wiconfig.c revision 1.11
1 1.11 cgd /* $NetBSD: wiconfig.c,v 1.11 2001/02/19 23:22:49 cgd Exp $ */ 2 1.8 enami 3 1.1 sommerfe /* 4 1.1 sommerfe * Copyright (c) 1997, 1998, 1999 5 1.1 sommerfe * Bill Paul <wpaul (at) ctr.columbia.edu>. All rights reserved. 6 1.1 sommerfe * 7 1.1 sommerfe * Redistribution and use in source and binary forms, with or without 8 1.1 sommerfe * modification, are permitted provided that the following conditions 9 1.1 sommerfe * are met: 10 1.1 sommerfe * 1. Redistributions of source code must retain the above copyright 11 1.1 sommerfe * notice, this list of conditions and the following disclaimer. 12 1.1 sommerfe * 2. Redistributions in binary form must reproduce the above copyright 13 1.1 sommerfe * notice, this list of conditions and the following disclaimer in the 14 1.1 sommerfe * documentation and/or other materials provided with the distribution. 15 1.1 sommerfe * 3. All advertising materials mentioning features or use of this software 16 1.1 sommerfe * must display the following acknowledgement: 17 1.1 sommerfe * This product includes software developed by Bill Paul. 18 1.1 sommerfe * 4. Neither the name of the author nor the names of any co-contributors 19 1.1 sommerfe * may be used to endorse or promote products derived from this software 20 1.1 sommerfe * without specific prior written permission. 21 1.1 sommerfe * 22 1.1 sommerfe * THIS SOFTWARE IS PROVIDED BY Bill Paul AND CONTRIBUTORS ``AS IS'' AND 23 1.1 sommerfe * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 24 1.1 sommerfe * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 25 1.1 sommerfe * ARE DISCLAIMED. IN NO EVENT SHALL Bill Paul OR THE VOICES IN HIS HEAD 26 1.1 sommerfe * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 27 1.1 sommerfe * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 28 1.1 sommerfe * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 29 1.1 sommerfe * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 30 1.1 sommerfe * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 31 1.1 sommerfe * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF 32 1.1 sommerfe * THE POSSIBILITY OF SUCH DAMAGE. 33 1.1 sommerfe * 34 1.8 enami * From: Id: wicontrol.c,v 1.6 1999/05/22 16:12:49 wpaul Exp $ 35 1.1 sommerfe */ 36 1.1 sommerfe 37 1.1 sommerfe #include <sys/types.h> 38 1.1 sommerfe #include <sys/cdefs.h> 39 1.1 sommerfe #include <sys/param.h> 40 1.1 sommerfe #include <sys/socket.h> 41 1.1 sommerfe #include <sys/ioctl.h> 42 1.1 sommerfe #include <sys/socket.h> 43 1.1 sommerfe 44 1.1 sommerfe #include <net/if.h> 45 1.2 explorer #ifdef __FreeBSD__ 46 1.2 explorer #include <net/if_var.h> 47 1.2 explorer #include <net/ethernet.h> 48 1.2 explorer 49 1.2 explorer #include <machine/if_wavelan_ieee.h> 50 1.2 explorer #else 51 1.2 explorer #include <netinet/in.h> 52 1.2 explorer #include <netinet/if_ether.h> 53 1.2 explorer #ifdef __NetBSD__ 54 1.1 sommerfe #include <dev/pcmcia/if_wi_ieee.h> 55 1.2 explorer #else 56 1.2 explorer #include <dev/pcmcia/if_wavelan_ieee.h> 57 1.2 explorer #endif 58 1.2 explorer #endif 59 1.1 sommerfe 60 1.1 sommerfe #include <stdio.h> 61 1.1 sommerfe #include <string.h> 62 1.2 explorer #include <ctype.h> 63 1.1 sommerfe #include <stdlib.h> 64 1.1 sommerfe #include <unistd.h> 65 1.1 sommerfe #include <errno.h> 66 1.1 sommerfe #include <err.h> 67 1.1 sommerfe 68 1.1 sommerfe #if !defined(lint) 69 1.1 sommerfe static const char copyright[] = "@(#) Copyright (c) 1997, 1998, 1999\ 70 1.1 sommerfe Bill Paul. All rights reserved."; 71 1.1 sommerfe static const char