axppmic.c revision 1.25.2.1
1 1.25.2.1 martin /* $NetBSD: axppmic.c,v 1.25.2.1 2019/10/03 17:23:11 martin Exp $ */ 2 1.1 jmcneill 3 1.1 jmcneill /*- 4 1.1 jmcneill * Copyright (c) 2014-2018 Jared McNeill <jmcneill (at) invisible.ca> 5 1.1 jmcneill * All rights reserved. 6 1.1 jmcneill * 7 1.1 jmcneill * Redistribution and use in source and binary forms, with or without 8 1.1 jmcneill * modification, are permitted provided that the following conditions 9 1.1 jmcneill * are met: 10 1.1 jmcneill * 1. Redistributions of source code must retain the above copyright 11 1.1 jmcneill * notice, this list of conditions and the following disclaimer. 12 1.1 jmcneill * 2. Redistributions in binary form must reproduce the above copyright 13 1.1 jmcneill * notice, this list of conditions and the following disclaimer in the 14 1.1 jmcneill * documentation and/or other materials provided with the distribution. 15 1.1 jmcneill * 16 1.1 jmcneill * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 17 1.1 jmcneill * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 18 1.1 jmcneill * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 19 1.1 jmcneill * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 20 1.1 jmcneill * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 21 1.1 jmcneill * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 22 1.1 jmcneill * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 23 1.1 jmcneill * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 24 1.1 jmcneill * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 25 1.1 jmcneill * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 26 1.1 jmcneill * POSSIBILITY OF SUCH DAMAGE. 27 1.1 jmcneill */ 28 1.1 jmcneill 29 1.1 jmcneill #include <sys/cdefs.h> 30 1.25.2.1 martin __KERNEL_RCSID(0, "$NetBSD: axppmic.c,v 1.25.2.1 2019/10/03 17:23:11 martin Exp $"); 31 1.1 jmcneill 32 1.1 jmcneill #include <sys/param.h> 33 1.1 jmcneill #include <sys/systm.h> 34 1.1 jmcneill #include <sys/kernel.h> 35 1.1 jmcneill #include <sys/device.h> 36 1.1 jmcneill #include <sys/conf.h> 37 1.1 jmcneill #include <sys/bus.h> 38 1.1 jmcneill #include <sys/kmem.h> 39 1.1 jmcneill 40 1.1 jmcneill #include <dev/i2c/i2cvar.h> 41 1.1 jmcneill 42 1.1 jmcneill #include <dev/sysmon/sysmonvar.h> 43 1.1 jmcneill #include <dev/sysmon/sysmon_taskq.h> 44 1.1 jmcneill 45 1.1 jmcneill #include <dev/fdt/fdtvar.h> 46 1.1 jmcneill 47 1.3 jmcneill #define AXP_POWER_SOURCE_REG 0x00 48 1.3 jmcneill #define AXP_POWER_SOURCE_ACIN_PRESENT __BIT(7) 49 1.3 jmcneill #define AXP_POWER_SOURCE_VBUS_PRESENT __BIT(5) 50 1.10 jmcneill #define AXP_POWER_SOURCE_CHARGE_DIRECTION __BIT(2) 51 1.3 jmcneill 52 1.2 jmcneill #define AXP_POWER_MODE_REG 0x01 53 1.2 jmcneill #define AXP_POWER_MODE_BATT_VALID __BIT(4) 54 1.2 jmcneill #define AXP_POWER_MODE_BATT_PRESENT __BIT(5) 55 1.2 jmcneill #define AXP_POWER_MODE_BATT_CHARGING __BIT(6) 56 1.2 jmcneill 57 1.19 jmcneill #define AXP_CHIP_ID_REG 0x03 58 1.19 jmcneill 59 1.1 jmcneill #define AXP_POWER_DISABLE_REG 0x32 60 1.1 jmcneill #define AXP_POWER_DISABLE_CTRL __BIT(7) 61 1.1 jmcneill 62 1.1 jmcneill #define AXP_IRQ_ENABLE_REG(n) (0x40 + (n) - 1) 63 1.5 jmcneill #define AXP_IRQ1_ACIN_RAISE __BIT(6) 64 1.5 jmcneill #define AXP_IRQ1_ACIN_LOWER __BIT(5) 65 1.5 jmcneill #define AXP_IRQ1_VBUS_RAISE __BIT(3) 66 1.5 jmcneill #define AXP_IRQ1_VBUS_LOWER __BIT(2) 67 1.1 jmcneill #define AXP_IRQ_STATUS_REG(n) (0x48 + (n) - 1) 68 1.1 jmcneill 69 1.10 jmcneill #define AXP_BATSENSE_HI_REG 0x78 70 1.10 jmcneill #define AXP_BATSENSE_LO_REG 0x79 71 1.10 jmcneill 72 1.10 jmcneill #define AXP_BATTCHG_HI_REG 0x7a 73 1.10 jmcneill #define AXP_BATTCHG_LO_REG 0x7b 74 1.10 jmcneill 75 1.10 jmcneill #define AXP_BATTDISCHG_HI_REG 0x7c 76 1.10 jmcneill #define AXP_BATTDISCHG_LO_REG 0x7d 77 1.10 jmcneill 78 1.10 jmcneill #define AXP_ADC_RAW(_hi, _lo) \ 79 1.15 jakllsch (((u_int)(_hi) << 4) | ((_lo) & 0xf)) 80 1.10 jmcneill 81 1.2 jmcneill #define AXP_FUEL_GAUGE_CTRL_REG 0xb8 82 1.2 jmcneill #define AXP_FUEL_GAUGE_CTRL_EN __BIT(7) 83 1.10 jmcneill 84 1.2 jmcneill #define AXP_BATT_CAP_REG 0xb9 85 1.2 jmcneill #define AXP_BATT_CAP_VALID __BIT(7) 86 1.2 jmcneill #define AXP_BATT_CAP_PERCENT __BITS(6,0) 87 1.2 jmcneill 88 1.16 jakllsch #define AXP_BATT_MAX_CAP_HI_REG 0xe0 89 1.16 jakllsch #define AXP_BATT_MAX_CAP_VALID __BIT(7) 90 1.16 jakllsch #define AXP_BATT_MAX_CAP_LO_REG 0xe1 91 1.16 jakllsch 92 1.16 jakllsch #define AXP_BATT_COULOMB_HI_REG 0xe2 93 1.16 jakllsch #define AXP_BATT_COULOMB_VALID __BIT(7) 94 1.16 jakllsch #define AXP_BATT_COULOMB_LO_REG 0xe3 95 1.16 jakllsch 96 1.16 jakllsch #define AXP_COULOMB_RAW(_hi, _lo) \ 97 1.16 jakllsch (((u_int)(_hi & ~__BIT(7)) << 8) | (_lo)) 98 1.16 jakllsch 99 1.2 jmcneill #define AXP_BATT_CAP_WARN_REG 0xe6 100 1.2 jmcneill #define AXP_BATT_CAP_WARN_LV1 __BITS(7,4) 101 1.2 jmcneill #define AXP_BATT_CAP_WARN_LV2 __BITS(3,0) 102 1.2 jmcneill 103 1.19 jmcneill #define AXP_ADDR_EXT_REG 0xff /* AXP806 */ 104 1.19 jmcneill #define AXP_ADDR_EXT_MASTER 0 105 1.19 jmcneill #define AXP_ADDR_EXT_SLAVE __BIT(4) 106 1.19 jmcneill 107 1.1 jmcneill struct axppmic_ctrl { 108 1.1 jmcneill device_t c_dev; 109 1.1 jmcneill 110 1.1 jmcneill const char * c_name; 111 1.1 jmcneill u_int c_min; 112 1.1 jmcneill u_int c_max; 113 1.1 jmcneill u_int c_step1; 114 1.1 jmcneill u_int c_step1cnt; 115 1.1 jmcneill u_int c_step2; 116 1.1 jmcneill u_int c_step2cnt; 117 1.24 jmcneill u_int c_step2start; 118 1.1 jmcneill 119 1.1 jmcneill uint8_t c_enable_reg; 120 1.1 jmcneill uint8_t c_enable_mask; 121 1.23 jmcneill uint8_t c_enable_val; 122 1.23 jmcneill uint8_t c_disable_val; 123 1.1 jmcneill 124 1.1 jmcneill uint8_t c_voltage_reg; 125 1.1 jmcneill uint8_t c_voltage_mask; 126 1.1 jmcneill }; 127 1.1 jmcneill 128 1.1 jmcneill #define AXP_CTRL(name, min, max, step, ereg, emask, vreg, vmask) \ 129 1.1 jmcneill { .c_name = (name), .c_min = (min), .c_max = (max), \ 130 1.1 jmcneill .c_step1 = (step), .c_step1cnt = (((max) - (min)) / (step)) + 1, \ 131 1.1 jmcneill .c_step2 = 0, .c_step2cnt = 0, \ 132 1.1 jmcneill .c_enable_reg = (ereg), .c_enable_mask = (emask), \ 133 1.23 jmcneill .c_enable_val = (emask), .c_disable_val = 0, \ 134 1.1 jmcneill .c_voltage_reg = (vreg), .c_voltage_mask = (vmask) } 135 1.1 jmcneill 136 1.1 jmcneill #define AXP_CTRL2(name, min, max, step1, step1cnt, step2, step2cnt, ereg, emask, vreg, vmask) \ 137 1.1 jmcneill { .c_name = (name), .c_min = (min), .c_max = (max), \ 138 1.1 jmcneill .c_step1 = (step1), .c_step1cnt = (step1cnt), \ 139 1.1 jmcneill .c_step2 = (step2), .c_step2cnt = (step2cnt), \ 140 1.1 jmcneill .c_enable_reg = (ereg), .c_enable_mask = (emask), \ 141 1.23 jmcneill .c_enable_val = (emask), .c_disable_val = 0, \ 142 1.1 jmcneill .c_voltage_reg = (vreg), .c_voltage_mask = (vmask) } 143 1.1 jmcneill 144 1.24 jmcneill #define AXP_CTRL2_RANGE(name, min, max, step1, step1cnt, step2start, step2, step2cnt, ereg, emask, vreg, vmask) \ 145 1.24 jmcneill { .c_name = (name), .c_min = (min), .c_max = (max), \ 146 1.24 jmcneill .c_step1 = (step1), .c_step1cnt = (step1cnt), \ 147 1.24 jmcneill .c_step2start = (step2start), \ 148 1.24 jmcneill .c_step2 = (step2), .c_step2cnt = (step2cnt), \ 149 1.24 jmcneill .c_enable_reg = (ereg), .c_enable_mask = (emask), \ 150 1.24 jmcneill .c_enable_val = (emask), .c_disable_val = 0, \ 151 1.24 jmcneill .c_voltage_reg = (vreg), .c_voltage_mask = (vmask) } 152 1.24 jmcneill 153 1.23 jmcneill #define AXP_CTRL_IO(name, min, max, step, ereg, emask, eval, dval, vreg, vmask) \ 154 1.23 jmcneill { .c_name = (name), .c_min = (min), .c_max = (max), \ 155 1.23 jmcneill .c_step1 = (step), .c_step1cnt = (((max) - (min)) / (step)) + 1, \ 156 1.23 jmcneill .c_step2 = 0, .c_step2cnt = 0, \ 157 1.23 jmcneill .c_enable_reg = (ereg), .c_enable_mask = (emask), \ 158 1.23 jmcneill .c_enable_val = (eval), .c_disable_val = (dval), \ 159 1.23 jmcneill .c_voltage_reg = (vreg), .c_voltage_mask = (vmask) } 160 1.23 jmcneill 161 1.24 jmcneill #define AXP_CTRL_SW(name, ereg, emask) \ 162 1.24 jmcneill { .c_name = (name), \ 163 1.24 jmcneill .c_enable_reg = (ereg), .c_enable_mask = (emask), \ 164 1.24 jmcneill .c_enable_val = (emask), .c_disable_val = 0 } 165 1.23 jmcneill 166 1.1 jmcneill static const struct axppmic_ctrl axp803_ctrls[] = { 167 1.1 jmcneill AXP_CTRL("dldo1", 700, 3300, 100, 168 1.1 jmcneill 0x12, __BIT(3), 0x15, __BITS(4,0)), 169 1.1 jmcneill AXP_CTRL2("dldo2", 700, 4200, 100, 28, 200, 4, 170 1.1 jmcneill 0x12, __BIT(4), 0x16, __BITS(4,0)), 171 1.1 jmcneill AXP_CTRL("dldo3", 700, 3300, 100, 172 1.1 jmcneill 0x12, __BIT(5), 0x17, __BITS(4,0)), 173 1.1 jmcneill AXP_CTRL("dldo4", 700, 3300, 100, 174 1.1 jmcneill 0x12, __BIT(6), 0x18, __BITS(4,0)), 175 1.1 jmcneill AXP_CTRL("eldo1", 700, 1900, 50, 176 1.1 jmcneill 0x12, __BIT(0), 0x19, __BITS(4,0)), 177 1.1 jmcneill AXP_CTRL("eldo2", 700, 1900, 50, 178 1.1 jmcneill 0x12, __BIT(1), 0x1a, __BITS(4,0)), 179 1.1 jmcneill AXP_CTRL("eldo3", 700, 1900, 50, 180 1.1 jmcneill 0x12, __BIT(2), 0x1b, __BITS(4,0)), 181 1.1 jmcneill AXP_CTRL("fldo1", 700, 1450, 50, 182 1.1 jmcneill 0x13, __BIT(2), 0x1c, __BITS(3,0)), 183 1.1 jmcneill AXP_CTRL("fldo2", 700, 1450, 50, 184 1.1 jmcneill 0x13, __BIT(3), 0x1d, __BITS(3,0)), 185 1.1 jmcneill AXP_CTRL("dcdc1", 1600, 3400, 100, 186 1.1 jmcneill 0x10, __BIT(0), 0x20, __BITS(4,0)), 187 1.6 jmcneill AXP_CTRL2("dcdc2", 500, 1300, 10, 70, 20, 5, 188 1.1 jmcneill 0x10, __BIT(1), 0x21, __BITS(6,0)), 189 1.6 jmcneill AXP_CTRL2("dcdc3", 500, 1300, 10, 70, 20, 5, 190 1.1 jmcneill 0x10, __BIT(2), 0x22, __BITS(6,0)), 191 1.6 jmcneill AXP_CTRL2("dcdc4", 500, 1300, 10, 70, 20, 5, 192 1.1 jmcneill 0x10, __BIT(3), 0x23, __BITS(6,0)), 193 1.1 jmcneill AXP_CTRL2("dcdc5", 800, 1840, 10, 33, 20, 36, 194 1.1 jmcneill 0x10, __BIT(4), 0x24, __BITS(6,0)), 195 1.1 jmcneill AXP_CTRL2("dcdc6", 600, 1520, 10, 51, 20, 21, 196 1.1 jmcneill 0x10, __BIT(5), 0x25, __BITS(6,0)), 197 1.1 jmcneill AXP_CTRL("aldo1", 700, 3300, 100, 198 1.1 jmcneill 0x13, __BIT(5), 0x28, __BITS(4,0)), 199 1.1 jmcneill AXP_CTRL("aldo2", 700, 3300, 100, 200 1.1 jmcneill 0x13, __BIT(6), 0x29, __BITS(4,0)), 201 1.1 jmcneill AXP_CTRL("aldo3", 700, 3300, 100, 202 1.1 jmcneill 0x13, __BIT(7), 0x2a, __BITS(4,0)), 203 1.1 jmcneill }; 204 1.1 jmcneill 205 1.1 jmcneill static const struct axppmic_ctrl axp805_ctrls[] = { 206 1.1 jmcneill AXP_CTRL2("dcdca", 600, 1520, 10, 51, 20, 21, 207 1.1 jmcneill 0x10, __BIT(0), 0x12, __BITS(6,0)), 208 1.1 jmcneill AXP_CTRL("dcdcb", 1000, 2550, 50, 209 1.1 jmcneill 0x10, __BIT(1), 0x13, __BITS(4,0)), 210 1.1 jmcneill AXP_CTRL2("dcdcc", 600, 1520, 10, 51, 20, 21, 211 1.1 jmcneill 0x10, __BIT(2), 0x14, __BITS(6,0)), 212 1.1 jmcneill AXP_CTRL2("dcdcd", 600, 3300, 20, 46, 100, 18, 213 1.1 jmcneill 0x10, __BIT(3), 0x15, __BITS(5,0)), 214 1.1 jmcneill AXP_CTRL("dcdce", 1100, 3400, 100, 215 1.1 jmcneill 0x10, __BIT(4), 0x16, __BITS(4,0)), 216 1.1 jmcneill AXP_CTRL("aldo1", 700, 3300, 100, 217 1.1 jmcneill 0x10, __BIT(5), 0x17, __BITS(4,0)), 218 1.1 jmcneill AXP_CTRL("aldo2", 700, 3400, 100, 219 1.1 jmcneill 0x10, __BIT(6), 0x18, __BITS(4,0)), 220 1.1 jmcneill AXP_CTRL("aldo3", 700, 3300, 100, 221 1.1 jmcneill 0x10, __BIT(7), 0x19, __BITS(4,0)), 222 1.1 jmcneill AXP_CTRL("bldo1", 700, 1900, 100, 223 1.1 jmcneill 0x11, __BIT(0), 0x20, __BITS(3,0)), 224 1.1 jmcneill AXP_CTRL("bldo2", 700, 1900, 100, 225 1.1 jmcneill 0x11, __BIT(1), 0x21, __BITS(3,0)), 226 1.1 jmcneill AXP_CTRL("bldo3", 700, 1900, 100, 227 1.1 jmcneill 0x11, __BIT(2), 0x22, __BITS(3,0)), 228 1.1 jmcneill AXP_CTRL("bldo4", 700, 1900, 100, 229 1.1 jmcneill 0x11, __BIT(3), 0x23, __BITS(3,0)), 230 1.1 jmcneill AXP_CTRL("cldo1", 700, 3300, 100, 231 1.1 jmcneill 0x11, __BIT(4), 0x24, __BITS(4,0)), 232 1.1 jmcneill AXP_CTRL2("cldo2", 700, 4200, 100, 28, 200, 4, 233 1.1 jmcneill 0x11, __BIT(5), 0x25, __BITS(4,0)), 234 1.1 jmcneill AXP_CTRL("cldo3", 700, 3300, 100, 235 1.1 jmcneill 0x11, __BIT(6), 0x26, __BITS(4,0)), 236 1.1 jmcneill }; 237 1.1 jmcneill 238 1.21 jmcneill static const struct axppmic_ctrl axp809_ctrls[] = { 239 1.24 jmcneill AXP_CTRL("dc5ldo", 700, 1400, 100, 240 1.24 jmcneill 0x10, __BIT(0), 0x1c, __BITS(2,0)), 241 1.24 jmcneill AXP_CTRL("dcdc1", 1600, 3400, 100, 242 1.24 jmcneill 0x10, __BIT(1), 0x21, __BITS(4,0)), 243 1.24 jmcneill AXP_CTRL("dcdc2", 600, 1540, 20, 244 1.24 jmcneill 0x10, __BIT(2), 0x22, __BITS(5,0)), 245 1.24 jmcneill AXP_CTRL("dcdc3", 600, 1860, 20, 246 1.24 jmcneill 0x10, __BIT(3), 0x23, __BITS(5,0)), 247 1.24 jmcneill AXP_CTRL2_RANGE("dcdc4", 600, 2600, 20, 47, 1800, 100, 9, 248 1.24 jmcneill 0x10, __BIT(4), 0x24, __BITS(5,0)), 249 1.24 jmcneill AXP_CTRL("dcdc5", 1000, 2550, 50, 250 1.24 jmcneill 0x10, __BIT(5), 0x25, __BITS(4,0)), 251 1.24 jmcneill AXP_CTRL("aldo1", 700, 3300, 100, 252 1.24 jmcneill 0x10, __BIT(6), 0x28, __BITS(4,0)), 253 1.24 jmcneill AXP_CTRL("aldo2", 700, 3300, 100, 254 1.24 jmcneill 0x10, __BIT(7), 0x29, __BITS(4,0)), 255 1.24 jmcneill AXP_CTRL("eldo1", 700, 3300, 100, 256 1.24 jmcneill 0x12, __BIT(0), 0x19, __BITS(4,0)), 257 1.24 jmcneill AXP_CTRL("eldo2", 700, 3300, 