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[flang] add option to generate runtime type info as external (#145901)

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So far flang generates runtime derived type info global definitions (as
opposed to declarations) for all the types used in the current
compilation unit even when the derived types are defined in other
compilation units. It is using linkonce_odr to achieve derived type
descriptor address "uniqueness" aspect needed to match two derived type
inside the runtime.

This comes at a big compile time cost because of all the extra globals
and their definitions in apps with many and complex derived types.

This patch adds and experimental option to only generate the rtti
definition for the types defined in the current compilation unit and to
only generate external declaration for the derived type descriptor
object of types defined elsewhere.

Note that objects compiled with this option are not compatible with
object files compiled without because files compiled without it may drop
the rtti for type they defined if it is not used in the compilation unit
because of the linkonce_odr aspect.

I am adding the option so that we can better measure the extra cost of
the current approach on apps and allow speeding up some compilation
where devirtualization does not matter (and the build config links to
all module file object anyway).
This commit is contained in:
jeanPerier
2025-06-27 13:00:29 +02:00
committed by GitHub
parent f0f46e25ec
commit e816817bbb
15 changed files with 256 additions and 153 deletions
Download Patch File Download Diff File Expand all files Collapse all files

1
flang/include/flang/Evaluate/tools.h
View File

@@ -1585,6 +1585,7 @@ bool IsExtensibleType(const DerivedTypeSpec *);
bool IsSequenceOrBindCType(const DerivedTypeSpec *);
bool IsBuiltinDerivedType(const DerivedTypeSpec *derived, const char *name);
bool IsBuiltinCPtr(const Symbol &);
bool IsFromBuiltinModule(const Symbol &);
bool IsEventType(const DerivedTypeSpec *);
bool IsLockType(const DerivedTypeSpec *);
bool IsNotifyType(const DerivedTypeSpec *);

3
flang/include/flang/Optimizer/CodeGen/CodeGen.h
View File

@@ -39,6 +39,9 @@ struct FIRToLLVMPassOptions {
// that such programs would crash at runtime if the derived type descriptors
// are required by the runtime, so this is only an option to help debugging.
bool ignoreMissingTypeDescriptors = false;
// Similar to ignoreMissingTypeDescriptors, but generate external declaration
// for the missing type descriptor globals instead.
bool skipExternalRttiDefinition = false;
// Generate TBAA information for FIR types and memory accessing operations.
bool applyTBAA = false;

13
flang/include/flang/Optimizer/Passes/CommandLineOpts.h
View File

@@ -32,6 +32,19 @@ extern llvm::cl::opt<std::size_t> arrayStackAllocationThreshold;
/// generated by the frontend.
extern llvm::cl::opt<bool> ignoreMissingTypeDescriptors;
/// Shared option in tools to only generate rtti static object definitions for
/// derived types defined in the current compilation unit. Derived type
/// descriptor object for types defined in other objects will only be declared
/// as external. This also changes the linkage of rtti objects defined in the
/// current compilation unit from linkonce_odr to external so that unused rtti
/// objects are retained and can be accessed from other compilation units. This
/// is an experimental option to explore compilation speed improvements and is
/// an ABI breaking change because of the linkage change.
/// It will also require linking against module file objects of modules defining
/// only types (even for trivial types without type bound procedures, which
/// differs from most compilers).
extern llvm::cl::opt<bool> skipExternalRttiDefinition;
/// Default optimization level used to create Flang pass pipeline is O0.
extern llvm::OptimizationLevel defaultOptLevel;

26
flang/include/flang/Optimizer/Support/Utils.h
View File

@@ -35,32 +35,6 @@ inline std::int64_t toInt(mlir::arith::ConstantOp cop) {
.getSExtValue();
}
// Reconstruct binding tables for dynamic dispatch.
using BindingTable = llvm::DenseMap<llvm::StringRef, unsigned>;
using BindingTables = llvm::DenseMap<llvm::StringRef, BindingTable>;
inline void buildBindingTables(BindingTables &bindingTables,
mlir::ModuleOp mod) {
// The binding tables are defined in FIR after lowering inside fir.type_info
// operations. Go through each binding tables and store the procedure name and
// binding index for later use by the fir.dispatch conversion pattern.
for (auto typeInfo : mod.getOps<fir::TypeInfoOp>()) {
unsigned bindingIdx = 0;
BindingTable bindings;
if (typeInfo.getDispatchTable().empty()) {
bindingTables[typeInfo.getSymName()] = bindings;
continue;
}
for (auto dtEntry :
typeInfo.getDispatchTable().front().getOps<fir::DTEntryOp>()) {
bindings[dtEntry.getMethod()] = bindingIdx;
++bindingIdx;
}
bindingTables[typeInfo.getSymName()] = bindings;
}
}
// Translate front-end KINDs for use in the IR and code gen.
inline std::vector<fir::KindTy>
fromDefaultKinds(const Fortran::common::IntrinsicTypeDefaultKinds &defKinds) {

4
flang/include/flang/Semantics/runtime-type-info.h
View File

@@ -38,6 +38,10 @@ RuntimeDerivedTypeTables BuildRuntimeDerivedTypeTables(SemanticsContext &);
/// to describe other derived types at runtime in flang descriptor.
constexpr char typeInfoBuiltinModule[]{"__fortran_type_info"};
/// Name of the builtin derived type in __fortran_type_inf that is used for
/// derived type descriptors.
constexpr char typeDescriptorTypeName[]{"derivedtype"};
/// Name of the bindings descriptor component in the DerivedType type of the
/// __Fortran_type_info module
constexpr char bindingDescCompName[]{"binding"};

5
flang/lib/Evaluate/tools.cpp
View File

@@ -2334,6 +2334,11 @@ bool IsBuiltinCPtr(const Symbol &symbol) {
return false;
}
bool IsFromBuiltinModule(const Symbol &symbol) {
const Scope &scope{symbol.GetUltimate().owner()};
return IsSameModule(&scope, scope.context().GetBuiltinsScope());
}
bool IsIsoCType(const DerivedTypeSpec *derived) {
return IsBuiltinDerivedType(derived, "c_ptr") ||
IsBuiltinDerivedType(derived, "c_funptr");