rcsid[] = 72 1.11 cgd "@(#) $Id: wiconfig.c,v 1.11 2001/02/19 23:22:49 cgd Exp $"; 73 1.1 sommerfe #endif 74 1.1 sommerfe 75 1.7 enami struct wi_table { 76 1.7 enami int wi_type; 77 1.7 enami int wi_code; 78 1.7 enami #define WI_NONE 0x00 79 1.7 enami #define WI_STRING 0x01 80 1.7 enami #define WI_BOOL 0x02 81 1.7 enami #define WI_WORDS 0x03 82 1.7 enami #define WI_HEXBYTES 0x04 83 1.7 enami #define WI_KEYSTRUCT 0x05 84 1.7 enami char *wi_label; /* label used to print info */ 85 1.7 enami int wi_opt; /* option character to set this */ 86 1.7 enami char *wi_desc; 87 1.7 enami char *wi_optval; 88 1.7 enami }; 89 1.7 enami 90 1.1 sommerfe static void wi_getval __P((char *, struct wi_req *)); 91 1.1 sommerfe static void wi_setval __P((char *, struct wi_req *)); 92 1.1 sommerfe static void wi_printstr __P((struct wi_req *)); 93 1.1 sommerfe static void wi_setstr __P((char *, int, char *)); 94 1.1 sommerfe static void wi_setbytes __P((char *, int, char *, int)); 95 1.1 sommerfe static void wi_setword __P((char *, int, int)); 96 1.1 sommerfe static void wi_sethex __P((char *, int, char *)); 97 1.1 sommerfe static void wi_printwords __P((struct wi_req *)); 98 1.1 sommerfe static void wi_printbool __P((struct wi_req *)); 99 1.1 sommerfe static void wi_printhex __P((struct wi_req *)); 100 1.1 sommerfe static void wi_dumpinfo __P((char *)); 101 1.2 explorer static void wi_setkeys __P((char *, char *, int)); 102 1.2 explorer static void wi_printkeys __P((struct wi_req *)); 103 1.1 sommerfe static void wi_dumpstats __P((char *)); 104 1.7 enami static void usage __P((void)); 105 1.7 enami static struct wi_table * 106 1.7 enami wi_optlookup __P((struct wi_table *, int)); 107 1.2 explorer static int wi_hex2int(char c); 108 1.2 explorer static void wi_str2key __P((char *, struct wi_key *)); 109 1.1 sommerfe int main __P((int argc, char **argv)); 110 1.1 sommerfe 111 1.1 sommerfe static void wi_getval(iface, wreq) 112 1.1 sommerfe char *iface; 113 1.1 sommerfe struct wi_req *wreq; 114 1.1 sommerfe { 115 1.1 sommerfe struct ifreq ifr; 116 1.1 sommerfe int s; 117 1.1 sommerfe 118 1.1 sommerfe bzero((char *)&ifr, sizeof(ifr)); 119 1.1 sommerfe 120 1.1 sommerfe strcpy(ifr.ifr_name, iface); 121 1.1 sommerfe ifr.ifr_data = (caddr_t)wreq; 122 1.1 sommerfe 123 1.1 sommerfe s = socket(AF_INET, SOCK_DGRAM, 0); 124 1.1 sommerfe 125 1.1 sommerfe if (s == -1) 126 1.1 sommerfe err(1, "socket"); 127 1.1 sommerfe 128 1.1 sommerfe if (ioctl(s, SIOCGWAVELAN, &ifr) == -1) 129 1.1 sommerfe err(1, "SIOCGWAVELAN"); 130 1.1 sommerfe 131 1.1 sommerfe close(s); 132 1.1 sommerfe 133 1.1 sommerfe return; 134 1.1 sommerfe } 135 1.1 sommerfe 136 1.1 sommerfe static void wi_setval(iface, wreq) 137 1.1 sommerfe char *iface; 138 1.1 sommerfe struct wi_req *wreq; 139 1.1 sommerfe { 140 1.1 sommerfe struct ifreq ifr; 141 1.1 sommerfe int s; 142 1.1 sommerfe 143 1.1 sommerfe bzero((char *)&ifr, sizeof(ifr)); 144 1.1 sommerfe 145 1.1 sommerfe strcpy(ifr.ifr_name, iface); 146 1.1 sommerfe ifr.ifr_data = (caddr_t)wreq; 147 1.1 sommerfe 148 1.1 sommerfe s = socket(AF_INET, SOCK_DGRAM, 0); 149 1.1 sommerfe 150 1.1 sommerfe if (s == -1) 151 1.1 sommerfe err(1, "socket"); 152 1.1 sommerfe 153 1.1 sommerfe if (ioctl(s, SIOCSWAVELAN, &ifr) == -1) 154 1.1 sommerfe err(1, "SIOCSWAVELAN"); 155 1.1 sommerfe 156 1.1 sommerfe close(s); 157 1.1 sommerfe 158 1.1 sommerfe return; 159 1.1 sommerfe } 160 1.1 sommerfe 161 1.1 sommerfe void wi_printstr(wreq) 162 1.1 sommerfe struct wi_req *wreq; 163 1.1 sommerfe { 164 1.1 sommerfe char *ptr; 165 1.1 sommerfe int i; 166 1.1 sommerfe 