mirror of https://gitee.com/openkylin/linux.git
578 lines
29 KiB
ReStructuredText
578 lines
29 KiB
ReStructuredText
.. SPDX-License-Identifier: GPL-2.0+
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.. |ssh_ptl| replace:: :c:type:`struct ssh_ptl <ssh_ptl>`
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.. |ssh_ptl_submit| replace:: :c:func:`ssh_ptl_submit`
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.. |ssh_ptl_cancel| replace:: :c:func:`ssh_ptl_cancel`
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.. |ssh_ptl_shutdown| replace:: :c:func:`ssh_ptl_shutdown`
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.. |ssh_ptl_rx_rcvbuf| replace:: :c:func:`ssh_ptl_rx_rcvbuf`
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.. |ssh_rtl| replace:: :c:type:`struct ssh_rtl <ssh_rtl>`
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.. |ssh_rtl_submit| replace:: :c:func:`ssh_rtl_submit`
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.. |ssh_rtl_cancel| replace:: :c:func:`ssh_rtl_cancel`
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.. |ssh_rtl_shutdown| replace:: :c:func:`ssh_rtl_shutdown`
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.. |ssh_packet| replace:: :c:type:`struct ssh_packet <ssh_packet>`
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.. |ssh_packet_get| replace:: :c:func:`ssh_packet_get`
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.. |ssh_packet_put| replace:: :c:func:`ssh_packet_put`
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.. |ssh_packet_ops| replace:: :c:type:`struct ssh_packet_ops <ssh_packet_ops>`
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.. |ssh_packet_base_priority| replace:: :c:type:`enum ssh_packet_base_priority <ssh_packet_base_priority>`
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.. |ssh_packet_flags| replace:: :c:type:`enum ssh_packet_flags <ssh_packet_flags>`
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.. |SSH_PACKET_PRIORITY| replace:: :c:func:`SSH_PACKET_PRIORITY`
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.. |ssh_frame| replace:: :c:type:`struct ssh_frame <ssh_frame>`
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.. |ssh_command| replace:: :c:type:`struct ssh_command <ssh_command>`
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.. |ssh_request| replace:: :c:type:`struct ssh_request <ssh_request>`
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.. |ssh_request_get| replace:: :c:func:`ssh_request_get`
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.. |ssh_request_put| replace:: :c:func:`ssh_request_put`
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.. |ssh_request_ops| replace:: :c:type:`struct ssh_request_ops <ssh_request_ops>`
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.. |ssh_request_init| replace:: :c:func:`ssh_request_init`
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.. |ssh_request_flags| replace:: :c:type:`enum ssh_request_flags <ssh_request_flags>`
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.. |ssam_controller| replace:: :c:type:`struct ssam_controller <ssam_controller>`
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.. |ssam_device| replace:: :c:type:`struct ssam_device <ssam_device>`
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.. |ssam_device_driver| replace:: :c:type:`struct ssam_device_driver <ssam_device_driver>`
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.. |ssam_client_bind| replace:: :c:func:`ssam_client_bind`
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.. |ssam_client_link| replace:: :c:func:`ssam_client_link`
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.. |ssam_request_sync| replace:: :c:type:`struct ssam_request_sync <ssam_request_sync>`
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.. |ssam_event_registry| replace:: :c:type:`struct ssam_event_registry <ssam_event_registry>`
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.. |ssam_event_id| replace:: :c:type:`struct ssam_event_id <ssam_event_id>`
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.. |ssam_nf| replace:: :c:type:`struct ssam_nf <ssam_nf>`
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.. |ssam_nf_refcount_inc| replace:: :c:func:`ssam_nf_refcount_inc`
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.. |ssam_nf_refcount_dec| replace:: :c:func:`ssam_nf_refcount_dec`
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.. |ssam_notifier_register| replace:: :c:func:`ssam_notifier_register`
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.. |ssam_notifier_unregister| replace:: :c:func:`ssam_notifier_unregister`
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.. |ssam_cplt| replace:: :c:type:`struct ssam_cplt <ssam_cplt>`
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.. |ssam_event_queue| replace:: :c:type:`struct ssam_event_queue <ssam_event_queue>`
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.. |ssam_request_sync_submit| replace:: :c:func:`ssam_request_sync_submit`
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=====================
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Core Driver Internals
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=====================
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Architectural overview of the Surface System Aggregator Module (SSAM) core
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and Surface Serial Hub (SSH) driver. For the API documentation, refer to:
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.. toctree::
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:maxdepth: 2
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internal-api
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Overview
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========
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The SSAM core implementation is structured in layers, somewhat following the
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SSH protocol structure:
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Lower-level packet transport is implemented in the *packet transport layer
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(PTL)*, directly building on top of the serial device (serdev)
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infrastructure of the kernel. As the name indicates, this layer deals with
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the packet transport logic and handles things like packet validation, packet
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acknowledgment (ACKing), packet (retransmission) timeouts, and relaying
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packet payloads to higher-level layers.
