{# j2lint: disable=operator-enclosed-by-spaces #} ### Autogenerated by interfaces_wireless.py ### ### hostapd.conf reference: ### https://w1.fi/cgit/hostap/tree/hostapd/hostapd.conf?h=hostap_2_10&id=cff80b4f7d3c0a47c052e8187d671710f48939e4 {% if description is vyos_defined %} # Description: {{ description }} # User-friendly description of device; up to 32 octets encoded in UTF-8 device_name={{ description | truncate(32, True) }} {% endif %} interface={{ ifname }} {% if is_bridge_member is vyos_defined %} {# as there can only be one bridge interface it is save to loop #} {% for bridge in is_bridge_member %} bridge={{ bridge }} {% endfor %} wds_sta=1 {% endif %} driver=nl80211 logger_syslog=-1 logger_syslog_level=0 logger_stdout=-1 logger_stdout_level=0 {# regulatory domain and protocol stuff #} {% if country_code %} {# Watch out for default value of "00" - World Regulatory Domain is set by "XX" in hostapd.conf #} {% if '00' in country_code %} country_code=XX {% else %} country_code={{ country_code | upper }} {% endif %} ieee80211d=1 {% endif %} {% if ssid %} ssid={{ ssid }} {% endif %} {% if channel %} channel={{ channel }} {% endif %} {% if mode is vyos_defined %} {% if mode is vyos_defined('n') %} hw_mode=g {% elif mode is vyos_defined('ac') %} hw_mode=a ieee80211h=1 ieee80211ac=1 {% elif mode is vyos_defined('ax') %} hw_mode=a ieee80211h=1 ieee80211ax=1 {% else %} hw_mode={{ mode }} {% endif %} {% endif %} {% if 'disabled' in mgmt_frame_protection %} ieee80211w=0 {% elif 'optional' in mgmt_frame_protection %} ieee80211w=1 {% elif 'required' in mgmt_frame_protection %} ieee80211w=2 {% endif %} {% if enable_bf_protection is vyos_defined %} beacon_prot=1 {% else %} beacon_prot=0 {% endif %} {# HT (802.11n 2.4GHz and 5GHz) #} {% if capabilities.ht is vyos_defined %} {% set output = namespace(value='') %} {% if capabilities.ht.fourtymhz_incapable is vyos_defined %} {% set output.value = output.value ~ '[40-INTOLERANT]' %} {% endif %} {% if capabilities.ht.delayed_block_ack is vyos_defined %} {% set output.value = output.value ~ '[DELAYED-BA]' %} {% endif %} {% if capabilities.ht.dsss_cck_40 is vyos_defined %} {% set output.value = output.value ~ '[DSSS_CCK-40]' %} {% endif %} {% if capabilities.ht.greenfield is vyos_defined %} {% set output.value = output.value ~ '[GF]' %} {% endif %} {% if capabilities.ht.ldpc is vyos_defined %} {% set output.value = output.value ~ '[LDPC]' %} {% endif %} {% if capabilities.ht.lsig_protection is vyos_defined %} {% set output.value = output.value ~ '[LSIG-TXOP-PROT]' %} {% endif %} {% if capabilities.ht.stbc.tx is vyos_defined %} {% set output.value = output.value ~ '[TX-STBC]' %} {% endif %} {% if capabilities.ht.stbc.rx is vyos_defined %} {% set output.value = output.value ~ '[RX-STBC-' ~ capabilities.ht.stbc.rx | upper ~ ']' %} {% endif %} {% if capabilities.ht.max_amsdu is vyos_defined %} {% set output.value = output.value ~ '[MAX-AMSDU-' ~ capabilities.ht.max_amsdu ~ ']' %} {% endif %} {% if capabilities.ht.smps is vyos_defined %} {% set output.value = output.value ~ '[SMPS-' ~ capabilities.ht.smps | upper ~ ']' %} {% endif %} {% if capabilities.ht.channel_set_width is vyos_defined %} {% for csw in capabilities.ht.channel_set_width %} {% set output.value = output.value ~ '[' ~ csw | upper ~ ']' %} {% endfor %} {% endif %} {% if capabilities.ht.short_gi is vyos_defined %} {% for short_gi in capabilities.ht.short_gi %} {% set output.value = output.value ~ '[SHORT-GI-' ~ short_gi | upper ~ ']' %} {% endfor %} {% endif %} ht_capab={{ output.value }} {% if capabilities.ht.auto_powersave is vyos_defined %} uapsd_advertisement_enabled=1 {% endif %} {% endif %} {% if capabilities.require_ht is vyos_defined %} require_ht=1 {% endif %} {# VHT (802.11ac 5GHz) #} {% if capabilities.vht is vyos_defined %} {% if capabilities.vht.center_channel_freq.freq_1 is vyos_defined %} vht_oper_centr_freq_seg0_idx={{ capabilities.vht.center_channel_freq.freq_1 }} {% endif %} {% if capabilities.vht.center_channel_freq.freq_2 is vyos_defined %} vht_oper_centr_freq_seg1_idx={{ capabilities.vht.center_channel_freq.freq_2 }} {% endif %} {% if capabilities.vht.channel_set_width is vyos_defined %} vht_oper_chwidth={{ capabilities.vht.channel_set_width }} {% endif %} {% set output = namespace(value='') %} {% if capabilities.vht.channel_set_width is vyos_defined('2') %} {% set output.value = output.value ~ '[VHT160]' %} {% elif capabilities.vht.channel_set_width is vyos_defined('3') %} {% set output.value = output.value ~ '[VHT160-80PLUS80]' %} {% endif %} {% if capabilities.vht.stbc.tx is vyos_defined %} {% set output.value = output.value ~ '[TX-STBC-2BY1]' %} {% endif %} {% if capabilities.vht.stbc.rx is vyos_defined %} {% set output.value = output.value ~ '[RX-STBC-' ~ capabilities.vht.stbc.rx ~ ']' %} {% endif %} {% if capabilities.vht.ldpc is vyos_defined %} {% set output.value = output.value ~ '[RXLDPC]' %} {% endif %} {% if capabilities.vht.tx_powersave is vyos_defined %} {% set output.value = output.value ~ '[VHT-TXOP-PS]' %} {% endif %} {% if capabilities.vht.vht_cf is vyos_defined %} {% set output.value = output.value ~ '[HTC-VHT]' %} {% endif %} {% if capabilities.vht.antenna_pattern_fixed is vyos_defined %} {% set output.value = output.value ~ '[RX-ANTENNA-PATTERN][TX-ANTENNA-PATTERN]' %} {% endif %} {% if capabilities.vht.max_mpdu is vyos_defined %} {% set output.value = output.value ~ '[MAX-MPDU-' ~ capabilities.vht.max_mpdu ~ ']' %} {% endif %} {% if capabilities.vht.max_mpdu_exp is vyos_defined %} {% set output.value = output.value ~ '[MAX-A-MPDU-LEN-EXP-' ~ capabilities.vht.max_mpdu_exp ~ ']' %} {% endif %} {% if capabilities.vht.link_adaptation is vyos_defined('unsolicited') %} {% set output.value = output.value ~ '[VHT-LINK-ADAPT2]' %} {% elif capabilities.vht.link_adaptation is vyos_defined('both') %} {% set output.value = output.value ~ '[VHT-LINK-ADAPT3]' %} {% endif %} {% for short_gi in capabilities.vht.short_gi if capabilities.vht.short_gi is vyos_defined %} {% set output.value = output.value ~ '[SHORT-GI-' ~ short_gi | upper ~ ']' %} {% endfor %} {% if capabilities.vht.beamform is vyos_defined %} {% for bf in capabilities.vht.beamform %} {% set output.value = output.value ~ '[SU-BEAMFORMER]' if bf is vyos_defined('single-user-beamformer') else output.value %} {% set output.value = output.value ~ '[SU-BEAMFORMEE]' if bf is vyos_defined('single-user-beamformee') else output.value %} {% set output.value = output.value ~ '[MU-BEAMFORMER]' if bf is vyos_defined('multi-user-beamformer') else output.value %} {% set output.value = output.value ~ '[MU-BEAMFORMEE]' if bf is vyos_defined('multi-user-beamformee') else output.value %} {% endfor %} {% if capabilities.vht.antenna_count is vyos_defined and capabilities.vht.antenna_count | int > 1 %} {% if 'single-user-beamformer' in capabilities.vht.beamform %} {% if capabilities.vht.antenna_count is vyos_defined and capabilities.vht.antenna_count | int > 1 and capabilities.vht.antenna_count | int < 6 %} {% set dimension = capabilities.vht.antenna_count | int - 1 %} {% set output.value = output.value ~ '[BF-ANTENNA-' ~ dimension ~ ']' %} {% set output.value = output.value ~ '[SOUNDING-DIMENSION-' ~ dimension ~ ']' %} {% endif %} {% else %} {% if capabilities.vht.antenna_count is vyos_defined and capabilities.vht.antenna_count | int > 1 and capabilities.vht.antenna_count | int < 5 %} {% set output.value = output.value ~ '[BF-ANTENNA-' ~ capabilities.vht.antenna_count ~ ']' %} {% set output.value = output.value ~ '[SOUNDING-DIMENSION-' ~ capabilities.vht.antenna_count ~ ']' %} {% endif %} {% endif %} {% endif %} {% endif %} vht_capab={{ output.value }} {% endif %} {# TODO: Research if require_(ht|vht|he) are mutually exclusive! #} {% if capabilities.require_vht is vyos_defined or capabilities.require_he is vyos_defined %} {% if capabilities.require_vht is vyos_defined %} ieee80211n=0 require_vht=1 {% endif %} {% if capabilities.require_he is vyos_defined %} ieee80211n=0 require_he=1 {% endif %} {% else %} ieee80211n={{ '1' if 'n' in mode or 'ac' in mode or 'ax' in mode else '0' }} {% endif %} {# HE (802.11ax 6GHz) #} {% if capabilities.he is vyos_defined and mode in 'ax' %} {# For now, hard-code power levels for indoor-only AP #} he_6ghz_reg_pwr_type=0 {# If we had an option to set indoor/outdoor/all environments for a reg domain, we would need to configure the country3 value as well! #} {# country3=0x4f #} {% if capabilities.he.center_channel_freq.freq_1 is vyos_defined %} he_oper_centr_freq_seg0_idx={{ capabilities.he.center_channel_freq.freq_1 }} {% endif %} {% if capabilities.he.center_channel_freq.freq_2 is vyos_defined %} he_oper_centr_freq_seg1_idx={{ capabilities.he.center_channel_freq.freq_2 }} {% endif %} {% if capabilities.he.channel_set_width is vyos_defined %} op_class={{ capabilities.he.channel_set_width }} {% endif %} {% if capabilities.he.bss_color is vyos_defined %} he_bss_color={{ capabilities.he.bss_color }} {% endif %} he_6ghz_rx_ant_pat={{ '1' if capabilities.he.antenna_pattern_fixed is vyos_defined else '0' }} he_su_beamformer={{ '1' if capabilities.he.beamform.single_user_beamformer is vyos_defined else '0' }} he_su_beamformee={{ '1' if capabilities.he.beamform.single_user_beamformee is vyos_defined else '0' }} he_mu_beamformer={{ '1' if capabilities.he.beamform.multi_user_beamformer is vyos_defined else '0' }} {% endif %} {# generic stuff #} {% if disable_broadcast_ssid is vyos_defined %} ignore_broadcast_ssid=1 {% endif %} {% if type is vyos_defined('access-point') %} macaddr_acl={{ '0' if security.station_address.mode is vyos_defined('accept') else '1' }} accept_mac_file={{ hostapd_accept_station_conf }} deny_mac_file={{ hostapd_deny_station_conf }} {% endif %} {% if stationary_ap is vyos_defined %} stationary_ap=1 {% endif %} {% if max_stations is vyos_defined %} max_num_sta={{ max_stations }} {% endif %} {% if isolate_stations is vyos_defined %} ap_isolate=1 {% endif %} {# enable_background_radar not yet supported by VyOS's version of hostapd {% if background_radar_detection is vyos_defined %} enable_background_radar=1 {% endif %} #} {% if reduce_transmit_power is vyos_defined %} local_pwr_constraint={{ reduce_transmit_power }} {% endif %} {% if expunge_failing_stations is vyos_defined %} disassoc_low_ack=1 {% endif %} {% if security.wep is vyos_defined %} auth_algs=2 wep_key_len_broadcast=5 wep_key_len_unicast=5 wep_default_key=0 {% if security.wep.key is vyos_defined %} {% for key in sec_wep_key %} wep_key{{ loop.index -1 }}={{ security.wep.key }} {% endfor %} {% endif %} {% elif security.wpa is vyos_defined %} auth_algs=1 {% if security.wpa.mode is vyos_defined('wpa+wpa2') %} wpa=3 {% elif security.wpa.mode is vyos_defined('wpa2') or security.wpa.mode is vyos_defined('wpa3') %} wpa=2 {% elif security.wpa.mode is vyos_defined('wpa') %} wpa=1 {% endif %} {% if security.wpa.cipher is vyos_defined %} {% if security.wpa.mode is vyos_defined('wpa2') or security.wpa.mode is vyos_defined('wpa3') %} rsn_pairwise={{ security.wpa.cipher | join(" ") }} {% else %} wpa_pairwise={{ security.wpa.cipher | join(" ") }} {% endif %} {% endif %} {% if security.wpa.group_cipher is vyos_defined %} group_cipher={{ security.wpa.group_cipher }} {% endif %} {% if security.wpa.group_mgmt_cipher is vyos_defined %} group_mgmt_cipher={{ security.wpa.group_mgmt_cipher }} {% endif %} {% if security.wpa.passphrase is vyos_defined %} {% if security.wpa.mode is vyos_defined('wpa3') %} wpa_key_mgmt=SAE sae_password={{ security.wpa.passphrase }} extended_key_id=1 wpa_gmk_rekey=86400 wpa_group_rekey=86400 wpa_group_update_count=4 {% else %} wpa_key_mgmt=WPA-PSK WPA-PSK-SHA256 wpa_passphrase={{ security.wpa.passphrase }} {% endif %} {% elif security.wpa.radius is vyos_defined %} ieee8021x=1 {% if security.wpa.mode is vyos_defined('wpa3') %} wpa_key_mgmt=WPA-EAP-SUITE-B-192 {% else %} wpa_key_mgmt=WPA-EAP WPA-EAP-SHA256 {% endif %} {% if security.wpa.radius.server is vyos_defined %} {% if security.wpa.radius.source_address is vyos_defined %} radius_client_addr={{ security.wpa.radius.source_address }} own_ip_addr={{ security.wpa.radius.source_address }} {% else %} own_ip_addr=127.0.0.1 {% endif %} {% for radius in security.wpa.radius.server if not radius.disabled %} auth_server_addr={{ radius.server }} auth_server_port={{ radius.port }} auth_server_shared_secret={{ radius.key }} {% if radius.acc_port %} acct_server_addr={{ radius.server }} acct_server_port={{ radius.acc_port }} acct_server_shared_secret={{ radius.key }} {% endif %} {% endfor %} {% else %} auth_algs=1 {% endif %} {% endif %} {% endif %} tx_queue_data3_aifs=7 tx_queue_data3_cwmin=15 tx_queue_data3_cwmax=1023 tx_queue_data3_burst=0 tx_queue_data2_aifs=3 tx_queue_data2_cwmin=15 tx_queue_data2_cwmax=63 tx_queue_data2_burst=0 tx_queue_data1_aifs=1 tx_queue_data1_cwmin=7 tx_queue_data1_cwmax=15 tx_queue_data1_burst=3.0 tx_queue_data0_aifs=1 tx_queue_data0_cwmin=3 tx_queue_data0_cwmax=7 tx_queue_data0_burst=1.5 wme_enabled=1 wmm_enabled=1 wmm_ac_bk_cwmin=4 wmm_ac_bk_cwmax=10 wmm_ac_bk_aifs=7 wmm_ac_bk_txop_limit=0 wmm_ac_bk_acm=0 wmm_ac_be_aifs=3 wmm_ac_be_cwmin=4 wmm_ac_be_cwmax=10 wmm_ac_be_txop_limit=0 wmm_ac_be_acm=0 wmm_ac_vi_aifs=2 wmm_ac_vi_cwmin=3 wmm_ac_vi_cwmax=4 wmm_ac_vi_txop_limit=94 wmm_ac_vi_acm=0 wmm_ac_vo_aifs=2 wmm_ac_vo_cwmin=2 wmm_ac_vo_cwmax=3 wmm_ac_vo_txop_limit=47 wmm_ac_vo_acm=0 {# # hostapd.conf for hostapd 2.10 # hostapd.conf reference: # https://w1.fi/cgit/hostap/tree/hostapd/hostapd.conf?h=hostap_2_10&id=cff80b4f7d3c0a47c052e8187d671710f48939e4 ##### hostapd configuration file ############################################## # Empty lines and lines starting with # are ignored # AP netdevice name (without 'ap' postfix, i.e., wlan0 uses wlan0ap for # management frames with the Host AP driver); wlan0 with many nl80211 drivers # Note: This attribute can be overridden by the values supplied with the '-i' # command line parameter. interface=wlan0 # In case of atheros and nl80211 driver interfaces, an additional # configuration parameter, bridge, may be used to notify hostapd if the # interface is included in a bridge. This parameter is not used with Host AP # driver. If the bridge parameter is not set, the drivers will automatically # figure out the bridge interface (assuming sysfs is enabled and mounted to # /sys) and this parameter may not be needed. # # For nl80211, this parameter can be used to request the AP interface to be # added to the bridge automatically (brctl may refuse to do this before hostapd # has been started to change the interface mode). If needed, the bridge # interface is also created. #bridge=br0 # Driver interface type (hostap/wired/none/nl80211/bsd); # default: hostap). nl80211 is used with all Linux mac80211 drivers. # Use driver=none if building hostapd as a standalone RADIUS server that does # not control any wireless/wired driver. # driver=hostap # Driver interface parameters (mainly for development testing use) # driver_params=<params> # hostapd event logger configuration # # Two output method: syslog and stdout (only usable if not forking to # background). # # Module bitfield (ORed bitfield of modules that will be logged; -1 = all # modules): # bit 0 (1) = IEEE 802.11 # bit 1 (2) = IEEE 802.1X # bit 2 (4) = RADIUS # bit 3 (8) = WPA # bit 4 (16) = driver interface # bit 6 (64) = MLME # # Levels (minimum value for logged events): # 0 = verbose debugging # 1 = debugging # 2 = informational messages # 3 = notification # 4 = warning # logger_syslog=-1 logger_syslog_level=2 logger_stdout=-1 logger_stdout_level=2 # Interface for separate control program. If this is specified, hostapd # will create this directory and a UNIX domain socket 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 hostapd processes/interfaces can be run at the same time if more # than one interface is used. # /var/run/hostapd is the recommended directory for sockets and by default, # hostapd_cli will use it when trying to connect with hostapd. ctrl_interface=/var/run/hostapd # 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 hostapd 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, hostapd 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. # # This variable can be a group name or gid. #ctrl_interface_group=wheel ctrl_interface_group=0 ##### IEEE 802.11 related configuration ####################################### # SSID to be used in IEEE 802.11 management frames ssid=test # Alternative formats for configuring SSID # (double quoted string, hexdump, printf-escaped string) #ssid2="test" #ssid2=74657374 #ssid2=P"hello\nthere" # UTF-8 SSID: Whether the SSID is to be interpreted using UTF-8 encoding #utf8_ssid=1 # Country code (ISO/IEC 3166-1). Used to set regulatory domain. # Set as needed to indicate country in which device is operating. # This can limit available channels and transmit power. # These two octets are used as the first two octets of the Country String # (dot11CountryString) #country_code=US # The third octet of the Country String (dot11CountryString) # This parameter is used to set the third octet of the country string. # # All environments of the current frequency band and country (default) #country3=0x20 # Outdoor environment only #country3=0x4f # Indoor environment only #country3=0x49 # Noncountry entity (country_code=XX) #country3=0x58 # IEEE 802.11 standard Annex E table indication: 0x01 .. 