. It might be better to limit this to variables
- // that are actually referenced, although that is more complicated when
- // there are equivalenced variables.
- auto &scopeVariableListMap =
- Fortran::lower::pft::getScopeVariableListMap(funit);
- for (auto *scp = &scope.parent(); !scp->IsGlobal(); scp = &scp->parent())
- if (scp->kind() == Fortran::semantics::Scope::Kind::Module)
- for (const auto &var : Fortran::lower::pft::getScopeVariableList(
- *scp, scopeVariableListMap))
- instantiateVar(var, storeMap);
+void FirConverter::genFIR(const Fortran::parser::PauseStmt &stmt) {
+ genPauseStatement(*this, stmt);
+}
- // Map function equivalences and variables.
- mlir::Value primaryFuncResultStorage;
- for (const Fortran::lower::pft::Variable &var :
- Fortran::lower::pft::getScopeVariableList(scope)) {
- // Always instantiate aggregate storage blocks.
- if (var.isAggregateStore()) {
- instantiateVar(var, storeMap);
- continue;
- }
- const Fortran::semantics::Symbol &sym = var.getSymbol();
- if (funit.parentHasHostAssoc()) {
- // Never instantiate host associated variables, as they are already
- // instantiated from an argument tuple. Instead, just bind the symbol
- // to the host variable, which must be in the map.
- const Fortran::semantics::Symbol &ultimate = sym.GetUltimate();
- if (funit.parentHostAssoc().isAssociated(ultimate)) {
- copySymbolBinding(ultimate, sym);
- continue;
- }
- }
- if (!sym.IsFuncResult() || !funit.primaryResult) {
- instantiateVar(var, storeMap);
- } else if (&sym == funit.primaryResult) {
- instantiateVar(var, storeMap);
- primaryFuncResultStorage = getSymbolAddress(sym);
- } else {
- deferredFuncResultList.push_back(var);
- }
- }
+// call FAIL IMAGE in runtime
+void FirConverter::genFIR(const Fortran::parser::FailImageStmt &stmt) {
+ genFailImageStatement(*this);
+}
- // TODO: should use same mechanism as equivalence?
- // One blocking point is character entry returns that need special handling
- // since they are not locally allocated but come as argument. CHARACTER(*)
- // is not something that fits well with equivalence lowering.
- for (const Fortran::lower::pft::Variable &altResult :
- deferredFuncResultList) {
- Fortran::lower::StatementContext stmtCtx;
- if (std::optional<Fortran::lower::CalleeInterface::PassedEntity>
- passedResult = callee.getPassedResult()) {
- mapBlockArgToDummyOrResult(altResult.getSymbol(), resultArg.getAddr());
- Fortran::lower::mapSymbolAttributes(*this, altResult, localSymbols,
- stmtCtx);
- } else {
- // catch cases where the allocation for the function result storage type
- // doesn't match the type of this symbol
- mlir::Value preAlloc = primaryFuncResultStorage;
- mlir::Type resTy = primaryFuncResultStorage.getType();
- mlir::Type symTy = genType(altResult);
- mlir::Type wrappedSymTy = fir::ReferenceType::get(symTy);
- if (resTy != wrappedSymTy) {
- // check size of the pointed to type so we can't overflow by writing
- // double precision to a single precision allocation, etc
- LLVM_ATTRIBUTE_UNUSED auto getBitWidth = [this](mlir::Type ty) {
- // 15.6.2.6.3: differering result types should be integer, real,
- // complex or logical
- if (auto cmplx = mlir::dyn_cast_or_null<fir::ComplexType>(ty)) {
- fir::KindTy kind = cmplx.getFKind();
- return 2 * builder->getKindMap().getRealBitsize(kind);
- }
- if (auto logical = mlir::dyn_cast_or_null<fir::LogicalType>(ty)) {
- fir::KindTy kind = logical.getFKind();
- return builder->getKindMap().getLogicalBitsize(kind);
- }
- return ty.getIntOrFloatBitWidth();
- };
- assert(getBitWidth(fir::unwrapRefType(resTy)) >= getBitWidth(symTy));
-
- // convert the storage to the symbol type so that the hlfir.declare
- // gets the correct type for this symbol
- preAlloc = builder->create<fir::ConvertOp>(getCurrentLocation(),
- wrappedSymTy, preAlloc);
- }
+// call STOP, ERROR STOP in runtime
+void FirConverter::genFIR(const Fortran::parser::StopStmt &stmt) {
+ genStopStatement(*this, stmt);
+}
- Fortran::lower::mapSymbolAttributes(*this, altResult, localSymbols,
- stmtCtx, preAlloc);
- }
+void FirConverter::genFIR(const Fortran::parser::ReturnStmt &stmt) {
+ Fortran::lower::pft::FunctionLikeUnit *funit = getEval().getOwningProcedure();
+ assert(funit && "not inside main program, function or subroutine");
+ for (auto it = activeConstructStack.rbegin(),
+ rend = activeConstructStack.rend();
+ it != rend; ++it) {
+ it->stmtCtx.finalizeAndKeep();
+ }
+ if (funit->isMainProgram()) {
+ bridge.fctCtx().finalizeAndKeep();
+ genExitRoutine();
+ return;
+ }
+ mlir::Location loc = toLocation();
+ if (stmt.v) {
+ // Alternate return statement - If this is a subroutine where some
+ // alternate entries have alternate returns, but the active entry point
+ // does not, ignore the alternate return value. Otherwise, assign it
+ // to the compiler-generated result variable.
+ const Fortran::semantics::Symbol &symbol = funit->getSubprogramSymbol();
+ if (Fortran::semantics::HasAlternateReturns(symbol)) {
+ Fortran::lower::StatementContext stmtCtx;
+ const Fortran::lower::SomeExpr *expr =
+ Fortran::semantics::GetExpr(*stmt.v);
+ assert(expr && "missing alternate return expression");
+ mlir::Value altReturnIndex = builder->createConvert(
+ loc, builder->getIndexType(), createFIRExpr(loc, expr, stmtCtx));
+ builder->create<fir::StoreOp>(loc, altReturnIndex,
+ getAltReturnResult(symbol));
}
+ }
+ // Branch to the last block of the SUBROUTINE, which has the actual return.
+ if (!funit->finalBlock) {
+ mlir::OpBuilder::InsertPoint insPt = builder->saveInsertionPoint();
+ Fortran::lower::setInsertionPointAfterOpenACCLoopIfInside(*builder);
+ funit->finalBlock = builder->createBlock(&builder->getRegion());
+ builder->restoreInsertionPoint(insPt);
+ }
- // If this is a host procedure with host associations, then create the tuple
- // of pointers for passing to the internal procedures.
- if (!funit.getHostAssoc().empty())
- funit.getHostAssoc().hostProcedureBindings(*this, localSymbols);
+ if (Fortran::lower::isInOpenACCLoop(*builder))
+ Fortran::lower::genEarlyReturnInOpenACCLoop(*builder, loc);
+ else
+ builder->create<mlir::cf::BranchOp>(loc, funit->finalBlock);
+}
- // Create most function blocks in advance.
- createEmptyBlocks(funit.evaluationList);
+void FirConverter::genFIR(const Fortran::parser::CycleStmt &) {
+ genConstructExitBranch(*getEval().controlSuccessor);
+}
- // Reinstate entry block as the current insertion point.
- builder->setInsertionPointToEnd(&func.front());
+void FirConverter::genFIR(const Fortran::parser::ExitStmt &) {
+ genConstructExitBranch(*getEval().controlSuccessor);
+}
- if (callee.hasAlternateReturns()) {
- // Create a local temp to hold the alternate return index.
- // Give it an integer index type and the subroutine name (for dumps).
- // Attach it to the subroutine symbol in the localSymbols map.
- // Initialize it to zero, the "fallthrough" alternate return value.
- const Fortran::semantics::Symbol &symbol = funit.getSubprogramSymbol();
- mlir::Location loc = toLocation();
- mlir::Type idxTy = builder->getIndexType();
- mlir::Value altResult =
- builder->createTemporary(loc, idxTy, toStringRef(symbol.name()));
- addSymbol(symbol, altResult);
- mlir::Value zero = builder->createIntegerConstant(loc, idxTy, 0);
- builder->create<fir::StoreOp>(loc, zero, altResult);
- }
+void FirConverter::genFIR(const Fortran::parser::GotoStmt &) {
+ genConstructExitBranch(*getEval().controlSuccessor);
+}
- if (Fortran::lower::pft::Evaluation *alternateEntryEval =
- funit.getEntryEval())
- genBranch(alternateEntryEval->lexicalSuccessor->block);
+/// Generate FIR for Evaluation \p eval.
+void FirConverter::genFIR(Fortran::lower::pft::Evaluation &eval,
+ bool unstructuredContext) {
+ // Start a new unstructured block when applicable. When transitioning
+ // from unstructured to structured code, unstructuredContext is true,
+ // which accounts for the possibility that the structured code could be
+ // a target that starts a new block.
+ if (unstructuredContext)
+ maybeStartBlock(eval.isConstruct() && eval.lowerAsStructured()
+ ? eval.getFirstNestedEvaluation().block
+ : eval.block);
+
+ // Generate evaluation specific code. Even nop calls should usually reach
+ // here in case they start a new block or require generation of a generic
+ // end-of-block branch. An alternative is to add special case code
+ // elsewhere, such as in the genFIR code for a parent construct.
+ setCurrentEval(eval);
+ setCurrentPosition(eval.position);
+ eval.visit([&](const auto &stmt) { genFIR(stmt); });
+
+ // Generate an end-of-block branch for several special cases. For
+ // constructs, this can be done for either the end construct statement,
+ // or for the construct itself, which will skip this code if the
+ // end statement was visited first and generated a branch.
+ Fortran::lower::pft::Evaluation *successor =
+ eval.isConstruct() ? eval.getLastNestedEvaluation().lexicalSuccessor
+ : eval.lexicalSuccessor;
+ if (successor && blockIsUnterminated()) {
+ if (successor->isIntermediateConstructStmt() &&
+ successor->parentConstruct->lowerAsUnstructured())
+ // Exit from an intermediate unstructured IF or SELECT construct block.
+ genBranch(successor->parentConstruct->constructExit->block);
+ else if (unstructuredContext && eval.isConstructStmt() &&
+ successor == eval.controlSuccessor)
+ // Exit from a degenerate, empty construct block.
+ genBranch(eval.parentConstruct->constructExit->block);
}
+}
- /// Create global blocks for the current function. This eliminates the
- /// distinction between forward and backward targets when generating
- /// branches. A block is "global" if it can be the target of a GOTO or
- /// other source code branch. A block that can only be targeted by a
- /// compiler generated branch is "local". For example, a DO loop preheader
- /// block containing loop initialization code is global. A loop header
- /// block, which is the target of the loop back edge, is local. Blocks
- /// belong to a region. Any block within a nested region must be replaced
- /// with a block belonging to that region. Branches may not cross region
- /// boundaries.
- void createEmptyBlocks(
- std::list<Fortran::lower::pft::Evaluation> &evaluationList) {
- mlir::Region *region = &builder->getRegion();
- for (Fortran::lower::pft::Evaluation &eval : evaluationList) {
- if (eval.isNewBlock)
- eval.block = builder->createBlock(region);
- if (eval.isConstruct() || eval.isDirective()) {
- if (eval.lowerAsUnstructured()) {
- createEmptyBlocks(eval.getNestedEvaluations());
- } else if (eval.hasNestedEvaluations()) {
- // A structured construct that is a target starts a new block.
- Fortran::lower::pft::Evaluation &constructStmt =
- eval.getFirstNestedEvaluation();
- if (constructStmt.isNewBlock)
- constructStmt.block = builder->createBlock(region);
- }
+/// Map mlir function block arguments to the corresponding Fortran dummy
+/// variables. When the result is passed as a hidden argument, the Fortran
+/// result is also mapped. The symbol map is used to hold this mapping.
+void FirConverter::mapDummiesAndResults(
+ Fortran::lower::pft::FunctionLikeUnit &funit,
+ const Fortran::lower::CalleeInterface &callee) {
+ assert(builder && "require a builder object at this point");
+ using PassBy = Fortran::lower::CalleeInterface::PassEntityBy;
+ auto mapPassedEntity = [&](const auto arg) {
+ if (arg.passBy == PassBy::AddressAndLength) {
+ if (callee.characterize().IsBindC())
+ return;
+ // TODO: now that fir call has some attributes regarding character
+ // return, PassBy::AddressAndLength should be retired.
+ mlir::Location loc = toLocation();
+ fir::factory::CharacterExprHelper charHelp{*builder, loc};
+ mlir::Value box =
+ charHelp.createEmboxChar(arg.firArgument, arg.firLength);
+ mapBlockArgToDummyOrResult(arg.entity->get(), box);
+ } else {
+ if (arg.entity.has_value()) {
+ mapBlockArgToDummyOrResult(arg.entity->get(), arg.firArgument);
+ } else {
+ assert(funit.parentHasTupleHostAssoc() && "expect tuple argument");
}
}
+ };
+ for (const Fortran::lower::CalleeInterface::PassedEntity &arg :
+ callee.getPassedArguments())
+ mapPassedEntity(arg);
+ if (std::optional<Fortran::lower::CalleeInterface::PassedEntity>
+ passedResult = callee.getPassedResult()) {
+ mapPassedEntity(*passedResult);
+ // FIXME: need to make sure things are OK here. addSymbol may not be OK
+ if (funit.primaryResult &&
+ passedResult->entity->get() != *funit.primaryResult)
+ mapBlockArgToDummyOrResult(*funit.primaryResult,
+ getSymbolAddress(passedResult->entity->get()));
}
+}
- /// Return the predicate: "current block does not have a terminator branch".
- bool blockIsUnterminated() {
- mlir::Block *currentBlock = builder->getBlock();
- return currentBlock->empty() ||
- !currentBlock->back().hasTrait<mlir::OpTrait::IsTerminator>();
- }
-
- /// Unconditionally switch code insertion to a new block.
- void startBlock(mlir::Block *newBlock) {
- assert(newBlock && "missing block");
- // Default termination for the current block is a fallthrough branch to
- // the new block.
- if (blockIsUnterminated())
- genBranch(newBlock);
- // Some blocks may be re/started more than once, and might not be empty.
- // If the new block already has (only) a terminator, set the insertion
- // point to the start of the block. Otherwise set it to the end.
- builder->setInsertionPointToStart(newBlock);
- if (blockIsUnterminated())
- builder->setInsertionPointToEnd(newBlock);
- }
-
- /// Conditionally switch code insertion to a new block.
- void maybeStartBlock(mlir::Block *newBlock) {
- if (newBlock)
- startBlock(newBlock);
- }
+/// Instantiate variable \p var and add it to the symbol map.
+/// See ConvertVariable.cpp.
+void FirConverter::instantiateVar(const Fortran::lower::pft::Variable &var,
+ Fortran::lower::AggregateStoreMap &storeMap) {
+ Fortran::lower::instantiateVariable(*this, var, localSymbols, storeMap);
+ if (var.hasSymbol()) {
+ if (var.getSymbol().test(
+ Fortran::semantics::Symbol::Flag::OmpThreadprivate))
+ Fortran::lower::genThreadprivateOp(*this, var);
- void eraseDeadCodeAndBlocks(mlir::RewriterBase &rewriter,
- llvm::MutableArrayRef<mlir::Region> regions) {
- // WARNING: Do not add passes that can do folding or code motion here
- // because they might cross omp.target region boundaries, which can result
- // in incorrect code. Optimization passes like these must be added after
- // OMP early outlining has been done.
- (void)mlir::eraseUnreachableBlocks(rewriter, regions);
- (void)mlir::runRegionDCE(rewriter, regions);
+ if (var.getSymbol().test(
+ Fortran::semantics::Symbol::Flag::OmpDeclareTarget))
+ Fortran::lower::genDeclareTargetIntGlobal(*this, var);
}
+}
- /// Finish translation of a function.
- void endNewFunction(Fortran::lower::pft::FunctionLikeUnit &funit) {
- setCurrentPosition(Fortran::lower::pft::stmtSourceLoc(funit.endStmt));
- if (funit.isMainProgram()) {
- bridge.openAccCtx().finalizeAndPop();
- bridge.fctCtx().finalizeAndPop();
- genExitRoutine();
- } else {
- genFIRProcedureExit(funit, funit.getSubprogramSymbol());
- }
- funit.finalBlock = nullptr;
- LLVM_DEBUG(llvm::dbgs() << "\n[bridge - endNewFunction";
- if (auto *sym = funit.scope->symbol()) llvm::dbgs()
- << " " << sym->name();
- llvm::dbgs() << "] generated IR:\n\n"
- << *builder->getFunction() << '\n');
- // Eliminate dead code as a prerequisite to calling other IR passes.
- // FIXME: This simplification should happen in a normal pass, not here.
- mlir::IRRewriter rewriter(*builder);
- (void)eraseDeadCodeAndBlocks(rewriter, {builder->getRegion()});
- delete builder;
- builder = nullptr;
- hostAssocTuple = mlir::Value{};
- localSymbols.clear();
- blockId = 0;
+/// Where applicable, save the exception state and halting and rounding
+/// modes at function entry and restore them at function exits.
+void FirConverter::manageFPEnvironment(
+ Fortran::lower::pft::FunctionLikeUnit &funit) {
+ mlir::Location loc = toLocation();
+ mlir::Location endLoc =
+ toLocation(Fortran::lower::pft::stmtSourceLoc(funit.endStmt));
+ if (funit.hasIeeeAccess) {
+ // Subject to F18 Clause 17.1p3, 17.3p3 states: If a flag is signaling
+ // on entry to a procedure [...], the processor will set it to quiet
+ // on entry and restore it to signaling on return. If a flag signals
+ // during execution of a procedure, the processor shall not set it to
+ // quiet on return.
+ mlir::func::FuncOp testExcept = fir::factory::getFetestexcept(*builder);
+ mlir::func::FuncOp clearExcept = fir::factory::getFeclearexcept(*builder);
+ mlir::func::FuncOp raiseExcept = fir::factory::getFeraiseexcept(*builder);
+ mlir::Value ones = builder->createIntegerConstant(
+ loc, testExcept.getFunctionType().getInput(0), -1);
+ mlir::Value exceptSet =
+ builder->create<fir::CallOp>(loc, testExcept, ones).getResult(0);
+ builder->create<fir::CallOp>(loc, clearExcept, exceptSet);
+ bridge.fctCtx().attachCleanup([=]() {
+ builder->create<fir::CallOp>(endLoc, raiseExcept, exceptSet);
+ });
}
-
- /// Helper to generate GlobalOps when the builder is not positioned in any
- /// region block. This is required because the FirOpBuilder assumes it is
- /// always positioned inside a region block when creating globals, the easiest
- /// way comply is to create a dummy function and to throw it afterwards.
- void createGlobalOutsideOfFunctionLowering(
- const std::function<void()> &createGlobals) {
- // FIXME: get rid of the bogus function context and instantiate the
- // globals directly into the module.
- mlir::MLIRContext *context = &getMLIRContext();
- mlir::func::FuncOp func = fir::FirOpBuilder::createFunction(
- mlir::UnknownLoc::get(context), getModuleOp(),
- fir::NameUniquer::doGenerated("Sham"),
- mlir::FunctionType::get(context, std::nullopt, std::nullopt));
- func.addEntryBlock();
- builder = new fir::FirOpBuilder(func, bridge.getKindMap());
- assert(builder && "FirOpBuilder did not instantiate");
- builder->setFastMathFlags(bridge.getLoweringOptions().getMathOptions());
- createGlobals();
- if (mlir::Region *region = func.getCallableRegion())
- region->dropAllReferences();
- func.erase();
- delete builder;
- builder = nullptr;
- localSymbols.clear();
+ if (funit.mayModifyHaltingMode) {
+ // F18 Clause 17.6p1: In a procedure [...], the processor shall not
+ // change the halting mode on entry, and on return shall ensure that
+ // the halting mode is the same as it was on entry.
+ mlir::func::FuncOp getExcept = fir::factory::getFegetexcept(*builder);
+ mlir::func::FuncOp disableExcept =
+ fir::factory::getFedisableexcept(*builder);
+ mlir::func::FuncOp enableExcept = fir::factory::getFeenableexcept(*builder);
+ mlir::Value exceptSet =
+ builder->create<fir::CallOp>(loc, getExcept).getResult(0);
+ mlir::Value ones = builder->createIntegerConstant(
+ loc, disableExcept.getFunctionType().getInput(0), -1);
+ bridge.fctCtx().attachCleanup([=]() {
+ builder->create<fir::CallOp>(endLoc, disableExcept, ones);
+ builder->create<fir::CallOp>(endLoc, enableExcept, exceptSet);
+ });
}
-
- /// Instantiate the data from a BLOCK DATA unit.
- void lowerBlockData(Fortran::lower::pft::BlockDataUnit &bdunit) {
- createGlobalOutsideOfFunctionLowering([&]() {
- Fortran::lower::AggregateStoreMap fakeMap;
- for (const auto &[_, sym] : bdunit.symTab) {
- if (sym->has<Fortran::semantics::ObjectEntityDetails>()) {
- Fortran::lower::pft::Variable var(*sym, true);
- instantiateVar(var, fakeMap);
- }
- }
+ if (funit.mayModifyRoundingMode) {
+ // F18 Clause 17.4.5: In a procedure [...], the processor shall not
+ // change the rounding modes on entry, and on return shall ensure that
+ // the rounding modes are the same as they were on entry.
+ mlir::func::FuncOp getRounding = fir::factory::getLlvmGetRounding(*builder);
+ mlir::func::FuncOp setRounding = fir::factory::getLlvmSetRounding(*builder);
+ mlir::Value roundingMode =
+ builder->create<fir::CallOp>(loc, getRounding).getResult(0);
+ bridge.fctCtx().attachCleanup([=]() {
+ builder->create<fir::CallOp>(endLoc, setRounding, roundingMode);
});
}
+}
- /// Create fir::Global for all the common blocks that appear in the program.
- void
- lowerCommonBlocks(const Fortran::semantics::CommonBlockList &commonBlocks) {
- createGlobalOutsideOfFunctionLowering(
- [&]() { Fortran::lower::defineCommonBlocks(*this, commonBlocks); });
- }
+/// Start translation of a function.
+void FirConverter::startNewFunction(
+ Fortran::lower::pft::FunctionLikeUnit &funit) {
+ assert(!builder && "expected nullptr");
+ bridge.fctCtx().pushScope();
+ bridge.openAccCtx().pushScope();
+ const Fortran::semantics::Scope &scope = funit.getScope();
+ LLVM_DEBUG(llvm::dbgs() << "\n[bridge - startNewFunction]";
+ if (auto *sym = scope.symbol()) llvm::dbgs() << " " << *sym;
+ llvm::dbgs() << "\n");
+ Fortran::lower::CalleeInterface callee(funit, *this);
+ mlir::func::FuncOp func = callee.addEntryBlockAndMapArguments();
+ builder = new fir::FirOpBuilder(func, bridge.getKindMap());
+ assert(builder && "FirOpBuilder did not instantiate");
+ builder->setFastMathFlags(bridge.getLoweringOptions().getMathOptions());
+ builder->setInsertionPointToStart(&func.front());
+ func.setVisibility(mlir::SymbolTable::Visibility::Public);
+ assert(blockId == 0 && "invalid blockId");
+ assert(activeConstructStack.empty() && "invalid construct stack state");
+
+ // Manage floating point exception, halting mode, and rounding mode
+ // settings at function entry and exit.
+ if (!funit.isMainProgram())
+ manageFPEnvironment(funit);
+
+ mapDummiesAndResults(funit, callee);
+
+ // Map host associated symbols from parent procedure if any.
+ if (funit.parentHasHostAssoc())
+ funit.parentHostAssoc().internalProcedureBindings(*this, localSymbols);
+
+ // Non-primary results of a function with multiple entry points.
+ // These result values share storage with the primary result.
+ llvm::SmallVector<Fortran::lower::pft::Variable> deferredFuncResultList;
+
+ // Backup actual argument for entry character results with different
+ // lengths. It needs to be added to the non-primary results symbol before
+ // mapSymbolAttributes is called.
+ Fortran::lower::SymbolBox resultArg;
+ if (std::optional<Fortran::lower::CalleeInterface::PassedEntity>
+ passedResult = callee.getPassedResult())
+ resultArg = lookupSymbol(passedResult->entity->get());
+
+ Fortran::lower::AggregateStoreMap storeMap;
+
+ // Map all containing submodule and module equivalences and variables, in
+ // case they are referenced. It might be better to limit this to variables
+ // that are actually referenced, although that is more complicated when
+ // there are equivalenced variables.
+ auto &scopeVariableListMap =
+ Fortran::lower::pft::getScopeVariableListMap(funit);
+ for (auto *scp = &scope.parent(); !scp->IsGlobal(); scp = &scp->parent())
+ if (scp->kind() == Fortran::semantics::Scope::Kind::Module)
+ for (const auto &var : Fortran::lower::pft::getScopeVariableList(
+ *scp, scopeVariableListMap))
+ instantiateVar(var, storeMap);
- /// Create intrinsic module array constant definitions.
- void createIntrinsicModuleDefinitions(Fortran::lower::pft::Program &pft) {
- // The intrinsic module scope, if present, is the first scope.
- const Fortran::semantics::Scope *intrinsicModuleScope = nullptr;
- for (Fortran::lower::pft::Program::Units &u : pft.getUnits()) {
- std::visit(Fortran::common::visitors{
- [&](Fortran::lower::pft::FunctionLikeUnit &f) {
- intrinsicModuleScope = &f.getScope().parent();
- },
- [&](Fortran::lower::pft::ModuleLikeUnit &m) {
- intrinsicModuleScope = &m.getScope().parent();
- },
- [&](Fortran::lower::pft::BlockDataUnit &b) {},
- [&](Fortran::lower::pft::CompilerDirectiveUnit &d) {},
- [&](Fortran::lower::pft::OpenACCDirectiveUnit &d) {},
- },
- u);
- if (intrinsicModuleScope) {
- while (!intrinsicModuleScope->IsGlobal())
- intrinsicModuleScope = &intrinsicModuleScope->parent();
- intrinsicModuleScope = &intrinsicModuleScope->children().front();
- break;
- }
+ // Map function equivalences and variables.
+ mlir::Value primaryFuncResultStorage;
+ for (const Fortran::lower::pft::Variable &var :
+ Fortran::lower::pft::getScopeVariableList(scope)) {
+ // Always instantiate aggregate storage blocks.
+ if (var.isAggregateStore()) {
+ instantiateVar(var, storeMap);
+ continue;
}
- if (!intrinsicModuleScope || !intrinsicModuleScope->IsIntrinsicModules())
- return;
- for (const auto &scope : intrinsicModuleScope->children()) {
- llvm::StringRef modName = toStringRef(scope.symbol()->name());
- if (modName != "__fortran_ieee_exceptions")
+ const Fortran::semantics::Symbol &sym = var.getSymbol();
+ if (funit.parentHasHostAssoc()) {
+ // Never instantiate host associated variables, as they are already
+ // instantiated from an argument tuple. Instead, just bind the symbol
+ // to the host variable, which must be in the map.
+ const Fortran::semantics::Symbol &ultimate = sym.GetUltimate();
+ if (funit.parentHostAssoc().isAssociated(ultimate)) {
+ copySymbolBinding(ultimate, sym);
continue;
- for (auto &var : Fortran::lower::pft::getScopeVariableList(scope)) {
- const Fortran::semantics::Symbol &sym = var.getSymbol();
- if (sym.test(Fortran::semantics::Symbol::Flag::CompilerCreated))
- continue;
- const auto *object =
- sym.detailsIf<Fortran::semantics::ObjectEntityDetails>();
- if (object && object->IsArray() && object->init())
- Fortran::lower::createIntrinsicModuleGlobal(*this, var);
}
}
- }
-
- /// Lower a procedure (nest).
- void lowerFunc(Fortran::lower::pft::FunctionLikeUnit &funit) {
- setCurrentPosition(funit.getStartingSourceLoc());
- for (int entryIndex = 0, last = funit.entryPointList.size();
- entryIndex < last; ++entryIndex) {
- funit.setActiveEntry(entryIndex);
- startNewFunction(funit); // the entry point for lowering this procedure
- for (Fortran::lower::pft::Evaluation &eval : funit.evaluationList)
- genFIR(eval);
- endNewFunction(funit);
+ if (!sym.IsFuncResult() || !funit.primaryResult) {
+ instantiateVar(var, storeMap);
+ } else if (&sym == funit.primaryResult) {
+ instantiateVar(var, storeMap);
+ primaryFuncResultStorage = getSymbolAddress(sym);
+ } else {
+ deferredFuncResultList.push_back(var);
}
- funit.setActiveEntry(0);
- for (Fortran::lower::pft::FunctionLikeUnit &f : funit.nestedFunctions)
- lowerFunc(f); // internal procedure
}
- /// Lower module variable definitions to fir::globalOp and OpenMP/OpenACC
- /// declarative construct.
- void lowerModuleDeclScope(Fortran::lower::pft::ModuleLikeUnit &mod) {
- setCurrentPosition(mod.getStartingSourceLoc());
- createGlobalOutsideOfFunctionLowering([&]() {
- auto &scopeVariableListMap =
- Fortran::lower::pft::getScopeVariableListMap(mod);
- for (const auto &var : Fortran::lower::pft::getScopeVariableList(
- mod.getScope(), scopeVariableListMap)) {
- // Only define the variables owned by this module.
- const Fortran::semantics::Scope *owningScope = var.getOwningScope();
- if (!owningScope || mod.getScope() == *owningScope)
- Fortran::lower::defineModuleVariable(*this, var);
+ // TODO: should use same mechanism as equivalence?
+ // One blocking point is character entry returns that need special handling
+ // since they are not locally allocated but come as argument. CHARACTER(*)
+ // is not something that fits well with equivalence lowering.
+ for (const Fortran::lower::pft::Variable &altResult :
+ deferredFuncResultList) {
+ Fortran::lower::StatementContext stmtCtx;
+ if (std::optional<Fortran::lower::CalleeInterface::PassedEntity>
+ passedResult = callee.getPassedResult()) {
+ mapBlockArgToDummyOrResult(altResult.getSymbol(), resultArg.getAddr());
+ Fortran::lower::mapSymbolAttributes(*this, altResult, localSymbols,
+ stmtCtx);
+ } else {
+ // catch cases where the allocation for the function result storage type
+ // doesn't match the type of this symbol
+ mlir::Value preAlloc = primaryFuncResultStorage;
+ mlir::Type resTy = primaryFuncResultStorage.getType();
+ mlir::Type symTy = genType(altResult);
+ mlir::Type wrappedSymTy = fir::ReferenceType::get(symTy);
+ if (resTy != wrappedSymTy) {
+ // check size of the pointed to type so we can't overflow by writing
+ // double precision to a single precision allocation, etc
+ LLVM_ATTRIBUTE_UNUSED auto getBitWidth = [this](mlir::Type ty) {
+ // 15.6.2.6.3: differering result types should be integer, real,
+ // complex or logical
+ if (auto cmplx = mlir::dyn_cast_or_null<fir::ComplexType>(ty)) {
+ fir::KindTy kind = cmplx.getFKind();
+ return 2 * builder->getKindMap().getRealBitsize(kind);
+ }
+ if (auto logical = mlir::dyn_cast_or_null<fir::LogicalType>(ty)) {
+ fir::KindTy kind = logical.getFKind();
+ return builder->getKindMap().getLogicalBitsize(kind);
+ }
+ return ty.getIntOrFloatBitWidth();
+ };
+ assert(getBitWidth(fir::unwrapRefType(resTy)) >= getBitWidth(symTy));
+
+ // convert the storage to the symbol type so that the hlfir.declare
+ // gets the correct type for this symbol
+ preAlloc = builder->create<fir::ConvertOp>(getCurrentLocation(),
+ wrappedSymTy, preAlloc);
}
- for (auto &eval : mod.evaluationList)
- genFIR(eval);
- });
- }
- /// Lower functions contained in a module.
- void lowerMod(Fortran::lower::pft::ModuleLikeUnit &mod) {
- for (Fortran::lower::pft::FunctionLikeUnit &f : mod.nestedFunctions)
- lowerFunc(f);
+ Fortran::lower::mapSymbolAttributes(*this, altResult, localSymbols,
+ stmtCtx, preAlloc);
+ }
}
- void setCurrentPosition(const Fortran::parser::CharBlock &position) {
- if (position != Fortran::parser::CharBlock{})
- currentPosition = position;
- }
+ // If this is a host procedure with host associations, then create the tuple
+ // of pointers for passing to the internal procedures.
+ if (!funit.getHostAssoc().empty())
+ funit.getHostAssoc().hostProcedureBindings(*this, localSymbols);
- /// Set current position at the location of \p parseTreeNode. Note that the
- /// position is updated automatically when visiting statements, but not when
- /// entering higher level nodes like constructs or procedures. This helper is
- /// intended to cover the latter cases.
- template <typename A>
- void setCurrentPositionAt(const A &parseTreeNode) {
- setCurrentPosition(Fortran::parser::FindSourceLocation(parseTreeNode));
- }
+ // Create most function blocks in advance.
+ createEmptyBlocks(funit.evaluationList);
- //===--------------------------------------------------------------------===//
- // Utility methods
- //===--------------------------------------------------------------------===//
+ // Reinstate entry block as the current insertion point.
+ builder->setInsertionPointToEnd(&func.front());
- /// Convert a parser CharBlock to a Location
- mlir::Location toLocation(const Fortran::parser::CharBlock &cb) {
- return genLocation(cb);
+ if (callee.hasAlternateReturns()) {
+ // Create a local temp to hold the alternate return index.
+ // Give it an integer index type and the subroutine name (for dumps).
+ // Attach it to the subroutine symbol in the localSymbols map.
+ // Initialize it to zero, the "fallthrough" alternate return value.
+ const Fortran::semantics::Symbol &symbol = funit.getSubprogramSymbol();
+ mlir::Location loc = toLocation();
+ mlir::Type idxTy = builder->getIndexType();
+ mlir::Value altResult =
+ builder->createTemporary(loc, idxTy, toStringRef(symbol.name()));
+ addSymbol(symbol, altResult);
+ mlir::Value zero = builder->createIntegerConstant(loc, idxTy, 0);
+ builder->create<fir::StoreOp>(loc, zero, altResult);
}
- mlir::Location toLocation() { return toLocation(currentPosition); }
- void setCurrentEval(Fortran::lower::pft::Evaluation &eval) {
- evalPtr = &eval;
- }
- Fortran::lower::pft::Evaluation &getEval() {
- assert(evalPtr);
- return *evalPtr;
- }
+ if (Fortran::lower::pft::Evaluation *alternateEntryEval =
+ funit.getEntryEval())
+ genBranch(alternateEntryEval->lexicalSuccessor->block);
+}
- std::optional<Fortran::evaluate::Shape>
- getShape(const Fortran::lower::SomeExpr &expr) {
- return Fortran::evaluate::GetShape(foldingContext, expr);
+/// Create global blocks for the current function. This eliminates the
+/// distinction between forward and backward targets when generating
+/// branches. A block is "global" if it can be the target of a GOTO or
+/// other source code branch. A block that can only be targeted by a
+/// compiler generated branch is "local". For example, a DO loop preheader
+/// block containing loop initialization code is global. A loop header
+/// block, which is the target of the loop back edge, is local. Blocks
+/// belong to a region. Any block within a nested region must be replaced
+/// with a block belonging to that region. Branches may not cross region
+/// boundaries.
+void FirConverter::createEmptyBlocks(
+ std::list<Fortran::lower::pft::Evaluation> &evaluationList) {
+ mlir::Region *region = &builder->getRegion();
+ for (Fortran::lower::pft::Evaluation &eval : evaluationList) {
+ if (eval.isNewBlock)
+ eval.block = builder->createBlock(region);
+ if (eval.isConstruct() || eval.isDirective()) {
+ if (eval.lowerAsUnstructured()) {
+ createEmptyBlocks(eval.getNestedEvaluations());
+ } else if (eval.hasNestedEvaluations()) {
+ // A structured construct that is a target starts a new block.
+ Fortran::lower::pft::Evaluation &constructStmt =
+ eval.getFirstNestedEvaluation();
+ if (constructStmt.isNewBlock)
+ constructStmt.block = builder->createBlock(region);
+ }
+ }
}
+}
- //===--------------------------------------------------------------------===//
- // Analysis on a nested explicit iteration space.
- //===--------------------------------------------------------------------===//
+/// Unconditionally switch code insertion to a new block.
+void FirConverter::startBlock(mlir::Block *newBlock) {
+ assert(newBlock && "missing block");
+ // Default termination for the current block is a fallthrough branch to
+ // the new block.
+ if (blockIsUnterminated())
+ genBranch(newBlock);
+ // Some blocks may be re/started more than once, and might not be empty.
+ // If the new block already has (only) a terminator, set the insertion
+ // point to the start of the block. Otherwise set it to the end.
+ builder->setInsertionPointToStart(newBlock);
+ if (blockIsUnterminated())
+ builder->setInsertionPointToEnd(newBlock);
+}
- void analyzeExplicitSpace(const Fortran::parser::ConcurrentHeader &header) {
- explicitIterSpace.pushLevel();
- for (const Fortran::parser::ConcurrentControl &ctrl :
- std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t)) {
- const Fortran::semantics::Symbol *ctrlVar =
- std::get<Fortran::parser::Name>(ctrl.t).symbol;
- explicitIterSpace.addSymbol(ctrlVar);
+void FirConverter::eraseDeadCodeAndBlocks(
+ mlir::RewriterBase &rewriter, llvm::MutableArrayRef<mlir::Region> regions) {
+ // WARNING: Do not add passes that can do folding or code motion here
+ // because they might cross omp.target region boundaries, which can result
+ // in incorrect code. Optimization passes like these must be added after
+ // OMP early outlining has been done.
+ (void)mlir::eraseUnreachableBlocks(rewriter, regions);
+ (void)mlir::runRegionDCE(rewriter, regions);
+}
+
+/// Finish translation of a function.
+void FirConverter::endNewFunction(
+ Fortran::lower::pft::FunctionLikeUnit &funit) {
+ setCurrentPosition(Fortran::lower::pft::stmtSourceLoc(funit.endStmt));
+ if (funit.isMainProgram()) {
+ bridge.openAccCtx().finalizeAndPop();
+ bridge.fctCtx().finalizeAndPop();
+ genExitRoutine();
+ } else {
+ genFIRProcedureExit(funit, funit.getSubprogramSymbol());
+ }
+ funit.finalBlock = nullptr;
+ LLVM_DEBUG(llvm::dbgs() << "\n[bridge - endNewFunction";
+ if (auto *sym = funit.scope->symbol()) llvm::dbgs()
+ << " " << sym->name();
+ llvm::dbgs() << "] generated IR:\n\n"
+ << *builder->getFunction() << '\n');
+ // Eliminate dead code as a prerequisite to calling other IR passes.
+ // FIXME: This simplification should happen in a normal pass, not here.
+ mlir::IRRewriter rewriter(*builder);
+ (void)eraseDeadCodeAndBlocks(rewriter, {builder->getRegion()});
+ delete builder;
+ builder = nullptr;
+ hostAssocTuple = mlir::Value{};
+ localSymbols.clear();
+ blockId = 0;
+}
+
+/// Helper to generate GlobalOps when the builder is not positioned in any
+/// region block. This is required because the FirOpBuilder assumes it is
+/// always positioned inside a region block when creating globals, the easiest
+/// way comply is to create a dummy function and to throw it afterwards.
+void FirConverter::createGlobalOutsideOfFunctionLowering(
+ const std::function<void()> &createGlobals) {
+ // FIXME: get rid of the bogus function context and instantiate the
+ // globals directly into the module.
+ mlir::MLIRContext *context = &getMLIRContext();
+ mlir::func::FuncOp func = fir::FirOpBuilder::createFunction(
+ mlir::UnknownLoc::get(context), getModuleOp(),
+ fir::NameUniquer::doGenerated("Sham"),
+ mlir::FunctionType::get(context, std::nullopt, std::nullopt));
+ func.addEntryBlock();
+ builder = new fir::FirOpBuilder(func, bridge.getKindMap());
+ assert(builder && "FirOpBuilder did not instantiate");
+ builder->setFastMathFlags(bridge.getLoweringOptions().getMathOptions());
+ createGlobals();
+ if (mlir::Region *region = func.getCallableRegion())
+ region->dropAllReferences();
+ func.erase();
+ delete builder;
+ builder = nullptr;
+ localSymbols.clear();
+}
+
+/// Instantiate the data from a BLOCK DATA unit.
+void FirConverter::lowerBlockData(Fortran::lower::pft::BlockDataUnit &bdunit) {
+ createGlobalOutsideOfFunctionLowering([&]() {
+ Fortran::lower::AggregateStoreMap fakeMap;
+ for (const auto &[_, sym] : bdunit.symTab) {
+ if (sym->has<Fortran::semantics::ObjectEntityDetails>()) {
+ Fortran::lower::pft::Variable var(*sym, true);
+ instantiateVar(var, fakeMap);
+ }
}
- if (const auto &mask =
- std::get<std::optional<Fortran::parser::ScalarLogicalExpr>>(
- header.t);
- mask.has_value())
- analyzeExplicitSpace(*Fortran::semantics::GetExpr(*mask));
- }
- template <bool LHS = false, typename A>
- void analyzeExplicitSpace(const Fortran::evaluate::Expr<A> &e) {
- explicitIterSpace.exprBase(&e, LHS);
- }
- void analyzeExplicitSpace(const Fortran::evaluate::Assignment *assign) {
- auto analyzeAssign = [&](const Fortran::lower::SomeExpr &lhs,
- const Fortran::lower::SomeExpr &rhs) {
- analyzeExplicitSpace</*LHS=*/true>(lhs);
- analyzeExplicitSpace(rhs);
- };
- std::visit(
- Fortran::common::visitors{
- [&](const Fortran::evaluate::ProcedureRef &procRef) {
- // Ensure the procRef expressions are the one being visited.
- assert(procRef.arguments().size() == 2);
- const Fortran::lower::SomeExpr *lhs =
- procRef.arguments()[0].value().UnwrapExpr();
- const Fortran::lower::SomeExpr *rhs =
- procRef.arguments()[1].value().UnwrapExpr();
- assert(lhs && rhs &&
- "user defined assignment arguments must be expressions");
- analyzeAssign(*lhs, *rhs);
- },
- [&](const auto &) { analyzeAssign(assign->lhs, assign->rhs); }},
- assign->u);
- explicitIterSpace.endAssign();
- }
- void analyzeExplicitSpace(const Fortran::parser::ForallAssignmentStmt &stmt) {
- std::visit([&](const auto &s) { analyzeExplicitSpace(s); }, stmt.u);
- }
- void analyzeExplicitSpace(const Fortran::parser::AssignmentStmt &s) {
- analyzeExplicitSpace(s.typedAssignment->v.operator->());
- }
- void analyzeExplicitSpace(const Fortran::parser::PointerAssignmentStmt &s) {
- analyzeExplicitSpace(s.typedAssignment->v.operator->());
- }
- void analyzeExplicitSpace(const Fortran::parser::WhereConstruct &c) {
- analyzeExplicitSpace(
- std::get<
- Fortran::parser::Statement<Fortran::parser::WhereConstructStmt>>(
- c.t)
- .statement);
- for (const Fortran::parser::WhereBodyConstruct &body :
- std::get<std::list<Fortran::parser::WhereBodyConstruct>>(c.t))
- analyzeExplicitSpace(body);
- for (const Fortran::parser::WhereConstruct::MaskedElsewhere &e :
- std::get<std::list<Fortran::parser::WhereConstruct::MaskedElsewhere>>(
- c.t))
- analyzeExplicitSpace(e);
- if (const auto &e =
- std::get<std::optional<Fortran::parser::WhereConstruct::Elsewhere>>(
- c.t);
- e.has_value())
- analyzeExplicitSpace(e.operator->());
- }
- void analyzeExplicitSpace(const Fortran::parser::WhereConstructStmt &ws) {
- const Fortran::lower::SomeExpr *exp = Fortran::semantics::GetExpr(
- std::get<Fortran::parser::LogicalExpr>(ws.t));
- addMaskVariable(exp);
- analyzeExplicitSpace(*exp);
- }
- void analyzeExplicitSpace(
- const Fortran::parser::WhereConstruct::MaskedElsewhere &ew) {
- analyzeExplicitSpace(
- std::get<
- Fortran::parser::Statement<Fortran::parser::MaskedElsewhereStmt>>(
- ew.t)
- .statement);
- for (const Fortran::parser::WhereBodyConstruct &e :
- std::get<std::list<Fortran::parser::WhereBodyConstruct>>(ew.t))
- analyzeExplicitSpace(e);
- }
- void analyzeExplicitSpace(const Fortran::parser::WhereBodyConstruct &body) {
+ });
+}
+
+/// Create intrinsic module array constant definitions.
+void FirConverter::createIntrinsicModuleDefinitions(
+ Fortran::lower::pft::Program &pft) {
+ // The intrinsic module scope, if present, is the first scope.
+ const Fortran::semantics::Scope *intrinsicModuleScope = nullptr;
+ for (Fortran::lower::pft::Program::Units &u : pft.getUnits()) {
std::visit(Fortran::common::visitors{
- [&](const Fortran::common::Indirection<
- Fortran::parser::WhereConstruct> &wc) {
- analyzeExplicitSpace(wc.value());
+ [&](Fortran::lower::pft::FunctionLikeUnit &f) {
+ intrinsicModuleScope = &f.getScope().parent();
},
- [&](const auto &s) { analyzeExplicitSpace(s.statement); }},
- body.u);
- }
- void analyzeExplicitSpace(const Fortran::parser::MaskedElsewhereStmt &stmt) {
- const Fortran::lower::SomeExpr *exp = Fortran::semantics::GetExpr(
- std::get<Fortran::parser::LogicalExpr>(stmt.t));
- addMaskVariable(exp);
- analyzeExplicitSpace(*exp);
- }
- void
- analyzeExplicitSpace(const Fortran::parser::WhereConstruct::Elsewhere *ew) {
- for (const Fortran::parser::WhereBodyConstruct &e :
- std::get<std::list<Fortran::parser::WhereBodyConstruct>>(ew->t))
- analyzeExplicitSpace(e);
- }
- void analyzeExplicitSpace(const Fortran::parser::WhereStmt &stmt) {
- const Fortran::lower::SomeExpr *exp = Fortran::semantics::GetExpr(
- std::get<Fortran::parser::LogicalExpr>(stmt.t));
- addMaskVariable(exp);
- analyzeExplicitSpace(*exp);
- const std::optional<Fortran::evaluate::Assignment> &assign =
- std::get<Fortran::parser::AssignmentStmt>(stmt.t).typedAssignment->v;
- assert(assign.has_value() && "WHERE has no statement");
- analyzeExplicitSpace(assign.operator->());
- }
- void analyzeExplicitSpace(const Fortran::parser::ForallStmt &forall) {
- analyzeExplicitSpace(
- std::get<
- Fortran::common::Indirection<Fortran::parser::ConcurrentHeader>>(
- forall.t)
- .value());
- analyzeExplicitSpace(std::get<Fortran::parser::UnlabeledStatement<
- Fortran::parser::ForallAssignmentStmt>>(forall.t)
- .statement);
- analyzeExplicitSpacePop();
- }
- void
- analyzeExplicitSpace(const Fortran::parser::ForallConstructStmt &forall) {
- analyzeExplicitSpace(
- std::get<
- Fortran::common::Indirection<Fortran::parser::ConcurrentHeader>>(
- forall.t)
- .value());
+ [&](Fortran::lower::pft::ModuleLikeUnit &m) {
+ intrinsicModuleScope = &m.getScope().parent();
+ },
+ [&](Fortran::lower::pft::BlockDataUnit &b) {},
+ [&](Fortran::lower::pft::CompilerDirectiveUnit &d) {},
+ [&](Fortran::lower::pft::OpenACCDirectiveUnit &d) {},
+ },
+ u);
+ if (intrinsicModuleScope) {
+ while (!intrinsicModuleScope->IsGlobal())
+ intrinsicModuleScope = &intrinsicModuleScope->parent();
+ intrinsicModuleScope = &intrinsicModuleScope->children().front();
+ break;
+ }
}
- void analyzeExplicitSpace(const Fortran::parser::ForallConstruct &forall) {
- analyzeExplicitSpace(
- std::get<
- Fortran::parser::Statement<Fortran::parser::ForallConstructStmt>>(
- forall.t)
- .statement);
- for (const Fortran::parser::ForallBodyConstruct &s :
- std::get<std::list<Fortran::parser::ForallBodyConstruct>>(forall.t)) {
- std::visit(Fortran::common::visitors{
- [&](const Fortran::common::Indirection<
- Fortran::parser::ForallConstruct> &b) {
- analyzeExplicitSpace(b.value());
- },
- [&](const Fortran::parser::WhereConstruct &w) {
- analyzeExplicitSpace(w);
- },
- [&](const auto &b) { analyzeExplicitSpace(b.statement); }},
- s.u);
+ if (!intrinsicModuleScope || !intrinsicModuleScope->IsIntrinsicModules())
+ return;
+ for (const auto &scope : intrinsicModuleScope->children()) {
+ llvm::StringRef modName = toStringRef(scope.symbol()->name());
+ if (modName != "__fortran_ieee_exceptions")
+ continue;
+ for (auto &var : Fortran::lower::pft::getScopeVariableList(scope)) {
+ const Fortran::semantics::Symbol &sym = var.getSymbol();
+ if (sym.test(Fortran::semantics::Symbol::Flag::CompilerCreated))
+ continue;
+ const auto *object =
+ sym.detailsIf<Fortran::semantics::ObjectEntityDetails>();
+ if (object && object->IsArray() && object->init())
+ Fortran::lower::createIntrinsicModuleGlobal(*this, var);
}
- analyzeExplicitSpacePop();
}
+}
- void analyzeExplicitSpacePop() { explicitIterSpace.popLevel(); }
-
- void addMaskVariable(Fortran::lower::FrontEndExpr exp) {
- // Note: use i8 to store bool values. This avoids round-down behavior found
- // with sequences of i1. That is, an array of i1 will be truncated in size
- // and be too small. For example, a buffer of type fir.array<7xi1> will have
- // 0 size.
- mlir::Type i64Ty = builder->getIntegerType(64);
- mlir::TupleType ty = fir::factory::getRaggedArrayHeaderType(*builder);
- mlir::Type buffTy = ty.getType(1);
- mlir::Type shTy = ty.getType(2);
- mlir::Location loc = toLocation();
- mlir::Value hdr = builder->createTemporary(loc, ty);
- // FIXME: Is there a way to create a `zeroinitializer` in LLVM-IR dialect?
- // For now, explicitly set lazy ragged header to all zeros.
- // auto nilTup = builder->createNullConstant(loc, ty);
- // builder->create<fir::StoreOp>(loc, nilTup, hdr);
- mlir::Type i32Ty = builder->getIntegerType(32);
- mlir::Value zero = builder->createIntegerConstant(loc, i32Ty, 0);
- mlir::Value zero64 = builder->createIntegerConstant(loc, i64Ty, 0);
- mlir::Value flags = builder->create<fir::CoordinateOp>(
- loc, builder->getRefType(i64Ty), hdr, zero);
- builder->create<fir::StoreOp>(loc, zero64, flags);
- mlir::Value one = builder->createIntegerConstant(loc, i32Ty, 1);
- mlir::Value nullPtr1 = builder->createNullConstant(loc, buffTy);
- mlir::Value var = builder->create<fir::CoordinateOp>(
- loc, builder->getRefType(buffTy), hdr, one);
- builder->create<fir::StoreOp>(loc, nullPtr1, var);
- mlir::Value two = builder->createIntegerConstant(loc, i32Ty, 2);
- mlir::Value nullPtr2 = builder->createNullConstant(loc, shTy);
- mlir::Value shape = builder->create<fir::CoordinateOp>(
- loc, builder->getRefType(shTy), hdr, two);
- builder->create<fir::StoreOp>(loc, nullPtr2, shape);
- implicitIterSpace.addMaskVariable(exp, var, shape, hdr);
- explicitIterSpace.outermostContext().attachCleanup(
- [builder = this->builder, hdr, loc]() {
- fir::runtime::genRaggedArrayDeallocate(loc, *builder, hdr);
- });
- }
+/// Lower a procedure (nest).
+void FirConverter::lowerFunc(Fortran::lower::pft::FunctionLikeUnit &funit) {
+ setCurrentPosition(funit.getStartingSourceLoc());
+ for (int entryIndex = 0, last = funit.entryPointList.size();
+ entryIndex < last; ++entryIndex) {
+ funit.setActiveEntry(entryIndex);
+ startNewFunction(funit); // the entry point for lowering this procedure
+ for (Fortran::lower::pft::Evaluation &eval : funit.evaluationList)
+ genFIR(eval);
+ endNewFunction(funit);
+ }
+ funit.setActiveEntry(0);
+ for (Fortran::lower::pft::FunctionLikeUnit &f : funit.nestedFunctions)
+ lowerFunc(f); // internal procedure
+}
- void createRuntimeTypeInfoGlobals() {}
+/// Lower module variable definitions to fir::globalOp and OpenMP/OpenACC
+/// declarative construct.
+void FirConverter::lowerModuleDeclScope(
+ Fortran::lower::pft::ModuleLikeUnit &mod) {
+ setCurrentPosition(mod.getStartingSourceLoc());
+ createGlobalOutsideOfFunctionLowering([&]() {
+ auto &scopeVariableListMap =
+ Fortran::lower::pft::getScopeVariableListMap(mod);
+ for (const auto &var : Fortran::lower::pft::getScopeVariableList(
+ mod.getScope(), scopeVariableListMap)) {
+ // Only define the variables owned by this module.
+ const Fortran::semantics::Scope *owningScope = var.getOwningScope();
+ if (!owningScope || mod.getScope() == *owningScope)
+ Fortran::lower::defineModuleVariable(*this, var);
+ }
+ for (auto &eval : mod.evaluationList)
+ genFIR(eval);
+ });
+}
- bool lowerToHighLevelFIR() const {
- return bridge.getLoweringOptions().getLowerToHighLevelFIR();
- }
+/// Lower functions contained in a module.
+void FirConverter::lowerMod(Fortran::lower::pft::ModuleLikeUnit &mod) {
+ for (Fortran::lower::pft::FunctionLikeUnit &f : mod.nestedFunctions)
+ lowerFunc(f);
+}
- // Returns the mangling prefix for the given constant expression.
- std::string getConstantExprManglePrefix(mlir::Location loc,
- const Fortran::lower::SomeExpr &expr,
- mlir::Type eleTy) {
- return std::visit(
- [&](const auto &x) -> std::string {
- using T = std::decay_t<decltype(x)>;
- if constexpr (Fortran::common::HasMember<
- T, Fortran::lower::CategoryExpression>) {
- if constexpr (T::Result::category ==
- Fortran::common::TypeCategory::Derived) {
- if (const auto *constant =
- std::get_if<Fortran::evaluate::Constant<
- Fortran::evaluate::SomeDerived>>(&x.u))
- return Fortran::lower::mangle::mangleArrayLiteral(eleTy,
- *constant);
- fir::emitFatalError(loc,
- "non a constant derived type expression");
- } else {
- return std::visit(
- [&](const auto &someKind) -> std::string {
- using T = std::decay_t<decltype(someKind)>;
- using TK = Fortran::evaluate::Type<T::Result::category,
- T::Result::kind>;
- if (const auto *constant =
- std::get_if<Fortran::evaluate::Constant<TK>>(
- &someKind.u)) {
- return Fortran::lower::mangle::mangleArrayLiteral(
- nullptr, *constant);
- }
- fir::emitFatalError(
- loc, "not a Fortran::evaluate::Constant<T> expression");
- return {};
- },
- x.u);
- }
- } else {
- fir::emitFatalError(loc, "unexpected expression");
- }
- },
- expr.u);
- }
+//===--------------------------------------------------------------------===//
+// Analysis on a nested explicit iteration space.
+//===--------------------------------------------------------------------===//
+
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::ConcurrentHeader &header) {
+ explicitIterSpace.pushLevel();
+ for (const Fortran::parser::ConcurrentControl &ctrl :
+ std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t)) {
+ const Fortran::semantics::Symbol *ctrlVar =
+ std::get<Fortran::parser::Name>(ctrl.t).symbol;
+ explicitIterSpace.addSymbol(ctrlVar);
+ }
+ if (const auto &mask =
+ std::get<std::optional<Fortran::parser::ScalarLogicalExpr>>(header.t);
+ mask.has_value())
+ analyzeExplicitSpace(*Fortran::semantics::GetExpr(*mask));
+}
- /// Performing OpenACC lowering action that were deferred to the end of
- /// lowering.
- void finalizeOpenACCLowering() {
- Fortran::lower::finalizeOpenACCRoutineAttachment(getModuleOp(),
- accRoutineInfos);
- }
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::evaluate::Assignment *assign) {
+ auto analyzeAssign = [&](const Fortran::lower::SomeExpr &lhs,
+ const Fortran::lower::SomeExpr &rhs) {
+ analyzeExplicitSpace</*LHS=*/true>(lhs);
+ analyzeExplicitSpace(rhs);
+ };
+ std::visit(
+ Fortran::common::visitors{
+ [&](const Fortran::evaluate::ProcedureRef &procRef) {
+ // Ensure the procRef expressions are the one being visited.
+ assert(procRef.arguments().size() == 2);
+ const Fortran::lower::SomeExpr *lhs =
+ procRef.arguments()[0].value().UnwrapExpr();
+ const Fortran::lower::SomeExpr *rhs =
+ procRef.arguments()[1].value().UnwrapExpr();
+ assert(lhs && rhs &&
+ "user defined assignment arguments must be expressions");
+ analyzeAssign(*lhs, *rhs);
+ },
+ [&](const auto &) { analyzeAssign(assign->lhs, assign->rhs); }},
+ assign->u);
+ explicitIterSpace.endAssign();
+}
- /// Performing OpenMP lowering actions that were deferred to the end of
- /// lowering.
- void finalizeOpenMPLowering(
- const Fortran::semantics::Symbol *globalOmpRequiresSymbol) {
- // Set the module attribute related to OpenMP requires directives
- if (ompDeviceCodeFound)
- Fortran::lower::genOpenMPRequires(getModuleOp().getOperation(),
- globalOmpRequiresSymbol);
- }
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::WhereConstruct &c) {
+ analyzeExplicitSpace(
+ std::get<Fortran::parser::Statement<Fortran::parser::WhereConstructStmt>>(
+ c.t)
+ .statement);
+ for (const Fortran::parser::WhereBodyConstruct &body :
+ std::get<std::list<Fortran::parser::WhereBodyConstruct>>(c.t))
+ analyzeExplicitSpace(body);
+ for (const Fortran::parser::WhereConstruct::MaskedElsewhere &e :
+ std::get<std::list<Fortran::parser::WhereConstruct::MaskedElsewhere>>(
+ c.t))
+ analyzeExplicitSpace(e);
+ if (const auto &e =
+ std::get<std::optional<Fortran::parser::WhereConstruct::Elsewhere>>(
+ c.t);
+ e.has_value())
+ analyzeExplicitSpace(e.operator->());
+}
- //===--------------------------------------------------------------------===//
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::WhereConstructStmt &ws) {
+ const Fortran::lower::SomeExpr *exp =
+ Fortran::semantics::GetExpr(std::get<Fortran::parser::LogicalExpr>(ws.t));
+ addMaskVariable(exp);
+ analyzeExplicitSpace(*exp);
+}
- Fortran::lower::LoweringBridge &bridge;
- Fortran::evaluate::FoldingContext foldingContext;
- fir::FirOpBuilder *builder = nullptr;
- Fortran::lower::pft::Evaluation *evalPtr = nullptr;
- Fortran::lower::SymMap localSymbols;
- Fortran::parser::CharBlock currentPosition;
- TypeInfoConverter typeInfoConverter;
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::WhereConstruct::MaskedElsewhere &ew) {
+ analyzeExplicitSpace(
+ std::get<
+ Fortran::parser::Statement<Fortran::parser::MaskedElsewhereStmt>>(
+ ew.t)
+ .statement);
+ for (const Fortran::parser::WhereBodyConstruct &e :
+ std::get<std::list<Fortran::parser::WhereBodyConstruct>>(ew.t))
+ analyzeExplicitSpace(e);
+}
- // Stack to manage object deallocation and finalization at construct exits.
- llvm::SmallVector<ConstructContext> activeConstructStack;
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::WhereBodyConstruct &body) {
+ std::visit(Fortran::common::visitors{
+ [&](const Fortran::common::Indirection<
+ Fortran::parser::WhereConstruct> &wc) {
+ analyzeExplicitSpace(wc.value());
+ },
+ [&](const auto &s) { analyzeExplicitSpace(s.statement); }},
+ body.u);
+}
- /// BLOCK name mangling component map
- int blockId = 0;
- Fortran::lower::mangle::ScopeBlockIdMap scopeBlockIdMap;
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::MaskedElsewhereStmt &stmt) {
+ const Fortran::lower::SomeExpr *exp = Fortran::semantics::GetExpr(
+ std::get<Fortran::parser::LogicalExpr>(stmt.t));
+ addMaskVariable(exp);
+ analyzeExplicitSpace(*exp);
+}
- /// FORALL statement/construct context
- Fortran::lower::ExplicitIterSpace explicitIterSpace;
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::WhereConstruct::Elsewhere *ew) {
+ for (const Fortran::parser::WhereBodyConstruct &e :
+ std::get<std::list<Fortran::parser::WhereBodyConstruct>>(ew->t))
+ analyzeExplicitSpace(e);
+}
- /// WHERE statement/construct mask expression stack
- Fortran::lower::ImplicitIterSpace implicitIterSpace;
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::WhereStmt &stmt) {
+ const Fortran::lower::SomeExpr *exp = Fortran::semantics::GetExpr(
+ std::get<Fortran::parser::LogicalExpr>(stmt.t));
+ addMaskVariable(exp);
+ analyzeExplicitSpace(*exp);
+ const std::optional<Fortran::evaluate::Assignment> &assign =
+ std::get<Fortran::parser::AssignmentStmt>(stmt.t).typedAssignment->v;
+ assert(assign.has_value() && "WHERE has no statement");
+ analyzeExplicitSpace(assign.operator->());
+}
- /// Tuple of host associated variables
- mlir::Value hostAssocTuple;
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::ForallStmt &forall) {
+ analyzeExplicitSpace(
+ std::get<Fortran::common::Indirection<Fortran::parser::ConcurrentHeader>>(
+ forall.t)
+ .value());
+ analyzeExplicitSpace(std::get<Fortran::parser::UnlabeledStatement<
+ Fortran::parser::ForallAssignmentStmt>>(forall.t)
+ .statement);
+ analyzeExplicitSpacePop();
+}
- /// A map of unique names for constant expressions.
- /// The names are used for representing the constant expressions
- /// with global constant initialized objects.
- /// The names are usually prefixed by a mangling string based
- /// on the element type of the constant expression, but the element
- /// type is not used as a key into the map (so the assumption is that
- /// the equivalent constant expressions are prefixed using the same
- /// element type).
- llvm::DenseMap<const Fortran::lower::SomeExpr *, std::string> literalNamesMap;
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::ForallConstructStmt &forall) {
+ analyzeExplicitSpace(
+ std::get<Fortran::common::Indirection<Fortran::parser::ConcurrentHeader>>(
+ forall.t)
+ .value());
+}
- /// Storage for Constant expressions used as keys for literalNamesMap.
- llvm::SmallVector<std::unique_ptr<Fortran::lower::SomeExpr>>
- literalExprsStorage;
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::ForallConstruct &forall) {
+ analyzeExplicitSpace(
+ std::get<
+ Fortran::parser::Statement<Fortran::parser::ForallConstructStmt>>(
+ forall.t)
+ .statement);
+ for (const Fortran::parser::ForallBodyConstruct &s :
+ std::get<std::list<Fortran::parser::ForallBodyConstruct>>(forall.t)) {
+ std::visit(Fortran::common::visitors{
+ [&](const Fortran::common::Indirection<
+ Fortran::parser::ForallConstruct> &b) {
+ analyzeExplicitSpace(b.value());
+ },
+ [&](const Fortran::parser::WhereConstruct &w) {
+ analyzeExplicitSpace(w);
+ },
+ [&](const auto &b) { analyzeExplicitSpace(b.statement); }},
+ s.u);
+ }
+ analyzeExplicitSpacePop();
+}
- /// A counter for uniquing names in `literalNamesMap`.
- std::uint64_t uniqueLitId = 0;
+void FirConverter::addMaskVariable(Fortran::lower::FrontEndExpr exp) {
+ // Note: use i8 to store bool values. This avoids round-down behavior found
+ // with sequences of i1. That is, an array of i1 will be truncated in size
+ // and be too small. For example, a buffer of type fir.array<7xi1> will have
+ // 0 size.
+ mlir::Type i64Ty = builder->getIntegerType(64);
+ mlir::TupleType ty = fir::factory::getRaggedArrayHeaderType(*builder);
+ mlir::Type buffTy = ty.getType(1);
+ mlir::Type shTy = ty.getType(2);
+ mlir::Location loc = toLocation();
+ mlir::Value hdr = builder->createTemporary(loc, ty);
+ // FIXME: Is there a way to create a `zeroinitializer` in LLVM-IR dialect?
+ // For now, explicitly set lazy ragged header to all zeros.
