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linux-stable/drivers/leds/rgb/leds-qcom-lpg.c
Uwe Kleine-König 6061302092 leds: Convert all platform drivers to return void 
The .remove() callback for a platform driver returns an int which makes
many driver authors wrongly assume it's possible to do error handling by
returning an error code. However the value returned is ignored (apart
from emitting a warning) and this typically results in resource leaks.
To improve here there is a quest to make the remove callback return
void. In the first step of this quest all drivers are converted to
.remove_new() which already returns void. Eventually after all drivers
are converted, .remove_new() is renamed to .remove().

All platform drivers below drivers/leds/ unconditionally return zero in
their remove callback and so can be converted trivially to the variant
returning void.

Signed-off-by: Uwe Kleine-König <u.kleine-koenig@pengutronix.de>
Link: https://lore.kernel.org/r/20230917130947.1122198-1-u.kleine-koenig@pengutronix.de
Signed-off-by: Lee Jones <lee@kernel.org>
2023-11-01 11:28:35 +00:00

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// SPDX-License-Identifier: GPL-2.0-only
/*
* Copyright (c) 2017-2022 Linaro Ltd
* Copyright (c) 2010-2012, The Linux Foundation. All rights reserved.
* Copyright (c) 2023, Qualcomm Innovation Center, Inc. All rights reserved.
*/
#include <linux/bits.h>
#include <linux/bitfield.h>
#include <linux/led-class-multicolor.h>
#include <linux/module.h>
#include <linux/of.h>
#include <linux/platform_device.h>
#include <linux/pwm.h>
#include <linux/regmap.h>
#include <linux/slab.h>
#define LPG_SUBTYPE_REG 0x05
#define LPG_SUBTYPE_LPG 0x2
#define LPG_SUBTYPE_PWM 0xb
#define LPG_SUBTYPE_HI_RES_PWM 0xc
#define LPG_SUBTYPE_LPG_LITE 0x11
#define LPG_PATTERN_CONFIG_REG 0x40
#define LPG_SIZE_CLK_REG 0x41
#define PWM_CLK_SELECT_MASK GENMASK(1, 0)
#define PWM_CLK_SELECT_HI_RES_MASK GENMASK(2, 0)
#define PWM_SIZE_HI_RES_MASK GENMASK(6, 4)
#define LPG_PREDIV_CLK_REG 0x42
#define PWM_FREQ_PRE_DIV_MASK GENMASK(6, 5)
#define PWM_FREQ_EXP_MASK GENMASK(2, 0)
#define PWM_TYPE_CONFIG_REG 0x43
#define PWM_VALUE_REG 0x44
#define PWM_ENABLE_CONTROL_REG 0x46
#define PWM_SYNC_REG 0x47
#define LPG_RAMP_DURATION_REG 0x50
#define LPG_HI_PAUSE_REG 0x52
#define LPG_LO_PAUSE_REG 0x54
#define LPG_HI_IDX_REG 0x56
#define LPG_LO_IDX_REG 0x57
#define PWM_SEC_ACCESS_REG 0xd0
#define PWM_DTEST_REG(x) (0xe2 + (x) - 1)
#define TRI_LED_SRC_SEL 0x45
#define TRI_LED_EN_CTL 0x46
#define TRI_LED_ATC_CTL 0x47
#define LPG_LUT_REG(x) (0x40 + (x) * 2)
#define RAMP_CONTROL_REG 0xc8
#define LPG_RESOLUTION_9BIT BIT(9)
#define LPG_RESOLUTION_15BIT BIT(15)
#define LPG_MAX_M 7
#define LPG_MAX_PREDIV 6
struct lpg_channel;
struct lpg_data;
/**
* struct lpg - LPG device context
* @dev: pointer to LPG device
* @map: regmap for register access
* @lock: used to synchronize LED and pwm callback requests
* @pwm: PWM-chip object, if operating in PWM mode
* @data: reference to version specific data
* @lut_base: base address of the LUT block (optional)
* @lut_size: number of entries in the LUT block
* @lut_bitmap: allocation bitmap for LUT entries
* @triled_base: base address of the TRILED block (optional)
* @triled_src: power-source for the TRILED
* @triled_has_atc_ctl: true if there is TRI_LED_ATC_CTL register
* @triled_has_src_sel: true if there is TRI_LED_SRC_SEL register
* @channels: list of PWM channels
* @num_channels: number of @channels
*/
struct lpg {
struct device *dev;
struct regmap *map;
struct mutex lock;
struct pwm_chip pwm;
const struct lpg_data *data;
u32 lut_base;
u32 lut_size;
unsigned long *lut_bitmap;
u32 triled_base;
u32 triled_src;
bool triled_has_atc_ctl;
bool triled_has_src_sel;
struct lpg_channel *channels;
unsigned int num_channels;
};
/**
* struct lpg_channel - per channel data
* @lpg: reference to parent lpg
* @base: base address of the PWM channel
* @triled_mask: mask in TRILED to enable this channel
* @lut_mask: mask in LUT to start pattern generator for this channel
* @subtype: PMIC hardware block subtype
* @in_use: channel is exposed to LED framework
* @color: color of the LED attached to this channel
* @dtest_line: DTEST line for output, or 0 if disabled
* @dtest_value: DTEST line configuration
* @pwm_value: duty (in microseconds) of the generated pulses, overridden by LUT
* @enabled: output enabled?
