32.3 Wireless Networking

Loader, Marc Fonvieille, and Murray Stokely.

32.3.1 Wireless Networking Basics

Most wireless networks are based on the IEEE® 802.11 standards. A basic wireless network consists of multiple stations communicating with radios that broadcast in either the 2.4GHz or 5GHz band (though this varies according to the locale and is also changing to enable communication in the 2.3GHz and 4.9GHz ranges).

802.11 networks are organized in two ways: in infrastructure mode one station acts as a master with all the other stations associating to it; the network is known as a BSS and the master station is termed an access point (AP). In a BSS all communication passes through the AP; even when one station wants to communicate with another wireless station messages must go through the AP. In the second form of network there is no master and stations communicate directly. This form of network is termed an IBSS and is commonly known as an ad-hoc network.

802.11 networks were first deployed in the 2.4GHz band using protocols defined by the IEEE 802.11 and 802.11b standard. These specifications include the operating frequencies, MAC layer characteristics including framing and transmission rates (communication can be done at various rates). Later the 802.11a standard defined operation in the 5GHz band, including different signalling mechanisms and higher transmission rates. Still later the 802.11g standard was defined to enable use of 802.11a signalling and transmission mechanisms in the 2.4GHz band in such a way as to be backwards compatible with 802.11b networks.

Separate from the underlying transmission techniques 802.11 networks have a variety of security mechanisms. The original 802.11 specifications defined a simple security protocol called WEP. This protocol uses a fixed pre-shared key and the RC4 cryptographic cipher to encode data transmitted on a network. Stations must all agree on the fixed key in order to communicate. This scheme was shown to be easily broken and is now rarely used except to discourage transient users from joining networks. Current security practice is given by the IEEE 802.11i specification that defines new cryptographic ciphers and an additional protocol to authenticate stations to an access point and exchange keys for doing data communication. Further, cryptographic keys are periodically refreshed and there are mechanisms for detecting intrusion attempts (and for countering intrusion attempts). Another security protocol specification commonly used in wireless networks is termed WPA. This was a precursor to 802.11i defined by an industry group as an interim measure while waiting for 802.11i to be ratified. WPA specifies a subset of the requirements found in 802.11i and is designed for implementation on legacy hardware. Specifically WPA requires only the TKIP cipher that is derived from the original WEP cipher. 802.11i permits use of TKIP but also requires support for a stronger cipher, AES-CCM, for encrypting data. (The AES cipher was not required in WPA because it was deemed too computationally costly to be implemented on legacy hardware.)

Other than the above protocol standards the other important standard to be aware of is 802.11e. This defines protocols for deploying multi-media applications such as streaming video and voice over IP (VoIP) in an 802.11 network. Like 802.11i, 802.11e also has a precursor specification termed WME (later renamed WMM) that has been defined by an industry group as a subset of 802.11e that can be deployed now to enable multi-media applications while waiting for the final ratification of 802.11e. The most important thing to know about 802.11e and WME/WMM is that it enables prioritized traffic use of a wireless network through Quality of Service (QoS) protocols and enhanced media access protocols. Proper implementation of these protocols enable high speed bursting of data and prioritized traffic flow.

FreeBSD supports networks that operate using 802.11a, 802.11b, and 802.11g. The WPA and 802.11i security protocols are likewise supported (in conjunction with any of 11a, 11b, and 11g) and QoS and traffic prioritization required by the WME/WMM protocols are supported for a limited set of wireless devices.

32.3.2 Basic Setup

32.3.2.1 Kernel Configuration

To use wireless networking, you need a wireless networking card and to configure the kernel with the appropriate wireless networking support. The latter is separated into multiple modules so that you only need to configure the software you are actually going to use.

The first thing you need is a wireless device. The most commonly used devices are those that use parts made by Atheros. These devices are supported by the ath(4) driver and require the following line to be added to /boot/loader.conf:

if_ath_load="YES"

The Atheros driver is split up into three separate pieces: the proper driver (ath(4)), the hardware support layer that handles chip-specific functions (ath_hal(4)), and an algorithm for selecting which of several possible rates for transmitting frames (ath_rate_sample here). When this support is loaded as kernel modules, these dependencies are automatically handled for you. If, instead of an Atheros device, you had another device you would select the module for that device; e.g.:

if_wi_load="YES"

for devices based on the Intersil Prism parts (wi(4) driver).

Note: In the rest of this document, we will use an ath(4) device, the device name in the examples must be changed according to your configuration. A list of available wireless drivers and supported adapters can be found in the FreeBSD Hardware Notes. Copies of these notes for various releases and architectures are available on the Release Information page of the FreeBSD Web site. If a native FreeBSD driver for your wireless device does not exist, it may be possible to directly use the Windows® driver with the help of the NDIS driver wrapper.

Under FreeBSD 7.X, with a device driver you need to also bring in the 802.11 networking support required by the driver. For the ath(4) driver these are at least the wlan(4), wlan_scan_ap and wlan_scan_sta modules; the wlan(4) module is automatically loaded with the wireless device driver, the remaining modules must be loaded at boot time in /boot/loader.conf:

wlan_scan_ap_load="YES"
wlan_scan_sta_load="YES"

Since FreeBSD 8.0, these modules are part of the base wlan(4) driver which is dynamically loaded with the adapter driver.

With that, you will need the modules that implement cryptographic support for the security protocols you intend to use. These are intended to be dynamically loaded on demand by the wlan(4) module but for now they must be manually configured. The following modules are available: wlan_wep(4), wlan_ccmp(4) and wlan_tkip(4). Both wlan_ccmp(4) and wlan_tkip(4) drivers are only needed if you intend to use the WPA and/or 802.11i security protocols. If your network does not use encryption, you will not need wlan_wep(4) support. To load these modules at boot time, add the following lines to /boot/loader.conf:

wlan_wep_load="YES"
wlan_ccmp_load="YES"
wlan_tkip_load="YES"

With this information in the system bootstrap configuration file (i.e., /boot/loader.conf), you have to reboot your FreeBSD box. If you do not want to reboot your machine for the moment, you can load the modules by hand using kldload(8).

