//=== WebAssemblyLowerEmscriptenEHSjLj.cpp - Lower exceptions for Emscripten =// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// /// /// \file /// This file lowers exception-related instructions and setjmp/longjmp /// function calls in order to use Emscripten's JavaScript try and catch /// mechanism. /// /// To handle exceptions and setjmp/longjmps, this scheme relies on JavaScript's /// try and catch syntax and relevant exception-related libraries implemented /// in JavaScript glue code that will be produced by Emscripten. This is similar /// to the current Emscripten asm.js exception handling in fastcomp. For /// fastcomp's EH / SjLj scheme, see these files in fastcomp LLVM branch: /// (Location: https://github.com/kripken/emscripten-fastcomp) /// lib/Target/JSBackend/NaCl/LowerEmExceptionsPass.cpp /// lib/Target/JSBackend/NaCl/LowerEmSetjmp.cpp /// lib/Target/JSBackend/JSBackend.cpp /// lib/Target/JSBackend/CallHandlers.h /// /// * Exception handling /// This pass lowers invokes and landingpads into library functions in JS glue /// code. Invokes are lowered into function wrappers called invoke wrappers that /// exist in JS side, which wraps the original function call with JS try-catch. /// If an exception occurred, cxa_throw() function in JS side sets some /// variables (see below) so we can check whether an exception occurred from /// wasm code and handle it appropriately. /// /// * Setjmp-longjmp handling /// This pass lowers setjmp to a reasonably-performant approach for emscripten. /// The idea is that each block with a setjmp is broken up into two parts: the /// part containing setjmp and the part right after the setjmp. The latter part /// is either reached from the setjmp, or later from a longjmp. To handle the /// longjmp, all calls that might longjmp are also called using invoke wrappers /// and thus JS / try-catch. JS longjmp() function also sets some variables so /// we can check / whether a longjmp occurred from wasm code. Each block with a /// function call that might longjmp is also split up after the longjmp call. /// After the longjmp call, we check whether a longjmp occurred, and if it did, /// which setjmp it corresponds to, and jump to the right post-setjmp block. /// We assume setjmp-longjmp handling always run after EH handling, which means /// we don't expect any exception-related instructions when SjLj runs. /// FIXME Currently this scheme does not support indirect call of setjmp, /// because of the limitation of the scheme itself. fastcomp does not support it /// either. /// /// In detail, this pass does following things: /// /// 1) Assumes the existence of global variables: __THREW__, __threwValue /// __THREW__ and __threwValue will be set in invoke wrappers /// in JS glue code. For what invoke wrappers are, refer to 3). These /// variables are used for both exceptions and setjmp/longjmps. /// __THREW__ indicates whether an exception or a longjmp occurred or not. 0 /// means nothing occurred, 1 means an exception occurred, and other numbers /// mean a longjmp occurred. In the case of longjmp, __threwValue variable /// indicates the corresponding setjmp buffer the longjmp corresponds to. /// /// * Exception handling /// /// 2) We assume the existence of setThrew and setTempRet0/getTempRet0 functions /// at link time. /// The global variables in 1) will exist in wasm address space, /// but their values should be set in JS code, so these functions /// as interfaces to JS glue code. These functions are equivalent to the /// following JS functions, which actually exist in asm.js version of JS /// library. /// /// function setThrew(threw, value) { /// if (__THREW__ == 0) { /// __THREW__ = threw; /// __threwValue = value; /// } /// } // /// setTempRet0 is called from __cxa_find_matching_catch() in JS glue code. /// /// In exception handling, getTempRet0 indicates the type of an exception /// caught, and in setjmp/longjmp, it means the second argument to longjmp /// function. /// /// 3) Lower /// invoke @func(arg1, arg2) to label %invoke.cont unwind label %lpad /// into /// __THREW__ = 0; /// call @__invoke_SIG(func, arg1, arg2) /// %__THREW__.val = __THREW__; /// __THREW__ = 0; /// if (%__THREW__.val == 1) /// goto %lpad /// else /// goto %invoke.cont /// SIG is a mangled string generated based on the LLVM IR-level function /// signature. After LLVM IR types are lowered to the target wasm types, /// the names for these wrappers will change based on wasm types as well, /// as in invoke_vi (function takes an int and returns void). The bodies of /// these wrappers will be generated in JS glue code, and inside those /// wrappers we use JS try-catch to generate actual exception effects. It /// also calls the original callee function. An example wrapper in JS code /// would look like this: /// function invoke_vi(index,a1) { /// try { /// Module["dynCall_vi"](index,a1); // This calls original callee /// } catch(e) { /// if (typeof e !