File: [local] / sys / dev / pci / sv.c (download)
Revision 1.1.1.1 (vendor branch), Tue Mar 4 16:13:54 2008 UTC (16 years, 5 months ago) by nbrk
Branch: OPENBSD_4_2_BASE, MAIN
CVS Tags: jornada-partial-support-wip, HEAD Changes since 1.1: +0 -0 lines
Import of OpenBSD 4.2 release kernel tree with initial code to support
Jornada 720/728, StrongARM 1110-based handheld PC.
At this point kernel roots on NFS and boots into vfs_mountroot() and traps.
What is supported:
- glass console, Jornada framebuffer (jfb) works in 16bpp direct color mode
(needs some palette tweaks for non black/white/blue colors, i think)
- saic, SA11x0 interrupt controller (needs cleanup)
- sacom, SA11x0 UART (supported only as boot console for now)
- SA11x0 GPIO controller fully supported (but can't handle multiple interrupt
handlers on one gpio pin)
- sassp, SSP port on SA11x0 that attaches spibus
- Jornada microcontroller (jmcu) to control kbd, battery, etc throught
the SPI bus (wskbd attaches on jmcu, but not tested)
- tod functions seem work
- initial code for SA-1111 (chip companion) : this is TODO
Next important steps, i think:
- gpio and intc on sa1111
- pcmcia support for sa11x0 (and sa1111 help logic)
- REAL root on nfs when we have PCMCIA support (we may use any of supported pccard NICs)
- root on wd0! (using already supported PCMCIA-ATA)
|
/* $OpenBSD: sv.c,v 1.21 2005/09/11 18:17:08 mickey Exp $ */
/*
* Copyright (c) 1998 Constantine Paul Sapuntzakis
* All rights reserved
*
* Author: Constantine Paul Sapuntzakis (csapuntz@cvs.openbsd.org)
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. The author's name or those of the contributors may be used to
* endorse or promote products derived from this software without
* specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR(S) AND CONTRIBUTORS
* ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
* TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
/*
* S3 SonicVibes driver
* Heavily based on the eap driver by Lennart Augustsson
*/
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/kernel.h>
#include <sys/malloc.h>
#include <sys/device.h>
#include <dev/pci/pcireg.h>
#include <dev/pci/pcivar.h>
#include <dev/pci/pcidevs.h>
#include <sys/audioio.h>
#include <dev/audio_if.h>
#include <dev/mulaw.h>
#include <dev/auconv.h>
#include <dev/ic/i8237reg.h>
#include <dev/ic/s3_617.h>
#include <machine/bus.h>
#ifdef __OpenBSD__
struct cfdriver sv_cd = {
NULL, "sv", DV_DULL
};
#endif
#ifdef AUDIO_DEBUG
#define DPRINTF(x) if (svdebug) printf x
#define DPRINTFN(n,x) if (svdebug>(n)) printf x
static int svdebug = 100;
#else
#define DPRINTF(x)
#define DPRINTFN(n,x)
#endif
int sv_match(struct device *, void *, void *);
static void sv_attach(struct device *, struct device *, void *);
int sv_intr(void *);
struct sv_dma {
bus_dmamap_t map;
caddr_t addr;
bus_dma_segment_t segs[1];
int nsegs;
size_t size;
struct sv_dma *next;
};
#define DMAADDR(map) ((map)->segs[0].ds_addr)
#define KERNADDR(map) ((void *)((map)->addr))
enum {
SV_DMAA_CONFIGURED = 1,
SV_DMAC_CONFIGURED = 2,
SV_DMAA_TRIED_CONFIGURE = 4,
SV_DMAC_TRIED_CONFIGURE = 8
};
struct sv_softc {
struct device sc_dev; /* base device */
void *sc_ih; /* interrupt vectoring */
pci_chipset_tag_t sc_pci_chipset_tag;
pcitag_t sc_pci_tag;
bus_space_tag_t sc_iot;
bus_space_handle_t sc_ioh;
bus_space_handle_t sc_dmaa_ioh;
bus_space_handle_t sc_dmac_ioh;
bus_dma_tag_t sc_dmatag; /* DMA tag */
struct sv_dma *sc_dmas;
void (*sc_pintr)(void *); /* dma completion intr handler */
void *sc_parg; /* arg for sc_intr() */
void (*sc_rintr)(void *); /* dma completion intr handler */
void *sc_rarg; /* arg for sc_intr() */
char sc_enable;
char sc_trd;
char sc_dma_configured;
u_int sc_record_source; /* recording source mask */
};
struct cfattach sv_ca = {
sizeof(struct sv_softc), sv_match, sv_attach
};
struct audio_device sv_device = {
"S3 SonicVibes",
"",
"sv"
};
#define ARRAY_SIZE(foo) ((sizeof(foo)) / sizeof(foo[0]))
int sv_allocmem(struct sv_softc *, size_t, size_t, struct sv_dma *);
int sv_freemem(struct sv_softc *, struct sv_dma *);
int sv_open(void *, int);
void sv_close(void *);
int sv_query_encoding(void *, struct audio_encoding *);
int sv_set_params(void *, int, int, struct audio_params *, struct audio_params *);
int sv_round_blocksize(void *, int);
int sv_dma_init_output(void *, void *, int);
int sv_dma_init_input(void *, void *, int);
int sv_dma_output(void *, void *, int, void (*)(void *), void *);
int sv_dma_input(void *, void *, int, void (*)(void *), void *);
int sv_halt_in_dma(void *);
int sv_halt_out_dma(void *);
