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linux-next/drivers/iio/adc/ab8500-gpadc.c
Linus Walleij 07063bbfa9 iio: adc: New driver for the AB8500 GPADC
This is a new driver for the ST-Ericsson AB8500 GPADC, which
replaces the old driver in drivers/mfd/ab8500-gpadc.c and
thus gets rid of another necessarily different custom driver
from the times before IIO existed.

The AB8500 GPADC can convert 10 different channels and these
are used for monitoring voltages in the U8500 chipset, some
are used for battery charging, some for temperature
monitoring.

As this is very core functionality that a lot of drivers
depend on and was formerly compiled in with the AB8500 core
driver, we deafault it to 'y' in Kconfig: it can be compiled
out but it is really not advisible: the platform can
for example overheat if we do.

Reviewed-by: Jonathan Cameron <Jonathan.Cameron@huawei.com>
Signed-off-by: Linus Walleij <linus.walleij@linaro.org>
Signed-off-by: Jonathan Cameron <Jonathan.Cameron@huawei.com>
2019-10-18 19:37:44 +01:00

1219 lines
36 KiB
C

// SPDX-License-Identifier: GPL-2.0-only
/*
* Copyright (C) ST-Ericsson SA 2010
*
* Author: Arun R Murthy <arun.murthy@stericsson.com>
* Author: Daniel Willerud <daniel.willerud@stericsson.com>
* Author: Johan Palsson <johan.palsson@stericsson.com>
* Author: M'boumba Cedric Madianga
* Author: Linus Walleij <linus.walleij@linaro.org>
*
* AB8500 General Purpose ADC driver. The AB8500 uses reference voltages:
* VinVADC, and VADC relative to GND to do its job. It monitors main and backup
* battery voltages, AC (mains) voltage, USB cable voltage, as well as voltages
* representing the temperature of the chip die and battery, accessory
* detection by resistance measurements using relative voltages and GSM burst
* information.
*
* Some of the voltages are measured on external pins on the IC, such as
* battery temperature or "ADC aux" 1 and 2. Other voltages are internal rails
* from other parts of the ASIC such as main charger voltage, main and battery
* backup voltage or USB VBUS voltage. For this reason drivers for other
* parts of the system are required to obtain handles to the ADC to do work
* for them and the IIO driver provides arbitration among these consumers.
*/
#include <linux/init.h>
#include <linux/bits.h>
#include <linux/iio/iio.h>
#include <linux/iio/sysfs.h>
#include <linux/device.h>
#include <linux/interrupt.h>
#include <linux/spinlock.h>
#include <linux/delay.h>
#include <linux/pm_runtime.h>
#include <linux/platform_device.h>
#include <linux/completion.h>
#include <linux/regulator/consumer.h>
#include <linux/random.h>
#include <linux/err.h>
#include <linux/slab.h>
#include <linux/mfd/abx500.h>
#include <linux/mfd/abx500/ab8500.h>
/* GPADC register offsets and bit definitions */
#define AB8500_GPADC_CTRL1_REG 0x00
/* GPADC control register 1 bits */
#define AB8500_GPADC_CTRL1_DISABLE 0x00
#define AB8500_GPADC_CTRL1_ENABLE BIT(0)
#define AB8500_GPADC_CTRL1_TRIG_ENA BIT(1)
#define AB8500_GPADC_CTRL1_START_SW_CONV BIT(2)
#define AB8500_GPADC_CTRL1_BTEMP_PULL_UP BIT(3)
/* 0 = use rising edge, 1 = use falling edge */
#define AB8500_GPADC_CTRL1_TRIG_EDGE BIT(4)
/* 0 = use VTVOUT, 1 = use VRTC as pull-up supply for battery temp NTC */
#define AB8500_GPADC_CTRL1_PUPSUPSEL BIT(5)
#define AB8500_GPADC_CTRL1_BUF_ENA BIT(6)
#define AB8500_GPADC_CTRL1_ICHAR_ENA BIT(7)
#define AB8500_GPADC_CTRL2_REG 0x01
#define AB8500_GPADC_CTRL3_REG 0x02
/*
* GPADC control register 2 and 3 bits
* the bit layout is the same for SW and HW conversion set-up
*/
#define AB8500_GPADC_CTRL2_AVG_1 0x00
#define AB8500_GPADC_CTRL2_AVG_4 BIT(5)
#define AB8500_GPADC_CTRL2_AVG_8 BIT(6)
#define AB8500_GPADC_CTRL2_AVG_16 (BIT(5) | BIT(6))
enum ab8500_gpadc_channel {
AB8500_GPADC_CHAN_UNUSED = 0x00,
AB8500_GPADC_CHAN_BAT_CTRL = 0x01,
AB8500_GPADC_CHAN_BAT_TEMP = 0x02,
/* This is not used on AB8505 */
AB8500_GPADC_CHAN_MAIN_CHARGER = 0x03,
AB8500_GPADC_CHAN_ACC_DET_1 = 0x04,
AB8500_GPADC_CHAN_ACC_DET_2 = 0x05,
AB8500_GPADC_CHAN_ADC_AUX_1 = 0x06,
AB8500_GPADC_CHAN_ADC_AUX_2 = 0x07,
AB8500_GPADC_CHAN_VBAT_A = 0x08,
AB8500_GPADC_CHAN_VBUS = 0x09,
AB8500_GPADC_CHAN_MAIN_CHARGER_CURRENT = 0x0a,
AB8500_GPADC_CHAN_USB_CHARGER_CURRENT = 0x0b,
AB8500_GPADC_CHAN_BACKUP_BAT = 0x0c,
/* Only on AB8505 */
AB8505_GPADC_CHAN_DIE_TEMP = 0x0d,
AB8500_GPADC_CHAN_ID = 0x0e,
AB8500_GPADC_CHAN_INTERNAL_TEST_1 = 0x0f,
AB8500_GPADC_CHAN_INTERNAL_TEST_2 = 0x10,
AB8500_GPADC_CHAN_INTERNAL_TEST_3 = 0x11,
/* FIXME: Applicable to all ASIC variants? */
AB8500_GPADC_CHAN_XTAL_TEMP = 0x12,
AB8500_GPADC_CHAN_VBAT_TRUE_MEAS = 0x13,
/* FIXME: Doesn't seem to work with pure AB8500 */
AB8500_GPADC_CHAN_BAT_CTRL_AND_IBAT = 0x1c,
AB8500_GPADC_CHAN_VBAT_MEAS_AND_IBAT = 0x1d,
AB8500_GPADC_CHAN_VBAT_TRUE_MEAS_AND_IBAT = 0x1e,
AB8500_GPADC_CHAN_BAT_TEMP_AND_IBAT = 0x1f,
/*
* Virtual channel used only for ibat conversion to ampere.
