kernel_samsung_a34x-permissive/drivers/battery/common/sec_adc.c

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/*
* sec_adc.c
* Samsung Mobile Battery Driver
*
* Copyright (C) 2012 Samsung Electronics
*
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 as
* published by the Free Software Foundation.
*/
#include <linux/version.h>
#include "sec_adc.h"
#define DEBUG
#if defined(CONFIG_SEC_KUNIT)
#include <kunit/mock.h>
#endif
struct adc_list {
const char *name;
struct iio_channel *channel;
bool is_used;
int prev_value;
};
static DEFINE_MUTEX(adclock);
static struct adc_list batt_adc_list[SEC_BAT_ADC_CHANNEL_NUM] = {
{.name = "adc-cable"},
{.name = "adc-bat-id"},
{.name = "adc-temp"},
{.name = "adc-temp-amb"},
{.name = "adc-full"},
{.name = "adc-volt"},
{.name = "adc-chg-temp"},
{.name = "adc-in-bat"},
{.name = "adc-dischg"},
{.name = "adc-dischg-ntc"},
{.name = "adc-wpc-temp"},
{.name = "adc-sub-chg-temp"},
{.name = "adc-usb-temp"},
{.name = "adc-sub-bat"},
{.name = "adc-blkt-temp"},
};
static int adc_init_count;
#if defined(CONFIG_SEC_KUNIT)
int __mockable adc_read_type(struct device *dev, int channel, int batt_adc_type)
#else
int adc_read_type(struct device *dev, int channel, int batt_adc_type)
#endif
{
int adc = -1;
int ret = 0;
int retry_cnt = RETRY_CNT;
/* adc init retry because adc init was failed when probe time */
if (!adc_init_count) {
int i = 0;
struct iio_channel *temp_adc;
pr_err("%s: ADC init retry!!\n", __func__);
for (i = 0; i < SEC_BAT_ADC_CHANNEL_NUM; i++) {
temp_adc = iio_channel_get(dev, batt_adc_list[i].name);
batt_adc_list[i].channel = temp_adc;
batt_adc_list[i].is_used = !IS_ERR_OR_NULL(temp_adc);
if (batt_adc_list[i].is_used)
adc_init_count++;
}
}
if (batt_adc_list[channel].is_used) {
do {
switch (batt_adc_type) {
case SEC_BATTERY_ADC_RAW:
ret = iio_read_channel_raw(batt_adc_list[channel].channel, &adc);
break;
default:
/* SEC_BATTERY_ADC_PROCESSED */
ret = iio_read_channel_processed(batt_adc_list[channel].channel, &adc);
break;
}
retry_cnt--;
} while ((retry_cnt > 0) && (adc < 0));
} else {
ret = 0;
}
if (retry_cnt <= 0) {
pr_err("%s: Error in ADC\n", __func__);
adc = batt_adc_list[channel].prev_value;
} else {
batt_adc_list[channel].prev_value = adc;
}
pr_debug("%s: [%d] ADC (type:%s) = %d\n", __func__, channel,
(batt_adc_type ? "raw" : "proc."), adc);
return adc;
}
int sec_bat_get_adc_data(struct device *dev, int adc_ch, int count, int batt_adc_type)
{
int adc_data = 0;
int adc_max = 0;
int adc_min = 0xFFFF;
int adc_total = 0;
int i = 0;
if (count < 3)
count = 3;
for (i = 0; i < count; i++) {
mutex_lock(&adclock);
adc_data = adc_read_type(dev, adc_ch, batt_adc_type);
mutex_unlock(&adclock);
if (i != 0) {
if (adc_data > adc_max)
adc_max = adc_data;
else if (adc_data < adc_min)
adc_min = adc_data;
} else {
adc_max = adc_data;
adc_min = adc_data;
}
adc_total += adc_data;
}
return (adc_total - adc_max - adc_min) / (count - 2);
}
EXPORT_SYMBOL(sec_bat_get_adc_data);
int sec_bat_get_charger_type_adc(struct sec_battery_info *battery)
{
/* It is true something valid is connected to the device for charging.
* By default this something is considered to be USB.
