// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (c) 2016-2019, The Linux Foundation. All rights reserved. * Copyright (c) 2023, Qualcomm Innovation Center, Inc. All rights reserved. */ #define pr_fmt(fmt) "LCDB: %s: " fmt, __func__ #include #include #include #include #include #include #include #include #include #include #include #include #define QPNP_LCDB_REGULATOR_DRIVER_NAME "qcom,qpnp-lcdb-regulator" #define QPNP_LCDB_REGULATOR_DRIVER_660 "qcom,lcdb-pm660" #define QPNP_LCDB_REGULATOR_DRIVER_632 "qcom,lcdb-pmi632" #define QPNP_LCDB_REGULATOR_DRIVER_6150L "qcom,lcdb-pm6150l" #define QPNP_LCDB_REGULATOR_DRIVER_7325B "qcom,lcdb-pm7325b" /* LCDB */ #define LCDB_REVISION3_REG 0x02 #define LCDB_REVISION4_REG 0x03 #define LCDB_STS1_REG 0x08 #define INT_RT_STATUS_REG 0x10 #define VREG_OK_RT_STS_BIT BIT(0) #define SC_ERROR_RT_STS_BIT BIT(1) #define LCDB_STS3_REG 0x0A #define LDO_VREG_OK_BIT BIT(7) #define LCDB_STS4_REG 0x0B #define NCP_VREG_OK_BIT BIT(7) #define LCDB_AUTO_TOUCH_WAKE_CTL_REG 0x40 #define EN_AUTO_TOUCH_WAKE_BIT BIT(7) #define ATTW_TOFF_TIME_MASK GENMASK(3, 2) #define ATTW_TON_TIME_MASK GENMASK(1, 0) #define ATTW_TOFF_TIME_SHIFT 2 #define ATTW_MIN_MS 4 #define ATTW_MAX_MS 32 #define LCDB_BST_OUTPUT_VOLTAGE_REG 0x41 #define PM660_BST_OUTPUT_VOLTAGE_MASK GENMASK(4, 0) #define BST_OUTPUT_VOLTAGE_MASK GENMASK(5, 0) #define PM7325B_BST_OUTPUT_VOLTAGE_MASK GENMASK(7, 0) #define LCDB_STEPPER_VOUT_CTL_REG 0x42 #define VOUT_STEP_DLY_2US 0x4 #define LCDB_CONFIG_SEL_REG 0x43 #define EN_FAST_STARTUP_BIT BIT(7) #define PDN_CONFIG_SEL_BIT BIT(4) #define PWRUP_CONFIG_SEL_MASK GENMASK(2, 0) #define PWRUP_CONFIG_MAX 0x4 #define LCDB_MODULE_RDY_REG 0x45 #define MODULE_RDY_BIT BIT(7) #define LCDB_ENABLE_CTL1_REG 0x46 #define MODULE_EN_BIT BIT(7) #define HWEN_RDY_BIT BIT(6) /* BST */ #define LCDB_BST_PD_CTL_REG 0x47 #define BOOST_DIS_PULLDOWN_BIT BIT(1) #define BOOST_PD_STRENGTH_BIT BIT(0) #define PM7325B_BOOST_EN_PULLDOWN_BIT BIT(7) #define LCDB_BST_ILIM_CTL_REG 0x4B #define EN_BST_ILIM_BIT BIT(7) #define SET_BST_ILIM_MASK GENMASK(2, 0) #define MIN_BST_ILIM_MA 200 #define MAX_BST_ILIM_MA 1600 #define PM7325B_MIN_BST_ILIM_MA 1130 #define PM7325B_MAX_BST_ILIM_MA 2250 #define PM7325B_BST_ILIM_MA_STEP 160 #define LCDB_PS_CTL_REG 0x50 #define EN_PS_BIT BIT(7) #define PM660_PS_THRESH_MASK GENMASK(1, 0) #define PS_THRESH_MASK GENMASK(2, 0) #define MIN_BST_PS_MA 50 #define MAX_BST_PS_MA 80 #define PM7325B_MIN_BST_PS_MV 360 #define PM7325B_MAX_BST_PS_MV 528 #define LCDB_RDSON_MGMNT_REG 0x53 #define NFET_SW_SIZE_MASK GENMASK(3, 2) #define NFET_SW_SIZE_SHIFT 2 #define PFET_SW_SIZE_MASK GENMASK(1, 0) #define PM7325B_LCDB_P2_BLANK_TIMER_REG 0x54 #define HIGH_P2_BLK_SEL_MASK GENMASK(6, 4) #define HIGH_P2_BLK_SEL_SHIFT 4 #define LOW_P2_BLK_SEL_MASK GENMASK(2, 0) #define LCDB_BST_VREG_OK_CTL_REG 0x55 #define BST_VREG_OK_DEB_MASK GENMASK(1, 0) #define PM7325B_LCDB_BST_VREG_OK_CTL_REG 0x56 #define LCDB_BST_SS_CTL_REG 0x5B #define BST_SS_TIME_MASK GENMASK(1, 0) #define BST_PRECHG_SHORT_ALARM_SHIFT 2 #define BST_PRECHARGE_DONE_DEB_BIT BIT(4) #define BST_SS_TIME_OVERRIDE_SHIFT 5 #define BST_SS_TIME_OVERRIDE_0MS 0 #define BST_SS_TIME_OVERRIDE_0P5_MS 1 #define BST_SS_TIME_OVERRIDE_1MS 2 #define BST_SS_TIME_OVERRIDE_2MS 3 #define EN_BST_PRECHG_SHORT_ALARM 0 #define DIS_BST_PRECHG_SHORT_ALARM 1 #define PM7325B_LCDB_WARMUP_DLY_SEL_1_REG 0x5C #define PM7325B_LCDB_WARMUP_DLY_SEL_2_REG 0x5D #define PM7325B_LCDB_PRECHARGE_CTL_REG 0x5E #define LCDB_SOFT_START_CTL_REG 0x5F #define LCDB_MISC_CTL_REG 0x60 #define AUTO_GM_EN_BIT BIT(4) #define EN_TOUCH_WAKE_BIT BIT(3) #define DIS_SCP_BIT BIT(0) #define PM7325B_LCDB_MPC_CTL_REG 0x60 #define MPC_NCP_SD_SEL_MASK GENMASK(2, 0) #define MPC_CURRENT_MIN 160 #define MPC_CURRENT_MAX 440 #define MPC_CURRENT_STEP 40 #define LCDB_PFM_CTL_REG 0x62 #define EN_PFM_BIT BIT(7) #define BYP_BST_SOFT_START_COMP_BIT BIT(0) #define PFM_HYSTERESIS_SHIFT 4 #define PFM_CURRENT_SHIFT 2 #define LCDB_PWRUP_PWRDN_CTL_REG 0x66 #define PWRUP_DELAY_MASK GENMASK(3, 2) #define PWRDN_DELAY_MASK GENMASK(1, 0) #define PWRUP_DELAY_SHIFT 2 #define PWRDN_DELAY_MIN_MS 0 #define PWRDN_DELAY_MAX_MS 8 /* LDO */ #define LCDB_LDO_OUTPUT_VOLTAGE_REG 0x71 #define SET_OUTPUT_VOLTAGE_MASK GENMASK(4, 0) #define PM7325B_SET_OUTPUT_VOLTAGE_MASK GENMASK(5, 0) #define LCDB_LDO_VREG_OK_CTL_REG 0x75 #define VREG_OK_DEB_MASK GENMASK(1, 0) #define LCDB_LDO_PD_CTL_REG 0x77 #define LDO_DIS_PULLDOWN_BIT BIT(1) #define LDO_PD_STRENGTH_BIT BIT(0) #define PM7325B_LDO_EN_PULLDOWN_BIT BIT(7) #define LCDB_LDO_FORCE_PD_CTL_REG 0x79 #define LDO_FORCE_PD_EN_BIT BIT(0) #define LDO_FORCE_PD_MODE BIT(7) #define LCDB_LDO_ILIM_CTL1_REG 0x7B #define EN_LDO_ILIM_BIT BIT(7) #define SET_LDO_ILIM_MASK GENMASK(2, 0) #define SET_LDO_ILIM_MASK_SD GENMASK(6, 4) #define SET_LDO_ILIM_MASK_SD_SHIFT 4 #define MIN_LDO_ILIM_MA 110 #define MAX_LDO_ILIM_MA 460 #define PM7325B_MIN_LDO_ILIM_MA 35 #define PM7325B_MAX_LDO_ILIM_MA 840 #define LDO_ILIM_STEP_MA 50 #define LCDB_LDO_ILIM_CTL2_REG 0x7C #define LCDB_LDO_SOFT_START_CTL_REG 0x7F #define SOFT_START_MASK GENMASK(1, 0) /* NCP */ #define LCDB_NCP_OUTPUT_VOLTAGE_REG 0x81 #define EN_NCP_VOUT_SYMMETRY_BIT BIT(7) #define LCDB_NCP_VREG_OK_CTL_REG 0x85 #define LCDB_NCP_PD_CTL_REG 0x87 #define NCP_DIS_PULLDOWN_BIT BIT(1) #define NCP_PD_STRENGTH_BIT BIT(0) #define PM7325B_EN_NCP_PULLDOWN_BIT BIT(1) #define PM7325B_EN_PD_SYMMETRY_BIT BIT(7) #define LCDB_NCP_ILIM_CTL1_REG 0x8B #define EN_NCP_ILIM_BIT BIT(7) #define SET_NCP_ILIM_MASK GENMASK(1, 0) #define PM7325B_SET_NCP_ILIM_SD_MASK GENMASK(5, 4) #define MIN_NCP_ILIM_MA 260 #define MAX_NCP_ILIM_MA 810 #define PM7325B_MIN_NCP_ILIM_MA 700 #define PM7325B_MAX_NCP_ILIM_MA 1000 #define LCDB_NCP_ILIM_CTL2_REG 0x8C #define LCDB_NCP_SOFT_START_CTL_REG 0x8F /* common for BST/NCP/LDO */ #define MIN_DBC_US 2 #define MAX_DBC_US 32 #define MIN_SOFT_START_US 0 #define MAX_SOFT_START_US 2000 #define PM660_BST_HEADROOM_DEFAULT_MV 200 #define BST_HEADROOM_DEFAULT_MV 150 #define PMIC5_LCDB_OFF_ON_DELAY_US 20000 struct ldo_regulator { struct regulator_desc rdesc; struct regulator_dev *rdev; struct device_node *node; /* LDO DT params */ int pd; int pd_strength; int ilim_ma; int soft_start_us; int vreg_ok_dbc_us; int voltage_mv; int prev_voltage_mv; }; struct ncp_regulator { struct regulator_desc rdesc; struct regulator_dev *rdev; struct device_node *node; /* NCP DT params */ int pd; int pd_strength; int ilim_ma; int soft_start_us; int vreg_ok_dbc_us; int voltage_mv; int prev_voltage_mv; }; struct bst_params { struct device_node *node; /* BST DT params */ int pd; int pd_strength; int ilim_ma; int ps; int ps_threshold; int soft_start_us; int vreg_ok_dbc_us; int voltage_mv; u16 headroom_mv; }; enum pmic_type { PM_DEFAULT, PM660L, PMI632, PM6150L, PM7325B, }; struct qpnp_lcdb { struct device *dev; struct platform_device *pdev; struct regmap *regmap; enum pmic_type subtype; u32 base; u32 wa_flags; int sc_irq; int pwrdn_delay_ms; int pwrup_delay_ms; int min_voltage_mv; int max_voltage_mv; int pwrup_config; int high_p2_blk_ns; int low_p2_blk_ns; int mpc_current_thr_ma; bool ncp_symmetry; /* TTW params */ bool ttw_enable; bool ttw_mode_sw; /* status parameters */ bool lcdb_enabled; bool settings_saved; bool lcdb_sc_disable; bool voltage_step_ramp; int sc_count; ktime_t sc_module_enable_time; struct mutex lcdb_mutex; struct mutex read_write_mutex; struct bst_params bst; struct ldo_regulator ldo; struct ncp_regulator ncp; }; struct settings { u16 address; u8 value; bool sec_access; bool valid; }; enum lcdb_module { LDO, NCP, BST, LDO_NCP, }; enum pfm_hysteresis { PFM_HYST_15MV, PFM_HYST_25MV, PFM_HYST_35MV, PFM_HYST_45MV, }; enum pfm_peak_current { PFM_PEAK_CURRENT_300MA, PFM_PEAK_CURRENT_400MA, PFM_PEAK_CURRENT_500MA, PFM_PEAK_CURRENT_600MA, }; enum rdson_fet_size { RDSON_QUARTER, RDSON_HALF, RDSON_THREE_FOURTH, RDSON_FULLSIZE, }; enum lcdb_settings_index { LCDB_BST_PD_CTL = 