Documentation/hid/intel-ish-hid.txt - LeafOS-Devices/android_kernel_samsung_exynos9820 - Gitiles

 Intel Integrated Sensor Hub (ISH)
 ===============================

 A sensor hub enables the ability to offload sensor polling and algorithm
 processing to a dedicated low power co-processor. This allows the core
 processor to go into low power modes more often, resulting in the increased
 battery life.

 There are many vendors providing external sensor hubs confirming to HID
 Sensor usage tables, and used in several tablets, 2 in 1 convertible laptops
 and embedded products. Linux had this support since Linux 3.9.

 Intel® introduced integrated sensor hubs as a part of the SoC starting from
 Cherry Trail and now supported on multiple generations of CPU packages. There
 are many commercial devices already shipped with Integrated Sensor Hubs (ISH).
 These ISH also comply to HID sensor specification, but the  difference is the
 transport protocol used for communication. The current external sensor hubs
 mainly use HID over i2C or USB. But ISH doesn't use either i2c or USB.

 1. Overview

 Using a analogy with a usbhid implementation, the ISH follows a similar model
 for a very high speed communication:

 	-----------------		----------------------
 	|    USB HID	|	-->	|    ISH HID	     |
 	-----------------		----------------------
 	-----------------		----------------------
 	|  USB protocol	|	-->	|    ISH Transport   |
 	-----------------		----------------------
 	-----------------		----------------------
 	|  EHCI/XHCI	|	-->	|    ISH IPC	     |
 	-----------------		----------------------
 	      PCI				 PCI
 	-----------------		----------------------
         |Host controller|	-->	|    ISH processor   |
 	-----------------		----------------------
 	     USB Link
 	-----------------		----------------------
 	| USB End points|	-->	|    ISH Clients     |
 	-----------------		----------------------

 Like USB protocol provides a method for device enumeration, link management
 and user data encapsulation, the ISH also provides similar services. But it is
 very light weight tailored to manage and communicate with ISH client
 applications implemented in the firmware.

 The ISH allows multiple sensor management applications executing in the
 firmware. Like USB endpoints the messaging can be to/from a client. As part of
 enumeration process, these clients are identified. These clients can be simple
 HID sensor applications, sensor calibration application or senor firmware
 update application.

 The implementation model is similar, like USB bus, ISH transport is also
 implemented as a bus. Each client application executing in the ISH processor
 is registered as a device on this bus. The driver, which binds each device
 (ISH HID driver) identifies the device type and registers with the hid core.

 2. ISH Implementation: Block Diagram

 	 ---------------------------
 	|  User Space Applications  |
 	 ---------------------------

 ----------------IIO ABI----------------
 	 --------------------------
 	|  IIO Sensor Drivers	  |
 	 --------------------------
 	 --------------------------
 	|	 IIO core	  |
 	 --------------------------
 	 --------------------------
 	|   HID Sensor Hub MFD	  |
 	 --------------------------
 	 --------------------------
 	|       HID Core	  |
 	 --------------------------
 	 --------------------------
 	|   HID over ISH Client   |
 	 --------------------------
 	 --------------------------
 	|   ISH Transport (ISHTP) |
 	 --------------------------
 	 --------------------------
 	|      IPC Drivers	  |
 	 --------------------------
 OS
 ----------------   PCI -----------------
 Hardware + Firmware
 	 ----------------------------
 	| ISH Hardware/Firmware(FW) |
 	 ----------------------------

 3. High level processing in above blocks

 3.1 Hardware Interface

 The ISH is exposed as "Non-VGA unclassified PCI device" to the host. The PCI
 product and vendor IDs are changed from different generations of processors. So
 the source code which enumerate drivers needs to update from generation to
 generation.

 3.2 Inter Processor Communication (IPC) driver
 Location: drivers/hid/intel-ish-hid/ipc

 The IPC message used memory mapped I/O. The registers are defined in
 hw-ish-regs.h.

 3.2.1 IPC/FW message types

 There are two types of messages, one for management of link and other messages
 are to and from transport layers.

 TX and RX of Transport messages

 A set of memory mapped register offers support of multi byte messages TX and
 RX (E.g.IPC_REG_ISH2HOST_MSG, IPC_REG_HOST2ISH_MSG). The IPC layer maintains
 internal queues to sequence messages and send them in order to the FW.
 Optionally the caller can register handler to get notification of completion.
 A door bell mechanism is used in messaging to trigger processing in host and
 client firmware side. When ISH interrupt handler is called, the ISH2HOST
 doorbell register is used by host drivers to determine that the interrupt
 is for ISH.

 Each side has 32 32-bit message registers and a 32-bit doorbell. Doorbell
 register has the following format:
 Bits 0..6: fragment length (7 bits are used)
 Bits 10..13: encapsulated protocol
 Bits 16..19: management command (for IPC management protocol)
 Bit 31: doorbell trigger (signal H/W interrupt to the other side)
 Other bits are reserved, should be 0.

