/*
* 86Box A hypervisor and IBM PC system emulator that specializes in
* running old operating systems and software designed for IBM
* PC systems and compatibles from 1981 through fairly recent
* system designs based on the PCI bus.
*
* This file is part of the 86Box distribution.
*
* AD1848 / CS4248 / CS4231 (Windows Sound System) codec emulation.
*
*
*
* Authors: Sarah Walker,
* TheCollector1995,
* RichardG,
*
* Copyright 2008-2020 Sarah Walker.
* Copyright 2018-2020 TheCollector1995.
* Copyright 2021-2025 RichardG.
*/
#include
#include
#include
#include
#include
#include
#define HAVE_STDARG_H
#include <86box/86box.h>
#include <86box/dma.h>
#include <86box/pic.h>
#include <86box/timer.h>
#include <86box/sound.h>
#include <86box/snd_ad1848.h>
#include <86box/plat_fallthrough.h>
#define CS4231 0x80
#define CS4232 0x02
#define CS4236 0x03
#ifdef ENABLE_AD1848_LOG
int ad1848_do_log = ENABLE_AD1848_LOG;
static void
ad1848_log(const char *fmt, ...)
{
va_list ap;
if (ad1848_do_log) {
va_start(ap, fmt);
pclog_ex(fmt, ap);
va_end(ap);
}
}
#else
# define ad1848_log(fmt, ...)
#endif
static int ad1848_vols_7bits[128];
static double ad1848_vols_5bits_aux_gain[32];
/* Borrowed from snd_sb_dsp */
extern int8_t scaleMap4[64];
extern uint8_t adjustMap4[64];
void
ad1848_setirq(ad1848_t *ad1848, int irq)
{
ad1848_log("AD1848: setirq(%d)\n", irq);
ad1848->irq = irq;
}
void
ad1848_setdma(ad1848_t *ad1848, int newdma)
{
ad1848_log("AD1848: setdma(%d)\n", newdma);
ad1848->dma = newdma;
}
void
ad1848_updatevolmask(ad1848_t *ad1848)
{
if ((ad1848->type == AD1848_TYPE_CS4236B) && !(ad1848->xregs[4] & 0x10) && !ad1848->wten)
ad1848->wave_vol_mask = 0x7f;
else
ad1848->wave_vol_mask = 0x3f;
ad1848_log("AD1848: updatevolmask(%02X)\n", ad1848->wave_vol_mask);
}
static double
ad1848_get_default_freq(ad1848_t *ad1848)
{
double freq = (ad1848->regs[8] & 1) ? 16934400.0 : 24576000.0;
switch ((ad1848->regs[8] >> 1) & 7) {
default:
break;
case 0:
freq /= 3072.0;
break;
case 1:
freq /= 1536.0;
break;
case 2:
freq /= 896.0;
break;
case 3:
freq /= 768.0;
break;
case 4:
freq /= 448.0;
break;
case 5:
freq /= 384.0;
break;
case 6:
freq /= 512.0;
break;
case 7:
freq /= 2560.0;
break;
}
ad1848_log("AD1848: Frequency %f through default path\n", freq);
return freq;
}
static void
ad1848_updatefreq(ad1848_t *ad1848)
{
double freq;
if (ad1848->type >= AD1848_TYPE_CS4232) {
if (ad1848->xregs[11] & 0x20) { /* CS4236B+ only */
freq = 16934400.0;
switch (ad1848->xregs[13]) {
default:
freq /= 16.0 * MAX(ad1848->xregs[13], 21);
break;
case 1:
freq /= 353.0;
break;
case 2:
freq /= 529.0;
break;
case 3:
freq /= 617.0;
break;
case 4:
freq /= 1058.0;
break;
case 5:
freq /= 1764.0;
break;
case 6:
freq /= 2117.0;
break;
case 7:
freq /= 2558.0;
break;
}
ad1848_log("AD1848: Frequency %f through CS4236B+ path\n", freq);
} else if (ad1848->regs[22] & 0x80) {
const uint8_t set = (ad1848->regs[22] >> 1) & 0x3f;
