Beispiel #1
0
/// Returns true if FirstIV is a SILArgument or SILInstruction in a BB that
/// dominates the BB of A.
static bool dominatesArgument(DominanceInfo *DI, SILArgument *A,
                              SILValue FirstIV) {
  SILBasicBlock *OtherBB = FirstIV->getParentBlock();
  if (!OtherBB || OtherBB == A->getParent())
    return false;
  return DI->dominates(OtherBB, A->getParent());
}
Beispiel #2
0
/// TODO: Refactor this code so the decision on whether or not to accept an
/// instruction.
bool swift::getFinalReleasesForValue(SILValue V, ReleaseTracker &Tracker) {
  llvm::SmallPtrSet<SILBasicBlock *, 16> LiveIn;
  llvm::SmallPtrSet<SILBasicBlock *, 16> UseBlocks;

  // First attempt to get the BB where this value resides.
  auto *DefBB = V->getParentBlock();
  if (!DefBB)
    return false;

  bool seenRelease = false;
  SILInstruction *OneRelease = nullptr;

  // We'll treat this like a liveness problem where the value is the def. Each
  // block that has a use of the value has the value live-in unless it is the
  // block with the value.
  for (auto *UI : V->getUses()) {
    auto *User = UI->getUser();
    auto *BB = User->getParent();

    if (!Tracker.isUserAcceptable(User))
      return false;
    Tracker.trackUser(User);

    if (BB != DefBB)
      LiveIn.insert(BB);

    // Also keep track of the blocks with uses.
    UseBlocks.insert(BB);

    // Try to speed up the trivial case of single release/dealloc.
    if (isa<StrongReleaseInst>(User) || isa<DeallocBoxInst>(User)) {
      if (!seenRelease)
        OneRelease = User;
      else
        OneRelease = nullptr;

      seenRelease = true;
    }
  }

  // Only a single release/dealloc? We're done!
  if (OneRelease) {
    Tracker.trackLastRelease(OneRelease);
    return true;
  }

  propagateLiveness(LiveIn, DefBB);

  // Now examine each block we saw a use in. If it has no successors
  // that are in LiveIn, then the last use in the block is the final
  // release/dealloc.
  for (auto *BB : UseBlocks)
    if (!successorHasLiveIn(BB, LiveIn))
      if (!addLastUse(V, BB, Tracker))
        return false;

  return true;
}
Beispiel #3
0
/// Copy the array load to the insert point.
static SILValue copyArrayLoad(SILValue ArrayStructValue,
                               SILInstruction *InsertBefore,
                               DominanceInfo *DT) {
  if (DT->dominates(ArrayStructValue->getParentBlock(),
                    InsertBefore->getParent()))
    return ArrayStructValue;

  auto *LI = cast<LoadInst>(ArrayStructValue);

  // Recursively move struct_element_addr.
  ValueBase *Val = LI->getOperand();
  auto *InsertPt = InsertBefore;
  while (!DT->dominates(Val->getParentBlock(), InsertBefore->getParent())) {
    auto *Inst = cast<StructElementAddrInst>(Val);
    Inst->moveBefore(InsertPt);
    Val = Inst->getOperand();
    InsertPt = Inst;
  }

  return cast<LoadInst>(LI->clone(InsertBefore));
}
Beispiel #4
0
// Find the final releases of the alloc_box along any given path.
// These can include paths from a release back to the alloc_box in a
// loop.
static bool
getFinalReleases(SILValue Box,
                 llvm::SmallVectorImpl<SILInstruction *> &Releases) {
  llvm::SmallPtrSet<SILBasicBlock*, 16> LiveIn;
  llvm::SmallPtrSet<SILBasicBlock*, 16> UseBlocks;

  auto *DefBB = Box->getParentBlock();

  auto seenRelease = false;
  SILInstruction *OneRelease = nullptr;

  // We'll treat this like a liveness problem where the alloc_box is
  // the def. Each block that has a use of the owning pointer has the
  // value live-in unless it is the block with the alloc_box.
  llvm::SmallVector<Operand *, 32> Worklist(Box->use_begin(), Box->use_end());
  while (!Worklist.empty()) {
    auto *Op = Worklist.pop_back_val();
    auto *User = Op->getUser();
    auto *BB = User->getParent();

    if (isa<ProjectBoxInst>(User))
      continue;

    if (BB != DefBB)
      LiveIn.insert(BB);

    // Also keep track of the blocks with uses.
    UseBlocks.insert(BB);

    // If we have a copy value or a mark_uninitialized, add its uses to the work
    // list and continue.
    if (isa<MarkUninitializedInst>(User) || isa<CopyValueInst>(User)) {
      copy(cast<SingleValueInstruction>(User)->getUses(),
           std::back_inserter(Worklist));
      continue;
    }

    // Try to speed up the trivial case of single release/dealloc.
    if (isa<StrongReleaseInst>(User) || isa<DeallocBoxInst>(User) ||
        isa<DestroyValueInst>(User)) {
      if (!seenRelease)
        OneRelease = User;
      else
        OneRelease = nullptr;

      seenRelease = true;
    }
  }

  // Only a single release/dealloc? We're done!
  if (OneRelease) {
    Releases.push_back(OneRelease);
    return true;
  }

  propagateLiveness(LiveIn, DefBB);

  // Now examine each block we saw a use in. If it has no successors
  // that are in LiveIn, then the last use in the block is the final
  // release/dealloc.
  for (auto *BB : UseBlocks)
    if (!successorHasLiveIn(BB, LiveIn))
      if (!addLastRelease(Box, BB, Releases))
        return false;

  return true;
}
LinearLifetimeError swift::valueHasLinearLifetime(
    SILValue value, ArrayRef<BranchPropagatedUser> consumingUses,
    ArrayRef<BranchPropagatedUser> nonConsumingUses,
    SmallPtrSetImpl<SILBasicBlock *> &visitedBlocks, DeadEndBlocks &deBlocks,
    ErrorBehaviorKind errorBehavior,
    SmallVectorImpl<SILBasicBlock *> *leakingBlocks) {
  assert(!consumingUses.empty() && "Must have at least one consuming user?!");