100, 258 1.24 jmcneill 0x12, __BIT(1), 0x1a, __BITS(4,0)), 259 1.24 jmcneill AXP_CTRL("eldo3", 700, 3300, 100, 260 1.24 jmcneill 0x12, __BIT(2), 0x1b, __BITS(4,0)), 261 1.24 jmcneill AXP_CTRL2_RANGE("dldo1", 700, 4000, 100, 26, 3400, 200, 4, 262 1.24 jmcneill 0x12, __BIT(3), 0x15, __BITS(4,0)), 263 1.24 jmcneill AXP_CTRL("dldo2", 700, 3300, 100, 264 1.24 jmcneill 0x12, __BIT(4), 0x16, __BITS(4,0)), 265 1.24 jmcneill AXP_CTRL("aldo3", 700, 3300, 100, 266 1.24 jmcneill 0x12, __BIT(5), 0x2a, __BITS(4,0)), 267 1.24 jmcneill AXP_CTRL_SW("sw", 268 1.24 jmcneill 0x12, __BIT(6)), 269 1.24 jmcneill /* dc1sw is another switch for dcdc1 */ 270 1.24 jmcneill AXP_CTRL("dc1sw", 1600, 3400, 100, 271 1.24 jmcneill 0x12, __BIT(7), 0x21, __BITS(4,0)), 272 1.23 jmcneill AXP_CTRL_IO("ldo_io0", 700, 3300, 100, 273 1.23 jmcneill 0x90, __BITS(3,0), 0x3, 0x7, 0x91, __BITS(4,0)), 274 1.23 jmcneill AXP_CTRL_IO("ldo_io1", 700, 3300, 100, 275 1.23 jmcneill 0x92, __BITS(3,0), 0x3, 0x7, 0x93, __BITS(4,0)), 276 1.21 jmcneill }; 277 1.21 jmcneill 278 1.17 jmcneill static const struct axppmic_ctrl axp813_ctrls[] = { 279 1.17 jmcneill AXP_CTRL("dldo1", 700, 3300, 100, 280 1.17 jmcneill 0x12, __BIT(3), 0x15, __BITS(4,0)), 281 1.17 jmcneill AXP_CTRL2("dldo2", 700, 4200, 100, 28, 200, 4, 282 1.17 jmcneill 0x12, __BIT(4), 0x16, __BITS(4,0)), 283 1.17 jmcneill AXP_CTRL("dldo3", 700, 3300, 100, 284 1.17 jmcneill 0x12, __BIT(5), 0x17, __BITS(4,0)), 285 1.17 jmcneill AXP_CTRL("dldo4", 700, 3300, 100, 286 1.17 jmcneill 0x12, __BIT(6), 0x18, __BITS(4,0)), 287 1.17 jmcneill AXP_CTRL("eldo1", 700, 1900, 50, 288 1.17 jmcneill 0x12, __BIT(0), 0x19, __BITS(4,0)), 289 1.17 jmcneill AXP_CTRL("eldo2", 700, 1900, 50, 290 1.17 jmcneill 0x12, __BIT(1), 0x1a, __BITS(4,0)), 291 1.17 jmcneill AXP_CTRL("eldo3", 700, 1900, 50, 292 1.17 jmcneill 0x12, __BIT(2), 0x1b, __BITS(4,0)), 293 1.17 jmcneill AXP_CTRL("fldo1", 700, 1450, 50, 294 1.17 jmcneill 0x13, __BIT(2), 0x1c, __BITS(3,0)), 295 1.17 jmcneill AXP_CTRL("fldo2", 700, 1450, 50, 296 1.17 jmcneill 0x13, __BIT(3), 0x1d, __BITS(3,0)), 297 1.17 jmcneill AXP_CTRL("dcdc1", 1600, 3400, 100, 298 1.17 jmcneill 0x10, __BIT(0), 0x20, __BITS(4,0)), 299 1.17 jmcneill AXP_CTRL2("dcdc2", 500, 1300, 10, 70, 20, 5, 300 1.17 jmcneill 0x10, __BIT(1), 0x21, __BITS(6,0)), 301 1.17 jmcneill AXP_CTRL2("dcdc3", 500, 1300, 10, 70, 20, 5, 302 1.17 jmcneill 0x10, __BIT(2), 0x22, __BITS(6,0)), 303 1.17 jmcneill AXP_CTRL2("dcdc4", 500, 1300, 10, 70, 20, 5, 304 1.17 jmcneill 0x10, __BIT(3), 0x23, __BITS(6,0)), 305 1.17 jmcneill AXP_CTRL2("dcdc5", 800, 1840, 10, 33, 20, 36, 306 1.17 jmcneill 0x10, __BIT(4), 0x24, __BITS(6,0)), 307 1.17 jmcneill AXP_CTRL2("dcdc6", 600, 1520, 10, 51, 20, 21, 308 1.17 jmcneill 0x10, __BIT(5), 0x25, __BITS(6,0)), 309 1.17 jmcneill AXP_CTRL2("dcdc7", 600, 1520, 10, 51, 20, 21, 310 1.17 jmcneill 0x10, __BIT(6), 0x26, __BITS(6,0)), 311 1.17 jmcneill AXP_CTRL("aldo1", 700, 3300, 100, 312 1.17 jmcneill 0x13, __BIT(5), 0x28, __BITS(4,0)), 313 1.17 jmcneill AXP_CTRL("aldo2", 700, 3300, 100, 314 1.17 jmcneill 0x13, __BIT(6), 0x29, __BITS(4,0)), 315 1.17 jmcneill AXP_CTRL("aldo3", 700, 3300, 100, 316 1.17 jmcneill 0x13, __BIT(7), 0x2a, __BITS(4,0)), 317 1.17 jmcneill }; 318 1.17 jmcneill 319 1.8 jmcneill struct axppmic_irq { 320 1.8 jmcneill u_int reg; 321 1.8 jmcneill uint8_t mask; 322 1.8 jmcneill }; 323 1.8 jmcneill 324 1.8 jmcneill #define AXPPMIC_IRQ(_reg, _mask) \ 325 1.8 jmcneill { .reg = (_reg), .mask = (_mask) } 326 1.8 jmcneill 327 1.1 jmcneill struct axppmic_config { 328 1.1 jmcneill const char *name; 329 1.1 jmcneill const struct axppmic_ctrl *controls; 330 1.1 jmcneill u_int ncontrols; 331 1.1 jmcneill u_int irq_regs; 332 1.2 jmcneill bool has_battery; 333 1.2 jmcneill bool has_fuel_gauge; 334 1.19 jmcneill bool has_mode_set; 335 1.8 jmcneill struct axppmic_irq poklirq; 336 1.8 jmcneill struct axppmic_irq acinirq; 337 1.8 jmcneill struct axppmic_irq vbusirq; 338 1.8 jmcneill struct axppmic_irq battirq; 339 1.8 jmcneill struct axppmic_irq chargeirq; 340 1.8 jmcneill struct axppmic_irq chargestirq; 341 1.10 jmcneill u_int batsense_step; /* uV */ 342 1.10 jmcneill u_int charge_step; /* uA */ 343 1.10 jmcneill u_int discharge_step; /* uA */ 344 1.10 jmcneill u_int maxcap_step; /* uAh */ 345 1.10 jmcneill u_int coulomb_step; /* uAh */ 346 1.2 jmcneill }; 347 1.2 jmcneill 348 1.2 jmcneill enum axppmic_sensor { 349 1.3 jmcneill AXP_SENSOR_ACIN_PRESENT, 350 1.3 jmcneill AXP_SENSOR_VBUS_PRESENT, 351 1.2 jmcneill AXP_SENSOR_BATT_PRESENT, 352 1.2 jmcneill AXP_SENSOR_BATT_CHARGING, 353 1.2 jmcneill AXP_SENSOR_BATT_CHARGE_STATE, 354 1.10 jmcneill AXP_SENSOR_BATT_VOLTAGE, 355 1.10 jmcneill AXP_SENSOR_BATT_CHARGE_CURRENT, 356 1.10 jmcneill AXP_SENSOR_BATT_DISCHARGE_CURRENT, 357 1.10 jmcneill AXP_SENSOR_BATT_CAPACITY_PERCENT, 358 1.16 jakllsch AXP_SENSOR_BATT_MAXIMUM_CAPACITY, 359 1.16 jakllsch AXP_SENSOR_BATT_CURRENT_CAPACITY, 360 1.2 jmcneill AXP_NSENSORS 361 1.1 jmcneill }; 362 1.1 jmcneill 363 1.1 jmcneill struct axppmic_softc { 364 1.1 jmcneill device_t sc_dev; 365 1.1 jmcneill i2c_tag_t sc_i2c; 366 1.1 jmcneill i2c_addr_t sc_addr; 367 1.1 jmcneill int sc_phandle; 368 1.1 jmcneill 369 1.8 jmcneill const struct axppmic_config *sc_conf; 370 1.2 jmcneill 371 1.1 jmcneill struct sysmon_pswitch sc_smpsw; 372 1.1 jmcneill 373 1.2 jmcneill struct sysmon_envsys *sc_sme; 374 1.3 jmcneill 375 1.2 jmcneill envsys_data_t sc_sensor[AXP_NSENSORS]; 376 1.4 jmcneill 377 1.4 jmcneill u_int sc_warn_thres; 378 1.4 jmcneill u_int sc_shut_thres; 379 1.1 jmcneill }; 380 1.1 jmcneill 381 1.1 jmcneill struct axpreg_softc { 382 1.1 jmcneill device_t sc_dev; 383 1.1 jmcneill i2c_tag_t sc_i2c; 384 1.1 jmcneill i2c_addr_t sc_addr; 385 1.1 jmcneill const struct axppmic_ctrl *sc_ctrl; 386 1.1 jmcneill }; 387 1.1 jmcneill 388 1.1 jmcneill struct axpreg_attach_args { 389 1.1 jmcneill const struct axppmic_ctrl *reg_ctrl; 390 1.1 jmcneill int reg_phandle; 391 1.1 jmcneill i2c_tag_t reg_i2c; 392 1.1 jmcneill i2c_addr_t reg_addr; 393 1.1 jmcneill }; 394 1.1 jmcneill 395 1.1 jmcneill static const struct axppmic_config axp803_config = { 396 1.1 jmcneill .name = "AXP803", 397 1.1 jmcneill .controls = axp803_ctrls, 398 1.1 jmcneill .ncontrols = __arraycount(axp803_ctrls), 399 1.1 jmcneill .irq_regs = 6, 400 1.2 jmcneill .has_battery = true, 401 1.2 jmcneill .has_fuel_gauge = true, 402 1.10 jmcneill .batsense_step = 1100, 403 1.10 jmcneill .charge_step = 1000, 404 1.10 jmcneill .discharge_step = 1000, 405 1.16 jakllsch .maxcap_step = 1456, 406 1.16 jakllsch .coulomb_step = 1456, 407 1.8 jmcneill .poklirq = AXPPMIC_IRQ(5, __BIT(3)), 408 1.8 jmcneill .acinirq = AXPPMIC_IRQ(1, __BITS(6,5)), 409 1.8 jmcneill .vbusirq = AXPPMIC_IRQ(1, __BITS(3,2)), 410 1.8 jmcneill .battirq = AXPPMIC_IRQ(2, __BITS(7,6)), 411 1.8 jmcneill .chargeirq = AXPPMIC_IRQ(2, __BITS(3,2)), 412 1.8 jmcneill .chargestirq = AXPPMIC_IRQ(4, __BITS(1,0)), 413 1.1 jmcneill }; 414 1.1 jmcneill 415 1.1 jmcneill static const struct axppmic_config axp805_config = { 416 1.19 jmcneill .name = "AXP805", 417 1.19 jmcneill .controls = axp805_ctrls, 418 1.19 jmcneill .ncontrols = __arraycount(axp805_ctrls), 419 1.19 jmcneill .irq_regs = 2, 420 1.19 jmcneill .poklirq = AXPPMIC_IRQ(2, __BIT(0)), 421 1.19 jmcneill }; 422 1.19 jmcneill 423 1.19 jmcneill static const struct axppmic_config axp806_config = { 424 1.19 jmcneill .name = "AXP806", 425 1.1 jmcneill .controls = axp805_ctrls, 426 1.1 jmcneill .ncontrols = __arraycount(axp805_ctrls), 427 1.19 jmcneill #if notyet 428 1.1 jmcneill .irq_regs = 2, 429 1.8 jmcneill .poklirq = AXPPMIC_IRQ(2, __BIT(0)), 430 1.19 jmcneill #endif 431 1.19 jmcneill .has_mode_set = true, 432 1.1 jmcneill }; 433 1.1 jmcneill 434 1.21 jmcneill static const struct axppmic_config axp809_config = { 435 1.21 jmcneill .name = "AXP809", 436 1.21 jmcneill .controls = axp809_ctrls, 437 1.21 jmcneill .ncontrols = __arraycount(axp809_ctrls), 438 1.21 jmcneill }; 439 1.21 jmcneill 440 1.17 jmcneill static const struct axppmic_config axp813_config = { 441 1.17 jmcneill .name = "AXP813", 442 1.17 jmcneill .controls = axp813_ctrls, 443 1.17 jmcneill .ncontrols = __arraycount(axp813_ctrls), 444 1.17 jmcneill .irq_regs = 6, 445 1.17 jmcneill .has_battery = true, 446 1.17 jmcneill .has_fuel_gauge = true, 447 1.17 jmcneill .batsense_step = 1100, 448 1.17 jmcneill .charge_step = 1000, 449 1.17 jmcneill .discharge_step = 1000, 450 1.17 jmcneill .maxcap_step = 1456, 451 1.17 jmcneill .coulomb_step = 1456, 452 1.17 jmcneill .poklirq = AXPPMIC_IRQ(5, __BIT(3)), 453 1.17 jmcneill .acinirq = AXPPMIC_IRQ(1, __BITS(6,5)), 454 1.17 jmcneill .vbusirq = AXPPMIC_IRQ(1, __BITS(3,2)), 455 1.17 jmcneill .battirq = AXPPMIC_IRQ(2, __BITS(7,6)), 456 1.17 jmcneill .chargeirq = AXPPMIC_IRQ(2, __BITS(3,2)), 457 1.17 jmcneill .chargestirq = AXPPMIC_IRQ(4, __BITS(1,0)), 458 1.17 jmcneill }; 459 1.17 jmcneill 460 1.14 thorpej static const struct device_compatible_entry compat_data[] = { 461 1.14 thorpej { "x-powers,axp803", (uintptr_t)&axp803_config }, 462 1.14 thorpej { "x-powers,axp805", (uintptr_t)&axp805_config }, 463 1.19 jmcneill { "x-powers,axp806", (uintptr_t)&axp806_config }, 464 1.21 jmcneill { "x-powers,axp809", (uintptr_t)&axp809_config }, 465 1.17 jmcneill { "x-powers,axp813", (uintptr_t)&axp813_config }, 466 1.14 thorpej { NULL, 0 } 467 1.1 jmcneill }; 468 1.1 jmcneill 469 1.1 jmcneill static int 470 1.1 jmcneill axppmic_read(i2c_tag_t tag, i2c_addr_t addr, uint8_t reg, uint8_t *val, int flags) 471 1.1 jmcneill { 472 1.1 jmcneill return iic_smbus_read_byte(tag, addr, reg, val, flags); 473 1.1 jmcneill } 474 1.1 jmcneill 475 1.1 jmcneill static int 476 1.1 jmcneill axppmic_write(i2c_tag_t tag, i2c_addr_t addr, uint8_t reg, uint8_t val, int flags) 477 1.1 jmcneill { 478 1.1 jmcneill return iic_smbus_write_byte(tag, addr, reg, val, flags); 479 1.1 jmcneill } 480 1.1 jmcneill 481 1.1 jmcneill static int 482 1.1 jmcneill axppmic_set_voltage(i2c_tag_t tag, i2c_addr_t addr, const struct axppmic_ctrl *c, u_int min, u_int max) 483 1.1 jmcneill { 484 1.25 thorpej const int flags = 0; 485 1.1 jmcneill u_int vol, reg_val; 486 1.1 jmcneill int nstep, error; 487 1.1 jmcneill uint8_t val; 488 1.1 jmcneill 489 1.1 jmcneill if (!c->c_voltage_mask) 490 1.1 jmcneill return EINVAL; 491 1.1 jmcneill 492 1.1 jmcneill if (min < c->c_min || min > c->c_max) 493 1.1 jmcneill return EINVAL; 494 1.1 jmcneill 495 1.1 jmcneill reg_val = 0; 496 1.1 jmcneill nstep = 1; 497 1.1 jmcneill vol = c->c_min; 498 1.1 jmcneill 499 1.1 jmcneill for (nstep = 0; nstep < c->c_step1cnt && vol < min; nstep++) { 500 1.1 jmcneill ++reg_val; 501 1.1 jmcneill vol += c->c_step1; 502 1.1 jmcneill } 503 1.24 jmcneill 504 1.24 jmcneill if (c->c_step2start) 505 1.24 jmcneill vol = c->c_step2start; 506 1.24 jmcneill 507 1.1 jmcneill for (nstep = 0; nstep < c->c_step2cnt && vol < min; nstep++) { 508 1.1 jmcneill ++reg_val; 509 1.1 jmcneill vol += c->c_step2; 510 1.1 jmcneill } 511 1.1 jmcneill 512 1.1 jmcneill if (vol > max) 513 1.1 jmcneill return EINVAL; 514 1.1 jmcneill 515 1.1 jmcneill iic_acquire_bus(tag, flags); 516 1.1 jmcneill if ((error = axppmic_read(tag, addr, c->c_voltage_reg, &val, flags)) == 0) { 517 1.1 jmcneill val &= ~c->c_voltage_mask; 518 1.1 jmcneill val |= __SHIFTIN(reg_val, c->c_voltage_mask); 519 1.1 jmcneill error = axppmic_write(tag, addr, c->c_voltage_reg, val, flags); 520 1.1 jmcneill } 521 1.1 jmcneill iic_release_bus(tag, flags); 522 1.1 jmcneill 523 1.1 jmcneill return error; 524 1.1 jmcneill } 525 1.1 jmcneill 526 1.1 jmcneill static int 527 1.1 jmcneill axppmic_get_voltage(i2c_tag_t tag, i2c_addr_t addr, const struct axppmic_ctrl *c, u_int *pvol) 528 1.1 jmcneill { 529 1.25 thorpej const int flags = 0; 530 1.1 jmcneill int reg_val, error; 531 1.1 jmcneill uint8_t val; 532 1.1 jmcneill 533 1.1 jmcneill if (!c->c_voltage_mask) 534 1.1 jmcneill return EINVAL; 535 1.1 jmcneill 536 1.1 jmcneill iic_acquire_bus(tag, flags); 537 1.1 jmcneill error = axppmic_read(tag, addr, c->c_voltage_reg, &val, flags); 538 1.1 jmcneill iic_release_bus(tag, flags); 539 1.1 jmcneill if (error) 540 1.1 jmcneill return error; 541 1.1 jmcneill 542 1.1 jmcneill reg_val = __SHIFTOUT(val, c->c_voltage_mask); 543 1.1 jmcneill if (reg_val < c->c_step1cnt) { 544 1.1 jmcneill *pvol = c->c_min + reg_val * c->c_step1; 545 1.24 jmcneill } else if (c->c_step2start) { 546 1.24 jmcneill *pvol = c->c_step2start + 547 1.24 jmcneill ((reg_val - c->c_step1cnt) * c->c_step2); 548 1.1 jmcneill } else { 549 1.1 jmcneill *pvol = c->c_min + (c->c_step1cnt * c->c_step1) + 550 1.1 jmcneill ((reg_val - c->c_step1cnt) * c->c_step2); 551 1.1 jmcneill } 552 1.1 jmcneill 553 1.1 jmcneill return 0; 554 1.1 jmcneill } 555 1.1 jmcneill 556 1.1 jmcneill static void 557 1.1 jmcneill axppmic_power_poweroff(device_t dev) 558 1.1 jmcneill { 559 1.1 jmcneill struct axppmic_softc *sc = device_private(dev); 560 1.1 jmcneill 561 1.1 jmcneill delay(1000000); 562 1.1 jmcneill 563 1.1 jmcneill iic_acquire_bus(sc->sc_i2c, I2C_F_POLL); 564 1.1 jmcneill axppmic_write(sc->sc_i2c, sc->sc_addr, AXP_POWER_DISABLE_REG, AXP_POWER_DISABLE_CTRL, I2C_F_POLL); 