subr_kobj.c revision 1.9.10.1
1 1.9.10.1 mjf /* $NetBSD: subr_kobj.c,v 1.9.10.1 2008/04/03 12:43:03 mjf Exp $ */ 2 1.1 ad 3 1.1 ad /*- 4 1.1 ad * Copyright (c) 2008 The NetBSD Foundation, Inc. 5 1.1 ad * All rights reserved. 6 1.1 ad * 7 1.1 ad * Redistribution and use in source and binary forms, with or without 8 1.1 ad * modification, are permitted provided that the following conditions 9 1.1 ad * are met: 10 1.1 ad * 1. Redistributions of source code must retain the above copyright 11 1.1 ad * notice, this list of conditions and the following disclaimer. 12 1.1 ad * 2. Redistributions in binary form must reproduce the above copyright 13 1.1 ad * notice, this list of conditions and the following disclaimer in the 14 1.1 ad * documentation and/or other materials provided with the distribution. 15 1.1 ad * 3. All advertising materials mentioning features or use of this software 16 1.1 ad * must display the following acknowledgement: 17 1.1 ad * This product includes software developed by the NetBSD 18 1.1 ad * Foundation, Inc. and its contributors. 19 1.1 ad * 4. Neither the name of The NetBSD Foundation nor the names of its 20 1.1 ad * contributors may be used to endorse or promote products derived 21 1.1 ad * from this software without specific prior written permission. 22 1.1 ad * 23 1.1 ad * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 24 1.1 ad * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 25 1.1 ad * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 26 1.1 ad * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 27 1.1 ad * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 28 1.1 ad * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 29 1.1 ad * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 30 1.1 ad * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 31 1.1 ad * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 32 1.1 ad * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 33 1.1 ad * POSSIBILITY OF SUCH DAMAGE. 34 1.1 ad */ 35 1.1 ad 36 1.1 ad /*- 37 1.1 ad * Copyright (c) 1998-2000 Doug Rabson 38 1.1 ad * Copyright (c) 2004 Peter Wemm 39 1.1 ad * All rights reserved. 40 1.1 ad * 41 1.1 ad * Redistribution and use in source and binary forms, with or without 42 1.1 ad * modification, are permitted provided that the following conditions 43 1.1 ad * are met: 44 1.1 ad * 1. Redistributions of source code must retain the above copyright 45 1.1 ad * notice, this list of conditions and the following disclaimer. 46 1.1 ad * 2. Redistributions in binary form must reproduce the above copyright 47 1.1 ad * notice, this list of conditions and the following disclaimer in the 48 1.1 ad * documentation and/or other materials provided with the distribution. 49 1.1 ad * 50 1.1 ad * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND 51 1.1 ad * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 52 1.1 ad * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 53 1.1 ad * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE 54 1.1 ad * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 55 1.1 ad * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 56 1.1 ad * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 57 1.1 ad * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 58 1.1 ad * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 59 1.1 ad * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 60 1.1 ad * SUCH DAMAGE. 61 1.1 ad */ 62 1.1 ad 63 1.1 ad /* 64 1.1 ad * Kernel loader for ELF objects. 65 1.1 ad * 66 1.1 ad * TODO: adjust kmem_alloc() calls to avoid needless fragmentation. 67 1.1 ad */ 68 1.1 ad 69 1.5 ad #include "opt_modular.h" 70 1.5 ad 71 1.1 ad #include <sys/cdefs.h> 72 1.9.10.1 mjf __KERNEL_RCSID(0, "$NetBSD: subr_kobj.c,v 1.9.10.1 2008/04/03 12:43:03 mjf Exp $"); 73 1.1 ad 74 1.1 ad #define ELFSIZE ARCH_ELFSIZE 75 1.1 ad 76 1.1 ad #include <sys/param.h> 77 1.1 ad #include <sys/systm.h> 78 1.1 ad #include <sys/kernel.h> 79 1.1 ad #include <sys/kmem.h> 80 1.1 ad #include <sys/proc.h> 81 1.1 ad #include <sys/namei.h> 82 1.1 ad #include <sys/vnode.h> 83 1.1 ad #include <sys/fcntl.h> 84 1.1 ad #include <sys/kobj.h> 85 1.1 ad #include <sys/ksyms.h> 86 1.1 ad #include <sys/lkm.h> 87 1.1 ad #include <sys/exec.h> 88 1.1 ad #include <sys/exec_elf.h> 89 1.1 ad 90 1.1 ad #include <machine/stdarg.h> 91 1.1 ad 92 1.1 ad #include <uvm/uvm_extern.h> 93 1.1 ad 94 1.5 ad #ifdef MODULAR 95 1.5 ad 96 1.1 ad typedef struct { 97 1.1 ad void *addr; 98 1.1 ad Elf_Off size; 99 1.1 ad int flags; 100 1.1 ad int sec; /* Original section */ 101 1.1 ad const char *name; 102 1.1 ad } progent_t; 103 1.1 ad 104 1.1 ad typedef struct { 105 1.1 ad Elf_Rel *rel; 106 1.1 ad int nrel; 107 1.1 ad int sec; 108 1.1 ad size_t size; 109 1.1 ad } relent_t; 110 1.1 ad 111 1.1 ad typedef struct { 112 1.1 ad Elf_Rela *rela; 113 1.1 ad int nrela; 114 1.1 ad int sec; 115 1.1 ad size_t size; 116 1.1 ad } relaent_t; 117 1.1 ad 118 1.3 ad typedef enum kobjtype { 119 1.3 ad KT_UNSET, 120 1.3 ad KT_VNODE, 121 1.3 ad KT_MEMORY 122 1.3 ad } kobjtype_t; 123 1.3 ad 124 1.1 ad struct kobj { 125 1.1 ad char ko_name[MAXLKMNAME]; 126 1.3 ad kobjtype_t ko_type; 127 1.3 ad void *ko_source; 128 1.3 ad ssize_t ko_memsize; 129 1.1 ad vaddr_t ko_address; /* Relocation address */ 130 1.1 ad Elf_Shdr *ko_shdr; 131 1.1 ad progent_t *ko_progtab; 132 1.1 ad relaent_t *ko_relatab; 133 1.1 ad relent_t *ko_reltab; 134 1.1 ad Elf_Sym *ko_symtab; /* Symbol table */ 135 1.1 ad char *ko_strtab; /* String table */ 136 1.8 ad char *ko_shstrtab; /* Section name string table */ 137 1.1 ad size_t ko_size; /* Size of text/data/bss */ 138 1.1 ad size_t ko_symcnt; /* Number of symbols */ 139 1.1 ad size_t ko_strtabsz; /* Number of bytes in string table */ 140 1.8 ad size_t ko_shstrtabsz; /* Number of bytes in scn str table */ 141 1.1 ad size_t ko_shdrsz; 142 1.1 ad int ko_nrel; 143 1.1 ad int ko_nrela; 144 1.1 ad int ko_nprogtab; 145 1.1 ad bool ko_ksyms; 146 1.3 ad bool ko_loaded; 147 1.1 ad }; 148 1.1 ad 149 1.1 ad static int kobj_relocate(kobj_t); 150 1.1 ad static void kobj_error(const char *, ...); 151 1.3 ad static int kobj_read(kobj_t, void *, size_t, off_t); 152 1.1 ad static void kobj_release_mem(kobj_t); 153 1.1 ad 154 1.1 ad extern struct vm_map *lkm_map; 155 1.1 ad static const char *kobj_path = "/modules"; /* XXX ??? */ 156 1.1 ad 157 1.1 ad /* 158 1.3 ad * kobj_open_file: 159 1.1 ad * 160 1.6 ad * Open an object located in the file system. 161 1.1 ad */ 162 1.1 ad int 163 1.6 ad kobj_open_file(kobj_t *kop, const char *filename) 164 1.1 ad { 165 1.1 ad struct nameidata nd; 166 1.1 ad kauth_cred_t cred; 167 1.1 ad char *path; 168 1.1 ad int error; 169 1.1 ad kobj_t ko; 170 1.1 ad 171 1.1 ad cred = kauth_cred_get(); 172 1.1 ad 173 1.1 ad ko = kmem_zalloc(sizeof(*ko), KM_SLEEP); 174 1.1 ad if (ko == NULL) { 175 1.1 ad return ENOMEM; 176 1.1 ad } 177 1.1 ad 178 1.3 ad /* XXX where to look? */ 179 1.3 ad NDINIT(&nd, LOOKUP, FOLLOW, UIO_SYSSPACE, filename); 180 1.1 ad error = vn_open(&nd, FREAD, 0); 181 1.1 ad if (error != 0) { 182 1.2 ad if (error != ENOENT) { 183 1.2 ad goto out; 184 1.2 ad } 185 1.2 ad path = PNBUF_GET(); 186 1.3 ad snprintf(path, MAXPATHLEN - 1, "%s/%s", kobj_path, 187 1.3 ad filename); 188 1.2 ad NDINIT(&nd, LOOKUP, FOLLOW, UIO_SYSSPACE, path); 189 1.2 ad error = vn_open(&nd, FREAD, 0); 190 1.9 rumble if (error != 0) { 191 1.9 rumble strlcat(path, ".o", MAXPATHLEN); 192 1.9 rumble NDINIT(&nd, LOOKUP, FOLLOW, UIO_SYSSPACE, path); 193 1.9 rumble error = vn_open(&nd, FREAD, 0); 194 1.9 rumble } 195 1.2 ad PNBUF_PUT(path); 196 1.2 ad if (error != 0) { 197 1.2 ad goto out; 198 1.2 ad } 199 1.1 ad } 200 1.1 ad 201 1.3 ad out: 202 1.3 ad if (error != 0) { 203 1.3 ad kmem_free(ko, sizeof(*ko)); 204 1.3 ad } else { 205 1.3 ad ko->ko_type = KT_VNODE; 206 1.3 ad ko->ko_source = nd.ni_vp; 207 1.3 ad *kop = ko; 208 1.3 ad } 209 1.3 ad return error; 210 1.3 ad } 211 1.3 ad 212 1.3 ad /* 213 1.3 ad * kobj_open_mem: 214 1.3 ad * 215 1.3 ad * Open a pre-loaded object already resident in memory. If size 216 1.6 ad * is not -1, the complete size of the object is known. 217 1.3 ad */ 218 1.3 ad int 219 1.6 ad kobj_open_mem(kobj_t *kop, void *base, ssize_t size) 220 1.3 ad { 221 1.3 ad kobj_t ko; 222 1.3 ad 223 1.3 ad ko = kmem_zalloc(sizeof(*ko), KM_SLEEP); 224 1.3 ad if (ko == NULL) { 225 1.3 ad return ENOMEM; 226 1.3 ad } 227 1.3 ad 228 1.3 ad ko->ko_type = KT_MEMORY; 229 1.3 ad ko->ko_source = base; 230 1.3 ad ko->ko_memsize = size; 231 1.3 ad *kop = ko; 232 1.3 ad 233 1.3 ad return 0; 234 1.3 ad } 235 1.3 ad 236 1.3 ad /* 237 1.3 ad * kobj_close: 238 1.3 ad * 239 1.3 ad * Close an open ELF object. If the object was not successfully 240 1.3 ad * loaded, it will be destroyed. 