lib/SILOptimizer/Transforms/ArrayElementValuePropagation.cpp - third_party/swift - Git at Google

 //===--- ArrayElementValuePropagation.cpp - Propagate values of arrays ----===//
 //
 // This source file is part of the Swift.org open source project
 //
 // Copyright (c) 2014 - 2017 Apple Inc. and the Swift project authors
 // Licensed under Apache License v2.0 with Runtime Library Exception
 //
 // See https://swift.org/LICENSE.txt for license information
 // See https://swift.org/CONTRIBUTORS.txt for the list of Swift project authors
 //
 //===----------------------------------------------------------------------===//
 #define DEBUG_TYPE "array-element-propagation"

 #include "swift/AST/NameLookup.h"
 #include "swift/AST/ParameterList.h"
 #include "swift/AST/GenericEnvironment.h"
 #include "swift/SIL/SILBasicBlock.h"
 #include "swift/SIL/SILInstruction.h"
 #include "swift/SIL/DebugUtils.h"
 #include "swift/SILOptimizer/Analysis/ArraySemantic.h"
 #include "swift/SILOptimizer/PassManager/Passes.h"
 #include "swift/SILOptimizer/PassManager/Transforms.h"
 #include "llvm/ADT/SmallVector.h"

 using namespace swift;

 /// Propagate the elements of array values to calls of the array's get_element
 /// method, and replace calls of append(contentsOf:) with append(element:).
 ///
 /// Array literal construction and array initialization of array values
 /// associates element values with the array value. These values can be
 /// propagated to the get_element method if we can prove that the array value
 /// has not changed until reading the array value's element. These values can
 /// also be used to replace append(contentsOf:) with multiple append(element:)
 /// calls.
 ///
 /// Propagation of the elements of one array allocation.
 ///
 /// We propagate the elements associated with calls of
 ///
 /// * Array.init(count:repeatedValue:)
 ///   The 'repeatedValue'.
 ///   TODO: this is not yet implemented.
 ///
 /// * Array._adoptStorage(storage:count:)
 ///   The stores on the returned array element buffer pointer.
 ///
 namespace {

 /// Utility class for analysis array literal initializations.
 ///
 /// Array literals are initialized by allocating an array buffer, and storing
 /// the elements into it.
 /// This class analysis all the code which does the array literal
 /// initialization. It also collects uses of the array, like getElement calls
 /// and append(contentsOf) calls.
 class ArrayAllocation {
   /// The array value returned by the allocation call.
   SILValue ArrayValue;

   /// The calls to Array get_element that use this array allocation.
   llvm::SmallSetVector<ApplyInst *, 16> GetElementCalls;

   /// The calls to Array append_contentsOf that use this array allocation.
   llvm::SmallVector<ApplyInst *, 4> AppendContentsOfCalls;

   /// A map of Array indices to element values
   llvm::DenseMap<uint64_t, SILValue> ElementValueMap;

   bool mapInitializationStores(SILValue ElementBuffer);
   bool recursivelyCollectUses(ValueBase *Def);
   bool replacementsAreValid();

   // After approx. this many elements, it's faster to use append(contentsOf:)
   static constexpr unsigned APPEND_CONTENTSOF_REPLACEMENT_VALUES_MAX = 6;

 public:

   ArrayAllocation() {}

   /// Analyzes an array allocation call.
   ///
   /// Returns true if \p Alloc is the allocation of an array literal (or a
   /// similar pattern) and the array values can be used to replace get_element
   /// or append(contentof) calls.
   bool analyze(ApplyInst *Alloc);

   /// Replace getElement calls with the actual values.
   bool replaceGetElements();

   /// Replace append(contentsOf:) with multiple append(element:)
   bool replaceAppendContentOf();
 };

 /// Map the indices of array element initialization stores to their values.
 bool ArrayAllocation::mapInitializationStores(SILValue ElementBuffer) {
   assert(ElementBuffer &&
          "Must have identified an array element storage pointer");

