llvm-mirror/lib/Analysis/CGSCCPassManager.cpp

//===- CGSCCPassManager.cpp - Managing & running CGSCC passes -------------===//
//
//                     The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//

#include "llvm/Analysis/CGSCCPassManager.h"
#include "llvm/IR/CallSite.h"
#include "llvm/IR/InstIterator.h"

using namespace llvm;

// Explicit template instantiations and specialization defininitions for core
// template typedefs.
namespace llvm {

// Explicit instantiations for the core proxy templates.
template class AllAnalysesOn<LazyCallGraph::SCC>;
template class AnalysisManager<LazyCallGraph::SCC, LazyCallGraph &>;
template class PassManager<LazyCallGraph::SCC, CGSCCAnalysisManager,
                           LazyCallGraph &, CGSCCUpdateResult &>;
template class InnerAnalysisManagerProxy<CGSCCAnalysisManager, Module>;
template class OuterAnalysisManagerProxy<ModuleAnalysisManager,
                                         LazyCallGraph::SCC>;
template class OuterAnalysisManagerProxy<CGSCCAnalysisManager, Function>;

/// Explicitly specialize the pass manager run method to handle call graph
/// updates.
template <>
PreservedAnalyses
PassManager<LazyCallGraph::SCC, CGSCCAnalysisManager, LazyCallGraph &,
            CGSCCUpdateResult &>::run(LazyCallGraph::SCC &InitialC,
                                      CGSCCAnalysisManager &AM,
                                      LazyCallGraph &G, CGSCCUpdateResult &UR) {
  PreservedAnalyses PA = PreservedAnalyses::all();

  if (DebugLogging)
    dbgs() << "Starting CGSCC pass manager run.\n";

  // The SCC may be refined while we are running passes over it, so set up
  // a pointer that we can update.
  LazyCallGraph::SCC *C = &InitialC;

  for (auto &Pass : Passes) {
    if (DebugLogging)
      dbgs() << "Running pass: " << Pass->name() << " on " << *C << "\n";

    PreservedAnalyses PassPA = Pass->run(*C, AM, G, UR);

    // Update the SCC if necessary.
    C = UR.UpdatedC ? UR.UpdatedC : C;

    // Check that we didn't miss any update scenario.
    assert(!UR.InvalidatedSCCs.count(C) && "Processing an invalid SCC!");
    assert(C->begin() != C->end() && "Cannot have an empty SCC!");

    // Update the analysis manager as each pass runs and potentially
    // invalidates analyses.
    AM.invalidate(*C, PassPA);

    // Finally, we intersect the final preserved analyses to compute the
    // aggregate preserved set for this pass manager.
    PA.intersect(std::move(PassPA));

    // FIXME: Historically, the pass managers all called the LLVM context's
    // yield function here. We don't have a generic way to acquire the
    // context and it isn't yet clear what the right pattern is for yielding
    // in the new pass manager so it is currently omitted.
    // ...getContext().yield();
  }

  // Invaliadtion was handled after each pass in the above loop for the current
  // SCC. Therefore, the remaining analysis results in the AnalysisManager are
  // preserved. We mark this with a set so that we don't need to inspect each
  // one individually.
  PA.preserveSet<AllAnalysesOn<LazyCallGraph::SCC>>();

  if (DebugLogging)
    dbgs() << "Finished CGSCC pass manager run.\n";

  return PA;
}

bool CGSCCAnalysisManagerModuleProxy::Result::invalidate(
    Module &M, const PreservedAnalyses &PA,
    ModuleAnalysisManager::Invalidator &Inv) {
  // If literally everything is preserved, we're done.
  if (PA.areAllPreserved())
    return false; // This is still a valid proxy.

  // If this proxy or the call graph is going to be invalidated, we also need
  // to clear all the keys coming from that analysis.
  //
  // We also directly invalidate the FAM's module proxy if necessary, and if
  // that proxy isn't preserved we can't preserve this proxy either. We rely on
  // it to handle module -> function analysis invalidation in the face of
  // structural changes and so if it's unavailable we conservatively clear the
  // entire SCC layer as well rather than trying to do invalidation ourselves.
  auto PAC = PA.getChecker<CGSCCAnalysisManagerModuleProxy>();
  if (!(PAC.preserved() || PAC.preservedSet<AllAnalysesOn<Module>>()) ||
      Inv.invalidate<LazyCallGraphAnalysis>(M, PA) ||
      Inv.invalidate<FunctionAnalysisManagerModuleProxy>(M, PA)) {
    InnerAM->clear();

