dev/isa/gus.c

1.101    cegger /*	$NetBSD: gus.c,v 1.101 2008/04/08 20:08:49 cegger Exp $	*/
  1.2       cgd
  1.5       jtc /*-
 1.65   mycroft  * Copyright (c) 1996, 1999 The NetBSD Foundation, Inc.
  1.5       jtc  * All rights reserved.
  1.5       jtc  *
  1.5       jtc  * This code is derived from software contributed to The NetBSD Foundation
  1.5       jtc  * by Ken Hornstein and John Kohl.
  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:
 1.88     perry  *        This product includes software developed by the NetBSD
  1.5       jtc  *	  Foundation, Inc. and its contributors.
 1.88     perry  * 4. Neither the name of The NetBSD Foundation nor the names of its
 1.88     perry  *    contributors may be used to endorse or promote products derived
  1.5       jtc  *    from this software without specific prior written permission.
  1.1    brezak  *
  1.6       jtc  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
  1.6       jtc  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
  1.6       jtc  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 1.45       jtc  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
 1.45       jtc  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
  1.6       jtc  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
  1.6       jtc  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
  1.6       jtc  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
  1.6       jtc  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
  1.6       jtc  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
  1.6       jtc  * POSSIBILITY OF SUCH DAMAGE.
  1.1    brezak  */
  1.2       cgd
  1.1    brezak /*
  1.2       cgd  *
  1.1    brezak  * TODO:
  1.1    brezak  *	. figure out why mixer activity while sound is playing causes problems
  1.1    brezak  *	  (phantom interrupts?)
 1.87      kent  *	. figure out a better deinterleave strategy that avoids sucking up
  1.1    brezak  *	  CPU, memory and cache bandwidth.  (Maybe a special encoding?
  1.1    brezak  *	  Maybe use the double-speed sampling/hardware deinterleave trick
  1.1    brezak  *	  from the GUS SDK?)  A 486/33 isn't quite fast enough to keep
  1.1    brezak  *	  up with 44.1kHz 16-bit stereo output without some drop-outs.
 1.79       wiz  *	. use CS4231 for 16-bit sampling, for A-law and mu-law playback.
  1.1    brezak  *	. actually test full-duplex sampling(recording) and playback.
  1.1    brezak  */
  1.2       cgd
  1.1    brezak /*
  1.1    brezak  * Gravis UltraSound driver
  1.1    brezak  *
  1.1    brezak  * For more detailed information, see the GUS developers' kit
  1.1    brezak  * available on the net at:
  1.1    brezak  *
 1.53  augustss  * http://www.gravis.com/Public/sdk/GUSDK222.ZIP
 1.53  augustss  *
  1.1    brezak  *		See ultrawrd.doc inside--it's MS Word (ick), but it's the bible
  1.1    brezak  *
  1.1    brezak  */
  1.2       cgd
  1.1    brezak /*
  1.1    brezak  * The GUS Max has a slightly strange set of connections between the CS4231
  1.1    brezak  * and the GF1 and the DMA interconnects.  It's set up so that the CS4231 can
  1.1    brezak  * be playing while the GF1 is loading patches from the system.
  1.1    brezak  *
  1.1    brezak  * Here's a recreation of the DMA interconnect diagram:
  1.1    brezak  *
  1.1    brezak  *       GF1
  1.1    brezak  *   +---------+				 digital
  1.1    brezak  *   |         |  record			 ASIC
  1.1    brezak  *   |         |--------------+
  1.1    brezak  *   |         |              |		       +--------+
  1.1    brezak  *   |         | play (dram)  |      +----+    |	|
  1.1    brezak  *   |         |--------------(------|-\  |    |   +-+  |
 1.80       wiz  *   +---------+              |      |  >-|----|---|C|--|------  DMA chan 1
 1.87      kent  *                            |  +---|-/  |    |   +-+	|
  1.1    brezak  *                            |  |   +----+    |    |   |
  1.1    brezak  *                            |	 |   +----+    |    |   |
  1.1    brezak  *   +---------+        +-+   +--(---|-\  |    |    |   |
 1.80       wiz  *   |         | play   |8|      |   |  >-|----|----+---|------  DMA chan 2
  1.1    brezak  *   | ---C----|--------|/|------(---|-/  |    |        |
  1.1    brezak  *   |    ^    |record  |1|      |   +----+    |	|
 1.87      kent  *   |    |    |   /----|6|------+	       +--------+
  1.1    brezak  *   | ---+----|--/     +-+
  1.1    brezak  *   +---------+
 1.87      kent  *     CS4231		8-to-16 bit bus conversion, if needed
  1.1    brezak  *
  1.1    brezak  *
  1.1    brezak  * "C" is an optional combiner.
  1.1    brezak  *
  1.1    brezak  */
 1.73     lukem
 1.73     lukem #include <sys/cdefs.h>
1.101    cegger __KERNEL_RCSID(0, "$NetBSD: gus.c,v 1.101 2008/04/08 20:08:49 cegger Exp $");
  1.1    brezak
  1.1    brezak #include "gus.h"
  1.1    brezak #if NGUS > 0
  1.1    brezak
  1.1    brezak #include <sys/param.h>
  1.1    brezak #include <sys/systm.h>
 1.69   thorpej #include <sys/callout.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 <sys/fcntl.h>
  1.1    brezak #include <sys/malloc.h>
  1.1    brezak #include <sys/kernel.h>
  1.1    brezak
1.100        ad #include <sys/cpu.h>
1.100        ad #include <sys/intr.h>
1.100        ad #include <sys/bus.h>
 1.99        ad
  1.1    brezak #include <sys/audioio.h>
  1.1    brezak #include <dev/audio_if.h>
  1.1    brezak #include <dev/mulaw.h>
 1.36  augustss #include <dev/auconv.h>
  1.1    brezak
  1.1    brezak #include <dev/isa/isavar.h>
  1.1    brezak #include <dev/isa/isadmavar.h>
  1.1    brezak
  1.1    brezak #include <dev/ic/ics2101reg.h>
  1.1    brezak #include <dev/ic/cs4231reg.h>
  1.1    brezak #include <dev/ic/ad1848reg.h>
  1.1    brezak #include <dev/isa/ics2101var.h>
  1.1    brezak #include <dev/isa/ad1848var.h>
 1.12       jtk #include <dev/isa/cs4231var.h>
  1.1    brezak #include "gusreg.h"
  1.1    brezak
  1.8       jtk #ifdef AUDIO_DEBUG
  1.8       jtk #define STATIC /* empty; for debugging symbols */
  1.8       jtk #else
  1.8       jtk #define STATIC static
  1.8       jtk #endif
  1.8       jtk
  1.1    brezak /*
  1.1    brezak  * Software state of a single "voice" on the GUS
  1.1    brezak  */
  1.1    brezak
  1.1    brezak struct gus_voice {
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Various control bits
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	unsigned char voccntl;	/* State of voice control register */
  1.1    brezak 	unsigned char volcntl;	/* State of volume control register */
  1.1    brezak 	unsigned char pan_pos;	/* Position of volume panning (4 bits) */
  1.1    brezak 	int rate;		/* Sample rate of voice being played back */
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Address of the voice data into the GUS's DRAM.  20 bits each
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	u_long start_addr;	/* Starting address of voice data loop area */
  1.1    brezak 	u_long end_addr;	/* Ending address of voice data loop */
  1.1    brezak 	u_long current_addr;	/* Beginning address of voice data
  1.1    brezak 				   (start playing here) */
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * linear volume values for the GUS's volume ramp.  0-511 (9 bits).
  1.1    brezak 	 * These values must be translated into the logarithmic values using
  1.1    brezak 	 * gus_log_volumes[]
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	int start_volume;	/* Starting position of volume ramp */
  1.1    brezak 	int current_volume;	/* Current position of volume on volume ramp */
  1.1    brezak 	int end_volume;		/* Ending position of volume on volume ramp */
  1.1    brezak };
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Software state of GUS
  1.1    brezak  */
  1.1    brezak
  1.1    brezak struct gus_softc {
  1.1    brezak 	struct device sc_dev;		/* base device */
  1.1    brezak 	void *sc_ih;			/* interrupt vector */
 1.22  augustss 	bus_space_tag_t sc_iot;		/* tag */
 1.55   thorpej 	isa_chipset_tag_t sc_ic;	/* ISA chipset info */
 1.43  augustss 	bus_space_handle_t sc_ioh1;	/* handle */
 1.43  augustss 	bus_space_handle_t sc_ioh2;	/* handle */
 1.43  augustss 	bus_space_handle_t sc_ioh3;	/* ICS2101 handle */
 1.43  augustss 	bus_space_handle_t sc_ioh4;	/* MIDI handle */
  1.1    brezak
 1.98        ad 	callout_t sc_dmaout_ch;
 1.69   thorpej
  1.3   mycroft 	int sc_iobase;			/* I/O base address */
  1.3   mycroft 	int sc_irq;			/* IRQ used */
 1.66   mycroft 	int sc_playdrq;			/* DMA channel for play */
 1.68   thorpej 	bus_size_t sc_play_maxsize;	/* DMA size for play */
  1.3   mycroft 	int sc_recdrq;			/* DMA channel for recording */
 1.68   thorpej 	bus_size_t sc_req_maxsize;	/* DMA size for recording */
  1.1    brezak
  1.1    brezak 	int sc_flags;			/* Various flags about the GUS */
  1.1    brezak #define GUS_MIXER_INSTALLED	0x01	/* An ICS mixer is installed */
  1.1    brezak #define GUS_LOCKED		0x02	/* GUS is busy doing multi-phase DMA */
  1.1    brezak #define GUS_CODEC_INSTALLED	0x04	/* CS4231 installed/MAX */
  1.1    brezak #define GUS_PLAYING		0x08	/* GUS is playing a voice */
  1.1    brezak #define GUS_DMAOUT_ACTIVE	0x10	/* GUS is busy doing audio DMA */
  1.1    brezak #define GUS_DMAIN_ACTIVE	0x20	/* GUS is busy sampling  */
  1.1    brezak #define GUS_OPEN		0x100	/* GUS is open */
  1.1    brezak 	int sc_dsize;			/* Size of GUS DRAM */
  1.1    brezak 	int sc_voices;			/* Number of active voices */
  1.1    brezak 	u_char sc_revision;		/* Board revision of GUS */
  1.1    brezak 	u_char sc_mixcontrol;		/* Value of GUS_MIX_CONTROL register */
  1.1    brezak
  1.1    brezak 	u_long sc_orate;		/* Output sampling rate */
  1.1    brezak 	u_long sc_irate;		/* Input sampling rate */
  1.1    brezak
  1.1    brezak 	int sc_encoding;		/* Current data encoding type */
  1.1    brezak 	int sc_precision;		/* # of bits of precision */
  1.1    brezak 	int sc_channels;		/* Number of active channels */
  1.1    brezak 	int sc_blocksize;		/* Current blocksize */
  1.1    brezak 	int sc_chanblocksize;		/* Current blocksize for each in-use
  1.1    brezak 					   channel */
  1.1    brezak 	short sc_nbufs;			/* how many on-GUS bufs per-channel */
  1.1    brezak 	short sc_bufcnt;		/* how many need to be played */
  1.1    brezak 	void *sc_deintr_buf;		/* deinterleave buffer for stereo */
  1.1    brezak
  1.1    brezak 	int sc_ogain;			/* Output gain control */
  1.1    brezak 	u_char sc_out_port;		/* Current out port (generic only) */
  1.1    brezak 	u_char sc_in_port;		/* keep track of it when no codec */
  1.1    brezak
 1.87      kent 	void (*sc_dmaoutintr)(void*);	/* DMA completion intr handler */
  1.1    brezak 	void *sc_outarg;		/* argument for sc_dmaoutintr() */
  1.1    brezak 	u_char *sc_dmaoutaddr;		/* for isa_dmadone */
  1.1    brezak 	u_long sc_gusaddr;		/* where did we just put it? */
  1.1    brezak 	int sc_dmaoutcnt;		/* for isa_dmadone */
  1.1    brezak
 1.87      kent 	void (*sc_dmainintr)(void*);	/* DMA completion intr handler */
  1.1    brezak 	void *sc_inarg;			/* argument for sc_dmaoutintr() */
  1.1    brezak 	u_char *sc_dmainaddr;		/* for isa_dmadone */
  1.1    brezak 	int sc_dmaincnt;		/* for isa_dmadone */
  1.1    brezak
  1.1    brezak 	struct stereo_dma_intr {
 1.87      kent 		void (*intr)(void *);
  1.1    brezak 		void *arg;
  1.1    brezak 		u_char *buffer;
  1.1    brezak 		u_long dmabuf;
  1.1    brezak 		int size;
  1.1    brezak 		int flags;
  1.1    brezak 	} sc_stereo;
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * State information for linear audio layer
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	int sc_dmabuf;			/* Which ring buffer we're DMA'ing to */
  1.1    brezak 	int sc_playbuf;			/* Which ring buffer we're playing */
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Voice information array.  All voice-specific information is stored
  1.1    brezak 	 * here
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	struct gus_voice sc_voc[32];	/* Voice data for each voice */
  1.1    brezak 	union {
  1.1    brezak 		struct ics2101_softc sc_mixer_u;
 1.60        pk 		struct ad1848_isa_softc sc_codec_u;
  1.1    brezak 	} u;
  1.1    brezak #define sc_mixer u.sc_mixer_u
  1.1    brezak #define sc_codec u.sc_codec_u
  1.1    brezak };
  1.1    brezak
  1.1    brezak struct ics2101_volume {
  1.1    brezak 	u_char left;
  1.1    brezak 	u_char right;
  1.1    brezak };
  1.1    brezak
  1.1    brezak #define HAS_CODEC(sc) ((sc)->sc_flags & GUS_CODEC_INSTALLED)
  1.1    brezak #define HAS_MIXER(sc) ((sc)->sc_flags & GUS_MIXER_INSTALLED)
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Mixer devices for ICS2101
  1.1    brezak  */
  1.1    brezak /* MIC IN mute, line in mute, line out mute are first since they can be done
  1.1    brezak    even if no ICS mixer. */
  1.1    brezak #define GUSICS_MIC_IN_MUTE		0
  1.1    brezak #define GUSICS_LINE_IN_MUTE		1
  1.1    brezak #define GUSICS_MASTER_MUTE		2
  1.1    brezak #define GUSICS_CD_MUTE			3
  1.1    brezak #define GUSICS_DAC_MUTE			4
  1.1    brezak #define GUSICS_MIC_IN_LVL		5
  1.1    brezak #define GUSICS_LINE_IN_LVL		6
  1.1    brezak #define GUSICS_CD_LVL			7
  1.1    brezak #define GUSICS_DAC_LVL			8
  1.1    brezak #define GUSICS_MASTER_LVL		9
  1.1    brezak
  1.1    brezak #define GUSICS_RECORD_SOURCE		10
  1.1    brezak
  1.1    brezak /* Classes */
  1.1    brezak #define GUSICS_INPUT_CLASS		11
  1.1    brezak #define GUSICS_OUTPUT_CLASS		12
  1.1    brezak #define GUSICS_RECORD_CLASS		13
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Mixer & MUX devices for CS4231
  1.1    brezak  */
 1.31       jtk #define GUSMAX_MONO_LVL			0 /* mic input to MUX;
  1.1    brezak 					     also mono mixer input */
 1.31       jtk #define GUSMAX_DAC_LVL			1 /* input to MUX; also mixer input */
 1.31       jtk #define GUSMAX_LINE_IN_LVL		2 /* input to MUX; also mixer input */
 1.31       jtk #define GUSMAX_CD_LVL			3 /* mixer input only */
 1.31       jtk #define GUSMAX_MONITOR_LVL		4 /* digital mix (?) */
 1.31       jtk #define GUSMAX_OUT_LVL			5 /* output level. (?) */
 1.31       jtk #define GUSMAX_SPEAKER_LVL		6 /* pseudo-device for mute */
 1.31       jtk #define GUSMAX_LINE_IN_MUTE		7 /* pre-mixer */
 1.31       jtk #define GUSMAX_DAC_MUTE			8 /* pre-mixer */
 1.31       jtk #define GUSMAX_CD_MUTE			9 /* pre-mixer */
 1.31       jtk #define GUSMAX_MONO_MUTE		10 /* pre-mixer--microphone/mono */
 1.31       jtk #define GUSMAX_MONITOR_MUTE		11 /* post-mixer level/mute */
 1.31       jtk #define GUSMAX_SPEAKER_MUTE		12 /* speaker mute */
  1.1    brezak
 1.31       jtk #define GUSMAX_REC_LVL			13 /* post-MUX gain */
  1.1    brezak
 1.31       jtk #define GUSMAX_RECORD_SOURCE		14
  1.1    brezak
  1.1    brezak /* Classes */
 1.31       jtk #define GUSMAX_INPUT_CLASS		15
 1.31       jtk #define GUSMAX_RECORD_CLASS		16
 1.31       jtk #define GUSMAX_MONITOR_CLASS		17
 1.31       jtk #define GUSMAX_OUTPUT_CLASS		18
  1.1    brezak
  1.1    brezak #ifdef AUDIO_DEBUG
  1.1    brezak #define GUSPLAYDEBUG	/*XXX*/
 1.33  augustss #define DPRINTF(x)	if (gusdebug) printf x
 1.33  augustss #define DMAPRINTF(x)	if (gusdmadebug) printf x
  1.1    brezak int	gusdebug = 0;
  1.1    brezak int	gusdmadebug = 0;
  1.1    brezak #else
  1.1    brezak #define DPRINTF(x)
  1.1    brezak #define DMAPRINTF(x)
  1.1    brezak #endif
  1.1    brezak int	gus_dostereo = 1;
  1.1    brezak
  1.1    brezak #define NDMARECS 2048
  1.1    brezak #ifdef GUSPLAYDEBUG
  1.1    brezak int	gusstats = 0;
  1.1    brezak struct dma_record {
 1.87      kent 	struct timeval tv;
 1.87      kent 	u_long gusaddr;
 1.97  christos 	void *bsdaddr;
 1.87      kent 	u_short count;
 1.87      kent 	u_char channel;
 1.87      kent 	u_char direction;
  1.1    brezak } dmarecords[NDMARECS];
  1.1    brezak
  1.1    brezak int dmarecord_index = 0;
  1.1    brezak #endif
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * local routines
  1.1    brezak  */
  1.1    brezak
 1.87      kent int	gusopen(void *, int);
 1.87      kent void	gusclose(void *);
 1.87      kent void	gusmax_close(void *);
 1.87      kent int	gusintr(void *);
 1.97  christos int	gus_set_in_gain(void *, u_int, u_char);
 1.97  christos int	gus_get_in_gain(void *);
 1.97  christos int	gus_set_out_gain(void *, u_int, u_char);
 1.97  christos int	gus_get_out_gain(void *);
 1.87      kent int	gus_set_params(void *, int, int, audio_params_t *,
 1.87      kent 	    audio_params_t *, stream_filter_list_t *, stream_filter_list_t *);
 1.87      kent int	gusmax_set_params(void *, int, int, audio_params_t *,
 1.87      kent 	    audio_params_t *, stream_filter_list_t *, stream_filter_list_t *);
 1.87      kent int	gus_round_blocksize(void *, int, int, const audio_params_t *);
 1.87      kent int	gus_commit_settings(void *);
 1.87      kent int	gus_dma_output(void *, void *, int, void (*)(void *), void *);
 1.87      kent int	gus_dma_input(void *, void *, int, void (*)(void *), void *);
 1.87      kent int	gus_halt_out_dma(void *);
 1.87      kent int	gus_halt_in_dma(void *);
 1.87      kent int	gus_speaker_ctl(void *, int);
 1.87      kent int	gusmaxopen(void *, int);
 1.87      kent int	gusmax_round_blocksize(void *, int, int, const audio_params_t *);
 1.87      kent int	gusmax_commit_settings(void *);
 1.87      kent int	gusmax_dma_output(void *, void *, int, void (*)(void *), void *);
 1.87      kent int	gusmax_dma_input(void *, void *, int, void (*)(void *), void *);
 1.87      kent int	gusmax_halt_out_dma(void *);
 1.87      kent int	gusmax_halt_in_dma(void *);
 1.87      kent int	gusmax_speaker_ctl(void *, int);
 1.87      kent int	gus_getdev(void *, struct audio_device *);
 1.87      kent
 1.87      kent STATIC void	gus_deinterleave(struct gus_softc *, void *, int);
 1.87      kent
 1.87      kent STATIC int	gus_mic_ctl(void *, int);
 1.87      kent STATIC int	gus_linein_ctl(void *, int);
 1.87      kent STATIC int	gus_test_iobase(bus_space_tag_t, int);
 1.87      kent STATIC void	guspoke(bus_space_tag_t, bus_space_handle_t, long, u_char);
 1.97  christos STATIC void	gusdmaout(struct gus_softc *, int, u_long, void *, int);
 1.87      kent STATIC int	gus_init_cs4231(struct gus_softc *);
 1.87      kent STATIC void	gus_init_ics2101(struct gus_softc *);
 1.87      kent
 1.87      kent STATIC void	gus_set_chan_addrs(struct gus_softc *);
 1.87      kent STATIC void	gusreset(struct gus_softc *, int);
 1.87      kent STATIC void	gus_set_voices(struct gus_softc *, int);
 1.87      kent STATIC void	gus_set_volume(struct gus_softc *, int, int);
 1.87      kent STATIC void	gus_set_samprate(struct gus_softc *, int, int);
 1.87      kent STATIC void	gus_set_recrate(struct gus_softc *, u_long);
 1.87      kent STATIC void	gus_start_voice(struct gus_softc *, int, int);
 1.87      kent STATIC void	gus_stop_voice(struct gus_softc *, int, int);
 1.87      kent STATIC void	gus_set_endaddr(struct gus_softc *, int, u_long);
 1.15       jtk #ifdef GUSPLAYDEBUG
 1.87      kent STATIC void	gus_set_curaddr(struct gus_softc *, int, u_long);
 1.87      kent STATIC u_long	gus_get_curaddr(struct gus_softc *, int);
 1.14  christos #endif
 1.87      kent STATIC int	gus_dmaout_intr(struct gus_softc *);
 1.87      kent STATIC void	gus_dmaout_dointr(struct gus_softc *);
 1.87      kent STATIC void	gus_dmaout_timeout(void *);
 1.87      kent STATIC int	gus_dmain_intr(struct gus_softc *);
 1.87      kent STATIC int	gus_voice_intr(struct gus_softc *);
 1.87      kent STATIC void	gus_start_playing(struct gus_softc *, int);
 1.87      kent STATIC int	gus_continue_playing(struct gus_softc *, int);
 1.87      kent STATIC u_char guspeek(bus_space_tag_t, bus_space_handle_t, u_long);
 1.87      kent STATIC u_long convert_to_16bit(u_long);
 1.87      kent STATIC int	gus_mixer_set_port(void *, mixer_ctrl_t *);
 1.87      kent STATIC int	gus_mixer_get_port(void *, mixer_ctrl_t *);
 1.87      kent STATIC int	gusmax_mixer_set_port(void *, mixer_ctrl_t *);
 1.87      kent STATIC int	gusmax_mixer_get_port(void *, mixer_ctrl_t *);
 1.87      kent STATIC int	gus_mixer_query_devinfo(void *, mixer_devinfo_t *);
 1.87      kent STATIC int	gusmax_mixer_query_devinfo(void *, mixer_devinfo_t *);
 1.87      kent STATIC int	gus_query_encoding(void *, struct audio_encoding *);
 1.87      kent STATIC int	gus_get_props(void *);
 1.87      kent STATIC int	gusmax_get_props(void *);
 1.87      kent
 1.87      kent STATIC void	gusics_master_mute(struct ics2101_softc *, int);
 1.87      kent STATIC void	gusics_dac_mute(struct ics2101_softc *, int);
 1.87      kent STATIC void	gusics_mic_mute(struct ics2101_softc *, int);
 1.87      kent STATIC void	gusics_linein_mute(struct ics2101_softc *, int);
 1.87      kent STATIC void	gusics_cd_mute(struct ics2101_softc *, int);
  1.1    brezak
 1.87      kent void	stereo_dmaintr(void *);
 1.14  christos
  1.1    brezak /*
  1.1    brezak  * ISA bus driver routines
  1.1    brezak  */
  1.1    brezak
 1.87      kent int	gusprobe(struct device *, struct cfdata *, void *);
 1.87      kent void	gusattach(struct device *, struct device *, void *);
  1.7   mycroft
 1.76   thorpej CFATTACH_DECL(gus, sizeof(struct gus_softc),
 1.77   thorpej     gusprobe, gusattach, NULL, NULL);
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * A mapping from IRQ/DRQ values to the values used in the GUS's internal
  1.1    brezak  * registers.  A zero means that the referenced IRQ/DRQ is invalid
  1.1    brezak  */
  1.1    brezak
 1.70  jdolecek static const int gus_irq_map[] = {
 1.84  drochner 	-1, -1, 1, 3, -1, 2, -1, 4,
 1.84  drochner 	-1, 1, -1, 5, 6, -1, -1, 7
  1.3   mycroft };
 1.70  jdolecek static const int gus_drq_map[] = {
 1.84  drochner 	-1, 1, -1, 2, -1, 3, 4, 5
  1.3   mycroft };
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * A list of valid base addresses for the GUS
  1.1    brezak  */
  1.1    brezak
 1.70  jdolecek static const int gus_base_addrs[] = {
  1.3   mycroft 	0x210, 0x220, 0x230, 0x240, 0x250, 0x260
  1.3   mycroft };
 1.70  jdolecek static const int gus_addrs = sizeof(gus_base_addrs) / sizeof(gus_base_addrs[0]);
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Maximum frequency values of the GUS based on the number of currently active
  1.1    brezak  * voices.  Since the GUS samples a voice every 1.6 us, the maximum frequency
  1.1    brezak  * is dependent on the number of active voices.  Yes, it is pretty weird.
  1.1    brezak  */
  1.1    brezak
 1.70  jdolecek static const int gus_max_frequency[] = {
  1.1    brezak 		44100,		/* 14 voices */
  1.1    brezak 		41160,		/* 15 voices */
  1.1    brezak 		38587,		/* 16 voices */
  1.1    brezak 		36317,		/* 17 voices */
  1.1    brezak 		34300,		/* 18 voices */
  1.1    brezak 		32494,		/* 19 voices */
  1.1    brezak 		30870,		/* 20 voices */
  1.1    brezak 		29400,		/* 21 voices */
  1.1    brezak 		28063,		/* 22 voices */
  1.1    brezak 		26843,		/* 23 voices */
  1.1    brezak 		25725,		/* 24 voices */
  1.1    brezak 		24696,		/* 25 voices */
  1.1    brezak 		23746,		/* 26 voices */
  1.1    brezak 		22866,		/* 27 voices */
  1.1    brezak 		22050,		/* 28 voices */
  1.1    brezak 		21289,		/* 29 voices */
  1.1    brezak 		20580,		/* 30 voices */
  1.1    brezak 		19916,		/* 31 voices */
  1.1    brezak 		19293		/* 32 voices */
  1.1    brezak };
  1.1    brezak /*
  1.1    brezak  * A mapping of linear volume levels to the logarithmic volume values used
  1.1    brezak  * by the GF1 chip on the GUS.  From GUS SDK vol1.c.