241 1.3 ad */ 242 1.3 ad void 243 1.3 ad kobj_close(kobj_t ko) 244 1.3 ad { 245 1.3 ad 246 1.3 ad KASSERT(ko->ko_source != NULL); 247 1.3 ad 248 1.3 ad switch (ko->ko_type) { 249 1.3 ad case KT_VNODE: 250 1.3 ad VOP_UNLOCK(ko->ko_source, 0); 251 1.9.10.1 mjf vn_close(ko->ko_source, FREAD, kauth_cred_get()); 252 1.3 ad break; 253 1.3 ad case KT_MEMORY: 254 1.3 ad /* nothing */ 255 1.3 ad break; 256 1.3 ad default: 257 1.3 ad panic("kobj_close: unknown type"); 258 1.3 ad break; 259 1.3 ad } 260 1.3 ad 261 1.3 ad ko->ko_source = NULL; 262 1.3 ad ko->ko_type = KT_UNSET; 263 1.3 ad 264 1.8 ad /* Program table and section strings are no longer needed. */ 265 1.8 ad if (ko->ko_progtab != NULL) { 266 1.8 ad kmem_free(ko->ko_progtab, ko->ko_nprogtab * 267 1.8 ad sizeof(*ko->ko_progtab)); 268 1.8 ad ko->ko_progtab = NULL; 269 1.8 ad } 270 1.8 ad if (ko->ko_shstrtab) { 271 1.8 ad kmem_free(ko->ko_shstrtab, ko->ko_shstrtabsz); 272 1.8 ad ko->ko_shstrtab = NULL; 273 1.8 ad } 274 1.8 ad 275 1.3 ad /* If the object hasn't been loaded, then destroy it. */ 276 1.3 ad if (!ko->ko_loaded) { 277 1.3 ad kobj_unload(ko); 278 1.3 ad } 279 1.3 ad } 280 1.3 ad 281 1.3 ad /* 282 1.3 ad * kobj_load: 283 1.3 ad * 284 1.3 ad * Load an ELF object from the file system and link into the 285 1.3 ad * running kernel image. 286 1.3 ad */ 287 1.3 ad int 288 1.3 ad kobj_load(kobj_t ko) 289 1.3 ad { 290 1.3 ad Elf_Ehdr *hdr; 291 1.3 ad Elf_Shdr *shdr; 292 1.3 ad Elf_Sym *es; 293 1.3 ad vaddr_t mapbase; 294 1.3 ad size_t mapsize; 295 1.3 ad int error; 296 1.3 ad int symtabindex; 297 1.3 ad int symstrindex; 298 1.3 ad int nsym; 299 1.3 ad int pb, rl, ra; 300 1.3 ad int alignmask; 301 1.3 ad int i, j; 302 1.3 ad 303 1.3 ad KASSERT(ko->ko_type != KT_UNSET); 304 1.3 ad KASSERT(ko->ko_source != NULL); 305 1.3 ad 306 1.3 ad shdr = NULL; 307 1.3 ad mapsize = 0; 308 1.3 ad error = 0; 309 1.3 ad hdr = NULL; 310 1.3 ad 311 1.1 ad /* 312 1.1 ad * Read the elf header from the file. 313 1.1 ad */ 314 1.1 ad hdr = kmem_alloc(sizeof(*hdr), KM_SLEEP); 315 1.1 ad if (hdr == NULL) { 316 1.1 ad error = ENOMEM; 317 1.1 ad goto out; 318 1.1 ad } 319 1.3 ad error = kobj_read(ko, hdr, sizeof(*hdr), 0); 320 1.1 ad if (error != 0) 321 1.1 ad goto out; 322 1.1 ad if (memcmp(hdr->e_ident, ELFMAG, SELFMAG) != 0) { 323 1.3 ad kobj_error("not an ELF object"); 324 1.1 ad error = ENOEXEC; 325 1.1 ad goto out; 326 1.1 ad } 327 1.1 ad 328 1.1 ad if (hdr->e_ident[EI_VERSION] != EV_CURRENT || 329 1.1 ad hdr->e_version != EV_CURRENT) { 330 1.1 ad kobj_error("unsupported file version"); 331 1.1 ad error = ENOEXEC; 332 1.1 ad goto out; 333 1.1 ad } 334 1.1 ad if (hdr->e_type != ET_REL) { 335 1.1 ad kobj_error("unsupported file type"); 336 1.1 ad error = ENOEXEC; 337 1.1 ad goto out; 338 1.1 ad } 339 1.1 ad switch (hdr->e_machine) { 340 1.1 ad #if ELFSIZE == 32 341 1.1 ad ELF32_MACHDEP_ID_CASES 342 1.1 ad #else 343 1.1 ad ELF64_MACHDEP_ID_CASES 344 1.1 ad #endif 345 1.1 ad default: 346 1.1 ad kobj_error("unsupported machine"); 347 1.1 ad error = ENOEXEC; 348 1.1 ad goto out; 349 1.1 ad } 350 1.1 ad 351 1.1 ad ko->ko_nprogtab = 0; 352 1.1 ad ko->ko_shdr = 0; 353 1.1 ad ko->ko_nrel = 0; 354 1.1 ad ko->ko_nrela = 0; 355 1.1 ad 356 1.1 ad /* 357 1.1 ad * Allocate and read in the section header. 358 1.1 ad */ 359 1.1 ad ko->ko_shdrsz = hdr->e_shnum * hdr->e_shentsize; 360 1.1 ad if (ko->ko_shdrsz == 0 || hdr->e_shoff == 0 || 361 1.1 ad hdr->e_shentsize != sizeof(Elf_Shdr)) { 362 1.1 ad error = ENOEXEC; 363 1.1 ad goto out; 364 1.1 ad } 365 1.1 ad shdr = kmem_alloc(ko->ko_shdrsz, KM_SLEEP); 366 1.1 ad if (shdr == NULL) { 367 1.1 ad error = ENOMEM; 368 1.1 ad goto out; 369 1.1 ad } 370 1.1 ad ko->ko_shdr = shdr; 371 1.3 ad error = kobj_read(ko, shdr, ko->ko_shdrsz, hdr->e_shoff); 372 1.1 ad if (error != 0) { 373 1.1 ad goto out; 374 1.1 ad } 375 1.1 ad 376 1.1 ad /* 377 1.1 ad * Scan the section header for information and table sizing. 