コード例 #1
0
/// Checks whether any of the arguments to the apply are closures and diagnoses
/// if any of the @inout_aliasable captures passed to those closures have
/// in-progress accesses that would conflict with any access the summary
/// says the closure would perform.
//
/// TODO: We currently fail to statically diagnose non-escaping closures pased
/// via @block_storage convention. To enforce this case, we should statically
/// recognize when the apply takes a block argument that has been initialized to
/// a non-escaping closure.
static void checkForViolationsInNoEscapeClosures(
    const StorageMap &Accesses, FullApplySite FAS, AccessSummaryAnalysis *ASA,
    llvm::SmallVectorImpl<ConflictingAccess> &ConflictingAccesses) {

  SILFunction *Callee = FAS.getCalleeFunction();
  if (Callee && !Callee->empty()) {
    // Check for violation with directly called closure
    checkForViolationWithCall(Accesses, Callee, 0, FAS.getArguments(), ASA,
                              ConflictingAccesses);
  }

  // Check for violation with closures passed as arguments
  for (SILValue Argument : FAS.getArguments()) {
    auto *PAI = lookThroughForPartialApply(Argument);
    if (!PAI)
      continue;

    SILFunction *Closure = PAI->getCalleeFunction();
    if (!Closure || Closure->empty())
      continue;

    // Check the closure's captures, which are a suffix of the closure's
    // parameters.
    unsigned StartIndex =
        Closure->getArguments().size() - PAI->getNumCallArguments();
    checkForViolationWithCall(Accesses, Closure, StartIndex,
                              PAI->getArguments(), ASA, ConflictingAccesses);
  }
}
コード例 #2
0
/// Attempt to devirtualize the given apply if possible, and return a
/// new instruction in that case, or nullptr otherwise.
DevirtualizationResult
swift::tryDevirtualizeApply(FullApplySite AI, ClassHierarchyAnalysis *CHA) {
  DEBUG(llvm::dbgs() << "    Trying to devirtualize: " << *AI.getInstruction());

  // Devirtualize apply instructions that call witness_method instructions:
  //
  //   %8 = witness_method $Optional<UInt16>, #LogicValue.boolValue!getter.1
  //   %9 = apply %8<Self = CodeUnit?>(%6#1) : ...
  //
  if (isa<WitnessMethodInst>(AI.getCallee()))
    return tryDevirtualizeWitnessMethod(AI);

  /// Optimize a class_method and alloc_ref pair into a direct function
  /// reference:
  ///
  /// \code
  /// %XX = alloc_ref $Foo
  /// %YY = class_method %XX : $Foo, #Foo.get!1 : $@convention(method)...
  /// \endcode
  ///
  ///  or
  ///
  /// %XX = metatype $...
  /// %YY = class_method %XX : ...
  ///
  ///  into
  ///
  /// %YY = function_ref @...
  if (auto *CMI = dyn_cast<ClassMethodInst>(AI.getCallee())) {
    auto &M = AI.getModule();
    auto Instance = stripUpCasts(CMI->getOperand());
    auto ClassType = Instance->getType();
    if (ClassType.is<MetatypeType>())
      ClassType = ClassType.getMetatypeInstanceType(M);

    auto *CD = ClassType.getClassOrBoundGenericClass();

    if (isEffectivelyFinalMethod(AI, ClassType, CD, CHA))
      return tryDevirtualizeClassMethod(AI, Instance);

    // Try to check if the exact dynamic type of the instance is statically
    // known.
    if (auto Instance = getInstanceWithExactDynamicType(CMI->getOperand(),
                                                        CMI->getModule(),
                                                        CHA))
      return tryDevirtualizeClassMethod(AI, Instance);
  }

  if (isa<SuperMethodInst>(AI.getCallee())) {
    if (AI.hasSelfArgument()) {
      return tryDevirtualizeClassMethod(AI, AI.getSelfArgument());
    }

    // It is an invocation of a class method.
    // Last operand is the metatype that should be used for dispatching.
    return tryDevirtualizeClassMethod(AI, AI.getArguments().back());
  }

  return std::make_pair(nullptr, FullApplySite());
}
コード例 #3
0
// A utility function for cloning the apply instruction.
static FullApplySite CloneApply(FullApplySite AI, SILBuilder &Builder) {
  // Clone the Apply.
  Builder.setCurrentDebugScope(AI.getDebugScope());
  Builder.addOpenedArchetypeOperands(AI.getInstruction());
  auto Args = AI.getArguments();
  SmallVector<SILValue, 8> Ret(Args.size());
  for (unsigned i = 0, e = Args.size(); i != e; ++i)
    Ret[i] = Args[i];