565 1.1 jmcneill iic_release_bus(sc->sc_i2c, I2C_F_POLL); 566 1.1 jmcneill } 567 1.1 jmcneill 568 1.1 jmcneill static struct fdtbus_power_controller_func axppmic_power_funcs = { 569 1.1 jmcneill .poweroff = axppmic_power_poweroff, 570 1.1 jmcneill }; 571 1.1 jmcneill 572 1.1 jmcneill static void 573 1.1 jmcneill axppmic_task_shut(void *priv) 574 1.1 jmcneill { 575 1.1 jmcneill struct axppmic_softc *sc = priv; 576 1.1 jmcneill 577 1.1 jmcneill sysmon_pswitch_event(&sc->sc_smpsw, PSWITCH_EVENT_PRESSED); 578 1.1 jmcneill } 579 1.1 jmcneill 580 1.2 jmcneill static void 581 1.8 jmcneill axppmic_sensor_update(struct sysmon_envsys *sme, envsys_data_t *e) 582 1.2 jmcneill { 583 1.2 jmcneill struct axppmic_softc *sc = sme->sme_cookie; 584 1.10 jmcneill const struct axppmic_config *c = sc->sc_conf; 585 1.2 jmcneill const int flags = I2C_F_POLL; 586 1.10 jmcneill uint8_t val, lo, hi; 587 1.2 jmcneill 588 1.2 jmcneill e->state = ENVSYS_SINVALID; 589 1.2 jmcneill 590 1.10 jmcneill const bool battery_present = 591 1.10 jmcneill sc->sc_sensor[AXP_SENSOR_BATT_PRESENT].state == ENVSYS_SVALID && 592 1.10 jmcneill sc->sc_sensor[AXP_SENSOR_BATT_PRESENT].value_cur == 1; 593 1.10 jmcneill 594 1.2 jmcneill switch (e->private) { 595 1.3 jmcneill case AXP_SENSOR_ACIN_PRESENT: 596 1.3 jmcneill if (axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_POWER_SOURCE_REG, &val, flags) == 0) { 597 1.3 jmcneill e->state = ENVSYS_SVALID; 598 1.3 jmcneill e->value_cur = !!(val & AXP_POWER_SOURCE_ACIN_PRESENT); 599 1.3 jmcneill } 600 1.3 jmcneill break; 601 1.3 jmcneill case AXP_SENSOR_VBUS_PRESENT: 602 1.3 jmcneill if (axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_POWER_SOURCE_REG, &val, flags) == 0) { 603 1.3 jmcneill e->state = ENVSYS_SVALID; 604 1.3 jmcneill e->value_cur = !!(val & AXP_POWER_SOURCE_VBUS_PRESENT); 605 1.3 jmcneill } 606 1.3 jmcneill break; 607 1.2 jmcneill case AXP_SENSOR_BATT_PRESENT: 608 1.2 jmcneill if (axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_POWER_MODE_REG, &val, flags) == 0) { 609 1.2 jmcneill if (val & AXP_POWER_MODE_BATT_VALID) { 610 1.2 jmcneill e->state = ENVSYS_SVALID; 611 1.2 jmcneill e->value_cur = !!(val & AXP_POWER_MODE_BATT_PRESENT); 612 1.2 jmcneill } 613 1.2 jmcneill } 614 1.2 jmcneill break; 615 1.2 jmcneill case AXP_SENSOR_BATT_CHARGING: 616 1.2 jmcneill if (axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_POWER_MODE_REG, &val, flags) == 0) { 617 1.2 jmcneill e->state = ENVSYS_SVALID; 618 1.2 jmcneill e->value_cur = !!(val & AXP_POWER_MODE_BATT_CHARGING); 619 1.2 jmcneill } 620 1.2 jmcneill break; 621 1.2 jmcneill case AXP_SENSOR_BATT_CHARGE_STATE: 622 1.10 jmcneill if (battery_present && 623 1.2 jmcneill axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_BATT_CAP_REG, &val, flags) == 0 && 624 1.4 jmcneill (val & AXP_BATT_CAP_VALID) != 0) { 625 1.2 jmcneill const u_int batt_val = __SHIFTOUT(val, AXP_BATT_CAP_PERCENT); 626 1.4 jmcneill if (batt_val <= sc->sc_shut_thres) { 627 1.2 jmcneill e->state = ENVSYS_SCRITICAL; 628 1.2 jmcneill e->value_cur = ENVSYS_BATTERY_CAPACITY_CRITICAL; 629 1.4 jmcneill } else if (batt_val <= sc->sc_warn_thres) { 630 1.2 jmcneill e->state = ENVSYS_SWARNUNDER; 631 1.2 jmcneill e->value_cur = ENVSYS_BATTERY_CAPACITY_WARNING; 632 1.2 jmcneill } else { 633 1.2 jmcneill e->state = ENVSYS_SVALID; 634 1.2 jmcneill e->value_cur = ENVSYS_BATTERY_CAPACITY_NORMAL; 635 1.2 jmcneill } 636 1.2 jmcneill } 637 1.2 jmcneill break; 638 1.10 jmcneill case AXP_SENSOR_BATT_CAPACITY_PERCENT: 639 1.10 jmcneill if (battery_present && 640 1.2 jmcneill axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_BATT_CAP_REG, &val, flags) == 0 && 641 1.2 jmcneill (val & AXP_BATT_CAP_VALID) != 0) { 642 1.2 jmcneill e->state = ENVSYS_SVALID; 643 1.2 jmcneill e->value_cur = __SHIFTOUT(val, AXP_BATT_CAP_PERCENT); 644 1.2 jmcneill } 645 1.2 jmcneill break; 646 1.10 jmcneill case AXP_SENSOR_BATT_VOLTAGE: 647 1.10 jmcneill if (battery_present && 648 1.10 jmcneill axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_BATSENSE_HI_REG, &hi, flags) == 0 && 649 1.10 jmcneill axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_BATSENSE_LO_REG, &lo, flags) == 0) { 650 1.10 jmcneill e->state = ENVSYS_SVALID; 651 1.10 jmcneill e->value_cur = AXP_ADC_RAW(hi, lo) * c->batsense_step; 652 1.10 jmcneill } 653 1.10 jmcneill break; 654 1.10 jmcneill case AXP_SENSOR_BATT_CHARGE_CURRENT: 655 1.10 jmcneill if (battery_present && 656 1.10 jmcneill axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_POWER_SOURCE_REG, &val, flags) == 0 && 657 1.10 jmcneill (val & AXP_POWER_SOURCE_CHARGE_DIRECTION) != 0 && 658 1.10 jmcneill axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_BATTCHG_HI_REG, &hi, flags) == 0 && 659 1.10 jmcneill axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_BATTCHG_LO_REG, &lo, flags) == 0) { 660 1.10 jmcneill e->state = ENVSYS_SVALID; 661 1.10 jmcneill e->value_cur = AXP_ADC_RAW(hi, lo) * c->charge_step; 662 1.10 jmcneill } 663 1.10 jmcneill break; 664 1.10 jmcneill case AXP_SENSOR_BATT_DISCHARGE_CURRENT: 665 1.10 jmcneill if (battery_present && 666 1.10 jmcneill axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_POWER_SOURCE_REG, &val, flags) == 0 && 667 1.10 jmcneill (val & AXP_POWER_SOURCE_CHARGE_DIRECTION) == 0 && 668 1.10 jmcneill axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_BATTDISCHG_HI_REG, &hi, flags) == 0 && 669 1.10 jmcneill axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_BATTDISCHG_LO_REG, &lo, flags) == 0) { 670 1.10 jmcneill e->state = ENVSYS_SVALID; 671 1.10 jmcneill e->value_cur = AXP_ADC_RAW(hi, lo) * c->discharge_step; 672 1.10 jmcneill } 673 1.10 jmcneill break; 674 1.16 jakllsch case AXP_SENSOR_BATT_MAXIMUM_CAPACITY: 675 1.16 jakllsch if (battery_present && 676 1.16 jakllsch axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_BATT_MAX_CAP_HI_REG, &hi, flags) == 0 && 677 1.16 jakllsch axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_BATT_MAX_CAP_LO_REG, &lo, flags) == 0) { 678 1.16 jakllsch e->state = (hi & AXP_BATT_MAX_CAP_VALID) ? ENVSYS_SVALID : ENVSYS_SINVALID; 679 1.16 jakllsch e->value_cur = AXP_COULOMB_RAW(hi, lo) * c->maxcap_step; 680 1.16 jakllsch } 681 1.16 jakllsch break; 682 1.16 jakllsch case AXP_SENSOR_BATT_CURRENT_CAPACITY: 683 1.16 jakllsch if (battery_present && 684 1.16 jakllsch axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_BATT_COULOMB_HI_REG, &hi, flags) == 0 && 685 1.16 jakllsch axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_BATT_COULOMB_LO_REG, &lo, flags) == 0) { 686 1.16 jakllsch e->state = (hi & AXP_BATT_COULOMB_VALID) ? ENVSYS_SVALID : ENVSYS_SINVALID; 687 1.16 jakllsch e->value_cur = AXP_COULOMB_RAW(hi, lo) * c->coulomb_step; 688 1.16 jakllsch } 689 1.16 jakllsch break; 690 1.2 jmcneill } 691 1.8 jmcneill } 692 1.8 jmcneill 693 1.8 jmcneill static void 694 1.8 jmcneill axppmic_sensor_refresh(struct sysmon_envsys *sme, envsys_data_t *e) 695 1.8 jmcneill { 696 1.8 jmcneill struct axppmic_softc *sc = sme->sme_cookie; 697 1.8 jmcneill const int flags = I2C_F_POLL; 698 1.8 jmcneill 699 1.8 jmcneill switch (e->private) { 700 1.10 jmcneill case AXP_SENSOR_BATT_CAPACITY_PERCENT: 701 1.10 jmcneill case AXP_SENSOR_BATT_VOLTAGE: 702 1.10 jmcneill case AXP_SENSOR_BATT_CHARGE_CURRENT: 703 1.10 jmcneill case AXP_SENSOR_BATT_DISCHARGE_CURRENT: 704 1.10 jmcneill /* Always update battery capacity and ADCs */ 705 1.8 jmcneill iic_acquire_bus(sc->sc_i2c, flags); 706 1.8 jmcneill axppmic_sensor_update(sme, e); 707 1.8 jmcneill iic_release_bus(sc->sc_i2c, flags); 708 1.8 jmcneill break; 709 1.8 jmcneill default: 710 1.8 jmcneill /* Refresh if the sensor is not in valid state */ 711 1.8 jmcneill if (e->state != ENVSYS_SVALID) { 712 1.8 jmcneill iic_acquire_bus(sc->sc_i2c, flags); 713 1.8 jmcneill axppmic_sensor_update(sme, e); 714 1.8 jmcneill iic_release_bus(sc->sc_i2c, flags); 715 1.8 jmcneill } 716 1.8 jmcneill break; 717 1.8 jmcneill } 718 1.8 jmcneill } 719 1.8 jmcneill 720 1.8 jmcneill static int 721 1.8 jmcneill axppmic_intr(void *priv) 722 1.8 jmcneill { 723 1.8 jmcneill struct axppmic_softc *sc = priv; 724 1.8 jmcneill const struct axppmic_config *c = sc->sc_conf; 725 1.8 jmcneill const int flags = I2C_F_POLL; 726 1.8 jmcneill uint8_t stat; 727 1.8 jmcneill u_int n; 728 1.8 jmcneill 729 1.8 jmcneill iic_acquire_bus(sc->sc_i2c, flags); 730 1.8 jmcneill for (n = 1; n <= c->irq_regs; n++) { 731 1.8 jmcneill if (axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_IRQ_STATUS_REG(n), &stat, flags) == 0) { 732 1.8 jmcneill if (n == c->poklirq.reg && (stat & c->poklirq.mask) != 0) 733 1.8 jmcneill sysmon_task_queue_sched(0, axppmic_task_shut, sc); 734 1.8 jmcneill if (n == c->acinirq.reg && (stat & c->acinirq.mask) != 0) 735 1.8 jmcneill axppmic_sensor_update(sc->sc_sme, &sc->sc_sensor[AXP_SENSOR_ACIN_PRESENT]); 736 1.8 jmcneill if (n == c->vbusirq.reg && (stat & c->vbusirq.mask) != 0) 737 1.8 jmcneill axppmic_sensor_update(sc->sc_sme, &sc->sc_sensor[AXP_SENSOR_VBUS_PRESENT]); 738 1.8 jmcneill if (n == c->battirq.reg && (stat & c->battirq.mask) != 0) 739 1.8 jmcneill axppmic_sensor_update(sc->sc_sme, &sc->sc_sensor[AXP_SENSOR_BATT_PRESENT]); 740 1.8 jmcneill if (n == c->chargeirq.reg && (stat & c->chargeirq.mask) != 0) 741 1.8 jmcneill axppmic_sensor_update(sc->sc_sme, &sc->sc_sensor[AXP_SENSOR_BATT_CHARGING]); 742 1.8 jmcneill if (n == c->chargestirq.reg && (stat & c->chargestirq.mask) != 0) 743 1.8 jmcneill axppmic_sensor_update(sc->sc_sme, &sc->sc_sensor[AXP_SENSOR_BATT_CHARGE_STATE]); 744 1.8 jmcneill 745 1.8 jmcneill if (stat != 0) 746 1.8 jmcneill axppmic_write(sc->sc_i2c, sc->sc_addr, 747 1.8 jmcneill AXP_IRQ_STATUS_REG(n), stat, flags); 748 1.8 jmcneill } 749 1.8 jmcneill } 750 1.2 jmcneill iic_release_bus(sc->sc_i2c, flags); 751 1.8 jmcneill 752 1.8 jmcneill return 1; 753 1.2 jmcneill } 754 1.2 jmcneill 755 1.2 jmcneill static void 756 1.3 jmcneill axppmic_attach_acadapter(struct axppmic_softc *sc) 757 1.3 jmcneill { 758 1.3 jmcneill envsys_data_t *e; 759 1.3 jmcneill 760 1.3 jmcneill e = &sc->sc_sensor[AXP_SENSOR_ACIN_PRESENT]; 761 1.3 jmcneill e->private = AXP_SENSOR_ACIN_PRESENT; 762 1.3 jmcneill e->units = ENVSYS_INDICATOR; 763 1.3 jmcneill e->state = ENVSYS_SINVALID; 764 1.3 jmcneill strlcpy(e->desc, "ACIN present", sizeof(e->desc)); 765 1.3 jmcneill sysmon_envsys_sensor_attach(sc->sc_sme, e); 766 1.3 jmcneill 767 1.3 jmcneill e = &sc->sc_sensor[AXP_SENSOR_VBUS_PRESENT]; 768 1.3 jmcneill e->private = AXP_SENSOR_VBUS_PRESENT; 769 1.3 jmcneill e->units = ENVSYS_INDICATOR; 770 1.3 jmcneill e->state = ENVSYS_SINVALID; 771 1.3 jmcneill strlcpy(e->desc, "VBUS present", sizeof(e->desc)); 772 1.3 jmcneill sysmon_envsys_sensor_attach(sc->sc_sme, e); 773 1.3 jmcneill } 774 1.3 jmcneill 775 1.3 jmcneill static void 776 1.2 jmcneill axppmic_attach_battery(struct axppmic_softc *sc) 777 1.2 jmcneill { 778 1.10 jmcneill const struct axppmic_config *c = sc->sc_conf; 779 1.2 jmcneill envsys_data_t *e; 780 1.4 jmcneill uint8_t val; 781 1.4 jmcneill 782 1.4 jmcneill iic_acquire_bus(sc->sc_i2c, I2C_F_POLL); 783 1.4 jmcneill if (axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_BATT_CAP_WARN_REG, &val, I2C_F_POLL) == 0) { 784 1.4 jmcneill sc->sc_warn_thres = __SHIFTOUT(val, AXP_BATT_CAP_WARN_LV1) + 5; 785 1.4 jmcneill sc->sc_shut_thres = __SHIFTOUT(val, AXP_BATT_CAP_WARN_LV2); 786 1.4 jmcneill } 787 1.4 jmcneill iic_release_bus(sc->sc_i2c, I2C_F_POLL); 788 1.2 jmcneill 789 1.2 jmcneill e = &sc->sc_sensor[AXP_SENSOR_BATT_PRESENT]; 790 1.2 jmcneill e->private = AXP_SENSOR_BATT_PRESENT; 791 1.2 jmcneill e->units = ENVSYS_INDICATOR; 792 1.2 jmcneill e->state = ENVSYS_SINVALID; 793 1.2 jmcneill strlcpy(e->desc, "battery present", sizeof(e->desc)); 794 1.2 jmcneill sysmon_envsys_sensor_attach(sc->sc_sme, e); 795 1.2 jmcneill 796 1.2 jmcneill e = &sc->sc_sensor[AXP_SENSOR_BATT_CHARGING]; 797 1.2 jmcneill e->private = AXP_SENSOR_BATT_CHARGING; 798 1.2 jmcneill e->units = ENVSYS_BATTERY_CHARGE; 799 1.2 jmcneill e->state = ENVSYS_SINVALID; 800 1.2 jmcneill strlcpy(e->desc, "charging", sizeof(e->desc)); 801 1.2 jmcneill sysmon_envsys_sensor_attach(sc->sc_sme, e); 802 1.2 jmcneill 803 1.2 jmcneill e = &sc->sc_sensor[AXP_SENSOR_BATT_CHARGE_STATE]; 804 1.2 jmcneill e->private = AXP_SENSOR_BATT_CHARGE_STATE; 805 1.2 jmcneill e->units = ENVSYS_BATTERY_CAPACITY; 806 1.2 jmcneill e->flags = ENVSYS_FMONSTCHANGED; 807 1.9 jmcneill e->state = ENVSYS_SINVALID; 808 1.2 jmcneill e->value_cur = ENVSYS_BATTERY_CAPACITY_NORMAL; 809 1.2 jmcneill strlcpy(e->desc, "charge state", sizeof(e->desc)); 810 1.2 jmcneill sysmon_envsys_sensor_attach(sc->sc_sme, e); 811 1.2 jmcneill 812 1.10 jmcneill if (c->batsense_step) { 813 1.10 jmcneill e = &sc->sc_sensor[AXP_SENSOR_BATT_VOLTAGE]; 814 1.10 jmcneill e->private = AXP_SENSOR_BATT_VOLTAGE; 815 1.10 jmcneill e->units = ENVSYS_SVOLTS_DC; 816 1.10 jmcneill e->state = ENVSYS_SINVALID; 817 1.10 jmcneill strlcpy(e->desc, "battery voltage", sizeof(e->desc)); 818 1.10 jmcneill sysmon_envsys_sensor_attach(sc->sc_sme, e); 