int sv_getdev(void *, struct audio_device *);
int sv_mixer_set_port(void *, mixer_ctrl_t *);
int sv_mixer_get_port(void *, mixer_ctrl_t *);
int sv_query_devinfo(void *, mixer_devinfo_t *);
void *sv_malloc(void *, int, size_t, int, int);
void sv_free(void *, void *, int);
paddr_t sv_mappage(void *, void *, off_t, int);
int sv_get_props(void *);
void sv_dumpregs(struct sv_softc *sc);
struct audio_hw_if sv_hw_if = {
sv_open,
sv_close,
NULL,
sv_query_encoding,
sv_set_params,
sv_round_blocksize,
NULL,
sv_dma_init_output,
sv_dma_init_input,
sv_dma_output,
sv_dma_input,
sv_halt_out_dma,
sv_halt_in_dma,
NULL,
sv_getdev,
NULL,
sv_mixer_set_port,
sv_mixer_get_port,
sv_query_devinfo,
sv_malloc,
sv_free,
NULL,
sv_mappage,
sv_get_props,
NULL,
NULL
};
static __inline__ u_int8_t sv_read(struct sv_softc *, u_int8_t);
static __inline__ u_int8_t sv_read_indirect(struct sv_softc *, u_int8_t);
static __inline__ void sv_write(struct sv_softc *, u_int8_t, u_int8_t );
static __inline__ void sv_write_indirect(struct sv_softc *, u_int8_t, u_int8_t );
static void sv_init_mixer(struct sv_softc *);
static __inline__ void
sv_write (sc, reg, val)
struct sv_softc *sc;
u_int8_t reg, val;
{
bus_space_write_1(sc->sc_iot, sc->sc_ioh, reg, val);
}
static __inline__ u_int8_t
sv_read (sc, reg)
struct sv_softc *sc;
u_int8_t reg;
{
return (bus_space_read_1(sc->sc_iot, sc->sc_ioh, reg));
}
static __inline__ u_int8_t
sv_read_indirect (sc, reg)
struct sv_softc *sc;
u_int8_t reg;
{
u_int8_t iaddr = 0;
if (sc->sc_trd > 0)
iaddr |= SV_IADDR_TRD;
iaddr |= (reg & SV_IADDR_MASK);
sv_write (sc, SV_CODEC_IADDR, iaddr);
return (sv_read(sc, SV_CODEC_IDATA));
}
static __inline__ void
sv_write_indirect (sc, reg, val)
struct sv_softc *sc;
u_int8_t reg, val;
{
u_int8_t iaddr = 0;
#ifdef DIAGNOSTIC
if (reg > 0x3f) {
printf ("Invalid register\n");
return;
}
#endif
if (reg == SV_DMA_DATA_FORMAT)
iaddr |= SV_IADDR_MCE;
if (sc->sc_trd > 0)
iaddr |= SV_IADDR_TRD;
iaddr |= (reg & SV_IADDR_MASK);
sv_write (sc, SV_CODEC_IADDR, iaddr);
sv_write (sc, SV_CODEC_IDATA, val);
}
int
sv_match(parent, match, aux)
struct device *parent;
void *match, *aux;
{
struct pci_attach_args *pa = aux;
if (PCI_VENDOR(pa->pa_id) == PCI_VENDOR_S3 &&
PCI_PRODUCT(pa->pa_id) == PCI_PRODUCT_S3_SONICVIBES)
return (1);
return (0);
}
static void
sv_attach(parent, self, aux)
struct device *parent, *self;
void *aux;
{
struct sv_softc *sc = (struct sv_softc *)self;
struct pci_attach_args *pa = aux;
pci_chipset_tag_t pc = pa->pa_pc;
pci_intr_handle_t ih;
bus_size_t iosize;
char const *intrstr;
u_int32_t dmareg, dmaio;
u_int8_t reg;
sc->sc_pci_chipset_tag = pc;
sc->sc_pci_tag = pa->pa_tag;
/* Map the enhanced port only */
if (pci_mapreg_map(pa, SV_ENHANCED_PORTBASE_SLOT, PCI_MAPREG_TYPE_IO, 0,
&sc->sc_iot, &sc->sc_ioh, NULL, &iosize, 0)) {
printf (": Couldn't map enhanced synth I/O range\n");
return;
}
sc->sc_dmatag = pa->pa_dmat;
dmareg = pci_conf_read(pa->pa_pc, pa->pa_tag, SV_DMAA_CONFIG_OFF);
iosize = 0x10;
dmaio = dmareg & ~(iosize - 1);
if (dmaio) {
dmareg &= 0xF;
if (bus_space_map(sc->sc_iot, dmaio, iosize, 0, &sc->sc_dmaa_ioh)) {
/* The BIOS assigned us some bad I/O address! Make sure to clear
and disable this DMA before we enable the device */
pci_conf_write(pa->pa_pc, pa->pa_tag, SV_DMAA_CONFIG_OFF, 0);
printf (": can't map DMA i/o space\n");
goto enable;
}
pci_conf_write(pa->pa_pc, pa->pa_tag, SV_DMAA_CONFIG_OFF,
dmaio | dmareg |
SV_DMA_CHANNEL_ENABLE | SV_DMAA_EXTENDED_ADDR);
sc->sc_dma_configured |= SV_DMAA_CONFIGURED;
}
dmareg = pci_conf_read(pa->pa_pc, pa->pa_tag, SV_DMAC_CONFIG_OFF);
dmaio = dmareg & ~(iosize - 1);
if (dmaio) {
dmareg &= 0xF;
if (bus_space_map(sc->sc_iot, dmaio, iosize, 0, &sc->sc_dmac_ioh)) {
/* The BIOS assigned us some bad I/O address! Make sure to clear
and disable this DMA before we enable the device */
pci_conf_write (pa->pa_pc, pa->pa_tag, SV_DMAC_CONFIG_OFF,
dmareg & ~SV_DMA_CHANNEL_ENABLE);
printf (": can't map DMA i/o space\n");
goto enable;
}
pci_conf_write(pa->pa_pc, pa->pa_tag, SV_DMAC_CONFIG_OFF,
dmaio | dmareg | SV_DMA_CHANNEL_ENABLE);
sc->sc_dma_configured |= SV_DMAC_CONFIGURED;
}
/* Enable the device. */
enable:
sv_write_indirect(sc, SV_ANALOG_POWER_DOWN_CONTROL, 0);
sv_write_indirect(sc, SV_DIGITAL_POWER_DOWN_CONTROL, 0);
/* initialize codec registers */
reg = sv_read(sc, SV_CODEC_CONTROL);
reg |= SV_CTL_RESET;
sv_write(sc, SV_CODEC_CONTROL, reg);
delay(50);
reg = sv_read(sc, SV_CODEC_CONTROL);
reg &= ~SV_CTL_RESET;
reg |= SV_CTL_INTA | SV_CTL_ENHANCED;
/* This write clears the reset */
sv_write(sc, SV_CODEC_CONTROL, reg);
delay(50);