  FullApplySite NAI;

  switch (AI.getInstruction()->getKind()) {
  case SILInstructionKind::ApplyInst:
    NAI = Builder.createApply(AI.getLoc(), AI.getCallee(),
                                   AI.getSubstitutions(),
                                   Ret,
                                   cast<ApplyInst>(AI)->isNonThrowing());
    break;
  case SILInstructionKind::TryApplyInst: {
    auto *TryApplyI = cast<TryApplyInst>(AI.getInstruction());
    NAI = Builder.createTryApply(AI.getLoc(), AI.getCallee(),
                                      AI.getSubstitutions(),
                                      Ret,
                                      TryApplyI->getNormalBB(),
                                      TryApplyI->getErrorBB());
    }
    break;
  default:
    llvm_unreachable("Trying to clone an unsupported apply instruction");
  }

  NAI.getInstruction();
  return NAI;
}
コード例 #4
0
ファイル: Devirtualize.cpp プロジェクト: asdfeng/swift
/// \brief Devirtualize an apply of a class method.
///
/// \p AI is the apply to devirtualize.
/// \p ClassOrMetatype is a class value or metatype value that is the
///    self argument of the apply we will devirtualize.
/// return the result value of the new ApplyInst if created one or null.
DevirtualizationResult swift::devirtualizeClassMethod(FullApplySite AI,
                                                     SILValue ClassOrMetatype) {
  DEBUG(llvm::dbgs() << "    Trying to devirtualize : " << *AI.getInstruction());

  SILModule &Mod = AI.getModule();
  auto *CMI = cast<ClassMethodInst>(AI.getCallee());
  auto ClassOrMetatypeType = ClassOrMetatype.getType();
  auto *F = getTargetClassMethod(Mod, ClassOrMetatypeType, CMI->getMember());

  CanSILFunctionType GenCalleeType = F->getLoweredFunctionType();

  auto Subs = getSubstitutionsForCallee(Mod, GenCalleeType,
                                        ClassOrMetatypeType, AI);
  CanSILFunctionType SubstCalleeType = GenCalleeType;
  if (GenCalleeType->isPolymorphic())
    SubstCalleeType = GenCalleeType->substGenericArgs(Mod, Mod.getSwiftModule(), Subs);

  SILBuilderWithScope B(AI.getInstruction());
  FunctionRefInst *FRI = B.createFunctionRef(AI.getLoc(), F);

  // Create the argument list for the new apply, casting when needed
  // in order to handle covariant indirect return types and
  // contravariant argument types.
  llvm::SmallVector<SILValue, 8> NewArgs;
  auto Args = AI.getArguments();
  auto ParamTypes = SubstCalleeType->getParameterSILTypes();

  for (unsigned i = 0, e = Args.size() - 1; i != e; ++i)
    NewArgs.push_back(castValueToABICompatibleType(&B, AI.getLoc(), Args[i],
                                                   Args[i].getType(),
                                                   ParamTypes[i]).getValue());

  // Add the self argument, upcasting if required because we're
  // calling a base class's method.
  auto SelfParamTy = SubstCalleeType->getSelfParameter().getSILType();
  NewArgs.push_back(castValueToABICompatibleType(&B, AI.getLoc(),
                                                 ClassOrMetatype,
                                                 ClassOrMetatypeType,
                                                 SelfParamTy).getValue());

  // If we have a direct return type, make sure we use the subst callee return
  // type. If we have an indirect return type, AI's return type of the empty
  // tuple should be ok.
  SILType ResultTy = AI.getType();
  if (!SubstCalleeType->hasIndirectResult()) {
    ResultTy = SubstCalleeType->getSILResult();
  }

  SILType SubstCalleeSILType =
    SILType::getPrimitiveObjectType(SubstCalleeType);
  FullApplySite NewAI;

  SILBasicBlock *ResultBB = nullptr;
  SILBasicBlock *NormalBB = nullptr;
  SILValue ResultValue;
  bool ResultCastRequired = false;
  SmallVector<Operand *, 4> OriginalResultUses;

  if (!isa<TryApplyInst>(AI)) {
    NewAI = B.createApply(AI.getLoc(), FRI, SubstCalleeSILType, ResultTy,
                          Subs, NewArgs, cast<ApplyInst>(AI)->isNonThrowing());
    ResultValue = SILValue(NewAI.getInstruction(), 0);
  } else {
    auto *TAI = cast<TryApplyInst>(AI);
    // Create new normal and error BBs only if:
    // - re-using a BB would create a critical edge
    // - or, the result of the new apply would be of different
    //   type than the argument of the original normal BB.
    if (TAI->getNormalBB()->getSinglePredecessor())
      ResultBB = TAI->getNormalBB();
    else {
      ResultBB = B.getFunction().createBasicBlock();
      ResultBB->createBBArg(ResultTy);
    }

