zaurus/dev/scoop.c

1.9  dyoung /*	$NetBSD: scoop.c,v 1.9 2011/07/19 15:11:49 dyoung Exp $	*/
1.1    ober /*	$OpenBSD: zaurus_scoop.c,v 1.12 2005/11/17 05:26:31 uwe Exp $	*/
1.1    ober
1.1    ober /*
1.1    ober  * Copyright (c) 2005 Uwe Stuehler <uwe (at) bsdx.de>
1.1    ober  *
1.1    ober  * Permission to use, copy, modify, and distribute this software for any
1.1    ober  * purpose with or without fee is hereby granted, provided that the above
1.1    ober  * copyright notice and this permission notice appear in all copies.
1.1    ober  *
1.1    ober  * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
1.1    ober  * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
1.1    ober  * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
1.1    ober  * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
1.1    ober  * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
1.1    ober  * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
1.1    ober  * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
1.1    ober  */
1.1    ober
1.1    ober #include <sys/cdefs.h>
1.9  dyoung __KERNEL_RCSID(0, "$NetBSD: scoop.c,v 1.9 2011/07/19 15:11:49 dyoung Exp $");
1.1    ober
1.1    ober #include <sys/param.h>
1.1    ober #include <sys/systm.h>
1.1    ober #include <sys/device.h>
1.1    ober #include <sys/conf.h>
1.1    ober #include <sys/gpio.h>
1.9  dyoung #include <sys/bus.h>
1.1    ober
1.1    ober #include <arm/xscale/pxa2x0var.h>
1.1    ober
1.1    ober #include <zaurus/zaurus/zaurus_reg.h>
1.1    ober #include <zaurus/zaurus/zaurus_var.h>
1.1    ober
1.1    ober #include <zaurus/dev/scoopreg.h>
1.1    ober #include <zaurus/dev/scoopvar.h>
1.1    ober
1.1    ober #include "ioconf.h"
1.1    ober
1.1    ober struct scoop_softc {
1.6  nonaka 	device_t		sc_dev;
1.2   peter
1.2   peter 	bus_space_tag_t		sc_iot;
1.2   peter 	bus_space_handle_t	sc_ioh;
1.2   peter
1.2   peter 	uint16_t		sc_gpwr;	/* GPIO state before suspend */
1.1    ober };
1.1    ober
1.6  nonaka static int	scoopmatch(device_t, cfdata_t, void *);
1.6  nonaka static void	scoopattach(device_t, device_t, void *);
1.1    ober
1.6  nonaka CFATTACH_DECL_NEW(scoop, sizeof(struct scoop_softc),
1.6  nonaka     scoopmatch, scoopattach, NULL, NULL);
1.1    ober
1.2   peter #if 0
1.6  nonaka static int	scoop_gpio_pin_read(struct scoop_softc *, int);
1.2   peter #endif
1.6  nonaka static void	scoop_gpio_pin_write(struct scoop_softc *, int, int);
1.6  nonaka static void	scoop_gpio_pin_ctl(struct scoop_softc *, int, int);
1.1    ober
1.3  nonaka enum scoop_card {
1.3  nonaka 	SD_CARD,
1.3  nonaka 	CF_CARD		/* socket 0 (external) */
1.3  nonaka };
1.3  nonaka
1.3  nonaka static void	scoop0_set_card_power(enum scoop_card card, int new_cpr);
1.3  nonaka
1.1    ober static int
1.6  nonaka scoopmatch(device_t parent, cfdata_t cf, void *aux)
1.1    ober {
1.1    ober
1.1    ober 	/*
1.1    ober 	 * Only C3000-like models are known to have two SCOOPs.
