For an overview of what Mozpool is and how it's used at Mozilla, see
https://wiki.mozilla.org/ReleaseEngineering/Mozpool
MozPool is a tool for managing a pool of untrustworthy mobile devices. It is deployed as a single system, but comprised of several distinct components for design simplicity.
It shouldn't cause too much confusion that the top-level component is also known as MozPool. It's just such a great name.
MozPool is responsible for matching requests with devices. A new request is submitted by a client with parameters for acceptable devices (may be as broad as "anything" or as narrow as "this panda" and the expected condition of that device (Android suitable for Fennec, or a particular B2G image, or booted to the live image for diagnostic purposes). Clients can be automated test systems (Buildbot, Autophone) or flesh-and-blood users.
Requests are filled by matching them with a single device. Once that match is made and returned to the client, the request stays around as a form of reservation. Reservations time out if they are not renewed periodically, where the period is specified by the client (so flesh-and-blood users can reserve a device for a day or two, while automated systems can use 30 minutes or something smaller).
When matching a request to a device, MozPool picks a device itself, but relies on LifeGuard to keep information about the available devices up to date, and to put the requested device in the desired state. If LifeGuard fails to set up the device as desired, MozPool is responsible for picking another device that satisfies the request, or indicating failure to the client, if the parameters of the request cannot be satisfied.
MozPool also provides various statistics and reports as needed to maintain the health of the pool. These include summaries of the status of devices by type (where status is divided into simple categories like "in use", "idle", "processing", and "failed"); and lists of devices in known failure states requiring human remediation.
In the initial design, MozPool is entirely reactive, but the design does not preclude predictive or proactive operations, e.g., balancing the distribution of images on spare devices, predictively installing B2G images, etc.
LifeGuard deals only with devices. It actively tracks the state of every device, and handles requests from MozPool to change the state of a device, via events. These events ask the device to "please" perform some action. If the device is not in the expected state, the request is ignored.
Most states for a device involve periodic checks from LifeGuard.
BMM, short for Black Mobile Magic, is the lowest-level component, and handles technical operations on devices as requested from LifeGuard. The available operations are power-cycling a device; PXE-booting a device; pinging a device; and running commands on a device via SUTAgent. BMM includes TFTP and HTTP services to allow a device to be booted into a Linux live-boot environment, and scripts run there to perform whatever actions are appropriate.
Specific scripts implement actions required by LifeGuard: install Android, install a B2G image, run an SSH server in maintenance mode, run system checks, etc. Each of these have corresponding states in the Lifeguard state machine.
BMM abstracts away the details of how power is controlled for each device, as well as the particulars of boot images for specific hardware.
As much logging as possible is funneled through syslog and into the mysql database, to help with debugging.
Logs are expired after some time by the database itself (see sql/schema.sql
).
The Mozilla inventory (https://inventory.mozilla.org) is the source of truth from which the list of devices is derived. The database is automatically synchronized with inventory periodically.
Each device is assigned, in inventory, to a specific mobile-imaging server. In general, that server is "close" to the device, physically or virtually.
All three major components are implemented in the same Python daemon, running web services based on web.py. An instance of this daemon runs on each mobile-imaging server.
The daemon runs background processes in separate threads. In particular, various operations poll for status.
There is no front-end load balancer. If an imaging server is down or unavailable, the devices assigned to it are also unavailable, but other devices continue to be accessible.
Clients access MozPool using an HTTP API. The endpoint for that API is any mobile-imaging server, since all are configured identically. Clients should be pre-configured with a list of servers, and retry servers in random order until successful.
The entire lifetime of each request is handled by MozPool as a formal state machine. The state is stored in the database.
All state transitions and actions are handled on the server where the request was originally made. Timeouts are handled by polling the database for requests with timeout timestamps in the past (using threads within the daemon).
If an imaging server is lost, the requests it manages become invalid when their refresh interval expires.
Boards are claimed by inserting into a correspondance table in the database, with constraints such that only one request can claim a device.
