Documentation/driver-api/generic-counter.rst - linux/kernel/git/bpf/bpf - Git at Google

 .. SPDX-License-Identifier: GPL-2.0

 =========================
 Generic Counter Interface
 =========================

 Introduction
 ============

 Counter devices are prevalent among a diverse spectrum of industries.
 The ubiquitous presence of these devices necessitates a common interface
 and standard of interaction and exposure. This driver API attempts to
 resolve the issue of duplicate code found among existing counter device
 drivers by introducing a generic counter interface for consumption. The
 Generic Counter interface enables drivers to support and expose a common
 set of components and functionality present in counter devices.

 Theory
 ======

 Counter devices can vary greatly in design, but regardless of whether
 some devices are quadrature encoder counters or tally counters, all
 counter devices consist of a core set of components. This core set of
 components, shared by all counter devices, is what forms the essence of
 the Generic Counter interface.

 There are three core components to a counter:

 * Signal:
   Stream of data to be evaluated by the counter.

 * Synapse:
   Association of a Signal, and evaluation trigger, with a Count.

 * Count:
   Accumulation of the effects of connected Synapses.

 SIGNAL
 ------
 A Signal represents a stream of data. This is the input data that is
 evaluated by the counter to determine the count data; e.g. a quadrature
 signal output line of a rotary encoder. Not all counter devices provide
 user access to the Signal data, so exposure is optional for drivers.

 When the Signal data is available for user access, the Generic Counter
 interface provides the following available signal values:

 * SIGNAL_LOW:
   Signal line is in a low state.

 * SIGNAL_HIGH:
   Signal line is in a high state.

 A Signal may be associated with one or more Counts.

 SYNAPSE
 -------
 A Synapse represents the association of a Signal with a Count. Signal
 data affects respective Count data, and the Synapse represents this
 relationship.

 The Synapse action mode specifies the Signal data condition that
 triggers the respective Count's count function evaluation to update the
 count data. The Generic Counter interface provides the following
 available action modes:

 * None:
   Signal does not trigger the count function. In Pulse-Direction count
   function mode, this Signal is evaluated as Direction.

 * Rising Edge:
   Low state transitions to high state.

 * Falling Edge:
   High state transitions to low state.

 * Both Edges:
   Any state transition.

 A counter is defined as a set of input signals associated with count
 data that are generated by the evaluation of the state of the associated
 input signals as defined by the respective count functions. Within the
 context of the Generic Counter interface, a counter consists of Counts
 each associated with a set of Signals, whose respective Synapse
 instances represent the count function update conditions for the
 associated Counts.

 A Synapse associates one Signal with one Count.

 COUNT
 -----
 A Count represents the accumulation of the effects of connected
 Synapses; i.e. the count data for a set of Signals. The Generic
 Counter interface represents the count data as a natural number.

 A Count has a count function mode which represents the update behavior
 for the count data. The Generic Counter interface provides the following
 available count function modes:

 * Increase:
   Accumulated count is incremented.

 * Decrease:
   Accumulated count is decremented.

 * Pulse-Direction:
   Rising edges on signal A updates the respective count. The input level
   of signal B determines direction.

 * Quadrature:
   A pair of quadrature encoding signals are evaluated to determine
   position and direction. The following Quadrature modes are available:

   - x1 A:
     If direction is forward, rising edges on quadrature pair signal A
     updates the respective count; if the direction is backward, falling
     edges on quadrature pair signal A updates the respective count.
     Quadrature encoding determines the direction.

   - x1 B:
     If direction is forward, rising edges on quadrature pair signal B
     updates the respective count; if the direction is backward, falling
     edges on quadrature pair signal B updates the respective count.
     Quadrature encoding determines the direction.

   - x2 A:
     Any state transition on quadrature pair signal A updates the
     respective count. Quadrature encoding determines the direction.

   - x2 B:
     Any state transition on quadrature pair signal B updates the
     respective count. Quadrature encoding determines the direction.

   - x4:
     Any state transition on either quadrature pair signals updates the
     respective count. Quadrature encoding determines the direction.

 A Count has a set of one or more associated Synapses.