 3.2.2 Transport layer interface

 To abstract HW level IPC communication, a set of callbacks are registered.
 The transport layer uses them to send and receive messages.
 Refer to  struct ishtp_hw_ops for callbacks.

 3.3 ISH Transport layer
 Location: drivers/hid/intel-ish-hid/ishtp/

 3.3.1 A Generic Transport Layer

 The transport layer is a bi-directional protocol, which defines:
 - Set of commands to start, stop, connect, disconnect and flow control
 (ishtp/hbm.h) for details
 - A flow control mechanism to avoid buffer overflows

 This protocol resembles bus messages described in the following document:
 http://www.intel.com/content/dam/www/public/us/en/documents/technical-\
 specifications/dcmi-hi-1-0-spec.pdf "Chapter 7: Bus Message Layer"

 3.3.2 Connection and Flow Control Mechanism

 Each FW client and a protocol is identified by an UUID. In order to communicate
 to a FW client, a connection must be established using connect request and
 response bus messages. If successful, a pair (host_client_id and fw_client_id)
 will identify the connection.

 Once connection is established, peers send each other flow control bus messages
 independently. Every peer may send a message only if it has received a
 flow-control credit before. Once it sent a message, it may not send another one
 before receiving the next flow control credit.
 Either side can send disconnect request bus message to end communication. Also
 the link will be dropped if major FW reset occurs.

 3.3.3 Peer to Peer data transfer

 Peer to Peer data transfer can happen with or without using DMA. Depending on
 the sensor bandwidth requirement DMA can be enabled by using module parameter
 ishtp_use_dma under intel_ishtp.

 Each side (host and FW) manages its DMA transfer memory independently. When an
 ISHTP client from either host or FW side wants to send something, it decides
 whether to send over IPC or over DMA; for each transfer the decision is
 independent. The sending side sends DMA_XFER message when the message is in
 the respective host buffer (TX when host client sends, RX when FW client
 sends). The recipient of DMA message responds with DMA_XFER_ACK, indicating
 the sender that the memory region for that message may be reused.

 DMA initialization is started with host sending DMA_ALLOC_NOTIFY bus message
 (that includes RX buffer) and FW responds with DMA_ALLOC_NOTIFY_ACK.
 Additionally to DMA address communication, this sequence checks capabilities:
 if thw host doesn't support DMA, then it won't send DMA allocation, so FW can't
 send DMA; if FW doesn't support DMA then it won't respond with
 DMA_ALLOC_NOTIFY_ACK, in which case host will not use DMA transfers.
 Here ISH acts as busmaster DMA controller. Hence when host sends DMA_XFER,
 it's request to do host->ISH DMA transfer; when FW sends DMA_XFER, it means
 that it already did DMA and the message resides at host. Thus, DMA_XFER
 and DMA_XFER_ACK act as ownership indicators.

 At initial state all outgoing memory belongs to the sender (TX to host, RX to
 FW), DMA_XFER transfers ownership on the region that contains ISHTP message to
 the receiving side, DMA_XFER_ACK returns ownership to the sender. A sender
 needs not wait for previous DMA_XFER to be ack'ed, and may send another message
 as long as remaining continuous memory in its ownership is enough.
 In principle, multiple DMA_XFER and DMA_XFER_ACK messages may be sent at once
 (up to IPC MTU), thus allowing for interrupt throttling.
 Currently, ISH FW decides to send over DMA if ISHTP message is more than 3 IPC
 fragments and via IPC otherwise.

 3.3.4 Ring Buffers

 When a client initiate a connection, a ring or RX and TX buffers are allocated.
 The size of ring can be specified by the client. HID client set 16 and 32 for
 TX and RX buffers respectively. On send request from client, the data to be
 sent is copied to one of the send ring buffer and scheduled to be sent using
 bus message protocol. These buffers are required because the FW may have not
 have processed the last message and may not have enough flow control credits
 to send. Same thing holds true on receive side and flow control is required.

 3.3.5 Host Enumeration

 The host enumeration bus command allow discovery of clients present in the FW.
 There can be multiple sensor clients and clients for calibration function.

 To ease in implantation and allow independent driver handle each client
 this transport layer takes advantage of Linux Bus driver model. Each
 client is registered as device on the the transport bus (ishtp bus).

 Enumeration sequence of messages:
 - Host sends HOST_START_REQ_CMD, indicating that host ISHTP layer is up.
 - FW responds with HOST_START_RES_CMD
 - Host sends HOST_ENUM_REQ_CMD (enumerate FW clients)
 - FW responds with HOST_ENUM_RES_CMD that includes bitmap of available FW
 client IDs
 - For each FW ID found in that bitmap host sends
 HOST_CLIENT_PROPERTIES_REQ_CMD
 - FW responds with HOST_CLIENT_PROPERTIES_RES_CMD. Properties include UUID,
 max ISHTP message size, etc.
 - Once host received properties for that last discovered client, it considers
 ISHTP device fully functional (and allocates DMA buffers)

 3.4 HID over ISH Client
 Location: drivers/hid/intel-ish-hid

 The ISHTP client driver is responsible for:
 - enumerate HID devices under FW ISH client
 - Get Report descriptor
 - Register with HID core as a LL driver
 - Process Get/Set feature request
 - Get input reports