    NormalBB = TAI->getNormalBB();

    SILBasicBlock *ErrorBB = nullptr;
    if (TAI->getErrorBB()->getSinglePredecessor())
      ErrorBB = TAI->getErrorBB();
    else {
      ErrorBB = B.getFunction().createBasicBlock();
      ErrorBB->createBBArg(TAI->getErrorBB()->getBBArg(0)->getType());
    }

    NewAI = B.createTryApply(AI.getLoc(), FRI, SubstCalleeSILType,
                             Subs, NewArgs,
                             ResultBB, ErrorBB);
    if (ErrorBB != TAI->getErrorBB()) {
      B.setInsertionPoint(ErrorBB);
      B.createBranch(TAI->getLoc(), TAI->getErrorBB(),
                     {ErrorBB->getBBArg(0)});
    }

    // Does the result value need to be casted?
    ResultCastRequired = ResultTy != NormalBB->getBBArg(0)->getType();

    if (ResultBB != NormalBB)
      B.setInsertionPoint(ResultBB);
    else if (ResultCastRequired) {
      B.setInsertionPoint(NormalBB->begin());
      // Collect all uses, before casting.
      for (auto *Use : NormalBB->getBBArg(0)->getUses()) {
        OriginalResultUses.push_back(Use);
      }
      NormalBB->getBBArg(0)->replaceAllUsesWith(SILUndef::get(AI.getType(), Mod));
      NormalBB->replaceBBArg(0, ResultTy, nullptr);
    }

    // The result value is passed as a parameter to the normal block.
    ResultValue = ResultBB->getBBArg(0);
  }

  // Check if any casting is required for the return value.
  ResultValue = castValueToABICompatibleType(&B, NewAI.getLoc(), ResultValue,
                                             ResultTy, AI.getType()).getValue();

  DEBUG(llvm::dbgs() << "        SUCCESS: " << F->getName() << "\n");
  NumClassDevirt++;

  if (NormalBB) {
    if (NormalBB != ResultBB) {
      // If artificial normal BB was introduced, branch
      // to the original normal BB.
      B.createBranch(NewAI.getLoc(), NormalBB, { ResultValue });
    } else if (ResultCastRequired) {
      // Update all original uses by the new value.
      for(auto *Use: OriginalResultUses) {
        Use->set(ResultValue);
      }
    }
    return std::make_pair(NewAI.getInstruction(), NewAI);
  }

  // We need to return a pair of values here:
  // - the first one is the actual result of the devirtualized call, possibly
  //   casted into an appropriate type. This SILValue may be a BB arg, if it
  //   was a cast between optional types.
  // - the second one is the new apply site.
  return std::make_pair(ResultValue.getDef(), NewAI);
}
コード例 #5
0
ファイル: ClosureSpecializer.cpp プロジェクト: uygar/swift
/// Update the callsite to pass in the correct arguments.
static void rewriteApplyInst(const CallSiteDescriptor &CSDesc,
                             SILFunction *NewF) {
  FullApplySite AI = CSDesc.getApplyInst();
  SingleValueInstruction *Closure = CSDesc.getClosure();
  SILBuilderWithScope Builder(Closure);
  FunctionRefInst *FRI = Builder.createFunctionRef(AI.getLoc(), NewF);

  // Create the args for the new apply by removing the closure argument...
  llvm::SmallVector<SILValue, 8> NewArgs;
  unsigned Index = 0;
  for (auto Arg : AI.getArguments()) {
    if (Index != CSDesc.getClosureIndex())
      NewArgs.push_back(Arg);
    Index++;
  }

  // ... and appending the captured arguments. We also insert retains here at
  // the location of the original closure. This is needed to balance the
  // implicit release of all captured arguments that occurs when the partial
  // apply is destroyed.
  SILModule &M = NewF->getModule();
  auto ClosureCalleeConv = CSDesc.getClosureCallee()->getConventions();
  unsigned ClosureArgIdx =
      ClosureCalleeConv.getNumSILArguments() - CSDesc.getNumArguments();
  for (auto Arg : CSDesc.getArguments()) {
    SILType ArgTy = Arg->getType();

    // If our argument is of trivial type, continue...
    if (ArgTy.isTrivial(M)) {
      NewArgs.push_back(Arg);
      ++ClosureArgIdx;
      continue;
    }

    auto ArgConvention =
        ClosureCalleeConv.getSILArgumentConvention(ClosureArgIdx);

    // Non-inout indirect arguments are not supported yet.
    assert(ArgTy.isObject() ||
           !isNonInoutIndirectSILArgument(Arg, ArgConvention));

    // If argument is not an object and it is an inout parameter,
    // continue...
    if (!ArgTy.isObject() &&
        !isNonInoutIndirectSILArgument(Arg, ArgConvention)) {
      NewArgs.push_back(Arg);
      ++ClosureArgIdx;
      continue;
    }

    // TODO: When we support address types, this code path will need to be
    // updated.

