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gerrit-public.fairphone.software / kernel / lk / refs/heads/rel/p/fp2/20.12.0-beta / . / dev / pmic / pm8921 / pm8921.c
blob: 9cf5e91febb2e03f652c296436a5a38bed57e381 [file] [log] [blame]
/*
* Copyright (c) 2011-2013, Linux Foundation. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the following
* disclaimer in the documentation and/or other materials provided
* with the distribution.
* * Neither the name of Linux Foundation, Inc. nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED
* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT
* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS
* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
* BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
* OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
* IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <assert.h>
#include <string.h>
#include <sys/types.h>
#include <err.h>
#include <dev/pm8921.h>
#include <platform/timer.h>
#include "pm8921_hw.h"
static pm8921_dev_t *dev;
static uint8_t ldo_n_voltage_mult[LDO_VOLTAGE_ENTRIES] = {
18, /* 1.2V */
0,
0,
};
static uint8_t ldo_p_voltage_mult[LDO_VOLTAGE_ENTRIES] = {
0,
6, /* 1.8V */
30, /* 3.0V */
};
/* Intialize the pmic driver */
void pm8921_init(pm8921_dev_t *pmic)
{
ASSERT(pmic);
ASSERT(pmic->read);
ASSERT(pmic->write);
dev = pmic;
dev->initialized = 1;
}
static int pm8921_masked_write(uint16_t addr,
uint8_t mask, uint8_t val)
{
int rc;
uint8_t reg;
rc = dev->read(&reg, 1, addr);
if (rc)
{
return rc;
}
reg &= ~mask;
reg |= val & mask;
rc = dev->write(&reg, 1, addr);
return rc;
}
/* Set the BOOT_DONE flag */
void pm8921_boot_done(void)
{
uint8_t val;
ASSERT(dev);
ASSERT(dev->initialized);
dev->read(&val, 1, PBL_ACCESS_2);
val |= PBL_ACCESS_2_ENUM_TIMER_STOP;
/* TODO: Remove next line when h/w is rewired for battery simulation.*/
val |= (0x7 << 2);
dev->write(&val, 1, PBL_ACCESS_2);
dev->read(&val, 1, SYS_CONFIG_2);
val |= (SYS_CONFIG_2_BOOT_DONE | SYS_CONFIG_2_ADAPTIVE_BOOT_DISABLE);
dev->write(&val, 1, SYS_CONFIG_2);
}
/* Configure PMIC GPIO */
int pm8921_gpio_config(int gpio, struct pm8921_gpio *param)
{
int ret;
uint8_t bank[6];
uint8_t output_buf_config;
uint8_t output_value;
static uint8_t dir_map[] = {
PM_GPIO_MODE_OFF,
PM_GPIO_MODE_OUTPUT,
PM_GPIO_MODE_INPUT,
PM_GPIO_MODE_BOTH,
};
if (param == NULL) {
dprintf (CRITICAL, "pm8291_gpio struct not defined\n");
return -1;
}
/* Select banks and configure the gpio */
bank[0] = PM_GPIO_WRITE |
((param->vin_sel << PM_GPIO_VIN_SHIFT) &
PM_GPIO_VIN_MASK) |
PM_GPIO_MODE_ENABLE;
/* bank1 */
if ((param->direction & PM_GPIO_DIR_OUT) && param->output_buffer)
output_buf_config = PM_GPIO_OUT_BUFFER_OPEN_DRAIN;
else
output_buf_config = 0;
if ((param->direction & PM_GPIO_DIR_OUT) && param->output_value)
output_value = 1;
else
output_value = 0;
bank[1] = PM_GPIO_WRITE |
((1 << PM_GPIO_BANK_SHIFT) & PM_GPIO_BANK_MASK) |
((dir_map[param->direction] << PM_GPIO_MODE_SHIFT)
& PM_GPIO_MODE_MASK) |
output_buf_config |
output_value;
bank[2] = PM_GPIO_WRITE |
((2 << PM_GPIO_BANK_SHIFT) & PM_GPIO_BANK_MASK) |
