/* $NetBSD: nslm7x.c,v 1.13 2001/11/13 13:14:42 lukem Exp $ */ /*- * Copyright (c) 2000 The NetBSD Foundation, Inc. * All rights reserved. * * This code is derived from software contributed to The NetBSD Foundation * by Bill Squier. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the NetBSD * Foundation, Inc. and its contributors. * 4. Neither the name of The NetBSD Foundation nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ #include __KERNEL_RCSID(0, "$NetBSD: nslm7x.c,v 1.13 2001/11/13 13:14:42 lukem Exp $"); #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if defined(LMDEBUG) #define DPRINTF(x) do { printf x; } while (0) #else #define DPRINTF(x) #endif const struct envsys_range lm_ranges[] = { /* sc->sensors sub-intervals */ /* for each unit type */ { 7, 7, ENVSYS_STEMP }, { 8, 10, ENVSYS_SFANRPM }, { 1, 0, ENVSYS_SVOLTS_AC }, /* None */ { 0, 6, ENVSYS_SVOLTS_DC }, { 1, 0, ENVSYS_SOHMS }, /* None */ { 1, 0, ENVSYS_SWATTS }, /* None */ { 1, 0, ENVSYS_SAMPS } /* None */ }; u_int8_t lm_readreg __P((struct lm_softc *, int)); void lm_writereg __P((struct lm_softc *, int, int)); static void setup_fan __P((struct lm_softc *, int, int)); static void setup_temp __P((struct lm_softc *, int, int)); static void wb_setup_volt __P((struct lm_softc *)); int lm_match __P((struct lm_softc *)); int wb_match __P((struct lm_softc *)); int def_match __P((struct lm_softc *)); void lm_common_match __P((struct lm_softc *)); static void generic_stemp __P((struct lm_softc *, struct envsys_tre_data *)); static void generic_svolt __P((struct lm_softc *, struct envsys_tre_data *, struct envsys_basic_info *)); static void generic_fanrpm __P((struct lm_softc *, struct envsys_tre_data *)); void lm_refresh_sensor_data __P((struct lm_softc *)); static void wb_svolt __P((struct lm_softc *)); static void wb_stemp __P((struct lm_softc *, struct envsys_tre_data *, int)); static void wb_fanrpm __P((struct lm_softc *, struct envsys_tre_data *)); void wb781_refresh_sensor_data __P((struct lm_softc *)); void wb782_refresh_sensor_data __P((struct lm_softc *)); void wb697_refresh_sensor_data __P((struct lm_softc *)); int lm_gtredata __P((struct sysmon_envsys *, struct envsys_tre_data *)); int generic_streinfo_fan __P((struct lm_softc *, struct envsys_basic_info *, int, struct envsys_basic_info *)); int lm_streinfo __P((struct sysmon_envsys *, struct envsys_basic_info *)); int wb781_streinfo __P((struct sysmon_envsys *, struct envsys_basic_info *)); int wb782_streinfo __P((struct sysmon_envsys *, struct envsys_basic_info *)); struct lm_chip { int (*chip_match) __P((struct lm_softc *)); }; struct lm_chip lm_chips[] = { { wb_match }, { lm_match }, { def_match } /* Must be last */ }; u_int8_t lm_readreg(sc, reg) struct lm_softc *sc; int reg; { bus_space_write_1(sc->lm_iot, sc->lm_ioh, LMC_ADDR, reg); return (bus_space_read_1(sc->lm_iot, sc->lm_ioh, LMC_DATA)); } void lm_writereg(sc, reg, val) struct lm_softc *sc; int reg; int val; { bus_space_write_1(sc->lm_iot, sc->lm_ioh, LMC_ADDR, reg); bus_space_write_1(sc->lm_iot, sc->lm_ioh, LMC_DATA, val); } /* * bus independent probe */ int lm_probe(iot, ioh) bus_space_tag_t