/* Copyright (c) 2014-2015, The Linux Foundation. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 and * only version 2 as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ #define pr_fmt(fmt) "BMS: %s: " fmt, __func__ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define _BMS_MASK(BITS, POS) \ ((unsigned char)(((1 << (BITS)) - 1) << (POS))) #define BMS_MASK(LEFT_BIT_POS, RIGHT_BIT_POS) \ _BMS_MASK((LEFT_BIT_POS) - (RIGHT_BIT_POS) + 1, \ (RIGHT_BIT_POS)) /* Config / Data registers */ #define REVISION1_REG 0x0 #define STATUS1_REG 0x8 #define FSM_STATE_MASK BMS_MASK(5, 3) #define FSM_STATE_SHIFT 3 #define STATUS2_REG 0x9 #define FIFO_CNT_SD_MASK BMS_MASK(7, 4) #define FIFO_CNT_SD_SHIFT 4 #define MODE_CTL_REG 0x40 #define FORCE_S3_MODE BIT(0) #define ENABLE_S3_MODE BIT(1) #define FORCE_S2_MODE BIT(2) #define ENABLE_S2_MODE BIT(3) #define S2_MODE_MASK BMS_MASK(3, 2) #define S3_MODE_MASK BMS_MASK(1, 0) #define DATA_CTL1_REG 0x42 #define MASTER_HOLD_BIT BIT(0) #define DATA_CTL2_REG 0x43 #define FIFO_CNT_SD_CLR_BIT BIT(2) #define ACC_DATA_SD_CLR_BIT BIT(1) #define ACC_CNT_SD_CLR_BIT BIT(0) #define S3_OCV_TOL_CTL_REG 0x44 #define EN_CTL_REG 0x46 #define BMS_EN_BIT BIT(7) #define FIFO_LENGTH_REG 0x47 #define S1_FIFO_LENGTH_MASK BMS_MASK(3, 0) #define S2_FIFO_LENGTH_MASK BMS_MASK(7, 4) #define S2_FIFO_LENGTH_SHIFT 4 #define S1_SAMPLE_INTVL_REG 0x55 #define S2_SAMPLE_INTVL_REG 0x56 #define S3_SAMPLE_INTVL_REG 0x57 #define S1_ACC_CNT_REG 0x5E #define S2_ACC_CNT_REG 0x5F #define ACC_CNT_MASK BMS_MASK(2, 0) #define ACC_DATA0_SD_REG 0x63 #define ACC_CNT_SD_REG 0x67 #define OCV_DATA0_REG 0x6A #define FIFO_0_LSB_REG 0xC0 #define BMS_SOC_REG 0xB0 #define BMS_OCV_REG 0xB1 /* B1 & B2 */ #define SOC_STORAGE_MASK 0xFE #define CHARGE_INCREASE_STORAGE 0xB3 #define CHARGE_CYCLE_STORAGE_LSB 0xB4 /* B4 & B5 */ #define SEC_ACCESS 0xD0 #define QPNP_CHARGER_PRESENT BIT(7) /* Constants */ #define OCV_TOL_LSB_UV 300 #define MAX_OCV_TOL_THRESHOLD (OCV_TOL_LSB_UV * 0xFF) #define MAX_SAMPLE_COUNT 256 #define MAX_SAMPLE_INTERVAL 2550 #define BMS_READ_TIMEOUT 500 #define BMS_DEFAULT_TEMP 250 #define OCV_INVALID 0xFFFF #define SOC_INVALID 0xFF #define OCV_UNINITIALIZED 0xFFFF #define VBATT_ERROR_MARGIN 20000 #define CV_DROP_MARGIN 10000 #define MIN_OCV_UV 2000000 #define TIME_PER_PERCENT_UUC 60 #define IAVG_SAMPLES 16 #define MIN_SOC_UUC 3 #define QPNP_VM_BMS_DEV_NAME "qcom,qpnp-vm-bms" /* indicates the state of BMS */ enum { IDLE_STATE, S1_STATE, S2_STATE, S3_STATE, S7_STATE, }; enum { WRKARND_PON_OCV_COMP = BIT(0), }; struct bms_irq { int irq; unsigned long disabled; }; struct bms_wakeup_source { struct wakeup_source source; unsigned long disabled; }; struct temp_curr_comp_map { int temp_decideg; int current_ma; }; struct bms_dt_cfg { bool cfg_report_charger_eoc; bool cfg_force_bms_active_on_charger; bool cfg_force_s3_on_suspend; bool cfg_ignore_shutdown_soc; bool cfg_use_voltage_soc; int cfg_v_cutoff_uv; int cfg_max_voltage_uv; int cfg_r_conn_mohm; int cfg_shutdown_soc_valid_limit; int cfg_low_soc_calc_threshold; int cfg_low_soc_calculate_soc_ms; int cfg_low_voltage_threshold; int cfg_low_voltage_calculate_soc_ms; int cfg_low_soc_fifo_length; int cfg_calculate_soc_ms; int cfg_voltage_soc_timeout_ms; int cfg_s1_sample_interval_ms; int cfg_s2_sample_interval_ms; int cfg_s1_sample_count; int cfg_s2_sample_count; int cfg_s1_fifo_length; int cfg_s2_fifo_length; int cfg_disable_bms; int cfg_s3_ocv_tol_uv; int cfg_soc_resume_limit; int cfg_low_temp_threshold; int cfg_ibat_avg_samples; int cfg_battery_aging_comp; bool cfg_use_reported_soc; }; struct qpnp_bms_chip { struct device *dev; struct spmi_device *spmi; dev_t dev_no; u16 base; u8 revision[2]; u32 batt_pres_addr; u32 chg_pres_addr; /* status variables */ u8 current_fsm_state; bool last_soc_invalid; bool warm_reset; bool bms_psy_registered; bool battery_full; bool bms_dev_open; bool data_ready; bool apply_suspend_config; bool in_cv_state; bool low_soc_fifo_set; int battery_status; int calculated_soc; int current_now; int prev_current_now; int prev_voltage_based_soc; int calculate_soc_ms; int voltage_soc_uv; int battery_present; int last_soc; int last_soc_unbound; int last_soc_change_sec; int charge_start_tm_sec; int catch_up_time_sec; int delta_time_s; int uuc_delta_time_s; int ocv_at_100; int last_ocv_uv; int s2_fifo_length; int last_acc; int hi_power_state; unsigned int vadc_v0625; unsigned int vadc_v1250; unsigned long tm_sec; unsigned long workaround_flag; unsigned long uuc_tm_sec; u32 seq_num; u8 shutdown_soc; bool shutdown_soc_invalid; u16 last_ocv_raw; u32 shutdown_ocv; bool suspend_data_valid; int iavg_num_samples; unsigned int iavg_index; int iavg_samples_ma[IAVG_SAMPLES]; int iavg_ma; int prev_soc_uuc; int eoc_reported; u8 charge_increase; u16 charge_cycles; unsigned int start_soc; unsigned int end_soc; struct bms_battery_data *batt_data; struct bms_dt_cfg dt; struct dentry *debug_root; struct bms_wakeup_source vbms_lv_wake_source; struct bms_wakeup_source vbms_cv_wake_source; struct bms_wakeup_source vbms_soc_wake_source; wait_queue_head_t bms_wait_q; struct delayed_work monitor_soc_work; struct delayed_work voltage_soc_timeout_work; struct mutex bms_data_mutex; struct mutex bms_device_mutex; struct mutex last_soc_mutex; struct mutex state_change_mutex; struct class *bms_class; struct device *bms_device; struct cdev bms_cdev; struct qpnp_vm_bms_data bms_data; struct qpnp_vadc_chip *vadc_dev; struct qpnp_adc_tm_chip *adc_tm_dev; struct pmic_revid_data *revid_data; struct qpnp_adc_tm_btm_param vbat_monitor_params; struct bms_irq fifo_update_done_irq; struct bms_irq fsm_state_change_irq; struct power_supply bms_psy; struct power_supply *batt_psy; struct power_supply *usb_psy; bool reported_soc_in_use; bool charger_removed_since_full; bool charger_reinserted; bool reported_soc_high_current; int reported_soc; int reported_soc_change_sec; int reported_soc_delta; }; static struct qpnp_bms_chip *the_chip; static struct temp_curr_comp_map temp_curr_comp_lut[] = { {-300, 15}, {250, 17}, {850, 28}, }; static void disable_bms_irq(struct bms_irq *irq) { if (!__test_and_set_bit(0, &irq->disabled)) { disable_irq(irq->irq); pr_debug("disabled irq %d\n", irq->irq); } } static void enable_bms_irq(struct bms_irq *irq) { if (__test_and_clear_bit(0, &irq->disabled)) { enable_irq(irq->irq); pr_debug("enable irq %d\n", irq->irq); } } static void bms_stay_awake(struct bms_wakeup_source *source) { if (__test_and_clear_bit(0, &source->disabled)) { __pm_stay_awake(&source->source); pr_debug("enabled source %s\n", source->source.name); } } static void bms_relax(struct bms_wakeup_source *source) { if (!__test_and_set_bit(0, &source->disabled)) { __pm_relax(&source->source); pr_debug("disabled source %s\n", source->source.name); } } static bool bms_wake_active(struct bms_wakeup_source *source) { return !source->disabled; } static int bound_soc(int soc) { soc = max(0, soc); soc = min(100, soc); return soc; } static char *qpnp_vm_bms_supplicants[] = { "battery", }; static int qpnp_read_wrapper(struct qpnp_bms_chip *chip, u8 *val, u16 base, int count) { int rc; struct spmi_device *spmi = chip->spmi; rc = spmi_ext_register_readl(spmi->ctrl, spmi->sid, base, val, count); if (rc) pr_err("SPMI read failed rc=%d\n", rc); return rc; } static int qpnp_write_wrapper(struct qpnp_bms_chip *chip, u8 *val, u16 base, int count) { int rc; struct spmi_device *spmi = chip->spmi; rc = spmi_ext_register_writel(spmi->ctrl, spmi->sid, base, val, count); if (rc) pr_err("SPMI write failed rc=%d\n", rc); return rc; } static int qpnp_masked_write_base(struct qpnp_bms_chip *chip, u16 addr, u8 mask, u8 val) { int rc; u8 reg; rc = qpnp_read_wrapper(chip, ®, addr, 1); if (rc) { pr_err("read failed addr = %03X, rc = %d\n", addr, rc); return rc; } reg &= ~mask; reg |= val & mask; rc = qpnp_write_wrapper(chip, ®, addr, 1); if (rc) pr_err("write failed addr = %03X, val = %02x, mask = %02x, reg = %02x, rc = %d\n", addr, val, mask, reg, rc); return rc; } static int qpnp_secure_write_wrapper(struct qpnp_bms_chip *chip, u8 *val, u16 base) { int rc; u8 reg; reg = 0xA5; rc = qpnp_write_wrapper(chip, ®, chip->base + SEC_ACCESS, 1); if (rc) { pr_err("Error %d writing 0xA5 to 0x%x reg\n", rc, SEC_ACCESS); return rc; } rc = qpnp_write_wrapper(chip, val, base, 1); if (rc) pr_err("Error %d writing %d to 0x%x reg\n", rc, *val, base); return rc; } static int backup_ocv_soc(struct qpnp_bms_chip *chip, int ocv_uv, int soc) { int rc; u16 ocv_mv = ocv_uv / 1000; rc = qpnp_write_wrapper(chip, (u8 *)&ocv_mv, chip->base + BMS_OCV_REG, 2); if (rc) pr_err("Unable to backup OCV rc=%d\n", rc); rc = qpnp_masked_write_base(chip, chip->base + BMS_SOC_REG, SOC_STORAGE_MASK, (soc + 1) << 1); if (rc) pr_err("Unable to backup SOC rc=%d\n", rc); pr_debug("ocv_mv=%d soc=%d\n", ocv_mv, soc); return rc; } static int get_current_time(unsigned long *now_tm_sec) { struct rtc_time tm; struct rtc_device *rtc; int rc; rtc = rtc_class_open(CONFIG_RTC_HCTOSYS_DEVICE); if (rtc == NULL) { pr_err("%s: unable to open rtc device (%s)\n", __FILE__, CONFIG_RTC_HCTOSYS_DEVICE); return -EINVAL; } rc = rtc_read_time(rtc, &tm); if (rc) { pr_err("Error reading rtc device (%s) : %d\n", CONFIG_RTC_HCTOSYS_DEVICE, rc); goto close_time; } rc = rtc_valid_tm(&tm); if (rc) { pr_err("Invalid RTC time (%s): %d\n", CONFIG_RTC_HCTOSYS_DEVICE, rc); goto close_time; } rtc_tm_to_time(&tm, now_tm_sec); close_time: rtc_class_close(rtc); return rc; } static int calculate_delta_time(unsigned long *time_stamp, int *delta_time_s) { unsigned long now_tm_sec = 0; /* default to delta time = 0 if anything fails */ *delta_time_s = 0; if (get_current_time(&now_tm_sec)) { pr_err("RTC read failed\n"); return 0; } *delta_time_s = (now_tm_sec - *time_stamp); /* remember this time */ *time_stamp = now_tm_sec; return 0; } static bool is_charger_present(struct qpnp_bms_chip *chip) { union power_supply_propval ret = {0,}; if (chip->usb_psy == NULL) chip->usb_psy = power_supply_get_by_name("usb"); if (chip->usb_psy) { chip->usb_psy->get_property(chip->usb_psy, POWER_SUPPLY_PROP_PRESENT, &ret); return ret.intval; } return false; } static bool is_battery_charging(struct qpnp_bms_chip *chip) { union power_supply_propval ret = {0,}; if (chip->batt_psy == NULL) chip->batt_psy = power_supply_get_by_name("battery"); if (chip->batt_psy) { /* if battery has been registered, use the type property */ chip->batt_psy->get_property(chip->batt_psy, POWER_SUPPLY_PROP_CHARGE_TYPE, &ret); return ret.intval != POWER_SUPPLY_CHARGE_TYPE_NONE; } /* Default to false if the battery power supply is not registered. */ pr_debug("battery power supply is not registered\n"); return false; } #define BAT_PRES_BIT BIT(7) static bool is_battery_present(struct qpnp_bms_chip *chip) { union power_supply_propval ret = {0,}; int rc; u8 batt_pres; /* first try to use the batt_pres register if given */ if (chip->batt_pres_addr) { rc = qpnp_read_wrapper(chip, &batt_pres, chip->batt_pres_addr, 1); if (!rc && (batt_pres & BAT_PRES_BIT)) return true; else return false; } if (chip->batt_psy == NULL) chip->batt_psy = power_supply_get_by_name("battery"); if (chip->batt_psy) { /* if battery has been registered, use the present property */ chip->batt_psy->get_property(chip->batt_psy, POWER_SUPPLY_PROP_PRESENT, &ret); return ret.intval; } /* Default to false if the battery power supply is not registered. */ pr_debug("battery power supply is not registered\n"); return false; } #define BAT_REMOVED_OFFMODE_BIT BIT(6) static bool is_battery_replaced_in_offmode(struct qpnp_bms_chip *chip) { u8 batt_pres; int rc; if (chip->batt_pres_addr) { rc = qpnp_read_wrapper(chip, &batt_pres, chip->batt_pres_addr, 1); pr_debug("offmode removed: %02x\n", batt_pres); if (!rc && (batt_pres & BAT_REMOVED_OFFMODE_BIT)) return true; } return false; } static bool is_battery_taper_charging(struct qpnp_bms_chip *chip) { union power_supply_propval ret = {0,}; if (chip->batt_psy == NULL) chip->batt_psy = power_supply_get_by_name("battery"); if (chip->batt_psy) { chip->batt_psy->get_property(chip->batt_psy, POWER_SUPPLY_PROP_CHARGE_TYPE, &ret); return ret.intval == POWER_SUPPLY_CHARGE_TYPE_TAPER; } return false; } static int master_hold_control(struct qpnp_bms_chip *chip, bool enable) { u8 reg = 0; int rc; reg = enable ? MASTER_HOLD_BIT : 0; rc = qpnp_secure_write_wrapper(chip, ®, chip->base + DATA_CTL1_REG); if (rc) pr_err("Unable to write reg=%x rc=%d\n", DATA_CTL1_REG, rc); return rc; } static int force_fsm_state(struct qpnp_bms_chip *chip, u8 state) { int rc; u8 mode_ctl = 0; switch (state) { case S2_STATE: mode_ctl = (FORCE_S2_MODE | ENABLE_S2_MODE); break; case S3_STATE: mode_ctl = (FORCE_S3_MODE | ENABLE_S3_MODE); break; default: pr_debug("Invalid state %d\n", state); return -EINVAL; } rc = qpnp_secure_write_wrapper(chip, &mode_ctl, chip->base + MODE_CTL_REG); if (rc) { pr_err("Unable to write reg=%x rc=%d\n", MODE_CTL_REG, rc); return rc; } /* delay for the FSM state to take affect in hardware */ usleep_range(500, 