+ // auto nilTup = builder->createNullConstant(loc, ty);
+ // builder->create<fir::StoreOp>(loc, nilTup, hdr);
+ mlir::Type i32Ty = builder->getIntegerType(32);
+ mlir::Value zero = builder->createIntegerConstant(loc, i32Ty, 0);
+ mlir::Value zero64 = builder->createIntegerConstant(loc, i64Ty, 0);
+ mlir::Value flags = builder->create<fir::CoordinateOp>(
+ loc, builder->getRefType(i64Ty), hdr, zero);
+ builder->create<fir::StoreOp>(loc, zero64, flags);
+ mlir::Value one = builder->createIntegerConstant(loc, i32Ty, 1);
+ mlir::Value nullPtr1 = builder->createNullConstant(loc, buffTy);
+ mlir::Value var = builder->create<fir::CoordinateOp>(
+ loc, builder->getRefType(buffTy), hdr, one);
+ builder->create<fir::StoreOp>(loc, nullPtr1, var);
+ mlir::Value two = builder->createIntegerConstant(loc, i32Ty, 2);
+ mlir::Value nullPtr2 = builder->createNullConstant(loc, shTy);
+ mlir::Value shape = builder->create<fir::CoordinateOp>(
+ loc, builder->getRefType(shTy), hdr, two);
+ builder->create<fir::StoreOp>(loc, nullPtr2, shape);
+ implicitIterSpace.addMaskVariable(exp, var, shape, hdr);
+ explicitIterSpace.outermostContext().attachCleanup(
+ [builder = this->builder, hdr, loc]() {
+ fir::runtime::genRaggedArrayDeallocate(loc, *builder, hdr);
+ });
+}
- /// Deferred OpenACC routine attachment.
- Fortran::lower::AccRoutineInfoMappingList accRoutineInfos;
+// Returns the mangling prefix for the given constant expression.
+std::string
+FirConverter::getConstantExprManglePrefix(mlir::Location loc,
+ const Fortran::lower::SomeExpr &expr,
+ mlir::Type eleTy) {
+ return std::visit(
+ [&](const auto &x) -> std::string {
+ using T = std::decay_t<decltype(x)>;
+ if constexpr (Fortran::common::HasMember<
+ T, Fortran::lower::CategoryExpression>) {
+ if constexpr (T::Result::category ==
+ Fortran::common::TypeCategory::Derived) {
+ if (const auto *constant = std::get_if<Fortran::evaluate::Constant<
+ Fortran::evaluate::SomeDerived>>(&x.u))
+ return Fortran::lower::mangle::mangleArrayLiteral(eleTy,
+ *constant);
+ fir::emitFatalError(loc, "non a constant derived type expression");
+ } else {
+ return std::visit(
+ [&](const auto &someKind) -> std::string {
+ using T = std::decay_t<decltype(someKind)>;
+ using TK = Fortran::evaluate::Type<T::Result::category,
+ T::Result::kind>;
+ if (const auto *constant =
+ std::get_if<Fortran::evaluate::Constant<TK>>(
+ &someKind.u)) {
+ return Fortran::lower::mangle::mangleArrayLiteral(
+ nullptr, *constant);
+ }
+ fir::emitFatalError(
+ loc, "not a Fortran::evaluate::Constant<T> expression");
+ return {};
+ },
+ x.u);
+ }
+ } else {
+ fir::emitFatalError(loc, "unexpected expression");
+ }
+ },
+ expr.u);
+}
- /// Whether an OpenMP target region or declare target function/subroutine
- /// intended for device offloading has been detected
- bool ompDeviceCodeFound = false;
+/// Performing OpenACC lowering action that were deferred to the end of
+/// lowering.
+void FirConverter::finalizeOpenACCLowering() {
+ Fortran::lower::finalizeOpenACCRoutineAttachment(getModuleOp(),
+ accRoutineInfos);
+}
- const Fortran::lower::ExprToValueMap *exprValueOverrides{nullptr};
-};
+/// Performing OpenMP lowering actions that were deferred to the end of
+/// lowering.
+void FirConverter::finalizeOpenMPLowering(
+ const Fortran::semantics::Symbol *globalOmpRequiresSymbol) {
+ // Set the module attribute related to OpenMP requires directives
+ if (ompDeviceCodeFound)
+ Fortran::lower::genOpenMPRequires(getModuleOp().getOperation(),
+ globalOmpRequiresSymbol);
+}
-} // namespace
+} // namespace Fortran::lower
Fortran::evaluate::FoldingContext
Fortran::lower::LoweringBridge::createFoldingContext() const {
diff --git a/flang/lib/Lower/FirConverter.h b/flang/lib/Lower/FirConverter.h
new file mode 100644
index 0000000000000..f05b80b6ea002
--- /dev/null
+++ b/flang/lib/Lower/FirConverter.h
@@ -0,0 +1,1066 @@
+//===-- FirConverter.h ----------------------------------------------------===//
+//
+// 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
+//
+//===----------------------------------------------------------------------===//
+//
+// Coding style: https://mlir.llvm.org/getting_started/DeveloperGuide/
+//
+//===----------------------------------------------------------------------===//
+
+#ifndef FORTRAN_LOWER_FIRCONVERTER_H
+#define FORTRAN_LOWER_FIRCONVERTER_H
+
+#include "flang/Common/Fortran.h"
+#include "flang/Lower/AbstractConverter.h"
+#include "flang/Lower/Bridge.h"
+#include "flang/Lower/CallInterface.h"
+#include "flang/Lower/ConvertExpr.h"
+#include "flang/Lower/ConvertType.h"
+#include "flang/Lower/ConvertVariable.h"
+#include "flang/Lower/IterationSpace.h"
+#include "flang/Lower/Mangler.h"
+#include "flang/Lower/OpenACC.h"
+#include "flang/Lower/PFTBuilder.h"
+#include "flang/Lower/PFTDefs.h"
+#include "flang/Lower/StatementContext.h"
+#include "flang/Lower/SymbolMap.h"
+#include "flang/Optimizer/Builder/BoxValue.h"
+#include "flang/Optimizer/Builder/FIRBuilder.h"
+#include "flang/Optimizer/Builder/HLFIRTools.h"
+#include "flang/Optimizer/Dialect/FIRType.h"
+#include "flang/Optimizer/Dialect/Support/KindMapping.h"
+#include "flang/Optimizer/HLFIR/HLFIROps.h"
+#include "flang/Parser/parse-tree.h"
+#include "flang/Runtime/iostat.h"
+#include "flang/Semantics/scope.h"
+#include "flang/Semantics/semantics.h"
+#include "flang/Semantics/symbol.h"
+#include "flang/Semantics/tools.h"
+#include "flang/Semantics/type.h"
+
+#include "mlir/Dialect/Arith/IR/Arith.h"
+#include "mlir/Dialect/ControlFlow/IR/ControlFlowOps.h"
+#include "mlir/Dialect/Func/IR/FuncOps.h"
+#include "mlir/IR/Block.h"
+#include "mlir/IR/Builders.h"
+#include "mlir/IR/BuiltinOps.h"
+#include "mlir/IR/BuiltinTypes.h"
+#include "mlir/IR/Location.h"
+#include "mlir/IR/MLIRContext.h"
+#include "mlir/IR/Operation.h"
+#include "mlir/IR/PatternMatch.h"
+#include "mlir/IR/Region.h"
+#include "mlir/IR/Types.h"
+#include "mlir/IR/Value.h"
+
+#include "llvm/ADT/ArrayRef.h"
+#include "llvm/ADT/DenseMap.h"
+#include "llvm/ADT/SetVector.h"
+#include "llvm/ADT/SmallVector.h"
+#include "llvm/ADT/StringRef.h"
+#include "llvm/Support/Casting.h"
+
+#include <cstddef>
+#include <functional>
+#include <list>
+#include <memory>
+#include <optional>
+#include <string>
+#include <tuple>
+#include <variant>
+
+namespace Fortran::lower {
+
+class FirConverter : public Fortran::lower::AbstractConverter {
+public:
+ explicit FirConverter(Fortran::lower::LoweringBridge &bridge)
+ : Fortran::lower::AbstractConverter(bridge.getLoweringOptions()),
+ bridge{bridge}, foldingContext{bridge.createFoldingContext()} {}
+ virtual ~FirConverter() = default;
+
+ void run(Fortran::lower::pft::Program &pft);
+
+ void declareFunction(Fortran::lower::pft::FunctionLikeUnit &funit);
+
+ const Fortran::semantics::Scope &
+ getSymbolHostScope(const Fortran::semantics::Symbol &sym);
+
+ void collectHostAssociatedVariables(
+ Fortran::lower::pft::FunctionLikeUnit &funit,
+ llvm::SetVector<const Fortran::semantics::Symbol *> &escapees);
+
+ //===--------------------------------------------------------------------===//
+ // AbstractConverter overrides
+ //===--------------------------------------------------------------------===//
+
+ mlir::Value getSymbolAddress(Fortran::lower::SymbolRef sym) override final {
+ return lookupSymbol(sym).getAddr();
+ }
+
+ fir::ExtendedValue
+ symBoxToExtendedValue(const Fortran::lower::SymbolBox &symBox);
+
+ fir::ExtendedValue
+ getSymbolExtendedValue(const Fortran::semantics::Symbol &sym,
+ Fortran::lower::SymMap *symMap) override final;
+
+ mlir::Value impliedDoBinding(llvm::StringRef name) override final;
+
+ void copySymbolBinding(Fortran::lower::SymbolRef src,
+ Fortran::lower::SymbolRef target) override final {
+ localSymbols.copySymbolBinding(src, target);
+ }
+
+ bool bindIfNewSymbol(Fortran::lower::SymbolRef sym,
+ const fir::ExtendedValue &exval);
+
+ void bindSymbol(Fortran::lower::SymbolRef sym,
+ const fir::ExtendedValue &exval) override final {
+ addSymbol(sym, exval, /*forced=*/true);
+ }
+
+ void
+ overrideExprValues(const Fortran::lower::ExprToValueMap *map) override final {
+ exprValueOverrides = map;
+ }
+
+ const Fortran::lower::ExprToValueMap *getExprOverrides() override final {
+ return exprValueOverrides;
+ }
+
+ bool lookupLabelSet(Fortran::lower::SymbolRef sym,
+ Fortran::lower::pft::LabelSet &labelSet) override final;
+
+ Fortran::lower::pft::Evaluation *
+ lookupLabel(Fortran::lower::pft::Label label) override final {
+ Fortran::lower::pft::FunctionLikeUnit &owningProc =
+ *getEval().getOwningProcedure();
+ return owningProc.labelEvaluationMap.lookup(label);
+ }
+
+ fir::ExtendedValue
+ genExprAddr(const Fortran::lower::SomeExpr &expr,
+ Fortran::lower::StatementContext &context,
+ mlir::Location *locPtr = nullptr) override final;
+
+ fir::ExtendedValue
+ genExprValue(const Fortran::lower::SomeExpr &expr,
+ Fortran::lower::StatementContext &context,
+ mlir::Location *locPtr = nullptr) override final;
+
+ fir::ExtendedValue
+ genExprBox(mlir::Location loc, const Fortran::lower::SomeExpr &expr,
+ Fortran::lower::StatementContext &stmtCtx) override final;
+
+ Fortran::evaluate::FoldingContext &getFoldingContext() override final {
+ return foldingContext;
+ }
+
+ mlir::Type genType(const Fortran::lower::SomeExpr &expr) override final {
+ return Fortran::lower::translateSomeExprToFIRType(*this, expr);
+ }
+
+ mlir::Type genType(const Fortran::lower::pft::Variable &var) override final {
+ return Fortran::lower::translateVariableToFIRType(*this, var);
+ }
+
+ mlir::Type genType(Fortran::lower::SymbolRef sym) override final {
+ return Fortran::lower::translateSymbolToFIRType(*this, sym);
+ }
+
+ mlir::Type
+ genType(Fortran::common::TypeCategory tc, int kind,
+ llvm::ArrayRef<std::int64_t> lenParameters) override final {
+ return Fortran::lower::getFIRType(&getMLIRContext(), tc, kind,
+ lenParameters);
+ }
+
+ mlir::Type
+ genType(const Fortran::semantics::DerivedTypeSpec &tySpec) override final {
+ return Fortran::lower::translateDerivedTypeToFIRType(*this, tySpec);
+ }
+
+ mlir::Type genType(Fortran::common::TypeCategory tc) override final {
+ return Fortran::lower::getFIRType(
+ &getMLIRContext(), tc, bridge.getDefaultKinds().GetDefaultKind(tc),
+ std::nullopt);
+ }
+
+ bool isPresentShallowLookup(Fortran::semantics::Symbol &sym) override final {
+ return bool(shallowLookupSymbol(sym));
+ }
+
+ bool createHostAssociateVarClone(
+ const Fortran::semantics::Symbol &sym) override final;
+
+ void createHostAssociateVarCloneDealloc(
+ const Fortran::semantics::Symbol &sym) override final;
+
+ void copyHostAssociateVar(
+ const Fortran::semantics::Symbol &sym,
+ mlir::OpBuilder::InsertPoint *copyAssignIP = nullptr) override final;
+
+ //===--------------------------------------------------------------------===//
+ // Utility methods
+ //===--------------------------------------------------------------------===//
+
+ void collectSymbolSet(
+ Fortran::lower::pft::Evaluation &eval,
+ llvm::SetVector<const Fortran::semantics::Symbol *> &symbolSet,
+ Fortran::semantics::Symbol::Flag flag, bool collectSymbols,
+ bool checkHostAssociatedSymbols) override final;
+
+ mlir::Location getCurrentLocation() override final { return toLocation(); }
+
+ /// Generate a dummy location.
+ mlir::Location genUnknownLocation() override final {
+ // Note: builder may not be instantiated yet
+ return mlir::UnknownLoc::get(&getMLIRContext());
+ }
+
+ mlir::Location
+ genLocation(const Fortran::parser::CharBlock &block) override final;
+
+ const Fortran::semantics::Scope &getCurrentScope() override final {
+ return bridge.getSemanticsContext().FindScope(currentPosition);
+ }
+
+ fir::FirOpBuilder &getFirOpBuilder() override final { return *builder; }
+
+ mlir::ModuleOp &getModuleOp() override final { return bridge.getModule(); }
+
+ mlir::MLIRContext &getMLIRContext() override final {
+ return bridge.getMLIRContext();
+ }
+ std::string
+ mangleName(const Fortran::semantics::Symbol &symbol) override final {
+ return Fortran::lower::mangle::mangleName(
+ symbol, scopeBlockIdMap, /*keepExternalInScope=*/false,
+ getLoweringOptions().getUnderscoring());
+ }
+ std::string mangleName(
+ const Fortran::semantics::DerivedTypeSpec &derivedType) override final {
+ return Fortran::lower::mangle::mangleName(derivedType, scopeBlockIdMap);
+ }
+ std::string mangleName(std::string &name) override final {
+ return Fortran::lower::mangle::mangleName(name, getCurrentScope(),
+ scopeBlockIdMap);
+ }
+ std::string getRecordTypeFieldName(
+ const Fortran::semantics::Symbol &component) override final {
+ return Fortran::lower::mangle::getRecordTypeFieldName(component,
+ scopeBlockIdMap);
+ }
+ const fir::KindMapping &getKindMap() override final {
+ return bridge.getKindMap();
+ }
+
+ Fortran::lower::StatementContext &getFctCtx() override final;
+
+ mlir::Value hostAssocTupleValue() override final { return hostAssocTuple; }
+
+ /// Record a binding for the ssa-value of the tuple for this function.
+ void bindHostAssocTuple(mlir::Value val) override final {
+ assert(!hostAssocTuple && val);
+ hostAssocTuple = val;
+ }
+
+ void registerTypeInfo(mlir::Location loc,
+ Fortran::lower::SymbolRef typeInfoSym,
+ const Fortran::semantics::DerivedTypeSpec &typeSpec,
+ fir::RecordType type) override final {
+ typeInfoConverter.registerTypeInfo(*this, loc, typeInfoSym, typeSpec, type);
+ }
+
+ llvm::StringRef
+ getUniqueLitName(mlir::Location loc,
+ std::unique_ptr<Fortran::lower::SomeExpr> expr,
+ mlir::Type eleTy) override final;
+
+private:
+ FirConverter() = delete;
+ FirConverter(const FirConverter &) = delete;
+ FirConverter &operator=(const FirConverter &) = delete;
+
+ /// Helper classes
+
+ /// Information for generating a structured or unstructured increment loop.
+ struct IncrementLoopInfo {
+ template <typename T>
+ explicit IncrementLoopInfo(Fortran::semantics::Symbol &sym, const T &lower,
+ const T &upper, const std::optional<T> &step,
+ bool isUnordered = false)
+ : loopVariableSym{&sym}, lowerExpr{Fortran::semantics::GetExpr(lower)},
+ upperExpr{Fortran::semantics::GetExpr(upper)},
+ stepExpr{Fortran::semantics::GetExpr(step)},
+ isUnordered{isUnordered} {}
+
+ IncrementLoopInfo(IncrementLoopInfo &&) = default;
+ IncrementLoopInfo &operator=(IncrementLoopInfo &&x) = default;
+
+ bool isStructured() const { return !headerBlock; }
+
+ mlir::Type getLoopVariableType() const {
+ assert(loopVariable && "must be set");
+ return fir::unwrapRefType(loopVariable.getType());
+ }
+
+ bool hasLocalitySpecs() const {
+ return !localSymList.empty() || !localInitSymList.empty() ||
+ !sharedSymList.empty();
+ }
+
+ // Data members common to both structured and unstructured loops.
+ const Fortran::semantics::Symbol *loopVariableSym;
+ const Fortran::lower::SomeExpr *lowerExpr;
+ const Fortran::lower::SomeExpr *upperExpr;
+ const Fortran::lower::SomeExpr *stepExpr;
+ const Fortran::lower::SomeExpr *maskExpr = nullptr;
+ bool isUnordered; // do concurrent, forall
+ llvm::SmallVector<const Fortran::semantics::Symbol *> localSymList;
+ llvm::SmallVector<const Fortran::semantics::Symbol *> localInitSymList;
+ llvm::SmallVector<const Fortran::semantics::Symbol *> sharedSymList;
+ mlir::Value loopVariable = nullptr;
+
+ // Data members for structured loops.
+ fir::DoLoopOp doLoop = nullptr;
+
+ // Data members for unstructured loops.
+ bool hasRealControl = false;
+ mlir::Value tripVariable = nullptr;
+ mlir::Value stepVariable = nullptr;
+ mlir::Block *headerBlock = nullptr; // loop entry and test block
+ mlir::Block *maskBlock = nullptr; // concurrent loop mask block
+ mlir::Block *bodyBlock = nullptr; // first loop body block
+ mlir::Block *exitBlock = nullptr; // loop exit target block
+ };
+
+ using IncrementLoopNestInfo = llvm::SmallVector<IncrementLoopInfo, 8>;
+
+ /// Information to support stack management, object deallocation, and
+ /// object finalization at early and normal construct exits.
+ struct ConstructContext {
+ explicit ConstructContext(Fortran::lower::pft::Evaluation &eval,
+ Fortran::lower::StatementContext &stmtCtx)
+ : eval{eval}, stmtCtx{stmtCtx} {}
+
+ Fortran::lower::pft::Evaluation &eval; // construct eval
+ Fortran::lower::StatementContext &stmtCtx; // construct exit code
+ };
+
+ /// Helper class to generate the runtime type info global data and the
+ /// fir.type_info operations that contain the dipatch tables (if any).
+ /// The type info global data is required to describe the derived type to the
+ /// runtime so that it can operate over it.
+ /// It must be ensured these operations will be generated for every derived
+ /// type lowered in the current translated unit. However, these operations
+ /// cannot be generated before FuncOp have been created for functions since
+ /// the initializers may take their address (e.g for type bound procedures).
+ /// This class allows registering all the required type info while it is not
+ /// possible to create GlobalOp/TypeInfoOp, and to generate this data afte
+ /// function lowering.
+ class TypeInfoConverter {
+ /// Store the location and symbols of derived type info to be generated.
+ /// The location of the derived type instantiation is also stored because
+ /// runtime type descriptor symbols are compiler generated and cannot be
+ /// mapped to user code on their own.
+ struct TypeInfo {
+ Fortran::semantics::SymbolRef symbol;
+ const Fortran::semantics::DerivedTypeSpec &typeSpec;
+ fir::RecordType type;
+ mlir::Location loc;
+ };
+
+ public:
+ void registerTypeInfo(Fortran::lower::AbstractConverter &converter,
+ mlir::Location loc,
+ Fortran::semantics::SymbolRef typeInfoSym,
+ const Fortran::semantics::DerivedTypeSpec &typeSpec,
+ fir::RecordType type);
+ void createTypeInfo(Fortran::lower::AbstractConverter &converter);
+
+ private:
+ void createTypeInfoOpAndGlobal(Fortran::lower::AbstractConverter &converter,
+ const TypeInfo &info);
+ void createTypeInfoOp(Fortran::lower::AbstractConverter &converter,
+ const TypeInfo &info);
+
+ /// Store the front-end data that will be required to generate the type info
+ /// for the derived types that have been converted to fir.type<>.
+ llvm::SmallVector<TypeInfo> registeredTypeInfo;
+ /// Create derived type info immediately without storing the
+ /// symbol in registeredTypeInfo.
+ bool skipRegistration = false;
+ /// Track symbols symbols processed during and after the registration
+ /// to avoid infinite loops between type conversions and global variable
+ /// creation.
+ llvm::SmallSetVector<Fortran::semantics::SymbolRef, 32> seen;
+ };
+
+ //===--------------------------------------------------------------------===//
+ // Helper member functions
+ //===--------------------------------------------------------------------===//
+
+ mlir::Value createFIRExpr(mlir::Location loc,
+ const Fortran::lower::SomeExpr *expr,
+ Fortran::lower::StatementContext &stmtCtx) {
+ return fir::getBase(genExprValue(*expr, stmtCtx, &loc));
+ }
+
+ Fortran::lower::SymbolBox
+ lookupSymbol(const Fortran::semantics::Symbol &sym,
+ Fortran::lower::SymMap *symMap = nullptr);
+
+ /// Find the symbol in the inner-most level of the local map or return null.
+ Fortran::lower::SymbolBox
+ shallowLookupSymbol(const Fortran::semantics::Symbol &sym) {
+ if (Fortran::lower::SymbolBox v = localSymbols.shallowLookupSymbol(sym))
+ return v;
+ return {};
+ }
+
+ /// Find the symbol in one level up of symbol map such as for host-association
+ /// in OpenMP code or return null.
+ Fortran::lower::SymbolBox
+ lookupOneLevelUpSymbol(const Fortran::semantics::Symbol &sym) {
+ if (Fortran::lower::SymbolBox v = localSymbols.lookupOneLevelUpSymbol(sym))
+ return v;
+ return {};
+ }
+
+ bool addSymbol(const Fortran::semantics::SymbolRef sym,
+ fir::ExtendedValue val, bool forced = false);
+
+ bool mapBlockArgToDummyOrResult(const Fortran::semantics::SymbolRef sym,
+ mlir::Value val, bool forced = false);
+
+ mlir::Value genLoopVariableAddress(mlir::Location loc,
+ const Fortran::semantics::Symbol &sym,
+ bool isUnordered);
+
+ static bool isNumericScalarCategory(Fortran::common::TypeCategory cat) {
+ return cat == Fortran::common::TypeCategory::Integer ||
+ cat == Fortran::common::TypeCategory::Real ||
+ cat == Fortran::common::TypeCategory::Complex ||
+ cat == Fortran::common::TypeCategory::Logical;
+ }
+ static bool isLogicalCategory(Fortran::common::TypeCategory cat) {
+ return cat == Fortran::common::TypeCategory::Logical;
+ }
+ static bool isCharacterCategory(Fortran::common::TypeCategory cat) {
+ return cat == Fortran::common::TypeCategory::Character;
+ }
+ static bool isDerivedCategory(Fortran::common::TypeCategory cat) {
+ return cat == Fortran::common::TypeCategory::Derived;
+ }
+
+ mlir::Block *insertBlock(mlir::Block *block);
+
+ Fortran::lower::pft::Evaluation &evalOfLabel(Fortran::parser::Label label);
+
+ void genBranch(mlir::Block *targetBlock) {
+ assert(targetBlock && "missing unconditional target block");
+ builder->create<mlir::cf::BranchOp>(toLocation(), targetBlock);
+ }
+
+ void genConditionalBranch(mlir::Value cond, mlir::Block *trueTarget,
+ mlir::Block *falseTarget);
+ void genConditionalBranch(mlir::Value cond,
+ Fortran::lower::pft::Evaluation *trueTarget,
+ Fortran::lower::pft::Evaluation *falseTarget) {
+ genConditionalBranch(cond, trueTarget->block, falseTarget->block);
+ }
+
+ void genConditionalBranch(const Fortran::parser::ScalarLogicalExpr &expr,
+ mlir::Block *trueTarget, mlir::Block *falseTarget);
+ void genConditionalBranch(const Fortran::parser::ScalarLogicalExpr &expr,
+ Fortran::lower::pft::Evaluation *trueTarget,
+ Fortran::lower::pft::Evaluation *falseTarget);
+
+ Fortran::lower::pft::Evaluation *
+ getActiveAncestor(const Fortran::lower::pft::Evaluation &eval);
+
+ bool hasExitCode(const Fortran::lower::pft::Evaluation &targetEval);
+
+ void
+ genConstructExitBranch(const Fortran::lower::pft::Evaluation &targetEval);
+
+ void genMultiwayBranch(mlir::Value selector,
+ llvm::SmallVector<int64_t> valueList,
+ llvm::SmallVector<Fortran::parser::Label> labelList,
+ const Fortran::lower::pft::Evaluation &defaultEval,
+ mlir::Block *errorBlock = nullptr);
+
+ void pushActiveConstruct(Fortran::lower::pft::Evaluation &eval,
+ Fortran::lower::StatementContext &stmtCtx) {
+ activeConstructStack.push_back(ConstructContext{eval, stmtCtx});
+ eval.activeConstruct = true;
+ }
+
+ void popActiveConstruct() {
+ assert(!activeConstructStack.empty() && "invalid active construct stack");
+ activeConstructStack.back().eval.activeConstruct = false;
+ activeConstructStack.pop_back();
+ }
+
+ //===--------------------------------------------------------------------===//
+ // Termination of symbolically referenced execution units
+ //===--------------------------------------------------------------------===//
+
+ /// END of program
+ ///
+ /// Generate the cleanup block before the program exits
+ void genExitRoutine() {
+ if (blockIsUnterminated())
+ builder->create<mlir::func::ReturnOp>(toLocation());
+ }
+
+ /// END of procedure-like constructs
+ ///
+ void genReturnSymbol(const Fortran::semantics::Symbol &functionSymbol);
+
+ /// Get the return value of a call to \p symbol, which is a subroutine entry
+ /// point that has alternative return specifiers.
+ const mlir::Value
+ getAltReturnResult(const Fortran::semantics::Symbol &symbol) {
+ assert(Fortran::semantics::HasAlternateReturns(symbol) &&
+ "subroutine does not have alternate returns");
+ return getSymbolAddress(symbol);
+ }
+
+ void genFIRProcedureExit(Fortran::lower::pft::FunctionLikeUnit &funit,
+ const Fortran::semantics::Symbol &symbol);
+
+ //
+ // Statements that have control-flow semantics
+ //
+
+ /// Generate an If[Then]Stmt condition or its negation.
+ template <typename A>
+ mlir::Value genIfCondition(const A *stmt, bool negate = false) {
+ mlir::Location loc = toLocation();
+ Fortran::lower::StatementContext stmtCtx;
+ mlir::Value condExpr = createFIRExpr(
+ loc,
+ Fortran::semantics::GetExpr(
+ std::get<Fortran::parser::ScalarLogicalExpr>(stmt->t)),
+ stmtCtx);
+ stmtCtx.finalizeAndReset();
+ mlir::Value cond =
+ builder->createConvert(loc, builder->getI1Type(), condExpr);
+ if (negate)
+ cond = builder->create<mlir::arith::XOrIOp>(
+ loc, cond, builder->createIntegerConstant(loc, cond.getType(), 1));
+ return cond;
+ }
+
+ mlir::func::FuncOp getFunc(llvm::StringRef name, mlir::FunctionType ty);
+
+ void genFIR(const Fortran::parser::CallStmt &stmt);
+ void genFIR(const Fortran::parser::ComputedGotoStmt &stmt);
+ void genFIR(const Fortran::parser::ArithmeticIfStmt &stmt);
+ void genFIR(const Fortran::parser::AssignedGotoStmt &stmt);
+
+ IncrementLoopNestInfo getConcurrentControl(
+ const Fortran::parser::ConcurrentHeader &header,
+ const std::list<Fortran::parser::LocalitySpec> &localityList = {});
+
+ void handleLocalitySpecs(const IncrementLoopInfo &info);
+
+ void genFIR(const Fortran::parser::DoConstruct &doConstruct);
+
+ mlir::Value genControlValue(const Fortran::lower::SomeExpr *expr,
+ const IncrementLoopInfo &info,
+ bool *isConst = nullptr);
+
+ void genFIRIncrementLoopBegin(IncrementLoopNestInfo &incrementLoopNestInfo);
+ void genFIRIncrementLoopEnd(IncrementLoopNestInfo &incrementLoopNestInfo);
+
+ void genFIR(const Fortran::parser::IfConstruct &);
+ void genFIR(const Fortran::parser::CaseConstruct &);
+
+ template <typename A>
+ void genNestedStatement(const Fortran::parser::Statement<A> &stmt) {
+ setCurrentPosition(stmt.source);
+ genFIR(stmt.statement);
+ }
+
+ void forceControlVariableBinding(const Fortran::semantics::Symbol *sym,
+ mlir::Value inducVar);
+
+ void genFIR(const Fortran::parser::ConcurrentHeader &header);
+ void genFIR(const Fortran::parser::ForallAssignmentStmt &stmt);
+ void genFIR(const Fortran::parser::EndForallStmt &);
+
+ template <typename A> void prepareExplicitSpace(const A &forall) {
+ if (!explicitIterSpace.isActive())
+ analyzeExplicitSpace(forall);
+ localSymbols.pushScope();
+ explicitIterSpace.enter();
+ }
+
+ /// Cleanup all the FORALL context information when we exit.
+ void cleanupExplicitSpace() {
+ explicitIterSpace.leave();
+ localSymbols.popScope();
+ }
+
+ void genFIR(const Fortran::parser::ForallStmt &stmt);
+ void genFIR(const Fortran::parser::ForallConstruct &forall);
+ void genFIR(const Fortran::parser::ForallConstructStmt &stmt);
+
+ void genForallNest(const Fortran::parser::ConcurrentHeader &header);
+
+ void genFIR(const Fortran::parser::CompilerDirective &);
+ void genFIR(const Fortran::parser::OpenACCConstruct &acc);
+ void genFIR(const Fortran::parser::OpenACCDeclarativeConstruct &accDecl);
+ void genFIR(const Fortran::parser::OpenACCRoutineConstruct &acc);
+ void genFIR(const Fortran::parser::OpenMPConstruct &omp);
+ void genFIR(const Fortran::parser::OpenMPDeclarativeConstruct &ompDecl);
+ void genFIR(const Fortran::parser::SelectCaseStmt &stmt);
+
+ fir::ExtendedValue
+ genAssociateSelector(const Fortran::lower::SomeExpr &selector,
+ Fortran::lower::StatementContext &stmtCtx);
+
+ void genFIR(const Fortran::parser::AssociateConstruct &);
+ void genFIR(const Fortran::parser::BlockConstruct &blockConstruct);
+ void genFIR(const Fortran::parser::ChangeTeamConstruct &construct);
+ void genFIR(const Fortran::parser::ChangeTeamStmt &stmt);
+ void genFIR(const Fortran::parser::EndChangeTeamStmt &stmt);
+ void genFIR(const Fortran::parser::CriticalConstruct &criticalConstruct);
+ void genFIR(const Fortran::parser::CriticalStmt &);
+ void genFIR(const Fortran::parser::EndCriticalStmt &);
+ void genFIR(const Fortran::parser::SelectRankConstruct &selectRankConstruct);
+ void genFIR(const Fortran::parser::SelectRankStmt &);
+ void genFIR(const Fortran::parser::SelectRankCaseStmt &);
+ void genFIR(const Fortran::parser::SelectTypeConstruct &selectTypeConstruct);
+ void genFIR(const Fortran::parser::BackspaceStmt &stmt);
+ void genFIR(const Fortran::parser::CloseStmt &stmt);
+ void genFIR(const Fortran::parser::EndfileStmt &stmt);
+ void genFIR(const Fortran::parser::FlushStmt &stmt);
+ void genFIR(const Fortran::parser::InquireStmt &stmt);
+ void genFIR(const Fortran::parser::OpenStmt &stmt);
+ void genFIR(const Fortran::parser::PrintStmt &stmt);
+ void genFIR(const Fortran::parser::ReadStmt &stmt);
+ void genFIR(const Fortran::parser::RewindStmt &stmt);
+ void genFIR(const Fortran::parser::WaitStmt &stmt);
+ void genFIR(const Fortran::parser::WriteStmt &stmt);
+
+ template <typename A>
+ void genIoConditionBranches(Fortran::lower::pft::Evaluation &eval,
+ const A &specList, mlir::Value iostat) {
+ if (!iostat)
+ return;
+
+ Fortran::parser::Label endLabel{};
+ Fortran::parser::Label eorLabel{};
+ Fortran::parser::Label errLabel{};
+ bool hasIostat{};
+ for (const auto &spec : specList) {
+ std::visit(
+ Fortran::common::visitors{
+ [&](const Fortran::parser::EndLabel &label) {
+ endLabel = label.v;
+ },
+ [&](const Fortran::parser::EorLabel &label) {
+ eorLabel = label.v;
+ },
+ [&](const Fortran::parser::ErrLabel &label) {
+ errLabel = label.v;
+ },
+ [&](const Fortran::parser::StatVariable &) { hasIostat = true; },
+ [](const auto &) {}},
+ spec.u);
+ }
+ if (!endLabel && !eorLabel && !errLabel)
+ return;
+
+ // An ERR specifier branch is taken on any positive error value rather than
+ // some single specific value. If ERR and IOSTAT specifiers are given and
+ // END and EOR specifiers are allowed, the latter two specifiers must have
+ // explicit branch targets to allow the ERR branch to be implemented as a
+ // default/else target. A label=0 target for an absent END or EOR specifier
+ // indicates that these specifiers have a fallthrough target. END and EOR
+ // specifiers may appear on READ and WAIT statements.
+ bool allSpecifiersRequired = errLabel && hasIostat &&
+ (eval.isA<Fortran::parser::ReadStmt>() ||
+ eval.isA<Fortran::parser::WaitStmt>());
+ mlir::Value selector =
+ builder->createConvert(toLocation(), builder->getIndexType(), iostat);
+ llvm::SmallVector<int64_t> valueList;
+ llvm::SmallVector<Fortran::parser::Label> labelList;
+ if (eorLabel || allSpecifiersRequired) {
+ valueList.push_back(Fortran::runtime::io::IostatEor);
+ labelList.push_back(eorLabel ? eorLabel : 0);
+ }
+ if (endLabel || allSpecifiersRequired) {
+ valueList.push_back(Fortran::runtime::io::IostatEnd);
+ labelList.push_back(endLabel ? endLabel : 0);
+ }
+ if (errLabel) {
+ // Must be last. Value 0 is interpreted as any positive value, or
+ // equivalently as any value other than 0, IostatEor, or IostatEnd.
+ valueList.push_back(0);
+ labelList.push_back(errLabel);
+ }
+ genMultiwayBranch(selector, valueList, labelList, eval.nonNopSuccessor());
+ }
+
+ void genFIR(const Fortran::parser::AllocateStmt &stmt);
+ void genFIR(const Fortran::parser::DeallocateStmt &stmt);
+ void genFIR(const Fortran::parser::NullifyStmt &stmt);
+ void genFIR(const Fortran::parser::EventPostStmt &stmt);
+ void genFIR(const Fortran::parser::EventWaitStmt &stmt);
+ void genFIR(const Fortran::parser::FormTeamStmt &stmt);
+ void genFIR(const Fortran::parser::LockStmt &stmt);
+
+ fir::ExtendedValue
+ genInitializerExprValue(const Fortran::lower::SomeExpr &expr,
+ Fortran::lower::StatementContext &stmtCtx) {
+ return Fortran::lower::createSomeInitializerExpression(
+ toLocation(), *this, expr, localSymbols, stmtCtx);
+ }
+
+ /// Return true if the current context is a conditionalized and implied
+ /// iteration space.
+ bool implicitIterationSpace() { return !implicitIterSpace.empty(); }
+
+ /// Return true if context is currently an explicit iteration space. A scalar
+ /// assignment expression may be contextually within a user-defined iteration
+ /// space, transforming it into an array expression.
+ bool explicitIterationSpace() { return explicitIterSpace.isActive(); }
+
+ void genArrayAssignment(
+ const Fortran::evaluate::Assignment &assign,
+ Fortran::lower::StatementContext &localStmtCtx,
+ std::optional<llvm::SmallVector<mlir::Value>> lbounds = std::nullopt,
+ std::optional<llvm::SmallVector<mlir::Value>> ubounds = std::nullopt);
+
+#if !defined(NDEBUG)
+ static bool isFuncResultDesignator(const Fortran::lower::SomeExpr &expr) {
+ const Fortran::semantics::Symbol *sym =
+ Fortran::evaluate::GetFirstSymbol(expr);
+ return sym && sym->IsFuncResult();
+ }
+#endif
+
+ fir::MutableBoxValue
+ genExprMutableBox(mlir::Location loc,
+ const Fortran::lower::SomeExpr &expr) override final;
+
+ mlir::Value createLboundArray(llvm::ArrayRef<mlir::Value> lbounds,
+ mlir::Location loc);
+
+ void genPointerAssignment(
+ mlir::Location loc, const Fortran::evaluate::Assignment &assign,
+ const Fortran::evaluate::Assignment::BoundsSpec &lbExprs);
+
+ mlir::Value createBoundArray(llvm::ArrayRef<mlir::Value> lbounds,
+ llvm::ArrayRef<mlir::Value> ubounds,
+ mlir::Location loc);
+
+ void genPointerAssignment(
+ mlir::Location loc, const Fortran::evaluate::Assignment &assign,
+ const Fortran::evaluate::Assignment::BoundsRemapping &boundExprs);
+
+ hlfir::Entity genImplicitConvert(const Fortran::evaluate::Assignment &assign,
+ hlfir::Entity rhs, bool preserveLowerBounds,
+ Fortran::lower::StatementContext &stmtCtx);
+
+ static void
+ genCleanUpInRegionIfAny(mlir::Location loc, fir::FirOpBuilder &builder,
+ mlir::Region ®ion,
+ Fortran::lower::StatementContext &context);
+
+ bool firstDummyIsPointerOrAllocatable(
+ const Fortran::evaluate::ProcedureRef &userDefinedAssignment);
+
+ void genDataAssignment(
+ const Fortran::evaluate::Assignment &assign,
+ const Fortran::evaluate::ProcedureRef *userDefinedAssignment);
+
+ void genAssignment(const Fortran::evaluate::Assignment &assign);
+
+ // Is the insertion point of the builder directly or indirectly set
+ // inside any operation of type "Op"?
+ template <typename... Op> bool isInsideOp() const {
+ mlir::Block *block = builder->getInsertionBlock();
+ mlir::Operation *op = block ? block->getParentOp() : nullptr;
+ while (op) {
+ if (mlir::isa<Op...>(op))
+ return true;
+ op = op->getParentOp();
+ }
+ return false;
+ }
+
+ bool isInsideHlfirForallOrWhere() const {
+ return isInsideOp<hlfir::ForallOp, hlfir::WhereOp>();
+ }
+
+ bool isInsideHlfirWhere() const { return isInsideOp<hlfir::WhereOp>(); }
+
+ void genFIR(const Fortran::parser::WhereConstruct &c);
+ void genFIR(const Fortran::parser::WhereBodyConstruct &body);
+
+ void lowerWhereMaskToHlfir(mlir::Location loc,
+ const Fortran::semantics::SomeExpr *maskExpr);
+ void genFIR(const Fortran::parser::WhereConstructStmt &stmt);
+ void genFIR(const Fortran::parser::WhereConstruct::MaskedElsewhere &ew);
+ void genFIR(const Fortran::parser::MaskedElsewhereStmt &stmt);
+ void genFIR(const Fortran::parser::WhereConstruct::Elsewhere &ew);
+ void genFIR(const Fortran::parser::ElsewhereStmt &stmt);
+ void genFIR(const Fortran::parser::EndWhereStmt &);
+ void genFIR(const Fortran::parser::WhereStmt &stmt);
+ void genFIR(const Fortran::parser::PointerAssignmentStmt &stmt);
+ void genFIR(const Fortran::parser::AssignmentStmt &stmt);
+ void genFIR(const Fortran::parser::SyncAllStmt &stmt);
+ void genFIR(const Fortran::parser::SyncImagesStmt &stmt);
+ void genFIR(const Fortran::parser::SyncMemoryStmt &stmt);
+ void genFIR(const Fortran::parser::SyncTeamStmt &stmt);
+ void genFIR(const Fortran::parser::UnlockStmt &stmt);
+ void genFIR(const Fortran::parser::AssignStmt &stmt);
+ void genFIR(const Fortran::parser::FormatStmt &);
+ void genFIR(const Fortran::parser::PauseStmt &stmt);
+ void genFIR(const Fortran::parser::FailImageStmt &stmt);
+ void genFIR(const Fortran::parser::StopStmt &stmt);
+ void genFIR(const Fortran::parser::ReturnStmt &stmt);
+ void genFIR(const Fortran::parser::CycleStmt &);
+ void genFIR(const Fortran::parser::ExitStmt &);
+ void genFIR(const Fortran::parser::GotoStmt &);
+
+ // Nop statements - No code, or code is generated at the construct level.
+ // But note that the genFIR call immediately below that wraps one of these
+ // calls does block management, possibly starting a new block, and possibly
+ // generating a branch to end a block. So these calls may still be required
+ // for that functionality.
+ void genFIR(const Fortran::parser::AssociateStmt &) {} // nop
+ void genFIR(const Fortran::parser::BlockStmt &) {} // nop
+ void genFIR(const Fortran::parser::CaseStmt &) {} // nop
+ void genFIR(const Fortran::parser::ContinueStmt &) {} // nop
+ void genFIR(const Fortran::parser::ElseIfStmt &) {} // nop
+ void genFIR(const Fortran::parser::ElseStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndAssociateStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndBlockStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndDoStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndFunctionStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndIfStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndMpSubprogramStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndProgramStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndSelectStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndSubroutineStmt &) {} // nop
+ void genFIR(const Fortran::parser::EntryStmt &) {} // nop
+ void genFIR(const Fortran::parser::IfStmt &) {} // nop
+ void genFIR(const Fortran::parser::IfThenStmt &) {} // nop
+ void genFIR(const Fortran::parser::NonLabelDoStmt &) {} // nop
+ void genFIR(const Fortran::parser::OmpEndLoopDirective &) {} // nop
+ void genFIR(const Fortran::parser::SelectTypeStmt &) {} // nop
+ void genFIR(const Fortran::parser::TypeGuardStmt &) {} // nop
+
+ void genFIR(Fortran::lower::pft::Evaluation &eval,
+ bool unstructuredContext = true);
+
+ void mapDummiesAndResults(Fortran::lower::pft::FunctionLikeUnit &funit,
+ const Fortran::lower::CalleeInterface &callee);
+
+ void instantiateVar(const Fortran::lower::pft::Variable &var,
+ Fortran::lower::AggregateStoreMap &storeMap);
+
+ void manageFPEnvironment(Fortran::lower::pft::FunctionLikeUnit &funit);
+
+ void startNewFunction(Fortran::lower::pft::FunctionLikeUnit &funit);
+
+ void
+ createEmptyBlocks(std::list<Fortran::lower::pft::Evaluation> &evaluationList);
+
+ /// Return the predicate: "current block does not have a terminator branch".
+ bool blockIsUnterminated() {
+ mlir::Block *currentBlock = builder->getBlock();
+ return currentBlock->empty() ||
+ !currentBlock->back().hasTrait<mlir::OpTrait::IsTerminator>();
+ }
+
+ void startBlock(mlir::Block *newBlock);
+
+ /// Conditionally switch code insertion to a new block.
+ void maybeStartBlock(mlir::Block *newBlock) {
+ if (newBlock)
+ startBlock(newBlock);
+ }
+
+ void eraseDeadCodeAndBlocks(mlir::RewriterBase &rewriter,
+ llvm::MutableArrayRef<mlir::Region> regions);
+
+ void endNewFunction(Fortran::lower::pft::FunctionLikeUnit &funit);
+
+ void createGlobalOutsideOfFunctionLowering(
+ const std::function<void()> &createGlobals);
+
+ void lowerBlockData(Fortran::lower::pft::BlockDataUnit &bdunit);
+
+ /// Create fir::Global for all the common blocks that appear in the program.
+ void
+ lowerCommonBlocks(const Fortran::semantics::CommonBlockList &commonBlocks) {
+ createGlobalOutsideOfFunctionLowering(
+ [&]() { Fortran::lower::defineCommonBlocks(*this, commonBlocks); });
+ }
+
+ void createIntrinsicModuleDefinitions(Fortran::lower::pft::Program &pft);
+
+ void lowerFunc(Fortran::lower::pft::FunctionLikeUnit &funit);
+ void lowerModuleDeclScope(Fortran::lower::pft::ModuleLikeUnit &mod);
+ void lowerMod(Fortran::lower::pft::ModuleLikeUnit &mod);
+
+ void setCurrentPosition(const Fortran::parser::CharBlock &position) {
+ if (position != Fortran::parser::CharBlock{})
+ currentPosition = position;
+ }
+
+ /// Set current position at the location of \p parseTreeNode. Note that the
+ /// position is updated automatically when visiting statements, but not when
+ /// entering higher level nodes like constructs or procedures. This helper is
+ /// intended to cover the latter cases.
+ template <typename A> void setCurrentPositionAt(const A &parseTreeNode) {
+ setCurrentPosition(Fortran::parser::FindSourceLocation(parseTreeNode));
+ }
+
+ //===--------------------------------------------------------------------===//
+ // Utility methods
+ //===--------------------------------------------------------------------===//
+
+ /// Convert a parser CharBlock to a Location
+ mlir::Location toLocation(const Fortran::parser::CharBlock &cb) {
+ return genLocation(cb);
+ }
+
+ mlir::Location toLocation() { return toLocation(currentPosition); }
+ void setCurrentEval(Fortran::lower::pft::Evaluation &eval) {
+ evalPtr = &eval;
+ }
+
+ Fortran::lower::pft::Evaluation &getEval() {
+ assert(evalPtr);
+ return *evalPtr;
+ }
+
+ std::optional<Fortran::evaluate::Shape>
+ getShape(const Fortran::lower::SomeExpr &expr) {
+ return Fortran::evaluate::GetShape(foldingContext, expr);
+ }
+
+ //===--------------------------------------------------------------------===//
+ // Analysis on a nested explicit iteration space.
+ //===--------------------------------------------------------------------===//
+
+ void analyzeExplicitSpace(const Fortran::parser::ConcurrentHeader &header);
+
+ template <bool LHS = false, typename A>
+ void analyzeExplicitSpace(const Fortran::evaluate::Expr<A> &e) {
+ explicitIterSpace.exprBase(&e, LHS);
+ }
+
+ void analyzeExplicitSpace(const Fortran::evaluate::Assignment *assign);
+
+ void analyzeExplicitSpace(const Fortran::parser::ForallAssignmentStmt &stmt) {
+ std::visit([&](const auto &s) { analyzeExplicitSpace(s); }, stmt.u);
+ }
+
+ void analyzeExplicitSpace(const Fortran::parser::AssignmentStmt &s) {
+ analyzeExplicitSpace(s.typedAssignment->v.operator->());
+ }
+
+ void analyzeExplicitSpace(const Fortran::parser::PointerAssignmentStmt &s) {
+ analyzeExplicitSpace(s.typedAssignment->v.operator->());
+ }
+
+ void analyzeExplicitSpace(const Fortran::parser::WhereConstruct &c);
+ void analyzeExplicitSpace(const Fortran::parser::WhereConstructStmt &ws);
+ void analyzeExplicitSpace(
+ const Fortran::parser::WhereConstruct::MaskedElsewhere &ew);
+ void analyzeExplicitSpace(const Fortran::parser::WhereBodyConstruct &body);
+ void analyzeExplicitSpace(const Fortran::parser::MaskedElsewhereStmt &stmt);
+ void
+ analyzeExplicitSpace(const Fortran::parser::WhereConstruct::Elsewhere *ew);
+ void analyzeExplicitSpace(const Fortran::parser::WhereStmt &stmt);
+ void analyzeExplicitSpace(const Fortran::parser::ForallStmt &forall);
+ void analyzeExplicitSpace(const Fortran::parser::ForallConstructStmt &forall);
+ void analyzeExplicitSpace(const Fortran::parser::ForallConstruct &forall);
+
+ void analyzeExplicitSpacePop() { explicitIterSpace.popLevel(); }
+
+ void addMaskVariable(Fortran::lower::FrontEndExpr exp);
+
+ void createRuntimeTypeInfoGlobals() {}
+
+ bool lowerToHighLevelFIR() const {
+ return bridge.getLoweringOptions().getLowerToHighLevelFIR();
+ }
+
+ std::string getConstantExprManglePrefix(mlir::Location loc,
+ const Fortran::lower::SomeExpr &expr,
+ mlir::Type eleTy);
+
+ void finalizeOpenACCLowering();
+ void finalizeOpenMPLowering(
+ const Fortran::semantics::Symbol *globalOmpRequiresSymbol);
+
+ //===--------------------------------------------------------------------===//
+
+ Fortran::lower::LoweringBridge &bridge;
+ Fortran::evaluate::FoldingContext foldingContext;
+ fir::FirOpBuilder *builder = nullptr;
+ Fortran::lower::pft::Evaluation *evalPtr = nullptr;
+ Fortran::lower::SymMap localSymbols;
+ Fortran::parser::CharBlock currentPosition;
+ TypeInfoConverter typeInfoConverter;
+
+ // Stack to manage object deallocation and finalization at construct exits.
+ llvm::SmallVector<ConstructContext> activeConstructStack;
+
+ /// BLOCK name mangling component map
+ int blockId = 0;
+ Fortran::lower::mangle::ScopeBlockIdMap scopeBlockIdMap;
+
+ /// FORALL statement/construct context
+ Fortran::lower::ExplicitIterSpace explicitIterSpace;
+
+ /// WHERE statement/construct mask expression stack
+ Fortran::lower::ImplicitIterSpace implicitIterSpace;
+
+ /// Tuple of host associated variables
+ mlir::Value hostAssocTuple;
+
+ /// A map of unique names for constant expressions.
+ /// The names are used for representing the constant expressions
+ /// with global constant initialized objects.
+ /// The names are usually prefixed by a mangling string based
+ /// on the element type of the constant expression, but the element
+ /// type is not used as a key into the map (so the assumption is that
+ /// the equivalent constant expressions are prefixed using the same
+ /// element type).
+ llvm::DenseMap<const Fortran::lower::SomeExpr *, std::string> literalNamesMap;
+
+ /// Storage for Constant expressions used as keys for literalNamesMap.
+ llvm::SmallVector<std::unique_ptr<Fortran::lower::SomeExpr>>
+ literalExprsStorage;
+
+ /// A counter for uniquing names in `literalNamesMap`.
+ std::uint64_t uniqueLitId = 0;
+
+ /// Deferred OpenACC routine attachment.
+ Fortran::lower::AccRoutineInfoMappingList accRoutineInfos;
+
+ /// Whether an OpenMP target region or declare target function/subroutine
+ /// intended for device offloading has been detected
+ bool ompDeviceCodeFound = false;
+
+ const Fortran::lower::ExprToValueMap *exprValueOverrides{nullptr};
+};
+
+} // namespace Fortran::lower
+
+#endif // FORTRAN_LOWER_FIRCONVERTER_H
>From 2ae85f374c2888c0aa9135761bb5f7bb95556638 Mon Sep 17 00:00:00 2001
From: Krzysztof Parzyszek <Krzysztof.Parzyszek at amd.com>
Date: Thu, 7 Dec 2023 11:48:20 -0600
Subject: [PATCH 2/3] Group declarations of `genFIR` functions together, NFC
This is to make the FIR generation interface stand out visually.
The functions in the cpp file have also been reordered to match
the header.
There are no functional changes.
---
flang/lib/Lower/Bridge.cpp | 6528 ++++++++++++++++----------------
flang/lib/Lower/FirConverter.h | 282 +-
2 files changed, 3407 insertions(+), 3403 deletions(-)
diff --git a/flang/lib/Lower/Bridge.cpp b/flang/lib/Lower/Bridge.cpp
index bb705d1cf4da7..885c9307b8caf 100644
--- a/flang/lib/Lower/Bridge.cpp
+++ b/flang/lib/Lower/Bridge.cpp
@@ -173,3530 +173,3536 @@ void FirConverter::run(Fortran::lower::pft::Program &pft) {
finalizeOpenMPLowering(globalOmpRequiresSymbol);
}
-/// Declare a function.
-void FirConverter::declareFunction(
- Fortran::lower::pft::FunctionLikeUnit &funit) {
- setCurrentPosition(funit.getStartingSourceLoc());
- for (int entryIndex = 0, last = funit.entryPointList.size();
- entryIndex < last; ++entryIndex) {
- funit.setActiveEntry(entryIndex);
- // Calling CalleeInterface ctor will build a declaration
- // mlir::func::FuncOp with no other side effects.
- // TODO: when doing some compiler profiling on real apps, it may be worth
- // to check it's better to save the CalleeInterface instead of recomputing
- // it later when lowering the body. CalleeInterface ctor should be linear
- // with the number of arguments, so it is not awful to do it that way for
- // now, but the linear coefficient might be non negligible. Until
- // measured, stick to the solution that impacts the code less.
- Fortran::lower::CalleeInterface{funit, *this};
- }
- funit.setActiveEntry(0);
+/// Generate FIR for Evaluation \p eval.
+void FirConverter::genFIR(Fortran::lower::pft::Evaluation &eval,
+ bool unstructuredContext) {
+ // Start a new unstructured block when applicable. When transitioning
+ // from unstructured to structured code, unstructuredContext is true,
+ // which accounts for the possibility that the structured code could be
+ // a target that starts a new block.
+ if (unstructuredContext)
+ maybeStartBlock(eval.isConstruct() && eval.lowerAsStructured()
+ ? eval.getFirstNestedEvaluation().block
+ : eval.block);
- // Compute the set of host associated entities from the nested functions.
- llvm::SetVector<const Fortran::semantics::Symbol *> escapeHost;
- for (Fortran::lower::pft::FunctionLikeUnit &f : funit.nestedFunctions)
- collectHostAssociatedVariables(f, escapeHost);
- funit.setHostAssociatedSymbols(escapeHost);
+ // Generate evaluation specific code. Even nop calls should usually reach
+ // here in case they start a new block or require generation of a generic
+ // end-of-block branch. An alternative is to add special case code
+ // elsewhere, such as in the genFIR code for a parent construct.
+ setCurrentEval(eval);
+ setCurrentPosition(eval.position);
+ eval.visit([&](const auto &stmt) { genFIR(stmt); });
- // Declare internal procedures
- for (Fortran::lower::pft::FunctionLikeUnit &f : funit.nestedFunctions)
- declareFunction(f);
+ // Generate an end-of-block branch for several special cases. For
+ // constructs, this can be done for either the end construct statement,
+ // or for the construct itself, which will skip this code if the
+ // end statement was visited first and generated a branch.
+ Fortran::lower::pft::Evaluation *successor =
+ eval.isConstruct() ? eval.getLastNestedEvaluation().lexicalSuccessor
+ : eval.lexicalSuccessor;
+ if (successor && blockIsUnterminated()) {
+ if (successor->isIntermediateConstructStmt() &&
+ successor->parentConstruct->lowerAsUnstructured())
+ // Exit from an intermediate unstructured IF or SELECT construct block.
+ genBranch(successor->parentConstruct->constructExit->block);
+ else if (unstructuredContext && eval.isConstructStmt() &&
+ successor == eval.controlSuccessor)
+ // Exit from a degenerate, empty construct block.
+ genBranch(eval.parentConstruct->constructExit->block);
+ }
}
-/// Get the scope that is defining or using \p sym. The returned scope is not
-/// the ultimate scope, since this helper does not traverse use association.
-/// This allows capturing module variables that are referenced in an internal
-/// procedure but whose use statement is inside the host program.
-const Fortran::semantics::Scope &
-FirConverter::getSymbolHostScope(const Fortran::semantics::Symbol &sym) {
- const Fortran::semantics::Symbol *hostSymbol = &sym;
- while (const auto *details =
- hostSymbol->detailsIf<Fortran::semantics::HostAssocDetails>())
- hostSymbol = &details->symbol();
- return hostSymbol->owner();
+void FirConverter::genFIR(const Fortran::parser::AllocateStmt &stmt) {
+ Fortran::lower::genAllocateStmt(*this, stmt, toLocation());
}
-/// Collects the canonical list of all host associated symbols. These bindings
-/// must be aggregated into a tuple which can then be added to each of the
-/// internal procedure declarations and passed at each call site.
-void FirConverter::collectHostAssociatedVariables(
- Fortran::lower::pft::FunctionLikeUnit &funit,
- llvm::SetVector<const Fortran::semantics::Symbol *> &escapees) {
- const Fortran::semantics::Scope *internalScope =
- funit.getSubprogramSymbol().scope();
- assert(internalScope && "internal procedures symbol must create a scope");
- auto addToListIfEscapee = [&](const Fortran::semantics::Symbol &sym) {
- const Fortran::semantics::Symbol &ultimate = sym.GetUltimate();
- const auto *namelistDetails =
- ultimate.detailsIf<Fortran::semantics::NamelistDetails>();
- if (ultimate.has<Fortran::semantics::ObjectEntityDetails>() ||
- Fortran::semantics::IsProcedurePointer(ultimate) ||
- Fortran::semantics::IsDummy(sym) || namelistDetails) {
- const Fortran::semantics::Scope &symbolScope = getSymbolHostScope(sym);
- if (symbolScope.kind() == Fortran::semantics::Scope::Kind::MainProgram ||
- symbolScope.kind() == Fortran::semantics::Scope::Kind::Subprogram)
- if (symbolScope != *internalScope &&
- symbolScope.Contains(*internalScope)) {
- if (namelistDetails) {
- // So far, namelist symbols are processed on the fly in IO and
- // the related namelist data structure is not added to the symbol
- // map, so it cannot be passed to the internal procedures.
- // Instead, all the symbols of the host namelist used in the
- // internal procedure must be considered as host associated so
- // that IO lowering can find them when needed.
- for (const auto &namelistObject : namelistDetails->objects())
- escapees.insert(&*namelistObject);
- } else {
- escapees.insert(&ultimate);
- }
- }
- }
- };
- Fortran::lower::pft::visitAllSymbols(funit, addToListIfEscapee);
+void FirConverter::genFIR(const Fortran::parser::ArithmeticIfStmt &stmt) {
+ Fortran::lower::StatementContext stmtCtx;
+ mlir::Value expr = createFIRExpr(
+ toLocation(),
+ Fortran::semantics::GetExpr(std::get<Fortran::parser::Expr>(stmt.t)),
+ stmtCtx);
+ stmtCtx.finalizeAndReset();
+ // Raise an exception if REAL expr is a NaN.
+ if (expr.getType().isa<mlir::FloatType>())
+ expr = builder->create<mlir::arith::AddFOp>(toLocation(), expr, expr);
+ // An empty valueList indicates to genMultiwayBranch that the branch is
+ // an ArithmeticIfStmt that has two branches on value 0 or 0.0.
+ llvm::SmallVector<int64_t> valueList;
+ llvm::SmallVector<Fortran::parser::Label> labelList;
+ labelList.push_back(std::get<1>(stmt.t));
+ labelList.push_back(std::get<3>(stmt.t));
+ const Fortran::lower::pft::LabelEvalMap &labelEvaluationMap =
+ getEval().getOwningProcedure()->labelEvaluationMap;
+ const auto iter = labelEvaluationMap.find(std::get<2>(stmt.t));
+ assert(iter != labelEvaluationMap.end() && "label missing from map");
+ genMultiwayBranch(expr, valueList, labelList, *iter->second);
}
-//===--------------------------------------------------------------------===//
-// AbstractConverter overrides
-//===--------------------------------------------------------------------===//
+void FirConverter::genFIR(const Fortran::parser::AssignedGotoStmt &stmt) {
+ // See Fortran 90 Clause 8.2.4.
+ // Relax the requirement that the GOTO variable must have a value in the
+ // label list when a list is present, and allow a branch to any non-format
+ // target that has an ASSIGN statement for the variable.
+ mlir::Location loc = toLocation();
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ Fortran::lower::pft::FunctionLikeUnit &owningProc =
+ *eval.getOwningProcedure();
+ const Fortran::lower::pft::SymbolLabelMap &symbolLabelMap =
+ owningProc.assignSymbolLabelMap;
+ const Fortran::lower::pft::LabelEvalMap &labelEvalMap =
+ owningProc.labelEvaluationMap;
+ const Fortran::semantics::Symbol &symbol =
+ *std::get<Fortran::parser::Name>(stmt.t).symbol;
+ auto labelSetIter = symbolLabelMap.find(symbol);
+ llvm::SmallVector<int64_t> valueList;
+ llvm::SmallVector<Fortran::parser::Label> labelList;
+ if (labelSetIter != symbolLabelMap.end()) {
+ for (auto &label : labelSetIter->second) {
+ const auto evalIter = labelEvalMap.find(label);
+ assert(evalIter != labelEvalMap.end() && "assigned goto label missing");
+ if (evalIter->second->block) { // non-format statement
+ valueList.push_back(label); // label as an integer
+ labelList.push_back(label);
+ }
+ }
+ }
+ if (!labelList.empty()) {
+ auto selectExpr =
+ builder->create<fir::LoadOp>(loc, getSymbolAddress(symbol));
+ // Add a default error target in case the goto is nonconforming.
+ mlir::Block *errorBlock =
+ builder->getBlock()->splitBlock(builder->getInsertionPoint());
+ genMultiwayBranch(selectExpr, valueList, labelList, eval.nonNopSuccessor(),
+ errorBlock);
+ startBlock(errorBlock);
+ }
+ fir::runtime::genReportFatalUserError(
+ *builder, loc,
+ "Assigned GOTO variable '" + symbol.name().ToString() +
+ "' does not have a valid target label value");
+ builder->create<fir::UnreachableOp>(loc);
+}
-fir::ExtendedValue
-FirConverter::symBoxToExtendedValue(const Fortran::lower::SymbolBox &symBox) {
- return symBox.match(
- [](const Fortran::lower::SymbolBox::Intrinsic &box)
- -> fir::ExtendedValue { return box.getAddr(); },
- [](const Fortran::lower::SymbolBox::None &) -> fir::ExtendedValue {
- llvm::report_fatal_error("symbol not mapped");
- },
- [&](const fir::FortranVariableOpInterface &x) -> fir::ExtendedValue {
- return hlfir::translateToExtendedValue(getCurrentLocation(),
- getFirOpBuilder(), x);
- },
- [](const auto &box) -> fir::ExtendedValue { return box; });
+void FirConverter::genFIR(const Fortran::parser::AssignmentStmt &stmt) {
+ genAssignment(*stmt.typedAssignment->v);
}
-fir::ExtendedValue
-FirConverter::getSymbolExtendedValue(const Fortran::semantics::Symbol &sym,
- Fortran::lower::SymMap *symMap) {
- Fortran::lower::SymbolBox sb = lookupSymbol(sym, symMap);
- if (!sb) {
- LLVM_DEBUG(llvm::dbgs() << "unknown symbol: " << sym << "\nmap: "
- << (symMap ? *symMap : localSymbols) << '\n');
- fir::emitFatalError(getCurrentLocation(),
- "symbol is not mapped to any IR value");
- }
- return symBoxToExtendedValue(sb);
+void FirConverter::genFIR(const Fortran::parser::AssignStmt &stmt) {
+ const Fortran::semantics::Symbol &symbol =
+ *std::get<Fortran::parser::Name>(stmt.t).symbol;
+ mlir::Location loc = toLocation();
+ mlir::Value labelValue = builder->createIntegerConstant(
+ loc, genType(symbol), std::get<Fortran::parser::Label>(stmt.t));
+ builder->create<fir::StoreOp>(loc, labelValue, getSymbolAddress(symbol));
}
-mlir::Value FirConverter::impliedDoBinding(llvm::StringRef name) {
- mlir::Value val = localSymbols.lookupImpliedDo(name);
- if (!val)
- fir::emitFatalError(toLocation(), "ac-do-variable has no binding");
- return val;
+void FirConverter::genFIR(const Fortran::parser::AssociateConstruct &) {
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ Fortran::lower::StatementContext stmtCtx;
+ pushActiveConstruct(eval, stmtCtx);
+ for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
+ if (auto *stmt = e.getIf<Fortran::parser::AssociateStmt>()) {
+ if (eval.lowerAsUnstructured())
+ maybeStartBlock(e.block);
+ localSymbols.pushScope();
+ for (const Fortran::parser::Association &assoc :
+ std::get<std::list<Fortran::parser::Association>>(stmt->t)) {
+ Fortran::semantics::Symbol &sym =
+ *std::get<Fortran::parser::Name>(assoc.t).symbol;
+ const Fortran::lower::SomeExpr &selector =
+ *sym.get<Fortran::semantics::AssocEntityDetails>().expr();
+ addSymbol(sym, genAssociateSelector(selector, stmtCtx));
+ }
+ } else if (e.getIf<Fortran::parser::EndAssociateStmt>()) {
+ if (eval.lowerAsUnstructured())
+ maybeStartBlock(e.block);
+ localSymbols.popScope();
+ } else {
+ genFIR(e);
+ }
+ }
+ popActiveConstruct();
}
-/// Add the symbol binding to the inner-most level of the symbol map and
-/// return true if it is not already present. Otherwise, return false.