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Above this sits the *request transport layer (RTL)*. This layer is centered
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around command-type packet payloads, i.e. requests (sent from host to EC),
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responses of the EC to those requests, and events (sent from EC to host).
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It, specifically, distinguishes events from request responses, matches
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responses to their corresponding requests, and implements request timeouts.
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The *controller* layer is building on top of this and essentially decides
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how request responses and, especially, events are dealt with. It provides an
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event notifier system, handles event activation/deactivation, provides a
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workqueue for event and asynchronous request completion, and also manages
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the message counters required for building command messages (``SEQ``,
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``RQID``). This layer basically provides a fundamental interface to the SAM
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EC for use in other kernel drivers.
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While the controller layer already provides an interface for other kernel
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drivers, the client *bus* extends this interface to provide support for
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native SSAM devices, i.e. devices that are not defined in ACPI and not
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implemented as platform devices, via |ssam_device| and |ssam_device_driver|
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simplify management of client devices and client drivers.
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Refer to :doc:`client` for documentation regarding the client device/driver
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API and interface options for other kernel drivers. It is recommended to
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familiarize oneself with that chapter and the :doc:`ssh` before continuing
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with the architectural overview below.
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Packet Transport Layer
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======================
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The packet transport layer is represented via |ssh_ptl| and is structured
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around the following key concepts:
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Packets
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-------
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Packets are the fundamental transmission unit of the SSH protocol. They are
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managed by the packet transport layer, which is essentially the lowest layer
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of the driver and is built upon by other components of the SSAM core.
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Packets to be transmitted by the SSAM core are represented via |ssh_packet|
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(in contrast, packets received by the core do not have any specific
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structure and are managed entirely via the raw |ssh_frame|).
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This structure contains the required fields to manage the packet inside the
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transport layer, as well as a reference to the buffer containing the data to
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be transmitted (i.e. the message wrapped in |ssh_frame|). Most notably, it
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contains an internal reference count, which is used for managing its
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lifetime (accessible via |ssh_packet_get| and |ssh_packet_put|). When this
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counter reaches zero, the ``release()`` callback provided to the packet via
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its |ssh_packet_ops| reference is executed, which may then deallocate the
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packet or its enclosing structure (e.g. |ssh_request|).
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In addition to the ``release`` callback, the |ssh_packet_ops| reference also
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provides a ``complete()`` callback, which is run once the packet has been
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completed and provides the status of this completion, i.e. zero on success
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or a negative errno value in case of an error. Once the packet has been
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submitted to the packet transport layer, the ``complete()`` callback is
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always guaranteed to be executed before the ``release()`` callback, i.e. the
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packet will always be completed, either successfully, with an error, or due
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to cancellation, before it will be released.
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The state of a packet is managed via its ``state`` flags
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(|ssh_packet_flags|), which also contains the packet type. In particular,
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the following bits are noteworthy:
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* ``SSH_PACKET_SF_LOCKED_BIT``: This bit is set when completion, either
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through error or success, is imminent. It indicates that no further
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references of the packet should be taken and any existing references
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should be dropped as soon as possible. The process setting this bit is
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responsible for removing any references to this packet from the packet
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queue and pending set.
