Merge branch 'for-5.12/doc' into for-linus

- HID documentation fixes from Randy Dunlap

Documentation/hid/amd-sfh-hid.rst

@@ -3,13 +3,13 @@
 
 AMD Sensor Fusion Hub
 =====================
-AMD Sensor Fusion Hub (SFH) is part of an SOC starting from Ryzen based platforms.
+AMD Sensor Fusion Hub (SFH) is part of an SOC starting from Ryzen-based platforms.
 The solution is working well on several OEM products. AMD SFH uses HID over PCIe bus.
 In terms of architecture it resembles ISH, however the major difference is all
 the HID reports are generated as part of the kernel driver.
 
-1. Block Diagram
-================
+Block Diagram
+-------------
 
 ::
 
@@ -45,20 +45,20 @@ the HID reports are generated as part of the kernel driver.
 AMD HID Transport Layer
 -----------------------
 AMD SFH transport is also implemented as a bus. Each client application executing in the AMD MP2 is
-registered as a device on this bus. Here: MP2 which is an ARM core connected to x86 for processing
+registered as a device on this bus. Here, MP2 is an ARM core connected to x86 for processing
 sensor data. The layer, which binds each device (AMD SFH HID driver) identifies the device type and
-registers with the hid core. Transport layer attach a constant "struct hid_ll_driver" object with
+registers with the HID core. Transport layer attaches a constant "struct hid_ll_driver" object with
 each device. Once a device is registered with HID core, the callbacks provided via this struct are
 used by HID core to communicate with the device. AMD HID Transport layer implements the synchronous calls.
 
 AMD HID Client Layer
 --------------------
-This layer is responsible to implement HID request and descriptors. As firmware is OS agnostic, HID
+This layer is responsible to implement HID requests and descriptors. As firmware is OS agnostic, HID
 client layer fills the HID request structure and descriptors. HID client layer is complex as it is
-interface between MP2 PCIe layer and HID. HID client layer initialized the MP2 PCIe layer and holds
-the instance of MP2 layer. It identifies the number of sensors connected using MP2-PCIe layer. Base
-on that allocates the DRAM address for each and every sensor and pass it to MP2-PCIe driver.On
-enumeration of each the sensor, client layer fills the HID Descriptor structure and HID input repor
+interface between MP2 PCIe layer and HID. HID client layer initializes the MP2 PCIe layer and holds
+the instance of MP2 layer. It identifies the number of sensors connected using MP2-PCIe layer. Based
+on that allocates the DRAM address for each and every sensor and passes it to MP2-PCIe driver. On
+enumeration of each sensor, client layer fills the HID Descriptor structure and HID input report
 structure. HID Feature report structure is optional. The report descriptor structure varies from
 sensor to sensor.
 
@@ -72,7 +72,7 @@ The communication between X86 and MP2 is split into three parts.
 2. Data transfer via DRAM.
 3. Supported sensor info via P2C registers.
 
-Commands are sent to MP2 using C2P Mailbox registers. Writing into C2P Message registers generate
+Commands are sent to MP2 using C2P Mailbox registers. Writing into C2P Message registers generates
 interrupt to MP2. The client layer allocates the physical memory and the same is sent to MP2 via
 the PCI layer. MP2 firmware writes the command output to the access DRAM memory which the client
 layer has allocated. Firmware always writes minimum of 32 bytes into DRAM. So as a protocol driver

Documentation/hid/hid-alps.rst

@@ -64,7 +64,7 @@ Case2	ReportID_3	TP	Absolute
 
 Command Read/Write
 ------------------
-To read/write to RAM, need to send a commands to the device.
+To read/write to RAM, need to send a command to the device.
 
 The command format is as below.
 
@@ -80,7 +80,7 @@ Byte6	Value Byte
 Byte7	Checksum
 =====	======================
 
-Command Byte is read=0xD1/write=0xD2 .
+Command Byte is read=0xD1/write=0xD2.
 
 Address is read/write RAM address.
 

