// cae_alsa.cpp
//
// The ALSA Driver for the Core Audio Engine component of Rivendell
//
// (C) Copyright 2002-2015 Fred Gleason <fredg@paravelsystems.com>
//
// This program is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License version 2 as
// published by the Free Software Foundation.
//
// This program 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 General Public License for more details.
//
// You should have received a copy of the GNU General Public
// License along with this program; if not, write to the Free Software
// Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
//
#include <math.h>
#include <signal.h>
#include <samplerate.h>
#include <qsignalmapper.h>
#include <rd.h>
#include <rdringbuffer.h>
#include <rdmeteraverage.h>
#include <cae.h>
#ifdef ALSA
//
// Callback Variables
//
volatile int alsa_input_channels[RD_MAX_CARDS][RD_MAX_PORTS];
volatile int alsa_output_channels[RD_MAX_CARDS][RD_MAX_STREAMS];
RDMeterAverage *alsa_input_meter[RD_MAX_CARDS][RD_MAX_PORTS][2];
RDMeterAverage *alsa_output_meter[RD_MAX_CARDS][RD_MAX_PORTS][2];
RDMeterAverage *alsa_stream_output_meter[RD_MAX_CARDS][RD_MAX_STREAMS][2];
volatile double alsa_input_volume[RD_MAX_CARDS][RD_MAX_PORTS];
volatile double alsa_output_volume[RD_MAX_CARDS][RD_MAX_PORTS][RD_MAX_STREAMS];
volatile double
alsa_passthrough_volume[RD_MAX_CARDS][RD_MAX_PORTS][RD_MAX_PORTS];
volatile double alsa_input_vox[RD_MAX_CARDS][RD_MAX_PORTS];
RDRingBuffer *alsa_play_ring[RD_MAX_CARDS][RD_MAX_STREAMS];
RDRingBuffer *alsa_record_ring[RD_MAX_CARDS][RD_MAX_PORTS];
RDRingBuffer *alsa_passthrough_ring[RD_MAX_CARDS][RD_MAX_PORTS];
volatile bool alsa_playing[RD_MAX_CARDS][RD_MAX_STREAMS];
volatile bool alsa_stopping[RD_MAX_CARDS][RD_MAX_STREAMS];
volatile bool alsa_eof[RD_MAX_CARDS][RD_MAX_STREAMS];
volatile int alsa_output_pos[RD_MAX_CARDS][RD_MAX_STREAMS];
volatile bool alsa_recording[RD_MAX_CARDS][RD_MAX_PORTS];
volatile bool alsa_ready[RD_MAX_CARDS][RD_MAX_PORTS];
volatile int alsa_channels;
void AlsaCapture1Callback(struct alsa_format *alsa_format)
{
}
void AlsaCapture2Callback(struct alsa_format *alsa_format)
{
char alsa_buffer[RINGBUFFER_SIZE];
int modulo;
int16_t in_meter[RD_MAX_PORTS][2];
while(!alsa_format->exiting) {
int s=snd_pcm_readi(alsa_format->pcm,alsa_format->card_buffer,
rd_config->alsaPeriodSize()/(alsa_format->periods*2));
if(((snd_pcm_state(alsa_format->pcm)!=SND_PCM_STATE_RUNNING)&&
(!alsa_format->exiting))||(s<0)) {
snd_pcm_drop (alsa_format->pcm);
snd_pcm_prepare(alsa_format->pcm);
LogLine(RDConfig::LogNotice,QString().
sprintf("****** ALSA Capture Xrun - Card: %d ******",
alsa_format->card));
}
else {
switch(alsa_format->format) {
case SND_PCM_FORMAT_S16_LE:
modulo=alsa_format->channels;
for(unsigned i=0;i<(alsa_format->channels/2);i++) {
if(alsa_recording[alsa_format->card][i]) {
if(alsa_input_volume[alsa_format->card][i]!=0.0) {
switch(alsa_input_channels[alsa_format->card][i]) {
case 1:
for(int k=0;k<(2*s);k++) {
((int16_t *)alsa_buffer)[k]=
(int16_t)(alsa_input_volume[alsa_format->card][i]*
(double)(((int16_t *)alsa_format->
card_buffer)
[modulo*k+2*i]))+
(int16_t)(alsa_input_volume[alsa_format->card][i]*
(double)(((int16_t *)alsa_format->
card_buffer)
[modulo*k+2*i+1]));
}
alsa_record_ring[alsa_format->card][i]->
write(alsa_buffer,s*sizeof(int16_t));
break;
case 2:
for(int k=0;k<s;k++) {
((int16_t *)alsa_buffer)[2*k]=
(int16_t)(alsa_input_volume[alsa_format->card][i]*
(double)(((int16_t *)alsa_format->
card_buffer)
[modulo*k+2*i]));
((int16_t *)alsa_buffer)[2*k+1]=
(int16_t)(alsa_input_volume[alsa_format->card][i]*
(double)(((int16_t *)alsa_format->
card_buffer)
[modulo*k+2*i+1]));
}
alsa_record_ring[alsa_format->card][i]->
write(alsa_buffer,s*2*sizeof(int16_t));
break;
}
}
}
}
//
// Process Passthroughs
//
for(unsigned i=0;i<alsa_format->channels;i+=2) {
for(unsigned j=0;j<2;j++) {
for(int k=0;k<s;k++) {
((int16_t *)alsa_format->passthrough_buffer)[2*k+j]=
((int16_t *)alsa_format->
card_buffer)[alsa_format->channels*k+i+j];