*/
int result = SEC_BATTERY_CABLE_USB;
int adc = 0;
int i = 0;
/* Do NOT check cable type when cable_switch_check() returns false
* and keep current cable type
*/
if (battery->pdata->cable_switch_check && !battery->pdata->cable_switch_check())
return battery->cable_type;
adc = sec_bat_get_adc_data(battery->dev, SEC_BAT_ADC_CHANNEL_CABLE_CHECK,
battery->pdata->adc_check_count, battery->pdata->adc_read_type);
/* Do NOT check cable type when cable_switch_normal() returns false
* and keep current cable type
*/
if (battery->pdata->cable_switch_normal && !battery->pdata->cable_switch_normal())
return battery->cable_type;
for (i = 0; i < SEC_BATTERY_CABLE_MAX; i++)
if ((adc > battery->pdata->cable_adc_value[i].min) && (adc < battery->pdata->cable_adc_value[i].max))
break;
if (i >= SEC_BATTERY_CABLE_MAX)
dev_err(battery->dev, "%s: default USB\n", __func__);
else
result = i;
dev_dbg(battery->dev, "%s: result(%d), adc(%d)\n", __func__, result, adc);
return result;
}
EXPORT_SYMBOL(sec_bat_get_charger_type_adc);
bool sec_bat_convert_adc_to_val(int adc, int offset, sec_bat_adc_table_data_t *adc_table, int size, int *value)
{
int temp = 0;
int low = 0;
int high = 0;
int mid = 0;
if (size <= 0)
return false;
adc = (offset) ? (offset - adc) : (adc);
if (adc_table[0].adc >= adc) {
temp = adc_table[0].data;
goto temp_by_adc_goto;
} else if (adc_table[size-1].adc <= adc) {
temp = adc_table[size-1].data;
goto temp_by_adc_goto;
}
high = size - 1;
while (low <= high) {
mid = (low + high) / 2;
if (adc_table[mid].adc > adc)
high = mid - 1;
else if (adc_table[mid].adc < adc)
low = mid + 1;
else {
temp = adc_table[mid].data;
goto temp_by_adc_goto;
}
}
temp = adc_table[high].data;
temp += ((adc_table[low].data - adc_table[high].data) *
(adc - adc_table[high].adc)) /
(adc_table[low].adc - adc_table[high].adc);
temp_by_adc_goto:
*value = temp;
pr_debug("%s: Temp(%d), Temp-ADC(%d)\n", __func__, temp, adc);
return true;
}
EXPORT_SYMBOL(sec_bat_convert_adc_to_val);
int sec_bat_get_inbat_vol_by_adc(struct sec_battery_info *battery)
{
int inbat = 0;
int inbat_adc;
int low = 0;
int high = 0;
int mid = 0;
const sec_bat_adc_table_data_t *inbat_adc_table;
unsigned int inbat_adc_table_size;
if (!battery->pdata->inbat_adc_table) {
dev_err(battery->dev, "%s: not designed to read in-bat voltage\n", __func__);
return -1;
}
inbat_adc_table = battery->pdata->inbat_adc_table;
inbat_adc_table_size = battery->pdata->inbat_adc_table_size;
inbat_adc = sec_bat_get_adc_data(battery->dev, SEC_BAT_ADC_CHANNEL_INBAT_VOLTAGE,
battery->pdata->adc_check_count, battery->pdata->adc_read_type);
if (inbat_adc <= 0)
return inbat_adc;
battery->inbat_adc = inbat_adc;
if (inbat_adc_table[0].adc <= inbat_adc) {
inbat = inbat_adc_table[0].data;
goto inbat_by_adc_goto;
} else if (inbat_adc_table[inbat_adc_table_size-1].adc >= inbat_adc) {
inbat = inbat_adc_table[inbat_adc_table_size-1].data;
goto inbat_by_adc_goto;
}
high = inbat_adc_table_size - 1;
while (low <= high) {
mid = (low + high) / 2;
if (inbat_adc_table[mid].adc < inbat_adc)
high = mid - 1;
else if (inbat_adc_table[mid].adc > inbat_adc)
low = mid + 1;
else {
inbat = inbat_adc_table[mid].data;
goto inbat_by_adc_goto;
}
}
inbat = inbat_adc_table[high].data;
inbat +=
((inbat_adc_table[low].data - inbat_adc_table[high].data) *
(inbat_adc - inbat_adc_table[high].adc)) /