freq = (ad1848->regs[22] & 1) ? 33868800.0 : 49152000.0;
switch (ad1848->regs[10] & 0x30) {
default:
break;
case 0x00:
freq /= 128 * set;
break;
case 0x10:
freq /= 64 * set;
break;
case 0x20:
freq /= 256 * set;
break;
}
ad1848_log("AD1848: Frequency %f through CS4232+ path\n", freq);
} else
freq = ad1848_get_default_freq(ad1848);
} else
freq = ad1848_get_default_freq(ad1848);
ad1848->freq = (int) trunc(freq);
ad1848->timer_latch = (uint64_t) ((double) TIMER_USEC * (1000000.0 / (double) ad1848->freq));
}
uint8_t
ad1848_read(uint16_t addr, void *priv)
{
ad1848_t *ad1848 = (ad1848_t *) priv;
uint8_t ret = 0xff;
uint8_t temp = 0;
switch (addr & 3) {
case 0: /* Index */
ret = ad1848->index | ad1848->trd | ad1848->mce;
break;
case 1:
ret = ad1848->regs[ad1848->index];
switch (ad1848->index) {
case 11:
ret ^= 0x20;
ad1848->regs[ad1848->index] = ret;
break;
case 18 ... 19:
if (ad1848->type >= AD1848_TYPE_CS4236B) {
if ((ad1848->xregs[4] & 0x14) == 0x14) /* FM remapping */
ret = ad1848->xregs[6 | (ad1848->index & 1)]; /* real FM volume on registers 6 and 7 */
else if (ad1848->wten && !(ad1848->xregs[4] & 0x08)) /* wavetable remapping */
ret = ad1848->xregs[16 | (ad1848->index & 1)]; /* real wavetable volume on registers 16 and 17 */
}
break;
case 20 ... 21:
/* Backdoor to the Control/RAM registers on CS4235+. */
if ((ad1848->type >= AD1848_TYPE_CS4235) && (ad1848->xregs[18] & 0x80))
ret = ad1848->cram_read(ad1848->index - 15, ad1848->cram_priv);
break;
case 23:
if ((ad1848->type >= AD1848_TYPE_CS4236B) && (ad1848->regs[23] & 0x08)) {
ret = ad1848->xregs[ad1848->xindex];
switch (ad1848->xindex) {
case 0 ... 1:
/* Remapped line volume. */
ret = ad1848->regs[18 + ad1848->xindex];
break;
case 23 ... 24:
case 29:
/* Backdoor to control indirect registers on CS4235+. */
if (ad1848->type >= AD1848_TYPE_CS4235) {
temp = ad1848->cram_read(3, ad1848->cram_priv);
ad1848->cram_write(3, (ad1848->xindex == 23) ? 2 : ((ad1848->xindex == 24) ? 8 : 9), ad1848->cram_priv);
ret = ad1848->cram_read(4, ad1848->cram_priv);
ad1848->cram_write(3, temp, ad1848->cram_priv);
}
break;
case 26 ... 28:
case 30:
/* Backdoor to control registers on CS4235+. */
if (ad1848->type >= AD1848_TYPE_CS4235)
ret = ad1848->cram_read((ad1848->xindex == 30) ? 7 : (ad1848->xindex - 26), ad1848->cram_priv);
break;
default:
break;
}
ad1848_log("AD1848: read(X%d) = %02X\n", ad1848->xindex, ret);
return ret;
}
break;
default:
break;
}
ad1848_log("AD1848: read(I%d) = %02X\n", ad1848->index, ret);
return ret;
case 2:
ret = ad1848->status;
break;
default:
break;
}
ad1848_log("AD1848: read(%04X) = %02X\n", addr, ret);
return ret;
}
void
ad1848_write(uint16_t addr, uint8_t val, void *priv)
{
ad1848_t *ad1848 = (ad1848_t *) priv;
uint8_t temp = 0;
uint8_t updatefreq = 0;
switch (addr & 3) {
case 0: /* Index */
if ((ad1848->regs[12] & 0x40) && (ad1848->type >= AD1848_TYPE_CS4231))
ad1848->index = val & 0x1f; /* cs4231a extended mode enabled */