}
}
alsa_passthrough_ring[alsa_format->card][i/2]->
write(alsa_format->passthrough_buffer,4*s);
}
//
// Process Input Meters
//
for(unsigned i=0;i<alsa_format->channels;i+=2) {
for(unsigned j=0;j<2;j++) {
in_meter[i/2][j]=0;
for(int k=0;k<s;k++) {
if(((int16_t *)alsa_format->
card_buffer)[alsa_format->channels*k+2*i+j]>
in_meter[i][j]) {
in_meter[i][j]=
((int16_t *)alsa_format->
card_buffer)[alsa_format->channels*k+2*i+j];
}
}
alsa_input_meter[alsa_format->card][i/2][j]->
addValue(((double)in_meter[i/2][j])/32768.0);
}
}
break;
case SND_PCM_FORMAT_S32_LE:
modulo=alsa_format->channels*2;
for(unsigned i=0;i<(alsa_format->channels/2);i++) {
if(alsa_recording[alsa_format->card][i]) {
if(alsa_input_volume[alsa_format->card][i]!=0.0) {
switch(alsa_input_channels[alsa_format->card][i]) {
case 1:
for(int k=0;k<(2*s);k++) {
((int16_t *)alsa_buffer)[k]=
(int16_t)(alsa_input_volume[alsa_format->card][i]*
(double)(((int16_t *)alsa_format->
card_buffer)
[modulo*k+4*i+1]))+
(int16_t)(alsa_input_volume[alsa_format->card][i]*
(double)(((int16_t *)alsa_format->
card_buffer)
[modulo*k+4*i+3]));
}
alsa_record_ring[alsa_format->card][i]->
write(alsa_buffer,s*sizeof(int16_t));
break;
case 2:
for(int k=0;k<s;k++) {
((int16_t *)alsa_buffer)[2*k]=
(int16_t)(alsa_input_volume[alsa_format->card][i]*
(double)(((int16_t *)alsa_format->card_buffer)
[modulo*k+4*i+1]));
((int16_t *)alsa_buffer)[2*k+1]=
(int16_t)(alsa_input_volume[alsa_format->card][i]*
(double)(((int16_t *)alsa_format->card_buffer)
[modulo*k+4*i+3]));
}
alsa_record_ring[alsa_format->card][i]->
write(alsa_buffer,s*2*sizeof(int16_t));
break;
}
}
}
}
//
// Process Passthroughs
//
for(unsigned i=0;i<alsa_format->channels;i+=2) {
for(unsigned j=0;j<2;j++) {
for(int k=0;k<s;k++) {
((int32_t *)alsa_format->passthrough_buffer)[2*k+j]=
((int32_t *)alsa_format->
card_buffer)[alsa_format->channels*k+i+j];
}
}
alsa_passthrough_ring[alsa_format->card][i/2]->
write(alsa_format->passthrough_buffer,8*s);
}
//
// Process Input Meters
//
for(unsigned i=0;i<alsa_format->channels;i+=2) {
for(unsigned j=0;j<2;j++) {
in_meter[i/2][j]=0;
for(int k=0;k<s;k++) {
if(((int16_t *)alsa_format->
card_buffer)[alsa_format->channels*2*k+2*i+1+2*j]>
in_meter[i/2][j]) {
in_meter[i/2][j]=
((int16_t *)alsa_format->
card_buffer)[alsa_format->channels*2*k+2*i+1+2*j];
}
}
alsa_input_meter[alsa_format->card][i/2][j]->
addValue(((double)in_meter[i/2][j])/32768.0);
}
}
break;
default:
break;
}
}
}
}
void *AlsaCaptureCallback(void *ptr)
{
struct alsa_format *alsa_format=(struct alsa_format *)ptr;
signal(SIGTERM,SigHandler);
signal(SIGINT,SigHandler);
switch(alsa_channels) {
case 1:
AlsaCapture1Callback(alsa_format);
break;
case 2:
AlsaCapture2Callback(alsa_format);
break;
}
return 0;
}
void AlsaPlay1Callback(struct alsa_format *alsa_format)
{
}
void AlsaPlay2Callback(struct alsa_format *alsa_format)
{
int n=0;
int p;
char alsa_buffer[RINGBUFFER_SIZE];
int modulo;
int16_t out_meter[RD_MAX_PORTS][2];
int16_t stream_out_meter=0;
while(!alsa_format->exiting) {
memset(alsa_format->card_buffer,0,alsa_format->card_buffer_size);
switch(alsa_format->format) {
case SND_PCM_FORMAT_S16_LE:
for(unsigned j=0;j<RD_MAX_STREAMS;j++) {
if(alsa_playing[alsa_format->card][j]) {
switch(alsa_output_channels[alsa_format->card][j]) {
case 1:
n=alsa_play_ring[alsa_format->card][j]->
read(alsa_buffer,alsa_format->
buffer_size/alsa_format->periods)/
(2*sizeof(int16_t));
stream_out_meter=0; // Stream Output Meters
for(int k=0;k<n;k++) {
if(abs(((int16_t *)alsa_buffer)[k])>stream_out_meter) {
stream_out_meter=abs(((int16_t *)alsa_buffer)[k]);
}
}
alsa_stream_output_meter[alsa_format->card][j][0]->
addValue(((double)stream_out_meter)/32768.0);
alsa_stream_output_meter[alsa_format->card][j][1]->
addValue(((double)stream_out_meter)/32768.0);
modulo=alsa_format->channels;
for(unsigned i=0;i<(alsa_format->channels/2);i++) {
if(alsa_output_volume[alsa_format->card][i][j]!=0.0) {
for(int k=0;k<(2*n);k++) {
((int16_t *)alsa_format->card_buffer)[modulo*k+2*i]+=