 Paradigm
 ========

 The most basic counter device may be expressed as a single Count
 associated with a single Signal via a single Synapse. Take for example
 a counter device which simply accumulates a count of rising edges on a
 source input line::

                 Count                Synapse        Signal
                 -----                -------        ------
         +---------------------+
         | Data: Count         |    Rising Edge     ________
         | Function: Increase  |  <-------------   / Source \
         |                     |                  ____________
         +---------------------+

 In this example, the Signal is a source input line with a pulsing
 voltage, while the Count is a persistent count value which is repeatedly
 incremented. The Signal is associated with the respective Count via a
 Synapse. The increase function is triggered by the Signal data condition
 specified by the Synapse -- in this case a rising edge condition on the
 voltage input line. In summary, the counter device existence and
 behavior is aptly represented by respective Count, Signal, and Synapse
 components: a rising edge condition triggers an increase function on an
 accumulating count datum.

 A counter device is not limited to a single Signal; in fact, in theory
 many Signals may be associated with even a single Count. For example, a
 quadrature encoder counter device can keep track of position based on
 the states of two input lines::

                    Count                 Synapse     Signal
                    -----                 -------     ------
         +-------------------------+
         | Data: Position          |    Both Edges     ___
         | Function: Quadrature x4 |  <------------   / A \
         |                         |                 _______
         |                         |
         |                         |    Both Edges     ___
         |                         |  <------------   / B \
         |                         |                 _______
         +-------------------------+

 In this example, two Signals (quadrature encoder lines A and B) are
 associated with a single Count: a rising or falling edge on either A or
 B triggers the "Quadrature x4" function which determines the direction
 of movement and updates the respective position data. The "Quadrature
 x4" function is likely implemented in the hardware of the quadrature
 encoder counter device; the Count, Signals, and Synapses simply
 represent this hardware behavior and functionality.

 Signals associated with the same Count can have differing Synapse action
 mode conditions. For example, a quadrature encoder counter device
 operating in a non-quadrature Pulse-Direction mode could have one input
 line dedicated for movement and a second input line dedicated for
 direction::

                    Count                   Synapse      Signal
                    -----                   -------      ------
         +---------------------------+
         | Data: Position            |    Rising Edge     ___
         | Function: Pulse-Direction |  <-------------   / A \ (Movement)
         |                           |                  _______
         |                           |
         |                           |       None         ___
         |                           |  <-------------   / B \ (Direction)
         |                           |                  _______
         +---------------------------+

 Only Signal A triggers the "Pulse-Direction" update function, but the
 instantaneous state of Signal B is still required in order to know the
 direction so that the position data may be properly updated. Ultimately,
 both Signals are associated with the same Count via two respective
 Synapses, but only one Synapse has an active action mode condition which
 triggers the respective count function while the other is left with a
 "None" condition action mode to indicate its respective Signal's
 availability for state evaluation despite its non-triggering mode.

 Keep in mind that the Signal, Synapse, and Count are abstract
 representations which do not need to be closely married to their
 respective physical sources. This allows the user of a counter to
 divorce themselves from the nuances of physical components (such as
 whether an input line is differential or single-ended) and instead focus
 on the core idea of what the data and process represent (e.g. position
 as interpreted from quadrature encoding data).

 Userspace Interface
 ===================

 Several sysfs attributes are generated by the Generic Counter interface,
 and reside under the /sys/bus/counter/devices/counterX directory, where
 counterX refers to the respective counter device. Please see
 Documentation/ABI/testing/sysfs-bus-counter for detailed
 information on each Generic Counter interface sysfs attribute.

 Through these sysfs attributes, programs and scripts may interact with
 the Generic Counter paradigm Counts, Signals, and Synapses of respective
 counter devices.

 Driver API
 ==========

 Driver authors may utilize the Generic Counter interface in their code
 by including the include/linux/counter.h header file. This header file
 provides several core data structures, function prototypes, and macros
 for defining a counter device.

 .. kernel-doc:: include/linux/counter.h
    :internal:

 .. kernel-doc:: drivers/counter/counter.c
    :export:

 Implementation
 ==============

 To support a counter device, a driver must first allocate the available
 Counter Signals via counter_signal structures. These Signals should
 be stored as an array and set to the signals array member of an
 allocated counter_device structure before the Counter is registered to
 the system.

