bool VisitCXXOperatorCallExpr(clang::CXXOperatorCallExpr* op_call) {
// if (!TheRewriter.getSourceMgr().isInMainFile(op_call->getLocStart())) return true;
if (clang::OO_Pipe == op_call->getOperator()) {
FunctionDecl* callee = op_call->getDirectCallee();
if (callee) {
StringRef fname_ref = TheRewriter.getSourceMgr().getFilename(callee->getLocStart());
if(fname_ref.find("op_impl.h") != clang::StringRef::npos) {
// this is the overloaded | operator
// whose parent is ExprWithCleanups
CommStmtWalker stmt_walker;
stmt_walker.TraverseStmt(op_call);
auto free_vars = stmt_walker.get_free_vars();
stmt_fv_map[op_call] = free_vars;
}
}
}
return true;
}
Expr* ValueExtractionSynthesizer::SynthesizeSVRInit(Expr* E) {
if (!m_gClingVD)
FindAndCacheRuntimeDecls();
// Build a reference to gCling
ExprResult gClingDRE
= m_Sema->BuildDeclRefExpr(m_gClingVD, m_Context->VoidPtrTy,
VK_RValue, SourceLocation());
// We have the wrapper as Sema's CurContext
FunctionDecl* FD = cast<FunctionDecl>(m_Sema->CurContext);
ExprWithCleanups* Cleanups = 0;
// In case of ExprWithCleanups we need to extend its 'scope' to the call.
if (E && isa<ExprWithCleanups>(E)) {
Cleanups = cast<ExprWithCleanups>(E);
E = Cleanups->getSubExpr();
}
// Build a reference to Value* in the wrapper, should be
// the only argument of the wrapper.
SourceLocation locStart = (E) ? E->getLocStart() : FD->getLocStart();
SourceLocation locEnd = (E) ? E->getLocEnd() : FD->getLocEnd();
ExprResult wrapperSVRDRE
= m_Sema->BuildDeclRefExpr(FD->getParamDecl(0), m_Context->VoidPtrTy,
VK_RValue, locStart);
QualType ETy = (E) ? E->getType() : m_Context->VoidTy;
QualType desugaredTy = ETy.getDesugaredType(*m_Context);
// The expr result is transported as reference, pointer, array, float etc
// based on the desugared type. We should still expose the typedef'ed
// (sugared) type to the cling::Value.
if (desugaredTy->isRecordType() && E->getValueKind() == VK_LValue) {
// returning a lvalue (not a temporary): the value should contain
// a reference to the lvalue instead of copying it.
desugaredTy = m_Context->getLValueReferenceType(desugaredTy);
ETy = m_Context->getLValueReferenceType(ETy);
}
Expr* ETyVP
= utils::Synthesize::CStyleCastPtrExpr(m_Sema, m_Context->VoidPtrTy,
(uint64_t)ETy.getAsOpaquePtr());
Expr* ETransaction
= utils::Synthesize::CStyleCastPtrExpr(m_Sema, m_Context->VoidPtrTy,
(uint64_t)getTransaction());
llvm::SmallVector<Expr*, 6> CallArgs;
CallArgs.push_back(gClingDRE.take());
CallArgs.push_back(wrapperSVRDRE.take());
CallArgs.push_back(ETyVP);
CallArgs.push_back(ETransaction);
ExprResult Call;
SourceLocation noLoc;
if (desugaredTy->isVoidType()) {
// In cases where the cling::Value gets reused we need to reset the
// previous settings to void.
// We need to synthesize setValueNoAlloc(...), E, because we still need
// to run E.
// FIXME: Suboptimal: this discards the already created AST nodes.