== 'number' && e !== 'longjmp') throw e; /// asm["setThrew"](1, 0); // setThrew is called here /// } /// } /// If an exception is thrown, __THREW__ will be set to true in a wrapper, /// so we can jump to the right BB based on this value. /// /// 4) Lower /// %val = landingpad catch c1 catch c2 catch c3 ... /// ... use %val ... /// into /// %fmc = call @__cxa_find_matching_catch_N(c1, c2, c3, ...) /// %val = {%fmc, getTempRet0()} /// ... use %val ... /// Here N is a number calculated based on the number of clauses. /// setTempRet0 is called from __cxa_find_matching_catch() in JS glue code. /// /// 5) Lower /// resume {%a, %b} /// into /// call @__resumeException(%a) /// where __resumeException() is a function in JS glue code. /// /// 6) Lower /// call @llvm.eh.typeid.for(type) (intrinsic) /// into /// call @llvm_eh_typeid_for(type) /// llvm_eh_typeid_for function will be generated in JS glue code. /// /// * Setjmp / Longjmp handling /// /// In case calls to longjmp() exists /// /// 1) Lower /// longjmp(buf, value) /// into /// emscripten_longjmp_jmpbuf(buf, value) /// emscripten_longjmp_jmpbuf will be lowered to emscripten_longjmp later. /// /// In case calls to setjmp() exists /// /// 2) In the function entry that calls setjmp, initialize setjmpTable and /// sejmpTableSize as follows: /// setjmpTableSize = 4; /// setjmpTable = (int *) malloc(40); /// setjmpTable[0] = 0; /// setjmpTable and setjmpTableSize are used in saveSetjmp() function in JS /// code. /// /// 3) Lower /// setjmp(buf) /// into /// setjmpTable = saveSetjmp(buf, label, setjmpTable, setjmpTableSize); /// setjmpTableSize = getTempRet0(); /// For each dynamic setjmp call, setjmpTable stores its ID (a number which /// is incrementally assigned from 0) and its label (a unique number that /// represents each callsite of setjmp). When we need more entries in /// setjmpTable, it is reallocated in saveSetjmp() in JS code and it will /// return the new table address, and assign the new table size in /// setTempRet0(). saveSetjmp also stores the setjmp's ID into the buffer /// buf. A BB with setjmp is split into two after setjmp call in order to /// make the post-setjmp BB the possible destination of longjmp BB. /// /// /// 4) Lower every call that might longjmp into /// __THREW__ = 0; /// call @__invoke_SIG(func, arg1, arg2) /// %__THREW__.val = __THREW__; /// __THREW__ = 0; /// if (%__THREW__.val != 0 & __threwValue != 0) { /// %label = testSetjmp(mem[%__THREW__.val], setjmpTable, /// setjmpTableSize); /// if (%label == 0) /// emscripten_longjmp(%__THREW__.val, __threwValue); /// setTempRet0(__threwValue); /// } else { /// %label = -1; /// } /// longjmp_result = getTempRet0(); /// switch label { /// label 1: goto post-setjmp BB 1 /// label 2: goto post-setjmp BB 2 /// ... /// default: goto splitted next BB /// } /// testSetjmp examines setjmpTable to see if there is a matching setjmp /// call. After calling an invoke wrapper, if a longjmp occurred, __THREW__ /// will be the address of matching jmp_buf buffer and __threwValue be the /// second argument to longjmp. mem[__THREW__.val] is a setjmp ID that is /// stored in saveSetjmp. testSetjmp returns a setjmp label, a unique ID to /// each setjmp callsite. Label 0 means this longjmp buffer does not /// correspond to one of the setjmp callsites in this function, so in this /// case we just chain the longjmp to the caller. (Here we call /// emscripten_longjmp, which is different from emscripten_longjmp_jmpbuf. /// emscripten_longjmp_jmpbuf takes jmp_buf as its first argument, while /// emscripten_longjmp takes an int. Both of them will eventually be lowered /// to emscripten_longjmp in s2wasm, but here we need two signatures - we /// can't translate an int value to a jmp_buf.) /// Label -1 means no longjmp occurred. Otherwise we jump to the right /// post-setjmp BB based on the label. /// ///===----------------------------------------------------------------------===// #include "WebAssembly.h" #include "llvm/IR/CallSite.h" #include "llvm/IR/Dominators.h" #include "llvm/IR/IRBuilder.h" #include "llvm/Transforms/Utils/BasicBlockUtils.h" #include "llvm/Transforms/Utils/SSAUpdater.h" using namespace llvm; #define DEBUG_TYPE "wasm-lower-em-ehsjlj" static cl::list EHWhitelist("emscripten-cxx-exceptions-whitelist", cl::desc("The list of function names in which Emscripten-style " "exception handling is enabled (see emscripten " "EMSCRIPTEN_CATCHING_WHITELIST options)"), cl::CommaSeparated); namespace { class WebAssemblyLowerEmscriptenEHSjLj final : public ModulePass { static const char *ResumeFName; static const char *EHTypeIDFName; static const char *EmLongjmpFName; static const char *EmLongjmpJmpbufFName; static const char *SaveSetjmpFName; static const char *TestSetjmpFName; static