0x1f # Annex E, Table E-4 (Global operating classes) #country3=0x04 # Enable IEEE 802.11d. This advertises the country_code and the set of allowed # channels and transmit power levels based on the regulatory limits. The # country_code setting must be configured with the correct country for # IEEE 802.11d functions. # (default: 0 = disabled) #ieee80211d=1 # Enable IEEE 802.11h. This enables radar detection and DFS support if # available. DFS support is required on outdoor 5 GHz channels in most countries # of the world. This can be used only with ieee80211d=1. # (default: 0 = disabled) #ieee80211h=1 # Add Power Constraint element to Beacon and Probe Response frames # This config option adds Power Constraint element when applicable and Country # element is added. Power Constraint element is required by Transmit Power # Control. This can be used only with ieee80211d=1. # Valid values are 0..255. #local_pwr_constraint=3 # Set Spectrum Management subfield in the Capability Information field. # This config option forces the Spectrum Management bit to be set. When this # option is not set, the value of the Spectrum Management bit depends on whether # DFS or TPC is required by regulatory authorities. This can be used only with # ieee80211d=1 and local_pwr_constraint configured. #spectrum_mgmt_required=1 # Operation mode (a = IEEE 802.11a (5 GHz), b = IEEE 802.11b (2.4 GHz), # g = IEEE 802.11g (2.4 GHz), ad = IEEE 802.11ad (60 GHz); a/g options are used # with IEEE 802.11n (HT), too, to specify band). For IEEE 802.11ac (VHT), this # needs to be set to hw_mode=a. For IEEE 802.11ax (HE) on 6 GHz this needs # to be set to hw_mode=a. When using ACS (see channel parameter), a # special value "any" can be used to indicate that any support band can be used. # This special case is currently supported only with drivers with which # offloaded ACS is used. # Default: IEEE 802.11b hw_mode=g # Channel number (IEEE 802.11) # (default: 0, i.e., not set) # Please note that some drivers do not use this value from hostapd and the # channel will need to be configured separately with iwconfig. # # If CONFIG_ACS build option is enabled, the channel can be selected # automatically at run time by setting channel=acs_survey or channel=0, both of # which will enable the ACS survey based algorithm. channel=1 # Global operating class (IEEE 802.11, Annex E, Table E-4) # This option allows hostapd to specify the operating class of the channel # configured with the channel parameter. channel and op_class together can # uniquely identify channels across different bands, including the 6 GHz band. #op_class=131 # ACS tuning - Automatic Channel Selection # See: https://wireless.wiki.kernel.org/en/users/documentation/acs # # You can customize the ACS survey algorithm with following variables: # # acs_num_scans requirement is 1..100 - number of scans to be performed that # are used to trigger survey data gathering of an underlying device driver. # Scans are passive and typically take a little over 100ms (depending on the # driver) on each available channel for given hw_mode. Increasing this value # means sacrificing startup time and gathering more data wrt channel # interference that may help choosing a better channel. This can also help fine # tune the ACS scan time in case a driver has different scan dwell times. # # acs_chan_bias is a space-separated list of <channel>:<bias> pairs. It can be # used to increase (or decrease) the likelihood of a specific channel to be # selected by the ACS algorithm. The total interference factor for each channel # gets multiplied by the specified bias value before finding the channel with # the lowest value. In other words, values between 0.0 and 1.0 can be used to # make a channel more likely to be picked while values larger than 1.0 make the # specified channel less likely to be picked. This can be used, e.g., to prefer # the commonly used 2.4 GHz band channels 1, 6, and 11 (which is the default # behavior on 2.4 GHz band if no acs_chan_bias parameter is specified). # # Defaults: #acs_num_scans=5 #acs_chan_bias=1:0.8 6:0.8 11:0.8 # Channel list restriction. This option allows hostapd to select one of the # provided channels when a channel should be automatically selected. # Channel list can be provided as range using hyphen ('-') or individual # channels can be specified by space (' ') separated values # Default: all channels allowed in selected hw_mode #chanlist=100 104 108 112 116 #chanlist=1 6 11-13 # Frequency list restriction. This option allows hostapd to select one of the # provided frequencies when a frequency should be automatically selected. # Frequency list can be provided as range using hyphen ('-') or individual # frequencies can be specified by comma (',') separated values # Default: all frequencies allowed in selected hw_mode #freqlist=2437,5955,5975 #freqlist=2437,5985-6105 # Exclude DFS channels from ACS # This option can be used to exclude all DFS channels from the ACS channel list # in cases where the driver supports DFS channels. #acs_exclude_dfs=1 # Include only preferred scan channels from 6 GHz band for ACS # This option can be used to include only preferred scan channels in the 6 GHz # band. This can be useful in particular for devices that operate only a 6 GHz # BSS without a collocated 2.4/5 GHz BSS. # Default behavior is to include all PSC and non-PSC channels. #acs_exclude_6ghz_non_psc=1 # Set minimum permitted max TX power (in dBm) for ACS and DFS channel selection. # (default 0, i.e., not constraint) #min_tx_power=20 # Beacon interval in kus (1.024 ms) (default: 100; range 15..65535) beacon_int=100 # DTIM (delivery traffic information message) period (range 1..255): # number of beacons between DTIMs (1 = every beacon includes DTIM element) # (default: 2) dtim_period=2 # Maximum number of stations allowed in station table. New stations will be # rejected after the station table is full. IEEE 802.11 has a limit of 2007 # different association IDs, so this number should not be larger than that. # (default: 2007) max_num_sta=255 # RTS/CTS threshold; -1 = disabled (default); range -1..65535 # If this field is not included in hostapd.conf, hostapd will not control # RTS threshold and 'iwconfig wlan# rts <val>' can be used to set it. rts_threshold=-1 # Fragmentation threshold; -1 = disabled (default); range -1, 256..2346 # If this field is not included in hostapd.conf, hostapd will not control # fragmentation threshold and 'iwconfig wlan# frag <val>' can be used to set # it. fragm_threshold=-1 # Rate configuration # Default is to enable all rates supported by the hardware. This configuration # item allows this list be filtered so that only the listed rates will be left # in the list. If the list is empty, all rates are used. This list can have # entries that are not in the list of rates the hardware supports (such entries # are ignored). The entries in this list are in 100 kbps, i.e., 11 Mbps = 110. # If this item is present, at least one rate have to be matching with the rates # hardware supports. # default: use the most common supported rate setting for the selected # hw_mode (i.e., this line can be removed from configuration file in most # cases) #supported_rates=10 20 55 110 60 90 120 180 240 360 480 540 # Basic rate set configuration # List of rates (in 100 kbps) that are included in the basic rate set. # If this item is not included, usually reasonable default set is used. #basic_rates=10 20 #basic_rates=10 20 55 110 #basic_rates=60 120 240 # Beacon frame TX rate configuration # This sets the TX rate that is used to transmit Beacon frames. If this item is # not included, the driver default rate (likely lowest rate) is used. # Legacy (CCK/OFDM rates): # beacon_rate=<legacy rate in 100 kbps> # HT: # beacon_rate=ht:<HT MCS> # VHT: # beacon_rate=vht:<VHT MCS> # HE: # beacon_rate=he:<HE MCS> # # For example, beacon_rate=10 for 1 Mbps or beacon_rate=60 for 6 Mbps (OFDM). #beacon_rate=10 # Short Preamble # This parameter can be used to enable optional use of short preamble for # frames sent at 2 Mbps, 5.5 Mbps, and 11 Mbps to improve network performance. # This applies only to IEEE 802.11b-compatible networks and this should only be # enabled if the local hardware supports use of short preamble. If any of the # associated STAs do not support short preamble, use of short preamble will be # disabled (and enabled when such STAs disassociate) dynamically. # 0 = do not allow use of short preamble (default) # 1 = allow use of short preamble #preamble=1 # Station MAC address -based authentication # Please note that this kind of access control requires a driver that uses # hostapd to take care of management frame processing and as such, this can be # used with driver=hostap or driver=nl80211, but not with driver=atheros. # 0 = accept unless in deny list # 1 = deny unless in accept list # 2 = use external RADIUS server (accept/deny lists are searched first) macaddr_acl=0 # Accept/deny lists are read from separate files (containing list of # MAC addresses, one per line). Use absolute path name to make sure that the # files can be read on SIGHUP configuration reloads. #accept_mac_file=/etc/hostapd.accept #deny_mac_file=/etc/hostapd.deny # IEEE 802.11 specifies two authentication algorithms. hostapd can be # configured to allow both of these or only one. Open system authentication # should be used with IEEE 802.1X. # Bit fields of allowed authentication algorithms: # bit 0 = Open System Authentication # bit 1 = Shared Key Authentication (requires WEP) auth_algs=3 # Send empty SSID in beacons and ignore probe request frames that do not # specify full SSID, i.e., require stations to know SSID. # default: disabled (0) # 1 = send empty (length=0) SSID in beacon and ignore probe request for # broadcast SSID # 2 = clear SSID (ASCII 0), but keep the original length (this may be required # with some clients that do not support empty SSID) and ignore probe # requests for broadcast SSID ignore_broadcast_ssid=0 # Do not reply to broadcast Probe Request frames from unassociated STA if there # is no room for additional stations (max_num_sta). This can be used to # discourage a STA from trying to associate with this AP if the association # would be rejected due to maximum STA limit. # Default: 0 (disabled) #no_probe_resp_if_max_sta=0 # Additional vendor specific elements for Beacon and Probe Response frames # This parameter can be used to add additional vendor specific element(s) into # the end of the Beacon and Probe Response frames. The format for these # element(s) is a hexdump of the raw information elements (id+len+payload for # one or more elements) #vendor_elements=dd0411223301 # Additional vendor specific elements for (Re)Association Response frames # This parameter can be used to add additional vendor specific element(s) into # the end of the (Re)Association Response frames. The format for these # element(s) is a hexdump of the raw information elements (id+len+payload for # one or more elements) #assocresp_elements=dd0411223301 # TX queue parameters (EDCF / bursting) # tx_queue_<queue name>_<param> # queues: data0, data1, data2, data3 # (data0 is the highest priority queue) # parameters: # aifs: AIFS (default 2) # cwmin: cwMin (1, 3, 7, 15, 31, 63, 127, 255, 511, 1023, 2047, 4095, 8191, # 16383, 32767) # cwmax: cwMax (same values as cwMin, cwMax >= cwMin) # burst: maximum length (in milliseconds with precision of up to 0.1 ms) for # bursting # # Default WMM parameters (IEEE 802.11 draft; 11-03-0504-03-000e): # These parameters are used by the access point when transmitting frames # to the clients. # # Low priority / AC_BK = background #tx_queue_data3_aifs=7 #tx_queue_data3_cwmin=15 #tx_queue_data3_cwmax=1023 #tx_queue_data3_burst=0 # Note: for IEEE 802.11b mode: cWmin=31 cWmax=1023 burst=0 # # Normal priority / AC_BE = best effort #tx_queue_data2_aifs=3 #tx_queue_data2_cwmin=15 #tx_queue_data2_cwmax=63 #tx_queue_data2_burst=0 # Note: for IEEE 802.11b mode: cWmin=31 cWmax=127 burst=0 # # High priority / AC_VI = video #tx_queue_data1_aifs=1 #tx_queue_data1_cwmin=7 #tx_queue_data1_cwmax=15 #tx_queue_data1_burst=3.0 # Note: for IEEE 802.11b mode: cWmin=15 cWmax=31 burst=6.0 # # Highest priority / AC_VO = voice #tx_queue_data0_aifs=1 #tx_queue_data0_cwmin=3 #tx_queue_data0_cwmax=7 #tx_queue_data0_burst=1.5 # Note: for IEEE 802.11b mode: cWmin=7 cWmax=15 burst=3.3 # 802.1D Tag (= UP) to AC mappings # WMM specifies following mapping of data frames to different ACs. This mapping # can be configured using Linux QoS/tc and sch_pktpri.o module. # 802.1D Tag 802.1D Designation Access Category WMM Designation # 1 BK AC_BK Background # 2 - AC_BK Background # 0 BE AC_BE Best Effort # 3 EE AC_BE Best Effort # 4 CL AC_VI Video # 5 VI AC_VI Video # 6 VO AC_VO Voice # 7 NC AC_VO Voice # Data frames with no priority information: AC_BE # Management frames: AC_VO # PS-Poll frames: AC_BE # Default WMM parameters (IEEE 802.11 draft; 11-03-0504-03-000e): # for 802.11a or 802.11g networks # These parameters are sent to WMM clients when they associate. # The parameters will be used by WMM clients for frames transmitted to the # access point. # # note - txop_limit is in units of 32microseconds # note - acm is admission control mandatory flag. 0 = admission control not # required, 1 = mandatory # note - Here cwMin and cmMax are in exponent form. The actual cw value used # will be (2^n)-1 where n is the value given here. The allowed range for these # wmm_ac_??_{cwmin,cwmax} is 0..15 with cwmax >= cwmin. # wmm_enabled=1 # # WMM-PS Unscheduled Automatic Power Save Delivery [U-APSD] # Enable this flag if U-APSD supported outside hostapd (eg., Firmware/driver) #uapsd_advertisement_enabled=1 # # Low priority / AC_BK = background wmm_ac_bk_cwmin=4 wmm_ac_bk_cwmax=10 wmm_ac_bk_aifs=7 wmm_ac_bk_txop_limit=0 wmm_ac_bk_acm=0 # Note: for IEEE 802.11b mode: cWmin=5 cWmax=10 # # Normal priority / AC_BE = best effort wmm_ac_be_aifs=3 wmm_ac_be_cwmin=4 wmm_ac_be_cwmax=10 wmm_ac_be_txop_limit=0 wmm_ac_be_acm=0 # Note: for IEEE 802.11b mode: cWmin=5 cWmax=7 # # High priority / AC_VI = video wmm_ac_vi_aifs=2 wmm_ac_vi_cwmin=3 wmm_ac_vi_cwmax=4 wmm_ac_vi_txop_limit=94 wmm_ac_vi_acm=0 # Note: for IEEE 802.11b mode: cWmin=4 cWmax=5 txop_limit=188 # # Highest priority / AC_VO = voice wmm_ac_vo_aifs=2 wmm_ac_vo_cwmin=2 wmm_ac_vo_cwmax=3 wmm_ac_vo_txop_limit=47 wmm_ac_vo_acm=0 # Note: for IEEE 802.11b mode: cWmin=3 cWmax=4 burst=102 # Enable Multi-AP functionality # 0 = disabled (default) # 1 = AP support backhaul BSS # 2 = AP support fronthaul BSS # 3 = AP supports both backhaul BSS and fronthaul BSS #multi_ap=0 # Static WEP key configuration # # The key number to use when transmitting. # It must be between 0 and 3, and the corresponding key must be set. # default: not set #wep_default_key=0 # The WEP keys to use. # A key may be a quoted string or unquoted hexadecimal digits. # The key length should be 5, 13, or 16 characters, or 10, 26, or 32 # digits, depending on whether 40-bit (64-bit), 104-bit (128-bit), or # 128-bit (152-bit) WEP is used. # Only the default key must be supplied; the others are optional. # default: not set #wep_key0=123456789a #wep_key1="vwxyz" #wep_key2=0102030405060708090a0b0c0d #wep_key3=".2.4.6.8.0.23" # Station inactivity limit # # If a station does not send anything in ap_max_inactivity seconds, an # empty data frame is sent to it in order to verify whether it is # still in range. If this frame is not ACKed, the station will be # disassociated and then deauthenticated. This feature is used to # clear station table of old entries when the STAs move out of the # range. # # The station can associate again with the AP if it is still in range; # this inactivity poll is just used as a nicer way of verifying # inactivity; i.e., client will not report broken connection because # disassociation frame is not sent immediately without first polling # the STA with a data frame. # default: 300 (i.e., 5 minutes) #ap_max_inactivity=300 # # The inactivity polling can be disabled to disconnect stations based on # inactivity timeout so that idle stations are more likely to be disconnected # even if they are still in range of the AP. This can be done by setting # skip_inactivity_poll to 1 (default 0). #skip_inactivity_poll=0 # Disassociate stations based on excessive transmission failures or other # indications of connection loss. This depends on the driver capabilities and # may not be available with all drivers. #disassoc_low_ack=1 # Maximum allowed Listen Interval (how many Beacon periods STAs are allowed to # remain asleep). Default: 65535 (no limit apart from field size) #max_listen_interval=100 # WDS (4-address frame) mode with per-station virtual interfaces # (only supported with driver=nl80211) # This mode allows associated stations to use 4-address frames to allow layer 2 # bridging to be used. #wds_sta=1 # If bridge parameter is set, the WDS STA interface will be added to the same # bridge by default. This can be overridden with the wds_bridge parameter to # use a separate bridge. #wds_bridge=wds-br0 # Start the AP with beaconing disabled by default. #start_disabled=0 # Client isolation can be used to prevent low-level bridging of frames between # associated stations in the BSS. By default, this bridging is allowed. #ap_isolate=1 # BSS Load update period (in BUs) # This field is used to enable and configure adding a BSS Load element into # Beacon and Probe Response frames. #bss_load_update_period=50 # Channel utilization averaging