iot; bus_space_handle_t ioh; { u_int8_t cr; int rv; /* Check for some power-on defaults */ bus_space_write_1(iot, ioh, LMC_ADDR, LMD_CONFIG); /* Perform LM78 reset */ bus_space_write_1(iot, ioh, LMC_DATA, 0x80); /* XXX - Why do I have to reselect the register? */ bus_space_write_1(iot, ioh, LMC_ADDR, LMD_CONFIG); cr = bus_space_read_1(iot, ioh, LMC_DATA); /* XXX - spec says *only* 0x08! */ if ((cr == 0x08) || (cr == 0x01)) rv = 1; else rv = 0; DPRINTF(("lm: rv = %d, cr = %x\n", rv, cr)); return (rv); } /* * pre: lmsc contains valid busspace tag and handle */ void lm_attach(lmsc) struct lm_softc *lmsc; { int i; for (i = 0; i < sizeof(lm_chips) / sizeof(lm_chips[0]); i++) if (lm_chips[i].chip_match(lmsc)) break; /* Start the monitoring loop */ lm_writereg(lmsc, LMD_CONFIG, 0x01); /* Indicate we have never read the registers */ timerclear(&lmsc->lastread); /* Initialize sensors */ for (i = 0; i < lmsc->numsensors; ++i) { lmsc->sensors[i].sensor = lmsc->info[i].sensor = i; lmsc->sensors[i].validflags = (ENVSYS_FVALID|ENVSYS_FCURVALID); lmsc->info[i].validflags = ENVSYS_FVALID; lmsc->sensors[i].warnflags = ENVSYS_WARN_OK; } /* * Hook into the System Monitor. */ lmsc->sc_sysmon.sme_ranges = lm_ranges; lmsc->sc_sysmon.sme_sensor_info = lmsc->info; lmsc->sc_sysmon.sme_sensor_data = lmsc->sensors; lmsc->sc_sysmon.sme_cookie = lmsc; lmsc->sc_sysmon.sme_gtredata = lm_gtredata; /* sme_streinfo set in chip-specific attach */ lmsc->sc_sysmon.sme_nsensors = lmsc->numsensors; lmsc->sc_sysmon.sme_envsys_version = 1000; if (sysmon_envsys_register(&lmsc->sc_sysmon)) printf("%s: unable to register with sysmon\n", lmsc->sc_dev.dv_xname); } int lm_match(sc) struct lm_softc *sc; { int i; /* See if we have an LM78 or LM79 */ i = lm_readreg(sc, LMD_CHIPID) & LM_ID_MASK; switch(i) { case LM_ID_LM78: printf(": LM78\n"); break; case LM_ID_LM78J: printf(": LM78J\n"); break; case LM_ID_LM79: printf(": LM79\n"); break; default: return 0; } lm_common_match(sc); return 1; } int def_match(sc) struct lm_softc *sc; { int i; i = lm_readreg(sc, LMD_CHIPID) & LM_ID_MASK; printf(": Unknow chip (ID %d)\n", i); lm_common_match(sc); return 1; } void lm_common_match(sc) struct lm_softc *sc; { int i; sc->numsensors = LM_NUM_SENSORS; sc->refresh_sensor_data = lm_refresh_sensor_data; for (i = 0; i < 7; ++i) { sc->sensors[i].units = sc->info[i].units = ENVSYS_SVOLTS_DC; sprintf(sc->info[i].desc, "IN %d", i); } /* default correction factors for resistors on higher voltage inputs */ sc->info[0].rfact = sc->info[1].rfact = sc->info[2].rfact = 10000; sc->info[3].rfact = (int)(( 90.9 / 60.4) * 10000); sc->info[4].rfact = (int)(( 38.0 / 10.0) * 10000); sc->info[5].rfact = (int)((210.0 / 60.4) * 10000); sc->info[6].rfact = (int)(( 90.9 / 60.4) * 10000); sc->sensors[7].units = ENVSYS_STEMP; strcpy(sc->info[7].desc, "Temp"); setup_fan(sc, 8, 3); sc->sc_sysmon.sme_streinfo = lm_streinfo; } int wb_match(sc) struct lm_softc *sc; { int i, j; lm_writereg(sc, WB_BANKSEL, WB_BANKSEL_HBAC); j = lm_readreg(sc, WB_VENDID) << 8; lm_writereg(sc, WB_BANKSEL, 0); j |= lm_readreg(sc, WB_VENDID); DPRINTF(("winbond vend id 