//===- StackSafetyAnalysis.cpp - Stack memory safety analysis -------------===// // // 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 "llvm/Analysis/StackSafetyAnalysis.h" #include "llvm/ADT/APInt.h" #include "llvm/ADT/SmallPtrSet.h" #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/Statistic.h" #include "llvm/Analysis/ModuleSummaryAnalysis.h" #include "llvm/Analysis/ScalarEvolution.h" #include "llvm/Analysis/StackLifetime.h" #include "llvm/IR/ConstantRange.h" #include "llvm/IR/DerivedTypes.h" #include "llvm/IR/GlobalValue.h" #include "llvm/IR/InstIterator.h" #include "llvm/IR/Instruction.h" #include "llvm/IR/Instructions.h" #include "llvm/IR/IntrinsicInst.h" #include "llvm/IR/ModuleSummaryIndex.h" #include "llvm/InitializePasses.h" #include "llvm/Support/Casting.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/FormatVariadic.h" #include "llvm/Support/raw_ostream.h" #include #include #include using namespace llvm; #define DEBUG_TYPE "stack-safety" STATISTIC(NumAllocaStackSafe, "Number of safe allocas"); STATISTIC(NumAllocaTotal, "Number of total allocas"); STATISTIC(NumCombinedCalleeLookupTotal, "Number of total callee lookups on combined index."); STATISTIC(NumCombinedCalleeLookupFailed, "Number of failed callee lookups on combined index."); STATISTIC(NumModuleCalleeLookupTotal, "Number of total callee lookups on module index."); STATISTIC(NumModuleCalleeLookupFailed, "Number of failed callee lookups on module index."); STATISTIC(NumCombinedParamAccessesBefore, "Number of total param accesses before generateParamAccessSummary."); STATISTIC(NumCombinedParamAccessesAfter, "Number of total param accesses after generateParamAccessSummary."); STATISTIC(NumCombinedDataFlowNodes, "Number of total nodes in combined index for dataflow processing."); STATISTIC(NumIndexCalleeUnhandled, "Number of index callee which are unhandled."); STATISTIC(NumIndexCalleeMultipleWeak, "Number of index callee non-unique weak."); STATISTIC(NumIndexCalleeMultipleExternal, "Number of index callee non-unique external."); static cl::opt StackSafetyMaxIterations("stack-safety-max-iterations", cl::init(20), cl::Hidden); static cl::opt StackSafetyPrint("stack-safety-print", cl::init(false), cl::Hidden); static cl::opt StackSafetyRun("stack-safety-run", cl::init(false), cl::Hidden); namespace { // Check if we should bailout for such ranges. bool isUnsafe(const ConstantRange &R) { return R.isEmptySet() || R.isFullSet() || R.isUpperSignWrapped(); } ConstantRange addOverflowNever(const ConstantRange &L, const ConstantRange &R) { assert(!L.isSignWrappedSet()); assert(!R.isSignWrappedSet()); if (L.signedAddMayOverflow(R) != ConstantRange::OverflowResult::NeverOverflows) return ConstantRange::getFull(L.getBitWidth()); ConstantRange Result = L.add(R); assert(!Result.isSignWrappedSet()); return Result; } ConstantRange unionNoWrap(const ConstantRange &L, const ConstantRange &R) { assert(!L.isSignWrappedSet()); assert(!R.isSignWrappedSet()); auto Result = L.unionWith(R); // Two non-wrapped sets can produce wrapped. if (Result.isSignWrappedSet()) Result = ConstantRange::getFull(Result.getBitWidth()); return Result; } /// Describes use of address in as a function call argument. template struct CallInfo { /// Function being called. const CalleeTy *Callee = nullptr; /// Index of argument which pass address. size_t ParamNo = 0; CallInfo(const CalleeTy *Callee, size_t ParamNo) : Callee(Callee), ParamNo(ParamNo) {} struct Less { bool operator()(const CallInfo &L, const CallInfo &R) const { return std::tie(L.ParamNo, L.Callee) < std::tie(R.ParamNo, R.Callee); } }; }; /// Describe uses of address (alloca or parameter) inside of the function. template struct UseInfo { // Access range if the address (alloca or parameters). // It is allowed to be empty-set when there are no known accesses. ConstantRange Range; std::set UnsafeAccesses; // List of calls which pass address as an argument. // Value is offset range of address from base address (alloca or calling // function argument). Range should never set to empty-set, that is an invalid // access range that can cause empty-set to be propagated with // ConstantRange::add using CallsTy = std::map, ConstantRange, typename