  1.1    brezak  */
  1.1    brezak
 1.70  jdolecek static const unsigned short gus_log_volumes[512] = {
  1.1    brezak  0x0000,
  1.1    brezak  0x0700, 0x07ff, 0x0880, 0x08ff, 0x0940, 0x0980, 0x09c0, 0x09ff, 0x0a20,
  1.1    brezak  0x0a40, 0x0a60, 0x0a80, 0x0aa0, 0x0ac0, 0x0ae0, 0x0aff, 0x0b10, 0x0b20,
  1.1    brezak  0x0b30, 0x0b40, 0x0b50, 0x0b60, 0x0b70, 0x0b80, 0x0b90, 0x0ba0, 0x0bb0,
  1.1    brezak  0x0bc0, 0x0bd0, 0x0be0, 0x0bf0, 0x0bff, 0x0c08, 0x0c10, 0x0c18, 0x0c20,
  1.1    brezak  0x0c28, 0x0c30, 0x0c38, 0x0c40, 0x0c48, 0x0c50, 0x0c58, 0x0c60, 0x0c68,
  1.1    brezak  0x0c70, 0x0c78, 0x0c80, 0x0c88, 0x0c90, 0x0c98, 0x0ca0, 0x0ca8, 0x0cb0,
  1.1    brezak  0x0cb8, 0x0cc0, 0x0cc8, 0x0cd0, 0x0cd8, 0x0ce0, 0x0ce8, 0x0cf0, 0x0cf8,
  1.1    brezak  0x0cff, 0x0d04, 0x0d08, 0x0d0c, 0x0d10, 0x0d14, 0x0d18, 0x0d1c, 0x0d20,
  1.1    brezak  0x0d24, 0x0d28, 0x0d2c, 0x0d30, 0x0d34, 0x0d38, 0x0d3c, 0x0d40, 0x0d44,
  1.1    brezak  0x0d48, 0x0d4c, 0x0d50, 0x0d54, 0x0d58, 0x0d5c, 0x0d60, 0x0d64, 0x0d68,
  1.1    brezak  0x0d6c, 0x0d70, 0x0d74, 0x0d78, 0x0d7c, 0x0d80, 0x0d84, 0x0d88, 0x0d8c,
  1.1    brezak  0x0d90, 0x0d94, 0x0d98, 0x0d9c, 0x0da0, 0x0da4, 0x0da8, 0x0dac, 0x0db0,
  1.1    brezak  0x0db4, 0x0db8, 0x0dbc, 0x0dc0, 0x0dc4, 0x0dc8, 0x0dcc, 0x0dd0, 0x0dd4,
  1.1    brezak  0x0dd8, 0x0ddc, 0x0de0, 0x0de4, 0x0de8, 0x0dec, 0x0df0, 0x0df4, 0x0df8,
  1.1    brezak  0x0dfc, 0x0dff, 0x0e02, 0x0e04, 0x0e06, 0x0e08, 0x0e0a, 0x0e0c, 0x0e0e,
  1.1    brezak  0x0e10, 0x0e12, 0x0e14, 0x0e16, 0x0e18, 0x0e1a, 0x0e1c, 0x0e1e, 0x0e20,
  1.1    brezak  0x0e22, 0x0e24, 0x0e26, 0x0e28, 0x0e2a, 0x0e2c, 0x0e2e, 0x0e30, 0x0e32,
  1.1    brezak  0x0e34, 0x0e36, 0x0e38, 0x0e3a, 0x0e3c, 0x0e3e, 0x0e40, 0x0e42, 0x0e44,
  1.1    brezak  0x0e46, 0x0e48, 0x0e4a, 0x0e4c, 0x0e4e, 0x0e50, 0x0e52, 0x0e54, 0x0e56,
  1.1    brezak  0x0e58, 0x0e5a, 0x0e5c, 0x0e5e, 0x0e60, 0x0e62, 0x0e64, 0x0e66, 0x0e68,
  1.1    brezak  0x0e6a, 0x0e6c, 0x0e6e, 0x0e70, 0x0e72, 0x0e74, 0x0e76, 0x0e78, 0x0e7a,
  1.1    brezak  0x0e7c, 0x0e7e, 0x0e80, 0x0e82, 0x0e84, 0x0e86, 0x0e88, 0x0e8a, 0x0e8c,
  1.1    brezak  0x0e8e, 0x0e90, 0x0e92, 0x0e94, 0x0e96, 0x0e98, 0x0e9a, 0x0e9c, 0x0e9e,
  1.1    brezak  0x0ea0, 0x0ea2, 0x0ea4, 0x0ea6, 0x0ea8, 0x0eaa, 0x0eac, 0x0eae, 0x0eb0,
  1.1    brezak  0x0eb2, 0x0eb4, 0x0eb6, 0x0eb8, 0x0eba, 0x0ebc, 0x0ebe, 0x0ec0, 0x0ec2,
  1.1    brezak  0x0ec4, 0x0ec6, 0x0ec8, 0x0eca, 0x0ecc, 0x0ece, 0x0ed0, 0x0ed2, 0x0ed4,
  1.1    brezak  0x0ed6, 0x0ed8, 0x0eda, 0x0edc, 0x0ede, 0x0ee0, 0x0ee2, 0x0ee4, 0x0ee6,
  1.1    brezak  0x0ee8, 0x0eea, 0x0eec, 0x0eee, 0x0ef0, 0x0ef2, 0x0ef4, 0x0ef6, 0x0ef8,
  1.1    brezak  0x0efa, 0x0efc, 0x0efe, 0x0eff, 0x0f01, 0x0f02, 0x0f03, 0x0f04, 0x0f05,
  1.1    brezak  0x0f06, 0x0f07, 0x0f08, 0x0f09, 0x0f0a, 0x0f0b, 0x0f0c, 0x0f0d, 0x0f0e,
  1.1    brezak  0x0f0f, 0x0f10, 0x0f11, 0x0f12, 0x0f13, 0x0f14, 0x0f15, 0x0f16, 0x0f17,
  1.1    brezak  0x0f18, 0x0f19, 0x0f1a, 0x0f1b, 0x0f1c, 0x0f1d, 0x0f1e, 0x0f1f, 0x0f20,
  1.1    brezak  0x0f21, 0x0f22, 0x0f23, 0x0f24, 0x0f25, 0x0f26, 0x0f27, 0x0f28, 0x0f29,
  1.1    brezak  0x0f2a, 0x0f2b, 0x0f2c, 0x0f2d, 0x0f2e, 0x0f2f, 0x0f30, 0x0f31, 0x0f32,
  1.1    brezak  0x0f33, 0x0f34, 0x0f35, 0x0f36, 0x0f37, 0x0f38, 0x0f39, 0x0f3a, 0x0f3b,
  1.1    brezak  0x0f3c, 0x0f3d, 0x0f3e, 0x0f3f, 0x0f40, 0x0f41, 0x0f42, 0x0f43, 0x0f44,
  1.1    brezak  0x0f45, 0x0f46, 0x0f47, 0x0f48, 0x0f49, 0x0f4a, 0x0f4b, 0x0f4c, 0x0f4d,
  1.1    brezak  0x0f4e, 0x0f4f, 0x0f50, 0x0f51, 0x0f52, 0x0f53, 0x0f54, 0x0f55, 0x0f56,
  1.1    brezak  0x0f57, 0x0f58, 0x0f59, 0x0f5a, 0x0f5b, 0x0f5c, 0x0f5d, 0x0f5e, 0x0f5f,
  1.1    brezak  0x0f60, 0x0f61, 0x0f62, 0x0f63, 0x0f64, 0x0f65, 0x0f66, 0x0f67, 0x0f68,
  1.1    brezak  0x0f69, 0x0f6a, 0x0f6b, 0x0f6c, 0x0f6d, 0x0f6e, 0x0f6f, 0x0f70, 0x0f71,
  1.1    brezak  0x0f72, 0x0f73, 0x0f74, 0x0f75, 0x0f76, 0x0f77, 0x0f78, 0x0f79, 0x0f7a,
  1.1    brezak  0x0f7b, 0x0f7c, 0x0f7d, 0x0f7e, 0x0f7f, 0x0f80, 0x0f81, 0x0f82, 0x0f83,
  1.1    brezak  0x0f84, 0x0f85, 0x0f86, 0x0f87, 0x0f88, 0x0f89, 0x0f8a, 0x0f8b, 0x0f8c,
  1.1    brezak  0x0f8d, 0x0f8e, 0x0f8f, 0x0f90, 0x0f91, 0x0f92, 0x0f93, 0x0f94, 0x0f95,
  1.1    brezak  0x0f96, 0x0f97, 0x0f98, 0x0f99, 0x0f9a, 0x0f9b, 0x0f9c, 0x0f9d, 0x0f9e,
  1.1    brezak  0x0f9f, 0x0fa0, 0x0fa1, 0x0fa2, 0x0fa3, 0x0fa4, 0x0fa5, 0x0fa6, 0x0fa7,
  1.1    brezak  0x0fa8, 0x0fa9, 0x0faa, 0x0fab, 0x0fac, 0x0fad, 0x0fae, 0x0faf, 0x0fb0,
  1.1    brezak  0x0fb1, 0x0fb2, 0x0fb3, 0x0fb4, 0x0fb5, 0x0fb6, 0x0fb7, 0x0fb8, 0x0fb9,
  1.1    brezak  0x0fba, 0x0fbb, 0x0fbc, 0x0fbd, 0x0fbe, 0x0fbf, 0x0fc0, 0x0fc1, 0x0fc2,
  1.1    brezak  0x0fc3, 0x0fc4, 0x0fc5, 0x0fc6, 0x0fc7, 0x0fc8, 0x0fc9, 0x0fca, 0x0fcb,
  1.1    brezak  0x0fcc, 0x0fcd, 0x0fce, 0x0fcf, 0x0fd0, 0x0fd1, 0x0fd2, 0x0fd3, 0x0fd4,
  1.1    brezak  0x0fd5, 0x0fd6, 0x0fd7, 0x0fd8, 0x0fd9, 0x0fda, 0x0fdb, 0x0fdc, 0x0fdd,
  1.1    brezak  0x0fde, 0x0fdf, 0x0fe0, 0x0fe1, 0x0fe2, 0x0fe3, 0x0fe4, 0x0fe5, 0x0fe6,
  1.1    brezak  0x0fe7, 0x0fe8, 0x0fe9, 0x0fea, 0x0feb, 0x0fec, 0x0fed, 0x0fee, 0x0fef,
  1.1    brezak  0x0ff0, 0x0ff1, 0x0ff2, 0x0ff3, 0x0ff4, 0x0ff5, 0x0ff6, 0x0ff7, 0x0ff8,
  1.1    brezak  0x0ff9, 0x0ffa, 0x0ffb, 0x0ffc, 0x0ffd, 0x0ffe, 0x0fff};
  1.1    brezak
 1.43  augustss #define SELECT_GUS_REG(iot,ioh1,x) bus_space_write_1(iot,ioh1,GUS_REG_SELECT,x)
  1.1    brezak #define ADDR_HIGH(x) (unsigned int) ((x >> 7L) & 0x1fffL)
  1.1    brezak #define ADDR_LOW(x) (unsigned int) ((x & 0x7fL) << 9L)
  1.1    brezak
  1.1    brezak #define GUS_MIN_VOICES 14	/* Minimum possible number of voices */
  1.1    brezak #define GUS_MAX_VOICES 32	/* Maximum possible number of voices */
  1.1    brezak #define GUS_VOICE_LEFT 0	/* Voice used for left (and mono) playback */
  1.1    brezak #define GUS_VOICE_RIGHT 1	/* Voice used for right playback */
  1.1    brezak #define GUS_MEM_OFFSET 32	/* Offset into GUS memory to begin of buffer */
  1.1    brezak #define GUS_BUFFER_MULTIPLE 1024	/* Audio buffers are multiples of this */
  1.1    brezak #define	GUS_MEM_FOR_BUFFERS	131072	/* use this many bytes on-GUS */
  1.1    brezak #define	GUS_LEFT_RIGHT_OFFSET	(sc->sc_nbufs * sc->sc_chanblocksize + GUS_MEM_OFFSET)
  1.1    brezak
  1.1    brezak #define GUS_PREC_BYTES (sc->sc_precision >> 3) /* precision to bytes */
  1.1    brezak
  1.1    brezak /* splgus() must be splaudio() */
  1.1    brezak
  1.1    brezak #define splgus splaudio
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Interface to higher level audio driver
  1.1    brezak  */
  1.1    brezak
 1.85      yamt const struct audio_hw_if gus_hw_if = {
  1.1    brezak 	gusopen,
  1.1    brezak 	gusclose,
  1.1    brezak 	NULL,				/* drain */
  1.1    brezak 	gus_query_encoding,
 1.25  augustss 	gus_set_params,
  1.1    brezak 	gus_round_blocksize,
  1.1    brezak 	gus_commit_settings,
 1.33  augustss 	NULL,
 1.33  augustss 	NULL,
  1.1    brezak 	gus_dma_output,
  1.1    brezak 	gus_dma_input,
  1.1    brezak 	gus_halt_out_dma,
  1.1    brezak 	gus_halt_in_dma,
  1.1    brezak 	gus_speaker_ctl,
  1.1    brezak 	gus_getdev,
 1.34  augustss 	NULL,
  1.1    brezak 	gus_mixer_set_port,
  1.1    brezak 	gus_mixer_get_port,
  1.1    brezak 	gus_mixer_query_devinfo,
 1.63   thorpej 	ad1848_isa_malloc,
 1.63   thorpej 	ad1848_isa_free,
 1.87      kent 	ad1848_isa_round_buffersize,
 1.87      kent 	ad1848_isa_mappage,
 1.36  augustss 	gus_get_props,
 1.72  augustss 	NULL,
 1.72  augustss 	NULL,
 1.72  augustss 	NULL,
 1.94  christos 	NULL,
  1.1    brezak };
  1.1    brezak
 1.85      yamt static const struct audio_hw_if gusmax_hw_if = {
 1.43  augustss 	gusmaxopen,
 1.43  augustss 	gusmax_close,
 1.87      kent 	NULL,			/* drain */
 1.87      kent 	gus_query_encoding,	/* query encoding */
 1.43  augustss 	gusmax_set_params,
 1.43  augustss 	gusmax_round_blocksize,
 1.43  augustss 	gusmax_commit_settings,
 1.43  augustss 	NULL,
 1.43  augustss 	NULL,
 1.43  augustss 	gusmax_dma_output,
 1.43  augustss 	gusmax_dma_input,
 1.43  augustss 	gusmax_halt_out_dma,
 1.43  augustss 	gusmax_halt_in_dma,
 1.43  augustss 	gusmax_speaker_ctl,
 1.43  augustss 	gus_getdev,
 1.43  augustss 	NULL,
 1.43  augustss 	gusmax_mixer_set_port,
 1.43  augustss 	gusmax_mixer_get_port,
 1.43  augustss 	gusmax_mixer_query_devinfo,
 1.63   thorpej 	ad1848_isa_malloc,
 1.63   thorpej 	ad1848_isa_free,
 1.87      kent 	ad1848_isa_round_buffersize,
 1.87      kent 	ad1848_isa_mappage,
 1.43  augustss 	gusmax_get_props,
 1.72  augustss 	NULL,
 1.72  augustss 	NULL,
 1.72  augustss 	NULL,
 1.94  christos 	NULL,
 1.43  augustss };
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Some info about the current audio device
  1.1    brezak  */
  1.1    brezak
  1.1    brezak struct audio_device gus_device = {
  1.1    brezak 	"UltraSound",
  1.1    brezak 	"",
  1.1    brezak 	"gus",
  1.1    brezak };
  1.1    brezak
  1.1    brezak #define FLIP_REV	5		/* This rev has flipped mixer chans */
  1.1    brezak
  1.1    brezak
  1.1    brezak int
 1.96  christos gusprobe(struct device *parent, struct cfdata *match,
 1.95  christos     void *aux)
  1.1    brezak {
 1.87      kent 	struct isa_attach_args *ia;
 1.74   thorpej 	int iobase, recdrq;
 1.74   thorpej
 1.87      kent 	ia = aux;
 1.74   thorpej 	if (ia->ia_nio < 1)
 1.87      kent 		return 0;
 1.74   thorpej 	if (ia->ia_nirq < 1)
 1.87      kent 		return 0;
 1.74   thorpej 	if (ia->ia_ndrq < 1)
 1.87      kent 		return 0;
 1.74   thorpej
 1.74   thorpej 	if (ISA_DIRECT_CONFIG(ia))
 1.87      kent 		return 0;
 1.74   thorpej
 1.74   thorpej 	iobase = ia->ia_io[0].ir_addr;
 1.74   thorpej 	if (ia->ia_ndrq > 1)
 1.74   thorpej 		recdrq = ia->ia_drq[1].ir_drq;
 1.74   thorpej 	else
 1.84  drochner 		recdrq = ISA_UNKNOWN_DRQ;
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Before we do anything else, make sure requested IRQ and DRQ are
  1.1    brezak 	 * valid for this card.
  1.1    brezak 	 */
  1.1    brezak
 1.43  augustss 	/* XXX range check before indexing!! */
 1.84  drochner 	if (ia->ia_irq[0].ir_irq == ISA_UNKNOWN_IRQ ||
 1.84  drochner 	    gus_irq_map[ia->ia_irq[0].ir_irq] == -1) {
 1.74   thorpej 		printf("gus: invalid irq %d, card not probed\n",
 1.74   thorpej 		    ia->ia_irq[0].ir_irq);
 1.43  augustss 		return 0;
  1.1    brezak 	}
  1.1    brezak
 1.84  drochner 	if (ia->ia_drq[0].ir_drq == ISA_UNKNOWN_DRQ ||
 1.84  drochner 	    gus_drq_map[ia->ia_drq[0].ir_drq] == -1) {
 1.74   thorpej 		printf("gus: invalid drq %d, card not probed\n",
 1.74   thorpej 		    ia->ia_drq[0].ir_drq);
 1.43  augustss 		return 0;
  1.1    brezak 	}
  1.1    brezak
 1.84  drochner 	if (recdrq != ISA_UNKNOWN_DRQ) {
 1.84  drochner 		if (recdrq > 7 || gus_drq_map[recdrq] == -1) {
 1.87      kent 			printf("gus: invalid second DMA channel (%d), card not "
 1.87      kent 			    "probed\n", recdrq);
 1.87      kent 			return 0;
 1.87      kent 		}
  1.1    brezak 	} else
 1.74   thorpej 		recdrq = ia->ia_drq[0].ir_drq;
  1.1    brezak
 1.84  drochner 	if (iobase == ISA_UNKNOWN_PORT) {
  1.1    brezak 		int i;
 1.87      kent 		for (i = 0; i < gus_addrs; i++)
 1.50  drochner 			if (gus_test_iobase(ia->ia_iot, gus_base_addrs[i])) {
  1.1    brezak 				iobase = gus_base_addrs[i];
  1.1    brezak 				goto done;
  1.1    brezak 			}
  1.1    brezak 		return 0;
 1.50  drochner 	} else if (!gus_test_iobase(ia->ia_iot, iobase))
  1.1    brezak 			return 0;
  1.1    brezak
  1.1    brezak done:
 1.74   thorpej 	if (!isa_drq_isfree(ia->ia_ic, ia->ia_drq[0].ir_drq) ||
 1.74   thorpej 	    (recdrq != ia->ia_drq[0].ir_drq &&
 1.74   thorpej 	     !isa_drq_isfree(ia->ia_ic, recdrq)))
 1.44  augustss 		return 0;
 1.44  augustss
 1.74   thorpej 	ia->ia_nio = 1;
 1.74   thorpej 	ia->ia_io[0].ir_addr = iobase;
 1.74   thorpej 	ia->ia_io[0].ir_size = GUS_NPORT1;
 1.74   thorpej
 1.74   thorpej 	ia->ia_nirq = 1;
 1.74   thorpej 	ia->ia_ndrq = (recdrq != ia->ia_drq[0].ir_drq) ? 2 : 1;
 1.74   thorpej
 1.74   thorpej 	ia->ia_niomem = 0;
 1.74   thorpej
 1.43  augustss 	return 1;
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Test to see if a particular I/O base is valid for the GUS.  Return true
  1.1    brezak  * if it is.
  1.1    brezak  */
  1.1    brezak
  1.8       jtk STATIC int
 1.87      kent gus_test_iobase (bus_space_tag_t iot, int iobase)
  1.1    brezak {
 1.43  augustss 	bus_space_handle_t ioh1, ioh2, ioh3, ioh4;
  1.1    brezak 	u_char s1, s2;
 1.87      kent 	int s, rv;
 1.43  augustss
 1.87      kent 	rv = 0;
 1.43  augustss 	/* Map i/o space */
 1.43  augustss 	if (bus_space_map(iot, iobase, GUS_NPORT1, 0, &ioh1))
 1.43  augustss 		return 0;
 1.43  augustss 	if (bus_space_map(iot, iobase+GUS_IOH2_OFFSET, GUS_NPORT2, 0, &ioh2))
 1.43  augustss 		goto bad1;
 1.43  augustss
 1.43  augustss 	/* XXX Maybe we shouldn't fail on mapping this, but just assume
 1.43  augustss 	 * the card is of revision 0? */
 1.43  augustss 	if (bus_space_map(iot, iobase+GUS_IOH3_OFFSET, GUS_NPORT3, 0, &ioh3))
 1.43  augustss 		goto bad2;
 1.43  augustss
 1.43  augustss 	if (bus_space_map(iot, iobase+GUS_IOH4_OFFSET, GUS_NPORT4, 0, &ioh4))
 1.43  augustss 		goto bad3;
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Reset GUS to an initial state before we do anything.
  1.1    brezak 	 */
  1.1    brezak
 1.43  augustss 	s = splgus();
  1.1    brezak 	delay(500);
  1.1    brezak
 1.87      kent 	SELECT_GUS_REG(iot, ioh2, GUSREG_RESET);
 1.87      kent 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 0x00);
  1.1    brezak
 1.87      kent 	delay(500);
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_RESET);
 1.87      kent 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, GUSMASK_MASTER_RESET);
  1.1    brezak
 1.87      kent 	delay(500);
  1.1    brezak
 1.43  augustss 	splx(s);
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * See if we can write to the board's memory
  1.1    brezak 	 */
  1.1    brezak
 1.87      kent 	s1 = guspeek(iot, ioh2, 0L);
 1.87      kent 	s2 = guspeek(iot, ioh2, 1L);
  1.1    brezak
 1.87      kent 	guspoke(iot, ioh2, 0L, 0xaa);
 1.87      kent 	guspoke(iot, ioh2, 1L, 0x55);
  1.1    brezak
 1.87      kent 	if (guspeek(iot, ioh2, 0L) != 0xaa)
 1.43  augustss 		goto bad;
  1.1    brezak
 1.43  augustss 	guspoke(iot, ioh2, 0L, s1);
 1.43  augustss 	guspoke(iot, ioh2, 1L, s2);
  1.1    brezak
 1.50  drochner 	rv = 1;
 1.43  augustss
 1.43  augustss bad:
 1.50  drochner 	bus_space_unmap(iot, ioh4, GUS_NPORT4);
 1.43  augustss bad3:
 1.50  drochner 	bus_space_unmap(iot, ioh3, GUS_NPORT3);
 1.43  augustss bad2:
 1.50  drochner 	bus_space_unmap(iot, ioh2, GUS_NPORT2);
 1.43  augustss bad1:
 1.50  drochner 	bus_space_unmap(iot, ioh1, GUS_NPORT1);
 1.50  drochner 	return rv;
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Setup the GUS for use; called shortly after probe
  1.1    brezak  */
  1.1    brezak
  1.1    brezak void
 1.96  christos gusattach(struct device *parent, struct device *self, void *aux)
  1.1    brezak {
 1.87      kent 	struct gus_softc *sc;
 1.87      kent 	struct isa_attach_args *ia;
 1.50  drochner 	bus_space_tag_t iot;
 1.50  drochner 	bus_space_handle_t ioh1, ioh2, ioh3, ioh4;
 1.87      kent 	int		iobase, i;
 1.93  christos 	unsigned char	c, m;
 1.99        ad 	int d = -1, s;
 1.85      yamt 	const struct audio_hw_if *hwif;
 1.50  drochner
 1.87      kent 	sc = (void *) self;
 1.87      kent 	ia = aux;
 1.98        ad 	callout_init(&sc->sc_dmaout_ch, 0);
 1.69   thorpej
 1.50  drochner 	sc->sc_iot = iot = ia->ia_iot;
 1.55   thorpej 	sc->sc_ic = ia->ia_ic;
 1.74   thorpej 	iobase = ia->ia_io[0].ir_addr;
 1.50  drochner
 1.50  drochner 	/* Map i/o space */
 1.50  drochner 	if (bus_space_map(iot, iobase, GUS_NPORT1, 0, &ioh1))
1.101    cegger 		panic("%s: can't map io port range 1", device_xname(self));
 1.50  drochner 	sc->sc_ioh1 = ioh1;
 1.50  drochner 	if (bus_space_map(iot, iobase+GUS_IOH2_OFFSET, GUS_NPORT2, 0, &ioh2))
1.101    cegger 		panic("%s: can't map io port range 2", device_xname(self));
 1.50  drochner 	sc->sc_ioh2 = ioh2;
 1.50  drochner
 1.50  drochner 	/* XXX Maybe we shouldn't fail on mapping this, but just assume
 1.50  drochner 	 * the card is of revision 0? */
 1.50  drochner 	if (bus_space_map(iot, iobase+GUS_IOH3_OFFSET, GUS_NPORT3, 0, &ioh3))
1.101    cegger 		panic("%s: can't map io port range 3", device_xname(self));
 1.50  drochner 	sc->sc_ioh3 = ioh3;
 1.50  drochner
 1.50  drochner 	if (bus_space_map(iot, iobase+GUS_IOH4_OFFSET, GUS_NPORT4, 0, &ioh4))
1.101    cegger 		panic("%s: can't map io port range 4", device_xname(self));
 1.50  drochner 	sc->sc_ioh4 = ioh4;
 1.50  drochner
 1.50  drochner 	sc->sc_iobase = iobase;
 1.74   thorpej 	sc->sc_irq = ia->ia_irq[0].ir_irq;
 1.74   thorpej 	sc->sc_playdrq = ia->ia_drq[0].ir_drq;
 1.74   thorpej 	sc->sc_recdrq = (ia->ia_ndrq == 2) ?
 1.74   thorpej 	    ia->ia_drq[1].ir_drq : ia->ia_drq[0].ir_drq;
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Figure out our board rev, and see if we need to initialize the
  1.1    brezak 	 * mixer
  1.1    brezak 	 */
  1.1    brezak
 1.55   thorpej 	sc->sc_ic = ia->ia_ic;
 1.44  augustss
 1.87      kent 	delay(500);
  1.1    brezak
 1.87      kent 	c = bus_space_read_1(iot, ioh3, GUS_BOARD_REV);
  1.1    brezak 	if (c != 0xff)
  1.1    brezak 		sc->sc_revision = c;
  1.1    brezak 	else
  1.1    brezak 		sc->sc_revision = 0;
  1.1    brezak
  1.1    brezak
 1.87      kent 	SELECT_GUS_REG(iot, ioh2, GUSREG_RESET);
 1.87      kent 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 0x00);
  1.1    brezak
  1.1    brezak 	gusreset(sc, GUS_MAX_VOICES); /* initialize all voices */
  1.1    brezak 	gusreset(sc, GUS_MIN_VOICES); /* then set to just the ones we use */
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Setup the IRQ and DRQ lines in software, using values from
  1.1    brezak 	 * config file
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	m = GUSMASK_LINE_IN|GUSMASK_LINE_OUT;		/* disable all */
  1.1    brezak
 1.74   thorpej 	c = ((unsigned char) gus_irq_map[ia->ia_irq[0].ir_irq]) |
 1.74   thorpej 	    GUSMASK_BOTH_RQ;
  1.1    brezak
 1.93  christos 	if (sc->sc_playdrq != -1) {
 1.93  christos 		if (sc->sc_recdrq == sc->sc_playdrq)
 1.93  christos 			d = (unsigned char) (gus_drq_map[sc->sc_playdrq] |
 1.93  christos 			    GUSMASK_BOTH_RQ);
 1.93  christos 		else if (sc->sc_recdrq != -1)
 1.93  christos 			d = (unsigned char) (gus_drq_map[sc->sc_playdrq] |
 1.93  christos 			    gus_drq_map[sc->sc_recdrq] << 3);
 1.93  christos 	}
 1.93  christos 	if (d == -1)
 1.93  christos 		printf("%s: WARNING: Cannot initialize drq\n",
1.101    cegger 		    device_xname(&sc->sc_dev));
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Program the IRQ and DMA channels on the GUS.  Note that we hardwire
  1.1    brezak 	 * the GUS to only use one IRQ channel, but we give the user the
 1.53  augustss 	 * option of using two DMA channels (the other one given by the drq2
  1.1    brezak 	 * option in the config file).  Two DMA channels are needed for full-
  1.1    brezak 	 * duplex operation.