167 1.1 sommerfe if (wreq->wi_type == WI_RID_SERIALNO) { 168 1.1 sommerfe ptr = (char *)&wreq->wi_val; 169 1.1 sommerfe for (i = 0; i < (wreq->wi_len - 1) * 2; i++) { 170 1.1 sommerfe if (ptr[i] == '\0') 171 1.1 sommerfe ptr[i] = ' '; 172 1.1 sommerfe } 173 1.1 sommerfe } else { 174 1.1 sommerfe ptr = (char *)&wreq->wi_val[1]; 175 1.1 sommerfe for (i = 0; i < wreq->wi_val[0]; i++) { 176 1.1 sommerfe if (ptr[i] == '\0') 177 1.1 sommerfe ptr[i] = ' '; 178 1.1 sommerfe } 179 1.1 sommerfe } 180 1.1 sommerfe 181 1.1 sommerfe ptr[i] = '\0'; 182 1.1 sommerfe printf("[ %s ]", ptr); 183 1.1 sommerfe 184 1.1 sommerfe return; 185 1.1 sommerfe } 186 1.1 sommerfe 187 1.1 sommerfe void wi_setstr(iface, code, str) 188 1.1 sommerfe char *iface; 189 1.1 sommerfe int code; 190 1.1 sommerfe char *str; 191 1.1 sommerfe { 192 1.1 sommerfe struct wi_req wreq; 193 1.1 sommerfe 194 1.1 sommerfe bzero((char *)&wreq, sizeof(wreq)); 195 1.1 sommerfe 196 1.1 sommerfe if (strlen(str) > 30) 197 1.1 sommerfe errx(1, "string too long"); 198 1.1 sommerfe 199 1.1 sommerfe wreq.wi_type = code; 200 1.1 sommerfe wreq.wi_len = 18; 201 1.1 sommerfe wreq.wi_val[0] = strlen(str); 202 1.1 sommerfe bcopy(str, (char *)&wreq.wi_val[1], strlen(str)); 203 1.1 sommerfe 204 1.1 sommerfe wi_setval(iface, &wreq); 205 1.1 sommerfe 206 1.1 sommerfe return; 207 1.1 sommerfe } 208 1.1 sommerfe 209 1.1 sommerfe void wi_setbytes(iface, code, bytes, len) 210 1.1 sommerfe char *iface; 211 1.1 sommerfe int code; 212 1.1 sommerfe char *bytes; 213 1.1 sommerfe int len; 214 1.1 sommerfe { 215 1.1 sommerfe struct wi_req wreq; 216 1.1 sommerfe 217 1.1 sommerfe bzero((char *)&wreq, sizeof(wreq)); 218 1.1 sommerfe 219 1.1 sommerfe wreq.wi_type = code; 220 1.1 sommerfe wreq.wi_len = (len / 2) + 1; 221 1.1 sommerfe bcopy(bytes, (char *)&wreq.wi_val[0], len); 222 1.1 sommerfe 223 1.1 sommerfe wi_setval(iface, &wreq); 224 1.1 sommerfe 225 1.1 sommerfe return; 226 1.1 sommerfe } 227 1.1 sommerfe 228 1.1 sommerfe void wi_setword(iface, code, word) 229 1.1 sommerfe char *iface; 230 1.1 sommerfe int code; 231 1.1 sommerfe int word; 232 1.1 sommerfe { 233 1.1 sommerfe struct wi_req wreq; 234 1.1 sommerfe 235 1.1 sommerfe bzero((char *)&wreq, sizeof(wreq)); 236 1.1 sommerfe 237 1.1 sommerfe wreq.wi_type = code; 238 1.1 sommerfe wreq.wi_len = 2; 239 1.1 sommerfe wreq.wi_val[0] = word; 240 1.1 sommerfe 241 1.1 sommerfe wi_setval(iface, &wreq); 242 1.1 sommerfe 243 1.1 sommerfe return; 244 1.1 sommerfe } 245 1.1 sommerfe 246 1.1 sommerfe void wi_sethex(iface, code, str) 247 1.1 sommerfe char *iface; 248 1.1 sommerfe int code; 249 1.1 sommerfe char *str; 250 1.1 sommerfe { 251 1.1 sommerfe struct ether_addr *addr; 252 1.1 sommerfe 253 1.1 sommerfe addr = ether_aton(str); 254 1.1 sommerfe if (addr == NULL) 255 1.1 sommerfe errx(1, "badly formatted address"); 256 1.1 sommerfe 257 1.1 sommerfe wi_setbytes(iface, code, (char *)addr, ETHER_ADDR_LEN); 258 1.1 sommerfe 259 1.1 sommerfe return; 260 1.1 sommerfe } 261 1.1 sommerfe 262 1.2 explorer static int 263 1.2 explorer wi_hex2int(char c) 264 1.2 explorer { 265 1.2 explorer if (c >= '0' && c <= '9') 266 1.2 explorer return (c - '0'); 267 1.2 explorer if (c >= 'A' && c <= 'F') 268 1.2 explorer return (c - 'A' + 10); 269 1.2 explorer if (c >= 'a' && c <= 'f') 270 1.2 explorer return (c - 'a' + 10); 271 1.2 explorer 272 1.2 explorer return (0); 273 1.2 explorer } 274 1.2 explorer 275 1.2 explorer static void wi_str2key(s, k) 276 1.2 explorer char *s; 277 1.2 explorer struct wi_key *k; 278 1.2 explorer { 279 1.2 explorer int n, i; 280 1.2 explorer