-bool FirConverter::bindIfNewSymbol(Fortran::lower::SymbolRef sym,
- const fir::ExtendedValue &exval) {
- if (shallowLookupSymbol(sym))
- return false;
- bindSymbol(sym, exval);
- return true;
+void FirConverter::genFIR(const Fortran::parser::BackspaceStmt &stmt) {
+ mlir::Value iostat = genBackspaceStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.v, iostat);
}
-bool FirConverter::lookupLabelSet(Fortran::lower::SymbolRef sym,
- Fortran::lower::pft::LabelSet &labelSet) {
- Fortran::lower::pft::FunctionLikeUnit &owningProc =
- *getEval().getOwningProcedure();
- auto iter = owningProc.assignSymbolLabelMap.find(sym);
- if (iter == owningProc.assignSymbolLabelMap.end())
- return false;
- labelSet = iter->second;
- return true;
+void FirConverter::genFIR(
+ const Fortran::parser::BlockConstruct &blockConstruct) {
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ Fortran::lower::StatementContext stmtCtx;
+ pushActiveConstruct(eval, stmtCtx);
+ for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
+ if (e.getIf<Fortran::parser::BlockStmt>()) {
+ if (eval.lowerAsUnstructured())
+ maybeStartBlock(e.block);
+ setCurrentPosition(e.position);
+ const Fortran::parser::CharBlock &endPosition =
+ eval.getLastNestedEvaluation().position;
+ localSymbols.pushScope();
+ mlir::func::FuncOp stackSave = fir::factory::getLlvmStackSave(*builder);
+ mlir::func::FuncOp stackRestore =
+ fir::factory::getLlvmStackRestore(*builder);
+ mlir::Value stackPtr =
+ builder->create<fir::CallOp>(toLocation(), stackSave).getResult(0);
+ mlir::Location endLoc = genLocation(endPosition);
+ stmtCtx.attachCleanup([=]() {
+ builder->create<fir::CallOp>(endLoc, stackRestore, stackPtr);
+ });
+ Fortran::semantics::Scope &scope =
+ bridge.getSemanticsContext().FindScope(endPosition);
+ scopeBlockIdMap.try_emplace(&scope, ++blockId);
+ Fortran::lower::AggregateStoreMap storeMap;
+ for (const Fortran::lower::pft::Variable &var :
+ Fortran::lower::pft::getScopeVariableList(scope)) {
+ // Do no instantiate again variables from the block host
+ // that appears in specification of block variables.
+ if (!var.hasSymbol() || !lookupSymbol(var.getSymbol()))
+ instantiateVar(var, storeMap);
+ }
+ } else if (e.getIf<Fortran::parser::EndBlockStmt>()) {
+ if (eval.lowerAsUnstructured())
+ maybeStartBlock(e.block);
+ setCurrentPosition(e.position);
+ localSymbols.popScope();
+ } else {
+ genFIR(e);
+ }
+ }
+ popActiveConstruct();
}
-fir::ExtendedValue
-FirConverter::genExprAddr(const Fortran::lower::SomeExpr &expr,
- Fortran::lower::StatementContext &context,
- mlir::Location *locPtr) {
- mlir::Location loc = locPtr ? *locPtr : toLocation();
- if (lowerToHighLevelFIR())
- return Fortran::lower::convertExprToAddress(loc, *this, expr, localSymbols,
- context);
- return Fortran::lower::createSomeExtendedAddress(loc, *this, expr,
- localSymbols, context);
+/// Lowering of CALL statement
+void FirConverter::genFIR(const Fortran::parser::CallStmt &stmt) {
+ Fortran::lower::StatementContext stmtCtx;
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ setCurrentPosition(stmt.source);
+ assert(stmt.typedCall && "Call was not analyzed");
+ mlir::Value res{};
+ if (lowerToHighLevelFIR()) {
+ std::optional<mlir::Type> resultType;
+ if (stmt.typedCall->hasAlternateReturns())
+ resultType = builder->getIndexType();
+ auto hlfirRes =
+ Fortran::lower::convertCallToHLFIR(toLocation(), *this, *stmt.typedCall,
+ resultType, localSymbols, stmtCtx);
+ if (hlfirRes)
+ res = *hlfirRes;
+ } else {
+ // Call statement lowering shares code with function call lowering.
+ res = Fortran::lower::createSubroutineCall(
+ *this, *stmt.typedCall, explicitIterSpace, implicitIterSpace,
+ localSymbols, stmtCtx, /*isUserDefAssignment=*/false);
+ }
+ stmtCtx.finalizeAndReset();
+ if (!res)
+ return; // "Normal" subroutine call.
+ // Call with alternate return specifiers.
+ // The call returns an index that selects an alternate return branch target.
+ llvm::SmallVector<int64_t> indexList;
+ llvm::SmallVector<Fortran::parser::Label> labelList;
+ int64_t index = 0;
+ for (const Fortran::parser::ActualArgSpec &arg :
+ std::get<std::list<Fortran::parser::ActualArgSpec>>(stmt.call.t)) {
+ const auto &actual = std::get<Fortran::parser::ActualArg>(arg.t);
+ if (const auto *altReturn =
+ std::get_if<Fortran::parser::AltReturnSpec>(&actual.u)) {
+ indexList.push_back(++index);
+ labelList.push_back(altReturn->v);
+ }
+ }
+ genMultiwayBranch(res, indexList, labelList, eval.nonNopSuccessor());
}
-fir::ExtendedValue
-FirConverter::genExprValue(const Fortran::lower::SomeExpr &expr,
- Fortran::lower::StatementContext &context,
- mlir::Location *locPtr) {
- mlir::Location loc = locPtr ? *locPtr : toLocation();
- if (lowerToHighLevelFIR())
- return Fortran::lower::convertExprToValue(loc, *this, expr, localSymbols,
- context);
- return Fortran::lower::createSomeExtendedExpression(loc, *this, expr,
- localSymbols, context);
+void FirConverter::genFIR(const Fortran::parser::CaseConstruct &) {
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ Fortran::lower::StatementContext stmtCtx;
+ pushActiveConstruct(eval, stmtCtx);
+ for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
+ if (e.getIf<Fortran::parser::EndSelectStmt>())
+ maybeStartBlock(e.block);
+ else
+ genFIR(e);
+ }
+ popActiveConstruct();
}
-fir::ExtendedValue
-FirConverter::genExprBox(mlir::Location loc,
- const Fortran::lower::SomeExpr &expr,
- Fortran::lower::StatementContext &stmtCtx) {
- if (lowerToHighLevelFIR())
- return Fortran::lower::convertExprToBox(loc, *this, expr, localSymbols,
- stmtCtx);
- return Fortran::lower::createBoxValue(loc, *this, expr, localSymbols,
- stmtCtx);
+void FirConverter::genFIR(
+ const Fortran::parser::ChangeTeamConstruct &construct) {
+ TODO(toLocation(), "coarray: ChangeTeamConstruct");
}
-bool FirConverter::createHostAssociateVarClone(
- const Fortran::semantics::Symbol &sym) {
- mlir::Location loc = genLocation(sym.name());
- mlir::Type symType = genType(sym);
- const auto *details = sym.detailsIf<Fortran::semantics::HostAssocDetails>();
- assert(details && "No host-association found");
- const Fortran::semantics::Symbol &hsym = details->symbol();
- mlir::Type hSymType = genType(hsym);
- Fortran::lower::SymbolBox hsb = lookupSymbol(hsym);
-
- auto allocate = [&](llvm::ArrayRef<mlir::Value> shape,
- llvm::ArrayRef<mlir::Value> typeParams) -> mlir::Value {
- mlir::Value allocVal = builder->allocateLocal(
- loc,
- Fortran::semantics::IsAllocatableOrObjectPointer(&hsym.GetUltimate())
- ? hSymType
- : symType,
- mangleName(sym), toStringRef(sym.GetUltimate().name()),
- /*pinned=*/true, shape, typeParams,
- sym.GetUltimate().attrs().test(Fortran::semantics::Attr::TARGET));
- return allocVal;
- };
-
- fir::ExtendedValue hexv = symBoxToExtendedValue(hsb);
- fir::ExtendedValue exv = hexv.match(
- [&](const fir::BoxValue &box) -> fir::ExtendedValue {
- const Fortran::semantics::DeclTypeSpec *type = sym.GetType();
- if (type && type->IsPolymorphic())
- TODO(loc, "create polymorphic host associated copy");
- // Create a contiguous temp with the same shape and length as
- // the original variable described by a fir.box.
- llvm::SmallVector<mlir::Value> extents =
- fir::factory::getExtents(loc, *builder, hexv);
- if (box.isDerivedWithLenParameters())
- TODO(loc, "get length parameters from derived type BoxValue");
- if (box.isCharacter()) {
- mlir::Value len = fir::factory::readCharLen(*builder, loc, box);
- mlir::Value temp = allocate(extents, {len});
- return fir::CharArrayBoxValue{temp, len, extents};
- }
- return fir::ArrayBoxValue{allocate(extents, {}), extents};
- },
- [&](const fir::MutableBoxValue &box) -> fir::ExtendedValue {
- // Allocate storage for a pointer/allocatble descriptor.
- // No shape/lengths to be passed to the alloca.
- return fir::MutableBoxValue(allocate({}, {}), {}, {});
- },
- [&](const auto &) -> fir::ExtendedValue {
- mlir::Value temp =
- allocate(fir::factory::getExtents(loc, *builder, hexv),
- fir::factory::getTypeParams(loc, *builder, hexv));
- return fir::substBase(hexv, temp);
- });
-
- // Initialise cloned allocatable
- hexv.match(
- [&](const fir::MutableBoxValue &box) -> void {
- // Do not process pointers
- if (Fortran::semantics::IsPointer(sym.GetUltimate())) {
- return;
- }
- // Allocate storage for a pointer/allocatble descriptor.
- // No shape/lengths to be passed to the alloca.
- const auto new_box = exv.getBoxOf<fir::MutableBoxValue>();
+void FirConverter::genFIR(const Fortran::parser::ChangeTeamStmt &stmt) {
+ TODO(toLocation(), "coarray: ChangeTeamStmt");
+}
- // allocate if allocated
- mlir::Value isAllocated =
- fir::factory::genIsAllocatedOrAssociatedTest(*builder, loc, box);
- auto if_builder = builder->genIfThenElse(loc, isAllocated);
- if_builder.genThen([&]() {
- std::string name = mangleName(sym) + ".alloc";
- if (auto seqTy = symType.dyn_cast<fir::SequenceType>()) {
- fir::ExtendedValue read = fir::factory::genMutableBoxRead(
- *builder, loc, box, /*mayBePolymorphic=*/false);
- if (auto read_arr_box = read.getBoxOf<fir::ArrayBoxValue>()) {
- fir::factory::genInlinedAllocation(
- *builder, loc, *new_box, read_arr_box->getLBounds(),
- read_arr_box->getExtents(),
- /*lenParams=*/std::nullopt, name,
- /*mustBeHeap=*/true);
- } else if (auto read_char_arr_box =
- read.getBoxOf<fir::CharArrayBoxValue>()) {
- fir::factory::genInlinedAllocation(
- *builder, loc, *new_box, read_char_arr_box->getLBounds(),
- read_char_arr_box->getExtents(), read_char_arr_box->getLen(),
- name,
- /*mustBeHeap=*/true);
- } else {
- TODO(loc, "Unhandled allocatable box type");
- }
- } else {
- fir::factory::genInlinedAllocation(
- *builder, loc, *new_box, box.getMutableProperties().lbounds,
- box.getMutableProperties().extents, box.nonDeferredLenParams(),
- name,
- /*mustBeHeap=*/true);
- }
- });
- if_builder.genElse([&]() {
- // nullify box
- auto empty = fir::factory::createUnallocatedBox(
- *builder, loc, new_box->getBoxTy(),
- new_box->nonDeferredLenParams(), {});
- builder->create<fir::StoreOp>(loc, empty, new_box->getAddr());
- });
- if_builder.end();
- },
- [&](const auto &) -> void {
- // Do nothing
- });
+void FirConverter::genFIR(const Fortran::parser::CloseStmt &stmt) {
+ mlir::Value iostat = genCloseStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.v, iostat);
+}
- return bindIfNewSymbol(sym, exv);
+void FirConverter::genFIR(const Fortran::parser::CompilerDirective &) {
+ // TODO
}
-void FirConverter::createHostAssociateVarCloneDealloc(
- const Fortran::semantics::Symbol &sym) {
- mlir::Location loc = genLocation(sym.name());
- Fortran::lower::SymbolBox hsb = lookupSymbol(sym);
-
- fir::ExtendedValue hexv = symBoxToExtendedValue(hsb);
- hexv.match(
- [&](const fir::MutableBoxValue &new_box) -> void {
- // Do not process pointers
- if (Fortran::semantics::IsPointer(sym.GetUltimate())) {
- return;
- }
- // deallocate allocated in createHostAssociateVarClone value
- Fortran::lower::genDeallocateIfAllocated(*this, new_box, loc);
- },
- [&](const auto &) -> void {
- // Do nothing
- });
+void FirConverter::genFIR(const Fortran::parser::ComputedGotoStmt &stmt) {
+ Fortran::lower::StatementContext stmtCtx;
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ mlir::Value selectExpr =
+ createFIRExpr(toLocation(),
+ Fortran::semantics::GetExpr(
+ std::get<Fortran::parser::ScalarIntExpr>(stmt.t)),
+ stmtCtx);
+ stmtCtx.finalizeAndReset();
+ llvm::SmallVector<int64_t> indexList;
+ llvm::SmallVector<Fortran::parser::Label> labelList;
+ int64_t index = 0;
+ for (Fortran::parser::Label label :
+ std::get<std::list<Fortran::parser::Label>>(stmt.t)) {
+ indexList.push_back(++index);
+ labelList.push_back(label);
+ }
+ genMultiwayBranch(selectExpr, indexList, labelList, eval.nonNopSuccessor());
}
-void FirConverter::copyHostAssociateVar(
- const Fortran::semantics::Symbol &sym,
- mlir::OpBuilder::InsertPoint *copyAssignIP) {
- // 1) Fetch the original copy of the variable.
- assert(sym.has<Fortran::semantics::HostAssocDetails>() &&
- "No host-association found");
- const Fortran::semantics::Symbol &hsym = sym.GetUltimate();
- Fortran::lower::SymbolBox hsb = lookupOneLevelUpSymbol(hsym);
- assert(hsb && "Host symbol box not found");
-
- // 2) Fetch the copied one that will mask the original.
- Fortran::lower::SymbolBox sb = shallowLookupSymbol(sym);
- assert(sb && "Host-associated symbol box not found");
- assert(hsb.getAddr() != sb.getAddr() &&
- "Host and associated symbol boxes are the same");
-
- // 3) Perform the assignment.
- mlir::OpBuilder::InsertPoint insPt = builder->saveInsertionPoint();
- if (copyAssignIP && copyAssignIP->isSet())
- builder->restoreInsertionPoint(*copyAssignIP);
- else
- builder->setInsertionPointAfter(sb.getAddr().getDefiningOp());
-
- Fortran::lower::SymbolBox *lhs_sb, *rhs_sb;
- if (copyAssignIP && copyAssignIP->isSet() &&
- sym.test(Fortran::semantics::Symbol::Flag::OmpLastPrivate)) {
- // lastprivate case
- lhs_sb = &hsb;
- rhs_sb = &sb;
- } else {
- lhs_sb = &sb;
- rhs_sb = &hsb;
+/// Process a concurrent header for a FORALL. (Concurrent headers for DO
+/// CONCURRENT loops are lowered elsewhere.)
+void FirConverter::genFIR(const Fortran::parser::ConcurrentHeader &header) {
+ llvm::SmallVector<mlir::Value> lows;
+ llvm::SmallVector<mlir::Value> highs;
+ llvm::SmallVector<mlir::Value> steps;
+ if (explicitIterSpace.isOutermostForall()) {
+ // For the outermost forall, we evaluate the bounds expressions once.
+ // Contrastingly, if this forall is nested, the bounds expressions are
+ // assumed to be pure, possibly dependent on outer concurrent control
+ // variables, possibly variant with respect to arguments, and will be
+ // re-evaluated.
+ mlir::Location loc = toLocation();
+ mlir::Type idxTy = builder->getIndexType();
+ Fortran::lower::StatementContext &stmtCtx = explicitIterSpace.stmtContext();
+ auto lowerExpr = [&](auto &e) {
+ return fir::getBase(genExprValue(e, stmtCtx));
+ };
+ for (const Fortran::parser::ConcurrentControl &ctrl :
+ std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t)) {
+ const Fortran::lower::SomeExpr *lo =
+ Fortran::semantics::GetExpr(std::get<1>(ctrl.t));
+ const Fortran::lower::SomeExpr *hi =
+ Fortran::semantics::GetExpr(std::get<2>(ctrl.t));
+ auto &optStep =
+ std::get<std::optional<Fortran::parser::ScalarIntExpr>>(ctrl.t);
+ lows.push_back(builder->createConvert(loc, idxTy, lowerExpr(*lo)));
+ highs.push_back(builder->createConvert(loc, idxTy, lowerExpr(*hi)));
+ steps.push_back(
+ optStep.has_value()
+ ? builder->createConvert(
+ loc, idxTy,
+ lowerExpr(*Fortran::semantics::GetExpr(*optStep)))
+ : builder->createIntegerConstant(loc, idxTy, 1));
+ }
}
-
- mlir::Location loc = genLocation(sym.name());
-
- if (lowerToHighLevelFIR()) {
- hlfir::Entity lhs{lhs_sb->getAddr()};
- hlfir::Entity rhs{rhs_sb->getAddr()};
- // Temporary_lhs is set to true in hlfir.assign below to avoid
- // user assignment to be used and finalization to be called on
- // the LHS. This may or may not be correct but mimics the current behaviour
- // without HLFIR.
- auto copyData = [&](hlfir::Entity l, hlfir::Entity r) {
- // Dereference RHS and load it if trivial scalar.
- r = hlfir::loadTrivialScalar(loc, *builder, r);
- builder->create<hlfir::AssignOp>(
- loc, r, l,
- /*isWholeAllocatableAssignment=*/false,
- /*keepLhsLengthInAllocatableAssignment=*/false,
- /*temporary_lhs=*/true);
+ auto lambda = [&, lows, highs, steps]() {
+ // Create our iteration space from the header spec.
+ mlir::Location loc = toLocation();
+ mlir::Type idxTy = builder->getIndexType();
+ llvm::SmallVector<fir::DoLoopOp> loops;
+ Fortran::lower::StatementContext &stmtCtx = explicitIterSpace.stmtContext();
+ auto lowerExpr = [&](auto &e) {
+ return fir::getBase(genExprValue(e, stmtCtx));
};
- if (lhs.isAllocatable()) {
- // Deep copy allocatable if it is allocated.
- // Note that when allocated, the RHS is already allocated with the LHS
- // shape for copy on entry in createHostAssociateVarClone.
- // For lastprivate, this assumes that the RHS was not reallocated in
- // the OpenMP region.
- lhs = hlfir::derefPointersAndAllocatables(loc, *builder, lhs);
- mlir::Value addr = hlfir::genVariableRawAddress(loc, *builder, lhs);
- mlir::Value isAllocated = builder->genIsNotNullAddr(loc, addr);
- builder->genIfThen(loc, isAllocated)
- .genThen([&]() {
- // Copy the DATA, not the descriptors.
- copyData(lhs, rhs);
- })
- .end();
- } else if (lhs.isPointer()) {
- // Set LHS target to the target of RHS (do not copy the RHS
- // target data into the LHS target storage).
- auto loadVal = builder->create<fir::LoadOp>(loc, rhs);
- builder->create<fir::StoreOp>(loc, loadVal, lhs);
- } else {
- // Non ALLOCATABLE/POINTER variable. Simple DATA copy.
- copyData(lhs, rhs);
+ const bool outermost = !lows.empty();
+ std::size_t headerIndex = 0;
+ for (const Fortran::parser::ConcurrentControl &ctrl :
+ std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t)) {
+ const Fortran::semantics::Symbol *ctrlVar =
+ std::get<Fortran::parser::Name>(ctrl.t).symbol;
+ mlir::Value lb;
+ mlir::Value ub;
+ mlir::Value by;
+ if (outermost) {
+ assert(headerIndex < lows.size());
+ if (headerIndex == 0)
+ explicitIterSpace.resetInnerArgs();
+ lb = lows[headerIndex];
+ ub = highs[headerIndex];
+ by = steps[headerIndex++];
+ } else {
+ const Fortran::lower::SomeExpr *lo =
+ Fortran::semantics::GetExpr(std::get<1>(ctrl.t));
+ const Fortran::lower::SomeExpr *hi =
+ Fortran::semantics::GetExpr(std::get<2>(ctrl.t));
+ auto &optStep =
+ std::get<std::optional<Fortran::parser::ScalarIntExpr>>(ctrl.t);
+ lb = builder->createConvert(loc, idxTy, lowerExpr(*lo));
+ ub = builder->createConvert(loc, idxTy, lowerExpr(*hi));
+ by = optStep.has_value()
+ ? builder->createConvert(
+ loc, idxTy,
+ lowerExpr(*Fortran::semantics::GetExpr(*optStep)))
+ : builder->createIntegerConstant(loc, idxTy, 1);
+ }
+ auto lp = builder->create<fir::DoLoopOp>(
+ loc, lb, ub, by, /*unordered=*/true,
+ /*finalCount=*/false, explicitIterSpace.getInnerArgs());
+ if ((!loops.empty() || !outermost) && !lp.getRegionIterArgs().empty())
+ builder->create<fir::ResultOp>(loc, lp.getResults());
+ explicitIterSpace.setInnerArgs(lp.getRegionIterArgs());
+ builder->setInsertionPointToStart(lp.getBody());
+ forceControlVariableBinding(ctrlVar, lp.getInductionVar());
+ loops.push_back(lp);
}
- } else {
- fir::ExtendedValue lhs = symBoxToExtendedValue(*lhs_sb);
- fir::ExtendedValue rhs = symBoxToExtendedValue(*rhs_sb);
- mlir::Type symType = genType(sym);
- if (auto seqTy = symType.dyn_cast<fir::SequenceType>()) {
- Fortran::lower::StatementContext stmtCtx;
- Fortran::lower::createSomeArrayAssignment(*this, lhs, rhs, localSymbols,
- stmtCtx);
- stmtCtx.finalizeAndReset();
- } else if (lhs.getBoxOf<fir::CharBoxValue>()) {
- fir::factory::CharacterExprHelper{*builder, loc}.createAssign(lhs, rhs);
- } else {
- auto loadVal = builder->create<fir::LoadOp>(loc, fir::getBase(rhs));
- builder->create<fir::StoreOp>(loc, loadVal, fir::getBase(lhs));
+ if (outermost)
+ explicitIterSpace.setOuterLoop(loops[0]);
+ explicitIterSpace.appendLoops(loops);
+ if (const auto &mask =
+ std::get<std::optional<Fortran::parser::ScalarLogicalExpr>>(
+ header.t);
+ mask.has_value()) {
+ mlir::Type i1Ty = builder->getI1Type();
+ fir::ExtendedValue maskExv =
+ genExprValue(*Fortran::semantics::GetExpr(mask.value()), stmtCtx);
+ mlir::Value cond =
+ builder->createConvert(loc, i1Ty, fir::getBase(maskExv));
+ auto ifOp = builder->create<fir::IfOp>(
+ loc, explicitIterSpace.innerArgTypes(), cond,
+ /*withElseRegion=*/true);
+ builder->create<fir::ResultOp>(loc, ifOp.getResults());
+ builder->setInsertionPointToStart(&ifOp.getElseRegion().front());
+ builder->create<fir::ResultOp>(loc, explicitIterSpace.getInnerArgs());
+ builder->setInsertionPointToStart(&ifOp.getThenRegion().front());
}
- }
+ };
+ // Push the lambda to gen the loop nest context.
+ explicitIterSpace.pushLoopNest(lambda);
+}
- if (copyAssignIP && copyAssignIP->isSet() &&
- sym.test(Fortran::semantics::Symbol::Flag::OmpLastPrivate)) {
- builder->restoreInsertionPoint(insPt);
- }
+void FirConverter::genFIR(
+ const Fortran::parser::CriticalConstruct &criticalConstruct) {
+ setCurrentPositionAt(criticalConstruct);
+ TODO(toLocation(), "coarray: CriticalConstruct");
}
-//===--------------------------------------------------------------------===//
-// Utility methods
-//===--------------------------------------------------------------------===//
+void FirConverter::genFIR(const Fortran::parser::CriticalStmt &) {
+ TODO(toLocation(), "coarray: CriticalStmt");
+}
-void FirConverter::collectSymbolSet(
- Fortran::lower::pft::Evaluation &eval,
- llvm::SetVector<const Fortran::semantics::Symbol *> &symbolSet,
- Fortran::semantics::Symbol::Flag flag, bool collectSymbols,
- bool checkHostAssociatedSymbols) {
- auto addToList = [&](const Fortran::semantics::Symbol &sym) {
- std::function<void(const Fortran::semantics::Symbol &, bool)>
- insertSymbols = [&](const Fortran::semantics::Symbol &oriSymbol,
- bool collectSymbol) {
- if (collectSymbol && oriSymbol.test(flag))
- symbolSet.insert(&oriSymbol);
- if (checkHostAssociatedSymbols)
- if (const auto *details{
- oriSymbol
- .detailsIf<Fortran::semantics::HostAssocDetails>()})
- insertSymbols(details->symbol(), true);
- };
- insertSymbols(sym, collectSymbols);
- };
- Fortran::lower::pft::visitAllSymbols(eval, addToList);
+void FirConverter::genFIR(const Fortran::parser::CycleStmt &) {
+ genConstructExitBranch(*getEval().controlSuccessor);
}
-/// Generate a `Location` from the `CharBlock`.
-mlir::Location
-FirConverter::genLocation(const Fortran::parser::CharBlock &block) {
- if (const Fortran::parser::AllCookedSources *cooked =
- bridge.getCookedSource()) {
- if (std::optional<Fortran::parser::ProvenanceRange> provenance =
- cooked->GetProvenanceRange(block)) {
- if (std::optional<Fortran::parser::SourcePosition> filePos =
- cooked->allSources().GetSourcePosition(provenance->start())) {
- llvm::SmallString<256> filePath(*filePos->path);
- llvm::sys::fs::make_absolute(filePath);
- llvm::sys::path::remove_dots(filePath);
- return mlir::FileLineColLoc::get(&getMLIRContext(), filePath.str(),
- filePos->line, filePos->column);
+void FirConverter::genFIR(const Fortran::parser::DeallocateStmt &stmt) {
+ Fortran::lower::genDeallocateStmt(*this, stmt, toLocation());
+}
+
+/// Generate FIR for a DO construct. There are six variants:
+/// - unstructured infinite and while loops
+/// - structured and unstructured increment loops
+/// - structured and unstructured concurrent loops
+void FirConverter::genFIR(const Fortran::parser::DoConstruct &doConstruct) {
+ setCurrentPositionAt(doConstruct);
+ // Collect loop nest information.
+ // Generate begin loop code directly for infinite and while loops.
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ bool unstructuredContext = eval.lowerAsUnstructured();
+ Fortran::lower::pft::Evaluation &doStmtEval = eval.getFirstNestedEvaluation();
+ auto *doStmt = doStmtEval.getIf<Fortran::parser::NonLabelDoStmt>();
+ const auto &loopControl =
+ std::get<std::optional<Fortran::parser::LoopControl>>(doStmt->t);
+ mlir::Block *preheaderBlock = doStmtEval.block;
+ mlir::Block *beginBlock =
+ preheaderBlock ? preheaderBlock : builder->getBlock();
+ auto createNextBeginBlock = [&]() {
+ // Step beginBlock through unstructured preheader, header, and mask
+ // blocks, created in outermost to innermost order.
+ return beginBlock = beginBlock->splitBlock(beginBlock->end());
+ };
+ mlir::Block *headerBlock =
+ unstructuredContext ? createNextBeginBlock() : nullptr;
+ mlir::Block *bodyBlock = doStmtEval.lexicalSuccessor->block;
+ mlir::Block *exitBlock = doStmtEval.parentConstruct->constructExit->block;
+ IncrementLoopNestInfo incrementLoopNestInfo;
+ const Fortran::parser::ScalarLogicalExpr *whileCondition = nullptr;
+ bool infiniteLoop = !loopControl.has_value();
+ if (infiniteLoop) {
+ assert(unstructuredContext && "infinite loop must be unstructured");
+ startBlock(headerBlock);
+ } else if ((whileCondition = std::get_if<Fortran::parser::ScalarLogicalExpr>(
+ &loopControl->u))) {
+ assert(unstructuredContext && "while loop must be unstructured");
+ maybeStartBlock(preheaderBlock); // no block or empty block
+ startBlock(headerBlock);
+ genConditionalBranch(*whileCondition, bodyBlock, exitBlock);
+ } else if (const auto *bounds =
+ std::get_if<Fortran::parser::LoopControl::Bounds>(
+ &loopControl->u)) {
+ // Non-concurrent increment loop.
+ IncrementLoopInfo &info = incrementLoopNestInfo.emplace_back(
+ *bounds->name.thing.symbol, bounds->lower, bounds->upper, bounds->step);
+ if (unstructuredContext) {
+ maybeStartBlock(preheaderBlock);
+ info.hasRealControl = info.loopVariableSym->GetType()->IsNumeric(
+ Fortran::common::TypeCategory::Real);
+ info.headerBlock = headerBlock;
+ info.bodyBlock = bodyBlock;
+ info.exitBlock = exitBlock;
+ }
+ } else {
+ const auto *concurrent =
+ std::get_if<Fortran::parser::LoopControl::Concurrent>(&loopControl->u);
+ assert(concurrent && "invalid DO loop variant");
+ incrementLoopNestInfo = getConcurrentControl(
+ std::get<Fortran::parser::ConcurrentHeader>(concurrent->t),
+ std::get<std::list<Fortran::parser::LocalitySpec>>(concurrent->t));
+ if (unstructuredContext) {
+ maybeStartBlock(preheaderBlock);
+ for (IncrementLoopInfo &info : incrementLoopNestInfo) {
+ // The original loop body provides the body and latch blocks of the
+ // innermost dimension. The (first) body block of a non-innermost
+ // dimension is the preheader block of the immediately enclosed
+ // dimension. The latch block of a non-innermost dimension is the
+ // exit block of the immediately enclosed dimension.
+ auto createNextExitBlock = [&]() {
+ // Create unstructured loop exit blocks, outermost to innermost.
+ return exitBlock = insertBlock(exitBlock);
+ };
+ bool isInnermost = &info == &incrementLoopNestInfo.back();
+ bool isOutermost = &info == &incrementLoopNestInfo.front();
+ info.headerBlock = isOutermost ? headerBlock : createNextBeginBlock();
+ info.bodyBlock = isInnermost ? bodyBlock : createNextBeginBlock();
+ info.exitBlock = isOutermost ? exitBlock : createNextExitBlock();
+ if (info.maskExpr)
+ info.maskBlock = createNextBeginBlock();
}
}
}
- return genUnknownLocation();
-}
-/// Return the current function context, which may be a nested BLOCK context
-/// or a full subprogram context.
-Fortran::lower::StatementContext &FirConverter::getFctCtx() {
- if (!activeConstructStack.empty() &&
- activeConstructStack.back().eval.isA<Fortran::parser::BlockConstruct>())
- return activeConstructStack.back().stmtCtx;
- return bridge.fctCtx();
-}
+ // Increment loop begin code. (Infinite/while code was already generated.)
+ if (!infiniteLoop && !whileCondition)
+ genFIRIncrementLoopBegin(incrementLoopNestInfo);
-llvm::StringRef
-FirConverter::getUniqueLitName(mlir::Location loc,
- std::unique_ptr<Fortran::lower::SomeExpr> expr,
- mlir::Type eleTy) {
- std::string namePrefix = getConstantExprManglePrefix(loc, *expr.get(), eleTy);
- auto [it, inserted] = literalNamesMap.try_emplace(
- expr.get(), namePrefix + std::to_string(uniqueLitId));
- const auto &name = it->second;
- if (inserted) {
- // Keep ownership of the expr key.
- literalExprsStorage.push_back(std::move(expr));
+ // Loop body code.
+ auto iter = eval.getNestedEvaluations().begin();
+ for (auto end = --eval.getNestedEvaluations().end(); iter != end; ++iter)
+ genFIR(*iter, unstructuredContext);
- // If we've just added a new name, we have to make sure
- // there is no global object with the same name in the module.
- fir::GlobalOp global = builder->getNamedGlobal(name);
- if (global)
- fir::emitFatalError(loc, llvm::Twine("global object with name '") +
- llvm::Twine(name) +
- llvm::Twine("' already exists"));
- ++uniqueLitId;
- return name;
- }
+ // An EndDoStmt in unstructured code may start a new block.
+ Fortran::lower::pft::Evaluation &endDoEval = *iter;
+ assert(endDoEval.getIf<Fortran::parser::EndDoStmt>() && "no enddo stmt");
+ if (unstructuredContext)
+ maybeStartBlock(endDoEval.block);
- // The name already exists. Verify that the prefix is the same.
- if (!llvm::StringRef(name).starts_with(namePrefix))
- fir::emitFatalError(loc, llvm::Twine("conflicting prefixes: '") +
- llvm::Twine(name) +
- llvm::Twine("' does not start with '") +
- llvm::Twine(namePrefix) + llvm::Twine("'"));
+ // Loop end code.
+ if (infiniteLoop || whileCondition)
+ genBranch(headerBlock);
+ else
+ genFIRIncrementLoopEnd(incrementLoopNestInfo);
- return name;
+ // This call may generate a branch in some contexts.
+ genFIR(endDoEval, unstructuredContext);
}
-void FirConverter::TypeInfoConverter::registerTypeInfo(
- Fortran::lower::AbstractConverter &converter, mlir::Location loc,
- Fortran::semantics::SymbolRef typeInfoSym,
- const Fortran::semantics::DerivedTypeSpec &typeSpec, fir::RecordType type) {
- if (seen.contains(typeInfoSym))
- return;
- seen.insert(typeInfoSym);
- if (!skipRegistration) {
- registeredTypeInfo.emplace_back(TypeInfo{typeInfoSym, typeSpec, type, loc});
- return;
- }
- // Once the registration is closed, symbols cannot be added to the
- // registeredTypeInfoSymbols list because it may be iterated over.
- // However, after registration is closed, it is safe to directly generate
- // the globals because all FuncOps whose addresses may be required by the
- // initializers have been generated.
- createTypeInfoOpAndGlobal(converter,
- TypeInfo{typeInfoSym, typeSpec, type, loc});
+void FirConverter::genFIR(const Fortran::parser::ElsewhereStmt &stmt) {
+ if (!lowerToHighLevelFIR())
+ implicitIterSpace.append(nullptr);
}
-void FirConverter::TypeInfoConverter::createTypeInfo(
- Fortran::lower::AbstractConverter &converter) {
- skipRegistration = true;
- for (const TypeInfo &info : registeredTypeInfo)
- createTypeInfoOpAndGlobal(converter, info);
- registeredTypeInfo.clear();
+void FirConverter::genFIR(const Fortran::parser::EndChangeTeamStmt &stmt) {
+ TODO(toLocation(), "coarray: EndChangeTeamStmt");
}
-void FirConverter::TypeInfoConverter::createTypeInfoOpAndGlobal(
- Fortran::lower::AbstractConverter &converter, const TypeInfo &info) {
- Fortran::lower::createRuntimeTypeInfoGlobal(converter, info.symbol.get());
- createTypeInfoOp(converter, info);
+void FirConverter::genFIR(const Fortran::parser::EndCriticalStmt &) {
+ TODO(toLocation(), "coarray: EndCriticalStmt");
}
-void FirConverter::TypeInfoConverter::createTypeInfoOp(
- Fortran::lower::AbstractConverter &converter, const TypeInfo &info) {
- fir::RecordType parentType{};
- if (const Fortran::semantics::DerivedTypeSpec *parent =
- Fortran::evaluate::GetParentTypeSpec(info.typeSpec))
- parentType = mlir::cast<fir::RecordType>(converter.genType(*parent));
+void FirConverter::genFIR(const Fortran::parser::EndfileStmt &stmt) {
+ mlir::Value iostat = genEndfileStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.v, iostat);
+}
- fir::FirOpBuilder &builder = converter.getFirOpBuilder();
- mlir::ModuleOp module = builder.getModule();
- fir::TypeInfoOp dt =
- module.lookupSymbol<fir::TypeInfoOp>(info.type.getName());
- if (dt)
- return; // Already created.
- auto insertPt = builder.saveInsertionPoint();
- builder.setInsertionPoint(module.getBody(), module.getBody()->end());
- dt = builder.create<fir::TypeInfoOp>(info.loc, info.type, parentType);
+void FirConverter::genFIR(const Fortran::parser::EndForallStmt &) {
+ if (!lowerToHighLevelFIR())
+ cleanupExplicitSpace();
+}
- if (!info.typeSpec.HasDefaultInitialization(/*ignoreAllocatable=*/false,
- /*ignorePointer=*/false))
- dt->setAttr(dt.getNoInitAttrName(), builder.getUnitAttr());
- if (!info.typeSpec.HasDestruction())
- dt->setAttr(dt.getNoDestroyAttrName(), builder.getUnitAttr());
- if (!Fortran::semantics::MayRequireFinalization(info.typeSpec))
- dt->setAttr(dt.getNoFinalAttrName(), builder.getUnitAttr());
+void FirConverter::genFIR(const Fortran::parser::EndWhereStmt &) {
+ if (!lowerToHighLevelFIR())
+ implicitIterSpace.shrinkStack();
+}
- const Fortran::semantics::Scope *scope = info.typeSpec.scope();
- if (!scope)
- scope = info.typeSpec.typeSymbol().scope();
- assert(scope && "failed to find type scope");
+void FirConverter::genFIR(const Fortran::parser::EventPostStmt &stmt) {
+ genEventPostStatement(*this, stmt);
+}
- Fortran::semantics::SymbolVector bindings =
- Fortran::semantics::CollectBindings(*scope);
- if (!bindings.empty()) {
- builder.createBlock(&dt.getDispatchTable());
- for (const Fortran::semantics::SymbolRef &binding : bindings) {
- const auto &details =
- binding.get().get<Fortran::semantics::ProcBindingDetails>();
- std::string tbpName = binding.get().name().ToString();
- if (details.numPrivatesNotOverridden() > 0)
- tbpName += "."s + std::to_string(details.numPrivatesNotOverridden());
- std::string bindingName = converter.mangleName(details.symbol());
- builder.create<fir::DTEntryOp>(
- info.loc, mlir::StringAttr::get(builder.getContext(), tbpName),
- mlir::SymbolRefAttr::get(builder.getContext(), bindingName));
- }
- builder.create<fir::FirEndOp>(info.loc);
- }
- builder.restoreInsertionPoint(insertPt);
+void FirConverter::genFIR(const Fortran::parser::EventWaitStmt &stmt) {
+ genEventWaitStatement(*this, stmt);
}
-//===--------------------------------------------------------------------===//
-// Helper member functions
-//===--------------------------------------------------------------------===//
-
-/// Find the symbol in the local map or return null.
-Fortran::lower::SymbolBox
-FirConverter::lookupSymbol(const Fortran::semantics::Symbol &sym,
- Fortran::lower::SymMap *symMap) {
- symMap = symMap ? symMap : &localSymbols;
- if (lowerToHighLevelFIR()) {
- if (std::optional<fir::FortranVariableOpInterface> var =
- symMap->lookupVariableDefinition(sym)) {
- auto exv = hlfir::translateToExtendedValue(toLocation(), *builder, *var);
- return exv.match(
- [](mlir::Value x) -> Fortran::lower::SymbolBox {
- return Fortran::lower::SymbolBox::Intrinsic{x};
- },
- [](auto x) -> Fortran::lower::SymbolBox { return x; });
- }
-
- // Entry character result represented as an argument pair
- // needs to be represented in the symbol table even before
- // we can create DeclareOp for it. The temporary mapping
- // is EmboxCharOp that conveys the address and length information.
- // After mapSymbolAttributes is done, the mapping is replaced
- // with the new DeclareOp, and the following table lookups
- // do not reach here.
- if (sym.IsFuncResult())
- if (const Fortran::semantics::DeclTypeSpec *declTy = sym.GetType())
- if (declTy->category() ==
- Fortran::semantics::DeclTypeSpec::Category::Character)
- return symMap->lookupSymbol(sym);
-
- // Procedure dummies are not mapped with an hlfir.declare because
- // they are not "variable" (cannot be assigned to), and it would
- // make hlfir.declare more complex than it needs to to allow this.
- // Do a regular lookup.
- if (Fortran::semantics::IsProcedure(sym))
- return symMap->lookupSymbol(sym);
-
- // Commonblock names are not variables, but in some lowerings (like
- // OpenMP) it is useful to maintain the address of the commonblock in an
- // MLIR value and query it. hlfir.declare need not be created for these.
- if (sym.detailsIf<Fortran::semantics::CommonBlockDetails>())
- return symMap->lookupSymbol(sym);
-
- return {};
- }
- if (Fortran::lower::SymbolBox v = symMap->lookupSymbol(sym))
- return v;
- return {};
+void FirConverter::genFIR(const Fortran::parser::ExitStmt &) {
+ genConstructExitBranch(*getEval().controlSuccessor);
}
-/// Add the symbol to the local map and return `true`. If the symbol is
-/// already in the map and \p forced is `false`, the map is not updated.
-/// Instead the value `false` is returned.
-bool FirConverter::addSymbol(const Fortran::semantics::SymbolRef sym,
- fir::ExtendedValue val, bool forced) {
- if (!forced && lookupSymbol(sym))
- return false;
- if (lowerToHighLevelFIR()) {
- Fortran::lower::genDeclareSymbol(*this, localSymbols, sym, val,
- fir::FortranVariableFlagsEnum::None,
- forced);
- } else {
- localSymbols.addSymbol(sym, val, forced);
- }
- return true;
+void FirConverter::genFIR(const Fortran::parser::FailImageStmt &stmt) {
+ genFailImageStatement(*this);
}
-/// Map a block argument to a result or dummy symbol. This is not the
-/// definitive mapping. The specification expression have not been lowered
-/// yet. The final mapping will be done using this pre-mapping in
-/// Fortran::lower::mapSymbolAttributes.
-bool FirConverter::mapBlockArgToDummyOrResult(
- const Fortran::semantics::SymbolRef sym, mlir::Value val, bool forced) {
- if (!forced && lookupSymbol(sym))
- return false;
- localSymbols.addSymbol(sym, val, forced);
- return true;
+void FirConverter::genFIR(const Fortran::parser::FlushStmt &stmt) {
+ mlir::Value iostat = genFlushStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.v, iostat);
}
-/// Generate the address of loop variable \p sym.
-/// If \p sym is not mapped yet, allocate local storage for it.
-mlir::Value
-FirConverter::genLoopVariableAddress(mlir::Location loc,
- const Fortran::semantics::Symbol &sym,
- bool isUnordered) {
- if (isUnordered || sym.has<Fortran::semantics::HostAssocDetails>() ||
- sym.has<Fortran::semantics::UseDetails>()) {
- if (!shallowLookupSymbol(sym)) {
- // Do concurrent loop variables are not mapped yet since they are local
- // to the Do concurrent scope (same for OpenMP loops).
- mlir::OpBuilder::InsertPoint insPt = builder->saveInsertionPoint();
- builder->setInsertionPointToStart(builder->getAllocaBlock());
- mlir::Type tempTy = genType(sym);
- mlir::Value temp =
- builder->createTemporaryAlloc(loc, tempTy, toStringRef(sym.name()));
- bindIfNewSymbol(sym, temp);
- builder->restoreInsertionPoint(insPt);
- }
- }
- auto entry = lookupSymbol(sym);
- (void)entry;
- assert(entry && "loop control variable must already be in map");
- Fortran::lower::StatementContext stmtCtx;
- return fir::getBase(
- genExprAddr(Fortran::evaluate::AsGenericExpr(sym).value(), stmtCtx));
+void FirConverter::genFIR(const Fortran::parser::ForallAssignmentStmt &stmt) {
+ std::visit([&](const auto &x) { genFIR(x); }, stmt.u);
}
-/// Insert a new block before \p block. Leave the insertion point unchanged.
-mlir::Block *FirConverter::insertBlock(mlir::Block *block) {
+/// Generate FIR for a FORALL construct.
+void FirConverter::genFIR(const Fortran::parser::ForallConstruct &forall) {
mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
- mlir::Block *newBlock = builder->createBlock(block);
- builder->restoreInsertionPoint(insertPt);
- return newBlock;
-}
-
-Fortran::lower::pft::Evaluation &
-FirConverter::evalOfLabel(Fortran::parser::Label label) {
- const Fortran::lower::pft::LabelEvalMap &labelEvaluationMap =
- getEval().getOwningProcedure()->labelEvaluationMap;
- const auto iter = labelEvaluationMap.find(label);
- assert(iter != labelEvaluationMap.end() && "label missing from map");
- return *iter->second;
+ if (lowerToHighLevelFIR())
+ localSymbols.pushScope();
+ else
+ prepareExplicitSpace(forall);
+ genNestedStatement(
+ std::get<
+ Fortran::parser::Statement<Fortran::parser::ForallConstructStmt>>(
+ forall.t));
+ for (const Fortran::parser::ForallBodyConstruct &s :
+ std::get<std::list<Fortran::parser::ForallBodyConstruct>>(forall.t)) {
+ std::visit(
+ Fortran::common::visitors{
+ [&](const Fortran::parser::WhereConstruct &b) { genFIR(b); },
+ [&](const Fortran::common::Indirection<
+ Fortran::parser::ForallConstruct> &b) { genFIR(b.value()); },
+ [&](const auto &b) { genNestedStatement(b); }},
+ s.u);
+ }
+ genNestedStatement(
+ std::get<Fortran::parser::Statement<Fortran::parser::EndForallStmt>>(
+ forall.t));
+ if (lowerToHighLevelFIR()) {
+ localSymbols.popScope();
+ builder->restoreInsertionPoint(insertPt);
+ }
}
-void FirConverter::genConditionalBranch(mlir::Value cond,
- mlir::Block *trueTarget,
- mlir::Block *falseTarget) {
- assert(trueTarget && "missing conditional branch true block");
- assert(falseTarget && "missing conditional branch false block");
- mlir::Location loc = toLocation();
- mlir::Value bcc = builder->createConvert(loc, builder->getI1Type(), cond);
- builder->create<mlir::cf::CondBranchOp>(loc, bcc, trueTarget, std::nullopt,
- falseTarget, std::nullopt);
+/// Lower the concurrent header specification.
+void FirConverter::genFIR(const Fortran::parser::ForallConstructStmt &stmt) {
+ const auto &concurrentHeader =
+ std::get<Fortran::common::Indirection<Fortran::parser::ConcurrentHeader>>(
+ stmt.t)
+ .value();
+ if (lowerToHighLevelFIR())
+ genForallNest(concurrentHeader);
+ else
+ genFIR(concurrentHeader);
}
-void FirConverter::genConditionalBranch(
- const Fortran::parser::ScalarLogicalExpr &expr, mlir::Block *trueTarget,
- mlir::Block *falseTarget) {
- Fortran::lower::StatementContext stmtCtx;
- mlir::Value cond =
- createFIRExpr(toLocation(), Fortran::semantics::GetExpr(expr), stmtCtx);
- stmtCtx.finalizeAndReset();
- genConditionalBranch(cond, trueTarget, falseTarget);
+/// Generate FIR for a FORALL statement.
+void FirConverter::genFIR(const Fortran::parser::ForallStmt &stmt) {
+ const auto &concurrentHeader =
+ std::get<Fortran::common::Indirection<Fortran::parser::ConcurrentHeader>>(
+ stmt.t)
+ .value();
+ if (lowerToHighLevelFIR()) {
+ mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
+ localSymbols.pushScope();
+ genForallNest(concurrentHeader);
+ genFIR(std::get<Fortran::parser::UnlabeledStatement<
+ Fortran::parser::ForallAssignmentStmt>>(stmt.t)
+ .statement);
+ localSymbols.popScope();
+ builder->restoreInsertionPoint(insertPt);
+ return;
+ }
+ prepareExplicitSpace(stmt);
+ genFIR(concurrentHeader);
+ genFIR(std::get<Fortran::parser::UnlabeledStatement<
+ Fortran::parser::ForallAssignmentStmt>>(stmt.t)
+ .statement);
+ cleanupExplicitSpace();
}
-void FirConverter::genConditionalBranch(
- const Fortran::parser::ScalarLogicalExpr &expr,
- Fortran::lower::pft::Evaluation *trueTarget,
- Fortran::lower::pft::Evaluation *falseTarget) {
- Fortran::lower::StatementContext stmtCtx;
- mlir::Value cond =
- createFIRExpr(toLocation(), Fortran::semantics::GetExpr(expr), stmtCtx);
- stmtCtx.finalizeAndReset();
- genConditionalBranch(cond, trueTarget->block, falseTarget->block);
-}
+void FirConverter::genFIR(const Fortran::parser::FormatStmt &) {
+ // do nothing.
-/// Return the nearest active ancestor construct of \p eval, or nullptr.
-Fortran::lower::pft::Evaluation *
-FirConverter::getActiveAncestor(const Fortran::lower::pft::Evaluation &eval) {
- Fortran::lower::pft::Evaluation *ancestor = eval.parentConstruct;
- for (; ancestor; ancestor = ancestor->parentConstruct)
- if (ancestor->activeConstruct)
- break;
- return ancestor;
+ // FORMAT statements have no semantics. They may be lowered if used by a
+ // data transfer statement.
}
-/// Return the predicate: "a branch to \p targetEval has exit code".
-bool FirConverter::hasExitCode(
- const Fortran::lower::pft::Evaluation &targetEval) {
- Fortran::lower::pft::Evaluation *activeAncestor =
- getActiveAncestor(targetEval);
- for (auto it = activeConstructStack.rbegin(),
- rend = activeConstructStack.rend();
- it != rend; ++it) {
- if (&it->eval == activeAncestor)
- break;
- if (it->stmtCtx.hasCode())
- return true;
- }
- return false;
+void FirConverter::genFIR(const Fortran::parser::FormTeamStmt &stmt) {
+ genFormTeamStatement(*this, getEval(), stmt);
}
-/// Generate a branch to \p targetEval after generating on-exit code for
-/// any enclosing construct scopes that are exited by taking the branch.
-void FirConverter::genConstructExitBranch(
- const Fortran::lower::pft::Evaluation &targetEval) {
- Fortran::lower::pft::Evaluation *activeAncestor =
- getActiveAncestor(targetEval);
- for (auto it = activeConstructStack.rbegin(),
- rend = activeConstructStack.rend();
- it != rend; ++it) {
- if (&it->eval == activeAncestor)
- break;
- it->stmtCtx.finalizeAndKeep();
- }
- genBranch(targetEval.block);
+void FirConverter::genFIR(const Fortran::parser::GotoStmt &) {
+ genConstructExitBranch(*getEval().controlSuccessor);
}
-/// Generate a SelectOp or branch sequence that compares \p selector against
-/// values in \p valueList and targets corresponding labels in \p labelList.
-/// If no value matches the selector, branch to \p defaultEval.
-///
-/// Three cases require special processing.
-///
-/// An empty \p valueList indicates an ArithmeticIfStmt context that requires
-/// two comparisons against 0 or 0.0. The selector may have either INTEGER
-/// or REAL type.
-///
-/// A nonpositive \p valuelist value indicates an IO statement context
-/// (0 for ERR, -1 for END, -2 for EOR). An ERR branch must be taken for
-/// any positive (IOSTAT) value. A missing (zero) label requires a branch
-/// to \p defaultEval for that value.
-///
-/// A non-null \p errorBlock indicates an AssignedGotoStmt context that
-/// must always branch to an explicit target. There is no valid defaultEval
-/// in this case. Generate a branch to \p errorBlock for an AssignedGotoStmt
-/// that violates this program requirement.
-///
-/// If this is not an ArithmeticIfStmt and no targets have exit code,
-/// generate a SelectOp. Otherwise, for each target, if it has exit code,
-/// branch to a new block, insert exit code, and then branch to the target.
-/// Otherwise, branch directly to the target.
-void FirConverter::genMultiwayBranch(
- mlir::Value selector, llvm::SmallVector<int64_t> valueList,
- llvm::SmallVector<Fortran::parser::Label> labelList,
- const Fortran::lower::pft::Evaluation &defaultEval,
- mlir::Block *errorBlock) {
- bool inArithmeticIfContext = valueList.empty();
- assert(((inArithmeticIfContext && labelList.size() == 2) ||
- (valueList.size() && labelList.size() == valueList.size())) &&
- "mismatched multiway branch targets");
- mlir::Block *defaultBlock = errorBlock ? errorBlock : defaultEval.block;
- bool defaultHasExitCode = !errorBlock && hasExitCode(defaultEval);
- bool hasAnyExitCode = defaultHasExitCode;
- if (!hasAnyExitCode)
- for (auto label : labelList)
- if (label && hasExitCode(evalOfLabel(label))) {
- hasAnyExitCode = true;
- break;
- }
+/// Generate structured or unstructured FIR for an IF construct.
+/// The initial statement may be either an IfStmt or an IfThenStmt.
+void FirConverter::genFIR(const Fortran::parser::IfConstruct &) {
mlir::Location loc = toLocation();
- size_t branchCount = labelList.size();
- if (!inArithmeticIfContext && !hasAnyExitCode &&
- !getEval().forceAsUnstructured()) { // from -no-structured-fir option
- // Generate a SelectOp.
- llvm::SmallVector<mlir::Block *> blockList;
- for (auto label : labelList) {
- mlir::Block *block = label ? evalOfLabel(label).block : defaultEval.block;
- assert(block && "missing multiway branch block");
- blockList.push_back(block);
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ if (eval.lowerAsStructured()) {
+ // Structured fir.if nest.
+ fir::IfOp topIfOp, currentIfOp;
+ for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
+ auto genIfOp = [&](mlir::Value cond) {
+ auto ifOp = builder->create<fir::IfOp>(loc, cond, /*withElse=*/true);
+ builder->setInsertionPointToStart(&ifOp.getThenRegion().front());
+ return ifOp;
+ };
+ if (auto *s = e.getIf<Fortran::parser::IfThenStmt>()) {
+ topIfOp = currentIfOp = genIfOp(genIfCondition(s, e.negateCondition));
+ } else if (auto *s = e.getIf<Fortran::parser::IfStmt>()) {
+ topIfOp = currentIfOp = genIfOp(genIfCondition(s, e.negateCondition));
+ } else if (auto *s = e.getIf<Fortran::parser::ElseIfStmt>()) {
+ builder->setInsertionPointToStart(¤tIfOp.getElseRegion().front());
+ currentIfOp = genIfOp(genIfCondition(s));
+ } else if (e.isA<Fortran::parser::ElseStmt>()) {
+ builder->setInsertionPointToStart(¤tIfOp.getElseRegion().front());
+ } else if (e.isA<Fortran::parser::EndIfStmt>()) {
+ builder->setInsertionPointAfter(topIfOp);
+ genFIR(e, /*unstructuredContext=*/false); // may generate branch
+ } else {
+ genFIR(e, /*unstructuredContext=*/false);
+ }
}
- blockList.push_back(defaultBlock);
- if (valueList[branchCount - 1] == 0) // Swap IO ERR and default blocks.
- std::swap(blockList[branchCount - 1], blockList[branchCount]);
- builder->create<fir::SelectOp>(loc, selector, valueList, blockList);
return;
}
- mlir::Type selectorType = selector.getType();
- bool realSelector = selectorType.isa<mlir::FloatType>();
- assert((inArithmeticIfContext || !realSelector) && "invalid selector type");
- mlir::Value zero;
- if (inArithmeticIfContext)
- zero = realSelector ? builder->create<mlir::arith::ConstantOp>(
- loc, selectorType,
- builder->getFloatAttr(selectorType, 0.0))
- : builder->createIntegerConstant(loc, selectorType, 0);
- for (auto label : llvm::enumerate(labelList)) {
- mlir::Value cond;
- if (realSelector) // inArithmeticIfContext
- cond = builder->create<mlir::arith::CmpFOp>(
- loc,
- label.index() == 0 ? mlir::arith::CmpFPredicate::OLT
- : mlir::arith::CmpFPredicate::OGT,
- selector, zero);
- else if (inArithmeticIfContext) // INTEGER selector
- cond = builder->create<mlir::arith::CmpIOp>(
- loc,
- label.index() == 0 ? mlir::arith::CmpIPredicate::slt
- : mlir::arith::CmpIPredicate::sgt,
- selector, zero);
- else // A value of 0 is an IO ERR branch: invert comparison.
- cond = builder->create<mlir::arith::CmpIOp>(
- loc,
- valueList[label.index()] == 0 ? mlir::arith::CmpIPredicate::ne
- : mlir::arith::CmpIPredicate::eq,
- selector,
- builder->createIntegerConstant(loc, selectorType,
- valueList[label.index()]));
- // Branch to a new block with exit code and then to the target, or branch
- // directly to the target. defaultBlock is the "else" target.
- bool lastBranch = label.index() == branchCount - 1;
- mlir::Block *nextBlock =
- lastBranch && !defaultHasExitCode
- ? defaultBlock
- : builder->getBlock()->splitBlock(builder->getInsertionPoint());
- const Fortran::lower::pft::Evaluation &targetEval =
- label.value() ? evalOfLabel(label.value()) : defaultEval;
- if (hasExitCode(targetEval)) {
- mlir::Block *jumpBlock =
- builder->getBlock()->splitBlock(builder->getInsertionPoint());
- genConditionalBranch(cond, jumpBlock, nextBlock);
- startBlock(jumpBlock);
- genConstructExitBranch(targetEval);
+
+ // Unstructured branch sequence.
+ for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
+ auto genIfBranch = [&](mlir::Value cond) {
+ if (e.lexicalSuccessor == e.controlSuccessor) // empty block -> exit
+ genConditionalBranch(cond, e.parentConstruct->constructExit,
+ e.controlSuccessor);
+ else // non-empty block
+ genConditionalBranch(cond, e.lexicalSuccessor, e.controlSuccessor);
+ };
+ if (auto *s = e.getIf<Fortran::parser::IfThenStmt>()) {
+ maybeStartBlock(e.block);
+ genIfBranch(genIfCondition(s, e.negateCondition));
+ } else if (auto *s = e.getIf<Fortran::parser::IfStmt>()) {
+ maybeStartBlock(e.block);
+ genIfBranch(genIfCondition(s, e.negateCondition));
+ } else if (auto *s = e.getIf<Fortran::parser::ElseIfStmt>()) {
+ startBlock(e.block);
+ genIfBranch(genIfCondition(s));
} else {
- genConditionalBranch(cond, targetEval.block, nextBlock);
- }
- if (!lastBranch) {
- startBlock(nextBlock);
- } else if (defaultHasExitCode) {
- startBlock(nextBlock);
- genConstructExitBranch(defaultEval);
+ genFIR(e);
}
}
}
-//===--------------------------------------------------------------------===//
-// Termination of symbolically referenced execution units
-//===--------------------------------------------------------------------===//
+void FirConverter::genFIR(const Fortran::parser::InquireStmt &stmt) {
+ mlir::Value iostat = genInquireStatement(*this, stmt);
+ if (const auto *specs =
+ std::get_if<std::list<Fortran::parser::InquireSpec>>(&stmt.u))
+ genIoConditionBranches(getEval(), *specs, iostat);
+}
-/// END of procedure-like constructs
+void FirConverter::genFIR(const Fortran::parser::LockStmt &stmt) {
+ genLockStatement(*this, stmt);
+}
+
+void FirConverter::genFIR(const Fortran::parser::MaskedElsewhereStmt &stmt) {
+ const auto *maskExpr = Fortran::semantics::GetExpr(
+ std::get<Fortran::parser::LogicalExpr>(stmt.t));
+ if (lowerToHighLevelFIR())
+ lowerWhereMaskToHlfir(getCurrentLocation(), maskExpr);
+ else
+ implicitIterSpace.append(maskExpr);
+}
+
+/// Nullify pointer object list
///
-/// Generate the cleanup block before the procedure exits
-void FirConverter::genReturnSymbol(
- const Fortran::semantics::Symbol &functionSymbol) {
- const Fortran::semantics::Symbol &resultSym =
- functionSymbol.get<Fortran::semantics::SubprogramDetails>().result();
- Fortran::lower::SymbolBox resultSymBox = lookupSymbol(resultSym);
+/// For each pointer object, reset the pointer to a disassociated status.
+/// We do this by setting each pointer to null.
+void FirConverter::genFIR(const Fortran::parser::NullifyStmt &stmt) {
mlir::Location loc = toLocation();
- if (!resultSymBox) {
- mlir::emitError(loc, "internal error when processing function return");
- return;
+ for (auto &pointerObject : stmt.v) {
+ const Fortran::lower::SomeExpr *expr =
+ Fortran::semantics::GetExpr(pointerObject);
+ assert(expr);
+ if (Fortran::evaluate::IsProcedurePointer(*expr)) {
+ Fortran::lower::StatementContext stmtCtx;
+ hlfir::Entity pptr = Fortran::lower::convertExprToHLFIR(
+ loc, *this, *expr, localSymbols, stmtCtx);
+ auto boxTy{Fortran::lower::getUntypedBoxProcType(builder->getContext())};
+ hlfir::Entity nullBoxProc(
+ fir::factory::createNullBoxProc(*builder, loc, boxTy));
+ builder->createStoreWithConvert(loc, nullBoxProc, pptr);
+ return;
+ }
+ fir::MutableBoxValue box = genExprMutableBox(loc, *expr);
+ fir::factory::disassociateMutableBox(*builder, loc, box);
}
- mlir::Value resultVal = resultSymBox.match(
- [&](const fir::CharBoxValue &x) -> mlir::Value {
- if (Fortran::semantics::IsBindCProcedure(functionSymbol))
- return builder->create<fir::LoadOp>(loc, x.getBuffer());
- return fir::factory::CharacterExprHelper{*builder, loc}.createEmboxChar(
- x.getBuffer(), x.getLen());
- },
- [&](const fir::MutableBoxValue &x) -> mlir::Value {
- mlir::Value resultRef = resultSymBox.getAddr();
- mlir::Value load = builder->create<fir::LoadOp>(loc, resultRef);
- unsigned rank = x.rank();
- if (x.isAllocatable() && rank > 0) {
- // ALLOCATABLE array result must have default lower bounds.
- // At the call site the result box of a function reference
- // might be considered having default lower bounds, but
- // the runtime box should probably comply with this assumption
- // as well. If the result box has proper lbounds in runtime,
- // this may improve the debugging experience of Fortran apps.
- // We may consider removing this, if the overhead of setting
- // default lower bounds is too big.
- mlir::Value one =
- builder->createIntegerConstant(loc, builder->getIndexType(), 1);
- llvm::SmallVector<mlir::Value> lbounds{rank, one};
- auto shiftTy = fir::ShiftType::get(builder->getContext(), rank);
- mlir::Value shiftOp =
- builder->create<fir::ShiftOp>(loc, shiftTy, lbounds);
- load = builder->create<fir::ReboxOp>(
- loc, load.getType(), load, shiftOp, /*slice=*/mlir::Value{});
- }
- return load;
- },
- [&](const auto &) -> mlir::Value {
- mlir::Value resultRef = resultSymBox.getAddr();
- mlir::Type resultType = genType(resultSym);
- mlir::Type resultRefType = builder->getRefType(resultType);
- // A function with multiple entry points returning different types
- // tags all result variables with one of the largest types to allow
- // them to share the same storage. Convert this to the actual type.
- if (resultRef.getType() != resultRefType)
- resultRef = builder->createConvert(loc, resultRefType, resultRef);
- return builder->create<fir::LoadOp>(loc, resultRef);
- });
- bridge.openAccCtx().finalizeAndPop();
- bridge.fctCtx().finalizeAndPop();
- builder->create<mlir::func::ReturnOp>(loc, resultVal);
}
-void FirConverter::genFIRProcedureExit(
- Fortran::lower::pft::FunctionLikeUnit &funit,
- const Fortran::semantics::Symbol &symbol) {
- if (mlir::Block *finalBlock = funit.finalBlock) {
- // The current block must end with a terminator.
- if (blockIsUnterminated())
- builder->create<mlir::cf::BranchOp>(toLocation(), finalBlock);
- // Set insertion point to final block.
