Documentation/driver-api/surface_aggregator/overview.rst - linux - Git at Google

 .. SPDX-License-Identifier: GPL-2.0+

 ========
 Overview
 ========

 The Surface/System Aggregator Module (SAM, SSAM) is an (arguably *the*)
 embedded controller (EC) on Microsoft Surface devices. It has been originally
 introduced on 4th generation devices (Surface Pro 4, Surface Book 1), but
 its responsibilities and feature-set have since been expanded significantly
 with the following generations.


 Features and Integration
 ========================

 Not much is currently known about SAM on 4th generation devices (Surface Pro
 4, Surface Book 1), due to the use of a different communication interface
 between host and EC (as detailed below). On 5th (Surface Pro 2017, Surface
 Book 2, Surface Laptop 1) and later generation devices, SAM is responsible
 for providing battery information (both current status and static values,
 such as maximum capacity etc.), as well as an assortment of temperature
 sensors (e.g. skin temperature) and cooling/performance-mode setting to the
 host. On the Surface Book 2, specifically, it additionally provides an
 interface for properly handling clipboard detachment (i.e. separating the
 display part from the keyboard part of the device), on the Surface Laptop 1
 and 2 it is required for keyboard HID input. This HID subsystem has been
 restructured for 7th generation devices and on those, specifically Surface
 Laptop 3 and Surface Book 3, is responsible for all major HID input (i.e.
 keyboard and touchpad).

 While features have not changed much on a coarse level since the 5th
 generation, internal interfaces have undergone some rather large changes. On
 5th and 6th generation devices, both battery and temperature information is
 exposed to ACPI via a shim driver (referred to as Surface ACPI Notify, or
 SAN), translating ACPI generic serial bus write-/read-accesses to SAM
 requests. On 7th generation devices, this additional layer is gone and these
 devices require a driver hooking directly into the SAM interface. Equally,
 on newer generations, less devices are declared in ACPI, making them a bit
 harder to discover and requiring us to hard-code a sort of device registry.
 Due to this, a SSAM bus and subsystem with client devices
 (:c:type:`struct ssam_device <ssam_device>`) has been implemented.


 Communication
 =============

 The type of communication interface between host and EC depends on the
 generation of the Surface device. On 4th generation devices, host and EC
 communicate via HID, specifically using a HID-over-I2C device, whereas on
 5th and later generations, communication takes place via a USART serial
 device. In accordance to the drivers found on other operating systems, we
 refer to the serial device and its driver as Surface Serial Hub (SSH). When
 needed, we differentiate between both types of SAM by referring to them as
 SAM-over-SSH and SAM-over-HID.

 Currently, this subsystem only supports SAM-over-SSH. The SSH communication
 interface is described in more detail below. The HID interface has not been
 reverse engineered yet and it is, at the moment, unclear how many (and
 which) concepts of the SSH interface detailed below can be transferred to
 it.

 Surface Serial Hub
 ------------------

 As already elaborated above, the Surface Serial Hub (SSH) is the
 communication interface for SAM on 5th- and all later-generation Surface
 devices. On the highest level, communication can be separated into two main
 types: Requests, messages sent from host to EC that may trigger a direct
 response from the EC (explicitly associated with the request), and events
 (sometimes also referred to as notifications), sent from EC to host without
 being a direct response to a previous request. We may also refer to requests
 without response as commands. In general, events need to be enabled via one
 of multiple dedicated requests before they are sent by the EC.

 See Documentation/driver-api/surface_aggregator/ssh.rst for a
 more technical protocol documentation and
 Documentation/driver-api/surface_aggregator/internal.rst for an
 overview of the internal driver architecture.
	.. SPDX-License-Identifier: GPL-2.0+

	========
	Overview
	========

	The Surface/System Aggregator Module (SAM, SSAM) is an (arguably the)
	embedded controller (EC) on Microsoft Surface devices. It has been originally
	introduced on 4th generation devices (Surface Pro 4, Surface Book 1), but
	its responsibilities and feature-set have since been expanded significantly
	with the following generations.


	Features and Integration
	========================

	Not much is currently known about SAM on 4th generation devices (Surface Pro
	4, Surface Book 1), due to the use of a different communication interface
	between host and EC (as detailed below). On 5th (Surface Pro 2017, Surface
	Book 2, Surface Laptop 1) and later generation devices, SAM is responsible
	for providing battery information (both current status and static values,
	such as maximum capacity etc.), as well as an assortment of temperature
	sensors (e.g. skin temperature) and cooling/performance-mode setting to the
	host. On the Surface Book 2, specifically, it additionally provides an
	interface for properly handling clipboard detachment (i.e. separating the
	display part from the keyboard part of the device), on the Surface Laptop 1
	and 2 it is required for keyboard HID input. This HID subsystem has been
	restructured for 7th generation devices and on those, specifically Surface
	Laptop 3 and Surface Book 3, is responsible for all major HID input (i.e.
	keyboard and touchpad).

	While features have not changed much on a coarse level since the 5th
	generation, internal interfaces have undergone some rather large changes. On
	5th and 6th generation devices, both battery and temperature information is
	exposed to ACPI via a shim driver (referred to as Surface ACPI Notify, or
	SAN), translating ACPI generic serial bus write-/read-accesses to SAM
	requests. On 7th generation devices, this additional layer is gone and these
	devices require a driver hooking directly into the SAM interface. Equally,
	on newer generations, less devices are declared in ACPI, making them a bit
	harder to discover and requiring us to hard-code a sort of device registry.
	Due to this, a SSAM bus and subsystem with client devices
	(:c:type:`struct ssam_device <ssam_device>`) has been implemented.


	Communication
	=============

	The type of communication interface between host and EC depends on the
	generation of the Surface device. On 4th generation devices, host and EC
	communicate via HID, specifically using a HID-over-I2C device, whereas on
	5th and later generations, communication takes place via a USART serial
	device. In accordance to the drivers found on other operating systems, we
	refer to the serial device and its driver as Surface Serial Hub (SSH). When
	needed, we differentiate between both types of SAM by referring to them as
	SAM-over-SSH and SAM-over-HID.

	Currently, this subsystem only supports SAM-over-SSH. The SSH communication
	interface is described in more detail below. The HID interface has not been
	reverse engineered yet and it is, at the moment, unclear how many (and
	which) concepts of the SSH interface detailed below can be transferred to
	it.

	Surface Serial Hub
	------------------

	As already elaborated above, the Surface Serial Hub (SSH) is the
	communication interface for SAM on 5th- and all later-generation Surface
	devices. On the highest level, communication can be separated into two main
	types: Requests, messages sent from host to EC that may trigger a direct
	response from the EC (explicitly associated with the request), and events
	(sometimes also referred to as notifications), sent from EC to host without
	being a direct response to a previous request. We may also refer to requests
	without response as commands. In general, events need to be enabled via one
	of multiple dedicated requests before they are sent by the EC.

	See Documentation/driver-api/surface_aggregator/ssh.rst for a
	more technical protocol documentation and
	Documentation/driver-api/surface_aggregator/internal.rst for an
	overview of the internal driver architecture.