/* * AXP221 and AXP223 driver * * IMPORTANT when making changes to this file check that the registers * used are the same for the axp221 and axp223. * * (C) Copyright 2014 Hans de Goede * (C) Copyright 2013 Oliver Schinagl * * SPDX-License-Identifier: GPL-2.0+ */ #include #include #include #include #include #include /* * The axp221 uses the p2wi bus, the axp223 is identical (for all registers * used sofar) but uses the rsb bus. These functions abstract this. */ static int pmic_bus_init(void) { #ifdef CONFIG_MACH_SUN6I p2wi_init(); return p2wi_change_to_p2wi_mode(AXP221_CHIP_ADDR, AXP221_CTRL_ADDR, AXP221_INIT_DATA); #else int ret; ret = rsb_init(); if (ret) return ret; return rsb_set_device_address(AXP223_DEVICE_ADDR, AXP223_RUNTIME_ADDR); #endif } static int pmic_bus_read(const u8 addr, u8 *data) { #ifdef CONFIG_MACH_SUN6I return p2wi_read(addr, data); #else return rsb_read(AXP223_RUNTIME_ADDR, addr, data); #endif } static int pmic_bus_write(const u8 addr, u8 data) { #ifdef CONFIG_MACH_SUN6I return p2wi_write(addr, data); #else return rsb_write(AXP223_RUNTIME_ADDR, addr, data); #endif } static u8 axp221_mvolt_to_cfg(int mvolt, int min, int max, int div) { if (mvolt < min) mvolt = min; else if (mvolt > max) mvolt = max; return (mvolt - min) / div; } static int axp221_setbits(u8 reg, u8 bits) { int ret; u8 val; ret = pmic_bus_read(reg, &val); if (ret) return ret; val |= bits; return pmic_bus_write(reg, val); } static int axp221_clrbits(u8 reg, u8 bits) { int ret; u8 val; ret = pmic_bus_read(reg, &val); if (ret) return ret; val &= ~bits; return pmic_bus_write(reg, val); } int axp221_set_dcdc1(unsigned int mvolt) { int ret; u8 cfg = axp221_mvolt_to_cfg(mvolt, 1600, 3400, 100); if (mvolt == 0) return axp221_clrbits(AXP221_OUTPUT_CTRL1, AXP221_OUTPUT_CTRL1_DCDC1_EN); ret = pmic_bus_write(AXP221_DCDC1_CTRL, cfg); if (ret) return ret; ret = axp221_setbits(AXP221_OUTPUT_CTRL2, AXP221_OUTPUT_CTRL2_DCDC1SW_EN); if (ret) return ret; return axp221_setbits(AXP221_OUTPUT_CTRL1, AXP221_OUTPUT_CTRL1_DCDC1_EN); } int axp221_set_dcdc2(unsigned int mvolt) { int ret; u8 cfg = axp221_mvolt_to_cfg(mvolt, 600, 1540, 20); if (mvolt == 0) return axp221_clrbits(AXP221_OUTPUT_CTRL1, AXP221_OUTPUT_CTRL1_DCDC2_EN); ret = pmic_bus_write(AXP221_DCDC2_CTRL, cfg); if (ret) return ret; return axp221_setbits(AXP221_OUTPUT_CTRL1, AXP221_OUTPUT_CTRL1_DCDC2_EN); } int axp221_set_dcdc3(unsigned int mvolt) { int ret; u8 cfg = axp221_mvolt_to_cfg(mvolt, 600, 1860, 20); if (mvolt == 0) return axp221_clrbits(AXP221_OUTPUT_CTRL1, AXP221_OUTPUT_CTRL1_DCDC3_EN); ret = pmic_bus_write(AXP221_DCDC3_CTRL, cfg); if (ret) return ret; return axp221_setbits(AXP221_OUTPUT_CTRL1, AXP221_OUTPUT_CTRL1_DCDC3_EN); } int