const char *FindMatchingCatchPrefix; static const char *InvokePrefix; bool EnableEH; // Enable exception handling bool EnableSjLj; // Enable setjmp/longjmp handling GlobalVariable *ThrewGV; GlobalVariable *ThrewValueGV; Function *GetTempRet0Func; Function *SetTempRet0Func; Function *ResumeF; Function *EHTypeIDF; Function *EmLongjmpF; Function *EmLongjmpJmpbufF; Function *SaveSetjmpF; Function *TestSetjmpF; // __cxa_find_matching_catch_N functions. // Indexed by the number of clauses in an original landingpad instruction. DenseMap FindMatchingCatches; // Map of StringMap InvokeWrappers; // Set of whitelisted function names for exception handling std::set EHWhitelistSet; StringRef getPassName() const override { return "WebAssembly Lower Emscripten Exceptions"; } bool runEHOnFunction(Function &F); bool runSjLjOnFunction(Function &F); Function *getFindMatchingCatch(Module &M, unsigned NumClauses); template Value *wrapInvoke(CallOrInvoke *CI); void wrapTestSetjmp(BasicBlock *BB, Instruction *InsertPt, Value *Threw, Value *SetjmpTable, Value *SetjmpTableSize, Value *&Label, Value *&LongjmpResult, BasicBlock *&EndBB); template Function *getInvokeWrapper(CallOrInvoke *CI); bool areAllExceptionsAllowed() const { return EHWhitelistSet.empty(); } bool canLongjmp(Module &M, const Value *Callee) const; void rebuildSSA(Function &F); public: static char ID; WebAssemblyLowerEmscriptenEHSjLj(bool EnableEH = true, bool EnableSjLj = true) : ModulePass(ID), EnableEH(EnableEH), EnableSjLj(EnableSjLj), ThrewGV(nullptr), ThrewValueGV(nullptr), GetTempRet0Func(nullptr), SetTempRet0Func(nullptr), ResumeF(nullptr), EHTypeIDF(nullptr), EmLongjmpF(nullptr), EmLongjmpJmpbufF(nullptr), SaveSetjmpF(nullptr), TestSetjmpF(nullptr) { EHWhitelistSet.insert(EHWhitelist.begin(), EHWhitelist.end()); } bool runOnModule(Module &M) override; void getAnalysisUsage(AnalysisUsage &AU) const override { AU.addRequired(); } }; } // End anonymous namespace const char *WebAssemblyLowerEmscriptenEHSjLj::ResumeFName = "__resumeException"; const char *WebAssemblyLowerEmscriptenEHSjLj::EHTypeIDFName = "llvm_eh_typeid_for"; const char *WebAssemblyLowerEmscriptenEHSjLj::EmLongjmpFName = "emscripten_longjmp"; const char *WebAssemblyLowerEmscriptenEHSjLj::EmLongjmpJmpbufFName = "emscripten_longjmp_jmpbuf"; const char *WebAssemblyLowerEmscriptenEHSjLj::SaveSetjmpFName = "saveSetjmp"; const char *WebAssemblyLowerEmscriptenEHSjLj::TestSetjmpFName = "testSetjmp"; const char *WebAssemblyLowerEmscriptenEHSjLj::FindMatchingCatchPrefix = "__cxa_find_matching_catch_"; const char *WebAssemblyLowerEmscriptenEHSjLj::InvokePrefix = "__invoke_"; char WebAssemblyLowerEmscriptenEHSjLj::ID = 0; INITIALIZE_PASS(WebAssemblyLowerEmscriptenEHSjLj, DEBUG_TYPE, "WebAssembly Lower Emscripten Exceptions / Setjmp / Longjmp", false, false) ModulePass *llvm::createWebAssemblyLowerEmscriptenEHSjLj(bool EnableEH, bool EnableSjLj) { return new WebAssemblyLowerEmscriptenEHSjLj(EnableEH, EnableSjLj); } static bool canThrow(const Value *V) { if (const auto *F = dyn_cast(V)) { // Intrinsics cannot throw if (F->isIntrinsic()) return false; StringRef Name = F->getName(); // leave setjmp and longjmp (mostly) alone, we process them properly later if (Name == "setjmp" || Name == "longjmp") return false; return !F->doesNotThrow(); } // not a function, so an indirect call - can throw, we can't tell return true; } // Get a global variable with the given name. If it doesn't exist declare it, // which will generate an import and asssumes that it will exist at link time. static GlobalVariable *getGlobalVariableI32(Module &M, IRBuilder<> &IRB, const char *Name) { if (M.getNamedGlobal(Name)) report_fatal_error(Twine("variable name is reserved: ") + Name); return new GlobalVariable(M, IRB.getInt32Ty(), false, GlobalValue::ExternalLinkage, nullptr, Name); } // Simple function name mangler. // This function simply takes LLVM's string representation of parameter types // and concatenate them with '_'. There are non-alphanumeric characters but llc // is ok with it, and we need to postprocess these names after the lowering // phase anyway. static std::string getSignature(FunctionType *FTy) { std::string Sig; raw_string_ostream OS(Sig); OS << *FTy->getReturnType(); for (Type *ParamTy : FTy->params()) OS << "_" << *ParamTy; if (FTy->isVarArg()) OS << "_..."; Sig = OS.str(); Sig.erase(remove_if(Sig, isspace), Sig.end()); // When s2wasm parses .s file, a comma means the end of an argument. So a // mangled function name can contain any character but a comma. std::replace(Sig.begin(), Sig.end(), ',', '.'); return Sig; } // Returns __cxa_find_matching_catch_N function, where N = NumClauses + 2. // This is because a landingpad instruction contains two more arguments, a // personality function and a cleanup bit, and __cxa_find_matching_catch_N // functions are named after the number