kern_ksyms.c revision 1.27.20.1
1 1.1 ragge /* 2 1.1 ragge * Copyright (c) 2001, 2003 Anders Magnusson (ragge (at) ludd.luth.se). 3 1.1 ragge * All rights reserved. 4 1.1 ragge * 5 1.1 ragge * Redistribution and use in source and binary forms, with or without 6 1.1 ragge * modification, are permitted provided that the following conditions 7 1.1 ragge * are met: 8 1.1 ragge * 1. Redistributions of source code must retain the above copyright 9 1.1 ragge * notice, this list of conditions and the following disclaimer. 10 1.1 ragge * 2. Redistributions in binary form must reproduce the above copyright 11 1.1 ragge * notice, this list of conditions and the following disclaimer in the 12 1.1 ragge * documentation and/or other materials provided with the distribution. 13 1.1 ragge * 3. The name of the author may not be used to endorse or promote products 14 1.1 ragge * derived from this software without specific prior written permission 15 1.1 ragge * 16 1.1 ragge * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 17 1.1 ragge * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 18 1.1 ragge * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 19 1.1 ragge * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 20 1.1 ragge * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT 21 1.1 ragge * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 22 1.1 ragge * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 23 1.1 ragge * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 24 1.1 ragge * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF 25 1.1 ragge * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 26 1.1 ragge */ 27 1.1 ragge 28 1.1 ragge /* 29 1.1 ragge * Code to deal with in-kernel symbol table management + /dev/ksyms. 30 1.1 ragge * 31 1.1 ragge * For each loaded module the symbol table info is kept track of by a 32 1.1 ragge * struct, placed in a circular list. The first entry is the kernel 33 1.1 ragge * symbol table. 34 1.1 ragge */ 35 1.1 ragge 36 1.1 ragge /* 37 1.1 ragge * TODO: 38 1.1 ragge * Change the ugly way of adding new symbols (comes with linker) 39 1.1 ragge * Add kernel locking stuff. 40 1.1 ragge * (Ev) add support for poll. 41 1.1 ragge * (Ev) fix support for mmap. 42 1.1 ragge * 43 1.1 ragge * Export ksyms internal logic for use in post-mortem debuggers? 44 1.1 ragge * Need to move struct symtab to ksyms.h for that. 45 1.1 ragge */ 46 1.11 jdolecek 47 1.11 jdolecek #include <sys/cdefs.h> 48 1.27.20.1 ad __KERNEL_RCSID(0, "$NetBSD: kern_ksyms.c,v 1.27.20.1 2006/11/18 21:39:22 ad Exp $"); 49 1.1 ragge 50 1.1 ragge #ifdef _KERNEL 51 1.1 ragge #include "opt_ddb.h" 52 1.3 ragge #include "opt_ddbparam.h" /* for SYMTAB_SPACE */ 53 1.1 ragge #endif 54 1.1 ragge 55 1.1 ragge #include <sys/param.h> 56 1.1 ragge #include <sys/errno.h> 57 1.1 ragge #include <sys/queue.h> 58 1.1 ragge #include <sys/exec.h> 59 1.1 ragge #include <sys/systm.h> 60 1.1 ragge #include <sys/conf.h> 61 1.1 ragge #include <sys/device.h> 62 1.1 ragge #include <sys/malloc.h> 63 1.1 ragge #include <sys/proc.h> 64 1.1 ragge 65 1.1 ragge #include <machine/elf_machdep.h> /* XXX */ 66 1.1 ragge #define ELFSIZE ARCH_ELFSIZE 67 1.1 ragge 68 1.1 ragge #include <sys/exec_elf.h> 69 1.1 ragge #include <sys/ksyms.h> 70 1.1 ragge 71 1.1 ragge #include <lib/libkern/libkern.h> 72 1.1 ragge 73 1.1 ragge #ifdef DDB 74 1.1 ragge #include <ddb/db_output.h> 75 1.1 ragge #endif 76 1.1 ragge 77 1.1 ragge #include "ksyms.h" 78 1.1 ragge 79 1.1 ragge static int ksymsinited = 0; 80 1.1 ragge 81 1.1 ragge #if NKSYMS 82 1.1 ragge static void ksyms_hdr_init(caddr_t hdraddr); 83 1.1 ragge static void ksyms_sizes_calc(void); 84 1.1 ragge static int ksyms_isopen; 85 1.5 ragge static int ksyms_maxlen; 86 1.1 ragge #endif 87 1.1 ragge 88 1.1 ragge #ifdef KSYMS_DEBUG 89 1.1 ragge #define FOLLOW_CALLS 1 90 1.1 ragge #define FOLLOW_MORE_CALLS 2 91 1.1 ragge #define FOLLOW_DEVKSYMS 4 92 1.1 ragge static int ksyms_debug; 93 1.1 ragge #endif 94 1.1 ragge 95 1.3 ragge #ifdef SYMTAB_SPACE 96 1.3 ragge #define SYMTAB_FILLER "|This is the symbol table!" 97 1.3 ragge 98 1.3 ragge char db_symtab[SYMTAB_SPACE] = SYMTAB_FILLER; 99 1.3 ragge int db_symtabsize = SYMTAB_SPACE; 100 1.3 ragge #endif 101 1.1 ragge 102 1.1 ragge /* 103 1.1 ragge * Store the different symbol tables in a double-linked list. 104 1.1 ragge */ 105 1.1 ragge struct symtab { 106 1.1 ragge CIRCLEQ_ENTRY(symtab) sd_queue; 107 1.9 jdolecek const char *sd_name; /* Name of this table */ 108 1.1 ragge Elf_Sym *sd_symstart; /* Address of symbol table */ 109 1.1 ragge caddr_t sd_strstart; /* Adderss of corresponding string table */ 110 1.17 cube int sd_usroffset; /* Real address for userspace */ 111 1.1 ragge int sd_symsize; /* Size in bytes of symbol table */ 112 1.1 ragge int sd_strsize; /* Size of string table */ 113 1.1 ragge int *sd_symnmoff; /* Used when calculating the name offset */ 114 1.1 ragge }; 115 1.1 ragge 116 1.1 ragge static CIRCLEQ_HEAD(, symtab) symtab_queue = 117 1.1 ragge CIRCLEQ_HEAD_INITIALIZER(symtab_queue); 118 1.1 ragge 119 1.1 ragge static struct symtab kernel_symtab; 120 1.1 ragge 121 1.8 ragge #define USE_PTREE 122 1.8 ragge #ifdef USE_PTREE 123 1.8 ragge /* 124 1.8 ragge * Patricia-tree-based lookup structure for the in-kernel global symbols. 125 1.8 ragge * Based on a design by Mikael Sundstrom, msm (at) sm.luth.se. 126 1.8 ragge */ 127 1.8 ragge struct ptree { 128 1.8 ragge int16_t bitno; 129 1.8 ragge int16_t lr[2]; 130 1.8 ragge } *symb; 131 1.8 ragge static int16_t baseidx; 132 1.8 ragge static int treex = 1; 133 1.8 ragge 134 1.8 ragge #define P_BIT(key, bit) ((key[bit >> 3] >> (bit & 7)) & 1) 135 1.8 ragge #define STRING(idx) kernel_symtab.sd_symstart[idx].st_name + \ 136 1.8 ragge kernel_symtab.sd_strstart 137 1.8 ragge 138 1.8 ragge /* 139 1.8 ragge * Walk down the tree until a terminal node is found. 