- builder->setInsertionPoint(finalBlock, finalBlock->end());
- }
- if (Fortran::semantics::IsFunction(symbol)) {
- genReturnSymbol(symbol);
- } else if (Fortran::semantics::HasAlternateReturns(symbol)) {
- mlir::Value retval =
- builder->create<fir::LoadOp>(toLocation(), getAltReturnResult(symbol));
- bridge.openAccCtx().finalizeAndPop();
- bridge.fctCtx().finalizeAndPop();
- builder->create<mlir::func::ReturnOp>(toLocation(), retval);
- } else {
- bridge.openAccCtx().finalizeAndPop();
- bridge.fctCtx().finalizeAndPop();
- genExitRoutine();
+void FirConverter::genFIR(const Fortran::parser::OpenACCConstruct &acc) {
+ mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
+ localSymbols.pushScope();
+ mlir::Value exitCond =
+ genOpenACCConstruct(*this, bridge.getSemanticsContext(), getEval(), acc);
+ for (Fortran::lower::pft::Evaluation &e : getEval().getNestedEvaluations())
+ genFIR(e);
+ localSymbols.popScope();
+ builder->restoreInsertionPoint(insertPt);
+
+ const Fortran::parser::OpenACCLoopConstruct *accLoop =
+ std::get_if<Fortran::parser::OpenACCLoopConstruct>(&acc.u);
+ if (accLoop && exitCond) {
+ Fortran::lower::pft::FunctionLikeUnit *funit =
+ getEval().getOwningProcedure();
+ assert(funit && "not inside main program, function or subroutine");
+ mlir::Block *continueBlock =
+ builder->getBlock()->splitBlock(builder->getBlock()->end());
+ builder->create<mlir::cf::CondBranchOp>(toLocation(), exitCond,
+ funit->finalBlock, continueBlock);
+ builder->setInsertionPointToEnd(continueBlock);
}
}
-//
-// Statements that have control-flow semantics
-//
+void FirConverter::genFIR(
+ const Fortran::parser::OpenACCDeclarativeConstruct &accDecl) {
+ genOpenACCDeclarativeConstruct(*this, bridge.getSemanticsContext(),
+ bridge.openAccCtx(), accDecl, accRoutineInfos);
+ for (Fortran::lower::pft::Evaluation &e : getEval().getNestedEvaluations())
+ genFIR(e);
+}
-mlir::func::FuncOp FirConverter::getFunc(llvm::StringRef name,
- mlir::FunctionType ty) {
- if (mlir::func::FuncOp func = builder->getNamedFunction(name)) {
- assert(func.getFunctionType() == ty);
- return func;
- }
- return builder->createFunction(toLocation(), name, ty);
+void FirConverter::genFIR(const Fortran::parser::OpenACCRoutineConstruct &acc) {
+ // Handled by genFIR(const Fortran::parser::OpenACCDeclarativeConstruct &)
}
-/// Lowering of CALL statement
-void FirConverter::genFIR(const Fortran::parser::CallStmt &stmt) {
- Fortran::lower::StatementContext stmtCtx;
- Fortran::lower::pft::Evaluation &eval = getEval();
- setCurrentPosition(stmt.source);
- assert(stmt.typedCall && "Call was not analyzed");
- mlir::Value res{};
- if (lowerToHighLevelFIR()) {
- std::optional<mlir::Type> resultType;
- if (stmt.typedCall->hasAlternateReturns())
- resultType = builder->getIndexType();
- auto hlfirRes =
- Fortran::lower::convertCallToHLFIR(toLocation(), *this, *stmt.typedCall,
- resultType, localSymbols, stmtCtx);
- if (hlfirRes)
- res = *hlfirRes;
- } else {
- // Call statement lowering shares code with function call lowering.
- res = Fortran::lower::createSubroutineCall(
- *this, *stmt.typedCall, explicitIterSpace, implicitIterSpace,
- localSymbols, stmtCtx, /*isUserDefAssignment=*/false);
- }
- stmtCtx.finalizeAndReset();
- if (!res)
- return; // "Normal" subroutine call.
- // Call with alternate return specifiers.
- // The call returns an index that selects an alternate return branch target.
- llvm::SmallVector<int64_t> indexList;
- llvm::SmallVector<Fortran::parser::Label> labelList;
- int64_t index = 0;
- for (const Fortran::parser::ActualArgSpec &arg :
- std::get<std::list<Fortran::parser::ActualArgSpec>>(stmt.call.t)) {
- const auto &actual = std::get<Fortran::parser::ActualArg>(arg.t);
- if (const auto *altReturn =
- std::get_if<Fortran::parser::AltReturnSpec>(&actual.u)) {
- indexList.push_back(++index);
- labelList.push_back(altReturn->v);
+void FirConverter::genFIR(const Fortran::parser::OpenMPConstruct &omp) {
+ mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
+ localSymbols.pushScope();
+ genOpenMPConstruct(*this, bridge.getSemanticsContext(), getEval(), omp);
+
+ const Fortran::parser::OpenMPLoopConstruct *ompLoop =
+ std::get_if<Fortran::parser::OpenMPLoopConstruct>(&omp.u);
+ const Fortran::parser::OpenMPBlockConstruct *ompBlock =
+ std::get_if<Fortran::parser::OpenMPBlockConstruct>(&omp.u);
+
+ // If loop is part of an OpenMP Construct then the OpenMP dialect
+ // workshare loop operation has already been created. Only the
+ // body needs to be created here and the do_loop can be skipped.
+ // Skip the number of collapsed loops, which is 1 when there is a
+ // no collapse requested.
+
+ Fortran::lower::pft::Evaluation *curEval = &getEval();
+ const Fortran::parser::OmpClauseList *loopOpClauseList = nullptr;
+ if (ompLoop) {
+ loopOpClauseList = &std::get<Fortran::parser::OmpClauseList>(
+ std::get<Fortran::parser::OmpBeginLoopDirective>(ompLoop->t).t);
+ int64_t collapseValue = Fortran::lower::getCollapseValue(*loopOpClauseList);
+
+ curEval = &curEval->getFirstNestedEvaluation();
+ for (int64_t i = 1; i < collapseValue; i++) {
+ curEval = &*std::next(curEval->getNestedEvaluations().begin());
}
}
- genMultiwayBranch(res, indexList, labelList, eval.nonNopSuccessor());
-}
-void FirConverter::genFIR(const Fortran::parser::ComputedGotoStmt &stmt) {
- Fortran::lower::StatementContext stmtCtx;
- Fortran::lower::pft::Evaluation &eval = getEval();
- mlir::Value selectExpr =
- createFIRExpr(toLocation(),
- Fortran::semantics::GetExpr(
- std::get<Fortran::parser::ScalarIntExpr>(stmt.t)),
- stmtCtx);
- stmtCtx.finalizeAndReset();
- llvm::SmallVector<int64_t> indexList;
- llvm::SmallVector<Fortran::parser::Label> labelList;
- int64_t index = 0;
- for (Fortran::parser::Label label :
- std::get<std::list<Fortran::parser::Label>>(stmt.t)) {
- indexList.push_back(++index);
- labelList.push_back(label);
+ for (Fortran::lower::pft::Evaluation &e : curEval->getNestedEvaluations())
+ genFIR(e);
+
+ if (ompLoop) {
+ genOpenMPReduction(*this, *loopOpClauseList);
+ } else if (ompBlock) {
+ const auto &blockStart =
+ std::get<Fortran::parser::OmpBeginBlockDirective>(ompBlock->t);
+ const auto &blockClauses =
+ std::get<Fortran::parser::OmpClauseList>(blockStart.t);
+ genOpenMPReduction(*this, blockClauses);
}
- genMultiwayBranch(selectExpr, indexList, labelList, eval.nonNopSuccessor());
+
+ localSymbols.popScope();
+ builder->restoreInsertionPoint(insertPt);
+
+ // Register if a target region was found
+ ompDeviceCodeFound =
+ ompDeviceCodeFound || Fortran::lower::isOpenMPTargetConstruct(omp);
}
-void FirConverter::genFIR(const Fortran::parser::ArithmeticIfStmt &stmt) {
- Fortran::lower::StatementContext stmtCtx;
- mlir::Value expr = createFIRExpr(
- toLocation(),
- Fortran::semantics::GetExpr(std::get<Fortran::parser::Expr>(stmt.t)),
- stmtCtx);
- stmtCtx.finalizeAndReset();
- // Raise an exception if REAL expr is a NaN.
- if (expr.getType().isa<mlir::FloatType>())
- expr = builder->create<mlir::arith::AddFOp>(toLocation(), expr, expr);
- // An empty valueList indicates to genMultiwayBranch that the branch is
- // an ArithmeticIfStmt that has two branches on value 0 or 0.0.
- llvm::SmallVector<int64_t> valueList;
- llvm::SmallVector<Fortran::parser::Label> labelList;
- labelList.push_back(std::get<1>(stmt.t));
- labelList.push_back(std::get<3>(stmt.t));
- const Fortran::lower::pft::LabelEvalMap &labelEvaluationMap =
- getEval().getOwningProcedure()->labelEvaluationMap;
- const auto iter = labelEvaluationMap.find(std::get<2>(stmt.t));
- assert(iter != labelEvaluationMap.end() && "label missing from map");
- genMultiwayBranch(expr, valueList, labelList, *iter->second);
+void FirConverter::genFIR(
+ const Fortran::parser::OpenMPDeclarativeConstruct &ompDecl) {
+ mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
+ // Register if a declare target construct intended for a target device was
+ // found
+ ompDeviceCodeFound =
+ ompDeviceCodeFound ||
+ Fortran::lower::isOpenMPDeviceDeclareTarget(*this, getEval(), ompDecl);
+ genOpenMPDeclarativeConstruct(*this, getEval(), ompDecl);
+ for (Fortran::lower::pft::Evaluation &e : getEval().getNestedEvaluations())
+ genFIR(e);
+ builder->restoreInsertionPoint(insertPt);
}
-void FirConverter::genFIR(const Fortran::parser::AssignedGotoStmt &stmt) {
- // See Fortran 90 Clause 8.2.4.
- // Relax the requirement that the GOTO variable must have a value in the
- // label list when a list is present, and allow a branch to any non-format
- // target that has an ASSIGN statement for the variable.
- mlir::Location loc = toLocation();
- Fortran::lower::pft::Evaluation &eval = getEval();
- Fortran::lower::pft::FunctionLikeUnit &owningProc =
- *eval.getOwningProcedure();
- const Fortran::lower::pft::SymbolLabelMap &symbolLabelMap =
- owningProc.assignSymbolLabelMap;
- const Fortran::lower::pft::LabelEvalMap &labelEvalMap =
- owningProc.labelEvaluationMap;
- const Fortran::semantics::Symbol &symbol =
- *std::get<Fortran::parser::Name>(stmt.t).symbol;
- auto labelSetIter = symbolLabelMap.find(symbol);
- llvm::SmallVector<int64_t> valueList;
- llvm::SmallVector<Fortran::parser::Label> labelList;
- if (labelSetIter != symbolLabelMap.end()) {
- for (auto &label : labelSetIter->second) {
- const auto evalIter = labelEvalMap.find(label);
- assert(evalIter != labelEvalMap.end() && "assigned goto label missing");
- if (evalIter->second->block) { // non-format statement
- valueList.push_back(label); // label as an integer
- labelList.push_back(label);
- }
- }
- }
- if (!labelList.empty()) {
- auto selectExpr =
- builder->create<fir::LoadOp>(loc, getSymbolAddress(symbol));
- // Add a default error target in case the goto is nonconforming.
- mlir::Block *errorBlock =
- builder->getBlock()->splitBlock(builder->getInsertionPoint());
- genMultiwayBranch(selectExpr, valueList, labelList, eval.nonNopSuccessor(),
- errorBlock);
- startBlock(errorBlock);
- }
- fir::runtime::genReportFatalUserError(
- *builder, loc,
- "Assigned GOTO variable '" + symbol.name().ToString() +
- "' does not have a valid target label value");
- builder->create<fir::UnreachableOp>(loc);
+void FirConverter::genFIR(const Fortran::parser::OpenStmt &stmt) {
+ mlir::Value iostat = genOpenStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.v, iostat);
}
-/// Collect DO CONCURRENT or FORALL loop control information.
-FirConverter::IncrementLoopNestInfo FirConverter::getConcurrentControl(
- const Fortran::parser::ConcurrentHeader &header,
- const std::list<Fortran::parser::LocalitySpec> &localityList) {
- IncrementLoopNestInfo incrementLoopNestInfo;
- for (const Fortran::parser::ConcurrentControl &control :
- std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t))
- incrementLoopNestInfo.emplace_back(
- *std::get<0>(control.t).symbol, std::get<1>(control.t),
- std::get<2>(control.t), std::get<3>(control.t), /*isUnordered=*/true);
- IncrementLoopInfo &info = incrementLoopNestInfo.back();
- info.maskExpr = Fortran::semantics::GetExpr(
- std::get<std::optional<Fortran::parser::ScalarLogicalExpr>>(header.t));
- for (const Fortran::parser::LocalitySpec &x : localityList) {
- if (const auto *localList =
- std::get_if<Fortran::parser::LocalitySpec::Local>(&x.u))
- for (const Fortran::parser::Name &x : localList->v)
- info.localSymList.push_back(x.symbol);
- if (const auto *localInitList =
- std::get_if<Fortran::parser::LocalitySpec::LocalInit>(&x.u))
- for (const Fortran::parser::Name &x : localInitList->v)
- info.localInitSymList.push_back(x.symbol);
- if (const auto *sharedList =
- std::get_if<Fortran::parser::LocalitySpec::Shared>(&x.u))
- for (const Fortran::parser::Name &x : sharedList->v)
- info.sharedSymList.push_back(x.symbol);
- }
- return incrementLoopNestInfo;
+void FirConverter::genFIR(const Fortran::parser::PauseStmt &stmt) {
+ genPauseStatement(*this, stmt);
}
-/// Create DO CONCURRENT construct symbol bindings and generate LOCAL_INIT
-/// assignments.
-void FirConverter::handleLocalitySpecs(const IncrementLoopInfo &info) {
- Fortran::semantics::SemanticsContext &semanticsContext =
- bridge.getSemanticsContext();
- for (const Fortran::semantics::Symbol *sym : info.localSymList)
- createHostAssociateVarClone(*sym);
- for (const Fortran::semantics::Symbol *sym : info.localInitSymList) {
- createHostAssociateVarClone(*sym);
- const auto *hostDetails =
- sym->detailsIf<Fortran::semantics::HostAssocDetails>();
- assert(hostDetails && "missing locality spec host symbol");
- const Fortran::semantics::Symbol *hostSym = &hostDetails->symbol();
- Fortran::evaluate::ExpressionAnalyzer ea{semanticsContext};
- Fortran::evaluate::Assignment assign{
- ea.Designate(Fortran::evaluate::DataRef{*sym}).value(),
- ea.Designate(Fortran::evaluate::DataRef{*hostSym}).value()};
- if (Fortran::semantics::IsPointer(*sym))
- assign.u = Fortran::evaluate::Assignment::BoundsSpec{};
- genAssignment(assign);
- }
- for (const Fortran::semantics::Symbol *sym : info.sharedSymList) {
- const auto *hostDetails =
- sym->detailsIf<Fortran::semantics::HostAssocDetails>();
- copySymbolBinding(hostDetails->symbol(), *sym);
- }
+void FirConverter::genFIR(const Fortran::parser::PointerAssignmentStmt &stmt) {
+ genAssignment(*stmt.typedAssignment->v);
}
-/// Generate FIR for a DO construct. There are six variants:
-/// - unstructured infinite and while loops
-/// - structured and unstructured increment loops
-/// - structured and unstructured concurrent loops
-void FirConverter::genFIR(const Fortran::parser::DoConstruct &doConstruct) {
- setCurrentPositionAt(doConstruct);
- // Collect loop nest information.
- // Generate begin loop code directly for infinite and while loops.
- Fortran::lower::pft::Evaluation &eval = getEval();
- bool unstructuredContext = eval.lowerAsUnstructured();
- Fortran::lower::pft::Evaluation &doStmtEval = eval.getFirstNestedEvaluation();
- auto *doStmt = doStmtEval.getIf<Fortran::parser::NonLabelDoStmt>();
- const auto &loopControl =
- std::get<std::optional<Fortran::parser::LoopControl>>(doStmt->t);
- mlir::Block *preheaderBlock = doStmtEval.block;
- mlir::Block *beginBlock =
- preheaderBlock ? preheaderBlock : builder->getBlock();
- auto createNextBeginBlock = [&]() {
- // Step beginBlock through unstructured preheader, header, and mask
- // blocks, created in outermost to innermost order.
- return beginBlock = beginBlock->splitBlock(beginBlock->end());
- };
- mlir::Block *headerBlock =
- unstructuredContext ? createNextBeginBlock() : nullptr;
- mlir::Block *bodyBlock = doStmtEval.lexicalSuccessor->block;
- mlir::Block *exitBlock = doStmtEval.parentConstruct->constructExit->block;
- IncrementLoopNestInfo incrementLoopNestInfo;
- const Fortran::parser::ScalarLogicalExpr *whileCondition = nullptr;
- bool infiniteLoop = !loopControl.has_value();
- if (infiniteLoop) {
- assert(unstructuredContext && "infinite loop must be unstructured");
- startBlock(headerBlock);
- } else if ((whileCondition = std::get_if<Fortran::parser::ScalarLogicalExpr>(
- &loopControl->u))) {
- assert(unstructuredContext && "while loop must be unstructured");
- maybeStartBlock(preheaderBlock); // no block or empty block
- startBlock(headerBlock);
- genConditionalBranch(*whileCondition, bodyBlock, exitBlock);
- } else if (const auto *bounds =
- std::get_if<Fortran::parser::LoopControl::Bounds>(
- &loopControl->u)) {
- // Non-concurrent increment loop.
- IncrementLoopInfo &info = incrementLoopNestInfo.emplace_back(
- *bounds->name.thing.symbol, bounds->lower, bounds->upper, bounds->step);
- if (unstructuredContext) {
- maybeStartBlock(preheaderBlock);
- info.hasRealControl = info.loopVariableSym->GetType()->IsNumeric(
- Fortran::common::TypeCategory::Real);
- info.headerBlock = headerBlock;
- info.bodyBlock = bodyBlock;
- info.exitBlock = exitBlock;
- }
- } else {
- const auto *concurrent =
- std::get_if<Fortran::parser::LoopControl::Concurrent>(&loopControl->u);
- assert(concurrent && "invalid DO loop variant");
- incrementLoopNestInfo = getConcurrentControl(
- std::get<Fortran::parser::ConcurrentHeader>(concurrent->t),
- std::get<std::list<Fortran::parser::LocalitySpec>>(concurrent->t));
- if (unstructuredContext) {
- maybeStartBlock(preheaderBlock);
- for (IncrementLoopInfo &info : incrementLoopNestInfo) {
- // The original loop body provides the body and latch blocks of the
- // innermost dimension. The (first) body block of a non-innermost
- // dimension is the preheader block of the immediately enclosed
- // dimension. The latch block of a non-innermost dimension is the
- // exit block of the immediately enclosed dimension.
- auto createNextExitBlock = [&]() {
- // Create unstructured loop exit blocks, outermost to innermost.
- return exitBlock = insertBlock(exitBlock);
- };
- bool isInnermost = &info == &incrementLoopNestInfo.back();
- bool isOutermost = &info == &incrementLoopNestInfo.front();
- info.headerBlock = isOutermost ? headerBlock : createNextBeginBlock();
- info.bodyBlock = isInnermost ? bodyBlock : createNextBeginBlock();
- info.exitBlock = isOutermost ? exitBlock : createNextExitBlock();
- if (info.maskExpr)
- info.maskBlock = createNextBeginBlock();
- }
- }
- }
-
- // Increment loop begin code. (Infinite/while code was already generated.)
- if (!infiniteLoop && !whileCondition)
- genFIRIncrementLoopBegin(incrementLoopNestInfo);
-
- // Loop body code.
- auto iter = eval.getNestedEvaluations().begin();
- for (auto end = --eval.getNestedEvaluations().end(); iter != end; ++iter)
- genFIR(*iter, unstructuredContext);
-
- // An EndDoStmt in unstructured code may start a new block.
- Fortran::lower::pft::Evaluation &endDoEval = *iter;
- assert(endDoEval.getIf<Fortran::parser::EndDoStmt>() && "no enddo stmt");
- if (unstructuredContext)
- maybeStartBlock(endDoEval.block);
-
- // Loop end code.
- if (infiniteLoop || whileCondition)
- genBranch(headerBlock);
- else
- genFIRIncrementLoopEnd(incrementLoopNestInfo);
+void FirConverter::genFIR(const Fortran::parser::PrintStmt &stmt) {
+ genPrintStatement(*this, stmt);
+}
- // This call may generate a branch in some contexts.
- genFIR(endDoEval, unstructuredContext);
+void FirConverter::genFIR(const Fortran::parser::ReadStmt &stmt) {
+ mlir::Value iostat = genReadStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.controls, iostat);
}
-/// Generate FIR to evaluate loop control values (lower, upper and step).
-mlir::Value FirConverter::genControlValue(const Fortran::lower::SomeExpr *expr,
- const IncrementLoopInfo &info,
- bool *isConst) {
+void FirConverter::genFIR(const Fortran::parser::ReturnStmt &stmt) {
+ Fortran::lower::pft::FunctionLikeUnit *funit = getEval().getOwningProcedure();
+ assert(funit && "not inside main program, function or subroutine");
+ for (auto it = activeConstructStack.rbegin(),
+ rend = activeConstructStack.rend();
+ it != rend; ++it) {
+ it->stmtCtx.finalizeAndKeep();
+ }
+ if (funit->isMainProgram()) {
+ bridge.fctCtx().finalizeAndKeep();
+ genExitRoutine();
+ return;
+ }
mlir::Location loc = toLocation();
- mlir::Type controlType = info.isStructured() ? builder->getIndexType()
- : info.getLoopVariableType();
- Fortran::lower::StatementContext stmtCtx;
- if (expr) {
- if (isConst)
- *isConst = Fortran::evaluate::IsConstantExpr(*expr);
- return builder->createConvert(loc, controlType,
- createFIRExpr(loc, expr, stmtCtx));
+ if (stmt.v) {
+ // Alternate return statement - If this is a subroutine where some
+ // alternate entries have alternate returns, but the active entry point
+ // does not, ignore the alternate return value. Otherwise, assign it
+ // to the compiler-generated result variable.
+ const Fortran::semantics::Symbol &symbol = funit->getSubprogramSymbol();
+ if (Fortran::semantics::HasAlternateReturns(symbol)) {
+ Fortran::lower::StatementContext stmtCtx;
+ const Fortran::lower::SomeExpr *expr =
+ Fortran::semantics::GetExpr(*stmt.v);
+ assert(expr && "missing alternate return expression");
+ mlir::Value altReturnIndex = builder->createConvert(
+ loc, builder->getIndexType(), createFIRExpr(loc, expr, stmtCtx));
+ builder->create<fir::StoreOp>(loc, altReturnIndex,
+ getAltReturnResult(symbol));
+ }
+ }
+ // Branch to the last block of the SUBROUTINE, which has the actual return.
+ if (!funit->finalBlock) {
+ mlir::OpBuilder::InsertPoint insPt = builder->saveInsertionPoint();
+ Fortran::lower::setInsertionPointAfterOpenACCLoopIfInside(*builder);
+ funit->finalBlock = builder->createBlock(&builder->getRegion());
+ builder->restoreInsertionPoint(insPt);
}
- if (isConst)
- *isConst = true;
- if (info.hasRealControl)
- return builder->createRealConstant(loc, controlType, 1u);
- return builder->createIntegerConstant(loc, controlType, 1); // step
+ if (Fortran::lower::isInOpenACCLoop(*builder))
+ Fortran::lower::genEarlyReturnInOpenACCLoop(*builder, loc);
+ else
+ builder->create<mlir::cf::BranchOp>(loc, funit->finalBlock);
}
-/// Generate FIR to begin a structured or unstructured increment loop nest.
-void FirConverter::genFIRIncrementLoopBegin(
- IncrementLoopNestInfo &incrementLoopNestInfo) {
- assert(!incrementLoopNestInfo.empty() && "empty loop nest");
- mlir::Location loc = toLocation();
- for (IncrementLoopInfo &info : incrementLoopNestInfo) {
- info.loopVariable =
- genLoopVariableAddress(loc, *info.loopVariableSym, info.isUnordered);
- mlir::Value lowerValue = genControlValue(info.lowerExpr, info);
- mlir::Value upperValue = genControlValue(info.upperExpr, info);
- bool isConst = true;
- mlir::Value stepValue = genControlValue(
- info.stepExpr, info, info.isStructured() ? nullptr : &isConst);
- // Use a temp variable for unstructured loops with non-const step.
- if (!isConst) {
- info.stepVariable = builder->createTemporary(loc, stepValue.getType());
- builder->create<fir::StoreOp>(loc, stepValue, info.stepVariable);
- }
+void FirConverter::genFIR(const Fortran::parser::RewindStmt &stmt) {
+ mlir::Value iostat = genRewindStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.v, iostat);
+}
- // Structured loop - generate fir.do_loop.
- if (info.isStructured()) {
- mlir::Type loopVarType = info.getLoopVariableType();
- mlir::Value loopValue;
- if (info.isUnordered) {
- // The loop variable value is explicitly updated.
- info.doLoop = builder->create<fir::DoLoopOp>(
- loc, lowerValue, upperValue, stepValue, /*unordered=*/true);
- builder->setInsertionPointToStart(info.doLoop.getBody());
- loopValue = builder->createConvert(loc, loopVarType,
- info.doLoop.getInductionVar());
- } else {
- // The loop variable is a doLoop op argument.
- info.doLoop = builder->create<fir::DoLoopOp>(
- loc, lowerValue, upperValue, stepValue, /*unordered=*/false,
- /*finalCountValue=*/true,
- builder->createConvert(loc, loopVarType, lowerValue));
- builder->setInsertionPointToStart(info.doLoop.getBody());
- loopValue = info.doLoop.getRegionIterArgs()[0];
- }
- // Update the loop variable value in case it has non-index references.
- builder->create<fir::StoreOp>(loc, loopValue, info.loopVariable);
- if (info.maskExpr) {
- Fortran::lower::StatementContext stmtCtx;
- mlir::Value maskCond = createFIRExpr(loc, info.maskExpr, stmtCtx);
- stmtCtx.finalizeAndReset();
- mlir::Value maskCondCast =
- builder->createConvert(loc, builder->getI1Type(), maskCond);
- auto ifOp = builder->create<fir::IfOp>(loc, maskCondCast,
- /*withElseRegion=*/false);
- builder->setInsertionPointToStart(&ifOp.getThenRegion().front());
- }
- if (info.hasLocalitySpecs())
- handleLocalitySpecs(info);
+/// Generate FIR for a SELECT CASE statement.
+/// The selector may have CHARACTER, INTEGER, or LOGICAL type.
+void FirConverter::genFIR(const Fortran::parser::SelectCaseStmt &stmt) {
+ Fortran::lower::pft::Evaluation &eval = getEval();
+ Fortran::lower::pft::Evaluation *parentConstruct = eval.parentConstruct;
+ assert(!activeConstructStack.empty() &&
+ &activeConstructStack.back().eval == parentConstruct &&
+ "select case construct is not active");
+ Fortran::lower::StatementContext &stmtCtx =
+ activeConstructStack.back().stmtCtx;
+ const Fortran::lower::SomeExpr *expr = Fortran::semantics::GetExpr(
+ std::get<Fortran::parser::Scalar<Fortran::parser::Expr>>(stmt.t));
+ bool isCharSelector = isCharacterCategory(expr->GetType()->category());
+ bool isLogicalSelector = isLogicalCategory(expr->GetType()->category());
+ mlir::MLIRContext *context = builder->getContext();
+ mlir::Location loc = toLocation();
+ auto charValue = [&](const Fortran::lower::SomeExpr *expr) {
+ fir::ExtendedValue exv = genExprAddr(*expr, stmtCtx, &loc);
+ return exv.match(
+ [&](const fir::CharBoxValue &cbv) {
+ return fir::factory::CharacterExprHelper{*builder, loc}
+ .createEmboxChar(cbv.getAddr(), cbv.getLen());
+ },
+ [&](auto) {
+ fir::emitFatalError(loc, "not a character");
+ return mlir::Value{};
+ });
+ };
+ mlir::Value selector;
+ if (isCharSelector) {
+ selector = charValue(expr);
+ } else {
+ selector = createFIRExpr(loc, expr, stmtCtx);
+ if (isLogicalSelector)
+ selector = builder->createConvert(loc, builder->getI1Type(), selector);
+ }
+ mlir::Type selectType = selector.getType();
+ llvm::SmallVector<mlir::Attribute> attrList;
+ llvm::SmallVector<mlir::Value> valueList;
+ llvm::SmallVector<mlir::Block *> blockList;
+ mlir::Block *defaultBlock = parentConstruct->constructExit->block;
+ using CaseValue = Fortran::parser::Scalar<Fortran::parser::ConstantExpr>;
+ auto addValue = [&](const CaseValue &caseValue) {
+ const Fortran::lower::SomeExpr *expr =
+ Fortran::semantics::GetExpr(caseValue.thing);
+ if (isCharSelector)
+ valueList.push_back(charValue(expr));
+ else if (isLogicalSelector)
+ valueList.push_back(builder->createConvert(
+ loc, selectType, createFIRExpr(toLocation(), expr, stmtCtx)));
+ else
+ valueList.push_back(builder->createIntegerConstant(
+ loc, selectType, *Fortran::evaluate::ToInt64(*expr)));
+ };
+ for (Fortran::lower::pft::Evaluation *e = eval.controlSuccessor; e;
+ e = e->controlSuccessor) {
+ const auto &caseStmt = e->getIf<Fortran::parser::CaseStmt>();
+ assert(e->block && "missing CaseStmt block");
+ const auto &caseSelector =
+ std::get<Fortran::parser::CaseSelector>(caseStmt->t);
+ const auto *caseValueRangeList =
+ std::get_if<std::list<Fortran::parser::CaseValueRange>>(
+ &caseSelector.u);
+ if (!caseValueRangeList) {
+ defaultBlock = e->block;
continue;
}
+ for (const Fortran::parser::CaseValueRange &caseValueRange :
+ *caseValueRangeList) {
+ blockList.push_back(e->block);
+ if (const auto *caseValue = std::get_if<CaseValue>(&caseValueRange.u)) {
+ attrList.push_back(fir::PointIntervalAttr::get(context));
+ addValue(*caseValue);
+ continue;
+ }
+ const auto &caseRange =
+ std::get<Fortran::parser::CaseValueRange::Range>(caseValueRange.u);
+ if (caseRange.lower && caseRange.upper) {
+ attrList.push_back(fir::ClosedIntervalAttr::get(context));
+ addValue(*caseRange.lower);
+ addValue(*caseRange.upper);
+ } else if (caseRange.lower) {
+ attrList.push_back(fir::LowerBoundAttr::get(context));
+ addValue(*caseRange.lower);
+ } else {
+ attrList.push_back(fir::UpperBoundAttr::get(context));
+ addValue(*caseRange.upper);
+ }
+ }
+ }
+ // Skip a logical default block that can never be referenced.
+ if (isLogicalSelector && attrList.size() == 2)
+ defaultBlock = parentConstruct->constructExit->block;
+ attrList.push_back(mlir::UnitAttr::get(context));
+ blockList.push_back(defaultBlock);
- // Unstructured loop preheader - initialize tripVariable and loopVariable.
- mlir::Value tripCount;
- if (info.hasRealControl) {
- auto diff1 =
- builder->create<mlir::arith::SubFOp>(loc, upperValue, lowerValue);
- auto diff2 = builder->create<mlir::arith::AddFOp>(loc, diff1, stepValue);
- tripCount = builder->create<mlir::arith::DivFOp>(loc, diff2, stepValue);
- tripCount =
- builder->createConvert(loc, builder->getIndexType(), tripCount);
- } else {
- auto diff1 =
- builder->create<mlir::arith::SubIOp>(loc, upperValue, lowerValue);
- auto diff2 = builder->create<mlir::arith::AddIOp>(loc, diff1, stepValue);
- tripCount = builder->create<mlir::arith::DivSIOp>(loc, diff2, stepValue);
+ // Generate a fir::SelectCaseOp. Explicit branch code is better for the
+ // LOGICAL type. The CHARACTER type does not have downstream SelectOp
+ // support. The -no-structured-fir option can be used to force generation
+ // of INTEGER type branch code.
+ if (!isLogicalSelector && !isCharSelector &&
+ !getEval().forceAsUnstructured()) {
+ // The selector is in an ssa register. Any temps that may have been
+ // generated while evaluating it can be cleaned up now.
+ stmtCtx.finalizeAndReset();
+ builder->create<fir::SelectCaseOp>(loc, selector, attrList, valueList,
+ blockList);
+ return;
+ }
+
+ // Generate a sequence of case value comparisons and branches.
+ auto caseValue = valueList.begin();
+ auto caseBlock = blockList.begin();
+ for (mlir::Attribute attr : attrList) {
+ if (attr.isa<mlir::UnitAttr>()) {
+ genBranch(*caseBlock++);
+ break;
}
- if (forceLoopToExecuteOnce) { // minimum tripCount is 1
- mlir::Value one =
- builder->createIntegerConstant(loc, tripCount.getType(), 1);
- auto cond = builder->create<mlir::arith::CmpIOp>(
- loc, mlir::arith::CmpIPredicate::slt, tripCount, one);
- tripCount =
- builder->create<mlir::arith::SelectOp>(loc, cond, one, tripCount);
+ auto genCond = [&](mlir::Value rhs,
+ mlir::arith::CmpIPredicate pred) -> mlir::Value {
+ if (!isCharSelector)
+ return builder->create<mlir::arith::CmpIOp>(loc, pred, selector, rhs);
+ fir::factory::CharacterExprHelper charHelper{*builder, loc};
+ std::pair<mlir::Value, mlir::Value> lhsVal =
+ charHelper.createUnboxChar(selector);
+ std::pair<mlir::Value, mlir::Value> rhsVal =
+ charHelper.createUnboxChar(rhs);
+ return fir::runtime::genCharCompare(*builder, loc, pred, lhsVal.first,
+ lhsVal.second, rhsVal.first,
+ rhsVal.second);
+ };
+ mlir::Block *newBlock = insertBlock(*caseBlock);
+ if (attr.isa<fir::ClosedIntervalAttr>()) {
+ mlir::Block *newBlock2 = insertBlock(*caseBlock);
+ mlir::Value cond = genCond(*caseValue++, mlir::arith::CmpIPredicate::sge);
+ genConditionalBranch(cond, newBlock, newBlock2);
+ builder->setInsertionPointToEnd(newBlock);
+ mlir::Value cond2 =
+ genCond(*caseValue++, mlir::arith::CmpIPredicate::sle);
+ genConditionalBranch(cond2, *caseBlock++, newBlock2);
+ builder->setInsertionPointToEnd(newBlock2);
+ continue;
}
- info.tripVariable = builder->createTemporary(loc, tripCount.getType());
- builder->create<fir::StoreOp>(loc, tripCount, info.tripVariable);
- builder->create<fir::StoreOp>(loc, lowerValue, info.loopVariable);
-
- // Unstructured loop header - generate loop condition and mask.
- // Note - Currently there is no way to tag a loop as a concurrent loop.
- startBlock(info.headerBlock);
- tripCount = builder->create<fir::LoadOp>(loc, info.tripVariable);
- mlir::Value zero =
- builder->createIntegerConstant(loc, tripCount.getType(), 0);
- auto cond = builder->create<mlir::arith::CmpIOp>(
- loc, mlir::arith::CmpIPredicate::sgt, tripCount, zero);
- if (info.maskExpr) {
- genConditionalBranch(cond, info.maskBlock, info.exitBlock);
- startBlock(info.maskBlock);
- mlir::Block *latchBlock = getEval().getLastNestedEvaluation().block;
- assert(latchBlock && "missing masked concurrent loop latch block");
- Fortran::lower::StatementContext stmtCtx;
- mlir::Value maskCond = createFIRExpr(loc, info.maskExpr, stmtCtx);
- stmtCtx.finalizeAndReset();
- genConditionalBranch(maskCond, info.bodyBlock, latchBlock);
+ mlir::arith::CmpIPredicate pred;
+ if (attr.isa<fir::PointIntervalAttr>()) {
+ pred = mlir::arith::CmpIPredicate::eq;
+ } else if (attr.isa<fir::LowerBoundAttr>()) {
+ pred = mlir::arith::CmpIPredicate::sge;
} else {
- genConditionalBranch(cond, info.bodyBlock, info.exitBlock);
- if (&info != &incrementLoopNestInfo.back()) // not innermost
- startBlock(info.bodyBlock); // preheader block of enclosed dimension
- }
- if (info.hasLocalitySpecs()) {
- mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
- builder->setInsertionPointToStart(info.bodyBlock);
- handleLocalitySpecs(info);
- builder->restoreInsertionPoint(insertPt);
+ assert(attr.isa<fir::UpperBoundAttr>() && "unexpected predicate");
+ pred = mlir::arith::CmpIPredicate::sle;
}
+ mlir::Value cond = genCond(*caseValue++, pred);
+ genConditionalBranch(cond, *caseBlock++, newBlock);
+ builder->setInsertionPointToEnd(newBlock);
}
+ assert(caseValue == valueList.end() && caseBlock == blockList.end() &&
+ "select case list mismatch");
}
-/// Generate FIR to end a structured or unstructured increment loop nest.
-void FirConverter::genFIRIncrementLoopEnd(
- IncrementLoopNestInfo &incrementLoopNestInfo) {
- assert(!incrementLoopNestInfo.empty() && "empty loop nest");
- mlir::Location loc = toLocation();
- for (auto it = incrementLoopNestInfo.rbegin(),
- rend = incrementLoopNestInfo.rend();
- it != rend; ++it) {
- IncrementLoopInfo &info = *it;
- if (info.isStructured()) {
- // End fir.do_loop.
- if (info.isUnordered) {
- builder->setInsertionPointAfter(info.doLoop);
- continue;
- }
- // Decrement tripVariable.
- builder->setInsertionPointToEnd(info.doLoop.getBody());
- llvm::SmallVector<mlir::Value, 2> results;
- results.push_back(builder->create<mlir::arith::AddIOp>(
- loc, info.doLoop.getInductionVar(), info.doLoop.getStep()));
- // Step loopVariable to help optimizations such as vectorization.
- // Induction variable elimination will clean up as necessary.
- mlir::Value step = builder->createConvert(loc, info.getLoopVariableType(),
- info.doLoop.getStep());
- mlir::Value loopVar =
- builder->create<fir::LoadOp>(loc, info.loopVariable);
- results.push_back(
- builder->create<mlir::arith::AddIOp>(loc, loopVar, step));
- builder->create<fir::ResultOp>(loc, results);
- builder->setInsertionPointAfter(info.doLoop);
- // The loop control variable may be used after the loop.
- builder->create<fir::StoreOp>(loc, info.doLoop.getResult(1),
- info.loopVariable);
- continue;
- }
+void FirConverter::genFIR(const Fortran::parser::SelectRankCaseStmt &) {
+ TODO(toLocation(), "coarray: SelectRankCaseStmt");
+}
- // Unstructured loop - decrement tripVariable and step loopVariable.
- mlir::Value tripCount =
- builder->create<fir::LoadOp>(loc, info.tripVariable);
- mlir::Value one =
- builder->createIntegerConstant(loc, tripCount.getType(), 1);
- tripCount = builder->create<mlir::arith::SubIOp>(loc, tripCount, one);
- builder->create<fir::StoreOp>(loc, tripCount, info.tripVariable);
- mlir::Value value = builder->create<fir::LoadOp>(loc, info.loopVariable);
- mlir::Value step;
- if (info.stepVariable)
- step = builder->create<fir::LoadOp>(loc, info.stepVariable);
- else
- step = genControlValue(info.stepExpr, info);
- if (info.hasRealControl)
- value = builder->create<mlir::arith::AddFOp>(loc, value, step);
- else
- value = builder->create<mlir::arith::AddIOp>(loc, value, step);
- builder->create<fir::StoreOp>(loc, value, info.loopVariable);
+void FirConverter::genFIR(
+ const Fortran::parser::SelectRankConstruct &selectRankConstruct) {
+ setCurrentPositionAt(selectRankConstruct);
+ TODO(toLocation(), "coarray: SelectRankConstruct");
+}
- genBranch(info.headerBlock);
- if (&info != &incrementLoopNestInfo.front()) // not outermost
- startBlock(info.exitBlock); // latch block of enclosing dimension
- }
+void FirConverter::genFIR(const Fortran::parser::SelectRankStmt &) {
+ TODO(toLocation(), "coarray: SelectRankStmt");
}
-/// Generate structured or unstructured FIR for an IF construct.
-/// The initial statement may be either an IfStmt or an IfThenStmt.
-void FirConverter::genFIR(const Fortran::parser::IfConstruct &) {
+void FirConverter::genFIR(
+ const Fortran::parser::SelectTypeConstruct &selectTypeConstruct) {
mlir::Location loc = toLocation();
- Fortran::lower::pft::Evaluation &eval = getEval();
- if (eval.lowerAsStructured()) {
- // Structured fir.if nest.
- fir::IfOp topIfOp, currentIfOp;
- for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
- auto genIfOp = [&](mlir::Value cond) {
- auto ifOp = builder->create<fir::IfOp>(loc, cond, /*withElse=*/true);
- builder->setInsertionPointToStart(&ifOp.getThenRegion().front());
- return ifOp;
- };
- if (auto *s = e.getIf<Fortran::parser::IfThenStmt>()) {
- topIfOp = currentIfOp = genIfOp(genIfCondition(s, e.negateCondition));
- } else if (auto *s = e.getIf<Fortran::parser::IfStmt>()) {
- topIfOp = currentIfOp = genIfOp(genIfCondition(s, e.negateCondition));
- } else if (auto *s = e.getIf<Fortran::parser::ElseIfStmt>()) {
- builder->setInsertionPointToStart(¤tIfOp.getElseRegion().front());
- currentIfOp = genIfOp(genIfCondition(s));
- } else if (e.isA<Fortran::parser::ElseStmt>()) {
- builder->setInsertionPointToStart(¤tIfOp.getElseRegion().front());
- } else if (e.isA<Fortran::parser::EndIfStmt>()) {
- builder->setInsertionPointAfter(topIfOp);
- genFIR(e, /*unstructuredContext=*/false); // may generate branch
- } else {
- genFIR(e, /*unstructuredContext=*/false);
- }
- }
- return;
- }
+ mlir::MLIRContext *context = builder->getContext();
+ Fortran::lower::StatementContext stmtCtx;
+ fir::ExtendedValue selector;
+ llvm::SmallVector<mlir::Attribute> attrList;
+ llvm::SmallVector<mlir::Block *> blockList;
+ unsigned typeGuardIdx = 0;
+ std::size_t defaultAttrPos = std::numeric_limits<size_t>::max();
+ bool hasLocalScope = false;
+ llvm::SmallVector<const Fortran::semantics::Scope *> typeCaseScopes;
- // Unstructured branch sequence.
- for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
- auto genIfBranch = [&](mlir::Value cond) {
- if (e.lexicalSuccessor == e.controlSuccessor) // empty block -> exit
- genConditionalBranch(cond, e.parentConstruct->constructExit,
- e.controlSuccessor);
- else // non-empty block
- genConditionalBranch(cond, e.lexicalSuccessor, e.controlSuccessor);
- };
- if (auto *s = e.getIf<Fortran::parser::IfThenStmt>()) {
- maybeStartBlock(e.block);
- genIfBranch(genIfCondition(s, e.negateCondition));
- } else if (auto *s = e.getIf<Fortran::parser::IfStmt>()) {
- maybeStartBlock(e.block);
- genIfBranch(genIfCondition(s, e.negateCondition));
- } else if (auto *s = e.getIf<Fortran::parser::ElseIfStmt>()) {
- startBlock(e.block);
- genIfBranch(genIfCondition(s));
- } else {
- genFIR(e);
- }
+ const auto &typeCaseList =
+ std::get<std::list<Fortran::parser::SelectTypeConstruct::TypeCase>>(
+ selectTypeConstruct.t);
+ for (const auto &typeCase : typeCaseList) {
+ const auto &stmt =
+ std::get<Fortran::parser::Statement<Fortran::parser::TypeGuardStmt>>(
+ typeCase.t);
+ const Fortran::semantics::Scope &scope =
+ bridge.getSemanticsContext().FindScope(stmt.source);
+ typeCaseScopes.push_back(&scope);
}
-}
-void FirConverter::genFIR(const Fortran::parser::CaseConstruct &) {
- Fortran::lower::pft::Evaluation &eval = getEval();
- Fortran::lower::StatementContext stmtCtx;
- pushActiveConstruct(eval, stmtCtx);
- for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
- if (e.getIf<Fortran::parser::EndSelectStmt>())
- maybeStartBlock(e.block);
- else
- genFIR(e);
- }
- popActiveConstruct();
-}
+ pushActiveConstruct(getEval(), stmtCtx);
+ for (Fortran::lower::pft::Evaluation &eval :
+ getEval().getNestedEvaluations()) {
+ if (auto *selectTypeStmt = eval.getIf<Fortran::parser::SelectTypeStmt>()) {
+ // A genFIR(SelectTypeStmt) call would have unwanted side effects.
+ maybeStartBlock(eval.block);
+ // Retrieve the selector
+ const auto &s = std::get<Fortran::parser::Selector>(selectTypeStmt->t);
+ if (const auto *v = std::get_if<Fortran::parser::Variable>(&s.u))
+ selector = genExprBox(loc, *Fortran::semantics::GetExpr(*v), stmtCtx);
+ else if (const auto *e = std::get_if<Fortran::parser::Expr>(&s.u))
+ selector = genExprBox(loc, *Fortran::semantics::GetExpr(*e), stmtCtx);
-/// Force the binding of an explicit symbol. This is used to bind and re-bind
-/// a concurrent control symbol to its value.
-void FirConverter::forceControlVariableBinding(
- const Fortran::semantics::Symbol *sym, mlir::Value inducVar) {
- mlir::Location loc = toLocation();
- assert(sym && "There must be a symbol to bind");
- mlir::Type toTy = genType(*sym);
- // FIXME: this should be a "per iteration" temporary.
- mlir::Value tmp = builder->createTemporary(
- loc, toTy, toStringRef(sym->name()),
- llvm::ArrayRef<mlir::NamedAttribute>{fir::getAdaptToByRefAttr(*builder)});
- mlir::Value cast = builder->createConvert(loc, toTy, inducVar);
- builder->create<fir::StoreOp>(loc, cast, tmp);
- addSymbol(*sym, tmp, /*force=*/true);
-}
+ // Going through the controlSuccessor first to create the
+ // fir.select_type operation.
+ mlir::Block *defaultBlock = eval.parentConstruct->constructExit->block;
+ for (Fortran::lower::pft::Evaluation *e = eval.controlSuccessor; e;
+ e = e->controlSuccessor) {
+ const auto &typeGuardStmt = e->getIf<Fortran::parser::TypeGuardStmt>();
+ const auto &guard =
+ std::get<Fortran::parser::TypeGuardStmt::Guard>(typeGuardStmt->t);
+ assert(e->block && "missing TypeGuardStmt block");
+ // CLASS DEFAULT
+ if (std::holds_alternative<Fortran::parser::Default>(guard.u)) {
+ defaultBlock = e->block;
+ // Keep track of the actual position of the CLASS DEFAULT type guard
+ // in the SELECT TYPE construct.
+ defaultAttrPos = attrList.size();
+ continue;
+ }
-/// Process a concurrent header for a FORALL. (Concurrent headers for DO
-/// CONCURRENT loops are lowered elsewhere.)
-void FirConverter::genFIR(const Fortran::parser::ConcurrentHeader &header) {
- llvm::SmallVector<mlir::Value> lows;
- llvm::SmallVector<mlir::Value> highs;
- llvm::SmallVector<mlir::Value> steps;
- if (explicitIterSpace.isOutermostForall()) {
- // For the outermost forall, we evaluate the bounds expressions once.
- // Contrastingly, if this forall is nested, the bounds expressions are
- // assumed to be pure, possibly dependent on outer concurrent control
- // variables, possibly variant with respect to arguments, and will be
- // re-evaluated.
- mlir::Location loc = toLocation();
- mlir::Type idxTy = builder->getIndexType();
- Fortran::lower::StatementContext &stmtCtx = explicitIterSpace.stmtContext();
- auto lowerExpr = [&](auto &e) {
- return fir::getBase(genExprValue(e, stmtCtx));
- };
- for (const Fortran::parser::ConcurrentControl &ctrl :
- std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t)) {
- const Fortran::lower::SomeExpr *lo =
- Fortran::semantics::GetExpr(std::get<1>(ctrl.t));
- const Fortran::lower::SomeExpr *hi =
- Fortran::semantics::GetExpr(std::get<2>(ctrl.t));
- auto &optStep =
- std::get<std::optional<Fortran::parser::ScalarIntExpr>>(ctrl.t);
- lows.push_back(builder->createConvert(loc, idxTy, lowerExpr(*lo)));
- highs.push_back(builder->createConvert(loc, idxTy, lowerExpr(*hi)));
- steps.push_back(
- optStep.has_value()
- ? builder->createConvert(
- loc, idxTy,
- lowerExpr(*Fortran::semantics::GetExpr(*optStep)))
- : builder->createIntegerConstant(loc, idxTy, 1));
- }
- }
- auto lambda = [&, lows, highs, steps]() {
- // Create our iteration space from the header spec.
- mlir::Location loc = toLocation();
- mlir::Type idxTy = builder->getIndexType();
- llvm::SmallVector<fir::DoLoopOp> loops;
- Fortran::lower::StatementContext &stmtCtx = explicitIterSpace.stmtContext();
- auto lowerExpr = [&](auto &e) {
- return fir::getBase(genExprValue(e, stmtCtx));
- };
- const bool outermost = !lows.empty();
- std::size_t headerIndex = 0;
- for (const Fortran::parser::ConcurrentControl &ctrl :
- std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t)) {
- const Fortran::semantics::Symbol *ctrlVar =
- std::get<Fortran::parser::Name>(ctrl.t).symbol;
- mlir::Value lb;
- mlir::Value ub;
- mlir::Value by;
- if (outermost) {
- assert(headerIndex < lows.size());
- if (headerIndex == 0)
- explicitIterSpace.resetInnerArgs();
- lb = lows[headerIndex];
- ub = highs[headerIndex];
- by = steps[headerIndex++];
- } else {
- const Fortran::lower::SomeExpr *lo =
- Fortran::semantics::GetExpr(std::get<1>(ctrl.t));
- const Fortran::lower::SomeExpr *hi =
- Fortran::semantics::GetExpr(std::get<2>(ctrl.t));
- auto &optStep =
- std::get<std::optional<Fortran::parser::ScalarIntExpr>>(ctrl.t);
- lb = builder->createConvert(loc, idxTy, lowerExpr(*lo));
- ub = builder->createConvert(loc, idxTy, lowerExpr(*hi));
- by = optStep.has_value()
- ? builder->createConvert(
- loc, idxTy,
- lowerExpr(*Fortran::semantics::GetExpr(*optStep)))
- : builder->createIntegerConstant(loc, idxTy, 1);
+ blockList.push_back(e->block);
+ if (const auto *typeSpec =
+ std::get_if<Fortran::parser::TypeSpec>(&guard.u)) {
+ // TYPE IS
+ mlir::Type ty;
+ if (std::holds_alternative<Fortran::parser::IntrinsicTypeSpec>(
+ typeSpec->u)) {
+ const Fortran::semantics::IntrinsicTypeSpec *intrinsic =
+ typeSpec->declTypeSpec->AsIntrinsic();
+ int kind =
+ Fortran::evaluate::ToInt64(intrinsic->kind()).value_or(kind);
+ llvm::SmallVector<Fortran::lower::LenParameterTy> params;
+ ty = genType(intrinsic->category(), kind, params);
+ } else {
+ const Fortran::semantics::DerivedTypeSpec *derived =
+ typeSpec->declTypeSpec->AsDerived();
+ ty = genType(*derived);
+ }
+ attrList.push_back(fir::ExactTypeAttr::get(ty));
+ } else if (const auto *derived =
+ std::get_if<Fortran::parser::DerivedTypeSpec>(
+ &guard.u)) {
+ // CLASS IS
+ assert(derived->derivedTypeSpec && "derived type spec is null");
+ mlir::Type ty = genType(*(derived->derivedTypeSpec));
+ attrList.push_back(fir::SubclassAttr::get(ty));
+ }
}
- auto lp = builder->create<fir::DoLoopOp>(
- loc, lb, ub, by, /*unordered=*/true,
- /*finalCount=*/false, explicitIterSpace.getInnerArgs());
- if ((!loops.empty() || !outermost) && !lp.getRegionIterArgs().empty())
- builder->create<fir::ResultOp>(loc, lp.getResults());
- explicitIterSpace.setInnerArgs(lp.getRegionIterArgs());
- builder->setInsertionPointToStart(lp.getBody());
- forceControlVariableBinding(ctrlVar, lp.getInductionVar());
- loops.push_back(lp);
- }
- if (outermost)
- explicitIterSpace.setOuterLoop(loops[0]);
- explicitIterSpace.appendLoops(loops);
- if (const auto &mask =
- std::get<std::optional<Fortran::parser::ScalarLogicalExpr>>(
- header.t);
- mask.has_value()) {
- mlir::Type i1Ty = builder->getI1Type();
- fir::ExtendedValue maskExv =
- genExprValue(*Fortran::semantics::GetExpr(mask.value()), stmtCtx);
- mlir::Value cond =
- builder->createConvert(loc, i1Ty, fir::getBase(maskExv));
- auto ifOp = builder->create<fir::IfOp>(
- loc, explicitIterSpace.innerArgTypes(), cond,
- /*withElseRegion=*/true);
- builder->create<fir::ResultOp>(loc, ifOp.getResults());
- builder->setInsertionPointToStart(&ifOp.getElseRegion().front());
- builder->create<fir::ResultOp>(loc, explicitIterSpace.getInnerArgs());
- builder->setInsertionPointToStart(&ifOp.getThenRegion().front());
+ attrList.push_back(mlir::UnitAttr::get(context));
+ blockList.push_back(defaultBlock);
+ builder->create<fir::SelectTypeOp>(loc, fir::getBase(selector), attrList,
+ blockList);
+
+ // If the actual position of CLASS DEFAULT type guard is not the last
+ // one, it needs to be put back at its correct position for the rest of
+ // the processing. TypeGuardStmt are processed in the same order they
+ // appear in the Fortran code.
+ if (defaultAttrPos < attrList.size() - 1) {
+ auto attrIt = attrList.begin();
+ attrIt = attrIt + defaultAttrPos;
+ auto blockIt = blockList.begin();
+ blockIt = blockIt + defaultAttrPos;
+ attrList.insert(attrIt, mlir::UnitAttr::get(context));
+ blockList.insert(blockIt, defaultBlock);
+ attrList.pop_back();
+ blockList.pop_back();
+ }
+ } else if (auto *typeGuardStmt =
+ eval.getIf<Fortran::parser::TypeGuardStmt>()) {
+ // Map the type guard local symbol for the selector to a more precise
+ // typed entity in the TypeGuardStmt when necessary.
+ genFIR(eval);
+ const auto &guard =
+ std::get<Fortran::parser::TypeGuardStmt::Guard>(typeGuardStmt->t);
+ if (hasLocalScope)
+ localSymbols.popScope();
+ localSymbols.pushScope();
+ hasLocalScope = true;
+ assert(attrList.size() >= typeGuardIdx && "TypeGuard attribute missing");
+ mlir::Attribute typeGuardAttr = attrList[typeGuardIdx];
+ mlir::Block *typeGuardBlock = blockList[typeGuardIdx];
+ mlir::OpBuilder::InsertPoint crtInsPt = builder->saveInsertionPoint();
+ builder->setInsertionPointToStart(typeGuardBlock);
+
+ auto addAssocEntitySymbol = [&](fir::ExtendedValue exv) {
+ for (auto &symbol : typeCaseScopes[typeGuardIdx]->GetSymbols()) {
+ if (symbol->GetUltimate()
+ .detailsIf<Fortran::semantics::AssocEntityDetails>()) {
+ addSymbol(symbol, exv);
+ break;
+ }
+ }
+ };
+
+ mlir::Type baseTy = fir::getBase(selector).getType();
+ bool isPointer = fir::isPointerType(baseTy);
+ bool isAllocatable = fir::isAllocatableType(baseTy);
+ bool isArray =
+ fir::dyn_cast_ptrOrBoxEleTy(baseTy).isa<fir::SequenceType>();
+ const fir::BoxValue *selectorBox = selector.getBoxOf<fir::BoxValue>();
+ if (std::holds_alternative<Fortran::parser::Default>(guard.u)) {
+ // CLASS DEFAULT
+ addAssocEntitySymbol(selector);
+ } else if (const auto *typeSpec =
+ std::get_if<Fortran::parser::TypeSpec>(&guard.u)) {
+ // TYPE IS
+ fir::ExactTypeAttr attr = typeGuardAttr.dyn_cast<fir::ExactTypeAttr>();
+ mlir::Value exactValue;
+ mlir::Type addrTy = attr.getType();
+ if (isArray) {
+ auto seqTy =
+ fir::dyn_cast_ptrOrBoxEleTy(baseTy).dyn_cast<fir::SequenceType>();
+ addrTy = fir::SequenceType::get(seqTy.getShape(), attr.getType());
+ }
+ if (isPointer)
+ addrTy = fir::PointerType::get(addrTy);
+ if (isAllocatable)
+ addrTy = fir::HeapType::get(addrTy);
+ if (std::holds_alternative<Fortran::parser::IntrinsicTypeSpec>(
+ typeSpec->u)) {
+ mlir::Type refTy = fir::ReferenceType::get(addrTy);
+ if (isPointer || isAllocatable)
+ refTy = addrTy;
+ exactValue = builder->create<fir::BoxAddrOp>(loc, refTy,
+ fir::getBase(selector));
+ const Fortran::semantics::IntrinsicTypeSpec *intrinsic =
+ typeSpec->declTypeSpec->AsIntrinsic();
+ if (isArray) {
+ mlir::Value exact = builder->create<fir::ConvertOp>(
+ loc, fir::BoxType::get(addrTy), fir::getBase(selector));
+ addAssocEntitySymbol(selectorBox->clone(exact));
+ } else if (intrinsic->category() ==
+ Fortran::common::TypeCategory::Character) {
+ auto charTy = attr.getType().dyn_cast<fir::CharacterType>();
+ mlir::Value charLen =
+ fir::factory::CharacterExprHelper(*builder, loc)
+ .readLengthFromBox(fir::getBase(selector), charTy);
+ addAssocEntitySymbol(fir::CharBoxValue(exactValue, charLen));
+ } else {
+ addAssocEntitySymbol(exactValue);
+ }
+ } else if (std::holds_alternative<Fortran::parser::DerivedTypeSpec>(
+ typeSpec->u)) {
+ exactValue = builder->create<fir::ConvertOp>(
+ loc, fir::BoxType::get(addrTy), fir::getBase(selector));
+ addAssocEntitySymbol(selectorBox->clone(exactValue));
+ }
+ } else if (std::holds_alternative<Fortran::parser::DerivedTypeSpec>(
+ guard.u)) {
+ // CLASS IS
+ fir::SubclassAttr attr = typeGuardAttr.dyn_cast<fir::SubclassAttr>();
+ mlir::Type addrTy = attr.getType();
+ if (isArray) {
+ auto seqTy =
+ fir::dyn_cast_ptrOrBoxEleTy(baseTy).dyn_cast<fir::SequenceType>();
+ addrTy = fir::SequenceType::get(seqTy.getShape(), attr.getType());
+ }
+ if (isPointer)
+ addrTy = fir::PointerType::get(addrTy);
+ if (isAllocatable)
+ addrTy = fir::HeapType::get(addrTy);
+ mlir::Type classTy = fir::ClassType::get(addrTy);
+ if (classTy == baseTy) {
+ addAssocEntitySymbol(selector);
+ } else {
+ mlir::Value derived = builder->create<fir::ConvertOp>(
+ loc, classTy, fir::getBase(selector));
+ addAssocEntitySymbol(selectorBox->clone(derived));
+ }
+ }
+ builder->restoreInsertionPoint(crtInsPt);
+ ++typeGuardIdx;
+ } else if (eval.getIf<Fortran::parser::EndSelectStmt>()) {
+ maybeStartBlock(eval.block);
+ if (hasLocalScope)
+ localSymbols.popScope();
+ } else {
+ genFIR(eval);
}
- };
- // Push the lambda to gen the loop nest context.
- explicitIterSpace.pushLoopNest(lambda);
+ }
+ popActiveConstruct();
}
-void FirConverter::genFIR(const Fortran::parser::ForallAssignmentStmt &stmt) {
- std::visit([&](const auto &x) { genFIR(x); }, stmt.u);
+// call FAIL IMAGE in runtime
+// call STOP, ERROR STOP in runtime
+void FirConverter::genFIR(const Fortran::parser::StopStmt &stmt) {
+ genStopStatement(*this, stmt);
}
-void FirConverter::genFIR(const Fortran::parser::EndForallStmt &) {
- if (!lowerToHighLevelFIR())
- cleanupExplicitSpace();
+void FirConverter::genFIR(const Fortran::parser::SyncAllStmt &stmt) {
+ genSyncAllStatement(*this, stmt);
}
-/// Generate FIR for a FORALL statement.
-void FirConverter::genFIR(const Fortran::parser::ForallStmt &stmt) {
- const auto &concurrentHeader =
- std::get<Fortran::common::Indirection<Fortran::parser::ConcurrentHeader>>(
- stmt.t)
- .value();
- if (lowerToHighLevelFIR()) {
- mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
- localSymbols.pushScope();
- genForallNest(concurrentHeader);
- genFIR(std::get<Fortran::parser::UnlabeledStatement<
- Fortran::parser::ForallAssignmentStmt>>(stmt.t)
- .statement);
- localSymbols.popScope();
- builder->restoreInsertionPoint(insertPt);
- return;
- }
- prepareExplicitSpace(stmt);
- genFIR(concurrentHeader);
- genFIR(std::get<Fortran::parser::UnlabeledStatement<
- Fortran::parser::ForallAssignmentStmt>>(stmt.t)
- .statement);
- cleanupExplicitSpace();
+void FirConverter::genFIR(const Fortran::parser::SyncImagesStmt &stmt) {
+ genSyncImagesStatement(*this, stmt);
}
-/// Generate FIR for a FORALL construct.
-void FirConverter::genFIR(const Fortran::parser::ForallConstruct &forall) {
- mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
- if (lowerToHighLevelFIR())
- localSymbols.pushScope();
- else
- prepareExplicitSpace(forall);
- genNestedStatement(
- std::get<
- Fortran::parser::Statement<Fortran::parser::ForallConstructStmt>>(
- forall.t));
- for (const Fortran::parser::ForallBodyConstruct &s :
- std::get<std::list<Fortran::parser::ForallBodyConstruct>>(forall.t)) {
- std::visit(
- Fortran::common::visitors{
- [&](const Fortran::parser::WhereConstruct &b) { genFIR(b); },
- [&](const Fortran::common::Indirection<
- Fortran::parser::ForallConstruct> &b) { genFIR(b.value()); },
- [&](const auto &b) { genNestedStatement(b); }},
- s.u);
- }
- genNestedStatement(
- std::get<Fortran::parser::Statement<Fortran::parser::EndForallStmt>>(
- forall.t));
- if (lowerToHighLevelFIR()) {
- localSymbols.popScope();
- builder->restoreInsertionPoint(insertPt);
- }
+void FirConverter::genFIR(const Fortran::parser::SyncMemoryStmt &stmt) {
+ genSyncMemoryStatement(*this, stmt);
}
-/// Lower the concurrent header specification.
-void FirConverter::genFIR(const Fortran::parser::ForallConstructStmt &stmt) {
- const auto &concurrentHeader =
- std::get<Fortran::common::Indirection<Fortran::parser::ConcurrentHeader>>(
- stmt.t)
- .value();
- if (lowerToHighLevelFIR())
- genForallNest(concurrentHeader);
- else
- genFIR(concurrentHeader);
+void FirConverter::genFIR(const Fortran::parser::SyncTeamStmt &stmt) {
+ genSyncTeamStatement(*this, stmt);
}
-/// Generate hlfir.forall and hlfir.forall_mask nest given a Forall
-/// concurrent header
-void FirConverter::genForallNest(
- const Fortran::parser::ConcurrentHeader &header) {
- mlir::Location loc = getCurrentLocation();
- const bool isOutterForall = !isInsideHlfirForallOrWhere();
- hlfir::ForallOp outerForall;
- auto evaluateControl = [&](const auto &parserExpr, mlir::Region ®ion,
- bool isMask = false) {
- if (region.empty())
- builder->createBlock(®ion);
- Fortran::lower::StatementContext localStmtCtx;
- const Fortran::semantics::SomeExpr *anlalyzedExpr =
- Fortran::semantics::GetExpr(parserExpr);
- assert(anlalyzedExpr && "expression semantics failed");
- // Generate the controls of outer forall outside of the hlfir.forall
- // region. They do not depend on any previous forall indices (C1123) and
- // no assignment has been made yet that could modify their value. This
- // will simplify hlfir.forall analysis because the SSA integer value
- // yielded will obviously not depend on any variable modified by the
- // forall when produced outside of it.
- // This is not done for the mask because it may (and in usual code, does)
- // depend on the forall indices that have just been defined as
- // hlfir.forall block arguments.
