Bochs/bochs/iodev/sound/soundlow.cc
2019-01-02 17:13:36 +00:00

677 lines
16 KiB
C++

/////////////////////////////////////////////////////////////////////////
// $Id$
/////////////////////////////////////////////////////////////////////////
//
// Copyright (C) 2011-2017 The Bochs Project
//
// This library is free software; you can redistribute it and/or
// modify it under the terms of the GNU Lesser General Public
// License as published by the Free Software Foundation; either
// version 2 of the License, or (at your option) any later version.
//
// This library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
// Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public
// License along with this library; if not, write to the Free Software
// Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
// Common sound module code and base classes for sound lowlevel functions
#include "iodev.h"
#if BX_SUPPORT_SOUNDLOW
#include "soundlow.h"
#define LOG_THIS
// audio buffer support
bx_audio_buffer_c *audio_buffers[2];
bx_audio_buffer_c::bx_audio_buffer_c(Bit8u _format)
{
format = _format;
root = NULL;
}
bx_audio_buffer_c::~bx_audio_buffer_c()
{
while (root != NULL) {
delete_buffer();
}
}
audio_buffer_t* bx_audio_buffer_c::new_buffer(Bit32u size)
{
audio_buffer_t *newbuffer = new audio_buffer_t;
if (format == BUFTYPE_FLOAT) {
newbuffer->fdata = new float[size];
} else {
newbuffer->data = new Bit8u[size];
}
newbuffer->size = size;
newbuffer->pos = 0;
newbuffer->next = NULL;
if (root == NULL) {
root = newbuffer;
} else {
audio_buffer_t *temp = root;
while (temp->next)
temp = temp->next;
temp->next = newbuffer;
}
return newbuffer;
}
audio_buffer_t* bx_audio_buffer_c::get_buffer()
{
return root;
}
void bx_audio_buffer_c::delete_buffer()
{
audio_buffer_t *tmpbuffer = root;
root = tmpbuffer->next;
if (tmpbuffer->size > 0) {
if (format == BUFTYPE_FLOAT) {
delete [] tmpbuffer->fdata;
} else {
delete [] tmpbuffer->data;
}
}
delete tmpbuffer;
}
// convert to float format for resampler
static void convert_to_float(Bit8u *src, unsigned srcsize, audio_buffer_t *audiobuf)
{
unsigned i, j;
bx_pcm_param_t *param = &audiobuf->param;
bx_bool issigned = (param->format & 1);
bx_bool setvol = (param->volume != BX_MAX_BIT16U);
Bit16s val16s;
Bit16u val16u;
float volume[2];
float *dst = audiobuf->fdata;
if (setvol) {
volume[0] = ((float)(param->volume & 0xff)) / 255.0F;
volume[1] = ((float)(param->volume >> 8)) / 255.0F;
}
if (param->bits == 8) {
if (issigned) {
for (i = 0; i < srcsize; i++) {
dst[i] = ((float)src[i]) / 128.0F;
if (setvol) {
dst[i] *= volume[i & 1];
}
}
} else {
for (i = 0; i < srcsize; i++) {
dst[i] = (((float)src[i]) - 128.0F) / 128.0F;
if (setvol) {
dst[i] *= volume[i & 1];
}
}
}
} else {
j = 0;
if (issigned) {
for (i = 0; i < srcsize; i += 2) {
val16s = (Bit16s)(src[i] | (src[i+1] << 8));
