/* $OpenBSD: uthum.c,v 1.26 2014/03/19 08:59:37 mpi Exp $ */ /* * Copyright (c) 2009, 2010 Yojiro UO * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ /* Driver for HID base TEMPer seriese Temperature(/Humidity) sensors */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef UTHUM_DEBUG #define DPRINTF(x) do { printf x; } while (0) #else #define DPRINTF(x) #endif /* Device types */ #define UTHUM_TYPE_TEMPERHUM 0x535a #define UTHUM_TYPE_TEMPERHUM_2 0x575a /* alternative TEMPerHUM */ #define UTHUM_TYPE_TEMPER1 0x5758 /* TEMPer1 and HID TEMPer */ #define UTHUM_TYPE_TEMPER2 0x5759 #define UTHUM_TYPE_TEMPERNTC 0x575b #define UTHUM_TYPE_UNKNOWN 0xffff /* Common */ #define UTHUM_CAL_OFFSET 0x14 #define UTHUM_MAX_SENSORS 2 #define CMD_DEVTYPE 0x52 #define DEVTYPE_EOF 0x53 /* query commands */ #define CMD_GETDATA_NTC 0x41 /* TEMPerNTC NTC part */ #define CMD_RESET0 0x43 /* TEMPer, TEMPer[12], TEMPerNTC */ #define CMD_RESET1 0x44 /* TEMPer, TEMPer[12] */ #define CMD_GETDATA 0x48 /* TEMPerHUM */ #define CMD_GETDATA_OUTER 0x53 /* TEMPer, TEMPer[12], TEMPerNTC */ #define CMD_GETDATA_INNER 0x54 /* TEMPer, TEMPer[12], TEMPerNTC */ #define CMD_GETDATA_EOF 0x31 #define CMD_GETDATA_EOF2 0xaa /* temperntc mode */ #define TEMPERNTC_MODE_BASE 0x61 /* 0x61 - 0x68 */ #define TEMPERNTC_MODE_MAX 0x68 #define CMD_TEMPERNTC_MODE_DONE 0x69 #define UTHUM_NTC_MIN_THRESHOLD 0xb300 #define UTHUM_NTC_MAX_THRESHOLD 0xf200 /* sensor name */ #define UTHUM_TEMPER_INNER 0 #define UTHUM_TEMPER_OUTER 1 #define UTHUM_TEMPER_NTC 1 #define UTHUM_TEMPERHUM_TEMP 0 #define UTHUM_TEMPERHUM_HUM 1 enum uthum_sensor_type { UTHUM_SENSOR_UNKNOWN, UTHUM_SENSOR_SHT1X, UTHUM_SENSOR_DS75, UTHUM_SENSOR_NTC, UTHUM_SENSOR_MAXTYPES, }; static const char * const uthum_sensor_type_s[UTHUM_SENSOR_MAXTYPES] = { "unknown", "sht1x", "ds75/12bit", "NTC" }; static uint8_t cmd_issue[8] = { 0x0a, 0x0b, 0x0c, 0x0d, 0x00, 0x00, 0x02, 0x00 }; static uint8_t cmd_query[8] = { 0x0a, 0x0b, 0x0c, 0x0d, 0x00, 0x00, 0x01, 0x00 }; struct uthum_sensor { struct ksensor sensor; int cal_offset; /* mC or m%RH */ int attached; enum uthum_sensor_type dev_type; int cur_state; /* for TEMPerNTC */ }; struct uthum_softc { struct uhidev sc_hdev; struct usbd_device *sc_udev; int sc_device_type; int sc_num_sensors; /* uhidev parameters */ size_t sc_flen; /* feature report length */ size_t sc_ilen; /* input report length */ size_t sc_olen; /* output report length */ /* sensor framework */ struct uthum_sensor sc_sensor[UTHUM_MAX_SENSORS]; struct ksensordev sc_sensordev; struct sensor_task *sc_sensortask; }; const struct usb_devno uthum_devs[] = { /* XXX: various TEMPer variants are using same VID/PID */ { USB_VENDOR_TENX, USB_PRODUCT_TENX_TEMPER}, }; #define uthum_lookup(v, p) usb_lookup(uthum_devs, v, p) int uthum_match(struct