- mlir::OpBuilder::InsertPoint innerInsertionPoint;
- if (outerForall && !isMask) {
- innerInsertionPoint = builder->saveInsertionPoint();
- builder->setInsertionPoint(outerForall);
- }
- mlir::Value exprVal =
- fir::getBase(genExprValue(*anlalyzedExpr, localStmtCtx, &loc));
- localStmtCtx.finalizeAndPop();
- if (isMask)
- exprVal = builder->createConvert(loc, builder->getI1Type(), exprVal);
- if (innerInsertionPoint.isSet())
- builder->restoreInsertionPoint(innerInsertionPoint);
- builder->create<hlfir::YieldOp>(loc, exprVal);
- };
- for (const Fortran::parser::ConcurrentControl &control :
- std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t)) {
- auto forallOp = builder->create<hlfir::ForallOp>(loc);
- if (isOutterForall && !outerForall)
- outerForall = forallOp;
- evaluateControl(std::get<1>(control.t), forallOp.getLbRegion());
- evaluateControl(std::get<2>(control.t), forallOp.getUbRegion());
- if (const auto &optionalStep =
- std::get<std::optional<Fortran::parser::ScalarIntExpr>>(control.t))
- evaluateControl(*optionalStep, forallOp.getStepRegion());
- // Create block argument and map it to a symbol via an hlfir.forall_index
- // op (symbols must be mapped to in memory values).
- const Fortran::semantics::Symbol *controlVar =
- std::get<Fortran::parser::Name>(control.t).symbol;
- assert(controlVar && "symbol analysis failed");
- mlir::Type controlVarType = genType(*controlVar);
- mlir::Block *forallBody =
- builder->createBlock(&forallOp.getBody(), {}, {controlVarType}, {loc});
- auto forallIndex = builder->create<hlfir::ForallIndexOp>(
- loc, fir::ReferenceType::get(controlVarType),
- forallBody->getArguments()[0],
- builder->getStringAttr(controlVar->name().ToString()));
- localSymbols.addVariableDefinition(*controlVar, forallIndex,
- /*force=*/true);
- auto end = builder->create<fir::FirEndOp>(loc);
- builder->setInsertionPoint(end);
- }
-
- if (const auto &maskExpr =
- std::get<std::optional<Fortran::parser::ScalarLogicalExpr>>(
- header.t)) {
- // Create hlfir.forall_mask and set insertion point in its body.
- auto forallMaskOp = builder->create<hlfir::ForallMaskOp>(loc);
- evaluateControl(*maskExpr, forallMaskOp.getMaskRegion(), /*isMask=*/true);
- builder->createBlock(&forallMaskOp.getBody());
- auto end = builder->create<fir::FirEndOp>(loc);
- builder->setInsertionPoint(end);
- }
-}
-
-void FirConverter::genFIR(const Fortran::parser::CompilerDirective &) {
- // TODO
+void FirConverter::genFIR(const Fortran::parser::UnlockStmt &stmt) {
+ genUnlockStatement(*this, stmt);
}
-void FirConverter::genFIR(const Fortran::parser::OpenACCConstruct &acc) {
- mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
- localSymbols.pushScope();
- mlir::Value exitCond =
- genOpenACCConstruct(*this, bridge.getSemanticsContext(), getEval(), acc);
- for (Fortran::lower::pft::Evaluation &e : getEval().getNestedEvaluations())
- genFIR(e);
- localSymbols.popScope();
- builder->restoreInsertionPoint(insertPt);
-
- const Fortran::parser::OpenACCLoopConstruct *accLoop =
- std::get_if<Fortran::parser::OpenACCLoopConstruct>(&acc.u);
- if (accLoop && exitCond) {
- Fortran::lower::pft::FunctionLikeUnit *funit =
- getEval().getOwningProcedure();
- assert(funit && "not inside main program, function or subroutine");
- mlir::Block *continueBlock =
- builder->getBlock()->splitBlock(builder->getBlock()->end());
- builder->create<mlir::cf::CondBranchOp>(toLocation(), exitCond,
- funit->finalBlock, continueBlock);
- builder->setInsertionPointToEnd(continueBlock);
- }
+void FirConverter::genFIR(const Fortran::parser::WaitStmt &stmt) {
+ mlir::Value iostat = genWaitStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.v, iostat);
}
-void FirConverter::genFIR(
- const Fortran::parser::OpenACCDeclarativeConstruct &accDecl) {
- genOpenACCDeclarativeConstruct(*this, bridge.getSemanticsContext(),
- bridge.openAccCtx(), accDecl, accRoutineInfos);
- for (Fortran::lower::pft::Evaluation &e : getEval().getNestedEvaluations())
- genFIR(e);
+void FirConverter::genFIR(const Fortran::parser::WhereBodyConstruct &body) {
+ std::visit(
+ Fortran::common::visitors{
+ [&](const Fortran::parser::Statement<Fortran::parser::AssignmentStmt>
+ &stmt) { genNestedStatement(stmt); },
+ [&](const Fortran::parser::Statement<Fortran::parser::WhereStmt>
+ &stmt) { genNestedStatement(stmt); },
+ [&](const Fortran::common::Indirection<
+ Fortran::parser::WhereConstruct> &c) { genFIR(c.value()); },
+ },
+ body.u);
}
-void FirConverter::genFIR(const Fortran::parser::OpenACCRoutineConstruct &acc) {
- // Handled by genFIR(const Fortran::parser::OpenACCDeclarativeConstruct &)
-}
+void FirConverter::genFIR(const Fortran::parser::WhereConstruct &c) {
+ mlir::Location loc = getCurrentLocation();
+ hlfir::WhereOp whereOp;
-void FirConverter::genFIR(const Fortran::parser::OpenMPConstruct &omp) {
- mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
- localSymbols.pushScope();
- genOpenMPConstruct(*this, bridge.getSemanticsContext(), getEval(), omp);
+ if (!lowerToHighLevelFIR()) {
+ implicitIterSpace.growStack();
+ } else {
+ whereOp = builder->create<hlfir::WhereOp>(loc);
+ builder->createBlock(&whereOp.getMaskRegion());
+ }
- const Fortran::parser::OpenMPLoopConstruct *ompLoop =
- std::get_if<Fortran::parser::OpenMPLoopConstruct>(&omp.u);
- const Fortran::parser::OpenMPBlockConstruct *ompBlock =
- std::get_if<Fortran::parser::OpenMPBlockConstruct>(&omp.u);
+ // Lower the where mask. For HLFIR, this is done in the hlfir.where mask
+ // region.
+ genNestedStatement(
+ std::get<Fortran::parser::Statement<Fortran::parser::WhereConstructStmt>>(
+ c.t));
- // If loop is part of an OpenMP Construct then the OpenMP dialect
- // workshare loop operation has already been created. Only the
- // body needs to be created here and the do_loop can be skipped.
- // Skip the number of collapsed loops, which is 1 when there is a
- // no collapse requested.
+ // Lower WHERE body. For HLFIR, this is done in the hlfir.where body
+ // region.
+ if (whereOp)
+ builder->createBlock(&whereOp.getBody());
- Fortran::lower::pft::Evaluation *curEval = &getEval();
- const Fortran::parser::OmpClauseList *loopOpClauseList = nullptr;
- if (ompLoop) {
- loopOpClauseList = &std::get<Fortran::parser::OmpClauseList>(
- std::get<Fortran::parser::OmpBeginLoopDirective>(ompLoop->t).t);
- int64_t collapseValue = Fortran::lower::getCollapseValue(*loopOpClauseList);
+ for (const auto &body :
+ std::get<std::list<Fortran::parser::WhereBodyConstruct>>(c.t))
+ genFIR(body);
+ for (const auto &e :
+ std::get<std::list<Fortran::parser::WhereConstruct::MaskedElsewhere>>(
+ c.t))
+ genFIR(e);
+ if (const auto &e =
+ std::get<std::optional<Fortran::parser::WhereConstruct::Elsewhere>>(
+ c.t);
+ e.has_value())
+ genFIR(*e);
+ genNestedStatement(
+ std::get<Fortran::parser::Statement<Fortran::parser::EndWhereStmt>>(c.t));
- curEval = &curEval->getFirstNestedEvaluation();
- for (int64_t i = 1; i < collapseValue; i++) {
- curEval = &*std::next(curEval->getNestedEvaluations().begin());
- }
+ if (whereOp) {
+ // For HLFIR, create fir.end terminator in the last hlfir.elsewhere, or
+ // in the hlfir.where if it had no elsewhere.
+ builder->create<fir::FirEndOp>(loc);
+ builder->setInsertionPointAfter(whereOp);
}
+}
- for (Fortran::lower::pft::Evaluation &e : curEval->getNestedEvaluations())
- genFIR(e);
+void FirConverter::genFIR(
+ const Fortran::parser::WhereConstruct::Elsewhere &ew) {
+ if (lowerToHighLevelFIR()) {
+ auto elsewhereOp =
+ builder->create<hlfir::ElseWhereOp>(getCurrentLocation());
+ builder->createBlock(&elsewhereOp.getBody());
+ }
+ genNestedStatement(
+ std::get<Fortran::parser::Statement<Fortran::parser::ElsewhereStmt>>(
+ ew.t));
+ for (const auto &body :
+ std::get<std::list<Fortran::parser::WhereBodyConstruct>>(ew.t))
+ genFIR(body);
+}
- if (ompLoop) {
- genOpenMPReduction(*this, *loopOpClauseList);
- } else if (ompBlock) {
- const auto &blockStart =
- std::get<Fortran::parser::OmpBeginBlockDirective>(ompBlock->t);
- const auto &blockClauses =
- std::get<Fortran::parser::OmpClauseList>(blockStart.t);
- genOpenMPReduction(*this, blockClauses);
+void FirConverter::genFIR(
+ const Fortran::parser::WhereConstruct::MaskedElsewhere &ew) {
+ mlir::Location loc = getCurrentLocation();
+ hlfir::ElseWhereOp elsewhereOp;
+ if (lowerToHighLevelFIR()) {
+ elsewhereOp = builder->create<hlfir::ElseWhereOp>(loc);
+ // Lower mask in the mask region.
+ builder->createBlock(&elsewhereOp.getMaskRegion());
}
+ genNestedStatement(
+ std::get<
+ Fortran::parser::Statement<Fortran::parser::MaskedElsewhereStmt>>(
+ ew.t));
- localSymbols.popScope();
- builder->restoreInsertionPoint(insertPt);
+ // For HLFIR, lower the body in the hlfir.elsewhere body region.
+ if (elsewhereOp)
+ builder->createBlock(&elsewhereOp.getBody());
- // Register if a target region was found
- ompDeviceCodeFound =
- ompDeviceCodeFound || Fortran::lower::isOpenMPTargetConstruct(omp);
+ for (const auto &body :
+ std::get<std::list<Fortran::parser::WhereBodyConstruct>>(ew.t))
+ genFIR(body);
}
-void FirConverter::genFIR(
- const Fortran::parser::OpenMPDeclarativeConstruct &ompDecl) {
- mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
- // Register if a declare target construct intended for a target device was
- // found
- ompDeviceCodeFound =
- ompDeviceCodeFound ||
- Fortran::lower::isOpenMPDeviceDeclareTarget(*this, getEval(), ompDecl);
- genOpenMPDeclarativeConstruct(*this, getEval(), ompDecl);
- for (Fortran::lower::pft::Evaluation &e : getEval().getNestedEvaluations())
- genFIR(e);
- builder->restoreInsertionPoint(insertPt);
+void FirConverter::genFIR(const Fortran::parser::WhereConstructStmt &stmt) {
+ const Fortran::semantics::SomeExpr *maskExpr = Fortran::semantics::GetExpr(
+ std::get<Fortran::parser::LogicalExpr>(stmt.t));
+ if (lowerToHighLevelFIR())
+ lowerWhereMaskToHlfir(getCurrentLocation(), maskExpr);
+ else
+ implicitIterSpace.append(maskExpr);
}
-/// Generate FIR for a SELECT CASE statement.
-/// The selector may have CHARACTER, INTEGER, or LOGICAL type.
-void FirConverter::genFIR(const Fortran::parser::SelectCaseStmt &stmt) {
- Fortran::lower::pft::Evaluation &eval = getEval();
- Fortran::lower::pft::Evaluation *parentConstruct = eval.parentConstruct;
- assert(!activeConstructStack.empty() &&
- &activeConstructStack.back().eval == parentConstruct &&
- "select case construct is not active");
- Fortran::lower::StatementContext &stmtCtx =
- activeConstructStack.back().stmtCtx;
- const Fortran::lower::SomeExpr *expr = Fortran::semantics::GetExpr(
- std::get<Fortran::parser::Scalar<Fortran::parser::Expr>>(stmt.t));
- bool isCharSelector = isCharacterCategory(expr->GetType()->category());
- bool isLogicalSelector = isLogicalCategory(expr->GetType()->category());
- mlir::MLIRContext *context = builder->getContext();
- mlir::Location loc = toLocation();
- auto charValue = [&](const Fortran::lower::SomeExpr *expr) {
- fir::ExtendedValue exv = genExprAddr(*expr, stmtCtx, &loc);
- return exv.match(
- [&](const fir::CharBoxValue &cbv) {
- return fir::factory::CharacterExprHelper{*builder, loc}
- .createEmboxChar(cbv.getAddr(), cbv.getLen());
- },
- [&](auto) {
- fir::emitFatalError(loc, "not a character");
- return mlir::Value{};
- });
- };
- mlir::Value selector;
- if (isCharSelector) {
- selector = charValue(expr);
- } else {
- selector = createFIRExpr(loc, expr, stmtCtx);
- if (isLogicalSelector)
- selector = builder->createConvert(loc, builder->getI1Type(), selector);
- }
- mlir::Type selectType = selector.getType();
- llvm::SmallVector<mlir::Attribute> attrList;
- llvm::SmallVector<mlir::Value> valueList;
- llvm::SmallVector<mlir::Block *> blockList;
- mlir::Block *defaultBlock = parentConstruct->constructExit->block;
- using CaseValue = Fortran::parser::Scalar<Fortran::parser::ConstantExpr>;
- auto addValue = [&](const CaseValue &caseValue) {
- const Fortran::lower::SomeExpr *expr =
- Fortran::semantics::GetExpr(caseValue.thing);
- if (isCharSelector)
- valueList.push_back(charValue(expr));
- else if (isLogicalSelector)
- valueList.push_back(builder->createConvert(
- loc, selectType, createFIRExpr(toLocation(), expr, stmtCtx)));
- else
- valueList.push_back(builder->createIntegerConstant(
- loc, selectType, *Fortran::evaluate::ToInt64(*expr)));
- };
- for (Fortran::lower::pft::Evaluation *e = eval.controlSuccessor; e;
- e = e->controlSuccessor) {
- const auto &caseStmt = e->getIf<Fortran::parser::CaseStmt>();
- assert(e->block && "missing CaseStmt block");
- const auto &caseSelector =
- std::get<Fortran::parser::CaseSelector>(caseStmt->t);
- const auto *caseValueRangeList =
- std::get_if<std::list<Fortran::parser::CaseValueRange>>(
- &caseSelector.u);
- if (!caseValueRangeList) {
- defaultBlock = e->block;
- continue;
- }
- for (const Fortran::parser::CaseValueRange &caseValueRange :
- *caseValueRangeList) {
- blockList.push_back(e->block);
- if (const auto *caseValue = std::get_if<CaseValue>(&caseValueRange.u)) {
- attrList.push_back(fir::PointIntervalAttr::get(context));
- addValue(*caseValue);
- continue;
- }
- const auto &caseRange =
- std::get<Fortran::parser::CaseValueRange::Range>(caseValueRange.u);
- if (caseRange.lower && caseRange.upper) {
- attrList.push_back(fir::ClosedIntervalAttr::get(context));
- addValue(*caseRange.lower);
- addValue(*caseRange.upper);
- } else if (caseRange.lower) {
- attrList.push_back(fir::LowerBoundAttr::get(context));
- addValue(*caseRange.lower);
- } else {
- attrList.push_back(fir::UpperBoundAttr::get(context));
- addValue(*caseRange.upper);
- }
- }
- }
- // Skip a logical default block that can never be referenced.
- if (isLogicalSelector && attrList.size() == 2)
- defaultBlock = parentConstruct->constructExit->block;
- attrList.push_back(mlir::UnitAttr::get(context));
- blockList.push_back(defaultBlock);
-
- // Generate a fir::SelectCaseOp. Explicit branch code is better for the
- // LOGICAL type. The CHARACTER type does not have downstream SelectOp
- // support. The -no-structured-fir option can be used to force generation
- // of INTEGER type branch code.
- if (!isLogicalSelector && !isCharSelector &&
- !getEval().forceAsUnstructured()) {
- // The selector is in an ssa register. Any temps that may have been
- // generated while evaluating it can be cleaned up now.
- stmtCtx.finalizeAndReset();
- builder->create<fir::SelectCaseOp>(loc, selector, attrList, valueList,
- blockList);
+void FirConverter::genFIR(const Fortran::parser::WhereStmt &stmt) {
+ Fortran::lower::StatementContext stmtCtx;
+ const auto &assign = std::get<Fortran::parser::AssignmentStmt>(stmt.t);
+ const auto *mask = Fortran::semantics::GetExpr(
+ std::get<Fortran::parser::LogicalExpr>(stmt.t));
+ if (lowerToHighLevelFIR()) {
+ mlir::Location loc = getCurrentLocation();
+ auto whereOp = builder->create<hlfir::WhereOp>(loc);
+ builder->createBlock(&whereOp.getMaskRegion());
+ lowerWhereMaskToHlfir(loc, mask);
+ builder->createBlock(&whereOp.getBody());
+ genAssignment(*assign.typedAssignment->v);
+ builder->create<fir::FirEndOp>(loc);
+ builder->setInsertionPointAfter(whereOp);
return;
}
+ implicitIterSpace.growStack();
+ implicitIterSpace.append(mask);
+ genAssignment(*assign.typedAssignment->v);
+ implicitIterSpace.shrinkStack();
+}
- // Generate a sequence of case value comparisons and branches.
- auto caseValue = valueList.begin();
- auto caseBlock = blockList.begin();
- for (mlir::Attribute attr : attrList) {
- if (attr.isa<mlir::UnitAttr>()) {
- genBranch(*caseBlock++);
- break;
- }
- auto genCond = [&](mlir::Value rhs,
- mlir::arith::CmpIPredicate pred) -> mlir::Value {
- if (!isCharSelector)
- return builder->create<mlir::arith::CmpIOp>(loc, pred, selector, rhs);
- fir::factory::CharacterExprHelper charHelper{*builder, loc};
- std::pair<mlir::Value, mlir::Value> lhsVal =
- charHelper.createUnboxChar(selector);
- std::pair<mlir::Value, mlir::Value> rhsVal =
- charHelper.createUnboxChar(rhs);
- return fir::runtime::genCharCompare(*builder, loc, pred, lhsVal.first,
- lhsVal.second, rhsVal.first,
- rhsVal.second);
- };
- mlir::Block *newBlock = insertBlock(*caseBlock);
- if (attr.isa<fir::ClosedIntervalAttr>()) {
- mlir::Block *newBlock2 = insertBlock(*caseBlock);
- mlir::Value cond = genCond(*caseValue++, mlir::arith::CmpIPredicate::sge);
- genConditionalBranch(cond, newBlock, newBlock2);
- builder->setInsertionPointToEnd(newBlock);
- mlir::Value cond2 =
- genCond(*caseValue++, mlir::arith::CmpIPredicate::sle);
- genConditionalBranch(cond2, *caseBlock++, newBlock2);
- builder->setInsertionPointToEnd(newBlock2);
- continue;
- }
- mlir::arith::CmpIPredicate pred;
- if (attr.isa<fir::PointIntervalAttr>()) {
- pred = mlir::arith::CmpIPredicate::eq;
- } else if (attr.isa<fir::LowerBoundAttr>()) {
- pred = mlir::arith::CmpIPredicate::sge;
- } else {
- assert(attr.isa<fir::UpperBoundAttr>() && "unexpected predicate");
- pred = mlir::arith::CmpIPredicate::sle;
- }
- mlir::Value cond = genCond(*caseValue++, pred);
- genConditionalBranch(cond, *caseBlock++, newBlock);
- builder->setInsertionPointToEnd(newBlock);
- }
- assert(caseValue == valueList.end() && caseBlock == blockList.end() &&
- "select case list mismatch");
+void FirConverter::genFIR(const Fortran::parser::WriteStmt &stmt) {
+ mlir::Value iostat = genWriteStatement(*this, stmt);
+ genIoConditionBranches(getEval(), stmt.controls, iostat);
}
+//===--------------------------------------------------------------------===//
+// AbstractConverter overrides
+//===--------------------------------------------------------------------===//
+
fir::ExtendedValue
-FirConverter::genAssociateSelector(const Fortran::lower::SomeExpr &selector,
- Fortran::lower::StatementContext &stmtCtx) {
- if (lowerToHighLevelFIR())
- return genExprAddr(selector, stmtCtx);
- return Fortran::lower::isArraySectionWithoutVectorSubscript(selector)
- ? Fortran::lower::createSomeArrayBox(*this, selector, localSymbols,
- stmtCtx)
- : genExprAddr(selector, stmtCtx);
+FirConverter::symBoxToExtendedValue(const Fortran::lower::SymbolBox &symBox) {
+ return symBox.match(
+ [](const Fortran::lower::SymbolBox::Intrinsic &box)
+ -> fir::ExtendedValue { return box.getAddr(); },
+ [](const Fortran::lower::SymbolBox::None &) -> fir::ExtendedValue {
+ llvm::report_fatal_error("symbol not mapped");
+ },
+ [&](const fir::FortranVariableOpInterface &x) -> fir::ExtendedValue {
+ return hlfir::translateToExtendedValue(getCurrentLocation(),
+ getFirOpBuilder(), x);
+ },
+ [](const auto &box) -> fir::ExtendedValue { return box; });
}
-void FirConverter::genFIR(const Fortran::parser::AssociateConstruct &) {
- Fortran::lower::pft::Evaluation &eval = getEval();
- Fortran::lower::StatementContext stmtCtx;
- pushActiveConstruct(eval, stmtCtx);
- for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
- if (auto *stmt = e.getIf<Fortran::parser::AssociateStmt>()) {
- if (eval.lowerAsUnstructured())
- maybeStartBlock(e.block);
- localSymbols.pushScope();
- for (const Fortran::parser::Association &assoc :
- std::get<std::list<Fortran::parser::Association>>(stmt->t)) {
- Fortran::semantics::Symbol &sym =
- *std::get<Fortran::parser::Name>(assoc.t).symbol;
- const Fortran::lower::SomeExpr &selector =
- *sym.get<Fortran::semantics::AssocEntityDetails>().expr();
- addSymbol(sym, genAssociateSelector(selector, stmtCtx));
- }
- } else if (e.getIf<Fortran::parser::EndAssociateStmt>()) {
- if (eval.lowerAsUnstructured())
- maybeStartBlock(e.block);
- localSymbols.popScope();
- } else {
- genFIR(e);
- }
+fir::ExtendedValue
+FirConverter::getSymbolExtendedValue(const Fortran::semantics::Symbol &sym,
+ Fortran::lower::SymMap *symMap) {
+ Fortran::lower::SymbolBox sb = lookupSymbol(sym, symMap);
+ if (!sb) {
+ LLVM_DEBUG(llvm::dbgs() << "unknown symbol: " << sym << "\nmap: "
+ << (symMap ? *symMap : localSymbols) << '\n');
+ fir::emitFatalError(getCurrentLocation(),
+ "symbol is not mapped to any IR value");
}
- popActiveConstruct();
+ return symBoxToExtendedValue(sb);
}
-void FirConverter::genFIR(
- const Fortran::parser::BlockConstruct &blockConstruct) {
- Fortran::lower::pft::Evaluation &eval = getEval();
- Fortran::lower::StatementContext stmtCtx;
- pushActiveConstruct(eval, stmtCtx);
- for (Fortran::lower::pft::Evaluation &e : eval.getNestedEvaluations()) {
- if (e.getIf<Fortran::parser::BlockStmt>()) {
- if (eval.lowerAsUnstructured())
- maybeStartBlock(e.block);
- setCurrentPosition(e.position);
- const Fortran::parser::CharBlock &endPosition =
- eval.getLastNestedEvaluation().position;
- localSymbols.pushScope();
- mlir::func::FuncOp stackSave = fir::factory::getLlvmStackSave(*builder);
- mlir::func::FuncOp stackRestore =
- fir::factory::getLlvmStackRestore(*builder);
- mlir::Value stackPtr =
- builder->create<fir::CallOp>(toLocation(), stackSave).getResult(0);
- mlir::Location endLoc = genLocation(endPosition);
- stmtCtx.attachCleanup([=]() {
- builder->create<fir::CallOp>(endLoc, stackRestore, stackPtr);
- });
- Fortran::semantics::Scope &scope =
- bridge.getSemanticsContext().FindScope(endPosition);
- scopeBlockIdMap.try_emplace(&scope, ++blockId);
- Fortran::lower::AggregateStoreMap storeMap;
- for (const Fortran::lower::pft::Variable &var :
- Fortran::lower::pft::getScopeVariableList(scope)) {
- // Do no instantiate again variables from the block host
- // that appears in specification of block variables.
- if (!var.hasSymbol() || !lookupSymbol(var.getSymbol()))
- instantiateVar(var, storeMap);
- }
- } else if (e.getIf<Fortran::parser::EndBlockStmt>()) {
- if (eval.lowerAsUnstructured())
- maybeStartBlock(e.block);
- setCurrentPosition(e.position);
- localSymbols.popScope();
- } else {
- genFIR(e);
- }
- }
- popActiveConstruct();
+mlir::Value FirConverter::impliedDoBinding(llvm::StringRef name) {
+ mlir::Value val = localSymbols.lookupImpliedDo(name);
+ if (!val)
+ fir::emitFatalError(toLocation(), "ac-do-variable has no binding");
+ return val;
}
-void FirConverter::genFIR(
- const Fortran::parser::ChangeTeamConstruct &construct) {
- TODO(toLocation(), "coarray: ChangeTeamConstruct");
-}
-void FirConverter::genFIR(const Fortran::parser::ChangeTeamStmt &stmt) {
- TODO(toLocation(), "coarray: ChangeTeamStmt");
-}
-void FirConverter::genFIR(const Fortran::parser::EndChangeTeamStmt &stmt) {
- TODO(toLocation(), "coarray: EndChangeTeamStmt");
+/// Add the symbol binding to the inner-most level of the symbol map and
+/// return true if it is not already present. Otherwise, return false.
+bool FirConverter::bindIfNewSymbol(Fortran::lower::SymbolRef sym,
+ const fir::ExtendedValue &exval) {
+ if (shallowLookupSymbol(sym))
+ return false;
+ bindSymbol(sym, exval);
+ return true;
}
-void FirConverter::genFIR(
- const Fortran::parser::CriticalConstruct &criticalConstruct) {
- setCurrentPositionAt(criticalConstruct);
- TODO(toLocation(), "coarray: CriticalConstruct");
-}
-void FirConverter::genFIR(const Fortran::parser::CriticalStmt &) {
- TODO(toLocation(), "coarray: CriticalStmt");
-}
-void FirConverter::genFIR(const Fortran::parser::EndCriticalStmt &) {
- TODO(toLocation(), "coarray: EndCriticalStmt");
+bool FirConverter::lookupLabelSet(Fortran::lower::SymbolRef sym,
+ Fortran::lower::pft::LabelSet &labelSet) {
+ Fortran::lower::pft::FunctionLikeUnit &owningProc =
+ *getEval().getOwningProcedure();
+ auto iter = owningProc.assignSymbolLabelMap.find(sym);
+ if (iter == owningProc.assignSymbolLabelMap.end())
+ return false;
+ labelSet = iter->second;
+ return true;
}
-void FirConverter::genFIR(
- const Fortran::parser::SelectRankConstruct &selectRankConstruct) {
- setCurrentPositionAt(selectRankConstruct);
- TODO(toLocation(), "coarray: SelectRankConstruct");
+fir::ExtendedValue
+FirConverter::genExprAddr(const Fortran::lower::SomeExpr &expr,
+ Fortran::lower::StatementContext &context,
+ mlir::Location *locPtr) {
+ mlir::Location loc = locPtr ? *locPtr : toLocation();
+ if (lowerToHighLevelFIR())
+ return Fortran::lower::convertExprToAddress(loc, *this, expr, localSymbols,
+ context);
+ return Fortran::lower::createSomeExtendedAddress(loc, *this, expr,
+ localSymbols, context);
}
-void FirConverter::genFIR(const Fortran::parser::SelectRankStmt &) {
- TODO(toLocation(), "coarray: SelectRankStmt");
+
+fir::ExtendedValue
+FirConverter::genExprValue(const Fortran::lower::SomeExpr &expr,
+ Fortran::lower::StatementContext &context,
+ mlir::Location *locPtr) {
+ mlir::Location loc = locPtr ? *locPtr : toLocation();
+ if (lowerToHighLevelFIR())
+ return Fortran::lower::convertExprToValue(loc, *this, expr, localSymbols,
+ context);
+ return Fortran::lower::createSomeExtendedExpression(loc, *this, expr,
+ localSymbols, context);
}
-void FirConverter::genFIR(const Fortran::parser::SelectRankCaseStmt &) {
- TODO(toLocation(), "coarray: SelectRankCaseStmt");
+
+fir::ExtendedValue
+FirConverter::genExprBox(mlir::Location loc,
+ const Fortran::lower::SomeExpr &expr,
+ Fortran::lower::StatementContext &stmtCtx) {
+ if (lowerToHighLevelFIR())
+ return Fortran::lower::convertExprToBox(loc, *this, expr, localSymbols,
+ stmtCtx);
+ return Fortran::lower::createBoxValue(loc, *this, expr, localSymbols,
+ stmtCtx);
}
-void FirConverter::genFIR(
- const Fortran::parser::SelectTypeConstruct &selectTypeConstruct) {
- mlir::Location loc = toLocation();
- mlir::MLIRContext *context = builder->getContext();
- Fortran::lower::StatementContext stmtCtx;
- fir::ExtendedValue selector;
- llvm::SmallVector<mlir::Attribute> attrList;
- llvm::SmallVector<mlir::Block *> blockList;
- unsigned typeGuardIdx = 0;
- std::size_t defaultAttrPos = std::numeric_limits<size_t>::max();
- bool hasLocalScope = false;
- llvm::SmallVector<const Fortran::semantics::Scope *> typeCaseScopes;
+bool FirConverter::createHostAssociateVarClone(
+ const Fortran::semantics::Symbol &sym) {
+ mlir::Location loc = genLocation(sym.name());
+ mlir::Type symType = genType(sym);
+ const auto *details = sym.detailsIf<Fortran::semantics::HostAssocDetails>();
+ assert(details && "No host-association found");
+ const Fortran::semantics::Symbol &hsym = details->symbol();
+ mlir::Type hSymType = genType(hsym);
+ Fortran::lower::SymbolBox hsb = lookupSymbol(hsym);
- const auto &typeCaseList =
- std::get<std::list<Fortran::parser::SelectTypeConstruct::TypeCase>>(
- selectTypeConstruct.t);
- for (const auto &typeCase : typeCaseList) {
- const auto &stmt =
- std::get<Fortran::parser::Statement<Fortran::parser::TypeGuardStmt>>(
- typeCase.t);
- const Fortran::semantics::Scope &scope =
- bridge.getSemanticsContext().FindScope(stmt.source);
- typeCaseScopes.push_back(&scope);
- }
+ auto allocate = [&](llvm::ArrayRef<mlir::Value> shape,
+ llvm::ArrayRef<mlir::Value> typeParams) -> mlir::Value {
+ mlir::Value allocVal = builder->allocateLocal(
+ loc,
+ Fortran::semantics::IsAllocatableOrObjectPointer(&hsym.GetUltimate())
+ ? hSymType
+ : symType,
+ mangleName(sym), toStringRef(sym.GetUltimate().name()),
+ /*pinned=*/true, shape, typeParams,
+ sym.GetUltimate().attrs().test(Fortran::semantics::Attr::TARGET));
+ return allocVal;
+ };
- pushActiveConstruct(getEval(), stmtCtx);
- for (Fortran::lower::pft::Evaluation &eval :
- getEval().getNestedEvaluations()) {
- if (auto *selectTypeStmt = eval.getIf<Fortran::parser::SelectTypeStmt>()) {
- // A genFIR(SelectTypeStmt) call would have unwanted side effects.
- maybeStartBlock(eval.block);
- // Retrieve the selector
- const auto &s = std::get<Fortran::parser::Selector>(selectTypeStmt->t);
- if (const auto *v = std::get_if<Fortran::parser::Variable>(&s.u))
- selector = genExprBox(loc, *Fortran::semantics::GetExpr(*v), stmtCtx);
- else if (const auto *e = std::get_if<Fortran::parser::Expr>(&s.u))
- selector = genExprBox(loc, *Fortran::semantics::GetExpr(*e), stmtCtx);
+ fir::ExtendedValue hexv = symBoxToExtendedValue(hsb);
+ fir::ExtendedValue exv = hexv.match(
+ [&](const fir::BoxValue &box) -> fir::ExtendedValue {
+ const Fortran::semantics::DeclTypeSpec *type = sym.GetType();
+ if (type && type->IsPolymorphic())
+ TODO(loc, "create polymorphic host associated copy");
+ // Create a contiguous temp with the same shape and length as
+ // the original variable described by a fir.box.
+ llvm::SmallVector<mlir::Value> extents =
+ fir::factory::getExtents(loc, *builder, hexv);
+ if (box.isDerivedWithLenParameters())
+ TODO(loc, "get length parameters from derived type BoxValue");
+ if (box.isCharacter()) {
+ mlir::Value len = fir::factory::readCharLen(*builder, loc, box);
+ mlir::Value temp = allocate(extents, {len});
+ return fir::CharArrayBoxValue{temp, len, extents};
+ }
+ return fir::ArrayBoxValue{allocate(extents, {}), extents};
+ },
+ [&](const fir::MutableBoxValue &box) -> fir::ExtendedValue {
+ // Allocate storage for a pointer/allocatble descriptor.
+ // No shape/lengths to be passed to the alloca.
+ return fir::MutableBoxValue(allocate({}, {}), {}, {});
+ },
+ [&](const auto &) -> fir::ExtendedValue {
+ mlir::Value temp =
+ allocate(fir::factory::getExtents(loc, *builder, hexv),
+ fir::factory::getTypeParams(loc, *builder, hexv));
+ return fir::substBase(hexv, temp);
+ });
- // Going through the controlSuccessor first to create the
- // fir.select_type operation.
- mlir::Block *defaultBlock = eval.parentConstruct->constructExit->block;
- for (Fortran::lower::pft::Evaluation *e = eval.controlSuccessor; e;
- e = e->controlSuccessor) {
- const auto &typeGuardStmt = e->getIf<Fortran::parser::TypeGuardStmt>();
- const auto &guard =
- std::get<Fortran::parser::TypeGuardStmt::Guard>(typeGuardStmt->t);
- assert(e->block && "missing TypeGuardStmt block");
- // CLASS DEFAULT
- if (std::holds_alternative<Fortran::parser::Default>(guard.u)) {
- defaultBlock = e->block;
- // Keep track of the actual position of the CLASS DEFAULT type guard
- // in the SELECT TYPE construct.
- defaultAttrPos = attrList.size();
- continue;
+ // Initialise cloned allocatable
+ hexv.match(
+ [&](const fir::MutableBoxValue &box) -> void {
+ // Do not process pointers
+ if (Fortran::semantics::IsPointer(sym.GetUltimate())) {
+ return;
}
+ // Allocate storage for a pointer/allocatble descriptor.
+ // No shape/lengths to be passed to the alloca.
+ const auto new_box = exv.getBoxOf<fir::MutableBoxValue>();
- blockList.push_back(e->block);
- if (const auto *typeSpec =
- std::get_if<Fortran::parser::TypeSpec>(&guard.u)) {
- // TYPE IS
- mlir::Type ty;
- if (std::holds_alternative<Fortran::parser::IntrinsicTypeSpec>(
- typeSpec->u)) {
- const Fortran::semantics::IntrinsicTypeSpec *intrinsic =
- typeSpec->declTypeSpec->AsIntrinsic();
- int kind =
- Fortran::evaluate::ToInt64(intrinsic->kind()).value_or(kind);
- llvm::SmallVector<Fortran::lower::LenParameterTy> params;
- ty = genType(intrinsic->category(), kind, params);
+ // allocate if allocated
+ mlir::Value isAllocated =
+ fir::factory::genIsAllocatedOrAssociatedTest(*builder, loc, box);
+ auto if_builder = builder->genIfThenElse(loc, isAllocated);
+ if_builder.genThen([&]() {
+ std::string name = mangleName(sym) + ".alloc";
+ if (auto seqTy = symType.dyn_cast<fir::SequenceType>()) {
+ fir::ExtendedValue read = fir::factory::genMutableBoxRead(
+ *builder, loc, box, /*mayBePolymorphic=*/false);
+ if (auto read_arr_box = read.getBoxOf<fir::ArrayBoxValue>()) {
+ fir::factory::genInlinedAllocation(
+ *builder, loc, *new_box, read_arr_box->getLBounds(),
+ read_arr_box->getExtents(),
+ /*lenParams=*/std::nullopt, name,
+ /*mustBeHeap=*/true);
+ } else if (auto read_char_arr_box =
+ read.getBoxOf<fir::CharArrayBoxValue>()) {
+ fir::factory::genInlinedAllocation(
+ *builder, loc, *new_box, read_char_arr_box->getLBounds(),
+ read_char_arr_box->getExtents(), read_char_arr_box->getLen(),
+ name,
+ /*mustBeHeap=*/true);
+ } else {
+ TODO(loc, "Unhandled allocatable box type");
+ }
} else {
- const Fortran::semantics::DerivedTypeSpec *derived =
- typeSpec->declTypeSpec->AsDerived();
- ty = genType(*derived);
+ fir::factory::genInlinedAllocation(
+ *builder, loc, *new_box, box.getMutableProperties().lbounds,
+ box.getMutableProperties().extents, box.nonDeferredLenParams(),
+ name,
+ /*mustBeHeap=*/true);
}
- attrList.push_back(fir::ExactTypeAttr::get(ty));
- } else if (const auto *derived =
- std::get_if<Fortran::parser::DerivedTypeSpec>(
- &guard.u)) {
- // CLASS IS
- assert(derived->derivedTypeSpec && "derived type spec is null");
- mlir::Type ty = genType(*(derived->derivedTypeSpec));
- attrList.push_back(fir::SubclassAttr::get(ty));
- }
- }
- attrList.push_back(mlir::UnitAttr::get(context));
- blockList.push_back(defaultBlock);
- builder->create<fir::SelectTypeOp>(loc, fir::getBase(selector), attrList,
- blockList);
-
- // If the actual position of CLASS DEFAULT type guard is not the last
- // one, it needs to be put back at its correct position for the rest of
- // the processing. TypeGuardStmt are processed in the same order they
- // appear in the Fortran code.
- if (defaultAttrPos < attrList.size() - 1) {
- auto attrIt = attrList.begin();
- attrIt = attrIt + defaultAttrPos;
- auto blockIt = blockList.begin();
- blockIt = blockIt + defaultAttrPos;
- attrList.insert(attrIt, mlir::UnitAttr::get(context));
- blockList.insert(blockIt, defaultBlock);
- attrList.pop_back();
- blockList.pop_back();
- }
- } else if (auto *typeGuardStmt =
- eval.getIf<Fortran::parser::TypeGuardStmt>()) {
- // Map the type guard local symbol for the selector to a more precise
- // typed entity in the TypeGuardStmt when necessary.
- genFIR(eval);
- const auto &guard =
- std::get<Fortran::parser::TypeGuardStmt::Guard>(typeGuardStmt->t);
- if (hasLocalScope)
- localSymbols.popScope();
- localSymbols.pushScope();
- hasLocalScope = true;
- assert(attrList.size() >= typeGuardIdx && "TypeGuard attribute missing");
- mlir::Attribute typeGuardAttr = attrList[typeGuardIdx];
- mlir::Block *typeGuardBlock = blockList[typeGuardIdx];
- mlir::OpBuilder::InsertPoint crtInsPt = builder->saveInsertionPoint();
- builder->setInsertionPointToStart(typeGuardBlock);
+ });
+ if_builder.genElse([&]() {
+ // nullify box
+ auto empty = fir::factory::createUnallocatedBox(
+ *builder, loc, new_box->getBoxTy(),
+ new_box->nonDeferredLenParams(), {});
+ builder->create<fir::StoreOp>(loc, empty, new_box->getAddr());
+ });
+ if_builder.end();
+ },
+ [&](const auto &) -> void {
+ // Do nothing
+ });
- auto addAssocEntitySymbol = [&](fir::ExtendedValue exv) {
- for (auto &symbol : typeCaseScopes[typeGuardIdx]->GetSymbols()) {
- if (symbol->GetUltimate()
- .detailsIf<Fortran::semantics::AssocEntityDetails>()) {
- addSymbol(symbol, exv);
- break;
- }
- }
- };
+ return bindIfNewSymbol(sym, exv);
+}
- mlir::Type baseTy = fir::getBase(selector).getType();
- bool isPointer = fir::isPointerType(baseTy);
- bool isAllocatable = fir::isAllocatableType(baseTy);
- bool isArray =
- fir::dyn_cast_ptrOrBoxEleTy(baseTy).isa<fir::SequenceType>();
- const fir::BoxValue *selectorBox = selector.getBoxOf<fir::BoxValue>();
- if (std::holds_alternative<Fortran::parser::Default>(guard.u)) {
- // CLASS DEFAULT
- addAssocEntitySymbol(selector);
- } else if (const auto *typeSpec =
- std::get_if<Fortran::parser::TypeSpec>(&guard.u)) {
- // TYPE IS
- fir::ExactTypeAttr attr = typeGuardAttr.dyn_cast<fir::ExactTypeAttr>();
- mlir::Value exactValue;
- mlir::Type addrTy = attr.getType();
- if (isArray) {
- auto seqTy =
- fir::dyn_cast_ptrOrBoxEleTy(baseTy).dyn_cast<fir::SequenceType>();
- addrTy = fir::SequenceType::get(seqTy.getShape(), attr.getType());
- }
- if (isPointer)
- addrTy = fir::PointerType::get(addrTy);
- if (isAllocatable)
- addrTy = fir::HeapType::get(addrTy);
- if (std::holds_alternative<Fortran::parser::IntrinsicTypeSpec>(
- typeSpec->u)) {
- mlir::Type refTy = fir::ReferenceType::get(addrTy);
- if (isPointer || isAllocatable)
- refTy = addrTy;
- exactValue = builder->create<fir::BoxAddrOp>(loc, refTy,
- fir::getBase(selector));
- const Fortran::semantics::IntrinsicTypeSpec *intrinsic =
- typeSpec->declTypeSpec->AsIntrinsic();
- if (isArray) {
- mlir::Value exact = builder->create<fir::ConvertOp>(
- loc, fir::BoxType::get(addrTy), fir::getBase(selector));
- addAssocEntitySymbol(selectorBox->clone(exact));
- } else if (intrinsic->category() ==
- Fortran::common::TypeCategory::Character) {
- auto charTy = attr.getType().dyn_cast<fir::CharacterType>();
- mlir::Value charLen =
- fir::factory::CharacterExprHelper(*builder, loc)
- .readLengthFromBox(fir::getBase(selector), charTy);
- addAssocEntitySymbol(fir::CharBoxValue(exactValue, charLen));
- } else {
- addAssocEntitySymbol(exactValue);
- }
- } else if (std::holds_alternative<Fortran::parser::DerivedTypeSpec>(
- typeSpec->u)) {
- exactValue = builder->create<fir::ConvertOp>(
- loc, fir::BoxType::get(addrTy), fir::getBase(selector));
- addAssocEntitySymbol(selectorBox->clone(exactValue));
- }
- } else if (std::holds_alternative<Fortran::parser::DerivedTypeSpec>(
- guard.u)) {
- // CLASS IS
- fir::SubclassAttr attr = typeGuardAttr.dyn_cast<fir::SubclassAttr>();
- mlir::Type addrTy = attr.getType();
- if (isArray) {
- auto seqTy =
- fir::dyn_cast_ptrOrBoxEleTy(baseTy).dyn_cast<fir::SequenceType>();
- addrTy = fir::SequenceType::get(seqTy.getShape(), attr.getType());
- }
- if (isPointer)
- addrTy = fir::PointerType::get(addrTy);
- if (isAllocatable)
- addrTy = fir::HeapType::get(addrTy);
- mlir::Type classTy = fir::ClassType::get(addrTy);
- if (classTy == baseTy) {
- addAssocEntitySymbol(selector);
- } else {
- mlir::Value derived = builder->create<fir::ConvertOp>(
- loc, classTy, fir::getBase(selector));
- addAssocEntitySymbol(selectorBox->clone(derived));
+void FirConverter::createHostAssociateVarCloneDealloc(
+ const Fortran::semantics::Symbol &sym) {
+ mlir::Location loc = genLocation(sym.name());
+ Fortran::lower::SymbolBox hsb = lookupSymbol(sym);
+
+ fir::ExtendedValue hexv = symBoxToExtendedValue(hsb);
+ hexv.match(
+ [&](const fir::MutableBoxValue &new_box) -> void {
+ // Do not process pointers
+ if (Fortran::semantics::IsPointer(sym.GetUltimate())) {
+ return;
}
- }
- builder->restoreInsertionPoint(crtInsPt);
- ++typeGuardIdx;
- } else if (eval.getIf<Fortran::parser::EndSelectStmt>()) {
- maybeStartBlock(eval.block);
- if (hasLocalScope)
- localSymbols.popScope();
+ // deallocate allocated in createHostAssociateVarClone value
+ Fortran::lower::genDeallocateIfAllocated(*this, new_box, loc);
+ },
+ [&](const auto &) -> void {
+ // Do nothing
+ });
+}
+
+void FirConverter::copyHostAssociateVar(
+ const Fortran::semantics::Symbol &sym,
+ mlir::OpBuilder::InsertPoint *copyAssignIP) {
+ // 1) Fetch the original copy of the variable.
+ assert(sym.has<Fortran::semantics::HostAssocDetails>() &&
+ "No host-association found");
+ const Fortran::semantics::Symbol &hsym = sym.GetUltimate();
+ Fortran::lower::SymbolBox hsb = lookupOneLevelUpSymbol(hsym);
+ assert(hsb && "Host symbol box not found");
+
+ // 2) Fetch the copied one that will mask the original.
+ Fortran::lower::SymbolBox sb = shallowLookupSymbol(sym);
+ assert(sb && "Host-associated symbol box not found");
+ assert(hsb.getAddr() != sb.getAddr() &&
+ "Host and associated symbol boxes are the same");
+
+ // 3) Perform the assignment.
+ mlir::OpBuilder::InsertPoint insPt = builder->saveInsertionPoint();
+ if (copyAssignIP && copyAssignIP->isSet())
+ builder->restoreInsertionPoint(*copyAssignIP);
+ else
+ builder->setInsertionPointAfter(sb.getAddr().getDefiningOp());
+
+ Fortran::lower::SymbolBox *lhs_sb, *rhs_sb;
+ if (copyAssignIP && copyAssignIP->isSet() &&
+ sym.test(Fortran::semantics::Symbol::Flag::OmpLastPrivate)) {
+ // lastprivate case
+ lhs_sb = &hsb;
+ rhs_sb = &sb;
+ } else {
+ lhs_sb = &sb;
+ rhs_sb = &hsb;
+ }
+
+ mlir::Location loc = genLocation(sym.name());
+
+ if (lowerToHighLevelFIR()) {
+ hlfir::Entity lhs{lhs_sb->getAddr()};
+ hlfir::Entity rhs{rhs_sb->getAddr()};
+ // Temporary_lhs is set to true in hlfir.assign below to avoid
+ // user assignment to be used and finalization to be called on
+ // the LHS. This may or may not be correct but mimics the current behaviour
+ // without HLFIR.
+ auto copyData = [&](hlfir::Entity l, hlfir::Entity r) {
+ // Dereference RHS and load it if trivial scalar.
+ r = hlfir::loadTrivialScalar(loc, *builder, r);
+ builder->create<hlfir::AssignOp>(
+ loc, r, l,
+ /*isWholeAllocatableAssignment=*/false,
+ /*keepLhsLengthInAllocatableAssignment=*/false,
+ /*temporary_lhs=*/true);
+ };
+ if (lhs.isAllocatable()) {
+ // Deep copy allocatable if it is allocated.
+ // Note that when allocated, the RHS is already allocated with the LHS
+ // shape for copy on entry in createHostAssociateVarClone.
+ // For lastprivate, this assumes that the RHS was not reallocated in
+ // the OpenMP region.
+ lhs = hlfir::derefPointersAndAllocatables(loc, *builder, lhs);
+ mlir::Value addr = hlfir::genVariableRawAddress(loc, *builder, lhs);
+ mlir::Value isAllocated = builder->genIsNotNullAddr(loc, addr);
+ builder->genIfThen(loc, isAllocated)
+ .genThen([&]() {
+ // Copy the DATA, not the descriptors.
+ copyData(lhs, rhs);
+ })
+ .end();
+ } else if (lhs.isPointer()) {
+ // Set LHS target to the target of RHS (do not copy the RHS
+ // target data into the LHS target storage).
+ auto loadVal = builder->create<fir::LoadOp>(loc, rhs);
+ builder->create<fir::StoreOp>(loc, loadVal, lhs);
} else {
- genFIR(eval);
+ // Non ALLOCATABLE/POINTER variable. Simple DATA copy.
+ copyData(lhs, rhs);
+ }
+ } else {
+ fir::ExtendedValue lhs = symBoxToExtendedValue(*lhs_sb);
+ fir::ExtendedValue rhs = symBoxToExtendedValue(*rhs_sb);
+ mlir::Type symType = genType(sym);
+ if (auto seqTy = symType.dyn_cast<fir::SequenceType>()) {
+ Fortran::lower::StatementContext stmtCtx;
+ Fortran::lower::createSomeArrayAssignment(*this, lhs, rhs, localSymbols,
+ stmtCtx);
+ stmtCtx.finalizeAndReset();
+ } else if (lhs.getBoxOf<fir::CharBoxValue>()) {
+ fir::factory::CharacterExprHelper{*builder, loc}.createAssign(lhs, rhs);
+ } else {
+ auto loadVal = builder->create<fir::LoadOp>(loc, fir::getBase(rhs));
+ builder->create<fir::StoreOp>(loc, loadVal, fir::getBase(lhs));
}
}
- popActiveConstruct();
+
+ if (copyAssignIP && copyAssignIP->isSet() &&
+ sym.test(Fortran::semantics::Symbol::Flag::OmpLastPrivate)) {
+ builder->restoreInsertionPoint(insPt);
+ }
}
//===--------------------------------------------------------------------===//
-// IO statements (see io.h)
+// Utility methods
//===--------------------------------------------------------------------===//
-void FirConverter::genFIR(const Fortran::parser::BackspaceStmt &stmt) {
- mlir::Value iostat = genBackspaceStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.v, iostat);
-}
-void FirConverter::genFIR(const Fortran::parser::CloseStmt &stmt) {
- mlir::Value iostat = genCloseStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.v, iostat);
-}
-void FirConverter::genFIR(const Fortran::parser::EndfileStmt &stmt) {
- mlir::Value iostat = genEndfileStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.v, iostat);
-}
-void FirConverter::genFIR(const Fortran::parser::FlushStmt &stmt) {
- mlir::Value iostat = genFlushStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.v, iostat);
-}
-void FirConverter::genFIR(const Fortran::parser::InquireStmt &stmt) {
- mlir::Value iostat = genInquireStatement(*this, stmt);
- if (const auto *specs =
- std::get_if<std::list<Fortran::parser::InquireSpec>>(&stmt.u))
- genIoConditionBranches(getEval(), *specs, iostat);
-}
-void FirConverter::genFIR(const Fortran::parser::OpenStmt &stmt) {
- mlir::Value iostat = genOpenStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.v, iostat);
-}
-void FirConverter::genFIR(const Fortran::parser::PrintStmt &stmt) {
- genPrintStatement(*this, stmt);
-}
-void FirConverter::genFIR(const Fortran::parser::ReadStmt &stmt) {
- mlir::Value iostat = genReadStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.controls, iostat);
-}
-void FirConverter::genFIR(const Fortran::parser::RewindStmt &stmt) {
- mlir::Value iostat = genRewindStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.v, iostat);
-}
-void FirConverter::genFIR(const Fortran::parser::WaitStmt &stmt) {
- mlir::Value iostat = genWaitStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.v, iostat);
-}
-void FirConverter::genFIR(const Fortran::parser::WriteStmt &stmt) {
- mlir::Value iostat = genWriteStatement(*this, stmt);
- genIoConditionBranches(getEval(), stmt.controls, iostat);
+void FirConverter::collectSymbolSet(
+ Fortran::lower::pft::Evaluation &eval,
+ llvm::SetVector<const Fortran::semantics::Symbol *> &symbolSet,
+ Fortran::semantics::Symbol::Flag flag, bool collectSymbols,
+ bool checkHostAssociatedSymbols) {
+ auto addToList = [&](const Fortran::semantics::Symbol &sym) {
+ std::function<void(const Fortran::semantics::Symbol &, bool)>
+ insertSymbols = [&](const Fortran::semantics::Symbol &oriSymbol,
+ bool collectSymbol) {
+ if (collectSymbol && oriSymbol.test(flag))
+ symbolSet.insert(&oriSymbol);
+ if (checkHostAssociatedSymbols)
+ if (const auto *details{
+ oriSymbol
+ .detailsIf<Fortran::semantics::HostAssocDetails>()})
+ insertSymbols(details->symbol(), true);
+ };
+ insertSymbols(sym, collectSymbols);
+ };
+ Fortran::lower::pft::visitAllSymbols(eval, addToList);
}
-//===--------------------------------------------------------------------===//
-// Memory allocation and deallocation
-//===--------------------------------------------------------------------===//
-
-void FirConverter::genFIR(const Fortran::parser::AllocateStmt &stmt) {
- Fortran::lower::genAllocateStmt(*this, stmt, toLocation());
+/// Generate a `Location` from the `CharBlock`.
+mlir::Location
+FirConverter::genLocation(const Fortran::parser::CharBlock &block) {
+ if (const Fortran::parser::AllCookedSources *cooked =
+ bridge.getCookedSource()) {
+ if (std::optional<Fortran::parser::ProvenanceRange> provenance =
+ cooked->GetProvenanceRange(block)) {
+ if (std::optional<Fortran::parser::SourcePosition> filePos =
+ cooked->allSources().GetSourcePosition(provenance->start())) {
+ llvm::SmallString<256> filePath(*filePos->path);
+ llvm::sys::fs::make_absolute(filePath);
+ llvm::sys::path::remove_dots(filePath);
+ return mlir::FileLineColLoc::get(&getMLIRContext(), filePath.str(),
+ filePos->line, filePos->column);
+ }
+ }
+ }
+ return genUnknownLocation();
}
-void FirConverter::genFIR(const Fortran::parser::DeallocateStmt &stmt) {
- Fortran::lower::genDeallocateStmt(*this, stmt, toLocation());
+/// Return the current function context, which may be a nested BLOCK context
+/// or a full subprogram context.
+Fortran::lower::StatementContext &FirConverter::getFctCtx() {
+ if (!activeConstructStack.empty() &&
+ activeConstructStack.back().eval.isA<Fortran::parser::BlockConstruct>())
+ return activeConstructStack.back().stmtCtx;
+ return bridge.fctCtx();
}
-/// Nullify pointer object list
-///
-/// For each pointer object, reset the pointer to a disassociated status.
-/// We do this by setting each pointer to null.
-void FirConverter::genFIR(const Fortran::parser::NullifyStmt &stmt) {
- mlir::Location loc = toLocation();
- for (auto &pointerObject : stmt.v) {
- const Fortran::lower::SomeExpr *expr =
- Fortran::semantics::GetExpr(pointerObject);
- assert(expr);
- if (Fortran::evaluate::IsProcedurePointer(*expr)) {
- Fortran::lower::StatementContext stmtCtx;
- hlfir::Entity pptr = Fortran::lower::convertExprToHLFIR(
- loc, *this, *expr, localSymbols, stmtCtx);
- auto boxTy{Fortran::lower::getUntypedBoxProcType(builder->getContext())};
- hlfir::Entity nullBoxProc(
- fir::factory::createNullBoxProc(*builder, loc, boxTy));
- builder->createStoreWithConvert(loc, nullBoxProc, pptr);
- return;
- }
- fir::MutableBoxValue box = genExprMutableBox(loc, *expr);
- fir::factory::disassociateMutableBox(*builder, loc, box);
+llvm::StringRef
+FirConverter::getUniqueLitName(mlir::Location loc,
+ std::unique_ptr<Fortran::lower::SomeExpr> expr,
+ mlir::Type eleTy) {
+ std::string namePrefix = getConstantExprManglePrefix(loc, *expr.get(), eleTy);
+ auto [it, inserted] = literalNamesMap.try_emplace(
+ expr.get(), namePrefix + std::to_string(uniqueLitId));
+ const auto &name = it->second;
+ if (inserted) {
+ // Keep ownership of the expr key.
+ literalExprsStorage.push_back(std::move(expr));
+
+ // If we've just added a new name, we have to make sure
+ // there is no global object with the same name in the module.
+ fir::GlobalOp global = builder->getNamedGlobal(name);
+ if (global)
+ fir::emitFatalError(loc, llvm::Twine("global object with name '") +
+ llvm::Twine(name) +
+ llvm::Twine("' already exists"));
+ ++uniqueLitId;
+ return name;
}
-}
-//===--------------------------------------------------------------------===//
+ // The name already exists. Verify that the prefix is the same.
+ if (!llvm::StringRef(name).starts_with(namePrefix))
+ fir::emitFatalError(loc, llvm::Twine("conflicting prefixes: '") +
+ llvm::Twine(name) +
+ llvm::Twine("' does not start with '") +
+ llvm::Twine(namePrefix) + llvm::Twine("'"));
-void FirConverter::genFIR(const Fortran::parser::EventPostStmt &stmt) {
- genEventPostStatement(*this, stmt);
+ return name;
}
-void FirConverter::genFIR(const Fortran::parser::EventWaitStmt &stmt) {
- genEventWaitStatement(*this, stmt);
+void FirConverter::TypeInfoConverter::registerTypeInfo(
+ Fortran::lower::AbstractConverter &converter, mlir::Location loc,
+ Fortran::semantics::SymbolRef typeInfoSym,
+ const Fortran::semantics::DerivedTypeSpec &typeSpec, fir::RecordType type) {
+ if (seen.contains(typeInfoSym))
+ return;
+ seen.insert(typeInfoSym);
+ if (!skipRegistration) {
+ registeredTypeInfo.emplace_back(TypeInfo{typeInfoSym, typeSpec, type, loc});
+ return;
+ }
+ // Once the registration is closed, symbols cannot be added to the
+ // registeredTypeInfoSymbols list because it may be iterated over.
+ // However, after registration is closed, it is safe to directly generate
+ // the globals because all FuncOps whose addresses may be required by the
+ // initializers have been generated.
+ createTypeInfoOpAndGlobal(converter,
+ TypeInfo{typeInfoSym, typeSpec, type, loc});
}
-void FirConverter::genFIR(const Fortran::parser::FormTeamStmt &stmt) {
- genFormTeamStatement(*this, getEval(), stmt);
+void FirConverter::TypeInfoConverter::createTypeInfo(
+ Fortran::lower::AbstractConverter &converter) {
+ skipRegistration = true;
+ for (const TypeInfo &info : registeredTypeInfo)
+ createTypeInfoOpAndGlobal(converter, info);
+ registeredTypeInfo.clear();
}
-void FirConverter::genFIR(const Fortran::parser::LockStmt &stmt) {
- genLockStatement(*this, stmt);
+void FirConverter::TypeInfoConverter::createTypeInfoOpAndGlobal(
+ Fortran::lower::AbstractConverter &converter, const TypeInfo &info) {
+ Fortran::lower::createRuntimeTypeInfoGlobal(converter, info.symbol.get());
+ createTypeInfoOp(converter, info);
}
-/// Generate an array assignment.
-/// This is an assignment expression with rank > 0. The assignment may or may
-/// not be in a WHERE and/or FORALL context.
-/// In a FORALL context, the assignment may be a pointer assignment and the \p
-/// lbounds and \p ubounds parameters should only be used in such a pointer
-/// assignment case. (If both are None then the array assignment cannot be a
-/// pointer assignment.)
-void FirConverter::genArrayAssignment(
- const Fortran::evaluate::Assignment &assign,
- Fortran::lower::StatementContext &localStmtCtx,
- std::optional<llvm::SmallVector<mlir::Value>> lbounds,
- std::optional<llvm::SmallVector<mlir::Value>> ubounds) {
+void FirConverter::TypeInfoConverter::createTypeInfoOp(
+ Fortran::lower::AbstractConverter &converter, const TypeInfo &info) {
+ fir::RecordType parentType{};
+ if (const Fortran::semantics::DerivedTypeSpec *parent =
+ Fortran::evaluate::GetParentTypeSpec(info.typeSpec))
+ parentType = mlir::cast<fir::RecordType>(converter.genType(*parent));
- Fortran::lower::StatementContext &stmtCtx =
- explicitIterationSpace()
- ? explicitIterSpace.stmtContext()
- : (implicitIterationSpace() ? implicitIterSpace.stmtContext()
- : localStmtCtx);
- if (Fortran::lower::isWholeAllocatable(assign.lhs)) {
- // Assignment to allocatables may require the lhs to be
- // deallocated/reallocated. See Fortran 2018 10.2.1.3 p3
- Fortran::lower::createAllocatableArrayAssignment(
- *this, assign.lhs, assign.rhs, explicitIterSpace, implicitIterSpace,
- localSymbols, stmtCtx);
- return;
- }
+ fir::FirOpBuilder &builder = converter.getFirOpBuilder();
+ mlir::ModuleOp module = builder.getModule();
+ fir::TypeInfoOp dt =
+ module.lookupSymbol<fir::TypeInfoOp>(info.type.getName());
+ if (dt)
+ return; // Already created.
+ auto insertPt = builder.saveInsertionPoint();
+ builder.setInsertionPoint(module.getBody(), module.getBody()->end());
+ dt = builder.create<fir::TypeInfoOp>(info.loc, info.type, parentType);
- if (lbounds) {
- // Array of POINTER entities, with elemental assignment.
- if (!Fortran::lower::isWholePointer(assign.lhs))
- fir::emitFatalError(toLocation(), "pointer assignment to non-pointer");
+ if (!info.typeSpec.HasDefaultInitialization(/*ignoreAllocatable=*/false,
+ /*ignorePointer=*/false))
+ dt->setAttr(dt.getNoInitAttrName(), builder.getUnitAttr());
+ if (!info.typeSpec.HasDestruction())
+ dt->setAttr(dt.getNoDestroyAttrName(), builder.getUnitAttr());
+ if (!Fortran::semantics::MayRequireFinalization(info.typeSpec))
+ dt->setAttr(dt.getNoFinalAttrName(), builder.getUnitAttr());
- Fortran::lower::createArrayOfPointerAssignment(
- *this, assign.lhs, assign.rhs, explicitIterSpace, implicitIterSpace,
- *lbounds, ubounds, localSymbols, stmtCtx);
- return;
+ const Fortran::semantics::Scope *scope = info.typeSpec.scope();
+ if (!scope)
+ scope = info.typeSpec.typeSymbol().scope();
+ assert(scope && "failed to find type scope");
+
+ Fortran::semantics::SymbolVector bindings =
+ Fortran::semantics::CollectBindings(*scope);
+ if (!bindings.empty()) {
+ builder.createBlock(&dt.getDispatchTable());
+ for (const Fortran::semantics::SymbolRef &binding : bindings) {
+ const auto &details =
+ binding.get().get<Fortran::semantics::ProcBindingDetails>();
+ std::string tbpName = binding.get().name().ToString();
+ if (details.numPrivatesNotOverridden() > 0)
+ tbpName += "."s + std::to_string(details.numPrivatesNotOverridden());
+ std::string bindingName = converter.mangleName(details.symbol());
+ builder.create<fir::DTEntryOp>(
+ info.loc, mlir::StringAttr::get(builder.getContext(), tbpName),
+ mlir::SymbolRefAttr::get(builder.getContext(), bindingName));
+ }
+ builder.create<fir::FirEndOp>(info.loc);
}
+ builder.restoreInsertionPoint(insertPt);
+}
- if (!implicitIterationSpace() && !explicitIterationSpace()) {
- // No masks and the iteration space is implied by the array, so create a
- // simple array assignment.
- Fortran::lower::createSomeArrayAssignment(*this, assign.lhs, assign.rhs,
- localSymbols, stmtCtx);
- return;
+/// Declare a function.
+void FirConverter::declareFunction(
+ Fortran::lower::pft::FunctionLikeUnit &funit) {
+ setCurrentPosition(funit.getStartingSourceLoc());
+ for (int entryIndex = 0, last = funit.entryPointList.size();
+ entryIndex < last; ++entryIndex) {
+ funit.setActiveEntry(entryIndex);
+ // Calling CalleeInterface ctor will build a declaration
+ // mlir::func::FuncOp with no other side effects.
+ // TODO: when doing some compiler profiling on real apps, it may be worth
+ // to check it's better to save the CalleeInterface instead of recomputing
+ // it later when lowering the body. CalleeInterface ctor should be linear
+ // with the number of arguments, so it is not awful to do it that way for
+ // now, but the linear coefficient might be non negligible. Until
+ // measured, stick to the solution that impacts the code less.