  1.1    brezak 	 *
  1.1    brezak 	 * The order of these operations is very magical.
  1.1    brezak 	 */
  1.1    brezak
 1.99        ad 	s = splhigh();		/* XXX needed? */
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh1, GUS_REG_CONTROL, GUS_REG_IRQCTL);
 1.43  augustss 	bus_space_write_1(iot, ioh1, GUS_MIX_CONTROL, m);
 1.43  augustss 	bus_space_write_1(iot, ioh1, GUS_IRQCTL_CONTROL, 0x00);
 1.43  augustss 	bus_space_write_1(iot, ioh1, 0x0f, 0x00);
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh1, GUS_MIX_CONTROL, m);
 1.43  augustss 	bus_space_write_1(iot, ioh1, GUS_DMA_CONTROL, d | 0x80); /* magic reset? */
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh1, GUS_MIX_CONTROL, m | GUSMASK_CONTROL_SEL);
 1.43  augustss 	bus_space_write_1(iot, ioh1, GUS_IRQ_CONTROL, c);
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh1, GUS_MIX_CONTROL, m);
 1.43  augustss 	bus_space_write_1(iot, ioh1, GUS_DMA_CONTROL, d);
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh1, GUS_MIX_CONTROL, m | GUSMASK_CONTROL_SEL);
 1.43  augustss 	bus_space_write_1(iot, ioh1, GUS_IRQ_CONTROL, c);
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_VOICE_SELECT, 0x00);
  1.1    brezak
  1.1    brezak 	/* enable line in, line out.  leave mic disabled. */
 1.43  augustss 	bus_space_write_1(iot, ioh1, GUS_MIX_CONTROL,
  1.1    brezak 	     (m | GUSMASK_LATCHES) & ~(GUSMASK_LINE_OUT|GUSMASK_LINE_IN));
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_VOICE_SELECT, 0x00);
  1.1    brezak
 1.99        ad 	splx(s);
  1.1    brezak
  1.1    brezak 	sc->sc_mixcontrol =
  1.1    brezak 		(m | GUSMASK_LATCHES) & ~(GUSMASK_LINE_OUT|GUSMASK_LINE_IN);
  1.1    brezak
 1.67   mycroft 	if (sc->sc_playdrq != -1) {
 1.68   thorpej 		sc->sc_play_maxsize = isa_dmamaxsize(sc->sc_ic,
 1.68   thorpej 		    sc->sc_playdrq);
 1.81      fvdl 		if (isa_drq_alloc(sc->sc_ic, sc->sc_playdrq) != 0) {
1.101    cegger 			aprint_error_dev(&sc->sc_dev, "can't reserve drq %d\n",
1.101    cegger 			    sc->sc_playdrq);
 1.81      fvdl 			return;
 1.81      fvdl 		}
 1.67   mycroft 		if (isa_dmamap_create(sc->sc_ic, sc->sc_playdrq,
 1.68   thorpej 		    sc->sc_play_maxsize, BUS_DMA_NOWAIT|BUS_DMA_ALLOCNOW)) {
1.101    cegger 			aprint_error_dev(&sc->sc_dev, "can't create map for drq %d\n",
1.101    cegger 			       sc->sc_playdrq);
 1.67   mycroft 			return;
 1.44  augustss 		}
 1.67   mycroft 	}
 1.67   mycroft 	if (sc->sc_recdrq != -1 && sc->sc_recdrq != sc->sc_playdrq) {
 1.68   thorpej 		sc->sc_req_maxsize = isa_dmamaxsize(sc->sc_ic,
 1.68   thorpej 		    sc->sc_recdrq);
 1.81      fvdl 		if (isa_drq_alloc(sc->sc_ic, sc->sc_recdrq) != 0) {
1.101    cegger 			aprint_error_dev(&sc->sc_dev, "can't reserve drq %d\n",
1.101    cegger 			    sc->sc_recdrq);
 1.81      fvdl 			return;
 1.81      fvdl 		}
 1.67   mycroft 		if (isa_dmamap_create(sc->sc_ic, sc->sc_recdrq,
 1.68   thorpej 		    sc->sc_req_maxsize, BUS_DMA_NOWAIT|BUS_DMA_ALLOCNOW)) {
1.101    cegger 			aprint_error_dev(&sc->sc_dev, "can't create map for drq %d\n",
1.101    cegger 			       sc->sc_recdrq);
 1.67   mycroft 			return;
 1.44  augustss 		}
  1.1    brezak 	}
  1.1    brezak
 1.68   thorpej 	/* XXX WILL THIS ALWAYS WORK THE WAY THEY'RE OVERLAYED?! */
 1.68   thorpej 	sc->sc_codec.sc_ic = sc->sc_ic;
 1.68   thorpej
 1.87      kent 	if (sc->sc_revision >= 5 && sc->sc_revision <= 9) {
 1.87      kent 		sc->sc_flags |= GUS_MIXER_INSTALLED;
 1.87      kent 		gus_init_ics2101(sc);
 1.68   thorpej 	}
 1.85      yamt 	hwif = &gus_hw_if;
 1.68   thorpej 	if (sc->sc_revision >= 10)
 1.85      yamt 		if (gus_init_cs4231(sc))
 1.85      yamt 			hwif = &gusmax_hw_if;
 1.68   thorpej
 1.87      kent 	SELECT_GUS_REG(iot, ioh2, GUSREG_RESET);
 1.87      kent 	/*
 1.87      kent 	 * Check to see how much memory we have on this card; see if any
 1.87      kent 	 * "mirroring" occurs.  We're assuming at least 256K already exists
 1.87      kent 	 * on the card; otherwise the initial probe would have failed
 1.87      kent 	 */
  1.1    brezak
 1.43  augustss 	guspoke(iot, ioh2, 0L, 0x00);
 1.87      kent 	for (i = 1; i < 1024; i++) {
 1.14  christos 		u_long loc;
  1.1    brezak
  1.1    brezak 		/*
  1.1    brezak 		 * See if we've run into mirroring yet
  1.1    brezak 		 */
  1.1    brezak
 1.43  augustss 		if (guspeek(iot, ioh2, 0L) != 0)
  1.1    brezak 			break;
  1.1    brezak
  1.1    brezak 		loc = i << 10;
  1.1    brezak
 1.43  augustss 		guspoke(iot, ioh2, loc, 0xaa);
 1.43  augustss 		if (guspeek(iot, ioh2, loc) != 0xaa)
  1.1    brezak 			break;
  1.1    brezak 	}
  1.1    brezak
  1.1    brezak 	sc->sc_dsize = i;
  1.1    brezak
 1.53  augustss 	/* The "official" (3.x) version number cannot easily be obtained.
 1.53  augustss 	 * The revision register does not correspond to the minor number
 1.53  augustss 	 * of the board version. Simply use the revision register as
 1.53  augustss 	 * identification.
 1.53  augustss 	 */
 1.83    itojun 	snprintf(gus_device.version, sizeof(gus_device.version), "%d",
 1.83    itojun 	    sc->sc_revision);
 1.53  augustss
1.101    cegger 	printf("\n%s: Gravis UltraSound", device_xname(&sc->sc_dev));
 1.53  augustss 	if (sc->sc_revision >= 10)
 1.53  augustss 		printf(" MAX");
 1.53  augustss 	else {
 1.53  augustss 		if (HAS_MIXER(sc))
 1.53  augustss 			printf(", mixer");
 1.53  augustss 		if (HAS_CODEC(sc))
 1.53  augustss 			printf(" with CODEC module");
 1.53  augustss 	}
 1.53  augustss 	printf(", %dKB memory\n", sc->sc_dsize);
 1.53  augustss
 1.53  augustss 	/* A GUS MAX should always have a CODEC installed */
 1.53  augustss 	if ((sc->sc_revision >= 10) & !(HAS_CODEC(sc)))
 1.87      kent 		printf("%s: WARNING: did not attach CODEC on MAX\n",
1.101    cegger 		    device_xname(&sc->sc_dev));
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Setup a default interrupt handler
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	/* XXX we shouldn't have to use splgus == splclock, nor should
  1.4   mycroft 	 * we use IPL_CLOCK.
  1.1    brezak 	 */
 1.74   thorpej 	sc->sc_ih = isa_intr_establish(ia->ia_ic, ia->ia_irq[0].ir_irq,
 1.74   thorpej 	    IST_EDGE, IPL_AUDIO, gusintr, sc /* sc->sc_gusdsp */);
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Set some default values
 1.79       wiz 	 * XXX others start with 8kHz mono mu-law
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	sc->sc_irate = sc->sc_orate = 44100;
 1.32  augustss 	sc->sc_encoding = AUDIO_ENCODING_SLINEAR_LE;
  1.1    brezak 	sc->sc_precision = 16;
  1.1    brezak 	sc->sc_voc[GUS_VOICE_LEFT].voccntl |= GUSMASK_DATA_SIZE16;
  1.1    brezak 	sc->sc_voc[GUS_VOICE_RIGHT].voccntl |= GUSMASK_DATA_SIZE16;
  1.1    brezak 	sc->sc_channels = 1;
  1.1    brezak 	sc->sc_ogain = 340;
  1.1    brezak 	gus_commit_settings(sc);
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * We always put the left channel full left & right channel
  1.1    brezak 	 * full right.
  1.1    brezak 	 * For mono playback, we set up both voices playing the same buffer.
  1.1    brezak 	 */
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_VOICE_SELECT, (unsigned char) GUS_VOICE_LEFT);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_PAN_POS);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, GUS_PAN_FULL_LEFT);
 1.43  augustss
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_VOICE_SELECT, (unsigned char) GUS_VOICE_RIGHT);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_PAN_POS);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, GUS_PAN_FULL_RIGHT);
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Attach to the generic audio layer
  1.1    brezak 	 */
  1.1    brezak
 1.85      yamt 	audio_attach_mi(hwif,
 1.85      yamt 	    HAS_CODEC(sc) ? (void *)&sc->sc_codec : (void *)sc, &sc->sc_dev);
  1.1    brezak }
  1.1    brezak
  1.1    brezak int
 1.87      kent gusopen(void *addr, int flags)
  1.1    brezak {
 1.87      kent 	struct gus_softc *sc;
  1.1    brezak
 1.87      kent 	sc = addr;
  1.1    brezak 	DPRINTF(("gusopen() called\n"));
  1.1    brezak
  1.1    brezak 	if (sc->sc_flags & GUS_OPEN)
  1.1    brezak 		return EBUSY;
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Some initialization
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	sc->sc_flags |= GUS_OPEN;
  1.1    brezak 	sc->sc_dmabuf = 0;
  1.1    brezak 	sc->sc_playbuf = -1;
  1.1    brezak 	sc->sc_bufcnt = 0;
  1.1    brezak 	sc->sc_voc[GUS_VOICE_LEFT].start_addr = GUS_MEM_OFFSET - 1;
  1.1    brezak 	sc->sc_voc[GUS_VOICE_LEFT].current_addr = GUS_MEM_OFFSET;
  1.1    brezak
  1.1    brezak 	if (HAS_CODEC(sc)) {
 1.62       jtk 		ad1848_open(&sc->sc_codec.sc_ad1848, flags);
 1.60        pk 		sc->sc_codec.sc_ad1848.mute[AD1848_AUX1_CHANNEL] = 0;
 1.60        pk
 1.60        pk 		/* turn on DAC output */
 1.60        pk 		ad1848_mute_channel(&sc->sc_codec.sc_ad1848,
 1.60        pk 				    AD1848_AUX1_CHANNEL, 0);
  1.1    brezak 		if (flags & FREAD) {
 1.60        pk 			sc->sc_codec.sc_ad1848.mute[AD1848_MONO_CHANNEL] = 0;
 1.60        pk 			ad1848_mute_channel(&sc->sc_codec.sc_ad1848,
 1.60        pk 					    AD1848_MONO_CHANNEL, 0);
  1.1    brezak 		}
  1.1    brezak 	} else if (flags & FREAD) {
  1.1    brezak 		/* enable/unmute the microphone */
  1.1    brezak 		if (HAS_MIXER(sc)) {
  1.1    brezak 			gusics_mic_mute(&sc->sc_mixer, 0);
  1.1    brezak 		} else
  1.1    brezak 			gus_mic_ctl(sc, SPKR_ON);
  1.1    brezak 	}
  1.1    brezak 	if (sc->sc_nbufs == 0)
 1.86      kent 	    gus_round_blocksize(sc, GUS_BUFFER_MULTIPLE, /* default blksiz */
 1.86      kent 				0, NULL); /* XXX */
  1.1    brezak 	return 0;
  1.1    brezak }
  1.1    brezak
 1.36  augustss int
 1.87      kent gusmaxopen(void *addr, int flags)
 1.36  augustss {
 1.87      kent 	struct ad1848_isa_softc *ac;
 1.87      kent
 1.87      kent 	ac = addr;
 1.62       jtk 	return gusopen(ac->sc_ad1848.parent, flags);
 1.36  augustss }
 1.36  augustss
  1.8       jtk STATIC void
 1.89  christos gus_deinterleave(struct gus_softc *sc, void *tbuf, int size)
  1.1    brezak {
  1.1    brezak 	/* deinterleave the stereo data.  We can use sc->sc_deintr_buf
  1.1    brezak 	   for scratch space. */
 1.38  augustss 	int i;
  1.1    brezak
 1.28  augustss 	if (size > sc->sc_blocksize) {
 1.28  augustss 		printf("gus: deinterleave %d > %d\n", size, sc->sc_blocksize);
 1.28  augustss 		return;
 1.28  augustss 	} else if (size < sc->sc_blocksize) {
 1.28  augustss 		DPRINTF(("gus: deinterleave %d < %d\n", size, sc->sc_blocksize));
 1.28  augustss 	}
 1.28  augustss
  1.1    brezak 	/*
  1.1    brezak 	 * size is in bytes.
  1.1    brezak 	 */
  1.1    brezak 	if (sc->sc_precision == 16) {
 1.38  augustss 		u_short *dei = sc->sc_deintr_buf;
 1.89  christos 		u_short *sbuf = tbuf;
  1.1    brezak 		size >>= 1;		/* bytecnt to shortcnt */
  1.1    brezak 		/* copy 2nd of each pair of samples to the staging area, while
  1.1    brezak 		   compacting the 1st of each pair into the original area. */
  1.1    brezak 		for (i = 0; i < size/2-1; i++)  {
  1.1    brezak 			dei[i] = sbuf[i*2+1];
  1.1    brezak 			sbuf[i+1] = sbuf[i*2+2];
  1.1    brezak 		}
  1.1    brezak 		/*
  1.1    brezak 		 * this has copied one less sample than half of the
  1.1    brezak 		 * buffer.  The first sample of the 1st stream was
  1.1    brezak 		 * already in place and didn't need copying.
  1.1    brezak 		 * Therefore, we've moved all of the 1st stream's
  1.1    brezak 		 * samples into place.  We have one sample from 2nd
  1.1    brezak 		 * stream in the last slot of original area, not
  1.1    brezak 		 * copied to the staging area (But we don't need to!).
  1.1    brezak 		 * Copy the remainder of the original stream into place.
  1.1    brezak 		 */
 1.71   thorpej 		memcpy(&sbuf[size/2], dei, i * sizeof(short));
  1.1    brezak 	} else {
 1.38  augustss 		u_char *dei = sc->sc_deintr_buf;
 1.89  christos 		u_char *sbuf = tbuf;
  1.1    brezak 		for (i = 0; i < size/2-1; i++)  {
  1.1    brezak 			dei[i] = sbuf[i*2+1];
  1.1    brezak 			sbuf[i+1] = sbuf[i*2+2];
  1.1    brezak 		}
 1.71   thorpej 		memcpy(&sbuf[size/2], dei, i);
  1.1    brezak 	}
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Actually output a buffer to the DSP chip
  1.1    brezak  */
  1.1    brezak
  1.1    brezak int
 1.89  christos gusmax_dma_output(void *addr, void *tbuf, int size,
 1.87      kent 		  void (*intr)(void *), void *arg)
  1.1    brezak {
 1.87      kent 	struct ad1848_isa_softc *ac;
 1.87      kent
 1.87      kent 	ac = addr;
 1.89  christos 	return gus_dma_output(ac->sc_ad1848.parent, tbuf, size, intr, arg);
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * called at splgus() from interrupt handler.
  1.1    brezak  */
  1.1    brezak void
 1.87      kent stereo_dmaintr(void *arg)
  1.1    brezak {
 1.87      kent 	struct gus_softc *sc;
 1.87      kent 	struct stereo_dma_intr *sa;
  1.1    brezak
 1.87      kent 	DMAPRINTF(("stereo_dmaintr"));
 1.87      kent 	sc = arg;
 1.87      kent 	sa = &sc->sc_stereo;
  1.1    brezak
 1.87      kent 	/*
 1.87      kent 	 * Put other half in its place, then call the real interrupt routine :)
 1.87      kent 	 */
  1.1    brezak
 1.87      kent 	sc->sc_dmaoutintr = sa->intr;
 1.87      kent 	sc->sc_outarg = sa->arg;
  1.1    brezak
  1.1    brezak #ifdef GUSPLAYDEBUG
 1.87      kent 	if (gusstats) {
 1.87      kent 		microtime(&dmarecords[dmarecord_index].tv);
 1.87      kent 		dmarecords[dmarecord_index].gusaddr = sa->dmabuf;
 1.87      kent 		dmarecords[dmarecord_index].bsdaddr = sa->buffer;
 1.87      kent 		dmarecords[dmarecord_index].count = sa->size;
 1.87      kent 		dmarecords[dmarecord_index].channel = 1;
 1.87      kent 		dmarecords[dmarecord_index].direction = 1;
 1.87      kent 		dmarecord_index = (dmarecord_index + 1) % NDMARECS;
 1.87      kent 	}
  1.1    brezak #endif
  1.1    brezak
 1.97  christos 	gusdmaout(sc, sa->flags, sa->dmabuf, (void *) sa->buffer, sa->size);
  1.1    brezak
 1.87      kent 	sa->flags = 0;
 1.87      kent 	sa->dmabuf = 0;
 1.87      kent 	sa->buffer = 0;
 1.87      kent 	sa->size = 0;
 1.87      kent 	sa->intr = 0;
 1.87      kent 	sa->arg = 0;
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Start up DMA output to the card.
  1.1    brezak  * Called at splgus/splaudio already, either from intr handler or from
  1.1    brezak  * generic audio code.
  1.1    brezak  */
  1.1    brezak int
 1.89  christos gus_dma_output(void *addr, void *tbuf, int size,
 1.87      kent 	       void (*intr)(void *), void *arg)
  1.1    brezak {
 1.87      kent 	struct gus_softc *sc;
 1.87      kent 	u_char *buffer;
  1.1    brezak 	u_long boarddma;
 1.14  christos 	int flags;
  1.1    brezak
 1.89  christos 	DMAPRINTF(("gus_dma_output %d @ %p\n", size, tbuf));
 1.87      kent 	sc = addr;
 1.89  christos 	buffer = tbuf;
  1.1    brezak
  1.1    brezak 	if (size != sc->sc_blocksize) {
 1.87      kent 		DPRINTF(("gus_dma_output reqsize %d not sc_blocksize %d\n",
  1.1    brezak 		     size, sc->sc_blocksize));
 1.87      kent 		return EINVAL;
  1.1    brezak 	}
  1.1    brezak
  1.1    brezak 	flags = GUSMASK_DMA_WRITE;
  1.1    brezak 	if (sc->sc_precision == 16)
 1.87      kent 		flags |= GUSMASK_DMA_DATA_SIZE;
  1.1    brezak 	if (sc->sc_encoding == AUDIO_ENCODING_ULAW ||
 1.39  augustss 	    sc->sc_encoding == AUDIO_ENCODING_ALAW ||
 1.29       jtk 	    sc->sc_encoding == AUDIO_ENCODING_ULINEAR_BE ||
 1.24  augustss 	    sc->sc_encoding == AUDIO_ENCODING_ULINEAR_LE)
 1.87      kent 		flags |= GUSMASK_DMA_INVBIT;
  1.1    brezak
  1.1    brezak 	if (sc->sc_channels == 2) {
  1.1    brezak 		if (sc->sc_precision == 16) {
  1.1    brezak 			if (size & 3) {
  1.1    brezak 				DPRINTF(("gus_dma_output: unpaired 16bit samples"));
  1.1    brezak 				size &= 3;
  1.1    brezak 			}
  1.1    brezak 		} else if (size & 1) {
  1.1    brezak 			DPRINTF(("gus_dma_output: unpaired samples"));
  1.1    brezak 			size &= 1;
  1.1    brezak 		}
  1.1    brezak 		if (size == 0)
  1.1    brezak 			return 0;
 1.28  augustss
 1.28  augustss 		gus_deinterleave(sc, (void *)buffer, size);
 1.28  augustss
  1.1    brezak 		size >>= 1;
  1.1    brezak
 1.87      kent 		boarddma = size * sc->sc_dmabuf + GUS_MEM_OFFSET;
  1.1    brezak
  1.1    brezak 		sc->sc_stereo.intr = intr;
  1.1    brezak 		sc->sc_stereo.arg = arg;
  1.1    brezak 		sc->sc_stereo.size = size;
  1.1    brezak 		sc->sc_stereo.dmabuf = boarddma + GUS_LEFT_RIGHT_OFFSET;
  1.1    brezak 		sc->sc_stereo.buffer = buffer + size;
  1.1    brezak 		sc->sc_stereo.flags = flags;
  1.1    brezak 		if (gus_dostereo) {
 1.87      kent 			intr = stereo_dmaintr;
 1.87      kent 			arg = sc;
  1.1    brezak 		}
  1.1    brezak 	} else
  1.1    brezak 		boarddma = size * sc->sc_dmabuf + GUS_MEM_OFFSET;
  1.1    brezak
  1.1    brezak
  1.1    brezak 	sc->sc_flags |= GUS_LOCKED;
  1.1    brezak 	sc->sc_dmaoutintr = intr;
  1.1    brezak 	sc->sc_outarg = arg;
  1.1    brezak
  1.1    brezak #ifdef GUSPLAYDEBUG
  1.1    brezak 	if (gusstats) {
 1.87      kent 		microtime(&dmarecords[dmarecord_index].tv);
 1.87      kent 		dmarecords[dmarecord_index].gusaddr = boarddma;
 1.87      kent 		dmarecords[dmarecord_index].bsdaddr = buffer;
 1.87      kent 		dmarecords[dmarecord_index].count = size;
 1.87      kent 		dmarecords[dmarecord_index].channel = 0;
 1.87      kent 		dmarecords[dmarecord_index].direction = 1;
 1.87      kent 		dmarecord_index = (dmarecord_index + 1) % NDMARECS;
  1.1    brezak 	}
  1.1    brezak #endif
  1.1    brezak
 1.97  christos 	gusdmaout(sc, flags, boarddma, (void *) buffer, size);
  1.1    brezak
  1.1    brezak 	return 0;
  1.1    brezak }
  1.1    brezak
  1.1    brezak void
 1.87      kent gusmax_close(void *addr)
  1.1    brezak {
 1.87      kent 	struct ad1848_isa_softc *ac;
 1.87      kent 	struct gus_softc *sc;
 1.87      kent
 1.87      kent 	ac = addr;
 1.87      kent 	sc = ac->sc_ad1848.parent;
 1.14  christos #if 0
 1.54  augustss 	ac->mute[AD1848_AUX1_CHANNEL] = MUTE_ALL;
 1.54  augustss 	ad1848_mute_channel(ac, MUTE_ALL); /* turn off DAC output */
 1.14  christos #endif
 1.62       jtk 	ad1848_close(&ac->sc_ad1848);
  1.1    brezak 	gusclose(sc);
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Close out device stuff.  Called at splgus() from generic audio layer.