 3.5 HID Sensor Hub MFD and IIO sensor drivers

 The functionality in these drivers is the same as an external sensor hub.
 Refer to
 Documentation/hid/hid-sensor.txt for HID sensor
 Documentation/ABI/testing/sysfs-bus-iio for IIO ABIs to user space

 3.6 End to End HID transport Sequence Diagram

 HID-ISH-CLN			ISHTP			IPC				HW
 	|			|			|				|
 	|			|			|-----WAKE UP------------------>|
 	|			|			|				|
 	|			|			|-----HOST READY--------------->|
 	|			|			|				|
 	|			|			|<----MNG_RESET_NOTIFY_ACK----- |
 	|			|			|				|
 	|			|<----ISHTP_START------ |				|
 	|			|			|				|
 	|			|<-----------------HOST_START_RES_CMD-------------------|
 	|			|			|				|
 	|			|------------------QUERY_SUBSCRIBER-------------------->|
 	|			|			|				|
 	|			|------------------HOST_ENUM_REQ_CMD------------------->|
 	|			|			|				|
 	|			|<-----------------HOST_ENUM_RES_CMD--------------------|
 	|			|			|				|
 	|			|------------------HOST_CLIENT_PROPERTIES_REQ_CMD------>|
 	|			|			|				|
 	|			|<-----------------HOST_CLIENT_PROPERTIES_RES_CMD-------|
 	|	Create new device on in ishtp bus	|				|
 	|			|			|				|
 	|			|------------------HOST_CLIENT_PROPERTIES_REQ_CMD------>|
 	|			|			|				|
 	|			|<-----------------HOST_CLIENT_PROPERTIES_RES_CMD-------|
 	|	Create new device on in ishtp bus	|				|
 	|			|			|				|
 	|			|--Repeat HOST_CLIENT_PROPERTIES_REQ_CMD-till last one--|
 	|			|			|				|
      probed()
 	|----ishtp_cl_connect-->|----------------- CLIENT_CONNECT_REQ_CMD-------------->|
 	|			|			|				|
 	|			|<----------------CLIENT_CONNECT_RES_CMD----------------|
 	|			|			|				|
 	|register event callback|			|				|
 	|			|			|				|
 	|ishtp_cl_send(
 	HOSTIF_DM_ENUM_DEVICES) |----------fill ishtp_msg_hdr struct write to HW-----  >|
 	|			|			|				|
 	|			|			|<-----IRQ(IPC_PROTOCOL_ISHTP---|
 	|			|			|				|
 	|<--ENUM_DEVICE RSP-----|			|				|
 	|			|			|				|
 for each enumerated device
 	|ishtp_cl_send(
 	HOSTIF_GET_HID_DESCRIPTOR |----------fill ishtp_msg_hdr struct write to HW---  >|
 	|			|			|				|
 	...Response
 	|			|			|				|
 for each enumerated device
 	|ishtp_cl_send(
 	HOSTIF_GET_REPORT_DESCRIPTOR |----------fill ishtp_msg_hdr struct write to HW- >|
 	|			|			|				|
 	|			|			|				|
  hid_allocate_device
 	|			|			|				|
  hid_add_device			|			|				|
 	|			|			|				|


 3.7 ISH Debugging

 To debug ISH, event tracing mechanism is used. To enable debug logs
 echo 1 > /sys/kernel/debug/tracing/events/intel_ish/enable
 cat sys/kernel/debug/tracing/trace

