##### Example wpa_supplicant configuration file ############################### # # This file describes configuration file format and lists all available option. # Please also take a look at simpler configuration examples in 'examples' # subdirectory. # # Empty lines and lines starting with # are ignored # NOTE! This file may contain password information and should probably be made # readable only by root user on multiuser systems. # Note: All file paths in this configuration file should use full (absolute, # not relative to working directory) path in order to allow working directory # to be changed. This can happen if wpa_supplicant is run in the background. # Whether to allow wpa_supplicant to update (overwrite) configuration # # This option can be used to allow wpa_supplicant to overwrite configuration # file whenever configuration is changed (e.g., new network block is added with # wpa_cli or wpa_gui, or a password is changed). This is required for # wpa_cli/wpa_gui to be able to store the configuration changes permanently. # Please note that overwriting configuration file will remove the comments from # it. update_config=1 # global configuration (shared by all network blocks) # # Parameters for the control interface. If this is specified, wpa_supplicant # will open a control interface that is available for external programs to # manage wpa_supplicant. The meaning of this string depends on which control # interface mechanism is used. For all cases, the existance of this parameter # in configuration is used to determine whether the control interface is # enabled. # # For UNIX domain sockets (default on Linux and BSD): This is a directory that # will be created for UNIX domain sockets for listening to requests from # external programs (CLI/GUI, etc.) for status information and configuration. # The socket file will be named based on the interface name, so multiple # wpa_supplicant processes can be run at the same time if more than one # interface is used. # /var/run/wpa_supplicant is the recommended directory for sockets and by # default, wpa_cli will use it when trying to connect with wpa_supplicant. # # Access control for the control interface can be configured by setting the # directory to allow only members of a group to use sockets. This way, it is # possible to run wpa_supplicant as root (since it needs to change network # configuration and open raw sockets) and still allow GUI/CLI components to be # run as non-root users. However, since the control interface can be used to # change the network configuration, this access needs to be protected in many # cases. By default, wpa_supplicant is configured to use gid 0 (root). If you # want to allow non-root users to use the control interface, add a new group # and change this value to match with that group. Add users that should have # control interface access to this group. If this variable is commented out or # not included in the configuration file, group will not be changed from the # value it got by default when the directory or socket was created. # # When configuring both the directory and group, use following format: # DIR=/var/run/wpa_supplicant GROUP=wheel # DIR=/var/run/wpa_supplicant GROUP=0 # (group can be either group name or gid) ctrl_interface=wlan0 # IEEE 802.1X/EAPOL version # wpa_supplicant is implemented based on IEEE Std 802.1X-2004 which defines # EAPOL version 2. However, there are many APs that do not handle the new # version number correctly (they seem to drop the frames completely). In order # to make wpa_supplicant interoperate with these APs, the version number is set # to 1 by default. This configuration value can be used to set it to the new # version (2). eapol_version=1 # AP scanning/selection # By default, wpa_supplicant requests driver to perform AP scanning and then # uses the scan results to select a suitable AP. Another alternative is to # allow the driver to take care of AP scanning and selection and use # wpa_supplicant just to process EAPOL frames based on