600); pr_debug("force_mode=%d mode_cntl_reg=%x\n", state, mode_ctl); return 0; } static int get_sample_interval(struct qpnp_bms_chip *chip, u8 fsm_state, u32 *interval) { int rc; u8 val = 0, reg; *interval = 0; switch (fsm_state) { case S1_STATE: reg = S1_SAMPLE_INTVL_REG; break; case S2_STATE: reg = S2_SAMPLE_INTVL_REG; break; case S3_STATE: reg = S3_SAMPLE_INTVL_REG; break; default: pr_err("Invalid state %d\n", fsm_state); return -EINVAL; } rc = qpnp_read_wrapper(chip, &val, chip->base + reg, 1); if (rc) { pr_err("Failed to get state(%d) sample_interval, rc=%d\n", fsm_state, rc); return rc; } *interval = val * 10; return 0; } static int get_sample_count(struct qpnp_bms_chip *chip, u8 fsm_state, u32 *count) { int rc; u8 val = 0, reg; *count = 0; switch (fsm_state) { case S1_STATE: reg = S1_ACC_CNT_REG; break; case S2_STATE: reg = S2_ACC_CNT_REG; break; default: pr_err("Invalid state %d\n", fsm_state); return -EINVAL; } rc = qpnp_read_wrapper(chip, &val, chip->base + reg, 1); if (rc) { pr_err("Failed to get state(%d) sample_count, rc=%d\n", fsm_state, rc); return rc; } val &= ACC_CNT_MASK; *count = val ? (1 << (val + 1)) : 1; return 0; } static int get_fifo_length(struct qpnp_bms_chip *chip, u8 fsm_state, u32 *fifo_length) { int rc; u8 val = 0, reg, mask = 0, shift = 0; *fifo_length = 0; switch (fsm_state) { case S1_STATE: reg = FIFO_LENGTH_REG; mask = S1_FIFO_LENGTH_MASK; shift = 0; break; case S2_STATE: reg = FIFO_LENGTH_REG; mask = S2_FIFO_LENGTH_MASK; shift = S2_FIFO_LENGTH_SHIFT; break; default: pr_err("Invalid state %d\n", fsm_state); return -EINVAL; } rc = qpnp_read_wrapper(chip, &val, chip->base + reg, 1); if (rc) { pr_err("Failed to get state(%d) fifo_length, rc=%d\n", fsm_state, rc); return rc; } val &= mask; val >>= shift; *fifo_length = val; return 0; } static int set_fifo_length(struct qpnp_bms_chip *chip, u8 fsm_state, u32 fifo_length) { int rc; u8 reg, mask = 0, shift = 0; /* fifo_length of 1 is not supported due to a hardware issue */ if ((fifo_length <= 1) || (fifo_length > MAX_FIFO_REGS)) { pr_err("Invalid FIFO length = %d\n", fifo_length); return -EINVAL; } switch (fsm_state) { case S1_STATE: reg = FIFO_LENGTH_REG; mask = S1_FIFO_LENGTH_MASK; shift = 0; break; case S2_STATE: reg = FIFO_LENGTH_REG; mask = S2_FIFO_LENGTH_MASK; shift = S2_FIFO_LENGTH_SHIFT; break; default: pr_err("Invalid state %d\n", fsm_state); return -EINVAL; } rc = master_hold_control(chip, true); if (rc) pr_err("Unable to apply master_hold rc=%d\n", rc); rc = qpnp_masked_write_base(chip, chip->base + reg, mask, fifo_length << shift); if (rc) pr_err("Unable to set fifo length rc=%d\n", rc); rc = master_hold_control(chip, false); if (rc) pr_err("Unable to apply master_hold rc=%d\n", rc); return rc; } static int get_fsm_state(struct qpnp_bms_chip *chip, u8 *state) { int rc; /* * To read the STATUS1 register, write a value(any) to this register, * wait for 10ms and then read the register. */ *state = 0; rc = qpnp_write_wrapper(chip, state, chip->base + STATUS1_REG, 1); if (rc) { pr_err("Unable to write STATUS1_REG rc=%d\n", rc); return rc; } usleep_range(10000, 11000); /* read the current FSM state */ rc = qpnp_read_wrapper(chip, state, chip->base + STATUS1_REG, 1); if (rc) { pr_err("Unable to read STATUS1_REG rc=%d\n", rc); return rc; } *state = (*state & FSM_STATE_MASK) >> FSM_STATE_SHIFT; return rc; } static int update_fsm_state(struct qpnp_bms_chip *chip) { u8 state = 0; int rc; mutex_lock(&chip->state_change_mutex); rc = get_fsm_state(chip, &state); if (rc) { pr_err("Unable to get fsm_state rc=%d\n", rc); goto fail_fsm; } chip->current_fsm_state = state; fail_fsm: mutex_unlock(&chip->state_change_mutex); return rc; } static int backup_charge_cycle(struct qpnp_bms_chip *chip) { int rc = 0; if (chip->charge_increase >= 0) { rc = qpnp_write_wrapper(chip, &chip->charge_increase, chip->base + CHARGE_INCREASE_STORAGE, 1); if (rc) pr_err("Unable to backup charge_increase rc=%d\n", rc); } if (chip->charge_cycles >= 0) { rc = qpnp_write_wrapper(chip, (u8 *)&chip->charge_cycles, chip->base + CHARGE_CYCLE_STORAGE_LSB, 2); if (rc) pr_err("Unable to backup charge_cycles rc=%d\n", rc); } pr_debug("%s storing charge_increase=%u charge_cycle=%u\n", rc ? "Unable to" : "Sucessfully", chip->charge_increase, chip->charge_cycles); return rc; } static int read_chgcycle_data_from_backup(struct qpnp_bms_chip *chip) { int rc; uint16_t temp_u16 = 0; u8 temp_u8 = 0; rc = qpnp_read_wrapper(chip, &temp_u8, chip->base + CHARGE_INCREASE_STORAGE, 1); if (rc) { pr_err("Unable to read charge_increase rc=%d\n", rc); return rc; } rc = qpnp_read_wrapper(chip, (u8 *)&temp_u16, chip->base + CHARGE_CYCLE_STORAGE_LSB, 2); if (rc) { pr_err("Unable to read charge_cycle rc=%d\n", rc); return rc; } if ((temp_u8 == 0xFF) || (temp_u16 == 0xFFFF)) { chip->charge_cycles = 0; chip->charge_increase = 0; pr_info("rejecting aging data charge_increase=%u charge_cycle=%u\n", temp_u8, temp_u16); rc = backup_charge_cycle(chip); if (rc) pr_err("Unable to reset charge cycles rc=%d\n", rc); } else { chip->charge_increase = temp_u8; chip->charge_cycles = temp_u16; } pr_debug("charge_increase=%u charge_cycle=%u\n", chip->charge_increase, chip->charge_cycles); return rc; } static int calculate_uuc_iavg(struct qpnp_bms_chip *chip) { int i; int iavg_ma = chip->current_now / 1000; /* only continue if ibat has changed */ if (chip->current_now == chip->prev_current_now) goto ibat_unchanged; else chip->prev_current_now = chip->current_now; chip->iavg_samples_ma[chip->iavg_index] = iavg_ma; chip->iavg_index = (chip->iavg_index + 1) % chip->dt.cfg_ibat_avg_samples; chip->iavg_num_samples++; if (chip->iavg_num_samples >= chip->dt.cfg_ibat_avg_samples) chip->iavg_num_samples = chip->dt.cfg_ibat_avg_samples; if (chip->iavg_num_samples) { iavg_ma = 0; /* maintain a 16 sample average of ibat */ for (i = 0; i < chip->iavg_num_samples; i++) { pr_debug("iavg_samples_ma[%d] = %d\n", i, chip->iavg_samples_ma[i]); iavg_ma += chip->iavg_samples_ma[i]; } chip->iavg_ma = DIV_ROUND_CLOSEST(iavg_ma, chip->iavg_num_samples); } ibat_unchanged: pr_debug("current_now_ma=%d averaged_iavg_ma=%d\n", chip->current_now / 1000, chip->iavg_ma); return chip->iavg_ma; } static int adjust_uuc(struct qpnp_bms_chip *chip, int soc_uuc) { int max_percent_change; calculate_delta_time(&chip->uuc_tm_sec, &chip->uuc_delta_time_s); /* make sure that the UUC changes 1% at a time */ max_percent_change = max(chip->uuc_delta_time_s / TIME_PER_PERCENT_UUC, 1); if (chip->prev_soc_uuc == -EINVAL) { /* start with a minimum UUC if the initial UUC is high */ if (soc_uuc > MIN_SOC_UUC) chip->prev_soc_uuc = MIN_SOC_UUC; else chip->prev_soc_uuc = soc_uuc; } else { if (abs(chip->prev_soc_uuc - soc_uuc) <= max_percent_change) chip->prev_soc_uuc = soc_uuc; else if (soc_uuc > chip->prev_soc_uuc) chip->prev_soc_uuc += max_percent_change; else chip->prev_soc_uuc -= max_percent_change; } pr_debug("soc_uuc=%d new_soc_uuc=%d\n", soc_uuc, chip->prev_soc_uuc); return chip->prev_soc_uuc; } static int lookup_soc_ocv(struct qpnp_bms_chip *chip, int ocv_uv, int batt_temp) { int soc_ocv = 0, soc_cutoff = 0, soc_final = 0; int fcc, acc, soc_uuc = 0, soc_acc = 0, iavg_ma = 0; soc_ocv = interpolate_pc(chip->batt_data->pc_temp_ocv_lut, batt_temp, ocv_uv / 1000); soc_cutoff = interpolate_pc(chip->batt_data->pc_temp_ocv_lut, batt_temp, chip->dt.cfg_v_cutoff_uv / 1000); soc_final = DIV_ROUND_CLOSEST(100 * (soc_ocv - soc_cutoff), (100 - soc_cutoff)); if (chip->batt_data->ibat_acc_lut) { /* Apply ACC logic only if we discharging */ if (!is_battery_charging(chip) && chip->current_now > 0) { /* * IBAT averaging is disabled at low temp. * allowing the SOC to catcup quickly. */ if (batt_temp > chip->dt.cfg_low_temp_threshold) iavg_ma = calculate_uuc_iavg(chip); else iavg_ma = chip->current_now / 1000; fcc = interpolate_fcc(chip->batt_data->fcc_temp_lut, batt_temp); acc = interpolate_acc(chip->batt_data->ibat_acc_lut, batt_temp, iavg_ma); if (acc <= 0) { if (chip->last_acc) acc = chip->last_acc; else acc = fcc; } soc_uuc = ((fcc - acc) * 100) / fcc; if (batt_temp > chip->dt.cfg_low_temp_threshold) soc_uuc = adjust_uuc(chip, soc_uuc); soc_acc = DIV_ROUND_CLOSEST(100 * (soc_ocv - soc_uuc), (100 - soc_uuc)); pr_debug("fcc=%d acc=%d soc_final=%d soc_uuc=%d soc_acc=%d current_now=%d iavg_ma=%d\n", fcc, acc, soc_final, soc_uuc, soc_acc, chip->current_now / 1000, iavg_ma); soc_final = soc_acc; chip->last_acc = acc; } else { /* charging - reset all the counters */ chip->last_acc = 0; chip->iavg_num_samples = 0; chip->iavg_index = 0; chip->iavg_ma = 0; chip->prev_current_now = 0; chip->prev_soc_uuc = -EINVAL; } } soc_final = bound_soc(soc_final); pr_debug("soc_final=%d soc_ocv=%d soc_cutoff=%d ocv_uv=%u batt_temp=%d\n", soc_final, soc_ocv, soc_cutoff, ocv_uv, batt_temp); return soc_final; } #define V_PER_BIT_MUL_FACTOR 97656 #define V_PER_BIT_DIV_FACTOR 1000 #define VADC_INTRINSIC_OFFSET 0x6000 static int vadc_reading_to_uv(int reading, bool vadc_bms) { int64_t value; if (!vadc_bms) { /* * All the BMS H/W VADC values are pre-compensated * for VADC_INTRINSIC_OFFSET, subtract this offset * only if this reading is not obtained from BMS */ if (reading <= VADC_INTRINSIC_OFFSET) return 0; reading -= VADC_INTRINSIC_OFFSET; } value = (reading * V_PER_BIT_MUL_FACTOR); return div_u64(value, (u32)V_PER_BIT_DIV_FACTOR); } static int get_calculation_delay_ms(struct qpnp_bms_chip *chip) { if (bms_wake_active(&chip->vbms_lv_wake_source)) return chip->dt.cfg_low_voltage_calculate_soc_ms; if (chip->calculated_soc < chip->dt.cfg_low_soc_calc_threshold) return chip->dt.cfg_low_soc_calculate_soc_ms; else return chip->dt.cfg_calculate_soc_ms; } #define VADC_CALIB_UV 625000 #define VBATT_MUL_FACTOR 3 static int adjust_vbatt_reading(struct qpnp_bms_chip *chip, int reading_uv) { s64 numerator, denominator; if (reading_uv == 0) return 0; /* don't adjust if not calibrated */ if (chip->vadc_v0625 == 0 || chip->vadc_v1250 == 0) { pr_debug("No cal yet return %d\n", VBATT_MUL_FACTOR * reading_uv); return VBATT_MUL_FACTOR * reading_uv; } numerator = ((s64)reading_uv - chip->vadc_v0625) * VADC_CALIB_UV; denominator = (s64)chip->vadc_v1250 - chip->vadc_v0625; if (denominator == 0) return reading_uv * VBATT_MUL_FACTOR; return (VADC_CALIB_UV + div_s64(numerator, denominator)) * VBATT_MUL_FACTOR; } static int calib_vadc(struct qpnp_bms_chip *chip) { int rc, raw_0625, raw_1250; struct qpnp_vadc_result result; rc = qpnp_vadc_read(chip->vadc_dev, REF_625MV, &result); if (rc) { pr_debug("vadc read failed with rc = %d\n", rc); return rc; } raw_0625 = result.adc_code; rc = qpnp_vadc_read(chip->vadc_dev, REF_125V, &result); if (rc) { pr_debug("vadc read failed with rc = %d\n", rc); return rc; } raw_1250 = result.adc_code; chip->vadc_v0625 = vadc_reading_to_uv(raw_0625, false); chip->vadc_v1250 = vadc_reading_to_uv(raw_1250, false); pr_debug("vadc calib: 0625=%d raw (%d uv), 1250=%d raw (%d uv)\n", raw_0625, chip->vadc_v0625, raw_1250, chip->vadc_v1250); return 0; } static int convert_vbatt_raw_to_uv(struct qpnp_bms_chip *chip, u16 reading, bool is_pon_ocv) { int64_t uv, vbatt; int rc; uv = vadc_reading_to_uv(reading, true); pr_debug("%u raw converted into %lld uv\n", reading, uv); uv = adjust_vbatt_reading(chip, uv); pr_debug("adjusted into %lld uv\n", uv); vbatt = uv; rc = qpnp_vbat_sns_comp_result(chip->vadc_dev, &uv, is_pon_ocv); if (rc) { pr_debug("Vbatt compensation failed rc = %d\n", rc); uv = vbatt; } else { pr_debug("temp-compensated %lld into %lld uv\n", vbatt, uv); } return uv; } static void convert_and_store_ocv(struct qpnp_bms_chip *chip, int batt_temp, bool is_pon_ocv) { int rc; rc = calib_vadc(chip); if (rc) pr_err("Vadc reference voltage read failed, rc = %d\n", rc); chip->last_ocv_uv = convert_vbatt_raw_to_uv(chip, chip->last_ocv_raw, is_pon_ocv); pr_debug("last_ocv_uv = %d\n", chip->last_ocv_uv); } static int read_and_update_ocv(struct qpnp_bms_chip *chip, int batt_temp, bool is_pon_ocv) { int rc, ocv_uv; u16 ocv_data = 0; /* read the BMS h/w OCV */ rc = qpnp_read_wrapper(chip, (u8 *)&ocv_data, chip->base + OCV_DATA0_REG, 2); if (rc) { pr_err("Error reading ocv: rc = %d\n", rc); return -ENXIO; } /* check if OCV is within limits */ ocv_uv = convert_vbatt_raw_to_uv(chip, ocv_data, is_pon_ocv); if (ocv_uv < MIN_OCV_UV) { pr_err("OCV too low or invalid (%d)- rejecting it\n", ocv_uv); return 0; } if ((chip->last_ocv_raw == OCV_UNINITIALIZED) || (chip->last_ocv_raw != ocv_data)) { pr_debug("new OCV!