dst[j] = ((float)val16s) / 32768.0F;
if (setvol) {
dst[j] *= volume[i & 1];
}
j++;
}
} else {
for (i = 0; i < srcsize; i += 2) {
val16u = (Bit16u)(src[i] | (src[i+1] << 8));
dst[j] = (((float)val16u) - 32768.0F) / 32768.0F;
if (setvol) {
dst[j] *= volume[i & 1];
}
j++;
}
}
}
}
// convert from float format for output
void convert_float_to_s16le(float *src, unsigned srcsize, Bit8u *dst)
{
Bit16s val16s;
unsigned i, j = 0;
for (i = 0; i < srcsize; i++) {
val16s = (Bit16s)(src[i] * 32768.0F);
dst[j++] =(Bit8u)(val16s & 0xff);
dst[j++] = (Bit8u)(val16s >> 8);
}
}
// audio buffer callback function
Bit32u pcm_callback(void *dev, Bit16u rate, Bit8u *buffer, Bit32u len)
{
Bit32u copied = 0;
UNUSED(dev);
UNUSED(rate);
while (len > 0) {
audio_buffer_t *curbuffer = audio_buffers[1]->get_buffer();
if (curbuffer == NULL)
break;
Bit32u tmplen = curbuffer->size - curbuffer->pos;
if (tmplen > len) {
tmplen = len;
}
if (tmplen > 0) {
memcpy(buffer+copied, curbuffer->data+curbuffer->pos, tmplen);
curbuffer->pos += tmplen;
copied += tmplen;
len -= tmplen;
}
if (curbuffer->pos >= curbuffer->size) {
audio_buffers[1]->delete_buffer();
}
}
return copied;
}
// resampler & mixer thread support
BX_MUTEX(resampler_mutex);
BX_MUTEX(mixer_mutex);
BX_THREAD_FUNC(resampler_thread, indata)
{
bx_soundlow_waveout_c *waveout = (bx_soundlow_waveout_c*)indata;
while (waveout->resampler_running()) {
BX_LOCK(resampler_mutex);
audio_buffer_t *curbuffer = audio_buffers[0]->get_buffer();
BX_UNLOCK(resampler_mutex);
if (curbuffer != NULL) {
waveout->resampler(curbuffer, NULL);
BX_LOCK(resampler_mutex);
audio_buffers[0]->delete_buffer();
BX_UNLOCK(resampler_mutex);
} else {
BX_MSLEEP(20);
}
}
BX_THREAD_EXIT;
}
BX_THREAD_FUNC(mixer_thread, indata)
{
int len;
bx_soundlow_waveout_c *waveout = (bx_soundlow_waveout_c*)indata;
Bit8u *mixbuffer = new Bit8u[BX_SOUNDLOW_WAVEPACKETSIZE];
while (waveout->mixer_running()) {
len = waveout->get_packetsize();
memset(mixbuffer, 0, len);
if (waveout->mixer_common(mixbuffer, len)) {
waveout->output(len, mixbuffer);
} else {
BX_MSLEEP(25);
}
}
delete [] mixbuffer;
waveout->closewaveoutput();
BX_THREAD_EXIT;
}
// bx_soundlow_waveout_c class implementation
// The dummy output methods don't do anything.
bx_soundlow_waveout_c::bx_soundlow_waveout_c()
{
put("waveout", "WAVOUT");
if (audio_buffers[0] == NULL) {
audio_buffers[0] = new bx_audio_buffer_c(BUFTYPE_FLOAT);
audio_buffers[1] = new bx_audio_buffer_c(BUFTYPE_UCHAR);
}
real_pcm_param = default_pcm_param;
cb_count = 0;
pcm_callback_id = -1;
res_thread_start = 0;
mix_thread_start = 0;
#if BX_HAVE_LIBSAMPLERATE || BX_HAVE_SOXR_LSR
int ret = 0;
src_state = src_new(SRC_SINC_MEDIUM_QUALITY, 2, &ret);
#endif
}
bx_soundlow_waveout_c::~bx_soundlow_waveout_c()
{
if (pcm_callback_id >= 0) {
#if BX_HAVE_LIBSAMPLERATE || BX_HAVE_SOXR_LSR
src_delete(src_state);
#endif
