/* $OpenBSD: lm78.c,v 1.20 2007/06/25 22:50:18 cnst Exp $ */ /* * Copyright (c) 2005, 2006 Mark Kettenis * Copyright (c) 2006, 2007 Constantine A. Murenin * * 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 DISCLAIMS 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. */ #include #include #include #include #include "lm78var.h" #include "../wbsio/wbsioreg.h" #if defined(LMDEBUG) #define DPRINTF(x) do { kprintf x; } while (0) #else #define DPRINTF(x) #endif /* * LM78-compatible chips can typically measure voltages up to 4.096 V. * To measure higher voltages the input is attenuated with (external) * resistors. Negative voltages are measured using inverting op amps * and resistors. So we have to convert the sensor values back to * real voltages by applying the appropriate resistor factor. */ #define RFACT_NONE 10000 #define RFACT(x, y) (RFACT_NONE * ((x) + (y)) / (y)) #define NRFACT(x, y) (-RFACT_NONE * (x) / (y)) int lm_match(struct lm_softc *); int wb_match(struct lm_softc *); int def_match(struct lm_softc *); void lm_setup_sensors(struct lm_softc *, struct lm_sensor *); void lm_refresh(void *); void lm_refresh_sensor_data(struct lm_softc *); void lm_refresh_volt(struct lm_softc *, int); void lm_refresh_temp(struct lm_softc *, int); void lm_refresh_fanrpm(struct lm_softc *, int); void wb_refresh_sensor_data(struct lm_softc *); void wb_w83637hf_refresh_vcore(struct lm_softc *, int); void wb_refresh_nvolt(struct lm_softc *, int); void wb_w83627ehf_refresh_nvolt(struct lm_softc *, int); void wb_refresh_temp(struct lm_softc *, int); void wb_refresh_fanrpm(struct lm_softc *, int); void wb_nct6776f_refresh_fanrpm(struct lm_softc *, int); void wb_w83792d_refresh_fanrpm(struct lm_softc *, int); void as_refresh_temp(struct lm_softc *, int); struct lm_chip { int (*chip_match)(struct lm_softc *); }; struct lm_chip lm_chips[] = { { wb_match }, { lm_match }, { def_match } /* Must be last */ }; struct lm_sensor lm78_sensors[] = { /* Voltage */ { "VCore A", SENSOR_VOLTS_DC, 0, 0x20, lm_refresh_volt, RFACT_NONE }, { "VCore B", SENSOR_VOLTS_DC, 0, 0x21, lm_refresh_volt, RFACT_NONE }, { "+3.3V", SENSOR_VOLTS_DC, 0, 0x22, lm_refresh_volt, RFACT_NONE }, { "+5V", SENSOR_VOLTS_DC, 0, 0x23, lm_refresh_volt, RFACT(68, 100) }, { "+12V", SENSOR_VOLTS_DC, 0, 0x24, lm_refresh_volt, RFACT(30, 10) }, { "-12V", SENSOR_VOLTS_DC, 0, 0x25, lm_refresh_volt, NRFACT(240, 60) }, { "-5V", SENSOR_VOLTS_DC, 0, 0x26, lm_refresh_volt, NRFACT(100, 60) }, /* Temperature */ { "", SENSOR_TEMP, 0, 0x27, lm_refresh_temp }, /* Fans */ { "", SENSOR_FANRPM, 0, 0x28, lm_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x29, lm_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x2a, lm_refresh_fanrpm }, { NULL } }; struct lm_sensor w83627hf_sensors[] = { /* Voltage */ { "VCore A", SENSOR_VOLTS_DC, 0, 0x20, lm_refresh_volt, RFACT_NONE }, { "VCore B", SENSOR_VOLTS_DC, 0, 0x21, lm_refresh_volt, RFACT_NONE }, { "+3.3V", SENSOR_VOLTS_DC, 0, 0x22, lm_refresh_volt, RFACT_NONE }, { "+5V", SENSOR_VOLTS_DC, 0, 0x23, lm_refresh_volt, RFACT(34, 50) }, { "+12V", SENSOR_VOLTS_DC, 0, 0x24, lm_refresh_volt, RFACT(28, 10) }, { "-12V", SENSOR_VOLTS_DC, 0, 0x25, wb_refresh_nvolt, RFACT(232, 56) }, { "-5V", SENSOR_VOLTS_DC, 0, 0x26, wb_refresh_nvolt, RFACT(120, 56) }, { "5VSB", SENSOR_VOLTS_DC, 5, 0x50, lm_refresh_volt, RFACT(17, 33) }, { "VBAT", SENSOR_VOLTS_DC, 5, 0x51, lm_refresh_volt, RFACT_NONE }, /* Temperature */ { "", SENSOR_TEMP, 0, 0x27, lm_refresh_temp }, { "", SENSOR_TEMP, 1, 0x50, wb_refresh_temp }, { "", SENSOR_TEMP, 2, 0x50, wb_refresh_temp }, /* Fans */ { "", SENSOR_FANRPM, 0, 0x28, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x29, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x2a, wb_refresh_fanrpm }, { NULL } }; /* * The W83627EHF can measure voltages up to 2.048 V instead of the * traditional 4.096 V. For measuring positive voltages, this can be * accounted for by halving the resistor factor. Negative voltages * need special treatment, also because the reference voltage is 2.048 V * instead of the traditional 3.6 V. */ struct lm_sensor w83627ehf_sensors[] = { /* Voltage */ { "VCore", SENSOR_VOLTS_DC, 0, 0x20, lm_refresh_volt, RFACT_NONE / 2}, { "+12V", SENSOR_VOLTS_DC, 0, 0x21, lm_refresh_volt, RFACT(56, 10) / 2 }, { "+3.3V", SENSOR_VOLTS_DC, 0, 0x22, lm_refresh_volt, RFACT(34, 34) / 2 }, { "+3.3V", SENSOR_VOLTS_DC, 0, 0x23, lm_refresh_volt, RFACT(34, 34) / 2 }, { "-12V", SENSOR_VOLTS_DC, 0, 0x24, wb_w83627ehf_refresh_nvolt }, { "", SENSOR_VOLTS_DC, 0, 0x25, lm_refresh_volt, RFACT_NONE / 2 }, { "", SENSOR_VOLTS_DC, 0, 0x26, lm_refresh_volt, RFACT_NONE / 2 }, { "3.3VSB", SENSOR_VOLTS_DC, 5, 0x50, lm_refresh_volt, RFACT(34, 34) / 2 }, { "VBAT", SENSOR_VOLTS_DC, 5, 0x51, lm_refresh_volt, RFACT_NONE / 2 }, { "", SENSOR_VOLTS_DC, 5, 0x52, lm_refresh_volt, RFACT_NONE / 2 }, /* Temperature */ { "", SENSOR_TEMP, 0, 0x27, lm_refresh_temp }, { "", SENSOR_TEMP, 1, 0x50, wb_refresh_temp }, { "", SENSOR_TEMP, 2, 0x50, wb_refresh_temp }, /* Fans */ { "", SENSOR_FANRPM, 0, 0x28, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x29, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x2a, wb_refresh_fanrpm }, { NULL } }; /* * w83627dhg is almost identical to w83627ehf, except that * it has 9 instead of 10 voltage sensors */ struct lm_sensor w83627dhg_sensors[] = { /* Voltage */ { "VCore", SENSOR_VOLTS_DC, 0, 0x20, lm_refresh_volt, RFACT_NONE / 2}, { "+12V", SENSOR_VOLTS_DC, 0, 0x21, lm_refresh_volt, RFACT(56, 10) / 2 }, { "+3.3V", SENSOR_VOLTS_DC, 0, 0x22, lm_refresh_volt, RFACT(34, 34) / 2 }, { "+3.3V", SENSOR_VOLTS_DC, 0, 0x23, lm_refresh_volt, RFACT(34, 34) / 2 }, { "-12V", SENSOR_VOLTS_DC, 0, 0x24, wb_w83627ehf_refresh_nvolt }, { "", SENSOR_VOLTS_DC, 0, 0x25, lm_refresh_volt, RFACT_NONE / 2 }, { "", SENSOR_VOLTS_DC, 0, 0x26, lm_refresh_volt, RFACT_NONE / 2 }, { "3.3VSB", SENSOR_VOLTS_DC, 5, 0x50, lm_refresh_volt, RFACT(34, 34) / 2 }, { "VBAT", SENSOR_VOLTS_DC, 5, 0x51, lm_refresh_volt, RFACT_NONE / 2 }, /* Temperature */ { "", SENSOR_TEMP, 0, 0x27, lm_refresh_temp }, { "", SENSOR_TEMP, 1, 0x50, wb_refresh_temp }, { "", SENSOR_TEMP, 2, 0x50, wb_refresh_temp }, /* Fans */ { "", SENSOR_FANRPM, 0, 0x28, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x29, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x2a, wb_refresh_fanrpm }, { NULL } }; struct lm_sensor nct6776f_sensors[] = { /* Voltage */ { "VCore", SENSOR_VOLTS_DC, 0, 0x20, lm_refresh_volt, RFACT_NONE / 2}, { "+12V", SENSOR_VOLTS_DC, 0, 0x21, lm_refresh_volt, RFACT(56, 10) / 2 }, { "+3.3V", SENSOR_VOLTS_DC, 0, 0x22, lm_refresh_volt, RFACT(34, 34) / 2 }, { "+3.3V", SENSOR_VOLTS_DC, 0, 0x23, lm_refresh_volt, RFACT(34, 34) / 2 }, { "-12V", SENSOR_VOLTS_DC, 0, 0x24, wb_w83627ehf_refresh_nvolt }, { "", SENSOR_VOLTS_DC, 0, 0x25, lm_refresh_volt, RFACT_NONE / 2 }, { "", SENSOR_VOLTS_DC, 0, 0x26, lm_refresh_volt, RFACT_NONE / 2 }, { "3.3VSB", SENSOR_VOLTS_DC, 5, 