CallInfo::Less>; CallsTy Calls; UseInfo(unsigned PointerSize) : Range{PointerSize, false} {} void updateRange(const ConstantRange &R) { Range = unionNoWrap(Range, R); } void addRange(const Instruction *I, const ConstantRange &R, bool IsSafe) { if (!IsSafe) UnsafeAccesses.insert(I); updateRange(R); } }; template raw_ostream &operator<<(raw_ostream &OS, const UseInfo &U) { OS << U.Range; for (auto &Call : U.Calls) OS << ", " << "@" << Call.first.Callee->getName() << "(arg" << Call.first.ParamNo << ", " << Call.second << ")"; return OS; } /// Calculate the allocation size of a given alloca. Returns empty range // in case of confution. ConstantRange getStaticAllocaSizeRange(const AllocaInst &AI) { const DataLayout &DL = AI.getModule()->getDataLayout(); TypeSize TS = DL.getTypeAllocSize(AI.getAllocatedType()); unsigned PointerSize = DL.getPointerTypeSizeInBits(AI.getType()); // Fallback to empty range for alloca size. ConstantRange R = ConstantRange::getEmpty(PointerSize); if (TS.isScalable()) return R; APInt APSize(PointerSize, TS.getFixedValue(), true); if (APSize.isNonPositive()) return R; if (AI.isArrayAllocation()) { const auto *C = dyn_cast(AI.getArraySize()); if (!C) return R; bool Overflow = false; APInt Mul = C->getValue(); if (Mul.isNonPositive()) return R; Mul = Mul.sextOrTrunc(PointerSize); APSize = APSize.smul_ov(Mul, Overflow); if (Overflow) return R; } R = ConstantRange(APInt::getZero(PointerSize), APSize); assert(!isUnsafe(R)); return R; } template struct FunctionInfo { std::map> Allocas; std::map> Params; // TODO: describe return value as depending on one or more of its arguments. // StackSafetyDataFlowAnalysis counter stored here for faster access. int UpdateCount = 0; void print(raw_ostream &O, StringRef Name, const Function *F) const { // TODO: Consider different printout format after // StackSafetyDataFlowAnalysis. Calls and parameters are irrelevant then. O << " @" << Name << ((F && F->isDSOLocal()) ? "" : " dso_preemptable") << ((F && F->isInterposable()) ? " interposable" : "") << "\n"; O << " args uses:\n"; for (auto &KV : Params) { O << " "; if (F) O << F->getArg(KV.first)->getName(); else O << formatv("arg{0}", KV.first); O << "[]: " << KV.second << "\n"; } O << " allocas uses:\n"; if (F) { for (const auto &I : instructions(F)) { if (const AllocaInst *AI = dyn_cast(&I)) { auto &AS = Allocas.find(AI)->second; O << " " << AI->getName() << "[" << getStaticAllocaSizeRange(*AI).getUpper() << "]: " << AS << "\n"; } } } else { assert(Allocas.empty()); } } }; using GVToSSI = std::map>; } // namespace struct StackSafetyInfo::InfoTy { FunctionInfo Info; }; struct StackSafetyGlobalInfo::InfoTy { GVToSSI Info; SmallPtrSet SafeAllocas; std::set UnsafeAccesses; }; namespace { class StackSafetyLocalAnalysis { Function &F; const DataLayout &DL; ScalarEvolution &SE; unsigned PointerSize = 0; const ConstantRange UnknownRange; ConstantRange offsetFrom(Value *Addr, Value *Base); ConstantRange getAccessRange(Value *Addr, Value *Base, const ConstantRange &SizeRange); ConstantRange getAccessRange(Value *Addr, Value *Base, TypeSize Size); ConstantRange getMemIntrinsicAccessRange(const MemIntrinsic *MI, const Use &U, Value *Base); void analyzeAllUses(Value *Ptr, UseInfo &AS, const StackLifetime &SL); bool isSafeAccess(const Use &U, AllocaInst *AI, const SCEV *AccessSize); bool isSafeAccess(const Use &U, AllocaInst *AI, Value *V); bool isSafeAccess(const Use &U, AllocaInst *AI, TypeSize AccessSize); public: StackSafetyLocalAnalysis(Function &F, ScalarEvolution &SE) : F(F), DL(F.getParent()->getDataLayout()), SE(SE), PointerSize(DL.getPointerSizeInBits()), UnknownRange(PointerSize, true) {} // Run the transformation on the associated function. FunctionInfo run(); }; ConstantRange StackSafetyLocalAnalysis::offsetFrom(Value *Addr, Value *Base) { if (!SE.isSCEVable(Addr->getType()) || !SE.isSCEVable(Base->getType())) return UnknownRange; auto *PtrTy = PointerType::getUnqual(SE.getContext()); const SCEV *AddrExp = SE.getTruncateOrZeroExtend(SE.getSCEV(Addr), PtrTy); const SCEV *BaseExp = SE.getTruncateOrZeroExtend(SE.getSCEV(Base), PtrTy); const SCEV *Diff = SE.getMinusSCEV(AddrExp, BaseExp); if (isa(Diff)) return UnknownRange; ConstantRange Offset = SE.getSignedRange(Diff); if (isUnsafe(Offset)) return UnknownRange; return Offset.sextOrTrunc(PointerSize); } ConstantRange StackSafetyLocalAnalysis::getAccessRange(Value *Addr, Value *Base, const ConstantRange &SizeRange) { // Zero-size loads and stores do not access memory. if (SizeRange.isEmptySet()) return ConstantRange::getEmpty(PointerSize); assert(!isUnsafe(SizeRange)); ConstantRange Offsets = offsetFrom(Addr, Base); if (isUnsafe(Offsets)) return UnknownRange; Offsets = addOverflowNever(Offsets, SizeRange); if (isUnsafe(Offsets)) return UnknownRange; return Offsets; } ConstantRange StackSafetyLocalAnalysis::getAccessRange(Value *Addr, Value *Base, TypeSize Size) { if (Size.isScalable()) return UnknownRange; APInt APSize(PointerSize, Size.getFixedValue(), true); if (APSize.isNegative()) return UnknownRange; return getAccessRange(Addr, Base, ConstantRange(APInt::getZero(PointerSize), APSize)); } ConstantRange StackSafetyLocalAnalysis::getMemIntrinsicAccessRange( const MemIntrinsic *MI, const Use &U, Value *Base) { if (const auto *MTI = dyn_cast(MI)) { if (MTI->getRawSource() != U && MTI->getRawDest() != U) return ConstantRange::getEmpty(PointerSize); } else { if (MI->getRawDest() != U) return ConstantRange::getEmpty(PointerSize); } auto *CalculationTy = IntegerType::getIntNTy(SE.getContext(), PointerSize); if (!SE.isSCEVable(MI->getLength()->getType())) return UnknownRange; const SCEV *Expr = SE.getTruncateOrZeroExtend(SE.getSCEV(MI->getLength()), CalculationTy); ConstantRange Sizes = SE.getSignedRange(Expr); if (!Sizes.getUpper().isStrictlyPositive() || isUnsafe(Sizes)) return UnknownRange; Sizes = Sizes.sextOrTrunc(PointerSize); ConstantRange SizeRange(APInt::getZero(PointerSize), Sizes.getUpper() - 1); return getAccessRange(U, Base, SizeRange); } bool StackSafetyLocalAnalysis::isSafeAccess(const Use &U, AllocaInst *AI, Value *V) { return isSafeAccess(U, AI, SE.getSCEV(V)); } bool StackSafetyLocalAnalysis::isSafeAccess(const Use &U, AllocaInst *AI, TypeSize TS) { if (TS.isScalable()) return false; auto *CalculationTy = IntegerType::getIntNTy(SE.getContext(), PointerSize); const SCEV *SV = SE.getConstant(CalculationTy, TS.getFixedValue()); return isSafeAccess(U, AI, SV); } bool StackSafetyLocalAnalysis::isSafeAccess(const Use &U, AllocaInst *AI, const SCEV *AccessSize) { if (!AI) return true; // This only judges whether it is a safe *stack* access. if (isa(AccessSize)) return false; const auto *I = cast(U.getUser()); auto ToCharPtr = [&](const SCEV *V) { auto *PtrTy = PointerType::getUnqual(SE.getContext()); return SE.getTruncateOrZeroExtend(V, PtrTy); }; const SCEV *AddrExp = ToCharPtr(SE.getSCEV(U.get())); const SCEV *BaseExp = ToCharPtr(SE.getSCEV(AI)); const SCEV *Diff = SE.getMinusSCEV(AddrExp, BaseExp); if (isa(Diff)) return false; auto Size = getStaticAllocaSizeRange(*AI); auto *CalculationTy = IntegerType::getIntNTy(SE.getContext(), PointerSize); auto ToDiffTy = [&](const SCEV *V) { return SE.getTruncateOrZeroExtend(V, CalculationTy); }; const SCEV *Min = ToDiffTy(SE.getConstant(Size.getLower())); const SCEV *Max = SE.getMinusSCEV(ToDiffTy(SE.getConstant(Size.getUpper())), ToDiffTy(AccessSize)); return SE.evaluatePredicateAt(ICmpInst::Predicate::ICMP_SGE, Diff, Min, I) .value_or(false) && SE.evaluatePredicateAt(ICmpInst::Predicate::ICMP_SLE, Diff, Max, I) .value_or(false); } /// The function analyzes all local uses of Ptr (alloca or argument) and /// calculates local access range and all function calls where it was used. void StackSafetyLocalAnalysis::analyzeAllUses(Value *Ptr, UseInfo &US, const StackLifetime &SL) { SmallPtrSet Visited; SmallVector WorkList; WorkList.push_back(Ptr); AllocaInst *AI = dyn_cast(Ptr); // A DFS search through all uses of the alloca in bitcasts/PHI/GEPs/etc. while (!WorkList.empty()) { const Value *V = WorkList.pop_back_val(); for (const Use &UI : V->uses()) { const auto *I = cast(UI.getUser()); if (!SL.isReachable(I)) continue; assert(V == UI.get()); auto RecordStore = [&](const Value* StoredVal) { if (V == StoredVal) { // Stored the pointer - conservatively assume it may be unsafe. US.addRange(I, UnknownRange, /*IsSafe=*/false); return; } if (AI && !SL.isAliveAfter(AI, I)) { US.addRange(I, UnknownRange, /*IsSafe=*/false); return; } auto TypeSize = DL.getTypeStoreSize(StoredVal->getType()); auto AccessRange = getAccessRange(UI, Ptr, TypeSize); bool Safe = isSafeAccess(UI, AI, TypeSize); US.addRange(I, AccessRange, Safe); return; }; switch (I->getOpcode()) { case Instruction::Load: { if (AI && !SL.isAliveAfter(AI, I)) { US.addRange(I, UnknownRange, /*IsSafe=*/false); break; } auto TypeSize = DL.getTypeStoreSize(I->getType()); auto AccessRange = getAccessRange(UI, Ptr, TypeSize); bool Safe = isSafeAccess(UI, AI, TypeSize); US.addRange(I, AccessRange, Safe); break; } case Instruction::VAArg: // "va-arg" from a pointer is safe. break; case Instruction::Store: RecordStore(cast(I)->getValueOperand()); break; case Instruction::AtomicCmpXchg: RecordStore(cast(I)->getNewValOperand()); break; case Instruction::AtomicRMW: RecordStore(cast(I)->getValOperand()); break; case Instruction::Ret: // Information leak. // FIXME: Process parameters correctly. This is a leak only if we return // alloca. US.addRange(I, UnknownRange, /*IsSafe=*/false); break; case Instruction::Call: case Instruction::Invoke: { if (I->isLifetimeStartOrEnd()) break; if (AI && !SL.isAliveAfter(AI, I)) { US.addRange(I, UnknownRange, /*IsSafe=*/false); break; } if (const MemIntrinsic *MI = dyn_cast(I)) { auto AccessRange = getMemIntrinsicAccessRange(MI, UI, Ptr); bool Safe = false; if (const auto *MTI = dyn_cast(MI)) { if (MTI->getRawSource() != UI && MTI->getRawDest() != UI) Safe = true; } else if (MI->getRawDest() != UI) { Safe = true; } Safe = Safe || isSafeAccess(UI, AI, MI->getLength()); US.addRange(I, AccessRange, Safe); break; } const auto &CB = cast(*I); if (CB.getReturnedArgOperand() == V) { if (Visited.insert(I).second) WorkList.push_back(cast(I)); } if (!CB.isArgOperand(&UI)) { US.addRange(I, UnknownRange, /*IsSafe=*/false); break; } unsigned ArgNo = CB.getArgOperandNo(&UI); if (CB.isByValArgument(ArgNo)) { auto TypeSize = DL.getTypeStoreSize(CB.getParamByValType(ArgNo)); auto AccessRange = getAccessRange(UI, Ptr, TypeSize); bool Safe = isSafeAccess(UI, AI, TypeSize); US.addRange(I, AccessRange, Safe); break; } // FIXME: consult devirt? // Do not follow aliases, otherwise we could inadvertently follow // dso_preemptable aliases or aliases with interposable linkage. const GlobalValue *Callee = dyn_cast(CB.getCalledOperand()->stripPointerCasts()); if (!Callee) { US.addRange(I, UnknownRange, /*IsSafe=*/false); break; } assert(isa(Callee) || isa(Callee)); ConstantRange Offsets = offsetFrom(UI, Ptr); auto Insert = US.Calls.emplace(CallInfo(Callee, ArgNo), Offsets); if (!Insert.second) Insert.first->second = Insert.first->second.unionWith(Offsets); break; } default: if (Visited.insert(I).second) WorkList.push_back(cast(I)); } } } } FunctionInfo StackSafetyLocalAnalysis::run() { FunctionInfo Info; assert(!F.isDeclaration() && "Can't run StackSafety on a function declaration"); LLVM_DEBUG(dbgs() << "[StackSafety] " << F.getName() << "\n"); SmallVector Allocas; for (auto &I : instructions(F)) if (auto *AI = dyn_cast(&I)) Allocas.push_back(AI); StackLifetime SL(F, Allocas, StackLifetime::LivenessType::Must); SL.run(); for (auto *AI : Allocas) { auto &UI = Info.Allocas.emplace(AI, PointerSize).first->second; analyzeAllUses(AI, UI, SL); } for (Argument &A : F.args()) { // Non pointers and bypass arguments are not going to be used in any global // processing. if (A.getType()->isPointerTy() && !A.hasByValAttr()) { auto &UI = Info.Params.emplace(A.getArgNo(), PointerSize).first->second; analyzeAllUses(&A, UI, SL); } } LLVM_DEBUG(Info.print(dbgs(), F.getName(), &F)); LLVM_DEBUG(dbgs() << "\n[StackSafety] done\n"); return Info; } template class StackSafetyDataFlowAnalysis { using FunctionMap = std::map>; FunctionMap Functions; const ConstantRange UnknownRange; // Callee-to-Caller multimap. DenseMap> Callers; SetVector WorkList; bool updateOneUse(UseInfo &US, bool UpdateToFullSet); void updateOneNode(const CalleeTy *Callee, FunctionInfo &FS); void updateOneNode(const CalleeTy *Callee) { updateOneNode(Callee, Functions.find(Callee)->second); } void updateAllNodes() { for (auto &F : Functions) updateOneNode(F.first, F.second); } void runDataFlow(); #ifndef NDEBUG void verifyFixedPoint(); #endif public: StackSafetyDataFlowAnalysis(uint32_t PointerBitWidth, FunctionMap Functions) : Functions(std::move(Functions)), UnknownRange(ConstantRange::getFull(PointerBitWidth)) {} const FunctionMap &run(); ConstantRange getArgumentAccessRange(const CalleeTy *Callee, unsigned ParamNo, const ConstantRange &Offsets) const; }; template ConstantRange StackSafetyDataFlowAnalysis::getArgumentAccessRange( const CalleeTy *Callee, unsigned ParamNo, const ConstantRange &Offsets) const { auto FnIt = Functions.find(Callee); // Unknown callee (outside of LTO domain or an indirect call). if (FnIt == Functions.end()) return UnknownRange; auto &FS = FnIt->second; auto ParamIt = FS.Params.find(ParamNo); if (ParamIt == FS.Params.end()) return UnknownRange; auto &Access = ParamIt->second.Range; if (Access.isEmptySet()) return Access; if (Access.isFullSet()) return UnknownRange; return addOverflowNever(Access, Offsets); } template bool StackSafetyDataFlowAnalysis::updateOneUse(UseInfo &US, bool UpdateToFullSet) { bool Changed = false; for (auto &KV : US.Calls) { assert(!KV.second.isEmptySet() && "Param range can't be empty-set, invalid offset range"); ConstantRange CalleeRange = getArgumentAccessRange(KV.first.Callee, KV.first.ParamNo, KV.second); if (!US.Range.contains(CalleeRange)) { Changed = true; if (UpdateToFullSet) US.Range = UnknownRange; else US.updateRange(CalleeRange); } } return Changed; } template void StackSafetyDataFlowAnalysis::updateOneNode( const CalleeTy *Callee, FunctionInfo &FS) { bool UpdateToFullSet = FS.UpdateCount > StackSafetyMaxIterations; bool Changed = false; for (auto &KV : FS.Params) Changed |= updateOneUse(KV.second, UpdateToFullSet); if (Changed) { LLVM_DEBUG(dbgs() << "=== update [" << FS.UpdateCount << (UpdateToFullSet ? ", full-set" : "") << "] " << &FS << "\n"); // Callers of this function may need updating. for (auto &CallerID : Callers[Callee]) WorkList.insert(CallerID); ++FS.UpdateCount; } } template void StackSafetyDataFlowAnalysis::runDataFlow() { SmallVector Callees; for (auto &F : Functions) { Callees.clear(); auto &FS = F.second; for (auto &KV : FS.Params) for (auto &CS : KV.second.Calls) Callees.push_back(CS.first.Callee); llvm::sort(Callees); Callees.erase(std::unique(Callees.begin(), Callees.end()), Callees.end()); for (auto &Callee : Callees) Callers[Callee].push_back(F.first); } updateAllNodes(); while (!WorkList.empty()) { const CalleeTy *Callee = WorkList.pop_back_val(); updateOneNode(Callee); } } #ifndef NDEBUG template void StackSafetyDataFlowAnalysis::verifyFixedPoint() { WorkList.clear(); updateAllNodes(); assert(WorkList.empty()); } #endif template const typename StackSafetyDataFlowAnalysis::FunctionMap & StackSafetyDataFlowAnalysis::run() { runDataFlow(); LLVM_DEBUG(verifyFixedPoint()); return Functions; } FunctionSummary *findCalleeFunctionSummary(ValueInfo VI, StringRef ModuleId) { if (!VI) return nullptr; auto SummaryList = VI.getSummaryList(); GlobalValueSummary* S = nullptr; for (const auto& GVS : SummaryList) { if (!GVS->isLive()) continue; if (const AliasSummary *AS = dyn_cast(GVS.get())) if (!AS->hasAliasee()) continue; if (!isa(GVS->getBaseObject())) continue; if (GlobalValue::isLocalLinkage(GVS->linkage())) { if (GVS->modulePath() == ModuleId) { S = GVS.get(); break; } } else if (GlobalValue::isExternalLinkage(GVS->linkage())) { if (S) { ++NumIndexCalleeMultipleExternal; return nullptr; } S = GVS.get(); } else if (GlobalValue::isWeakLinkage(GVS->linkage())) { if (S) { ++NumIndexCalleeMultipleWeak; return nullptr; } S = GVS.get(); } else if (GlobalValue::isAvailableExternallyLinkage(GVS->linkage()) || GlobalValue::isLinkOnceLinkage(GVS->linkage())) { if (SummaryList.size() == 1) S = GVS.get(); // According thinLTOResolvePrevailingGUID these are unlikely prevailing. } else { ++NumIndexCalleeUnhandled; } }; while (S) { if (!S->isLive() || !S->isDSOLocal()) return nullptr; if (FunctionSummary *FS = dyn_cast(S)) return FS; AliasSummary *AS = dyn_cast(S); if (!AS || !AS->hasAliasee()) return nullptr; S = AS->getBaseObject(); if (S == AS) return nullptr; } return