device *, void *, void *); void uthum_attach(struct device *, struct device *, void *); int uthum_detach(struct device *, int); int uthum_issue_cmd(struct uthum_softc *, uint8_t, int); int uthum_read_data(struct uthum_softc *, uint8_t, uint8_t *, size_t, int); int uthum_check_device_info(struct uthum_softc *); void uthum_reset_device(struct uthum_softc *); void uthum_setup_sensors(struct uthum_softc *); void uthum_intr(struct uhidev *, void *, u_int); void uthum_refresh(void *); void uthum_refresh_temper(struct uthum_softc *, int); void uthum_refresh_temperhum(struct uthum_softc *); void uthum_refresh_temperntc(struct uthum_softc *, int); int uthum_ntc_getdata(struct uthum_softc *, int *); int uthum_ntc_tuning(struct uthum_softc *, int, int *); int64_t uthum_ntc_temp(int64_t, int); int uthum_sht1x_temp(uint8_t, uint8_t); int uthum_sht1x_rh(uint8_t, uint8_t, int); int uthum_ds75_temp(uint8_t, uint8_t); void uthum_print_sensorinfo(struct uthum_softc *, int); struct cfdriver uthum_cd = { NULL, "uthum", DV_DULL }; const struct cfattach uthum_ca = { sizeof(struct uthum_softc), uthum_match, uthum_attach, uthum_detach }; int uthum_match(struct device *parent, void *match, void *aux) { struct uhidev_attach_arg *uha = aux; if (uha->reportid == UHIDEV_CLAIM_ALLREPORTID) return (UMATCH_NONE); if (uthum_lookup(uha->uaa->vendor, uha->uaa->product) == NULL) return UMATCH_NONE; #if 0 /* attach only sensor part of HID as uthum* */ #define HUG_UNKNOWN_3 0x0003 void *desc; int size; uhidev_get_report_desc(uha->parent, &desc, &size); if (!hid_is_collection(desc, size, uha->reportid, HID_USAGE2(HUP_GENERIC_DESKTOP, HUG_UNKNOWN_3))) return (UMATCH_NONE); #undef HUG_UNKNOWN_3 #endif return (UMATCH_VENDOR_PRODUCT); } void uthum_attach(struct device *parent, struct device *self, void *aux) { struct uthum_softc *sc = (struct uthum_softc *)self; struct usb_attach_arg *uaa = aux; struct uhidev_attach_arg *uha = (struct uhidev_attach_arg *)uaa; struct usbd_device *dev = uha->parent->sc_udev; int i, size, repid; void *desc; sc->sc_udev = dev; sc->sc_hdev.sc_intr = uthum_intr; sc->sc_hdev.sc_parent = uha->parent; sc->sc_hdev.sc_report_id = uha->reportid; sc->sc_num_sensors = 0; uhidev_get_report_desc(uha->parent, &desc, &size); repid = uha->reportid; sc->sc_ilen = hid_report_size(desc, size, hid_input, repid); sc->sc_olen = hid_report_size(desc, size, hid_output, repid); sc->sc_flen = hid_report_size(desc, size, hid_feature, repid); printf("\n"); if (sc->sc_flen < 32) { /* not sensor interface, just attach */ return; } /* maybe unsupported device */ if (uthum_check_device_info(sc) < 0) { DPRINTF(("uthum: unknown device\n")); return; }; /* attach sensor */ strlcpy(sc->sc_sensordev.xname, sc->sc_hdev.sc_dev.dv_xname, sizeof(sc->sc_sensordev.xname)); uthum_setup_sensors(sc); /* attach