dev/isa/sbdsp.c

1.40       jtk /*	$NetBSD: sbdsp.c,v 1.40 1997/03/29 05:41:28 jtk Exp $	*/
 1.1    brezak
 1.1    brezak /*
 1.1    brezak  * Copyright (c) 1991-1993 Regents of the University of California.
 1.1    brezak  * All rights reserved.
 1.1    brezak  *
 1.1    brezak  * Redistribution and use in source and binary forms, with or without
 1.1    brezak  * modification, are permitted provided that the following conditions
 1.1    brezak  * are met:
 1.1    brezak  * 1. Redistributions of source code must retain the above copyright
 1.1    brezak  *    notice, this list of conditions and the following disclaimer.
 1.1    brezak  * 2. Redistributions in binary form must reproduce the above copyright
 1.1    brezak  *    notice, this list of conditions and the following disclaimer in the
 1.1    brezak  *    documentation and/or other materials provided with the distribution.
 1.1    brezak  * 3. All advertising materials mentioning features or use of this software
 1.1    brezak  *    must display the following acknowledgement:
 1.1    brezak  *	This product includes software developed by the Computer Systems
 1.1    brezak  *	Engineering Group at Lawrence Berkeley Laboratory.
 1.1    brezak  * 4. Neither the name of the University nor of the Laboratory may be used
 1.1    brezak  *    to endorse or promote products derived from this software without
 1.1    brezak  *    specific prior written permission.
 1.1    brezak  *
 1.1    brezak  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
 1.1    brezak  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 1.1    brezak  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 1.1    brezak  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
 1.1    brezak  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
 1.1    brezak  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
 1.1    brezak  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 1.1    brezak  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 1.1    brezak  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
 1.1    brezak  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 1.1    brezak  * SUCH DAMAGE.
 1.1    brezak  *
 1.1    brezak  */
1.39   mycroft
 1.1    brezak /*
 1.1    brezak  * SoundBlaster Pro code provided by John Kohl, based on lots of
 1.1    brezak  * information he gleaned from Steve Haehnichen <steve (at) vigra.com>'s
 1.1    brezak  * SBlast driver for 386BSD and DOS driver code from Daniel Sachs
 1.1    brezak  * <sachs (at) meibm15.cen.uiuc.edu>.
 1.1    brezak  */
 1.1    brezak
 1.1    brezak #include <sys/param.h>
 1.1    brezak #include <sys/systm.h>
 1.1    brezak #include <sys/errno.h>
 1.1    brezak #include <sys/ioctl.h>
 1.1    brezak #include <sys/syslog.h>
 1.1    brezak #include <sys/device.h>
 1.1    brezak #include <sys/proc.h>
 1.1    brezak #include <sys/buf.h>
 1.1    brezak #include <vm/vm.h>
 1.1    brezak
 1.1    brezak #include <machine/cpu.h>
1.26   mycroft #include <machine/intr.h>
 1.1    brezak #include <machine/pio.h>
 1.1    brezak
 1.1    brezak #include <sys/audioio.h>
 1.1    brezak #include <dev/audio_if.h>
 1.1    brezak
 1.6       cgd #include <dev/isa/isavar.h>
 1.6       cgd #include <dev/isa/isadmavar.h>
 1.7       cgd #include <i386/isa/icu.h>			/* XXX BROKEN; WHY? */
 1.1    brezak
 1.7       cgd #include <dev/isa/sbreg.h>
 1.7       cgd #include <dev/isa/sbdspvar.h>
 1.1    brezak
1.12    brezak #ifdef AUDIO_DEBUG
 1.1    brezak extern void Dprintf __P((const char *, ...));
1.12    brezak #define DPRINTF(x)	if (sbdspdebug) Dprintf x
 1.1    brezak int	sbdspdebug = 0;
 1.1    brezak #else
 1.1    brezak #define DPRINTF(x)
 1.1    brezak #endif
 1.1    brezak
 1.1    brezak #ifndef SBDSP_NPOLL
 1.1    brezak #define SBDSP_NPOLL 3000
 1.1    brezak #endif
 1.1    brezak
 1.1    brezak struct {
 1.1    brezak 	int wdsp;
 1.1    brezak 	int rdsp;
 1.1    brezak 	int wmidi;
 1.1    brezak } sberr;
 1.1    brezak
1.24       jtk int sbdsp_srtotc __P((struct sbdsp_softc *sc, int sr, int isdac,
1.24       jtk 		      int *tcp, int *modep));
1.24       jtk u_int sbdsp_jazz16_probe __P((struct sbdsp_softc *));
1.24       jtk
1.16   mycroft /*
1.16   mycroft  * Time constant routines follow.  See SBK, section 12.
1.16   mycroft  * Although they don't come out and say it (in the docs),
1.16   mycroft  * the card clearly uses a 1MHz countdown timer, as the
1.16   mycroft  * low-speed formula (p. 12-4) is:
1.16   mycroft  *	tc = 256 - 10^6 / sr
1.16   mycroft  * In high-speed mode, the constant is the upper byte of a 16-bit counter,
1.16   mycroft  * and a 256MHz clock is used:
1.16   mycroft  *	tc = 65536 - 256 * 10^ 6 / sr
1.16   mycroft  * Since we can only use the upper byte of the HS TC, the two formulae
1.16   mycroft  * are equivalent.  (Why didn't they say so?)  E.g.,
1.16   mycroft  * 	(65536 - 256 * 10 ^ 6 / x) >> 8 = 256 - 10^6 / x
1.16   mycroft  *
1.16   mycroft  * The crossover point (from low- to high-speed modes) is different
1.16   mycroft  * for the SBPRO and SB20.  The table on p. 12-5 gives the following data:
1.16   mycroft  *
1.16   mycroft  *				SBPRO			SB20
1.16   mycroft  *				-----			--------
1.16   mycroft  * input ls min			4	KHz		4	KHz
1.16   mycroft  * input ls max			23	KHz		13	KHz
1.16   mycroft  * input hs max			44.1	KHz		15	KHz
1.16   mycroft  * output ls min		4	KHz		4	KHz
1.16   mycroft  * output ls max		23	KHz		23	KHz
1.16   mycroft  * output hs max		44.1	KHz		44.1	KHz
1.16   mycroft  */
1.16   mycroft #define SB_LS_MIN	0x06	/* 4000 Hz */
1.16   mycroft #define	SB_8K		0x83	/* 8000 Hz */
1.16   mycroft #define SBPRO_ADC_LS_MAX	0xd4	/* 22727 Hz */
1.16   mycroft #define SBPRO_ADC_HS_MAX	0xea	/* 45454 Hz */
1.16   mycroft #define SBCLA_ADC_LS_MAX	0xb3	/* 12987 Hz */
1.16   mycroft #define SBCLA_ADC_HS_MAX	0xbd	/* 14925 Hz */
1.16   mycroft #define SB_DAC_LS_MAX	0xd4	/* 22727 Hz */
1.16   mycroft #define SB_DAC_HS_MAX	0xea	/* 45454 Hz */
1.16   mycroft
1.31  christos int	sbdsp16_wait __P((struct sbdsp_softc *));
1.25  christos void	sbdsp_to __P((void *));
1.25  christos void	sbdsp_pause __P((struct sbdsp_softc *));
1.35   mycroft int	sbdsp16_setrate __P((struct sbdsp_softc *, int, int, int *));
1.25  christos int	sbdsp_tctosr __P((struct sbdsp_softc *, int));
1.25  christos int	sbdsp_set_timeconst __P((struct sbdsp_softc *, int));
1.25  christos
1.25  christos #ifdef AUDIO_DEBUG
1.25  christos void sb_printsc __P((struct sbdsp_softc *));
1.25  christos #endif
1.25  christos
1.12    brezak #ifdef AUDIO_DEBUG
 1.1    brezak void
1.25  christos sb_printsc(sc)
1.25  christos 	struct sbdsp_softc *sc;
 1.1    brezak {
 1.1    brezak 	int i;
 1.1    brezak
1.35   mycroft 	printf("open %d dmachan %d/%d/%d iobase %x\n",
1.39   mycroft 	    sc->sc_open, sc->dmachan, sc->sc_drq8, sc->sc_drq16, sc->sc_iobase);
1.28  christos 	printf("irate %d itc %d imode %d orate %d otc %d omode %d encoding %x\n",
1.23   mycroft 	    sc->sc_irate, sc->sc_itc, sc->sc_imode,
1.34   mycroft 	    sc->sc_orate, sc->sc_otc, sc->sc_omode, sc->sc_encoding);
1.29       jtk 	printf("outport %d inport %d spkron %d nintr %lu\n",
1.16   mycroft 	    sc->out_port, sc->in_port, sc->spkr_state, sc->sc_interrupts);
1.29       jtk 	printf("precision %d channels %d intr %p arg %p\n",
1.23   mycroft 	    sc->sc_precision, sc->sc_channels, sc->sc_intr, sc->sc_arg);
1.28  christos 	printf("gain: ");
 1.1    brezak 	for (i = 0; i < SB_NDEVS; i++)
1.28  christos 		printf("%d ", sc->gain[i]);
1.28  christos 	printf("\n");
 1.1    brezak }
 1.1    brezak #endif
 1.1    brezak
 1.1    brezak /*
 1.1    brezak  * Probe / attach routines.
 1.1    brezak  */
 1.1    brezak
 1.1    brezak /*
 1.1    brezak  * Probe for the soundblaster hardware.
 1.1    brezak  */
 1.1    brezak int
 1.1    brezak sbdsp_probe(sc)
 1.1    brezak 	struct sbdsp_softc *sc;
 1.1    brezak {
 1.1    brezak
 1.1    brezak 	if (sbdsp_reset(sc) < 0) {
 1.1    brezak 		DPRINTF(("sbdsp: couldn't reset card\n"));
 1.1    brezak 		return 0;
 1.1    brezak 	}
1.24       jtk 	/* if flags set, go and probe the jazz16 stuff */
1.40       jtk 	if (sc->sc_dev.dv_cfdata->cf_flags != 0) {
1.24       jtk 		sc->sc_model = sbdsp_jazz16_probe(sc);
1.40       jtk 	} else {
1.24       jtk 		sc->sc_model = sbversion(sc);
1.40       jtk 	}
 1.1    brezak
 1.1    brezak 	return 1;
 1.1    brezak }
 1.1    brezak
 1.1    brezak /*
1.24       jtk  * Try add-on stuff for Jazz16.
