//===--- InterpFrame.cpp - Call Frame implementation for the VM -*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "InterpFrame.h" #include "Boolean.h" #include "Function.h" #include "InterpStack.h" #include "InterpState.h" #include "MemberPointer.h" #include "Pointer.h" #include "PrimType.h" #include "Program.h" #include "clang/AST/ASTContext.h" #include "clang/AST/DeclCXX.h" #include "clang/AST/ExprCXX.h" using namespace clang; using namespace clang::interp; InterpFrame::InterpFrame(InterpState &S) : Caller(nullptr), S(S), Depth(0), Func(nullptr), RetPC(CodePtr()), ArgSize(0), Args(nullptr), FrameOffset(0), IsBottom(true) {} InterpFrame::InterpFrame(InterpState &S, const Function *Func, InterpFrame *Caller, CodePtr RetPC, unsigned ArgSize) : Caller(Caller), S(S), Depth(Caller ? Caller->Depth + 1 : 0), Func(Func), RetPC(RetPC), ArgSize(ArgSize), Args(static_cast(S.Stk.top())), FrameOffset(S.Stk.size()), IsBottom(!Caller) { if (!Func) return; unsigned FrameSize = Func->getFrameSize(); if (FrameSize == 0) return; Locals = std::make_unique(FrameSize); for (auto &Scope : Func->scopes()) { for (auto &Local : Scope.locals()) { new (localBlock(Local.Offset)) Block(S.Ctx.getEvalID(), Local.Desc); // Note that we are NOT calling invokeCtor() here, since that is done // via the InitScope op. new (localInlineDesc(Local.Offset)) InlineDescriptor(Local.Desc); } } } InterpFrame::InterpFrame(InterpState &S, const Function *Func, CodePtr RetPC, unsigned VarArgSize) : InterpFrame(S, Func, S.Current, RetPC, Func->getArgSize() + VarArgSize) { // As per our calling convention, the this pointer is // part of the ArgSize. // If the function has RVO, the RVO pointer is first. // If the fuction has a This pointer, that one is next. // Then follow the actual arguments (but those are handled // in getParamPointer()). if (Func->hasRVO()) RVOPtr = stackRef(0); if (Func->hasThisPointer()) { if (Func->hasRVO()) This = stackRef(sizeof(Pointer)); else This = stackRef(0); } } InterpFrame::~InterpFrame() { for (auto &Param : Params) S.deallocate(reinterpret_cast(Param.second.get())); // When destroying the InterpFrame, call the Dtor for all block // that haven't been destroyed via a destroy() op yet. // This happens when the execution is interruped midway-through. destroyScopes(); } void InterpFrame::destroyScopes() { if (!Func) return; for (auto &Scope : Func->scopes()) { for (auto &Local : Scope.locals()) { S.deallocate(localBlock(Local.Offset)); } } } void InterpFrame::initScope(unsigned Idx) { if (!Func) return; for (auto &Local : Func->getScope(Idx).locals()) { localBlock(Local.Offset)->invokeCtor(); } } void InterpFrame::destroy(unsigned Idx) { for (auto &Local : Func->getScope(Idx).locals_reverse()) { S.deallocate(localBlock(Local.Offset)); } } template static void print(llvm::raw_ostream &OS, const T &V, ASTContext &ASTCtx, QualType Ty) { if constexpr (std::is_same_v) { if (Ty->isPointerOrReferenceType()) V.toAPValue(ASTCtx).printPretty(OS, ASTCtx, Ty); else { if (std::optional RValue = V.toRValue(ASTCtx, Ty)) RValue->printPretty(OS, ASTCtx, Ty); else OS << "..."; } } else { V.toAPValue(ASTCtx).printPretty(OS, ASTCtx, Ty); } } static bool shouldSkipInBacktrace(const Function *F) { if (F->isLambdaStaticInvoker()) return true; const FunctionDecl *FD = F->getDecl(); if (FD->getDeclName().getCXXOverloadedOperator() == OO_New || FD->getDeclName().getCXXOverloadedOperator() == OO_Array_New) return true; return false; } void InterpFrame::describe(llvm::raw_ostream &OS) const { // For lambda static invokers, we would just print __invoke(). if (const auto *F = getFunction(); F && shouldSkipInBacktrace(F)) return; const Expr *CallExpr = Caller->getExpr(getRetPC()); const FunctionDecl *F = getCallee(); bool IsMemberCall = isa(F) && !isa(F) && cast(F)->isImplicitObjectMemberFunction(); if (Func->hasThisPointer() && IsMemberCall) { if (const auto *MCE = dyn_cast_if_present(CallExpr)) { const Expr *Object = MCE->getImplicitObjectArgument(); Object->printPretty(OS, /*Helper=*/nullptr, S.getASTContext().getPrintingPolicy(), /*Indentation=*/0); if (Object->getType()->isPointerType()) OS << "->"; else OS << "."; } else if (const auto *OCE = dyn_cast_if_present(CallExpr)) { OCE->getArg(0)->printPretty(OS, /*Helper=*/nullptr, S.getASTContext().getPrintingPolicy(), /*Indentation=*/0); OS << "."; } else if (const auto *M = dyn_cast(F)) { print(OS, This, S.getASTContext(), S.getASTContext().getLValueReferenceType( S.getASTContext().getRecordType(M->getParent()))); OS << "."; } } F->getNameForDiagnostic(OS, S.getASTContext().getPrintingPolicy(), /*Qualified=*/false); OS << '('; unsigned Off = 0; Off += Func->hasRVO() ? primSize(PT_Ptr) : 0; Off += Func->hasThisPointer() ? primSize(PT_Ptr) : 0; for (unsigned I = 0, N = F->getNumParams(); I < N; ++I) { QualType Ty = F->getParamDecl(I)->getType(); PrimType PrimTy = S.Ctx.classify(Ty).value_or(PT_Ptr); TYPE_SWITCH(PrimTy, print(OS, stackRef(Off), S.getASTContext(), Ty)); Off += align(primSize(PrimTy)); if (I + 1 != N) OS << ", "; } OS << ")"; } Frame *InterpFrame::getCaller() const { if (Caller->Caller) return Caller; return S.getSplitFrame(); } SourceRange InterpFrame::getCallRange() const { if (!Caller->Func) { if (SourceRange NullRange = S.getRange(nullptr, {}); NullRange.isValid()) return NullRange; return S.EvalLocation; } return S.getRange(Caller->Func, RetPC - sizeof(uintptr_t)); } const FunctionDecl *InterpFrame::getCallee() const { if (!Func) return nullptr; return Func->getDecl(); } Pointer InterpFrame::getLocalPointer(unsigned Offset) const { assert(Offset < Func->getFrameSize() && "Invalid local offset."); return Pointer(localBlock(Offset)); } Pointer InterpFrame::getParamPointer(unsigned Off) { // Return the block if it was created previously. if (auto Pt = Params.find(Off); Pt != Params.end()) return Pointer(reinterpret_cast(Pt->second.get())); // Allocate memory to store the parameter and the block metadata. const auto &Desc = Func->getParamDescriptor(Off); size_t BlockSize = sizeof(Block) + Desc.second->getAllocSize(); auto Memory = std::make_unique(BlockSize); auto *B = new (Memory.get()) Block(S.Ctx.getEvalID(), Desc.second); B->invokeCtor(); // Copy the initial value. TYPE_SWITCH(Desc.first, new (B->data()) T(stackRef(Off))); // Record the param. Params.insert({Off, std::move(Memory)}); return Pointer(B); } static bool funcHasUsableBody(const Function *F) { assert(F); if (F->isConstructor() || F->isDestructor()) return true; return !F->getDecl()->isImplicit(); } SourceInfo InterpFrame::getSource(CodePtr PC) const { // Implicitly created functions don't have any code we could point at, // so return the call site. if (Func && !funcHasUsableBody(Func) && Caller) return Caller->getSource(RetPC); // Similarly, if the resulting source location is invalid anyway, // point to the caller instead. SourceInfo Result = S.getSource(Func, PC); if (Result.getLoc().isInvalid() && Caller) return Caller->getSource(RetPC); return Result; } const Expr *InterpFrame::getExpr(CodePtr PC) const { if (Func && !funcHasUsableBody(Func) && Caller) return Caller->getExpr(RetPC); return S.getExpr(Func, PC); } SourceLocation InterpFrame::getLocation(CodePtr PC) const { if (Func && !funcHasUsableBody(Func) && Caller) return Caller->getLocation(RetPC); return S.getLocation(Func, PC); } SourceRange InterpFrame::getRange(CodePtr PC) const { if (Func && !funcHasUsableBody(Func) && Caller) return Caller->getRange(RetPC); return S.getRange(Func, PC); } bool InterpFrame::isStdFunction() const { if (!Func) return false; for (const DeclContext *DC = Func->getDecl(); DC; DC = DC->getParent()) if (DC->isStdNamespace()) return true; return false; }