sensors */ for (i = 0; i < UTHUM_MAX_SENSORS; i++) { if (sc->sc_sensor[i].dev_type == UTHUM_SENSOR_UNKNOWN) continue; uthum_print_sensorinfo(sc, i); sc->sc_sensor[i].sensor.flags |= SENSOR_FINVALID; sensor_attach(&sc->sc_sensordev, &sc->sc_sensor[i].sensor); sc->sc_sensor[i].attached = 1; sc->sc_num_sensors++; } if (sc->sc_num_sensors > 0) { /* 0.1Hz */ sc->sc_sensortask = sensor_task_register(sc, uthum_refresh, 6); if (sc->sc_sensortask == NULL) { printf(", unable to register update task\n"); return; } sensordev_install(&sc->sc_sensordev); } DPRINTF(("uthum_attach: complete\n")); } int uthum_detach(struct device *self, int flags) { struct uthum_softc *sc = (struct uthum_softc *)self; int i, rv = 0; if (sc->sc_num_sensors > 0) { wakeup(&sc->sc_sensortask); sensordev_deinstall(&sc->sc_sensordev); for (i = 0; i < UTHUM_MAX_SENSORS; i++) { if (sc->sc_sensor[i].attached) sensor_detach(&sc->sc_sensordev, &sc->sc_sensor[i].sensor); } if (sc->sc_sensortask != NULL) sensor_task_unregister(sc->sc_sensortask); } uthum_reset_device(sc); return (rv); } void uthum_intr(struct uhidev *addr, void *ibuf, u_int len) { /* do nothing */ } int uthum_issue_cmd(struct uthum_softc *sc, uint8_t target_cmd, int delay) { int i; uint8_t cmdbuf[32]; bzero(cmdbuf, sizeof(cmdbuf)); memcpy(cmdbuf, cmd_issue, sizeof(cmd_issue)); if (uhidev_set_report(&sc->sc_hdev, UHID_OUTPUT_REPORT, cmdbuf, sc->sc_olen)) return EIO; bzero(cmdbuf, sizeof(cmdbuf)); cmdbuf[0] = target_cmd; if (uhidev_set_report(&sc->sc_hdev, UHID_OUTPUT_REPORT, cmdbuf, sc->sc_olen)) return EIO; bzero(cmdbuf, sizeof(cmdbuf)); for (i = 0; i < 7; i++) { if (uhidev_set_report(&sc->sc_hdev, UHID_OUTPUT_REPORT, cmdbuf, sc->sc_olen)) return EIO; } /* wait if required */ if (delay > 0) tsleep(&sc->sc_sensortask, 0, "uthum", (delay*hz+999)/1000 + 1); return 0; } int uthum_read_data(struct uthum_softc *sc, uint8_t target_cmd, uint8_t *buf, size_t len, int delay) { uint8_t cmdbuf[32], report[256]; /* if return buffer is null, do nothing */ if ((buf == NULL) || len == 0) return 0; if (uthum_issue_cmd(sc, target_cmd, 50)) return 0; bzero(cmdbuf, sizeof(cmdbuf)); memcpy(cmdbuf, cmd_query, sizeof(cmd_query)); if (uhidev_set_report(&sc->sc_hdev, UHID_OUTPUT_REPORT, cmdbuf, sc->sc_olen)) return EIO; /* wait if required */ if (delay > 0) tsleep(&sc->sc_sensortask, 0, "uthum", (delay*hz+999)/1000 + 1); /* get answer */ if (uhidev_get_report(&sc->sc_hdev, UHID_FEATURE_REPORT, report, sc->sc_flen)) return EIO; memcpy(buf, report, len); return 0; } int uthum_check_device_info(struct uthum_softc *sc) { struct uthum_dev_info { uint16_t dev_type; uint8_t cal[2][2]; /* calibration offsets */ uint8_t footer; uint8_t padding[25]; } dinfo; int val, dev_type; int retry = 3; /* issue query to device */ while (retry) { if (uthum_read_data(sc, CMD_DEVTYPE, (void *)&dinfo, sizeof(struct uthum_dev_info), 0) != 0) { DPRINTF(("uthum: device information query fail.