 3.8 ISH IIO sysfs Example on Lenovo thinkpad Yoga 260

 root@otcpl-ThinkPad-Yoga-260:~# tree -l /sys/bus/iio/devices/
 /sys/bus/iio/devices/
 ├── iio:device0 -> ../../../devices/0044:8086:22D8.0001/HID-SENSOR-200073.9.auto/iio:device0
 │   ├── buffer
 │   │   ├── enable
 │   │   ├── length
 │   │   └── watermark
 ...
 │   ├── in_accel_hysteresis
 │   ├── in_accel_offset
 │   ├── in_accel_sampling_frequency
 │   ├── in_accel_scale
 │   ├── in_accel_x_raw
 │   ├── in_accel_y_raw
 │   ├── in_accel_z_raw
 │   ├── name
 │   ├── scan_elements
 │   │   ├── in_accel_x_en
 │   │   ├── in_accel_x_index
 │   │   ├── in_accel_x_type
 │   │   ├── in_accel_y_en
 │   │   ├── in_accel_y_index
 │   │   ├── in_accel_y_type
 │   │   ├── in_accel_z_en
 │   │   ├── in_accel_z_index
 │   │   └── in_accel_z_type
 ...
 │   │   ├── devices
 │   │   │   │   ├── buffer
 │   │   │   │   │   ├── enable
 │   │   │   │   │   ├── length
 │   │   │   │   │   └── watermark
 │   │   │   │   ├── dev
 │   │   │   │   ├── in_intensity_both_raw
 │   │   │   │   ├── in_intensity_hysteresis
 │   │   │   │   ├── in_intensity_offset
 │   │   │   │   ├── in_intensity_sampling_frequency
 │   │   │   │   ├── in_intensity_scale
 │   │   │   │   ├── name
 │   │   │   │   ├── scan_elements
 │   │   │   │   │   ├── in_intensity_both_en
 │   │   │   │   │   ├── in_intensity_both_index
 │   │   │   │   │   └── in_intensity_both_type
 │   │   │   │   ├── trigger
 │   │   │   │   │   └── current_trigger
 ...
 │   │   │   │   ├── buffer
 │   │   │   │   │   ├── enable
 │   │   │   │   │   ├── length
 │   │   │   │   │   └── watermark
 │   │   │   │   ├── dev
 │   │   │   │   ├── in_magn_hysteresis
 │   │   │   │   ├── in_magn_offset
 │   │   │   │   ├── in_magn_sampling_frequency
 │   │   │   │   ├── in_magn_scale
 │   │   │   │   ├── in_magn_x_raw
 │   │   │   │   ├── in_magn_y_raw
 │   │   │   │   ├── in_magn_z_raw
 │   │   │   │   ├── in_rot_from_north_magnetic_tilt_comp_raw
 │   │   │   │   ├── in_rot_hysteresis
 │   │   │   │   ├── in_rot_offset
 │   │   │   │   ├── in_rot_sampling_frequency
 │   │   │   │   ├── in_rot_scale
 │   │   │   │   ├── name
 ...
 │   │   │   │   ├── scan_elements
 │   │   │   │   │   ├── in_magn_x_en
 │   │   │   │   │   ├── in_magn_x_index
 │   │   │   │   │   ├── in_magn_x_type
 │   │   │   │   │   ├── in_magn_y_en
 │   │   │   │   │   ├── in_magn_y_index
 │   │   │   │   │   ├── in_magn_y_type
 │   │   │   │   │   ├── in_magn_z_en
 │   │   │   │   │   ├── in_magn_z_index
 │   │   │   │   │   ├── in_magn_z_type
 │   │   │   │   │   ├── in_rot_from_north_magnetic_tilt_comp_en
 │   │   │   │   │   ├── in_rot_from_north_magnetic_tilt_comp_index
 │   │   │   │   │   └── in_rot_from_north_magnetic_tilt_comp_type
 │   │   │   │   ├── trigger
 │   │   │   │   │   └── current_trigger
 ...
 │   │   │   │   ├── buffer
 │   │   │   │   │   ├── enable
 │   │   │   │   │   ├── length
 │   │   │   │   │   └── watermark
 │   │   │   │   ├── dev
 │   │   │   │   ├── in_anglvel_hysteresis
 │   │   │   │   ├── in_anglvel_offset
 │   │   │   │   ├── in_anglvel_sampling_frequency
 │   │   │   │   ├── in_anglvel_scale
 │   │   │   │   ├── in_anglvel_x_raw
 │   │   │   │   ├── in_anglvel_y_raw
 │   │   │   │   ├── in_anglvel_z_raw
 │   │   │   │   ├── name
 │   │   │   │   ├── scan_elements
 │   │   │   │   │   ├── in_anglvel_x_en
 │   │   │   │   │   ├── in_anglvel_x_index
 │   │   │   │   │   ├── in_anglvel_x_type
 │   │   │   │   │   ├── in_anglvel_y_en
 │   │   │   │   │   ├── in_anglvel_y_index
 │   │   │   │   │   ├── in_anglvel_y_type
 │   │   │   │   │   ├── in_anglvel_z_en
 │   │   │   │   │   ├── in_anglvel_z_index
 │   │   │   │   │   └── in_anglvel_z_type
 │   │   │   │   ├── trigger
 │   │   │   │   │   └── current_trigger
 ...
 │   │   │   │   ├── buffer
 │   │   │   │   │   ├── enable
 │   │   │   │   │   ├── length
 │   │   │   │   │   └── watermark
 │   │   │   │   ├── dev
 │   │   │   │   ├── in_anglvel_hysteresis
 │   │   │   │   ├── in_anglvel_offset
 │   │   │   │   ├── in_anglvel_sampling_frequency
 │   │   │   │   ├── in_anglvel_scale
 │   │   │   │   ├── in_anglvel_x_raw
 │   │   │   │   ├── in_anglvel_y_raw
 │   │   │   │   ├── in_anglvel_z_raw
 │   │   │   │   ├── name
 │   │   │   │   ├── scan_elements
 │   │   │   │   │   ├── in_anglvel_x_en
 │   │   │   │   │   ├── in_anglvel_x_index
 │   │   │   │   │   ├── in_anglvel_x_type
 │   │   │   │   │   ├── in_anglvel_y_en
 │   │   │   │   │   ├── in_anglvel_y_index
 │   │   │   │   │   ├── in_anglvel_y_type
 │   │   │   │   │   ├── in_anglvel_z_en
 │   │   │   │   │   ├── in_anglvel_z_index
 │   │   │   │   │   └── in_anglvel_z_type
 │   │   │   │   ├── trigger
 │   │   │   │   │   └── current_trigger
 ...
	Intel Integrated Sensor Hub (ISH)
	===============================

	A sensor hub enables the ability to offload sensor polling and algorithm
	processing to a dedicated low power co-processor. This allows the core
	processor to go into low power modes more often, resulting in the increased
	battery life.