((param->pull << PM_GPIO_PULL_SHIFT) &
PM_GPIO_PULL_MASK);
bank[3] = PM_GPIO_WRITE |
((3 << PM_GPIO_BANK_SHIFT) & PM_GPIO_BANK_MASK) |
((param->out_strength << PM_GPIO_OUT_STRENGTH_SHIFT) &
PM_GPIO_OUT_STRENGTH_MASK) |
(param->disable_pin ? PM_GPIO_PIN_DISABLE : PM_GPIO_PIN_ENABLE);
bank[4] = PM_GPIO_WRITE |
((4 << PM_GPIO_BANK_SHIFT) & PM_GPIO_BANK_MASK) |
((param->function << PM_GPIO_FUNC_SHIFT) &
PM_GPIO_FUNC_MASK);
bank[5] = PM_GPIO_WRITE |
((5 << PM_GPIO_BANK_SHIFT) & PM_GPIO_BANK_MASK) |
(param->inv_int_pol ? 0 : PM_GPIO_NON_INT_POL_INV);
ret = dev->write(bank, 6, GPIO_CNTL(gpio));
if (ret) {
dprintf(CRITICAL, "Failed to write to PM8921 ret=%d.\n", ret);
return -1;
}
return 0;
}
/* Reads the value of the irq status for the requested block */
int pm8921_irq_get_block_status(uint8_t block, uint8_t *status)
{
int ret = 0;
/* Select the irq block to be read */
ret = dev->write(&block, 1, IRQ_BLOCK_SEL_USR_ADDR);
if(!ret)
{
/* Read the real time irq status value for the block */
ret = dev->read(status, 1, IRQ_STATUS_RT_USR_ADDR);
}
return ret;
}
/* Reads the status of requested gpio */
int pm8921_gpio_get(uint8_t gpio, uint8_t *status)
{
int ret = 0;
uint8_t block_status;
ret = pm8921_irq_get_block_status(PM_GPIO_BLOCK_ID(gpio), &block_status);
if(!ret)
{
if(block_status & PM_GPIO_ID_TO_BIT_MASK(gpio))
*status = 1;
else
*status = 0;
}
return ret;
}
int pm8921_pwrkey_status(uint8_t *is_pwrkey_pressed)
{
int ret = 0;
uint8_t block_status;
ret = pm8921_irq_get_block_status(PM_PWRKEY_BLOCK_ID, &block_status);
if (!ret)
{
if(block_status & PM_PWRKEY_PRESS_BIT)
*is_pwrkey_pressed = 1;
else
*is_pwrkey_pressed = 0;
}
return ret;
}
int pm8921_ldo_set_voltage(uint32_t ldo_id, uint32_t voltage)
{
uint8_t mult;
uint8_t val = 0;
uint32_t ldo_number = (ldo_id & ~LDO_P_MASK);
int32_t ret = 0;
/* Find the voltage multiplying factor */
if(ldo_id & LDO_P_MASK)
mult = ldo_p_voltage_mult[voltage];
else
mult = ldo_n_voltage_mult[voltage];
/* Program the TEST reg */
if (ldo_id & LDO_P_MASK){
/* Bank 2, only for p ldo, use 1.25V reference */
val = 0x0;
val |= ( 1 << PM8921_LDO_TEST_REG_RW );
val |= ( 2 << PM8921_LDO_TEST_REG_BANK_SEL);
ret = dev->write(&val, 1, PM8921_LDO_TEST_REG(ldo_number));
if (ret) {
dprintf(CRITICAL, "Failed to write to PM8921 LDO Test Reg ret=%d.\n", ret);
return -1;
}
/* Bank 4, only for p ldo, disable output range ext, normal capacitance */
val = 0x0;
val |= ( 1 << PM8921_LDO_TEST_REG_RW );
val |= ( 4 << PM8921_LDO_TEST_REG_BANK_SEL);
ret = dev->write(&val, 1, PM8921_LDO_TEST_REG(ldo_number));
if (ret) {
dprintf(CRITICAL, "Failed to write to PM8921 LDO Test Reg ret=%d.\n", ret);
return -1;
}
}
/* Program the CTRL reg */
val = 0x0;
val |= ( 1 << PM8921_LDO_CTRL_REG_ENABLE);
val |= ( 1 << PM8921_LDO_CTRL_REG_PULL_DOWN);
val |= ( 0 << PM8921_LDO_CTRL_REG_POWER_MODE);
val |= ( mult << PM8921_LDO_CTRL_REG_VOLTAGE);
ret = dev->write(&val, 1, PM8921_LDO_CTRL_REG(ldo_number));
if (ret) {
dprintf(CRITICAL, "Failed to write to PM8921 LDO Ctrl Reg ret=%d.\n", ret);
return -1;
}
return 0;
}
/*
* Configure PMIC for reset and power off.
