1fb2f18f8Sesaxe /* 2fb2f18f8Sesaxe * CDDL HEADER START 3fb2f18f8Sesaxe * 4fb2f18f8Sesaxe * The contents of this file are subject to the terms of the 5fb2f18f8Sesaxe * Common Development and Distribution License (the "License"). 6fb2f18f8Sesaxe * You may not use this file except in compliance with the License. 7fb2f18f8Sesaxe * 8fb2f18f8Sesaxe * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE 9fb2f18f8Sesaxe * or http://www.opensolaris.org/os/licensing. 10fb2f18f8Sesaxe * See the License for the specific language governing permissions 11fb2f18f8Sesaxe * and limitations under the License. 12fb2f18f8Sesaxe * 13fb2f18f8Sesaxe * When distributing Covered Code, include this CDDL HEADER in each 14fb2f18f8Sesaxe * file and include the License file at usr/src/OPENSOLARIS.LICENSE. 15fb2f18f8Sesaxe * If applicable, add the following below this CDDL HEADER, with the 16fb2f18f8Sesaxe * fields enclosed by brackets "[]" replaced with your own identifying 17fb2f18f8Sesaxe * information: Portions Copyright [yyyy] [name of copyright owner] 18fb2f18f8Sesaxe * 19fb2f18f8Sesaxe * CDDL HEADER END 20fb2f18f8Sesaxe */ 21fb2f18f8Sesaxe /* 22*0e751525SEric Saxe * Copyright 2009 Sun Microsystems, Inc. All rights reserved. 23fb2f18f8Sesaxe * Use is subject to license terms. 24fb2f18f8Sesaxe */ 25fb2f18f8Sesaxe 26fb2f18f8Sesaxe #include <sys/systm.h> 27fb2f18f8Sesaxe #include <sys/param.h> 28fb2f18f8Sesaxe #include <sys/debug.h> 29fb2f18f8Sesaxe #include <sys/kmem.h> 30fb2f18f8Sesaxe #include <sys/group.h> 31fb2f18f8Sesaxe 32fb2f18f8Sesaxe 33fb2f18f8Sesaxe #define GRP_SET_SIZE_DEFAULT 2 34fb2f18f8Sesaxe 35fb2f18f8Sesaxe static void group_grow_set(group_t *); 36fb2f18f8Sesaxe static void group_shrink_set(group_t *); 37fb2f18f8Sesaxe static void group_pack_set(void **, uint_t); 38fb2f18f8Sesaxe 39fb2f18f8Sesaxe /* 40fb2f18f8Sesaxe * Initialize a group_t 41fb2f18f8Sesaxe */ 42fb2f18f8Sesaxe void 43fb2f18f8Sesaxe group_create(group_t *g) 44fb2f18f8Sesaxe { 45fb2f18f8Sesaxe bzero(g, sizeof (group_t)); 46fb2f18f8Sesaxe } 47fb2f18f8Sesaxe 48fb2f18f8Sesaxe /* 49fb2f18f8Sesaxe * Destroy a group_t 50fb2f18f8Sesaxe * The group must already be empty 51fb2f18f8Sesaxe */ 52fb2f18f8Sesaxe void 53fb2f18f8Sesaxe group_destroy(group_t *g) 54fb2f18f8Sesaxe { 55fb2f18f8Sesaxe ASSERT(g->grp_size == 0); 56fb2f18f8Sesaxe 57fb2f18f8Sesaxe if (g->grp_capacity > 0) { 58fb2f18f8Sesaxe kmem_free(g->grp_set, g->grp_capacity * sizeof (void *)); 59fb2f18f8Sesaxe g->grp_capacity = 0; 60fb2f18f8Sesaxe } 61fb2f18f8Sesaxe g->grp_set = NULL; 62fb2f18f8Sesaxe } 63fb2f18f8Sesaxe 64fb2f18f8Sesaxe /* 65*0e751525SEric Saxe * Empty a group_t 66*0e751525SEric Saxe * Capacity is preserved. 