	There are many vendors providing external sensor hubs confirming to HID
	Sensor usage tables, and used in several tablets, 2 in 1 convertible laptops
	and embedded products. Linux had this support since Linux 3.9.

	Intel® introduced integrated sensor hubs as a part of the SoC starting from
	Cherry Trail and now supported on multiple generations of CPU packages. There
	are many commercial devices already shipped with Integrated Sensor Hubs (ISH).
	These ISH also comply to HID sensor specification, but the difference is the
	transport protocol used for communication. The current external sensor hubs
	mainly use HID over i2C or USB. But ISH doesn't use either i2c or USB.

	1. Overview

	Using a analogy with a usbhid implementation, the ISH follows a similar model
	for a very high speed communication:

	----------------- ----------------------
	\| USB HID \| --> \| ISH HID \|
	----------------- ----------------------
	----------------- ----------------------
	\| USB protocol \| --> \| ISH Transport \|
	----------------- ----------------------
	----------------- ----------------------
	\| EHCI/XHCI \| --> \| ISH IPC \|
	----------------- ----------------------
	PCI PCI
	----------------- ----------------------
	\|Host controller\| --> \| ISH processor \|
	----------------- ----------------------
	USB Link
	----------------- ----------------------
	\| USB End points\| --> \| ISH Clients \|
	----------------- ----------------------

	Like USB protocol provides a method for device enumeration, link management
	and user data encapsulation, the ISH also provides similar services. But it is
	very light weight tailored to manage and communicate with ISH client
	applications implemented in the firmware.

	The ISH allows multiple sensor management applications executing in the
	firmware. Like USB endpoints the messaging can be to/from a client. As part of
	enumeration process, these clients are identified. These clients can be simple
	HID sensor applications, sensor calibration application or senor firmware
	update application.

	The implementation model is similar, like USB bus, ISH transport is also
	implemented as a bus. Each client application executing in the ISH processor
	is registered as a device on this bus. The driver, which binds each device
	(ISH HID driver) identifies the device type and registers with the hid core.

	2. ISH Implementation: Block Diagram

	---------------------------
	\| User Space Applications \|
	---------------------------

	----------------IIO ABI----------------
	--------------------------
	\| IIO Sensor Drivers \|
	--------------------------
	--------------------------
	\| IIO core \|
	--------------------------
	--------------------------
	\| HID Sensor Hub MFD \|
	--------------------------
	--------------------------
	\| HID Core \|
	--------------------------
	--------------------------
	\| HID over ISH Client \|
	--------------------------
	--------------------------
	\| ISH Transport (ISHTP) \|
	--------------------------
	--------------------------
	\| IPC Drivers \|
	--------------------------
	OS
	---------------- PCI -----------------
	Hardware + Firmware
	----------------------------
	\| ISH Hardware/Firmware(FW) \|
	----------------------------

	3. High level processing in above blocks

	3.1 Hardware Interface

	The ISH is exposed as "Non-VGA unclassified PCI device" to the host. The PCI
	product and vendor IDs are changed from different generations of processors. So
	the source code which enumerate drivers needs to update from generation to
	generation.

	3.2 Inter Processor Communication (IPC) driver
	Location: drivers/hid/intel-ish-hid/ipc

	The IPC message used memory mapped I/O. The registers are defined in
	hw-ish-regs.h.

	3.2.1 IPC/FW message types

	There are two types of messages, one for management of link and other messages
	are to and from transport layers.

	TX and RX of Transport messages

	A set of memory mapped register offers support of multi byte messages TX and
	RX (E.g.IPC_REG_ISH2HOST_MSG, IPC_REG_HOST2ISH_MSG). The IPC layer maintains
	internal queues to sequence messages and send them in order to the FW.
	Optionally the caller can register handler to get notification of completion.
	A door bell mechanism is used in messaging to trigger processing in host and
	client firmware side. When ISH interrupt handler is called, the ISH2HOST
	doorbell register is used by host drivers to determine that the interrupt
	is for ISH.

	Each side has 32 32-bit message registers and a 32-bit doorbell. Doorbell
	register has the following format:
	Bits 0..6: fragment length (7 bits are used)
	Bits 10..13: encapsulated protocol
	Bits 16..19: management command (for IPC management protocol)
	Bit 31: doorbell trigger (signal H/W interrupt to the other side)
	Other bits are reserved, should be 0.

	3.2.2 Transport layer interface

	To abstract HW level IPC communication, a set of callbacks are registered.
	The transport layer uses them to send and receive messages.
	Refer to struct ishtp_hw_ops for callbacks.

