2 * Copyright (c) 1991, 1993
3 * The Regents of the University of California. All rights reserved.
5 * This code is derived from software contributed to Berkeley by
6 * Ronnie Kon at Mindcraft Inc., Kevin Lew and Elmer Yglesias.
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18 * This product includes software developed by the University of
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36 * @(#)heapsort.c 8.1 (Berkeley) 6/4/93
37 * $DragonFly: src/lib/libcr/stdlib/Attic/heapsort.c,v 1.5 2003/12/08 13:56:35 eirikn Exp $
45 * Swap two areas of size number of bytes. Although qsort(3) permits random
46 * blocks of memory to be sorted, sorting pointers is almost certainly the
47 * common case (and, were it not, could easily be made so). Regardless, it
48 * isn't worth optimizing; the SWAP's get sped up by the cache, and pointer
49 * arithmetic gets lost in the time required for comparison function calls.
51 #define SWAP(a, b, count, size, tmp) { \
60 /* Copy one block of size size to another. */
61 #define COPY(a, b, count, size, tmp1, tmp2) { \
71 * Build the list into a heap, where a heap is defined such that for
72 * the records K1 ... KN, Kj/2 >= Kj for 1 <= j/2 <= j <= N.
74 * There two cases. If j == nmemb, select largest of Ki and Kj. If
75 * j < nmemb, select largest of Ki, Kj and Kj+1.
77 #define CREATE(initval, nmemb, par_i, child_i, par, child, size, count, tmp) { \
78 for (par_i = initval; (child_i = par_i * 2) <= nmemb; \
80 child = base + child_i * size; \
81 if (child_i < nmemb && compar(child, child + size) < 0) { \
85 par = base + par_i * size; \
86 if (compar(child, par) <= 0) \
88 SWAP(par, child, count, size, tmp); \
93 * Select the top of the heap and 'heapify'. Since by far the most expensive
94 * action is the call to the compar function, a considerable optimization
95 * in the average case can be achieved due to the fact that k, the displaced
96 * elememt, is ususally quite small, so it would be preferable to first
97 * heapify, always maintaining the invariant that the larger child is copied
98 * over its parent's record.
100 * Then, starting from the *bottom* of the heap, finding k's correct place,
101 * again maintianing the invariant. As a result of the invariant no element
102 * is 'lost' when k is assigned its correct place in the heap.
104 * The time savings from this optimization are on the order of 15-20% for the
105 * average case. See Knuth, Vol. 3, page 158, problem 18.
107 * XXX Don't break the #define SELECT line, below. Reiser cpp gets upset.
109 #define SELECT(par_i, child_i, nmemb, par, child, size, k, count, tmp1, tmp2) { \
110 for (par_i = 1; (child_i = par_i * 2) <= nmemb; par_i = child_i) { \
111 child = base + child_i * size; \
112 if (child_i < nmemb && compar(child, child + size) < 0) { \
116 par = base + par_i * size; \
117 COPY(par, child, count, size, tmp1, tmp2); \
121 par_i = child_i / 2; \
122 child = base + child_i * size; \
123 par = base + par_i * size; \
124 if (child_i == 1 || compar(k, par) < 0) { \
125 COPY(child, k, count, size, tmp1, tmp2); \
128 COPY(child, par, count, size, tmp1, tmp2); \
133 * Heapsort -- Knuth, Vol. 3, page 145. Runs in O (N lg N), both average
134 * and worst. While heapsort is faster than the worst case of quicksort,
135 * the BSD quicksort does median selection so that the chance of finding
136 * a data set that will trigger the worst case is nonexistent. Heapsort's
137 * only advantage over quicksort is that it requires little additional memory.
140 heapsort(vbase, nmemb, size, compar)
143 int (*compar) (const void *, const void *);
146 char tmp, *tmp1, *tmp2;
147 char *base, *k, *p, *t;
157 if ((k = malloc(size)) == NULL)
161 * Items are numbered from 1 to nmemb, so offset from size bytes
162 * below the starting address.
164 base = (char *)vbase - size;
166 for (l = nmemb / 2 + 1; --l;)
167 CREATE(l, nmemb, i, j, t, p, size, cnt, tmp);
170 * For each element of the heap, save the largest element into its
171 * final slot, save the displaced element (k), then recreate the
175 COPY(k, base + nmemb * size, cnt, size, tmp1, tmp2);
176 COPY(base + nmemb * size, base + size, cnt, size, tmp1, tmp2);
178 SELECT(i, j, nmemb, t, p, size, k, cnt, tmp1, tmp2);
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