(int16_t)(alsa_output_volume[alsa_format->card][i][j]*
(double)(((int16_t *)alsa_buffer)[k]));
((int16_t *)alsa_format->card_buffer)[modulo*k+2*i+1]+=
(int16_t)(alsa_output_volume[alsa_format->card][i][j]*
(double)(((int16_t *)alsa_buffer)[k]));
}
}
}
n*=2;
break;
case 2:
n=alsa_play_ring[alsa_format->card][j]->
read(alsa_buffer,alsa_format->buffer_size*2/
alsa_format->periods)/(2*sizeof(int16_t));
for(unsigned k=0;k<2;k++) { // Stream Output Meters
stream_out_meter=0;
for(int l=0;l<n;l+=2) {
if(abs(((int16_t *)alsa_buffer)[l+k])>stream_out_meter) {
stream_out_meter=abs(((int16_t *)alsa_buffer)[l+k]);
}
}
alsa_stream_output_meter[alsa_format->card][j][k]->
addValue(((double)stream_out_meter)/32768.0);
}
modulo=alsa_format->channels;
for(unsigned i=0;i<(alsa_format->channels/2);i++) {
if(alsa_output_volume[alsa_format->card][i][j]!=0.0) {
for(int k=0;k<n;k++) {
((int16_t *)alsa_format->card_buffer)[modulo*k+2*i]+=
(int16_t)(alsa_output_volume[alsa_format->card][i][j]*
(double)(((int16_t *)alsa_buffer)[2*k]));
((int16_t *)alsa_format->card_buffer)[modulo*k+2*i+1]+=
(int16_t)(alsa_output_volume[alsa_format->card][i][j]*
(double)(((int16_t *)alsa_buffer)[2*k+1]));
}
}
}
break;
}
alsa_output_pos[alsa_format->card][j]+=n;
if((n==0)&&alsa_eof[alsa_format->card][j]) {
alsa_stopping[alsa_format->card][j]=true;
}
}
}
n=alsa_format->buffer_size/(2*alsa_format->periods);
//
// Process Passthroughs
//
for(unsigned i=0;i<alsa_format->capture_channels;i+=2) {
p=alsa_passthrough_ring[alsa_format->card][i/2]->
read(alsa_format->passthrough_buffer,4*n)/4;
for(unsigned j=0;j<alsa_format->channels;j+=2) {
for(unsigned k=0;k<2;k++) {
for(int l=0;l<p;l++) {
((int16_t *)alsa_format->
card_buffer)[alsa_format->channels*l+j+k]+=
(int16_t)((double)((int16_t *)
alsa_format->passthrough_buffer)[2*l+k]*
alsa_passthrough_volume[alsa_format->card][i/2][j/2]);
}
}
}
}
//
// Process Output Meters
//
for(unsigned i=0;i<alsa_format->channels;i+=2) {
unsigned port=i/2;
for(unsigned j=0;j<2;j++) {
out_meter[port][j]=0;
for(unsigned k=0;k<alsa_format->buffer_size;k++) {
if(((int16_t *)alsa_format->
card_buffer)[alsa_format->channels*k+2*i+j]>
out_meter[i][j]) {
out_meter[i][j]=
((int16_t *)alsa_format->
card_buffer)[alsa_format->channels*k+2*i+j];
}
}
alsa_output_meter[alsa_format->card][i][j]->
addValue(((double)out_meter[i][j])/32768.0);
}
}
break;
case SND_PCM_FORMAT_S32_LE:
for(unsigned j=0;j<RD_MAX_STREAMS;j++) {
if(alsa_playing[alsa_format->card][j]) {
switch(alsa_output_channels[alsa_format->card][j]) {
case 1:
n=alsa_play_ring[alsa_format->card][j]->
read(alsa_buffer,alsa_format->buffer_size/
alsa_format->periods)/(2*sizeof(int16_t));
stream_out_meter=0;
for(int k=0;k<n;k++) { // Stream Output Meters
if(abs(((int16_t *)alsa_buffer)[k])>stream_out_meter) {
stream_out_meter=abs(((int16_t *)alsa_buffer)[k]);
}
}
alsa_stream_output_meter[alsa_format->card][j][0]->
addValue(((double)stream_out_meter)/32768.0);
alsa_stream_output_meter[alsa_format->card][j][1]->
addValue(((double)stream_out_meter)/32768.0);
modulo=alsa_format->channels*2;
for(unsigned i=0;i<(alsa_format->channels/2);i++) {
if(alsa_output_volume[alsa_format->card][i][j]!=0.0) {
for(int k=0;k<(2*n);k++) {
((int16_t *)alsa_format->card_buffer)[modulo*k+4*i+1]+=
(int16_t)(alsa_output_volume[alsa_format->card][i][j]*
(double)(((int16_t *)alsa_buffer)[k]));
((int16_t *)alsa_format->card_buffer)[modulo*k+4*i+3]+=
(int16_t)(alsa_output_volume[alsa_format->card][i][j]*
(double)(((int16_t *)alsa_buffer)[k]));
}
}
}
n*=2;
break;
case 2:
n=alsa_play_ring[alsa_format->card][j]->
read(alsa_buffer,alsa_format->buffer_size*2/
alsa_format->periods)/(2*sizeof(int16_t));
for(unsigned k=0;k<2;k++) { // Stream Output Meters
stream_out_meter=0;
for(int l=0;l<n;l+=2) {
if(abs(((int16_t *)alsa_buffer)[l+k])>stream_out_meter) {
stream_out_meter=abs(((int16_t *)alsa_buffer)[l+k]);
}
}
alsa_stream_output_meter[alsa_format->card][j][k]->
addValue(((double)stream_out_meter)/32768.0);
}