QualType vpQT = m_Context->VoidPtrTy;
QualType vQT = m_Context->VoidTy;
Expr* vpQTVP
= utils::Synthesize::CStyleCastPtrExpr(m_Sema, vpQT,
(uint64_t)vQT.getAsOpaquePtr());
CallArgs[2] = vpQTVP;
Call = m_Sema->ActOnCallExpr(/*Scope*/0, m_UnresolvedNoAlloc,
locStart, CallArgs, locEnd);
if (E)
Call = m_Sema->CreateBuiltinBinOp(locStart, BO_Comma, Call.take(), E);
}
else if (desugaredTy->isRecordType() || desugaredTy->isConstantArrayType()){
// 2) object types :
// check existance of copy constructor before call
if (!availableCopyConstructor(desugaredTy, m_Sema))
return E;
// call new (setValueWithAlloc(gCling, &SVR, ETy)) (E)
Call = m_Sema->ActOnCallExpr(/*Scope*/0, m_UnresolvedWithAlloc,
locStart, CallArgs, locEnd);
Expr* placement = Call.take();
if (const ConstantArrayType* constArray
= dyn_cast<ConstantArrayType>(desugaredTy.getTypePtr())) {
CallArgs.clear();
CallArgs.push_back(E);
CallArgs.push_back(placement);
uint64_t arrSize
= m_Context->getConstantArrayElementCount(constArray);
Expr* arrSizeExpr
= utils::Synthesize::IntegerLiteralExpr(*m_Context, arrSize);
CallArgs.push_back(arrSizeExpr);
// 2.1) arrays:
// call copyArray(T* src, void* placement, int size)
Call = m_Sema->ActOnCallExpr(/*Scope*/0, m_UnresolvedCopyArray,
locStart, CallArgs, locEnd);
}
else {
TypeSourceInfo* ETSI
= m_Context->getTrivialTypeSourceInfo(ETy, noLoc);
Call = m_Sema->BuildCXXNew(E->getSourceRange(),
/*useGlobal ::*/true,
/*placementLParen*/ noLoc,
MultiExprArg(placement),
/*placementRParen*/ noLoc,
/*TypeIdParens*/ SourceRange(),
/*allocType*/ ETSI->getType(),
/*allocTypeInfo*/ETSI,
/*arraySize*/0,
/*directInitRange*/E->getSourceRange(),
/*initializer*/E,
/*mayContainAuto*/false
);
}
}
else if (desugaredTy->isIntegralOrEnumerationType()
|| desugaredTy->isReferenceType()
|| desugaredTy->isPointerType()
|| desugaredTy->isFloatingType()) {
if (desugaredTy->isIntegralOrEnumerationType()) {
// 1) enum, integral, float, double, referece, pointer types :
// call to cling::internal::setValueNoAlloc(...);
// If the type is enum or integral we need to force-cast it into
// uint64 in order to pick up the correct overload.
if (desugaredTy->isIntegralOrEnumerationType()) {
QualType UInt64Ty = m_Context->UnsignedLongLongTy;
TypeSourceInfo* TSI
= m_Context->getTrivialTypeSourceInfo(UInt64Ty, noLoc);
Expr* castedE
= m_Sema->BuildCStyleCastExpr(noLoc, TSI, noLoc, E).take();
CallArgs.push_back(castedE);
}
}
else if (desugaredTy->isReferenceType()) {
// we need to get the address of the references
Expr* AddrOfE = m_Sema->BuildUnaryOp(/*Scope*/0, noLoc, UO_AddrOf,
E).take();
CallArgs.push_back(AddrOfE);
}
else if (desugaredTy->isPointerType()) {
// function pointers need explicit void* cast.
QualType VoidPtrTy = m_Context->VoidPtrTy;
TypeSourceInfo* TSI
= m_Context->getTrivialTypeSourceInfo(VoidPtrTy, noLoc);
Expr* castedE
= m_Sema->BuildCStyleCastExpr(noLoc, TSI, noLoc, E).take();
CallArgs.push_back(castedE);
}
else if (desugaredTy->isFloatingType()) {
// floats and double will fall naturally in the correct
// case, because of the overload resolution.
CallArgs.push_back(E);
}
Call = m_Sema->ActOnCallExpr(/*Scope*/0, m_UnresolvedNoAlloc,
locStart, CallArgs, locEnd);
}
else
assert(0 && "Unhandled code path?");
assert(!Call.isInvalid() && "Invalid Call");
// Extend the scope of the temporary cleaner if applicable.
if (Cleanups) {
Cleanups->setSubExpr(Call.take());
Cleanups->setValueKind(Call.take()->getValueKind());
Cleanups->setType(Call.take()->getType());
return Cleanups;
}
return Call.take();
}