16
flang/lib/Lower/Bridge.cpp
View File

@@ -52,6 +52,7 @@
#include "flang/Optimizer/Dialect/FIROps.h"
#include "flang/Optimizer/Dialect/Support/FIRContext.h"
#include "flang/Optimizer/HLFIR/HLFIROps.h"
#include "flang/Optimizer/Passes/CommandLineOpts.h"
#include "flang/Optimizer/Support/DataLayout.h"
#include "flang/Optimizer/Support/FatalError.h"
#include "flang/Optimizer/Support/InternalNames.h"
@@ -262,6 +263,7 @@ public:
}
void createTypeInfo(Fortran::lower::AbstractConverter &converter) {
createTypeInfoForTypeDescriptorBuiltinType(converter);
while (!registeredTypeInfoA.empty()) {
currentTypeInfoStack = &registeredTypeInfoB;
for (const TypeInfo &info : registeredTypeInfoA)
@@ -277,10 +279,22 @@ public:
private:
void createTypeInfoOpAndGlobal(Fortran::lower::AbstractConverter &converter,
const TypeInfo &info) {
Fortran::lower::createRuntimeTypeInfoGlobal(converter, info.symbol.get());
if (!::skipExternalRttiDefinition)
Fortran::lower::createRuntimeTypeInfoGlobal(converter, info.symbol.get());
createTypeInfoOp(converter, info);
}
void createTypeInfoForTypeDescriptorBuiltinType(
Fortran::lower::AbstractConverter &converter) {
if (registeredTypeInfoA.empty())
return;
auto builtinTypeInfoType = llvm::cast<fir::RecordType>(
converter.genType(registeredTypeInfoA[0].symbol.get()));
converter.getFirOpBuilder().createTypeInfoOp(
registeredTypeInfoA[0].loc, builtinTypeInfoType,
/*parentType=*/fir::RecordType{});
}
void createTypeInfoOp(Fortran::lower::AbstractConverter &converter,
const TypeInfo &info) {
fir::RecordType parentType{};

10
flang/lib/Lower/ConvertVariable.cpp
View File

@@ -38,6 +38,7 @@
#include "flang/Optimizer/Dialect/FIROps.h"
#include "flang/Optimizer/Dialect/Support/FIRContext.h"
#include "flang/Optimizer/HLFIR/HLFIROps.h"
#include "flang/Optimizer/Passes/CommandLineOpts.h"
#include "flang/Optimizer/Support/FatalError.h"
#include "flang/Optimizer/Support/InternalNames.h"
#include "flang/Optimizer/Support/Utils.h"
@@ -652,8 +653,13 @@ getLinkageAttribute(fir::FirOpBuilder &builder,
// Runtime type info for a same derived type is identical in each compilation
// unit. It desired to avoid having to link against module that only define a
// type. Therefore the runtime type info is generated everywhere it is needed
// with `linkonce_odr` LLVM linkage.
if (var.isRuntimeTypeInfoData())
// with `linkonce_odr` LLVM linkage (unless the skipExternalRttiDefinition
// option is set, in which case one will need to link against objects of
// modules defining types). Builtin objects rtti is always generated because
// the builtin module is currently not compiled or part of the runtime.
if (var.isRuntimeTypeInfoData() &&
(!::skipExternalRttiDefinition ||
Fortran::semantics::IsFromBuiltinModule(var.getSymbol())))
return builder.createLinkOnceODRLinkage();
if (var.isModuleOrSubmoduleVariable())
return {}; // external linkage