* Battery current conversion (ibat) cannot be requested as a
* single conversion but it is always requested in combination
* with other input requests.
*/
AB8500_GPADC_CHAN_IBAT_VIRTUAL = 0xFF,
};
#define AB8500_GPADC_AUTO_TIMER_REG 0x03
#define AB8500_GPADC_STAT_REG 0x04
#define AB8500_GPADC_STAT_BUSY BIT(0)
#define AB8500_GPADC_MANDATAL_REG 0x05
#define AB8500_GPADC_MANDATAH_REG 0x06
#define AB8500_GPADC_AUTODATAL_REG 0x07
#define AB8500_GPADC_AUTODATAH_REG 0x08
#define AB8500_GPADC_MUX_CTRL_REG 0x09
#define AB8540_GPADC_MANDATA2L_REG 0x09
#define AB8540_GPADC_MANDATA2H_REG 0x0A
#define AB8540_GPADC_APEAAX_REG 0x10
#define AB8540_GPADC_APEAAT_REG 0x11
#define AB8540_GPADC_APEAAM_REG 0x12
#define AB8540_GPADC_APEAAH_REG 0x13
#define AB8540_GPADC_APEAAL_REG 0x14
/*
* OTP register offsets
* Bank : 0x15
*/
#define AB8500_GPADC_CAL_1 0x0F
#define AB8500_GPADC_CAL_2 0x10
#define AB8500_GPADC_CAL_3 0x11
#define AB8500_GPADC_CAL_4 0x12
#define AB8500_GPADC_CAL_5 0x13
#define AB8500_GPADC_CAL_6 0x14
#define AB8500_GPADC_CAL_7 0x15
/* New calibration for 8540 */
#define AB8540_GPADC_OTP4_REG_7 0x38
#define AB8540_GPADC_OTP4_REG_6 0x39
#define AB8540_GPADC_OTP4_REG_5 0x3A
#define AB8540_GPADC_DIS_ZERO 0x00
#define AB8540_GPADC_EN_VBIAS_XTAL_TEMP 0x02
/* GPADC constants from AB8500 spec, UM0836 */
#define AB8500_ADC_RESOLUTION 1024
#define AB8500_ADC_CH_BTEMP_MIN 0
#define AB8500_ADC_CH_BTEMP_MAX 1350
#define AB8500_ADC_CH_DIETEMP_MIN 0
#define AB8500_ADC_CH_DIETEMP_MAX 1350
#define AB8500_ADC_CH_CHG_V_MIN 0
#define AB8500_ADC_CH_CHG_V_MAX 20030
#define AB8500_ADC_CH_ACCDET2_MIN 0
#define AB8500_ADC_CH_ACCDET2_MAX 2500
#define AB8500_ADC_CH_VBAT_MIN 2300
#define AB8500_ADC_CH_VBAT_MAX 4800
#define AB8500_ADC_CH_CHG_I_MIN 0
#define AB8500_ADC_CH_CHG_I_MAX 1500
#define AB8500_ADC_CH_BKBAT_MIN 0
#define AB8500_ADC_CH_BKBAT_MAX 3200
/* GPADC constants from AB8540 spec */
#define AB8500_ADC_CH_IBAT_MIN (-6000) /* mA range measured by ADC for ibat */
#define AB8500_ADC_CH_IBAT_MAX 6000
#define AB8500_ADC_CH_IBAT_MIN_V (-60) /* mV range measured by ADC for ibat */
#define AB8500_ADC_CH_IBAT_MAX_V 60
#define AB8500_GPADC_IBAT_VDROP_L (-56) /* mV */
#define AB8500_GPADC_IBAT_VDROP_H 56
/* This is used to not lose precision when dividing to get gain and offset */
#define AB8500_GPADC_CALIB_SCALE 1000
/*
* Number of bits shift used to not lose precision
* when dividing to get ibat gain.
*/
#define AB8500_GPADC_CALIB_SHIFT_IBAT 20
/* Time in ms before disabling regulator */
#define AB8500_GPADC_AUTOSUSPEND_DELAY 1
#define AB8500_GPADC_CONVERSION_TIME 500 /* ms */
enum ab8500_cal_channels {
AB8500_CAL_VMAIN = 0,
AB8500_CAL_BTEMP,
AB8500_CAL_VBAT,
AB8500_CAL_IBAT,
AB8500_CAL_NR,
};
/**
* struct ab8500_adc_cal_data - Table for storing gain and offset for the
* calibrated ADC channels
* @gain: Gain of the ADC channel
* @offset: Offset of the ADC channel
* @otp_calib_hi: Calibration from OTP
* @otp_calib_lo: Calibration from OTP
*/
struct ab8500_adc_cal_data {
s64 gain;
s64 offset;
u16 otp_calib_hi;
u16 otp_calib_lo;
};
/**
* struct ab8500_gpadc_chan_info - per-channel GPADC info
* @name: name of the channel
* @id: the internal AB8500 ID number for the channel
* @hardware_control: indicate that we want to use hardware ADC control
* on this channel, the default is software ADC control. Hardware control
* is normally only used to test the battery voltage during GSM bursts
* and needs a hardware trigger on the GPADCTrig pin of the ASIC.
* @falling_edge: indicate that we want to trigger on falling edge
* rather than rising edge, rising edge is the default
* @avg_sample: how many samples to average: must be 1, 4, 8 or 16.
