docs: leds: convert to ReST

Rename the leds documentation files to ReST, add an
index for them and adjust in order to produce a nice html
output via the Sphinx build system.

At its new index.rst, let's add a :orphan: while this is not linked to
the main index.rst file, in order to avoid build warnings.

Signed-off-by: Mauro Carvalho Chehab <mchehab+samsung@kernel.org>
Acked-by: Pavel Machek <pavel@ucw.cz>
Signed-off-by: Jacek Anaszewski <jacek.anaszewski@gmail.com>
This commit is contained in:
Mauro Carvalho Chehab 2019-06-28 09:20:20 -03:00 committed by Jacek Anaszewski
parent 25529edef5
commit 8dab91970a
25 changed files with 996 additions and 778 deletions

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@ -679,7 +679,7 @@ status as "unknown". The available commands are:
sysfs notes:
The ThinkLight sysfs interface is documented by the LED class
documentation, in Documentation/leds/leds-class.txt. The ThinkLight LED name
documentation, in Documentation/leds/leds-class.rst. The ThinkLight LED name
is "tpacpi::thinklight".
Due to limitations in the sysfs LED class, if the status of the ThinkLight
@ -779,7 +779,7 @@ All of the above can be turned on and off and can be made to blink.
sysfs notes:
The ThinkPad LED sysfs interface is described in detail by the LED class
documentation, in Documentation/leds/leds-class.txt.
documentation, in Documentation/leds/leds-class.rst.
The LEDs are named (in LED ID order, from 0 to 12):
"tpacpi::power", "tpacpi:orange:batt", "tpacpi:green:batt",

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@ -0,0 +1,25 @@
:orphan:
====
LEDs
====
.. toctree::
:maxdepth: 1
leds-class
leds-class-flash
ledtrig-oneshot
ledtrig-transient
ledtrig-usbport
uleds
leds-blinkm
leds-lm3556
leds-lp3944
leds-lp5521
leds-lp5523
leds-lp5562
leds-lp55xx
leds-mlxcpld

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@ -1,3 +1,7 @@
==================
Leds BlinkM driver
==================
The leds-blinkm driver supports the devices of the BlinkM family.
They are RGB-LED modules driven by a (AT)tiny microcontroller and
@ -14,35 +18,36 @@ The interface this driver provides is 2-fold:
a) LED class interface for use with triggers
############################################
The registration follows the scheme:
blinkm-<i2c-bus-nr>-<i2c-device-nr>-<color>
The registration follows the scheme::
$ ls -h /sys/class/leds/blinkm-6-*
/sys/class/leds/blinkm-6-9-blue:
brightness device max_brightness power subsystem trigger uevent
blinkm-<i2c-bus-nr>-<i2c-device-nr>-<color>
/sys/class/leds/blinkm-6-9-green:
brightness device max_brightness power subsystem trigger uevent
$ ls -h /sys/class/leds/blinkm-6-*
/sys/class/leds/blinkm-6-9-blue:
brightness device max_brightness power subsystem trigger uevent
/sys/class/leds/blinkm-6-9-red:
brightness device max_brightness power subsystem trigger uevent
/sys/class/leds/blinkm-6-9-green:
brightness device max_brightness power subsystem trigger uevent
/sys/class/leds/blinkm-6-9-red:
brightness device max_brightness power subsystem trigger uevent
(same is /sys/bus/i2c/devices/6-0009/leds)
We can control the colors separated into red, green and blue and
assign triggers on each color.
E.g.:
E.g.::
$ cat blinkm-6-9-blue/brightness
05
$ cat blinkm-6-9-blue/brightness
05
$ echo 200 > blinkm-6-9-blue/brightness
$
$ echo 200 > blinkm-6-9-blue/brightness
$
$ modprobe ledtrig-heartbeat
$ echo heartbeat > blinkm-6-9-green/trigger
$
$ modprobe ledtrig-heartbeat
$ echo heartbeat > blinkm-6-9-green/trigger
$
b) Sysfs group to control rgb, fade, hsb, scripts ...
@ -52,29 +57,28 @@ This extended interface is available as folder blinkm
in the sysfs folder of the I2C device.
E.g. below /sys/bus/i2c/devices/6-0009/blinkm
$ ls -h /sys/bus/i2c/devices/6-0009/blinkm/
blue green red test
$ ls -h /sys/bus/i2c/devices/6-0009/blinkm/
blue green red test
Currently supported is just setting red, green, blue
and a test sequence.
E.g.:
E.g.::
$ cat *
00
00
00
#Write into test to start test sequence!#
$ cat *
00
00
00
#Write into test to start test sequence!#
$ echo 1 > test
$
$ echo 1 > test
$
$ echo 255 > red
$
$ echo 255 > red
$
as of 6/2012
dl9pf <at> gmx <dot> de

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@ -1,9 +1,9 @@
==============================
Flash LED handling under Linux
==============================
Some LED devices provide two modes - torch and flash. In the LED subsystem
those modes are supported by LED class (see Documentation/leds/leds-class.txt)
those modes are supported by LED class (see Documentation/leds/leds-class.rst)
and LED Flash class respectively. The torch mode related features are enabled
by default and the flash ones only if a driver declares it by setting
LED_DEV_CAP_FLASH flag.
@ -14,6 +14,7 @@ registered in the LED subsystem with led_classdev_flash_register function.
Following sysfs attributes are exposed for controlling flash LED devices:
(see Documentation/ABI/testing/sysfs-class-led-flash)
- flash_brightness
- max_flash_brightness
- flash_timeout
@ -31,30 +32,46 @@ be defined in the kernel config.
The driver must call the v4l2_flash_init function to get registered in the
V4L2 subsystem. The function takes six arguments:
- dev : flash device, e.g. an I2C device
- of_node : of_node of the LED, may be NULL if the same as device's
- fled_cdev : LED flash class device to wrap
- iled_cdev : LED flash class device representing indicator LED associated with
fled_cdev, may be NULL
- ops : V4L2 specific ops
* external_strobe_set - defines the source of the flash LED strobe -
- dev:
flash device, e.g. an I2C device
- of_node:
of_node of the LED, may be NULL if the same as device's
- fled_cdev:
LED flash class device to wrap
- iled_cdev:
LED flash class device representing indicator LED associated with
fled_cdev, may be NULL
- ops:
V4L2 specific ops
* external_strobe_set
defines the source of the flash LED strobe -
V4L2_CID_FLASH_STROBE control or external source, typically
a sensor, which makes it possible to synchronise the flash
strobe start with exposure start,
* intensity_to_led_brightness and led_brightness_to_intensity - perform
* intensity_to_led_brightness and led_brightness_to_intensity
perform
enum led_brightness <-> V4L2 intensity conversion in a device
specific manner - they can be used for devices with non-linear
LED current scale.
- config : configuration for V4L2 Flash sub-device
* dev_name - the name of the media entity, unique in the system,
* flash_faults - bitmask of flash faults that the LED flash class
- config:
configuration for V4L2 Flash sub-device
* dev_name
the name of the media entity, unique in the system,
* flash_faults
bitmask of flash faults that the LED flash class
device can report; corresponding LED_FAULT* bit definitions are
available in <linux/led-class-flash.h>,
* torch_intensity - constraints for the LED in TORCH mode
* torch_intensity
constraints for the LED in TORCH mode
in microamperes,
* indicator_intensity - constraints for the indicator LED
* indicator_intensity
constraints for the indicator LED
in microamperes,
* has_external_strobe - determines whether the flash strobe source
* has_external_strobe
determines whether the flash strobe source
can be switched to external,
On remove the v4l2_flash_release function has to be called, which takes one

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@ -1,4 +1,4 @@
========================
LED handling under Linux
========================
@ -43,7 +43,7 @@ LED Device Naming
Is currently of the form:
"devicename:colour:function"
"devicename:colour:function"
There have been calls for LED properties such as colour to be exported as
individual led class attributes. As a solution which doesn't incur as much
@ -57,9 +57,12 @@ Brightness setting API
LED subsystem core exposes following API for setting brightness:
- led_set_brightness : it is guaranteed not to sleep, passing LED_OFF stops
- led_set_brightness:
it is guaranteed not to sleep, passing LED_OFF stops
blinking,
- led_set_brightness_sync : for use cases when immediate effect is desired -
- led_set_brightness_sync:
for use cases when immediate effect is desired -
it can block the caller for the time required for accessing
device registers and can sleep, passing LED_OFF stops hardware
blinking, returns -EBUSY if software blink fallback is enabled.
@ -70,7 +73,7 @@ LED registration API
A driver wanting to register a LED classdev for use by other drivers /
userspace needs to allocate and fill a led_classdev struct and then call
[devm_]led_classdev_register. If the non devm version is used the driver
`[devm_]led_classdev_register`. If the non devm version is used the driver
must call led_classdev_unregister from its remove function before
free-ing the led_classdev struct.
@ -94,7 +97,7 @@ with brightness value LED_OFF, which should stop any software
timers that may have been required for blinking.
The blink_set() function should choose a user friendly blinking value
if it is called with *delay_on==0 && *delay_off==0 parameters. In this
if it is called with `*delay_on==0` && `*delay_off==0` parameters. In this
case the driver should give back the chosen value through delay_on and
delay_off parameters to the leds subsystem.

