src/zone/zone-list.h - platform/external/v8 - Git at Google

 // Copyright 2020 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef V8_ZONE_ZONE_LIST_H_
 #define V8_ZONE_ZONE_LIST_H_

 #include "src/base/logging.h"
 #include "src/zone/zone.h"

 namespace v8 {
 namespace internal {

 template <typename T>
 class Vector;

 // ZoneLists are growable lists with constant-time access to the elements.
 // The list itself and all its elements are supposed to be allocated in zone
 // memory. Unlike ZoneVector container, the ZoneList instance has minimal
 // possible size which makes it a good candidate for embedding into other
 // often-allocated zone objects.
 //
 // Note, ZoneLists' elements cannot be deleted individually and the destructor
 // intentionally does not free the backing store. Because of the latter, the
 // ZoneList must not be used outsize of zone memory. Consider using ZoneVector
 // or other containers instead.
 template <typename T>
 class ZoneList final : public ZoneObject {
  public:
   // Construct a new ZoneList with the given capacity; the length is
   // always zero. The capacity must be non-negative.
   ZoneList(int capacity, Zone* zone) : capacity_(capacity) {
     DCHECK_GE(capacity, 0);
     data_ = (capacity_ > 0) ? zone->NewArray<T>(capacity_) : nullptr;
   }

   // Construct a new ZoneList by copying the elements of the given ZoneList.
   ZoneList(const ZoneList<T>& other, Zone* zone)
       : ZoneList(other.length(), zone) {
     AddAll(other, zone);
   }

   // Construct a new ZoneList by copying the elements of the given vector.
   ZoneList(const Vector<const T>& other, Zone* zone)
       : ZoneList(other.length(), zone) {
     AddAll(other, zone);
   }

   ZoneList(ZoneList<T>&& other) V8_NOEXCEPT { *this = std::move(other); }

   // The ZoneList objects are usually allocated as a fields in other
   // zone-allocated objects for which destructors are not called anyway, so
   // we are not going to clear the memory here as well.
   ~ZoneList() = default;

   ZoneList& operator=(ZoneList&& other) V8_NOEXCEPT {
     // We don't have a Zone object, so we'll have to drop the data_ array.
     // If this assert ever fails, consider calling Clear(Zone*) or
     // DropAndClear() before the move assignment to make it explicit what's
     // happenning with the lvalue.
     DCHECK_NULL(data_);
     data_ = other.data_;
     capacity_ = other.capacity_;
     length_ = other.length_;
     other.DropAndClear();
     return *this;
   }

   // Returns a reference to the element at index i. This reference is not safe
   // to use after operations that can change the list's backing store
   // (e.g. Add).
   inline T& operator[](int i) const {
     DCHECK_LE(0, i);
     DCHECK_GT(static_cast<unsigned>(length_), static_cast<unsigned>(i));
     return data_[i];
   }
   inline T& at(int i) const { return operator[](i); }
   inline T& last() const { return at(length_ - 1); }
   inline T& first() const { return at(0); }

   using iterator = T*;
   inline iterator begin() { return &data_[0]; }
   inline iterator end() { return &data_[length_]; }

   using const_iterator = const T*;
   inline const_iterator begin() const { return &data_[0]; }
   inline const_iterator end() const { return &data_[length_]; }

   V8_INLINE bool is_empty() const { return length_ == 0; }
   V8_INLINE int length() const { return length_; }
   V8_INLINE int capacity() const { return capacity_; }

   Vector<T> ToVector() const { return Vector<T>(data_, length_); }
   Vector<T> ToVector(int start, int length) const {
     DCHECK_LE(start, length_);
     return Vector<T>(&data_[start], std::min(length_ - start, length));
   }

   Vector<const T> ToConstVector() const {
     return Vector<const T>(data_, length_);
   }

   // Adds a copy of the given 'element' to the end of the list,
   // expanding the list if necessary.
   void Add(const T& element, Zone* zone);
   // Add all the elements from the argument list to this list.
   void AddAll(const ZoneList<T>& other, Zone* zone);
   // Add all the elements from the vector to this list.
   void AddAll(const Vector<const T>& other, Zone* zone);
   // Inserts the element at the specific index.
   void InsertAt(int index, const T& element, Zone* zone);

   // Added 'count' elements with the value 'value' and returns a
   // vector that allows access to the elements. The vector is valid
   // until the next change is made to this list.
   Vector<T> AddBlock(T value, int count, Zone* zone);