* @trig_timer: how long to wait for the trigger, in 32kHz periods:
* 0 .. 255 periods
*/
struct ab8500_gpadc_chan_info {
const char *name;
u8 id;
bool hardware_control;
bool falling_edge;
u8 avg_sample;
u8 trig_timer;
};
/**
* struct ab8500_gpadc - AB8500 GPADC device information
* @dev: pointer to the containing device
* @ab8500: pointer to the parent AB8500 device
* @chans: internal per-channel information container
* @nchans: number of channels
* @complete: pointer to the completion that indicates
* the completion of an gpadc conversion cycle
* @vddadc: pointer to the regulator supplying VDDADC
* @irq_sw: interrupt number that is used by gpadc for software ADC conversion
* @irq_hw: interrupt number that is used by gpadc for hardware ADC conversion
* @cal_data: array of ADC calibration data structs
*/
struct ab8500_gpadc {
struct device *dev;
struct ab8500 *ab8500;
struct ab8500_gpadc_chan_info *chans;
unsigned int nchans;
struct completion complete;
struct regulator *vddadc;
int irq_sw;
int irq_hw;
struct ab8500_adc_cal_data cal_data[AB8500_CAL_NR];
};
static struct ab8500_gpadc_chan_info *
ab8500_gpadc_get_channel(struct ab8500_gpadc *gpadc, u8 chan)
{
struct ab8500_gpadc_chan_info *ch;
int i;
for (i = 0; i < gpadc->nchans; i++) {
ch = &gpadc->chans[i];
if (ch->id == chan)
break;
}
if (i == gpadc->nchans)
return NULL;
return ch;
}
/**
* ab8500_gpadc_ad_to_voltage() - Convert a raw ADC value to a voltage
* @gpadc: GPADC instance
* @ch: the sampled channel this raw value is coming from
* @ad_value: the raw value
*/
static int ab8500_gpadc_ad_to_voltage(struct ab8500_gpadc *gpadc,
enum ab8500_gpadc_channel ch,
int ad_value)
{
int res;
switch (ch) {
case AB8500_GPADC_CHAN_MAIN_CHARGER:
/* No calibration data available: just interpolate */
if (!gpadc->cal_data[AB8500_CAL_VMAIN].gain) {
res = AB8500_ADC_CH_CHG_V_MIN + (AB8500_ADC_CH_CHG_V_MAX -
AB8500_ADC_CH_CHG_V_MIN) * ad_value /
AB8500_ADC_RESOLUTION;
break;
}
/* Here we can use calibration */
res = (int) (ad_value * gpadc->cal_data[AB8500_CAL_VMAIN].gain +
gpadc->cal_data[AB8500_CAL_VMAIN].offset) / AB8500_GPADC_CALIB_SCALE;
break;
case AB8500_GPADC_CHAN_BAT_CTRL:
case AB8500_GPADC_CHAN_BAT_TEMP:
case AB8500_GPADC_CHAN_ACC_DET_1:
case AB8500_GPADC_CHAN_ADC_AUX_1:
case AB8500_GPADC_CHAN_ADC_AUX_2:
case AB8500_GPADC_CHAN_XTAL_TEMP:
/* No calibration data available: just interpolate */
if (!gpadc->cal_data[AB8500_CAL_BTEMP].gain) {
res = AB8500_ADC_CH_BTEMP_MIN + (AB8500_ADC_CH_BTEMP_MAX -
AB8500_ADC_CH_BTEMP_MIN) * ad_value /
AB8500_ADC_RESOLUTION;
break;
}
/* Here we can use calibration */
res = (int) (ad_value * gpadc->cal_data[AB8500_CAL_BTEMP].gain +
gpadc->cal_data[AB8500_CAL_BTEMP].offset) / AB8500_GPADC_CALIB_SCALE;
break;
case AB8500_GPADC_CHAN_VBAT_A:
case AB8500_GPADC_CHAN_VBAT_TRUE_MEAS:
/* No calibration data available: just interpolate */
if (!gpadc->cal_data[AB8500_CAL_VBAT].gain) {
res = AB8500_ADC_CH_VBAT_MIN + (AB8500_ADC_CH_VBAT_MAX -
AB8500_ADC_CH_VBAT_MIN) * ad_value /
AB8500_ADC_RESOLUTION;
break;
}
/* Here we can use calibration */
res = (int) (ad_value * gpadc->cal_data[AB8500_CAL_VBAT].gain +
gpadc->cal_data[AB8500_CAL_VBAT].offset) / AB8500_GPADC_CALIB_SCALE;
break;
case AB8505_GPADC_CHAN_DIE_TEMP:
res = AB8500_ADC_CH_DIETEMP_MIN +
(AB8500_ADC_CH_DIETEMP_MAX - AB8500_ADC_CH_DIETEMP_MIN) * ad_value /
AB8500_ADC_RESOLUTION;
break;
case AB8500_GPADC_CHAN_ACC_DET_2:
res = AB8500_ADC_CH_ACCDET2_MIN +
(AB8500_ADC_CH_ACCDET2_MAX - AB8500_ADC_CH_ACCDET2_MIN) * ad_value /
AB8500_ADC_RESOLUTION;
break;
case AB8500_GPADC_CHAN_VBUS:
res = AB8500_ADC_CH_CHG_V_MIN +
(AB8500_ADC_CH_CHG_V_MAX - AB8500_ADC_CH_CHG_V_MIN) * ad_value /
AB8500_ADC_RESOLUTION;
break;
case AB8500_GPADC_CHAN_MAIN_CHARGER_CURRENT:
case AB8500_GPADC_CHAN_USB_CHARGER_CURRENT:
res = AB8500_ADC_CH_CHG_I_MIN +
(AB8500_ADC_CH_CHG_I_MAX - AB8500_ADC_CH_CHG_I_MIN) * ad_value /
AB8500_ADC_RESOLUTION;
break;
case AB8500_GPADC_CHAN_BACKUP_BAT:
res = AB8500_ADC_CH_BKBAT_MIN +
(AB8500_ADC_CH_BKBAT_MAX - AB8500_ADC_CH_BKBAT_MIN) * ad_value /
AB8500_ADC_RESOLUTION;
break;
case AB8500_GPADC_CHAN_IBAT_VIRTUAL:
/* No calibration data available: just interpolate */
if (!gpadc->cal_data[AB8500_CAL_IBAT].gain) {
res = AB8500_ADC_CH_IBAT_MIN + (AB8500_ADC_CH_IBAT_MAX -
AB8500_ADC_CH_IBAT_MIN) * ad_value /
AB8500_ADC_RESOLUTION;
break;
}
/* Here we can use calibration */
res = (int) (ad_value * gpadc->cal_data[AB8500_CAL_IBAT].gain +
gpadc->cal_data[AB8500_CAL_IBAT].offset)
>> AB8500_GPADC_CALIB_SHIFT_IBAT;
break;
default:
dev_err(gpadc->dev,
"unknown channel ID: %d, not possible to convert\n",
ch);
res = -EINVAL;
break;
}
return res;
}
static int ab8500_gpadc_read(struct ab8500_gpadc *gpadc,
const struct ab8500_gpadc_chan_info *ch,
int *ibat)
{
int ret;
int looplimit = 0;
unsigned long completion_timeout;
u8 val;
u8 low_data, high_data, low_data2, high_data2;
u8 ctrl1;
u8 ctrl23;
unsigned int delay_min = 0;
unsigned int delay_max = 0;
u8 data_low_addr, data_high_addr;
if (!gpadc)
return -ENODEV;
/* check if conversion is supported */
if ((gpadc->irq_sw <= 0) && !ch->hardware_control)
return -ENOTSUPP;
if ((gpadc->irq_hw <= 0) && ch->hardware_control)
return -ENOTSUPP;
/* Enable vddadc by grabbing PM runtime */
pm_runtime_get_sync(gpadc->dev);
/* Check if ADC is not busy, lock and proceed */
do {
ret = abx500_get_register_interruptible(gpadc->dev,
AB8500_GPADC, AB8500_GPADC_STAT_REG, &val);
if (ret < 0)
goto out;
if (!(val & AB8500_GPADC_STAT_BUSY))
break;
msleep(20);
} while (++looplimit < 10);
if (looplimit >= 10 && (val & AB8500_GPADC_STAT_BUSY)) {