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@ -1,68 +1,118 @@
========================
Kernel driver for lm3556
========================
*Texas Instrument:
1.5 A Synchronous Boost LED Flash Driver w/ High-Side Current Source
* Texas Instrument:
1.5 A Synchronous Boost LED Flash Driver w/ High-Side Current Source
* Datasheet: http://www.national.com/ds/LM/LM3556.pdf
Authors:
Daniel Jeong
- Daniel Jeong
Contact:Daniel Jeong(daniel.jeong-at-ti.com, gshark.jeong-at-gmail.com)
Description
-----------
There are 3 functions in LM3556, Flash, Torch and Indicator.
FLASH MODE
Flash Mode
^^^^^^^^^^
In Flash Mode, the LED current source(LED) provides 16 target current levels
from 93.75 mA to 1500 mA.The Flash currents are adjusted via the CURRENT
CONTROL REGISTER(0x09).Flash mode is activated by the ENABLE REGISTER(0x0A),
or by pulling the STROBE pin HIGH.
LM3556 Flash can be controlled through sys/class/leds/flash/brightness file
* if STROBE pin is enabled, below example control brightness only, and
ON / OFF will be controlled by STROBE pin.
ON / OFF will be controlled by STROBE pin.
Flash Example:
OFF : #echo 0 > sys/class/leds/flash/brightness
93.75 mA: #echo 1 > sys/class/leds/flash/brightness
... .....
1500 mA: #echo 16 > sys/class/leds/flash/brightness
TORCH MODE
OFF::
#echo 0 > sys/class/leds/flash/brightness
93.75 mA::
#echo 1 > sys/class/leds/flash/brightness
...
1500 mA::
#echo 16 > sys/class/leds/flash/brightness
Torch Mode
^^^^^^^^^^
In Torch Mode, the current source(LED) is programmed via the CURRENT CONTROL
REGISTER(0x09).Torch Mode is activated by the ENABLE REGISTER(0x0A) or by the
hardware TORCH input.
LM3556 torch can be controlled through sys/class/leds/torch/brightness file.
* if TORCH pin is enabled, below example control brightness only,
and ON / OFF will be controlled by TORCH pin.
Torch Example:
OFF : #echo 0 > sys/class/leds/torch/brightness
46.88 mA: #echo 1 > sys/class/leds/torch/brightness
... .....
375 mA : #echo 8 > sys/class/leds/torch/brightness
INDICATOR MODE
OFF::
#echo 0 > sys/class/leds/torch/brightness
46.88 mA::
#echo 1 > sys/class/leds/torch/brightness
...
375 mA::
#echo 8 > sys/class/leds/torch/brightness
Indicator Mode
^^^^^^^^^^^^^^
Indicator pattern can be set through sys/class/leds/indicator/pattern file,
and 4 patterns are pre-defined in indicator_pattern array.
According to N-lank, Pulse time and N Period values, different pattern wiill
be generated.If you want new patterns for your own device, change
indicator_pattern array with your own values and INDIC_PATTERN_SIZE.
Please refer datasheet for more detail about N-Blank, Pulse time and N Period.
Indicator pattern example:
pattern 0: #echo 0 > sys/class/leds/indicator/pattern
....
pattern 3: #echo 3 > sys/class/leds/indicator/pattern
pattern 0::
#echo 0 > sys/class/leds/indicator/pattern
...
pattern 3::
#echo 3 > sys/class/leds/indicator/pattern
Indicator brightness can be controlled through
sys/class/leds/indicator/brightness file.
Example:
OFF : #echo 0 > sys/class/leds/indicator/brightness
5.86 mA : #echo 1 > sys/class/leds/indicator/brightness
........
46.875mA : #echo 8 > sys/class/leds/indicator/brightness
OFF::
#echo 0 > sys/class/leds/indicator/brightness
5.86 mA::
#echo 1 > sys/class/leds/indicator/brightness
...
46.875mA::
#echo 8 > sys/class/leds/indicator/brightness
Notes
-----
@ -70,7 +120,8 @@ Driver expects it is registered using the i2c_board_info mechanism.
To register the chip at address 0x63 on specific adapter, set the platform data
according to include/linux/platform_data/leds-lm3556.h, set the i2c board info
Example:
Example::
static struct i2c_board_info board_i2c_ch4[] __initdata = {
{
I2C_BOARD_INFO(LM3556_NAME, 0x63),
@ -80,6 +131,7 @@ Example:
and register it in the platform init function
Example:
Example::
board_register_i2c_bus(4, 400,
board_i2c_ch4, ARRAY_SIZE(board_i2c_ch4));

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@ -1,14 +1,20 @@
====================
Kernel driver lp3944
====================
* National Semiconductor LP3944 Fun-light Chip
Prefix: 'lp3944'
Addresses scanned: None (see the Notes section below)
Datasheet: Publicly available at the National Semiconductor website
http://www.national.com/pf/LP/LP3944.html
Datasheet:
Publicly available at the National Semiconductor website
http://www.national.com/pf/LP/LP3944.html
Authors:
Antonio Ospite <ospite@studenti.unina.it>
Antonio Ospite <ospite@studenti.unina.it>
Description
@ -19,8 +25,11 @@ is used as a led controller.
The DIM modes are used to set _blink_ patterns for leds, the pattern is
specified supplying two parameters:
- period: from 0s to 1.6s
- duty cycle: percentage of the period the led is on, from 0 to 100
- period:
from 0s to 1.6s
- duty cycle:
percentage of the period the led is on, from 0 to 100
Setting a led in DIM0 or DIM1 mode makes it blink according to the pattern.
See the datasheet for details.
@ -35,7 +44,7 @@ The chip is used mainly in embedded contexts, so this driver expects it is
registered using the i2c_board_info mechanism.
To register the chip at address 0x60 on adapter 0, set the platform data
according to include/linux/leds-lp3944.h, set the i2c board info:
according to include/linux/leds-lp3944.h, set the i2c board info::
static struct i2c_board_info a910_i2c_board_info[] __initdata = {
{
@ -44,7 +53,7 @@ according to include/linux/leds-lp3944.h, set the i2c board info:
},
};
and register it in the platform init function
and register it in the platform init function::
i2c_register_board_info(0, a910_i2c_board_info,
ARRAY_SIZE(a910_i2c_board_info));

