//===- PlaceSafepoints.cpp - Place GC Safepoints --------------------------===// // // 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 // //===----------------------------------------------------------------------===// // // Place garbage collection safepoints at appropriate locations in the IR. This // does not make relocation semantics or variable liveness explicit. That's // done by RewriteStatepointsForGC. // // Terminology: // - A call is said to be "parseable" if there is a stack map generated for the // return PC of the call. A runtime can determine where values listed in the // deopt arguments and (after RewriteStatepointsForGC) gc arguments are located // on the stack when the code is suspended inside such a call. Every parse // point is represented by a call wrapped in an gc.statepoint intrinsic. // - A "poll" is an explicit check in the generated code to determine if the // runtime needs the generated code to cooperate by calling a helper routine // and thus suspending its execution at a known state. The call to the helper // routine will be parseable. The (gc & runtime specific) logic of a poll is // assumed to be provided in a function of the name "gc.safepoint_poll". // // We aim to insert polls such that running code can quickly be brought to a // well defined state for inspection by the collector. In the current // implementation, this is done via the insertion of poll sites at method entry // and the backedge of most loops. We try to avoid inserting more polls than // are necessary to ensure a finite period between poll sites. This is not // because the poll itself is expensive in the generated code; it's not. Polls // do tend to impact the optimizer itself in negative ways; we'd like to avoid // perturbing the optimization of the method as much as we can. // // We also need to make most call sites parseable. The callee might execute a // poll (or otherwise be inspected by the GC). If so, the entire stack // (including the suspended frame of the current method) must be parseable. // // This pass will insert: // - Call parse points ("call safepoints") for any call which may need to // reach a safepoint during the execution of the callee function. // - Backedge safepoint polls and entry safepoint polls to ensure that // executing code reaches a safepoint poll in a finite amount of time. // // We do not currently support return statepoints, but adding them would not // be hard. They are not required for correctness - entry safepoints are an // alternative - but some GCs may prefer them. Patches welcome. // //===----------------------------------------------------------------------===// #include "llvm/InitializePasses.h" #include "llvm/Pass.h" #include "llvm/ADT/SetVector.h" #include "llvm/ADT/Statistic.h" #include "llvm/Analysis/CFG.h" #include "llvm/Analysis/ScalarEvolution.h" #include "llvm/Analysis/TargetLibraryInfo.h" #include "llvm/Transforms/Utils/Local.h" #include "llvm/IR/Dominators.h" #include "llvm/IR/IntrinsicInst.h" #include "llvm/IR/LegacyPassManager.h" #include "llvm/IR/Statepoint.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/Debug.h" #include "llvm/Transforms/Scalar.h" #include "llvm/Transforms/Utils/BasicBlockUtils.h" #include "llvm/Transforms/Utils/Cloning.h" #define DEBUG_TYPE "safepoint-placement" STATISTIC(NumEntrySafepoints, "Number of entry safepoints inserted"); STATISTIC(NumBackedgeSafepoints, "Number of backedge safepoints inserted"); STATISTIC(CallInLoop, "Number of loops without safepoints due to calls in loop"); STATISTIC(FiniteExecution, "Number of loops without safepoints finite execution"); using namespace llvm; // Ignore opportunities to avoid placing safepoints on backedges, useful for // validation static cl::opt AllBackedges("spp-all-backedges", cl::Hidden, cl::init(false)); /// How narrow does the trip count of a loop have to be to have to be considered /// "counted"? Counted loops do not get safepoints at backedges. static cl::opt CountedLoopTripWidth("spp-counted-loop-trip-width", cl::Hidden, cl::init(32)); // If true, split the backedge of a loop when placing