819 1.10 jmcneill } 820 1.10 jmcneill 821 1.10 jmcneill if (c->charge_step) { 822 1.10 jmcneill e = &sc->sc_sensor[AXP_SENSOR_BATT_CHARGE_CURRENT]; 823 1.10 jmcneill e->private = AXP_SENSOR_BATT_CHARGE_CURRENT; 824 1.10 jmcneill e->units = ENVSYS_SAMPS; 825 1.10 jmcneill e->state = ENVSYS_SINVALID; 826 1.10 jmcneill strlcpy(e->desc, "battery charge current", sizeof(e->desc)); 827 1.10 jmcneill sysmon_envsys_sensor_attach(sc->sc_sme, e); 828 1.10 jmcneill } 829 1.10 jmcneill 830 1.10 jmcneill if (c->discharge_step) { 831 1.10 jmcneill e = &sc->sc_sensor[AXP_SENSOR_BATT_DISCHARGE_CURRENT]; 832 1.10 jmcneill e->private = AXP_SENSOR_BATT_DISCHARGE_CURRENT; 833 1.10 jmcneill e->units = ENVSYS_SAMPS; 834 1.10 jmcneill e->state = ENVSYS_SINVALID; 835 1.10 jmcneill strlcpy(e->desc, "battery discharge current", sizeof(e->desc)); 836 1.10 jmcneill sysmon_envsys_sensor_attach(sc->sc_sme, e); 837 1.10 jmcneill } 838 1.10 jmcneill 839 1.10 jmcneill if (c->has_fuel_gauge) { 840 1.10 jmcneill e = &sc->sc_sensor[AXP_SENSOR_BATT_CAPACITY_PERCENT]; 841 1.10 jmcneill e->private = AXP_SENSOR_BATT_CAPACITY_PERCENT; 842 1.2 jmcneill e->units = ENVSYS_INTEGER; 843 1.2 jmcneill e->state = ENVSYS_SINVALID; 844 1.2 jmcneill e->flags = ENVSYS_FPERCENT; 845 1.2 jmcneill strlcpy(e->desc, "battery percent", sizeof(e->desc)); 846 1.2 jmcneill sysmon_envsys_sensor_attach(sc->sc_sme, e); 847 1.2 jmcneill } 848 1.16 jakllsch 849 1.16 jakllsch if (c->maxcap_step) { 850 1.16 jakllsch e = &sc->sc_sensor[AXP_SENSOR_BATT_MAXIMUM_CAPACITY]; 851 1.16 jakllsch e->private = AXP_SENSOR_BATT_MAXIMUM_CAPACITY; 852 1.16 jakllsch e->units = ENVSYS_SAMPHOUR; 853 1.16 jakllsch e->state = ENVSYS_SINVALID; 854 1.16 jakllsch strlcpy(e->desc, "battery maximum capacity", sizeof(e->desc)); 855 1.16 jakllsch sysmon_envsys_sensor_attach(sc->sc_sme, e); 856 1.16 jakllsch } 857 1.16 jakllsch 858 1.16 jakllsch if (c->coulomb_step) { 859 1.16 jakllsch e = &sc->sc_sensor[AXP_SENSOR_BATT_CURRENT_CAPACITY]; 860 1.16 jakllsch e->private = AXP_SENSOR_BATT_CURRENT_CAPACITY; 861 1.16 jakllsch e->units = ENVSYS_SAMPHOUR; 862 1.16 jakllsch e->state = ENVSYS_SINVALID; 863 1.16 jakllsch strlcpy(e->desc, "battery current capacity", sizeof(e->desc)); 864 1.16 jakllsch sysmon_envsys_sensor_attach(sc->sc_sme, e); 865 1.16 jakllsch } 866 1.2 jmcneill } 867 1.2 jmcneill 868 1.2 jmcneill static void 869 1.2 jmcneill axppmic_attach_sensors(struct axppmic_softc *sc) 870 1.2 jmcneill { 871 1.8 jmcneill if (sc->sc_conf->has_battery) { 872 1.2 jmcneill sc->sc_sme = sysmon_envsys_create(); 873 1.2 jmcneill sc->sc_sme->sme_name = device_xname(sc->sc_dev); 874 1.2 jmcneill sc->sc_sme->sme_cookie = sc; 875 1.2 jmcneill sc->sc_sme->sme_refresh = axppmic_sensor_refresh; 876 1.2 jmcneill sc->sc_sme->sme_class = SME_CLASS_BATTERY; 877 1.5 jmcneill sc->sc_sme->sme_flags = SME_INIT_REFRESH; 878 1.2 jmcneill 879 1.3 jmcneill axppmic_attach_acadapter(sc); 880 1.2 jmcneill axppmic_attach_battery(sc); 881 1.2 jmcneill 882 1.2 jmcneill sysmon_envsys_register(sc->sc_sme); 883 1.2 jmcneill } 884 1.2 jmcneill } 885 1.2 jmcneill 886 1.2 jmcneill 887 1.1 jmcneill static int 888 1.1 jmcneill axppmic_match(device_t parent, cfdata_t match, void *aux) 889 1.1 jmcneill { 890 1.1 jmcneill struct i2c_attach_args *ia = aux; 891 1.12 thorpej int match_result; 892 1.1 jmcneill 893 1.14 thorpej if (iic_use_direct_match(ia, match, compat_data, &match_result)) 894 1.12 thorpej return match_result; 895 1.1 jmcneill 896 1.11 thorpej /* This device is direct-config only. */ 897 1.11 thorpej 898 1.11 thorpej return 0; 899 1.1 jmcneill } 900 1.1 jmcneill 901 1.1 jmcneill static void 902 1.1 jmcneill axppmic_attach(device_t parent, device_t self, void *aux) 903 1.1 jmcneill { 904 1.1 jmcneill struct axppmic_softc *sc = device_private(self); 905 1.13 thorpej const struct device_compatible_entry *dce = NULL; 906 1.1 jmcneill const struct axppmic_config *c; 907 1.1 jmcneill struct axpreg_attach_args aaa; 908 1.1 jmcneill struct i2c_attach_args *ia = aux; 909 1.1 jmcneill int phandle, child, i; 910 1.19 jmcneill uint8_t irq_mask, val; 911 1.19 jmcneill int error; 912 1.1 jmcneill void *ih; 913 1.1 jmcneill 914 1.14 thorpej (void) iic_compatible_match(ia, compat_data, &dce); 915 1.12 thorpej KASSERT(dce != NULL); 916 1.14 thorpej c = (void *)dce->data; 917 1.1 jmcneill 918 1.1 jmcneill sc->sc_dev = self; 919 1.1 jmcneill sc->sc_i2c = ia->ia_tag; 920 1.1 jmcneill sc->sc_addr = ia->ia_addr; 921 1.1 jmcneill sc->sc_phandle = ia->ia_cookie; 922 1.8 jmcneill sc->sc_conf = c; 923 1.1 jmcneill 924 1.1 jmcneill aprint_naive("\n"); 925 1.1 jmcneill aprint_normal(": %s\n", c->name); 926 1.1 jmcneill 927 1.19 jmcneill if (c->has_mode_set) { 928 1.19 jmcneill const bool master_mode = of_hasprop(sc->sc_phandle, "x-powers,self-working-mode") || 929 1.19 jmcneill of_hasprop(sc->sc_phandle, "x-powers,master-mode"); 930 1.19 jmcneill 931 1.19 jmcneill iic_acquire_bus(sc->sc_i2c, I2C_F_POLL); 932 1.19 jmcneill axppmic_write(sc->sc_i2c, sc->sc_addr, AXP_ADDR_EXT_REG, 933 1.19 jmcneill master_mode ? AXP_ADDR_EXT_MASTER : AXP_ADDR_EXT_SLAVE, I2C_F_POLL); 934 1.19 jmcneill iic_release_bus(sc->sc_i2c, I2C_F_POLL); 935 1.19 jmcneill } 936 1.19 jmcneill 937 1.19 jmcneill iic_acquire_bus(sc->sc_i2c, I2C_F_POLL); 938 1.19 jmcneill error = axppmic_read(sc->sc_i2c, sc->sc_addr, AXP_CHIP_ID_REG, &val, I2C_F_POLL); 939 1.19 jmcneill iic_release_bus(sc->sc_i2c, I2C_F_POLL); 940 1.19 jmcneill if (error != 0) { 941 1.19 jmcneill aprint_error_dev(self, "couldn't read chipid\n"); 942 1.19 jmcneill return; 943 1.19 jmcneill } 944 1.19 jmcneill aprint_debug_dev(self, "chipid %#x\n", val); 945 1.19 jmcneill 946 1.1 jmcneill sc->sc_smpsw.smpsw_name = device_xname(self); 947 1.1 jmcneill sc->sc_smpsw.smpsw_type = PSWITCH_TYPE_POWER; 948 1.1 jmcneill sysmon_pswitch_register(&sc->sc_smpsw); 949 1.1 jmcneill 950 1.19 jmcneill if (c->irq_regs > 0) { 951 1.19 jmcneill iic_acquire_bus(sc->sc_i2c, I2C_F_POLL); 952 1.19 jmcneill for (i = 1; i <= c->irq_regs; i++) { 953 1.19 jmcneill irq_mask = 0; 954 1.19 jmcneill if (i == c->poklirq.reg) 955 1.19 jmcneill irq_mask |= c->poklirq.mask; 956 1.19 jmcneill if (i == c->acinirq.reg) 957 1.19 jmcneill irq_mask |= c->acinirq.mask; 958 1.19 jmcneill if (i == c->vbusirq.reg) 959 1.19 jmcneill irq_mask |= c->vbusirq.mask; 960 1.19 jmcneill if (i == c->battirq.reg) 961 1.19 jmcneill irq_mask |= c->battirq.mask; 962 1.19 jmcneill if (i == c->chargeirq.reg) 963 1.19 jmcneill irq_mask |= c->chargeirq.mask; 964 1.19 jmcneill if (i == c->chargestirq.reg) 965 1.19 jmcneill irq_mask |= c->chargestirq.mask; 966 1.19 jmcneill axppmic_write(sc->sc_i2c, sc->sc_addr, AXP_IRQ_ENABLE_REG(i), irq_mask, I2C_F_POLL); 967 1.19 jmcneill } 968 1.19 jmcneill iic_release_bus(sc->sc_i2c, I2C_F_POLL); 969 1.19 jmcneill 970 1.19 jmcneill ih = fdtbus_intr_establish(sc->sc_phandle, 0, IPL_VM, FDT_INTR_MPSAFE, 971 1.19 jmcneill axppmic_intr, sc); 972 1.19 jmcneill if (ih == NULL) { 973 1.19 jmcneill aprint_error_dev(self, "WARNING: couldn't establish interrupt handler\n"); 974 1.19 jmcneill } 975 1.1 jmcneill } 976 1.1 jmcneill 977 1.1 jmcneill fdtbus_register_power_controller(sc->sc_dev, sc->sc_phandle, 978 1.1 jmcneill &axppmic_power_funcs); 979 1.1 jmcneill 980 1.1 jmcneill phandle = of_find_firstchild_byname(sc->sc_phandle, "regulators"); 981 1.2 jmcneill if (phandle > 0) { 982 1.2 jmcneill aaa.reg_i2c = sc->sc_i2c; 983 1.2 jmcneill aaa.reg_addr = sc->sc_addr; 984 1.2 jmcneill for (i = 0; i < c->ncontrols; i++) { 985 1.2 jmcneill const struct axppmic_ctrl *ctrl = &c->controls[i]; 986 1.2 jmcneill child = of_find_firstchild_byname(phandle, ctrl->c_name); 987 1.2 jmcneill if (child <= 0) 988 1.2 jmcneill continue; 989 1.2 jmcneill aaa.reg_ctrl = ctrl; 990 1.2 jmcneill aaa.reg_phandle = child; 991 1.2 jmcneill config_found(sc->sc_dev, &aaa, NULL); 992 1.2 jmcneill } 993 1.2 jmcneill } 994 1.1 jmcneill 995 1.2 jmcneill if (c->has_battery) 996 1.2 jmcneill axppmic_attach_sensors(sc); 997 1.1 jmcneill } 998 1.1 jmcneill 999 1.1 jmcneill static int 1000 1.1 jmcneill axpreg_acquire(device_t dev) 1001 1.1 jmcneill { 1002 1.1 jmcneill return 0; 1003 1.1 jmcneill } 1004 1.1 jmcneill 1005 1.1 jmcneill static void 1006 1.1 jmcneill axpreg_release(device_t dev) 1007 1.1 jmcneill { 1008 1.1 jmcneill } 1009 1.1 jmcneill 1010 1.1 jmcneill static int 1011 1.1 jmcneill axpreg_enable(device_t dev, bool enable) 1012 1.1 jmcneill { 1013 1.1 jmcneill struct axpreg_softc *sc = device_private(dev); 1014 1.1 jmcneill const struct axppmic_ctrl *c = sc->sc_ctrl; 1015 1.25 thorpej const int flags = 0; 1016 1.1 jmcneill uint8_t val; 1017 1.1 jmcneill int error; 1018 1.1 jmcneill 1019 1.1 jmcneill if (!c->c_enable_mask) 1020 1.1 jmcneill return EINVAL; 1021 1.1 jmcneill 1022 1.1 jmcneill iic_acquire_bus(sc->sc_i2c, flags); 1023 1.1 jmcneill if ((error = axppmic_read(sc->sc_i2c, sc->sc_addr, c->c_enable_reg, &val, flags)) == 0) { 1024 1.23 jmcneill val &= ~c->c_enable_mask; 1025 1.1 jmcneill if (enable) 1026 1.23 jmcneill val |= c->c_enable_val; 1027 1.1 jmcneill else 1028 1.23 jmcneill val |= c->c_disable_val; 1029 1.1 jmcneill error = axppmic_write(sc->sc_i2c, sc->sc_addr, c->c_enable_reg, val, flags); 1030 1.1 jmcneill } 1031 1.1 jmcneill iic_release_bus(sc->sc_i2c, flags); 1032 1.1 jmcneill 1033 1.1 jmcneill return error; 1034 1.1 jmcneill } 1035 1.1 jmcneill 1036 1.1 jmcneill static int 1037 1.1 jmcneill axpreg_set_voltage(device_t dev, u_int min_uvol, u_int max_uvol) 1038 1.1 jmcneill { 1039 1.1 jmcneill struct axpreg_softc *sc = device_private(dev); 1040 1.1 jmcneill const struct axppmic_ctrl *c = sc->sc_ctrl; 1041 1.1 jmcneill 1042 1.1 jmcneill return axppmic_set_voltage(sc->sc_i2c, sc->sc_addr, c, 1043 1.1 jmcneill min_uvol / 1000, max_uvol / 1000); 1044 1.1 jmcneill } 1045 1.1 jmcneill 1046 1.1 jmcneill static int 1047 1.1 jmcneill axpreg_get_voltage(device_t dev, u_int *puvol) 1048 1.1 jmcneill { 1049 1.1 jmcneill struct axpreg_softc *sc = device_private(dev); 1050 1.1 jmcneill const struct axppmic_ctrl *c = sc->sc_ctrl; 1051 1.1 jmcneill int error; 1052 1.1 jmcneill u_int vol; 1053 1.1 jmcneill 1054 1.1 jmcneill error = axppmic_get_voltage(sc->sc_i2c, sc->sc_addr, c, &vol); 1055 1.1 jmcneill if (error) 1056 1.1 jmcneill return error; 1057 1.1 jmcneill 1058 1.1 jmcneill *puvol = vol * 1000; 1059 1.1 jmcneill return 0; 1060 1.1 jmcneill } 1061 1.1 jmcneill 1062 1.1 jmcneill static struct fdtbus_regulator_controller_func axpreg_funcs = { 1063 1.1 jmcneill .acquire = axpreg_acquire, 1064 1.1 jmcneill .release = axpreg_release, 1065 1.1 jmcneill .enable = axpreg_enable, 1066 1.1 jmcneill .set_voltage = axpreg_set_voltage, 1067 1.1 jmcneill .get_voltage = axpreg_get_voltage, 1068 1.1 jmcneill }; 1069 1.1 jmcneill 1070 1.1 jmcneill static int 1071 1.1 jmcneill axpreg_match(device_t parent, cfdata_t match, void *aux) 1072 1.1 jmcneill { 1073 1.1 jmcneill return 1; 1074 1.1 jmcneill } 1075 1.1 jmcneill 1076 1.1 jmcneill static void 1077 1.1 jmcneill axpreg_attach(device_t parent, device_t self, void *aux) 1078 1.1 jmcneill { 1079 1.1 jmcneill struct axpreg_softc *sc = device_private(self); 1080 1.1 jmcneill struct axpreg_attach_args *aaa = aux; 1081 1.1 jmcneill const int phandle = aaa->reg_phandle; 1082 1.1 jmcneill const char *name; 1083 1.20 jmcneill u_int uvol, min_uvol, max_uvol; 1084 1.1 jmcneill 1085 1.1 jmcneill sc->sc_dev = self; 1086 1.1 jmcneill sc->sc_i2c = aaa->reg_i2c; 1087 1.1 jmcneill sc->sc_addr = aaa->reg_addr; 1088 1.1 jmcneill sc->sc_ctrl = aaa->reg_ctrl; 1089 1.1 jmcneill 1090 1.1 jmcneill fdtbus_register_regulator_controller(self, phandle, 1091 1.1 jmcneill &axpreg_funcs); 1092 1.1 jmcneill 1093 1.1 jmcneill aprint_naive("\n"); 1094 1.1 jmcneill name = fdtbus_get_string(phandle, "regulator-name"); 1095 1.1 jmcneill if (name) 1096 1.1 jmcneill aprint_normal(": %s\n", name); 1097 1.1 jmcneill else 1098 1.1 jmcneill aprint_normal("\n"); 1099 1.20 jmcneill 1100 1.20 jmcneill axpreg_get_voltage(self, &uvol); 1101 1.20 jmcneill if (of_getprop_uint32(phandle, "regulator-min-microvolt", &min_uvol) == 0 && 1102 1.20 jmcneill of_getprop_uint32(phandle, "regulator-max-microvolt", &max_uvol) == 0) { 1103 1.20 jmcneill if (uvol < min_uvol || uvol > max_uvol) { 1104 1.22 jmcneill aprint_debug_dev(self, "fix voltage %u uV -> %u/%u uV\n", 1105 1.22 jmcneill uvol, min_uvol, max_uvol); 1106 1.20 jmcneill axpreg_set_voltage(self, min_uvol, max_uvol); 1107 1.20 jmcneill } 1108 1.20 jmcneill } 1109 1.22 jmcneill 1110 1.22 jmcneill if (of_hasprop(phandle, "regulator-always-on") || 1111 1.22 jmcneill of_hasprop(phandle, "regulator-boot-on")) { 1112 1.22 jmcneill axpreg_enable(self, true); 1113 1.22 jmcneill } 1114 1.1 jmcneill } 1115 1.1 jmcneill 1116 1.1 jmcneill CFATTACH_DECL_NEW(axppmic, sizeof(struct axppmic_softc), 1117 1.1 jmcneill axppmic_match, axppmic_attach, NULL, NULL); 1118 1.1 jmcneill 1119 1.1 jmcneill CFATTACH_DECL_NEW(axpreg, sizeof(struct axpreg_softc), 1120 1.1 jmcneill axpreg_match, axpreg_attach, NULL, NULL); 1121
Indexes created Thu Oct 02 14:10:14 GMT 2025