   // Overwrites the element at the specific index.
   void Set(int index, const T& element);

   // Removes the i'th element without deleting it even if T is a
   // pointer type; moves all elements above i "down". Returns the
   // removed element.  This function's complexity is linear in the
   // size of the list.
   T Remove(int i);

   // Removes the last element without deleting it even if T is a
   // pointer type. Returns the removed element.
   V8_INLINE T RemoveLast() { return Remove(length_ - 1); }

   // Clears the list by freeing the storage memory. If you want to keep the
   // memory, use Rewind(0) instead. Be aware, that even if T is a
   // pointer type, clearing the list doesn't delete the entries.
   V8_INLINE void Clear(Zone* zone);

   // Clears the list but unlike Clear(), it doesn't free the storage memory.
   // It's useful when the whole zone containing the backing store will be
   // released but the list will be used further.
   V8_INLINE void DropAndClear() {
     data_ = nullptr;
     capacity_ = 0;
     length_ = 0;
   }

   // Drops all but the first 'pos' elements from the list.
   V8_INLINE void Rewind(int pos);

   inline bool Contains(const T& elm) const {
     for (int i = 0; i < length_; i++) {
       if (data_[i] == elm) return true;
     }
     return false;
   }

   // Iterate through all list entries, starting at index 0.
   template <class Visitor>
   void Iterate(Visitor* visitor);

   // Sort all list entries (using QuickSort)
   template <typename CompareFunction>
   void Sort(CompareFunction cmp);
   template <typename CompareFunction>
   void StableSort(CompareFunction cmp, size_t start, size_t length);

  private:
   T* data_ = nullptr;
   int capacity_ = 0;
   int length_ = 0;

   // Increase the capacity of a full list, and add an element.
   // List must be full already.
   void ResizeAdd(const T& element, Zone* zone);

   // Inlined implementation of ResizeAdd, shared by inlined and
   // non-inlined versions of ResizeAdd.
   void ResizeAddInternal(const T& element, Zone* zone);

   // Resize the list.
   void Resize(int new_capacity, Zone* zone);

   DISALLOW_COPY_AND_ASSIGN(ZoneList);
 };

 }  // namespace internal
 }  // namespace v8

 #endif  // V8_ZONE_ZONE_LIST_H_
	// Copyright 2020 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef V8_ZONE_ZONE_LIST_H_
	#define V8_ZONE_ZONE_LIST_H_

	#include "src/base/logging.h"
	#include "src/zone/zone.h"

	namespace v8 {
	namespace internal {

	template <typename T>
	class Vector;

	// ZoneLists are growable lists with constant-time access to the elements.
	// The list itself and all its elements are supposed to be allocated in zone
	// memory. Unlike ZoneVector container, the ZoneList instance has minimal
	// possible size which makes it a good candidate for embedding into other
	// often-allocated zone objects.
	//
	// Note, ZoneLists' elements cannot be deleted individually and the destructor
	// intentionally does not free the backing store. Because of the latter, the
	// ZoneList must not be used outsize of zone memory. Consider using ZoneVector
	// or other containers instead.
	template <typename T>
	class ZoneList final : public ZoneObject {
	public:
	// Construct a new ZoneList with the given capacity; the length is
	// always zero. The capacity must be non-negative.
	ZoneList(int capacity, Zone* zone) : capacity_(capacity) {
	DCHECK_GE(capacity, 0);
	data_ = (capacity_ > 0) ? zone->NewArray<T>(capacity_) : nullptr;
	}

	// Construct a new ZoneList by copying the elements of the given ZoneList.
	ZoneList(const ZoneList<T>& other, Zone* zone)
	: ZoneList(other.length(), zone) {
	AddAll(other, zone);
	}

	// Construct a new ZoneList by copying the elements of the given vector.
	ZoneList(const Vector<const T>& other, Zone* zone)
	: ZoneList(other.length(), zone) {
	AddAll(other, zone);
	}

	ZoneList(ZoneList<T>&& other) V8_NOEXCEPT { *this = std::move(other); }

	// The ZoneList objects are usually allocated as a fields in other
	// zone-allocated objects for which destructors are not called anyway, so
	// we are not going to clear the memory here as well.
	~ZoneList() = default;

