1 WPA Supplicant
2 ==============
3
4 Copyright (c) 2003-2009, Jouni Malinen <j (a] w1.fi> and contributors
5 All Rights Reserved.
6
7 This program is dual-licensed under both the GPL version 2 and BSD
8 license. Either license may be used at your option.
9
10
11
12 License
13 -------
14
15 GPL v2:
16
17 This program is free software; you can redistribute it and/or modify
18 it under the terms of the GNU General Public License version 2 as
19 published by the Free Software Foundation.
20
21 This program is distributed in the hope that it will be useful,
22 but WITHOUT ANY WARRANTY; without even the implied warranty of
23 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
24 GNU General Public License for more details.
25
26 You should have received a copy of the GNU General Public License
27 along with this program; if not, write to the Free Software
28 Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
29
30 (this copy of the license is in COPYING file)
31
32
33 Alternatively, this software may be distributed, used, and modified
34 under the terms of BSD license:
35
36 Redistribution and use in source and binary forms, with or without
37 modification, are permitted provided that the following conditions are
38 met:
39
40 1. Redistributions of source code must retain the above copyright
41 notice, this list of conditions and the following disclaimer.
42
43 2. Redistributions in binary form must reproduce the above copyright
44 notice, this list of conditions and the following disclaimer in the
45 documentation and/or other materials provided with the distribution.
46
47 3. Neither the name(s) of the above-listed copyright holder(s) nor the
48 names of its contributors may be used to endorse or promote products
49 derived from this software without specific prior written permission.
50
51 THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
52 "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
53 LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
54 A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
55 OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
56 SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
57 LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
58 DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
59 THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
60 (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
61 OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
62
63
64
65 Features
66 --------
67
68 Supported WPA/IEEE 802.11i features:
69 - WPA-PSK ("WPA-Personal")
70 - WPA with EAP (e.g., with RADIUS authentication server) ("WPA-Enterprise")
71 Following authentication methods are supported with an integrate IEEE 802.1X
72 Supplicant:
73 * EAP-TLS
74 * EAP-PEAP/MSCHAPv2 (both PEAPv0 and PEAPv1)
75 * EAP-PEAP/TLS (both PEAPv0 and PEAPv1)
76 * EAP-PEAP/GTC (both PEAPv0 and PEAPv1)
77 * EAP-PEAP/OTP (both PEAPv0 and PEAPv1)
78 * EAP-PEAP/MD5-Challenge (both PEAPv0 and PEAPv1)
79 * EAP-TTLS/EAP-MD5-Challenge
80 * EAP-TTLS/EAP-GTC
81 * EAP-TTLS/EAP-OTP
82 * EAP-TTLS/EAP-MSCHAPv2
83 * EAP-TTLS/EAP-TLS
84 * EAP-TTLS/MSCHAPv2
85 * EAP-TTLS/MSCHAP
86 * EAP-TTLS/PAP
87 * EAP-TTLS/CHAP
88 * EAP-SIM
89 * EAP-AKA
90 * EAP-PSK
91 * EAP-PAX
92 * EAP-SAKE
93 * EAP-IKEv2
94 * EAP-GPSK
95 * LEAP (note: requires special support from the driver for IEEE 802.11
96 authentication)
97 (following methods are supported, but since they do not generate keying
98 material, they cannot be used with WPA or IEEE 802.1X WEP keying)
99 * EAP-MD5-Challenge
100 * EAP-MSCHAPv2
101 * EAP-GTC
102 * EAP-OTP
103 - key management for CCMP, TKIP, WEP104, WEP40
104 - RSN/WPA2 (IEEE 802.11i)
105 * pre-authentication
106 * PMKSA caching
107
108 Supported TLS/crypto libraries:
109 - OpenSSL (default)
110 - GnuTLS
111
112 Internal TLS/crypto implementation (optional):
113 - can be used in place of an external TLS/crypto library
114 - TLSv1
115 - X.509 certificate processing
116 - PKCS #1
117 - ASN.1
118 - RSA
119 - bignum
120 - minimal size (ca. 50 kB binary, parts of which are already needed for WPA;
121 TLSv1/X.509/ASN.1/RSA/bignum parts are about 25 kB on x86)
122
123
124 Requirements
125 ------------
126
127 Current hardware/software requirements:
128 - Linux kernel 2.4.x or 2.6.x with Linux Wireless Extensions v15 or newer
129 - FreeBSD 6-CURRENT
130 - NetBSD-current
131 - Microsoft Windows with WinPcap (at least WinXP, may work with other versions)
132 - drivers:
133 Linux drivers that support WPA/WPA2 configuration with the generic
134 Linux wireless extensions (WE-18 or newer). Even though there are
135 number of driver specific interface included in wpa_supplicant, please
136 note that Linux drivers are moving to use generic wireless extensions
137 and driver_wext (-Dwext on wpa_supplicant command line) should be the
138 default option to start with before falling back to driver specific
139 interface.
140
141 Host AP driver for Prism2/2.5/3 (development snapshot/v0.2.x)
142 (http://hostap.epitest.fi/)
143 Driver need to be set in Managed mode ('iwconfig wlan0 mode managed').
144 Please note that station firmware version needs to be 1.7.0 or newer
145 to work in WPA mode.
146
147 Linuxant DriverLoader (http://www.linuxant.com/driverloader/)
148 with Windows NDIS driver for your wlan card supporting WPA.
149
150 Agere Systems Inc. Linux Driver
151 (http://www.agere.com/support/drivers/)
152 Please note that the driver interface file (driver_hermes.c) and
153 hardware specific include files are not included in the
154 wpa_supplicant distribution. You will need to copy these from the
155 source package of the Agere driver.
156
157 madwifi driver for cards based on Atheros chip set (ar521x)
158 (http://sourceforge.net/projects/madwifi/)
159 Please note that you will need to modify the wpa_supplicant .config
160 file to use the correct path for the madwifi driver root directory
161 (CFLAGS += -I../madwifi/wpa line in example defconfig).
162
163 ATMEL AT76C5XXx driver for USB and PCMCIA cards
164 (http://atmelwlandriver.sourceforge.net/).