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* ``SSH_PACKET_SF_COMPLETED_BIT``: This bit is set by the process running the
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``complete()`` callback and is used to ensure that this callback only runs
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once.
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* ``SSH_PACKET_SF_QUEUED_BIT``: This bit is set when the packet is queued on
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the packet queue and cleared when it is dequeued.
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* ``SSH_PACKET_SF_PENDING_BIT``: This bit is set when the packet is added to
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the pending set and cleared when it is removed from it.
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Packet Queue
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------------
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The packet queue is the first of the two fundamental collections in the
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packet transport layer. It is a priority queue, with priority of the
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respective packets based on the packet type (major) and number of tries
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(minor). See |SSH_PACKET_PRIORITY| for more details on the priority value.
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All packets to be transmitted by the transport layer must be submitted to
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this queue via |ssh_ptl_submit|. Note that this includes control packets
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sent by the transport layer itself. Internally, data packets can be
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re-submitted to this queue due to timeouts or NAK packets sent by the EC.
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Pending Set
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-----------
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The pending set is the second of the two fundamental collections in the
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packet transport layer. It stores references to packets that have already
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been transmitted, but wait for acknowledgment (e.g. the corresponding ACK
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packet) by the EC.
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Note that a packet may both be pending and queued if it has been
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re-submitted due to a packet acknowledgment timeout or NAK. On such a
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re-submission, packets are not removed from the pending set.
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Transmitter Thread
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------------------
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The transmitter thread is responsible for most of the actual work regarding
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packet transmission. In each iteration, it (waits for and) checks if the
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next packet on the queue (if any) can be transmitted and, if so, removes it
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from the queue and increments its counter for the number of transmission
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attempts, i.e. tries. If the packet is sequenced, i.e. requires an ACK by
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the EC, the packet is added to the pending set. Next, the packet's data is
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submitted to the serdev subsystem. In case of an error or timeout during
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this submission, the packet is completed by the transmitter thread with the
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status value of the callback set accordingly. In case the packet is
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unsequenced, i.e. does not require an ACK by the EC, the packet is completed
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with success on the transmitter thread.
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Transmission of sequenced packets is limited by the number of concurrently
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pending packets, i.e. a limit on how many packets may be waiting for an ACK
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from the EC in parallel. This limit is currently set to one (see :doc:`ssh`
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for the reasoning behind this). Control packets (i.e. ACK and NAK) can
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always be transmitted.
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Receiver Thread
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---------------
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Any data received from the EC is put into a FIFO buffer for further
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processing. This processing happens on the receiver thread. The receiver
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thread parses and validates the received message into its |ssh_frame| and
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corresponding payload. It prepares and submits the necessary ACK (and on
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validation error or invalid data NAK) packets for the received messages.
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This thread also handles further processing, such as matching ACK messages
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to the corresponding pending packet (via sequence ID) and completing it, as
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well as initiating re-submission of all currently pending packets on
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receival of a NAK message (re-submission in case of a NAK is similar to
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re-submission due to timeout, see below for more details on that). Note that
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the successful completion of a sequenced packet will always run on the
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receiver thread (whereas any failure-indicating completion will run on the
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process where the failure occurred).
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Any payload data is forwarded via a callback to the next upper layer, i.e.
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the request transport layer.
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Timeout Reaper
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--------------
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The packet acknowledgment timeout is a per-packet timeout for sequenced
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packets, started when the respective packet begins (re-)transmission (i.e.
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this timeout is armed once per transmission attempt on the transmitter
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thread). It is used to trigger re-submission or, when the number of tries
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has been exceeded, cancellation of the packet in question.
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This timeout is handled via a dedicated reaper task, which is essentially a
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work item (re-)scheduled to run when the next packet is set to time out. The
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work item then checks the set of pending packets for any packets that have
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exceeded the timeout and, if there are any remaining packets, re-schedules
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itself to the next appropriate point in time.