Documentation/hid/hid-sensor.rst

@@ -48,12 +48,12 @@ for different sensors. For example an accelerometer can send X,Y and Z data, whe
 an ambient light sensor can send illumination data.
 So the implementation has two parts:
 
-- Core hid driver
+- Core HID driver
 - Individual sensor processing part (sensor drivers)
 
 Core driver
 -----------
-The core driver registers (hid-sensor-hub) registers as a HID driver. It parses
+The core driver (hid-sensor-hub) registers as a HID driver. It parses
 report descriptors and identifies all the sensors present. It adds an MFD device
 with name HID-SENSOR-xxxx (where xxxx is usage id from the specification).
 
@@ -95,14 +95,14 @@ Registration functions::
 			u32 usage_id,
 			struct hid_sensor_hub_callbacks *usage_callback):
 
-Registers callbacks for an usage id. The callback functions are not allowed
+Registers callbacks for a usage id. The callback functions are not allowed
 to sleep::
 
 
   int sensor_hub_remove_callback(struct hid_sensor_hub_device *hsdev,
 			u32 usage_id):
 
-Removes callbacks for an usage id.
+Removes callbacks for a usage id.
 
 
 Parsing function::
@@ -166,7 +166,7 @@ This allows some differentiating use cases, where vendor can provide application
 Some common use cases are debug other sensors or to provide some events like
 keyboard attached/detached or lid open/close.
 
-To allow application to utilize these sensors, here they are exported uses sysfs
+To allow application to utilize these sensors, here they are exported using sysfs
 attribute groups, attributes and misc device interface.
 
 An example of this representation on sysfs::
@@ -207,9 +207,9 @@ An example of this representation on sysfs::
   │   │   │   ├── input-1-200202-units
   │   │   │   ├── input-1-200202-value
 
-Here there is a custom sensors with four fields, two feature and two inputs.
+Here there is a custom sensor with four fields: two feature and two inputs.
 Each field is represented by a set of attributes. All fields except the "value"
-are read only. The value field is a RW field.
+are read only. The value field is a read-write field.
 
 Example::
 
@@ -237,6 +237,6 @@ These reports are pushed using misc device interface in a FIFO order::
 	│   │   │   ├── 10:53 -> ../HID-SENSOR-2000e1.6.auto
 	│   ├──  HID-SENSOR-2000e1.6.auto
 
-Each reports can be of variable length preceded by a header. This header
-consist of a 32 bit usage id, 64 bit time stamp and 32 bit length field of raw
+Each report can be of variable length preceded by a header. This header
+consists of a 32-bit usage id, 64-bit time stamp and 32-bit length field of raw
 data.

Documentation/hid/hid-transport.rst

@@ -12,8 +12,8 @@ Bluetooth, I2C and user-space I/O drivers.
 
 The HID subsystem is designed as a bus. Any I/O subsystem may provide HID
 devices and register them with the HID bus. HID core then loads generic device
-drivers on top of it. The transport drivers are responsible of raw data
-transport and device setup/management. HID core is responsible of
+drivers on top of it. The transport drivers are responsible for raw data
+transport and device setup/management. HID core is responsible for
 report-parsing, report interpretation and the user-space API. Device specifics
 and quirks are handled by all layers depending on the quirk.
 
@@ -67,7 +67,7 @@ Transport drivers attach a constant "struct hid_ll_driver" object with each
 device. Once a device is registered with HID core, the callbacks provided via
 this struct are used by HID core to communicate with the device.
 
-Transport drivers are responsible of detecting device failures and unplugging.
+Transport drivers are responsible for detecting device failures and unplugging.
 HID core will operate a device as long as it is registered regardless of any
 device failures. Once transport drivers detect unplug or failure events, they
 must unregister the device from HID core and HID core will stop using the
@@ -101,7 +101,7 @@ properties in common.
    channel. Any unrequested incoming or outgoing data report must be sent on
    this channel and is never acknowledged by the remote side. Devices usually
    send their input events on this channel. Outgoing events are normally
-   not send via intr, except if high throughput is required.
+   not sent via intr, except if high throughput is required.
  - Control Channel (ctrl): The ctrl channel is used for synchronous requests and
    device management. Unrequested data input events must not be sent on this
    channel and are normally ignored. Instead, devices only send management
@@ -161,7 +161,7 @@ allowed on the intr channel and are the only means of data there.
    payload may be blocked by the underlying transport driver if the
    specification does not allow them.
  - SET_REPORT: A SET_REPORT request has a report ID plus data as payload. It is
-   sent from host to device and a device must update it's current report state
+   sent from host to device and a device must update its current report state
    according to the given data. Any of the 3 report types can be used. However,
    INPUT reports as payload might be blocked by the underlying transport driver
    if the specification does not allow them.
@@ -294,7 +294,7 @@ The available HID callbacks are:
       void (*request) (struct hid_device *hdev, struct hid_report *report,
 		       int reqtype)
 