0, LCDB_RDSON_MGMNT, LCDB_MISC_CTL, LCDB_SOFT_START_CTL, LCDB_PFM_CTL, LCDB_PWRUP_PWRDN_CTL, LCDB_LDO_PD_CTL, LCDB_LDO_SOFT_START_CTL, LCDB_NCP_PD_CTL, LCDB_NCP_SOFT_START_CTL, LCDB_BST_SS_CTL, LCDB_LDO_VREG_OK_CTL, LCDB_STEPPER_VOUT_CTL, LCDB_CONFIG_SEL, PM7325B_LCDB_BST_VREG_OK_CTL, PM7325B_LCDB_WARMUP_DLY_SEL_1, PM7325B_LCDB_WARMUP_DLY_SEL_2, PM7325B_LCDB_PRECHARGE_CTL, LCDB_SETTING_MAX, }; enum lcdb_wa_flags { NCP_SCP_DISABLE_WA = BIT(0), FORCE_PD_ENABLE_WA = BIT(1), }; static const u32 soft_start_us[] = { 0, 500, 1000, 2000, }; static const u32 dbc_us[] = { 2, 4, 16, 32, }; static const u32 ncp_ilim_ma[] = { 260, 460, 640, 810, }; static const u32 pwrup_pwrdn_ms[] = { 0, 1, 4, 8, }; static const u32 ncp_dbc_us[] = { 64, 128, 256, 512, }; static const u32 bst_dbc_us[] = { 4, 8, 16, 32, }; static const u32 pm7325b_ncp_ilim_ma[] = { 700, 800, 900, 1000, }; static const u32 pm7325b_ldo_ilim_ma[] = { 35, 175, 280, 420, 455, 595, 700, 840, }; static const u32 pm7325b_p2_blk_ns[] = { 40, 69, 99, 129, 159, 189, 220, 250, }; #define SETTING(_id, _sec_access, _valid) \ [_id] = { \ .address = _id##_REG, \ .sec_access = _sec_access, \ .valid = _valid \ } \ static int qpnp_lcdb_set_voltage_step(struct qpnp_lcdb *lcdb, int voltage_start_mv, u8 type); static int qpnp_lcdb_set_voltage(struct qpnp_lcdb *lcdb, int voltage_mv, u8 type); static bool is_between(int value, int min, int max) { if (value < min || value > max) return false; return true; } static int qpnp_lcdb_read(struct qpnp_lcdb *lcdb, u16 addr, u8 *value, u8 count) { int rc = 0; mutex_lock(&lcdb->read_write_mutex); rc = regmap_bulk_read(lcdb->regmap, addr, value, count); if (rc < 0) pr_err("Failed to read from addr=0x%02x rc=%d\n", addr, rc); mutex_unlock(&lcdb->read_write_mutex); return rc; } static int qpnp_lcdb_write(struct qpnp_lcdb *lcdb, u16 addr, u8 *value, u8 count) { int rc; mutex_lock(&lcdb->read_write_mutex); rc = regmap_bulk_write(lcdb->regmap, addr, value, count); if (rc < 0) pr_err("Failed to write to addr=0x%02x rc=%d\n", addr, rc); mutex_unlock(&lcdb->read_write_mutex); return rc; } #define SEC_ADDRESS_REG 0xD0 #define SECURE_UNLOCK_VALUE 0xA5 static int qpnp_lcdb_secure_write(struct qpnp_lcdb *lcdb, u16 addr, u8 value) { int rc; u8 val = SECURE_UNLOCK_VALUE; mutex_lock(&lcdb->read_write_mutex); if (lcdb->subtype == PM660L) { rc = regmap_write(lcdb->regmap, lcdb->base + SEC_ADDRESS_REG, val); if (rc < 0) { pr_err("Failed to unlock register rc=%d\n", rc); goto fail_write; } } rc = regmap_write(lcdb->regmap, addr, value); if (rc < 0) pr_err("Failed to write to addr=0x%02x rc=%d\n", addr, rc); fail_write: mutex_unlock(&lcdb->read_write_mutex); return rc; } static int qpnp_lcdb_masked_write(struct qpnp_lcdb *lcdb, u16 addr, u8 mask, u8 value) { int rc = 0; mutex_lock(&lcdb->read_write_mutex); rc = regmap_update_bits(lcdb->regmap, addr, mask, value); if (rc < 0) pr_err("Failed to write addr=0x%02x value=0x%02x rc=%d\n", addr, value, rc); mutex_unlock(&lcdb->read_write_mutex); return rc; } static bool is_lcdb_enabled(struct qpnp_lcdb *lcdb) { int rc; u8 val = 0; rc = qpnp_lcdb_read(lcdb, lcdb->base + LCDB_ENABLE_CTL1_REG, &val, 1); if (rc < 0) pr_err("Failed to read ENABLE_CTL1 rc=%d\n", rc); return rc ? false : !!(val & MODULE_EN_BIT); } static int dump_status_registers(struct qpnp_lcdb *lcdb) { int rc = 0, len = (lcdb->subtype == PM7325B) ? 5 : 6; u8 sts[6] = {0}; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_STS1_REG, &sts[0], len); if (rc < 0) { pr_err("Failed to write to STS registers rc=%d\n", rc); } else { rc = qpnp_lcdb_read(lcdb, lcdb->base + LCDB_STS1_REG, sts, len); if (rc < 0) pr_err("Failed to read lcdb status rc=%d\n", rc); else { pr_err("STS1=0x%02x STS2=0x%02x STS3=0x%02x STS4=0x%02x STS5=0x%02x\n", sts[0], sts[1], sts[2], sts[3], sts[4]); if (lcdb->subtype != PM7325B) pr_err("STS6=0x%02x\n", sts[5]); } } return rc; } static struct settings lcdb_settings_pm660l[] = { SETTING(LCDB_BST_PD_CTL, false, true), SETTING(LCDB_RDSON_MGMNT, false, true), SETTING(LCDB_MISC_CTL, false, true), SETTING(LCDB_SOFT_START_CTL, false, true), SETTING(LCDB_PFM_CTL, false, true), SETTING(LCDB_PWRUP_PWRDN_CTL, true, true), SETTING(LCDB_LDO_PD_CTL, false, true), SETTING(LCDB_LDO_SOFT_START_CTL, false, true), SETTING(LCDB_NCP_PD_CTL, false, true), SETTING(LCDB_NCP_SOFT_START_CTL, false, true), SETTING(LCDB_BST_SS_CTL, false, false), SETTING(LCDB_LDO_VREG_OK_CTL, false, false), }; /* For PMICs like pmi632/pm8150L */ static struct settings lcdb_settings[] = { SETTING(LCDB_BST_PD_CTL, false, true), SETTING(LCDB_RDSON_MGMNT, false, false), SETTING(LCDB_MISC_CTL, false, false), SETTING(LCDB_SOFT_START_CTL, false, false), SETTING(LCDB_PFM_CTL, false, false), SETTING(LCDB_PWRUP_PWRDN_CTL, false, true), SETTING(LCDB_LDO_PD_CTL, false, true), SETTING(LCDB_LDO_SOFT_START_CTL, false, true), SETTING(LCDB_NCP_PD_CTL, false, true), SETTING(LCDB_NCP_SOFT_START_CTL, false, true), SETTING(LCDB_BST_SS_CTL, false, true), SETTING(LCDB_LDO_VREG_OK_CTL, false, true), }; static struct settings lcdb_settings_pm7325b[] = { SETTING(LCDB_BST_PD_CTL, false, true), SETTING(LCDB_RDSON_MGMNT, false, false), SETTING(LCDB_MISC_CTL, false, false), SETTING(LCDB_SOFT_START_CTL, false, false), SETTING(LCDB_PFM_CTL, false, false), SETTING(LCDB_PWRUP_PWRDN_CTL, false, false), SETTING(LCDB_LDO_PD_CTL, false, true), SETTING(LCDB_LDO_SOFT_START_CTL, false, true), SETTING(LCDB_NCP_PD_CTL, false, true), SETTING(LCDB_NCP_SOFT_START_CTL, false, true), SETTING(LCDB_BST_SS_CTL, false, true), SETTING(LCDB_LDO_VREG_OK_CTL, false, false), SETTING(PM7325B_LCDB_BST_VREG_OK_CTL, false, true), SETTING(LCDB_STEPPER_VOUT_CTL, false, true), SETTING(LCDB_CONFIG_SEL, false, true), SETTING(PM7325B_LCDB_WARMUP_DLY_SEL_1, false, true), SETTING(PM7325B_LCDB_WARMUP_DLY_SEL_2, false, true), SETTING(PM7325B_LCDB_PRECHARGE_CTL, false, true), }; static int qpnp_lcdb_save_settings(struct qpnp_lcdb *lcdb) { int i, size, rc = 0; struct settings *setting; switch (lcdb->subtype) { case PM660L: setting = lcdb_settings_pm660l; size = ARRAY_SIZE(lcdb_settings_pm660l); break; case PM7325B: setting = lcdb_settings_pm7325b; size = ARRAY_SIZE(lcdb_settings_pm7325b); break; default: setting = lcdb_settings; size = ARRAY_SIZE(lcdb_settings); break; } for (i = 0; i < size; i++) { if (setting[i].valid) { rc = qpnp_lcdb_read(lcdb, lcdb->base + setting[i].address, &setting[i].value, 1); if (rc < 0) { pr_err("Failed to read lcdb register address=%x\n", setting[i].address); return rc; } } } return 0; } static int qpnp_lcdb_restore_settings(struct qpnp_lcdb *lcdb) { int i, size, rc = 0; struct settings *setting; switch (lcdb->subtype) { case PM660L: setting = lcdb_settings_pm660l; size = ARRAY_SIZE(lcdb_settings_pm660l); break; case PM7325B: setting = lcdb_settings_pm7325b; size = ARRAY_SIZE(lcdb_settings_pm7325b); break; default: setting = lcdb_settings; size = ARRAY_SIZE(lcdb_settings); break; } for (i = 0; i < size; i++) { if (setting[i].valid) { if (setting[i].sec_access) rc = qpnp_lcdb_secure_write(lcdb, lcdb->base + setting[i].address, setting[i].value); else rc = qpnp_lcdb_write(lcdb, lcdb->base + setting[i].address, &setting[i].value, 1); if (rc < 0) { pr_err("Failed to write register address=%x\n", setting[i].address); return rc; } } } return 0; } static int qpnp_lcdb_ttw_enter(struct qpnp_lcdb *lcdb) { int rc; u8 val; if (!lcdb->settings_saved) { rc = qpnp_lcdb_save_settings(lcdb); if (rc < 0) { pr_err("Failed to save LCDB settings rc=%d\n", rc); return rc; } lcdb->settings_saved = true; } val = (BST_SS_TIME_OVERRIDE_1MS << BST_SS_TIME_OVERRIDE_SHIFT) | (DIS_BST_PRECHG_SHORT_ALARM << BST_PRECHG_SHORT_ALARM_SHIFT); rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_BST_SS_CTL_REG, &val, 1); if (rc < 0) return rc; val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_NCP_SOFT_START_CTL_REG, &val, 1); if (rc < 0) return rc; val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_LDO_SOFT_START_CTL_REG, &val, 1); if (rc < 0) return rc; val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_PWRUP_PWRDN_CTL_REG, &val, 1); if (rc < 0) return rc; val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_BST_VREG_OK_CTL_REG, &val, 1); if (rc < 0) return rc; val = BOOST_DIS_PULLDOWN_BIT; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_BST_PD_CTL_REG, &val, 