/* * Created by Brett on 26/12/22. * Licensed under GNU General Public License V3.0 * See LICENSE file for license detail */ #ifndef BLT_QUEUE_H #define BLT_QUEUE_H /** * */ namespace blt { /** * Standard array backed first in first out queue * @tparam T type stored in the queue */ template class flat_stack { private: int m_size = 16; int m_insertIndex = 0; T* m_data = new T[m_size]; /** * Expands the internal array to the new size, copying over the data and shifting its minimal position to index 0 * and deletes the old array from memory. * @param newSize new size of the internal array */ void expand() { int new_size = m_size * 2; auto tempData = new T[new_size]; for (int i = 0; i < m_insertIndex; i++) tempData[i] = m_data[i]; delete[] m_data; m_data = tempData; m_size = new_size; } public: void push(const T& t) { if (m_insertIndex >= m_size) { expand(); } m_data[m_insertIndex++] = t; } /** * Warning does not contain runtime error checking! * @return the element at the "front" of the queue. */ [[nodiscard]] const T& top() const { return m_data[m_insertIndex - 1]; } void pop() { if (empty()) return; m_insertIndex--; } [[nodiscard]] inline bool empty() const { return m_insertIndex <= 0; } [[nodiscard]] inline int size() const { return m_insertIndex; } ~flat_stack() { delete[](m_data); } }; /** * Standard array backed first in last out queue (stack) * @tparam T type stored in the queue */ template class flat_queue { private: int m_size = 16; int m_headIndex = 0; int m_insertIndex = 0; T* m_data; /** * Expands the internal array to allow for more storage of elements */ void expand() { int new_size = m_size * 2; int removed_size = m_size - m_headIndex; auto tempData = new T[new_size]; // only copy data from where we've removed onward for (int i = 0; i < removed_size; i++) tempData[i] = m_data[i + m_headIndex]; // but don't copy data we've pop'd delete[] m_data; m_headIndex = 0; m_insertIndex = removed_size - 1; m_data = tempData; m_size = new_size; } public: flat_queue(): m_data(new T[m_size]) { } inline void push(const T& t) { if (m_insertIndex + 1 >= m_size) { expand(); } m_data[m_insertIndex++] = t; } /** * Warning does not contain runtime error checking! * @return the element at the "front" of the queue. */ [[nodiscard]] const T& front() const { return m_data[m_headIndex]; } [[nodiscard]] T& front() { return m_data[m_headIndex]; } inline void pop() { if (empty()) return; m_headIndex++; } [[nodiscard]] inline bool empty() const { return m_headIndex >= m_size; } [[nodiscard]] inline int size() const { return m_insertIndex - m_headIndex; } inline T* begin() { return m_data[m_headIndex]; } inline T* end() { return m_data[m_insertIndex]; } ~flat_queue() { delete[](m_data); } }; template class linked_stack { private: struct node { T t; node* next; node(const T& t, node* node): t(t), next(node) {} node(T&& t, node* node): t(std::move(t)), next(node) {} }; node* head = nullptr; public: inline void push(const T& t) { head = new node(t, head); } inline void push(T&& t) { head = new node(std::move(t), head); } inline T& top() { return head->t; } inline const T& top() const { return head->t; } inline void pop() { auto* h = head; head = head->next; delete h; } ~linked_stack() { auto* h = head; while (h != nullptr) { auto* hc = h; h = h->next; delete hc; } } }; } #endif //BLT_QUEUE_H