140 1.8 ragge */ 141 1.8 ragge static int 142 1.24 christos symbol_traverse(const char *key) 143 1.8 ragge { 144 1.8 ragge int16_t nb, rbit = baseidx; 145 1.8 ragge 146 1.8 ragge while (rbit > 0) { 147 1.8 ragge nb = symb[rbit].bitno; 148 1.8 ragge rbit = symb[rbit].lr[P_BIT(key, nb)]; 149 1.8 ragge } 150 1.8 ragge return -rbit; 151 1.8 ragge } 152 1.8 ragge 153 1.8 ragge static int 154 1.8 ragge ptree_add(char *key, int val) 155 1.8 ragge { 156 1.8 ragge int idx; 157 1.15 christos int nix, cix, bit, rbit, sb, lastrbit, svbit = 0, ix; 158 1.8 ragge char *m, *k; 159 1.8 ragge 160 1.8 ragge if (baseidx == 0) { 161 1.8 ragge baseidx = -val; 162 1.8 ragge return 0; /* First element */ 163 1.8 ragge } 164 1.8 ragge 165 1.8 ragge /* Get string to match against */ 166 1.8 ragge idx = symbol_traverse(key); 167 1.8 ragge 168 1.8 ragge /* Find first mismatching bit */ 169 1.8 ragge m = STRING(idx); 170 1.8 ragge k = key; 171 1.8 ragge if (strcmp(m, k) == 0) 172 1.8 ragge return 1; 173 1.8 ragge 174 1.8 ragge for (cix = 0; *m && *k && *m == *k; m++, k++, cix += 8) 175 1.8 ragge ; 176 1.8 ragge ix = ffs((int)*m ^ (int)*k) - 1; 177 1.8 ragge cix += ix; 178 1.8 ragge 179 1.8 ragge /* Create new node */ 180 1.8 ragge nix = treex++; 181 1.8 ragge bit = P_BIT(key, cix); 182 1.8 ragge symb[nix].bitno = cix; 183 1.8 ragge symb[nix].lr[bit] = -val; 184 1.8 ragge 185 1.8 ragge /* Find where to insert node */ 186 1.8 ragge rbit = baseidx; 187 1.8 ragge lastrbit = 0; 188 1.8 ragge for (;;) { 189 1.8 ragge if (rbit < 0) 190 1.8 ragge break; 191 1.8 ragge sb = symb[rbit].bitno; 192 1.8 ragge if (sb > cix) 193 1.8 ragge break; 194 1.8 ragge if (sb == cix) 195 1.8 ragge printf("symb[rbit].bitno == cix!!!\n"); 196 1.8 ragge lastrbit = rbit; 197 1.8 ragge svbit = P_BIT(key, sb); 198 1.8 ragge rbit = symb[rbit].lr[svbit]; 199 1.8 ragge } 200 1.8 ragge 201 1.8 ragge /* Do the actual insertion */ 202 1.8 ragge if (lastrbit == 0) { 203 1.8 ragge /* first element */ 204 1.8 ragge symb[nix].lr[!bit] = baseidx; 205 1.8 ragge baseidx = nix; 206 1.8 ragge } else { 207 1.8 ragge symb[nix].lr[!bit] = rbit; 208 1.8 ragge symb[lastrbit].lr[svbit] = nix; 209 1.8 ragge } 210 1.8 ragge return 0; 211 1.8 ragge } 212 1.8 ragge 213 1.8 ragge static int 214 1.24 christos ptree_find(const char *key) 215 1.8 ragge { 216 1.8 ragge int idx; 217 1.8 ragge 218 1.8 ragge if (baseidx == 0) 219 1.8 ragge return 0; 220 1.8 ragge idx = symbol_traverse(key); 221 1.8 ragge 222 1.8 ragge if (strcmp(key, STRING(idx)) == 0) 223 1.8 ragge return idx; 224 1.8 ragge return 0; 225 1.8 ragge } 226 1.8 ragge 227 1.8 ragge static void 228 1.8 ragge ptree_gen(char *off, struct symtab *tab) 229 1.8 ragge { 230 1.8 ragge Elf_Sym *sym; 231 1.16 ragge int i, nsym; 232 1.8 ragge 233 1.8 ragge if (off != NULL) 234 1.8 ragge symb = (struct ptree *)ALIGN(off); 235 1.8 ragge else 236 1.8 ragge symb = malloc((tab->sd_symsize/sizeof(Elf_Sym)) * 237 1.8 ragge sizeof(struct ptree), M_DEVBUF, M_WAITOK); 238 1.8 ragge symb--; /* sym index won't be 0 */ 239 1.8 ragge 240 1.8 ragge sym = tab->sd_symstart; 241 1.16 ragge if ((nsym = tab->sd_symsize/sizeof(Elf_Sym)) > INT16_MAX) { 242 1.16 ragge printf("Too many symbols for tree, skipping %d symbols\n", 243 1.16 ragge nsym-INT16_MAX); 244 1.16 ragge nsym = INT16_MAX; 245 1.16 ragge } 246 1.16 ragge for (i = 1; i < nsym; i++) { 247 1.8 ragge if (ELF_ST_BIND(sym[i].st_info) != STB_GLOBAL) 248 1.8 ragge continue; 249 1.8 ragge ptree_add(tab->sd_strstart+sym[i].st_name, i); 250 1.8 ragge } 251 1.8 ragge } 252 1.25 thorpej #endif /* USE_PTREE */ 253 1.8 ragge 254 1.1 ragge /* 255 1.1 ragge * Finds a certain symbol name in a certain symbol table. 256 1.1 ragge */ 257 1.1 ragge static Elf_Sym * 258 1.24 christos findsym(const char *name, struct symtab *table) 259 1.1 ragge { 260 1.1 ragge Elf_Sym *start = table->sd_symstart; 261 1.1 ragge int i, sz = table->sd_symsize/sizeof(Elf_Sym); 262 1.1 ragge char *np; 263 1.22 cube caddr_t realstart = table->sd_strstart - table->sd_usroffset; 264 1.1 ragge 265 1.8 ragge #ifdef USE_PTREE 266 1.8 ragge if (table == &kernel_symtab && (i = ptree_find(name)) != 0) 267 1.8 ragge return &start[i]; 268 1.8 ragge #endif 269 1.8 ragge 270 1.1 ragge for (i = 0; i < sz; i++) { 271 1.17 cube np = realstart + start[i].st_name; 272 1.1 ragge if (name[0] == np[0] && name[1] == np[1] && 273 1.1 ragge strcmp(name, np) == 0) 274 1.1 ragge return &start[i]; 275 1.1 ragge } 276 1.1 ragge return NULL; 277 1.1 ragge } 278 1.1 ragge 279 1.1 ragge /* 280 1.1 ragge * The "attach" is in reality done in ksyms_init(). 281 1.1 ragge */ 282 1.1 ragge void ksymsattach(int); 283 1.1 ragge void 284 1.1 ragge ksymsattach(int arg) 285 1.1 ragge { 286 1.8 ragge 287 1.8 ragge #ifdef USE_PTREE 288 1.8 ragge if (baseidx == 0) 289 1.8 ragge ptree_gen(0, &kernel_symtab); 290 1.8 ragge #endif 291 1.8 ragge 292 1.1 ragge } 293 1.1 ragge 294 1.1 ragge /* 295 1.27.20.1 ad * Add a symbol table. 296 1.27.20.1 ad * This is intended for use when the symbol table and its corresponding 297 1.27.20.1 ad * string table are easily available. If they are embedded in an ELF 298 1.27.20.1 ad * image, use addsymtab_elf() instead. 299 1.27.20.1 ad * 300 1.27.20.1 ad * name - Symbol's table name. 301 1.27.20.1 ad * symstart, symsize - Address and size of the symbol table. 302 1.27.20.1 ad * strstart, strsize - Address and size of the string table. 303 1.27.20.1 ad * tab - Symbol table to be updated with this information. 304 1.27.20.1 ad * newstart - Address to which the symbol table has to be copied during 305 1.27.20.1 ad * shrinking. If NULL, it is not moved. 