378 1.1 ad */ 379 1.1 ad nsym = 0; 380 1.1 ad symtabindex = -1; 381 1.1 ad symstrindex = -1; 382 1.1 ad for (i = 0; i < hdr->e_shnum; i++) { 383 1.1 ad switch (shdr[i].sh_type) { 384 1.1 ad case SHT_PROGBITS: 385 1.1 ad case SHT_NOBITS: 386 1.1 ad ko->ko_nprogtab++; 387 1.1 ad break; 388 1.1 ad case SHT_SYMTAB: 389 1.1 ad nsym++; 390 1.1 ad symtabindex = i; 391 1.1 ad symstrindex = shdr[i].sh_link; 392 1.1 ad break; 393 1.1 ad case SHT_REL: 394 1.1 ad ko->ko_nrel++; 395 1.1 ad break; 396 1.1 ad case SHT_RELA: 397 1.1 ad ko->ko_nrela++; 398 1.1 ad break; 399 1.1 ad case SHT_STRTAB: 400 1.1 ad break; 401 1.1 ad } 402 1.1 ad } 403 1.1 ad if (ko->ko_nprogtab == 0) { 404 1.1 ad kobj_error("file has no contents"); 405 1.1 ad error = ENOEXEC; 406 1.1 ad goto out; 407 1.1 ad } 408 1.1 ad if (nsym != 1) { 409 1.1 ad /* Only allow one symbol table for now */ 410 1.1 ad kobj_error("file has no valid symbol table"); 411 1.1 ad error = ENOEXEC; 412 1.1 ad goto out; 413 1.1 ad } 414 1.1 ad if (symstrindex < 0 || symstrindex > hdr->e_shnum || 415 1.1 ad shdr[symstrindex].sh_type != SHT_STRTAB) { 416 1.1 ad kobj_error("file has invalid symbol strings"); 417 1.1 ad error = ENOEXEC; 418 1.1 ad goto out; 419 1.1 ad } 420 1.1 ad 421 1.1 ad /* 422 1.1 ad * Allocate space for tracking the load chunks. 423 1.1 ad */ 424 1.1 ad if (ko->ko_nprogtab != 0) { 425 1.1 ad ko->ko_progtab = kmem_zalloc(ko->ko_nprogtab * 426 1.1 ad sizeof(*ko->ko_progtab), KM_SLEEP); 427 1.1 ad if (ko->ko_progtab == NULL) { 428 1.1 ad error = ENOMEM; 429 1.1 ad goto out; 430 1.1 ad } 431 1.1 ad } 432 1.1 ad if (ko->ko_nrel != 0) { 433 1.1 ad ko->ko_reltab = kmem_zalloc(ko->ko_nrel * 434 1.1 ad sizeof(*ko->ko_reltab), KM_SLEEP); 435 1.1 ad if (ko->ko_reltab == NULL) { 436 1.1 ad error = ENOMEM; 437 1.1 ad goto out; 438 1.1 ad } 439 1.1 ad } 440 1.1 ad if (ko->ko_nrela != 0) { 441 1.1 ad ko->ko_relatab = kmem_zalloc(ko->ko_nrela * 442 1.1 ad sizeof(*ko->ko_relatab), KM_SLEEP); 443 1.1 ad if (ko->ko_relatab == NULL) { 444 1.1 ad error = ENOMEM; 445 1.1 ad goto out; 446 1.1 ad } 447 1.1 ad } 448 1.1 ad if (symtabindex == -1) { 449 1.1 ad kobj_error("lost symbol table index"); 450 1.1 ad goto out; 451 1.1 ad } 452 1.1 ad 453 1.1 ad /* 454 1.1 ad * Allocate space for and load the symbol table. 455 1.1 ad */ 456 1.1 ad ko->ko_symcnt = shdr[symtabindex].sh_size / sizeof(Elf_Sym); 457 1.1 ad if (ko->ko_symcnt == 0) { 458 1.1 ad kobj_error("no symbol table"); 459 1.1 ad goto out; 460 1.1 ad } 461 1.1 ad ko->ko_symtab = kmem_alloc(ko->ko_symcnt * sizeof(Elf_Sym), KM_SLEEP); 462 1.1 ad if (ko->ko_symtab == NULL) { 463 1.1 ad error = ENOMEM; 464 1.1 ad goto out; 465 1.1 ad } 466 1.3 ad error = kobj_read(ko, ko->ko_symtab, shdr[symtabindex].sh_size, 467 1.1 ad shdr[symtabindex].sh_offset); 468 1.1 ad if (error != 0) { 469 1.1 ad goto out; 470 1.1 ad } 471 1.1 ad 472 1.1 ad /* 473 1.1 ad * Allocate space for and load the symbol strings. 474 1.1 ad */ 475 1.1 ad ko->ko_strtabsz = shdr[symstrindex].sh_size; 476 1.1 ad if (ko->ko_strtabsz == 0) { 477 1.1 ad kobj_error("no symbol strings"); 478 1.1 ad goto out; 479 1.1 ad } 480 1.1 ad ko->ko_strtab = kmem_alloc(ko->ko_strtabsz, KM_SLEEP); 481 1.1 ad if (ko->ko_strtab == NULL) { 482 1.1 ad error = ENOMEM; 483 1.1 ad goto out; 484 1.1 ad } 485 1.3 ad error = kobj_read(ko, ko->ko_strtab, shdr[symstrindex].sh_size, 486 1.1 ad shdr[symstrindex].sh_offset); 487 1.1 ad if (error != 0) { 488 1.1 ad goto out; 489 1.1 ad } 490 1.1 ad 491 1.1 ad /* 492 1.8 ad * Do we have a string table for the section names? 493 1.8 ad */ 494 1.8 ad if (hdr->e_shstrndx != 0 && shdr[hdr->e_shstrndx].sh_size != 0 && 495 1.8 ad shdr[hdr->e_shstrndx].sh_type == SHT_STRTAB) { 496 1.8 ad ko->ko_shstrtabsz = shdr[hdr->e_shstrndx].sh_size; 497 1.8 ad ko->ko_shstrtab = kmem_alloc(shdr[hdr->e_shstrndx].sh_size, 498 1.8 ad KM_SLEEP); 499 1.8 ad if (ko->ko_shstrtab == NULL) { 500 1.8 ad error = ENOMEM; 501 1.8 ad goto out; 502 1.8 ad } 503 1.8 ad error = kobj_read(ko, ko->ko_shstrtab, 504 1.8 ad shdr[hdr->e_shstrndx].sh_size, 505 1.8 ad shdr[hdr->e_shstrndx].sh_offset); 506 1.8 ad if (error != 0) { 507 1.8 ad goto out; 508 1.8 ad } 509 1.8 ad } 510 1.8 ad 511 1.8 ad /* 512 1.1 ad * Size up code/data(progbits) and bss(nobits). 