modulo=alsa_format->channels*2;
for(unsigned i=0;i<(alsa_format->channels/2);i++) {
if(alsa_output_volume[alsa_format->card][i][j]!=0.0) {
for(int k=0;k<n;k++) {
((int16_t *)alsa_format->card_buffer)[modulo*k+4*i+1]+=
(int16_t)(alsa_output_volume[alsa_format->card][i][j]*
(double)(((int16_t *)alsa_buffer)[2*k]));
((int16_t *)alsa_format->card_buffer)[modulo*k+4*i+3]+=
(int16_t)(alsa_output_volume[alsa_format->card][i][j]*
(double)(((int16_t *)alsa_buffer)[2*k+1]));
}
}
}
break;
}
alsa_output_pos[alsa_format->card][j]+=n;
if((n==0)&&alsa_eof[alsa_format->card][j]) {
alsa_stopping[alsa_format->card][j]=true;
// Empty the ring buffer
while(alsa_play_ring[alsa_format->card][j]->
read(alsa_buffer,alsa_format->buffer_size*2/
alsa_format->periods)/(2*sizeof(int16_t))>0);
}
}
}
n=alsa_format->buffer_size/(2*alsa_format->periods);
//
// Process Passthroughs
//
for(unsigned i=0;i<alsa_format->capture_channels;i+=2) {
p=alsa_passthrough_ring[alsa_format->card][i/2]->
read(alsa_format->passthrough_buffer,8*n)/8;
for(unsigned j=0;j<alsa_format->channels;j+=2) {
for(unsigned k=0;k<2;k++) {
for(int l=0;l<p;l++) {
((int32_t *)alsa_format->
card_buffer)[alsa_format->channels*l+j+k]+=
(int32_t)((double)((int32_t *)
alsa_format->passthrough_buffer)[2*l+k]*
alsa_passthrough_volume[alsa_format->card][i/2][j/2]);
}
}
}
}
//
// Process Output Meters
//
for(unsigned i=0;i<alsa_format->channels;i+=2) {
unsigned port=i/2;
for(unsigned j=0;j<2;j++) {
out_meter[port][j]=0;
for(unsigned k=0;
k<(alsa_format->buffer_size*2/alsa_format->periods);
k++) {
if(((int16_t *)alsa_format->
card_buffer)[alsa_format->channels*2*k+2*i+1+2*j]>
out_meter[port][j]) {
out_meter[port][j]=
((int16_t *)alsa_format->
card_buffer)[alsa_format->channels*2*k+2*i+1+2*j];
}
}
alsa_output_meter[alsa_format->card][port][j]->
addValue(((double)out_meter[port][j])/32768.0);
}
}
break;
default:
break;
}
int s=snd_pcm_writei(alsa_format->pcm,alsa_format->card_buffer,n);
if(s!=n) {
if(s<0) {
LogLine(RDConfig::LogNotice,
QString().sprintf("*** alsa error %d: %s",-s,snd_strerror(s)));
}
else {
LogLine(RDConfig::LogNotice,
QString().sprintf("period size mismatch - wrote %d\n",s));
}
}
if((snd_pcm_state(alsa_format->pcm)!=SND_PCM_STATE_RUNNING)&&
(!alsa_format->exiting)) {
snd_pcm_drop (alsa_format->pcm);
snd_pcm_prepare(alsa_format->pcm);
LogLine(RDConfig::LogNotice,QString().
sprintf("****** ALSA Playout Xrun - Card: %d ******",
alsa_format->card));
}
}
}
void *AlsaPlayCallback(void *ptr)
{
struct alsa_format *alsa_format=(struct alsa_format *)ptr;
signal(SIGTERM,SigHandler);
signal(SIGINT,SigHandler);
switch(alsa_channels) {
case 1:
AlsaPlay1Callback(alsa_format);
break;
case 2:
AlsaPlay2Callback(alsa_format);
break;
}
return 0;
}
void MainObject::AlsaInitCallback()
{
int avg_periods=
(330*system_sample_rate)/(1000*rd_config->alsaPeriodSize());
for(int i=0;i<RD_MAX_CARDS;i++) {
for(int j=0;j<RD_MAX_PORTS;j++) {
alsa_recording[i][j]=false;
alsa_ready[i][j]=false;
alsa_input_volume[i][j]=1.0;
alsa_input_vox[i][j]=0.0;
for(int k=0;k<2;k++) {
alsa_input_meter[i][j][k]=new RDMeterAverage(avg_periods);
alsa_output_meter[i][j][k]=new RDMeterAverage(avg_periods);
}
for(int k=0;k<RD_MAX_STREAMS;k++) {
alsa_output_volume[i][j][k]=1.0;
}
alsa_passthrough_ring[i][j]=new RDRingBuffer(RINGBUFFER_SIZE);
alsa_passthrough_ring[i][j]->reset();
alsa_record_ring[i][j]=NULL;
for(int k=0;k<RD_MAX_PORTS;k++) {
alsa_passthrough_volume[i][j][k]=0.0;
}
}
for(int j=0;j<RD_MAX_STREAMS;j++) {
alsa_play_ring[i][j]=NULL;
alsa_playing[i][j]=false;
for(int k=0;k<2;k++) {
alsa_stream_output_meter[i][j][k]=new RDMeterAverage(avg_periods);
}
}
}
}
#endif // ALSA
void MainObject::alsaStopTimerData(int cardstream)
{
LogLine(RDConfig::LogErr,QString().sprintf("alsaStopTimerData(%d)",cardstream));
#ifdef ALSA
int card=cardstream/RD_MAX_STREAMS;
int stream=cardstream-card*RD_MAX_STREAMS;
alsaStopPlayback(card,stream);
statePlayUpdate(card,stream,2);
#endif // ALSA
}
void MainObject::alsaFadeTimerData(int cardstream)
{