102
flang/lib/Optimizer/CodeGen/CodeGen.cpp
View File

@@ -1294,6 +1294,51 @@ genCUFAllocDescriptor(mlir::Location loc,
.getResult();
}
/// Get the address of the type descriptor global variable that was created by
/// lowering for derived type \p recType.
template <typename ModOpTy>
static mlir::Value
getTypeDescriptor(ModOpTy mod, mlir::ConversionPatternRewriter &rewriter,
mlir::Location loc, fir::RecordType recType,
const fir::FIRToLLVMPassOptions &options) {
std::string name =
options.typeDescriptorsRenamedForAssembly
? fir::NameUniquer::getTypeDescriptorAssemblyName(recType.getName())
: fir::NameUniquer::getTypeDescriptorName(recType.getName());
mlir::Type llvmPtrTy = ::getLlvmPtrType(mod.getContext());
if (auto global = mod.template lookupSymbol<fir::GlobalOp>(name))
return rewriter.create<mlir::LLVM::AddressOfOp>(loc, llvmPtrTy,
global.getSymName());
// The global may have already been translated to LLVM.
if (auto global = mod.template lookupSymbol<mlir::LLVM::GlobalOp>(name))
return rewriter.create<mlir::LLVM::AddressOfOp>(loc, llvmPtrTy,
global.getSymName());
// Type info derived types do not have type descriptors since they are the
// types defining type descriptors.
if (options.ignoreMissingTypeDescriptors ||
fir::NameUniquer::belongsToModule(
name, Fortran::semantics::typeInfoBuiltinModule))
return rewriter.create<mlir::LLVM::ZeroOp>(loc, llvmPtrTy);
if (!options.skipExternalRttiDefinition)
fir::emitFatalError(loc,
"runtime derived type info descriptor was not "
"generated and skipExternalRttiDefinition and "
"ignoreMissingTypeDescriptors options are not set");
// Rtti for a derived type defined in another compilation unit and for which
// rtti was not defined in lowering because of the skipExternalRttiDefinition
// option. Generate the object declaration now.
auto insertPt = rewriter.saveInsertionPoint();
rewriter.setInsertionPoint(mod.getBody(), mod.getBody()->end());
mlir::LLVM::GlobalOp global = rewriter.create<mlir::LLVM::GlobalOp>(
loc, llvmPtrTy, /*constant=*/true, mlir::LLVM::Linkage::External, name,
mlir::Attribute());
rewriter.restoreInsertionPoint(insertPt);
return rewriter.create<mlir::LLVM::AddressOfOp>(loc, llvmPtrTy,
global.getSymName());
}
/// Common base class for embox to descriptor conversion.
template <typename OP>
struct EmboxCommonConversion : public fir::FIROpConversion<OP> {
@@ -1406,36 +1451,6 @@ struct EmboxCommonConversion : public fir::FIROpConversion<OP> {
stride);
}
/// Get the address of the type descriptor global variable that was created by
/// lowering for derived type \p recType.
template <typename ModOpTy>
mlir::Value
getTypeDescriptor(ModOpTy mod, mlir::ConversionPatternRewriter &rewriter,
mlir::Location loc, fir::RecordType recType) const {
std::string name =
this->options.typeDescriptorsRenamedForAssembly
? fir::NameUniquer::getTypeDescriptorAssemblyName(recType.getName())
: fir::NameUniquer::getTypeDescriptorName(recType.getName());
mlir::Type llvmPtrTy = ::getLlvmPtrType(mod.getContext());
if (auto global = mod.template lookupSymbol<fir::GlobalOp>(name)) {
return rewriter.create<mlir::LLVM::AddressOfOp>(loc, llvmPtrTy,
global.getSymName());
}
if (auto global = mod.template lookupSymbol<mlir::LLVM::GlobalOp>(name)) {
// The global may have already been translated to LLVM.
return rewriter.create<mlir::LLVM::AddressOfOp>(loc, llvmPtrTy,
global.getSymName());
}
// Type info derived types do not have type descriptors since they are the
// types defining type descriptors.
if (!this->options.ignoreMissingTypeDescriptors &&
!fir::NameUniquer::belongsToModule(
name, Fortran::semantics::typeInfoBuiltinModule))
fir::emitFatalError(
loc, "runtime derived type info descriptor was not generated");
return rewriter.create<mlir::LLVM::ZeroOp>(loc, llvmPtrTy);
}
template <typename ModOpTy>
mlir::Value populateDescriptor(mlir::Location loc, ModOpTy mod,
fir::BaseBoxType boxTy, mlir::Type inputType,
@@ -1500,7 +1515,8 @@ struct EmboxCommonConversion : public fir::FIROpConversion<OP> {
mlir::Type innerType = fir::unwrapInnerType(inputType);
if (innerType && mlir::isa<fir::RecordType>(innerType)) {
auto recTy = mlir::dyn_cast<fir::RecordType>(innerType);
typeDesc = getTypeDescriptor(mod, rewriter, loc, recTy);
typeDesc =
getTypeDescriptor(mod, rewriter, loc, recTy, this->options);
} else {
// Unlimited polymorphic type descriptor with no record type. Set
// type descriptor address to a clean state.
@@ -1508,8 +1524,8 @@ struct EmboxCommonConversion : public fir::FIROpConversion<OP> {
loc, ::getLlvmPtrType(mod.getContext()));
}
} else {
typeDesc = getTypeDescriptor(mod, rewriter, loc,
fir::unwrapIfDerived(boxTy));
typeDesc = getTypeDescriptor(
mod, rewriter, loc, fir::unwrapIfDerived(boxTy), this->options);
}
}
if (typeDesc)
@@ -3021,22 +3037,10 @@ struct TypeDescOpConversion : public fir::FIROpConversion<fir::TypeDescOp> {
assert(mlir::isa<fir::RecordType>(inTy) && "expecting fir.type");
auto recordType = mlir::dyn_cast<fir::RecordType>(inTy);
auto module = typeDescOp.getOperation()->getParentOfType<mlir::ModuleOp>();
std::string typeDescName =
this->options.typeDescriptorsRenamedForAssembly
? fir::NameUniquer::getTypeDescriptorAssemblyName(
recordType.getName())
: fir::NameUniquer::getTypeDescriptorName(recordType.getName());
auto llvmPtrTy = ::getLlvmPtrType(typeDescOp.getContext());
if (auto global = module.lookupSymbol<mlir::LLVM::GlobalOp>(typeDescName)) {
rewriter.replaceOpWithNewOp<mlir::LLVM::AddressOfOp>(
typeDescOp, llvmPtrTy, global.getSymName());
return mlir::success();
} else if (auto global = module.lookupSymbol<fir::GlobalOp>(typeDescName)) {
rewriter.replaceOpWithNewOp<mlir::LLVM::AddressOfOp>(
typeDescOp, llvmPtrTy, global.getSymName());
return mlir::success();
}
return mlir::failure();
mlir::Value typeDesc = getTypeDescriptor(
module, rewriter, typeDescOp.getLoc(), recordType, this->options);
rewriter.replaceOp(typeDescOp, typeDesc);
return mlir::success();
}
};

6
flang/lib/Optimizer/Passes/CommandLineOpts.cpp
View File

@@ -39,6 +39,12 @@ cl::opt<bool> ignoreMissingTypeDescriptors(
"translating FIR to LLVM"),
cl::init(false), cl::Hidden);
cl::opt<bool> skipExternalRttiDefinition(
"skip-external-rtti-definition", llvm::cl::init(false),
llvm::cl::desc("do not define rtti static objects for types belonging to "
"other compilation units"),
cl::Hidden);
OptimizationLevel defaultOptLevel{OptimizationLevel::O0};
codegenoptions::DebugInfoKind noDebugInfo{codegenoptions::NoDebugInfo};

1
flang/lib/Optimizer/Passes/Pipelines.cpp
View File

@@ -108,6 +108,7 @@ void addFIRToLLVMPass(mlir::PassManager &pm,
const MLIRToLLVMPassPipelineConfig &config) {
fir::FIRToLLVMPassOptions options;
options.ignoreMissingTypeDescriptors = ignoreMissingTypeDescriptors;
options.skipExternalRttiDefinition = skipExternalRttiDefinition;
options.applyTBAA = config.AliasAnalysis;
options.forceUnifiedTBAATree = useOldAliasTags;
options.typeDescriptorsRenamedForAssembly =