0x50, lm_refresh_volt, RFACT(34, 34) / 2 }, { "VBAT", SENSOR_VOLTS_DC, 5, 0x51, lm_refresh_volt, RFACT_NONE / 2 }, /* Temperature */ { "", SENSOR_TEMP, 0, 0x27, lm_refresh_temp }, { "", SENSOR_TEMP, 1, 0x50, wb_refresh_temp }, { "", SENSOR_TEMP, 2, 0x50, wb_refresh_temp }, /* Fans */ { "", SENSOR_FANRPM, 6, 0x56, wb_nct6776f_refresh_fanrpm }, { "", SENSOR_FANRPM, 6, 0x58, wb_nct6776f_refresh_fanrpm }, { "", SENSOR_FANRPM, 6, 0x5a, wb_nct6776f_refresh_fanrpm }, { "", SENSOR_FANRPM, 6, 0x5c, wb_nct6776f_refresh_fanrpm }, { "", SENSOR_FANRPM, 6, 0x5e, wb_nct6776f_refresh_fanrpm }, { NULL } }; struct lm_sensor w83637hf_sensors[] = { /* Voltage */ { "VCore", SENSOR_VOLTS_DC, 0, 0x20, wb_w83637hf_refresh_vcore }, { "+12V", SENSOR_VOLTS_DC, 0, 0x21, lm_refresh_volt, RFACT(28, 10) }, { "+3.3V", SENSOR_VOLTS_DC, 0, 0x22, lm_refresh_volt, RFACT_NONE }, { "+5V", SENSOR_VOLTS_DC, 0, 0x23, lm_refresh_volt, RFACT(34, 51) }, { "-12V", SENSOR_VOLTS_DC, 0, 0x24, wb_refresh_nvolt, RFACT(232, 56) }, { "5VSB", SENSOR_VOLTS_DC, 5, 0x50, lm_refresh_volt, RFACT(34, 51) }, { "VBAT", SENSOR_VOLTS_DC, 5, 0x51, lm_refresh_volt, RFACT_NONE }, /* Temperature */ { "", SENSOR_TEMP, 0, 0x27, lm_refresh_temp }, { "", SENSOR_TEMP, 1, 0x50, wb_refresh_temp }, { "", SENSOR_TEMP, 2, 0x50, wb_refresh_temp }, /* Fans */ { "", SENSOR_FANRPM, 0, 0x28, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x29, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x2a, wb_refresh_fanrpm }, { NULL } }; struct lm_sensor w83697hf_sensors[] = { /* Voltage */ { "VCore", SENSOR_VOLTS_DC, 0, 0x20, lm_refresh_volt, RFACT_NONE }, { "+3.3V", SENSOR_VOLTS_DC, 0, 0x22, lm_refresh_volt, RFACT_NONE }, { "+5V", SENSOR_VOLTS_DC, 0, 0x23, lm_refresh_volt, RFACT(34, 50) }, { "+12V", SENSOR_VOLTS_DC, 0, 0x24, lm_refresh_volt, RFACT(28, 10) }, { "-12V", SENSOR_VOLTS_DC, 0, 0x25, wb_refresh_nvolt, RFACT(232, 56) }, { "-5V", SENSOR_VOLTS_DC, 0, 0x26, wb_refresh_nvolt, RFACT(120, 56) }, { "5VSB", SENSOR_VOLTS_DC, 5, 0x50, lm_refresh_volt, RFACT(17, 33) }, { "VBAT", SENSOR_VOLTS_DC, 5, 0x51, lm_refresh_volt, RFACT_NONE }, /* Temperature */ { "", SENSOR_TEMP, 0, 0x27, lm_refresh_temp }, { "", SENSOR_TEMP, 1, 0x50, wb_refresh_temp }, /* Fans */ { "", SENSOR_FANRPM, 0, 0x28, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x29, wb_refresh_fanrpm }, { NULL } }; /* * The datasheet doesn't mention the (internal) resistors used for the * +5V, but using the values from the W83782D datasheets seems to * provide sensible results. */ struct lm_sensor w83781d_sensors[] = { /* Voltage */ { "VCore A", SENSOR_VOLTS_DC, 0, 0x20, lm_refresh_volt, RFACT_NONE }, { "VCore B", SENSOR_VOLTS_DC, 0, 0x21, lm_refresh_volt, RFACT_NONE }, { "+3.3V", SENSOR_VOLTS_DC, 0, 0x22, lm_refresh_volt, RFACT_NONE }, { "+5V", SENSOR_VOLTS_DC, 0, 0x23, lm_refresh_volt, RFACT(34, 50) }, { "+12V", SENSOR_VOLTS_DC, 0, 0x24, lm_refresh_volt, RFACT(28, 10) }, { "-12V", SENSOR_VOLTS_DC, 0, 0x25, lm_refresh_volt, NRFACT(2100, 604) }, { "-5V", SENSOR_VOLTS_DC, 0, 0x26, lm_refresh_volt, NRFACT(909, 604) }, /* Temperature */ { "", SENSOR_TEMP, 0, 0x27, lm_refresh_temp }, { "", SENSOR_TEMP, 1, 0x50, wb_refresh_temp }, { "", SENSOR_TEMP, 2, 0x50, wb_refresh_temp }, /* Fans */ { "", SENSOR_FANRPM, 0, 0x28, lm_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x29, lm_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x2a, lm_refresh_fanrpm }, { NULL } }; struct lm_sensor w83782d_sensors[] = { /* Voltage */ { "VCore", SENSOR_VOLTS_DC, 