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If a timeout has been detected by the reaper, the packet will either be
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re-submitted if it still has some remaining tries left, or completed with
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``-ETIMEDOUT`` as status if not. Note that re-submission, in this case and
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triggered by receival of a NAK, means that the packet is added to the queue
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with a now incremented number of tries, yielding a higher priority. The
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timeout for the packet will be disabled until the next transmission attempt
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and the packet remains on the pending set.
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Note that due to transmission and packet acknowledgment timeouts, the packet
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transport layer is always guaranteed to make progress, if only through
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timing out packets, and will never fully block.
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Concurrency and Locking
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-----------------------
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There are two main locks in the packet transport layer: One guarding access
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to the packet queue and one guarding access to the pending set. These
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collections may only be accessed and modified under the respective lock. If
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access to both collections is needed, the pending lock must be acquired
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before the queue lock to avoid deadlocks.
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In addition to guarding the collections, after initial packet submission
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certain packet fields may only be accessed under one of the locks.
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Specifically, the packet priority must only be accessed while holding the
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queue lock and the packet timestamp must only be accessed while holding the
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pending lock.
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Other parts of the packet transport layer are guarded independently. State
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flags are managed by atomic bit operations and, if necessary, memory
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barriers. Modifications to the timeout reaper work item and expiration date
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are guarded by their own lock.
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The reference of the packet to the packet transport layer (``ptl``) is
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somewhat special. It is either set when the upper layer request is submitted
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or, if there is none, when the packet is first submitted. After it is set,
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it will not change its value. Functions that may run concurrently with
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submission, i.e. cancellation, can not rely on the ``ptl`` reference to be
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set. Access to it in these functions is guarded by ``READ_ONCE()``, whereas
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setting ``ptl`` is equally guarded with ``WRITE_ONCE()`` for symmetry.
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Some packet fields may be read outside of the respective locks guarding
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them, specifically priority and state for tracing. In those cases, proper
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access is ensured by employing ``WRITE_ONCE()`` and ``READ_ONCE()``. Such
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read-only access is only allowed when stale values are not critical.
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With respect to the interface for higher layers, packet submission
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(|ssh_ptl_submit|), packet cancellation (|ssh_ptl_cancel|), data receival
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(|ssh_ptl_rx_rcvbuf|), and layer shutdown (|ssh_ptl_shutdown|) may always be
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executed concurrently with respect to each other. Note that packet
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submission may not run concurrently with itself for the same packet.
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Equally, shutdown and data receival may also not run concurrently with
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themselves (but may run concurrently with each other).
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Request Transport Layer
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=======================
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The request transport layer is represented via |ssh_rtl| and builds on top
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of the packet transport layer. It deals with requests, i.e. SSH packets sent
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by the host containing a |ssh_command| as frame payload. This layer
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separates responses to requests from events, which are also sent by the EC
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via a |ssh_command| payload. While responses are handled in this layer,
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events are relayed to the next upper layer, i.e. the controller layer, via
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the corresponding callback. The request transport layer is structured around
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the following key concepts:
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Request
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-------
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Requests are packets with a command-type payload, sent from host to EC to
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query data from or trigger an action on it (or both simultaneously). They
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are represented by |ssh_request|, wrapping the underlying |ssh_packet|
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storing its message data (i.e. SSH frame with command payload). Note that
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all top-level representations, e.g. |ssam_request_sync| are built upon this
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struct.
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As |ssh_request| extends |ssh_packet|, its lifetime is also managed by the
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reference counter inside the packet struct (which can be accessed via
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|ssh_request_get| and |ssh_request_put|). Once the counter reaches zero, the
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``release()`` callback of the |ssh_request_ops| reference of the request is
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called.
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Requests can have an optional response that is equally sent via a SSH
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message with command-type payload (from EC to host). The party constructing
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the request must know if a response is expected and mark this in the request
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flags provided to |ssh_request_init|, so that the request transport layer
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can wait for this response.
