ds1307.c revision 1.25.2.1
1 1.25.2.1 pgoyette /* $NetBSD: ds1307.c,v 1.25.2.1 2018/06/25 07:25:50 pgoyette Exp $ */ 2 1.1 thorpej 3 1.1 thorpej /* 4 1.1 thorpej * Copyright (c) 2003 Wasabi Systems, Inc. 5 1.1 thorpej * All rights reserved. 6 1.1 thorpej * 7 1.1 thorpej * Written by Steve C. Woodford and Jason R. Thorpe for Wasabi Systems, Inc. 8 1.1 thorpej * 9 1.1 thorpej * Redistribution and use in source and binary forms, with or without 10 1.1 thorpej * modification, are permitted provided that the following conditions 11 1.1 thorpej * are met: 12 1.1 thorpej * 1. Redistributions of source code must retain the above copyright 13 1.1 thorpej * notice, this list of conditions and the following disclaimer. 14 1.1 thorpej * 2. Redistributions in binary form must reproduce the above copyright 15 1.1 thorpej * notice, this list of conditions and the following disclaimer in the 16 1.1 thorpej * documentation and/or other materials provided with the distribution. 17 1.1 thorpej * 3. All advertising materials mentioning features or use of this software 18 1.1 thorpej * must display the following acknowledgement: 19 1.1 thorpej * This product includes software developed for the NetBSD Project by 20 1.1 thorpej * Wasabi Systems, Inc. 21 1.1 thorpej * 4. The name of Wasabi Systems, Inc. may not be used to endorse 22 1.1 thorpej * or promote products derived from this software without specific prior 23 1.1 thorpej * written permission. 24 1.1 thorpej * 25 1.1 thorpej * THIS SOFTWARE IS PROVIDED BY WASABI SYSTEMS, INC. ``AS IS'' AND 26 1.1 thorpej * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 27 1.1 thorpej * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 28 1.1 thorpej * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL WASABI SYSTEMS, INC 29 1.1 thorpej * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 30 1.1 thorpej * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 31 1.1 thorpej * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 32 1.1 thorpej * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 33 1.1 thorpej * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 34 1.1 thorpej * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 35 1.1 thorpej * POSSIBILITY OF SUCH DAMAGE. 36 1.1 thorpej */ 37 1.1 thorpej 38 1.9 lukem #include <sys/cdefs.h> 39 1.25.2.1 pgoyette __KERNEL_RCSID(0, "$NetBSD: ds1307.c,v 1.25.2.1 2018/06/25 07:25:50 pgoyette Exp $"); 40 1.9 lukem 41 1.1 thorpej #include <sys/param.h> 42 1.1 thorpej #include <sys/systm.h> 43 1.1 thorpej #include <sys/device.h> 44 1.1 thorpej #include <sys/kernel.h> 45 1.1 thorpej #include <sys/fcntl.h> 46 1.1 thorpej #include <sys/uio.h> 47 1.1 thorpej #include <sys/conf.h> 48 1.1 thorpej #include <sys/event.h> 49 1.1 thorpej 50 1.1 thorpej #include <dev/clock_subr.h> 51 1.1 thorpej 52 1.1 thorpej #include <dev/i2c/i2cvar.h> 53 1.1 thorpej #include <dev/i2c/ds1307reg.h> 54 1.19 macallan #include <dev/sysmon/sysmonvar.h> 55 1.1 thorpej 56 1.25 riastrad #include "ioconf.h" 57 1.25 riastrad 58 1.15 matt struct dsrtc_model { 59 1.25.2.1 pgoyette const i2c_addr_t *dm_valid_addrs; 60 1.15 matt uint16_t dm_model; 61 1.15 matt uint8_t dm_ch_reg; 62 1.15 matt uint8_t dm_ch_value; 63 1.24 aymeric uint8_t dm_vbaten_reg; 64 1.24 aymeric uint8_t dm_vbaten_value; 65 1.15 matt uint8_t dm_rtc_start; 66 1.15 matt uint8_t dm_rtc_size; 67 1.15 matt uint8_t dm_nvram_start; 68 1.15 matt uint8_t dm_nvram_size; 69 1.15 matt uint8_t dm_flags; 70 1.24 aymeric #define DSRTC_FLAG_CLOCK_HOLD 0x01 71 1.24 aymeric #define DSRTC_FLAG_BCD 0x02 72 1.24 aymeric #define DSRTC_FLAG_TEMP 0x04 73 1.24 aymeric #define DSRTC_FLAG_VBATEN 0x08 74 1.24 aymeric #define DSRTC_FLAG_YEAR_START_2K 0x10 75 1.24 aymeric #define DSRTC_FLAG_CLOCK_HOLD_REVERSED 0x20 76 1.15 matt }; 77 1.15 matt 78 1.25.2.1 pgoyette static const char *ds1307_compats[] = { "dallas,ds1307", "maxim,ds1307", NULL }; 79 1.25.2.1 pgoyette static const i2c_addr_t ds1307_valid_addrs[] = { DS1307_ADDR, 0 }; 80 1.25.2.1 pgoyette static const struct dsrtc_model ds1307_model = { 81 1.25.2.1 pgoyette .dm_valid_addrs = ds1307_valid_addrs, 82 1.25.2.1 pgoyette .dm_model = 1307, 83 1.25.2.1 pgoyette .dm_ch_reg = DSXXXX_SECONDS, 84 1.25.2.1 pgoyette .dm_ch_value = DS1307_SECONDS_CH, 85 1.25.2.1 pgoyette .dm_rtc_start = DS1307_RTC_START, 86 1.25.2.1 pgoyette .dm_rtc_size = DS1307_RTC_SIZE, 87 1.25.2.1 pgoyette .dm_nvram_start = DS1307_NVRAM_START, 88 1.25.2.1 pgoyette .dm_nvram_size = DS1307_NVRAM_SIZE, 89 1.25.2.1 pgoyette .dm_flags = DSRTC_FLAG_BCD | DSRTC_FLAG_CLOCK_HOLD, 90 1.25.2.1 pgoyette }; 91 1.25.2.1 pgoyette 92 1.25.2.1 pgoyette static const char *ds1339_compats[] = { "dallas,ds1339", "maxim,ds1339", NULL }; 93 1.25.2.1 pgoyette static const struct dsrtc_model ds1339_model = { 94 1.25.2.1 pgoyette .dm_valid_addrs = ds1307_valid_addrs, 95 1.25.2.1 pgoyette .dm_model = 1339, 96 1.25.2.1 pgoyette .dm_rtc_start = DS1339_RTC_START, 97 1.25.2.1 pgoyette .dm_rtc_size = DS1339_RTC_SIZE, 98 1.25.2.1 pgoyette .dm_flags = DSRTC_FLAG_BCD, 99 1.25.2.1 pgoyette }; 100 1.25.2.1 pgoyette 101 1.25.2.1 pgoyette static const char *ds1340_compats[] = { "dallas,ds1340", "maxim,ds1340", NULL }; 102 1.25.2.1 pgoyette static const struct dsrtc_model ds1340_model = { 103 1.25.2.1 pgoyette .dm_valid_addrs = ds1307_valid_addrs, 104 1.25.2.1 pgoyette .dm_model = 1340, 105 1.25.2.1 pgoyette .dm_ch_reg = DSXXXX_SECONDS, 106 1.25.2.1 pgoyette .dm_ch_value = DS1340_SECONDS_EOSC, 107 1.25.2.1 pgoyette .dm_rtc_start = DS1340_RTC_START, 108 1.25.2.1 pgoyette .dm_rtc_size = DS1340_RTC_SIZE, 109 1.25.2.1 pgoyette .dm_flags = DSRTC_FLAG_BCD, 110 1.25.2.1 pgoyette }; 111 1.25.2.1 pgoyette 112 1.25.2.1 pgoyette static const char *ds1672_compats[] = { "dallas,ds1672", "maxim,ds1672", NULL }; 113 1.25.2.1 pgoyette static const struct dsrtc_model ds1672_model = { 114 1.25.2.1 pgoyette .dm_valid_addrs = ds1307_valid_addrs, 115 1.25.2.1 pgoyette .dm_model = 1672, 116 1.25.2.1 pgoyette .dm_rtc_start = DS1672_RTC_START, 117 1.25.2.1 pgoyette .dm_rtc_size = DS1672_RTC_SIZE, 118 1.25.2.1 pgoyette .dm_ch_reg = DS1672_CONTROL, 119 1.25.2.1 pgoyette .dm_ch_value = DS1672_CONTROL_CH, 120 1.25.2.1 pgoyette .dm_flags = 0, 121 1.25.2.1 pgoyette }; 122 1.25.2.1 pgoyette 123 1.25.2.1 pgoyette static const char *ds3231_compats[] = { "dallas,ds3231", "maxim,ds3231", NULL }; 124 1.25.2.1 pgoyette static const struct dsrtc_model ds3231_model = { 125 1.25.2.1 pgoyette .dm_valid_addrs = ds1307_valid_addrs, 126 1.25.2.1 pgoyette .dm_model = 3231, 127 1.25.2.1 pgoyette .dm_rtc_start = DS3232_RTC_START, 128 1.25.2.1 pgoyette .dm_rtc_size = DS3232_RTC_SIZE, 129 1.25.2.1 pgoyette .dm_flags = DSRTC_FLAG_BCD | DSRTC_FLAG_TEMP, 130 1.25.2.1 pgoyette }; 131 1.25.2.1 pgoyette 132 1.25.2.1 pgoyette static const char *ds3232_compats[] = { "dallas,ds3232", "maxim,ds3232", NULL }; 133 1.25.2.1 pgoyette static const struct dsrtc_model ds3232_model = { 134 1.25.2.1 pgoyette .dm_valid_addrs = ds1307_valid_addrs, 135 1.25.2.1 pgoyette .dm_model = 3232, 136 1.25.2.1 pgoyette .dm_rtc_start = DS3232_RTC_START, 137 1.25.2.1 pgoyette .dm_rtc_size = DS3232_RTC_SIZE, 138 1.25.2.1 pgoyette .dm_nvram_start = DS3232_NVRAM_START, 139 1.25.2.1 pgoyette .dm_nvram_size = DS3232_NVRAM_SIZE, 140 1.25.2.1 pgoyette /* 141 1.25.2.1 pgoyette * XXX 142 1.25.2.1 pgoyette * the DS3232 likely has the temperature sensor too but I can't 143 1.25.2.1 pgoyette * easily verify or test that right now 144 1.25.2.1 pgoyette */ 145 1.25.2.1 pgoyette .dm_flags = DSRTC_FLAG_BCD, 146 1.25.2.1 pgoyette }; 147 1.25.2.1 pgoyette 148 1.25.2.1 pgoyette /* XXX vendor prefix */ 149 1.25.2.1 pgoyette static const char *mcp7940_compats[] = { "microchip,mcp7940", NULL }; 150 1.25.2.1 pgoyette static const i2c_addr_t mcp7940_valid_addrs[] = { MCP7940_ADDR, 0 }; 151 1.25.2.1 pgoyette static const struct dsrtc_model mcp7940_model = { 152 1.25.2.1 pgoyette .dm_valid_addrs = mcp7940_valid_addrs, 153 1.25.2.1 pgoyette .dm_model = 7940, 154 1.25.2.1 pgoyette .dm_rtc_start = DS1307_RTC_START, 155 1.25.2.1 pgoyette .dm_rtc_size = DS1307_RTC_SIZE, 156 1.25.2.1 pgoyette .dm_ch_reg = DSXXXX_SECONDS, 157 1.25.2.1 pgoyette .dm_ch_value = DS1307_SECONDS_CH, 158 1.25.2.1 pgoyette .dm_vbaten_reg = DSXXXX_DAY, 159 1.25.2.1 pgoyette .dm_vbaten_value = MCP7940_TOD_DAY_VBATEN, 160 1.25.2.1 pgoyette .dm_nvram_start = MCP7940_NVRAM_START, 161 1.25.2.1 pgoyette .dm_nvram_size = MCP7940_NVRAM_SIZE, 162 1.25.2.1 pgoyette .dm_flags = DSRTC_FLAG_BCD | DSRTC_FLAG_CLOCK_HOLD | 163 1.25.2.1 pgoyette DSRTC_FLAG_VBATEN | DSRTC_FLAG_CLOCK_HOLD_REVERSED, 164 1.25.2.1 pgoyette }; 165 1.25.2.1 pgoyette 166 1.25.2.1 pgoyette static const struct device_compatible_entry dsrtc_compat_data[] = { 167 1.25.2.1 pgoyette DEVICE_COMPAT_ENTRY_WITH_DATA(ds1307_compats, &ds1307_model), 168 1.25.2.1 pgoyette DEVICE_COMPAT_ENTRY_WITH_DATA(ds1339_compats, &ds1339_model), 169 1.25.2.1 pgoyette DEVICE_COMPAT_ENTRY_WITH_DATA(ds1340_compats, &ds1340_model), 170 1.25.2.1 pgoyette DEVICE_COMPAT_ENTRY_WITH_DATA(ds1672_compats, &ds1672_model), 