0, 0x20, lm_refresh_volt, RFACT_NONE }, { "VINR0", SENSOR_VOLTS_DC, 0, 0x21, lm_refresh_volt, RFACT_NONE }, { "+3.3V", SENSOR_VOLTS_DC, 0, 0x22, lm_refresh_volt, RFACT_NONE }, { "+5V", SENSOR_VOLTS_DC, 0, 0x23, lm_refresh_volt, RFACT(34, 50) }, { "+12V", SENSOR_VOLTS_DC, 0, 0x24, lm_refresh_volt, RFACT(28, 10) }, { "-12V", SENSOR_VOLTS_DC, 0, 0x25, wb_refresh_nvolt, RFACT(232, 56) }, { "-5V", SENSOR_VOLTS_DC, 0, 0x26, wb_refresh_nvolt, RFACT(120, 56) }, { "5VSB", SENSOR_VOLTS_DC, 5, 0x50, lm_refresh_volt, RFACT(17, 33) }, { "VBAT", SENSOR_VOLTS_DC, 5, 0x51, lm_refresh_volt, RFACT_NONE }, /* Temperature */ { "", SENSOR_TEMP, 0, 0x27, lm_refresh_temp }, { "", SENSOR_TEMP, 1, 0x50, wb_refresh_temp }, { "", SENSOR_TEMP, 2, 0x50, wb_refresh_temp }, /* Fans */ { "", SENSOR_FANRPM, 0, 0x28, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x29, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x2a, wb_refresh_fanrpm }, { NULL } }; struct lm_sensor w83783s_sensors[] = { /* Voltage */ { "VCore", SENSOR_VOLTS_DC, 0, 0x20, lm_refresh_volt, RFACT_NONE }, { "+3.3V", SENSOR_VOLTS_DC, 0, 0x22, lm_refresh_volt, RFACT_NONE }, { "+5V", SENSOR_VOLTS_DC, 0, 0x23, lm_refresh_volt, RFACT(34, 50) }, { "+12V", SENSOR_VOLTS_DC, 0, 0x24, lm_refresh_volt, RFACT(28, 10) }, { "-12V", SENSOR_VOLTS_DC, 0, 0x25, wb_refresh_nvolt, RFACT(232, 56) }, { "-5V", SENSOR_VOLTS_DC, 0, 0x26, wb_refresh_nvolt, RFACT(120, 56) }, /* Temperature */ { "", SENSOR_TEMP, 0, 0x27, lm_refresh_temp }, { "", SENSOR_TEMP, 1, 0x50, wb_refresh_temp }, /* Fans */ { "", SENSOR_FANRPM, 0, 0x28, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x29, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x2a, wb_refresh_fanrpm }, { NULL } }; struct lm_sensor w83791d_sensors[] = { /* Voltage */ { "VCore", SENSOR_VOLTS_DC, 0, 0x20, lm_refresh_volt, RFACT_NONE }, { "VINR0", SENSOR_VOLTS_DC, 0, 0x21, lm_refresh_volt, RFACT_NONE }, { "+3.3V", SENSOR_VOLTS_DC, 0, 0x22, lm_refresh_volt, RFACT_NONE }, { "+5V", SENSOR_VOLTS_DC, 0, 0x23, lm_refresh_volt, RFACT(34, 50) }, { "+12V", SENSOR_VOLTS_DC, 0, 0x24, lm_refresh_volt, RFACT(28, 10) }, { "-12V", SENSOR_VOLTS_DC, 0, 0x25, wb_refresh_nvolt, RFACT(232, 56) }, { "-5V", SENSOR_VOLTS_DC, 0, 0x26, wb_refresh_nvolt, RFACT(120, 56) }, { "5VSB", SENSOR_VOLTS_DC, 0, 0xb0, lm_refresh_volt, RFACT(17, 33) }, { "VBAT", SENSOR_VOLTS_DC, 0, 0xb1, lm_refresh_volt, RFACT_NONE }, { "VINR1", SENSOR_VOLTS_DC, 0, 0xb2, lm_refresh_volt, RFACT_NONE }, /* Temperature */ { "", SENSOR_TEMP, 0, 0x27, lm_refresh_temp }, { "", SENSOR_TEMP, 0, 0xc0, wb_refresh_temp }, { "", SENSOR_TEMP, 0, 0xc8, wb_refresh_temp }, /* Fans */ { "", SENSOR_FANRPM, 0, 0x28, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x29, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x2a, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0xba, wb_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0xbb, wb_refresh_fanrpm }, { NULL } }; struct lm_sensor w83792d_sensors[] = { /* Voltage */ { "VCore A", SENSOR_VOLTS_DC, 0, 0x20, lm_refresh_volt, RFACT_NONE }, { "VCore B", SENSOR_VOLTS_DC, 0, 0x21, lm_refresh_volt, RFACT_NONE }, { "+3.3V", SENSOR_VOLTS_DC, 0, 0x22, lm_refresh_volt, RFACT_NONE }, { "-5V", SENSOR_VOLTS_DC, 0, 0x23, wb_refresh_nvolt, RFACT(120, 56) }, { "+12V", SENSOR_VOLTS_DC, 0, 0x24, lm_refresh_volt, RFACT(28, 10) }, { "-12V", SENSOR_VOLTS_DC, 0, 0x25, wb_refresh_nvolt, RFACT(232, 56) }, { "+5V", SENSOR_VOLTS_DC, 0, 0x26, lm_refresh_volt, RFACT(34, 