of arguments in the original landingpad // instruction. Function * WebAssemblyLowerEmscriptenEHSjLj::getFindMatchingCatch(Module &M, unsigned NumClauses) { if (FindMatchingCatches.count(NumClauses)) return FindMatchingCatches[NumClauses]; PointerType *Int8PtrTy = Type::getInt8PtrTy(M.getContext()); SmallVector Args(NumClauses, Int8PtrTy); FunctionType *FTy = FunctionType::get(Int8PtrTy, Args, false); Function *F = Function::Create(FTy, GlobalValue::ExternalLinkage, FindMatchingCatchPrefix + Twine(NumClauses + 2), &M); FindMatchingCatches[NumClauses] = F; return F; } // Generate invoke wrapper seqence with preamble and postamble // Preamble: // __THREW__ = 0; // Postamble: // %__THREW__.val = __THREW__; __THREW__ = 0; // Returns %__THREW__.val, which indicates whether an exception is thrown (or // whether longjmp occurred), for future use. template Value *WebAssemblyLowerEmscriptenEHSjLj::wrapInvoke(CallOrInvoke *CI) { LLVMContext &C = CI->getModule()->getContext(); // If we are calling a function that is noreturn, we must remove that // attribute. The code we insert here does expect it to return, after we // catch the exception. if (CI->doesNotReturn()) { if (auto *F = dyn_cast(CI->getCalledValue())) F->removeFnAttr(Attribute::NoReturn); CI->removeAttribute(AttributeList::FunctionIndex, Attribute::NoReturn); } IRBuilder<> IRB(C); IRB.SetInsertPoint(CI); // Pre-invoke // __THREW__ = 0; IRB.CreateStore(IRB.getInt32(0), ThrewGV); // Invoke function wrapper in JavaScript SmallVector Args; // Put the pointer to the callee as first argument, so it can be called // within the invoke wrapper later Args.push_back(CI->getCalledValue()); Args.append(CI->arg_begin(), CI->arg_end()); CallInst *NewCall = IRB.CreateCall(getInvokeWrapper(CI), Args); NewCall->takeName(CI); NewCall->setCallingConv(CI->getCallingConv()); NewCall->setDebugLoc(CI->getDebugLoc()); // Because we added the pointer to the callee as first argument, all // argument attribute indices have to be incremented by one. SmallVector ArgAttributes; const AttributeList &InvokeAL = CI->getAttributes(); // No attributes for the callee pointer. ArgAttributes.push_back(AttributeSet()); // Copy the argument attributes from the original for (unsigned i = 0, e = CI->getNumArgOperands(); i < e; ++i) ArgAttributes.push_back(InvokeAL.getParamAttributes(i)); // Reconstruct the AttributesList based on the vector we constructed. AttributeList NewCallAL = AttributeList::get(C, InvokeAL.getFnAttributes(), InvokeAL.getRetAttributes(), ArgAttributes); NewCall->setAttributes(NewCallAL); CI->replaceAllUsesWith(NewCall); // Post-invoke // %__THREW__.val = __THREW__; __THREW__ = 0; Value *Threw = IRB.CreateLoad(ThrewGV, ThrewGV->getName() + ".val"); IRB.CreateStore(IRB.getInt32(0), ThrewGV); return Threw; } // Get matching invoke wrapper based on callee signature template Function *WebAssemblyLowerEmscriptenEHSjLj::getInvokeWrapper(CallOrInvoke *CI) { Module *M = CI->getModule(); SmallVector ArgTys; Value *Callee = CI->getCalledValue(); FunctionType *CalleeFTy; if (auto *F = dyn_cast(Callee)) CalleeFTy = F->getFunctionType(); else { auto *CalleeTy = cast(Callee->getType())->getElementType(); CalleeFTy = dyn_cast(CalleeTy); } std::string Sig = getSignature(CalleeFTy); if (InvokeWrappers.find(Sig) != InvokeWrappers.end()) return InvokeWrappers[Sig]; // Put the pointer to the callee as first argument ArgTys.push_back(PointerType::getUnqual(CalleeFTy)); // Add argument types ArgTys.append(CalleeFTy->param_begin(), CalleeFTy->param_end()); FunctionType *FTy = FunctionType::get(CalleeFTy->getReturnType(), ArgTys, CalleeFTy->isVarArg()); Function *F = Function::Create(FTy, GlobalValue::ExternalLinkage, InvokePrefix + Sig, M); InvokeWrappers[Sig] = F; return F; } bool WebAssemblyLowerEmscriptenEHSjLj::canLongjmp(Module &M, const Value *Callee) const { if (auto *CalleeF = dyn_cast(Callee)) if (CalleeF->isIntrinsic()) return false; // The reason we include malloc/free here is to exclude the malloc/free // calls generated in setjmp prep / cleanup routines. Function *SetjmpF = M.getFunction("setjmp"); Function *MallocF = M.getFunction("malloc"); Function *FreeF = M.getFunction("free"); if (Callee == SetjmpF || Callee == MallocF || Callee == FreeF) return false; // There are functions in JS glue code if (Callee == ResumeF || Callee == EHTypeIDF || Callee == SaveSetjmpF || Callee == TestSetjmpF) return false; // __cxa_find_matching_catch_N functions cannot longjmp if (Callee->getName().startswith(FindMatchingCatchPrefix)) return false; // Exception-catching related functions Function *BeginCatchF = M.getFunction("__cxa_begin_catch"); Function *EndCatchF = M.getFunction("__cxa_end_catch"); Function *AllocExceptionF = M.getFunction("__cxa_allocate_exception"); Function *ThrowF = M.getFunction("__cxa_throw"); Function *TerminateF = M.getFunction("__clang_call_terminate"); if (Callee == BeginCatchF || Callee == EndCatchF || Callee == AllocExceptionF || Callee == ThrowF || Callee == TerminateF || Callee == GetTempRet0Func || Callee == SetTempRet0Func) return false; // Otherwise we don't know return true; } // Generate testSetjmp function call seqence with preamble and postamble. // The code this generates is equivalent to the following JavaScript code: // if (%__THREW__.val != 0 & threwValue != 0) { // %label = _testSetjmp(mem[%__THREW__.val], setjmpTable, setjmpTableSize); // if (%label == 0) // emscripten_longjmp(%__THREW__.val, threwValue); // setTempRet0(threwValue); // } else { // %label = -1; // } // %longjmp_result = getTempRet0(); // // As output parameters. returns %label, %longjmp_result, and the BB the last // instruction (%longjmp_result = ...) is in. void WebAssemblyLowerEmscriptenEHSjLj::wrapTestSetjmp( BasicBlock *BB, Instruction *InsertPt, Value *Threw, Value *SetjmpTable, Value *SetjmpTableSize, Value *&Label, Value *&LongjmpResult, BasicBlock *&EndBB) { Function *F = BB->getParent(); LLVMContext &C = BB->getModule()->getContext(); IRBuilder<> IRB(C); IRB.SetInsertPoint(InsertPt); // if (%__THREW__.val != 0 & threwValue != 0) IRB.SetInsertPoint(BB); BasicBlock *ThenBB1 = BasicBlock::Create(C, "if.then1", F); BasicBlock *ElseBB1 = BasicBlock::Create(C, "if.else1", F); BasicBlock *EndBB1 = BasicBlock::Create(C, "if.end", F); Value *ThrewCmp = IRB.CreateICmpNE(Threw, IRB.getInt32(0)); Value *ThrewValue = IRB.CreateLoad(ThrewValueGV, ThrewValueGV->getName() + ".val"); Value *ThrewValueCmp = IRB.CreateICmpNE(ThrewValue, IRB.getInt32(0)); Value *Cmp1 = IRB.CreateAnd(ThrewCmp, ThrewValueCmp, "cmp1"); IRB.CreateCondBr(Cmp1, ThenBB1, ElseBB1); // %label = _testSetjmp(mem[%__THREW__.val], _setjmpTable, _setjmpTableSize); // if (%label == 0) IRB.SetInsertPoint(ThenBB1); BasicBlock *ThenBB2 = BasicBlock::Create(C, "if.then2", F); BasicBlock *EndBB2 = BasicBlock::Create(C, "if.end2", F); Value *ThrewInt = IRB.CreateIntToPtr(Threw, Type::getInt32PtrTy(C), Threw->getName() + ".i32p"); Value *LoadedThrew = IRB.CreateLoad(ThrewInt, ThrewInt->getName() + ".loaded"); Value *ThenLabel = IRB.CreateCall( TestSetjmpF, {LoadedThrew, SetjmpTable, SetjmpTableSize}, "label"); Value *Cmp2 = IRB.CreateICmpEQ(ThenLabel, IRB.getInt32(0)); IRB.CreateCondBr(Cmp2, ThenBB2, EndBB2); // emscripten_longjmp(%__THREW__.val, threwValue); IRB.SetInsertPoint(ThenBB2); IRB.CreateCall(EmLongjmpF, {Threw, ThrewValue}); IRB.CreateUnreachable(); // setTempRet0(threwValue); IRB.SetInsertPoint(EndBB2); IRB.CreateCall(SetTempRet0Func, ThrewValue); IRB.CreateBr(EndBB1); IRB.SetInsertPoint(ElseBB1); IRB.CreateBr(EndBB1); // longjmp_result = getTempRet0(); IRB.SetInsertPoint(EndBB1); PHINode *LabelPHI = IRB.CreatePHI(IRB.getInt32Ty(), 2, "label"); LabelPHI->addIncoming(ThenLabel, EndBB2); LabelPHI->addIncoming(IRB.getInt32(-1), ElseBB1); // Output parameter assignment Label = LabelPHI; EndBB = EndBB1; LongjmpResult = IRB.CreateCall(GetTempRet0Func, None, "longjmp_result"); } void WebAssemblyLowerEmscriptenEHSjLj::rebuildSSA(Function &F) { DominatorTree &DT = getAnalysis(F).getDomTree(); DT.recalculate(F); // CFG has been changed SSAUpdater SSA; for (BasicBlock &BB : F) { for (Instruction &I : BB) { for (auto UI = I.use_begin(), UE = I.use_end(); UI != UE;) { Use &U = *UI; ++UI; SSA.Initialize(I.getType(), I.getName()); SSA.AddAvailableValue(&BB, &I); Instruction *User = cast(U.getUser()); if (User->getParent() == &BB) continue; if (PHINode *UserPN = dyn_cast(User)) if (UserPN->getIncomingBlock(U) == &BB) continue; if (DT.dominates(&I, User)) continue; SSA.RewriteUseAfterInsertions(U); } } } } bool WebAssemblyLowerEmscriptenEHSjLj::runOnModule(Module &M) { LLVM_DEBUG(dbgs() << "********** Lower Emscripten EH & SjLj **********\n"); LLVMContext &C = M.getContext(); IRBuilder<> IRB(C); Function *SetjmpF = M.getFunction("setjmp"); Function *LongjmpF = M.getFunction("longjmp"); bool SetjmpUsed = SetjmpF && !SetjmpF->use_empty(); bool LongjmpUsed = LongjmpF && !LongjmpF->use_empty(); bool DoSjLj = EnableSjLj && (SetjmpUsed || LongjmpUsed); // Declare (or get) global variables __THREW__, __threwValue, and // getTempRet0/setTempRet0 function which are used in common for both // exception handling and setjmp/longjmp handling ThrewGV = getGlobalVariableI32(M, IRB, "__THREW__"); ThrewValueGV = getGlobalVariableI32(M, IRB, "__threwValue"); GetTempRet0Func = Function::Create(FunctionType::get(IRB.getInt32Ty(), false), GlobalValue::ExternalLinkage, "getTempRet0", &M); SetTempRet0Func = Function::Create( FunctionType::get(IRB.getVoidTy(), IRB.getInt32Ty(), false), GlobalValue::ExternalLinkage, "setTempRet0", &M); GetTempRet0Func->setDoesNotThrow(); SetTempRet0Func->setDoesNotThrow(); bool Changed = false; // Exception handling if (EnableEH) { // Register __resumeException