306 1.1 ragge */ 307 1.1 ragge static void 308 1.27.20.1 ad addsymtab(const char *name, 309 1.27.20.1 ad caddr_t symstart, size_t symsize, 310 1.27.20.1 ad caddr_t strstart, size_t strsize, 311 1.27.20.1 ad struct symtab *tab, 312 1.27.20.1 ad caddr_t newstart) 313 1.1 ragge { 314 1.8 ragge caddr_t send; 315 1.8 ragge Elf_Sym *sym, *nsym; 316 1.27.20.1 ad int i, n, g; 317 1.8 ragge char *str; 318 1.1 ragge 319 1.27.20.1 ad if (newstart == NULL) 320 1.27.20.1 ad newstart = symstart; 321 1.27.20.1 ad KASSERT(newstart <= symstart && symstart <= strstart); 322 1.27.20.1 ad 323 1.27.20.1 ad tab->sd_symstart = (Elf_Sym *)symstart; 324 1.27.20.1 ad tab->sd_symsize = symsize; 325 1.27.20.1 ad tab->sd_strstart = strstart; 326 1.27.20.1 ad tab->sd_strsize = strsize; 327 1.1 ragge tab->sd_name = name; 328 1.8 ragge send = tab->sd_strstart + tab->sd_strsize; 329 1.8 ragge 330 1.8 ragge #ifdef KSYMS_DEBUG 331 1.27.20.1 ad printf("newstart %p sym %p symsz %d str %p strsz %d send %p\n", 332 1.27.20.1 ad newstart, symstart, symsize, strstart, strsize, send); 333 1.8 ragge #endif 334 1.1 ragge 335 1.8 ragge /* 336 1.8 ragge * Pack symbol table by removing all file name references 337 1.8 ragge * and overwrite the elf header. 338 1.8 ragge */ 339 1.8 ragge sym = tab->sd_symstart; 340 1.27.20.1 ad nsym = (Elf_Sym *)newstart; 341 1.8 ragge str = tab->sd_strstart; 342 1.8 ragge for (g = i = n = 0; i < tab->sd_symsize/sizeof(Elf_Sym); i++) { 343 1.8 ragge if (i == 0) { 344 1.8 ragge nsym[n++] = sym[i]; 345 1.8 ragge continue; 346 1.8 ragge } 347 1.8 ragge /* 348 1.8 ragge * Remove useless symbols. 349 1.8 ragge * Should actually remove all typeless symbols. 350 1.8 ragge */ 351 1.5 ragge if (sym[i].st_name == 0) 352 1.8 ragge continue; /* Skip nameless entries */ 353 1.8 ragge if (ELF_ST_TYPE(sym[i].st_info) == STT_FILE) 354 1.8 ragge continue; /* Skip filenames */ 355 1.8 ragge if (ELF_ST_TYPE(sym[i].st_info) == STT_NOTYPE && 356 1.8 ragge sym[i].st_value == 0 && 357 1.8 ragge strcmp(str + sym[i].st_name, "*ABS*") == 0) 358 1.8 ragge continue; /* XXX */ 359 1.8 ragge if (ELF_ST_TYPE(sym[i].st_info) == STT_NOTYPE && 360 1.8 ragge strcmp(str + sym[i].st_name, "gcc2_compiled.") == 0) 361 1.8 ragge continue; /* XXX */ 362 1.8 ragge 363 1.8 ragge #ifndef DDB 364 1.8 ragge /* Only need global symbols */ 365 1.8 ragge if (ELF_ST_BIND(sym[i].st_info) != STB_GLOBAL) 366 1.5 ragge continue; 367 1.8 ragge #endif 368 1.8 ragge 369 1.8 ragge /* Save symbol. Set it as an absolute offset */ 370 1.8 ragge nsym[n] = sym[i]; 371 1.8 ragge nsym[n].st_shndx = SHN_ABS; 372 1.8 ragge if (ELF_ST_BIND(nsym[n].st_info) == STB_GLOBAL) 373 1.8 ragge g++; 374 1.6 tron #if NKSYMS 375 1.27.20.1 ad { 376 1.27.20.1 ad int j; 377 1.27.20.1 ad j = strlen(nsym[n].st_name + tab->sd_strstart) + 1; 378 1.27.20.1 ad if (j > ksyms_maxlen) 379 1.27.20.1 ad ksyms_maxlen = j; 380 1.27.20.1 ad } 381 1.6 tron #endif 382 1.8 ragge n++; 383 1.8 ragge 384 1.5 ragge } 385 1.8 ragge tab->sd_symstart = nsym; 386 1.8 ragge tab->sd_symsize = n * sizeof(Elf_Sym); 387 1.8 ragge 388 1.8 ragge #ifdef notyet 389 1.8 ragge /* 390 1.8 ragge * Remove left-over strings. 391 1.8 ragge */ 392 1.8 ragge sym = tab->sd_symstart; 393 1.8 ragge str = (caddr_t)tab->sd_symstart + tab->sd_symsize; 394 1.8 ragge str[0] = 0; 395 1.8 ragge n = 1; 396 1.8 ragge for (i = 1; i < tab->sd_symsize/sizeof(Elf_Sym); i++) { 397 1.10 itojun strcpy(str + n, tab->sd_strstart + sym[i].st_name); 398 1.8 ragge sym[i].st_name = n; 399 1.8 ragge n += strlen(str+n) + 1; 400 1.8 ragge } 401 1.8 ragge tab->sd_strstart = str; 402 1.8 ragge tab->sd_strsize = n; 403 1.8 ragge 404 1.8 ragge #ifdef KSYMS_DEBUG 405 1.8 ragge printf("str %p strsz %d send %p\n", str, n, send); 406 1.8 ragge #endif 407 1.8 ragge #endif 408 1.1 ragge 409 1.1 ragge CIRCLEQ_INSERT_HEAD(&symtab_queue, tab, sd_queue); 410 1.8 ragge 411 1.8 ragge #ifdef notyet 412 1.8 ragge #ifdef USE_PTREE 413 1.8 ragge /* Try to use the freed space, if possible */ 414 1.8 ragge if (send - str - n > g * sizeof(struct ptree)) 415 1.8 ragge ptree_gen(str + n, tab); 416 1.8 ragge #endif 417 1.8 ragge #endif 418 1.1 ragge } 419 1.1 ragge 420 1.1 ragge /* 421 1.27.20.1 ad * Add a symbol table named name. 422 1.27.20.1 ad * This is intended for use when the kernel loader enters the table. 423 1.27.20.1 ad */ 424 1.27.20.1 ad static void 425 1.27.20.1 ad addsymtab_elf(const char *name, Elf_Ehdr *ehdr, struct symtab *tab) 426 1.27.20.1 ad { 427 1.27.20.1 ad int i, j; 428 1.27.20.1 ad caddr_t start = (caddr_t)ehdr; 429 1.27.20.1 ad Elf_Shdr *shdr; 430 1.27.20.1 ad caddr_t symstart = NULL, strstart = NULL; 431 1.27.20.1 ad size_t symsize = 0, strsize = 0; 432 1.27.20.1 ad 433 1.27.20.1 ad /* Find the symbol table and the corresponding string table. */ 434 1.27.20.1 ad shdr = (Elf_Shdr *)(start + ehdr->e_shoff); 435 1.27.20.1 ad for (i = 1; i < ehdr->e_shnum; i++) { 436 1.27.20.1 ad if (shdr[i].sh_type != SHT_SYMTAB) 437 1.27.20.1 ad continue; 438 1.27.20.1 ad if (shdr[i].sh_offset == 0) 439 1.27.20.1 ad continue; 440 1.27.20.1 ad symstart = start + shdr[i].sh_offset; 441 1.27.20.1 ad symsize = shdr[i].sh_size; 442 1.27.20.1 ad j = shdr[i].sh_link; 443 1.27.20.1 ad if (shdr[j].sh_offset == 0) 444 1.27.20.1 ad continue; /* Can this happen? */ 445 1.27.20.1 ad strstart = start + shdr[j].sh_offset; 446 1.27.20.1 ad strsize = shdr[j].sh_size; 447 1.27.20.1 ad break; 448 1.27.20.1 ad } 449 1.27.20.1 ad 450 1.27.20.1 ad KASSERT(symstart != NULL && strstart != NULL); 451 1.27.20.1 ad 452 1.27.20.1 ad addsymtab(name, symstart, symsize, strstart, strsize, tab, start); 453 1.27.20.1 ad } 454 1.27.20.1 ad 455 1.27.20.1 ad /* 456 1.1 ragge * Setup the kernel symbol table stuff. 