/*====================================================================* - Copyright (C) 2001 Leptonica. All rights reserved. - This software is distributed in the hope that it will be - useful, but with NO WARRANTY OF ANY KIND. - No author or distributor accepts responsibility to anyone for the - consequences of using this software, or for whether it serves any - particular purpose or works at all, unless he or she says so in - writing. Everyone is granted permission to copy, modify and - redistribute this source code, for commercial or non-commercial - purposes, with the following restrictions: (1) the origin of this - source code must not be misrepresented; (2) modified versions must - be plainly marked as such; and (3) this notice may not be removed - or altered from any source or modified source distribution. *====================================================================*/ #ifndef LEPTONICA_HEAP_H #define LEPTONICA_HEAP_H /* * heap.h * * Expandable priority queue configured as a heap for arbitrary void* data * * The L_Heap is used to implement a priority queue. The elements * in the heap are ordered in either increasing or decreasing key value. * The key is a float field 'keyval' that is required to be * contained in the elements of the queue. * * The heap is a simple binary tree with the following constraints: * - the key of each node is >= the keys of the two children * - the tree is complete, meaning that each level (1, 2, 4, ...) * is filled and the last level is filled from left to right * * The tree structure is implicit in the queue array, with the * array elements numbered as a breadth-first search of the tree * from left to right. It is thus guaranteed that the largest * (or smallest) key belongs to the first element in the array. * * Heap sort is used to sort the array. Once an array has been * sorted as a heap, it is convenient to use it as a priority queue, * because the min (or max) elements are always at the root of * the tree (element 0), and once removed, the heap can be * resorted in not more than log[n] steps, where n is the number * of elements on the heap. Likewise, if an arbitrary element is * added to the end of the array A, the sorted heap can be restored * in not more than log[n] steps. * * A L_Heap differs from a L_Queue in that the elements in the former * are sorted by a key. Internally, the array is maintained * as a queue, with a pointer to the end of the array. The * head of the array always remains at array[0]. The array is * maintained (sorted) as a heap. When an item is removed from * the head, the last item takes its place (thus reducing the * array length by 1), and this is followed by array element * swaps to restore the heap property. When an item is added, * it goes at the end of the array, and is swapped up to restore * the heap. If the ptr array is full, adding another item causes * the ptr array size to double. * * For further implementation details, see heap.c. */ struct L_Heap { l_int32 nalloc; /* size of allocated ptr array */ l_int32 n; /* number of elements stored in the heap */ void **array; /* ptr array */ l_int32 direction; /* L_SORT_INCREASING or L_SORT_DECREASING */ }; typedef struct L_Heap L_HEAP; #endif /* LEPTONICA_HEAP_H */