    // And the proxy itself should be marked as invalid so that we can observe
    // the new call graph. This isn't strictly necessary because we cheat
    // above, but is still useful.
    return true;
  }

  // Directly check if the relevant set is preserved so we can short circuit
  // invalidating SCCs below.
  bool AreSCCAnalysesPreserved =
      PA.allAnalysesInSetPreserved<AllAnalysesOn<LazyCallGraph::SCC>>();

  // Ok, we have a graph, so we can propagate the invalidation down into it.
  for (auto &RC : G->postorder_ref_sccs())
    for (auto &C : RC) {
      Optional<PreservedAnalyses> InnerPA;

      // Check to see whether the preserved set needs to be adjusted based on
      // module-level analysis invalidation triggering deferred invalidation
      // for this SCC.
      if (auto *OuterProxy =
              InnerAM->getCachedResult<ModuleAnalysisManagerCGSCCProxy>(C))
        for (const auto &OuterInvalidationPair :
             OuterProxy->getOuterInvalidations()) {
          AnalysisKey *OuterAnalysisID = OuterInvalidationPair.first;
          const auto &InnerAnalysisIDs = OuterInvalidationPair.second;
          if (Inv.invalidate(OuterAnalysisID, M, PA)) {
            if (!InnerPA)
              InnerPA = PA;
            for (AnalysisKey *InnerAnalysisID : InnerAnalysisIDs)
              InnerPA->abandon(InnerAnalysisID);
          }
        }

      // Check if we needed a custom PA set. If so we'll need to run the inner
      // invalidation.
      if (InnerPA) {
        InnerAM->invalidate(C, *InnerPA);
        continue;
      }

      // Otherwise we only need to do invalidation if the original PA set didn't
      // preserve all SCC analyses.
      if (!AreSCCAnalysesPreserved)
        InnerAM->invalidate(C, PA);
    }

  // Return false to indicate that this result is still a valid proxy.
  return false;
}

template <>
CGSCCAnalysisManagerModuleProxy::Result
CGSCCAnalysisManagerModuleProxy::run(Module &M, ModuleAnalysisManager &AM) {
  // Force the Function analysis manager to also be available so that it can
  // be accessed in an SCC analysis and proxied onward to function passes.
  // FIXME: It is pretty awkward to just drop the result here and assert that
  // we can find it again later.
  (void)AM.getResult<FunctionAnalysisManagerModuleProxy>(M);

  return Result(*InnerAM, AM.getResult<LazyCallGraphAnalysis>(M));
}

AnalysisKey FunctionAnalysisManagerCGSCCProxy::Key;

FunctionAnalysisManagerCGSCCProxy::Result
FunctionAnalysisManagerCGSCCProxy::run(LazyCallGraph::SCC &C,
                                       CGSCCAnalysisManager &AM,
                                       LazyCallGraph &CG) {
  // Collect the FunctionAnalysisManager from the Module layer and use that to
  // build the proxy result.
  //
  // This allows us to rely on the FunctionAnalysisMangaerModuleProxy to
  // invalidate the function analyses.
  auto &MAM = AM.getResult<ModuleAnalysisManagerCGSCCProxy>(C, CG).getManager();
  Module &M = *C.begin()->getFunction().getParent();
  auto *FAMProxy = MAM.getCachedResult<FunctionAnalysisManagerModuleProxy>(M);
  assert(FAMProxy && "The CGSCC pass manager requires that the FAM module "
                     "proxy is run on the module prior to entering the CGSCC "
                     "walk.");

  // Note that we special-case invalidation handling of this proxy in the CGSCC
  // analysis manager's Module proxy. This avoids the need to do anything
  // special here to recompute all of this if ever the FAM's module proxy goes
  // away.
  return Result(FAMProxy->getManager());
}

bool FunctionAnalysisManagerCGSCCProxy::Result::invalidate(
    LazyCallGraph::SCC &C, const PreservedAnalyses &PA,
    CGSCCAnalysisManager::Invalidator &Inv) {
  for (LazyCallGraph::Node &N : C)
    FAM->invalidate(N.getFunction(), PA);

  // This proxy doesn't need to handle invalidation itself. Instead, the
  // module-level CGSCC proxy handles it above by ensuring that if the
  // module-level FAM proxy becomes invalid the entire SCC layer, which
  // includes this proxy, is cleared.
  return false;
}

