261 строка
11 KiB
ReStructuredText
261 строка
11 KiB
ReStructuredText
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LED handling under Linux
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========================
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In its simplest form, the LED class just allows control of LEDs from
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userspace. LEDs appear in /sys/class/leds/. The maximum brightness of the
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LED is defined in max_brightness file. The brightness file will set the brightness
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of the LED (taking a value 0-max_brightness). Most LEDs don't have hardware
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brightness support so will just be turned on for non-zero brightness settings.
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The class also introduces the optional concept of an LED trigger. A trigger
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is a kernel based source of led events. Triggers can either be simple or
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complex. A simple trigger isn't configurable and is designed to slot into
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existing subsystems with minimal additional code. Examples are the disk-activity,
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nand-disk and sharpsl-charge triggers. With led triggers disabled, the code
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optimises away.
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Complex triggers while available to all LEDs have LED specific
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parameters and work on a per LED basis. The timer trigger is an example.
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The timer trigger will periodically change the LED brightness between
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LED_OFF and the current brightness setting. The "on" and "off" time can
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be specified via /sys/class/leds/<device>/delay_{on,off} in milliseconds.
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You can change the brightness value of a LED independently of the timer
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trigger. However, if you set the brightness value to LED_OFF it will
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also disable the timer trigger.
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You can change triggers in a similar manner to the way an IO scheduler
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is chosen (via /sys/class/leds/<device>/trigger). Trigger specific
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parameters can appear in /sys/class/leds/<device> once a given trigger is
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selected.
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Design Philosophy
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=================
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The underlying design philosophy is simplicity. LEDs are simple devices
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and the aim is to keep a small amount of code giving as much functionality
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as possible. Please keep this in mind when suggesting enhancements.
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LED Device Naming
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=================
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Is currently of the form:
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"devicename:color:function"
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- devicename:
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it should refer to a unique identifier created by the kernel,
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like e.g. phyN for network devices or inputN for input devices, rather
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than to the hardware; the information related to the product and the bus
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to which given device is hooked is available in sysfs and can be
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retrieved using get_led_device_info.sh script from tools/leds; generally
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this section is expected mostly for LEDs that are somehow associated with
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other devices.
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- color:
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one of LED_COLOR_ID_* definitions from the header
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include/dt-bindings/leds/common.h.
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- function:
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one of LED_FUNCTION_* definitions from the header
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include/dt-bindings/leds/common.h.
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If required color or function is missing, please submit a patch
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to linux-leds@vger.kernel.org.
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It is possible that more than one LED with the same color and function will
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be required for given platform, differing only with an ordinal number.
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In this case it is preferable to just concatenate the predefined LED_FUNCTION_*
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name with required "-N" suffix in the driver. fwnode based drivers can use
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function-enumerator property for that and then the concatenation will be handled
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automatically by the LED core upon LED class device registration.
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LED subsystem has also a protection against name clash, that may occur
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when LED class device is created by a driver of hot-pluggable device and
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it doesn't provide unique devicename section. In this case numerical
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suffix (e.g. "_1", "_2", "_3" etc.) is added to the requested LED class
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device name.
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There might be still LED class drivers around using vendor or product name
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for devicename, but this approach is now deprecated as it doesn't convey
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any added value. Product information can be found in other places in sysfs
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(see tools/leds/get_led_device_info.sh).
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Examples of proper LED names:
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- "red:disk"
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- "white:flash"
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- "red:indicator"
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- "phy1:green:wlan"
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- "phy3::wlan"
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- ":kbd_backlight"
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- "input5::kbd_backlight"
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- "input3::numlock"
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- "input3::scrolllock"
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- "input3::capslock"
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- "mmc1::status"
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- "white:status"
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get_led_device_info.sh script can be used for verifying if the LED name
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meets the requirements pointed out here. It performs validation of the LED class
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devicename sections and gives hints on expected value for a section in case
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the validation fails for it. So far the script supports validation
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of associations between LEDs and following types of devices:
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- input devices
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- ieee80211 compliant USB devices
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The script is open to extensions.
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There have been calls for LED properties such as color to be exported as
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individual led class attributes. As a solution which doesn't incur as much
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overhead, I suggest these become part of the device name. The naming scheme
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above leaves scope for further attributes should they be needed. If sections
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of the name don't apply, just leave that section blank.
