//===--- EvalEmitter.cpp - Instruction emitter 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 "EvalEmitter.h" #include "Context.h" #include "Interp.h" #include "Opcode.h" #include "Program.h" #include "clang/AST/DeclCXX.h" using namespace clang; using namespace clang::interp; using APSInt = llvm::APSInt; template using Expected = llvm::Expected; EvalEmitter::EvalEmitter(Context &Ctx, Program &P, State &Parent, InterpStack &Stk, APValue &Result) : Ctx(Ctx), P(P), S(Parent, P, Stk, Ctx, this), Result(Result) { // Create a dummy frame for the interpreter which does not have locals. S.Current = new InterpFrame(S, /*Func=*/nullptr, /*Caller=*/nullptr, CodePtr()); } llvm::Expected EvalEmitter::interpretExpr(const Expr *E) { if (this->visitExpr(E)) return true; if (BailLocation) return llvm::make_error(*BailLocation); return false; } llvm::Expected EvalEmitter::interpretDecl(const VarDecl *VD) { if (this->visitDecl(VD)) return true; if (BailLocation) return llvm::make_error(*BailLocation); return false; } void EvalEmitter::emitLabel(LabelTy Label) { CurrentLabel = Label; } EvalEmitter::LabelTy EvalEmitter::getLabel() { return NextLabel++; } Scope::Local EvalEmitter::createLocal(Descriptor *D) { // Allocate memory for a local. auto Memory = std::make_unique(sizeof(Block) + D->getAllocSize()); auto *B = new (Memory.get()) Block(D, /*isStatic=*/false); B->invokeCtor(); // Initialize local variable inline descriptor. InlineDescriptor &Desc = *reinterpret_cast(B->rawData()); Desc.Desc = D; Desc.Offset = sizeof(InlineDescriptor); Desc.IsActive = true; Desc.IsBase = false; Desc.IsFieldMutable = false; Desc.IsConst = false; Desc.IsInitialized = false; // Register the local. unsigned Off = Locals.size(); Locals.insert({Off, std::move(Memory)}); return {Off, D}; } bool EvalEmitter::bail(const SourceLocation &Loc) { if (!BailLocation) BailLocation = Loc; return false; } bool EvalEmitter::jumpTrue(const LabelTy &Label) { if (isActive()) { if (S.Stk.pop()) ActiveLabel = Label; } return true; } bool EvalEmitter::jumpFalse(const LabelTy &Label) { if (isActive()) { if (!S.Stk.pop()) ActiveLabel = Label; } return true; } bool EvalEmitter::jump(const LabelTy &Label) { if (isActive()) CurrentLabel = ActiveLabel = Label; return true; } bool EvalEmitter::fallthrough(const LabelTy &Label) { if (isActive()) ActiveLabel = Label; CurrentLabel = Label; return true; } template bool EvalEmitter::emitRet(const SourceInfo &Info) { if (!isActive()) return true; using T = typename PrimConv::T; return ReturnValue(S.Stk.pop(), Result); } bool EvalEmitter::emitRetVoid(const SourceInfo &Info) { return true; } bool EvalEmitter::emitRetValue(const SourceInfo &Info) { // Method to recursively traverse composites. std::function Composite; Composite = [this, &Composite](QualType Ty, const Pointer &Ptr, APValue &R) { if (auto *AT = Ty->getAs()) Ty = AT->getValueType(); if (auto *RT = Ty->getAs()) { auto *Record = Ptr.getRecord(); assert(Record && "Missing record descriptor"); bool Ok = true; if (RT->getDecl()->isUnion()) { const FieldDecl *ActiveField = nullptr; APValue Value; for (auto &F : Record->fields()) { const Pointer &FP = Ptr.atField(F.Offset); QualType FieldTy = F.Decl->getType(); if (FP.isActive()) { if (std::optional T = Ctx.classify(FieldTy)) { TYPE_SWITCH(*T, Ok &= ReturnValue(FP.deref(), Value)); } else { Ok &= Composite(FieldTy, FP, Value); } break; } } R = APValue(ActiveField, Value); } else { unsigned NF = Record->getNumFields(); unsigned NB = Record->getNumBases(); unsigned NV = Ptr.isBaseClass() ? 