\n"); chip->last_ocv_raw = ocv_data; convert_and_store_ocv(chip, batt_temp, is_pon_ocv); } pr_debug("ocv_raw=0x%x last_ocv_raw=0x%x last_ocv_uv=%d\n", ocv_data, chip->last_ocv_raw, chip->last_ocv_uv); return 0; } static int get_battery_voltage(struct qpnp_bms_chip *chip, int *result_uv) { int rc; struct qpnp_vadc_result adc_result; rc = qpnp_vadc_read(chip->vadc_dev, VBAT_SNS, &adc_result); if (rc) { pr_err("error reading adc channel = %d, rc = %d\n", VBAT_SNS, rc); return rc; } pr_debug("mvolts phy=%lld meas=0x%llx\n", adc_result.physical, adc_result.measurement); *result_uv = (int)adc_result.physical; return 0; } static int get_battery_status(struct qpnp_bms_chip *chip) { union power_supply_propval ret = {0,}; if (chip->batt_psy == NULL) chip->batt_psy = power_supply_get_by_name("battery"); if (chip->batt_psy) { /* if battery has been registered, use the status property */ chip->batt_psy->get_property(chip->batt_psy, POWER_SUPPLY_PROP_STATUS, &ret); return ret.intval; } /* Default to false if the battery power supply is not registered. */ pr_debug("battery power supply is not registered\n"); return POWER_SUPPLY_STATUS_UNKNOWN; } static int get_batt_therm(struct qpnp_bms_chip *chip, int *batt_temp) { int rc; struct qpnp_vadc_result result; rc = qpnp_vadc_read(chip->vadc_dev, LR_MUX1_BATT_THERM, &result); if (rc) { pr_err("error reading adc channel = %d, rc = %d\n", LR_MUX1_BATT_THERM, rc); return rc; } pr_debug("batt_temp phy = %lld meas = 0x%llx\n", result.physical, result.measurement); *batt_temp = (int)result.physical; return 0; } static int get_prop_bms_rbatt(struct qpnp_bms_chip *chip) { return chip->batt_data->default_rbatt_mohm; } static int get_rbatt(struct qpnp_bms_chip *chip, int soc, int batt_temp) { int rbatt_mohm, scalefactor; rbatt_mohm = chip->batt_data->default_rbatt_mohm; if (chip->batt_data->rbatt_sf_lut == NULL) { pr_debug("RBATT = %d\n", rbatt_mohm); return rbatt_mohm; } scalefactor = interpolate_scalingfactor(chip->batt_data->rbatt_sf_lut, batt_temp, soc); rbatt_mohm = (rbatt_mohm * scalefactor) / 100; if (chip->dt.cfg_r_conn_mohm > 0) rbatt_mohm += chip->dt.cfg_r_conn_mohm; return rbatt_mohm; } static void charging_began(struct qpnp_bms_chip *chip) { int rc; u8 state; mutex_lock(&chip->last_soc_mutex); chip->charge_start_tm_sec = 0; chip->catch_up_time_sec = 0; chip->start_soc = chip->last_soc; /* * reset ocv_at_100 to -EINVAL to indicate * start of charging. */ chip->ocv_at_100 = -EINVAL; mutex_unlock(&chip->last_soc_mutex); /* * If the BMS state is not in S2, force it in S2. Such * a condition can only occur if we are coming out of * suspend. */ mutex_lock(&chip->state_change_mutex); rc = get_fsm_state(chip, &state); if (rc) pr_err("Unable to get FSM state rc=%d\n", rc); if (rc || (state != S2_STATE)) { pr_debug("Forcing S2 state\n"); rc = force_fsm_state(chip, S2_STATE); if (rc) pr_err("Unable to set FSM state rc=%d\n", rc); } mutex_unlock(&chip->state_change_mutex); } static void charging_ended(struct qpnp_bms_chip *chip) { u8 state; int rc, status = get_battery_status(chip); mutex_lock(&chip->last_soc_mutex); chip->charge_start_tm_sec = 0; chip->catch_up_time_sec = 0; chip->end_soc = chip->last_soc; if (status == POWER_SUPPLY_STATUS_FULL) chip->last_soc_invalid = true; mutex_unlock(&chip->last_soc_mutex); /* * If the BMS state is not in S2, force it in S2. Such * a condition can only occur if we are coming out of * suspend. */ mutex_lock(&chip->state_change_mutex); rc = get_fsm_state(chip, &state); if (rc) pr_err("Unable to get FSM state rc=%d\n", rc); if (rc || (state != S2_STATE)) { pr_debug("Forcing S2 state\n"); rc = force_fsm_state(chip, S2_STATE); if (rc) pr_err("Unable to set FSM state rc=%d\n", rc); } mutex_unlock(&chip->state_change_mutex); /* Calculate charge accumulated and update charge cycle */ if (chip->dt.cfg_battery_aging_comp && (chip->end_soc > chip->start_soc)) { chip->charge_increase += (chip->end_soc - chip->start_soc); if (chip->charge_increase > 100) { chip->charge_cycles++; chip->charge_increase %= 100; } pr_debug("start_soc=%u end_soc=%u charge_cycles=%u charge_increase=%u\n", chip->start_soc, chip->end_soc, chip->charge_cycles, chip->charge_increase); rc = backup_charge_cycle(chip); if (rc) pr_err("Unable to store charge cycles rc=%d\n", rc); } } static int estimate_ocv(struct qpnp_bms_chip *chip) { int i, rc, vbatt = 0, vbatt_final = 0; for (i = 0; i < 5; i++) { rc = get_battery_voltage(chip, &vbatt); if (rc) { pr_err("Unable to read battery-voltage rc=%d\n", rc); return rc; } /* * Conservatively select the lowest vbatt to avoid reporting * a higher ocv due to variations in bootup current. */ if (i == 0) vbatt_final = vbatt; else if (vbatt < vbatt_final) vbatt_final = vbatt; msleep(20); } /* * TODO: Revisit the OCV calcuations to use approximate ibatt * and rbatt. */ return vbatt_final; } static int scale_soc_while_chg(struct qpnp_bms_chip *chip, int chg_time_sec, int catch_up_sec, int new_soc, int prev_soc) { int scaled_soc; int numerator; /* * Don't report a high value immediately slowly scale the * value from prev_soc to the new soc based on a charge time * weighted average */ pr_debug("cts=%d catch_up_sec=%d\n", chg_time_sec, catch_up_sec); if (catch_up_sec == 0) return new_soc; if (chg_time_sec > catch_up_sec) return new_soc; numerator = (catch_up_sec - chg_time_sec) * prev_soc + chg_time_sec * new_soc; scaled_soc = numerator / catch_up_sec; pr_debug("cts=%d new_soc=%d prev_soc=%d scaled_soc=%d\n", chg_time_sec, new_soc, prev_soc, scaled_soc); return scaled_soc; } static int report_eoc(struct qpnp_bms_chip *chip) { int rc = -EINVAL; union power_supply_propval ret = {0,}; if (chip->batt_psy == NULL) chip->batt_psy = power_supply_get_by_name("battery"); if (chip->batt_psy) { rc = chip->batt_psy->get_property(chip->batt_psy, POWER_SUPPLY_PROP_STATUS, &ret); if (rc) { pr_err("Unable to get battery 'STATUS' rc=%d\n", rc); } else if (ret.intval != POWER_SUPPLY_STATUS_FULL) { pr_debug("Report EOC to charger\n"); ret.intval = POWER_SUPPLY_STATUS_FULL; rc = chip->batt_psy->set_property(chip->batt_psy, POWER_SUPPLY_PROP_STATUS, &ret); if (rc) { pr_err("Unable to set 'STATUS' rc=%d\n", rc); return rc; } chip->eoc_reported = true; } } else { pr_err("battery psy not registered\n"); } return rc; } static void check_recharge_condition(struct qpnp_bms_chip *chip) { int rc; union power_supply_propval ret = {0,}; int status = get_battery_status(chip); if (chip->last_soc > chip->dt.cfg_soc_resume_limit) return; if (status == POWER_SUPPLY_STATUS_UNKNOWN) { pr_debug("Unable to read battery status\n"); return; } /* Report recharge to charger for SOC based resume of charging */ if ((status != POWER_SUPPLY_STATUS_CHARGING) && chip->eoc_reported) { ret.intval = POWER_SUPPLY_STATUS_CHARGING; rc = chip->batt_psy->set_property(chip->batt_psy, POWER_SUPPLY_PROP_STATUS, &ret); if (rc < 0) { pr_err("Unable to set battery property rc=%d\n", rc); } else { pr_info("soc dropped below resume_soc soc=%d resume_soc=%d, restart charging\n", chip->last_soc, chip->dt.cfg_soc_resume_limit); chip->eoc_reported = false; } } } static void check_eoc_condition(struct qpnp_bms_chip *chip) { int rc; int status = get_battery_status(chip); union power_supply_propval ret = {0,}; if (status == POWER_SUPPLY_STATUS_UNKNOWN) { pr_err("Unable to read battery status\n"); return; } /* * Check battery status: * if last_soc is 100 and battery status is still charging * reset ocv_at_100 and force reporting of eoc to charger. */ if ((chip->last_soc == 100) && (status == POWER_SUPPLY_STATUS_CHARGING)) chip->ocv_at_100 = -EINVAL; /* * Store the OCV value at 100. If the new ocv is greater than * ocv_at_100 (battery settles), update ocv_at_100. Else * if the SOC drops, reset ocv_at_100. */ if (chip->ocv_at_100 == -EINVAL) { if (chip->last_soc == 100) { if (chip->dt.cfg_report_charger_eoc) { rc = report_eoc(chip); if (!rc) { /* * update ocv_at_100 only if EOC is * reported successfully. */ chip->ocv_at_100 = chip->last_ocv_uv; pr_debug("Battery FULL\n"); } else { pr_err("Unable to report eoc rc=%d\n", rc); chip->ocv_at_100 = -EINVAL; } } if (chip->dt.cfg_use_reported_soc) { /* begin reported_soc process */ chip->reported_soc_in_use = true; chip->charger_removed_since_full = false; chip->charger_reinserted = false; chip->reported_soc = 100; pr_debug("Begin reported_soc process\n"); } } } else { if (chip->last_ocv_uv >= chip->ocv_at_100) { pr_debug("new_ocv(%d) > ocv_at_100(%d) maintaining SOC to 100\n", chip->last_ocv_uv, chip->ocv_at_100); chip->ocv_at_100 = chip->last_ocv_uv; chip->last_soc = 100; } else if (chip->last_soc != 100) { /* * Report that the battery is discharging. * This gets called once when the SOC falls * below 100. */ if (chip->reported_soc_in_use && chip->reported_soc == 100) { pr_debug("reported_soc=100, last_soc=%d, do not send DISCHARING status\n", chip->last_soc); } else { ret.intval = POWER_SUPPLY_STATUS_DISCHARGING; chip->batt_psy->set_property(chip->batt_psy, POWER_SUPPLY_PROP_STATUS, &ret); } pr_debug("SOC dropped (%d) discarding ocv_at_100\n", chip->last_soc); chip->ocv_at_100 = -EINVAL; } } } static int report_voltage_based_soc(struct qpnp_bms_chip *chip) { pr_debug("Reported voltage based soc = %d\n", chip->prev_voltage_based_soc); return chip->prev_voltage_based_soc; } static int prepare_reported_soc(struct qpnp_bms_chip *chip) { if (chip->charger_removed_since_full == false) { /* * charger is not removed since full, * keep reported_soc as 100 and calculate the delta soc * between reported_soc and last_soc */ chip->reported_soc = 100; chip->reported_soc_delta = 100 - chip->last_soc; pr_debug("Keep at reported_soc 100, reported_soc_delta=%d, last_soc=%d\n", chip->reported_soc_delta, chip->last_soc); } else { /* charger is removed since full */ if (chip->charger_reinserted) { /* * charger reinserted, keep the reported_soc * until it equals to last_soc. */ if (chip->reported_soc == chip->last_soc) { chip->reported_soc_in_use = false; chip->reported_soc_high_current = false; pr_debug("reported_soc equals to last_soc, stop reported_soc process\n"); } chip->reported_soc_change_sec = 0; } } pr_debug("Reporting reported_soc=%d, last_soc=%d\n", chip->reported_soc, chip->last_soc); return chip->reported_soc; } #define SOC_CATCHUP_SEC_MAX 600 #define SOC_CATCHUP_SEC_PER_PERCENT 60 #define MAX_CATCHUP_SOC (SOC_CATCHUP_SEC_MAX / SOC_CATCHUP_SEC_PER_PERCENT) #define SOC_CHANGE_PER_SEC 5 static int report_vm_bms_soc(struct qpnp_bms_chip *chip) { int soc, soc_change, batt_temp, rc; int time_since_last_change_sec = 0, charge_time_sec = 0; unsigned long last_change_sec; bool charging; soc = chip->calculated_soc; last_change_sec = chip->last_soc_change_sec; calculate_delta_time(&last_change_sec, &time_since_last_change_sec); charging = is_battery_charging(chip); pr_debug("charging=%d last_soc=%d last_soc_unbound=%d\n", charging, chip->last_soc, chip->last_soc_unbound); /* * account for charge time - limit it to SOC_CATCHUP_SEC to * avoid overflows when charging continues for extended periods */ if (charging && chip->last_soc != -EINVAL) { if (chip->charge_start_tm_sec == 0) { /* * calculating soc for the first time * after start of chg. Initialize catchup time */ if (abs(soc - chip->last_soc) < MAX_CATCHUP_SOC) chip->catch_up_time_sec = (soc - chip->last_soc) * SOC_CATCHUP_SEC_PER_PERCENT; else chip->catch_up_time_sec = SOC_CATCHUP_SEC_MAX; if (chip->catch_up_time_sec < 0) chip->catch_up_time_sec = 0; chip->charge_start_tm_sec = last_change_sec; } charge_time_sec = min(SOC_CATCHUP_SEC_MAX, (int)last_change_sec - chip->charge_start_tm_sec); /* end catchup if calculated soc and last soc are same */ if (chip->last_soc == soc) chip->catch_up_time_sec = 0; } if (chip->last_soc != -EINVAL) { /* * last_soc < soc ... if we have not been charging at all * since the last time this was called, report previous SoC. * Otherwise, scale and catch up. */ rc = get_batt_therm(chip, &batt_temp); if (rc) batt_temp = BMS_DEFAULT_TEMP; if (chip->last_soc < soc && !charging) soc = chip->last_soc; else if (chip->last_soc < soc && soc != 100) soc = scale_soc_while_chg(chip, charge_time_sec, chip->catch_up_time_sec, soc, chip->last_soc); /* * if the battery is close to cutoff or if the batt_temp * is under the low-temp threshold allow bigger change */ if (bms_wake_active(&chip->vbms_lv_wake_source) || (batt_temp <= chip->dt.cfg_low_temp_threshold)) soc_change = min((int)abs(chip->last_soc - soc), time_since_last_change_sec); else soc_change = min((int)abs(chip->last_soc - soc), time_since_last_change_sec / SOC_CHANGE_PER_SEC); if (chip->last_soc_unbound) { chip->last_soc_unbound = false; } else { /* * if soc have not been unbound by resume, * only change reported SoC by 1. */ soc_change = min(1, soc_change); } if (soc < chip->last_soc && soc != 0) soc = chip->last_soc - soc_change; if (soc > chip->last_soc && soc != 100) soc = chip->last_soc + soc_change; } if (chip->last_soc != soc && !chip->last_soc_unbound) chip->last_soc_change_sec = last_change_sec; /* * Check/update eoc under following condition: * if there is change in soc: * soc != chip->last_soc * during bootup if soc is 100: */ soc = bound_soc(soc); if ((soc != chip->last_soc) || (soc == 100)) { chip->last_soc = soc; check_eoc_condition(chip); if ((chip->dt.cfg_soc_resume_limit > 0) && !charging) check_recharge_condition(chip); } pr_debug("last_soc=%d calculated_soc=%d soc=%d time_since_last_change=%d\n", chip->last_soc, chip->calculated_soc, soc, time_since_last_change_sec); /* * Backup the actual ocv (last_ocv_uv) and not the * last_soc-interpolated ocv. This makes sure that * the BMS algorithm always uses the correct ocv and * can catch up on the last_soc (across reboots). * We do not want the algorithm to be based of a wrong * initial OCV. */ backup_ocv_soc(chip, chip->last_ocv_uv, chip->last_soc); if (chip->reported_soc_in_use) return prepare_reported_soc(chip); pr_debug("Reported SOC=%d\n", chip->last_soc); return chip->last_soc; } static int report_state_of_charge(struct qpnp_bms_chip *chip) { int soc; mutex_lock(&chip->last_soc_mutex); if (chip->dt.cfg_use_voltage_soc) soc = report_voltage_based_soc(chip); else soc = report_vm_bms_soc(chip); mutex_unlock(&chip->last_soc_mutex); return soc; } static void btm_notify_vbat(enum qpnp_tm_state state, void *ctx) { struct qpnp_bms_chip *chip = ctx; int vbat_uv; int rc; rc = get_battery_voltage(chip, &vbat_uv); if (rc) { pr_err("error reading vbat_sns adc channel=%d, rc=%d\n", VBAT_SNS, rc); goto out; } pr_debug("vbat is at %d, state is at %d\n", vbat_uv, state); if (state == ADC_TM_LOW_STATE) { pr_debug("low voltage btm notification triggered\n"); if (vbat_uv <= (chip->vbat_monitor_params.low_thr + VBATT_ERROR_MARGIN)) { if (!bms_wake_active(&chip->vbms_lv_wake_source)) bms_stay_awake(&chip->vbms_lv_wake_source); chip->vbat_monitor_params.state_request = ADC_TM_HIGH_THR_ENABLE; } else { pr_debug("faulty btm trigger, discarding\n"); goto out; } } else if (state == ADC_TM_HIGH_STATE) { pr_debug("high voltage btm notification triggered\n"); if (vbat_uv > chip->vbat_monitor_params.high_thr) { chip->vbat_monitor_params.state_request = ADC_TM_LOW_THR_ENABLE; if (bms_wake_active(&chip->vbms_lv_wake_source)) bms_relax(&chip->vbms_lv_wake_source); } else { pr_debug("faulty btm trigger, discarding\n"); goto out; } } else { pr_debug("unknown voltage notification state: %d\n", state); goto out; } if (chip->bms_psy_registered) power_supply_changed(&chip->bms_psy); out: qpnp_adc_tm_channel_measure(chip->adc_tm_dev, &chip->vbat_monitor_params); } static int reset_vbat_monitoring(struct qpnp_bms_chip *chip) { int rc; chip->vbat_monitor_params.state_request = ADC_TM_HIGH_LOW_THR_DISABLE; rc = qpnp_adc_tm_channel_measure(chip->adc_tm_dev, &chip->vbat_monitor_params); if (rc) { pr_err("tm disable failed: %d\n", rc); return rc; } if (bms_wake_active(&chip->vbms_lv_wake_source)) bms_relax(&chip->vbms_lv_wake_source); return 0; } static int setup_vbat_monitoring(struct qpnp_bms_chip *chip) { int rc; chip->vbat_monitor_params.low_thr = chip->dt.cfg_low_voltage_threshold; chip->vbat_monitor_params.high_thr = chip->dt.cfg_low_voltage_threshold + VBATT_ERROR_MARGIN; chip->vbat_monitor_params.state_request = ADC_TM_LOW_THR_ENABLE; chip->vbat_monitor_params.channel = VBAT_SNS; chip->vbat_monitor_params.btm_ctx = chip; chip->vbat_monitor_params.timer_interval = ADC_MEAS1_INTERVAL_1S; chip->vbat_monitor_params.threshold_notification = &btm_notify_vbat; pr_debug("set low thr to %d and high to %d\n", chip->vbat_monitor_params.low_thr, chip->vbat_monitor_params.high_thr); rc = qpnp_adc_tm_channel_measure(chip->adc_tm_dev, &chip->vbat_monitor_params); if (rc) { pr_err("adc-tm setup failed: %d\n", rc); return rc; } pr_debug("vbat monitoring setup complete\n"); return 0; } static void very_low_voltage_check(struct qpnp_bms_chip *chip, int vbat_uv) { if (!bms_wake_active(&chip->vbms_lv_wake_source) && (vbat_uv <= chip->dt.cfg_low_voltage_threshold)) { pr_debug("voltage=%d holding low voltage ws\n", vbat_uv); bms_stay_awake(&chip->vbms_lv_wake_source); } else if (bms_wake_active(&chip->vbms_lv_wake_source) && (vbat_uv > chip->dt.cfg_low_voltage_threshold)) { pr_debug("voltage=%d releasing low voltage ws\n", vbat_uv); bms_relax(&chip->vbms_lv_wake_source); } } static void cv_voltage_check(struct qpnp_bms_chip *chip, int vbat_uv) { if (bms_wake_active(&chip->vbms_cv_wake_source)) { if ((vbat_uv < (chip->dt.cfg_max_voltage_uv - VBATT_ERROR_MARGIN + CV_DROP_MARGIN)) && !is_battery_taper_charging(chip)) { pr_debug("Fell below CV, releasing cv ws\n"); chip->in_cv_state = false; bms_relax(&chip->vbms_cv_wake_source); } else if (!is_battery_charging(chip)) { pr_debug("charging stopped, releasing cv ws\n"); chip->in_cv_state = false; bms_relax(&chip->vbms_cv_wake_source); } } else if (!bms_wake_active(&chip->vbms_cv_wake_source) && is_battery_charging(chip) && ((vbat_uv > (chip->dt.cfg_max_voltage_uv - VBATT_ERROR_MARGIN)) || is_battery_taper_charging(chip))) { pr_debug("CC_TO_CV voltage=%d holding cv ws\n", vbat_uv); chip->in_cv_state = true; bms_stay_awake(&chip->vbms_cv_wake_source); } } static void low_soc_check(struct qpnp_bms_chip *chip) { int rc; if (chip->dt.cfg_low_soc_fifo_length < 1) return; mutex_lock(&chip->state_change_mutex); if (chip->calculated_soc <= chip->dt.cfg_low_soc_calc_threshold) { if (!chip->low_soc_fifo_set) { pr_debug("soc=%d (low-soc) setting fifo_length to %d\n", chip->calculated_soc, chip->dt.cfg_low_soc_fifo_length); rc = get_fifo_length(chip, S2_STATE, &chip->s2_fifo_length); if (rc) { pr_err("Unable to get_fifo_length rc=%d", rc); goto low_soc_exit; } rc = set_fifo_length(chip, S2_STATE, chip->dt.cfg_low_soc_fifo_length); if (rc) { pr_err("Unable to set_fifo_length rc=%d", rc); goto low_soc_exit; } chip->low_soc_fifo_set = true; } } else { if (chip->low_soc_fifo_set) { pr_debug("soc=%d setting back fifo_length to %d\n", chip->calculated_soc, chip->s2_fifo_length); rc = set_fifo_length(chip, S2_STATE, chip->s2_fifo_length); if (rc) { pr_err("Unable to set_fifo_length rc=%d", rc); goto low_soc_exit; } chip->low_soc_fifo_set = false; } } low_soc_exit: mutex_unlock(&chip->state_change_mutex); } static int calculate_soc_from_voltage(struct qpnp_bms_chip *chip) { int voltage_range_uv, voltage_remaining_uv, voltage_based_soc; int rc, vbat_uv; /* check if we have the averaged fifo data */ if (chip->voltage_soc_uv) { vbat_uv = chip->voltage_soc_uv; } else { rc = get_battery_voltage(chip, &vbat_uv); if (rc < 0) { pr_err("adc vbat failed err = %d\n", rc); return rc; } pr_debug("instant-voltage based voltage-soc\n"); } voltage_range_uv = chip->dt.cfg_max_voltage_uv - chip->dt.cfg_v_cutoff_uv; voltage_remaining_uv = vbat_uv - chip->dt.cfg_v_cutoff_uv; voltage_based_soc = voltage_remaining_uv * 100 / voltage_range_uv; voltage_based_soc = clamp(voltage_based_soc, 0, 100); if (chip->prev_voltage_based_soc != voltage_based_soc && chip->bms_psy_registered) { pr_debug("update bms_psy\n"); power_supply_changed(&chip->bms_psy); } chip->prev_voltage_based_soc = voltage_based_soc; pr_debug("vbat used = %duv\n", vbat_uv); pr_debug("Calculated voltage based soc=%d\n", voltage_based_soc); if (voltage_based_soc == 100) if (chip->dt.cfg_report_charger_eoc) report_eoc(chip); return 0; } static void calculate_reported_soc(struct qpnp_bms_chip *chip) { union power_supply_propval ret = {0,}; if (chip->reported_soc > chip->last_soc) { /*send DISCHARGING status if the reported_soc drops from 100 */ if (chip->reported_soc == 100) { ret.intval = POWER_SUPPLY_STATUS_DISCHARGING; chip->batt_psy->set_property(chip->batt_psy, POWER_SUPPLY_PROP_STATUS, &ret); pr_debug("Report discharging status, reported_soc=%d, last_soc=%d\n", chip->reported_soc, chip->last_soc); } /* * reported_soc_delta is used to prevent * the big change in last_soc, * this is not used in high current mode */ if (chip->reported_soc_delta > 0) chip->reported_soc_delta--; if (chip->reported_soc_high_current) chip->reported_soc--; else chip->reported_soc = chip->last_soc + chip->reported_soc_delta; pr_debug("New reported_soc=%d, last_soc is=%d\n", chip->reported_soc, chip->last_soc); } else { chip->reported_soc_in_use = false; chip->reported_soc_high_current = false; pr_debug("reported_soc equals last_soc,stop reported_soc process\n"); } pr_debug("bms power_supply_changed\n"); power_supply_changed(&chip->bms_psy); } static int clamp_soc_based_on_voltage(struct qpnp_bms_chip *chip, int soc) { int rc, vbat_uv; rc = get_battery_voltage(chip, &vbat_uv); if (rc < 0) { pr_err("adc vbat failed err = %d\n", rc); return soc; } /* only clamp when discharging */ if (is_battery_charging(chip)) return soc; if (soc <= 0 && vbat_uv > chip->dt.cfg_v_cutoff_uv) { pr_debug("clamping soc to 1, vbat (%d) > cutoff (%d)\n", vbat_uv, chip->dt.cfg_v_cutoff_uv); return 1; } else { pr_debug("not clamping, using soc = %d, vbat = %d and cutoff = %d\n", soc, vbat_uv, chip->dt.cfg_v_cutoff_uv); return soc; } } #define UI_SOC_CATCHUP_TIME (60) static void monitor_soc_work(struct work_struct *work) { struct qpnp_bms_chip *chip = container_of(work, struct qpnp_bms_chip, monitor_soc_work.work); int rc, vbat_uv = 0, new_soc = 0, batt_temp; bms_stay_awake(&chip->vbms_soc_wake_source); calculate_delta_time(&chip->tm_sec, &chip->delta_time_s); pr_debug("elapsed_time=%d\n", chip->delta_time_s); mutex_lock(&chip->last_soc_mutex); if (!is_battery_present(chip)) { /* if battery is not preset report 100% SOC */ pr_debug("battery gone, reporting 100\n"); chip->last_soc_invalid = true; chip->last_soc = -EINVAL; new_soc = 100; } else { rc = get_battery_voltage(chip, &vbat_uv); if (rc < 0) { pr_err("Failed to read battery-voltage rc=%d\n", rc); } else { very_low_voltage_check(chip, vbat_uv); cv_voltage_check(chip, vbat_uv); } if (chip->dt.cfg_use_voltage_soc) { calculate_soc_from_voltage(chip); } else { rc = get_batt_therm(chip, &batt_temp); if (rc < 0) { pr_err("Unable to read batt temp rc=%d, using default=%d\n", rc, BMS_DEFAULT_TEMP); batt_temp = BMS_DEFAULT_TEMP; } if (chip->last_soc_invalid) { chip->last_soc_invalid = false; chip->last_soc = -EINVAL; } new_soc = lookup_soc_ocv(chip, chip->last_ocv_uv, batt_temp); /* clamp soc due to BMS hw/sw immaturities */ new_soc = clamp_soc_based_on_voltage(chip, new_soc); if (chip->calculated_soc != new_soc) { pr_debug("SOC changed! new_soc=%d prev_soc=%d\n", new_soc, chip->calculated_soc); chip->calculated_soc = new_soc; if (chip->calculated_soc == 100) /* update last_soc immediately */ report_vm_bms_soc(chip); pr_debug("update bms_psy\n"); power_supply_changed(&chip->bms_psy); } else if (chip->last_soc != chip->calculated_soc) { pr_debug("update bms_psy\n"); power_supply_changed(&chip->bms_psy); } else { report_vm_bms_soc(chip); } } /* low SOC configuration */ low_soc_check(chip); } /* * schedule the work only if last_soc has not caught up with * the calculated soc or if we are using voltage based soc */ if ((chip->last_soc != chip->calculated_soc) || chip->dt.cfg_use_voltage_soc) schedule_delayed_work(&chip->monitor_soc_work, msecs_to_jiffies(get_calculation_delay_ms(chip))); if (chip->reported_soc_in_use && chip->charger_removed_since_full && !chip->charger_reinserted) { /* record the elapsed time after last reported_soc change */ chip->reported_soc_change_sec += chip->delta_time_s; pr_debug("reported_soc_change_sec=%d\n", chip->reported_soc_change_sec); /* above the catch up time, calculate new reported_soc */ if (chip->reported_soc_change_sec > UI_SOC_CATCHUP_TIME) { calculate_reported_soc(chip); chip->reported_soc_change_sec = 0; } } mutex_unlock(&chip->last_soc_mutex); bms_relax(&chip->vbms_soc_wake_source); } static void voltage_soc_timeout_work(struct work_struct *work) { struct qpnp_bms_chip *chip = container_of(work, struct qpnp_bms_chip, voltage_soc_timeout_work.work); mutex_lock(&chip->bms_device_mutex); if (!chip->bms_dev_open) { pr_warn("BMS device not opened, using voltage based SOC\n"); chip->dt.cfg_use_voltage_soc = true; } mutex_unlock(&chip->bms_device_mutex); } static int get_prop_bms_capacity(struct qpnp_bms_chip *chip) { return report_state_of_charge(chip); } static bool is_hi_power_state_requested(struct qpnp_bms_chip *chip) { pr_debug("hi_power_state=0x%x\n", chip->hi_power_state); if (chip->hi_power_state & VMBMS_IGNORE_ALL_BIT) return false; else return !!chip->hi_power_state; } static int qpnp_vm_bms_config_power_state(struct qpnp_bms_chip *chip, int usecase, bool hi_power_enable) { if (usecase < 0) { pr_err("Invalid power-usecase %x\n", usecase); return -EINVAL; } if (hi_power_enable) chip->hi_power_state |= usecase; else chip->hi_power_state &= ~usecase; pr_debug("hi_power_state=%x usecase=%x hi_power_enable=%d\n", chip->hi_power_state, usecase, hi_power_enable); return 0; } static int get_prop_bms_current_now(struct qpnp_bms_chip *chip) { return chip->current_now; } static enum power_supply_property bms_power_props[] = { POWER_SUPPLY_PROP_CAPACITY, POWER_SUPPLY_PROP_STATUS, POWER_SUPPLY_PROP_RESISTANCE, POWER_SUPPLY_PROP_RESISTANCE_CAPACITIVE, POWER_SUPPLY_PROP_CURRENT_NOW, POWER_SUPPLY_PROP_VOLTAGE_OCV, POWER_SUPPLY_PROP_HI_POWER, POWER_SUPPLY_PROP_LOW_POWER, POWER_SUPPLY_PROP_BATTERY_TYPE, POWER_SUPPLY_PROP_TEMP, POWER_SUPPLY_PROP_CYCLE_COUNT, }; static int qpnp_vm_bms_property_is_writeable(struct power_supply *psy, enum power_supply_property psp) { switch (psp) { case POWER_SUPPLY_PROP_CURRENT_NOW: case POWER_SUPPLY_PROP_VOLTAGE_OCV: case POWER_SUPPLY_PROP_HI_POWER: case POWER_SUPPLY_PROP_LOW_POWER: return 1; default: break; } return 