std::string getFullyQualifiedName(QualType QT,
const ASTContext &Ctx) {
PrintingPolicy Policy(Ctx.getPrintingPolicy());
Policy.SuppressScope = false;
Policy.AnonymousTagLocations = false;
Policy.PolishForDeclaration = true;
Policy.SuppressUnwrittenScope = true;
QualType FQQT = getFullyQualifiedType(QT, Ctx);
return FQQT.getAsString(Policy);
}
void ClangInternalState::printAST(llvm::raw_ostream& Out, ASTContext& C) {
TranslationUnitDecl* TU = C.getTranslationUnitDecl();
unsigned Indentation = 0;
bool PrintInstantiation = false;
std::string ErrMsg;
clang::PrintingPolicy policy = C.getPrintingPolicy();
TU->print(Out, policy, Indentation, PrintInstantiation);
// TODO: For future when we relpace the bump allocation with slab.
//
//Out << "Allocated memory: " << C.getAllocatedMemory();
//Out << "Side table allocated memory: " << C.getSideTableAllocatedMemory();
Out.flush();
}
PrintingPolicy Sema::getPrintingPolicy(const ASTContext &Context,
const Preprocessor &PP) {
PrintingPolicy Policy = Context.getPrintingPolicy();
Policy.Bool = Context.getLangOpts().Bool;
if (!Policy.Bool) {
if (MacroInfo *BoolMacro = PP.getMacroInfo(&Context.Idents.get("bool"))) {
Policy.Bool = BoolMacro->isObjectLike() &&
BoolMacro->getNumTokens() == 1 &&
BoolMacro->getReplacementToken(0).is(tok::kw__Bool);
}
}
return Policy;
}
SourceRange StackAddrEscapeChecker::genName(raw_ostream &os, const MemRegion *R,
ASTContext &Ctx) {
// Get the base region, stripping away fields and elements.
R = R->getBaseRegion();
SourceManager &SM = Ctx.getSourceManager();
SourceRange range;
os << "Address of ";
// Check if the region is a compound literal.
if (const CompoundLiteralRegion* CR = dyn_cast<CompoundLiteralRegion>(R)) {
const CompoundLiteralExpr *CL = CR->getLiteralExpr();
os << "stack memory associated with a compound literal "
"declared on line "
<< SM.getExpansionLineNumber(CL->getLocStart())
<< " returned to caller";
range = CL->getSourceRange();
}
else if (const AllocaRegion* AR = dyn_cast<AllocaRegion>(R)) {
const Expr *ARE = AR->getExpr();
SourceLocation L = ARE->getLocStart();
range = ARE->getSourceRange();
os << "stack memory allocated by call to alloca() on line "
<< SM.getExpansionLineNumber(L);
}
else if (const BlockDataRegion *BR = dyn_cast<BlockDataRegion>(R)) {
const BlockDecl *BD = BR->getCodeRegion()->getDecl();
SourceLocation L = BD->getLocStart();
range = BD->getSourceRange();
os << "stack-allocated block declared on line "
<< SM.getExpansionLineNumber(L);
}
else if (const VarRegion *VR = dyn_cast<VarRegion>(R)) {
os << "stack memory associated with local variable '"
<< VR->getString() << '\'';
range = VR->getDecl()->getSourceRange();
}
else if (const CXXTempObjectRegion *TOR = dyn_cast<CXXTempObjectRegion>(R)) {
QualType Ty = TOR->getValueType().getLocalUnqualifiedType();
os << "stack memory associated with temporary object of type '";
Ty.print(os, Ctx.getPrintingPolicy());
os << "'";
range = TOR->getExpr()->getSourceRange();
}
else {
llvm_unreachable("Invalid region in ReturnStackAddressChecker.");
}
return range;
}
void
TraverseTUnitConsumer::InvestigateASTContextTypes( ASTContext& context )
{
// const SmallVectorImpl<Type *>&
auto& types = context.getTypes();
TypePrinter printer(context.getPrintingPolicy(), /* indentation */ 2);
const char *placeholder = ""; // "hey"
for(const Type *type : types) {
llvm::errs() << " - ";
printer.print(type, Qualifiers(), llvm::errs(), placeholder);
llvm::errs() << "\n";
}
(terrs().magenta() << "InvestigateASTContextTypes(): END.\n").reset();
}
/// \brief Convert the given type to a string suitable for printing as part of
/// a diagnostic.
///
/// There are four main criteria when determining whether we should have an
/// a.k.a. clause when pretty-printing a type:
///
/// 1) Some types provide very minimal sugar that doesn't impede the
/// user's understanding --- for example, elaborated type
/// specifiers. If this is all the sugar we see, we don't want an
/// a.k.a. clause.
/// 2) Some types are technically sugared but are much more familiar
/// when seen in their sugared form --- for example, va_list,
/// vector types, and the magic Objective C types. We don't
/// want to desugar these, even if we do produce an a.k.a. clause.