* reset = 1: Configure reset.
* reset = 0: Configure power off.
*/
int pm8921_config_reset_pwr_off(unsigned reset)
{
int rc;
/* Enable SMPL(Short Momentary Power Loss) if resetting is desired. */
rc = pm8921_masked_write(PM8921_SLEEP_CTRL_REG,
SLEEP_CTRL_SMPL_EN_MASK,
(reset ? SLEEP_CTRL_SMPL_EN_RESET : SLEEP_CTRL_SMPL_EN_PWR_OFF));
if (rc)
{
goto read_write_err;
}
/*
* Select action to perform (reset or shutdown) when PS_HOLD goes low.
* Also ensure that KPD, CBL0, and CBL1 pull ups are enabled and that
* USB charging is enabled.
*/
rc = pm8921_masked_write(PM8921_PON_CTRL_1_REG,
PON_CTRL_1_PULL_UP_MASK | PON_CTRL_1_USB_PWR_EN
| PON_CTRL_1_WD_EN_MASK,
PON_CTRL_1_PULL_UP_MASK | PON_CTRL_1_USB_PWR_EN
| (reset ? PON_CTRL_1_WD_EN_RESET : PON_CTRL_1_WD_EN_PWR_OFF));
if (rc)
{
goto read_write_err;
}
read_write_err:
return rc;
}
/* A wrapper function to configure PMIC PWM
* pwm_id : Channel number to configure
* duty_us : duty cycle for output waveform in micro seconds
* period_us : period for output waveform in micro seconds
*/
int pm8921_set_pwm_config(uint8_t pwm_id, uint32_t duty_us, uint32_t period_us)
{
int rc;
rc = pm8921_pwm_config(pwm_id, duty_us, period_us, dev);
return rc;
}
/* A wrapper function to enable PMIC PWM
* pwm_id : Channel number to enable
*/
int pm8921_pwm_channel_enable(uint8_t pwm_id)
{
int rc;
rc = pm8921_pwm_enable(pwm_id, dev);
return rc;
}
/* Configure LED's for current sinks
* enable = 1: Configure external signal detection
* for the sink with the current level
* enable = 0: Turn off external signal detection
*
* Values for sink are defined as follows:
* 0 = MANUAL, turn on LED when curent [00000, 10100]
* 1 = PWM1
* 2 = PWM2
* 3 = PWM3
* 4 = DBUS1
* 5 = DBUS2
* 6 = DBUS3
* 7 = DBUS4
*
* Current settings are calculated as per the equation:
* [00000, 10100]: Iout = current * 2 mA
* [10101, 11111]: invalid settings
*/
int pm8921_config_led_current(enum pm8921_leds led_num,
uint8_t current,
enum led_mode sink,
int enable)
{
uint8_t val;
int ret;
/* Program the CTRL reg */
val = 0x0;
if (enable != 0)
{
if (current > 0x15)
{
dprintf(CRITICAL, "Invalid current settings for PM8921 LED Ctrl Reg \
current=%d.\n", current);
return -1;
}
if (sink > 0x7)
{
dprintf(CRITICAL, "Invalid signal selection for PM8921 LED Ctrl Reg \
sink=%d.\n", sink);
return -1;
}
val |= LED_CURRENT_SET(current);
val |= LED_SIGNAL_SELECT(sink);
}
ret = dev->write(&val, 1, PM8921_LED_CNTL_REG(led_num));
if (ret)
dprintf(CRITICAL, "Failed to write to PM8921 LED Ctrl Reg ret=%d.\n", ret);
return ret;
}
/* Configure DRV_KEYPAD
*drv_flash_sel:
* 0000 = off
* Iout = drv_flash_sel * 20 mA (300 mA driver)
* Iout = drv_flash_sel * 40 mA (600 mA driver)
*
* flash_logic = 0 : flash is on when DTEST is high
* flash_logic = 0 : flash is off when DTEST is high