	3.3 ISH Transport layer
	Location: drivers/hid/intel-ish-hid/ishtp/

	3.3.1 A Generic Transport Layer

	The transport layer is a bi-directional protocol, which defines:
	- Set of commands to start, stop, connect, disconnect and flow control
	(ishtp/hbm.h) for details
	- A flow control mechanism to avoid buffer overflows

	This protocol resembles bus messages described in the following document:
	http://www.intel.com/content/dam/www/public/us/en/documents/technical-\
	specifications/dcmi-hi-1-0-spec.pdf "Chapter 7: Bus Message Layer"

	3.3.2 Connection and Flow Control Mechanism

	Each FW client and a protocol is identified by an UUID. In order to communicate
	to a FW client, a connection must be established using connect request and
	response bus messages. If successful, a pair (host_client_id and fw_client_id)
	will identify the connection.

	Once connection is established, peers send each other flow control bus messages
	independently. Every peer may send a message only if it has received a
	flow-control credit before. Once it sent a message, it may not send another one
	before receiving the next flow control credit.
	Either side can send disconnect request bus message to end communication. Also
	the link will be dropped if major FW reset occurs.

	3.3.3 Peer to Peer data transfer

	Peer to Peer data transfer can happen with or without using DMA. Depending on
	the sensor bandwidth requirement DMA can be enabled by using module parameter
	ishtp_use_dma under intel_ishtp.

	Each side (host and FW) manages its DMA transfer memory independently. When an
	ISHTP client from either host or FW side wants to send something, it decides
	whether to send over IPC or over DMA; for each transfer the decision is
	independent. The sending side sends DMA_XFER message when the message is in
	the respective host buffer (TX when host client sends, RX when FW client
	sends). The recipient of DMA message responds with DMA_XFER_ACK, indicating
	the sender that the memory region for that message may be reused.

	DMA initialization is started with host sending DMA_ALLOC_NOTIFY bus message
	(that includes RX buffer) and FW responds with DMA_ALLOC_NOTIFY_ACK.
	Additionally to DMA address communication, this sequence checks capabilities:
	if thw host doesn't support DMA, then it won't send DMA allocation, so FW can't
	send DMA; if FW doesn't support DMA then it won't respond with
	DMA_ALLOC_NOTIFY_ACK, in which case host will not use DMA transfers.
	Here ISH acts as busmaster DMA controller. Hence when host sends DMA_XFER,
	it's request to do host->ISH DMA transfer; when FW sends DMA_XFER, it means
	that it already did DMA and the message resides at host. Thus, DMA_XFER
	and DMA_XFER_ACK act as ownership indicators.

	At initial state all outgoing memory belongs to the sender (TX to host, RX to
	FW), DMA_XFER transfers ownership on the region that contains ISHTP message to
	the receiving side, DMA_XFER_ACK returns ownership to the sender. A sender
	needs not wait for previous DMA_XFER to be ack'ed, and may send another message
	as long as remaining continuous memory in its ownership is enough.
	In principle, multiple DMA_XFER and DMA_XFER_ACK messages may be sent at once
	(up to IPC MTU), thus allowing for interrupt throttling.
	Currently, ISH FW decides to send over DMA if ISHTP message is more than 3 IPC
	fragments and via IPC otherwise.

	3.3.4 Ring Buffers

	When a client initiate a connection, a ring or RX and TX buffers are allocated.
	The size of ring can be specified by the client. HID client set 16 and 32 for
	TX and RX buffers respectively. On send request from client, the data to be
	sent is copied to one of the send ring buffer and scheduled to be sent using
	bus message protocol. These buffers are required because the FW may have not
	have processed the last message and may not have enough flow control credits
	to send. Same thing holds true on receive side and flow control is required.

	3.3.5 Host Enumeration

	The host enumeration bus command allow discovery of clients present in the FW.
	There can be multiple sensor clients and clients for calibration function.

	To ease in implantation and allow independent driver handle each client
	this transport layer takes advantage of Linux Bus driver model. Each
	client is registered as device on the the transport bus (ishtp bus).

	Enumeration sequence of messages:
	- Host sends HOST_START_REQ_CMD, indicating that host ISHTP layer is up.
	- FW responds with HOST_START_RES_CMD
	- Host sends HOST_ENUM_REQ_CMD (enumerate FW clients)
	- FW responds with HOST_ENUM_RES_CMD that includes bitmap of available FW
	client IDs
	- For each FW ID found in that bitmap host sends
	HOST_CLIENT_PROPERTIES_REQ_CMD
	- FW responds with HOST_CLIENT_PROPERTIES_RES_CMD. Properties include UUID,
	max ISHTP message size, etc.
	- Once host received properties for that last discovered client, it considers
	ISHTP device fully functional (and allocates DMA buffers)

	3.4 HID over ISH Client
	Location: drivers/hid/intel-ish-hid

	The ISHTP client driver is responsible for:
	- enumerate HID devices under FW ISH client
	- Get Report descriptor
	- Register with HID core as a LL driver
	- Process Get/Set feature request
	- Get input reports

