Gazoo Device Manager
Project description
Gazoo Device Manager (also known as gazoo_device or GDM)
gazoo_device is a python package for interacting with smart devices.
It contains Gazoo Device Manager (GDM), which defines a common device
interface. The common device interface standardizes device interactions
and allows test writers to share tests across devices despite the
underlying differences in communication types, OSes, and logic.
GDM is available as a Python package for use in tests and comes with
its own CLI for quick device interactions.
GDM is the open-source architecture which enables device-agnostic
interations. Device controllers used by GDM are contained in separate
Python packages and can be registered with the GDM architecture.
GDM runs on the test host and communicates with the physical devices via
one or more device transports (such as SSH, ADB, HTTPS, UART). GDM does
not require any additional support from the device firmware.
GDM is used for on-device testing at Google Nest.
The code is ready for use. There's one caveat for CLI usage: using user-defined extension packages in the GDM CLI requires minor source code modifications to your virtual environment. This will be addressed soon.
Supporting items (documentation, example controller package, functional tests, unit tests) haven't yet been updated since the early release in November 2020 and are under active development. Expect most of these items to be complete by early June. We're releasing GDM as early as possible to help early adopters meet their timelines.
TODO(gdm-authors): Update documentation (most of it doesn't actually need to change).
Table of contents
- Install
- Quick start
- Virtual environment
- Device controllers in GDM
- Config files
- Logs
- Detecting devices
- Using the CLI
- Using the gazoo_device python package
- How to use GDM with test frameworks
- Contributor documentation
- License
- Disclaimer
Install
Supported host operating systems:
- Debian;
- Ubuntu;
- MacOS.
Note: Raspberry Pi 4 on 64-bit Ubuntu 20.04 LTS is also supported as a host (see the relevant device setup section).
MacOS prerequisites:
-
Install Xcode Command Line Tools:
xcode-select --install
-
Install Brew (MacOS package manager):
Installation steps:
-
Download the GDM installer archive:
curl -OL https://github.com/google/gazoo-device/releases/latest/download/gdm-install.sh
-
Run the installer:
bash gdm-install.sh
You should see the following message at the end of the installation:
Install done (exit 0)
Run a few GDM CLI commands to verify GDM works:
gdm -v
gdm devices
gdm
gdm -v
displays versions of the GDM launcher and of the python package:
Gazoo Device Manager launcher 1.0
Gazoo Device Manager 1.0.0
Typical output of gdm devices
:
Device Alias Type Model Connected
--------------- --------------- ----------- ---------------- ------------
Other Devices Alias Type Model Available
--------------- --------------- ----------- ---------------- ------------
0 total Gazoo device(s) available.
gdm
displays a help menu.
To update GDM to the latest version:
gdm update-gdm
To update (or downgrade) GDM to a specific version:
gdm update-gdm <version> # Example: gdm update-gdm 1.0.0
To install GDM in a virtual environment:
/path_to_virtual_env/bin/pip install gazoo-device
Uninstall
To uninstall GDM:
curl -OL https://github.com/google/gazoo-device/releases/latest/download/gdm-cleanup.sh
bash gdm-cleanup.sh
Quick start
This is the quickest way to get your hands dirty with GDM. You'll need a Raspberry Pi.
-
Set up your Raspberry Pi as an auxiliary device in GDM and try out the CLI.
-
Run
gdm devices
and record the name of your Raspberry Pi (likeraspberrypi-1234
). -
Create a Mobly testbed for your Raspberry Pi:
cp ~/gazoo/testbeds/One-Exampledevice.yml ~/gazoo/testbeds/One-Raspberrypi.yml vi ~/gazoo/testbeds/One-Raspberrypi.yml # Or use a text editor of your choice # Replace "exampledevice-1234" with your device name (like "raspberrypi-1234") # Update the testbed name ("Testbed-One-Exampledevice-01" -> "Testbed-One-Raspberrypi-01")
-
Check out the GDM repo (which includes on-device regression tests):
git clone https://github.com/google/gazoo-device.git
-
Run the GDM regression test suite for Raspberry Pi on your device:
cd gazoo-device/tests/ ./run_tests.sh -d functional_test_suites/ -f regression_test_suite.py -c ~/gazoo/testbeds/One-Raspberrypi.yml
Virtual environment
GDM creates a virtual environment for the CLI at ~/gazoo/gdm/virtual_env
.
To use GDM in this virtual environment do the following:
source ~/gazoo/gdm/virtual_env/bin/activate
- Then use GDM (
gdm
) as usual.
To use GDM in a different virtual environment do the following:
source /path/to_other_virtual_environment/bin/activate
- Install GDM in this other virtual environment (if needed):
~/gazoo/gdm/bin/gdm update-gdm
- Then use GDM as usual.
