kernel_samsung_a34x-permissive/drivers/power/supply/mtk_pulse_charger.c
2024-04-28 15:49:01 +02:00

555 lines
14 KiB
C
Executable file

// SPDX-License-Identifier: GPL-2.0
/*
* Copyright (c) 2019 MediaTek Inc.
*/
/*
*
* Filename:
* ---------
* mtk_pulse_charger.c
*
* Project:
* --------
* Android_Software
*
* Description:
* ------------
* This Module defines functions of Battery charging
*
* Author:
* -------
* Wy Chuang
*
*/
#include <linux/init.h> /* For init/exit macros */
#include <linux/module.h> /* For MODULE_ marcros */
#include <linux/fs.h>
#include <linux/device.h>
#include <linux/interrupt.h>
#include <linux/spinlock.h>
#include <linux/platform_device.h>
#include <linux/device.h>
#include <linux/kdev_t.h>
#include <linux/fs.h>
#include <linux/cdev.h>
#include <linux/delay.h>
#include <linux/kernel.h>
#include <linux/init.h>
#include <linux/types.h>
#include <linux/wait.h>
#include <linux/slab.h>
#include <linux/fs.h>
#include <linux/sched.h>
#include <linux/poll.h>
#include <linux/power_supply.h>
#include <linux/pm_wakeup.h>
#include <linux/time.h>
#include <linux/mutex.h>
#include <linux/kthread.h>
#include <linux/proc_fs.h>
#include <linux/platform_device.h>
#include <linux/seq_file.h>
#include <linux/scatterlist.h>
#include <linux/suspend.h>
#include <linux/of.h>
#include <linux/of_irq.h>
#include <linux/of_address.h>
#include <linux/reboot.h>
#include "mtk_charger.h"
#define MAX_TOPOFF_CHARGING_TIME (3 * 60 * 60) /* 3 hours */
#define RECHARGE_OFFSET 150000 /* uV */
#define TOPOFF_VOLTAGE 4200000 /* uV */
#define CHG_FULL_CURRENT 150000 /* uA */
struct pcharger_data {
int state;
bool disable_charging;
unsigned int total_charging_time;
unsigned int cc_charging_time;
unsigned int topoff_charging_time;
unsigned int full_charging_time;
struct timespec topoff_begin_time;
struct timespec charging_begin_time;
int recharge_offset; /* uv */
int topoff_voltage; /* uv */
int chg_full_current; /* uA */
};
enum pcharger_state_enum {
CHR_CC,
CHR_TOPOFF,
CHR_BATFULL,
CHR_ERROR
};
static int _uA_to_mA(int uA)
{
if (uA == -1)
return -1;
else
return uA / 1000;
}
static void pchr_select_cv(struct mtk_charger *info)
{
u32 constant_voltage;
if (info->enable_sw_jeita)
if (info->sw_jeita.cv != 0) {
info->setting.cv = info->sw_jeita.cv;
return;
}
constant_voltage = info->data.battery_cv;
info->setting.cv = constant_voltage;
charger_dev_set_constant_voltage(info->chg1_dev,
info->setting.cv);
}
static bool pchr_select_charging_current_limit(struct mtk_charger *info,
struct chg_limit_setting *setting)
{
struct charger_data *pdata;
bool is_basic = false;
u32 ichg1_min = 0, aicr1_min = 0;
int ret;
pchr_select_cv(info);
pdata = &info->chg_data[CHG1_SETTING];
if (info->usb_unlimited) {
pdata->input_current_limit =
info->data.ac_charger_input_current;
pdata->charging_current_limit =
info->data.ac_charger_current;
is_basic = true;
goto done;
}
if ((info->bootmode == 1) ||
(info->bootmode == 5)) {
pdata->input_current_limit = 200000; /* 200mA */
is_basic = true;
goto done;
}
if (info->atm_enabled == true
&& (info->chr_type == POWER_SUPPLY_TYPE_USB ||
info->chr_type == POWER_SUPPLY_TYPE_USB_CDP)
) {
pdata->input_current_limit = 100000; /* 100mA */
is_basic = true;
goto done;
}
if (info->chr_type == POWER_SUPPLY_TYPE_USB) {
pdata->input_current_limit =
info->data.usb_charger_current;
/* it can be larger */
pdata->charging_current_limit =
info->data.usb_charger_current;
is_basic = true;
} else if (info->chr_type == POWER_SUPPLY_TYPE_USB_DCP) {
