X-Git-Url: http://info.iut-bm.univ-fcomte.fr/pub/gitweb/simgrid.git/blobdiff_plain/ed2b5490d6323626eff2efb0021d1deba7e2fd60..488566dad1ae2b42f26a8e291824ff9b16a976f7:/src/xbt/heap.c diff --git a/src/xbt/heap.c b/src/xbt/heap.c index f5549a46f0..2eced61e99 100644 --- a/src/xbt/heap.c +++ b/src/xbt/heap.c @@ -1,67 +1,102 @@ /* a generic and efficient heap */ -/* Authors: Arnaud Legrand */ +/* Copyright (c) 2004, 2005, 2007, 2008, 2009, 2010. The SimGrid Team. + * All rights reserved. */ /* This program is free software; you can redistribute it and/or modify it - under the terms of the license (GNU LGPL) which comes with this package. */ + * under the terms of the license (GNU LGPL) which comes with this package. */ +#include "xbt/sysdep.h" +#include "xbt/log.h" #include "heap_private.h" +#include + + +/** @addtogroup XBT_heap + * \brief This section describes the API to generic heap with O(log(n)) access. + */ + /** - * xbt_heap_new: - * @init_size: initial size of the heap - * @free_func: function to call on each element when you want to free the whole heap (or NULL if nothing to do). + * @brief Creates a new heap. + * \param init_size initial size of the heap + * \param free_func function to call on each element when you want to free + * the whole heap (or NULL if nothing to do). * * Creates a new heap. */ -xbt_heap_t xbt_heap_new(int init_size, void_f_pvoid_t * const free_func) +XBT_INLINE xbt_heap_t xbt_heap_new(int init_size, + void_f_pvoid_t const free_func) { - xbt_heap_t H = calloc(1, sizeof(struct xbt_heap)); + xbt_heap_t H = xbt_new0(struct xbt_heap, 1); H->size = init_size; H->count = 0; - H->items = - (xbt_heapItem_t) calloc(init_size, sizeof(struct xbt_heapItem)); - H->free = free; + H->items = (xbt_heapItem_t) xbt_new0(struct xbt_heapItem, init_size); + H->free = free_func; return H; } /** - * xbt_heap_free: - * @H: poor victim - * - * kilkil a heap and its content + * @brief Set the update callback function. + * @param H the heap we're working on + * \param update_callback function to call on each element to update its index when needed. + */ +XBT_INLINE void xbt_heap_set_update_callback(xbt_heap_t H, + void (*update_callback) (void + *, + int)) +{ + H->update_callback = update_callback; +} + + +/** + * @brief kilkil a heap and its content + * @param H poor victim */ void xbt_heap_free(xbt_heap_t H) { int i; if (H->free) - for (i = 0; i < H->size; i++) - H->free(H->items[i].content); + for (i = 0; i < H->count; i++) + (*(H->free)) (H->items[i].content); free(H->items); free(H); return; } /** - * xbt_heap_push: - * @H: the heap we're working on - * @content: the object you want to add to the heap - * @key: the key associated to this object + * @brief returns the number of elements in the heap + * @param H the heap we're working on + * @return the number of elements in the heap + */ +XBT_INLINE int xbt_heap_size(xbt_heap_t H) +{ + return (H->count); +} + +/** + * @brief Add an element into the heap. + * \param H the heap we're working on + * \param content the object you want to add to the heap + * \param key the key associated to this object * - * Add an element int the heap. The element with the smallest key is - * automatically moved at the top of the heap. + * The element with the smallest key is automatically moved at the top of the heap. */ -void xbt_heap_push(xbt_heap_t H, void *content, xbt_heap_float_t key) +void xbt_heap_push(xbt_heap_t H, void *content, double key) { int count = ++(H->count); + int size = H->size; xbt_heapItem_t item; + if (count > size) { H->size = 2 * size + 1; H->items = - (void *) realloc(H->items, - (H->size) * sizeof(struct xbt_heapItem)); + (void *) realloc(H->items, + (H->size) * sizeof(struct xbt_heapItem)); } + item = &(H->items[count - 1]); item->key = key; item->content = content; @@ -70,8 +105,9 @@ void xbt_heap_push(xbt_heap_t H, void *content, xbt_heap_float_t