#ifdef ALSA
int card=cardstream/RD_MAX_STREAMS;
int stream=cardstream-card*RD_MAX_STREAMS;
int16_t level;
if(alsa_fade_up[card][stream]) {
level=alsa_output_volume_db[card][alsa_fade_port[card][stream]][stream]+
alsa_fade_increment[card][stream];
if(level>=alsa_fade_volume_db[card][stream]) {
level=alsa_fade_volume_db[card][stream];
alsa_fade_timer[card][stream]->stop();
}
}
else {
level=alsa_output_volume_db[card][alsa_fade_port[card][stream]][stream]-
alsa_fade_increment[card][stream];
if(level<=alsa_fade_volume_db[card][stream]) {
level=alsa_fade_volume_db[card][stream];
alsa_fade_timer[card][stream]->stop();
}
}
LogLine(RDConfig::LogDebug,QString().sprintf("FadeLevel: %d",level));
alsaSetOutputVolume(card,stream,alsa_fade_port[card][stream],level);
#endif // ALSA
}
void MainObject::alsaRecordTimerData(int cardport)
{
#ifdef ALSA
int card=cardport/RD_MAX_PORTS;
int stream=cardport-card*RD_MAX_PORTS;
alsaStopRecord(card,stream);
stateRecordUpdate(card,stream,2);
#endif // ALSA
}
void MainObject::alsaInit(RDStation *station)
{
#ifdef ALSA
QString dev;
int card=0;
snd_pcm_t *pcm_play_handle;
snd_pcm_t *pcm_capture_handle;
snd_ctl_t *snd_ctl;
snd_ctl_card_info_t *card_info=NULL;
bool pcm_opened;
//
// Initialize Data Structures
//
for(int i=0;i<RD_MAX_CARDS;i++) {
for(int j=0;j<RD_MAX_STREAMS;j++) {
alsa_input_volume_db[i][j]=0;
alsa_samples_recorded[i][j]=0;
#ifdef HAVE_MAD
mad_mpeg[i][j]=new unsigned char[16384];
#endif // HAVE_MAD
for(int k=0;k<RD_MAX_PORTS;k++) {
alsa_output_volume_db[i][k][j]=0;
}
}
for(int j=0;j<RD_MAX_PORTS;j++) {
for(int k=0;k<RD_MAX_PORTS;k++) {
alsa_passthrough_volume_db[i][j][k]=RD_MUTE_DEPTH;
}
}
}
alsa_channels=rd_config->channels();
//
// Stop & Fade Timers
//
QSignalMapper *stop_mapper=new QSignalMapper(this,"stop_mapper");
connect(stop_mapper,SIGNAL(mapped(int)),this,SLOT(alsaStopTimerData(int)));
QSignalMapper *fade_mapper=new QSignalMapper(this,"fade_mapper");
connect(fade_mapper,SIGNAL(mapped(int)),this,SLOT(alsaFadeTimerData(int)));
QSignalMapper *record_mapper=new QSignalMapper(this,"record_mapper");
connect(record_mapper,SIGNAL(mapped(int)),
this,SLOT(alsaRecordTimerData(int)));
for(int i=0;i<RD_MAX_CARDS;i++) {
for(int j=0;j<RD_MAX_STREAMS;j++) {
alsa_stop_timer[i][j]=new QTimer(this);
stop_mapper->setMapping(alsa_stop_timer[i][j],i*RD_MAX_STREAMS+j);
connect(alsa_stop_timer[i][j],SIGNAL(timeout()),stop_mapper,SLOT(map()));
alsa_fade_timer[i][j]=new QTimer(this);
fade_mapper->setMapping(alsa_fade_timer[i][j],i*RD_MAX_STREAMS+j);
connect(alsa_fade_timer[i][j],SIGNAL(timeout()),fade_mapper,SLOT(map()));
}
for(int j=0;j<RD_MAX_PORTS;j++) {
alsa_record_timer[i][j]=new QTimer(this);
record_mapper->setMapping(alsa_record_timer[i][j],i*RD_MAX_PORTS+j);
connect(alsa_record_timer[i][j],SIGNAL(timeout()),
record_mapper,SLOT(map()));
}
}
//
// Allocate Temporary Buffers
//
AlsaInitCallback();
alsa_wave_buffer=new int16_t[RINGBUFFER_SIZE];
alsa_wave24_buffer=new uint8_t[2*RINGBUFFER_SIZE];
//alsa_resample_buffer=new int16_t[2*RINGBUFFER_SIZE];
//
// Start Up Interfaces
//
for(int i=0;i<RD_MAX_CARDS;i++) {
if(cae_driver[i]==RDStation::None) {
pcm_opened=false;
// These are used to flag bits of card that are not setup
// They are cleared just before the pthreads are created.
alsa_play_format[i].exiting = true;
alsa_capture_format[i].exiting = true;
dev=QString().sprintf("rd%d",card);
if(snd_pcm_open(&pcm_play_handle,(const char *)dev,
SND_PCM_STREAM_PLAYBACK,0)==0){
pcm_opened=true;
if(AlsaStartPlayDevice(dev,i,pcm_play_handle)) {
cae_driver[i]=RDStation::Alsa;
}
else {
snd_pcm_close(pcm_play_handle);
}
}
if(snd_pcm_open(&pcm_capture_handle,(const char *)dev,
SND_PCM_STREAM_CAPTURE,0)==0) {
pcm_opened=true;
if(AlsaStartCaptureDevice(dev,i,pcm_capture_handle)) {
cae_driver[i]=RDStation::Alsa;
}
else {
snd_pcm_close(pcm_capture_handle);
}
}
if(cae_driver[i]==RDStation::Alsa) {
station->setCardDriver(i,RDStation::Alsa);
if(snd_ctl_open(&snd_ctl,dev,0)<0) {
LogLine(RDConfig::LogNotice,QString().