/* This write actually shoves the new values in */
sv_write(sc, SV_CODEC_CONTROL, reg);
DPRINTF (("reg: %x\n", sv_read(sc, SV_CODEC_CONTROL)));
/* Enable DMA interrupts */
reg = sv_read(sc, SV_CODEC_INTMASK);
reg &= ~(SV_INTMASK_DMAA | SV_INTMASK_DMAC);
reg |= SV_INTMASK_UD | SV_INTMASK_SINT | SV_INTMASK_MIDI;
sv_write(sc, SV_CODEC_INTMASK, reg);
sv_read(sc, SV_CODEC_STATUS);
sc->sc_trd = 0;
sc->sc_enable = 0;
/* Map and establish the interrupt. */
if (pci_intr_map(pa, &ih)) {
printf(": couldn't map interrupt\n");
return;
}
intrstr = pci_intr_string(pc, ih);
sc->sc_ih = pci_intr_establish(pc, ih, IPL_AUDIO, sv_intr, sc,
sc->sc_dev.dv_xname);
if (sc->sc_ih == NULL) {
printf(": couldn't establish interrupt");
if (intrstr != NULL)
printf(" at %s", intrstr);
printf("\n");
return;
}
printf(": %s\n", intrstr);
sv_init_mixer(sc);
audio_attach_mi(&sv_hw_if, sc, &sc->sc_dev);
}
#ifdef AUDIO_DEBUG
void
sv_dumpregs(sc)
struct sv_softc *sc;
{
int idx;
{ int idx;
for (idx = 0; idx < 0x50; idx += 4) {
printf ("%02x = %x\n", idx, pci_conf_read(sc->sc_pci_chipset_tag,
sc->sc_pci_tag, idx));
}
}
for (idx = 0; idx < 6; idx++) {
printf ("REG %02x = %02x\n", idx, sv_read(sc, idx));
}
for (idx = 0; idx < 0x32; idx++) {
printf ("IREG %02x = %02x\n", idx, sv_read_indirect(sc, idx));
}
for (idx = 0; idx < 0x10; idx++) {
printf ("DMA %02x = %02x\n", idx,
bus_space_read_1(sc->sc_iot, sc->sc_dmaa_ioh, idx));
}
return;
}
#endif
int
sv_intr(p)
void *p;
{
struct sv_softc *sc = p;
u_int8_t intr;
intr = sv_read(sc, SV_CODEC_STATUS);
if (!(intr & (SV_INTSTATUS_DMAA | SV_INTSTATUS_DMAC)))
return (0);
if (intr & SV_INTSTATUS_DMAA) {
if (sc->sc_pintr)
sc->sc_pintr(sc->sc_parg);
}
if (intr & SV_INTSTATUS_DMAC) {
if (sc->sc_rintr)
sc->sc_rintr(sc->sc_rarg);
}
return (1);
}
int
sv_allocmem(sc, size, align, p)
struct sv_softc *sc;
size_t size;
size_t align;
struct sv_dma *p;
{
int error;
p->size = size;
error = bus_dmamem_alloc(sc->sc_dmatag, p->size, align, 0,
p->segs, ARRAY_SIZE(p->segs),
&p->nsegs, BUS_DMA_NOWAIT);
if (error)
return (error);
error = bus_dmamem_map(sc->sc_dmatag, p->segs, p->nsegs, p->size,
&p->addr, BUS_DMA_NOWAIT|BUS_DMA_COHERENT);
if (error)
goto free;
error = bus_dmamap_create(sc->sc_dmatag, p->size, 1, p->size,
0, BUS_DMA_NOWAIT, &p->map);
if (error)
goto unmap;
error = bus_dmamap_load(sc->sc_dmatag, p->map, p->addr, p->size, NULL,
BUS_DMA_NOWAIT);
if (error)
goto destroy;
return (0);
destroy:
bus_dmamap_destroy(sc->sc_dmatag, p->map);
unmap:
bus_dmamem_unmap(sc->sc_dmatag, p->addr, p->size);
free:
bus_dmamem_free(sc->sc_dmatag, p->segs, p->nsegs);
return (error);
}
int
sv_freemem(sc, p)
struct sv_softc *sc;
struct sv_dma *p;
{
bus_dmamap_unload(sc->sc_dmatag, p->map);
bus_dmamap_destroy(sc->sc_dmatag, p->map);
bus_dmamem_unmap(sc->sc_dmatag, p->addr, p->size);
bus_dmamem_free(sc->sc_dmatag, p->segs, p->nsegs);
return (0);
}
int
sv_open(addr, flags)
void *addr;
int flags;
{
struct sv_softc *sc = addr;
int intr_mask = 0;
u_int8_t reg;
/* Map the DMA channels, if necessary */
if (!(sc->sc_dma_configured & SV_DMAA_CONFIGURED)) {
/* XXX - there seems to be no general way to find an
I/O range */
int dmaio;
int iosize = 0x10;
if (sc->sc_dma_configured & SV_DMAA_TRIED_CONFIGURE)
return (ENXIO);
for (dmaio = 0xa000; dmaio < 0xb000; dmaio += iosize) {
if (!bus_space_map(sc->sc_iot, dmaio, iosize, 0,
&sc->sc_dmaa_ioh)) {
goto found_dmaa;
}
}
sc->sc_dma_configured |= SV_DMAA_TRIED_CONFIGURE;
return (ENXIO);
found_dmaa:
pci_conf_write(sc->sc_pci_chipset_tag, sc->sc_pci_tag,
SV_DMAA_CONFIG_OFF,
dmaio | SV_DMA_CHANNEL_ENABLE
| SV_DMAA_EXTENDED_ADDR);
sc->sc_dma_configured |= SV_DMAA_CONFIGURED;
intr_mask = 1;
}
if (!(sc->sc_dma_configured & SV_DMAC_CONFIGURED)) {
/* XXX - there seems to be no general way to find an
I/O range */
int dmaio;
int iosize = 0x10;
if (sc->sc_dma_configured & SV_DMAC_TRIED_CONFIGURE)
return (ENXIO);
for (dmaio = 0xa000; dmaio < 0xb000; dmaio += iosize) {
if (!bus_space_map(sc->sc_iot, dmaio, iosize, 0,
&sc->sc_dmac_ioh)) {
goto found_dmac;
}
}
sc->sc_dma_configured |= SV_DMAC_TRIED_CONFIGURE;
return (ENXIO);
found_dmac:
pci_conf_write(sc->sc_pci_chipset_tag, sc->sc_pci_tag,
SV_DMAC_CONFIG_OFF,
dmaio | SV_DMA_CHANNEL_ENABLE);
sc->sc_dma_configured |= SV_DMAC_CONFIGURED;
intr_mask = 1;
}
/* Make sure DMA interrupts are enabled */
if (intr_mask) {
reg = sv_read(sc, SV_CODEC_INTMASK);
reg &= ~(SV_INTMASK_DMAA | SV_INTMASK_DMAC);
reg |= SV_INTMASK_UD | SV_INTMASK_SINT | SV_INTMASK_MIDI;
sv_write(sc, SV_CODEC_INTMASK, reg);
}
sc->sc_pintr = 0;
sc->sc_rintr = 0;
return (0);
}
/*
* Close function is called at splaudio().