key) } /** - * xbt_heap_pop: - * @H: the heap we're working on + * @brief Extracts from the heap and returns the element with the smallest key. + * \param H the heap we're working on + * \return the element with the smallest key * * Extracts from the heap and returns the element with the smallest * key. The element with the next smallest key is automatically moved @@ -79,49 +115,80 @@ void xbt_heap_push(xbt_heap_t H, void *content, xbt_heap_float_t key) */ void *xbt_heap_pop(xbt_heap_t H) { - void *max = CONTENT(H, 0); + void *max; + + if (H->count == 0) + return NULL; + + max = CONTENT(H, 0); + H->items[0] = H->items[(H->count) - 1]; (H->count)--; xbt_heap_maxHeapify(H); if (H->count < H->size / 4 && H->size > 16) { H->size = H->size / 2 + 1; H->items = - (void *) realloc(H->items, - (H->size) * sizeof(struct xbt_heapItem)); + (void *) realloc(H->items, + (H->size) * sizeof(struct xbt_heapItem)); } + + if (H->update_callback) + H->update_callback(max, -1); return max; } /** - * xbt_heap_maxkey: - * @H: the heap we're working on + * @brief Extracts from the heap and returns the element at position i. + * \param H the heap we're working on + * \param i element position + * \return the element at position i if ok, NULL otherwise * - * Returns the smallest key in the heap without modifying the heap. + * Extracts from the heap and returns the element at position i. The head is automatically reorded. */ -xbt_heap_float_t xbt_heap_maxkey(xbt_heap_t H) +void *xbt_heap_remove(xbt_heap_t H, int i) { + if ((i < 0) || (i > H->count - 1)) + return NULL; + /* put element i at head */ + if (i > 0) { + KEY(H, i) = MIN_KEY_VALUE; + xbt_heap_increaseKey(H, i); + } + + return xbt_heap_pop(H); +} + +/** + * @brief returns the smallest key in the heap (heap unchanged) + * \param H the heap we're working on + * + * \return the smallest key in the heap without modifying the heap. + */ +XBT_INLINE double xbt_heap_maxkey(xbt_heap_t H) +{ + xbt_assert0(H->count != 0, "Empty heap"); return KEY(H, 0); } /** - * xbt_heap_maxcontent: - * @H: the heap we're working on + * @brief returns the value associated to the smallest key in the heap (heap unchanged) + * \param H the heap we're working on * - * Returns the value associated to the smallest key in the heap + * \return the value associated to the smallest key in the heap * without modifying the heap. */ void *xbt_heap_maxcontent(xbt_heap_t H) { + xbt_assert0(H->count != 0, "Empty heap"); return CONTENT(H, 0); } -/** - * xbt_heap_maxcontent: - * @H: the heap we're working on - * +/* <<<< private >>>> + * \param H the heap we're working on + * * Restores the heap property once an element has been deleted. */ -void xbt_heap_maxHeapify(xbt_heap_t H) +static void xbt_heap_maxHeapify(xbt_heap_t H) { int i = 0; while (1) { @@ -137,27 +204,35 @@ void xbt_heap_maxHeapify(xbt_heap_t H) struct xbt_heapItem tmp = H->items[i]; H->items[i] = H->items[greatest]; H->items[greatest] = tmp; + if (H->update_callback) + H->update_callback(CONTENT(H, i), i); i = greatest; - } else + } else { + if (H->update_callback) + H->update_callback(CONTENT(H, i), i); return; + } } } -/** - * xbt_heap_maxcontent: - * @H: the heap we're working on - * @i: an item position in the heap - * +/* <<<< private >>>> + * \param H the heap we're working on + * \param i an item position in the heap + * * Moves up an item at position i to its correct position. Works only * when called from xbt_heap_push. Do not use otherwise. */ -void xbt_heap_increaseKey(xbt_heap_t H, int i) +static void xbt_heap_increaseKey(xbt_heap_t H, int i) { while (i > 0 && KEY(H, PARENT(i)) > KEY(H, i)) { struct xbt_heapItem tmp = H->items[i]; H->items[i] = H->items[PARENT(i)]; H->items[PARENT(i)] = tmp; + if (H->update_callback) + H->update_callback(CONTENT(H, i), i); i = PARENT(i); } + if (H->update_callback) + H->update_callback(CONTENT(H, i), i); return; }