   // Match initialization stores.
   // %83 = struct_extract %element_buffer : $UnsafeMutablePointer<Int>
   // %84 = pointer_to_address %83 : $Builtin.RawPointer to strict $*Int
   // store %85 to %84 : $*Int
   // %87 = integer_literal $Builtin.Word, 1
   // %88 = index_addr %84 : $*Int, %87 : $Builtin.Word
   // store %some_value to %88 : $*Int

   auto *UnsafeMutablePointerExtract =
       dyn_cast_or_null<StructExtractInst>(getSingleNonDebugUser(ElementBuffer));
   if (!UnsafeMutablePointerExtract)
     return false;
   auto *PointerToAddress = dyn_cast_or_null<PointerToAddressInst>(
       getSingleNonDebugUser(UnsafeMutablePointerExtract));
   if (!PointerToAddress)
     return false;

   // Match the stores. We can have either a store directly to the address or
   // to an index_addr projection.
   for (auto *Op : PointerToAddress->getUses()) {
     auto *Inst = Op->getUser();

     // Store to the base.
     auto *SI = dyn_cast<StoreInst>(Inst);
     if (SI && SI->getDest() == PointerToAddress) {
       // We have already seen an entry for this index bail.
       if (ElementValueMap.count(0))
         return false;
       ElementValueMap[0] = SI->getSrc();
       continue;
     } else if (SI)
       return false;

     // Store an index_addr projection.
     auto *IndexAddr = dyn_cast<IndexAddrInst>(Inst);
     if (!IndexAddr)
       return false;
     SI = dyn_cast_or_null<StoreInst>(getSingleNonDebugUser(IndexAddr));
     if (!SI || SI->getDest() != IndexAddr)
       return false;
     auto *Index = dyn_cast<IntegerLiteralInst>(IndexAddr->getIndex());
     if (!Index)
       return false;
     auto IndexVal = Index->getValue();
     // Let's not blow up our map.
     if (IndexVal.getActiveBits() > 16)
       return false;
     // Already saw an entry.
     if (ElementValueMap.count(IndexVal.getZExtValue()))
       return false;

     ElementValueMap[IndexVal.getZExtValue()] = SI->getSrc();
   }
   return !ElementValueMap.empty();
 }

 bool ArrayAllocation::replacementsAreValid() {
   unsigned ElementCount = ElementValueMap.size();

   if (ElementCount > APPEND_CONTENTSOF_REPLACEMENT_VALUES_MAX)
     return false;

   // Bail if elements aren't contiguous
   for (unsigned i = 0; i < ElementCount; ++i)
     if (!ElementValueMap.count(i))
       return false;

   return true;
 }

 /// Recursively look at all uses of this definition. Abort if the array value
 /// could escape or be changed. Collect all uses that are calls to array.count.
 bool ArrayAllocation::recursivelyCollectUses(ValueBase *Def) {
   for (auto *Opd : Def->getUses()) {
     auto *User = Opd->getUser();
     // Ignore reference counting and debug instructions.
     if (isa<RefCountingInst>(User) ||
         isa<DebugValueInst>(User))
       continue;

     // Array value projection.
     if (auto *SEI = dyn_cast<StructExtractInst>(User)) {
       if (!recursivelyCollectUses(SEI))
         return false;
       continue;
     }

     // Check array semantic calls.
     ArraySemanticsCall ArrayOp(User);
     if (ArrayOp) {
       if (ArrayOp.getKind() == ArrayCallKind::kAppendContentsOf) {
         AppendContentsOfCalls.push_back(ArrayOp);
         continue;
       } else if (ArrayOp.getKind() == ArrayCallKind::kGetElement) {
         GetElementCalls.insert(ArrayOp);
         continue;
       } else if (ArrayOp.doesNotChangeArray()) {
         continue;
       }
     }

     // An operation that escapes or modifies the array value.
     return false;
   }
   return true;
 }

 bool ArrayAllocation::analyze(ApplyInst *Alloc) {
   GetElementCalls.clear();
   AppendContentsOfCalls.clear();
   ElementValueMap.clear();

   ArraySemanticsCall Uninitialized(Alloc, "array.uninitialized");
   if (!Uninitialized)
     return false;