165
166 Linux ndiswrapper (http://ndiswrapper.sourceforge.net/) with
167 Windows NDIS driver.
168
169 Broadcom wl.o driver (old version only)
170 This is a generic Linux driver for Broadcom IEEE 802.11a/g cards.
171 However, it is proprietary driver that is not publicly available
172 except for couple of exceptions, mainly Broadcom-based APs/wireless
173 routers that use Linux. The driver binary can be downloaded, e.g.,
174 from Linksys support site (http://www.linksys.com/support/gpl.asp)
175 for Linksys WRT54G. The GPL tarball includes cross-compiler and
176 the needed header file, wlioctl.h, for compiling wpa_supplicant.
177 This driver support in wpa_supplicant is expected to work also with
178 other devices based on Broadcom driver (assuming the driver includes
179 client mode support). Please note that the newer Broadcom driver
180 ("hybrid Linux driver") supports Linux wireless extensions and does
181 not need (or even work) with the specific driver wrapper. Use -Dwext
182 with that driver.
183
184 Intel ipw2100 driver
185 (http://sourceforge.net/projects/ipw2100/)
186
187 Intel ipw2200 driver
188 (http://sourceforge.net/projects/ipw2200/)
189
190 In theory, any driver that supports Linux wireless extensions can be
191 used with IEEE 802.1X (i.e., not WPA) when using ap_scan=0 option in
192 configuration file.
193
194 Wired Ethernet drivers (with ap_scan=0)
195
196 BSD net80211 layer (e.g., Atheros driver)
197 At the moment, this is for FreeBSD 6-CURRENT branch and NetBSD-current.
198
199 Windows NDIS
200 The current Windows port requires WinPcap (http://winpcap.polito.it/).
201 See README-Windows.txt for more information.
202
203 wpa_supplicant was designed to be portable for different drivers and
204 operating systems. Hopefully, support for more wlan cards and OSes will be
205 added in the future. See developer's documentation
206 (http://hostap.epitest.fi/wpa_supplicant/devel/) for more information about the
207 design of wpa_supplicant and porting to other drivers. One main goal
208 is to add full WPA/WPA2 support to Linux wireless extensions to allow
209 new drivers to be supported without having to implement new
210 driver-specific interface code in wpa_supplicant.
211
212 Optional libraries for layer2 packet processing:
213 - libpcap (tested with 0.7.2, most relatively recent versions assumed to work,
214 this is likely to be available with most distributions,
215 http://tcpdump.org/)
216 - libdnet (tested with v1.4, most versions assumed to work,
217 http://libdnet.sourceforge.net/)
218
219 These libraries are _not_ used in the default Linux build. Instead,
220 internal Linux specific implementation is used. libpcap/libdnet are
221 more portable and they can be used by adding CONFIG_L2_PACKET=pcap into
222 .config. They may also be selected automatically for other operating
223 systems. In case of Windows builds, WinPcap is used by default
224 (CONFIG_L2_PACKET=winpcap).
225
226
227 Optional libraries for EAP-TLS, EAP-PEAP, and EAP-TTLS:
228 - OpenSSL (tested with 0.9.7c and 0.9.7d, and 0.9.8 versions; assumed to
229 work with most relatively recent versions; this is likely to be
230 available with most distributions, http://www.openssl.org/)
231 - GnuTLS
232 - internal TLSv1 implementation
233
234 TLS options for EAP-FAST:
235 - OpenSSL 0.9.8d _with_ openssl-0.9.8d-tls-extensions.patch applied
236 (i.e., the default OpenSSL package does not include support for
237 extensions needed for EAP-FAST)
238 - internal TLSv1 implementation
239
240 One of these libraries is needed when EAP-TLS, EAP-PEAP, EAP-TTLS, or
241 EAP-FAST support is enabled. WPA-PSK mode does not require this or EAPOL/EAP
242 implementation. A configuration file, .config, for compilation is
243 needed to enable IEEE 802.1X/EAPOL and EAP methods. Note that EAP-MD5,
244 EAP-GTC, EAP-OTP, and EAP-MSCHAPV2 cannot be used alone with WPA, so
245 they should only be enabled if testing the EAPOL/EAP state
246 machines. However, there can be used as inner authentication
247 algorithms with EAP-PEAP and EAP-TTLS.
248
249 See Building and installing section below for more detailed
250 information about the wpa_supplicant build time configuration.
251
252
253
254 WPA
255 ---
256
257 The original security mechanism of IEEE 802.11 standard was not
258 designed to be strong and has proven to be insufficient for most
259 networks that require some kind of security. Task group I (Security)
260 of IEEE 802.11 working group (http://www.ieee802.org/11/) has worked
261 to address the flaws of the base standard and has in practice
262 completed its work in May 2004. The IEEE 802.11i amendment to the IEEE
263 802.11 standard was approved in June 2004 and published in July 2004.
264
265 Wi-Fi Alliance (http://www.wi-fi.org/) used a draft version of the
266 IEEE 802.11i work (draft 3.0) to define a subset of the security
267 enhancements that can be implemented with existing wlan hardware. This
268 is called Wi-Fi Protected Access<TM> (WPA). This has now become a
269 mandatory component of interoperability testing and certification done
270 by Wi-Fi Alliance. Wi-Fi provides information about WPA at its web
271 site (http://www.wi-fi.org/OpenSection/protected_access.asp).
272
273 IEEE 802.11 standard defined wired equivalent privacy (WEP) algorithm
274 for protecting wireless networks. WEP uses RC4 with 40-bit keys,
275 24-bit initialization vector (IV), and CRC32 to protect against packet
276 forgery. All these choices have proven to be insufficient: key space is
277 too small against current attacks, RC4 key scheduling is insufficient
278 (beginning of the pseudorandom stream should be skipped), IV space is
279 too small and IV reuse makes attacks easier, there is no replay
280 protection, and non-keyed authentication does not protect against bit
281 flipping packet data.
282
283 WPA is an intermediate solution for the security issues. It uses
284 Temporal Key Integrity Protocol (TKIP) to replace WEP. TKIP is a
285 compromise on strong security and possibility to use existing
286 hardware. It still uses RC4 for the encryption like WEP, but with
287 per-packet RC4 keys. In addition, it implements replay protection,
288 keyed packet authentication mechanism (Michael MIC).