513 1.1 ad */ 514 1.1 ad alignmask = 0; 515 1.1 ad for (i = 0; i < hdr->e_shnum; i++) { 516 1.1 ad switch (shdr[i].sh_type) { 517 1.1 ad case SHT_PROGBITS: 518 1.1 ad case SHT_NOBITS: 519 1.1 ad alignmask = shdr[i].sh_addralign - 1; 520 1.1 ad mapsize += alignmask; 521 1.1 ad mapsize &= ~alignmask; 522 1.1 ad mapsize += shdr[i].sh_size; 523 1.1 ad break; 524 1.1 ad } 525 1.1 ad } 526 1.1 ad 527 1.1 ad /* 528 1.1 ad * We know how much space we need for the text/data/bss/etc. 529 1.1 ad * This stuff needs to be in a single chunk so that profiling etc 530 1.1 ad * can get the bounds and gdb can associate offsets with modules. 531 1.1 ad */ 532 1.1 ad if (mapsize == 0) { 533 1.1 ad kobj_error("no text/data/bss"); 534 1.1 ad goto out; 535 1.1 ad } 536 1.1 ad mapbase = uvm_km_alloc(lkm_map, round_page(mapsize), 0, 537 1.1 ad UVM_KMF_WIRED | UVM_KMF_EXEC); 538 1.1 ad if (mapbase == 0) { 539 1.1 ad error = ENOMEM; 540 1.1 ad goto out; 541 1.1 ad } 542 1.1 ad ko->ko_address = mapbase; 543 1.1 ad ko->ko_size = mapsize; 544 1.1 ad 545 1.1 ad /* 546 1.1 ad * Now load code/data(progbits), zero bss(nobits), allocate space 547 1.1 ad * for and load relocs 548 1.1 ad */ 549 1.1 ad pb = 0; 550 1.1 ad rl = 0; 551 1.1 ad ra = 0; 552 1.1 ad alignmask = 0; 553 1.1 ad for (i = 0; i < hdr->e_shnum; i++) { 554 1.1 ad switch (shdr[i].sh_type) { 555 1.1 ad case SHT_PROGBITS: 556 1.1 ad case SHT_NOBITS: 557 1.1 ad alignmask = shdr[i].sh_addralign - 1; 558 1.1 ad mapbase += alignmask; 559 1.1 ad mapbase &= ~alignmask; 560 1.1 ad ko->ko_progtab[pb].addr = (void *)mapbase; 561 1.1 ad if (shdr[i].sh_type == SHT_PROGBITS) { 562 1.1 ad ko->ko_progtab[pb].name = "<<PROGBITS>>"; 563 1.3 ad error = kobj_read(ko, 564 1.1 ad ko->ko_progtab[pb].addr, shdr[i].sh_size, 565 1.1 ad shdr[i].sh_offset); 566 1.1 ad if (error != 0) { 567 1.1 ad goto out; 568 1.1 ad } 569 1.1 ad } else { 570 1.1 ad ko->ko_progtab[pb].name = "<<NOBITS>>"; 571 1.1 ad memset(ko->ko_progtab[pb].addr, 0, 572 1.1 ad shdr[i].sh_size); 573 1.1 ad } 574 1.1 ad ko->ko_progtab[pb].size = shdr[i].sh_size; 575 1.1 ad ko->ko_progtab[pb].sec = i; 576 1.8 ad if (ko->ko_shstrtab != NULL && shdr[i].sh_name != 0) { 577 1.8 ad ko->ko_progtab[pb].name = 578 1.8 ad ko->ko_shstrtab + shdr[i].sh_name; 579 1.8 ad } 580 1.1 ad 581 1.1 ad /* Update all symbol values with the offset. */ 582 1.1 ad for (j = 0; j < ko->ko_symcnt; j++) { 583 1.1 ad es = &ko->ko_symtab[j]; 584 1.1 ad if (es->st_shndx != i) { 585 1.1 ad continue; 586 1.1 ad } 587 1.1 ad es->st_value += 588 1.1 ad (Elf_Addr)ko->ko_progtab[pb].addr; 589 1.1 ad } 590 1.1 ad mapbase += shdr[i].sh_size; 591 1.1 ad pb++; 592 1.1 ad break; 593 1.1 ad case SHT_REL: 594 1.1 ad ko->ko_reltab[rl].size = shdr[i].sh_size; 595 1.1 ad ko->ko_reltab[rl].size -= 596 1.1 ad shdr[i].sh_size % sizeof(Elf_Rel); 597 1.1 ad if (ko->ko_reltab[rl].size != 0) { 598 1.1 ad ko->ko_reltab[rl].rel = 599 1.1 ad kmem_alloc(ko->ko_reltab[rl].size, 600 1.1 ad KM_SLEEP); 601 1.1 ad ko->ko_reltab[rl].nrel = 602 1.1 ad shdr[i].sh_size / sizeof(Elf_Rel); 603 1.1 ad ko->ko_reltab[rl].sec = shdr[i].sh_info; 604 1.3 ad error = kobj_read(ko, 605 1.1 ad ko->ko_reltab[rl].rel, 606 1.1 ad ko->ko_reltab[rl].size, 607 1.1 ad shdr[i].sh_offset); 608 1.1 ad if (error != 0) { 609 1.1 ad goto out; 610 1.1 ad } 611 1.1 ad } 612 1.1 ad rl++; 613 1.1 ad break; 614 1.1 ad case SHT_RELA: 615 1.1 ad ko->ko_relatab[ra].size = shdr[i].sh_size; 616 1.1 ad ko->ko_relatab[ra].size -= 617 1.1 ad shdr[i].sh_size % sizeof(Elf_Rela); 618 1.1 ad if (ko->ko_relatab[ra].size != 0) { 619 1.1 ad ko->ko_relatab[ra].rela = 620 1.1 ad kmem_alloc(ko->ko_relatab[ra].size, 621 1.1 ad KM_SLEEP); 622 1.1 ad ko->ko_relatab[ra].nrela = 623 1.1 ad shdr[i].sh_size / sizeof(Elf_Rela); 624 1.1 ad ko->ko_relatab[ra].sec = shdr[i].sh_info; 625 1.3 ad error = kobj_read(ko, 626 1.1 ad ko->ko_relatab[ra].rela, 627 1.1 ad shdr[i].sh_size, 628 1.1 ad shdr[i].sh_offset); 629 1.1 ad if (error != 0) { 630 1.1 ad goto out; 631 1.1 ad } 632 1.1 ad } 633 1.1 ad ra++; 634 1.1 ad break; 635 1.1 ad } 636 1.1 ad } 637 1.1 ad if (pb != ko->ko_nprogtab) { 638 1.1 ad panic("lost progbits"); 639 1.1 ad } 640 1.1 ad if (rl != ko->ko_nrel) { 641 1.1 ad panic("lost rel"); 642 1.1 ad } 643 1.1 ad if (ra != ko->ko_nrela) { 644 1.1 ad panic("lost rela"); 645 1.1 ad } 646 1.1 ad if (mapbase != ko->ko_address + mapsize) { 647 1.1 ad panic("mapbase 0x%lx != address %lx + mapsize 0x%lx (0x%lx)\n", 648 1.1 ad (long)mapbase, (long)ko->ko_address, (long)mapsize, 649 1.1 ad (long)ko->ko_address + mapsize); 650 1.1 ad } 651 1.1 ad 652 1.1 ad /* 653 1.1 ad * Perform relocations. Done before registering with ksyms, 654 1.1 ad * which will pack our symbol table. 