/* * max77833_fuelgauge.c * Samsung MAX77833 Fuel Gauge Driver * * Copyright (C) 2012 Samsung Electronics * * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 as * published by the Free Software Foundation. */ #define DEBUG /* #define BATTERY_LOG_MESSAGE */ #include #include #include #include static enum power_supply_property max77833_fuelgauge_props[] = { POWER_SUPPLY_PROP_STATUS, #if defined(CONFIG_BATTERY_AGE_FORECAST) POWER_SUPPLY_PROP_VOLTAGE_MAX_DESIGN, #endif POWER_SUPPLY_PROP_VOLTAGE_NOW, POWER_SUPPLY_PROP_VOLTAGE_AVG, POWER_SUPPLY_PROP_CURRENT_NOW, POWER_SUPPLY_PROP_CURRENT_AVG, POWER_SUPPLY_PROP_CHARGE_FULL, POWER_SUPPLY_PROP_ENERGY_NOW, POWER_SUPPLY_PROP_CAPACITY, POWER_SUPPLY_PROP_TEMP, POWER_SUPPLY_PROP_TEMP_AMBIENT, #if defined(CONFIG_EN_OOPS) POWER_SUPPLY_PROP_CHARGE_FULL_DESIGN, #endif POWER_SUPPLY_PROP_ENERGY_FULL, POWER_SUPPLY_PROP_ENERGY_FULL_DESIGN, POWER_SUPPLY_PROP_TIME_TO_FULL_NOW, }; #if !defined(CONFIG_SEC_FACTORY) static void max77833_fg_read_time(struct max77833_fuelgauge_data *fuelgauge) { u16 data; u8 test_data[2]; int lsb, msb, time; if (max77833_read_fg(fuelgauge->i2c, TIME_TO_FULL_REG, &data) < 0) { pr_err("%s: Failed to read TTF\n", __func__); return; } test_data[0] = data & 0xFF; test_data[1] = (data >> 8); lsb = test_data[0] & 0x1f; msb = ((test_data[1] << 3) + ((test_data[0] & 0xe0) >> 5)); time = msb * 180 + (lsb * 5625) / 1000; pr_info("[Time-to-FULL] %d(secs), %d(mins)\n", time, time / 60); if (max77833_read_fg(fuelgauge->i2c, TIME_TO_EMPTY_REG, &data) < 0) { pr_err("%s: Failed to read TTE\n", __func__); return; } test_data[0] = data & 0xFF; test_data[1] = (data >> 8); lsb = test_data[0] & 0x1f; msb = ((test_data[1] << 3) + ((test_data[0] & 0xe0) >> 5)); time = msb * 180 + (lsb * 5625) / 1000; pr_info("[Time-to-EMPTY] %d(secs), %d(mins)\n", time, time / 60); } static void max77833_fg_test_print(struct max77833_fuelgauge_data *fuelgauge) { #ifdef BATTERY_LOG_MESSAGE u16 reg_data; max77833_read_fg(fuelgauge->i2c, FULLCAP_REG, ®_data); pr_info("%s: FULLCAP(%d), data(0x%04x)\n", __func__, reg_data/2, reg_data); max77833_read_fg(fuelgauge->i2c, REMCAP_REP_REG, ®_data); pr_info("%s: REMCAP_REP(%d), data(0x%04x)\n", __func__, reg_data/2, reg_data); max77833_read_fg(fuelgauge->i2c, REMCAP_MIX_REG, ®_data); pr_info("%s: REMCAP_MIX(%d), data(0x%04x)\n", __func__, reg_data/2, reg_data); max77833_read_fg(fuelgauge->i2c, REMCAP_AV_REG, ®_data); pr_info("%s: REMCAP_AV(%d), data(0x%04x)\n", __func__, reg_data/2, reg_data); max77833_read_fg(fuelgauge->i2c, CONFIG_REG, ®_data); pr_info("%s: CONFIG_REG(0x%02x), data(0x%04x)\n", __func__, CONFIG_REG, reg_data); #endif max77833_fg_read_time(fuelgauge); } static void max77833_fg_periodic_read(struct max77833_fuelgauge_data *fuelgauge) { u8 reg; int i; u16 data[0x10]; char *str = NULL; str = kzalloc(sizeof(char)*1024, GFP_KERNEL); if (!str) return; for (i = 0; i < 16; i++) { for (reg = 0; reg < 0x10; reg++) { max77833_read_fg(fuelgauge->i2c, reg + i * 0x10, &data[reg]); if (data[reg] < 0) { kfree(str); return; } } if (i == 12) continue; sprintf(str+strlen(str), "%04xh,%04xh,%04xh,%04xh,%04xh,%04xh,%04xh,%04xh,", data[0x00], data[0x01], data[0x02], data[0x03], data[0x04], data[0x05], data[0x06], data[0x07]); sprintf(str+strlen(str), "%04xh,%04xh,%04xh,%04xh,%04xh,%04xh,%04xh,%04xh,", data[0x08], data[0x09], data[0x0a], data[0x0b], data[0x0c], data[0x0d], data[0x0e], data[0x0f]); if (i == 4) i = 10; } pr_info("[FG] %s\n", str); kfree(str); } #endif static int max77833_fg_read_vcell(struct max77833_fuelgauge_data *fuelgauge) { u16 data; u32 vcell; u32 temp; u32 temp2; if (max77833_read_fg(fuelgauge->i2c, VCELL_REG, &data) < 0) { pr_err("%s: Failed to read VCELL\n", __func__); return -1; } temp = (data & 0xFFF) * 78125; vcell = temp / 1000000; temp = ((data & 0xF000) >> 4) * 78125; temp2 = temp / 1000000; vcell += (temp2 << 4); if (!(fuelgauge->info.pr_cnt++ % PRINT_COUNT)) { fuelgauge->info.pr_cnt = 1; pr_info("%s: VCELL(%d), data(0x%04x)\n", __func__, vcell, data); } return vcell; } static int max77833_fg_read_vfocv(struct max77833_fuelgauge_data *fuelgauge) { u16 data; u32 vfocv = 0; u32 temp; u32 temp2; if (max77833_read_fg(fuelgauge->i2c, VFOCV_REG, &data) < 0) { pr_err("%s: Failed to read VFOCV\n", __func__); return -1; } temp = (data & 0xFFF) * 78125; vfocv = temp / 1000000; temp = ((data & 0xF000) >> 4) * 78125; temp2 = temp / 1000000; vfocv += (temp2 << 4); #if !defined(CONFIG_SEC_FACTORY) max77833_fg_test_print(fuelgauge); max77833_fg_periodic_read(fuelgauge); #endif return vfocv; } static int max77833_fg_read_avg_vcell(struct max77833_fuelgauge_data *fuelgauge) { u32 avg_vcell = 0; u16 data; u32 temp; u32 temp2; if (max77833_read_fg(fuelgauge->i2c, AVR_VCELL_REG, &data) < 0) { pr_err("%s: Failed to read AVG_VCELL\n", __func__); return -1; } temp = (data & 0xFFF) * 78125; avg_vcell = temp / 1000000; temp = ((data & 0xF000) >> 4) * 78125; temp2 = temp / 1000000; avg_vcell += (temp2 << 4); return avg_vcell; } static int max77833_fg_check_battery_present(struct max77833_fuelgauge_data *fuelgauge) { u16 status_data; int ret = 1; /* 1. Check Bst bit */ if (max77833_read_fg(fuelgauge->i2c, STATUS_REG, &status_data) < 0) { pr_err("%s: Failed to read STATUS_REG\n", __func__); return 0; } if (status_data & (0x1 << 3)) { pr_info("%s: addr(0x01), data(0x%04x)\n", __func__, status_data); pr_info("%s: battery is absent!!\n", __func__); ret = 0; } return ret; } static int max77833_fg_write_temp(struct max77833_fuelgauge_data *fuelgauge, int temperature) { u8 data[2]; u8 reg_data; data[0] = (temperature%10) * 1000 / 39; data[1] = temperature / 10; reg_data = (data[1] << 8) | data[0]; max77833_write_fg(fuelgauge->i2c, TEMPERATURE_REG, reg_data); pr_debug("%s: temperature to (%d, 0x%04x)\n", __func__, temperature, reg_data); return temperature; } static int max77833_fg_read_temp(struct max77833_fuelgauge_data *fuelgauge) { u8 data[2] = {0, 0}; u16 reg_data; int temper = 0; if (max77833_fg_check_battery_present(fuelgauge)) { if (max77833_read_fg(fuelgauge->i2c, TEMPERATURE_REG, ®_data) < 0) { pr_err("%s: Failed to read TEMPERATURE_REG\n", __func__); return -1; } data[1] = (reg_data >> 8); data[0] = (reg_data & 0xFF); if (data[1]&(0x1 << 7)) { temper = ((~(data[1]))&0xFF)+1; temper *= (-1000); temper -= ((~((int)data[0]))+1) * 39 / 10; } else { temper = data[1] & 0x7f; temper *= 1000; temper += data[0] * 39 / 10; } } else temper = 20000; if (!(fuelgauge->info.pr_cnt % PRINT_COUNT)) pr_info("%s: TEMPERATURE(%d), data(0x%04x)\n", __func__, temper, (data[1]<<8) | data[0]); return temper/100; } /* soc should be 0.1% unit */ static int max77833_fg_read_vfsoc(struct max77833_fuelgauge_data *fuelgauge) { u16 reg_data; u8 data[2]; int soc; if (max77833_read_fg(fuelgauge->i2c, VFSOC_REG, ®_data) < 0) { pr_err("%s: Failed to read VFSOC\n", __func__); return -1; } data[1] = (reg_data >> 8); data[0] = (reg_data & 0xFF); soc = ((data[1] * 100) + (data[0] * 100 / 256)) / 10; return min(soc, 1000); } /* soc should be 0.1% unit */ static int max77833_fg_read_avsoc(struct max77833_fuelgauge_data *fuelgauge) { u16 reg_data; u8 data[2]; int soc; if (max77833_read_fg(fuelgauge->i2c, SOCAV_REG, ®_data) < 0) { pr_err("%s: Failed to read AVSOC\n", __func__); return -1; } data[1] = (reg_data >> 8); data[0] = (reg_data & 0xFF); soc = ((data[1] * 100) + (data[0] * 100 / 256)) / 10; return min(soc, 1000); } /* soc should be 0.1% unit */ static int max77833_fg_read_soc(struct max77833_fuelgauge_data *fuelgauge) { u16 reg_data; u8 data[2]; int soc, vf_soc; if (max77833_read_fg(fuelgauge->i2c, SOCREP_REG, ®_data) < 0) { pr_err("%s: Failed to read SOCREP\n", __func__); return -1; } data[1] = (reg_data >> 8); data[0] = (reg_data & 0xFF); soc = ((data[1] * 100) + (data[0] * 100 / 256)) / 10; vf_soc = max77833_fg_read_vfsoc(fuelgauge); #ifdef BATTERY_LOG_MESSAGE pr_debug("%s: raw capacity (%d)\n", __func__, soc); if (!