457 1.1 ragge */ 458 1.1 ragge void 459 1.4 ragge ksyms_init(int symsize, void *start, void *end) 460 1.1 ragge { 461 1.3 ragge Elf_Ehdr *ehdr; 462 1.3 ragge 463 1.3 ragge #ifdef SYMTAB_SPACE 464 1.3 ragge if (symsize <= 0 && 465 1.3 ragge strncmp(db_symtab, SYMTAB_FILLER, sizeof(SYMTAB_FILLER))) { 466 1.3 ragge symsize = db_symtabsize; 467 1.3 ragge start = db_symtab; 468 1.3 ragge end = db_symtab + db_symtabsize; 469 1.3 ragge } 470 1.3 ragge #endif 471 1.3 ragge if (symsize <= 0) { 472 1.3 ragge printf("[ Kernel symbol table missing! ]\n"); 473 1.3 ragge return; 474 1.3 ragge } 475 1.3 ragge 476 1.3 ragge /* Sanity check */ 477 1.3 ragge if (ALIGNED_POINTER(start, long) == 0) { 478 1.3 ragge printf("[ Kernel symbol table has bad start address %p ]\n", 479 1.3 ragge start); 480 1.3 ragge return; 481 1.3 ragge } 482 1.3 ragge 483 1.3 ragge ehdr = (Elf_Ehdr *)start; 484 1.1 ragge 485 1.1 ragge /* check if this is a valid ELF header */ 486 1.1 ragge /* No reason to verify arch type, the kernel is actually running! */ 487 1.1 ragge if (memcmp(ehdr->e_ident, ELFMAG, SELFMAG) || 488 1.1 ragge ehdr->e_ident[EI_CLASS] != ELFCLASS || 489 1.1 ragge ehdr->e_version > 1) { 490 1.3 ragge #ifdef notyet /* DDB */ 491 1.3 ragge if (ddb_init(symsize, start, end)) 492 1.3 ragge return; /* old-style symbol table */ 493 1.3 ragge #endif 494 1.3 ragge printf("[ Kernel symbol table invalid! ]\n"); 495 1.1 ragge return; /* nothing to do */ 496 1.1 ragge } 497 1.1 ragge 498 1.8 ragge #if NKSYMS 499 1.8 ragge /* Loaded header will be scratched in addsymtab */ 500 1.8 ragge ksyms_hdr_init(start); 501 1.8 ragge #endif 502 1.8 ragge 503 1.27.20.1 ad addsymtab_elf("netbsd", ehdr, &kernel_symtab); 504 1.8 ragge 505 1.1 ragge #if NKSYMS 506 1.1 ragge ksyms_sizes_calc(); 507 1.1 ragge #endif 508 1.8 ragge 509 1.1 ragge ksymsinited = 1; 510 1.8 ragge 511 1.1 ragge #ifdef DEBUG 512 1.1 ragge printf("Loaded initial symtab at %p, strtab at %p, # entries %ld\n", 513 1.1 ragge kernel_symtab.sd_symstart, kernel_symtab.sd_strstart, 514 1.2 ragge (long)kernel_symtab.sd_symsize/sizeof(Elf_Sym)); 515 1.1 ragge #endif 516 1.1 ragge } 517 1.1 ragge 518 1.1 ragge /* 519 1.27.20.1 ad * Setup the kernel symbol table stuff. 520 1.27.20.1 ad * Use this when the address of the symbol and string tables are known; 521 1.27.20.1 ad * otherwise use ksyms_init with an ELF image. 522 1.27.20.1 ad * We need to pass a minimal ELF header which will later be completed by 523 1.27.20.1 ad * ksyms_hdr_init and handed off to userland through /dev/ksyms. We use 524 1.27.20.1 ad * a caddr_t rather than a pointer to avoid exposing the Elf_Ehdr type. 525 1.27.20.1 ad */ 526 1.27.20.1 ad void 527 1.27.20.1 ad ksyms_init_explicit(caddr_t ehdr, caddr_t symstart, size_t symsize, 528 1.27.20.1 ad caddr_t strstart, size_t strsize) 529 1.27.20.1 ad { 530 1.27.20.1 ad 531 1.27.20.1 ad KASSERT(symstart != NULL); 532 1.27.20.1 ad KASSERT(strstart != NULL); 533 1.27.20.1 ad KASSERT(symstart <= strstart); 534 1.27.20.1 ad 535 1.27.20.1 ad #if NKSYMS 536 1.27.20.1 ad ksyms_hdr_init(ehdr); 537 1.27.20.1 ad #endif 538 1.27.20.1 ad 539 1.27.20.1 ad addsymtab("netbsd", symstart, symsize, strstart, strsize, 540 1.27.20.1 ad &kernel_symtab, NULL); 541 1.27.20.1 ad 542 1.27.20.1 ad #if NKSYMS 543 1.27.20.1 ad ksyms_sizes_calc(); 544 1.27.20.1 ad #endif 545 1.27.20.1 ad 546 1.27.20.1 ad ksymsinited = 1; 547 1.27.20.1 ad } 548 1.27.20.1 ad 549 1.27.20.1 ad /* 550 1.1 ragge * Get the value associated with a symbol. 551 1.23 perry * "mod" is the module name, or null if any module. 552 1.1 ragge * "sym" is the symbol name. 553 1.1 ragge * "val" is a pointer to the corresponding value, if call succeeded. 554 1.1 ragge * Returns 0 if success or ENOENT if no such entry. 555 1.1 ragge */ 556 1.1 ragge int 557 1.24 christos ksyms_getval(const char *mod, const char *sym, unsigned long *val, int type) 558 1.1 ragge { 559 1.1 ragge struct symtab *st; 560 1.1 ragge Elf_Sym *es; 561 1.1 ragge 562 1.1 ragge if (ksymsinited == 0) 563 1.1 ragge return ENOENT; 564 1.1 ragge 565 1.1 ragge #ifdef KSYMS_DEBUG 566 1.1 ragge if (ksyms_debug & FOLLOW_CALLS) 567 1.1 ragge printf("ksyms_getval: mod %s sym %s valp %p\n", mod, sym, val); 568 1.1 ragge #endif 569 1.1 ragge 570 1.1 ragge CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) { 571 1.1 ragge if (mod && strcmp(st->sd_name, mod)) 572 1.1 ragge continue; 573 1.22 cube if ((es = findsym(sym, st)) == NULL) 574 1.1 ragge continue; 575 1.1 ragge 576 1.1 ragge /* Skip if bad binding */ 577 1.1 ragge if (type == KSYMS_EXTERN && 578 1.1 ragge ELF_ST_BIND(es->st_info) != STB_GLOBAL) 579 1.1 ragge continue; 580 1.1 ragge 581 1.1 ragge if (val) 582 1.1 ragge *val = es->st_value; 583 1.1 ragge return 0; 584 1.1 ragge } 585 1.1 ragge return ENOENT; 586 1.1 ragge } 587 1.1 ragge 588 1.1 ragge /* 589 1.1 ragge * Get "mod" and "symbol" associated with an address. 590 1.1 ragge * Returns 0 if success or ENOENT if no such entry. 591 1.1 ragge */ 592 1.1 ragge int 593 1.24 christos ksyms_getname(const char **mod, const char **sym, vaddr_t v, int f) 594 1.1 ragge { 595 1.1 ragge struct symtab *st; 596 1.1 ragge Elf_Sym *les, *es = NULL; 597 1.1 ragge vaddr_t laddr = 0; 598 1.15 christos const char *lmod = NULL; 599 1.15 christos char *stable = NULL; 600 1.1 ragge int type, i, sz; 601 1.1 ragge 602 1.1 ragge if (ksymsinited == 0) 603 1.1 ragge return ENOENT; 604 1.1 ragge 605 1.1 ragge CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) { 606 1.1 ragge sz = st->sd_symsize/sizeof(Elf_Sym); 607 1.1 ragge for (i = 0; i < sz; i++) { 608 1.1 ragge les = st->sd_symstart + i; 609 1.1 ragge type = ELF_ST_TYPE(les->st_info); 610 1.1 ragge 611 1.1 ragge if ((f & KSYMS_PROC) && (type != STT_FUNC)) 612 1.1 ragge continue; 613 1.1 ragge 614 1.1 ragge if (type == STT_NOTYPE) 615 1.1 ragge continue; 616 1.1 ragge 617 1.1 ragge if (((f & KSYMS_ANY) == 0) && 618 1.1 ragge (type != STT_FUNC) && (type != STT_OBJECT)) 619 1.1 ragge continue; 620 1.1 ragge 621 1.1 ragge if ((les->st_value <= v) && (les->st_value > laddr)) { 622 1.1 ragge laddr = les->st_value; 623 1.1 ragge es = les; 624 1.1 ragge lmod = st->sd_name; 625 1.17 cube stable = st->sd_strstart - st->sd_usroffset; 626 1.1 ragge } 627 1.1 ragge } 628 1.1 ragge } 629 1.1 ragge if (es == NULL) 630 1.1 ragge return ENOENT; 631 1.1 ragge if ((f & KSYMS_EXACT) && (v != es->st_value)) 632 1.1 ragge return ENOENT; 633 1.1 ragge if (mod) 634 1.1 ragge *mod = lmod; 635 1.1 ragge if (sym) 636 1.1 ragge *sym = stable + es->st_name; 637 1.1 ragge return 0; 638 1.1 ragge } 639 1.1 ragge 640 1.1 ragge #if NKSYMS 641 1.1 ragge static int symsz, strsz; 642 1.1 ragge 643 1.22 cube /* 644 1.22 cube * In case we exposing the symbol table to the userland using the pseudo- 645 1.22 cube * device /dev/ksyms, it is easier to provide all the tables as one. 646 1.22 cube * However, it means we have to change all the st_name fields for the 647 1.22 cube * symbols so they match the ELF image that the userland will read 648 1.22 cube * through the device. 