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Add documentation for the Surface Aggregator subsystem and its client drivers, giving an overview of the subsystem, its use-cases, its internal structure and internal API, as well as its external API for writing client drivers. Signed-off-by: Maximilian Luz <luzmaximilian@gmail.com> Reviewed-by: Hans de Goede <hdegoede@redhat.com> Link: https://lore.kernel.org/r/20201221183959.1186143-8-luzmaximilian@gmail.com Signed-off-by: Hans de Goede <hdegoede@redhat.com>
345 lines
14 KiB
ReStructuredText
345 lines
14 KiB
ReStructuredText
.. SPDX-License-Identifier: GPL-2.0+
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.. |u8| replace:: :c:type:`u8 <u8>`
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.. |u16| replace:: :c:type:`u16 <u16>`
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.. |TYPE| replace:: ``TYPE``
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.. |LEN| replace:: ``LEN``
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.. |SEQ| replace:: ``SEQ``
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.. |SYN| replace:: ``SYN``
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.. |NAK| replace:: ``NAK``
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.. |ACK| replace:: ``ACK``
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.. |DATA| replace:: ``DATA``
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.. |DATA_SEQ| replace:: ``DATA_SEQ``
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.. |DATA_NSQ| replace:: ``DATA_NSQ``
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.. |TC| replace:: ``TC``
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.. |TID| replace:: ``TID``
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.. |IID| replace:: ``IID``
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.. |RQID| replace:: ``RQID``
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.. |CID| replace:: ``CID``
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===========================
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Surface Serial Hub Protocol
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===========================
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The Surface Serial Hub (SSH) is the central communication interface for the
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embedded Surface Aggregator Module controller (SAM or EC), found on newer
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Surface generations. We will refer to this protocol and interface as
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SAM-over-SSH, as opposed to SAM-over-HID for the older generations.
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On Surface devices with SAM-over-SSH, SAM is connected to the host via UART
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and defined in ACPI as device with ID ``MSHW0084``. On these devices,
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significant functionality is provided via SAM, including access to battery
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and power information and events, thermal read-outs and events, and many
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more. For Surface Laptops, keyboard input is handled via HID directed
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through SAM, on the Surface Laptop 3 and Surface Book 3 this also includes
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touchpad input.
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Note that the standard disclaimer for this subsystem also applies to this
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document: All of this has been reverse-engineered and may thus be erroneous
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and/or incomplete.
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All CRCs used in the following are two-byte ``crc_ccitt_false(0xffff, ...)``.
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All multi-byte values are little-endian, there is no implicit padding between
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values.
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SSH Packet Protocol: Definitions
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================================
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The fundamental communication unit of the SSH protocol is a frame
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(:c:type:`struct ssh_frame <ssh_frame>`). A frame consists of the following
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fields, packed together and in order:
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.. flat-table:: SSH Frame
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:widths: 1 1 4
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:header-rows: 1
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* - Field
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- Type
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- Description
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* - |TYPE|
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- |u8|
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- Type identifier of the frame.
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* - |LEN|
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- |u16|
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- Length of the payload associated with the frame.
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* - |SEQ|
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- |u8|
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- Sequence ID (see explanation below).
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Each frame structure is followed by a CRC over this structure. The CRC over
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the frame structure (|TYPE|, |LEN|, and |SEQ| fields) is placed directly
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after the frame structure and before the payload. The payload is followed by
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its own CRC (over all payload bytes). If the payload is not present (i.e.
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the frame has ``LEN=0``), the CRC of the payload is still present and will
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evaluate to ``0xffff``. The |LEN| field does not include any of the CRCs, it
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equals the number of bytes inbetween the CRC of the frame and the CRC of the
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payload.
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Additionally, the following fixed two-byte sequences are used:
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.. flat-table:: SSH Byte Sequences
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:widths: 1 1 4
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:header-rows: 1
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* - Name
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- Value
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- Description
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* - |SYN|
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- ``[0xAA, 0x55]``
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- Synchronization bytes.
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A message consists of |SYN|, followed by the frame (|TYPE|, |LEN|, |SEQ| and
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CRC) and, if specified in the frame (i.e. ``LEN > 0``), payload bytes,
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followed finally, regardless if the payload is present, the payload CRC. The
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messages corresponding to an exchange are, in part, identified by having the
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same sequence ID (|SEQ|), stored inside the frame (more on this in the next
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section). The sequence ID is a wrapping counter.
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A frame can have the following types
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(:c:type:`enum ssh_frame_type <ssh_frame_type>`):
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.. flat-table:: SSH Frame Types
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:widths: 1 1 4
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:header-rows: 1
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* - Name
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- Value
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- Short Description
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* - |NAK|
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- ``0x04``
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- Sent on error in previously received message.
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* - |ACK|
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- ``0x40``
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- Sent to acknowledge receival of |DATA| frame.
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* - |DATA_SEQ|
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- ``0x80``
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- Sent to transfer data. Sequenced.