+ Fortran::lower::CalleeInterface{funit, *this};
}
+ funit.setActiveEntry(0);
- // If there is an explicit iteration space, generate an array assignment
- // with a user-specified iteration space and possibly with masks. These
- // assignments may *appear* to be scalar expressions, but the scalar
- // expression is evaluated at all points in the user-defined space much like
- // an ordinary array assignment. More specifically, the semantics inside the
- // FORALL much more closely resembles that of WHERE than a scalar
- // assignment.
- // Otherwise, generate a masked array assignment. The iteration space is
- // implied by the lhs array expression.
- Fortran::lower::createAnyMaskedArrayAssignment(
- *this, assign.lhs, assign.rhs, explicitIterSpace, implicitIterSpace,
- localSymbols, stmtCtx);
+ // Compute the set of host associated entities from the nested functions.
+ llvm::SetVector<const Fortran::semantics::Symbol *> escapeHost;
+ for (Fortran::lower::pft::FunctionLikeUnit &f : funit.nestedFunctions)
+ collectHostAssociatedVariables(f, escapeHost);
+ funit.setHostAssociatedSymbols(escapeHost);
+
+ // Declare internal procedures
+ for (Fortran::lower::pft::FunctionLikeUnit &f : funit.nestedFunctions)
+ declareFunction(f);
}
-inline fir::MutableBoxValue
-FirConverter::genExprMutableBox(mlir::Location loc,
- const Fortran::lower::SomeExpr &expr) {
- if (lowerToHighLevelFIR())
- return Fortran::lower::convertExprToMutableBox(loc, *this, expr,
- localSymbols);
- return Fortran::lower::createMutableBox(loc, *this, expr, localSymbols);
+/// Get the scope that is defining or using \p sym. The returned scope is not
+/// the ultimate scope, since this helper does not traverse use association.
+/// This allows capturing module variables that are referenced in an internal
+/// procedure but whose use statement is inside the host program.
+const Fortran::semantics::Scope &
+FirConverter::getSymbolHostScope(const Fortran::semantics::Symbol &sym) {
+ const Fortran::semantics::Symbol *hostSymbol = &sym;
+ while (const auto *details =
+ hostSymbol->detailsIf<Fortran::semantics::HostAssocDetails>())
+ hostSymbol = &details->symbol();
+ return hostSymbol->owner();
}
-// Create the [newRank] array with the lower bounds to be passed to the
-// runtime as a descriptor.
-mlir::Value FirConverter::createLboundArray(llvm::ArrayRef<mlir::Value> lbounds,
- mlir::Location loc) {
- mlir::Type indexTy = builder->getIndexType();
- mlir::Type boundArrayTy = fir::SequenceType::get(
- {static_cast<int64_t>(lbounds.size())}, builder->getI64Type());
- mlir::Value boundArray = builder->create<fir::AllocaOp>(loc, boundArrayTy);
- mlir::Value array = builder->create<fir::UndefOp>(loc, boundArrayTy);
- for (unsigned i = 0; i < lbounds.size(); ++i) {
- array = builder->create<fir::InsertValueOp>(
- loc, boundArrayTy, array, lbounds[i],
- builder->getArrayAttr({builder->getIntegerAttr(builder->getIndexType(),
- static_cast<int>(i))}));
- }
- builder->create<fir::StoreOp>(loc, array, boundArray);
- mlir::Type boxTy = fir::BoxType::get(boundArrayTy);
- mlir::Value ext =
- builder->createIntegerConstant(loc, indexTy, lbounds.size());
- llvm::SmallVector<mlir::Value> shapes = {ext};
- mlir::Value shapeOp = builder->genShape(loc, shapes);
- return builder->create<fir::EmboxOp>(loc, boxTy, boundArray, shapeOp);
+/// Collects the canonical list of all host associated symbols. These bindings
+/// must be aggregated into a tuple which can then be added to each of the
+/// internal procedure declarations and passed at each call site.
+void FirConverter::collectHostAssociatedVariables(
+ Fortran::lower::pft::FunctionLikeUnit &funit,
+ llvm::SetVector<const Fortran::semantics::Symbol *> &escapees) {
+ const Fortran::semantics::Scope *internalScope =
+ funit.getSubprogramSymbol().scope();
+ assert(internalScope && "internal procedures symbol must create a scope");
+ auto addToListIfEscapee = [&](const Fortran::semantics::Symbol &sym) {
+ const Fortran::semantics::Symbol &ultimate = sym.GetUltimate();
+ const auto *namelistDetails =
+ ultimate.detailsIf<Fortran::semantics::NamelistDetails>();
+ if (ultimate.has<Fortran::semantics::ObjectEntityDetails>() ||
+ Fortran::semantics::IsProcedurePointer(ultimate) ||
+ Fortran::semantics::IsDummy(sym) || namelistDetails) {
+ const Fortran::semantics::Scope &symbolScope = getSymbolHostScope(sym);
+ if (symbolScope.kind() == Fortran::semantics::Scope::Kind::MainProgram ||
+ symbolScope.kind() == Fortran::semantics::Scope::Kind::Subprogram)
+ if (symbolScope != *internalScope &&
+ symbolScope.Contains(*internalScope)) {
+ if (namelistDetails) {
+ // So far, namelist symbols are processed on the fly in IO and
+ // the related namelist data structure is not added to the symbol
+ // map, so it cannot be passed to the internal procedures.
+ // Instead, all the symbols of the host namelist used in the
+ // internal procedure must be considered as host associated so
+ // that IO lowering can find them when needed.
+ for (const auto &namelistObject : namelistDetails->objects())
+ escapees.insert(&*namelistObject);
+ } else {
+ escapees.insert(&ultimate);
+ }
+ }
+ }
+ };
+ Fortran::lower::pft::visitAllSymbols(funit, addToListIfEscapee);
}
-// Generate pointer assignment with possibly empty bounds-spec. R1035: a
-// bounds-spec is a lower bound value.
-void FirConverter::genPointerAssignment(
- mlir::Location loc, const Fortran::evaluate::Assignment &assign,
- const Fortran::evaluate::Assignment::BoundsSpec &lbExprs) {
- Fortran::lower::StatementContext stmtCtx;
+//===--------------------------------------------------------------------===//
+// Helper member functions
+//===--------------------------------------------------------------------===//
- if (!lowerToHighLevelFIR() && Fortran::evaluate::IsProcedure(assign.rhs))
- TODO(loc, "procedure pointer assignment");
- if (Fortran::evaluate::IsProcedurePointer(assign.lhs)) {
- hlfir::Entity lhs = Fortran::lower::convertExprToHLFIR(
- loc, *this, assign.lhs, localSymbols, stmtCtx);
- if (Fortran::evaluate::IsNullProcedurePointer(assign.rhs)) {
- auto boxTy{Fortran::lower::getUntypedBoxProcType(&getMLIRContext())};
- hlfir::Entity rhs(fir::factory::createNullBoxProc(*builder, loc, boxTy));
- builder->createStoreWithConvert(loc, rhs, lhs);
- return;
+/// Find the symbol in the local map or return null.
+Fortran::lower::SymbolBox
+FirConverter::lookupSymbol(const Fortran::semantics::Symbol &sym,
+ Fortran::lower::SymMap *symMap) {
+ symMap = symMap ? symMap : &localSymbols;
+ if (lowerToHighLevelFIR()) {
+ if (std::optional<fir::FortranVariableOpInterface> var =
+ symMap->lookupVariableDefinition(sym)) {
+ auto exv = hlfir::translateToExtendedValue(toLocation(), *builder, *var);
+ return exv.match(
+ [](mlir::Value x) -> Fortran::lower::SymbolBox {
+ return Fortran::lower::SymbolBox::Intrinsic{x};
+ },
+ [](auto x) -> Fortran::lower::SymbolBox { return x; });
}
- hlfir::Entity rhs(getBase(Fortran::lower::convertExprToAddress(
- loc, *this, assign.rhs, localSymbols, stmtCtx)));
- builder->createStoreWithConvert(loc, rhs, lhs);
- return;
- }
- std::optional<Fortran::evaluate::DynamicType> lhsType = assign.lhs.GetType();
- // Delegate pointer association to unlimited polymorphic pointer
- // to the runtime. element size, type code, attribute and of
- // course base_addr might need to be updated.
- if (lhsType && lhsType->IsPolymorphic()) {
- if (!lowerToHighLevelFIR() && explicitIterationSpace())
- TODO(loc, "polymorphic pointer assignment in FORALL");
- llvm::SmallVector<mlir::Value> lbounds;
- for (const Fortran::evaluate::ExtentExpr &lbExpr : lbExprs)
- lbounds.push_back(fir::getBase(genExprValue(toEvExpr(lbExpr), stmtCtx)));
- fir::MutableBoxValue lhsMutableBox = genExprMutableBox(loc, assign.lhs);
- if (Fortran::evaluate::UnwrapExpr<Fortran::evaluate::NullPointer>(
- assign.rhs)) {
- fir::factory::disassociateMutableBox(*builder, loc, lhsMutableBox);
- return;
- }
- mlir::Value lhs = lhsMutableBox.getAddr();
- mlir::Value rhs = fir::getBase(genExprBox(loc, assign.rhs, stmtCtx));
- if (!lbounds.empty()) {
- mlir::Value boundsDesc = createLboundArray(lbounds, loc);
- Fortran::lower::genPointerAssociateLowerBounds(*builder, loc, lhs, rhs,
- boundsDesc);
- return;
- }
- Fortran::lower::genPointerAssociate(*builder, loc, lhs, rhs);
- return;
+ // Entry character result represented as an argument pair
+ // needs to be represented in the symbol table even before
+ // we can create DeclareOp for it. The temporary mapping
+ // is EmboxCharOp that conveys the address and length information.
+ // After mapSymbolAttributes is done, the mapping is replaced
+ // with the new DeclareOp, and the following table lookups
+ // do not reach here.
+ if (sym.IsFuncResult())
+ if (const Fortran::semantics::DeclTypeSpec *declTy = sym.GetType())
+ if (declTy->category() ==
+ Fortran::semantics::DeclTypeSpec::Category::Character)
+ return symMap->lookupSymbol(sym);
+
+ // Procedure dummies are not mapped with an hlfir.declare because
+ // they are not "variable" (cannot be assigned to), and it would
+ // make hlfir.declare more complex than it needs to to allow this.
+ // Do a regular lookup.
+ if (Fortran::semantics::IsProcedure(sym))
+ return symMap->lookupSymbol(sym);
+
+ // Commonblock names are not variables, but in some lowerings (like
+ // OpenMP) it is useful to maintain the address of the commonblock in an
+ // MLIR value and query it. hlfir.declare need not be created for these.
+ if (sym.detailsIf<Fortran::semantics::CommonBlockDetails>())
+ return symMap->lookupSymbol(sym);
+
+ return {};
}
+ if (Fortran::lower::SymbolBox v = symMap->lookupSymbol(sym))
+ return v;
+ return {};
+}
- llvm::SmallVector<mlir::Value> lbounds;
- for (const Fortran::evaluate::ExtentExpr &lbExpr : lbExprs)
- lbounds.push_back(fir::getBase(genExprValue(toEvExpr(lbExpr), stmtCtx)));
- if (!lowerToHighLevelFIR() && explicitIterationSpace()) {
- // Pointer assignment in FORALL context. Copy the rhs box value
- // into the lhs box variable.
- genArrayAssignment(assign, stmtCtx, lbounds);
- return;
+/// Add the symbol to the local map and return `true`. If the symbol is
+/// already in the map and \p forced is `false`, the map is not updated.
+/// Instead the value `false` is returned.
+bool FirConverter::addSymbol(const Fortran::semantics::SymbolRef sym,
+ fir::ExtendedValue val, bool forced) {
+ if (!forced && lookupSymbol(sym))
+ return false;
+ if (lowerToHighLevelFIR()) {
+ Fortran::lower::genDeclareSymbol(*this, localSymbols, sym, val,
+ fir::FortranVariableFlagsEnum::None,
+ forced);
+ } else {
+ localSymbols.addSymbol(sym, val, forced);
}
- fir::MutableBoxValue lhs = genExprMutableBox(loc, assign.lhs);
- Fortran::lower::associateMutableBox(*this, loc, lhs, assign.rhs, lbounds,
- stmtCtx);
+ return true;
}
-// Create the 2 x newRank array with the bounds to be passed to the runtime as
-// a descriptor.
-mlir::Value FirConverter::createBoundArray(llvm::ArrayRef<mlir::Value> lbounds,
- llvm::ArrayRef<mlir::Value> ubounds,
- mlir::Location loc) {
- assert(lbounds.size() && ubounds.size());
- mlir::Type indexTy = builder->getIndexType();
- mlir::Type boundArrayTy = fir::SequenceType::get(
- {2, static_cast<int64_t>(lbounds.size())}, builder->getI64Type());
- mlir::Value boundArray = builder->create<fir::AllocaOp>(loc, boundArrayTy);
- mlir::Value array = builder->create<fir::UndefOp>(loc, boundArrayTy);
- for (unsigned i = 0; i < lbounds.size(); ++i) {
- array = builder->create<fir::InsertValueOp>(
- loc, boundArrayTy, array, lbounds[i],
- builder->getArrayAttr(
- {builder->getIntegerAttr(builder->getIndexType(), 0),
- builder->getIntegerAttr(builder->getIndexType(),
- static_cast<int>(i))}));
- array = builder->create<fir::InsertValueOp>(
- loc, boundArrayTy, array, ubounds[i],
- builder->getArrayAttr(
- {builder->getIntegerAttr(builder->getIndexType(), 1),
- builder->getIntegerAttr(builder->getIndexType(),
- static_cast<int>(i))}));
- }
- builder->create<fir::StoreOp>(loc, array, boundArray);
- mlir::Type boxTy = fir::BoxType::get(boundArrayTy);
- mlir::Value ext =
- builder->createIntegerConstant(loc, indexTy, lbounds.size());
- mlir::Value c2 = builder->createIntegerConstant(loc, indexTy, 2);
- llvm::SmallVector<mlir::Value> shapes = {c2, ext};
- mlir::Value shapeOp = builder->genShape(loc, shapes);
- return builder->create<fir::EmboxOp>(loc, boxTy, boundArray, shapeOp);
+/// Map a block argument to a result or dummy symbol. This is not the
+/// definitive mapping. The specification expression have not been lowered
+/// yet. The final mapping will be done using this pre-mapping in
+/// Fortran::lower::mapSymbolAttributes.
+bool FirConverter::mapBlockArgToDummyOrResult(
+ const Fortran::semantics::SymbolRef sym, mlir::Value val, bool forced) {
+ if (!forced && lookupSymbol(sym))
+ return false;
+ localSymbols.addSymbol(sym, val, forced);
+ return true;
}
-// Pointer assignment with bounds-remapping. R1036: a bounds-remapping is a
-// pair, lower bound and upper bound.
-void FirConverter::genPointerAssignment(
- mlir::Location loc, const Fortran::evaluate::Assignment &assign,
- const Fortran::evaluate::Assignment::BoundsRemapping &boundExprs) {
- Fortran::lower::StatementContext stmtCtx;
- llvm::SmallVector<mlir::Value> lbounds;
- llvm::SmallVector<mlir::Value> ubounds;
- for (const std::pair<Fortran::evaluate::ExtentExpr,
- Fortran::evaluate::ExtentExpr> &pair : boundExprs) {
- const Fortran::evaluate::ExtentExpr &lbExpr = pair.first;
- const Fortran::evaluate::ExtentExpr &ubExpr = pair.second;
- lbounds.push_back(fir::getBase(genExprValue(toEvExpr(lbExpr), stmtCtx)));
- ubounds.push_back(fir::getBase(genExprValue(toEvExpr(ubExpr), stmtCtx)));
+/// Generate the address of loop variable \p sym.
+/// If \p sym is not mapped yet, allocate local storage for it.
+mlir::Value
+FirConverter::genLoopVariableAddress(mlir::Location loc,
+ const Fortran::semantics::Symbol &sym,
+ bool isUnordered) {
+ if (isUnordered || sym.has<Fortran::semantics::HostAssocDetails>() ||
+ sym.has<Fortran::semantics::UseDetails>()) {
+ if (!shallowLookupSymbol(sym)) {
+ // Do concurrent loop variables are not mapped yet since they are local
+ // to the Do concurrent scope (same for OpenMP loops).
+ mlir::OpBuilder::InsertPoint insPt = builder->saveInsertionPoint();
+ builder->setInsertionPointToStart(builder->getAllocaBlock());
+ mlir::Type tempTy = genType(sym);
+ mlir::Value temp =
+ builder->createTemporaryAlloc(loc, tempTy, toStringRef(sym.name()));
+ bindIfNewSymbol(sym, temp);
+ builder->restoreInsertionPoint(insPt);
+ }
}
+ auto entry = lookupSymbol(sym);
+ (void)entry;
+ assert(entry && "loop control variable must already be in map");
+ Fortran::lower::StatementContext stmtCtx;
+ return fir::getBase(
+ genExprAddr(Fortran::evaluate::AsGenericExpr(sym).value(), stmtCtx));
+}
- std::optional<Fortran::evaluate::DynamicType> lhsType = assign.lhs.GetType();
- std::optional<Fortran::evaluate::DynamicType> rhsType = assign.rhs.GetType();
- // Polymorphic lhs/rhs need more care. See F2018 10.2.2.3.
- if ((lhsType && lhsType->IsPolymorphic()) ||
- (rhsType && rhsType->IsPolymorphic())) {
- if (!lowerToHighLevelFIR() && explicitIterationSpace())
- TODO(loc, "polymorphic pointer assignment in FORALL");
+/// Insert a new block before \p block. Leave the insertion point unchanged.
+mlir::Block *FirConverter::insertBlock(mlir::Block *block) {
+ mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
+ mlir::Block *newBlock = builder->createBlock(block);
+ builder->restoreInsertionPoint(insertPt);
+ return newBlock;
+}
- fir::MutableBoxValue lhsMutableBox = genExprMutableBox(loc, assign.lhs);
- if (Fortran::evaluate::UnwrapExpr<Fortran::evaluate::NullPointer>(
- assign.rhs)) {
- fir::factory::disassociateMutableBox(*builder, loc, lhsMutableBox);
- return;
- }
- mlir::Value lhs = lhsMutableBox.getAddr();
- mlir::Value rhs = fir::getBase(genExprBox(loc, assign.rhs, stmtCtx));
- mlir::Value boundsDesc = createBoundArray(lbounds, ubounds, loc);
- Fortran::lower::genPointerAssociateRemapping(*builder, loc, lhs, rhs,
- boundsDesc);
- return;
- }
- if (!lowerToHighLevelFIR() && explicitIterationSpace()) {
- // Pointer assignment in FORALL context. Copy the rhs box value
- // into the lhs box variable.
- genArrayAssignment(assign, stmtCtx, lbounds, ubounds);
- return;
- }
- fir::MutableBoxValue lhs = genExprMutableBox(loc, assign.lhs);
- if (Fortran::evaluate::UnwrapExpr<Fortran::evaluate::NullPointer>(
- assign.rhs)) {
- fir::factory::disassociateMutableBox(*builder, loc, lhs);
- return;
- }
- // Do not generate a temp in case rhs is an array section.
- fir::ExtendedValue rhs =
- Fortran::lower::isArraySectionWithoutVectorSubscript(assign.rhs)
- ? Fortran::lower::createSomeArrayBox(*this, assign.rhs, localSymbols,
- stmtCtx)
- : genExprAddr(assign.rhs, stmtCtx);
- fir::factory::associateMutableBoxWithRemap(*builder, loc, lhs, rhs, lbounds,
- ubounds);
- if (!lowerToHighLevelFIR() && explicitIterationSpace()) {
- mlir::ValueRange inners = explicitIterSpace.getInnerArgs();
- if (!inners.empty())
- builder->create<fir::ResultOp>(loc, inners);
- }
+Fortran::lower::pft::Evaluation &
+FirConverter::evalOfLabel(Fortran::parser::Label label) {
+ const Fortran::lower::pft::LabelEvalMap &labelEvaluationMap =
+ getEval().getOwningProcedure()->labelEvaluationMap;
+ const auto iter = labelEvaluationMap.find(label);
+ assert(iter != labelEvaluationMap.end() && "label missing from map");
+ return *iter->second;
}
-/// Given converted LHS and RHS of the assignment, materialize any
-/// implicit conversion of the RHS to the LHS type. The front-end
-/// usually already makes those explicit, except for non-standard
-/// LOGICAL <-> INTEGER, or if the LHS is a whole allocatable
-/// (making the conversion explicit in the front-end would prevent
-/// propagation of the LHS lower bound in the reallocation).
-/// If array temporaries or values are created, the cleanups are
-/// added in the statement context.
-hlfir::Entity
-FirConverter::genImplicitConvert(const Fortran::evaluate::Assignment &assign,
- hlfir::Entity rhs, bool preserveLowerBounds,
- Fortran::lower::StatementContext &stmtCtx) {
+void FirConverter::genConditionalBranch(mlir::Value cond,
+ mlir::Block *trueTarget,
+ mlir::Block *falseTarget) {
+ assert(trueTarget && "missing conditional branch true block");
+ assert(falseTarget && "missing conditional branch false block");
mlir::Location loc = toLocation();
- auto &builder = getFirOpBuilder();
- mlir::Type toType = genType(assign.lhs);
- auto valueAndPair = hlfir::genTypeAndKindConvert(loc, builder, rhs, toType,
- preserveLowerBounds);
- if (valueAndPair.second)
- stmtCtx.attachCleanup(*valueAndPair.second);
- return hlfir::Entity{valueAndPair.first};
+ mlir::Value bcc = builder->createConvert(loc, builder->getI1Type(), cond);
+ builder->create<mlir::cf::CondBranchOp>(loc, bcc, trueTarget, std::nullopt,
+ falseTarget, std::nullopt);
}
-void FirConverter::genCleanUpInRegionIfAny(
- mlir::Location loc, fir::FirOpBuilder &builder, mlir::Region ®ion,
- Fortran::lower::StatementContext &context) {
- if (!context.hasCode())
- return;
- mlir::OpBuilder::InsertPoint insertPt = builder.saveInsertionPoint();
- if (region.empty())
- builder.createBlock(®ion);
- else
- builder.setInsertionPointToEnd(®ion.front());
- context.finalizeAndPop();
- hlfir::YieldOp::ensureTerminator(region, builder, loc);
- builder.restoreInsertionPoint(insertPt);
+void FirConverter::genConditionalBranch(
+ const Fortran::parser::ScalarLogicalExpr &expr, mlir::Block *trueTarget,
+ mlir::Block *falseTarget) {
+ Fortran::lower::StatementContext stmtCtx;
+ mlir::Value cond =
+ createFIRExpr(toLocation(), Fortran::semantics::GetExpr(expr), stmtCtx);
+ stmtCtx.finalizeAndReset();
+ genConditionalBranch(cond, trueTarget, falseTarget);
}
-bool FirConverter::firstDummyIsPointerOrAllocatable(
- const Fortran::evaluate::ProcedureRef &userDefinedAssignment) {
- using DummyAttr = Fortran::evaluate::characteristics::DummyDataObject::Attr;
- if (auto procedure =
- Fortran::evaluate::characteristics::Procedure::Characterize(
- userDefinedAssignment.proc(), getFoldingContext()))
- if (!procedure->dummyArguments.empty())
- if (const auto *dataArg =
- std::get_if<Fortran::evaluate::characteristics::DummyDataObject>(
- &procedure->dummyArguments[0].u))
- return dataArg->attrs.test(DummyAttr::Pointer) ||
- dataArg->attrs.test(DummyAttr::Allocatable);
+void FirConverter::genConditionalBranch(
+ const Fortran::parser::ScalarLogicalExpr &expr,
+ Fortran::lower::pft::Evaluation *trueTarget,
+ Fortran::lower::pft::Evaluation *falseTarget) {
+ Fortran::lower::StatementContext stmtCtx;
+ mlir::Value cond =
+ createFIRExpr(toLocation(), Fortran::semantics::GetExpr(expr), stmtCtx);
+ stmtCtx.finalizeAndReset();
+ genConditionalBranch(cond, trueTarget->block, falseTarget->block);
+}
+
+/// Return the nearest active ancestor construct of \p eval, or nullptr.
+Fortran::lower::pft::Evaluation *
+FirConverter::getActiveAncestor(const Fortran::lower::pft::Evaluation &eval) {
+ Fortran::lower::pft::Evaluation *ancestor = eval.parentConstruct;
+ for (; ancestor; ancestor = ancestor->parentConstruct)
+ if (ancestor->activeConstruct)
+ break;
+ return ancestor;
+}
+
+/// Return the predicate: "a branch to \p targetEval has exit code".
+bool FirConverter::hasExitCode(
+ const Fortran::lower::pft::Evaluation &targetEval) {
+ Fortran::lower::pft::Evaluation *activeAncestor =
+ getActiveAncestor(targetEval);
+ for (auto it = activeConstructStack.rbegin(),
+ rend = activeConstructStack.rend();
+ it != rend; ++it) {
+ if (&it->eval == activeAncestor)
+ break;
+ if (it->stmtCtx.hasCode())
+ return true;
+ }
return false;
}
-void FirConverter::genDataAssignment(
- const Fortran::evaluate::Assignment &assign,
- const Fortran::evaluate::ProcedureRef *userDefinedAssignment) {
- mlir::Location loc = getCurrentLocation();
- fir::FirOpBuilder &builder = getFirOpBuilder();
- // Gather some information about the assignment that will impact how it is
- // lowered.
- const bool isWholeAllocatableAssignment =
- !userDefinedAssignment && !isInsideHlfirWhere() &&
- Fortran::lower::isWholeAllocatable(assign.lhs);
- const bool isUserDefAssignToPointerOrAllocatable =
- userDefinedAssignment &&
- firstDummyIsPointerOrAllocatable(*userDefinedAssignment);
- std::optional<Fortran::evaluate::DynamicType> lhsType = assign.lhs.GetType();
- const bool keepLhsLengthInAllocatableAssignment =
- isWholeAllocatableAssignment && lhsType.has_value() &&
- lhsType->category() == Fortran::common::TypeCategory::Character &&
- !lhsType->HasDeferredTypeParameter();
- const bool lhsHasVectorSubscripts =
- Fortran::evaluate::HasVectorSubscript(assign.lhs);
+/// Generate a branch to \p targetEval after generating on-exit code for
+/// any enclosing construct scopes that are exited by taking the branch.
+void FirConverter::genConstructExitBranch(
+ const Fortran::lower::pft::Evaluation &targetEval) {
+ Fortran::lower::pft::Evaluation *activeAncestor =
+ getActiveAncestor(targetEval);
+ for (auto it = activeConstructStack.rbegin(),
+ rend = activeConstructStack.rend();
+ it != rend; ++it) {
+ if (&it->eval == activeAncestor)
+ break;
+ it->stmtCtx.finalizeAndKeep();
+ }
+ genBranch(targetEval.block);
+}
- // Helper to generate the code evaluating the right-hand side.
- auto evaluateRhs = [&](Fortran::lower::StatementContext &stmtCtx) {
- hlfir::Entity rhs = Fortran::lower::convertExprToHLFIR(
- loc, *this, assign.rhs, localSymbols, stmtCtx);
- // Load trivial scalar RHS to allow the loads to be hoisted outside of
- // loops early if possible. This also dereferences pointer and
- // allocatable RHS: the target is being assigned from.
- rhs = hlfir::loadTrivialScalar(loc, builder, rhs);
- // In intrinsic assignments, the LHS type may not match the RHS type, in
- // which case an implicit conversion of the LHS must be done. The
- // front-end usually makes it explicit, unless it cannot (whole
- // allocatable LHS or Logical<->Integer assignment extension). Recognize
- // any type mismatches here and insert explicit scalar convert or
- // ElementalOp for array assignment. Preserve the RHS lower bounds on the
- // converted entity in case of assignment to whole allocatables so to
- // propagate the lower bounds to the LHS in case of reallocation.
- if (!userDefinedAssignment)
- rhs = genImplicitConvert(assign, rhs, isWholeAllocatableAssignment,
- stmtCtx);
- return rhs;
- };
+/// Generate a SelectOp or branch sequence that compares \p selector against
+/// values in \p valueList and targets corresponding labels in \p labelList.
+/// If no value matches the selector, branch to \p defaultEval.
+///
+/// Three cases require special processing.
+///
+/// An empty \p valueList indicates an ArithmeticIfStmt context that requires
+/// two comparisons against 0 or 0.0. The selector may have either INTEGER
+/// or REAL type.
+///
+/// A nonpositive \p valuelist value indicates an IO statement context
+/// (0 for ERR, -1 for END, -2 for EOR). An ERR branch must be taken for
+/// any positive (IOSTAT) value. A missing (zero) label requires a branch
+/// to \p defaultEval for that value.
+///
+/// A non-null \p errorBlock indicates an AssignedGotoStmt context that
+/// must always branch to an explicit target. There is no valid defaultEval
+/// in this case. Generate a branch to \p errorBlock for an AssignedGotoStmt
+/// that violates this program requirement.
+///
+/// If this is not an ArithmeticIfStmt and no targets have exit code,
+/// generate a SelectOp. Otherwise, for each target, if it has exit code,
+/// branch to a new block, insert exit code, and then branch to the target.
+/// Otherwise, branch directly to the target.
+void FirConverter::genMultiwayBranch(
+ mlir::Value selector, llvm::SmallVector<int64_t> valueList,
+ llvm::SmallVector<Fortran::parser::Label> labelList,
+ const Fortran::lower::pft::Evaluation &defaultEval,
+ mlir::Block *errorBlock) {
+ bool inArithmeticIfContext = valueList.empty();
+ assert(((inArithmeticIfContext && labelList.size() == 2) ||
+ (valueList.size() && labelList.size() == valueList.size())) &&
+ "mismatched multiway branch targets");
+ mlir::Block *defaultBlock = errorBlock ? errorBlock : defaultEval.block;
+ bool defaultHasExitCode = !errorBlock && hasExitCode(defaultEval);
+ bool hasAnyExitCode = defaultHasExitCode;
+ if (!hasAnyExitCode)
+ for (auto label : labelList)
+ if (label && hasExitCode(evalOfLabel(label))) {
+ hasAnyExitCode = true;
+ break;
+ }
+ mlir::Location loc = toLocation();
+ size_t branchCount = labelList.size();
+ if (!inArithmeticIfContext && !hasAnyExitCode &&
+ !getEval().forceAsUnstructured()) { // from -no-structured-fir option
+ // Generate a SelectOp.
+ llvm::SmallVector<mlir::Block *> blockList;
+ for (auto label : labelList) {
+ mlir::Block *block = label ? evalOfLabel(label).block : defaultEval.block;
+ assert(block && "missing multiway branch block");
+ blockList.push_back(block);
+ }
+ blockList.push_back(defaultBlock);
+ if (valueList[branchCount - 1] == 0) // Swap IO ERR and default blocks.
+ std::swap(blockList[branchCount - 1], blockList[branchCount]);
+ builder->create<fir::SelectOp>(loc, selector, valueList, blockList);
+ return;
+ }
+ mlir::Type selectorType = selector.getType();
+ bool realSelector = selectorType.isa<mlir::FloatType>();
+ assert((inArithmeticIfContext || !realSelector) && "invalid selector type");
+ mlir::Value zero;
+ if (inArithmeticIfContext)
+ zero = realSelector ? builder->create<mlir::arith::ConstantOp>(
+ loc, selectorType,
+ builder->getFloatAttr(selectorType, 0.0))
+ : builder->createIntegerConstant(loc, selectorType, 0);
+ for (auto label : llvm::enumerate(labelList)) {
+ mlir::Value cond;
+ if (realSelector) // inArithmeticIfContext
+ cond = builder->create<mlir::arith::CmpFOp>(
+ loc,
+ label.index() == 0 ? mlir::arith::CmpFPredicate::OLT
+ : mlir::arith::CmpFPredicate::OGT,
+ selector, zero);
+ else if (inArithmeticIfContext) // INTEGER selector
+ cond = builder->create<mlir::arith::CmpIOp>(
+ loc,
+ label.index() == 0 ? mlir::arith::CmpIPredicate::slt
+ : mlir::arith::CmpIPredicate::sgt,
+ selector, zero);
+ else // A value of 0 is an IO ERR branch: invert comparison.
+ cond = builder->create<mlir::arith::CmpIOp>(
+ loc,
+ valueList[label.index()] == 0 ? mlir::arith::CmpIPredicate::ne
+ : mlir::arith::CmpIPredicate::eq,
+ selector,
+ builder->createIntegerConstant(loc, selectorType,
+ valueList[label.index()]));
+ // Branch to a new block with exit code and then to the target, or branch
+ // directly to the target. defaultBlock is the "else" target.
+ bool lastBranch = label.index() == branchCount - 1;
+ mlir::Block *nextBlock =
+ lastBranch && !defaultHasExitCode
+ ? defaultBlock
+ : builder->getBlock()->splitBlock(builder->getInsertionPoint());
+ const Fortran::lower::pft::Evaluation &targetEval =
+ label.value() ? evalOfLabel(label.value()) : defaultEval;
+ if (hasExitCode(targetEval)) {
+ mlir::Block *jumpBlock =
+ builder->getBlock()->splitBlock(builder->getInsertionPoint());
+ genConditionalBranch(cond, jumpBlock, nextBlock);
+ startBlock(jumpBlock);
+ genConstructExitBranch(targetEval);
+ } else {
+ genConditionalBranch(cond, targetEval.block, nextBlock);
+ }
+ if (!lastBranch) {
+ startBlock(nextBlock);
+ } else if (defaultHasExitCode) {
+ startBlock(nextBlock);
+ genConstructExitBranch(defaultEval);
+ }
+ }
+}
+
+//===--------------------------------------------------------------------===//
+// Termination of symbolically referenced execution units
+//===--------------------------------------------------------------------===//
+
+/// END of procedure-like constructs
+///
+/// Generate the cleanup block before the procedure exits
+void FirConverter::genReturnSymbol(
+ const Fortran::semantics::Symbol &functionSymbol) {
+ const Fortran::semantics::Symbol &resultSym =
+ functionSymbol.get<Fortran::semantics::SubprogramDetails>().result();
+ Fortran::lower::SymbolBox resultSymBox = lookupSymbol(resultSym);
+ mlir::Location loc = toLocation();
+ if (!resultSymBox) {
+ mlir::emitError(loc, "internal error when processing function return");
+ return;
+ }
+ mlir::Value resultVal = resultSymBox.match(
+ [&](const fir::CharBoxValue &x) -> mlir::Value {
+ if (Fortran::semantics::IsBindCProcedure(functionSymbol))
+ return builder->create<fir::LoadOp>(loc, x.getBuffer());
+ return fir::factory::CharacterExprHelper{*builder, loc}.createEmboxChar(
+ x.getBuffer(), x.getLen());
+ },
+ [&](const fir::MutableBoxValue &x) -> mlir::Value {
+ mlir::Value resultRef = resultSymBox.getAddr();
+ mlir::Value load = builder->create<fir::LoadOp>(loc, resultRef);
+ unsigned rank = x.rank();
+ if (x.isAllocatable() && rank > 0) {
+ // ALLOCATABLE array result must have default lower bounds.
+ // At the call site the result box of a function reference
+ // might be considered having default lower bounds, but
+ // the runtime box should probably comply with this assumption
+ // as well. If the result box has proper lbounds in runtime,
+ // this may improve the debugging experience of Fortran apps.
+ // We may consider removing this, if the overhead of setting
+ // default lower bounds is too big.
+ mlir::Value one =
+ builder->createIntegerConstant(loc, builder->getIndexType(), 1);
+ llvm::SmallVector<mlir::Value> lbounds{rank, one};
+ auto shiftTy = fir::ShiftType::get(builder->getContext(), rank);
+ mlir::Value shiftOp =
+ builder->create<fir::ShiftOp>(loc, shiftTy, lbounds);
+ load = builder->create<fir::ReboxOp>(
+ loc, load.getType(), load, shiftOp, /*slice=*/mlir::Value{});
+ }
+ return load;
+ },
+ [&](const auto &) -> mlir::Value {
+ mlir::Value resultRef = resultSymBox.getAddr();
+ mlir::Type resultType = genType(resultSym);
+ mlir::Type resultRefType = builder->getRefType(resultType);
+ // A function with multiple entry points returning different types
+ // tags all result variables with one of the largest types to allow
+ // them to share the same storage. Convert this to the actual type.
+ if (resultRef.getType() != resultRefType)
+ resultRef = builder->createConvert(loc, resultRefType, resultRef);
+ return builder->create<fir::LoadOp>(loc, resultRef);
+ });
+ bridge.openAccCtx().finalizeAndPop();
+ bridge.fctCtx().finalizeAndPop();
+ builder->create<mlir::func::ReturnOp>(loc, resultVal);
+}
+
+void FirConverter::genFIRProcedureExit(
+ Fortran::lower::pft::FunctionLikeUnit &funit,
+ const Fortran::semantics::Symbol &symbol) {
+ if (mlir::Block *finalBlock = funit.finalBlock) {
+ // The current block must end with a terminator.
+ if (blockIsUnterminated())
+ builder->create<mlir::cf::BranchOp>(toLocation(), finalBlock);
+ // Set insertion point to final block.
+ builder->setInsertionPoint(finalBlock, finalBlock->end());
+ }
+ if (Fortran::semantics::IsFunction(symbol)) {
+ genReturnSymbol(symbol);
+ } else if (Fortran::semantics::HasAlternateReturns(symbol)) {
+ mlir::Value retval =
+ builder->create<fir::LoadOp>(toLocation(), getAltReturnResult(symbol));
+ bridge.openAccCtx().finalizeAndPop();
+ bridge.fctCtx().finalizeAndPop();
+ builder->create<mlir::func::ReturnOp>(toLocation(), retval);
+ } else {
+ bridge.openAccCtx().finalizeAndPop();
+ bridge.fctCtx().finalizeAndPop();
+ genExitRoutine();
+ }
+}
+
+//
+// Statements that have control-flow semantics
+//
+
+mlir::func::FuncOp FirConverter::getFunc(llvm::StringRef name,
+ mlir::FunctionType ty) {
+ if (mlir::func::FuncOp func = builder->getNamedFunction(name)) {
+ assert(func.getFunctionType() == ty);
+ return func;
+ }
+ return builder->createFunction(toLocation(), name, ty);
+}
+
+/// Generate FIR to begin a structured or unstructured increment loop nest.
+void FirConverter::genFIRIncrementLoopBegin(
+ IncrementLoopNestInfo &incrementLoopNestInfo) {
+ assert(!incrementLoopNestInfo.empty() && "empty loop nest");
+ mlir::Location loc = toLocation();
+ for (IncrementLoopInfo &info : incrementLoopNestInfo) {
+ info.loopVariable =
+ genLoopVariableAddress(loc, *info.loopVariableSym, info.isUnordered);
+ mlir::Value lowerValue = genControlValue(info.lowerExpr, info);
+ mlir::Value upperValue = genControlValue(info.upperExpr, info);
+ bool isConst = true;
+ mlir::Value stepValue = genControlValue(
+ info.stepExpr, info, info.isStructured() ? nullptr : &isConst);
+ // Use a temp variable for unstructured loops with non-const step.
+ if (!isConst) {
+ info.stepVariable = builder->createTemporary(loc, stepValue.getType());
+ builder->create<fir::StoreOp>(loc, stepValue, info.stepVariable);
+ }
+
+ // Structured loop - generate fir.do_loop.
+ if (info.isStructured()) {
+ mlir::Type loopVarType = info.getLoopVariableType();
+ mlir::Value loopValue;
+ if (info.isUnordered) {
+ // The loop variable value is explicitly updated.
+ info.doLoop = builder->create<fir::DoLoopOp>(
+ loc, lowerValue, upperValue, stepValue, /*unordered=*/true);
+ builder->setInsertionPointToStart(info.doLoop.getBody());
+ loopValue = builder->createConvert(loc, loopVarType,
+ info.doLoop.getInductionVar());
+ } else {
+ // The loop variable is a doLoop op argument.
+ info.doLoop = builder->create<fir::DoLoopOp>(
+ loc, lowerValue, upperValue, stepValue, /*unordered=*/false,
+ /*finalCountValue=*/true,
+ builder->createConvert(loc, loopVarType, lowerValue));
+ builder->setInsertionPointToStart(info.doLoop.getBody());
+ loopValue = info.doLoop.getRegionIterArgs()[0];
+ }
+ // Update the loop variable value in case it has non-index references.
+ builder->create<fir::StoreOp>(loc, loopValue, info.loopVariable);
+ if (info.maskExpr) {
+ Fortran::lower::StatementContext stmtCtx;
+ mlir::Value maskCond = createFIRExpr(loc, info.maskExpr, stmtCtx);
+ stmtCtx.finalizeAndReset();
+ mlir::Value maskCondCast =
+ builder->createConvert(loc, builder->getI1Type(), maskCond);
+ auto ifOp = builder->create<fir::IfOp>(loc, maskCondCast,
+ /*withElseRegion=*/false);
+ builder->setInsertionPointToStart(&ifOp.getThenRegion().front());
+ }
+ if (info.hasLocalitySpecs())
+ handleLocalitySpecs(info);
+ continue;
+ }
+
+ // Unstructured loop preheader - initialize tripVariable and loopVariable.
+ mlir::Value tripCount;
+ if (info.hasRealControl) {
+ auto diff1 =
+ builder->create<mlir::arith::SubFOp>(loc, upperValue, lowerValue);
+ auto diff2 = builder->create<mlir::arith::AddFOp>(loc, diff1, stepValue);
+ tripCount = builder->create<mlir::arith::DivFOp>(loc, diff2, stepValue);
+ tripCount =
+ builder->createConvert(loc, builder->getIndexType(), tripCount);
+ } else {
+ auto diff1 =
+ builder->create<mlir::arith::SubIOp>(loc, upperValue, lowerValue);
+ auto diff2 = builder->create<mlir::arith::AddIOp>(loc, diff1, stepValue);
+ tripCount = builder->create<mlir::arith::DivSIOp>(loc, diff2, stepValue);
+ }
+ if (forceLoopToExecuteOnce) { // minimum tripCount is 1
+ mlir::Value one =
+ builder->createIntegerConstant(loc, tripCount.getType(), 1);
+ auto cond = builder->create<mlir::arith::CmpIOp>(
+ loc, mlir::arith::CmpIPredicate::slt, tripCount, one);
+ tripCount =
+ builder->create<mlir::arith::SelectOp>(loc, cond, one, tripCount);
+ }
+ info.tripVariable = builder->createTemporary(loc, tripCount.getType());
+ builder->create<fir::StoreOp>(loc, tripCount, info.tripVariable);
+ builder->create<fir::StoreOp>(loc, lowerValue, info.loopVariable);
+
+ // Unstructured loop header - generate loop condition and mask.
+ // Note - Currently there is no way to tag a loop as a concurrent loop.
+ startBlock(info.headerBlock);
+ tripCount = builder->create<fir::LoadOp>(loc, info.tripVariable);
+ mlir::Value zero =
+ builder->createIntegerConstant(loc, tripCount.getType(), 0);
+ auto cond = builder->create<mlir::arith::CmpIOp>(
+ loc, mlir::arith::CmpIPredicate::sgt, tripCount, zero);
+ if (info.maskExpr) {
+ genConditionalBranch(cond, info.maskBlock, info.exitBlock);
+ startBlock(info.maskBlock);
+ mlir::Block *latchBlock = getEval().getLastNestedEvaluation().block;
+ assert(latchBlock && "missing masked concurrent loop latch block");
+ Fortran::lower::StatementContext stmtCtx;
+ mlir::Value maskCond = createFIRExpr(loc, info.maskExpr, stmtCtx);
+ stmtCtx.finalizeAndReset();
+ genConditionalBranch(maskCond, info.bodyBlock, latchBlock);
+ } else {
+ genConditionalBranch(cond, info.bodyBlock, info.exitBlock);
+ if (&info != &incrementLoopNestInfo.back()) // not innermost
+ startBlock(info.bodyBlock); // preheader block of enclosed dimension
+ }
+ if (info.hasLocalitySpecs()) {
+ mlir::OpBuilder::InsertPoint insertPt = builder->saveInsertionPoint();
+ builder->setInsertionPointToStart(info.bodyBlock);
+ handleLocalitySpecs(info);
+ builder->restoreInsertionPoint(insertPt);
+ }
+ }
+}
+
+/// Generate FIR to end a structured or unstructured increment loop nest.
+void FirConverter::genFIRIncrementLoopEnd(
+ IncrementLoopNestInfo &incrementLoopNestInfo) {
+ assert(!incrementLoopNestInfo.empty() && "empty loop nest");
+ mlir::Location loc = toLocation();
+ for (auto it = incrementLoopNestInfo.rbegin(),
+ rend = incrementLoopNestInfo.rend();
+ it != rend; ++it) {
+ IncrementLoopInfo &info = *it;
+ if (info.isStructured()) {
+ // End fir.do_loop.
+ if (info.isUnordered) {
+ builder->setInsertionPointAfter(info.doLoop);
+ continue;
+ }
+ // Decrement tripVariable.
+ builder->setInsertionPointToEnd(info.doLoop.getBody());
+ llvm::SmallVector<mlir::Value, 2> results;
+ results.push_back(builder->create<mlir::arith::AddIOp>(
+ loc, info.doLoop.getInductionVar(), info.doLoop.getStep()));
+ // Step loopVariable to help optimizations such as vectorization.
+ // Induction variable elimination will clean up as necessary.
+ mlir::Value step = builder->createConvert(loc, info.getLoopVariableType(),
+ info.doLoop.getStep());
+ mlir::Value loopVar =
+ builder->create<fir::LoadOp>(loc, info.loopVariable);
+ results.push_back(
+ builder->create<mlir::arith::AddIOp>(loc, loopVar, step));
+ builder->create<fir::ResultOp>(loc, results);
+ builder->setInsertionPointAfter(info.doLoop);
+ // The loop control variable may be used after the loop.
+ builder->create<fir::StoreOp>(loc, info.doLoop.getResult(1),
+ info.loopVariable);
+ continue;
+ }
- // Helper to generate the code evaluating the left-hand side.
- auto evaluateLhs = [&](Fortran::lower::StatementContext &stmtCtx) {
- hlfir::Entity lhs = Fortran::lower::convertExprToHLFIR(
- loc, *this, assign.lhs, localSymbols, stmtCtx);
- // Dereference pointer LHS: the target is being assigned to.
- // Same for allocatables outside of whole allocatable assignments.
- if (!isWholeAllocatableAssignment && !isUserDefAssignToPointerOrAllocatable)
- lhs = hlfir::derefPointersAndAllocatables(loc, builder, lhs);
- return lhs;
- };
+ // Unstructured loop - decrement tripVariable and step loopVariable.
+ mlir::Value tripCount =
+ builder->create<fir::LoadOp>(loc, info.tripVariable);
+ mlir::Value one =
+ builder->createIntegerConstant(loc, tripCount.getType(), 1);
+ tripCount = builder->create<mlir::arith::SubIOp>(loc, tripCount, one);
+ builder->create<fir::StoreOp>(loc, tripCount, info.tripVariable);
+ mlir::Value value = builder->create<fir::LoadOp>(loc, info.loopVariable);
+ mlir::Value step;
+ if (info.stepVariable)
+ step = builder->create<fir::LoadOp>(loc, info.stepVariable);
+ else
+ step = genControlValue(info.stepExpr, info);
+ if (info.hasRealControl)
+ value = builder->create<mlir::arith::AddFOp>(loc, value, step);
+ else
+ value = builder->create<mlir::arith::AddIOp>(loc, value, step);
+ builder->create<fir::StoreOp>(loc, value, info.loopVariable);
- if (!isInsideHlfirForallOrWhere() && !lhsHasVectorSubscripts &&
- !userDefinedAssignment) {
- Fortran::lower::StatementContext localStmtCtx;
- hlfir::Entity rhs = evaluateRhs(localStmtCtx);
- hlfir::Entity lhs = evaluateLhs(localStmtCtx);
- builder.create<hlfir::AssignOp>(loc, rhs, lhs, isWholeAllocatableAssignment,
- keepLhsLengthInAllocatableAssignment);
- return;
+ genBranch(info.headerBlock);
+ if (&info != &incrementLoopNestInfo.front()) // not outermost
+ startBlock(info.exitBlock); // latch block of enclosing dimension
}
- // Assignments inside Forall, Where, or assignments to a vector subscripted
- // left-hand side requires using an hlfir.region_assign in HLFIR. The
- // right-hand side and left-hand side must be evaluated inside the
- // hlfir.region_assign regions.
- auto regionAssignOp = builder.create<hlfir::RegionAssignOp>(loc);
+}
- // Lower RHS in its own region.
- builder.createBlock(®ionAssignOp.getRhsRegion());
- Fortran::lower::StatementContext rhsContext;
- hlfir::Entity rhs = evaluateRhs(rhsContext);
- auto rhsYieldOp = builder.create<hlfir::YieldOp>(loc, rhs);
- genCleanUpInRegionIfAny(loc, builder, rhsYieldOp.getCleanup(), rhsContext);
- // Lower LHS in its own region.
- builder.createBlock(®ionAssignOp.getLhsRegion());
- Fortran::lower::StatementContext lhsContext;
- mlir::Value lhsYield = nullptr;
- if (!lhsHasVectorSubscripts) {
- hlfir::Entity lhs = evaluateLhs(lhsContext);
- auto lhsYieldOp = builder.create<hlfir::YieldOp>(loc, lhs);
- genCleanUpInRegionIfAny(loc, builder, lhsYieldOp.getCleanup(), lhsContext);
- lhsYield = lhs;
- } else {
- hlfir::ElementalAddrOp elementalAddr =
- Fortran::lower::convertVectorSubscriptedExprToElementalAddr(
- loc, *this, assign.lhs, localSymbols, lhsContext);
- genCleanUpInRegionIfAny(loc, builder, elementalAddr.getCleanup(),
- lhsContext);
- lhsYield = elementalAddr.getYieldOp().getEntity();
+/// Collect DO CONCURRENT or FORALL loop control information.
+FirConverter::IncrementLoopNestInfo FirConverter::getConcurrentControl(
+ const Fortran::parser::ConcurrentHeader &header,
+ const std::list<Fortran::parser::LocalitySpec> &localityList) {
+ IncrementLoopNestInfo incrementLoopNestInfo;
+ for (const Fortran::parser::ConcurrentControl &control :
+ std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t))
+ incrementLoopNestInfo.emplace_back(
+ *std::get<0>(control.t).symbol, std::get<1>(control.t),
+ std::get<2>(control.t), std::get<3>(control.t), /*isUnordered=*/true);
+ IncrementLoopInfo &info = incrementLoopNestInfo.back();
+ info.maskExpr = Fortran::semantics::GetExpr(
+ std::get<std::optional<Fortran::parser::ScalarLogicalExpr>>(header.t));
+ for (const Fortran::parser::LocalitySpec &x : localityList) {
+ if (const auto *localList =
+ std::get_if<Fortran::parser::LocalitySpec::Local>(&x.u))
+ for (const Fortran::parser::Name &x : localList->v)
+ info.localSymList.push_back(x.symbol);
+ if (const auto *localInitList =
+ std::get_if<Fortran::parser::LocalitySpec::LocalInit>(&x.u))
+ for (const Fortran::parser::Name &x : localInitList->v)
+ info.localInitSymList.push_back(x.symbol);
+ if (const auto *sharedList =
+ std::get_if<Fortran::parser::LocalitySpec::Shared>(&x.u))
+ for (const Fortran::parser::Name &x : sharedList->v)
+ info.sharedSymList.push_back(x.symbol);
}
- assert(lhsYield && "must have been set");
-
- // Add "realloc" flag to hlfir.region_assign.
- if (isWholeAllocatableAssignment)
- TODO(loc, "assignment to a whole allocatable inside FORALL");
+ return incrementLoopNestInfo;
+}
- // Generate the hlfir.region_assign userDefinedAssignment region.
- if (userDefinedAssignment) {
- mlir::Type rhsType = rhs.getType();
- mlir::Type lhsType = lhsYield.getType();
- if (userDefinedAssignment->IsElemental()) {
- rhsType = hlfir::getEntityElementType(rhs);
- lhsType = hlfir::getEntityElementType(hlfir::Entity{lhsYield});
- }
- builder.createBlock(®ionAssignOp.getUserDefinedAssignment(),
- mlir::Region::iterator{}, {rhsType, lhsType},
- {loc, loc});
- auto end = builder.create<fir::FirEndOp>(loc);
- builder.setInsertionPoint(end);
- hlfir::Entity lhsBlockArg{regionAssignOp.getUserAssignmentLhs()};
- hlfir::Entity rhsBlockArg{regionAssignOp.getUserAssignmentRhs()};
- Fortran::lower::convertUserDefinedAssignmentToHLFIR(
- loc, *this, *userDefinedAssignment, lhsBlockArg, rhsBlockArg,
- localSymbols);
+/// Create DO CONCURRENT construct symbol bindings and generate LOCAL_INIT
+/// assignments.
+void FirConverter::handleLocalitySpecs(const IncrementLoopInfo &info) {
+ Fortran::semantics::SemanticsContext &semanticsContext =
+ bridge.getSemanticsContext();
+ for (const Fortran::semantics::Symbol *sym : info.localSymList)
+ createHostAssociateVarClone(*sym);
+ for (const Fortran::semantics::Symbol *sym : info.localInitSymList) {
+ createHostAssociateVarClone(*sym);
+ const auto *hostDetails =
+ sym->detailsIf<Fortran::semantics::HostAssocDetails>();
+ assert(hostDetails && "missing locality spec host symbol");
+ const Fortran::semantics::Symbol *hostSym = &hostDetails->symbol();
+ Fortran::evaluate::ExpressionAnalyzer ea{semanticsContext};
+ Fortran::evaluate::Assignment assign{
+ ea.Designate(Fortran::evaluate::DataRef{*sym}).value(),
+ ea.Designate(Fortran::evaluate::DataRef{*hostSym}).value()};
+ if (Fortran::semantics::IsPointer(*sym))
+ assign.u = Fortran::evaluate::Assignment::BoundsSpec{};
+ genAssignment(assign);
+ }
+ for (const Fortran::semantics::Symbol *sym : info.sharedSymList) {
+ const auto *hostDetails =
+ sym->detailsIf<Fortran::semantics::HostAssocDetails>();
+ copySymbolBinding(hostDetails->symbol(), *sym);
}
- builder.setInsertionPointAfter(regionAssignOp);
}
-/// Shared for both assignments and pointer assignments.
-void FirConverter::genAssignment(const Fortran::evaluate::Assignment &assign) {
+/// Generate FIR to evaluate loop control values (lower, upper and step).
+mlir::Value FirConverter::genControlValue(const Fortran::lower::SomeExpr *expr,
+ const IncrementLoopInfo &info,
+ bool *isConst) {
mlir::Location loc = toLocation();
- if (lowerToHighLevelFIR()) {
- std::visit(
- Fortran::common::visitors{
- [&](const Fortran::evaluate::Assignment::Intrinsic &) {
- genDataAssignment(assign, /*userDefinedAssignment=*/nullptr);
- },
- [&](const Fortran::evaluate::ProcedureRef &procRef) {
- genDataAssignment(assign, /*userDefinedAssignment=*/&procRef);
- },
- [&](const Fortran::evaluate::Assignment::BoundsSpec &lbExprs) {
- if (isInsideHlfirForallOrWhere())
- TODO(loc, "pointer assignment inside FORALL");
- genPointerAssignment(loc, assign, lbExprs);
- },
- [&](const Fortran::evaluate::Assignment::BoundsRemapping
- &boundExprs) {
- if (isInsideHlfirForallOrWhere())
- TODO(loc, "pointer assignment inside FORALL");
- genPointerAssignment(loc, assign, boundExprs);
- },
- },
- assign.u);
- return;
- }
- if (explicitIterationSpace()) {
- Fortran::lower::createArrayLoads(*this, explicitIterSpace, localSymbols);
- explicitIterSpace.genLoopNest();
- }
+ mlir::Type controlType = info.isStructured() ? builder->getIndexType()
+ : info.getLoopVariableType();
Fortran::lower::StatementContext stmtCtx;
- std::visit(
- Fortran::common::visitors{
- // [1] Plain old assignment.
- [&](const Fortran::evaluate::Assignment::Intrinsic &) {
- const Fortran::semantics::Symbol *sym =
- Fortran::evaluate::GetLastSymbol(assign.lhs);
-
- if (!sym)
- TODO(loc, "assignment to pointer result of function reference");
-
- std::optional<Fortran::evaluate::DynamicType> lhsType =
- assign.lhs.GetType();
- assert(lhsType && "lhs cannot be typeless");
- std::optional<Fortran::evaluate::DynamicType> rhsType =
- assign.rhs.GetType();
-
- // Assignment to/from polymorphic entities are done with the
- // runtime.
- if (lhsType->IsPolymorphic() || lhsType->IsUnlimitedPolymorphic() ||
- (rhsType && (rhsType->IsPolymorphic() ||
- rhsType->IsUnlimitedPolymorphic()))) {
- mlir::Value lhs;
- if (Fortran::lower::isWholeAllocatable(assign.lhs))
- lhs = genExprMutableBox(loc, assign.lhs).getAddr();
- else
- lhs = fir::getBase(genExprBox(loc, assign.lhs, stmtCtx));
- mlir::Value rhs =
- fir::getBase(genExprBox(loc, assign.rhs, stmtCtx));
- if ((lhsType->IsPolymorphic() ||
- lhsType->IsUnlimitedPolymorphic()) &&
- Fortran::lower::isWholeAllocatable(assign.lhs))
- fir::runtime::genAssignPolymorphic(*builder, loc, lhs, rhs);
- else
- fir::runtime::genAssign(*builder, loc, lhs, rhs);
- return;
- }
-
- // Note: No ad-hoc handling for pointers is required here. The
- // target will be assigned as per 2018 10.2.1.3 p2. genExprAddr
- // on a pointer returns the target address and not the address of
- // the pointer variable.
-
- if (assign.lhs.Rank() > 0 || explicitIterationSpace()) {
- if (isDerivedCategory(lhsType->category()) &&
- Fortran::semantics::IsFinalizable(
- lhsType->GetDerivedTypeSpec()))
- TODO(loc, "derived-type finalization with array assignment");
- // Array assignment
- // See Fortran 2018 10.2.1.3 p5, p6, and p7
- genArrayAssignment(assign, stmtCtx);
- return;
- }
+ if (expr) {
+ if (isConst)
+ *isConst = Fortran::evaluate::IsConstantExpr(*expr);
+ return builder->createConvert(loc, controlType,
+ createFIRExpr(loc, expr, stmtCtx));
+ }
- // Scalar assignment
- const bool isNumericScalar =
- isNumericScalarCategory(lhsType->category());
- const bool isVector = isDerivedCategory(lhsType->category()) &&
- lhsType->GetDerivedTypeSpec().IsVectorType();
- fir::ExtendedValue rhs = (isNumericScalar || isVector)
- ? genExprValue(assign.rhs, stmtCtx)
- : genExprAddr(assign.rhs, stmtCtx);
- const bool lhsIsWholeAllocatable =
- Fortran::lower::isWholeAllocatable(assign.lhs);
- std::optional<fir::factory::MutableBoxReallocation> lhsRealloc;
- std::optional<fir::MutableBoxValue> lhsMutableBox;
+ if (isConst)
+ *isConst = true;
+ if (info.hasRealControl)
+ return builder->createRealConstant(loc, controlType, 1u);
+ return builder->createIntegerConstant(loc, controlType, 1); // step
+}
- // Set flag to know if the LHS needs finalization. Polymorphic,
- // unlimited polymorphic assignment will be done with genAssign.
- // Assign runtime function performs the finalization.
- bool needFinalization = !lhsType->IsPolymorphic() &&
- !lhsType->IsUnlimitedPolymorphic() &&
- (isDerivedCategory(lhsType->category()) &&
- Fortran::semantics::IsFinalizable(
- lhsType->GetDerivedTypeSpec()));
+/// Force the binding of an explicit symbol. This is used to bind and re-bind
+/// a concurrent control symbol to its value.
+void FirConverter::forceControlVariableBinding(
+ const Fortran::semantics::Symbol *sym, mlir::Value inducVar) {
+ mlir::Location loc = toLocation();
+ assert(sym && "There must be a symbol to bind");
+ mlir::Type toTy = genType(*sym);
+ // FIXME: this should be a "per iteration" temporary.
+ mlir::Value tmp = builder->createTemporary(
+ loc, toTy, toStringRef(sym->name()),
+ llvm::ArrayRef<mlir::NamedAttribute>{fir::getAdaptToByRefAttr(*builder)});
+ mlir::Value cast = builder->createConvert(loc, toTy, inducVar);
+ builder->create<fir::StoreOp>(loc, cast, tmp);
+ addSymbol(*sym, tmp, /*force=*/true);
+}
- auto lhs = [&]() -> fir::ExtendedValue {
- if (lhsIsWholeAllocatable) {
- lhsMutableBox = genExprMutableBox(loc, assign.lhs);
- // Finalize if needed.
- if (needFinalization) {
- mlir::Value isAllocated =
- fir::factory::genIsAllocatedOrAssociatedTest(
- *builder, loc, *lhsMutableBox);
- builder->genIfThen(loc, isAllocated)
- .genThen([&]() {
- fir::runtime::genDerivedTypeDestroy(
- *builder, loc, fir::getBase(*lhsMutableBox));
- })
- .end();
- needFinalization = false;
- }
+/// Generate hlfir.forall and hlfir.forall_mask nest given a Forall
+/// concurrent header
+void FirConverter::genForallNest(
+ const Fortran::parser::ConcurrentHeader &header) {
+ mlir::Location loc = getCurrentLocation();
+ const bool isOutterForall = !isInsideHlfirForallOrWhere();
+ hlfir::ForallOp outerForall;
+ auto evaluateControl = [&](const auto &parserExpr, mlir::Region ®ion,
+ bool isMask = false) {
+ if (region.empty())
+ builder->createBlock(®ion);
+ Fortran::lower::StatementContext localStmtCtx;
+ const Fortran::semantics::SomeExpr *anlalyzedExpr =
+ Fortran::semantics::GetExpr(parserExpr);
+ assert(anlalyzedExpr && "expression semantics failed");
+ // Generate the controls of outer forall outside of the hlfir.forall
+ // region. They do not depend on any previous forall indices (C1123) and
+ // no assignment has been made yet that could modify their value. This
+ // will simplify hlfir.forall analysis because the SSA integer value
+ // yielded will obviously not depend on any variable modified by the
+ // forall when produced outside of it.
+ // This is not done for the mask because it may (and in usual code, does)
+ // depend on the forall indices that have just been defined as
+ // hlfir.forall block arguments.
+ mlir::OpBuilder::InsertPoint innerInsertionPoint;
+ if (outerForall && !isMask) {
+ innerInsertionPoint = builder->saveInsertionPoint();
+ builder->setInsertionPoint(outerForall);
+ }
+ mlir::Value exprVal =
+ fir::getBase(genExprValue(*anlalyzedExpr, localStmtCtx, &loc));
+ localStmtCtx.finalizeAndPop();
+ if (isMask)
+ exprVal = builder->createConvert(loc, builder->getI1Type(), exprVal);
+ if (innerInsertionPoint.isSet())
+ builder->restoreInsertionPoint(innerInsertionPoint);
+ builder->create<hlfir::YieldOp>(loc, exprVal);
+ };
+ for (const Fortran::parser::ConcurrentControl &control :
+ std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t)) {
+ auto forallOp = builder->create<hlfir::ForallOp>(loc);
+ if (isOutterForall && !outerForall)
+ outerForall = forallOp;
+ evaluateControl(std::get<1>(control.t), forallOp.getLbRegion());
+ evaluateControl(std::get<2>(control.t), forallOp.getUbRegion());
+ if (const auto &optionalStep =
+ std::get<std::optional<Fortran::parser::ScalarIntExpr>>(control.t))
+ evaluateControl(*optionalStep, forallOp.getStepRegion());
+ // Create block argument and map it to a symbol via an hlfir.forall_index
+ // op (symbols must be mapped to in memory values).
+ const Fortran::semantics::Symbol *controlVar =
+ std::get<Fortran::parser::Name>(control.t).symbol;
+ assert(controlVar && "symbol analysis failed");
+ mlir::Type controlVarType = genType(*controlVar);
+ mlir::Block *forallBody =
+ builder->createBlock(&forallOp.getBody(), {}, {controlVarType}, {loc});
+ auto forallIndex = builder->create<hlfir::ForallIndexOp>(
+ loc, fir::ReferenceType::get(controlVarType),
+ forallBody->getArguments()[0],
+ builder->getStringAttr(controlVar->name().ToString()));
+ localSymbols.addVariableDefinition(*controlVar, forallIndex,
+ /*force=*/true);
+ auto end = builder->create<fir::FirEndOp>(loc);
+ builder->setInsertionPoint(end);
+ }
- llvm::SmallVector<mlir::Value> lengthParams;
- if (const fir::CharBoxValue *charBox = rhs.getCharBox())
- lengthParams.push_back(charBox->getLen());
- else if (fir::isDerivedWithLenParameters(rhs))
- TODO(loc, "assignment to derived type allocatable with "
- "LEN parameters");
- lhsRealloc = fir::factory::genReallocIfNeeded(
- *builder, loc, *lhsMutableBox,
- /*shape=*/std::nullopt, lengthParams);
- return lhsRealloc->newValue;
- }
- return genExprAddr(assign.lhs, stmtCtx);
- }();
+ if (const auto &maskExpr =
+ std::get<std::optional<Fortran::parser::ScalarLogicalExpr>>(
+ header.t)) {
+ // Create hlfir.forall_mask and set insertion point in its body.