*
* flash_ensel = 0 : manual mode, turn on flash when drv_flash_sel > 0
* flash_ensel = 1 : DBUS1
* flash_ensel = 2 : DBUS2
* flash_ensel = 3 : enable flash from LPG
*/
int pm8921_config_drv_keypad(unsigned int drv_flash_sel, unsigned int flash_logic, unsigned int flash_ensel)
{
uint8_t val;
int ret;
/* Program the CTRL reg */
val = 0x0;
if (drv_flash_sel != 0)
{
if (drv_flash_sel > 0x0F)
{
dprintf(CRITICAL, "Invalid current settings for PM8921 \
KEYPAD_DRV Ctrl Reg drv_flash_sel=%d.\n", drv_flash_sel);
return -1;
}
if (flash_logic > 1)
{
dprintf(CRITICAL, "Invalid signal selection for PM8921 \
KEYPAD_DRV Ctrl Reg flash_logic=%d.\n", flash_logic);
return -1;
}
if (flash_ensel > 3)
{
dprintf(CRITICAL, "Invalid signal selection for PM8921 \
KEYPAD_DRV Ctrl Reg flash_ensel=%d.\n", flash_ensel);
return -1;
}
val |= DRV_FLASH_SEL(drv_flash_sel);
val |= FLASH_LOGIC_SEL(flash_logic);
val |= FLASH_ENSEL(flash_ensel);
}
ret = dev->write(&val, 1, PM8921_DRV_KEYPAD_CNTL_REG);
if (ret)
dprintf(CRITICAL, "Failed to write to PM8921 KEYPAD_DRV Ctrl Reg ret=%d.\n", ret);
return ret;
}
int pm8921_low_voltage_switch_enable(uint8_t lvs_id)
{
int ret = NO_ERROR;
uint8_t val;
if (lvs_id < lvs_start || lvs_id > lvs_end) {
dprintf(CRITICAL, "Requested unsupported LVS.\n");
return ERROR;
}
if (lvs_id == lvs_2) {
dprintf(CRITICAL, "No support for LVS2 yet!\n");
return ERROR;
}
/* Read LVS_TEST Reg first*/
ret = dev->read(&val, 1, PM8921_LVS_TEST_REG(lvs_id));
if (ret) {
dprintf(CRITICAL, "Failed to read LVS_TEST Reg ret=%d.\n", ret);
return ret;
}
/* Check if switch is already ON */
val = val & PM8921_LVS_100_TEST_VOUT_OK;
if (val)
return ret;
/* Turn on switch in normal mode */
val = 0;
val |= PM8921_LVS_100_CTRL_SW_EN; /* Enable Switch */
val |= PM8921_LVS_100_CTRL_SLEEP_B_IGNORE; /* Ignore sleep mode pin */
ret = dev->write(&val, 1, PM8921_LVS_CTRL_REG(lvs_id));
if (ret)
dprintf(CRITICAL, "Failed to write LVS_CTRL Reg ret=%d.\n", ret);
return ret;
}
int pm8921_mpp_set_digital_output(uint8_t mpp_id)
{
int ret = NO_ERROR;
uint8_t val;
if (mpp_id < mpp_start || mpp_id > mpp_end) {
dprintf(CRITICAL, "Requested unsupported MPP.\n");
return ERROR;
}
val = 0;
/* Configure in digital output mode */
val |= PM8921_MPP_CTRL_DIGITAL_OUTPUT;
val |= PM8921_MPP_CTRL_VIO_1; /* Set input voltage to 1.8V */
val |= PM8921_MPP_CTRL_OUTPUT_HIGH; /* Set mpp to high */
ret = dev->write(&val, 1, PM8921_MPP_CTRL_REG(mpp_id));
if (ret) {
dprintf(CRITICAL, "Failed to write MPP_CTRL Reg ret=%d.\n",
ret);
}
return ret;
}
int pm8921_HDMI_Switch(void)
{
int ret = NO_ERROR;
uint8_t val;
/* Value for HDMI MVS 5V Switch */
val = 0x068;
/* Turn on MVS 5V HDMI switch */
ret = dev->write(&val, 1, PM8921_MVS_5V_HDMI_SWITCH);
if (ret) {
dprintf(CRITICAL,