-   Send an HID request on the ctrl channel. "report" contains the report that
+   Send a HID request on the ctrl channel. "report" contains the report that
    should be sent and "reqtype" the request type. Request-type can be
    HID_REQ_SET_REPORT or HID_REQ_GET_REPORT.
 

Documentation/hid/hiddev.rst

@@ -27,7 +27,7 @@ the following::
                           --> hiddev.c ----> POWER / MONITOR CONTROL
 
 In addition, other subsystems (apart from USB) can potentially feed
-events into the input subsystem, but these have no effect on the hid
+events into the input subsystem, but these have no effect on the HID
 device interface.
 
 Using the HID Device Interface
@@ -73,7 +73,7 @@ The hiddev API uses a read() interface, and a set of ioctl() calls.
 HID devices exchange data with the host computer using data
 bundles called "reports".  Each report is divided into "fields",
 each of which can have one or more "usages".  In the hid-core,
-each one of these usages has a single signed 32 bit value.
+each one of these usages has a single signed 32-bit value.
 
 read():
 -------
@@ -113,7 +113,7 @@ HIDIOCAPPLICATION
   - (none)
 
 This ioctl call returns the HID application usage associated with the
-hid device. The third argument to ioctl() specifies which application
+HID device. The third argument to ioctl() specifies which application
 index to get. This is useful when the device has more than one
 application collection. If the index is invalid (greater or equal to
 the number of application collections this device has) the ioctl
@@ -181,7 +181,7 @@ looked up by type (input, output or feature) and id, so these fields
 must be filled in by the user. The ID can be absolute -- the actual
 report id as reported by the device -- or relative --
 HID_REPORT_ID_FIRST for the first report, and (HID_REPORT_ID_NEXT |
-report_id) for the next report after report_id. Without a-priori
+report_id) for the next report after report_id. Without a priori
 information about report ids, the right way to use this ioctl is to
 use the relative IDs above to enumerate the valid IDs. The ioctl
 returns non-zero when there is no more next ID. The real report ID is
@@ -200,7 +200,7 @@ HIDIOCGUCODE
   - struct hiddev_usage_ref (read/write)
 
 Returns the usage_code in a hiddev_usage_ref structure, given that
-given its report type, report id, field index, and index within the
+its report type, report id, field index, and index within the
 field have already been filled into the structure.
 
 HIDIOCGUSAGE

Documentation/hid/hidraw.rst

@@ -21,7 +21,7 @@ Hidraw is the only alternative, short of writing a custom kernel driver, for
 these non-conformant devices.
 
 A benefit of hidraw is that its use by userspace applications is independent
-of the underlying hardware type.  Currently, Hidraw is implemented for USB
+of the underlying hardware type.  Currently, hidraw is implemented for USB
 and Bluetooth.  In the future, as new hardware bus types are developed which
 use the HID specification, hidraw will be expanded to add support for these
 new bus types.
@@ -31,9 +31,10 @@ create hidraw device nodes.  Udev will typically create the device nodes
 directly under /dev (eg: /dev/hidraw0).  As this location is distribution-
 and udev rule-dependent, applications should use libudev to locate hidraw
 devices attached to the system.  There is a tutorial on libudev with a
-working example at:
+working example at::
 
 	http://www.signal11.us/oss/udev/
+	https://web.archive.org/web/2019*/www.signal11.us
 
 The HIDRAW API
 ---------------

Documentation/hid/intel-ish-hid.rst

@@ -4,19 +4,19 @@ 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
+processor to go into low power modes more often, resulting in 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.
+There are many vendors providing external sensor hubs conforming to HID
+Sensor usage tables. These may be found in tablets, 2-in-1 convertible laptops
+and embedded products. Linux has 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
+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.
+mainly use HID over I2C or USB. But ISH doesn't use either I2C or USB.
 