289
290 Keys can be managed using two different mechanisms. WPA can either use
291 an external authentication server (e.g., RADIUS) and EAP just like
292 IEEE 802.1X is using or pre-shared keys without need for additional
293 servers. Wi-Fi calls these "WPA-Enterprise" and "WPA-Personal",
294 respectively. Both mechanisms will generate a master session key for
295 the Authenticator (AP) and Supplicant (client station).
296
297 WPA implements a new key handshake (4-Way Handshake and Group Key
298 Handshake) for generating and exchanging data encryption keys between
299 the Authenticator and Supplicant. This handshake is also used to
300 verify that both Authenticator and Supplicant know the master session
301 key. These handshakes are identical regardless of the selected key
302 management mechanism (only the method for generating master session
303 key changes).
304
305
306
307 IEEE 802.11i / WPA2
308 -------------------
309
310 The design for parts of IEEE 802.11i that were not included in WPA has
311 finished (May 2004) and this amendment to IEEE 802.11 was approved in
312 June 2004. Wi-Fi Alliance is using the final IEEE 802.11i as a new
313 version of WPA called WPA2. This includes, e.g., support for more
314 robust encryption algorithm (CCMP: AES in Counter mode with CBC-MAC)
315 to replace TKIP and optimizations for handoff (reduced number of
316 messages in initial key handshake, pre-authentication, and PMKSA caching).
317
318
319
320 wpa_supplicant
321 --------------
322
323 wpa_supplicant is an implementation of the WPA Supplicant component,
324 i.e., the part that runs in the client stations. It implements WPA key
325 negotiation with a WPA Authenticator and EAP authentication with
326 Authentication Server. In addition, it controls the roaming and IEEE
327 802.11 authentication/association of the wlan driver.
328
329 wpa_supplicant is designed to be a "daemon" program that runs in the
330 background and acts as the backend component controlling the wireless
331 connection. wpa_supplicant supports separate frontend programs and an
332 example text-based frontend, wpa_cli, is included with wpa_supplicant.
333
334 Following steps are used when associating with an AP using WPA:
335
336 - wpa_supplicant requests the kernel driver to scan neighboring BSSes
337 - wpa_supplicant selects a BSS based on its configuration
338 - wpa_supplicant requests the kernel driver to associate with the chosen
339 BSS
340 - If WPA-EAP: integrated IEEE 802.1X Supplicant completes EAP
341 authentication with the authentication server (proxied by the
342 Authenticator in the AP)
343 - If WPA-EAP: master key is received from the IEEE 802.1X Supplicant
344 - If WPA-PSK: wpa_supplicant uses PSK as the master session key
345 - wpa_supplicant completes WPA 4-Way Handshake and Group Key Handshake
346 with the Authenticator (AP)
347 - wpa_supplicant configures encryption keys for unicast and broadcast
348 - normal data packets can be transmitted and received
349
350
351
352 Building and installing
353 -----------------------
354
355 In order to be able to build wpa_supplicant, you will first need to
356 select which parts of it will be included. This is done by creating a
357 build time configuration file, .config, in the wpa_supplicant root
358 directory. Configuration options are text lines using following
359 format: CONFIG_<option>=y. Lines starting with # are considered
360 comments and are ignored. See defconfig file for an example configuration
361 and a list of available options and additional notes.
362
363 The build time configuration can be used to select only the needed
364 features and limit the binary size and requirements for external
365 libraries. The main configuration parts are the selection of which
366 driver interfaces (e.g., hostap, madwifi, ..) and which authentication
367 methods (e.g., EAP-TLS, EAP-PEAP, ..) are included.
368
369 Following build time configuration options are used to control IEEE
370 802.1X/EAPOL and EAP state machines and all EAP methods. Including
371 TLS, PEAP, or TTLS will require linking wpa_supplicant with OpenSSL
372 library for TLS implementation. Alternatively, GnuTLS or the internal
373 TLSv1 implementation can be used for TLS functionaly.
374
375 CONFIG_IEEE8021X_EAPOL=y
376 CONFIG_EAP_MD5=y
377 CONFIG_EAP_MSCHAPV2=y
378 CONFIG_EAP_TLS=y
379 CONFIG_EAP_PEAP=y
380 CONFIG_EAP_TTLS=y
381 CONFIG_EAP_GTC=y
382 CONFIG_EAP_OTP=y
383 CONFIG_EAP_SIM=y
384 CONFIG_EAP_AKA=y
385 CONFIG_EAP_PSK=y
386 CONFIG_EAP_SAKE=y
387 CONFIG_EAP_GPSK=y
388 CONFIG_EAP_PAX=y
389 CONFIG_EAP_LEAP=y
390 CONFIG_EAP_IKEV2=y
391
392 Following option can be used to include GSM SIM/USIM interface for GSM/UMTS
393 authentication algorithm (for EAP-SIM/EAP-AKA). This requires pcsc-lite
394 (http://www.linuxnet.com/) for smart card access.
395
396 CONFIG_PCSC=y
397
398 Following options can be added to .config to select which driver
399 interfaces are included. Hermes driver interface needs to be downloaded
400 from Agere (see above).
401
402 CONFIG_DRIVER_HOSTAP=y
403 CONFIG_DRIVER_HERMES=y
404 CONFIG_DRIVER_MADWIFI=y
405 CONFIG_DRIVER_ATMEL=y
406 CONFIG_DRIVER_WEXT=y
407 CONFIG_DRIVER_RALINK=y
408 CONFIG_DRIVER_NDISWRAPPER=y
409 CONFIG_DRIVER_BROADCOM=y
410 CONFIG_DRIVER_IPW=y
411 CONFIG_DRIVER_BSD=y
412 CONFIG_DRIVER_NDIS=y
413
414 Following example includes all features and driver interfaces that are
415 included in the wpa_supplicant package:
416
417 CONFIG_DRIVER_HOSTAP=y
418 CONFIG_DRIVER_HERMES=y
419 CONFIG_DRIVER_MADWIFI=y
420 CONFIG_DRIVER_ATMEL=y
421 CONFIG_DRIVER_WEXT=y
422 CONFIG_DRIVER_NDISWRAPPER=y
423 CONFIG_DRIVER_BROADCOM=y
424 CONFIG_DRIVER_IPW=y
425 CONFIG_DRIVER_BSD=y
426 CONFIG_DRIVER_NDIS=y
427 CONFIG_IEEE8021X_EAPOL=y
428 CONFIG_EAP_MD5=y
429 CONFIG_EAP_MSCHAPV2=y
430 CONFIG_EAP_TLS=y
431 CONFIG_EAP_PEAP=y
432 CONFIG_EAP_TTLS=y
433 CONFIG_EAP_GTC=y
434 CONFIG_EAP_OTP=y
435 CONFIG_EAP_SIM=y
436 CONFIG_EAP_AKA=y
437 CONFIG_EAP_PSK=y
438 CONFIG_EAP_SAKE=y
439 CONFIG_EAP_GPSK=y
440 CONFIG_EAP_PAX=y
441 CONFIG_EAP_LEAP=y
442 CONFIG_EAP_IKEV2=y
443 CONFIG_PCSC=y
444
445 EAP-PEAP and EAP-TTLS will automatically include configured EAP
446 methods (MD5, OTP, GTC, MSCHAPV2) for inner authentication selection.