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@ -0,0 +1,115 @@
========================
Kernel driver for lp5521
========================
* National Semiconductor LP5521 led driver chip
* Datasheet: http://www.national.com/pf/LP/LP5521.html
Authors: Mathias Nyman, Yuri Zaporozhets, Samu Onkalo
Contact: Samu Onkalo (samu.p.onkalo-at-nokia.com)
Description
-----------
LP5521 can drive up to 3 channels. Leds can be controlled directly via
the led class control interface. Channels have generic names:
lp5521:channelx, where x is 0 .. 2
All three channels can be also controlled using the engine micro programs.
More details of the instructions can be found from the public data sheet.
LP5521 has the internal program memory for running various LED patterns.
There are two ways to run LED patterns.
1) Legacy interface - enginex_mode and enginex_load
Control interface for the engines:
x is 1 .. 3
enginex_mode:
disabled, load, run
enginex_load:
store program (visible only in engine load mode)
Example (start to blink the channel 2 led)::
cd /sys/class/leds/lp5521:channel2/device
echo "load" > engine3_mode
echo "037f4d0003ff6000" > engine3_load
echo "run" > engine3_mode
To stop the engine::
echo "disabled" > engine3_mode
2) Firmware interface - LP55xx common interface
For the details, please refer to 'firmware' section in leds-lp55xx.txt
sysfs contains a selftest entry.
The test communicates with the chip and checks that
the clock mode is automatically set to the requested one.
Each channel has its own led current settings.
- /sys/class/leds/lp5521:channel0/led_current - RW
- /sys/class/leds/lp5521:channel0/max_current - RO
Format: 10x mA i.e 10 means 1.0 mA
example platform data::
static struct lp55xx_led_config lp5521_led_config[] = {
{
.name = "red",
.chan_nr = 0,
.led_current = 50,
.max_current = 130,
}, {
.name = "green",
.chan_nr = 1,
.led_current = 0,
.max_current = 130,
}, {
.name = "blue",
.chan_nr = 2,
.led_current = 0,
.max_current = 130,
}
};
static int lp5521_setup(void)
{
/* setup HW resources */
}
static void lp5521_release(void)
{
/* Release HW resources */
}
static void lp5521_enable(bool state)
{
/* Control of chip enable signal */
}
static struct lp55xx_platform_data lp5521_platform_data = {
.led_config = lp5521_led_config,
.num_channels = ARRAY_SIZE(lp5521_led_config),
.clock_mode = LP55XX_CLOCK_EXT,
.setup_resources = lp5521_setup,
.release_resources = lp5521_release,
.enable = lp5521_enable,
};
Note:
chan_nr can have values between 0 and 2.
The name of each channel can be configurable.
If the name field is not defined, the default name will be set to 'xxxx:channelN'
(XXXX : pdata->label or i2c client name, N : channel number)
If the current is set to 0 in the platform data, that channel is
disabled and it is not visible in the sysfs.

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@ -1,101 +0,0 @@
Kernel driver for lp5521
========================
* National Semiconductor LP5521 led driver chip
* Datasheet: http://www.national.com/pf/LP/LP5521.html
Authors: Mathias Nyman, Yuri Zaporozhets, Samu Onkalo
Contact: Samu Onkalo (samu.p.onkalo-at-nokia.com)
Description
-----------
LP5521 can drive up to 3 channels. Leds can be controlled directly via
the led class control interface. Channels have generic names:
lp5521:channelx, where x is 0 .. 2
All three channels can be also controlled using the engine micro programs.
More details of the instructions can be found from the public data sheet.
LP5521 has the internal program memory for running various LED patterns.
There are two ways to run LED patterns.
1) Legacy interface - enginex_mode and enginex_load
Control interface for the engines:
x is 1 .. 3
enginex_mode : disabled, load, run
enginex_load : store program (visible only in engine load mode)
Example (start to blink the channel 2 led):
cd /sys/class/leds/lp5521:channel2/device
echo "load" > engine3_mode
echo "037f4d0003ff6000" > engine3_load
echo "run" > engine3_mode
To stop the engine:
echo "disabled" > engine3_mode
2) Firmware interface - LP55xx common interface
For the details, please refer to 'firmware' section in leds-lp55xx.txt
sysfs contains a selftest entry.
The test communicates with the chip and checks that
the clock mode is automatically set to the requested one.
Each channel has its own led current settings.
/sys/class/leds/lp5521:channel0/led_current - RW
/sys/class/leds/lp5521:channel0/max_current - RO
Format: 10x mA i.e 10 means 1.0 mA
example platform data:
Note: chan_nr can have values between 0 and 2.
The name of each channel can be configurable.
If the name field is not defined, the default name will be set to 'xxxx:channelN'
(XXXX : pdata->label or i2c client name, N : channel number)
static struct lp55xx_led_config lp5521_led_config[] = {
{
.name = "red",
.chan_nr = 0,
.led_current = 50,
.max_current = 130,
}, {
.name = "green",
.chan_nr = 1,
.led_current = 0,
.max_current = 130,
}, {
.name = "blue",
.chan_nr = 2,
.led_current = 0,
.max_current = 130,
}
};
static int lp5521_setup(void)
{
/* setup HW resources */
}
static void lp5521_release(void)
{
/* Release HW resources */
}
static void lp5521_enable(bool state)
{
/* Control of chip enable signal */
}
static struct lp55xx_platform_data lp5521_platform_data = {
.led_config = lp5521_led_config,
.num_channels = ARRAY_SIZE(lp5521_led_config),
.clock_mode = LP55XX_CLOCK_EXT,
.setup_resources = lp5521_setup,
.release_resources = lp5521_release,
.enable = lp5521_enable,
};
If the current is set to 0 in the platform data, that channel is
disabled and it is not visible in the sysfs.

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@ -0,0 +1,147 @@
========================
Kernel driver for lp5523
========================
* National Semiconductor LP5523 led driver chip
* Datasheet: http://www.national.com/pf/LP/LP5523.html
Authors: Mathias Nyman, Yuri Zaporozhets, Samu Onkalo
Contact: Samu Onkalo (samu.p.onkalo-at-nokia.com)
Description
-----------
LP5523 can drive up to 9 channels. Leds can be controlled directly via
the led class control interface.
The name of each channel is configurable in the platform data - name and label.
There are three options to make the channel name.
a) Define the 'name' in the platform data
To make specific channel name, then use 'name' platform data.
- /sys/class/leds/R1 (name: 'R1')
- /sys/class/leds/B1 (name: 'B1')
b) Use the 'label' with no 'name' field
For one device name with channel number, then use 'label'.
- /sys/class/leds/RGB:channelN (label: 'RGB', N: 0 ~ 8)
c) Default
If both fields are NULL, 'lp5523' is used by default.
- /sys/class/leds/lp5523:channelN (N: 0 ~ 8)
LP5523 has the internal program memory for running various LED patterns.
There are two ways to run LED patterns.
1) Legacy interface - enginex_mode, enginex_load and enginex_leds
Control interface for the engines:
x is 1 .. 3
enginex_mode:
disabled, load, run
enginex_load:
microcode load
enginex_leds:
led mux control
::
cd /sys/class/leds/lp5523:channel2/device
echo "load" > engine3_mode
echo "9d80400004ff05ff437f0000" > engine3_load
echo "111111111" > engine3_leds
echo "run" > engine3_mode
To stop the engine::
echo "disabled" > engine3_mode
2) Firmware interface - LP55xx common interface
For the details, please refer to 'firmware' section in leds-lp55xx.txt
LP5523 has three master faders. If a channel is mapped to one of
the master faders, its output is dimmed based on the value of the master
fader.
For example::
echo "123000123" > master_fader_leds
creates the following channel-fader mappings::
channel 0,6 to master_fader1
channel 1,7 to master_fader2
channel 2,8 to master_fader3
Then, to have 25% of the original output on channel 0,6::
echo 64 > master_fader1
To have 0% of the original output (i.e. no output) channel 1,7::
echo 0 > master_fader2
To have 100% of the original output (i.e. no dimming) on channel 2,8::
echo 255 > master_fader3
To clear all master fader controls::
echo "000000000" > master_fader_leds
Selftest uses always the current from the platform data.
Each channel contains led current settings.
- /sys/class/leds/lp5523:channel2/led_current - RW
- /sys/class/leds/lp5523:channel2/max_current - RO
Format: 10x mA i.e 10 means 1.0 mA
Example platform data::
static struct lp55xx_led_config lp5523_led_config[] = {
{
.name = "D1",
.chan_nr = 0,
.led_current = 50,
.max_current = 130,
},
...
{
.chan_nr = 8,
.led_current = 50,
.max_current = 130,
}
};
static int lp5523_setup(void)
{
/* Setup HW resources */
}
static void lp5523_release(void)
{
/* Release HW resources */
}
static void lp5523_enable(bool state)
{
/* Control chip enable signal */
}
static struct lp55xx_platform_data lp5523_platform_data = {
.led_config = lp5523_led_config,
.num_channels = ARRAY_SIZE(lp5523_led_config),
.clock_mode = LP55XX_CLOCK_EXT,
.setup_resources = lp5523_setup,
.release_resources = lp5523_release,
.enable = lp5523_enable,
};
Note
chan_nr can have values between 0 and 8.

