//===-- WebAssemblyCFGStackify.cpp - CFG Stackification -------------------===// // // 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 // //===----------------------------------------------------------------------===// /// /// \file /// This file implements a CFG stacking pass. /// /// This pass inserts BLOCK, LOOP, and TRY markers to mark the start of scopes, /// since scope boundaries serve as the labels for WebAssembly's control /// transfers. /// /// This is sufficient to convert arbitrary CFGs into a form that works on /// WebAssembly, provided that all loops are single-entry. /// /// In case we use exceptions, this pass also fixes mismatches in unwind /// destinations created during transforming CFG into wasm structured format. /// //===----------------------------------------------------------------------===// #include "Utils/WebAssemblyTypeUtilities.h" #include "Utils/WebAssemblyUtilities.h" #include "WebAssembly.h" #include "WebAssemblyExceptionInfo.h" #include "WebAssemblyMachineFunctionInfo.h" #include "WebAssemblySortRegion.h" #include "WebAssemblySubtarget.h" #include "llvm/ADT/Statistic.h" #include "llvm/CodeGen/MachineDominators.h" #include "llvm/CodeGen/MachineInstrBuilder.h" #include "llvm/CodeGen/MachineLoopInfo.h" #include "llvm/CodeGen/WasmEHFuncInfo.h" #include "llvm/MC/MCAsmInfo.h" #include "llvm/Target/TargetMachine.h" using namespace llvm; using WebAssembly::SortRegionInfo; #define DEBUG_TYPE "wasm-cfg-stackify" STATISTIC(NumCallUnwindMismatches, "Number of call unwind mismatches found"); STATISTIC(NumCatchUnwindMismatches, "Number of catch unwind mismatches found"); namespace { class WebAssemblyCFGStackify final : public MachineFunctionPass { StringRef getPassName() const override { return "WebAssembly CFG Stackify"; } void getAnalysisUsage(AnalysisUsage &AU) const override { AU.addRequired(); AU.addRequired(); AU.addRequired(); MachineFunctionPass::getAnalysisUsage(AU); } bool runOnMachineFunction(MachineFunction &MF) override; // For each block whose label represents the end of a scope, record the block // which holds the beginning of the scope. This will allow us to quickly skip // over scoped regions when walking blocks. SmallVector ScopeTops; void updateScopeTops(MachineBasicBlock *Begin, MachineBasicBlock *End) { int EndNo = End->getNumber(); if (!ScopeTops[EndNo] || ScopeTops[EndNo]->getNumber() > Begin->getNumber()) ScopeTops[EndNo] = Begin; } // Placing markers. void placeMarkers(MachineFunction &MF); void placeBlockMarker(MachineBasicBlock &MBB); void placeLoopMarker(MachineBasicBlock &MBB); void placeTryMarker(MachineBasicBlock &MBB); // Exception handling related functions bool fixCallUnwindMismatches(MachineFunction &MF); bool fixCatchUnwindMismatches(MachineFunction &MF); void addTryDelegate(MachineInstr *RangeBegin, MachineInstr *RangeEnd, MachineBasicBlock *DelegateDest); void recalculateScopeTops(MachineFunction &MF); void removeUnnecessaryInstrs(MachineFunction &MF); // Wrap-up using EndMarkerInfo = std::pair; unsigned getBranchDepth(const SmallVectorImpl &Stack, const MachineBasicBlock *MBB); unsigned getDelegateDepth(const SmallVectorImpl &Stack, const MachineBasicBlock *MBB); unsigned getRethrowDepth(const SmallVectorImpl &Stack, const SmallVectorImpl &EHPadStack); void rewriteDepthImmediates(MachineFunction &MF); void fixEndsAtEndOfFunction(MachineFunction &MF); void cleanupFunctionData(MachineFunction &MF); // For each BLOCK|LOOP|TRY, the corresponding END_(BLOCK|LOOP|TRY) or DELEGATE // (in case of TRY). DenseMap BeginToEnd; // For each END_(BLOCK|LOOP|TRY) or DELEGATE, the corresponding // BLOCK|LOOP|TRY. DenseMap EndToBegin; // map DenseMap TryToEHPad; // map DenseMap EHPadToTry; // We need an appendix block to place 'end_loop' or 'end_try' marker when the // loop / exception bottom block is the last block in a function MachineBasicBlock *AppendixBB = nullptr; MachineBasicBlock *getAppendixBlock(MachineFunction &MF) { if (!AppendixBB) { AppendixBB = MF.CreateMachineBasicBlock(); // Give it a fake predecessor so that AsmPrinter prints its label. AppendixBB->addSuccessor(AppendixBB); MF.push_back(AppendixBB); } return AppendixBB; } // Before running rewriteDepthImmediates function, 'delegate' has a BB as its // destination operand. getFakeCallerBlock() returns a fake BB that will be // used for the operand when 'delegate' needs to rethrow to the caller. This // will be rewritten as an immediate value that is the number of block depths // + 1 in rewriteDepthImmediates, and this fake BB will be removed at the end // of the pass. MachineBasicBlock *FakeCallerBB = nullptr; MachineBasicBlock *getFakeCallerBlock(MachineFunction &MF) { if (!FakeCallerBB) FakeCallerBB = MF.CreateMachineBasicBlock(); return FakeCallerBB; } // Helper functions to register / unregister scope information created by // marker instructions. void registerScope(MachineInstr *Begin, MachineInstr *End); void registerTryScope(MachineInstr *Begin, MachineInstr *End, MachineBasicBlock *EHPad); void unregisterScope(MachineInstr *Begin); public: static char ID; // Pass identification, replacement for typeid WebAssemblyCFGStackify() : MachineFunctionPass(ID) {} ~WebAssemblyCFGStackify() override { releaseMemory(); } void releaseMemory() override; }; } // end anonymous namespace char WebAssemblyCFGStackify::ID = 0; INITIALIZE_PASS(WebAssemblyCFGStackify, DEBUG_TYPE, "Insert BLOCK/LOOP/TRY markers for WebAssembly scopes", false, false) FunctionPass *llvm::createWebAssemblyCFGStackify() { return new WebAssemblyCFGStackify(); } /// Test whether Pred has any terminators explicitly branching to MBB, as /// opposed to falling through. Note that it's possible (eg. in unoptimized /// code) for a branch instruction to both branch to a block and fallthrough /// to it, so we check the actual branch operands to see if there are any /// explicit mentions. static bool explicitlyBranchesTo(MachineBasicBlock *Pred, MachineBasicBlock *MBB) { for (MachineInstr &MI : Pred->terminators()) for (MachineOperand &MO : MI.explicit_operands()) if (MO.isMBB() && MO.getMBB() == MBB) return true; return false; } // Returns an iterator to the earliest position possible within the MBB, // satisfying the restrictions given by BeforeSet and AfterSet. BeforeSet // contains instructions that should go before the marker, and AfterSet contains // ones that should go after the marker. In this function, AfterSet is only // used for validation checking. template static MachineBasicBlock::iterator getEarliestInsertPos(MachineBasicBlock *MBB, const Container &BeforeSet, const Container &AfterSet) { auto InsertPos = MBB->end(); while (InsertPos != MBB->begin()) { if (BeforeSet.count(&*std::prev(InsertPos))) { #ifndef NDEBUG // Validation check for (auto Pos = InsertPos, E = MBB->begin(); Pos != E; --Pos) assert(!AfterSet.count(&*std::prev(Pos))); #endif break; } --InsertPos; } return InsertPos; } // Returns an iterator to the latest position possible within the MBB, // satisfying the restrictions given by BeforeSet and AfterSet. BeforeSet // contains instructions