(fuelgauge->info.pr_cnt % PRINT_COUNT)) { pr_debug("%s: raw capacity (%d), data(0x%04x)\n", __func__, soc, (data[1]<<8) | data[0]); pr_debug("%s: REPSOC (%d), VFSOC (%d), data(0x%04x)\n", __func__, soc/10, vf_soc/10, (data[1]<<8) | data[0]); } #endif return min(soc, 1000); } /* soc should be 0.01% unit */ static int max77833_fg_read_rawsoc(struct max77833_fuelgauge_data *fuelgauge) { u16 reg_data; u8 data[2]; int soc; if (max77833_read_fg(fuelgauge->i2c, SOCREP_REG, ®_data) < 0) { pr_err("%s: Failed to read SOCREP\n", __func__); return -1; } data[1] = (reg_data >> 8); data[0] = (reg_data & 0xFF); soc = (data[1] * 100) + (data[0] * 100 / 256); pr_debug("%s: raw capacity (0.01%%) (%d)\n", __func__, soc); if (!(fuelgauge->info.pr_cnt % PRINT_COUNT)) pr_debug("%s: raw capacity (%d), data(0x%04x)\n", __func__, soc, (data[1]<<8) | data[0]); return min(soc, 10000); } static int max77833_fg_read_fullcap(struct max77833_fuelgauge_data *fuelgauge) { u16 data; if (max77833_read_fg(fuelgauge->i2c, FULLCAP_REG, &data) < 0) { pr_err("%s: Failed to read FULLCAP\n", __func__); return -1; } return (int)data; } static int max77833_fg_read_fullcaprep(struct max77833_fuelgauge_data *fuelgauge) { u8 data[2]; int ret; if (max77833_bulk_read(fuelgauge->i2c, FULLCAPREP_REG, 2, data) < 0) { pr_err("%s: Failed to read FULLCAP\n", __func__); return -1; } ret = (data[1] << 8) + data[0]; return ret; } static int max77833_fg_read_fullcapnom(struct max77833_fuelgauge_data *fuelgauge) { u8 data[2]; int ret; if (max77833_bulk_read(fuelgauge->i2c, FULLCAP_NOM_REG, 2, data) < 0) { pr_err("%s: Failed to read FULLCAP\n", __func__); return -1; } ret = (data[1] << 8) + data[0]; return ret; } static int max77833_fg_read_mixcap(struct max77833_fuelgauge_data *fuelgauge) { u16 data; if (max77833_read_fg(fuelgauge->i2c, REMCAP_MIX_REG, &data) < 0) { pr_err("%s: Failed to read REMCAP_MIX_REG\n", __func__); return -1; } return (int)data; } static int max77833_fg_read_avcap(struct max77833_fuelgauge_data *fuelgauge) { u16 data; if (max77833_read_fg(fuelgauge->i2c, REMCAP_AV_REG, &data) < 0) { pr_err("%s: Failed to read REMCAP_AV_REG\n", __func__); return -1; } return (int)data; } static int max77833_fg_read_repcap(struct max77833_fuelgauge_data *fuelgauge) { u16 data; if (max77833_read_fg(fuelgauge->i2c, REMCAP_REP_REG, &data) < 0) { pr_err("%s: Failed to read REMCAP_REP_REG\n", __func__); return -1; } return (int)data; } static int max77833_fg_read_current(struct max77833_fuelgauge_data *fuelgauge, int unit) { u16 data1; u32 temp, sign; s32 i_current; if (max77833_read_fg(fuelgauge->i2c, CURRENT_REG, &data1) <0) { pr_err("%s: Failed to read CURRENT\n", __func__); return -1; } temp = data1 & 0xFFFF; /* Debug log for abnormal current case */ if (temp & (0x1 << 15)) { sign = MAX77833_NEGATIVE; temp = (~temp & 0xFFFF) + 1; } else sign = MAX77833_POSITIVE; /* 1.5625uV/0.0O5hm(Rsense) = 312.5uA */ switch (unit) { case SEC_BATTERY_CURRENT_UA: i_current = temp * 15625 / 50; break; case SEC_BATTERY_CURRENT_MA: default: i_current = temp * 15625 / 50000; } if (sign) i_current *= -1; return i_current; } static int max77833_fg_read_avg_current(struct max77833_fuelgauge_data *fuelgauge, int unit) { u16 data2; u32 temp, sign; s32 avg_current; int vcell; static int cnt; if (max77833_read_fg(fuelgauge->i2c, AVG_CURRENT_REG, &data2) < 0) { pr_err("%s: Failed to read AVERAGE CURRENT\n", __func__); return -1; } temp = data2 & 0xFFFF; if (temp & (0x1 << 15)) { sign = MAX77833_NEGATIVE; temp = (~temp & 0xFFFF) + 1; } else sign = MAX77833_POSITIVE; /* 1.5625uV/0.005hm(Rsense) = 312.5uA */ switch (unit) { case SEC_BATTERY_CURRENT_UA: avg_current = temp * 15625 / 50; break; case SEC_BATTERY_CURRENT_MA: default: avg_current = temp * 15625 / 50000; } if (sign) avg_current *= -1; vcell = max77833_fg_read_vcell(fuelgauge); if ((vcell < 3500) && (cnt < 10) && (avg_current < 0) && fuelgauge->is_charging) { avg_current = 1; cnt++; } return avg_current; } static int max77833_fg_read_cycle(struct max77833_fuelgauge_data *fuelgauge) { u8 data[2]; int ret; if (max77833_bulk_read(fuelgauge->i2c, CYCLES_REG, 2, data) < 0) { pr_err("%s: Failed to read FULLCAPCYCLE\n", __func__); return -1; } ret = (data[1] << 8) + data[0]; return ret; } int max77833_fg_reset_soc(struct max77833_fuelgauge_data *fuelgauge) { u16 reg_data, fullcap; int vfocv; /* delay for current stablization */ msleep(500); pr_info("%s: Before quick-start - VCELL(%d), VFOCV(%d), VfSOC(%d), RepSOC(%d)\n", __func__, max77833_fg_read_vcell(fuelgauge), max77833_fg_read_vfocv(fuelgauge), max77833_fg_read_vfsoc(fuelgauge), max77833_fg_read_soc(fuelgauge)); pr_info("%s: Before quick-start - current(%d), avg current(%d)\n", __func__, max77833_fg_read_current(fuelgauge, SEC_BATTERY_CURRENT_MA), max77833_fg_read_avg_current(fuelgauge, SEC_BATTERY_CURRENT_MA)); if (fuelgauge->pdata->check_jig_status && !fuelgauge->pdata->check_jig_status()) { pr_info("%s : Return by No JIG_ON signal\n", __func__); return 0; } max77833_write_fg(fuelgauge->i2c, CYCLES_REG, 0); if (max77833_read_fg(fuelgauge->i2c, MISCCFG_REG, ®_data) < 0) { pr_err("%s: Failed to read MiscCFG\n", __func__); return -1; } reg_data |= (0x1 << 10); if (max77833_write_fg(fuelgauge->i2c, MISCCFG_REG, reg_data) < 0) { pr_err("%s: Failed to write MiscCFG\n", __func__); return -1; } msleep(250); max77833_write_fg(fuelgauge->i2c, FULLCAP_REG, fuelgauge->battery_data->Capacity); msleep(500); pr_info("%s: After quick-start - VCELL(%d), VFOCV(%d), VfSOC(%d), RepSOC(%d)\n", __func__, max77833_fg_read_vcell(fuelgauge), max77833_fg_read_vfocv(fuelgauge), max77833_fg_read_vfsoc(fuelgauge), max77833_fg_read_soc(fuelgauge)); pr_info("%s: After quick-start - current(%d), avg current(%d)\n", __func__, max77833_fg_read_current(fuelgauge, SEC_BATTERY_CURRENT_MA), max77833_fg_read_avg_current(fuelgauge, SEC_BATTERY_CURRENT_MA)); max77833_write_fg(fuelgauge->i2c, CYCLES_REG, 0x00A0); /* P8 is not turned off by Quickstart @3.4V * (It's not a problem, depend on mode data) * Power off for factory test(File system, etc..) */ vfocv = max77833_fg_read_vfocv(fuelgauge); if (vfocv < POWER_OFF_VOLTAGE_LOW_MARGIN) { pr_info("%s: Power off condition(%d)\n", __func__, vfocv); max77833_read_fg(fuelgauge->i2c, FULLCAP_REG, &fullcap); /* FullCAP * 0.009 */ max77833_write_fg(fuelgauge->i2c, REMCAP_REP_REG, (fullcap * 9 / 1000)); msleep(200); pr_info("%s: new soc=%d, vfocv=%d\n", __func__, max77833_fg_read_soc(fuelgauge), vfocv); } pr_info("%s: Additional step - VfOCV(%d), VfSOC(%d), RepSOC(%d)\n", __func__, max77833_fg_read_vfocv(fuelgauge), max77833_fg_read_vfsoc(fuelgauge), max77833_fg_read_soc(fuelgauge)); return 0; } int max77833_fg_reset_capacity_by_jig_connection(struct max77833_fuelgauge_data *fuelgauge) { pr_info("%s: DesignCap = Capacity - 1 (Jig Connection)\n", __func__); return max77833_write_fg(fuelgauge->i2c, DESIGNCAP_REG, fuelgauge->battery_data->Capacity-1); } void max77833_fg_low_batt_compensation(struct max77833_fuelgauge_data *fuelgauge, u32 level) { u16 read_val; u32 temp; pr_info("%s: Adjust SOCrep to %d!!