Device controllers in GDM
To interact with devices, GDM creates one Python device controller object for each physical device. The lifecycle of GDM device controllers is as follows:
-
a new device is connected to the host and is detected by GDM (one-time setup step), which makes the device known to GDM:
gdm detect
-
a device controller instance is created at the beginning of a test or a CLI device interaction;
-
one or more device commands are issued through the device controller instance;
-
the device controller instance is closed when the test is finished or the CLI interaction completes;
-
if the device is permanently disconnected from the host, it is removed from the list of devices known to GDM (also a one-time step) through
gdm delete device-1234
Note that the term "device" is ambiguous in the context of GDM: it can refer to either the device controller or the physical device. Device controllers can also be referred to as device classes.
Config files
GDM device configs are found in ~/gazoo/gdm/conf
.
You should not modify them directly. Instead, use set-prop
and
get-prop
commands:
-
To set an optional device property:
gdm set-prop device-1234 property-name property-value
-
To retrieve a property value:
gdm get-prop device-1234 property-name
-
To set a GDM property (config value):
gdm set-prop property-name property-value
-
To retrieve a GDM property (config value):
gdm get-prop property-name
Logs
By default all GDM logs go to ~/gazoo/gdm/log/
. Log verbosity, output
directory, and standard output behavior can be configured via arguments to
Manager.__init__
(see gazoo_device/manager.py).
GDM creates three types of log files.
The gdm.txt
log
All GDM logs go here. Device logs are not captured in this file. This log file persists across GDM invocations. It provides the best history, but it can be difficult to pinpoint the logs for a particular device interaction.
Device log files, such as linuxexample-1eb2-20201113-123538.txt
These capture all communications between GDM and the device.
Each log line is prefixed with GDM-<letter_or_digit>
, such as GDM-M
,
GDM-0
, or GDM-1
.
GDM-M
are logs written by GDM. These include the commands that GDM
wrote, the regular expressions GDM expects to find after writing a
command and the maximum time window for the response, and the result of
the expect (which regular expression matched, if any).
GDM-0
, GDM-1
, and other GDM-<digit>
logs come from device
transports. The digit corresponds to the index of the transport (as
defined by get_transport_list()
methods of communication types in
gazoo_device/switchboard/communication_types.py).
For some communication types, such as SSH and ADB, logs and command
responses come from different transports. In that case device responses
come from GDM-0
and device logs come from GDM-1
.
For other communication types, there may only be a single transport, in
which case both device responses and logs come from GDM-0
.
The names of device log files are logged during every CLI interaction. For example:
linuxexample-1eb2 logging to file /Users/artorl/gdm/log/linuxexample-1eb2-20201113-123548.txt
Device log event files, such as linuxexample-1eb2-20201113-123548-events.txt
These contain device log events. The log events to be captured are defined by log event filters in gazoo_device/filters/.
A log filtering process receives all device logs in real time and captures lines which match any of the device log filters into the device log event file.
The name of the log event file is constructed as
<name_of_log_file>-events.txt
. For example,
linuxexample-1eb2-20201113-123548-events.txt
is the log event file for
the linuxexample-1eb2-20201113-123548.txt
device log file.
Detecting devices
To detect all devices attached to your host, run gdm detect
on the
host. This is a one-time step that is required when GDM is installed on
the host or when a new device is connected to the host. Devices
typically require a special setup before being usable with GDM. This can
include a special cable connection configuration, renaming serial
cables, updating device firmware to a specific version, setting up the
device on a static IP address, or setting up passwordless SSH access to
the device. Refer to docs/DEVICE_SETUP.md for
instructions.
Device detection populates device configs:
- persistent properties are stored in
~/gazoo/gdm/conf/devices.json
; - optional (settable) properties are stored in
~/gazoo/gdm/conf/device_options.json
.
To view all devices currently known to GDM, run gdm devices
.
Sample detection output (cambrionix-kljo
was detected):
$ gdm detect
##### Step 1/3: Detecting potential new communication addresses. #####
detecting potential AdbComms communication addresses
detecting potential DockerComms communication addresses
Unable to detect DockerComms communication addresses. Err: FileNotFoundError(2, 'No such file or directory')
detecting potential JlinkSerialComms communication addresses
detecting potential PtyProcessComms communication addresses
detecting potential SerialComms communication addresses
Warning: no read/write permission for these serial address(es): ['/dev/bus/usb/001/001', '/dev/bus/usb/001/002', '/dev/bus/usb/002/001']
detecting potential SshComms communication addresses
detecting potential YepkitComms communication addresses
Found 1 possible serialcomms connections:
/dev/serial/by-id/usb-FTDI_FT230X_Basic_UART_DM01KLJO-if00-port0
##### Step 2/3 Identify Device Type of Connections. #####
Identifying serialcomms devices..
/dev/serial/by-id/usb-FTDI_FT230X_Basic_UART_DM01KLJO-if00-port0 is a cambrionix.
serialcomms device_type detection complete.