that should go before the marker, and AfterSet contains // ones that should go after the marker. In this function, BeforeSet is only // used for validation checking. template static MachineBasicBlock::iterator getLatestInsertPos(MachineBasicBlock *MBB, const Container &BeforeSet, const Container &AfterSet) { auto InsertPos = MBB->begin(); while (InsertPos != MBB->end()) { if (AfterSet.count(&*InsertPos)) { #ifndef NDEBUG // Validation check for (auto Pos = InsertPos, E = MBB->end(); Pos != E; ++Pos) assert(!BeforeSet.count(&*Pos)); #endif break; } ++InsertPos; } return InsertPos; } void WebAssemblyCFGStackify::registerScope(MachineInstr *Begin, MachineInstr *End) { BeginToEnd[Begin] = End; EndToBegin[End] = Begin; } // When 'End' is not an 'end_try' but 'delegate, EHPad is nullptr. void WebAssemblyCFGStackify::registerTryScope(MachineInstr *Begin, MachineInstr *End, MachineBasicBlock *EHPad) { registerScope(Begin, End); TryToEHPad[Begin] = EHPad; EHPadToTry[EHPad] = Begin; } void WebAssemblyCFGStackify::unregisterScope(MachineInstr *Begin) { assert(BeginToEnd.count(Begin)); MachineInstr *End = BeginToEnd[Begin]; assert(EndToBegin.count(End)); BeginToEnd.erase(Begin); EndToBegin.erase(End); MachineBasicBlock *EHPad = TryToEHPad.lookup(Begin); if (EHPad) { assert(EHPadToTry.count(EHPad)); TryToEHPad.erase(Begin); EHPadToTry.erase(EHPad); } } /// Insert a BLOCK marker for branches to MBB (if needed). // TODO Consider a more generalized way of handling block (and also loop and // try) signatures when we implement the multi-value proposal later. void WebAssemblyCFGStackify::placeBlockMarker(MachineBasicBlock &MBB) { assert(!MBB.isEHPad()); MachineFunction &MF = *MBB.getParent(); auto &MDT = getAnalysis(); const auto &TII = *MF.getSubtarget().getInstrInfo(); const auto &MFI = *MF.getInfo(); // First compute the nearest common dominator of all forward non-fallthrough // predecessors so that we minimize the time that the BLOCK is on the stack, // which reduces overall stack height. MachineBasicBlock *Header = nullptr; bool IsBranchedTo = false; int MBBNumber = MBB.getNumber(); for (MachineBasicBlock *Pred : MBB.predecessors()) { if (Pred->getNumber() < MBBNumber) { Header = Header ? MDT.findNearestCommonDominator(Header, Pred) : Pred; if (explicitlyBranchesTo(Pred, &MBB)) IsBranchedTo = true; } } if (!Header) return; if (!IsBranchedTo) return; assert(&MBB != &MF.front() && "Header blocks shouldn't have predecessors"); MachineBasicBlock *LayoutPred = MBB.getPrevNode(); // If the nearest common dominator is inside a more deeply nested context, // walk out to the nearest scope which isn't more deeply nested. for (MachineFunction::iterator I(LayoutPred), E(Header); I != E; --I) { if (MachineBasicBlock *ScopeTop = ScopeTops[I->getNumber()]) { if (ScopeTop->getNumber() > Header->getNumber()) { // Skip over an intervening scope. I = std::next(ScopeTop->getIterator()); } else { // We found a scope level at an appropriate depth. Header = ScopeTop; break; } } } // Decide where in Header to put the BLOCK. // Instructions that should go before the BLOCK. SmallPtrSet BeforeSet; // Instructions that should go after the BLOCK. SmallPtrSet AfterSet; for (const auto &MI : *Header) { // If there is a previously placed LOOP marker and the bottom block of the // loop is above MBB, it should be after the BLOCK, because the loop is // nested in this BLOCK. Otherwise it should be before the BLOCK. if (MI.getOpcode() == WebAssembly::LOOP) { auto *LoopBottom = BeginToEnd[&MI]->getParent()->getPrevNode(); if (MBB.getNumber() > LoopBottom->getNumber()) AfterSet.insert(&MI); #ifndef NDEBUG else BeforeSet.insert(&MI); #endif } // If there is a previously placed BLOCK/TRY marker and its corresponding // END marker is before the current BLOCK's END marker, that should be // placed after this BLOCK. Otherwise it should be placed before this BLOCK // marker. if (MI.getOpcode() == WebAssembly::BLOCK || MI.getOpcode() == WebAssembly::TRY) { if (BeginToEnd[&MI]->getParent()->getNumber() <= MBB.getNumber()) AfterSet.insert(&MI); #ifndef NDEBUG else BeforeSet.insert(&MI); #endif } #ifndef NDEBUG // All END_(BLOCK|LOOP|TRY) markers should be before the BLOCK. if (MI.getOpcode() == WebAssembly::END_BLOCK || MI.getOpcode() == WebAssembly::END_LOOP || MI.getOpcode() == WebAssembly::END_TRY) BeforeSet.insert(&MI); #endif // Terminators should go after the BLOCK. if (MI.isTerminator()) AfterSet.insert(&MI); } // Local expression tree should go after the BLOCK. for (auto I = Header->getFirstTerminator(), E = Header->begin(); I != E; --I) { if (std::prev(I)->isDebugInstr() || std::prev(I)->isPosition()) continue; if (WebAssembly::isChild(*std::prev(I), MFI)) AfterSet.insert(&*std::prev(I)); else break; } // Add the BLOCK. WebAssembly::BlockType ReturnType = WebAssembly::BlockType::Void; auto InsertPos = getLatestInsertPos(Header, BeforeSet, AfterSet); MachineInstr *Begin = BuildMI(*Header, InsertPos, Header->findDebugLoc(InsertPos), TII.get(WebAssembly::BLOCK)) .addImm(int64_t(ReturnType)); // Decide where in Header to put the END_BLOCK. BeforeSet.clear(); AfterSet.clear(); for (auto &MI : MBB) { #ifndef NDEBUG // END_BLOCK should precede existing LOOP and TRY markers. if (MI.getOpcode() == WebAssembly::LOOP || MI.getOpcode() == WebAssembly::TRY) AfterSet.insert(&MI); #endif // If there is a previously placed END_LOOP marker and the header of the // loop is above this block's header, the END_LOOP should be placed after // the BLOCK, because the loop contains this block. Otherwise the END_LOOP // should be placed before the BLOCK. The same for END_TRY. if (MI.getOpcode() == WebAssembly::END_LOOP || MI.getOpcode() == WebAssembly::END_TRY) { if (EndToBegin[&MI]->getParent()->getNumber() >= Header->getNumber()) BeforeSet.insert(&MI); #ifndef NDEBUG else AfterSet.insert(&MI); #endif } } // Mark the end of the block. InsertPos = getEarliestInsertPos(&MBB, BeforeSet, AfterSet); MachineInstr *End = BuildMI(MBB, InsertPos, MBB.findPrevDebugLoc(InsertPos), TII.get(WebAssembly::END_BLOCK)); registerScope(Begin, End); // Track the farthest-spanning scope that ends at this point. updateScopeTops(Header, &MBB); } /// Insert a LOOP marker for a loop starting at MBB (if it's a loop header). void WebAssemblyCFGStackify::placeLoopMarker(MachineBasicBlock &MBB) { MachineFunction &MF = *MBB.getParent(); const auto &MLI = getAnalysis(); const auto &WEI = getAnalysis(); SortRegionInfo SRI(MLI, WEI); const auto &TII = *MF.getSubtarget().getInstrInfo(); MachineLoop *Loop = MLI.getLoopFor(&MBB); if (!Loop || Loop->getHeader() != &MBB) return; // The operand of a LOOP is the first block after the loop. If the loop is the // bottom of the function, insert a dummy block at the end. MachineBasicBlock *Bottom = SRI.getBottom(Loop); auto Iter = std::next(Bottom->getIterator()); if (Iter == MF.end()) { getAppendixBlock(MF); Iter = std::next(Bottom->getIterator()); } MachineBasicBlock *AfterLoop = &*Iter; // Decide where in Header to put the LOOP. SmallPtrSet BeforeSet; SmallPtrSet AfterSet; for (const auto &MI : MBB) { // LOOP marker should be after any existing loop that ends here. Otherwise // we assume the instruction belongs to the loop. if (MI.getOpcode() == WebAssembly::END_LOOP) BeforeSet.insert(&MI); #ifndef NDEBUG else AfterSet.insert(&MI); #endif } // Mark the beginning of the loop. auto InsertPos = getEarliestInsertPos(&MBB, BeforeSet, AfterSet); MachineInstr *Begin = BuildMI(MBB, InsertPos, MBB.findDebugLoc(InsertPos), TII.get(WebAssembly::LOOP)) .addImm(int64_t(WebAssembly::BlockType::Void)); // Decide where in Header to put the END_LOOP. BeforeSet.clear(); AfterSet.clear(); #ifndef NDEBUG for (const auto &MI : MBB) // Existing END_LOOP markers belong to parent loops of this loop if (MI.getOpcode() == WebAssembly::END_LOOP) AfterSet.insert(&MI); #endif // Mark the end of the loop (using arbitrary debug location that branched to // the loop end as its location). InsertPos = getEarliestInsertPos(AfterLoop, BeforeSet, AfterSet); DebugLoc EndDL = AfterLoop->pred_empty() ? DebugLoc() : (*AfterLoop->pred_rbegin())->findBranchDebugLoc(); MachineInstr *End = BuildMI(*AfterLoop, InsertPos, EndDL, TII.get(WebAssembly::END_LOOP)); registerScope(Begin, End); assert((!ScopeTops[AfterLoop->getNumber()] || ScopeTops[AfterLoop->getNumber()]->getNumber() < MBB.getNumber()) && "With block sorting the outermost loop for a block should be first."); updateScopeTops(&MBB, AfterLoop); } void WebAssemblyCFGStackify::placeTryMarker(MachineBasicBlock &MBB) { assert(MBB.isEHPad()); MachineFunction &MF = *MBB.getParent(); auto &MDT = getAnalysis(); const auto &TII = *MF.getSubtarget().getInstrInfo(); const auto &MLI = getAnalysis(); const auto &WEI = getAnalysis(); SortRegionInfo SRI(MLI, WEI); const auto &MFI = *MF.getInfo(); // Compute the nearest common dominator of all unwind predecessors MachineBasicBlock *Header = nullptr; int MBBNumber = MBB.getNumber(); for (auto *Pred : MBB.predecessors()) { if (Pred->getNumber() < MBBNumber) { Header = Header ? MDT.findNearestCommonDominator(Header, Pred) : Pred; assert(!explicitlyBranchesTo(Pred, &MBB) && "Explicit branch to an EH pad!"); } } if (!Header) return; // If this try is at the bottom of the function, insert a dummy block at the // end. WebAssemblyException *WE = WEI.getExceptionFor(&MBB); assert(WE); MachineBasicBlock *Bottom = SRI.getBottom(WE); auto Iter = std::next(Bottom->getIterator()); if (Iter == MF.end()) { getAppendixBlock(MF); Iter = std::next(Bottom->getIterator()); } MachineBasicBlock *Cont = &*Iter; assert(Cont != &MF.front()); MachineBasicBlock *LayoutPred = Cont->getPrevNode(); // If the nearest common dominator is inside a more deeply nested context, // walk out to the nearest scope which isn't more deeply nested. for (MachineFunction::iterator I(LayoutPred), E(Header); I != E; --I) { if (MachineBasicBlock *ScopeTop = ScopeTops[I->getNumber()]) { if (ScopeTop->getNumber() > Header->getNumber()) { // Skip over an intervening scope. I = std::next(ScopeTop->getIterator()); } else { // We found a scope level at an appropriate depth. Header = ScopeTop; break; } } } // Decide where in Header to put the TRY. // Instructions that should go before the TRY. SmallPtrSet BeforeSet; // Instructions that should go after the TRY. SmallPtrSet AfterSet; for (const auto &MI : *Header) { // If there is a previously placed LOOP marker and the bottom block of the // loop is above MBB, it should be after the TRY, because the loop is nested // in this TRY. Otherwise it should be before the TRY. if (MI.getOpcode() == WebAssembly::LOOP) { auto *LoopBottom = BeginToEnd[&MI]->getParent()->getPrevNode(); if (MBB.getNumber() > LoopBottom->getNumber()) AfterSet.insert(&MI); #ifndef NDEBUG else BeforeSet.insert(&MI); #endif } // All previously inserted BLOCK/TRY markers should be after the TRY because // they are all nested trys. if (MI.getOpcode() == WebAssembly::BLOCK || MI.getOpcode() == WebAssembly::TRY) AfterSet.insert(&MI); #ifndef NDEBUG // All END_(BLOCK/LOOP/TRY) markers should be before the TRY. if (MI.getOpcode() == WebAssembly::END_BLOCK || MI.getOpcode() == WebAssembly::END_LOOP || MI.getOpcode() == WebAssembly::END_TRY) BeforeSet.insert(&MI); #endif // Terminators should go after the TRY. if (MI.isTerminator()) AfterSet.insert(&MI); } // If Header unwinds to MBB (= Header contains 'invoke'), the try block should // contain the call within it. So the call should go after the TRY. The // exception is when the header's terminator is a rethrow instruction, in // which case that instruction, not a call instruction before it, is gonna // throw. MachineInstr *ThrowingCall = nullptr; if (MBB.isPredecessor(Header)) { auto TermPos = Header->getFirstTerminator(); if (TermPos == Header->end() || TermPos->getOpcode() != WebAssembly::RETHROW) { for (auto &MI : reverse(*Header)) { if (MI.isCall()) { AfterSet.insert(&MI); ThrowingCall = &MI; // Possibly throwing calls are usually wrapped by EH_LABEL // instructions. We don't want to split them and the call. if (MI.getIterator() != Header->begin() && std::prev(MI.getIterator())->isEHLabel()) { AfterSet.insert(&*std::prev(MI.getIterator())); ThrowingCall = &*std::prev(MI.getIterator()); } break; } } } } // Local expression tree should go after the TRY. // For BLOCK placement, we start the search from the previous instruction of a // BB's terminator, but in TRY's case, we should start from the previous // instruction of a call that can throw, or a EH_LABEL that precedes the call, // because the return values of the call's previous instructions can be // stackified and consumed by the throwing call. auto SearchStartPt = ThrowingCall ? MachineBasicBlock::iterator(ThrowingCall) : Header->getFirstTerminator(); for (auto I = SearchStartPt, E = Header->begin(); I != E; --I) { if (std::prev(I)->isDebugInstr() || std::prev(I)->isPosition()) continue; if (WebAssembly::isChild(*std::prev(I), MFI)) AfterSet.insert(&*std::prev(I)); else break; } // Add the TRY. auto InsertPos = getLatestInsertPos(Header, BeforeSet, AfterSet); MachineInstr *Begin = BuildMI(*Header, InsertPos, Header->findDebugLoc(InsertPos), TII.get(WebAssembly::TRY)) .addImm(int64_t(WebAssembly::BlockType::Void)); // Decide where in Header to put the END_TRY. BeforeSet.clear(); AfterSet.clear(); for (const auto &MI : *Cont) { #ifndef NDEBUG // END_TRY should precede existing LOOP and BLOCK markers. if (MI.getOpcode() == WebAssembly::LOOP || MI.getOpcode() == WebAssembly::BLOCK) AfterSet.insert(&MI); // All END_TRY markers placed earlier belong to exceptions that contains // this one. if (MI.getOpcode() == WebAssembly::END_TRY) AfterSet.insert(&MI); #endif // If there is a previously placed END_LOOP marker and its header is after // where TRY marker is, this loop is contained within the 'catch' part, so // the END_TRY marker should go after that. Otherwise, the whole try-catch // is contained within this loop, so the END_TRY should go before that. if (MI.getOpcode() == WebAssembly::END_LOOP) { // For a LOOP to be after TRY, LOOP's BB should be after TRY's BB; if they // are in the same BB, LOOP is always before