the safepoint, otherwise // split the latch block itself. Both are useful to support for // experimentation, but in practice, it looks like splitting the backedge // optimizes better. static cl::opt SplitBackedge("spp-split-backedge", cl::Hidden, cl::init(false)); namespace { /// An analysis pass whose purpose is to identify each of the backedges in /// the function which require a safepoint poll to be inserted. struct PlaceBackedgeSafepointsImpl : public FunctionPass { static char ID; /// The output of the pass - gives a list of each backedge (described by /// pointing at the branch) which need a poll inserted. std::vector PollLocations; /// True unless we're running spp-no-calls in which case we need to disable /// the call-dependent placement opts. bool CallSafepointsEnabled; ScalarEvolution *SE = nullptr; DominatorTree *DT = nullptr; LoopInfo *LI = nullptr; TargetLibraryInfo *TLI = nullptr; PlaceBackedgeSafepointsImpl(bool CallSafepoints = false) : FunctionPass(ID), CallSafepointsEnabled(CallSafepoints) { initializePlaceBackedgeSafepointsImplPass(*PassRegistry::getPassRegistry()); } bool runOnLoop(Loop *); void runOnLoopAndSubLoops(Loop *L) { // Visit all the subloops for (Loop *I : *L) runOnLoopAndSubLoops(I); runOnLoop(L); } bool runOnFunction(Function &F) override { SE = &getAnalysis().getSE(); DT = &getAnalysis().getDomTree(); LI = &getAnalysis().getLoopInfo(); TLI = &getAnalysis().getTLI(F); for (Loop *I : *LI) { runOnLoopAndSubLoops(I); } return false; } void getAnalysisUsage(AnalysisUsage &AU) const override { AU.addRequired(); AU.addRequired(); AU.addRequired(); AU.addRequired(); // We no longer modify the IR at all in this pass. Thus all // analysis are preserved. AU.setPreservesAll(); } }; } static cl::opt NoEntry("spp-no-entry", cl::Hidden, cl::init(false)); static cl::opt NoCall("spp-no-call", cl::Hidden, cl::init(false)); static cl::opt NoBackedge("spp-no-backedge", cl::Hidden, cl::init(false)); namespace { struct PlaceSafepoints : public FunctionPass { static char ID; // Pass identification, replacement for typeid PlaceSafepoints() : FunctionPass(ID) { initializePlaceSafepointsPass(*PassRegistry::getPassRegistry()); } bool runOnFunction(Function &F) override; void getAnalysisUsage(AnalysisUsage &AU) const override { // We modify the graph wholesale (inlining, block insertion, etc). We // preserve nothing at the moment. We could potentially preserve dom tree // if that was worth doing AU.addRequired(); } }; } // Insert a safepoint poll immediately before the given instruction. Does // not handle the parsability of state at the runtime call, that's the // callers job. static void InsertSafepointPoll(Instruction *InsertBefore, std::vector &ParsePointsNeeded /*rval*/, const TargetLibraryInfo &TLI); static bool needsStatepoint(CallBase *Call, const TargetLibraryInfo &TLI) { if (callsGCLeafFunction(Call, TLI)) return false; if (auto *CI = dyn_cast(Call)) { if (CI->isInlineAsm()) return false; } return !(isa(Call) || isa(Call) || isa(Call)); } /// Returns true if this loop is known to contain a call safepoint which /// must unconditionally execute on any iteration of the loop which returns /// to the loop header via an edge from Pred. Returns a conservative correct /// answer; i.e. false is always valid. static bool containsUnconditionalCallSafepoint(Loop *L, BasicBlock *Header, BasicBlock *Pred, DominatorTree &DT, const TargetLibraryInfo &TLI) { // In general, we're looking for any cut of the graph which ensures // there's a call safepoint along every edge between Header and Pred. // For the moment, we look only for the 'cuts' that consist of a single call // instruction in a block which is dominated by the Header and dominates the // loop latch (Pred) block. Somewhat surprisingly, walking the entire chain // of such dominating blocks gets substantially more occurrences than just // checking the Pred and Header blocks themselves. This may be due to the // density of loop exit conditions caused by range and null checks. // TODO: structure this as an analysis pass, cache the result for subloops, // avoid dom