    // We need to balance the consumed argument of the new partial_apply in the
    // specialized callee by a retain. If both the original partial_apply and
    // the apply of the callee are in the same basic block we can assume they
    // are executed the same number of times. Therefore it is sufficient to just
    // retain the argument at the site of the original partial_apply.
    //
    //    %closure = partial_apply (%arg)
    //             = apply %callee(%closure)
    //  =>
    //             retain %arg
    //    %closure = partial_apply (%arg)
    //               apply %specialized_callee(..., %arg)
    //
    // However, if they are not in the same basic block the callee might be
    // executed more frequently than the closure (for example, if the closure is
    // created in a loop preheader and the callee taking the closure is executed
    // in the loop). In such a case we must keep the argument live across the
    // call site of the callee and emit a matching retain for every invocation
    // of the callee.
    //
    //    %closure = partial_apply (%arg)
    //
    //    while () {
    //             = %callee(%closure)
    //    }
    // =>
    //               retain %arg
    //    %closure = partial_apply (%arg)
    //
    //    while () {
    //               retain %arg
    //               apply %specialized_callee(.., %arg)
    //    }
    //               release %arg
    //
    if (AI.getParent() != Closure->getParent()) {
      // Emit the retain and release that keeps the argument life across the
      // callee using the closure.
      CSDesc.extendArgumentLifetime(Arg, ArgConvention);

      // Emit the retain that matches the captured argument by the
      // partial_apply
      // in the callee that is consumed by the partial_apply.
      Builder.setInsertionPoint(AI.getInstruction());
      Builder.createRetainValue(Closure->getLoc(), Arg,
                                Builder.getDefaultAtomicity());
    } else {
      Builder.createRetainValue(Closure->getLoc(), Arg,
                                Builder.getDefaultAtomicity());
    }

    NewArgs.push_back(Arg);
    ++ClosureArgIdx;
  }

  Builder.setInsertionPoint(AI.getInstruction());
  FullApplySite NewAI;
  switch (AI.getKind()) {
  case FullApplySiteKind::TryApplyInst: {
    auto *TAI = cast<TryApplyInst>(AI);
    NewAI = Builder.createTryApply(AI.getLoc(), FRI,
                                   SubstitutionMap(), NewArgs,
                                   TAI->getNormalBB(), TAI->getErrorBB());
    // If we passed in the original closure as @owned, then insert a release
    // right after NewAI. This is to balance the +1 from being an @owned
    // argument to AI.
    if (!CSDesc.isClosureConsumed() || !CSDesc.closureHasRefSemanticContext()) {
      break;
    }

    Builder.setInsertionPoint(TAI->getNormalBB()->begin());
    Builder.createReleaseValue(Closure->getLoc(), Closure,
                               Builder.getDefaultAtomicity());
    Builder.setInsertionPoint(TAI->getErrorBB()->begin());
    Builder.createReleaseValue(Closure->getLoc(), Closure,
                               Builder.getDefaultAtomicity());
    Builder.setInsertionPoint(AI.getInstruction());
    break;
  }
  case FullApplySiteKind::ApplyInst: {
    auto oldApply = cast<ApplyInst>(AI);
    auto newApply = Builder.createApply(oldApply->getLoc(), FRI,
                                        SubstitutionMap(),
                                        NewArgs, oldApply->isNonThrowing());
    // If we passed in the original closure as @owned, then insert a release
    // right after NewAI. This is to balance the +1 from being an @owned
    // argument to AI.
    if (CSDesc.isClosureConsumed() && CSDesc.closureHasRefSemanticContext())
      Builder.createReleaseValue(Closure->getLoc(), Closure,
                                 Builder.getDefaultAtomicity());

    // Replace all uses of the old apply with the new apply.
    oldApply->replaceAllUsesWith(newApply);
    break;
  }
  case FullApplySiteKind::BeginApplyInst:
    llvm_unreachable("Unhandled case");
  }
    
  // Erase the old apply.
  AI.getInstruction()->eraseFromParent();

  // TODO: Maybe include invalidation code for CallSiteDescriptor after we erase
  // AI from parent?
}
コード例 #6
0
/// Process an apply instruction which uses a partial_apply
/// as its callee.
/// Returns true on success.
bool PartialApplyCombiner::processSingleApply(FullApplySite AI) {
    Builder.setInsertionPoint(AI.getInstruction());
    Builder.setCurrentDebugScope(AI.getDebugScope());

    // Prepare the args.
    SmallVector<SILValue, 8> Args;
    // First the ApplyInst args.
    for (auto Op : AI.getArguments())
        Args.push_back(Op);

    SILInstruction *InsertionPoint = &*Builder.getInsertionPoint();
    // Next, the partial apply args.