sprintf("no control device found for %s",
(const char *)dev));
station->
setCardName(i,
QString().sprintf("ALSA Device %s",(const char *)dev));
}
else {
snd_ctl_card_info_malloc(&card_info);
snd_ctl_card_info(snd_ctl,card_info);
station->
setCardName(i,snd_ctl_card_info_get_longname(card_info));
snd_ctl_close(snd_ctl);
}
station->
setCardInputs(i,
alsa_capture_format[i].channels/rd_config->channels());
station->
setCardOutputs(i,alsa_play_format[i].channels/rd_config->channels());
}
else {
i--;
}
card++;
if(!pcm_opened) {
return;
}
}
}
#endif // ALSA
}
void MainObject::alsaFree()
{
#ifdef ALSA
for(int i=0;i<RD_MAX_CARDS;i++) {
if(cae_driver[i]==RDStation::Alsa) {
alsa_play_format[i].exiting=true;
pthread_join(alsa_play_format[i].thread,NULL);
snd_pcm_close(alsa_play_format[i].pcm);
if(alsa_capture_format[i].pcm!=NULL) {
printf("SHUTDOWN 1\n");
alsa_capture_format[i].exiting=true;
printf("SHUTDOWN 2\n");
pthread_join(alsa_capture_format[i].thread,NULL);
printf("SHUTDOWN 3\n");
snd_pcm_close(alsa_capture_format[i].pcm);
printf("SHUTDOWN 4\n");
}
}
}
#endif // ALSA
}
bool MainObject::alsaLoadPlayback(int card,QString wavename,int *stream)
{
#ifdef ALSA
if(alsa_play_format[card].exiting||((*stream=GetAlsaOutputStream(card))<0)) {
LogLine(RDConfig::LogErr,QString().sprintf(
"Error: alsaLoadPlayback(%s) GetAlsaOutputStream():%d < 0",
(const char *) wavename,
*stream) );
return false;
}
alsa_play_wave[card][*stream]=new RDWaveFile(wavename);
if(!alsa_play_wave[card][*stream]->openWave()) {
LogLine(RDConfig::LogErr,QString().sprintf(
"Error: alsaLoadPlayback(%s) openWave() failed to open file",
(const char *) wavename) );
delete alsa_play_wave[card][*stream];
alsa_play_wave[card][*stream]=NULL;
FreeAlsaOutputStream(card,*stream);
*stream=-1;
return false;
}
switch(alsa_play_wave[card][*stream]->getFormatTag()) {
case WAVE_FORMAT_PCM:
case WAVE_FORMAT_VORBIS:
break;
case WAVE_FORMAT_MPEG:
InitMadDecoder(card,*stream,alsa_play_wave[card][*stream]);
break;
default:
LogLine(RDConfig::LogErr,QString().sprintf(
"Error: alsaLoadPlayback(%s) getFormatTag()%d || getBistsPerSample()%d failed",
(const char *) wavename,
alsa_play_wave[card][*stream]->getFormatTag(),
alsa_play_wave[card][*stream]->getBitsPerSample() ));
delete alsa_play_wave[card][*stream];
alsa_play_wave[card][*stream]=NULL;
FreeAlsaOutputStream(card,*stream);
*stream=-1;
return false;
}
alsa_output_channels[card][*stream]=
alsa_play_wave[card][*stream]->getChannels();
alsa_stopping[card][*stream]=false;
alsa_offset[card][*stream]=0;
alsa_output_pos[card][*stream]=0;
alsa_eof[card][*stream]=false;
alsa_play_ring[card][*stream]->reset();
FillAlsaOutputStream(card,*stream);
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaUnloadPlayback(int card,int stream)
{
#ifdef ALSA
if(alsa_play_ring[card][stream]==NULL) {
return false;
}
alsa_playing[card][stream]=false;
switch(alsa_play_wave[card][stream]->getFormatTag()) {
case WAVE_FORMAT_MPEG:
FreeMadDecoder(card,stream);
break;
}
alsa_play_wave[card][stream]->closeWave();
delete alsa_play_wave[card][stream];
alsa_play_wave[card][stream]=NULL;
FreeAlsaOutputStream(card,stream);
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaPlaybackPosition(int card,int stream,unsigned pos)
{
#ifdef ALSA
unsigned offset=0;
if(alsa_play_format[card].exiting){
return false;
}
switch(alsa_play_wave[card][stream]->getFormatTag()) {
case WAVE_FORMAT_PCM:
offset=(unsigned)((double)alsa_play_wave[card][stream]->getSamplesPerSec()*
(double)alsa_play_wave[card][stream]->getBlockAlign()*
(double)pos/1000);
alsa_offset[card][stream]=
offset/alsa_play_wave[card][stream]->getBlockAlign();
offset=
alsa_offset[card][stream]*alsa_play_wave[card][stream]->getBlockAlign();
break;
case WAVE_FORMAT_MPEG:
offset=(unsigned)((double)alsa_play_wave[card][stream]->getSamplesPerSec()*
(double)pos/1000);
alsa_offset[card][stream]=offset/1152*1152;
offset=alsa_offset[card][stream]/1152*
alsa_play_wave[card][stream]->getBlockAlign();
FreeMadDecoder(card,stream);
InitMadDecoder(card,stream,alsa_play_wave[card][stream]);
break;
}
if(alsa_offset[card][stream]>
(int)alsa_play_wave[card][stream]->getSampleLength()) {
return false;
}
alsa_output_pos[card][stream]=0;
alsa_play_wave[card][stream]->seekWave(offset,SEEK_SET);
alsa_eof[card][stream]=false;
alsa_play_ring[card][stream]->reset();
FillAlsaOutputStream(card,stream);
if(alsa_playing[card][stream]) {
alsa_stop_timer[card][stream]->stop();
alsa_stop_timer[card][stream]->
start(alsa_play_wave[card][stream]->getExtTimeLength()-pos,true);
}
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaPlay(int card,int stream,int length,int speed,bool pitch,
bool rates)
{
#ifdef ALSA
if((alsa_play_ring[card][stream]==NULL)||
alsa_playing[card][stream]||(speed!=RD_TIMESCALE_DIVISOR)) {
return false;
}
alsa_playing[card][stream]=true;
if(length>0) {
alsa_stop_timer[card][stream]->start(length,true);
}
statePlayUpdate(card,stream,1);