447
448
449 After you have created a configuration file, you can build
450 wpa_supplicant and wpa_cli with 'make' command. You may then install
451 the binaries to a suitable system directory, e.g., /usr/local/bin.
452
453 Example commands:
454
455 # build wpa_supplicant and wpa_cli
456 make
457 # install binaries (this may need root privileges)
458 cp wpa_cli wpa_supplicant /usr/local/bin
459
460
461 You will need to make a configuration file, e.g.,
462 /etc/wpa_supplicant.conf, with network configuration for the networks
463 you are going to use. Configuration file section below includes
464 explanation fo the configuration file format and includes various
465 examples. Once the configuration is ready, you can test whether the
466 configuration work by first running wpa_supplicant with following
467 command to start it on foreground with debugging enabled:
468
469 wpa_supplicant -iwlan0 -c/etc/wpa_supplicant.conf -d
470
471 Assuming everything goes fine, you can start using following command
472 to start wpa_supplicant on background without debugging:
473
474 wpa_supplicant -iwlan0 -c/etc/wpa_supplicant.conf -B
475
476 Please note that if you included more than one driver interface in the
477 build time configuration (.config), you may need to specify which
478 interface to use by including -D<driver name> option on the command
479 line. See following section for more details on command line options
480 for wpa_supplicant.
481
482
483
484 Command line options
485 --------------------
486
487 usage:
488 wpa_supplicant [-BddfhKLqqtuvwW] [-P<pid file>] [-g<global ctrl>] \
489 -i<ifname> -c<config file> [-C<ctrl>] [-D<driver>] [-p<driver_param>] \
490 [-b<br_ifname> [-N -i<ifname> -c<conf> [-C<ctrl>] [-D<driver>] \
491 [-p<driver_param>] [-b<br_ifname>] ...]
492
493 options:
494 -b = optional bridge interface name
495 -B = run daemon in the background
496 -c = Configuration file
497 -C = ctrl_interface parameter (only used if -c is not)
498 -i = interface name
499 -d = increase debugging verbosity (-dd even more)
500 -D = driver name
501 -f = Log output to default log location (normally /tmp)
502 -g = global ctrl_interface
503 -K = include keys (passwords, etc.) in debug output
504 -t = include timestamp in debug messages
505 -h = show this help text
506 -L = show license (GPL and BSD)
507 -p = driver parameters
508 -P = PID file
509 -q = decrease debugging verbosity (-qq even less)
510 -u = enable DBus control interface
511 -v = show version
512 -w = wait for interface to be added, if needed
513 -W = wait for a control interface monitor before starting
514 -N = start describing new interface
515
516 drivers:
517 hostap = Host AP driver (Intersil Prism2/2.5/3) [default]
518 (this can also be used with Linuxant DriverLoader)
519 hermes = Agere Systems Inc. driver (Hermes-I/Hermes-II)
520 madwifi = MADWIFI 802.11 support (Atheros, etc.) (deprecated; use wext)
521 atmel = ATMEL AT76C5XXx (USB, PCMCIA)
522 wext = Linux wireless extensions (generic)
523 ralink = Ralink Client driver
524 ndiswrapper = Linux ndiswrapper (deprecated; use wext)
525 broadcom = Broadcom wl.o driver
526 ipw = Intel ipw2100/2200 driver (old; use wext with Linux 2.6.13 or newer)
527 wired = wpa_supplicant wired Ethernet driver
528 roboswitch = wpa_supplicant Broadcom switch driver
529 bsd = BSD 802.11 support (Atheros, etc.)
530 ndis = Windows NDIS driver
531
532 In most common cases, wpa_supplicant is started with
533
534 wpa_supplicant -B -c/etc/wpa_supplicant.conf -iwlan0
535
536 This makes the process fork into background.
537
538 The easiest way to debug problems, and to get debug log for bug
539 reports, is to start wpa_supplicant on foreground with debugging
540 enabled:
541
542 wpa_supplicant -c/etc/wpa_supplicant.conf -iwlan0 -d
543
544
545 wpa_supplicant can control multiple interfaces (radios) either by
546 running one process for each interface separately or by running just
547 one process and list of options at command line. Each interface is
548 separated with -N argument. As an example, following command would
549 start wpa_supplicant for two interfaces:
550
551 wpa_supplicant \
552 -c wpa1.conf -i wlan0 -D hostap -N \
553 -c wpa2.conf -i ath0 -D madwifi
554
555
556 If the interface is added in a Linux bridge (e.g., br0), the bridge
557 interface needs to be configured to wpa_supplicant in addition to the
558 main interface:
559
560 wpa_supplicant -cw.conf -Dmadwifi -iath0 -bbr0
561
562
563 Configuration file
564 ------------------
565
566 wpa_supplicant is configured using a text file that lists all accepted
567 networks and security policies, including pre-shared keys. See
568 example configuration file, wpa_supplicant.conf, for detailed
569 information about the configuration format and supported fields.
570
571 Changes to configuration file can be reloaded be sending SIGHUP signal
572 to wpa_supplicant ('killall -HUP wpa_supplicant'). Similarly,
573 reloading can be triggered with 'wpa_cli reconfigure' command.
574
575 Configuration file can include one or more network blocks, e.g., one
576 for each used SSID. wpa_supplicant will automatically select the best
577 betwork based on the order of network blocks in the configuration
578 file, network security level (WPA/WPA2 is preferred), and signal
579 strength.
