include/swift/Basic/BlotSetVector.h - third_party/swift - Git at Google

 //===--- BlotSetVector.h ----------------------------------------*- C++ -*-===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//

 #ifndef SWIFT_BASIC_BLOTSETVECTOR_H
 #define SWIFT_BASIC_BLOTSETVECTOR_H

 #include "swift/Basic/LLVM.h"
 #include "llvm/ADT/DenseMap.h"
 #include "llvm/ADT/SmallVector.h"
 #include <vector>

 namespace swift {

 /// This is a set container with the following properties:
 ///
 /// 1. Fast insertion-order iteration.
 ///
 /// 2. Stable index offsets for all values after all operations including
 /// erase.
 ///
 /// This contrasts with SetVector where index offsets are not stable due to
 /// usage of std::vector::erase(). In contrast, BlotSetVector uses the `blot
 /// operation' (a) which trades memory for runtime and index offset stability.
 ///
 /// 3. Fast replacement of a value v1 with a second value v2 guaranteeing that
 /// v2 is placed into the same array index as v1, just deleting v1 if v2 is
 /// already in the array.
 ///
 /// This is important if one has other data structures referring to v1 via v1's
 /// index in the vector that one wishes to now refer to v2.
 ///
 /// 4. Fast deletion via the 'blot' operation.
 ///
 /// 5. Fast insertion.
 ///
 /// (a) The `blot operation' is leaving the value in the set vector, but marking
 /// the value as being dead.
 template <typename ValueT, typename VectorT = std::vector<Optional<ValueT>>,
           typename MapT = llvm::DenseMap<ValueT, unsigned>>
 class BlotSetVector {
   VectorT vector;
   MapT map;

 public:
   /// Construct an empty BlotSetVector.
   BlotSetVector() {}

   bool empty() const { return vector.empty(); }

   unsigned size() const { return vector.size(); }

   using iterator = typename VectorT::iterator;
   using const_iterator = typename VectorT::const_iterator;
   iterator begin() { return vector.begin(); }
   iterator end() { return vector.end(); }
   const_iterator begin() const { return vector.begin(); }
   const_iterator end() const { return vector.end(); }

   ArrayRef<Optional<ValueT>> getArray() const { return vector; }

   iterator_range<const_iterator> getRange() const {
     return {begin(), end()};
   }

   using const_reverse_iterator = typename VectorT::const_reverse_iterator;
   const_reverse_iterator rbegin() const { return vector.rbegin(); }
   const_reverse_iterator rend() const { return vector.rend(); }
   iterator_range<const_reverse_iterator> getReverseRange() const {
     return {rbegin(), rend()};
   }

   const Optional<ValueT> &operator[](unsigned n) const {
     assert(n < vector.size() && "Out of range!");
     return vector[n];
   }

   /// Grow the set vector so that it can contain at least \p capacity items
   /// before resizing again.
   ///
   /// \param capacity The minimum size that the set vector will be able to grow
   ///                 to before a resize is required to insert additional items.
   void reserve(unsigned capacity) {
     vector.reserve(capacity);
     map.reserve(capacity);
   }

   /// Insert \p value into the SetVector if it is not there already.
   ///
   /// \param value The item to insert if not already present.
   ///
   /// \returns Both the index of the item and whether it was inserted in a pair.
   ///          If the item was already present, its preexisting index along with
   ///          false will be returned.  If the item was newly added, its new
   ///          index along with true will be returned.
   std::pair<unsigned, bool> insert(const ValueT &value) {
     auto iterator = map.find(value);
     if (iterator != map.end())
       return {iterator->second, false};

     unsigned index = vector.size();
     map[value] = index;
     vector.push_back(value);
     return {index, true};
   }

   /// Replace \p value1 with \p value2 placing \p value2 into the position in
   /// the array where value1 used to be. If \p value2 is already in the set,
   /// this just erases \p value1.
   void replace(const ValueT &value1, const ValueT &value2) {
     auto iterator1 = map.find(value1);
     assert(iterator1 != map.end() && "Cannot replace value that is not in set");
     unsigned index1 = iterator1->second;
     map.erase(value1);

     auto iterator2 = map.find(value2);
     if (iterator2 != map.end()) {
       vector[index1] = None;
       return;
     }

     map[value2] = index1;
     vector[index1] = value2;
   }

   /// Erase the value \p value if it is in the set. Returns true if value was
   /// successfully erased and false otherwise.
   bool erase(const ValueT &value) {
     auto iterator = map.find(value);
     if (iterator == map.end())
       return false;
     unsigned index = iterator->second;
     map.erase(iterator);
     vector[index] = None;
     return true;
   }

   /// Return the last element of the blot map vector. Will be None if blotted.
   Optional<ValueT> pop_back_val() {
     auto result = vector.pop_back_val();
     if (!result)
       return result;
     map.erase(*result);
     return result;
   }

   /// Attempt to lookup the index of \p value. Returns None upon failure and the
   /// value on success.
   Optional<unsigned> getIndex(const ValueT &value) {
     auto iterator = map.find(value);
     if (iterator == map.end())
       return None;
     return iterator->second;
   }

   /// Clear the backing vector and map.
   void clear() {
     vector.clear();
     map.clear();
   }
 };

 template <typename ValueT, unsigned N>
 class SmallBlotSetVector
     : public BlotSetVector<ValueT, llvm::SmallVector<Optional<ValueT>, N>,
                            llvm::SmallDenseMap<ValueT, unsigned, N>> {
 public:
   SmallBlotSetVector() {}
 };