   ArrayValue = Uninitialized.getArrayValue();
   if (!ArrayValue)
     return false;

   SILValue ElementBuffer = Uninitialized.getArrayElementStoragePointer();
   if (!ElementBuffer)
     return false;

   // Figure out all stores to the array.
   if (!mapInitializationStores(ElementBuffer))
     return false;

   // Check if the array value was stored or has escaped.
   if (!recursivelyCollectUses(ArrayValue))
     return false;

   return true;
 }

 /// Replace getElement calls with the actual values.
 ///
 /// \code
 ///    store %x to %element_address
 ///    ...
 ///    %e = apply %getElement(%array, %constant_index)
 /// \endcode
 /// The value %e is replaced with %x.
 bool ArrayAllocation::replaceGetElements() {
   bool Changed = false;
   for (auto *GetElementCall : GetElementCalls) {
     ArraySemanticsCall GetElement(GetElementCall);
     assert(GetElement.getKind() == ArrayCallKind::kGetElement);

     auto ConstantIndex = GetElement.getConstantIndex();
     if (ConstantIndex == None)
       continue;

     assert(*ConstantIndex >= 0 && "Must have a positive index");

     auto EltValueIt = ElementValueMap.find(*ConstantIndex);
     if (EltValueIt == ElementValueMap.end())
       continue;

     Changed |= GetElement.replaceByValue(EltValueIt->second);
   }
   return Changed;
 }

 /// Replace append(contentsOf:) with multiple append(element:)
 ///
 /// \code
 ///    store %x to %source_array_element_address_0
 ///    store %y to %source_array_element_address_1
 ///    ...
 ///    apply %append_contentsOf(%dest_array, %source_array)
 /// \endcode
 /// is replaced by
 /// \code
 ///    store %x to %source_array_element_address_0
 ///    store %y to %source_array_element_address_1
 ///    ...
 ///    apply %reserveCapacityForAppend(%dest_array, %number_of_values)
 ///    apply %append_element(%dest_array, %x)
 ///    apply %append_element(%dest_array, %y)
 ///    ...
 /// \endcode
 /// The source_array and its initialization code can then be deleted (if not
 /// used otherwise).
 bool ArrayAllocation::replaceAppendContentOf() {
   if (AppendContentsOfCalls.empty())
     return false;
   if (ElementValueMap.empty())
     return false;

   // Check if there is a store to each element.
   if (!replacementsAreValid())
     return false;

   llvm::SmallVector<SILValue, 4> ElementValueVector;
   for (unsigned i = 0; i < ElementValueMap.size(); ++i) {
     SILValue V = ElementValueMap[i];
     ElementValueVector.push_back(V);
   }

   SILFunction *Fn = AppendContentsOfCalls[0]->getFunction();
   SILModule &M = Fn->getModule();
   ASTContext &Ctx = M.getASTContext();

   LLVM_DEBUG(llvm::dbgs() << "Array append contentsOf calls replaced in "
              << Fn->getName() << "\n");

   // Get the needed Array helper functions.
   FuncDecl *AppendFnDecl = Ctx.getArrayAppendElementDecl();
   if (!AppendFnDecl)
     return false;

   FuncDecl *ReserveFnDecl = Ctx.getArrayReserveCapacityDecl();
   if (!ReserveFnDecl)
     return false;

   auto Mangled = SILDeclRef(AppendFnDecl, SILDeclRef::Kind::Func).mangle();
   SILFunction *AppendFn = M.findFunction(Mangled, SILLinkage::PublicExternal);
   if (!AppendFn)
     return false;

   Mangled = SILDeclRef(ReserveFnDecl, SILDeclRef::Kind::Func).mangle();
   SILFunction *ReserveFn = M.findFunction(Mangled, SILLinkage::PublicExternal);
   if (!ReserveFn)
     return false;

   bool Changed = false;
   // Usually there is only a single append(contentsOf:) call. But there might
   // be multiple - with the same source array to append.
   for (ApplyInst *AppendContentOfCall : AppendContentsOfCalls) {
     ArraySemanticsCall AppendContentsOf(AppendContentOfCall);
     assert(AppendContentsOf && "Must be AppendContentsOf call");

