/* * Copyright (C) 2019 Allwinner. * weidonghui * * SUNXI AXP21 Driver * * SPDX-License-Identifier: GPL-2.0+ */ #include #include #include #include /*#include */ #ifdef PMU_DEBUG #define axp_info(fmt...) tick_printf("[axp][info]: " fmt) #define axp_err(fmt...) tick_printf("[axp][err]: " fmt) #else #define axp_info(fmt...) #define axp_err(fmt...) tick_printf("[axp][err]: " fmt) #endif typedef struct _axp_contrl_info { char name[16]; u32 min_vol; u32 max_vol; u32 cfg_reg_addr; u32 cfg_reg_mask; u32 step0_val; u32 split1_val; u32 step1_val; u32 ctrl_reg_addr; u32 ctrl_bit_ofs; u32 step2_val; u32 split2_val; } axp_contrl_info; __attribute__((section(".data"))) axp_contrl_info pmu_axp1530_ctrl_tbl[] = { /*name, min, max, reg, mask, step0,split1_val, step1,ctrl_reg,ctrl_bit */ { "dcdc1", 500, 3400, AXP1530_DC1OUT_VOL, 0x7f, 10, 1200, 20, AXP1530_OUTPUT_POWER_ON_OFF_CTL, 0, 100, 1540 }, { "dcdc2", 500, 1540, AXP1530_DC2OUT_VOL, 0x7f, 10, 1200, 20, AXP1530_OUTPUT_POWER_ON_OFF_CTL, 1 }, { "dcdc3", 500, 1840, AXP1530_DC3OUT_VOL, 0x7f, 10, 1200, 20, AXP1530_OUTPUT_POWER_ON_OFF_CTL, 2 }, { "aldo1", 500, 3500, AXP1530_ALDO1OUT_VOL, 0x1f, 100, 0, 0, AXP1530_OUTPUT_POWER_ON_OFF_CTL, 3 }, { "dldo1", 500, 3500, AXP1530_DLDO1OUT_VOL, 0x1f, 100, 0, 0, AXP1530_OUTPUT_POWER_ON_OFF_CTL, 4 }, }; static axp_contrl_info *get_ctrl_info_from_tbl(char *name) { int i = 0; int size = ARRAY_SIZE(pmu_axp1530_ctrl_tbl); axp_contrl_info *p; for (i = 0; i < size; i++) { if (!strncmp(name, pmu_axp1530_ctrl_tbl[i].name, strlen(pmu_axp1530_ctrl_tbl[i].name))) { break; } } if (i >= size) { axp_err("can't find %s from table\n", name); return NULL; } p = pmu_axp1530_ctrl_tbl + i; return p; } static int pmu_axp1530_necessary_reg_enable(void) { __attribute__((unused)) u8 reg_value; #ifdef CONFIG_AXP1530A_NECESSARY_REG_ENABLE if (pmic_bus_read(AXP1530_RUNTIME_ADDR, AXP1530_WRITE_LOCK, ®_value)) return -1; reg_value |= 0x5; if (pmic_bus_write(AXP1530_RUNTIME_ADDR, AXP1530_WRITE_LOCK, reg_value)) return -1; if (pmic_bus_read(AXP1530_RUNTIME_ADDR, AXP1530_ERROR_MANAGEMENT, ®_value)) return -1; reg_value |= 0x8; if (pmic_bus_write(AXP1530_RUNTIME_ADDR, AXP1530_ERROR_MANAGEMENT, reg_value)) return -1; if (pmic_bus_read(AXP1530_RUNTIME_ADDR, AXP1530_DCDC_DVM_PWM_CTL, ®_value)) return -1; reg_value |= (0x1 << 5); if (pmic_bus_write(AXP1530_RUNTIME_ADDR, AXP1530_DCDC_DVM_PWM_CTL, reg_value)) return -1; #endif return 0; } static int pmu_axp1530_probe(void) { u8 pmu_chip_id; if (pmic_bus_init(AXP1530_DEVICE_ADDR, AXP1530_RUNTIME_ADDR)) { tick_printf("%s pmic_bus_init fail\n", __func__); return -1; } if (pmic_bus_read(AXP1530_RUNTIME_ADDR, AXP1530_VERSION, &pmu_chip_id)) { tick_printf("%s pmic_bus_read fail\n", __func__); return -1; } pmu_chip_id &= 0XCF; if (pmu_chip_id == AXP1530_CHIP_ID) { /*pmu type AXP1530*/ pmu_axp1530_necessary_reg_enable(); tick_printf("PMU: AXP1530\n"); return 0; } return -1; } static int pmu_axp1530_get_info(char *name, unsigned char *chipid) { strncpy(name, "axp1530", sizeof("axp1530")); *chipid = AXP1530_CHIP_ID; return 0; } static int pmu_axp1530_set_voltage(char *name, uint set_vol, uint onoff) { u8 reg_value; axp_contrl_info *p_item = NULL; u8 base_step = 0; p_item = get_ctrl_info_from_tbl(name); if (!p_item) { return -1; } axp_info( "name %s, min_vol %dmv, max_vol %d, cfg_reg 0x%x, cfg_mask 0x%x \ step0_val %d, split1_val %d, step1_val %d, ctrl_reg_addr 0x%x, ctrl_bit_ofs %d\n", p_item->name, p_item->min_vol, p_item->max_vol, p_item->cfg_reg_addr, p_item->cfg_reg_mask, p_item->step0_val, p_item->split1_val, p_item->step1_val, p_item->ctrl_reg_addr, p_item->ctrl_bit_ofs); if ((set_vol > 0) && (p_item->min_vol)) { if (set_vol < p_item->min_vol) { set_vol = p_item->min_vol; } else if (set_vol > p_item->max_vol) { set_vol = p_item->max_vol; } if (pmic_bus_read(AXP1530_RUNTIME_ADDR, p_item->cfg_reg_addr, ®_value)) { return -1; } reg_value &= ~p_item->cfg_reg_mask; if (p_item->split2_val && (set_vol > p_item->split2_val)) { base_step = (p_item->split2_val - p_item->split1_val) / p_item->step1_val; base_step += (p_item->split1_val - p_item->min_vol) / p_item->step0_val; reg_value |= (base_step + (set_vol - p_item->split2_val/p_item->step2_val*p_item->step2_val) / p_item->step2_val); } else if (p_item->split1_val && (set_vol > p_item->split1_val)) { if (p_item->split1_val < p_item->min_vol) { axp_err("bad split val(%d) for %s\n", p_item->split1_val, name); } base_step = (p_item->split1_val - p_item->min_vol) / p_item->step0_val; reg_value |= (base_step + (set_vol - p_item->split1_val) / p_item->step1_val); } else { reg_value |= (set_vol - p_item->min_vol) / p_item->step0_val; } if (pmic_bus_write(AXP1530_RUNTIME_ADDR, p_item->cfg_reg_addr, reg_value)) { axp_err("unable to set %s\n", name); return -1; } } if (onoff < 0) { return 0; } if (pmic_bus_read(AXP1530_RUNTIME_ADDR, p_item->ctrl_reg_addr, ®_value)) { return -1; } if (onoff == 0) { reg_value &= ~(1 << p_item->ctrl_bit_ofs); } else { reg_value |= (1 << p_item->ctrl_bit_ofs); } if (pmic_bus_write(AXP1530_RUNTIME_ADDR, p_item->ctrl_reg_addr, reg_value)) { axp_err("unable to onoff %s\n", name); return -1; } return 0; } static int pmu_axp1530_get_voltage(char *name) { u8 reg_value; axp_contrl_info *p_item = NULL; u8 base_step; int vol; p_item = get_ctrl_info_from_tbl(name); if (!p_item) { return -1; } if (pmic_bus_read(AXP1530_RUNTIME_ADDR, p_item->ctrl_reg_addr, ®_value)) { return -1; } if (!(reg_value & (0x01 << p_item->ctrl_bit_ofs))) { return 0; } if (pmic_bus_read(AXP1530_RUNTIME_ADDR, p_item->cfg_reg_addr, ®_value)) { return -1; } reg_value &= p_item->cfg_reg_mask; if (p_item->split2_val) { u32 base_step2; base_step = (p_item->split1_val - p_item->min_vol) / p_item->step0_val; base_step2 = base_step + (p_item->split2_val - p_item->split1_val) / p_item->step1_val; if (reg_value >= base_step2) { vol = ALIGN(p_item->split2_val, p_item->step2_val) + p_item->step2_val * (reg_value - base_step2); } else if (reg_value >= base_step) { vol = p_item->split1_val + p_item->step1_val * (reg_value - base_step); } else { vol = p_item->min_vol + p_item->step0_val * reg_value; } } else if (p_item->split1_val) { base_step = (p_item->split1_val - p_item->min_vol) / p_item->step0_val; if (reg_value > base_step) { vol = p_item->split1_val + p_item->step1_val * (reg_value - base_step); } else { vol = p_item->min_vol + p_item->step0_val * reg_value; } } else { vol = p_item->min_vol + p_item->step0_val * reg_value; } return vol; } static int pmu_axp1530_set_power_off(void) { u8 reg_value; if (pmic_bus_read(AXP1530_RUNTIME_ADDR, AXP1530_POWER_DOMN_SEQUENCE, ®_value)) { return -1; } reg_value |= (1<<7); if (pmic_bus_write(AXP1530_RUNTIME_ADDR, AXP1530_POWER_DOMN_SEQUENCE, reg_value)) { return -1; } return 0; } static int pmu_axp1530_get_key_irq(void) { u8 reg_value; if (pmic_bus_read(AXP1530_RUNTIME_ADDR, AXP1530_IRQ_STATUS, ®_value)) { return -1; } reg_value &= (0x03 << 4); if (reg_value) { if (pmic_bus_write(AXP1530_RUNTIME_ADDR, AXP1530_IRQ_STATUS, reg_value)) { return -1; } } return (reg_value >> 4) & 3; } unsigned char pmu_axp1530_get_reg_value(unsigned char reg_addr) { u8 reg_value; if (pmic_bus_read(AXP1530_RUNTIME_ADDR, reg_addr, ®_value)) { return -1; } return reg_value; } unsigned char pmu_axp1530_set_reg_value(unsigned char reg_addr, unsigned char reg_value) { unsigned char reg; if (pmic_bus_write(AXP1530_RUNTIME_ADDR, reg_addr, reg_value)) { return -1; } if (pmic_bus_read(AXP1530_RUNTIME_ADDR, reg_addr, ®)) { return -1; } return reg; } U_BOOT_AXP_PMU_INIT(pmu_axp1530) = { .pmu_name = "pmu_axp1530", .get_info = pmu_axp1530_get_info, .probe = pmu_axp1530_probe, .set_voltage = pmu_axp1530_set_voltage, .get_voltage = pmu_axp1530_get_voltage, .set_power_off = pmu_axp1530_set_power_off, /*.set_sys_mode = pmu_axp1530_set_sys_mode,*/ /*.get_sys_mode = pmu_axp1530_get_sys_mode,*/ .get_key_irq = pmu_axp1530_get_key_irq, /*.set_bus_vol_limit = pmu_axp1530_set_bus_vol_limit,*/ .get_reg_value = pmu_axp1530_get_reg_value, .set_reg_value = pmu_axp1530_set_reg_value, };