pdata->input_current_limit =
info->data.ac_charger_input_current;
pdata->charging_current_limit =
info->data.ac_charger_current;
} else if (info->chr_type == POWER_SUPPLY_TYPE_USB_CDP) {
pdata->input_current_limit =
info->data.charging_host_charger_current;
pdata->charging_current_limit =
info->data.charging_host_charger_current;
is_basic = true;
}
if (info->enable_sw_jeita) {
if (IS_ENABLED(CONFIG_USBIF_COMPLIANCE)
&& info->chr_type == POWER_SUPPLY_TYPE_USB)
chr_debug("USBIF & STAND_HOST skip current check\n");
else {
if (info->sw_jeita.sm == TEMP_T0_TO_T1) {
pdata->input_current_limit = 500000;
pdata->charging_current_limit = 350000;
}
}
}
if (pdata->thermal_charging_current_limit != -1) {
if (pdata->thermal_charging_current_limit <
pdata->charging_current_limit) {
pdata->charging_current_limit =
pdata->thermal_charging_current_limit;
info->setting.charging_current_limit1 =
pdata->thermal_charging_current_limit;
}
} else
info->setting.charging_current_limit1 = -1;
if (pdata->thermal_input_current_limit != -1) {
if (pdata->thermal_input_current_limit <
pdata->input_current_limit) {
pdata->input_current_limit =
pdata->thermal_input_current_limit;
info->setting.input_current_limit1 =
pdata->thermal_input_current_limit;
}
} else
info->setting.input_current_limit1 = -1;
if (info->pd_type == MTK_PD_CONNECT_PE_READY_SNK ||
info->pd_type == MTK_PD_CONNECT_PE_READY_SNK_PD30 ||
info->pd_type == MTK_PD_CONNECT_PE_READY_SNK_APDO)
is_basic = false;
done:
ret = charger_dev_get_min_charging_current(info->chg1_dev, &ichg1_min);
if (ret != -ENOTSUPP && pdata->charging_current_limit < ichg1_min)
pdata->charging_current_limit = 0;
ret = charger_dev_get_min_input_current(info->chg1_dev, &aicr1_min);
if (ret != -ENOTSUPP && pdata->input_current_limit < aicr1_min)
pdata->input_current_limit = 0;
chr_err("thermal:%d %d setting:%d %d type:%d:%d usb_unlimited:%d usbif:%d usbsm:%d aicl:%d atm:%d bm:%d b:%d\n",
_uA_to_mA(pdata->thermal_input_current_limit),
_uA_to_mA(pdata->thermal_charging_current_limit),
_uA_to_mA(pdata->input_current_limit),
_uA_to_mA(pdata->charging_current_limit),
info->chr_type, info->pd_type,
info->usb_unlimited,
IS_ENABLED(CONFIG_USBIF_COMPLIANCE), info->usb_state,
pdata->input_current_limit_by_aicl, info->atm_enabled,
info->bootmode, is_basic);
return is_basic;
}
static void linear_chg_turn_on_charging(struct mtk_charger *info)
{
struct pcharger_data *algo_data = info->algo.algo_data;
bool charging_enable = true;
struct charger_data *pdata;
pdata = &info->chg_data[CHG1_SETTING];
if (algo_data->state == CHR_ERROR) {
charging_enable = false;
chr_err("[charger]Charger Error, turn OFF charging !\n");
#ifdef SUPPORT_BOOTMODE
} else if ((get_boot_mode() == META_BOOT) ||
((get_boot_mode() == ADVMETA_BOOT))) {
charging_enable = false;
chr_err("[charger]In meta or advanced meta mode, disable charging\n");
#endif
} else {
pchr_select_charging_current_limit(info, &info->setting);
if (info->chg_data[CHG1_SETTING].charging_current_limit == 0) {
charging_enable = false;
chr_err("[charger]charging current is set 0mA, turn off charging\n");
}
charger_dev_set_input_current(info->chg1_dev,
pdata->input_current_limit);
charger_dev_set_charging_current(info->chg1_dev,
pdata->charging_current_limit);
charger_dev_set_constant_voltage(info->chg1_dev,
info->setting.cv);
}
charger_dev_enable(info->chg1_dev, charging_enable);
}
static int mtk_linear_chr_cc(struct mtk_charger *info)
{
struct timespec time_now, charging_time;