TRY. if (EndToBegin[&MI]->getParent()->getNumber() > Header->getNumber()) BeforeSet.insert(&MI); #ifndef NDEBUG else AfterSet.insert(&MI); #endif } // It is not possible for an END_BLOCK to be already in this block. } // Mark the end of the TRY. InsertPos = getEarliestInsertPos(Cont, BeforeSet, AfterSet); MachineInstr *End = BuildMI(*Cont, InsertPos, Bottom->findBranchDebugLoc(), TII.get(WebAssembly::END_TRY)); registerTryScope(Begin, End, &MBB); // Track the farthest-spanning scope that ends at this point. We create two // mappings: (BB with 'end_try' -> BB with 'try') and (BB with 'catch' -> BB // with 'try'). We need to create 'catch' -> 'try' mapping here too because // markers should not span across 'catch'. For example, this should not // happen: // // try // block --| (X) // catch | // end_block --| // end_try for (auto *End : {&MBB, Cont}) updateScopeTops(Header, End); } void WebAssemblyCFGStackify::removeUnnecessaryInstrs(MachineFunction &MF) { const auto &TII = *MF.getSubtarget().getInstrInfo(); // When there is an unconditional branch right before a catch instruction and // it branches to the end of end_try marker, we don't need the branch, because // it there is no exception, the control flow transfers to that point anyway. // bb0: // try // ... // br bb2 <- Not necessary // bb1 (ehpad): // catch // ... // bb2: <- Continuation BB // end // // A more involved case: When the BB where 'end' is located is an another EH // pad, the Cont (= continuation) BB is that EH pad's 'end' BB. For example, // bb0: // try // try // ... // br bb3 <- Not necessary // bb1 (ehpad): // catch // bb2 (ehpad): // end // catch // ... // bb3: <- Continuation BB // end // // When the EH pad at hand is bb1, its matching end_try is in bb2. But it is // another EH pad, so bb0's continuation BB becomes bb3. So 'br bb3' in the // code can be deleted. This is why we run 'while' until 'Cont' is not an EH // pad. for (auto &MBB : MF) { if (!MBB.isEHPad()) continue; MachineBasicBlock *TBB = nullptr, *FBB = nullptr; SmallVector Cond; MachineBasicBlock *EHPadLayoutPred = MBB.getPrevNode(); MachineBasicBlock *Cont = &MBB; while (Cont->isEHPad()) { MachineInstr *Try = EHPadToTry[Cont]; MachineInstr *EndTry = BeginToEnd[Try]; // We started from an EH pad, so the end marker cannot be a delegate assert(EndTry->getOpcode() != WebAssembly::DELEGATE); Cont = EndTry->getParent(); } bool Analyzable = !TII.analyzeBranch(*EHPadLayoutPred, TBB, FBB, Cond); // This condition means either // 1. This BB ends with a single unconditional branch whose destinaion is // Cont. // 2. This BB ends with a conditional branch followed by an unconditional // branch, and the unconditional branch's destination is Cont. // In both cases, we want to remove the last (= unconditional) branch. if (Analyzable && ((Cond.empty() && TBB && TBB == Cont) || (!Cond.empty() && FBB && FBB == Cont))) { bool ErasedUncondBr = false; (void)ErasedUncondBr; for (auto I = EHPadLayoutPred->end(), E = EHPadLayoutPred->begin(); I != E; --I) { auto PrevI = std::prev(I); if (PrevI->isTerminator()) { assert(PrevI->getOpcode() == WebAssembly::BR); PrevI->eraseFromParent(); ErasedUncondBr = true; break; } } assert(ErasedUncondBr && "Unconditional branch not erased!"); } } // When there are block / end_block markers that overlap with try / end_try // markers, and the block and try markers' return types are the same, the // block /end_block markers are not necessary, because try / end_try markers // also can serve as boundaries for branches. // block <- Not necessary // try // ... // catch // ... // end // end <- Not necessary SmallVector ToDelete; for (auto &MBB : MF) { for (auto &MI : MBB) { if (MI.getOpcode() != WebAssembly::TRY) continue; MachineInstr *Try = &MI, *EndTry = BeginToEnd[Try]; if (EndTry->getOpcode() == WebAssembly::DELEGATE) continue; MachineBasicBlock *TryBB = Try->getParent(); MachineBasicBlock *Cont = EndTry->getParent(); int64_t RetType = Try->getOperand(0).getImm(); for (auto B = Try->getIterator(), E = std::next(EndTry->getIterator()); B != TryBB->begin() && E != Cont->end() && std::prev(B)->getOpcode() == WebAssembly::BLOCK && E->getOpcode() == WebAssembly::END_BLOCK && std::prev(B)->getOperand(0).getImm() == RetType; --B, ++E) { ToDelete.push_back(&*std::prev(B)); ToDelete.push_back(&*E); } } } for (auto *MI : ToDelete) { if (MI->getOpcode() == WebAssembly::BLOCK) unregisterScope(MI); MI->eraseFromParent(); } } // When MBB is split into MBB and Split, we should unstackify defs in MBB that // have their uses in Split. static void unstackifyVRegsUsedInSplitBB(MachineBasicBlock &MBB, MachineBasicBlock &Split) { MachineFunction &MF = *MBB.getParent(); const auto &TII = *MF.getSubtarget().getInstrInfo(); auto &MFI = *MF.getInfo(); auto &MRI = MF.getRegInfo(); for (auto &MI : Split) { for (auto &MO : MI.explicit_uses()) { if (!MO.isReg() || MO.getReg().isPhysical()) continue; if (MachineInstr *Def = MRI.getUniqueVRegDef(MO.getReg())) if (Def->getParent() == &MBB) MFI.unstackifyVReg(MO.getReg()); } } // In RegStackify, when a register definition is used multiple times, // Reg = INST ... // INST ..., Reg, ... // INST ..., Reg, ... // INST ..., Reg, ... // // we introduce a TEE, which has the following form: // DefReg = INST ... // TeeReg, Reg = TEE_... DefReg // INST ..., TeeReg, ... // INST ..., Reg, ... // INST ..., Reg, ... // with DefReg and TeeReg stackified but Reg not stackified. // // But the invariant that TeeReg should be stackified can be violated while we // unstackify registers in the split BB above. In this case, we convert TEEs // into two COPYs. This COPY will be eventually eliminated in ExplicitLocals. // DefReg = INST ... // TeeReg = COPY DefReg // Reg = COPY DefReg // INST ..., TeeReg, ... // INST ..., Reg, ... // INST ..., Reg, ... for (MachineInstr &MI : llvm::make_early_inc_range(MBB)) { if (!WebAssembly::isTee(MI.getOpcode())) continue; Register TeeReg = MI.getOperand(0).getReg(); Register Reg = MI.getOperand(1).getReg(); Register DefReg = MI.getOperand(2).getReg(); if (!MFI.isVRegStackified(TeeReg)) { // Now we are not using TEE anymore, so unstackify DefReg too MFI.unstackifyVReg(DefReg); unsigned CopyOpc = WebAssembly::getCopyOpcodeForRegClass(MRI.getRegClass(DefReg)); BuildMI(MBB, &MI, MI.getDebugLoc(), TII.get(CopyOpc), TeeReg) .addReg(DefReg); BuildMI(MBB, &MI, MI.getDebugLoc(), TII.get(CopyOpc), Reg).addReg(DefReg); MI.eraseFromParent(); } } } // Wrap the given range of instruction with try-delegate. RangeBegin and // RangeEnd are inclusive. void WebAssemblyCFGStackify::addTryDelegate(MachineInstr *RangeBegin, MachineInstr *RangeEnd, MachineBasicBlock *DelegateDest) { auto *BeginBB = RangeBegin->getParent(); auto *EndBB = RangeEnd->getParent(); MachineFunction &MF = *BeginBB->getParent(); const auto &MFI = *MF.getInfo(); const auto &TII = *MF.getSubtarget().getInstrInfo(); // Local expression tree before the first call of this range should go // after the nested TRY. SmallPtrSet AfterSet; AfterSet.insert(RangeBegin); for (auto I = MachineBasicBlock::iterator(RangeBegin), E = BeginBB->begin(); I != E; --I) { if (std::prev(I)->isDebugInstr() || std::prev(I)->isPosition()) continue; if (WebAssembly::isChild(*std::prev(I), MFI)) AfterSet.insert(&*std::prev(I)); else break; } // Create the nested try instruction. auto TryPos = getLatestInsertPos( BeginBB, SmallPtrSet(), AfterSet); MachineInstr *Try = BuildMI(*BeginBB, TryPos, RangeBegin->getDebugLoc(), TII.get(WebAssembly::TRY)) .addImm(int64_t(WebAssembly::BlockType::Void)); // Create a BB to insert the 'delegate' instruction. MachineBasicBlock *DelegateBB = MF.CreateMachineBasicBlock(); // If the destination of 'delegate' is not the caller, adds the destination to // the BB's successors. if (DelegateDest != FakeCallerBB) DelegateBB->addSuccessor(DelegateDest); auto SplitPos = std::next(RangeEnd->getIterator()); if (SplitPos == EndBB->end()) { // If the range's end instruction is at the end of the BB, insert the new // delegate BB after the current BB. MF.insert(std::next(EndBB->getIterator()), DelegateBB); EndBB->addSuccessor(DelegateBB); } else { // When the split pos is in the middle of a BB, we split the BB into two and // put the 'delegate' BB in between. We normally create a split BB and make // it a successor of the original BB (PostSplit == true), but in case the BB // is an EH pad and the split pos is before 'catch', we should preserve the // BB's property, including that it is an EH pad, in the later part of the // BB, where 'catch' is. In this case we set PostSplit to false. bool PostSplit = true; if (EndBB->isEHPad()) { for (auto I = MachineBasicBlock::iterator(SplitPos), E = EndBB->end(); I != E; ++I) { if (WebAssembly::isCatch(I->getOpcode())) { PostSplit = false; break; } } } MachineBasicBlock *PreBB = nullptr, *PostBB = nullptr; if (PostSplit) { // If the range's end instruction is in the middle of the BB, we split the // BB into two and insert the delegate BB in between. // - Before: // bb: // range_end // other_insts // // - After: // pre_bb: (previous 'bb') // range_end // delegate_bb: (new) // delegate // post_bb: (new) // other_insts PreBB = EndBB; PostBB = MF.CreateMachineBasicBlock(); MF.insert(std::next(PreBB->getIterator()), PostBB); MF.insert(std::next(PreBB->getIterator()), DelegateBB); PostBB->splice(PostBB->end(), PreBB, SplitPos, PreBB->end()); PostBB->transferSuccessors(PreBB); } else { // - Before: // ehpad: // range_end // catch // ... // // - After: // pre_bb: (new) // range_end // delegate_bb: (new) // delegate // post_bb: (previous 'ehpad') // catch // ... assert(EndBB->isEHPad()); PreBB = MF.CreateMachineBasicBlock(); PostBB = EndBB; MF.insert(PostBB->getIterator(), PreBB); MF.insert(PostBB->getIterator(), DelegateBB); PreBB->splice(PreBB->end(), PostBB, PostBB->begin(), SplitPos); // We don't need to transfer predecessors of the EH pad to 'PreBB', // because an EH pad's predecessors are all through unwind edges and they // should still unwind to the EH pad, not PreBB. } unstackifyVRegsUsedInSplitBB(*PreBB, *PostBB); PreBB->addSuccessor(DelegateBB); PreBB->addSuccessor(PostBB); } // Add 'delegate' instruction in the delegate BB created above. MachineInstr *Delegate = BuildMI(DelegateBB, RangeEnd->getDebugLoc(), TII.get(WebAssembly::DELEGATE)) .addMBB(DelegateDest); registerTryScope(Try, Delegate, nullptr); } bool WebAssemblyCFGStackify::fixCallUnwindMismatches(MachineFunction &MF) { // Linearizing the control flow by placing TRY / END_TRY markers can create // mismatches in unwind destinations for throwing instructions, such as calls. // // We use the 'delegate' instruction to fix the unwind mismatches. 'delegate' // instruction delegates an exception to an outer 'catch'. It can target not // only 'catch' but all block-like structures including another 'delegate', // but with slightly different semantics than branches. When it targets a // 'catch', it will delegate the exception to that catch. It is being // discussed how to define the semantics when 'delegate''s target is a non-try // block: it will either be a validation failure or it will target the next // outer try-catch. But anyway our LLVM backend currently does not generate // such code. The example below illustrates where the 'delegate' instruction // in the middle will delegate the exception to, depending on the value of N. // try // try // block // try // try // call @foo // delegate N ;; Where will this delegate to? // catch ;; N == 0 // end // end ;; N == 1 (invalid; will not be generated) // delegate ;; N == 2 // catch ;; N == 3 // end // ;; N == 4 (to caller) // 1. When an instruction may throw, but the EH pad it will unwind to can be // different from the original CFG. // // Example: we have the following CFG: // bb0: // call @foo ; if it throws, unwind to bb2 // bb1: // call @bar ; if it throws, unwind to bb3 // bb2 (ehpad): // catch // ... // bb3 (ehpad) // catch // ... // // And the CFG is sorted in this order. Then after placing TRY markers, it // will look like: (BB markers are omitted) // try // try // call @foo // call @bar ;; if it throws, unwind to bb3 // catch ;; ehpad (bb2) // ... // end_try // catch ;; ehpad (bb3) // ... // end_try // // Now if bar() throws, it is going to end up ip in bb2, not bb3, where it // is supposed to end up. We solve this problem by wrapping the mismatching // call with an inner try-delegate that rethrows the exception to the right // 'catch'. // // try // try // call @foo // try ;; (new) // call @bar // delegate 1 (bb3) ;; (new) // catch ;; ehpad (bb2) // ... // end_try // catch ;; ehpad (bb3) // ... // end_try // // --- // 2. The same as 1, but in this case an instruction unwinds to a caller // function and not another EH pad. // // Example: we have the following CFG: // bb0: // call @foo ; if it throws, unwind to bb2 // bb1: // call @bar ; if it throws, unwind to caller // bb2 (ehpad): // catch // ... // // And the CFG is sorted in this order. Then after placing TRY markers, it // will look like: // try // call @foo // call @bar ;; if it throws, unwind to caller // catch ;; ehpad (bb2) // ... // end_try // // Now if bar() throws, it is going to end up ip in bb2, when it is supposed // throw up to the caller. We solve this problem in the same way, but in this // case 'delegate's immediate argument is the number of block depths + 1, // which means it rethrows to the caller. // try // call @foo // try ;; (new) // call @bar // delegate 1 (caller) ;; (new) // catch ;; ehpad (bb2) // ... // end_try // // Before rewriteDepthImmediates, delegate's argument is a BB. In case of the // caller, it will take a fake BB generated by getFakeCallerBlock(), which // will be converted to a correct immediate argument later. // // In case there are multiple calls in a BB that may throw to the caller, they // can be wrapped together in one nested try-delegate scope. (In 1, this // couldn't happen, because may-throwing instruction there had an unwind // destination, i.e., it was an invoke before, and there could be only one // invoke within a BB.) SmallVector EHPadStack; // Range of intructions to be wrapped in a new nested try/catch. A