/* $OpenBSD: kb3310.c,v 1.16 2010/10/14 21:23:04 pirofti Exp $ */ /* * Copyright (c) 2010 Otto Moerbeek * * 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 #include #include #include #include #include #include #include #include #include #include "apm.h" #include "pckbd.h" #include "hidkbd.h" #if NPCKBD > 0 || NHIDKBD > 0 #include #include #include #endif struct cfdriver ykbec_cd = { NULL, "ykbec", DV_DULL, }; #ifdef KB3310_DEBUG #define DPRINTF(x) printf x #else #define DPRINTF(x) #endif #define IO_YKBEC 0x381 #define IO_YKBECSIZE 0x3 static const struct { const char *desc; int type; } ykbec_table[] = { #define YKBEC_FAN 0 { NULL, SENSOR_FANRPM }, #define YKBEC_ITEMP 1 { "Internal temperature", SENSOR_TEMP }, #define YKBEC_FCAP 2 { "Battery full charge capacity", SENSOR_AMPHOUR }, #define YKBEC_BCURRENT 3 { "Battery current", SENSOR_AMPS }, #define YKBEC_BVOLT 4 { "Battery voltage", SENSOR_VOLTS_DC }, #define YKBEC_BTEMP 5 { "Battery temperature", SENSOR_TEMP }, #define YKBEC_CAP 6 { "Battery capacity", SENSOR_PERCENT }, #define YKBEC_CHARGING 7 { "Battery charging", SENSOR_INDICATOR }, #define YKBEC_AC 8 { "AC-Power", SENSOR_INDICATOR } #define YKBEC_NSENSORS 9 }; struct ykbec_softc { struct device sc_dev; bus_space_tag_t sc_iot; bus_space_handle_t sc_ioh; struct ksensor sc_sensor[YKBEC_NSENSORS]; struct ksensordev sc_sensordev; #if NPCKBD > 0 || NHIDKBD > 0 struct timeout sc_bell_tmo; #endif }; static struct ykbec_softc *ykbec_sc; static int ykbec_chip_config; extern void loongson_set_isa_imr(uint); int ykbec_match(struct device *, void *, void *); void ykbec_attach(struct device *, struct device *, void *); const struct cfattach ykbec_ca = { sizeof(struct ykbec_softc), ykbec_match, ykbec_attach }; int ykbec_apminfo(struct apm_power_info *); void ykbec_bell(void *, u_int, u_int, u_int, int); void ykbec_bell_stop(void *); void ykbec_print_bat_info(struct ykbec_softc *); u_int ykbec_read(struct ykbec_softc *, u_int); u_int ykbec_read16(struct ykbec_softc *, u_int); void ykbec_refresh(void *arg); void ykbec_write(struct ykbec_softc *, u_int, u_int); #if NAPM > 0 struct apm_power_info ykbec_apmdata; const char *ykbec_batstate[] = { "high", "low", "critical", "charging", "unknown" }; #define BATTERY_STRING(x) ((x) < nitems(ykbec_batstate) ? \ ykbec_batstate[x] : ykbec_batstate[4]) #endif int ykbec_match(struct device *parent, void *match, void *aux) { struct isa_attach_args *ia = aux; bus_space_handle_t ioh; if (sys_platform->system_type != LOONGSON_YEELOONG) return (0); if ((ia->ia_iobase != IOBASEUNK && ia->ia_iobase != IO_YKBEC) || /* (ia->ia_iosize != 0 && ia->ia_iosize != IO_YKBECSIZE) || XXX isa.c */ ia->ia_maddr != MADDRUNK || ia->ia_msize != 0 || ia->ia_irq != IRQUNK || ia->ia_drq != DRQUNK) return (0); if (bus_space_map(ia->ia_iot, IO_YKBEC, IO_YKBECSIZE, 0, &ioh)) return (0); bus_space_unmap(ia->ia_iot, ioh, IO_YKBECSIZE); ia->ia_iobase = IO_YKBEC; ia->ia_iosize = IO_YKBECSIZE; return (1); } void ykbec_attach(struct device *parent, struct device *self, void *aux) { struct isa_attach_args *ia = aux; struct ykbec_softc *sc = (struct ykbec_softc *)self; int i; sc->sc_iot = ia->ia_iot; if (bus_space_map(sc->sc_iot, ia->ia_iobase, ia->ia_iosize, 