67*0e751525SEric Saxe */ 68*0e751525SEric Saxe void 69*0e751525SEric Saxe group_empty(group_t *g) 70*0e751525SEric Saxe { 71*0e751525SEric Saxe int i; 72*0e751525SEric Saxe int sz = g->grp_size; 73*0e751525SEric Saxe 74*0e751525SEric Saxe g->grp_size = 0; 75*0e751525SEric Saxe for (i = 0; i < sz; i++) 76*0e751525SEric Saxe g->grp_set[i] = NULL; 77*0e751525SEric Saxe } 78*0e751525SEric Saxe 79*0e751525SEric Saxe /* 80fb2f18f8Sesaxe * Add element "e" to group "g" 81fb2f18f8Sesaxe * 82fb2f18f8Sesaxe * Returns -1 if addition would result in overcapacity, and 83fb2f18f8Sesaxe * resize operations aren't allowed, and 0 otherwise 84fb2f18f8Sesaxe */ 85fb2f18f8Sesaxe int 86fb2f18f8Sesaxe group_add(group_t *g, void *e, int gflag) 87fb2f18f8Sesaxe { 88fb2f18f8Sesaxe int entry; 89fb2f18f8Sesaxe 90fb2f18f8Sesaxe if ((gflag & GRP_NORESIZE) && 91fb2f18f8Sesaxe g->grp_size == g->grp_capacity) 92fb2f18f8Sesaxe return (-1); 93fb2f18f8Sesaxe 94fb2f18f8Sesaxe ASSERT(g->grp_size != g->grp_capacity || (gflag & GRP_RESIZE)); 95fb2f18f8Sesaxe 96fb2f18f8Sesaxe entry = g->grp_size++; 97fb2f18f8Sesaxe if (g->grp_size > g->grp_capacity) 98fb2f18f8Sesaxe group_grow_set(g); 99fb2f18f8Sesaxe 100fb2f18f8Sesaxe ASSERT(g->grp_set[entry] == NULL); 101fb2f18f8Sesaxe g->grp_set[entry] = e; 102fb2f18f8Sesaxe 103fb2f18f8Sesaxe return (0); 104fb2f18f8Sesaxe } 105fb2f18f8Sesaxe 106fb2f18f8Sesaxe /* 107fb2f18f8Sesaxe * Remove element "e" from group "g" 108fb2f18f8Sesaxe * 109fb2f18f8Sesaxe * Returns -1 if "e" was not present in "g" and 0 otherwise 110fb2f18f8Sesaxe */ 111fb2f18f8Sesaxe int 112fb2f18f8Sesaxe group_remove(group_t *g, void *e, int gflag) 113fb2f18f8Sesaxe { 114fb2f18f8Sesaxe int i; 115fb2f18f8Sesaxe 116fb2f18f8Sesaxe /* 117fb2f18f8Sesaxe * Find the element in the group's set 118fb2f18f8Sesaxe */ 119fb2f18f8Sesaxe for (i = 0; i < g->grp_size; i++) 120fb2f18f8Sesaxe if (g->grp_set[i] == e) 121fb2f18f8Sesaxe break; 122fb2f18f8Sesaxe if (g->grp_set[i] != e) 123fb2f18f8Sesaxe return (-1); 124fb2f18f8Sesaxe 125fb2f18f8Sesaxe g->grp_set[i] = NULL; 126fb2f18f8Sesaxe group_pack_set(g->grp_set, g->grp_size); 127fb2f18f8Sesaxe g->grp_size--; 128fb2f18f8Sesaxe 129fb2f18f8Sesaxe if ((gflag & GRP_RESIZE) && 130fb2f18f8Sesaxe g->grp_size > GRP_SET_SIZE_DEFAULT && 131fb2f18f8Sesaxe ((g->grp_size - 1) & g->grp_size) == 0) 132fb2f18f8Sesaxe group_shrink_set(g); 133fb2f18f8Sesaxe 134fb2f18f8Sesaxe return (0); 135fb2f18f8Sesaxe } 136fb2f18f8Sesaxe 137fb2f18f8Sesaxe /* 138fb2f18f8Sesaxe * Expand the capacity of group "g" so that it may 139fb2f18f8Sesaxe * contain at least "n" elements 140fb2f18f8Sesaxe */ 141fb2f18f8Sesaxe void 142fb2f18f8Sesaxe group_expand(group_t *g, uint_t n) 143fb2f18f8Sesaxe { 144fb2f18f8Sesaxe while (g->grp_capacity < n) 145fb2f18f8Sesaxe group_grow_set(g); 146fb2f18f8Sesaxe } 147fb2f18f8Sesaxe 148fb2f18f8Sesaxe /* 149fb2f18f8Sesaxe * Upsize a group's holding capacity 150fb2f18f8Sesaxe */ 151fb2f18f8Sesaxe static void 152fb2f18f8Sesaxe group_grow_set(group_t *g) 153fb2f18f8Sesaxe { 154fb2f18f8Sesaxe uint_t cap_old, cap_new; 155fb2f18f8Sesaxe void **set_old, **set_new; 156fb2f18f8Sesaxe 157fb2f18f8Sesaxe cap_old = g->grp_capacity; 158fb2f18f8Sesaxe set_old = g->grp_set; 159fb2f18f8Sesaxe 160fb2f18f8Sesaxe /* 161fb2f18f8Sesaxe * The array size grows in powers of two 162fb2f18f8Sesaxe */ 163fb2f18f8Sesaxe if ((cap_new = (cap_old << 1)) == 0) { 164fb2f18f8Sesaxe /* 165fb2f18f8Sesaxe * The set is unallocated. 166fb2f18f8Sesaxe * Allocate a default sized set. 167fb2f18f8Sesaxe */ 168fb2f18f8Sesaxe cap_new = GRP_SET_SIZE_DEFAULT; 169fb2f18f8Sesaxe g->grp_set = kmem_zalloc(cap_new * sizeof (void *), KM_SLEEP); 170fb2f18f8Sesaxe g->grp_capacity = cap_new; 171fb2f18f8Sesaxe } else { 172fb2f18f8Sesaxe /* 173fb2f18f8Sesaxe * Allocate a newly sized array, 174fb2f18f8Sesaxe * copy the data, and free the old array. 175fb2f18f8Sesaxe */ 176fb2f18f8Sesaxe set_new = kmem_zalloc(cap_new * sizeof (void *), KM_SLEEP); 177fb2f18f8Sesaxe (void) kcopy(set_old, set_new, cap_old * sizeof (void *)); 178fb2f18f8Sesaxe g->grp_set = set_new; 179fb2f18f8Sesaxe g->grp_capacity = cap_new; 180fb2f18f8Sesaxe kmem_free(set_old, cap_old * sizeof (void *)); 181fb2f18f8Sesaxe } 182fb2f18f8Sesaxe /* 183fb2f18f8Sesaxe * The new array size should be a power of two 184fb2f18f8Sesaxe */ 185fb2f18f8Sesaxe ASSERT(((cap_new - 1) & cap_new) == 0); 186fb2f18f8Sesaxe } 187fb2f18f8Sesaxe 188fb2f18f8Sesaxe /* 189fb2f18f8Sesaxe * Downsize a group's holding capacity 190fb2f18f8Sesaxe */ 191fb2f18f8Sesaxe static void 192fb2f18f8Sesaxe group_shrink_set(group_t *g) 193fb2f18f8Sesaxe { 194fb2f18f8Sesaxe uint_t cap_old, cap_new; 195fb2f18f8Sesaxe void **set_old, **set_new; 196fb2f18f8Sesaxe 197fb2f18f8Sesaxe cap_old = g->grp_capacity; 198fb2f18f8Sesaxe set_old = g->grp_set; 199fb2f18f8Sesaxe 200fb2f18f8Sesaxe /* 201fb2f18f8Sesaxe * The group's existing array size must already 202fb2f18f8Sesaxe * be a power of two 203fb2f18f8Sesaxe */ 204fb2f18f8Sesaxe ASSERT(((cap_old - 1) & cap_old) == 0); 205fb2f18f8Sesaxe