/* Copyright (c) 2010-2011, The Linux Foundation. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 and * only version 2 as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ #include #include #include #include #include #include #include #include #include /* Regulator types */ #define REGULATOR_TYPE_LDO 0 #define REGULATOR_TYPE_SMPS 1 #define REGULATOR_TYPE_VS 2 /* Bank select/write macros */ #define REGULATOR_BANK_SEL(n) ((n) << 4) #define REGULATOR_BANK_WRITE 0x80 #define LDO_TEST_BANKS 7 #define REGULATOR_BANK_MASK 0xF0 /* Pin mask resource register programming */ #define VREG_PMR_STATE_MASK 0x60 #define VREG_PMR_STATE_HPM 0x60 #define VREG_PMR_STATE_LPM 0x40 #define VREG_PMR_STATE_OFF 0x20 #define VREG_PMR_STATE_PIN_CTRL 0x20 #define VREG_PMR_MODE_ACTION_MASK 0x10 #define VREG_PMR_MODE_ACTION_SLEEP 0x10 #define VREG_PMR_MODE_ACTION_OFF 0x00 #define VREG_PMR_MODE_PIN_MASK 0x08 #define VREG_PMR_MODE_PIN_MASKED 0x08 #define VREG_PMR_CTRL_PIN2_MASK 0x04 #define VREG_PMR_CTRL_PIN2_MASKED 0x04 #define VREG_PMR_CTRL_PIN1_MASK 0x02 #define VREG_PMR_CTRL_PIN1_MASKED 0x02 #define VREG_PMR_CTRL_PIN0_MASK 0x01 #define VREG_PMR_CTRL_PIN0_MASKED 0x01 #define VREG_PMR_PIN_CTRL_ALL_MASK 0x1F #define VREG_PMR_PIN_CTRL_ALL_MASKED 0x1F #define REGULATOR_IS_EN(pmr_reg) \ ((pmr_reg & VREG_PMR_STATE_MASK) == VREG_PMR_STATE_HPM || \ (pmr_reg & VREG_PMR_STATE_MASK) == VREG_PMR_STATE_LPM) /* FTSMPS programming */ /* CTRL register */ #define SMPS_VCTRL_BAND_MASK 0xC0 #define SMPS_VCTRL_BAND_OFF 0x00 #define SMPS_VCTRL_BAND_1 0x40 #define SMPS_VCTRL_BAND_2 0x80 #define SMPS_VCTRL_BAND_3 0xC0 #define SMPS_VCTRL_VPROG_MASK 0x3F #define SMPS_BAND_1_UV_MIN 350000 #define SMPS_BAND_1_UV_MAX 650000 #define SMPS_BAND_1_UV_STEP 6250 #define SMPS_BAND_2_UV_MIN 700000 #define SMPS_BAND_2_UV_MAX 1400000 #define SMPS_BAND_2_UV_STEP 12500 #define SMPS_BAND_3_UV_SETPOINT_MIN 1500000 #define SMPS_BAND_3_UV_MIN 1400000 #define SMPS_BAND_3_UV_MAX 3300000 #define SMPS_BAND_3_UV_STEP 50000 #define SMPS_UV_MIN SMPS_BAND_1_UV_MIN #define SMPS_UV_MAX SMPS_BAND_3_UV_MAX /* PWR_CNFG register */ #define SMPS_PULL_DOWN_ENABLE_MASK 0x40 #define SMPS_PULL_DOWN_ENABLE 0x40 /* LDO programming */ /* CTRL register */ #define LDO_LOCAL_ENABLE_MASK 0x80 #define LDO_LOCAL_ENABLE 0x80 #define LDO_PULL_DOWN_ENABLE_MASK 0x40 #define LDO_PULL_DOWN_ENABLE 0x40 #define LDO_CTRL_VPROG_MASK 0x1F /* TEST register bank 2 */ #define LDO_TEST_VPROG_UPDATE_MASK 0x08 #define LDO_TEST_RANGE_SEL_MASK 0x04 #define LDO_TEST_FINE_STEP_MASK 0x02 #define LDO_TEST_FINE_STEP_SHIFT 1 /* TEST register bank 4 */ #define LDO_TEST_RANGE_EXT_MASK 0x01 /* Allowable voltage ranges */ #define PLDO_LOW_UV_MIN 750000 #define PLDO_LOW_UV_MAX 1537500 #define PLDO_LOW_FINE_STEP_UV 12500 #define PLDO_NORM_UV_MIN 1500000 #define PLDO_NORM_UV_MAX 3075000 #define PLDO_NORM_FINE_STEP_UV 25000 #define PLDO_HIGH_UV_MIN 1750000 #define PLDO_HIGH_UV_MAX 4900000 #define PLDO_HIGH_FINE_STEP_UV 50000 #define NLDO_UV_MIN 750000 #define NLDO_UV_MAX 1537500 #define NLDO_FINE_STEP_UV 12500 /* VS programming */ /* CTRL register */ #define VS_CTRL_ENABLE_MASK 0xC0 #define VS_CTRL_DISABLE 0x00 #define VS_CTRL_ENABLE 0x40 #define VS_CTRL_USE_PMR 0xC0 #define VS_PULL_DOWN_ENABLE_MASK 0x20 #define VS_PULL_DOWN_ENABLE 0x20 struct pm8901_vreg { struct device *dev; struct pm8901_vreg_pdata *pdata; struct regulator_dev *rdev; int hpm_min_load; unsigned pc_vote; unsigned optimum; unsigned mode_initialized; u16 ctrl_addr; u16 pmr_addr; u16 test_addr; u16 pfm_ctrl_addr; u16 pwr_cnfg_addr; u8 type; u8 ctrl_reg; u8 pmr_reg; u8 test_reg[LDO_TEST_BANKS]; u8 pfm_ctrl_reg; u8 pwr_cnfg_reg; u8 is_nmos; u8 state; }; /* * These are used to compensate for the PMIC 8901 v1 FTS regulators which * output ~10% higher than the programmed set point. */ #define IS_PMIC_8901_V1(rev) ((rev) == PM8XXX_REVISION_8901_1p0 || \ (rev) == PM8XXX_REVISION_8901_1p1) #define PMIC_8901_V1_SCALE(uV) ((((uV) - 62100) * 23) / 25) #define PMIC_8901_V1_SCALE_INV(uV) (((uV) * 25) / 23 + 62100) /* * Band 1 of PMIC 8901 SMPS regulators only supports set points with the 3 LSB's * equal to 0. This is accomplished in the macro by truncating the bits. */ #define PM8901_SMPS_BAND_1_COMPENSATE(vprog) ((vprog) & 0xF8) #define LDO(_id, _ctrl_addr, _pmr_addr, _test_addr, _is_nmos) \ [_id] = { \ .ctrl_addr = _ctrl_addr, \ .pmr_addr = _pmr_addr, \ .test_addr = _test_addr, \ .type = REGULATOR_TYPE_LDO, \ .is_nmos = _is_nmos, \ .hpm_min_load = PM8901_VREG_LDO_300_HPM_MIN_LOAD, \ } #define SMPS(_id, _ctrl_addr, _pmr_addr, _pfm_ctrl_addr, _pwr_cnfg_addr) \ [_id] = { \ .ctrl_addr = _ctrl_addr, \ .pmr_addr = _pmr_addr, \ .pfm_ctrl_addr = _pfm_ctrl_addr, \ .pwr_cnfg_addr = _pwr_cnfg_addr, \ .type = REGULATOR_TYPE_SMPS, \ .hpm_min_load = PM8901_VREG_FTSMPS_HPM_MIN_LOAD, \ } #define VS(_id, _ctrl_addr, _pmr_addr) \ [_id] = { \ .ctrl_addr = _ctrl_addr, \ .pmr_addr = _pmr_addr, \ .type = REGULATOR_TYPE_VS, \ } static struct pm8901_vreg pm8901_vreg[] = { /* id ctrl pmr tst n/p */ LDO(PM8901_VREG_ID_L0, 0x02F, 0x0AB, 0x030, 1), LDO(PM8901_VREG_ID_L1, 0x031, 0x0AC, 0x032, 0), LDO(PM8901_VREG_ID_L2, 0x033, 0x0AD, 0x034, 0), LDO(PM8901_VREG_ID_L3, 0x035, 0x0AE, 0x036, 0), LDO(PM8901_VREG_ID_L4, 0x037, 0x0AF, 0x038, 0), LDO(PM8901_VREG_ID_L5, 0x039, 0x0B0, 0x03A, 0), LDO(PM8901_VREG_ID_L6, 0x03B, 0x0B1, 0x03C, 0), /* id ctrl pmr pfm pwr */ SMPS(PM8901_VREG_ID_S0, 0x05B, 0x0A6, 0x05C, 0x0E3), SMPS(PM8901_VREG_ID_S1, 0x06A, 0x0A7, 0x06B, 0x0EC), SMPS(PM8901_VREG_ID_S2, 0x079, 0x0A8, 0x07A, 0x0F1), SMPS(PM8901_VREG_ID_S3, 0x088, 0x0A9, 0x089, 0x0F6), SMPS(PM8901_VREG_ID_S4, 0x097, 0x0AA, 0x098, 0x0FB), /* id ctrl pmr */ VS(PM8901_VREG_ID_LVS0, 0x046, 0x0B2), VS(PM8901_VREG_ID_LVS1, 0x048, 0x0B3), VS(PM8901_VREG_ID_LVS2, 0x04A, 0x0B4), VS(PM8901_VREG_ID_LVS3, 0x04C, 0x0B5), VS(PM8901_VREG_ID_MVS0, 0x052, 0x0B6), VS(PM8901_VREG_ID_USB_OTG, 0x055, 0x0B7), VS(PM8901_VREG_ID_HDMI_MVS, 0x058, 0x0B8), }; static void print_write_error(struct pm8901_vreg *vreg, int rc, const char *func); static int pm8901_vreg_write(struct pm8901_vreg *vreg, u16 addr, u8 val, u8 mask, u8 *reg_save) { int rc = 0; u8 reg; reg = (*reg_save & ~mask) | (val & mask); if (reg != *reg_save) rc = pm8xxx_writeb(vreg->dev->parent, addr, reg); if (!rc) *reg_save = reg; return rc; } /* Set pin control bits based on new mode. */ static int pm8901_vreg_select_pin_ctrl(struct pm8901_vreg *vreg, u8 *pmr_reg) { *pmr_reg |= VREG_PMR_PIN_CTRL_ALL_MASKED; if ((*pmr_reg & VREG_PMR_STATE_MASK) == VREG_PMR_STATE_PIN_CTRL) { if (vreg->pdata->pin_fn == PM8901_VREG_PIN_FN_MODE) *pmr_reg = (*pmr_reg & ~VREG_PMR_STATE_MASK) | VREG_PMR_STATE_LPM; if (vreg->pdata->pin_ctrl & PM8901_VREG_PIN_CTRL_A0) *pmr_reg &= ~VREG_PMR_CTRL_PIN0_MASKED; if (vreg->pdata->pin_ctrl & PM8901_VREG_PIN_CTRL_A1) *pmr_reg &= ~VREG_PMR_CTRL_PIN1_MASKED; if (vreg->pdata->pin_ctrl & PM8901_VREG_PIN_CTRL_D0) *pmr_reg &= ~VREG_PMR_CTRL_PIN2_MASKED; } return 0; } static int pm8901_vreg_enable(struct regulator_dev *dev) { struct pm8901_vreg *vreg = rdev_get_drvdata(dev); u8 val = VREG_PMR_STATE_HPM; int rc; if (!vreg->mode_initialized && vreg->pc_vote) val = VREG_PMR_STATE_PIN_CTRL; else if (vreg->optimum == REGULATOR_MODE_FAST) val = VREG_PMR_STATE_HPM; else if (vreg->pc_vote) val = VREG_PMR_STATE_PIN_CTRL; else if (vreg->optimum == REGULATOR_MODE_STANDBY) val = VREG_PMR_STATE_LPM; pm8901_vreg_select_pin_ctrl(vreg, &val); rc = pm8901_vreg_write(vreg, vreg->pmr_addr, val, VREG_PMR_STATE_MASK | VREG_PMR_PIN_CTRL_ALL_MASK, &vreg->pmr_reg); if (rc) print_write_error(vreg, rc, __func__); return rc; } static int pm8901_vreg_disable(struct regulator_dev *dev) { struct pm8901_vreg *vreg = rdev_get_drvdata(dev); int rc; rc = pm8901_vreg_write(vreg, vreg->pmr_addr, VREG_PMR_STATE_OFF | VREG_PMR_PIN_CTRL_ALL_MASKED, VREG_PMR_STATE_MASK | VREG_PMR_PIN_CTRL_ALL_MASK, &vreg->pmr_reg); if (rc) print_write_error(vreg, rc, __func__); return rc; } /* * Cases that count as enabled: * * 1. PMR register has mode == HPM or LPM. * 2. Any pin control bits are unmasked. * 3. The regulator is an LDO and its local enable bit is set. */ static int _pm8901_vreg_is_enabled(struct pm8901_vreg *vreg) { if ((vreg->type == REGULATOR_TYPE_LDO) && (vreg->ctrl_reg & LDO_LOCAL_ENABLE_MASK)) return 1; else if (vreg->type == REGULATOR_TYPE_VS) { if ((vreg->ctrl_reg & VS_CTRL_ENABLE_MASK) == VS_CTRL_ENABLE) return 1; else if ((vreg->ctrl_reg & VS_CTRL_ENABLE_MASK) == VS_CTRL_DISABLE) return 0; } return REGULATOR_IS_EN(vreg->pmr_reg) || ((vreg->pmr_reg & VREG_PMR_PIN_CTRL_ALL_MASK) != VREG_PMR_PIN_CTRL_ALL_MASKED); } static int pm8901_vreg_is_enabled(struct regulator_dev *dev) { struct pm8901_vreg *vreg = rdev_get_drvdata(dev); return _pm8901_vreg_is_enabled(vreg); } static int pm8901_ldo_disable(struct regulator_dev *dev) { struct pm8901_vreg *vreg = rdev_get_drvdata(dev); int rc; /* Disassert local enable bit in CTRL register. */ rc = pm8901_vreg_write(vreg, vreg->ctrl_addr, 0, LDO_LOCAL_ENABLE_MASK, &vreg->ctrl_reg); if (rc) print_write_error(vreg, rc, __func__); /* Disassert enable bit in PMR register. */ rc = pm8901_vreg_disable(dev); return rc; } static int pm8901_pldo_set_voltage(struct pm8901_vreg *vreg, int uV) { int vmin, rc = 0; unsigned vprog, fine_step; u8 range_ext, range_sel, fine_step_reg; if (uV < PLDO_LOW_UV_MIN || uV > PLDO_HIGH_UV_MAX) return -EINVAL; if (uV < PLDO_LOW_UV_MAX + PLDO_LOW_FINE_STEP_UV) { vmin = PLDO_LOW_UV_MIN; fine_step = PLDO_LOW_FINE_STEP_UV; range_ext = 0; range_sel = LDO_TEST_RANGE_SEL_MASK; } else if (uV < PLDO_NORM_UV_MAX + PLDO_NORM_FINE_STEP_UV) { vmin = PLDO_NORM_UV_MIN; fine_step = PLDO_NORM_FINE_STEP_UV; range_ext = 0; range_sel = 0; } else { vmin = PLDO_HIGH_UV_MIN; fine_step = PLDO_HIGH_FINE_STEP_UV; range_ext = LDO_TEST_RANGE_EXT_MASK; range_sel = 0; } vprog = (uV - vmin) / fine_step; fine_step_reg = (vprog & 1) << LDO_TEST_FINE_STEP_SHIFT; vprog >>= 