*/
void
sv_close(addr)
void *addr;
{
struct sv_softc *sc = addr;
sv_halt_in_dma(sc);
sv_halt_out_dma(sc);
sc->sc_pintr = 0;
sc->sc_rintr = 0;
}
int
sv_query_encoding(addr, fp)
void *addr;
struct audio_encoding *fp;
{
switch (fp->index) {
case 0:
strlcpy(fp->name, AudioEulinear, sizeof fp->name);
fp->encoding = AUDIO_ENCODING_ULINEAR;
fp->precision = 8;
fp->flags = 0;
return (0);
case 1:
strlcpy(fp->name, AudioEmulaw, sizeof fp->name);
fp->encoding = AUDIO_ENCODING_ULAW;
fp->precision = 8;
fp->flags = AUDIO_ENCODINGFLAG_EMULATED;
return (0);
case 2:
strlcpy(fp->name, AudioEalaw, sizeof fp->name);
fp->encoding = AUDIO_ENCODING_ALAW;
fp->precision = 8;
fp->flags = AUDIO_ENCODINGFLAG_EMULATED;
return (0);
case 3:
strlcpy(fp->name, AudioEslinear, sizeof fp->name);
fp->encoding = AUDIO_ENCODING_SLINEAR;
fp->precision = 8;
fp->flags = AUDIO_ENCODINGFLAG_EMULATED;
return (0);
case 4:
strlcpy(fp->name, AudioEslinear_le, sizeof fp->name);
fp->encoding = AUDIO_ENCODING_SLINEAR_LE;
fp->precision = 16;
fp->flags = 0;
return (0);
case 5:
strlcpy(fp->name, AudioEulinear_le, sizeof fp->name);
fp->encoding = AUDIO_ENCODING_ULINEAR_LE;
fp->precision = 16;
fp->flags = AUDIO_ENCODINGFLAG_EMULATED;
return (0);
case 6:
strlcpy(fp->name, AudioEslinear_be, sizeof fp->name);
fp->encoding = AUDIO_ENCODING_SLINEAR_BE;
fp->precision = 16;
fp->flags = AUDIO_ENCODINGFLAG_EMULATED;
return (0);
case 7:
strlcpy(fp->name, AudioEulinear_be, sizeof fp->name);
fp->encoding = AUDIO_ENCODING_ULINEAR_BE;
fp->precision = 16;
fp->flags = AUDIO_ENCODINGFLAG_EMULATED;
return (0);
default:
return (EINVAL);
}
}
int
sv_set_params(addr, setmode, usemode, p, r)
void *addr;
int setmode, usemode;
struct audio_params *p, *r;
{
struct sv_softc *sc = addr;
void (*pswcode)(void *, u_char *buf, int cnt);
void (*rswcode)(void *, u_char *buf, int cnt);
u_int32_t mode, val;
u_int8_t reg;
pswcode = rswcode = 0;
switch (p->encoding) {
case AUDIO_ENCODING_SLINEAR_BE:
if (p->precision == 16)
rswcode = pswcode = swap_bytes;
else
pswcode = rswcode = change_sign8;
break;
case AUDIO_ENCODING_SLINEAR_LE:
if (p->precision != 16)
pswcode = rswcode = change_sign8;
break;
case AUDIO_ENCODING_ULINEAR_BE:
if (p->precision == 16) {
pswcode = swap_bytes_change_sign16;
rswcode = change_sign16_swap_bytes;
}
break;
case AUDIO_ENCODING_ULINEAR_LE:
if (p->precision == 16)
pswcode = rswcode = change_sign16;
break;
case AUDIO_ENCODING_ULAW:
pswcode = mulaw_to_ulinear8;
rswcode = ulinear8_to_mulaw;
break;
case AUDIO_ENCODING_ALAW:
pswcode = alaw_to_ulinear8;
rswcode = ulinear8_to_alaw;
break;
default:
return (EINVAL);
}
if (p->precision == 16)
mode = SV_DMAA_FORMAT16 | SV_DMAC_FORMAT16;
else
mode = 0;
if (p->channels == 2)
mode |= SV_DMAA_STEREO | SV_DMAC_STEREO;
else if (p->channels != 1)
return (EINVAL);
if (p->sample_rate < 2000 || p->sample_rate > 48000)
return (EINVAL);
p->sw_code = pswcode;
r->sw_code = rswcode;
/* Set the encoding */
reg = sv_read_indirect(sc, SV_DMA_DATA_FORMAT);
reg &= ~(SV_DMAA_FORMAT16 | SV_DMAC_FORMAT16 | SV_DMAA_STEREO |
SV_DMAC_STEREO);
reg |= (mode);
sv_write_indirect(sc, SV_DMA_DATA_FORMAT, reg);
val = p->sample_rate * 65536 / 48000;
sv_write_indirect(sc, SV_PCM_SAMPLE_RATE_0, (val & 0xff));
sv_write_indirect(sc, SV_PCM_SAMPLE_RATE_1, (val >> 8));
#define F_REF 24576000
if (setmode & AUMODE_RECORD)
{
/* The ADC reference frequency (f_out) is 512 * the sample rate */
/* f_out is dervied from the 24.576MHZ crystal by three values:
M & N & R. The equation is as follows:
f_out = (m + 2) * f_ref / ((n + 2) * (2 ^ a))
with the constraint that:
80 MhZ < (m + 2) / (n + 2) * f_ref <= 150MHz
and n, m >= 1
*/
int goal_f_out = 512 * r->sample_rate;
int a, n, m, best_n, best_m, best_error = 10000000;
int pll_sample;
for (a = 0; a < 8; a++) {
if ((goal_f_out * (1 << a)) >= 80000000)
break;
}
/* a != 8 because sample_rate >= 2000 */