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@ -1,130 +0,0 @@
Kernel driver for lp5523
========================
* National Semiconductor LP5523 led driver chip
* Datasheet: http://www.national.com/pf/LP/LP5523.html
Authors: Mathias Nyman, Yuri Zaporozhets, Samu Onkalo
Contact: Samu Onkalo (samu.p.onkalo-at-nokia.com)
Description
-----------
LP5523 can drive up to 9 channels. Leds can be controlled directly via
the led class control interface.
The name of each channel is configurable in the platform data - name and label.
There are three options to make the channel name.
a) Define the 'name' in the platform data
To make specific channel name, then use 'name' platform data.
/sys/class/leds/R1 (name: 'R1')
/sys/class/leds/B1 (name: 'B1')
b) Use the 'label' with no 'name' field
For one device name with channel number, then use 'label'.
/sys/class/leds/RGB:channelN (label: 'RGB', N: 0 ~ 8)
c) Default
If both fields are NULL, 'lp5523' is used by default.
/sys/class/leds/lp5523:channelN (N: 0 ~ 8)
LP5523 has the internal program memory for running various LED patterns.
There are two ways to run LED patterns.
1) Legacy interface - enginex_mode, enginex_load and enginex_leds
Control interface for the engines:
x is 1 .. 3
enginex_mode : disabled, load, run
enginex_load : microcode load
enginex_leds : led mux control
cd /sys/class/leds/lp5523:channel2/device
echo "load" > engine3_mode
echo "9d80400004ff05ff437f0000" > engine3_load
echo "111111111" > engine3_leds
echo "run" > engine3_mode
To stop the engine:
echo "disabled" > engine3_mode
2) Firmware interface - LP55xx common interface
For the details, please refer to 'firmware' section in leds-lp55xx.txt
LP5523 has three master faders. If a channel is mapped to one of
the master faders, its output is dimmed based on the value of the master
fader.
For example,
echo "123000123" > master_fader_leds
creates the following channel-fader mappings:
channel 0,6 to master_fader1
channel 1,7 to master_fader2
channel 2,8 to master_fader3
Then, to have 25% of the original output on channel 0,6:
echo 64 > master_fader1
To have 0% of the original output (i.e. no output) channel 1,7:
echo 0 > master_fader2
To have 100% of the original output (i.e. no dimming) on channel 2,8:
echo 255 > master_fader3
To clear all master fader controls:
echo "000000000" > master_fader_leds
Selftest uses always the current from the platform data.
Each channel contains led current settings.
/sys/class/leds/lp5523:channel2/led_current - RW
/sys/class/leds/lp5523:channel2/max_current - RO
Format: 10x mA i.e 10 means 1.0 mA
Example platform data:
Note - chan_nr can have values between 0 and 8.
static struct lp55xx_led_config lp5523_led_config[] = {
{
.name = "D1",
.chan_nr = 0,
.led_current = 50,
.max_current = 130,
},
...
{
.chan_nr = 8,
.led_current = 50,
.max_current = 130,
}
};
static int lp5523_setup(void)
{
/* Setup HW resources */
}
static void lp5523_release(void)
{
/* Release HW resources */
}
static void lp5523_enable(bool state)
{
/* Control chip enable signal */
}
static struct lp55xx_platform_data lp5523_platform_data = {
.led_config = lp5523_led_config,
.num_channels = ARRAY_SIZE(lp5523_led_config),
.clock_mode = LP55XX_CLOCK_EXT,
.setup_resources = lp5523_setup,
.release_resources = lp5523_release,
.enable = lp5523_enable,
};

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========================
Kernel driver for lp5562
========================
* TI LP5562 LED Driver
Author: Milo(Woogyom) Kim <milo.kim@ti.com>
Description
===========
LP5562 can drive up to 4 channels. R/G/B and White.
LEDs can be controlled directly via the led class control interface.
All four channels can be also controlled using the engine micro programs.
LP5562 has the internal program memory for running various LED patterns.
For the details, please refer to 'firmware' section in leds-lp55xx.txt
Device attribute
================
engine_mux
3 Engines are allocated in LP5562, but the number of channel is 4.
Therefore each channel should be mapped to the engine number.
Value: RGB or W
This attribute is used for programming LED data with the firmware interface.
Unlike the LP5521/LP5523/55231, LP5562 has unique feature for the engine mux,
so additional sysfs is required
LED Map
===== === ===============================
Red ... Engine 1 (fixed)
Green ... Engine 2 (fixed)
Blue ... Engine 3 (fixed)
White ... Engine 1 or 2 or 3 (selective)
===== === ===============================
How to load the program data using engine_mux
=============================================
Before loading the LP5562 program data, engine_mux should be written between
the engine selection and loading the firmware.
Engine mux has two different mode, RGB and W.
RGB is used for loading RGB program data, W is used for W program data.
For example, run blinking green channel pattern::
echo 2 > /sys/bus/i2c/devices/xxxx/select_engine # 2 is for green channel
echo "RGB" > /sys/bus/i2c/devices/xxxx/engine_mux # engine mux for RGB
echo 1 > /sys/class/firmware/lp5562/loading
echo "4000600040FF6000" > /sys/class/firmware/lp5562/data
echo 0 > /sys/class/firmware/lp5562/loading
echo 1 > /sys/bus/i2c/devices/xxxx/run_engine
To run a blinking white pattern::
echo 1 or 2 or 3 > /sys/bus/i2c/devices/xxxx/select_engine
echo "W" > /sys/bus/i2c/devices/xxxx/engine_mux
echo 1 > /sys/class/firmware/lp5562/loading
echo "4000600040FF6000" > /sys/class/firmware/lp5562/data
echo 0 > /sys/class/firmware/lp5562/loading
echo 1 > /sys/bus/i2c/devices/xxxx/run_engine
How to load the predefined patterns
===================================
Please refer to 'leds-lp55xx.txt"
Setting Current of Each Channel
===============================
Like LP5521 and LP5523/55231, LP5562 provides LED current settings.
The 'led_current' and 'max_current' are used.
Example of Platform data
========================
::
static struct lp55xx_led_config lp5562_led_config[] = {
{
.name = "R",
.chan_nr = 0,
.led_current = 20,
.max_current = 40,
},
{
.name = "G",
.chan_nr = 1,
.led_current = 20,
.max_current = 40,
},
{
.name = "B",
.chan_nr = 2,
.led_current = 20,
.max_current = 40,
},
{
.name = "W",
.chan_nr = 3,
.led_current = 20,
.max_current = 40,
},
};
static int lp5562_setup(void)
{
/* setup HW resources */
}
static void lp5562_release(void)
{
/* Release HW resources */
}
static void lp5562_enable(bool state)
{
/* Control of chip enable signal */
}
static struct lp55xx_platform_data lp5562_platform_data = {
.led_config = lp5562_led_config,
.num_channels = ARRAY_SIZE(lp5562_led_config),
.setup_resources = lp5562_setup,
.release_resources = lp5562_release,
.enable = lp5562_enable,
};
To configure the platform specific data, lp55xx_platform_data structure is used
If the current is set to 0 in the platform data, that channel is
disabled and it is not visible in the sysfs.