range // exists in a single BB and does not span multiple BBs. using TryRange = std::pair; // In original CFG, DenseMap> UnwindDestToTryRanges; // Gather possibly throwing calls (i.e., previously invokes) whose current // unwind destination is not the same as the original CFG. (Case 1) for (auto &MBB : reverse(MF)) { bool SeenThrowableInstInBB = false; for (auto &MI : reverse(MBB)) { if (MI.getOpcode() == WebAssembly::TRY) EHPadStack.pop_back(); else if (WebAssembly::isCatch(MI.getOpcode())) EHPadStack.push_back(MI.getParent()); // In this loop we only gather calls that have an EH pad to unwind. So // there will be at most 1 such call (= invoke) in a BB, so after we've // seen one, we can skip the rest of BB. Also if MBB has no EH pad // successor or MI does not throw, this is not an invoke. if (SeenThrowableInstInBB || !MBB.hasEHPadSuccessor() || !WebAssembly::mayThrow(MI)) continue; SeenThrowableInstInBB = true; // If the EH pad on the stack top is where this instruction should unwind // next, we're good. MachineBasicBlock *UnwindDest = getFakeCallerBlock(MF); for (auto *Succ : MBB.successors()) { // Even though semantically a BB can have multiple successors in case an // exception is not caught by a catchpad, in our backend implementation // it is guaranteed that a BB can have at most one EH pad successor. For // details, refer to comments in findWasmUnwindDestinations function in // SelectionDAGBuilder.cpp. if (Succ->isEHPad()) { UnwindDest = Succ; break; } } if (EHPadStack.back() == UnwindDest) continue; // Include EH_LABELs in the range before and afer the invoke MachineInstr *RangeBegin = &MI, *RangeEnd = &MI; if (RangeBegin->getIterator() != MBB.begin() && std::prev(RangeBegin->getIterator())->isEHLabel()) RangeBegin = &*std::prev(RangeBegin->getIterator()); if (std::next(RangeEnd->getIterator()) != MBB.end() && std::next(RangeEnd->getIterator())->isEHLabel()) RangeEnd = &*std::next(RangeEnd->getIterator()); // If not, record the range. UnwindDestToTryRanges[UnwindDest].push_back( TryRange(RangeBegin, RangeEnd)); LLVM_DEBUG(dbgs() << "- Call unwind mismatch: MBB = " << MBB.getName() << "\nCall = " << MI << "\nOriginal dest = " << UnwindDest->getName() << " Current dest = " << EHPadStack.back()->getName() << "\n\n"); } } assert(EHPadStack.empty()); // Gather possibly throwing calls that are supposed to unwind up to the caller // if they throw, but currently unwind to an incorrect destination. Unlike the // loop above, there can be multiple calls within a BB that unwind to the // caller, which we should group together in a range. (Case 2) MachineInstr *RangeBegin = nullptr, *RangeEnd = nullptr; // inclusive // Record the range. auto RecordCallerMismatchRange = [&](const MachineBasicBlock *CurrentDest) { UnwindDestToTryRanges[getFakeCallerBlock(MF)].push_back( TryRange(RangeBegin, RangeEnd)); LLVM_DEBUG(dbgs() << "- Call unwind mismatch: MBB = " << RangeBegin->getParent()->getName() << "\nRange begin = " << *RangeBegin << "Range end = " << *RangeEnd << "\nOriginal dest = caller Current dest = " << CurrentDest->getName() << "\n\n"); RangeBegin = RangeEnd = nullptr; // Reset range pointers }; for (auto &MBB : reverse(MF)) { bool SeenThrowableInstInBB = false; for (auto &MI : reverse(MBB)) { bool MayThrow = WebAssembly::mayThrow(MI); // If MBB has an EH pad successor and this is the last instruction that // may throw, this instruction unwinds to the EH pad and not to the // caller. if (MBB.hasEHPadSuccessor() && MayThrow && !SeenThrowableInstInBB) SeenThrowableInstInBB = true; // We wrap up the current range when we see a marker even if we haven't // finished a BB. else if (RangeEnd && WebAssembly::isMarker(MI.getOpcode())) RecordCallerMismatchRange(EHPadStack.back()); // If EHPadStack is empty, that means it correctly unwinds to the caller // if it throws, so we're good. If MI does not throw, we're good too. else if (EHPadStack.empty() || !MayThrow) { } // We found an instruction that unwinds to the caller but currently has an // incorrect unwind destination. Create a new range or increment the // currently existing range. else { if (!RangeEnd) RangeBegin = RangeEnd = &MI; else RangeBegin = &MI; } // Update EHPadStack. if (MI.getOpcode() == WebAssembly::TRY) EHPadStack.pop_back(); else if (WebAssembly::isCatch(MI.getOpcode())) EHPadStack.push_back(MI.getParent()); } if (RangeEnd) RecordCallerMismatchRange(EHPadStack.back()); } assert(EHPadStack.empty()); // We don't have any unwind destination mismatches to resolve. if (UnwindDestToTryRanges.empty()) return false; // Now we fix the mismatches by wrapping calls with inner try-delegates. for (auto &P : UnwindDestToTryRanges) { NumCallUnwindMismatches += P.second.size(); MachineBasicBlock *UnwindDest = P.first; auto &TryRanges = P.second; for (auto Range : TryRanges) { MachineInstr *RangeBegin = nullptr, *RangeEnd = nullptr; std::tie(RangeBegin, RangeEnd) = Range; auto *MBB = RangeBegin->getParent(); // If this BB has an EH pad successor, i.e., ends with an 'invoke', now we // are going to wrap the invoke with try-delegate, making the 'delegate' // BB the new successor instead, so remove the EH pad succesor here. The // BB may not have an EH pad successor if calls in this BB throw to the // caller. MachineBasicBlock *EHPad = nullptr; for (auto *Succ : MBB->successors()) { if (Succ->isEHPad()) { EHPad = Succ; break; } } if (EHPad) MBB->removeSuccessor(EHPad); addTryDelegate(RangeBegin, RangeEnd, UnwindDest); } } return true; } bool WebAssemblyCFGStackify::fixCatchUnwindMismatches(MachineFunction &MF) { // There is another kind of unwind destination mismatches besides call unwind // mismatches, which we will call "catch unwind mismatches". See this example // after the marker placement: // try // try // call @foo // catch __cpp_exception ;; ehpad A (next unwind dest: caller) // ... // end_try // catch_all ;; ehpad B // ... // end_try // // 'call @foo's unwind destination is the ehpad A. But suppose 'call @foo' // throws a foreign exception that is not caught by ehpad A, and its next // destination should be the caller. But after control flow linearization, // another EH pad can be placed in between (e.g. ehpad B here), making the // next unwind destination incorrect. In this case, the foreign exception // will instead go to ehpad B and will be caught there instead. In this // example the correct next unwind destination is the caller, but it can be // another outer catch in other cases. // // There is no specific 'call' or 'throw' instruction to wrap with a // try-delegate, so we wrap the whole try-catch-end with a try-delegate and // make it rethrow to the right destination, as in the example below: // try // try ;; (new) // try // call @foo // catch __cpp_exception ;; ehpad A (next unwind dest: caller) // ... // end_try // delegate 1 (caller) ;; (new) // catch_all ;; ehpad B // ... // end_try const auto *EHInfo = MF.getWasmEHFuncInfo(); SmallVector EHPadStack; // For EH pads that have catch unwind mismatches, a map of . DenseMap EHPadToUnwindDest; for (auto &MBB : reverse(MF)) { for (auto &MI : reverse(MBB)) { if (MI.getOpcode() == WebAssembly::TRY) EHPadStack.pop_back(); else if (MI.getOpcode() == WebAssembly::DELEGATE) EHPadStack.push_back(&MBB); else if (WebAssembly::isCatch(MI.getOpcode())) { auto *EHPad = &MBB; // catch_all always catches an exception, so we don't need to do // anything if (MI.getOpcode() == WebAssembly::CATCH_ALL) { } // This can happen when the unwind dest was removed during the // optimization, e.g. because it was unreachable. else if (EHPadStack.empty() && EHInfo->hasUnwindDest(EHPad)) { LLVM_DEBUG(dbgs() << "EHPad (" << EHPad->getName() << "'s unwind destination does not exist anymore" << "\n\n"); } // The EHPad's next unwind destination is the caller, but we incorrectly // unwind to another EH pad. else if (!EHPadStack.empty() && !EHInfo->hasUnwindDest(EHPad)) { EHPadToUnwindDest[EHPad] = getFakeCallerBlock(MF); LLVM_DEBUG(dbgs() << "- Catch unwind mismatch:\nEHPad = " << EHPad->getName() << " Original dest = caller Current dest = " << EHPadStack.back()->getName() << "\n\n"); } // The EHPad's next unwind destination is an EH pad, whereas we // incorrectly unwind to another EH pad. else if (!EHPadStack.empty() && EHInfo->hasUnwindDest(EHPad)) { auto *UnwindDest = EHInfo->getUnwindDest(EHPad); if (EHPadStack.back() != UnwindDest) { EHPadToUnwindDest[EHPad] = UnwindDest; LLVM_DEBUG(dbgs() << "- Catch unwind mismatch:\nEHPad = " << EHPad->getName() << " Original dest = " << UnwindDest->getName() << " Current dest = " << EHPadStack.back()->getName() << "\n\n"); } } EHPadStack.push_back(EHPad); } } } assert(EHPadStack.empty()); if (EHPadToUnwindDest.empty()) return false; NumCatchUnwindMismatches += EHPadToUnwindDest.size(); SmallPtrSet NewEndTryBBs; for (auto &P : EHPadToUnwindDest) { MachineBasicBlock *EHPad = P.first; MachineBasicBlock *UnwindDest = P.second; MachineInstr *Try = EHPadToTry[EHPad]; MachineInstr *EndTry = BeginToEnd[Try]; addTryDelegate(Try, EndTry, UnwindDest); NewEndTryBBs.insert(EndTry->getParent()); } // Adding a try-delegate wrapping an existing try-catch-end can make existing // branch destination BBs invalid. For example, // // - Before: // bb0: // block // br bb3 // bb1: // try // ... // bb2: (ehpad) // catch // bb3: // end_try // end_block ;; 'br bb3' targets here // // Suppose this try-catch-end has a catch unwind mismatch, so we need to wrap // this with a try-delegate. Then this becomes: // // - After: // bb0: // block // br bb3 ;; invalid destination! // bb1: // try ;; (new instruction) // try // ... // bb2: (ehpad) // catch // bb3: // end_try ;; 'br bb3' still incorrectly targets here! // delegate_bb: ;; (new BB) // delegate ;; (new instruction) // split_bb: ;; (new BB) // end_block // // Now 'br bb3' incorrectly branches to an inner scope. // // As we can see in this case, when branches target a BB that has both // 'end_try' and 'end_block' and the BB is split to insert a 'delegate', we // have to remap existing branch destinations so that they target not the // 'end_try' BB but the new 'end_block' BB. There can be multiple 'delegate's // in between, so we try to find the next BB with 'end_block' instruction. In // this example, the 'br bb3' instruction should be remapped to 'br split_bb'. for (auto &MBB : MF) { for (auto &MI : MBB) { if (MI.isTerminator()) { for (auto &MO : MI.operands()) { if (MO.isMBB() && NewEndTryBBs.count(MO.getMBB())) { auto *BrDest = MO.getMBB(); bool FoundEndBlock = false; for (; std::next(BrDest->getIterator()) != MF.end(); BrDest = BrDest->getNextNode()) { for (const auto &MI : *BrDest) { if (MI.getOpcode() == WebAssembly::END_BLOCK) { FoundEndBlock = true; break; } } if (FoundEndBlock) break; } assert(FoundEndBlock); MO.setMBB(BrDest); } } } } } return true; } void WebAssemblyCFGStackify::recalculateScopeTops(MachineFunction &MF) { // Renumber BBs and recalculate ScopeTop info because new BBs might have been // created and inserted during fixing unwind mismatches. MF.RenumberBlocks(); ScopeTops.clear(); ScopeTops.resize(MF.getNumBlockIDs()); for (auto &MBB : reverse(MF)) { for (auto &MI : reverse(MBB)) { if (ScopeTops[MBB.getNumber()]) break; switch (MI.getOpcode()) { case WebAssembly::END_BLOCK: case WebAssembly::END_LOOP: case WebAssembly::END_TRY: case WebAssembly::DELEGATE: updateScopeTops(EndToBegin[&MI]->getParent(), &MBB); break; case WebAssembly::CATCH: case WebAssembly::CATCH_ALL: updateScopeTops(EHPadToTry[&MBB]->getParent(), &MBB); break; } } } } /// In normal assembly languages, when the end of a function is unreachable, /// because the function ends in an infinite loop or a noreturn call or similar, /// it isn't necessary to worry about the function return type at the end of /// the function, because it's never reached. However, in WebAssembly, blocks /// that end at the function end need to have a return type signature that /// matches the function signature, even though it's unreachable. This function /// checks for such cases and fixes up the signatures. void WebAssemblyCFGStackify::fixEndsAtEndOfFunction(MachineFunction &MF) { const auto &MFI = *MF.getInfo(); if (MFI.getResults().empty()) return; // MCInstLower will add the proper types to multivalue signatures based on the // function return type WebAssembly::BlockType RetType = MFI.getResults().size() > 1 ? WebAssembly::BlockType::Multivalue : WebAssembly::BlockType( WebAssembly::toValType(MFI.getResults().front())); SmallVector Worklist; Worklist.push_back(MF.rbegin()->rbegin()); auto Process = [&](MachineBasicBlock::reverse_iterator It) { auto *MBB = It->getParent(); while (It != MBB->rend()) { MachineInstr &MI = *It++; if (MI.isPosition() || MI.isDebugInstr()) continue; switch (MI.getOpcode()) { case WebAssembly::END_TRY: { // If a 'try''s return type is fixed, both its try body and catch body // should satisfy the return type, so we need to search 'end' // instructions before its corresponding 'catch' too. auto *EHPad = TryToEHPad.lookup(EndToBegin[&MI]); assert(EHPad); auto NextIt = std::next(WebAssembly::findCatch(EHPad)->getReverseIterator()); if (NextIt != EHPad->rend()) Worklist.push_back(NextIt); [[fallthrough]]; } case WebAssembly::END_BLOCK: case WebAssembly::END_LOOP: case WebAssembly::DELEGATE: EndToBegin[&MI]->getOperand(0).setImm(int32_t(RetType)); continue; default: // Something other than an `end`. We're done for this BB. return; } } // We've reached the beginning of a BB. Continue the search in the previous // BB. Worklist.push_back(MBB->getPrevNode()->rbegin()); }; while (!Worklist.empty()) Process(Worklist.pop_back_val()); } // WebAssembly functions end with an end instruction, as if the function body // were a block. static void appendEndToFunction(MachineFunction &MF, const WebAssemblyInstrInfo &TII) { BuildMI(MF.back(), MF.back().end(), MF.back().findPrevDebugLoc(MF.back().end()), TII.get(WebAssembly::END_FUNCTION)); } /// Insert LOOP/TRY/BLOCK markers at appropriate places. void WebAssemblyCFGStackify::placeMarkers(MachineFunction &MF) { // We allocate one more than the number of blocks in the function to // accommodate for the