/// 3) Some types may have already been desugared previously in this diagnostic.
/// if this is the case, doing another "aka" would just be clutter.
/// 4) Two different types within the same diagnostic have the same output
/// string. In this case, force an a.k.a with the desugared type when
/// doing so will provide additional information.
///
/// \param Context the context in which the type was allocated
/// \param Ty the type to print
/// \param QualTypeVals pointer values to QualTypes which are used in the
/// diagnostic message
static std::string
ConvertTypeToDiagnosticString(ASTContext &Context, QualType Ty,
const DiagnosticsEngine::ArgumentValue *PrevArgs,
unsigned NumPrevArgs,
ArrayRef<intptr_t> QualTypeVals) {
// FIXME: Playing with std::string is really slow.
bool ForceAKA = false;
QualType CanTy = Ty.getCanonicalType();
std::string S = Ty.getAsString(Context.getPrintingPolicy());
std::string CanS = CanTy.getAsString(Context.getPrintingPolicy());
for (unsigned I = 0, E = QualTypeVals.size(); I != E; ++I) {
QualType CompareTy =
QualType::getFromOpaquePtr(reinterpret_cast<void*>(QualTypeVals[I]));
if (CompareTy.isNull())
continue;
if (CompareTy == Ty)
continue; // Same types
QualType CompareCanTy = CompareTy.getCanonicalType();
if (CompareCanTy == CanTy)
continue; // Same canonical types
std::string CompareS = CompareTy.getAsString(Context.getPrintingPolicy());
bool aka;
QualType CompareDesugar = Desugar(Context, CompareTy, aka);
std::string CompareDesugarStr =
CompareDesugar.getAsString(Context.getPrintingPolicy());
if (CompareS != S && CompareDesugarStr != S)
continue; // The type string is different than the comparison string
// and the desugared comparison string.
std::string CompareCanS =
CompareCanTy.getAsString(Context.getPrintingPolicy());
if (CompareCanS == CanS)
continue; // No new info from canonical type
ForceAKA = true;
break;
}
// Check to see if we already desugared this type in this
// diagnostic. If so, don't do it again.
bool Repeated = false;
for (unsigned i = 0; i != NumPrevArgs; ++i) {
// TODO: Handle ak_declcontext case.
if (PrevArgs[i].first == DiagnosticsEngine::ak_qualtype) {
void *Ptr = (void*)PrevArgs[i].second;
QualType PrevTy(QualType::getFromOpaquePtr(Ptr));
if (PrevTy == Ty) {
Repeated = true;
break;
}
}
}
// Consider producing an a.k.a. clause if removing all the direct
// sugar gives us something "significantly different".
if (!Repeated) {
bool ShouldAKA = false;
QualType DesugaredTy = Desugar(Context, Ty, ShouldAKA);
if (ShouldAKA || ForceAKA) {
if (DesugaredTy == Ty) {
DesugaredTy = Ty.getCanonicalType();
}
std::string akaStr = DesugaredTy.getAsString(Context.getPrintingPolicy());
if (akaStr != S) {
S = "'" + S + "' (aka '" + akaStr + "')";
return S;
}
}
}
S = "'" + S + "'";
return S;
}
void APValue::printPretty(raw_ostream &Out, ASTContext &Ctx, QualType Ty) const{
switch (getKind()) {
case APValue::Uninitialized:
Out << "<uninitialized>";
return;
case APValue::Int:
if (Ty->isBooleanType())
Out << (getInt().getBoolValue() ? "true" : "false");
else
Out << getInt();
return;
case APValue::Float:
Out << GetApproxValue(getFloat());
return;
case APValue::Vector: {
Out << '{';
QualType ElemTy = Ty->getAs<VectorType>()->getElementType();
getVectorElt(0).printPretty(Out, Ctx, ElemTy);
for (unsigned i = 1; i != getVectorLength(); ++i) {
Out << ", ";
getVectorElt(i).printPretty(Out, Ctx, ElemTy);
}
Out << '}';
return;
}
case APValue::ComplexInt:
Out << getComplexIntReal() << "+" << getComplexIntImag() << "i";
return;
case APValue::ComplexFloat:
Out << GetApproxValue(getComplexFloatReal()) << "+"
<< GetApproxValue(getComplexFloatImag()) << "i";
return;
case APValue::LValue: {
LValueBase Base = getLValueBase();
if (!Base) {
Out << "0";
return;
}
bool IsReference = Ty->isReferenceType();
QualType InnerTy
= IsReference ? Ty.getNonReferenceType() : Ty->getPointeeType();
if (InnerTy.isNull())
InnerTy = Ty;
if (!hasLValuePath()) {
// No lvalue path: just print the offset.