1.1    ober 	 */
1.1    ober         if (ZAURUS_ISC3000)
1.1    ober 		return (cf->cf_unit < 2);
1.1    ober 	return (cf->cf_unit == 0);
1.1    ober }
1.1    ober
1.1    ober static void
1.6  nonaka scoopattach(device_t parent, device_t self, void *aux)
1.1    ober {
1.6  nonaka 	struct scoop_softc *sc = device_private(self);
1.1    ober 	struct pxaip_attach_args *pxa = (struct pxaip_attach_args *)aux;
1.1    ober 	bus_addr_t addr;
1.1    ober 	bus_size_t size;
1.1    ober
1.6  nonaka 	sc->sc_dev = self;
1.1    ober 	sc->sc_iot = pxa->pxa_iot;
1.1    ober
1.6  nonaka 	aprint_normal(": PCMCIA/GPIO controller\n");
1.6  nonaka 	aprint_naive("\n");
1.6  nonaka
1.1    ober 	if (pxa->pxa_addr != -1)
1.1    ober 		addr = pxa->pxa_addr;
1.6  nonaka 	else if (sc->sc_dev->dv_unit == 0)
1.1    ober 		addr = C3000_SCOOP0_BASE;
1.1    ober 	else
1.1    ober 		addr = C3000_SCOOP1_BASE;
1.1    ober
1.1    ober 	size = pxa->pxa_size < SCOOP_SIZE ? SCOOP_SIZE : pxa->pxa_size;
1.1    ober
1.1    ober 	if (bus_space_map(sc->sc_iot, addr, size, 0, &sc->sc_ioh) != 0) {
1.6  nonaka 		aprint_error_dev(sc->sc_dev, "couldn't map registers\n");
1.1    ober 		return;
1.1    ober 	}
1.1    ober
1.6  nonaka 	if (ZAURUS_ISC3000 && sc->sc_dev->dv_unit == 1) {
1.1    ober 		scoop_gpio_pin_ctl(sc, SCOOP1_AKIN_PULLUP, GPIO_PIN_OUTPUT);
1.1    ober 		scoop_gpio_pin_write(sc, SCOOP1_AKIN_PULLUP, GPIO_PIN_LOW);
1.8  nonaka 	} else if (ZAURUS_ISC860) {
1.1    ober 		scoop_gpio_pin_ctl(sc, SCOOP0_AKIN_PULLUP, GPIO_PIN_OUTPUT);
1.1    ober 		scoop_gpio_pin_write(sc, SCOOP0_AKIN_PULLUP, GPIO_PIN_LOW);
1.1    ober 	}
1.1    ober }
1.1    ober
1.2   peter #if 0
1.2   peter static int
1.1    ober scoop_gpio_pin_read(struct scoop_softc *sc, int pin)
1.1    ober {
1.1    ober 	uint16_t bit = (1 << pin);
1.1    ober 	uint16_t rv;
1.1    ober
1.1    ober 	rv = bus_space_read_2(sc->sc_iot, sc->sc_ioh, SCOOP_GPWR);
1.2   peter 	return (rv & bit) ? 1 : 0;
1.1    ober }
1.2   peter #endif
1.1    ober
1.2   peter static void
1.1    ober scoop_gpio_pin_write(struct scoop_softc *sc, int pin, int level)
1.1    ober {
1.1    ober 	uint16_t bit = (1 << pin);
1.1    ober 	uint16_t rv;
1.1    ober
1.1    ober 	rv = bus_space_read_2(sc->sc_iot, sc->sc_ioh, SCOOP_GPWR);
1.1    ober 	bus_space_write_2(sc->sc_iot, sc->sc_ioh, SCOOP_GPWR,
1.2   peter 	    (level == GPIO_PIN_LOW) ? (rv & ~bit) : (rv | bit));
1.1    ober }
1.1    ober
1.2   peter static void
1.1    ober scoop_gpio_pin_ctl(struct scoop_softc *sc, int pin, int flags)
1.1    ober {
1.1    ober 	uint16_t bit = (1 << pin);
1.1    ober 	uint16_t rv;
1.1    ober
1.1    ober 	rv = bus_space_read_2(sc->sc_iot, sc->sc_ioh, SCOOP_GPCR);
1.1    ober 	switch (flags & (GPIO_PIN_INPUT|GPIO_PIN_OUTPUT)) {
1.1    ober 	case GPIO_PIN_INPUT:
1.1    ober 		rv &= ~bit;
1.1    ober 		break;
1.1    ober 	case GPIO_PIN_OUTPUT:
1.1    ober 		rv |= bit;
1.1    ober 		break;
1.1    ober 	}
1.1    ober 	bus_space_write_2(sc->sc_iot, sc->sc_ioh, SCOOP_GPCR, rv);
1.1    ober }
1.1    ober
1.1    ober /*
1.1    ober  * Turn the LCD background light and contrast signal on or off.