  1.1    brezak  */
  1.1    brezak void
 1.87      kent gusclose(void *addr)
  1.1    brezak {
 1.87      kent 	struct gus_softc *sc;
  1.1    brezak
 1.87      kent 	sc = addr;
 1.87      kent 	DPRINTF(("gus_close: sc=%p\n", sc));
  1.1    brezak
  1.1    brezak
  1.1    brezak /*	if (sc->sc_flags & GUS_DMAOUT_ACTIVE) */ {
  1.1    brezak 		gus_halt_out_dma(sc);
  1.1    brezak 	}
  1.1    brezak /*	if (sc->sc_flags & GUS_DMAIN_ACTIVE) */ {
  1.1    brezak 		gus_halt_in_dma(sc);
  1.1    brezak 	}
  1.1    brezak 	sc->sc_flags &= ~(GUS_OPEN|GUS_LOCKED|GUS_DMAOUT_ACTIVE|GUS_DMAIN_ACTIVE);
  1.1    brezak
  1.1    brezak 	if (sc->sc_deintr_buf) {
  1.1    brezak 		FREE(sc->sc_deintr_buf, M_DEVBUF);
  1.1    brezak 		sc->sc_deintr_buf = NULL;
  1.1    brezak 	}
  1.1    brezak 	/* turn off speaker, etc. */
  1.1    brezak
  1.1    brezak 	/* make sure the voices shut up: */
  1.1    brezak 	gus_stop_voice(sc, GUS_VOICE_LEFT, 1);
  1.1    brezak 	gus_stop_voice(sc, GUS_VOICE_RIGHT, 0);
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Service interrupts.  Farm them off to helper routines if we are using the
  1.1    brezak  * GUS for simple playback/record
  1.1    brezak  */
  1.1    brezak
  1.1    brezak #ifdef DIAGNOSTIC
  1.1    brezak int gusintrcnt;
  1.1    brezak int gusdmaintrcnt;
  1.1    brezak int gusvocintrcnt;
  1.1    brezak #endif
  1.1    brezak
  1.1    brezak int
 1.87      kent gusintr(void *arg)
  1.1    brezak {
 1.87      kent 	struct gus_softc *sc;
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh1;
 1.87      kent 	bus_space_handle_t ioh2;
  1.1    brezak 	unsigned char intr;
 1.87      kent 	int retval;
  1.1    brezak
  1.1    brezak 	DPRINTF(("gusintr\n"));
 1.87      kent 	sc = arg;
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh1 = sc->sc_ioh1;
 1.87      kent 	ioh2 = sc->sc_ioh2;
 1.87      kent 	retval = 0;
  1.1    brezak #ifdef DIAGNOSTIC
  1.1    brezak 	gusintrcnt++;
  1.1    brezak #endif
  1.1    brezak 	if (HAS_CODEC(sc))
 1.60        pk 		retval = ad1848_isa_intr(&sc->sc_codec);
 1.43  augustss 	if ((intr = bus_space_read_1(iot, ioh1, GUS_IRQ_STATUS)) & GUSMASK_IRQ_DMATC) {
 1.80       wiz 		DMAPRINTF(("gusintr DMA flags=%x\n", sc->sc_flags));
  1.1    brezak #ifdef DIAGNOSTIC
  1.1    brezak 		gusdmaintrcnt++;
  1.1    brezak #endif
  1.1    brezak 		retval += gus_dmaout_intr(sc);
  1.1    brezak 		if (sc->sc_flags & GUS_DMAIN_ACTIVE) {
 1.87      kent 			SELECT_GUS_REG(iot, ioh2, GUSREG_SAMPLE_CONTROL);
 1.87      kent 			intr = bus_space_read_1(iot, ioh2, GUS_DATA_HIGH);
 1.87      kent 			if (intr & GUSMASK_SAMPLE_DMATC) {
 1.87      kent 				retval += gus_dmain_intr(sc);
 1.87      kent 			}
  1.1    brezak 		}
  1.1    brezak 	}
  1.1    brezak 	if (intr & (GUSMASK_IRQ_VOICE | GUSMASK_IRQ_VOLUME)) {
  1.1    brezak 		DMAPRINTF(("gusintr voice flags=%x\n", sc->sc_flags));
  1.1    brezak #ifdef DIAGNOSTIC
  1.1    brezak 		gusvocintrcnt++;
  1.1    brezak #endif
  1.1    brezak 		retval += gus_voice_intr(sc);
  1.1    brezak 	}
  1.1    brezak 	if (retval)
  1.1    brezak 		return 1;
  1.1    brezak 	return retval;
  1.1    brezak }
  1.1    brezak
  1.1    brezak int gus_bufcnt[GUS_MEM_FOR_BUFFERS / GUS_BUFFER_MULTIPLE];
  1.1    brezak int gus_restart;				/* how many restarts? */
  1.1    brezak int gus_stops;				/* how many times did voice stop? */
  1.1    brezak int gus_falsestops;			/* stopped but not done? */
  1.1    brezak int gus_continues;
  1.1    brezak
  1.1    brezak struct playcont {
  1.1    brezak 	struct timeval tv;
  1.1    brezak 	u_int playbuf;
  1.1    brezak 	u_int dmabuf;
  1.1    brezak 	u_char bufcnt;
  1.1    brezak 	u_char vaction;
  1.1    brezak 	u_char voccntl;
  1.1    brezak 	u_char volcntl;
  1.1    brezak 	u_long curaddr;
  1.1    brezak 	u_long endaddr;
  1.1    brezak } playstats[NDMARECS];
  1.1    brezak
  1.1    brezak int playcntr;
  1.1    brezak
  1.8       jtk STATIC void
 1.87      kent gus_dmaout_timeout(void *arg)
  1.1    brezak {
 1.87      kent 	struct gus_softc *sc;
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
 1.87      kent 	int s;
 1.87      kent
 1.87      kent 	sc = arg;
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
1.101    cegger 	printf("%s: dmaout timeout\n", device_xname(&sc->sc_dev));
 1.87      kent 	/*
 1.87      kent 	 * Stop any DMA.
 1.87      kent 	 */
 1.87      kent 	s = splgus();
 1.87      kent 	SELECT_GUS_REG(iot, ioh2, GUSREG_DMA_CONTROL);
 1.87      kent 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 0);
 1.14  christos #if 0
 1.87      kent 	/* XXX we will dmadone below? */
 1.92   thorpej 	isa_dmaabort(device_parent(&sc->sc_dev), sc->sc_playdrq);
 1.14  christos #endif
 1.87      kent
 1.87      kent 	gus_dmaout_dointr(sc);
 1.87      kent 	splx(s);
  1.1    brezak }
  1.1    brezak
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Service DMA interrupts.  This routine will only get called if we're doing
  1.1    brezak  * a DMA transfer for playback/record requests from the audio layer.
  1.1    brezak  */
  1.1    brezak
  1.8       jtk STATIC int
 1.87      kent gus_dmaout_intr(struct gus_softc *sc)
  1.1    brezak {
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
  1.1    brezak
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
  1.1    brezak 	/*
  1.1    brezak 	 * If we got a DMA transfer complete from the GUS DRAM, then deal
  1.1    brezak 	 * with it.
  1.1    brezak 	 */
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_DMA_CONTROL);
 1.87      kent 	if (bus_space_read_1(iot, ioh2, GUS_DATA_HIGH) & GUSMASK_DMA_IRQPEND) {
 1.87      kent 		callout_stop(&sc->sc_dmaout_ch);
 1.87      kent 		gus_dmaout_dointr(sc);
 1.87      kent 		return 1;
  1.1    brezak 	}
  1.1    brezak 	return 0;
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC void
 1.87      kent gus_dmaout_dointr(struct gus_softc *sc)
  1.1    brezak {
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
  1.1    brezak
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
  1.1    brezak 	/* sc->sc_dmaoutcnt - 1 because DMA controller counts from zero?. */
 1.87      kent 	isa_dmadone(sc->sc_ic, sc->sc_playdrq);
  1.1    brezak 	sc->sc_flags &= ~GUS_DMAOUT_ACTIVE;  /* pending DMA is done */
 1.87      kent 	DMAPRINTF(("gus_dmaout_dointr %d @ %p\n", sc->sc_dmaoutcnt,
  1.1    brezak 		   sc->sc_dmaoutaddr));
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * to prevent clicking, we need to copy last sample
  1.1    brezak 	 * from last buffer to scratch area just before beginning of
  1.1    brezak 	 * buffer.  However, if we're doing formats that are converted by
  1.1    brezak 	 * the card during the DMA process, we need to pick up the converted
  1.1    brezak 	 * byte rather than the one we have in memory.
  1.1    brezak 	 */
  1.1    brezak 	if (sc->sc_dmabuf == sc->sc_nbufs - 1) {
 1.87      kent 		int i;
 1.87      kent 		switch (sc->sc_encoding) {
 1.87      kent 		case AUDIO_ENCODING_SLINEAR_LE:
 1.87      kent 		case AUDIO_ENCODING_SLINEAR_BE:
 1.87      kent 			if (sc->sc_precision == 8)
 1.87      kent 				goto byte;
 1.87      kent 			/* we have the native format */
 1.87      kent 			for (i = 1; i <= 2; i++)
 1.87      kent 				guspoke(iot, ioh2, sc->sc_gusaddr -
 1.87      kent 					(sc->sc_nbufs - 1) * sc->sc_chanblocksize - i,
 1.87      kent 					sc->sc_dmaoutaddr[sc->sc_dmaoutcnt-i]);
 1.87      kent 			break;
 1.87      kent 		case AUDIO_ENCODING_ULINEAR_LE:
 1.87      kent 		case AUDIO_ENCODING_ULINEAR_BE:
 1.87      kent 			guspoke(iot, ioh2, sc->sc_gusaddr -
 1.87      kent 				(sc->sc_nbufs - 1) * sc->sc_chanblocksize - 2,
 1.87      kent 				guspeek(iot, ioh2,
 1.87      kent 					sc->sc_gusaddr + sc->sc_chanblocksize - 2));
 1.87      kent 		case AUDIO_ENCODING_ALAW:
 1.87      kent 		case AUDIO_ENCODING_ULAW:
 1.87      kent 		byte:
 1.87      kent 			/* we need to fetch the translated byte, then stuff it. */
 1.87      kent 			guspoke(iot, ioh2, sc->sc_gusaddr -
 1.87      kent 				(sc->sc_nbufs - 1) * sc->sc_chanblocksize - 1,
 1.87      kent 				guspeek(iot, ioh2,
 1.87      kent 					sc->sc_gusaddr + sc->sc_chanblocksize - 1));
 1.87      kent 			break;
 1.87      kent 		}
  1.1    brezak 	}
  1.1    brezak 	/*
  1.1    brezak 	 * If this is the first half of stereo, "ignore" this one
  1.1    brezak 	 * and copy out the second half.
  1.1    brezak 	 */
  1.1    brezak 	if (sc->sc_dmaoutintr == stereo_dmaintr) {
 1.87      kent 		(*sc->sc_dmaoutintr)(sc->sc_outarg);
 1.87      kent 		return;
  1.1    brezak 	}
  1.1    brezak 	/*
  1.1    brezak 	 * If the voice is stopped, then start it.  Reset the loop
  1.1    brezak 	 * and roll bits.  Call the audio layer routine, since if
  1.1    brezak 	 * we're starting a stopped voice, that means that the next
  1.1    brezak 	 * buffer can be filled
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	sc->sc_flags &= ~GUS_LOCKED;
  1.1    brezak 	if (sc->sc_voc[GUS_VOICE_LEFT].voccntl &
  1.1    brezak 	    GUSMASK_VOICE_STOPPED) {
 1.87      kent 		if (sc->sc_flags & GUS_PLAYING) {
1.101    cegger 			printf("%s: playing yet stopped?\n", device_xname(&sc->sc_dev));
 1.87      kent 		}
 1.87      kent 		sc->sc_bufcnt++; /* another yet to be played */
 1.87      kent 		gus_start_playing(sc, sc->sc_dmabuf);
 1.87      kent 		gus_restart++;
  1.1    brezak 	} else {
  1.1    brezak 		/*
 1.87      kent 		 * set the sound action based on which buffer we
 1.87      kent 		 * just transferred.  If we just transferred buffer 0
 1.87      kent 		 * we want the sound to loop when it gets to the nth
 1.87      kent 		 * buffer; if we just transferred
 1.87      kent 		 * any other buffer, we want the sound to roll over
 1.87      kent 		 * at least one more time.  The voice interrupt
 1.87      kent 		 * handlers will take care of accounting &
 1.87      kent 		 * setting control bits if it's not caught up to us
 1.87      kent 		 * yet.
  1.1    brezak 		 */
 1.87      kent 		if (++sc->sc_bufcnt == 2) {
 1.87      kent 			/*
 1.88     perry 			 * XXX
 1.87      kent 			 * If we're too slow in reaction here,
 1.87      kent 			 * the voice could be just approaching the
 1.87      kent 			 * end of its run.  It should be set to stop,
 1.87      kent 			 * so these adjustments might not DTRT.
 1.87      kent 			 */
 1.87      kent 			if (sc->sc_dmabuf == 0 &&
 1.87      kent 			    sc->sc_playbuf == sc->sc_nbufs - 1) {
 1.89  christos 				/* player is just at the last tbuf, we're at the
 1.87      kent 				   first.  Turn on looping, turn off rolling. */
 1.87      kent 				sc->sc_voc[GUS_VOICE_LEFT].voccntl |= GUSMASK_LOOP_ENABLE;
 1.87      kent 				sc->sc_voc[GUS_VOICE_LEFT].volcntl &= ~GUSMASK_VOICE_ROLL;
 1.87      kent 				playstats[playcntr].vaction = 3;
 1.87      kent 			} else {
 1.89  christos 				/* player is at previous tbuf:
 1.87      kent 				   turn on rolling, turn off looping */
 1.87      kent 				sc->sc_voc[GUS_VOICE_LEFT].voccntl &= ~GUSMASK_LOOP_ENABLE;
 1.87      kent 				sc->sc_voc[GUS_VOICE_LEFT].volcntl |= GUSMASK_VOICE_ROLL;
 1.87      kent 				playstats[playcntr].vaction = 4;
 1.87      kent 			}
  1.1    brezak #ifdef GUSPLAYDEBUG
 1.87      kent 			if (gusstats) {
 1.87      kent 				microtime(&playstats[playcntr].tv);
 1.87      kent 				playstats[playcntr].endaddr
 1.87      kent 				    = sc->sc_voc[GUS_VOICE_LEFT].end_addr;
 1.87      kent 				playstats[playcntr].voccntl
 1.87      kent 				    = sc->sc_voc[GUS_VOICE_LEFT].voccntl;
 1.87      kent 				playstats[playcntr].volcntl
 1.87      kent 				    = sc->sc_voc[GUS_VOICE_LEFT].volcntl;
 1.87      kent 				playstats[playcntr].playbuf = sc->sc_playbuf;
 1.87      kent 				playstats[playcntr].dmabuf = sc->sc_dmabuf;
 1.87      kent 				playstats[playcntr].bufcnt = sc->sc_bufcnt;
 1.87      kent 				playstats[playcntr].curaddr
 1.87      kent 				    = gus_get_curaddr(sc, GUS_VOICE_LEFT);
 1.87      kent 				playcntr = (playcntr + 1) % NDMARECS;
 1.87      kent 			}
 1.87      kent #endif
 1.87      kent 			bus_space_write_1(iot, ioh2, GUS_VOICE_SELECT, GUS_VOICE_LEFT);
 1.87      kent 			SELECT_GUS_REG(iot, ioh2, GUSREG_VOICE_CNTL);
 1.87      kent 			bus_space_write_1(iot, ioh2, GUS_DATA_HIGH,
 1.87      kent 					  sc->sc_voc[GUS_VOICE_LEFT].voccntl);
 1.87      kent 			SELECT_GUS_REG(iot, ioh2, GUSREG_VOLUME_CONTROL);
 1.87      kent 			bus_space_write_1(iot, ioh2, GUS_DATA_HIGH,
 1.87      kent 					  sc->sc_voc[GUS_VOICE_LEFT].volcntl);
  1.1    brezak 		}
  1.1    brezak 	}
  1.1    brezak 	gus_bufcnt[sc->sc_bufcnt-1]++;
  1.1    brezak 	/*
  1.1    brezak 	 * flip to the next DMA buffer
  1.1    brezak 	 */
  1.1    brezak
 1.87      kent 	sc->sc_dmabuf = ++sc->sc_dmabuf % sc->sc_nbufs;
  1.1    brezak 	/*
  1.1    brezak 	 * See comments below about DMA admission control strategy.
  1.1    brezak 	 * We can call the upper level here if we have an
  1.1    brezak 	 * idle buffer (not currently playing) to DMA into.
  1.1    brezak 	 */
  1.1    brezak 	if (sc->sc_dmaoutintr && sc->sc_bufcnt < sc->sc_nbufs) {
 1.87      kent 		/* clean out to prevent double calls */
 1.87      kent 		void (*pfunc)(void *);
 1.87      kent 		void *arg;
 1.87      kent
 1.87      kent 		pfunc = sc->sc_dmaoutintr;
 1.87      kent 		arg = sc->sc_outarg;
 1.87      kent 		sc->sc_outarg = 0;
 1.87      kent 		sc->sc_dmaoutintr = 0;
 1.87      kent 		(*pfunc)(arg);
  1.1    brezak 	}
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Service voice interrupts
  1.1    brezak  */
  1.1    brezak
  1.8       jtk STATIC int
 1.87      kent gus_voice_intr(struct gus_softc *sc)
  1.1    brezak {
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
 1.87      kent 	int ignore, voice, rval;
  1.1    brezak 	unsigned char intr, status;
  1.1    brezak
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
 1.87      kent 	ignore = 0;
 1.87      kent 	rval = 0;
  1.1    brezak 	/*
  1.1    brezak 	 * The point of this may not be obvious at first.  A voice can
  1.1    brezak 	 * interrupt more than once; according to the GUS SDK we are supposed
  1.1    brezak 	 * to ignore multiple interrupts for the same voice.
  1.1    brezak 	 */
  1.1    brezak
 1.87      kent 	while (1) {
 1.43  augustss 		SELECT_GUS_REG(iot, ioh2, GUSREG_IRQ_STATUS);
 1.43  augustss 		intr = bus_space_read_1(iot, ioh2, GUS_DATA_HIGH);
  1.1    brezak
  1.1    brezak 		if ((intr & (GUSMASK_WIRQ_VOLUME | GUSMASK_WIRQ_VOICE))
  1.1    brezak 			== (GUSMASK_WIRQ_VOLUME | GUSMASK_WIRQ_VOICE))
  1.1    brezak 			/*
  1.1    brezak 			 * No more interrupts, time to return
  1.1    brezak 			 */
 1.87      kent 			return rval;
  1.1    brezak
  1.1    brezak 		if ((intr & GUSMASK_WIRQ_VOICE) == 0) {
  1.1    brezak
 1.87      kent 			/*
 1.87      kent 			 * We've got a voice interrupt.  Ignore previous
 1.87      kent 			 * interrupts by the same voice.
 1.87      kent 			 */
  1.1    brezak
 1.87      kent 			rval = 1;
 1.87      kent 			voice = intr & GUSMASK_WIRQ_VOICEMASK;
  1.1    brezak
 1.87      kent 			if ((1 << voice) & ignore)
 1.87      kent 				break;
  1.1    brezak
 1.87      kent 			ignore |= 1 << voice;
  1.1    brezak
  1.1    brezak 			/*
 1.87      kent 			 * If the voice is stopped, then force it to stop
 1.87      kent 			 * (this stops it from continuously generating IRQs)
  1.1    brezak 			 */
 1.87      kent
 1.87      kent 			SELECT_GUS_REG(iot, ioh2, GUSREG_VOICE_CNTL+0x80);
 1.87      kent 			status = bus_space_read_1(iot, ioh2, GUS_DATA_HIGH);
 1.87      kent 			if (status & GUSMASK_VOICE_STOPPED) {
 1.87      kent 				if (voice != GUS_VOICE_LEFT) {
 1.87      kent 					DMAPRINTF(("%s: spurious voice %d stop?\n",
1.101    cegger 						   device_xname(&sc->sc_dev), voice));
 1.87      kent 					gus_stop_voice(sc, voice, 0);
 1.87      kent 					continue;
 1.87      kent 				}
 1.87      kent 				gus_stop_voice(sc, voice, 1);
 1.87      kent 				/* also kill right voice */
 1.87      kent 				gus_stop_voice(sc, GUS_VOICE_RIGHT, 0);
 1.87      kent 				sc->sc_bufcnt--; /* it finished a buffer */
 1.87      kent 				if (sc->sc_bufcnt > 0) {
 1.87      kent 					/*
 1.87      kent 					 * probably a race to get here: the
 1.87      kent 					 * voice stopped while the DMA code was
 1.87      kent 					 * just trying to get the next buffer
 1.87      kent 					 * in place.  Start the voice again.
 1.87      kent 					 */
 1.87      kent 					printf("%s: stopped voice not drained? (%x)\n",
1.101    cegger 					       device_xname(&sc->sc_dev), sc->sc_bufcnt);
 1.87      kent 					gus_falsestops++;
 1.87      kent
 1.87      kent 					sc->sc_playbuf = ++sc->sc_playbuf % sc->sc_nbufs;
 1.87      kent 					gus_start_playing(sc, sc->sc_playbuf);
 1.87      kent 				} else if (sc->sc_bufcnt < 0) {
 1.87      kent 					panic("%s: negative bufcnt in stopped voice",
1.101    cegger 					      device_xname(&sc->sc_dev));
 1.87      kent 				} else {
 1.87      kent 					sc->sc_playbuf = -1; /* none are active */
 1.87      kent 					gus_stops++;
 1.87      kent 				}
 1.87      kent 				/* fall through to callback and admit another
 1.87      kent 				   buffer.... */
 1.87      kent 			} else if (sc->sc_bufcnt != 0) {
  1.8       jtk 				/*
 1.87      kent 				 * This should always be taken if the voice
 1.87      kent 				 * is not stopped.
  1.8       jtk 				 */
 1.87      kent 				gus_continues++;
 1.87      kent 				if (gus_continue_playing(sc, voice)) {
 1.87      kent 					/*
 1.87      kent 					 * we shouldn't have continued--active
 1.87      kent 					 * DMA is in the way in the ring, for
 1.87      kent 					 * some as-yet undebugged reason.
 1.87      kent 					 */
 1.87      kent 					gus_stop_voice(sc, GUS_VOICE_LEFT, 1);
 1.87      kent 					/* also kill right voice */
 1.87      kent 					gus_stop_voice(sc, GUS_VOICE_RIGHT, 0);
 1.87      kent 					sc->sc_playbuf = -1;
 1.87      kent 					gus_stops++;
 1.87      kent 				}
  1.8       jtk 			}
 1.87      kent 			/*
 1.87      kent 			 * call the upper level to send on down another
 1.87      kent 			 * block. We do admission rate control as follows:
 1.87      kent 			 *
 1.87      kent 			 * When starting up output (in the first N
 1.87      kent 			 * blocks), call the upper layer after the DMA is
 1.87      kent 			 * complete (see above in gus_dmaout_intr()).
 1.87      kent 			 *
 1.87      kent 			 * When output is already in progress and we have
 1.87      kent 			 * no more GUS buffers to use for DMA, the DMA
 1.87      kent 			 * output routines do not call the upper layer.
 1.87      kent 			 * Instead, we call the DMA completion routine
 1.87      kent 			 * here, after the voice interrupts indicating
 1.87      kent 			 * that it's finished with a buffer.
 1.87      kent 			 *
 1.87      kent 			 * However, don't call anything here if the DMA
 1.87      kent 			 * output flag is set, (which shouldn't happen)
 1.87      kent 			 * because we'll squish somebody else's DMA if
 1.87      kent 			 * that's the case.  When DMA is done, it will
 1.87      kent 			 * call back if there is a spare buffer.
 1.87      kent 			 */
 1.87      kent 			if (sc->sc_dmaoutintr && !(sc->sc_flags & GUS_LOCKED)) {
 1.87      kent 				if (sc->sc_dmaoutintr == stereo_dmaintr)
 1.87      kent 					printf("gusdmaout botch?\n");
 1.87      kent 				else {
 1.87      kent 					/* clean out to avoid double calls */
 1.87      kent 					void (*pfunc)(void *);
 1.87      kent 					void *arg;
 1.87      kent
 1.87      kent 					pfunc = sc->sc_dmaoutintr;
 1.87      kent 					arg = sc->sc_outarg;
 1.87      kent 					sc->sc_outarg = 0;
 1.87      kent 					sc->sc_dmaoutintr = 0;
 1.87      kent 					(*pfunc)(arg);
 1.87      kent 				}
  1.1    brezak 			}
  1.1    brezak 		}
  1.1    brezak
  1.1    brezak 		/*
  1.1    brezak 		 * Ignore other interrupts for now
  1.1    brezak 		 */
  1.1    brezak 	}
 1.14  christos 	return 0;
  1.1    brezak }
  1.1    brezak
 1.87      kent /*
 1.87      kent  * Start the voices playing, with buffer BUFNO.
 1.87      kent  */
  1.8       jtk STATIC void
 1.87      kent gus_start_playing(struct gus_softc *sc, int bufno)
  1.1    brezak {
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
  1.1    brezak
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
 1.43  augustss 	/*
 1.43  augustss 	 * Loop or roll if we have buffers ready.
 1.43  augustss 	 */
  1.1    brezak
 1.43  augustss 	if (sc->sc_bufcnt == 1) {
 1.43  augustss 		sc->sc_voc[GUS_VOICE_LEFT].voccntl &= ~(GUSMASK_LOOP_ENABLE);
 1.43  augustss 		sc->sc_voc[GUS_VOICE_LEFT].volcntl &= ~(GUSMASK_VOICE_ROLL);
  1.1    brezak 	} else {
 1.43  augustss 		if (bufno == sc->sc_nbufs - 1) {
 1.43  augustss 			sc->sc_voc[GUS_VOICE_LEFT].voccntl |= GUSMASK_LOOP_ENABLE;
 1.43  augustss 			sc->sc_voc[GUS_VOICE_LEFT].volcntl &= ~(GUSMASK_VOICE_ROLL);
 1.43  augustss 		} else {
 1.43  augustss 			sc->sc_voc[GUS_VOICE_LEFT].voccntl &= ~GUSMASK_LOOP_ENABLE;
 1.43  augustss 			sc->sc_voc[GUS_VOICE_LEFT].volcntl |= GUSMASK_VOICE_ROLL;
 1.43  augustss 		}
  1.1    brezak 	}
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_VOICE_SELECT, GUS_VOICE_LEFT);
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_VOICE_CNTL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, sc->sc_voc[GUS_VOICE_LEFT].voccntl);
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_VOLUME_CONTROL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, sc->sc_voc[GUS_VOICE_LEFT].volcntl);
  1.1    brezak
 1.43  augustss 	sc->sc_voc[GUS_VOICE_LEFT].current_addr =
 1.87      kent 	    GUS_MEM_OFFSET + sc->sc_chanblocksize * bufno;
 1.43  augustss 	sc->sc_voc[GUS_VOICE_LEFT].end_addr =
 1.87      kent 	    sc->sc_voc[GUS_VOICE_LEFT].current_addr + sc->sc_chanblocksize - 1;
 1.43  augustss 	sc->sc_voc[GUS_VOICE_RIGHT].current_addr =
 1.87      kent 	    sc->sc_voc[GUS_VOICE_LEFT].current_addr +
 1.87      kent 	    (gus_dostereo && sc->sc_channels == 2 ? GUS_LEFT_RIGHT_OFFSET : 0);
 1.43  augustss 	/*
 1.43  augustss 	 * set up right channel to just loop forever, no interrupts,
 1.43  augustss 	 * starting at the buffer we just filled.  We'll feed it data
 1.43  augustss 	 * at the same time as left channel.
 1.43  augustss 	 */
 1.43  augustss 	sc->sc_voc[GUS_VOICE_RIGHT].voccntl |= GUSMASK_LOOP_ENABLE;
 1.43  augustss 	sc->sc_voc[GUS_VOICE_RIGHT].volcntl &= ~(GUSMASK_VOICE_ROLL);
  1.1    brezak
  1.1    brezak #ifdef GUSPLAYDEBUG
 1.43  augustss 	if (gusstats) {
 1.43  augustss 		microtime(&playstats[playcntr].tv);
 1.43  augustss 		playstats[playcntr].curaddr = sc->sc_voc[GUS_VOICE_LEFT].current_addr;
  1.1    brezak
 1.43  augustss 		playstats[playcntr].voccntl = sc->sc_voc[GUS_VOICE_LEFT].voccntl;
 1.43  augustss 		playstats[playcntr].volcntl = sc->sc_voc[GUS_VOICE_LEFT].volcntl;
 1.43  augustss 		playstats[playcntr].endaddr = sc->sc_voc[GUS_VOICE_LEFT].end_addr;
 1.43  augustss 		playstats[playcntr].playbuf = bufno;
 1.43  augustss 		playstats[playcntr].dmabuf = sc->sc_dmabuf;
 1.43  augustss 		playstats[playcntr].bufcnt = sc->sc_bufcnt;
 1.43  augustss 		playstats[playcntr].vaction = 5;
 1.82      gson 		playcntr = (playcntr + 1) % NDMARECS;
 1.43  augustss 	}
  1.1    brezak #endif
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_VOICE_SELECT, GUS_VOICE_RIGHT);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_VOICE_CNTL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, sc->sc_voc[GUS_VOICE_RIGHT].voccntl);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_VOLUME_CONTROL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, sc->sc_voc[GUS_VOICE_RIGHT].volcntl);
 1.43  augustss
 1.43  augustss 	gus_start_voice(sc, GUS_VOICE_RIGHT, 0);
 1.43  augustss 	gus_start_voice(sc, GUS_VOICE_LEFT, 1);
 1.43  augustss 	if (sc->sc_playbuf == -1)
 1.43  augustss 		/* mark start of playing */
 1.43  augustss 		sc->sc_playbuf = bufno;
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC int
 1.87      kent gus_continue_playing(struct gus_softc *sc, int voice)
  1.1    brezak {
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
  1.1    brezak
 1.43  augustss 	/*
 1.43  augustss 	 * stop this voice from interrupting while we work.