 } // namespace swift

 #endif // SWIFT_BASIC_BLOTSETVECTOR_H
	//===--- BlotSetVector.h ----------------------------------------- C++ --===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//

	#ifndef SWIFT_BASIC_BLOTSETVECTOR_H
	#define SWIFT_BASIC_BLOTSETVECTOR_H

	#include "swift/Basic/LLVM.h"
	#include "llvm/ADT/DenseMap.h"
	#include "llvm/ADT/SmallVector.h"
	#include <vector>

	namespace swift {

	/// This is a set container with the following properties:
	///
	/// 1. Fast insertion-order iteration.
	///
	/// 2. Stable index offsets for all values after all operations including
	/// erase.
	///
	/// This contrasts with SetVector where index offsets are not stable due to
	/// usage of std::vector::erase(). In contrast, BlotSetVector uses the `blot
	/// operation' (a) which trades memory for runtime and index offset stability.
	///
	/// 3. Fast replacement of a value v1 with a second value v2 guaranteeing that
	/// v2 is placed into the same array index as v1, just deleting v1 if v2 is
	/// already in the array.
	///
	/// This is important if one has other data structures referring to v1 via v1's
	/// index in the vector that one wishes to now refer to v2.
	///
	/// 4. Fast deletion via the 'blot' operation.
	///
	/// 5. Fast insertion.
	///
	/// (a) The `blot operation' is leaving the value in the set vector, but marking
	/// the value as being dead.
	template <typename ValueT, typename VectorT = std::vector<Optional<ValueT>>,
	typename MapT = llvm::DenseMap<ValueT, unsigned>>
	class BlotSetVector {
	VectorT vector;
	MapT map;

	public:
	/// Construct an empty BlotSetVector.
	BlotSetVector() {}

	bool empty() const { return vector.empty(); }

	unsigned size() const { return vector.size(); }

	using iterator = typename VectorT::iterator;
	using const_iterator = typename VectorT::const_iterator;
	iterator begin() { return vector.begin(); }
	iterator end() { return vector.end(); }
	const_iterator begin() const { return vector.begin(); }
	const_iterator end() const { return vector.end(); }

	ArrayRef<Optional<ValueT>> getArray() const { return vector; }

	iterator_range<const_iterator> getRange() const {
	return {begin(), end()};
	}

	using const_reverse_iterator = typename VectorT::const_reverse_iterator;
	const_reverse_iterator rbegin() const { return vector.rbegin(); }
	const_reverse_iterator rend() const { return vector.rend(); }
	iterator_range<const_reverse_iterator> getReverseRange() const {
	return {rbegin(), rend()};
	}

	const Optional<ValueT> &operator[](unsigned n) const {
	assert(n < vector.size() && "Out of range!");
	return vector[n];
	}

	/// Grow the set vector so that it can contain at least \p capacity items
	/// before resizing again.
	///
	/// \param capacity The minimum size that the set vector will be able to grow
	/// to before a resize is required to insert additional items.
	void reserve(unsigned capacity) {
	vector.reserve(capacity);
	map.reserve(capacity);
	}

	/// Insert \p value into the SetVector if it is not there already.
	///
	/// \param value The item to insert if not already present.
	///
	/// \returns Both the index of the item and whether it was inserted in a pair.
	/// If the item was already present, its preexisting index along with
	/// false will be returned. If the item was newly added, its new
	/// index along with true will be returned.
	std::pair<unsigned, bool> insert(const ValueT &value) {
	auto iterator = map.find(value);
	if (iterator != map.end())
	return {iterator->second, false};

	unsigned index = vector.size();
	map[value] = index;
	vector.push_back(value);
	return {index, true};
	}

	/// Replace \p value1 with \p value2 placing \p value2 into the position in
	/// the array where value1 used to be. If \p value2 is already in the set,
	/// this just erases \p value1.
	void replace(const ValueT &value1, const ValueT &value2) {
	auto iterator1 = map.find(value1);
	assert(iterator1 != map.end() && "Cannot replace value that is not in set");
	unsigned index1 = iterator1->second;
	map.erase(value1);

	auto iterator2 = map.find(value2);
	if (iterator2 != map.end()) {
	vector[index1] = None;
	return;
	}

	map[value2] = index1;
	vector[index1] = value2;
	}

	/// Erase the value \p value if it is in the set. Returns true if value was
	/// successfully erased and false otherwise.
	bool erase(const ValueT &value) {
	auto iterator = map.find(value);
	if (iterator == map.end())
	return false;
	unsigned index = iterator->second;
	map.erase(iterator);
	vector[index] = None;
	return true;
	}

	/// Return the last element of the blot map vector. Will be None if blotted.
	Optional<ValueT> pop_back_val() {
	auto result = vector.pop_back_val();
	if (!result)
	return result;
	map.erase(*result);
	return result;
	}

	/// Attempt to lookup the index of \p value. Returns None upon failure and the
	/// value on success.
	Optional<unsigned> getIndex(const ValueT &value) {
	auto iterator = map.find(value);
	if (iterator == map.end())
	return None;
	return iterator->second;
	}

	/// Clear the backing vector and map.
	void clear() {
	vector.clear();
	map.clear();
	}
	};

	template <typename ValueT, unsigned N>
	class SmallBlotSetVector
	: public BlotSetVector<ValueT, llvm::SmallVector<Optional<ValueT>, N>,
	llvm::SmallDenseMap<ValueT, unsigned, N>> {
	public:
	SmallBlotSetVector() {}
	};

	} // namespace swift

	#endif // SWIFT_BASIC_BLOTSETVECTOR_H