1); if (rc < 0) return rc; val = LDO_DIS_PULLDOWN_BIT; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_LDO_PD_CTL_REG, &val, 1); if (rc < 0) return rc; val = NCP_DIS_PULLDOWN_BIT; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_NCP_PD_CTL_REG, &val, 1); if (rc < 0) return rc; val = HWEN_RDY_BIT; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_ENABLE_CTL1_REG, &val, 1); return rc; } static int qpnp_lcdb_ttw_enter_pm660l(struct qpnp_lcdb *lcdb) { int rc; u8 val; if (!lcdb->settings_saved) { rc = qpnp_lcdb_save_settings(lcdb); if (rc < 0) { pr_err("Failed to save LCDB settings rc=%d\n", rc); return rc; } lcdb->settings_saved = true; } val = BOOST_DIS_PULLDOWN_BIT; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_BST_PD_CTL_REG, &val, 1); if (rc < 0) { pr_err("Failed to set BST PD rc=%d\n", rc); return rc; } val = (RDSON_HALF << NFET_SW_SIZE_SHIFT) | RDSON_HALF; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_RDSON_MGMNT_REG, &val, 1); if (rc < 0) { pr_err("Failed to set RDSON MGMT rc=%d\n", rc); return rc; } val = AUTO_GM_EN_BIT | EN_TOUCH_WAKE_BIT | DIS_SCP_BIT; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_MISC_CTL_REG, &val, 1); if (rc < 0) { pr_err("Failed to set MISC CTL rc=%d\n", rc); return rc; } val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_SOFT_START_CTL_REG, &val, 1); if (rc < 0) { pr_err("Failed to set LCDB_SOFT_START rc=%d\n", rc); return rc; } val = EN_PFM_BIT | (PFM_HYST_25MV << PFM_HYSTERESIS_SHIFT) | (PFM_PEAK_CURRENT_400MA << PFM_CURRENT_SHIFT) | BYP_BST_SOFT_START_COMP_BIT; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_PFM_CTL_REG, &val, 1); if (rc < 0) { pr_err("Failed to set PFM_CTL rc=%d\n", rc); return rc; } val = 0; rc = qpnp_lcdb_secure_write(lcdb, lcdb->base + LCDB_PWRUP_PWRDN_CTL_REG, val); if (rc < 0) { pr_err("Failed to set PWRUP_PWRDN_CTL rc=%d\n", rc); return rc; } val = LDO_DIS_PULLDOWN_BIT; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_LDO_PD_CTL_REG, &val, 1); if (rc < 0) { pr_err("Failed to set LDO_PD_CTL rc=%d\n", rc); return rc; } val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_LDO_SOFT_START_CTL_REG, &val, 1); if (rc < 0) { pr_err("Failed to set LDO_SOFT_START rc=%d\n", rc); return rc; } val = NCP_DIS_PULLDOWN_BIT; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_NCP_PD_CTL_REG, &val, 1); if (rc < 0) { pr_err("Failed to set NCP_PD_CTL rc=%d\n", rc); return rc; } val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_NCP_SOFT_START_CTL_REG, &val, 1); if (rc < 0) { pr_err("Failed to set NCP_SOFT_START rc=%d\n", rc); return rc; } if (lcdb->ttw_mode_sw) { rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_AUTO_TOUCH_WAKE_CTL_REG, EN_AUTO_TOUCH_WAKE_BIT, EN_AUTO_TOUCH_WAKE_BIT); if (rc < 0) pr_err("Failed to enable auto(sw) TTW\n rc = %d\n", rc); } else { val = HWEN_RDY_BIT; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_ENABLE_CTL1_REG, &val, 1); if (rc < 0) pr_err("Failed to hw_enable lcdb rc= %d\n", rc); } return rc; } static int qpnp_lcdb_ttw_enter_pm7325b(struct qpnp_lcdb *lcdb) { int rc; u8 val; if (!lcdb->settings_saved) { rc = qpnp_lcdb_save_settings(lcdb); if (rc < 0) { pr_err("Failed to save LCDB settings rc=%d\n", rc); return rc; } lcdb->settings_saved = true; } val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_BST_PD_CTL_REG, &val, 1); if (rc < 0) return rc; val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + PM7325B_LCDB_BST_VREG_OK_CTL_REG, &val, 1); if (rc < 0) return rc; val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + PM7325B_LCDB_WARMUP_DLY_SEL_1_REG, &val, 1); if (rc < 0) return rc; val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + PM7325B_LCDB_WARMUP_DLY_SEL_2_REG, &val, 1); if (rc < 0) return rc; val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + PM7325B_LCDB_PRECHARGE_CTL_REG, &val, 1); if (rc < 0) return rc; val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_BST_SS_CTL_REG, &val, 1); if (rc < 0) return rc; val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_LDO_PD_CTL_REG, &val, 1); if (rc < 0) return rc; val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_LDO_SOFT_START_CTL_REG, &val, 1); if (rc < 0) return rc; val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_NCP_PD_CTL_REG, &val, 1); if (rc < 0) return rc; val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_NCP_SOFT_START_CTL_REG, &val, 1); if (rc < 0) return rc; val = VOUT_STEP_DLY_2US; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_STEPPER_VOUT_CTL_REG, &val, 1); if (rc < 0) return rc; val = EN_FAST_STARTUP_BIT; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_CONFIG_SEL_REG, &val, 1); if (rc < 0) return rc; val = HWEN_RDY_BIT; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_ENABLE_CTL1_REG, &val, 1); return rc; } static int qpnp_lcdb_ttw_exit(struct qpnp_lcdb *lcdb) { int rc; if (lcdb->settings_saved) { rc = qpnp_lcdb_restore_settings(lcdb); if (rc < 0) { pr_err("Failed to restore lcdb settings rc=%d\n", rc); return rc; } lcdb->settings_saved = false; } return 0; } static int qpnp_lcdb_enable_wa(struct qpnp_lcdb *lcdb) { int rc; u8 val = 0; /* required only for PM660L */ if (lcdb->subtype != PM660L) return 0; val = MODULE_EN_BIT; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_ENABLE_CTL1_REG, &val, 1); if (rc < 0) { pr_err("Failed to enable lcdb rc= %d\n", rc); return rc; } val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_ENABLE_CTL1_REG, &val, 1); if (rc < 0) { pr_err("Failed to disable lcdb rc= %d\n", rc); return rc; } return 0; } #define VOLTAGE_START_MV 4500 #define VOLTAGE_STEP_MV 500 static int qpnp_lcdb_enable(struct qpnp_lcdb *lcdb) { int rc = 0, timeout, delay; int voltage_mv = VOLTAGE_START_MV; u8 val = 0; if (lcdb->lcdb_enabled || lcdb->lcdb_sc_disable) { pr_debug("lcdb_enabled=%d lcdb_sc_disable=%d\n", lcdb->lcdb_enabled, lcdb->lcdb_sc_disable); return 0; } if (lcdb->ttw_enable) { rc = qpnp_lcdb_ttw_exit(lcdb); if (rc < 0) { pr_err("Failed to exit TTW mode rc=%d\n", rc); return rc; } } rc = qpnp_lcdb_enable_wa(lcdb); if (rc < 0) { pr_err("Failed to execute enable_wa rc=%d\n", rc); return rc; } if (lcdb->voltage_step_ramp) { if (lcdb->ldo.voltage_mv < VOLTAGE_START_MV) voltage_mv = lcdb->ldo.voltage_mv; rc = qpnp_lcdb_set_voltage(lcdb, voltage_mv, LDO); if (rc < 0) return rc; if (lcdb->ncp.voltage_mv < VOLTAGE_START_MV) voltage_mv = lcdb->ncp.voltage_mv; rc = qpnp_lcdb_set_voltage(lcdb, voltage_mv, NCP); if (rc < 0) return rc; } val = MODULE_EN_BIT; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_ENABLE_CTL1_REG, &val, 1); if (rc < 0) { pr_err("Failed to disable lcdb rc= %d\n", rc); goto fail_enable; } /* poll for vreg_ok */ timeout = 10; delay = lcdb->bst.soft_start_us + lcdb->ldo.soft_start_us + lcdb->ncp.soft_start_us; delay += lcdb->bst.vreg_ok_dbc_us + lcdb->ldo.vreg_ok_dbc_us + lcdb->ncp.vreg_ok_dbc_us; while (timeout--) { rc = qpnp_lcdb_read(lcdb, lcdb->base + INT_RT_STATUS_REG, &val, 1); if (rc < 0) { pr_err("Failed to poll for vreg-ok status rc=%d\n", rc); break; } if (val & VREG_OK_RT_STS_BIT) break; usleep_range(delay, delay + 100); } if (rc || !timeout) { if (!timeout) { pr_err("lcdb-vreg-ok status failed to change\n"); rc = -ETIMEDOUT; } goto fail_enable; } lcdb->lcdb_enabled = true; if (lcdb->voltage_step_ramp) { usleep_range(10000, 11000); rc = qpnp_lcdb_set_voltage_step(lcdb, voltage_mv + VOLTAGE_STEP_MV, LDO_NCP); if (rc < 0) { pr_err("Failed to set LCDB voltage rc=%d\n", rc); return rc; } } pr_debug("lcdb enabled successfully!