Note: If you do not want to use modules, it is possible to compile these drivers into the kernel by adding the following lines to your kernel configuration file:

device wlan              # 802.11 support
device wlan_wep          # 802.11 WEP support
device wlan_ccmp         # 802.11 CCMP support
device wlan_tkip         # 802.11 TKIP support
device wlan_amrr         # AMRR transmit rate control algorithm
device ath               # Atheros pci/cardbus NIC's
device ath_hal           # pci/cardbus chip support
options AH_SUPPORT_AR5416 # enable AR5416 tx/rx descriptors
device ath_rate_sample   # SampleRate tx rate control for ath

Both following lines are also required by FreeBSD 7.X, other FreeBSD versions do not need them:

device wlan_scan_ap      # 802.11 AP mode scanning
device wlan_scan_sta     # 802.11 STA mode scanning

With this information in the kernel configuration file, recompile the kernel and reboot your FreeBSD machine.

When the system is up, we could find some information about the wireless device in the boot messages, like this:

ath0: <Atheros 5212> mem 0x88000000-0x8800ffff irq 11 at device 0.0 on cardbus1
ath0: [ITHREAD]
ath0: AR2413 mac 7.9 RF2413 phy 4.5

32.3.3 Infrastructure Mode

The infrastructure mode or BSS mode is the mode that is typically used. In this mode, a number of wireless access points are connected to a wired network. Each wireless network has its own name, this name is called the SSID of the network. Wireless clients connect to the wireless access points.

32.3.3.1 FreeBSD Clients

32.3.3.1.1 How to Find Access Points

To scan for networks, use the ifconfig command. This request may take a few moments to complete as it requires that the system switches to each available wireless frequency and probes for available access points. Only the super-user can initiate such a scan:

# ifconfig wlan0 create wlandev ath0
# ifconfig wlan0 up scan
SSID/MESH ID    BSSID              CHAN RATE   S:N     INT CAPS
dlinkap         00:13:46:49:41:76   11   54M -90:96   100 EPS  WPA WME
freebsdap       00:11:95:c3:0d:ac    1   54M -83:96   100 EPS  WPA

Note: You must mark the interface up before you can scan. Subsequent scan requests do not require you to mark the interface up again.

Note: Under FreeBSD 7.X, the adapter device, for example ath0, is used directly instead of the wlan0 device. This requires you to replace the both previous lines with:

# ifconfig ath0 up scan

In the rest of this document, FreeBSD 7.X users will need to change the command and configuration lines according to that scheme.

The output of a scan request lists each BSS/IBSS network found. Beside the name of the network, SSID, we find the BSSID which is the MAC address of the access point. The CAPS field identifies the type of each network and the capabilities of the stations operating there:

Table 32-1. Station Capability Codes

Capability Code Meaning
E Extended Service Set (ESS). Indicates that the station is part of an infrastructure network (in contrast to an IBSS/ad-hoc network).
I IBSS/ad-hoc network. Indicates that the station is part of an ad-hoc network (in contrast to an ESS network).
P Privacy. Data confidentiality is required for all data frames exchanged within the BSS. This means that this BSS requires the station to use cryptographic means such as WEP, TKIP or AES-CCMP to encrypt/decrypt data frames being exchanged with others.
S Short Preamble. Indicates that the network is using short preambles (defined in 802.11b High Rate/DSSS PHY, short preamble utilizes a 56 bit sync field in contrast to a 128 bit field used in long preamble mode).
s Short slot time. Indicates that the 802.11g network is using a short slot time because there are no legacy (802.11b) stations present.

One can also display the current list of known networks with:

# ifconfig wlan0 list scan

This information may be updated automatically by the adapter or manually with a scan request. Old data is automatically removed from the cache, so over time this list may shrink unless more scans are done.

32.3.3.1.2 Basic Settings

This section provides a simple example of how to make the wireless network adapter work in FreeBSD without encryption. After you are familiar with these concepts, we strongly recommend using WPA to set up your wireless network.

There are three basic steps to configure a wireless network: selecting an access point, authenticating your station, and configuring an IP address. The following sections discuss each step.

32.3.3.1.2.1 Selecting an Access Point

Most of time it is sufficient to let the system choose an access point using the builtin heuristics. This is the default behaviour when you mark an interface up or otherwise configure an interface by listing it in /etc/rc.conf, e.g.:

wlans_ath0="wlan0"
ifconfig_wlan0="DHCP"

Note: As previously mentioned, FreeBSD 7.X will only require a line related to the adapter device:

ifconfig_ath0="DHCP"

If there are multiple access points and you want to select a specific one, you can select it by its SSID:

wlans_ath0="wlan0"
ifconfig_wlan0="ssid your_ssid_here DHCP"

In an environment where there are multiple access points with the same SSID (often done to simplify roaming) it may be necessary to associate to one specific device. In this case you can also specify the BSSID of the access point (you can also leave off the SSID):

wlans_ath0="wlan0"
ifconfig_wlan0="ssid your_ssid_here bssid xx:xx:xx:xx:xx:xx DHCP"

There are other ways to constrain the choice of an access point such as limiting the set of frequencies the system will scan on. This may be useful if you have a multi-band wireless card as scanning all the possible channels can be time-consuming. To limit operation to a specific band you can use the mode parameter; e.g.:

wlans_ath0="wlan0"
ifconfig_wlan0="mode 11g ssid your_ssid_here DHCP"

will force the card to operate in 802.11g which is defined only for 2.4GHz frequencies so any 5GHz channels will not be considered. Other ways to do this are the channel parameter, to lock operation to one specific frequency, and the chanlist parameter, to specify a list of channels for scanning. More information about these parameters can be found in the ifconfig(8) manual page.