cap_new = cap_old >> 1; 206fb2f18f8Sesaxe 207fb2f18f8Sesaxe /* 208fb2f18f8Sesaxe * GRP_SET_SIZE_DEFAULT is the minumum set size. 209fb2f18f8Sesaxe */ 210fb2f18f8Sesaxe if (cap_new < GRP_SET_SIZE_DEFAULT) 211fb2f18f8Sesaxe return; 212fb2f18f8Sesaxe 213fb2f18f8Sesaxe set_new = kmem_zalloc(cap_new * sizeof (void *), KM_SLEEP); 214fb2f18f8Sesaxe (void) kcopy(set_old, set_new, cap_new * sizeof (void *)); 215fb2f18f8Sesaxe g->grp_capacity = cap_new; 216fb2f18f8Sesaxe g->grp_set = set_new; 217fb2f18f8Sesaxe 218fb2f18f8Sesaxe ASSERT(((cap_new - 1) & cap_new) == 0); 219fb2f18f8Sesaxe kmem_free(set_old, cap_old * sizeof (void *)); 220fb2f18f8Sesaxe } 221fb2f18f8Sesaxe 222fb2f18f8Sesaxe /* 223fb2f18f8Sesaxe * Pack a group's set 224fb2f18f8Sesaxe * Element order is not preserved 225fb2f18f8Sesaxe */ 226fb2f18f8Sesaxe static void 227fb2f18f8Sesaxe group_pack_set(void **set, uint_t sz) 228fb2f18f8Sesaxe { 229fb2f18f8Sesaxe uint_t i, j, free; 230fb2f18f8Sesaxe 231fb2f18f8Sesaxe free = (uint_t)-1; 232fb2f18f8Sesaxe 233fb2f18f8Sesaxe for (i = 0; i < sz; i++) { 234fb2f18f8Sesaxe if (set[i] == NULL && free == (uint_t)-1) { 235fb2f18f8Sesaxe /* 236fb2f18f8Sesaxe * Found a new free slot. 237fb2f18f8Sesaxe * Start packing from here. 238fb2f18f8Sesaxe */ 239fb2f18f8Sesaxe free = i; 240fb2f18f8Sesaxe } else if (set[i] != NULL && free != (uint_t)-1) { 241fb2f18f8Sesaxe /* 242fb2f18f8Sesaxe * Found a slot to pack into 243fb2f18f8Sesaxe * an earlier free slot. 244fb2f18f8Sesaxe */ 245fb2f18f8Sesaxe ASSERT(set[free] == NULL); 246fb2f18f8Sesaxe set[free] = set[i]; 247fb2f18f8Sesaxe set[i] = NULL; 248fb2f18f8Sesaxe 249fb2f18f8Sesaxe /* 250fb2f18f8Sesaxe * Find the next free slot 251fb2f18f8Sesaxe */ 252fb2f18f8Sesaxe for (j = free + 1; set[j] != NULL; j++) { 253fb2f18f8Sesaxe ASSERT(j <= i); 254fb2f18f8Sesaxe if (j == i) 255fb2f18f8Sesaxe break; 256fb2f18f8Sesaxe } 257fb2f18f8Sesaxe if (set[j] == NULL) 258fb2f18f8Sesaxe free = j; 259fb2f18f8Sesaxe else 260fb2f18f8Sesaxe free = (uint_t)-1; 261fb2f18f8Sesaxe } 262fb2f18f8Sesaxe } 263fb2f18f8Sesaxe } 264fb2f18f8Sesaxe 265fb2f18f8Sesaxe /* 266fb2f18f8Sesaxe * Initialize a group iterator cookie 267fb2f18f8Sesaxe */ 268fb2f18f8Sesaxe void 269fb2f18f8Sesaxe group_iter_init(group_iter_t *iter) 270fb2f18f8Sesaxe { 271fb2f18f8Sesaxe *iter = 0; 272fb2f18f8Sesaxe } 273fb2f18f8Sesaxe 274fb2f18f8Sesaxe /* 275fb2f18f8Sesaxe * Iterate over the elements in a group 276fb2f18f8Sesaxe */ 277fb2f18f8Sesaxe void * 278fb2f18f8Sesaxe group_iterate(group_t *g, group_iter_t *iter) 279fb2f18f8Sesaxe { 280fb2f18f8Sesaxe uint_t idx = *iter; 281fb2f18f8Sesaxe void *data = NULL; 282fb2f18f8Sesaxe 283fb2f18f8Sesaxe while (idx < g->grp_size) { 284fb2f18f8Sesaxe data = g->grp_set[idx++]; 285fb2f18f8Sesaxe if (data != NULL) 286fb2f18f8Sesaxe break; 287fb2f18f8Sesaxe } 288fb2f18f8Sesaxe *iter = idx; 289fb2f18f8Sesaxe 290fb2f18f8Sesaxe return (data); 291fb2f18f8Sesaxe } 292fb2f18f8Sesaxe 293fb2f18f8Sesaxe /* 294fb2f18f8Sesaxe * Indexed access to a group's elements 295fb2f18f8Sesaxe */ 296fb2f18f8Sesaxe void * 297fb2f18f8Sesaxe group_access_at(group_t *g, uint_t idx) 298fb2f18f8Sesaxe { 299fb2f18f8Sesaxe if (idx >= g->grp_capacity) 300fb2f18f8Sesaxe return (NULL); 301fb2f18f8Sesaxe 302fb2f18f8Sesaxe return (g->grp_set[idx]); 303fb2f18f8Sesaxe } 304fb2f18f8Sesaxe 305fb2f18f8Sesaxe /* 306fb2f18f8Sesaxe * Add a new ordered group element at specified 307fb2f18f8Sesaxe * index. The group must already be of sufficient 308fb2f18f8Sesaxe * capacity to hold an element at the specified index. 309fb2f18f8Sesaxe * 310fb2f18f8Sesaxe * Returns 0 if addition was sucessful, and -1 if the 311fb2f18f8Sesaxe * addition failed because the table was too small 312fb2f18f8Sesaxe */ 313fb2f18f8Sesaxe int 314fb2f18f8Sesaxe group_add_at(group_t *g, void *e, uint_t idx) 315fb2f18f8Sesaxe { 316fb2f18f8Sesaxe if (idx >= g->grp_capacity) 317fb2f18f8Sesaxe return (-1); 318fb2f18f8Sesaxe 319fb2f18f8Sesaxe if (idx >= g->grp_size) 320fb2f18f8Sesaxe g->grp_size = idx + 1; 321fb2f18f8Sesaxe 322fb2f18f8Sesaxe ASSERT(g->grp_set[idx] == NULL); 323fb2f18f8Sesaxe g->grp_set[idx] = e; 324fb2f18f8Sesaxe return (0); 325fb2f18f8Sesaxe } 326fb2f18f8Sesaxe 327fb2f18f8Sesaxe /* 328*0e751525SEric Saxe * Remove the element at the specified index 329fb2f18f8Sesaxe */ 330fb2f18f8Sesaxe void 331fb2f18f8Sesaxe group_remove_at(group_t *g, uint_t idx) 332fb2f18f8Sesaxe { 333fb2f18f8Sesaxe ASSERT(idx < g->grp_capacity); 334fb2f18f8Sesaxe g->grp_set[idx] = NULL; 335fb2f18f8Sesaxe } 336*0e751525SEric Saxe 337*0e751525SEric Saxe /* 338*0e751525SEric Saxe * Find an element in the group, and return its index 339*0e751525SEric Saxe * Returns -1 if the element could not be found. 340*0e751525SEric Saxe */ 341*0e751525SEric Saxe uint_t 342*0e751525SEric Saxe group_find(group_t *g, void *e) 343*0e751525SEric Saxe { 344*0e751525SEric Saxe uint_t idx; 345*0e751525SEric Saxe 346*0e751525SEric Saxe for (idx = 0; idx < g->grp_capacity; idx++) { 347*0e751525SEric Saxe if (g->grp_set[idx] == e) 348*0e751525SEric Saxe return (idx); 349*0e751525SEric Saxe } 350*0e751525SEric Saxe return ((uint_t)-1); 351*0e751525SEric Saxe } 352