1.24       jtk  */
1.24       jtk u_int
1.24       jtk sbdsp_jazz16_probe(sc)
1.24       jtk 	struct sbdsp_softc *sc;
1.24       jtk {
1.24       jtk 	static u_char jazz16_irq_conf[16] = {
1.24       jtk 	    -1, -1, 0x02, 0x03,
1.24       jtk 	    -1, 0x01, -1, 0x04,
1.24       jtk 	    -1, 0x02, 0x05, -1,
1.24       jtk 	    -1, -1, -1, 0x06};
1.24       jtk 	static u_char jazz16_drq_conf[8] = {
1.24       jtk 	    -1, 0x01, -1, 0x02,
1.24       jtk 	    -1, 0x03, -1, 0x04};
1.24       jtk
1.24       jtk 	u_int rval = sbversion(sc);
1.31  christos 	bus_space_tag_t iot = sc->sc_iot;
1.31  christos 	bus_space_handle_t ioh;
1.31  christos
1.40       jtk 	DPRINTF(("jazz16 probe\n"));
1.40       jtk
1.40       jtk 	if (bus_space_map(iot, JAZZ16_CONFIG_PORT, 1, 0, &ioh)) {
1.40       jtk 		DPRINTF(("bus map failed\n"));
1.31  christos 		return rval;
1.40       jtk 	}
1.24       jtk
1.35   mycroft 	if (jazz16_drq_conf[sc->sc_drq8] == (u_char)-1 ||
1.40       jtk 	    jazz16_irq_conf[sc->sc_irq] == (u_char)-1) {
1.40       jtk 		DPRINTF(("drq/irq check failed\n"));
1.31  christos 		goto done;		/* give up, we can't do it. */
1.40       jtk 	}
1.31  christos
1.31  christos 	bus_space_write_1(iot, ioh, 0, JAZZ16_WAKEUP);
1.24       jtk 	delay(10000);			/* delay 10 ms */
1.31  christos 	bus_space_write_1(iot, ioh, 0, JAZZ16_SETBASE);
1.31  christos 	bus_space_write_1(iot, ioh, 0, sc->sc_iobase & 0x70);
1.24       jtk
1.40       jtk 	if (sbdsp_reset(sc) < 0) {
1.40       jtk 		DPRINTF(("sbdsp_reset check failed\n"));
1.31  christos 		goto done;		/* XXX? what else could we do? */
1.40       jtk 	}
1.24       jtk
1.40       jtk 	if (sbdsp_wdsp(sc, JAZZ16_READ_VER)) {
1.40       jtk 		DPRINTF(("read16 setup failed\n"));
1.31  christos 		goto done;
1.40       jtk 	}
1.31  christos
1.40       jtk 	if (sbdsp_rdsp(sc) != JAZZ16_VER_JAZZ) {
1.40       jtk 		DPRINTF(("read16 failed\n"));
1.31  christos 		goto done;
1.40       jtk 	}
1.24       jtk
1.35   mycroft 	/* XXX set both 8 & 16-bit drq to same channel, it works fine. */
1.35   mycroft 	sc->sc_drq16 = sc->sc_drq8;
1.31  christos 	if (sbdsp_wdsp(sc, JAZZ16_SET_DMAINTR) ||
1.35   mycroft 	    sbdsp_wdsp(sc, (jazz16_drq_conf[sc->sc_drq16] << 4) |
1.35   mycroft 		jazz16_drq_conf[sc->sc_drq8]) ||
1.40       jtk 	    sbdsp_wdsp(sc, jazz16_irq_conf[sc->sc_irq])) {
1.40       jtk 		DPRINTF(("sbdsp: can't write jazz16 probe stuff\n"));
1.40       jtk 	} else {
1.40       jtk 		DPRINTF(("jazz16 detected!\n"));
1.31  christos 		rval |= MODEL_JAZZ16;
1.40       jtk 	}
1.31  christos
1.31  christos done:
1.31  christos 	bus_space_unmap(iot, ioh, 1);
1.32  christos 	return rval;
1.24       jtk }
1.24       jtk
1.24       jtk /*
 1.1    brezak  * Attach hardware to driver, attach hardware driver to audio
 1.1    brezak  * pseudo-device driver .
 1.1    brezak  */
 1.1    brezak void
 1.1    brezak sbdsp_attach(sc)
 1.1    brezak 	struct sbdsp_softc *sc;
 1.1    brezak {
 1.1    brezak
 1.1    brezak 	/* Set defaults */
1.23   mycroft 	if (ISSB16CLASS(sc))
1.23   mycroft 		sc->sc_irate = sc->sc_orate = 8000;
1.23   mycroft 	else if (ISSBPROCLASS(sc))
1.23   mycroft 		sc->sc_itc = sc->sc_otc = SB_8K;
 1.1    brezak   	else
1.23   mycroft 		sc->sc_itc = sc->sc_otc = SB_8K;
1.34   mycroft 	sc->sc_encoding = AUDIO_ENCODING_ULAW;
1.23   mycroft 	sc->sc_precision = 8;
1.23   mycroft 	sc->sc_channels = 1;
 1.1    brezak
 1.5   mycroft 	(void) sbdsp_set_in_port(sc, SB_MIC_PORT);
 1.5   mycroft 	(void) sbdsp_set_out_port(sc, SB_SPEAKER);
 1.1    brezak
 1.1    brezak 	if (ISSBPROCLASS(sc)) {
 1.1    brezak 		int i;
 1.1    brezak
 1.1    brezak 		/* set mixer to default levels, by sending a mixer
 1.1    brezak                    reset command. */
 1.1    brezak 		sbdsp_mix_write(sc, SBP_MIX_RESET, SBP_MIX_RESET);
 1.1    brezak 		/* then some adjustments :) */
 1.1    brezak 		sbdsp_mix_write(sc, SBP_CD_VOL,
 1.1    brezak 				sbdsp_stereo_vol(SBP_MAXVOL, SBP_MAXVOL));
 1.1    brezak 		sbdsp_mix_write(sc, SBP_DAC_VOL,
 1.1    brezak 				sbdsp_stereo_vol(SBP_MAXVOL, SBP_MAXVOL));
 1.1    brezak 		sbdsp_mix_write(sc, SBP_MASTER_VOL,
1.17       jtk 				sbdsp_stereo_vol(SBP_MAXVOL/2, SBP_MAXVOL/2));
 1.1    brezak 		sbdsp_mix_write(sc, SBP_LINE_VOL,
 1.1    brezak 				sbdsp_stereo_vol(SBP_MAXVOL, SBP_MAXVOL));
 1.1    brezak 		for (i = 0; i < SB_NDEVS; i++)
1.16   mycroft 			sc->gain[i] = sbdsp_stereo_vol(SBP_MAXVOL, SBP_MAXVOL);
1.17       jtk 		sc->in_filter = 0;	/* no filters turned on, please */
 1.1    brezak 	}
1.16   mycroft
1.28  christos 	printf(": dsp v%d.%02d%s\n",
1.24       jtk 	       SBVER_MAJOR(sc->sc_model), SBVER_MINOR(sc->sc_model),
1.24       jtk 	       ISJAZZ16(sc) ? ": <Jazz16>" : "");
 1.1    brezak }
 1.1    brezak
 1.1    brezak /*
 1.1    brezak  * Various routines to interface to higher level audio driver
 1.1    brezak  */
 1.1    brezak
 1.1    brezak void
 1.1    brezak sbdsp_mix_write(sc, mixerport, val)
 1.1    brezak 	struct sbdsp_softc *sc;
 1.1    brezak 	int mixerport;
 1.1    brezak 	int val;
 1.1    brezak {
1.31  christos 	bus_space_tag_t iot = sc->sc_iot;
1.31  christos 	bus_space_handle_t ioh = sc->sc_ioh;
1.31  christos
1.31  christos 	bus_space_write_1(iot, ioh, SBP_MIXER_ADDR, mixerport);
 1.1    brezak 	delay(10);
1.31  christos 	bus_space_write_1(iot, ioh, SBP_MIXER_DATA, val);
 1.1    brezak 	delay(30);
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_mix_read(sc, mixerport)
 1.1    brezak 	struct sbdsp_softc *sc;
 1.1    brezak 	int mixerport;
 1.1    brezak {
1.31  christos 	bus_space_tag_t iot = sc->sc_iot;
1.31  christos 	bus_space_handle_t ioh = sc->sc_ioh;
1.31  christos
1.31  christos 	bus_space_write_1(iot, ioh, SBP_MIXER_ADDR, mixerport);
 1.1    brezak 	delay(10);
1.31  christos 	return bus_space_read_1(iot, ioh, SBP_MIXER_DATA);
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_set_in_sr(addr, sr)
 1.5   mycroft 	void *addr;
 1.1    brezak 	u_long sr;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
1.23   mycroft 	if (ISSB16CLASS(sc))
1.35   mycroft 		return (sbdsp16_setrate(sc, sr, SB_INPUT_RATE, &sc->sc_irate));
1.23   mycroft 	else
1.23   mycroft 		return (sbdsp_srtotc(sc, sr, SB_INPUT_RATE, &sc->sc_itc, &sc->sc_imode));
 1.1    brezak }
 1.1    brezak
 1.1    brezak u_long
 1.1    brezak sbdsp_get_in_sr(addr)
 1.5   mycroft 	void *addr;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
1.23   mycroft 	if (ISSB16CLASS(sc))
1.23   mycroft 		return (sc->sc_irate);
1.23   mycroft 	else
1.23   mycroft 		return (sbdsp_tctosr(sc, sc->sc_itc));
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_set_out_sr(addr, sr)
 1.5   mycroft 	void *addr;
 1.1    brezak 	u_long sr;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
1.23   mycroft 	if (ISSB16CLASS(sc))
1.35   mycroft 		return (sbdsp16_setrate(sc, sr, SB_OUTPUT_RATE, &sc->sc_orate));
1.23   mycroft 	else
1.23   mycroft 		return (sbdsp_srtotc(sc, sr, SB_OUTPUT_RATE, &sc->sc_otc, &sc->sc_omode));
 1.1    brezak }
 1.1    brezak
 1.1    brezak u_long
 1.1    brezak sbdsp_get_out_sr(addr)
 1.5   mycroft 	void *addr;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
1.23   mycroft 	if (ISSB16CLASS(sc))
1.23   mycroft 		return (sc->sc_orate);
1.23   mycroft 	else
1.23   mycroft 		return (sbdsp_tctosr(sc, sc->sc_otc));
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_query_encoding(addr, fp)
1.16   mycroft 	void *addr;
1.16   mycroft 	struct audio_encoding *fp;
 1.1    brezak {
1.16   mycroft 	switch (fp->index) {
1.16   mycroft 	case 0:
1.16   mycroft 		strcpy(fp->name, AudioEmulaw);
1.16   mycroft 		fp->format_id = AUDIO_ENCODING_ULAW;
1.16   mycroft 		break;
1.16   mycroft 	case 1:
1.16   mycroft 		strcpy(fp->name, AudioEpcm16);
1.16   mycroft 		fp->format_id = AUDIO_ENCODING_PCM16;
1.16   mycroft 		break;
1.16   mycroft 	default:
1.16   mycroft 		return (EINVAL);
1.16   mycroft 	}
1.16   mycroft 	return (0);
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
1.34   mycroft sbdsp_set_format(addr, encoding, precision)
 1.5   mycroft 	void *addr;
1.34   mycroft 	u_int encoding, precision;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
1.23   mycroft 	switch (encoding) {
 1.1    brezak 	case AUDIO_ENCODING_ULAW:
1.34   mycroft 	case AUDIO_ENCODING_PCM16:
1.34   mycroft 	case AUDIO_ENCODING_PCM8:
 1.1    brezak 		break;
 1.1    brezak 	default:
 1.1    brezak 		return (EINVAL);
 1.1    brezak 	}
1.23   mycroft
1.34   mycroft 	if (precision == 16)
1.34   mycroft 		if (!ISSB16CLASS(sc) && !ISJAZZ16(sc))
1.34   mycroft 			return (EINVAL);
1.34   mycroft
1.34   mycroft 	sc->sc_encoding = encoding;
1.34   mycroft 	sc->sc_precision = precision;
1.34   mycroft
 1.1    brezak 	return (0);
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_get_encoding(addr)
 1.5   mycroft 	void *addr;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
1.34   mycroft 	return (sc->sc_encoding);
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_get_precision(addr)
 1.5   mycroft 	void *addr;
 1.1    brezak {
1.23   mycroft 	register struct sbdsp_softc *sc = addr;
1.23   mycroft
1.23   mycroft 	return (sc->sc_precision);
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
1.23   mycroft sbdsp_set_channels(addr, channels)
 1.5   mycroft 	void *addr;
1.23   mycroft 	int channels;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
 1.1    brezak 	if (ISSBPROCLASS(sc)) {
1.23   mycroft 		if (channels != 1 && channels != 2)
1.16   mycroft 			return (EINVAL);
1.23   mycroft 		sc->sc_channels = channels;
1.23   mycroft 		sc->sc_dmadir = SB_DMA_NONE;
1.23   mycroft 		/*
1.23   mycroft 		 * XXXX
1.23   mycroft 		 * With 2 channels, SBPro can't do more than 22kHz.
