/* $OpenBSD: modload.c,v 1.11 1997/01/18 15:12:44 mickey Exp $ */ /* $NetBSD: modload.c,v 1.13 1995/05/28 05:21:58 jtc Exp $ */ /* * Copyright (c) 1993 Terrence R. Lambert. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by Terrence R. Lambert. * 4. The name Terrence R. Lambert may not be used to endorse or promote * products derived from this software without specific prior written * permission. * * THIS SOFTWARE IS PROVIDED BY TERRENCE R. LAMBERT ``AS IS'' AND ANY * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE TERRENCE R. LAMBERT BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "pathnames.h" #define min(a, b) ((a) < (b) ? (a) : (b)) /* * Expected linker options: * * -A executable to link against * -e entry point * -o output file * -T address to link to in hex (assumes it's a page boundry) * object file */ int debug = 0; int verbose = 0; int symtab = 1; int quiet = 0; int dounlink = 0; void linkcmd(kernel, entry, outfile, address, object) char *kernel, *entry, *outfile; u_int address; /* XXX */ char *object; { char addrbuf[32], entrybuf[_POSIX2_LINE_MAX]; pid_t pid; int status; snprintf(entrybuf, sizeof entrybuf, "_%s", entry); snprintf(addrbuf, sizeof addrbuf, "%x", address); if (debug) printf("%s -A %s -e %s -o %s -T %s %s\n", _PATH_LD, kernel, entrybuf, outfile, addrbuf, object); if ((pid = fork()) < 0) err(18, "fork"); if(pid == 0) { execl(_PATH_LD, "ld", "-A", kernel, "-e", entrybuf, "-o", outfile, "-T", addrbuf, object, (char *)0); exit(128 + errno); } waitpid(pid, &status, 0); if(WIFSIGNALED(status)) { errx(1, "%s got signal: %s", _PATH_LD, sys_siglist[WTERMSIG(status)]); } if(WEXITSTATUS(status) > 128) { errno = WEXITSTATUS(status) - 128; err(1, "exec(%s)", _PATH_LD); } if(WEXITSTATUS(status) != 0) errx(1, "%s: return code %d", _PATH_LD, WEXITSTATUS(status)); } void usage() { fprintf(stderr, "usage: modload [-dvqu] [-A ] [-e ] [-o ] \n"); exit(1); } int fileopen = 0; #define DEV_OPEN 0x01 #define MOD_OPEN 0x02 #define PART_RESRV 0x04 int devfd, modfd; struct lmc_resrv resrv; char modout[80]; void cleanup() { if (fileopen & PART_RESRV) { /* * Free up kernel memory */ if (ioctl(devfd, LMUNRESRV, 0) == -1) warn("can't release slot 0x%08x memory", resrv.slot); } if (fileopen & DEV_OPEN) close(devfd); if (fileopen & MOD_OPEN) close(modfd); if(dounlink && unlink(modout) != 0) err(17, "unlink(%s)", modout); } int main(argc, argv) int argc; char *argv[]; { int c; char *kname = _PATH_UNIX; char *entry = NULL; char *post = NULL; char *out = NULL; char *modobj; char *p; struct exec info_buf; struct stat stb; u_int modsize; /* XXX */ u_int modentry; /* XXX */ struct nlist nl, *nlp; int strtablen, numsyms; struct lmc_loadbuf ldbuf; int sz, bytesleft, old = 0; char buf[MODIOBUF]; char *symbuf; while ((c = getopt(argc, argv, "dvsuqA:e:p:o:")) != -1) { switch (c) { case 'd': debug = 1; break; /* debug */ case 'v': verbose = 1; break; /* verbose */ case 'u': dounlink = 1; break; /* unlink tmp file */ case 'q': quiet = 1; break; /* be quiet */ case 'A': kname = optarg; break; /* kernel */ case 'e': entry = optarg; break; /* entry point */ case 'p': post = optarg; break; /* postinstall */ case 'o': out = optarg; break; /* output file */ case 's': symtab = 0; break; case '?': usage(); default: printf("default!