 1.43  augustss 	 */
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_VOICE_CNTL);
 1.87      kent 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH,
 1.87      kent 	    sc->sc_voc[voice].voccntl & ~(GUSMASK_VOICE_IRQ));
  1.1    brezak
 1.87      kent 	/*
 1.43  augustss 	 * update playbuf to point to the buffer the hardware just started
 1.43  augustss 	 * playing
 1.43  augustss 	 */
 1.43  augustss 	sc->sc_playbuf = ++sc->sc_playbuf % sc->sc_nbufs;
 1.87      kent
 1.43  augustss 	/*
 1.43  augustss 	 * account for buffer just finished
 1.43  augustss 	 */
 1.43  augustss 	if (--sc->sc_bufcnt == 0) {
 1.43  augustss 		DPRINTF(("gus: bufcnt 0 on continuing voice?\n"));
 1.43  augustss 	}
 1.43  augustss 	if (sc->sc_playbuf == sc->sc_dmabuf && (sc->sc_flags & GUS_LOCKED)) {
1.101    cegger 		aprint_error_dev(&sc->sc_dev, "continue into active dmabuf?\n");
 1.43  augustss 		return 1;
 1.43  augustss 	}
  1.1    brezak
 1.43  augustss 	/*
 1.43  augustss 	 * Select the end of the buffer based on the currently active
 1.43  augustss 	 * buffer, [plus extra contiguous buffers (if ready)].
 1.43  augustss 	 */
  1.1    brezak
 1.87      kent 	/*
 1.43  augustss 	 * set endpoint at end of buffer we just started playing.
 1.43  augustss 	 *
 1.43  augustss 	 * The total gets -1 because end addrs are one less than you might
 1.43  augustss 	 * think (the end_addr is the address of the last sample to play)
 1.43  augustss 	 */
 1.43  augustss 	gus_set_endaddr(sc, voice, GUS_MEM_OFFSET +
 1.43  augustss 			sc->sc_chanblocksize * (sc->sc_playbuf + 1) - 1);
  1.1    brezak
 1.43  augustss 	if (sc->sc_bufcnt < 2) {
 1.43  augustss 		/*
 1.43  augustss 		 * Clear out the loop and roll flags, and rotate the currently
 1.43  augustss 		 * playing buffer.  That way, if we don't manage to get more
 1.43  augustss 		 * data before this buffer finishes, we'll just stop.
 1.43  augustss 		 */
 1.43  augustss 		sc->sc_voc[voice].voccntl &= ~GUSMASK_LOOP_ENABLE;
 1.43  augustss 		sc->sc_voc[voice].volcntl &= ~GUSMASK_VOICE_ROLL;
 1.43  augustss 		playstats[playcntr].vaction = 0;
  1.1    brezak 	} else {
 1.43  augustss 		/*
 1.43  augustss 		 * We have some buffers to play.  set LOOP if we're on the
 1.43  augustss 		 * last buffer in the ring, otherwise set ROLL.
 1.43  augustss 		 */
 1.43  augustss 		if (sc->sc_playbuf == sc->sc_nbufs - 1) {
 1.43  augustss 			sc->sc_voc[voice].voccntl |= GUSMASK_LOOP_ENABLE;
 1.43  augustss 			sc->sc_voc[voice].volcntl &= ~GUSMASK_VOICE_ROLL;
 1.43  augustss 			playstats[playcntr].vaction = 1;
 1.43  augustss 		} else {
 1.43  augustss 			sc->sc_voc[voice].voccntl &= ~GUSMASK_LOOP_ENABLE;
 1.43  augustss 			sc->sc_voc[voice].volcntl |= GUSMASK_VOICE_ROLL;
 1.43  augustss 			playstats[playcntr].vaction = 2;
 1.43  augustss 		}
  1.1    brezak 	}
  1.1    brezak #ifdef GUSPLAYDEBUG
 1.43  augustss 	if (gusstats) {
 1.43  augustss 		microtime(&playstats[playcntr].tv);
 1.43  augustss 		playstats[playcntr].curaddr = gus_get_curaddr(sc, voice);
  1.1    brezak
 1.43  augustss 		playstats[playcntr].voccntl = sc->sc_voc[voice].voccntl;
 1.43  augustss 		playstats[playcntr].volcntl = sc->sc_voc[voice].volcntl;
 1.43  augustss 		playstats[playcntr].endaddr = sc->sc_voc[voice].end_addr;
 1.43  augustss 		playstats[playcntr].playbuf = sc->sc_playbuf;
 1.43  augustss 		playstats[playcntr].dmabuf = sc->sc_dmabuf;
 1.43  augustss 		playstats[playcntr].bufcnt = sc->sc_bufcnt;
 1.82      gson 		playcntr = (playcntr + 1) % NDMARECS;
 1.43  augustss 	}
  1.1    brezak #endif
  1.1    brezak
 1.43  augustss 	/*
 1.43  augustss 	 * (re-)set voice parameters.  This will reenable interrupts from this
 1.43  augustss 	 * voice.
 1.43  augustss 	 */
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_VOICE_CNTL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, sc->sc_voc[voice].voccntl);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_VOLUME_CONTROL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, sc->sc_voc[voice].volcntl);
 1.43  augustss 	return 0;
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Send/receive data into GUS's DRAM using DMA.  Called at splgus()
  1.1    brezak  */
  1.8       jtk STATIC void
 1.87      kent gusdmaout(struct gus_softc *sc, int flags,
 1.97  christos 	  u_long gusaddr, void *buffaddr, int length)
  1.1    brezak {
 1.87      kent 	unsigned char c;
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
  1.1    brezak
  1.1    brezak 	DMAPRINTF(("gusdmaout flags=%x scflags=%x\n", flags, sc->sc_flags));
 1.87      kent 	c = (unsigned char) flags;
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
  1.1    brezak
  1.1    brezak 	sc->sc_gusaddr = gusaddr;
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * If we're using a 16 bit DMA channel, we have to jump through some
  1.1    brezak 	 * extra hoops; this includes translating the DRAM address a bit
  1.1    brezak 	 */
  1.1    brezak
 1.66   mycroft 	if (sc->sc_playdrq >= 4) {
  1.1    brezak 		c |= GUSMASK_DMA_WIDTH;
  1.1    brezak 		gusaddr = convert_to_16bit(gusaddr);
  1.1    brezak 	}
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Add flag bits that we always set - fast DMA, enable IRQ
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	c |= GUSMASK_DMA_ENABLE | GUSMASK_DMA_R0 | GUSMASK_DMA_IRQ;
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Make sure the GUS _isn't_ setup for DMA
  1.1    brezak 	 */
  1.1    brezak
 1.87      kent 	SELECT_GUS_REG(iot, ioh2, GUSREG_DMA_CONTROL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 0);
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Tell the PC DMA controller to start doing DMA
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	sc->sc_dmaoutaddr = (u_char *) buffaddr;
  1.1    brezak 	sc->sc_dmaoutcnt = length;
 1.87      kent 	isa_dmastart(sc->sc_ic, sc->sc_playdrq, buffaddr, length,
 1.87      kent 	    NULL, DMAMODE_WRITE, BUS_DMA_NOWAIT);
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Set up DMA address - use the upper 16 bits ONLY
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	sc->sc_flags |= GUS_DMAOUT_ACTIVE;
  1.1    brezak
 1.87      kent 	SELECT_GUS_REG(iot, ioh2, GUSREG_DMA_START);
 1.87      kent 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, (int) (gusaddr >> 4));
  1.1    brezak
 1.87      kent 	/*
 1.87      kent 	 * Tell the GUS to start doing DMA
 1.87      kent 	 */
  1.1    brezak
 1.87      kent 	SELECT_GUS_REG(iot, ioh2, GUSREG_DMA_CONTROL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, c);
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * XXX If we don't finish in one second, give up...
  1.1    brezak 	 */
 1.69   thorpej 	callout_reset(&sc->sc_dmaout_ch, hz, gus_dmaout_timeout, sc);
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Start a voice playing on the GUS.  Called from interrupt handler at
  1.1    brezak  * splgus().
  1.1    brezak  */
  1.1    brezak
  1.8       jtk STATIC void
 1.87      kent gus_start_voice(struct gus_softc *sc, int voice, int intrs)
  1.1    brezak {
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
 1.14  christos 	u_long start;
 1.14  christos 	u_long current;
 1.14  christos 	u_long end;
  1.1    brezak
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
  1.1    brezak 	/*
  1.1    brezak 	 * Pick all the values for the voice out of the gus_voice struct
  1.1    brezak 	 * and use those to program the voice
  1.1    brezak 	 */
  1.1    brezak
 1.87      kent 	start = sc->sc_voc[voice].start_addr;
 1.87      kent 	current = sc->sc_voc[voice].current_addr;
 1.87      kent 	end = sc->sc_voc[voice].end_addr;
  1.1    brezak
 1.87      kent 	/*
  1.1    brezak 	 * If we're using 16 bit data, mangle the addresses a bit
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	if (sc->sc_voc[voice].voccntl & GUSMASK_DATA_SIZE16) {
 1.87      kent 		/* -1 on start so that we get onto sample boundary--other
 1.87      kent 		 * code always sets it for 1-byte rollover protection */
  1.1    brezak 		start = convert_to_16bit(start-1);
  1.1    brezak 		current = convert_to_16bit(current);
  1.1    brezak 		end = convert_to_16bit(end);
  1.1    brezak 	}
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Select the voice we want to use, and program the data addresses
  1.1    brezak 	 */
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_VOICE_SELECT, (unsigned char) voice);
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_START_ADDR_HIGH);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, ADDR_HIGH(start));
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_START_ADDR_LOW);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, ADDR_LOW(start));
 1.43  augustss
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_CUR_ADDR_HIGH);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, ADDR_HIGH(current));
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_CUR_ADDR_LOW);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, ADDR_LOW(current));
 1.43  augustss
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_END_ADDR_HIGH);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, ADDR_HIGH(end));
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_END_ADDR_LOW);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, ADDR_LOW(end));
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * (maybe) enable interrupts, disable voice stopping
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	if (intrs) {
  1.1    brezak 		sc->sc_flags |= GUS_PLAYING; /* playing is about to start */
  1.1    brezak 		sc->sc_voc[voice].voccntl |= GUSMASK_VOICE_IRQ;
  1.1    brezak 		DMAPRINTF(("gus voice playing=%x\n", sc->sc_flags));
  1.1    brezak 	} else
  1.1    brezak 		sc->sc_voc[voice].voccntl &= ~GUSMASK_VOICE_IRQ;
  1.1    brezak 	sc->sc_voc[voice].voccntl &= ~(GUSMASK_VOICE_STOPPED |
 1.87      kent 	    GUSMASK_STOP_VOICE);
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Tell the GUS about it.  Note that we're doing volume ramping here
  1.1    brezak 	 * from 0 up to the set volume to help reduce clicks.
  1.1    brezak 	 */
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_START_VOLUME);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 0x00);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_END_VOLUME);
 1.87      kent 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH,
 1.87      kent 	    sc->sc_voc[voice].current_volume >> 4);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_CUR_VOLUME);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, 0x00);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_VOLUME_RATE);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 63);
 1.43  augustss
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_VOICE_CNTL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, sc->sc_voc[voice].voccntl);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_VOLUME_CONTROL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 0x00);
  1.1    brezak 	delay(50);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_VOICE_CNTL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, sc->sc_voc[voice].voccntl);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_VOLUME_CONTROL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 0x00);
  1.1    brezak
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Stop a given voice.  called at splgus()
  1.1    brezak  */
  1.8       jtk STATIC void
 1.87      kent gus_stop_voice(struct gus_softc *sc, int voice, int intrs_too)
  1.1    brezak {
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
  1.1    brezak
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
  1.1    brezak 	sc->sc_voc[voice].voccntl |= GUSMASK_VOICE_STOPPED |
 1.87      kent 	    GUSMASK_STOP_VOICE;
  1.1    brezak 	if (intrs_too) {
 1.87      kent 		sc->sc_voc[voice].voccntl &= ~(GUSMASK_VOICE_IRQ);
 1.87      kent 		/* no more DMA to do */
 1.87      kent 		sc->sc_flags &= ~GUS_PLAYING;
  1.1    brezak 	}
  1.1    brezak 	DMAPRINTF(("gusintr voice notplaying=%x\n", sc->sc_flags));
  1.1    brezak
 1.43  augustss 	guspoke(iot, ioh2, 0L, 0);
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_VOICE_SELECT, (unsigned char) voice);
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_CUR_VOLUME);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, 0x0000);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_VOICE_CNTL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, sc->sc_voc[voice].voccntl);
  1.1    brezak 	delay(100);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_CUR_VOLUME);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, 0x0000);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_VOICE_CNTL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, sc->sc_voc[voice].voccntl);
 1.43  augustss
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_CUR_ADDR_HIGH);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, 0x0000);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_CUR_ADDR_LOW);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, 0x0000);
  1.1    brezak
  1.1    brezak }
  1.1    brezak
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Set the volume of a given voice.  Called at splgus().
  1.1    brezak  */
  1.8       jtk STATIC void
 1.87      kent gus_set_volume(struct gus_softc *sc, int voice, int volume)
  1.1    brezak {
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
  1.1    brezak 	unsigned int gusvol;
  1.1    brezak
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
  1.1    brezak 	gusvol = gus_log_volumes[volume < 512 ? volume : 511];
  1.1    brezak
  1.1    brezak 	sc->sc_voc[voice].current_volume = gusvol;
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_VOICE_SELECT, (unsigned char) voice);
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_START_VOLUME);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, (unsigned char) (gusvol >> 4));
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_END_VOLUME);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, (unsigned char) (gusvol >> 4));
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_CUR_VOLUME);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, gusvol << 4);
  1.1    brezak 	delay(500);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, gusvol << 4);
  1.1    brezak
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
 1.23  augustss  * Interface to the audio layer.
  1.1    brezak  */
  1.1    brezak
  1.1    brezak int
 1.87      kent gusmax_set_params(void *addr, int setmode, int usemode, audio_params_t *p,
 1.87      kent 		  audio_params_t *r, stream_filter_list_t *pfil,
 1.87      kent 		  stream_filter_list_t *rfil)
 1.23  augustss {
 1.87      kent 	struct ad1848_isa_softc *ac;
 1.87      kent 	struct gus_softc *sc;
 1.23  augustss 	int error;
 1.23  augustss
 1.87      kent 	ac = addr;
 1.87      kent 	sc = ac->sc_ad1848.parent;
 1.86      kent 	error = ad1848_set_params(ac, setmode, usemode, p, r, pfil, rfil);
 1.23  augustss 	if (error)
 1.23  augustss 		return error;
 1.86      kent 	/*
 1.86      kent 	 * ad1848_set_params() sets a filter for
 1.86      kent 	 *  SLINEAR_LE 8, SLINEAR_BE 16, ULINEAR_LE 16, ULINEAR_BE 16.
 1.86      kent 	 * gus_set_params() sets a filter for
 1.86      kent 	 *  ULAW, ALAW, ULINEAR_BE (16), SLINEAR_BE (16)
 1.86      kent 	 */
 1.86      kent 	error = gus_set_params(sc, setmode, usemode, p, r, pfil, rfil);
 1.25  augustss 	return error;
 1.23  augustss }
 1.23  augustss
 1.23  augustss int
 1.87      kent gus_set_params(
 1.95  christos     void *addr,
 1.96  christos     int setmode, int usemode,
 1.96  christos     audio_params_t *p, audio_params_t *r,
 1.95  christos     stream_filter_list_t *pfil, stream_filter_list_t *rfil)
 1.23  augustss {
 1.86      kent 	audio_params_t hw;
 1.87      kent 	struct gus_softc *sc;
 1.21   mycroft 	int s;
  1.1    brezak
 1.87      kent 	sc = addr;
 1.23  augustss 	switch (p->encoding) {
 1.21   mycroft 	case AUDIO_ENCODING_ULAW:
 1.39  augustss 	case AUDIO_ENCODING_ALAW:
 1.32  augustss 	case AUDIO_ENCODING_SLINEAR_LE:
 1.24  augustss 	case AUDIO_ENCODING_ULINEAR_LE:
 1.32  augustss 	case AUDIO_ENCODING_SLINEAR_BE:
 1.29       jtk 	case AUDIO_ENCODING_ULINEAR_BE:
 1.21   mycroft 		break;
 1.21   mycroft 	default:
 1.87      kent 		return EINVAL;
 1.21   mycroft 	}
  1.1    brezak
 1.21   mycroft 	s = splaudio();
  1.1    brezak
 1.23  augustss 	if (p->precision == 8) {
  1.1    brezak 		sc->sc_voc[GUS_VOICE_LEFT].voccntl &= ~GUSMASK_DATA_SIZE16;
  1.1    brezak 		sc->sc_voc[GUS_VOICE_RIGHT].voccntl &= ~GUSMASK_DATA_SIZE16;
  1.1    brezak 	} else {
  1.1    brezak 		sc->sc_voc[GUS_VOICE_LEFT].voccntl |= GUSMASK_DATA_SIZE16;
  1.1    brezak 		sc->sc_voc[GUS_VOICE_RIGHT].voccntl |= GUSMASK_DATA_SIZE16;
  1.1    brezak 	}
 1.21   mycroft
 1.23  augustss 	sc->sc_encoding = p->encoding;
 1.23  augustss 	sc->sc_precision = p->precision;
 1.27       jtk 	sc->sc_channels = p->channels;
 1.21   mycroft
 1.21   mycroft 	splx(s);
 1.21   mycroft
 1.28  augustss 	if (p->sample_rate > gus_max_frequency[sc->sc_voices - GUS_MIN_VOICES])
 1.28  augustss 		p->sample_rate = gus_max_frequency[sc->sc_voices - GUS_MIN_VOICES];
 1.41  augustss 	if (setmode & AUMODE_RECORD)
 1.28  augustss 		sc->sc_irate = p->sample_rate;
 1.41  augustss 	if (setmode & AUMODE_PLAY)
 1.28  augustss 		sc->sc_orate = p->sample_rate;
 1.28  augustss
 1.86      kent 	hw = *p;
 1.86      kent 	/* clear req_size before setting a filter to avoid confliction
 1.86      kent 	 * in gusmax_set_params() */
 1.29       jtk 	switch (p->encoding) {
 1.29       jtk 	case AUDIO_ENCODING_ULAW:
 1.86      kent 		hw.encoding = AUDIO_ENCODING_ULINEAR_LE;
 1.86      kent 		pfil->req_size = rfil->req_size = 0;
 1.86      kent 		pfil->append(pfil, mulaw_to_linear8, &hw);
 1.86      kent 		rfil->append(rfil, linear8_to_mulaw, &hw);
 1.29       jtk 		break;
 1.39  augustss 	case AUDIO_ENCODING_ALAW:
 1.86      kent 		hw.encoding = AUDIO_ENCODING_ULINEAR_LE;
 1.86      kent 		pfil->req_size = rfil->req_size = 0;
 1.86      kent 		pfil->append(pfil, alaw_to_linear8, &hw);
 1.86      kent 		rfil->append(rfil, linear8_to_alaw, &hw);
 1.39  augustss 		break;
 1.29       jtk 	case AUDIO_ENCODING_ULINEAR_BE:
 1.86      kent 		hw.encoding = AUDIO_ENCODING_ULINEAR_LE;
 1.86      kent 		pfil->req_size = rfil->req_size = 0;
 1.86      kent 		pfil->append(pfil, swap_bytes, &hw);
 1.86      kent 		rfil->append(rfil, swap_bytes, &hw);
 1.86      kent 		break;
 1.32  augustss 	case AUDIO_ENCODING_SLINEAR_BE:
 1.86      kent 		hw.encoding = AUDIO_ENCODING_SLINEAR_LE;
 1.86      kent 		pfil->req_size = rfil->req_size = 0;
 1.86      kent 		pfil->append(pfil, swap_bytes, &hw);
 1.86      kent 		rfil->append(rfil, swap_bytes, &hw);
 1.29       jtk 		break;
 1.29       jtk 	}
 1.28  augustss
  1.1    brezak 	return 0;
  1.1    brezak }
 1.28  augustss
  1.1    brezak /*
  1.1    brezak  * Interface to the audio layer - set the blocksize to the correct number
  1.1    brezak  * of units
  1.1    brezak  */
  1.1    brezak
  1.1    brezak int
 1.97  christos gusmax_round_blocksize(void *addr, int blocksize,
 1.87      kent 		       int mode, const audio_params_t *param)
  1.1    brezak {
 1.87      kent 	struct ad1848_isa_softc *ac;
 1.87      kent 	struct gus_softc *sc;
  1.1    brezak
 1.87      kent 	ac = addr;
 1.87      kent 	sc = ac->sc_ad1848.parent;
 1.86      kent /*	blocksize = ad1848_round_blocksize(ac, blocksize, mode, param);*/
 1.86      kent 	return gus_round_blocksize(sc, blocksize, mode, param);
  1.1    brezak }
  1.1    brezak
  1.1    brezak int
 1.97  christos gus_round_blocksize(void *addr, int blocksize,
 1.96  christos     int mode, const audio_params_t *param)
  1.1    brezak {
 1.87      kent 	struct gus_softc *sc;
  1.1    brezak
  1.1    brezak 	DPRINTF(("gus_round_blocksize called\n"));
 1.87      kent 	sc = addr;
  1.1    brezak
 1.39  augustss 	if ((sc->sc_encoding == AUDIO_ENCODING_ULAW ||
 1.39  augustss 	     sc->sc_encoding == AUDIO_ENCODING_ALAW) && blocksize > 32768)
  1.1    brezak 		blocksize = 32768;
  1.1    brezak 	else if (blocksize > 65536)
  1.1    brezak 		blocksize = 65536;
  1.1    brezak
  1.1    brezak 	if ((blocksize % GUS_BUFFER_MULTIPLE) != 0)
  1.1    brezak 		blocksize = (blocksize / GUS_BUFFER_MULTIPLE + 1) *
  1.1    brezak 			GUS_BUFFER_MULTIPLE;
  1.1    brezak
  1.1    brezak 	/* set up temporary buffer to hold the deinterleave, if necessary
  1.1    brezak 	   for stereo output */
  1.1    brezak 	if (sc->sc_deintr_buf) {
  1.1    brezak 		FREE(sc->sc_deintr_buf, M_DEVBUF);
  1.1    brezak 		sc->sc_deintr_buf = NULL;
  1.1    brezak 	}
 1.91  christos 	sc->sc_deintr_buf = malloc(blocksize>>1, M_DEVBUF, M_WAITOK);
  1.1    brezak
  1.1    brezak 	sc->sc_blocksize = blocksize;
  1.1    brezak 	/* multi-buffering not quite working yet. */
  1.1    brezak 	sc->sc_nbufs = /*GUS_MEM_FOR_BUFFERS / blocksize*/ 2;
  1.1    brezak
  1.1    brezak 	gus_set_chan_addrs(sc);
  1.1    brezak
  1.1    brezak 	return blocksize;
  1.1    brezak }
  1.1    brezak
  1.1    brezak int
 1.97  christos gus_get_out_gain(void *addr)
  1.1    brezak {
 1.87      kent 	struct gus_softc *sc;
  1.1    brezak
  1.1    brezak 	DPRINTF(("gus_get_out_gain called\n"));
 1.87      kent 	sc = (struct gus_softc *) addr;
  1.1    brezak 	return sc->sc_ogain / 2;
  1.1    brezak }
  1.1    brezak
 1.87      kent STATIC inline void
 1.87      kent gus_set_voices(struct gus_softc *sc, int voices)
  1.1    brezak {
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
 1.87      kent
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
  1.1    brezak 	/*
  1.1    brezak 	 * Select the active number of voices
  1.1    brezak 	 */
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_ACTIVE_VOICES);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, (voices-1) | 0xc0);
  1.1    brezak
  1.1    brezak 	sc->sc_voices = voices;
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Actually set the settings of various values on the card
  1.1    brezak  */
  1.1    brezak int
 1.97  christos gusmax_commit_settings(void *addr)
  1.1    brezak {
 1.87      kent 	struct ad1848_isa_softc *ac;
 1.87      kent 	struct gus_softc *sc;
 1.41  augustss 	int error;
  1.1    brezak
 1.87      kent 	ac = addr;
 1.87      kent 	sc = ac->sc_ad1848.parent;
 1.41  augustss 	error = ad1848_commit_settings(ac);
 1.41  augustss 	if (error)
 1.41  augustss 		return error;
  1.1    brezak 	return gus_commit_settings(sc);
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Commit the settings.  Called at normal IPL.
  1.1    brezak  */
  1.1    brezak int
 1.87      kent gus_commit_settings(void *addr)
  1.1    brezak {
 1.87      kent 	struct gus_softc *sc;
  1.1    brezak 	int s;
  1.1    brezak
 1.87      kent 	sc = addr;
  1.1    brezak 	DPRINTF(("gus_commit_settings called (gain = %d)\n",sc->sc_ogain));
  1.1    brezak
  1.1    brezak
  1.1    brezak 	s = splgus();
  1.1    brezak
  1.1    brezak 	gus_set_recrate(sc, sc->sc_irate);
  1.1    brezak 	gus_set_volume(sc, GUS_VOICE_LEFT, sc->sc_ogain);
  1.1    brezak 	gus_set_volume(sc, GUS_VOICE_RIGHT, sc->sc_ogain);
  1.1    brezak 	gus_set_samprate(sc, GUS_VOICE_LEFT, sc->sc_orate);
  1.1    brezak 	gus_set_samprate(sc, GUS_VOICE_RIGHT, sc->sc_orate);
  1.1    brezak 	splx(s);
  1.1    brezak 	gus_set_chan_addrs(sc);
  1.1    brezak
  1.1    brezak 	return 0;
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC void
 1.87      kent gus_set_chan_addrs(struct gus_softc *sc)
  1.1    brezak {
 1.87      kent
  1.1    brezak 	/*
  1.1    brezak 	 * We use sc_nbufs * blocksize bytes of storage in the on-board GUS
 1.88     perry 	 * ram.
  1.1    brezak 	 * For mono, each of the sc_nbufs buffers is DMA'd to in one chunk,
  1.1    brezak 	 * and both left & right channels play the same buffer.
  1.1    brezak 	 *
  1.1    brezak 	 * For stereo, each channel gets a contiguous half of the memory,
  1.1    brezak 	 * and each has sc_nbufs buffers of size blocksize/2.
  1.1    brezak 	 * Stereo data are deinterleaved in main memory before the DMA out
  1.1    brezak 	 * routines are called to queue the output.
  1.1    brezak 	 *
  1.1    brezak 	 * The blocksize per channel is kept in sc_chanblocksize.
  1.1    brezak 	 */
  1.1    brezak 	if (sc->sc_channels == 2)
  1.1    brezak 	    sc->sc_chanblocksize = sc->sc_blocksize/2;
  1.1    brezak 	else
  1.1    brezak 	    sc->sc_chanblocksize = sc->sc_blocksize;
  1.1    brezak
  1.1    brezak 	sc->sc_voc[GUS_VOICE_LEFT].start_addr = GUS_MEM_OFFSET - 1;
  1.1    brezak 	sc->sc_voc[GUS_VOICE_RIGHT].start_addr =
  1.1    brezak 	    (gus_dostereo && sc->sc_channels == 2 ? GUS_LEFT_RIGHT_OFFSET : 0)
  1.1    brezak 	      + GUS_MEM_OFFSET - 1;
  1.1    brezak 	sc->sc_voc[GUS_VOICE_RIGHT].current_addr =
  1.1    brezak 	    sc->sc_voc[GUS_VOICE_RIGHT].start_addr + 1;
  1.1    brezak 	sc->sc_voc[GUS_VOICE_RIGHT].end_addr =
  1.1    brezak 	    sc->sc_voc[GUS_VOICE_RIGHT].start_addr +
  1.1    brezak 	    sc->sc_nbufs * sc->sc_chanblocksize;
  1.1    brezak
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Set the sample rate of the given voice.  Called at splgus().