char *p; 281 1.2 explorer 282 1.2 explorer /* Is this a hex string? */ 283 1.2 explorer if (s[0] == '0' && (s[1] == 'x' || s[1] == 'X')) { 284 1.2 explorer /* Yes, convert to int. */ 285 1.2 explorer n = 0; 286 1.2 explorer p = (char *)&k->wi_keydat[0]; 287 1.2 explorer for (i = 2; i < strlen(s); i+= 2) { 288 1.2 explorer *p++ = (wi_hex2int(s[i]) << 4) + wi_hex2int(s[i + 1]); 289 1.2 explorer n++; 290 1.2 explorer } 291 1.2 explorer k->wi_keylen = n; 292 1.2 explorer } else { 293 1.2 explorer /* No, just copy it in. */ 294 1.2 explorer bcopy(s, k->wi_keydat, strlen(s)); 295 1.2 explorer k->wi_keylen = strlen(s); 296 1.2 explorer } 297 1.2 explorer 298 1.2 explorer return; 299 1.2 explorer } 300 1.2 explorer 301 1.2 explorer static void wi_setkeys(iface, key, idx) 302 1.2 explorer char *iface; 303 1.2 explorer char *key; 304 1.2 explorer int idx; 305 1.2 explorer { 306 1.2 explorer struct wi_req wreq; 307 1.2 explorer struct wi_ltv_keys *keys; 308 1.2 explorer struct wi_key *k; 309 1.2 explorer 310 1.2 explorer bzero((char *)&wreq, sizeof(wreq)); 311 1.2 explorer wreq.wi_len = WI_MAX_DATALEN; 312 1.2 explorer wreq.wi_type = WI_RID_WEP_AVAIL; 313 1.2 explorer 314 1.2 explorer wi_getval(iface, &wreq); 315 1.2 explorer if (wreq.wi_val[0] == 0) 316 1.2 explorer err(1, "no WEP option available on this card"); 317 1.2 explorer 318 1.2 explorer bzero((char *)&wreq, sizeof(wreq)); 319 1.2 explorer wreq.wi_len = WI_MAX_DATALEN; 320 1.2 explorer wreq.wi_type = WI_RID_DEFLT_CRYPT_KEYS; 321 1.2 explorer 322 1.2 explorer wi_getval(iface, &wreq); 323 1.2 explorer keys = (struct wi_ltv_keys *)&wreq; 324 1.2 explorer 325 1.2 explorer if (key[0] == '0' && (key[1] == 'x' || key[1] == 'X')) { 326 1.2 explorer if (strlen(key) > 30) 327 1.2 explorer err(1, "encryption key must be no " 328 1.2 explorer "more than 28 hex digits long"); 329 1.2 explorer } else { 330 1.2 explorer if (strlen(key) > 14) 331 1.2 explorer err(1, "encryption key must be no " 332 1.2 explorer "more than 14 characters long"); 333 1.2 explorer } 334 1.2 explorer 335 1.2 explorer if (idx > 3) 336 1.2 explorer err(1, "only 4 encryption keys available"); 337 1.2 explorer 338 1.2 explorer k = &keys->wi_keys[idx]; 339 1.2 explorer wi_str2key(key, k); 340 1.2 explorer 341 1.2 explorer wreq.wi_len = (sizeof(struct wi_ltv_keys) / 2) + 1; 342 1.2 explorer wreq.wi_type = WI_RID_DEFLT_CRYPT_KEYS; 343 1.2 explorer wi_setval(iface, &wreq); 344 1.2 explorer 345 1.2 explorer return; 346 1.2 explorer } 347 1.2 explorer 348 1.2 explorer static void wi_printkeys(wreq) 349 1.2 explorer struct wi_req *wreq; 350 1.2 explorer { 351 1.2 explorer int i, j, bn; 352 1.2 explorer struct wi_key *k; 353 1.2 explorer struct wi_ltv_keys *keys; 354 1.2 explorer char *ptr; 355 1.2 explorer 356 1.2 explorer keys = (struct wi_ltv_keys *)wreq; 357 1.2 explorer 358 1.2 explorer for (i = 0, bn = 0; i < 4; i++, bn = 0) { 359 1.2 explorer k = &keys->wi_keys[i]; 360 1.2 explorer ptr = (char *)k->wi_keydat; 361 1.2 explorer for (j = 0; j < k->wi_keylen; j++) { 362 1.10 jdolecek if (!isprint((unsigned char) ptr[j])) { 363 1.2 explorer bn = 1; 364 1.2 explorer break; 365 1.2 explorer } 366 1.2 explorer } 367 1.2 explorer 368 1.2 explorer if (bn) { 369 1.2 explorer printf("[ 0x"); 370 1.2 explorer for (j = 0; j < k->wi_keylen; j++) 371 1.2 explorer printf("%02x", ((unsigned char *) ptr)[j]); 372 1.2 explorer printf(" ]"); 373 1.2 explorer } else { 374 1.2 explorer ptr[j] = '\0'; 375 1.2 explorer printf("[ %s ]", ptr); 376 1.2 explorer } 377 1.2 explorer } 378 1.2 explorer 379 1.2 explorer return; 