32.3.3.1.2.2 Authentication

Once you have selected an access point your station needs to authenticate before it can pass data. Authentication can happen in several ways. The most common scheme used is termed open authentication and allows any station to join the network and communicate. This is the authentication you should use for test purpose the first time you set up a wireless network. Other schemes require cryptographic handshakes be completed before data traffic can flow; either using pre-shared keys or secrets, or more complex schemes that involve backend services such as RADIUS. Most users will use open authentication which is the default setting. Next most common setup is WPA-PSK, also known as WPA Personal, which is described below.

Note: If you have an Apple® AirPort® Extreme base station for an access point you may need to configure shared-key authentication together with a WEP key. This can be done in the /etc/rc.conf file or using the wpa_supplicant(8) program. If you have a single AirPort base station you can setup access with something like:

wlans_ath0="wlan0"
ifconfig_wlan0="authmode shared wepmode on weptxkey 1 wepkey 01234567 DHCP"

In general shared key authentication is to be avoided because it uses the WEP key material in a highly-constrained manner making it even easier to crack the key. If WEP must be used (e.g., for compatibility with legacy devices) it is better to use WEP with open authentication. More information regarding WEP can be found in the Section 32.3.3.1.4.

32.3.3.1.2.3 Getting an IP Address with DHCP

Once you have selected an access point and set the authentication parameters, you will have to get an IP address to communicate. Most of time you will obtain your wireless IP address via DHCP. To achieve that, edit /etc/rc.conf and add DHCP to the configuration for your device as shown in various examples above:

wlans_ath0="wlan0"
ifconfig_wlan0="DHCP"

At this point, you are ready to bring up the wireless interface:

# service netif start

Once the interface is running, use ifconfig to see the status of the interface ath0:

# ifconfig wlan0
wlan0: flags=8843<UP,BROADCAST,RUNNING,SIMPLEX,MULTICAST> mtu 1500
        ether 00:11:95:d5:43:62
        inet 192.168.1.100 netmask 0xffffff00 broadcast 192.168.1.255
        media: IEEE 802.11 Wireless Ethernet OFDM/54Mbps mode 11g
        status: associated
        ssid dlinkap channel 11 (2462 Mhz 11g) bssid 00:13:46:49:41:76
        country US ecm authmode OPEN privacy OFF txpower 21.5 bmiss 7
        scanvalid 60 bgscan bgscanintvl 300 bgscanidle 250 roam:rssi 7
        roam:rate 5 protmode CTS wme burst

The status: associated means you are connected to the wireless network (to the dlinkap network in our case). The bssid 00:13:46:49:41:76 part is the MAC address of your access point; the authmode OPEN part informs you that the communication is not encrypted.

32.3.3.1.2.4 Static IP Address

In the case you cannot obtain an IP address from a DHCP server, you can set a fixed IP address. Replace the DHCP keyword shown above with the address information. Be sure to retain any other parameters you have set up for selecting an access point:

wlans_ath0="wlan0"
ifconfig_wlan0="inet 192.168.1.100 netmask 255.255.255.0 ssid your_ssid_here"

32.3.3.1.3 WPA

WPA (Wi-Fi Protected Access) is a security protocol used together with 802.11 networks to address the lack of proper authentication and the weakness of WEP. WPA leverages the 802.1X authentication protocol and uses one of several ciphers instead of WEP for data integrity. The only cipher required by WPA is TKIP (Temporary Key Integrity Protocol). TKIP is a cipher that extends the basic RC4 cipher used by WEP by adding integrity checking, tamper detection, and measures for responding to any detected intrusions. TKIP is designed to work on legacy hardware with only software modification; it represents a compromise that improves security but is still not entirely immune to attack. WPA also specifies the AES-CCMP cipher as an alternative to TKIP and that is preferred when possible; for this specification the term WPA2 (or RSN) is commonly used.

WPA defines authentication and encryption protocols. Authentication is most commonly done using one of two techniques: by 802.1X and a backend authentication service such as RADIUS, or by a minimal handshake between the station and the access point using a pre-shared secret. The former is commonly termed WPA Enterprise with the latter known as WPA Personal. Since most people will not set up a RADIUS backend server for their wireless network, WPA-PSK is by far the most commonly encountered configuration for WPA.

The control of the wireless connection and the authentication (key negotiation or authentication with a server) is done with the wpa_supplicant(8) utility. This program requires a configuration file, /etc/wpa_supplicant.conf, to run. More information regarding this file can be found in the wpa_supplicant.conf(5) manual page.

32.3.3.1.3.1 WPA-PSK

WPA-PSK, also known as WPA-Personal, is based on a pre-shared key (PSK) generated from a given password and that will be used as the master key in the wireless network. This means every wireless user will share the same key. WPA-PSK is intended for small networks where the use of an authentication server is not possible or desired.

Warning: Always use strong passwords that are sufficiently long and made from a rich alphabet so they will not be guessed and/or attacked.