580
581 Example configuration files for some common configurations:
582
583 1) WPA-Personal (PSK) as home network and WPA-Enterprise with EAP-TLS as work
584 network
585
586 # allow frontend (e.g., wpa_cli) to be used by all users in 'wheel' group
587 ctrl_interface=/var/run/wpa_supplicant
588 ctrl_interface_group=wheel
589 #
590 # home network; allow all valid ciphers
591 network={
592 ssid="home"
593 scan_ssid=1
594 key_mgmt=WPA-PSK
595 psk="very secret passphrase"
596 }
597 #
598 # work network; use EAP-TLS with WPA; allow only CCMP and TKIP ciphers
599 network={
600 ssid="work"
601 scan_ssid=1
602 key_mgmt=WPA-EAP
603 pairwise=CCMP TKIP
604 group=CCMP TKIP
605 eap=TLS
606 identity="user (a] example.com"
607 ca_cert="/etc/cert/ca.pem"
608 client_cert="/etc/cert/user.pem"
609 private_key="/etc/cert/user.prv"
610 private_key_passwd="password"
611 }
612
613
614 2) WPA-RADIUS/EAP-PEAP/MSCHAPv2 with RADIUS servers that use old peaplabel
615 (e.g., Funk Odyssey and SBR, Meetinghouse Aegis, Interlink RAD-Series)
616
617 ctrl_interface=/var/run/wpa_supplicant
618 ctrl_interface_group=wheel
619 network={
620 ssid="example"
621 scan_ssid=1
622 key_mgmt=WPA-EAP
623 eap=PEAP
624 identity="user (a] example.com"
625 password="foobar"
626 ca_cert="/etc/cert/ca.pem"
627 phase1="peaplabel=0"
628 phase2="auth=MSCHAPV2"
629 }
630
631
632 3) EAP-TTLS/EAP-MD5-Challenge configuration with anonymous identity for the
633 unencrypted use. Real identity is sent only within an encrypted TLS tunnel.
634
635 ctrl_interface=/var/run/wpa_supplicant
636 ctrl_interface_group=wheel
637 network={
638 ssid="example"
639 scan_ssid=1
640 key_mgmt=WPA-EAP
641 eap=TTLS
642 identity="user (a] example.com"
643 anonymous_identity="anonymous (a] example.com"
644 password="foobar"
645 ca_cert="/etc/cert/ca.pem"
646 phase2="auth=MD5"
647 }
648
649
650 4) IEEE 802.1X (i.e., no WPA) with dynamic WEP keys (require both unicast and
651 broadcast); use EAP-TLS for authentication
652
653 ctrl_interface=/var/run/wpa_supplicant
654 ctrl_interface_group=wheel
655 network={
656 ssid="1x-test"
657 scan_ssid=1
658 key_mgmt=IEEE8021X
659 eap=TLS
660 identity="user (a] example.com"
661 ca_cert="/etc/cert/ca.pem"
662 client_cert="/etc/cert/user.pem"
663 private_key="/etc/cert/user.prv"
664 private_key_passwd="password"
665 eapol_flags=3
666 }
667
668
669 5) Catch all example that allows more or less all configuration modes. The
670 configuration options are used based on what security policy is used in the
671 selected SSID. This is mostly for testing and is not recommended for normal
672 use.
673
674 ctrl_interface=/var/run/wpa_supplicant
675 ctrl_interface_group=wheel
676 network={
677 ssid="example"
678 scan_ssid=1
679 key_mgmt=WPA-EAP WPA-PSK IEEE8021X NONE
680 pairwise=CCMP TKIP
681 group=CCMP TKIP WEP104 WEP40
682 psk="very secret passphrase"
683 eap=TTLS PEAP TLS
684 identity="user (a] example.com"
685 password="foobar"
686 ca_cert="/etc/cert/ca.pem"
687 client_cert="/etc/cert/user.pem"
688 private_key="/etc/cert/user.prv"
689 private_key_passwd="password"
690 phase1="peaplabel=0"
691 ca_cert2="/etc/cert/ca2.pem"
692 client_cert2="/etc/cer/user.pem"
693 private_key2="/etc/cer/user.prv"
694 private_key2_passwd="password"
695 }
696
697
698 6) Authentication for wired Ethernet. This can be used with 'wired' or
699 'roboswitch' interface (-Dwired or -Droboswitch on command line).
700
701 ctrl_interface=/var/run/wpa_supplicant
702 ctrl_interface_group=wheel
703 ap_scan=0
704 network={
705 key_mgmt=IEEE8021X
706 eap=MD5
707 identity="user"
708 password="password"
709 eapol_flags=0
710 }
711
712
713
714 Certificates
715 ------------
716
717 Some EAP authentication methods require use of certificates. EAP-TLS
718 uses both server side and client certificates whereas EAP-PEAP and
719 EAP-TTLS only require the server side certificate. When client
720 certificate is used, a matching private key file has to also be
721 included in configuration. If the private key uses a passphrase, this
722 has to be configured in wpa_supplicant.conf ("private_key_passwd").
723
724 wpa_supplicant supports X.509 certificates in PEM and DER
725 formats. User certificate and private key can be included in the same
726 file.
727
728 If the user certificate and private key is received in PKCS#12/PFX
729 format, they need to be converted to suitable PEM/DER format for
730 wpa_supplicant. This can be done, e.g., with following commands:
731
732 # convert client certificate and private key to PEM format
733 openssl pkcs12 -in example.pfx -out user.pem -clcerts
734 # convert CA certificate (if included in PFX file) to PEM format
735 openssl pkcs12 -in example.pfx -out ca.pem -cacerts -nokeys
736
737
738
739 wpa_cli
740 -------
741
742 wpa_cli is a text-based frontend program for interacting with
743 wpa_supplicant. It is used to query current status, change
744 configuration, trigger events, and request interactive user input.
745
746 wpa_cli can show the current authentication status, selected security
747 mode, dot11 and dot1x MIBs, etc. In addition, it can configure some
748 variables like EAPOL state machine parameters and trigger events like
749 reassociation and IEEE 802.1X logoff/logon. wpa_cli provides a user
750 interface to request authentication information, like username and
751 password, if these are not included in the configuration. This can be
752 used to implement, e.g., one-time-passwords or generic token card
753 authentication where the authentication is based on a
754 challenge-response that uses an external device for generating the
755 response.