\n"); break; } } argc -= optind; argv += optind; if (argc != 1) usage(); modobj = argv[0]; atexit(cleanup); /* * Open the virtual device device driver for exclusive use (needed * to write the new module to it as our means of getting it in the * kernel). */ if ((devfd = open(_PATH_LKM, O_RDWR, 0)) == -1) err(3, _PATH_LKM); fileopen |= DEV_OPEN; p = strrchr(modobj, '.'); if (!p || p[1] != 'o' || p[2] != '\0') errx(2, "module object must end in .o"); if (out == NULL) { p = strrchr(modobj, '/'); if (p) p++; /* skip over '/' */ else p = modobj; snprintf(modout, sizeof modout, "%s%sut", _PATH_TMP, p); out = modout; /* * reverse meaning of -u - if we've generated a /tmp * file, remove it automatically... */ dounlink = !dounlink; } if (!entry) { /* calculate default entry point */ entry = strrchr(modobj, '/'); if (entry) entry++; /* skip over '/' */ else entry = modobj; entry = strdup(entry); /* so we can modify it */ if (!entry) errx(1, "Could not allocate memory"); entry[strlen(entry) - 2] = '\0'; /* chop off .o */ } if((modfd = open(out, O_RDWR | O_EXCL | O_CREAT, 0666)) < 0) err(1, "creating %s", out); close(modfd); /* * Prelink to get file size */ linkcmd(kname, entry, out, 0, modobj); /* * Pre-open the 0-linked module to get the size information */ if ((modfd = open(out, O_RDONLY, 0)) == -1) err(4, out); fileopen |= MOD_OPEN; /* * Get the load module post load size... do this by reading the * header and doing page counts. */ if (read(modfd, &info_buf, sizeof(struct exec)) == -1) err(3, "read `%s'", out); /* * stat for filesize to figure out string table size */ if (fstat(modfd, &stb) == -1) err(3, "fstat `%s'", out); /* * Close the dummy module -- we have our sizing information. */ close(modfd); fileopen &= ~MOD_OPEN; /* * Magic number... */ if (N_BADMAG(info_buf)) errx(4, "not an a.out format file"); /* * Calculate the size of the module */ modsize = info_buf.a_text + info_buf.a_data + info_buf.a_bss; /* * Reserve the required amount of kernel memory -- this may fail * to be successful. */ resrv.size = modsize; /* size in bytes */ resrv.name = modout; /* objname w/o ".o" */ resrv.slot = -1; /* returned */ resrv.addr = 0; /* returned */ strtablen = stb.st_size - N_STROFF(info_buf); if (symtab) { /* XXX TODO: grovel through symbol table looking for just the symbol table stuff from the new module, and skip the stuff from the kernel. */ resrv.sym_size = info_buf.a_syms + strtablen; resrv.sym_symsize = info_buf.a_syms; } else resrv.sym_size = resrv.sym_symsize = 0; if (ioctl(devfd, LMRESERV, &resrv) == -1) { if (symtab) warn("not loading symbols: kernel does not support symbol table loading"); doold: symtab = 0; if (ioctl(devfd, LMRESERV_O, &resrv) == -1) err(9, "can't reserve memory"); old = 1; } fileopen |= PART_RESRV; /* * Relink at kernel load address */ linkcmd(kname, entry, out, resrv.addr, modobj); /* * Open the relinked module to load it... */ if ((modfd = open(out, O_RDONLY, 0)) == -1) err(4, out); fileopen |= MOD_OPEN; /* * Reread the header to get the actual entry point *after* the * relink. */ if (read(modfd, &info_buf, sizeof(struct exec)) == -1) err(3, "read `%s'", out); /* * Get the entry point (for initialization) */ modentry = info_buf.a_entry; /* place to call */ /* * Seek to the text offset to start loading... */ if (lseek(modfd, N_TXTOFF(info_buf), 0) == -1) err(12, "lseek"); /* * Transfer the relinked module to kernel memory in chunks of * MODIOBUF size at a time. */ for (bytesleft = info_buf.a_text + info_buf.a_data; bytesleft > 0; bytesleft -= sz) { sz = min(bytesleft, MODIOBUF); read(modfd, buf, sz); ldbuf.cnt = sz; ldbuf.data = buf; if (ioctl(devfd, LMLOADBUF, &ldbuf) == -1) err(11, "error transferring buffer"); } if (symtab) { /* * Seek to the symbol table to start loading it... */ if (lseek(modfd, N_SYMOFF(info_buf), SEEK_SET) == -1) err(12, "lseek"); /* * Transfer the symbol table entries. First, read them all in, * then adjust their string table pointers, then * copy in bulk. Then copy the string table itself. */ symbuf = malloc(info_buf.a_syms); if (symbuf == 0) err(13, "malloc"); if (read(modfd, symbuf, info_buf.a_syms) != info_buf.a_syms) err(14, "read"); numsyms = info_buf.a_syms / sizeof(struct nlist); for (nlp = (struct nlist *)symbuf; (char *)nlp < symbuf + info_buf.a_syms; nlp++) { register int strx; strx = nlp->n_un.n_strx; if (strx != 0) { /* If a valid name, set the name ptr to point at the * loaded address for the string in the string table. */ if (strx > strtablen) nlp->n_un.n_name = 0; else nlp->n_un.n_name = (char *)(strx + resrv.sym_addr + info_buf.a_syms); } } /* * we've fixed the symbol table entries, now load them */ for (bytesleft = info_buf.a_syms; bytesleft > 0; bytesleft -= sz) { sz = min(bytesleft, MODIOBUF); ldbuf.cnt = sz; ldbuf.data = symbuf; if (ioctl(devfd, LMLOADSYMS, &ldbuf) == -1) err(11, "error transferring sym buffer"); symbuf += sz; } free(symbuf - info_buf.a_syms); /* and now read the string table and load it. */ for (bytesleft = strtablen; bytesleft > 0; bytesleft -= sz) { sz = min(bytesleft, MODIOBUF); read(modfd, buf, sz); ldbuf.cnt = sz; ldbuf.data = buf; if (ioctl(devfd, LMLOADSYMS, &ldbuf) == -1) err(11, "error transferring stringtable buffer"); } } /* * Save ourselves before disaster (potentitally) strikes... */ sync(); /* * Trigger the module as loaded by calling the entry procedure; * this will do all necessary table fixup to ensure that state * is maintained on success, or blow everything back to ground * zero on failure. */ if (ioctl(devfd, LMREADY, &modentry) == -1) { if (errno == EINVAL && !old) { if (fileopen & MOD_OPEN) close(modfd); /* PART_RESRV is not true since the kernel cleans up after a failed LMREADY */ fileopen &= ~(MOD_OPEN|PART_RESRV); /* try using oldstyle */ warn("module failed to load using new version; trying old version"); goto doold; } else err(14, "error initializing module"); } /* * Success! */ fileopen &= ~PART_RESRV; /* loaded */ if (!quiet) printf("Module loaded as ID %d\n", resrv.slot); /* * Execute the post-install program, if specified. */ if (post) { struct lmc_stat sbuf; char name[MAXLKMNAME] = ""; char id[16], type[16], offset[16]; sbuf.id = resrv.slot; sbuf.name = name; if (ioctl(devfd, LMSTAT, &sbuf) == -1) err(15, "error fetching module stats for post-install"); sprintf(id, "%d", sbuf.id); sprintf(type, "0x%x", sbuf.type); sprintf(offset, "%d", sbuf.offset); /* * XXX * The modload docs say that drivers can install bdevsw & * cdevsw, but the interface only supports one at a time. */ execl(post, post, id, type, offset, 0); err(16, "can't exec `%s'", post); } return 0; }