The first step is the configuration of the /etc/wpa_supplicant.conf file with the SSID and the pre-shared key of your network:

network={
  ssid="freebsdap"
  psk="freebsdmall"
}

Then, in /etc/rc.conf, we indicate that the wireless device configuration will be done with WPA and the IP address will be obtained with DHCP:

wlans_ath0="wlan0"
ifconfig_wlan0="WPA DHCP"

Then we can bring up the interface:

# service netif start
Starting wpa_supplicant.
DHCPDISCOVER on wlan0 to 255.255.255.255 port 67 interval 5
DHCPDISCOVER on wlan0 to 255.255.255.255 port 67 interval 6
DHCPOFFER from 192.168.0.1
DHCPREQUEST on wlan0 to 255.255.255.255 port 67
DHCPACK from 192.168.0.1
bound to 192.168.0.254 -- renewal in 300 seconds.
wlan0: flags=8843<UP,BROADCAST,RUNNING,SIMPLEX,MULTICAST> mtu 1500
      ether 00:11:95:d5:43:62
      inet 192.168.0.254 netmask 0xffffff00 broadcast 192.168.0.255
      media: IEEE 802.11 Wireless Ethernet OFDM/36Mbps mode 11g
      status: associated
      ssid freebsdap channel 1 (2412 Mhz 11g) bssid 00:11:95:c3:0d:ac
      country US ecm authmode WPA2/802.11i privacy ON deftxkey UNDEF
      AES-CCM 3:128-bit txpower 21.5 bmiss 7 scanvalid 450 bgscan
      bgscanintvl 300 bgscanidle 250 roam:rssi 7 roam:rate 5 protmode CTS
      wme burst roaming MANUAL

Or you can try to configure it manually using the same /etc/wpa_supplicant.conf above, and run:

# wpa_supplicant -i wlan0 -c /etc/wpa_supplicant.conf
Trying to associate with 00:11:95:c3:0d:ac (SSID='freebsdap' freq=2412 MHz)
Associated with 00:11:95:c3:0d:ac
WPA: Key negotiation completed with 00:11:95:c3:0d:ac [PTK=CCMP GTK=CCMP]
CTRL-EVENT-CONNECTED - Connection to 00:11:95:c3:0d:ac completed (auth) [id=0 id_str=]

The next operation is the launch of the dhclient command to get the IP address from the DHCP server:

# dhclient wlan0
DHCPREQUEST on wlan0 to 255.255.255.255 port 67
DHCPACK from 192.168.0.1
bound to 192.168.0.254 -- renewal in 300 seconds.
# ifconfig wlan0
wlan0: flags=8843<UP,BROADCAST,RUNNING,SIMPLEX,MULTICAST> mtu 1500
      ether 00:11:95:d5:43:62
      inet 192.168.0.254 netmask 0xffffff00 broadcast 192.168.0.255
      media: IEEE 802.11 Wireless Ethernet OFDM/36Mbps mode 11g
      status: associated
      ssid freebsdap channel 1 (2412 Mhz 11g) bssid 00:11:95:c3:0d:ac
      country US ecm authmode WPA2/802.11i privacy ON deftxkey UNDEF
      AES-CCM 3:128-bit txpower 21.5 bmiss 7 scanvalid 450 bgscan
      bgscanintvl 300 bgscanidle 250 roam:rssi 7 roam:rate 5 protmode CTS
      wme burst roaming MANUAL

Note: If /etc/rc.conf has an ifconfig_wlan0 entry with the DHCP string (like ifconfig_wlan0="DHCP"), dhclient will be launched automatically after wpa_supplicant associates with the access point.

If DHCP is not possible or desired, you can set a static IP address after wpa_supplicant has authenticated the station:

# ifconfig wlan0 inet 192.168.0.100 netmask 255.255.255.0
# ifconfig wlan0
wlan0: flags=8843<UP,BROADCAST,RUNNING,SIMPLEX,MULTICAST> mtu 1500
      ether 00:11:95:d5:43:62
      inet 192.168.0.100 netmask 0xffffff00 broadcast 192.168.0.255
      media: IEEE 802.11 Wireless Ethernet OFDM/36Mbps mode 11g
      status: associated
      ssid freebsdap channel 1 (2412 Mhz 11g) bssid 00:11:95:c3:0d:ac
      country US ecm authmode WPA2/802.11i privacy ON deftxkey UNDEF
      AES-CCM 3:128-bit txpower 21.5 bmiss 7 scanvalid 450 bgscan
      bgscanintvl 300 bgscanidle 250 roam:rssi 7 roam:rate 5 protmode CTS
      wme burst roaming MANUAL

When DHCP is not used, you also have to manually set the default gateway and the nameserver:

# route add default your_default_router
# echo "nameserver your_DNS_server" >> /etc/resolv.conf
32.3.3.1.3.2 WPA with EAP-TLS

The second way to use WPA is with an 802.1X backend authentication server. In this case WPA is called WPA-Enterprise to differentiate it from the less secure WPA-Personal with its pre-shared key. Authentication in WPA-Enterprise is based on the Extensible Authentication Protocol (EAP).

EAP does not come with an encryption method. Instead, it was decided to embed EAP inside an encrypted tunnel. There are many EAP authentication methods, but EAP-TLS, EAP-TTLS, and EAP-PEAP are the most common.

EAP-TLS (EAP with Transport Layer Security) is a very well-supported authentication protocol in the wireless world since it was the first EAP method to be certified by the Wi-Fi alliance. EAP-TLS will require three certificates to run: the CA certificate (installed on all machines), the server certificate for your authentication server, and one client certificate for each wireless client. In this EAP method, both authentication server and wireless client authenticate each other in presenting their respective certificates, and they verify that these certificates were signed by your organization's certificate authority (CA).