    // Pre-process partial_apply arguments only once, lazily.
    if (isFirstTime) {
        isFirstTime = false;
        if (!allocateTemporaries())
            return false;
    }

    // Now, copy over the partial apply args.
    for (auto Op : PAI->getArguments()) {
        auto Arg = Op;
        // If there is new temporary for this argument, use it instead.
        if (isa<AllocStackInst>(Arg)) {
            if (ArgToTmp.count(Arg)) {
                Op = ArgToTmp.lookup(Arg);
            }
        }
        Args.push_back(Op);
    }

    Builder.setInsertionPoint(InsertionPoint);
    Builder.setCurrentDebugScope(AI.getDebugScope());

    // The thunk that implements the partial apply calls the closure function
    // that expects all arguments to be consumed by the function. However, the
    // captured arguments are not arguments of *this* apply, so they are not
    // pre-incremented. When we combine the partial_apply and this apply into
    // a new apply we need to retain all of the closure non-address type
    // arguments.
    auto ParamInfo = PAI->getSubstCalleeType()->getParameters();
    auto PartialApplyArgs = PAI->getArguments();
    // Set of arguments that need to be released after each invocation.
    SmallVector<SILValue, 8> ToBeReleasedArgs;
    for (unsigned i = 0, e = PartialApplyArgs.size(); i < e; ++i) {
        SILValue Arg = PartialApplyArgs[i];
        if (!Arg->getType().isAddress()) {
            // Retain the argument as the callee may consume it.
            Builder.emitRetainValueOperation(PAI->getLoc(), Arg);
            // For non consumed parameters (e.g. guaranteed), we also need to
            // insert releases after each apply instruction that we create.
            if (!ParamInfo[ParamInfo.size() - PartialApplyArgs.size() + i].
                    isConsumed())
                ToBeReleasedArgs.push_back(Arg);
        }
    }

    auto *F = FRI->getReferencedFunction();
    SILType FnType = F->getLoweredType();
    SILType ResultTy = F->getLoweredFunctionType()->getSILResult();
    ArrayRef<Substitution> Subs = PAI->getSubstitutions();
    if (!Subs.empty()) {
        FnType = FnType.substGenericArgs(PAI->getModule(), Subs);
        ResultTy = FnType.getAs<SILFunctionType>()->getSILResult();
    }

    FullApplySite NAI;
    if (auto *TAI = dyn_cast<TryApplyInst>(AI))
        NAI =
            Builder.createTryApply(AI.getLoc(), FRI, FnType, Subs, Args,
                                   TAI->getNormalBB(), TAI->getErrorBB());
    else
        NAI =
            Builder.createApply(AI.getLoc(), FRI, FnType, ResultTy, Subs, Args,
                                cast<ApplyInst>(AI)->isNonThrowing());

    // We also need to release the partial_apply instruction itself because it
    // is consumed by the apply_instruction.
    if (auto *TAI = dyn_cast<TryApplyInst>(AI)) {
        Builder.setInsertionPoint(TAI->getNormalBB()->begin());
        for (auto Arg : ToBeReleasedArgs) {
            Builder.emitReleaseValueOperation(PAI->getLoc(), Arg);
        }
        Builder.createStrongRelease(AI.getLoc(), PAI, Atomicity::Atomic);
        Builder.setInsertionPoint(TAI->getErrorBB()->begin());
        // Release the non-consumed parameters.
        for (auto Arg : ToBeReleasedArgs) {
            Builder.emitReleaseValueOperation(PAI->getLoc(), Arg);
        }
        Builder.createStrongRelease(AI.getLoc(), PAI, Atomicity::Atomic);
        Builder.setInsertionPoint(AI.getInstruction());
    } else {
        // Release the non-consumed parameters.
        for (auto Arg : ToBeReleasedArgs) {
            Builder.emitReleaseValueOperation(PAI->getLoc(), Arg);
        }
        Builder.createStrongRelease(AI.getLoc(), PAI, Atomicity::Atomic);
    }