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Similar to |ssh_packet|, |ssh_request| also has a ``complete()`` callback
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provided via its request ops reference and is guaranteed to be completed
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before it is released once it has been submitted to the request transport
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layer via |ssh_rtl_submit|. For a request without a response, successful
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completion will occur once the underlying packet has been successfully
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transmitted by the packet transport layer (i.e. from within the packet
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completion callback). For a request with response, successful completion
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will occur once the response has been received and matched to the request
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via its request ID (which happens on the packet layer's data-received
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callback running on the receiver thread). If the request is completed with
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an error, the status value will be set to the corresponding (negative) errno
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value.
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The state of a request is again managed via its ``state`` flags
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(|ssh_request_flags|), which also encode the request type. In particular,
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the following bits are noteworthy:
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* ``SSH_REQUEST_SF_LOCKED_BIT``: This bit is set when completion, either
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through error or success, is imminent. It indicates that no further
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references of the request should be taken and any existing references
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should be dropped as soon as possible. The process setting this bit is
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responsible for removing any references to this request from the request
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queue and pending set.
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* ``SSH_REQUEST_SF_COMPLETED_BIT``: This bit is set by the process running the
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``complete()`` callback and is used to ensure that this callback only runs
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once.
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* ``SSH_REQUEST_SF_QUEUED_BIT``: This bit is set when the request is queued on
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the request queue and cleared when it is dequeued.
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* ``SSH_REQUEST_SF_PENDING_BIT``: This bit is set when the request is added to
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the pending set and cleared when it is removed from it.
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Request Queue
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-------------
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The request queue is the first of the two fundamental collections in the
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request transport layer. In contrast to the packet queue of the packet
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transport layer, it is not a priority queue and the simple first come first
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serve principle applies.
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All requests to be transmitted by the request transport layer must be
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submitted to this queue via |ssh_rtl_submit|. Once submitted, requests may
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not be re-submitted, and will not be re-submitted automatically on timeout.
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Instead, the request is completed with a timeout error. If desired, the
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caller can create and submit a new request for another try, but it must not
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submit the same request again.
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Pending Set
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-----------
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The pending set is the second of the two fundamental collections in the
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request transport layer. This collection stores references to all pending
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requests, i.e. requests awaiting a response from the EC (similar to what the
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pending set of the packet transport layer does for packets).
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Transmitter Task
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----------------
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The transmitter task is scheduled when a new request is available for
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transmission. It checks if the next request on the request queue can be
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transmitted and, if so, submits its underlying packet to the packet
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transport layer. This check ensures that only a limited number of
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requests can be pending, i.e. waiting for a response, at the same time. If
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the request requires a response, the request is added to the pending set
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before its packet is submitted.
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Packet Completion Callback
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--------------------------
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The packet completion callback is executed once the underlying packet of a
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request has been completed. In case of an error completion, the
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corresponding request is completed with the error value provided in this
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callback.
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On successful packet completion, further processing depends on the request.
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If the request expects a response, it is marked as transmitted and the
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request timeout is started. If the request does not expect a response, it is
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completed with success.
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Data-Received Callback
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----------------------
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The data received callback notifies the request transport layer of data
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being received by the underlying packet transport layer via a data-type
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frame. In general, this is expected to be a command-type payload.
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If the request ID of the command is one of the request IDs reserved for
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events (one to ``SSH_NUM_EVENTS``, inclusively), it is forwarded to the
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event callback registered in the request transport layer. If the request ID
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indicates a response to a request, the respective request is looked up in
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the pending set and, if found and marked as transmitted, completed with
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success.
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Timeout Reaper
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--------------
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The request-response-timeout is a per-request timeout for requests expecting
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a response. It is used to ensure that a request does not wait indefinitely
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on a response from the EC and is started after the underlying packet has
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been successfully completed.