##### Step 3/3: Extract Persistent Info from Detected Devices. #####
Getting info from communication port /dev/serial/by-id/usb-FTDI_FT230X_Basic_UART_DM01KLJO-if00-port0 for cambrionix
cambrionix_detect starting AuxiliaryDevice.check_device_ready
cambrionix_detect health check 1/2 succeeded: Device is connected.
cambrionix_detect health check 2/2 succeeded: Clear flags.
cambrionix_detect AuxiliaryDevice.check_device_ready successful. It took 0s.
cambrionix_detect starting Cambrionix.get_detection_info
cambrionix_detect Cambrionix.get_detection_info successful. It took 1s.
##### Detection Summary #####
1 new devices detected:
cambrionix-kljo
Device Alias Type Model Connected
--------------- --------------- ----------- ---------------- ------------
Other Devices Alias Type Model Available
--------------- --------------- ----------- ---------------- ------------
cambrionix-kljo <undefined> cambrionix PP15S available
0 total device(s) available.
Device names are created as devicetype-1234
, where the device type is
provided by the device controller, and the digits are the last 4 digits
of the device's serial number.
Detection only detects new devices. It does not re-detect already known devices. \
-
To delete a known device:
gdm delete device-1234
-
To redetect a device:
gdm redetect device-1234
Using the CLI
Exploring device capabilities without a physical device
GDM comes equipped with auto-generated documentation. To access it, you do not need a device.
To see all commands available through the Manager class, run:
gdm
You can also explore Manager functionality via the dynamic Fire CLI. For example:
gdm -- --help
gdm create_device -- --help
To start exploring device documentation, run:
gdm man
It will list all supported devices and provide commands to run if you're interested in exploring capabilities of a specific device.
To see what's supported by a device type:
gdm man device_type
For example:
gdm man raspberrypi
To explore a device method, property, or capability, issue:
gdm man device_type attribute_name
For example:
gdm man raspberrypi firmware_version
gdm man raspberrypi reboot
gdm man raspberrypi file_transfer
To explore a capability method or property, issue:
gdm man device_type capability_name method_or_property_name
For example:
gdm man cambrionix switch_power off
gdm man raspberrypi file_transfer send_file_to_device
Exploring device capabilities with a physical device
If you have a physical device, you can use the dynamic Fire CLI
to get help about any attribute of the device. There are no limitations
to this documentation, and it's more detailed and more accurate, but the
drawback is that it requires a physical device. For example, assuming a
raspberrypi-kljo
is attached:
gdm issue raspberrypi-kljo -- --help
gdm issue raspberrypi-kljo - reboot -- --help
Basic CLI usage
Let's assume you have a raspberrypi-kljo
connected.
Here are a few commonly used CLI commands:
-
list all known devices:
gdm devices
-
detect new devices:
gdm detect
or
gdm detect --static_ips=10.20.30.40,50.60.70.80
Note: detection does not remove devices which are already known to GDM.
-
set a device property (such as an alias):
gdm set-prop raspberrypi-kljo alias rpi
-
check GDM version:
gdm -v
-
run health checks on a device:
gdm health-check raspberrypi-kljo
if you set the alias above, the following will also work:
gdm health-check rpi
-
run health checks, then issue a device command or retrieve a property:
gdm issue raspberrypi-kljo - reboot
-
issue a device command or retrieve a property without running health checks:
gdm exec raspberrypi-kljo - reboot
-
use a device capability:
gdm issue raspberrypi-kljo - file_transfer - recv_file_from_device --src="/tmp/foo" --dest="/tmp/bar"
(or use
exec
to skip health checks).
Sometimes passing the arguments to the Fire CLI gets a bit tricky. Refer to the Python Fire documentation and definitely review the argument parsing section.
The most commonly used device method is shell
. It runs a shell
command on the device. It's required for primary devices, but is
optional for auxiliary devices. The only auxiliary device included with
GDM that implements shell()
is Raspberry Pi. If you have a Raspberry
Pi connected, you can try it out:
gdm issue raspberrypi-1234 - shell "echo 'foo'"
Using the gazoo_device python package
Launch Python from a virtual environment with gazoo_device installed.
You can use the GDM virtual environment:
~/gazoo/gdm/virtual_env/bin/python
.
from gazoo_device import Manager
mgr = Manager()
rpi = mgr.create_device('raspberrypi-962c')
rpi.reboot()
Note that the device you're creating should be shown as "available" in
the output of gdm devices
.
How to use GDM with test frameworks
GDM with Mobly
Example testbed file (~/gazoo/testbeds/One-Raspberrypi.yml
):
TestBeds:
- Name: Testbed-One-Raspberrypi-01
Controllers:
GazooDevice:
- 'raspberrypi-kljo'
Example device test using GDM with Mobly: example_mobly_test.py.
For working examples of gazoo_device + mobly, see GDM's functional tests in tests/functional_tests/.
GDM with Unittest
Example device test using GDM with Unittest: example_unittest_test.py.
Contributor documentation
If you're interested in adding support for your device(s) to GDM, refer to CONTRIBUTING.md.
License
Licensed under the Apache 2.0 License.
Disclaimer
This is not an official Google product.
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