/* $Id$ */ /* * This file is part of OpenTTD. * OpenTTD is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, version 2. * OpenTTD is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. * See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with OpenTTD. If not, see . */ /** @file binaryheap.hpp Binary heap implementation. */ #ifndef BINARYHEAP_HPP #define BINARYHEAP_HPP /** * Binary Heap as C++ template. * * For information about Binary Heap algotithm, * see: http://www.policyalmanac.org/games/binaryHeaps.htm * * Implementation specific notes: * * 1) It allocates space for item pointers (array). Items are allocated elsewhere. * * 2) T*[0] is never used. Total array size is max_items + 1, because we * use indices 1..max_items instead of zero based C indexing. * * 3) Item of the binary heap should support these public members: * - 'lower-than' operator '<' - used for comparing items before moving * */ template class CBinaryHeapT { private: uint m_size; ///< Number of items in the heap uint m_max_size; ///< Maximum number of items the heap can hold T **m_items; ///< The heap item pointers public: explicit CBinaryHeapT(uint max_items) : m_size(0) , m_max_size(max_items) { m_items = MallocT(max_items + 1); } ~CBinaryHeapT() { Clear(); free(m_items); m_items = NULL; } protected: /** Heapify (move gap) down */ FORCEINLINE uint HeapifyDown(uint gap, T *item) { assert(gap != 0); uint child = gap * 2; // first child is at [parent * 2] /* while children are valid */ while (child <= m_size) { /* choose the smaller child */ if (child < m_size && *m_items[child + 1] < *m_items[child]) child++; /* is it smaller than our parent? */ if (!(*m_items[child] < *item)) { /* the smaller child is still bigger or same as parent => we are done */ break; } /* if smaller child is smaller than parent, it will become new parent */ m_items[gap] = m_items[child]; gap = child; /* where do we have our new children? */ child = gap * 2; } return gap; } /** Heapify (move gap) up */ FORCEINLINE uint HeapifyUp(uint gap, T *item) { assert(gap != 0); uint parent; while (gap > 1) { /* compare [gap] with its parent */ parent = gap / 2; if (!(*item <*m_items[parent])) { /* we don't need to continue upstairs */ break; } m_items[gap] = m_items[parent]; gap = parent; } return gap; } public: /** Return the number of items stored in the priority queue. * @return number of items in the queue */ FORCEINLINE uint Size() const {return m_size;}; /** Test if the priority queue is empty. * @return true if empty */ FORCEINLINE bool IsEmpty() const {return (m_size == 0);}; /** Test if the priority queue is full. * @return true if full. */ FORCEINLINE bool IsFull() const {return (m_size >= m_max_size);}; /** Find the smallest item in the priority queue. * Return the smallest item, or throw assert if empty. */ FORCEINLINE T *Begin() { assert(!IsEmpty()); return m_items[1]; } FORCEINLINE T *End() { return m_items[1 + m_size]; } /** Insert new item into the priority queue, maintaining heap order. * @return false if the queue is full. */ FORCEINLINE void Push(T *new_item) { if (IsFull()) { m_max_size *= 2; m_items = ReallocT(m_items, m_max_size + 1); } /* make place for new item */ uint gap = HeapifyUp(++m_size, new_item); m_items[gap] = new_item; CheckConsistency(); } /** Remove and return the smallest item from the priority queue. */ FORCEINLINE T *Shift() { assert(!IsEmpty()); T *first = Begin(); m_size--; /* at index 1 we have a gap now */ T *last = End(); uint gap = HeapifyDown(1, last); /* move last item to the proper place */ if (!IsEmpty()) m_items[gap] = last; CheckConsistency(); return first; } /** Remove item specified by index */ FORCEINLINE void RemoveByIdx(uint idx) { if (idx < m_size) { assert(idx != 0); m_size--; /* at position idx we have a gap now */ T *last = End(); /* Fix binary tree up and downwards */ uint gap = HeapifyUp(idx, last); gap = HeapifyDown(gap, last); /* move last item to the proper place */ if (!IsEmpty()) m_items[gap] = last; } else { assert(idx == m_size); m_size--; } CheckConsistency(); } /** return index of the item that matches (using &item1 == &item2) the given item. */ FORCEINLINE uint FindLinear(const T& item) const { if (IsEmpty()) return 0; for (T **ppI = m_items + 1, **ppLast = ppI + m_size; ppI <= ppLast; ppI++) { if (*ppI == &item) { return ppI - m_items; } } return 0; } /** Make the priority queue empty. * All remaining items will remain untouched. */ FORCEINLINE void Clear() {m_size = 0;} /** verifies the heap consistency (added during first YAPF debug phase) */ FORCEINLINE void CheckConsistency() { /* enable it if you suspect binary heap doesn't work well */ #if 0 for (uint child = 2; child <= m_size; child++) { uint parent = child / 2; assert(!(*m_items[child] < *m_items[parent])); } #endif } }; #endif /* BINARYHEAP_HPP */