1.23   mycroft 		 * No framework to check this.
1.23   mycroft 		 */
1.16   mycroft 	} else {
1.23   mycroft 		if (channels != 1)
1.16   mycroft 			return (EINVAL);
1.23   mycroft 		sc->sc_channels = channels;
 1.1    brezak 	}
 1.1    brezak
1.16   mycroft 	return (0);
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_get_channels(addr)
 1.5   mycroft 	void *addr;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
1.23   mycroft 	return (sc->sc_channels);
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
1.17       jtk sbdsp_set_ifilter(addr, which)
1.17       jtk 	void *addr;
1.17       jtk 	int which;
1.17       jtk {
1.17       jtk 	register struct sbdsp_softc *sc = addr;
1.25  christos 	int mixval;
1.17       jtk
1.35   mycroft 	/* XXXX SB16 */
1.17       jtk 	if (ISSBPROCLASS(sc)) {
1.17       jtk 		mixval = sbdsp_mix_read(sc, SBP_INFILTER) & ~SBP_IFILTER_MASK;
1.17       jtk 		switch (which) {
1.17       jtk 		case 0:
1.18   mycroft 			mixval |= SBP_FILTER_OFF;
1.18   mycroft 			break;
1.17       jtk 		case SBP_TREBLE_EQ:
1.18   mycroft 			mixval |= SBP_FILTER_ON | SBP_IFILTER_HIGH;
1.18   mycroft 			break;
1.17       jtk 		case SBP_BASS_EQ:
1.18   mycroft 			mixval |= SBP_FILTER_ON | SBP_IFILTER_LOW;
1.18   mycroft 			break;
1.18   mycroft 		default:
1.18   mycroft 			return (EINVAL);
1.17       jtk 		}
1.17       jtk 		sc->in_filter = mixval & SBP_IFILTER_MASK;
1.17       jtk 		sbdsp_mix_write(sc, SBP_INFILTER, mixval);
1.18   mycroft 		return (0);
1.18   mycroft 	} else
1.18   mycroft 		return (EINVAL);
1.17       jtk }
1.17       jtk
1.17       jtk int
1.17       jtk sbdsp_get_ifilter(addr)
1.17       jtk 	void *addr;
1.17       jtk {
1.17       jtk 	register struct sbdsp_softc *sc = addr;
1.17       jtk
1.35   mycroft 	/* XXXX SB16 */
1.17       jtk 	if (ISSBPROCLASS(sc)) {
1.18   mycroft 		sc->in_filter =
1.18   mycroft 		    sbdsp_mix_read(sc, SBP_INFILTER) & SBP_IFILTER_MASK;
1.18   mycroft 		switch (sc->in_filter) {
1.18   mycroft 		case SBP_FILTER_ON|SBP_IFILTER_HIGH:
1.18   mycroft 			return (SBP_TREBLE_EQ);
1.18   mycroft 		case SBP_FILTER_ON|SBP_IFILTER_LOW:
1.18   mycroft 			return (SBP_BASS_EQ);
1.18   mycroft 		case SBP_FILTER_OFF:
1.18   mycroft 		default:
1.18   mycroft 			return (0);
1.18   mycroft 		}
1.17       jtk 	} else
1.18   mycroft 		return (0);
1.17       jtk }
1.17       jtk
1.17       jtk int
 1.1    brezak sbdsp_set_out_port(addr, port)
 1.5   mycroft 	void *addr;
 1.1    brezak 	int port;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
 1.1    brezak 	sc->out_port = port; /* Just record it */
 1.1    brezak
1.16   mycroft 	return (0);
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_get_out_port(addr)
 1.5   mycroft 	void *addr;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
1.16   mycroft 	return (sc->out_port);
 1.1    brezak }
 1.1    brezak
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_set_in_port(addr, port)
 1.5   mycroft 	void *addr;
 1.1    brezak 	int port;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak 	int mixport, sbport;
 1.1    brezak
 1.1    brezak 	if (ISSBPROCLASS(sc)) {
1.16   mycroft 		switch (port) {
1.16   mycroft 		case SB_MIC_PORT:
1.16   mycroft 			sbport = SBP_FROM_MIC;
1.16   mycroft 			mixport = SBP_MIC_VOL;
1.16   mycroft 			break;
1.16   mycroft 		case SB_LINE_IN_PORT:
1.16   mycroft 			sbport = SBP_FROM_LINE;
1.16   mycroft 			mixport = SBP_LINE_VOL;
1.16   mycroft 			break;
1.16   mycroft 		case SB_CD_PORT:
1.16   mycroft 			sbport = SBP_FROM_CD;
1.16   mycroft 			mixport = SBP_CD_VOL;
1.16   mycroft 			break;
1.16   mycroft 		case SB_DAC_PORT:
1.16   mycroft 		case SB_FM_PORT:
1.16   mycroft 		default:
1.16   mycroft 			return (EINVAL);
1.16   mycroft 		}
1.16   mycroft 	} else {
1.16   mycroft 		switch (port) {
1.16   mycroft 		case SB_MIC_PORT:
1.16   mycroft 			sbport = SBP_FROM_MIC;
1.16   mycroft 			mixport = SBP_MIC_VOL;
1.16   mycroft 			break;
1.16   mycroft 		default:
1.16   mycroft 			return (EINVAL);
1.16   mycroft 		}
 1.1    brezak 	}
 1.1    brezak
 1.1    brezak 	sc->in_port = port;	/* Just record it */
 1.1    brezak
1.35   mycroft 	/* XXXX SB16 */
 1.1    brezak 	if (ISSBPROCLASS(sc)) {
 1.1    brezak 		/* record from that port */
 1.1    brezak 		sbdsp_mix_write(sc, SBP_RECORD_SOURCE,
1.18   mycroft 		    SBP_RECORD_FROM(sbport, SBP_FILTER_OFF, SBP_IFILTER_HIGH));
 1.1    brezak 		/* fetch gain from that port */
 1.1    brezak 		sc->gain[port] = sbdsp_mix_read(sc, mixport);
 1.1    brezak 	}
 1.1    brezak
1.16   mycroft 	return (0);
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_get_in_port(addr)
 1.5   mycroft 	void *addr;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
1.16   mycroft 	return (sc->in_port);
 1.1    brezak }
 1.1    brezak
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_speaker_ctl(addr, newstate)
 1.5   mycroft 	void *addr;
 1.1    brezak 	int newstate;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
 1.1    brezak 	if ((newstate == SPKR_ON) &&
 1.1    brezak 	    (sc->spkr_state == SPKR_OFF)) {
 1.1    brezak 		sbdsp_spkron(sc);
 1.1    brezak 		sc->spkr_state = SPKR_ON;
 1.1    brezak 	}
 1.1    brezak 	if ((newstate == SPKR_OFF) &&
 1.1    brezak 	    (sc->spkr_state == SPKR_ON)) {
 1.1    brezak 		sbdsp_spkroff(sc);
 1.1    brezak 		sc->spkr_state = SPKR_OFF;
 1.1    brezak 	}
 1.1    brezak 	return(0);
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_round_blocksize(addr, blk)
 1.5   mycroft 	void *addr;
 1.1    brezak 	int blk;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
1.15   mycroft 	sc->sc_last_hs_size = 0;
 1.1    brezak
1.38   mycroft 	/* Don't try to DMA too much at once. */
1.16   mycroft 	if (blk > NBPG)
1.16   mycroft 		blk = NBPG;
1.38   mycroft
1.38   mycroft 	/* Round to a multiple of the sample size. */
1.38   mycroft 	blk &= -(sc->sc_channels * sc->sc_precision / 8);
1.38   mycroft
1.38   mycroft 	return (blk);
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_commit_settings(addr)
 1.5   mycroft 	void *addr;
 1.1    brezak {
1.16   mycroft 	register struct sbdsp_softc *sc = addr;
1.16   mycroft
 1.1    brezak 	/* due to potentially unfortunate ordering in the above layers,
 1.1    brezak 	   re-do a few sets which may be important--input gains
 1.1    brezak 	   (adjust the proper channels), number of input channels (hit the
 1.1    brezak 	   record rate and set mode) */
 1.1    brezak
1.24       jtk 	if (ISSBPRO(sc)) {
1.24       jtk 		/*
1.24       jtk 		 * With 2 channels, SBPro can't do more than 22kHz.
1.24       jtk 		 * Whack the rates down to speed if necessary.
1.24       jtk 		 * Reset the time constant anyway
1.24       jtk 		 * because it may have been adjusted with a different number
1.24       jtk 		 * of channels, which means it might have computed the wrong
1.24       jtk 		 * mode (low/high speed).
1.24       jtk 		 */
1.24       jtk 		if (sc->sc_channels == 2 &&
1.24       jtk 		    sbdsp_tctosr(sc, sc->sc_itc) > 22727) {
1.24       jtk 			sbdsp_srtotc(sc, 22727, SB_INPUT_RATE,
1.24       jtk 				     &sc->sc_itc, &sc->sc_imode);
1.24       jtk 		} else
1.24       jtk 			sbdsp_srtotc(sc, sbdsp_tctosr(sc, sc->sc_itc),
1.24       jtk 				     SB_INPUT_RATE, &sc->sc_itc,
1.24       jtk 				     &sc->sc_imode);
1.24       jtk
1.24       jtk 		if (sc->sc_channels == 2 &&
1.24       jtk 		    sbdsp_tctosr(sc, sc->sc_otc) > 22727) {
1.24       jtk 			sbdsp_srtotc(sc, 22727, SB_OUTPUT_RATE,
1.24       jtk 				     &sc->sc_otc, &sc->sc_omode);
1.24       jtk 		} else
1.24       jtk 			sbdsp_srtotc(sc, sbdsp_tctosr(sc, sc->sc_otc),
1.24       jtk 				     SB_OUTPUT_RATE, &sc->sc_otc,
1.24       jtk 				     &sc->sc_omode);
1.24       jtk 	}
1.34   mycroft
1.16   mycroft 	/*
1.16   mycroft 	 * XXX
1.16   mycroft 	 * Should wait for chip to be idle.