dev_err(gpadc->dev, "gpadc_conversion: GPADC busy");
ret = -EINVAL;
goto out;
}
/* Enable GPADC */
ctrl1 = AB8500_GPADC_CTRL1_ENABLE;
/* Select the channel source and set average samples */
switch (ch->avg_sample) {
case 1:
ctrl23 = ch->id | AB8500_GPADC_CTRL2_AVG_1;
break;
case 4:
ctrl23 = ch->id | AB8500_GPADC_CTRL2_AVG_4;
break;
case 8:
ctrl23 = ch->id | AB8500_GPADC_CTRL2_AVG_8;
break;
default:
ctrl23 = ch->id | AB8500_GPADC_CTRL2_AVG_16;
break;
}
if (ch->hardware_control) {
ret = abx500_set_register_interruptible(gpadc->dev,
AB8500_GPADC, AB8500_GPADC_CTRL3_REG, ctrl23);
ctrl1 |= AB8500_GPADC_CTRL1_TRIG_ENA;
if (ch->falling_edge)
ctrl1 |= AB8500_GPADC_CTRL1_TRIG_EDGE;
} else {
ret = abx500_set_register_interruptible(gpadc->dev,
AB8500_GPADC, AB8500_GPADC_CTRL2_REG, ctrl23);
}
if (ret < 0) {
dev_err(gpadc->dev,
"gpadc_conversion: set avg samples failed\n");
goto out;
}
/*
* Enable ADC, buffering, select rising edge and enable ADC path
* charging current sense if it needed, ABB 3.0 needs some special
* treatment too.
*/
switch (ch->id) {
case AB8500_GPADC_CHAN_MAIN_CHARGER_CURRENT:
case AB8500_GPADC_CHAN_USB_CHARGER_CURRENT:
ctrl1 |= AB8500_GPADC_CTRL1_BUF_ENA |
AB8500_GPADC_CTRL1_ICHAR_ENA;
break;
case AB8500_GPADC_CHAN_BAT_TEMP:
if (!is_ab8500_2p0_or_earlier(gpadc->ab8500)) {
ctrl1 |= AB8500_GPADC_CTRL1_BUF_ENA |
AB8500_GPADC_CTRL1_BTEMP_PULL_UP;
/*
* Delay might be needed for ABB8500 cut 3.0, if not,
* remove when hardware will be available
*/
delay_min = 1000; /* Delay in micro seconds */
delay_max = 10000; /* large range optimises sleepmode */
break;
}
/* Fall through */
default:
ctrl1 |= AB8500_GPADC_CTRL1_BUF_ENA;
break;
}
/* Write configuration to control register 1 */
ret = abx500_set_register_interruptible(gpadc->dev,
AB8500_GPADC, AB8500_GPADC_CTRL1_REG, ctrl1);
if (ret < 0) {
dev_err(gpadc->dev,
"gpadc_conversion: set Control register failed\n");
goto out;
}
if (delay_min != 0)
usleep_range(delay_min, delay_max);
if (ch->hardware_control) {
/* Set trigger delay timer */
ret = abx500_set_register_interruptible(gpadc->dev,
AB8500_GPADC, AB8500_GPADC_AUTO_TIMER_REG,
ch->trig_timer);
if (ret < 0) {
dev_err(gpadc->dev,
"gpadc_conversion: trig timer failed\n");
goto out;
}
completion_timeout = 2 * HZ;
data_low_addr = AB8500_GPADC_AUTODATAL_REG;
data_high_addr = AB8500_GPADC_AUTODATAH_REG;
} else {
/* Start SW conversion */
ret = abx500_mask_and_set_register_interruptible(gpadc->dev,
AB8500_GPADC, AB8500_GPADC_CTRL1_REG,
AB8500_GPADC_CTRL1_START_SW_CONV,
AB8500_GPADC_CTRL1_START_SW_CONV);
if (ret < 0) {
dev_err(gpadc->dev,
"gpadc_conversion: start s/w conv failed\n");
goto out;
}
completion_timeout = msecs_to_jiffies(AB8500_GPADC_CONVERSION_TIME);
data_low_addr = AB8500_GPADC_MANDATAL_REG;
data_high_addr = AB8500_GPADC_MANDATAH_REG;
}
/* Wait for completion of conversion */
if (!wait_for_completion_timeout(&gpadc->complete,
completion_timeout)) {
dev_err(gpadc->dev,
"timeout didn't receive GPADC conv interrupt\n");
ret = -EINVAL;
goto out;
}
/* Read the converted RAW data */
ret = abx500_get_register_interruptible(gpadc->dev,
AB8500_GPADC, data_low_addr, &low_data);
if (ret < 0) {
dev_err(gpadc->dev,
"gpadc_conversion: read low data failed\n");
goto out;
}
ret = abx500_get_register_interruptible(gpadc->dev,
AB8500_GPADC, data_high_addr, &high_data);
if (ret < 0) {
dev_err(gpadc->dev,
"gpadc_conversion: read high data failed\n");
goto out;
}
/* Check if double conversion is required */
if ((ch->id == AB8500_GPADC_CHAN_BAT_CTRL_AND_IBAT) ||
(ch->id == AB8500_GPADC_CHAN_VBAT_MEAS_AND_IBAT) ||
(ch->id == AB8500_GPADC_CHAN_VBAT_TRUE_MEAS_AND_IBAT) ||
(ch->id == AB8500_GPADC_CHAN_BAT_TEMP_AND_IBAT)) {
if (ch->hardware_control) {
/* not supported */
ret = -ENOTSUPP;
dev_err(gpadc->dev,
"gpadc_conversion: only SW double conversion supported\n");
goto out;
} else {
/* Read the converted RAW data 2 */
ret = abx500_get_register_interruptible(gpadc->dev,
AB8500_GPADC, AB8540_GPADC_MANDATA2L_REG,
&low_data2);
if (ret < 0) {
dev_err(gpadc->dev,
"gpadc_conversion: read sw low data 2 failed\n");
goto out;
}
ret = abx500_get_register_interruptible(gpadc->dev,
AB8500_GPADC, AB8540_GPADC_MANDATA2H_REG,
&high_data2);
if (ret < 0) {
dev_err(gpadc->dev,
"gpadc_conversion: read sw high data 2 failed\n");
goto out;
}
if (ibat != NULL) {
*ibat = (high_data2 << 8) | low_data2;
} else {
dev_warn(gpadc->dev,
"gpadc_conversion: ibat not stored\n");
}
}
}
/* Disable GPADC */
ret = abx500_set_register_interruptible(gpadc->dev, AB8500_GPADC,
AB8500_GPADC_CTRL1_REG, AB8500_GPADC_CTRL1_DISABLE);
if (ret < 0) {
dev_err(gpadc->dev, "gpadc_conversion: disable gpadc failed\n");
goto out;
}
/* This eventually drops the regulator */
pm_runtime_mark_last_busy(gpadc->dev);
pm_runtime_put_autosuspend(gpadc->dev);
return (high_data << 8) | low_data;
out:
/*
* It has shown to be needed to turn off the GPADC if an error occurs,
* otherwise we might have problem when waiting for the busy bit in the
* GPADC status register to go low. In V1.1 there wait_for_completion
* seems to timeout when waiting for an interrupt.. Not seen in V2.0
*/
(void) abx500_set_register_interruptible(gpadc->dev, AB8500_GPADC,
AB8500_GPADC_CTRL1_REG, AB8500_GPADC_CTRL1_DISABLE);
pm_runtime_put(gpadc->dev);
dev_err(gpadc->dev,
"gpadc_conversion: Failed to AD convert channel %d\n", ch->id);
return ret;
}
/**
* ab8500_bm_gpadcconvend_handler() - isr for gpadc conversion completion
* @irq: irq number
* @data: pointer to the data passed during request irq
*
* This is a interrupt service routine for gpadc conversion completion.