nullptr; } const Function *findCalleeInModule(const GlobalValue *GV) { while (GV) { if (GV->isDeclaration() || GV->isInterposable() || !GV->isDSOLocal()) return nullptr; if (const Function *F = dyn_cast(GV)) return F; const GlobalAlias *A = dyn_cast(GV); if (!A) return nullptr; GV = A->getAliaseeObject(); if (GV == A) return nullptr; } return nullptr; } const ConstantRange *findParamAccess(const FunctionSummary &FS, uint32_t ParamNo) { assert(FS.isLive()); assert(FS.isDSOLocal()); for (const auto &PS : FS.paramAccesses()) if (ParamNo == PS.ParamNo) return &PS.Use; return nullptr; } void resolveAllCalls(UseInfo &Use, const ModuleSummaryIndex *Index) { ConstantRange FullSet(Use.Range.getBitWidth(), true); // Move Use.Calls to a temp storage and repopulate - don't use std::move as it // leaves Use.Calls in an undefined state. UseInfo::CallsTy TmpCalls; std::swap(TmpCalls, Use.Calls); for (const auto &C : TmpCalls) { const Function *F = findCalleeInModule(C.first.Callee); if (F) { Use.Calls.emplace(CallInfo(F, C.first.ParamNo), C.second); continue; } if (!Index) return Use.updateRange(FullSet); FunctionSummary *FS = findCalleeFunctionSummary(Index->getValueInfo(C.first.Callee->getGUID()), C.first.Callee->getParent()->getModuleIdentifier()); ++NumModuleCalleeLookupTotal; if (!FS) { ++NumModuleCalleeLookupFailed; return Use.updateRange(FullSet); } const ConstantRange *Found = findParamAccess(*FS, C.first.ParamNo); if (!Found || Found->isFullSet()) return Use.updateRange(FullSet); ConstantRange Access = Found->sextOrTrunc(Use.Range.getBitWidth()); if (!Access.isEmptySet()) Use.updateRange(addOverflowNever(Access, C.second)); } } GVToSSI createGlobalStackSafetyInfo( std::map> Functions, const ModuleSummaryIndex *Index) { GVToSSI SSI; if (Functions.empty()) return SSI; // FIXME: Simplify printing and remove copying here. auto Copy = Functions; for (auto &FnKV : Copy) for (auto &KV : FnKV.second.Params) { resolveAllCalls(KV.second, Index); if (KV.second.Range.isFullSet()) KV.second.Calls.clear(); } uint32_t PointerSize = Copy.begin()->first->getParent()->getDataLayout().getPointerSizeInBits(); StackSafetyDataFlowAnalysis SSDFA(PointerSize, std::move(Copy)); for (const auto &F : SSDFA.run()) { auto FI = F.second; auto &SrcF = Functions[F.first]; for (auto &KV : FI.Allocas) { auto &A = KV.second; resolveAllCalls(A, Index); for (auto &C : A.Calls) { A.updateRange(SSDFA.getArgumentAccessRange(C.first.Callee, C.first.ParamNo, C.second)); } // FIXME: This is needed only to preserve calls in print() results. A.Calls = SrcF.Allocas.find(KV.first)->second.Calls; } for (auto &KV : FI.Params) { auto &P = KV.second; P.Calls = SrcF.Params.find(KV.first)->second.Calls; } SSI[F.first] = std::move(FI); } return SSI; } } // end anonymous namespace StackSafetyInfo::StackSafetyInfo() = default; StackSafetyInfo::StackSafetyInfo(Function *F, std::function GetSE) : F(F), GetSE(GetSE) {} StackSafetyInfo::StackSafetyInfo(StackSafetyInfo &&) = default; StackSafetyInfo &StackSafetyInfo::operator=(StackSafetyInfo &&) = default; StackSafetyInfo::~StackSafetyInfo() = default; const StackSafetyInfo::InfoTy &StackSafetyInfo::getInfo() const { if (!Info) { StackSafetyLocalAnalysis SSLA(*F, GetSE()); Info.reset(new InfoTy{SSLA.run()}); } return *Info; } void StackSafetyInfo::print(raw_ostream &O) const { getInfo().Info.print(O, F->getName(), dyn_cast(F)); O << "\n"; } const StackSafetyGlobalInfo::InfoTy &StackSafetyGlobalInfo::getInfo() const { if (!Info) { std::map> Functions; for (auto &F : M->functions()) { if (!F.isDeclaration()) { auto FI = GetSSI(F).getInfo().Info; Functions.emplace(&F, std::move(FI)); } } Info.reset(new InfoTy{ createGlobalStackSafetyInfo(std::move(Functions), Index), {}, {}}); for (auto &FnKV : Info->Info) { for (auto &KV : FnKV.second.Allocas) { ++NumAllocaTotal; const AllocaInst *AI = KV.first; auto AIRange = getStaticAllocaSizeRange(*AI); if (AIRange.contains(KV.second.Range)) { Info->SafeAllocas.insert(AI); ++NumAllocaStackSafe; } Info->UnsafeAccesses.insert(KV.second.UnsafeAccesses.begin(), KV.second.UnsafeAccesses.end()); } } if (StackSafetyPrint) print(errs()); } return *Info; } std::vector StackSafetyInfo::getParamAccesses(ModuleSummaryIndex &Index) const { // Implementation transforms internal representation of parameter information // into FunctionSummary format. std::vector ParamAccesses; for (const auto &KV : getInfo().Info.Params) { auto &PS = KV.second; // Parameter accessed by any or unknown offset, represented as FullSet by // StackSafety, is handled as the parameter for which we have no // StackSafety info at all. So drop it to reduce summary size. if (PS.Range.isFullSet()) continue; ParamAccesses.emplace_back(KV.first, PS.Range); FunctionSummary::ParamAccess &Param = ParamAccesses.back(); Param.Calls.reserve(PS.Calls.size()); for (const auto &C : PS.Calls) { // Parameter forwarded into another function by any or unknown offset // will make ParamAccess::Range as FullSet anyway. So we can drop the // entire parameter like we did above. // TODO(vitalybuka): Return already filtered parameters from getInfo(). if (C.second.isFullSet()) { ParamAccesses.pop_back(); break; } Param.Calls.emplace_back(C.first.ParamNo, Index.getOrInsertValueInfo(C.first.Callee), C.second); } } for (FunctionSummary::ParamAccess &Param : ParamAccesses) { sort(Param.Calls, [](const FunctionSummary::ParamAccess::Call &L, const FunctionSummary::ParamAccess::Call &R) { return std::tie(L.ParamNo, L.Callee) < std::tie(R.ParamNo, R.Callee); }); } return ParamAccesses; } StackSafetyGlobalInfo::StackSafetyGlobalInfo() = default; StackSafetyGlobalInfo::StackSafetyGlobalInfo( Module *M, std::function GetSSI, const ModuleSummaryIndex *Index) : M(M), GetSSI(GetSSI), Index(Index) { if (StackSafetyRun) getInfo(); } StackSafetyGlobalInfo::StackSafetyGlobalInfo(StackSafetyGlobalInfo &&) = default; StackSafetyGlobalInfo & StackSafetyGlobalInfo::operator=(StackSafetyGlobalInfo &&) = default; StackSafetyGlobalInfo::~StackSafetyGlobalInfo() = default; bool StackSafetyGlobalInfo::isSafe(const AllocaInst &AI) const { const auto &Info = getInfo(); return Info.SafeAllocas.count(&AI); } bool StackSafetyGlobalInfo::stackAccessIsSafe(const Instruction &I) const { const auto &Info = getInfo(); return Info.UnsafeAccesses.find(&I) == Info.UnsafeAccesses.end(); } void StackSafetyGlobalInfo::print(raw_ostream &O) const { auto &SSI = getInfo().Info; if (SSI.empty()) return; const Module &M = *SSI.begin()->first->getParent(); for (const auto &F : M.functions()) { if (!F.isDeclaration()) { SSI.find(&F)->second.print(O, F.getName(), &F); O << " safe accesses:" << "\n"; for (const auto &I : instructions(F)) { const CallInst *Call = dyn_cast(&I); if ((isa(I) || isa(I) || isa(I) || isa(I) || isa(I) || (Call && Call->hasByValArgument())) && stackAccessIsSafe(I)) { O << " " << I << "\n"; } } O << "\n"; } } } LLVM_DUMP_METHOD void StackSafetyGlobalInfo::dump() const { print(dbgs()); } AnalysisKey StackSafetyAnalysis::Key; StackSafetyInfo StackSafetyAnalysis::run(Function &F, FunctionAnalysisManager &AM) { return StackSafetyInfo(&F, [&AM, &F]() -> ScalarEvolution & { return AM.getResult(F); }); } PreservedAnalyses StackSafetyPrinterPass::run(Function &F, FunctionAnalysisManager &AM) { OS << "'Stack Safety Local Analysis' for function '" << F.getName() << "'\n"; AM.getResult(F).print(OS); return PreservedAnalyses::all(); } char StackSafetyInfoWrapperPass::ID = 0; StackSafetyInfoWrapperPass::StackSafetyInfoWrapperPass() : FunctionPass(ID) { initializeStackSafetyInfoWrapperPassPass(*PassRegistry::getPassRegistry()); } void StackSafetyInfoWrapperPass::getAnalysisUsage(AnalysisUsage &AU) const { AU.addRequiredTransitive(); AU.setPreservesAll(); } void StackSafetyInfoWrapperPass::print(raw_ostream &O, const Module *M) const { SSI.print(O); } bool StackSafetyInfoWrapperPass::runOnFunction(Function &F) { auto *SE = &getAnalysis().getSE(); SSI = {&F, [SE]() -> ScalarEvolution & { return *SE; }}; return false; } AnalysisKey StackSafetyGlobalAnalysis::Key; StackSafetyGlobalInfo StackSafetyGlobalAnalysis::run(Module &M, ModuleAnalysisManager &AM) { // FIXME: Lookup Module Summary. FunctionAnalysisManager &FAM = AM.getResult(M).getManager(); return {&M, [&FAM](Function &F) -> const StackSafetyInfo & { return FAM.getResult(F); }, nullptr}; } PreservedAnalyses StackSafetyGlobalPrinterPass::run(Module &M, ModuleAnalysisManager &AM) { OS << "'Stack Safety Analysis' for module '" << M.getName() << "'\n"; AM.getResult(M).print(OS); return PreservedAnalyses::all(); } char StackSafetyGlobalInfoWrapperPass::ID = 0; StackSafetyGlobalInfoWrapperPass::StackSafetyGlobalInfoWrapperPass() : ModulePass(ID) { initializeStackSafetyGlobalInfoWrapperPassPass( *PassRegistry::getPassRegistry()); } StackSafetyGlobalInfoWrapperPass::~StackSafetyGlobalInfoWrapperPass() = default; void StackSafetyGlobalInfoWrapperPass::print(raw_ostream &O, const Module *M) const { SSGI.print(O); } void StackSafetyGlobalInfoWrapperPass::getAnalysisUsage( AnalysisUsage &AU) const { AU.setPreservesAll(); AU.addRequired(); } bool StackSafetyGlobalInfoWrapperPass::runOnModule(Module &M) { const ModuleSummaryIndex *ImportSummary = nullptr; if (auto *IndexWrapperPass = getAnalysisIfAvailable()) ImportSummary = IndexWrapperPass->getIndex(); SSGI = {&M, [this](Function &F) -> const StackSafetyInfo & { return getAnalysis(F).getResult(); }, ImportSummary}; return false; } bool llvm::needsParamAccessSummary(const Module &M) { if (StackSafetyRun) return true; for (const auto &F : M.functions()) if (F.hasFnAttribute(Attribute::SanitizeMemTag)) return true; return false; } void llvm::generateParamAccessSummary(ModuleSummaryIndex &Index) { if (!Index.hasParamAccess()) return; const ConstantRange FullSet(FunctionSummary::ParamAccess::RangeWidth, true); auto CountParamAccesses = [&](auto &Stat) { if (!AreStatisticsEnabled()) return; for (auto &GVS : Index) for (auto &GV : GVS.second.SummaryList) if (FunctionSummary *FS = dyn_cast(GV.get())) Stat += FS->paramAccesses().size(); }; CountParamAccesses(NumCombinedParamAccessesBefore); std::map> Functions; // Convert the ModuleSummaryIndex to a FunctionMap for (auto &GVS : Index) { for (auto &GV : GVS.second.SummaryList) { FunctionSummary *FS = dyn_cast(GV.get()); if (!FS || FS->paramAccesses().empty()) continue; if (FS->isLive() && FS->isDSOLocal()) { FunctionInfo FI; for (const auto &PS : FS->paramAccesses()) { auto &US = FI.Params .emplace(PS.ParamNo, FunctionSummary::ParamAccess::RangeWidth) .first->second; US.Range = PS.Use; for (const auto &Call : PS.Calls) { assert(!Call.Offsets.isFullSet()); FunctionSummary *S = findCalleeFunctionSummary(Call.Callee, FS->modulePath()); ++NumCombinedCalleeLookupTotal; if (!S) { ++NumCombinedCalleeLookupFailed; US.Range = FullSet; US.Calls.clear(); break; } US.Calls.emplace(CallInfo(S, Call.ParamNo), Call.Offsets); } } Functions.emplace(FS, std::move(FI)); } // Reset data for all summaries. Alive and DSO local will be set back from // of data flow results below. Anything else will not be accessed // by ThinLTO backend, so we can save on bitcode size. FS->setParamAccesses({}); } } NumCombinedDataFlowNodes += Functions.size(); StackSafetyDataFlowAnalysis SSDFA( FunctionSummary::ParamAccess::RangeWidth, std::move(Functions)); for (const auto &KV : SSDFA.run()) { std::vector NewParams; NewParams.reserve(KV.second.Params.size()); for (const auto &Param : KV.second.Params) { // It's not needed as FullSet is processed the same as a missing value. if (Param.second.Range.isFullSet()) continue; NewParams.emplace_back(); FunctionSummary::ParamAccess &New = NewParams.back(); New.ParamNo = Param.first; New.Use = Param.second.Range; // Only range is needed. } const_cast(KV.first)->setParamAccesses( std::move(NewParams)); } CountParamAccesses(NumCombinedParamAccessesAfter); } static const char LocalPassArg[] = "stack-safety-local"; static const char LocalPassName[] = "Stack Safety Local Analysis"; INITIALIZE_PASS_BEGIN(StackSafetyInfoWrapperPass, LocalPassArg, LocalPassName, false, true) INITIALIZE_PASS_DEPENDENCY(ScalarEvolutionWrapperPass) INITIALIZE_PASS_END(StackSafetyInfoWrapperPass, LocalPassArg, LocalPassName, false, true) static const char GlobalPassName[] = "Stack Safety Analysis"; INITIALIZE_PASS_BEGIN(StackSafetyGlobalInfoWrapperPass, DEBUG_TYPE, GlobalPassName, false, true) INITIALIZE_PASS_DEPENDENCY(StackSafetyInfoWrapperPass) INITIALIZE_PASS_DEPENDENCY(ImmutableModuleSummaryIndexWrapperPass) INITIALIZE_PASS_END(StackSafetyGlobalInfoWrapperPass, DEBUG_TYPE, GlobalPassName, false, true)