1*6070Srobj /*
2*6070Srobj * CDDL HEADER START
3*6070Srobj *
4*6070Srobj * The contents of this file are subject to the terms of the
5*6070Srobj * Common Development and Distribution License (the "License").
6*6070Srobj * You may not use this file except in compliance with the License.
7*6070Srobj *
8*6070Srobj * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9*6070Srobj * or http://www.opensolaris.org/os/licensing.
10*6070Srobj * See the License for the specific language governing permissions
11*6070Srobj * and limitations under the License.
12*6070Srobj *
13*6070Srobj * When distributing Covered Code, include this CDDL HEADER in each
14*6070Srobj * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15*6070Srobj * If applicable, add the following below this CDDL HEADER, with the
16*6070Srobj * fields enclosed by brackets "[]" replaced with your own identifying
17*6070Srobj * information: Portions Copyright [yyyy] [name of copyright owner]
18*6070Srobj *
19*6070Srobj * CDDL HEADER END
20*6070Srobj */
21*6070Srobj /*
22*6070Srobj * Copyright 2008 Sun Microsystems, Inc. All rights reserved.
23*6070Srobj * Use is subject to license terms.
24*6070Srobj */
25*6070Srobj
26*6070Srobj #pragma ident "%Z%%M% %I% %E% SMI"
27*6070Srobj
28*6070Srobj #include <strings.h>
29*6070Srobj
30*6070Srobj #include <assert.h>
31*6070Srobj #include <ipmi_impl.h>
32*6070Srobj #include <string.h>
33*6070Srobj #include <strings.h>
34*6070Srobj
35*6070Srobj /*
36*6070Srobj * The (prime) number 137 happens to have the nice property that -- when
37*6070Srobj * multiplied by two and added to 33 -- one gets a pretty long series of
38*6070Srobj * primes:
39*6070Srobj *
40*6070Srobj * 307, 647, 1327, 2687, 5407, 10847, 21727, 43487
41*6070Srobj *
42*6070Srobj * And beyond 43487, the numbers in the series have few factors or are prime.
43*6070Srobj * That is, one can have a prime number and roughly double it to get another
44*6070Srobj * prime number -- but the series starts at 137. A size of 137 buckets doesn't
45*6070Srobj * particularly accommodate small hash tables, but we note that 13 also yields
46*6070Srobj * a reasonable sequence when doubling it and adding 5:
47*6070Srobj *
48*6070Srobj * 13, 31, 67, 139, 283, 571
49*6070Srobj *
50*6070Srobj * So we start with this second sequence, crossing over to the first when
51*6070Srobj * the size is greater than 137. (And when reducing the size of the hash
52*6070Srobj * table, we cross back when the size gets below 67.)
53*6070Srobj */
54*6070Srobj #define IPMI_HASHCROSSOVER 137
55*6070Srobj #define IPMI_HASHCROSSUNDER 67
56*6070Srobj #define IPMI_HASHMINSIZE 13
57*6070Srobj
58*6070Srobj static ulong_t
ipmi_hash_double(ulong_t size)59*6070Srobj ipmi_hash_double(ulong_t size)
60*6070Srobj {
61*6070Srobj ulong_t nsize;
62*6070Srobj
63*6070Srobj if (size < IPMI_HASHCROSSOVER) {
64*6070Srobj nsize = (size * 2) + 5;