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Kernel driver for LP5562
========================
* TI LP5562 LED Driver
Author: Milo(Woogyom) Kim <milo.kim@ti.com>
Description
LP5562 can drive up to 4 channels. R/G/B and White.
LEDs can be controlled directly via the led class control interface.
All four channels can be also controlled using the engine micro programs.
LP5562 has the internal program memory for running various LED patterns.
For the details, please refer to 'firmware' section in leds-lp55xx.txt
Device attribute: engine_mux
3 Engines are allocated in LP5562, but the number of channel is 4.
Therefore each channel should be mapped to the engine number.
Value : RGB or W
This attribute is used for programming LED data with the firmware interface.
Unlike the LP5521/LP5523/55231, LP5562 has unique feature for the engine mux,
so additional sysfs is required.
LED Map
Red ... Engine 1 (fixed)
Green ... Engine 2 (fixed)
Blue ... Engine 3 (fixed)
White ... Engine 1 or 2 or 3 (selective)
How to load the program data using engine_mux
Before loading the LP5562 program data, engine_mux should be written between
the engine selection and loading the firmware.
Engine mux has two different mode, RGB and W.
RGB is used for loading RGB program data, W is used for W program data.
For example, run blinking green channel pattern,
echo 2 > /sys/bus/i2c/devices/xxxx/select_engine # 2 is for green channel
echo "RGB" > /sys/bus/i2c/devices/xxxx/engine_mux # engine mux for RGB
echo 1 > /sys/class/firmware/lp5562/loading
echo "4000600040FF6000" > /sys/class/firmware/lp5562/data
echo 0 > /sys/class/firmware/lp5562/loading
echo 1 > /sys/bus/i2c/devices/xxxx/run_engine
To run a blinking white pattern,
echo 1 or 2 or 3 > /sys/bus/i2c/devices/xxxx/select_engine
echo "W" > /sys/bus/i2c/devices/xxxx/engine_mux
echo 1 > /sys/class/firmware/lp5562/loading
echo "4000600040FF6000" > /sys/class/firmware/lp5562/data
echo 0 > /sys/class/firmware/lp5562/loading
echo 1 > /sys/bus/i2c/devices/xxxx/run_engine
How to load the predefined patterns
Please refer to 'leds-lp55xx.txt"
Setting Current of Each Channel
Like LP5521 and LP5523/55231, LP5562 provides LED current settings.
The 'led_current' and 'max_current' are used.
(Example of Platform data)
To configure the platform specific data, lp55xx_platform_data structure is used.
static struct lp55xx_led_config lp5562_led_config[] = {
{
.name = "R",
.chan_nr = 0,
.led_current = 20,
.max_current = 40,
},
{
.name = "G",
.chan_nr = 1,
.led_current = 20,
.max_current = 40,
},
{
.name = "B",
.chan_nr = 2,
.led_current = 20,
.max_current = 40,
},
{
.name = "W",
.chan_nr = 3,
.led_current = 20,
.max_current = 40,
},
};
static int lp5562_setup(void)
{
/* setup HW resources */
}
static void lp5562_release(void)
{
/* Release HW resources */
}
static void lp5562_enable(bool state)
{
/* Control of chip enable signal */
}
static struct lp55xx_platform_data lp5562_platform_data = {
.led_config = lp5562_led_config,
.num_channels = ARRAY_SIZE(lp5562_led_config),
.setup_resources = lp5562_setup,
.release_resources = lp5562_release,
.enable = lp5562_enable,
};
If the current is set to 0 in the platform data, that channel is
disabled and it is not visible in the sysfs.

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=================================================
LP5521/LP5523/LP55231/LP5562/LP8501 Common Driver
=================================================
Authors: Milo(Woogyom) Kim <milo.kim@ti.com>
Description
-----------
LP5521, LP5523/55231, LP5562 and LP8501 have common features as below.
Register access via the I2C
Device initialization/deinitialization
Create LED class devices for multiple output channels
Device attributes for user-space interface
Program memory for running LED patterns
The LP55xx common driver provides these features using exported functions.
lp55xx_init_device() / lp55xx_deinit_device()
lp55xx_register_leds() / lp55xx_unregister_leds()
lp55xx_regsister_sysfs() / lp55xx_unregister_sysfs()
( Driver Structure Data )
In lp55xx common driver, two different data structure is used.
* lp55xx_led
control multi output LED channels such as led current, channel index.
* lp55xx_chip
general chip control such like the I2C and platform data.
For example, LP5521 has maximum 3 LED channels.
LP5523/55231 has 9 output channels::
lp55xx_chip for LP5521 ... lp55xx_led #1
lp55xx_led #2
lp55xx_led #3
lp55xx_chip for LP5523 ... lp55xx_led #1
lp55xx_led #2
.
.
lp55xx_led #9
( Chip Dependent Code )
To support device specific configurations, special structure
'lpxx_device_config' is used.
- Maximum number of channels
- Reset command, chip enable command
- Chip specific initialization
- Brightness control register access
- Setting LED output current
- Program memory address access for running patterns
- Additional device specific attributes
( Firmware Interface )
LP55xx family devices have the internal program memory for running
various LED patterns.
This pattern data is saved as a file in the user-land or
hex byte string is written into the memory through the I2C.
LP55xx common driver supports the firmware interface.
LP55xx chips have three program engines.
To load and run the pattern, the programming sequence is following.
(1) Select an engine number (1/2/3)
(2) Mode change to load
(3) Write pattern data into selected area
(4) Mode change to run
The LP55xx common driver provides simple interfaces as below.
select_engine:
Select which engine is used for running program
run_engine:
Start program which is loaded via the firmware interface
firmware:
Load program data
In case of LP5523, one more command is required, 'enginex_leds'.
It is used for selecting LED output(s) at each engine number.
In more details, please refer to 'leds-lp5523.txt'.
For example, run blinking pattern in engine #1 of LP5521::
echo 1 > /sys/bus/i2c/devices/xxxx/select_engine
echo 1 > /sys/class/firmware/lp5521/loading
echo "4000600040FF6000" > /sys/class/firmware/lp5521/data
echo 0 > /sys/class/firmware/lp5521/loading
echo 1 > /sys/bus/i2c/devices/xxxx/run_engine
For example, run blinking pattern in engine #3 of LP55231
Two LEDs are configured as pattern output channels::
echo 3 > /sys/bus/i2c/devices/xxxx/select_engine
echo 1 > /sys/class/firmware/lp55231/loading
echo "9d0740ff7e0040007e00a0010000" > /sys/class/firmware/lp55231/data
echo 0 > /sys/class/firmware/lp55231/loading
echo "000001100" > /sys/bus/i2c/devices/xxxx/engine3_leds
echo 1 > /sys/bus/i2c/devices/xxxx/run_engine
To start blinking patterns in engine #2 and #3 simultaneously::
for idx in 2 3
do
echo $idx > /sys/class/leds/red/device/select_engine
sleep 0.1
echo 1 > /sys/class/firmware/lp5521/loading
echo "4000600040FF6000" > /sys/class/firmware/lp5521/data
echo 0 > /sys/class/firmware/lp5521/loading
done
echo 1 > /sys/class/leds/red/device/run_engine
Here is another example for LP5523.
Full LED strings are selected by 'engine2_leds'::
echo 2 > /sys/bus/i2c/devices/xxxx/select_engine
echo 1 > /sys/class/firmware/lp5523/loading
echo "9d80400004ff05ff437f0000" > /sys/class/firmware/lp5523/data
echo 0 > /sys/class/firmware/lp5523/loading
echo "111111111" > /sys/bus/i2c/devices/xxxx/engine2_leds
echo 1 > /sys/bus/i2c/devices/xxxx/run_engine
As soon as 'loading' is set to 0, registered callback is called.
Inside the callback, the selected engine is loaded and memory is updated.
To run programmed pattern, 'run_engine' attribute should be enabled.
The pattern sequence of LP8501 is similar to LP5523.
However pattern data is specific.
Ex 1) Engine 1 is used::
echo 1 > /sys/bus/i2c/devices/xxxx/select_engine
echo 1 > /sys/class/firmware/lp8501/loading
echo "9d0140ff7e0040007e00a001c000" > /sys/class/firmware/lp8501/data
echo 0 > /sys/class/firmware/lp8501/loading
echo 1 > /sys/bus/i2c/devices/xxxx/run_engine
Ex 2) Engine 2 and 3 are used at the same time::
echo 2 > /sys/bus/i2c/devices/xxxx/select_engine
sleep 1
echo 1 > /sys/class/firmware/lp8501/loading
echo "9d0140ff7e0040007e00a001c000" > /sys/class/firmware/lp8501/data
echo 0 > /sys/class/firmware/lp8501/loading
sleep 1
echo 3 > /sys/bus/i2c/devices/xxxx/select_engine
sleep 1
echo 1 > /sys/class/firmware/lp8501/loading
echo "9d0340ff7e0040007e00a001c000" > /sys/class/firmware/lp8501/data
echo 0 > /sys/class/firmware/lp8501/loading
sleep 1
echo 1 > /sys/class/leds/d1/device/run_engine
( 'run_engine' and 'firmware_cb' )
The sequence of running the program data is common.
But each device has own specific register addresses for commands.
To support this, 'run_engine' and 'firmware_cb' are configurable in each driver.
run_engine:
Control the selected engine
firmware_cb:
The callback function after loading the firmware is done.
Chip specific commands for loading and updating program memory.
( Predefined pattern data )
Without the firmware interface, LP55xx driver provides another method for
loading a LED pattern. That is 'predefined' pattern.
A predefined pattern is defined in the platform data and load it(or them)
via the sysfs if needed.
To use the predefined pattern concept, 'patterns' and 'num_patterns' should be
configured.
Example of predefined pattern data::
/* mode_1: blinking data */
static const u8 mode_1[] = {
0x40, 0x00, 0x60, 0x00, 0x40, 0xFF, 0x60, 0x00,
};
/* mode_2: always on */
static const u8 mode_2[] = { 0x40, 0xFF, };
struct lp55xx_predef_pattern board_led_patterns[] = {
{
.r = mode_1,
.size_r = ARRAY_SIZE(mode_1),
},
{
.b = mode_2,
.size_b = ARRAY_SIZE(mode_2),
},
}
struct lp55xx_platform_data lp5562_pdata = {
...
.patterns = board_led_patterns,
.num_patterns = ARRAY_SIZE(board_led_patterns),
};
Then, mode_1 and mode_2 can be run via through the sysfs::
echo 1 > /sys/bus/i2c/devices/xxxx/led_pattern # red blinking LED pattern
echo 2 > /sys/bus/i2c/devices/xxxx/led_pattern # blue LED always on
To stop running pattern::
echo 0 > /sys/bus/i2c/devices/xxxx/led_pattern