As previously, the configuration is done via /etc/wpa_supplicant.conf:

network={
  ssid="freebsdap" (1)
  proto=RSN  (2)
  key_mgmt=WPA-EAP (3)
  eap=TLS (4)
  identity="loader" (5)
  ca_cert="/etc/certs/cacert.pem" (6)
  client_cert="/etc/certs/clientcert.pem" (7)
  private_key="/etc/certs/clientkey.pem" (8)
  private_key_passwd="freebsdmallclient" (9)
}
(1)
This field indicates the network name (SSID).
(2)
Here, we use RSN (IEEE 802.11i) protocol, i.e., WPA2.
(3)
The key_mgmt line refers to the key management protocol we use. In our case it is WPA using EAP authentication: WPA-EAP.
(4)
In this field, we mention the EAP method for our connection.
(5)
The identity field contains the identity string for EAP.
(6)
The ca_cert field indicates the pathname of the CA certificate file. This file is needed to verify the server certificate.
(7)
The client_cert line gives the pathname to the client certificate file. This certificate is unique to each wireless client of the network.
(8)
The private_key field is the pathname to the client certificate private key file.
(9)
The private_key_passwd field contains the passphrase for the private key.

Then add the following lines to /etc/rc.conf:

wlans_ath0="wlan0"
ifconfig_wlan0="WPA DHCP"

The next step is to bring up the interface:

# service netif start
Starting wpa_supplicant.
DHCPREQUEST on wlan0 to 255.255.255.255 port 67 interval 7
DHCPREQUEST on wlan0 to 255.255.255.255 port 67 interval 15
DHCPACK from 192.168.0.20
bound to 192.168.0.254 -- renewal in 300 seconds.
wlan0: flags=8843<UP,BROADCAST,RUNNING,SIMPLEX,MULTICAST> mtu 1500
      ether 00:11:95:d5:43:62
      inet 192.168.0.254 netmask 0xffffff00 broadcast 192.168.0.255
      media: IEEE 802.11 Wireless Ethernet DS/11Mbps mode 11g
      status: associated
      ssid freebsdap channel 1 (2412 Mhz 11g) bssid 00:11:95:c3:0d:ac
      country US ecm authmode WPA2/802.11i privacy ON deftxkey UNDEF
      AES-CCM 3:128-bit txpower 21.5 bmiss 7 scanvalid 450 bgscan
      bgscanintvl 300 bgscanidle 250 roam:rssi 7 roam:rate 5 protmode CTS
      wme burst roaming MANUAL

As previously shown, it is also possible to bring up the interface manually with both wpa_supplicant and ifconfig commands.

32.3.3.1.3.3 WPA with EAP-TTLS

With EAP-TLS both the authentication server and the client need a certificate, with EAP-TTLS (EAP-Tunneled Transport Layer Security) a client certificate is optional. This method is close to what some secure web sites do , where the web server can create a secure SSL tunnel even if the visitors do not have client-side certificates. EAP-TTLS will use the encrypted TLS tunnel for safe transport of the authentication data.

The configuration is done via the /etc/wpa_supplicant.conf file:

network={
  ssid="freebsdap"
  proto=RSN
  key_mgmt=WPA-EAP
  eap=TTLS (1)
  identity="test" (2)
  password="test" (3)
  ca_cert="/etc/certs/cacert.pem" (4)
  phase2="auth=MD5" (5)
}
(1)
In this field, we mention the EAP method for our connection.
(2)
The identity field contains the identity string for EAP authentication inside the encrypted TLS tunnel.
(3)
The password field contains the passphrase for the EAP authentication.
(4)
The ca_cert field indicates the pathname of the CA certificate file. This file is needed to verify the server certificate.
(5)
In this field, we mention the authentication method used in the encrypted TLS tunnel. In our case, EAP with MD5-Challenge has been used. The “inner authentication” phase is often called “phase2”.

You also have to add the following lines to /etc/rc.conf:

wlans_ath0="wlan0"
ifconfig_wlan0="WPA DHCP"

The next step is to bring up the interface:

# service netif start
Starting wpa_supplicant.
DHCPREQUEST on wlan0 to 255.255.255.255 port 67 interval 7
DHCPREQUEST on wlan0 to 255.255.255.255 port 67 interval 15
DHCPREQUEST on wlan0 to 255.255.255.255 port 67 interval 21
DHCPACK from 192.168.0.20
bound to 192.168.0.254 -- renewal in 300 seconds.
wlan0: flags=8843<UP,BROADCAST,RUNNING,SIMPLEX,MULTICAST> mtu 1500
      ether 00:11:95:d5:43:62
      inet 192.168.0.254 netmask 0xffffff00 broadcast 192.168.0.255
      media: IEEE 802.11 Wireless Ethernet DS/11Mbps mode 11g
      status: associated
      ssid freebsdap channel 1 (2412 Mhz 11g) bssid 00:11:95:c3:0d:ac
      country US ecm authmode WPA2/802.11i privacy ON deftxkey UNDEF
      AES-CCM 3:128-bit txpower 21.5 bmiss 7 scanvalid 450 bgscan
      bgscanintvl 300 bgscanidle 250 roam:rssi 7 roam:rate 5 protmode CTS
      wme burst roaming MANUAL
32.3.3.1.3.4 WPA with EAP-PEAP

Note: PEAPv0/EAP-MSCHAPv2 is the most common PEAP method. In the rest of this document, we will use the PEAP term to refer to that method.

PEAP (Protected EAP) has been designed as an alternative to EAP-TTLS, and is the most used EAP standard after EAP-TLS. In other words, if you have a network with mixed OSes, PEAP should be the most supported standard after EAP-TLS.

PEAP is similar to EAP-TTLS: it uses a server-side certificate to authenticate clients by creating an encrypted TLS tunnel between the client and the authentication server, which protects the ensuing exchange of authentication information. In terms of security, the difference between EAP-TTLS and PEAP is that PEAP authentication broadcasts the username in the clear, with only the password sent in the encrypted TLS tunnel. EAP-TTLS will use the TLS tunnel for both username and password.