649 1.22 cube * 650 1.22 cube * The actual (correct) value of st_name is preserved through a global 651 1.22 cube * offset stored in the symbol table structure. 652 1.22 cube */ 653 1.22 cube 654 1.1 ragge static void 655 1.1 ragge ksyms_sizes_calc(void) 656 1.23 perry { 657 1.23 perry struct symtab *st; 658 1.1 ragge int i; 659 1.1 ragge 660 1.1 ragge symsz = strsz = 0; 661 1.1 ragge CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) { 662 1.1 ragge if (st != &kernel_symtab) { 663 1.1 ragge for (i = 0; i < st->sd_symsize/sizeof(Elf_Sym); i++) 664 1.1 ragge st->sd_symstart[i].st_name = 665 1.1 ragge strsz + st->sd_symnmoff[i]; 666 1.17 cube st->sd_usroffset = strsz; 667 1.1 ragge } 668 1.1 ragge symsz += st->sd_symsize; 669 1.1 ragge strsz += st->sd_strsize; 670 1.17 cube } 671 1.1 ragge } 672 1.25 thorpej #endif /* NKSYMS */ 673 1.1 ragge 674 1.1 ragge /* 675 1.20 matt * Temporary work structure for dynamic loaded symbol tables. 676 1.1 ragge * Will go away when in-kernel linker is in place. 677 1.1 ragge */ 678 1.20 matt 679 1.20 matt struct syminfo { 680 1.20 matt size_t cursyms; 681 1.20 matt size_t curnamep; 682 1.20 matt size_t maxsyms; 683 1.20 matt size_t maxnamep; 684 1.20 matt Elf_Sym *syms; 685 1.20 matt int *symnmoff; 686 1.20 matt char *symnames; 687 1.20 matt }; 688 1.23 perry 689 1.1 ragge 690 1.1 ragge /* 691 1.1 ragge * Add a symbol to the temporary save area for symbols. 692 1.1 ragge * This routine will go away when the in-kernel linker is in place. 693 1.1 ragge */ 694 1.1 ragge static void 695 1.20 matt addsym(struct syminfo *info, const Elf_Sym *sym, const char *name, 696 1.20 matt const char *mod) 697 1.1 ragge { 698 1.20 matt int len, mlen; 699 1.1 ragge 700 1.1 ragge #ifdef KSYMS_DEBUG 701 1.1 ragge if (ksyms_debug & FOLLOW_MORE_CALLS) 702 1.1 ragge printf("addsym: name %s val %lx\n", name, (long)sym->st_value); 703 1.1 ragge #endif 704 1.20 matt len = strlen(name) + 1; 705 1.20 matt if (mod) 706 1.20 matt mlen = 1 + strlen(mod); 707 1.20 matt else 708 1.20 matt mlen = 0; 709 1.23 perry if (info->cursyms == info->maxsyms || 710 1.20 matt (len + mlen + info->curnamep) > info->maxnamep) { 711 1.19 matt printf("addsym: too many symbols, skipping '%s'\n", name); 712 1.1 ragge return; 713 1.1 ragge } 714 1.20 matt strlcpy(&info->symnames[info->curnamep], name, 715 1.20 matt info->maxnamep - info->curnamep); 716 1.20 matt if (mlen) { 717 1.20 matt info->symnames[info->curnamep + len - 1] = '.'; 718 1.20 matt strlcpy(&info->symnames[info->curnamep + len], mod, 719 1.20 matt info->maxnamep - (info->curnamep + len)); 720 1.20 matt len += mlen; 721 1.20 matt } 722 1.20 matt info->syms[info->cursyms] = *sym; 723 1.20 matt info->syms[info->cursyms].st_name = info->curnamep; 724 1.20 matt info->symnmoff[info->cursyms] = info->curnamep; 725 1.20 matt info->curnamep += len; 726 1.7 ragge #if NKSYMS 727 1.5 ragge if (len > ksyms_maxlen) 728 1.5 ragge ksyms_maxlen = len; 729 1.6 tron #endif 730 1.20 matt info->cursyms++; 731 1.1 ragge } 732 1.1 ragge /* 733 1.1 ragge * Adds a symbol table. 734 1.1 ragge * "name" is the module name, "start" and "size" is where the symbol table 735 1.1 ragge * is located, and "type" is in which binary format the symbol table is. 736 1.1 ragge * New memory for keeping the symbol table is allocated in this function. 737 1.1 ragge * Returns 0 if success and EEXIST if the module name is in use. 738 1.1 ragge */ 739 1.21 matt static int 740 1.21 matt specialsym(const char *symname) 741 1.21 matt { 742 1.21 matt return !strcmp(symname, "_bss_start") || 743 1.21 matt !strcmp(symname, "__bss_start") || 744 1.21 matt !strcmp(symname, "_bss_end__") || 745 1.21 matt !strcmp(symname, "__bss_end__") || 746 1.21 matt !strcmp(symname, "_edata") || 747 1.21 matt !strcmp(symname, "_end") || 748 1.21 matt !strcmp(symname, "__end") || 749 1.21 matt !strcmp(symname, "__end__") || 750 1.21 matt !strncmp(symname, "__start_link_set_", 17) || 751 1.21 matt !strncmp(symname, "__stop_link_set_", 16); 752 1.21 matt } 753 1.21 matt 754 1.1 ragge int 755 1.9 jdolecek ksyms_addsymtab(const char *mod, void *symstart, vsize_t symsize, 756 1.1 ragge char *strstart, vsize_t strsize) 757 1.1 ragge { 758 1.1 ragge Elf_Sym *sym = symstart; 759 1.1 ragge struct symtab *st; 760 1.14 ragge unsigned long rval; 761 1.1 ragge int i; 762 1.20 matt char *name; 763 1.20 matt struct syminfo info; 764 1.1 ragge 765 1.1 ragge #ifdef KSYMS_DEBUG 766 1.1 ragge if (ksyms_debug & FOLLOW_CALLS) 767 1.1 ragge printf("ksyms_addsymtab: mod %s symsize %lx strsize %lx\n", 768 1.1 ragge mod, symsize, strsize); 769 1.1 ragge #endif 770 1.1 ragge 771 1.1 ragge #if NKSYMS 772 1.1 ragge /* 773 1.1 ragge * Do not try to add a symbol table while someone is reading 774 1.1 ragge * from /dev/ksyms. 775 1.1 ragge */ 776 1.1 ragge while (ksyms_isopen != 0) 777 1.1 ragge tsleep(&ksyms_isopen, PWAIT, "ksyms", 0); 778 1.1 ragge #endif 779 1.1 ragge 780 1.1 ragge /* Check if this symtab already loaded */ 781 1.1 ragge CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) { 782 1.1 ragge if (strcmp(mod, st->sd_name) == 0) 783 1.1 ragge return EEXIST; 784 1.1 ragge } 785 1.1 ragge 786 1.1 ragge /* 787 1.1 ragge * XXX - Only add a symbol if it do not exist already. 788 1.1 ragge * This is because of a flaw in the current LKM implementation, 789 1.20 matt * these loops will be removed once the in-kernel linker is in place. 