* @period: period (in nanoseconds) of the generated pulses
* @clk_sel: reference clock frequency selector
* @pre_div_sel: divider selector of the reference clock
* @pre_div_exp: exponential divider of the reference clock
* @pwm_resolution_sel: pwm resolution selector
* @ramp_enabled: duty cycle is driven by iterating over lookup table
* @ramp_ping_pong: reverse through pattern, rather than wrapping to start
* @ramp_oneshot: perform only a single pass over the pattern
* @ramp_reverse: iterate over pattern backwards
* @ramp_tick_ms: length (in milliseconds) of one step in the pattern
* @ramp_lo_pause_ms: pause (in milliseconds) before iterating over pattern
* @ramp_hi_pause_ms: pause (in milliseconds) after iterating over pattern
* @pattern_lo_idx: start index of associated pattern
* @pattern_hi_idx: last index of associated pattern
*/
struct lpg_channel {
struct lpg *lpg;
u32 base;
unsigned int triled_mask;
unsigned int lut_mask;
unsigned int subtype;
bool in_use;
int color;
u32 dtest_line;
u32 dtest_value;
u16 pwm_value;
bool enabled;
u64 period;
unsigned int clk_sel;
unsigned int pre_div_sel;
unsigned int pre_div_exp;
unsigned int pwm_resolution_sel;
bool ramp_enabled;
bool ramp_ping_pong;
bool ramp_oneshot;
bool ramp_reverse;
unsigned short ramp_tick_ms;
unsigned long ramp_lo_pause_ms;
unsigned long ramp_hi_pause_ms;
unsigned int pattern_lo_idx;
unsigned int pattern_hi_idx;
};
/**
* struct lpg_led - logical LED object
* @lpg: lpg context reference
* @cdev: LED class device
* @mcdev: Multicolor LED class device
* @num_channels: number of @channels
* @channels: list of channels associated with the LED
*/
struct lpg_led {
struct lpg *lpg;
struct led_classdev cdev;
struct led_classdev_mc mcdev;
unsigned int num_channels;
struct lpg_channel *channels[] __counted_by(num_channels);
};
/**
* struct lpg_channel_data - per channel initialization data
* @base: base address for PWM channel registers
* @triled_mask: bitmask for controlling this channel in TRILED
*/
struct lpg_channel_data {
unsigned int base;
u8 triled_mask;
};
/**
* struct lpg_data - initialization data
* @lut_base: base address of LUT block
* @lut_size: number of entries in LUT
* @triled_base: base address of TRILED
* @triled_has_atc_ctl: true if there is TRI_LED_ATC_CTL register
* @triled_has_src_sel: true if there is TRI_LED_SRC_SEL register
* @num_channels: number of channels in LPG
* @channels: list of channel initialization data
*/
struct lpg_data {
unsigned int lut_base;
unsigned int lut_size;
unsigned int triled_base;
bool triled_has_atc_ctl;
bool triled_has_src_sel;
int num_channels;
const struct lpg_channel_data *channels;
};
static int triled_set(struct lpg *lpg, unsigned int mask, unsigned int enable)
{
/* Skip if we don't have a triled block */
if (!lpg->triled_base)
return 0;
return regmap_update_bits(lpg->map, lpg->triled_base + TRI_LED_EN_CTL,
mask, enable);
}
static int lpg_lut_store(struct lpg *lpg, struct led_pattern *pattern,
size_t len, unsigned int *lo_idx, unsigned int *hi_idx)
{
unsigned int idx;
u16 val;
int i;
idx = bitmap_find_next_zero_area(lpg->lut_bitmap, lpg->lut_size,
0, len, 0);
if (idx >= lpg->lut_size)
return -ENOMEM;
for (i = 0; i < len; i++) {
val = pattern[i].brightness;
regmap_bulk_write(lpg->map, lpg->lut_base + LPG_LUT_REG(idx + i),
&val, sizeof(val));
}
bitmap_set(lpg->lut_bitmap, idx, len);
*lo_idx = idx;
*hi_idx = idx + len - 1;
return 0;
}
static void lpg_lut_free(struct lpg *lpg, unsigned int lo_idx, unsigned int hi_idx)
{
int len;
len = hi_idx - lo_idx + 1;
if (len == 1)
return;
bitmap_clear(lpg->lut_bitmap, lo_idx, len);
}
static int lpg_lut_sync(struct lpg *lpg, unsigned int mask)
{
return regmap_write(lpg->map, lpg->lut_base + RAMP_CONTROL_REG, mask);
}
static const unsigned int lpg_clk_rates[] = {0, 1024, 32768, 19200000};
static const unsigned int lpg_clk_rates_hi_res[] = {0, 1024, 32768, 19200000, 76800000};
static const unsigned int lpg_pre_divs[] = {1, 3, 5, 6};
static const unsigned int lpg_pwm_resolution[] = {9};
static const unsigned int lpg_pwm_resolution_hi_res[] = {8, 9, 10, 11, 12, 13, 14, 15};
static int lpg_calc_freq(struct lpg_channel *chan, uint64_t period)
{
unsigned int i, pwm_resolution_count, best_pwm_resolution_sel = 0;
const unsigned int *clk_rate_arr, *pwm_resolution_arr;
unsigned int clk_sel, clk_len, best_clk = 0;
unsigned int div, best_div = 0;
unsigned int m, best_m = 0;
unsigned int resolution;
unsigned int error;
unsigned int best_err = UINT_MAX;
u64 max_period, min_period;
u64 best_period = 0;
u64 max_res;
/*
* The PWM period is determined by:
*
* resolution * pre_div * 2^M
* period = --------------------------
* refclk
*
* Resolution = 2^9 bits for PWM or
* 2^{8, 9, 10, 11, 12, 13, 14, 15} bits for high resolution PWM
* pre_div = {1, 3, 5, 6} and
* M = [0..7].
*
* This allows for periods between 27uS and 384s for PWM channels and periods between
* 3uS and 24576s for high resolution PWMs.
* The PWM framework wants a period of equal or lower length than requested,
* reject anything below minimum period.