 1. Overview
 ===========
@@ -35,7 +35,7 @@ for a very high speed communication::
 	-----------------		----------------------
 	      PCI				 PCI
 	-----------------		----------------------
-        |Host controller|	-->	|    ISH processor   |
+	|Host controller|	-->	|    ISH processor   |
 	-----------------		----------------------
 	     USB Link
 	-----------------		----------------------
@@ -50,13 +50,13 @@ 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.
+HID sensor applications, sensor calibration applications or sensor firmware
+update applications.
 
 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.
+(ISH HID driver) identifies the device type and registers with the HID core.
 
 2. ISH Implementation: Block Diagram
 ====================================
@@ -104,7 +104,7 @@ is registered as a device on this bus. The driver, which binds each device
 
 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
+the source code which enumerates drivers needs to update from generation to
 generation.
 
 3.2 Inter Processor Communication (IPC) driver
@@ -112,41 +112,42 @@ generation.
 
 Location: drivers/hid/intel-ish-hid/ipc
 
-The IPC message used memory mapped I/O. The registers are defined in
+The IPC message uses 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.
+There are two types of messages, one for management of link and another for
+messages 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.
+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 firmware.
 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
+A doorbell 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.
+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.
+To abstract HW level IPC communication, a set of callbacks is registered.
 The transport layer uses them to send and receive messages.
-Refer to  struct ishtp_hw_ops for callbacks.
+Refer to struct ishtp_hw_ops for callbacks.
 
 3.3 ISH Transport layer
 -----------------------
@@ -158,7 +159,7 @@ Location: drivers/hid/intel-ish-hid/ishtp/
 
 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
+(see ishtp/hbm.h for details)
 - A flow control mechanism to avoid buffer overflows
 
 This protocol resembles bus messages described in the following document:
@@ -168,14 +169,14 @@ 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
+Each FW client and a protocol is identified by a 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
+flow-control credit before. Once it has 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.
@@ -209,7 +210,7 @@ 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
+need 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.
@@ -219,8 +220,8 @@ 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
+When a client initiates a connection, a ring of RX and TX buffers is allocated.
+The size of ring can be specified by the client. HID client sets 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
@@ -230,10 +231,10 @@ 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.
+The host enumeration bus command allows 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
+To ease implementation and allow independent drivers to handle each client,
 this transport layer takes advantage of Linux Bus driver model. Each
 client is registered as device on the transport bus (ishtp bus).
 
@@ -270,7 +271,7 @@ The ISHTP client driver is responsible for:
 The functionality in these drivers is the same as an external sensor hub.
 Refer to
 Documentation/hid/hid-sensor.rst for HID sensor
-Documentation/ABI/testing/sysfs-bus-iio for IIO ABIs to user space
+Documentation/ABI/testing/sysfs-bus-iio for IIO ABIs to user space.
 
 3.6 End to End HID transport Sequence Diagram
 ---------------------------------------------
@@ -341,9 +342,10 @@ Documentation/ABI/testing/sysfs-bus-iio for IIO ABIs to user space
 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
+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
 -----------------------------------------------------

Documentation/hid/uhid.rst

@@ -3,7 +3,7 @@ UHID - User-space I/O driver support for HID subsystem
 ======================================================
 
 UHID allows user-space to implement HID transport drivers. Please see
-hid-transport.txt for an introduction into HID transport drivers. This document
+hid-transport.rst for an introduction into HID transport drivers. This document
 relies heavily on the definitions declared there.
 
 With UHID, a user-space transport driver can create kernel hid-devices for each
@@ -15,7 +15,7 @@ There is an example user-space application in ./samples/uhid/uhid-example.c
 The UHID API
 ------------
 
-UHID is accessed through a character misc-device. The minor-number is allocated
+UHID is accessed through a character misc-device. The minor number is allocated
 dynamically so you need to rely on udev (or similar) to create the device node.
 This is /dev/uhid by default.
 
@@ -45,23 +45,23 @@ The "type" field defines the payload. For each type, there is a
 payload-structure available in the union "u" (except for empty payloads). This
 payload contains management and/or device data.
 