790 1.1 ragge */ 791 1.20 matt memset(&info, 0, sizeof(info)); 792 1.1 ragge for (i = 0; i < symsize/sizeof(Elf_Sym); i++) { 793 1.20 matt char * const symname = strstart + sym[i].st_name; 794 1.1 ragge if (sym[i].st_name == 0) 795 1.1 ragge continue; /* Just ignore */ 796 1.1 ragge 797 1.1 ragge /* check validity of the symbol */ 798 1.1 ragge /* XXX - save local symbols if DDB */ 799 1.1 ragge if (ELF_ST_BIND(sym[i].st_info) != STB_GLOBAL) 800 1.1 ragge continue; 801 1.23 perry 802 1.1 ragge /* Check if the symbol exists */ 803 1.22 cube if (ksyms_getval(NULL, symname, &rval, KSYMS_EXTERN) == 0) { 804 1.1 ragge /* Check (and complain) about differing values */ 805 1.1 ragge if (sym[i].st_value != rval) { 806 1.21 matt if (specialsym(symname)) { 807 1.20 matt info.maxsyms++; 808 1.20 matt info.maxnamep += strlen(symname) + 1 + 809 1.20 matt strlen(mod) + 1; 810 1.20 matt } else { 811 1.20 matt printf("%s: symbol '%s' redeclared with" 812 1.20 matt " different value (%lx != %lx)\n", 813 1.20 matt mod, symname, 814 1.20 matt rval, (long)sym[i].st_value); 815 1.20 matt } 816 1.20 matt } 817 1.20 matt } else { 818 1.20 matt /* 819 1.20 matt * Count this symbol 820 1.20 matt */ 821 1.20 matt info.maxsyms++; 822 1.20 matt info.maxnamep += strlen(symname) + 1; 823 1.20 matt } 824 1.20 matt } 825 1.20 matt 826 1.20 matt /* 827 1.20 matt * Now that we know the sizes, malloc the structures. 828 1.20 matt */ 829 1.20 matt info.syms = malloc(sizeof(Elf_Sym)*info.maxsyms, M_DEVBUF, M_WAITOK); 830 1.20 matt info.symnames = malloc(info.maxnamep, M_DEVBUF, M_WAITOK); 831 1.20 matt info.symnmoff = malloc(sizeof(int)*info.maxsyms, M_DEVBUF, M_WAITOK); 832 1.20 matt 833 1.20 matt /* 834 1.20 matt * Now that we have the symbols, actually fill in the structures. 835 1.20 matt */ 836 1.20 matt for (i = 0; i < symsize/sizeof(Elf_Sym); i++) { 837 1.20 matt char * const symname = strstart + sym[i].st_name; 838 1.20 matt if (sym[i].st_name == 0) 839 1.20 matt continue; /* Just ignore */ 840 1.20 matt 841 1.20 matt /* check validity of the symbol */ 842 1.20 matt /* XXX - save local symbols if DDB */ 843 1.20 matt if (ELF_ST_BIND(sym[i].st_info) != STB_GLOBAL) 844 1.20 matt continue; 845 1.23 perry 846 1.20 matt /* Check if the symbol exists */ 847 1.22 cube if (ksyms_getval(NULL, symname, &rval, KSYMS_EXTERN) == 0) { 848 1.21 matt if ((sym[i].st_value != rval) && specialsym(symname)) { 849 1.20 matt addsym(&info, &sym[i], symname, mod); 850 1.1 ragge } 851 1.1 ragge } else 852 1.1 ragge /* Ok, save this symbol */ 853 1.20 matt addsym(&info, &sym[i], symname, NULL); 854 1.1 ragge } 855 1.5 ragge 856 1.1 ragge st = malloc(sizeof(struct symtab), M_DEVBUF, M_WAITOK); 857 1.10 itojun i = strlen(mod) + 1; 858 1.10 itojun name = malloc(i, M_DEVBUF, M_WAITOK); 859 1.10 itojun strlcpy(name, mod, i); 860 1.9 jdolecek st->sd_name = name; 861 1.20 matt st->sd_symnmoff = info.symnmoff; 862 1.20 matt st->sd_symstart = info.syms; 863 1.20 matt st->sd_symsize = sizeof(Elf_Sym)*info.maxsyms; 864 1.20 matt st->sd_strstart = info.symnames; 865 1.20 matt st->sd_strsize = info.maxnamep; 866 1.1 ragge 867 1.1 ragge /* Make them absolute references */ 868 1.1 ragge sym = st->sd_symstart; 869 1.1 ragge for (i = 0; i < st->sd_symsize/sizeof(Elf_Sym); i++) 870 1.1 ragge sym[i].st_shndx = SHN_ABS; 871 1.1 ragge 872 1.1 ragge CIRCLEQ_INSERT_TAIL(&symtab_queue, st, sd_queue); 873 1.1 ragge #if NKSYMS 874 1.1 ragge ksyms_sizes_calc(); 875 1.1 ragge #endif 876 1.1 ragge return 0; 877 1.1 ragge } 878 1.1 ragge 879 1.1 ragge /* 880 1.1 ragge * Remove a symbol table specified by name. 881 1.1 ragge * Returns 0 if success, EBUSY if device open and ENOENT if no such name. 882 1.1 ragge */ 883 1.1 ragge int 884 1.9 jdolecek ksyms_delsymtab(const char *mod) 885 1.1 ragge { 886 1.1 ragge struct symtab *st; 887 1.1 ragge int found = 0; 888 1.1 ragge 889 1.1 ragge #if NKSYMS 890 1.1 ragge /* 891 1.1 ragge * Do not try to delete a symbol table while someone is reading 892 1.1 ragge * from /dev/ksyms. 893 1.1 ragge */ 894 1.1 ragge while (ksyms_isopen != 0) 895 1.1 ragge tsleep(&ksyms_isopen, PWAIT, "ksyms", 0); 896 1.1 ragge #endif 897 1.1 ragge 898 1.1 ragge CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) { 899 1.1 ragge if (strcmp(mod, st->sd_name) == 0) { 900 1.1 ragge found = 1; 901 1.1 ragge break; 902 1.1 ragge } 903 1.1 ragge } 904 1.1 ragge if (found == 0) 905 1.1 ragge return ENOENT; 906 1.1 ragge CIRCLEQ_REMOVE(&symtab_queue, st, sd_queue); 907 1.1 ragge free(st->sd_symstart, M_DEVBUF); 908 1.1 ragge free(st->sd_strstart, M_DEVBUF); 909 1.1 ragge free(st->sd_symnmoff, M_DEVBUF); 910 1.24 christos /* XXXUNCONST LINTED - const castaway */ 911 1.24 christos free(__UNCONST(st->sd_name), M_DEVBUF); 912 1.1 ragge free(st, M_DEVBUF); 913 1.1 ragge #if NKSYMS 914 1.1 ragge ksyms_sizes_calc(); 915 1.1 ragge #endif 916 1.1 ragge return 0; 917 1.1 ragge } 918 1.1 ragge 919 1.17 cube int 920 1.17 cube ksyms_rensymtab(const char *old, const char *new) 921 1.17 cube { 922 1.17 cube struct symtab *st, *oldst = NULL; 923 1.17 cube char *newstr; 924 1.17 cube 925 1.17 cube CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) { 926 1.17 cube if (strcmp(old, st->sd_name) == 0) 927 1.17 cube oldst = st; 928 1.17 cube if (strcmp(new, st->sd_name) == 0) 929 1.17 cube return (EEXIST); 930 1.17 cube } 931 1.17 cube if (oldst == NULL) 932 1.17 cube return (ENOENT); 933 1.17 cube 934 1.17 cube newstr = malloc(strlen(new)+1, M_DEVBUF, M_WAITOK); 935 1.17 cube if (!newstr) 936 1.17 cube return (ENOMEM); 937 1.17 cube strcpy(newstr, new); 938 1.24 christos /*XXXUNCONST*/ 939 1.24 christos free(__UNCONST(oldst->sd_name), M_DEVBUF); 940 1.17 cube oldst->sd_name = newstr; 941 1.17 cube 942 1.17 cube return (0); 943 1.17 cube } 944 1.17 cube 945 1.1 ragge #ifdef DDB 946 1.1 ragge /* 947 1.1 ragge * Keep sifting stuff here, to avoid export of ksyms internals. 