756
757 The control interface of wpa_supplicant can be configured to allow
758 non-root user access (ctrl_interface_group in the configuration
759 file). This makes it possible to run wpa_cli with a normal user
760 account.
761
762 wpa_cli supports two modes: interactive and command line. Both modes
763 share the same command set and the main difference is in interactive
764 mode providing access to unsolicited messages (event messages,
765 username/password requests).
766
767 Interactive mode is started when wpa_cli is executed without including
768 the command as a command line parameter. Commands are then entered on
769 the wpa_cli prompt. In command line mode, the same commands are
770 entered as command line arguments for wpa_cli.
771
772
773 Interactive authentication parameters request
774
775 When wpa_supplicant need authentication parameters, like username and
776 password, which are not present in the configuration file, it sends a
777 request message to all attached frontend programs, e.g., wpa_cli in
778 interactive mode. wpa_cli shows these requests with
779 "CTRL-REQ-<type>-<id>:<text>" prefix. <type> is IDENTITY, PASSWORD, or
780 OTP (one-time-password). <id> is a unique identifier for the current
781 network. <text> is description of the request. In case of OTP request,
782 it includes the challenge from the authentication server.
783
784 The reply to these requests can be given with 'identity', 'password',
785 and 'otp' commands. <id> needs to be copied from the the matching
786 request. 'password' and 'otp' commands can be used regardless of
787 whether the request was for PASSWORD or OTP. The main difference
788 between these two commands is that values given with 'password' are
789 remembered as long as wpa_supplicant is running whereas values given
790 with 'otp' are used only once and then forgotten, i.e., wpa_supplicant
791 will ask frontend for a new value for every use. This can be used to
792 implement one-time-password lists and generic token card -based
793 authentication.
794
795 Example request for password and a matching reply:
796
797 CTRL-REQ-PASSWORD-1:Password needed for SSID foobar
798 > password 1 mysecretpassword
799
800 Example request for generic token card challenge-response:
801
802 CTRL-REQ-OTP-2:Challenge 1235663 needed for SSID foobar
803 > otp 2 9876
804
805
806 wpa_cli commands
807
808 status = get current WPA/EAPOL/EAP status
809 mib = get MIB variables (dot1x, dot11)
810 help = show this usage help
811 interface [ifname] = show interfaces/select interface
812 level <debug level> = change debug level
813 license = show full wpa_cli license
814 logoff = IEEE 802.1X EAPOL state machine logoff
815 logon = IEEE 802.1X EAPOL state machine logon
816 set = set variables (shows list of variables when run without arguments)
817 pmksa = show PMKSA cache
818 reassociate = force reassociation
819 reconfigure = force wpa_supplicant to re-read its configuration file
820 preauthenticate <BSSID> = force preauthentication
821 identity <network id> <identity> = configure identity for an SSID
822 password <network id> <password> = configure password for an SSID
823 pin <network id> <pin> = configure pin for an SSID
824 otp <network id> <password> = configure one-time-password for an SSID
825 passphrase <network id> <passphrase> = configure private key passphrase
826 for an SSID
827 bssid <network id> <BSSID> = set preferred BSSID for an SSID
828 list_networks = list configured networks
829 select_network <network id> = select a network (disable others)
830 enable_network <network id> = enable a network
831 disable_network <network id> = disable a network
832 add_network = add a network
833 remove_network <network id> = remove a network
834 set_network <network id> <variable> <value> = set network variables (shows
835 list of variables when run without arguments)
836 get_network <network id> <variable> = get network variables
837 save_config = save the current configuration
838 disconnect = disconnect and wait for reassociate command before connecting
839 scan = request new BSS scan
840 scan_results = get latest scan results
841 get_capability <eap/pairwise/group/key_mgmt/proto/auth_alg> = get capabilies
842 terminate = terminate wpa_supplicant
843 quit = exit wpa_cli
844
845
846 wpa_cli command line options
847
848 wpa_cli [-p<path to ctrl sockets>] [-i<ifname>] [-hvB] [-a<action file>] \
849 [-P<pid file>] [-g<global ctrl>] [command..]
850 -h = help (show this usage text)
851 -v = shown version information
852 -a = run in daemon mode executing the action file based on events from
853 wpa_supplicant
854 -B = run a daemon in the background
855 default path: /var/run/wpa_supplicant
856 default interface: first interface found in socket path
857
858
859 Using wpa_cli to run external program on connect/disconnect
860 -----------------------------------------------------------
861
862 wpa_cli can used to run external programs whenever wpa_supplicant
863 connects or disconnects from a network. This can be used, e.g., to
864 update network configuration and/or trigget DHCP client to update IP
865 addresses, etc.
866
867 One wpa_cli process in "action" mode needs to be started for each
868 interface. For example, the following command starts wpa_cli for the
869 default ingterface (-i can be used to select the interface in case of
870 more than one interface being used at the same time):
871
872 wpa_cli -a/sbin/wpa_action.sh -B
873
874 The action file (-a option, /sbin/wpa_action.sh in this example) will
875 be executed whenever wpa_supplicant completes authentication (connect
876 event) or detects disconnection). The action script will be called
877 with two command line arguments: interface name and event (CONNECTED
878 or DISCONNECTED). If the action script needs to get more information
879 about the current network, it can use 'wpa_cli status' to query
880 wpa_supplicant for more information.
881
882 Following example can be used as a simple template for an action
883 script:
884
885 #!/bin/sh
886
887 IFNAME=$1
888 CMD=$2
889
890 if [ "$CMD" == "CONNECTED" ]; then
891 SSID=`wpa_cli -i$IFNAME status | grep ^ssid= | cut -f2- -d=`
892 # configure network, signal DHCP client, etc.
893 fi
894
895 if [ "$CMD" == "DISCONNECTED" ]; then
896 # remove network configuration, if needed
897 fi
898
899
900
901 Integrating with pcmcia-cs/cardmgr scripts
902 ------------------------------------------
903
904 wpa_supplicant needs to be running when using a wireless network with
905 WPA. It can be started either from system startup scripts or from
906 pcmcia-cs/cardmgr scripts (when using PC Cards). WPA handshake must be
907 completed before data frames can be exchanged, so wpa_supplicant
908 should be started before DHCP client.