for (n = 33; n > 2; n--) {
int error;
m = (goal_f_out * n * (1 << a)) / F_REF;
if ((m > 257) || (m < 3)) continue;
pll_sample = (m * F_REF) / (n * (1 << a));
pll_sample /= 512;
/* Threshold might be good here */
error = pll_sample - r->sample_rate;
error = abs(error);
if (error < best_error) {
best_error = error;
best_n = n;
best_m = m;
if (error == 0) break;
}
}
best_n -= 2;
best_m -= 2;
sv_write_indirect(sc, SV_ADC_PLL_M, best_m);
sv_write_indirect(sc, SV_ADC_PLL_N, best_n | (a << SV_PLL_R_SHIFT));
}
return (0);
}
int
sv_round_blocksize(addr, blk)
void *addr;
int blk;
{
return ((blk + 31) & -32); /* keep good alignment */
}
int
sv_dma_init_input(addr, buf, cc)
void *addr;
void *buf;
int cc;
{
struct sv_softc *sc = addr;
struct sv_dma *p;
int dma_count;
DPRINTF(("sv_dma_init_input: dma start loop input addr=%p cc=%d\n",
buf, cc));
for (p = sc->sc_dmas; p && KERNADDR(p) != buf; p = p->next)
;
if (!p) {
printf("sv_dma_init_input: bad addr %p\n", buf);
return (EINVAL);
}
dma_count = (cc >> 1) - 1;
bus_space_write_4(sc->sc_iot, sc->sc_dmac_ioh, SV_DMA_ADDR0,
DMAADDR(p));
bus_space_write_4(sc->sc_iot, sc->sc_dmac_ioh, SV_DMA_COUNT0,
dma_count);
bus_space_write_1(sc->sc_iot, sc->sc_dmac_ioh, SV_DMA_MODE,
DMA37MD_WRITE | DMA37MD_LOOP);
return (0);
}
int
sv_dma_init_output(addr, buf, cc)
void *addr;
void *buf;
int cc;
{
struct sv_softc *sc = addr;
struct sv_dma *p;
int dma_count;
DPRINTF(("eap: dma start loop output buf=%p cc=%d\n", buf, cc));
for (p = sc->sc_dmas; p && KERNADDR(p) != buf; p = p->next)
;
if (!p) {
printf("sv_dma_init_output: bad addr %p\n", buf);
return (EINVAL);
}
dma_count = cc - 1;
bus_space_write_4(sc->sc_iot, sc->sc_dmaa_ioh, SV_DMA_ADDR0,
DMAADDR(p));
bus_space_write_4(sc->sc_iot, sc->sc_dmaa_ioh, SV_DMA_COUNT0,
dma_count);
bus_space_write_1(sc->sc_iot, sc->sc_dmaa_ioh, SV_DMA_MODE,
DMA37MD_READ | DMA37MD_LOOP);
return (0);
}
int
sv_dma_output(addr, p, cc, intr, arg)
void *addr;
void *p;
int cc;
void (*intr)(void *);
void *arg;
{
struct sv_softc *sc = addr;
u_int8_t mode;
DPRINTFN(1,
("sv_dma_output: sc=%p buf=%p cc=%d intr=%p(%p)\n",
addr, p, cc, intr, arg));
sc->sc_pintr = intr;
sc->sc_parg = arg;
if (!(sc->sc_enable & SV_PLAY_ENABLE)) {
int dma_count = cc - 1;
sv_write_indirect(sc, SV_DMAA_COUNT1, dma_count >> 8);
sv_write_indirect(sc, SV_DMAA_COUNT0, (dma_count & 0xFF));
mode = sv_read_indirect(sc, SV_PLAY_RECORD_ENABLE);
mode |= SV_PLAY_ENABLE;
sv_write_indirect(sc, SV_PLAY_RECORD_ENABLE, mode);
sc->sc_enable |= SV_PLAY_ENABLE;
}
return (0);
}
int
sv_dma_input(addr, p, cc, intr, arg)
void *addr;
void *p;
int cc;
void (*intr)(void *);
void *arg;
{
struct sv_softc *sc = addr;
u_int8_t mode;
DPRINTFN(1, ("sv_dma_input: sc=%p buf=%p cc=%d intr=%p(%p)\n",
addr, p, cc, intr, arg));
sc->sc_rintr = intr;
sc->sc_rarg = arg;
if (!(sc->sc_enable & SV_RECORD_ENABLE)) {
int dma_count = (cc >> 1) - 1;
sv_write_indirect(sc, SV_DMAC_COUNT1, dma_count >> 8);
sv_write_indirect(sc, SV_DMAC_COUNT0, (dma_count & 0xFF));
mode = sv_read_indirect(sc, SV_PLAY_RECORD_ENABLE);
mode |= SV_RECORD_ENABLE;
sv_write_indirect(sc, SV_PLAY_RECORD_ENABLE, mode);
sc->sc_enable |= SV_RECORD_ENABLE;
}
return (0);
}
int
sv_halt_out_dma(addr)
void *addr;
{
struct sv_softc *sc = addr;
u_int8_t mode;
DPRINTF(("eap: sv_halt_out_dma\n"));
mode = sv_read_indirect(sc, SV_PLAY_RECORD_ENABLE);
mode &= ~SV_PLAY_ENABLE;
sc->sc_enable &= ~SV_PLAY_ENABLE;
sv_write_indirect(sc, SV_PLAY_RECORD_ENABLE, mode);
return (0);
}
int
sv_halt_in_dma(addr)
void *addr;
{
struct sv_softc *sc = addr;
u_int8_t mode;
DPRINTF(("eap: sv_halt_in_dma\n"));
mode = sv_read_indirect(sc, SV_PLAY_RECORD_ENABLE);
mode &= ~SV_RECORD_ENABLE;
sc->sc_enable &= ~SV_RECORD_ENABLE;
sv_write_indirect(sc, SV_PLAY_RECORD_ENABLE, mode);
return (0);
}
int
sv_getdev(addr, retp)
void *addr;
struct audio_device *retp;
{
*retp = sv_device;
return (0);
}
/*