655 1.1 ad */ 656 1.1 ad error = kobj_relocate(ko); 657 1.1 ad if (error != 0) { 658 1.1 ad goto out; 659 1.1 ad } 660 1.1 ad 661 1.1 ad /* 662 1.1 ad * Notify MD code that a module has been loaded. 663 1.1 ad */ 664 1.1 ad error = kobj_machdep(ko, (void *)ko->ko_address, ko->ko_size, true); 665 1.1 ad if (error != 0) { 666 1.1 ad kobj_error("machine dependent init failed"); 667 1.1 ad goto out; 668 1.1 ad } 669 1.3 ad ko->ko_loaded = true; 670 1.1 ad out: 671 1.1 ad kobj_release_mem(ko); 672 1.3 ad if (hdr != NULL) { 673 1.1 ad kmem_free(hdr, sizeof(*hdr)); 674 1.1 ad } 675 1.1 ad 676 1.1 ad return error; 677 1.1 ad } 678 1.1 ad 679 1.1 ad /* 680 1.1 ad * kobj_unload: 681 1.1 ad * 682 1.1 ad * Unload an object previously loaded by kobj_load(). 683 1.1 ad */ 684 1.1 ad void 685 1.1 ad kobj_unload(kobj_t ko) 686 1.1 ad { 687 1.1 ad int error; 688 1.1 ad 689 1.8 ad KASSERT(ko->ko_progtab == NULL); 690 1.8 ad KASSERT(ko->ko_shstrtab == NULL); 691 1.8 ad 692 1.1 ad if (ko->ko_address != 0) { 693 1.1 ad uvm_km_free(lkm_map, ko->ko_address, round_page(ko->ko_size), 694 1.1 ad UVM_KMF_WIRED); 695 1.1 ad } 696 1.1 ad if (ko->ko_ksyms == true) { 697 1.1 ad ksyms_delsymtab(ko->ko_name); 698 1.1 ad } 699 1.1 ad if (ko->ko_symtab != NULL) { 700 1.1 ad kmem_free(ko->ko_symtab, ko->ko_symcnt * sizeof(Elf_Sym)); 701 1.1 ad } 702 1.1 ad if (ko->ko_strtab != NULL) { 703 1.1 ad kmem_free(ko->ko_strtab, ko->ko_strtabsz); 704 1.1 ad } 705 1.1 ad 706 1.1 ad /* 707 1.1 ad * Notify MD code that a module has been unloaded. 708 1.1 ad */ 709 1.3 ad if (ko->ko_loaded) { 710 1.3 ad error = kobj_machdep(ko, (void *)ko->ko_address, ko->ko_size, 711 1.3 ad false); 712 1.3 ad if (error != 0) { 713 1.3 ad kobj_error("machine dependent deinit failed"); 714 1.3 ad } 715 1.1 ad } 716 1.3 ad 717 1.3 ad kmem_free(ko, sizeof(*ko)); 718 1.1 ad } 719 1.1 ad 720 1.1 ad /* 721 1.2 ad * kobj_stat: 722 1.2 ad * 723 1.2 ad * Return size and load address of an object. 724 1.2 ad */ 725 1.2 ad void 726 1.8 ad kobj_stat(kobj_t ko, vaddr_t *address, size_t *size) 727 1.2 ad { 728 1.2 ad 729 1.2 ad if (address != NULL) { 730 1.2 ad *address = ko->ko_address; 731 1.2 ad } 732 1.2 ad if (size != NULL) { 733 1.2 ad *size = ko->ko_size; 734 1.2 ad } 735 1.2 ad } 736 1.2 ad 737 1.2 ad /* 738 1.3 ad * kobj_set_name: 739 1.3 ad * 740 1.3 ad * Set an object's name. Used only for symbol table lookups. 741 1.3 ad * May only be called after the module is loaded. 742 1.3 ad */ 743 1.6 ad int 744 1.3 ad kobj_set_name(kobj_t ko, const char *name) 745 1.3 ad { 746 1.6 ad int error; 747 1.3 ad 748 1.3 ad KASSERT(ko->ko_loaded); 749 1.3 ad 750 1.3 ad strlcpy(ko->ko_name, name, sizeof(ko->ko_name)); 751 1.6 ad 752 1.6 ad /* 753 1.6 ad * Now that we know the name, register the symbol table. 754 1.6 ad */ 755 1.6 ad error = ksyms_addsymtab(ko->ko_name, ko->ko_symtab, ko->ko_symcnt * 756 1.6 ad sizeof(Elf_Sym), ko->ko_strtab, ko->ko_strtabsz); 757 1.6 ad if (error != 0) { 758 1.6 ad kobj_error("unable to register module symbol table"); 759 1.6 ad } else { 760 1.6 ad ko->ko_ksyms = true; 761 1.6 ad } 762 1.6 ad 763 1.6 ad return error; 764 1.3 ad } 765 1.3 ad 766 1.3 ad /* 767 1.8 ad * kobj_find_section: 768 1.8 ad * 769 1.8 ad * Given a section name, search the loaded object and return 770 1.8 ad * virtual address if present and loaded. 771 1.8 ad */ 772 1.8 ad int 773 1.8 ad kobj_find_section(kobj_t ko, const char *name, void **addr, size_t *size) 774 1.8 ad { 775 1.8 ad int i; 776 1.8 ad 777 1.8 ad KASSERT(ko->ko_progtab != NULL); 778 1.8 ad 779 1.8 ad for (i = 0; i < ko->ko_nprogtab; i++) { 780 1.8 ad if (strcmp(ko->ko_progtab[i].name, name) == 0) { 781 1.8 ad if (addr != NULL) { 782 1.8 ad *addr = ko->ko_progtab[i].addr; 783 1.8 ad } 784 1.8 ad if (size != NULL) { 785 1.8 ad *size = ko->ko_progtab[i].size; 786 1.8 ad } 787 1.8 ad return 0; 788 1.8 ad } 789 1.8 ad } 790 1.8 ad 791 1.8 ad return ENOENT; 792 1.8 ad } 793 1.8 ad 794 1.8 ad /* 795 1.1 ad * kobj_release_mem: 796 1.1 ad * 797 1.1 ad * Release object data not needed after loading. 