 Counter Counts may be allocated via counter_count structures, and
 respective Counter Signal associations (Synapses) made via
 counter_synapse structures. Associated counter_synapse structures are
 stored as an array and set to the the synapses array member of the
 respective counter_count structure. These counter_count structures are
 set to the counts array member of an allocated counter_device structure
 before the Counter is registered to the system.

 Driver callbacks should be provided to the counter_device structure via
 a constant counter_ops structure in order to communicate with the
 device: to read and write various Signals and Counts, and to set and get
 the "action mode" and "function mode" for various Synapses and Counts
 respectively.

 A defined counter_device structure may be registered to the system by
 passing it to the counter_register function, and unregistered by passing
 it to the counter_unregister function. Similarly, the
 devm_counter_register and devm_counter_unregister functions may be used
 if device memory-managed registration is desired.

 Extension sysfs attributes can be created for auxiliary functionality
 and data by passing in defined counter_device_ext, counter_count_ext,
 and counter_signal_ext structures. In these cases, the
 counter_device_ext structure is used for global/miscellaneous exposure
 and configuration of the respective Counter device, while the
 counter_count_ext and counter_signal_ext structures allow for auxiliary
 exposure and configuration of a specific Count or Signal respectively.

 Determining the type of extension to create is a matter of scope.

 * Signal extensions are attributes that expose information/control
   specific to a Signal. These types of attributes will exist under a
   Signal's directory in sysfs.

   For example, if you have an invert feature for a Signal, you can have
   a Signal extension called "invert" that toggles that feature:
   /sys/bus/counter/devices/counterX/signalY/invert

 * Count extensions are attributes that expose information/control
   specific to a Count. These type of attributes will exist under a
   Count's directory in sysfs.

   For example, if you want to pause/unpause a Count from updating, you
   can have a Count extension called "enable" that toggles such:
   /sys/bus/counter/devices/counterX/countY/enable

 * Device extensions are attributes that expose information/control
   non-specific to a particular Count or Signal. This is where you would
   put your global features or other miscellanous functionality.

   For example, if your device has an overtemp sensor, you can report the
   chip overheated via a device extension called "error_overtemp":
   /sys/bus/counter/devices/counterX/error_overtemp

 Architecture
 ============

 When the Generic Counter interface counter module is loaded, the
 counter_init function is called which registers a bus_type named
 "counter" to the system. Subsequently, when the module is unloaded, the
 counter_exit function is called which unregisters the bus_type named
 "counter" from the system.

 Counter devices are registered to the system via the counter_register
 function, and later removed via the counter_unregister function. The
 counter_register function establishes a unique ID for the Counter
 device and creates a respective sysfs directory, where X is the
 mentioned unique ID:

     /sys/bus/counter/devices/counterX

 Sysfs attributes are created within the counterX directory to expose
 functionality, configurations, and data relating to the Counts, Signals,
 and Synapses of the Counter device, as well as options and information
 for the Counter device itself.

 Each Signal has a directory created to house its relevant sysfs
 attributes, where Y is the unique ID of the respective Signal:

     /sys/bus/counter/devices/counterX/signalY

 Similarly, each Count has a directory created to house its relevant
 sysfs attributes, where Y is the unique ID of the respective Count:

     /sys/bus/counter/devices/counterX/countY

 For a more detailed breakdown of the available Generic Counter interface
 sysfs attributes, please refer to the
 Documentation/ABI/testing/sysfs-bus-counter file.

 The Signals and Counts associated with the Counter device are registered
 to the system as well by the counter_register function. The
 signal_read/signal_write driver callbacks are associated with their
 respective Signal attributes, while the count_read/count_write and
 function_get/function_set driver callbacks are associated with their
 respective Count attributes; similarly, the same is true for the
 action_get/action_set driver callbacks and their respective Synapse
 attributes. If a driver callback is left undefined, then the respective
 read/write permission is left disabled for the relevant attributes.