axp221_set_dcdc4(unsigned int mvolt) { int ret; u8 cfg = axp221_mvolt_to_cfg(mvolt, 600, 1540, 20); if (mvolt == 0) return axp221_clrbits(AXP221_OUTPUT_CTRL1, AXP221_OUTPUT_CTRL1_DCDC4_EN); ret = pmic_bus_write(AXP221_DCDC4_CTRL, cfg); if (ret) return ret; return axp221_setbits(AXP221_OUTPUT_CTRL1, AXP221_OUTPUT_CTRL1_DCDC4_EN); } int axp221_set_dcdc5(unsigned int mvolt) { int ret; u8 cfg = axp221_mvolt_to_cfg(mvolt, 1000, 2550, 50); if (mvolt == 0) return axp221_clrbits(AXP221_OUTPUT_CTRL1, AXP221_OUTPUT_CTRL1_DCDC5_EN); ret = pmic_bus_write(AXP221_DCDC5_CTRL, cfg); if (ret) return ret; return axp221_setbits(AXP221_OUTPUT_CTRL1, AXP221_OUTPUT_CTRL1_DCDC5_EN); } int axp221_set_dldo1(unsigned int mvolt) { int ret; u8 cfg = axp221_mvolt_to_cfg(mvolt, 700, 3300, 100); if (mvolt == 0) return axp221_clrbits(AXP221_OUTPUT_CTRL2, AXP221_OUTPUT_CTRL2_DLDO1_EN); ret = pmic_bus_write(AXP221_DLDO1_CTRL, cfg); if (ret) return ret; return axp221_setbits(AXP221_OUTPUT_CTRL2, AXP221_OUTPUT_CTRL2_DLDO1_EN); } int axp221_set_dldo2(unsigned int mvolt) { int ret; u8 cfg = axp221_mvolt_to_cfg(mvolt, 700, 3300, 100); if (mvolt == 0) return axp221_clrbits(AXP221_OUTPUT_CTRL2, AXP221_OUTPUT_CTRL2_DLDO2_EN); ret = pmic_bus_write(AXP221_DLDO2_CTRL, cfg); if (ret) return ret; return axp221_setbits(AXP221_OUTPUT_CTRL2, AXP221_OUTPUT_CTRL2_DLDO2_EN); } int axp221_set_dldo3(unsigned int mvolt) { int ret; u8 cfg = axp221_mvolt_to_cfg(mvolt, 700, 3300, 100); if (mvolt == 0) return axp221_clrbits(AXP221_OUTPUT_CTRL2, AXP221_OUTPUT_CTRL2_DLDO3_EN); ret = pmic_bus_write(AXP221_DLDO3_CTRL, cfg); if (ret) return ret; return axp221_setbits(AXP221_OUTPUT_CTRL2, AXP221_OUTPUT_CTRL2_DLDO3_EN); } int axp221_set_dldo4(unsigned int mvolt) { int ret; u8 cfg = axp221_mvolt_to_cfg(mvolt, 700, 3300, 100); if (mvolt == 0) return axp221_clrbits(AXP221_OUTPUT_CTRL2, AXP221_OUTPUT_CTRL2_DLDO4_EN); ret = pmic_bus_write(AXP221_DLDO4_CTRL, cfg); if (ret) return ret; return axp221_setbits(AXP221_OUTPUT_CTRL2, AXP221_OUTPUT_CTRL2_DLDO4_EN); } int axp221_set_aldo1(unsigned int mvolt) { int ret; u8 cfg = axp221_mvolt_to_cfg(mvolt, 700, 3300, 100); if (mvolt == 0) return axp221_clrbits(AXP221_OUTPUT_CTRL1, AXP221_OUTPUT_CTRL1_ALDO1_EN); ret = pmic_bus_write(AXP221_ALDO1_CTRL, cfg); if (ret) return ret; return axp221_setbits(AXP221_OUTPUT_CTRL1, AXP221_OUTPUT_CTRL1_ALDO1_EN); } int axp221_set_aldo2(unsigned int mvolt) { int ret; u8 cfg = axp221_mvolt_to_cfg(mvolt, 700, 3300, 100); if (mvolt == 0) return axp221_clrbits(AXP221_OUTPUT_CTRL1, AXP221_OUTPUT_CTRL1_ALDO2_EN); ret = pmic_bus_write(AXP221_ALDO2_CTRL, cfg); if (ret) return ret; return axp221_setbits(AXP221_OUTPUT_CTRL1, AXP221_OUTPUT_CTRL1_ALDO2_EN); } int