tree recalculations assert(DT.dominates(Header, Pred) && "loop latch not dominated by header?"); BasicBlock *Current = Pred; while (true) { for (Instruction &I : *Current) { if (auto *Call = dyn_cast(&I)) // Note: Technically, needing a safepoint isn't quite the right // condition here. We should instead be checking if the target method // has an // unconditional poll. In practice, this is only a theoretical concern // since we don't have any methods with conditional-only safepoint // polls. if (needsStatepoint(Call, TLI)) return true; } if (Current == Header) break; Current = DT.getNode(Current)->getIDom()->getBlock(); } return false; } /// Returns true if this loop is known to terminate in a finite number of /// iterations. Note that this function may return false for a loop which /// does actual terminate in a finite constant number of iterations due to /// conservatism in the analysis. static bool mustBeFiniteCountedLoop(Loop *L, ScalarEvolution *SE, BasicBlock *Pred) { // A conservative bound on the loop as a whole. const SCEV *MaxTrips = SE->getConstantMaxBackedgeTakenCount(L); if (!isa(MaxTrips) && SE->getUnsignedRange(MaxTrips).getUnsignedMax().isIntN( CountedLoopTripWidth)) return true; // If this is a conditional branch to the header with the alternate path // being outside the loop, we can ask questions about the execution frequency // of the exit block. if (L->isLoopExiting(Pred)) { // This returns an exact expression only. TODO: We really only need an // upper bound here, but SE doesn't expose that. const SCEV *MaxExec = SE->getExitCount(L, Pred); if (!isa(MaxExec) && SE->getUnsignedRange(MaxExec).getUnsignedMax().isIntN( CountedLoopTripWidth)) return true; } return /* not finite */ false; } static void scanOneBB(Instruction *Start, Instruction *End, std::vector &Calls, DenseSet &Seen, std::vector &Worklist) { for (BasicBlock::iterator BBI(Start), BBE0 = Start->getParent()->end(), BBE1 = BasicBlock::iterator(End); BBI != BBE0 && BBI != BBE1; BBI++) { if (CallInst *CI = dyn_cast(&*BBI)) Calls.push_back(CI); // FIXME: This code does not handle invokes assert(!isa(&*BBI) && "support for invokes in poll code needed"); // Only add the successor blocks if we reach the terminator instruction // without encountering end first if (BBI->isTerminator()) { BasicBlock *BB = BBI->getParent(); for (BasicBlock *Succ : successors(BB)) { if (Seen.insert(Succ).second) { Worklist.push_back(Succ); } } } } } static void scanInlinedCode(Instruction *Start, Instruction *End, std::vector &Calls, DenseSet &Seen) { Calls.clear(); std::vector Worklist; Seen.insert(Start->getParent()); scanOneBB(Start, End, Calls, Seen, Worklist); while (!Worklist.empty()) { BasicBlock *BB = Worklist.back(); Worklist.pop_back(); scanOneBB(&*BB->begin(), End, Calls, Seen, Worklist); } } bool PlaceBackedgeSafepointsImpl::runOnLoop(Loop *L) { // Loop through all loop latches (branches controlling backedges). We need // to place a safepoint on every backedge (potentially). // Note: In common usage, there will be only one edge due to LoopSimplify // having run sometime earlier in the pipeline, but this code must be correct // w.r.t. loops with multiple backedges. BasicBlock *Header = L->getHeader(); SmallVector LoopLatches; L->getLoopLatches(LoopLatches); for (BasicBlock *Pred : LoopLatches) { assert(L->contains(Pred)); // Make a policy decision about whether this loop needs a safepoint or // not. Note that this is about unburdening the optimizer in loops, not // avoiding the runtime cost of the actual safepoint. if (!AllBackedges) { if (mustBeFiniteCountedLoop(L, SE, Pred)) { LLVM_DEBUG(dbgs() << "skipping safepoint placement in finite loop\n"); FiniteExecution++; continue; } if (CallSafepointsEnabled && containsUnconditionalCallSafepoint(L, Header, Pred, *DT, *TLI)) { // Note: This is only semantically legal since we won't do any further // IPO or inlining before the actual call insertion.. If we hadn't, we // might latter loose this call safepoint. LLVM_DEBUG( dbgs() << "skipping safepoint placement due to unconditional call\n"); CallInLoop++; continue; } } // TODO: We can create an inner loop which runs a finite number of // iterations with an outer loop which contains a safepoint. This would // not help runtime performance that much, but it might help our ability to // optimize the inner loop. // Safepoint insertion would involve creating a new basic block (as the // target of the current backedge) which does the safepoint (of all live // variables) and branches to the true header Instruction *Term = Pred->getTerminator(); LLVM_DEBUG(dbgs() << "[LSP] terminator instruction: " << *Term); PollLocations.push_back(Term); } return false; } /// Returns true if an entry safepoint is not required before this callsite in /// the caller function. static bool doesNotRequireEntrySafepointBefore(CallBase *Call) { if (IntrinsicInst *II = dyn_cast(Call)) { switch (II->getIntrinsicID()) { case Intrinsic::experimental_gc_statepoint: case Intrinsic::experimental_patchpoint_void: case Intrinsic::experimental_patchpoint_i64: // The can wrap an actual call which may grow the stack by an unbounded // amount or run forever. return false; default: // Most LLVM intrinsics are things which do not expand to actual calls, or // at least if they do, are leaf functions that cause only finite stack // growth. In particular, the optimizer likes to form things like memsets // out of stores in the original IR. Another important example is // llvm.localescape which must occur in the entry block. Inserting a // safepoint before it is not legal since it could push the localescape // out of the entry block. return true; } } return false; } static Instruction *findLocationForEntrySafepoint(Function &F, DominatorTree &DT) { // Conceptually, this poll needs to be on method entry, but in // practice, we place it as late in the entry block as possible. We // can place it as late as we want as long as it dominates all calls // that can grow the stack. This, combined with backedge polls, // give us all the progress guarantees we need. // hasNextInstruction and nextInstruction are used to iterate // through a "straight line" execution sequence. auto HasNextInstruction = [](Instruction *I) { if (!I->isTerminator()) return true; BasicBlock *nextBB = I->getParent()->getUniqueSuccessor(); return nextBB && (nextBB->getUniquePredecessor() != nullptr); }; auto NextInstruction = [&](Instruction *I) { assert(HasNextInstruction(I) && "first check if there is a next instruction!"); if (I->isTerminator()) return &I->getParent()->getUniqueSuccessor()->front(); return &*++I->getIterator(); }; Instruction *Cursor = nullptr; for (Cursor = &F.getEntryBlock().front(); HasNextInstruction(Cursor); Cursor = NextInstruction(Cursor)) { // We need to ensure a safepoint poll occurs before any 'real' call. The // easiest way to ensure finite execution between safepoints in the face of // recursive and mutually recursive functions is to enforce that each take // a safepoint. Additionally, we need to ensure a poll before any call // which can grow the stack by an unbounded amount. This isn't required // for GC semantics per se, but is a common requirement for languages // which detect stack overflow via guard pages and then throw exceptions. if (auto *Call = dyn_cast(Cursor)) { if (doesNotRequireEntrySafepointBefore(Call)) continue; break; } } assert((HasNextInstruction(Cursor) || Cursor->isTerminator()) && "either we stopped because of a call, or because of terminator"); return Cursor; } const char GCSafepointPollName[] = "gc.safepoint_poll"; static bool isGCSafepointPoll(Function &F) { return F.getName().equals(GCSafepointPollName); } /// Returns true if this function should be rewritten to include safepoint /// polls and parseable call sites. The main point of this function is to be /// an extension point for custom logic. static bool shouldRewriteFunction(Function &F) { // TODO: This should check the GCStrategy if (F.hasGC()) { const auto &FunctionGCName = F.getGC(); const StringRef StatepointExampleName("statepoint-example"); const StringRef CoreCLRName("coreclr"); return (StatepointExampleName == FunctionGCName) || (CoreCLRName == FunctionGCName); } else return false; } // TODO: These should become properties of the GCStrategy, possibly with // command line overrides. static bool enableEntrySafepoints(Function &F) { return !NoEntry; } static bool enableBackedgeSafepoints(Function &F) { return !NoBackedge; } static bool enableCallSafepoints(Function &F) { return !NoCall; } bool PlaceSafepoints::runOnFunction(Function &F) { if (F.isDeclaration() || F.empty()) { // This is a declaration, nothing to do. Must exit early to avoid crash in // dom tree calculation return false; } if (isGCSafepointPoll(F)) { // Given we're inlining this inside of safepoint poll insertion, this // doesn't make any sense. Note that we do make any contained calls // parseable after we inline a poll. return false; } if (!shouldRewriteFunction(F)) return false; const TargetLibraryInfo &TLI = getAnalysis().getTLI(F); bool Modified = false; // In various bits below, we rely on the fact that uses are reachable from // defs. When there are basic blocks unreachable from the entry, dominance // and reachablity queries return non-sensical results. Thus, we preprocess // the function to ensure these properties hold. Modified |= removeUnreachableBlocks(F); // STEP 1 - Insert the safepoint polling locations. We do not need to // actually insert parse points yet. That will be done for all polls and // calls in a single pass. DominatorTree DT; DT.recalculate(F); SmallVector PollsNeeded; std::vector ParsePointNeeded; if (enableBackedgeSafepoints(F)) { // Construct a pass manager to run the LoopPass backedge logic. We // need the pass manager to handle scheduling all the loop passes // appropriately. Doing this by hand is painful and just not worth messing // with for the moment. legacy::FunctionPassManager FPM(F.getParent()); bool CanAssumeCallSafepoints = enableCallSafepoints(F); auto *PBS = new PlaceBackedgeSafepointsImpl(CanAssumeCallSafepoints); FPM.add(PBS); FPM.run(F); // We preserve dominance information when inserting the poll, otherwise // we'd have to recalculate this on every insert DT.recalculate(F); auto &PollLocations = PBS->PollLocations; auto OrderByBBName = [](Instruction *a, Instruction *b) { return a->getParent()->getName() < b->getParent()->getName(); }; // We need the order of list to be stable so that naming ends up stable // when we split edges. This makes test cases much easier to write. llvm::sort(PollLocations, OrderByBBName); // We can sometimes end up with duplicate poll locations. This happens if // a single loop is visited more than once. The fact this happens seems // wrong, but it does happen for the split-backedge.ll test case. PollLocations.erase(std::unique(PollLocations.begin(), PollLocations.end()), PollLocations.end()); // Insert a poll at each point the analysis pass identified // The poll location must be the terminator of a loop latch block. for (Instruction *Term : PollLocations) { // We are inserting a poll, the function is modified Modified = true; if (SplitBackedge) { // Split the backedge of the loop and insert the poll within that new // basic block. This creates a loop with two latches per original // latch (which is non-ideal), but this appears to be easier to // optimize in practice than inserting the poll immediately before the // latch test. // Since this is a latch, at least one of the successors must dominate // it. Its possible that we have a) duplicate edges to the same header // and b) edges to distinct loop headers. We need to insert pools on // each. SetVector Headers; for (unsigned i = 0; i < Term->getNumSuccessors(); i++) { BasicBlock *Succ = Term->getSuccessor(i); if (DT.dominates(Succ, Term->getParent())) { Headers.insert(Succ); } } assert(!Headers.empty() && "poll location is not a loop latch?"); // The split loop structure here is so that we only need to recalculate // the dominator tree once. Alternatively, we could just keep it up to // date and use a more natural merged loop. SetVector SplitBackedges; for (BasicBlock *Header : Headers) { BasicBlock *NewBB = SplitEdge(Term->getParent(), Header, &DT); PollsNeeded.push_back(NewBB->getTerminator()); NumBackedgeSafepoints++; } } else { // Split the latch block itself, right before the terminator. PollsNeeded.push_back(Term); NumBackedgeSafepoints++; } } } if (enableEntrySafepoints(F)) { if (Instruction *Location = findLocationForEntrySafepoint(F, DT)) { PollsNeeded.push_back(Location); Modified = true; NumEntrySafepoints++; } // TODO: else we should assert that there was, in fact, a policy choice to // not insert a entry safepoint poll. } // Now that we've identified all the needed safepoint poll locations, insert // safepoint polls themselves. for (Instruction *PollLocation : PollsNeeded) { std::vector RuntimeCalls; InsertSafepointPoll(PollLocation, RuntimeCalls, TLI); llvm::append_range(ParsePointNeeded, RuntimeCalls); } return Modified; } char PlaceBackedgeSafepointsImpl::ID = 0; char PlaceSafepoints::ID = 0; FunctionPass *llvm::createPlaceSafepointsPass() { return new PlaceSafepoints(); } INITIALIZE_PASS_BEGIN(PlaceBackedgeSafepointsImpl, "place-backedge-safepoints-impl", "Place Backedge Safepoints", false, false) INITIALIZE_PASS_DEPENDENCY(ScalarEvolutionWrapperPass) INITIALIZE_PASS_DEPENDENCY(DominatorTreeWrapperPass) INITIALIZE_PASS_DEPENDENCY(LoopInfoWrapperPass) INITIALIZE_PASS_END(PlaceBackedgeSafepointsImpl, "place-backedge-safepoints-impl", "Place Backedge Safepoints", false, false) INITIALIZE_PASS_BEGIN(PlaceSafepoints, "place-safepoints", "Place Safepoints", false, false) INITIALIZE_PASS_END(PlaceSafepoints, "place-safepoints", "Place Safepoints", false, false) static void InsertSafepointPoll(Instruction *InsertBefore, std::vector &ParsePointsNeeded /*rval*/, const TargetLibraryInfo &TLI) { BasicBlock *OrigBB = InsertBefore->getParent(); Module *M = InsertBefore->getModule(); assert(M && "must be part of a module"); // Inline the safepoint poll implementation - this will get all the branch, // control flow, etc.. Most importantly, it will introduce the actual slow // path call - where we need to insert a safepoint (parsepoint). auto *F = M->getFunction(GCSafepointPollName); assert(F && "gc.safepoint_poll function is missing"); assert(F->getValueType() == FunctionType::get(Type::getVoidTy(M->getContext()), false) && "gc.safepoint_poll declared with wrong type"); assert(!F->empty() && "gc.safepoint_poll must be a non-empty function"); CallInst *PollCall = CallInst::Create(F, "", InsertBefore); // Record some information about the call site we're replacing BasicBlock::iterator Before(PollCall), After(PollCall); bool IsBegin = false; if (Before == OrigBB->begin()) IsBegin = true; else Before--; After++; assert(After != OrigBB->end() && "must have successor"); // Do the actual inlining InlineFunctionInfo IFI; bool InlineStatus = InlineFunction(*PollCall, IFI).isSuccess(); assert(InlineStatus && "inline must succeed"); (void)InlineStatus; // suppress warning in release-asserts // Check post-conditions assert(IFI.StaticAllocas.empty() && "can't have allocs"); std::vector Calls; // new calls DenseSet BBs; // new BBs + insertee // Include only the newly inserted instructions, Note: begin may not be valid // if we inserted to the beginning of the basic block BasicBlock::iterator Start = IsBegin ? OrigBB->begin() : std::next(Before); // If your poll function includes an unreachable at the end, that's not // valid. Bugpoint likes to create this, so check for it. assert(isPotentiallyReachable(&*Start, &*After) && "malformed poll function"); scanInlinedCode(&*Start, &*After, Calls, BBs); assert(!Calls.empty() && "slow path not found for safepoint poll"); // Record the fact we need a parsable state at the runtime call contained in // the poll function. This is required so that the runtime knows how to // parse the last frame when we actually take the safepoint (i.e. execute // the slow path) assert(ParsePointsNeeded.empty()); for (auto *CI : Calls) { // No safepoint needed or wanted if (!needsStatepoint(CI, TLI)) continue; // These are likely runtime calls. Should we assert that via calling // convention or something? ParsePointsNeeded.push_back(CI); } assert(ParsePointsNeeded.size() <= Calls.size()); }