unregister_wave_callback(pcm_callback_id);
if (res_thread_start) {
res_thread_start = 0;
BX_MSLEEP(20);
BX_FINI_MUTEX(resampler_mutex);
}
if (mix_thread_start) {
mix_thread_start = 0;
BX_MSLEEP(25);
BX_FINI_MUTEX(mixer_mutex);
}
if (audio_buffers[0] != NULL) {
delete audio_buffers[0];
delete audio_buffers[1];
audio_buffers[0] = NULL;
}
}
}
int bx_soundlow_waveout_c::openwaveoutput(const char *wavedev)
{
UNUSED(wavedev);
return BX_SOUNDLOW_OK;
}
int bx_soundlow_waveout_c::set_pcm_params(bx_pcm_param_t *param)
{
UNUSED(param);
return BX_SOUNDLOW_OK;
}
int bx_soundlow_waveout_c::sendwavepacket(int length, Bit8u data[], bx_pcm_param_t *src_param)
{
unsigned len1 = length;
if (src_param->bits == 16) len1 >>= 1;
if (pcm_callback_id >= 0) {
BX_LOCK(resampler_mutex);
audio_buffer_t *inbuffer = audio_buffers[0]->new_buffer(len1);
memcpy(&inbuffer->param, src_param, sizeof(bx_pcm_param_t));
convert_to_float(data, length, inbuffer);
BX_UNLOCK(resampler_mutex);
} else {
audio_buffer_t *inbuffer = new audio_buffer_t;
inbuffer->fdata = new float[len1];
inbuffer->size = len1;
memcpy(&inbuffer->param, src_param, sizeof(bx_pcm_param_t));
audio_buffer_t *outbuffer = new audio_buffer_t;
memset(outbuffer, 0, sizeof(audio_buffer_t));
convert_to_float(data, length, inbuffer);
resampler(inbuffer, outbuffer);
output(outbuffer->size, outbuffer->data);
delete outbuffer;
delete inbuffer;
}
return BX_SOUNDLOW_OK;
}
int bx_soundlow_waveout_c::get_packetsize()
{
return (real_pcm_param.samplerate * 4 / 10);
}
int bx_soundlow_waveout_c::output(int length, Bit8u data[])
{
UNUSED(length);
UNUSED(data);
return BX_SOUNDLOW_OK;
}
int bx_soundlow_waveout_c::closewaveoutput()
{
return BX_SOUNDLOW_OK;
}
int bx_soundlow_waveout_c::register_wave_callback(void *arg, get_wave_cb_t wd_cb)
{
if (cb_count < BX_MAX_WAVE_CALLBACKS) {
get_wave[cb_count].device = arg;
get_wave[cb_count].cb = wd_cb;
return cb_count++;
}
return -1;
}
void bx_soundlow_waveout_c::unregister_wave_callback(int callback_id)
{
BX_LOCK(mixer_mutex);
if ((callback_id >= 0) && (callback_id < BX_MAX_WAVE_CALLBACKS)) {
get_wave[callback_id].device = NULL;
get_wave[callback_id].cb = NULL;
}
BX_UNLOCK(mixer_mutex);
}
bx_bool bx_soundlow_waveout_c::mixer_common(Bit8u *buffer, int len)
{
Bit32u count, len2 = 0, len3 = 0;
Bit16s src1, src2, dst_val;
Bit32s tmp_val;
Bit8u *src, *dst;
Bit8u *tmpbuffer = new Bit8u[len];
BX_LOCK(mixer_mutex);
for (int i = 0; i < cb_count; i++) {
if (get_wave[i].cb != NULL) {
memset(tmpbuffer, 0, len);
len2 = get_wave[i].cb(get_wave[i].device, real_pcm_param.samplerate, tmpbuffer, len);
if (len2 > 0) {
src = tmpbuffer;
dst = buffer;
count = len / 2;
while (count--) {
src1 = (src[0] | (src[1] << 8));
src2 = (dst[0] | (dst[1] << 8));
tmp_val = (Bit32s)src1 + (Bit32s)src2;
if (tmp_val > BX_MAX_BIT16S) {
tmp_val = BX_MAX_BIT16S;