1.1    ober  */
1.1    ober void
1.1    ober scoop_set_backlight(int on, int cont)
1.1    ober {
1.5  cegger 	struct scoop_softc *sc;
1.5  cegger #if 0
1.5  cegger 	struct scoop_softc *sc0;
1.5  cegger
1.5  cegger 	sc0 = device_lookup_private(&scoop_cd, 0);
1.5  cegger #endif
1.1    ober
1.5  cegger 	sc = device_lookup_private(&scoop_cd, 1);
1.5  cegger 	if (sc != NULL) {
1.1    ober 		/* C3000 */
1.8  nonaka 		scoop_gpio_pin_write(sc, SCOOP1_BACKLIGHT_CONT, !cont);
1.8  nonaka 		scoop_gpio_pin_write(sc, SCOOP1_BACKLIGHT_ON, on);
1.1    ober 	}
1.1    ober #if 0
1.5  cegger 	else if (sc0 != NULL) {
1.5  cegger 		scoop_gpio_pin_write(sc0,
1.1    ober 		    SCOOP0_BACKLIGHT_CONT, cont);
1.1    ober 	}
1.1    ober #endif
1.1    ober }
1.1    ober
1.1    ober /*
1.1    ober  * Turn the infrared LED on or off (must be on while transmitting).
1.1    ober  */
1.1    ober void
1.1    ober scoop_set_irled(int on)
1.1    ober {
1.5  cegger 	struct scoop_softc *sc;
1.2   peter
1.5  cegger 	sc = device_lookup_private(&scoop_cd, 1);
1.5  cegger 	if (sc != NULL) {
1.1    ober 		/* IR_ON is inverted */
1.8  nonaka 		scoop_gpio_pin_write(sc, SCOOP1_IR_ON, !on);
1.2   peter 	}
1.1    ober }
1.1    ober
1.1    ober /*
1.1    ober  * Turn the green and orange LEDs on or off.  If the orange LED is on,
1.1    ober  * then it is wired to indicate if A/C is connected.  The green LED has
1.1    ober  * no such predefined function.
1.1    ober  */
1.1    ober void
1.1    ober scoop_led_set(int led, int on)
1.1    ober {
1.5  cegger 	struct scoop_softc *sc;
1.1    ober
1.5  cegger 	sc = device_lookup_private(&scoop_cd, 0);
1.5  cegger 	if (sc != NULL) {
1.1    ober 		if ((led & SCOOP_LED_GREEN) != 0) {
1.8  nonaka 			scoop_gpio_pin_write(sc, SCOOP0_LED_GREEN, on);
1.1    ober 		}
1.1    ober 		if (scoop_cd.cd_ndevs > 1 && (led & SCOOP_LED_ORANGE) != 0) {
1.8  nonaka 			scoop_gpio_pin_write(sc, SCOOP0_LED_ORANGE_C3000, on);
1.1    ober 		}
1.1    ober 	}
1.1    ober }
1.1    ober
1.1    ober /*
1.1    ober  * Enable or disable the headphone output connection.