-The first thing you should do is sending an UHID_CREATE2 event. This will
-register the device. UHID will respond with an UHID_START event. You can now
+The first thing you should do is send a UHID_CREATE2 event. This will
+register the device. UHID will respond with a UHID_START event. You can now
 start sending data to and reading data from UHID. However, unless UHID sends the
 UHID_OPEN event, the internally attached HID Device Driver has no user attached.
 That is, you might put your device asleep unless you receive the UHID_OPEN
 event. If you receive the UHID_OPEN event, you should start I/O. If the last
-user closes the HID device, you will receive an UHID_CLOSE event. This may be
-followed by an UHID_OPEN event again and so on. There is no need to perform
+user closes the HID device, you will receive a UHID_CLOSE event. This may be
+followed by a UHID_OPEN event again and so on. There is no need to perform
 reference-counting in user-space. That is, you will never receive multiple
-UHID_OPEN events without an UHID_CLOSE event. The HID subsystem performs
+UHID_OPEN events without a UHID_CLOSE event. The HID subsystem performs
 ref-counting for you.
 You may decide to ignore UHID_OPEN/UHID_CLOSE, though. I/O is allowed even
 though the device may have no users.
 
 If you want to send data on the interrupt channel to the HID subsystem, you send
-an HID_INPUT2 event with your raw data payload. If the kernel wants to send data
-on the interrupt channel to the device, you will read an UHID_OUTPUT event.
+a HID_INPUT2 event with your raw data payload. If the kernel wants to send data
+on the interrupt channel to the device, you will read a UHID_OUTPUT event.
 Data requests on the control channel are currently limited to GET_REPORT and
 SET_REPORT (no other data reports on the control channel are defined so far).
 Those requests are always synchronous. That means, the kernel sends
@@ -71,7 +71,7 @@ the response via UHID_GET_REPORT_REPLY and UHID_SET_REPORT_REPLY to the kernel.
 The kernel blocks internal driver-execution during such round-trips (times out
 after a hard-coded period).
 
-If your device disconnects, you should send an UHID_DESTROY event. This will
+If your device disconnects, you should send a UHID_DESTROY event. This will
 unregister the device. You can now send UHID_CREATE2 again to register a new
 device.
 If you close() the fd, the device is automatically unregistered and destroyed
@@ -125,7 +125,7 @@ UHID_START:
   This is sent when the HID device is started. Consider this as an answer to
   UHID_CREATE2. This is always the first event that is sent. Note that this
   event might not be available immediately after write(UHID_CREATE2) returns.
-  Device drivers might required delayed setups.
+  Device drivers might require delayed setups.
   This event contains a payload of type uhid_start_req. The "dev_flags" field
   describes special behaviors of a device. The following flags are defined:
 
@@ -149,7 +149,7 @@ UHID_STOP:
   reloaded/changed the device driver loaded on your HID device (or some other
   maintenance actions happened).
 
-  You can usually ignored any UHID_STOP events safely.
+  You can usually ignore any UHID_STOP events safely.
 
 UHID_OPEN:
   This is sent when the HID device is opened. That is, the data that the HID
@@ -166,17 +166,17 @@ UHID_OUTPUT:
   This is sent if the HID device driver wants to send raw data to the I/O
   device on the interrupt channel. You should read the payload and forward it to
   the device. The payload is of type "struct uhid_output_req".
-  This may be received even though you haven't received UHID_OPEN, yet.
+  This may be received even though you haven't received UHID_OPEN yet.
 
 UHID_GET_REPORT:
   This event is sent if the kernel driver wants to perform a GET_REPORT request
-  on the control channeld as described in the HID specs. The report-type and
+  on the control channel as described in the HID specs. The report-type and
   report-number are available in the payload.
   The kernel serializes GET_REPORT requests so there will never be two in
   parallel. However, if you fail to respond with a UHID_GET_REPORT_REPLY, the
   request might silently time out.
-  Once you read a GET_REPORT request, you shall forward it to the hid device and
-  remember the "id" field in the payload. Once your hid device responds to the
+  Once you read a GET_REPORT request, you shall forward it to the HID device and
+  remember the "id" field in the payload. Once your HID device responds to the
   GET_REPORT (or if it fails), you must send a UHID_GET_REPORT_REPLY to the
   kernel with the exact same "id" as in the request. If the request already
   timed out, the kernel will ignore the response silently. The "id" field is
@@ -184,7 +184,7 @@ UHID_GET_REPORT:
 