function FunctionType *ResumeFTy = FunctionType::get(IRB.getVoidTy(), IRB.getInt8PtrTy(), false); ResumeF = Function::Create(ResumeFTy, GlobalValue::ExternalLinkage, ResumeFName, &M); // Register llvm_eh_typeid_for function FunctionType *EHTypeIDTy = FunctionType::get(IRB.getInt32Ty(), IRB.getInt8PtrTy(), false); EHTypeIDF = Function::Create(EHTypeIDTy, GlobalValue::ExternalLinkage, EHTypeIDFName, &M); for (Function &F : M) { if (F.isDeclaration()) continue; Changed |= runEHOnFunction(F); } } // Setjmp/longjmp handling if (DoSjLj) { Changed = true; // We have setjmp or longjmp somewhere if (LongjmpF) { // Replace all uses of longjmp with emscripten_longjmp_jmpbuf, which is // defined in JS code EmLongjmpJmpbufF = Function::Create(LongjmpF->getFunctionType(), GlobalValue::ExternalLinkage, EmLongjmpJmpbufFName, &M); LongjmpF->replaceAllUsesWith(EmLongjmpJmpbufF); } if (SetjmpF) { // Register saveSetjmp function FunctionType *SetjmpFTy = SetjmpF->getFunctionType(); SmallVector Params = {SetjmpFTy->getParamType(0), IRB.getInt32Ty(), Type::getInt32PtrTy(C), IRB.getInt32Ty()}; FunctionType *FTy = FunctionType::get(Type::getInt32PtrTy(C), Params, false); SaveSetjmpF = Function::Create(FTy, GlobalValue::ExternalLinkage, SaveSetjmpFName, &M); // Register testSetjmp function Params = {IRB.getInt32Ty(), Type::getInt32PtrTy(C), IRB.getInt32Ty()}; FTy = FunctionType::get(IRB.getInt32Ty(), Params, false); TestSetjmpF = Function::Create(FTy, GlobalValue::ExternalLinkage, TestSetjmpFName, &M); FTy = FunctionType::get(IRB.getVoidTy(), {IRB.getInt32Ty(), IRB.getInt32Ty()}, false); EmLongjmpF = Function::Create(FTy, GlobalValue::ExternalLinkage, EmLongjmpFName, &M); // Only traverse functions that uses setjmp in order not to insert // unnecessary prep / cleanup code in every function SmallPtrSet SetjmpUsers; for (User *U : SetjmpF->users()) { auto *UI = cast(U); SetjmpUsers.insert(UI->getFunction()); } for (Function *F : SetjmpUsers) runSjLjOnFunction(*F); } } if (!Changed) { // Delete unused global variables and functions if (ResumeF) ResumeF->eraseFromParent(); if (EHTypeIDF) EHTypeIDF->eraseFromParent(); if (EmLongjmpF) EmLongjmpF->eraseFromParent(); if (SaveSetjmpF) SaveSetjmpF->eraseFromParent(); if (TestSetjmpF) TestSetjmpF->eraseFromParent(); return false; } return true; } bool WebAssemblyLowerEmscriptenEHSjLj::runEHOnFunction(Function &F) { Module &M = *F.getParent(); LLVMContext &C = F.getContext(); IRBuilder<> IRB(C); bool Changed = false; SmallVector ToErase; SmallPtrSet LandingPads; bool AllowExceptions = areAllExceptionsAllowed() || EHWhitelistSet.count(F.getName()); for (BasicBlock &BB : F) { auto *II = dyn_cast(BB.getTerminator()); if (!II) continue; Changed = true; LandingPads.insert(II->getLandingPadInst()); IRB.SetInsertPoint(II); bool NeedInvoke = AllowExceptions && canThrow(II->getCalledValue()); if (NeedInvoke) { // Wrap invoke with invoke wrapper and generate preamble/postamble Value *Threw = wrapInvoke(II); ToErase.push_back(II); // Insert a branch based on __THREW__ variable Value *Cmp = IRB.CreateICmpEQ(Threw, IRB.getInt32(1), "cmp"); IRB.CreateCondBr(Cmp, II->getUnwindDest(), II->getNormalDest()); } else { // This can't throw, and we don't need this invoke, just replace it with a // call+branch SmallVector Args(II->arg_begin(), II->arg_end()); CallInst *NewCall = IRB.CreateCall(II->getCalledValue(), Args); NewCall->takeName(II); NewCall->setCallingConv(II->getCallingConv()); NewCall->setDebugLoc(II->getDebugLoc()); NewCall->setAttributes(II->getAttributes()); II->replaceAllUsesWith(NewCall); ToErase.push_back(II); IRB.CreateBr(II->getNormalDest()); // Remove any PHI node entries from the exception destination II->getUnwindDest()->removePredecessor(&BB); } } // Process resume instructions for (BasicBlock &BB : F) { // Scan the body of the basic block for resumes for (Instruction &I : BB) { auto *RI = dyn_cast(&I); if (!RI) continue; // Split the input into legal values Value *Input = RI->getValue(); IRB.SetInsertPoint(RI); Value *Low = IRB.CreateExtractValue(Input, 0, "low"); // Create a call to __resumeException function IRB.CreateCall(ResumeF, {Low}); // Add a terminator to the block IRB.CreateUnreachable(); ToErase.push_back(RI); } } // Process llvm.eh.typeid.for intrinsics for (BasicBlock &BB : F) { for (Instruction &I : BB) { auto *CI = dyn_cast(&I); if (!CI) continue; const Function *Callee = CI->getCalledFunction(); if (!Callee) continue; if (Callee->getIntrinsicID() != Intrinsic::eh_typeid_for) continue; IRB.SetInsertPoint(CI); CallInst *NewCI = IRB.CreateCall(EHTypeIDF, CI->getArgOperand(0), "typeid"); CI->replaceAllUsesWith(NewCI); ToErase.push_back(CI); } } // Look for orphan landingpads, can occur in blocks with no predecessors for (BasicBlock &BB : F) { Instruction *I = BB.getFirstNonPHI(); if (auto *LPI = dyn_cast(I)) LandingPads.insert(LPI); } // Handle