171 1.25.2.1 pgoyette DEVICE_COMPAT_ENTRY_WITH_DATA(ds3231_compats, &ds3231_model), 172 1.25.2.1 pgoyette DEVICE_COMPAT_ENTRY_WITH_DATA(ds3232_compats, &ds3232_model), 173 1.25.2.1 pgoyette DEVICE_COMPAT_ENTRY_WITH_DATA(mcp7940_compats, &mcp7940_model), 174 1.25.2.1 pgoyette DEVICE_COMPAT_TERMINATOR 175 1.15 matt }; 176 1.15 matt 177 1.1 thorpej struct dsrtc_softc { 178 1.11 xtraeme device_t sc_dev; 179 1.1 thorpej i2c_tag_t sc_tag; 180 1.15 matt uint8_t sc_address; 181 1.15 matt bool sc_open; 182 1.15 matt struct dsrtc_model sc_model; 183 1.1 thorpej struct todr_chip_handle sc_todr; 184 1.19 macallan struct sysmon_envsys *sc_sme; 185 1.19 macallan envsys_data_t sc_sensor; 186 1.1 thorpej }; 187 1.1 thorpej 188 1.11 xtraeme static void dsrtc_attach(device_t, device_t, void *); 189 1.11 xtraeme static int dsrtc_match(device_t, cfdata_t, void *); 190 1.1 thorpej 191 1.11 xtraeme CFATTACH_DECL_NEW(dsrtc, sizeof(struct dsrtc_softc), 192 1.1 thorpej dsrtc_match, dsrtc_attach, NULL, NULL); 193 1.1 thorpej 194 1.1 thorpej dev_type_open(dsrtc_open); 195 1.1 thorpej dev_type_close(dsrtc_close); 196 1.1 thorpej dev_type_read(dsrtc_read); 197 1.1 thorpej dev_type_write(dsrtc_write); 198 1.1 thorpej 199 1.1 thorpej const struct cdevsw dsrtc_cdevsw = { 200 1.17 dholland .d_open = dsrtc_open, 201 1.17 dholland .d_close = dsrtc_close, 202 1.17 dholland .d_read = dsrtc_read, 203 1.17 dholland .d_write = dsrtc_write, 204 1.17 dholland .d_ioctl = noioctl, 205 1.17 dholland .d_stop = nostop, 206 1.17 dholland .d_tty = notty, 207 1.17 dholland .d_poll = nopoll, 208 1.17 dholland .d_mmap = nommap, 209 1.17 dholland .d_kqfilter = nokqfilter, 210 1.18 dholland .d_discard = nodiscard, 211 1.17 dholland .d_flag = D_OTHER 212 1.1 thorpej }; 213 1.1 thorpej 214 1.15 matt static int dsrtc_gettime_ymdhms(struct todr_chip_handle *, struct clock_ymdhms *); 215 1.15 matt static int dsrtc_settime_ymdhms(struct todr_chip_handle *, struct clock_ymdhms *); 216 1.15 matt static int dsrtc_clock_read_ymdhms(struct dsrtc_softc *, struct clock_ymdhms *); 217 1.15 matt static int dsrtc_clock_write_ymdhms(struct dsrtc_softc *, struct clock_ymdhms *); 218 1.15 matt 219 1.15 matt static int dsrtc_gettime_timeval(struct todr_chip_handle *, struct timeval *); 220 1.15 matt static int dsrtc_settime_timeval(struct todr_chip_handle *, struct timeval *); 221 1.15 matt static int dsrtc_clock_read_timeval(struct dsrtc_softc *, time_t *); 222 1.15 matt static int dsrtc_clock_write_timeval(struct dsrtc_softc *, time_t); 223 1.15 matt 224 1.19 macallan static int dsrtc_read_temp(struct dsrtc_softc *, uint32_t *); 225 1.19 macallan static void dsrtc_refresh(struct sysmon_envsys *, envsys_data_t *); 226 1.19 macallan 227 1.15 matt static const struct dsrtc_model * 228 1.25.2.1 pgoyette dsrtc_model_by_number(u_int model) 229 1.15 matt { 230 1.25.2.1 pgoyette const struct device_compatible_entry *dce; 231 1.25.2.1 pgoyette const struct dsrtc_model *dm; 232 1.25.2.1 pgoyette 233 1.25.2.1 pgoyette /* no model given, assume it's a DS1307 */ 234 1.15 matt if (model == 0) 235 1.25.2.1 pgoyette return &ds1307_model; 236 1.15 matt 237 1.25.2.1 pgoyette for (dce = dsrtc_compat_data; 238 1.25.2.1 pgoyette DEVICE_COMPAT_ENTRY_IS_TERMINATOR(dce) == false; dce++) { 239 1.25.2.1 pgoyette dm = DEVICE_COMPAT_ENTRY_GET_PTR(dce); 240 1.15 matt if (dm->dm_model == model) 241 1.15 matt return dm; 242 1.15 matt } 243 1.15 matt return NULL; 244 1.15 matt } 245 1.1 thorpej 246 1.25.2.1 pgoyette static const struct dsrtc_model * 247 1.25.2.1 pgoyette dsrtc_model_by_compat(const struct i2c_attach_args *ia) 248 1.25.2.1 pgoyette { 249 1.25.2.1 pgoyette const struct dsrtc_model *dm = NULL; 250 1.25.2.1 pgoyette const struct device_compatible_entry *dce; 251 1.25.2.1 pgoyette 252 1.25.2.1 pgoyette dce = iic_compatible_match(ia, dsrtc_compat_data, NULL); 253 1.25.2.1 pgoyette if (dce != NULL) 254 1.25.2.1 pgoyette dm = DEVICE_COMPAT_ENTRY_GET_PTR(dce); 255 1.25.2.1 pgoyette 256 1.25.2.1 pgoyette return dm; 257 1.25.2.1 pgoyette } 258 1.25.2.1 pgoyette 259 1.25.2.1 pgoyette static bool 260 1.25.2.1 pgoyette dsrtc_is_valid_addr_for_model(const struct dsrtc_model *dm, i2c_addr_t addr) 261 1.25.2.1 pgoyette { 262 1.25.2.1 pgoyette 263 1.25.2.1 pgoyette for (int i = 0; dm->dm_valid_addrs[i] != 0; i++) { 264 1.25.2.1 pgoyette if (addr == dm->dm_valid_addrs[i]) 265 1.25.2.1 pgoyette return true; 266 1.25.2.1 pgoyette } 267 1.25.2.1 pgoyette return false; 268 1.25.2.1 pgoyette } 269 1.25.2.1 pgoyette 