IEEE 802.11 association # information from the driver. # 1: wpa_supplicant initiates scanning and AP selection # 0: driver takes care of scanning, AP selection, and IEEE 802.11 association # parameters (e.g., WPA IE generation); this mode can also be used with # non-WPA drivers when using IEEE 802.1X mode; do not try to associate with # APs (i.e., external program needs to control association). This mode must # also be used when using wired Ethernet drivers. # 2: like 0, but associate with APs using security policy and SSID (but not # BSSID); this can be used, e.g., with ndiswrapper and NDIS drivers to # enable operation with hidden SSIDs and optimized roaming; in this mode, # the network blocks in the configuration file are tried one by one until # the driver reports successful association; each network block should have # explicit security policy (i.e., only one option in the lists) for # key_mgmt, pairwise, group, proto variables ap_scan=1 # EAP fast re-authentication # By default, fast re-authentication is enabled for all EAP methods that # support it. This variable can be used to disable fast re-authentication. # Normally, there is no need to disable this. fast_reauth=1 #Disable the default behavior of adding a separate interface for the P2P #group when driver support for concurrent interfaces is available. p2p_no_group_iface=1 # OpenSSL Engine support # These options can be used to load OpenSSL engines. # The two engines that are supported currently are shown below: # They are both from the opensc project (http://www.opensc.org/) # By default no engines are loaded. # make the opensc engine available #opensc_engine_path=/usr/lib/opensc/engine_opensc.so # make the pkcs11 engine available #pkcs11_engine_path=/usr/lib/opensc/engine_pkcs11.so # configure the path to the pkcs11 module required by the pkcs11 engine #pkcs11_module_path=/usr/lib/pkcs11/opensc-pkcs11.so # Dynamic EAP methods # If EAP methods were built dynamically as shared object files, they need to be # loaded here before being used in the network blocks. By default, EAP methods # are included statically in the build, so these lines are not needed #load_dynamic_eap=/usr/lib/wpa_supplicant/eap_tls.so #load_dynamic_eap=/usr/lib/wpa_supplicant/eap_md5.so # Driver interface parameters # This field can be used to configure arbitrary driver interace parameters. The # format is specific to the selected driver interface. This field is not used # in most cases. #driver_param="field=value" # Country code # The ISO/IEC alpha2 country code for the country in which this device is # currently operating. #country=US # Maximum lifetime for PMKSA in seconds; default 43200 #dot11RSNAConfigPMKLifetime=43200 # Threshold for reauthentication (percentage of PMK lifetime); default 70 #dot11RSNAConfigPMKReauthThreshold=70 # Timeout for security association negotiation in seconds; default 60 #dot11RSNAConfigSATimeout=60 # Wi-Fi Protected Setup (WPS) parameters # Universally Unique IDentifier (UUID; see RFC 4122) of the device # If not configured, UUID will be generated based on the local MAC address. #uuid=12345678-9abc-def0-1234-56789abcdef0 # Device Name # User-friendly description of device; up to 32 octets encoded in UTF-8 #device_name=Wireless Client # Manufacturer # The manufacturer of the device (up to 64 ASCII characters) #manufacturer=Company # Model Name # Model of the device (up to 32 ASCII characters) #model_name=cmodel # Model Number # Additional device description (up to 32 ASCII characters) #model_number=123 # Serial Number # Serial number of the device (up to 32 characters) #serial_number=12345 # Primary Device Type # Used format: <categ>-<OUI>-<subcateg> # categ = Category as an integer value # OUI = OUI and type octet as a 4-octet hex-encoded value; 0050F204 for # default WPS OUI # subcateg = OUI-specific Sub Category as an integer value # Examples: # 1-0050F204-1 (Computer / PC) # 1-0050F204-2 (Computer / Server) # 5-0050F204-1 (Storage / NAS) # 6-0050F204-1 (Network Infrastructure / AP) #device_type=1-0050F204-1 # OS Version # 4-octet operating system version number (hex string) #os_version=01020300 # Credential processing # 0 = process received credentials internally (default) # 1 = do not process received credentials; just pass them over ctrl_iface to # external program(s) # 2 = process received credentials internally and pass them over ctrl_iface # to external program(s) #wps_cred_processing=0 # network block # # Each network (usually AP's sharing the same SSID) is configured as a separate # block in this configuration file. The network blocks are in preference order # (the first match is used). # # network block fields: # # disabled: # 0 = this network can be used (default) # 1 = this network block is disabled (can be enabled through ctrl_iface, # e.g., with wpa_cli or wpa_gui) # # id_str: Network identifier string for external scripts. This value is passed # to external action script through wpa_cli as WPA_ID_STR environment # variable to make it easier to do network specific configuration. # # ssid: SSID (mandatory); either as an ASCII string with double quotation or # as hex string; network name # # scan_ssid: # 0 = do not scan this SSID with specific Probe Request frames (default) # 1 = scan with SSID-specific Probe Request frames (this can be used to # find APs that do not accept broadcast SSID or use multiple SSIDs; # this will add latency to scanning, so enable this only when needed) # # bssid: BSSID (optional); if set, this network block is used only when # associating with the AP using the configured BSSID # # priority: priority group (integer) # By default, all networks will get same priority group (0). If some of the # networks are more desirable, this field can be used to change the order in # which wpa_supplicant goes through the networks when selecting a BSS. The # priority groups will be iterated in decreasing priority (i.e., the larger the # priority value, the sooner the network is matched against the scan results). # Within each priority group, networks will be selected based on security # policy, signal strength, etc. # Please note that AP scanning with scan_ssid=1 and ap_scan=2 mode are not # using this priority to select the order for scanning. Instead, they try the # networks in the order that used in the configuration file. # # mode: IEEE 802.11 operation mode # 0 = infrastructure (Managed) mode, i.e., associate with an AP (default) # 1 = IBSS (ad-hoc, peer-to-peer) # Note: IBSS can only be used with key_mgmt NONE (plaintext and static WEP) # and key_mgmt=WPA-NONE (fixed group key TKIP/CCMP). In addition, ap_scan has # to be set to 2 for IBSS. WPA-None requires following network block options: # proto=WPA, key_mgmt=WPA-NONE, pairwise=NONE, group=TKIP (or CCMP, but not # both), and psk must also be set. # # frequency: Channel frequency in megahertz (MHz) for IBSS, e.g., # 2412 = IEEE 802.11b/g channel 1. This value is used to configure the initial # channel for IBSS (adhoc) networks. It is ignored in the infrastructure mode. # In addition, this value is only used by the station that creates the IBSS. If # an IBSS network with the configured SSID is already present, the frequency of # the network will be used instead of this configured value. # # proto: list of accepted protocols # WPA = WPA/IEEE 802.11i/D3.0 # RSN = WPA2/IEEE 802.11i (also WPA2 can be used as an alias for RSN) # If not set, this defaults to: WPA RSN # # key_mgmt: list of accepted authenticated key management protocols # WPA-PSK = WPA pre-shared key (this requires 'psk' field) # WPA-EAP = WPA using EAP authentication # IEEE8021X = IEEE 802.1X using EAP authentication and (optionally) dynamically # generated WEP keys # NONE = WPA is not used; plaintext or static WEP could be used # WPA-PSK-SHA256 = Like WPA-PSK but using stronger SHA256-based algorithms # WPA-EAP-SHA256 = Like WPA-EAP but using stronger SHA256-based algorithms # If not set, this defaults to: WPA-PSK WPA-EAP # # auth_alg: list of allowed IEEE 802.11 authentication algorithms # OPEN = Open System authentication (required for WPA/WPA2) # SHARED = Shared Key authentication (requires static WEP keys) # LEAP = LEAP/Network EAP (only used with LEAP) # If not set, automatic selection is used (Open System with LEAP enabled if # LEAP is allowed as one of the EAP methods). # # pairwise: list of accepted pairwise (unicast) ciphers for WPA # CCMP = AES in Counter mode with CBC-MAC [RFC 3610, IEEE 802.11i/D7.0] # TKIP = Temporal Key Integrity Protocol [IEEE 802.11i/D7.0] # NONE = Use only Group Keys (deprecated, should not be included if APs support # pairwise keys) # If not set, this defaults to: CCMP TKIP # # group: list of accepted group (broadcast/multicast) ciphers for WPA # CCMP = AES in Counter mode with CBC-MAC [RFC 3610, IEEE 802.11i/D7.0] # TKIP = Temporal Key Integrity Protocol [IEEE 802.11i/D7.0] # WEP104 = WEP (Wired Equivalent Privacy) with 104-bit key # WEP40 = WEP (Wired Equivalent Privacy) with 40-bit key [IEEE 802.11] # If not set, this defaults to: CCMP TKIP WEP104 WEP40 # # psk: WPA preshared key; 256-bit pre-shared key # The key used in WPA-PSK mode can be entered either as 64 hex-digits, i.e., # 32 bytes or as an ASCII passphrase (in which case, the real PSK will be # generated using the passphrase and SSID). ASCII passphrase must be between # 8 and 63 characters (inclusive). # This field is not needed, if WPA-EAP is used. # Note: Separate tool, wpa_passphrase, can be used to generate 256-bit keys # from ASCII passphrase. This process uses lot of CPU and wpa_supplicant # startup and reconfiguration time can be optimized by generating the PSK only # only when the passphrase or SSID has actually changed. # # eapol_flags: IEEE 802.1X/EAPOL options (bit field) # Dynamic WEP key required for non-WPA mode # bit0 (1): require dynamically generated unicast WEP key # bit1 (2): require dynamically generated broadcast WEP key # (3 = require both keys; default) # Note: When using wired authentication, eapol_flags must be set to 0 for the # authentication to be completed successfully. # # mixed_cell: This option can be used to configure whether so called mixed # cells, i.e., networks that use both plaintext and encryption in the same # SSID, are allowed when selecting a BSS form scan results. # 0 = disabled (default) # 1 = enabled # # proactive_key_caching: # Enable/disable opportunistic PMKSA caching for WPA2. # 0 = disabled (default) # 1 = enabled # # wep_key0..3: Static WEP key (ASCII in double quotation, e.g. "abcde" or # hex without quotation, e.g., 0102030405) # wep_tx_keyidx: Default WEP key index (TX) (0..3) # # peerkey: Whether PeerKey negotiation for direct links (IEEE 802.11e DLS) is # allowed. This is only used with RSN/WPA2. # 0 = disabled (default) # 1 = enabled #peerkey=1 # # wpa_ptk_rekey: Maximum lifetime for PTK in seconds. This can be used to # enforce rekeying of PTK to mitigate some attacks against TKIP deficiencies. # # Following fields are only used with internal EAP implementation. # eap: space-separated list of accepted EAP methods # MD5 = EAP-MD5 (unsecure and does not generate keying material -> # cannot be used with WPA; to be used as a Phase 2 method # with EAP-PEAP or EAP-TTLS) # MSCHAPV2 = EAP-MSCHAPv2 (cannot be used separately with WPA; to be used # as a Phase 2 method with EAP-PEAP or EAP-TTLS) # OTP = EAP-OTP (cannot be used separately with WPA; to be used # as a Phase 2 method with EAP-PEAP or EAP-TTLS) # GTC = EAP-GTC (cannot be used separately with WPA; to be used # as a Phase 2 method with EAP-PEAP or EAP-TTLS) # TLS = EAP-TLS (client and server certificate) # PEAP = EAP-PEAP (with tunnelled EAP authentication) # TTLS = EAP-TTLS (with tunnelled EAP or PAP/CHAP/MSCHAP/MSCHAPV2 # authentication) # If not set, all compiled in methods are allowed. # # identity: Identity string for EAP # This field is also used to configure user NAI for # EAP-PSK/PAX/SAKE/GPSK. # anonymous_identity: Anonymous identity string for EAP (to be used as the # unencrypted identity with EAP types that support