 Similarly, extension sysfs attributes are created for the defined
 counter_device_ext, counter_count_ext, and counter_signal_ext
 structures that are passed in.
	.. SPDX-License-Identifier: GPL-2.0

	=========================
	Generic Counter Interface
	=========================

	Introduction
	============

	Counter devices are prevalent among a diverse spectrum of industries.
	The ubiquitous presence of these devices necessitates a common interface
	and standard of interaction and exposure. This driver API attempts to
	resolve the issue of duplicate code found among existing counter device
	drivers by introducing a generic counter interface for consumption. The
	Generic Counter interface enables drivers to support and expose a common
	set of components and functionality present in counter devices.

	Theory
	======

	Counter devices can vary greatly in design, but regardless of whether
	some devices are quadrature encoder counters or tally counters, all
	counter devices consist of a core set of components. This core set of
	components, shared by all counter devices, is what forms the essence of
	the Generic Counter interface.

	There are three core components to a counter:

	* Signal:
	Stream of data to be evaluated by the counter.

	* Synapse:
	Association of a Signal, and evaluation trigger, with a Count.

	* Count:
	Accumulation of the effects of connected Synapses.

	SIGNAL
	------
	A Signal represents a stream of data. This is the input data that is
	evaluated by the counter to determine the count data; e.g. a quadrature
	signal output line of a rotary encoder. Not all counter devices provide
	user access to the Signal data, so exposure is optional for drivers.

	When the Signal data is available for user access, the Generic Counter
	interface provides the following available signal values:

	* SIGNAL_LOW:
	Signal line is in a low state.

	* SIGNAL_HIGH:
	Signal line is in a high state.

	A Signal may be associated with one or more Counts.

	SYNAPSE
	-------
	A Synapse represents the association of a Signal with a Count. Signal
	data affects respective Count data, and the Synapse represents this
	relationship.

	The Synapse action mode specifies the Signal data condition that
	triggers the respective Count's count function evaluation to update the
	count data. The Generic Counter interface provides the following
	available action modes:

	* None:
	Signal does not trigger the count function. In Pulse-Direction count
	function mode, this Signal is evaluated as Direction.

	* Rising Edge:
	Low state transitions to high state.

	* Falling Edge:
	High state transitions to low state.

	* Both Edges:
	Any state transition.

	A counter is defined as a set of input signals associated with count
	data that are generated by the evaluation of the state of the associated
	input signals as defined by the respective count functions. Within the
	context of the Generic Counter interface, a counter consists of Counts
	each associated with a set of Signals, whose respective Synapse
	instances represent the count function update conditions for the
	associated Counts.

	A Synapse associates one Signal with one Count.

	COUNT
	-----
	A Count represents the accumulation of the effects of connected
	Synapses; i.e. the count data for a set of Signals. The Generic
	Counter interface represents the count data as a natural number.

	A Count has a count function mode which represents the update behavior
	for the count data. The Generic Counter interface provides the following
	available count function modes:

	* Increase:
	Accumulated count is incremented.

	* Decrease:
	Accumulated count is decremented.

	* Pulse-Direction:
	Rising edges on signal A updates the respective count. The input level
	of signal B determines direction.

	* Quadrature:
	A pair of quadrature encoding signals are evaluated to determine
	position and direction. The following Quadrature modes are available:

	- x1 A:
	If direction is forward, rising edges on quadrature pair signal A
	updates the respective count; if the direction is backward, falling
	edges on quadrature pair signal A updates the respective count.
	Quadrature encoding determines the direction.

	- x1 B:
	If direction is forward, rising edges on quadrature pair signal B
	updates the respective count; if the direction is backward, falling
	edges on quadrature pair signal B updates the respective count.
	Quadrature encoding determines the direction.

	- x2 A:
	Any state transition on quadrature pair signal A updates the
	respective count. Quadrature encoding determines the direction.

	- x2 B:
	Any state transition on quadrature pair signal B updates the
	respective count. Quadrature encoding determines the direction.

	- x4:
	Any state transition on either quadrature pair signals updates the
	respective count. Quadrature encoding determines the direction.

	A Count has a set of one or more associated Synapses.

