subr_kmem.c revision 1.66.4.2
1 1.66.4.2 martin /* $NetBSD: subr_kmem.c,v 1.66.4.2 2020/04/13 08:05:04 martin Exp $ */ 2 1.1 yamt 3 1.66.4.2 martin /* 4 1.66.4.2 martin * Copyright (c) 2009-2020 The NetBSD Foundation, Inc. 5 1.23 ad * All rights reserved. 6 1.23 ad * 7 1.23 ad * This code is derived from software contributed to The NetBSD Foundation 8 1.61 maxv * by Andrew Doran and Maxime Villard. 9 1.23 ad * 10 1.23 ad * Redistribution and use in source and binary forms, with or without 11 1.23 ad * modification, are permitted provided that the following conditions 12 1.23 ad * are met: 13 1.23 ad * 1. Redistributions of source code must retain the above copyright 14 1.23 ad * notice, this list of conditions and the following disclaimer. 15 1.23 ad * 2. Redistributions in binary form must reproduce the above copyright 16 1.23 ad * notice, this list of conditions and the following disclaimer in the 17 1.23 ad * documentation and/or other materials provided with the distribution. 18 1.23 ad * 19 1.23 ad * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 20 1.23 ad * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 21 1.23 ad * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 22 1.23 ad * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 23 1.23 ad * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 24 1.23 ad * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 25 1.23 ad * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 26 1.23 ad * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 27 1.23 ad * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 28 1.23 ad * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 29 1.23 ad * POSSIBILITY OF SUCH DAMAGE. 30 1.23 ad */ 31 1.23 ad 32 1.66.4.2 martin /* 33 1.1 yamt * Copyright (c)2006 YAMAMOTO Takashi, 34 1.1 yamt * All rights reserved. 35 1.1 yamt * 36 1.1 yamt * Redistribution and use in source and binary forms, with or without 37 1.1 yamt * modification, are permitted provided that the following conditions 38 1.1 yamt * are met: 39 1.1 yamt * 1. Redistributions of source code must retain the above copyright 40 1.1 yamt * notice, this list of conditions and the following disclaimer. 41 1.1 yamt * 2. Redistributions in binary form must reproduce the above copyright 42 1.1 yamt * notice, this list of conditions and the following disclaimer in the 43 1.1 yamt * documentation and/or other materials provided with the distribution. 44 1.1 yamt * 45 1.1 yamt * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND 46 1.1 yamt * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 47 1.1 yamt * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 48 1.1 yamt * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE 49 1.1 yamt * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 50 1.1 yamt * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 51 1.1 yamt * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 52 1.1 yamt * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 53 1.1 yamt * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 54 1.1 yamt * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 55 1.1 yamt * SUCH DAMAGE. 