1.16   mycroft 	 */
1.16   mycroft 	sc->sc_dmadir = SB_DMA_NONE;
 1.3    brezak
1.15   mycroft 	return 0;
 1.1    brezak }
 1.1    brezak
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_open(sc, dev, flags)
 1.1    brezak 	register struct sbdsp_softc *sc;
 1.1    brezak 	dev_t dev;
 1.1    brezak 	int flags;
 1.1    brezak {
 1.1    brezak         DPRINTF(("sbdsp_open: sc=0x%x\n", sc));
 1.1    brezak
 1.1    brezak 	if (sc->sc_open != 0 || sbdsp_reset(sc) != 0)
 1.1    brezak 		return ENXIO;
 1.1    brezak
 1.1    brezak 	sc->sc_open = 1;
 1.1    brezak 	sc->sc_mintr = 0;
 1.1    brezak 	if (ISSBPROCLASS(sc) &&
1.31  christos 	    sbdsp_wdsp(sc, SB_DSP_RECORD_MONO) < 0) {
 1.1    brezak 		DPRINTF(("sbdsp_open: can't set mono mode\n"));
 1.1    brezak 		/* we'll readjust when it's time for DMA. */
 1.1    brezak 	}
 1.1    brezak
 1.1    brezak 	/*
 1.1    brezak 	 * Leave most things as they were; users must change things if
 1.1    brezak 	 * the previous process didn't leave it they way they wanted.
 1.1    brezak 	 * Looked at another way, it's easy to set up a configuration
 1.1    brezak 	 * in one program and leave it for another to inherit.
 1.1    brezak 	 */
 1.1    brezak 	DPRINTF(("sbdsp_open: opened\n"));
 1.1    brezak
 1.1    brezak 	return 0;
 1.1    brezak }
 1.1    brezak
 1.1    brezak void
 1.1    brezak sbdsp_close(addr)
 1.5   mycroft 	void *addr;
 1.1    brezak {
 1.5   mycroft 	struct sbdsp_softc *sc = addr;
 1.1    brezak
 1.1    brezak         DPRINTF(("sbdsp_close: sc=0x%x\n", sc));
 1.1    brezak
 1.1    brezak 	sc->sc_open = 0;
 1.1    brezak 	sbdsp_spkroff(sc);
 1.1    brezak 	sc->spkr_state = SPKR_OFF;
 1.1    brezak 	sc->sc_mintr = 0;
1.15   mycroft 	sbdsp_haltdma(sc);
 1.1    brezak
 1.1    brezak 	DPRINTF(("sbdsp_close: closed\n"));
 1.1    brezak }
 1.1    brezak
 1.1    brezak /*
 1.1    brezak  * Lower-level routines
 1.1    brezak  */
 1.1    brezak
 1.1    brezak /*
 1.1    brezak  * Reset the card.
 1.1    brezak  * Return non-zero if the card isn't detected.
 1.1    brezak  */
 1.1    brezak int
 1.1    brezak sbdsp_reset(sc)
 1.1    brezak 	register struct sbdsp_softc *sc;
 1.1    brezak {
1.31  christos 	bus_space_tag_t iot = sc->sc_iot;
1.31  christos 	bus_space_handle_t ioh = sc->sc_ioh;
 1.1    brezak
1.15   mycroft 	sc->sc_intr = 0;
1.16   mycroft 	if (sc->sc_dmadir != SB_DMA_NONE) {
1.39   mycroft 		isa_dmaabort(sc->dmachan);
1.16   mycroft 		sc->sc_dmadir = SB_DMA_NONE;
1.15   mycroft 	}
1.15   mycroft 	sc->sc_last_hs_size = 0;
1.15   mycroft
 1.1    brezak 	/*
 1.1    brezak 	 * See SBK, section 11.3.
 1.1    brezak 	 * We pulse a reset signal into the card.
 1.1    brezak 	 * Gee, what a brilliant hardware design.
 1.1    brezak 	 */
1.31  christos 	bus_space_write_1(iot, ioh, SBP_DSP_RESET, 1);
1.15   mycroft 	delay(10);
1.31  christos 	bus_space_write_1(iot, ioh, SBP_DSP_RESET, 0);
1.15   mycroft 	delay(30);
1.31  christos 	if (sbdsp_rdsp(sc) != SB_MAGIC)
 1.1    brezak 		return -1;
1.15   mycroft
 1.1    brezak 	return 0;
 1.1    brezak }
 1.1    brezak
1.23   mycroft int
1.31  christos sbdsp16_wait(sc)
1.31  christos 	struct sbdsp_softc *sc;
1.23   mycroft {
1.31  christos 	bus_space_tag_t iot = sc->sc_iot;
1.31  christos 	bus_space_handle_t ioh = sc->sc_ioh;
1.23   mycroft 	register int i;
1.23   mycroft
1.23   mycroft 	for (i = SBDSP_NPOLL; --i >= 0; ) {
1.23   mycroft 		register u_char x;
1.31  christos 		x = bus_space_read_1(iot, ioh, SBP_DSP_WSTAT);
1.23   mycroft 		delay(10);
1.23   mycroft 		if ((x & SB_DSP_BUSY) == 0)
1.23   mycroft 			continue;
1.23   mycroft 		return 0;
1.23   mycroft 	}
1.23   mycroft 	++sberr.wdsp;
1.23   mycroft 	return -1;
1.23   mycroft }
1.23   mycroft
 1.1    brezak /*
 1.1    brezak  * Write a byte to the dsp.
 1.1    brezak  * XXX We are at the mercy of the card as we use a
 1.1    brezak  * polling loop and wait until it can take the byte.
 1.1    brezak  */
 1.1    brezak int
1.31  christos sbdsp_wdsp(sc, v)
1.31  christos 	struct sbdsp_softc *sc;
1.31  christos 	int v;
 1.1    brezak {
1.31  christos 	bus_space_tag_t iot = sc->sc_iot;
1.31  christos 	bus_space_handle_t ioh = sc->sc_ioh;
 1.1    brezak 	register int i;
 1.1    brezak
 1.1    brezak 	for (i = SBDSP_NPOLL; --i >= 0; ) {
1.15   mycroft 		register u_char x;
1.31  christos 		x = bus_space_read_1(iot, ioh, SBP_DSP_WSTAT);
1.15   mycroft 		delay(10);
1.15   mycroft 		if ((x & SB_DSP_BUSY) != 0)
1.15   mycroft 			continue;
1.31  christos 		bus_space_write_1(iot, ioh, SBP_DSP_WRITE, v);
1.15   mycroft 		delay(10);
 1.1    brezak 		return 0;
 1.1    brezak 	}
 1.1    brezak 	++sberr.wdsp;
 1.1    brezak 	return -1;
 1.1    brezak }
 1.1    brezak
 1.1    brezak /*
 1.1    brezak  * Read a byte from the DSP, using polling.
 1.1    brezak  */
 1.1    brezak int
1.31  christos sbdsp_rdsp(sc)
1.31  christos 	struct sbdsp_softc *sc;
 1.1    brezak {
1.31  christos 	bus_space_tag_t iot = sc->sc_iot;
1.31  christos 	bus_space_handle_t ioh = sc->sc_ioh;
 1.1    brezak 	register int i;
 1.1    brezak
 1.1    brezak 	for (i = SBDSP_NPOLL; --i >= 0; ) {
1.15   mycroft 		register u_char x;
1.31  christos 		x = bus_space_read_1(iot, ioh, SBP_DSP_RSTAT);
1.15   mycroft 		delay(10);
1.15   mycroft 		if ((x & SB_DSP_READY) == 0)
 1.1    brezak 			continue;
1.31  christos 		x = bus_space_read_1(iot, ioh, SBP_DSP_READ);
1.15   mycroft 		delay(10);
1.15   mycroft 		return x;
 1.1    brezak 	}
 1.1    brezak 	++sberr.rdsp;
 1.1    brezak 	return -1;
 1.1    brezak }
 1.1    brezak
 1.1    brezak /*
 1.1    brezak  * Doing certain things (like toggling the speaker) make
 1.1    brezak  * the SB hardware go away for a while, so pause a little.
 1.1    brezak  */
 1.1    brezak void
 1.1    brezak sbdsp_to(arg)
 1.1    brezak 	void *arg;
 1.1    brezak {
 1.1    brezak 	wakeup(arg);
 1.1    brezak }
 1.1    brezak
 1.1    brezak void
 1.1    brezak sbdsp_pause(sc)
 1.1    brezak 	struct sbdsp_softc *sc;
 1.1    brezak {
 1.1    brezak 	extern int hz;
 1.1    brezak
 1.1    brezak 	timeout(sbdsp_to, sbdsp_to, hz/8);
 1.5   mycroft 	(void)tsleep(sbdsp_to, PWAIT, "sbpause", 0);
 1.1    brezak }
 1.1    brezak
 1.1    brezak /*
 1.1    brezak  * Turn on the speaker.  The SBK documention says this operation
 1.1    brezak  * can take up to 1/10 of a second.  Higher level layers should
 1.1    brezak  * probably let the task sleep for this amount of time after
 1.1    brezak  * calling here.  Otherwise, things might not work (because
 1.1    brezak  * sbdsp_wdsp() and sbdsp_rdsp() will probably timeout.)
 1.1    brezak  *
 1.1    brezak  * These engineers had their heads up their ass when
 1.1    brezak  * they designed this card.
 1.1    brezak  */
 1.1    brezak void
 1.1    brezak sbdsp_spkron(sc)
 1.1    brezak 	struct sbdsp_softc *sc;
 1.1    brezak {
1.31  christos 	(void)sbdsp_wdsp(sc, SB_DSP_SPKR_ON);
 1.1    brezak 	sbdsp_pause(sc);
 1.1    brezak }
 1.1    brezak
 1.1    brezak /*
 1.1    brezak  * Turn off the speaker; see comment above.
 1.1    brezak  */
 1.1    brezak void
 1.1    brezak sbdsp_spkroff(sc)
 1.1    brezak 	struct sbdsp_softc *sc;
 1.1    brezak {
1.31  christos 	(void)sbdsp_wdsp(sc, SB_DSP_SPKR_OFF);
 1.1    brezak 	sbdsp_pause(sc);
 1.1    brezak }
 1.1    brezak
 1.1    brezak /*
 1.1    brezak  * Read the version number out of the card.  Return major code
 1.1    brezak  * in high byte, and minor code in low byte.
 1.1    brezak  */
 1.1    brezak short
 1.1    brezak sbversion(sc)
 1.1    brezak 	struct sbdsp_softc *sc;
 1.1    brezak {
 1.1    brezak 	short v;
 1.1    brezak
1.31  christos 	if (sbdsp_wdsp(sc, SB_DSP_VERSION) < 0)
 1.1    brezak 		return 0;
1.31  christos 	v = sbdsp_rdsp(sc) << 8;
1.31  christos 	v |= sbdsp_rdsp(sc);
 1.1    brezak 	return ((v >= 0) ? v : 0);
 1.1    brezak }
 1.1    brezak
 1.1    brezak /*
 1.1    brezak  * Halt a DMA in progress.  A low-speed transfer can be
 1.1    brezak  * resumed with sbdsp_contdma().
 1.1    brezak  */
 1.1    brezak int
 1.1    brezak sbdsp_haltdma(addr)
 1.5   mycroft 	void *addr;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
 1.1    brezak 	DPRINTF(("sbdsp_haltdma: sc=0x%x\n", sc));
 1.1    brezak
1.15   mycroft 	sbdsp_reset(sc);
1.15   mycroft 	return 0;
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_contdma(addr)
 1.5   mycroft 	void *addr;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
 1.1    brezak 	DPRINTF(("sbdsp_contdma: sc=0x%x\n", sc));
 1.1    brezak
 1.1    brezak 	/* XXX how do we reinitialize the DMA controller state?  do we care? */
1.31  christos 	(void)sbdsp_wdsp(sc, SB_DSP_CONT);
 1.1    brezak 	return(0);
 1.1    brezak }
 1.1    brezak
1.23   mycroft int
1.35   mycroft sbdsp16_setrate(sc, sr, isdac, ratep)
1.23   mycroft 	register struct sbdsp_softc *sc;
1.23   mycroft 	int sr;
1.23   mycroft 	int isdac;
1.23   mycroft 	int *ratep;
1.23   mycroft {
1.23   mycroft
1.23   mycroft 	/*
1.23   mycroft 	 * XXXX
1.23   mycroft 	 * More checks here?