95
flang/lib/Optimizer/Transforms/PolymorphicOpConversion.cpp
View File

@@ -16,7 +16,6 @@
#include "flang/Optimizer/Dialect/Support/KindMapping.h"
#include "flang/Optimizer/Support/InternalNames.h"
#include "flang/Optimizer/Support/TypeCode.h"
#include "flang/Optimizer/Support/Utils.h"
#include "flang/Optimizer/Transforms/Passes.h"
#include "flang/Runtime/derived-api.h"
#include "flang/Semantics/runtime-type-info.h"
@@ -38,6 +37,45 @@ namespace fir {
using namespace fir;
using namespace mlir;
// Reconstruct binding tables for dynamic dispatch.
using BindingTable = llvm::DenseMap<llvm::StringRef, unsigned>;
using BindingTables = llvm::DenseMap<llvm::StringRef, BindingTable>;
static std::string getTypeDescriptorTypeName() {
llvm::SmallVector<llvm::StringRef, 1> modules = {
Fortran::semantics::typeInfoBuiltinModule};
return fir::NameUniquer::doType(modules, /*proc=*/{}, /*blockId=*/0,
Fortran::semantics::typeDescriptorTypeName,
/*kinds=*/{});
}
static std::optional<mlir::Type>
buildBindingTables(BindingTables &bindingTables, mlir::ModuleOp mod) {
std::optional<mlir::Type> typeDescriptorType;
std::string typeDescriptorTypeName = getTypeDescriptorTypeName();
// The binding tables are defined in FIR after lowering inside fir.type_info
// operations. Go through each binding tables and store the procedure name and
// binding index for later use by the fir.dispatch conversion pattern.
for (auto typeInfo : mod.getOps<fir::TypeInfoOp>()) {
if (!typeDescriptorType && typeInfo.getSymName() == typeDescriptorTypeName)
typeDescriptorType = typeInfo.getType();
unsigned bindingIdx = 0;
BindingTable bindings;
if (typeInfo.getDispatchTable().empty()) {
bindingTables[typeInfo.getSymName()] = bindings;
continue;
}
for (auto dtEntry :
typeInfo.getDispatchTable().front().getOps<fir::DTEntryOp>()) {
bindings[dtEntry.getMethod()] = bindingIdx;
++bindingIdx;
}
bindingTables[typeInfo.getSymName()] = bindings;
}
return typeDescriptorType;
}
namespace {
/// SelectTypeOp converted to an if-then-else chain
@@ -77,9 +115,10 @@ private:
struct DispatchOpConv : public OpConversionPattern<fir::DispatchOp> {
using OpConversionPattern<fir::DispatchOp>::OpConversionPattern;
DispatchOpConv(mlir::MLIRContext *ctx, const BindingTables &bindingTables)
DispatchOpConv(mlir::MLIRContext *ctx, const BindingTables &bindingTables,
std::optional<mlir::Type> typeDescriptorType)
: mlir::OpConversionPattern<fir::DispatchOp>(ctx),
bindingTables(bindingTables) {}
bindingTables(bindingTables), typeDescriptorType{typeDescriptorType} {}
llvm::LogicalResult
matchAndRewrite(fir::DispatchOp dispatch, OpAdaptor adaptor,
@@ -111,13 +150,11 @@ struct DispatchOpConv : public OpConversionPattern<fir::DispatchOp> {
mlir::Value passedObject = dispatch.getObject();
auto module = dispatch.getOperation()->getParentOfType<mlir::ModuleOp>();
Type typeDescTy;
std::string typeDescName =
NameUniquer::getTypeDescriptorName(recordType.getName());
if (auto global = module.lookupSymbol<fir::GlobalOp>(typeDescName)) {
typeDescTy = global.getType();
}
if (!typeDescriptorType)
return emitError(loc) << "cannot find " << getTypeDescriptorTypeName()
<< " fir.type_info that is required to get the "
"related builtin type and lower fir.dispatch";
mlir::Type typeDescTy = *typeDescriptorType;
// clang-format off
// Before:
@@ -213,6 +250,7 @@ struct DispatchOpConv : public OpConversionPattern<fir::DispatchOp> {
private:
BindingTables bindingTables;
std::optional<mlir::Type> typeDescriptorType;
};
/// Convert FIR structured control flow ops to CFG ops.
@@ -229,10 +267,11 @@ public:
mlir::RewritePatternSet patterns(context);
BindingTables bindingTables;
buildBindingTables(bindingTables, mod);
std::optional<mlir::Type> typeDescriptorType =
buildBindingTables(bindingTables, mod);
patterns.insert<SelectTypeConv>(context);
patterns.insert<DispatchOpConv>(context, bindingTables);
patterns.insert<DispatchOpConv>(context, bindingTables, typeDescriptorType);
mlir::ConversionTarget target(*context);
target.addLegalDialect<mlir::affine::AffineDialect,
mlir::cf::ControlFlowDialect, FIROpsDialect,
@@ -379,16 +418,11 @@ llvm::LogicalResult SelectTypeConv::genTypeLadderStep(
} else if (auto a = mlir::dyn_cast<fir::SubclassAttr>(attr)) {
// Retrieve the type descriptor from the type guard statement record type.
assert(mlir::isa<fir::RecordType>(a.getType()) && "expect fir.record type");
fir::RecordType recTy = mlir::dyn_cast<fir::RecordType>(a.getType());
std::string typeDescName =
fir::NameUniquer::getTypeDescriptorName(recTy.getName());
auto typeDescGlobal = mod.lookupSymbol<fir::GlobalOp>(typeDescName);
auto typeDescAddr = rewriter.create<fir::AddrOfOp>(
loc, fir::ReferenceType::get(typeDescGlobal.getType()),
typeDescGlobal.getSymbol());
mlir::Type typeDescTy = ReferenceType::get(rewriter.getNoneType());
mlir::Value typeDescAddr =
rewriter.create<fir::TypeDescOp>(loc, mlir::TypeAttr::get(a.getType()));
mlir::Type refNoneType = ReferenceType::get(rewriter.getNoneType());
mlir::Value typeDesc =
rewriter.create<ConvertOp>(loc, typeDescTy, typeDescAddr);
rewriter.create<ConvertOp>(loc, refNoneType, typeDescAddr);
// Prepare the selector descriptor for the runtime call.
mlir::Type descNoneTy = fir::BoxType::get(rewriter.getNoneType());
@@ -406,7 +440,7 @@ llvm::LogicalResult SelectTypeConv::genTypeLadderStep(
mlir::UnitAttr::get(rewriter.getContext()));
callee =
fir::createFuncOp(rewriter.getUnknownLoc(), mod, fctName,
rewriter.getFunctionType({descNoneTy, typeDescTy},
rewriter.getFunctionType({descNoneTy, refNoneType},
rewriter.getI1Type()),
{runtimeAttr});
}
@@ -435,20 +469,11 @@ SelectTypeConv::genTypeDescCompare(mlir::Location loc, mlir::Value selector,
mlir::Type ty, mlir::ModuleOp mod,
mlir::PatternRewriter &rewriter) const {
assert(mlir::isa<fir::RecordType>(ty) && "expect fir.record type");
fir::RecordType recTy = mlir::dyn_cast<fir::RecordType>(ty);
std::string typeDescName =
fir::NameUniquer::getTypeDescriptorName(recTy.getName());
auto typeDescGlobal = mod.lookupSymbol<fir::GlobalOp>(typeDescName);
if (!typeDescGlobal)
return {};
auto typeDescAddr = rewriter.create<fir::AddrOfOp>(
loc, fir::ReferenceType::get(typeDescGlobal.getType()),
typeDescGlobal.getSymbol());
mlir::Value typeDescAddr =
rewriter.create<fir::TypeDescOp>(loc, mlir::TypeAttr::get(ty));
mlir::Value selectorTdescAddr = rewriter.create<fir::BoxTypeDescOp>(
loc, typeDescAddr.getType(), selector);
auto intPtrTy = rewriter.getIndexType();
mlir::Type tdescType =
fir::TypeDescType::get(mlir::NoneType::get(rewriter.getContext()));
mlir::Value selectorTdescAddr =
rewriter.create<fir::BoxTypeDescOp>(loc, tdescType, selector);
auto typeDescInt =
rewriter.create<fir::ConvertOp>(loc, intPtrTy, typeDescAddr);
auto selectorTdescInt =