1.1    ober  */
1.1    ober void
1.1    ober scoop_set_headphone(int on)
1.1    ober {
1.5  cegger 	struct scoop_softc *sc;
1.1    ober
1.5  cegger 	sc = device_lookup_private(&scoop_cd, 0);
1.5  cegger 	if (sc == NULL)
1.1    ober 		return;
1.1    ober
1.8  nonaka 	scoop_gpio_pin_ctl(sc, SCOOP0_MUTE_L, GPIO_PIN_OUTPUT);
1.8  nonaka 	scoop_gpio_pin_ctl(sc, SCOOP0_MUTE_R, GPIO_PIN_OUTPUT);
1.1    ober
1.1    ober 	if (on) {
1.8  nonaka 		scoop_gpio_pin_write(sc, SCOOP0_MUTE_L, GPIO_PIN_HIGH);
1.8  nonaka 		scoop_gpio_pin_write(sc, SCOOP0_MUTE_R, GPIO_PIN_HIGH);
1.1    ober 	} else {
1.8  nonaka 		scoop_gpio_pin_write(sc, SCOOP0_MUTE_L, GPIO_PIN_LOW);
1.8  nonaka 		scoop_gpio_pin_write(sc, SCOOP0_MUTE_R, GPIO_PIN_LOW);
1.1    ober 	}
1.1    ober }
1.1    ober
1.1    ober /*
1.7  nonaka  * Enable or disable the mic bias
1.7  nonaka  */
1.7  nonaka void
1.7  nonaka scoop_set_mic_bias(int onoff)
1.7  nonaka {
1.7  nonaka 	struct scoop_softc *sc1;
1.7  nonaka
1.7  nonaka 	sc1 = device_lookup_private(&scoop_cd, 1);
1.7  nonaka 	if (sc1 != NULL)
1.7  nonaka 		scoop_gpio_pin_write(sc1, SCOOP1_MIC_BIAS, onoff);
1.7  nonaka }
1.7  nonaka
1.7  nonaka /*
1.1    ober  * Turn on pullup resistor while not reading the remote control.
1.1    ober  */
1.1    ober void
1.1    ober scoop_akin_pullup(int enable)
1.1    ober {
1.5  cegger 	struct scoop_softc *sc0;
1.5  cegger 	struct scoop_softc *sc1;
1.5  cegger
1.5  cegger 	sc0 = device_lookup_private(&scoop_cd, 0);
1.5  cegger 	sc1 = device_lookup_private(&scoop_cd, 1);
1.1    ober
1.5  cegger 	if (sc1 != NULL) {
1.8  nonaka 		scoop_gpio_pin_write(sc1, SCOOP1_AKIN_PULLUP, enable);
1.5  cegger 	} else if (sc0 != NULL) {
1.8  nonaka 		scoop_gpio_pin_write(sc0, SCOOP0_AKIN_PULLUP, enable);
1.1    ober 	}
1.1    ober }
1.1    ober
1.1    ober void
1.1    ober scoop_battery_temp_adc(int enable)
1.1    ober {
1.5  cegger 	struct scoop_softc *sc;
1.5  cegger
1.5  cegger 	sc = device_lookup_private(&scoop_cd, 0);
1.1    ober
1.5  cegger 	if (sc != NULL) {
1.8  nonaka 		scoop_gpio_pin_write(sc, SCOOP0_ADC_TEMP_ON_C3000, enable);
1.1    ober 	}
1.1    ober }
1.1    ober
1.1    ober void
1.1    ober scoop_charge_battery(int enable, int voltage_high)
1.1    ober {
1.5  cegger 	struct scoop_softc *sc;
1.5  cegger
1.5  cegger 	sc = device_lookup_private(&scoop_cd, 0);
1.1    ober
1.5  cegger 	if (sc != NULL) {
1.8  nonaka 		scoop_gpio_pin_write(sc, SCOOP0_JK_B_C3000, voltage_high);
1.8  nonaka 		scoop_gpio_pin_write(sc, SCOOP0_CHARGE_OFF_C3000, !enable);
1.1    ober 	}
1.1    ober }
1.1    ober
1.1    ober void
1.1    ober scoop_discharge_battery(int enable)
1.1    ober {
1.5  cegger 	struct scoop_softc *sc;
1.1    ober
1.5  cegger 	sc = device_lookup_private(&scoop_cd, 0);
1.5  cegger
1.5  cegger 	if (sc != NULL) {
1.8  nonaka 		scoop_gpio_pin_write(sc, SCOOP0_JK_A_C3000, enable);
1.1    ober 	}
1.1    ober }
1.1    ober
1.3  nonaka /*
1.3  nonaka  * Enable or disable 3.3V power to the SD/MMC card slot.