270 1.1 thorpej static int 271 1.11 xtraeme dsrtc_match(device_t parent, cfdata_t cf, void *arg) 272 1.1 thorpej { 273 1.1 thorpej struct i2c_attach_args *ia = arg; 274 1.25.2.1 pgoyette const struct dsrtc_model *dm; 275 1.25.2.1 pgoyette int match_result; 276 1.25.2.1 pgoyette 277 1.25.2.1 pgoyette if (iic_use_direct_match(ia, cf, dsrtc_compat_data, &match_result)) 278 1.25.2.1 pgoyette return match_result; 279 1.25.2.1 pgoyette 280 1.25.2.1 pgoyette dm = dsrtc_model_by_number(cf->cf_flags & 0xffff); 281 1.25.2.1 pgoyette if (dm == NULL) 282 1.25.2.1 pgoyette return 0; 283 1.25.2.1 pgoyette 284 1.25.2.1 pgoyette if (dsrtc_is_valid_addr_for_model(dm, ia->ia_addr)) 285 1.25.2.1 pgoyette return I2C_MATCH_ADDRESS_ONLY; 286 1.1 thorpej 287 1.13 phx return 0; 288 1.1 thorpej } 289 1.1 thorpej 290 1.1 thorpej static void 291 1.11 xtraeme dsrtc_attach(device_t parent, device_t self, void *arg) 292 1.1 thorpej { 293 1.5 thorpej struct dsrtc_softc *sc = device_private(self); 294 1.1 thorpej struct i2c_attach_args *ia = arg; 295 1.25.2.1 pgoyette const struct dsrtc_model *dm; 296 1.25.2.1 pgoyette 297 1.25.2.1 pgoyette if ((dm = dsrtc_model_by_compat(ia)) == NULL) 298 1.25.2.1 pgoyette dm = dsrtc_model_by_number(device_cfdata(self)->cf_flags); 299 1.25.2.1 pgoyette 300 1.25.2.1 pgoyette if (dm == NULL) { 301 1.25.2.1 pgoyette aprint_error(": unable to determine model!\n"); 302 1.25.2.1 pgoyette return; 303 1.25.2.1 pgoyette } 304 1.1 thorpej 305 1.15 matt aprint_naive(": Real-time Clock%s\n", 306 1.15 matt dm->dm_nvram_size > 0 ? "/NVRAM" : ""); 307 1.15 matt aprint_normal(": DS%u Real-time Clock%s\n", dm->dm_model, 308 1.15 matt dm->dm_nvram_size > 0 ? "/NVRAM" : ""); 309 1.1 thorpej 310 1.1 thorpej sc->sc_tag = ia->ia_tag; 311 1.1 thorpej sc->sc_address = ia->ia_addr; 312 1.15 matt sc->sc_model = *dm; 313 1.11 xtraeme sc->sc_dev = self; 314 1.1 thorpej sc->sc_open = 0; 315 1.1 thorpej sc->sc_todr.cookie = sc; 316 1.15 matt if (dm->dm_flags & DSRTC_FLAG_BCD) { 317 1.15 matt sc->sc_todr.todr_gettime_ymdhms = dsrtc_gettime_ymdhms; 318 1.15 matt sc->sc_todr.todr_settime_ymdhms = dsrtc_settime_ymdhms; 319 1.15 matt } else { 320 1.15 matt sc->sc_todr.todr_gettime = dsrtc_gettime_timeval; 321 1.15 matt sc->sc_todr.todr_settime = dsrtc_settime_timeval; 322 1.15 matt } 323 1.1 thorpej sc->sc_todr.todr_setwen = NULL; 324 1.1 thorpej 325 1.1 thorpej todr_attach(&sc->sc_todr); 326 1.19 macallan if ((sc->sc_model.dm_flags & DSRTC_FLAG_TEMP) != 0) { 327 1.19 macallan int error; 328 1.19 macallan 329 1.19 macallan sc->sc_sme = sysmon_envsys_create(); 330 1.19 macallan sc->sc_sme->sme_name = device_xname(self); 331 1.19 macallan sc->sc_sme->sme_cookie = sc; 332 1.19 macallan sc->sc_sme->sme_refresh = dsrtc_refresh; 333 1.19 macallan 334 1.19 macallan sc->sc_sensor.units = ENVSYS_STEMP; 335 1.19 macallan sc->sc_sensor.state = ENVSYS_SINVALID; 336 1.19 macallan sc->sc_sensor.flags = 0; 337 1.19 macallan (void)strlcpy(sc->sc_sensor.desc, "temperature", 338 1.19 macallan sizeof(sc->sc_sensor.desc)); 339 1.19 macallan 340 1.19 macallan if (sysmon_envsys_sensor_attach(sc->sc_sme, &sc->sc_sensor)) { 341 1.19 macallan aprint_error_dev(self, "unable to attach sensor\n"); 342 1.19 macallan goto bad; 343 1.19 macallan } 344 1.19 macallan 345 1.19 macallan error = sysmon_envsys_register(sc->sc_sme); 346 1.19 macallan if (error) { 347 1.19 macallan aprint_error_dev(self, 348 1.19 macallan "error %d registering with sysmon\n", error); 349 1.19 macallan goto bad; 350 1.19 macallan } 351 1.19 macallan } 352 1.19 macallan return; 353 1.19 macallan bad: 354 1.19 macallan sysmon_envsys_destroy(sc->sc_sme); 355 1.1 thorpej } 356 1.1 thorpej 357 1.1 thorpej /*ARGSUSED*/ 358 1.1 thorpej int 359 1.4 abs dsrtc_open(dev_t dev, int flag, int fmt, struct lwp *l) 360 1.1 thorpej { 361 1.1 thorpej struct dsrtc_softc *sc; 362 1.1 thorpej 363 1.12 tsutsui if ((sc = device_lookup_private(&dsrtc_cd, minor(dev))) == NULL) 364 1.14 phx return ENXIO; 365 1.1 thorpej 366 1.1 thorpej /* XXX: Locking */ 367 1.1 thorpej if (sc->sc_open) 368 1.14 phx return EBUSY; 369 1.1 thorpej 370 1.15 matt sc->sc_open = true; 371 1.14 phx return 0; 372 1.1 thorpej } 373 1.1 thorpej 374 1.1 thorpej /*ARGSUSED*/ 375 1.1 thorpej int 376 1.4 abs dsrtc_close(dev_t dev, int flag, int fmt, struct lwp *l) 377 1.1 thorpej { 378 1.1 thorpej struct dsrtc_softc *sc; 379 1.1 thorpej 380 1.12 tsutsui if ((sc = device_lookup_private(&dsrtc_cd, minor(dev))) == NULL) 381 1.14 phx return ENXIO; 382 1.1 thorpej 383 