47
flang/test/Integration/skip-external-rtti-definition.F90 Normal file
View File

@@ -0,0 +1,47 @@
! Test -skip-external-rtti-definition option
!RUN: rm -rf %t && mkdir -p %t
!RUN: %flang_fc1 -fsyntax-only -DSTEP=1 -J%t %s
!RUN: %flang_fc1 -emit-llvm -J%t %s -o - | FileCheck %s -check-prefix=LINKONCE
!RUN: %flang_fc1 -emit-llvm -J%t -mllvm -skip-external-rtti-definition %s -o - | FileCheck %s -check-prefix=EXTERNAL
#if STEP == 1
module module_external_type_definition
type t1
end type
end module
#else
module module_same_unit_type_definition
type t2
end type
end module
subroutine test
use module_external_type_definition
use module_same_unit_type_definition
interface
subroutine needs_descriptor(x)
class(*) :: x
end subroutine
end interface
type(t1) :: x1
type(t2) :: x2
call needs_descriptor(x1)
call needs_descriptor(x2)
end subroutine
#endif
! LINKONCE-DAG: @_QMmodule_external_type_definitionEXnXt1 = linkonce_odr constant [2 x i8] c"t1", comdat
! LINKONCE-DAG: @_QMmodule_external_type_definitionEXdtXt1 = linkonce_odr constant {{.*}} {
! LINKONCE-DAG: @_QMmodule_same_unit_type_definitionEXnXt2 = linkonce_odr constant [2 x i8] c"t2", comdat
! LINKONCE-DAG: @_QMmodule_same_unit_type_definitionEXdtXt2 = linkonce_odr constant {{.*}} {
! EXTERNAL-NOT: @_QMmodule_external_type_definitionEXnXt1
! EXTERNAL: @_QMmodule_same_unit_type_definitionEXnXt2 = constant [2 x i8] c"t2"
! EXTERNAL-NOT: @_QMmodule_external_type_definitionEXnXt1
! EXTERNAL: @_QMmodule_same_unit_type_definitionEXdtXt2 = constant {{.*}} {
! EXTERNAL-NOT: @_QMmodule_external_type_definitionEXnXt1
! EXTERNAL: @_QMmodule_external_type_definitionEXdtXt1 = external constant ptr
! EXTERNAL-NOT: @_QMmodule_external_type_definitionEXnXt1

8
flang/test/Lower/select-type-2.f90
View File

@@ -30,8 +30,8 @@ contains
! CHECK-LABEL: func.func @_QMselect_type_2Pselect_type1(
! CHECK-SAME: %[[ARG0:.*]]: !fir.class<!fir.type<_QMselect_type_2Tp1{a:i32,b:i32}>> {fir.bindc_name = "a"}) {
! CHECK: %[[TDESC_P3_ADDR:.*]] = fir.address_of(@_QMselect_type_2E.dt.p3) : !fir.ref<!fir.type<{{.*}}>>
! CHECK: %[[TDESC_P3_CONV:.*]] = fir.convert %[[TDESC_P3_ADDR]] : (!fir.ref<!fir.type<{{.*}}>>) -> !fir.ref<none>
! CHECK: %[[TDESC_P3_ADDR:.*]] = fir.type_desc !fir.type<_QMselect_type_2Tp3
! CHECK: %[[TDESC_P3_CONV:.*]] = fir.convert %[[TDESC_P3_ADDR]] : (!fir.tdesc{{.*}}>) -> !fir.ref<none>
! CHECK: %[[BOX_NONE:.*]] = fir.convert %[[ARG0]] : (!fir.class<!fir.type<_QMselect_type_2Tp1{a:i32,b:i32}>>) -> !fir.box<none>
! CHECK: %[[CLASS_IS_CMP:.*]] = fir.call @_FortranAClassIs(%[[BOX_NONE]], %[[TDESC_P3_CONV]]) : (!fir.box<none>, !fir.ref<none>) -> i1
! CHECK: cf.cond_br %[[CLASS_IS_CMP]], ^[[CLASS_IS_P3_BLK:.*]], ^[[NOT_CLASS_IS_P3_BLK:.*]]
@@ -40,8 +40,8 @@ contains
! CHECK: ^bb[[CLASS_IS_P1:[0-9]]]:
! CHECK: cf.br ^bb[[END_SELECT_BLK:[0-9]]]
! CHECK: ^[[NOT_CLASS_IS_P3_BLK]]:
! CHECK: %[[TDESC_P1_ADDR:.*]] = fir.address_of(@_QMselect_type_2E.dt.p1) : !fir.ref<!fir.type<{{.*}}>>
! CHECK: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.ref<!fir.type<{{.*}}>>) -> !fir.ref<none>
! CHECK: %[[TDESC_P1_ADDR:.*]] = fir.type_desc !fir.type<_QMselect_type_2Tp1
! CHECK: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.tdesc{{.*}}>) -> !fir.ref<none>
! CHECK: %[[BOX_NONE:.*]] = fir.convert %[[ARG0]] : (!fir.class<!fir.type<_QMselect_type_2Tp1{a:i32,b:i32}>>) -> !fir.box<none>
! CHECK: %[[CLASS_IS_CMP:.*]] = fir.call @_FortranAClassIs(%[[BOX_NONE]], %[[TDESC_P1_CONV]]) : (!fir.box<none>, !fir.ref<none>) -> i1
! CHECK: cf.cond_br %[[CLASS_IS_CMP]], ^bb[[CLASS_IS_P1]], ^bb[[NOT_CLASS_IS_P1]]