else
ad1848->index = val & 0x0f; /* ad1848/cs4248 mode TODO: some variants/clones DO NOT mirror, just ignore the writes? */
if (ad1848->type >= AD1848_TYPE_CS4236B)
ad1848->regs[23] &= ~0x08; /* clear XRAE */
ad1848->trd = val & 0x20;
ad1848->mce = val & 0x40;
break;
case 1:
switch (ad1848->index) {
case 10:
if (ad1848->type < AD1848_TYPE_CS4232)
break;
fallthrough;
case 8:
updatefreq = 1;
break;
case 9:
if (!ad1848->enable && (val & 0x41) == 0x01) {
ad1848->adpcm_pos = 0;
ad1848->dma_ff = 0;
if (ad1848->timer_latch)
timer_set_delay_u64(&ad1848->timer_count, ad1848->timer_latch);
else
timer_set_delay_u64(&ad1848->timer_count, TIMER_USEC);
}
ad1848->enable = ((val & 0x41) == 0x01);
if (!ad1848->enable) {
timer_disable(&ad1848->timer_count);
ad1848->out_l = ad1848->out_r = 0;
}
break;
case 11:
goto readonly_i;
case 12:
if (ad1848->type >= AD1848_TYPE_CS4248) {
ad1848->regs[12] = 0x80 | (val & 0x70) | (ad1848->regs[12] & 0x0f);
if ((ad1848->type >= AD1848_TYPE_CS4231) && (ad1848->type < AD1848_TYPE_CS4235)) {
if (val & 0x40)
ad1848->fmt_mask |= 0x80;
else
ad1848->fmt_mask &= ~0x80;
}
}
goto readonly_i;
case 14:
ad1848->count = ad1848->regs[15] | (val << 8);
break;
case 18 ... 19:
if (ad1848->type >= AD1848_TYPE_CS4236B) {
if (ad1848->type >= AD1848_TYPE_CS4235) {
if (ad1848->xregs[18] & 0x20) /* AUX1 remapping */
ad1848->regs[ad1848->index & 3] = val; /* also controls AUX1 on registers 2 and 3 */
} else {
temp = 0;
if ((ad1848->xregs[4] & 0x14) == 0x14) { /* FM remapping */
ad1848->xregs[6 | (ad1848->index & 1)] = val; /* real FM volume on extended registers 6 and 7 */
temp = 1;
if (ad1848->index == 18) {
if (val & 0x80)
ad1848->fm_vol_l = 0;
else
ad1848->fm_vol_l = ad1848_vols_7bits[val & 0x3f];
} else {
if (val & 0x80)
ad1848->fm_vol_r = 0;
else
ad1848->fm_vol_r = ad1848_vols_7bits[val & 0x3f];
}
}
if (ad1848->wten && !(ad1848->xregs[4] & 0x08)) { /* wavetable remapping */
ad1848->xregs[16 | (ad1848->index & 1)] = val; /* real wavetable volume on extended registers 16 and 17 */
temp = 1;
}
/* Stop here if any remapping is enabled. */
if (temp)
goto readonly_i;
}
/* HACK: the Windows 9x driver's "Synth" control writes to this
register with no remapping, even if internal FM is enabled. */
if (ad1848->index == 18) {
if (val & 0x80)
ad1848->fm_vol_l = 0;
else
ad1848->fm_vol_l = (int) ad1848_vols_5bits_aux_gain[val & 0x1f];
} else {
if (val & 0x80)
ad1848->fm_vol_r = 0;
else
ad1848->fm_vol_r = (int) ad1848_vols_5bits_aux_gain[val & 0x1f];
}
}
break;
case 20 ... 21:
/* Backdoor to the Control/RAM registers on CS4235+. */
if ((ad1848->type >= AD1848_TYPE_CS4235) && (ad1848->xregs[18] & 0x80)) {
ad1848->cram_write(ad1848->index - 15, val, ad1848->cram_priv);
val = ad1848->regs[ad1848->index];
}
break;
case 22:
updatefreq = 1;
break;
case 23:
if ((ad1848->type >= AD1848_TYPE_CS4236B) && ((ad1848->regs[12] & 0x60) == 0x60)) {