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This timeout is, similar to the packet acknowledgment timeout on the packet
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|
transport layer, handled via a dedicated reaper task. This task is
|
|
essentially a work-item (re-)scheduled to run when the next request is set
|
|
to time out. The work item then scans the set of pending requests for any
|
|
requests that have timed out and completes them with ``-ETIMEDOUT`` as
|
|
status. Requests will not be re-submitted automatically. Instead, the issuer
|
|
of the request must construct and submit a new request, if so desired.
|
|
|
|
Note that this timeout, in combination with packet transmission and
|
|
acknowledgment timeouts, guarantees that the request layer will always make
|
|
progress, even if only through timing out packets, and never fully block.
|
|
|
|
Concurrency and Locking
|
|
-----------------------
|
|
|
|
Similar to the packet transport layer, there are two main locks in the
|
|
request transport layer: One guarding access to the request queue and one
|
|
guarding access to the pending set. These collections may only be accessed
|
|
and modified under the respective lock.
|
|
|
|
Other parts of the request transport layer are guarded independently. State
|
|
flags are (again) managed by atomic bit operations and, if necessary, memory
|
|
barriers. Modifications to the timeout reaper work item and expiration date
|
|
are guarded by their own lock.
|
|
|
|
Some request fields may be read outside of the respective locks guarding
|
|
them, specifically the state for tracing. In those cases, proper access is
|
|
ensured by employing ``WRITE_ONCE()`` and ``READ_ONCE()``. Such read-only
|
|
access is only allowed when stale values are not critical.
|
|
|
|
With respect to the interface for higher layers, request submission
|
|
(|ssh_rtl_submit|), request cancellation (|ssh_rtl_cancel|), and layer
|
|
shutdown (|ssh_rtl_shutdown|) may always be executed concurrently with
|
|
respect to each other. Note that request submission may not run concurrently
|
|
with itself for the same request (and also may only be called once per
|
|
request). Equally, shutdown may also not run concurrently with itself.
|
|
|
|
|
|
Controller Layer
|
|
================
|
|
|
|
The controller layer extends on the request transport layer to provide an
|
|
easy-to-use interface for client drivers. It is represented by
|
|
|ssam_controller| and the SSH driver. While the lower level transport layers
|
|
take care of transmitting and handling packets and requests, the controller
|
|
layer takes on more of a management role. Specifically, it handles device
|
|
initialization, power management, and event handling, including event
|
|
delivery and registration via the (event) completion system (|ssam_cplt|).
|
|
|
|
Event Registration
|
|
------------------
|
|
|
|
In general, an event (or rather a class of events) has to be explicitly
|
|
requested by the host before the EC will send it (HID input events seem to
|
|
be the exception). This is done via an event-enable request (similarly,
|
|
events should be disabled via an event-disable request once no longer
|
|
desired).
|
|
|
|
The specific request used to enable (or disable) an event is given via an
|
|
event registry, i.e. the governing authority of this event (so to speak),
|
|
represented by |ssam_event_registry|. As parameters to this request, the
|
|
target category and, depending on the event registry, instance ID of the
|
|
event to be enabled must be provided. This (optional) instance ID must be
|
|
zero if the registry does not use it. Together, target category and instance
|
|
ID form the event ID, represented by |ssam_event_id|. In short, both, event
|
|
registry and event ID, are required to uniquely identify a respective class
|
|
of events.
|
|
|
|
Note that a further *request ID* parameter must be provided for the
|
|
enable-event request. This parameter does not influence the class of events
|
|
being enabled, but instead is set as the request ID (RQID) on each event of
|
|
this class sent by the EC. It is used to identify events (as a limited
|
|
number of request IDs is reserved for use in events only, specifically one
|
|
to ``SSH_NUM_EVENTS`` inclusively) and also map events to their specific
|
|
class. Currently, the controller always sets this parameter to the target
|
|
category specified in |ssam_event_id|.