1.23   mycroft 	 */
1.35   mycroft 	if (sr < 5000 || sr > 45454)
1.23   mycroft 		return (EINVAL);
1.23   mycroft 	*ratep = sr;
1.23   mycroft 	return (0);
1.23   mycroft }
1.23   mycroft
 1.1    brezak /*
 1.1    brezak  * Convert a linear sampling rate into the DAC time constant.
 1.1    brezak  * Set *mode to indicate the high/low-speed DMA operation.
 1.1    brezak  * Because of limitations of the card, not all rates are possible.
 1.1    brezak  * We return the time constant of the closest possible rate.
 1.1    brezak  * The sampling rate limits are different for the DAC and ADC,
 1.1    brezak  * so isdac indicates output, and !isdac indicates input.
 1.1    brezak  */
 1.1    brezak int
1.16   mycroft sbdsp_srtotc(sc, sr, isdac, tcp, modep)
 1.1    brezak 	register struct sbdsp_softc *sc;
 1.1    brezak 	int sr;
 1.1    brezak 	int isdac;
1.16   mycroft 	int *tcp, *modep;
 1.1    brezak {
1.24       jtk 	int tc, realtc, mode;
 1.1    brezak
1.24       jtk 	/*
1.24       jtk 	 * Don't forget to compute which mode we'll be in based on whether
1.24       jtk 	 * we need to double the rate for stereo on SBPRO.
1.24       jtk 	 */
1.24       jtk
 1.1    brezak 	if (sr == 0) {
1.16   mycroft 		tc = SB_LS_MIN;
1.16   mycroft 		mode = SB_ADAC_LS;
1.16   mycroft 		goto out;
 1.1    brezak 	}
1.16   mycroft
1.16   mycroft 	tc = 256 - (1000000 / sr);
1.24       jtk
1.24       jtk 	if (sc->sc_channels == 2 && ISSBPRO(sc))
1.24       jtk 		/* compute based on 2x sample rate when needed */
1.24       jtk 		realtc = 256 - ( 500000 / sr);
1.24       jtk 	else
1.24       jtk 		realtc = tc;
 1.1    brezak
 1.1    brezak 	if (tc < SB_LS_MIN) {
 1.1    brezak 		tc = SB_LS_MIN;
1.24       jtk 		mode = SB_ADAC_LS;	/* NB: 2x minimum speed is still low
1.24       jtk 					 * speed mode. */
1.16   mycroft 		goto out;
 1.1    brezak 	} else if (isdac) {
1.24       jtk 		if (realtc <= SB_DAC_LS_MAX)
1.16   mycroft 			mode = SB_ADAC_LS;
 1.1    brezak 		else {
1.16   mycroft 			mode = SB_ADAC_HS;
 1.1    brezak 			if (tc > SB_DAC_HS_MAX)
 1.1    brezak 				tc = SB_DAC_HS_MAX;
 1.1    brezak 		}
 1.1    brezak 	} else {
1.16   mycroft 		int adc_ls_max, adc_hs_max;
1.16   mycroft
1.16   mycroft 		/* XXX use better rounding--compare distance to nearest tc on both
1.16   mycroft 		   sides of requested speed */
1.16   mycroft 		if (ISSBPROCLASS(sc)) {
1.16   mycroft 			adc_ls_max = SBPRO_ADC_LS_MAX;
1.16   mycroft 			adc_hs_max = SBPRO_ADC_HS_MAX;
1.16   mycroft 		} else {
1.16   mycroft 			adc_ls_max = SBCLA_ADC_LS_MAX;
1.16   mycroft 			adc_hs_max = SBCLA_ADC_HS_MAX;
1.16   mycroft 		}
1.16   mycroft
1.24       jtk 		if (realtc <= adc_ls_max)
1.16   mycroft 			mode = SB_ADAC_LS;
 1.1    brezak 		else {
1.16   mycroft 			mode = SB_ADAC_HS;
 1.1    brezak 			if (tc > adc_hs_max)
 1.1    brezak 				tc = adc_hs_max;
 1.1    brezak 		}
 1.1    brezak 	}
1.16   mycroft
1.16   mycroft out:
1.16   mycroft 	*tcp = tc;
1.16   mycroft 	*modep = mode;
1.16   mycroft 	return (0);
 1.1    brezak }
 1.1    brezak
 1.1    brezak /*
 1.1    brezak  * Convert a DAC time constant to a sampling rate.
 1.1    brezak  * See SBK, section 12.
 1.1    brezak  */
 1.1    brezak int
 1.1    brezak sbdsp_tctosr(sc, tc)
 1.1    brezak 	register struct sbdsp_softc *sc;
 1.1    brezak 	int tc;
 1.1    brezak {
 1.1    brezak 	int adc;
 1.1    brezak
 1.1    brezak 	if (ISSBPROCLASS(sc))
 1.1    brezak 		adc = SBPRO_ADC_HS_MAX;
 1.1    brezak 	else
 1.1    brezak 		adc = SBCLA_ADC_HS_MAX;
 1.1    brezak
 1.1    brezak 	if (tc > adc)
 1.1    brezak 		tc = adc;
 1.1    brezak
 1.1    brezak 	return (1000000 / (256 - tc));
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
1.23   mycroft sbdsp_set_timeconst(sc, tc)
 1.1    brezak 	register struct sbdsp_softc *sc;
1.16   mycroft 	int tc;
 1.1    brezak {
 1.1    brezak 	/*
 1.1    brezak 	 * A SBPro in stereo mode uses time constants at double the
 1.1    brezak 	 * actual rate.
 1.1    brezak 	 */
1.23   mycroft 	if (ISSBPRO(sc) && sc->sc_channels == 2)
1.16   mycroft 		tc = 256 - ((256 - tc) / 2);
 1.1    brezak
1.23   mycroft 	DPRINTF(("sbdsp_set_timeconst: sc=%p tc=%d\n", sc, tc));
 1.1    brezak
1.31  christos 	if (sbdsp_wdsp(sc, SB_DSP_TIMECONST) < 0 ||
1.31  christos 	    sbdsp_wdsp(sc, tc) < 0)
1.16   mycroft 		return (EIO);
 1.1    brezak
1.16   mycroft 	return (0);
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_dma_input(addr, p, cc, intr, arg)
 1.5   mycroft 	void *addr;
 1.1    brezak 	void *p;
 1.1    brezak 	int cc;
1.25  christos 	void (*intr) __P((void *));
 1.1    brezak 	void *arg;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
1.12    brezak #ifdef AUDIO_DEBUG
 1.1    brezak 	if (sbdspdebug > 1)
 1.1    brezak 		Dprintf("sbdsp_dma_input: cc=%d 0x%x (0x%x)\n", cc, intr, arg);
 1.1    brezak #endif
1.23   mycroft 	if (sc->sc_channels == 2 && (cc & 1)) {
 1.1    brezak 		DPRINTF(("sbdsp_dma_input: stereo input, odd bytecnt\n"));
 1.1    brezak 		return EIO;
 1.1    brezak 	}
1.15   mycroft
1.16   mycroft 	if (sc->sc_dmadir != SB_DMA_IN) {
1.23   mycroft 		if (ISSBPRO(sc)) {
1.23   mycroft 			if (sc->sc_channels == 2) {
1.24       jtk 				if (ISJAZZ16(sc) && sc->sc_precision == 16) {
1.31  christos 					if (sbdsp_wdsp(sc,
1.24       jtk 						       JAZZ16_RECORD_STEREO) < 0) {
1.24       jtk 						goto badmode;
1.24       jtk 					}
1.31  christos 				} else if (sbdsp_wdsp(sc,
1.24       jtk 						      SB_DSP_RECORD_STEREO) < 0)
1.16   mycroft 					goto badmode;
1.16   mycroft 				sbdsp_mix_write(sc, SBP_INFILTER,
1.18   mycroft 				    (sbdsp_mix_read(sc, SBP_INFILTER) &
1.18   mycroft 				    ~SBP_IFILTER_MASK) | SBP_FILTER_OFF);
1.16   mycroft 			} else {
1.24       jtk 				if (ISJAZZ16(sc) && sc->sc_precision == 16) {
1.31  christos 					if (sbdsp_wdsp(sc,
1.24       jtk 						       JAZZ16_RECORD_MONO) < 0)
1.24       jtk 					{
1.24       jtk 						goto badmode;
1.24       jtk 					}
1.31  christos 				} else if (sbdsp_wdsp(sc, SB_DSP_RECORD_MONO) < 0)
1.16   mycroft 					goto badmode;
1.17       jtk 				sbdsp_mix_write(sc, SBP_INFILTER,
1.18   mycroft 				    (sbdsp_mix_read(sc, SBP_INFILTER) &
1.18   mycroft 				    ~SBP_IFILTER_MASK) | sc->in_filter);
1.16   mycroft 			}
 1.1    brezak 		}
1.16   mycroft
1.23   mycroft 		if (ISSB16CLASS(sc)) {
1.31  christos 			if (sbdsp_wdsp(sc, SB_DSP16_INPUTRATE) < 0 ||
1.31  christos 			    sbdsp_wdsp(sc, sc->sc_irate >> 8) < 0 ||
1.31  christos 			    sbdsp_wdsp(sc, sc->sc_irate) < 0)
1.23   mycroft 				goto giveup;
1.23   mycroft 		} else
1.23   mycroft 			sbdsp_set_timeconst(sc, sc->sc_itc);
1.39   mycroft
1.16   mycroft 		sc->sc_dmadir = SB_DMA_IN;
1.39   mycroft 		sc->dmaflags = DMAMODE_READ;
1.39   mycroft 		if (ISSB2CLASS(sc))
1.39   mycroft 			sc->dmaflags |= DMAMODE_LOOP;
1.39   mycroft 	} else {
1.39   mycroft 		/* Already started; just return. */
1.39   mycroft 		if (ISSB2CLASS(sc))
1.39   mycroft 			return 0;
 1.1    brezak 	}
 1.1    brezak
1.39   mycroft 	sc->dmaaddr = p;
1.39   mycroft 	sc->dmacnt = ISSB2CLASS(sc) ? (NBPG/cc)*cc : cc;
1.39   mycroft 	sc->dmachan = sc->sc_precision == 16 ? sc->sc_drq16 : sc->sc_drq8;
1.39   mycroft 	isa_dmastart(sc->dmaflags, sc->dmaaddr, sc->dmacnt, sc->dmachan);