\n"); return 0; fail_enable: dump_status_registers(lcdb); pr_err("Failed to enable lcdb rc=%d\n", rc); return rc; } static int qpnp_lcdb_disable(struct qpnp_lcdb *lcdb) { int rc = 0; u8 val = 0; if (!lcdb->lcdb_enabled) return 0; if (lcdb->ttw_enable) { switch (lcdb->subtype) { case PM660L: rc = qpnp_lcdb_ttw_enter_pm660l(lcdb); break; case PM7325B: rc = qpnp_lcdb_ttw_enter_pm7325b(lcdb); break; default: rc = qpnp_lcdb_ttw_enter(lcdb); break; } if (rc < 0) { pr_err("Failed to enable TTW mode rc=%d\n", rc); return rc; } lcdb->lcdb_enabled = false; return 0; } if (lcdb->wa_flags & FORCE_PD_ENABLE_WA) { /* * force pull-down to enable quick discharge after * turning off */ val = LDO_FORCE_PD_EN_BIT | LDO_FORCE_PD_MODE; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_LDO_FORCE_PD_CTL_REG, &val, 1); if (rc < 0) return rc; } val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_ENABLE_CTL1_REG, &val, 1); if (rc < 0) pr_err("Failed to disable lcdb rc= %d\n", rc); else lcdb->lcdb_enabled = false; if (lcdb->wa_flags & FORCE_PD_ENABLE_WA) { /* wait for 10 msec after module disable for LDO to discharge */ usleep_range(10000, 11000); val = 0; rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_LDO_FORCE_PD_CTL_REG, &val, 1); if (rc < 0) return rc; } return rc; } #define LCDB_SC_RESET_CNT_DLY_US 1000000 #define LCDB_SC_CNT_MAX 10 static int qpnp_lcdb_handle_sc_event(struct qpnp_lcdb *lcdb) { int rc = 0; s64 elapsed_time_us; mutex_lock(&lcdb->lcdb_mutex); rc = qpnp_lcdb_disable(lcdb); if (rc < 0) { pr_err("Failed to disable lcdb rc=%d\n", rc); goto unlock_mutex; } /* Check if the SC re-occurred immediately */ elapsed_time_us = ktime_us_delta(ktime_get(), lcdb->sc_module_enable_time); if (elapsed_time_us > LCDB_SC_RESET_CNT_DLY_US) { lcdb->sc_count = 0; } else if (lcdb->sc_count > LCDB_SC_CNT_MAX) { pr_err("SC triggered %d times, disabling LCDB forever!\n", lcdb->sc_count); lcdb->lcdb_sc_disable = true; goto unlock_mutex; } lcdb->sc_count++; lcdb->sc_module_enable_time = ktime_get(); /* delay for SC to clear */ usleep_range(10000, 10100); rc = qpnp_lcdb_enable(lcdb); if (rc < 0) pr_err("Failed to enable lcdb rc=%d\n", rc); unlock_mutex: mutex_unlock(&lcdb->lcdb_mutex); return rc; } static irqreturn_t qpnp_lcdb_sc_irq_handler(int irq, void *data) { struct qpnp_lcdb *lcdb = data; int rc; u8 val, val2[2] = {0}; mutex_lock(&lcdb->lcdb_mutex); rc = qpnp_lcdb_read(lcdb, lcdb->base + INT_RT_STATUS_REG, &val, 1); mutex_unlock(&lcdb->lcdb_mutex); if (rc < 0) goto irq_handled; if (val & SC_ERROR_RT_STS_BIT) { rc = qpnp_lcdb_read(lcdb, lcdb->base + LCDB_MISC_CTL_REG, &val, 1); if (rc < 0) goto irq_handled; if (lcdb->subtype == PM660L && (val & EN_TOUCH_WAKE_BIT)) { /* blanking time */ usleep_range(300, 310); /* * The status registers need to written with any value * before reading */ rc = qpnp_lcdb_write(lcdb, lcdb->base + LCDB_STS3_REG, val2, 2); if (rc < 0) goto irq_handled; rc = qpnp_lcdb_read(lcdb, lcdb->base + LCDB_STS3_REG, val2, 2); if (rc < 0) goto irq_handled; if (!(val2[0] & LDO_VREG_OK_BIT) || !(val2[1] & NCP_VREG_OK_BIT)) { rc = qpnp_lcdb_handle_sc_event(lcdb); if (rc < 0) { pr_err("Failed to handle SC rc=%d\n", rc); goto irq_handled; } } } else { /* blanking time */ usleep_range(2000, 2100); /* Read the SC status again to confirm true SC */ mutex_lock(&lcdb->lcdb_mutex); /* * Wait for the completion of LCDB module enable, * which could be initiated in a previous SC event, * to avoid multiple module disable/enable calls. */ rc = qpnp_lcdb_read(lcdb, lcdb->base + INT_RT_STATUS_REG, &val, 1); mutex_unlock(&lcdb->lcdb_mutex); if (rc < 0) goto irq_handled; if (val & SC_ERROR_RT_STS_BIT) { rc = qpnp_lcdb_handle_sc_event(lcdb); if (rc < 0) { pr_err("Failed to handle SC rc=%d\n", rc); goto irq_handled; } } } } irq_handled: return IRQ_HANDLED; } #define MIN_BST_VOLTAGE_MV 4700 #define PM7325B_MIN_BST_VOLTAGE_MV 2000 #define PM660_MAX_BST_VOLTAGE_MV 6250 #define MAX_BST_VOLTAGE_MV 6275 #define PM7325B_MAX_BST_VOLTAGE_MV 6400 #define MIN_VOLTAGE_MV 4000 #define MAX_VOLTAGE_MV 6000 #define PM7325B_MIN_VOLTAGE_MV 4400 #define PM7325B_MAX_VOLTAGE_MV 6000 #define VOLTAGE_MIN_STEP_100_MV 4000 #define VOLTAGE_MIN_STEP_50_MV 4950 #define VOLTAGE_STEP_100_MV 100 #define VOLTAGE_STEP_50_MV 50 #define VOLTAGE_STEP_25_MV 25 #define VOLTAGE_STEP_50MV_OFFSET 0xA static int qpnp_lcdb_set_bst_voltage(struct qpnp_lcdb *lcdb, int voltage_mv, u8 type) { int rc = 0; u8 val, voltage_step, mask = 0; int bst_voltage_mv, min_bst_voltage; struct ldo_regulator *ldo = &lcdb->ldo; struct ncp_regulator *ncp = &lcdb->ncp; struct bst_params *bst = &lcdb->bst; /* Vout_Boost = headroom_mv + max( Vout_LDO, abs (Vout_NCP)) */ bst_voltage_mv = max(voltage_mv, max(ldo->voltage_mv, ncp->voltage_mv)); bst_voltage_mv += bst->headroom_mv; if (bst_voltage_mv < MIN_BST_VOLTAGE_MV) bst_voltage_mv = MIN_BST_VOLTAGE_MV; switch (lcdb->subtype) { case PM660L: if (bst_voltage_mv > PM660_MAX_BST_VOLTAGE_MV) bst_voltage_mv = PM660_MAX_BST_VOLTAGE_MV; break; case PM7325B: if (bst_voltage_mv > PM7325B_MAX_BST_VOLTAGE_MV) bst_voltage_mv = PM7325B_MAX_BST_VOLTAGE_MV; break; default: if (bst_voltage_mv > MAX_BST_VOLTAGE_MV) bst_voltage_mv = MAX_BST_VOLTAGE_MV; break; } if (bst_voltage_mv != bst->voltage_mv) { switch (lcdb->subtype) { case PM660L: mask = PM660_BST_OUTPUT_VOLTAGE_MASK; voltage_step = VOLTAGE_STEP_50_MV; min_bst_voltage = MIN_BST_VOLTAGE_MV; break; case PM7325B: mask = PM7325B_BST_OUTPUT_VOLTAGE_MASK; voltage_step = VOLTAGE_STEP_25_MV; min_bst_voltage = PM7325B_MIN_BST_VOLTAGE_MV; break; default: mask = BST_OUTPUT_VOLTAGE_MASK; voltage_step = VOLTAGE_STEP_25_MV; min_bst_voltage = MIN_BST_VOLTAGE_MV; break; } val = DIV_ROUND_UP(bst_voltage_mv - min_bst_voltage, voltage_step); rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_BST_OUTPUT_VOLTAGE_REG, mask, val); if (rc < 0) { pr_err("Failed to set boost voltage %d mv rc=%d\n", bst_voltage_mv, rc); } else { pr_debug("Boost voltage set = %d mv (0x%02x = 0x%02x)\n", bst_voltage_mv, LCDB_BST_OUTPUT_VOLTAGE_REG, val); bst->voltage_mv = bst_voltage_mv; } } return rc; } static int qpnp_lcdb_get_bst_voltage(struct qpnp_lcdb *lcdb, int *voltage_mv) { int rc, min_bst_voltage; u8 val, voltage_step, mask = 0; rc = qpnp_lcdb_read(lcdb, lcdb->base + LCDB_BST_OUTPUT_VOLTAGE_REG, &val, 1); if (rc < 0) { pr_err("Failed to reat BST voltage rc=%d\n", rc); return rc; } switch (lcdb->subtype) { case PM660L: mask = PM660_BST_OUTPUT_VOLTAGE_MASK; voltage_step = VOLTAGE_STEP_50_MV; min_bst_voltage = MIN_BST_VOLTAGE_MV; break; case PM7325B: mask = PM7325B_BST_OUTPUT_VOLTAGE_MASK; voltage_step = VOLTAGE_STEP_25_MV; min_bst_voltage = PM7325B_MIN_BST_VOLTAGE_MV; break; default: mask = BST_OUTPUT_VOLTAGE_MASK; voltage_step = VOLTAGE_STEP_25_MV; min_bst_voltage = MIN_BST_VOLTAGE_MV; } val &= mask; *voltage_mv = (val * voltage_step) + min_bst_voltage; return 0; } static int qpnp_lcdb_set_voltage(struct qpnp_lcdb *lcdb, int voltage_mv, u8 type) { int rc = 0; u16 offset = LCDB_LDO_OUTPUT_VOLTAGE_REG; u8 val = 0; int voltage_mask = (lcdb->subtype == PM7325B) ? PM7325B_SET_OUTPUT_VOLTAGE_MASK : SET_OUTPUT_VOLTAGE_MASK; if (!is_between(voltage_mv, lcdb->min_voltage_mv, lcdb->max_voltage_mv)) { pr_err("Invalid voltage %dmv (min=%d max=%d)\n", voltage_mv, lcdb->min_voltage_mv, lcdb->max_voltage_mv); return -EINVAL; } rc = qpnp_lcdb_set_bst_voltage(lcdb, voltage_mv, type); if (rc < 0) { pr_err("Failed to set boost voltage rc=%d\n", rc); return rc; } /* Below logic is only valid for LDO and NCP type */ if (voltage_mv < VOLTAGE_MIN_STEP_50_MV) { val = DIV_ROUND_UP(voltage_mv - VOLTAGE_MIN_STEP_100_MV, VOLTAGE_STEP_100_MV); } else { val = DIV_ROUND_UP(voltage_mv - VOLTAGE_MIN_STEP_50_MV, VOLTAGE_STEP_50_MV); val += VOLTAGE_STEP_50MV_OFFSET; } if (type == NCP) offset = LCDB_NCP_OUTPUT_VOLTAGE_REG; rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + offset, voltage_mask, val); if (rc < 0) pr_err("Failed to set output voltage %d mv for %s rc=%d\n", voltage_mv, (type == LDO) ? "LDO" : "NCP", rc); else pr_debug("%s voltage set = %d mv (0x%02x = 0x%02x)\n", (type == LDO) ? "LDO" : "NCP", voltage_mv, offset, val); return rc; } static int qpnp_lcdb_set_voltage_step(struct qpnp_lcdb *lcdb, int voltage_start_mv, u8 type) { int i, ldo_voltage, ncp_voltage, voltage, rc = 0; for (i = voltage_start_mv; i <= (MAX_VOLTAGE_MV + VOLTAGE_STEP_MV); i += VOLTAGE_STEP_MV) { ldo_voltage = (lcdb->ldo.voltage_mv < i) ? lcdb->ldo.voltage_mv : i; ncp_voltage = (lcdb->ncp.voltage_mv < i) ? lcdb->ncp.voltage_mv : i; if (type == LDO_NCP) { rc = qpnp_lcdb_set_voltage(lcdb, ldo_voltage, LDO); if (rc < 0) return rc; rc = qpnp_lcdb_set_voltage(lcdb, ncp_voltage, NCP); if (rc < 0) return rc; pr_debug(" LDO