all the landingpad for this function together, as multiple invokes // may share a single lp for (LandingPadInst *LPI : LandingPads) { IRB.SetInsertPoint(LPI); SmallVector FMCArgs; for (unsigned i = 0, e = LPI->getNumClauses(); i < e; ++i) { Constant *Clause = LPI->getClause(i); // As a temporary workaround for the lack of aggregate varargs support // in the interface between JS and wasm, break out filter operands into // their component elements. if (LPI->isFilter(i)) { auto *ATy = cast(Clause->getType()); for (unsigned j = 0, e = ATy->getNumElements(); j < e; ++j) { Value *EV = IRB.CreateExtractValue(Clause, makeArrayRef(j), "filter"); FMCArgs.push_back(EV); } } else FMCArgs.push_back(Clause); } // Create a call to __cxa_find_matching_catch_N function Function *FMCF = getFindMatchingCatch(M, FMCArgs.size()); CallInst *FMCI = IRB.CreateCall(FMCF, FMCArgs, "fmc"); Value *Undef = UndefValue::get(LPI->getType()); Value *Pair0 = IRB.CreateInsertValue(Undef, FMCI, 0, "pair0"); Value *TempRet0 = IRB.CreateCall(GetTempRet0Func, None, "tempret0"); Value *Pair1 = IRB.CreateInsertValue(Pair0, TempRet0, 1, "pair1"); LPI->replaceAllUsesWith(Pair1); ToErase.push_back(LPI); } // Erase everything we no longer need in this function for (Instruction *I : ToErase) I->eraseFromParent(); return Changed; } bool WebAssemblyLowerEmscriptenEHSjLj::runSjLjOnFunction(Function &F) { Module &M = *F.getParent(); LLVMContext &C = F.getContext(); IRBuilder<> IRB(C); SmallVector ToErase; // Vector of %setjmpTable values std::vector SetjmpTableInsts; // Vector of %setjmpTableSize values std::vector SetjmpTableSizeInsts; // Setjmp preparation // This instruction effectively means %setjmpTableSize = 4. // We create this as an instruction intentionally, and we don't want to fold // this instruction to a constant 4, because this value will be used in // SSAUpdater.AddAvailableValue(...) later. BasicBlock &EntryBB = F.getEntryBlock(); BinaryOperator *SetjmpTableSize = BinaryOperator::Create( Instruction::Add, IRB.getInt32(4), IRB.getInt32(0), "setjmpTableSize", &*EntryBB.getFirstInsertionPt()); // setjmpTable = (int *) malloc(40); Instruction *SetjmpTable = CallInst::CreateMalloc( SetjmpTableSize, IRB.getInt32Ty(), IRB.getInt32Ty(), IRB.getInt32(40), nullptr, nullptr, "setjmpTable"); // setjmpTable[0] = 0; IRB.SetInsertPoint(SetjmpTableSize); IRB.CreateStore(IRB.getInt32(0), SetjmpTable); SetjmpTableInsts.push_back(SetjmpTable); SetjmpTableSizeInsts.push_back(SetjmpTableSize); // Setjmp transformation std::vector SetjmpRetPHIs; Function *SetjmpF = M.getFunction("setjmp"); for (User *U : SetjmpF->users()) { auto *CI = dyn_cast(U); if (!CI) report_fatal_error("Does not support indirect calls to setjmp"); BasicBlock *BB = CI->getParent(); if (BB->getParent() != &F) // in other function continue; // The tail is everything right after the call, and will be reached once // when setjmp is called, and later when longjmp returns to the setjmp BasicBlock *Tail = SplitBlock(BB, CI->getNextNode()); // Add a phi to the tail, which will be the output of setjmp, which // indicates if this is the first call or a longjmp back. The phi directly // uses the right value based on where we arrive from IRB.SetInsertPoint(Tail->getFirstNonPHI()); PHINode *SetjmpRet = IRB.CreatePHI(IRB.getInt32Ty(), 2, "setjmp.ret"); // setjmp initial call returns 0 SetjmpRet->addIncoming(IRB.getInt32(0), BB); // The proper output is now this, not the setjmp call itself CI->replaceAllUsesWith(SetjmpRet); // longjmp returns to the setjmp will add themselves to this phi SetjmpRetPHIs.push_back(SetjmpRet); // Fix call target // Our index in the function is our place in the array + 1 to avoid index // 0, because index 0 means the longjmp is not ours to handle. IRB.SetInsertPoint(CI); Value *Args[] = {CI->getArgOperand(0), IRB.getInt32(SetjmpRetPHIs.size()), SetjmpTable, SetjmpTableSize}; Instruction *NewSetjmpTable = IRB.CreateCall(SaveSetjmpF, Args, "setjmpTable"); Instruction *NewSetjmpTableSize = IRB.CreateCall(GetTempRet0Func, None, "setjmpTableSize"); SetjmpTableInsts.push_back(NewSetjmpTable); SetjmpTableSizeInsts.push_back(NewSetjmpTableSize); ToErase.push_back(CI); } // Update each call that can longjmp so it can return to a setjmp where // relevant. // Because we are creating new BBs while processing and don't want to make // all these newly created BBs candidates again for longjmp processing, we // first make the vector of candidate BBs. std::vector BBs; for (BasicBlock &BB : F) BBs.push_back(&BB); // BBs.size() will change within the loop, so we query it every time for (unsigned i = 0; i < BBs.size(); i++) { BasicBlock *BB = BBs[i]; for (Instruction &I : *BB) { assert(!isa(&I)); auto *CI = dyn_cast(&I); if (!CI) continue; const Value *Callee = CI->getCalledValue(); if (!canLongjmp(M, Callee)) continue; Value *Threw = nullptr; BasicBlock *Tail; if (Callee->getName().startswith(InvokePrefix)) { // If invoke wrapper has already been generated for this call in // previous EH phase, search for the load instruction // %__THREW__.val = __THREW__; // in postamble after the invoke wrapper call LoadInst *ThrewLI = nullptr; StoreInst *ThrewResetSI = nullptr; for (auto I = std::next(BasicBlock::iterator(CI)), IE = BB->end(); I != IE; ++I) { if (auto *LI = dyn_cast(I)) if (auto *GV = dyn_cast(LI->getPointerOperand())) if (GV == ThrewGV) { Threw = ThrewLI = LI; break; } } // Search for the store instruction after the load above // __THREW__ = 0; for (auto I = std::next(BasicBlock::iterator(ThrewLI)), IE = BB->end(); I != IE; ++I) { if (auto *SI = dyn_cast(I)) if (auto *GV = dyn_cast(SI->getPointerOperand())) if (GV == ThrewGV && SI->getValueOperand() == IRB.getInt32(0)) { ThrewResetSI = SI; break; } } assert(Threw && ThrewLI && "Cannot find __THREW__ load after invoke"); assert(ThrewResetSI && "Cannot find __THREW__ store after invoke"); Tail = SplitBlock(BB, ThrewResetSI->getNextNode()); } else { // Wrap call with invoke wrapper and generate preamble/postamble Threw = wrapInvoke(CI); ToErase.push_back(CI); Tail = SplitBlock(BB, CI->getNextNode()); } // We need to replace the terminator in Tail - SplitBlock makes BB go // straight to Tail, we need to check if a longjmp occurred, and go to the // right setjmp-tail if so ToErase.push_back(BB->getTerminator()); // Generate a function call to testSetjmp function and preamble/postamble // code to figure out (1) whether longjmp occurred (2) if longjmp // occurred, which setjmp it corresponds to Value *Label = nullptr; Value *LongjmpResult = nullptr; BasicBlock *EndBB = nullptr; wrapTestSetjmp(BB, CI, Threw, SetjmpTable, SetjmpTableSize, Label, LongjmpResult, EndBB); assert(Label && LongjmpResult && EndBB); // Create switch instruction IRB.SetInsertPoint(EndBB); SwitchInst *SI = IRB.CreateSwitch(Label, Tail, SetjmpRetPHIs.size()); // -1 means no longjmp happened, continue normally (will hit the default // switch case). 0 means a longjmp that is not ours to handle, needs a // rethrow. Otherwise the index is the same as the index in P+1 (to avoid // 0). for (unsigned i = 0; i < SetjmpRetPHIs.size(); i++) { SI->addCase(IRB.getInt32(i + 1), SetjmpRetPHIs[i]->getParent()); SetjmpRetPHIs[i]->addIncoming(LongjmpResult, EndBB); } // We are splitting the block here, and must continue to find other calls // in the block - which is now split. so continue to traverse in the Tail BBs.push_back(Tail); } } // Erase everything we no longer need in this function for (Instruction *I : ToErase) I->eraseFromParent(); // Free setjmpTable buffer before each return instruction for (BasicBlock &BB : F) { Instruction *TI = BB.getTerminator(); if (isa(TI)) CallInst::CreateFree(SetjmpTable, TI); } // Every call to saveSetjmp can change setjmpTable and setjmpTableSize // (when buffer reallocation occurs) // entry: // setjmpTableSize = 4; // setjmpTable = (int *) malloc(40); // setjmpTable[0] = 0; // ... // somebb: // setjmpTable = saveSetjmp(buf, label, setjmpTable, setjmpTableSize); // setjmpTableSize = getTempRet0(); // So we need to make sure the SSA for these variables is valid so that every // saveSetjmp and testSetjmp calls have the correct arguments. SSAUpdater SetjmpTableSSA; SSAUpdater SetjmpTableSizeSSA; SetjmpTableSSA.Initialize(Type::getInt32PtrTy(C), "setjmpTable"); SetjmpTableSizeSSA.Initialize(Type::getInt32Ty(C), "setjmpTableSize"); for (Instruction *I : SetjmpTableInsts) SetjmpTableSSA.AddAvailableValue(I->getParent(), I); for (Instruction *I : SetjmpTableSizeInsts) SetjmpTableSizeSSA.AddAvailableValue(I->getParent(), I); for (auto UI = SetjmpTable->use_begin(), UE = SetjmpTable->use_end(); UI != UE;) { // Grab the use before incrementing the iterator. Use &U = *UI; // Increment the iterator before removing the use from the list. ++UI; if (Instruction *I = dyn_cast(U.getUser())) if (I->getParent() != &EntryBB) SetjmpTableSSA.RewriteUse(U); } for (auto UI = SetjmpTableSize->use_begin(), UE = SetjmpTableSize->use_end(); UI != UE;) { Use &U = *UI; ++UI; if (Instruction *I = dyn_cast(U.getUser())) if (I->getParent() != &EntryBB) SetjmpTableSizeSSA.RewriteUse(U); } // Finally, our modifications to the cfg can break dominance of SSA variables. // For example, in this code, // if (x()) { .. setjmp() .. } // if (y()) { .. longjmp() .. } // We must split the longjmp block, and it can jump into the block splitted // from setjmp one. But that means that when we split the setjmp block, it's // first part no longer dominates its second part - there is a theoretically // possible control flow path where x() is false, then y() is true and we // reach the second part of the setjmp block, without ever reaching the first // part. So, we rebuild SSA form here. rebuildSSA(F); return true; }