56 1.1 yamt */ 57 1.1 yamt 58 1.1 yamt /* 59 1.55 maxv * Allocator of kernel wired memory. This allocator has some debug features 60 1.55 maxv * enabled with "option DIAGNOSTIC" and "option DEBUG". 61 1.50 yamt */ 62 1.50 yamt 63 1.50 yamt /* 64 1.55 maxv * KMEM_SIZE: detect alloc/free size mismatch bugs. 65 1.66.4.2 martin * Append to each allocation a fixed-sized footer and record the exact 66 1.66.4.2 martin * user-requested allocation size in it. When freeing, compare it with 67 1.66.4.2 martin * kmem_free's "size" argument. 68 1.60 maxv * 69 1.66.4.2 martin * This option is enabled on DIAGNOSTIC. 70 1.50 yamt * 71 1.66.4.2 martin * |CHUNK|CHUNK|CHUNK|CHUNK|CHUNK|CHUNK|CHUNK|CHUNK|CHUNK| | 72 1.66.4.2 martin * +-----+-----+-----+-----+-----+-----+-----+-----+-----+-+ 73 1.66.4.2 martin * | | | | | | | | |/////|U| 74 1.66.4.2 martin * | | | | | | | | |/HSZ/|U| 75 1.66.4.2 martin * | | | | | | | | |/////|U| 76 1.66.4.2 martin * +-----+-----+-----+-----+-----+-----+-----+-----+-----+-+ 77 1.66.4.2 martin * | Buffer usable by the caller (requested size) |Size |Unused 78 1.1 yamt */ 79 1.1 yamt 80 1.1 yamt #include <sys/cdefs.h> 81 1.66.4.2 martin __KERNEL_RCSID(0, "$NetBSD: subr_kmem.c,v 1.66.4.2 2020/04/13 08:05:04 martin Exp $"); 82 1.63 christos 83 1.63 christos #ifdef _KERNEL_OPT 84 1.63 christos #include "opt_kmem.h" 85 1.63 christos #endif 86 1.1 yamt 87 1.1 yamt #include <sys/param.h> 88 1.6 yamt #include <sys/callback.h> 89 1.1 yamt #include <sys/kmem.h> 90 1.39 para #include <sys/pool.h> 91 1.13 ad #include <sys/debug.h> 92 1.17 ad #include <sys/lockdebug.h> 93 1.23 ad #include <sys/cpu.h> 94 1.66.4.1 christos #include <sys/asan.h> 95 1.66.4.2 martin #include <sys/msan.h> 96 1.1 yamt 97 1.6 yamt #include <uvm/uvm_extern.h> 98 1.6 yamt #include <uvm/uvm_map.h> 99 1.6 yamt 100 1.1 yamt #include <lib/libkern/libkern.h> 101 1.1 yamt 102 1.46 para struct kmem_cache_info { 103 1.40 rmind size_t kc_size; 104 1.40 rmind const char * kc_name; 105 1.46 para }; 106 1.46 para 107 1.46 para static const struct kmem_cache_info kmem_cache_sizes[] = { 108 1.66.4.2 martin { 8, "kmem-00008" }, 109 1.66.4.2 martin { 16, "kmem-00016" }, 110 1.66.4.2 martin { 24, "kmem-00024" }, 111 1.66.4.2 martin { 32, "kmem-00032" }, 112 1.66.4.2 martin { 40, "kmem-00040" }, 113 1.66.4.2 martin { 48, "kmem-00048" }, 114 1.66.4.2 martin { 56, "kmem-00056" }, 115 1.66.4.2 martin { 64, "kmem-00064" }, 116 1.66.4.2 martin { 80, "kmem-00080" }, 117 1.66.4.2 martin { 96, "kmem-00096" }, 118 1.66.4.2 martin { 112, "kmem-00112" }, 119 1.66.4.2 martin { 128, "kmem-00128" }, 120 1.66.4.2 martin { 160, "kmem-00160" }, 121 1.66.4.2 martin { 192, "kmem-00192" }, 122 1.66.4.2 martin { 224, "kmem-00224" }, 123 1.66.4.2 martin { 256, "kmem-00256" }, 124 1.66.4.2 martin { 320, "kmem-00320" }, 125 1.66.4.2 martin { 384, "kmem-00384" }, 126 1.66.4.2 martin { 448, "kmem-00448" }, 127 1.66.4.2 martin { 512, "kmem-00512" }, 128 1.66.4.2 martin { 768, "kmem-00768" }, 129 1.66.4.2 martin { 1024, "kmem-01024" }, 130 1.46 para { 0, NULL } 131 1.46 para }; 132 1.46 para 133 1.46 para static const struct kmem_cache_info kmem_cache_big_sizes[] = { 134 1.66.4.2 martin { 2048, "kmem-02048" }, 135 1.66.4.2 martin { 4096, "kmem-04096" }, 136 1.66.4.2 martin { 8192, "kmem-08192" }, 137 1.46 para { 16384, "kmem-16384" }, 138 1.39 para { 0, NULL } 139 1.39 para }; 140 1.1 yamt 141 1.39 para /* 142 1.40 rmind * KMEM_ALIGN is the smallest guaranteed alignment and also the 143 1.46 para * smallest allocateable quantum. 