909
910 For example, following small changes to pcmcia-cs scripts can be used
911 to enable WPA support:
912
913 Add MODE="Managed" and WPA="y" to the network scheme in
914 /etc/pcmcia/wireless.opts.
915
916 Add the following block to the end of 'start' action handler in
917 /etc/pcmcia/wireless:
918
919 if [ "$WPA" = "y" -a -x /usr/local/bin/wpa_supplicant ]; then
920 /usr/local/bin/wpa_supplicant -B -c/etc/wpa_supplicant.conf \
921 -i$DEVICE
922 fi
923
924 Add the following block to the end of 'stop' action handler (may need
925 to be separated from other actions) in /etc/pcmcia/wireless:
926
927 if [ "$WPA" = "y" -a -x /usr/local/bin/wpa_supplicant ]; then
928 killall wpa_supplicant
929 fi
930
931 This will make cardmgr start wpa_supplicant when the card is plugged
932 in.
933
934
935
936 Dynamic interface add and operation without configuration files
937 ---------------------------------------------------------------
938
939 wpa_supplicant can be started without any configuration files or
940 network interfaces. When used in this way, a global (i.e., per
941 wpa_supplicant process) control interface is used to add and remove
942 network interfaces. Each network interface can then be configured
943 through a per-network interface control interface. For example,
944 following commands show how to start wpa_supplicant without any
945 network interfaces and then add a network interface and configure a
946 network (SSID):
947
948 # Start wpa_supplicant in the background
949 wpa_supplicant -g/var/run/wpa_supplicant-global -B
950
951 # Add a new interface (wlan0, no configuration file, driver=wext, and
952 # enable control interface)
953 wpa_cli -g/var/run/wpa_supplicant-global interface_add wlan0 \
954 "" wext /var/run/wpa_supplicant
955
956 # Configure a network using the newly added network interface:
957 wpa_cli -iwlan0 add_network
958 wpa_cli -iwlan0 set_network 0 ssid '"test"'
959 wpa_cli -iwlan0 set_network 0 key_mgmt WPA-PSK
960 wpa_cli -iwlan0 set_network 0 psk '"12345678"'
961 wpa_cli -iwlan0 set_network 0 pairwise TKIP
962 wpa_cli -iwlan0 set_network 0 group TKIP
963 wpa_cli -iwlan0 set_network 0 proto WPA
964 wpa_cli -iwlan0 enable_network 0
965
966 # At this point, the new network interface should start trying to associate
967 # with the WPA-PSK network using SSID test.
968
969 # Remove network interface
970 wpa_cli -g/var/run/wpa_supplicant-global interface_remove wlan0
971
972
973 Privilege separation
974 --------------------
975
976 To minimize the size of code that needs to be run with root privileges
977 (e.g., to control wireless interface operation), wpa_supplicant
978 supports optional privilege separation. If enabled, this separates the
979 privileged operations into a separate process (wpa_priv) while leaving
980 rest of the code (e.g., EAP authentication and WPA handshakes) into an
981 unprivileged process (wpa_supplicant) that can be run as non-root
982 user. Privilege separation restricts the effects of potential software
983 errors by containing the majority of the code in an unprivileged
984 process to avoid full system compromise.
985
986 Privilege separation is not enabled by default and it can be enabled
987 by adding CONFIG_PRIVSEP=y to the build configuration (.config). When
988 enabled, the privileged operations (driver wrapper and l2_packet) are
989 linked into a separate daemon program, wpa_priv. The unprivileged
990 program, wpa_supplicant, will be built with a special driver/l2_packet
991 wrappers that communicate with the privileged wpa_priv process to
992 perform the needed operations. wpa_priv can control what privileged
993 are allowed.
994
995 wpa_priv needs to be run with network admin privileges (usually, root
996 user). It opens a UNIX domain socket for each interface that is
997 included on the command line; any other interface will be off limits
998 for wpa_supplicant in this kind of configuration. After this,
999 wpa_supplicant can be run as a non-root user (e.g., all standard users
1000 on a laptop or as a special non-privileged user account created just
1001 for this purpose to limit access to user files even further).
1002
1003
1004 Example configuration:
1005 - create user group for users that are allowed to use wpa_supplicant
1006 ('wpapriv' in this example) and assign users that should be able to
1007 use wpa_supplicant into that group
1008 - create /var/run/wpa_priv directory for UNIX domain sockets and control
1009 user access by setting it accessible only for the wpapriv group:
1010 mkdir /var/run/wpa_priv
1011 chown root:wpapriv /var/run/wpa_priv
1012 chmod 0750 /var/run/wpa_priv
1013 - start wpa_priv as root (e.g., from system startup scripts) with the
1014 enabled interfaces configured on the command line:
1015 wpa_priv -B -P /var/run/wpa_priv.pid wext:ath0
1016 - run wpa_supplicant as non-root with a user that is in wpapriv group:
1017 wpa_supplicant -i ath0 -c wpa_supplicant.conf
1018
1019 wpa_priv does not use the network interface before wpa_supplicant is
1020 started, so it is fine to include network interfaces that are not
1021 available at the time wpa_priv is started. As an alternative, wpa_priv
1022 can be started when an interface is added (hotplug/udev/etc. scripts).
1023 wpa_priv can control multiple interface with one process, but it is
1024 also possible to run multiple wpa_priv processes at the same time, if
1025 desired.
1026
1 wpa_supplicant and Wi-Fi Protected Setup (WPS)
2 ==============================================
3
4 This document describes how the WPS implementation in wpa_supplicant
5 can be configured and how an external component on the client (e.g.,
6 management GUI) is used to enable WPS enrollment and registrar
7 registration.
8
9
10 Introduction to WPS
11 -------------------
12
13 Wi-Fi Protected Setup (WPS) is a mechanism for easy configuration of a
14 wireless network. It allows automated generation of random keys (WPA
15 passphrase/PSK) and configuration of an access point and client
16 devices. WPS includes number of methods for setting up connections
17 with PIN method and push-button configuration (PBC) being the most
18 commonly deployed options.
19
20 While WPS can enable more home networks to use encryption in the
21 wireless network, it should be noted that the use of the PIN and
22 especially PBC mechanisms for authenticating the initial key setup is
23 not very secure. As such, use of WPS may not be suitable for
24 environments that require secure network access without chance for
25 allowing outsiders to gain access during the setup phase.
