mirror of
https://github.com/vanhoefm/fragattacks.git
synced 2024-11-25 00:38:24 -05:00
6e3027a57e
The extra sanity check for replay protection in these procedures ended up breaking the tests. RESET_PN cannot be used before RESEND_* commands since that would prevent the DUT from accepting the retransmitted EAPOL-Key frames. Signed-off-by: Jouni Malinen <jouni@qca.qualcomm.com>
378 lines
13 KiB
Plaintext
378 lines
13 KiB
Plaintext
Cipher suite (CCMP, TKIP, GCMP, ..) and key management testing
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==============================================================
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wpa_supplicant and hostapd include number of extensions that allow
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special test builds to be used for testing functionality related to
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correct implementation of IEEE 802.11. These extensions allow behavior
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to be modified and invalid operations to be performed to verify behavior
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of other devices in unexpected situations. While most of the testing
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extensions are focused on the fully automated testing framework with
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mac80211_hwsim (see tests/hwsim subdirectory), many of these can be used
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for over-the-air testing of the protocol as well.
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Since some of the testing extensions can result in exposing key
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information or allowing non-compliant behavior, these changes are
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disabled in default wpa_supplicant and hostapd builds for production
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purposes. Testing functionality can be enabled by adding
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CONFIG_TESTING_OPTIONS=y into build configuration (hostapd/.config and
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wpa_supplicant/.config).
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Testing setup
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-------------
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These tests can be run as black-box testing without having to modify the
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tested device at all or without knowing details of its
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functionality. The test commands in wpa_supplicant/hostapd control
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interfaces are used to perform unexpected operations and normal data
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traffic is used to verify reaction of the tested device to such
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operations.
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In theory, the test functionality is available with most drivers
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supported by wpa_supplicant/hostapd, but the most reliable results are
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likely available through ath9k-based devices. If you are using something
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else, it is strongly recommended that you'll run the first tests with
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sniffer captures and verify that the test tools are behaving correctly.
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wpa_supplicant is used to control a test device in station mode to test
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an AP and hostapd is similarly used to control a test device in AP mode
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to test a station.
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Various data traffic generators could be used to test the behavior, but
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this document focuses on using ping to test unicast traffic and arping
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to test broadcast traffic. To keep things simple and to reduce
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interference from unrelated traffic, the steps here assume static IPv4
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addresses are used and IPv6 is disabled.
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The tests here use WPA2-Personal for simplicity. WPA2-Enterprise and
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other cipher suites can also be tested for more complete coverage.
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Example hostapd.conf for the test tool in AP mode:
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driver=nl80211
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hw_mode=g
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channel=1
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ieee80211n=1
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interface=wlan0
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ctrl_interface=/var/run/hostapd
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ctrl_interface_group=adm
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ssid=test-psk
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wpa=2
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wpa_key_mgmt=WPA-PSK
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wpa_pairwise=CCMP
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wpa_passphrase=12345678
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Example wpa_supplicant.conf for the test tool in station mode:
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ctrl_interface=DIR=/var/run/wpa_supplicant GROUP=adm
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network={
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ssid="test-psk"
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key_mgmt=WPA-PSK
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psk="12345678"
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}
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The examples in this document assume following IPv4 address
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configuration:
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Test tool (either AP or station mode): 192.168.1.1/24
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Device under test: 192.168.1.2/24
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Data traffic tests
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------------------
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ping is used to test whether unicast frames go through on the data
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link. It should be noted that ping may need to use broadcast ARP at the
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beginning if the other device is not yet in the ARP table, so working
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broadcast and unicast connectivity may be needed to get this started.
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Example:
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$ ping -n -c 5 192.168.1.2
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PING 192.168.1.2 (192.168.1.2) 56(84) bytes of data.
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64 bytes from 192.168.1.2: icmp_seq=1 ttl=64 time=43.7 ms
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64 bytes from 192.168.1.2: icmp_seq=2 ttl=64 time=67.9 ms
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64 bytes from 192.168.1.2: icmp_seq=3 ttl=64 time=900 ms
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64 bytes from 192.168.1.2: icmp_seq=4 ttl=64 time=5.81 ms
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64 bytes from 192.168.1.2: icmp_seq=5 ttl=64 time=135 ms
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--- 192.168.1.2 ping statistics ---
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5 packets transmitted, 5 received, 0% packet loss, time 4004ms
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rtt min/avg/max/mdev = 5.811/230.605/900.223/337.451 ms
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This shows working unicast data connectivity.
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$ ping -n -c 5 192.168.1.2
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PING 192.168.1.2 (192.168.1.2) 56(84) bytes of data.
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--- 192.168.1.2 ping statistics ---
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5 packets transmitted, 0 received, 100% packet loss, time 4033ms
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This shows not working unicast data connectivity.