65*6070Srobj return (nsize < IPMI_HASHCROSSOVER ? nsize :
66*6070Srobj IPMI_HASHCROSSOVER);
67*6070Srobj }
68*6070Srobj
69*6070Srobj return ((size * 2) + 33);
70*6070Srobj }
71*6070Srobj
72*6070Srobj static ulong_t
ipmi_hash_half(ulong_t size)73*6070Srobj ipmi_hash_half(ulong_t size)
74*6070Srobj {
75*6070Srobj ulong_t nsize;
76*6070Srobj
77*6070Srobj if (size > IPMI_HASHCROSSUNDER) {
78*6070Srobj nsize = (size - 33) / 2;
79*6070Srobj return (nsize > IPMI_HASHCROSSUNDER ? nsize :
80*6070Srobj IPMI_HASHCROSSUNDER);
81*6070Srobj }
82*6070Srobj
83*6070Srobj nsize = (size - 5) / 2;
84*6070Srobj
85*6070Srobj return (nsize > IPMI_HASHMINSIZE ? nsize : IPMI_HASHMINSIZE);
86*6070Srobj }
87*6070Srobj
88*6070Srobj ipmi_hash_t *
ipmi_hash_create(ipmi_handle_t * hp,size_t linkoffs,const void * (* convert)(const void * elem),ulong_t (* compute)(const void * key),int (* compare)(const void * lkey,const void * rkey))89*6070Srobj ipmi_hash_create(ipmi_handle_t *hp, size_t linkoffs,
90*6070Srobj const void *(*convert)(const void *elem),
91*6070Srobj ulong_t (*compute)(const void *key),
92*6070Srobj int (*compare)(const void *lkey, const void *rkey))
93*6070Srobj {
94*6070Srobj ipmi_hash_t *ihp;
95*6070Srobj
96*6070Srobj if ((ihp = ipmi_zalloc(hp, sizeof (ipmi_hash_t))) == NULL)
97*6070Srobj return (NULL);
98*6070Srobj
99*6070Srobj ihp->ih_handle = hp;
100*6070Srobj ihp->ih_nbuckets = IPMI_HASHMINSIZE;
101*6070Srobj ihp->ih_linkoffs = linkoffs;
102*6070Srobj ihp->ih_convert = convert;
103*6070Srobj ihp->ih_compute = compute;
104*6070Srobj ihp->ih_compare = compare;
105*6070Srobj
106*6070Srobj if ((ihp->ih_buckets = ipmi_zalloc(hp,
107*6070Srobj ihp->ih_nbuckets * sizeof (void *))) == NULL) {
108*6070Srobj ipmi_free(hp, ihp);
109*6070Srobj return (NULL);
110*6070Srobj }
111*6070Srobj
112*6070Srobj return (ihp);
113*6070Srobj }
114*6070Srobj
115*6070Srobj void
ipmi_hash_destroy(ipmi_hash_t * ihp)116*6070Srobj ipmi_hash_destroy(ipmi_hash_t *ihp)
117*6070Srobj {
118*6070Srobj if (ihp != NULL) {
119*6070Srobj ipmi_free(ihp->ih_handle, ihp->ih_buckets);
120*6070Srobj ipmi_free(ihp->ih_handle, ihp);
121*6070Srobj }
122*6070Srobj }
123*6070Srobj
124*6070Srobj ulong_t
ipmi_hash_strhash(const void * key)125*6070Srobj ipmi_hash_strhash(const void *key)
126*6070Srobj {
127*6070Srobj ulong_t g, h = 0;
128*6070Srobj const char *p;
129*6070Srobj
130*6070Srobj for (p = key; *p != '\0'; p++) {
131*6070Srobj h = (h << 4) + *p;
132*6070Srobj
133*6070Srobj if ((g = (h & 0xf0000000)) != 0) {
134*6070Srobj h ^= (g >> 24);
135*6070Srobj h ^= g;
136*6070Srobj }
137*6070Srobj }
138*6070Srobj
139*6070Srobj return (h);
140*6070Srobj }
141*6070Srobj
142*6070Srobj int
ipmi_hash_strcmp(const void * lhs,const void * rhs)143*6070Srobj ipmi_hash_strcmp(const void *lhs, const void *rhs)
144*6070Srobj {
145*6070Srobj return (strcmp(lhs, rhs));
146*6070Srobj }