798 1.1 ad */ 799 1.1 ad static void 800 1.1 ad kobj_release_mem(kobj_t ko) 801 1.1 ad { 802 1.1 ad int i; 803 1.1 ad 804 1.1 ad for (i = 0; i < ko->ko_nrel; i++) { 805 1.1 ad if (ko->ko_reltab[i].rel) { 806 1.1 ad kmem_free(ko->ko_reltab[i].rel, 807 1.1 ad ko->ko_reltab[i].size); 808 1.1 ad } 809 1.1 ad } 810 1.1 ad for (i = 0; i < ko->ko_nrela; i++) { 811 1.1 ad if (ko->ko_relatab[i].rela) { 812 1.1 ad kmem_free(ko->ko_relatab[i].rela, 813 1.1 ad ko->ko_relatab[i].size); 814 1.1 ad } 815 1.1 ad } 816 1.1 ad if (ko->ko_reltab != NULL) { 817 1.1 ad kmem_free(ko->ko_reltab, ko->ko_nrel * 818 1.1 ad sizeof(*ko->ko_reltab)); 819 1.1 ad ko->ko_reltab = NULL; 820 1.1 ad ko->ko_nrel = 0; 821 1.1 ad } 822 1.1 ad if (ko->ko_relatab != NULL) { 823 1.1 ad kmem_free(ko->ko_relatab, ko->ko_nrela * 824 1.1 ad sizeof(*ko->ko_relatab)); 825 1.1 ad ko->ko_relatab = NULL; 826 1.1 ad ko->ko_nrela = 0; 827 1.1 ad } 828 1.1 ad if (ko->ko_shdr != NULL) { 829 1.1 ad kmem_free(ko->ko_shdr, ko->ko_shdrsz); 830 1.1 ad ko->ko_shdr = NULL; 831 1.1 ad } 832 1.1 ad } 833 1.1 ad 834 1.1 ad /* 835 1.1 ad * kobj_sym_lookup: 836 1.1 ad * 837 1.1 ad * Symbol lookup function to be used when the symbol index 838 1.1 ad * is known (ie during relocation). 839 1.1 ad */ 840 1.1 ad uintptr_t 841 1.1 ad kobj_sym_lookup(kobj_t ko, uintptr_t symidx) 842 1.1 ad { 843 1.1 ad const Elf_Sym *sym; 844 1.1 ad const char *symbol; 845 1.1 ad int error; 846 1.1 ad u_long addr; 847 1.1 ad 848 1.1 ad /* Don't even try to lookup the symbol if the index is bogus. */ 849 1.1 ad if (symidx >= ko->ko_symcnt) 850 1.1 ad return 0; 851 1.1 ad 852 1.1 ad sym = ko->ko_symtab + symidx; 853 1.1 ad 854 1.1 ad /* Quick answer if there is a definition included. */ 855 1.1 ad if (sym->st_shndx != SHN_UNDEF) { 856 1.1 ad return sym->st_value; 857 1.1 ad } 858 1.1 ad 859 1.1 ad /* If we get here, then it is undefined and needs a lookup. */ 860 1.1 ad switch (ELF_ST_BIND(sym->st_info)) { 861 1.1 ad case STB_LOCAL: 862 1.1 ad /* Local, but undefined? huh? */ 863 1.1 ad kobj_error("local symbol undefined"); 864 1.1 ad return 0; 865 1.1 ad 866 1.1 ad case STB_GLOBAL: 867 1.1 ad /* Relative to Data or Function name */ 868 1.1 ad symbol = ko->ko_strtab + sym->st_name; 869 1.1 ad 870 1.1 ad /* Force a lookup failure if the symbol name is bogus. */ 871 1.1 ad if (*symbol == 0) { 872 1.1 ad kobj_error("bad symbol name"); 873 1.1 ad return 0; 874 1.1 ad } 875 1.1 ad 876 1.1 ad error = ksyms_getval(NULL, symbol, &addr, KSYMS_ANY); 877 1.1 ad if (error != 0) { 878 1.1 ad kobj_error("symbol %s undefined", symbol); 879 1.1 ad return (uintptr_t)0; 880 1.1 ad } 881 1.1 ad return (uintptr_t)addr; 882 1.1 ad 883 1.1 ad case STB_WEAK: 884 1.1 ad kobj_error("weak symbols not supported\n"); 885 1.1 ad return 0; 886 1.1 ad 887 1.1 ad default: 888 1.1 ad return 0; 889 1.1 ad } 890 1.1 ad } 891 1.1 ad 892 1.1 ad /* 893 1.1 ad * kobj_findbase: 894 1.1 ad * 895 1.1 ad * Return base address of the given section. 896 1.1 ad */ 897 1.1 ad static uintptr_t 898 1.1 ad kobj_findbase(kobj_t ko, int sec) 899 1.1 ad { 900 1.1 ad int i; 901 1.1 ad 902 1.1 ad for (i = 0; i < ko->ko_nprogtab; i++) { 903 1.1 ad if (sec == ko->ko_progtab[i].sec) { 904 1.1 ad return (uintptr_t)ko->ko_progtab[i].addr; 905 1.1 ad } 906 1.1 ad } 907 1.1 ad return 0; 908 1.1 ad } 909 1.1 ad 910 1.1 ad /* 911 1.1 ad * kobj_relocate: 912 1.1 ad * 913 1.1 ad * Resolve all relocations for the loaded object. 914 1.1 ad */ 915 1.1 ad static int 916 1.1 ad kobj_relocate(kobj_t ko) 917 1.1 ad { 918 1.1 ad const Elf_Rel *rellim; 919 1.1 ad const Elf_Rel *rel; 920 1.1 ad const Elf_Rela *relalim; 921 1.1 ad const Elf_Rela *rela; 922 1.1 ad const Elf_Sym *sym; 923 1.1 ad uintptr_t base; 924 1.8 ad int i, error; 925 1.1 ad uintptr_t symidx; 926 1.1 ad 927 1.1 ad /* 928 1.1 ad * Perform relocations without addend if there are any. 929 1.1 ad */ 930 1.1 ad for (i = 0; i < ko->ko_nrel; i++) { 931 1.1 ad rel = ko->ko_reltab[i].rel; 932 1.1 ad if (rel == NULL) { 933 1.1 ad continue; 934 1.1 ad } 935 1.1 ad rellim = rel + ko->ko_reltab[i].nrel; 936 1.1 ad base = kobj_findbase(ko, ko->ko_reltab[i].sec); 937 1.1 ad if (base == 0) { 938 1.1 ad panic("lost