 1.1    brezak 	sc->sc_intr = intr;
 1.1    brezak 	sc->sc_arg = arg;
1.15   mycroft
1.35   mycroft 	if (sc->sc_precision == 16)
1.23   mycroft 		cc >>= 1;
1.23   mycroft 	--cc;
1.23   mycroft 	if (ISSB16CLASS(sc)) {
1.31  christos 		if (sbdsp_wdsp(sc, sc->sc_precision == 16 ? SB_DSP16_RDMA_16 :
1.35   mycroft 							    SB_DSP16_RDMA_8) < 0 ||
1.31  christos 		    sbdsp_wdsp(sc, (sc->sc_precision == 16 ? 0x10 : 0x00) |
1.23   mycroft 				       (sc->sc_channels == 2 ? 0x20 : 0x00)) < 0 ||
1.31  christos 		    sbdsp16_wait(sc) ||
1.31  christos 		    sbdsp_wdsp(sc, cc) < 0 ||
1.31  christos 		    sbdsp_wdsp(sc, cc >> 8) < 0) {
1.23   mycroft 			DPRINTF(("sbdsp_dma_input: SB16 DMA start failed\n"));
1.23   mycroft 			goto giveup;
1.23   mycroft 		}
1.39   mycroft 	} else if (ISSB2CLASS(sc)) {
1.15   mycroft 		if (cc != sc->sc_last_hs_size) {
1.31  christos 			if (sbdsp_wdsp(sc, SB_DSP_BLOCKSIZE) < 0 ||
1.31  christos 			    sbdsp_wdsp(sc, cc) < 0 ||
1.31  christos 			    sbdsp_wdsp(sc, cc >> 8) < 0) {
1.39   mycroft 				DPRINTF(("sbdsp_dma_input: SB2 DMA start failed\n"));
 1.1    brezak 				goto giveup;
1.15   mycroft 			}
1.15   mycroft 			sc->sc_last_hs_size = cc;
 1.1    brezak 		}
1.39   mycroft 		if (sbdsp_wdsp(sc,
1.39   mycroft 		    sc->sc_imode == SB_ADAC_LS ? SB_DSP_RDMA_LOOP :
1.39   mycroft 						 SB_DSP_HS_INPUT) < 0) {
1.39   mycroft 			DPRINTF(("sbdsp_dma_input: SB2 DMA restart failed\n"));
1.39   mycroft 			goto giveup;
1.39   mycroft 		}
1.39   mycroft 	} else {
1.39   mycroft 		if (sbdsp_wdsp(sc, SB_DSP_RDMA) < 0 ||
1.39   mycroft 		    sbdsp_wdsp(sc, cc) < 0 ||
1.39   mycroft 		    sbdsp_wdsp(sc, cc >> 8) < 0) {
1.39   mycroft 		        DPRINTF(("sbdsp_dma_input: SB1 DMA start failed\n"));
 1.1    brezak 			goto giveup;
1.15   mycroft 		}
 1.1    brezak 	}
 1.1    brezak 	return 0;
 1.1    brezak
 1.1    brezak giveup:
 1.1    brezak 	sbdsp_reset(sc);
 1.1    brezak 	return EIO;
1.15   mycroft
 1.1    brezak badmode:
 1.1    brezak 	DPRINTF(("sbdsp_dma_input: can't set %s mode\n",
1.23   mycroft 		 sc->sc_channels == 2 ? "stereo" : "mono"));
 1.1    brezak 	return EIO;
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_dma_output(addr, p, cc, intr, arg)
 1.5   mycroft 	void *addr;
 1.1    brezak 	void *p;
 1.1    brezak 	int cc;
1.25  christos 	void (*intr) __P((void *));
 1.1    brezak 	void *arg;
 1.1    brezak {
 1.5   mycroft 	register struct sbdsp_softc *sc = addr;
 1.1    brezak
1.12    brezak #ifdef AUDIO_DEBUG
 1.1    brezak 	if (sbdspdebug > 1)
 1.1    brezak 		Dprintf("sbdsp_dma_output: cc=%d 0x%x (0x%x)\n", cc, intr, arg);
 1.1    brezak #endif
1.23   mycroft 	if (sc->sc_channels == 2 && (cc & 1)) {
 1.1    brezak 		DPRINTF(("stereo playback odd bytes (%d)\n", cc));
 1.1    brezak 		return EIO;
 1.1    brezak 	}
 1.1    brezak
1.16   mycroft 	if (sc->sc_dmadir != SB_DMA_OUT) {
1.23   mycroft 		if (ISSBPRO(sc)) {
1.16   mycroft 			/* make sure we re-set stereo mixer bit when we start
1.16   mycroft 			   output. */
1.16   mycroft 			sbdsp_mix_write(sc, SBP_STEREO,
1.16   mycroft 			    (sbdsp_mix_read(sc, SBP_STEREO) & ~SBP_PLAYMODE_MASK) |
1.23   mycroft 			    (sc->sc_channels == 2 ?  SBP_PLAYMODE_STEREO : SBP_PLAYMODE_MONO));
1.24       jtk 			if (ISJAZZ16(sc)) {
1.24       jtk 				/* Yes, we write the record mode to set
1.24       jtk 				   16-bit playback mode. weird, huh? */
1.24       jtk 				if (sc->sc_precision == 16) {
1.31  christos 					sbdsp_wdsp(sc,
1.24       jtk 						   sc->sc_channels == 2 ?
1.24       jtk 						   JAZZ16_RECORD_STEREO :
1.24       jtk 						   JAZZ16_RECORD_MONO);
1.24       jtk 				} else {
1.31  christos 					sbdsp_wdsp(sc,
1.24       jtk 						   sc->sc_channels == 2 ?
1.24       jtk 						   SB_DSP_RECORD_STEREO :
1.24       jtk 						   SB_DSP_RECORD_MONO);
1.24       jtk 				}
1.24       jtk 			}
1.16   mycroft 		}
1.16   mycroft
1.23   mycroft 		if (ISSB16CLASS(sc)) {
1.31  christos 			if (sbdsp_wdsp(sc, SB_DSP16_OUTPUTRATE) < 0 ||
1.31  christos 			    sbdsp_wdsp(sc, sc->sc_orate >> 8) < 0 ||
1.31  christos 			    sbdsp_wdsp(sc, sc->sc_orate) < 0)
1.23   mycroft 				goto giveup;
1.23   mycroft 		} else
1.23   mycroft 			sbdsp_set_timeconst(sc, sc->sc_otc);
1.39   mycroft
1.16   mycroft 		sc->sc_dmadir = SB_DMA_OUT;
1.39   mycroft 		sc->dmaflags = DMAMODE_WRITE;
1.39   mycroft 		if (ISSB2CLASS(sc))
1.39   mycroft 			sc->dmaflags |= DMAMODE_LOOP;
1.39   mycroft 	} else {
1.39   mycroft 		/* Already started; just return. */
1.39   mycroft 		if (ISSB2CLASS(sc))
1.39   mycroft 			return 0;
 1.1    brezak 	}
1.15   mycroft
1.39   mycroft 	sc->dmaaddr = p;
1.39   mycroft 	sc->dmacnt = ISSB2CLASS(sc) ? (NBPG/cc)*cc : cc;
1.39   mycroft 	sc->dmachan = sc->sc_precision == 16 ? sc->sc_drq16 : sc->sc_drq8;
1.39   mycroft 	isa_dmastart(sc->dmaflags, sc->dmaaddr, sc->dmacnt, sc->dmachan);
 1.1    brezak 	sc->sc_intr = intr;
 1.1    brezak 	sc->sc_arg = arg;
 1.1    brezak
1.35   mycroft 	if (sc->sc_precision == 16)
1.23   mycroft 		cc >>= 1;
1.23   mycroft 	--cc;
1.23   mycroft 	if (ISSB16CLASS(sc)) {
1.31  christos 		if (sbdsp_wdsp(sc, sc->sc_precision == 16 ? SB_DSP16_WDMA_16 :
1.35   mycroft 							    SB_DSP16_WDMA_8) < 0 ||
1.31  christos 		    sbdsp_wdsp(sc, (sc->sc_precision == 16 ? 0x10 : 0x00) |
1.23   mycroft 				       (sc->sc_channels == 2 ? 0x20 : 0x00)) < 0 ||
1.31  christos 		    sbdsp16_wait(sc) ||
1.31  christos 		    sbdsp_wdsp(sc, cc) < 0 ||
1.31  christos 		    sbdsp_wdsp(sc, cc >> 8) < 0) {
1.23   mycroft 			DPRINTF(("sbdsp_dma_output: SB16 DMA start failed\n"));
1.23   mycroft 			goto giveup;
1.23   mycroft 		}
1.39   mycroft 	} else if (ISSB2CLASS(sc)) {
1.15   mycroft 		if (cc != sc->sc_last_hs_size) {
1.31  christos 			if (sbdsp_wdsp(sc, SB_DSP_BLOCKSIZE) < 0 ||
1.31  christos 			    sbdsp_wdsp(sc, cc) < 0 ||
1.31  christos 			    sbdsp_wdsp(sc, cc >> 8) < 0) {
1.39   mycroft 				DPRINTF(("sbdsp_dma_output: SB2 DMA start failed\n"));
 1.1    brezak 				goto giveup;
 1.1    brezak 			}
1.15   mycroft 			sc->sc_last_hs_size = cc;
 1.1    brezak 		}
1.39   mycroft 		if (sbdsp_wdsp(sc,
1.39   mycroft 		    sc->sc_omode == SB_ADAC_LS ? SB_DSP_WDMA_LOOP :
1.39   mycroft 						 SB_DSP_HS_OUTPUT) < 0) {
1.39   mycroft 			DPRINTF(("sbdsp_dma_output: SB2 DMA restart failed\n"));
1.39   mycroft 			goto giveup;
1.39   mycroft 		}
1.39   mycroft 	} else {
1.39   mycroft 		if (sbdsp_wdsp(sc, SB_DSP_WDMA) < 0 ||
1.39   mycroft 		    sbdsp_wdsp(sc, cc) < 0 ||
1.39   mycroft 		    sbdsp_wdsp(sc, cc >> 8) < 0) {
1.39   mycroft 		        DPRINTF(("sbdsp_dma_output: SB1 DMA start failed\n"));
1.15   mycroft 			goto giveup;
 1.1    brezak 		}
 1.1    brezak 	}
 1.1    brezak 	return 0;
 1.1    brezak
1.15   mycroft giveup:
 1.1    brezak 	sbdsp_reset(sc);
 1.1    brezak 	return EIO;
 1.1    brezak }
 1.1    brezak
 1.1    brezak /*
 1.1    brezak  * Only the DSP unit on the sound blaster generates interrupts.
 1.1    brezak  * There are three cases of interrupt: reception of a midi byte
 1.1    brezak  * (when mode is enabled), completion of dma transmission, or
 1.1    brezak  * completion of a dma reception.  The three modes are mutually
 1.1    brezak  * exclusive so we know a priori which event has occurred.