period (in BUs) # This field is used to enable and configure channel utilization average # calculation with bss_load_update_period. This should be in multiples of # bss_load_update_period for more accurate calculation. #chan_util_avg_period=600 # Fixed BSS Load value for testing purposes # This field can be used to configure hostapd to add a fixed BSS Load element # into Beacon and Probe Response frames for testing purposes. The format is # <station count>:<channel utilization>:<available admission capacity> #bss_load_test=12:80:20000 # Multicast to unicast conversion # Request that the AP will do multicast-to-unicast conversion for ARP, IPv4, and # IPv6 frames (possibly within 802.1Q). If enabled, such frames are to be sent # to each station separately, with the DA replaced by their own MAC address # rather than the group address. # # Note that this may break certain expectations of the receiver, such as the # ability to drop unicast IP packets received within multicast L2 frames, or the # ability to not send ICMP destination unreachable messages for packets received # in L2 multicast (which is required, but the receiver can't tell the difference # if this new option is enabled). # # This also doesn't implement the 802.11 DMS (directed multicast service). # #multicast_to_unicast=0 # Send broadcast Deauthentication frame on AP start/stop # Default: 1 (enabled) #broadcast_deauth=1 # Get notifications for received Management frames on control interface # Default: 0 (disabled) #notify_mgmt_frames=0 ##### IEEE 802.11n related configuration ###################################### # ieee80211n: Whether IEEE 802.11n (HT) is enabled # 0 = disabled (default) # 1 = enabled # Note: You will also need to enable WMM for full HT functionality. # Note: hw_mode=g (2.4 GHz) and hw_mode=a (5 GHz) is used to specify the band. #ieee80211n=1 # disable_11n: Boolean (0/1) to disable HT for a specific BSS #disable_11n=0 # ht_capab: HT capabilities (list of flags) # LDPC coding capability: [LDPC] = supported # Supported channel width set: [HT40-] = both 20 MHz and 40 MHz with secondary # channel below the primary channel; [HT40+] = both 20 MHz and 40 MHz # with secondary channel above the primary channel # (20 MHz only if neither is set) # Note: There are limits on which channels can be used with HT40- and # HT40+. Following table shows the channels that may be available for # HT40- and HT40+ use per IEEE 802.11n Annex J: # freq HT40- HT40+ # 2.4 GHz 5-13 1-7 (1-9 in Europe/Japan) # 5 GHz 40,48,56,64 36,44,52,60 # (depending on the location, not all of these channels may be available # for use) # Please note that 40 MHz channels may switch their primary and secondary # channels if needed or creation of 40 MHz channel maybe rejected based # on overlapping BSSes. These changes are done automatically when hostapd # is setting up the 40 MHz channel. # HT-greenfield: [GF] (disabled if not set) # Short GI for 20 MHz: [SHORT-GI-20] (disabled if not set) # Short GI for 40 MHz: [SHORT-GI-40] (disabled if not set) # Tx STBC: [TX-STBC] (disabled if not set) # Rx STBC: [RX-STBC1] (one spatial stream), [RX-STBC12] (one or two spatial # streams), or [RX-STBC123] (one, two, or three spatial streams); Rx STBC # disabled if none of these set # HT-delayed Block Ack: [DELAYED-BA] (disabled if not set) # Maximum A-MSDU length: [MAX-AMSDU-7935] for 7935 octets (3839 octets if not # set) # DSSS/CCK Mode in 40 MHz: [DSSS_CCK-40] = allowed (not allowed if not set) # 40 MHz intolerant [40-INTOLERANT] (not advertised if not set) # L-SIG TXOP protection support: [LSIG-TXOP-PROT] (disabled if not set) #ht_capab=[HT40-][SHORT-GI-20][SHORT-GI-40] # Require stations to support HT PHY (reject association if they do not) #require_ht=1 # If set non-zero, require stations to perform scans of overlapping # channels to test for stations which would be affected by 40 MHz traffic. # This parameter sets the interval in seconds between these scans. Setting this # to non-zero allows 2.4 GHz band AP to move dynamically to a 40 MHz channel if # no co-existence issues with neighboring devices are found. #obss_interval=0 ##### IEEE 802.11ac related configuration ##################################### # ieee80211ac: Whether IEEE 802.11ac (VHT) is enabled # 0 = disabled (default) # 1 = enabled # Note: You will also need to enable WMM for full VHT functionality. # Note: hw_mode=a is used to specify that 5 GHz band is used with VHT. #ieee80211ac=1 # disable_11ac: Boolean (0/1) to disable VHT for a specific BSS #disable_11ac=0 # vht_capab: VHT capabilities (list of flags) # # vht_max_mpdu_len: [MAX-MPDU-7991] [MAX-MPDU-11454] # Indicates maximum MPDU length # 0 = 3895 octets (default) # 1 = 7991 octets # 2 = 11454 octets # 3 = reserved # # supported_chan_width: [VHT160] [VHT160-80PLUS80] # Indicates supported Channel widths # 0 = 160 MHz & 80+80 channel widths are not supported (default) # 1 = 160 MHz channel width is supported # 2 = 160 MHz & 80+80 channel widths are supported # 3 = reserved # # Rx LDPC coding capability: [RXLDPC] # Indicates support for receiving LDPC coded pkts # 0 = Not supported (default) # 1 = Supported # # Short GI for 80 MHz: [SHORT-GI-80] # Indicates short GI support for reception of packets transmitted with TXVECTOR # params format equal to VHT and CBW = 80Mhz # 0 = Not supported (default) # 1 = Supported # # Short GI for 160 MHz: [SHORT-GI-160] # Indicates short GI support for reception of packets transmitted with TXVECTOR # params format equal to VHT and CBW = 160Mhz # 0 = Not supported (default) # 1 = Supported # # Tx STBC: [TX-STBC-2BY1] # Indicates support for the transmission of at least 2x1 STBC # 0 = Not supported (default) # 1 = Supported # # Rx STBC: [RX-STBC-1] [RX-STBC-12] [RX-STBC-123] [RX-STBC-1234] # Indicates support for the reception of PPDUs using STBC # 0 = Not supported (default) # 1 = support of one spatial stream # 2 = support of one and two spatial streams # 3 = support of one, two and three spatial streams # 4 = support of one, two, three and four spatial streams # 5,6,7 = reserved # # SU Beamformer Capable: [SU-BEAMFORMER] # Indicates support for operation as a single user beamformer # 0 = Not supported (default) # 1 = Supported # # SU Beamformee Capable: [SU-BEAMFORMEE] # Indicates support for operation as a single user beamformee # 0 = Not supported (default) # 1 = Supported # # Compressed Steering Number of Beamformer Antennas Supported: # [BF-ANTENNA-2] [BF-ANTENNA-3] [BF-ANTENNA-4] # Beamformee's capability indicating the maximum number of beamformer # antennas the beamformee can support when sending compressed beamforming # feedback # If SU beamformer capable, set to maximum value minus 1 # else reserved (default) # # Number of Sounding Dimensions: # [SOUNDING-DIMENSION-2] [SOUNDING-DIMENSION-3] [SOUNDING-DIMENSION-4] # Beamformer's capability indicating the maximum value of the NUM_STS parameter # in the TXVECTOR of a VHT NDP # If SU beamformer capable, set to maximum value minus 1 # else reserved (default) # # MU Beamformer Capable: [MU-BEAMFORMER] # Indicates support for operation as an MU beamformer # 0 = Not supported or sent by Non-AP STA (default) # 1 = Supported # # VHT TXOP PS: [VHT-TXOP-PS] # Indicates whether or not the AP supports VHT TXOP Power Save Mode # or whether or not the STA is in VHT TXOP Power Save mode # 0 = VHT AP doesn't support VHT TXOP PS mode (OR) VHT STA not in VHT TXOP PS # mode # 1 = VHT AP supports VHT TXOP PS mode (OR) VHT STA is in VHT TXOP power save # mode # # +HTC-VHT Capable: [HTC-VHT] # Indicates whether or not the STA supports receiving a VHT variant HT Control # field. # 0 = Not supported (default) # 1 = supported # # Maximum A-MPDU Length Exponent: [MAX-A-MPDU-LEN-EXP0]..[MAX-A-MPDU-LEN-EXP7] # Indicates the maximum length of A-MPDU pre-EOF padding that the STA can recv # This field is an integer in the range of 0 to 7. # The length defined by this field is equal to # 2 pow(13 + Maximum A-MPDU Length Exponent) -1 octets # # VHT Link Adaptation Capable: [VHT-LINK-ADAPT2] [VHT-LINK-ADAPT3] # Indicates whether or not the STA supports link adaptation using VHT variant # HT Control field # If +HTC-VHTcapable is 1 # 0 = (no feedback) if the STA does not provide VHT MFB (default) # 1 = reserved # 2 = (Unsolicited) if the STA provides only unsolicited VHT MFB # 3 = (Both) if the STA can provide VHT MFB in response to VHT MRQ and if the # STA provides unsolicited VHT MFB # Reserved if +HTC-VHTcapable is 0 # # Rx Antenna Pattern Consistency: [RX-ANTENNA-PATTERN] # Indicates the possibility of Rx antenna pattern change # 0 = Rx antenna pattern might change during the lifetime of an association # 1 = Rx antenna pattern does not change during the lifetime of an association # # Tx Antenna Pattern Consistency: [TX-ANTENNA-PATTERN] # Indicates the possibility of Tx antenna pattern change # 0 = Tx antenna pattern might change during the lifetime of an association # 1 = Tx antenna pattern does not change during the lifetime of an association #vht_capab=[SHORT-GI-80][HTC-VHT] # # Require stations to support VHT PHY (reject association if they do not) #require_vht=1 # 0 = 20 or 40 MHz operating Channel width # 1 = 80 MHz channel width # 2 = 160 MHz channel width # 3 = 80+80 MHz channel width #vht_oper_chwidth=1 # # center freq = 5 GHz + (5 * index) # So index 42 gives center freq 5.210 GHz # which is channel 42 in 5G band # #vht_oper_centr_freq_seg0_idx=42 # # center freq = 5 GHz + (5 * index) # So index 159 gives center freq 5.795 GHz # which is channel 159 in 5G band # #vht_oper_centr_freq_seg1_idx=159 # Workaround to use station's nsts capability in (Re)Association Response frame # This may be needed with some deployed devices as an interoperability # workaround for beamforming if the AP's capability is greater than the # station's capability. This is disabled by default and can be enabled by # setting use_sta_nsts=1. #use_sta_nsts=0 ##### IEEE 802.11ax related configuration ##################################### #ieee80211ax: Whether IEEE 802.11ax (HE) is enabled # 0 = disabled (default) # 1 = enabled #ieee80211ax=1 # disable_11ax: Boolean (0/1) to disable HE for a specific BSS #disable_11ax=0 #he_su_beamformer: HE single user beamformer support # 0 = not supported (default) # 1 = supported #he_su_beamformer=1 #he_su_beamformee: HE single user beamformee support # 0 = not supported (default) # 1 = supported #he_su_beamformee=1 #he_mu_beamformer: HE multiple user beamformer support # 0 = not supported (default) # 1 = supported #he_mu_beamformer=1 # he_bss_color: BSS color (1-63) #he_bss_color=1 # he_bss_color_partial: BSS color AID equation #he_bss_color_partial=0 #he_default_pe_duration: The duration of PE field in an HE PPDU in us # Possible values are 0 us (default), 4 us, 8 us, 12 us, and 16 us #he_default_pe_duration=0 #he_twt_required: Whether TWT is required # 0 = not required (default) # 1 = required #he_twt_required=0 #he_twt_responder: Whether TWT (HE) responder is enabled # 0 = disabled # 1 = enabled if supported by the driver (default) #he_twt_responder=1 #he_rts_threshold: Duration of STA transmission # 0 = not set (default) # unsigned integer = duration in units of 16 us #he_rts_threshold=0 #he_er_su_disable: Disable 242-tone HE ER SU PPDU reception by the AP # 0 = enable reception (default) # 1 = disable reception #he_er_su_disable=0 # HE operating channel information; see matching vht_* parameters for details. # he_oper_centr_freq_seg0_idx field is used to indicate center frequency of 80 # and 160 MHz bandwidth operation. In 80+80 MHz operation, it is the center # frequency of the lower frequency segment. he_oper_centr_freq_seg1_idx field # is used only with 80+80 MHz bandwidth operation and it is used to transmit # the center frequency of the second segment. # On the 6 GHz band the center freq calculation starts from 5.950 GHz offset. # For example idx=3 would result in 5965 MHz center frequency. In addition, # he_oper_chwidth is ignored, and the channel width is derived from the # configured operating class or center frequency indexes (see # IEEE P802.11ax/D6.1 Annex E, Table E-4). #he_oper_chwidth #he_oper_centr_freq_seg0_idx #he_oper_centr_freq_seg1_idx #he_basic_mcs_nss_set: Basic NSS/MCS set # 16-bit combination of 2-bit values of Max HE-MCS For 1..8 SS; each 2-bit # value having following meaning: # 0 = HE-MCS 0-7, 1 = HE-MCS 0-9, 2 = HE-MCS 0-11, 3 = not supported #he_basic_mcs_nss_set #he_mu_edca_qos_info_param_count #he_mu_edca_qos_info_q_ack #he_mu_edca_qos_info_queue_request=1 #he_mu_edca_qos_info_txop_request #he_mu_edca_ac_be_aifsn=0 #he_mu_edca_ac_be_ecwmin=15 #he_mu_edca_ac_be_ecwmax=15 #he_mu_edca_ac_be_timer=255 #he_mu_edca_ac_bk_aifsn=0 #he_mu_edca_ac_bk_aci=1 #he_mu_edca_ac_bk_ecwmin=15 #he_mu_edca_ac_bk_ecwmax=15 #he_mu_edca_ac_bk_timer=255 #he_mu_edca_ac_vi_ecwmin=15 #he_mu_edca_ac_vi_ecwmax=15 #he_mu_edca_ac_vi_aifsn=0 #he_mu_edca_ac_vi_aci=2 #he_mu_edca_ac_vi_timer=255 #he_mu_edca_ac_vo_aifsn=0 #he_mu_edca_ac_vo_aci=3 #he_mu_edca_ac_vo_ecwmin=15 #he_mu_edca_ac_vo_ecwmax=15 #he_mu_edca_ac_vo_timer=255 # Spatial Reuse Parameter Set # # SR Control field value # B0 = PSR Disallowed # B1 = Non-SRG OBSS PD SR Disallowed # B2 = Non-SRG Offset Present # B3 = SRG Information Present # B4 = HESIGA_Spatial_reuse_value15_allowed #he_spr_sr_control # # Non-SRG OBSS PD Max Offset (included if he_spr_sr_control B2=1) #he_spr_non_srg_obss_pd_max_offset # SRG OBSS PD Min Offset (included if he_spr_sr_control B3=1) #he_spr_srg_obss_pd_min_offset # # SRG OBSS PD Max Offset (included if he_spr_sr_control B3=1) #he_spr_srg_obss_pd_max_offset # # SPR SRG BSS Color (included if he_spr_sr_control B3=1) # This config represents SRG BSS Color Bitmap field of Spatial Reuse Parameter # Set element that indicates the BSS color values used by members of the # SRG of which the transmitting STA is a member. The value is in range of 0-63. #he_spr_srg_bss_colors=1 2 10 63 # # SPR SRG Partial BSSID (included if he_spr_sr_control B3=1) # This config represents SRG Partial BSSID Bitmap field of Spatial Reuse # Parameter Set element that indicates the Partial BSSID values used by members # of the SRG of which the transmitting STA is a member. The value range # corresponds to one of the 64 possible values of BSSID[39:44], where the lowest # numbered bit corresponds to Partial BSSID value 0 and the highest numbered bit # corresponds to Partial BSSID value 63. #he_spr_srg_partial_bssid=0 1 3 63 # #he_6ghz_max_mpdu: Maximum MPDU Length of HE 6 GHz band capabilities. # Indicates maximum MPDU length # 0 = 3895 octets # 1 = 7991 octets # 2 = 11454 octets (default) #he_6ghz_max_mpdu=2 # #he_6ghz_max_ampdu_len_exp: Maximum A-MPDU Length Exponent of HE 6 GHz band # capabilities. Indicates the maximum length of A-MPDU pre-EOF padding that # the STA can receive. This field is an integer in the range of 0 to 7. # The length defined by this field is equal to # 2 pow(13 + Maximum A-MPDU Length Exponent) -1 octets # 0 = AMPDU length of 8k # 1 = AMPDU length of 16k # 2 = AMPDU length of 32k # 3 = AMPDU length of 65k # 4 = AMPDU length of 131k # 5 = AMPDU length of 262k # 6 = AMPDU length of 524k # 7 = AMPDU length of 1048k (default) #he_6ghz_max_ampdu_len_exp=7 # #he_6ghz_rx_ant_pat: Rx Antenna Pattern Consistency of HE 6 GHz capability. # Indicates the possibility of Rx antenna pattern change # 0 = Rx antenna pattern might change during the lifetime of an association # 1 = Rx antenna pattern does not change during the lifetime of an association # (default) #he_6ghz_rx_ant_pat=1 # #he_6ghz_tx_ant_pat: Tx Antenna Pattern Consistency of HE 6 GHz capability. # Indicates the possibility of Tx antenna pattern change # 0 = Tx antenna pattern might change during the lifetime of an association # 1 = Tx antenna pattern does not change during the lifetime of an association # (default) #he_6ghz_tx_ant_pat=1 # Unsolicited broadcast Probe Response transmission settings # This is for the 6 GHz band only. If the interval is set to a non-zero value, # the AP schedules unsolicited broadcast Probe Response frames to be # transmitted for in-band discovery. Refer to # IEEE P802.11ax/D8.0 26.17.2.3.2, AP behavior for fast passive scanning. # Valid range: 0..20 TUs; default is 0 (disabled) #unsol_bcast_probe_resp_interval=0 ##### IEEE 802.1X-2004 related configuration ################################## # Require IEEE 802.1X authorization #ieee8021x=1 # IEEE 802.1X/EAPOL version # hostapd is implemented based on IEEE Std 802.1X-2004 which defines EAPOL # version 2. However, there are many client implementations that do not handle # the new version number correctly (they seem to drop the frames completely). # In order to make hostapd interoperate with these clients, the version number # can be set to the older version (1) with this configuration value. # Note: When using MACsec, eapol_version shall be set to 3, which is # defined in IEEE Std 802.1X-2010. #eapol_version=2 # Optional displayable message sent with EAP Request-Identity. The first \0 # in this string will be converted to ASCII-0 (nul). This can be used to # separate network info (comma separated list of attribute=value pairs); see, # e.g., RFC 4284. #eap_message=hello #eap_message=hello\0networkid=netw,nasid=foo,portid=0,NAIRealms=example.com # WEP rekeying (disabled if key lengths are not set or are set to 0) # Key lengths for default/broadcast and individual/unicast keys: # 5 = 40-bit WEP (also known as 64-bit WEP with 40 secret bits) # 13 = 104-bit WEP (also known as 128-bit WEP with 104 secret bits) #wep_key_len_broadcast=5 #wep_key_len_unicast=5 # Rekeying period in seconds. 