possible fake block we may insert at the end. ScopeTops.resize(MF.getNumBlockIDs() + 1); // Place the LOOP for MBB if MBB is the header of a loop. for (auto &MBB : MF) placeLoopMarker(MBB); const MCAsmInfo *MCAI = MF.getTarget().getMCAsmInfo(); for (auto &MBB : MF) { if (MBB.isEHPad()) { // Place the TRY for MBB if MBB is the EH pad of an exception. if (MCAI->getExceptionHandlingType() == ExceptionHandling::Wasm && MF.getFunction().hasPersonalityFn()) placeTryMarker(MBB); } else { // Place the BLOCK for MBB if MBB is branched to from above. placeBlockMarker(MBB); } } // Fix mismatches in unwind destinations induced by linearizing the code. if (MCAI->getExceptionHandlingType() == ExceptionHandling::Wasm && MF.getFunction().hasPersonalityFn()) { bool Changed = fixCallUnwindMismatches(MF); Changed |= fixCatchUnwindMismatches(MF); if (Changed) recalculateScopeTops(MF); } } unsigned WebAssemblyCFGStackify::getBranchDepth( const SmallVectorImpl &Stack, const MachineBasicBlock *MBB) { unsigned Depth = 0; for (auto X : reverse(Stack)) { if (X.first == MBB) break; ++Depth; } assert(Depth < Stack.size() && "Branch destination should be in scope"); return Depth; } unsigned WebAssemblyCFGStackify::getDelegateDepth( const SmallVectorImpl &Stack, const MachineBasicBlock *MBB) { if (MBB == FakeCallerBB) return Stack.size(); // Delegate's destination is either a catch or a another delegate BB. When the // destination is another delegate, we can compute the argument in the same // way as branches, because the target delegate BB only contains the single // delegate instruction. if (!MBB->isEHPad()) // Target is a delegate BB return getBranchDepth(Stack, MBB); // When the delegate's destination is a catch BB, we need to use its // corresponding try's end_try BB because Stack contains each marker's end BB. // Also we need to check if the end marker instruction matches, because a // single BB can contain multiple end markers, like this: // bb: // END_BLOCK // END_TRY // END_BLOCK // END_TRY // ... // // In case of branches getting the immediate that targets any of these is // fine, but delegate has to exactly target the correct try. unsigned Depth = 0; const MachineInstr *EndTry = BeginToEnd[EHPadToTry[MBB]]; for (auto X : reverse(Stack)) { if (X.first == EndTry->getParent() && X.second == EndTry) break; ++Depth; } assert(Depth < Stack.size() && "Delegate destination should be in scope"); return Depth; } unsigned WebAssemblyCFGStackify::getRethrowDepth( const SmallVectorImpl &Stack, const SmallVectorImpl &EHPadStack) { unsigned Depth = 0; // In our current implementation, rethrows always rethrow the exception caught // by the innermost enclosing catch. This means while traversing Stack in the // reverse direction, when we encounter END_TRY, we should check if the // END_TRY corresponds to the current innermost EH pad. For example: // try // ... // catch ;; (a) // try // rethrow 1 ;; (b) // catch ;; (c) // rethrow 0 ;; (d) // end ;; (e) // end ;; (f) // // When we are at 'rethrow' (d), while reversely traversing Stack the first // 'end' we encounter is the 'end' (e), which corresponds to the 'catch' (c). // And 'rethrow' (d) rethrows the exception caught by 'catch' (c), so we stop // there and the depth should be 0. But when we are at 'rethrow' (b), it // rethrows the exception caught by 'catch' (a), so when traversing Stack // reversely, we should skip the 'end' (e) and choose 'end' (f), which // corresponds to 'catch' (a). for (auto X : reverse(Stack)) { const MachineInstr *End = X.second; if (End->getOpcode() == WebAssembly::END_TRY) { auto *EHPad = TryToEHPad[EndToBegin[End]]; if (EHPadStack.back() == EHPad) break; } ++Depth; } assert(Depth < Stack.size() && "Rethrow destination should be in scope"); return Depth; } void WebAssemblyCFGStackify::rewriteDepthImmediates(MachineFunction &MF) { // Now rewrite references to basic blocks to be depth immediates. SmallVector Stack; SmallVector EHPadStack; for (auto &MBB : reverse(MF)) { for (MachineInstr &MI : llvm::reverse(MBB)) { switch (MI.getOpcode()) { case WebAssembly::BLOCK: case WebAssembly::TRY: assert(ScopeTops[Stack.back().first->getNumber()]->getNumber() <= MBB.getNumber() && "Block/try marker should be balanced"); Stack.pop_back(); break; case WebAssembly::LOOP: assert(Stack.back().first == &MBB && "Loop top should be balanced"); Stack.pop_back(); break; case WebAssembly::END_BLOCK: Stack.push_back(std::make_pair(&MBB, &MI)); break; case WebAssembly::END_TRY: { // We handle DELEGATE in the default level, because DELEGATE has // immediate operands to rewrite. Stack.push_back(std::make_pair(&MBB, &MI)); auto *EHPad = TryToEHPad[EndToBegin[&MI]]; EHPadStack.push_back(EHPad); break; } case WebAssembly::END_LOOP: Stack.push_back(std::make_pair(EndToBegin[&MI]->getParent(), &MI)); break; case WebAssembly::CATCH: case WebAssembly::CATCH_ALL: EHPadStack.pop_back(); break; case WebAssembly::RETHROW: MI.getOperand(0).setImm(getRethrowDepth(Stack, EHPadStack)); break; default: if (MI.isTerminator()) { // Rewrite MBB operands to be depth immediates. SmallVector Ops(MI.operands()); while (MI.getNumOperands() > 0) MI.removeOperand(MI.getNumOperands() - 1); for (auto MO : Ops) { if (MO.isMBB()) { if (MI.getOpcode() == WebAssembly::DELEGATE) MO = MachineOperand::CreateImm( getDelegateDepth(Stack, MO.getMBB())); else MO = MachineOperand::CreateImm( getBranchDepth(Stack, MO.getMBB())); } MI.addOperand(MF, MO); } } if (MI.getOpcode() == WebAssembly::DELEGATE) Stack.push_back(std::make_pair(&MBB, &MI)); break; } } } assert(Stack.empty() && "Control flow should be balanced"); } void WebAssemblyCFGStackify::cleanupFunctionData(MachineFunction &MF) { if (FakeCallerBB) MF.deleteMachineBasicBlock(FakeCallerBB); AppendixBB = FakeCallerBB = nullptr; } void WebAssemblyCFGStackify::releaseMemory() { ScopeTops.clear(); BeginToEnd.clear(); EndToBegin.clear(); TryToEHPad.clear(); EHPadToTry.clear(); } bool WebAssemblyCFGStackify::runOnMachineFunction(MachineFunction &MF) { LLVM_DEBUG(dbgs() << "********** CFG Stackifying **********\n" "********** Function: " << MF.getName() << '\n'); const MCAsmInfo *MCAI = MF.getTarget().getMCAsmInfo(); releaseMemory(); // Liveness is not tracked for VALUE_STACK physreg. MF.getRegInfo().invalidateLiveness(); // Place the BLOCK/LOOP/TRY markers to indicate the beginnings of scopes. placeMarkers(MF); // Remove unnecessary instructions possibly introduced by try/end_trys. if (MCAI->getExceptionHandlingType() == ExceptionHandling::Wasm && MF.getFunction().hasPersonalityFn()) removeUnnecessaryInstrs(MF); // Convert MBB operands in terminators to relative depth immediates. rewriteDepthImmediates(MF); // Fix up block/loop/try signatures at the end of the function to conform to // WebAssembly's rules. fixEndsAtEndOfFunction(MF); // Add an end instruction at the end of the function body. const auto &TII = *MF.getSubtarget().getInstrInfo(); if (!MF.getSubtarget() .getTargetTriple() .isOSBinFormatELF()) appendEndToFunction(MF, TII); cleanupFunctionData(MF); MF.getInfo()->setCFGStackified(); return true; }