144 1.46 para * Every cache size >= CACHE_LINE_SIZE gets CACHE_LINE_SIZE alignment. 145 1.39 para */ 146 1.40 rmind #define KMEM_ALIGN 8 147 1.40 rmind #define KMEM_SHIFT 3 148 1.46 para #define KMEM_MAXSIZE 1024 149 1.40 rmind #define KMEM_CACHE_COUNT (KMEM_MAXSIZE >> KMEM_SHIFT) 150 1.1 yamt 151 1.40 rmind static pool_cache_t kmem_cache[KMEM_CACHE_COUNT] __cacheline_aligned; 152 1.40 rmind static size_t kmem_cache_maxidx __read_mostly; 153 1.23 ad 154 1.46 para #define KMEM_BIG_ALIGN 2048 155 1.46 para #define KMEM_BIG_SHIFT 11 156 1.46 para #define KMEM_BIG_MAXSIZE 16384 157 1.46 para #define KMEM_CACHE_BIG_COUNT (KMEM_BIG_MAXSIZE >> KMEM_BIG_SHIFT) 158 1.46 para 159 1.46 para static pool_cache_t kmem_cache_big[KMEM_CACHE_BIG_COUNT] __cacheline_aligned; 160 1.46 para static size_t kmem_cache_big_maxidx __read_mostly; 161 1.46 para 162 1.53 maxv #if defined(DIAGNOSTIC) && defined(_HARDKERNEL) 163 1.57 maxv #define KMEM_SIZE 164 1.66.4.1 christos #endif 165 1.53 maxv 166 1.45 martin #if defined(DEBUG) && defined(_HARDKERNEL) 167 1.61 maxv static void *kmem_freecheck; 168 1.66.4.1 christos #endif 169 1.4 yamt 170 1.23 ad #if defined(KMEM_SIZE) 171 1.66.4.2 martin #define SIZE_SIZE sizeof(size_t) 172 1.23 ad static void kmem_size_set(void *, size_t); 173 1.39 para static void kmem_size_check(void *, size_t); 174 1.23 ad #else 175 1.23 ad #define SIZE_SIZE 0 176 1.23 ad #define kmem_size_set(p, sz) /* nothing */ 177 1.23 ad #define kmem_size_check(p, sz) /* nothing */ 178 1.23 ad #endif 179 1.23 ad 180 1.32 skrll CTASSERT(KM_SLEEP == PR_WAITOK); 181 1.32 skrll CTASSERT(KM_NOSLEEP == PR_NOWAIT); 182 1.32 skrll 183 1.46 para /* 184 1.46 para * kmem_intr_alloc: allocate wired memory. 185 1.46 para */ 186 1.39 para void * 187 1.50 yamt kmem_intr_alloc(size_t requested_size, km_flag_t kmflags) 188 1.1 yamt { 189 1.66.4.1 christos #ifdef KASAN 190 1.66.4.1 christos const size_t origsize = requested_size; 191 1.66.4.1 christos #endif 192 1.40 rmind size_t allocsz, index; 193 1.50 yamt size_t size; 194 1.39 para pool_cache_t pc; 195 1.39 para uint8_t *p; 196 1.1 yamt 197 1.50 yamt KASSERT(requested_size > 0); 198 1.1 yamt 199 1.65 riastrad KASSERT((kmflags & KM_SLEEP) || (kmflags & KM_NOSLEEP)); 200 1.65 riastrad KASSERT(!(kmflags & KM_SLEEP) || !(kmflags & KM_NOSLEEP)); 201 1.65 riastrad 202 1.66.4.1 christos kasan_add_redzone(&requested_size); 203 1.50 yamt size = kmem_roundup_size(requested_size); 204 1.54 maxv allocsz = size + SIZE_SIZE; 205 1.54 maxv 206 1.46 para if ((index = ((allocsz -1) >> KMEM_SHIFT)) 207 1.46 para < kmem_cache_maxidx) { 208 1.46 para pc = kmem_cache[index]; 209 1.46 para } else if ((index = ((allocsz - 1) >> KMEM_BIG_SHIFT)) 210 1.55 maxv < kmem_cache_big_maxidx) { 211 1.46 para pc = kmem_cache_big[index]; 212 1.48 uebayasi } else { 213 1.40 rmind int ret = uvm_km_kmem_alloc(kmem_va_arena, 214 1.43 para (vsize_t)round_page(size), 215 1.39 para ((kmflags & KM_SLEEP) ? VM_SLEEP : VM_NOSLEEP) 216 1.39 para | VM_INSTANTFIT, (vmem_addr_t *)&p); 217 1.46 para if (ret) { 218 1.46 para return NULL; 219 1.46 para } 