CharUnits O = getLValueOffset();
CharUnits S = Ctx.getTypeSizeInChars(InnerTy);
if (!O.isZero()) {
if (IsReference)
Out << "*(";
if (O % S) {
Out << "(char*)";
S = CharUnits::One();
}
Out << '&';
} else if (!IsReference)
Out << '&';
if (const ValueDecl *VD = Base.dyn_cast<const ValueDecl*>())
Out << *VD;
else {
assert(Base.get<const Expr *>() != nullptr &&
"Expecting non-null Expr");
Base.get<const Expr*>()->printPretty(Out, nullptr,
Ctx.getPrintingPolicy());
}
if (!O.isZero()) {
Out << " + " << (O / S);
if (IsReference)
Out << ')';
}
return;
}
// We have an lvalue path. Print it out nicely.
if (!IsReference)
Out << '&';
else if (isLValueOnePastTheEnd())
Out << "*(&";
QualType ElemTy;
if (const ValueDecl *VD = Base.dyn_cast<const ValueDecl*>()) {
Out << *VD;
ElemTy = VD->getType();
} else {
const Expr *E = Base.get<const Expr*>();
assert(E != nullptr && "Expecting non-null Expr");
E->printPretty(Out, nullptr, Ctx.getPrintingPolicy());
ElemTy = E->getType();
}
ArrayRef<LValuePathEntry> Path = getLValuePath();
const CXXRecordDecl *CastToBase = nullptr;
for (unsigned I = 0, N = Path.size(); I != N; ++I) {
if (ElemTy->getAs<RecordType>()) {
// The lvalue refers to a class type, so the next path entry is a base
// or member.
const Decl *BaseOrMember =
BaseOrMemberType::getFromOpaqueValue(Path[I].BaseOrMember).getPointer();
if (const CXXRecordDecl *RD = dyn_cast<CXXRecordDecl>(BaseOrMember)) {
CastToBase = RD;
ElemTy = Ctx.getRecordType(RD);
} else {
const ValueDecl *VD = cast<ValueDecl>(BaseOrMember);
Out << ".";
if (CastToBase)
Out << *CastToBase << "::";
Out << *VD;
ElemTy = VD->getType();
}
} else {
// The lvalue must refer to an array.
Out << '[' << Path[I].ArrayIndex << ']';
ElemTy = Ctx.getAsArrayType(ElemTy)->getElementType();
}
}
// Handle formatting of one-past-the-end lvalues.
if (isLValueOnePastTheEnd()) {
// FIXME: If CastToBase is non-0, we should prefix the output with
// "(CastToBase*)".
Out << " + 1";
if (IsReference)
Out << ')';
}
return;
}
case APValue::Array: {
const ArrayType *AT = Ctx.getAsArrayType(Ty);
QualType ElemTy = AT->getElementType();
Out << '{';
if (unsigned N = getArrayInitializedElts()) {
getArrayInitializedElt(0).printPretty(Out, Ctx, ElemTy);
for (unsigned I = 1; I != N; ++I) {
Out << ", ";
if (I == 10) {
// Avoid printing out the entire contents of large arrays.
Out << "...";
break;
}
getArrayInitializedElt(I).printPretty(Out, Ctx, ElemTy);
}
}
Out << '}';
return;
}
case APValue::Struct: {
Out << '{';
const RecordDecl *RD = Ty->getAs<RecordType>()->getDecl();
bool First = true;
if (unsigned N = getStructNumBases()) {
const CXXRecordDecl *CD = cast<CXXRecordDecl>(RD);
CXXRecordDecl::base_class_const_iterator BI = CD->bases_begin();
for (unsigned I = 0; I != N; ++I, ++BI) {
assert(BI != CD->bases_end());
if (!First)
Out << ", ";
getStructBase(I).printPretty(Out, Ctx, BI->getType());
First = false;
}
}
for (const auto *FI : RD->fields()) {
if (!First)
Out << ", ";
if (FI->isUnnamedBitfield()) continue;
getStructField(FI->getFieldIndex()).
printPretty(Out, Ctx, FI->getType());
First = false;
}
Out << '}';
return;
}
case APValue::Union:
Out << '{';
if (const FieldDecl *FD = getUnionField()) {
Out << "." << *FD << " = ";
getUnionValue().printPretty(Out, Ctx, FD->getType());
}
Out << '}';
return;
case APValue::MemberPointer:
// FIXME: This is not enough to unambiguously identify the member in a
// multiple-inheritance scenario.
if (const ValueDecl *VD = getMemberPointerDecl()) {
Out << '&' << *cast<CXXRecordDecl>(VD->getDeclContext()) << "::" << *VD;
return;
}
Out << "0";
return;
case APValue::AddrLabelDiff:
Out << "&&" << getAddrLabelDiffLHS()->getLabel()->getName();
Out << " - ";
Out << "&&" << getAddrLabelDiffRHS()->getLabel()->getName();
return;
}
llvm_unreachable("Unknown APValue kind!");
}