* Notifies the gpadc completion is completed and the converted raw value
* can be read from the registers.
* Returns IRQ status(IRQ_HANDLED)
*/
static irqreturn_t ab8500_bm_gpadcconvend_handler(int irq, void *data)
{
struct ab8500_gpadc *gpadc = data;
complete(&gpadc->complete);
return IRQ_HANDLED;
}
static int otp_cal_regs[] = {
AB8500_GPADC_CAL_1,
AB8500_GPADC_CAL_2,
AB8500_GPADC_CAL_3,
AB8500_GPADC_CAL_4,
AB8500_GPADC_CAL_5,
AB8500_GPADC_CAL_6,
AB8500_GPADC_CAL_7,
};
static int otp4_cal_regs[] = {
AB8540_GPADC_OTP4_REG_7,
AB8540_GPADC_OTP4_REG_6,
AB8540_GPADC_OTP4_REG_5,
};
static void ab8500_gpadc_read_calibration_data(struct ab8500_gpadc *gpadc)
{
int i;
int ret[ARRAY_SIZE(otp_cal_regs)];
u8 gpadc_cal[ARRAY_SIZE(otp_cal_regs)];
int ret_otp4[ARRAY_SIZE(otp4_cal_regs)];
u8 gpadc_otp4[ARRAY_SIZE(otp4_cal_regs)];
int vmain_high, vmain_low;
int btemp_high, btemp_low;
int vbat_high, vbat_low;
int ibat_high, ibat_low;
s64 V_gain, V_offset, V2A_gain, V2A_offset;
/* First we read all OTP registers and store the error code */
for (i = 0; i < ARRAY_SIZE(otp_cal_regs); i++) {
ret[i] = abx500_get_register_interruptible(gpadc->dev,
AB8500_OTP_EMUL, otp_cal_regs[i], &gpadc_cal[i]);
if (ret[i] < 0) {
/* Continue anyway: maybe the other registers are OK */
dev_err(gpadc->dev, "%s: read otp reg 0x%02x failed\n",
__func__, otp_cal_regs[i]);
} else {
/* Put this in the entropy pool as device-unique */
add_device_randomness(&ret[i], sizeof(ret[i]));
}
}
/*
* The ADC calibration data is stored in OTP registers.
* The layout of the calibration data is outlined below and a more
* detailed description can be found in UM0836
*
* vm_h/l = vmain_high/low
* bt_h/l = btemp_high/low
* vb_h/l = vbat_high/low
*
* Data bits 8500/9540:
* | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0
* |.......|.......|.......|.......|.......|.......|.......|.......
* | | vm_h9 | vm_h8
* |.......|.......|.......|.......|.......|.......|.......|.......
* | | vm_h7 | vm_h6 | vm_h5 | vm_h4 | vm_h3 | vm_h2
* |.......|.......|.......|.......|.......|.......|.......|.......
* | vm_h1 | vm_h0 | vm_l4 | vm_l3 | vm_l2 | vm_l1 | vm_l0 | bt_h9
* |.......|.......|.......|.......|.......|.......|.......|.......
* | bt_h8 | bt_h7 | bt_h6 | bt_h5 | bt_h4 | bt_h3 | bt_h2 | bt_h1
* |.......|.......|.......|.......|.......|.......|.......|.......
* | bt_h0 | bt_l4 | bt_l3 | bt_l2 | bt_l1 | bt_l0 | vb_h9 | vb_h8
* |.......|.......|.......|.......|.......|.......|.......|.......
* | vb_h7 | vb_h6 | vb_h5 | vb_h4 | vb_h3 | vb_h2 | vb_h1 | vb_h0
* |.......|.......|.......|.......|.......|.......|.......|.......
* | vb_l5 | vb_l4 | vb_l3 | vb_l2 | vb_l1 | vb_l0 |
* |.......|.......|.......|.......|.......|.......|.......|.......
*
* Data bits 8540:
* OTP2
* | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0
* |.......|.......|.......|.......|.......|.......|.......|.......
* |
* |.......|.......|.......|.......|.......|.......|.......|.......
* | vm_h9 | vm_h8 | vm_h7 | vm_h6 | vm_h5 | vm_h4 | vm_h3 | vm_h2
* |.......|.......|.......|.......|.......|.......|.......|.......
* | vm_h1 | vm_h0 | vm_l4 | vm_l3 | vm_l2 | vm_l1 | vm_l0 | bt_h9
* |.......|.......|.......|.......|.......|.......|.......|.......
* | bt_h8 | bt_h7 | bt_h6 | bt_h5 | bt_h4 | bt_h3 | bt_h2 | bt_h1
* |.......|.......|.......|.......|.......|.......|.......|.......