if (!(ad1848->regs[23] & 0x08)) { /* existing (not new) XRAE is clear */
ad1848->xindex = ((val & 0x04) << 2) | (val >> 4);
break;
}
switch (ad1848->xindex) {
case 0 ... 1:
if (ad1848->type < AD1848_TYPE_CS4235) {
/* Remapped line volume. */
ad1848->regs[18 | ad1848->xindex] = val;
}
break;
case 6:
if (val & 0x80)
ad1848->fm_vol_l = 0;
else
ad1848->fm_vol_l = ad1848_vols_7bits[val & 0x3f];
break;
case 7:
if (val & 0x80)
ad1848->fm_vol_r = 0;
else
ad1848->fm_vol_r = ad1848_vols_7bits[val & 0x3f];
break;
case 11:
case 13:
updatefreq = 1;
break;
case 23 ... 24:
case 29:
/* Backdoor to control indirect registers on CS4235+. */
if (ad1848->type >= AD1848_TYPE_CS4235) {
temp = ad1848->cram_read(3, ad1848->cram_priv);
ad1848->cram_write(3, (ad1848->xindex == 23) ? 2 : ((ad1848->xindex == 24) ? 8 : 9), ad1848->cram_priv);
ad1848->cram_write(4, val, ad1848->cram_priv);
ad1848->cram_write(3, temp, ad1848->cram_priv);
}
break;
case 25:
goto readonly_x;
case 26 ... 28:
case 30:
/* Backdoor to control registers on CS4235+. */
if (ad1848->type >= AD1848_TYPE_CS4235)
ad1848->cram_write((ad1848->xindex == 30) ? 7 : (ad1848->xindex - 26), val, ad1848->cram_priv);
break;
default:
break;
}
ad1848->xregs[ad1848->xindex] = val;
if (updatefreq)
ad1848_updatefreq(ad1848);
readonly_x:
ad1848_log("AD1848: write(X%d, %02X)\n", ad1848->xindex, val);
return;
}
break;
case 24:
val = ad1848->regs[24] & ((val & 0x70) | 0x0f);
if (!(val & 0x70)) {
ad1848->status &= 0xfe;
picintc(1 << ad1848->irq);
}
break;
case 25:
goto readonly_i;
case 27:
if ((ad1848->type != AD1848_TYPE_CS4232) && (ad1848->type != AD1848_TYPE_CS4236))
goto readonly_i;
break;
case 29:
if ((ad1848->type != AD1848_TYPE_CS4232) && (ad1848->type != AD1848_TYPE_CS4236))
goto readonly_i;
break;
default:
break;
}
ad1848->regs[ad1848->index] = val;
if (updatefreq)
ad1848_updatefreq(ad1848);
temp = (ad1848->type < AD1848_TYPE_CS4231) ? 2 : ((ad1848->type == AD1848_TYPE_CS4231) ? 18 : 4);
if (ad1848->regs[temp] & 0x80)
ad1848->cd_vol_l = 0;
else
ad1848->cd_vol_l = ad1848_vols_5bits_aux_gain[ad1848->regs[temp] & 0x1f];
temp++;
if (ad1848->regs[temp] & 0x80)
ad1848->cd_vol_r = 0;
else
ad1848->cd_vol_r = ad1848_vols_5bits_aux_gain[ad1848->regs[temp] & 0x1f];
readonly_i:
ad1848_log("AD1848: write(I%d, %02X)\n", ad1848->index, val);
return;
case 2:
ad1848->status &= 0xfe;
ad1848->regs[24] &= 0x0f;
break;
default:
break;
}
ad1848_log("AD1848: write(%04X, %02X)\n", addr, val);
}
void
ad1848_speed_changed(ad1848_t *ad1848)
{
ad1848->timer_latch = (uint64_t) ((double) TIMER_USEC * (1000000.0 / (double) ad1848->freq));
}
void
ad1848_update(ad1848_t *ad1848)
{
for (; ad1848->pos < sound_pos_global; ad1848->pos++) {
ad1848->buffer[ad1848->pos * 2] = ad1848->out_l;
ad1848->buffer[ad1848->pos * 2 + 1] = ad1848->out_r;
}
}
static int16_t
ad1848_process_mulaw(uint8_t byte)
{
byte = ~byte;
int temp = (((byte & 0x0f) << 3) + 0x84);
temp <<= ((byte & 0x70) >> 4);
