LazyRen/heap.cpp

## heap.cpp
template <typename T>
class Heap {
private:
  using size_type = size_t;
  T* arr;
  size_type _size;
  size_type _capacity;
  bool is_max_heap;
  static constexpr size_type DEFAULT_CAP = 32;

public:
  Heap(bool is_max_heap = true) : arr{new T[DEFAULT_CAP]}, _size{0}, _capacity{DEFAULT_CAP}, is_max_heap{is_max_heap} {}
  Heap(T inp[], size_type length, bool is_max_heap = true) : arr{nullptr}, _size{length}, _capacity{DEFAULT_CAP}, is_max_heap{is_max_heap} {
    heapify(inp, length);
  }
  ~Heap() { delete[] arr; }

  void heapify(T inp[], size_type length, bool is_max_heap = true) {
    this->is_max_heap = is_max_heap;
    if (length > _capacity) {
      while (length > _capacity)
        _capacity *= 2;
      delete[] arr;
      arr = new T[_capacity];
    }

    for (size_type i = 0; i < length; i++)
      arr[i] = inp[i];

    _size = length;
    size_type cur = getParent(_size - 1);

    while (cur > 0)
      siftDown(cur--);
    siftDown(cur);
  }

  void push(T item) {
    if (_size == _capacity) {
      _capacity *= 2;
      T *tmp = new T[_capacity];
      for (size_type i = 0; i < _size; i++)
        tmp[i] = arr[i];
      delete[] arr;
      arr = tmp;
    }
    arr[_size] = item;
    siftUp(_size++);
  }

  void pop() {
    if (_size == 0)
      throw std::out_of_range("Empty heap");
    arr[0] = arr[--_size];
    siftDown(0);
  }

  T top() const {
    if (_size == 0)
      throw std::out_of_range("Empty heap");
    return arr[0];
  }

  void reserve(size_type cap) {
    if (_capacity >= cap)
      return;
    T *tmp = new T[cap];
    for (size_type i = 0; i < _size; i++)
      tmp[i] = arr[i];
    delete[] arr;
    arr = tmp;
    _capacity = cap;
  }

  void clear(bool is_max_heap = true) {
    delete[] arr;
    arr = new T[DEFAULT_CAP];
    _size = 0;
    _capacity = DEFAULT_CAP;
    this->is_max_heap = is_max_heap;
  }

  inline size_type size() const { return _size; }
  inline size_type capacity() const { return _capacity; }
  inline bool empty() const { return _size == 0; }

private:
  inline size_type getParent(size_type idx) const { return (idx - 1) >> 1; }
  inline size_type getLeftChild(size_type idx) const { return (idx << 1) + 1; }
  inline size_type getRightChild(size_type idx) const { return (idx << 1) + 2; }

  inline bool needToSwap(T& a, T& b) const {
    if (is_max_heap)
      return a < b;
    else
      return a > b;
  }

  inline void swap(T& a, T& b) {
    T tmp = a;
    a = b;
    b = tmp;
  }

  void siftUp(size_type cur) {
    while (true) {
      if (cur == 0)
        break;
      size_type parent = getParent(cur);
      if (needToSwap(arr[parent], arr[cur]))
        swap(arr[cur], arr[parent]);
      else
        break;
      cur = parent;
    }
  }

  void siftDown(size_type cur) {
    while (getLeftChild(cur) < _size) {
      size_type left = getLeftChild(cur), right = getRightChild(cur);
      size_type to_swap = cur;

      if (needToSwap(arr[to_swap], arr[left]))
        to_swap = left;
      if (right < _size && needToSwap(arr[to_swap], arr[right]))
        to_swap = right;

      if (to_swap != cur) {
        swap(arr[to_swap], arr[cur]);
        cur = to_swap;
      } else {
          return;
      }
    }
  }
};
	template <typename T>
	class Heap {
	private:
	using size_type = size_t;
	T* arr;
	size_type _size;
	size_type _capacity;
	bool is_max_heap;
	static constexpr size_type DEFAULT_CAP = 32;

	public:
	Heap(bool is_max_heap = true) : arr{new T[DEFAULT_CAP]}, _size{0}, _capacity{DEFAULT_CAP}, is_max_heap{is_max_heap} {}
	Heap(T inp[], size_type length, bool is_max_heap = true) : arr{nullptr}, _size{length}, _capacity{DEFAULT_CAP}, is_max_heap{is_max_heap} {
	heapify(inp, length);
	}
	~Heap() { delete[] arr; }

	void heapify(T inp[], size_type length, bool is_max_heap = true) {
	this->is_max_heap = is_max_heap;
	if (length > _capacity) {
	while (length > _capacity)
	_capacity *= 2;
	delete[] arr;
	arr = new T[_capacity];
	}

	for (size_type i = 0; i < length; i++)
	arr[i] = inp[i];

	_size = length;
	size_type cur = getParent(_size - 1);

	while (cur > 0)
	siftDown(cur--);
	siftDown(cur);
	}

	void push(T item) {
	if (_size == _capacity) {
	_capacity *= 2;
	T *tmp = new T[_capacity];
	for (size_type i = 0; i < _size; i++)
	tmp[i] = arr[i];
	delete[] arr;
	arr = tmp;
	}
	arr[_size] = item;
	siftUp(_size++);
	}

	void pop() {
	if (_size == 0)
	throw std::out_of_range("Empty heap");
	arr[0] = arr[--_size];
	siftDown(0);
	}

	T top() const {
	if (_size == 0)
	throw std::out_of_range("Empty heap");
	return arr[0];
	}

	void reserve(size_type cap) {
	if (_capacity >= cap)
	return;
	T *tmp = new T[cap];
	for (size_type i = 0; i < _size; i++)
	tmp[i] = arr[i];
	delete[] arr;
	arr = tmp;
	_capacity = cap;
	}

	void clear(bool is_max_heap = true) {
	delete[] arr;
	arr = new T[DEFAULT_CAP];
	_size = 0;
	_capacity = DEFAULT_CAP;
	this->is_max_heap = is_max_heap;
	}

	inline size_type size() const { return _size; }
	inline size_type capacity() const { return _capacity; }
	inline bool empty() const { return _size == 0; }

	private:
	inline size_type getParent(size_type idx) const { return (idx - 1) >> 1; }
	inline size_type getLeftChild(size_type idx) const { return (idx << 1) + 1; }
	inline size_type getRightChild(size_type idx) const { return (idx << 1) + 2; }

	inline bool needToSwap(T& a, T& b) const {
	if (is_max_heap)
	return a < b;
	else
	return a > b;
	}

	inline void swap(T& a, T& b) {
	T tmp = a;
	a = b;
	b = tmp;
	}

	void siftUp(size_type cur) {
	while (true) {
	if (cur == 0)
	break;
	size_type parent = getParent(cur);
	if (needToSwap(arr[parent], arr[cur]))
	swap(arr[cur], arr[parent]);
	else
	break;
	cur = parent;
	}
	}

	void siftDown(size_type cur) {
	while (getLeftChild(cur) < _size) {
	size_type left = getLeftChild(cur), right = getRightChild(cur);
	size_type to_swap = cur;

	if (needToSwap(arr[to_swap], arr[left]))
	to_swap = left;
	if (right < _size && needToSwap(arr[to_swap], arr[right]))
	to_swap = right;

	if (to_swap != cur) {
	swap(arr[to_swap], arr[cur]);
	cur = to_swap;
	} else {
	return;
	}
	}
	}
	};