50) }, { "5VSB", SENSOR_VOLTS_DC, 0, 0xb0, lm_refresh_volt, RFACT(17, 33) }, { "VBAT", SENSOR_VOLTS_DC, 0, 0xb1, lm_refresh_volt, RFACT_NONE }, /* Temperature */ { "", SENSOR_TEMP, 0, 0x27, lm_refresh_temp }, { "", SENSOR_TEMP, 0, 0xc0, wb_refresh_temp }, { "", SENSOR_TEMP, 0, 0xc8, wb_refresh_temp }, /* Fans */ { "", SENSOR_FANRPM, 0, 0x28, wb_w83792d_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x29, wb_w83792d_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x2a, wb_w83792d_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0xb8, wb_w83792d_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0xb9, wb_w83792d_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0xba, wb_w83792d_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0xbe, wb_w83792d_refresh_fanrpm }, { NULL } }; struct lm_sensor as99127f_sensors[] = { /* Voltage */ { "VCore A", SENSOR_VOLTS_DC, 0, 0x20, lm_refresh_volt, RFACT_NONE }, { "VCore B", SENSOR_VOLTS_DC, 0, 0x21, lm_refresh_volt, RFACT_NONE }, { "+3.3V", SENSOR_VOLTS_DC, 0, 0x22, lm_refresh_volt, RFACT_NONE }, { "+5V", SENSOR_VOLTS_DC, 0, 0x23, lm_refresh_volt, RFACT(34, 50) }, { "+12V", SENSOR_VOLTS_DC, 0, 0x24, lm_refresh_volt, RFACT(28, 10) }, { "-12V", SENSOR_VOLTS_DC, 0, 0x25, wb_refresh_nvolt, RFACT(232, 56) }, { "-5V", SENSOR_VOLTS_DC, 0, 0x26, wb_refresh_nvolt, RFACT(120, 56) }, /* Temperature */ { "", SENSOR_TEMP, 0, 0x27, lm_refresh_temp }, { "", SENSOR_TEMP, 1, 0x50, as_refresh_temp }, { "", SENSOR_TEMP, 2, 0x50, as_refresh_temp }, /* Fans */ { "", SENSOR_FANRPM, 0, 0x28, lm_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x29, lm_refresh_fanrpm }, { "", SENSOR_FANRPM, 0, 0x2a, lm_refresh_fanrpm }, { NULL } }; void lm_probe(struct lm_softc *sc) { int i; for (i = 0; i < NELEM(lm_chips); i++) if (lm_chips[i].chip_match(sc)) break; } void lm_attach(struct lm_softc *sc) { u_int i, config; /* No point in doing anything if we don't have any sensors. */ if (sc->numsensors == 0) return; sensor_task_register(sc, lm_refresh, 5); /* Start the monitoring loop */ config = sc->lm_readreg(sc, LM_CONFIG); sc->lm_writereg(sc, LM_CONFIG, config | 0x01); /* Add sensors */ strlcpy(sc->sensordev.xname, device_get_nameunit(sc->sc_dev), sizeof(sc->sensordev.xname)); for (i = 0; i < sc->numsensors; ++i) sensor_attach(&sc->sensordev, &sc->sensors[i]); sensordev_install(&sc->sensordev); } int lm_detach(struct lm_softc *sc) { int i; /* Remove sensors */ sensordev_deinstall(&sc->sensordev); for (i = 0; i < sc->numsensors; i++) sensor_detach(&sc->sensordev, &sc->sensors[i]); sensor_task_unregister(sc); return 0; } int lm_match(struct lm_softc *sc) { int chipid; const char *cdesc; char fulldesc[64]; /* See if we have an LM78 or LM79. */ chipid = sc->lm_readreg(sc, LM_CHIPID) & LM_CHIPID_MASK; switch(chipid) { case LM_CHIPID_LM78: cdesc = "LM78"; break; case LM_CHIPID_LM78J: cdesc = "LM78J"; break; case LM_CHIPID_LM79: cdesc = "LM79"; break; case LM_CHIPID_LM81: cdesc = "LM81"; break; default: return 0; } ksnprintf(fulldesc, sizeof(fulldesc), "National Semiconductor %s Hardware Monitor", cdesc); device_set_desc_copy(sc->sc_dev, fulldesc); lm_setup_sensors(sc, lm78_sensors); sc->refresh_sensor_data = lm_refresh_sensor_data; return 1; } int def_match(struct lm_softc *sc) { int chipid; char fulldesc[64]; chipid = sc->lm_readreg(sc, LM_CHIPID) & LM_CHIPID_MASK; ksnprintf(fulldesc, sizeof(fulldesc), "unknown Hardware Monitor (ID 