We have to edit the /etc/wpa_supplicant.conf file and add the EAP-PEAP related settings:

network={
  ssid="freebsdap"
  proto=RSN
  key_mgmt=WPA-EAP
  eap=PEAP (1)
  identity="test" (2)
  password="test" (3)
  ca_cert="/etc/certs/cacert.pem" (4)
  phase1="peaplabel=0" (5)
  phase2="auth=MSCHAPV2" (6)
}
(1)
In this field, we mention the EAP method for our connection.
(2)
The identity field contains the identity string for EAP authentication inside the encrypted TLS tunnel.
(3)
The password field contains the passphrase for the EAP authentication.
(4)
The ca_cert field indicates the pathname of the CA certificate file. This file is needed to verify the server certificate.
(5)
This field contains the parameters for the first phase of authentication (the TLS tunnel). According to the authentication server used, you will have to specify a specific label for authentication. Most of the time, the label will be “client EAP encryption” which is set by using peaplabel=0. More information can be found in the wpa_supplicant.conf(5) manual page.
(6)
In this field, we mention the authentication protocol used in the encrypted TLS tunnel. In the case of PEAP, it is auth=MSCHAPV2.

The following must be added to /etc/rc.conf:

wlans_ath0="wlan0"
ifconfig_wlan0="WPA DHCP"

Then we can bring up the interface:

# service netif start
Starting wpa_supplicant.
DHCPREQUEST on wlan0 to 255.255.255.255 port 67 interval 7
DHCPREQUEST on wlan0 to 255.255.255.255 port 67 interval 15
DHCPREQUEST on wlan0 to 255.255.255.255 port 67 interval 21
DHCPACK from 192.168.0.20
bound to 192.168.0.254 -- renewal in 300 seconds.
wlan0: flags=8843<UP,BROADCAST,RUNNING,SIMPLEX,MULTICAST> mtu 1500
      ether 00:11:95:d5:43:62
      inet 192.168.0.254 netmask 0xffffff00 broadcast 192.168.0.255
      media: IEEE 802.11 Wireless Ethernet DS/11Mbps mode 11g
      status: associated
      ssid freebsdap channel 1 (2412 Mhz 11g) bssid 00:11:95:c3:0d:ac
      country US ecm authmode WPA2/802.11i privacy ON deftxkey UNDEF
      AES-CCM 3:128-bit txpower 21.5 bmiss 7 scanvalid 450 bgscan
      bgscanintvl 300 bgscanidle 250 roam:rssi 7 roam:rate 5 protmode CTS
      wme burst roaming MANUAL

32.3.3.1.4 WEP

WEP (Wired Equivalent Privacy) is part of the original 802.11 standard. There is no authentication mechanism, only a weak form of access control, and it is easily cracked.

WEP can be set up with ifconfig:

# ifconfig wlan0 create wlandev ath0
# ifconfig wlan0 inet 192.168.1.100 netmask 255.255.255.0 \
	    ssid my_net wepmode on weptxkey 3 wepkey 3:0x3456789012
  • The weptxkey means which WEP key will be used in the transmission. Here we used the third key. This must match the setting in the access point. If you do not have any idea of which key is used by the access point, try 1 (i.e., the first key) for this value.

  • The wepkey selects one of the WEP keys. It should be in the format index:key. Key 1 is used by default; the index only needs to be set if we use a key other than the first key.

    Note: You must replace the 0x3456789012 with the key configured for use on the access point.

You are encouraged to read the ifconfig(8) manual page for further information.

The wpa_supplicant facility also can be used to configure your wireless interface with WEP. The example above can be set up by adding the following lines to /etc/wpa_supplicant.conf:

network={
  ssid="my_net"
  key_mgmt=NONE
  wep_key3=3456789012
  wep_tx_keyidx=3
}

Then:

# wpa_supplicant -i wlan0 -c /etc/wpa_supplicant.conf
Trying to associate with 00:13:46:49:41:76 (SSID='dlinkap' freq=2437 MHz)
Associated with 00:13:46:49:41:76

32.3.4 Ad-hoc Mode

IBSS mode, also called ad-hoc mode, is designed for point to point connections. For example, to establish an ad-hoc network between the machine A and the machine B, we will just need to choose two IP addresses and a SSID.

On the box A:

# ifconfig wlan0 create wlandev ath0 wlanmode adhoc
# ifconfig wlan0 inet 192.168.0.1 netmask 255.255.255.0 ssid freebsdap
# ifconfig wlan0
  wlan0: flags=8843<UP,BROADCAST,RUNNING,SIMPLEX,MULTICAST> metric 0 mtu 1500
	  ether 00:11:95:c3:0d:ac
	  inet 192.168.0.1 netmask 0xffffff00 broadcast 192.168.0.255
	  media: IEEE 802.11 Wireless Ethernet autoselect mode 11g <adhoc>
	  status: running
	  ssid freebsdap channel 2 (2417 Mhz 11g) bssid 02:11:95:c3:0d:ac
	  country US ecm authmode OPEN privacy OFF txpower 21.5 scanvalid 60
	  protmode CTS wme burst

The adhoc parameter indicates the interface is running in the IBSS mode.