0 = do not rekey (i.e., set keys only once) #wep_rekey_period=300 # EAPOL-Key index workaround (set bit7) for WinXP Supplicant (needed only if # only broadcast keys are used) eapol_key_index_workaround=0 # EAP reauthentication period in seconds (default: 3600 seconds; 0 = disable # reauthentication). # Note: Reauthentications may enforce a disconnection, check the related # parameter wpa_deny_ptk0_rekey for details. #eap_reauth_period=3600 # Use PAE group address (01:80:c2:00:00:03) instead of individual target # address when sending EAPOL frames with driver=wired. This is the most common # mechanism used in wired authentication, but it also requires that the port # is only used by one station. #use_pae_group_addr=1 # EAP Re-authentication Protocol (ERP) authenticator (RFC 6696) # # Whether to initiate EAP authentication with EAP-Initiate/Re-auth-Start before # EAP-Identity/Request #erp_send_reauth_start=1 # # Domain name for EAP-Initiate/Re-auth-Start. Omitted from the message if not # set (no local ER server). This is also used by the integrated EAP server if # ERP is enabled (eap_server_erp=1). #erp_domain=example.com ##### MACsec ################################################################## # macsec_policy: IEEE 802.1X/MACsec options # This determines how sessions are secured with MACsec (only for MACsec # drivers). # 0: MACsec not in use (default) # 1: MACsec enabled - Should secure, accept key server's advice to # determine whether to use a secure session or not. # # macsec_integ_only: IEEE 802.1X/MACsec transmit mode # This setting applies only when MACsec is in use, i.e., # - macsec_policy is enabled # - the key server has decided to enable MACsec # 0: Encrypt traffic (default) # 1: Integrity only # # macsec_replay_protect: IEEE 802.1X/MACsec replay protection # This setting applies only when MACsec is in use, i.e., # - macsec_policy is enabled # - the key server has decided to enable MACsec # 0: Replay protection disabled (default) # 1: Replay protection enabled # # macsec_replay_window: IEEE 802.1X/MACsec replay protection window # This determines a window in which replay is tolerated, to allow receipt # of frames that have been misordered by the network. # This setting applies only when MACsec replay protection active, i.e., # - macsec_replay_protect is enabled # - the key server has decided to enable MACsec # 0: No replay window, strict check (default) # 1..2^32-1: number of packets that could be misordered # # macsec_port: IEEE 802.1X/MACsec port # Port component of the SCI # Range: 1-65534 (default: 1) # # mka_priority (Priority of MKA Actor) # Range: 0..255 (default: 255) # # mka_cak, mka_ckn, and mka_priority: IEEE 802.1X/MACsec pre-shared key mode # This allows to configure MACsec with a pre-shared key using a (CAK,CKN) pair. # In this mode, instances of hostapd can act as MACsec peers. The peer # with lower priority will become the key server and start distributing SAKs. # mka_cak (CAK = Secure Connectivity Association Key) takes a 16-byte (128-bit) # hex-string (32 hex-digits) or a 32-byte (256-bit) hex-string (64 hex-digits) # mka_ckn (CKN = CAK Name) takes a 1..32-bytes (8..256 bit) hex-string # (2..64 hex-digits) ##### Integrated EAP server ################################################### # Optionally, hostapd can be configured to use an integrated EAP server # to process EAP authentication locally without need for an external RADIUS # server. This functionality can be used both as a local authentication server # for IEEE 802.1X/EAPOL and as a RADIUS server for other devices. # Use integrated EAP server instead of external RADIUS authentication # server. This is also needed if hostapd is configured to act as a RADIUS # authentication server. eap_server=0 # Path for EAP server user database # If SQLite support is included, this can be set to "sqlite:/path/to/sqlite.db" # to use SQLite database instead of a text file. #eap_user_file=/etc/hostapd.eap_user # CA certificate (PEM or DER file) for EAP-TLS/PEAP/TTLS #ca_cert=/etc/hostapd.ca.pem # Server certificate (PEM or DER file) for EAP-TLS/PEAP/TTLS #server_cert=/etc/hostapd.server.pem # Private key matching with the server certificate for EAP-TLS/PEAP/TTLS # This may point to the same file as server_cert if both certificate and key # are included in a single file. PKCS#12 (PFX) file (.p12/.pfx) can also be # used by commenting out server_cert and specifying the PFX file as the # private_key. #private_key=/etc/hostapd.server.prv # Passphrase for private key #private_key_passwd=secret passphrase # An alternative server certificate and private key can be configured with the # following parameters (with values just like the parameters above without the # '2' suffix). The ca_cert file (in PEM encoding) is used to add the trust roots # for both server certificates and/or client certificates). # # The main use case for this alternative server certificate configuration is to # enable both RSA and ECC public keys. The server will pick which one to use # based on the client preferences for the cipher suite (in the TLS ClientHello # message). It should be noted that number of deployed EAP peer implementations # do not filter out the cipher suite list based on their local configuration and # as such, configuration of alternative types of certificates on the server may # result in interoperability issues. #server_cert2=/etc/hostapd.server-ecc.pem #private_key2=/etc/hostapd.server-ecc.prv #private_key_passwd2=secret passphrase # Server identity # EAP methods that provide mechanism for authenticated server identity delivery # use this value. If not set, "hostapd" is used as a default. #server_id=server.example.com # Enable CRL verification. # Note: hostapd does not yet support CRL downloading based on CDP. Thus, a # valid CRL signed by the CA is required to be included in the ca_cert file. # This can be done by using PEM format for CA certificate and CRL and # concatenating these into one file. Whenever CRL changes, hostapd needs to be # restarted to take the new CRL into use. Alternatively, crl_reload_interval can # be used to configure periodic updating of the loaded CRL information. # 0 = do not verify CRLs (default) # 1 = check the CRL of the user certificate # 2 = check all CRLs in the certificate path #check_crl=1 # Specify whether to ignore certificate CRL validity time mismatches with # errors X509_V_ERR_CRL_HAS_EXPIRED and X509_V_ERR_CRL_NOT_YET_VALID. # # 0 = ignore errors # 1 = do not ignore errors (default) #check_crl_strict=1 # CRL reload interval in seconds # This can be used to reload ca_cert file and the included CRL on every new TLS # session if difference between last reload and the current reload time in # seconds is greater than crl_reload_interval. # Note: If interval time is very short, CPU overhead may be negatively affected # and it is advised to not go below 300 seconds. # This is applicable only with check_crl values 1 and 2. # 0 = do not reload CRLs (default) # crl_reload_interval = 300 # If check_cert_subject is set, the value of every field will be checked # against the DN of the subject in the client certificate. If the values do # not match, the certificate verification will fail, rejecting the user. # This option allows hostapd to match every individual field in the right order # against the DN of the subject in the client certificate. # # For example, check_cert_subject=C=US/O=XX/OU=ABC/OU=XYZ/CN=1234 will check # every individual DN field of the subject in the client certificate. If OU=XYZ # comes first in terms of the order in the client certificate (DN field of # client certificate C=US/O=XX/OU=XYZ/OU=ABC/CN=1234), hostapd will reject the # client because the order of 'OU' is not matching the specified string in # check_cert_subject. # # This option also allows '*' as a wildcard. This option has some limitation. # It can only be used as per the following example. # # For example, check_cert_subject=C=US/O=XX/OU=Production* and we have two # clients and DN of the subject in the first client certificate is # (C=US/O=XX/OU=Production Unit) and DN of the subject in the second client is # (C=US/O=XX/OU=Production Factory). In this case, hostapd will allow both # clients because the value of 'OU' field in both client certificates matches # 'OU' value in 'check_cert_subject' up to 'wildcard'. # # * (Allow all clients, e.g., check_cert_subject=*) #check_cert_subject=string # TLS Session Lifetime in seconds # This can be used to allow TLS sessions to be cached and resumed with an # abbreviated handshake when using EAP-TLS/TTLS/PEAP. # (default: 0 = session caching and resumption disabled) #tls_session_lifetime=3600 # TLS flags # [ALLOW-SIGN-RSA-MD5] = allow MD5-based certificate signatures (depending on # the TLS library, these may be disabled by default to enforce stronger # security) # [DISABLE-TIME-CHECKS] = ignore certificate validity time (this requests # the TLS library to accept certificates even if they are not currently # valid, i.e., have expired or have not yet become valid; this should be # used only for testing purposes) # [DISABLE-TLSv1.0] = disable use of TLSv1.0 # [ENABLE-TLSv1.0] = explicitly enable use of TLSv1.0 (this allows # systemwide TLS policies to be overridden) # [DISABLE-TLSv1.1] = disable use of TLSv1.1 # [ENABLE-TLSv1.1] = explicitly enable use of TLSv1.1 (this allows # systemwide TLS policies to be overridden) # [DISABLE-TLSv1.2] = disable use of TLSv1.2 # [ENABLE-TLSv1.2] = explicitly enable use of TLSv1.2 (this allows # systemwide TLS policies to be overridden) # [DISABLE-TLSv1.3] = disable use of TLSv1.3 # [ENABLE-TLSv1.3] = enable TLSv1.3 (experimental - disabled by default) #tls_flags=[flag1][flag2]... # Maximum number of EAP message rounds with data (default: 100) #max_auth_rounds=100 # Maximum number of short EAP message rounds (default: 50) #max_auth_rounds_short=50 # Cached OCSP stapling response (DER encoded) # If set, this file is sent as a certificate status response by the EAP server # if the EAP peer requests certificate status in the ClientHello message. # This cache file can be updated, e.g., by running following command # periodically to get an update from the OCSP responder: # openssl ocsp \ # -no_nonce \ # -CAfile /etc/hostapd.ca.pem \ # -issuer /etc/hostapd.ca.pem \ # -cert /etc/hostapd.server.pem \ # -url http://ocsp.example.com:8888/ \ # -respout /tmp/ocsp-cache.der #ocsp_stapling_response=/tmp/ocsp-cache.der # Cached OCSP stapling response list (DER encoded OCSPResponseList) # This is similar to ocsp_stapling_response, but the extended version defined in # RFC 6961 to allow multiple OCSP responses to be provided. #ocsp_stapling_response_multi=/tmp/ocsp-multi-cache.der # 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. This parameter is required if anonymous EAP-FAST is used. # You can generate DH parameters file with OpenSSL, e.g., # "openssl dhparam -out /etc/hostapd.dh.pem 2048" #dh_file=/etc/hostapd.dh.pem # OpenSSL cipher string # # This is an OpenSSL specific configuration option for configuring the default # ciphers. If not set, the value configured at build time ("DEFAULT:!EXP:!LOW" # by default) is used. # See https://www.openssl.org/docs/apps/ciphers.html for OpenSSL documentation # on cipher suite configuration. This is applicable only if hostapd is built to # use OpenSSL. #openssl_ciphers=DEFAULT:!EXP:!LOW # OpenSSL ECDH curves # # This is an OpenSSL specific configuration option for configuring the ECDH # curves for EAP-TLS/TTLS/PEAP/FAST server. If not set, automatic curve # selection is enabled. If set to an empty string, ECDH curve configuration is # not done (the exact library behavior depends on the library version). # Otherwise, this is a colon separated list of the supported curves (e.g., # P-521:P-384:P-256). This is applicable only if hostapd is built to use # OpenSSL. This must not be used for Suite B cases since the same OpenSSL # parameter is set differently in those cases and this might conflict with that # design. #openssl_ecdh_curves=P-521:P-384:P-256 # Fragment size for EAP methods #fragment_size=1400 # Finite cyclic group for EAP-pwd. Number maps to group of domain parameters # using the IANA repository for IKE (RFC 2409). #pwd_group=19 # Configuration data for EAP-SIM database/authentication gateway interface. # This is a text string in implementation specific format. The example # implementation in eap_sim_db.c uses this as the UNIX domain socket name for # the HLR/AuC gateway (e.g., hlr_auc_gw). In this case, the path uses "unix:" # prefix. If hostapd is built with SQLite support (CONFIG_SQLITE=y in .config), # database file can be described with an optional db=<path> parameter. #eap_sim_db=unix:/tmp/hlr_auc_gw.sock #eap_sim_db=unix:/tmp/hlr_auc_gw.sock db=/tmp/hostapd.db # EAP-SIM DB request timeout # This parameter sets the maximum time to wait for a database request response. # The parameter value is in seconds. #eap_sim_db_timeout=1 # Encryption key for EAP-FAST PAC-Opaque values. This key must be a secret, # random value. It is configured as a 16-octet value in hex format. It can be # generated, e.g., with the following command: # od -tx1 -v -N16 /dev/random | colrm 1 8 | tr -d ' ' #pac_opaque_encr_key=000102030405060708090a0b0c0d0e0f # EAP-FAST authority identity (A-ID) # A-ID indicates the identity of the authority that issues PACs. The A-ID # should be unique across all issuing servers. In theory, this is a variable # length field, but due to some existing implementations requiring A-ID to be # 16 octets in length, it is strongly recommended to use that length for the # field to provide interoperability with deployed peer implementations. This # field is configured in hex format. #eap_fast_a_id=101112131415161718191a1b1c1d1e1f # EAP-FAST authority identifier information (A-ID-Info) # This is a user-friendly name for the A-ID. For example, the enterprise name # and server name in a human-readable format. This field is encoded as UTF-8. #eap_fast_a_id_info=test server # Enable/disable different EAP-FAST provisioning modes: #0 = provisioning disabled #1 = only anonymous provisioning allowed #2 = only authenticated provisioning allowed #3 = both provisioning modes allowed (default) #eap_fast_prov=3 # EAP-FAST PAC-Key lifetime in seconds (hard limit) #pac_key_lifetime=604800 # EAP-FAST PAC-Key refresh time in seconds (soft limit on remaining hard # limit). The server will generate a new PAC-Key when this number of seconds # (or fewer) of the lifetime remains. #pac_key_refresh_time=86400 # EAP-TEAP authentication type # 0 = inner EAP (default) # 1 = Basic-Password-Auth # 2 = Do not require Phase 2 authentication if client can be authenticated # during Phase 1 #eap_teap_auth=0 # EAP-TEAP authentication behavior when using PAC # 0 = perform inner authentication (default) # 1 = skip inner authentication (inner EAP/Basic-Password-Auth) #eap_teap_pac_no_inner=0 # EAP-TEAP behavior with Result TLV # 0 = include with Intermediate-Result TLV (default) # 1 = send in a separate message (for testing purposes) #eap_teap_separate_result=0 # EAP-TEAP identities # 0 = allow any identity type (default) # 1 = require user identity # 2 = require machine identity # 3 = request user identity; accept either user or machine identity # 4 = request machine identity; accept either user or machine identity # 5 = require both user and machine identity #eap_teap_id=0 # EAP-SIM and EAP-AKA protected success/failure indication using AT_RESULT_IND # (default: 0 = disabled). #eap_sim_aka_result_ind=1 # EAP-SIM and EAP-AKA identity options # 0 = do not use pseudonyms or fast reauthentication # 1 = use pseudonyms, but not fast reauthentication # 2 = do not use pseudonyms, but use fast reauthentication # 3 = use pseudonyms and use fast reauthentication (default) #eap_sim_id=3 # Trusted Network Connect (TNC) # If enabled, TNC validation will be required before the peer is allowed to # connect. Note: This is only used with EAP-TTLS and EAP-FAST. If any other # EAP method is enabled, the peer will be allowed to connect without TNC. #tnc=1 # EAP Re-authentication Protocol (ERP) - RFC 6696 # # Whether to enable ERP on the EAP server. #eap_server_erp=1 ##### RADIUS client configuration ############################################# # for IEEE 802.1X with external Authentication Server, IEEE 802.11 # authentication with external ACL for MAC addresses, and accounting # The own IP address of the access point (used as NAS-IP-Address) own_ip_addr=127.0.0.1 # NAS-Identifier string for RADIUS messages. When used, this should be unique # to the NAS within the scope of the RADIUS server. Please note that hostapd # uses a separate RADIUS client for each BSS and as such, a unique # nas_identifier value should be configured separately for each BSS. This is # particularly important for cases where RADIUS accounting is used # (Accounting-On/Off messages are interpreted as clearing all ongoing sessions # and that may get interpreted as applying to all BSSes if the same # NAS-Identifier value is used.) For example, a fully qualified domain name # prefixed with a unique identifier of the BSS (e.g., BSSID) can be used here. # # When using IEEE 802.11r, nas_identifier must be set and must be between 1 and # 48 octets