*/
if (chan->subtype == LPG_SUBTYPE_HI_RES_PWM) {
clk_rate_arr = lpg_clk_rates_hi_res;
clk_len = ARRAY_SIZE(lpg_clk_rates_hi_res);
pwm_resolution_arr = lpg_pwm_resolution_hi_res;
pwm_resolution_count = ARRAY_SIZE(lpg_pwm_resolution_hi_res);
max_res = LPG_RESOLUTION_15BIT;
} else {
clk_rate_arr = lpg_clk_rates;
clk_len = ARRAY_SIZE(lpg_clk_rates);
pwm_resolution_arr = lpg_pwm_resolution;
pwm_resolution_count = ARRAY_SIZE(lpg_pwm_resolution);
max_res = LPG_RESOLUTION_9BIT;
}
min_period = div64_u64((u64)NSEC_PER_SEC * (1 << pwm_resolution_arr[0]),
clk_rate_arr[clk_len - 1]);
if (period <= min_period)
return -EINVAL;
/* Limit period to largest possible value, to avoid overflows */
max_period = div64_u64((u64)NSEC_PER_SEC * max_res * LPG_MAX_PREDIV * (1 << LPG_MAX_M),
1024);
if (period > max_period)
period = max_period;
/*
* Search for the pre_div, refclk, resolution and M by solving the rewritten formula
* for each refclk, resolution and pre_div value:
*
* period * refclk
* M = log2 -------------------------------------
* NSEC_PER_SEC * pre_div * resolution
*/
for (i = 0; i < pwm_resolution_count; i++) {
resolution = 1 << pwm_resolution_arr[i];
for (clk_sel = 1; clk_sel < clk_len; clk_sel++) {
u64 numerator = period * clk_rate_arr[clk_sel];
for (div = 0; div < ARRAY_SIZE(lpg_pre_divs); div++) {
u64 denominator = (u64)NSEC_PER_SEC * lpg_pre_divs[div] *
resolution;
u64 actual;
u64 ratio;
if (numerator < denominator)
continue;
ratio = div64_u64(numerator, denominator);
m = ilog2(ratio);
if (m > LPG_MAX_M)
m = LPG_MAX_M;
actual = DIV_ROUND_UP_ULL(denominator * (1 << m),
clk_rate_arr[clk_sel]);
error = period - actual;
if (error < best_err) {
best_err = error;
best_div = div;
best_m = m;
best_clk = clk_sel;
best_period = actual;
best_pwm_resolution_sel = i;
}
}
}
}
chan->clk_sel = best_clk;
chan->pre_div_sel = best_div;
chan->pre_div_exp = best_m;
chan->period = best_period;
chan->pwm_resolution_sel = best_pwm_resolution_sel;
return 0;
}
static void lpg_calc_duty(struct lpg_channel *chan, uint64_t duty)
{
unsigned int max;
unsigned int val;
unsigned int clk_rate;
if (chan->subtype == LPG_SUBTYPE_HI_RES_PWM) {
max = LPG_RESOLUTION_15BIT - 1;
clk_rate = lpg_clk_rates_hi_res[chan->clk_sel];
} else {
max = LPG_RESOLUTION_9BIT - 1;
clk_rate = lpg_clk_rates[chan->clk_sel];
}
val = div64_u64(duty * clk_rate,
(u64)NSEC_PER_SEC * lpg_pre_divs[chan->pre_div_sel] * (1 << chan->pre_div_exp));
chan->pwm_value = min(val, max);
}
static void lpg_apply_freq(struct lpg_channel *chan)
{
unsigned long val;
struct lpg *lpg = chan->lpg;
if (!chan->enabled)
return;
val = chan->clk_sel;
/* Specify resolution, based on the subtype of the channel */
switch (chan->subtype) {
case LPG_SUBTYPE_LPG:
val |= GENMASK(5, 4);
break;
case LPG_SUBTYPE_PWM:
val |= BIT(2);
break;
case LPG_SUBTYPE_HI_RES_PWM:
val |= FIELD_PREP(PWM_SIZE_HI_RES_MASK, chan->pwm_resolution_sel);
break;
case LPG_SUBTYPE_LPG_LITE:
default:
val |= BIT(4);
break;
}
regmap_write(lpg->map, chan->base + LPG_SIZE_CLK_REG, val);
val = FIELD_PREP(PWM_FREQ_PRE_DIV_MASK, chan->pre_div_sel) |
FIELD_PREP(PWM_FREQ_EXP_MASK, chan->pre_div_exp);
regmap_write(lpg->map, chan->base + LPG_PREDIV_CLK_REG, val);
}
#define LPG_ENABLE_GLITCH_REMOVAL BIT(5)
static void lpg_enable_glitch(struct lpg_channel *chan)
{
struct lpg *lpg = chan->lpg;
regmap_update_bits(lpg->map, chan->base + PWM_TYPE_CONFIG_REG,
LPG_ENABLE_GLITCH_REMOVAL, 0);
}
static void lpg_disable_glitch(struct lpg_channel *chan)
{
struct lpg *lpg = chan->lpg;
regmap_update_bits(lpg->map, chan->base + PWM_TYPE_CONFIG_REG,
LPG_ENABLE_GLITCH_REMOVAL,
LPG_ENABLE_GLITCH_REMOVAL);
}
static void lpg_apply_pwm_value(struct lpg_channel *chan)
{
struct lpg *lpg = chan->lpg;
u16 val = chan->pwm_value;
if (!chan->enabled)
return;
regmap_bulk_write(lpg->map, chan->base + PWM_VALUE_REG, &val, sizeof(val));
}
#define LPG_PATTERN_CONFIG_LO_TO_HI BIT(4)
#define LPG_PATTERN_CONFIG_REPEAT BIT(3)
#define LPG_PATTERN_CONFIG_TOGGLE BIT(2)
#define LPG_PATTERN_CONFIG_PAUSE_HI BIT(1)
#define LPG_PATTERN_CONFIG_PAUSE_LO BIT(0)
static void lpg_apply_lut_control(struct lpg_channel *chan)
{
struct lpg *lpg = chan->lpg;
unsigned int hi_pause;
unsigned int lo_pause;
unsigned int conf = 0;
unsigned int lo_idx = chan->pattern_lo_idx;
unsigned int hi_idx = chan->pattern_hi_idx;
u16 step = chan->ramp_tick_ms;
if (!chan->ramp_enabled || chan->pattern_lo_idx == chan->pattern_hi_idx)
return;
hi_pause = DIV_ROUND_UP(chan->ramp_hi_pause_ms, step);
lo_pause = DIV_ROUND_UP(chan->ramp_lo_pause_ms, step);
if (!chan->ramp_reverse)
conf |= LPG_PATTERN_CONFIG_LO_TO_HI;
if (!chan->ramp_oneshot)
conf |= LPG_PATTERN_CONFIG_REPEAT;
if (chan->ramp_ping_pong)
conf |= LPG_PATTERN_CONFIG_TOGGLE;
if (chan->ramp_hi_pause_ms)
conf |= LPG_PATTERN_CONFIG_PAUSE_HI;
if (chan->ramp_lo_pause_ms)
conf |= LPG_PATTERN_CONFIG_PAUSE_LO;
regmap_write(lpg->map, chan->base + LPG_PATTERN_CONFIG_REG, conf);
regmap_write(lpg->map, chan->base + LPG_HI_IDX_REG, hi_idx);
regmap_write(lpg->map, chan->base + LPG_LO_IDX_REG, lo_idx);
regmap_bulk_write(lpg->map, chan->base + LPG_RAMP_DURATION_REG, &step, sizeof(step));
regmap_write(lpg->map, chan->base + LPG_HI_PAUSE_REG, hi_pause);
regmap_write(lpg->map, chan->base + LPG_LO_PAUSE_REG, lo_pause);
}
#define LPG_ENABLE_CONTROL_OUTPUT BIT(7)
#define LPG_ENABLE_CONTROL_BUFFER_TRISTATE BIT(5)
#define LPG_ENABLE_CONTROL_SRC_PWM BIT(2)
#define LPG_ENABLE_CONTROL_RAMP_GEN BIT(1)
static void lpg_apply_control(struct lpg_channel *chan)
{
unsigned int ctrl;
struct lpg *lpg = chan->lpg;
ctrl = LPG_ENABLE_CONTROL_BUFFER_TRISTATE;
if (chan->enabled)
ctrl |= LPG_ENABLE_CONTROL_OUTPUT;
if (chan->pattern_lo_idx != chan->pattern_hi_idx)
ctrl |= LPG_ENABLE_CONTROL_RAMP_GEN;
else
ctrl |= LPG_ENABLE_CONTROL_SRC_PWM;
regmap_write(lpg->map, chan->base + PWM_ENABLE_CONTROL_REG, ctrl);
/*
* Due to LPG hardware bug, in the PWM mode, having enabled PWM,
* We have to write PWM values one more time.