     NominalTypeDecl *AppendSelfArray = AppendContentsOf.getSelf()->getType().
     getASTType()->getAnyNominal();

     // In case if it's not an Array, but e.g. an ContiguousArray
     if (AppendSelfArray != Ctx.getArrayDecl())
       continue;

     SILType ArrayType = ArrayValue->getType();
     auto *NTD = ArrayType.getASTType()->getAnyNominal();
     SubstitutionMap ArraySubMap = ArrayType.getASTType()
       ->getContextSubstitutionMap(M.getSwiftModule(), NTD);

     AppendContentsOf.replaceByAppendingValues(AppendFn, ReserveFn,
                                               ElementValueVector,
                                               ArraySubMap);
     Changed = true;
   }
   return Changed;
 }

 // =============================================================================
 //                                 Driver
 // =============================================================================

 class ArrayElementPropagation : public SILFunctionTransform {
 public:
   ArrayElementPropagation() {}

   void run() override {
     auto &Fn = *getFunction();

     // FIXME: Update for ownership.
     if (Fn.hasOwnership())
       return;

     bool Changed = false;

     for (auto &BB :Fn) {
       for (auto &Inst : BB) {
         if (auto *Apply = dyn_cast<ApplyInst>(&Inst)) {
           ArrayAllocation ALit;
           if (!ALit.analyze(Apply))
             continue;

           // First optimization: replace getElemente calls.
           if (ALit.replaceGetElements()) {
             Changed = true;
             // Re-do the analysis if the SIL changed.
             if (!ALit.analyze(Apply))
               continue;
           }
           // Second optimization: replace append(contentsOf:) calls.
           Changed |= ALit.replaceAppendContentOf();
         }
       }
     }

     if (Changed) {
       PM->invalidateAnalysis(
           &Fn, SILAnalysis::InvalidationKind::CallsAndInstructions);
     }
   }
 };
 } // end anonymous namespace

 SILTransform *swift::createArrayElementPropagation() {
   return new ArrayElementPropagation();
 }
	//===--- ArrayElementValuePropagation.cpp - Propagate values of arrays ----===//
	//
	// This source file is part of the Swift.org open source project
	//
	// Copyright (c) 2014 - 2017 Apple Inc. and the Swift project authors
	// Licensed under Apache License v2.0 with Runtime Library Exception
	//
	// See https://swift.org/LICENSE.txt for license information
	// See https://swift.org/CONTRIBUTORS.txt for the list of Swift project authors
	//
	//===----------------------------------------------------------------------===//
	#define DEBUG_TYPE "array-element-propagation"

	#include "swift/AST/NameLookup.h"
	#include "swift/AST/ParameterList.h"
	#include "swift/AST/GenericEnvironment.h"
	#include "swift/SIL/SILBasicBlock.h"
	#include "swift/SIL/SILInstruction.h"
	#include "swift/SIL/DebugUtils.h"
	#include "swift/SILOptimizer/Analysis/ArraySemantic.h"
	#include "swift/SILOptimizer/PassManager/Passes.h"
	#include "swift/SILOptimizer/PassManager/Transforms.h"
	#include "llvm/ADT/SmallVector.h"

	using namespace swift;

	/// Propagate the elements of array values to calls of the array's get_element
	/// method, and replace calls of append(contentsOf:) with append(element:).
	///
	/// Array literal construction and array initialization of array values
	/// associates element values with the array value. These values can be
	/// propagated to the get_element method if we can prove that the array value
	/// has not changed until reading the array value's element. These values can
	/// also be used to replace append(contentsOf:) with multiple append(element:)
	/// calls.
	///
	/// Propagation of the elements of one array allocation.
	///
	/// We propagate the elements associated with calls of
	///
	/// * Array.init(count:repeatedValue:)
	/// The 'repeatedValue'.
	/// TODO: this is not yet implemented.
	///
	/// * Array._adoptStorage(storage:count:)
	/// The stores on the returned array element buffer pointer.
	///
	namespace {