voltage step %d NCP voltage step %d\n", ldo_voltage, ncp_voltage); if ((i >= lcdb->ncp.voltage_mv) && (i >= lcdb->ldo.voltage_mv)) break; } else { voltage = (type == LDO) ? ldo_voltage : ncp_voltage; rc = qpnp_lcdb_set_voltage(lcdb, voltage, type); if (rc < 0) return rc; pr_debug("%s voltage step %d\n", (type == LDO) ? "LDO" : "NCP", voltage); if ((type == LDO) && (i >= lcdb->ldo.voltage_mv)) break; if ((type == NCP) && (i >= lcdb->ncp.voltage_mv)) break; } usleep_range(1000, 1100); } return rc; } static int qpnp_lcdb_get_voltage(struct qpnp_lcdb *lcdb, u32 *voltage_mv, u8 type) { int rc = 0; u16 offset = LCDB_LDO_OUTPUT_VOLTAGE_REG; u8 val = 0; int voltage_mask = (lcdb->subtype == PM7325B) ? PM7325B_SET_OUTPUT_VOLTAGE_MASK : SET_OUTPUT_VOLTAGE_MASK; if (type == BST) return qpnp_lcdb_get_bst_voltage(lcdb, voltage_mv); /* When symmetry is enabled, NCP voltage directly follows LDO voltage */ if (type == NCP && !lcdb->ncp_symmetry) offset = LCDB_NCP_OUTPUT_VOLTAGE_REG; rc = qpnp_lcdb_read(lcdb, lcdb->base + offset, &val, 1); if (rc < 0) { pr_err("Failed to read %s volatge rc=%d\n", (type == LDO) ? "LDO" : "NCP", rc); return rc; } val &= voltage_mask; if (val < VOLTAGE_STEP_50MV_OFFSET) { *voltage_mv = VOLTAGE_MIN_STEP_100_MV + (val * VOLTAGE_STEP_100_MV); } else { *voltage_mv = VOLTAGE_MIN_STEP_50_MV + ((val - VOLTAGE_STEP_50MV_OFFSET) * VOLTAGE_STEP_50_MV); } if (!rc) pr_debug("%s voltage read-back = %d mv (0x%02x = 0x%02x)\n", (type == LDO) ? "LDO" : "NCP", *voltage_mv, offset, val); return rc; } static int qpnp_lcdb_set_soft_start(struct qpnp_lcdb *lcdb, u32 ss_us, u8 type) { int rc = 0, i = 0; u16 offset = LCDB_LDO_SOFT_START_CTL_REG; u8 val = 0; if (type == NCP) offset = LCDB_NCP_SOFT_START_CTL_REG; if (!is_between(ss_us, MIN_SOFT_START_US, MAX_SOFT_START_US)) { pr_err("Invalid soft_start_us %d (min=%d max=%d)\n", ss_us, MIN_SOFT_START_US, MAX_SOFT_START_US); return -EINVAL; } i = 0; while (ss_us >= soft_start_us[i]) i++; val = ((i == 0) ? 0 : i - 1) & SOFT_START_MASK; rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + offset, SOFT_START_MASK, val); if (rc < 0) pr_err("Failed to write %s soft-start time %d rc=%d\n", (type == LDO) ? "LDO" : "NCP", soft_start_us[i], rc); return rc; } static int qpnp_lcdb_ldo_regulator_enable(struct regulator_dev *rdev) { int rc = 0; struct qpnp_lcdb *lcdb = rdev_get_drvdata(rdev); mutex_lock(&lcdb->lcdb_mutex); rc = qpnp_lcdb_enable(lcdb); if (rc < 0) pr_err("Failed to enable lcdb rc=%d\n", rc); mutex_unlock(&lcdb->lcdb_mutex); return rc; } static int qpnp_lcdb_ldo_regulator_disable(struct regulator_dev *rdev) { int rc = 0; struct qpnp_lcdb *lcdb = rdev_get_drvdata(rdev); mutex_lock(&lcdb->lcdb_mutex); rc = qpnp_lcdb_disable(lcdb); if (rc < 0) pr_err("Failed to disable lcdb rc=%d\n", rc); mutex_unlock(&lcdb->lcdb_mutex); return rc; } static int qpnp_lcdb_ldo_regulator_is_enabled(struct regulator_dev *rdev) { struct qpnp_lcdb *lcdb = rdev_get_drvdata(rdev); return lcdb->lcdb_enabled; } static int qpnp_lcdb_ldo_regulator_set_voltage(struct regulator_dev *rdev, int min_uV, int max_uV, unsigned int *selector) { int rc = 0; struct qpnp_lcdb *lcdb = rdev_get_drvdata(rdev); lcdb->ldo.voltage_mv = min_uV / 1000; if (lcdb->voltage_step_ramp) rc = qpnp_lcdb_set_voltage_step(lcdb, lcdb->ldo.prev_voltage_mv + VOLTAGE_STEP_MV, LDO); else rc = qpnp_lcdb_set_voltage(lcdb, lcdb->ldo.voltage_mv, LDO); if (rc < 0) pr_err("Failed to set LDO voltage rc=%c\n", rc); else lcdb->ldo.prev_voltage_mv = lcdb->ldo.voltage_mv; return rc; } static int qpnp_lcdb_ldo_regulator_get_voltage(struct regulator_dev *rdev) { int rc = 0; u32 voltage_mv = 0; struct qpnp_lcdb *lcdb = rdev_get_drvdata(rdev); rc = qpnp_lcdb_get_voltage(lcdb, &voltage_mv, LDO); if (rc < 0) { pr_err("Failed to get ldo voltage rc=%d\n", rc); return rc; } return voltage_mv * 1000; } static const struct regulator_ops qpnp_lcdb_ldo_ops = { .enable = qpnp_lcdb_ldo_regulator_enable, .disable = qpnp_lcdb_ldo_regulator_disable, .is_enabled = qpnp_lcdb_ldo_regulator_is_enabled, .set_voltage = qpnp_lcdb_ldo_regulator_set_voltage, .get_voltage = qpnp_lcdb_ldo_regulator_get_voltage, }; static int qpnp_lcdb_ncp_regulator_enable(struct regulator_dev *rdev) { int rc = 0; struct qpnp_lcdb *lcdb = rdev_get_drvdata(rdev); mutex_lock(&lcdb->lcdb_mutex); rc = qpnp_lcdb_enable(lcdb); if (rc < 0) pr_err("Failed to enable lcdb rc=%d\n", rc); mutex_unlock(&lcdb->lcdb_mutex); return rc; } static int qpnp_lcdb_ncp_regulator_disable(struct regulator_dev *rdev) { int rc = 0; struct qpnp_lcdb *lcdb = rdev_get_drvdata(rdev); mutex_lock(&lcdb->lcdb_mutex); rc = qpnp_lcdb_disable(lcdb); if (rc < 0) pr_err("Failed to disable lcdb rc=%d\n", rc); mutex_unlock(&lcdb->lcdb_mutex); return rc; } static int qpnp_lcdb_ncp_regulator_is_enabled(struct regulator_dev *rdev) { struct qpnp_lcdb *lcdb = rdev_get_drvdata(rdev); return lcdb->lcdb_enabled; } static int qpnp_lcdb_ncp_regulator_set_voltage(struct regulator_dev *rdev, int min_uV, int max_uV, unsigned int *selector) { int rc = 0; struct qpnp_lcdb *lcdb = rdev_get_drvdata(rdev); lcdb->ncp.voltage_mv = min_uV / 1000; if (lcdb->voltage_step_ramp) rc = qpnp_lcdb_set_voltage_step(lcdb, lcdb->ncp.prev_voltage_mv + VOLTAGE_STEP_MV, NCP); else rc = qpnp_lcdb_set_voltage(lcdb, lcdb->ncp.voltage_mv, NCP); if (rc < 0) pr_err("Failed to set NCP voltage rc=%c\n", rc); else lcdb->ncp.prev_voltage_mv = lcdb->ncp.voltage_mv; return rc; } static int qpnp_lcdb_ncp_regulator_get_voltage(struct regulator_dev *rdev) { int rc; u32 voltage_mv = 0; struct qpnp_lcdb *lcdb = rdev_get_drvdata(rdev); rc = qpnp_lcdb_get_voltage(lcdb, &voltage_mv, NCP); if (rc < 0) { pr_err("Failed to get ncp voltage rc=%d\n", rc); return rc; } return voltage_mv * 1000; } static const struct regulator_ops qpnp_lcdb_ncp_ops = { .enable = qpnp_lcdb_ncp_regulator_enable, .disable = qpnp_lcdb_ncp_regulator_disable, .is_enabled = qpnp_lcdb_ncp_regulator_is_enabled, .set_voltage = qpnp_lcdb_ncp_regulator_set_voltage, .get_voltage = qpnp_lcdb_ncp_regulator_get_voltage, }; static int qpnp_lcdb_regulator_register(struct qpnp_lcdb *lcdb, u8 type) { int rc = 0, off_on_delay = 0, voltage_step = VOLTAGE_STEP_50_MV; struct regulator_init_data *init_data; struct regulator_config cfg = {}; struct regulator_desc *rdesc; struct regulator_dev *rdev; struct device_node *node; if (lcdb->subtype != PM660L) off_on_delay = PMIC5_LCDB_OFF_ON_DELAY_US; if (type == LDO) { node = lcdb->ldo.node; rdesc = &lcdb->ldo.rdesc; rdesc->ops = &qpnp_lcdb_ldo_ops; rdesc->off_on_delay = off_on_delay; rdesc->n_voltages = ((lcdb->max_voltage_mv - lcdb->min_voltage_mv) / voltage_step) + 1; rdev = lcdb->ldo.rdev; } else if (type == NCP) { node = lcdb->ncp.node; rdesc = &lcdb->ncp.rdesc; rdesc->ops = &qpnp_lcdb_ncp_ops; rdesc->off_on_delay = off_on_delay; rdesc->n_voltages = ((lcdb->max_voltage_mv - lcdb->min_voltage_mv) / voltage_step) + 1; rdev = lcdb->ncp.rdev; } else { pr_err("Invalid regulator type %d\n", type); return -EINVAL; } init_data = of_get_regulator_init_data(lcdb->dev, node, rdesc); if (!init_data) { pr_err("Failed to get regulator_init_data for %s\n", (type == LDO) ? "LDO" : "NCP"); return -ENOMEM; } if (init_data->constraints.name) { rdesc->owner = THIS_MODULE; rdesc->type = REGULATOR_VOLTAGE; rdesc->name = init_data->constraints.name; cfg.dev = lcdb->dev; cfg.init_data = init_data; cfg.driver_data = lcdb; cfg.of_node = node; if (of_get_property(lcdb->dev->of_node, "parent-supply", NULL)) init_data->supply_regulator = "parent"; init_data->constraints.valid_ops_mask |= REGULATOR_CHANGE_VOLTAGE | REGULATOR_CHANGE_STATUS; rdev = devm_regulator_register(lcdb->dev, rdesc, &cfg); if (IS_ERR(rdev)) { rc = PTR_ERR(rdev); rdev = NULL; pr_err("Failed to register lcdb_%s regulator rc = %d\n", (type == LDO) ? "LDO" : "NCP", rc); return rc; } } else { pr_err("%s_regulator name missing\n", (type == LDO) ? "LDO" : "NCP"); return -EINVAL; } return rc; } static int qpnp_lcdb_parse_ttw(struct qpnp_lcdb *lcdb) { int rc = 0; u32 temp; u8 val = 0; struct device_node *node = lcdb->dev->of_node; /* LCDB_AUTO_TOUCH_WAKE_CTL_REG is removed for PM7325B, but