0; } static int qpnp_vm_bms_power_get_property(struct power_supply *psy, enum power_supply_property psp, union power_supply_propval *val) { struct qpnp_bms_chip *chip = container_of(psy, struct qpnp_bms_chip, bms_psy); int value = 0, rc; val->intval = 0; switch (psp) { case POWER_SUPPLY_PROP_CAPACITY: val->intval = get_prop_bms_capacity(chip); break; case POWER_SUPPLY_PROP_STATUS: val->intval = chip->battery_status; break; case POWER_SUPPLY_PROP_RESISTANCE: val->intval = get_prop_bms_rbatt(chip); break; case POWER_SUPPLY_PROP_RESISTANCE_CAPACITIVE: if (chip->batt_data->rbatt_capacitive_mohm > 0) val->intval = chip->batt_data->rbatt_capacitive_mohm; if (chip->dt.cfg_r_conn_mohm > 0) val->intval += chip->dt.cfg_r_conn_mohm; break; case POWER_SUPPLY_PROP_CURRENT_NOW: val->intval = get_prop_bms_current_now(chip); break; case POWER_SUPPLY_PROP_BATTERY_TYPE: val->strval = chip->batt_data->battery_type; break; case POWER_SUPPLY_PROP_VOLTAGE_OCV: val->intval = chip->last_ocv_uv; break; case POWER_SUPPLY_PROP_TEMP: rc = get_batt_therm(chip, &value); if (rc < 0) value = BMS_DEFAULT_TEMP; val->intval = value; break; case POWER_SUPPLY_PROP_HI_POWER: val->intval = is_hi_power_state_requested(chip); break; case POWER_SUPPLY_PROP_LOW_POWER: val->intval = !is_hi_power_state_requested(chip); break; case POWER_SUPPLY_PROP_CYCLE_COUNT: if (chip->dt.cfg_battery_aging_comp) val->intval = chip->charge_cycles; else val->intval = -EINVAL; break; default: return -EINVAL; } return 0; } static int qpnp_vm_bms_power_set_property(struct power_supply *psy, enum power_supply_property psp, const union power_supply_propval *val) { int rc = 0; struct qpnp_bms_chip *chip = container_of(psy, struct qpnp_bms_chip, bms_psy); switch (psp) { case POWER_SUPPLY_PROP_CURRENT_NOW: chip->current_now = val->intval; pr_debug("IBATT = %d\n", val->intval); break; case POWER_SUPPLY_PROP_VOLTAGE_OCV: cancel_delayed_work_sync(&chip->monitor_soc_work); chip->last_ocv_uv = val->intval; pr_debug("OCV = %d\n", val->intval); schedule_delayed_work(&chip->monitor_soc_work, 0); break; case POWER_SUPPLY_PROP_HI_POWER: rc = qpnp_vm_bms_config_power_state(chip, val->intval, true); if (rc) pr_err("Unable to set power-state rc=%d\n", rc); break; case POWER_SUPPLY_PROP_LOW_POWER: rc = qpnp_vm_bms_config_power_state(chip, val->intval, false); if (rc) pr_err("Unable to set power-state rc=%d\n", rc); break; default: return -EINVAL; } return rc; } static void bms_new_battery_setup(struct qpnp_bms_chip *chip) { int rc; mutex_lock(&chip->bms_data_mutex); chip->last_soc_invalid = true; /* * disable and re-enable the BMS hardware to reset * the realtime-FIFO data and restart accumulation */ rc = qpnp_masked_write_base(chip, chip->base + EN_CTL_REG, BMS_EN_BIT, 0); /* delay for the BMS hardware to reset its state */ msleep(200); rc |= qpnp_masked_write_base(chip, chip->base + EN_CTL_REG, BMS_EN_BIT, BMS_EN_BIT); /* delay for the BMS hardware to re-start */ msleep(200); if (rc) pr_err("Unable to reset BMS rc=%d\n", rc); chip->last_ocv_uv = estimate_ocv(chip); memset(&chip->bms_data, 0, sizeof(chip->bms_data)); /* update the sequence number */ chip->bms_data.seq_num = chip->seq_num++; /* signal the read thread */ chip->data_ready = 1; wake_up_interruptible(&chip->bms_wait_q); /* hold a wake lock until the read thread is scheduled */ if (chip->bms_dev_open) pm_stay_awake(chip->dev); mutex_unlock(&chip->bms_data_mutex); /* reset aging variables */ if (chip->dt.cfg_battery_aging_comp) { chip->charge_cycles = 0; chip->charge_increase = 0; rc = backup_charge_cycle(chip); if (rc) pr_err("Unable to reset aging data rc=%d\n", rc); } } static void battery_insertion_check(struct qpnp_bms_chip *chip) { int present = (int)is_battery_present(chip); if (chip->battery_present != present) { pr_debug("shadow_sts=%d status=%d\n", chip->battery_present, present); if (chip->battery_present != -EINVAL) { if (present) { /* new battery inserted */ bms_new_battery_setup(chip); setup_vbat_monitoring(chip); pr_debug("New battery inserted!\n"); } else { /* battery removed */ reset_vbat_monitoring(chip); pr_debug("Battery removed\n"); } } chip->battery_present = present; } } static void battery_status_check(struct qpnp_bms_chip *chip) { int status = get_battery_status(chip); if (chip->battery_status != status) { if (status == POWER_SUPPLY_STATUS_CHARGING) { pr_debug("charging started\n"); charging_began(chip); } else if (chip->battery_status == POWER_SUPPLY_STATUS_CHARGING) { pr_debug("charging stopped\n"); charging_ended(chip); } if (status == POWER_SUPPLY_STATUS_FULL) { pr_debug("battery full\n"); chip->battery_full = true; } else if (chip->battery_status == POWER_SUPPLY_STATUS_FULL) { pr_debug("battery not-full anymore\n"); chip->battery_full = false; } chip->battery_status = status; } } #define HIGH_CURRENT_TH 2 static void reported_soc_check_status(struct qpnp_bms_chip *chip) { u8 present; present = is_charger_present(chip); pr_debug("usb_present=%d\n", present); if (!present && !chip->charger_removed_since_full) { chip->charger_removed_since_full = true; pr_debug("reported_soc: charger removed since full\n"); return; } if (chip->reported_soc_high_current) { pr_debug("reported_soc in high current mode, return\n"); return; } if ((chip->reported_soc - chip->last_soc) > (100 - chip->dt.cfg_soc_resume_limit + HIGH_CURRENT_TH)) { chip->reported_soc_high_current = true; chip->charger_removed_since_full = true; chip->charger_reinserted = false; pr_debug("reported_soc enters high current mode\n"); return; } if (present && chip->charger_removed_since_full) { chip->charger_reinserted = true; pr_debug("reported_soc: charger reinserted\n"); } if (!present && chip->charger_removed_since_full) { chip->charger_reinserted = false; pr_debug("reported_soc: charger removed again\n"); } } static void qpnp_vm_bms_ext_power_changed(struct power_supply *psy) { struct qpnp_bms_chip *chip = container_of(psy, struct qpnp_bms_chip, bms_psy); pr_debug("Triggered!\n"); battery_status_check(chip); battery_insertion_check(chip); if (chip->reported_soc_in_use) reported_soc_check_status(chip); } static void dump_bms_data(const char *func, struct qpnp_bms_chip *chip) { int i; pr_debug("%s: fifo_count=%d acc_count=%d seq_num=%d\n", func, chip->bms_data.num_fifo, chip->bms_data.acc_count, chip->bms_data.seq_num); for (i = 0; i < chip->bms_data.num_fifo; i++) pr_debug("fifo=%d fifo_uv=%d sample_interval=%d sample_count=%d\n", i, chip->bms_data.fifo_uv[i], chip->bms_data.sample_interval_ms, chip->bms_data.sample_count); pr_debug("avg_acc_data=%d\n", chip->bms_data.acc_uv); } static int read_and_populate_fifo_data(struct qpnp_bms_chip *chip) { u8 fifo_count = 0, val = 0; u8 fifo_data_raw[MAX_FIFO_REGS * 2]; u16 fifo_data; int rc, i, j; int64_t voltage_soc_avg = 0; /* read the completed FIFO count */ rc = qpnp_read_wrapper(chip, &val, chip->base + STATUS2_REG, 1); if (rc) { pr_err("Unable to read STATUS2 register rc=%d\n", rc); return rc; } fifo_count = (val & FIFO_CNT_SD_MASK) >> FIFO_CNT_SD_SHIFT; pr_debug("fifo_count=%d\n", fifo_count); if (!fifo_count) { pr_debug("No data in FIFO\n"); return 0; } else if (fifo_count > MAX_FIFO_REGS) { pr_err("Invalid fifo-length %d rejecting data\n", fifo_count); chip->bms_data.num_fifo = 0; return 0; } /* read the FIFO data */ for (i = 0; i < fifo_count * 2; i++) { rc = qpnp_read_wrapper(chip, &fifo_data_raw[i], chip->base + FIFO_0_LSB_REG + i, 1); if (rc) { pr_err("Unable to read FIFO register(%d) rc=%d\n", i, rc); return rc; } } /* populate the structure */ chip->bms_data.num_fifo = fifo_count; rc = get_sample_interval(chip, chip->current_fsm_state, &chip->bms_data.sample_interval_ms); if (rc) { pr_err("Unable to read state=%d sample_interval rc=%d\n", chip->current_fsm_state, rc); return rc; } rc = get_sample_count(chip, chip->current_fsm_state, &chip->bms_data.sample_count); if (rc) { pr_err("Unable to read state=%d sample_count rc=%d\n", chip->current_fsm_state, rc); return rc; } for (i = 0, j = 0; i < fifo_count * 2; i = i + 2, j++) { fifo_data = fifo_data_raw[i] | (fifo_data_raw[i + 1] << 8); chip->bms_data.fifo_uv[j] = convert_vbatt_raw_to_uv(chip, fifo_data, 0); voltage_soc_avg += chip->bms_data.fifo_uv[j]; } /* store the fifo average for voltage-based-soc */ chip->voltage_soc_uv = div_u64(voltage_soc_avg, fifo_count); return 0; } static int read_and_populate_acc_data(struct qpnp_bms_chip *chip) { int rc; u32 acc_data_sd = 0, acc_count_sd = 0, avg_acc_data = 0; /* read ACC SD count */ rc = qpnp_read_wrapper(chip, (u8 *)&acc_count_sd, chip->base + ACC_CNT_SD_REG, 1); if (rc) { pr_err("Unable to read ACC_CNT_SD_REG rc=%d\n", rc); return rc; } if (!acc_count_sd) { pr_debug("No data in accumulator\n"); return 0; } /* read ACC SD data */ rc = qpnp_read_wrapper(chip, (u8 *)&acc_data_sd, chip->base + ACC_DATA0_SD_REG, 3); if (rc) { pr_err("Unable to read ACC_DATA0_SD_REG rc=%d\n", rc); return rc; } avg_acc_data = div_u64(acc_data_sd, acc_count_sd); chip->bms_data.acc_uv = convert_vbatt_raw_to_uv(chip, avg_acc_data, 0); chip->bms_data.acc_count = acc_count_sd; rc = get_sample_interval(chip, chip->current_fsm_state, &chip->bms_data.sample_interval_ms); if (rc) { pr_err("Unable to read state=%d sample_interval rc=%d\n", chip->current_fsm_state, rc); return rc; } rc = get_sample_count(chip, chip->current_fsm_state, &chip->bms_data.sample_count); if (rc) { pr_err("Unable to read state=%d sample_count rc=%d\n", chip->current_fsm_state, rc); return rc; } return 0; } static int clear_fifo_acc_data(struct qpnp_bms_chip *chip) { int rc; u8 reg = 0; reg = FIFO_CNT_SD_CLR_BIT | ACC_DATA_SD_CLR_BIT | ACC_CNT_SD_CLR_BIT; rc = qpnp_masked_write_base(chip, chip->base + DATA_CTL2_REG, reg, reg); if (rc) pr_err("Unable to write DATA_CTL2_REG rc=%d\n", rc); return rc; } static irqreturn_t bms_fifo_update_done_irq_handler(int irq, void *_chip) { int rc; struct qpnp_bms_chip *chip = _chip; pr_debug("fifo_update_done triggered\n"); mutex_lock(&chip->bms_data_mutex); if (chip->suspend_data_valid) { pr_debug("Suspend data not processed yet\n"); goto fail_fifo; } rc = calib_vadc(chip); if (rc) pr_err("Unable to calibrate vadc rc=%d\n", rc); /* clear old data */ memset(&chip->bms_data, 0, sizeof(chip->bms_data)); /* * 1. Read FIFO and populate the bms_data * 2. Clear FIFO data * 3. Notify userspace */ rc = update_fsm_state(chip); if (rc) { pr_err("Unable to read FSM state rc=%d\n", rc); goto fail_fifo; } pr_debug("fsm_state=%d\n", chip->current_fsm_state); rc = read_and_populate_fifo_data(chip); if (rc) { pr_err("Unable to read FIFO data rc=%d\n", rc); goto fail_fifo; } rc = clear_fifo_acc_data(chip); if (rc) pr_err("Unable to clear FIFO/ACC data rc=%d\n", rc); /* update the sequence number */ chip->bms_data.seq_num = chip->seq_num++; dump_bms_data(__func__, chip); /* signal the read thread */ chip->data_ready = 1; wake_up_interruptible(&chip->bms_wait_q); /* hold a wake lock until the read thread is scheduled */ if (chip->bms_dev_open) pm_stay_awake(chip->dev); fail_fifo: mutex_unlock(&chip->bms_data_mutex); return IRQ_HANDLED; } static irqreturn_t bms_fsm_state_change_irq_handler(int irq, void *_chip) { int rc; struct qpnp_bms_chip *chip = _chip; pr_debug("fsm_state_changed triggered\n"); mutex_lock(&chip->bms_data_mutex); if (chip->suspend_data_valid) { pr_debug("Suspend data not processed yet\n"); goto fail_state; } rc = calib_vadc(chip); if (rc) pr_err("Unable to calibrate vadc rc=%d\n", rc); /* clear old data */ memset(&chip->bms_data, 0, sizeof(chip->bms_data)); /* * 1. Read FIFO and ACC_DATA and populate the bms_data * 2. Clear FIFO & ACC data * 3. Notify userspace */ pr_debug("prev_fsm_state=%d\n", chip->current_fsm_state); rc = read_and_populate_fifo_data(chip); if (rc) { pr_err("Unable to read FIFO data rc=%d\n", rc); goto fail_state; } /* read accumulator data */ rc = read_and_populate_acc_data(chip); if (rc) { pr_err("Unable to read ACC_SD data rc=%d\n", rc); goto fail_state; } rc = update_fsm_state(chip); if (rc) { pr_err("Unable to read FSM state rc=%d\n", rc); goto fail_state; } rc = clear_fifo_acc_data(chip); if (rc) pr_err("Unable to clear FIFO/ACC data rc=%d\n", rc); /* update the sequence number */ chip->bms_data.seq_num = chip->seq_num++; dump_bms_data(__func__, chip); /* signal the read thread */ chip->data_ready = 1; wake_up_interruptible(&chip->bms_wait_q); /* hold a wake lock until the read thread is scheduled */ if (chip->bms_dev_open) pm_stay_awake(chip->dev); fail_state: mutex_unlock(&chip->bms_data_mutex); return IRQ_HANDLED; } static int read_shutdown_ocv_soc(struct qpnp_bms_chip *chip) { u8 stored_soc = 0; u16 stored_ocv = 0; int rc; rc = qpnp_read_wrapper(chip, (u8 *)&stored_ocv, chip->base + BMS_OCV_REG, 2); if (rc) { pr_err("failed to read addr = %d %d\n", chip->base + BMS_OCV_REG, rc); return -EINVAL; } /* if shutdwon ocv is invalid, reject shutdown soc too */ if (!stored_ocv || (stored_ocv == OCV_INVALID)) { pr_debug("shutdown OCV %d - invalid\n", stored_ocv); chip->shutdown_ocv = OCV_INVALID; chip->shutdown_soc = SOC_INVALID; return -EINVAL; } chip->shutdown_ocv = stored_ocv * 1000; /* * The previous SOC is stored in the first 7 bits of the register as * (Shutdown SOC + 1). This allows for register reset values of both * 0x00 and 0xFF. */ rc = qpnp_read_wrapper(chip, &stored_soc, chip->base + BMS_SOC_REG, 1); if (rc) { pr_err("failed to read addr = %d %d\n", chip->base + BMS_SOC_REG, rc); return -EINVAL; } if (!stored_soc || stored_soc == SOC_INVALID) { chip->shutdown_soc = SOC_INVALID; chip->shutdown_ocv = OCV_INVALID; return -EINVAL; } else { chip->shutdown_soc = (stored_soc >> 1) - 1; } pr_debug("shutdown_ocv=%d shutdown_soc=%d\n", chip->shutdown_ocv, chip->shutdown_soc); return 0; } static int interpolate_current_comp(int die_temp) { int i; int num_rows = ARRAY_SIZE(temp_curr_comp_lut); if (die_temp <= (temp_curr_comp_lut[0].temp_decideg)) return temp_curr_comp_lut[0].current_ma; if (die_temp >= (temp_curr_comp_lut[num_rows - 1].temp_decideg)) return temp_curr_comp_lut[num_rows - 1].current_ma; for (i = 0; i < num_rows - 1; i++) if (die_temp <= (temp_curr_comp_lut[i].temp_decideg)) break; if (die_temp == (temp_curr_comp_lut[i].temp_decideg)) return temp_curr_comp_lut[i].current_ma; return linear_interpolate( temp_curr_comp_lut[i - 1].current_ma, temp_curr_comp_lut[i - 1].temp_decideg, temp_curr_comp_lut[i].current_ma, temp_curr_comp_lut[i].temp_decideg, die_temp); } static void adjust_pon_ocv(struct qpnp_bms_chip *chip, int batt_temp) { int rc, current_ma, rbatt_mohm, die_temp, delta_uv, pc; struct qpnp_vadc_result result; rc = qpnp_vadc_read(chip->vadc_dev, DIE_TEMP, &result); if (rc) { pr_err("error reading adc channel=%d, rc=%d\n", DIE_TEMP, rc); } else { pc = interpolate_pc(chip->batt_data->pc_temp_ocv_lut, batt_temp, chip->last_ocv_uv / 1000); /* * For pc < 2, use the rbatt of pc = 2. This is to avoid * the huge rbatt values at pc < 2 which can disrupt the pon_ocv * calculations. */ if (pc < 2) pc = 2; rbatt_mohm = get_rbatt(chip, pc, batt_temp); /* convert die_temp to DECIDEGC */ die_temp = (int)result.physical / 100; current_ma = interpolate_current_comp(die_temp); delta_uv = rbatt_mohm * current_ma; pr_debug("PON OCV changed from %d to %d pc=%d rbatt=%d current_ma=%d die_temp=%d batt_temp=%d delta_uv=%d\n", chip->last_ocv_uv, chip->last_ocv_uv + delta_uv, pc, rbatt_mohm, current_ma, die_temp, batt_temp, delta_uv); chip->last_ocv_uv += delta_uv; } } static int calculate_initial_soc(struct qpnp_bms_chip *chip) { int rc, batt_temp = 0, est_ocv = 0; rc = get_batt_therm(chip, &batt_temp); if (rc < 0) { pr_err("Unable to read batt temp, using default=%d\n", BMS_DEFAULT_TEMP); batt_temp = BMS_DEFAULT_TEMP; } rc = read_and_update_ocv(chip, batt_temp, true); if (rc) { pr_err("Unable to read PON OCV rc=%d\n", rc); return rc; } rc = read_shutdown_ocv_soc(chip); if (rc < 0 || chip->dt.cfg_ignore_shutdown_soc) chip->shutdown_soc_invalid = true; if (chip->warm_reset) { /* * if we have powered on from warm reset - * Always use shutdown SOC. If shudown SOC is invalid then * estimate OCV */ if (chip->shutdown_soc_invalid) { pr_debug("Estimate OCV\n"); est_ocv = estimate_ocv(chip); if (est_ocv <= 0) { pr_err("Unable to estimate OCV rc=%d\n", est_ocv); return -EINVAL; } chip->last_ocv_uv = est_ocv; chip->calculated_soc = lookup_soc_ocv(chip, est_ocv, batt_temp); } else { chip->last_ocv_uv = chip->shutdown_ocv; chip->last_soc = chip->shutdown_soc; chip->calculated_soc = lookup_soc_ocv(chip, chip->shutdown_ocv, batt_temp); pr_debug("Using shutdown SOC\n"); } } else { /* * In PM8916 2.0 PON OCV calculation is delayed due to * change in the ordering of power-on sequence of LDO6. * Adjust PON OCV to include current during PON. */ if (chip->workaround_flag & WRKARND_PON_OCV_COMP) adjust_pon_ocv(chip, batt_temp); /* !warm_reset use PON OCV only if shutdown SOC is invalid */ chip->calculated_soc = lookup_soc_ocv(chip, chip->last_ocv_uv, batt_temp); if (!chip->shutdown_soc_invalid && (abs(chip->shutdown_soc - chip->calculated_soc) < chip->dt.cfg_shutdown_soc_valid_limit)) { chip->last_ocv_uv = chip->shutdown_ocv; chip->last_soc = chip->shutdown_soc; chip->calculated_soc = lookup_soc_ocv(chip, chip->shutdown_ocv, batt_temp); pr_debug("Using shutdown SOC\n"); } else { chip->shutdown_soc_invalid = true; pr_debug("Using PON SOC\n"); } } /* store the start-up OCV for voltage-based-soc */ chip->voltage_soc_uv = chip->last_ocv_uv; pr_info("warm_reset=%d est_ocv=%d shutdown_soc_invalid=%d shutdown_ocv=%d shutdown_soc=%d last_soc=%d calculated_soc=%d last_ocv_uv=%d\n", chip->warm_reset, est_ocv, chip->shutdown_soc_invalid, chip->shutdown_ocv, chip->shutdown_soc, chip->last_soc, chip->calculated_soc, chip->last_ocv_uv); return 0; } static int calculate_initial_aging_comp(struct qpnp_bms_chip *chip) { int rc; bool battery_removed = is_battery_replaced_in_offmode(chip); if (battery_removed || chip->shutdown_soc_invalid) { pr_info("Clearing aging data battery_removed=%d shutdown_soc_invalid=%d\n", battery_removed, chip->shutdown_soc_invalid); chip->charge_cycles = 0; chip->charge_increase = 0; rc = backup_charge_cycle(chip); if (rc) pr_err("Unable to reset aging data rc=%d\n", rc); } else { rc = read_chgcycle_data_from_backup(chip); if (rc) pr_err("Unable to read aging data rc=%d\n", rc); } pr_debug("Initial aging data charge_cycles=%u charge_increase=%u\n", chip->charge_cycles, chip->charge_increase); return rc; } static int bms_load_hw_defaults(struct qpnp_bms_chip *chip) { u8 val, state, bms_en = 0; u32 interval[2], count[2], fifo[2]; int rc; /* S3 OCV tolerence threshold */ if (chip->dt.cfg_s3_ocv_tol_uv >= 0 && chip->dt.cfg_s3_ocv_tol_uv <= MAX_OCV_TOL_THRESHOLD) { val = chip->dt.cfg_s3_ocv_tol_uv / OCV_TOL_LSB_UV; rc = qpnp_masked_write_base(chip, chip->base + S3_OCV_TOL_CTL_REG, 0xFF, val); if (rc) { pr_err("Unable to write s3_ocv_tol_threshold rc=%d\n", rc); return rc; } } /* S1 accumulator threshold */ if (chip->dt.cfg_s1_sample_count >= 1 && chip->dt.cfg_s1_sample_count <= MAX_SAMPLE_COUNT) { val = (chip->dt.cfg_s1_sample_count > 1) ? (ilog2(chip->dt.cfg_s1_sample_count) - 1) : 0; rc = qpnp_masked_write_base(chip, chip->base + S1_ACC_CNT_REG, ACC_CNT_MASK, val); if (rc) { pr_err("Unable to write s1 sample count rc=%d\n", rc); return rc; } } /* S2 accumulator threshold */ if (chip->dt.cfg_s2_sample_count >= 1 && chip->dt.cfg_s2_sample_count <= MAX_SAMPLE_COUNT) { val = (chip->dt.cfg_s2_sample_count > 1) ? (ilog2(chip->dt.cfg_s2_sample_count) - 1) : 0; rc = qpnp_masked_write_base(chip, chip->base + S2_ACC_CNT_REG, ACC_CNT_MASK, val); if (rc) { pr_err("Unable to write s2 sample count rc=%d\n", rc); return rc; } } if (chip->dt.cfg_s1_sample_interval_ms >= 0 && chip->dt.cfg_s1_sample_interval_ms <= MAX_SAMPLE_INTERVAL) { val = chip->dt.cfg_s1_sample_interval_ms / 10; rc = qpnp_write_wrapper(chip, &val, chip->base + S1_SAMPLE_INTVL_REG, 1); if (rc) { pr_err("Unable to write s1 sample inteval rc=%d\n", rc); return rc; } } if (chip->dt.cfg_s2_sample_interval_ms >= 0 && chip->dt.cfg_s2_sample_interval_ms <= MAX_SAMPLE_INTERVAL) { val = chip->dt.cfg_s2_sample_interval_ms / 10; rc = qpnp_write_wrapper(chip, &val, chip->base + S2_SAMPLE_INTVL_REG, 1); if (rc) { pr_err("Unable to write s2 sample inteval rc=%d\n", rc); return rc; } } if (chip->dt.cfg_s1_fifo_length >= 0 && chip->dt.cfg_s1_fifo_length <= MAX_FIFO_REGS) { rc = qpnp_masked_write_base(chip, chip->base + FIFO_LENGTH_REG, S1_FIFO_LENGTH_MASK, chip->dt.cfg_s1_fifo_length); if (rc) { pr_err("Unable to write s1 fifo length rc=%d\n", rc); return rc; } } if (chip->dt.cfg_s2_fifo_length >= 0 && chip->dt.cfg_s2_fifo_length <= MAX_FIFO_REGS) { rc = qpnp_masked_write_base(chip, chip->base + FIFO_LENGTH_REG, S2_FIFO_LENGTH_MASK, chip->dt.cfg_s2_fifo_length << S2_FIFO_LENGTH_SHIFT); if (rc) { pr_err("Unable to write s2 fifo length rc=%d\n", rc); return rc; } } get_sample_interval(chip, S1_STATE, &interval[0]); get_sample_interval(chip, S2_STATE, &interval[1]); get_sample_count(chip, S1_STATE, &count[0]); get_sample_count(chip, S2_STATE, &count[1]); get_fifo_length(chip, S1_STATE, &fifo[0]); get_fifo_length(chip, S2_STATE, &fifo[1]); /* Force the BMS state to S2 at boot-up */ rc = get_fsm_state(chip, &state); if (rc) pr_err("Unable to get FSM state rc=%d\n", rc); if (rc || (state != S2_STATE)) { pr_debug("Forcing S2 state\n"); rc = force_fsm_state(chip, S2_STATE); if (rc) pr_err("Unable to set FSM state rc=%d\n", rc); } rc = qpnp_read_wrapper(chip, &bms_en, chip->base + EN_CTL_REG, 1); if (rc) { pr_err("Unable to read BMS_EN state rc=%d\n", rc); return rc; } rc = update_fsm_state(chip); if (rc) { pr_err("Unable to read FSM state rc=%d\n", rc); return rc; } pr_info("BMS_EN=%d Sample_Interval-S1=[%d]S2=[%d] Sample_Count-S1=[%d]S2=[%d] Fifo_Length-S1=[%d]S2=[%d] FSM_state=%d\n", !!bms_en, interval[0], interval[1], count[0], count[1], fifo[0], fifo[1], chip->current_fsm_state); return 0; } static ssize_t vm_bms_read(struct file *file, char __user *buf, size_t count, loff_t *ppos) { int rc; struct qpnp_bms_chip *chip = file->private_data; if (!chip->data_ready && (file->f_flags & O_NONBLOCK)) { rc = -EAGAIN; goto fail_read; } rc = wait_event_interruptible(chip->bms_wait_q, chip->data_ready); if (rc) { pr_debug("wait failed! rc=%d\n", rc); goto fail_read; } if (!chip->data_ready) { pr_debug("No Data, false wakeup\n"); rc = -EFAULT; goto fail_read; } mutex_lock(&chip->bms_data_mutex); if (copy_to_user(buf, &chip->bms_data, sizeof(chip->bms_data))) { pr_err("Failed in copy_to_user\n"); mutex_unlock(&chip->bms_data_mutex); rc = -EFAULT; goto fail_read; } pr_debug("Data copied!!\n"); chip->data_ready = 0; mutex_unlock(&chip->bms_data_mutex); /* wakelock-timeout for userspace to pick up */ pm_wakeup_event(chip->dev, BMS_READ_TIMEOUT); return sizeof(chip->bms_data); fail_read: pm_relax(chip->dev); return rc; } static int vm_bms_open(struct inode *inode, struct file *file) { struct qpnp_bms_chip *chip = container_of(inode->i_cdev, struct qpnp_bms_chip, bms_cdev); mutex_lock(&chip->bms_device_mutex); if (chip->bms_dev_open) { pr_debug("BMS device already open\n"); mutex_unlock(&chip->bms_device_mutex); return -EBUSY; } chip->bms_dev_open = true; file->private_data = chip; pr_debug("BMS device opened\n"); mutex_unlock(&chip->bms_device_mutex); return 0; } static int vm_bms_release(struct inode *inode, struct file *file) { struct qpnp_bms_chip *chip = container_of(inode->i_cdev, struct qpnp_bms_chip, bms_cdev); mutex_lock(&chip->bms_device_mutex); chip->bms_dev_open = false; pm_relax(chip->dev); pr_debug("BMS device closed\n"); mutex_unlock(&chip->bms_device_mutex); return 0; } static const struct file_operations bms_fops = { .owner = THIS_MODULE, .open = vm_bms_open, .read = vm_bms_read, .release = vm_bms_release, }; static void bms_init_defaults(struct qpnp_bms_chip *chip) { chip->data_ready = 0; chip->last_ocv_raw = OCV_UNINITIALIZED; chip->battery_status = POWER_SUPPLY_STATUS_UNKNOWN; chip->battery_present = -EINVAL; chip->calculated_soc = -EINVAL; chip->last_soc = -EINVAL; chip->vbms_lv_wake_source.disabled = 1; chip->vbms_cv_wake_source.disabled = 1; chip->vbms_soc_wake_source.disabled = 1; chip->ocv_at_100 = -EINVAL; chip->prev_soc_uuc = -EINVAL; chip->charge_cycles = 0; chip->start_soc = 0; chip->end_soc = 0; chip->charge_increase = 0; } #define SPMI_REQUEST_IRQ(chip, rc, irq_name) \ do { \ rc = devm_request_threaded_irq(chip->dev, \ chip->irq_name##_irq.irq, NULL, \ bms_##irq_name##_irq_handler, \ IRQF_TRIGGER_RISING | IRQF_ONESHOT, \ #irq_name, chip); \ if (rc < 0) \ pr_err("Unable to request " #irq_name " irq: %d\n", rc);\ } while (0) #define SPMI_FIND_IRQ(chip, irq_name, rc) \ do { \ chip->irq_name##_irq.irq = spmi_get_irq_byname(chip->spmi, \ resource, #irq_name); \ if (chip->irq_name##_irq.irq < 0) { \ rc = chip->irq_name##_irq.irq; \ pr_err("Unable to get " #irq_name " irq rc=%d\n", rc); \ } \ } while (0) static int bms_request_irqs(struct qpnp_bms_chip *chip) { int rc; SPMI_REQUEST_IRQ(chip, rc, fifo_update_done); if (rc < 0) return rc; SPMI_REQUEST_IRQ(chip, rc, fsm_state_change); if (rc < 0) return rc; /* Disable the state change IRQ */ disable_bms_irq(&chip->fsm_state_change_irq); enable_irq_wake(chip->fifo_update_done_irq.irq); return 0; } static int bms_find_irqs(struct qpnp_bms_chip *chip, struct spmi_resource *resource) { int rc = 0; SPMI_FIND_IRQ(chip, fifo_update_done, rc); if (rc < 0) return rc; SPMI_FIND_IRQ(chip, fsm_state_change, rc); if (rc < 0) return rc; return 0; } static int64_t read_battery_id(struct qpnp_bms_chip *chip) { int rc; struct qpnp_vadc_result result; rc = qpnp_vadc_read(chip->vadc_dev, LR_MUX2_BAT_ID, &result); if (rc) { pr_err("error reading batt id channel = %d, rc = %d\n", LR_MUX2_BAT_ID, rc); return rc; } return result.physical; } static int show_bms_config(struct seq_file *m, void *data) { struct qpnp_bms_chip *chip = m->private; int s1_sample_interval, s2_sample_interval; int s1_sample_count, s2_sample_count; int