temp = (byte & 0x80) ? (0x84 - temp) : (temp - 0x84);
if (temp > 32767)
return 32767;
else if (temp < -32768)
return -32768;
return (int16_t) temp;
}
static int16_t
ad1848_process_alaw(uint8_t byte)
{
byte ^= 0x55;
int dec = ((byte & 0x0f) << 4);;
const int seg = (int) ((byte & 0x70) >> 4);
switch (seg) {
default:
dec |= 0x108;
dec <<= seg - 1;
break;
case 0:
dec |= 0x8;
break;
case 1:
dec |= 0x108;
break;
}
return (int16_t) ((byte & 0x80) ? dec : -dec);
}
static uint32_t
ad1848_dma_channel_read(ad1848_t *ad1848, int channel)
{
uint32_t ret;
if (channel >= 4) {
if (ad1848->dma_ff) {
ret = (ad1848->dma_data & 0xff00) >> 8;
ret |= (ad1848->dma_data & 0xffff0000);
} else {
ad1848->dma_data = dma_channel_read(channel);
if (ad1848->dma_data == DMA_NODATA)
return DMA_NODATA;
ret = ad1848->dma_data & 0xff;
}
ad1848->dma_ff = !ad1848->dma_ff;
} else
ret = dma_channel_read(channel);
return ret;
}
static int16_t
ad1848_process_adpcm(ad1848_t *ad1848)
{
int temp;
if (ad1848->adpcm_pos++ & 1) {
temp = (ad1848->adpcm_data & 0x0f) + ad1848->adpcm_step;
} else {
ad1848->adpcm_data = (int) (ad1848_dma_channel_read(ad1848, ad1848->dma) & 0xffff);
temp = (ad1848->adpcm_data >> 4) + ad1848->adpcm_step;
}
if (temp < 0)
temp = 0;
else if (temp > 63)
temp = 63;
ad1848->adpcm_ref += scaleMap4[temp];
if (ad1848->adpcm_ref > 0xff)
ad1848->adpcm_ref = 0xff;
else if (ad1848->adpcm_ref < 0x00)
ad1848->adpcm_ref = 0x00;
ad1848->adpcm_step = (int8_t) ((ad1848->adpcm_step + adjustMap4[temp]) & 0xff);
return (int16_t) ((ad1848->adpcm_ref ^ 0x80) << 8);
}
static void
ad1848_poll(void *priv)
{
ad1848_t *ad1848 = (ad1848_t *) priv;
if (ad1848->timer_latch)
timer_advance_u64(&ad1848->timer_count, ad1848->timer_latch);
else
timer_advance_u64(&ad1848->timer_count, TIMER_USEC * 1000);
ad1848_update(ad1848);
if (ad1848->enable) {
int32_t temp;
switch (ad1848->regs[8] & ad1848->fmt_mask) {
case 0x00: /* Mono, 8-bit PCM */
ad1848->out_l = ad1848->out_r = (int16_t) ((ad1848_dma_channel_read(ad1848, ad1848->dma) ^ 0x80) << 8);
break;
case 0x10: /* Stereo, 8-bit PCM */
ad1848->out_l = (int16_t) ((ad1848_dma_channel_read(ad1848, ad1848->dma) ^ 0x80) << 8);
ad1848->out_r = (int16_t) ((ad1848_dma_channel_read(ad1848, ad1848->dma) ^ 0x80) << 8);
break;
case 0x20: /* Mono, 8-bit Mu-Law */
ad1848->out_l = ad1848->out_r = ad1848_process_mulaw(ad1848_dma_channel_read(ad1848, ad1848->dma));
break;
case 0x30: /* Stereo, 8-bit Mu-Law */
ad1848->out_l = ad1848_process_mulaw(ad1848_dma_channel_read(ad1848, ad1848->dma));
ad1848->out_r = ad1848_process_mulaw(ad1848_dma_channel_read(ad1848, ad1848->dma));
break;
case 0x40: /* Mono, 16-bit PCM little endian */
temp = (int32_t) ad1848_dma_channel_read(ad1848, ad1848->dma);
ad1848->out_l = ad1848->out_r = (int16_t) ((ad1848_dma_channel_read(ad1848, ad1848->dma) << 8) | temp);
break;
case 0x50: /* Stereo, 16-bit PCM little endian */
temp = (int32_t) ad1848_dma_channel_read(ad1848, ad1848->dma);