0 : Record->getNumVirtualBases(); R = APValue(APValue::UninitStruct(), NB, NF); for (unsigned I = 0; I < NF; ++I) { const Record::Field *FD = Record->getField(I); QualType FieldTy = FD->Decl->getType(); const Pointer &FP = Ptr.atField(FD->Offset); APValue &Value = R.getStructField(I); if (std::optional T = Ctx.classify(FieldTy)) { TYPE_SWITCH(*T, Ok &= ReturnValue(FP.deref(), Value)); } else { Ok &= Composite(FieldTy, FP, Value); } } for (unsigned I = 0; I < NB; ++I) { const Record::Base *BD = Record->getBase(I); QualType BaseTy = Ctx.getASTContext().getRecordType(BD->Decl); const Pointer &BP = Ptr.atField(BD->Offset); Ok &= Composite(BaseTy, BP, R.getStructBase(I)); } for (unsigned I = 0; I < NV; ++I) { const Record::Base *VD = Record->getVirtualBase(I); QualType VirtBaseTy = Ctx.getASTContext().getRecordType(VD->Decl); const Pointer &VP = Ptr.atField(VD->Offset); Ok &= Composite(VirtBaseTy, VP, R.getStructBase(NB + I)); } } return Ok; } if (auto *AT = Ty->getAsArrayTypeUnsafe()) { const size_t NumElems = Ptr.getNumElems(); QualType ElemTy = AT->getElementType(); R = APValue(APValue::UninitArray{}, NumElems, NumElems); bool Ok = true; for (unsigned I = 0; I < NumElems; ++I) { APValue &Slot = R.getArrayInitializedElt(I); const Pointer &EP = Ptr.atIndex(I); if (std::optional T = Ctx.classify(ElemTy)) { TYPE_SWITCH(*T, Ok &= ReturnValue(EP.deref(), Slot)); } else { Ok &= Composite(ElemTy, EP.narrow(), Slot); } } return Ok; } llvm_unreachable("invalid value to return"); }; // Return the composite type. const auto &Ptr = S.Stk.pop(); return Composite(Ptr.getType(), Ptr, Result); } bool EvalEmitter::emitGetPtrLocal(uint32_t I, const SourceInfo &Info) { if (!isActive()) return true; auto It = Locals.find(I); assert(It != Locals.end() && "Missing local variable"); Block *B = reinterpret_cast(It->second.get()); S.Stk.push(B, sizeof(InlineDescriptor)); return true; } template bool EvalEmitter::emitGetLocal(uint32_t I, const SourceInfo &Info) { if (!isActive()) return true; using T = typename PrimConv::T; auto It = Locals.find(I); assert(It != Locals.end() && "Missing local variable"); auto *B = reinterpret_cast(It->second.get()); S.Stk.push(*reinterpret_cast(B->data())); return true; } template bool EvalEmitter::emitSetLocal(uint32_t I, const SourceInfo &Info) { if (!isActive()) return true; using T = typename PrimConv::T; auto It = Locals.find(I); assert(It != Locals.end() && "Missing local variable"); auto *B = reinterpret_cast(It->second.get()); *reinterpret_cast(B->data()) = S.Stk.pop(); InlineDescriptor &Desc = *reinterpret_cast(B->rawData()); Desc.IsInitialized = true; return true; } bool EvalEmitter::emitDestroy(uint32_t I, const SourceInfo &Info) { if (!isActive()) return true; for (auto &Local : Descriptors[I]) { auto It = Locals.find(Local.Offset); assert(It != Locals.end() && "Missing local variable"); S.deallocate(reinterpret_cast(It->second.get())); } return true; } //===----------------------------------------------------------------------===// // Opcode evaluators //===----------------------------------------------------------------------===// #define GET_EVAL_IMPL #include "Opcodes.inc" #undef GET_EVAL_IMPL