 1.1    brezak  */
 1.1    brezak int
 1.6       cgd sbdsp_intr(arg)
 1.6       cgd 	void *arg;
 1.1    brezak {
 1.6       cgd 	register struct sbdsp_softc *sc = arg;
1.15   mycroft 	u_char x;
 1.1    brezak
1.12    brezak #ifdef AUDIO_DEBUG
 1.1    brezak 	if (sbdspdebug > 1)
 1.1    brezak 		Dprintf("sbdsp_intr: intr=0x%x\n", sc->sc_intr);
 1.1    brezak #endif
1.39   mycroft 	if (ISSB16CLASS(sc)) {
1.39   mycroft 		x = sbdsp_mix_read(sc, SBP_IRQ_STATUS);
1.39   mycroft 		if ((x & 3) == 0)
1.39   mycroft 			return 0;
1.39   mycroft 	} else {
1.39   mycroft 		if (!isa_dmafinished(sc->dmachan))
1.39   mycroft 			return 0;
1.20   mycroft 	}
 1.1    brezak 	sc->sc_interrupts++;
1.15   mycroft 	delay(10);
 1.1    brezak #if 0
 1.1    brezak 	if (sc->sc_mintr != 0) {
1.31  christos 		x = sbdsp_rdsp(sc);
1.15   mycroft 		(*sc->sc_mintr)(sc->sc_arg, x);
 1.1    brezak 	} else
 1.1    brezak #endif
 1.1    brezak 	if (sc->sc_intr != 0) {
1.35   mycroft 		/* clear interrupt */
1.35   mycroft 		x = bus_space_read_1(sc->sc_iot, sc->sc_ioh,
1.35   mycroft 		    sc->sc_precision == 16 ? SBP_DSP_IRQACK16 :
1.35   mycroft 					     SBP_DSP_IRQACK8);
1.39   mycroft 		if (!ISSB2CLASS(sc))
1.39   mycroft 			isa_dmadone(sc->dmaflags, sc->dmaaddr, sc->dmacnt,
1.39   mycroft 			    sc->dmachan);
 1.1    brezak 		(*sc->sc_intr)(sc->sc_arg);
1.35   mycroft 	} else {
1.35   mycroft 		return 0;
 1.1    brezak 	}
 1.1    brezak 	return 1;
 1.1    brezak }
 1.1    brezak
 1.1    brezak #if 0
 1.1    brezak /*
 1.1    brezak  * Enter midi uart mode and arrange for read interrupts
 1.1    brezak  * to vector to `intr'.  This puts the card in a mode
 1.1    brezak  * which allows only midi I/O; the card must be reset
 1.1    brezak  * to leave this mode.  Unfortunately, the card does not
 1.1    brezak  * use transmit interrupts, so bytes must be output
 1.1    brezak  * using polling.  To keep the polling overhead to a
 1.1    brezak  * minimum, output should be driven off a timer.
 1.1    brezak  * This is a little tricky since only 320us separate
 1.1    brezak  * consecutive midi bytes.
 1.1    brezak  */
 1.1    brezak void
 1.1    brezak sbdsp_set_midi_mode(sc, intr, arg)
 1.1    brezak 	struct sbdsp_softc *sc;
 1.1    brezak 	void (*intr)();
 1.1    brezak 	void *arg;
 1.1    brezak {
 1.1    brezak
1.31  christos 	sbdsp_wdsp(sc, SB_MIDI_UART_INTR);
 1.1    brezak 	sc->sc_mintr = intr;
 1.1    brezak 	sc->sc_intr = 0;
 1.1    brezak 	sc->sc_arg = arg;
 1.1    brezak }
 1.1    brezak
 1.1    brezak /*
 1.1    brezak  * Write a byte to the midi port, when in midi uart mode.
 1.1    brezak  */
 1.1    brezak void
 1.1    brezak sbdsp_midi_output(sc, v)
 1.1    brezak 	struct sbdsp_softc *sc;
 1.1    brezak 	int v;
 1.1    brezak {
 1.1    brezak
1.31  christos 	if (sbdsp_wdsp(sc, v) < 0)
 1.1    brezak 		++sberr.wmidi;
 1.1    brezak }
 1.1    brezak #endif
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_setfd(addr, flag)
 1.5   mycroft 	void *addr;
 1.1    brezak 	int flag;
 1.1    brezak {
 1.1    brezak 	/* Can't do full-duplex */
 1.1    brezak 	return(ENOTTY);
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_mixer_set_port(addr, cp)
1.18   mycroft 	void *addr;
1.18   mycroft 	mixer_ctrl_t *cp;
 1.1    brezak {
1.18   mycroft 	register struct sbdsp_softc *sc = addr;
1.18   mycroft 	int src, gain;
 1.1    brezak
1.18   mycroft 	DPRINTF(("sbdsp_mixer_set_port: port=%d num_channels=%d\n", cp->dev,
1.18   mycroft 	    cp->un.value.num_channels));
 1.1    brezak
1.22   mycroft 	if (!ISSBPROCLASS(sc))
1.22   mycroft 		return EINVAL;
1.22   mycroft
 1.1    brezak 	/*
1.18   mycroft 	 * Everything is a value except for SBPro BASS/TREBLE and
1.18   mycroft 	 * RECORD_SOURCE
 1.1    brezak 	 */
1.18   mycroft 	switch (cp->dev) {
 1.1    brezak 	case SB_SPEAKER:
1.18   mycroft 		cp->dev = SB_MASTER_VOL;
1.18   mycroft 	case SB_MIC_PORT:
1.18   mycroft 	case SB_LINE_IN_PORT:
1.18   mycroft 	case SB_DAC_PORT:
1.18   mycroft 	case SB_FM_PORT:
1.18   mycroft 	case SB_CD_PORT:
1.18   mycroft 	case SB_MASTER_VOL:
1.18   mycroft 		if (cp->type != AUDIO_MIXER_VALUE)
1.18   mycroft 			return EINVAL;
1.18   mycroft
1.18   mycroft 		/*
1.18   mycroft 		 * All the mixer ports are stereo except for the microphone.
1.18   mycroft 		 * If we get a single-channel gain value passed in, then we
1.18   mycroft 		 * duplicate it to both left and right channels.
1.18   mycroft 		 */
1.18   mycroft
1.18   mycroft 		switch (cp->dev) {
1.18   mycroft 		case SB_MIC_PORT:
1.18   mycroft 			if (cp->un.value.num_channels != 1)
1.18   mycroft 				return EINVAL;
1.18   mycroft
1.18   mycroft 			/* handle funny microphone gain */
1.18   mycroft 			gain = SBP_AGAIN_TO_MICGAIN(cp->un.value.level[AUDIO_MIXER_LEVEL_MONO]);
1.18   mycroft 			break;
1.18   mycroft 		case SB_LINE_IN_PORT:
1.18   mycroft 		case SB_DAC_PORT:
1.18   mycroft 		case SB_FM_PORT:
1.18   mycroft 		case SB_CD_PORT:
1.18   mycroft 		case SB_MASTER_VOL:
1.18   mycroft 			switch (cp->un.value.num_channels) {
1.18   mycroft 			case 1:
1.21   mycroft 				gain = sbdsp_mono_vol(SBP_AGAIN_TO_SBGAIN(cp->un.value.level[AUDIO_MIXER_LEVEL_MONO]));
1.18   mycroft 				break;
1.18   mycroft 			case 2:
1.18   mycroft 				gain = sbdsp_stereo_vol(SBP_AGAIN_TO_SBGAIN(cp->un.value.level[AUDIO_MIXER_LEVEL_LEFT]),
1.18   mycroft 							SBP_AGAIN_TO_SBGAIN(cp->un.value.level[AUDIO_MIXER_LEVEL_RIGHT]));
1.18   mycroft 				break;
1.18   mycroft 			default:
1.18   mycroft 				return EINVAL;
1.18   mycroft 			}
1.18   mycroft 			break;
1.25  christos 		default:
1.25  christos 			return EINVAL;
1.18   mycroft 		}
1.18   mycroft
1.18   mycroft 		switch (cp->dev) {
1.18   mycroft 		case SB_MIC_PORT:
1.18   mycroft 			src = SBP_MIC_VOL;
1.18   mycroft 			break;
1.18   mycroft 		case SB_MASTER_VOL:
1.18   mycroft 			src = SBP_MASTER_VOL;
1.18   mycroft 			break;
1.18   mycroft 		case SB_LINE_IN_PORT:
1.18   mycroft 			src = SBP_LINE_VOL;
1.18   mycroft 			break;
1.18   mycroft 		case SB_DAC_PORT:
1.18   mycroft 			src = SBP_DAC_VOL;
1.18   mycroft 			break;
1.18   mycroft 		case SB_FM_PORT:
1.18   mycroft 			src = SBP_FM_VOL;
1.18   mycroft 			break;
1.18   mycroft 		case SB_CD_PORT:
1.18   mycroft 			src = SBP_CD_VOL;
1.18   mycroft 			break;
1.25  christos 		default:
1.25  christos 			return EINVAL;
1.18   mycroft 		}
1.18   mycroft
1.18   mycroft 		sbdsp_mix_write(sc, src, gain);
1.18   mycroft 		sc->gain[cp->dev] = gain;
1.18   mycroft 		break;
1.18   mycroft
1.18   mycroft 	case SB_TREBLE:
1.18   mycroft 	case SB_BASS:
 1.1    brezak 	case SB_RECORD_SOURCE:
1.18   mycroft 		if (cp->type != AUDIO_MIXER_ENUM)
1.18   mycroft 			return EINVAL;
1.18   mycroft
1.18   mycroft 		switch (cp->dev) {
1.18   mycroft 		case SB_TREBLE:
1.18   mycroft 			return sbdsp_set_ifilter(addr, cp->un.ord ? SBP_TREBLE_EQ : 0);
1.18   mycroft 		case SB_BASS:
1.18   mycroft 			return sbdsp_set_ifilter(addr, cp->un.ord ? SBP_BASS_EQ : 0);
1.18   mycroft 		case SB_RECORD_SOURCE:
1.18   mycroft 			return sbdsp_set_in_port(addr, cp->un.ord);
1.18   mycroft 		}
 1.1    brezak
1.18   mycroft 		break;
1.22   mycroft
1.22   mycroft 	default:
1.22   mycroft 		return EINVAL;
1.18   mycroft 	}
 1.1    brezak
1.18   mycroft 	return (0);
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_mixer_get_port(addr, cp)
1.18   mycroft 	void *addr;
1.18   mycroft 	mixer_ctrl_t *cp;
 1.1    brezak {
1.18   mycroft 	register struct sbdsp_softc *sc = addr;
1.19   mycroft 	int gain;
 1.1    brezak
1.18   mycroft 	DPRINTF(("sbdsp_mixer_get_port: port=%d", cp->dev));
 1.1    brezak
1.22   mycroft 	if (!ISSBPROCLASS(sc))
1.22   mycroft 		return EINVAL;
1.22   mycroft
1.18   mycroft 	switch (cp->dev) {
1.18   mycroft 	case SB_SPEAKER:
1.18   mycroft 		cp->dev = SB_MASTER_VOL;
1.17       jtk 	case SB_MIC_PORT:
 1.1    brezak 	case SB_LINE_IN_PORT:
1.18   mycroft 	case SB_DAC_PORT:
1.18   mycroft 	case SB_FM_PORT:
1.18   mycroft 	case SB_CD_PORT:
1.18   mycroft 	case SB_MASTER_VOL:
1.18   mycroft 		gain = sc->gain[cp->dev];
1.18   mycroft
1.18   mycroft 		switch (cp->dev) {
1.18   mycroft 		case SB_MIC_PORT:
1.18   mycroft 			if (cp->un.value.num_channels != 1)
1.18   mycroft 				return EINVAL;