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Brightness setting API
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======================
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LED subsystem core exposes following API for setting brightness:
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- led_set_brightness:
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it is guaranteed not to sleep, passing LED_OFF stops
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blinking,
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- led_set_brightness_sync:
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for use cases when immediate effect is desired -
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it can block the caller for the time required for accessing
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device registers and can sleep, passing LED_OFF stops hardware
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blinking, returns -EBUSY if software blink fallback is enabled.
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LED registration API
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====================
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A driver wanting to register a LED classdev for use by other drivers /
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userspace needs to allocate and fill a led_classdev struct and then call
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`[devm_]led_classdev_register`. If the non devm version is used the driver
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must call led_classdev_unregister from its remove function before
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free-ing the led_classdev struct.
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If the driver can detect hardware initiated brightness changes and thus
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wants to have a brightness_hw_changed attribute then the LED_BRIGHT_HW_CHANGED
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flag must be set in flags before registering. Calling
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led_classdev_notify_brightness_hw_changed on a classdev not registered with
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the LED_BRIGHT_HW_CHANGED flag is a bug and will trigger a WARN_ON.
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Hardware accelerated blink of LEDs
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==================================
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Some LEDs can be programmed to blink without any CPU interaction. To
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support this feature, a LED driver can optionally implement the
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blink_set() function (see <linux/leds.h>). To set an LED to blinking,
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however, it is better to use the API function led_blink_set(), as it
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will check and implement software fallback if necessary.
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To turn off blinking, use the API function led_brightness_set()
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with brightness value LED_OFF, which should stop any software
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timers that may have been required for blinking.
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The blink_set() function should choose a user friendly blinking value
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if it is called with `*delay_on==0` && `*delay_off==0` parameters. In this
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case the driver should give back the chosen value through delay_on and
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delay_off parameters to the leds subsystem.
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Setting the brightness to zero with brightness_set() callback function
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should completely turn off the LED and cancel the previously programmed
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hardware blinking function, if any.
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Hardware driven LEDs
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====================
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Some LEDs can be programmed to be driven by hardware. This is not
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limited to blink but also to turn off or on autonomously.
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To support this feature, a LED needs to implement various additional
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ops and needs to declare specific support for the supported triggers.
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With hw control we refer to the LED driven by hardware.
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LED driver must define the following value to support hw control:
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- hw_control_trigger:
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unique trigger name supported by the LED in hw control
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mode.
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LED driver must implement the following API to support hw control:
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- hw_control_is_supported:
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check if the flags passed by the supported trigger can
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be parsed and activate hw control on the LED.
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Return 0 if the passed flags mask is supported and
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can be set with hw_control_set().
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If the passed flags mask is not supported -EOPNOTSUPP
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must be returned, the LED trigger will use software
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fallback in this case.
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Return a negative error in case of any other error like
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device not ready or timeouts.
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- hw_control_set:
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activate hw control. LED driver will use the provided
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flags passed from the supported trigger, parse them to
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a set of mode and setup the LED to be driven by hardware
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following the requested modes.
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Set LED_OFF via the brightness_set to deactivate hw control.
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Return 0 on success, a negative error number on failing to
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apply flags.
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- hw_control_get:
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get active modes from a LED already in hw control, parse
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them and set in flags the current active flags for the
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supported trigger.
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Return 0 on success, a negative error number on failing
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parsing the initial mode.
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Error from this function is NOT FATAL as the device may
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be in a not supported initial state by the attached LED
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trigger.
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- hw_control_get_device:
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return the device associated with the LED driver in
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hw control. A trigger might use this to match the
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returned device from this function with a configured
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device for the trigger as the source for blinking
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events and correctly enable hw control.
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(example a netdev trigger configured to blink for a
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particular dev match the returned dev from get_device
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to set hw control)
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Returns a pointer to a struct device or NULL if nothing
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is currently attached.
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LED driver can activate additional modes by default to workaround the
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impossibility of supporting each different mode on the supported trigger.
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Examples are hardcoding the blink speed to a set interval, enable special
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feature like bypassing blink if some requirements are not met.
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A trigger should first check if the hw control API are supported by the LED
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driver and check if the trigger is supported to verify if hw control is possible,
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use hw_control_is_supported to check if the flags are supported and only at
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the end use hw_control_set to activate hw control.
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A trigger can use hw_control_get to check if a LED is already in hw control
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and init their flags.
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When the LED is in hw control, no software blink is possible and doing so
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will effectively disable hw control.
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Known Issues
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============
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The LED Trigger core cannot be a module as the simple trigger functions
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would cause nightmare dependency issues. I see this as a minor issue
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compared to the benefits the simple trigger functionality brings. The
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rest of the LED subsystem can be modular.
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