"Failed to turn ON MVS 5V hdmi switch ret=%d.\n", ret);
}
return ret;
}
int pm8921_rtc_alarm_disable(void)
{
int rc;
uint8_t reg;
rc = dev->read(&reg, 1, PM8921_RTC_CTRL);
if (rc) {
dprintf(CRITICAL,"Failed to read RTC_CTRL reg = %d\n",rc);
return rc;
}
reg = (reg & ~PM8921_RTC_ALARM_ENABLE);
rc = dev->write(&reg, 1, PM8921_RTC_CTRL);
if (rc) {
dprintf(CRITICAL,"Failed to write RTC_CTRL reg = %d\n",rc);
return rc;
}
return rc;
}
/*
* Set battery alarm with low & high threshold values
*/
int pm89xx_bat_alarm_set(bat_vol_t up_thresh_vol, bat_vol_t low_thresh_vol)
{
int rc;
uint8_t reg = 0;
if ((up_thresh_vol > BAT_VOL_4_3) || (low_thresh_vol > BAT_VOL_4_3)) {
dprintf(CRITICAL, "Input voltage not in permissible range\n");
return 1;
}
/*
* Write upper & lower threshold values
*/
reg = (up_thresh_vol << PM89XX_BAT_UP_THRESH_VOL) | low_thresh_vol;
rc = dev->write(&reg, 1, PM89XX_BAT_ALRM_THRESH);
if (rc) {
dprintf(CRITICAL, "Failed to set BAT_THRESH reg = %d\n", rc);
return rc;
}
/* Read Alarm control to use the existing hysteresis values */
rc = dev->read(&reg, 1, PM89XX_BAT_ALRM_CTRL);
if (rc) {
dprintf(CRITICAL, "Failed to read BAT_ALARM reg = %d\n", rc);
return rc;
}
/* Enable battery alarm */
reg |= PM89XX_BAT_ALRM_ENABLE;
rc = dev->write(&reg, 1, PM89XX_BAT_ALRM_CTRL);
if (rc) {
dprintf(CRITICAL, "Failed to enable BAT_ALARM reg = %d\n", rc);
return rc;
}
/* Wait for the comparator o/p to settle */
mdelay(10);
return rc;
}
/*
* API to return status of battery
* if the vbatt is below upper threshold return 0
* if the vbatt is below lower threshold return 1
*/
int pm89xx_bat_alarm_status(uint8_t *high_status, uint8_t *low_status)
{
int rc = 0;
uint8_t reg = 0;
/* Read the battery status */
rc = dev->read(&reg, 1, PM89XX_BAT_ALRM_CTRL);
if (rc) {
dprintf(CRITICAL, "Failed to read BAT_ALARM reg = %d\n", rc);
return rc;
}
/* Return the status if battery alarm is enabled */
if (reg & PM89XX_BAT_ALRM_ENABLE) {
*high_status = (reg & PM89XX_BAT_UPR_STATUS);
*low_status = (reg & PM89XX_BAT_LWR_STATUS);
} else {
dprintf(CRITICAL, "Battery alarm is not enabled\n");
return 1;
}
return rc;
}
/*
* Return 1 if VBUS is connected, 0 otherwise
*/
int pm89xx_vbus_status(void)
{
int rc;
uint8_t reg = 0;
rc = dev->read(&reg, 1, PM89XX_USB_OVP_CTRL);
if (rc) {
dprintf(CRITICAL, "Failed to read USB OVP CTRL = %d\n", rc);
return rc;
}
reg &= PM89XX_VBUS_INPUT_STATUS;
return reg;
}
static struct pm89xx_vreg *ldo_get(const char *ldo_name)
{
uint8_t i;
struct pm89xx_vreg *ldo = NULL;
for (i = 0; i < ARRAY_SIZE(ldo_data); i++) {
ldo = &ldo_data[i];
if (!strncmp(ldo->name, ldo_name, strlen(ldo_name)))
break;
}
return ldo;
}
/*
* API takes LDO name & voltage as input
* Input voltage is taken in mVs
* PLDO voltage ranging from 1500mV to 3000mV