1.15 matt sc->sc_open = false; 384 1.14 phx return 0; 385 1.1 thorpej } 386 1.1 thorpej 387 1.1 thorpej /*ARGSUSED*/ 388 1.1 thorpej int 389 1.1 thorpej dsrtc_read(dev_t dev, struct uio *uio, int flags) 390 1.1 thorpej { 391 1.1 thorpej struct dsrtc_softc *sc; 392 1.15 matt int error; 393 1.1 thorpej 394 1.12 tsutsui if ((sc = device_lookup_private(&dsrtc_cd, minor(dev))) == NULL) 395 1.14 phx return ENXIO; 396 1.1 thorpej 397 1.15 matt const struct dsrtc_model * const dm = &sc->sc_model; 398 1.15 matt if (uio->uio_offset >= dm->dm_nvram_size) 399 1.14 phx return EINVAL; 400 1.1 thorpej 401 1.1 thorpej if ((error = iic_acquire_bus(sc->sc_tag, 0)) != 0) 402 1.14 phx return error; 403 1.1 thorpej 404 1.15 matt KASSERT(uio->uio_offset >= 0); 405 1.15 matt while (uio->uio_resid && uio->uio_offset < dm->dm_nvram_size) { 406 1.15 matt uint8_t ch, cmd; 407 1.15 matt const u_int a = uio->uio_offset; 408 1.15 matt cmd = a + dm->dm_nvram_start; 409 1.15 matt if ((error = iic_exec(sc->sc_tag, 410 1.15 matt uio->uio_resid > 1 ? I2C_OP_READ : I2C_OP_READ_WITH_STOP, 411 1.15 matt sc->sc_address, &cmd, 1, &ch, 1, 0)) != 0) { 412 1.1 thorpej iic_release_bus(sc->sc_tag, 0); 413 1.11 xtraeme aprint_error_dev(sc->sc_dev, 414 1.16 matt "%s: read failed at 0x%x: %d\n", 415 1.16 matt __func__, a, error); 416 1.14 phx return error; 417 1.1 thorpej } 418 1.1 thorpej if ((error = uiomove(&ch, 1, uio)) != 0) { 419 1.1 thorpej iic_release_bus(sc->sc_tag, 0); 420 1.14 phx return error; 421 1.1 thorpej } 422 1.1 thorpej } 423 1.1 thorpej 424 1.1 thorpej iic_release_bus(sc->sc_tag, 0); 425 1.1 thorpej 426 1.14 phx return 0; 427 1.1 thorpej } 428 1.1 thorpej 429 1.1 thorpej /*ARGSUSED*/ 430 1.1 thorpej int 431 1.1 thorpej dsrtc_write(dev_t dev, struct uio *uio, int flags) 432 1.1 thorpej { 433 1.1 thorpej struct dsrtc_softc *sc; 434 1.15 matt int error; 435 1.1 thorpej 436 1.12 tsutsui if ((sc = device_lookup_private(&dsrtc_cd, minor(dev))) == NULL) 437 1.14 phx return ENXIO; 438 1.1 thorpej 439 1.15 matt const struct dsrtc_model * const dm = &sc->sc_model; 440 1.15 matt if (uio->uio_offset >= dm->dm_nvram_size) 441 1.14 phx return EINVAL; 442 1.1 thorpej 443 1.1 thorpej if ((error = iic_acquire_bus(sc->sc_tag, 0)) != 0) 444 1.14 phx return error; 445 1.1 thorpej 446 1.15 matt while (uio->uio_resid && uio->uio_offset < dm->dm_nvram_size) { 447 1.15 matt uint8_t cmdbuf[2]; 448 1.15 matt const u_int a = (int)uio->uio_offset; 449 1.15 matt cmdbuf[0] = a + dm->dm_nvram_start; 450 1.1 thorpej if ((error = uiomove(&cmdbuf[1], 1, uio)) != 0) 451 1.1 thorpej break; 452 1.1 thorpej 453 1.1 thorpej if ((error = iic_exec(sc->sc_tag, 454 1.1 thorpej uio->uio_resid ? I2C_OP_WRITE : I2C_OP_WRITE_WITH_STOP, 455 1.1 thorpej sc->sc_address, cmdbuf, 1, &cmdbuf[1], 1, 0)) != 0) { 456 1.11 xtraeme aprint_error_dev(sc->sc_dev, 457 1.16 matt "%s: write failed at 0x%x: %d\n", 458 1.16 matt __func__, a, error); 459 1.1 thorpej break; 460 1.1 thorpej } 461 1.1 thorpej } 462 1.1 thorpej 463 1.1 thorpej iic_release_bus(sc->sc_tag, 0); 464 1.1 thorpej 465 1.14 phx return error; 466 1.1 thorpej } 467 1.1 thorpej 468 1.1 thorpej static int 469 1.15 matt dsrtc_gettime_ymdhms(struct todr_chip_handle *ch, struct clock_ymdhms *dt) 470 1.1 thorpej { 471 1.1 thorpej struct dsrtc_softc *sc = ch->cookie; 472 1.7 gdamore struct clock_ymdhms check; 473 1.1 thorpej int retries; 474 1.1 thorpej 475 1.7 gdamore memset(dt, 0, sizeof(*dt)); 476 1.1 thorpej memset(&check, 0, sizeof(check)); 477 1.1 thorpej 478 1.1 thorpej /* 479 1.1 thorpej * Since we don't support Burst Read, we have to read the clock twice 480 1.1 thorpej * until we get two consecutive identical results. 481 1.1 thorpej */ 482 1.1 thorpej retries = 5; 483 1.1 thorpej do { 484 1.15 matt dsrtc_clock_read_ymdhms(sc, dt); 485 1.15 matt dsrtc_clock_read_ymdhms(sc, &check); 486 1.7 gdamore } while (memcmp(dt, &check, sizeof(check)) != 0 && --retries); 487 1.1 thorpej 488 1.14 phx return 0; 489 1.1 thorpej } 490 1.1 thorpej 491 1.1 thorpej static int 492 1.15 matt dsrtc_settime_ymdhms(struct todr_chip_handle *ch, struct clock_ymdhms *dt) 493 1.1 thorpej { 494 1.1 thorpej struct dsrtc_softc *sc = ch->cookie; 495 1.1 thorpej 496 1.15 matt if (dsrtc_clock_write_ymdhms(sc, dt) == 0) 497 1.14 phx return -1; 498 1.1 thorpej 499 1.14 phx return 0; 500 1.1 thorpej } 501 1.1 thorpej 502 1.1 thorpej static int 503 1.15 matt dsrtc_clock_read_ymdhms(struct dsrtc_softc *sc, struct clock_ymdhms *dt) 504 1.1 thorpej { 505 1.15 matt struct dsrtc_model * const dm = &sc->sc_model; 506 1.15 matt uint8_t bcd[DSXXXX_RTC_SIZE], cmdbuf[1]; 507 1.16 matt int error; 508 1.15 matt 509 1.15 matt KASSERT(DSXXXX_RTC_SIZE >= dm->dm_rtc_size); 510 1.1 thorpej 511 1.16 matt if ((error = iic_acquire_bus(sc->sc_tag, I2C_F_POLL)) != 0) { 512 1.11 xtraeme aprint_error_dev(sc->sc_dev, 513 1.16 matt "%s: failed to acquire I2C bus: %d\n", 514 1.16 matt __func__, error); 515 1.14 phx return 0; 516 1.1 thorpej } 517 1.1 thorpej 518 1.1 thorpej /* Read each RTC register in order. */ 519 1.16 matt for (u_int i = 0; !error && i < dm->dm_rtc_size; i++) { 520 1.15 matt cmdbuf[0] = dm->dm_rtc_start + i; 521 1.1 thorpej 522 1.16 matt error = iic_exec(sc->sc_tag, I2C_OP_READ_WITH_STOP, 523 1.16 matt sc->sc_address, cmdbuf, 1, &bcd[i], 1, I2C_F_POLL); 524 1.1 thorpej } 525 1.1 thorpej 526 1.1 thorpej /* Done with I2C */ 527 1.1 thorpej iic_release_bus(sc->sc_tag, I2C_F_POLL); 528 1.1 thorpej 529 1.16 matt if (error != 0) { 530 1.16 matt aprint_error_dev(sc->sc_dev, 531 1.16 matt "%s: failed to read rtc at 0x%x: %d\n", 532 1.16 matt __func__, cmdbuf[0], error); 533 1.16 matt return 0; 534 1.16 matt } 535 1.16 matt 536 1.1 thorpej /* 537 1.15 matt * Convert the RTC's register values into something useable 538 1.1 thorpej */ 539 1.21 christos dt->dt_sec = bcdtobin(bcd[DSXXXX_SECONDS] & DSXXXX_SECONDS_MASK); 540 1.21 christos dt->dt_min = bcdtobin(bcd[DSXXXX_MINUTES] & DSXXXX_MINUTES_MASK); 541 1.1 thorpej 542 1.15 matt if ((bcd[DSXXXX_HOURS] & DSXXXX_HOURS_12HRS_MODE) != 0) { 543 1.21 christos dt->dt_hour = bcdtobin(bcd[DSXXXX_HOURS] & 544 1.15 matt DSXXXX_HOURS_12MASK) % 12; /* 12AM -> 0, 12PM -> 12 */ 545 1.15 matt if (bcd[DSXXXX_HOURS] & DSXXXX_HOURS_12HRS_PM) 546 1.1 thorpej dt->dt_hour += 12; 547 1.14 phx } else 548 1.21 christos dt->dt_hour = bcdtobin(bcd[DSXXXX_HOURS] & 549 1.15 matt DSXXXX_HOURS_24MASK); 550 1.1 thorpej 551 1.21 christos dt->dt_day = bcdtobin(bcd[DSXXXX_DATE] & DSXXXX_DATE_MASK); 552 1.21 christos dt->dt_mon = bcdtobin(bcd[DSXXXX_MONTH] & DSXXXX_MONTH_MASK); 553 1.1 thorpej 554 1.1 thorpej /* XXX: Should be an MD way to specify EPOCH used by BIOS/Firmware */ 555 1.24 aymeric if (sc->sc_model.dm_flags & DSRTC_FLAG_YEAR_START_2K) 556 1.24 aymeric dt->dt_year = bcdtobin(bcd[DSXXXX_YEAR]) + 2000; 557 1.24 aymeric else { 558 1.24 aymeric dt->dt_year = bcdtobin(bcd[DSXXXX_YEAR]) + POSIX_BASE_YEAR; 559 1.24 aymeric if (bcd[DSXXXX_MONTH] & DSXXXX_MONTH_CENTURY) 560 1.24 aymeric dt->dt_year += 100; 561 1.24 aymeric } 562 1.1 thorpej 563 1.14 phx return 1; 564 1.1 thorpej } 565 1.1 thorpej 566 1.1 thorpej static int 567 1.15 matt dsrtc_clock_write_ymdhms(struct dsrtc_softc *sc, struct clock_ymdhms *dt) 568 1.1 thorpej { 569 1.15 matt struct dsrtc_model * const dm = &sc->sc_model; 570 1.15 matt uint8_t bcd[DSXXXX_RTC_SIZE], cmdbuf[2]; 571 1.16 matt int error; 572 1.15 matt 573 1.15 matt KASSERT(DSXXXX_RTC_SIZE >= dm->dm_rtc_size); 574 1.1 thorpej 575 1.1 thorpej /* 576 1.15 matt * Convert our time representation into something the DSXXXX 577 1.1 thorpej * can understand. 578 1.1 thorpej */ 579 1.21 christos bcd[DSXXXX_SECONDS] = bintobcd(dt->dt_sec); 580 1.21 christos bcd[DSXXXX_MINUTES] = bintobcd(dt->dt_min); 581 1.21 christos bcd[DSXXXX_HOURS] = bintobcd(dt->dt_hour); /* DSXXXX_HOURS_12HRS_MODE=0 */ 582 1.21 christos bcd[DSXXXX_DATE] = bintobcd(dt->dt_day); 583 1.21 christos bcd[DSXXXX_DAY] = bintobcd(dt->dt_wday); 584 1.21 christos bcd[DSXXXX_MONTH] = bintobcd(dt->dt_mon); 585 1.21 christos bcd[DSXXXX_YEAR] = bintobcd((dt->dt_year - POSIX_BASE_YEAR) % 100); 586 1.15 matt if (dt->dt_year - POSIX_BASE_YEAR >= 100) 587 1.15 matt bcd[DSXXXX_MONTH] |= DSXXXX_MONTH_CENTURY; 588 1.1 thorpej 589 1.16 matt if ((error = iic_acquire_bus(sc->sc_tag, I2C_F_POLL)) != 0) { 590 1.11 xtraeme aprint_error_dev(sc->sc_dev, 591 1.16 matt "%s: failed to acquire I2C bus: %d\n", 592 1.16 matt __func__, error); 593 1.14 phx return 0; 594 1.1 thorpej } 595 1.1 thorpej 596 1.1 thorpej /* Stop the clock */ 597 1.15 matt cmdbuf[0] = dm->dm_ch_reg; 598 1.15 matt 599 1.16 matt if ((error = iic_exec(sc->sc_tag, I2C_OP_READ, sc->sc_address, 600 1.16 matt cmdbuf, 1, &cmdbuf[1], 1, I2C_F_POLL)) != 0) { 601 1.15 matt iic_release_bus(sc->sc_tag, I2C_F_POLL); 602 1.15 matt aprint_error_dev(sc->sc_dev, 603 1.16 matt "%s: failed to read Hold Clock: %d\n", 604 1.16 matt __func__, error); 605 1.15 matt return 0; 606 1.15 matt } 607 1.15 matt 608 1.24 aymeric if (sc->sc_model.dm_flags & DSRTC_FLAG_CLOCK_HOLD_REVERSED) 609 1.24 aymeric cmdbuf[1] &= ~dm->dm_ch_value; 610 1.24 aymeric else 611 1.24 aymeric cmdbuf[1] |= dm->dm_ch_value; 612 1.1 thorpej 613 1.16 matt if ((error = iic_exec(sc->sc_tag, I2C_OP_WRITE, sc->sc_address, 614 1.16 matt cmdbuf, 1, &cmdbuf[1], 1, I2C_F_POLL)) != 0) { 615 1.1 thorpej iic_release_bus(sc->sc_tag, I2C_F_POLL); 616 1.11 xtraeme aprint_error_dev(sc->sc_dev, 617 1.16 matt "%s: failed to write Hold Clock: %d\n", 618 1.16 matt __func__, error); 619 1.14 phx return 0; 620 1.1 thorpej } 621 1.1 thorpej 622 1.1 thorpej /* 623 1.1 thorpej * Write registers in reverse order. The last write (to the Seconds 624 1.1 thorpej * register) will undo the Clock Hold, above. 