long. # # It is mandatory to configure either own_ip_addr or nas_identifier to be # compliant with the RADIUS protocol. When using RADIUS accounting, it is # strongly recommended that nas_identifier is set to a unique value for each # BSS. #nas_identifier=ap.example.com # RADIUS client forced local IP address for the access point # Normally the local IP address is determined automatically based on configured # IP addresses, but this field can be used to force a specific address to be # used, e.g., when the device has multiple IP addresses. #radius_client_addr=127.0.0.1 # RADIUS client forced local interface. Helps run properly with VRF # Default is none set which allows the network stack to pick the appropriate # interface automatically. # Example below binds to eth0 #radius_client_dev=eth0 # RADIUS authentication server #auth_server_addr=127.0.0.1 #auth_server_port=1812 #auth_server_shared_secret=secret # RADIUS accounting server #acct_server_addr=127.0.0.1 #acct_server_port=1813 #acct_server_shared_secret=secret # Secondary RADIUS servers; to be used if primary one does not reply to # RADIUS packets. These are optional and there can be more than one secondary # server listed. #auth_server_addr=127.0.0.2 #auth_server_port=1812 #auth_server_shared_secret=secret2 # #acct_server_addr=127.0.0.2 #acct_server_port=1813 #acct_server_shared_secret=secret2 # Retry interval for trying to return to the primary RADIUS server (in # seconds). RADIUS client code will automatically try to use the next server # when the current server is not replying to requests. If this interval is set, # primary server will be retried after configured amount of time even if the # currently used secondary server is still working. #radius_retry_primary_interval=600 # Interim accounting update interval # If this is set (larger than 0) and acct_server is configured, hostapd will # send interim accounting updates every N seconds. Note: if set, this overrides # possible Acct-Interim-Interval attribute in Access-Accept message. Thus, this # value should not be configured in hostapd.conf, if RADIUS server is used to # control the interim interval. # This value should not be less 600 (10 minutes) and must not be less than # 60 (1 minute). #radius_acct_interim_interval=600 # Request Chargeable-User-Identity (RFC 4372) # This parameter can be used to configure hostapd to request CUI from the # RADIUS server by including Chargeable-User-Identity attribute into # Access-Request packets. #radius_request_cui=1 # Dynamic VLAN mode; allow RADIUS authentication server to decide which VLAN # is used for the stations. This information is parsed from following RADIUS # attributes based on RFC 3580 and RFC 2868: Tunnel-Type (value 13 = VLAN), # Tunnel-Medium-Type (value 6 = IEEE 802), Tunnel-Private-Group-ID (value # VLANID as a string). Optionally, the local MAC ACL list (accept_mac_file) can # be used to set static client MAC address to VLAN ID mapping. # Dynamic VLAN mode is also used with VLAN ID assignment based on WPA/WPA2 # passphrase from wpa_psk_file or vlan_id parameter from sae_password. # 0 = disabled (default); only VLAN IDs from accept_mac_file will be used # 1 = optional; use default interface if RADIUS server does not include VLAN ID # 2 = required; reject authentication if RADIUS server does not include VLAN ID #dynamic_vlan=0 # Per-Station AP_VLAN interface mode # If enabled, each station is assigned its own AP_VLAN interface. # This implies per-station group keying and ebtables filtering of inter-STA # traffic (when passed through the AP). # If the sta is not assigned to any VLAN, then its AP_VLAN interface will be # added to the bridge given by the "bridge" configuration option (see above). # Otherwise, it will be added to the per-VLAN bridge. # 0 = disabled (default) # 1 = enabled #per_sta_vif=0 # VLAN interface list for dynamic VLAN mode is read from a separate text file. # This list is used to map VLAN ID from the RADIUS server to a network # interface. Each station is bound to one interface in the same way as with # multiple BSSIDs or SSIDs. Each line in this text file is defining a new # interface and the line must include VLAN ID and interface name separated by # white space (space or tab). # If no entries are provided by this file, the station is statically mapped # to <bss-iface>.<vlan-id> interfaces. # Each line can optionally also contain the name of a bridge to add the VLAN to #vlan_file=/etc/hostapd.vlan # Interface where 802.1q tagged packets should appear when a RADIUS server is # used to determine which VLAN a station is on. hostapd creates a bridge for # each VLAN. Then hostapd adds a VLAN interface (associated with the interface # indicated by 'vlan_tagged_interface') and the appropriate wireless interface # to the bridge. #vlan_tagged_interface=eth0 # Bridge (prefix) to add the wifi and the tagged interface to. This gets the # VLAN ID appended. It defaults to brvlan%d if no tagged interface is given # and br%s.%d if a tagged interface is given, provided %s = tagged interface # and %d = VLAN ID. #vlan_bridge=brvlan # When hostapd creates a VLAN interface on vlan_tagged_interfaces, it needs # to know how to name it. # 0 = vlan<XXX>, e.g., vlan1 # 1 = <vlan_tagged_interface>.<XXX>, e.g. eth0.1 #vlan_naming=0 # Arbitrary RADIUS attributes can be added into Access-Request and # Accounting-Request packets by specifying the contents of the attributes with # the following configuration parameters. There can be multiple of these to # add multiple attributes. These parameters can also be used to override some # of the attributes added automatically by hostapd. # Format: <attr_id>[:<syntax:value>] # attr_id: RADIUS attribute type (e.g., 26 = Vendor-Specific) # syntax: s = string (UTF-8), d = integer, x = octet string # value: attribute value in format indicated by the syntax # If syntax and value parts are omitted, a null value (single 0x00 octet) is # used. # # Additional Access-Request attributes # radius_auth_req_attr=<attr_id>[:<syntax:value>] # Examples: # Operator-Name = "Operator" #radius_auth_req_attr=126:s:Operator # Service-Type = Framed (2) #radius_auth_req_attr=6:d:2 # Connect-Info = "testing" (this overrides the automatically generated value) #radius_auth_req_attr=77:s:testing # Same Connect-Info value set as a hexdump #radius_auth_req_attr=77:x:74657374696e67 # # Additional Accounting-Request attributes # radius_acct_req_attr=<attr_id>[:<syntax:value>] # Examples: # Operator-Name = "Operator" #radius_acct_req_attr=126:s:Operator # If SQLite support is included, path to a database from which additional # RADIUS request attributes are extracted based on the station MAC address. # # The schema for the radius_attributes table is: # id | sta | reqtype | attr : multi-key (sta, reqtype) # id = autonumber # sta = station MAC address in `11:22:33:44:55:66` format. # type = `auth` | `acct` | NULL (match any) # attr = existing config file format, e.g. `126:s:Test Operator` #radius_req_attr_sqlite=radius_attr.sqlite # Dynamic Authorization Extensions (RFC 5176) # This mechanism can be used to allow dynamic changes to user session based on # commands from a RADIUS server (or some other disconnect client that has the # needed session information). For example, Disconnect message can be used to # request an associated station to be disconnected. # # This is disabled by default. Set radius_das_port to non-zero UDP port # number to enable. #radius_das_port=3799 # # DAS client (the host that can send Disconnect/CoA requests) and shared secret # Format: <IP address> <shared secret> # IP address 0.0.0.0 can be used to allow requests from any address. #radius_das_client=192.168.1.123 shared secret here # # DAS Event-Timestamp time window in seconds #radius_das_time_window=300 # # DAS require Event-Timestamp #radius_das_require_event_timestamp=1 # # DAS require Message-Authenticator #radius_das_require_message_authenticator=1 ##### RADIUS authentication server configuration ############################## # hostapd can be used as a RADIUS authentication server for other hosts. This # requires that the integrated EAP server is also enabled and both # authentication services are sharing the same configuration. # File name of the RADIUS clients configuration for the RADIUS server. If this # commented out, RADIUS server is disabled. #radius_server_clients=/etc/hostapd.radius_clients # The UDP port number for the RADIUS authentication server #radius_server_auth_port=1812 # The UDP port number for the RADIUS accounting server # Commenting this out or setting this to 0 can be used to disable RADIUS # accounting while still enabling RADIUS authentication. #radius_server_acct_port=1813 # Use IPv6 with RADIUS server (IPv4 will also be supported using IPv6 API) #radius_server_ipv6=1 ##### WPA/IEEE 802.11i configuration ########################################## # Enable WPA. Setting this variable configures the AP to require WPA (either # WPA-PSK or WPA-RADIUS/EAP based on other configuration). For WPA-PSK, either # wpa_psk or wpa_passphrase must be set and wpa_key_mgmt must include WPA-PSK. # Instead of wpa_psk / wpa_passphrase, wpa_psk_radius might suffice. # For WPA-RADIUS/EAP, ieee8021x must be set (but without dynamic WEP keys), # RADIUS authentication server must be configured, and WPA-EAP must be included # in wpa_key_mgmt. # This field is a bit field that can be used to enable WPA (IEEE 802.11i/D3.0) # and/or WPA2 (full IEEE 802.11i/RSN): # bit0 = WPA # bit1 = IEEE 802.11i/RSN (WPA2) (dot11RSNAEnabled) # Note that WPA3 is also configured with bit1 since it uses RSN just like WPA2. # In other words, for WPA3, wpa=2 is used the configuration (and # wpa_key_mgmt=SAE for WPA3-Personal instead of wpa_key_mgmt=WPA-PSK). #wpa=2 # Extended Key ID support for Individually Addressed frames # # Extended Key ID allows to rekey PTK keys without the impacts the "normal" # PTK rekeying with only a single Key ID 0 has. It can only be used when the # driver supports it and RSN/WPA2 is used with a CCMP/GCMP pairwise cipher. # # 0 = force off, i.e., use only Key ID 0 (default) # 1 = enable and use Extended Key ID support when possible # 2 = identical to 1 but start with Key ID 1 when possible #extended_key_id=0 # WPA pre-shared keys for WPA-PSK. This can be either entered as a 256-bit # secret in hex format (64 hex digits), wpa_psk, or as an ASCII passphrase # (8..63 characters) that will be converted to PSK. This conversion uses SSID # so the PSK changes when ASCII passphrase is used and the SSID is changed. # wpa_psk (dot11RSNAConfigPSKValue) # wpa_passphrase (dot11RSNAConfigPSKPassPhrase) #wpa_psk=0123456789abcdef0123456789abcdef0123456789abcdef0123456789abcdef #wpa_passphrase=secret passphrase # Optionally, WPA PSKs can be read from a separate text file (containing list # of (PSK,MAC address) pairs. This allows more than one PSK to be configured. # Use absolute path name to make sure that the files can be read on SIGHUP # configuration reloads. #wpa_psk_file=/etc/hostapd.wpa_psk # Optionally, WPA passphrase can be received from RADIUS authentication server # This requires macaddr_acl to be set to 2 (RADIUS) # 0 = disabled (default) # 1 = optional; use default passphrase/psk if RADIUS server does not include # Tunnel-Password # 2 = required; reject authentication if RADIUS server does not include # Tunnel-Password #wpa_psk_radius=0 # Set of accepted key management algorithms (WPA-PSK, WPA-EAP, or both). The # entries are separated with a space. WPA-PSK-SHA256 and WPA-EAP-SHA256 can be # added to enable SHA256-based stronger algorithms. # WPA-PSK = WPA-Personal / WPA2-Personal # WPA-PSK-SHA256 = WPA2-Personal using SHA256 # WPA-EAP = WPA-Enterprise / WPA2-Enterprise # WPA-EAP-SHA256 = WPA2-Enterprise using SHA256 # SAE = SAE (WPA3-Personal) # WPA-EAP-SUITE-B-192 = WPA3-Enterprise with 192-bit security/CNSA suite # FT-PSK = FT with passphrase/PSK # FT-EAP = FT with EAP # FT-EAP-SHA384 = FT with EAP using SHA384 # FT-SAE = FT with SAE # FILS-SHA256 = Fast Initial Link Setup with SHA256 # FILS-SHA384 = Fast Initial Link Setup with SHA384 # FT-FILS-SHA256 = FT and Fast Initial Link Setup with SHA256 # FT-FILS-SHA384 = FT and Fast Initial Link Setup with SHA384 # OWE = Opportunistic Wireless Encryption (a.k.a. Enhanced Open) # DPP = Device Provisioning Protocol # OSEN = Hotspot 2.0 online signup with encryption # (dot11RSNAConfigAuthenticationSuitesTable) #wpa_key_mgmt=WPA-PSK WPA-EAP # Set of accepted cipher suites (encryption algorithms) for pairwise keys # (unicast packets). This is a space separated list of algorithms: # CCMP = AES in Counter mode with CBC-MAC (CCMP-128) # TKIP = Temporal Key Integrity Protocol # CCMP-256 = AES in Counter mode with CBC-MAC with 256-bit key # GCMP = Galois/counter mode protocol (GCMP-128) # GCMP-256 = Galois/counter mode protocol with 256-bit key # Group cipher suite (encryption algorithm for broadcast and multicast frames) # is automatically selected based on this configuration. If only CCMP is # allowed as the pairwise cipher, group cipher will also be CCMP. Otherwise, # TKIP will be used as the group cipher. The optional group_cipher parameter can # be used to override this automatic selection. # # (dot11RSNAConfigPairwiseCiphersTable) # Pairwise cipher for WPA (v1) (default: TKIP) #wpa_pairwise=TKIP CCMP # Pairwise cipher for RSN/WPA2 (default: use wpa_pairwise value) #rsn_pairwise=CCMP # Optional override for automatic group cipher selection # This can be used to select a specific group cipher regardless of which # pairwise ciphers were enabled for WPA and RSN. It should be noted that # overriding the group cipher with an unexpected value can result in # interoperability issues and in general, this parameter is mainly used for # testing purposes. #group_cipher=CCMP # Time interval for rekeying GTK (broadcast/multicast encryption keys) in # seconds. (dot11RSNAConfigGroupRekeyTime) # This defaults to 86400 seconds (once per day) when using CCMP/GCMP as the # group cipher and 600 seconds (once per 10 minutes) when using TKIP as the # group cipher. #wpa_group_rekey=86400 # Rekey GTK when any STA that possesses the current GTK is leaving the BSS. # (dot11RSNAConfigGroupRekeyStrict) #wpa_strict_rekey=1 # The number of times EAPOL-Key Message 1/2 in the RSN Group Key Handshake is #retried per GTK Handshake attempt. (dot11RSNAConfigGroupUpdateCount) # This value should only be increased when stations are constantly # deauthenticated during GTK rekeying with the log message # "group key handshake failed...". # You should consider to also increase wpa_pairwise_update_count then. # Range 1..4294967295; default: 4 #wpa_group_update_count=4 # Time interval for rekeying GMK (master key used internally to generate GTKs # (in seconds). #wpa_gmk_rekey=86400 # Maximum lifetime for PTK in seconds. This can be used to enforce rekeying of # PTK to mitigate some attacks against TKIP deficiencies. # Warning: PTK rekeying is buggy with many drivers/devices and with such # devices, the only secure method to rekey the PTK without Extended Key ID # support requires a disconnection. Check the related parameter # wpa_deny_ptk0_rekey for details. #wpa_ptk_rekey=600 # Workaround for PTK rekey issues # # PTK0 rekeys (rekeying the PTK without "Extended Key ID for Individually # Addressed Frames") can degrade the security and stability with some cards. # To avoid such issues hostapd can replace those PTK rekeys (including EAP # reauthentications) with disconnects. # # Available options: # 0 = always rekey when configured/instructed (default) # 1 = only rekey when the local driver is explicitly indicating it can perform # this operation without issues # 2 = never allow PTK0 rekeys #wpa_deny_ptk0_rekey=0 # The number of times EAPOL-Key Message 1/4 and Message 3/4 in the RSN 4-Way # Handshake are retried per 4-Way Handshake attempt. # (dot11RSNAConfigPairwiseUpdateCount) # Range 1..4294967295; default: 4 #wpa_pairwise_update_count=4 # Workaround for key reinstallation attacks # # This parameter can be used to disable retransmission of EAPOL-Key frames that # are used to install keys (EAPOL-Key message 3/4 and group message 1/2). This # is similar to setting wpa_group_update_count=1 and # wpa_pairwise_update_count=1, but with no impact to message 1/4 and with # extended timeout on the response to avoid causing issues with stations that # may use aggressive power saving have very long time in replying to the # EAPOL-Key messages. # # This option can be used to work around key reinstallation attacks on the # station (supplicant) side in cases those station devices cannot be updated # for some reason. By removing the retransmissions the attacker cannot cause # key reinstallation with a delayed frame transmission. This is related to the # station side vulnerabilities CVE-2017-13077, CVE-2017-13078, CVE-2017-13079, # CVE-2017-13080, and CVE-2017-13081. # # This workaround might cause interoperability issues and reduced robustness of # key negotiation especially in environments with heavy traffic load due to the # number of attempts to perform the key exchange is reduced significantly. As # such, this workaround is disabled by default (unless overridden in build # configuration). To enable this, set the parameter to 1. #wpa_disable_eapol_key_retries=1 # Enable IEEE 802.11i/RSN/WPA2 pre-authentication. This is used to speed up # roaming be pre-authenticating IEEE 802.1X/EAP part of