	/// Utility class for analysis array literal initializations.
	///
	/// Array literals are initialized by allocating an array buffer, and storing
	/// the elements into it.
	/// This class analysis all the code which does the array literal
	/// initialization. It also collects uses of the array, like getElement calls
	/// and append(contentsOf) calls.
	class ArrayAllocation {
	/// The array value returned by the allocation call.
	SILValue ArrayValue;

	/// The calls to Array get_element that use this array allocation.
	llvm::SmallSetVector<ApplyInst *, 16> GetElementCalls;

	/// The calls to Array append_contentsOf that use this array allocation.
	llvm::SmallVector<ApplyInst *, 4> AppendContentsOfCalls;

	/// A map of Array indices to element values
	llvm::DenseMap<uint64_t, SILValue> ElementValueMap;

	bool mapInitializationStores(SILValue ElementBuffer);
	bool recursivelyCollectUses(ValueBase *Def);
	bool replacementsAreValid();

	// After approx. this many elements, it's faster to use append(contentsOf:)
	static constexpr unsigned APPEND_CONTENTSOF_REPLACEMENT_VALUES_MAX = 6;

	public:

	ArrayAllocation() {}

	/// Analyzes an array allocation call.
	///
	/// Returns true if \p Alloc is the allocation of an array literal (or a
	/// similar pattern) and the array values can be used to replace get_element
	/// or append(contentof) calls.
	bool analyze(ApplyInst *Alloc);

	/// Replace getElement calls with the actual values.
	bool replaceGetElements();

	/// Replace append(contentsOf:) with multiple append(element:)
	bool replaceAppendContentOf();
	};

	/// Map the indices of array element initialization stores to their values.
	bool ArrayAllocation::mapInitializationStores(SILValue ElementBuffer) {
	assert(ElementBuffer &&
	"Must have identified an array element storage pointer");

	// Match initialization stores.
	// %83 = struct_extract %element_buffer : $UnsafeMutablePointer<Int>
	// %84 = pointer_to_address %83 : $Builtin.RawPointer to strict $*Int
	// store %85 to %84 : $*Int
	// %87 = integer_literal $Builtin.Word, 1
	// %88 = index_addr %84 : $*Int, %87 : $Builtin.Word
	// store %some_value to %88 : $*Int

	auto *UnsafeMutablePointerExtract =
	dyn_cast_or_null<StructExtractInst>(getSingleNonDebugUser(ElementBuffer));
	if (!UnsafeMutablePointerExtract)
	return false;
	auto *PointerToAddress = dyn_cast_or_null<PointerToAddressInst>(
	getSingleNonDebugUser(UnsafeMutablePointerExtract));
	if (!PointerToAddress)
	return false;

	// Match the stores. We can have either a store directly to the address or
	// to an index_addr projection.
	for (auto *Op : PointerToAddress->getUses()) {
	auto *Inst = Op->getUser();

	// Store to the base.
	auto *SI = dyn_cast<StoreInst>(Inst);
	if (SI && SI->getDest() == PointerToAddress) {
	// We have already seen an entry for this index bail.
	if (ElementValueMap.count(0))
	return false;
	ElementValueMap[0] = SI->getSrc();
	continue;
	} else if (SI)
	return false;

	// Store an index_addr projection.
	auto *IndexAddr = dyn_cast<IndexAddrInst>(Inst);
	if (!IndexAddr)
	return false;
	SI = dyn_cast_or_null<StoreInst>(getSingleNonDebugUser(IndexAddr));
	if (!SI \|\| SI->getDest() != IndexAddr)
	return false;
	auto *Index = dyn_cast<IntegerLiteralInst>(IndexAddr->getIndex());
	if (!Index)
	return false;
	auto IndexVal = Index->getValue();
	// Let's not blow up our map.
	if (IndexVal.getActiveBits() > 16)
	return false;
	// Already saw an entry.
	if (ElementValueMap.count(IndexVal.getZExtValue()))
	return false;