625 1.1 thorpej */ 626 1.15 matt uint8_t op = I2C_OP_WRITE; 627 1.15 matt for (signed int i = dm->dm_rtc_size - 1; i >= 0; i--) { 628 1.15 matt cmdbuf[0] = dm->dm_rtc_start + i; 629 1.24 aymeric if ((dm->dm_flags & DSRTC_FLAG_VBATEN) && 630 1.24 aymeric dm->dm_rtc_start + i == dm->dm_vbaten_reg) 631 1.24 aymeric bcd[i] |= dm->dm_vbaten_value; 632 1.15 matt if (dm->dm_rtc_start + i == dm->dm_ch_reg) { 633 1.15 matt op = I2C_OP_WRITE_WITH_STOP; 634 1.24 aymeric if (dm->dm_flags & DSRTC_FLAG_CLOCK_HOLD_REVERSED) 635 1.24 aymeric bcd[i] |= dm->dm_ch_value; 636 1.15 matt } 637 1.16 matt if ((error = iic_exec(sc->sc_tag, op, sc->sc_address, 638 1.16 matt cmdbuf, 1, &bcd[i], 1, I2C_F_POLL)) != 0) { 639 1.1 thorpej iic_release_bus(sc->sc_tag, I2C_F_POLL); 640 1.11 xtraeme aprint_error_dev(sc->sc_dev, 641 1.16 matt "%s: failed to write rtc at 0x%x: %d\n", 642 1.16 matt __func__, i, error); 643 1.1 thorpej /* XXX: Clock Hold is likely still asserted! */ 644 1.14 phx return 0; 645 1.1 thorpej } 646 1.1 thorpej } 647 1.15 matt /* 648 1.15 matt * If the clock hold register isn't the same register as seconds, 649 1.15 matt * we need to reeanble the clock. 650 1.15 matt */ 651 1.15 matt if (op != I2C_OP_WRITE_WITH_STOP) { 652 1.15 matt cmdbuf[0] = dm->dm_ch_reg; 653 1.24 aymeric if (dm->dm_flags & DSRTC_FLAG_CLOCK_HOLD_REVERSED) 654 1.24 aymeric cmdbuf[1] |= dm->dm_ch_value; 655 1.24 aymeric else 656 1.24 aymeric cmdbuf[1] &= ~dm->dm_ch_value; 657 1.15 matt 658 1.16 matt if ((error = iic_exec(sc->sc_tag, I2C_OP_WRITE_WITH_STOP, 659 1.16 matt sc->sc_address, cmdbuf, 1, &cmdbuf[1], 1, 660 1.16 matt I2C_F_POLL)) != 0) { 661 1.15 matt iic_release_bus(sc->sc_tag, I2C_F_POLL); 662 1.15 matt aprint_error_dev(sc->sc_dev, 663 1.16 matt "%s: failed to Hold Clock: %d\n", 664 1.16 matt __func__, error); 665 1.15 matt return 0; 666 1.15 matt } 667 1.15 matt } 668 1.1 thorpej 669 1.1 thorpej iic_release_bus(sc->sc_tag, I2C_F_POLL); 670 1.1 thorpej 671 1.14 phx return 1; 672 1.1 thorpej } 673 1.15 matt 674 1.15 matt static int 675 1.15 matt dsrtc_gettime_timeval(struct todr_chip_handle *ch, struct timeval *tv) 676 1.15 matt { 677 1.15 matt struct dsrtc_softc *sc = ch->cookie; 678 1.15 matt struct timeval check; 679 1.15 matt int retries; 680 1.15 matt 681 1.15 matt memset(tv, 0, sizeof(*tv)); 682 1.15 matt memset(&check, 0, sizeof(check)); 683 1.15 matt 684 1.15 matt /* 685 1.15 matt * Since we don't support Burst Read, we have to read the clock twice 686 1.15 matt * until we get two consecutive identical results. 687 1.15 matt */ 688 1.15 matt retries = 5; 689 1.15 matt do { 690 1.15 matt dsrtc_clock_read_timeval(sc, &tv->tv_sec); 691 1.15 matt dsrtc_clock_read_timeval(sc, &check.tv_sec); 692 1.15 matt } while (memcmp(tv, &check, sizeof(check)) != 0 && --retries); 693 1.15 matt 694 1.15 matt return 0; 695 1.15 matt } 696 1.15 matt 697 1.15 matt static int 698 1.15 matt dsrtc_settime_timeval(struct todr_chip_handle *ch, struct timeval *tv) 699 1.15 matt { 700 1.15 matt struct dsrtc_softc *sc = ch->cookie; 701 1.15 matt 702 1.15 matt if (dsrtc_clock_write_timeval(sc, tv->tv_sec) == 0) 703 1.15 matt return -1; 704 1.15 matt 705 1.15 matt return 0; 706 1.15 matt } 707 1.15 matt 708 1.15 matt /* 709 1.15 matt * The RTC probably has a nice Clock Burst Read/Write command, but we can't use 710 1.15 matt * it, since some I2C controllers don't support anything other than single-byte 711 1.15 matt * transfers. 