1.3  nonaka  */
1.3  nonaka void
1.3  nonaka scoop_set_sdmmc_power(int on)
1.3  nonaka {
1.3  nonaka
1.3  nonaka 	scoop0_set_card_power(SD_CARD, on ? SCP_CPR_SD_3V : SCP_CPR_OFF);
1.3  nonaka }
1.3  nonaka
1.3  nonaka /*
1.3  nonaka  * The Card Power Register of the first SCOOP unit controls the power
1.3  nonaka  * for the first CompactFlash slot and the SD/MMC card slot as well.
1.3  nonaka  */
1.2   peter void
1.3  nonaka scoop0_set_card_power(enum scoop_card card, int new_cpr)
1.2   peter {
1.2   peter 	struct scoop_softc *sc;
1.2   peter 	bus_space_tag_t iot;
1.2   peter 	bus_space_handle_t ioh;
1.3  nonaka 	uint16_t cpr;
1.2   peter
1.5  cegger 	sc = device_lookup_private(&scoop_cd, 0);
1.5  cegger 	if (sc == NULL)
1.3  nonaka 		return;
1.2   peter
1.3  nonaka 	iot = sc->sc_iot;
1.3  nonaka 	ioh = sc->sc_ioh;
1.3  nonaka
1.3  nonaka 	cpr = bus_space_read_2(iot, ioh, SCOOP_CPR);
1.3  nonaka 	if (new_cpr & SCP_CPR_VOLTAGE_MSK) {
1.3  nonaka 		if (card == CF_CARD)
1.3  nonaka 			cpr |= SCP_CPR_5V;
1.3  nonaka 		else if (card == SD_CARD)
1.3  nonaka 			cpr |= SCP_CPR_SD_3V;
1.3  nonaka
1.3  nonaka 		scoop_gpio_pin_write(sc, SCOOP0_CF_POWER_C3000, 1);
1.3  nonaka 		if (!ISSET(cpr, SCP_CPR_5V) && !ISSET(cpr, SCP_CPR_SD_3V))
1.3  nonaka 			delay(5000);
1.3  nonaka 		bus_space_write_2(iot, ioh, SCOOP_CPR, cpr | new_cpr);
1.3  nonaka 	} else {
1.3  nonaka 		if (card == CF_CARD)
1.3  nonaka 			cpr &= ~SCP_CPR_5V;
1.3  nonaka 		else if (card == SD_CARD)
1.3  nonaka 			cpr &= ~SCP_CPR_SD_3V;
1.3  nonaka
1.3  nonaka 		if (!ISSET(cpr, SCP_CPR_5V) && !ISSET(cpr, SCP_CPR_SD_3V)) {
1.3  nonaka 			bus_space_write_2(iot, ioh, SCOOP_CPR, SCP_CPR_OFF);
1.3  nonaka 			delay(1000);
1.3  nonaka 			scoop_gpio_pin_write(sc, SCOOP0_CF_POWER_C3000, 0);
1.3  nonaka 		} else
1.3  nonaka 			bus_space_write_2(iot, ioh, SCOOP_CPR, cpr | new_cpr);
1.2   peter 	}
1.2   peter }
1.2   peter
1.1    ober void
1.1    ober scoop_check_mcr(void)
1.1    ober {
1.5  cegger 	struct scoop_softc *sc0, *sc1, *sc;
1.1    ober 	uint16_t v;
1.1    ober
1.5  cegger 	sc0 = device_lookup_private(&scoop_cd, 0);
1.5  cegger 	sc1 = device_lookup_private(&scoop_cd, 1);
1.5  cegger
1.1    ober 	/* C3000 */
1.5  cegger 	if (sc1 != NULL) {
1.5  cegger 		sc = sc0;
1.1    ober 		v = bus_space_read_2(sc->sc_iot, sc->sc_ioh, SCOOP_MCR);
1.1    ober 		if ((v & 0x100) == 0) {
1.1    ober 			bus_space_write_2(sc->sc_iot, sc->sc_ioh, SCOOP_MCR,