*/
if (chan->enabled)
lpg_apply_pwm_value(chan);
}
#define LPG_SYNC_PWM BIT(0)
static void lpg_apply_sync(struct lpg_channel *chan)
{
struct lpg *lpg = chan->lpg;
regmap_write(lpg->map, chan->base + PWM_SYNC_REG, LPG_SYNC_PWM);
}
static int lpg_parse_dtest(struct lpg *lpg)
{
struct lpg_channel *chan;
struct device_node *np = lpg->dev->of_node;
int count;
int ret;
int i;
count = of_property_count_u32_elems(np, "qcom,dtest");
if (count == -EINVAL) {
return 0;
} else if (count < 0) {
ret = count;
goto err_malformed;
} else if (count != lpg->data->num_channels * 2) {
dev_err(lpg->dev, "qcom,dtest needs to be %d items\n",
lpg->data->num_channels * 2);
return -EINVAL;
}
for (i = 0; i < lpg->data->num_channels; i++) {
chan = &lpg->channels[i];
ret = of_property_read_u32_index(np, "qcom,dtest", i * 2,
&chan->dtest_line);
if (ret)
goto err_malformed;
ret = of_property_read_u32_index(np, "qcom,dtest", i * 2 + 1,
&chan->dtest_value);
if (ret)
goto err_malformed;
}
return 0;
err_malformed:
dev_err(lpg->dev, "malformed qcom,dtest\n");
return ret;
}
static void lpg_apply_dtest(struct lpg_channel *chan)
{
struct lpg *lpg = chan->lpg;
if (!chan->dtest_line)
return;
regmap_write(lpg->map, chan->base + PWM_SEC_ACCESS_REG, 0xa5);
regmap_write(lpg->map, chan->base + PWM_DTEST_REG(chan->dtest_line),
chan->dtest_value);
}
static void lpg_apply(struct lpg_channel *chan)
{
lpg_disable_glitch(chan);
lpg_apply_freq(chan);
lpg_apply_pwm_value(chan);
lpg_apply_control(chan);
lpg_apply_sync(chan);
lpg_apply_lut_control(chan);
lpg_enable_glitch(chan);
}
static void lpg_brightness_set(struct lpg_led *led, struct led_classdev *cdev,
struct mc_subled *subleds)
{
enum led_brightness brightness;
struct lpg_channel *chan;
unsigned int triled_enabled = 0;
unsigned int triled_mask = 0;
unsigned int lut_mask = 0;
unsigned int duty;
struct lpg *lpg = led->lpg;
int i;
for (i = 0; i < led->num_channels; i++) {
chan = led->channels[i];
brightness = subleds[i].brightness;
if (brightness == LED_OFF) {
chan->enabled = false;
chan->ramp_enabled = false;
} else if (chan->pattern_lo_idx != chan->pattern_hi_idx) {
lpg_calc_freq(chan, NSEC_PER_MSEC);
chan->enabled = true;
chan->ramp_enabled = true;
lut_mask |= chan->lut_mask;
triled_enabled |= chan->triled_mask;
} else {
lpg_calc_freq(chan, NSEC_PER_MSEC);
duty = div_u64(brightness * chan->period, cdev->max_brightness);
lpg_calc_duty(chan, duty);
chan->enabled = true;
chan->ramp_enabled = false;
triled_enabled |= chan->triled_mask;
}
triled_mask |= chan->triled_mask;
lpg_apply(chan);
}
/* Toggle triled lines */
if (triled_mask)
triled_set(lpg, triled_mask, triled_enabled);
/* Trigger start of ramp generator(s) */
if (lut_mask)
lpg_lut_sync(lpg, lut_mask);
}
static int lpg_brightness_single_set(struct led_classdev *cdev,
enum led_brightness value)
{
struct lpg_led *led = container_of(cdev, struct lpg_led, cdev);
struct mc_subled info;
mutex_lock(&led->lpg->lock);
info.brightness = value;
lpg_brightness_set(led, cdev, &info);
mutex_unlock(&led->lpg->lock);
return 0;
}
static int lpg_brightness_mc_set(struct led_classdev *cdev,
enum led_brightness value)
{
struct led_classdev_mc *mc = lcdev_to_mccdev(cdev);
struct lpg_led *led = container_of(mc, struct lpg_led, mcdev);
mutex_lock(&led->lpg->lock);
led_mc_calc_color_components(mc, value);
lpg_brightness_set(led, cdev, mc->subled_info);
mutex_unlock(&led->lpg->lock);
return 0;
}
static int lpg_blink_set(struct lpg_led *led,
unsigned long *delay_on, unsigned long *delay_off)
{
struct lpg_channel *chan;
unsigned int period;
unsigned int triled_mask = 0;
struct lpg *lpg = led->lpg;
u64 duty;
int i;
if (!*delay_on && !*delay_off) {
*delay_on = 500;
*delay_off = 500;
}
duty = *delay_on * NSEC_PER_MSEC;
period = (*delay_on + *delay_off) * NSEC_PER_MSEC;
for (i = 0; i < led->num_channels; i++) {
chan = led->channels[i];
lpg_calc_freq(chan, period);
lpg_calc_duty(chan, duty);
chan->enabled = true;
chan->ramp_enabled = false;
triled_mask |= chan->triled_mask;
lpg_apply(chan);
}
/* Enable triled lines */
triled_set(lpg, triled_mask, triled_mask);
chan = led->channels[0];
duty = div_u64(chan->pwm_value * chan->period, LPG_RESOLUTION_9BIT);
*delay_on = div_u64(duty, NSEC_PER_MSEC);
*delay_off = div_u64(chan->period - duty, NSEC_PER_MSEC);
return 0;
}
static int lpg_blink_single_set(struct led_classdev *cdev,
unsigned long *delay_on, unsigned long *delay_off)
{
struct lpg_led *led = container_of(cdev, struct lpg_led, cdev);
int ret;
mutex_lock(&led->lpg->lock);
ret = lpg_blink_set(led, delay_on, delay_off);
mutex_unlock(&led->lpg->lock);
return ret;
}
static int lpg_blink_mc_set(struct led_classdev *cdev,
unsigned long *delay_on, unsigned long *delay_off)
{
struct led_classdev_mc *mc = lcdev_to_mccdev(cdev);
struct lpg_led *led = container_of(mc, struct lpg_led, mcdev);
int ret;
mutex_lock(&led->lpg->lock);
ret = lpg_blink_set(led, delay_on, delay_off);
mutex_unlock(&led->lpg->lock);
return ret;
}
static int lpg_pattern_set(struct lpg_led *led, struct led_pattern *led_pattern,
u32 len, int repeat)
{
struct lpg_channel *chan;
struct lpg *lpg = led->lpg;
struct led_pattern *pattern;
unsigned int brightness_a;
unsigned int brightness_b;
unsigned int actual_len;
unsigned int hi_pause;
unsigned int lo_pause;
unsigned int delta_t;
unsigned int lo_idx;
unsigned int hi_idx;
unsigned int i;