 UHID_SET_REPORT:
   This is the SET_REPORT equivalent of UHID_GET_REPORT. On receipt, you shall
-  send a SET_REPORT request to your hid device. Once it replies, you must tell
+  send a SET_REPORT request to your HID device. Once it replies, you must tell
   the kernel about it via UHID_SET_REPORT_REPLY.
   The same restrictions as for UHID_GET_REPORT apply.
 

drivers/hid/hid-quirks.c

@@ -1029,7 +1029,7 @@ static DEFINE_MUTEX(dquirks_lock);
 /* Runtime ("dynamic") quirks manipulation functions */
 
 /**
- * hid_exists_dquirk: find any dynamic quirks for a HID device
+ * hid_exists_dquirk - find any dynamic quirks for a HID device
  * @hdev: the HID device to match
  *
  * Description:
@@ -1037,7 +1037,7 @@ static DEFINE_MUTEX(dquirks_lock);
  *         the pointer to the relevant struct hid_device_id if found.
  *         Must be called with a read lock held on dquirks_lock.
  *
- * Returns: NULL if no quirk found, struct hid_device_id * if found.
+ * Return: NULL if no quirk found, struct hid_device_id * if found.
  */
 static struct hid_device_id *hid_exists_dquirk(const struct hid_device *hdev)
 {
@@ -1061,7 +1061,7 @@ static struct hid_device_id *hid_exists_dquirk(const struct hid_device *hdev)
 
 
 /**
- * hid_modify_dquirk: add/replace a HID quirk
+ * hid_modify_dquirk - add/replace a HID quirk
  * @id: the HID device to match
  * @quirks: the unsigned long quirks value to add/replace
  *
@@ -1070,7 +1070,7 @@ static struct hid_device_id *hid_exists_dquirk(const struct hid_device *hdev)
  *         quirks value with what was provided.  Otherwise, add the quirk
  *         to the dynamic quirks list.
  *
- * Returns: 0 OK, -error on failure.
+ * Return: 0 OK, -error on failure.
  */
 static int hid_modify_dquirk(const struct hid_device_id *id,
 			     const unsigned long quirks)
@@ -1122,7 +1122,7 @@ static int hid_modify_dquirk(const struct hid_device_id *id,
 }
 
 /**
- * hid_remove_all_dquirks: remove all runtime HID quirks from memory
+ * hid_remove_all_dquirks - remove all runtime HID quirks from memory
  * @bus: bus to match against. Use HID_BUS_ANY if all need to be removed.
  *
  * Description:
@@ -1146,7 +1146,10 @@ static void hid_remove_all_dquirks(__u16 bus)
 }
 
 /**
- * hid_quirks_init: apply HID quirks specified at module load time
+ * hid_quirks_init - apply HID quirks specified at module load time
+ * @quirks_param: array of quirks strings (vendor:product:quirks)
+ * @bus: bus type
+ * @count: number of quirks to check
  */
 int hid_quirks_init(char **quirks_param, __u16 bus, int count)
 {
@@ -1177,7 +1180,7 @@ int hid_quirks_init(char **quirks_param, __u16 bus, int count)
 EXPORT_SYMBOL_GPL(hid_quirks_init);
 
 /**
- * hid_quirks_exit: release memory associated with dynamic_quirks
+ * hid_quirks_exit - release memory associated with dynamic_quirks
  * @bus: a bus to match against
  *
  * Description:
@@ -1194,14 +1197,14 @@ void hid_quirks_exit(__u16 bus)
 EXPORT_SYMBOL_GPL(hid_quirks_exit);
 
 /**
- * hid_gets_squirk: return any static quirks for a HID device
+ * hid_gets_squirk - return any static quirks for a HID device
  * @hdev: the HID device to match
  *
  * Description:
  *     Given a HID device, return a pointer to the quirked hid_device_id entry
  *     associated with that device.
  *
- * Returns: the quirks.
+ * Return: the quirks.
  */
 static unsigned long hid_gets_squirk(const struct hid_device *hdev)
 {
@@ -1225,13 +1228,13 @@ static unsigned long hid_gets_squirk(const struct hid_device *hdev)
 }
 