26
27 WPS uses following terms to describe the entities participating in the
28 network setup:
29 - access point: the WLAN access point
30 - Registrar: a device that control a network and can authorize
31 addition of new devices); this may be either in the AP ("internal
32 Registrar") or in an external device, e.g., a laptop, ("external
33 Registrar")
34 - Enrollee: a device that is being authorized to use the network
35
36 It should also be noted that the AP and a client device may change
37 roles (i.e., AP acts as an Enrollee and client device as a Registrar)
38 when WPS is used to configure the access point.
39
40
41 More information about WPS is available from Wi-Fi Alliance:
42 http://www.wi-fi.org/wifi-protected-setup
43
44
45 wpa_supplicant implementation
46 -----------------------------
47
48 wpa_supplicant includes an optional WPS component that can be used as
49 an Enrollee to enroll new network credential or as a Registrar to
50 configure an AP. The current version of wpa_supplicant does not
51 support operation as an external WLAN Management Registrar for adding
52 new client devices or configuring the AP over UPnP.
53
54
55 wpa_supplicant configuration
56 ----------------------------
57
58 WPS is an optional component that needs to be enabled in
59 wpa_supplicant build configuration (.config). Here is an example
60 configuration that includes WPS support and Linux wireless extensions
61 -based driver interface:
62
63 CONFIG_DRIVER_WEXT=y
64 CONFIG_EAP=y
65 CONFIG_WPS=y
66
67
68 WPS needs the Universally Unique IDentifier (UUID; see RFC 4122) for
69 the device. This is configured in the runtime configuration for
70 wpa_supplicant (if not set, UUID will be generated based on local MAC
71 address):
72
73 # example UUID for WPS
74 uuid=12345678-9abc-def0-1234-56789abcdef0
75
76 The network configuration blocks needed for WPS are added
77 automatically based on control interface commands, so they do not need
78 to be added explicitly in the configuration file.
79
80 WPS registration will generate new network blocks for the acquired
81 credentials. If these are to be stored for future use (after
82 restarting wpa_supplicant), wpa_supplicant will need to be configured
83 to allow configuration file updates:
84
85 update_config=1
86
87
88
89 External operations
90 -------------------
91
92 WPS requires either a device PIN code (usually, 8-digit number) or a
93 pushbutton event (for PBC) to allow a new WPS Enrollee to join the
94 network. wpa_supplicant uses the control interface as an input channel
95 for these events.
96
97 If the client device has a display, a random PIN has to be generated
98 for each WPS registration session. wpa_supplicant can do this with a
99 control interface request, e.g., by calling wpa_cli:
100
101 wpa_cli wps_pin any
102
103 This will return the generated 8-digit PIN which will then need to be
104 entered at the Registrar to complete WPS registration. At that point,
105 the client will be enrolled with credentials needed to connect to the
106 AP to access the network.
107
108
109 If the client device does not have a display that could show the
110 random PIN, a hardcoded PIN that is printed on a label can be
111 used. wpa_supplicant is notified this with a control interface
112 request, e.g., by calling wpa_cli:
113
114 wpa_cli wps_pin any 12345670
115
116 This starts the WPS negotiation in the same way as above with the
117 generated PIN.
118
119
120 If the client design wants to support optional WPS PBC mode, this can
121 be enabled by either a physical button in the client device or a
122 virtual button in the user interface. The PBC operation requires that
123 a button is also pressed at the AP/Registrar at about the same time (2
124 minute window). wpa_supplicant is notified of the local button event
125 over the control interface, e.g., by calling wpa_cli:
126
127 wpa_cli wps_pbc
128
129 At this point, the AP/Registrar has two minutes to complete WPS
130 negotiation which will generate a new WPA PSK in the same way as the
131 PIN method described above.
132
133
134 If the client wants to operate in the Registrar role to configure an
135 AP, wpa_supplicant is notified over the control interface, e.g., with
136 wpa_cli:
137
138 wpa_cli wps_reg <AP BSSID> <AP PIN>
139 (example: wpa_cli wps_reg 02:34:56:78:9a:bc 12345670)
140
141 This is currently only used to fetch the current AP settings instead
142 of actually changing them. The main difference with the wps_pin
143 command is that wps_reg uses the AP PIN (e.g., from a label on the AP)
144 instead of a PIN generated at the client.
145
146
147 Scanning
148 --------
149
150 Scan results ('wpa_cli scan_results' or 'wpa_cli bss <idx>') include a
151 flags field that is used to indicate whether the BSS support WPS. If
152 the AP support WPS, but has not recently activated a Registrar, [WPS]
153 flag will be included. If PIN method has been recently selected,
154 [WPS-PIN] is shown instead. Similarly, [WPS-PBC] is shown if PBC mode
155 is in progress. GUI programs can use these as triggers for suggesting
156 a guided WPS configuration to the user. In addition, control interface
157 monitor events WPS-AP-AVAILABLE{,-PBC,-PIN} can be used to find out if
158 there are WPS enabled APs in scan results without having to go through
159 all the details in the GUI. These notification could be used, e.g., to
160 suggest possible WPS connection to the user.
161
162
163 wpa_gui
164 -------
165
166 wpa_gui-qt4 directory contains a sample GUI that shows an example of
167 how WPS support can be integrated into the GUI. Its main window has a
168 WPS tab that guides user through WPS registration with automatic AP
169 selection. In addition, it shows how WPS can be started manually by
170 selecting an AP from scan results.
171
172
173 Credential processing
174 ---------------------
175
176 By default, wpa_supplicant processes received credentials and updates
177 its configuration internally. However, it is possible to
178 control these operations from external programs, if desired.
179
180 This internal processing can be disabled with wps_cred_processing=1
181 option. When this is used, an external program is responsible for
182 processing the credential attributes and updating wpa_supplicant
183 configuration based on them.
184
185 Following control interface messages are sent out for external programs:
186
187 WPS-CRED-RECEIVED <hexdump of Credential attribute(s)>
188 For example:
189 <2>WPS-CRED-RECEIVED 100e006f10260001011045000c6a6b6d2d7770732d74657374100300020020100f000200081027004030653462303435366332363666653064333961643135353461316634626637313234333761636664623766333939653534663166316230323061643434386235102000060266a0ee1727
190