1.1    ober 			    0x0101);
1.1    ober 		}
1.1    ober
1.5  cegger 		sc = sc1;
1.1    ober 		v = bus_space_read_2(sc->sc_iot, sc->sc_ioh, SCOOP_MCR);
1.1    ober 		if ((v & 0x100) == 0) {
1.1    ober 			bus_space_write_2(sc->sc_iot, sc->sc_ioh, SCOOP_MCR,
1.1    ober 			    0x0101);
1.1    ober 		}
1.1    ober 	}
1.1    ober }
1.1    ober
1.1    ober void
1.1    ober scoop_suspend(void)
1.1    ober {
1.5  cegger 	struct scoop_softc *sc, *sc0, *sc1;
1.1    ober 	uint32_t rv;
1.1    ober
1.5  cegger 	sc0 = device_lookup_private(&scoop_cd, 0);
1.5  cegger 	sc1 = device_lookup_private(&scoop_cd, 1);
1.5  cegger
1.5  cegger 	if (sc0 != NULL) {
1.5  cegger 		sc = sc0;
1.1    ober 		sc->sc_gpwr = bus_space_read_2(sc->sc_iot, sc->sc_ioh,
1.1    ober 		    SCOOP_GPWR);
1.1    ober 		/* C3000 */
1.1    ober 		bus_space_write_2(sc->sc_iot, sc->sc_ioh, SCOOP_GPWR,
1.1    ober 		    sc->sc_gpwr & ~((1<<SCOOP0_MUTE_L) | (1<<SCOOP0_MUTE_R) |
1.1    ober 		    (1<<SCOOP0_JK_A_C3000) | (1<<SCOOP0_ADC_TEMP_ON_C3000) |
1.1    ober 		    (1<<SCOOP0_LED_GREEN)));
1.1    ober 	}
1.1    ober
1.1    ober 	/* C3000 */
1.5  cegger 	if (sc1 != NULL) {
1.5  cegger 		sc = sc1;
1.1    ober 		sc->sc_gpwr = bus_space_read_2(sc->sc_iot, sc->sc_ioh,
1.1    ober 		    SCOOP_GPWR);
1.1    ober 		bus_space_write_2(sc->sc_iot, sc->sc_ioh, SCOOP_GPWR,
1.1    ober 		    sc->sc_gpwr & ~((1<<SCOOP1_RESERVED_4) |
1.1    ober 		    (1<<SCOOP1_RESERVED_5) | (1<<SCOOP1_RESERVED_6) |
1.1    ober 		    (1<<SCOOP1_BACKLIGHT_CONT) | (1<<SCOOP1_BACKLIGHT_ON) |
1.1    ober 		    (1<<SCOOP1_MIC_BIAS)));
1.1    ober 		rv = bus_space_read_2(sc->sc_iot, sc->sc_ioh, SCOOP_GPWR);
1.1    ober 		bus_space_write_2(sc->sc_iot, sc->sc_ioh, SCOOP_GPWR,
1.1    ober 		    rv | ((1<<SCOOP1_IR_ON) | (1<<SCOOP1_RESERVED_3)));
1.1    ober 	}
1.1    ober }
1.1    ober
1.1    ober void
1.1    ober scoop_resume(void)
1.1    ober {
1.5  cegger 	struct scoop_softc *sc, *sc0, *sc1;
1.5  cegger
1.5  cegger 	sc0 = device_lookup_private(&scoop_cd, 0);
1.5  cegger 	sc1 = device_lookup_private(&scoop_cd, 1);
1.1    ober
1.5  cegger 	if (sc0 != NULL) {
1.5  cegger 		sc = sc0;
1.1    ober 		bus_space_write_2(sc->sc_iot, sc->sc_ioh, SCOOP_GPWR,
1.1    ober 		    sc->sc_gpwr);
1.1    ober 	}
1.1    ober
1.5  cegger 	if (sc1 != NULL) {
1.5  cegger 		sc = sc1;
1.1    ober 		bus_space_write_2(sc->sc_iot, sc->sc_ioh, SCOOP_GPWR,
1.1    ober 		    sc->sc_gpwr);
1.1    ober 	}
1.1    ober }