} // End llvm namespace

namespace {
/// Helper function to update both the \c CGSCCAnalysisManager \p AM and the \c
/// CGSCCPassManager's \c CGSCCUpdateResult \p UR based on a range of newly
/// added SCCs.
///
/// The range of new SCCs must be in postorder already. The SCC they were split
/// out of must be provided as \p C. The current node being mutated and
/// triggering updates must be passed as \p N.
///
/// This function returns the SCC containing \p N. This will be either \p C if
/// no new SCCs have been split out, or it will be the new SCC containing \p N.
template <typename SCCRangeT>
LazyCallGraph::SCC *
incorporateNewSCCRange(const SCCRangeT &NewSCCRange, LazyCallGraph &G,
                       LazyCallGraph::Node &N, LazyCallGraph::SCC *C,
                       CGSCCAnalysisManager &AM, CGSCCUpdateResult &UR,
                       bool DebugLogging = false) {
  typedef LazyCallGraph::SCC SCC;

  if (NewSCCRange.begin() == NewSCCRange.end())
    return C;

  // Add the current SCC to the worklist as its shape has changed.
  UR.CWorklist.insert(C);
  if (DebugLogging)
    dbgs() << "Enqueuing the existing SCC in the worklist:" << *C << "\n";

  SCC *OldC = C;
  (void)OldC;

  // Update the current SCC. Note that if we have new SCCs, this must actually
  // change the SCC.
  assert(C != &*NewSCCRange.begin() &&
         "Cannot insert new SCCs without changing current SCC!");
  C = &*NewSCCRange.begin();
  assert(G.lookupSCC(N) == C && "Failed to update current SCC!");

  for (SCC &NewC :
       reverse(make_range(std::next(NewSCCRange.begin()), NewSCCRange.end()))) {
    assert(C != &NewC && "No need to re-visit the current SCC!");
    assert(OldC != &NewC && "Already handled the original SCC!");
    UR.CWorklist.insert(&NewC);
    if (DebugLogging)
      dbgs() << "Enqueuing a newly formed SCC:" << NewC << "\n";
  }
  return C;
}
}

LazyCallGraph::SCC &llvm::updateCGAndAnalysisManagerForFunctionPass(
    LazyCallGraph &G, LazyCallGraph::SCC &InitialC, LazyCallGraph::Node &N,
    CGSCCAnalysisManager &AM, CGSCCUpdateResult &UR, bool DebugLogging) {
  typedef LazyCallGraph::Node Node;
  typedef LazyCallGraph::Edge Edge;
  typedef LazyCallGraph::SCC SCC;
  typedef LazyCallGraph::RefSCC RefSCC;

  RefSCC &InitialRC = InitialC.getOuterRefSCC();
  SCC *C = &InitialC;
  RefSCC *RC = &InitialRC;
  Function &F = N.getFunction();

  // Walk the function body and build up the set of retained, promoted, and
  // demoted edges.
  SmallVector<Constant *, 16> Worklist;
  SmallPtrSet<Constant *, 16> Visited;
  SmallPtrSet<Function *, 16> RetainedEdges;
  SmallSetVector<Function *, 4> PromotedRefTargets;
  SmallSetVector<Function *, 4> DemotedCallTargets;

  // First walk the function and handle all called functions. We do this first
  // because if there is a single call edge, whether there are ref edges is
  // irrelevant.
  for (Instruction &I : instructions(F))
    if (auto CS = CallSite(&I))
      if (Function *Callee = CS.getCalledFunction())
        if (Visited.insert(Callee).second && !Callee->isDeclaration()) {
          const Edge *E = N.lookup(*Callee);
          // FIXME: We should really handle adding new calls. While it will
          // make downstream usage more complex, there is no fundamental
          // limitation and it will allow passes within the CGSCC to be a bit
          // more flexible in what transforms they can do. Until then, we
          // verify that new calls haven't been introduced.
          assert(E && "No function transformations should introduce *new* "
                      "call edges! Any new calls should be modeled as "
                      "promoted existing ref edges!");
          RetainedEdges.insert(Callee);
          if (!E->isCall())
            PromotedRefTargets.insert(Callee);
        }

  // Now walk all references.
  for (Instruction &I : instructions(F))
    for (Value *Op : I.operand_values())
      if (Constant *C = dyn_cast<Constant>(Op))
        if (Visited.insert(C).second)
          Worklist.push_back(C);

  LazyCallGraph::visitReferences(Worklist, Visited, [&](Function &Referee) {
    const Edge *E = N.lookup(Referee);
    // FIXME: Similarly to new calls, we also currently preclude
    // introducing new references. See above for details.
    assert(E && "No function transformations should introduce *new* ref "
                "edges! Any new ref edges would require IPO which "
                "function passes aren't allowed to do!");
    RetainedEdges.insert(&Referee);
    if (E->isCall())
      DemotedCallTargets.insert(&Referee);
  });