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LP5521/LP5523/LP55231/LP5562/LP8501 Common Driver
=================================================
Authors: Milo(Woogyom) Kim <milo.kim@ti.com>
Description
-----------
LP5521, LP5523/55231, LP5562 and LP8501 have common features as below.
Register access via the I2C
Device initialization/deinitialization
Create LED class devices for multiple output channels
Device attributes for user-space interface
Program memory for running LED patterns
The LP55xx common driver provides these features using exported functions.
lp55xx_init_device() / lp55xx_deinit_device()
lp55xx_register_leds() / lp55xx_unregister_leds()
lp55xx_regsister_sysfs() / lp55xx_unregister_sysfs()
( Driver Structure Data )
In lp55xx common driver, two different data structure is used.
o lp55xx_led
control multi output LED channels such as led current, channel index.
o lp55xx_chip
general chip control such like the I2C and platform data.
For example, LP5521 has maximum 3 LED channels.
LP5523/55231 has 9 output channels.
lp55xx_chip for LP5521 ... lp55xx_led #1
lp55xx_led #2
lp55xx_led #3
lp55xx_chip for LP5523 ... lp55xx_led #1
lp55xx_led #2
.
.
lp55xx_led #9
( Chip Dependent Code )
To support device specific configurations, special structure
'lpxx_device_config' is used.
Maximum number of channels
Reset command, chip enable command
Chip specific initialization
Brightness control register access
Setting LED output current
Program memory address access for running patterns
Additional device specific attributes
( Firmware Interface )
LP55xx family devices have the internal program memory for running
various LED patterns.
This pattern data is saved as a file in the user-land or
hex byte string is written into the memory through the I2C.
LP55xx common driver supports the firmware interface.
LP55xx chips have three program engines.
To load and run the pattern, the programming sequence is following.
(1) Select an engine number (1/2/3)
(2) Mode change to load
(3) Write pattern data into selected area
(4) Mode change to run
The LP55xx common driver provides simple interfaces as below.
select_engine : Select which engine is used for running program
run_engine : Start program which is loaded via the firmware interface
firmware : Load program data
In case of LP5523, one more command is required, 'enginex_leds'.
It is used for selecting LED output(s) at each engine number.
In more details, please refer to 'leds-lp5523.txt'.
For example, run blinking pattern in engine #1 of LP5521
echo 1 > /sys/bus/i2c/devices/xxxx/select_engine
echo 1 > /sys/class/firmware/lp5521/loading
echo "4000600040FF6000" > /sys/class/firmware/lp5521/data
echo 0 > /sys/class/firmware/lp5521/loading
echo 1 > /sys/bus/i2c/devices/xxxx/run_engine
For example, run blinking pattern in engine #3 of LP55231
Two LEDs are configured as pattern output channels.
echo 3 > /sys/bus/i2c/devices/xxxx/select_engine
echo 1 > /sys/class/firmware/lp55231/loading
echo "9d0740ff7e0040007e00a0010000" > /sys/class/firmware/lp55231/data
echo 0 > /sys/class/firmware/lp55231/loading
echo "000001100" > /sys/bus/i2c/devices/xxxx/engine3_leds
echo 1 > /sys/bus/i2c/devices/xxxx/run_engine
To start blinking patterns in engine #2 and #3 simultaneously,
for idx in 2 3
do
echo $idx > /sys/class/leds/red/device/select_engine
sleep 0.1
echo 1 > /sys/class/firmware/lp5521/loading
echo "4000600040FF6000" > /sys/class/firmware/lp5521/data
echo 0 > /sys/class/firmware/lp5521/loading
done
echo 1 > /sys/class/leds/red/device/run_engine
Here is another example for LP5523.
Full LED strings are selected by 'engine2_leds'.
echo 2 > /sys/bus/i2c/devices/xxxx/select_engine
echo 1 > /sys/class/firmware/lp5523/loading
echo "9d80400004ff05ff437f0000" > /sys/class/firmware/lp5523/data
echo 0 > /sys/class/firmware/lp5523/loading
echo "111111111" > /sys/bus/i2c/devices/xxxx/engine2_leds
echo 1 > /sys/bus/i2c/devices/xxxx/run_engine
As soon as 'loading' is set to 0, registered callback is called.
Inside the callback, the selected engine is loaded and memory is updated.
To run programmed pattern, 'run_engine' attribute should be enabled.
The pattern sequence of LP8501 is similar to LP5523.
However pattern data is specific.
Ex 1) Engine 1 is used
echo 1 > /sys/bus/i2c/devices/xxxx/select_engine
echo 1 > /sys/class/firmware/lp8501/loading
echo "9d0140ff7e0040007e00a001c000" > /sys/class/firmware/lp8501/data
echo 0 > /sys/class/firmware/lp8501/loading
echo 1 > /sys/bus/i2c/devices/xxxx/run_engine
Ex 2) Engine 2 and 3 are used at the same time
echo 2 > /sys/bus/i2c/devices/xxxx/select_engine
sleep 1
echo 1 > /sys/class/firmware/lp8501/loading
echo "9d0140ff7e0040007e00a001c000" > /sys/class/firmware/lp8501/data
echo 0 > /sys/class/firmware/lp8501/loading
sleep 1
echo 3 > /sys/bus/i2c/devices/xxxx/select_engine
sleep 1
echo 1 > /sys/class/firmware/lp8501/loading
echo "9d0340ff7e0040007e00a001c000" > /sys/class/firmware/lp8501/data
echo 0 > /sys/class/firmware/lp8501/loading
sleep 1
echo 1 > /sys/class/leds/d1/device/run_engine
( 'run_engine' and 'firmware_cb' )
The sequence of running the program data is common.
But each device has own specific register addresses for commands.
To support this, 'run_engine' and 'firmware_cb' are configurable in each driver.
run_engine : Control the selected engine
firmware_cb : The callback function after loading the firmware is done.
Chip specific commands for loading and updating program memory.
( Predefined pattern data )
Without the firmware interface, LP55xx driver provides another method for
loading a LED pattern. That is 'predefined' pattern.
A predefined pattern is defined in the platform data and load it(or them)
via the sysfs if needed.
To use the predefined pattern concept, 'patterns' and 'num_patterns' should be
configured.
Example of predefined pattern data:
/* mode_1: blinking data */
static const u8 mode_1[] = {
0x40, 0x00, 0x60, 0x00, 0x40, 0xFF, 0x60, 0x00,
};
/* mode_2: always on */
static const u8 mode_2[] = { 0x40, 0xFF, };
struct lp55xx_predef_pattern board_led_patterns[] = {
{
.r = mode_1,
.size_r = ARRAY_SIZE(mode_1),
},
{
.b = mode_2,
.size_b = ARRAY_SIZE(mode_2),
},
}
struct lp55xx_platform_data lp5562_pdata = {
...
.patterns = board_led_patterns,
.num_patterns = ARRAY_SIZE(board_led_patterns),
};
Then, mode_1 and mode_2 can be run via through the sysfs.
echo 1 > /sys/bus/i2c/devices/xxxx/led_pattern # red blinking LED pattern
echo 2 > /sys/bus/i2c/devices/xxxx/led_pattern # blue LED always on
To stop running pattern,
echo 0 > /sys/bus/i2c/devices/xxxx/led_pattern