* Mixer related code is here
*
*/
#define SV_INPUT_CLASS 0
#define SV_OUTPUT_CLASS 1
#define SV_RECORD_CLASS 2
#define SV_LAST_CLASS 2
static const char *mixer_classes[] = { AudioCinputs, AudioCoutputs, AudioCrecord };
static const struct {
u_int8_t l_port;
u_int8_t r_port;
u_int8_t mask;
u_int8_t class;
const char *audio;
} ports[] = {
{ SV_LEFT_AUX1_INPUT_CONTROL, SV_RIGHT_AUX1_INPUT_CONTROL, SV_AUX1_MASK,
SV_INPUT_CLASS, "aux1" },
{ SV_LEFT_CD_INPUT_CONTROL, SV_RIGHT_CD_INPUT_CONTROL, SV_CD_MASK,
SV_INPUT_CLASS, AudioNcd },
{ SV_LEFT_LINE_IN_INPUT_CONTROL, SV_RIGHT_LINE_IN_INPUT_CONTROL, SV_LINE_IN_MASK,
SV_INPUT_CLASS, AudioNline },
{ SV_MIC_INPUT_CONTROL, 0, SV_MIC_MASK, SV_INPUT_CLASS, AudioNmicrophone },
{ SV_LEFT_SYNTH_INPUT_CONTROL, SV_RIGHT_SYNTH_INPUT_CONTROL,
SV_SYNTH_MASK, SV_INPUT_CLASS, AudioNfmsynth },
{ SV_LEFT_AUX2_INPUT_CONTROL, SV_RIGHT_AUX2_INPUT_CONTROL, SV_AUX2_MASK,
SV_INPUT_CLASS, "aux2" },
{ SV_LEFT_PCM_INPUT_CONTROL, SV_RIGHT_PCM_INPUT_CONTROL, SV_PCM_MASK,
SV_INPUT_CLASS, AudioNdac },
{ SV_LEFT_MIXER_OUTPUT_CONTROL, SV_RIGHT_MIXER_OUTPUT_CONTROL,
SV_MIXER_OUT_MASK, SV_OUTPUT_CLASS, AudioNmaster }
};
static const struct {
int idx;
const char *name;
} record_sources[] = {
{ SV_REC_CD, AudioNcd },
{ SV_REC_DAC, AudioNdac },
{ SV_REC_AUX2, "aux2" },
{ SV_REC_LINE, AudioNline },
{ SV_REC_AUX1, "aux1" },
{ SV_REC_MIC, AudioNmicrophone },
{ SV_REC_MIXER, AudioNmixerout }
};
#define SV_DEVICES_PER_PORT 2
#define SV_FIRST_MIXER (SV_LAST_CLASS + 1)
#define SV_LAST_MIXER (SV_DEVICES_PER_PORT * (ARRAY_SIZE(ports)) + SV_LAST_CLASS)
#define SV_RECORD_SOURCE (SV_LAST_MIXER + 1)
#define SV_MIC_BOOST (SV_LAST_MIXER + 2)
#define SV_RECORD_GAIN (SV_LAST_MIXER + 3)
#define SV_SRS_MODE (SV_LAST_MIXER + 4)
int
sv_query_devinfo(addr, dip)
void *addr;
mixer_devinfo_t *dip;
{
/* It's a class */
if (dip->index <= SV_LAST_CLASS) {
dip->type = AUDIO_MIXER_CLASS;
dip->mixer_class = dip->index;
dip->next = dip->prev = AUDIO_MIXER_LAST;
strlcpy(dip->label.name, mixer_classes[dip->index],
sizeof dip->label.name);
return (0);
}
if (dip->index >= SV_FIRST_MIXER &&
dip->index <= SV_LAST_MIXER) {
int off = dip->index - SV_FIRST_MIXER;
int mute = (off % SV_DEVICES_PER_PORT);
int idx = off / SV_DEVICES_PER_PORT;
dip->mixer_class = ports[idx].class;
strlcpy(dip->label.name, ports[idx].audio, sizeof dip->label.name);
if (!mute) {
dip->type = AUDIO_MIXER_VALUE;
dip->prev = AUDIO_MIXER_LAST;
dip->next = dip->index + 1;
if (ports[idx].r_port != 0)
dip->un.v.num_channels = 2;
else
dip->un.v.num_channels = 1;
strlcpy(dip->un.v.units.name, AudioNvolume, sizeof dip->un.v.units.name);
} else {
dip->type = AUDIO_MIXER_ENUM;
dip->prev = dip->index - 1;
dip->next = AUDIO_MIXER_LAST;
strlcpy(dip->label.name, AudioNmute, sizeof dip->label.name);
dip->un.e.num_mem = 2;
strlcpy(dip->un.e.member[0].label.name, AudioNoff,
sizeof dip->un.e.member[0].label.name);
dip->un.e.member[0].ord = 0;
strlcpy(dip->un.e.member[1].label.name, AudioNon,
sizeof dip->un.e.member[1].label.name);
dip->un.e.member[1].ord = 1;
}
return (0);
}
switch (dip->index) {
case SV_RECORD_SOURCE:
dip->mixer_class = SV_RECORD_CLASS;
dip->prev = AUDIO_MIXER_LAST;
dip->next = SV_RECORD_GAIN;
strlcpy(dip->label.name, AudioNsource, sizeof dip->label.name);
dip->type = AUDIO_MIXER_ENUM;
dip->un.e.num_mem = ARRAY_SIZE(record_sources);
{
int idx;
for (idx = 0; idx < ARRAY_SIZE(record_sources); idx++) {
strlcpy(dip->un.e.member[idx].label.name, record_sources[idx].name,
sizeof dip->un.e.member[idx].label.name);
dip->un.e.member[idx].ord = record_sources[idx].idx;
}
}
return (0);
case SV_RECORD_GAIN:
dip->mixer_class = SV_RECORD_CLASS;
dip->prev = SV_RECORD_SOURCE;
dip->next = AUDIO_MIXER_LAST;
strlcpy(dip->label.name, "gain", sizeof dip->label.name);
dip->type = AUDIO_MIXER_VALUE;
dip->un.v.num_channels = 1;