	ZoneList& operator=(ZoneList&& other) V8_NOEXCEPT {
	// We don't have a Zone object, so we'll have to drop the data_ array.
	// If this assert ever fails, consider calling Clear(Zone*) or
	// DropAndClear() before the move assignment to make it explicit what's
	// happenning with the lvalue.
	DCHECK_NULL(data_);
	data_ = other.data_;
	capacity_ = other.capacity_;
	length_ = other.length_;
	other.DropAndClear();
	return *this;
	}

	// Returns a reference to the element at index i. This reference is not safe
	// to use after operations that can change the list's backing store
	// (e.g. Add).
	inline T& operator[](int i) const {
	DCHECK_LE(0, i);
	DCHECK_GT(static_cast<unsigned>(length_), static_cast<unsigned>(i));
	return data_[i];
	}
	inline T& at(int i) const { return operator[](i); }
	inline T& last() const { return at(length_ - 1); }
	inline T& first() const { return at(0); }

	using iterator = T*;
	inline iterator begin() { return &data_[0]; }
	inline iterator end() { return &data_[length_]; }

	using const_iterator = const T*;
	inline const_iterator begin() const { return &data_[0]; }
	inline const_iterator end() const { return &data_[length_]; }

	V8_INLINE bool is_empty() const { return length_ == 0; }
	V8_INLINE int length() const { return length_; }
	V8_INLINE int capacity() const { return capacity_; }

	Vector<T> ToVector() const { return Vector<T>(data_, length_); }
	Vector<T> ToVector(int start, int length) const {
	DCHECK_LE(start, length_);
	return Vector<T>(&data_[start], std::min(length_ - start, length));
	}

	Vector<const T> ToConstVector() const {
	return Vector<const T>(data_, length_);
	}

	// Adds a copy of the given 'element' to the end of the list,
	// expanding the list if necessary.
	void Add(const T& element, Zone* zone);
	// Add all the elements from the argument list to this list.
	void AddAll(const ZoneList<T>& other, Zone* zone);
	// Add all the elements from the vector to this list.
	void AddAll(const Vector<const T>& other, Zone* zone);
	// Inserts the element at the specific index.
	void InsertAt(int index, const T& element, Zone* zone);

	// Added 'count' elements with the value 'value' and returns a
	// vector that allows access to the elements. The vector is valid
	// until the next change is made to this list.
	Vector<T> AddBlock(T value, int count, Zone* zone);

	// Overwrites the element at the specific index.
	void Set(int index, const T& element);

	// Removes the i'th element without deleting it even if T is a
	// pointer type; moves all elements above i "down". Returns the
	// removed element. This function's complexity is linear in the
	// size of the list.
	T Remove(int i);

	// Removes the last element without deleting it even if T is a
	// pointer type. Returns the removed element.
	V8_INLINE T RemoveLast() { return Remove(length_ - 1); }

	// Clears the list by freeing the storage memory. If you want to keep the
	// memory, use Rewind(0) instead. Be aware, that even if T is a
	// pointer type, clearing the list doesn't delete the entries.
	V8_INLINE void Clear(Zone* zone);

	// Clears the list but unlike Clear(), it doesn't free the storage memory.
	// It's useful when the whole zone containing the backing store will be
	// released but the list will be used further.
	V8_INLINE void DropAndClear() {
	data_ = nullptr;
	capacity_ = 0;
	length_ = 0;
	}

	// Drops all but the first 'pos' elements from the list.
	V8_INLINE void Rewind(int pos);

	inline bool Contains(const T& elm) const {
	for (int i = 0; i < length_; i++) {
	if (data_[i] == elm) return true;
	}
	return false;
	}

	// Iterate through all list entries, starting at index 0.
	template <class Visitor>
	void Iterate(Visitor* visitor);

	// Sort all list entries (using QuickSort)
	template <typename CompareFunction>
	void Sort(CompareFunction cmp);
	template <typename CompareFunction>
	void StableSort(CompareFunction cmp, size_t start, size_t length);

	private:
	T* data_ = nullptr;
	int capacity_ = 0;
	int length_ = 0;

	// Increase the capacity of a full list, and add an element.
	// List must be full already.
	void ResizeAdd(const T& element, Zone* zone);

	// Inlined implementation of ResizeAdd, shared by inlined and
	// non-inlined versions of ResizeAdd.
	void ResizeAddInternal(const T& element, Zone* zone);

	// Resize the list.
	void Resize(int new_capacity, Zone* zone);

	DISALLOW_COPY_AND_ASSIGN(ZoneList);
	};

	} // namespace internal
	} // namespace v8

	#endif // V8_ZONE_ZONE_LIST_H_