s1_fifo_length, s2_fifo_length; get_sample_interval(chip, S1_STATE, &s1_sample_interval); get_sample_interval(chip, S2_STATE, &s2_sample_interval); get_sample_count(chip, S1_STATE, &s1_sample_count); get_sample_count(chip, S2_STATE, &s2_sample_count); get_fifo_length(chip, S1_STATE, &s1_fifo_length); get_fifo_length(chip, S2_STATE, &s2_fifo_length); seq_printf(m, "r_conn_mohm\t=\t%d\n" "v_cutoff_uv\t=\t%d\n" "max_voltage_uv\t=\t%d\n" "use_voltage_soc\t=\t%d\n" "low_soc_calc_threshold\t=\t%d\n" "low_soc_calculate_soc_ms\t=\t%d\n" "low_voltage_threshold\t=\t%d\n" "low_voltage_calculate_soc_ms\t=\t%d\n" "calculate_soc_ms\t=\t%d\n" "voltage_soc_timeout_ms\t=\t%d\n" "ignore_shutdown_soc\t=\t%d\n" "shutdown_soc_valid_limit\t=\t%d\n" "force_s3_on_suspend\t=\t%d\n" "report_charger_eoc\t=\t%d\n" "aging_compensation\t=\t%d\n" "use_reported_soc\t=\t%d\n" "s1_sample_interval_ms\t=\t%d\n" "s2_sample_interval_ms\t=\t%d\n" "s1_sample_count\t=\t%d\n" "s2_sample_count\t=\t%d\n" "s1_fifo_length\t=\t%d\n" "s2_fifo_length\t=\t%d\n", chip->dt.cfg_r_conn_mohm, chip->dt.cfg_v_cutoff_uv, chip->dt.cfg_max_voltage_uv, chip->dt.cfg_use_voltage_soc, chip->dt.cfg_low_soc_calc_threshold, chip->dt.cfg_low_soc_calculate_soc_ms, chip->dt.cfg_low_voltage_threshold, chip->dt.cfg_low_voltage_calculate_soc_ms, chip->dt.cfg_calculate_soc_ms, chip->dt.cfg_voltage_soc_timeout_ms, chip->dt.cfg_ignore_shutdown_soc, chip->dt.cfg_shutdown_soc_valid_limit, chip->dt.cfg_force_s3_on_suspend, chip->dt.cfg_report_charger_eoc, chip->dt.cfg_battery_aging_comp, chip->dt.cfg_use_reported_soc, s1_sample_interval, s2_sample_interval, s1_sample_count, s2_sample_count, s1_fifo_length, s2_fifo_length); return 0; } static int bms_config_open(struct inode *inode, struct file *file) { struct qpnp_bms_chip *chip = inode->i_private; return single_open(file, show_bms_config, chip); } static const struct file_operations bms_config_debugfs_ops = { .owner = THIS_MODULE, .open = bms_config_open, .read = seq_read, .llseek = seq_lseek, .release = single_release, }; static int show_bms_status(struct seq_file *m, void *data) { struct qpnp_bms_chip *chip = m->private; seq_printf(m, "bms_psy_registered\t=\t%d\n" "bms_dev_open\t=\t%d\n" "warm_reset\t=\t%d\n" "battery_status\t=\t%d\n" "battery_present\t=\t%d\n" "in_cv_state\t=\t%d\n" "calculated_soc\t=\t%d\n" "last_soc\t=\t%d\n" "last_ocv_uv\t=\t%d\n" "last_ocv_raw\t=\t%d\n" "last_soc_unbound\t=\t%d\n" "current_fsm_state\t=\t%d\n" "current_now\t=\t%d\n" "ocv_at_100\t=\t%d\n" "low_voltage_ws_active\t=\t%d\n" "cv_ws_active\t=\t%d\n", chip->bms_psy_registered, chip->bms_dev_open, chip->warm_reset, chip->battery_status, chip->battery_present, chip->in_cv_state, chip->calculated_soc, chip->last_soc, chip->last_ocv_uv, chip->last_ocv_raw, chip->last_soc_unbound, chip->current_fsm_state, chip->current_now, chip->ocv_at_100, bms_wake_active(&chip->vbms_lv_wake_source), bms_wake_active(&chip->vbms_cv_wake_source)); return 0; } static int bms_status_open(struct inode *inode, struct file *file) { struct qpnp_bms_chip *chip = inode->i_private; return single_open(file, show_bms_status, chip); } static const struct file_operations bms_status_debugfs_ops = { .owner = THIS_MODULE, .open = bms_status_open, .read = seq_read, .llseek = seq_lseek, .release = single_release, }; static int show_bms_data(struct seq_file *m, void *data) { struct qpnp_bms_chip *chip = m->private; int i; mutex_lock(&chip->bms_data_mutex); seq_printf(m, "seq_num=%d\n", chip->bms_data.seq_num); for (i = 0; i < chip->bms_data.num_fifo; i++) seq_printf(m, "fifo_uv[%d]=%d sample_count=%d interval_ms=%d\n", i, chip->bms_data.fifo_uv[i], chip->bms_data.sample_count, chip->bms_data.sample_interval_ms); seq_printf(m, "acc_uv=%d sample_count=%d sample_interval=%d\n", chip->bms_data.acc_uv, chip->bms_data.acc_count, chip->bms_data.sample_interval_ms); mutex_unlock(&chip->bms_data_mutex); return 0; } static int bms_data_open(struct inode *inode, struct file *file) { struct qpnp_bms_chip *chip = inode->i_private; return single_open(file, show_bms_data, chip); } static const struct file_operations bms_data_debugfs_ops = { .owner = THIS_MODULE, .open = bms_data_open, .read = seq_read, .llseek = seq_lseek, .release = single_release, }; static int set_battery_data(struct qpnp_bms_chip *chip) { int64_t battery_id; int rc = 0; struct bms_battery_data *batt_data; struct device_node *node; battery_id = read_battery_id(chip); if (battery_id < 0) { pr_err("cannot read battery id err = %lld\n", battery_id); return battery_id; } node = of_find_node_by_name(chip->spmi->dev.of_node, "qcom,battery-data"); if (!node) { pr_err("No available batterydata\n"); return -EINVAL; } batt_data = devm_kzalloc(chip->dev, sizeof(struct bms_battery_data), GFP_KERNEL); if (!batt_data) { pr_err("Could not alloc battery data\n"); return -EINVAL; } batt_data->fcc_temp_lut = devm_kzalloc(chip->dev, sizeof(struct single_row_lut), GFP_KERNEL); batt_data->pc_temp_ocv_lut = devm_kzalloc(chip->dev, sizeof(struct pc_temp_ocv_lut), GFP_KERNEL); batt_data->rbatt_sf_lut = devm_kzalloc(chip->dev, sizeof(struct sf_lut), GFP_KERNEL); batt_data->ibat_acc_lut = devm_kzalloc(chip->dev, sizeof(struct ibat_temp_acc_lut), GFP_KERNEL); batt_data->max_voltage_uv = -1; batt_data->cutoff_uv = -1; batt_data->iterm_ua = -1; /* * if the alloced luts are 0s, of_batterydata_read_data ignores * them. */ rc = of_batterydata_read_data(node, batt_data, battery_id); if (rc || !batt_data->pc_temp_ocv_lut || !batt_data->fcc_temp_lut || !batt_data->rbatt_sf_lut) { pr_err("battery data load failed\n"); devm_kfree(chip->dev, batt_data->fcc_temp_lut); devm_kfree(chip->dev, batt_data->pc_temp_ocv_lut); devm_kfree(chip->dev, batt_data->rbatt_sf_lut); devm_kfree(chip->dev, batt_data->ibat_acc_lut); devm_kfree(chip->dev, batt_data); return rc; } if (batt_data->pc_temp_ocv_lut == NULL) { pr_err("temp ocv lut table has not been loaded\n"); devm_kfree(chip->dev, batt_data->fcc_temp_lut); devm_kfree(chip->dev, batt_data->pc_temp_ocv_lut); devm_kfree(chip->dev, batt_data->rbatt_sf_lut); devm_kfree(chip->dev, batt_data->ibat_acc_lut); devm_kfree(chip->dev, batt_data); return -EINVAL; } /* check if ibat_acc_lut is valid */ if (!batt_data->ibat_acc_lut->rows) { pr_info("ibat_acc_lut not present\n"); devm_kfree(chip->dev, batt_data->ibat_acc_lut); batt_data->ibat_acc_lut = NULL; } /* Override battery properties if specified in the battery profile */ if (batt_data->max_voltage_uv >= 0) chip->dt.cfg_max_voltage_uv = batt_data->max_voltage_uv; if (batt_data->cutoff_uv >= 0) chip->dt.cfg_v_cutoff_uv = batt_data->cutoff_uv; chip->batt_data = batt_data; return 0; } static int parse_spmi_dt_properties(struct qpnp_bms_chip *chip, struct spmi_device *spmi) { struct spmi_resource *spmi_resource; struct resource *resource; int rc; chip->dev = &(spmi->dev); chip->spmi = spmi; spmi_for_each_container_dev(spmi_resource, spmi) { if (!spmi_resource) { pr_err("qpnp_vm_bms: spmi resource absent\n"); return -ENXIO; } resource = spmi_get_resource(spmi, spmi_resource, IORESOURCE_MEM, 0); if (!(resource && resource->start)) { pr_err("node %s IO resource absent!\n", spmi->dev.of_node->full_name); return -ENXIO; } pr_debug("Node name = %s\n", spmi_resource->of_node->name); if (strcmp("qcom,batt-pres-status", spmi_resource->of_node->name) == 0) { chip->batt_pres_addr = resource->start; continue; } if (strcmp("qcom,qpnp-chg-pres", spmi_resource->of_node->name) == 0) { chip->chg_pres_addr = resource->start; continue; } chip->base = resource->start; rc = bms_find_irqs(chip, spmi_resource); if (rc) { pr_err("Could not find irqs rc=%d\n", rc); return rc; } } if (chip->base == 0) { dev_err(&spmi->dev, "BMS peripheral was not registered\n"); return -EINVAL; } pr_debug("bms-base=0x%04x bat-pres-reg=0x%04x qpnp-chg-pres=0x%04x\n", chip->base, chip->batt_pres_addr, chip->chg_pres_addr); return 0; } #define SPMI_PROP_READ(chip_prop, qpnp_spmi_property, retval) \ do { \ if (retval) \ break; \ retval = of_property_read_u32(chip->spmi->dev.of_node, \ "qcom," qpnp_spmi_property, \ &chip->dt.chip_prop); \ if (retval) { \ pr_err("Error reading " #qpnp_spmi_property \ " property %d\n", retval); \ } \ } while (0) #define SPMI_PROP_READ_OPTIONAL(chip_prop, qpnp_spmi_property, retval) \ do { \ retval = of_property_read_u32(chip->spmi->dev.of_node, \ "qcom," qpnp_spmi_property, \ &chip->dt.chip_prop); \ if (retval) \ chip->dt.chip_prop = -EINVAL; \ } while (0) static int parse_bms_dt_properties(struct qpnp_bms_chip *chip) { int rc = 0; SPMI_PROP_READ(cfg_v_cutoff_uv, "v-cutoff-uv", rc); SPMI_PROP_READ(cfg_max_voltage_uv, "max-voltage-uv", rc); SPMI_PROP_READ(cfg_r_conn_mohm, "r-conn-mohm", rc); SPMI_PROP_READ(cfg_shutdown_soc_valid_limit, "shutdown-soc-valid-limit", rc); SPMI_PROP_READ(cfg_low_soc_calc_threshold, "low-soc-calculate-soc-threshold", rc); SPMI_PROP_READ(cfg_low_soc_calculate_soc_ms, "low-soc-calculate-soc-ms", rc); SPMI_PROP_READ(cfg_low_voltage_calculate_soc_ms, "low-voltage-calculate-soc-ms", rc); SPMI_PROP_READ(cfg_calculate_soc_ms, "calculate-soc-ms", rc); SPMI_PROP_READ(cfg_low_voltage_threshold, "low-voltage-threshold", rc); SPMI_PROP_READ(cfg_voltage_soc_timeout_ms, "volatge-soc-timeout-ms", rc); if (rc) { pr_err("Missing required properties rc=%d\n", rc); return rc; } SPMI_PROP_READ_OPTIONAL(cfg_s1_sample_interval_ms, "s1-sample-interval-ms", rc); SPMI_PROP_READ_OPTIONAL(cfg_s2_sample_interval_ms, "s2-sample-interval-ms", rc); SPMI_PROP_READ_OPTIONAL(cfg_s1_sample_count, "s1-sample-count", rc); SPMI_PROP_READ_OPTIONAL(cfg_s2_sample_count, "s2-sample-count", rc); SPMI_PROP_READ_OPTIONAL(cfg_s1_fifo_length, "s1-fifo-length", rc); SPMI_PROP_READ_OPTIONAL(cfg_s2_fifo_length, "s2-fifo-length", rc); SPMI_PROP_READ_OPTIONAL(cfg_s3_ocv_tol_uv, "s3-ocv-tolerence-uv", rc); SPMI_PROP_READ_OPTIONAL(cfg_low_soc_fifo_length, "low-soc-fifo-length", rc); SPMI_PROP_READ_OPTIONAL(cfg_soc_resume_limit, "resume-soc", rc); SPMI_PROP_READ_OPTIONAL(cfg_low_temp_threshold, "low-temp-threshold", rc); if (rc) chip->dt.cfg_low_temp_threshold = 0; SPMI_PROP_READ_OPTIONAL(cfg_ibat_avg_samples, "ibat-avg-samples", rc); if (rc || (chip->dt.cfg_ibat_avg_samples <= 0) || (chip->dt.cfg_ibat_avg_samples > IAVG_SAMPLES)) chip->dt.cfg_ibat_avg_samples = IAVG_SAMPLES; chip->dt.cfg_ignore_shutdown_soc = of_property_read_bool( chip->spmi->dev.of_node, "qcom,ignore-shutdown-soc"); chip->dt.cfg_use_voltage_soc = of_property_read_bool( chip->spmi->dev.of_node, "qcom,use-voltage-soc"); chip->dt.cfg_force_s3_on_suspend = of_property_read_bool( chip->spmi->dev.of_node, "qcom,force-s3-on-suspend"); chip->dt.cfg_report_charger_eoc = of_property_read_bool( chip->spmi->dev.of_node, "qcom,report-charger-eoc"); chip->dt.cfg_disable_bms = of_property_read_bool( chip->spmi->dev.of_node, "qcom,disable-bms"); chip->dt.cfg_force_bms_active_on_charger = of_property_read_bool( chip->spmi->dev.of_node, "qcom,force-bms-active-on-charger"); chip->dt.cfg_battery_aging_comp = of_property_read_bool( chip->spmi->dev.of_node, "qcom,batt-aging-comp"); chip->dt.cfg_use_reported_soc = of_property_read_bool( chip->spmi->dev.of_node, "qcom,use-reported-soc"); pr_debug("v_cutoff_uv=%d, max_v=%d\n", chip->dt.cfg_v_cutoff_uv, chip->dt.cfg_max_voltage_uv); pr_debug("r_conn=%d shutdown_soc_valid_limit=%d low_temp_threshold=%d ibat_avg_samples=%d\n", chip->dt.cfg_r_conn_mohm, chip->dt.cfg_shutdown_soc_valid_limit, chip->dt.cfg_low_temp_threshold, chip->dt.cfg_ibat_avg_samples); pr_debug("ignore_shutdown_soc=%d, use_voltage_soc=%d low_soc_fifo_length=%d\n", chip->dt.cfg_ignore_shutdown_soc, chip->dt.cfg_use_voltage_soc, chip->dt.cfg_low_soc_fifo_length); pr_debug("force-s3-on-suspend=%d report-charger-eoc=%d disable-bms=%d disable-suspend-on-usb=%d aging_compensation=%d\n", chip->dt.cfg_force_s3_on_suspend, chip->dt.cfg_report_charger_eoc, chip->dt.cfg_disable_bms, chip->dt.cfg_force_bms_active_on_charger, chip->dt.cfg_battery_aging_comp); pr_debug("use-reported-soc is %d\n", chip->dt.cfg_use_reported_soc); return 0; } static int bms_get_adc(struct qpnp_bms_chip *chip, struct spmi_device *spmi) { int rc = 0; chip->vadc_dev = qpnp_get_vadc(&spmi->dev, "bms"); if (IS_ERR(chip->vadc_dev)) { rc = PTR_ERR(chip->vadc_dev); if (rc == -EPROBE_DEFER) pr_err("vadc not found - defer probe rc=%d\n", rc); else pr_err("vadc property missing, rc=%d\n", rc); return rc; } chip->adc_tm_dev = qpnp_get_adc_tm(&spmi->dev, "bms"); if (IS_ERR(chip->adc_tm_dev)) { rc = PTR_ERR(chip->adc_tm_dev); if (rc == -EPROBE_DEFER) pr_err("adc-tm not found - defer probe rc=%d\n", rc); else pr_err("adc-tm property missing, rc=%d\n", rc); } return rc; } static int register_bms_char_device(struct qpnp_bms_chip *chip) { int rc; rc = alloc_chrdev_region(&chip->dev_no, 0, 1, "vm_bms"); if (rc) { pr_err("Unable to allocate chrdev rc=%d\n", rc); return rc; } cdev_init(&chip->bms_cdev, &bms_fops); rc = cdev_add(&chip->bms_cdev, chip->dev_no, 1); if (rc) { pr_err("Unable to add bms_cdev rc=%d\n", rc); goto unregister_chrdev; } chip->bms_class = class_create(THIS_MODULE, "vm_bms"); if (IS_ERR_OR_NULL(chip->bms_class)) { pr_err("Fail to create bms class\n"); rc = -EINVAL; goto delete_cdev; } chip->bms_device = device_create(chip->bms_class, NULL, chip->dev_no, NULL, "vm_bms"); if (IS_ERR(chip->bms_device)) { pr_err("Fail to create bms_device device\n"); rc = -EINVAL; goto delete_cdev; } return 0; delete_cdev: cdev_del(&chip->bms_cdev); unregister_chrdev: unregister_chrdev_region(chip->dev_no, 1); return rc; } static int qpnp_vm_bms_probe(struct spmi_device *spmi) { struct qpnp_bms_chip *chip; struct device_node *revid_dev_node; int rc, vbatt = 0; chip = devm_kzalloc(&spmi->dev, sizeof(*chip), GFP_KERNEL); if (!chip) { pr_err("kzalloc() failed.