the full RSN # authentication and key handshake before actually associating with a new AP. # (dot11RSNAPreauthenticationEnabled) #rsn_preauth=1 # # Space separated list of interfaces from which pre-authentication frames are # accepted (e.g., 'eth0' or 'eth0 wlan0wds0'. This list should include all # interface that are used for connections to other APs. This could include # wired interfaces and WDS links. The normal wireless data interface towards # associated stations (e.g., wlan0) should not be added, since # pre-authentication is only used with APs other than the currently associated # one. #rsn_preauth_interfaces=eth0 # ieee80211w: Whether management frame protection (MFP) is enabled # 0 = disabled (default) # 1 = optional # 2 = required #ieee80211w=0 # The most common configuration options for this based on the PMF (protected # management frames) certification program are: # PMF enabled: ieee80211w=1 and wpa_key_mgmt=WPA-EAP WPA-EAP-SHA256 # PMF required: ieee80211w=2 and wpa_key_mgmt=WPA-EAP-SHA256 # (and similarly for WPA-PSK and WPA-PSK-SHA256 if WPA2-Personal is used) # WPA3-Personal-only mode: ieee80211w=2 and wpa_key_mgmt=SAE # Group management cipher suite # Default: AES-128-CMAC (BIP) # Other options (depending on driver support): # BIP-GMAC-128 # BIP-GMAC-256 # BIP-CMAC-256 # Note: All the stations connecting to the BSS will also need to support the # selected cipher. The default AES-128-CMAC is the only option that is commonly # available in deployed devices. #group_mgmt_cipher=AES-128-CMAC # Beacon Protection (management frame protection for Beacon frames) # This depends on management frame protection being enabled (ieee80211w != 0) # and beacon protection support indication from the driver. # 0 = disabled (default) # 1 = enabled #beacon_prot=0 # Association SA Query maximum timeout (in TU = 1.024 ms; for MFP) # (maximum time to wait for a SA Query response) # dot11AssociationSAQueryMaximumTimeout, 1...4294967295 #assoc_sa_query_max_timeout=1000 # Association SA Query retry timeout (in TU = 1.024 ms; for MFP) # (time between two subsequent SA Query requests) # dot11AssociationSAQueryRetryTimeout, 1...4294967295 #assoc_sa_query_retry_timeout=201 # ocv: Operating Channel Validation # This is a countermeasure against multi-channel on-path attacks. # Enabling this depends on the driver's support for OCV when the driver SME is # used. If hostapd SME is used, this will be enabled just based on this # configuration. # Enabling this automatically also enables ieee80211w, if not yet enabled. # 0 = disabled (default) # 1 = enabled # 2 = enabled in workaround mode - Allow STA that claims OCV capability to # connect even if the STA doesn't send OCI or negotiate PMF. This # workaround is to improve interoperability with legacy STAs which are # wrongly copying reserved bits of RSN capabilities from the AP's # RSNE into (Re)Association Request frames. When this configuration is # enabled, the AP considers STA is OCV capable only when the STA indicates # MFP capability in (Re)Association Request frames and sends OCI in # EAPOL-Key msg 2/4/FT Reassociation Request frame/FILS (Re)Association # Request frame; otherwise, the AP disables OCV for the current connection # with the STA. Enabling this workaround mode reduced OCV protection to # some extend since it allows misbehavior to go through. As such, this # should be enabled only if interoperability with misbehaving STAs is # needed. #ocv=1 # disable_pmksa_caching: Disable PMKSA caching # This parameter can be used to disable caching of PMKSA created through EAP # authentication. RSN preauthentication may still end up using PMKSA caching if # it is enabled (rsn_preauth=1). # 0 = PMKSA caching enabled (default) # 1 = PMKSA caching disabled #disable_pmksa_caching=0 # okc: Opportunistic Key Caching (aka Proactive Key Caching) # Allow PMK cache to be shared opportunistically among configured interfaces # and BSSes (i.e., all configurations within a single hostapd process). # 0 = disabled (default) # 1 = enabled #okc=1 # SAE password # This parameter can be used to set passwords for SAE. By default, the # wpa_passphrase value is used if this separate parameter is not used, but # wpa_passphrase follows the WPA-PSK constraints (8..63 characters) even though # SAE passwords do not have such constraints. If the BSS enabled both SAE and # WPA-PSK and both values are set, SAE uses the sae_password values and WPA-PSK # uses the wpa_passphrase value. # # Each sae_password entry is added to a list of available passwords. This # corresponds to the dot11RSNAConfigPasswordValueEntry. sae_password value # starts with the password (dot11RSNAConfigPasswordCredential). That value can # be followed by optional peer MAC address (dot11RSNAConfigPasswordPeerMac) and # by optional password identifier (dot11RSNAConfigPasswordIdentifier). In # addition, an optional VLAN ID specification can be used to bind the station # to the specified VLAN whenever the specific SAE password entry is used. # # If the peer MAC address is not included or is set to the wildcard address # (ff:ff:ff:ff:ff:ff), the entry is available for any station to use. If a # specific peer MAC address is included, only a station with that MAC address # is allowed to use the entry. # # If the password identifier (with non-zero length) is included, the entry is # limited to be used only with that specified identifier. # The last matching (based on peer MAC address and identifier) entry is used to # select which password to use. Setting sae_password to an empty string has a # special meaning of removing all previously added entries. # # sae_password uses the following encoding: #<password/credential>[|mac=<peer mac>][|vlanid=<VLAN ID>] #[|pk=<m:ECPrivateKey-base64>][|id=<identifier>] # Examples: #sae_password=secret #sae_password=really secret|mac=ff:ff:ff:ff:ff:ff #sae_password=example secret|mac=02:03:04:05:06:07|id=pw identifier #sae_password=example secret|vlanid=3|id=pw identifier # SAE threshold for anti-clogging mechanism (dot11RSNASAEAntiCloggingThreshold) # This parameter defines how many open SAE instances can be in progress at the # same time before the anti-clogging mechanism is taken into use. #sae_anti_clogging_threshold=5 (deprecated) #anti_clogging_threshold=5 # Maximum number of SAE synchronization errors (dot11RSNASAESync) # The offending SAE peer will be disconnected if more than this many # synchronization errors happen. #sae_sync=5 # Enabled SAE finite cyclic groups # SAE implementation are required to support group 19 (ECC group defined over a # 256-bit prime order field). This configuration parameter can be used to # specify a set of allowed groups. If not included, only the mandatory group 19 # is enabled. # The group values are listed in the IANA registry: # http://www.iana.org/assignments/ipsec-registry/ipsec-registry.xml#ipsec-registry-9 # Note that groups 1, 2, 5, 22, 23, and 24 should not be used in production # purposes due limited security (see RFC 8247). Groups that are not as strong as # group 19 (ECC, NIST P-256) are unlikely to be useful for production use cases # since all implementations are required to support group 19. #sae_groups=19 20 21 # Require MFP for all associations using SAE # This parameter can be used to enforce negotiation of MFP for all associations # that negotiate use of SAE. This is used in cases where SAE-capable devices are # known to be MFP-capable and the BSS is configured with optional MFP # (ieee80211w=1) for legacy support. The non-SAE stations can connect without # MFP while SAE stations are required to negotiate MFP if sae_require_mfp=1. #sae_require_mfp=0 # SAE Confirm behavior # By default, AP will send out only SAE Commit message in response to a received # SAE Commit message. This parameter can be set to 1 to override that behavior # to send both SAE Commit and SAE Confirm messages without waiting for the STA # to send its SAE Confirm message first. #sae_confirm_immediate=0 # SAE mechanism for PWE derivation # 0 = hunting-and-pecking loop only (default without password identifier) # 1 = hash-to-element only (default with password identifier) # 2 = both hunting-and-pecking loop and hash-to-element enabled # Note: The default value is likely to change from 0 to 2 once the new # hash-to-element mechanism has received more interoperability testing. # When using SAE password identifier, the hash-to-element mechanism is used # regardless of the sae_pwe parameter value. #sae_pwe=0 # FILS Cache Identifier (16-bit value in hexdump format) #fils_cache_id=0011 # FILS Realm Information # One or more FILS realms need to be configured when FILS is enabled. This list # of realms is used to define which realms (used in keyName-NAI by the client) # can be used with FILS shared key authentication for ERP. #fils_realm=example.com #fils_realm=example.org # FILS DH Group for PFS # 0 = PFS disabled with FILS shared key authentication (default) # 1-65535 DH Group to use for FILS PFS #fils_dh_group=0 # OWE DH groups # OWE implementations are required to support group 19 (NIST P-256). All groups # that are supported by the implementation (e.g., groups 19, 20, and 21 when # using OpenSSL) are enabled by default. This configuration parameter can be # used to specify a limited set of allowed groups. The group values are listed # in the IANA registry: # http://www.iana.org/assignments/ipsec-registry/ipsec-registry.xml#ipsec-registry-10 #owe_groups=19 20 21 # OWE PTK derivation workaround # Initial OWE implementation used SHA256 when deriving the PTK for all OWE # groups. This was supposed to change to SHA384 for group 20 and SHA512 for # group 21. This parameter can be used to enable workaround for interoperability # with stations that use SHA256 with groups 20 and 21. By default (0) only the # appropriate hash function is accepted. When workaround is enabled (1), the # appropriate hash function is tried first and if that fails, SHA256-based PTK # derivation is attempted. This workaround can result in reduced security for # groups 20 and 21, but is required for interoperability with older # implementations. There is no impact to group 19 behavior. The workaround is # disabled by default and can be enabled by uncommenting the following line. #owe_ptk_workaround=1 # OWE transition mode configuration # Pointer to the matching open/OWE BSS #owe_transition_bssid=<bssid> # SSID in same format as ssid2 described above. #owe_transition_ssid=<SSID> # Alternatively, OWE transition mode BSSID/SSID can be configured with a # reference to a BSS operated by this hostapd process. #owe_transition_ifname=<ifname> # DHCP server for FILS HLP # If configured, hostapd will act as a DHCP relay for all FILS HLP requests # that include a DHCPDISCOVER message and send them to the specific DHCP # server for processing. hostapd will then wait for a response from that server # before replying with (Re)Association Response frame that encapsulates this # DHCP response. own_ip_addr is used as the local address for the communication # with the DHCP server. #dhcp_server=127.0.0.1 # DHCP server UDP port # Default: 67 #dhcp_server_port=67 # DHCP relay UDP port on the local device # Default: 67; 0 means not to bind any specific port #dhcp_relay_port=67 # DHCP rapid commit proxy # If set to 1, this enables hostapd to act as a DHCP rapid commit proxy to # allow the rapid commit options (two message DHCP exchange) to be used with a # server that supports only the four message DHCP exchange. This is disabled by # default (= 0) and can be enabled by setting this to 1. #dhcp_rapid_commit_proxy=0 # Wait time for FILS HLP (dot11HLPWaitTime) in TUs # default: 30 TUs (= 30.72 milliseconds) #fils_hlp_wait_time=30 # FILS Discovery frame transmission minimum and maximum interval settings. # If fils_discovery_max_interval is non-zero, the AP enables FILS Discovery # frame transmission. These values use TUs as the unit and have allowed range # of 0-10000. fils_discovery_min_interval defaults to 20. #fils_discovery_min_interval=20 #fils_discovery_max_interval=0 # Transition Disable indication # The AP can notify authenticated stations to disable transition mode in their # network profiles when the network has completed transition steps, i.e., once # sufficiently large number of APs in the ESS have been updated to support the # more secure alternative. When this indication is used, the stations are # expected to automatically disable transition mode and less secure security # options. This includes use of WEP, TKIP (including use of TKIP as the group # cipher), and connections without PMF. # Bitmap bits: # bit 0 (0x01): WPA3-Personal (i.e., disable WPA2-Personal = WPA-PSK and only # allow SAE to be used) # bit 1 (0x02): SAE-PK (disable SAE without use of SAE-PK) # bit 2 (0x04): WPA3-Enterprise (move to requiring PMF) # bit 3 (0x08): Enhanced Open (disable use of open network; require OWE) # (default: 0 = do not include Transition Disable KDE) #transition_disable=0x01 # PASN ECDH groups # PASN implementations are required to support group 19 (NIST P-256). If this # parameter is not set, only group 19 is supported by default. This # configuration parameter can be used to specify a limited set of allowed # groups. The group values are listed in the IANA registry: # http://www.iana.org/assignments/ipsec-registry/ipsec-registry.xml#ipsec-registry-10 #pasn_groups=19 20 21 # PASN comeback after time in TUs # In case the AP is temporarily unable to handle a PASN authentication exchange # due to a too large number of parallel operations, this value indicates to the # peer after how many TUs it can try the PASN exchange again. # (default: 10 TUs) #pasn_comeback_after=10 ##### IEEE 802.11r configuration ############################################## # Mobility Domain identifier (dot11FTMobilityDomainID, MDID) # MDID is used to indicate a group of APs (within an ESS, i.e., sharing the # same SSID) between which a STA can use Fast BSS Transition. # 2-octet identifier as a hex string. #mobility_domain=a1b2 # PMK-R0 Key Holder identifier (dot11FTR0KeyHolderID) # 1 to 48 octet identifier. # This is configured with nas_identifier (see RADIUS client section above). # Default lifetime of the PMK-R0 in seconds; range 60..4294967295 # (default: 14 days / 1209600 seconds; 0 = disable timeout) # (dot11FTR0KeyLifetime) #ft_r0_key_lifetime=1209600 # Maximum lifetime for PMK-R1; applied only if not zero # PMK-R1 is removed at latest after this limit. # Removing any PMK-R1 for expiry can be disabled by setting this to -1. # (default: 0) #r1_max_key_lifetime=0 # PMK-R1 Key Holder identifier (dot11FTR1KeyHolderID) # 6-octet identifier as a hex string. # Defaults to BSSID. #r1_key_holder=000102030405 # Reassociation deadline in time units (TUs / 1.024 ms; range 1000..65535) # (dot11FTReassociationDeadline) #reassociation_deadline=1000 # List of R0KHs in the same Mobility Domain # format: <MAC address> <NAS Identifier> <256-bit key as hex string> # This list is used to map R0KH-ID (NAS Identifier) to a destination MAC # address when requesting PMK-R1 key from the R0KH that the STA used during the # Initial Mobility Domain Association. #r0kh=02:01:02:03:04:05 r0kh-1.example.com 000102030405060708090a0b0c0d0e0f000102030405060708090a0b0c0d0e0f #r0kh=02:01:02:03:04:06 r0kh-2.example.com 00112233445566778899aabbccddeeff00112233445566778899aabbccddeeff # And so on.. One line per R0KH. # Wildcard entry: # Upon receiving a response from R0KH, it will be added to this list, so # subsequent requests won't be broadcast. If R0KH does not reply, it will be # temporarily blocked (see rkh_neg_timeout). #r0kh=ff:ff:ff:ff:ff:ff * 00112233445566778899aabbccddeeff # List of R1KHs in the same Mobility Domain # format: <MAC address> <R1KH-ID> <256-bit key as hex string> # This list is used to map R1KH-ID to a destination MAC address when sending # PMK-R1 key from the R0KH. This is also the list of authorized R1KHs in the MD # that can request PMK-R1 keys. #r1kh=02:01:02:03:04:05 02:11:22:33:44:55 000102030405060708090a0b0c0d0e0f000102030405060708090a0b0c0d0e0f #r1kh=02:01:02:03:04:06 02:11:22:33:44:66 00112233445566778899aabbccddeeff00112233445566778899aabbccddeeff # And so on.. One line per R1KH. # Wildcard entry: # Upon receiving a request from an R1KH not yet known, it will be added to this # list and thus will receive push notifications. #r1kh=00:00:00:00:00:00 00:00:00:00:00:00 00112233445566778899aabbccddeeff # Timeout (seconds) for newly discovered R0KH/R1KH (see wildcard entries above) # Special values: 0 -> do not expire # Warning: do not cache implies no sequence number validation with wildcards #rkh_pos_timeout=86400 (default = 1 day) # Timeout (milliseconds) for requesting PMK-R1 from R0KH using PULL request # and number of retries. #rkh_pull_timeout=1000 (default = 1 second) #rkh_pull_retries=4 (default) # Timeout (seconds) for non replying R0KH (see wildcard entries above) # Special values: 0 -> do not cache # default: 60 seconds #rkh_neg_timeout=60 # Note: The R0KH/R1KH keys used to be 128-bit in length before the message # format was changed. That shorter key length is still supported for backwards # compatibility of the configuration files. If such a shorter key is used, a # 256-bit key is derived from it. For new deployments, configuring the 256-bit # key is recommended. # Whether PMK-R1 push is enabled at R0KH # 0 = do not push PMK-R1 to all configured R1KHs (default) # 1 = push