axp221_set_aldo3(unsigned int mvolt) { int ret; u8 cfg = axp221_mvolt_to_cfg(mvolt, 700, 3300, 100); if (mvolt == 0) return axp221_clrbits(AXP221_OUTPUT_CTRL3, AXP221_OUTPUT_CTRL3_ALDO3_EN); ret = pmic_bus_write(AXP221_ALDO3_CTRL, cfg); if (ret) return ret; return axp221_setbits(AXP221_OUTPUT_CTRL3, AXP221_OUTPUT_CTRL3_ALDO3_EN); } int axp221_set_eldo(int eldo_num, unsigned int mvolt) { int ret; u8 cfg = axp221_mvolt_to_cfg(mvolt, 700, 3300, 100); u8 addr, bits; switch (eldo_num) { case 3: addr = AXP221_ELDO3_CTRL; bits = AXP221_OUTPUT_CTRL2_ELDO3_EN; break; case 2: addr = AXP221_ELDO2_CTRL; bits = AXP221_OUTPUT_CTRL2_ELDO2_EN; break; case 1: addr = AXP221_ELDO1_CTRL; bits = AXP221_OUTPUT_CTRL2_ELDO1_EN; break; default: return -EINVAL; } if (mvolt == 0) return axp221_clrbits(AXP221_OUTPUT_CTRL2, bits); ret = pmic_bus_write(addr, cfg); if (ret) return ret; return axp221_setbits(AXP221_OUTPUT_CTRL2, bits); } int axp221_init(void) { /* This cannot be 0 because it is used in SPL before BSS is ready */ static int needs_init = 1; u8 axp_chip_id; int ret; if (!needs_init) return 0; ret = pmic_bus_init(); if (ret) return ret; ret = pmic_bus_read(AXP221_CHIP_ID, &axp_chip_id); if (ret) return ret; if (!(axp_chip_id == 0x6 || axp_chip_id == 0x7 || axp_chip_id == 0x17)) return -ENODEV; needs_init = 0; return 0; } int axp221_get_sid(unsigned int *sid) { u8 *dest = (u8 *)sid; int i, ret; ret = axp221_init(); if (ret) return ret; ret = pmic_bus_write(AXP221_PAGE, 1); if (ret) return ret; for (i = 0; i < 16; i++) { ret = pmic_bus_read(AXP221_SID + i, &dest[i]); if (ret) return ret; } pmic_bus_write(AXP221_PAGE, 0); for (i = 0; i < 4; i++) sid[i] = be32_to_cpu(sid[i]); return 0; } int axp_gpio_direction_input(unsigned int pin) { switch (pin) { case SUNXI_GPIO_AXP0_VBUS_DETECT: return 0; default: return -EINVAL; } } int axp_gpio_direction_output(unsigned int pin, unsigned int val) { int ret; switch (pin) { case SUNXI_GPIO_AXP0_VBUS_ENABLE: ret = axp221_clrbits(AXP221_MISC_CTRL, AXP221_MISC_CTRL_N_VBUSEN_FUNC); if (ret) return ret; return axp_gpio_set_value(pin, val); default: return -EINVAL; } } int axp_gpio_get_value(unsigned int pin) { int ret; u8 val; switch (pin) { case SUNXI_GPIO_AXP0_VBUS_DETECT: ret = pmic_bus_read(AXP221_POWER_STATUS, &val); if (ret) return ret; return !!(val & AXP221_POWER_STATUS_VBUS_AVAIL); default: return -EINVAL; } } int axp_gpio_set_value(unsigned int pin, unsigned int val) { int ret; switch (pin) { case SUNXI_GPIO_AXP0_VBUS_ENABLE: if (val) ret = axp221_setbits(AXP221_VBUS_IPSOUT, AXP221_VBUS_IPSOUT_DRIVEBUS); else ret = axp221_clrbits(AXP221_VBUS_IPSOUT, AXP221_VBUS_IPSOUT_DRIVEBUS); if (ret) return ret; } return 0; }