948 1.1 ragge */ 949 1.1 ragge int 950 1.1 ragge ksyms_sift(char *mod, char *sym, int mode) 951 1.1 ragge { 952 1.1 ragge struct symtab *st; 953 1.1 ragge char *sb; 954 1.1 ragge int i, sz; 955 1.1 ragge 956 1.1 ragge if (ksymsinited == 0) 957 1.1 ragge return ENOENT; 958 1.1 ragge 959 1.1 ragge CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) { 960 1.1 ragge if (mod && strcmp(mod, st->sd_name)) 961 1.1 ragge continue; 962 1.1 ragge sb = st->sd_strstart; 963 1.1 ragge 964 1.1 ragge sz = st->sd_symsize/sizeof(Elf_Sym); 965 1.1 ragge for (i = 0; i < sz; i++) { 966 1.1 ragge Elf_Sym *les = st->sd_symstart + i; 967 1.1 ragge char c; 968 1.1 ragge 969 1.17 cube if (strstr(sb + les->st_name - st->sd_usroffset, sym) 970 1.17 cube == NULL) 971 1.1 ragge continue; 972 1.1 ragge 973 1.1 ragge if (mode == 'F') { 974 1.1 ragge switch (ELF_ST_TYPE(les->st_info)) { 975 1.1 ragge case STT_OBJECT: 976 1.1 ragge c = '+'; 977 1.1 ragge break; 978 1.1 ragge case STT_FUNC: 979 1.1 ragge c = '*'; 980 1.1 ragge break; 981 1.1 ragge case STT_SECTION: 982 1.1 ragge c = '&'; 983 1.1 ragge break; 984 1.1 ragge case STT_FILE: 985 1.1 ragge c = '/'; 986 1.1 ragge break; 987 1.1 ragge default: 988 1.1 ragge c = ' '; 989 1.1 ragge break; 990 1.1 ragge } 991 1.17 cube db_printf("%s%c ", sb + les->st_name - 992 1.17 cube st->sd_usroffset, c); 993 1.1 ragge } else 994 1.17 cube db_printf("%s ", sb + les->st_name - 995 1.17 cube st->sd_usroffset); 996 1.1 ragge } 997 1.1 ragge } 998 1.1 ragge return ENOENT; 999 1.1 ragge } 1000 1.25 thorpej #endif /* DDB */ 1001 1.1 ragge 1002 1.1 ragge #if NKSYMS 1003 1.1 ragge /* 1004 1.1 ragge * Static allocated ELF header. 1005 1.1 ragge * Basic info is filled in at attach, sizes at open. 1006 1.1 ragge */ 1007 1.1 ragge #define SYMTAB 1 1008 1.1 ragge #define STRTAB 2 1009 1.1 ragge #define SHSTRTAB 3 1010 1.1 ragge #define NSECHDR 4 1011 1.1 ragge 1012 1.1 ragge #define NPRGHDR 2 1013 1.1 ragge #define SHSTRSIZ 28 1014 1.1 ragge 1015 1.1 ragge static struct ksyms_hdr { 1016 1.1 ragge Elf_Ehdr kh_ehdr; 1017 1.1 ragge Elf_Phdr kh_phdr[NPRGHDR]; 1018 1.1 ragge Elf_Shdr kh_shdr[NSECHDR]; 1019 1.1 ragge char kh_strtab[SHSTRSIZ]; 1020 1.1 ragge } ksyms_hdr; 1021 1.1 ragge 1022 1.1 ragge 1023 1.25 thorpej static void 1024 1.1 ragge ksyms_hdr_init(caddr_t hdraddr) 1025 1.1 ragge { 1026 1.1 ragge 1027 1.1 ragge /* Copy the loaded elf exec header */ 1028 1.1 ragge memcpy(&ksyms_hdr.kh_ehdr, hdraddr, sizeof(Elf_Ehdr)); 1029 1.1 ragge 1030 1.1 ragge /* Set correct program/section header sizes, offsets and numbers */ 1031 1.1 ragge ksyms_hdr.kh_ehdr.e_phoff = offsetof(struct ksyms_hdr, kh_phdr[0]); 1032 1.1 ragge ksyms_hdr.kh_ehdr.e_phentsize = sizeof(Elf_Phdr); 1033 1.1 ragge ksyms_hdr.kh_ehdr.e_phnum = NPRGHDR; 1034 1.1 ragge ksyms_hdr.kh_ehdr.e_shoff = offsetof(struct ksyms_hdr, kh_shdr[0]); 1035 1.1 ragge ksyms_hdr.kh_ehdr.e_shentsize = sizeof(Elf_Shdr); 1036 1.1 ragge ksyms_hdr.kh_ehdr.e_shnum = NSECHDR; 1037 1.1 ragge ksyms_hdr.kh_ehdr.e_shstrndx = NSECHDR - 1; /* Last section */ 1038 1.1 ragge 1039 1.1 ragge /* 1040 1.1 ragge * Keep program headers zeroed (unused). 1041 1.1 ragge * The section headers are hand-crafted. 1042 1.1 ragge * First section is section zero. 1043 1.1 ragge */ 1044 1.1 ragge 1045 1.1 ragge /* Second section header; ".symtab" */ 1046 1.1 ragge ksyms_hdr.kh_shdr[SYMTAB].sh_name = 1; /* Section 3 offset */ 1047 1.1 ragge ksyms_hdr.kh_shdr[SYMTAB].sh_type = SHT_SYMTAB; 1048 1.1 ragge ksyms_hdr.kh_shdr[SYMTAB].sh_offset = sizeof(struct ksyms_hdr); 1049 1.1 ragge /* ksyms_hdr.kh_shdr[SYMTAB].sh_size = filled in at open */ 1050 1.1 ragge ksyms_hdr.kh_shdr[SYMTAB].sh_link = 2; /* Corresponding strtab */ 1051 1.1 ragge ksyms_hdr.kh_shdr[SYMTAB].sh_info = 0; /* XXX */ 1052 1.1 ragge ksyms_hdr.kh_shdr[SYMTAB].sh_addralign = sizeof(long); 1053 1.1 ragge ksyms_hdr.kh_shdr[SYMTAB].sh_entsize = sizeof(Elf_Sym); 1054 1.1 ragge 1055 1.1 ragge /* Third section header; ".strtab" */ 1056 1.1 ragge ksyms_hdr.kh_shdr[STRTAB].sh_name = 9; /* Section 3 offset */ 1057 1.1 ragge ksyms_hdr.kh_shdr[STRTAB].sh_type = SHT_STRTAB; 1058 1.1 ragge /* ksyms_hdr.kh_shdr[STRTAB].sh_offset = filled in at open */ 1059 1.1 ragge /* ksyms_hdr.kh_shdr[STRTAB].sh_size = filled in at open */ 1060 1.1 ragge /* ksyms_hdr.kh_shdr[STRTAB].sh_link = kept zero */ 1061 1.1 ragge ksyms_hdr.kh_shdr[STRTAB].sh_info = 0; 1062 1.1 ragge ksyms_hdr.kh_shdr[STRTAB].sh_addralign = sizeof(char); 1063 1.1 ragge ksyms_hdr.kh_shdr[STRTAB].sh_entsize = 0; 1064 1.1 ragge 1065 1.1 ragge /* Fourth section, ".shstrtab" */ 1066 1.1 ragge ksyms_hdr.kh_shdr[SHSTRTAB].sh_name = 17; /* This section name offset */ 1067 1.1 ragge ksyms_hdr.kh_shdr[SHSTRTAB].sh_type = SHT_STRTAB; 1068 1.1 ragge ksyms_hdr.kh_shdr[SHSTRTAB].sh_offset = 1069 1.1 ragge offsetof(struct ksyms_hdr, kh_strtab); 1070 1.1 ragge ksyms_hdr.kh_shdr[SHSTRTAB].sh_size = SHSTRSIZ; 1071 1.1 ragge ksyms_hdr.kh_shdr[SHSTRTAB].sh_addralign = sizeof(char); 1072 1.1 ragge 1073 1.1 ragge /* Set section names */ 1074 1.10 itojun strlcpy(&ksyms_hdr.kh_strtab[1], ".symtab", 1075 1.10 itojun sizeof(ksyms_hdr.kh_strtab) - 1); 1076 1.10 itojun strlcpy(&ksyms_hdr.kh_strtab[9], ".strtab", 1077 1.10 itojun sizeof(ksyms_hdr.kh_strtab) - 9); 1078 1.10 itojun strlcpy(&ksyms_hdr.kh_strtab[17], ".shstrtab", 1079 1.10 itojun sizeof(ksyms_hdr.kh_strtab) - 17); 1080 1.1 ragge }; 1081 1.1 ragge 1082 1.25 thorpej static int 1083 1.27 christos ksymsopen(dev_t dev, int oflags, int devtype, struct lwp *l) 1084 1.1 ragge { 1085 1.1 ragge 1086 1.1 ragge if (minor(dev)) 1087 1.1 ragge return ENXIO; 1088 1.18 cube if (ksymsinited == 0) 1089 1.18 cube return ENXIO; 1090 1.1 ragge 1091 1.1 ragge ksyms_hdr.kh_shdr[SYMTAB].sh_size = symsz; 1092 1.1 ragge ksyms_hdr.kh_shdr[STRTAB].sh_offset = symsz + 1093 1.1 ragge ksyms_hdr.kh_shdr[SYMTAB].sh_offset; 1094 1.1 ragge ksyms_hdr.kh_shdr[STRTAB].sh_size = strsz; 1095 1.1 ragge ksyms_isopen = 1; 1096 1.1 ragge 1097 