380 1.2 explorer }; 381 1.2 explorer 382 1.1 sommerfe void wi_printwords(wreq) 383 1.1 sommerfe struct wi_req *wreq; 384 1.1 sommerfe { 385 1.1 sommerfe int i; 386 1.1 sommerfe 387 1.1 sommerfe printf("[ "); 388 1.1 sommerfe for (i = 0; i < wreq->wi_len - 1; i++) 389 1.1 sommerfe printf("%d ", wreq->wi_val[i]); 390 1.1 sommerfe printf("]"); 391 1.1 sommerfe 392 1.1 sommerfe return; 393 1.1 sommerfe } 394 1.1 sommerfe 395 1.1 sommerfe void wi_printbool(wreq) 396 1.1 sommerfe struct wi_req *wreq; 397 1.1 sommerfe { 398 1.1 sommerfe if (wreq->wi_val[0]) 399 1.1 sommerfe printf("[ On ]"); 400 1.1 sommerfe else 401 1.1 sommerfe printf("[ Off ]"); 402 1.1 sommerfe 403 1.1 sommerfe return; 404 1.1 sommerfe } 405 1.1 sommerfe 406 1.1 sommerfe void wi_printhex(wreq) 407 1.1 sommerfe struct wi_req *wreq; 408 1.1 sommerfe { 409 1.1 sommerfe int i; 410 1.1 sommerfe unsigned char *c; 411 1.1 sommerfe 412 1.1 sommerfe c = (unsigned char *)&wreq->wi_val; 413 1.1 sommerfe 414 1.1 sommerfe printf("[ "); 415 1.1 sommerfe for (i = 0; i < (wreq->wi_len - 1) * 2; i++) { 416 1.1 sommerfe printf("%02x", c[i]); 417 1.1 sommerfe if (i < ((wreq->wi_len - 1) * 2) - 1) 418 1.1 sommerfe printf(":"); 419 1.1 sommerfe } 420 1.1 sommerfe 421 1.1 sommerfe printf(" ]"); 422 1.1 sommerfe return; 423 1.1 sommerfe } 424 1.1 sommerfe 425 1.1 sommerfe static struct wi_table wi_table[] = { 426 1.1 sommerfe { WI_RID_SERIALNO, WI_STRING, "NIC serial number:\t\t\t" }, 427 1.7 enami { WI_RID_NODENAME, WI_STRING, "Station name:\t\t\t\t", 428 1.7 enami 's', "station name" }, 429 1.7 enami { WI_RID_OWN_SSID, WI_STRING, "SSID for IBSS creation:\t\t\t", 430 1.7 enami 'q', "own SSID" }, 431 1.1 sommerfe { WI_RID_CURRENT_SSID, WI_STRING, "Current netname (SSID):\t\t\t" }, 432 1.7 enami { WI_RID_DESIRED_SSID, WI_STRING, "Desired netname (SSID):\t\t\t", 433 1.7 enami 'n', "network name" }, 434 1.1 sommerfe { WI_RID_CURRENT_BSSID, WI_HEXBYTES, "Current BSSID:\t\t\t\t" }, 435 1.1 sommerfe { WI_RID_CHANNEL_LIST, WI_WORDS, "Channel list:\t\t\t\t" }, 436 1.7 enami { WI_RID_OWN_CHNL, WI_WORDS, "IBSS channel:\t\t\t\t", 437 1.7 enami 'f', "frequency" }, 438 1.1 sommerfe { WI_RID_CURRENT_CHAN, WI_WORDS, "Current channel:\t\t\t" }, 439 1.1 sommerfe { WI_RID_COMMS_QUALITY, WI_WORDS, "Comms quality/signal/noise:\t\t" }, 440 1.1 sommerfe { WI_RID_PROMISC, WI_BOOL, "Promiscuous mode:\t\t\t" }, 441 1.7 enami { WI_RID_PORTTYPE, WI_WORDS, "Port type (1=BSS, 3=ad-hoc):\t\t", 442 1.7 enami 'p', "port type" }, 443 1.7 enami { WI_RID_MAC_NODE, WI_HEXBYTES, "MAC address:\t\t\t\t", 444 1.7 enami 'm', "MAC address" }, 445 1.7 enami { WI_RID_TX_RATE, WI_WORDS, "TX rate (selection):\t\t\t", 446 1.7 enami 't', "TX rate" }, 447 1.2 explorer { WI_RID_CUR_TX_RATE, WI_WORDS, "TX rate (actual speed):\t\t\t"}, 448 1.7 enami { WI_RID_MAX_DATALEN, WI_WORDS, "Maximum data length:\t\t\t", 449 1.7 enami 'd', "maximum data length" }, 450 1.7 enami { WI_RID_RTS_THRESH, WI_WORDS, "RTS/CTS handshake threshold:\t\t", 451 1.7 enami 'r', "RTS threshold" }, 452 1.7 enami { WI_RID_CREATE_IBSS, WI_BOOL, "Create IBSS:\t\t\t\t", 453 1.7 enami 'c', "create ibss" }, 454 1.7 enami { WI_RID_SYSTEM_SCALE, WI_WORDS, "Access point density:\t\t\t", 455 1.7 enami 'a', "system scale" }, 456 1.7 enami { WI_RID_PM_ENABLED, WI_WORDS, "Power Mgmt (1=on, 0=off):\t\t", 457 1.7 enami 'P', "power management enabled" }, 458 1.7 enami { WI_RID_MAX_SLEEP, WI_WORDS, "Max sleep time:\t\t\t\t", 459 1.7 enami 'S', "max sleep duration" }, 460 1.9 jhawk { WI_RID_MICROWAVE_OVEN, WI_WORDS, "Microwave oven robustness:\t\t", 461 1.9 jhawk 