README.google - platform/external/walt - Git at Google

 Overview
 ========

 This project is included in the internal Android source tree to support
 automated latency testing with Salad Fingers, a robot designed and built by
 Steve Pfetsch (spfetsch@). The three main components we use and modify are:

   - the android app (android/)
   - the WALT device firmware (arduino/)
   - the TCP-to-serial bridge (pywalt/)

 Salad Fingers uses a single Teensyduino running WALT firmware to test multiple
 devices without human intervention. The devices under test are connected to the
 same host as the Teensy. An end-to-end connection for a single device (only one
 device can use the WALT at a time) looks like this:

     Device ------ Host ------ Teensy
   (android/)    (pywalt/)   (arduino/)

 For the device to communicate with the host over TCP on a physical USB
 connection, a "reverse" port has to be set up with adb. For example:

   $ adb reverse tcp:50007 tcp:45454

 Any traffic the device sends to 127.0.0.1:50007 will come into the host on port
 45454 and vice versa. Port 50007 is defined in the app source, but the device
 port can be selected arbitrarily.

 The TCP-to-serial bridge runs on the host and connects the app's TCP pipe to
 the Teensy's serial pipe. However, there are two special commands the app can
 send to the bridge to synchronize the clocks between the device and the Teensy:
 "bridge sync" and "bridge update".

 This setup requires some modifications from the original source, which are
 explained in the next section, but behaves very similarly to a direct, Teensy-
 to-device USB connection.


 Modifications
 =============

 - Clock synchronization
   Despite the reliability and accuracy of NTP, device and host wall clocks can
   become significantly out of sync, especially if a device loses Wi-Fi
   connectivity. To avoid this problem and take advantage of the low-latency
   connection between the host and device, the clocks are synchronized based on
   the time difference between when the bridge zeroed the Teensy's clock and
   when the reply to the "bridge sync" command was sent to the device. This
   required parallel changes in pywalt/ and android/.

 - Automation intents
   The test scripts which control the robot (Salad Fingers) on which the Teensy
   is mounted require the ability to control certain aspects of the app running
   on a device. These are defined in a separate RobotAutomationEvent interface.
   This required changes to android/.

 - Reverse port support
   The WaltTcpConnection class was originally intended to communicate over a
   true network from a Chromebook to a dedicated bridge with a specific IP
   address. This address was changed to localhost in android/.

 - Strict networking and request ordering
   To prevent crashes due to network accesses performed on the main thread,
   which is disallowed in strict mode, all such accesses were moved to a
   dedicated network thread. As a side benefit, all requests sent to the bridge
   now wait for a response before the next request is sent. This complies with
   the serial nature of the device and guarantees correct ordering. This
   required changes to android/.

 - Hardware-specific firmware
   The Teensy on Salad Fingers uses sensors that are not bundled with the
   standard WALT hardware, so new thresholds for accelerometer shocks and photo-
   diode readings were required to achieve accurate results. This required
   changes to arduino/.


 Usage
 =====

 This project is not intended to be automatically built. Instead, as needed, the
 app will be built manually and checked in as a prebuilt that PTS will pick up.
 The firmware cannot be built or loaded automatically, as it requires a modded
 version of the Arduino project for Teensy. The required software can be loaded
 on a laptop to flash the Teensy mounted on Salad Fingers.


 See Also
 ========

 Project metadata: vendor/google_meta/platform/external/walt/
 PTS integration:  vendor/google_testing/pts/tests/salad_fingers/
	Overview
	========

	This project is included in the internal Android source tree to support
	automated latency testing with Salad Fingers, a robot designed and built by
	Steve Pfetsch (spfetsch@). The three main components we use and modify are:

	- the android app (android/)
	- the WALT device firmware (arduino/)
	- the TCP-to-serial bridge (pywalt/)

	Salad Fingers uses a single Teensyduino running WALT firmware to test multiple
	devices without human intervention. The devices under test are connected to the
	same host as the Teensy. An end-to-end connection for a single device (only one
	device can use the WALT at a time) looks like this:

	Device ------ Host ------ Teensy
	(android/) (pywalt/) (arduino/)

	For the device to communicate with the host over TCP on a physical USB
	connection, a "reverse" port has to be set up with adb. For example:

	$ adb reverse tcp:50007 tcp:45454

	Any traffic the device sends to 127.0.0.1:50007 will come into the host on port
	45454 and vice versa. Port 50007 is defined in the app source, but the device
	port can be selected arbitrarily.

	The TCP-to-serial bridge runs on the host and connects the app's TCP pipe to
	the Teensy's serial pipe. However, there are two special commands the app can
	send to the bridge to synchronize the clocks between the device and the Teensy:
	"bridge sync" and "bridge update".

	This setup requires some modifications from the original source, which are
	explained in the next section, but behaves very similarly to a direct, Teensy-
	to-device USB connection.


	Modifications
	=============

	- Clock synchronization
	Despite the reliability and accuracy of NTP, device and host wall clocks can
	become significantly out of sync, especially if a device loses Wi-Fi
	connectivity. To avoid this problem and take advantage of the low-latency
	connection between the host and device, the clocks are synchronized based on
	the time difference between when the bridge zeroed the Teensy's clock and
	when the reply to the "bridge sync" command was sent to the device. This
	required parallel changes in pywalt/ and android/.

	- Automation intents
	The test scripts which control the robot (Salad Fingers) on which the Teensy
	is mounted require the ability to control certain aspects of the app running
	on a device. These are defined in a separate RobotAutomationEvent interface.
	This required changes to android/.

	- Reverse port support
	The WaltTcpConnection class was originally intended to communicate over a
	true network from a Chromebook to a dedicated bridge with a specific IP
	address. This address was changed to localhost in android/.

	- Strict networking and request ordering
	To prevent crashes due to network accesses performed on the main thread,
	which is disallowed in strict mode, all such accesses were moved to a
	dedicated network thread. As a side benefit, all requests sent to the bridge
	now wait for a response before the next request is sent. This complies with
	the serial nature of the device and guarantees correct ordering. This
	required changes to android/.

	- Hardware-specific firmware
	The Teensy on Salad Fingers uses sensors that are not bundled with the
	standard WALT hardware, so new thresholds for accelerometer shocks and photo-
	diode readings were required to achieve accurate results. This required
	changes to arduino/.


	Usage
	=====

	This project is not intended to be automatically built. Instead, as needed, the
	app will be built manually and checked in as a prebuilt that PTS will pick up.
	The firmware cannot be built or loaded automatically, as it requires a modded
	version of the Arduino project for Teensy. The required software can be loaded
	on a laptop to flash the Teensy mounted on Salad Fingers.


	See Also
	========

	Project metadata: vendor/google_meta/platform/external/walt/
	PTS integration: vendor/google_testing/pts/tests/salad_fingers/