	ElementValueMap[IndexVal.getZExtValue()] = SI->getSrc();
	}
	return !ElementValueMap.empty();
	}

	bool ArrayAllocation::replacementsAreValid() {
	unsigned ElementCount = ElementValueMap.size();

	if (ElementCount > APPEND_CONTENTSOF_REPLACEMENT_VALUES_MAX)
	return false;

	// Bail if elements aren't contiguous
	for (unsigned i = 0; i < ElementCount; ++i)
	if (!ElementValueMap.count(i))
	return false;

	return true;
	}

	/// Recursively look at all uses of this definition. Abort if the array value
	/// could escape or be changed. Collect all uses that are calls to array.count.
	bool ArrayAllocation::recursivelyCollectUses(ValueBase *Def) {
	for (auto *Opd : Def->getUses()) {
	auto *User = Opd->getUser();
	// Ignore reference counting and debug instructions.
	if (isa<RefCountingInst>(User) \|\|
	isa<DebugValueInst>(User))
	continue;

	// Array value projection.
	if (auto *SEI = dyn_cast<StructExtractInst>(User)) {
	if (!recursivelyCollectUses(SEI))
	return false;
	continue;
	}

	// Check array semantic calls.
	ArraySemanticsCall ArrayOp(User);
	if (ArrayOp) {
	if (ArrayOp.getKind() == ArrayCallKind::kAppendContentsOf) {
	AppendContentsOfCalls.push_back(ArrayOp);
	continue;
	} else if (ArrayOp.getKind() == ArrayCallKind::kGetElement) {
	GetElementCalls.insert(ArrayOp);
	continue;
	} else if (ArrayOp.doesNotChangeArray()) {
	continue;
	}
	}

	// An operation that escapes or modifies the array value.
	return false;
	}
	return true;
	}

	bool ArrayAllocation::analyze(ApplyInst *Alloc) {
	GetElementCalls.clear();
	AppendContentsOfCalls.clear();
	ElementValueMap.clear();

	ArraySemanticsCall Uninitialized(Alloc, "array.uninitialized");
	if (!Uninitialized)
	return false;

	ArrayValue = Uninitialized.getArrayValue();
	if (!ArrayValue)
	return false;

	SILValue ElementBuffer = Uninitialized.getArrayElementStoragePointer();
	if (!ElementBuffer)
	return false;

	// Figure out all stores to the array.
	if (!mapInitializationStores(ElementBuffer))
	return false;

	// Check if the array value was stored or has escaped.
	if (!recursivelyCollectUses(ArrayValue))
	return false;

	return true;
	}

	/// Replace getElement calls with the actual values.
	///
	/// \code
	/// store %x to %element_address
	/// ...
	/// %e = apply %getElement(%array, %constant_index)
	/// \endcode
	/// The value %e is replaced with %x.
	bool ArrayAllocation::replaceGetElements() {
	bool Changed = false;
	for (auto *GetElementCall : GetElementCalls) {
	ArraySemanticsCall GetElement(GetElementCall);
	assert(GetElement.getKind() == ArrayCallKind::kGetElement);

	auto ConstantIndex = GetElement.getConstantIndex();
	if (ConstantIndex == None)
	continue;

	assert(*ConstantIndex >= 0 && "Must have a positive index");

	auto EltValueIt = ElementValueMap.find(*ConstantIndex);
	if (EltValueIt == ElementValueMap.end())
	continue;

	Changed \|= GetElement.replaceByValue(EltValueIt->second);
	}
	return Changed;
	}

	/// Replace append(contentsOf:) with multiple append(element:)
	///
	/// \code
	/// store %x to %source_array_element_address_0
	/// store %y to %source_array_element_address_1
	/// ...
	/// apply %append_contentsOf(%dest_array, %source_array)
	/// \endcode
	/// is replaced by
	/// \code
	/// store %x to %source_array_element_address_0
	/// store %y to %source_array_element_address_1
	/// ...
	/// apply %reserveCapacityForAppend(%dest_array, %number_of_values)
	/// apply %append_element(%dest_array, %x)
	/// apply %append_element(%dest_array, %y)
	/// ...
	/// \endcode
	/// The source_array and its initialization code can then be deleted (if not
	/// used otherwise).
	bool ArrayAllocation::replaceAppendContentOf() {
	if (AppendContentsOfCalls.empty())
	return false;
	if (ElementValueMap.empty())
	return false;