    SilCombiner->replaceInstUsesWith(*AI.getInstruction(), NAI.getInstruction());
    SilCombiner->eraseInstFromFunction(*AI.getInstruction());
    return true;
}
コード例 #7
0
/// Update the callsite to pass in the correct arguments.
static void rewriteApplyInst(const CallSiteDescriptor &CSDesc,
                             SILFunction *NewF) {
  FullApplySite AI = CSDesc.getApplyInst();
  SILInstruction *Closure = CSDesc.getClosure();
  SILBuilderWithScope Builder(Closure);
  FunctionRefInst *FRI = Builder.createFunctionRef(AI.getLoc(), NewF);

  // Create the args for the new apply by removing the closure argument...
  llvm::SmallVector<SILValue, 8> NewArgs;
  unsigned Index = 0;
  for (auto Arg : AI.getArguments()) {
    if (Index != CSDesc.getClosureIndex())
      NewArgs.push_back(Arg);
    Index++;
  }

  // ... and appending the captured arguments. We also insert retains here at
  // the location of the original closure. This is needed to balance the
  // implicit release of all captured arguments that occurs when the partial
  // apply is destroyed.
  SILModule &M = NewF->getModule();
  for (auto Arg : CSDesc.getArguments()) {
    NewArgs.push_back(Arg);

    SILType ArgTy = Arg->getType();

    // If our argument is of trivial type, continue...
    if (ArgTy.isTrivial(M))
      continue;

    // TODO: When we support address types, this code path will need to be
    // updated.

    // We need to balance the consumed argument of the new partial_apply in the
    // specialized callee by a retain. If both the original partial_apply and
    // the apply of the callee are in the same basic block we can assume they
    // are executed the same number of times. Therefore it is sufficient to just
    // retain the argument at the site of the original partial_apply.
    //
    //    %closure = partial_apply (%arg)
    //             = apply %callee(%closure)
    //  =>
    //             retain %arg
    //    %closure = partial_apply (%arg)
    //               apply %specialized_callee(..., %arg)
    //
    // However, if they are not in the same basic block the callee might be
    // executed more frequently than the closure (for example, if the closure is
    // created in a loop preheader and the callee taking the closure is executed
    // in the loop). In such a case we must keep the argument live across the
    // call site of the callee and emit a matching retain for every invocation
    // of the callee.
    //
    //    %closure = partial_apply (%arg)
    //
    //    while () {
    //             = %callee(%closure)
    //    }
    // =>
    //               retain %arg
    //    %closure = partial_apply (%arg)
    //
    //    while () {
    //               retain %arg
    //               apply %specialized_callee(.., %arg)
    //    }
    //               release %arg
    //
    if (AI.getParent() != Closure->getParent()) {
      // Emit the retain and release that keeps the argument life across the
      // callee using the closure.
      CSDesc.extendArgumentLifetime(Arg);

      // Emit the retain that matches the captured argument by the partial_apply
      // in the callee that is consumed by the partial_apply.
      Builder.setInsertionPoint(AI.getInstruction());
      Builder.createRetainValue(Closure->getLoc(), Arg, Atomicity::Atomic);
    } else {
      Builder.createRetainValue(Closure->getLoc(), Arg, Atomicity::Atomic);
    }
  }

  SILType LoweredType = NewF->getLoweredType();
  SILType ResultType = LoweredType.castTo<SILFunctionType>()->getSILResult();
  Builder.setInsertionPoint(AI.getInstruction());
  FullApplySite NewAI;
  if (auto *TAI = dyn_cast<TryApplyInst>(AI)) {
    NewAI = Builder.createTryApply(AI.getLoc(), FRI, LoweredType,
                                   ArrayRef<Substitution>(),
                                   NewArgs,
                                   TAI->getNormalBB(), TAI->getErrorBB());
    // If we passed in the original closure as @owned, then insert a release
    // right after NewAI. This is to balance the +1 from being an @owned
    // argument to AI.
    if (CSDesc.isClosureConsumed() && CSDesc.closureHasRefSemanticContext()) {
      Builder.setInsertionPoint(TAI->getNormalBB()->begin());
      Builder.createReleaseValue(Closure->getLoc(), Closure, Atomicity::Atomic);
      Builder.setInsertionPoint(TAI->getErrorBB()->begin());
      Builder.createReleaseValue(Closure->getLoc(), Closure, Atomicity::Atomic);
      Builder.setInsertionPoint(AI.getInstruction());
    }
  } else {
    NewAI = Builder.createApply(AI.getLoc(), FRI, LoweredType,
                                ResultType, ArrayRef<Substitution>(),
                                NewArgs, cast<ApplyInst>(AI)->isNonThrowing());
    // If we passed in the original closure as @owned, then insert a release
    // right after NewAI. This is to balance the +1 from being an @owned
    // argument to AI.
    if (CSDesc.isClosureConsumed() && CSDesc.closureHasRefSemanticContext())
      Builder.createReleaseValue(Closure->getLoc(), Closure, Atomicity::Atomic);
  }