\n"); return -ENOMEM; } rc = bms_get_adc(chip, spmi); if (rc < 0) { pr_err("Failed to get adc rc=%d\n", rc); return rc; } revid_dev_node = of_parse_phandle(spmi->dev.of_node, "qcom,pmic-revid", 0); if (!revid_dev_node) { pr_err("Missing qcom,pmic-revid property\n"); return -EINVAL; } chip->revid_data = get_revid_data(revid_dev_node); if (IS_ERR(chip->revid_data)) { pr_err("revid error rc = %ld\n", PTR_ERR(chip->revid_data)); return -EINVAL; } if ((chip->revid_data->pmic_subtype == PM8916_V2P0_SUBTYPE) && chip->revid_data->rev4 == PM8916_V2P0_REV4) chip->workaround_flag |= WRKARND_PON_OCV_COMP; rc = qpnp_pon_is_warm_reset(); if (rc < 0) { pr_err("Error reading warm reset status rc=%d\n", rc); return rc; } chip->warm_reset = !!rc; rc = parse_spmi_dt_properties(chip, spmi); if (rc) { pr_err("Error registering spmi resource rc=%d\n", rc); return rc; } rc = parse_bms_dt_properties(chip); if (rc) { pr_err("Unable to read all bms properties, rc = %d\n", rc); return rc; } if (chip->dt.cfg_disable_bms) { pr_info("VMBMS disabled (disable-bms = 1)\n"); rc = qpnp_masked_write_base(chip, chip->base + EN_CTL_REG, BMS_EN_BIT, 0); if (rc) pr_err("Unable to disable VMBMS rc=%d\n", rc); return -ENODEV; } rc = qpnp_read_wrapper(chip, chip->revision, chip->base + REVISION1_REG, 2); if (rc) { pr_err("Error reading version register rc=%d\n", rc); return rc; } pr_debug("BMS version: %hhu.%hhu\n", chip->revision[1], chip->revision[0]); dev_set_drvdata(&spmi->dev, chip); device_init_wakeup(&spmi->dev, 1); mutex_init(&chip->bms_data_mutex); mutex_init(&chip->bms_device_mutex); mutex_init(&chip->last_soc_mutex); mutex_init(&chip->state_change_mutex); init_waitqueue_head(&chip->bms_wait_q); /* read battery-id and select the battery profile */ rc = set_battery_data(chip); if (rc) { pr_err("Unable to read battery data %d\n", rc); goto fail_init; } /* set the battery profile */ rc = config_battery_data(chip->batt_data); if (rc) { pr_err("Unable to config battery data %d\n", rc); goto fail_init; } wakeup_source_init(&chip->vbms_lv_wake_source.source, "vbms_lv_wake"); wakeup_source_init(&chip->vbms_cv_wake_source.source, "vbms_cv_wake"); wakeup_source_init(&chip->vbms_soc_wake_source.source, "vbms_soc_wake"); INIT_DELAYED_WORK(&chip->monitor_soc_work, monitor_soc_work); INIT_DELAYED_WORK(&chip->voltage_soc_timeout_work, voltage_soc_timeout_work); bms_init_defaults(chip); bms_load_hw_defaults(chip); if (is_battery_present(chip)) { rc = setup_vbat_monitoring(chip); if (rc) { pr_err("fail to configure vbat monitoring rc=%d\n", rc); goto fail_setup; } } rc = bms_request_irqs(chip); if (rc) { pr_err("error requesting bms irqs, rc = %d\n", rc); goto fail_irq; } battery_insertion_check(chip); battery_status_check(chip); /* character device to pass data to the userspace */ rc = register_bms_char_device(chip); if (rc) { pr_err("Unable to regiter '/dev/vm_bms' rc=%d\n", rc); goto fail_bms_device; } the_chip = chip; calculate_initial_soc(chip); if (chip->dt.cfg_battery_aging_comp) { rc = calculate_initial_aging_comp(chip); if (rc) pr_err("Unable to calculate initial aging data rc=%d\n", rc); } /* setup & register the battery power supply */ chip->bms_psy.name = "bms"; chip->bms_psy.type = POWER_SUPPLY_TYPE_BMS; chip->bms_psy.properties = bms_power_props; chip->bms_psy.num_properties = ARRAY_SIZE(bms_power_props); chip->bms_psy.get_property = qpnp_vm_bms_power_get_property; chip->bms_psy.set_property = qpnp_vm_bms_power_set_property; chip->bms_psy.external_power_changed = qpnp_vm_bms_ext_power_changed; chip->bms_psy.property_is_writeable = qpnp_vm_bms_property_is_writeable; chip->bms_psy.supplied_to = qpnp_vm_bms_supplicants; chip->bms_psy.num_supplicants = ARRAY_SIZE(qpnp_vm_bms_supplicants); rc = power_supply_register(chip->dev, &chip->bms_psy); if (rc < 0) { pr_err("power_supply_register bms failed rc = %d\n", rc); goto fail_psy; } chip->bms_psy_registered = true; rc = get_battery_voltage(chip, &vbatt); if (rc) { pr_err("error reading vbat_sns adc channel=%d, rc=%d\n", VBAT_SNS, rc); goto fail_get_vtg; } chip->debug_root = debugfs_create_dir("qpnp_vmbms", NULL); if (!chip->debug_root) pr_err("Couldn't create debug dir\n"); if (chip->debug_root) { struct dentry *ent; ent = debugfs_create_file("bms_data", S_IFREG | S_IRUGO, chip->debug_root, chip, &bms_data_debugfs_ops); if (!ent) pr_err("Couldn't create bms_data debug file\n"); ent = debugfs_create_file("bms_config", S_IFREG | S_IRUGO, chip->debug_root, chip, &bms_config_debugfs_ops); if (!ent) pr_err("Couldn't create bms_config debug file\n"); ent = debugfs_create_file("bms_status", S_IFREG | S_IRUGO, chip->debug_root, chip, &bms_status_debugfs_ops); if (!ent) pr_err("Couldn't create bms_status debug file\n"); } schedule_delayed_work(&chip->monitor_soc_work, 0); /* * schedule a work to check if the userspace vmbms module * has registered. Fall-back to voltage-based-soc reporting * if it has not. */ schedule_delayed_work(&chip->voltage_soc_timeout_work, msecs_to_jiffies(chip->dt.cfg_voltage_soc_timeout_ms)); pr_info("probe success: soc=%d vbatt=%d ocv=%d warm_reset=%d\n", get_prop_bms_capacity(chip), vbatt, chip->last_ocv_uv, chip->warm_reset); return rc; fail_get_vtg: power_supply_unregister(&chip->bms_psy); fail_psy: device_destroy(chip->bms_class, chip->dev_no); cdev_del(&chip->bms_cdev); unregister_chrdev_region(chip->dev_no, 1); fail_bms_device: chip->bms_psy_registered = false; fail_irq: reset_vbat_monitoring(chip); fail_setup: wakeup_source_trash(&chip->vbms_lv_wake_source.source); wakeup_source_trash(&chip->vbms_cv_wake_source.source); wakeup_source_trash(&chip->vbms_soc_wake_source.source); fail_init: mutex_destroy(&chip->bms_data_mutex); mutex_destroy(&chip->last_soc_mutex); mutex_destroy(&chip->state_change_mutex); mutex_destroy(&chip->bms_device_mutex); the_chip = NULL; return rc; } static int qpnp_vm_bms_remove(struct spmi_device *spmi) { struct qpnp_bms_chip *chip = dev_get_drvdata(&spmi->dev); cancel_delayed_work_sync(&chip->monitor_soc_work); debugfs_remove_recursive(chip->debug_root); device_destroy(chip->bms_class, chip->dev_no); cdev_del(&chip->bms_cdev); unregister_chrdev_region(chip->dev_no, 1); reset_vbat_monitoring(chip); wakeup_source_trash(&chip->vbms_lv_wake_source.source); wakeup_source_trash(&chip->vbms_cv_wake_source.source); wakeup_source_trash(&chip->vbms_soc_wake_source.source); mutex_destroy(&chip->bms_data_mutex); mutex_destroy(&chip->last_soc_mutex); mutex_destroy(&chip->state_change_mutex); mutex_destroy(&chip->bms_device_mutex); power_supply_unregister(&chip->bms_psy); dev_set_drvdata(&spmi->dev, NULL); the_chip = NULL; return 0; } static void process_suspend_data(struct qpnp_bms_chip *chip) { int rc; mutex_lock(&chip->bms_data_mutex); chip->suspend_data_valid = false; memset(&chip->bms_data, 0, sizeof(chip->bms_data)); rc = read_and_populate_fifo_data(chip); if (rc) pr_err("Unable to read FIFO data rc=%d\n", rc); rc = read_and_populate_acc_data(chip); if (rc) pr_err("Unable to read ACC_SD data rc=%d\n", rc); rc = clear_fifo_acc_data(chip); if (rc) pr_err("Unable to clear FIFO/ACC data rc=%d\n", rc); if (chip->bms_data.num_fifo || chip->bms_data.acc_count) { pr_debug("suspend data valid\n"); chip->suspend_data_valid = true; } mutex_unlock(&chip->bms_data_mutex); } static void process_resume_data(struct qpnp_bms_chip *chip) { int rc, batt_temp = 0; int old_ocv = 0; bool ocv_updated = false; rc = get_batt_therm(chip, &batt_temp); if (rc < 0) { pr_err("Unable to read batt temp, using default=%d\n", BMS_DEFAULT_TEMP); batt_temp = BMS_DEFAULT_TEMP; } mutex_lock(&chip->bms_data_mutex); /* * We can get a h/w OCV update when the sleep_b * is low, which is possible when APPS is suspended. * So check for an OCV update only in bms_resume */ old_ocv = chip->last_ocv_uv; rc = read_and_update_ocv(chip, batt_temp, false); if (rc) pr_err("Unable to read/upadate OCV rc=%d\n", rc); if (old_ocv != chip->last_ocv_uv) { ocv_updated = true; /* new OCV, clear suspended data */ chip->suspend_data_valid = false; memset(&chip->bms_data, 0, sizeof(chip->bms_data)); chip->calculated_soc = lookup_soc_ocv(chip, chip->last_ocv_uv, batt_temp); pr_debug("OCV in sleep SOC=%d\n", chip->calculated_soc); chip->last_soc_unbound = true; chip->voltage_soc_uv = chip->last_ocv_uv; pr_debug("update bms_psy\n"); power_supply_changed(&chip->bms_psy); } if (ocv_updated || chip->suspend_data_valid) { /* there is data to be sent */ pr_debug("ocv_updated=%d suspend_data_valid=%d\n", ocv_updated, chip->suspend_data_valid); chip->bms_data.seq_num = chip->seq_num++; dump_bms_data(__func__, chip); chip->data_ready = 1; wake_up_interruptible(&chip->bms_wait_q); if (chip->bms_dev_open) pm_stay_awake(chip->dev); } chip->suspend_data_valid = false; mutex_unlock(&chip->bms_data_mutex); } static int bms_suspend(struct device *dev) { struct qpnp_bms_chip *chip = dev_get_drvdata(dev); bool battery_charging = is_battery_charging(chip); bool hi_power_state = is_hi_power_state_requested(chip); bool charger_present = is_charger_present(chip); bool bms_suspend_config; /* * Keep BMS FSM active if 'cfg_force_bms_active_on_charger' property * is present and charger inserted. This ensures that recharge * starts once battery SOC falls below resume_soc. */ bms_suspend_config = chip->dt.cfg_force_bms_active_on_charger && charger_present; chip->apply_suspend_config = false; if (!battery_charging && !hi_power_state && !bms_suspend_config) chip->apply_suspend_config = true; pr_debug("battery_charging=%d power_state=%s hi_power_state=0x%x apply_suspend_config=%d bms_suspend_config=%d usb_present=%d\n", battery_charging, hi_power_state ? "hi" : "low", chip->hi_power_state, chip->apply_suspend_config, bms_suspend_config, charger_present); if (chip->apply_suspend_config) { if (chip->dt.cfg_force_s3_on_suspend) { disable_bms_irq(&chip->fifo_update_done_irq); pr_debug("Forcing S3 state\n"); mutex_lock(&chip->state_change_mutex); force_fsm_state(chip, S3_STATE); mutex_unlock(&chip->state_change_mutex); /* Store accumulated data if any */ process_suspend_data(chip); } } cancel_delayed_work_sync(&chip->monitor_soc_work); return 0; } static int bms_resume(struct device *dev) { u8 state = 0; int rc, monitor_soc_delay = 0; unsigned long tm_now_sec; struct qpnp_bms_chip *chip = dev_get_drvdata(dev); if (chip->apply_suspend_config) { if (chip->dt.cfg_force_s3_on_suspend) { /* * Update the state to S2 only if we are in S3. There is * a possibility of being in S2 if we resumed on * a charger insertion */ mutex_lock(&chip->state_change_mutex); rc = get_fsm_state(chip, &state); if (rc) pr_err("Unable to get FSM state rc=%d\n", rc); if (rc || (state == S3_STATE)) { pr_debug("Unforcing S3 state, setting S2 state\n"); force_fsm_state(chip, S2_STATE); } mutex_unlock(&chip->state_change_mutex); enable_bms_irq(&chip->fifo_update_done_irq); /* * if we were charging while suspended, we will * be woken up by the fifo done interrupt and no * additional processing is needed. */ process_resume_data(chip); } } /* Start monitor_soc_work based on when it last executed */ rc = get_current_time(&tm_now_sec); if (rc) { pr_err("Could not read current time: %d\n", rc); } else { monitor_soc_delay = get_calculation_delay_ms(chip) - ((tm_now_sec - chip->tm_sec) * 1000); monitor_soc_delay = max(0, monitor_soc_delay); } pr_debug("monitor_soc_delay_sec=%d tm_now_sec=%ld chip->tm_sec=%ld\n", monitor_soc_delay / 1000, tm_now_sec, chip->tm_sec); schedule_delayed_work(&chip->monitor_soc_work, msecs_to_jiffies(monitor_soc_delay)); return 0; } static const struct dev_pm_ops qpnp_vm_bms_pm_ops = { .suspend = bms_suspend, .resume = bms_resume, }; static struct of_device_id qpnp_vm_bms_match_table[] = { { .compatible = QPNP_VM_BMS_DEV_NAME }, {} }; static struct spmi_driver qpnp_vm_bms_driver = { .probe = qpnp_vm_bms_probe, .remove = qpnp_vm_bms_remove, .driver = { .name = QPNP_VM_BMS_DEV_NAME, .owner = THIS_MODULE, .of_match_table = qpnp_vm_bms_match_table, .pm = &qpnp_vm_bms_pm_ops, }, }; static int __init qpnp_vm_bms_init(void) { return spmi_driver_register(&qpnp_vm_bms_driver); } module_init(qpnp_vm_bms_init); static void __exit qpnp_vm_bms_exit(void) { return spmi_driver_unregister(&qpnp_vm_bms_driver); } module_exit(qpnp_vm_bms_exit); MODULE_DESCRIPTION("QPNP VM-BMS Driver"); MODULE_LICENSE("GPL v2"); MODULE_ALIAS("platform:" QPNP_VM_BMS_DEV_NAME);