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* - |DATA_NSQ|
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- ``0x00``
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- Same as |DATA_SEQ|, but does not need to be ACKed.
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Both |NAK|- and |ACK|-type frames are used to control flow of messages and
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thus do not carry a payload. |DATA_SEQ|- and |DATA_NSQ|-type frames on the
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other hand must carry a payload. The flow sequence and interaction of
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different frame types will be described in more depth in the next section.
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SSH Packet Protocol: Flow Sequence
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==================================
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Each exchange begins with |SYN|, followed by a |DATA_SEQ|- or
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|DATA_NSQ|-type frame, followed by its CRC, payload, and payload CRC. In
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case of a |DATA_NSQ|-type frame, the exchange is then finished. In case of a
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|DATA_SEQ|-type frame, the receiving party has to acknowledge receival of
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the frame by responding with a message containing an |ACK|-type frame with
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the same sequence ID of the |DATA| frame. In other words, the sequence ID of
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the |ACK| frame specifies the |DATA| frame to be acknowledged. In case of an
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error, e.g. an invalid CRC, the receiving party responds with a message
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containing an |NAK|-type frame. As the sequence ID of the previous data
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frame, for which an error is indicated via the |NAK| frame, cannot be relied
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upon, the sequence ID of the |NAK| frame should not be used and is set to
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zero. After receival of an |NAK| frame, the sending party should re-send all
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outstanding (non-ACKed) messages.
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Sequence IDs are not synchronized between the two parties, meaning that they
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are managed independently for each party. Identifying the messages
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corresponding to a single exchange thus relies on the sequence ID as well as
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the type of the message, and the context. Specifically, the sequence ID is
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used to associate an ``ACK`` with its ``DATA_SEQ``-type frame, but not
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``DATA_SEQ``- or ``DATA_NSQ``-type frames with other ``DATA``- type frames.
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An example exchange might look like this:
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::
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tx: -- SYN FRAME(D) CRC(F) PAYLOAD CRC(P) -----------------------------
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rx: ------------------------------------- SYN FRAME(A) CRC(F) CRC(P) --
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where both frames have the same sequence ID (``SEQ``). Here, ``FRAME(D)``
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indicates a |DATA_SEQ|-type frame, ``FRAME(A)`` an ``ACK``-type frame,
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``CRC(F)`` the CRC over the previous frame, ``CRC(P)`` the CRC over the
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previous payload. In case of an error, the exchange would look like this:
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::
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tx: -- SYN FRAME(D) CRC(F) PAYLOAD CRC(P) -----------------------------
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rx: ------------------------------------- SYN FRAME(N) CRC(F) CRC(P) --
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upon which the sender should re-send the message. ``FRAME(N)`` indicates an
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|NAK|-type frame. Note that the sequence ID of the |NAK|-type frame is fixed
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to zero. For |DATA_NSQ|-type frames, both exchanges are the same:
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::
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tx: -- SYN FRAME(DATA_NSQ) CRC(F) PAYLOAD CRC(P) ----------------------
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rx: -------------------------------------------------------------------
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Here, an error can be detected, but not corrected or indicated to the
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sending party. These exchanges are symmetric, i.e. switching ``rx`` and
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``tx`` results again in a valid exchange. Currently, no longer exchanges are
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known.
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Commands: Requests, Responses, and Events
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=========================================
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Commands are sent as payload inside a data frame. Currently, this is the
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only known payload type of |DATA| frames, with a payload-type value of
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``0x80`` (:c:type:`SSH_PLD_TYPE_CMD <ssh_payload_type>`).
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The command-type payload (:c:type:`struct ssh_command <ssh_command>`)
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consists of an eight-byte command structure, followed by optional and
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variable length command data. The length of this optional data is derived
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from the frame payload length given in the corresponding frame, i.e. it is
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``frame.len - sizeof(struct ssh_command)``. The command struct contains the
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following fields, packed together and in order:
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.. flat-table:: SSH Command
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:widths: 1 1 4
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:header-rows: 1
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* - Field
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- Type
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- Description
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* - |TYPE|
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- |u8|
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- Type of the payload. For commands always ``0x80``.
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* - |TC|
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- |u8|
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- Target category.
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* - |TID| (out)
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- |u8|
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- Target ID for outgoing (host to EC) commands.
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* - |TID| (in)
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- |u8|
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- Target ID for incoming (EC to host) commands.
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* - |IID|
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- |u8|
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- Instance ID.
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* - |RQID|
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- |u16|
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- Request ID.
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* - |CID|
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- |u8|
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- Command ID.
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The command struct and data, in general, does not contain any failure
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detection mechanism (e.g. CRCs), this is solely done on the frame level.
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Command-type payloads are used by the host to send commands and requests to
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the EC as well as by the EC to send responses and events back to the host.
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We differentiate between requests (sent by the host), responses (sent by the
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EC in response to a request), and events (sent by the EC without a preceding
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request).