} else if (tmp_val < BX_MIN_BIT16S) {
tmp_val = BX_MIN_BIT16S;
}
dst_val = (Bit16s)tmp_val;
dst[0] = dst_val & 0xff;
dst[1] = (Bit8u)(dst_val >> 8);
src += 2;
dst += 2;
}
if (len3 < len2) len3 = len2;
}
}
}
BX_UNLOCK(mixer_mutex);
delete [] tmpbuffer;
return (len3 > 0);
}
void bx_soundlow_waveout_c::resampler(audio_buffer_t *inbuffer, audio_buffer_t *outbuffer)
{
Bit32u fcount;
float *fbuffer = NULL;
fcount = resampler_common(inbuffer, &fbuffer);
if (outbuffer == NULL) {
BX_LOCK(mixer_mutex);
audio_buffer_t *newbuffer = audio_buffers[1]->new_buffer(fcount << 1);
convert_float_to_s16le(fbuffer, fcount, newbuffer->data);
BX_UNLOCK(mixer_mutex);
} else {
outbuffer->data = new Bit8u[fcount << 1];
outbuffer->size = (fcount << 1);
convert_float_to_s16le(fbuffer, fcount, outbuffer->data);
}
if (fbuffer != NULL) {
delete [] fbuffer;
}
}
Bit32u bx_soundlow_waveout_c::resampler_common(audio_buffer_t *inbuffer, float **fbuffer)
{
unsigned i, j, fcount = 0;
bx_pcm_param_t param = inbuffer->param;
if (param.channels != real_pcm_param.channels) {
if (param.channels == 1) {
float *temp = new float[inbuffer->size * 2];
j = 0;
for (i = 0; i < inbuffer->size; i++) {
temp[j++] = inbuffer->fdata[i];
temp[j++] = inbuffer->fdata[i];
}
delete [] inbuffer->fdata;
inbuffer->fdata = temp;
inbuffer->size <<= 1;
} else {
BX_ERROR(("conversion from stereo to mono not implemented"));
}
}
#if BX_HAVE_LIBSAMPLERATE || BX_HAVE_SOXR_LSR
if (param.samplerate != real_pcm_param.samplerate) {
SRC_DATA data;
double irate = (double)param.samplerate;
double orate = (double)real_pcm_param.samplerate;
size_t ilen = inbuffer->size / 2;
size_t olen = (size_t)(ilen * orate / irate + 0.5);
*fbuffer = new float[olen * 2];
fcount = olen * 2;
int ret = 0;
data.data_in = inbuffer->fdata;
data.data_out = *fbuffer;
data.input_frames = (int)ilen;
data.output_frames = (int)olen;
data.src_ratio = orate / irate;
data.end_of_input = 0;
ret = src_process(src_state, &data);
if (ret != 0) {
BX_ERROR(("resampling error: %s", src_strerror(ret)));
}
} else {
*fbuffer = new float[inbuffer->size];
fcount = inbuffer->size;
memcpy(*fbuffer, inbuffer->data, sizeof(float) * fcount);
}
#else
if (param.samplerate != real_pcm_param.samplerate) {
real_pcm_param.samplerate = param.samplerate;
set_pcm_params(&real_pcm_param);
}
*fbuffer = new float[inbuffer->size];
fcount = inbuffer->size;
memcpy(*fbuffer, inbuffer->data, sizeof(float) * fcount);
#endif
return fcount;
}
void bx_soundlow_waveout_c::start_resampler_thread()
{
BX_INIT_MUTEX(resampler_mutex);
res_thread_start = 1;
BX_THREAD_CREATE(resampler_thread, this, res_thread_var);
}
void bx_soundlow_waveout_c::start_mixer_thread()
{
BX_INIT_MUTEX(mixer_mutex);
mix_thread_start = 1;
BX_THREAD_CREATE(mixer_thread, this, mix_thread_var);
}
// bx_soundlow_wavein_c class implementation
// The dummy input method returns silence.