220 1.46 para FREECHECK_OUT(&kmem_freecheck, p); 221 1.46 para return p; 222 1.1 yamt } 223 1.1 yamt 224 1.39 para p = pool_cache_get(pc, kmflags); 225 1.39 para 226 1.39 para if (__predict_true(p != NULL)) { 227 1.39 para FREECHECK_OUT(&kmem_freecheck, p); 228 1.50 yamt kmem_size_set(p, requested_size); 229 1.66.4.1 christos kasan_mark(p, origsize, size, KASAN_KMEM_REDZONE); 230 1.66.4.1 christos return p; 231 1.39 para } 232 1.47 para return p; 233 1.1 yamt } 234 1.1 yamt 235 1.46 para /* 236 1.46 para * kmem_intr_zalloc: allocate zeroed wired memory. 237 1.46 para */ 238 1.39 para void * 239 1.39 para kmem_intr_zalloc(size_t size, km_flag_t kmflags) 240 1.23 ad { 241 1.39 para void *p; 242 1.23 ad 243 1.39 para p = kmem_intr_alloc(size, kmflags); 244 1.39 para if (p != NULL) { 245 1.39 para memset(p, 0, size); 246 1.39 para } 247 1.39 para return p; 248 1.23 ad } 249 1.23 ad 250 1.46 para /* 251 1.46 para * kmem_intr_free: free wired memory allocated by kmem_alloc. 252 1.46 para */ 253 1.39 para void 254 1.50 yamt kmem_intr_free(void *p, size_t requested_size) 255 1.23 ad { 256 1.40 rmind size_t allocsz, index; 257 1.50 yamt size_t size; 258 1.39 para pool_cache_t pc; 259 1.23 ad 260 1.39 para KASSERT(p != NULL); 261 1.50 yamt KASSERT(requested_size > 0); 262 1.39 para 263 1.66.4.1 christos kasan_add_redzone(&requested_size); 264 1.50 yamt size = kmem_roundup_size(requested_size); 265 1.54 maxv allocsz = size + SIZE_SIZE; 266 1.54 maxv 267 1.46 para if ((index = ((allocsz -1) >> KMEM_SHIFT)) 268 1.46 para < kmem_cache_maxidx) { 269 1.46 para pc = kmem_cache[index]; 270 1.46 para } else if ((index = ((allocsz - 1) >> KMEM_BIG_SHIFT)) 271 1.55 maxv < kmem_cache_big_maxidx) { 272 1.46 para pc = kmem_cache_big[index]; 273 1.46 para } else { 274 1.46 para FREECHECK_IN(&kmem_freecheck, p); 275 1.39 para uvm_km_kmem_free(kmem_va_arena, (vaddr_t)p, 276 1.43 para round_page(size)); 277 1.39 para return; 278 1.39 para } 279 1.39 para 280 1.66.4.1 christos kasan_mark(p, size, size, 0); 281 1.66.4.1 christos 282 1.50 yamt kmem_size_check(p, requested_size); 283 1.39 para FREECHECK_IN(&kmem_freecheck, p); 284 1.46 para LOCKDEBUG_MEM_CHECK(p, size); 285 1.39 para 286 1.39 para pool_cache_put(pc, p); 287 1.23 ad } 288 1.23 ad 289 1.66.4.2 martin /* -------------------------------- Kmem API -------------------------------- */ 290 1.1 yamt 291 1.1 yamt /* 292 1.1 yamt * kmem_alloc: allocate wired memory. 293 1.1 yamt * => must not be called from interrupt context. 294 1.1 yamt */ 295 1.1 yamt void * 296 1.1 yamt kmem_alloc(size_t size, km_flag_t kmflags) 297 1.1 yamt { 298 1.62 chs void *v; 299 1.62 chs 300 1.40 rmind KASSERTMSG((!cpu_intr_p() && !cpu_softintr_p()), 301 1.40 rmind "kmem(9) should not be used from the interrupt context"); 302 1.62 chs v = kmem_intr_alloc(size, kmflags); 303 1.66.4.2 martin if (__predict_true(v != NULL)) { 304 1.66.4.2 martin kmsan_mark(v, size, KMSAN_STATE_UNINIT); 305 1.66.4.2 martin kmsan_orig(v, size, KMSAN_TYPE_KMEM, __RET_ADDR); 306 1.66.4.2 martin } 307 1.62 chs KASSERT(v || (kmflags & KM_NOSLEEP) != 0); 308 1.62 chs return v; 309 1.1 yamt } 310 1.1 yamt 311 1.1 yamt /* 312 1.39 para * kmem_zalloc: allocate zeroed wired memory. 313 1.2 yamt * => must not be called from interrupt context. 