ad1848->out_l = (int16_t) ((ad1848_dma_channel_read(ad1848, ad1848->dma) << 8) | temp);
temp = (int32_t) ad1848_dma_channel_read(ad1848, ad1848->dma);
ad1848->out_r = (int16_t) ((ad1848_dma_channel_read(ad1848, ad1848->dma) << 8) | temp);
break;
case 0x60: /* Mono, 8-bit A-Law */
ad1848->out_l = ad1848->out_r = ad1848_process_alaw(ad1848_dma_channel_read(ad1848, ad1848->dma));
break;
case 0x70: /* Stereo, 8-bit A-Law */
ad1848->out_l = ad1848_process_alaw(ad1848_dma_channel_read(ad1848, ad1848->dma));
ad1848->out_r = ad1848_process_alaw(ad1848_dma_channel_read(ad1848, ad1848->dma));
break;
/* 0x80 and 0x90 reserved */
case 0xa0: /* Mono, 4-bit ADPCM */
ad1848->out_l = ad1848->out_r = ad1848_process_adpcm(ad1848);
break;
case 0xb0: /* Stereo, 4-bit ADPCM */
ad1848->out_l = ad1848_process_adpcm(ad1848);
ad1848->out_r = ad1848_process_adpcm(ad1848);
break;
case 0xc0: /* Mono, 16-bit PCM big endian */
temp = (int32_t) ad1848_dma_channel_read(ad1848, ad1848->dma);
ad1848->out_l = ad1848->out_r = (int16_t) (ad1848_dma_channel_read(ad1848, ad1848->dma) | (temp << 8));
break;
case 0xd0: /* Stereo, 16-bit PCM big endian */
temp = (int32_t) ad1848_dma_channel_read(ad1848, ad1848->dma);
ad1848->out_l = (int16_t) (ad1848_dma_channel_read(ad1848, ad1848->dma) | (temp << 8));
temp = (int32_t) ad1848_dma_channel_read(ad1848, ad1848->dma);
ad1848->out_r = (int16_t) (ad1848_dma_channel_read(ad1848, ad1848->dma) | (temp << 8));
break;
/* 0xe0 and 0xf0 reserved */
default:
break;
}
if (ad1848->regs[6] & 0x80)
ad1848->out_l = 0;
else
ad1848->out_l = (int16_t) ((ad1848->out_l * ad1848_vols_7bits[ad1848->regs[6] & ad1848->wave_vol_mask]) >> 16);
if (ad1848->regs[7] & 0x80)
ad1848->out_r = 0;
else
ad1848->out_r = (int16_t) ((ad1848->out_r * ad1848_vols_7bits[ad1848->regs[7] & ad1848->wave_vol_mask]) >> 16);
if (ad1848->count < 0) {
ad1848->count = ad1848->regs[15] | (ad1848->regs[14] << 8);
ad1848->adpcm_pos = 0;
if (!(ad1848->status & 0x01)) {
ad1848->status |= 0x01;
ad1848->regs[24] |= 0x10;
}
if (ad1848->regs[10] & 2)
picint(1 << ad1848->irq);
else
picintc(1 << ad1848->irq);
}
if (!(ad1848->adpcm_pos & 7)) /* ADPCM counts down every 4 bytes */
ad1848->count--;
} else {
ad1848->out_l = ad1848->out_r = 0;
ad1848->cd_vol_l = ad1848->cd_vol_r = 0;
}
}
void
ad1848_filter_cd_audio(int channel, double *buffer, void *priv)
{
const ad1848_t *ad1848 = (ad1848_t *) priv;
double c;
double volume = channel ? ad1848->cd_vol_r : ad1848->cd_vol_l;
c = ((*buffer) * volume) / 65536.0;
*buffer = c;
}
void
ad1848_filter_aux2(void *priv, double *out_l, double *out_r)
{
const ad1848_t *ad1848 = (ad1848_t *) priv;
if (ad1848->regs[4] & 0x80) {
*out_l = 0.0;
} else {
*out_l = ((*out_l) * ad1848_vols_5bits_aux_gain[ad1848->regs[4] & 0x1f]) / 65536.0;
}
if (ad1848->regs[5] & 0x80) {
*out_r = 0.0;
} else {
*out_r = ((*out_r) * ad1848_vols_5bits_aux_gain[ad1848->regs[5] & 0x1f]) / 65536.0;