	Paradigm
	========

	The most basic counter device may be expressed as a single Count
	associated with a single Signal via a single Synapse. Take for example
	a counter device which simply accumulates a count of rising edges on a
	source input line::

	Count Synapse Signal
	----- ------- ------
	+---------------------+
	\| Data: Count \| Rising Edge ________
	\| Function: Increase \| <------------- / Source \
	\| \| ____________
	+---------------------+

	In this example, the Signal is a source input line with a pulsing
	voltage, while the Count is a persistent count value which is repeatedly
	incremented. The Signal is associated with the respective Count via a
	Synapse. The increase function is triggered by the Signal data condition
	specified by the Synapse -- in this case a rising edge condition on the
	voltage input line. In summary, the counter device existence and
	behavior is aptly represented by respective Count, Signal, and Synapse
	components: a rising edge condition triggers an increase function on an
	accumulating count datum.

	A counter device is not limited to a single Signal; in fact, in theory
	many Signals may be associated with even a single Count. For example, a
	quadrature encoder counter device can keep track of position based on
	the states of two input lines::

	Count Synapse Signal
	----- ------- ------
	+-------------------------+
	\| Data: Position \| Both Edges ___
	\| Function: Quadrature x4 \| <------------ / A \
	\| \| _______
	\| \|
	\| \| Both Edges ___
	\| \| <------------ / B \
	\| \| _______
	+-------------------------+

	In this example, two Signals (quadrature encoder lines A and B) are
	associated with a single Count: a rising or falling edge on either A or
	B triggers the "Quadrature x4" function which determines the direction
	of movement and updates the respective position data. The "Quadrature
	x4" function is likely implemented in the hardware of the quadrature
	encoder counter device; the Count, Signals, and Synapses simply
	represent this hardware behavior and functionality.

	Signals associated with the same Count can have differing Synapse action
	mode conditions. For example, a quadrature encoder counter device
	operating in a non-quadrature Pulse-Direction mode could have one input
	line dedicated for movement and a second input line dedicated for
	direction::

	Count Synapse Signal
	----- ------- ------
	+---------------------------+
	\| Data: Position \| Rising Edge ___
	\| Function: Pulse-Direction \| <------------- / A \ (Movement)
	\| \| _______
	\| \|
	\| \| None ___
	\| \| <------------- / B \ (Direction)
	\| \| _______
	+---------------------------+

	Only Signal A triggers the "Pulse-Direction" update function, but the
	instantaneous state of Signal B is still required in order to know the
	direction so that the position data may be properly updated. Ultimately,
	both Signals are associated with the same Count via two respective
	Synapses, but only one Synapse has an active action mode condition which
	triggers the respective count function while the other is left with a
	"None" condition action mode to indicate its respective Signal's
	availability for state evaluation despite its non-triggering mode.

	Keep in mind that the Signal, Synapse, and Count are abstract
	representations which do not need to be closely married to their
	respective physical sources. This allows the user of a counter to
	divorce themselves from the nuances of physical components (such as
	whether an input line is differential or single-ended) and instead focus
	on the core idea of what the data and process represent (e.g. position
	as interpreted from quadrature encoding data).

	Userspace Interface
	===================

	Several sysfs attributes are generated by the Generic Counter interface,
	and reside under the /sys/bus/counter/devices/counterX directory, where
	counterX refers to the respective counter device. Please see
	Documentation/ABI/testing/sysfs-bus-counter for detailed
	information on each Generic Counter interface sysfs attribute.

	Through these sysfs attributes, programs and scripts may interact with
	the Generic Counter paradigm Counts, Signals, and Synapses of respective
	counter devices.

	Driver API
	==========

	Driver authors may utilize the Generic Counter interface in their code
	by including the include/linux/counter.h header file. This header file
	provides several core data structures, function prototypes, and macros
	for defining a counter device.

	.. kernel-doc:: include/linux/counter.h
	:internal:

	.. kernel-doc:: drivers/counter/counter.c
	:export:

	Implementation
	==============

	To support a counter device, a driver must first allocate the available
	Counter Signals via counter_signal structures. These Signals should
	be stored as an array and set to the signals array member of an
	allocated counter_device structure before the Counter is registered to
	the system.