bool ping_pong = true;
int ret = -EINVAL;
/* Hardware only support oneshot or indefinite loops */
if (repeat != -1 && repeat != 1)
return -EINVAL;
/*
* The standardized leds-trigger-pattern format defines that the
* brightness of the LED follows a linear transition from one entry
* in the pattern to the next, over the given delta_t time. It
* describes that the way to perform instant transitions a zero-length
* entry should be added following a pattern entry.
*
* The LPG hardware is only able to perform the latter (no linear
* transitions), so require each entry in the pattern to be followed by
* a zero-length transition.
*/
if (len % 2)
return -EINVAL;
pattern = kcalloc(len / 2, sizeof(*pattern), GFP_KERNEL);
if (!pattern)
return -ENOMEM;
for (i = 0; i < len; i += 2) {
if (led_pattern[i].brightness != led_pattern[i + 1].brightness)
goto out_free_pattern;
if (led_pattern[i + 1].delta_t != 0)
goto out_free_pattern;
pattern[i / 2].brightness = led_pattern[i].brightness;
pattern[i / 2].delta_t = led_pattern[i].delta_t;
}
len /= 2;
/*
* Specifying a pattern of length 1 causes the hardware to iterate
* through the entire LUT, so prohibit this.
*/
if (len < 2)
goto out_free_pattern;
/*
* The LPG plays patterns with at a fixed pace, a "low pause" can be
* used to stretch the first delay of the pattern and a "high pause"
* the last one.
*
* In order to save space the pattern can be played in "ping pong"
* mode, in which the pattern is first played forward, then "high
* pause" is applied, then the pattern is played backwards and finally
* the "low pause" is applied.
*
* The middle elements of the pattern are used to determine delta_t and
* the "low pause" and "high pause" multipliers are derrived from this.
*
* The first element in the pattern is used to determine "low pause".
*
* If the specified pattern is a palindrome the ping pong mode is
* enabled. In this scenario the delta_t of the middle entry (i.e. the
* last in the programmed pattern) determines the "high pause".
*/
/* Detect palindromes and use "ping pong" to reduce LUT usage */
for (i = 0; i < len / 2; i++) {
brightness_a = pattern[i].brightness;
brightness_b = pattern[len - i - 1].brightness;
if (brightness_a != brightness_b) {
ping_pong = false;
break;
}
}
/* The pattern length to be written to the LUT */
if (ping_pong)
actual_len = (len + 1) / 2;
else
actual_len = len;
/*
* Validate that all delta_t in the pattern are the same, with the
* exception of the middle element in case of ping_pong.
*/
delta_t = pattern[1].delta_t;
for (i = 2; i < len; i++) {
if (pattern[i].delta_t != delta_t) {
/*
* Allow last entry in the full or shortened pattern to
* specify hi pause. Reject other variations.
*/
if (i != actual_len - 1)
goto out_free_pattern;
}
}
/* LPG_RAMP_DURATION_REG is a 9bit */
if (delta_t >= BIT(9))
goto out_free_pattern;
/* Find "low pause" and "high pause" in the pattern */
lo_pause = pattern[0].delta_t;
hi_pause = pattern[actual_len - 1].delta_t;
mutex_lock(&lpg->lock);
ret = lpg_lut_store(lpg, pattern, actual_len, &lo_idx, &hi_idx);
if (ret < 0)
goto out_unlock;
for (i = 0; i < led->num_channels; i++) {
chan = led->channels[i];
chan->ramp_tick_ms = delta_t;
chan->ramp_ping_pong = ping_pong;
chan->ramp_oneshot = repeat != -1;
chan->ramp_lo_pause_ms = lo_pause;
chan->ramp_hi_pause_ms = hi_pause;
chan->pattern_lo_idx = lo_idx;
chan->pattern_hi_idx = hi_idx;
}
out_unlock:
mutex_unlock(&lpg->lock);
out_free_pattern:
kfree(pattern);
return ret;
}
static int lpg_pattern_single_set(struct led_classdev *cdev,
struct led_pattern *pattern, u32 len,
int repeat)
{
struct lpg_led *led = container_of(cdev, struct lpg_led, cdev);
int ret;
ret = lpg_pattern_set(led, pattern, len, repeat);
if (ret < 0)
return ret;
lpg_brightness_single_set(cdev, LED_FULL);
return 0;
}
static int lpg_pattern_mc_set(struct led_classdev *cdev,
struct led_pattern *pattern, u32 len,
int repeat)
{
struct led_classdev_mc *mc = lcdev_to_mccdev(cdev);
struct lpg_led *led = container_of(mc, struct lpg_led, mcdev);
int ret;
ret = lpg_pattern_set(led, pattern, len, repeat);
if (ret < 0)
return ret;
led_mc_calc_color_components(mc, LED_FULL);
lpg_brightness_set(led, cdev, mc->subled_info);
return 0;
}
static int lpg_pattern_clear(struct lpg_led *led)
{
struct lpg_channel *chan;
struct lpg *lpg = led->lpg;
int i;
mutex_lock(&lpg->lock);
chan = led->channels[0];
lpg_lut_free(lpg, chan->pattern_lo_idx, chan->pattern_hi_idx);
for (i = 0; i < led->num_channels; i++) {
chan = led->channels[i];
chan->pattern_lo_idx = 0;
chan->pattern_hi_idx = 0;
}
mutex_unlock(&lpg->lock);
return 0;
}
static int lpg_pattern_single_clear(struct led_classdev *cdev)
{
struct lpg_led *led = container_of(cdev, struct lpg_led, cdev);
return lpg_pattern_clear(led);
}
static int lpg_pattern_mc_clear(struct led_classdev *cdev)
{
struct led_classdev_mc *mc = lcdev_to_mccdev(cdev);
struct lpg_led *led = container_of(mc, struct lpg_led, mcdev);
return lpg_pattern_clear(led);
}
static int lpg_pwm_request(struct pwm_chip *chip, struct pwm_device *pwm)
{
struct lpg *lpg = container_of(chip, struct lpg, pwm);
struct lpg_channel *chan = &lpg->channels[pwm->hwpwm];
return chan->in_use ? -EBUSY : 0;
}
/*
* Limitations:
* - Updating both duty and period is not done atomically, so the output signal
* will momentarily be a mix of the settings.