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arping is used to test broadcast connectivity.
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Example:
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$ arping -b -I wlan0 192.168.1.2 -c 5
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ARPING 192.168.1.2 from 192.168.1.1 wlan0
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Unicast reply from 192.168.1.2 [<DUT MAC address>] 119.695ms
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Unicast reply from 192.168.1.2 [<DUT MAC address>] 144.496ms
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Unicast reply from 192.168.1.2 [<DUT MAC address>] 166.788ms
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Unicast reply from 192.168.1.2 [<DUT MAC address>] 2.283ms
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Unicast reply from 192.168.1.2 [<DUT MAC address>] 2.234ms
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Sent 5 probes (5 broadcast(s))
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Received 5 response(s)
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This shows working broadcast data connectivity.
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$ arping -b -I wlan0 192.168.1.2 -c 5
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ARPING 192.168.1.2 from 192.168.1.1 wlan0
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Sent 5 probes (5 broadcast(s))
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Received 0 response(s)
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This shows not working broadcast data connectivity.
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If testing results do not look consistent, the testing state can be
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cleared by disconnection and reconnecting the station (the test tool or
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the DUT) to the network.
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Sniffer and wlantest
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--------------------
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It is useful to get a wireless sniffer capture from the operating
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channel of the AP to be able to confirm DUT behavior if any of the data
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tests indicate reason to believe something is not working as expected.
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wlantest (from the wlantest directory of hostap.git) can be used to
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decrypt and analyze a sniffer capture. For example:
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wlantest -r wlan0.pcap -n decrypted.pcap -p 12345678
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The debug prints and comments in the generated file indicate where
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unexpected behavior has been detected, e.g., when the test tool ends up
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clearing its packet number to test replay protection. That can help in
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checking whether the DUT actually replies to a frame that it was
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supposed to drop due replay.
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Testing replay protection on a station device
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---------------------------------------------
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Start hostapd and use hostapd_cli on the test device to control testing
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operations. Connect the DUT to the network.
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<3>AP-STA-CONNECTED <DUT MAC address>
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This indicates that the connection was completed successfully.
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Verify that broadcast and unicast traffic works correctly (if not,
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something is wrong in the test setup and that needs to be resolved
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before being able to run any tests).
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Verify that unicast traffic works and issue the following command in
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hostapd_cli:
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> raw RESET_PN <DUT MAC address>
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OK
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Verify that unicast traffic does not work anymore. If it does, the DUT
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does not implement replay protection correctly for unicast frames. Note
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that unicast traffic can recover once the packet number from the test
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device increases beyond the value used prior to that RESET_PN command.
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Verify that broadcast traffic works and issue the following command in
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hostapd_cli:
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> raw RESET_PN ff:ff:ff:ff:ff:ff
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OK
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Verify that broadcast traffic does not work anymore. If it does, the DUT
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does not implement replay protection correctly for broadcast
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frames. Note that broadcast traffic can recover once the packet number
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from the test device increases beyond the value used prior to that
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RESET_PN command.
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Testing replay protection on an AP device
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-----------------------------------------
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Start the AP (DUT) and start wpa_supplicant on the test device to
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connect to the network. Use wpa_cli to control the test device.
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<3>SME: Trying to authenticate with <DUT MAC address> (SSID='test-psk' freq=5240 MHz)
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<3>CTRL-EVENT-REGDOM-CHANGE init=CORE type=WORLD
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<3>Trying to associate with <DUT MAC address> (SSID='test-psk' freq=5240 MHz)
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<3>Associated with <DUT MAC address>
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<3>WPA: Key negotiation completed with <DUT MAC address> [PTK=CCMP GTK=CCMP]
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<3>CTRL-EVENT-CONNECTED - Connection to <DUT MAC address> completed [id=0 id_str=]
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Verify that unicast traffic works and issue the following command in
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wpa_cli:
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> raw RESET_PN
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OK
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Verify that unicast traffic does not work anymore. If it does, the DUT
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does not implement replay protection correctly. Note that unicast
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traffic can recover once the packet number from the test device
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increases beyond the value used prior to that RESET_PN command.
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IEEE 802.11 protocol uses unicast frames in station-to-AP direction, so
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there is no need to test AP replay protection behavior separately with
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the broadcast IPv4 traffic (which would be converted to unicast frames
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on the link layer).
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Testing GTK reinstallation protection on a station device (group handshake)
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---------------------------------------------------------------------------
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Use the procedure describe above for testing replay protection, but with
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the following hostapd_cli commands:
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Test broadcast connectivity; should work
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> raw RESEND_GROUP_M1 <DUT MAC address>
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OK
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> raw RESET_PN ff:ff:ff:ff:ff:ff
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OK
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Test broadcast connectivity; should not work; if it does, the device
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does not implement protection for delayed retransmission of Group Key
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Message 1/2.