strlcpy(dip->un.v.units.name, AudioNvolume, sizeof dip->un.v.units.name);
return (0);
case SV_MIC_BOOST:
dip->mixer_class = SV_RECORD_CLASS;
dip->prev = AUDIO_MIXER_LAST;
dip->next = AUDIO_MIXER_LAST;
strlcpy(dip->label.name, "micboost", sizeof dip->label.name);
goto on_off;
case SV_SRS_MODE:
dip->mixer_class = SV_OUTPUT_CLASS;
dip->prev = dip->next = AUDIO_MIXER_LAST;
strlcpy(dip->label.name, AudioNspatial, sizeof dip->label.name);
on_off:
dip->type = AUDIO_MIXER_ENUM;
dip->un.e.num_mem = 2;
strlcpy(dip->un.e.member[0].label.name, AudioNoff,
sizeof dip->un.e.member[0].label.name);
dip->un.e.member[0].ord = 0;
strlcpy(dip->un.e.member[1].label.name, AudioNon,
sizeof dip->un.e.member[1].label.name);
dip->un.e.member[1].ord = 1;
return (0);
}
return (ENXIO);
}
int
sv_mixer_set_port(addr, cp)
void *addr;
mixer_ctrl_t *cp;
{
struct sv_softc *sc = addr;
u_int8_t reg;
int idx;
if (cp->dev >= SV_FIRST_MIXER &&
cp->dev <= SV_LAST_MIXER) {
int off = cp->dev - SV_FIRST_MIXER;
int mute = (off % SV_DEVICES_PER_PORT);
idx = off / SV_DEVICES_PER_PORT;
if (mute) {
if (cp->type != AUDIO_MIXER_ENUM)
return (EINVAL);
reg = sv_read_indirect(sc, ports[idx].l_port);
if (cp->un.ord)
reg |= SV_MUTE_BIT;
else
reg &= ~SV_MUTE_BIT;
sv_write_indirect(sc, ports[idx].l_port, reg);
if (ports[idx].r_port) {
reg = sv_read_indirect(sc, ports[idx].r_port);
if (cp->un.ord)
reg |= SV_MUTE_BIT;
else
reg &= ~SV_MUTE_BIT;
sv_write_indirect(sc, ports[idx].r_port, reg);
}
} else {
int lval, rval;
if (cp->type != AUDIO_MIXER_VALUE)
return (EINVAL);
if (cp->un.value.num_channels != 1 &&
cp->un.value.num_channels != 2)
return (EINVAL);
if (ports[idx].r_port == 0) {
if (cp->un.value.num_channels != 1)
return (EINVAL);
lval = cp->un.value.level[AUDIO_MIXER_LEVEL_MONO];
} else {
if (cp->un.value.num_channels != 2)
return (EINVAL);
lval = cp->un.value.level[AUDIO_MIXER_LEVEL_LEFT];
rval = cp->un.value.level[AUDIO_MIXER_LEVEL_RIGHT];
}
sc->sc_trd = 1;
reg = sv_read_indirect(sc, ports[idx].l_port);
reg &= ~(ports[idx].mask);
lval = ((AUDIO_MAX_GAIN - lval) * ports[idx].mask) / AUDIO_MAX_GAIN;
reg |= lval;
sv_write_indirect(sc, ports[idx].l_port, reg);
if (ports[idx].r_port != 0) {
reg = sv_read_indirect(sc, ports[idx].r_port);
reg &= ~(ports[idx].mask);
rval = ((AUDIO_MAX_GAIN - rval) * ports[idx].mask) / AUDIO_MAX_GAIN;
reg |= rval;
sv_write_indirect(sc, ports[idx].r_port, reg);
}
sc->sc_trd = 0;
sv_read_indirect(sc, ports[idx].l_port);
}
return (0);
}
switch (cp->dev) {
case SV_RECORD_SOURCE:
if (cp->type != AUDIO_MIXER_ENUM)
return (EINVAL);
for (idx = 0; idx < ARRAY_SIZE(record_sources); idx++) {
if (record_sources[idx].idx == cp->un.ord)
goto found;
}
return (EINVAL);
found:
reg = sv_read_indirect(sc, SV_LEFT_ADC_INPUT_CONTROL);
reg &= ~SV_REC_SOURCE_MASK;
reg |= (((cp->un.ord) << SV_REC_SOURCE_SHIFT) & SV_REC_SOURCE_MASK);
sv_write_indirect(sc, SV_LEFT_ADC_INPUT_CONTROL, reg);
reg = sv_read_indirect(sc, SV_RIGHT_ADC_INPUT_CONTROL);
reg &= ~SV_REC_SOURCE_MASK;
reg |= (((cp->un.ord) << SV_REC_SOURCE_SHIFT) & SV_REC_SOURCE_MASK);
sv_write_indirect(sc, SV_RIGHT_ADC_INPUT_CONTROL, reg);
return (0);
case SV_RECORD_GAIN:
{
int val;
if (cp->type != AUDIO_MIXER_VALUE)
return (EINVAL);
if (cp->un.value.num_channels != 1)
return (EINVAL);
val = (cp->un.value.level[AUDIO_MIXER_LEVEL_MONO] * SV_REC_GAIN_MASK)
/ AUDIO_MAX_GAIN;
reg = sv_read_indirect(sc, SV_LEFT_ADC_INPUT_CONTROL);
reg &= ~SV_REC_GAIN_MASK;
reg |= val;
sv_write_indirect(sc, SV_LEFT_ADC_INPUT_CONTROL, reg);
reg = sv_read_indirect(sc, SV_RIGHT_ADC_INPUT_CONTROL);
reg &= ~SV_REC_GAIN_MASK;
reg |= val;
sv_write_indirect(sc, SV_RIGHT_ADC_INPUT_CONTROL, reg);
}
return (0);
case SV_MIC_BOOST:
if (cp->type != AUDIO_MIXER_ENUM)
return (EINVAL);
reg = sv_read_indirect(sc, SV_LEFT_ADC_INPUT_CONTROL);
if (cp->un.ord) {
reg |= SV_MIC_BOOST_BIT;
} else {
reg &= ~SV_MIC_BOOST_BIT;
}
sv_write_indirect(sc, SV_LEFT_ADC_INPUT_CONTROL, reg);