72
flang/test/Lower/select-type.f90
View File

@@ -68,15 +68,15 @@ contains
! CFG-LABEL: func.func @_QMselect_type_lower_testPselect_type1(
! CFG-SAME: %[[ARG0:.*]]: !fir.class<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>> {fir.bindc_name = "a"}) {
! CFG: %[[TDESC_P1_ADDR:.*]] = fir.address_of(@_QMselect_type_lower_testE.dt.p1) : !fir.ref<!fir.type<{{.*}}>>
! CFG: %[[BOX_TDESC:.*]] = fir.box_tdesc %[[ARG0]] : (!fir.class<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>) -> !fir.tdesc<none>
! CFG: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.ref<!fir.type<{{.*}}>>) -> index
! CFG: %[[BOX_TDESC_CONV:.*]] = fir.convert %[[BOX_TDESC]] : (!fir.tdesc<none>) -> index
! CFG: %[[TDESC_P1_ADDR:.*]] = fir.type_desc !fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>
! CFG: %[[BOX_TDESC:.*]] = fir.box_tdesc %[[ARG0]] : (!fir.class<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>) -> !fir.tdesc<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>
! CFG: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.tdesc<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>) -> index
! CFG: %[[BOX_TDESC_CONV:.*]] = fir.convert %[[BOX_TDESC]] : (!fir.tdesc<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>) -> index
! CFG: %[[TDESC_CMP:.*]] = arith.cmpi eq, %[[TDESC_P1_CONV]], %[[BOX_TDESC_CONV]] : index
! CFG: cf.cond_br %[[TDESC_CMP]], ^[[TYPE_IS_P1_BLK:.*]], ^[[NOT_TYPE_IS_P1_BLK:.*]]
! CFG: ^[[NOT_TYPE_IS_P1_BLK]]:
! CFG: %[[TDESC_P2_ADDR:.*]] = fir.address_of(@_QMselect_type_lower_testE.dt.p2) : !fir.ref<!fir.type<{{.*}}>>
! CFG: %[[TDESC_P2_CONV:.*]] = fir.convert %[[TDESC_P2_ADDR]] : (!fir.ref<!fir.type<{{.*}}>>) -> !fir.ref<none>
! CFG: %[[TDESC_P2_ADDR:.*]] = fir.type_desc !fir.type<_QMselect_type_lower_testTp2{{.*}}
! CFG: %[[TDESC_P2_CONV:.*]] = fir.convert %[[TDESC_P2_ADDR]] : (!fir.tdesc<{{.*}}>) -> !fir.ref<none>
! CFG: %[[BOX_NONE:.*]] = fir.convert %[[ARG0]] : (!fir.class<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>) -> !fir.box<none>
! CFG: %[[CLASS_IS:.*]] = fir.call @_FortranAClassIs(%[[BOX_NONE]], %[[TDESC_P2_CONV]]) : (!fir.box<none>, !fir.ref<none>) -> i1
! CFG: cf.cond_br %[[CLASS_IS]], ^bb[[CLASS_IS_P2_BLK:.*]], ^[[NOT_CLASS_IS_P2_BLK:.*]]
@@ -87,8 +87,8 @@ contains
! CFG: ^bb[[CLASS_IS_P1_BLK:[0-9]]]:
! CFG: cf.br ^[[END_SELECT_BLK:.*]]
! CFG: ^[[NOT_CLASS_IS_P2_BLK]]:
! CFG: %[[TDESC_P1_ADDR:.*]] = fir.address_of(@_QMselect_type_lower_testE.dt.p1) : !fir.ref<!fir.type<{{.*}}>>
! CFG: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.ref<!fir.type<{{.*}}>>) -> !fir.ref<none>
! CFG: %[[TDESC_P1_ADDR:.*]] = fir.type_desc !fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>
! CFG: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.tdesc<{{.*}}>) -> !fir.ref<none>
! CFG: %[[BOX_NONE:.*]] = fir.convert %[[ARG0]] : (!fir.class<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>) -> !fir.box<none>
! CFG: %[[CLASS_IS:.*]] = fir.call @_FortranAClassIs(%[[BOX_NONE]], %[[TDESC_P1_CONV]]) : (!fir.box<none>, !fir.ref<none>) -> i1
! CFG: cf.cond_br %[[CLASS_IS]], ^bb[[CLASS_IS_P1_BLK]], ^bb[[NOT_CLASS_IS_P1_BLK]]
@@ -126,15 +126,15 @@ contains
! CFG: %[[GET_CLASS:.*]] = fir.call @_QMselect_type_lower_testPget_class() {{.*}} : () -> !fir.class<!fir.ptr<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>>
! CFG: fir.save_result %[[GET_CLASS]] to %[[CLASS_ALLOCA]] : !fir.class<!fir.ptr<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>>, !fir.ref<!fir.class<!fir.ptr<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>>>
! CFG: %[[LOAD_CLASS:.*]] = fir.load %[[CLASS_ALLOCA]] : !fir.ref<!fir.class<!fir.ptr<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>>>
! CFG: %[[TDESC_P1_ADDR:.*]] = fir.address_of(@_QMselect_type_lower_testE.dt.p1) : !fir.ref<!fir.type<{{.*}}>>
! CFG: %[[CLASS_TDESC:.*]] = fir.box_tdesc %[[LOAD_CLASS]] : (!fir.class<!fir.ptr<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>>) -> !fir.tdesc<none>
! CFG: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.ref<!fir.type<{{.*}}>>) -> index
! CFG: %[[BOX_TDESC_CONV:.*]] = fir.convert %[[CLASS_TDESC]] : (!fir.tdesc<none>) -> index
! CFG: %[[TDESC_P1_ADDR:.*]] = fir.type_desc !fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>
! CFG: %[[CLASS_TDESC:.*]] = fir.box_tdesc %[[LOAD_CLASS]] : (!fir.class<!fir.ptr<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>>) -> !fir.tdesc<{{.*}}>
! CFG: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.tdesc{{.*}}>) -> index