712 1.15 matt */ 713 1.15 matt static int 714 1.15 matt dsrtc_clock_read_timeval(struct dsrtc_softc *sc, time_t *tp) 715 1.15 matt { 716 1.15 matt const struct dsrtc_model * const dm = &sc->sc_model; 717 1.15 matt uint8_t buf[4]; 718 1.16 matt int error; 719 1.15 matt 720 1.16 matt if ((error = iic_acquire_bus(sc->sc_tag, I2C_F_POLL)) != 0) { 721 1.16 matt aprint_error_dev(sc->sc_dev, 722 1.16 matt "%s: failed to acquire I2C bus: %d\n", 723 1.16 matt __func__, error); 724 1.16 matt return 0; 725 1.15 matt } 726 1.15 matt 727 1.15 matt /* read all registers: */ 728 1.15 matt uint8_t reg = dm->dm_rtc_start; 729 1.16 matt error = iic_exec(sc->sc_tag, I2C_OP_READ_WITH_STOP, sc->sc_address, 730 1.16 matt ®, 1, buf, 4, I2C_F_POLL); 731 1.15 matt 732 1.15 matt /* Done with I2C */ 733 1.15 matt iic_release_bus(sc->sc_tag, I2C_F_POLL); 734 1.15 matt 735 1.16 matt if (error != 0) { 736 1.16 matt aprint_error_dev(sc->sc_dev, 737 1.16 matt "%s: failed to read rtc at 0x%x: %d\n", 738 1.16 matt __func__, reg, error); 739 1.16 matt return 0; 740 1.16 matt } 741 1.16 matt 742 1.15 matt uint32_t v = (buf[3] << 24) | (buf[2] << 16) | (buf[1] << 8) | buf[0]; 743 1.15 matt *tp = v; 744 1.15 matt 745 1.15 matt aprint_debug_dev(sc->sc_dev, "%s: cntr=0x%08"PRIx32"\n", 746 1.15 matt __func__, v); 747 1.15 matt 748 1.16 matt return 1; 749 1.15 matt } 750 1.15 matt 751 1.15 matt static int 752 1.15 matt dsrtc_clock_write_timeval(struct dsrtc_softc *sc, time_t t) 753 1.15 matt { 754 1.15 matt const struct dsrtc_model * const dm = &sc->sc_model; 755 1.15 matt size_t buflen = dm->dm_rtc_size + 2; 756 1.15 matt uint8_t buf[buflen]; 757 1.16 matt int error; 758 1.15 matt 759 1.15 matt KASSERT((dm->dm_flags & DSRTC_FLAG_CLOCK_HOLD) == 0); 760 1.15 matt KASSERT(dm->dm_ch_reg == dm->dm_rtc_start + 4); 761 1.15 matt 762 1.15 matt buf[0] = dm->dm_rtc_start; 763 1.15 matt buf[1] = (t >> 0) & 0xff; 764 1.15 matt buf[2] = (t >> 8) & 0xff; 765 1.15 matt buf[3] = (t >> 16) & 0xff; 766 1.15 matt buf[4] = (t >> 24) & 0xff; 767 1.15 matt buf[5] = 0; 768 1.15 matt 769 1.16 matt if ((error = iic_acquire_bus(sc->sc_tag, I2C_F_POLL)) != 0) { 770 1.16 matt aprint_error_dev(sc->sc_dev, 771 1.16 matt "%s: failed to acquire I2C bus: %d\n", 772 1.16 matt __func__, error); 773 1.16 matt return 0; 774 1.15 matt } 775 1.15 matt 776 1.16 matt error = iic_exec(sc->sc_tag, I2C_OP_WRITE_WITH_STOP, sc->sc_address, 777 1.16 matt &buf, buflen, NULL, 0, I2C_F_POLL); 778 1.16 matt 779 1.16 matt /* Done with I2C */ 780 1.16 matt iic_release_bus(sc->sc_tag, I2C_F_POLL); 781 1.16 matt 782 1.15 matt /* send data */ 783 1.16 matt if (error != 0) { 784 1.16 matt aprint_error_dev(sc->sc_dev, 785 1.16 matt "%s: failed to set time: %d\n", 786 1.16 matt __func__, error); 787 1.16 matt return 0; 788 1.15 matt } 789 1.15 matt 790 1.16 matt return 1; 791 1.15 matt } 792 1.19 macallan 793 1.19 macallan static int 794 1.19 macallan dsrtc_read_temp(struct dsrtc_softc *sc, uint32_t *temp) 795 1.19 macallan { 796 1.19 macallan int error, tc; 797 1.19 macallan uint8_t reg = DS3232_TEMP_MSB; 798 1.19 macallan uint8_t buf[2]; 799 1.19 macallan 800 1.19 macallan if ((sc->sc_model.dm_flags & DSRTC_FLAG_TEMP) == 0) 801 1.19 macallan return ENOTSUP; 802 1.19 macallan 803 1.19 macallan if ((error = iic_acquire_bus(sc->sc_tag, I2C_F_POLL)) != 0) { 804 1.19 macallan aprint_error_dev(sc->sc_dev, 805 1.19 macallan "%s: failed to acquire I2C bus: %d\n", 806 1.19 macallan __func__, error); 807 1.19 macallan return 0; 808 1.19 macallan } 809 1.19 macallan 810 1.19 macallan /* read temperature registers: */ 811 1.19 macallan error = iic_exec(sc->sc_tag, I2C_OP_READ_WITH_STOP, sc->sc_address, 812 1.19 macallan ®, 1, buf, 2, I2C_F_POLL); 813 1.19 macallan 814 1.19 macallan /* Done with I2C */ 815 1.19 macallan iic_release_bus(sc->sc_tag, I2C_F_POLL); 816 1.19 macallan 817 1.19 macallan if (error != 0) { 818 1.19 macallan aprint_error_dev(sc->sc_dev, 819 1.19 macallan "%s: failed to read temperature: %d\n", 820 1.19 macallan __func__, error); 821 1.19 macallan return 0; 822 1.19 macallan } 823 1.19 macallan 824 1.19 macallan /* convert to microkelvin */ 825 1.19 macallan tc = buf[0] * 1000000 + (buf[1] >> 6) * 250000; 826 1.19 macallan *temp = tc + 273150000; 827 1.19 macallan return 1; 828 1.19 macallan } 829 1.19 macallan 830 1.19 macallan static void 831 1.19 macallan dsrtc_refresh(struct sysmon_envsys *sme, envsys_data_t *edata) 832 1.19 macallan { 833 1.19 macallan struct dsrtc_softc *sc = sme->sme_cookie; 834 1.20 martin uint32_t temp = 0; /* XXX gcc */ 835 1.19 macallan 836 1.19 macallan if (dsrtc_read_temp(sc, &temp) == 0) { 837 1.19 macallan edata->state = ENVSYS_SINVALID; 838 1.19 macallan return; 839 1.19 macallan } 840 1.19 macallan 841 1.19 macallan edata->value_cur = temp; 842 1.19 macallan 843 1.19 macallan edata->state = ENVSYS_SVALID; 844 1.19 macallan } 845
Indexes created Thu Oct 02 14:10:14 GMT 2025