0, &sc->sc_ioh)) { printf(": couldn't map I/O space"); return; } /* Initialize sensor data. */ strlcpy(sc->sc_sensordev.xname, sc->sc_dev.dv_xname, sizeof(sc->sc_sensordev.xname)); if (sensor_task_register(sc, ykbec_refresh, 5) == NULL) { printf(", unable to register update task\n"); return; } #ifdef DEBUG ykbec_print_bat_info(sc); #endif printf("\n"); for (i = 0; i < YKBEC_NSENSORS; i++) { sc->sc_sensor[i].type = ykbec_table[i].type; if (ykbec_table[i].desc) strlcpy(sc->sc_sensor[i].desc, ykbec_table[i].desc, sizeof(sc->sc_sensor[i].desc)); sensor_attach(&sc->sc_sensordev, &sc->sc_sensor[i]); } sensordev_install(&sc->sc_sensordev); #if NAPM > 0 /* make sure we have the apm state initialized before apm attaches */ ykbec_refresh(sc); apm_setinfohook(ykbec_apminfo); #endif #if NPCKBD > 0 || NHIDKBD > 0 timeout_set(&sc->sc_bell_tmo, ykbec_bell_stop, sc); #if NPCKBD > 0 pckbd_hookup_bell(ykbec_bell, sc); #endif #if NHIDKBD > 0 hidkbd_hookup_bell(ykbec_bell, sc); #endif #endif ykbec_sc = sc; } void ykbec_write(struct ykbec_softc *mcsc, u_int reg, u_int datum) { struct ykbec_softc *sc = (struct ykbec_softc *)mcsc; bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; bus_space_write_1(iot, ioh, 0, (reg >> 8) & 0xff); bus_space_write_1(iot, ioh, 1, (reg >> 0) & 0xff); bus_space_write_1(iot, ioh, 2, datum); } u_int ykbec_read(struct ykbec_softc *mcsc, u_int reg) { struct ykbec_softc *sc = (struct ykbec_softc *)mcsc; bus_space_tag_t iot = sc->sc_iot; bus_space_handle_t ioh = sc->sc_ioh; bus_space_write_1(iot, ioh, 0, (reg >> 8) & 0xff); bus_space_write_1(iot, ioh, 1, (reg >> 0) & 0xff); return bus_space_read_1(iot, ioh, 2); } u_int ykbec_read16(struct ykbec_softc *mcsc, u_int reg) { u_int val; val = ykbec_read(mcsc, reg); return (val << 8) | ykbec_read(mcsc, reg + 1); } #define KB3310_FAN_SPEED_DIVIDER 480000 #define ECTEMP_CURRENT_REG 0xf458 #define REG_FAN_SPEED_HIGH 0xfe22 #define REG_FAN_SPEED_LOW 0xfe23 #define REG_DESIGN_CAP_HIGH 0xf77d #define REG_DESIGN_CAP_LOW 0xf77e #define REG_FULLCHG_CAP_HIGH 0xf780 #define REG_FULLCHG_CAP_LOW 0xf781 #define REG_DESIGN_VOL_HIGH 0xf782 #define REG_DESIGN_VOL_LOW 0xf783 #define REG_CURRENT_HIGH 0xf784 #define REG_CURRENT_LOW 0xf785 #define REG_VOLTAGE_HIGH 0xf786 #define REG_VOLTAGE_LOW 0xf787 #define REG_TEMPERATURE_HIGH 0xf788 #define REG_TEMPERATURE_LOW 0xf789 #define REG_RELATIVE_CAT_HIGH 0xf492 #define REG_RELATIVE_CAT_LOW 0xf493 #define REG_BAT_VENDOR 0xf4c4 #define REG_BAT_CELL_COUNT 0xf4c6 #define REG_BAT_CHARGE 0xf4a2 #define BAT_CHARGE_AC 0x00 #define BAT_CHARGE_DISCHARGE 0x01 #define BAT_CHARGE_CHARGE 0x02 #define REG_POWER_FLAG 0xf440 #define POWER_FLAG_ADAPTER_IN (1<<0) #define POWER_FLAG_POWER_ON (1<<1) #define POWER_FLAG_ENTER_SUS (1<<2) #define REG_BAT_STATUS 0xf4b0 #define BAT_STATUS_BAT_EXISTS (1<<0) #define BAT_STATUS_BAT_FULL (1<<1) #define BAT_STATUS_BAT_DESTROY (1<<2) #define BAT_STATUS_BAT_LOW (1<<5) #define REG_CHARGE_STATUS 0xf4b1 #define CHARGE_STATUS_PRECHARGE (1<<1) #define CHARGE_STATUS_OVERHEAT (1<<2) #define REG_BAT_STATE 0xf482 #define BAT_STATE_DISCHARGING (1<<0) #define BAT_STATE_CHARGING (1<<1) #define REG_BEEP_CONTROL 0xf4d0 #define BEEP_ENABLE (1<<0) #define REG_PMUCFG 