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=======================================
Kernel driver for Mellanox systems LEDs
=======================================
Provide system LED support for the nex Mellanox systems:
"msx6710", "msx6720", "msb7700", "msn2700", "msx1410",
"msn2410", "msb7800", "msn2740", "msn2100".
Description
-----------
Driver provides the following LEDs for the systems "msx6710", "msx6720",
"msb7700", "msn2700", "msx1410", "msn2410", "msb7800", "msn2740":
- mlxcpld:fan1:green
- mlxcpld:fan1:red
- mlxcpld:fan2:green
- mlxcpld:fan2:red
- mlxcpld:fan3:green
- mlxcpld:fan3:red
- mlxcpld:fan4:green
- mlxcpld:fan4:red
- mlxcpld:psu:green
- mlxcpld:psu:red
- mlxcpld:status:green
- mlxcpld:status:red
"status"
- CPLD reg offset: 0x20
- Bits [3:0]
"psu"
- CPLD reg offset: 0x20
- Bits [7:4]
"fan1"
- CPLD reg offset: 0x21
- Bits [3:0]
"fan2"
- CPLD reg offset: 0x21
- Bits [7:4]
"fan3"
- CPLD reg offset: 0x22
- Bits [3:0]
"fan4"
- CPLD reg offset: 0x22
- Bits [7:4]
Color mask for all the above LEDs:
[bit3,bit2,bit1,bit0] or
[bit7,bit6,bit5,bit4]:
- [0,0,0,0] = LED OFF
- [0,1,0,1] = Red static ON
- [1,1,0,1] = Green static ON
- [0,1,1,0] = Red blink 3Hz
- [1,1,1,0] = Green blink 3Hz
- [0,1,1,1] = Red blink 6Hz
- [1,1,1,1] = Green blink 6Hz
Driver provides the following LEDs for the system "msn2100":
- mlxcpld:fan:green
- mlxcpld:fan:red
- mlxcpld:psu1:green
- mlxcpld:psu1:red
- mlxcpld:psu2:green
- mlxcpld:psu2:red
- mlxcpld:status:green
- mlxcpld:status:red
- mlxcpld:uid:blue
"status"
- CPLD reg offset: 0x20
- Bits [3:0]
"fan"
- CPLD reg offset: 0x21
- Bits [3:0]
"psu1"
- CPLD reg offset: 0x23
- Bits [3:0]
"psu2"
- CPLD reg offset: 0x23
- Bits [7:4]
"uid"
- CPLD reg offset: 0x24
- Bits [3:0]
Color mask for all the above LEDs, excepted uid:
[bit3,bit2,bit1,bit0] or
[bit7,bit6,bit5,bit4]:
- [0,0,0,0] = LED OFF
- [0,1,0,1] = Red static ON
- [1,1,0,1] = Green static ON
- [0,1,1,0] = Red blink 3Hz
- [1,1,1,0] = Green blink 3Hz
- [0,1,1,1] = Red blink 6Hz
- [1,1,1,1] = Green blink 6Hz
Color mask for uid LED:
[bit3,bit2,bit1,bit0]:
- [0,0,0,0] = LED OFF
- [1,1,0,1] = Blue static ON
- [1,1,1,0] = Blue blink 3Hz
- [1,1,1,1] = Blue blink 6Hz
Driver supports HW blinking at 3Hz and 6Hz frequency (50% duty cycle).
For 3Hz duty cylce is about 167 msec, for 6Hz is about 83 msec.

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@ -1,110 +0,0 @@
Kernel driver for Mellanox systems LEDs
=======================================
Provide system LED support for the nex Mellanox systems:
"msx6710", "msx6720", "msb7700", "msn2700", "msx1410",
"msn2410", "msb7800", "msn2740", "msn2100".
Description
-----------
Driver provides the following LEDs for the systems "msx6710", "msx6720",
"msb7700", "msn2700", "msx1410", "msn2410", "msb7800", "msn2740":
mlxcpld:fan1:green
mlxcpld:fan1:red
mlxcpld:fan2:green
mlxcpld:fan2:red
mlxcpld:fan3:green
mlxcpld:fan3:red
mlxcpld:fan4:green
mlxcpld:fan4:red
mlxcpld:psu:green
mlxcpld:psu:red
mlxcpld:status:green
mlxcpld:status:red
"status"
CPLD reg offset: 0x20
Bits [3:0]
"psu"
CPLD reg offset: 0x20
Bits [7:4]
"fan1"
CPLD reg offset: 0x21
Bits [3:0]
"fan2"
CPLD reg offset: 0x21
Bits [7:4]
"fan3"
CPLD reg offset: 0x22
Bits [3:0]
"fan4"
CPLD reg offset: 0x22
Bits [7:4]
Color mask for all the above LEDs:
[bit3,bit2,bit1,bit0] or
[bit7,bit6,bit5,bit4]:
[0,0,0,0] = LED OFF
[0,1,0,1] = Red static ON
[1,1,0,1] = Green static ON
[0,1,1,0] = Red blink 3Hz
[1,1,1,0] = Green blink 3Hz
[0,1,1,1] = Red blink 6Hz
[1,1,1,1] = Green blink 6Hz
Driver provides the following LEDs for the system "msn2100":
mlxcpld:fan:green
mlxcpld:fan:red
mlxcpld:psu1:green
mlxcpld:psu1:red
mlxcpld:psu2:green
mlxcpld:psu2:red
mlxcpld:status:green
mlxcpld:status:red
mlxcpld:uid:blue
"status"
CPLD reg offset: 0x20
Bits [3:0]
"fan"
CPLD reg offset: 0x21
Bits [3:0]
"psu1"
CPLD reg offset: 0x23
Bits [3:0]
"psu2"
CPLD reg offset: 0x23
Bits [7:4]
"uid"
CPLD reg offset: 0x24
Bits [3:0]
Color mask for all the above LEDs, excepted uid:
[bit3,bit2,bit1,bit0] or
[bit7,bit6,bit5,bit4]:
[0,0,0,0] = LED OFF
[0,1,0,1] = Red static ON
[1,1,0,1] = Green static ON
[0,1,1,0] = Red blink 3Hz
[1,1,1,0] = Green blink 3Hz
[0,1,1,1] = Red blink 6Hz
[1,1,1,1] = Green blink 6Hz
Color mask for uid LED:
[bit3,bit2,bit1,bit0]:
[0,0,0,0] = LED OFF
[1,1,0,1] = Blue static ON
[1,1,1,0] = Blue blink 3Hz
[1,1,1,1] = Blue blink 6Hz
Driver supports HW blinking at 3Hz and 6Hz frequency (50% duty cycle).
For 3Hz duty cylce is about 167 msec, for 6Hz is about 83 msec.