Like requests, devices are managed by LifeGuard as a formal state machine. MozPool has read-only visibility to device states for purposes of selecting devices for requests, but uses conditional requests to LifeGuard to cause state transitions (the intent being that MozPool will observe that a device is in the idle state, claim it, then ask that LifeGuard transition it from idle to rebooting; if the device has failed in the interim, LifeGuard will refuse to do so).
All state transitions and actions are handled on the server to which the device is assigned.
MozPool communicates with LifeGuard using an HTTP API, selecting the endpoint based on the assigned imaging server in the database. This may result in a MozPool server contacting itself via HTTP.
LifeGuard communicates with BMM using regular old Python function invocations.
Configuration should be based on the mozpool/config.ini.dist template. The
config can either be put in the mozpool/config.ini
, or anywhere else with
$MOZPOOL_CONFIG
giving the full path.
To run the server daemon:
mozpool-server
optionally, add a port on the command line for the HTTP server:
mozpool-server 8010
To install the DB schema (using the configured database):
mozpool-db create-schema
And to install test adta
mozpool-db run testdata.py
To control relays:
relay powercycle <hostname> <bank> <relay>
relay status <hostname> <bank> <relay>
relay turnon <hostname> <bank> <relay>
relay turnoff <hostname> <bank> <relay>
can be in the form host:port; the default port is 2101.
Note: do not manually adjust relays that are also under MozPool's active control!
PXE configurations can be edited with the pxe-config
command. See its help
for more information:
pxe-config --help
To synchronize the internal DB with inventory:
mozpool-inventorysync
(use --verbose
to see what it's up to - note that it's not too fast!)
Mozpool ships with a "fake" device implementation that emulates the Mozpool-facing behaviors of devices: power control, imaging scripts, and ping. It does not emulate the actual hardware or operating systems.
To activate this support, add the following to your config.ini
:
[testing]
run_fakes = true
and add devices to your database with imaging_server
matching the configured fqdn
, and with a relay_info
column starting with localhost
, and specifying an available port.
It is possible to mix fake and real devices in the same mozpool instance, although this may confuse consumers of the API!
The testdata.py
script conveniently sets this up for you:
mozpool-db run testdata.py -d 10 -p 2999
To run the tests:
- install mock
- install paste
- run
python runtests.py
NOTE: see UPGRADING.md
for instructions to upgrade from version to version.
- No bug: pass
ship_it
to the inventorysyncsync
function - Bug 988306: Add a missing
continue
- Bug 988321: Bail out if there are too many changes in an inventory sync
- Bug 988306: Synchronize from SREGs in inventory
- Bug 964960: Fix TIMEOUT=0 to mean 'now' and not 'never'
- Bug 962161: Only use cached state for the
/api/device/<name>/state/
endpoint if given?cache=1
- Bug 948244: Return earlier from finding a device, meaning the REST call to create a request is less likely to time out
- Bug 916414: SQL Schema change; revert to using source timestamps instead of database localtime
- Bug 856123: New
selftest.py
script and sample config json included for better hardware failure detection - Bug 914347: accept event call
failed_self_test
while inself_test_running
- Troubleshooting state allows image requests as originally intended in Bug 836013
- Bug 892651: don't shift-select hidden rows in the table views
- Bug 817762: terminate the process after 10m of a stuck thread
- Bug 890933: don't use
sut_reboot
to reboot devices, as it's unreliable - Bug 878880: remove debug logging (trivial)
- Bug 878880: Requests'
pending
state will now wait longer to hear back from Lifeguard, waiting forever (until the request expires) in the case where a specific device was requested. - Debugging changes for bug 817762, including heartbeat and extra logging, removed.
- Bug 835420:
/api/relay/{id}/test/
has been added for testing two-way communications with ProXR relay boards Note that this requires schema changes, detailed inUPGRADING.md
.
- Bug 856111: The file components for building preseed images are now included with the mozpool source
- Bug 863513: DMErrors no longer display tracebacks in the Mozpool log.
- Bug 864488: Lifeguard now waits a short time after doing a SUT reboot to give the device time to shut down.
- Bug 864908: SUT verifies following a SUT reboot no longer unintentionally verify before the reboot completes.
