2014-07-28 05:34:24 +02:00
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/*
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* c_heap.c - (Min-/Max-)Heap and PrioSet
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*
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* Copyright (C) 2014 Tobias Boege <tobias@gambas-buch.de>
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2, or (at your option)
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* any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston,
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* MA 02110-1301, USA.
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*/
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#define __C_HEAP_C
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#include "gambas.h"
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#include "gb_common.h" /* EXTERN for gbx_compare.h */
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#include "gbx_compare.h" /* GB_COMP_{ASCENT,DESCENT} */
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#include "gbx_type.h" /* TYPE_is_object() */
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#include "c_heap.h"
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typedef struct {
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GB_BASE ob;
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int mode;
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int count;
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GB_VARIANT_VALUE *h;
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} CHEAP; /* "Hey! Don't talk like this about my data structures!" */
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static inline int compare(CHEAP *heap, int i, int j)
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{
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int res = GB.CompVariant(&heap->h[i], &heap->h[j]);
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return heap->mode == GB_COMP_ASCENT ? res : -res;
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}
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static inline int compare1(CHEAP *heap, GB_VARIANT_VALUE *x, int j)
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{
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int res = GB.CompVariant(x, &heap->h[j]);
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return heap->mode == GB_COMP_ASCENT ? res : -res;
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}
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static inline int compare3(CHEAP *heap, GB_VARIANT_VALUE *x,
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GB_VARIANT_VALUE *y)
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{
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int res = GB.CompVariant(x, y);
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return heap->mode == GB_COMP_ASCENT ? res : -res;
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}
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static inline void copy(CHEAP *heap, int src, int dst)
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{
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memmove(&heap->h[dst], &heap->h[src], sizeof(GB_VARIANT_VALUE));
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}
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static inline void copy1(CHEAP *heap, int src, GB_VARIANT_VALUE *dst)
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{
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memmove(dst, &heap->h[src], sizeof(GB_VARIANT_VALUE));
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}
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static inline void copy2(CHEAP *heap, GB_VARIANT_VALUE *src, int dst)
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{
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memmove(&heap->h[dst], src, sizeof(GB_VARIANT_VALUE));
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}
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#define left(k) (2 * (k) + 1)
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#define right(k) (left(k) + 1)
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#define parent(k) (((k) - 1) / 2)
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static int upheap(CHEAP *heap, int k)
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{
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GB_VARIANT_VALUE x;
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int r = 0;
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copy1(heap, k, &x);
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while (k && compare1(heap, &x, parent(k)) < 0) {
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copy(heap, parent(k), k);
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k = parent(k);
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r++;
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}
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copy2(heap, &x, k);
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return r;
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}
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static int downheap(CHEAP *heap, int k)
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{
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int count = GB.Count(heap->h), r = 0;
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GB_VARIANT_VALUE x;
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copy1(heap, k, &x);
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while (k <= parent(count - 1)) {
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int j, l = j = left(k), r = right(k);
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if (r < count && compare(heap, l, r) > 0)
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j = r;
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if (compare1(heap, &x, j) <= 0)
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break;
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copy(heap, j, k);
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k = j;
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r++;
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}
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copy2(heap, &x, k);
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return r;
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}
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static void new_heap(CHEAP *heap, int count)
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{
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GB.NewArray(&heap->h, sizeof(*heap->h), count);
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}
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static void rebuild(CHEAP *heap)
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{
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int i;
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for (i = parent(GB.Count(heap->h) - 1); i >= 0; i--)
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downheap(heap, i);
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}
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static void from_array(CHEAP *heap, GB_ARRAY array)
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{
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int count = GB.Array.Count(array), i;
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new_heap(heap, count);
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for (i = 0; i < count; i++) {
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memcpy(&heap->h[i], GB.Array.Get(array, i),
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sizeof(*heap->h));
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if (TYPE_is_object(heap->h[i].type))
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GB.Ref(heap->h[i].value._object);
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}
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rebuild(heap);
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}
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#define THIS ((CHEAP *) _object)
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/**G
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* Creates a new Heap.
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*
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* If 'Mode' is gb.Ascent, it's a MinHeap, i.e. the smallest element is at
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* the beginning. If 'mode' is gb.Descent, it's a MaxHeap.
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*
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* If the 'Array' argument is given, a copy of that array is transformed
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* into a Heap (by using a bottom-up algorithm which is O(n)).