'M', "microwave oven robustness enabled" }, 462 1.7 enami { 0, WI_NONE } 463 1.1 sommerfe }; 464 1.1 sommerfe 465 1.2 explorer static struct wi_table wi_crypt_table[] = { 466 1.7 enami { WI_RID_ENCRYPTION, WI_BOOL, "WEP encryption:\t\t\t\t", 467 1.7 enami 'e', "encryption" }, 468 1.2 explorer { WI_RID_TX_CRYPT_KEY, WI_WORDS, "TX encryption key:\t\t\t" }, 469 1.2 explorer { WI_RID_DEFLT_CRYPT_KEYS, WI_KEYSTRUCT, "Encryption keys:\t\t\t" }, 470 1.7 enami { 0, WI_NONE } 471 1.7 enami }; 472 1.7 enami 473 1.7 enami static struct wi_table *wi_tables[] = { 474 1.7 enami wi_table, 475 1.7 enami wi_crypt_table, 476 1.7 enami NULL 477 1.2 explorer }; 478 1.2 explorer 479 1.7 enami static struct wi_table * 480 1.7 enami wi_optlookup(table, opt) 481 1.7 enami struct wi_table *table; 482 1.7 enami int opt; 483 1.7 enami { 484 1.7 enami struct wi_table *wt; 485 1.7 enami 486 1.7 enami for (wt = table; wt->wi_type != 0; wt++) 487 1.7 enami if (wt->wi_opt == opt) 488 1.7 enami return (wt); 489 1.7 enami return (NULL); 490 1.7 enami } 491 1.7 enami 492 1.1 sommerfe static void wi_dumpinfo(iface) 493 1.1 sommerfe char *iface; 494 1.1 sommerfe { 495 1.1 sommerfe struct wi_req wreq; 496 1.2 explorer int i, has_wep; 497 1.1 sommerfe struct wi_table *w; 498 1.1 sommerfe 499 1.2 explorer bzero((char *)&wreq, sizeof(wreq)); 500 1.2 explorer 501 1.2 explorer wreq.wi_len = WI_MAX_DATALEN; 502 1.2 explorer wreq.wi_type = WI_RID_WEP_AVAIL; 503 1.2 explorer 504 1.2 explorer wi_getval(iface, &wreq); 505 1.2 explorer has_wep = wreq.wi_val[0]; 506 1.2 explorer 507 1.1 sommerfe w = wi_table; 508 1.1 sommerfe 509 1.7 enami for (i = 0; w[i].wi_code != WI_NONE; i++) { 510 1.1 sommerfe bzero((char *)&wreq, sizeof(wreq)); 511 1.1 sommerfe 512 1.1 sommerfe wreq.wi_len = WI_MAX_DATALEN; 513 1.7 enami wreq.wi_type = w[i].wi_type; 514 1.1 sommerfe 515 1.1 sommerfe wi_getval(iface, &wreq); 516 1.7 enami printf("%s", w[i].wi_label); 517 1.7 enami switch (w[i].wi_code) { 518 1.1 sommerfe case WI_STRING: 519 1.1 sommerfe wi_printstr(&wreq); 520 1.1 sommerfe break; 521 1.1 sommerfe case WI_WORDS: 522 1.1 sommerfe wi_printwords(&wreq); 523 1.1 sommerfe break; 524 1.1 sommerfe case WI_BOOL: 525 1.1 sommerfe wi_printbool(&wreq); 526 1.1 sommerfe break; 527 1.1 sommerfe case WI_HEXBYTES: 528 1.1 sommerfe wi_printhex(&wreq); 529 1.1 sommerfe break; 530 1.1 sommerfe default: 531 1.1 sommerfe break; 532 1.1 sommerfe } 533 1.1 sommerfe printf("\n"); 534 1.1 sommerfe } 535 1.1 sommerfe 536 1.2 explorer if (has_wep) { 537 1.2 explorer w = wi_crypt_table; 538 1.7 enami for (i = 0; w[i].wi_code != WI_NONE; i++) { 539 1.2 explorer bzero((char *)&wreq, sizeof(wreq)); 540 1.2 explorer 541 1.2 explorer wreq.wi_len = WI_MAX_DATALEN; 542 1.7 enami wreq.wi_type = w[i].wi_type; 543 1.2 explorer 544 1.2 explorer wi_getval(iface, &wreq); 545 1.7 enami printf("%s", w[i].wi_label); 546 1.7 enami switch (w[i].wi_code) { 547 1.2 explorer case WI_STRING: 548 1.2 explorer wi_printstr(&wreq); 549 1.2 explorer break; 550 1.2 explorer case WI_WORDS: 551 1.2 explorer if (wreq.wi_type == WI_RID_TX_CRYPT_KEY) 552 1.2 explorer wreq.wi_val[0]++; 553 1.2 explorer wi_printwords(&wreq); 554 1.2 explorer break; 555 1.2 explorer case WI_BOOL: 556 1.2 explorer wi_printbool(&wreq); 557 1.2 explorer break; 558 1.2 explorer case WI_HEXBYTES: 559 1.2 explorer wi_printhex(&wreq); 560 1.2 explorer break; 561 1.2 explorer case WI_KEYSTRUCT: 562 1.2 explorer wi_printkeys(&wreq); 563 1.2 explorer break; 564 1.2 explorer default: 565 1.2 explorer break; 566 1.2 explorer } 567 1.2 explorer printf("\n"); 