147*6070Srobj
148*6070Srobj ulong_t
ipmi_hash_ptrhash(const void * key)149*6070Srobj ipmi_hash_ptrhash(const void *key)
150*6070Srobj {
151*6070Srobj return (*((const uintptr_t *)key) >> 4);
152*6070Srobj }
153*6070Srobj
154*6070Srobj int
ipmi_hash_ptrcmp(const void * lhs,const void * rhs)155*6070Srobj ipmi_hash_ptrcmp(const void *lhs, const void *rhs)
156*6070Srobj {
157*6070Srobj const uintptr_t *l = lhs, *r = rhs;
158*6070Srobj
159*6070Srobj return (*l == *r ? 0 : -1);
160*6070Srobj }
161*6070Srobj
162*6070Srobj
163*6070Srobj static ulong_t
ipmi_hash_compute(ipmi_hash_t * ihp,const void * elem)164*6070Srobj ipmi_hash_compute(ipmi_hash_t *ihp, const void *elem)
165*6070Srobj {
166*6070Srobj return (ihp->ih_compute(ihp->ih_convert(elem)) % ihp->ih_nbuckets);
167*6070Srobj }
168*6070Srobj
169*6070Srobj static void
ipmi_hash_resize(ipmi_hash_t * ihp,ulong_t nsize)170*6070Srobj ipmi_hash_resize(ipmi_hash_t *ihp, ulong_t nsize)
171*6070Srobj {
172*6070Srobj size_t osize = ihp->ih_nbuckets;
173*6070Srobj ipmi_handle_t *hp = ihp->ih_handle;
174*6070Srobj ipmi_hash_link_t *link, **nbuckets;
175*6070Srobj ulong_t idx, nidx;
176*6070Srobj
177*6070Srobj assert(nsize >= IPMI_HASHMINSIZE);
178*6070Srobj
179*6070Srobj if (nsize == osize)
180*6070Srobj return;
181*6070Srobj
182*6070Srobj if ((nbuckets = ipmi_zalloc(hp, nsize * sizeof (void *))) == NULL) {
183*6070Srobj /*
184*6070Srobj * This routine can't fail, so we just eat the failure here.
185*6070Srobj * The consequences of this failing are only for performance;
186*6070Srobj * correctness is not affected by our inability to resize
187*6070Srobj * the hash table.
188*6070Srobj */
189*6070Srobj return;
190*6070Srobj }
191*6070Srobj
192*6070Srobj ihp->ih_nbuckets = nsize;
193*6070Srobj
194*6070Srobj for (idx = 0; idx < osize; idx++) {
195*6070Srobj while ((link = ihp->ih_buckets[idx]) != NULL) {
196*6070Srobj void *elem;
197*6070Srobj
198*6070Srobj /*
199*6070Srobj * For every hash element, we need to remove it from
200*6070Srobj * this bucket, and rehash it given the new bucket
201*6070Srobj * size.
202*6070Srobj */
203*6070Srobj ihp->ih_buckets[idx] = link->ihl_next;
204*6070Srobj elem = (void *)((uintptr_t)link - ihp->ih_linkoffs);
205*6070Srobj nidx = ipmi_hash_compute(ihp, elem);
206*6070Srobj
207*6070Srobj link->ihl_next = nbuckets[nidx];
208*6070Srobj nbuckets[nidx] = link;
209*6070Srobj }
210*6070Srobj }
211*6070Srobj
212*6070Srobj ipmi_free(hp, ihp->ih_buckets);
213*6070Srobj ihp->ih_buckets = nbuckets;
214*6070Srobj }
215*6070Srobj
216*6070Srobj void *
ipmi_hash_lookup(ipmi_hash_t * ihp,const void * search)217*6070Srobj ipmi_hash_lookup(ipmi_hash_t *ihp, const void *search)
218*6070Srobj {
219*6070Srobj ulong_t idx = ihp->ih_compute(search) % ihp->ih_nbuckets;
220*6070Srobj ipmi_hash_link_t *hl;
221*6070Srobj
222*6070Srobj for (hl = ihp->ih_buckets[idx]; hl != NULL; hl = hl->ihl_next) {