TTW is supported */ if (lcdb->subtype == PM7325B) return 0; if (of_property_read_bool(node, "qcom,ttw-mode-sw")) { lcdb->ttw_mode_sw = true; rc = of_property_read_u32(node, "qcom,attw-toff-ms", &temp); if (!rc) { if (!is_between(temp, ATTW_MIN_MS, ATTW_MAX_MS)) { pr_err("Invalid TOFF val %d (min=%d max=%d)\n", temp, ATTW_MIN_MS, ATTW_MAX_MS); return -EINVAL; } val = ilog2(temp / 4) << ATTW_TOFF_TIME_SHIFT; } else { pr_err("qcom,attw-toff-ms not specified for TTW SW mode\n"); return rc; } rc = of_property_read_u32(node, "qcom,attw-ton-ms", &temp); if (!rc) { if (!is_between(temp, ATTW_MIN_MS, ATTW_MAX_MS)) { pr_err("Invalid TON value %d (min=%d max=%d)\n", temp, ATTW_MIN_MS, ATTW_MAX_MS); return -EINVAL; } val |= ilog2(temp / 4); } else { pr_err("qcom,attw-ton-ms not specified for TTW SW mode\n"); return rc; } rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_AUTO_TOUCH_WAKE_CTL_REG, ATTW_TON_TIME_MASK | ATTW_TOFF_TIME_MASK, val); if (rc < 0) { pr_err("Failed to write ATTW ON/OFF rc=%d\n", rc); return rc; } } return 0; } static int qpnp_lcdb_ldo_dt_init(struct qpnp_lcdb *lcdb) { int rc = 0; struct device_node *node = lcdb->ldo.node; int ilim_min = (lcdb->subtype == PM7325B) ? PM7325B_MIN_LDO_ILIM_MA : MIN_LDO_ILIM_MA; int ilim_max = (lcdb->subtype == PM7325B) ? PM7325B_MAX_LDO_ILIM_MA : MAX_LDO_ILIM_MA; /* LDO output voltage */ lcdb->ldo.voltage_mv = -EINVAL; rc = of_property_read_u32(node, "qcom,ldo-voltage-mv", &lcdb->ldo.voltage_mv); if (!rc && !is_between(lcdb->ldo.voltage_mv, lcdb->min_voltage_mv, lcdb->max_voltage_mv)) { pr_err("Invalid LDO voltage %dmv (min=%d max=%d)\n", lcdb->ldo.voltage_mv, lcdb->min_voltage_mv, lcdb->max_voltage_mv); return -EINVAL; } /* LDO PD configuration */ lcdb->ldo.pd = -EINVAL; of_property_read_u32(node, "qcom,ldo-pd", &lcdb->ldo.pd); lcdb->ldo.pd_strength = -EINVAL; of_property_read_u32(node, "qcom,ldo-pd-strength", &lcdb->ldo.pd_strength); /* LDO ILIM configuration */ lcdb->ldo.ilim_ma = -EINVAL; rc = of_property_read_u32(node, "qcom,ldo-ilim-ma", &lcdb->ldo.ilim_ma); if (!rc && !is_between(lcdb->ldo.ilim_ma, ilim_min, ilim_max)) { pr_err("Invalid ilim_ma %d (min=%d, max=%d)\n", lcdb->ldo.ilim_ma, ilim_min, ilim_max); return -EINVAL; } /* LDO soft-start (SS) configuration */ lcdb->ldo.soft_start_us = -EINVAL; of_property_read_u32(node, "qcom,ldo-soft-start-us", &lcdb->ldo.soft_start_us); return 0; } static int qpnp_lcdb_ncp_dt_init(struct qpnp_lcdb *lcdb) { int rc = 0; struct device_node *node = lcdb->ncp.node; int ilim_min = (lcdb->subtype == PM7325B) ? PM7325B_MIN_NCP_ILIM_MA : MIN_NCP_ILIM_MA; int ilim_max = (lcdb->subtype == PM7325B) ? PM7325B_MAX_NCP_ILIM_MA : MAX_NCP_ILIM_MA; /* NCP output voltage */ lcdb->ncp.voltage_mv = -EINVAL; rc = of_property_read_u32(node, "qcom,ncp-voltage-mv", &lcdb->ncp.voltage_mv); if (!rc && !is_between(lcdb->ncp.voltage_mv, lcdb->min_voltage_mv, lcdb->max_voltage_mv)) { pr_err("Invalid NCP voltage %dmv (min=%d max=%d)\n", lcdb->ldo.voltage_mv, lcdb->min_voltage_mv, lcdb->max_voltage_mv); return -EINVAL; } /* NCP PD configuration */ lcdb->ncp.pd = -EINVAL; of_property_read_u32(node, "qcom,ncp-pd", &lcdb->ncp.pd); lcdb->ncp.pd_strength = -EINVAL; of_property_read_u32(node, "qcom,ncp-pd-strength", &lcdb->ncp.pd_strength); /* NCP ILIM configuration */ lcdb->ncp.ilim_ma = -EINVAL; rc = of_property_read_u32(node, "qcom,ncp-ilim-ma", &lcdb->ncp.ilim_ma); if (!rc && !is_between(lcdb->ncp.ilim_ma, ilim_min, ilim_max)) { pr_err("Invalid ilim_ma %d (min=%d, max=%d)\n", lcdb->ncp.ilim_ma, ilim_min, ilim_max); return -EINVAL; } /* NCP soft-start (SS) configuration */ lcdb->ncp.soft_start_us = -EINVAL; of_property_read_u32(node, "qcom,ncp-soft-start-us", &lcdb->ncp.soft_start_us); return 0; } static int qpnp_lcdb_bst_dt_init(struct qpnp_lcdb *lcdb) { int rc = 0; struct device_node *node = lcdb->bst.node; u16 default_headroom_mv; int ilim_min = (lcdb->subtype == PM7325B) ? PM7325B_MIN_BST_ILIM_MA : MIN_BST_ILIM_MA; int ilim_max = (lcdb->subtype == PM7325B) ? PM7325B_MAX_BST_ILIM_MA : MAX_BST_ILIM_MA; /* Boost PD configuration */ lcdb->bst.pd = -EINVAL; of_property_read_u32(node, "qcom,bst-pd", &lcdb->bst.pd); lcdb->bst.pd_strength = -EINVAL; of_property_read_u32(node, "qcom,bst-pd-strength", &lcdb->bst.pd_strength); /* Boost ILIM */ lcdb->bst.ilim_ma = -EINVAL; rc = of_property_read_u32(node, "qcom,bst-ilim-ma", &lcdb->bst.ilim_ma); if (!rc && !is_between(lcdb->bst.ilim_ma, ilim_min, ilim_max)) { pr_err("Invalid ilim_ma %d (min=%d, max=%d)\n", lcdb->bst.ilim_ma, ilim_min, ilim_max); return -EINVAL; } /* Boost PS configuration */ lcdb->bst.ps = -EINVAL; of_property_read_u32(node, "qcom,bst-ps", &lcdb->bst.ps); lcdb->bst.ps_threshold = -EINVAL; if (lcdb->subtype == PM7325B) { rc = of_property_read_u32(node, "qcom,bst-ps-threshold-mv", &lcdb->bst.ps_threshold); if (!rc && !is_between(lcdb->bst.ps_threshold, PM7325B_MIN_BST_PS_MV, PM7325B_MAX_BST_PS_MV)) { pr_err("Invalid bst ps_threshold %d mV (min=%d, max=%d)\n", lcdb->bst.ps_threshold, PM7325B_MIN_BST_PS_MV, PM7325B_MAX_BST_PS_MV); return -EINVAL; } } else { rc = of_property_read_u32(node, "qcom,bst-ps-threshold-ma", &lcdb->bst.ps_threshold); if (!rc && !is_between(lcdb->bst.ps_threshold, MIN_BST_PS_MA, MAX_BST_PS_MA)) { pr_err("Invalid bst ps_threshold %d mA (min=%d, max=%d)\n", lcdb->bst.ps_threshold, MIN_BST_PS_MA, MAX_BST_PS_MA); return -EINVAL; } } default_headroom_mv = (lcdb->subtype == PM660L) ? PM660_BST_HEADROOM_DEFAULT_MV : BST_HEADROOM_DEFAULT_MV; /* Boost head room configuration */ of_property_read_u16(node, "qcom,bst-headroom-mv", &lcdb->bst.headroom_mv); if (lcdb->bst.headroom_mv < default_headroom_mv) lcdb->bst.headroom_mv = default_headroom_mv; return 0; } static int qpnp_lcdb_init_ldo(struct qpnp_lcdb *lcdb) { int rc = 0, ilim_ma, i = 0; u8 val = 0, pd_mask, pd_enable, ilim_ctl_reg, ilim_mask, ilim_sd_shift; if (lcdb->subtype == PM7325B) { pd_mask = (u8)PM7325B_LDO_EN_PULLDOWN_BIT; pd_enable = (u8)PM7325B_LDO_EN_PULLDOWN_BIT; ilim_ctl_reg = (u8)LCDB_LDO_ILIM_CTL1_REG; ilim_mask = (u8)SET_LDO_ILIM_MASK_SD; ilim_sd_shift = (u8)SET_LDO_ILIM_MASK_SD_SHIFT; } else { pd_mask = (u8)LDO_DIS_PULLDOWN_BIT; pd_enable = (u8)~LDO_DIS_PULLDOWN_BIT; ilim_ctl_reg = (u8)LCDB_LDO_ILIM_CTL2_REG; ilim_mask = (u8)SET_LDO_ILIM_MASK; ilim_sd_shift = 0; } /* configure parameters only if LCDB is disabled */ if (!is_lcdb_enabled(lcdb)) { if (lcdb->ldo.voltage_mv != -EINVAL) { rc = qpnp_lcdb_set_voltage(lcdb, lcdb->ldo.voltage_mv, LDO); if (rc < 0) { pr_err("Failed to set voltage rc=%d\n", rc); return rc; } } if (lcdb->ldo.pd != -EINVAL) { rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_LDO_PD_CTL_REG, pd_mask, lcdb->ldo.pd ? pd_enable : ~pd_enable); if (rc < 0) { pr_err("Failed to configure LDO PD rc=%d\n", rc); return rc; } } if (lcdb->ldo.pd_strength != -EINVAL) { rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_LDO_PD_CTL_REG, LDO_PD_STRENGTH_BIT, lcdb->ldo.pd_strength ? LDO_PD_STRENGTH_BIT : 0); if (rc < 0) { pr_err("Failed to configure LDO PD strength %s rc=%d\n", lcdb->ldo.pd_strength ? "(strong)" : "(weak)", rc); return rc; } } if (lcdb->ldo.ilim_ma != -EINVAL) { if (lcdb->subtype == PM7325B) { ilim_ma = lcdb->ldo.ilim_ma; /* * Select the highest current available below the specified current * if there is no exact match. */ for (i = 0; i < ARRAY_SIZE(pm7325b_ldo_ilim_ma); i++) if (ilim_ma < pm7325b_ldo_ilim_ma[i]) break; val = (i == 0) ? 