  1.1    brezak  */
  1.8       jtk STATIC void
 1.87      kent gus_set_samprate(struct gus_softc *sc, int voice, int freq)
  1.1    brezak {
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
  1.1    brezak 	unsigned int fc;
 1.87      kent 	u_long temp, f;
  1.1    brezak
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
 1.87      kent 	f = (u_long) freq;
  1.1    brezak 	/*
  1.1    brezak 	 * calculate fc based on the number of active voices;
  1.1    brezak 	 * we need to use longs to preserve enough bits
  1.1    brezak 	 */
  1.1    brezak
 1.14  christos 	temp = (u_long) gus_max_frequency[sc->sc_voices-GUS_MIN_VOICES];
  1.1    brezak
 1.87      kent 	fc = (unsigned int)(((f << 9L) + (temp >> 1L)) / temp);
 1.87      kent 	fc <<= 1;
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Program the voice frequency, and set it in the voice data record
  1.1    brezak 	 */
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_VOICE_SELECT, (unsigned char) voice);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_FREQ_CONTROL);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, fc);
  1.1    brezak
  1.1    brezak 	sc->sc_voc[voice].rate = freq;
  1.1    brezak
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Set the sample rate of the recording frequency.  Formula is from the GUS
  1.1    brezak  * SDK.  Called at splgus().
  1.1    brezak  */
  1.8       jtk STATIC void
 1.87      kent gus_set_recrate(struct gus_softc *sc, u_long rate)
  1.1    brezak {
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
  1.1    brezak 	u_char realrate;
 1.87      kent
  1.1    brezak 	DPRINTF(("gus_set_recrate %lu\n", rate));
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
  1.1    brezak
 1.14  christos #if 0
 1.14  christos 	realrate = 9878400/(16*(rate+2)); /* formula from GUS docs */
 1.14  christos #endif
  1.1    brezak 	realrate = (9878400 >> 4)/rate - 2; /* formula from code, sigh. */
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_SAMPLE_FREQ);
 1.87      kent 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, realrate);
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Interface to the audio layer - turn the output on or off.  Note that some
  1.1    brezak  * of these bits are flipped in the register
  1.1    brezak  */
  1.1    brezak
  1.1    brezak int
 1.87      kent gusmax_speaker_ctl(void *addr, int newstate)
  1.1    brezak {
 1.87      kent 	struct ad1848_isa_softc *sc;
 1.87      kent
 1.87      kent 	sc = addr;
 1.62       jtk 	return gus_speaker_ctl(sc->sc_ad1848.parent, newstate);
  1.1    brezak }
  1.1    brezak
  1.1    brezak int
 1.87      kent gus_speaker_ctl(void *addr, int newstate)
 1.87      kent {
 1.87      kent 	struct gus_softc *sc;
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh1;
  1.1    brezak
 1.87      kent 	sc = (struct gus_softc *) addr;
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh1 = sc->sc_ioh1;
  1.1    brezak 	/* Line out bit is flipped: 0 enables, 1 disables */
  1.1    brezak 	if ((newstate == SPKR_ON) &&
  1.1    brezak 	    (sc->sc_mixcontrol & GUSMASK_LINE_OUT)) {
  1.1    brezak 		sc->sc_mixcontrol &= ~GUSMASK_LINE_OUT;
 1.43  augustss 		bus_space_write_1(iot, ioh1, GUS_MIX_CONTROL, sc->sc_mixcontrol);
  1.1    brezak 	}
  1.1    brezak 	if ((newstate == SPKR_OFF) &&
  1.1    brezak 	    (sc->sc_mixcontrol & GUSMASK_LINE_OUT) == 0) {
  1.1    brezak 		sc->sc_mixcontrol |= GUSMASK_LINE_OUT;
 1.43  augustss 		bus_space_write_1(iot, ioh1, GUS_MIX_CONTROL, sc->sc_mixcontrol);
  1.1    brezak 	}
  1.1    brezak
  1.1    brezak 	return 0;
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC int
 1.87      kent gus_linein_ctl(void *addr, int newstate)
 1.87      kent {
 1.87      kent 	struct gus_softc *sc;
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh1;
  1.1    brezak
 1.87      kent 	sc = (struct gus_softc *) addr;
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh1 = sc->sc_ioh1;
  1.1    brezak 	/* Line in bit is flipped: 0 enables, 1 disables */
  1.1    brezak 	if ((newstate == SPKR_ON) &&
  1.1    brezak 	    (sc->sc_mixcontrol & GUSMASK_LINE_IN)) {
  1.1    brezak 		sc->sc_mixcontrol &= ~GUSMASK_LINE_IN;
 1.43  augustss 		bus_space_write_1(iot, ioh1, GUS_MIX_CONTROL, sc->sc_mixcontrol);
  1.1    brezak 	}
  1.1    brezak 	if ((newstate == SPKR_OFF) &&
  1.1    brezak 	    (sc->sc_mixcontrol & GUSMASK_LINE_IN) == 0) {
  1.1    brezak 		sc->sc_mixcontrol |= GUSMASK_LINE_IN;
 1.43  augustss 		bus_space_write_1(iot, ioh1, GUS_MIX_CONTROL, sc->sc_mixcontrol);
  1.1    brezak 	}
  1.1    brezak
  1.1    brezak 	return 0;
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC int
 1.87      kent gus_mic_ctl(void *addr, int newstate)
 1.87      kent {
 1.87      kent 	struct gus_softc *sc;
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh1;
  1.1    brezak
 1.87      kent 	sc = (struct gus_softc *) addr;
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh1 = sc->sc_ioh1;
  1.1    brezak 	/* Mic bit is normal: 1 enables, 0 disables */
  1.1    brezak 	if ((newstate == SPKR_ON) &&
  1.1    brezak 	    (sc->sc_mixcontrol & GUSMASK_MIC_IN) == 0) {
  1.1    brezak 		sc->sc_mixcontrol |= GUSMASK_MIC_IN;
 1.43  augustss 		bus_space_write_1(iot, ioh1, GUS_MIX_CONTROL, sc->sc_mixcontrol);
  1.1    brezak 	}
  1.1    brezak 	if ((newstate == SPKR_OFF) &&
  1.1    brezak 	    (sc->sc_mixcontrol & GUSMASK_MIC_IN)) {
  1.1    brezak 		sc->sc_mixcontrol &= ~GUSMASK_MIC_IN;
 1.43  augustss 		bus_space_write_1(iot, ioh1, GUS_MIX_CONTROL, sc->sc_mixcontrol);
  1.1    brezak 	}
  1.1    brezak
  1.1    brezak 	return 0;
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Set the end address of a give voice.  Called at splgus()
  1.1    brezak  */
  1.8       jtk STATIC void
 1.87      kent gus_set_endaddr(struct gus_softc *sc, int voice, u_long addr)
  1.1    brezak {
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
  1.1    brezak
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
  1.1    brezak 	sc->sc_voc[voice].end_addr = addr;
  1.1    brezak
  1.1    brezak 	if (sc->sc_voc[voice].voccntl & GUSMASK_DATA_SIZE16)
  1.1    brezak 		addr = convert_to_16bit(addr);
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_END_ADDR_HIGH);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, ADDR_HIGH(addr));
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_END_ADDR_LOW);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, ADDR_LOW(addr));
  1.1    brezak
  1.1    brezak }
  1.1    brezak
 1.15       jtk #ifdef GUSPLAYDEBUG
  1.1    brezak /*
  1.1    brezak  * Set current address.  called at splgus()
  1.1    brezak  */
  1.8       jtk STATIC void
 1.87      kent gus_set_curaddr(struct gus_softc *sc, int voice, u_long addr)
  1.1    brezak {
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
  1.1    brezak
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
  1.1    brezak 	sc->sc_voc[voice].current_addr = addr;
  1.1    brezak
  1.1    brezak 	if (sc->sc_voc[voice].voccntl & GUSMASK_DATA_SIZE16)
  1.1    brezak 		addr = convert_to_16bit(addr);
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_VOICE_SELECT, (unsigned char) voice);
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_CUR_ADDR_HIGH);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, ADDR_HIGH(addr));
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_CUR_ADDR_LOW);
 1.43  augustss 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, ADDR_LOW(addr));
  1.1    brezak
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Get current GUS playback address.  Called at splgus().
  1.1    brezak  */
 1.14  christos STATIC u_long
 1.87      kent gus_get_curaddr(struct gus_softc *sc, int voice)
  1.1    brezak {
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
 1.14  christos 	u_long addr;
  1.1    brezak
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_VOICE_SELECT, (unsigned char) voice);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_CUR_ADDR_HIGH|GUSREG_READ);
 1.43  augustss 	addr = (bus_space_read_2(iot, ioh2, GUS_DATA_LOW) & 0x1fff) << 7;
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_CUR_ADDR_LOW|GUSREG_READ);
 1.43  augustss 	addr |= (bus_space_read_2(iot, ioh2, GUS_DATA_LOW) >> 9L) & 0x7f;
  1.1    brezak
  1.1    brezak 	if (sc->sc_voc[voice].voccntl & GUSMASK_DATA_SIZE16)
  1.1    brezak 	    addr = (addr & 0xc0000) | ((addr & 0x1ffff) << 1); /* undo 16-bit change */
 1.33  augustss 	DPRINTF(("gus voice %d curaddr %ld end_addr %ld\n",
  1.1    brezak 		 voice, addr, sc->sc_voc[voice].end_addr));
  1.1    brezak 	/* XXX sanity check the address? */
  1.1    brezak
 1.87      kent 	return addr;
  1.1    brezak }
 1.14  christos #endif
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Convert an address value to a "16 bit" value - why this is necessary I
  1.1    brezak  * have NO idea
  1.1    brezak  */
  1.1    brezak
 1.14  christos STATIC u_long
 1.87      kent convert_to_16bit(u_long address)
  1.1    brezak {
 1.14  christos 	u_long old_address;
  1.1    brezak
  1.1    brezak 	old_address = address;
  1.1    brezak 	address >>= 1;
  1.1    brezak 	address &= 0x0001ffffL;
  1.1    brezak 	address |= (old_address & 0x000c0000L);
  1.1    brezak
 1.87      kent 	return address;
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Write a value into the GUS's DRAM
  1.1    brezak  */
  1.8       jtk STATIC void
 1.87      kent guspoke(bus_space_tag_t iot, bus_space_handle_t ioh2,
 1.87      kent 	long address, unsigned char value)
  1.1    brezak {
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Select the DRAM address
  1.1    brezak 	 */
  1.1    brezak
 1.87      kent 	SELECT_GUS_REG(iot, ioh2, GUSREG_DRAM_ADDR_LOW);
 1.87      kent 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, (unsigned int) (address & 0xffff));
 1.87      kent 	SELECT_GUS_REG(iot, ioh2, GUSREG_DRAM_ADDR_HIGH);
 1.87      kent 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, (unsigned char) ((address >> 16) & 0xff));
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Actually write the data
  1.1    brezak 	 */
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DRAM_DATA, value);
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Read a value from the GUS's DRAM
  1.1    brezak  */
  1.8       jtk STATIC unsigned char
 1.87      kent guspeek(bus_space_tag_t iot, bus_space_handle_t ioh2, u_long address)
  1.1    brezak {
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Select the DRAM address
  1.1    brezak 	 */
  1.1    brezak
 1.87      kent 	SELECT_GUS_REG(iot, ioh2, GUSREG_DRAM_ADDR_LOW);
 1.87      kent 	bus_space_write_2(iot, ioh2, GUS_DATA_LOW, (unsigned int) (address & 0xffff));
 1.87      kent 	SELECT_GUS_REG(iot, ioh2, GUSREG_DRAM_ADDR_HIGH);
 1.87      kent 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, (unsigned char) ((address >> 16) & 0xff));
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Read in the data from the board
  1.1    brezak 	 */
  1.1    brezak
 1.43  augustss 	return (unsigned char) bus_space_read_1(iot, ioh2, GUS_DRAM_DATA);
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Reset the Gravis UltraSound card, completely
  1.1    brezak  */
  1.8       jtk STATIC void
 1.87      kent gusreset(struct gus_softc *sc, int voices)
  1.1    brezak {
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh1;
 1.87      kent 	bus_space_handle_t ioh2;
 1.87      kent 	bus_space_handle_t ioh4;
  1.1    brezak 	int i,s;
  1.1    brezak
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh1 = sc->sc_ioh1;
 1.87      kent 	ioh2 = sc->sc_ioh2;
 1.87      kent 	ioh4 = sc->sc_ioh4;
  1.1    brezak 	s = splgus();
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Reset the GF1 chip
  1.1    brezak 	 */
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_RESET);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 0x00);
  1.1    brezak
  1.1    brezak 	delay(500);
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Release reset
  1.1    brezak 	 */
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_RESET);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, GUSMASK_MASTER_RESET);
  1.1    brezak
  1.1    brezak 	delay(500);
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Reset MIDI port as well
  1.1    brezak 	 */
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh4, GUS_MIDI_CONTROL, MIDI_RESET);
  1.1    brezak
  1.1    brezak 	delay(500);
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh4, GUS_MIDI_CONTROL, 0x00);
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Clear interrupts
  1.1    brezak 	 */
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_DMA_CONTROL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 0x00);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_TIMER_CONTROL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 0x00);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_SAMPLE_CONTROL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 0x00);
  1.1    brezak
  1.1    brezak 	gus_set_voices(sc, voices);
  1.1    brezak
 1.43  augustss 	bus_space_read_1(iot, ioh1, GUS_IRQ_STATUS);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_DMA_CONTROL);
 1.43  augustss 	bus_space_read_1(iot, ioh2, GUS_DATA_HIGH);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_SAMPLE_CONTROL);
 1.43  augustss 	bus_space_read_1(iot, ioh2, GUS_DATA_HIGH);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_IRQ_STATUS);
 1.43  augustss 	bus_space_read_1(iot, ioh2, GUS_DATA_HIGH);
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Reset voice specific information
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	for(i = 0; i < voices; i++) {
 1.43  augustss 		bus_space_write_1(iot, ioh2, GUS_VOICE_SELECT, (unsigned char) i);
  1.1    brezak
 1.43  augustss 		SELECT_GUS_REG(iot, ioh2, GUSREG_VOICE_CNTL);
  1.1    brezak
  1.1    brezak 		sc->sc_voc[i].voccntl = GUSMASK_VOICE_STOPPED |
  1.1    brezak 			GUSMASK_STOP_VOICE;
  1.1    brezak
 1.43  augustss 		bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, sc->sc_voc[i].voccntl);
  1.1    brezak
  1.1    brezak 		sc->sc_voc[i].volcntl = GUSMASK_VOLUME_STOPPED |
  1.1    brezak 				GUSMASK_STOP_VOLUME;
  1.1    brezak
 1.43  augustss 		SELECT_GUS_REG(iot, ioh2, GUSREG_VOLUME_CONTROL);
 1.43  augustss 		bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, sc->sc_voc[i].volcntl);
  1.1    brezak
  1.1    brezak 		delay(100);
  1.1    brezak
  1.1    brezak 		gus_set_samprate(sc, i, 8000);
 1.43  augustss 		SELECT_GUS_REG(iot, ioh2, GUSREG_START_ADDR_HIGH);
 1.43  augustss 		bus_space_write_2(iot, ioh2, GUS_DATA_LOW, 0x0000);
 1.43  augustss 		SELECT_GUS_REG(iot, ioh2, GUSREG_START_ADDR_LOW);
 1.43  augustss 		bus_space_write_2(iot, ioh2, GUS_DATA_LOW, 0x0000);
 1.43  augustss 		SELECT_GUS_REG(iot, ioh2, GUSREG_END_ADDR_HIGH);
 1.43  augustss 		bus_space_write_2(iot, ioh2, GUS_DATA_LOW, 0x0000);
 1.43  augustss 		SELECT_GUS_REG(iot, ioh2, GUSREG_END_ADDR_LOW);
 1.43  augustss 		bus_space_write_2(iot, ioh2, GUS_DATA_LOW, 0x0000);
 1.43  augustss 		SELECT_GUS_REG(iot, ioh2, GUSREG_VOLUME_RATE);
 1.43  augustss 		bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 0x01);
 1.43  augustss 		SELECT_GUS_REG(iot, ioh2, GUSREG_START_VOLUME);
 1.43  augustss 		bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 0x10);
 1.43  augustss 		SELECT_GUS_REG(iot, ioh2, GUSREG_END_VOLUME);
 1.43  augustss 		bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 0xe0);
 1.43  augustss 		SELECT_GUS_REG(iot, ioh2, GUSREG_CUR_VOLUME);
 1.43  augustss 		bus_space_write_2(iot, ioh2, GUS_DATA_LOW, 0x0000);
 1.43  augustss
 1.43  augustss 		SELECT_GUS_REG(iot, ioh2, GUSREG_CUR_ADDR_HIGH);
 1.43  augustss 		bus_space_write_2(iot, ioh2, GUS_DATA_LOW, 0x0000);
 1.43  augustss 		SELECT_GUS_REG(iot, ioh2, GUSREG_CUR_ADDR_LOW);
 1.43  augustss 		bus_space_write_2(iot, ioh2, GUS_DATA_LOW, 0x0000);
 1.43  augustss 		SELECT_GUS_REG(iot, ioh2, GUSREG_PAN_POS);
 1.43  augustss 		bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 0x07);
  1.1    brezak 	}
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Clear out any pending IRQs
  1.1    brezak 	 */
  1.1    brezak
 1.43  augustss 	bus_space_read_1(iot, ioh1, GUS_IRQ_STATUS);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_DMA_CONTROL);
 1.43  augustss 	bus_space_read_1(iot, ioh2, GUS_DATA_HIGH);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_SAMPLE_CONTROL);
 1.43  augustss 	bus_space_read_1(iot, ioh2, GUS_DATA_HIGH);
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_IRQ_STATUS);
 1.43  augustss 	bus_space_read_1(iot, ioh2, GUS_DATA_HIGH);
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_RESET);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, GUSMASK_MASTER_RESET | GUSMASK_DAC_ENABLE |
  1.1    brezak 		GUSMASK_IRQ_ENABLE);
  1.1    brezak
  1.1    brezak 	splx(s);
  1.1    brezak }
  1.1    brezak
  1.1    brezak
 1.51   mycroft STATIC int
 1.87      kent gus_init_cs4231(struct gus_softc *sc)
  1.1    brezak {
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh1;
 1.87      kent 	int port;
  1.1    brezak 	u_char ctrl;
  1.1    brezak
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh1 = sc->sc_ioh1;
 1.87      kent 	port = sc->sc_iobase;
  1.1    brezak 	ctrl = (port & 0xf0) >> 4;	/* set port address middle nibble */
  1.1    brezak 	/*
 1.80       wiz 	 * The codec is a bit weird--swapped DMA channels.
  1.1    brezak 	 */
  1.1    brezak 	ctrl |= GUS_MAX_CODEC_ENABLE;
 1.66   mycroft 	if (sc->sc_playdrq >= 4)
  1.1    brezak 		ctrl |= GUS_MAX_RECCHAN16;
  1.1    brezak 	if (sc->sc_recdrq >= 4)
  1.1    brezak 		ctrl |= GUS_MAX_PLAYCHAN16;
  1.1    brezak
 1.43  augustss 	bus_space_write_1(iot, ioh1, GUS_MAX_CTRL, ctrl);
  1.1    brezak
 1.60        pk 	sc->sc_codec.sc_ad1848.sc_iot = sc->sc_iot;
  1.1    brezak 	sc->sc_codec.sc_iobase = port+GUS_MAX_CODEC_BASE;
  1.1    brezak
 1.60        pk 	if (ad1848_isa_mapprobe(&sc->sc_codec, sc->sc_codec.sc_iobase) == 0) {
  1.1    brezak 		sc->sc_flags &= ~GUS_CODEC_INSTALLED;
 1.87      kent 		return 0;
  1.1    brezak 	} else {
  1.1    brezak 		struct ad1848_volume vol = {AUDIO_MAX_GAIN, AUDIO_MAX_GAIN};
  1.1    brezak 		sc->sc_flags |= GUS_CODEC_INSTALLED;
 1.60        pk 		sc->sc_codec.sc_ad1848.parent = sc;
 1.66   mycroft 		sc->sc_codec.sc_playdrq = sc->sc_recdrq;
 1.68   thorpej 		sc->sc_codec.sc_play_maxsize = sc->sc_req_maxsize;
 1.66   mycroft 		sc->sc_codec.sc_recdrq = sc->sc_playdrq;
 1.68   thorpej 		sc->sc_codec.sc_rec_maxsize = sc->sc_play_maxsize;
  1.1    brezak 		/* enable line in and mic in the GUS mixer; the codec chip
  1.1    brezak 		   will do the real mixing for them. */
  1.1    brezak 		sc->sc_mixcontrol &= ~GUSMASK_LINE_IN; /* 0 enables. */
  1.1    brezak 		sc->sc_mixcontrol |= GUSMASK_MIC_IN; /* 1 enables. */
 1.43  augustss 		bus_space_write_1(iot, ioh1, GUS_MIX_CONTROL, sc->sc_mixcontrol);
 1.87      kent
 1.61       jtk 		ad1848_isa_attach(&sc->sc_codec);
  1.1    brezak 		/* turn on pre-MUX microphone gain. */
 1.60        pk 		ad1848_set_mic_gain(&sc->sc_codec.sc_ad1848, &vol);
 1.51   mycroft
 1.87      kent 		return 1;
  1.1    brezak 	}
  1.1    brezak }
  1.1    brezak
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Return info about the audio device, for the AUDIO_GETINFO ioctl
  1.1    brezak  */
  1.1    brezak int
 1.96  christos gus_getdev(void *addr, struct audio_device *dev)
  1.1    brezak {
 1.87      kent
  1.1    brezak 	*dev = gus_device;
  1.1    brezak 	return 0;
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * stubs (XXX)
  1.1    brezak  */
  1.1    brezak
  1.1    brezak int
 1.97  christos gus_set_in_gain(void *addr, u_int gain,
 1.96  christos     u_char balance)
  1.1    brezak {
 1.87      kent
  1.1    brezak 	DPRINTF(("gus_set_in_gain called\n"));
  1.1    brezak 	return 0;
  1.1    brezak }
  1.1    brezak
  1.1    brezak int
 1.97  christos gus_get_in_gain(void *addr)
  1.1    brezak {
 1.87      kent
  1.1    brezak 	DPRINTF(("gus_get_in_gain called\n"));
  1.1    brezak 	return 0;
  1.1    brezak }
  1.1    brezak
  1.1    brezak int
 1.89  christos gusmax_dma_input(void *addr, void *tbuf, int size,
 1.87      kent 		 void (*callback)(void *), void *arg)
  1.1    brezak {
 1.87      kent 	struct ad1848_isa_softc *sc;
 1.87      kent
 1.87      kent 	sc = addr;
 1.89  christos 	return gus_dma_input(sc->sc_ad1848.parent, tbuf, size, callback, arg);
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Start sampling the input source into the requested DMA buffer.
  1.1    brezak  * Called at splgus(), either from top-half or from interrupt handler.
  1.1    brezak  */
  1.1    brezak int
 1.89  christos gus_dma_input(void *addr, void *tbuf, int size,
 1.87      kent 	      void (*callback)(void *), void *arg)
  1.1    brezak {
 1.87      kent 	struct gus_softc *sc;
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
 1.38  augustss 	u_char dmac;
 1.87      kent
  1.1    brezak 	DMAPRINTF(("gus_dma_input called\n"));
 1.87      kent 	sc = addr;
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
 1.87      kent
  1.1    brezak 	/*
  1.1    brezak 	 * Sample SIZE bytes of data from the card, into buffer at BUF.
  1.1    brezak 	 */
  1.1    brezak
  1.1    brezak 	if (sc->sc_precision == 16)
 1.87      kent 		return EINVAL;		/* XXX */
  1.1    brezak
  1.1    brezak 	/* set DMA modes */
  1.1    brezak 	dmac = GUSMASK_SAMPLE_IRQ|GUSMASK_SAMPLE_START;
  1.1    brezak 	if (sc->sc_recdrq >= 4)
  1.1    brezak 		dmac |= GUSMASK_SAMPLE_DATA16;
  1.1    brezak 	if (sc->sc_encoding == AUDIO_ENCODING_ULAW ||
 1.87      kent 	    sc->sc_encoding == AUDIO_ENCODING_ALAW ||
 1.87      kent 	    sc->sc_encoding == AUDIO_ENCODING_ULINEAR_LE ||
 1.87      kent 	    sc->sc_encoding == AUDIO_ENCODING_ULINEAR_BE)
 1.87      kent 		dmac |= GUSMASK_SAMPLE_INVBIT;
  1.1    brezak 	if (sc->sc_channels == 2)
 1.87      kent 		dmac |= GUSMASK_SAMPLE_STEREO;
 1.89  christos 	isa_dmastart(sc->sc_ic, sc->sc_recdrq, tbuf, size,
 1.87      kent 	    NULL, DMAMODE_READ, BUS_DMA_NOWAIT);
  1.1    brezak
  1.1    brezak 	DMAPRINTF(("gus_dma_input isa_dmastarted\n"));
  1.1    brezak 	sc->sc_flags |= GUS_DMAIN_ACTIVE;
  1.1    brezak 	sc->sc_dmainintr = callback;
  1.1    brezak 	sc->sc_inarg = arg;
  1.1    brezak 	sc->sc_dmaincnt = size;
 1.89  christos 	sc->sc_dmainaddr = tbuf;
  1.1    brezak
 1.43  augustss 	SELECT_GUS_REG(iot, ioh2, GUSREG_SAMPLE_CONTROL);
 1.43  augustss 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, dmac);	/* Go! */
  1.1    brezak
  1.1    brezak
  1.1    brezak 	DMAPRINTF(("gus_dma_input returning\n"));
  1.1    brezak
  1.1    brezak 	return 0;
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC int
 1.87      kent gus_dmain_intr(struct gus_softc *sc)
  1.1    brezak {
 1.87      kent 	void (*callback)(void *);
  1.1    brezak 	void *arg;
  1.1    brezak
  1.1    brezak 	DMAPRINTF(("gus_dmain_intr called\n"));
  1.1    brezak 	if (sc->sc_dmainintr) {
 1.87      kent 		isa_dmadone(sc->sc_ic, sc->sc_recdrq);
 1.87      kent 		callback = sc->sc_dmainintr;
 1.87      kent 		arg = sc->sc_inarg;
 1.87      kent
 1.87      kent 		sc->sc_dmainaddr = 0;
 1.87      kent 		sc->sc_dmaincnt = 0;
 1.87      kent 		sc->sc_dmainintr = 0;
 1.87      kent 		sc->sc_inarg = 0;
 1.87      kent
 1.87      kent 		sc->sc_flags &= ~GUS_DMAIN_ACTIVE;
 1.87      kent 		DMAPRINTF(("calling dmain_intr callback %p(%p)\n", callback, arg));
 1.87      kent 		(*callback)(arg);
 1.87      kent 		return 1;
  1.1    brezak 	} else {
 1.87      kent 		DMAPRINTF(("gus_dmain_intr false?\n"));
 1.87      kent 		return 0;			/* XXX ??? */
  1.1    brezak 	}
  1.1    brezak }
  1.1    brezak
  1.1    brezak int
 1.87      kent gusmax_halt_out_dma(void *addr)
  1.1    brezak {
 1.87      kent 	struct ad1848_isa_softc *sc;
 1.87      kent
 1.87      kent 	sc = addr;
 1.62       jtk 	return gus_halt_out_dma(sc->sc_ad1848.parent);
  1.1    brezak }
  1.1    brezak
  1.1    brezak
  1.1    brezak int
 1.87      kent gusmax_halt_in_dma(void *addr)
  1.1    brezak {
 1.87      kent 	struct ad1848_isa_softc *sc;
 1.87      kent
 1.87      kent 	sc = addr;
 1.62       jtk 	return gus_halt_in_dma(sc->sc_ad1848.parent);
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Stop any DMA output.  Called at splgus().