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaTimescaleSupported(int card)
{
#ifdef ALSA
return false;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaStopPlayback(int card,int stream)
{
#ifdef ALSA
if((alsa_play_ring[card][stream]==NULL)||(!alsa_playing[card][stream])) {
return false;
}
alsa_playing[card][stream]=false;
alsa_play_ring[card][stream]->reset();
alsa_stop_timer[card][stream]->stop();
statePlayUpdate(card,stream,2);
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaLoadRecord(int card,int stream,int coding,int chans,
int samprate,int bitrate,QString wavename)
{
#ifdef ALSA
alsa_record_wave[card][stream]=new RDWaveFile(wavename);
switch(coding) {
case 0: // PCM16
alsa_record_wave[card][stream]->setFormatTag(WAVE_FORMAT_PCM);
alsa_record_wave[card][stream]->setChannels(chans);
alsa_record_wave[card][stream]->setSamplesPerSec(samprate);
alsa_record_wave[card][stream]->setBitsPerSample(16);
break;
case 4: // PCM24
alsa_record_wave[card][stream]->setFormatTag(WAVE_FORMAT_PCM);
alsa_record_wave[card][stream]->setChannels(chans);
alsa_record_wave[card][stream]->setSamplesPerSec(samprate);
alsa_record_wave[card][stream]->setBitsPerSample(24);
break;
case 2: // MPEG Layer 2
if(!InitTwoLameEncoder(card,stream,chans,samprate,bitrate)) {
delete alsa_record_wave[card][stream];
alsa_record_wave[card][stream]=NULL;
return false;
}
alsa_record_wave[card][stream]->setFormatTag(WAVE_FORMAT_MPEG);
alsa_record_wave[card][stream]->setChannels(chans);
alsa_record_wave[card][stream]->setSamplesPerSec(samprate);
alsa_record_wave[card][stream]->setBitsPerSample(16);
alsa_record_wave[card][stream]->setHeadLayer(ACM_MPEG_LAYER2);
switch(chans) {
case 1:
alsa_record_wave[card][stream]->setHeadMode(ACM_MPEG_SINGLECHANNEL);
break;
case 2:
alsa_record_wave[card][stream]->setHeadMode(ACM_MPEG_STEREO);
break;
default:
LogLine(RDConfig::LogErr,QString().
sprintf("requested unsupported channel count %d, card: %d, stream: %d",
chans,card,stream));
delete alsa_record_wave[card][stream];
alsa_record_wave[card][stream]=NULL;
return false;
}
alsa_record_wave[card][stream]->setHeadBitRate(bitrate);
alsa_record_wave[card][stream]->setMextChunk(true);
alsa_record_wave[card][stream]->setMextHomogenous(true);
alsa_record_wave[card][stream]->setMextPaddingUsed(false);
alsa_record_wave[card][stream]->setMextHackedBitRate(true);
alsa_record_wave[card][stream]->setMextFreeFormat(false);
alsa_record_wave[card][stream]->
setMextFrameSize(144*alsa_record_wave[card][stream]->getHeadBitRate()/
alsa_record_wave[card][stream]->getSamplesPerSec());
alsa_record_wave[card][stream]->setMextAncillaryLength(5);
alsa_record_wave[card][stream]->setMextLeftEnergyPresent(true);
if(chans>1) {
alsa_record_wave[card][stream]->setMextRightEnergyPresent(true);
}
else {
alsa_record_wave[card][stream]->setMextRightEnergyPresent(false);
}
alsa_record_wave[card][stream]->setMextPrivateDataPresent(false);
break;
default:
LogLine(RDConfig::LogErr,QString().
sprintf("requested invalid audio encoding %d, card: %d, stream: %d",
coding,card,stream));
delete alsa_record_wave[card][stream];
alsa_record_wave[card][stream]=NULL;
return false;
}
alsa_record_wave[card][stream]->setBextChunk(true);
alsa_record_wave[card][stream]->setLevlChunk(true);
if(!alsa_record_wave[card][stream]->createWave()) {
delete alsa_record_wave[card][stream];
alsa_record_wave[card][stream]=NULL;
return false;
}
chown((const char *)wavename,rd_config->uid(),rd_config->gid());
alsa_input_channels[card][stream]=chans;
alsa_record_ring[card][stream]=new RDRingBuffer(RINGBUFFER_SIZE);
alsa_record_ring[card][stream]->reset();
alsa_ready[card][stream]=true;
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaUnloadRecord(int card,int stream,unsigned *len)
{
#ifdef ALSA
alsa_recording[card][stream]=false;
alsa_ready[card][stream]=false;
EmptyAlsaInputStream(card,stream);
*len=alsa_samples_recorded[card][stream];
alsa_samples_recorded[card][stream]=0;
alsa_record_wave[card][stream]->closeWave(*len);
delete alsa_record_wave[card][stream];
alsa_record_wave[card][stream]=NULL;
delete alsa_record_ring[card][stream];
alsa_record_ring[card][stream]=NULL;
FreeTwoLameEncoder(card,stream);
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaRecord(int card,int stream,int length,int thres)
{
#ifdef ALSA
if(!alsa_ready[card][stream]) {
return false;
}
alsa_recording[card][stream]=true;
if(alsa_input_vox[card][stream]==0.0) {
if(length>0) {
alsa_record_timer[card][stream]->start(length,true);
}
stateRecordUpdate(card,stream,4);
}
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaStopRecord(int card,int stream)
{
#ifdef ALSA
if(!alsa_recording[card][stream]) {
return false;
}
alsa_recording[card][stream]=false;
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaSetInputVolume(int card,int stream,int level)
{
#ifdef ALSA
if(level>-10000) {
alsa_input_volume[card][stream]=pow10((double)level/2000.0);