+ auto forallMaskOp = builder->create<hlfir::ForallMaskOp>(loc);
+ evaluateControl(*maskExpr, forallMaskOp.getMaskRegion(), /*isMask=*/true);
+ builder->createBlock(&forallMaskOp.getBody());
+ auto end = builder->create<fir::FirEndOp>(loc);
+ builder->setInsertionPoint(end);
+ }
+}
- if (isNumericScalar || isVector) {
- // Fortran 2018 10.2.1.3 p8 and p9
- // Conversions should have been inserted by semantic analysis,
- // but they can be incorrect between the rhs and lhs. Correct
- // that here.
- mlir::Value addr = fir::getBase(lhs);
- mlir::Value val = fir::getBase(rhs);
- // A function with multiple entry points returning different
- // types tags all result variables with one of the largest
- // types to allow them to share the same storage. Assignment
- // to a result variable of one of the other types requires
- // conversion to the actual type.
- mlir::Type toTy = genType(assign.lhs);
+fir::ExtendedValue
+FirConverter::genAssociateSelector(const Fortran::lower::SomeExpr &selector,
+ Fortran::lower::StatementContext &stmtCtx) {
+ if (lowerToHighLevelFIR())
+ return genExprAddr(selector, stmtCtx);
+ return Fortran::lower::isArraySectionWithoutVectorSubscript(selector)
+ ? Fortran::lower::createSomeArrayBox(*this, selector, localSymbols,
+ stmtCtx)
+ : genExprAddr(selector, stmtCtx);
+}
- // If Cray pointee, need to handle the address
- // Array is handled in genCoordinateOp.
- if (sym->test(Fortran::semantics::Symbol::Flag::CrayPointee) &&
- sym->Rank() == 0) {
- // get the corresponding Cray pointer
+/// Generate an array assignment.
+/// This is an assignment expression with rank > 0. The assignment may or may
+/// not be in a WHERE and/or FORALL context.
+/// In a FORALL context, the assignment may be a pointer assignment and the \p
+/// lbounds and \p ubounds parameters should only be used in such a pointer
+/// assignment case. (If both are None then the array assignment cannot be a
+/// pointer assignment.)
+void FirConverter::genArrayAssignment(
+ const Fortran::evaluate::Assignment &assign,
+ Fortran::lower::StatementContext &localStmtCtx,
+ std::optional<llvm::SmallVector<mlir::Value>> lbounds,
+ std::optional<llvm::SmallVector<mlir::Value>> ubounds) {
- auto ptrSym = Fortran::lower::getCrayPointer(*sym);
- fir::ExtendedValue ptr =
- getSymbolExtendedValue(ptrSym, nullptr);
- mlir::Value ptrVal = fir::getBase(ptr);
- mlir::Type ptrTy = genType(*ptrSym);
+ Fortran::lower::StatementContext &stmtCtx =
+ explicitIterationSpace()
+ ? explicitIterSpace.stmtContext()
+ : (implicitIterationSpace() ? implicitIterSpace.stmtContext()
+ : localStmtCtx);
+ if (Fortran::lower::isWholeAllocatable(assign.lhs)) {
+ // Assignment to allocatables may require the lhs to be
+ // deallocated/reallocated. See Fortran 2018 10.2.1.3 p3
+ Fortran::lower::createAllocatableArrayAssignment(
+ *this, assign.lhs, assign.rhs, explicitIterSpace, implicitIterSpace,
+ localSymbols, stmtCtx);
+ return;
+ }
- fir::ExtendedValue pte = getSymbolExtendedValue(*sym, nullptr);
- mlir::Value pteVal = fir::getBase(pte);
- mlir::Value cnvrt = Fortran::lower::addCrayPointerInst(
- loc, *builder, ptrVal, ptrTy, pteVal.getType());
- addr = builder->create<fir::LoadOp>(loc, cnvrt);
- }
- mlir::Value cast =
- isVector ? val
- : builder->convertWithSemantics(loc, toTy, val);
- if (fir::dyn_cast_ptrEleTy(addr.getType()) != toTy) {
- assert(isFuncResultDesignator(assign.lhs) && "type mismatch");
- addr = builder->createConvert(toLocation(),
- builder->getRefType(toTy), addr);
- }
- builder->create<fir::StoreOp>(loc, cast, addr);
- } else if (isCharacterCategory(lhsType->category())) {
- // Fortran 2018 10.2.1.3 p10 and p11
- fir::factory::CharacterExprHelper{*builder, loc}.createAssign(
- lhs, rhs);
- } else if (isDerivedCategory(lhsType->category())) {
- // Handle parent component.
- if (Fortran::lower::isParentComponent(assign.lhs)) {
- if (!fir::getBase(lhs).getType().isa<fir::BaseBoxType>())
- lhs = fir::getBase(builder->createBox(loc, lhs));
- lhs = Fortran::lower::updateBoxForParentComponent(*this, lhs,
- assign.lhs);
- }
+ if (lbounds) {
+ // Array of POINTER entities, with elemental assignment.
+ if (!Fortran::lower::isWholePointer(assign.lhs))
+ fir::emitFatalError(toLocation(), "pointer assignment to non-pointer");
- // Fortran 2018 10.2.1.3 p13 and p14
- // Recursively gen an assignment on each element pair.
- fir::factory::genRecordAssignment(*builder, loc, lhs, rhs,
- needFinalization);
- } else {
- llvm_unreachable("unknown category");
- }
- if (lhsIsWholeAllocatable) {
- assert(lhsRealloc.has_value());
- fir::factory::finalizeRealloc(*builder, loc, *lhsMutableBox,
- /*lbounds=*/std::nullopt,
- /*takeLboundsIfRealloc=*/false,
- *lhsRealloc);
- }
- },
+ Fortran::lower::createArrayOfPointerAssignment(
+ *this, assign.lhs, assign.rhs, explicitIterSpace, implicitIterSpace,
+ *lbounds, ubounds, localSymbols, stmtCtx);
+ return;
+ }
- // [2] User defined assignment. If the context is a scalar
- // expression then call the procedure.
- [&](const Fortran::evaluate::ProcedureRef &procRef) {
- Fortran::lower::StatementContext &ctx =
- explicitIterationSpace() ? explicitIterSpace.stmtContext()
- : stmtCtx;
- Fortran::lower::createSubroutineCall(
- *this, procRef, explicitIterSpace, implicitIterSpace,
- localSymbols, ctx, /*isUserDefAssignment=*/true);
- },
+ if (!implicitIterationSpace() && !explicitIterationSpace()) {
+ // No masks and the iteration space is implied by the array, so create a
+ // simple array assignment.
+ Fortran::lower::createSomeArrayAssignment(*this, assign.lhs, assign.rhs,
+ localSymbols, stmtCtx);
+ return;
+ }
- [&](const Fortran::evaluate::Assignment::BoundsSpec &lbExprs) {
- return genPointerAssignment(loc, assign, lbExprs);
- },
- [&](const Fortran::evaluate::Assignment::BoundsRemapping
- &boundExprs) {
- return genPointerAssignment(loc, assign, boundExprs);
- },
- },
- assign.u);
- if (explicitIterationSpace())
- Fortran::lower::createArrayMergeStores(*this, explicitIterSpace);
+ // If there is an explicit iteration space, generate an array assignment
+ // with a user-specified iteration space and possibly with masks. These
+ // assignments may *appear* to be scalar expressions, but the scalar
+ // expression is evaluated at all points in the user-defined space much like
+ // an ordinary array assignment. More specifically, the semantics inside the
+ // FORALL much more closely resembles that of WHERE than a scalar
+ // assignment.
+ // Otherwise, generate a masked array assignment. The iteration space is
+ // implied by the lhs array expression.
+ Fortran::lower::createAnyMaskedArrayAssignment(
+ *this, assign.lhs, assign.rhs, explicitIterSpace, implicitIterSpace,
+ localSymbols, stmtCtx);
}
-void FirConverter::genFIR(const Fortran::parser::WhereConstruct &c) {
- mlir::Location loc = getCurrentLocation();
- hlfir::WhereOp whereOp;
+inline fir::MutableBoxValue
+FirConverter::genExprMutableBox(mlir::Location loc,
+ const Fortran::lower::SomeExpr &expr) {
+ if (lowerToHighLevelFIR())
+ return Fortran::lower::convertExprToMutableBox(loc, *this, expr,
+ localSymbols);
+ return Fortran::lower::createMutableBox(loc, *this, expr, localSymbols);
+}
- if (!lowerToHighLevelFIR()) {
- implicitIterSpace.growStack();
- } else {
- whereOp = builder->create<hlfir::WhereOp>(loc);
- builder->createBlock(&whereOp.getMaskRegion());
+// Create the [newRank] array with the lower bounds to be passed to the
+// runtime as a descriptor.
+mlir::Value FirConverter::createLboundArray(llvm::ArrayRef<mlir::Value> lbounds,
+ mlir::Location loc) {
+ mlir::Type indexTy = builder->getIndexType();
+ mlir::Type boundArrayTy = fir::SequenceType::get(
+ {static_cast<int64_t>(lbounds.size())}, builder->getI64Type());
+ mlir::Value boundArray = builder->create<fir::AllocaOp>(loc, boundArrayTy);
+ mlir::Value array = builder->create<fir::UndefOp>(loc, boundArrayTy);
+ for (unsigned i = 0; i < lbounds.size(); ++i) {
+ array = builder->create<fir::InsertValueOp>(
+ loc, boundArrayTy, array, lbounds[i],
+ builder->getArrayAttr({builder->getIntegerAttr(builder->getIndexType(),
+ static_cast<int>(i))}));
}
+ builder->create<fir::StoreOp>(loc, array, boundArray);
+ mlir::Type boxTy = fir::BoxType::get(boundArrayTy);
+ mlir::Value ext =
+ builder->createIntegerConstant(loc, indexTy, lbounds.size());
+ llvm::SmallVector<mlir::Value> shapes = {ext};
+ mlir::Value shapeOp = builder->genShape(loc, shapes);
+ return builder->create<fir::EmboxOp>(loc, boxTy, boundArray, shapeOp);
+}
- // Lower the where mask. For HLFIR, this is done in the hlfir.where mask
- // region.
- genNestedStatement(
- std::get<Fortran::parser::Statement<Fortran::parser::WhereConstructStmt>>(
- c.t));
+// Create the 2 x newRank array with the bounds to be passed to the runtime as
+// a descriptor.
+mlir::Value FirConverter::createBoundArray(llvm::ArrayRef<mlir::Value> lbounds,
+ llvm::ArrayRef<mlir::Value> ubounds,
+ mlir::Location loc) {
+ assert(lbounds.size() && ubounds.size());
+ mlir::Type indexTy = builder->getIndexType();
+ mlir::Type boundArrayTy = fir::SequenceType::get(
+ {2, static_cast<int64_t>(lbounds.size())}, builder->getI64Type());
+ mlir::Value boundArray = builder->create<fir::AllocaOp>(loc, boundArrayTy);
+ mlir::Value array = builder->create<fir::UndefOp>(loc, boundArrayTy);
+ for (unsigned i = 0; i < lbounds.size(); ++i) {
+ array = builder->create<fir::InsertValueOp>(
+ loc, boundArrayTy, array, lbounds[i],
+ builder->getArrayAttr(
+ {builder->getIntegerAttr(builder->getIndexType(), 0),
+ builder->getIntegerAttr(builder->getIndexType(),
+ static_cast<int>(i))}));
+ array = builder->create<fir::InsertValueOp>(
+ loc, boundArrayTy, array, ubounds[i],
+ builder->getArrayAttr(
+ {builder->getIntegerAttr(builder->getIndexType(), 1),
+ builder->getIntegerAttr(builder->getIndexType(),
+ static_cast<int>(i))}));
+ }
+ builder->create<fir::StoreOp>(loc, array, boundArray);
+ mlir::Type boxTy = fir::BoxType::get(boundArrayTy);
+ mlir::Value ext =
+ builder->createIntegerConstant(loc, indexTy, lbounds.size());
+ mlir::Value c2 = builder->createIntegerConstant(loc, indexTy, 2);
+ llvm::SmallVector<mlir::Value> shapes = {c2, ext};
+ mlir::Value shapeOp = builder->genShape(loc, shapes);
+ return builder->create<fir::EmboxOp>(loc, boxTy, boundArray, shapeOp);
+}
- // Lower WHERE body. For HLFIR, this is done in the hlfir.where body
- // region.
- if (whereOp)
- builder->createBlock(&whereOp.getBody());
+// Generate pointer assignment with possibly empty bounds-spec. R1035: a
+// bounds-spec is a lower bound value.
+void FirConverter::genPointerAssignment(
+ mlir::Location loc, const Fortran::evaluate::Assignment &assign,
+ const Fortran::evaluate::Assignment::BoundsSpec &lbExprs) {
+ Fortran::lower::StatementContext stmtCtx;
- for (const auto &body :
- std::get<std::list<Fortran::parser::WhereBodyConstruct>>(c.t))
- genFIR(body);
- for (const auto &e :
- std::get<std::list<Fortran::parser::WhereConstruct::MaskedElsewhere>>(
- c.t))
- genFIR(e);
- if (const auto &e =
- std::get<std::optional<Fortran::parser::WhereConstruct::Elsewhere>>(
- c.t);
- e.has_value())
- genFIR(*e);
- genNestedStatement(
- std::get<Fortran::parser::Statement<Fortran::parser::EndWhereStmt>>(c.t));
+ if (!lowerToHighLevelFIR() && Fortran::evaluate::IsProcedure(assign.rhs))
+ TODO(loc, "procedure pointer assignment");
+ if (Fortran::evaluate::IsProcedurePointer(assign.lhs)) {
+ hlfir::Entity lhs = Fortran::lower::convertExprToHLFIR(
+ loc, *this, assign.lhs, localSymbols, stmtCtx);
+ if (Fortran::evaluate::IsNullProcedurePointer(assign.rhs)) {
+ auto boxTy{Fortran::lower::getUntypedBoxProcType(&getMLIRContext())};
+ hlfir::Entity rhs(fir::factory::createNullBoxProc(*builder, loc, boxTy));
+ builder->createStoreWithConvert(loc, rhs, lhs);
+ return;
+ }
+ hlfir::Entity rhs(getBase(Fortran::lower::convertExprToAddress(
+ loc, *this, assign.rhs, localSymbols, stmtCtx)));
+ builder->createStoreWithConvert(loc, rhs, lhs);
+ return;
+ }
- if (whereOp) {
- // For HLFIR, create fir.end terminator in the last hlfir.elsewhere, or
- // in the hlfir.where if it had no elsewhere.
- builder->create<fir::FirEndOp>(loc);
- builder->setInsertionPointAfter(whereOp);
+ std::optional<Fortran::evaluate::DynamicType> lhsType = assign.lhs.GetType();
+ // Delegate pointer association to unlimited polymorphic pointer
+ // to the runtime. element size, type code, attribute and of
+ // course base_addr might need to be updated.
+ if (lhsType && lhsType->IsPolymorphic()) {
+ if (!lowerToHighLevelFIR() && explicitIterationSpace())
+ TODO(loc, "polymorphic pointer assignment in FORALL");
+ llvm::SmallVector<mlir::Value> lbounds;
+ for (const Fortran::evaluate::ExtentExpr &lbExpr : lbExprs)
+ lbounds.push_back(fir::getBase(genExprValue(toEvExpr(lbExpr), stmtCtx)));
+ fir::MutableBoxValue lhsMutableBox = genExprMutableBox(loc, assign.lhs);
+ if (Fortran::evaluate::UnwrapExpr<Fortran::evaluate::NullPointer>(
+ assign.rhs)) {
+ fir::factory::disassociateMutableBox(*builder, loc, lhsMutableBox);
+ return;
+ }
+ mlir::Value lhs = lhsMutableBox.getAddr();
+ mlir::Value rhs = fir::getBase(genExprBox(loc, assign.rhs, stmtCtx));
+ if (!lbounds.empty()) {
+ mlir::Value boundsDesc = createLboundArray(lbounds, loc);
+ Fortran::lower::genPointerAssociateLowerBounds(*builder, loc, lhs, rhs,
+ boundsDesc);
+ return;
+ }
+ Fortran::lower::genPointerAssociate(*builder, loc, lhs, rhs);
+ return;
+ }
+
+ llvm::SmallVector<mlir::Value> lbounds;
+ for (const Fortran::evaluate::ExtentExpr &lbExpr : lbExprs)
+ lbounds.push_back(fir::getBase(genExprValue(toEvExpr(lbExpr), stmtCtx)));
+ if (!lowerToHighLevelFIR() && explicitIterationSpace()) {
+ // Pointer assignment in FORALL context. Copy the rhs box value
+ // into the lhs box variable.
+ genArrayAssignment(assign, stmtCtx, lbounds);
+ return;
}
+ fir::MutableBoxValue lhs = genExprMutableBox(loc, assign.lhs);
+ Fortran::lower::associateMutableBox(*this, loc, lhs, assign.rhs, lbounds,
+ stmtCtx);
}
-void FirConverter::genFIR(const Fortran::parser::WhereBodyConstruct &body) {
- std::visit(
- Fortran::common::visitors{
- [&](const Fortran::parser::Statement<Fortran::parser::AssignmentStmt>
- &stmt) { genNestedStatement(stmt); },
- [&](const Fortran::parser::Statement<Fortran::parser::WhereStmt>
- &stmt) { genNestedStatement(stmt); },
- [&](const Fortran::common::Indirection<
- Fortran::parser::WhereConstruct> &c) { genFIR(c.value()); },
- },
- body.u);
+// Pointer assignment with bounds-remapping. R1036: a bounds-remapping is a
+// pair, lower bound and upper bound.
+void FirConverter::genPointerAssignment(
+ mlir::Location loc, const Fortran::evaluate::Assignment &assign,
+ const Fortran::evaluate::Assignment::BoundsRemapping &boundExprs) {
+ Fortran::lower::StatementContext stmtCtx;
+ llvm::SmallVector<mlir::Value> lbounds;
+ llvm::SmallVector<mlir::Value> ubounds;
+ for (const std::pair<Fortran::evaluate::ExtentExpr,
+ Fortran::evaluate::ExtentExpr> &pair : boundExprs) {
+ const Fortran::evaluate::ExtentExpr &lbExpr = pair.first;
+ const Fortran::evaluate::ExtentExpr &ubExpr = pair.second;
+ lbounds.push_back(fir::getBase(genExprValue(toEvExpr(lbExpr), stmtCtx)));
+ ubounds.push_back(fir::getBase(genExprValue(toEvExpr(ubExpr), stmtCtx)));
+ }
+
+ std::optional<Fortran::evaluate::DynamicType> lhsType = assign.lhs.GetType();
+ std::optional<Fortran::evaluate::DynamicType> rhsType = assign.rhs.GetType();
+ // Polymorphic lhs/rhs need more care. See F2018 10.2.2.3.
+ if ((lhsType && lhsType->IsPolymorphic()) ||
+ (rhsType && rhsType->IsPolymorphic())) {
+ if (!lowerToHighLevelFIR() && explicitIterationSpace())
+ TODO(loc, "polymorphic pointer assignment in FORALL");
+
+ fir::MutableBoxValue lhsMutableBox = genExprMutableBox(loc, assign.lhs);
+ if (Fortran::evaluate::UnwrapExpr<Fortran::evaluate::NullPointer>(
+ assign.rhs)) {
+ fir::factory::disassociateMutableBox(*builder, loc, lhsMutableBox);
+ return;
+ }
+ mlir::Value lhs = lhsMutableBox.getAddr();
+ mlir::Value rhs = fir::getBase(genExprBox(loc, assign.rhs, stmtCtx));
+ mlir::Value boundsDesc = createBoundArray(lbounds, ubounds, loc);
+ Fortran::lower::genPointerAssociateRemapping(*builder, loc, lhs, rhs,
+ boundsDesc);
+ return;
+ }
+ if (!lowerToHighLevelFIR() && explicitIterationSpace()) {
+ // Pointer assignment in FORALL context. Copy the rhs box value
+ // into the lhs box variable.
+ genArrayAssignment(assign, stmtCtx, lbounds, ubounds);
+ return;
+ }
+ fir::MutableBoxValue lhs = genExprMutableBox(loc, assign.lhs);
+ if (Fortran::evaluate::UnwrapExpr<Fortran::evaluate::NullPointer>(
+ assign.rhs)) {
+ fir::factory::disassociateMutableBox(*builder, loc, lhs);
+ return;
+ }
+ // Do not generate a temp in case rhs is an array section.
+ fir::ExtendedValue rhs =
+ Fortran::lower::isArraySectionWithoutVectorSubscript(assign.rhs)
+ ? Fortran::lower::createSomeArrayBox(*this, assign.rhs, localSymbols,
+ stmtCtx)
+ : genExprAddr(assign.rhs, stmtCtx);
+ fir::factory::associateMutableBoxWithRemap(*builder, loc, lhs, rhs, lbounds,
+ ubounds);
+ if (!lowerToHighLevelFIR() && explicitIterationSpace()) {
+ mlir::ValueRange inners = explicitIterSpace.getInnerArgs();
+ if (!inners.empty())
+ builder->create<fir::ResultOp>(loc, inners);
+ }
}
-/// Lower a Where or Elsewhere mask into an hlfir mask region.
-void FirConverter::lowerWhereMaskToHlfir(
- mlir::Location loc, const Fortran::semantics::SomeExpr *maskExpr) {
- assert(maskExpr && "mask semantic analysis failed");
- Fortran::lower::StatementContext maskContext;
- hlfir::Entity mask = Fortran::lower::convertExprToHLFIR(
- loc, *this, *maskExpr, localSymbols, maskContext);
- mask = hlfir::loadTrivialScalar(loc, *builder, mask);
- auto yieldOp = builder->create<hlfir::YieldOp>(loc, mask);
- genCleanUpInRegionIfAny(loc, *builder, yieldOp.getCleanup(), maskContext);
+/// Given converted LHS and RHS of the assignment, materialize any
+/// implicit conversion of the RHS to the LHS type. The front-end
+/// usually already makes those explicit, except for non-standard
+/// LOGICAL <-> INTEGER, or if the LHS is a whole allocatable
+/// (making the conversion explicit in the front-end would prevent
+/// propagation of the LHS lower bound in the reallocation).
+/// If array temporaries or values are created, the cleanups are
+/// added in the statement context.
+hlfir::Entity
+FirConverter::genImplicitConvert(const Fortran::evaluate::Assignment &assign,
+ hlfir::Entity rhs, bool preserveLowerBounds,
+ Fortran::lower::StatementContext &stmtCtx) {
+ mlir::Location loc = toLocation();
+ auto &builder = getFirOpBuilder();
+ mlir::Type toType = genType(assign.lhs);
+ auto valueAndPair = hlfir::genTypeAndKindConvert(loc, builder, rhs, toType,
+ preserveLowerBounds);
+ if (valueAndPair.second)
+ stmtCtx.attachCleanup(*valueAndPair.second);
+ return hlfir::Entity{valueAndPair.first};
}
-void FirConverter::genFIR(const Fortran::parser::WhereConstructStmt &stmt) {
- const Fortran::semantics::SomeExpr *maskExpr = Fortran::semantics::GetExpr(
- std::get<Fortran::parser::LogicalExpr>(stmt.t));
- if (lowerToHighLevelFIR())
- lowerWhereMaskToHlfir(getCurrentLocation(), maskExpr);
+void FirConverter::genCleanUpInRegionIfAny(
+ mlir::Location loc, fir::FirOpBuilder &builder, mlir::Region ®ion,
+ Fortran::lower::StatementContext &context) {
+ if (!context.hasCode())
+ return;
+ mlir::OpBuilder::InsertPoint insertPt = builder.saveInsertionPoint();
+ if (region.empty())
+ builder.createBlock(®ion);
else
- implicitIterSpace.append(maskExpr);
+ builder.setInsertionPointToEnd(®ion.front());
+ context.finalizeAndPop();
+ hlfir::YieldOp::ensureTerminator(region, builder, loc);
+ builder.restoreInsertionPoint(insertPt);
}
-void FirConverter::genFIR(
- const Fortran::parser::WhereConstruct::MaskedElsewhere &ew) {
+bool FirConverter::firstDummyIsPointerOrAllocatable(
+ const Fortran::evaluate::ProcedureRef &userDefinedAssignment) {
+ using DummyAttr = Fortran::evaluate::characteristics::DummyDataObject::Attr;
+ if (auto procedure =
+ Fortran::evaluate::characteristics::Procedure::Characterize(
+ userDefinedAssignment.proc(), getFoldingContext()))
+ if (!procedure->dummyArguments.empty())
+ if (const auto *dataArg =
+ std::get_if<Fortran::evaluate::characteristics::DummyDataObject>(
+ &procedure->dummyArguments[0].u))
+ return dataArg->attrs.test(DummyAttr::Pointer) ||
+ dataArg->attrs.test(DummyAttr::Allocatable);
+ return false;
+}
+
+void FirConverter::genDataAssignment(
+ const Fortran::evaluate::Assignment &assign,
+ const Fortran::evaluate::ProcedureRef *userDefinedAssignment) {
mlir::Location loc = getCurrentLocation();
- hlfir::ElseWhereOp elsewhereOp;
- if (lowerToHighLevelFIR()) {
- elsewhereOp = builder->create<hlfir::ElseWhereOp>(loc);
- // Lower mask in the mask region.
- builder->createBlock(&elsewhereOp.getMaskRegion());
- }
- genNestedStatement(
- std::get<
- Fortran::parser::Statement<Fortran::parser::MaskedElsewhereStmt>>(
- ew.t));
+ fir::FirOpBuilder &builder = getFirOpBuilder();
+ // Gather some information about the assignment that will impact how it is
+ // lowered.
+ const bool isWholeAllocatableAssignment =
+ !userDefinedAssignment && !isInsideHlfirWhere() &&
+ Fortran::lower::isWholeAllocatable(assign.lhs);
+ const bool isUserDefAssignToPointerOrAllocatable =
+ userDefinedAssignment &&
+ firstDummyIsPointerOrAllocatable(*userDefinedAssignment);
+ std::optional<Fortran::evaluate::DynamicType> lhsType = assign.lhs.GetType();
+ const bool keepLhsLengthInAllocatableAssignment =
+ isWholeAllocatableAssignment && lhsType.has_value() &&
+ lhsType->category() == Fortran::common::TypeCategory::Character &&
+ !lhsType->HasDeferredTypeParameter();
+ const bool lhsHasVectorSubscripts =
+ Fortran::evaluate::HasVectorSubscript(assign.lhs);
- // For HLFIR, lower the body in the hlfir.elsewhere body region.
- if (elsewhereOp)
- builder->createBlock(&elsewhereOp.getBody());
+ // Helper to generate the code evaluating the right-hand side.
+ auto evaluateRhs = [&](Fortran::lower::StatementContext &stmtCtx) {
+ hlfir::Entity rhs = Fortran::lower::convertExprToHLFIR(
+ loc, *this, assign.rhs, localSymbols, stmtCtx);
+ // Load trivial scalar RHS to allow the loads to be hoisted outside of
+ // loops early if possible. This also dereferences pointer and
+ // allocatable RHS: the target is being assigned from.
+ rhs = hlfir::loadTrivialScalar(loc, builder, rhs);
+ // In intrinsic assignments, the LHS type may not match the RHS type, in
+ // which case an implicit conversion of the LHS must be done. The
+ // front-end usually makes it explicit, unless it cannot (whole
+ // allocatable LHS or Logical<->Integer assignment extension). Recognize
+ // any type mismatches here and insert explicit scalar convert or
+ // ElementalOp for array assignment. Preserve the RHS lower bounds on the
+ // converted entity in case of assignment to whole allocatables so to
+ // propagate the lower bounds to the LHS in case of reallocation.
+ if (!userDefinedAssignment)
+ rhs = genImplicitConvert(assign, rhs, isWholeAllocatableAssignment,
+ stmtCtx);
+ return rhs;
+ };
- for (const auto &body :
- std::get<std::list<Fortran::parser::WhereBodyConstruct>>(ew.t))
- genFIR(body);
-}
+ // Helper to generate the code evaluating the left-hand side.
+ auto evaluateLhs = [&](Fortran::lower::StatementContext &stmtCtx) {
+ hlfir::Entity lhs = Fortran::lower::convertExprToHLFIR(
+ loc, *this, assign.lhs, localSymbols, stmtCtx);
+ // Dereference pointer LHS: the target is being assigned to.
+ // Same for allocatables outside of whole allocatable assignments.
+ if (!isWholeAllocatableAssignment && !isUserDefAssignToPointerOrAllocatable)
+ lhs = hlfir::derefPointersAndAllocatables(loc, builder, lhs);
+ return lhs;
+ };
-void FirConverter::genFIR(const Fortran::parser::MaskedElsewhereStmt &stmt) {
- const auto *maskExpr = Fortran::semantics::GetExpr(
- std::get<Fortran::parser::LogicalExpr>(stmt.t));
- if (lowerToHighLevelFIR())
- lowerWhereMaskToHlfir(getCurrentLocation(), maskExpr);
- else
- implicitIterSpace.append(maskExpr);
-}
+ if (!isInsideHlfirForallOrWhere() && !lhsHasVectorSubscripts &&
+ !userDefinedAssignment) {
+ Fortran::lower::StatementContext localStmtCtx;
+ hlfir::Entity rhs = evaluateRhs(localStmtCtx);
+ hlfir::Entity lhs = evaluateLhs(localStmtCtx);
+ builder.create<hlfir::AssignOp>(loc, rhs, lhs, isWholeAllocatableAssignment,
+ keepLhsLengthInAllocatableAssignment);
+ return;
+ }
+ // Assignments inside Forall, Where, or assignments to a vector subscripted
+ // left-hand side requires using an hlfir.region_assign in HLFIR. The
+ // right-hand side and left-hand side must be evaluated inside the
+ // hlfir.region_assign regions.
+ auto regionAssignOp = builder.create<hlfir::RegionAssignOp>(loc);
-void FirConverter::genFIR(
- const Fortran::parser::WhereConstruct::Elsewhere &ew) {
- if (lowerToHighLevelFIR()) {
- auto elsewhereOp =
- builder->create<hlfir::ElseWhereOp>(getCurrentLocation());
- builder->createBlock(&elsewhereOp.getBody());
+ // Lower RHS in its own region.
+ builder.createBlock(®ionAssignOp.getRhsRegion());
+ Fortran::lower::StatementContext rhsContext;
+ hlfir::Entity rhs = evaluateRhs(rhsContext);
+ auto rhsYieldOp = builder.create<hlfir::YieldOp>(loc, rhs);
+ genCleanUpInRegionIfAny(loc, builder, rhsYieldOp.getCleanup(), rhsContext);
+ // Lower LHS in its own region.
+ builder.createBlock(®ionAssignOp.getLhsRegion());
+ Fortran::lower::StatementContext lhsContext;
+ mlir::Value lhsYield = nullptr;
+ if (!lhsHasVectorSubscripts) {
+ hlfir::Entity lhs = evaluateLhs(lhsContext);
+ auto lhsYieldOp = builder.create<hlfir::YieldOp>(loc, lhs);
+ genCleanUpInRegionIfAny(loc, builder, lhsYieldOp.getCleanup(), lhsContext);
+ lhsYield = lhs;
+ } else {
+ hlfir::ElementalAddrOp elementalAddr =
+ Fortran::lower::convertVectorSubscriptedExprToElementalAddr(
+ loc, *this, assign.lhs, localSymbols, lhsContext);
+ genCleanUpInRegionIfAny(loc, builder, elementalAddr.getCleanup(),
+ lhsContext);
+ lhsYield = elementalAddr.getYieldOp().getEntity();
}
- genNestedStatement(
- std::get<Fortran::parser::Statement<Fortran::parser::ElsewhereStmt>>(
- ew.t));
- for (const auto &body :
- std::get<std::list<Fortran::parser::WhereBodyConstruct>>(ew.t))
- genFIR(body);
-}
+ assert(lhsYield && "must have been set");
-void FirConverter::genFIR(const Fortran::parser::ElsewhereStmt &stmt) {
- if (!lowerToHighLevelFIR())
- implicitIterSpace.append(nullptr);
-}
+ // Add "realloc" flag to hlfir.region_assign.
+ if (isWholeAllocatableAssignment)
+ TODO(loc, "assignment to a whole allocatable inside FORALL");
-void FirConverter::genFIR(const Fortran::parser::EndWhereStmt &) {
- if (!lowerToHighLevelFIR())
- implicitIterSpace.shrinkStack();
+ // Generate the hlfir.region_assign userDefinedAssignment region.
+ if (userDefinedAssignment) {
+ mlir::Type rhsType = rhs.getType();
+ mlir::Type lhsType = lhsYield.getType();
+ if (userDefinedAssignment->IsElemental()) {
+ rhsType = hlfir::getEntityElementType(rhs);
+ lhsType = hlfir::getEntityElementType(hlfir::Entity{lhsYield});
+ }
+ builder.createBlock(®ionAssignOp.getUserDefinedAssignment(),
+ mlir::Region::iterator{}, {rhsType, lhsType},
+ {loc, loc});
+ auto end = builder.create<fir::FirEndOp>(loc);
+ builder.setInsertionPoint(end);
+ hlfir::Entity lhsBlockArg{regionAssignOp.getUserAssignmentLhs()};
+ hlfir::Entity rhsBlockArg{regionAssignOp.getUserAssignmentRhs()};
+ Fortran::lower::convertUserDefinedAssignmentToHLFIR(
+ loc, *this, *userDefinedAssignment, lhsBlockArg, rhsBlockArg,
+ localSymbols);
+ }
+ builder.setInsertionPointAfter(regionAssignOp);
}
-void FirConverter::genFIR(const Fortran::parser::WhereStmt &stmt) {
- Fortran::lower::StatementContext stmtCtx;
- const auto &assign = std::get<Fortran::parser::AssignmentStmt>(stmt.t);
- const auto *mask = Fortran::semantics::GetExpr(
- std::get<Fortran::parser::LogicalExpr>(stmt.t));
+/// Shared for both assignments and pointer assignments.
+void FirConverter::genAssignment(const Fortran::evaluate::Assignment &assign) {
+ mlir::Location loc = toLocation();
if (lowerToHighLevelFIR()) {
- mlir::Location loc = getCurrentLocation();
- auto whereOp = builder->create<hlfir::WhereOp>(loc);
- builder->createBlock(&whereOp.getMaskRegion());
- lowerWhereMaskToHlfir(loc, mask);
- builder->createBlock(&whereOp.getBody());
- genAssignment(*assign.typedAssignment->v);
- builder->create<fir::FirEndOp>(loc);
- builder->setInsertionPointAfter(whereOp);
+ std::visit(
+ Fortran::common::visitors{
+ [&](const Fortran::evaluate::Assignment::Intrinsic &) {
+ genDataAssignment(assign, /*userDefinedAssignment=*/nullptr);
+ },
+ [&](const Fortran::evaluate::ProcedureRef &procRef) {
+ genDataAssignment(assign, /*userDefinedAssignment=*/&procRef);
+ },
+ [&](const Fortran::evaluate::Assignment::BoundsSpec &lbExprs) {
+ if (isInsideHlfirForallOrWhere())
+ TODO(loc, "pointer assignment inside FORALL");
+ genPointerAssignment(loc, assign, lbExprs);
+ },
+ [&](const Fortran::evaluate::Assignment::BoundsRemapping
+ &boundExprs) {
+ if (isInsideHlfirForallOrWhere())
+ TODO(loc, "pointer assignment inside FORALL");
+ genPointerAssignment(loc, assign, boundExprs);
+ },
+ },
+ assign.u);
return;
}
- implicitIterSpace.growStack();
- implicitIterSpace.append(mask);
- genAssignment(*assign.typedAssignment->v);
- implicitIterSpace.shrinkStack();
-}
-
-void FirConverter::genFIR(const Fortran::parser::PointerAssignmentStmt &stmt) {
- genAssignment(*stmt.typedAssignment->v);
-}
-
-void FirConverter::genFIR(const Fortran::parser::AssignmentStmt &stmt) {
- genAssignment(*stmt.typedAssignment->v);
-}
-
-void FirConverter::genFIR(const Fortran::parser::SyncAllStmt &stmt) {
- genSyncAllStatement(*this, stmt);
-}
-
-void FirConverter::genFIR(const Fortran::parser::SyncImagesStmt &stmt) {
- genSyncImagesStatement(*this, stmt);
-}
+ if (explicitIterationSpace()) {
+ Fortran::lower::createArrayLoads(*this, explicitIterSpace, localSymbols);
+ explicitIterSpace.genLoopNest();
+ }
+ Fortran::lower::StatementContext stmtCtx;
+ std::visit(
+ Fortran::common::visitors{
+ // [1] Plain old assignment.
+ [&](const Fortran::evaluate::Assignment::Intrinsic &) {
+ const Fortran::semantics::Symbol *sym =
+ Fortran::evaluate::GetLastSymbol(assign.lhs);
-void FirConverter::genFIR(const Fortran::parser::SyncMemoryStmt &stmt) {
- genSyncMemoryStatement(*this, stmt);
-}
+ if (!sym)
+ TODO(loc, "assignment to pointer result of function reference");
-void FirConverter::genFIR(const Fortran::parser::SyncTeamStmt &stmt) {
- genSyncTeamStatement(*this, stmt);
-}
+ std::optional<Fortran::evaluate::DynamicType> lhsType =
+ assign.lhs.GetType();
+ assert(lhsType && "lhs cannot be typeless");
+ std::optional<Fortran::evaluate::DynamicType> rhsType =
+ assign.rhs.GetType();
-void FirConverter::genFIR(const Fortran::parser::UnlockStmt &stmt) {
- genUnlockStatement(*this, stmt);
-}
+ // Assignment to/from polymorphic entities are done with the
+ // runtime.
+ if (lhsType->IsPolymorphic() || lhsType->IsUnlimitedPolymorphic() ||
+ (rhsType && (rhsType->IsPolymorphic() ||
+ rhsType->IsUnlimitedPolymorphic()))) {
+ mlir::Value lhs;
+ if (Fortran::lower::isWholeAllocatable(assign.lhs))
+ lhs = genExprMutableBox(loc, assign.lhs).getAddr();
+ else
+ lhs = fir::getBase(genExprBox(loc, assign.lhs, stmtCtx));
+ mlir::Value rhs =
+ fir::getBase(genExprBox(loc, assign.rhs, stmtCtx));
+ if ((lhsType->IsPolymorphic() ||
+ lhsType->IsUnlimitedPolymorphic()) &&
+ Fortran::lower::isWholeAllocatable(assign.lhs))
+ fir::runtime::genAssignPolymorphic(*builder, loc, lhs, rhs);
+ else
+ fir::runtime::genAssign(*builder, loc, lhs, rhs);
+ return;
+ }
-void FirConverter::genFIR(const Fortran::parser::AssignStmt &stmt) {
- const Fortran::semantics::Symbol &symbol =
- *std::get<Fortran::parser::Name>(stmt.t).symbol;
- mlir::Location loc = toLocation();
- mlir::Value labelValue = builder->createIntegerConstant(
- loc, genType(symbol), std::get<Fortran::parser::Label>(stmt.t));
- builder->create<fir::StoreOp>(loc, labelValue, getSymbolAddress(symbol));
-}
+ // Note: No ad-hoc handling for pointers is required here. The
+ // target will be assigned as per 2018 10.2.1.3 p2. genExprAddr
+ // on a pointer returns the target address and not the address of
+ // the pointer variable.
-void FirConverter::genFIR(const Fortran::parser::FormatStmt &) {
- // do nothing.
+ if (assign.lhs.Rank() > 0 || explicitIterationSpace()) {
+ if (isDerivedCategory(lhsType->category()) &&
+ Fortran::semantics::IsFinalizable(
+ lhsType->GetDerivedTypeSpec()))
+ TODO(loc, "derived-type finalization with array assignment");
+ // Array assignment
+ // See Fortran 2018 10.2.1.3 p5, p6, and p7
+ genArrayAssignment(assign, stmtCtx);
+ return;
+ }
- // FORMAT statements have no semantics. They may be lowered if used by a
- // data transfer statement.
-}
+ // Scalar assignment
+ const bool isNumericScalar =
+ isNumericScalarCategory(lhsType->category());
+ const bool isVector = isDerivedCategory(lhsType->category()) &&
+ lhsType->GetDerivedTypeSpec().IsVectorType();
+ fir::ExtendedValue rhs = (isNumericScalar || isVector)
+ ? genExprValue(assign.rhs, stmtCtx)
+ : genExprAddr(assign.rhs, stmtCtx);
+ const bool lhsIsWholeAllocatable =
+ Fortran::lower::isWholeAllocatable(assign.lhs);
+ std::optional<fir::factory::MutableBoxReallocation> lhsRealloc;
+ std::optional<fir::MutableBoxValue> lhsMutableBox;
-void FirConverter::genFIR(const Fortran::parser::PauseStmt &stmt) {
- genPauseStatement(*this, stmt);
-}
+ // Set flag to know if the LHS needs finalization. Polymorphic,
+ // unlimited polymorphic assignment will be done with genAssign.
+ // Assign runtime function performs the finalization.
+ bool needFinalization = !lhsType->IsPolymorphic() &&
+ !lhsType->IsUnlimitedPolymorphic() &&
+ (isDerivedCategory(lhsType->category()) &&
+ Fortran::semantics::IsFinalizable(
+ lhsType->GetDerivedTypeSpec()));
-// call FAIL IMAGE in runtime
-void FirConverter::genFIR(const Fortran::parser::FailImageStmt &stmt) {
- genFailImageStatement(*this);
-}
+ auto lhs = [&]() -> fir::ExtendedValue {
+ if (lhsIsWholeAllocatable) {
+ lhsMutableBox = genExprMutableBox(loc, assign.lhs);
+ // Finalize if needed.
+ if (needFinalization) {
+ mlir::Value isAllocated =
+ fir::factory::genIsAllocatedOrAssociatedTest(
+ *builder, loc, *lhsMutableBox);
+ builder->genIfThen(loc, isAllocated)
+ .genThen([&]() {
+ fir::runtime::genDerivedTypeDestroy(
+ *builder, loc, fir::getBase(*lhsMutableBox));
+ })
+ .end();
+ needFinalization = false;
+ }
-// call STOP, ERROR STOP in runtime
-void FirConverter::genFIR(const Fortran::parser::StopStmt &stmt) {
- genStopStatement(*this, stmt);
-}
+ llvm::SmallVector<mlir::Value> lengthParams;
+ if (const fir::CharBoxValue *charBox = rhs.getCharBox())
+ lengthParams.push_back(charBox->getLen());
+ else if (fir::isDerivedWithLenParameters(rhs))
+ TODO(loc, "assignment to derived type allocatable with "
+ "LEN parameters");
+ lhsRealloc = fir::factory::genReallocIfNeeded(
+ *builder, loc, *lhsMutableBox,
+ /*shape=*/std::nullopt, lengthParams);
+ return lhsRealloc->newValue;
+ }
+ return genExprAddr(assign.lhs, stmtCtx);
+ }();
-void FirConverter::genFIR(const Fortran::parser::ReturnStmt &stmt) {
- Fortran::lower::pft::FunctionLikeUnit *funit = getEval().getOwningProcedure();
- assert(funit && "not inside main program, function or subroutine");
- for (auto it = activeConstructStack.rbegin(),
- rend = activeConstructStack.rend();
- it != rend; ++it) {
- it->stmtCtx.finalizeAndKeep();
- }
- if (funit->isMainProgram()) {
- bridge.fctCtx().finalizeAndKeep();
- genExitRoutine();
- return;
- }
- mlir::Location loc = toLocation();
- if (stmt.v) {
- // Alternate return statement - If this is a subroutine where some
- // alternate entries have alternate returns, but the active entry point
- // does not, ignore the alternate return value. Otherwise, assign it
- // to the compiler-generated result variable.
- const Fortran::semantics::Symbol &symbol = funit->getSubprogramSymbol();
- if (Fortran::semantics::HasAlternateReturns(symbol)) {
- Fortran::lower::StatementContext stmtCtx;
- const Fortran::lower::SomeExpr *expr =
- Fortran::semantics::GetExpr(*stmt.v);
- assert(expr && "missing alternate return expression");
- mlir::Value altReturnIndex = builder->createConvert(
- loc, builder->getIndexType(), createFIRExpr(loc, expr, stmtCtx));
- builder->create<fir::StoreOp>(loc, altReturnIndex,
- getAltReturnResult(symbol));
- }
- }
- // Branch to the last block of the SUBROUTINE, which has the actual return.
- if (!funit->finalBlock) {
- mlir::OpBuilder::InsertPoint insPt = builder->saveInsertionPoint();
- Fortran::lower::setInsertionPointAfterOpenACCLoopIfInside(*builder);
- funit->finalBlock = builder->createBlock(&builder->getRegion());
- builder->restoreInsertionPoint(insPt);
- }
+ if (isNumericScalar || isVector) {
+ // Fortran 2018 10.2.1.3 p8 and p9
+ // Conversions should have been inserted by semantic analysis,
+ // but they can be incorrect between the rhs and lhs. Correct
+ // that here.
+ mlir::Value addr = fir::getBase(lhs);
+ mlir::Value val = fir::getBase(rhs);
+ // A function with multiple entry points returning different
+ // types tags all result variables with one of the largest
+ // types to allow them to share the same storage. Assignment
+ // to a result variable of one of the other types requires
+ // conversion to the actual type.
+ mlir::Type toTy = genType(assign.lhs);
- if (Fortran::lower::isInOpenACCLoop(*builder))
- Fortran::lower::genEarlyReturnInOpenACCLoop(*builder, loc);
- else
- builder->create<mlir::cf::BranchOp>(loc, funit->finalBlock);
-}
+ // If Cray pointee, need to handle the address
+ // Array is handled in genCoordinateOp.
+ if (sym->test(Fortran::semantics::Symbol::Flag::CrayPointee) &&
+ sym->Rank() == 0) {
+ // get the corresponding Cray pointer
-void FirConverter::genFIR(const Fortran::parser::CycleStmt &) {
- genConstructExitBranch(*getEval().controlSuccessor);
-}
+ auto ptrSym = Fortran::lower::getCrayPointer(*sym);
+ fir::ExtendedValue ptr =
+ getSymbolExtendedValue(ptrSym, nullptr);
+ mlir::Value ptrVal = fir::getBase(ptr);
+ mlir::Type ptrTy = genType(*ptrSym);
-void FirConverter::genFIR(const Fortran::parser::ExitStmt &) {
- genConstructExitBranch(*getEval().controlSuccessor);
-}
+ fir::ExtendedValue pte = getSymbolExtendedValue(*sym, nullptr);
+ mlir::Value pteVal = fir::getBase(pte);
+ mlir::Value cnvrt = Fortran::lower::addCrayPointerInst(
+ loc, *builder, ptrVal, ptrTy, pteVal.getType());
+ addr = builder->create<fir::LoadOp>(loc, cnvrt);
+ }
+ mlir::Value cast =
+ isVector ? val
+ : builder->convertWithSemantics(loc, toTy, val);
+ if (fir::dyn_cast_ptrEleTy(addr.getType()) != toTy) {
+ assert(isFuncResultDesignator(assign.lhs) && "type mismatch");
+ addr = builder->createConvert(toLocation(),
+ builder->getRefType(toTy), addr);
+ }
+ builder->create<fir::StoreOp>(loc, cast, addr);
+ } else if (isCharacterCategory(lhsType->category())) {
+ // Fortran 2018 10.2.1.3 p10 and p11
+ fir::factory::CharacterExprHelper{*builder, loc}.createAssign(
+ lhs, rhs);
+ } else if (isDerivedCategory(lhsType->category())) {
+ // Handle parent component.
+ if (Fortran::lower::isParentComponent(assign.lhs)) {
+ if (!fir::getBase(lhs).getType().isa<fir::BaseBoxType>())
+ lhs = fir::getBase(builder->createBox(loc, lhs));
+ lhs = Fortran::lower::updateBoxForParentComponent(*this, lhs,
+ assign.lhs);
+ }
-void FirConverter::genFIR(const Fortran::parser::GotoStmt &) {
- genConstructExitBranch(*getEval().controlSuccessor);
-}
+ // Fortran 2018 10.2.1.3 p13 and p14
+ // Recursively gen an assignment on each element pair.
+ fir::factory::genRecordAssignment(*builder, loc, lhs, rhs,
+ needFinalization);
+ } else {
+ llvm_unreachable("unknown category");
+ }
+ if (lhsIsWholeAllocatable) {
+ assert(lhsRealloc.has_value());
+ fir::factory::finalizeRealloc(*builder, loc, *lhsMutableBox,
+ /*lbounds=*/std::nullopt,
+ /*takeLboundsIfRealloc=*/false,
+ *lhsRealloc);
+ }
+ },
-/// Generate FIR for Evaluation \p eval.
-void FirConverter::genFIR(Fortran::lower::pft::Evaluation &eval,
- bool unstructuredContext) {
- // Start a new unstructured block when applicable. When transitioning
- // from unstructured to structured code, unstructuredContext is true,
- // which accounts for the possibility that the structured code could be
- // a target that starts a new block.
- if (unstructuredContext)
- maybeStartBlock(eval.isConstruct() && eval.lowerAsStructured()
- ? eval.getFirstNestedEvaluation().block
- : eval.block);
+ // [2] User defined assignment. If the context is a scalar
+ // expression then call the procedure.
+ [&](const Fortran::evaluate::ProcedureRef &procRef) {
+ Fortran::lower::StatementContext &ctx =
+ explicitIterationSpace() ? explicitIterSpace.stmtContext()
+ : stmtCtx;
+ Fortran::lower::createSubroutineCall(
+ *this, procRef, explicitIterSpace, implicitIterSpace,
+ localSymbols, ctx, /*isUserDefAssignment=*/true);
+ },
- // Generate evaluation specific code. Even nop calls should usually reach
- // here in case they start a new block or require generation of a generic
- // end-of-block branch. An alternative is to add special case code
- // elsewhere, such as in the genFIR code for a parent construct.
- setCurrentEval(eval);
- setCurrentPosition(eval.position);
- eval.visit([&](const auto &stmt) { genFIR(stmt); });
+ [&](const Fortran::evaluate::Assignment::BoundsSpec &lbExprs) {
+ return genPointerAssignment(loc, assign, lbExprs);
+ },
+ [&](const Fortran::evaluate::Assignment::BoundsRemapping
+ &boundExprs) {
+ return genPointerAssignment(loc, assign, boundExprs);
+ },
+ },
+ assign.u);
+ if (explicitIterationSpace())
+ Fortran::lower::createArrayMergeStores(*this, explicitIterSpace);
+}
- // Generate an end-of-block branch for several special cases. For
- // constructs, this can be done for either the end construct statement,
- // or for the construct itself, which will skip this code if the
- // end statement was visited first and generated a branch.
- Fortran::lower::pft::Evaluation *successor =
- eval.isConstruct() ? eval.getLastNestedEvaluation().lexicalSuccessor
- : eval.lexicalSuccessor;
- if (successor && blockIsUnterminated()) {
- if (successor->isIntermediateConstructStmt() &&
- successor->parentConstruct->lowerAsUnstructured())
- // Exit from an intermediate unstructured IF or SELECT construct block.
- genBranch(successor->parentConstruct->constructExit->block);
- else if (unstructuredContext && eval.isConstructStmt() &&
- successor == eval.controlSuccessor)
- // Exit from a degenerate, empty construct block.
- genBranch(eval.parentConstruct->constructExit->block);
- }
+/// Lower a Where or Elsewhere mask into an hlfir mask region.
+void FirConverter::lowerWhereMaskToHlfir(
+ mlir::Location loc, const Fortran::semantics::SomeExpr *maskExpr) {
+ assert(maskExpr && "mask semantic analysis failed");
+ Fortran::lower::StatementContext maskContext;
+ hlfir::Entity mask = Fortran::lower::convertExprToHLFIR(
+ loc, *this, *maskExpr, localSymbols, maskContext);
+ mask = hlfir::loadTrivialScalar(loc, *builder, mask);
+ auto yieldOp = builder->create<hlfir::YieldOp>(loc, mask);
+ genCleanUpInRegionIfAny(loc, *builder, yieldOp.getCleanup(), maskContext);
}
/// Map mlir function block arguments to the corresponding Fortran dummy
@@ -4189,21 +4195,6 @@ void FirConverter::lowerMod(Fortran::lower::pft::ModuleLikeUnit &mod) {
// Analysis on a nested explicit iteration space.
//===--------------------------------------------------------------------===//
-void FirConverter::analyzeExplicitSpace(
- const Fortran::parser::ConcurrentHeader &header) {
- explicitIterSpace.pushLevel();
- for (const Fortran::parser::ConcurrentControl &ctrl :
- std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t)) {
- const Fortran::semantics::Symbol *ctrlVar =
- std::get<Fortran::parser::Name>(ctrl.t).symbol;
- explicitIterSpace.addSymbol(ctrlVar);
- }
- if (const auto &mask =
- std::get<std::optional<Fortran::parser::ScalarLogicalExpr>>(header.t);
- mask.has_value())
- analyzeExplicitSpace(*Fortran::semantics::GetExpr(*mask));
-}
-
void FirConverter::analyzeExplicitSpace(
const Fortran::evaluate::Assignment *assign) {
auto analyzeAssign = [&](const Fortran::lower::SomeExpr &lhs,
@@ -4229,6 +4220,83 @@ void FirConverter::analyzeExplicitSpace(
explicitIterSpace.endAssign();
}
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::ConcurrentHeader &header) {
+ explicitIterSpace.pushLevel();
+ for (const Fortran::parser::ConcurrentControl &ctrl :
+ std::get<std::list<Fortran::parser::ConcurrentControl>>(header.t)) {
+ const Fortran::semantics::Symbol *ctrlVar =
+ std::get<Fortran::parser::Name>(ctrl.t).symbol;
+ explicitIterSpace.addSymbol(ctrlVar);
+ }
+ if (const auto &mask =
+ std::get<std::optional<Fortran::parser::ScalarLogicalExpr>>(header.t);
+ mask.has_value())
+ analyzeExplicitSpace(*Fortran::semantics::GetExpr(*mask));
+}
+
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::ForallConstruct &forall) {
+ analyzeExplicitSpace(
+ std::get<
+ Fortran::parser::Statement<Fortran::parser::ForallConstructStmt>>(
+ forall.t)
+ .statement);
+ for (const Fortran::parser::ForallBodyConstruct &s :
+ std::get<std::list<Fortran::parser::ForallBodyConstruct>>(forall.t)) {
+ std::visit(Fortran::common::visitors{
+ [&](const Fortran::common::Indirection<
+ Fortran::parser::ForallConstruct> &b) {
+ analyzeExplicitSpace(b.value());
+ },
+ [&](const Fortran::parser::WhereConstruct &w) {
+ analyzeExplicitSpace(w);
+ },
+ [&](const auto &b) { analyzeExplicitSpace(b.statement); }},
+ s.u);
+ }
+ analyzeExplicitSpacePop();
+}
+
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::ForallConstructStmt &forall) {
+ analyzeExplicitSpace(
+ std::get<Fortran::common::Indirection<Fortran::parser::ConcurrentHeader>>(
+ forall.t)
+ .value());
+}
+
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::ForallStmt &forall) {
+ analyzeExplicitSpace(
+ std::get<Fortran::common::Indirection<Fortran::parser::ConcurrentHeader>>(
+ forall.t)
+ .value());
+ analyzeExplicitSpace(std::get<Fortran::parser::UnlabeledStatement<
+ Fortran::parser::ForallAssignmentStmt>>(forall.t)
+ .statement);
+ analyzeExplicitSpacePop();
+}
+
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::MaskedElsewhereStmt &stmt) {
+ const Fortran::lower::SomeExpr *exp = Fortran::semantics::GetExpr(
+ std::get<Fortran::parser::LogicalExpr>(stmt.t));
+ addMaskVariable(exp);
+ analyzeExplicitSpace(*exp);
+}
+
+void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::WhereBodyConstruct &body) {
+ std::visit(Fortran::common::visitors{
+ [&](const Fortran::common::Indirection<
+ Fortran::parser::WhereConstruct> &wc) {
+ analyzeExplicitSpace(wc.value());
+ },
+ [&](const auto &s) { analyzeExplicitSpace(s.statement); }},
+ body.u);
+}
+
void FirConverter::analyzeExplicitSpace(
const Fortran::parser::WhereConstruct &c) {
analyzeExplicitSpace(
@@ -4250,11 +4318,10 @@ void FirConverter::analyzeExplicitSpace(
}
void FirConverter::analyzeExplicitSpace(
- const Fortran::parser::WhereConstructStmt &ws) {
- const Fortran::lower::SomeExpr *exp =
- Fortran::semantics::GetExpr(std::get<Fortran::parser::LogicalExpr>(ws.t));
- addMaskVariable(exp);
- analyzeExplicitSpace(*exp);
+ const Fortran::parser::WhereConstruct::Elsewhere *ew) {
+ for (const Fortran::parser::WhereBodyConstruct &e :
+ std::get<std::list<Fortran::parser::WhereBodyConstruct>>(ew->t))
+ analyzeExplicitSpace(e);
}
void FirConverter::analyzeExplicitSpace(
@@ -4270,31 +4337,13 @@ void FirConverter::analyzeExplicitSpace(
}
void FirConverter::analyzeExplicitSpace(
- const Fortran::parser::WhereBodyConstruct &body) {
- std::visit(Fortran::common::visitors{
- [&](const Fortran::common::Indirection<
- Fortran::parser::WhereConstruct> &wc) {
- analyzeExplicitSpace(wc.value());
- },
- [&](const auto &s) { analyzeExplicitSpace(s.statement); }},
- body.u);
-}
-
-void FirConverter::analyzeExplicitSpace(
- const Fortran::parser::MaskedElsewhereStmt &stmt) {
- const Fortran::lower::SomeExpr *exp = Fortran::semantics::GetExpr(
- std::get<Fortran::parser::LogicalExpr>(stmt.t));
+ const Fortran::parser::WhereConstructStmt &ws) {
+ const Fortran::lower::SomeExpr *exp =
+ Fortran::semantics::GetExpr(std::get<Fortran::parser::LogicalExpr>(ws.t));
addMaskVariable(exp);
analyzeExplicitSpace(*exp);
}
-void FirConverter::analyzeExplicitSpace(
- const Fortran::parser::WhereConstruct::Elsewhere *ew) {
- for (const Fortran::parser::WhereBodyConstruct &e :
- std::get<std::list<Fortran::parser::WhereBodyConstruct>>(ew->t))
- analyzeExplicitSpace(e);
-}
-
void FirConverter::analyzeExplicitSpace(
const Fortran::parser::WhereStmt &stmt) {
const Fortran::lower::SomeExpr *exp = Fortran::semantics::GetExpr(
@@ -4307,49 +4356,6 @@ void FirConverter::analyzeExplicitSpace(
analyzeExplicitSpace(assign.operator->());
}
-void FirConverter::analyzeExplicitSpace(
- const Fortran::parser::ForallStmt &forall) {
- analyzeExplicitSpace(
- std::get<Fortran::common::Indirection<Fortran::parser::ConcurrentHeader>>(
- forall.t)
- .value());
- analyzeExplicitSpace(std::get<Fortran::parser::UnlabeledStatement<
- Fortran::parser::ForallAssignmentStmt>>(forall.t)
- .statement);
- analyzeExplicitSpacePop();
-}
-
-void FirConverter::analyzeExplicitSpace(
- const Fortran::parser::ForallConstructStmt &forall) {
- analyzeExplicitSpace(
- std::get<Fortran::common::Indirection<Fortran::parser::ConcurrentHeader>>(
- forall.t)
- .value());
-}
-
-void FirConverter::analyzeExplicitSpace(
- const Fortran::parser::ForallConstruct &forall) {
- analyzeExplicitSpace(
- std::get<
- Fortran::parser::Statement<Fortran::parser::ForallConstructStmt>>(
- forall.t)
- .statement);
- for (const Fortran::parser::ForallBodyConstruct &s :
- std::get<std::list<Fortran::parser::ForallBodyConstruct>>(forall.t)) {
- std::visit(Fortran::common::visitors{
- [&](const Fortran::common::Indirection<
- Fortran::parser::ForallConstruct> &b) {
- analyzeExplicitSpace(b.value());
- },
- [&](const Fortran::parser::WhereConstruct &w) {
- analyzeExplicitSpace(w);
- },
- [&](const auto &b) { analyzeExplicitSpace(b.statement); }},
- s.u);
- }
- analyzeExplicitSpacePop();
-}
-
void FirConverter::addMaskVariable(Fortran::lower::FrontEndExpr exp) {
// Note: use i8 to store bool values. This avoids round-down behavior found
// with sequences of i1. That is, an array of i1 will be truncated in size
diff --git a/flang/lib/Lower/FirConverter.h b/flang/lib/Lower/FirConverter.h
index f05b80b6ea002..a413417120d27 100644
--- a/flang/lib/Lower/FirConverter.h
+++ b/flang/lib/Lower/FirConverter.h
@@ -83,15 +83,122 @@ class FirConverter : public Fortran::lower::AbstractConverter {
void run(Fortran::lower::pft::Program &pft);
- void declareFunction(Fortran::lower::pft::FunctionLikeUnit &funit);
+ /// The core of the conversion: take an evaluation and generate FIR for it.
+ /// The generation for each individual element of PFT is done via a specific
+ /// genFIR function (see below).
+ /// This function will automatically call the genFIR function for the type
+ /// of the PFT construct.
+ void genFIR(Fortran::lower::pft::Evaluation &eval,
+ bool unstructuredContext = true);
- const Fortran::semantics::Scope &
- getSymbolHostScope(const Fortran::semantics::Symbol &sym);
+private:
+ // All core Fortran constructs:
- void collectHostAssociatedVariables(
- Fortran::lower::pft::FunctionLikeUnit &funit,
- llvm::SetVector<const Fortran::semantics::Symbol *> &escapees);
+ void genFIR(const Fortran::parser::AllocateStmt &);
+ void genFIR(const Fortran::parser::ArithmeticIfStmt &);
+ void genFIR(const Fortran::parser::AssignedGotoStmt &);
+ void genFIR(const Fortran::parser::AssignmentStmt &);
+ void genFIR(const Fortran::parser::AssignStmt &);
+ void genFIR(const Fortran::parser::AssociateConstruct &);
+ void genFIR(const Fortran::parser::BackspaceStmt &);
+ void genFIR(const Fortran::parser::BlockConstruct &);
+ void genFIR(const Fortran::parser::CallStmt &);
+ void genFIR(const Fortran::parser::CaseConstruct &);
+ void genFIR(const Fortran::parser::ChangeTeamConstruct &);
+ void genFIR(const Fortran::parser::ChangeTeamStmt &);
+ void genFIR(const Fortran::parser::CloseStmt &);
+ void genFIR(const Fortran::parser::CompilerDirective &);
+ void genFIR(const Fortran::parser::ComputedGotoStmt &);
+ void genFIR(const Fortran::parser::ConcurrentHeader &);
+ void genFIR(const Fortran::parser::CriticalConstruct &);
+ void genFIR(const Fortran::parser::CriticalStmt &);
+ void genFIR(const Fortran::parser::CycleStmt &);
+ void genFIR(const Fortran::parser::DeallocateStmt &);
+ void genFIR(const Fortran::parser::DoConstruct &);
+ void genFIR(const Fortran::parser::ElsewhereStmt &);
+ void genFIR(const Fortran::parser::EndChangeTeamStmt &);
+ void genFIR(const Fortran::parser::EndCriticalStmt &);
+ void genFIR(const Fortran::parser::EndfileStmt &);
+ void genFIR(const Fortran::parser::EndForallStmt &);
+ void genFIR(const Fortran::parser::EndWhereStmt &);
+ void genFIR(const Fortran::parser::EventPostStmt &);
+ void genFIR(const Fortran::parser::EventWaitStmt &);
+ void genFIR(const Fortran::parser::ExitStmt &);
+ void genFIR(const Fortran::parser::FailImageStmt &);
+ void genFIR(const Fortran::parser::FlushStmt &);
+ void genFIR(const Fortran::parser::ForallAssignmentStmt &);
+ void genFIR(const Fortran::parser::ForallConstruct &);
+ void genFIR(const Fortran::parser::ForallConstructStmt &);
+ void genFIR(const Fortran::parser::ForallStmt &);
+ void genFIR(const Fortran::parser::FormatStmt &);
+ void genFIR(const Fortran::parser::FormTeamStmt &);
+ void genFIR(const Fortran::parser::GotoStmt &);
+ void genFIR(const Fortran::parser::IfConstruct &);
+ void genFIR(const Fortran::parser::InquireStmt &);
+ void genFIR(const Fortran::parser::LockStmt &);
+ void genFIR(const Fortran::parser::MaskedElsewhereStmt &);
+ void genFIR(const Fortran::parser::NullifyStmt &);
+ void genFIR(const Fortran::parser::OpenACCConstruct &);
+ void genFIR(const Fortran::parser::OpenACCDeclarativeConstruct &);
+ void genFIR(const Fortran::parser::OpenACCRoutineConstruct &);
+ void genFIR(const Fortran::parser::OpenMPConstruct &);
+ void genFIR(const Fortran::parser::OpenMPDeclarativeConstruct &);
+ void genFIR(const Fortran::parser::OpenStmt &);
+ void genFIR(const Fortran::parser::PauseStmt &);
+ void genFIR(const Fortran::parser::PointerAssignmentStmt &);
+ void genFIR(const Fortran::parser::PrintStmt &);
+ void genFIR(const Fortran::parser::ReadStmt &);
+ void genFIR(const Fortran::parser::ReturnStmt &);
+ void genFIR(const Fortran::parser::RewindStmt &);
+ void genFIR(const Fortran::parser::SelectCaseStmt &);
+ void genFIR(const Fortran::parser::SelectRankCaseStmt &);
+ void genFIR(const Fortran::parser::SelectRankConstruct &);
+ void genFIR(const Fortran::parser::SelectRankStmt &);
+ void genFIR(const Fortran::parser::SelectTypeConstruct &);
+ void genFIR(const Fortran::parser::StopStmt &);
+ void genFIR(const Fortran::parser::SyncAllStmt &);
+ void genFIR(const Fortran::parser::SyncImagesStmt &);
+ void genFIR(const Fortran::parser::SyncMemoryStmt &);
+ void genFIR(const Fortran::parser::SyncTeamStmt &);
+ void genFIR(const Fortran::parser::UnlockStmt &);
+ void genFIR(const Fortran::parser::WaitStmt &);
+ void genFIR(const Fortran::parser::WhereBodyConstruct &);
+ void genFIR(const Fortran::parser::WhereConstruct &);
+ void genFIR(const Fortran::parser::WhereConstruct::Elsewhere &);
+ void genFIR(const Fortran::parser::WhereConstruct::MaskedElsewhere &);
+ void genFIR(const Fortran::parser::WhereConstructStmt &);
+ void genFIR(const Fortran::parser::WhereStmt &);
+ void genFIR(const Fortran::parser::WriteStmt &);
+
+ // Nop statements - No code, or code is generated at the construct level.