568 1.2 explorer } 569 1.2 explorer } 570 1.2 explorer 571 1.1 sommerfe return; 572 1.1 sommerfe } 573 1.1 sommerfe 574 1.1 sommerfe static void wi_dumpstats(iface) 575 1.1 sommerfe char *iface; 576 1.1 sommerfe { 577 1.1 sommerfe struct wi_req wreq; 578 1.1 sommerfe struct wi_counters *c; 579 1.1 sommerfe 580 1.1 sommerfe bzero((char *)&wreq, sizeof(wreq)); 581 1.1 sommerfe wreq.wi_len = WI_MAX_DATALEN; 582 1.1 sommerfe wreq.wi_type = WI_RID_IFACE_STATS; 583 1.1 sommerfe 584 1.1 sommerfe wi_getval(iface, &wreq); 585 1.1 sommerfe 586 1.1 sommerfe c = (struct wi_counters *)&wreq.wi_val; 587 1.1 sommerfe 588 1.1 sommerfe printf("Transmitted unicast frames:\t\t%d\n", 589 1.1 sommerfe c->wi_tx_unicast_frames); 590 1.1 sommerfe printf("Transmitted multicast frames:\t\t%d\n", 591 1.1 sommerfe c->wi_tx_multicast_frames); 592 1.1 sommerfe printf("Transmitted fragments:\t\t\t%d\n", 593 1.1 sommerfe c->wi_tx_fragments); 594 1.1 sommerfe printf("Transmitted unicast octets:\t\t%d\n", 595 1.1 sommerfe c->wi_tx_unicast_octets); 596 1.1 sommerfe printf("Transmitted multicast octets:\t\t%d\n", 597 1.1 sommerfe c->wi_tx_multicast_octets); 598 1.1 sommerfe printf("Single transmit retries:\t\t%d\n", 599 1.1 sommerfe c->wi_tx_single_retries); 600 1.1 sommerfe printf("Multiple transmit retries:\t\t%d\n", 601 1.1 sommerfe c->wi_tx_multi_retries); 602 1.1 sommerfe printf("Transmit retry limit exceeded:\t\t%d\n", 603 1.1 sommerfe c->wi_tx_retry_limit); 604 1.1 sommerfe printf("Transmit discards:\t\t\t%d\n", 605 1.1 sommerfe c->wi_tx_discards); 606 1.1 sommerfe printf("Transmit discards due to wrong SA:\t%d\n", 607 1.1 sommerfe c->wi_tx_discards_wrong_sa); 608 1.1 sommerfe printf("Received unicast frames:\t\t%d\n", 609 1.1 sommerfe c->wi_rx_unicast_frames); 610 1.1 sommerfe printf("Received multicast frames:\t\t%d\n", 611 1.1 sommerfe c->wi_rx_multicast_frames); 612 1.1 sommerfe printf("Received fragments:\t\t\t%d\n", 613 1.1 sommerfe c->wi_rx_fragments); 614 1.1 sommerfe printf("Received unicast octets:\t\t%d\n", 615 1.1 sommerfe c->wi_rx_unicast_octets); 616 1.1 sommerfe printf("Received multicast octets:\t\t%d\n", 617 1.1 sommerfe c->wi_rx_multicast_octets); 618 1.1 sommerfe printf("Receive FCS errors:\t\t\t%d\n", 619 1.1 sommerfe c->wi_rx_fcs_errors); 620 1.1 sommerfe printf("Receive discards due to no buffer:\t%d\n", 621 1.1 sommerfe c->wi_rx_discards_nobuf); 622 1.1 sommerfe printf("Can't decrypt WEP frame:\t\t%d\n", 623 1.1 sommerfe c->wi_rx_WEP_cant_decrypt); 624 1.1 sommerfe printf("Received message fragments:\t\t%d\n", 625 1.1 sommerfe c->wi_rx_msg_in_msg_frags); 626 1.1 sommerfe printf("Received message bad fragments:\t\t%d\n", 627 1.1 sommerfe c->wi_rx_msg_in_bad_msg_frags); 628 1.1 sommerfe 629 1.1 sommerfe return; 630 1.1 sommerfe } 631 1.1 sommerfe 632 1.7 enami static void 633 1.7 enami usage() 634 1.1 sommerfe { 635 1.7 enami 636 1.2 explorer fprintf(stderr, 637 1.7 enami "usage: %s interface " 638 1.2 explorer "[-o] [-t tx rate] [-n network name] [-s station name]\n" 639 1.2 explorer " [-e 0|1] [-k key [-v 1|2|3|4]] [-T 1|2|3|4]\n" 640 1.2 explorer " [-c 0|1] [-q SSID] [-p port type] [-a access point density]\n" 641 1.2 explorer " [-m MAC address] [-d max data length] [-r RTS threshold]\n" 642 1.9 jhawk " [-f frequency] [-M 0|1] [-P 0|1] [-S max sleep duration]\n" 643 1.9 jhawk , 644 1.11 cgd getprogname()); 645 1.1 sommerfe exit(1); 646 1.1 sommerfe } 647 1.1 sommerfe 648 1.1 sommerfe int main(argc, argv) 649 1.1 sommerfe int argc; 650 1.1 sommerfe char *argv[]; 651 1.1 sommerfe { 652 1.7 enami struct wi_table *wt, **table; 653 1.7 enami char *iface, *key, *keyv[4], *tx_crypt_key; 654 1.7 enami int ch, dumpinfo, dumpstats, modifier, oldind; 655 1.7 enami 656 1.7 enami #define SET_OPERAND(opr, desc) do { \ 657 1.7 enami if ((opr) == NULL) \ 658 1.7 enami (opr) = optarg; \ 659 1.7 enami else \ 660 1.7 enami warnx("%s is already specified to %s", \ 661 1.7 enami desc, (opr)); \ 662 1.7 enami } while (0) 663 1.7 enami 664 1.7 enami dumpinfo = 1; 665 1.7 enami dumpstats = 0; 666 1.7 enami iface = key = keyv[0] = keyv[1] = keyv[2] = keyv[3] = 667 1.7 enami tx_crypt_key = NULL; 668 1.2 explorer 669 1.2 explorer if (argc > 1 && argv[1][0] != '-') { 670 1.2 explorer iface = argv[1]; 671 1.5 enami optind++; 672 1.2 explorer } 673 1.1 sommerfe 674 1.3 itojun while ((ch = getopt(argc, argv, 675 1.9 jhawk "a:c:d:e:f:hi:k:m:n:op:q:r:s:t:M:S:P:T:")) != -1) { 676 1.7 enami if (ch != 'i') 677 1.7 enami dumpinfo = 0; 678 1.7 enami /* 679 1.7 enami * Lookup generic options and remeber operand if found. 680 1.7 enami */ 681 1.7 enami for (table = wi_tables; *table != NULL; table++) 682 1.7 enami if ((wt = wi_optlookup(*table, ch)) != NULL) { 683 1.7 enami SET_OPERAND(wt->wi_optval, wt->wi_desc); 684 1.7 enami break; 685 1.7 enami } 686 1.7 enami if (wt == NULL) 687 1.7 enami /* 688 1.7 enami * Handle special options. 689 1.7 enami */ 690 1.7 enami switch (ch) { 691 1.7 enami case 'o': 692 1.7 enami dumpstats = 1; 693 1.7 enami break; 694 1.7 enami case 'i': 695 1.7 enami SET_OPERAND(iface, "interface"); 696 1.7 enami break; 697 1.7 enami case 'k': 698 1.7 enami key = optarg; 699 1.7 enami oldind = optind; 700 1.7 enami opterr = 0; 701 1.7 enami ch = getopt(argc, argv, "v:"); 702 1.7 enami opterr = 1; 703 1.7 enami switch (ch) { 704 1.7 enami case 'v': 705 1.7 enami modifier = atoi(optarg) - 1; 706 1.7 enami break; 707 1.7 enami default: 708 1.7 enami modifier = 0; 709 1.7 enami optind = oldind; 710 1.7 enami break; 711 1.7 enami } 712 1.7 enami keyv[modifier] = key; 713 1.7 enami break; 714 1.7 enami case 'T': 715 1.7 enami SET_OPERAND(tx_crypt_key, "TX encryption key"); 716 1.7 enami break; 717 1.7 enami case 'h': 718 1.7 enami default: 719 1.7 enami usage(); 720 1.7 enami break; 721 1.7 enami } 722 1.1 sommerfe } 723 1.1 sommerfe 724 1.1 sommerfe if (iface == NULL) 725 1.7 enami usage(); 726 1.2 explorer 727 1.7 enami for (table = wi_tables; *table != NULL; table++) 728 1.7 enami for (wt = *table; wt->wi_code != WI_NONE; wt++) 729 1.7 enami if (wt->wi_optval != NULL) { 730 1.7 enami switch (wt->wi_code) { 731 1.7 enami case WI_BOOL: 732 1.7 enami case WI_WORDS: 733 1.7 enami wi_setword(iface, wt->wi_type, 734 1.7 enami atoi(wt->wi_optval)); 735 1.7 enami break; 736 1.7 enami case WI_STRING: 737 1.7 enami wi_setstr(iface, wt->wi_type, 738 1.7 enami wt->wi_optval); 739 1.7 enami break; 740 1.7 enami case WI_HEXBYTES: 741 1.7 enami wi_sethex(iface, wt->wi_type, 742 1.7 enami wt->wi_optval); 743 1.7 enami break; 744 1.7 enami } 745 1.7 enami } 746 1.7 enami 747 1.7 enami if (tx_crypt_key != NULL) 748 1.7 enami wi_setword(iface, WI_RID_TX_CRYPT_KEY, atoi(tx_crypt_key) - 1); 749 1.1 sommerfe 750 1.7 enami for (modifier = 0; modifier < sizeof(keyv) / sizeof(keyv[0]); 751 1.7 enami modifier++) 752 1.7 enami if (keyv[modifier] != NULL) 753 1.7 enami wi_setkeys(iface, keyv[modifier], modifier); 754 1.7 enami 755 1.7 enami if (dumpstats) 756 1.7 enami wi_dumpstats(iface); 757 1.7 enami if (dumpinfo) 758 1.7 enami wi_dumpinfo(iface); 759 1.1 sommerfe 760 1.1 sommerfe exit(0); 761 1.1 sommerfe } 762
Indexes created Tue Sep 30 20:09:53 GMT 2025