}
}
void
ad1848_init(ad1848_t *ad1848, uint8_t type)
{
uint8_t c;
double attenuation;
ad1848_log("AD1848: init(%02X)\n", type);
ad1848->status = 0xcc;
ad1848->index = ad1848->trd = 0;
ad1848->mce = 0x40;
ad1848->wten = 0;
ad1848->regs[0] = ad1848->regs[1] = 0;
ad1848->regs[2] = ad1848->regs[3] = 0x80; /* Line-in */
ad1848->regs[4] = ad1848->regs[5] = 0x80;
ad1848->regs[6] = ad1848->regs[7] = 0x80; /* Left/right Output */
ad1848->regs[8] = 0;
ad1848->regs[9] = 0x08;
ad1848->regs[10] = ad1848->regs[11] = 0;
ad1848->regs[12] = (type >= AD1848_TYPE_CS4248) ? 0x8a : 0xa;
ad1848->regs[13] = 0;
ad1848->regs[14] = ad1848->regs[15] = 0;
if (type == AD1848_TYPE_CS4231) {
ad1848->regs[16] = ad1848->regs[17] = 0;
ad1848->regs[18] = ad1848->regs[19] = 0x88;
ad1848->regs[22] = 0x80;
ad1848->regs[24] = 0;
ad1848->regs[25] = CS4231;
ad1848->regs[26] = 0x80;
ad1848->regs[29] = 0x80;
} else if (type >= AD1848_TYPE_CS4232) {
ad1848->regs[16] = ad1848->regs[17] = 0;
ad1848->regs[18] = ad1848->regs[19] = 0;
ad1848->regs[20] = ad1848->regs[21] = 0;
ad1848->regs[22] = ad1848->regs[23] = 0;
ad1848->regs[24] = 0;
ad1848->regs[25] = (type == AD1848_TYPE_CS4232) ? CS4232 : CS4236;
ad1848->regs[26] = 0xa0;
ad1848->regs[27] = ad1848->regs[29] = 0;
ad1848->regs[30] = ad1848->regs[31] = 0;
if (type >= AD1848_TYPE_CS4236B) {
if (type < AD1848_TYPE_CS4235)
ad1848->xregs[0] = ad1848->xregs[1] = 0xe8;
ad1848->xregs[2] = ad1848->xregs[3] = 0xcf;
ad1848->xregs[4] = 0x84;
ad1848->xregs[5] = 0;
ad1848->xregs[6] = ad1848->xregs[7] = 0x80;
ad1848->xregs[8] = ad1848->xregs[9] = 0;
ad1848->xregs[10] = 0x3f;
ad1848->xregs[11] = 0xc0;
ad1848->xregs[14] = ad1848->xregs[15] = 0;
ad1848->xregs[16] = ad1848->xregs[17] = 0;
}
}
ad1848_updatefreq(ad1848);
ad1848->out_l = ad1848->out_r = 0;
ad1848->fm_vol_l = ad1848->fm_vol_r = 65536;
ad1848_updatevolmask(ad1848);
if (type >= AD1848_TYPE_CS4235)
ad1848->fmt_mask = 0x50;
else
ad1848->fmt_mask = 0x70;
for (c = 0; c < 128; c++) {
attenuation = 0.0;
if (c & 0x40) {
if (c < 72)
attenuation = (c - 72) * -1.5;
} else {
if (c & 0x01)
attenuation -= 1.5;
if (c & 0x02)
attenuation -= 3.0;
if (c & 0x04)
attenuation -= 6.0;
if (c & 0x08)
attenuation -= 12.0;
if (c & 0x10)
attenuation -= 24.0;
if (c & 0x20)
attenuation -= 48.0;
}
attenuation = pow(10, attenuation / 10);
ad1848_vols_7bits[c] = (int) (attenuation * 65536);
}
for (c = 0; c < 32; c++) {
attenuation = 12.0;
if (c & 0x01)
attenuation -= 1.5;
if (c & 0x02)
attenuation -= 3.0;
if (c & 0x04)
attenuation -= 6.0;
if (c & 0x08)
attenuation -= 12.0;
if (c & 0x10)
attenuation -= 24.0;
attenuation = pow(10, attenuation / 10);
ad1848_vols_5bits_aux_gain[c] = (attenuation * 65536);
}
ad1848->type = type;
timer_add(&ad1848->timer_count, ad1848_poll, ad1848, 0);
if ((ad1848->type != AD1848_TYPE_DEFAULT) && (ad1848->type != AD1848_TYPE_CS4248))
sound_set_cd_audio_filter(ad1848_filter_cd_audio, ad1848);
}