PMK-R1 to all configured R1KHs whenever a new PMK-R0 is derived #pmk_r1_push=1 # Whether to enable FT-over-DS # 0 = FT-over-DS disabled # 1 = FT-over-DS enabled (default) #ft_over_ds=1 # Whether to generate FT response locally for PSK networks # This avoids use of PMK-R1 push/pull from other APs with FT-PSK networks as # the required information (PSK and other session data) is already locally # available. # 0 = disabled (default) # 1 = enabled #ft_psk_generate_local=0 ##### Neighbor table ########################################################## # Maximum number of entries kept in AP table (either for neighbor table or for # detecting Overlapping Legacy BSS Condition). The oldest entry will be # removed when adding a new entry that would make the list grow over this # limit. Note! WFA certification for IEEE 802.11g requires that OLBC is # enabled, so this field should not be set to 0 when using IEEE 802.11g. # default: 255 #ap_table_max_size=255 # Number of seconds of no frames received after which entries may be deleted # from the AP table. Since passive scanning is not usually performed frequently # this should not be set to very small value. In addition, there is no # guarantee that every scan cycle will receive beacon frames from the # neighboring APs. # default: 60 #ap_table_expiration_time=3600 # Maximum number of stations to track on the operating channel # This can be used to detect dualband capable stations before they have # associated, e.g., to provide guidance on which colocated BSS to use. # Default: 0 (disabled) #track_sta_max_num=100 # Maximum age of a station tracking entry in seconds # Default: 180 #track_sta_max_age=180 # Do not reply to group-addressed Probe Request from a station that was seen on # another radio. # Default: Disabled # # This can be used with enabled track_sta_max_num configuration on another # interface controlled by the same hostapd process to restrict Probe Request # frame handling from replying to group-addressed Probe Request frames from a # station that has been detected to be capable of operating on another band, # e.g., to try to reduce likelihood of the station selecting a 2.4 GHz BSS when # the AP operates both a 2.4 GHz and 5 GHz BSS concurrently. # # Note: Enabling this can cause connectivity issues and increase latency for # discovering the AP. #no_probe_resp_if_seen_on=wlan1 # Reject authentication from a station that was seen on another radio. # Default: Disabled # # This can be used with enabled track_sta_max_num configuration on another # interface controlled by the same hostapd process to reject authentication # attempts from a station that has been detected to be capable of operating on # another band, e.g., to try to reduce likelihood of the station selecting a # 2.4 GHz BSS when the AP operates both a 2.4 GHz and 5 GHz BSS concurrently. # # Note: Enabling this can cause connectivity issues and increase latency for # connecting with the AP. #no_auth_if_seen_on=wlan1 ##### Wi-Fi Protected Setup (WPS) ############################################# # WPS state # 0 = WPS disabled (default) # 1 = WPS enabled, not configured # 2 = WPS enabled, configured #wps_state=2 # Whether to manage this interface independently from other WPS interfaces # By default, a single hostapd process applies WPS operations to all configured # interfaces. This parameter can be used to disable that behavior for a subset # of interfaces. If this is set to non-zero for an interface, WPS commands # issued on that interface do not apply to other interfaces and WPS operations # performed on other interfaces do not affect this interface. #wps_independent=0 # AP can be configured into a locked state where new WPS Registrar are not # accepted, but previously authorized Registrars (including the internal one) # can continue to add new Enrollees. #ap_setup_locked=1 # Universally Unique IDentifier (UUID; see RFC 4122) of the device # This value is used as the UUID for the internal WPS Registrar. If the AP # is also using UPnP, this value should be set to the device's UPnP UUID. # If not configured, UUID will be generated based on the local MAC address. #uuid=12345678-9abc-def0-1234-56789abcdef0 # Note: If wpa_psk_file is set, WPS is used to generate random, per-device PSKs # that will be appended to the wpa_psk_file. If wpa_psk_file is not set, the # default PSK (wpa_psk/wpa_passphrase) will be delivered to Enrollees. Use of # per-device PSKs is recommended as the more secure option (i.e., make sure to # set wpa_psk_file when using WPS with WPA-PSK). # When an Enrollee requests access to the network with PIN method, the Enrollee # PIN will need to be entered for the Registrar. PIN request notifications are # sent to hostapd ctrl_iface monitor. In addition, they can be written to a # text file that could be used, e.g., to populate the AP administration UI with # pending PIN requests. If the following variable is set, the PIN requests will # be written to the configured file. #wps_pin_requests=/var/run/hostapd_wps_pin_requests # Device Name # User-friendly description of device; up to 32 octets encoded in UTF-8 #device_name=Wireless AP # 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=WAP # 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=6-0050F204-1 # OS Version # 4-octet operating system version number (hex string) #os_version=01020300 # Config Methods # List of the supported configuration methods # Available methods: usba ethernet label display ext_nfc_token int_nfc_token # nfc_interface push_button keypad virtual_display physical_display # virtual_push_button physical_push_button #config_methods=label virtual_display virtual_push_button keypad # WPS capability discovery workaround for PBC with Windows 7 # Windows 7 uses incorrect way of figuring out AP's WPS capabilities by acting # as a Registrar and using M1 from the AP. The config methods attribute in that # message is supposed to indicate only the configuration method supported by # the AP in Enrollee role, i.e., to add an external Registrar. For that case, # PBC shall not be used and as such, the PushButton config method is removed # from M1 by default. If pbc_in_m1=1 is included in the configuration file, # the PushButton config method is left in M1 (if included in config_methods # parameter) to allow Windows 7 to use PBC instead of PIN (e.g., from a label # in the AP). #pbc_in_m1=1 # Static access point PIN for initial configuration and adding Registrars # If not set, hostapd will not allow external WPS Registrars to control the # access point. The AP PIN can also be set at runtime with hostapd_cli # wps_ap_pin command. Use of temporary (enabled by user action) and random # AP PIN is much more secure than configuring a static AP PIN here. As such, # use of the ap_pin parameter is not recommended if the AP device has means for # displaying a random PIN. #ap_pin=12345670 # Skip building of automatic WPS credential # This can be used to allow the automatically generated Credential attribute to # be replaced with pre-configured Credential(s). #skip_cred_build=1 # Additional Credential attribute(s) # This option can be used to add pre-configured Credential attributes into M8 # message when acting as a Registrar. If skip_cred_build=1, this data will also # be able to override the Credential attribute that would have otherwise been # automatically generated based on network configuration. This configuration # option points to an external file that much contain the WPS Credential # attribute(s) as binary data. #extra_cred=hostapd.cred # 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) # Note: With wps_cred_processing=1, skip_cred_build should be set to 1 and # extra_cred be used to provide the Credential data for Enrollees. # # wps_cred_processing=1 will disabled automatic updates of hostapd.conf file # both for Credential processing and for marking AP Setup Locked based on # validation failures of AP PIN. An external program is responsible on updating # the configuration appropriately in this case. #wps_cred_processing=0 # Whether to enable SAE (WPA3-Personal transition mode) automatically for # WPA2-PSK credentials received using WPS. # 0 = only add the explicitly listed WPA2-PSK configuration (default) # 1 = add both the WPA2-PSK and SAE configuration and enable PMF so that the # AP gets configured in WPA3-Personal transition mode (supports both # WPA2-Personal (PSK) and WPA3-Personal (SAE) clients). #wps_cred_add_sae=0 # AP Settings Attributes for M7 # By default, hostapd generates the AP Settings Attributes for M7 based on the # current configuration. It is possible to override this by providing a file # with pre-configured attributes. This is similar to extra_cred file format, # but the AP Settings attributes are not encapsulated in a Credential # attribute. #ap_settings=hostapd.ap_settings # Multi-AP backhaul BSS config # Used in WPS when multi_ap=2 or 3. Defines "backhaul BSS" credentials. # These are passed in WPS M8 instead of the normal (fronthaul) credentials # if the Enrollee has the Multi-AP subelement set. Backhaul SSID is formatted # like ssid2. The key is set like wpa_psk or wpa_passphrase. #multi_ap_backhaul_ssid="backhaul" #multi_ap_backhaul_wpa_psk=0123456789abcdef0123456789abcdef0123456789abcdef0123456789abcdef #multi_ap_backhaul_wpa_passphrase=secret passphrase # WPS UPnP interface # If set, support for external Registrars is enabled. #upnp_iface=br0 # Friendly Name (required for UPnP) # Short description for end use. Should be less than 64 characters. #friendly_name=WPS Access Point # Manufacturer URL (optional for UPnP) #manufacturer_url=http://www.example.com/ # Model Description (recommended for UPnP) # Long description for end user. Should be less than 128 characters. #model_description=Wireless Access Point # Model URL (optional for UPnP) #model_url=http://www.example.com/model/ # Universal Product Code (optional for UPnP) # 12-digit, all-numeric code that identifies the consumer package. #upc=123456789012 # WPS RF Bands (a = 5G, b = 2.4G, g = 2.4G, ag = dual band, ad = 60 GHz) # This value should be set according to RF band(s) supported by the AP if # hw_mode is not set. For dual band dual concurrent devices, this needs to be # set to ag to allow both RF bands to be advertized. #wps_rf_bands=ag # NFC password token for WPS # These parameters can be used to configure a fixed NFC password token for the # AP. This can be generated, e.g., with nfc_pw_token from wpa_supplicant. When # these parameters are used, the AP is assumed to be deployed with a NFC tag # that includes the matching NFC password token (e.g., written based on the # NDEF record from nfc_pw_token). # #wps_nfc_dev_pw_id: Device Password ID (16..65535) #wps_nfc_dh_pubkey: Hexdump of DH Public Key #wps_nfc_dh_privkey: Hexdump of DH Private Key #wps_nfc_dev_pw: Hexdump of Device Password # Application Extension attribute for Beacon and Probe Response frames # This parameter can be used to add application extension into WPS IE. The # contents of this parameter starts with 16-octet (32 hexdump characters) of # UUID to identify the specific application and that is followed by the actual # application specific data. #wps_application_ext=<hexdump> ##### Wi-Fi Direct (P2P) ###################################################### # Enable P2P Device management #manage_p2p=1 # Allow cross connection #allow_cross_connection=1 ##### Device Provisioning Protocol (DPP) ###################################### # Name for Enrollee's DPP Configuration Request #dpp_name=Test # MUD URL for Enrollee's DPP Configuration Request (optional) #dpp_mud_url=https://example.com/mud #dpp_connector #dpp_netaccesskey #dpp_netaccesskey_expiry #dpp_csign #dpp_controller # Configurator Connectivity indication # 0: no Configurator is currently connected (default) # 1: advertise that a Configurator is available #dpp_configurator_connectivity=0 # DPP PFS # 0: allow PFS to be used or not used (default) # 1: require PFS to be used (note: not compatible with DPP R1) # 2: do not allow PFS to be used #dpp_pfs=0 #### TDLS (IEEE 802.11z-2010) ################################################# # Prohibit use of TDLS in this BSS #tdls_prohibit=1 # Prohibit use of TDLS Channel Switching in this BSS #tdls_prohibit_chan_switch=1 ##### IEEE 802.11v-2011 ####################################################### # Time advertisement # 0 = disabled (default) # 2 = UTC time at which the TSF timer is 0 #time_advertisement=2 # Local time zone as specified in 8.3 of IEEE Std 1003.1-2004: # stdoffset[dst[offset][,start[/time],end[/time]]] #time_zone=EST5 # WNM-Sleep Mode (extended sleep mode for stations) # 0 = disabled (default) # 1 = enabled (allow stations to use WNM-Sleep Mode) #wnm_sleep_mode=1 # WNM-Sleep Mode GTK/IGTK workaround # Normally, WNM-Sleep Mode exit with management frame protection negotiated # would result in the current GTK/IGTK getting added into the WNM-Sleep Mode # Response frame. Some station implementations may have a vulnerability that # results in GTK/IGTK reinstallation based on this frame being replayed. This # configuration parameter can be used to disable that behavior and use EAPOL-Key # frames for GTK/IGTK update instead. This would likely be only used with # wpa_disable_eapol_key_retries=1 that enables a workaround for similar issues # with EAPOL-Key. This is related to station side vulnerabilities CVE-2017-13087 # and CVE-2017-13088. To enable this AP-side workaround, set the parameter to 1. #wnm_sleep_mode_no_keys=0 # BSS Transition Management # 0 = disabled (default) # 1 = enabled #bss_transition=1 # Proxy ARP # 0 = disabled (default) # 1 = enabled #proxy_arp=1 # IPv6 Neighbor Advertisement multicast-to-unicast conversion # This can be used with Proxy ARP to allow multicast NAs to be forwarded to # associated STAs using link layer unicast delivery. # 0 = disabled (default) # 1 = enabled #na_mcast_to_ucast=0 ##### IEEE 802.11u-2011 ####################################################### # Enable Interworking service #interworking=1 # Access Network Type # 0 = Private network # 1 = Private network with guest access # 2 = Chargeable public network # 3 = Free public network # 4 = Personal device network # 5 = Emergency services only network # 14 = Test or experimental # 15 = Wildcard #access_network_type=0 # Whether the network provides connectivity to the Internet # 0 = Unspecified # 1 = Network provides connectivity to the Internet #internet=1 # Additional Step Required for Access # Note: This is only used with open network, i.e., ASRA shall ne set to 0 if # RSN is used. #asra=0 # Emergency services reachable #esr=0 # Unauthenticated emergency service accessible #uesa=0 # Venue Info (optional) # The available values are defined in IEEE Std 802.11u-2011, 7.3.1.34. # Example values (group,type): # 0,0 = Unspecified # 1,7 = Convention Center # 1,13 = Coffee Shop # 2,0 = Unspecified Business # 7,1 Private Residence #venue_group=7 #venue_type=1 # Homogeneous ESS identifier (optional; dot11HESSID) # If set, this shall be identifical to one of the BSSIDs in the homogeneous # ESS and this shall be set to the same value across all BSSs in homogeneous # ESS. #hessid=02:03:04:05:06:07 # Roaming Consortium List # Arbitrary number of Roaming Consortium OIs can be configured with each line # adding a new OI to the list. The first three entries are available through # Beacon and Probe Response frames. Any additional entry will be available only # through ANQP queries. Each OI is between 3 and 15 octets and is configured as # a hexstring. #roaming_consortium=021122 #roaming_consortium=2233445566 # Venue Name information # This parameter can be used to configure one or more Venue Name Duples for # Venue Name ANQP information. Each entry has a two or three character language # code (ISO-639) separated by colon from the venue name string. # Note that venue_group and venue_type have to be set for Venue Name # information to be complete. #venue_name=eng:Example venue #venue_name=fin:Esimerkkipaikka # Alternative format for language:value strings: # (double quoted string, printf-escaped string) #venue_name=P"eng:Example\nvenue" # Venue URL information # This parameter can be used to configure one or more Venue URL Duples to # provide additional information corresponding to Venue Name information. # Each entry has a Venue Number value separated by colon from the Venue URL # string. Venue Number indicates the corresponding venue_name entry (1 = 1st # venue_name, 2 = 2nd venue_name, and so on; 0 = no matching venue_name) #venue_url=1:http://www.example.com/info-eng #venue_url=2:http://www.example.com/info-fin # Network Authentication Type # This parameter indicates what type of network authentication is used in the # network. # format: <network auth type indicator (1-octet hex str)> [redirect URL] # Network Authentication Type Indicator values: # 00 = Acceptance of terms and conditions # 01 = On-line enrollment supported # 02 = http/https redirection # 03 = DNS redirection #network_auth_type=00 #network_auth_type=02http://www.example.com/redirect/me/here/ # IP Address Type Availability # format: <1-octet encoded value as hex str> # (ipv4_type & 0x3f) << 2 | (ipv6_type & 0x3) # ipv4_type: # 0 = Address type not available # 1 = Public IPv4 address available # 2 = Port-restricted IPv4 address available # 3 = Single NATed private IPv4 address available # 4 = Double NATed private IPv4 address available # 5 = Port-restricted IPv4 address and single NATed IPv4 address available # 6 = Port-restricted IPv4 address and double NATed IPv4 address available # 7 = Availability of the address type is not known # ipv6_type: # 0 = Address type not available # 1 = Address type available # 2 = Availability of the address type not known #ipaddr_type_availability=14 # Domain Name # format: <variable-octet str>[,<variable-octet str>] #domain_name=example.com,another.example.com,yet-another.example.com # 3GPP Cellular Network information # format: <MCC1,MNC1>[;<MCC2,MNC2>][;...] #anqp_3gpp_cell_net=244,91;310,026;234,56 # NAI Realm information # One or more realm can be advertised. Each nai_realm line adds a new realm to # the set. These parameters provide information for stations using Interworking # network selection to allow automatic connection to a network based on # credentials. # format: <encoding>,<NAI Realm(s)>[,<EAP Method 1>][,<EAP Method 2>][,...] # encoding: # 0 = Realm formatted in accordance with IETF RFC 4282 # 1 = UTF-8 formatted character string that is not formatted in # accordance with IETF RFC 4282 # NAI Realm(s): Semi-colon delimited NAI Realm(s) # EAP Method: <EAP Method>[:<[AuthParam1:Val1]>][<[AuthParam2:Val2]>][...] # EAP Method types, see: # http://www.iana.org/assignments/eap-numbers/eap-numbers.xhtml#eap-numbers-4 # AuthParam (Table 8-188 in IEEE Std 802.11-2012): # ID 2 = Non-EAP Inner Authentication Type # 1 = PAP, 2 = CHAP, 3 = MSCHAP, 4 = MSCHAPV2 # ID 3 = Inner authentication EAP Method Type # ID 5 = Credential Type # 1 = SIM, 2 = USIM, 3 = NFC Secure Element, 4 = Hardware Token, # 5 = Softoken, 6 = Certificate, 7 = username/password, 9 = Anonymous, # 10 = Vendor Specific #nai_realm=0,example.com;example.net # EAP methods EAP-TLS with certificate and EAP-TTLS/MSCHAPv2 with # username/password #nai_realm=0,example.org,13[5:6],21[2:4][5:7] # Arbitrary ANQP-element configuration # Additional ANQP-elements with arbitrary values can be defined by specifying # their contents in raw format as a hexdump of the payload. Note that these # values will override ANQP-element contents that may have been specified in the # more higher layer configuration parameters listed above. # format: anqp_elem=<InfoID>:<hexdump of payload> # For example, AP Geospatial Location ANQP-element with unknown location: #anqp_elem=265:0000 # For example, AP Civic Location ANQP-element with unknown location: #anqp_elem=266:000000 # GAS Address 3 behavior # 0 = P2P specification (Address3 = AP BSSID) workaround enabled by default # based on GAS request Address3 # 1 = IEEE 802.11 standard compliant regardless of GAS request Address3 # 2 = Force non-compliant behavior (Address3 = AP BSSID for all cases) #gas_address3=0 # QoS Map Set configuration # # Comma delimited QoS Map Set in decimal values # (see IEEE Std 802.11-2012, 8.4.2.97) # # format: # [<DSCP Exceptions[DSCP,UP]>,]<UP 0 range[low,high]>,...<UP 7 range[low,high]> # # There can be up to 21 optional DSCP Exceptions which are pairs of DSCP Value # (0..63 or 255) and User Priority (0..7). This is followed by eight DSCP Range # descriptions with DSCP Low Value and DSCP High Value pairs (0..63 or 255) for # each UP starting from 0. If both low and high value are set to 255, the # corresponding UP is not used. # # default: not set #qos_map_set=53,2,22,6,8,15,0,7,255,255,16,31,32,39,255,255,40,47,255,255 ##### Hotspot 2.0 ############################################################# # Enable Hotspot 2.0 support #hs20=1 # Disable Downstream Group-Addressed Forwarding (DGAF) # This can be used to configure a network where no group-addressed frames are # allowed. The AP will not forward any group-address frames to the stations and # random GTKs are issued for each station to prevent associated stations from # forging such frames to other stations in the BSS. #disable_dgaf=1 # OSU Server-Only Authenticated L2 Encryption Network #osen=1 # ANQP Domain ID (0..65535) # An identifier for a set of APs in an ESS that share the same common ANQP # information. 0 = Some of the ANQP information is unique to this AP (default). #anqp_domain_id=1234 # Deauthentication request timeout # If the RADIUS server indicates that the station is not allowed to connect to # the BSS/ESS, the AP can allow the station some time to download a # notification page (URL included in the message). This parameter sets that # timeout in seconds. #hs20_deauth_req_timeout=60 # Operator Friendly Name # This parameter can be used to configure one or more Operator Friendly Name # Duples. Each entry has a two or three character language code (ISO-639) # separated by colon from the operator friendly name string. #hs20_oper_friendly_name=eng:Example operator #hs20_oper_friendly_name=fin:Esimerkkioperaattori # Connection Capability # This can be used to advertise what type of IP traffic can be sent through the # hotspot (e.g., due to firewall allowing/blocking protocols/ports). # format: <IP Protocol>:<Port Number>:<Status> # IP Protocol: 1 = ICMP, 6 = TCP, 17 = UDP # Port Number: 0..65535 # Status: 0 = Closed, 1 = Open, 2 = Unknown # Each hs20_conn_capab line is added to the list of advertised tuples. #hs20_conn_capab=1:0:2 #hs20_conn_capab=6:22:1 #hs20_conn_capab=17:5060:0 # WAN Metrics # format: <WAN Info>:<DL Speed>:<UL Speed>:<DL Load>:<UL Load>:<LMD> # WAN Info: B0-B1: Link Status, B2: Symmetric Link, B3: At Capabity # (encoded as two hex digits) # Link Status: 1 = Link up, 2 = Link down, 3 = Link in test state # Downlink Speed: Estimate of WAN backhaul link current downlink speed in kbps; # 1..4294967295; 0 = unknown # Uplink Speed: Estimate of WAN backhaul link current uplink speed in kbps # 1..4294967295; 0 = unknown # Downlink Load: Current load of downlink WAN connection (scaled to 255 = 100%) # Uplink Load: Current load of uplink WAN connection (scaled to 255 = 100%) # Load Measurement Duration: Duration for measuring downlink/uplink load in # tenths of a second (1..65535); 0 if load cannot be determined #hs20_wan_metrics=01:8000:1000:80:240:3000 # Operating Class Indication # List of operating classes the BSSes in this ESS use. The Global operating # classes in Table E-4 of IEEE Std 802.11-2012 Annex E define the values that # can be used in this. # format: hexdump of operating class octets # for example, operating classes 81 (2.4 GHz channels 1-13) and 115 (5 GHz # channels 36-48): #hs20_operating_class=5173 # Terms and Conditions information # # hs20_t_c_filename contains the Terms and Conditions filename that the AP # indicates in RADIUS Access-Request messages. #hs20_t_c_filename=terms-and-conditions # # hs20_t_c_timestamp contains the Terms and Conditions timestamp that the AP # indicates in RADIUS Access-Request messages. Usually, this contains the number # of seconds since January 1, 1970 00:00 UTC showing the time when the file was # last modified. #hs20_t_c_timestamp=1234567 # # hs20_t_c_server_url contains a template for the Terms and Conditions server # URL. This template is used to generate the URL for a STA that needs to # acknowledge Terms and Conditions. Unlike the other hs20_t_c_* parameters, this # parameter is used on the authentication server, not the AP. # Macros: # @1@ = MAC address of the STA (colon separated hex octets) #hs20_t_c_server_url=https://example.com/t_and_c?addr=@1@&ap=123 # OSU and Operator icons # <Icon Width>:<Icon Height>:<Language code>:<Icon Type>:<Name>:<file path> #hs20_icon=32:32:eng:image/png:icon32:/tmp/icon32.png #hs20_icon=64:64:eng:image/png:icon64:/tmp/icon64.png # OSU SSID (see ssid2 for format description) # This is the SSID used for all OSU connections to all the listed OSU Providers. #osu_ssid="example" # OSU Providers # One or more sets of following parameter. Each OSU provider is started by the # mandatory osu_server_uri item. The other parameters add information for the # last added OSU provider. osu_nai specifies the OSU_NAI value for OSEN # authentication when using a standalone OSU BSS. osu_nai2 specifies the OSU_NAI # value for OSEN authentication when using a shared BSS (Single SSID) for OSU. # #osu_server_uri=https://example.com/osu/ #osu_friendly_name=eng:Example operator #osu_friendly_name=fin:Esimerkkipalveluntarjoaja #osu_nai=anonymous@example.com #osu_nai2=anonymous@example.com #osu_method_list=1 0 #osu_icon=icon32 #osu_icon=icon64 #osu_service_desc=eng:Example services #osu_service_desc=fin:Esimerkkipalveluja # #osu_server_uri=... # Operator Icons # Operator icons are specified using references to the hs20_icon entries # (Name subfield). This information, if present, is advertsised in the # Operator Icon Metadata ANQO-element. #operator_icon=icon32 #operator_icon=icon64 ##### Multiband Operation (MBO) ############################################### # # MBO enabled # 0 = disabled (default) # 1 = enabled #mbo=1 # # Cellular data connection preference # 0 = Excluded - AP does not want STA to use the cellular data connection # 1 = AP prefers the STA not to use cellular data connection # 255 = AP prefers the STA to use cellular data connection #mbo_cell_data_conn_pref=1 ##### Optimized Connectivity Experience (OCE) ################################# # # Enable OCE specific features (bitmap) # BIT(0) - Reserved # Set BIT(1) (= 2) to enable OCE in STA-CFON mode # Set BIT(2) (= 4) to enable OCE in AP mode # Default is 0 = OCE disabled #oce=0 # RSSI-based association rejection # # Reject STA association if RSSI is below given threshold (in dBm) # Allowed range: -60 to -90 dBm; default = 0 (rejection disabled) # Note: This rejection happens based on a signal strength detected while # receiving a single frame and as such, there is significant risk of the value # not being accurate and this resulting in valid stations being rejected. As # such, this functionality is not recommended to be used for purposes other than # testing. #rssi_reject_assoc_rssi=-75 # # Association retry delay in seconds allowed by the STA if RSSI has not met the # threshold (range: 0..255, default=30). #rssi_reject_assoc_timeout=30 # Ignore Probe Request frames if RSSI is below given threshold (in dBm) # Allowed range: -60 to -90 dBm; default = 0 (rejection disabled) #rssi_ignore_probe_request=-75 ##### Fast Session Transfer (FST) support ##################################### # # The options in this section are only available when the build configuration # option CONFIG_FST is set while compiling hostapd. They allow this interface # to be a part of FST setup. # # FST is the transfer of a session from a channel to another channel, in the # same or different frequency bands. # # For detals, see IEEE Std 802.11ad-2012. # Identifier of an FST Group the interface belongs to. #fst_group_id=bond0 # Interface priority within the FST Group. # Announcing a higher priority for an interface means declaring it more # preferable for FST switch. # fst_priority is in 1..255 range with 1 being the lowest priority. #fst_priority=100 # Default LLT value for this interface in milliseconds. The value used in case # no value provided during session setup. Default is 50 ms. # fst_llt is in 1..4294967 range (due to spec limitation, see 10.32.2.2 # Transitioning between states). #fst_llt=100 ##### Radio measurements / location ########################################### # The content of a LCI measurement subelement #lci=<Hexdump of binary data of the LCI report> # The content of a location civic measurement subelement #civic=<Hexdump of binary data of the location civic report> # Enable neighbor report via radio measurements #rrm_neighbor_report=1 # Enable beacon report via radio measurements #rrm_beacon_report=1 # Publish fine timing measurement (FTM) responder functionality # This parameter only controls publishing via Extended Capabilities element. # Actual functionality is managed outside hostapd. #ftm_responder=0 # Publish fine timing measurement (FTM) initiator functionality # This parameter only controls publishing via Extended Capabilities element. # Actual functionality is managed outside hostapd. #ftm_initiator=0 # # Stationary AP config indicates that the AP doesn't move hence location data # can be considered as always up to date. If configured, LCI data will be sent # as a radio measurement even if the request doesn't contain a max age element # that allows sending of such data. Default: 0. #stationary_ap=0 # Enable reduced neighbor reporting (RNR) #rnr=0 ##### Airtime policy configuration ########################################### # Set the airtime policy operating mode: # 0 = disabled (default) # 1 = static config # 2 = per-BSS dynamic config # 3 = per-BSS limit mode #airtime_mode=0 # Interval (in milliseconds) to poll the kernel for updated station activity in # dynamic and limit modes #airtime_update_interval=200 # Static configuration of station weights (when airtime_mode=1). Kernel default # weight is 256; set higher for larger airtime share, lower for smaller share. # Each entry is a MAC address followed by a weight. #airtime_sta_weight=02:01:02:03:04:05 256 #airtime_sta_weight=02:01:02:03:04:06 512 # Per-BSS airtime weight. In multi-BSS mode, set for each BSS and hostapd will # configure station weights to enforce the correct ratio between BSS weights # depending on the number of active stations. The *ratios* between different # BSSes is what's important, not the absolute numbers. # Must be set for all BSSes if airtime_mode=2 or 3, has no effect otherwise. #airtime_bss_weight=1 # Whether the current BSS should be limited (when airtime_mode=3). # # If set, the BSS weight ratio will be applied in the case where the current BSS # would exceed the share defined by the BSS weight ratio. E.g., if two BSSes are # set to the same weights, and one is set to limited, the limited BSS will get # no more than half the available airtime, but if the non-limited BSS has more # stations active, that *will* be allowed to exceed its half of the available # airtime. #airtime_bss_limit=1 ##### EDMG support ############################################################ # # Enable EDMG capability for AP mode in the 60 GHz band. Default value is false. # To configure channel bonding for an EDMG AP use edmg_channel below. # If enable_edmg is set and edmg_channel is not set, EDMG CB1 will be # configured. #enable_edmg=1 # # Configure channel bonding for AP mode in the 60 GHz band. # This parameter is relevant only if enable_edmg is set. # Default value is 0 (no channel bonding). #edmg_channel=9 ##### TESTING OPTIONS ######################################################### # # The options in this section are only available when the build configuration # option CONFIG_TESTING_OPTIONS is set while compiling hostapd. They allow # testing some scenarios that are otherwise difficult to reproduce. # # Ignore probe requests sent to hostapd with the given probability, must be a # floating point number in the range [0, 1). #ignore_probe_probability=0.0 # # Ignore authentication frames with the given probability #ignore_auth_probability=0.0 # # Ignore association requests with the given probability #ignore_assoc_probability=0.0 # # Ignore reassociation requests with the given probability #ignore_reassoc_probability=0.0 # # Corrupt Key MIC in GTK rekey EAPOL-Key frames with the given probability #corrupt_gtk_rekey_mic_probability=0.0 # # Include only ECSA IE without CSA IE where possible # (channel switch operating class is needed) #ecsa_ie_only=0 ##### Multiple BSSID support ################################################## # # Above configuration is using the default interface (wlan#, or multi-SSID VLAN # interfaces). Other BSSIDs can be added by using separator 'bss' with # default interface name to be allocated for the data packets of the new BSS. # # hostapd will generate BSSID mask based on the BSSIDs that are # configured. hostapd will verify that dev_addr & MASK == dev_addr. If this is # not the case, the MAC address of the radio must be changed before starting # hostapd (ifconfig wlan0 hw ether <MAC addr>). If a BSSID is configured for # every secondary BSS, this limitation is not applied at hostapd and other # masks may be used if the driver supports them (e.g., swap the locally # administered bit) # # BSSIDs are assigned in order to each BSS, unless an explicit BSSID is # specified using the 'bssid' parameter. # If an explicit BSSID is specified, it must be chosen such that it: # - results in a valid MASK that covers it and the dev_addr # - is not the same as the MAC address of the radio # - is not the same as any other explicitly specified BSSID # # Alternatively, the 'use_driver_iface_addr' parameter can be used to request # hostapd to use the driver auto-generated interface address (e.g., to use the # exact MAC addresses allocated to the device). # # Not all drivers support multiple BSSes. The exact mechanism for determining # the driver capabilities is driver specific. With the current (i.e., a recent # kernel) drivers using nl80211, this information can be checked with "iw list" # (search for "valid interface combinations"). # # Please note that hostapd uses some of the values configured for the first BSS # as the defaults for the following BSSes. However, it is recommended that all # BSSes include explicit configuration of all relevant configuration items. # #bss=wlan0_0 #ssid=test2 # most of the above items can be used here (apart from radio interface specific # items, like channel) #bss=wlan0_1 #bssid=00:13:10:95:fe:0b # ... #}