|
|
|
|
As multiple client drivers may rely on the same (or overlapping) classes of
|
|
events and enable/disable calls are strictly binary (i.e. on/off), the
|
|
controller has to manage access to these events. It does so via reference
|
|
counting, storing the counter inside an RB-tree based mapping with event
|
|
registry and ID as key (there is no known list of valid event registry and
|
|
event ID combinations). See |ssam_nf|, |ssam_nf_refcount_inc|, and
|
|
|ssam_nf_refcount_dec| for details.
|
|
|
|
This management is done together with notifier registration (described in
|
|
the next section) via the top-level |ssam_notifier_register| and
|
|
|ssam_notifier_unregister| functions.
|
|
|
|
Event Delivery
|
|
--------------
|
|
|
|
To receive events, a client driver has to register an event notifier via
|
|
|ssam_notifier_register|. This increments the reference counter for that
|
|
specific class of events (as detailed in the previous section), enables the
|
|
class on the EC (if it has not been enabled already), and installs the
|
|
provided notifier callback.
|
|
|
|
Notifier callbacks are stored in lists, with one (RCU) list per target
|
|
category (provided via the event ID; NB: there is a fixed known number of
|
|
target categories). There is no known association from the combination of
|
|
event registry and event ID to the command data (target ID, target category,
|
|
command ID, and instance ID) that can be provided by an event class, apart
|
|
from target category and instance ID given via the event ID.
|
|
|
|
Note that due to the way notifiers are (or rather have to be) stored, client
|
|
drivers may receive events that they have not requested and need to account
|
|
for them. Specifically, they will, by default, receive all events from the
|
|
same target category. To simplify dealing with this, filtering of events by
|
|
target ID (provided via the event registry) and instance ID (provided via
|
|
the event ID) can be requested when registering a notifier. This filtering
|
|
is applied when iterating over the notifiers at the time they are executed.
|
|
|
|
All notifier callbacks are executed on a dedicated workqueue, the so-called
|
|
completion workqueue. After an event has been received via the callback
|
|
installed in the request layer (running on the receiver thread of the packet
|
|
transport layer), it will be put on its respective event queue
|
|
(|ssam_event_queue|). From this event queue the completion work item of that
|
|
queue (running on the completion workqueue) will pick up the event and
|
|
execute the notifier callback. This is done to avoid blocking on the
|
|
receiver thread.
|
|
|
|
There is one event queue per combination of target ID and target category.
|
|
This is done to ensure that notifier callbacks are executed in sequence for
|
|
events of the same target ID and target category. Callbacks can be executed
|
|
in parallel for events with a different combination of target ID and target
|
|
category.
|
|
|
|
Concurrency and Locking
|
|
-----------------------
|
|
|
|
Most of the concurrency related safety guarantees of the controller are
|
|
provided by the lower-level request transport layer. In addition to this,
|
|
event (un-)registration is guarded by its own lock.
|
|
|
|
Access to the controller state is guarded by the state lock. This lock is a
|
|
read/write semaphore. The reader part can be used to ensure that the state
|
|
does not change while functions depending on the state to stay the same
|
|
(e.g. |ssam_notifier_register|, |ssam_notifier_unregister|,
|
|
|ssam_request_sync_submit|, and derivatives) are executed and this guarantee
|
|
is not already provided otherwise (e.g. through |ssam_client_bind| or
|
|
|ssam_client_link|). The writer part guards any transitions that will change
|
|
the state, i.e. initialization, destruction, suspension, and resumption.
|
|
|
|
The controller state may be accessed (read-only) outside the state lock for
|
|
smoke-testing against invalid API usage (e.g. in |ssam_request_sync_submit|).
|
|
Note that such checks are not supposed to (and will not) protect against all
|
|
invalid usages, but rather aim to help catch them. In those cases, proper
|
|
variable access is ensured by employing ``WRITE_ONCE()`` and ``READ_ONCE()``.
|
|
|
|
Assuming any preconditions on the state not changing have been satisfied,
|
|
all non-initialization and non-shutdown functions may run concurrently with
|
|
each other. This includes |ssam_notifier_register|, |ssam_notifier_unregister|,
|
|
|ssam_request_sync_submit|, as well as all functions building on top of those.
|