base for e_reltab"); 939 1.1 ad } 940 1.1 ad for (; rel < rellim; rel++) { 941 1.1 ad symidx = ELF_R_SYM(rel->r_info); 942 1.1 ad if (symidx >= ko->ko_symcnt) { 943 1.1 ad continue; 944 1.1 ad } 945 1.1 ad sym = ko->ko_symtab + symidx; 946 1.8 ad error = kobj_reloc(ko, base, rel, false, 947 1.8 ad ELF_ST_BIND(sym->st_info) == STB_LOCAL); 948 1.8 ad if (error != 0) { 949 1.1 ad return ENOENT; 950 1.1 ad } 951 1.1 ad } 952 1.1 ad } 953 1.1 ad 954 1.1 ad /* 955 1.1 ad * Perform relocations with addend if there are any. 956 1.1 ad */ 957 1.1 ad for (i = 0; i < ko->ko_nrela; i++) { 958 1.1 ad rela = ko->ko_relatab[i].rela; 959 1.1 ad if (rela == NULL) { 960 1.1 ad continue; 961 1.1 ad } 962 1.1 ad relalim = rela + ko->ko_relatab[i].nrela; 963 1.1 ad base = kobj_findbase(ko, ko->ko_relatab[i].sec); 964 1.1 ad if (base == 0) { 965 1.1 ad panic("lost base for e_relatab"); 966 1.1 ad } 967 1.1 ad for (; rela < relalim; rela++) { 968 1.1 ad symidx = ELF_R_SYM(rela->r_info); 969 1.1 ad if (symidx >= ko->ko_symcnt) { 970 1.1 ad continue; 971 1.1 ad } 972 1.1 ad sym = ko->ko_symtab + symidx; 973 1.8 ad error = kobj_reloc(ko, base, rela, true, 974 1.8 ad ELF_ST_BIND(sym->st_info) == STB_LOCAL); 975 1.8 ad if (error != 0) { 976 1.1 ad return ENOENT; 977 1.1 ad } 978 1.1 ad } 979 1.1 ad } 980 1.1 ad 981 1.1 ad return 0; 982 1.1 ad } 983 1.1 ad 984 1.1 ad /* 985 1.1 ad * kobj_error: 986 1.1 ad * 987 1.1 ad * Utility function: log an error. 988 1.1 ad */ 989 1.1 ad static void 990 1.1 ad kobj_error(const char *fmt, ...) 991 1.1 ad { 992 1.1 ad va_list ap; 993 1.1 ad 994 1.1 ad va_start(ap, fmt); 995 1.1 ad printf("WARNING: linker error: "); 996 1.1 ad vprintf(fmt, ap); 997 1.1 ad printf("\n"); 998 1.1 ad va_end(ap); 999 1.1 ad } 1000 1.1 ad 1001 1.1 ad /* 1002 1.1 ad * kobj_read: 1003 1.1 ad * 1004 1.1 ad * Utility function: read from the object. 1005 1.1 ad */ 1006 1.1 ad static int 1007 1.3 ad kobj_read(kobj_t ko, void *base, size_t size, off_t off) 1008 1.1 ad { 1009 1.1 ad size_t resid; 1010 1.1 ad int error; 1011 1.1 ad 1012 1.3 ad KASSERT(ko->ko_source != NULL); 1013 1.3 ad 1014 1.3 ad switch (ko->ko_type) { 1015 1.3 ad case KT_VNODE: 1016 1.3 ad error = vn_rdwr(UIO_READ, ko->ko_source, base, size, off, 1017 1.3 ad UIO_SYSSPACE, IO_NODELOCKED, curlwp->l_cred, &resid, 1018 1.3 ad curlwp); 1019 1.3 ad if (error == 0 && resid != 0) { 1020 1.3 ad error = EINVAL; 1021 1.3 ad } 1022 1.3 ad break; 1023 1.3 ad case KT_MEMORY: 1024 1.4 jmcneill if (ko->ko_memsize != -1 && off + size > ko->ko_memsize) { 1025 1.3 ad kobj_error("kobj_read: preloaded object short"); 1026 1.3 ad error = EINVAL; 1027 1.3 ad } else { 1028 1.3 ad memcpy(base, (uint8_t *)ko->ko_source + off, size); 1029 1.3 ad error = 0; 1030 1.3 ad } 1031 1.3 ad break; 1032 1.3 ad default: 1033 1.3 ad panic("kobj_read: invalid type"); 1034 1.3 ad } 1035 1.3 ad 1036 1.1 ad return error; 1037 1.1 ad } 1038 1.5 ad 1039 1.5 ad #else /* MODULAR */ 1040 1.5 ad 1041 1.5 ad int 1042 1.7 ad kobj_open_file(kobj_t *kop, const char *name) 1043 1.5 ad { 1044 1.5 ad 1045 1.5 ad return ENOSYS; 1046 1.5 ad } 1047 1.5 ad 1048 1.5 ad int 1049 1.7 ad kobj_open_mem(kobj_t *kop, void *base, ssize_t size) 1050 1.5 ad { 1051 1.5 ad 1052 1.5 ad return ENOSYS; 1053 1.5 ad } 1054 1.5 ad 1055 1.5 ad void 1056 1.5 ad kobj_close(kobj_t ko) 1057 1.5 ad { 1058 1.5 ad 1059 1.5 ad panic("not modular"); 1060 1.5 ad } 1061 1.5 ad 1062 1.5 ad int 1063 1.5 ad kobj_load(kobj_t ko) 1064 1.5 ad { 1065 1.5 ad 1066 1.5 ad panic("not modular"); 1067 1.5 ad } 1068 1.5 ad 1069 1.5 ad void 1070 1.5 ad kobj_unload(kobj_t ko) 1071 1.5 ad { 1072 1.5 ad 1073 1.5 ad panic("not modular"); 1074 1.5 ad } 1075 1.5 ad 1076 1.5 ad void 1077 1.8 ad kobj_stat(kobj_t ko, vaddr_t *base, size_t *size) 1078 1.5 ad { 1079 1.5 ad 1080 1.5 ad panic("not modular"); 1081 1.5 ad } 1082 1.5 ad 1083 1.7 ad int 1084 1.5 ad kobj_set_name(kobj_t ko, const char *name) 1085 1.5 ad { 1086 1.5 ad 1087 1.5 ad panic("not modular"); 1088 1.5 ad } 1089 1.5 ad 1090 1.8 ad int 1091 1.8 ad kobj_find_section(kobj_t ko, const char *name, void **addr, size_t *size) 1092 1.8 ad { 1093 1.8 ad 1094 1.8 ad panic("not modular"); 1095 1.8 ad } 1096 1.8 ad 1097 1.5 ad #endif /* MODULAR */ 1098
Indexes created Tue Sep 30 20:09:53 GMT 2025