0x%x\n", j)); if (j != WB_VENDID_WINBOND) return 0; /* read device ID */ lm_writereg(sc, WB_BANKSEL, WB_BANKSEL_B0); j = lm_readreg(sc, WB_BANK0_CHIPID); DPRINTF(("winbond chip id 0x%x\n", j)); switch(j) { case WB_CHIPID_83781: case WB_CHIPID_83781_2: printf(": W83781D\n"); for (i = 0; i < 7; ++i) { sc->sensors[i].units = sc->info[i].units = ENVSYS_SVOLTS_DC; sprintf(sc->info[i].desc, "IN %d", i); } /* default correction factors for higher voltage inputs */ sc->info[0].rfact = sc->info[1].rfact = sc->info[2].rfact = 10000; sc->info[3].rfact = (int)(( 90.9 / 60.4) * 10000); sc->info[4].rfact = (int)(( 38.0 / 10.0) * 10000); sc->info[5].rfact = (int)((210.0 / 60.4) * 10000); sc->info[6].rfact = (int)(( 90.9 / 60.4) * 10000); setup_temp(sc, 7, 3); setup_fan(sc, 10, 3); sc->numsensors = WB83781_NUM_SENSORS; sc->refresh_sensor_data = wb781_refresh_sensor_data; sc->sc_sysmon.sme_streinfo = wb781_streinfo; return 1; case WB_CHIPID_83697: printf(": W83697HF\n"); wb_setup_volt(sc); setup_temp(sc, 9, 2); setup_fan(sc, 11, 3); sc->numsensors = WB83697_NUM_SENSORS; sc->refresh_sensor_data = wb697_refresh_sensor_data; sc->sc_sysmon.sme_streinfo = wb782_streinfo; return 1; break; case WB_CHIPID_83782: printf(": W83782D\n"); break; case WB_CHIPID_83627: printf(": W83627HF\n"); break; default: printf(": unknow winbond chip ID 0x%x\n", j); /* handle as a standart lm7x */ lm_common_match(sc); return 1; } /* common code for the W83782D and W83627HF */ wb_setup_volt(sc); setup_temp(sc, 9, 3); setup_fan(sc, 12, 3); sc->numsensors = WB_NUM_SENSORS; sc->refresh_sensor_data = wb782_refresh_sensor_data; sc->sc_sysmon.sme_streinfo = wb782_streinfo; return 1; } static void wb_setup_volt(sc) struct lm_softc *sc; { sc->sensors[0].units = sc->info[0].units = ENVSYS_SVOLTS_DC; sprintf(sc->info[0].desc, "VCORE A"); sc->info[0].rfact = 10000; sc->sensors[1].units = sc->info[1].units = ENVSYS_SVOLTS_DC; sprintf(sc->info[1].desc, "VCORE B"); sc->info[1].rfact = 10000; sc->sensors[2].units = sc->info[2].units = ENVSYS_SVOLTS_DC; sprintf(sc->info[2].desc, "+3.3V"); sc->info[2].rfact = 10000; sc->sensors[3].units = sc->info[3].units = ENVSYS_SVOLTS_DC; sprintf(sc->info[3].desc, "+5V"); sc->info[3].rfact = 16778; sc->sensors[4].units = sc->info[4].units = ENVSYS_SVOLTS_DC; sprintf(sc->info[4].desc, "+12V"); sc->info[4].rfact = 38000; sc->sensors[5].units = sc->info[5].units = ENVSYS_SVOLTS_DC; sprintf(sc->info[5].desc, "-12V"); sc->info[5].rfact = 10000; sc->sensors[6].units = sc->info[6].units = ENVSYS_SVOLTS_DC; sprintf(sc->info[6].desc, "-5V"); sc->info[6].rfact = 10000; sc->sensors[7].units = sc->info[7].units = ENVSYS_SVOLTS_DC; sprintf(sc->info[7].desc, "+5VSB"); sc->info[7].rfact = 15151; sc->sensors[8].units = sc->info[8].units = ENVSYS_SVOLTS_DC; sprintf(sc->info[8].desc, "VBAT"); sc->info[8].rfact = 10000; } static void setup_temp(sc, start, n) struct lm_softc *sc; int start, n; { int i; for (i = 0; i < n; i++) { sc->sensors[start + i].units = ENVSYS_STEMP; sprintf(sc->info[start + i].desc, "Temp %d", i + 1); } } static void setup_fan(sc, start, n) struct lm_softc *sc; int start, n; { int i; for (i = 