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*/
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BEGIN_METHOD(Heap_new, GB_INTEGER mode; GB_OBJECT array)
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THIS->mode = VARG(mode);
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if (THIS->mode != GB_COMP_ASCENT && THIS->mode != GB_COMP_DESCENT) {
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GB.Error("Invalid mode");
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return;
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}
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if (MISSING(array)) {
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new_heap(THIS, 0);
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} else {
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GB_ARRAY array = (GB_ARRAY) VARG(array);
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if (GB.CheckObject(array))
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return;
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from_array(THIS, array);
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}
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END_METHOD
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/**G
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* Free up storage of the Heap
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*/
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BEGIN_METHOD_VOID(Heap_free)
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int count = GB.Count(THIS->h), i;
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for (i = 0; i < count; i++)
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GB.StoreVariant(NULL, &THIS->h[i]);
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GB.FreeArray(&THIS->h);
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END_METHOD
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/**G
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* Insert an element into the Heap.
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*/
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BEGIN_METHOD(Heap_Insert, GB_VARIANT data)
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GB.StoreVariant(ARG(data), GB.Add(&THIS->h));
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upheap(THIS, GB.Count(THIS->h) - 1);
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END_METHOD
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static void delete(CHEAP *heap, int i, GB_VARIANT_VALUE *x)
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{
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int count = GB.Count(heap->h);
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copy1(heap, i, x);
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copy(heap, count - 1, i);
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GB.Remove(&heap->h, count - 1, 1);
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downheap(heap, i);
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}
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/**G
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* Remove the first element.
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*/
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BEGIN_METHOD_VOID(Heap_Remove)
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int count = GB.Count(THIS->h);
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GB_VARIANT_VALUE x;
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if (!count) {
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GB.Error(GB_ERR_BOUND);
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return;
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}
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delete(THIS, 0, &x);
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GB.ReturnVariant(&x);
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GB.ReturnBorrow();
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GB.StoreVariant(NULL, &x);
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GB.ReturnRelease();
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END_METHOD
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2014-09-14 02:18:58 +02:00
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/*
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* Comparison by identity works as follows:
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* - if both are objects and have _identity() methods which return
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* variants, the return value is the comparison of those variants,
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* - if they are objects without _identity(), they are compared based
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* on their addresses in memory,
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* - else they are not objects and are normally compared.
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*/
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static int compare_identity(CHEAP *heap, GB_VARIANT_VALUE *a,
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GB_VARIANT_VALUE *b)
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{
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static int has_identity;
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static GB_FUNCTION aid;
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static GB_VARIANT_VALUE *last = NULL;
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static GB_VALUE x;
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GB_FUNCTION bid;
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GB_VALUE *y;
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if (!TYPE_is_object(a->type) || !TYPE_is_object(b->type))
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return compare3(heap, a, b);
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if (last != a) {
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if (!GB.GetFunction(&aid, a->value._object, "_identity",
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NULL, "v")) {
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has_identity = 1;
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memcpy(&x, GB.Call(&aid, 0, 0), sizeof(x));
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} else {
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has_identity = 0;
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}
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GB.Error(NULL); /* Clear any GetFunction error */
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last = a;
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}
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/* No _identity()? */
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if (!has_identity || GB.GetFunction(&bid, b->value._object,
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"_identity", NULL, "v")) {
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GB.Error(NULL);
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return a->value._object != b->value._object;
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}
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y = GB.Call(&bid, 0, 0);
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return compare3(heap, &x._variant.value, &y->_variant.value);
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}
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2014-07-28 05:34:24 +02:00
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/**G
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* Find all occurences of `Old' and replace them by `New'. This is an O(n)
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2014-09-14 02:18:58 +02:00
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* operation. Additionally the heap has to be rebuilt as soon as there is
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2014-07-28 05:34:24 +02:00
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* more than one replacement made.
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*
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* If `New' is Null, then the entry will be deleted.
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*
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2014-09-14 02:18:58 +02:00
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* The search for objects is done by identity and *not* by using the
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* _compare() method. "By identity" means that if two objects are to be
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* compared and both have a special _identity() method returning a Variant,
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* the return values of these methods are compared.
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*
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* If one of the objects does not implement the _identity() method, the
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* default is comparison by object addresses in memory. This strategy lets
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* you save primitive data types (Integer, Boolean, String), etc. in the
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* heap. But you can also *distinct* objects in equivalence classes. The
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* _compare() method defines your equivalence relation, the identity
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* comparison enables to discern different objects.