different tunnelled # identity, e.g., EAP-TTLS) # password: Password string for EAP. This field can include either the # plaintext password (using ASCII or hex string) or a NtPasswordHash # (16-byte MD4 hash of password) in hash:<32 hex digits> format. # NtPasswordHash can only be used when the password is for MSCHAPv2 or # MSCHAP (EAP-MSCHAPv2, EAP-TTLS/MSCHAPv2, EAP-TTLS/MSCHAP, LEAP). # EAP-PSK (128-bit PSK), EAP-PAX (128-bit PSK), and EAP-SAKE (256-bit # PSK) is also configured using this field. For EAP-GPSK, this is a # variable length PSK. # ca_cert: File path to CA certificate file (PEM/DER). This file can have one # or more trusted CA certificates. If ca_cert and ca_path are not # included, server certificate will not be verified. This is insecure and # a trusted CA certificate should always be configured when using # EAP-TLS/TTLS/PEAP. Full path should be used since working directory may # change when wpa_supplicant is run in the background. # On Windows, trusted CA certificates can be loaded from the system # certificate store by setting this to cert_store://<name>, e.g., # ca_cert="cert_store://CA" or ca_cert="cert_store://ROOT". # Note that when running wpa_supplicant as an application, the user # certificate store (My user account) is used, whereas computer store # (Computer account) is used when running wpasvc as a service. # ca_path: Directory path for CA certificate files (PEM). This path may # contain multiple CA certificates in OpenSSL format. Common use for this # is to point to system trusted CA list which is often installed into # directory like /etc/ssl/certs. If configured, these certificates are # added to the list of trusted CAs. ca_cert may also be included in that # case, but it is not required. # client_cert: File path to client certificate file (PEM/DER) # Full path should be used since working directory may change when # wpa_supplicant is run in the background. # Alternatively, a named configuration blob can be used by setting this # to blob://<blob name>. # private_key: File path to client private key file (PEM/DER/PFX) # When PKCS#12/PFX file (.p12/.pfx) is used, client_cert should be # commented out. Both the private key and certificate will be read from # the PKCS#12 file in this case. Full path should be used since working # directory may change when wpa_supplicant is run in the background. # Windows certificate store can be used by leaving client_cert out and # configuring private_key in one of the following formats: # cert://substring_to_match # hash://certificate_thumbprint_in_hex # for example: private_key="hash://63093aa9c47f56ae88334c7b65a4" # Note that when running wpa_supplicant as an application, the user # certificate store (My user account) is used, whereas computer store # (Computer account) is used when running wpasvc as a service. # Alternatively, a named configuration blob can be used by setting this # to blob://<blob name>. # private_key_passwd: Password for private key file (if left out, this will be # asked through control interface) # dh_file: File path to DH/DSA parameters file (in PEM format) # This is an optional configuration file for setting parameters for an # ephemeral DH key exchange. In most cases, the default RSA # authentication does not use this configuration. However, it is possible # setup RSA to use ephemeral DH key exchange. In addition, ciphers with # DSA keys always use ephemeral DH keys. This can be used to achieve # forward secrecy. If the file is in DSA parameters format, it will be # automatically converted into DH params. # subject_match: Substring to be matched against the subject of the # authentication server certificate. If this string is set, the server # sertificate is only accepted if it contains this string in the subject. # The subject string is in following format: # /C=US/ST=CA/L=San Francisco/CN=Test AS/emailAddress=as@example.com # altsubject_match: Semicolon separated string of entries to be matched against # the alternative subject name of the authentication