  // First remove all of the edges that are no longer present in this function.
  // We have to build a list of dead targets first and then remove them as the
  // data structures will all be invalidated by removing them.
  SmallVector<PointerIntPair<Node *, 1, Edge::Kind>, 4> DeadTargets;
  for (Edge &E : N)
    if (!RetainedEdges.count(&E.getFunction()))
      DeadTargets.push_back({E.getNode(), E.getKind()});
  for (auto DeadTarget : DeadTargets) {
    Node &TargetN = *DeadTarget.getPointer();
    bool IsCall = DeadTarget.getInt() == Edge::Call;
    SCC &TargetC = *G.lookupSCC(TargetN);
    RefSCC &TargetRC = TargetC.getOuterRefSCC();

    if (&TargetRC != RC) {
      RC->removeOutgoingEdge(N, TargetN);
      if (DebugLogging)
        dbgs() << "Deleting outgoing edge from '" << N << "' to '" << TargetN
               << "'\n";
      continue;
    }
    if (DebugLogging)
      dbgs() << "Deleting internal " << (IsCall ? "call" : "ref")
             << " edge from '" << N << "' to '" << TargetN << "'\n";

    if (IsCall) {
      if (C != &TargetC) {
        // For separate SCCs this is trivial.
        RC->switchTrivialInternalEdgeToRef(N, TargetN);
      } else {
        // Otherwise we may end up re-structuring the call graph. First,
        // invalidate any SCC analyses. We have to do this before we split
        // functions into new SCCs and lose track of where their analyses are
        // cached.
        // FIXME: We should accept a more precise preserved set here. For
        // example, it might be possible to preserve some function analyses
        // even as the SCC structure is changed.
        AM.invalidate(*C, PreservedAnalyses::none());
        // Now update the call graph.
        C = incorporateNewSCCRange(RC->switchInternalEdgeToRef(N, TargetN), G,
                                   N, C, AM, UR, DebugLogging);
      }
    }

    auto NewRefSCCs = RC->removeInternalRefEdge(N, TargetN);
    if (!NewRefSCCs.empty()) {
      // Note that we don't bother to invalidate analyses as ref-edge
      // connectivity is not really observable in any way and is intended
      // exclusively to be used for ordering of transforms rather than for
      // analysis conclusions.

      // The RC worklist is in reverse postorder, so we first enqueue the
      // current RefSCC as it will remain the parent of all split RefSCCs, then
      // we enqueue the new ones in RPO except for the one which contains the
      // source node as that is the "bottom" we will continue processing in the
      // bottom-up walk.
      UR.RCWorklist.insert(RC);
      if (DebugLogging)
        dbgs() << "Enqueuing the existing RefSCC in the update worklist: "
               << *RC << "\n";
      // Update the RC to the "bottom".
      assert(G.lookupSCC(N) == C && "Changed the SCC when splitting RefSCCs!");
      RC = &C->getOuterRefSCC();
      assert(G.lookupRefSCC(N) == RC && "Failed to update current RefSCC!");
      assert(NewRefSCCs.front() == RC &&
             "New current RefSCC not first in the returned list!");
      for (RefSCC *NewRC : reverse(
               make_range(std::next(NewRefSCCs.begin()), NewRefSCCs.end()))) {
        assert(NewRC != RC && "Should not encounter the current RefSCC further "
                              "in the postorder list of new RefSCCs.");
        UR.RCWorklist.insert(NewRC);
        if (DebugLogging)
          dbgs() << "Enqueuing a new RefSCC in the update worklist: " << *NewRC
                 << "\n";
      }
    }
  }

  // Next demote all the call edges that are now ref edges. This helps make
  // the SCCs small which should minimize the work below as we don't want to
  // form cycles that this would break.
  for (Function *RefTarget : DemotedCallTargets) {
    Node &TargetN = *G.lookup(*RefTarget);
    SCC &TargetC = *G.lookupSCC(TargetN);
    RefSCC &TargetRC = TargetC.getOuterRefSCC();

    // The easy case is when the target RefSCC is not this RefSCC. This is
    // only supported when the target RefSCC is a child of this RefSCC.
    if (&TargetRC != RC) {
      assert(RC->isAncestorOf(TargetRC) &&
             "Cannot potentially form RefSCC cycles here!");
      RC->switchOutgoingEdgeToRef(N, TargetN);
      if (DebugLogging)
        dbgs() << "Switch outgoing call edge to a ref edge from '" << N
               << "' to '" << TargetN << "'\n";
      continue;
    }