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@ -1,3 +1,4 @@
====================
One-shot LED Trigger
====================
@ -17,27 +18,27 @@ additional "invert" property specifies if the LED has to stay off (normal) or
on (inverted) when not rearmed.
The trigger can be activated from user space on led class devices as shown
below:
below::
echo oneshot > trigger
This adds sysfs attributes to the LED that are documented in:
Documentation/ABI/testing/sysfs-class-led-trigger-oneshot
Example use-case: network devices, initialization:
Example use-case: network devices, initialization::
echo oneshot > trigger # set trigger for this led
echo 33 > delay_on # blink at 1 / (33 + 33) Hz on continuous traffic
echo 33 > delay_off
interface goes up:
interface goes up::
echo 1 > invert # set led as normally-on, turn the led on
packet received/transmitted:
packet received/transmitted::
echo 1 > shot # led starts blinking, ignored if already blinking
interface goes down
interface goes down::
echo 0 > invert # set led as normally-off, turn the led off

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@ -1,3 +1,4 @@
=====================
LED Transient Trigger
=====================
@ -62,12 +63,13 @@ non-transient state. When driver gets suspended, irrespective of the transient
state, the LED state changes to LED_OFF.
Transient trigger can be enabled and disabled from user space on led class
devices, that support this trigger as shown below:
devices, that support this trigger as shown below::
echo transient > trigger
echo none > trigger
echo transient > trigger
echo none > trigger
NOTE: Add a new property trigger state to control the state.
NOTE:
Add a new property trigger state to control the state.
This trigger exports three properties, activate, state, and duration. When
transient trigger is activated these properties are set to default values.
@ -79,7 +81,8 @@ transient trigger is activated these properties are set to default values.
- state allows user to specify a transient state to be held for the specified
duration.
activate - one shot timer activate mechanism.
activate
- one shot timer activate mechanism.
1 when activated, 0 when deactivated.
default value is zero when transient trigger is enabled,
to allow duration to be set.
@ -89,12 +92,14 @@ transient trigger is activated these properties are set to default values.
deactivated state indicates that there is no active timer
running.
duration - one shot timer value. When activate is set, duration value
duration
- one shot timer value. When activate is set, duration value
is used to start a timer that runs once. This value doesn't
get changed by the trigger unless user does a set via
echo new_value > duration
state - transient state to be held. It has two values 0 or 1. 0 maps
state
- transient state to be held. It has two values 0 or 1. 0 maps
to LED_OFF and 1 maps to LED_FULL. The specified state is
held for the duration of the one shot timer and then the
state gets changed to the non-transient state which is the
@ -114,39 +119,49 @@ When timer expires activate goes back to deactivated state, duration is left
at the set value to be used when activate is set at a future time. This will
allow user app to set the time once and activate it to run it once for the
specified value as needed. When timer expires, state is restored to the
non-transient state which is the inverse of the transient state.
non-transient state which is the inverse of the transient state:
echo 1 > activate - starts timer = duration when duration is not 0.
echo 0 > activate - cancels currently running timer.
echo n > duration - stores timer value to be used upon next
activate. Currently active timer if
any, continues to run for the specified time.
echo 0 > duration - stores timer value to be used upon next
activate. Currently active timer if any,
continues to run for the specified time.
echo 1 > state - stores desired transient state LED_FULL to be
================= ===============================================
echo 1 > activate starts timer = duration when duration is not 0.
echo 0 > activate cancels currently running timer.
echo n > duration stores timer value to be used upon next
activate. Currently active timer if
any, continues to run for the specified time.
echo 0 > duration stores timer value to be used upon next
activate. Currently active timer if any,
continues to run for the specified time.
echo 1 > state stores desired transient state LED_FULL to be
held for the specified duration.
echo 0 > state - stores desired transient state LED_OFF to be
echo 0 > state stores desired transient state LED_OFF to be
held for the specified duration.
================= ===============================================
What is not supported
=====================
What is not supported:
======================
- Timer activation is one shot and extending and/or shortening the timer
is not supported.
Example use-case 1:
Examples
========
use-case 1::
echo transient > trigger
echo n > duration
echo 1 > state
repeat the following step as needed:
repeat the following step as needed::
echo 1 > activate - start timer = duration to run once
echo 1 > activate - start timer = duration to run once
echo none > trigger
This trigger is intended to be used for for the following example use cases:
- Control of vibrate (phones, tablets etc.) hardware by user space app.
- Use of LED by user space app as activity indicator.
- Use of LED by user space app as a kind of watchdog indicator -- as
long as the app is alive, it can keep the LED illuminated, if it dies
the LED will be extinguished automatically.
long as the app is alive, it can keep the LED illuminated, if it dies
the LED will be extinguished automatically.
- Use by any user space app that needs a transient GPIO output.

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@ -1,3 +1,4 @@
====================
USB port LED trigger
====================
@ -10,14 +11,18 @@ listed as separated entries in a "ports" subdirectory. Selecting is handled by
echoing "1" to a chosen port.
Please note that this trigger allows selecting multiple USB ports for a single
LED. This can be useful in two cases:
LED.
This can be useful in two cases:
1) Device with single USB LED and few physical ports
====================================================
In such a case LED will be turned on as long as there is at least one connected
USB device.
2) Device with a physical port handled by few controllers
=========================================================
Some devices may have one controller per PHY standard. E.g. USB 3.0 physical
port may be handled by ohci-platform, ehci-platform and xhci-hcd. If there is
@ -25,14 +30,14 @@ only one LED user will most likely want to assign ports from all 3 hubs.
This trigger can be activated from user space on led class devices as shown
below:
below::
echo usbport > trigger
This adds sysfs attributes to the LED that are documented in:
Documentation/ABI/testing/sysfs-class-led-trigger-usbport
Example use-case:
Example use-case::
echo usbport > trigger
echo 1 > ports/usb1-port1

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@ -1,3 +1,4 @@
==============
Userspace LEDs
==============
@ -10,12 +11,12 @@ Usage
When the driver is loaded, a character device is created at /dev/uleds. To
create a new LED class device, open /dev/uleds and write a uleds_user_dev
structure to it (found in kernel public header file linux/uleds.h).
structure to it (found in kernel public header file linux/uleds.h)::
#define LED_MAX_NAME_SIZE 64
struct uleds_user_dev {
char name[LED_MAX_NAME_SIZE];
char name[LED_MAX_NAME_SIZE];
};
A new LED class device will be created with the name given. The name can be

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@ -10117,7 +10117,7 @@ L: linux-leds@vger.kernel.org
S: Supported
F: drivers/leds/leds-mlxcpld.c
F: drivers/leds/leds-mlxreg.c
F: Documentation/leds/leds-mlxcpld.txt
F: Documentation/leds/leds-mlxcpld.rst
MELLANOX PLATFORM DRIVER
M: Vadim Pasternak <vadimp@mellanox.com>

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@ -14,7 +14,7 @@ config LEDS_TRIGGER_TIMER
This allows LEDs to be controlled by a programmable timer
via sysfs. Some LED hardware can be programmed to start
blinking the LED without any further software interaction.
For more details read Documentation/leds/leds-class.txt.
For more details read Documentation/leds/leds-class.rst.
If unsure, say Y.

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@ -3,7 +3,7 @@
// LED Kernel Transient Trigger
//
// Transient trigger allows one shot timer activation. Please refer to
// Documentation/leds/ledtrig-transient.txt for details
// Documentation/leds/ledtrig-transient.rst for details
// Copyright (C) 2012 Shuah Khan <shuahkhan@gmail.com>
//
// Based on Richard Purdie's ledtrig-timer.c and Atsushi Nemoto's

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@ -905,7 +905,7 @@ config NETFILTER_XT_TARGET_LED
echo netfilter-ssh > /sys/class/leds/<ledname>/trigger
For more information on the LEDs available on your system, see
Documentation/leds/leds-class.txt
Documentation/leds/leds-class.rst
config NETFILTER_XT_TARGET_LOG
tristate "LOG target support"