1.18   mycroft
1.18   mycroft 			cp->un.value.level[AUDIO_MIXER_LEVEL_MONO] = SBP_MICGAIN_TO_AGAIN(gain);
1.18   mycroft 			break;
1.18   mycroft 		case SB_LINE_IN_PORT:
1.18   mycroft 		case SB_DAC_PORT:
1.18   mycroft 		case SB_FM_PORT:
1.18   mycroft 		case SB_CD_PORT:
1.18   mycroft 		case SB_MASTER_VOL:
1.18   mycroft 			switch (cp->un.value.num_channels) {
1.18   mycroft 			case 1:
1.18   mycroft 				cp->un.value.level[AUDIO_MIXER_LEVEL_MONO] = SBP_SBGAIN_TO_AGAIN(gain);
1.18   mycroft 				break;
1.18   mycroft 			case 2:
1.18   mycroft 				cp->un.value.level[AUDIO_MIXER_LEVEL_LEFT] = SBP_LEFTGAIN(gain);
1.18   mycroft 				cp->un.value.level[AUDIO_MIXER_LEVEL_RIGHT] = SBP_RIGHTGAIN(gain);
1.18   mycroft 				break;
1.18   mycroft 			default:
1.18   mycroft 				return EINVAL;
1.18   mycroft 			}
1.18   mycroft 			break;
1.18   mycroft 		}
1.18   mycroft
1.22   mycroft 		break;
1.22   mycroft
1.17       jtk 	case SB_TREBLE:
1.17       jtk 	case SB_BASS:
1.18   mycroft 	case SB_RECORD_SOURCE:
1.18   mycroft 		switch (cp->dev) {
1.18   mycroft 		case SB_TREBLE:
1.18   mycroft 			cp->un.ord = sbdsp_get_ifilter(addr) == SBP_TREBLE_EQ;
1.18   mycroft 			return 0;
1.18   mycroft 		case SB_BASS:
1.18   mycroft 			cp->un.ord = sbdsp_get_ifilter(addr) == SBP_BASS_EQ;
1.18   mycroft 			return 0;
1.18   mycroft 		case SB_RECORD_SOURCE:
1.18   mycroft 			cp->un.ord = sbdsp_get_in_port(addr);
1.18   mycroft 			return 0;
1.18   mycroft 		}
1.18   mycroft
 1.1    brezak 		break;
1.22   mycroft
1.22   mycroft 	default:
1.22   mycroft 		return EINVAL;
1.18   mycroft 	}
1.18   mycroft
1.18   mycroft 	return (0);
 1.1    brezak }
 1.1    brezak
 1.1    brezak int
 1.1    brezak sbdsp_mixer_query_devinfo(addr, dip)
1.18   mycroft 	void *addr;
1.18   mycroft 	register mixer_devinfo_t *dip;
 1.1    brezak {
1.18   mycroft 	register struct sbdsp_softc *sc = addr;
1.18   mycroft
1.18   mycroft 	DPRINTF(("sbdsp_mixer_query_devinfo: index=%d\n", dip->index));
1.18   mycroft
1.18   mycroft 	switch (dip->index) {
1.18   mycroft 	case SB_MIC_PORT:
1.18   mycroft 		dip->type = AUDIO_MIXER_VALUE;
1.18   mycroft 		dip->mixer_class = SB_INPUT_CLASS;
1.18   mycroft 		dip->prev = AUDIO_MIXER_LAST;
1.18   mycroft 		dip->next = AUDIO_MIXER_LAST;
1.18   mycroft 		strcpy(dip->label.name, AudioNmicrophone);
1.18   mycroft 		dip->un.v.num_channels = 1;
1.18   mycroft 		strcpy(dip->un.v.units.name, AudioNvolume);
1.18   mycroft 		return 0;
1.18   mycroft
1.18   mycroft 	case SB_SPEAKER:
1.18   mycroft 		dip->type = AUDIO_MIXER_VALUE;
1.18   mycroft 		dip->mixer_class = SB_OUTPUT_CLASS;
1.18   mycroft 		dip->prev = AUDIO_MIXER_LAST;
1.18   mycroft 		dip->next = AUDIO_MIXER_LAST;
1.18   mycroft 		strcpy(dip->label.name, AudioNspeaker);
1.18   mycroft 		dip->un.v.num_channels = 1;
1.18   mycroft 		strcpy(dip->un.v.units.name, AudioNvolume);
1.18   mycroft 		return 0;
1.18   mycroft
1.18   mycroft 	case SB_INPUT_CLASS:
1.18   mycroft 		dip->type = AUDIO_MIXER_CLASS;
1.18   mycroft 		dip->mixer_class = SB_INPUT_CLASS;
1.18   mycroft 		dip->next = dip->prev = AUDIO_MIXER_LAST;
1.18   mycroft 		strcpy(dip->label.name, AudioCInputs);
1.18   mycroft 		return 0;
 1.1    brezak
1.18   mycroft 	case SB_OUTPUT_CLASS:
1.18   mycroft 		dip->type = AUDIO_MIXER_CLASS;
1.18   mycroft 		dip->mixer_class = SB_OUTPUT_CLASS;
1.18   mycroft 		dip->next = dip->prev = AUDIO_MIXER_LAST;
1.18   mycroft 		strcpy(dip->label.name, AudioCOutputs);
1.18   mycroft 		return 0;
1.18   mycroft 	}
1.18   mycroft
1.18   mycroft 	if (ISSBPROCLASS(sc)) {
1.18   mycroft 		switch (dip->index) {
1.18   mycroft 		case SB_LINE_IN_PORT:
1.18   mycroft 			dip->type = AUDIO_MIXER_VALUE;
1.18   mycroft 			dip->mixer_class = SB_INPUT_CLASS;
1.18   mycroft 			dip->prev = AUDIO_MIXER_LAST;
1.18   mycroft 			dip->next = AUDIO_MIXER_LAST;
1.18   mycroft 			strcpy(dip->label.name, AudioNline);
1.18   mycroft 			dip->un.v.num_channels = 2;
1.18   mycroft 			strcpy(dip->un.v.units.name, AudioNvolume);
1.18   mycroft 			return 0;
 1.1    brezak
1.18   mycroft 		case SB_DAC_PORT:
1.18   mycroft 			dip->type = AUDIO_MIXER_VALUE;
1.18   mycroft 			dip->mixer_class = SB_INPUT_CLASS;
1.18   mycroft 			dip->prev = AUDIO_MIXER_LAST;
1.18   mycroft 			dip->next = AUDIO_MIXER_LAST;
1.18   mycroft 			strcpy(dip->label.name, AudioNdac);
1.18   mycroft 			dip->un.v.num_channels = 2;
1.18   mycroft 			strcpy(dip->un.v.units.name, AudioNvolume);
1.18   mycroft 			return 0;
1.17       jtk
1.18   mycroft 		case SB_CD_PORT:
1.18   mycroft 			dip->type = AUDIO_MIXER_VALUE;
1.18   mycroft 			dip->mixer_class = SB_INPUT_CLASS;
1.18   mycroft 			dip->prev = AUDIO_MIXER_LAST;
1.18   mycroft 			dip->next = AUDIO_MIXER_LAST;
1.18   mycroft 			strcpy(dip->label.name, AudioNcd);
1.18   mycroft 			dip->un.v.num_channels = 2;
1.18   mycroft 			strcpy(dip->un.v.units.name, AudioNvolume);
1.18   mycroft 			return 0;
 1.1    brezak
1.18   mycroft 		case SB_FM_PORT:
1.18   mycroft 			dip->type = AUDIO_MIXER_VALUE;
1.18   mycroft 			dip->mixer_class = SB_INPUT_CLASS;
1.18   mycroft 			dip->prev = AUDIO_MIXER_LAST;
1.18   mycroft 			dip->next = AUDIO_MIXER_LAST;
1.18   mycroft 			strcpy(dip->label.name, AudioNfmsynth);
1.18   mycroft 			dip->un.v.num_channels = 2;
1.18   mycroft 			strcpy(dip->un.v.units.name, AudioNvolume);
1.18   mycroft 			return 0;
1.18   mycroft
1.18   mycroft 		case SB_MASTER_VOL:
1.18   mycroft 			dip->type = AUDIO_MIXER_VALUE;
1.18   mycroft 			dip->mixer_class = SB_OUTPUT_CLASS;
1.18   mycroft 			dip->prev = AUDIO_MIXER_LAST;
1.18   mycroft 			dip->next = AUDIO_MIXER_LAST;
1.18   mycroft 			strcpy(dip->label.name, AudioNvolume);
1.18   mycroft 			dip->un.v.num_channels = 2;
1.18   mycroft 			strcpy(dip->un.v.units.name, AudioNvolume);
1.18   mycroft 			return 0;
1.18   mycroft
1.18   mycroft 		case SB_RECORD_SOURCE:
1.18   mycroft 			dip->mixer_class = SB_RECORD_CLASS;
1.18   mycroft 			dip->type = AUDIO_MIXER_ENUM;
1.18   mycroft 			dip->prev = AUDIO_MIXER_LAST;
1.18   mycroft 			dip->next = AUDIO_MIXER_LAST;
1.18   mycroft 			strcpy(dip->label.name, AudioNsource);
1.18   mycroft 			dip->un.e.num_mem = 3;
1.18   mycroft 			strcpy(dip->un.e.member[0].label.name, AudioNmicrophone);
1.18   mycroft 			dip->un.e.member[0].ord = SB_MIC_PORT;
1.18   mycroft 			strcpy(dip->un.e.member[1].label.name, AudioNcd);
1.18   mycroft 			dip->un.e.member[1].ord = SB_CD_PORT;
1.18   mycroft 			strcpy(dip->un.e.member[2].label.name, AudioNline);
1.18   mycroft 			dip->un.e.member[2].ord = SB_LINE_IN_PORT;
1.18   mycroft 			return 0;
1.18   mycroft
1.18   mycroft 		case SB_BASS:
1.18   mycroft 			dip->type = AUDIO_MIXER_ENUM;
1.18   mycroft 			dip->mixer_class = SB_INPUT_CLASS;
1.18   mycroft 			dip->prev = AUDIO_MIXER_LAST;
1.18   mycroft 			dip->next = AUDIO_MIXER_LAST;
1.18   mycroft 			strcpy(dip->label.name, AudioNbass);
1.18   mycroft 			dip->un.e.num_mem = 2;
1.18   mycroft 			strcpy(dip->un.e.member[0].label.name, AudioNoff);
1.18   mycroft 			dip->un.e.member[0].ord = 0;
1.18   mycroft 			strcpy(dip->un.e.member[1].label.name, AudioNon);
1.18   mycroft 			dip->un.e.member[1].ord = 1;
1.18   mycroft 			return 0;
1.18   mycroft
1.18   mycroft 		case SB_TREBLE:
1.18   mycroft 			dip->type = AUDIO_MIXER_ENUM;
1.18   mycroft 			dip->mixer_class = SB_INPUT_CLASS;
1.18   mycroft 			dip->prev = AUDIO_MIXER_LAST;
1.18   mycroft 			dip->next = AUDIO_MIXER_LAST;
1.18   mycroft 			strcpy(dip->label.name, AudioNtreble);
1.18   mycroft 			dip->un.e.num_mem = 2;
1.18   mycroft 			strcpy(dip->un.e.member[0].label.name, AudioNoff);
1.18   mycroft 			dip->un.e.member[0].ord = 0;
1.18   mycroft 			strcpy(dip->un.e.member[1].label.name, AudioNon);
1.18   mycroft 			dip->un.e.member[1].ord = 1;
1.18   mycroft 			return 0;
1.18   mycroft
1.18   mycroft 		case SB_RECORD_CLASS:			/* record source class */
1.18   mycroft 			dip->type = AUDIO_MIXER_CLASS;
1.18   mycroft 			dip->mixer_class = SB_RECORD_CLASS;
1.18   mycroft 			dip->next = dip->prev = AUDIO_MIXER_LAST;
1.18   mycroft 			strcpy(dip->label.name, AudioCRecord);
1.18   mycroft 			return 0;
1.18   mycroft 		}
1.18   mycroft 	}
 1.1    brezak
1.18   mycroft 	return ENXIO;
 1.1    brezak }