\n", __func__, level); max77833_read_fg(fuelgauge->i2c, FULLCAP_REG, &read_val); /* RemCapREP (05h) = FullCap(10h) x 0.0090 */ temp = read_val * (level*90) / 10000; max77833_write_fg(fuelgauge->i2c, REMCAP_REP_REG, (u16)temp); } static int max77833_fg_check_status_reg(struct max77833_fuelgauge_data *fuelgauge) { u16 status_data; int ret = 0; /* 1. Check Smn was generatedread */ if (max77833_read_fg(fuelgauge->i2c, STATUS_REG, &status_data) < 0) { pr_err("%s: Failed to read STATUS_REG\n", __func__); return -1; } #ifdef BATTERY_LOG_MESSAGE pr_info("%s: addr(0x00), data(0x%04x)\n", __func__, status_data); #endif if (status_data & (0x1 << 10)) ret = 1; /* 2. clear Status reg */ status_data |= 0x0F; if (max77833_write_fg(fuelgauge->i2c, STATUS_REG, status_data) < 0) { pr_info("%s: Failed to write STATUS_REG\n", __func__); return -1; } return ret; } int max77833_get_fuelgauge_value(struct max77833_fuelgauge_data *fuelgauge, int data) { int ret; switch (data) { case MAX77833_FG_LEVEL: ret = max77833_fg_read_soc(fuelgauge); break; case MAX77833_FG_TEMPERATURE: ret = max77833_fg_read_temp(fuelgauge); break; case MAX77833_FG_VOLTAGE: ret = max77833_fg_read_vcell(fuelgauge); break; case MAX77833_FG_CURRENT: ret = max77833_fg_read_current(fuelgauge, SEC_BATTERY_CURRENT_MA); break; case MAX77833_FG_CURRENT_AVG: ret = max77833_fg_read_avg_current(fuelgauge, SEC_BATTERY_CURRENT_MA); break; case MAX77833_FG_CHECK_STATUS: ret = max77833_fg_check_status_reg(fuelgauge); break; case MAX77833_FG_RAW_SOC: ret = max77833_fg_read_rawsoc(fuelgauge); break; case MAX77833_FG_VF_SOC: ret = max77833_fg_read_vfsoc(fuelgauge); break; case MAX77833_FG_AV_SOC: ret = max77833_fg_read_avsoc(fuelgauge); break; case MAX77833_FG_FULLCAP: ret = max77833_fg_read_fullcap(fuelgauge); break; case MAX77833_FG_FULLCAPNOM: ret = max77833_fg_read_fullcapnom(fuelgauge); break; case MAX77833_FG_FULLCAPREP: ret = max77833_fg_read_fullcaprep(fuelgauge); break; case MAX77833_FG_MIXCAP: ret = max77833_fg_read_mixcap(fuelgauge); break; case MAX77833_FG_AVCAP: ret = max77833_fg_read_avcap(fuelgauge); break; case MAX77833_FG_REPCAP: ret = max77833_fg_read_repcap(fuelgauge); break; case MAX77833_FG_CYCLE: ret = max77833_fg_read_cycle(fuelgauge); break; default: ret = -1; break; } return ret; } #if defined(CONFIG_BATTERY_AGE_FORECAST) int max77833_get_age_forecast(struct max77833_fuelgauge_data *fuelgauge) { int fullcapnom = 0; int cycle = 0; int chg_float_voltage = 0; fullcapnom = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_FULLCAPNOM); fullcapnom = fullcapnom / 2; cycle = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_CYCLE); cycle = cycle / 100; pr_info("%s [FG] : cycle(%d), fullcapnom(%d)\n", __func__, cycle, fullcapnom); if (cycle < 50) { return 4400; } else if (fullcapnom > 2545) { return 4400; } else if (fullcapnom > 2475) { chg_float_voltage = 4375; } else if (fullcapnom > 2360) { chg_float_voltage = 4350; } else if (fullcapnom > 2246) { chg_float_voltage = 4325; } else if (fullcapnom > 2132) { chg_float_voltage = 4300; } else if (fullcapnom > 2017) { chg_float_voltage = 4275; } else { chg_float_voltage = 4250; } pr_info("%s [FG] : chg_float_voltage(%d)\n", __func__, chg_float_voltage); return chg_float_voltage; } #endif int max77833_fg_alert_init(struct max77833_fuelgauge_data *fuelgauge, int soc) { #if 0 u16 misccfg_data; u16 salrt_data; u16 config_data; u16 valrt_data; u16 talrt_data; u16 read_data = 0; fuelgauge->is_fuel_alerted = false; /* Using RepSOC */ if (max77833_read_fg(fuelgauge->i2c, MISCCFG_REG, &misccfg_data) < 0) { pr_err("%s: Failed to read MISCCFG_REG\n", __func__); return -1; } misccgf_data[0] = misccgf_data[0] & ~(0x03); if (max77833_bulk_write(fuelgauge->i2c, MISCCFG_REG, 2, misccgf_data) < 0) { pr_info("%s: Failed to write MISCCFG_REG\n", __func__); return -1; } /* SALRT Threshold setting */ salrt_data[1] = 0xff; salrt_data[0] = soc; if (max77833_bulk_write(fuelgauge->i2c, SALRT_THRESHOLD_REG, 2, salrt_data) < 0) { pr_info("%s: Failed to write SALRT_THRESHOLD_REG\n", __func__); return -1; } /* Reset VALRT Threshold setting (disable) */ valrt_data[1] = 0xFF; valrt_data[0] = 0x00; if (max77833_bulk_write(fuelgauge->i2c, VALRT_THRESHOLD_REG, 2, valrt_data) < 0) { pr_info("%s: Failed to write VALRT_THRESHOLD_REG\n", __func__); return -1; } read_data = max77833_read_word(fuelgauge->i2c, (u8)VALRT_THRESHOLD_REG); if (read_data != 0xff00) pr_err("%s: VALRT_THRESHOLD_REG is not valid (0x%x)\n", __func__, read_data); /* Reset TALRT Threshold setting (disable) */ talrt_data[1] = 0x7F; talrt_data[0] = 0x80; if (max77833_bulk_write(fuelgauge->i2c, TALRT_THRESHOLD_REG, 2, talrt_data) < 0) { pr_info("%s: Failed to write TALRT_THRESHOLD_REG\n", __func__); return -1; } read_data = max77833_read_word(fuelgauge->i2c, (u8)TALRT_THRESHOLD_REG); if (read_data != 0x7f80) pr_err("%s: TALRT_THRESHOLD_REG is not valid (0x%x)\n", __func__, read_data); /*mdelay(100);*/ /* Enable SOC alerts */ if (max77833_bulk_read(fuelgauge->i2c, CONFIG_REG, 2, config_data) < 0) { pr_err("%s: Failed to read CONFIG_REG\n", __func__); return -1; } config_data[0] = config_data[0] | (0x1 << 2); if (max77833_bulk_write(fuelgauge->i2c, CONFIG_REG, 2, config_data) < 0) { pr_info("%s: Failed to write CONFIG_REG\n", __func__); return -1; } max77833_update_reg(fuelgauge->pmic, MAX77833_PMIC_REG_INTSRC_MASK, ~MAX77833_IRQSRC_FG, MAX77833_IRQSRC_FG); pr_info("[%s] SALRT(0x%02x%02x), VALRT(0x%02x%02x), CONFIG(0x%02x%02x)\n", __func__, salrt_data[1], salrt_data[0], valrt_data[1], valrt_data[0], config_data[1], config_data[0]); #endif return 1; } static void max77833_display_low_batt_comp_cnt(struct max77833_fuelgauge_data *fuelgauge) { pr_info("Check Array(%s): [%d, %d], [%d, %d], ", fuelgauge->battery_data->type_str, fuelgauge->info.low_batt_comp_cnt[0][0], fuelgauge->info.low_batt_comp_cnt[0][1], fuelgauge->info.low_batt_comp_cnt[1][0], fuelgauge->info.low_batt_comp_cnt[1][1]); pr_info("[%d, %d], [%d, %d], [%d, %d]\n", fuelgauge->info.low_batt_comp_cnt[2][0], fuelgauge->info.low_batt_comp_cnt[2][1], fuelgauge->info.low_batt_comp_cnt[3][0], fuelgauge->info.low_batt_comp_cnt[3][1], fuelgauge->info.low_batt_comp_cnt[4][0], fuelgauge->info.low_batt_comp_cnt[4][1]); } static void max77833_add_low_batt_comp_cnt(struct max77833_fuelgauge_data *fuelgauge, int range, int level) { int i; int j; /* Increase the requested count value, and reset others. */ fuelgauge->info.low_batt_comp_cnt[range-1][level/2]++; for (i = 0; i < LOW_BATT_COMP_RANGE_NUM; i++) { for (j = 0; j < LOW_BATT_COMP_LEVEL_NUM; j++) { if (i == range-1 && j == level/2) continue; else fuelgauge->info.low_batt_comp_cnt[i][j] = 0; } } } void max77833_prevent_early_poweroff(struct max77833_fuelgauge_data *fuelgauge, int vcell, int *fg_soc) { int soc = 0; u16 read_val; soc = max77833_fg_read_soc(fuelgauge); /* No need to write REMCAP_REP in below normal cases */ if (soc > POWER_OFF_SOC_HIGH_MARGIN || vcell > fuelgauge->battery_data->low_battery_comp_voltage) return; pr_info("%s: soc=%d, vcell=%d\n", __func__, soc, vcell); if (vcell > POWER_OFF_VOLTAGE_HIGH_MARGIN) { max77833_read_fg(fuelgauge->i2c, FULLCAP_REG, &read_val); /* FullCAP * 