1; /* * Disable program voltage update if range extension, range select, * or fine step have changed and the regulator is enabled. */ if (_pm8901_vreg_is_enabled(vreg) && (((range_ext ^ vreg->test_reg[4]) & LDO_TEST_RANGE_EXT_MASK) || ((range_sel ^ vreg->test_reg[2]) & LDO_TEST_RANGE_SEL_MASK) || ((fine_step_reg ^ vreg->test_reg[2]) & LDO_TEST_FINE_STEP_MASK))) { rc = pm8901_vreg_write(vreg, vreg->test_addr, REGULATOR_BANK_SEL(2) | REGULATOR_BANK_WRITE, REGULATOR_BANK_MASK | LDO_TEST_VPROG_UPDATE_MASK, &vreg->test_reg[2]); if (rc) goto bail; } /* Write new voltage. */ rc = pm8901_vreg_write(vreg, vreg->ctrl_addr, vprog, LDO_CTRL_VPROG_MASK, &vreg->ctrl_reg); if (rc) goto bail; /* Write range extension. */ rc = pm8901_vreg_write(vreg, vreg->test_addr, range_ext | REGULATOR_BANK_SEL(4) | REGULATOR_BANK_WRITE, LDO_TEST_RANGE_EXT_MASK | REGULATOR_BANK_MASK, &vreg->test_reg[4]); if (rc) goto bail; /* Write fine step, range select and program voltage update. */ rc = pm8901_vreg_write(vreg, vreg->test_addr, fine_step_reg | range_sel | REGULATOR_BANK_SEL(2) | REGULATOR_BANK_WRITE | LDO_TEST_VPROG_UPDATE_MASK, LDO_TEST_FINE_STEP_MASK | LDO_TEST_RANGE_SEL_MASK | REGULATOR_BANK_MASK | LDO_TEST_VPROG_UPDATE_MASK, &vreg->test_reg[2]); bail: if (rc) print_write_error(vreg, rc, __func__); return rc; } static int pm8901_nldo_set_voltage(struct pm8901_vreg *vreg, int uV) { unsigned vprog, fine_step_reg; int rc; if (uV < NLDO_UV_MIN || uV > NLDO_UV_MAX) return -EINVAL; vprog = (uV - NLDO_UV_MIN) / NLDO_FINE_STEP_UV; fine_step_reg = (vprog & 1) << LDO_TEST_FINE_STEP_SHIFT; vprog >>= 1; /* Write new voltage. */ rc = pm8901_vreg_write(vreg, vreg->ctrl_addr, vprog, LDO_CTRL_VPROG_MASK, &vreg->ctrl_reg); if (rc) print_write_error(vreg, rc, __func__); /* Write fine step. */ rc = pm8901_vreg_write(vreg, vreg->test_addr, fine_step_reg | REGULATOR_BANK_SEL(2) | REGULATOR_BANK_WRITE | LDO_TEST_VPROG_UPDATE_MASK, LDO_TEST_FINE_STEP_MASK | REGULATOR_BANK_MASK | LDO_TEST_VPROG_UPDATE_MASK, &vreg->test_reg[2]); if (rc) print_write_error(vreg, rc, __func__); return rc; } static int pm8901_ldo_set_voltage(struct regulator_dev *dev, int min_uV, int max_uV, unsigned *selector) { struct pm8901_vreg *vreg = rdev_get_drvdata(dev); if (vreg->is_nmos) return pm8901_nldo_set_voltage(vreg, min_uV); else return pm8901_pldo_set_voltage(vreg, min_uV); } static int pm8901_pldo_get_voltage(struct pm8901_vreg *vreg) { int vmin, fine_step; u8 range_ext, range_sel, vprog, fine_step_reg; fine_step_reg = vreg->test_reg[2] & LDO_TEST_FINE_STEP_MASK; range_sel = vreg->test_reg[2] & LDO_TEST_RANGE_SEL_MASK; range_ext = vreg->test_reg[4] & LDO_TEST_RANGE_EXT_MASK; vprog = vreg->ctrl_reg & LDO_CTRL_VPROG_MASK; vprog = (vprog << 1) | (fine_step_reg >> LDO_TEST_FINE_STEP_SHIFT); if (range_sel) { /* low range mode */ fine_step = PLDO_LOW_FINE_STEP_UV; vmin = PLDO_LOW_UV_MIN; } else if (!range_ext) { /* normal mode */ fine_step = PLDO_NORM_FINE_STEP_UV; vmin = PLDO_NORM_UV_MIN; } else { /* high range mode */ fine_step = PLDO_HIGH_FINE_STEP_UV; vmin = PLDO_HIGH_UV_MIN; } return fine_step * vprog + vmin; } static int pm8901_nldo_get_voltage(struct pm8901_vreg *vreg) { u8 vprog, fine_step_reg; fine_step_reg = vreg->test_reg[2] & LDO_TEST_FINE_STEP_MASK; vprog = vreg->ctrl_reg & LDO_CTRL_VPROG_MASK; vprog = (vprog << 1) | (fine_step_reg >> LDO_TEST_FINE_STEP_SHIFT); return NLDO_FINE_STEP_UV * vprog + NLDO_UV_MIN; } static int pm8901_ldo_get_voltage(struct regulator_dev *dev) { struct pm8901_vreg *vreg = rdev_get_drvdata(dev); if (vreg->is_nmos) return pm8901_nldo_get_voltage(vreg); else return pm8901_pldo_get_voltage(vreg); } /* * Optimum mode programming: * REGULATOR_MODE_FAST: Go to HPM (highest priority) * REGULATOR_MODE_STANDBY: Go to pin ctrl mode if there are any pin ctrl * votes, else go to LPM * * Pin ctrl mode voting via regulator set_mode: * REGULATOR_MODE_IDLE: Go to pin ctrl mode if the optimum mode is LPM, else * go to HPM * REGULATOR_MODE_NORMAL: Go to LPM if it is the optimum mode, else go to HPM */ static int pm8901_vreg_set_mode(struct regulator_dev *dev, unsigned int mode) { struct pm8901_vreg *vreg = rdev_get_drvdata(dev); unsigned optimum = vreg->optimum; unsigned pc_vote = vreg->pc_vote; unsigned mode_initialized = vreg->mode_initialized; u8 val = 0; int rc = 0; /* Determine new mode to go into. */ switch (mode) { case REGULATOR_MODE_FAST: val = VREG_PMR_STATE_HPM; optimum = mode; mode_initialized = 1; break; case REGULATOR_MODE_STANDBY: if (pc_vote) val = VREG_PMR_STATE_PIN_CTRL; else val = VREG_PMR_STATE_LPM; optimum = mode; mode_initialized = 1; break; case REGULATOR_MODE_IDLE: if (pc_vote++) goto done; /* already taken care of */ if (mode_initialized && optimum == REGULATOR_MODE_FAST) val = VREG_PMR_STATE_HPM; else val = VREG_PMR_STATE_PIN_CTRL; break; case REGULATOR_MODE_NORMAL: if (pc_vote && --pc_vote) goto done; /* already taken care of */ if (optimum == REGULATOR_MODE_STANDBY) val = VREG_PMR_STATE_LPM; else val = VREG_PMR_STATE_HPM; break; default: pr_err("%s: unknown mode, mode=%u\n", __func__, mode); return -EINVAL; } /* Set pin control bits based on new mode. */ pm8901_vreg_select_pin_ctrl(vreg, &val); /* Only apply mode setting to hardware if currently enabled. */ if (pm8901_vreg_is_enabled(dev)) rc = pm8901_vreg_write(vreg, vreg->pmr_addr, val, VREG_PMR_STATE_MASK | VREG_PMR_PIN_CTRL_ALL_MASK, &vreg->pmr_reg); if (rc) { print_write_error(vreg, rc, __func__); return rc; } done: vreg->mode_initialized = mode_initialized; vreg->optimum = optimum; vreg->pc_vote = pc_vote; return 0; } static unsigned int pm8901_vreg_get_mode(struct regulator_dev *dev) { struct pm8901_vreg *vreg = rdev_get_drvdata(dev); int pin_mask = VREG_PMR_CTRL_PIN0_MASK | VREG_PMR_CTRL_PIN1_MASK | VREG_PMR_CTRL_PIN2_MASK; if (!vreg->mode_initialized && vreg->pc_vote) return REGULATOR_MODE_IDLE; else if (((vreg->pmr_reg & VREG_PMR_STATE_MASK) == VREG_PMR_STATE_OFF) && ((vreg->pmr_reg & pin_mask) != pin_mask)) return REGULATOR_MODE_IDLE; else if (((vreg->pmr_reg & VREG_PMR_STATE_MASK) == VREG_PMR_STATE_LPM) && ((vreg->pmr_reg & pin_mask) != pin_mask)) return REGULATOR_MODE_IDLE; else if (vreg->optimum == REGULATOR_MODE_FAST) return REGULATOR_MODE_FAST; else if (vreg->pc_vote) return REGULATOR_MODE_IDLE; else if (vreg->optimum == REGULATOR_MODE_STANDBY) return REGULATOR_MODE_STANDBY; return REGULATOR_MODE_FAST; } unsigned int pm8901_vreg_get_optimum_mode(struct regulator_dev *dev, int input_uV, int output_uV, int load_uA) { struct pm8901_vreg *vreg = rdev_get_drvdata(dev); if (load_uA <= 0) { /* * pm8901_vreg_get_optimum_mode is being