0; i < n; ++i) { sc->sensors[start + i].units = ENVSYS_SFANRPM; sc->info[start + i].units = ENVSYS_SFANRPM; sprintf(sc->info[start + i].desc, "Fan %d", i + 1); } } int lm_gtredata(sme, tred) struct sysmon_envsys *sme; struct envsys_tre_data *tred; { static const struct timeval onepointfive = { 1, 500000 }; struct timeval t; struct lm_softc *sc = sme->sme_cookie; int i, s; /* read new values at most once every 1.5 seconds */ timeradd(&sc->lastread, &onepointfive, &t); s = splclock(); i = timercmp(&mono_time, &t, >); if (i) { sc->lastread.tv_sec = mono_time.tv_sec; sc->lastread.tv_usec = mono_time.tv_usec; } splx(s); if (i) sc->refresh_sensor_data(sc); *tred = sc->sensors[tred->sensor]; return (0); } int generic_streinfo_fan(sc, info, n, binfo) struct lm_softc *sc; struct envsys_basic_info *info; int n; struct envsys_basic_info *binfo; { u_int8_t sdata; int divisor; /* FAN1 and FAN2 can have divisors set, but not FAN3 */ if ((sc->info[binfo->sensor].units == ENVSYS_SFANRPM) && (binfo->sensor != 2)) { if (binfo->rpms == 0) { binfo->validflags = 0; return (0); } /* 153 is the nominal FAN speed value */ divisor = 1350000 / (binfo->rpms * 153); /* ...but we need lg(divisor) */ if (divisor <= 1) divisor = 0; else if (divisor <= 2) divisor = 1; else if (divisor <= 4) divisor = 2; else divisor = 3; /* * FAN1 div is in bits <5:4>, FAN2 div is * in <7:6> */ sdata = lm_readreg(sc, LMD_VIDFAN); if ( binfo->sensor == 0 ) { /* FAN1 */ divisor <<= 4; sdata = (sdata & 0xCF) | divisor; } else { /* FAN2 */ divisor <<= 6; sdata = (sdata & 0x3F) | divisor; } lm_writereg(sc, LMD_VIDFAN, sdata); } return (0); } int lm_streinfo(sme, binfo) struct sysmon_envsys *sme; struct envsys_basic_info *binfo; { struct lm_softc *sc = sme->sme_cookie; if (sc->info[binfo->sensor].units == ENVSYS_SVOLTS_DC) sc->info[binfo->sensor].rfact = binfo->rfact; else { if (sc->info[binfo->sensor].units == ENVSYS_SFANRPM) { generic_streinfo_fan(sc, &sc->info[binfo->sensor], binfo->sensor - 8, binfo); } memcpy(sc->info[binfo->sensor].desc, binfo->desc, sizeof(sc->info[binfo->sensor].desc)); sc->info[binfo->sensor].desc[ sizeof(sc->info[binfo->sensor].desc) - 1] = '\0'; binfo->validflags = ENVSYS_FVALID; } return (0); } int wb781_streinfo(sme, binfo) struct sysmon_envsys *sme; struct envsys_basic_info *binfo; { struct lm_softc *sc = sme->sme_cookie; if (sc->info[binfo->sensor].units == ENVSYS_SVOLTS_DC) sc->info[binfo->sensor].rfact = binfo->rfact; else { if (sc->info[binfo->sensor].units == ENVSYS_SFANRPM) { generic_streinfo_fan(sc, &sc->info[binfo->sensor], binfo->sensor - 10, binfo); } memcpy(sc->info[binfo->sensor].desc, binfo->desc, sizeof(sc->info[binfo->sensor].desc)); sc->info[binfo->sensor].desc[ sizeof(sc->info[binfo->sensor].desc) - 1] = '\0'; binfo->validflags = ENVSYS_FVALID; } return (0); } int wb782_streinfo(sme, binfo) struct sysmon_envsys *sme; struct envsys_basic_info *binfo; { struct lm_softc *sc = sme->sme_cookie; int divisor; u_int8_t sdata; int i; if (sc->info[binfo->sensor].units == ENVSYS_SVOLTS_DC) sc->info[binfo->sensor].rfact = binfo->rfact; else { if (sc->info[binfo->sensor].units == ENVSYS_SFANRPM) { if (binfo->rpms == 0) { binfo->validflags = 0; return (0); } /* 153 is the nominal FAN speed value */ divisor = 1350000 / (binfo->rpms * 153); /* ...but we need lg(divisor) */ for (i = 0; i < 7; i++) { if (divisor <= (1 << i)) break; } divisor = i; if (binfo->sensor == 12 || binfo->sensor == 13) { /* * FAN1 div is in bits <5:4>, FAN2 div * is in <7:6> */ sdata = lm_readreg(sc, LMD_VIDFAN); if ( binfo->sensor == 12 ) { /* FAN1 */ sdata = (sdata & 0xCF) | ((divisor & 0x3) << 4); } else { /* FAN2 */ sdata = (sdata & 0x3F) | ((divisor & 0x3) << 6); } lm_writereg(sc, LMD_VIDFAN, sdata); } else { /* FAN3 is in WB_PIN <7:6> */ sdata = lm_readreg(sc, WB_PIN); sdata = (sdata & 0x3F) | ((divisor & 0x3) << 6); lm_writereg(sc, LMD_VIDFAN, sdata); } /* Bit 2 of divisor is in WB_BANK0_FANBAT */ lm_writereg(sc, WB_BANKSEL, WB_BANKSEL_B0); sdata = lm_readreg(sc, WB_BANK0_FANBAT); sdata &= ~(0x20 << (binfo->sensor - 12)); sdata |= (divisor & 0x4) << (binfo->sensor - 9); lm_writereg(sc, WB_BANK0_FANBAT, sdata); } memcpy(sc->info[binfo->sensor].desc, binfo->desc, sizeof(sc->info[binfo->sensor].desc)); sc->info[binfo->sensor].desc[ sizeof(sc->info[binfo->sensor].desc) - 1] = '\0'; binfo->validflags = ENVSYS_FVALID; } return (0); } static void generic_stemp(sc, sensor) struct lm_softc *sc; struct envsys_tre_data *sensor; { int sdata = lm_readreg(sc, LMD_SENSORBASE + 7); DPRINTF(("sdata[temp] 0x%x\n", sdata)); /* temp is given in deg. C, we convert to uK */ sensor->cur.data_us = sdata * 1000000 + 273150000; } static void generic_svolt(sc, sensors, infos) struct lm_softc *sc; struct envsys_tre_data *sensors; struct envsys_basic_info *infos; { int i, sdata; for (i = 0; i < 7; i++) { sdata = lm_readreg(sc, LMD_SENSORBASE + i); DPRINTF(("sdata[volt%d] 0x%x\n", i, sdata)); /* voltage returned as (mV >> 4), we convert to uVDC */ sensors[i].cur.data_s = (sdata << 4); /* rfact is (factor * 10^4) */ sensors[i].cur.data_s *= infos[i].rfact; /* division by 10 gets us back to uVDC */ sensors[i].cur.data_s /= 10; /* these two are negative voltages */ if ( (i == 5) || (i == 6) ) sensors[i].cur.data_s *= -1; } } static void generic_fanrpm(sc, sensors) struct lm_softc *sc; struct envsys_tre_data *sensors; { int i, sdata, divisor; for (i = 0; i < 3; i++) { sdata = lm_readreg(sc, LMD_SENSORBASE + 8 + i); DPRINTF(("sdata[fan%d] 0x%x\n", i, sdata)); if (i == 2) divisor = 2; /* Fixed divisor for FAN3 */ else if (i == 1) /* Bits 7 & 6 of VID/FAN */ divisor = (lm_readreg(sc, LMD_VIDFAN) >> 6) & 0x3; else divisor = (lm_readreg(sc, LMD_VIDFAN) >> 4) & 0x3; if (sdata == 0xff || sdata == 0x00) { sensors[i].cur.data_us = 0; } else { sensors[i].cur.data_us = 1350000 / (sdata << divisor); } } } /* * pre: last read occurred >= 1.5 seconds ago * post: sensors[] current data are the latest from the chip */ void lm_refresh_sensor_data(sc) struct lm_softc *sc; { /* Refresh our stored data for every sensor */ generic_stemp(sc, &sc->sensors[7]); generic_svolt(sc, &sc->sensors[0], &sc->info[0]); generic_fanrpm(sc, &sc->sensors[8]); } static void wb_svolt(sc) struct lm_softc *sc; { int i, sdata; for (i = 0; i < 9; ++i) { if (i < 7) { sdata = lm_readreg(sc, LMD_SENSORBASE + i); } else { /* from bank5 */ lm_writereg(sc, WB_BANKSEL, WB_BANKSEL_B5); sdata = lm_readreg(sc, (i == 7) ? WB_BANK5_5VSB : WB_BANK5_VBAT); } DPRINTF(("sdata[volt%d] 0x%x\n", i, sdata)); /* voltage returned as (mV >> 4), we convert to uV */ sdata = sdata << 4; /* special case for negative voltages */ if (i == 5) { /* * -12Vdc, assume Winbond recommended values for * resistors */ sdata = ((sdata * 1000) - (3600 * 805)) / 195; } else if (i == 6) { /* * -5Vdc, assume Winbond recommended values for * resistors */ sdata = ((sdata * 1000) - (3600 * 682)) / 318; } /* rfact is (factor * 10^4) */ sc->sensors[i].cur.data_s = sdata * sc->info[i].rfact; /* division by 10 gets us back to uVDC */ sc->sensors[i].cur.data_s /= 10; } } static void wb_stemp(sc, sensors, n) struct lm_softc *sc; struct envsys_tre_data *sensors; int n; { int sdata; /* temperatures. Given in dC, we convert to uK */ sdata = lm_readreg(sc, LMD_SENSORBASE + 7); DPRINTF(("sdata[temp0] 0x%x\n", sdata)); sensors[0].cur.data_us = sdata * 1000000 + 273150000; /* from bank1 */ lm_writereg(sc, WB_BANKSEL, WB_BANKSEL_B1); sdata = lm_readreg(sc, WB_BANK1_T2H) << 1; sdata |= (lm_readreg(sc, WB_BANK1_T2L) & 0x80) >> 7; DPRINTF(("sdata[temp1] 0x%x\n", sdata)); sensors[1].cur.data_us = (sdata * 1000000) / 2 + 273150000; if (n < 3) return; /* from bank2 */ lm_writereg(sc, WB_BANKSEL, WB_BANKSEL_B2); sdata = lm_readreg(sc, WB_BANK2_T3H) << 1; sdata |= (lm_readreg(sc, WB_BANK2_T3L) & 0x80) >> 7; DPRINTF(("sdata[temp2] 0x%x\n", sdata)); sensors[2].cur.data_us = (sdata * 1000000) / 2 + 273150000; } static void wb_fanrpm(sc, sensors) struct lm_softc *sc; struct envsys_tre_data *sensors; { int i, divisor, sdata; lm_writereg(sc, WB_BANKSEL, WB_BANKSEL_B0); for (i = 0; i < 3; i++) { sdata = lm_readreg(sc, LMD_SENSORBASE + i + 8); DPRINTF(("sdata[fan%d] 0x%x\n", i, sdata)); if (i == 0) divisor = (lm_readreg(sc, LMD_VIDFAN) >> 4) & 0x3; else if (i == 1) divisor = (lm_readreg(sc, LMD_VIDFAN) >> 6) & 0x3; else divisor = (lm_readreg(sc, WB_PIN) >> 6) & 0x3; divisor |= (lm_readreg(sc, WB_BANK0_FANBAT) >> (i + 3)) & 0x4; DPRINTF(("sdata[%d] 0x%x div 0x%x\n", i, sdata, divisor)); if (sdata == 0xff || sdata == 0x00) { sensors[i].cur.data_us = 0; } else { sensors[i].cur.data_us = 1350000 / (sdata << divisor); } } } void wb781_refresh_sensor_data(sc) struct lm_softc *sc; { /* Refresh our stored data for every sensor */ /* we need to reselect bank0 to access common registers */ lm_writereg(sc, WB_BANKSEL, WB_BANKSEL_B0); generic_svolt(sc, &sc->sensors[0], &sc->info[0]); lm_writereg(sc, WB_BANKSEL, WB_BANKSEL_B0); wb_stemp(sc, &sc->sensors[7], 3); lm_writereg(sc, WB_BANKSEL, WB_BANKSEL_B0); generic_fanrpm(sc, &sc->sensors[10]); } void wb782_refresh_sensor_data(sc) struct lm_softc *sc; { /* Refresh our stored data for every sensor */ wb_svolt(sc); wb_stemp(sc, &sc->sensors[9], 3); wb_fanrpm(sc, &sc->sensors[12]); } void wb697_refresh_sensor_data(sc) struct lm_softc *sc; { /* Refresh our stored data for every sensor */ wb_svolt(sc); wb_stemp(sc, &sc->sensors[9], 2); wb_fanrpm(sc, &sc->sensors[11]); }