0.013 */ max77833_write_fg(fuelgauge->i2c, REMCAP_REP_REG, (read_val * 13 / 1000)); msleep(200); *fg_soc = max77833_fg_read_soc(fuelgauge); pr_info("%s: new soc=%d, vcell=%d\n", __func__, *fg_soc, vcell); } } void max77833_reset_low_batt_comp_cnt(struct max77833_fuelgauge_data *fuelgauge) { memset(fuelgauge->info.low_batt_comp_cnt, 0, sizeof(fuelgauge->info.low_batt_comp_cnt)); } static int max77833_check_low_batt_comp_condition( struct max77833_fuelgauge_data *fuelgauge, int *nLevel) { int i; int j; int ret = 0; for (i = 0; i < LOW_BATT_COMP_RANGE_NUM; i++) { for (j = 0; j < LOW_BATT_COMP_LEVEL_NUM; j++) { if (fuelgauge->info.low_batt_comp_cnt[i][j] >= MAX_LOW_BATT_CHECK_CNT) { max77833_display_low_batt_comp_cnt(fuelgauge); ret = 1; *nLevel = j*2 + 1; break; } } } return ret; } static int max77833_get_low_batt_threshold(struct max77833_fuelgauge_data *fuelgauge, int range, int nCurrent, int level) { int ret = 0; ret = fuelgauge->battery_data->low_battery_table[range][MAX77833_OFFSET] + ((nCurrent * fuelgauge->battery_data->low_battery_table[range][MAX77833_SLOPE]) / 1000); return ret; } int max77833_low_batt_compensation(struct max77833_fuelgauge_data *fuelgauge, int fg_soc, int fg_vcell, int fg_current) { int fg_avg_current = 0; int fg_min_current = 0; int new_level = 0; int i, table_size; /* Not charging, Under low battery comp voltage */ if (fg_vcell <= fuelgauge->battery_data->low_battery_comp_voltage) { fg_avg_current = max77833_fg_read_avg_current(fuelgauge, SEC_BATTERY_CURRENT_MA); fg_min_current = min(fg_avg_current, fg_current); table_size = sizeof(fuelgauge->battery_data->low_battery_table) / (sizeof(s16)*MAX77833_TABLE_MAX); for (i = 1; i < CURRENT_RANGE_MAX_NUM; i++) { if ((fg_min_current >= fuelgauge->battery_data-> low_battery_table[i-1][MAX77833_RANGE]) && (fg_min_current < fuelgauge->battery_data-> low_battery_table[i][MAX77833_RANGE])) { if (fg_soc >= 10 && fg_vcell < max77833_get_low_batt_threshold(fuelgauge, i, fg_min_current, 1)) { max77833_add_low_batt_comp_cnt( fuelgauge, i, 1); } else { max77833_reset_low_batt_comp_cnt(fuelgauge); } } } if (max77833_check_low_batt_comp_condition(fuelgauge, &new_level)) { max77833_fg_low_batt_compensation(fuelgauge, new_level); max77833_reset_low_batt_comp_cnt(fuelgauge); /* Do not update soc right after * low battery compensation * to prevent from powering-off suddenly */ pr_info("%s: SOC is set to %d by low compensation!!\n", __func__, max77833_fg_read_soc(fuelgauge)); } } /* Prevent power off over 3500mV */ max77833_prevent_early_poweroff(fuelgauge, fg_vcell, &fg_soc); return fg_soc; } static bool max77833_fuelgauge_recovery_handler(struct max77833_fuelgauge_data *fuelgauge) { if (fuelgauge->info.soc < LOW_BATTERY_SOC_REDUCE_UNIT) { fuelgauge->info.is_low_batt_alarm = false; } else { pr_err("%s: Reduce the Reported SOC by 1%%\n", __func__); fuelgauge->info.soc -= LOW_BATTERY_SOC_REDUCE_UNIT; pr_err("%s: New Reduced RepSOC (%d)\n", __func__, fuelgauge->info.soc); } return fuelgauge->info.is_low_batt_alarm; } static int max77833_get_fuelgauge_soc(struct max77833_fuelgauge_data *fuelgauge) { union power_supply_propval value; int fg_soc = 0; int fg_vfsoc; int fg_vcell; int fg_current; int avg_current; if (fuelgauge->info.is_low_batt_alarm) if (max77833_fuelgauge_recovery_handler(fuelgauge)) { fg_soc = fuelgauge->info.soc; goto return_soc; } fg_soc = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_LEVEL); if (fg_soc < 0) { pr_info("Can't read soc!!!"); fg_soc = fuelgauge->info.soc; } fg_vcell = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_VOLTAGE); fg_current = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_CURRENT); avg_current = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_CURRENT_AVG); fg_vfsoc = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_VF_SOC); psy_do_property("battery", get, POWER_SUPPLY_PROP_STATUS, value); /* Checks vcell level and tries to compensate SOC if needed.*/ /* If jig cable is connected, then skip low batt compensation check. */ if (fuelgauge->pdata->check_jig_status && !fuelgauge->pdata->check_jig_status() && value.intval == POWER_SUPPLY_STATUS_DISCHARGING) fg_soc = max77833_low_batt_compensation( fuelgauge, fg_soc, fg_vcell, fg_current); if (fuelgauge->info.is_first_check) fuelgauge->info.is_first_check = false; if ((fg_vcell < 3400) && (avg_current < 0) && (fg_soc <= 10)) fg_soc = 0; fuelgauge->info.soc = fg_soc; return_soc: pr_debug("%s: soc(%d), low_batt_alarm(%d)\n", __func__, fuelgauge->info.soc, fuelgauge->info.is_low_batt_alarm); return fg_soc; } static irqreturn_t max77833_jig_irq_thread(int irq, void *irq_data) { struct max77833_fuelgauge_data *fuelgauge = irq_data; if (fuelgauge->pdata->check_jig_status && fuelgauge->pdata->check_jig_status()) max77833_fg_reset_capacity_by_jig_connection(fuelgauge); else pr_info("%s: jig removed\n", __func__); return IRQ_HANDLED; } bool max77833_fg_init(struct max77833_fuelgauge_data *fuelgauge) { ktime_t current_time; struct timespec ts; u16 data; #if defined(ANDROID_ALARM_ACTIVATED) current_time = alarm_get_elapsed_realtime(); ts = ktime_to_timespec(current_time); #else current_time = ktime_get_boottime(); ts = ktime_to_timespec(current_time); #endif fuelgauge->info.fullcap_check_interval = ts.tv_sec; fuelgauge->info.is_low_batt_alarm = false; fuelgauge->info.is_first_check = true; /* Init parameters to prevent wrong compensation. */ fuelgauge->info.previous_fullcap = max77833_read_word(fuelgauge->i2c, FULLCAP_REG); fuelgauge->info.previous_vffullcap = max77833_read_word(fuelgauge->i2c, FULLCAP_NOM_REG); if (fuelgauge->pdata->check_jig_status && fuelgauge->pdata->check_jig_status()) max77833_fg_reset_capacity_by_jig_connection(fuelgauge); else { if (fuelgauge->pdata->jig_irq) { int ret; ret = request_threaded_irq(fuelgauge->pdata->jig_irq, NULL, max77833_jig_irq_thread, fuelgauge->pdata->jig_irq_attr, "jig-irq", fuelgauge); if (ret) { pr_info("%s: Failed to Request IRQ\n", __func__); } } } /* NOT using FG for temperature */ if (fuelgauge->pdata->thermal_source != SEC_BATTERY_THERMAL_SOURCE_FG) { if (max77833_read_fg(fuelgauge->i2c, CONFIG_REG, &data) < 0) { pr_err ("%s : Failed to read CONFIG_REG\n", __func__); return false; } data |= 0x10; if (max77833_write_fg(fuelgauge->i2c, CONFIG_REG, data) < 0) { pr_info("%s : Failed to write CONFIG_REG\n", __func__); return false; } } /* Enable OCP (0xFF : 10.24A/256) */ data = 0x00FF; max77833_write_fg(fuelgauge->i2c, ISYSTH_REG, data); pr_info("%s: Enable OCP - IsysTH 0x%x\n", __func__, data); return true; } bool max77833_fg_fuelalert_init(struct max77833_fuelgauge_data *fuelgauge, int soc) { /* 1. Set max77833 alert configuration. */ if (max77833_fg_alert_init(fuelgauge, soc) > 0) return true; else return false; } void max77833_fg_fuelalert_set(struct max77833_fuelgauge_data *fuelgauge, int enable) { u16 config_data; if (max77833_read_fg(fuelgauge->i2c, CONFIG_REG, &config_data) < 0) pr_err("%s: Failed to read CONFIG_REG\n", __func__); if (enable) config_data |= ALERT_EN; else config_data &= ~ALERT_EN; pr_info("%s : CONIFG(0x%04x)\n", __func__, config_data); if (max77833_write_fg(fuelgauge->i2c, CONFIG_REG, config_data) < 0) pr_info("%s: Failed to write CONFIG_REG\n", __func__); } bool max77833_fg_fuelalert_process(void *irq_data) { struct max77833_fuelgauge_data *fuelgauge = (struct max77833_fuelgauge_data *)irq_data; max77833_fg_fuelalert_set(fuelgauge, 0); return true; } bool max77833_fg_reset(struct max77833_fuelgauge_data *fuelgauge) { if (!max77833_fg_reset_soc(fuelgauge)) return true; else return false; } #define CAPACITY_MAX_CONTROL_THRESHOLD 300 static void max77833_fg_get_scaled_capacity( struct max77833_fuelgauge_data *fuelgauge, union power_supply_propval *val) { union power_supply_propval value, chg_val, chg_val2; int max_temp; psy_do_property("battery", get, POWER_SUPPLY_PROP_ONLINE, value); psy_do_property("max77833-charger", get, POWER_SUPPLY_PROP_CURRENT_NOW, chg_val); psy_do_property("max77833-charger", get, POWER_SUPPLY_PROP_CHARGE_NOW, chg_val2); pr_info("%s : CABLE TYPE(%d) INPUT CURRENT(%d) CHARGINGE MODE(%s)\n", __func__, value.intval, chg_val.intval, chg_val2.strval); max_temp = fuelgauge->capacity_max; if ((value.intval != POWER_SUPPLY_TYPE_BATTERY) && (!strcmp(chg_val2.strval, "CV Mode")) && (chg_val.intval >= 1000)) { int temp, sample; int curr; int topoff; int capacity_threshold; static int cnt; curr = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_CURRENT_AVG); topoff = fuelgauge->pdata->charging_current[value.intval].full_check_current_1st; capacity_threshold = topoff + CAPACITY_MAX_CONTROL_THRESHOLD; pr_info("%s : curr(%d) topoff(%d) capacity_max(%d)\n", __func__, curr, topoff, max_temp); if ((curr < capacity_threshold) && (curr > topoff)) { if (!cnt) { cnt = 1; fuelgauge->standard_capacity = (val->intval < fuelgauge->pdata->capacity_min) ? 0 : ((val->intval - fuelgauge->pdata->capacity_min) * 999 / (fuelgauge->capacity_max - fuelgauge->pdata->capacity_min)); } else if (fuelgauge->standard_capacity < 999) { temp = (val->intval < fuelgauge->pdata->capacity_min) ? 0 : ((val->intval - fuelgauge->pdata->capacity_min) * 999 / (fuelgauge->capacity_max - fuelgauge->pdata->capacity_min)); sample = ((capacity_threshold - curr) * (999 - fuelgauge->standard_capacity)) / (capacity_threshold - topoff); pr_info("%s : %d = ((%d - %d) * (999 - %d)) / (%d - %d)\n", __func__, sample, capacity_threshold, curr, fuelgauge->standard_capacity, capacity_threshold, topoff); if ((temp - fuelgauge->standard_capacity) >= sample) { pr_info("%s : TEMP > SAMPLE\n", __func__); } else if ((sample - (temp - fuelgauge->standard_capacity)) < 5) { pr_info("%s : TEMP < SAMPLE && GAP UNDER 5\n", __func__); max_temp -= (sample - (temp - fuelgauge->standard_capacity)); } else { pr_info("%s : TEMP > SAMPLE && GAP OVER 5\n", __func__); max_temp -= 5; } pr_info("%s : TEMP(%d) SAMPLE(%d) CAPACITY_MAX(%d)\n", __func__, temp, sample, fuelgauge->capacity_max); } } else { cnt = 0; } } if (max_temp < fuelgauge->pdata->capacity_max - fuelgauge->pdata->capacity_max_margin) { fuelgauge->capacity_max = fuelgauge->pdata->capacity_max - fuelgauge->pdata->capacity_max_margin; pr_debug("%s: capacity_max (%d)", __func__, fuelgauge->capacity_max); } else { fuelgauge->capacity_max = (max_temp > fuelgauge->pdata->capacity_max + fuelgauge->pdata->capacity_max_margin) ? (fuelgauge->pdata->capacity_max + fuelgauge->pdata->capacity_max_margin) : max_temp; pr_debug("%s: capacity_max (%d)", __func__, fuelgauge->capacity_max); } val->intval = (val->intval < fuelgauge->pdata->capacity_min) ? 0 : ((val->intval - fuelgauge->pdata->capacity_min) * 1000 / (fuelgauge->capacity_max - fuelgauge->pdata->capacity_min)); pr_info("%s: scaled capacity (%d.%d)\n", __func__, val->intval/10, val->intval%10); } /* capacity is integer */ static void max77833_fg_get_atomic_capacity( struct max77833_fuelgauge_data *fuelgauge, union power_supply_propval *val) { pr_info("%s : NOW(%d), OLD(%d)\n", __func__, val->intval, fuelgauge->capacity_old); if (fuelgauge->pdata->capacity_calculation_type & SEC_FUELGAUGE_CAPACITY_TYPE_ATOMIC) { if (fuelgauge->capacity_old < val->intval) val->intval = fuelgauge->capacity_old + 1; else if (fuelgauge->capacity_old > val->intval) val->intval = fuelgauge->capacity_old - 1; } /* keep SOC stable in abnormal status */ if (fuelgauge->pdata->capacity_calculation_type & SEC_FUELGAUGE_CAPACITY_TYPE_SKIP_ABNORMAL) { if (!fuelgauge->is_charging && fuelgauge->capacity_old < val->intval) { pr_err("%s: capacity (old %d : new %d)\n", __func__, fuelgauge->capacity_old, val->intval); val->intval = fuelgauge->capacity_old; } } /* updated old capacity */ fuelgauge->capacity_old = val->intval; } static int max77833_fg_calculate_dynamic_scale( struct max77833_fuelgauge_data *fuelgauge, int capacity) { union power_supply_propval raw_soc_val; raw_soc_val.intval = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_RAW_SOC) / 10; if (raw_soc_val.intval < fuelgauge->pdata->capacity_max - fuelgauge->pdata->capacity_max_margin) { fuelgauge->capacity_max = fuelgauge->pdata->capacity_max - fuelgauge->pdata->capacity_max_margin; pr_debug("%s: capacity_max (%d)", __func__, fuelgauge->capacity_max); } else { fuelgauge->capacity_max = (raw_soc_val.intval > fuelgauge->pdata->capacity_max + fuelgauge->pdata->capacity_max_margin) ? (fuelgauge->pdata->capacity_max + fuelgauge->pdata->capacity_max_margin) : raw_soc_val.intval; pr_debug("%s: raw soc (%d)", __func__, fuelgauge->capacity_max); } if (capacity != 100) { fuelgauge->capacity_max = (fuelgauge->capacity_max * 100 / capacity); fuelgauge->capacity_old = capacity; } else { fuelgauge->capacity_max = (fuelgauge->capacity_max * 99 / 100); fuelgauge->capacity_old = 100; } pr_info("%s: %d is used for capacity_max, capacity(%d)\n", __func__, fuelgauge->capacity_max, capacity); return fuelgauge->capacity_max; } static void max77833_fg_check_qrtable(struct max77833_fuelgauge_data *fuelgauge) { u16 qrtable20, qrtable30; max77833_read_fg(fuelgauge->i2c, QRTABLE20_REG, &qrtable20); if (qrtable20 != fuelgauge->battery_data->QResidual20) { if (max77833_write_fg(fuelgauge->i2c, QRTABLE20_REG, fuelgauge->battery_data->QResidual20) < 0) pr_err("%s: Failed to write QRTABLE20\n", __func__); } max77833_read_fg(fuelgauge->i2c, QRTABLE30_REG, &qrtable30); if (qrtable30 != fuelgauge->battery_data->QResidual30) { if (max77833_write_fg(fuelgauge->i2c, QRTABLE30_REG, fuelgauge->battery_data->QResidual30) < 0) pr_err("%s: Failed to write QRTABLE30\n", __func__); } pr_info("%s: QRTABLE20_REG(0x%04x), QRTABLE30_REG(0x%04x)\n", __func__, qrtable20, qrtable30); } #if defined(CONFIG_EN_OOPS) static void max77833_set_full_value(struct max77833_fuelgauge_data *fuelgauge, int cable_type) { u16 ichgterm, misccfg, fullsocthr; if ((cable_type == POWER_SUPPLY_TYPE_HV_MAINS) || (cable_type == POWER_SUPPLY_TYPE_HV_ERR)) { ichgterm = fuelgauge->battery_data->ichgterm_2nd; misccfg = fuelgauge->battery_data->misccfg_2nd; fullsocthr = fuelgauge->battery_data->fullsocthr_2nd; } else { ichgterm = fuelgauge->battery_data->ichgterm; misccfg = fuelgauge->battery_data->misccfg; fullsocthr = fuelgauge->battery_data->fullsocthr; } max77833_write_fg(fuelgauge->i2c, ICHGTERM_REG, ichgterm); max77833_write_fg(fuelgauge->i2c, MISCCFG_REG, misccfg); max77833_write_fg(fuelgauge->i2c, FULLSOCTHR_REG, fullsocthr); pr_info("%s : ICHGTERM(0x%04x) FULLSOCTHR(0x%04x), MISCCFG(0x%04x)\n", __func__, ichgterm, misccfg, fullsocthr); } #endif static int calc_ttf(struct max77833_fuelgauge_data *fuelgauge, union power_supply_propval *val) { union power_supply_propval chg_val2; int i; int cc_time = 0; int soc = fuelgauge->raw_capacity; int current_now = fuelgauge->current_now; int current_avg = fuelgauge->current_avg; int