1.1 ragge #ifdef KSYMS_DEBUG 1098 1.1 ragge if (ksyms_debug & FOLLOW_DEVKSYMS) 1099 1.1 ragge printf("ksymsopen: symsz 0x%x strsz 0x%x\n", symsz, strsz); 1100 1.1 ragge #endif 1101 1.1 ragge 1102 1.1 ragge return 0; 1103 1.1 ragge } 1104 1.1 ragge 1105 1.25 thorpej static int 1106 1.27 christos ksymsclose(dev_t dev, int oflags, int devtype, struct lwp *l) 1107 1.1 ragge { 1108 1.1 ragge 1109 1.1 ragge #ifdef KSYMS_DEBUG 1110 1.1 ragge if (ksyms_debug & FOLLOW_DEVKSYMS) 1111 1.1 ragge printf("ksymsclose\n"); 1112 1.1 ragge #endif 1113 1.1 ragge 1114 1.1 ragge ksyms_isopen = 0; 1115 1.1 ragge wakeup(&ksyms_isopen); 1116 1.1 ragge return 0; 1117 1.1 ragge } 1118 1.1 ragge 1119 1.1 ragge #define HDRSIZ sizeof(struct ksyms_hdr) 1120 1.1 ragge 1121 1.25 thorpej static int 1122 1.1 ragge ksymsread(dev_t dev, struct uio *uio, int ioflag) 1123 1.1 ragge { 1124 1.1 ragge struct symtab *st; 1125 1.1 ragge size_t filepos, inpos, off; 1126 1.1 ragge 1127 1.1 ragge #ifdef KSYMS_DEBUG 1128 1.1 ragge if (ksyms_debug & FOLLOW_DEVKSYMS) 1129 1.26 riz printf("ksymsread: offset 0x%llx resid 0x%zx\n", 1130 1.1 ragge (long long)uio->uio_offset, uio->uio_resid); 1131 1.1 ragge #endif 1132 1.1 ragge 1133 1.1 ragge off = uio->uio_offset; 1134 1.1 ragge if (off >= (strsz + symsz + HDRSIZ)) 1135 1.1 ragge return 0; /* End of symtab */ 1136 1.1 ragge /* 1137 1.1 ragge * First: Copy out the ELF header. 1138 1.1 ragge */ 1139 1.1 ragge if (off < HDRSIZ) 1140 1.1 ragge uiomove((char *)&ksyms_hdr + off, HDRSIZ - off, uio); 1141 1.1 ragge 1142 1.1 ragge /* 1143 1.1 ragge * Copy out the symbol table. 1144 1.1 ragge */ 1145 1.1 ragge filepos = HDRSIZ; 1146 1.1 ragge CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) { 1147 1.1 ragge if (uio->uio_resid == 0) 1148 1.1 ragge return 0; 1149 1.1 ragge if (uio->uio_offset <= st->sd_symsize + filepos) { 1150 1.1 ragge inpos = uio->uio_offset - filepos; 1151 1.1 ragge uiomove((char *)st->sd_symstart + inpos, 1152 1.1 ragge st->sd_symsize - inpos, uio); 1153 1.1 ragge } 1154 1.1 ragge filepos += st->sd_symsize; 1155 1.1 ragge } 1156 1.1 ragge 1157 1.1 ragge if (filepos != HDRSIZ + symsz) 1158 1.1 ragge panic("ksymsread: unsunc"); 1159 1.1 ragge 1160 1.1 ragge /* 1161 1.1 ragge * Copy out the string table 1162 1.1 ragge */ 1163 1.1 ragge CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) { 1164 1.1 ragge if (uio->uio_resid == 0) 1165 1.1 ragge return 0; 1166 1.1 ragge if (uio->uio_offset <= st->sd_strsize + filepos) { 1167 1.1 ragge inpos = uio->uio_offset - filepos; 1168 1.1 ragge uiomove((char *)st->sd_strstart + inpos, 1169 1.1 ragge st->sd_strsize - inpos, uio); 1170 1.1 ragge } 1171 1.1 ragge filepos += st->sd_strsize; 1172 1.1 ragge } 1173 1.1 ragge return 0; 1174 1.1 ragge } 1175 1.1 ragge 1176 1.25 thorpej static int 1177 1.1 ragge ksymswrite(dev_t dev, struct uio *uio, int ioflag) 1178 1.1 ragge { 1179 1.27.20.1 ad 1180 1.1 ragge return EROFS; 1181 1.1 ragge } 1182 1.1 ragge 1183 1.25 thorpej static int 1184 1.27 christos ksymsioctl(dev_t dev, u_long cmd, caddr_t data, int fflag, struct lwp *l) 1185 1.1 ragge { 1186 1.1 ragge struct ksyms_gsymbol *kg = (struct ksyms_gsymbol *)data; 1187 1.1 ragge struct symtab *st; 1188 1.15 christos Elf_Sym *sym = NULL; 1189 1.1 ragge unsigned long val; 1190 1.1 ragge int error = 0; 1191 1.15 christos char *str = NULL; 1192 1.5 ragge 1193 1.5 ragge if (cmd == KIOCGVALUE || cmd == KIOCGSYMBOL) 1194 1.5 ragge str = malloc(ksyms_maxlen, M_DEVBUF, M_WAITOK); 1195 1.1 ragge 1196 1.1 ragge switch (cmd) { 1197 1.1 ragge case KIOCGVALUE: 1198 1.1 ragge /* 1199 1.1 ragge * Use the in-kernel symbol lookup code for fast 1200 1.1 ragge * retreival of a value. 1201 1.1 ragge */ 1202 1.5 ragge if ((error = copyinstr(kg->kg_name, str, ksyms_maxlen, NULL))) 1203 1.1 ragge break; 1204 1.22 cube if ((error = ksyms_getval(NULL, str, &val, KSYMS_EXTERN))) 1205 1.1 ragge break; 1206 1.1 ragge error = copyout(&val, kg->kg_value, sizeof(long)); 1207 1.1 ragge break; 1208 1.1 ragge 1209 1.1 ragge case KIOCGSYMBOL: 1210 1.1 ragge /* 1211 1.1 ragge * Use the in-kernel symbol lookup code for fast 1212 1.1 ragge * retreival of a symbol. 1213 1.1 ragge */ 1214 1.5 ragge if ((error = copyinstr(kg->kg_name, str, ksyms_maxlen, NULL))) 1215 1.1 ragge break; 1216 1.1 ragge CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) { 1217 1.22 cube if ((sym = findsym(str, st)) == NULL) /* from userland */ 1218 1.1 ragge continue; 1219 1.1 ragge 1220 1.1 ragge /* Skip if bad binding */ 1221 1.1 ragge if (ELF_ST_BIND(sym->st_info) != STB_GLOBAL) { 1222 1.1 ragge sym = NULL; 1223 1.1 ragge continue; 1224 1.1 ragge } 1225 1.1 ragge break; 1226 1.1 ragge } 1227 1.22 cube /* 1228 1.22 cube * XXX which value of sym->st_name should be returned? The real 1229 1.22 cube * one, or the one that matches what reading /dev/ksyms get? 1230 1.22 cube * 1231 1.22 cube * Currently, we're returning the /dev/ksyms one. 1232 1.22 cube */ 1233 1.1 ragge if (sym != NULL) 1234 1.1 ragge error = copyout(sym, kg->kg_sym, sizeof(Elf_Sym)); 1235 1.1 ragge else 1236 1.1 ragge error = ENOENT; 1237 1.1 ragge break; 1238 1.1 ragge 1239 1.1 ragge case KIOCGSIZE: 1240 1.1 ragge /* 1241 1.1 ragge * Get total size of symbol table. 1242 1.1 ragge */ 1243 1.1 ragge *(int *)data = strsz + symsz + HDRSIZ; 1244 1.1 ragge break; 1245 1.1 ragge 1246 1.1 ragge default: 1247 1.1 ragge error = ENOTTY; 1248 1.1 ragge break; 1249 1.1 ragge } 1250 1.5 ragge 1251 1.5 ragge if (cmd == KIOCGVALUE || cmd == KIOCGSYMBOL) 1252 1.5 ragge free(str, M_DEVBUF); 1253 1.5 ragge 1254 1.5 ragge return error; 1255 1.1 ragge } 1256 1.25 thorpej 1257 1.25 thorpej const struct cdevsw ksyms_cdevsw = { 1258 1.25 thorpej ksymsopen, ksymsclose, ksymsread, ksymswrite, ksymsioctl, 1259 1.25 thorpej nullstop, notty, nopoll, nommap, nullkqfilter, DV_DULL 1260 1.25 thorpej }; 1261 1.25 thorpej #endif /* NKSYMS */ 1262
Indexes created Sat Oct 11 16:09:52 GMT 2025