0 : i - 1; } else { ilim_ma = lcdb->ldo.ilim_ma - MIN_LDO_ILIM_MA; ilim_ma /= LDO_ILIM_STEP_MA; val = (ilim_ma & SET_LDO_ILIM_MASK); } rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_LDO_ILIM_CTL1_REG, SET_LDO_ILIM_MASK | EN_LDO_ILIM_BIT, (val | EN_LDO_ILIM_BIT)); if (rc < 0) { pr_err("Failed to configure LDO ilim_ma (CTL1=%d) rc=%d\n", val, rc); return rc; } val = val << ilim_sd_shift; rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + ilim_ctl_reg, ilim_mask, val); if (rc < 0) { pr_err("Failed to configure LDO ilim_ma (CTL2=%d) rc=%d\n", val, rc); return rc; } } if (lcdb->ldo.soft_start_us != -EINVAL) { rc = qpnp_lcdb_set_soft_start(lcdb, lcdb->ldo.soft_start_us, LDO); if (rc < 0) { pr_err("Failed to set LDO soft_start rc=%d\n", rc); return rc; } } } rc = qpnp_lcdb_get_voltage(lcdb, &lcdb->ldo.voltage_mv, LDO); if (rc < 0) { pr_err("Failed to get LDO volatge rc=%d\n", rc); return rc; } lcdb->ldo.prev_voltage_mv = lcdb->ldo.voltage_mv; rc = qpnp_lcdb_read(lcdb, lcdb->base + LCDB_LDO_VREG_OK_CTL_REG, &val, 1); if (rc < 0) { pr_err("Failed to read ldo_vreg_ok rc=%d\n", rc); return rc; } lcdb->ldo.vreg_ok_dbc_us = dbc_us[val & VREG_OK_DEB_MASK]; rc = qpnp_lcdb_read(lcdb, lcdb->base + LCDB_LDO_SOFT_START_CTL_REG, &val, 1); if (rc < 0) { pr_err("Failed to read ldo_soft_start_ctl rc=%d\n", rc); return rc; } lcdb->ldo.soft_start_us = soft_start_us[val & SOFT_START_MASK]; rc = qpnp_lcdb_regulator_register(lcdb, LDO); if (rc < 0) pr_err("Failed to register ldo rc=%d\n", rc); return rc; } static int qpnp_lcdb_init_ncp(struct qpnp_lcdb *lcdb) { int rc = 0, i = 0; const u32 *ncp_ilim, *dbc_ncp; u8 val = 0, pd_enable, ilim_ctl_reg, ilim_mask, ilim_sd_shift; if (lcdb->subtype == PM7325B) { pd_enable = (u8)PM7325B_EN_NCP_PULLDOWN_BIT; ilim_ctl_reg = (u8)LCDB_NCP_ILIM_CTL1_REG; ilim_mask = (u8)PM7325B_SET_NCP_ILIM_SD_MASK; ilim_sd_shift = (u8)SET_LDO_ILIM_MASK_SD_SHIFT; ncp_ilim = pm7325b_ncp_ilim_ma; dbc_ncp = ncp_dbc_us; } else { pd_enable = (u8)~NCP_DIS_PULLDOWN_BIT; ilim_ctl_reg = (u8)LCDB_NCP_ILIM_CTL2_REG; ilim_mask = (u8)SET_NCP_ILIM_MASK; ilim_sd_shift = 0; ncp_ilim = ncp_ilim_ma; dbc_ncp = dbc_us; } /* configure parameters only if LCDB is disabled */ if (!is_lcdb_enabled(lcdb)) { if (lcdb->ncp.voltage_mv != -EINVAL) { rc = qpnp_lcdb_set_voltage(lcdb, lcdb->ncp.voltage_mv, NCP); if (rc < 0) { pr_err("Failed to set voltage rc=%d\n", rc); return rc; } } if (lcdb->ncp.pd != -EINVAL) { rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_NCP_PD_CTL_REG, NCP_DIS_PULLDOWN_BIT, lcdb->ncp.pd ? pd_enable : ~pd_enable); if (rc < 0) { pr_err("Failed to configure NCP PD rc=%d\n", rc); return rc; } } if (lcdb->ncp.pd_strength != -EINVAL) { rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_NCP_PD_CTL_REG, NCP_PD_STRENGTH_BIT, lcdb->ncp.pd_strength ? NCP_PD_STRENGTH_BIT : 0); if (rc < 0) { pr_err("Failed to configure NCP PD strength %s rc=%d\n", lcdb->ncp.pd_strength ? "(strong)" : "(weak)", rc); return rc; } } if (lcdb->ncp.ilim_ma != -EINVAL) { while (lcdb->ncp.ilim_ma >= ncp_ilim[i]) i++; val = (i == 0) ? 0 : i - 1; val = (val & SET_NCP_ILIM_MASK); rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_NCP_ILIM_CTL1_REG, SET_NCP_ILIM_MASK | EN_NCP_ILIM_BIT, val | EN_NCP_ILIM_BIT); if (rc < 0) { pr_err("Failed to configure NCP ilim_ma (CTL1=%d) rc=%d\n", val, rc); return rc; } val = val << ilim_sd_shift; rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + ilim_ctl_reg, ilim_mask, val); if (rc < 0) { pr_err("Failed to configure NCP ilim_ma (CTL2=%d) rc=%d\n", val, rc); return rc; } } if (lcdb->ncp.soft_start_us != -EINVAL) { rc = qpnp_lcdb_set_soft_start(lcdb, lcdb->ncp.soft_start_us, NCP); if (rc < 0) { pr_err("Failed to set NCP soft_start rc=%d\n", rc); return rc; } } } rc = qpnp_lcdb_get_voltage(lcdb, &lcdb->ncp.voltage_mv, NCP); if (rc < 0) { pr_err("Failed to get NCP volatge rc=%d\n", rc); return rc; } lcdb->ncp.prev_voltage_mv = lcdb->ncp.voltage_mv; rc = qpnp_lcdb_read(lcdb, lcdb->base + LCDB_NCP_VREG_OK_CTL_REG, &val, 1); if (rc < 0) { pr_err("Failed to read ncp_vreg_ok rc=%d\n", rc); return rc; } lcdb->ncp.vreg_ok_dbc_us = dbc_ncp[val & VREG_OK_DEB_MASK]; rc = qpnp_lcdb_read(lcdb, lcdb->base + LCDB_NCP_SOFT_START_CTL_REG, &val, 1); if (rc < 0) { pr_err("Failed to read ncp_soft_start_ctl rc=%d\n", rc); return rc; } lcdb->ncp.soft_start_us = soft_start_us[val & SOFT_START_MASK]; rc = qpnp_lcdb_regulator_register(lcdb, NCP); if (rc < 0) pr_err("Failed to register NCP rc=%d\n", rc); return rc; } static int qpnp_lcdb_init_bst(struct qpnp_lcdb *lcdb) { int rc = 0, bst_ps_min, bst_ps_step; const u32 *dbc_bst; u8 val = 0, pd_mask, pd_enable, mask = 0, bst_ilim_en, bst_vreg_ok_reg; if (lcdb->subtype == PM7325B) { pd_mask = (u8)PM7325B_BOOST_EN_PULLDOWN_BIT; pd_enable = (u8)PM7325B_BOOST_EN_PULLDOWN_BIT; bst_ilim_en = 0; bst_ps_step = 24; bst_ps_min = PM7325B_MIN_BST_PS_MV; dbc_bst = bst_dbc_us; bst_vreg_ok_reg = (u8)PM7325B_LCDB_BST_VREG_OK_CTL_REG; } else { pd_mask = (u8)BOOST_DIS_PULLDOWN_BIT; pd_enable = (u8)~BOOST_DIS_PULLDOWN_BIT; bst_ilim_en = (u8)EN_BST_ILIM_BIT; bst_ps_step = 10; bst_ps_min = MIN_BST_PS_MA; dbc_bst = dbc_us; bst_vreg_ok_reg = (u8)LCDB_BST_VREG_OK_CTL_REG; } /* configure parameters only if LCDB is disabled */ if (!is_lcdb_enabled(lcdb)) { if (lcdb->bst.pd != -EINVAL) { rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_BST_PD_CTL_REG, pd_mask, lcdb->bst.pd ? pd_enable : ~pd_enable); if (rc < 0) { pr_err("Failed to configure BST PD rc=%d\n", rc); return rc; } } if (lcdb->bst.pd_strength != -EINVAL) { rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_BST_PD_CTL_REG, BOOST_PD_STRENGTH_BIT, lcdb->bst.pd_strength ? BOOST_PD_STRENGTH_BIT : 0); if (rc < 0) { pr_err("Failed to configure NCP PD strength %s rc=%d\n", lcdb->bst.pd_strength ? "(strong)" : "(weak)", rc); return rc; } } if (lcdb->bst.ilim_ma != -EINVAL) { if (lcdb->subtype == PM7325B) { val = (lcdb->bst.ilim_ma - PM7325B_MIN_BST_ILIM_MA) / PM7325B_BST_ILIM_MA_STEP; } else { val = (lcdb->bst.ilim_ma / MIN_BST_ILIM_MA) - 1; } val = (val & SET_BST_ILIM_MASK) | bst_ilim_en; rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_BST_ILIM_CTL_REG, SET_BST_ILIM_MASK | bst_ilim_en, val); if (rc < 0) { pr_err("Failed to configure BST ilim_ma rc=%d\n", rc); return rc; } } if (lcdb->bst.ps != -EINVAL) { rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_PS_CTL_REG, EN_PS_BIT, lcdb->bst.ps ? EN_PS_BIT : 0); if (rc < 0) { pr_err("Failed to disable BST PS rc=%d\n", rc); return rc; } } if (lcdb->bst.ps_threshold != -EINVAL) { mask = (lcdb->subtype == PM660L) ? PM660_PS_THRESH_MASK : PS_THRESH_MASK; val = (lcdb->bst.ps_threshold - bst_ps_min) / bst_ps_step; val = (val & mask) | EN_PS_BIT; rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_PS_CTL_REG, mask | EN_PS_BIT, val); if (rc < 0) { pr_err("Failed to configure BST PS threshold rc=%d\n", rc); return rc; } } } rc = qpnp_lcdb_get_voltage(lcdb, &lcdb->bst.voltage_mv, BST); if (rc < 0) { pr_err("Failed to get BST voltage rc=%d\n", rc); return rc; } rc = qpnp_lcdb_read(lcdb, lcdb->base + bst_vreg_ok_reg, &val, 1); if (rc < 0) { pr_err("Failed to read bst_vreg_ok rc=%d\n", rc); return rc; } lcdb->bst.vreg_ok_dbc_us = dbc_bst[val & VREG_OK_DEB_MASK]; if (lcdb->subtype == PM660L) { rc = qpnp_lcdb_read(lcdb, lcdb->base + LCDB_SOFT_START_CTL_REG, &val, 1); if (rc < 0) { pr_err("Failed to read lcdb_soft_start_ctl rc=%d\n", rc); return rc; } lcdb->bst.soft_start_us = (val & SOFT_START_MASK) * 200 + 200; if (!lcdb->bst.headroom_mv) lcdb->bst.headroom_mv = PM660_BST_HEADROOM_DEFAULT_MV; } else { rc = qpnp_lcdb_read(lcdb, lcdb->base + LCDB_BST_SS_CTL_REG, &val, 1); if (rc < 0) { pr_err("Failed to read bst_soft_start_ctl rc=%d\n", rc); return rc; } lcdb->bst.soft_start_us = soft_start_us[val & SOFT_START_MASK]; if (!lcdb->bst.headroom_mv) lcdb->bst.headroom_mv = BST_HEADROOM_DEFAULT_MV; } return 0; } static void qpnp_lcdb_pmic_config(struct qpnp_lcdb *lcdb) { switch (lcdb->subtype) { case PMI632: case PM6150L: case PM7325B: lcdb->wa_flags |= FORCE_PD_ENABLE_WA; break; default: break; } pr_debug("LCDB wa_flags = 0x%2x\n", lcdb->wa_flags); } static int qpnp_lcdb_hw_init(struct qpnp_lcdb *lcdb) { int rc = 0; u8 val = 0; qpnp_lcdb_pmic_config(lcdb); if (lcdb->pwrdn_delay_ms != -EINVAL) { rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_PWRUP_PWRDN_CTL_REG, PWRDN_DELAY_MASK, lcdb->pwrdn_delay_ms); if (rc < 0) return rc; } if (lcdb->pwrup_delay_ms != -EINVAL) { rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_PWRUP_PWRDN_CTL_REG, PWRUP_DELAY_MASK, lcdb->pwrup_delay_ms << PWRUP_DELAY_SHIFT); if (rc < 0) return rc; } if (lcdb->pwrup_config != -EINVAL) { rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_CONFIG_SEL_REG, PWRUP_CONFIG_SEL_MASK, lcdb->pwrup_config); if (rc < 0) return rc; } if (lcdb->high_p2_blk_ns != -EINVAL) { rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + PM7325B_LCDB_P2_BLANK_TIMER_REG, HIGH_P2_BLK_SEL_MASK, lcdb->high_p2_blk_ns << HIGH_P2_BLK_SEL_SHIFT); if (rc < 0) return rc; } if (lcdb->low_p2_blk_ns != -EINVAL) { rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + PM7325B_LCDB_P2_BLANK_TIMER_REG, LOW_P2_BLK_SEL_MASK, lcdb->low_p2_blk_ns); if (rc < 0) return rc; } if (lcdb->mpc_current_thr_ma != -EINVAL) { rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + PM7325B_LCDB_MPC_CTL_REG, MPC_NCP_SD_SEL_MASK, lcdb->mpc_current_thr_ma); if (rc < 0) return rc; } if (lcdb->ncp_symmetry) { rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_NCP_OUTPUT_VOLTAGE_REG, EN_NCP_VOUT_SYMMETRY_BIT, EN_NCP_VOUT_SYMMETRY_BIT); if (rc < 0) return rc; } rc = qpnp_lcdb_init_bst(lcdb); if (rc < 0) { pr_err("Failed to initialize BOOST rc=%d\n", rc); return rc; } rc = qpnp_lcdb_init_ldo(lcdb); if (rc < 0) { pr_err("Failed to initialize LDO rc=%d\n", rc); return rc; } rc = qpnp_lcdb_init_ncp(lcdb); if (rc < 0) { pr_err("Failed to initialize NCP rc=%d\n", rc); return rc; } if (lcdb->sc_irq >= 0 && lcdb->subtype != PM660L) { lcdb->sc_count = 0; rc = devm_request_threaded_irq(lcdb->dev, lcdb->sc_irq, NULL, qpnp_lcdb_sc_irq_handler, IRQF_ONESHOT, "qpnp_lcdb_sc_irq", lcdb); if (rc < 0) { pr_err("Unable to request sc(%d) irq rc=%d\n", lcdb->sc_irq, rc); return rc; } } if (!is_lcdb_enabled(lcdb)) { rc = qpnp_lcdb_read(lcdb, lcdb->base + LCDB_MODULE_RDY_REG, &val, 1); if (rc < 0) { pr_err("Failed to read MODULE_RDY rc=%d\n", rc); return rc; } if (!(val & MODULE_RDY_BIT)) { rc = qpnp_lcdb_masked_write(lcdb, lcdb->base + LCDB_MODULE_RDY_REG, MODULE_RDY_BIT, MODULE_RDY_BIT); if (rc < 0) { pr_err("Failed to set MODULE RDY rc=%d\n", rc); return rc; } } } else { /* module already enabled */ lcdb->lcdb_enabled = true; } return 0; } static int qpnp_lcdb_pwrup_dn_delay(int val, int *delay) { int i; if (!is_between(val, PWRDN_DELAY_MIN_MS, PWRDN_DELAY_MAX_MS)) { pr_err("Invalid PWR_UP_DN_DLY val %d (min=%d max=%d)\n", val, PWRDN_DELAY_MIN_MS, PWRDN_DELAY_MAX_MS); return -EINVAL; } for (i = 0; i < ARRAY_SIZE(pwrup_pwrdn_ms); i++) { if (val == pwrup_pwrdn_ms[i]) { *delay = i; break; } } return 0; } static int qpnp_lcdb_p2_blk_time(int val, int *time) { int i; if (!is_between(val, pm7325b_p2_blk_ns[0], pm7325b_p2_blk_ns[7])) { pr_err("Invalid P2_BLK_TIME val %d (min=%d max=%d)\n", val, pm7325b_p2_blk_ns[0], pm7325b_p2_blk_ns[7]); return -EINVAL; } for (i = 0; i < ARRAY_SIZE(pm7325b_p2_blk_ns); i++) { if (val == pm7325b_p2_blk_ns[i]) { *time = i; break; } } return 0; } static int qpnp_lcdb_mpc_current(int val, int *cur) { if (!is_between(val, MPC_CURRENT_MIN, MPC_CURRENT_MAX)) { pr_err("Invalid MPC_CURRENT val %d (min=%d max=%d)\n", val, MPC_CURRENT_MIN, MPC_CURRENT_MAX); return -EINVAL; } *cur = (val - MPC_CURRENT_MIN) / MPC_CURRENT_STEP; return 0; } static int qpnp_lcdb_parse_dt(struct qpnp_lcdb *lcdb) { int rc = 0; u32 tmp; const char *label; struct device_node *temp, *node = lcdb->dev->of_node; for_each_available_child_of_node(node, temp) { rc = of_property_read_string(temp, "label", &label); if (rc < 0) { pr_err("Failed to read label rc=%d\n", rc); return rc; } if (!strcmp(label, "ldo")) { lcdb->ldo.node = temp; rc = qpnp_lcdb_ldo_dt_init(lcdb); } else if (!strcmp(label, "ncp")) { lcdb->ncp.node = temp; rc = qpnp_lcdb_ncp_dt_init(lcdb); } else if (!strcmp(label, "bst")) { lcdb->bst.node = temp; rc = qpnp_lcdb_bst_dt_init(lcdb); } else { pr_err("Failed to identify label %s\n", label); return -EINVAL; } if (rc < 0) { pr_err("Failed to register %s module\n", label); return rc; } } if (of_property_read_bool(node, "qcom,ttw-enable")) { rc = qpnp_lcdb_parse_ttw(lcdb); if (rc < 0) { pr_err("Failed to parse ttw-params rc=%d\n", rc); return rc; } lcdb->ttw_enable = true; } lcdb->sc_irq = platform_get_irq_byname(lcdb->pdev, "sc-irq"); if (lcdb->sc_irq < 0) pr_debug("sc irq is not defined\n"); lcdb->voltage_step_ramp = of_property_read_bool(node, "qcom,voltage-step-ramp"); lcdb->ncp_symmetry = of_property_read_bool(node, "qcom,ncp-symmetry"); lcdb->pwrdn_delay_ms = -EINVAL; lcdb->pwrup_delay_ms = -EINVAL; lcdb->pwrup_config = -EINVAL; lcdb->high_p2_blk_ns = -EINVAL; lcdb->low_p2_blk_ns = -EINVAL; lcdb->mpc_current_thr_ma = -EINVAL; rc = of_property_read_u32(node, "qcom,pwrdn-delay-ms", &tmp); if (!rc) { rc = qpnp_lcdb_pwrup_dn_delay(tmp, &lcdb->pwrdn_delay_ms); if (rc < 0) return rc; } rc = of_property_read_u32(node, "qcom,pwrup-delay-ms", &tmp); if (!rc) { rc = qpnp_lcdb_pwrup_dn_delay(tmp, &lcdb->pwrup_delay_ms); if (rc < 0) return rc; } rc = of_property_read_u32(node, "qcom,pwrup-config", &lcdb->pwrup_config); if (!rc && lcdb->pwrup_config > PWRUP_CONFIG_MAX) { pr_err("Invalid pwrup config %d, max=%d\n", lcdb->pwrup_config, PWRUP_CONFIG_MAX); return -EINVAL; } rc = of_property_read_u32(node, "qcom,high-p2-blank-time-ns", &tmp); if (!rc) { rc = qpnp_lcdb_p2_blk_time(tmp, &lcdb->high_p2_blk_ns); if (rc < 0) return rc; } rc = of_property_read_u32(node, "qcom,low-p2-blank-time-ns", &tmp); if (!rc) { rc = qpnp_lcdb_p2_blk_time(tmp, &lcdb->low_p2_blk_ns); if (rc < 0) return rc; } rc = of_property_read_u32(node, "qcom,mpc-current-thr-ma", &tmp); if (!rc) { rc = qpnp_lcdb_mpc_current(tmp, &lcdb->mpc_current_thr_ma); if (rc < 0) return rc; } return 0; } static int qpnp_lcdb_regulator_probe(struct platform_device *pdev) { int rc; struct device_node *node; struct qpnp_lcdb *lcdb; const struct of_device_id *dev_id; node = pdev->dev.of_node; if (!node) { pr_err("No nodes defined\n"); return -ENODEV; } lcdb = devm_kzalloc(&pdev->dev, sizeof(*lcdb), GFP_KERNEL); if (!lcdb) return -ENOMEM; rc = of_property_read_u32(node, "reg", &lcdb->base); if (rc < 0) { pr_err("Failed to find reg node rc=%d\n", rc); return rc; } lcdb->regmap = dev_get_regmap(pdev->dev.parent, NULL); if (!lcdb->regmap) { pr_err("Failed to get the regmap handle rc=%d\n", rc); return -EINVAL; } lcdb->subtype = (u8)(unsigned long)of_device_get_match_data(&pdev->dev); lcdb->dev = &pdev->dev; lcdb->pdev = pdev; dev_id = of_match_device(lcdb->dev->driver->of_match_table, lcdb->dev); lcdb->min_voltage_mv = (lcdb->subtype == PM7325B) ? PM7325B_MIN_VOLTAGE_MV : MIN_VOLTAGE_MV; lcdb->max_voltage_mv = (lcdb->subtype == PM7325B) ? PM7325B_MAX_VOLTAGE_MV : MAX_VOLTAGE_MV; mutex_init(&lcdb->lcdb_mutex); mutex_init(&lcdb->read_write_mutex); rc = qpnp_lcdb_parse_dt(lcdb); if (rc < 0) { pr_err("Failed to parse dt rc=%d\n", rc); return rc; } rc = qpnp_lcdb_hw_init(lcdb); if (rc < 0) pr_err("Failed to initialize LCDB module rc=%d\n", rc); else pr_info("LCDB module: %s successfully registered! lcdb_en=%d ldo_voltage=%dmV ncp_voltage=%dmV bst_voltage=%dmV\n", dev_id->compatible, lcdb->lcdb_enabled, lcdb->ldo.voltage_mv, lcdb->ncp.voltage_mv, lcdb->bst.voltage_mv); return rc; } static int qpnp_lcdb_regulator_remove(struct platform_device *pdev) { struct qpnp_lcdb *lcdb = dev_get_drvdata(&pdev->dev); mutex_destroy(&lcdb->lcdb_mutex); mutex_destroy(&lcdb->read_write_mutex); return 0; } static const struct of_device_id lcdb_match_table[] = { { .compatible = QPNP_LCDB_REGULATOR_DRIVER_NAME, .data = (void *)PM_DEFAULT,}, { .compatible = QPNP_LCDB_REGULATOR_DRIVER_660, .data = (void *)PM660L,}, { .compatible = QPNP_LCDB_REGULATOR_DRIVER_632, .data = (void *)PMI632,}, { .compatible = QPNP_LCDB_REGULATOR_DRIVER_6150L, .data = (void *)PM6150L,}, { .compatible = QPNP_LCDB_REGULATOR_DRIVER_7325B, .data = (void *)PM7325B,}, { }, }; static struct platform_driver qpnp_lcdb_regulator_driver = { .driver = { .name = QPNP_LCDB_REGULATOR_DRIVER_NAME, .of_match_table = lcdb_match_table, }, .probe = qpnp_lcdb_regulator_probe, .remove = qpnp_lcdb_regulator_remove, }; static int __init qpnp_lcdb_regulator_init(void) { return platform_driver_register(&qpnp_lcdb_regulator_driver); } arch_initcall(qpnp_lcdb_regulator_init); static void __exit qpnp_lcdb_regulator_exit(void) { platform_driver_unregister(&qpnp_lcdb_regulator_driver); } module_exit(qpnp_lcdb_regulator_exit); MODULE_DESCRIPTION("QPNP LCDB regulator driver"); MODULE_LICENSE("GPL");