	// Check if there is a store to each element.
	if (!replacementsAreValid())
	return false;

	llvm::SmallVector<SILValue, 4> ElementValueVector;
	for (unsigned i = 0; i < ElementValueMap.size(); ++i) {
	SILValue V = ElementValueMap[i];
	ElementValueVector.push_back(V);
	}

	SILFunction *Fn = AppendContentsOfCalls[0]->getFunction();
	SILModule &M = Fn->getModule();
	ASTContext &Ctx = M.getASTContext();

	LLVM_DEBUG(llvm::dbgs() << "Array append contentsOf calls replaced in "
	<< Fn->getName() << "\n");

	// Get the needed Array helper functions.
	FuncDecl *AppendFnDecl = Ctx.getArrayAppendElementDecl();
	if (!AppendFnDecl)
	return false;

	FuncDecl *ReserveFnDecl = Ctx.getArrayReserveCapacityDecl();
	if (!ReserveFnDecl)
	return false;

	auto Mangled = SILDeclRef(AppendFnDecl, SILDeclRef::Kind::Func).mangle();
	SILFunction *AppendFn = M.findFunction(Mangled, SILLinkage::PublicExternal);
	if (!AppendFn)
	return false;

	Mangled = SILDeclRef(ReserveFnDecl, SILDeclRef::Kind::Func).mangle();
	SILFunction *ReserveFn = M.findFunction(Mangled, SILLinkage::PublicExternal);
	if (!ReserveFn)
	return false;

	bool Changed = false;
	// Usually there is only a single append(contentsOf:) call. But there might
	// be multiple - with the same source array to append.
	for (ApplyInst *AppendContentOfCall : AppendContentsOfCalls) {
	ArraySemanticsCall AppendContentsOf(AppendContentOfCall);
	assert(AppendContentsOf && "Must be AppendContentsOf call");

	NominalTypeDecl *AppendSelfArray = AppendContentsOf.getSelf()->getType().
	getASTType()->getAnyNominal();

	// In case if it's not an Array, but e.g. an ContiguousArray
	if (AppendSelfArray != Ctx.getArrayDecl())
	continue;

	SILType ArrayType = ArrayValue->getType();
	auto *NTD = ArrayType.getASTType()->getAnyNominal();
	SubstitutionMap ArraySubMap = ArrayType.getASTType()
	->getContextSubstitutionMap(M.getSwiftModule(), NTD);

	AppendContentsOf.replaceByAppendingValues(AppendFn, ReserveFn,
	ElementValueVector,
	ArraySubMap);
	Changed = true;
	}
	return Changed;
	}

	// =============================================================================
	// Driver
	// =============================================================================

	class ArrayElementPropagation : public SILFunctionTransform {
	public:
	ArrayElementPropagation() {}

	void run() override {
	auto &Fn = *getFunction();

	// FIXME: Update for ownership.
	if (Fn.hasOwnership())
	return;

	bool Changed = false;

	for (auto &BB :Fn) {
	for (auto &Inst : BB) {
	if (auto *Apply = dyn_cast<ApplyInst>(&Inst)) {
	ArrayAllocation ALit;
	if (!ALit.analyze(Apply))
	continue;

	// First optimization: replace getElemente calls.
	if (ALit.replaceGetElements()) {
	Changed = true;
	// Re-do the analysis if the SIL changed.
	if (!ALit.analyze(Apply))
	continue;
	}
	// Second optimization: replace append(contentsOf:) calls.
	Changed \|= ALit.replaceAppendContentOf();
	}
	}
	}

	if (Changed) {
	PM->invalidateAnalysis(
	&Fn, SILAnalysis::InvalidationKind::CallsAndInstructions);
	}
	}
	};
	} // end anonymous namespace

	SILTransform *swift::createArrayElementPropagation() {
	return new ArrayElementPropagation();
	}