	Counter Counts may be allocated via counter_count structures, and
	respective Counter Signal associations (Synapses) made via
	counter_synapse structures. Associated counter_synapse structures are
	stored as an array and set to the the synapses array member of the
	respective counter_count structure. These counter_count structures are
	set to the counts array member of an allocated counter_device structure
	before the Counter is registered to the system.

	Driver callbacks should be provided to the counter_device structure via
	a constant counter_ops structure in order to communicate with the
	device: to read and write various Signals and Counts, and to set and get
	the "action mode" and "function mode" for various Synapses and Counts
	respectively.

	A defined counter_device structure may be registered to the system by
	passing it to the counter_register function, and unregistered by passing
	it to the counter_unregister function. Similarly, the
	devm_counter_register and devm_counter_unregister functions may be used
	if device memory-managed registration is desired.

	Extension sysfs attributes can be created for auxiliary functionality
	and data by passing in defined counter_device_ext, counter_count_ext,
	and counter_signal_ext structures. In these cases, the
	counter_device_ext structure is used for global/miscellaneous exposure
	and configuration of the respective Counter device, while the
	counter_count_ext and counter_signal_ext structures allow for auxiliary
	exposure and configuration of a specific Count or Signal respectively.

	Determining the type of extension to create is a matter of scope.

	* Signal extensions are attributes that expose information/control
	specific to a Signal. These types of attributes will exist under a
	Signal's directory in sysfs.

	For example, if you have an invert feature for a Signal, you can have
	a Signal extension called "invert" that toggles that feature:
	/sys/bus/counter/devices/counterX/signalY/invert

	* Count extensions are attributes that expose information/control
	specific to a Count. These type of attributes will exist under a
	Count's directory in sysfs.

	For example, if you want to pause/unpause a Count from updating, you
	can have a Count extension called "enable" that toggles such:
	/sys/bus/counter/devices/counterX/countY/enable

	* Device extensions are attributes that expose information/control
	non-specific to a particular Count or Signal. This is where you would
	put your global features or other miscellanous functionality.

	For example, if your device has an overtemp sensor, you can report the
	chip overheated via a device extension called "error_overtemp":
	/sys/bus/counter/devices/counterX/error_overtemp

	Architecture
	============

	When the Generic Counter interface counter module is loaded, the
	counter_init function is called which registers a bus_type named
	"counter" to the system. Subsequently, when the module is unloaded, the
	counter_exit function is called which unregisters the bus_type named
	"counter" from the system.

	Counter devices are registered to the system via the counter_register
	function, and later removed via the counter_unregister function. The
	counter_register function establishes a unique ID for the Counter
	device and creates a respective sysfs directory, where X is the
	mentioned unique ID:

	/sys/bus/counter/devices/counterX

	Sysfs attributes are created within the counterX directory to expose
	functionality, configurations, and data relating to the Counts, Signals,
	and Synapses of the Counter device, as well as options and information
	for the Counter device itself.

	Each Signal has a directory created to house its relevant sysfs
	attributes, where Y is the unique ID of the respective Signal:

	/sys/bus/counter/devices/counterX/signalY

	Similarly, each Count has a directory created to house its relevant
	sysfs attributes, where Y is the unique ID of the respective Count:

	/sys/bus/counter/devices/counterX/countY

	For a more detailed breakdown of the available Generic Counter interface
	sysfs attributes, please refer to the
	Documentation/ABI/testing/sysfs-bus-counter file.

	The Signals and Counts associated with the Counter device are registered
	to the system as well by the counter_register function. The
	signal_read/signal_write driver callbacks are associated with their
	respective Signal attributes, while the count_read/count_write and
	function_get/function_set driver callbacks are associated with their
	respective Count attributes; similarly, the same is true for the
	action_get/action_set driver callbacks and their respective Synapse
	attributes. If a driver callback is left undefined, then the respective
	read/write permission is left disabled for the relevant attributes.

	Similarly, extension sysfs attributes are created for the defined
	counter_device_ext, counter_count_ext, and counter_signal_ext
	structures that are passed in.