  // Replace all uses of the old apply with the new apply.
  if (isa<ApplyInst>(AI))
    AI.getInstruction()->replaceAllUsesWith(NewAI.getInstruction());
  // Erase the old apply.
  AI.getInstruction()->eraseFromParent();

  // TODO: Maybe include invalidation code for CallSiteDescriptor after we erase
  // AI from parent?
}
コード例 #8
0
/// Insert monomorphic inline caches for a specific class or metatype
/// type \p SubClassTy.
static FullApplySite speculateMonomorphicTarget(FullApplySite AI,
                                                SILType SubType,
                                                CheckedCastBranchInst *&CCBI) {
  CCBI = nullptr;
  // Bail if this class_method cannot be devirtualized.
  if (!canDevirtualizeClassMethod(AI, SubType))
    return FullApplySite();

  // Create a diamond shaped control flow and a checked_cast_branch
  // instruction that checks the exact type of the object.
  // This cast selects between two paths: one that calls the slow dynamic
  // dispatch and one that calls the specific method.
  auto It = AI.getInstruction()->getIterator();
  SILFunction *F = AI.getFunction();
  SILBasicBlock *Entry = AI.getParent();

  // Iden is the basic block containing the direct call.
  SILBasicBlock *Iden = F->createBasicBlock();
  // Virt is the block containing the slow virtual call.
  SILBasicBlock *Virt = F->createBasicBlock();
  Iden->createBBArg(SubType);

  SILBasicBlock *Continue = Entry->splitBasicBlock(It);

  SILBuilderWithScope Builder(Entry, AI.getInstruction());
  // Create the checked_cast_branch instruction that checks at runtime if the
  // class instance is identical to the SILType.

  ClassMethodInst *CMI = cast<ClassMethodInst>(AI.getCallee());

  CCBI = Builder.createCheckedCastBranch(AI.getLoc(), /*exact*/ true,
                                       CMI->getOperand(), SubType, Iden,
                                       Virt);
  It = CCBI->getIterator();

  SILBuilderWithScope VirtBuilder(Virt, AI.getInstruction());
  SILBuilderWithScope IdenBuilder(Iden, AI.getInstruction());
  // This is the class reference downcasted into subclass SubType.
  SILValue DownCastedClassInstance = Iden->getBBArg(0);

  // Copy the two apply instructions into the two blocks.
  FullApplySite IdenAI = CloneApply(AI, IdenBuilder);
  FullApplySite VirtAI = CloneApply(AI, VirtBuilder);

  // See if Continue has a release on self as the instruction right after the
  // apply. If it exists, move it into position in the diamond.
  if (auto *Release =
          dyn_cast<StrongReleaseInst>(std::next(Continue->begin()))) {
    if (Release->getOperand() == CMI->getOperand()) {
      VirtBuilder.createStrongRelease(Release->getLoc(), CMI->getOperand());
      IdenBuilder.createStrongRelease(Release->getLoc(),
                                      DownCastedClassInstance);
      Release->eraseFromParent();
    }
  }

  // Create a PHInode for returning the return value from both apply
  // instructions.
  SILArgument *Arg = Continue->createBBArg(AI.getType());
  if (!isa<TryApplyInst>(AI)) {
    IdenBuilder.createBranch(AI.getLoc(), Continue,
                             ArrayRef<SILValue>(IdenAI.getInstruction()));
    VirtBuilder.createBranch(AI.getLoc(), Continue,
                             ArrayRef<SILValue>(VirtAI.getInstruction()));
  }

  // Remove the old Apply instruction.
  if (!isa<TryApplyInst>(AI))
    AI.getInstruction()->replaceAllUsesWith(Arg);
  auto *OriginalBB = AI.getParent();
  AI.getInstruction()->eraseFromParent();
  if (OriginalBB->empty())
    OriginalBB->removeFromParent();

  // Update the stats.
  NumTargetsPredicted++;

  // Devirtualize the apply instruction on the identical path.
  auto NewInstPair = devirtualizeClassMethod(IdenAI, DownCastedClassInstance);
  assert(NewInstPair.first && "Expected to be able to devirtualize apply!");
  replaceDeadApply(IdenAI, NewInstPair.first);