	3.5 HID Sensor Hub MFD and IIO sensor drivers

	The functionality in these drivers is the same as an external sensor hub.
	Refer to
	Documentation/hid/hid-sensor.txt for HID sensor
	Documentation/ABI/testing/sysfs-bus-iio for IIO ABIs to user space

	3.6 End to End HID transport Sequence Diagram

	HID-ISH-CLN ISHTP IPC HW
	\| \| \| \|
	\| \| \|-----WAKE UP------------------>\|
	\| \| \| \|
	\| \| \|-----HOST READY--------------->\|
	\| \| \| \|
	\| \| \|<----MNG_RESET_NOTIFY_ACK----- \|
	\| \| \| \|
	\| \|<----ISHTP_START------ \| \|
	\| \| \| \|
	\| \|<-----------------HOST_START_RES_CMD-------------------\|
	\| \| \| \|
	\| \|------------------QUERY_SUBSCRIBER-------------------->\|
	\| \| \| \|
	\| \|------------------HOST_ENUM_REQ_CMD------------------->\|
	\| \| \| \|
	\| \|<-----------------HOST_ENUM_RES_CMD--------------------\|
	\| \| \| \|
	\| \|------------------HOST_CLIENT_PROPERTIES_REQ_CMD------>\|
	\| \| \| \|
	\| \|<-----------------HOST_CLIENT_PROPERTIES_RES_CMD-------\|
	\| Create new device on in ishtp bus \| \|
	\| \| \| \|
	\| \|------------------HOST_CLIENT_PROPERTIES_REQ_CMD------>\|
	\| \| \| \|
	\| \|<-----------------HOST_CLIENT_PROPERTIES_RES_CMD-------\|
	\| Create new device on in ishtp bus \| \|
	\| \| \| \|
	\| \|--Repeat HOST_CLIENT_PROPERTIES_REQ_CMD-till last one--\|
	\| \| \| \|
	probed()
	\|----ishtp_cl_connect-->\|----------------- CLIENT_CONNECT_REQ_CMD-------------->\|
	\| \| \| \|
	\| \|<----------------CLIENT_CONNECT_RES_CMD----------------\|
	\| \| \| \|
	\|register event callback\| \| \|
	\| \| \| \|
	\|ishtp_cl_send(
	HOSTIF_DM_ENUM_DEVICES) \|----------fill ishtp_msg_hdr struct write to HW----- >\|
	\| \| \| \|
	\| \| \|<-----IRQ(IPC_PROTOCOL_ISHTP---\|
	\| \| \| \|
	\|<--ENUM_DEVICE RSP-----\| \| \|
	\| \| \| \|
	for each enumerated device
	\|ishtp_cl_send(
	HOSTIF_GET_HID_DESCRIPTOR \|----------fill ishtp_msg_hdr struct write to HW--- >\|
	\| \| \| \|
	...Response
	\| \| \| \|
	for each enumerated device
	\|ishtp_cl_send(
	HOSTIF_GET_REPORT_DESCRIPTOR \|----------fill ishtp_msg_hdr struct write to HW- >\|
	\| \| \| \|
	\| \| \| \|
	hid_allocate_device
	\| \| \| \|
	hid_add_device \| \| \|
	\| \| \| \|


	3.7 ISH Debugging

	To debug ISH, event tracing mechanism is used. To enable debug logs
	echo 1 > /sys/kernel/debug/tracing/events/intel_ish/enable
	cat sys/kernel/debug/tracing/trace