* - Changed parameters takes effect immediately.
* - A disabled channel outputs a logical 0.
*/
static int lpg_pwm_apply(struct pwm_chip *chip, struct pwm_device *pwm,
const struct pwm_state *state)
{
struct lpg *lpg = container_of(chip, struct lpg, pwm);
struct lpg_channel *chan = &lpg->channels[pwm->hwpwm];
int ret = 0;
if (state->polarity != PWM_POLARITY_NORMAL)
return -EINVAL;
mutex_lock(&lpg->lock);
if (state->enabled) {
ret = lpg_calc_freq(chan, state->period);
if (ret < 0)
goto out_unlock;
lpg_calc_duty(chan, state->duty_cycle);
}
chan->enabled = state->enabled;
lpg_apply(chan);
triled_set(lpg, chan->triled_mask, chan->enabled ? chan->triled_mask : 0);
out_unlock:
mutex_unlock(&lpg->lock);
return ret;
}
static int lpg_pwm_get_state(struct pwm_chip *chip, struct pwm_device *pwm,
struct pwm_state *state)
{
struct lpg *lpg = container_of(chip, struct lpg, pwm);
struct lpg_channel *chan = &lpg->channels[pwm->hwpwm];
unsigned int resolution;
unsigned int pre_div;
unsigned int refclk;
unsigned int val;
unsigned int m;
u16 pwm_value;
int ret;
ret = regmap_read(lpg->map, chan->base + LPG_SIZE_CLK_REG, &val);
if (ret)
return ret;
if (chan->subtype == LPG_SUBTYPE_HI_RES_PWM) {
refclk = lpg_clk_rates_hi_res[FIELD_GET(PWM_CLK_SELECT_HI_RES_MASK, val)];
resolution = lpg_pwm_resolution_hi_res[FIELD_GET(PWM_SIZE_HI_RES_MASK, val)];
} else {
refclk = lpg_clk_rates[FIELD_GET(PWM_CLK_SELECT_MASK, val)];
resolution = 9;
}
if (refclk) {
ret = regmap_read(lpg->map, chan->base + LPG_PREDIV_CLK_REG, &val);
if (ret)
return ret;
pre_div = lpg_pre_divs[FIELD_GET(PWM_FREQ_PRE_DIV_MASK, val)];
m = FIELD_GET(PWM_FREQ_EXP_MASK, val);
ret = regmap_bulk_read(lpg->map, chan->base + PWM_VALUE_REG, &pwm_value, sizeof(pwm_value));
if (ret)
return ret;
state->period = DIV_ROUND_UP_ULL((u64)NSEC_PER_SEC * (1 << resolution) *
pre_div * (1 << m), refclk);
state->duty_cycle = DIV_ROUND_UP_ULL((u64)NSEC_PER_SEC * pwm_value * pre_div * (1 << m), refclk);
} else {
state->period = 0;
state->duty_cycle = 0;
}
ret = regmap_read(lpg->map, chan->base + PWM_ENABLE_CONTROL_REG, &val);
if (ret)
return ret;
state->enabled = FIELD_GET(LPG_ENABLE_CONTROL_OUTPUT, val);
state->polarity = PWM_POLARITY_NORMAL;
if (state->duty_cycle > state->period)
state->duty_cycle = state->period;
return 0;
}
static const struct pwm_ops lpg_pwm_ops = {
.request = lpg_pwm_request,
.apply = lpg_pwm_apply,
.get_state = lpg_pwm_get_state,
.owner = THIS_MODULE,
};
static int lpg_add_pwm(struct lpg *lpg)
{
int ret;
lpg->pwm.dev = lpg->dev;
lpg->pwm.npwm = lpg->num_channels;
lpg->pwm.ops = &lpg_pwm_ops;
ret = pwmchip_add(&lpg->pwm);
if (ret)
dev_err(lpg->dev, "failed to add PWM chip: ret %d\n", ret);
return ret;
}
static int lpg_parse_channel(struct lpg *lpg, struct device_node *np,
struct lpg_channel **channel)
{
struct lpg_channel *chan;
u32 color = LED_COLOR_ID_GREEN;
u32 reg;
int ret;
ret = of_property_read_u32(np, "reg", &reg);
if (ret || !reg || reg > lpg->num_channels) {
dev_err(lpg->dev, "invalid \"reg\" of %pOFn\n", np);
return -EINVAL;
}
chan = &lpg->channels[reg - 1];
chan->in_use = true;
ret = of_property_read_u32(np, "color", &color);
if (ret < 0 && ret != -EINVAL) {
dev_err(lpg->dev, "failed to parse \"color\" of %pOF\n", np);
return ret;
}
chan->color = color;
*channel = chan;
return 0;
}
static int lpg_add_led(struct lpg *lpg, struct device_node *np)
{
struct led_init_data init_data = {};
struct led_classdev *cdev;
struct device_node *child;
struct mc_subled *info;
struct lpg_led *led;
const char *state;
int num_channels;
u32 color = 0;
int ret;
int i;
ret = of_property_read_u32(np, "color", &color);
if (ret < 0 && ret != -EINVAL) {
dev_err(lpg->dev, "failed to parse \"color\" of %pOF\n", np);
return ret;
}
if (color == LED_COLOR_ID_RGB)
num_channels = of_get_available_child_count(np);
else
num_channels = 1;
led = devm_kzalloc(lpg->dev, struct_size(led, channels, num_channels), GFP_KERNEL);
if (!led)
return -ENOMEM;
led->lpg = lpg;
led->num_channels = num_channels;
if (color == LED_COLOR_ID_RGB) {
info = devm_kcalloc(lpg->dev, num_channels, sizeof(*info), GFP_KERNEL);
if (!info)
return -ENOMEM;
i = 0;
for_each_available_child_of_node(np, child) {
ret = lpg_parse_channel(lpg, child, &led->channels[i]);
if (ret < 0) {
of_node_put(child);
return ret;
}