\n")); retry--; continue; } if (dinfo.footer != DEVTYPE_EOF) { /* it will be a bogus entry, retry. */ retry--; } else break; } if (retry <= 0) return EIO; dev_type = betoh16(dinfo.dev_type); /* TEMPerHUM has 2 different device identifiers, unify them */ if (dev_type == UTHUM_TYPE_TEMPERHUM_2) dev_type = UTHUM_TYPE_TEMPERHUM; /* check device type and calibration offset*/ switch (dev_type) { case UTHUM_TYPE_TEMPER2: case UTHUM_TYPE_TEMPERHUM: case UTHUM_TYPE_TEMPERNTC: val = (dinfo.cal[1][0] - UTHUM_CAL_OFFSET) * 100; val += dinfo.cal[1][1] * 10; sc->sc_sensor[1].cal_offset = val; /* fall down, don't break */ case UTHUM_TYPE_TEMPER1: val = (dinfo.cal[0][0] - UTHUM_CAL_OFFSET) * 100; val += dinfo.cal[0][1] * 10; sc->sc_sensor[0].cal_offset = val; sc->sc_device_type = dev_type; break; default: sc->sc_device_type = UTHUM_TYPE_UNKNOWN; printf("uthum: unknown device (devtype = 0x%.2x)\n", dev_type); return EIO; } /* device specific init process */ switch (dev_type) { case UTHUM_TYPE_TEMPERHUM: sc->sc_sensor[UTHUM_TEMPER_NTC].cur_state = 0; break; }; uthum_reset_device(sc); return 0; }; void uthum_reset_device(struct uthum_softc *sc) { switch (sc->sc_device_type) { case UTHUM_TYPE_TEMPER1: case UTHUM_TYPE_TEMPERNTC: uthum_issue_cmd(sc, CMD_RESET0, 200); break; case UTHUM_TYPE_TEMPER2: uthum_issue_cmd(sc, CMD_RESET0, 200); uthum_issue_cmd(sc, CMD_RESET1, 200); break; } } void uthum_setup_sensors(struct uthum_softc *sc) { int i; for (i = 0; i < UTHUM_MAX_SENSORS; i++) sc->sc_sensor[i].dev_type = UTHUM_SENSOR_UNKNOWN; switch (sc->sc_device_type) { case UTHUM_TYPE_TEMPER2: /* 2 temperature sensors */ sc->sc_sensor[UTHUM_TEMPER_OUTER].dev_type = UTHUM_SENSOR_DS75; sc->sc_sensor[UTHUM_TEMPER_OUTER].sensor.type = SENSOR_TEMP; strlcpy(sc->sc_sensor[UTHUM_TEMPER_OUTER].sensor.desc, "outer", sizeof(sc->sc_sensor[UTHUM_TEMPER_OUTER].sensor.desc)); /* fall down */ case UTHUM_TYPE_TEMPER1: /* 1 temperature sensor */ sc->sc_sensor[UTHUM_TEMPER_INNER].dev_type = UTHUM_SENSOR_DS75; sc->sc_sensor[UTHUM_TEMPER_INNER].sensor.type = SENSOR_TEMP; strlcpy(sc->sc_sensor[UTHUM_TEMPER_INNER].sensor.desc, "inner", sizeof(sc->sc_sensor[UTHUM_TEMPER_INNER].sensor.desc)); break; case UTHUM_TYPE_TEMPERHUM: /* 1 temperature sensor and 1 humidity sensor */ for (i = 0; i < 2; i++) sc->sc_sensor[i].dev_type = UTHUM_SENSOR_SHT1X; sc->sc_sensor[UTHUM_TEMPERHUM_TEMP].sensor.type = SENSOR_TEMP; sc->sc_sensor[UTHUM_TEMPERHUM_HUM].sensor.type = SENSOR_HUMIDITY; strlcpy(sc->sc_sensor[UTHUM_TEMPERHUM_HUM].sensor.desc, "RH", sizeof(sc->sc_sensor[UTHUM_TEMPERHUM_HUM].sensor.desc)); break; case UTHUM_TYPE_TEMPERNTC: /* 2 temperature sensors */ for (i = 0; i < 2; i++) sc->sc_sensor[i].sensor.type = SENSOR_TEMP; sc->sc_sensor[UTHUM_TEMPER_INNER].dev_type = UTHUM_SENSOR_DS75; sc->sc_sensor[UTHUM_TEMPER_NTC].dev_type = UTHUM_SENSOR_NTC; strlcpy(sc->sc_sensor[UTHUM_TEMPER_INNER].sensor.desc, "inner", sizeof(sc->sc_sensor[UTHUM_TEMPER_INNER].sensor.desc)); strlcpy(sc->sc_sensor[UTHUM_TEMPER_NTC].sensor.desc, "outer/ntc", sizeof(sc->sc_sensor[UTHUM_TEMPER_NTC].sensor.desc)); /* sensor state tuning */ for (i = 0; i < 4; i++) uthum_issue_cmd(sc, TEMPERNTC_MODE_BASE, 50); sc->sc_sensor[UTHUM_TEMPER_NTC].cur_state = TEMPERNTC_MODE_BASE; if (uthum_ntc_tuning(sc, UTHUM_TEMPER_NTC, NULL)) DPRINTF(("uthum: NTC sensor tuning failed\n")); uthum_issue_cmd(sc, CMD_TEMPERNTC_MODE_DONE, 100); break; default: /* do nothing */ break; } } int uthum_ntc_getdata(struct uthum_softc *sc, int *val) { uint8_t buf[8]; if (val == NULL) return EIO; /* get sensor value */ if (uthum_read_data(sc, CMD_GETDATA_NTC, buf, sizeof(buf), 10) != 0) { DPRINTF(("uthum: data read fail\n")); return EIO; } /* check data integrity */ if (buf[2] != CMD_GETDATA_EOF2) { DPRINTF(("uthum: broken ntc data 0x%.2x 0x%.2x 0x%.2x\n", buf[0], buf[1], buf[2])); return EIO; } *val = (buf[0] << 8) + buf[1]; return 0; } int uthum_ntc_tuning(struct uthum_softc *sc, int sensor, int *val) { struct uthum_sensor *s; int done, state, ostate, curval; int retry = 3; s = &sc->sc_sensor[sensor]; state = s->cur_state; /* get current sensor value */ if (val == NULL) { while (retry) { if (uthum_ntc_getdata(sc, &curval)) { retry--; continue; } else break; } if (retry <= 0) return EIO; } else { curval = *val; } /* no state change is required */ if ((curval >= UTHUM_NTC_MIN_THRESHOLD) && (curval <= UTHUM_NTC_MAX_THRESHOLD)) { return 0; } if (((curval < UTHUM_NTC_MIN_THRESHOLD) && (state == TEMPERNTC_MODE_MAX)) || ((curval > UTHUM_NTC_MAX_THRESHOLD) && (state == TEMPERNTC_MODE_BASE))) return 0; DPRINTF(("uthum: ntc tuning start. cur state = 0x%.2x, val = 0x%.4x\n", state, curval)); /* tuning loop */ ostate = state; done = 0; while (!done) { if (curval < UTHUM_NTC_MIN_THRESHOLD) { if (state == TEMPERNTC_MODE_MAX) done++; else state++; } else if (curval > UTHUM_NTC_MAX_THRESHOLD) { if (state == TEMPERNTC_MODE_BASE) done++; else state--; } else { uthum_ntc_getdata(sc, &curval); if ((curval >= UTHUM_NTC_MIN_THRESHOLD) && (curval <= UTHUM_NTC_MAX_THRESHOLD)) done++; } /* update state */ if (state != ostate) { uthum_issue_cmd(sc, state, 50); uthum_issue_cmd(sc, state, 50); uthum_ntc_getdata(sc, &curval); } ostate = state; } DPRINTF(("uthum: ntc tuning done. state change: 0x%.2x->0x%.2x\n", s->cur_state, state)); s->cur_state = state; if (val != NULL) *val = curval; return 0; } void uthum_refresh(void *arg) { struct uthum_softc *sc = arg; int i; switch (sc->sc_device_type) { case UTHUM_TYPE_TEMPER1: case UTHUM_TYPE_TEMPER2: case UTHUM_TYPE_TEMPERNTC: for (i = 0; i < sc->sc_num_sensors; i++) { if (sc->sc_sensor[i].dev_type == UTHUM_SENSOR_DS75) uthum_refresh_temper(sc, i); else if (sc->sc_sensor[i].dev_type == UTHUM_SENSOR_NTC) uthum_refresh_temperntc(sc, i); } break; case UTHUM_TYPE_TEMPERHUM: uthum_refresh_temperhum(sc); break; default: break; /* never reach */ } } void uthum_refresh_temperhum(struct uthum_softc *sc) { uint8_t buf[8]; int temp, rh; if (uthum_read_data(sc, CMD_GETDATA, buf, sizeof(buf), 1000) != 0) { DPRINTF(("uthum: data read fail\n")); sc->sc_sensor[UTHUM_TEMPERHUM_TEMP].sensor.flags |= SENSOR_FINVALID; sc->sc_sensor[UTHUM_TEMPERHUM_HUM].sensor.flags |= SENSOR_FINVALID; return; } temp = uthum_sht1x_temp(buf[0], buf[1]); rh = uthum_sht1x_rh(buf[2], buf[3], temp); /* apply calibration offsets */ temp += sc->sc_sensor[UTHUM_TEMPERHUM_TEMP].cal_offset; rh += sc->sc_sensor[UTHUM_TEMPERHUM_HUM].cal_offset; sc->sc_sensor[UTHUM_TEMPERHUM_TEMP].sensor.value = (temp * 10000) + 273150000; sc->sc_sensor[UTHUM_TEMPERHUM_TEMP].sensor.flags &= ~SENSOR_FINVALID; sc->sc_sensor[UTHUM_TEMPERHUM_HUM].sensor.value = rh; sc->sc_sensor[UTHUM_TEMPERHUM_HUM].sensor.flags &= ~SENSOR_FINVALID; } void uthum_refresh_temper(struct uthum_softc *sc, int sensor) { uint8_t buf[8]; uint8_t cmd; int temp; if (sensor == UTHUM_TEMPER_INNER) cmd = CMD_GETDATA_INNER; else if (sensor == UTHUM_TEMPER_OUTER) cmd = CMD_GETDATA_OUTER; else return; /* get sensor value */ if (uthum_read_data(sc, cmd, buf, sizeof(buf), 1000) != 0) { DPRINTF(("uthum: data read fail\n")); sc->sc_sensor[sensor].sensor.flags |= SENSOR_FINVALID; return; } /* check integrity */ if (buf[2] != CMD_GETDATA_EOF) { DPRINTF(("uthum: broken ds75 data: 0x%.2x 0x%.2x 0x%.2x\n", buf[0], buf[1], buf[2])); sc->sc_sensor[sensor].sensor.flags |= SENSOR_FINVALID; return; } temp = uthum_ds75_temp(buf[0], buf[1]); /* apply calibration offset */ temp += sc->sc_sensor[sensor].cal_offset; sc->sc_sensor[sensor].sensor.value = (temp * 10000) + 273150000; sc->sc_sensor[sensor].sensor.flags &= ~SENSOR_FINVALID; } void uthum_refresh_temperntc(struct uthum_softc *sc, int sensor) { int val; int64_t temp; /* get sensor data */ if (uthum_ntc_getdata(sc, &val)) { DPRINTF(("uthum: ntc data read fail\n")); sc->sc_sensor[sensor].sensor.flags |= SENSOR_FINVALID; return; } /* adjust sensor state */ if ((val < UTHUM_NTC_MIN_THRESHOLD) || (val > UTHUM_NTC_MAX_THRESHOLD)) { if (uthum_ntc_tuning(sc, UTHUM_TEMPER_NTC, &val)) { DPRINTF(("uthum: NTC sensor tuning failed\n")); sc->sc_sensor[sensor].sensor.flags |= SENSOR_FINVALID; return; } } temp = uthum_ntc_temp(val, sc->sc_sensor[sensor].cur_state); if (temp == 0) { /* XXX: work around. */ sc->sc_sensor[sensor].sensor.flags |= SENSOR_FINVALID; } else { /* apply calibration offset */ temp += sc->sc_sensor[sensor].cal_offset * 10000; sc->sc_sensor[sensor].sensor.value = temp; sc->sc_sensor[sensor].sensor.flags &= ~SENSOR_FINVALID; } } /* return C-degree * 100 value */ int uthum_ds75_temp(uint8_t msb, uint8_t lsb) { /* DS75: 12bit precision mode : 0.0625 degrees Celsius ticks */ return (msb * 100) + ((lsb >> 4) * 25 / 4); } /* return C-degree * 100 value */ int uthum_sht1x_temp(uint8_t msb, uint8_t lsb) { int ticks; /* sensor device VDD-bias value table * ---------------------------------------------- * VDD 2.5V 3.0V 3.5V 4.0V 5.0V * bias -3940 -3960 -3970 -3980 -4010 * ---------------------------------------------- * * as the VDD of the SHT10 on my TEMPerHUM is 3.43V +/- 0.05V, * bias -3970 will be best for that device. */ ticks = (msb * 256 + lsb) & 0x3fff; return (ticks - 3970); } /* return %RH * 1000 */ int uthum_sht1x_rh(uint8_t msb, uint8_t lsb, int temp) { int ticks, rh_l; ticks = (msb * 256 + lsb) & 0x0fff; rh_l = (-40000 + 405 * ticks) - ((7 * ticks * ticks) / 250); return ((temp - 2500) * (1 + (ticks >> 7)) + rh_l) / 10; } /* return muK */ int64_t uthum_ntc_temp(int64_t val, int state) { int64_t temp = 0; switch (state) { case TEMPERNTC_MODE_BASE: /* 0x61 */ case TEMPERNTC_MODE_BASE+1: /* 0x62 */ case TEMPERNTC_MODE_BASE+2: /* 0x63 */ case TEMPERNTC_MODE_BASE+3: /* 0x64 */ /* XXX, no data */ temp = -273150000; break; case TEMPERNTC_MODE_BASE+4: /* 0x65 */ temp = ((val * val * 2977) / 100000) - (val * 4300) + 152450000; break; case TEMPERNTC_MODE_BASE+5: /* 0x66 */ temp = ((val * val * 3887) / 100000) - (val * 5300) + 197590000; break; case TEMPERNTC_MODE_BASE+6: /* 0x67 */ temp = ((val * val * 3495) / 100000) - (val * 5000) + 210590000; break; case TEMPERNTC_MODE_BASE+7: /* 0x68 */ if (val < UTHUM_NTC_MIN_THRESHOLD) temp = (val * -1700) + 149630000; else temp = ((val * val * 3257) / 100000) - (val * 4900) + 230470000; break; default: DPRINTF(("NTC state error, unknown state 0x%.2x\n", state)); break; } /* convert muC->muK value */ return temp + 273150000; } void uthum_print_sensorinfo(struct uthum_softc *sc, int num) { struct uthum_sensor *s; s = &sc->sc_sensor[num]; printf("%s: ", sc->sc_hdev.sc_dev.dv_xname); switch (s->sensor.type) { case SENSOR_TEMP: printf("type %s (temperature)", uthum_sensor_type_s[s->dev_type]); if (s->cal_offset) printf(", calibration offset %c%d.%d degC", (s->cal_offset < 0) ? '-' : '+', abs(s->cal_offset / 100), abs(s->cal_offset % 100)); break; case SENSOR_HUMIDITY: printf("type %s (humidity)", uthum_sensor_type_s[s->dev_type]); if (s->cal_offset) printf("calibration offset %c%d.%d %%RH", (s->cal_offset < 0) ? '-' : '+', abs(s->cal_offset / 100), abs(s->cal_offset % 100)); break; default: printf("unknown"); } printf("\n"); }