* | bt_h0 | bt_l4 | bt_l3 | bt_l2 | bt_l1 | bt_l0 | vb_h9 | vb_h8
* |.......|.......|.......|.......|.......|.......|.......|.......
* | vb_h7 | vb_h6 | vb_h5 | vb_h4 | vb_h3 | vb_h2 | vb_h1 | vb_h0
* |.......|.......|.......|.......|.......|.......|.......|.......
* | vb_l5 | vb_l4 | vb_l3 | vb_l2 | vb_l1 | vb_l0 |
* |.......|.......|.......|.......|.......|.......|.......|.......
*
* Data bits 8540:
* OTP4
* | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0
* |.......|.......|.......|.......|.......|.......|.......|.......
* | | ib_h9 | ib_h8 | ib_h7
* |.......|.......|.......|.......|.......|.......|.......|.......
* | ib_h6 | ib_h5 | ib_h4 | ib_h3 | ib_h2 | ib_h1 | ib_h0 | ib_l5
* |.......|.......|.......|.......|.......|.......|.......|.......
* | ib_l4 | ib_l3 | ib_l2 | ib_l1 | ib_l0 |
*
*
* Ideal output ADC codes corresponding to injected input voltages
* during manufacturing is:
*
* vmain_high: Vin = 19500mV / ADC ideal code = 997
* vmain_low: Vin = 315mV / ADC ideal code = 16
* btemp_high: Vin = 1300mV / ADC ideal code = 985
* btemp_low: Vin = 21mV / ADC ideal code = 16
* vbat_high: Vin = 4700mV / ADC ideal code = 982
* vbat_low: Vin = 2380mV / ADC ideal code = 33
*/
if (is_ab8540(gpadc->ab8500)) {
/* Calculate gain and offset for VMAIN if all reads succeeded*/
if (!(ret[1] < 0 || ret[2] < 0)) {
vmain_high = (((gpadc_cal[1] & 0xFF) << 2) |
((gpadc_cal[2] & 0xC0) >> 6));
vmain_low = ((gpadc_cal[2] & 0x3E) >> 1);
gpadc->cal_data[AB8500_CAL_VMAIN].otp_calib_hi =
(u16)vmain_high;
gpadc->cal_data[AB8500_CAL_VMAIN].otp_calib_lo =
(u16)vmain_low;
gpadc->cal_data[AB8500_CAL_VMAIN].gain = AB8500_GPADC_CALIB_SCALE *
(19500 - 315) / (vmain_high - vmain_low);
gpadc->cal_data[AB8500_CAL_VMAIN].offset = AB8500_GPADC_CALIB_SCALE *
19500 - (AB8500_GPADC_CALIB_SCALE * (19500 - 315) /
(vmain_high - vmain_low)) * vmain_high;
} else {
gpadc->cal_data[AB8500_CAL_VMAIN].gain = 0;
}
/* Read IBAT calibration Data */
for (i = 0; i < ARRAY_SIZE(otp4_cal_regs); i++) {
ret_otp4[i] = abx500_get_register_interruptible(
gpadc->dev, AB8500_OTP_EMUL,
otp4_cal_regs[i], &gpadc_otp4[i]);
if (ret_otp4[i] < 0)
dev_err(gpadc->dev,
"%s: read otp4 reg 0x%02x failed\n",
__func__, otp4_cal_regs[i]);
}
/* Calculate gain and offset for IBAT if all reads succeeded */
if (!(ret_otp4[0] < 0 || ret_otp4[1] < 0 || ret_otp4[2] < 0)) {
ibat_high = (((gpadc_otp4[0] & 0x07) << 7) |
((gpadc_otp4[1] & 0xFE) >> 1));
ibat_low = (((gpadc_otp4[1] & 0x01) << 5) |
((gpadc_otp4[2] & 0xF8) >> 3));
gpadc->cal_data[AB8500_CAL_IBAT].otp_calib_hi =
(u16)ibat_high;
gpadc->cal_data[AB8500_CAL_IBAT].otp_calib_lo =
(u16)ibat_low;
V_gain = ((AB8500_GPADC_IBAT_VDROP_H - AB8500_GPADC_IBAT_VDROP_L)
<< AB8500_GPADC_CALIB_SHIFT_IBAT) / (ibat_high - ibat_low);
V_offset = (AB8500_GPADC_IBAT_VDROP_H << AB8500_GPADC_CALIB_SHIFT_IBAT) -
(((AB8500_GPADC_IBAT_VDROP_H - AB8500_GPADC_IBAT_VDROP_L) <<
AB8500_GPADC_CALIB_SHIFT_IBAT) / (ibat_high - ibat_low))
* ibat_high;
/*
* Result obtained is in mV (at a scale factor),
* we need to calculate gain and offset to get mA
*/
V2A_gain = (AB8500_ADC_CH_IBAT_MAX - AB8500_ADC_CH_IBAT_MIN)/
(AB8500_ADC_CH_IBAT_MAX_V - AB8500_ADC_CH_IBAT_MIN_V);
V2A_offset = ((AB8500_ADC_CH_IBAT_MAX_V * AB8500_ADC_CH_IBAT_MIN -
AB8500_ADC_CH_IBAT_MAX * AB8500_ADC_CH_IBAT_MIN_V)
<< AB8500_GPADC_CALIB_SHIFT_IBAT)
/ (AB8500_ADC_CH_IBAT_MAX_V - AB8500_ADC_CH_IBAT_MIN_V);
gpadc->cal_data[AB8500_CAL_IBAT].gain =
V_gain * V2A_gain;
gpadc->cal_data[AB8500_CAL_IBAT].offset =
V_offset * V2A_gain + V2A_offset;
} else {
gpadc->cal_data[AB8500_CAL_IBAT].gain = 0;
}
} else {
/* Calculate gain and offset for VMAIN if all reads succeeded */
if (!(ret[0] < 0 || ret[1] < 0 || ret[2] < 0)) {
vmain_high = (((gpadc_cal[0] & 0x03) << 8) |
((gpadc_cal[1] & 0x3F) << 2) |
((gpadc_cal[2] & 0xC0) >> 6));
vmain_low = ((gpadc_cal[2] & 0x3E) >> 1);
gpadc->cal_data[AB8500_CAL_VMAIN].otp_calib_hi =