 /**
- * hid_lookup_quirk: return any quirks associated with a HID device
+ * hid_lookup_quirk - return any quirks associated with a HID device
  * @hdev: the HID device to look for
  *
  * Description:
  *     Given a HID device, return any quirks associated with that device.
  *
- * Returns: an unsigned long quirks value.
+ * Return: an unsigned long quirks value.
  */
 unsigned long hid_lookup_quirk(const struct hid_device *hdev)
 {

include/linux/hid-sensor-hub.h

@@ -150,7 +150,7 @@ int sensor_hub_remove_callback(struct hid_sensor_hub_device *hsdev,
 * @info:	return information about attribute after parsing report
 *
 * Parses report and returns the attribute information such as report id,
-* field index, units and exponet etc.
+* field index, units and exponent etc.
 */
 int sensor_hub_input_get_attribute_info(struct hid_sensor_hub_device *hsdev,
 			u8 type,
@@ -167,7 +167,7 @@ int sensor_hub_input_get_attribute_info(struct hid_sensor_hub_device *hsdev,
 * @is_signed:   If true then fields < 32 bits will be sign-extended
 *
 * Issues a synchronous or asynchronous read request for an input attribute.
-* Returns data upto 32 bits.
+* Return: data up to 32 bits.
 */
 
 enum sensor_hub_read_flags {
@@ -205,8 +205,9 @@ int sensor_hub_set_feature(struct hid_sensor_hub_device *hsdev, u32 report_id,
 * @buffer:	buffer to copy output
 *
 * Used to get a field in feature report. For example this can get polling
-* interval, sensitivity, activate/deactivate state. On success it returns
-* number of bytes copied to buffer. On failure, it returns value < 0.
+* interval, sensitivity, activate/deactivate state.
+* Return: On success, it returns the number of bytes copied to buffer.
+* On failure, it returns value < 0.
 */
 int sensor_hub_get_feature(struct hid_sensor_hub_device *hsdev, u32 report_id,
 			   u32 field_index, int buffer_size, void *buffer);

include/linux/hid.h

@@ -918,7 +918,7 @@ __u32 hid_field_extract(const struct hid_device *hid, __u8 *report,
 /**
  * hid_device_io_start - enable HID input during probe, remove
  *
- * @hid - the device
+ * @hid: the device
  *
  * This should only be called during probe or remove and only be
  * called by the thread calling probe or remove. It will allow
@@ -936,7 +936,7 @@ static inline void hid_device_io_start(struct hid_device *hid) {
 /**
  * hid_device_io_stop - disable HID input during probe, remove
  *
- * @hid - the device
+ * @hid: the device
  *
  * Should only be called after hid_device_io_start. It will prevent
  * incoming packets from going to the driver for the duration of
@@ -1010,6 +1010,13 @@ static inline void hid_map_usage(struct hid_input *hidinput,
 /**
  * hid_map_usage_clear - map usage input bits and clear the input bit
  *
+ * @hidinput: hidinput which we are interested in
+ * @usage: usage to fill in
+ * @bit: pointer to input->{}bit (out parameter)
+ * @max: maximal valid usage->code to consider later (out parameter)
+ * @type: input event type (EV_KEY, EV_REL, ...)
+ * @c: code which corresponds to this usage and type
+ *
  * The same as hid_map_usage, except the @c bit is also cleared in supported
  * bits (@bit).
  */
@@ -1084,7 +1091,7 @@ static inline void hid_hw_request(struct hid_device *hdev,
  * @rtype: HID report type
  * @reqtype: HID_REQ_GET_REPORT or HID_REQ_SET_REPORT
  *
- * @return: count of data transfered, negative if error
+ * Return: count of data transferred, negative if error
  *
  * Same behavior as hid_hw_request, but with raw buffers instead.
  */
@@ -1106,7 +1113,7 @@ static inline int hid_hw_raw_request(struct hid_device *hdev,
  * @buf: raw data to transfer
  * @len: length of buf
  *
- * @return: count of data transfered, negative if error
+ * Return: count of data transferred, negative if error
  */
 static inline int hid_hw_output_report(struct hid_device *hdev, __u8 *buf,
 					size_t len)