u32 vbat;
struct pcharger_data *algo_data;
algo_data = info->algo.algo_data;
pr_notice("%s time:%d %d %d %d\n", __func__,
algo_data->total_charging_time,
algo_data->cc_charging_time,
algo_data->topoff_charging_time,
algo_data->full_charging_time);
get_monotonic_boottime(&time_now);
charging_time = timespec_sub(time_now, algo_data->charging_begin_time);
algo_data->cc_charging_time = charging_time.tv_sec;
algo_data->topoff_charging_time = 0;
algo_data->total_charging_time = charging_time.tv_sec;
/* discharge for 1 second and charge for 9 seconds */
charger_dev_enable(info->chg1_dev, false);
msleep(1000);
vbat = get_battery_voltage(info) * 1000; /* uV */
if (vbat > algo_data->topoff_voltage) {
algo_data->state = CHR_TOPOFF;
get_monotonic_boottime(&algo_data->topoff_begin_time);
pr_notice("%s: enter TOPOFF mode on vbat = %d uV\n",
__func__, vbat);
}
linear_chg_turn_on_charging(info);
return 0;
}
static bool charging_full_check(struct mtk_charger *info)
{
struct pcharger_data *algo_data = info->algo.algo_data;
static u32 full_check_count;
bool chg_full_status = false;
int chg_current = get_battery_current(info) * 1000; /* uA */
if (chg_current > algo_data->chg_full_current)
full_check_count = 0;
else {
full_check_count++;
if (full_check_count >= 6) {
full_check_count = 0;
chg_full_status = true;
}
}
return chg_full_status;
}
static int mtk_linear_chr_topoff(struct mtk_charger *info)
{
struct pcharger_data *algo_data = info->algo.algo_data;
struct timespec time_now, charging_time, topoff_time;
pr_notice("%s time:%d %d %d %d\n", __func__,
algo_data->total_charging_time,
algo_data->cc_charging_time,
algo_data->topoff_charging_time,
algo_data->full_charging_time);
get_monotonic_boottime(&time_now);
charging_time = timespec_sub(time_now, algo_data->charging_begin_time);
topoff_time = timespec_sub(time_now, algo_data->topoff_begin_time);
algo_data->cc_charging_time = 0;
algo_data->topoff_charging_time = topoff_time.tv_sec;
algo_data->total_charging_time = charging_time.tv_sec;
linear_chg_turn_on_charging(info);
if (algo_data->topoff_charging_time >= MAX_TOPOFF_CHARGING_TIME
|| charging_full_check(info) == true) {
algo_data->state = CHR_BATFULL;
/* Disable charging */
charger_dev_enable(info->chg1_dev, false);
pr_notice("%s: disable charging\n", __func__);
}
return 0;
}
static int mtk_linear_chr_full(struct mtk_charger *info)
{
struct pcharger_data *algo_data = info->algo.algo_data;
u32 vbat;
bool is_recharging = false;
algo_data->total_charging_time = 0;
algo_data->cc_charging_time = 0;
algo_data->topoff_charging_time = 0;
pr_notice("%s time:%d %d %d %d\n", __func__,
algo_data->total_charging_time,
algo_data->cc_charging_time,
algo_data->topoff_charging_time,
algo_data->full_charging_time);
/*
* If CV is set to lower value by JEITA,
* Reset CV to normal value if temperture is in normal zone
*/
pchr_select_cv(info);
info->polling_interval = CHARGING_FULL_INTERVAL;
vbat = get_battery_voltage(info) * 1000; /* uV */
if (info->enable_sw_jeita && info->sw_jeita.cv != 0) {
if (vbat < (info->sw_jeita.cv - algo_data->recharge_offset))
is_recharging = true;
} else {
if (vbat < (info->data.battery_cv - algo_data->recharge_offset))
is_recharging = true;
}
if (is_recharging) {
algo_data->state = CHR_CC;
get_monotonic_boottime(&algo_data->charging_begin_time);
pr_notice("battery recharging on vbat = %d uV\n", vbat);
info->polling_interval = CHARGING_INTERVAL;
}
return 0;
}
static void pchr_disable_all_charging(struct mtk_charger *info)