(inbat_adc_table[low].adc - inbat_adc_table[high].adc);
if (inbat < 0)
inbat = 0;
inbat_by_adc_goto:
dev_info(battery->dev, "%s: inbat(%d), inbat-ADC(%d)\n", __func__, inbat, inbat_adc);
return inbat;
}
EXPORT_SYMBOL(sec_bat_get_inbat_vol_by_adc);
bool sec_bat_check_vf_adc(struct sec_battery_info *battery)
{
int adc = 0;
adc = sec_bat_get_adc_data(battery->dev,
SEC_BAT_ADC_CHANNEL_BATID_CHECK,
battery->pdata->adc_check_count,
battery->pdata->adc_read_type);
if (adc < 0) {
dev_err(battery->dev, "%s: VF ADC error\n", __func__);
adc = battery->check_adc_value;
} else
battery->check_adc_value = adc;
if ((battery->check_adc_value <= battery->pdata->check_adc_max) &&
(battery->check_adc_value >= battery->pdata->check_adc_min)) {
return true;
} else {
dev_info(battery->dev, "%s: VF_ADC(%d) is out of range(min:%d, max:%d)\n",
__func__, battery->check_adc_value, battery->pdata->check_adc_min, battery->pdata->check_adc_max);
return false;
}
}
EXPORT_SYMBOL(sec_bat_check_vf_adc);
#if IS_ENABLED(CONFIG_DIRECT_CHARGING)
int sec_bat_get_direct_chg_temp_adc(
struct sec_battery_info *battery, int adc_data, int count, int check_type)
{
int temp = 0;
int temp_adc;
int low = 0;
int high = 0;
int mid = 0;
const sec_bat_adc_table_data_t *temp_adc_table = {0 , };
unsigned int temp_adc_table_size = 0;
int offset = battery->pdata->dchg_thm_info.offset;
if (check_type == SEC_BATTERY_TEMP_CHECK_FAKE)
return FAKE_TEMP;
temp_adc = (offset) ? (offset - adc_data) : (adc_data);
if (temp_adc < 0)
return 0;
temp_adc_table = battery->pdata->dchg_thm_info.adc_table;
temp_adc_table_size = battery->pdata->dchg_thm_info.adc_table_size;
battery->pdata->dchg_thm_info.adc = temp_adc;
if (temp_adc_table[0].adc >= temp_adc) {
temp = temp_adc_table[0].data;
goto direct_chg_temp_goto;
} else if (temp_adc_table[temp_adc_table_size - 1].adc <= temp_adc) {
temp = temp_adc_table[temp_adc_table_size - 1].data;
goto direct_chg_temp_goto;
}
high = temp_adc_table_size - 1;
while (low <= high) {
mid = (low + high) / 2;
if (temp_adc_table[mid].adc > temp_adc)
high = mid - 1;
else if (temp_adc_table[mid].adc < temp_adc)
low = mid + 1;
else {
temp = temp_adc_table[mid].data;
goto direct_chg_temp_goto;
}
}
temp = temp_adc_table[high].data;
temp += ((temp_adc_table[low].data - temp_adc_table[high].data) *
(temp_adc - temp_adc_table[high].adc)) /
(temp_adc_table[low].adc - temp_adc_table[high].adc);
direct_chg_temp_goto:
dev_info(battery->dev, "%s: temp(%d), direct-chg-temp-ADC(%d)\n", __func__, temp, adc_data);
return temp;
}
EXPORT_SYMBOL(sec_bat_get_direct_chg_temp_adc);
#endif
void adc_init(struct platform_device *pdev, struct sec_battery_info *battery)
{
int i = 0;
struct iio_channel *temp_adc;
for (i = 0; i < SEC_BAT_ADC_CHANNEL_NUM; i++) {
temp_adc = iio_channel_get(&pdev->dev, batt_adc_list[i].name);
batt_adc_list[i].channel = temp_adc;
batt_adc_list[i].is_used = !IS_ERR_OR_NULL(temp_adc);
if (batt_adc_list[i].is_used)
battery->adc_init_count++;
}
for (i = 0; i < SEC_BAT_ADC_CHANNEL_NUM; i++)
pr_info("%s: %s - %s\n", __func__,
batt_adc_list[i].name, batt_adc_list[i].is_used ? "used" : "not used");
}
EXPORT_SYMBOL(adc_init);
void adc_exit(struct sec_battery_info *battery)
{
int i = 0;
for (i = 0; i < SEC_BAT_ADC_CHANNEL_NUM; i++) {
if (batt_adc_list[i].is_used)
iio_channel_release(batt_adc_list[i].channel);
}
}
EXPORT_SYMBOL(adc_exit);