info[i].color_index = led->channels[i]->color;
info[i].intensity = 0;
i++;
}
led->mcdev.subled_info = info;
led->mcdev.num_colors = num_channels;
cdev = &led->mcdev.led_cdev;
cdev->brightness_set_blocking = lpg_brightness_mc_set;
cdev->blink_set = lpg_blink_mc_set;
/* Register pattern accessors only if we have a LUT block */
if (lpg->lut_base) {
cdev->pattern_set = lpg_pattern_mc_set;
cdev->pattern_clear = lpg_pattern_mc_clear;
}
} else {
ret = lpg_parse_channel(lpg, np, &led->channels[0]);
if (ret < 0)
return ret;
cdev = &led->cdev;
cdev->brightness_set_blocking = lpg_brightness_single_set;
cdev->blink_set = lpg_blink_single_set;
/* Register pattern accessors only if we have a LUT block */
if (lpg->lut_base) {
cdev->pattern_set = lpg_pattern_single_set;
cdev->pattern_clear = lpg_pattern_single_clear;
}
}
cdev->default_trigger = of_get_property(np, "linux,default-trigger", NULL);
cdev->max_brightness = LPG_RESOLUTION_9BIT - 1;
if (!of_property_read_string(np, "default-state", &state) &&
!strcmp(state, "on"))
cdev->brightness = cdev->max_brightness;
else
cdev->brightness = LED_OFF;
cdev->brightness_set_blocking(cdev, cdev->brightness);
init_data.fwnode = of_fwnode_handle(np);
if (color == LED_COLOR_ID_RGB)
ret = devm_led_classdev_multicolor_register_ext(lpg->dev, &led->mcdev, &init_data);
else
ret = devm_led_classdev_register_ext(lpg->dev, &led->cdev, &init_data);
if (ret)
dev_err(lpg->dev, "unable to register %s\n", cdev->name);
return ret;
}
static int lpg_init_channels(struct lpg *lpg)
{
const struct lpg_data *data = lpg->data;
struct lpg_channel *chan;
int i;
lpg->num_channels = data->num_channels;
lpg->channels = devm_kcalloc(lpg->dev, data->num_channels,
sizeof(struct lpg_channel), GFP_KERNEL);
if (!lpg->channels)
return -ENOMEM;
for (i = 0; i < data->num_channels; i++) {
chan = &lpg->channels[i];
chan->lpg = lpg;
chan->base = data->channels[i].base;
chan->triled_mask = data->channels[i].triled_mask;
chan->lut_mask = BIT(i);
regmap_read(lpg->map, chan->base + LPG_SUBTYPE_REG, &chan->subtype);
}
return 0;
}
static int lpg_init_triled(struct lpg *lpg)
{
struct device_node *np = lpg->dev->of_node;
int ret;
/* Skip initialization if we don't have a triled block */
if (!lpg->data->triled_base)
return 0;
lpg->triled_base = lpg->data->triled_base;
lpg->triled_has_atc_ctl = lpg->data->triled_has_atc_ctl;
lpg->triled_has_src_sel = lpg->data->triled_has_src_sel;
if (lpg->triled_has_src_sel) {
ret = of_property_read_u32(np, "qcom,power-source", &lpg->triled_src);
if (ret || lpg->triled_src == 2 || lpg->triled_src > 3) {
dev_err(lpg->dev, "invalid power source\n");
return -EINVAL;
}
}
/* Disable automatic trickle charge LED */
if (lpg->triled_has_atc_ctl)
regmap_write(lpg->map, lpg->triled_base + TRI_LED_ATC_CTL, 0);
/* Configure power source */
if (lpg->triled_has_src_sel)
regmap_write(lpg->map, lpg->triled_base + TRI_LED_SRC_SEL, lpg->triled_src);
/* Default all outputs to off */
regmap_write(lpg->map, lpg->triled_base + TRI_LED_EN_CTL, 0);
return 0;
}
static int lpg_init_lut(struct lpg *lpg)
{
const struct lpg_data *data = lpg->data;
if (!data->lut_base)
return 0;
lpg->lut_base = data->lut_base;
lpg->lut_size = data->lut_size;
lpg->lut_bitmap = devm_bitmap_zalloc(lpg->dev, lpg->lut_size, GFP_KERNEL);
if (!lpg->lut_bitmap)
return -ENOMEM;
return 0;
}
static int lpg_probe(struct platform_device *pdev)
{
struct device_node *np;
struct lpg *lpg;
int ret;
int i;
lpg = devm_kzalloc(&pdev->dev, sizeof(*lpg), GFP_KERNEL);
if (!lpg)
return -ENOMEM;
lpg->data = of_device_get_match_data(&pdev->dev);
if (!lpg->data)
return -EINVAL;
platform_set_drvdata(pdev, lpg);
lpg->dev = &pdev->dev;
mutex_init(&lpg->lock);
lpg->map = dev_get_regmap(pdev->dev.parent, NULL);
if (!lpg->map)
return dev_err_probe(&pdev->dev, -ENXIO, "parent regmap unavailable\n");
ret = lpg_init_channels(lpg);
if (ret < 0)
return ret;
ret = lpg_parse_dtest(lpg);
if (ret < 0)
return ret;
ret = lpg_init_triled(lpg);
if (ret < 0)
return ret;
ret = lpg_init_lut(lpg);
if (ret < 0)
return ret;
for_each_available_child_of_node(pdev->dev.of_node, np) {
ret = lpg_add_led(lpg, np);
if (ret) {
of_node_put(np);
return ret;
}
}
for (i = 0; i < lpg->num_channels; i++)
lpg_apply_dtest(&lpg->channels[i]);
return lpg_add_pwm(lpg);
}
static void lpg_remove(struct platform_device *pdev)
{