0x%x)", chipid); device_set_desc_copy(sc->sc_dev, fulldesc); lm_setup_sensors(sc, lm78_sensors); sc->refresh_sensor_data = lm_refresh_sensor_data; return 1; } int wb_match(struct lm_softc *sc) { int banksel, vendid, devid; const char *cdesc; char desc[64]; char fulldesc[64]; /* Read vendor ID */ banksel = sc->lm_readreg(sc, WB_BANKSEL); sc->lm_writereg(sc, WB_BANKSEL, WB_BANKSEL_HBAC); vendid = sc->lm_readreg(sc, WB_VENDID) << 8; sc->lm_writereg(sc, WB_BANKSEL, 0); vendid |= sc->lm_readreg(sc, WB_VENDID); sc->lm_writereg(sc, WB_BANKSEL, banksel); DPRINTF((" winbond vend id 0x%x\n", vendid)); if (vendid != WB_VENDID_WINBOND && vendid != WB_VENDID_ASUS) return 0; /* Read device/chip ID */ sc->lm_writereg(sc, WB_BANKSEL, WB_BANKSEL_B0); devid = sc->lm_readreg(sc, LM_CHIPID); sc->chipid = sc->lm_readreg(sc, WB_BANK0_CHIPID); sc->lm_writereg(sc, WB_BANKSEL, banksel); DPRINTF((" winbond chip id 0x%x\n", sc->chipid)); switch(sc->chipid) { case WB_CHIPID_W83627HF: cdesc = "W83627HF"; lm_setup_sensors(sc, w83627hf_sensors); break; case WB_CHIPID_W83627THF: cdesc = "W83627THF"; lm_setup_sensors(sc, w83637hf_sensors); break; case WB_CHIPID_W83627EHF_A: cdesc = "W83627EHF-A"; lm_setup_sensors(sc, w83627ehf_sensors); break; case WB_CHIPID_W83627EHF: cdesc = "W83627EHF"; lm_setup_sensors(sc, w83627ehf_sensors); break; case WB_CHIPID_W83627DHG: if (sc->sioid == WBSIO_ID_NCT6776F) { cdesc = "NCT6776F"; lm_setup_sensors(sc, nct6776f_sensors); } else { cdesc = "W83627DHG"; lm_setup_sensors(sc, w83627dhg_sensors); } break; case WB_CHIPID_W83637HF: cdesc = "W83637HF"; sc->lm_writereg(sc, WB_BANKSEL, WB_BANKSEL_B0); if (sc->lm_readreg(sc, WB_BANK0_CONFIG) & WB_CONFIG_VMR9) sc->vrm9 = 1; sc->lm_writereg(sc, WB_BANKSEL, banksel); lm_setup_sensors(sc, w83637hf_sensors); break; case WB_CHIPID_W83697HF: cdesc = "W83697HF"; lm_setup_sensors(sc, w83697hf_sensors); break; case WB_CHIPID_W83781D: case WB_CHIPID_W83781D_2: cdesc = "W83781D"; lm_setup_sensors(sc, w83781d_sensors); break; case WB_CHIPID_W83782D: cdesc = "W83782D"; lm_setup_sensors(sc, w83782d_sensors); break; case WB_CHIPID_W83783S: cdesc = "W83783S"; lm_setup_sensors(sc, w83783s_sensors); break; case WB_CHIPID_W83791D: cdesc = "W83791D"; lm_setup_sensors(sc, w83791d_sensors); break; case WB_CHIPID_W83791SD: cdesc = "W83791SD"; break; case WB_CHIPID_W83792D: if (devid >= 0x10 && devid <= 0x29) ksnprintf(desc, sizeof(desc), "W83792D rev %c", 'A' + devid - 0x10); else ksnprintf(desc, sizeof(desc), "W83792D rev 0x%x", devid); cdesc = desc; lm_setup_sensors(sc, w83792d_sensors); break; case WB_CHIPID_AS99127F: if (vendid == WB_VENDID_ASUS) { cdesc = "AS99127F"; lm_setup_sensors(sc, w83781d_sensors); } else { cdesc = "AS99127F rev 2"; lm_setup_sensors(sc, as99127f_sensors); } break; default: ksnprintf(fulldesc, sizeof(fulldesc), "unknown Winbond Hardware Monitor (Chip ID 0x%x)", sc->chipid); device_set_desc_copy(sc->sc_dev, fulldesc); /* Handle as a standard LM78. */ lm_setup_sensors(sc, lm78_sensors); sc->refresh_sensor_data = lm_refresh_sensor_data; return 1; } if (cdesc[0] == 'W') ksnprintf(fulldesc, sizeof(fulldesc), "Winbond %s Hardware Monitor", cdesc); else ksnprintf(fulldesc, sizeof(fulldesc), "ASUS %s Hardware Monitor", cdesc); device_set_desc_copy(sc->sc_dev, fulldesc); sc->refresh_sensor_data = wb_refresh_sensor_data; return 1; } void lm_setup_sensors(struct lm_softc *sc, struct lm_sensor *sensors) { int i; for (i = 0; sensors[i].desc; i++) { sc->sensors[i].type = sensors[i].type; strlcpy(sc->sensors[i].desc, sensors[i].desc, sizeof(sc->sensors[i].desc)); sc->numsensors++; } sc->lm_sensors = sensors; } void lm_refresh(void *arg) { struct lm_softc *sc = arg; sc->refresh_sensor_data(sc); } void lm_refresh_sensor_data(struct lm_softc *sc) { int i; for (i = 0; i < sc->numsensors; i++) sc->lm_sensors[i].refresh(sc, i); } void lm_refresh_volt(struct lm_softc *sc, int n) { struct ksensor *sensor = &sc->sensors[n]; int data; data = sc->lm_readreg(sc, sc->lm_sensors[n].reg); sensor->value = (data << 4); sensor->value *= sc->lm_sensors[n].rfact; sensor->value /= 10; } void lm_refresh_temp(struct lm_softc *sc, int n) { struct ksensor *sensor = &sc->sensors[n]; int sdata; /* * The data sheet suggests that the range of the temperature * sensor is between -55 degC and +125 degC. */ sdata = sc->lm_readreg(sc, sc->lm_sensors[n].reg); if (sdata > 0x7d && sdata < 0xc9) { sensor->flags |= SENSOR_FINVALID; sensor->value = 0; } else { if (sdata & 0x80) sdata -= 0x100; sensor->flags &= ~SENSOR_FINVALID; sensor->value = sdata * 1000000 + 273150000; } } void lm_refresh_fanrpm(struct lm_softc *sc, int n) { struct ksensor *sensor = &sc->sensors[n]; int data, divisor = 1; /* * We might get more accurate fan readings by adjusting the * divisor, but that might interfere with APM or other SMM * BIOS code reading the fan speeds. */ /* FAN3 has a fixed fan divisor. */ if (sc->lm_sensors[n].reg == LM_FAN1 || sc->lm_sensors[n].reg == LM_FAN2) { data = sc->lm_readreg(sc, LM_VIDFAN); if (sc->lm_sensors[n].reg == LM_FAN1) divisor = (data >> 4) & 0x03; else divisor = (data >> 6) & 0x03; } data = sc->lm_readreg(sc, sc->lm_sensors[n].reg); if (data == 0xff || data == 0x00) { sensor->flags |= SENSOR_FINVALID; sensor->value = 0; } else { sensor->flags &= ~SENSOR_FINVALID; sensor->value = 1350000 / (data << divisor); } } void wb_refresh_sensor_data(struct lm_softc *sc) { int banksel, bank, i; /* * Properly save and restore bank selection register. */ banksel = bank = sc->lm_readreg(sc, WB_BANKSEL); for (i = 0; i < sc->numsensors; i++) { if (bank != sc->lm_sensors[i].bank) { bank = sc->lm_sensors[i].bank; sc->lm_writereg(sc, WB_BANKSEL, bank); } sc->lm_sensors[i].refresh(sc, i); } sc->lm_writereg(sc, WB_BANKSEL, banksel); } void wb_w83637hf_refresh_vcore(struct lm_softc *sc, int n) { struct ksensor *sensor = &sc->sensors[n]; int data; data = sc->lm_readreg(sc, sc->lm_sensors[n].reg); /* * Depending on the voltage detection method, * one of the following formulas is used: * VRM8 method: value = raw * 0.016V * VRM9 method: value = raw * 0.00488V + 0.70V */ if (sc->vrm9) sensor->value = (data * 4880) + 700000; else sensor->value = (data * 16000); } void wb_refresh_nvolt(struct lm_softc *sc, int n) { struct ksensor *sensor = &sc->sensors[n]; int data; data = sc->lm_readreg(sc, sc->lm_sensors[n].reg); sensor->value = ((data << 4) - WB_VREF); sensor->value *= sc->lm_sensors[n].rfact; sensor->value /= 10; sensor->value += WB_VREF * 1000; } void wb_w83627ehf_refresh_nvolt(struct lm_softc *sc, int n) { struct ksensor *sensor = &sc->sensors[n]; int data; data = sc->lm_readreg(sc, sc->lm_sensors[n].reg); sensor->value = ((data << 3) - WB_W83627EHF_VREF); sensor->value *= RFACT(232, 10); sensor->value /= 10; sensor->value += WB_W83627EHF_VREF * 1000; } void wb_refresh_temp(struct lm_softc *sc, int n) { struct ksensor *sensor = &sc->sensors[n]; int sdata; /* * The data sheet suggests that the range of the temperature * sensor is between -55 degC and +125 degC. However, values * around -48 degC seem to be a very common bogus values. * Since such values are unreasonably low, we use -45 degC for * the lower limit instead. */ sdata = sc->lm_readreg(sc, sc->lm_sensors[n].reg) << 1; sdata += sc->lm_readreg(sc, sc->lm_sensors[n].reg + 1) >> 7; if (sdata > 0x0fa && sdata < 0x1a6) { sensor->flags |= SENSOR_FINVALID; sensor->value = 0; } else { if (sdata & 0x100) sdata -= 0x200; sensor->flags &= ~SENSOR_FINVALID; sensor->value = sdata * 500000 + 273150000; } } void wb_refresh_fanrpm(struct lm_softc *sc, int n) { struct ksensor *sensor = &sc->sensors[n]; int fan, data, divisor = 0; /* * This is madness; the fan divisor bits are scattered all * over the place. */ if (sc->lm_sensors[n].reg == LM_FAN1 || sc->lm_sensors[n].reg == LM_FAN2 || sc->lm_sensors[n].reg == LM_FAN3) { data = sc->lm_readreg(sc, WB_BANK0_VBAT); fan = (sc->lm_sensors[n].reg - LM_FAN1); if ((data >> 5) & (1 << fan)) divisor |= 0x04; } if (sc->lm_sensors[n].reg == LM_FAN1 || sc->lm_sensors[n].reg == LM_FAN2) { data = sc->lm_readreg(sc, LM_VIDFAN); if (sc->lm_sensors[n].reg == LM_FAN1) divisor |= (data >> 4) & 0x03; else divisor |= (data >> 6) & 0x03; } else if (sc->lm_sensors[n].reg == LM_FAN3) { data = sc->lm_readreg(sc, WB_PIN); divisor |= (data >> 6) & 0x03; } else if (sc->lm_sensors[n].reg == WB_BANK0_FAN4 || sc->lm_sensors[n].reg == WB_BANK0_FAN5) { data = sc->lm_readreg(sc, WB_BANK0_FAN45); if (sc->lm_sensors[n].reg == WB_BANK0_FAN4) divisor |= (data >> 0) & 0x07; else divisor |= (data >> 4) & 0x07; } data = sc->lm_readreg(sc, sc->lm_sensors[n].reg); if (data == 0xff || data == 0x00) { sensor->flags |= SENSOR_FINVALID; sensor->value = 0; } else { sensor->flags &= ~SENSOR_FINVALID; sensor->value = 1350000 / (data << divisor); } } void wb_w83792d_refresh_fanrpm(struct lm_softc *sc, int n) { struct ksensor *sensor = &sc->sensors[n]; int reg, shift, data, divisor = 1; switch (sc->lm_sensors[n].reg) { case 0x28: reg = 0x47; shift = 0; break; case 0x29: reg = 0x47; shift = 4; break; case 0x2a: reg = 0x5b; shift = 0; break; case 0xb8: reg = 0x5b; shift = 4; break; case 0xb9: reg = 0x5c; shift = 0; break; case 0xba: reg = 0x5c; shift = 4; break; case 0xbe: reg = 0x9e; shift = 0; break; default: reg = 0; shift = 0; break; } data = sc->lm_readreg(sc, sc->lm_sensors[n].reg); if (data == 0xff || data == 0x00) { sensor->flags |= SENSOR_FINVALID; sensor->value = 0; } else { if (reg != 0) divisor = (sc->lm_readreg(sc, reg) >> shift) & 0x7; sensor->flags &= ~SENSOR_FINVALID; sensor->value = 1350000 / (data << divisor); } } void wb_nct6776f_refresh_fanrpm(struct lm_softc *sc, int n) { struct ksensor *sensor = &sc->sensors[n]; int datah, datal; datah = sc->lm_readreg(sc, sc->lm_sensors[n].reg); datal = sc->lm_readreg(sc, sc->lm_sensors[n].reg + 1); if (datah == 0xff) { sensor->flags |= SENSOR_FINVALID; sensor->value = 0; } else { sensor->flags &= ~SENSOR_FINVALID; sensor->value = (datah << 8) | datal; } } void as_refresh_temp(struct lm_softc *sc, int n) { struct ksensor *sensor = &sc->sensors[n]; int sdata; /* * It seems a shorted temperature diode produces an all-ones * bit pattern. */ sdata = sc->lm_readreg(sc, sc->lm_sensors[n].reg) << 1; sdata += sc->lm_readreg(sc, sc->lm_sensors[n].reg + 1) >> 7; if (sdata == 0x1ff) { sensor->flags |= SENSOR_FINVALID; sensor->value = 0; } else { if (sdata & 0x100) sdata -= 0x200; sensor->flags &= ~SENSOR_FINVALID; sensor->value = sdata * 500000 + 273150000; } }