223*6070Srobj void *elem = (void *)((uintptr_t)hl - ihp->ih_linkoffs);
224*6070Srobj
225*6070Srobj if (ihp->ih_compare(ihp->ih_convert(elem), search) == 0)
226*6070Srobj return (elem);
227*6070Srobj }
228*6070Srobj
229*6070Srobj return (NULL);
230*6070Srobj }
231*6070Srobj
232*6070Srobj void *
ipmi_hash_first(ipmi_hash_t * ihp)233*6070Srobj ipmi_hash_first(ipmi_hash_t *ihp)
234*6070Srobj {
235*6070Srobj void *link = ipmi_list_next(&(ihp)->ih_list);
236*6070Srobj
237*6070Srobj if (link == NULL)
238*6070Srobj return (NULL);
239*6070Srobj
240*6070Srobj return ((void *)((uintptr_t)link - ihp->ih_linkoffs));
241*6070Srobj }
242*6070Srobj
243*6070Srobj void *
ipmi_hash_next(ipmi_hash_t * ihp,void * elem)244*6070Srobj ipmi_hash_next(ipmi_hash_t *ihp, void *elem)
245*6070Srobj {
246*6070Srobj void *link = ipmi_list_next((uintptr_t)elem + ihp->ih_linkoffs);
247*6070Srobj
248*6070Srobj if (link == NULL)
249*6070Srobj return (NULL);
250*6070Srobj
251*6070Srobj return ((void *)((uintptr_t)link - ihp->ih_linkoffs));
252*6070Srobj }
253*6070Srobj
254*6070Srobj void
ipmi_hash_insert(ipmi_hash_t * ihp,void * elem)255*6070Srobj ipmi_hash_insert(ipmi_hash_t *ihp, void *elem)
256*6070Srobj {
257*6070Srobj ipmi_hash_link_t *link = (void *)((uintptr_t)elem + ihp->ih_linkoffs);
258*6070Srobj ulong_t idx = ipmi_hash_compute(ihp, elem);
259*6070Srobj
260*6070Srobj assert(ipmi_hash_lookup(ihp, ihp->ih_convert(elem)) == NULL);
261*6070Srobj
262*6070Srobj link->ihl_next = ihp->ih_buckets[idx];
263*6070Srobj ihp->ih_buckets[idx] = link;
264*6070Srobj
265*6070Srobj ipmi_list_append(&ihp->ih_list, link);
266*6070Srobj
267*6070Srobj if (++ihp->ih_nelements > ihp->ih_nbuckets / 2)
268*6070Srobj ipmi_hash_resize(ihp, ipmi_hash_double(ihp->ih_nbuckets));
269*6070Srobj }
270*6070Srobj
271*6070Srobj void
ipmi_hash_remove(ipmi_hash_t * ihp,void * elem)272*6070Srobj ipmi_hash_remove(ipmi_hash_t *ihp, void *elem)
273*6070Srobj {
274*6070Srobj ulong_t idx = ipmi_hash_compute(ihp, elem);
275*6070Srobj ipmi_hash_link_t *link = (void *)((uintptr_t)elem + ihp->ih_linkoffs);
276*6070Srobj ipmi_hash_link_t **hlp = &ihp->ih_buckets[idx];
277*6070Srobj
278*6070Srobj for (; *hlp != NULL; hlp = &(*hlp)->ihl_next) {
279*6070Srobj if (*hlp == link)
280*6070Srobj break;
281*6070Srobj }
282*6070Srobj
283*6070Srobj assert(*hlp != NULL);
284*6070Srobj *hlp = (*hlp)->ihl_next;
285*6070Srobj
286*6070Srobj ipmi_list_delete(&ihp->ih_list, link);
287*6070Srobj
288*6070Srobj assert(ihp->ih_nelements > 0);
289*6070Srobj
290*6070Srobj if (--ihp->ih_nelements < ihp->ih_nbuckets / 4)
291*6070Srobj ipmi_hash_resize(ihp, ipmi_hash_half(ihp->ih_nbuckets));
292*6070Srobj }
293*6070Srobj
294*6070Srobj size_t
ipmi_hash_count(ipmi_hash_t * ihp)295*6070Srobj ipmi_hash_count(ipmi_hash_t *ihp)
296*6070Srobj {
297*6070Srobj return (ihp->ih_nelements);
298*6070Srobj }
299