(u16)vmain_high;
gpadc->cal_data[AB8500_CAL_VMAIN].otp_calib_lo =
(u16)vmain_low;
gpadc->cal_data[AB8500_CAL_VMAIN].gain = AB8500_GPADC_CALIB_SCALE *
(19500 - 315) / (vmain_high - vmain_low);
gpadc->cal_data[AB8500_CAL_VMAIN].offset = AB8500_GPADC_CALIB_SCALE *
19500 - (AB8500_GPADC_CALIB_SCALE * (19500 - 315) /
(vmain_high - vmain_low)) * vmain_high;
} else {
gpadc->cal_data[AB8500_CAL_VMAIN].gain = 0;
}
}
/* Calculate gain and offset for BTEMP if all reads succeeded */
if (!(ret[2] < 0 || ret[3] < 0 || ret[4] < 0)) {
btemp_high = (((gpadc_cal[2] & 0x01) << 9) |
(gpadc_cal[3] << 1) | ((gpadc_cal[4] & 0x80) >> 7));
btemp_low = ((gpadc_cal[4] & 0x7C) >> 2);
gpadc->cal_data[AB8500_CAL_BTEMP].otp_calib_hi = (u16)btemp_high;
gpadc->cal_data[AB8500_CAL_BTEMP].otp_calib_lo = (u16)btemp_low;
gpadc->cal_data[AB8500_CAL_BTEMP].gain =
AB8500_GPADC_CALIB_SCALE * (1300 - 21) / (btemp_high - btemp_low);
gpadc->cal_data[AB8500_CAL_BTEMP].offset = AB8500_GPADC_CALIB_SCALE * 1300 -
(AB8500_GPADC_CALIB_SCALE * (1300 - 21) / (btemp_high - btemp_low))
* btemp_high;
} else {
gpadc->cal_data[AB8500_CAL_BTEMP].gain = 0;
}
/* Calculate gain and offset for VBAT if all reads succeeded */
if (!(ret[4] < 0 || ret[5] < 0 || ret[6] < 0)) {
vbat_high = (((gpadc_cal[4] & 0x03) << 8) | gpadc_cal[5]);
vbat_low = ((gpadc_cal[6] & 0xFC) >> 2);
gpadc->cal_data[AB8500_CAL_VBAT].otp_calib_hi = (u16)vbat_high;
gpadc->cal_data[AB8500_CAL_VBAT].otp_calib_lo = (u16)vbat_low;
gpadc->cal_data[AB8500_CAL_VBAT].gain = AB8500_GPADC_CALIB_SCALE *
(4700 - 2380) / (vbat_high - vbat_low);
gpadc->cal_data[AB8500_CAL_VBAT].offset = AB8500_GPADC_CALIB_SCALE * 4700 -
(AB8500_GPADC_CALIB_SCALE * (4700 - 2380) /
(vbat_high - vbat_low)) * vbat_high;
} else {
gpadc->cal_data[AB8500_CAL_VBAT].gain = 0;
}
}
static int ab8500_gpadc_read_raw(struct iio_dev *indio_dev,
struct iio_chan_spec const *chan,
int *val, int *val2, long mask)
{
struct ab8500_gpadc *gpadc = iio_priv(indio_dev);
const struct ab8500_gpadc_chan_info *ch;
int raw_val;
int processed;
ch = ab8500_gpadc_get_channel(gpadc, chan->address);
if (!ch) {
dev_err(gpadc->dev, "no such channel %lu\n",
chan->address);
return -EINVAL;
}
raw_val = ab8500_gpadc_read(gpadc, ch, NULL);
if (raw_val < 0)
return raw_val;
if (mask == IIO_CHAN_INFO_RAW) {
*val = raw_val;
return IIO_VAL_INT;
}
if (mask == IIO_CHAN_INFO_PROCESSED) {
processed = ab8500_gpadc_ad_to_voltage(gpadc, ch->id, raw_val);
if (processed < 0)
return processed;
/* Return millivolt or milliamps or millicentigrades */
*val = processed * 1000;
return IIO_VAL_INT;
}
return -EINVAL;
}
static int ab8500_gpadc_of_xlate(struct iio_dev *indio_dev,
const struct of_phandle_args *iiospec)
{
int i;
for (i = 0; i < indio_dev->num_channels; i++)
if (indio_dev->channels[i].channel == iiospec->args[0])
return i;
return -EINVAL;
}
static const struct iio_info ab8500_gpadc_info = {
.of_xlate = ab8500_gpadc_of_xlate,
.read_raw = ab8500_gpadc_read_raw,
};
#ifdef CONFIG_PM
static int ab8500_gpadc_runtime_suspend(struct device *dev)
{
struct iio_dev *indio_dev = dev_get_drvdata(dev);
struct ab8500_gpadc *gpadc = iio_priv(indio_dev);
regulator_disable(gpadc->vddadc);
return 0;
}
static int ab8500_gpadc_runtime_resume(struct device *dev)
{
struct iio_dev *indio_dev = dev_get_drvdata(dev);
struct ab8500_gpadc *gpadc = iio_priv(indio_dev);
int ret;
ret = regulator_enable(gpadc->vddadc);
if (ret)
dev_err(dev, "Failed to enable vddadc: %d\n", ret);
return ret;
}
#endif
/**
* ab8500_gpadc_parse_channel() - process devicetree channel configuration
* @dev: pointer to containing device
* @np: device tree node for the channel to configure
* @ch: channel info to fill in
* @iio_chan: IIO channel specification to fill in
*
* The devicetree will set up the channel for use with the specific device,
* and define usage for things like AUX GPADC inputs more precisely.