bx_soundlow_wavein_c::bx_soundlow_wavein_c()
{
put("wavein", "WAVEIN");
record_timer_index = BX_NULL_TIMER_HANDLE;
}
bx_soundlow_wavein_c::~bx_soundlow_wavein_c()
{
stopwaverecord();
}
int bx_soundlow_wavein_c::openwaveinput(const char *wavedev, sound_record_handler_t rh)
{
UNUSED(wavedev);
record_handler = rh;
if (rh != NULL) {
record_timer_index = DEV_register_timer(this, record_timer_handler, 1, 1, 0, "wavein");
// record timer: inactive, continuous, frequency variable
}
return BX_SOUNDLOW_OK;
}
int bx_soundlow_wavein_c::startwaverecord(bx_pcm_param_t *param)
{
Bit64u timer_val;
Bit8u shift = 0;
if (record_timer_index != BX_NULL_TIMER_HANDLE) {
if (param->bits == 16) shift++;
if (param->channels == 2) shift++;
record_packet_size = (param->samplerate / 10) << shift; // 0.1 sec
if (record_packet_size > BX_SOUNDLOW_WAVEPACKETSIZE) {
record_packet_size = BX_SOUNDLOW_WAVEPACKETSIZE;
}
timer_val = (Bit64u)record_packet_size * 1000000 / (param->samplerate << shift);
bx_pc_system.activate_timer(record_timer_index, (Bit32u)timer_val, 1);
}
return BX_SOUNDLOW_OK;
}
int bx_soundlow_wavein_c::getwavepacket(int length, Bit8u data[])
{
memset(data, 0, length);
return BX_SOUNDLOW_OK;
}
int bx_soundlow_wavein_c::stopwaverecord()
{
if (record_timer_index != BX_NULL_TIMER_HANDLE) {
bx_pc_system.deactivate_timer(record_timer_index);
}
return BX_SOUNDLOW_OK;
}
void bx_soundlow_wavein_c::record_timer_handler(void *this_ptr)
{
bx_soundlow_wavein_c *class_ptr = (bx_soundlow_wavein_c *) this_ptr;
class_ptr->record_timer();
}
void bx_soundlow_wavein_c::record_timer(void)
{
record_handler(this, record_packet_size);
}
// bx_soundlow_midiout_c class implementation
// The dummy output methods don't do anything.
bx_soundlow_midiout_c::bx_soundlow_midiout_c()
{
put("midiout", "MIDI");
}
bx_soundlow_midiout_c::~bx_soundlow_midiout_c()
{
}
int bx_soundlow_midiout_c::openmidioutput(const char *mididev)
{
UNUSED(mididev);
return BX_SOUNDLOW_OK;
}
int bx_soundlow_midiout_c::midiready()
{
return BX_SOUNDLOW_OK;
}
int bx_soundlow_midiout_c::sendmidicommand(int delta, int command, int length, Bit8u data[])
{
UNUSED(delta);
UNUSED(command);
UNUSED(length);
UNUSED(data);
return BX_SOUNDLOW_OK;
}
int bx_soundlow_midiout_c::closemidioutput()
{
return BX_SOUNDLOW_OK;
}
bx_sound_lowlevel_c *bx_sound_lowlevel_c::all;
// bx_sound_lowlevel_c class implementation
bx_sound_lowlevel_c::bx_sound_lowlevel_c(const char *type)
{
put("soundlow", "SNDLOW");
waveout = NULL;
wavein = NULL;
midiout = NULL;
// self-registering static objects ported from the network code
next = all;
all = this;
this->type = type;
}
bx_sound_lowlevel_c::~bx_sound_lowlevel_c()
{
bx_sound_lowlevel_c *ptr = 0;
if (waveout != NULL) {
delete waveout;
}
if (wavein != NULL) {
delete wavein;
}
if (midiout != NULL) {
delete midiout;
}
// unregister sound driver
if (this == all) {
all = all->next;
} else {
ptr = all;
while (ptr != NULL) {
if (ptr->next != this) {
ptr = ptr->next;
} else {
break;
}
}
}
if (ptr) {
ptr->next = this->next;
}
}
bx_bool bx_sound_lowlevel_c::module_present(const char *type)
{
bx_sound_lowlevel_c *ptr = 0;
for (ptr = all; ptr != NULL; ptr = ptr->next) {
if (strcmp(type, ptr->type) == 0)
return 1;
}
return 0;
}
bx_sound_lowlevel_c* bx_sound_lowlevel_c::get_module(const char *type)
{
bx_sound_lowlevel_c *ptr = 0;
for (ptr = all; ptr != NULL; ptr = ptr->next) {
if (strcmp(type, ptr->type) == 0)
return ptr;
}
return NULL;
}
void bx_sound_lowlevel_c::cleanup()
{
#if BX_PLUGINS
while (all != NULL) {
PLUG_unload_snd_plugin(all->type);
}
#endif
}
#endif