called before consumers * have specified their load currents via * regulator_set_optimum_mode. Return whatever the existing mode * is. */ return pm8901_vreg_get_mode(dev); } if (load_uA >= vreg->hpm_min_load) return REGULATOR_MODE_FAST; return REGULATOR_MODE_STANDBY; } static int pm8901_smps_set_voltage(struct regulator_dev *dev, int min_uV, int max_uV, unsigned *selector) { struct pm8901_vreg *vreg = rdev_get_drvdata(dev); int rc; u8 val, band; if (IS_PMIC_8901_V1(pm8xxx_get_revision(vreg->dev->parent))) min_uV = PMIC_8901_V1_SCALE(min_uV); if (min_uV < SMPS_BAND_1_UV_MIN || min_uV > SMPS_BAND_3_UV_MAX) return -EINVAL; /* Round down for set points in the gaps between bands. */ if (min_uV > SMPS_BAND_1_UV_MAX && min_uV < SMPS_BAND_2_UV_MIN) min_uV = SMPS_BAND_1_UV_MAX; else if (min_uV > SMPS_BAND_2_UV_MAX && min_uV < SMPS_BAND_3_UV_SETPOINT_MIN) min_uV = SMPS_BAND_2_UV_MAX; if (min_uV < SMPS_BAND_2_UV_MIN) { val = ((min_uV - SMPS_BAND_1_UV_MIN) / SMPS_BAND_1_UV_STEP); val = PM8901_SMPS_BAND_1_COMPENSATE(val); band = SMPS_VCTRL_BAND_1; } else if (min_uV < SMPS_BAND_3_UV_SETPOINT_MIN) { val = ((min_uV - SMPS_BAND_2_UV_MIN) / SMPS_BAND_2_UV_STEP); band = SMPS_VCTRL_BAND_2; } else { val = ((min_uV - SMPS_BAND_3_UV_MIN) / SMPS_BAND_3_UV_STEP); band = SMPS_VCTRL_BAND_3; } rc = pm8901_vreg_write(vreg, vreg->ctrl_addr, band | val, SMPS_VCTRL_BAND_MASK | SMPS_VCTRL_VPROG_MASK, &vreg->ctrl_reg); if (rc) goto bail; rc = pm8901_vreg_write(vreg, vreg->pfm_ctrl_addr, band | val, SMPS_VCTRL_BAND_MASK | SMPS_VCTRL_VPROG_MASK, &vreg->pfm_ctrl_reg); bail: if (rc) print_write_error(vreg, rc, __func__); return rc; } static int pm8901_smps_get_voltage(struct regulator_dev *dev) { struct pm8901_vreg *vreg = rdev_get_drvdata(dev); u8 vprog, band; int ret = 0; if ((vreg->pmr_reg & VREG_PMR_STATE_MASK) == VREG_PMR_STATE_LPM) { vprog = vreg->pfm_ctrl_reg & SMPS_VCTRL_VPROG_MASK; band = vreg->pfm_ctrl_reg & SMPS_VCTRL_BAND_MASK; } else { vprog = vreg->ctrl_reg & SMPS_VCTRL_VPROG_MASK; band = vreg->ctrl_reg & SMPS_VCTRL_BAND_MASK; } if (band == SMPS_VCTRL_BAND_1) ret = vprog * SMPS_BAND_1_UV_STEP + SMPS_BAND_1_UV_MIN; else if (band == SMPS_VCTRL_BAND_2) ret = vprog * SMPS_BAND_2_UV_STEP + SMPS_BAND_2_UV_MIN; else ret = vprog * SMPS_BAND_3_UV_STEP + SMPS_BAND_3_UV_MIN; if (IS_PMIC_8901_V1(pm8xxx_get_revision(vreg->dev->parent))) ret = PMIC_8901_V1_SCALE_INV(ret); return ret; } static int pm8901_vs_enable(struct regulator_dev *dev) { struct pm8901_vreg *vreg = rdev_get_drvdata(dev); int rc; /* Assert enable bit in PMR register. */ rc = pm8901_vreg_enable(dev); /* Make sure that switch is controlled via PMR register */ rc = pm8901_vreg_write(vreg, vreg->ctrl_addr, VS_CTRL_USE_PMR, VS_CTRL_ENABLE_MASK, &vreg->ctrl_reg); if (rc) print_write_error(vreg, rc, __func__); return rc; } static int pm8901_vs_disable(struct regulator_dev *dev) { struct pm8901_vreg *vreg = rdev_get_drvdata(dev); int rc; /* Disassert enable bit in PMR register. */ rc = pm8901_vreg_disable(dev); /* Make sure that switch is controlled via PMR register */ rc = pm8901_vreg_write(vreg, vreg->ctrl_addr, VS_CTRL_USE_PMR, VS_CTRL_ENABLE_MASK, &vreg->ctrl_reg); if (rc) print_write_error(vreg, rc, __func__); return rc; } static struct regulator_ops pm8901_ldo_ops = { .enable = pm8901_vreg_enable, .disable = pm8901_ldo_disable, .is_enabled = pm8901_vreg_is_enabled, .set_voltage = pm8901_ldo_set_voltage, .get_voltage = pm8901_ldo_get_voltage, .set_mode = pm8901_vreg_set_mode, .get_mode = pm8901_vreg_get_mode, .get_optimum_mode = pm8901_vreg_get_optimum_mode, }; static struct regulator_ops pm8901_smps_ops = { .enable = pm8901_vreg_enable, .disable = pm8901_vreg_disable, .is_enabled = pm8901_vreg_is_enabled, .set_voltage = pm8901_smps_set_voltage, .get_voltage = pm8901_smps_get_voltage, .set_mode = pm8901_vreg_set_mode, .get_mode = pm8901_vreg_get_mode, .get_optimum_mode = pm8901_vreg_get_optimum_mode, }; static struct regulator_ops pm8901_vs_ops = { .enable = pm8901_vs_enable, .disable = pm8901_vs_disable, .is_enabled = pm8901_vreg_is_enabled, .set_mode = pm8901_vreg_set_mode, .get_mode = pm8901_vreg_get_mode, }; #define VREG_DESCRIP(_id, _name, _ops) \ [_id] = { \ .name = _name, \ .id = _id, \ .ops = _ops, \ .type = REGULATOR_VOLTAGE, \ .owner = THIS_MODULE, \ } static struct regulator_desc pm8901_vreg_descrip[] = { VREG_DESCRIP(PM8901_VREG_ID_L0, "8901_l0", &pm8901_ldo_ops), VREG_DESCRIP(PM8901_VREG_ID_L1, "8901_l1", &pm8901_ldo_ops), VREG_DESCRIP(PM8901_VREG_ID_L2, "8901_l2", &pm8901_ldo_ops), VREG_DESCRIP(PM8901_VREG_ID_L3, "8901_l3", &pm8901_ldo_ops), VREG_DESCRIP(PM8901_VREG_ID_L4, "8901_l4", &pm8901_ldo_ops), VREG_DESCRIP(PM8901_VREG_ID_L5, "8901_l5", &pm8901_ldo_ops), VREG_DESCRIP(PM8901_VREG_ID_L6, "8901_l6", &pm8901_ldo_ops), VREG_DESCRIP(PM8901_VREG_ID_S0, "8901_s0", &pm8901_smps_ops), VREG_DESCRIP(PM8901_VREG_ID_S1, "8901_s1", &pm8901_smps_ops), VREG_DESCRIP(PM8901_VREG_ID_S2, "8901_s2", &pm8901_smps_ops), VREG_DESCRIP(PM8901_VREG_ID_S3, "8901_s3", &pm8901_smps_ops), VREG_DESCRIP(PM8901_VREG_ID_S4, "8901_s4", &pm8901_smps_ops), VREG_DESCRIP(PM8901_VREG_ID_LVS0, "8901_lvs0", &pm8901_vs_ops), VREG_DESCRIP(PM8901_VREG_ID_LVS1, "8901_lvs1", &pm8901_vs_ops), VREG_DESCRIP(PM8901_VREG_ID_LVS2, "8901_lvs2", &pm8901_vs_ops), VREG_DESCRIP(PM8901_VREG_ID_LVS3, "8901_lvs3", &pm8901_vs_ops), VREG_DESCRIP(PM8901_VREG_ID_MVS0, "8901_mvs0", &pm8901_vs_ops), VREG_DESCRIP(PM8901_VREG_ID_USB_OTG, "8901_usb_otg", &pm8901_vs_ops), VREG_DESCRIP(PM8901_VREG_ID_HDMI_MVS, "8901_hdmi_mvs", &pm8901_vs_ops), }; static int pm8901_init_ldo(struct pm8901_vreg *vreg) { int rc = 0, i; u8 bank; /* Store current regulator register values. */ for (i = 0; i < LDO_TEST_BANKS; i++) { bank = REGULATOR_BANK_SEL(i); rc = pm8xxx_writeb(vreg->dev->parent, vreg->test_addr, bank); if (rc) goto bail; rc = pm8xxx_readb(vreg->dev->parent, vreg->test_addr, &vreg->test_reg[i]); if (rc) goto bail; vreg->test_reg[i] |= REGULATOR_BANK_WRITE; } /* Set pull down enable based on platform data. */ rc = pm8901_vreg_write(vreg, vreg->ctrl_addr, (vreg->pdata->pull_down_enable ? LDO_PULL_DOWN_ENABLE : 0), LDO_PULL_DOWN_ENABLE_MASK, &vreg->ctrl_reg); bail: return rc; } static int pm8901_init_smps(struct pm8901_vreg *vreg) { int rc; /* Store current regulator register values. */ rc = pm8xxx_readb(vreg->dev->parent, vreg->pfm_ctrl_addr, &vreg->pfm_ctrl_reg); if (rc) goto bail; rc = pm8xxx_readb(vreg->dev->parent, vreg->pwr_cnfg_addr, &vreg->pwr_cnfg_reg); if (rc) goto bail; /* Set pull down enable based on platform data. */ rc = pm8901_vreg_write(vreg, vreg->pwr_cnfg_addr, (vreg->pdata->pull_down_enable ? SMPS_PULL_DOWN_ENABLE : 0), SMPS_PULL_DOWN_ENABLE_MASK, &vreg->pwr_cnfg_reg); bail: return rc; } static int pm8901_init_vs(struct pm8901_vreg *vreg) { int rc = 0; /* Set pull down enable based on platform data. */ rc = pm8901_vreg_write(vreg, vreg->ctrl_addr, (vreg->pdata->pull_down_enable ? VS_PULL_DOWN_ENABLE : 0), VS_PULL_DOWN_ENABLE_MASK, &vreg->ctrl_reg); return rc; } static int pm8901_init_regulator(struct pm8901_vreg *vreg) { int rc; /* Store current regulator register values. */ rc = pm8xxx_readb(vreg->dev->parent, vreg->ctrl_addr, &vreg->ctrl_reg); if (rc) goto bail; rc = pm8xxx_readb(vreg->dev->parent, vreg->pmr_addr, &vreg->pmr_reg); if (rc) goto bail; /* Set initial mode based on hardware state. */ if ((vreg->pmr_reg & VREG_PMR_STATE_MASK) == VREG_PMR_STATE_LPM) vreg->optimum = REGULATOR_MODE_STANDBY; else vreg->optimum = REGULATOR_MODE_FAST; vreg->mode_initialized = 0; if (vreg->type == REGULATOR_TYPE_LDO) rc = pm8901_init_ldo(vreg); else if (vreg->type == REGULATOR_TYPE_SMPS) rc = pm8901_init_smps(vreg); else if (vreg->type == REGULATOR_TYPE_VS) rc = pm8901_init_vs(vreg); bail: if (rc) pr_err("%s: pm8901_read/write failed; initial register states " "unknown, rc=%d\n", __func__, rc); return rc; } static int __devinit pm8901_vreg_probe(struct platform_device *pdev) { struct regulator_desc *rdesc; struct pm8901_vreg *vreg; const char *reg_name = NULL; int rc = 0; if (pdev == NULL) return -EINVAL; if (pdev->id >= 0 && pdev->id < PM8901_VREG_MAX) { rdesc = &pm8901_vreg_descrip[pdev->id]; vreg = &pm8901_vreg[pdev->id]; vreg->pdata = pdev->dev.platform_data; reg_name = pm8901_vreg_descrip[pdev->id].name; vreg->dev = &pdev->dev; rc = pm8901_init_regulator(vreg); if (rc) goto bail; /* Disallow idle and normal modes if pin control isn't set. */ if (vreg->pdata->pin_ctrl == 0) vreg->pdata->init_data.constraints.valid_modes_mask &= ~(REGULATOR_MODE_NORMAL | REGULATOR_MODE_IDLE); vreg->rdev = regulator_register(rdesc, &pdev->dev, &vreg->pdata->init_data, vreg, NULL); if (IS_ERR(vreg->rdev)) { rc = PTR_ERR(vreg->rdev); pr_err("%s: regulator_register failed for %s, rc=%d\n", __func__, reg_name, rc); } } else { rc = -ENODEV; } bail: if (rc) pr_err("%s: error for %s, rc=%d\n", __func__, reg_name, rc); return rc; } static int __devexit pm8901_vreg_remove(struct platform_device *pdev) { regulator_unregister(pm8901_vreg[pdev->id].rdev); return 0; } static struct platform_driver pm8901_vreg_driver = { .probe = pm8901_vreg_probe, .remove = __devexit_p(pm8901_vreg_remove), .driver = { .name = "pm8901-regulator", .owner = THIS_MODULE, }, }; static int __init pm8901_vreg_init(void) { return platform_driver_register(&pm8901_vreg_driver); } static void __exit pm8901_vreg_exit(void) { platform_driver_unregister(&pm8901_vreg_driver); } static void print_write_error(struct pm8901_vreg *vreg, int rc, const char *func) { const char *reg_name = NULL; ptrdiff_t id = vreg - pm8901_vreg; if (id >= 0 && id < PM8901_VREG_MAX) reg_name = pm8901_vreg_descrip[id].name; pr_err("%s: pm8901_vreg_write failed for %s, rc=%d\n", func, reg_name, rc); } subsys_initcall(pm8901_vreg_init); module_exit(pm8901_vreg_exit); MODULE_LICENSE("GPL v2"); MODULE_DESCRIPTION("PMIC8901 regulator driver"); MODULE_VERSION("1.0"); MODULE_ALIAS("platform:pm8901-regulator");