* NLDO voltage ranging from 750mV to 1525mV
*/
int pm89xx_ldo_set_voltage(const char *ldo_name, uint32_t voltage)
{
uint8_t mult;
uint8_t val = 0;
int32_t ret = 0;
struct pm89xx_vreg *ldo;
/* Find the LDO info from table */
ldo = ldo_get(ldo_name);
if (!ldo) {
dprintf(CRITICAL, "Requested LDO is not supported : \
%s\n", ldo_name);
return -1;
}
/* Find the voltage multiplying factor */
if (ldo->type == PLDO_TYPE) {
if (voltage < PLDO_MV_VMIN)
voltage = PLDO_MV_VMIN;
else if (voltage > PLDO_MV_VMAX)
voltage = PLDO_MV_VMAX;
mult = (voltage - PLDO_MV_VMIN) / PLDO_MV_VSTEP;
} else {
if (voltage < NLDO_MV_VMIN)
voltage = NLDO_MV_VMIN;
else if (voltage > NLDO_MV_VMAX)
voltage = NLDO_MV_VMAX;
mult = (voltage - NLDO_MV_VMIN) / NLDO_MV_VSTEP;
}
/* Program the TEST reg */
if (ldo->type == PLDO_TYPE) {
/* Bank 2, only for p ldo, use 1.25V reference */
val = 0x0;
val |= (1 << PM8921_LDO_TEST_REG_RW);
val |= (2 << PM8921_LDO_TEST_REG_BANK_SEL);
ret = dev->write(&val, 1, ldo->test_reg);
if (ret) {
dprintf(CRITICAL, "Failed to write to PM8921 LDO Test \
Reg ret=%d.\n", ret);
return -1;
}
/*
* Bank 4, only for p ldo, disable output range ext,
* normal capacitance
*/
val = 0x0;
val |= (1 << PM8921_LDO_TEST_REG_RW);
val |= (4 << PM8921_LDO_TEST_REG_BANK_SEL);
ret = dev->write(&val, 1, ldo->test_reg);
if (ret) {
dprintf(CRITICAL, "Failed to write to PM8921 LDO Test \
Reg ret=%d.\n", ret);
return -1;
}
}
/* Program the CTRL reg */
val = 0x0;
val |= (1 << PM8921_LDO_CTRL_REG_ENABLE);
val |= (1 << PM8921_LDO_CTRL_REG_PULL_DOWN);
val |= (0 << PM8921_LDO_CTRL_REG_POWER_MODE);
val |= (mult << PM8921_LDO_CTRL_REG_VOLTAGE);
ret = dev->write(&val, 1, ldo->ctrl_reg);
if (ret) {
dprintf(CRITICAL, "Failed to write to PM8921 LDO Ctrl Reg \
ret=%d.\n", ret);
return -1;
}
return 0;
}
int pm8921_configure_wled(void)
{
pm8921_masked_write(WLED_BOOST_CFG_REG, 0xFF, 0x47);
pm8921_masked_write(WLED_HIGH_POLE_CAP_REG, 0xFF, 0x2c);
pm8921_masked_write(SSBI_REG_ADDR_WLED_CTRL(2), 0xFF, 0x19);
pm8921_masked_write(SSBI_REG_ADDR_WLED_CTRL(3), 0xFF, 0x59);
pm8921_masked_write(SSBI_REG_ADDR_WLED_CTRL(4), 0xFF, 0x59);
pm8921_masked_write(SSBI_REG_ADDR_WLED_CTRL(5), 0xFF, 0x66);
pm8921_masked_write(SSBI_REG_ADDR_WLED_CTRL(6), 0xFF, 0x66);
pm8921_masked_write(SSBI_REG_ADDR_WLED_CTRL(7), 0xFF, 0x0f);
pm8921_masked_write(SSBI_REG_ADDR_WLED_CTRL(8), 0xFF, 0xff);
pm8921_masked_write(SSBI_REG_ADDR_WLED_CTRL(9), 0xFF, 0x0f);
pm8921_masked_write(SSBI_REG_ADDR_WLED_CTRL(10), 0xFF, 0xff);
pm8921_masked_write(SSBI_REG_ADDR_WLED_CTRL(12), 0xFF, 0x16);
pm8921_masked_write(SSBI_REG_ADDR_WLED_CTRL(13), 0xFF, 0x55);
pm8921_masked_write(WLED_MOD_CTRL_REG, 0xFF, 0x7f);
pm8921_masked_write(WLED_SYNC_REG, WLED_SYNC_MASK, WLED_SYNC_VAL);
pm8921_masked_write(WLED_SYNC_REG, WLED_SYNC_MASK, WLED_SYNC_RESET_VAL);
}