  // Split critical edges resulting from VirtAI.
  if (auto *TAI = dyn_cast<TryApplyInst>(VirtAI)) {
    auto *ErrorBB = TAI->getFunction()->createBasicBlock();
    ErrorBB->createBBArg(TAI->getErrorBB()->getBBArg(0)->getType());
    Builder.setInsertionPoint(ErrorBB);
    Builder.createBranch(TAI->getLoc(), TAI->getErrorBB(),
                         {ErrorBB->getBBArg(0)});

    auto *NormalBB = TAI->getFunction()->createBasicBlock();
    NormalBB->createBBArg(TAI->getNormalBB()->getBBArg(0)->getType());
    Builder.setInsertionPoint(NormalBB);
    Builder.createBranch(TAI->getLoc(), TAI->getNormalBB(),
                        {NormalBB->getBBArg(0) });

    Builder.setInsertionPoint(VirtAI.getInstruction());
    SmallVector<SILValue, 4> Args;
    for (auto Arg : VirtAI.getArguments()) {
      Args.push_back(Arg);
    }
    FullApplySite NewVirtAI = Builder.createTryApply(VirtAI.getLoc(), VirtAI.getCallee(),
        VirtAI.getSubstCalleeSILType(), VirtAI.getSubstitutions(),
        Args, NormalBB, ErrorBB);
    VirtAI.getInstruction()->eraseFromParent();
    VirtAI = NewVirtAI;
  }

  return VirtAI;
}
コード例 #9
0
ファイル: Devirtualize.cpp プロジェクト: frsoares/swift
/// Attempt to devirtualize the given apply if possible, and return a
/// new instruction in that case, or nullptr otherwise.
ApplySite swift::tryDevirtualizeApply(ApplySite AI,
                                      ClassHierarchyAnalysis *CHA,
                                      OptRemark::Emitter *ORE) {
  LLVM_DEBUG(llvm::dbgs() << "    Trying to devirtualize: "
                          << *AI.getInstruction());

  // Devirtualize apply instructions that call witness_method instructions:
  //
  //   %8 = witness_method $Optional<UInt16>, #LogicValue.boolValue!getter.1
  //   %9 = apply %8<Self = CodeUnit?>(%6#1) : ...
  //
  if (isa<WitnessMethodInst>(AI.getCallee()))
    return tryDevirtualizeWitnessMethod(AI, ORE);

  // TODO: check if we can also de-virtualize partial applies of class methods.
  FullApplySite FAS = FullApplySite::isa(AI.getInstruction());
  if (!FAS)
    return ApplySite();

  /// Optimize a class_method and alloc_ref pair into a direct function
  /// reference:
  ///
  /// \code
  /// %XX = alloc_ref $Foo
  /// %YY = class_method %XX : $Foo, #Foo.get!1 : $@convention(method)...
  /// \endcode
  ///
  ///  or
  ///
  /// %XX = metatype $...
  /// %YY = class_method %XX : ...
  ///
  ///  into
  ///
  /// %YY = function_ref @...
  if (auto *CMI = dyn_cast<ClassMethodInst>(FAS.getCallee())) {
    auto &M = FAS.getModule();
    auto Instance = stripUpCasts(CMI->getOperand());
    auto ClassType = Instance->getType();
    if (ClassType.is<MetatypeType>())
      ClassType = ClassType.getMetatypeInstanceType(M);

    auto *CD = ClassType.getClassOrBoundGenericClass();

    if (isEffectivelyFinalMethod(FAS, ClassType, CD, CHA))
      return tryDevirtualizeClassMethod(FAS, Instance, ORE,
                                        true /*isEffectivelyFinalMethod*/);

    // Try to check if the exact dynamic type of the instance is statically
    // known.
    if (auto Instance = getInstanceWithExactDynamicType(CMI->getOperand(),
                                                        CMI->getModule(),
                                                        CHA))
      return tryDevirtualizeClassMethod(FAS, Instance, ORE);

    if (auto ExactTy = getExactDynamicType(CMI->getOperand(), CMI->getModule(),
                                           CHA)) {
      if (ExactTy == CMI->getOperand()->getType())
        return tryDevirtualizeClassMethod(FAS, CMI->getOperand(), ORE);
    }
  }

  if (isa<SuperMethodInst>(FAS.getCallee())) {
    if (FAS.hasSelfArgument()) {
      return tryDevirtualizeClassMethod(FAS, FAS.getSelfArgument(), ORE);
    }

    // It is an invocation of a class method.
    // Last operand is the metatype that should be used for dispatching.
    return tryDevirtualizeClassMethod(FAS, FAS.getArguments().back(), ORE);
  }

  return ApplySite();
}