LAVA Hacking Sessions¶
A LAVA hacking session is a special lava-test-shell test that provides interactive ssh access to a LAVA device inside a defined test environment. This support differs from the normal LAVA SSH protocol support in that the job waits for a real user to log in, instead of using an ssh connection to run a test shell.
Assumptions¶
The user has TCP/IP access to the device (this may require a VPN or other access if firewalls exist between the user and the device).
The test job deployment raises a usable networking interface.
The test job deployment starts a suitable daemon,
sshd
ordropbear
The test action uses Lava-Test Test Definition 1.0
Limitations¶
The session connection is SSH, not serial. This can change the way that certain operations run within the session compared to an automated test job. In particular, the MultiNode API does not operate either within a hacking session or between two hacking sessions. A test definition which runs either before or after the hacking session will be able to use the full MultiNode API.
Device requirements¶
Some devices may need parameters to configure the network correctly to allow
the user to log in to the hacking session. e.g. QEMU jobs need to setup a
tap
device:
context:
arch: amd64
netdevice: tap
Definitions¶
There are Lava-Test Test Definition 1.0 test definitions for hacking sessions provided by the LAVA developers at https://git.linaro.org/lava-team/hacking-session.git . Currently the following definitions are supported:
hacking-session-debian.yaml - Run the hacking session on a Debian or Ubuntu filesystem. The package openssh-server will be installed using the package manager if not already installed in the test image. The test image must raise a network interface automatically (this can be done with
lava_command_run
, see example).hacking-session-fedora.yaml - Run the hacking session on a Fedora filesystem. The package openssh-server will be installed using the package manager if not already installed in the test image. The test image must raise a network interface automatically (this can be done with
lava_command_run
, see example).hacking-session-oe.yaml - Run the hacking session on an Open Embedded filesystem. openssh-server must be installed in the test image, as it cannot easily be installed afterwards.
Parameters¶
There are several extra parameters to set when using these test definitions, some optional:
PUB_KEY
: A plain-text string containing the ssh public key(s) you wish to use when connecting to the deviceGATEWAY
: (optional) The gateway for the network the test device is on. This only needs to be set if the test is unable to determine the gateway correctly - check with your LAVA adminsIRC_USER
: (optional) IRC nick - this user will be alerted when the hacking session is ready for a connection with a private IRC message containing the details of how to connect to the session. (Debian hacking sessions only.)IRC_SERVER
: (optional) The IRC network to use for notifications, used if IRC_USER is also set. This defaults toirc.freenode.net
Starting a Hacking Session¶
Create a test job with your desired target and image
Add a lava-test-shell action at the point where you want hacking access:
- test:
failure_retry: 3
name: kvm-basic-hacking-session
timeout:
minutes: 5
definitions:
- repository: https://git.linaro.org/lava-team/hacking-session.git
from: git
path: hacking-session-debian.yaml
name: hacking
parameters:
"IRC_USER": "TYPE YOUR IRC NICK HERE"
"PUB_KEY": "PASTE_PUBKEY(S) HERE"
Other types of test action are not supported for hacking sessions.
It is possible to include multiple hacking sessions in the same job, even interleaved with other test actions.
As an alternative to an IRC message like this example, it is also possible to configure notification such that email will be sent when the job starts running. For more information, see User specified notifications.
See also
Hacking Session timeouts and Timeouts for clarification of the timeout support.
Connecting to a Hacking Session¶
The hacking session test definition will log the ssh command line needed for connection into the LAVA log file. To access the log file, you can use a web browser; navigate to your hacking session and scroll to the end of the job to see this command line, For an example see:
SSH tunnels¶
If your test device is located on a remote network, you may need to gain access via an ssh tunnel. If so:
verify your SSH key is setup and configured to connect:
~# ssh -T username@example.com
Modify your SSH config to allow agent forwarding:
Host example.com ForwardAgent yes
lava-test-shell helper functions in a hack session¶
Once logged in to the hacking session, the lava-test-shell helper functions can
be found on the test device in the directory /lava/bin
Record text to the LAVA log¶
During a hacking session, LAVA listens to the primary serial connection for the duration of the hacking session. From within the test device, any text you echo to that serial connection will therefore be recorded within LAVA. You may need to work out the correct device name for this connection, for example by looking at the CONSOLE setting in /proc/cmdline.