  1.1    brezak  */
  1.1    brezak int
 1.87      kent gus_halt_out_dma(void *addr)
  1.1    brezak {
 1.87      kent 	struct gus_softc *sc;
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
  1.1    brezak
  1.1    brezak 	DMAPRINTF(("gus_halt_out_dma called\n"));
 1.87      kent 	sc = addr;
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
  1.1    brezak 	/*
  1.1    brezak 	 * Make sure the GUS _isn't_ setup for DMA
  1.1    brezak 	 */
  1.1    brezak
 1.87      kent 	SELECT_GUS_REG(iot, ioh2, GUSREG_DMA_CONTROL);
 1.87      kent 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH, 0);
  1.1    brezak
 1.69   thorpej 	callout_stop(&sc->sc_dmaout_ch);
 1.87      kent 	isa_dmaabort(sc->sc_ic, sc->sc_playdrq);
  1.1    brezak 	sc->sc_flags &= ~(GUS_DMAOUT_ACTIVE|GUS_LOCKED);
  1.1    brezak 	sc->sc_dmaoutintr = 0;
  1.1    brezak 	sc->sc_outarg = 0;
  1.1    brezak 	sc->sc_dmaoutaddr = 0;
  1.1    brezak 	sc->sc_dmaoutcnt = 0;
  1.1    brezak 	sc->sc_dmabuf = 0;
  1.1    brezak 	sc->sc_bufcnt = 0;
  1.1    brezak 	sc->sc_playbuf = -1;
  1.1    brezak 	/* also stop playing */
  1.1    brezak 	gus_stop_voice(sc, GUS_VOICE_LEFT, 1);
  1.1    brezak 	gus_stop_voice(sc, GUS_VOICE_RIGHT, 0);
  1.1    brezak
  1.1    brezak 	return 0;
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Stop any DMA output.  Called at splgus().
  1.1    brezak  */
  1.1    brezak int
 1.87      kent gus_halt_in_dma(void *addr)
  1.1    brezak {
 1.87      kent 	struct gus_softc *sc;
 1.87      kent 	bus_space_tag_t iot;
 1.87      kent 	bus_space_handle_t ioh2;
 1.87      kent
  1.1    brezak 	DMAPRINTF(("gus_halt_in_dma called\n"));
 1.87      kent 	sc = addr;
 1.87      kent 	iot = sc->sc_iot;
 1.87      kent 	ioh2 = sc->sc_ioh2;
  1.1    brezak
  1.1    brezak 	/*
  1.1    brezak 	 * Make sure the GUS _isn't_ setup for DMA
  1.1    brezak 	 */
  1.1    brezak
 1.87      kent 	SELECT_GUS_REG(iot, ioh2, GUSREG_SAMPLE_CONTROL);
 1.87      kent 	bus_space_write_1(iot, ioh2, GUS_DATA_HIGH,
 1.87      kent 	    bus_space_read_1(iot, ioh2, GUS_DATA_HIGH)
 1.87      kent 	    & ~(GUSMASK_SAMPLE_START|GUSMASK_SAMPLE_IRQ));
 1.87      kent
 1.87      kent 	isa_dmaabort(sc->sc_ic, sc->sc_recdrq);
  1.1    brezak 	sc->sc_flags &= ~GUS_DMAIN_ACTIVE;
  1.1    brezak 	sc->sc_dmainintr = 0;
  1.1    brezak 	sc->sc_inarg = 0;
  1.1    brezak 	sc->sc_dmainaddr = 0;
  1.1    brezak 	sc->sc_dmaincnt = 0;
  1.1    brezak
  1.1    brezak 	return 0;
  1.1    brezak }
  1.1    brezak
  1.1    brezak
 1.54  augustss static ad1848_devmap_t gusmapping[] = {
 1.58   mycroft 	{ GUSMAX_DAC_LVL, AD1848_KIND_LVL, AD1848_AUX1_CHANNEL },
 1.58   mycroft 	{ GUSMAX_LINE_IN_LVL, AD1848_KIND_LVL, AD1848_LINE_CHANNEL },
 1.58   mycroft 	{ GUSMAX_MONO_LVL, AD1848_KIND_LVL, AD1848_MONO_CHANNEL },
 1.58   mycroft 	{ GUSMAX_CD_LVL, AD1848_KIND_LVL, AD1848_AUX2_CHANNEL },
 1.58   mycroft 	{ GUSMAX_MONITOR_LVL, AD1848_KIND_LVL, AD1848_MONITOR_CHANNEL },
 1.58   mycroft 	{ GUSMAX_OUT_LVL, AD1848_KIND_LVL, AD1848_DAC_CHANNEL },
 1.58   mycroft 	{ GUSMAX_DAC_MUTE, AD1848_KIND_MUTE, AD1848_AUX1_CHANNEL },
 1.58   mycroft 	{ GUSMAX_LINE_IN_MUTE, AD1848_KIND_MUTE, AD1848_LINE_CHANNEL },
 1.58   mycroft 	{ GUSMAX_MONO_MUTE, AD1848_KIND_MUTE, AD1848_MONO_CHANNEL },
 1.58   mycroft 	{ GUSMAX_CD_MUTE, AD1848_KIND_MUTE, AD1848_AUX2_CHANNEL },
 1.58   mycroft 	{ GUSMAX_MONITOR_MUTE, AD1848_KIND_MUTE, AD1848_MONITOR_CHANNEL },
 1.58   mycroft 	{ GUSMAX_REC_LVL, AD1848_KIND_RECORDGAIN, -1 },
 1.58   mycroft 	{ GUSMAX_RECORD_SOURCE, AD1848_KIND_RECORDSOURCE, -1 }
 1.54  augustss };
 1.54  augustss
 1.54  augustss static int nummap = sizeof(gusmapping) / sizeof(gusmapping[0]);
  1.1    brezak
  1.8       jtk STATIC int
 1.87      kent gusmax_mixer_get_port(void *addr, mixer_ctrl_t *cp)
  1.1    brezak {
 1.87      kent 	struct ad1848_isa_softc *ac;
 1.87      kent 	struct gus_softc *sc;
  1.1    brezak 	struct ad1848_volume vol;
 1.87      kent 	int error;
 1.87      kent
 1.87      kent 	ac = addr;
 1.87      kent 	sc = ac->sc_ad1848.parent;
 1.87      kent 	error = ad1848_mixer_get_port(&ac->sc_ad1848, gusmapping, nummap, cp);
 1.54  augustss 	if (error != ENXIO)
 1.87      kent 		return error;
 1.54  augustss
 1.54  augustss 	error = EINVAL;
  1.1    brezak
  1.1    brezak 	switch (cp->dev) {
  1.1    brezak 	case GUSMAX_SPEAKER_LVL:	/* fake speaker for mute naming */
  1.1    brezak 		if (cp->type == AUDIO_MIXER_VALUE) {
  1.1    brezak 			if (sc->sc_mixcontrol & GUSMASK_LINE_OUT)
  1.1    brezak 				vol.left = vol.right = AUDIO_MAX_GAIN;
  1.1    brezak 			else
  1.1    brezak 				vol.left = vol.right = AUDIO_MIN_GAIN;
  1.1    brezak 			error = 0;
 1.54  augustss 			ad1848_from_vol(cp, &vol);
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSMAX_SPEAKER_MUTE:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_ENUM) {
  1.1    brezak 			cp->un.ord = sc->sc_mixcontrol & GUSMASK_LINE_OUT ? 1 : 0;
  1.1    brezak 			error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak 	default:
  1.1    brezak 		error = ENXIO;
  1.1    brezak 		break;
  1.1    brezak 	}
  1.1    brezak
 1.87      kent 	return error;
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC int
 1.87      kent gus_mixer_get_port(void *addr, mixer_ctrl_t *cp)
  1.1    brezak {
 1.87      kent 	struct gus_softc *sc;
 1.87      kent 	struct ics2101_softc *ic;
  1.1    brezak 	struct ad1848_volume vol;
 1.87      kent 	int error;
  1.1    brezak
  1.1    brezak 	DPRINTF(("gus_mixer_get_port: dev=%d type=%d\n", cp->dev, cp->type));
 1.87      kent 	sc = addr;
 1.87      kent 	ic = &sc->sc_mixer;
 1.87      kent 	error = EINVAL;
  1.1    brezak
  1.1    brezak 	if (!HAS_MIXER(sc) && cp->dev > GUSICS_MASTER_MUTE)
  1.1    brezak 		return ENXIO;
 1.87      kent
  1.1    brezak 	switch (cp->dev) {
  1.1    brezak
  1.1    brezak 	case GUSICS_MIC_IN_MUTE:	/* Microphone */
  1.1    brezak 		if (cp->type == AUDIO_MIXER_ENUM) {
  1.1    brezak 			if (HAS_MIXER(sc))
  1.1    brezak 				cp->un.ord = ic->sc_mute[GUSMIX_CHAN_MIC][ICSMIX_LEFT];
  1.1    brezak 			else
  1.1    brezak 				cp->un.ord =
  1.1    brezak 				    sc->sc_mixcontrol & GUSMASK_MIC_IN ? 0 : 1;
  1.1    brezak 			error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_LINE_IN_MUTE:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_ENUM) {
  1.1    brezak 			if (HAS_MIXER(sc))
  1.1    brezak 				cp->un.ord = ic->sc_mute[GUSMIX_CHAN_LINE][ICSMIX_LEFT];
  1.1    brezak 			else
  1.1    brezak 				cp->un.ord =
  1.1    brezak 				    sc->sc_mixcontrol & GUSMASK_LINE_IN ? 1 : 0;
  1.1    brezak 			error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_MASTER_MUTE:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_ENUM) {
  1.1    brezak 			if (HAS_MIXER(sc))
  1.1    brezak 				cp->un.ord = ic->sc_mute[GUSMIX_CHAN_MASTER][ICSMIX_LEFT];
  1.1    brezak 			else
  1.1    brezak 				cp->un.ord =
  1.1    brezak 				    sc->sc_mixcontrol & GUSMASK_LINE_OUT ? 1 : 0;
  1.1    brezak 			error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_DAC_MUTE:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_ENUM) {
  1.1    brezak 			cp->un.ord = ic->sc_mute[GUSMIX_CHAN_DAC][ICSMIX_LEFT];
  1.1    brezak 			error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_CD_MUTE:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_ENUM) {
  1.1    brezak 			cp->un.ord = ic->sc_mute[GUSMIX_CHAN_CD][ICSMIX_LEFT];
  1.1    brezak 			error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_MASTER_LVL:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_VALUE) {
  1.1    brezak 			vol.left = ic->sc_setting[GUSMIX_CHAN_MASTER][ICSMIX_LEFT];
  1.1    brezak 			vol.right = ic->sc_setting[GUSMIX_CHAN_MASTER][ICSMIX_RIGHT];
 1.54  augustss 			if (ad1848_from_vol(cp, &vol))
  1.1    brezak 				error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_MIC_IN_LVL:	/* Microphone */
  1.1    brezak 		if (cp->type == AUDIO_MIXER_VALUE) {
  1.1    brezak 			vol.left = ic->sc_setting[GUSMIX_CHAN_MIC][ICSMIX_LEFT];
  1.1    brezak 			vol.right = ic->sc_setting[GUSMIX_CHAN_MIC][ICSMIX_RIGHT];
 1.54  augustss 			if (ad1848_from_vol(cp, &vol))
  1.1    brezak 				error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
 1.87      kent
  1.1    brezak 	case GUSICS_LINE_IN_LVL:	/* line in */
  1.1    brezak 		if (cp->type == AUDIO_MIXER_VALUE) {
  1.1    brezak 			vol.left = ic->sc_setting[GUSMIX_CHAN_LINE][ICSMIX_LEFT];
  1.1    brezak 			vol.right = ic->sc_setting[GUSMIX_CHAN_LINE][ICSMIX_RIGHT];
 1.54  augustss 			if (ad1848_from_vol(cp, &vol))
  1.1    brezak 				error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak
  1.1    brezak 	case GUSICS_CD_LVL:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_VALUE) {
  1.1    brezak 			vol.left = ic->sc_setting[GUSMIX_CHAN_CD][ICSMIX_LEFT];
  1.1    brezak 			vol.right = ic->sc_setting[GUSMIX_CHAN_CD][ICSMIX_RIGHT];
 1.54  augustss 			if (ad1848_from_vol(cp, &vol))
  1.1    brezak 				error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_DAC_LVL:		/* dac out */
  1.1    brezak 		if (cp->type == AUDIO_MIXER_VALUE) {
  1.1    brezak 			vol.left = ic->sc_setting[GUSMIX_CHAN_DAC][ICSMIX_LEFT];
  1.1    brezak 			vol.right = ic->sc_setting[GUSMIX_CHAN_DAC][ICSMIX_RIGHT];
 1.54  augustss 			if (ad1848_from_vol(cp, &vol))
  1.1    brezak 				error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak
  1.1    brezak 	case GUSICS_RECORD_SOURCE:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_ENUM) {
  1.1    brezak 			/* Can't set anything else useful, sigh. */
  1.1    brezak 			 cp->un.ord = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	default:
  1.1    brezak 		return ENXIO;
 1.87      kent 		/*NOTREACHED*/
  1.1    brezak 	}
  1.1    brezak 	return error;
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC void
 1.87      kent gusics_master_mute(struct ics2101_softc *ic, int mute)
  1.1    brezak {
 1.87      kent
  1.1    brezak 	ics2101_mix_mute(ic, GUSMIX_CHAN_MASTER, ICSMIX_LEFT, mute);
  1.1    brezak 	ics2101_mix_mute(ic, GUSMIX_CHAN_MASTER, ICSMIX_RIGHT, mute);
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC void
 1.87      kent gusics_mic_mute(struct ics2101_softc *ic, int mute)
  1.1    brezak {
 1.87      kent
  1.1    brezak 	ics2101_mix_mute(ic, GUSMIX_CHAN_MIC, ICSMIX_LEFT, mute);
  1.1    brezak 	ics2101_mix_mute(ic, GUSMIX_CHAN_MIC, ICSMIX_RIGHT, mute);
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC void
 1.87      kent gusics_linein_mute(struct ics2101_softc *ic, int mute)
  1.1    brezak {
 1.87      kent
  1.1    brezak 	ics2101_mix_mute(ic, GUSMIX_CHAN_LINE, ICSMIX_LEFT, mute);
  1.1    brezak 	ics2101_mix_mute(ic, GUSMIX_CHAN_LINE, ICSMIX_RIGHT, mute);
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC void
 1.87      kent gusics_cd_mute(struct ics2101_softc *ic, int mute)
  1.1    brezak {
 1.87      kent
  1.1    brezak 	ics2101_mix_mute(ic, GUSMIX_CHAN_CD, ICSMIX_LEFT, mute);
  1.1    brezak 	ics2101_mix_mute(ic, GUSMIX_CHAN_CD, ICSMIX_RIGHT, mute);
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC void
 1.87      kent gusics_dac_mute(struct ics2101_softc *ic, int mute)
  1.1    brezak {
 1.87      kent
  1.1    brezak 	ics2101_mix_mute(ic, GUSMIX_CHAN_DAC, ICSMIX_LEFT, mute);
  1.1    brezak 	ics2101_mix_mute(ic, GUSMIX_CHAN_DAC, ICSMIX_RIGHT, mute);
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC int
 1.87      kent gusmax_mixer_set_port(void *addr, mixer_ctrl_t *cp)
  1.1    brezak {
 1.87      kent 	struct ad1848_isa_softc *ac;
 1.87      kent 	struct gus_softc *sc;
  1.1    brezak 	struct ad1848_volume vol;
 1.87      kent 	int error;
 1.87      kent
 1.87      kent 	ac = addr;
 1.87      kent 	sc = ac->sc_ad1848.parent;
 1.87      kent 	error = ad1848_mixer_set_port(&ac->sc_ad1848, gusmapping, nummap, cp);
 1.54  augustss 	if (error != ENXIO)
 1.87      kent 		return error;
 1.54  augustss
  1.1    brezak 	DPRINTF(("gusmax_mixer_set_port: dev=%d type=%d\n", cp->dev, cp->type));
  1.1    brezak
  1.1    brezak 	switch (cp->dev) {
  1.1    brezak 	case GUSMAX_SPEAKER_LVL:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_VALUE &&
  1.1    brezak 		    cp->un.value.num_channels == 1) {
 1.54  augustss 			if (ad1848_to_vol(cp, &vol)) {
  1.1    brezak 				gus_speaker_ctl(sc, vol.left > AUDIO_MIN_GAIN ?
  1.1    brezak 						SPKR_ON : SPKR_OFF);
  1.1    brezak 				error = 0;
  1.1    brezak 			}
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSMAX_SPEAKER_MUTE:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_ENUM) {
  1.1    brezak 			gus_speaker_ctl(sc, cp->un.ord ? SPKR_OFF : SPKR_ON);
  1.1    brezak 			error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	default:
  1.1    brezak 		return ENXIO;
 1.87      kent 		/*NOTREACHED*/
 1.87      kent 	}
 1.87      kent 	return error;
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC int
 1.87      kent gus_mixer_set_port(void *addr, mixer_ctrl_t *cp)
  1.1    brezak {
 1.87      kent 	struct gus_softc *sc;
 1.87      kent 	struct ics2101_softc *ic;
  1.1    brezak 	struct ad1848_volume vol;
 1.87      kent 	int error;
  1.1    brezak
  1.1    brezak 	DPRINTF(("gus_mixer_set_port: dev=%d type=%d\n", cp->dev, cp->type));
 1.87      kent 	sc = addr;
 1.87      kent 	ic = &sc->sc_mixer;
 1.87      kent 	error = EINVAL;
  1.1    brezak
  1.1    brezak 	if (!HAS_MIXER(sc) && cp->dev > GUSICS_MASTER_MUTE)
  1.1    brezak 		return ENXIO;
 1.87      kent
  1.1    brezak 	switch (cp->dev) {
  1.1    brezak
  1.1    brezak 	case GUSICS_MIC_IN_MUTE:	/* Microphone */
  1.1    brezak 		if (cp->type == AUDIO_MIXER_ENUM) {
  1.1    brezak 			DPRINTF(("mic mute %d\n", cp->un.ord));
  1.1    brezak 			if (HAS_MIXER(sc)) {
  1.1    brezak 				gusics_mic_mute(ic, cp->un.ord);
  1.1    brezak 			}
  1.1    brezak 			gus_mic_ctl(sc, cp->un.ord ? SPKR_OFF : SPKR_ON);
  1.1    brezak 			error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_LINE_IN_MUTE:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_ENUM) {
  1.1    brezak 			DPRINTF(("linein mute %d\n", cp->un.ord));
  1.1    brezak 			if (HAS_MIXER(sc)) {
  1.1    brezak 				gusics_linein_mute(ic, cp->un.ord);
  1.1    brezak 			}
  1.1    brezak 			gus_linein_ctl(sc, cp->un.ord ? SPKR_OFF : SPKR_ON);
  1.1    brezak 			error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_MASTER_MUTE:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_ENUM) {
  1.1    brezak 			DPRINTF(("master mute %d\n", cp->un.ord));
  1.1    brezak 			if (HAS_MIXER(sc)) {
  1.1    brezak 				gusics_master_mute(ic, cp->un.ord);
  1.1    brezak 			}
  1.1    brezak 			gus_speaker_ctl(sc, cp->un.ord ? SPKR_OFF : SPKR_ON);
  1.1    brezak 			error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_DAC_MUTE:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_ENUM) {
  1.1    brezak 			gusics_dac_mute(ic, cp->un.ord);
  1.1    brezak 			error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_CD_MUTE:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_ENUM) {
  1.1    brezak 			gusics_cd_mute(ic, cp->un.ord);
  1.1    brezak 			error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_MASTER_LVL:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_VALUE) {
 1.54  augustss 			if (ad1848_to_vol(cp, &vol)) {
  1.1    brezak 				ics2101_mix_attenuate(ic,
  1.1    brezak 						      GUSMIX_CHAN_MASTER,
  1.1    brezak 						      ICSMIX_LEFT,
  1.1    brezak 						      vol.left);
  1.1    brezak 				ics2101_mix_attenuate(ic,
  1.1    brezak 						      GUSMIX_CHAN_MASTER,
  1.1    brezak 						      ICSMIX_RIGHT,
  1.1    brezak 						      vol.right);
  1.1    brezak 				error = 0;
  1.1    brezak 			}
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_MIC_IN_LVL:	/* Microphone */
  1.1    brezak 		if (cp->type == AUDIO_MIXER_VALUE) {
 1.54  augustss 			if (ad1848_to_vol(cp, &vol)) {
  1.1    brezak 				ics2101_mix_attenuate(ic,
  1.1    brezak 						      GUSMIX_CHAN_MIC,
  1.1    brezak 						      ICSMIX_LEFT,
  1.1    brezak 						      vol.left);
  1.1    brezak 				ics2101_mix_attenuate(ic,
  1.1    brezak 						      GUSMIX_CHAN_MIC,
  1.1    brezak 						      ICSMIX_RIGHT,
  1.1    brezak 						      vol.right);
  1.1    brezak 				error = 0;
  1.1    brezak 			}
  1.1    brezak 		}
  1.1    brezak 		break;
 1.87      kent
  1.1    brezak 	case GUSICS_LINE_IN_LVL:	/* line in */
  1.1    brezak 		if (cp->type == AUDIO_MIXER_VALUE) {
 1.54  augustss 			if (ad1848_to_vol(cp, &vol)) {
  1.1    brezak 				ics2101_mix_attenuate(ic,
  1.1    brezak 						      GUSMIX_CHAN_LINE,
  1.1    brezak 						      ICSMIX_LEFT,
  1.1    brezak 						      vol.left);
  1.1    brezak 				ics2101_mix_attenuate(ic,
  1.1    brezak 						      GUSMIX_CHAN_LINE,
  1.1    brezak 						      ICSMIX_RIGHT,
  1.1    brezak 						      vol.right);
  1.1    brezak 				error = 0;
  1.1    brezak 			}
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak
  1.1    brezak 	case GUSICS_CD_LVL:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_VALUE) {
 1.54  augustss 			if (ad1848_to_vol(cp, &vol)) {
  1.1    brezak 				ics2101_mix_attenuate(ic,
  1.1    brezak 						      GUSMIX_CHAN_CD,
  1.1    brezak 						      ICSMIX_LEFT,
  1.1    brezak 						      vol.left);
  1.1    brezak 				ics2101_mix_attenuate(ic,
  1.1    brezak 						      GUSMIX_CHAN_CD,
  1.1    brezak 						      ICSMIX_RIGHT,
  1.1    brezak 						      vol.right);
  1.1    brezak 				error = 0;
  1.1    brezak 			}
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_DAC_LVL:		/* dac out */
  1.1    brezak 		if (cp->type == AUDIO_MIXER_VALUE) {
 1.54  augustss 			if (ad1848_to_vol(cp, &vol)) {
  1.1    brezak 				ics2101_mix_attenuate(ic,
  1.1    brezak 						      GUSMIX_CHAN_DAC,
  1.1    brezak 						      ICSMIX_LEFT,
  1.1    brezak 						      vol.left);
  1.1    brezak 				ics2101_mix_attenuate(ic,
  1.1    brezak 						      GUSMIX_CHAN_DAC,
  1.1    brezak 						      ICSMIX_RIGHT,
  1.1    brezak 						      vol.right);
  1.1    brezak 				error = 0;
  1.1    brezak 			}
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak
  1.1    brezak 	case GUSICS_RECORD_SOURCE:
  1.1    brezak 		if (cp->type == AUDIO_MIXER_ENUM && cp->un.ord == 0) {
  1.1    brezak 			/* Can't set anything else useful, sigh. */
  1.1    brezak 			error = 0;
  1.1    brezak 		}
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	default:
  1.1    brezak 		return ENXIO;
 1.87      kent 		/*NOTREACHED*/
  1.1    brezak 	}
  1.1    brezak 	return error;
 1.36  augustss }
 1.36  augustss
 1.36  augustss STATIC int
 1.87      kent gus_get_props(void *addr)
 1.36  augustss {
 1.87      kent 	struct gus_softc *sc;
 1.87      kent
 1.87      kent 	sc = addr;
 1.87      kent 	return AUDIO_PROP_MMAP |
 1.87      kent 	    (sc->sc_recdrq == sc->sc_playdrq ? 0 : AUDIO_PROP_FULLDUPLEX);
 1.36  augustss }
 1.36  augustss
 1.36  augustss STATIC int
 1.87      kent gusmax_get_props(void *addr)
 1.36  augustss {
 1.87      kent 	struct ad1848_isa_softc *ac;
 1.87      kent
 1.87      kent 	ac = addr;
 1.62       jtk 	return gus_get_props(ac->sc_ad1848.parent);
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC int
 1.96  christos gusmax_mixer_query_devinfo(void *addr, mixer_devinfo_t *dip)
  1.1    brezak {
 1.87      kent
  1.1    brezak 	DPRINTF(("gusmax_query_devinfo: index=%d\n", dip->index));
  1.1    brezak
  1.1    brezak 	switch(dip->index) {
  1.1    brezak #if 0
 1.87      kent 	case GUSMAX_MIC_IN_LVL:	/* Microphone */
 1.87      kent 		dip->type = AUDIO_MIXER_VALUE;
 1.87      kent 		dip->mixer_class = GUSMAX_INPUT_CLASS;
 1.87      kent 		dip->prev = AUDIO_MIXER_LAST;
 1.87      kent 		dip->next = GUSMAX_MIC_IN_MUTE;
 1.87      kent 		strcpy(dip->label.name, AudioNmicrophone);
 1.87      kent 		dip->un.v.num_channels = 2;
 1.87      kent 		strcpy(dip->un.v.units.name, AudioNvolume);
 1.87      kent 		break;
  1.1    brezak #endif
  1.1    brezak
 1.87      kent 	case GUSMAX_MONO_LVL:	/* mono/microphone mixer */
 1.87      kent 		dip->type = AUDIO_MIXER_VALUE;