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Testing GTK reinstallation protection on a station device (4-way handshake)
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---------------------------------------------------------------------------
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Use the procedure described above for testing replay protection for
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broadcast traffic, but with the following hostapd_cli commands:
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Test broadcast connectivity; should work
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> raw RESEND_M3 <DUT MAC address>
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OK
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> raw RESET_PN ff:ff:ff:ff:ff:ff
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OK
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Test broadcast connectivity; should not work; if it does, the device
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does not implement protection for delayed retransmission of 4-way
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handshake EAPOL-Key Message 3/4.
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Variant 1: Include extra Message 1/4
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Otherwise same as above, but replace RESEND_M3 command with:
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> raw RESEND_M1 <DUT MAC address>
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OK
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> raw RESEND_M3 <DUT MAC address>
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OK
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Variant 2: Include two extra Message 1/4
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Otherwise same as above, but replace RESEND_M3 command with:
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> raw RESEND_M1 <DUT MAC address> change-anonce
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OK
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> raw RESEND_M1 <DUT MAC address>
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OK
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> raw RESEND_M3 <DUT MAC address>
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OK
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Testing TK reinstallation protection on a station device (4-way handshake)
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--------------------------------------------------------------------------
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Use the procedure described above for testing replay protection for
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unicast traffic, but with the following hostapd_cli commands:
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Test unicast connectivity; should work
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> raw RESEND_M3 <DUT MAC address>
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OK
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> raw RESET_PN <DUT MAC address>
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OK
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Test unicast connectivity; should not work; if it does, the device
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does not implement protection for delayed retransmission of 4-way
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handshake EAPOL-Key Message 3/4.
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Variant 1: Include extra Message 1/4
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Otherwise same as above, but replace RESEND_M3 command with:
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> raw RESEND_M1 <DUT MAC address>
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OK
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> raw RESEND_M3 <DUT MAC address>
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OK
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Variant 2: Include two extra Message 1/4
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Otherwise same as above, but replace RESEND_M3 command with:
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> raw RESEND_M1 <DUT MAC address> change-anonce
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OK
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> raw RESEND_M1 <DUT MAC address>
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OK
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> raw RESEND_M3 <DUT MAC address>
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OK
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Testing ANonce generation on an AP device
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-----------------------------------------
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Start the AP (DUT) and start wpa_supplicant on the test device to
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connect to the network. Use wpa_cli to control the test device.
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<3>SME: Trying to authenticate with <DUT MAC address> (SSID='test-psk' freq=5240 MHz)
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<3>CTRL-EVENT-REGDOM-CHANGE init=CORE type=WORLD
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<3>Trying to associate with <DUT MAC address> (SSID='test-psk' freq=5240 MHz)
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<3>Associated with <DUT MAC address>
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<3>WPA: Key negotiation completed with <DUT MAC address> [PTK=CCMP GTK=CCMP]
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<3>CTRL-EVENT-CONNECTED - Connection to <DUT MAC address> completed [id=0 id_str=]
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Show the ANonce from the first 4-way handshake, request PTK rekeying,
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and show the ANonce from the second 4-way handshake:
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> GET anonce
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df8c61d1f1f7aca9f1739dd888199547f4af2b8b07f8bf15b45ea271da0072b2
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> raw KEY_REQUEST 0 1
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OK
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> GET anonce
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d8ddcb716f28abfdf1352a05d51e7a70f58802122e99d13c730c3c0f09594aac
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If the ANonce values are same, the AP did not update the ANonce for
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rekeying (it should have as shown in the example above).
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Testing FT Reassociation Request frame retransmission on an AP device
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---------------------------------------------------------------------
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This test case requires a sniffer to be used and manually analyzed.
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Enable FT on the DUT AP (likely two AP devices needed), connect test
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tool to the AP using FT protocol (e.g., connect to another AP first and
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then use the "ROAM <BSSID>" command), and do the following steps:
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- verify unicast traffic from the AP to test station (either ping from
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the AP or from a device behind the AP); this needs to work
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- wpa_cli "raw RESEND_ASSOC"
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- verify unicast traffic from the AP to test station (either ping from
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the AP or from a device behind the AP); this is likely to fail, but
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the real analysis is done based on the sniffer capture
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In the sniffer capture, find the last Reassociation Request frame from
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the test station (this is more or less identical to the previous one and
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the only one that should not have Authentication frame exchange before
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it). Look at the last used PN in a unicast Data frame from the AP to the
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test station before the last Reassociation Request frame and the PN in
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the following unicast Data frame after the last Reassociation Request
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frame. If the PN goes down (e.g., is reset to 1), this would be a sign
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of a likely security vulnerability. The AP's TK configuration should be
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verified (i.e., whether it is configuring the same TK again and then
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allowing it to be used with reused PN values).
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