On B, we should be able to detect A:

# ifconfig wlan0 create wlandev ath0 wlanmode adhoc
# ifconfig wlan0 up scan
  SSID/MESH ID    BSSID              CHAN RATE   S:N     INT CAPS
  freebsdap       02:11:95:c3:0d:ac    2   54M -64:-96  100 IS   WME

The I in the output confirms the machine A is in ad-hoc mode. We just have to configure B with a different IP address:

# ifconfig wlan0 inet 192.168.0.2 netmask 255.255.255.0 ssid freebsdap
# ifconfig wlan0
  wlan0: flags=8843<UP,BROADCAST,RUNNING,SIMPLEX,MULTICAST> metric 0 mtu 1500
	  ether 00:11:95:d5:43:62
	  inet 192.168.0.2 netmask 0xffffff00 broadcast 192.168.0.255
	  media: IEEE 802.11 Wireless Ethernet autoselect mode 11g <adhoc>
	  status: running
	  ssid freebsdap channel 2 (2417 Mhz 11g) bssid 02:11:95:c3:0d:ac
	  country US ecm authmode OPEN privacy OFF txpower 21.5 scanvalid 60
	  protmode CTS wme burst

Both A and B are now ready to exchange information.

32.3.5 FreeBSD Host Access Points

FreeBSD can act as an Access Point (AP) which eliminates the need to buy a hardware AP or run an ad-hoc network. This can be particularly useful when your FreeBSD machine is acting as a gateway to another network (e.g., the Internet).

32.3.5.1 Basic Settings

Before configuring your FreeBSD machine as an AP, the kernel must be configured with the appropriate wireless networking support for your wireless card. You also have to add support for the security protocols you intend to use. For more details, see Section 32.3.2.

Note: The use of the NDIS driver wrapper and the Windows drivers do not currently allow AP operation. Only native FreeBSD wireless drivers support AP mode.

Once wireless networking support is loaded, you can check if your wireless device supports the host-based access point mode (also known as hostap mode):

# ifconfig wlan0 create wlandev ath0
# ifconfig wlan0 list caps
drivercaps=6f85edc1<STA,FF,TURBOP,IBSS,HOSTAP,AHDEMO,TXPMGT,SHSLOT,SHPREAMBLE,MONITOR,MBSS,WPA1,WPA2,BURST,WME,WDS,BGSCAN,TXFRAG>
cryptocaps=1f<WEP,TKIP,AES,AES_CCM,TKIPMIC>

This output displays the card capabilities; the HOSTAP word confirms this wireless card can act as an Access Point. Various supported ciphers are also mentioned: WEP, TKIP, AES, etc. This information is important to know what security protocols can be used on the Access Point.

The wireless device can only be put into hostap mode during the creation of the network pseudo-device, so a previously created device must be destroyed first:

# ifconfig wlan0 destroy

then regenerated with the correct option before setting the other parameters:

# ifconfig wlan0 create wlandev ath0 wlanmode hostap
# ifconfig wlan0 inet 192.168.0.1 netmask 255.255.255.0 ssid freebsdap mode 11g channel 1

Use ifconfig again to see the status of the wlan0 interface:

# ifconfig wlan0
  wlan0: flags=8843<UP,BROADCAST,RUNNING,SIMPLEX,MULTICAST> metric 0 mtu 1500
	  ether 00:11:95:c3:0d:ac
	  inet 192.168.0.1 netmask 0xffffff00 broadcast 192.168.0.255
	  media: IEEE 802.11 Wireless Ethernet autoselect mode 11g <hostap>
	  status: running
	  ssid freebsdap channel 1 (2412 Mhz 11g) bssid 00:11:95:c3:0d:ac
	  country US ecm authmode OPEN privacy OFF txpower 21.5 scanvalid 60
	  protmode CTS wme burst dtimperiod 1 -dfs

The hostap parameter indicates the interface is running in the host-based access point mode.

The interface configuration can be done automatically at boot time by adding the following lines to /etc/rc.conf:

wlans_ath0="wlan0"
create_args_wlan0="wlanmode hostap"
ifconfig_wlan0="inet 192.168.0.1 netmask 255.255.255.0 ssid freebsdap mode 11g channel 1"

32.3.5.2 Host-based Access Point Without Authentication or Encryption

Although it is not recommended to run an AP without any authentication or encryption, this is a simple way to check if your AP is working. This configuration is also important for debugging client issues.

Once the AP configured as previously shown, it is possible from another wireless machine to initiate a scan to find the AP:

# ifconfig wlan0 create wlandev ath0
# ifconfig wlan0 up scan
SSID/MESH ID    BSSID              CHAN RATE   S:N     INT CAPS
freebsdap       00:11:95:c3:0d:ac    1   54M -66:-96  100 ES   WME

The client machine found the Access Point and can be associated with it:

# ifconfig wlan0 inet 192.168.0.2 netmask 255.255.255.0 ssid freebsdap
# ifconfig wlan0
  wlan0: flags=8843<UP,BROADCAST,RUNNING,SIMPLEX,MULTICAST> metric 0 mtu 1500
	  ether 00:11:95:d5:43:62
	  inet 192.168.0.2 netmask 0xffffff00 broadcast 192.168.0.255
	  media: IEEE 802.11 Wireless Ethernet OFDM/54Mbps mode 11g
	  status: associated
	  ssid freebsdap channel 1 (2412 Mhz 11g) bssid 00:11:95:c3:0d:ac
	  country US ecm authmode OPEN privacy OFF txpower 21.5 bmiss 7
	  scanvalid 60 bgscan bgscanintvl 300 bgscanidle 250 roam:rssi 7
	  roam:rate 5 protmode CTS wme burst

32.3.5.3 WPA Host-based Access Point

This section will focus on setting up FreeBSD Access Point using the WPA security protocol. More details regarding WPA and the configuration of WPA-based wireless clients can be found in the Section 32.3.3.1.3.

The hostapd daemon is used to deal with client authentication and keys management on the WPA enabled Access Point.

In the following, all the configuration operations will be performed on the FreeBSD machine acting as AP. Once the AP is correctly working, hostapd should be automatically enabled at boot with the following line in /etc/rc.conf:

hostapd_enable="YES"

Before trying to configure hostapd, be sure you have done the basic settings introduced in the Section 32.3.5.1.