return (0);
case SV_SRS_MODE:
if (cp->type != AUDIO_MIXER_ENUM)
return (EINVAL);
reg = sv_read_indirect(sc, SV_SRS_SPACE_CONTROL);
if (cp->un.ord) {
reg &= ~SV_SRS_SPACE_ONOFF;
} else {
reg |= SV_SRS_SPACE_ONOFF;
}
sv_write_indirect(sc, SV_SRS_SPACE_CONTROL, reg);
return (0);
}
return (EINVAL);
}
int
sv_mixer_get_port(addr, cp)
void *addr;
mixer_ctrl_t *cp;
{
struct sv_softc *sc = addr;
int val;
u_int8_t reg;
if (cp->dev >= SV_FIRST_MIXER &&
cp->dev <= SV_LAST_MIXER) {
int off = cp->dev - SV_FIRST_MIXER;
int mute = (off % 2);
int idx = off / 2;
if (mute) {
if (cp->type != AUDIO_MIXER_ENUM)
return (EINVAL);
reg = sv_read_indirect(sc, ports[idx].l_port);
cp->un.ord = ((reg & SV_MUTE_BIT) ? 1 : 0);
} else {
if (cp->type != AUDIO_MIXER_VALUE)
return (EINVAL);
if (cp->un.value.num_channels != 1 &&
cp->un.value.num_channels != 2)
return (EINVAL);
if ((ports[idx].r_port == 0 &&
cp->un.value.num_channels != 1) ||
(ports[idx].r_port != 0 &&
cp->un.value.num_channels != 2))
return (EINVAL);
reg = sv_read_indirect(sc, ports[idx].l_port);
reg &= ports[idx].mask;
val = AUDIO_MAX_GAIN - ((reg * AUDIO_MAX_GAIN) / ports[idx].mask);
if (ports[idx].r_port != 0) {
cp->un.value.level[AUDIO_MIXER_LEVEL_LEFT] = val;
reg = sv_read_indirect(sc, ports[idx].r_port);
reg &= ports[idx].mask;
val = AUDIO_MAX_GAIN - ((reg * AUDIO_MAX_GAIN) / ports[idx].mask);
cp->un.value.level[AUDIO_MIXER_LEVEL_RIGHT] = val;
} else
cp->un.value.level[AUDIO_MIXER_LEVEL_MONO] = val;
}
return (0);
}
switch (cp->dev) {
case SV_RECORD_SOURCE:
if (cp->type != AUDIO_MIXER_ENUM)
return (EINVAL);
reg = sv_read_indirect(sc, SV_LEFT_ADC_INPUT_CONTROL);
cp->un.ord = ((reg & SV_REC_SOURCE_MASK) >> SV_REC_SOURCE_SHIFT);
return (0);
case SV_RECORD_GAIN:
if (cp->type != AUDIO_MIXER_VALUE)
return (EINVAL);
if (cp->un.value.num_channels != 1)
return (EINVAL);
reg = sv_read_indirect(sc, SV_LEFT_ADC_INPUT_CONTROL) & SV_REC_GAIN_MASK;
cp->un.value.level[AUDIO_MIXER_LEVEL_MONO] =
(((unsigned int)reg) * AUDIO_MAX_GAIN) / SV_REC_GAIN_MASK;
return (0);
case SV_MIC_BOOST:
if (cp->type != AUDIO_MIXER_ENUM)
return (EINVAL);
reg = sv_read_indirect(sc, SV_LEFT_ADC_INPUT_CONTROL);
cp->un.ord = ((reg & SV_MIC_BOOST_BIT) ? 1 : 0);
return (0);
case SV_SRS_MODE:
if (cp->type != AUDIO_MIXER_ENUM)
return (EINVAL);
reg = sv_read_indirect(sc, SV_SRS_SPACE_CONTROL);
cp->un.ord = ((reg & SV_SRS_SPACE_ONOFF) ? 0 : 1);
return (0);
}
return (EINVAL);
}
static void
sv_init_mixer(sc)
struct sv_softc *sc;
{
mixer_ctrl_t cp;
int idx;
cp.type = AUDIO_MIXER_ENUM;
cp.dev = SV_SRS_MODE;
cp.un.ord = 0;
sv_mixer_set_port(sc, &cp);
for (idx = 0; idx < ARRAY_SIZE(ports); idx++) {
if (ports[idx].audio == AudioNdac) {
cp.type = AUDIO_MIXER_ENUM;
cp.dev = SV_FIRST_MIXER + idx * SV_DEVICES_PER_PORT + 1;
cp.un.ord = 0;
sv_mixer_set_port(sc, &cp);
break;
}
}
}
void *
sv_malloc(addr, direction, size, pool, flags)
void *addr;
int direction;
size_t size;
int pool;
int flags;
{
struct sv_softc *sc = addr;
struct sv_dma *p;
int error;
p = malloc(sizeof(*p), pool, flags);
if (!p)
return (0);
error = sv_allocmem(sc, size, 16, p);
if (error) {
free(p, pool);
return (0);
}
p->next = sc->sc_dmas;
sc->sc_dmas = p;
return (KERNADDR(p));
}
void
sv_free(addr, ptr, pool)
void *addr;
void *ptr;
int pool;
{
struct sv_softc *sc = addr;
struct sv_dma **p;
for (p = &sc->sc_dmas; *p; p = &(*p)->next) {
if (KERNADDR(*p) == ptr) {
sv_freemem(sc, *p);
*p = (*p)->next;
free(*p, pool);
return;
}
}
}
paddr_t
sv_mappage(addr, mem, off, prot)
void *addr;
void *mem;
off_t off;
int prot;
{
struct sv_softc *sc = addr;
struct sv_dma *p;
for (p = sc->sc_dmas; p && KERNADDR(p) != mem; p = p->next)
;
if (!p)
return (-1);
return (bus_dmamem_mmap(sc->sc_dmatag, p->segs, p->nsegs,
off, prot, BUS_DMA_WAITOK));
}
int
sv_get_props(addr)
void *addr;
{
return (AUDIO_PROP_MMAP | AUDIO_PROP_FULLDUPLEX);
}