    // We are switching an internal call edge to a ref edge. This may split up
    // some SCCs.
    if (C != &TargetC) {
      // For separate SCCs this is trivial.
      RC->switchTrivialInternalEdgeToRef(N, TargetN);
      continue;
    }

    // Otherwise we may end up re-structuring the call graph. First, invalidate
    // any SCC analyses. We have to do this before we split functions into new
    // SCCs and lose track of where their analyses are cached.
    // FIXME: We should accept a more precise preserved set here. For example,
    // it might be possible to preserve some function analyses even as the SCC
    // structure is changed.
    AM.invalidate(*C, PreservedAnalyses::none());
    // Now update the call graph.
    C = incorporateNewSCCRange(RC->switchInternalEdgeToRef(N, TargetN), G,
                               N, C, AM, UR, DebugLogging);
  }

  // Now promote ref edges into call edges.
  for (Function *CallTarget : PromotedRefTargets) {
    Node &TargetN = *G.lookup(*CallTarget);
    SCC &TargetC = *G.lookupSCC(TargetN);
    RefSCC &TargetRC = TargetC.getOuterRefSCC();

    // The easy case is when the target RefSCC is not this RefSCC. This is
    // only supported when the target RefSCC is a child of this RefSCC.
    if (&TargetRC != RC) {
      assert(RC->isAncestorOf(TargetRC) &&
             "Cannot potentially form RefSCC cycles here!");
      RC->switchOutgoingEdgeToCall(N, TargetN);
      if (DebugLogging)
        dbgs() << "Switch outgoing ref edge to a call edge from '" << N
               << "' to '" << TargetN << "'\n";
      continue;
    }
    if (DebugLogging)
      dbgs() << "Switch an internal ref edge to a call edge from '" << N
             << "' to '" << TargetN << "'\n";

    // Otherwise we are switching an internal ref edge to a call edge. This
    // may merge away some SCCs, and we add those to the UpdateResult. We also
    // need to make sure to update the worklist in the event SCCs have moved
    // before the current one in the post-order sequence.
    auto InitialSCCIndex = RC->find(*C) - RC->begin();
    auto InvalidatedSCCs = RC->switchInternalEdgeToCall(N, TargetN);
    if (!InvalidatedSCCs.empty()) {
      C = &TargetC;
      assert(G.lookupSCC(N) == C && "Failed to update current SCC!");

      // Any analyses cached for this SCC are no longer precise as the shape
      // has changed by introducing this cycle.
      AM.invalidate(*C, PreservedAnalyses::none());

      for (SCC *InvalidatedC : InvalidatedSCCs) {
        assert(InvalidatedC != C && "Cannot invalidate the current SCC!");
        UR.InvalidatedSCCs.insert(InvalidatedC);

        // Also clear any cached analyses for the SCCs that are dead. This
        // isn't really necessary for correctness but can release memory.
        AM.clear(*InvalidatedC);
      }
    }
    auto NewSCCIndex = RC->find(*C) - RC->begin();
    if (InitialSCCIndex < NewSCCIndex) {
      // Put our current SCC back onto the worklist as we'll visit other SCCs
      // that are now definitively ordered prior to the current one in the
      // post-order sequence, and may end up observing more precise context to
      // optimize the current SCC.
      UR.CWorklist.insert(C);
      if (DebugLogging)
        dbgs() << "Enqueuing the existing SCC in the worklist: " << *C << "\n";
      // Enqueue in reverse order as we pop off the back of the worklist.
      for (SCC &MovedC : reverse(make_range(RC->begin() + InitialSCCIndex,
                                            RC->begin() + NewSCCIndex))) {
        UR.CWorklist.insert(&MovedC);
        if (DebugLogging)
          dbgs() << "Enqueuing a newly earlier in post-order SCC: " << MovedC
                 << "\n";
      }
    }
  }

  assert(!UR.InvalidatedSCCs.count(C) && "Invalidated the current SCC!");
  assert(!UR.InvalidatedRefSCCs.count(RC) && "Invalidated the current RefSCC!");
  assert(&C->getOuterRefSCC() == RC && "Current SCC not in current RefSCC!");

  // Record the current RefSCC and SCC for higher layers of the CGSCC pass
  // manager now that all the updates have been applied.
  if (RC != &InitialRC)
    UR.UpdatedRC = RC;
  if (C != &InitialC)
    UR.UpdatedC = C;

  return *C;
}