charge_current = (current_avg > 0)? current_avg : current_now; struct cv_slope *cv_data = fuelgauge->cv_data; int design_cap = fuelgauge->battery_data->Capacity / 2; if(!cv_data || (val->intval <= 0)) { pr_info("%s: no cv_data or val: %d\n", __func__, val->intval); return -1; } /* To prevent overflow if charge current is 30 under, change value*/ if (charge_current <= 30) { #if 1 charge_current = val->intval; #else pr_info("%s: current: %d, current_avg: %d \n", __func__, current_now, current_avg); return -1; #endif } psy_do_property("max77833-charger", get, POWER_SUPPLY_PROP_CHARGE_NOW, chg_val2); if (!strcmp(chg_val2.strval, "CC Mode") || !strcmp(chg_val2.strval, "NONE")) { //CC mode || NONE charge_current = val->intval; } for (i = 0; i < fuelgauge->cv_data_lenth ;i++) { if (charge_current >= cv_data[i].fg_current) break; } if (cv_data[i].soc < soc) { for (i = 0; i < fuelgauge->cv_data_lenth; i++) { if (soc <= cv_data[i].soc) break; } } else if (!strcmp(chg_val2.strval, "CC Mode") || !strcmp(chg_val2.strval, "NONE")) { //CC mode || NONE cc_time = design_cap * (cv_data[i].soc - soc)\ / val->intval * 3600 / 1000; pr_debug("%s: cc_time: %d\n", __func__, cc_time); if (cc_time < 0) { cc_time = 0; } } pr_debug("%s: soc: %4d, T: %6d, now: %4d, avg: %4d, cv soc: %4d, i: %4d, val: %d, %s\n", __func__, soc, cv_data[i].time + cc_time, current_now, current_avg, cv_data[i].soc, i, val->intval, chg_val2.strval); return cv_data[i].time + cc_time + 60; //minimum 1minutes } static int max77833_fg_get_property(struct power_supply *psy, enum power_supply_property psp, union power_supply_propval *val) { struct max77833_fuelgauge_data *fuelgauge = container_of(psy, struct max77833_fuelgauge_data, psy_fg); static int abnormal_current_cnt = 0; union power_supply_propval value; u16 data; unsigned int cnt = 0 ; switch (psp) { #if defined(CONFIG_BATTERY_AGE_FORECAST) case POWER_SUPPLY_PROP_VOLTAGE_MAX_DESIGN: val->intval = max77833_get_age_forecast(fuelgauge); break; #endif /* Cell voltage (VCELL, mV) */ case POWER_SUPPLY_PROP_VOLTAGE_NOW: val->intval = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_VOLTAGE); break; /* Additional Voltage Information (mV) */ case POWER_SUPPLY_PROP_VOLTAGE_AVG: switch (val->intval) { case SEC_BATTERY_VOLTAGE_OCV: val->intval = max77833_fg_read_vfocv(fuelgauge); break; case SEC_BATTERY_VOLTAGE_AVERAGE: default: val->intval = max77833_fg_read_avg_vcell(fuelgauge); break; } break; /* Current */ case POWER_SUPPLY_PROP_CURRENT_NOW: switch (val->intval) { case SEC_BATTERY_CURRENT_UA: val->intval = max77833_fg_read_current(fuelgauge, SEC_BATTERY_CURRENT_UA); break; case SEC_BATTERY_CURRENT_MA: default: /* Print System current use Isys, AvgISys register */ if (max77833_read_fg(fuelgauge->i2c, ISYS_REG, &data) < 0) pr_err("%s: Failed to read ISYS_REG\n", __func__); pr_info("%s: System current - ISYS_REG(0x%x, %d)\n", __func__, data, data); if (max77833_read_fg(fuelgauge->i2c, AVGISYS_REG, &data) < 0) pr_err("%s: Failed to read AVGISYS_REG\n", __func__); pr_info("%s: System current - AVGISYS_REG(0x%x, %d)\n", __func__, data, data); fuelgauge->current_now = val->intval = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_CURRENT); psy_do_property("battery", get, POWER_SUPPLY_PROP_STATUS, value); /* To save log for abnormal case */ if (value.intval == POWER_SUPPLY_STATUS_DISCHARGING && val->intval > 0) { abnormal_current_cnt++; if (abnormal_current_cnt >= 5) { pr_info("%s : Inow is increasing in not charging status\n", __func__); value.intval = fuelgauge->capacity_old + 15; psy_do_property("battery", set, POWER_SUPPLY_PROP_CAPACITY, value); abnormal_current_cnt = 0; value.intval = fuelgauge->capacity_old; psy_do_property("battery", set, POWER_SUPPLY_PROP_CAPACITY, value); } } else { abnormal_current_cnt = 0; } break; } break; /* Average Current */ case POWER_SUPPLY_PROP_CURRENT_AVG: switch (val->intval) { case SEC_BATTERY_CURRENT_UA: val->intval = max77833_fg_read_avg_current(fuelgauge, SEC_BATTERY_CURRENT_UA); break; case SEC_BATTERY_CURRENT_MA: default: val->intval = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_CURRENT_AVG); break; } break; /* Full Capacity */ case POWER_SUPPLY_PROP_ENERGY_NOW: switch (val->intval) { case SEC_BATTERY_CAPACITY_DESIGNED: val->intval = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_FULLCAP); break; case SEC_BATTERY_CAPACITY_ABSOLUTE: val->intval = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_MIXCAP); break; case SEC_BATTERY_CAPACITY_TEMPERARY: val->intval = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_AVCAP); break; case SEC_BATTERY_CAPACITY_CURRENT: val->intval = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_REPCAP); break; case SEC_BATTERY_CAPACITY_AGEDCELL: val->intval = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_FULLCAPNOM); break; case SEC_BATTERY_CAPACITY_CYCLE: val->intval = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_CYCLE); break; } break; /* SOC (%) */ case POWER_SUPPLY_PROP_CAPACITY: if (val->intval == SEC_FUELGAUGE_CAPACITY_TYPE_RAW) { val->intval = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_RAW_SOC); while(val->intval == 0){ pr_info(" %s: Battery level is 0 : cnt:%d \n",__func__, cnt); val->intval = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_RAW_SOC); cnt++; if(cnt > 3) break; } if(val->intval < 5) { pr_info("%s : CAPACITY_TYPE_RAW: Battery is too low!!! :%d\n", __func__,val->intval); } } else { val->intval = max77833_get_fuelgauge_soc(fuelgauge); fuelgauge->raw_capacity = val->intval; if (fuelgauge->pdata->capacity_calculation_type & (SEC_FUELGAUGE_CAPACITY_TYPE_SCALE | SEC_FUELGAUGE_CAPACITY_TYPE_DYNAMIC_SCALE)) max77833_fg_get_scaled_capacity(fuelgauge, val); /* capacity should be between 0% and 100% * (0.1% degree) */ if (val->intval > 1000) val->intval = 1000; if (val->intval < 0) val->intval = 0; while(val->intval == 0){ pr_info(" %s: Battery level is 0 : cnt:%d \n",__func__, cnt); val->intval = max77833_get_fuelgauge_soc(fuelgauge); fuelgauge->raw_capacity = val->intval; if (fuelgauge->pdata->capacity_calculation_type & (SEC_FUELGAUGE_CAPACITY_TYPE_SCALE | SEC_FUELGAUGE_CAPACITY_TYPE_DYNAMIC_SCALE)) max77833_fg_get_scaled_capacity(fuelgauge, val); /* capacity should be between 0% and 100% * (0.1% degree) */ if (val->intval > 1000) val->intval = 1000; if (val->intval < 0) val->intval = 0; cnt++; if(cnt > 3) break; } if(val->intval < 5) { pr_info("%s : Battery is too low!!! :%d\n", __func__,val->intval); } /* get only integer part */ val->intval /= 10; /* check whether doing the wake_unlock */ if ((val->intval > fuelgauge->pdata->fuel_alert_soc) && fuelgauge->is_fuel_alerted) { wake_unlock(&fuelgauge->fuel_alert_wake_lock); max77833_fg_fuelalert_init(fuelgauge, fuelgauge->pdata->fuel_alert_soc); } /* (Only for atomic capacity) * In initial time, capacity_old is 0. * and in resume from sleep, * capacity_old is too different from actual soc. * should update capacity_old * by val->intval in booting or resume. */ if (fuelgauge->initial_update_of_soc) { /* updated old capacity */ fuelgauge->capacity_old = val->intval; fuelgauge->initial_update_of_soc = false; break; } if (fuelgauge->pdata->capacity_calculation_type & (SEC_FUELGAUGE_CAPACITY_TYPE_ATOMIC | SEC_FUELGAUGE_CAPACITY_TYPE_SKIP_ABNORMAL)) max77833_fg_get_atomic_capacity(fuelgauge, val); } break; /* Battery Temperature */ case POWER_SUPPLY_PROP_TEMP: /* Target Temperature */ case POWER_SUPPLY_PROP_TEMP_AMBIENT: val->intval = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_TEMPERATURE); break; #if defined(CONFIG_EN_OOPS) case POWER_SUPPLY_PROP_CHARGE_FULL_DESIGN: return -ENODATA; #endif case POWER_SUPPLY_PROP_ENERGY_FULL: { int fullcap = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_FULLCAPNOM); val->intval = fullcap * 100 / fuelgauge->battery_data->Capacity; pr_info("%s: asoc(%d), fullcap(0x%x)\n", __func__, val->intval, fullcap); #if !defined(CONFIG_SEC_FACTORY) max77833_fg_periodic_read(fuelgauge); #endif } break; case POWER_SUPPLY_PROP_ENERGY_FULL_DESIGN: val->intval = fuelgauge->capacity_max; break; case POWER_SUPPLY_PROP_TIME_TO_FULL_NOW: val->intval = calc_ttf(fuelgauge, val); break; default: return -EINVAL; } return 0; } static int max77833_fg_set_property(struct power_supply *psy, enum power_supply_property psp, const union power_supply_propval *val) { struct max77833_fuelgauge_data *fuelgauge = container_of(psy, struct max77833_fuelgauge_data, psy_fg); switch (psp) { case POWER_SUPPLY_PROP_STATUS: break; #if defined(CONFIG_BATTERY_AGE_FORECAST) case POWER_SUPPLY_PROP_VOLTAGE_MAX_DESIGN: break; #endif case POWER_SUPPLY_PROP_CHARGE_FULL: if (fuelgauge->pdata->capacity_calculation_type & SEC_FUELGAUGE_CAPACITY_TYPE_DYNAMIC_SCALE) { #if defined(CONFIG_AFC_CHARGER_MODE) max77833_fg_calculate_dynamic_scale(fuelgauge, val->intval); #else max77833_fg_calculate_dynamic_scale(fuelgauge, 100); #endif } break; #if defined(CONFIG_EN_OOPS) case POWER_SUPPLY_PROP_CHARGE_FULL_DESIGN: max77833_set_full_value(fuelgauge, val->intval); break; #endif case POWER_SUPPLY_PROP_ONLINE: fuelgauge->cable_type = val->intval; if (val->intval == POWER_SUPPLY_TYPE_BATTERY) { fuelgauge->is_charging = false; } else { fuelgauge->is_charging = true; if (fuelgauge->info.is_low_batt_alarm) { pr_info("%s: Reset low_batt_alarm\n", __func__); fuelgauge->info.is_low_batt_alarm = false; } max77833_reset_low_batt_comp_cnt(fuelgauge); } break; /* Battery Temperature */ case POWER_SUPPLY_PROP_CAPACITY: if (val->intval == SEC_FUELGAUGE_CAPACITY_TYPE_RESET) { fuelgauge->initial_update_of_soc = true; if (!max77833_fg_reset(fuelgauge)) return -EINVAL; else break; } case POWER_SUPPLY_PROP_TEMP: max77833_fg_write_temp(fuelgauge, val->intval); max77833_fg_check_qrtable(fuelgauge); break; case POWER_SUPPLY_PROP_TEMP_AMBIENT: break; case POWER_SUPPLY_PROP_ENERGY_NOW: max77833_fg_reset_capacity_by_jig_connection(fuelgauge); break; case POWER_SUPPLY_PROP_ENERGY_FULL_DESIGN: pr_info("%s: capacity_max changed, %d -> %d\n", __func__, fuelgauge->capacity_max, val->intval); fuelgauge->capacity_max = val->intval; break; default: return -EINVAL; } return 0; } static void max77833_fg_isr_work(struct work_struct *work) { struct max77833_fuelgauge_data *fuelgauge = container_of(work, struct max77833_fuelgauge_data, isr_work.work); /* process for fuel gauge chip */ max77833_fg_fuelalert_process(fuelgauge); wake_unlock(&fuelgauge->fuel_alert_wake_lock); } static irqreturn_t max77833_fg_irq_thread(int irq, void *irq_data) { struct max77833_fuelgauge_data *fuelgauge = irq_data; max77833_update_reg(fuelgauge->pmic, MAX77833_PMIC_REG_INTSRC_MASK, MAX77833_IRQSRC_FG, MAX77833_IRQSRC_FG); pr_info("%s\n", __func__); if (fuelgauge->is_fuel_alerted) { return IRQ_HANDLED; } else { wake_lock(&fuelgauge->fuel_alert_wake_lock); fuelgauge->is_fuel_alerted = true; schedule_delayed_work(&fuelgauge->isr_work, 0); } return IRQ_HANDLED; } static int max77833_fuelgauge_debugfs_show(struct seq_file *s, void *data) { seq_printf(s, "MAX77833 FUELGAUGE IC :\n"); seq_printf(s, "===================\n"); seq_printf(s, "\n"); return 0; } static int max77833_fuelgauge_debugfs_open(struct inode *inode, struct file *file) { return single_open(file, max77833_fuelgauge_debugfs_show, inode->i_private); } static const struct file_operations max77833_fuelgauge_debugfs_fops = { .open = max77833_fuelgauge_debugfs_open, .read = seq_read, .llseek = seq_lseek, .release = single_release, }; #ifdef CONFIG_OF static int max77833_fuelgauge_parse_dt(struct max77833_fuelgauge_data *fuelgauge) { struct device_node *np = of_find_node_by_name(NULL, "max77833-fuelgauge"); sec_fuelgauge_platform_data_t *pdata = fuelgauge->pdata; int ret; int i, len; const u32 *p; /* reset, irq gpio info */ if (np == NULL) { pr_err("%s np NULL\n", __func__); } else { ret = of_property_read_u32(np, "fuelgauge,capacity_max", &pdata->capacity_max); if (ret < 0) pr_err("%s error reading capacity_max %d\n", __func__, ret); ret = of_property_read_u32(np, "fuelgauge,capacity_max_margin", &pdata->capacity_max_margin); if (ret < 0) pr_err("%s error reading capacity_max_margin %d\n", __func__, ret); ret = of_property_read_u32(np, "fuelgauge,capacity_min", &pdata->capacity_min); if (ret < 0) pr_err("%s error reading capacity_min %d\n", __func__, ret); ret = of_property_read_u32(np, "fuelgauge,capacity_calculation_type", &pdata->capacity_calculation_type); if (ret < 0) pr_err("%s error reading capacity_calculation_type %d\n", __func__, ret); ret = of_property_read_u32(np, "fuelgauge,fuel_alert_soc", &pdata->fuel_alert_soc); if (ret < 0) pr_err("%s error reading pdata->fuel_alert_soc %d\n", __func__, ret); pdata->repeated_fuelalert = of_property_read_bool(np, "fuelgauge,repeated_fuelalert"); ret = of_property_read_u32(np, "fuelgauge,qrtable20", &fuelgauge->battery_data->QResidual20); if (ret < 0) pr_err("%s error reading qrtable20 %d\n", __func__, ret); ret = of_property_read_u32(np, "fuelgauge,qrtable30", &fuelgauge->battery_data->QResidual30); if (ret < 0) pr_err("%s error reading qrtabel30 %d\n", __func__, ret); #if defined(CONFIG_EN_OOPS) ret = of_property_read_u32(np, "fuelgauge,ichgterm", &fuelgauge->battery_data->ichgterm); if (ret < 0) pr_err("%s error reading ichgterm %d\n", __func__, ret); ret = of_property_read_u32(np, "fuelgauge,ichgterm_2nd", &fuelgauge->battery_data->ichgterm_2nd); if (ret < 0) pr_err("%s error reading ichgterm_2nd %d\n", __func__, ret); ret = of_property_read_u32(np, "fuelgauge,misccfg", &fuelgauge->battery_data->misccfg); if (ret < 0) pr_err("%s error reading misccfg %d\n", __func__, ret); ret = of_property_read_u32(np, "fuelgauge,misccfg_2nd", &fuelgauge->battery_data->misccfg_2nd); if (ret < 0) pr_err("%s error reading misccfg_2nd %d\n", __func__, ret); ret = of_property_read_u32(np, "fuelgauge,fullsocthr", &fuelgauge->battery_data->fullsocthr); if (ret < 0) pr_err("%s error reading fullsocthr %d\n", __func__, ret); ret = of_property_read_u32(np, "fuelgauge,fullsocthr_2nd", &fuelgauge->battery_data->fullsocthr_2nd); if (ret < 0) pr_err("%s error reading fullsocthr_2nd %d\n", __func__, ret); #endif ret = of_property_read_u32(np, "fuelgauge,capacity", &fuelgauge->battery_data->Capacity); if (ret < 0) pr_err("%s error reading capacity_calculation_type %d\n", __func__, ret); ret = of_property_read_u32(np, "fuelgauge,low_battery_comp_voltage", &fuelgauge->battery_data->low_battery_comp_voltage); if (ret < 0) pr_err("%s error reading capacity_calculation_type %d\n", __func__, ret); for(i = 0; i < (CURRENT_RANGE_MAX_NUM * MAX77833_TABLE_MAX); i++) { ret = of_property_read_u32_index(np, "fuelgauge,low_battery_table", i, &fuelgauge->battery_data->low_battery_table[i/3][i%3]); pr_info("[%d]", fuelgauge->battery_data->low_battery_table[i/3][i%3]); if ((i%3) == 2) pr_info("\n"); } p = of_get_property(np, "fuelgauge,cv_data", &len); if (p) { fuelgauge->cv_data = kzalloc(len, GFP_KERNEL); fuelgauge->cv_data_lenth = len / sizeof(struct cv_slope); pr_err("%s len: %ld, lenth: %d, %d\n", __func__, sizeof(int) * len, len, fuelgauge->cv_data_lenth); ret = of_property_read_u32_array(np, "fuelgauge,cv_data", (u32 *)fuelgauge->cv_data, len/sizeof(u32)); for(i = 0; i < fuelgauge->cv_data_lenth; i++) { pr_err("%s %5d, %5d, %5d\n", __func__, fuelgauge->cv_data[i].fg_current, fuelgauge->cv_data[i].soc, fuelgauge->cv_data[i].time); } if (ret) { pr_err("%s failed to read fuelgauge->cv_data: %d\n", __func__, ret); kfree(fuelgauge->cv_data); fuelgauge->cv_data = NULL; } } else { pr_err("%s there is not cv_data\n", __func__); } np = of_find_node_by_name(NULL, "battery"); ret = of_property_read_u32(np, "battery,thermal_source", &pdata->thermal_source); if (ret < 0) { pr_err("%s error reading pdata->thermal_source %d\n", __func__, ret); } p = of_get_property(np, "battery,input_current_limit", &len); if (!p) return 1; len = len / sizeof(u32); pdata->charging_current = kzalloc(sizeof(sec_charging_current_t) * len, GFP_KERNEL); for(i = 0; i < len; i++) { ret = of_property_read_u32_index(np, "battery,input_current_limit", i, &pdata->charging_current[i].input_current_limit); ret = of_property_read_u32_index(np, "battery,fast_charging_current", i, &pdata->charging_current[i].fast_charging_current); ret = of_property_read_u32_index(np, "battery,full_check_current_1st", i, &pdata->charging_current[i].full_check_current_1st); ret = of_property_read_u32_index(np, "battery,full_check_current_2nd", i, &pdata->charging_current[i].full_check_current_2nd); } pr_info("%s fg_irq: %d, capacity_max: %d\n" "qrtable20: 0x%x, qrtable30 : 0x%x\n" "capacity_max_margin: %d, capacity_min: %d\n" "calculation_type: 0x%x, fuel_alert_soc: %d,\n" "repeated_fuelalert: %d\n", __func__, pdata->fg_irq, pdata->capacity_max, fuelgauge->battery_data->QResidual20, fuelgauge->battery_data->QResidual30, pdata->capacity_max_margin, pdata->capacity_min, pdata->capacity_calculation_type, pdata->fuel_alert_soc, pdata->repeated_fuelalert); } pr_info("[%s][%d][%d]\n", __func__, fuelgauge->battery_data->Capacity, fuelgauge->battery_data->low_battery_comp_voltage); return 0; } #endif static int __devinit max77833_fuelgauge_probe(struct platform_device *pdev) { struct max77833_dev *max77833 = dev_get_drvdata(pdev->dev.parent); struct max77833_platform_data *pdata = dev_get_platdata(max77833->dev); struct max77833_fuelgauge_data *fuelgauge; int ret = 0; union power_supply_propval raw_soc_val; pr_info("%s: MAX77833 Fuelgauge Driver Loading\n", __func__); fuelgauge = kzalloc(sizeof(*fuelgauge), GFP_KERNEL); if (!fuelgauge) return -ENOMEM; pdata->fuelgauge_data = kzalloc(sizeof(sec_fuelgauge_platform_data_t), GFP_KERNEL); if (!pdata->fuelgauge_data) { ret = -ENOMEM; goto err_free; } mutex_init(&fuelgauge->fg_lock); fuelgauge->dev = &pdev->dev; fuelgauge->pdata = pdata->fuelgauge_data; fuelgauge->i2c = max77833->fuelgauge; fuelgauge->pmic = max77833->i2c; fuelgauge->max77833_pdata = pdata; #if defined(CONFIG_OF) fuelgauge->battery_data = kzalloc(sizeof(struct battery_data_t), GFP_KERNEL); if(!fuelgauge->battery_data) { pr_err("Failed to allocate memory\n"); ret = -ENOMEM; goto err_pdata_free; } ret = max77833_fuelgauge_parse_dt(fuelgauge); if (ret < 0) { pr_err("%s not found charger dt! ret[%d]\n", __func__, ret); } #endif platform_set_drvdata(pdev, fuelgauge); fuelgauge->psy_fg.name = "max77833-fuelgauge"; fuelgauge->psy_fg.type = POWER_SUPPLY_TYPE_UNKNOWN; fuelgauge->psy_fg.get_property = max77833_fg_get_property; fuelgauge->psy_fg.set_property = max77833_fg_set_property; fuelgauge->psy_fg.properties = max77833_fuelgauge_props; fuelgauge->psy_fg.num_properties = ARRAY_SIZE(max77833_fuelgauge_props); fuelgauge->capacity_max = fuelgauge->pdata->capacity_max; raw_soc_val.intval = max77833_get_fuelgauge_value(fuelgauge, MAX77833_FG_RAW_SOC) / 10; if (raw_soc_val.intval > fuelgauge->capacity_max) max77833_fg_calculate_dynamic_scale(fuelgauge, 100); (void) debugfs_create_file("max77833-fuelgauge-regs", S_IRUGO, NULL, (void *)fuelgauge, &max77833_fuelgauge_debugfs_fops); if (!max77833_fg_init(fuelgauge)) { pr_err("%s: Failed to Initialize Fuelgauge\n", __func__); goto err_data_free; } ret = power_supply_register(&pdev->dev, &fuelgauge->psy_fg); if (ret) { pr_err("%s: Failed to Register psy_fg\n", __func__); goto err_data_free; } fuelgauge->fg_irq = pdata->irq_base + MAX77833_FG_IRQ_ALERT; pr_info("[%s]IRQ_BASE(%d) FG_IRQ(%d)\n", __func__, pdata->irq_base, fuelgauge->fg_irq); fuelgauge->is_fuel_alerted = false; if (fuelgauge->pdata->fuel_alert_soc >= 0) { if (max77833_fg_fuelalert_init(fuelgauge, fuelgauge->pdata->fuel_alert_soc)) { wake_lock_init(&fuelgauge->fuel_alert_wake_lock, WAKE_LOCK_SUSPEND, "fuel_alerted"); if (fuelgauge->fg_irq) { INIT_DELAYED_WORK(&fuelgauge->isr_work, max77833_fg_isr_work); ret = request_threaded_irq(fuelgauge->fg_irq, NULL, max77833_fg_irq_thread, IRQF_TRIGGER_FALLING | IRQF_ONESHOT, "fuelgauge-irq", fuelgauge); if (ret) { pr_err("%s: Failed to Request IRQ\n", __func__); goto err_supply_unreg; } } } else { pr_err("%s: Failed to Initialize Fuel-alert\n", __func__); goto err_supply_unreg; } } fuelgauge->initial_update_of_soc = true; //Temporary Code - In Rev00 CL33, SOC is 0 even if Vcell is high enough. if (max77833_fg_read_vcell(fuelgauge) >= 3500 && max77833_fg_read_soc(fuelgauge) == 0) { if (max77833_fg_reset(fuelgauge)) pr_err("%s: FG Reset Done!!!!\n", __func__); else pr_err("%s: FG Reset Failed!!!!\n", __func__); } pr_info("%s: MAX77833 Fuelgauge Driver Loaded\n", __func__); return 0; err_supply_unreg: power_supply_unregister(&fuelgauge->psy_fg); err_data_free: #if defined(CONFIG_OF) kfree(fuelgauge->battery_data); #endif err_pdata_free: kfree(pdata->fuelgauge_data); mutex_destroy(&fuelgauge->fg_lock); err_free: kfree(fuelgauge); return ret; } static int __devexit max77833_fuelgauge_remove(struct platform_device *pdev) { struct max77833_fuelgauge_data *fuelgauge = platform_get_drvdata(pdev); if (fuelgauge->pdata->fuel_alert_soc >= 0) wake_lock_destroy(&fuelgauge->fuel_alert_wake_lock); return 0; } static int max77833_fuelgauge_suspend(struct device *dev) { return 0; } static int max77833_fuelgauge_resume(struct device *dev) { struct max77833_fuelgauge_data *fuelgauge = dev_get_drvdata(dev); fuelgauge->initial_update_of_soc = true; return 0; } static void max77833_fuelgauge_shutdown(struct device *dev) { } static SIMPLE_DEV_PM_OPS(max77833_fuelgauge_pm_ops, max77833_fuelgauge_suspend, max77833_fuelgauge_resume); static struct platform_driver max77833_fuelgauge_driver = { .driver = { .name = "max77833-fuelgauge", .owner = THIS_MODULE, #ifdef CONFIG_PM .pm = &max77833_fuelgauge_pm_ops, #endif .shutdown = max77833_fuelgauge_shutdown, }, .probe = max77833_fuelgauge_probe, .remove = __devexit_p(max77833_fuelgauge_remove), }; static int __init max77833_fuelgauge_init(void) { pr_info("%s: \n", __func__); return platform_driver_register(&max77833_fuelgauge_driver); } static void __exit max77833_fuelgauge_exit(void) { platform_driver_unregister(&max77833_fuelgauge_driver); } module_init(max77833_fuelgauge_init); module_exit(max77833_fuelgauge_exit); MODULE_DESCRIPTION("Samsung MAX77833 Fuel Gauge Driver"); MODULE_AUTHOR("Samsung Electronics"); MODULE_LICENSE("GPL");