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Commands and events are uniquely identified by their target category
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(``TC``) and command ID (``CID``). The target category specifies a general
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category for the command (e.g. system in general, vs. battery and AC, vs.
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temperature, and so on), while the command ID specifies the command inside
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that category. Only the combination of |TC| + |CID| is unique. Additionally,
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commands have an instance ID (``IID``), which is used to differentiate
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between different sub-devices. For example ``TC=3`` ``CID=1`` is a
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request to get the temperature on a thermal sensor, where |IID| specifies
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the respective sensor. If the instance ID is not used, it should be set to
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zero. If instance IDs are used, they, in general, start with a value of one,
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whereas zero may be used for instance independent queries, if applicable. A
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response to a request should have the same target category, command ID, and
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instance ID as the corresponding request.
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Responses are matched to their corresponding request via the request ID
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(``RQID``) field. This is a 16 bit wrapping counter similar to the sequence
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ID on the frames. Note that the sequence ID of the frames for a
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request-response pair does not match. Only the request ID has to match.
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Frame-protocol wise these are two separate exchanges, and may even be
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separated, e.g. by an event being sent after the request but before the
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response. Not all commands produce a response, and this is not detectable by
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|TC| + |CID|. It is the responsibility of the issuing party to wait for a
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response (or signal this to the communication framework, as is done in
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SAN/ACPI via the ``SNC`` flag).
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Events are identified by unique and reserved request IDs. These IDs should
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not be used by the host when sending a new request. They are used on the
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host to, first, detect events and, second, match them with a registered
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event handler. Request IDs for events are chosen by the host and directed to
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the EC when setting up and enabling an event source (via the
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enable-event-source request). The EC then uses the specified request ID for
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events sent from the respective source. Note that an event should still be
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identified by its target category, command ID, and, if applicable, instance
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ID, as a single event source can send multiple different event types. In
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general, however, a single target category should map to a single reserved
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event request ID.
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Furthermore, requests, responses, and events have an associated target ID
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(``TID``). This target ID is split into output (host to EC) and input (EC to
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host) fields, with the respecting other field (e.g. output field on incoming
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messages) set to zero. Two ``TID`` values are known: Primary (``0x01``) and
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secondary (``0x02``). In general, the response to a request should have the
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same ``TID`` value, however, the field (output vs. input) should be used in
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accordance to the direction in which the response is sent (i.e. on the input
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field, as responses are generally sent from the EC to the host).
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Note that, even though requests and events should be uniquely identifiable
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by target category and command ID alone, the EC may require specific
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target ID and instance ID values to accept a command. A command that is
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accepted for ``TID=1``, for example, may not be accepted for ``TID=2``
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and vice versa.
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Limitations and Observations
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============================
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The protocol can, in theory, handle up to ``U8_MAX`` frames in parallel,
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with up to ``U16_MAX`` pending requests (neglecting request IDs reserved for
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events). In practice, however, this is more limited. From our testing
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(although via a python and thus a user-space program), it seems that the EC
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can handle up to four requests (mostly) reliably in parallel at a certain
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time. With five or more requests in parallel, consistent discarding of
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commands (ACKed frame but no command response) has been observed. For five
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simultaneous commands, this reproducibly resulted in one command being
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dropped and four commands being handled.
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However, it has also been noted that, even with three requests in parallel,
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occasional frame drops happen. Apart from this, with a limit of three
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pending requests, no dropped commands (i.e. command being dropped but frame
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carrying command being ACKed) have been observed. In any case, frames (and
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possibly also commands) should be re-sent by the host if a certain timeout
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is exceeded. This is done by the EC for frames with a timeout of one second,
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up to two re-tries (i.e. three transmissions in total). The limit of
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re-tries also applies to received NAKs, and, in a worst case scenario, can
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lead to entire messages being dropped.
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While this also seems to work fine for pending data frames as long as no
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transmission failures occur, implementation and handling of these seems to
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depend on the assumption that there is only one non-acknowledged data frame.
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In particular, the detection of repeated frames relies on the last sequence
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number. This means that, if a frame that has been successfully received by
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the EC is sent again, e.g. due to the host not receiving an |ACK|, the EC
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will only detect this if it has the sequence ID of the last frame received
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by the EC. As an example: Sending two frames with ``SEQ=0`` and ``SEQ=1``
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followed by a repetition of ``SEQ=0`` will not detect the second ``SEQ=0``
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frame as such, and thus execute the command in this frame each time it has
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been received, i.e. twice in this example. Sending ``SEQ=0``, ``SEQ=1`` and
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then repeating ``SEQ=1`` will detect the second ``SEQ=1`` as repetition of
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the first one and ignore it, thus executing the contained command only once.
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In conclusion, this suggests a limit of at most one pending un-ACKed frame
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(per party, effectively leading to synchronous communication regarding
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frames) and at most three pending commands. The limit to synchronous frame
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transfers seems to be consistent with behavior observed on Windows.
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