- Bug 863511: Requests no longer have an
expired
state. Requests are marked as closed when they expire. - Bug 856733: The Mozpool layer's failure states have been renamed to begin with
failure
. The states are now defined as part of the API.
- Bug 817762: log
sys._current_frames
whenever a timeout occurs - Bug 836013: Devices can be forced into a 'troubleshooting' state which doesn't timeout and accepts PleaseRequests
- The
/api/image/list?details=1
endpoint now returns arequest_id
column for each device. - Bug 826065: The database interface layer was completely rewritten for better hackability and testability.
- Bug 848561: Log entries and devices are now sorted properly in the web UI
- Bug 844363: The test suite was completely rewritten for easier maintenance and much better coverage.
- Bug 846542: Devices now store information about their current and next images separately.
This represents a schema change; see UPGRADING.md for details.
The API has changed to correspond: the
/api/device/list?details=1
resource now includes animage
key for every device, rather thanlast_image
(which was accidentally undocumented). - Bug 826746: Lifeguard now notifies Mozpool explicitly when an operation for a request is complete.
- Bug 837241: Lifeguard prefers SUT over relays and ping when it is available, falling back where necessary.
- Bug 834568: The lifeguard 'free' state has been dropped in favor of the 'ready' state. Devices in the ready state may or may not be attached to a request.
- The lifeguard UI now displays a link to the attached request for a device, if any.
- Bug 845428: Bmm now sends ProXR commands in a single sock.send to accommodate the new ProXR firmware (v3.2). This is backwards compatible with previous firmware versions.
- Mozpool now sets
SO_KEEPALIVE
on all MySQL sockets, only when using the PyMySQL driver. See bug 817762 for details.
This is a bug-fix release.
- Bug 838925: add capability to touch a heartbeat file on every timeout
- Bug 836065: fix errors in logging implementation in 2.0.1
This is a bug-fix release, with no schema changes or upgrade issues.
- Bug 836417: retry more slowly and more times in the
sut_verifying
state - Bug 836065: limit displayed log entries to the most recent 1000
- Bug 836272: log much less about pinging in the free state
- Bug 834246: log the Mozpool version number at startup
- Bug 819197: improve device-selection implementation
- Bug 819350: Add
mobile_init_started
state - Bug 822423: add support for emulating devices and relay boards in a running daemon, with initial state from the DB (Bug 825922)
- Bug 817057: poll with ping in the free state
- Bug 824816: use socket.settimeout instead of the asyncore madness
- Bug 825977: read hardware type/model from inventory
- Bug 816557: implement CORS correctly
- Bug 819335: add self-test, and require it to get out of failed or new states
- Bug 825071: Incompatible Change: remove support for PXE config and bootconfig in the POST body of the
/device/{id}/set-state/
API call - Bug 815785: Add support for SUT agent
- Bug 828030: clean up requests
Upgrade notes:
- Mozpool now requires at least version 1.0.0 of Requests
- A
hidden
column must be added to theimages
table. This can be done safely before the upgrade occurs. - Two new, hidden images must be added, with corresponding PXE configs:
self-test
andmaintenance
. - The
mobile-init.sh
script must send amobile_init_started
event.
- Bug 819081: Added assignee to requests table
- Bug 818953: Fix request logging
- Bug 819505: Support different hardware types and models
- Bug 819186: use a DB cronjob instead of scheduled events
- Bug 822113: add an API call for state and cache it (for use by monitoring scripts)
- Bug 819576: Store image data in db and verify request data against it
- Bug 817762: run state timeout handlers in threads, and log if they run for too long
-
Bug 817035: Add comments for devices and a
/device/{id}/set-comments/
API call to set them -
Bug 817035: add a
locked_out
state -
Bug 817035: Major UI refactor
- the toolbar is now "tabbed", albeit with a CSS implementation of tabs that will make your eyes bleed. Sorry.
- Lifeguard and BMM display different columns - we need the space!
- Can set comments in the web UI
- Hopefully a clearer delineation of PXE configs, bootconfig, and b2gbase
-
Bug 817035: Add "tailing" support to the log view
-
Bug 817035: Add environments and allow requests to specify one
First release following http://semver.org