32.3.5.3.1 WPA-PSK

WPA-PSK is intended for small networks where the use of an backend authentication server is not possible or desired.

The configuration is done in the /etc/hostapd.conf file:

interface=wlan0 (1)
debug=1 (2)
ctrl_interface=/var/run/hostapd (3)
ctrl_interface_group=wheel (4)
ssid=freebsdap (5)
wpa=1 (6)
wpa_passphrase=freebsdmall (7)
wpa_key_mgmt=WPA-PSK (8)
wpa_pairwise=CCMP TKIP (9)
(1)
This field indicates the wireless interface used for the Access Point.
(2)
This field sets the level of verbosity during the execution of hostapd. A value of 1 represents the minimal level.
(3)
The ctrl_interface field gives the pathname of the directory used by hostapd to stores its domain socket files for the communication with external programs such as hostapd_cli(8). The default value is used here.
(4)
The ctrl_interface_group line sets the group (here, it is the wheel group) allowed to access to the control interface files.
(5)
This field sets the network name.
(6)
The wpa field enables WPA and specifies which WPA authentication protocol will be required. A value of 1 configures the AP for WPA-PSK.
(7)
The wpa_passphrase field contains the ASCII passphrase for the WPA authentication.

Warning: Always use strong passwords that are sufficiently long and made from a rich alphabet so they will not be guessed and/or attacked.

(8)
The wpa_key_mgmt line refers to the key management protocol we use. In our case it is WPA-PSK.
(9)
The wpa_pairwise field indicates the set of accepted encryption algorithms by the Access Point. Here both TKIP (WPA) and CCMP (WPA2) ciphers are accepted. CCMP cipher is an alternative to TKIP and that is strongly preferred when possible; TKIP should be used solely for stations incapable of doing CCMP.

The next step is to start hostapd:

# service hostapd forcestart
# ifconfig wlan0
  wlan0: flags=8843<UP,BROADCAST,RUNNING,SIMPLEX,MULTICAST> mtu 2290
	  inet 192.168.0.1 netmask 0xffffff00 broadcast 192.168.0.255
	  inet6 fe80::211:95ff:fec3:dac%ath0 prefixlen 64 scopeid 0x4
	  ether 00:11:95:c3:0d:ac
	  media: IEEE 802.11 Wireless Ethernet autoselect mode 11g <hostap>
	  status: associated
	  ssid freebsdap channel 1 bssid 00:11:95:c3:0d:ac
	  authmode WPA2/802.11i privacy MIXED deftxkey 2 TKIP 2:128-bit txpowmax 36 protmode CTS dtimperiod 1 bintval 100

The Access Point is running, the clients can now be associated with it, see Section 32.3.3.1.3 for more details. It is possible to see the stations associated with the AP using the ifconfig wlan0 list sta command.

32.3.5.4 WEP Host-based Access Point

It is not recommended to use WEP for setting up an Access Point since there is no authentication mechanism and it is easily to be cracked. Some legacy wireless cards only support WEP as security protocol, these cards will only allow to set up AP without authentication or encryption or using the WEP protocol.

The wireless device can now be put into hostap mode and configured with the correct SSID and IP address:

# ifconfig wlan0 create wlandev ath0 wlanmode hostap
# ifconfig wlan0 inet 192.168.0.1 netmask 255.255.255.0 \
	ssid freebsdap wepmode on weptxkey 3 wepkey 3:0x3456789012 mode 11g
  • The weptxkey means which WEP key will be used in the transmission. Here we used the third key (note that the key numbering starts with 1). This parameter must be specified to really encrypt the data.

  • The wepkey means setting the selected WEP key. It should in the format index:key, if the index is not given, key 1 is set. That is to say we need to set the index if we use keys other than the first key.

Use again ifconfig to see the status of the wlan0 interface:

# ifconfig wlan0
  wlan0: flags=8843<UP,BROADCAST,RUNNING,SIMPLEX,MULTICAST> metric 0 mtu 1500
	  ether 00:11:95:c3:0d:ac
	  inet 192.168.0.1 netmask 0xffffff00 broadcast 192.168.0.255
	  media: IEEE 802.11 Wireless Ethernet autoselect mode 11g <hostap>
	  status: running
	  ssid freebsdap channel 4 (2427 Mhz 11g) bssid 00:11:95:c3:0d:ac
	  country US ecm authmode OPEN privacy ON deftxkey 3 wepkey 3:40-bit
	  txpower 21.5 scanvalid 60 protmode CTS wme burst dtimperiod 1 -dfs

From another wireless machine, it is possible to initiate a scan to find the AP:

# ifconfig wlan0 create wlandev ath0
# ifconfig wlan0 up scan
SSID            BSSID              CHAN RATE  S:N   INT CAPS
freebsdap       00:11:95:c3:0d:ac    1   54M 22:1   100 EPS

The client machine found the Access Point and can be associated with it using the correct parameters (key, etc.), see Section 32.3.3.1.4 for more details.

32.3.6 Using Both Wired and Wireless Connection

Wired connection provides better performance and reliability, while wireless connection provides flexibility and mobility, users of laptop computers usually want to combine these together and roam seamlessly between the two.

On FreeBSD, it is possible to combine two or even more network interfaces together in a “failover” fashion, that is, to use the most preferred and available connection from a group of network interfaces, and have the operating system switch automatically when the link state changes.

We will cover link aggregation and failover in Section 32.6 where an example for using both wired and wireless connection is also provided at Example 32-3.

32.3.7 Troubleshooting

If you are having trouble with wireless networking, there are a number of steps you can take to help troubleshoot the problem.

If the above information does not help to clarify the problem, please submit a problem report and include output from the above tools.