  State state(value, visitedBlocks, errorBehavior, leakingBlocks);

  // First add our non-consuming uses and their blocks to the
  // blocksWithNonConsumingUses map. While we do this, if we have multiple uses
  // in the same block, we only accept the last use since from a liveness
  // perspective that is all we care about.
  state.initializeAllNonConsumingUses(nonConsumingUses);

  // Then, we go through each one of our consuming users performing the
  // following operation:
  //
  // 1. Verifying that no two consuming users are in the same block. This
  // is accomplished by adding the user blocks to the blocksWithConsumingUsers
  // list. This avoids double consumes.
  //
  // 2. Verifying that no predecessor is a block with a consuming use. The
  // reason why this is necessary is because we wish to not add elements to the
  // worklist twice. Thus we want to check if we have already visited a
  // predecessor.
  SmallVector<BrPropUserAndBlockPair, 32> predsToAddToWorklist;
  state.initializeAllConsumingUses(consumingUses, predsToAddToWorklist);

  // If we have a singular consuming use and it is in the same block as value's
  // def, we bail early. Any use-after-frees due to non-consuming uses would
  // have been detected by initializing our consuming uses. So we are done.
  if (consumingUses.size() == 1 &&
      consumingUses[0].getParent() == value->getParentBlock()) {
    return state.error;
  }

  // Ok, we may have multiple consuming uses. Add the user block of each of our
  // consuming users to the visited list since we do not want them to be added
  // to the successors to visit set.
  for (const auto &i : consumingUses) {
    state.visitedBlocks.insert(i.getParent());
  }

  // Now that we have marked all of our producing blocks, we go through our
  // predsToAddToWorklist list and add our preds, making sure that none of these
  // preds are in blocksWithConsumingUses. This is important so that we do not
  // need to re-process.
  for (auto pair : predsToAddToWorklist) {
    BranchPropagatedUser user = pair.first;
    SILBasicBlock *predBlock = pair.second;

    // Make sure that the predecessor is not in our blocksWithConsumingUses
    // list.
    state.checkPredsForDoubleConsume(user, predBlock);

    if (!state.visitedBlocks.insert(predBlock).second)
      continue;

    state.worklist.push_back(predBlock);
  }

  // Now that our algorithm is completely prepared, run the
  // dataflow... If we find a failure, return false.
  state.performDataflow(deBlocks);

  // ...and then check that the end state shows that we have a valid linear
  // typed value.
  state.checkDataflowEndState(deBlocks);
  return state.error;
}
Beispiel #6
0
bool RCIdentityFunctionInfo::
findDominatingNonPayloadedEdge(SILBasicBlock *IncomingEdgeBB,
                               SILValue RCIdentity) {
  // First grab the NonPayloadedEnumBB and RCIdentityBB. If we cannot find
  // either of them, return false.
  SILBasicBlock *RCIdentityBB = RCIdentity->getParentBlock();
  if (!RCIdentityBB)
    return false;

  // Make sure that the incoming edge bb is not the RCIdentityBB. We are not
  // trying to handle this case here, so simplify by just bailing if we detect
  // it.
  //
  // I think the only way this can happen is if we have a switch_enum of some
  // sort with multiple incoming values going into the destination BB. We are
  // not interested in handling that case anyways.
  //
  // FIXME: If we ever split all critical edges, this should be relooked at.
  if (IncomingEdgeBB == RCIdentityBB)
    return false;

  // Now we know that RCIdentityBB and IncomingEdgeBB are different. Prove that
  // RCIdentityBB dominates IncomingEdgeBB.
  SILFunction *F = RCIdentityBB->getParent();

  // First make sure that IncomingEdgeBB dominates NonPayloadedEnumBB. If not,
  // return false.
  DominanceInfo *DI = DA->get(F);
  if (!DI->dominates(RCIdentityBB, IncomingEdgeBB))
    return false;

  // Now walk up the dominator tree from IncomingEdgeBB to RCIdentityBB and see
  // if we can find a use of RCIdentity that dominates IncomingEdgeBB and
  // enables us to know that RCIdentity must be a no-payload enum along
  // IncomingEdge. We don't care if the case or enum of RCIdentity match the
  // case or enum along RCIdentityBB since a pairing of retain, release of two
  // non-payloaded enums can always be eliminated (since we can always eliminate
  // ref count operations on non-payloaded enums).

  // RCIdentityBB must have a valid dominator tree node.
  auto *EndDomNode = DI->getNode(RCIdentityBB);
  if (!EndDomNode)
    return false;

  for (auto *Node = DI->getNode(IncomingEdgeBB); Node; Node = Node->getIDom()) {
    // Search for uses of RCIdentity in Node->getBlock() that will enable us to
    // know that it has a non-payloaded enum case.
    SILBasicBlock *DominatingBB = Node->getBlock();
    llvm::Optional<bool> Result =
        proveNonPayloadedEnumCase(DominatingBB, RCIdentity);

    // If we found either a signal of a payloaded or a non-payloaded enum,
    // return that value.
    if (Result.hasValue())
      return Result.getValue();

    // If we didn't reach RCIdentityBB, keep processing up the DomTree.
    if (DominatingBB != RCIdentityBB)
      continue;

    // Otherwise, we failed to find any interesting information, return false.
    return false;
  }

  return false;
}