0xff0c #define PMUCFG_STOP_MODE (1<<7) #define PMUCFG_IDLE_MODE (1<<6) #define PMUCFG_LPC_WAKEUP (1<<5) #define PMUCFG_RESET_8051 (1<<4) #define PMUCFG_SCI_WAKEUP (1<<3) #define PMUCFG_WDT_WAKEUP (1<<2) #define PMUCFG_GPWU_WAKEUP (1<<1) #define PMUCFG_IRQ_IDLE (1<<0) #define REG_USB0 0xf461 #define REG_USB1 0xf462 #define REG_USB2 0xf463 #define USB_FLAG_ON 1 #define USB_FLAG_OFF 0 #define REG_FAN_CONTROL 0xf4d2 #define REG_FAN_ON 1 #define REG_FAN_OFF 0 #define YKBEC_SCI_IRQ 0xa #ifdef DEBUG void ykbec_print_bat_info(struct ykbec_softc *sc) { uint bat_status, count, dvolt, dcap; printf(": battery "); bat_status = ykbec_read(sc, REG_BAT_STATUS); if (!ISSET(bat_status, BAT_STATUS_BAT_EXISTS)) { printf("absent"); return; } count = ykbec_read(sc, REG_BAT_CELL_COUNT); dvolt = ykbec_read16(sc, REG_DESIGN_VOL_HIGH); dcap = ykbec_read16(sc, REG_DESIGN_CAP_HIGH); printf("%d cells, design capacity %dmV %dmAh", count, dvolt, dcap); } #endif void ykbec_refresh(void *arg) { struct ykbec_softc *sc = (struct ykbec_softc *)arg; u_int val, bat_charge, bat_status, charge_status, bat_state, power_flag; u_int cap_pct, fullcap; int current; #if NAPM > 0 struct apm_power_info old; #endif val = ykbec_read16(sc, REG_FAN_SPEED_HIGH) & 0xfffff; if (val != 0) { val = KB3310_FAN_SPEED_DIVIDER / val; sc->sc_sensor[YKBEC_FAN].value = val; CLR(sc->sc_sensor[YKBEC_FAN].flags, SENSOR_FINVALID); } else SET(sc->sc_sensor[YKBEC_FAN].flags, SENSOR_FINVALID); val = ykbec_read(sc, ECTEMP_CURRENT_REG); sc->sc_sensor[YKBEC_ITEMP].value = val * 1000000 + 273150000; fullcap = ykbec_read16(sc, REG_FULLCHG_CAP_HIGH); sc->sc_sensor[YKBEC_FCAP].value = fullcap * 1000; current = ykbec_read16(sc, REG_CURRENT_HIGH); /* sign extend short -> int, int -> int64 will be done next statement */ current |= -(current & 0x8000); sc->sc_sensor[YKBEC_BCURRENT].value = -1000 * current; sc->sc_sensor[YKBEC_BVOLT].value = ykbec_read16(sc, REG_VOLTAGE_HIGH) * 1000; val = ykbec_read16(sc, REG_TEMPERATURE_HIGH); sc->sc_sensor[YKBEC_BTEMP].value = val * 1000000 + 273150000; cap_pct = ykbec_read16(sc, REG_RELATIVE_CAT_HIGH); sc->sc_sensor[YKBEC_CAP].value = cap_pct * 1000; bat_charge = ykbec_read(sc, REG_BAT_CHARGE); bat_status = ykbec_read(sc, REG_BAT_STATUS); charge_status = ykbec_read(sc, REG_CHARGE_STATUS); bat_state = ykbec_read(sc, REG_BAT_STATE); power_flag = ykbec_read(sc, REG_POWER_FLAG); sc->sc_sensor[YKBEC_CHARGING].value = !!ISSET(bat_state, BAT_STATE_CHARGING); sc->sc_sensor[YKBEC_AC].value = !!ISSET(power_flag, POWER_FLAG_ADAPTER_IN); sc->sc_sensor[YKBEC_CAP].status = ISSET(bat_status, BAT_STATUS_BAT_LOW) ? SENSOR_S_CRIT : SENSOR_S_OK; #if NAPM > 0 bcopy(&ykbec_apmdata, &old, sizeof(old)); ykbec_apmdata.battery_life = cap_pct; ykbec_apmdata.ac_state = ISSET(power_flag, POWER_FLAG_ADAPTER_IN) ? APM_AC_ON : APM_AC_OFF; if (!ISSET(bat_status, BAT_STATUS_BAT_EXISTS)) { ykbec_apmdata.battery_state = APM_BATTERY_ABSENT; ykbec_apmdata.minutes_left = 0; ykbec_apmdata.battery_life = 0; } else { if (ISSET(bat_state, BAT_STATE_CHARGING)) ykbec_apmdata.battery_state = APM_BATT_CHARGING; else if (ISSET(bat_status, BAT_STATUS_BAT_LOW)) ykbec_apmdata.battery_state = APM_BATT_CRITICAL; /* XXX arbitrary */ else if (cap_pct > 60) ykbec_apmdata.battery_state = APM_BATT_HIGH; else ykbec_apmdata.battery_state = APM_BATT_LOW; /* if charging, current is positive */ if (ISSET(bat_state, BAT_STATE_CHARGING)) current = 0; else current = -current; /* XXX Yeeloong draw is about 1A */ if (current <= 0) current = 1000; /* XXX at 5?