/* * Copyright (c) 2017-2019, ARM Limited and Contributors. All rights reserved. * Copyright (c) 2018, Icenowy Zheng * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #include #include #include #include #include #include #include #include static enum pmic_type { UNKNOWN, GENERIC_H5, GENERIC_A64, REF_DESIGN_H5, /* regulators controlled by GPIO pins on port L */ AXP803_RSB, /* PMIC connected via RSB on most A64 boards */ } pmic; #define AXP803_HW_ADDR 0x3a3 #define AXP803_RT_ADDR 0x2d /* * On boards without a proper PMIC we struggle to turn off the system properly. * Try to turn off as much off the system as we can, to reduce power * consumption. This should be entered with only one core running and SMP * disabled. * This function only cares about peripherals. */ static void sunxi_turn_off_soc(uint16_t socid) { int i; /** Turn off most peripherals, most importantly DRAM users. **/ /* Keep DRAM controller running for now. */ mmio_clrbits_32(SUNXI_CCU_BASE + 0x2c0, ~BIT_32(14)); mmio_clrbits_32(SUNXI_CCU_BASE + 0x60, ~BIT_32(14)); /* Contains msgbox (bit 21) and spinlock (bit 22) */ mmio_write_32(SUNXI_CCU_BASE + 0x2c4, 0); mmio_write_32(SUNXI_CCU_BASE + 0x64, 0); mmio_write_32(SUNXI_CCU_BASE + 0x2c8, 0); /* Keep PIO controller running for now. */ mmio_clrbits_32(SUNXI_CCU_BASE + 0x68, ~(BIT_32(5))); mmio_write_32(SUNXI_CCU_BASE + 0x2d0, 0); /* Contains UART0 (bit 16) */ mmio_write_32(SUNXI_CCU_BASE + 0x2d8, 0); mmio_write_32(SUNXI_CCU_BASE + 0x6c, 0); mmio_write_32(SUNXI_CCU_BASE + 0x70, 0); /** Turn off DRAM controller. **/ mmio_clrbits_32(SUNXI_CCU_BASE + 0x2c0, BIT_32(14)); mmio_clrbits_32(SUNXI_CCU_BASE + 0x60, BIT_32(14)); /** Migrate CPU and bus clocks away from the PLLs. **/ /* AHB1: use OSC24M/1, APB1 = AHB1 / 2 */ mmio_write_32(SUNXI_CCU_BASE + 0x54, 0x1000); /* APB2: use OSC24M */ mmio_write_32(SUNXI_CCU_BASE + 0x58, 0x1000000); /* AHB2: use AHB1 clock */ mmio_write_32(SUNXI_CCU_BASE + 0x5c, 0); /* CPU: use OSC24M */ mmio_write_32(SUNXI_CCU_BASE + 0x50, 0x10000); /** Turn off PLLs. **/ for (i = 0; i < 6; i++) mmio_clrbits_32(SUNXI_CCU_BASE + i * 8, BIT(31)); switch (socid) { case SUNXI_SOC_H5: mmio_clrbits_32(SUNXI_CCU_BASE + 0x44, BIT(31)); break; case SUNXI_SOC_A64: mmio_clrbits_32(SUNXI_CCU_BASE + 0x2c, BIT(31)); mmio_clrbits_32(SUNXI_CCU_BASE + 0x4c, BIT(31)); break; } } static int rsb_init(void) { int ret; ret = rsb_init_controller(); if (ret) return ret; /* Start with 400 KHz to issue the I2C->RSB switch command. */ ret = rsb_set_bus_speed(SUNXI_OSC24M_CLK_IN_HZ, 400000); if (ret) return ret; /* * Initiate an I2C transaction to write 0x7c into register 0x3e, * switching the PMIC to RSB mode. */ ret = rsb_set_device_mode(0x7c3e00); if (ret) return ret; /* Now in RSB mode, switch to the recommended 3 MHz. */ ret = rsb_set_bus_speed(SUNXI_OSC24M_CLK_IN_HZ, 3000000); if (ret) return ret; /* Associate the 8-bit runtime address with the 12-bit bus address. */ return rsb_assign_runtime_address(AXP803_HW_ADDR, AXP803_RT_ADDR); } static int axp_write(uint8_t reg, uint8_t val) { return rsb_write(AXP803_RT_ADDR, reg, val); } static int axp_clrsetbits(uint8_t reg, uint8_t clr_mask, uint8_t set_mask) { uint8_t regval; int ret; ret = rsb_read(AXP803_RT_ADDR, reg); if (ret < 0) return ret; regval = (ret & ~clr_mask) | set_mask; return rsb_write(AXP803_RT_ADDR, reg, regval); } #define axp_clrbits(reg, clr_mask) axp_clrsetbits(reg, clr_mask, 0) #define axp_setbits(reg, set_mask) axp_clrsetbits(reg, 0, set_mask) static bool should_enable_regulator(const void *fdt, int node) { if (fdt_getprop(fdt, node, "phandle", NULL) != NULL) return true; if (fdt_getprop(fdt, node, "regulator-always-on", NULL) != NULL) return true; return false; } /* * Retrieve the voltage from a given regulator DTB node. * Both the regulator-{min,max}-microvolt properties must be present and * have the same value. Return that value in millivolts. */ static int fdt_get_regulator_millivolt(const void *fdt, int node) { const fdt32_t *prop; uint32_t min_volt; prop = fdt_getprop(fdt, node, "regulator-min-microvolt", NULL); if (prop == NULL) return -EINVAL; min_volt = fdt32_to_cpu(*prop); prop = fdt_getprop(fdt, node, "regulator-max-microvolt", NULL); if (prop == NULL) return -EINVAL; if (fdt32_to_cpu(*prop) != min_volt) return -EINVAL; return min_volt / 1000; } #define NO_SPLIT 0xff static const struct axp_regulator { char *dt_name; uint16_t min_volt; uint16_t max_volt; uint16_t step; unsigned char split; unsigned char volt_reg; unsigned char switch_reg; unsigned char switch_bit; } regulators[] = { {"dcdc1", 1600, 3400, 100, NO_SPLIT, 0x20, 0x10, 0}, {"dcdc5", 800, 1840, 10, 32, 0x24, 0x10, 4}, {"dcdc6", 600, 1520, 10, 50, 0x25, 0x10, 5}, {"dldo1", 700, 3300, 100, NO_SPLIT, 0x15, 0x12, 3}, {"dldo2", 700, 4200, 100, 27, 0x16, 0x12, 4}, {"dldo3", 700, 3300, 100, NO_SPLIT, 0x17, 0x12, 5}, {"dldo4", 700, 3300, 100, NO_SPLIT, 0x18, 0x12, 6}, {"fldo1", 700, 1450, 50, NO_SPLIT, 0x1c, 0x13, 2}, {} }; static int setup_regulator(const void *fdt, int node, const struct axp_regulator *reg) { int mvolt; uint8_t regval; mvolt = fdt_get_regulator_millivolt(fdt, node); if (mvolt < reg->min_volt || mvolt > reg->max_volt) return -EINVAL; regval = (mvolt / reg->step) - (reg->min_volt / reg->step); if (regval > reg->split) regval = ((regval - reg->split) / 2) + reg->split; axp_write(reg->volt_reg, regval); if (reg->switch_reg < 0xff) axp_setbits(reg->switch_reg, BIT(reg->switch_bit)); INFO("PMIC: AXP803: %s voltage: %d.%03dV\n", reg->dt_name, mvolt / 1000, mvolt % 1000); return 0; } static void setup_axp803_rails(const void *fdt) { int node; bool dc1sw = false; /* locate the PMIC DT node, bail out if not found */ node = fdt_node_offset_by_compatible(fdt, -1, "x-powers,axp803"); if (node < 0) { WARN("PMIC: No PMIC DT node, skipping setup\n"); return; } if (fdt_getprop(fdt, node, "x-powers,drive-vbus-en", NULL)) { axp_clrbits(0x8f, BIT(4)); axp_setbits(0x30, BIT(2)); INFO("PMIC: AXP803: Enabling DRIVEVBUS\n"); } /* descend into the "regulators" subnode */ node = fdt_subnode_offset(fdt, node, "regulators"); if (node < 0) { WARN("PMIC: No regulators DT node, skipping setup\n"); return; } /* iterate over all regulators to find used ones */ for (node = fdt_first_subnode(fdt, node); node >= 0; node = fdt_next_subnode(fdt, node)) { const struct axp_regulator *reg; const char *name; int length; /* We only care if it's always on or referenced. */ if (!should_enable_regulator(fdt, node)) continue; name = fdt_get_name(fdt, node, &length); for (reg = regulators; reg->dt_name; reg++) { if (!strncmp(name, reg->dt_name, length)) { setup_regulator(fdt, node, reg); break; } } if (!strncmp(name, "dc1sw", length)) { /* Delay DC1SW enablement to avoid overheating. */ dc1sw = true; continue; } } /* * If DLDO2 is enabled after DC1SW, the PMIC overheats and shuts * down. So always enable DC1SW as the very last regulator. */ if (dc1sw) { INFO("PMIC: AXP803: Enabling DC1SW\n"); axp_setbits(0x12, BIT(7)); } } int sunxi_pmic_setup(uint16_t socid, const void *fdt) { int ret; switch (socid) { case SUNXI_SOC_H5: NOTICE("PMIC: Assuming H5 reference regulator design\n"); pmic = REF_DESIGN_H5; break; case SUNXI_SOC_A64: pmic = GENERIC_A64; INFO("PMIC: Probing AXP803 on RSB\n"); ret = sunxi_init_platform_r_twi(socid, true); if (ret) return ret; ret = rsb_init(); if (ret) return ret; pmic = AXP803_RSB; if (fdt) setup_axp803_rails(fdt); break; default: return -ENODEV; } return 0; } void sunxi_power_down(void) { switch (pmic) { case GENERIC_H5: /* Turn off as many peripherals and clocks as we can. */ sunxi_turn_off_soc(SUNXI_SOC_H5); /* Turn off the pin controller now. */ mmio_write_32(SUNXI_CCU_BASE + 0x68, 0); break; case GENERIC_A64: /* Turn off as many peripherals and clocks as we can. */ sunxi_turn_off_soc(SUNXI_SOC_A64); /* Turn off the pin controller now. */ mmio_write_32(SUNXI_CCU_BASE + 0x68, 0); break; case REF_DESIGN_H5: sunxi_turn_off_soc(SUNXI_SOC_H5); /* * Switch PL pins to power off the board: * - PL5 (VCC_IO) -> high * - PL8 (PWR-STB = CPU power supply) -> low * - PL9 (PWR-DRAM) ->low * - PL10 (power LED) -> low * Note: Clearing PL8 will reset the board, so keep it up. */ sunxi_set_gpio_out('L', 5, 1); sunxi_set_gpio_out('L', 9, 0); sunxi_set_gpio_out('L', 10, 0); /* Turn off pin controller now. */ mmio_write_32(SUNXI_CCU_BASE + 0x68, 0); break; case AXP803_RSB: /* (Re-)init RSB in case the rich OS has disabled it. */ sunxi_init_platform_r_twi(SUNXI_SOC_A64, true); rsb_init(); /* Set "power disable control" bit */ axp_setbits(0x32, BIT(7)); break; default: break; } }