server certificate. # If this string is set, the server sertificate is only accepted if it # contains one of the entries in an alternative subject name extension. # altSubjectName string is in following format: TYPE:VALUE # Example: EMAIL:server@example.com # Example: DNS:server.example.com;DNS:server2.example.com # Following types are supported: EMAIL, DNS, URI # phase1: Phase1 (outer authentication, i.e., TLS tunnel) parameters # (string with field-value pairs, e.g., "peapver=0" or # "peapver=1 peaplabel=1") # 'peapver' can be used to force which PEAP version (0 or 1) is used. # 'peaplabel=1' can be used to force new label, "client PEAP encryption", # to be used during key derivation when PEAPv1 or newer. Most existing # PEAPv1 implementation seem to be using the old label, "client EAP # encryption", and wpa_supplicant is now using that as the default value. # Some servers, e.g., Radiator, may require peaplabel=1 configuration to # interoperate with PEAPv1; see eap_testing.txt for more details. # 'peap_outer_success=0' can be used to terminate PEAP authentication on # tunneled EAP-Success. This is required with some RADIUS servers that # implement draft-josefsson-pppext-eap-tls-eap-05.txt (e.g., # Lucent NavisRadius v4.4.0 with PEAP in "IETF Draft 5" mode) # include_tls_length=1 can be used to force wpa_supplicant to include # TLS Message Length field in all TLS messages even if they are not # fragmented. # sim_min_num_chal=3 can be used to configure EAP-SIM to require three # challenges (by default, it accepts 2 or 3) # result_ind=1 can be used to enable EAP-SIM and EAP-AKA to use # protected result indication. # 'crypto_binding' option can be used to control PEAPv0 cryptobinding # behavior: # * 0 = do not use cryptobinding (default) # * 1 = use cryptobinding if server supports it # * 2 = require cryptobinding # EAP-WSC (WPS) uses following options: pin=<Device Password> or # pbc=1. # phase2: Phase2 (inner authentication with TLS tunnel) parameters # (string with field-value pairs, e.g., "auth=MSCHAPV2" for EAP-PEAP or # "autheap=MSCHAPV2 autheap=MD5" for EAP-TTLS) # Following certificate/private key fields are used in inner Phase2 # authentication when using EAP-TTLS or EAP-PEAP. # ca_cert2: File path to CA certificate file. This file can have one or more # trusted CA certificates. If ca_cert2 and ca_path2 are not included, # server certificate will not be verified. This is insecure and a trusted # CA certificate should always be configured. # ca_path2: Directory path for CA certificate files (PEM) # client_cert2: File path to client certificate file # private_key2: File path to client private key file # private_key2_passwd: Password for private key file # dh_file2: File path to DH/DSA parameters file (in PEM format) # subject_match2: Substring to be matched against the subject of the # authentication server certificate. # altsubject_match2: Substring to be matched against the alternative subject # name of the authentication server certificate. # # fragment_size: Maximum EAP fragment size in bytes (default 1398). # This value limits the fragment size for EAP methods that support # fragmentation (e.g., EAP-TLS and EAP-PEAP). This value should be set # small enough to make the EAP messages fit in MTU of the network # interface used for EAPOL. The default value is suitable for most # cases. # # EAP-FAST variables: # pac_file: File path for the PAC entries. wpa_supplicant will need to be able # to create this file and write updates to it when PAC is being # provisioned or refreshed. Full path to the file should be used since # working directory may change when wpa_supplicant is run in the # background. Alternatively, a named configuration blob can be used by # setting this to blob://<blob name> # phase1: fast_provisioning option can be used to enable in-line provisioning # of EAP-FAST credentials (PAC): # 0 = disabled, # 1 = allow unauthenticated provisioning, # 2 = allow authenticated provisioning, # 3 = allow both unauthenticated and authenticated