%, the Yeeloong shuts down */ if (cap_pct <= 5) cap_pct = 0; else cap_pct -= 5; fullcap = cap_pct * 60 * fullcap / 100; ykbec_apmdata.minutes_left = fullcap / current; } if (old.ac_state != ykbec_apmdata.ac_state) apm_record_event(APM_POWER_CHANGE, "AC power", ykbec_apmdata.ac_state ? "restored" : "lost"); if (old.battery_state != ykbec_apmdata.battery_state) apm_record_event(APM_POWER_CHANGE, "battery", BATTERY_STRING(ykbec_apmdata.battery_state)); #endif } #if NAPM > 0 int ykbec_apminfo(struct apm_power_info *info) { bcopy(&ykbec_apmdata, info, sizeof(struct apm_power_info)); return 0; } int ykbec_suspend() { struct ykbec_softc *sc = ykbec_sc; int ctrl; /* * Set up wakeup sources: currently only the internal keyboard. */ loongson_set_isa_imr(1 << 1); /* USB */ DPRINTF(("USB\n")); ykbec_write(sc, REG_USB0, USB_FLAG_OFF); ykbec_write(sc, REG_USB1, USB_FLAG_OFF); ykbec_write(sc, REG_USB2, USB_FLAG_OFF); /* EC */ DPRINTF(("REG_PMUCFG\n")); ctrl = PMUCFG_SCI_WAKEUP | PMUCFG_WDT_WAKEUP | PMUCFG_GPWU_WAKEUP | PMUCFG_LPC_WAKEUP | PMUCFG_STOP_MODE | PMUCFG_RESET_8051; ykbec_write(sc, REG_PMUCFG, ctrl); /* FAN */ DPRINTF(("FAN\n")); ykbec_write(sc, REG_FAN_CONTROL, REG_FAN_OFF); /* CPU */ DPRINTF(("CPU\n")); ykbec_chip_config = REGVAL(LOONGSON_CHIP_CONFIG0); enableintr(); REGVAL(LOONGSON_CHIP_CONFIG0) = ykbec_chip_config & ~0x7; (void)REGVAL(LOONGSON_CHIP_CONFIG0); /* * When a resume interrupt fires, we will enter the interrupt * dispatcher, which will do nothing because we are at splhigh, * and execution flow will return here and continue. */ (void)disableintr(); return 0; } int ykbec_resume() { struct ykbec_softc *sc = ykbec_sc; /* CPU */ DPRINTF(("CPU\n")); REGVAL(LOONGSON_CHIP_CONFIG0) = ykbec_chip_config; (void)REGVAL(LOONGSON_CHIP_CONFIG0); /* FAN */ DPRINTF(("FAN\n")); ykbec_write(sc, REG_FAN_CONTROL, REG_FAN_ON); /* USB */ DPRINTF(("USB\n")); ykbec_write(sc, REG_USB0, USB_FLAG_ON); ykbec_write(sc, REG_USB1, USB_FLAG_ON); ykbec_write(sc, REG_USB2, USB_FLAG_ON); ykbec_refresh(sc); return 0; } #endif #if NPCKBD > 0 || NHIDKBD > 0 void ykbec_bell(void *arg, u_int pitch, u_int period, u_int volume, int poll) { struct ykbec_softc *sc = (struct ykbec_softc *)arg; int bctrl; int s; s = spltty(); bctrl = ykbec_read(sc, REG_BEEP_CONTROL); if (volume == 0 || timeout_pending(&sc->sc_bell_tmo)) { timeout_del(&sc->sc_bell_tmo); /* inline ykbec_bell_stop(arg); */ ykbec_write(sc, REG_BEEP_CONTROL, bctrl & ~BEEP_ENABLE); } if (volume != 0) { ykbec_write(sc, REG_BEEP_CONTROL, bctrl | BEEP_ENABLE); if (poll) { delay(period * 1000); ykbec_write(sc, REG_BEEP_CONTROL, bctrl & ~BEEP_ENABLE); } else { timeout_add_msec(&sc->sc_bell_tmo, period); } } splx(s); } void ykbec_bell_stop(void *arg) { struct ykbec_softc *sc = (struct ykbec_softc *)arg; int s; s = spltty(); ykbec_write(sc, REG_BEEP_CONTROL, ykbec_read(sc, REG_BEEP_CONTROL) & ~BEEP_ENABLE); splx(s); } #endif