{
charger_dev_enable(info->chg1_dev, false);
}
static int mtk_linear_chr_err(struct mtk_charger *info)
{
struct pcharger_data *algo_data = info->algo.algo_data;
pr_notice("%s time:%d %d %d %d\n", __func__,
algo_data->total_charging_time,
algo_data->cc_charging_time,
algo_data->topoff_charging_time,
algo_data->full_charging_time);
if (info->enable_sw_jeita) {
if ((info->sw_jeita.sm == TEMP_BELOW_T0) ||
(info->sw_jeita.sm == TEMP_ABOVE_T4))
info->sw_jeita.error_recovery_flag = false;
if ((info->sw_jeita.error_recovery_flag == false) &&
(info->sw_jeita.sm != TEMP_BELOW_T0) &&
(info->sw_jeita.sm != TEMP_ABOVE_T4)) {
info->sw_jeita.error_recovery_flag = true;
algo_data->state = CHR_CC;
get_monotonic_boottime(&algo_data->charging_begin_time);
}
}
algo_data->total_charging_time = 0;
algo_data->cc_charging_time = 0;
algo_data->topoff_charging_time = 0;
pchr_disable_all_charging(info);
return 0;
}
static int pchr_do_algorithm(struct mtk_charger *info)
{
struct charger_data *pdata;
bool is_basic = true;
int ret;
struct pcharger_data *algo_data = info->algo.algo_data;
charger_dev_kick_wdt(info->chg1_dev);
pdata = &info->chg_data[CHG1_SETTING];
chr_err("%s: %d\n", __func__, algo_data->state);
switch (algo_data->state) {
case CHR_CC:
ret = mtk_linear_chr_cc(info);
break;
case CHR_TOPOFF:
ret = mtk_linear_chr_topoff(info);
break;
case CHR_BATFULL:
ret = mtk_linear_chr_full(info);
break;
case CHR_ERROR:
ret = mtk_linear_chr_err(info);
break;
}
if (is_basic == true) {
charger_dev_set_input_current(info->chg1_dev,
pdata->input_current_limit);
charger_dev_set_charging_current(info->chg1_dev,
pdata->charging_current_limit);
charger_dev_set_constant_voltage(info->chg1_dev,
info->setting.cv);
}
charger_dev_dump_registers(info->chg1_dev);
return 0;
}
static void mtk_pulse_charger_parse_dt(struct mtk_charger *info,
struct device *dev)
{
struct device_node *np = dev->of_node;
u32 val = 0;
struct pcharger_data *algo_data;
algo_data = info->algo.algo_data;
if (of_property_read_u32(np, "recharge_offset", &val) >= 0) {
algo_data->recharge_offset = val;
} else {
chr_err("use default RECHARGE_OFFSET: %d\n", RECHARGE_OFFSET);
algo_data->recharge_offset = RECHARGE_OFFSET;
}
if (of_property_read_u32(np, "topoff_voltage", &val) >= 0) {
algo_data->topoff_voltage = val;
} else {
chr_err("use default TOPOFF_VOLTAGE: %d\n", TOPOFF_VOLTAGE);
algo_data->topoff_voltage = TOPOFF_VOLTAGE;
}
if (of_property_read_u32(np, "chg_full_current", &val) >= 0) {
algo_data->chg_full_current = val;
} else {
chr_err("use default CHG_FULL_CURRENT: %d\n", CHG_FULL_CURRENT);
algo_data->chg_full_current = CHG_FULL_CURRENT;
}
}
static int mtk_linear_charging_do_charging(struct mtk_charger *info,
bool en)
{
struct pcharger_data *algo_data = info->algo.algo_data;
pr_info("%s en:%d %s\n", __func__, en, info->algorithm_name);
if (en) {
algo_data->disable_charging = false;
algo_data->state = CHR_CC;
get_monotonic_boottime(&algo_data->charging_begin_time);
} else {
algo_data->disable_charging = true;
algo_data->state = CHR_ERROR;
pchr_disable_all_charging(info);
}
return 0;
}
int mtk_pulse_charger_init(struct mtk_charger *info)
{
static struct pcharger_data pdata;
pr_notice("%s\n", __func__);
info->algo.do_algorithm = pchr_do_algorithm;
info->algo.enable_charging = mtk_linear_charging_do_charging;
//info->algo.do_event = charger_dev_event;
info->algo.algo_data = &pdata;
mtk_pulse_charger_parse_dt(info, &info->pdev->dev);
pr_notice("%s end\n", __func__);
return 0;
}