struct lpg *lpg = platform_get_drvdata(pdev);
pwmchip_remove(&lpg->pwm);
}
static const struct lpg_data pm8916_pwm_data = {
.num_channels = 1,
.channels = (const struct lpg_channel_data[]) {
{ .base = 0xbc00 },
},
};
static const struct lpg_data pm8941_lpg_data = {
.lut_base = 0xb000,
.lut_size = 64,
.triled_base = 0xd000,
.triled_has_atc_ctl = true,
.triled_has_src_sel = true,
.num_channels = 8,
.channels = (const struct lpg_channel_data[]) {
{ .base = 0xb100 },
{ .base = 0xb200 },
{ .base = 0xb300 },
{ .base = 0xb400 },
{ .base = 0xb500, .triled_mask = BIT(5) },
{ .base = 0xb600, .triled_mask = BIT(6) },
{ .base = 0xb700, .triled_mask = BIT(7) },
{ .base = 0xb800 },
},
};
static const struct lpg_data pm8994_lpg_data = {
.lut_base = 0xb000,
.lut_size = 64,
.num_channels = 6,
.channels = (const struct lpg_channel_data[]) {
{ .base = 0xb100 },
{ .base = 0xb200 },
{ .base = 0xb300 },
{ .base = 0xb400 },
{ .base = 0xb500 },
{ .base = 0xb600 },
},
};
/* PMI632 uses SDAM instead of LUT for pattern */
static const struct lpg_data pmi632_lpg_data = {
.triled_base = 0xd000,
.num_channels = 5,
.channels = (const struct lpg_channel_data[]) {
{ .base = 0xb300, .triled_mask = BIT(7) },
{ .base = 0xb400, .triled_mask = BIT(6) },
{ .base = 0xb500, .triled_mask = BIT(5) },
{ .base = 0xb600 },
{ .base = 0xb700 },
},
};
static const struct lpg_data pmi8994_lpg_data = {
.lut_base = 0xb000,
.lut_size = 24,
.triled_base = 0xd000,
.triled_has_atc_ctl = true,
.triled_has_src_sel = true,
.num_channels = 4,
.channels = (const struct lpg_channel_data[]) {
{ .base = 0xb100, .triled_mask = BIT(5) },
{ .base = 0xb200, .triled_mask = BIT(6) },
{ .base = 0xb300, .triled_mask = BIT(7) },
{ .base = 0xb400 },
},
};
static const struct lpg_data pmi8998_lpg_data = {
.lut_base = 0xb000,
.lut_size = 49,
.triled_base = 0xd000,
.num_channels = 6,
.channels = (const struct lpg_channel_data[]) {
{ .base = 0xb100 },
{ .base = 0xb200 },
{ .base = 0xb300, .triled_mask = BIT(5) },
{ .base = 0xb400, .triled_mask = BIT(6) },
{ .base = 0xb500, .triled_mask = BIT(7) },
{ .base = 0xb600 },
},
};
static const struct lpg_data pm8150b_lpg_data = {
.lut_base = 0xb000,
.lut_size = 24,
.triled_base = 0xd000,
.num_channels = 2,
.channels = (const struct lpg_channel_data[]) {
{ .base = 0xb100, .triled_mask = BIT(7) },
{ .base = 0xb200, .triled_mask = BIT(6) },
},
};
static const struct lpg_data pm8150l_lpg_data = {
.lut_base = 0xb000,
.lut_size = 48,
.triled_base = 0xd000,
.num_channels = 5,
.channels = (const struct lpg_channel_data[]) {
{ .base = 0xb100, .triled_mask = BIT(7) },
{ .base = 0xb200, .triled_mask = BIT(6) },
{ .base = 0xb300, .triled_mask = BIT(5) },
{ .base = 0xbc00 },
{ .base = 0xbd00 },
},
};
static const struct lpg_data pm8350c_pwm_data = {
.triled_base = 0xef00,
.num_channels = 4,
.channels = (const struct lpg_channel_data[]) {
{ .base = 0xe800, .triled_mask = BIT(7) },
{ .base = 0xe900, .triled_mask = BIT(6) },
{ .base = 0xea00, .triled_mask = BIT(5) },
{ .base = 0xeb00 },
},
};
static const struct lpg_data pmk8550_pwm_data = {
.num_channels = 2,
.channels = (const struct lpg_channel_data[]) {
{ .base = 0xe800 },
{ .base = 0xe900 },
},
};
static const struct of_device_id lpg_of_table[] = {
{ .compatible = "qcom,pm8150b-lpg", .data = &pm8150b_lpg_data },
{ .compatible = "qcom,pm8150l-lpg", .data = &pm8150l_lpg_data },
{ .compatible = "qcom,pm8350c-pwm", .data = &pm8350c_pwm_data },
{ .compatible = "qcom,pm8916-pwm", .data = &pm8916_pwm_data },
{ .compatible = "qcom,pm8941-lpg", .data = &pm8941_lpg_data },
{ .compatible = "qcom,pm8994-lpg", .data = &pm8994_lpg_data },
{ .compatible = "qcom,pmi632-lpg", .data = &pmi632_lpg_data },
{ .compatible = "qcom,pmi8994-lpg", .data = &pmi8994_lpg_data },
{ .compatible = "qcom,pmi8998-lpg", .data = &pmi8998_lpg_data },
{ .compatible = "qcom,pmc8180c-lpg", .data = &pm8150l_lpg_data },
{ .compatible = "qcom,pmk8550-pwm", .data = &pmk8550_pwm_data },
{}
};
MODULE_DEVICE_TABLE(of, lpg_of_table);
static struct platform_driver lpg_driver = {
.probe = lpg_probe,
.remove_new = lpg_remove,
.driver = {
.name = "qcom-spmi-lpg",
.of_match_table = lpg_of_table,
},
};
module_platform_driver(lpg_driver);
MODULE_DESCRIPTION("Qualcomm LPG LED driver");
MODULE_LICENSE("GPL v2");
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