314 1.2 yamt */ 315 1.2 yamt void * 316 1.2 yamt kmem_zalloc(size_t size, km_flag_t kmflags) 317 1.2 yamt { 318 1.62 chs void *v; 319 1.62 chs 320 1.40 rmind KASSERTMSG((!cpu_intr_p() && !cpu_softintr_p()), 321 1.40 rmind "kmem(9) should not be used from the interrupt context"); 322 1.62 chs v = kmem_intr_zalloc(size, kmflags); 323 1.62 chs KASSERT(v || (kmflags & KM_NOSLEEP) != 0); 324 1.62 chs return v; 325 1.2 yamt } 326 1.2 yamt 327 1.2 yamt /* 328 1.1 yamt * kmem_free: free wired memory allocated by kmem_alloc. 329 1.1 yamt * => must not be called from interrupt context. 330 1.1 yamt */ 331 1.1 yamt void 332 1.1 yamt kmem_free(void *p, size_t size) 333 1.1 yamt { 334 1.23 ad KASSERT(!cpu_intr_p()); 335 1.27 ad KASSERT(!cpu_softintr_p()); 336 1.39 para kmem_intr_free(p, size); 337 1.66.4.2 martin kmsan_mark(p, size, KMSAN_STATE_INITED); 338 1.1 yamt } 339 1.1 yamt 340 1.46 para static size_t 341 1.39 para kmem_create_caches(const struct kmem_cache_info *array, 342 1.46 para pool_cache_t alloc_table[], size_t maxsize, int shift, int ipl) 343 1.1 yamt { 344 1.46 para size_t maxidx = 0; 345 1.46 para size_t table_unit = (1 << shift); 346 1.39 para size_t size = table_unit; 347 1.23 ad int i; 348 1.1 yamt 349 1.39 para for (i = 0; array[i].kc_size != 0 ; i++) { 350 1.40 rmind const char *name = array[i].kc_name; 351 1.39 para size_t cache_size = array[i].kc_size; 352 1.46 para struct pool_allocator *pa; 353 1.66.4.1 christos int flags = 0; 354 1.40 rmind pool_cache_t pc; 355 1.39 para size_t align; 356 1.39 para 357 1.39 para /* check if we reached the requested size */ 358 1.46 para if (cache_size > maxsize || cache_size > PAGE_SIZE) { 359 1.23 ad break; 360 1.40 rmind } 361 1.66.4.2 martin 362 1.66.4.2 martin /* 363 1.66.4.2 martin * Exclude caches with size not a factor or multiple of the 364 1.66.4.2 martin * coherency unit. 365 1.66.4.2 martin */ 366 1.66.4.2 martin if (cache_size < COHERENCY_UNIT) { 367 1.66.4.2 martin if (COHERENCY_UNIT % cache_size > 0) { 368 1.66.4.2 martin continue; 369 1.66.4.2 martin } 370 1.66.4.2 martin flags |= PR_NOTOUCH; 371 1.66.4.2 martin align = KMEM_ALIGN; 372 1.66.4.2 martin } else if ((cache_size & (PAGE_SIZE - 1)) == 0) { 373 1.66.4.2 martin align = PAGE_SIZE; 374 1.66.4.2 martin } else { 375 1.66.4.2 martin if ((cache_size % COHERENCY_UNIT) > 0) { 376 1.66.4.2 martin continue; 377 1.66.4.2 martin } 378 1.66.4.2 martin align = COHERENCY_UNIT; 379 1.46 para } 380 1.46 para 381 1.46 para if ((cache_size >> shift) > maxidx) { 382 1.46 para maxidx = cache_size >> shift; 383 1.40 rmind } 384 1.1 yamt 385 1.46 para pa = &pool_allocator_kmem; 386 1.39 para pc = pool_cache_init(cache_size, align, 0, flags, 387 1.46 para name, pa, ipl, NULL, NULL, NULL); 388 1.1 yamt 389 1.39 para while (size <= cache_size) { 390 1.46 para alloc_table[(size - 1) >> shift] = pc; 391 1.39 para size += table_unit; 392 1.39 para } 393 1.1 yamt } 394 1.46 para return maxidx; 395 1.1 yamt } 396 1.1 yamt 397 1.39 para void 398 1.39 para kmem_init(void) 399 1.1 yamt { 400 1.46 para kmem_cache_maxidx = kmem_create_caches(kmem_cache_sizes, 401 1.46 para kmem_cache, KMEM_MAXSIZE, KMEM_SHIFT, IPL_VM); 402 1.55 maxv kmem_cache_big_maxidx = kmem_create_caches(kmem_cache_big_sizes, 403 1.46 para kmem_cache_big, PAGE_SIZE, KMEM_BIG_SHIFT, IPL_VM); 404 1.1 yamt } 405 1.4 yamt 406 1.39 para size_t 407 1.39 para kmem_roundup_size(size_t size) 408 1.7 yamt { 409 1.61 maxv return (size + (KMEM_ALIGN - 1)) & ~(KMEM_ALIGN - 1); 410 1.61 maxv } 411 1.7 yamt 412 1.61 maxv /* 413 1.61 maxv * Used to dynamically allocate string with kmem accordingly to format. 