 1.87      kent 		dip->mixer_class = GUSMAX_INPUT_CLASS;
 1.87      kent 		dip->prev = AUDIO_MIXER_LAST;
 1.87      kent 		dip->next = GUSMAX_MONO_MUTE;
 1.87      kent 		strcpy(dip->label.name, AudioNmicrophone);
 1.87      kent 		dip->un.v.num_channels = 1;
 1.87      kent 		strcpy(dip->un.v.units.name, AudioNvolume);
 1.87      kent 		break;
 1.87      kent
 1.87      kent 	case GUSMAX_DAC_LVL:		/*  dacout */
 1.87      kent 		dip->type = AUDIO_MIXER_VALUE;
 1.87      kent 		dip->mixer_class = GUSMAX_INPUT_CLASS;
 1.87      kent 		dip->prev = AUDIO_MIXER_LAST;
 1.87      kent 		dip->next = GUSMAX_DAC_MUTE;
 1.87      kent 		strcpy(dip->label.name, AudioNdac);
 1.87      kent 		dip->un.v.num_channels = 2;
 1.87      kent 		strcpy(dip->un.v.units.name, AudioNvolume);
 1.87      kent 		break;
 1.87      kent
 1.87      kent 	case GUSMAX_LINE_IN_LVL:	/* line */
 1.87      kent 		dip->type = AUDIO_MIXER_VALUE;
 1.87      kent 		dip->mixer_class = GUSMAX_INPUT_CLASS;
 1.87      kent 		dip->prev = AUDIO_MIXER_LAST;
 1.87      kent 		dip->next = GUSMAX_LINE_IN_MUTE;
 1.87      kent 		strcpy(dip->label.name, AudioNline);
 1.87      kent 		dip->un.v.num_channels = 2;
 1.87      kent 		strcpy(dip->un.v.units.name, AudioNvolume);
 1.87      kent 		break;
 1.87      kent
 1.87      kent 	case GUSMAX_CD_LVL:		/* cd */
 1.87      kent 		dip->type = AUDIO_MIXER_VALUE;
 1.87      kent 		dip->mixer_class = GUSMAX_INPUT_CLASS;
 1.87      kent 		dip->prev = AUDIO_MIXER_LAST;
 1.87      kent 		dip->next = GUSMAX_CD_MUTE;
 1.87      kent 		strcpy(dip->label.name, AudioNcd);
 1.87      kent 		dip->un.v.num_channels = 2;
 1.87      kent 		strcpy(dip->un.v.units.name, AudioNvolume);
 1.87      kent 		break;
 1.87      kent
 1.87      kent
 1.87      kent 	case GUSMAX_MONITOR_LVL:	/* monitor level */
 1.87      kent 		dip->type = AUDIO_MIXER_VALUE;
 1.87      kent 		dip->mixer_class = GUSMAX_MONITOR_CLASS;
 1.87      kent 		dip->next = GUSMAX_MONITOR_MUTE;
 1.87      kent 		dip->prev = AUDIO_MIXER_LAST;
 1.87      kent 		strcpy(dip->label.name, AudioNmonitor);
 1.87      kent 		dip->un.v.num_channels = 1;
 1.87      kent 		strcpy(dip->un.v.units.name, AudioNvolume);
 1.87      kent 		break;
 1.87      kent
 1.87      kent 	case GUSMAX_OUT_LVL:		/* cs4231 output volume: not useful? */
 1.87      kent 		dip->type = AUDIO_MIXER_VALUE;
 1.87      kent 		dip->mixer_class = GUSMAX_MONITOR_CLASS;
 1.87      kent 		dip->prev = dip->next = AUDIO_MIXER_LAST;
 1.87      kent 		strcpy(dip->label.name, AudioNoutput);
 1.87      kent 		dip->un.v.num_channels = 2;
 1.87      kent 		strcpy(dip->un.v.units.name, AudioNvolume);
 1.87      kent 		break;
 1.87      kent
 1.87      kent 	case GUSMAX_SPEAKER_LVL:		/* fake speaker volume */
 1.87      kent 		dip->type = AUDIO_MIXER_VALUE;
 1.87      kent 		dip->mixer_class = GUSMAX_MONITOR_CLASS;
 1.87      kent 		dip->prev = AUDIO_MIXER_LAST;
 1.87      kent 		dip->next = GUSMAX_SPEAKER_MUTE;
 1.87      kent 		strcpy(dip->label.name, AudioNmaster);
 1.87      kent 		dip->un.v.num_channels = 2;
 1.87      kent 		strcpy(dip->un.v.units.name, AudioNvolume);
 1.87      kent 		break;
 1.87      kent
 1.87      kent 	case GUSMAX_LINE_IN_MUTE:
 1.87      kent 		dip->mixer_class = GUSMAX_INPUT_CLASS;
 1.87      kent 		dip->type = AUDIO_MIXER_ENUM;
 1.87      kent 		dip->prev = GUSMAX_LINE_IN_LVL;
 1.87      kent 		dip->next = AUDIO_MIXER_LAST;
 1.87      kent 		goto mute;
 1.87      kent
 1.87      kent 	case GUSMAX_DAC_MUTE:
 1.87      kent 		dip->mixer_class = GUSMAX_INPUT_CLASS;
 1.87      kent 		dip->type = AUDIO_MIXER_ENUM;
 1.87      kent 		dip->prev = GUSMAX_DAC_LVL;
 1.87      kent 		dip->next = AUDIO_MIXER_LAST;
 1.87      kent 		goto mute;
 1.87      kent
 1.87      kent 	case GUSMAX_CD_MUTE:
 1.87      kent 		dip->mixer_class = GUSMAX_INPUT_CLASS;
 1.87      kent 		dip->type = AUDIO_MIXER_ENUM;
 1.87      kent 		dip->prev = GUSMAX_CD_LVL;
 1.87      kent 		dip->next = AUDIO_MIXER_LAST;
 1.87      kent 		goto mute;
 1.87      kent
 1.87      kent 	case GUSMAX_MONO_MUTE:
 1.87      kent 		dip->mixer_class = GUSMAX_INPUT_CLASS;
 1.87      kent 		dip->type = AUDIO_MIXER_ENUM;
 1.87      kent 		dip->prev = GUSMAX_MONO_LVL;
 1.87      kent 		dip->next = AUDIO_MIXER_LAST;
 1.87      kent 		goto mute;
 1.87      kent
 1.87      kent 	case GUSMAX_MONITOR_MUTE:
 1.87      kent 		dip->mixer_class = GUSMAX_OUTPUT_CLASS;
 1.87      kent 		dip->type = AUDIO_MIXER_ENUM;
 1.87      kent 		dip->prev = GUSMAX_MONITOR_LVL;
 1.87      kent 		dip->next = AUDIO_MIXER_LAST;
 1.87      kent 		goto mute;
 1.87      kent
 1.87      kent 	case GUSMAX_SPEAKER_MUTE:
 1.87      kent 		dip->mixer_class = GUSMAX_OUTPUT_CLASS;
 1.87      kent 		dip->type = AUDIO_MIXER_ENUM;
 1.87      kent 		dip->prev = GUSMAX_SPEAKER_LVL;
 1.87      kent 		dip->next = AUDIO_MIXER_LAST;
 1.87      kent 	mute:
 1.87      kent 		strcpy(dip->label.name, AudioNmute);
 1.87      kent 		dip->un.e.num_mem = 2;
 1.87      kent 		strcpy(dip->un.e.member[0].label.name, AudioNoff);
 1.87      kent 		dip->un.e.member[0].ord = 0;
 1.87      kent 		strcpy(dip->un.e.member[1].label.name, AudioNon);
 1.87      kent 		dip->un.e.member[1].ord = 1;
 1.87      kent 		break;
 1.87      kent
 1.87      kent 	case GUSMAX_REC_LVL:	/* record level */
 1.87      kent 		dip->type = AUDIO_MIXER_VALUE;
 1.87      kent 		dip->mixer_class = GUSMAX_RECORD_CLASS;
 1.87      kent 		dip->prev = AUDIO_MIXER_LAST;
 1.87      kent 		dip->next = GUSMAX_RECORD_SOURCE;
 1.87      kent 		strcpy(dip->label.name, AudioNrecord);
 1.87      kent 		dip->un.v.num_channels = 2;
 1.87      kent 		strcpy(dip->un.v.units.name, AudioNvolume);
 1.87      kent 		break;
 1.87      kent
 1.87      kent 	case GUSMAX_RECORD_SOURCE:
 1.87      kent 		dip->mixer_class = GUSMAX_RECORD_CLASS;
 1.87      kent 		dip->type = AUDIO_MIXER_ENUM;
 1.87      kent 		dip->prev = GUSMAX_REC_LVL;
 1.87      kent 		dip->next = AUDIO_MIXER_LAST;
 1.87      kent 		strcpy(dip->label.name, AudioNsource);
 1.87      kent 		dip->un.e.num_mem = 4;
 1.87      kent 		strcpy(dip->un.e.member[0].label.name, AudioNoutput);
 1.87      kent 		dip->un.e.member[0].ord = DAC_IN_PORT;
 1.87      kent 		strcpy(dip->un.e.member[1].label.name, AudioNmicrophone);
 1.87      kent 		dip->un.e.member[1].ord = MIC_IN_PORT;
 1.87      kent 		strcpy(dip->un.e.member[2].label.name, AudioNdac);
 1.87      kent 		dip->un.e.member[2].ord = AUX1_IN_PORT;
 1.87      kent 		strcpy(dip->un.e.member[3].label.name, AudioNline);
 1.87      kent 		dip->un.e.member[3].ord = LINE_IN_PORT;
 1.87      kent 		break;
 1.87      kent
 1.87      kent 	case GUSMAX_INPUT_CLASS:		/* input class descriptor */
 1.87      kent 		dip->type = AUDIO_MIXER_CLASS;
 1.87      kent 		dip->mixer_class = GUSMAX_INPUT_CLASS;
 1.87      kent 		dip->next = dip->prev = AUDIO_MIXER_LAST;
 1.87      kent 		strcpy(dip->label.name, AudioCinputs);
 1.87      kent 		break;
 1.87      kent
 1.87      kent 	case GUSMAX_OUTPUT_CLASS:		/* output class descriptor */
 1.87      kent 		dip->type = AUDIO_MIXER_CLASS;
 1.87      kent 		dip->mixer_class = GUSMAX_OUTPUT_CLASS;
 1.87      kent 		dip->next = dip->prev = AUDIO_MIXER_LAST;
 1.87      kent 		strcpy(dip->label.name, AudioCoutputs);
 1.87      kent 		break;
 1.87      kent
 1.87      kent 	case GUSMAX_MONITOR_CLASS:		/* monitor class descriptor */
 1.87      kent 		dip->type = AUDIO_MIXER_CLASS;
 1.87      kent 		dip->mixer_class = GUSMAX_MONITOR_CLASS;
 1.87      kent 		dip->next = dip->prev = AUDIO_MIXER_LAST;
 1.87      kent 		strcpy(dip->label.name, AudioCmonitor);
 1.87      kent 		break;
 1.87      kent
 1.87      kent 	case GUSMAX_RECORD_CLASS:		/* record source class */
 1.87      kent 		dip->type = AUDIO_MIXER_CLASS;
 1.87      kent 		dip->mixer_class = GUSMAX_RECORD_CLASS;
 1.87      kent 		dip->next = dip->prev = AUDIO_MIXER_LAST;
 1.87      kent 		strcpy(dip->label.name, AudioCrecord);
 1.87      kent 		break;
 1.87      kent
 1.87      kent 	default:
 1.87      kent 		return ENXIO;
 1.87      kent 		/*NOTREACHED*/
 1.87      kent 	}
 1.87      kent 	DPRINTF(("AUDIO_MIXER_DEVINFO: name=%s\n", dip->label.name));
  1.1    brezak 	return 0;
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC int
 1.87      kent gus_mixer_query_devinfo(void *addr, mixer_devinfo_t *dip)
  1.1    brezak {
 1.87      kent 	struct gus_softc *sc;
  1.1    brezak
  1.1    brezak 	DPRINTF(("gusmax_query_devinfo: index=%d\n", dip->index));
 1.87      kent 	sc = addr;
  1.1    brezak 	if (!HAS_MIXER(sc) && dip->index > GUSICS_MASTER_MUTE)
  1.1    brezak 		return ENXIO;
  1.1    brezak
  1.1    brezak 	switch(dip->index) {
  1.1    brezak
  1.1    brezak 	case GUSICS_MIC_IN_LVL:	/* Microphone */
  1.1    brezak 		dip->type = AUDIO_MIXER_VALUE;
  1.1    brezak 		dip->mixer_class = GUSICS_INPUT_CLASS;
  1.1    brezak 		dip->prev = AUDIO_MIXER_LAST;
  1.1    brezak 		dip->next = GUSICS_MIC_IN_MUTE;
  1.1    brezak 		strcpy(dip->label.name, AudioNmicrophone);
  1.1    brezak 		dip->un.v.num_channels = 2;
  1.1    brezak 		strcpy(dip->un.v.units.name, AudioNvolume);
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_LINE_IN_LVL:	/* line */
  1.1    brezak 		dip->type = AUDIO_MIXER_VALUE;
  1.1    brezak 		dip->mixer_class = GUSICS_INPUT_CLASS;
  1.1    brezak 		dip->prev = AUDIO_MIXER_LAST;
  1.1    brezak 		dip->next = GUSICS_LINE_IN_MUTE;
  1.1    brezak 		strcpy(dip->label.name, AudioNline);
  1.1    brezak 		dip->un.v.num_channels = 2;
  1.1    brezak 		strcpy(dip->un.v.units.name, AudioNvolume);
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_CD_LVL:		/* cd */
  1.1    brezak 		dip->type = AUDIO_MIXER_VALUE;
  1.1    brezak 		dip->mixer_class = GUSICS_INPUT_CLASS;
  1.1    brezak 		dip->prev = AUDIO_MIXER_LAST;
  1.1    brezak 		dip->next = GUSICS_CD_MUTE;
  1.1    brezak 		strcpy(dip->label.name, AudioNcd);
  1.1    brezak 		dip->un.v.num_channels = 2;
  1.1    brezak 		strcpy(dip->un.v.units.name, AudioNvolume);
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_DAC_LVL:		/*  dacout */
  1.1    brezak 		dip->type = AUDIO_MIXER_VALUE;
  1.1    brezak 		dip->mixer_class = GUSICS_INPUT_CLASS;
  1.1    brezak 		dip->prev = AUDIO_MIXER_LAST;
  1.1    brezak 		dip->next = GUSICS_DAC_MUTE;
  1.1    brezak 		strcpy(dip->label.name, AudioNdac);
  1.1    brezak 		dip->un.v.num_channels = 2;
  1.1    brezak 		strcpy(dip->un.v.units.name, AudioNvolume);
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_MASTER_LVL:		/*  master output */
  1.1    brezak 		dip->type = AUDIO_MIXER_VALUE;
  1.1    brezak 		dip->mixer_class = GUSICS_OUTPUT_CLASS;
  1.1    brezak 		dip->prev = AUDIO_MIXER_LAST;
  1.1    brezak 		dip->next = GUSICS_MASTER_MUTE;
 1.48  augustss 		strcpy(dip->label.name, AudioNmaster);
  1.1    brezak 		dip->un.v.num_channels = 2;
  1.1    brezak 		strcpy(dip->un.v.units.name, AudioNvolume);
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak
  1.1    brezak 	case GUSICS_LINE_IN_MUTE:
  1.1    brezak 		dip->mixer_class = GUSICS_INPUT_CLASS;
  1.1    brezak 		dip->type = AUDIO_MIXER_ENUM;
  1.1    brezak 		dip->prev = GUSICS_LINE_IN_LVL;
  1.1    brezak 		dip->next = AUDIO_MIXER_LAST;
  1.1    brezak 		goto mute;
 1.87      kent
  1.1    brezak 	case GUSICS_DAC_MUTE:
  1.1    brezak 		dip->mixer_class = GUSICS_INPUT_CLASS;
  1.1    brezak 		dip->type = AUDIO_MIXER_ENUM;
  1.1    brezak 		dip->prev = GUSICS_DAC_LVL;
  1.1    brezak 		dip->next = AUDIO_MIXER_LAST;
  1.1    brezak 		goto mute;
  1.1    brezak
  1.1    brezak 	case GUSICS_CD_MUTE:
  1.1    brezak 		dip->mixer_class = GUSICS_INPUT_CLASS;
  1.1    brezak 		dip->type = AUDIO_MIXER_ENUM;
  1.1    brezak 		dip->prev = GUSICS_CD_LVL;
  1.1    brezak 		dip->next = AUDIO_MIXER_LAST;
  1.1    brezak 		goto mute;
 1.87      kent
  1.1    brezak 	case GUSICS_MIC_IN_MUTE:
  1.1    brezak 		dip->mixer_class = GUSICS_INPUT_CLASS;
  1.1    brezak 		dip->type = AUDIO_MIXER_ENUM;
  1.1    brezak 		dip->prev = GUSICS_MIC_IN_LVL;
  1.1    brezak 		dip->next = AUDIO_MIXER_LAST;
  1.1    brezak 		goto mute;
  1.1    brezak
  1.1    brezak 	case GUSICS_MASTER_MUTE:
  1.1    brezak 		dip->mixer_class = GUSICS_OUTPUT_CLASS;
  1.1    brezak 		dip->type = AUDIO_MIXER_ENUM;
  1.1    brezak 		dip->prev = GUSICS_MASTER_LVL;
  1.1    brezak 		dip->next = AUDIO_MIXER_LAST;
  1.1    brezak mute:
  1.1    brezak 		strcpy(dip->label.name, AudioNmute);
  1.1    brezak 		dip->un.e.num_mem = 2;
  1.1    brezak 		strcpy(dip->un.e.member[0].label.name, AudioNoff);
  1.1    brezak 		dip->un.e.member[0].ord = 0;
  1.1    brezak 		strcpy(dip->un.e.member[1].label.name, AudioNon);
  1.1    brezak 		dip->un.e.member[1].ord = 1;
  1.1    brezak 		break;
 1.87      kent
  1.1    brezak 	case GUSICS_RECORD_SOURCE:
  1.1    brezak 		dip->mixer_class = GUSICS_RECORD_CLASS;
  1.1    brezak 		dip->type = AUDIO_MIXER_ENUM;
  1.1    brezak 		dip->prev = dip->next = AUDIO_MIXER_LAST;
  1.1    brezak 		strcpy(dip->label.name, AudioNsource);
  1.1    brezak 		dip->un.e.num_mem = 1;
  1.1    brezak 		strcpy(dip->un.e.member[0].label.name, AudioNoutput);
  1.1    brezak 		dip->un.e.member[0].ord = GUSICS_MASTER_LVL;
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_INPUT_CLASS:
  1.1    brezak 		dip->type = AUDIO_MIXER_CLASS;
  1.1    brezak 		dip->mixer_class = GUSICS_INPUT_CLASS;
  1.1    brezak 		dip->next = dip->prev = AUDIO_MIXER_LAST;
 1.46   mycroft 		strcpy(dip->label.name, AudioCinputs);
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_OUTPUT_CLASS:
  1.1    brezak 		dip->type = AUDIO_MIXER_CLASS;
  1.1    brezak 		dip->mixer_class = GUSICS_OUTPUT_CLASS;
  1.1    brezak 		dip->next = dip->prev = AUDIO_MIXER_LAST;
 1.46   mycroft 		strcpy(dip->label.name, AudioCoutputs);
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	case GUSICS_RECORD_CLASS:
  1.1    brezak 		dip->type = AUDIO_MIXER_CLASS;
  1.1    brezak 		dip->mixer_class = GUSICS_RECORD_CLASS;
  1.1    brezak 		dip->next = dip->prev = AUDIO_MIXER_LAST;
 1.46   mycroft 		strcpy(dip->label.name, AudioCrecord);
  1.1    brezak 		break;
  1.1    brezak
  1.1    brezak 	default:
  1.1    brezak 		return ENXIO;
 1.87      kent 		/*NOTREACHED*/
  1.1    brezak 	}
  1.1    brezak 	DPRINTF(("AUDIO_MIXER_DEVINFO: name=%s\n", dip->label.name));
  1.1    brezak 	return 0;
  1.1    brezak }
  1.1    brezak
  1.8       jtk STATIC int
 1.96  christos gus_query_encoding(void *addr, struct audio_encoding *fp)
  1.1    brezak {
 1.87      kent
  1.1    brezak 	switch (fp->index) {
  1.1    brezak 	case 0:
  1.1    brezak 		strcpy(fp->name, AudioEmulaw);
 1.24  augustss 		fp->encoding = AUDIO_ENCODING_ULAW;
 1.24  augustss 		fp->precision = 8;
 1.26       jtk 		fp->flags = AUDIO_ENCODINGFLAG_EMULATED;
  1.1    brezak 		break;
  1.1    brezak 	case 1:
 1.47   mycroft 		strcpy(fp->name, AudioEslinear);
 1.32  augustss 		fp->encoding = AUDIO_ENCODING_SLINEAR;
 1.24  augustss 		fp->precision = 8;
 1.24  augustss 		fp->flags = 0;
  1.1    brezak 		break;
  1.1    brezak 	case 2:
 1.47   mycroft 		strcpy(fp->name, AudioEslinear_le);
 1.32  augustss 		fp->encoding = AUDIO_ENCODING_SLINEAR_LE;
 1.24  augustss 		fp->precision = 16;
 1.24  augustss 		fp->flags = 0;
 1.24  augustss 		break;
 1.24  augustss 	case 3:
 1.26       jtk 		strcpy(fp->name, AudioEulinear);
 1.26       jtk 		fp->encoding = AUDIO_ENCODING_ULINEAR;
 1.24  augustss 		fp->precision = 8;
 1.24  augustss 		fp->flags = 0;
 1.24  augustss 		break;
 1.24  augustss 	case 4:
 1.24  augustss 		strcpy(fp->name, AudioEulinear_le);
 1.24  augustss 		fp->encoding = AUDIO_ENCODING_ULINEAR_LE;
 1.24  augustss 		fp->precision = 16;
 1.24  augustss 		fp->flags = 0;
 1.29       jtk 		break;
 1.29       jtk 	case 5:
 1.47   mycroft 		strcpy(fp->name, AudioEslinear_be);
 1.32  augustss 		fp->encoding = AUDIO_ENCODING_SLINEAR_BE;
 1.29       jtk 		fp->precision = 16;
 1.29       jtk 		fp->flags = AUDIO_ENCODINGFLAG_EMULATED;
 1.29       jtk 		break;
 1.29       jtk 	case 6:
 1.29       jtk 		strcpy(fp->name, AudioEulinear_be);
 1.29       jtk 		fp->encoding = AUDIO_ENCODING_ULINEAR_BE;
 1.29       jtk 		fp->precision = 16;
 1.29       jtk 		fp->flags = AUDIO_ENCODINGFLAG_EMULATED;
  1.1    brezak 		break;
 1.39  augustss 	case 7:
 1.39  augustss 		strcpy(fp->name, AudioEalaw);
 1.39  augustss 		fp->encoding = AUDIO_ENCODING_ALAW;
 1.39  augustss 		fp->precision = 8;
 1.39  augustss 		fp->flags = AUDIO_ENCODINGFLAG_EMULATED;
 1.39  augustss 		break;
 1.39  augustss
  1.1    brezak 	default:
 1.87      kent 		return EINVAL;
  1.1    brezak 		/*NOTREACHED*/
  1.1    brezak 	}
 1.87      kent 	return 0;
  1.1    brezak }
  1.1    brezak
  1.1    brezak /*
  1.1    brezak  * Setup the ICS mixer in "transparent" mode: reset everything to a sensible
  1.1    brezak  * level.  Levels as suggested by GUS SDK code.
  1.1    brezak  */
  1.8       jtk STATIC void
 1.87      kent gus_init_ics2101(struct gus_softc *sc)
  1.1    brezak {
 1.87      kent 	struct ics2101_softc *ic;
 1.87      kent
 1.87      kent 	ic = &sc->sc_mixer;
 1.43  augustss 	sc->sc_mixer.sc_iot = sc->sc_iot;
 1.43  augustss 	sc->sc_mixer.sc_selio = GUS_MIXER_SELECT;
 1.43  augustss 	sc->sc_mixer.sc_selio_ioh = sc->sc_ioh3;
 1.43  augustss 	sc->sc_mixer.sc_dataio = GUS_MIXER_DATA;
 1.43  augustss 	sc->sc_mixer.sc_dataio_ioh = sc->sc_ioh2;
  1.1    brezak 	sc->sc_mixer.sc_flags = (sc->sc_revision == 5) ? ICS_FLIP : 0;
  1.1    brezak
  1.1    brezak 	ics2101_mix_attenuate(ic,
  1.1    brezak 			      GUSMIX_CHAN_MIC,
  1.1    brezak 			      ICSMIX_LEFT,
  1.1    brezak 			      ICSMIX_MIN_ATTN);
  1.1    brezak 	ics2101_mix_attenuate(ic,
  1.1    brezak 			      GUSMIX_CHAN_MIC,
  1.1    brezak 			      ICSMIX_RIGHT,
  1.1    brezak 			      ICSMIX_MIN_ATTN);
  1.1    brezak 	/*
  1.1    brezak 	 * Start with microphone muted by the mixer...
  1.1    brezak 	 */
  1.1    brezak 	gusics_mic_mute(ic, 1);
  1.1    brezak
  1.1    brezak 	/* ... and enabled by the GUS master mix control */
  1.1    brezak 	gus_mic_ctl(sc, SPKR_ON);
  1.1    brezak
  1.1    brezak 	ics2101_mix_attenuate(ic,
  1.1    brezak 			      GUSMIX_CHAN_LINE,
  1.1    brezak 			      ICSMIX_LEFT,
  1.1    brezak 			      ICSMIX_MIN_ATTN);
  1.1    brezak 	ics2101_mix_attenuate(ic,
  1.1    brezak 			      GUSMIX_CHAN_LINE,
  1.1    brezak 			      ICSMIX_RIGHT,
  1.1    brezak 			      ICSMIX_MIN_ATTN);
  1.1    brezak
  1.1    brezak 	ics2101_mix_attenuate(ic,
  1.1    brezak 			      GUSMIX_CHAN_CD,
  1.1    brezak 			      ICSMIX_LEFT,
  1.1    brezak 			      ICSMIX_MIN_ATTN);
  1.1    brezak 	ics2101_mix_attenuate(ic,
  1.1    brezak 			      GUSMIX_CHAN_CD,
  1.1    brezak 			      ICSMIX_RIGHT,
  1.1    brezak 			      ICSMIX_MIN_ATTN);
  1.1    brezak
  1.1    brezak 	ics2101_mix_attenuate(ic,
  1.1    brezak 			      GUSMIX_CHAN_DAC,
  1.1    brezak 			      ICSMIX_LEFT,
  1.1    brezak 			      ICSMIX_MIN_ATTN);
  1.1    brezak 	ics2101_mix_attenuate(ic,
  1.1    brezak 			      GUSMIX_CHAN_DAC,
  1.1    brezak 			      ICSMIX_RIGHT,
  1.1    brezak 			      ICSMIX_MIN_ATTN);
  1.1    brezak
  1.1    brezak 	ics2101_mix_attenuate(ic,
  1.1    brezak 			      ICSMIX_CHAN_4,
  1.1    brezak 			      ICSMIX_LEFT,
  1.1    brezak 			      ICSMIX_MAX_ATTN);
  1.1    brezak 	ics2101_mix_attenuate(ic,
  1.1    brezak 			      ICSMIX_CHAN_4,
  1.1    brezak 			      ICSMIX_RIGHT,
  1.1    brezak 			      ICSMIX_MAX_ATTN);
  1.1    brezak
  1.1    brezak 	ics2101_mix_attenuate(ic,
  1.1    brezak 			      GUSMIX_CHAN_MASTER,
  1.1    brezak 			      ICSMIX_LEFT,
  1.1    brezak 			      ICSMIX_MIN_ATTN);
  1.1    brezak 	ics2101_mix_attenuate(ic,
  1.1    brezak 			      GUSMIX_CHAN_MASTER,
  1.1    brezak 			      ICSMIX_RIGHT,
  1.1    brezak 			      ICSMIX_MIN_ATTN);
  1.1    brezak 	/* unmute other stuff: */
  1.1    brezak 	gusics_cd_mute(ic, 0);
  1.1    brezak 	gusics_dac_mute(ic, 0);
  1.1    brezak 	gusics_linein_mute(ic, 0);
  1.1    brezak 	return;
  1.1    brezak }
  1.1    brezak
  1.1    brezak
  1.1    brezak #endif /* NGUS */