! CFG: %[[BOX_TDESC_CONV:.*]] = fir.convert %[[CLASS_TDESC]] : (!fir.tdesc<{{.*}}>) -> index
! CFG: %[[TDESC_CMP:.*]] = arith.cmpi eq, %[[TDESC_P1_CONV]], %[[BOX_TDESC_CONV]] : index
! CFG: cf.cond_br %[[TDESC_CMP]], ^[[TYPE_IS_P1_BLK:.*]], ^[[NOT_TYPE_IS_P1_BLK:.*]]
! CFG: ^[[NOT_TYPE_IS_P1_BLK]]:
! CFG: %[[TDESC_P1_ADDR:.*]] = fir.address_of(@_QMselect_type_lower_testE.dt.p1) : !fir.ref<!fir.type<{{.*}}>>
! CFG: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.ref<!fir.type<{{.*}}>>) -> !fir.ref<none>
! CFG: %[[TDESC_P1_ADDR:.*]] = fir.type_desc !fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>
! CFG: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.tdesc{{.*}}>) -> !fir.ref<none>
! CFG: %[[BOX_NONE:.*]] = fir.convert %[[LOAD_CLASS]] : (!fir.class<!fir.ptr<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>>) -> !fir.box<none>
! CFG: %[[CLASS_IS:.*]] = fir.call @_FortranAClassIs(%[[BOX_NONE]], %[[TDESC_P1_CONV]]) : (!fir.box<none>, !fir.ref<none>) -> i1
! CFG: cf.cond_br %[[CLASS_IS]], ^[[CLASS_IS_BLK:.*]], ^[[NOT_CLASS_IS_BLK:.*]]
@@ -176,15 +176,15 @@ contains
! CFG-LABEL: func.func @_QMselect_type_lower_testPselect_type3(
! CFG-SAME: %[[ARG0:.*]]: !fir.ref<!fir.class<!fir.ptr<!fir.array<?x!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>>>> {fir.bindc_name = "a"}) {
! CFG: %[[SELECTOR:.*]] = fir.embox %{{.*}} source_box %{{.*}} : (!fir.ref<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>, !fir.class<{{.*}}>) -> !fir.class<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>
! CFG: %[[TDESC_P1_ADDR:.*]] = fir.address_of(@_QMselect_type_lower_testE.dt.p1) : !fir.ref<!fir.type<{{.*}}>>
! CFG: %[[SELECTOR_TDESC:.*]] = fir.box_tdesc %[[SELECTOR]] : (!fir.class<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>) -> !fir.tdesc<none>
! CFG: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.ref<!fir.type<{{.*}}>>) -> index
! CFG: %[[TDESC_CONV:.*]] = fir.convert %[[SELECTOR_TDESC]] : (!fir.tdesc<none>) -> index
! CFG: %[[TDESC_P1_ADDR:.*]] = fir.type_desc !fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>
! CFG: %[[SELECTOR_TDESC:.*]] = fir.box_tdesc %[[SELECTOR]] : (!fir.class<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>) -> !fir.tdesc<{{.*}}>
! CFG: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.tdesc{{.*}}>) -> index
! CFG: %[[TDESC_CONV:.*]] = fir.convert %[[SELECTOR_TDESC]] : (!fir.tdesc<{{.*}}>) -> index
! CFG: %[[TDESC_CMP:.*]] = arith.cmpi eq, %[[TDESC_P1_CONV]], %[[TDESC_CONV]] : index
! CFG: cf.cond_br %[[TDESC_CMP]], ^[[TYPE_IS_P1_BLK:.*]], ^[[NOT_TYPE_IS_P1_BLK:.*]]
! CFG: ^[[NOT_TYPE_IS_P1_BLK]]:
! CFG: %[[TDESC_P1_ADDR:.*]] = fir.address_of(@_QMselect_type_lower_testE.dt.p1) : !fir.ref<!fir.type<{{.*}}>>
! CFG: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.ref<!fir.type<{{.*}}>>) -> !fir.ref<none>
! CFG: %[[TDESC_P1_ADDR:.*]] = fir.type_desc !fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>
! CFG: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.tdesc{{.*}}>) -> !fir.ref<none>
! CFG: %[[BOX_NONE:.*]] = fir.convert %[[SELECTOR]] : (!fir.class<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>) -> !fir.box<none>
! CFG: %[[CLASS_IS:.*]] = fir.call @_FortranAClassIs(%[[BOX_NONE]], %[[TDESC_P1_CONV]]) : (!fir.box<none>, !fir.ref<none>) -> i1
! CFG: cf.cond_br %[[CLASS_IS]], ^[[CLASS_IS_BLK:.*]], ^[[NOT_CLASS_IS:.*]]
@@ -222,25 +222,25 @@ contains
! CFG-LABEL: func.func @_QMselect_type_lower_testPselect_type4(
! CFG-SAME: %[[ARG0:.*]]: !fir.class<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>> {fir.bindc_name = "a"}) {
! CFG: %[[TDESC_P3_8_ADDR:.*]] = fir.address_of(@_QMselect_type_lower_testE.dt.p3.8) : !fir.ref<!fir.type<{{.*}}>>
! CFG: %[[BOX_TDESC:.*]] = fir.box_tdesc %[[ARG0]] : (!fir.class<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>) -> !fir.tdesc<none>
! CFG: %[[TDESC_P3_8_CONV:.*]] = fir.convert %[[TDESC_P3_8_ADDR]] : (!fir.ref<!fir.type<{{.*}}>>) -> index
! CFG: %[[BOX_TDESC_CONV:.*]] = fir.convert %[[BOX_TDESC]] : (!fir.tdesc<none>) -> index
! CFG: %[[TDESC_P3_8_ADDR:.*]] = fir.type_desc !fir.type<_QMselect_type_lower_testTp3K8
! CFG: %[[BOX_TDESC:.*]] = fir.box_tdesc %[[ARG0]] : (!fir.class<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>) -> !fir.tdesc<{{.*}}>
! CFG: %[[TDESC_P3_8_CONV:.*]] = fir.convert %[[TDESC_P3_8_ADDR]] : (!fir.tdesc{{.*}}>) -> index
! CFG: %[[BOX_TDESC_CONV:.*]] = fir.convert %[[BOX_TDESC]] : (!fir.tdesc<{{.*}}>) -> index
! CFG: %[[TDESC_CMP:.*]] = arith.cmpi eq, %[[TDESC_P3_8_CONV]], %[[BOX_TDESC_CONV]] : index