As an example, in a QEMU test, the device name will be /dev/ttyS0
. From
within the hacking session:
root@kvm01:~# echo "This is a test statement" > /dev/ttyS0
will output to the LAVA log like:
This is a test statement
There is an example of this online at https://validation.linaro.org/scheduler/job/1126092#L2300
Stopping a Hacking Session¶
During a hacking session, your test device can’t be used for other tasks. This will block other users who may want to run tests using the device. For that reason, your session is monitored for Hacking Session timeouts, or you can complete your session immediately:
Log out of your session (you can avoid closing the session on logout using the Continuing a Hacking Session support).
Cancel the job in the LAVA using the link in the job detail or job log pages.
Stop - Use the helper function
stop_hacking
from the command line within the hacking session
Note
Cancel
will end the entire job immediately. Use stop_hacking
to close the session and complete normal job processing that may be defined
after the hacking session.
Hacking Session timeouts¶
Note
This behavior changed after a session at Connect HKG15
All hacking sessions will time out after 1 hour if a login has not been
detected. If an IRC_USER
is specified, another IRC private messages will be
sent to that user explaining the termination.
The timer is running for the lifetime of the hacking session, so if you use Continuing a Hacking Session and logout, you will still need to log back in within one hour.
The session will timeout, regardless of activity, when the top-level timeout specified in the job is reached.
This support is separate from the Timeouts handling of the test job.
Continuing a Hacking Session¶
If you want to be able to log out of a hacking session and log back in within
the inactivity timeout, call the continue_hacking
script from the command
line within the hacking session. The hacking session is still monitored for
Hacking Session timeouts, so do remember to log back in.
Multiple hacking sessions¶
It is possible to use secondary connections to allow more than one person to have a hacking session on a device. Depending on how the test job is designed, it is possible to have two hacking sessions into the same machine or to contain each hacking session within a separate virtual machine. The secondary connection acts exactly as a second root login to the device, so it is up to the test writer to handle possible collisions between the sessions. It is possible to have multiple hacking sessions per person or one hacking session each for multiple users. Secondary connections separate each session as a single node in the MultiNode group.
Note
The MultiNode API does not support the synchronization or message sending primitives inside hacking sessions. Interactive users are required to exchange information between users in other means, either by using common files on a shared filesystem or other external methods like email or IRC.
Separating users using virtual machines¶
If users are to be separated within virtual machines, one test definition will be responsible for starting each of those machines and this definition will have full control of the QEMU command line for each machine. (It is therefore possible to launch virtual machines of different architectures or configurations for specific purposes.)
Notifying users in this situation is more difficult but the existing support within the standard hacking session can be re-used as it is simply a script being called with parameters from the test job. In particular, the notification will have to allow for declaring the IP address of the virtual machine for each user.
Caution
Separating hacking sessions into virtual machines is a more complex task and requires a lot of setup on the device. Consider if it is really necessary for each user to be on this one device at the same time or whether the separation between users would be better done with separate hacking session test jobs. Remember, users may not be able to share data or files across different virtual machines on one device. This method is not a workaround for a lack of hardware of a particular type of device.
In particular, pay attention to:
Identify unique MAC addresses for each virtual machine and check with the lab admins to ensure that these do not clash with any other device on the lab network.
Setup the bridging on the device before starting any virtual machines so that the machine will get an IP address which is visible to the user.
Start by creating a test job which can launch multiple virtual machines and identify the IP address of each machine. The exact mechanisms used to obtain this information will vary by use case. The IP address is then passed back to the dispatcher to initiate the secondary connection into the running virtual machine. The hacking session can then start as normal inside that virtual machine.
See also
Delaying the start of a job using Multinode for more information on creating a test job which can delay starting the secondary connections until the first test job has successfully launched the virtual machines.