	3.8 ISH IIO sysfs Example on Lenovo thinkpad Yoga 260

	root@otcpl-ThinkPad-Yoga-260:~# tree -l /sys/bus/iio/devices/
	/sys/bus/iio/devices/
	├── iio:device0 -> ../../../devices/0044:8086:22D8.0001/HID-SENSOR-200073.9.auto/iio:device0
	│ ├── buffer
	│ │ ├── enable
	│ │ ├── length
	│ │ └── watermark
	...
	│ ├── in_accel_hysteresis
	│ ├── in_accel_offset
	│ ├── in_accel_sampling_frequency
	│ ├── in_accel_scale
	│ ├── in_accel_x_raw
	│ ├── in_accel_y_raw
	│ ├── in_accel_z_raw
	│ ├── name
	│ ├── scan_elements
	│ │ ├── in_accel_x_en
	│ │ ├── in_accel_x_index
	│ │ ├── in_accel_x_type
	│ │ ├── in_accel_y_en
	│ │ ├── in_accel_y_index
	│ │ ├── in_accel_y_type
	│ │ ├── in_accel_z_en
	│ │ ├── in_accel_z_index
	│ │ └── in_accel_z_type
	...
	│ │ ├── devices
	│ │ │ │ ├── buffer
	│ │ │ │ │ ├── enable
	│ │ │ │ │ ├── length
	│ │ │ │ │ └── watermark
	│ │ │ │ ├── dev
	│ │ │ │ ├── in_intensity_both_raw
	│ │ │ │ ├── in_intensity_hysteresis
	│ │ │ │ ├── in_intensity_offset
	│ │ │ │ ├── in_intensity_sampling_frequency
	│ │ │ │ ├── in_intensity_scale
	│ │ │ │ ├── name
	│ │ │ │ ├── scan_elements
	│ │ │ │ │ ├── in_intensity_both_en
	│ │ │ │ │ ├── in_intensity_both_index
	│ │ │ │ │ └── in_intensity_both_type
	│ │ │ │ ├── trigger
	│ │ │ │ │ └── current_trigger
	...
	│ │ │ │ ├── buffer
	│ │ │ │ │ ├── enable
	│ │ │ │ │ ├── length
	│ │ │ │ │ └── watermark
	│ │ │ │ ├── dev
	│ │ │ │ ├── in_magn_hysteresis
	│ │ │ │ ├── in_magn_offset
	│ │ │ │ ├── in_magn_sampling_frequency
	│ │ │ │ ├── in_magn_scale
	│ │ │ │ ├── in_magn_x_raw
	│ │ │ │ ├── in_magn_y_raw
	│ │ │ │ ├── in_magn_z_raw
	│ │ │ │ ├── in_rot_from_north_magnetic_tilt_comp_raw
	│ │ │ │ ├── in_rot_hysteresis
	│ │ │ │ ├── in_rot_offset
	│ │ │ │ ├── in_rot_sampling_frequency
	│ │ │ │ ├── in_rot_scale
	│ │ │ │ ├── name
	...
	│ │ │ │ ├── scan_elements
	│ │ │ │ │ ├── in_magn_x_en
	│ │ │ │ │ ├── in_magn_x_index
	│ │ │ │ │ ├── in_magn_x_type
	│ │ │ │ │ ├── in_magn_y_en
	│ │ │ │ │ ├── in_magn_y_index
	│ │ │ │ │ ├── in_magn_y_type
	│ │ │ │ │ ├── in_magn_z_en
	│ │ │ │ │ ├── in_magn_z_index
	│ │ │ │ │ ├── in_magn_z_type
	│ │ │ │ │ ├── in_rot_from_north_magnetic_tilt_comp_en
	│ │ │ │ │ ├── in_rot_from_north_magnetic_tilt_comp_index
	│ │ │ │ │ └── in_rot_from_north_magnetic_tilt_comp_type
	│ │ │ │ ├── trigger
	│ │ │ │ │ └── current_trigger
	...
	│ │ │ │ ├── buffer
	│ │ │ │ │ ├── enable
	│ │ │ │ │ ├── length
	│ │ │ │ │ └── watermark
	│ │ │ │ ├── dev
	│ │ │ │ ├── in_anglvel_hysteresis
	│ │ │ │ ├── in_anglvel_offset
	│ │ │ │ ├── in_anglvel_sampling_frequency
	│ │ │ │ ├── in_anglvel_scale
	│ │ │ │ ├── in_anglvel_x_raw
	│ │ │ │ ├── in_anglvel_y_raw
	│ │ │ │ ├── in_anglvel_z_raw
	│ │ │ │ ├── name
	│ │ │ │ ├── scan_elements
	│ │ │ │ │ ├── in_anglvel_x_en
	│ │ │ │ │ ├── in_anglvel_x_index
	│ │ │ │ │ ├── in_anglvel_x_type
	│ │ │ │ │ ├── in_anglvel_y_en
	│ │ │ │ │ ├── in_anglvel_y_index
	│ │ │ │ │ ├── in_anglvel_y_type
	│ │ │ │ │ ├── in_anglvel_z_en
	│ │ │ │ │ ├── in_anglvel_z_index
	│ │ │ │ │ └── in_anglvel_z_type
	│ │ │ │ ├── trigger
	│ │ │ │ │ └── current_trigger
	...
	│ │ │ │ ├── buffer
	│ │ │ │ │ ├── enable
	│ │ │ │ │ ├── length
	│ │ │ │ │ └── watermark
	│ │ │ │ ├── dev
	│ │ │ │ ├── in_anglvel_hysteresis
	│ │ │ │ ├── in_anglvel_offset
	│ │ │ │ ├── in_anglvel_sampling_frequency
	│ │ │ │ ├── in_anglvel_scale
	│ │ │ │ ├── in_anglvel_x_raw
	│ │ │ │ ├── in_anglvel_y_raw
	│ │ │ │ ├── in_anglvel_z_raw
	│ │ │ │ ├── name
	│ │ │ │ ├── scan_elements
	│ │ │ │ │ ├── in_anglvel_x_en
	│ │ │ │ │ ├── in_anglvel_x_index
	│ │ │ │ │ ├── in_anglvel_x_type
	│ │ │ │ │ ├── in_anglvel_y_en
	│ │ │ │ │ ├── in_anglvel_y_index
	│ │ │ │ │ ├── in_anglvel_y_type
	│ │ │ │ │ ├── in_anglvel_z_en
	│ │ │ │ │ ├── in_anglvel_z_index
	│ │ │ │ │ └── in_anglvel_z_type
	│ │ │ │ ├── trigger
	│ │ │ │ │ └── current_trigger
	...