! CFG: cf.cond_br %[[TDESC_CMP]], ^[[P3_8_BLK:.*]], ^[[NOT_P3_8_BLK:.*]]
! CFG: ^[[NOT_P3_8_BLK]]:
! CFG: %[[TDESC_P3_4_ADDR:.*]] = fir.address_of(@_QMselect_type_lower_testE.dt.p3.4) : !fir.ref<!fir.type<{{.*}}>>
! CFG: %[[BOX_TDESC:.*]] = fir.box_tdesc %[[ARG0]] : (!fir.class<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>) -> !fir.tdesc<none>
! CFG: %[[TDESC_P3_4_CONV:.*]] = fir.convert %[[TDESC_P3_4_ADDR]] : (!fir.ref<!fir.type<{{.*}}>>) -> index
! CFG: %[[BOX_TDESC_CONV:.*]] = fir.convert %[[BOX_TDESC]] : (!fir.tdesc<none>) -> index
! CFG: %[[TDESC_P3_4_ADDR:.*]] = fir.type_desc !fir.type<_QMselect_type_lower_testTp3K4
! CFG: %[[BOX_TDESC:.*]] = fir.box_tdesc %[[ARG0]] : (!fir.class<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>) -> !fir.tdesc<{{.*}}>
! CFG: %[[TDESC_P3_4_CONV:.*]] = fir.convert %[[TDESC_P3_4_ADDR]] : (!fir.tdesc{{.*}}>) -> index
! CFG: %[[BOX_TDESC_CONV:.*]] = fir.convert %[[BOX_TDESC]] : (!fir.tdesc<{{.*}}>) -> index
! CFG: %[[TDESC_CMP:.*]] = arith.cmpi eq, %[[TDESC_P3_4_CONV]], %[[BOX_TDESC_CONV]] : index
! CFG: cf.cond_br %[[TDESC_CMP]], ^[[P3_4_BLK:.*]], ^[[NOT_P3_4_BLK:.*]]
! CFG: ^[[P3_8_BLK]]:
! CFG: _FortranAioOutputAscii
! CFG: cf.br ^bb[[EXIT_SELECT_BLK:[0-9]]]
! CFG: ^[[NOT_P3_4_BLK]]:
! CFG: %[[TDESC_P1_ADDR:.*]] = fir.address_of(@_QMselect_type_lower_testE.dt.p1) : !fir.ref<!fir.type<{{.*}}>>
! CFG: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.ref<!fir.type<{{.*}}>>) -> !fir.ref<none>
! CFG: %[[TDESC_P1_ADDR:.*]] = fir.type_desc !fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>
! CFG: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.tdesc{{.*}}>) -> !fir.ref<none>
! CFG: %[[BOX_NONE:.*]] = fir.convert %[[ARG0]] : (!fir.class<!fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>>) -> !fir.box<none>
! CFG: %[[CLASS_IS:.*]] = fir.call @_FortranAClassIs(%[[BOX_NONE]], %[[TDESC_P1_CONV]]) : (!fir.box<none>, !fir.ref<none>) -> i1
! CFG: cf.cond_br %[[CLASS_IS]], ^[[P1_BLK:.*]], ^[[NOT_P1_BLK:.*]]
@@ -409,8 +409,8 @@ contains
! CFG-LABEL: func.func @_QMselect_type_lower_testPselect_type7(
! CFG-SAME: %[[ARG0:.*]]: !fir.class<none> {fir.bindc_name = "a"}) {
! CFG: %[[TDESC_P4_ADDR:.*]] = fir.address_of(@_QMselect_type_lower_testE.dt.p4) : !fir.ref<!fir.type<{{.*}}>>
! CFG: %[[TDESC_P4_CONV:.*]] = fir.convert %[[TDESC_P4_ADDR]] : (!fir.ref<!fir.type<{{.*}}>>) -> !fir.ref<none>
! CFG: %[[TDESC_P4_ADDR:.*]] = fir.type_desc !fir.type<_QMselect_type_lower_testTp4
! CFG: %[[TDESC_P4_CONV:.*]] = fir.convert %[[TDESC_P4_ADDR]] : (!fir.tdesc{{.*}}>) -> !fir.ref<none>
! CFG: %[[BOX_NONE:.*]] = fir.convert %[[ARG0]] : (!fir.class<none>) -> !fir.box<none>
! CFG: %[[CLASS_IS_P4:.*]] = fir.call @_FortranAClassIs(%[[BOX_NONE]], %[[TDESC_P4_CONV]]) : (!fir.box<none>, !fir.ref<none>) -> i1
! CFG: cf.cond_br %[[CLASS_IS_P4]], ^[[CLASS_IS_P4_BLK:.*]], ^[[CLASS_NOT_P4_BLK:.*]]
@@ -419,16 +419,16 @@ contains
! CFG: ^bb[[CLASS_IS_P1_BLK:[0-9]]]:
! CFG: cf.br ^[[EXIT_SELECT_BLK:.*]]
! CFG: ^bb[[CLASS_NOT_P2_BLK:[0-9]]]:
! CFG: %[[TDESC_P1_ADDR:.*]] = fir.address_of(@_QMselect_type_lower_testE.dt.p1) : !fir.ref<!fir.type<{{.*}}>>
! CFG: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.ref<!fir.type<{{.*}}>>) -> !fir.ref<none>
! CFG: %[[TDESC_P1_ADDR:.*]] = fir.type_desc !fir.type<_QMselect_type_lower_testTp1{a:i32,b:i32}>
! CFG: %[[TDESC_P1_CONV:.*]] = fir.convert %[[TDESC_P1_ADDR]] : (!fir.tdesc{{.*}}>) -> !fir.ref<none>
! CFG: %[[BOX_NONE:.*]] = fir.convert %[[ARG0]] : (!fir.class<none>) -> !fir.box<none>
! CFG: %[[CLASS_IS_P1:.*]] = fir.call @_FortranAClassIs(%[[BOX_NONE]], %[[TDESC_P1_CONV]]) : (!fir.box<none>, !fir.ref<none>) -> i1
! CFG: cf.cond_br %[[CLASS_IS_P1]], ^bb[[CLASS_IS_P1_BLK]], ^bb[[CLASS_NOT_P1_BLK]]
! CFG: ^bb[[CLASS_IS_P2_BLK:[0-9]]]:
! CFG: cf.br ^[[EXIT_SELECT_BLK]]
! CFG: ^[[CLASS_NOT_P4_BLK]]:
! CFG: %[[TDESC_P2_ADDR:.*]] = fir.address_of(@_QMselect_type_lower_testE.dt.p2) : !fir.ref<!fir.type<{{.*}}>>
! CFG: %[[TDESC_P2_CONV:.*]] = fir.convert %[[TDESC_P2_ADDR]] : (!fir.ref<!fir.type<{{.*}}>>) -> !fir.ref<none>
! CFG: %[[TDESC_P2_ADDR:.*]] = fir.type_desc !fir.type<_QMselect_type_lower_testTp2
! CFG: %[[TDESC_P2_CONV:.*]] = fir.convert %[[TDESC_P2_ADDR]] : (!fir.tdesc{{.*}}>) -> !fir.ref<none>
! CFG: %[[BOX_NONE:.*]] = fir.convert %[[ARG0]] : (!fir.class<none>) -> !fir.box<none>
! CFG: %[[CLASS_IS_P2:.*]] = fir.call @_FortranAClassIs(%[[BOX_NONE]], %[[TDESC_P2_CONV]]) : (!fir.box<none>, !fir.ref<none>) -> i1
! CFG: cf.cond_br %[[CLASS_IS_P2]], ^bb[[CLASS_IS_P2_BLK]], ^bb[[CLASS_NOT_P2_BLK]]