+ // But note that the genFIR call immediately below that wraps one of these
+ // calls does block management, possibly starting a new block, and possibly
+ // generating a branch to end a block. So these calls may still be required
+ // for that functionality.
+ void genFIR(const Fortran::parser::AssociateStmt &) {} // nop
+ void genFIR(const Fortran::parser::BlockStmt &) {} // nop
+ void genFIR(const Fortran::parser::CaseStmt &) {} // nop
+ void genFIR(const Fortran::parser::ContinueStmt &) {} // nop
+ void genFIR(const Fortran::parser::ElseIfStmt &) {} // nop
+ void genFIR(const Fortran::parser::ElseStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndAssociateStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndBlockStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndDoStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndFunctionStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndIfStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndMpSubprogramStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndProgramStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndSelectStmt &) {} // nop
+ void genFIR(const Fortran::parser::EndSubroutineStmt &) {} // nop
+ void genFIR(const Fortran::parser::EntryStmt &) {} // nop
+ void genFIR(const Fortran::parser::IfStmt &) {} // nop
+ void genFIR(const Fortran::parser::IfThenStmt &) {} // nop
+ void genFIR(const Fortran::parser::NonLabelDoStmt &) {} // nop
+ void genFIR(const Fortran::parser::OmpEndLoopDirective &) {} // nop
+ void genFIR(const Fortran::parser::SelectTypeStmt &) {} // nop
+ void genFIR(const Fortran::parser::TypeGuardStmt &) {} // nop
+public:
//===--------------------------------------------------------------------===//
// AbstractConverter overrides
//===--------------------------------------------------------------------===//
@@ -400,6 +507,15 @@ class FirConverter : public Fortran::lower::AbstractConverter {
llvm::SmallSetVector<Fortran::semantics::SymbolRef, 32> seen;
};
+ void declareFunction(Fortran::lower::pft::FunctionLikeUnit &funit);
+
+ const Fortran::semantics::Scope &
+ getSymbolHostScope(const Fortran::semantics::Symbol &sym);
+
+ void collectHostAssociatedVariables(
+ Fortran::lower::pft::FunctionLikeUnit &funit,
+ llvm::SetVector<const Fortran::semantics::Symbol *> &escapees);
+
//===--------------------------------------------------------------------===//
// Helper member functions
//===--------------------------------------------------------------------===//
@@ -559,29 +675,18 @@ class FirConverter : public Fortran::lower::AbstractConverter {
mlir::func::FuncOp getFunc(llvm::StringRef name, mlir::FunctionType ty);
- void genFIR(const Fortran::parser::CallStmt &stmt);
- void genFIR(const Fortran::parser::ComputedGotoStmt &stmt);
- void genFIR(const Fortran::parser::ArithmeticIfStmt &stmt);
- void genFIR(const Fortran::parser::AssignedGotoStmt &stmt);
-
+ void genFIRIncrementLoopBegin(IncrementLoopNestInfo &incrementLoopNestInfo);
+ void genFIRIncrementLoopEnd(IncrementLoopNestInfo &incrementLoopNestInfo);
IncrementLoopNestInfo getConcurrentControl(
const Fortran::parser::ConcurrentHeader &header,
const std::list<Fortran::parser::LocalitySpec> &localityList = {});
void handleLocalitySpecs(const IncrementLoopInfo &info);
- void genFIR(const Fortran::parser::DoConstruct &doConstruct);
-
mlir::Value genControlValue(const Fortran::lower::SomeExpr *expr,
const IncrementLoopInfo &info,
bool *isConst = nullptr);
- void genFIRIncrementLoopBegin(IncrementLoopNestInfo &incrementLoopNestInfo);
- void genFIRIncrementLoopEnd(IncrementLoopNestInfo &incrementLoopNestInfo);
-
- void genFIR(const Fortran::parser::IfConstruct &);
- void genFIR(const Fortran::parser::CaseConstruct &);
-
template <typename A>
void genNestedStatement(const Fortran::parser::Statement<A> &stmt) {
setCurrentPosition(stmt.source);
@@ -591,10 +696,6 @@ class FirConverter : public Fortran::lower::AbstractConverter {
void forceControlVariableBinding(const Fortran::semantics::Symbol *sym,
mlir::Value inducVar);
- void genFIR(const Fortran::parser::ConcurrentHeader &header);
- void genFIR(const Fortran::parser::ForallAssignmentStmt &stmt);
- void genFIR(const Fortran::parser::EndForallStmt &);
-
template <typename A> void prepareExplicitSpace(const A &forall) {
if (!explicitIterSpace.isActive())
analyzeExplicitSpace(forall);
@@ -608,48 +709,12 @@ class FirConverter : public Fortran::lower::AbstractConverter {
localSymbols.popScope();
}
- void genFIR(const Fortran::parser::ForallStmt &stmt);
- void genFIR(const Fortran::parser::ForallConstruct &forall);
- void genFIR(const Fortran::parser::ForallConstructStmt &stmt);
-
void genForallNest(const Fortran::parser::ConcurrentHeader &header);
- void genFIR(const Fortran::parser::CompilerDirective &);
- void genFIR(const Fortran::parser::OpenACCConstruct &acc);
- void genFIR(const Fortran::parser::OpenACCDeclarativeConstruct &accDecl);
- void genFIR(const Fortran::parser::OpenACCRoutineConstruct &acc);
- void genFIR(const Fortran::parser::OpenMPConstruct &omp);
- void genFIR(const Fortran::parser::OpenMPDeclarativeConstruct &ompDecl);
- void genFIR(const Fortran::parser::SelectCaseStmt &stmt);
-
fir::ExtendedValue
genAssociateSelector(const Fortran::lower::SomeExpr &selector,
Fortran::lower::StatementContext &stmtCtx);
- void genFIR(const Fortran::parser::AssociateConstruct &);
- void genFIR(const Fortran::parser::BlockConstruct &blockConstruct);
- void genFIR(const Fortran::parser::ChangeTeamConstruct &construct);
- void genFIR(const Fortran::parser::ChangeTeamStmt &stmt);
- void genFIR(const Fortran::parser::EndChangeTeamStmt &stmt);
- void genFIR(const Fortran::parser::CriticalConstruct &criticalConstruct);
- void genFIR(const Fortran::parser::CriticalStmt &);
- void genFIR(const Fortran::parser::EndCriticalStmt &);
- void genFIR(const Fortran::parser::SelectRankConstruct &selectRankConstruct);
- void genFIR(const Fortran::parser::SelectRankStmt &);
- void genFIR(const Fortran::parser::SelectRankCaseStmt &);
- void genFIR(const Fortran::parser::SelectTypeConstruct &selectTypeConstruct);
- void genFIR(const Fortran::parser::BackspaceStmt &stmt);
- void genFIR(const Fortran::parser::CloseStmt &stmt);
- void genFIR(const Fortran::parser::EndfileStmt &stmt);
- void genFIR(const Fortran::parser::FlushStmt &stmt);
- void genFIR(const Fortran::parser::InquireStmt &stmt);
- void genFIR(const Fortran::parser::OpenStmt &stmt);
- void genFIR(const Fortran::parser::PrintStmt &stmt);
- void genFIR(const Fortran::parser::ReadStmt &stmt);
- void genFIR(const Fortran::parser::RewindStmt &stmt);
- void genFIR(const Fortran::parser::WaitStmt &stmt);
- void genFIR(const Fortran::parser::WriteStmt &stmt);
-
template <typename A>
void genIoConditionBranches(Fortran::lower::pft::Evaluation &eval,
const A &specList, mlir::Value iostat) {
@@ -710,14 +775,6 @@ class FirConverter : public Fortran::lower::AbstractConverter {
genMultiwayBranch(selector, valueList, labelList, eval.nonNopSuccessor());
}
- void genFIR(const Fortran::parser::AllocateStmt &stmt);
- void genFIR(const Fortran::parser::DeallocateStmt &stmt);
- void genFIR(const Fortran::parser::NullifyStmt &stmt);
- void genFIR(const Fortran::parser::EventPostStmt &stmt);
- void genFIR(const Fortran::parser::EventWaitStmt &stmt);
- void genFIR(const Fortran::parser::FormTeamStmt &stmt);
- void genFIR(const Fortran::parser::LockStmt &stmt);
-
fir::ExtendedValue
genInitializerExprValue(const Fortran::lower::SomeExpr &expr,
Fortran::lower::StatementContext &stmtCtx) {
@@ -755,14 +812,13 @@ class FirConverter : public Fortran::lower::AbstractConverter {
mlir::Value createLboundArray(llvm::ArrayRef<mlir::Value> lbounds,
mlir::Location loc);
- void genPointerAssignment(
- mlir::Location loc, const Fortran::evaluate::Assignment &assign,
- const Fortran::evaluate::Assignment::BoundsSpec &lbExprs);
-
mlir::Value createBoundArray(llvm::ArrayRef<mlir::Value> lbounds,
llvm::ArrayRef<mlir::Value> ubounds,
mlir::Location loc);
+ void genPointerAssignment(
+ mlir::Location loc, const Fortran::evaluate::Assignment &assign,
+ const Fortran::evaluate::Assignment::BoundsSpec &lbExprs);
void genPointerAssignment(
mlir::Location loc, const Fortran::evaluate::Assignment &assign,
const Fortran::evaluate::Assignment::BoundsRemapping &boundExprs);
@@ -804,65 +860,8 @@ class FirConverter : public Fortran::lower::AbstractConverter {
bool isInsideHlfirWhere() const { return isInsideOp<hlfir::WhereOp>(); }
- void genFIR(const Fortran::parser::WhereConstruct &c);
- void genFIR(const Fortran::parser::WhereBodyConstruct &body);
-
void lowerWhereMaskToHlfir(mlir::Location loc,
const Fortran::semantics::SomeExpr *maskExpr);
- void genFIR(const Fortran::parser::WhereConstructStmt &stmt);
- void genFIR(const Fortran::parser::WhereConstruct::MaskedElsewhere &ew);
- void genFIR(const Fortran::parser::MaskedElsewhereStmt &stmt);
- void genFIR(const Fortran::parser::WhereConstruct::Elsewhere &ew);
- void genFIR(const Fortran::parser::ElsewhereStmt &stmt);
- void genFIR(const Fortran::parser::EndWhereStmt &);
- void genFIR(const Fortran::parser::WhereStmt &stmt);
- void genFIR(const Fortran::parser::PointerAssignmentStmt &stmt);
- void genFIR(const Fortran::parser::AssignmentStmt &stmt);
- void genFIR(const Fortran::parser::SyncAllStmt &stmt);
- void genFIR(const Fortran::parser::SyncImagesStmt &stmt);
- void genFIR(const Fortran::parser::SyncMemoryStmt &stmt);
- void genFIR(const Fortran::parser::SyncTeamStmt &stmt);
- void genFIR(const Fortran::parser::UnlockStmt &stmt);
- void genFIR(const Fortran::parser::AssignStmt &stmt);
- void genFIR(const Fortran::parser::FormatStmt &);
- void genFIR(const Fortran::parser::PauseStmt &stmt);
- void genFIR(const Fortran::parser::FailImageStmt &stmt);
- void genFIR(const Fortran::parser::StopStmt &stmt);
- void genFIR(const Fortran::parser::ReturnStmt &stmt);
- void genFIR(const Fortran::parser::CycleStmt &);
- void genFIR(const Fortran::parser::ExitStmt &);
- void genFIR(const Fortran::parser::GotoStmt &);
-
- // Nop statements - No code, or code is generated at the construct level.
- // But note that the genFIR call immediately below that wraps one of these
- // calls does block management, possibly starting a new block, and possibly
- // generating a branch to end a block. So these calls may still be required
- // for that functionality.
- void genFIR(const Fortran::parser::AssociateStmt &) {} // nop
- void genFIR(const Fortran::parser::BlockStmt &) {} // nop
- void genFIR(const Fortran::parser::CaseStmt &) {} // nop
- void genFIR(const Fortran::parser::ContinueStmt &) {} // nop
- void genFIR(const Fortran::parser::ElseIfStmt &) {} // nop
- void genFIR(const Fortran::parser::ElseStmt &) {} // nop
- void genFIR(const Fortran::parser::EndAssociateStmt &) {} // nop
- void genFIR(const Fortran::parser::EndBlockStmt &) {} // nop
- void genFIR(const Fortran::parser::EndDoStmt &) {} // nop
- void genFIR(const Fortran::parser::EndFunctionStmt &) {} // nop
- void genFIR(const Fortran::parser::EndIfStmt &) {} // nop
- void genFIR(const Fortran::parser::EndMpSubprogramStmt &) {} // nop
- void genFIR(const Fortran::parser::EndProgramStmt &) {} // nop
- void genFIR(const Fortran::parser::EndSelectStmt &) {} // nop
- void genFIR(const Fortran::parser::EndSubroutineStmt &) {} // nop
- void genFIR(const Fortran::parser::EntryStmt &) {} // nop
- void genFIR(const Fortran::parser::IfStmt &) {} // nop
- void genFIR(const Fortran::parser::IfThenStmt &) {} // nop
- void genFIR(const Fortran::parser::NonLabelDoStmt &) {} // nop
- void genFIR(const Fortran::parser::OmpEndLoopDirective &) {} // nop
- void genFIR(const Fortran::parser::SelectTypeStmt &) {} // nop
- void genFIR(const Fortran::parser::TypeGuardStmt &) {} // nop
-
- void genFIR(Fortran::lower::pft::Evaluation &eval,
- bool unstructuredContext = true);
void mapDummiesAndResults(Fortran::lower::pft::FunctionLikeUnit &funit,
const Fortran::lower::CalleeInterface &callee);
@@ -956,8 +955,6 @@ class FirConverter : public Fortran::lower::AbstractConverter {
// Analysis on a nested explicit iteration space.
//===--------------------------------------------------------------------===//
- void analyzeExplicitSpace(const Fortran::parser::ConcurrentHeader &header);
-
template <bool LHS = false, typename A>
void analyzeExplicitSpace(const Fortran::evaluate::Expr<A> &e) {
explicitIterSpace.exprBase(&e, LHS);
@@ -965,30 +962,31 @@ class FirConverter : public Fortran::lower::AbstractConverter {
void analyzeExplicitSpace(const Fortran::evaluate::Assignment *assign);
- void analyzeExplicitSpace(const Fortran::parser::ForallAssignmentStmt &stmt) {
- std::visit([&](const auto &s) { analyzeExplicitSpace(s); }, stmt.u);
- }
-
void analyzeExplicitSpace(const Fortran::parser::AssignmentStmt &s) {
analyzeExplicitSpace(s.typedAssignment->v.operator->());
}
+ void analyzeExplicitSpace(const Fortran::parser::ConcurrentHeader &header);
+ void analyzeExplicitSpace(const Fortran::parser::ForallAssignmentStmt &stmt) {
+ std::visit([&](const auto &s) { analyzeExplicitSpace(s); }, stmt.u);
+ }
+
+ void analyzeExplicitSpace(const Fortran::parser::ForallConstruct &forall);
+ void analyzeExplicitSpace(const Fortran::parser::ForallConstructStmt &forall);
+ void analyzeExplicitSpace(const Fortran::parser::ForallStmt &forall);
+ void analyzeExplicitSpace(const Fortran::parser::MaskedElsewhereStmt &stmt);
void analyzeExplicitSpace(const Fortran::parser::PointerAssignmentStmt &s) {
analyzeExplicitSpace(s.typedAssignment->v.operator->());
}
+ void analyzeExplicitSpace(const Fortran::parser::WhereBodyConstruct &body);
void analyzeExplicitSpace(const Fortran::parser::WhereConstruct &c);
- void analyzeExplicitSpace(const Fortran::parser::WhereConstructStmt &ws);
+ void analyzeExplicitSpace(
+ const Fortran::parser::WhereConstruct::Elsewhere *ew);
void analyzeExplicitSpace(
const Fortran::parser::WhereConstruct::MaskedElsewhere &ew);
- void analyzeExplicitSpace(const Fortran::parser::WhereBodyConstruct &body);
- void analyzeExplicitSpace(const Fortran::parser::MaskedElsewhereStmt &stmt);
- void
- analyzeExplicitSpace(const Fortran::parser::WhereConstruct::Elsewhere *ew);
+ void analyzeExplicitSpace(const Fortran::parser::WhereConstructStmt &ws);
void analyzeExplicitSpace(const Fortran::parser::WhereStmt &stmt);
- void analyzeExplicitSpace(const Fortran::parser::ForallStmt &forall);
- void analyzeExplicitSpace(const Fortran::parser::ForallConstructStmt &forall);
- void analyzeExplicitSpace(const Fortran::parser::ForallConstruct &forall);
void analyzeExplicitSpacePop() { explicitIterSpace.popLevel(); }
>From d746452e9e98dfc36c33e6f2470f0f326af1dad0 Mon Sep 17 00:00:00 2001
From: Krzysztof Parzyszek <Krzysztof.Parzyszek at amd.com>
Date: Thu, 7 Dec 2023 12:14:16 -0600
Subject: [PATCH 3/3] Move bodies of inline functions out of class definition,
NFC
This is to make the class definition more readable. There are no
functional changes.
---
flang/lib/Lower/FirConverter.h | 908 ++++++++++++++++++++-------------
1 file changed, 557 insertions(+), 351 deletions(-)
diff --git a/flang/lib/Lower/FirConverter.h b/flang/lib/Lower/FirConverter.h
index a413417120d27..2f005fd16939d 100644
--- a/flang/lib/Lower/FirConverter.h
+++ b/flang/lib/Lower/FirConverter.h
@@ -203,9 +203,7 @@ class FirConverter : public Fortran::lower::AbstractConverter {
// AbstractConverter overrides
//===--------------------------------------------------------------------===//
- mlir::Value getSymbolAddress(Fortran::lower::SymbolRef sym) override final {
- return lookupSymbol(sym).getAddr();
- }
+ mlir::Value getSymbolAddress(Fortran::lower::SymbolRef sym) override final;
fir::ExtendedValue
symBoxToExtendedValue(const Fortran::lower::SymbolBox &symBox);
@@ -217,36 +215,24 @@ class FirConverter : public Fortran::lower::AbstractConverter {
mlir::Value impliedDoBinding(llvm::StringRef name) override final;
void copySymbolBinding(Fortran::lower::SymbolRef src,
- Fortran::lower::SymbolRef target) override final {
- localSymbols.copySymbolBinding(src, target);
- }
+ Fortran::lower::SymbolRef target) override final;
bool bindIfNewSymbol(Fortran::lower::SymbolRef sym,
const fir::ExtendedValue &exval);
void bindSymbol(Fortran::lower::SymbolRef sym,
- const fir::ExtendedValue &exval) override final {
- addSymbol(sym, exval, /*forced=*/true);
- }
+ const fir::ExtendedValue &exval) override final;
void
- overrideExprValues(const Fortran::lower::ExprToValueMap *map) override final {
- exprValueOverrides = map;
- }
+ overrideExprValues(const Fortran::lower::ExprToValueMap *map) override final;
- const Fortran::lower::ExprToValueMap *getExprOverrides() override final {
- return exprValueOverrides;
- }
+ const Fortran::lower::ExprToValueMap *getExprOverrides() override final;
bool lookupLabelSet(Fortran::lower::SymbolRef sym,
Fortran::lower::pft::LabelSet &labelSet) override final;
Fortran::lower::pft::Evaluation *
- lookupLabel(Fortran::lower::pft::Label label) override final {
- Fortran::lower::pft::FunctionLikeUnit &owningProc =
- *getEval().getOwningProcedure();
- return owningProc.labelEvaluationMap.lookup(label);
- }
+ lookupLabel(Fortran::lower::pft::Label label) override final;
fir::ExtendedValue
genExprAddr(const Fortran::lower::SomeExpr &expr,
@@ -262,43 +248,19 @@ class FirConverter : public Fortran::lower::AbstractConverter {
genExprBox(mlir::Location loc, const Fortran::lower::SomeExpr &expr,
Fortran::lower::StatementContext &stmtCtx) override final;
- Fortran::evaluate::FoldingContext &getFoldingContext() override final {
- return foldingContext;
- }
-
- mlir::Type genType(const Fortran::lower::SomeExpr &expr) override final {
- return Fortran::lower::translateSomeExprToFIRType(*this, expr);
- }
+ Fortran::evaluate::FoldingContext &getFoldingContext() override final;
- mlir::Type genType(const Fortran::lower::pft::Variable &var) override final {
- return Fortran::lower::translateVariableToFIRType(*this, var);
- }
-
- mlir::Type genType(Fortran::lower::SymbolRef sym) override final {
- return Fortran::lower::translateSymbolToFIRType(*this, sym);
- }
+ mlir::Type genType(const Fortran::lower::SomeExpr &expr) override final;
+ mlir::Type genType(const Fortran::lower::pft::Variable &var) override final;
+ mlir::Type genType(Fortran::lower::SymbolRef sym) override final;
+ mlir::Type genType(Fortran::common::TypeCategory tc, int kind,
+ llvm::ArrayRef<std::int64_t> lenParameters) override final;
mlir::Type
- genType(Fortran::common::TypeCategory tc, int kind,
- llvm::ArrayRef<std::int64_t> lenParameters) override final {
- return Fortran::lower::getFIRType(&getMLIRContext(), tc, kind,
- lenParameters);
- }
+ genType(const Fortran::semantics::DerivedTypeSpec &tySpec) override final;
+ mlir::Type genType(Fortran::common::TypeCategory tc) override final;
- mlir::Type
- genType(const Fortran::semantics::DerivedTypeSpec &tySpec) override final {
- return Fortran::lower::translateDerivedTypeToFIRType(*this, tySpec);
- }
-
- mlir::Type genType(Fortran::common::TypeCategory tc) override final {
- return Fortran::lower::getFIRType(
- &getMLIRContext(), tc, bridge.getDefaultKinds().GetDefaultKind(tc),
- std::nullopt);
- }
-
- bool isPresentShallowLookup(Fortran::semantics::Symbol &sym) override final {
- return bool(shallowLookupSymbol(sym));
- }
+ bool isPresentShallowLookup(Fortran::semantics::Symbol &sym) override final;
bool createHostAssociateVarClone(
const Fortran::semantics::Symbol &sym) override final;
@@ -320,67 +282,37 @@ class FirConverter : public Fortran::lower::AbstractConverter {
Fortran::semantics::Symbol::Flag flag, bool collectSymbols,
bool checkHostAssociatedSymbols) override final;
- mlir::Location getCurrentLocation() override final { return toLocation(); }
-
- /// Generate a dummy location.
- mlir::Location genUnknownLocation() override final {
- // Note: builder may not be instantiated yet
- return mlir::UnknownLoc::get(&getMLIRContext());
- }
+ mlir::Location getCurrentLocation() override final;
+ mlir::Location genUnknownLocation() override final;
mlir::Location
genLocation(const Fortran::parser::CharBlock &block) override final;
- const Fortran::semantics::Scope &getCurrentScope() override final {
- return bridge.getSemanticsContext().FindScope(currentPosition);
- }
-
- fir::FirOpBuilder &getFirOpBuilder() override final { return *builder; }
-
- mlir::ModuleOp &getModuleOp() override final { return bridge.getModule(); }
+ const Fortran::semantics::Scope &getCurrentScope() override final;
+ fir::FirOpBuilder &getFirOpBuilder() override final;
+ mlir::ModuleOp &getModuleOp() override final;
+ mlir::MLIRContext &getMLIRContext() override final;
- mlir::MLIRContext &getMLIRContext() override final {
- return bridge.getMLIRContext();
- }
std::string
- mangleName(const Fortran::semantics::Symbol &symbol) override final {
- return Fortran::lower::mangle::mangleName(
- symbol, scopeBlockIdMap, /*keepExternalInScope=*/false,
- getLoweringOptions().getUnderscoring());
- }
+ mangleName(const Fortran::semantics::Symbol &symbol) override final;
+
std::string mangleName(
- const Fortran::semantics::DerivedTypeSpec &derivedType) override final {
- return Fortran::lower::mangle::mangleName(derivedType, scopeBlockIdMap);
- }
- std::string mangleName(std::string &name) override final {
- return Fortran::lower::mangle::mangleName(name, getCurrentScope(),
- scopeBlockIdMap);
- }
+ const Fortran::semantics::DerivedTypeSpec &derivedType) override final;
+ std::string mangleName(std::string &name) override final;
+
std::string getRecordTypeFieldName(
- const Fortran::semantics::Symbol &component) override final {
- return Fortran::lower::mangle::getRecordTypeFieldName(component,
- scopeBlockIdMap);
- }
- const fir::KindMapping &getKindMap() override final {
- return bridge.getKindMap();
- }
+ const Fortran::semantics::Symbol &component) override final;
+ const fir::KindMapping &getKindMap() override final;
Fortran::lower::StatementContext &getFctCtx() override final;
- mlir::Value hostAssocTupleValue() override final { return hostAssocTuple; }
-
- /// Record a binding for the ssa-value of the tuple for this function.
- void bindHostAssocTuple(mlir::Value val) override final {
- assert(!hostAssocTuple && val);
- hostAssocTuple = val;
- }
+ mlir::Value hostAssocTupleValue() override final;
+ void bindHostAssocTuple(mlir::Value val) override final;
void registerTypeInfo(mlir::Location loc,
Fortran::lower::SymbolRef typeInfoSym,
const Fortran::semantics::DerivedTypeSpec &typeSpec,
- fir::RecordType type) override final {
- typeInfoConverter.registerTypeInfo(*this, loc, typeInfoSym, typeSpec, type);
- }
+ fir::RecordType type) override final;
llvm::StringRef
getUniqueLitName(mlir::Location loc,
@@ -522,30 +454,17 @@ class FirConverter : public Fortran::lower::AbstractConverter {
mlir::Value createFIRExpr(mlir::Location loc,
const Fortran::lower::SomeExpr *expr,
- Fortran::lower::StatementContext &stmtCtx) {
- return fir::getBase(genExprValue(*expr, stmtCtx, &loc));
- }
+ Fortran::lower::StatementContext &stmtCtx);
Fortran::lower::SymbolBox
lookupSymbol(const Fortran::semantics::Symbol &sym,
Fortran::lower::SymMap *symMap = nullptr);
- /// Find the symbol in the inner-most level of the local map or return null.
Fortran::lower::SymbolBox
- shallowLookupSymbol(const Fortran::semantics::Symbol &sym) {
- if (Fortran::lower::SymbolBox v = localSymbols.shallowLookupSymbol(sym))
- return v;
- return {};
- }
+ shallowLookupSymbol(const Fortran::semantics::Symbol &sym);
- /// Find the symbol in one level up of symbol map such as for host-association
- /// in OpenMP code or return null.
Fortran::lower::SymbolBox
- lookupOneLevelUpSymbol(const Fortran::semantics::Symbol &sym) {
- if (Fortran::lower::SymbolBox v = localSymbols.lookupOneLevelUpSymbol(sym))
- return v;
- return {};
- }
+ lookupOneLevelUpSymbol(const Fortran::semantics::Symbol &sym);
bool addSymbol(const Fortran::semantics::SymbolRef sym,
fir::ExtendedValue val, bool forced = false);
@@ -557,39 +476,22 @@ class FirConverter : public Fortran::lower::AbstractConverter {
const Fortran::semantics::Symbol &sym,
bool isUnordered);
- static bool isNumericScalarCategory(Fortran::common::TypeCategory cat) {
- return cat == Fortran::common::TypeCategory::Integer ||
- cat == Fortran::common::TypeCategory::Real ||
- cat == Fortran::common::TypeCategory::Complex ||
- cat == Fortran::common::TypeCategory::Logical;
- }
- static bool isLogicalCategory(Fortran::common::TypeCategory cat) {
- return cat == Fortran::common::TypeCategory::Logical;
- }
- static bool isCharacterCategory(Fortran::common::TypeCategory cat) {
- return cat == Fortran::common::TypeCategory::Character;
- }
- static bool isDerivedCategory(Fortran::common::TypeCategory cat) {
- return cat == Fortran::common::TypeCategory::Derived;
- }
+ static bool isNumericScalarCategory(Fortran::common::TypeCategory cat);
+ static bool isLogicalCategory(Fortran::common::TypeCategory cat);
+ static bool isCharacterCategory(Fortran::common::TypeCategory cat);
+ static bool isDerivedCategory(Fortran::common::TypeCategory cat);
mlir::Block *insertBlock(mlir::Block *block);
Fortran::lower::pft::Evaluation &evalOfLabel(Fortran::parser::Label label);
- void genBranch(mlir::Block *targetBlock) {
- assert(targetBlock && "missing unconditional target block");
- builder->create<mlir::cf::BranchOp>(toLocation(), targetBlock);
- }
+ void genBranch(mlir::Block *targetBlock);
void genConditionalBranch(mlir::Value cond, mlir::Block *trueTarget,
mlir::Block *falseTarget);
void genConditionalBranch(mlir::Value cond,
Fortran::lower::pft::Evaluation *trueTarget,
- Fortran::lower::pft::Evaluation *falseTarget) {
- genConditionalBranch(cond, trueTarget->block, falseTarget->block);
- }
-
+ Fortran::lower::pft::Evaluation *falseTarget);
void genConditionalBranch(const Fortran::parser::ScalarLogicalExpr &expr,
mlir::Block *trueTarget, mlir::Block *falseTarget);
void genConditionalBranch(const Fortran::parser::ScalarLogicalExpr &expr,
@@ -611,16 +513,8 @@ class FirConverter : public Fortran::lower::AbstractConverter {
mlir::Block *errorBlock = nullptr);
void pushActiveConstruct(Fortran::lower::pft::Evaluation &eval,
- Fortran::lower::StatementContext &stmtCtx) {
- activeConstructStack.push_back(ConstructContext{eval, stmtCtx});
- eval.activeConstruct = true;
- }
-
- void popActiveConstruct() {
- assert(!activeConstructStack.empty() && "invalid active construct stack");
- activeConstructStack.back().eval.activeConstruct = false;
- activeConstructStack.pop_back();
- }
+ Fortran::lower::StatementContext &stmtCtx);
+ void popActiveConstruct();
//===--------------------------------------------------------------------===//
// Termination of symbolically referenced execution units
@@ -628,24 +522,14 @@ class FirConverter : public Fortran::lower::AbstractConverter {
/// END of program
///
- /// Generate the cleanup block before the program exits
- void genExitRoutine() {
- if (blockIsUnterminated())
- builder->create<mlir::func::ReturnOp>(toLocation());
- }
+ void genExitRoutine();
/// END of procedure-like constructs
///
void genReturnSymbol(const Fortran::semantics::Symbol &functionSymbol);
- /// Get the return value of a call to \p symbol, which is a subroutine entry
- /// point that has alternative return specifiers.
const mlir::Value
- getAltReturnResult(const Fortran::semantics::Symbol &symbol) {
- assert(Fortran::semantics::HasAlternateReturns(symbol) &&
- "subroutine does not have alternate returns");
- return getSymbolAddress(symbol);
- }
+ getAltReturnResult(const Fortran::semantics::Symbol &symbol);
void genFIRProcedureExit(Fortran::lower::pft::FunctionLikeUnit &funit,
const Fortran::semantics::Symbol &symbol);
@@ -654,24 +538,8 @@ class FirConverter : public Fortran::lower::AbstractConverter {
// Statements that have control-flow semantics
//
- /// Generate an If[Then]Stmt condition or its negation.
template <typename A>
- mlir::Value genIfCondition(const A *stmt, bool negate = false) {
- mlir::Location loc = toLocation();
- Fortran::lower::StatementContext stmtCtx;
- mlir::Value condExpr = createFIRExpr(
- loc,
- Fortran::semantics::GetExpr(
- std::get<Fortran::parser::ScalarLogicalExpr>(stmt->t)),
- stmtCtx);
- stmtCtx.finalizeAndReset();
- mlir::Value cond =
- builder->createConvert(loc, builder->getI1Type(), condExpr);
- if (negate)
- cond = builder->create<mlir::arith::XOrIOp>(
- loc, cond, builder->createIntegerConstant(loc, cond.getType(), 1));
- return cond;
- }
+ mlir::Value genIfCondition(const A *stmt, bool negate = false);
mlir::func::FuncOp getFunc(llvm::StringRef name, mlir::FunctionType ty);
@@ -688,26 +556,14 @@ class FirConverter : public Fortran::lower::AbstractConverter {
bool *isConst = nullptr);
template <typename A>
- void genNestedStatement(const Fortran::parser::Statement<A> &stmt) {
- setCurrentPosition(stmt.source);
- genFIR(stmt.statement);
- }
+ void genNestedStatement(const Fortran::parser::Statement<A> &stmt);
void forceControlVariableBinding(const Fortran::semantics::Symbol *sym,
mlir::Value inducVar);
- template <typename A> void prepareExplicitSpace(const A &forall) {
- if (!explicitIterSpace.isActive())
- analyzeExplicitSpace(forall);
- localSymbols.pushScope();
- explicitIterSpace.enter();
- }
+ template <typename A> void prepareExplicitSpace(const A &forall);
- /// Cleanup all the FORALL context information when we exit.
- void cleanupExplicitSpace() {
- explicitIterSpace.leave();
- localSymbols.popScope();
- }
+ void cleanupExplicitSpace();
void genForallNest(const Fortran::parser::ConcurrentHeader &header);
@@ -717,79 +573,13 @@ class FirConverter : public Fortran::lower::AbstractConverter {
template <typename A>
void genIoConditionBranches(Fortran::lower::pft::Evaluation &eval,
- const A &specList, mlir::Value iostat) {
- if (!iostat)
- return;
-
- Fortran::parser::Label endLabel{};
- Fortran::parser::Label eorLabel{};
- Fortran::parser::Label errLabel{};
- bool hasIostat{};
- for (const auto &spec : specList) {
- std::visit(
- Fortran::common::visitors{
- [&](const Fortran::parser::EndLabel &label) {
- endLabel = label.v;
- },
- [&](const Fortran::parser::EorLabel &label) {
- eorLabel = label.v;
- },
- [&](const Fortran::parser::ErrLabel &label) {
- errLabel = label.v;
- },
- [&](const Fortran::parser::StatVariable &) { hasIostat = true; },
- [](const auto &) {}},
- spec.u);
- }
- if (!endLabel && !eorLabel && !errLabel)
- return;
-
- // An ERR specifier branch is taken on any positive error value rather than
- // some single specific value. If ERR and IOSTAT specifiers are given and
- // END and EOR specifiers are allowed, the latter two specifiers must have
- // explicit branch targets to allow the ERR branch to be implemented as a
- // default/else target. A label=0 target for an absent END or EOR specifier
- // indicates that these specifiers have a fallthrough target. END and EOR
- // specifiers may appear on READ and WAIT statements.
- bool allSpecifiersRequired = errLabel && hasIostat &&
- (eval.isA<Fortran::parser::ReadStmt>() ||
- eval.isA<Fortran::parser::WaitStmt>());
- mlir::Value selector =
- builder->createConvert(toLocation(), builder->getIndexType(), iostat);
- llvm::SmallVector<int64_t> valueList;
- llvm::SmallVector<Fortran::parser::Label> labelList;
- if (eorLabel || allSpecifiersRequired) {
- valueList.push_back(Fortran::runtime::io::IostatEor);
- labelList.push_back(eorLabel ? eorLabel : 0);
- }
- if (endLabel || allSpecifiersRequired) {
- valueList.push_back(Fortran::runtime::io::IostatEnd);
- labelList.push_back(endLabel ? endLabel : 0);
- }
- if (errLabel) {
- // Must be last. Value 0 is interpreted as any positive value, or
- // equivalently as any value other than 0, IostatEor, or IostatEnd.
- valueList.push_back(0);
- labelList.push_back(errLabel);
- }
- genMultiwayBranch(selector, valueList, labelList, eval.nonNopSuccessor());
- }
-
+ const A &specList, mlir::Value iostat);
fir::ExtendedValue
genInitializerExprValue(const Fortran::lower::SomeExpr &expr,
- Fortran::lower::StatementContext &stmtCtx) {
- return Fortran::lower::createSomeInitializerExpression(
- toLocation(), *this, expr, localSymbols, stmtCtx);
- }
+ Fortran::lower::StatementContext &stmtCtx);
- /// Return true if the current context is a conditionalized and implied
- /// iteration space.
- bool implicitIterationSpace() { return !implicitIterSpace.empty(); }
-
- /// Return true if context is currently an explicit iteration space. A scalar
- /// assignment expression may be contextually within a user-defined iteration
- /// space, transforming it into an array expression.
- bool explicitIterationSpace() { return explicitIterSpace.isActive(); }
+ bool implicitIterationSpace();
+ bool explicitIterationSpace();
void genArrayAssignment(
const Fortran::evaluate::Assignment &assign,
@@ -798,11 +588,7 @@ class FirConverter : public Fortran::lower::AbstractConverter {
std::optional<llvm::SmallVector<mlir::Value>> ubounds = std::nullopt);
#if !defined(NDEBUG)
- static bool isFuncResultDesignator(const Fortran::lower::SomeExpr &expr) {
- const Fortran::semantics::Symbol *sym =
- Fortran::evaluate::GetFirstSymbol(expr);
- return sym && sym->IsFuncResult();
- }
+ static bool isFuncResultDesignator(const Fortran::lower::SomeExpr &expr);
#endif
fir::MutableBoxValue
@@ -841,24 +627,10 @@ class FirConverter : public Fortran::lower::AbstractConverter {
void genAssignment(const Fortran::evaluate::Assignment &assign);
- // Is the insertion point of the builder directly or indirectly set
- // inside any operation of type "Op"?
- template <typename... Op> bool isInsideOp() const {
- mlir::Block *block = builder->getInsertionBlock();
- mlir::Operation *op = block ? block->getParentOp() : nullptr;
- while (op) {
- if (mlir::isa<Op...>(op))
- return true;
- op = op->getParentOp();
- }
- return false;
- }
+ template <typename... Op> bool isInsideOp() const;
- bool isInsideHlfirForallOrWhere() const {
- return isInsideOp<hlfir::ForallOp, hlfir::WhereOp>();
- }
-
- bool isInsideHlfirWhere() const { return isInsideOp<hlfir::WhereOp>(); }
+ bool isInsideHlfirForallOrWhere() const;
+ bool isInsideHlfirWhere() const;
void lowerWhereMaskToHlfir(mlir::Location loc,
const Fortran::semantics::SomeExpr *maskExpr);
@@ -876,20 +648,9 @@ class FirConverter : public Fortran::lower::AbstractConverter {
void
createEmptyBlocks(std::list<Fortran::lower::pft::Evaluation> &evaluationList);
- /// Return the predicate: "current block does not have a terminator branch".
- bool blockIsUnterminated() {
- mlir::Block *currentBlock = builder->getBlock();
- return currentBlock->empty() ||
- !currentBlock->back().hasTrait<mlir::OpTrait::IsTerminator>();
- }
-
+ bool blockIsUnterminated();
void startBlock(mlir::Block *newBlock);
-
- /// Conditionally switch code insertion to a new block.
- void maybeStartBlock(mlir::Block *newBlock) {
- if (newBlock)
- startBlock(newBlock);
- }
+ void maybeStartBlock(mlir::Block *newBlock);
void eraseDeadCodeAndBlocks(mlir::RewriterBase &rewriter,
llvm::MutableArrayRef<mlir::Region> regions);
@@ -901,12 +662,8 @@ class FirConverter : public Fortran::lower::AbstractConverter {
void lowerBlockData(Fortran::lower::pft::BlockDataUnit &bdunit);
- /// Create fir::Global for all the common blocks that appear in the program.
void
- lowerCommonBlocks(const Fortran::semantics::CommonBlockList &commonBlocks) {
- createGlobalOutsideOfFunctionLowering(
- [&]() { Fortran::lower::defineCommonBlocks(*this, commonBlocks); });
- }
+ lowerCommonBlocks(const Fortran::semantics::CommonBlockList &commonBlocks);
void createIntrinsicModuleDefinitions(Fortran::lower::pft::Program &pft);
@@ -914,89 +671,56 @@ class FirConverter : public Fortran::lower::AbstractConverter {
void lowerModuleDeclScope(Fortran::lower::pft::ModuleLikeUnit &mod);
void lowerMod(Fortran::lower::pft::ModuleLikeUnit &mod);
- void setCurrentPosition(const Fortran::parser::CharBlock &position) {
- if (position != Fortran::parser::CharBlock{})
- currentPosition = position;
- }
+ void setCurrentPosition(const Fortran::parser::CharBlock &position);
- /// Set current position at the location of \p parseTreeNode. Note that the
- /// position is updated automatically when visiting statements, but not when
- /// entering higher level nodes like constructs or procedures. This helper is
- /// intended to cover the latter cases.
- template <typename A> void setCurrentPositionAt(const A &parseTreeNode) {
- setCurrentPosition(Fortran::parser::FindSourceLocation(parseTreeNode));
- }
+ template <typename A> void setCurrentPositionAt(const A &parseTreeNode);
//===--------------------------------------------------------------------===//
// Utility methods
//===--------------------------------------------------------------------===//
/// Convert a parser CharBlock to a Location
- mlir::Location toLocation(const Fortran::parser::CharBlock &cb) {
- return genLocation(cb);
- }
-
- mlir::Location toLocation() { return toLocation(currentPosition); }
- void setCurrentEval(Fortran::lower::pft::Evaluation &eval) {
- evalPtr = &eval;
- }
+ mlir::Location toLocation(const Fortran::parser::CharBlock &cb);
+ mlir::Location toLocation();
- Fortran::lower::pft::Evaluation &getEval() {
- assert(evalPtr);
- return *evalPtr;
- }
+ void setCurrentEval(Fortran::lower::pft::Evaluation &eval);
+ Fortran::lower::pft::Evaluation &getEval();
std::optional<Fortran::evaluate::Shape>
- getShape(const Fortran::lower::SomeExpr &expr) {
- return Fortran::evaluate::GetShape(foldingContext, expr);
- }
+ getShape(const Fortran::lower::SomeExpr &expr);
//===--------------------------------------------------------------------===//
// Analysis on a nested explicit iteration space.
//===--------------------------------------------------------------------===//
template <bool LHS = false, typename A>
- void analyzeExplicitSpace(const Fortran::evaluate::Expr<A> &e) {
- explicitIterSpace.exprBase(&e, LHS);
- }
-
+ void analyzeExplicitSpace(const Fortran::evaluate::Expr<A> &e);
void analyzeExplicitSpace(const Fortran::evaluate::Assignment *assign);
- void analyzeExplicitSpace(const Fortran::parser::AssignmentStmt &s) {
- analyzeExplicitSpace(s.typedAssignment->v.operator->());
- }
-
+ void analyzeExplicitSpace(const Fortran::parser::AssignmentStmt &s);
void analyzeExplicitSpace(const Fortran::parser::ConcurrentHeader &header);
- void analyzeExplicitSpace(const Fortran::parser::ForallAssignmentStmt &stmt) {
- std::visit([&](const auto &s) { analyzeExplicitSpace(s); }, stmt.u);
- }
-
+ void analyzeExplicitSpace(const Fortran::parser::ForallAssignmentStmt &stmt);
void analyzeExplicitSpace(const Fortran::parser::ForallConstruct &forall);
void analyzeExplicitSpace(const Fortran::parser::ForallConstructStmt &forall);
void analyzeExplicitSpace(const Fortran::parser::ForallStmt &forall);
void analyzeExplicitSpace(const Fortran::parser::MaskedElsewhereStmt &stmt);
- void analyzeExplicitSpace(const Fortran::parser::PointerAssignmentStmt &s) {
- analyzeExplicitSpace(s.typedAssignment->v.operator->());
- }
-
+ void analyzeExplicitSpace(const Fortran::parser::PointerAssignmentStmt &s);
void analyzeExplicitSpace(const Fortran::parser::WhereBodyConstruct &body);
void analyzeExplicitSpace(const Fortran::parser::WhereConstruct &c);
- void analyzeExplicitSpace(
- const Fortran::parser::WhereConstruct::Elsewhere *ew);
+ void
+ analyzeExplicitSpace(const Fortran::parser::WhereConstruct::Elsewhere *ew);
void analyzeExplicitSpace(
const Fortran::parser::WhereConstruct::MaskedElsewhere &ew);
void analyzeExplicitSpace(const Fortran::parser::WhereConstructStmt &ws);
void analyzeExplicitSpace(const Fortran::parser::WhereStmt &stmt);
- void analyzeExplicitSpacePop() { explicitIterSpace.popLevel(); }
+ void analyzeExplicitSpacePop();
void addMaskVariable(Fortran::lower::FrontEndExpr exp);
- void createRuntimeTypeInfoGlobals() {}
+ void createRuntimeTypeInfoGlobals();
- bool lowerToHighLevelFIR() const {
- return bridge.getLoweringOptions().getLowerToHighLevelFIR();
- }
+ bool lowerToHighLevelFIR() const;
std::string getConstantExprManglePrefix(mlir::Location loc,
const Fortran::lower::SomeExpr &expr,
@@ -1059,6 +783,488 @@ class FirConverter : public Fortran::lower::AbstractConverter {
const Fortran::lower::ExprToValueMap *exprValueOverrides{nullptr};
};
+/// End of class definition
+
+inline mlir::Value
+FirConverter::getSymbolAddress(Fortran::lower::SymbolRef sym) {
+ return lookupSymbol(sym).getAddr();
+}
+
+inline void FirConverter::copySymbolBinding(Fortran::lower::SymbolRef src,
+ Fortran::lower::SymbolRef target) {
+ localSymbols.copySymbolBinding(src, target);
+}
+
+inline void FirConverter::bindSymbol(Fortran::lower::SymbolRef sym,
+ const fir::ExtendedValue &exval) {
+ addSymbol(sym, exval, /*forced=*/true);
+}
+
+inline void
+FirConverter::overrideExprValues(const Fortran::lower::ExprToValueMap *map) {
+ exprValueOverrides = map;
+}
+
+inline const Fortran::lower::ExprToValueMap *FirConverter::getExprOverrides() {
+ return exprValueOverrides;
+}
+
+inline Fortran::lower::pft::Evaluation *
+FirConverter::lookupLabel(Fortran::lower::pft::Label label) {
+ Fortran::lower::pft::FunctionLikeUnit &owningProc =
+ *getEval().getOwningProcedure();
+ return owningProc.labelEvaluationMap.lookup(label);
+}
+
+inline Fortran::evaluate::FoldingContext &FirConverter::getFoldingContext() {
+ return foldingContext;
+}
+
+inline mlir::Type FirConverter::genType(const Fortran::lower::SomeExpr &expr) {
+ return Fortran::lower::translateSomeExprToFIRType(*this, expr);
+}
+
+inline mlir::Type
+FirConverter::genType(const Fortran::lower::pft::Variable &var) {
+ return Fortran::lower::translateVariableToFIRType(*this, var);
+}
+
+inline mlir::Type FirConverter::genType(Fortran::lower::SymbolRef sym) {
+ return Fortran::lower::translateSymbolToFIRType(*this, sym);
+}
+
+inline mlir::Type
+FirConverter::genType(Fortran::common::TypeCategory tc, int kind,
+ llvm::ArrayRef<std::int64_t> lenParameters) {
+ return Fortran::lower::getFIRType(&getMLIRContext(), tc, kind, lenParameters);
+}
+
+inline mlir::Type
+FirConverter::genType(const Fortran::semantics::DerivedTypeSpec &tySpec) {
+ return Fortran::lower::translateDerivedTypeToFIRType(*this, tySpec);
+}
+
+inline mlir::Type FirConverter::genType(Fortran::common::TypeCategory tc) {
+ return Fortran::lower::getFIRType(&getMLIRContext(), tc,
+ bridge.getDefaultKinds().GetDefaultKind(tc),
+ std::nullopt);
+}
+
+inline bool
+FirConverter::isPresentShallowLookup(Fortran::semantics::Symbol &sym) {
+ return bool(shallowLookupSymbol(sym));
+}
+
+//===--------------------------------------------------------------------===//
+// Utility methods
+//===--------------------------------------------------------------------===//
+
+inline mlir::Location FirConverter::getCurrentLocation() {
+ return toLocation();
+}
+
+/// Generate a dummy location.
+inline mlir::Location FirConverter::genUnknownLocation() {
+ // Note: builder may not be instantiated yet
+ return mlir::UnknownLoc::get(&getMLIRContext());
+}
+
+inline const Fortran::semantics::Scope &FirConverter::getCurrentScope() {
+ return bridge.getSemanticsContext().FindScope(currentPosition);
+}
+
+inline fir::FirOpBuilder &FirConverter::getFirOpBuilder() { return *builder; }
+
+inline mlir::ModuleOp &FirConverter::getModuleOp() {
+ return bridge.getModule();
+}
+
+inline mlir::MLIRContext &FirConverter::getMLIRContext() {
+ return bridge.getMLIRContext();
+}
+
+inline std::string
+FirConverter::mangleName(const Fortran::semantics::Symbol &symbol) {
+ return Fortran::lower::mangle::mangleName(
+ symbol, scopeBlockIdMap, /*keepExternalInScope=*/false,
+ getLoweringOptions().getUnderscoring());
+}
+
+inline std::string FirConverter::mangleName(
+ const Fortran::semantics::DerivedTypeSpec &derivedType) {
+ return Fortran::lower::mangle::mangleName(derivedType, scopeBlockIdMap);
+}
+
+inline std::string FirConverter::mangleName(std::string &name) {
+ return Fortran::lower::mangle::mangleName(name, getCurrentScope(),
+ scopeBlockIdMap);
+}
+
+inline std::string FirConverter::getRecordTypeFieldName(
+ const Fortran::semantics::Symbol &component) {
+ return Fortran::lower::mangle::getRecordTypeFieldName(component,
+ scopeBlockIdMap);
+}
+inline const fir::KindMapping &FirConverter::getKindMap() {
+ return bridge.getKindMap();
+}
+
+inline mlir::Value FirConverter::hostAssocTupleValue() {
+ return hostAssocTuple;
+}
+
+/// Record a binding for the ssa-value of the tuple for this function.
+inline void FirConverter::bindHostAssocTuple(mlir::Value val) {
+ assert(!hostAssocTuple && val);
+ hostAssocTuple = val;
+}
+
+inline void FirConverter::registerTypeInfo(
+ mlir::Location loc, Fortran::lower::SymbolRef typeInfoSym,
+ const Fortran::semantics::DerivedTypeSpec &typeSpec, fir::RecordType type) {
+ typeInfoConverter.registerTypeInfo(*this, loc, typeInfoSym, typeSpec, type);
+}
+
+inline mlir::Value
+FirConverter::createFIRExpr(mlir::Location loc,
+ const Fortran::lower::SomeExpr *expr,
+ Fortran::lower::StatementContext &stmtCtx) {
+ return fir::getBase(genExprValue(*expr, stmtCtx, &loc));
+}
+
+/// Find the symbol in the inner-most level of the local map or return null.
+inline Fortran::lower::SymbolBox
+FirConverter::shallowLookupSymbol(const Fortran::semantics::Symbol &sym) {
+ if (Fortran::lower::SymbolBox v = localSymbols.shallowLookupSymbol(sym))
+ return v;
+ return {};
+}
+
+/// Find the symbol in one level up of symbol map such as for host-association
+/// in OpenMP code or return null.
+inline Fortran::lower::SymbolBox
+FirConverter::lookupOneLevelUpSymbol(const Fortran::semantics::Symbol &sym) {
+ if (Fortran::lower::SymbolBox v = localSymbols.lookupOneLevelUpSymbol(sym))
+ return v;
+ return {};
+}
+
+inline bool
+FirConverter::isNumericScalarCategory(Fortran::common::TypeCategory cat) {
+ return cat == Fortran::common::TypeCategory::Integer ||
+ cat == Fortran::common::TypeCategory::Real ||
+ cat == Fortran::common::TypeCategory::Complex ||
+ cat == Fortran::common::TypeCategory::Logical;
+}
+
+inline bool FirConverter::isLogicalCategory(Fortran::common::TypeCategory cat) {
+ return cat == Fortran::common::TypeCategory::Logical;
+}
+
+inline bool
+FirConverter::isCharacterCategory(Fortran::common::TypeCategory cat) {
+ return cat == Fortran::common::TypeCategory::Character;
+}
+
+inline bool FirConverter::isDerivedCategory(Fortran::common::TypeCategory cat) {
+ return cat == Fortran::common::TypeCategory::Derived;
+}
+
+inline void FirConverter::genBranch(mlir::Block *targetBlock) {
+ assert(targetBlock && "missing unconditional target block");
+ builder->create<mlir::cf::BranchOp>(toLocation(), targetBlock);
+}
+
+inline void FirConverter::genConditionalBranch(
+ mlir::Value cond, Fortran::lower::pft::Evaluation *trueTarget,
+ Fortran::lower::pft::Evaluation *falseTarget) {
+ genConditionalBranch(cond, trueTarget->block, falseTarget->block);
+}
+
+inline void
+FirConverter::pushActiveConstruct(Fortran::lower::pft::Evaluation &eval,
+ Fortran::lower::StatementContext &stmtCtx) {
+ activeConstructStack.push_back(ConstructContext{eval, stmtCtx});
+ eval.activeConstruct = true;
+}
+
+inline void FirConverter::popActiveConstruct() {
+ assert(!activeConstructStack.empty() && "invalid active construct stack");
+ activeConstructStack.back().eval.activeConstruct = false;
+ activeConstructStack.pop_back();
+}
+
+//===--------------------------------------------------------------------===//
+// Termination of symbolically referenced execution units
+//===--------------------------------------------------------------------===//
+
+/// END of program
+///
+/// Generate the cleanup block before the program exits
+inline void FirConverter::genExitRoutine() {
+ if (blockIsUnterminated())
+ builder->create<mlir::func::ReturnOp>(toLocation());
+}
+
+/// END of procedure-like constructs
+///
+/// Get the return value of a call to \p symbol, which is a subroutine entry
+/// point that has alternative return specifiers.
+inline const mlir::Value
+FirConverter::getAltReturnResult(const Fortran::semantics::Symbol &symbol) {
+ assert(Fortran::semantics::HasAlternateReturns(symbol) &&
+ "subroutine does not have alternate returns");
+ return getSymbolAddress(symbol);
+}
+
+//
+// Statements that have control-flow semantics
+//
+
+/// Generate an If[Then]Stmt condition or its negation.
+template <typename A>
+inline mlir::Value FirConverter::genIfCondition(const A *stmt, bool negate) {
+ mlir::Location loc = toLocation();
+ Fortran::lower::StatementContext stmtCtx;
+ mlir::Value condExpr =
+ createFIRExpr(loc,
+ Fortran::semantics::GetExpr(
+ std::get<Fortran::parser::ScalarLogicalExpr>(stmt->t)),
+ stmtCtx);
+ stmtCtx.finalizeAndReset();
+ mlir::Value cond =
+ builder->createConvert(loc, builder->getI1Type(), condExpr);
+ if (negate)
+ cond = builder->create<mlir::arith::XOrIOp>(
+ loc, cond, builder->createIntegerConstant(loc, cond.getType(), 1));
+ return cond;
+}
+
+template <typename A>
+inline void
+FirConverter::genNestedStatement(const Fortran::parser::Statement<A> &stmt) {
+ setCurrentPosition(stmt.source);
+ genFIR(stmt.statement);
+}
+
+template <typename A>
+inline void FirConverter::prepareExplicitSpace(const A &forall) {
+ if (!explicitIterSpace.isActive())
+ analyzeExplicitSpace(forall);
+ localSymbols.pushScope();
+ explicitIterSpace.enter();
+}
+
+/// Cleanup all the FORALL context information when we exit.
+inline void FirConverter::cleanupExplicitSpace() {
+ explicitIterSpace.leave();
+ localSymbols.popScope();
+}
+
+template <typename A>
+inline void
+FirConverter::genIoConditionBranches(Fortran::lower::pft::Evaluation &eval,
+ const A &specList, mlir::Value iostat) {
+ if (!iostat)
+ return;
+
+ Fortran::parser::Label endLabel{};
+ Fortran::parser::Label eorLabel{};
+ Fortran::parser::Label errLabel{};
+ bool hasIostat{};
+ for (const auto &spec : specList) {
+ std::visit(
+ Fortran::common::visitors{
+ [&](const Fortran::parser::EndLabel &label) { endLabel = label.v; },
+ [&](const Fortran::parser::EorLabel &label) { eorLabel = label.v; },
+ [&](const Fortran::parser::ErrLabel &label) { errLabel = label.v; },
+ [&](const Fortran::parser::StatVariable &) { hasIostat = true; },
+ [](const auto &) {}},
+ spec.u);
+ }
+ if (!endLabel && !eorLabel && !errLabel)
+ return;
+
+ // An ERR specifier branch is taken on any positive error value rather than
+ // some single specific value. If ERR and IOSTAT specifiers are given and
+ // END and EOR specifiers are allowed, the latter two specifiers must have
+ // explicit branch targets to allow the ERR branch to be implemented as a
+ // default/else target. A label=0 target for an absent END or EOR specifier
+ // indicates that these specifiers have a fallthrough target. END and EOR
+ // specifiers may appear on READ and WAIT statements.
+ bool allSpecifiersRequired = errLabel && hasIostat &&
+ (eval.isA<Fortran::parser::ReadStmt>() ||
+ eval.isA<Fortran::parser::WaitStmt>());
+ mlir::Value selector =
+ builder->createConvert(toLocation(), builder->getIndexType(), iostat);
+ llvm::SmallVector<int64_t> valueList;
+ llvm::SmallVector<Fortran::parser::Label> labelList;
+ if (eorLabel || allSpecifiersRequired) {
+ valueList.push_back(Fortran::runtime::io::IostatEor);
+ labelList.push_back(eorLabel ? eorLabel : 0);
+ }
+ if (endLabel || allSpecifiersRequired) {
+ valueList.push_back(Fortran::runtime::io::IostatEnd);
+ labelList.push_back(endLabel ? endLabel : 0);
+ }
+ if (errLabel) {
+ // Must be last. Value 0 is interpreted as any positive value, or
+ // equivalently as any value other than 0, IostatEor, or IostatEnd.
+ valueList.push_back(0);
+ labelList.push_back(errLabel);
+ }
+ genMultiwayBranch(selector, valueList, labelList, eval.nonNopSuccessor());
+}
+
+inline fir::ExtendedValue FirConverter::genInitializerExprValue(
+ const Fortran::lower::SomeExpr &expr,
+ Fortran::lower::StatementContext &stmtCtx) {
+ return Fortran::lower::createSomeInitializerExpression(
+ toLocation(), *this, expr, localSymbols, stmtCtx);
+}
+
+/// Return true if the current context is a conditionalized and implied
+/// iteration space.
+inline bool FirConverter::implicitIterationSpace() {
+ return !implicitIterSpace.empty();
+}
+
+/// Return true if context is currently an explicit iteration space. A scalar
+/// assignment expression may be contextually within a user-defined iteration
+/// space, transforming it into an array expression.
+inline bool FirConverter::explicitIterationSpace() {
+ return explicitIterSpace.isActive();
+}
+
+#if !defined(NDEBUG)
+inline bool
+FirConverter::isFuncResultDesignator(const Fortran::lower::SomeExpr &expr) {
+ const Fortran::semantics::Symbol *sym =
+ Fortran::evaluate::GetFirstSymbol(expr);
+ return sym && sym->IsFuncResult();
+}
+#endif
+
+// Is the insertion point of the builder directly or indirectly set
+// inside any operation of type "Op"?
+template <typename... Op> bool FirConverter::isInsideOp() const {
+ mlir::Block *block = builder->getInsertionBlock();
+ mlir::Operation *op = block ? block->getParentOp() : nullptr;
+ while (op) {
+ if (mlir::isa<Op...>(op))
+ return true;
+ op = op->getParentOp();
+ }
+ return false;
+}
+
+inline bool FirConverter::isInsideHlfirForallOrWhere() const {
+ return isInsideOp<hlfir::ForallOp, hlfir::WhereOp>();
+}
+
+inline bool FirConverter::isInsideHlfirWhere() const {
+ return isInsideOp<hlfir::WhereOp>();
+}
+
+/// Return the predicate: "current block does not have a terminator branch".
+inline bool FirConverter::blockIsUnterminated() {
+ mlir::Block *currentBlock = builder->getBlock();
+ return currentBlock->empty() ||
+ !currentBlock->back().hasTrait<mlir::OpTrait::IsTerminator>();
+}
+
+/// Conditionally switch code insertion to a new block.
+inline void FirConverter::maybeStartBlock(mlir::Block *newBlock) {
+ if (newBlock)
+ startBlock(newBlock);
+}
+
+/// Create fir::Global for all the common blocks that appear in the program.
+inline void FirConverter::lowerCommonBlocks(
+ const Fortran::semantics::CommonBlockList &commonBlocks) {
+ createGlobalOutsideOfFunctionLowering(
+ [&]() { Fortran::lower::defineCommonBlocks(*this, commonBlocks); });
+}
+
+inline void
+FirConverter::setCurrentPosition(const Fortran::parser::CharBlock &position) {
+ if (position != Fortran::parser::CharBlock{})
+ currentPosition = position;
+}
+
+/// Set current position at the location of \p parseTreeNode. Note that the
+/// position is updated automatically when visiting statements, but not when
+/// entering higher level nodes like constructs or procedures. This helper is
+/// intended to cover the latter cases.
+template <typename A>
+inline void FirConverter::setCurrentPositionAt(const A &parseTreeNode) {
+ setCurrentPosition(Fortran::parser::FindSourceLocation(parseTreeNode));
+}
+
+//===--------------------------------------------------------------------===//
+// Utility methods
+//===--------------------------------------------------------------------===//
+
+/// Convert a parser CharBlock to a Location
+inline mlir::Location
+FirConverter::toLocation(const Fortran::parser::CharBlock &cb) {
+ return genLocation(cb);
+}
+
+inline mlir::Location FirConverter::toLocation() {
+ return toLocation(currentPosition);
+}
+
+inline void
+FirConverter::setCurrentEval(Fortran::lower::pft::Evaluation &eval) {
+ evalPtr = &eval;
+}
+
+inline Fortran::lower::pft::Evaluation &FirConverter::getEval() {
+ assert(evalPtr);
+ return *evalPtr;
+}
+
+std::optional<Fortran::evaluate::Shape> inline FirConverter::getShape(
+ const Fortran::lower::SomeExpr &expr) {
+ return Fortran::evaluate::GetShape(foldingContext, expr);
+}
+
+//===--------------------------------------------------------------------===//
+// Analysis on a nested explicit iteration space.
+//===--------------------------------------------------------------------===//
+
+template <bool LHS, typename A>
+inline void
+FirConverter::analyzeExplicitSpace(const Fortran::evaluate::Expr<A> &e) {
+ explicitIterSpace.exprBase(&e, LHS);
+}
+
+inline void
+FirConverter::analyzeExplicitSpace(const Fortran::parser::AssignmentStmt &s) {
+ analyzeExplicitSpace(s.typedAssignment->v.operator->());
+}
+
+inline void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::ForallAssignmentStmt &stmt) {
+ std::visit([&](const auto &s) { analyzeExplicitSpace(s); }, stmt.u);
+}
+
+inline void FirConverter::analyzeExplicitSpace(
+ const Fortran::parser::PointerAssignmentStmt &s) {
+ analyzeExplicitSpace(s.typedAssignment->v.operator->());
+}
+
+inline void FirConverter::analyzeExplicitSpacePop() {
+ explicitIterSpace.popLevel();
+}
+
+inline void FirConverter::createRuntimeTypeInfoGlobals() {}
+
+inline bool FirConverter::lowerToHighLevelFIR() const {
+ return bridge.getLoweringOptions().getLowerToHighLevelFIR();
+}
+
} // namespace Fortran::lower
#endif // FORTRAN_LOWER_FIRCONVERTER_H
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