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2014-07-28 05:34:24 +02:00
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*
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* If we are a heap of objects whose _compare() methods compare some sort of
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* priority, and `Old' is the same object as `New', this can be used to
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* propagate a priority change made to the object and will correct its
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* position in the heap.
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*
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* This has an application in Dijkstra's algorithm (or any priority first
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* search like Prim or A*) where you would update a node's priority.
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*/
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BEGIN_METHOD(Heap_Update, GB_VARIANT old; GB_VARIANT new)
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int count = GB.Count(THIS->h), i, found = 0, idx = -1;
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GB_VARIANT_VALUE *old, *new;
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old = &VARG(old); new = &VARG(new);
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for (i = 0; i < count; i++) {
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if (compare_identity(THIS, old, &THIS->h[i]))
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2014-07-28 05:34:24 +02:00
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continue;
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/*
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* Make Null delete the entry. We don't count that as a
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* finding because we can fix the heap up on the fly.
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*/
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if (new->type == GB_T_NULL) {
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GB_VARIANT_VALUE buf;
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delete(THIS, i, &buf);
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GB.StoreVariant(NULL, &buf);
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count = GB.Count(THIS->h);
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continue;
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}
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/* XXX: If `old' and `new' are the same and if they're
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* objects, memory errors will occur if you store one over
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* the other... Maybe StoreVariant() wasn't made to replace
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* an object by itself (refcount goes to zero before it is
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* incremented again, maybe?) */
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if (!TYPE_is_object(THIS->h[i].type)
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|| THIS->h[i].value._object != new->value._object)
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GB.StoreVariant(ARG(new), &THIS->h[i]);
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found++;
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idx = i;
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}
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/*
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* Most applications will have pairwise distinct elements in the
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* heap, so that at most one element is changed. In this case, we
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* can get away more quickly (O(log n) vs. O(n)) with an upheap()
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* or downheap() call.
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*/
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if (found == 1) {
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if (!upheap(THIS, idx))
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downheap(THIS, idx);
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} else if (found) {
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rebuild(THIS);
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}
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END_METHOD
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/**G
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* Return or set the first element of the Heap.
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*/
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BEGIN_PROPERTY(Heap_First)
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if (!GB.Count(THIS->h)) {
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GB.Error(GB_ERR_BOUND);
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return;
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}
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if (READ_PROPERTY) {
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GB.ReturnVariant(&THIS->h[0]);
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return;
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}
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GB.StoreVariant(PROP(GB_VARIANT), &THIS->h[0]);
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downheap(THIS, 0);
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END_PROPERTY
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/**G
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* Return the number of elements in the Heap.
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*/
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BEGIN_PROPERTY(Heap_Count)
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GB.ReturnInteger(GB.Count(THIS->h));
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END_PROPERTY
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/**G
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* Return whether the Heap is empty.
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*/
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BEGIN_PROPERTY(Heap_IsEmpty)
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GB.ReturnBoolean(GB.Count(THIS->h) == 0);
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|
END_PROPERTY
|
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|
|
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|
|
GB_DESC CHeap[] = {
|
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|
|
/**G Heap
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|
|
* This class implements a dynamic heap. It can be a MinHeap or a
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|
|
* MaxHeap, depending on what mode you specify on construction.
|
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|
|
*
|
|
|
|
* Being `dynamic' means that this class allows you to update the
|
|
|
|
* data or the position of elements which are already in the heap.
|
|
|
|
*/
|
|
|
|
GB_DECLARE("Heap", sizeof(CHEAP)),
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|
|
GB_METHOD("_new", NULL, Heap_new, "(Mode)i[(Array)Variant[];]"),
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|
|
GB_METHOD("_free", NULL, Heap_free, NULL),
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|
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|
|
GB_METHOD("Insert", NULL, Heap_Insert, "(Data)v"),
|
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|
|
GB_METHOD("Remove", "v", Heap_Remove, NULL),
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|
|
GB_METHOD("Update", NULL, Heap_Update, "(Old)v(New)v"),
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|
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|
|
|
GB_PROPERTY("First", "v", Heap_First),
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|
|
GB_PROPERTY_READ("Count", "i", Heap_Count),
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|
|
|
GB_PROPERTY_READ("IsEmpty", "b", Heap_IsEmpty),
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|
|
|
|
|
|
|
GB_END_DECLARE
|
|
|
|
};
|