provisioning # fast_max_pac_list_len=<num> option can be used to set the maximum # number of PAC entries to store in a PAC list (default: 10) # fast_pac_format=binary option can be used to select binary format for # storing PAC entries in order to save some space (the default # text format uses about 2.5 times the size of minimal binary # format) # # wpa_supplicant supports number of "EAP workarounds" to work around # interoperability issues with incorrectly behaving authentication servers. # These are enabled by default because some of the issues are present in large # number of authentication servers. Strict EAP conformance mode can be # configured by disabling workarounds with eap_workaround=0. # Example blocks: # Simple case: WPA-PSK, PSK as an ASCII passphrase, allow all valid ciphers #network={ # ssid="simple" # psk="very secret passphrase" # priority=5 #} # ## Same as previous, but request SSID-specific scanning (for APs that reject ## broadcast SSID) #network={ # ssid="second ssid" # scan_ssid=1 # psk="very secret passphrase" # priority=2 #} # ## Only WPA-PSK is used. Any valid cipher combination is accepted. #network={ # ssid="example" # proto=WPA # key_mgmt=WPA-PSK # pairwise=CCMP TKIP # group=CCMP TKIP WEP104 WEP40 # psk=06b4be19da289f475aa46a33cb793029d4ab3db7a23ee92382eb0106c72ac7bb # priority=2 #} # ## WPA-Personal(PSK) with TKIP and enforcement for frequent PTK rekeying #network={ # ssid="example" # proto=WPA # key_mgmt=WPA-PSK # pairwise=TKIP # group=TKIP # psk="not so secure passphrase" # wpa_ptk_rekey=600 #} # ## Only WPA-EAP is used. Both CCMP and TKIP is accepted. An AP that used WEP104 ## or WEP40 as the group cipher will not be accepted. #network={ # ssid="example" # proto=RSN # key_mgmt=WPA-EAP # pairwise=CCMP TKIP # group=CCMP TKIP # eap=TLS # identity="user@example.com" # ca_cert="/etc/cert/ca.pem" # client_cert="/etc/cert/user.pem" # private_key="/etc/cert/user.prv" # private_key_passwd="password" # priority=1 #} # ## EAP-PEAP/MSCHAPv2 configuration for RADIUS servers that use the new peaplabel ## (e.g., Radiator) #network={ # ssid="example" # key_mgmt=WPA-EAP # eap=PEAP # identity="user@example.com" # password="foobar" # ca_cert="/etc/cert/ca.pem" # phase1="peaplabel=1" # phase2="auth=MSCHAPV2" # priority=10 #} # ## EAP-TTLS/EAP-MD5-Challenge configuration with anonymous identity for the ## unencrypted use. Real identity is sent only within an encrypted TLS tunnel. #network={ # ssid="example" # key_mgmt=WPA-EAP # eap=TTLS # identity="user@example.com" # anonymous_identity="anonymous@example.com" # password="foobar" # ca_cert="/etc/cert/ca.pem" # priority=2 #} # ## EAP-TTLS/MSCHAPv2 configuration with anonymous identity for the unencrypted ## use. Real identity is sent only within an encrypted TLS tunnel. #network={ # ssid="example" # key_mgmt=WPA-EAP # eap=TTLS # identity="user@example.com" # anonymous_identity="anonymous@example.com" # password="foobar" # ca_cert="/etc/cert/ca.pem" # phase2="auth=MSCHAPV2" #} # ## WPA-EAP, EAP-TTLS with different CA certificate used for outer and inner ## authentication. #network={ # ssid="example" # key_mgmt=WPA-EAP # eap=TTLS # # Phase1 / outer authentication # anonymous_identity="anonymous@example.com" # ca_cert="/etc/cert/ca.pem" # # Phase 2 / inner authentication # phase2="autheap=TLS" # ca_cert2="/etc/cert/ca2.pem" # client_cert2="/etc/cer/user.pem" # private_key2="/etc/cer/user.prv" # private_key2_passwd="password" # priority=2 #} # ## Both WPA-PSK and WPA-EAP is accepted. Only CCMP is accepted as pairwise and ## group cipher. #network={ # ssid="example" # bssid=00:11:22:33:44:55 # proto=WPA RSN # key_mgmt=WPA-PSK WPA-EAP # pairwise=CCMP # group=CCMP # psk=06b4be19da289f475aa46a33cb793029d4ab3db7a23ee92382eb0106c72ac7bb #} # ## Special characters in SSID, so use hex string. Default to WPA-PSK, WPA-EAP ## and all valid ciphers. #network={ # ssid=00010203 # psk=000102030405060708090a0b0c0d0e0f101112131415161718191a1b1c1d1e1f #} # # ## EAP-SIM with a GSM SIM or USIM #network={ # ssid="eap-sim-test" # key_mgmt=WPA-EAP # eap=SIM # pin="1234" # pcsc="" #} # # ## EAP-PSK #network={ # ssid="eap-psk-test" # key_mgmt=WPA-EAP # eap=PSK # anonymous_identity="eap_psk_user" # password=06b4be19da289f475aa46a33cb793029 # identity="eap_psk_user@example.com" #} # # ## IEEE 802.1X/EAPOL with dynamically generated WEP keys (i.e., no WPA) using ## EAP-TLS for authentication and key generation; require both unicast and ## broadcast WEP keys. #network={ # ssid="1x-test" # key_mgmt=IEEE8021X # eap=TLS # identity="user@example.com" # ca_cert="/etc/cert/ca.pem" # client_cert="/etc/cert/user.pem" # private_key="/etc/cert/user.prv" # private_key_passwd="password" # eapol_flags=3 #} # # ## LEAP with dynamic WEP keys #network={ # ssid="leap-example" # key_mgmt=IEEE8021X # eap=LEAP # identity="user" # password="foobar" #} # ## EAP-IKEv2 using shared secrets for both server and peer authentication #network={ # ssid="ikev2-example" # key_mgmt=WPA-EAP # eap=IKEV2 # identity="user" # password="foobar" #} # ## EAP-FAST with WPA (WPA or WPA2) #network={ # ssid="eap-fast-test" # key_mgmt=WPA-EAP # eap=FAST # anonymous_identity="FAST-000102030405" # identity="username" # password="password" # phase1="fast_provisioning=1" # pac_file="/etc/wpa_supplicant.eap-fast-pac" #} # #network={ # ssid="eap-fast-test" # key_mgmt=WPA-EAP # eap=FAST # anonymous_identity="FAST-000102030405" # identity="username" # password="password" # phase1="fast_provisioning=1" # pac_file="blob://eap-fast-pac" #} # ## Plaintext connection (no WPA, no IEEE 802.1X) #network={ # ssid="plaintext-test" # key_mgmt=NONE #} # # ## Shared WEP key connection (no WPA, no IEEE 802.1X) #network={ # ssid="static-wep-test" # key_mgmt=NONE # wep_key0="abcde" # wep_key1=0102030405 # wep_key2="1234567890123" # wep_tx_keyidx=0 # priority=5 #} # # ## Shared WEP key connection (no WPA, no IEEE 802.1X) using Shared Key ## IEEE 802.11 authentication #network={ # ssid="static-wep-test2" # key_mgmt=NONE # wep_key0="abcde" # wep_key1=0102030405 # wep_key2="1234567890123" # wep_tx_keyidx=0 # priority=5 # auth_alg=SHARED #} # # ## IBSS/ad-hoc network with WPA-None/TKIP. #network={ # ssid="test adhoc" # mode=1 # frequency=2412 # proto=WPA # key_mgmt=WPA-NONE # pairwise=NONE # group=TKIP # psk="secret passphrase" #} # # ## Catch all example that allows more or less all configuration modes #network={ # ssid="example" # scan_ssid=1 # key_mgmt=WPA-EAP WPA-PSK IEEE8021X NONE # pairwise=CCMP TKIP # group=CCMP TKIP WEP104 WEP40 # psk="very secret passphrase" # eap=TTLS PEAP TLS # identity="user@example.com" # password="foobar" # ca_cert="/etc/cert/ca.pem" # client_cert="/etc/cert/user.pem" # private_key="/etc/cert/user.prv" # private_key_passwd="password" # phase1="peaplabel=0" #} # ## Example of EAP-TLS with smartcard (openssl engine) #network={ # ssid="example" # key_mgmt=WPA-EAP # eap=TLS # proto=RSN # pairwise=CCMP TKIP # group=CCMP TKIP # identity="user@example.com" # ca_cert="/etc/cert/ca.pem" # client_cert="/etc/cert/user.pem" # # engine=1 # # # The engine configured here must be available. Look at # # OpenSSL engine support in the global section. # # The key available through the engine must be the private key # # matching the client certificate configured above. # # # use the opensc engine # #engine_id="opensc" # #key_id="45" # # # use the pkcs11 engine # engine_id="pkcs11" # key_id="id_45" # # # Optional PIN configuration; this can be left out and PIN will be # # asked through the control interface # pin="1234" #} # ## Example configuration showing how to use an inlined blob as a CA certificate ## data instead of using external file #network={ # ssid="example" # key_mgmt=WPA-EAP # eap=TTLS # identity="user@example.com" # anonymous_identity="anonymous@example.com" # password="foobar" # ca_cert="blob://exampleblob" # priority=20 #} # #blob-base64-exampleblob={ #SGVsbG8gV29ybGQhCg== #} # Wildcard match for SSID (plaintext APs only). This example select any # open AP regardless of its SSID. #network={ # key_mgmt=NONE #}