414 1.61 maxv */ 415 1.61 maxv char * 416 1.61 maxv kmem_asprintf(const char *fmt, ...) 417 1.61 maxv { 418 1.61 maxv int size __diagused, len; 419 1.61 maxv va_list va; 420 1.61 maxv char *str; 421 1.61 maxv 422 1.61 maxv va_start(va, fmt); 423 1.61 maxv len = vsnprintf(NULL, 0, fmt, va); 424 1.61 maxv va_end(va); 425 1.61 maxv 426 1.61 maxv str = kmem_alloc(len + 1, KM_SLEEP); 427 1.61 maxv 428 1.61 maxv va_start(va, fmt); 429 1.61 maxv size = vsnprintf(str, len + 1, fmt, va); 430 1.61 maxv va_end(va); 431 1.61 maxv 432 1.61 maxv KASSERT(size == len); 433 1.61 maxv 434 1.61 maxv return str; 435 1.7 yamt } 436 1.7 yamt 437 1.64 christos char * 438 1.64 christos kmem_strdupsize(const char *str, size_t *lenp, km_flag_t flags) 439 1.64 christos { 440 1.64 christos size_t len = strlen(str) + 1; 441 1.64 christos char *ptr = kmem_alloc(len, flags); 442 1.64 christos if (ptr == NULL) 443 1.64 christos return NULL; 444 1.64 christos 445 1.64 christos if (lenp) 446 1.64 christos *lenp = len; 447 1.64 christos memcpy(ptr, str, len); 448 1.64 christos return ptr; 449 1.64 christos } 450 1.64 christos 451 1.66 christos char * 452 1.66 christos kmem_strndup(const char *str, size_t maxlen, km_flag_t flags) 453 1.66 christos { 454 1.66 christos KASSERT(str != NULL); 455 1.66 christos KASSERT(maxlen != 0); 456 1.66 christos 457 1.66 christos size_t len = strnlen(str, maxlen); 458 1.66 christos char *ptr = kmem_alloc(len + 1, flags); 459 1.66 christos if (ptr == NULL) 460 1.66 christos return NULL; 461 1.66 christos 462 1.66 christos memcpy(ptr, str, len); 463 1.66 christos ptr[len] = '\0'; 464 1.66 christos 465 1.66 christos return ptr; 466 1.66 christos } 467 1.66 christos 468 1.64 christos void 469 1.64 christos kmem_strfree(char *str) 470 1.64 christos { 471 1.64 christos if (str == NULL) 472 1.64 christos return; 473 1.64 christos 474 1.64 christos kmem_free(str, strlen(str) + 1); 475 1.64 christos } 476 1.64 christos 477 1.66.4.2 martin /* --------------------------- DEBUG / DIAGNOSTIC --------------------------- */ 478 1.4 yamt 479 1.23 ad #if defined(KMEM_SIZE) 480 1.23 ad static void 481 1.23 ad kmem_size_set(void *p, size_t sz) 482 1.23 ad { 483 1.66.4.2 martin memcpy((size_t *)((uintptr_t)p + sz), &sz, sizeof(size_t)); 484 1.23 ad } 485 1.23 ad 486 1.23 ad static void 487 1.39 para kmem_size_check(void *p, size_t sz) 488 1.23 ad { 489 1.57 maxv size_t hsz; 490 1.23 ad 491 1.66.4.2 martin memcpy(&hsz, (size_t *)((uintptr_t)p + sz), sizeof(size_t)); 492 1.57 maxv 493 1.57 maxv if (hsz != sz) { 494 1.66.4.2 martin panic("kmem_free(%p, %zu) != allocated size %zu; overwrote?", 495 1.66.4.2 martin p, sz, hsz); 496 1.23 ad } 497 1.54 maxv 498 1.66.4.2 martin memset((size_t *)((uintptr_t)p + sz), 0xff, sizeof(size_t)); 499 1.54 maxv } 500 1.66.4.1 christos #endif /* defined(KMEM_SIZE) */ 501
Indexes created Mon Sep 22 13:09:51 GMT 2025