*/
static int ab8500_gpadc_parse_channel(struct device *dev,
struct device_node *np,
struct ab8500_gpadc_chan_info *ch,
struct iio_chan_spec *iio_chan)
{
const char *name = np->name;
u32 chan;
int ret;
ret = of_property_read_u32(np, "reg", &chan);
if (ret) {
dev_err(dev, "invalid channel number %s\n", name);
return ret;
}
if (chan > AB8500_GPADC_CHAN_BAT_TEMP_AND_IBAT) {
dev_err(dev, "%s channel number out of range %d\n", name, chan);
return -EINVAL;
}
iio_chan->channel = chan;
iio_chan->datasheet_name = name;
iio_chan->indexed = 1;
iio_chan->address = chan;
iio_chan->info_mask_separate = BIT(IIO_CHAN_INFO_RAW) |
BIT(IIO_CHAN_INFO_PROCESSED);
/* Most are voltages (also temperatures), some are currents */
if ((chan == AB8500_GPADC_CHAN_MAIN_CHARGER_CURRENT) ||
(chan == AB8500_GPADC_CHAN_USB_CHARGER_CURRENT))
iio_chan->type = IIO_CURRENT;
else
iio_chan->type = IIO_VOLTAGE;
ch->id = chan;
/* Sensible defaults */
ch->avg_sample = 16;
ch->hardware_control = false;
ch->falling_edge = false;
ch->trig_timer = 0;
return 0;
}
/**
* ab8500_gpadc_parse_channels() - Parse the GPADC channels from DT
* @gpadc: the GPADC to configure the channels for
* @np: device tree node containing the channel configurations
* @chans: the IIO channels we parsed
* @nchans: the number of IIO channels we parsed
*/
static int ab8500_gpadc_parse_channels(struct ab8500_gpadc *gpadc,
struct device_node *np,
struct iio_chan_spec **chans_parsed,
unsigned int *nchans_parsed)
{
struct device_node *child;
struct ab8500_gpadc_chan_info *ch;
struct iio_chan_spec *iio_chans;
unsigned int nchans;
int i;
nchans = of_get_available_child_count(np);
if (!nchans) {
dev_err(gpadc->dev, "no channel children\n");
return -ENODEV;
}
dev_info(gpadc->dev, "found %d ADC channels\n", nchans);
iio_chans = devm_kcalloc(gpadc->dev, nchans,
sizeof(*iio_chans), GFP_KERNEL);
if (!iio_chans)
return -ENOMEM;
gpadc->chans = devm_kcalloc(gpadc->dev, nchans,
sizeof(*gpadc->chans), GFP_KERNEL);
if (!gpadc->chans)
return -ENOMEM;
i = 0;
for_each_available_child_of_node(np, child) {
struct iio_chan_spec *iio_chan;
int ret;
ch = &gpadc->chans[i];
iio_chan = &iio_chans[i];
ret = ab8500_gpadc_parse_channel(gpadc->dev, child, ch,
iio_chan);
if (ret) {
of_node_put(child);
return ret;
}
i++;
}
gpadc->nchans = nchans;
*chans_parsed = iio_chans;
*nchans_parsed = nchans;
return 0;
}
static int ab8500_gpadc_probe(struct platform_device *pdev)
{
struct ab8500_gpadc *gpadc;
struct iio_dev *indio_dev;
struct device *dev = &pdev->dev;
struct device_node *np = pdev->dev.of_node;
struct iio_chan_spec *iio_chans;
unsigned int n_iio_chans;
int ret;
indio_dev = devm_iio_device_alloc(dev, sizeof(*gpadc));
if (!indio_dev)
return -ENOMEM;
platform_set_drvdata(pdev, indio_dev);
gpadc = iio_priv(indio_dev);
gpadc->dev = dev;
gpadc->ab8500 = dev_get_drvdata(dev->parent);
ret = ab8500_gpadc_parse_channels(gpadc, np, &iio_chans, &n_iio_chans);
if (ret)
return ret;
gpadc->irq_sw = platform_get_irq_byname(pdev, "SW_CONV_END");
if (gpadc->irq_sw < 0) {
dev_err(dev, "failed to get platform sw_conv_end irq\n");
return gpadc->irq_sw;
}
gpadc->irq_hw = platform_get_irq_byname(pdev, "HW_CONV_END");
if (gpadc->irq_hw < 0) {
dev_err(dev, "failed to get platform hw_conv_end irq\n");
return gpadc->irq_hw;
}
/* Initialize completion used to notify completion of conversion */
init_completion(&gpadc->complete);
/* Request interrupts */
ret = devm_request_threaded_irq(dev, gpadc->irq_sw, NULL,
ab8500_bm_gpadcconvend_handler, IRQF_NO_SUSPEND | IRQF_ONESHOT,
"ab8500-gpadc-sw", gpadc);
if (ret < 0) {
dev_err(dev,
"failed to request sw conversion irq %d\n",
gpadc->irq_sw);
return ret;
}
ret = devm_request_threaded_irq(dev, gpadc->irq_hw, NULL,
ab8500_bm_gpadcconvend_handler, IRQF_NO_SUSPEND | IRQF_ONESHOT,
"ab8500-gpadc-hw", gpadc);
if (ret < 0) {
dev_err(dev,
"Failed to request hw conversion irq: %d\n",
gpadc->irq_hw);
return ret;
}
/* The VTVout LDO used to power the AB8500 GPADC */
gpadc->vddadc = devm_regulator_get(dev, "vddadc");
if (IS_ERR(gpadc->vddadc)) {
ret = PTR_ERR(gpadc->vddadc);
dev_err(dev, "failed to get vddadc\n");
return ret;
}
ret = regulator_enable(gpadc->vddadc);
if (ret) {
dev_err(dev, "failed to enable vddadc: %d\n", ret);
return ret;
}
/* Enable runtime PM */
pm_runtime_get_noresume(dev);
pm_runtime_set_active(dev);
pm_runtime_enable(dev);
pm_runtime_set_autosuspend_delay(dev, AB8500_GPADC_AUTOSUSPEND_DELAY);
pm_runtime_use_autosuspend(dev);
ab8500_gpadc_read_calibration_data(gpadc);
pm_runtime_put(dev);
indio_dev->dev.parent = dev;
indio_dev->dev.of_node = np;
indio_dev->name = "ab8500-gpadc";
indio_dev->modes = INDIO_DIRECT_MODE;
indio_dev->info = &ab8500_gpadc_info;
indio_dev->channels = iio_chans;
indio_dev->num_channels = n_iio_chans;
ret = devm_iio_device_register(dev, indio_dev);
if (ret)
goto out_dis_pm;
return 0;
out_dis_pm:
pm_runtime_get_sync(dev);
pm_runtime_put_noidle(dev);
pm_runtime_disable(dev);
regulator_disable(gpadc->vddadc);
return ret;
}
static int ab8500_gpadc_remove(struct platform_device *pdev)
{
struct iio_dev *indio_dev = platform_get_drvdata(pdev);
struct ab8500_gpadc *gpadc = iio_priv(indio_dev);
pm_runtime_get_sync(gpadc->dev);
pm_runtime_put_noidle(gpadc->dev);
pm_runtime_disable(gpadc->dev);
regulator_disable(gpadc->vddadc);
return 0;
}
static const struct dev_pm_ops ab8500_gpadc_pm_ops = {
SET_SYSTEM_SLEEP_PM_OPS(pm_runtime_force_suspend,
pm_runtime_force_resume)
SET_RUNTIME_PM_OPS(ab8500_gpadc_runtime_suspend,
ab8500_gpadc_runtime_resume,
NULL)
};
static struct platform_driver ab8500_gpadc_driver = {
.probe = ab8500_gpadc_probe,
.remove = ab8500_gpadc_remove,
.driver = {
.name = "ab8500-gpadc",
.pm = &ab8500_gpadc_pm_ops,
},
};
builtin_platform_driver(ab8500_gpadc_driver);