alsa_input_volume_db[card][stream]=level;
}
else {
alsa_input_volume[card][stream]=0.0;
alsa_input_volume_db[card][stream]=-10000;
}
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaSetOutputVolume(int card,int stream,int port,int level)
{
#ifdef ALSA
if(level>-10000) {
alsa_output_volume[card][port][stream]=pow10((double)level/2000.0);
alsa_output_volume_db[card][port][stream]=level;
}
else {
alsa_output_volume[card][port][stream]=0.0;
alsa_output_volume_db[card][port][stream]=-10000;
}
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaFadeOutputVolume(int card,int stream,int port,int level,
int length)
{
#ifdef ALSA
int diff;
if(alsa_fade_timer[card][stream]->isActive()) {
alsa_fade_timer[card][stream]->stop();
}
if(level>alsa_output_volume_db[card][port][stream]) {
alsa_fade_up[card][stream]=true;
diff=level-alsa_output_volume_db[card][port][stream];
}
else {
alsa_fade_up[card][stream]=false;
diff=alsa_output_volume_db[card][port][stream]-level;
}
alsa_fade_volume_db[card][stream]=level;
alsa_fade_port[card][stream]=port;
alsa_fade_increment[card][stream]=diff*RD_ALSA_FADE_INTERVAL/length;
alsa_fade_timer[card][stream]->start(RD_ALSA_FADE_INTERVAL);
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaSetInputLevel(int card,int port,int level)
{
#ifdef ALSA
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaSetOutputLevel(int card,int port,int level)
{
#ifdef ALSA
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaSetInputMode(int card,int stream,int mode)
{
#ifdef ALSA
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaSetOutputMode(int card,int stream,int mode)
{
#ifdef ALSA
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaSetInputVoxLevel(int card,int stream,int level)
{
#ifdef ALSA
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaSetInputType(int card,int port,int type)
{
#ifdef ALSA
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaGetInputStatus(int card,int port)
{
#ifdef ALSA
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaGetInputMeters(int card,int port,int16_t levels[2])
{
#ifdef ALSA
double meter;
for(int i=0;i<2;i++) {
meter=alsa_input_meter[card][port][i]->average();
if(meter==0.0) {
levels[i]=-10000;
}
else {
levels[i]=(int16_t)(2000.0*log10(meter));
if(levels[i]<-10000) {
levels[i]=-10000;
}
}
}
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaGetOutputMeters(int card,int port,int16_t levels[2])
{
#ifdef ALSA
double meter;
for(int i=0;i<2;i++) {
meter=alsa_output_meter[card][port][i]->average();
if(meter==0.0) {
levels[i]=-10000;
}
else {
levels[i]=(int16_t)(2000.0*log10(meter));
if(levels[i]<-10000) {
levels[i]=-10000;
}
}
}
return true;
#else
return false;
#endif // ALSA
}
bool MainObject::alsaGetStreamOutputMeters(int card,int stream,int16_t levels[2])
{
#ifdef ALSA
double meter;
for(int i=0;i<2;i++) {
meter=alsa_stream_output_meter[card][stream][i]->average();
if(meter==0.0) {
levels[i]=-10000;
}
else {
levels[i]=(int16_t)(2000.0*log10(meter));
if(levels[i]<-10000) {
levels[i]=-10000;
}
}
}
return true;
#else
return false;
#endif // ALSA
}
void MainObject::alsaGetOutputPosition(int card,unsigned *pos)
{// pos is in miliseconds
#ifdef ALSA
for(int i=0;i<RD_MAX_STREAMS;i++) {
if((!alsa_play_format[card].exiting)&&(alsa_play_wave[card][i]!=NULL)) {
pos[i]=1000*(unsigned long long)(alsa_offset[card][i]+
alsa_output_pos[card][i])/
alsa_play_wave[card][i]->getSamplesPerSec();
}
else {
pos[i]=0;
}
}
#endif // ALSA
}
bool MainObject::alsaSetPassthroughLevel(int card,int in_port,int out_port,
int level)
{
#ifdef ALSA
if(level>-10000) {
alsa_passthrough_volume[card][in_port][out_port]=
pow10((double)level/2000.0);
alsa_passthrough_volume_db[card][in_port][out_port]=level;
}
else {
alsa_passthrough_volume[card][in_port][out_port]=0.0;
alsa_passthrough_volume_db[card][in_port][out_port]=-10000;
}
return true;
#else
return false;
#endif // ALSA
}
#ifdef ALSA
bool MainObject::AlsaStartCaptureDevice(QString &dev,int card,snd_pcm_t *pcm)
{
snd_pcm_hw_params_t *hwparams;
snd_pcm_sw_params_t *swparams;
int dir;
int err;
pthread_attr_t pthread_attr;
unsigned sr;
memset(&alsa_capture_format[card],0,sizeof(struct alsa_format));
snd_pcm_hw_params_alloca(&hwparams);
snd_pcm_hw_params_any(pcm,hwparams);
LogLine(RDConfig::LogInfo,QString().
sprintf("Starting ALSA Capture Device %s:",
(const char *)dev));
//
// Access Type
//
if(snd_pcm_hw_params_test_access(pcm,hwparams,
SND_PCM_ACCESS_RW_INTERLEAVED)<0) {
LogLine(RDConfig::LogErr," Interleaved access not supported,");
LogLine(RDConfig::LogErr," aborting initialization of device.");
return false;
}
snd_pcm_hw_params_set_access(pcm,hwparams,SND_PCM_ACCESS_RW_INTERLEAVED);
//
// Sample Format
//
if(snd_pcm_hw_params_test_format(pcm,hwparams,SND_PCM_FORMAT_S32_LE)==0) {
alsa_capture_format[card].format=SND_PCM_FORMAT_S32_LE;
LogLine(RDConfig::LogDebug," Format = 32 bit little-endian");
}
else {
if(snd_pcm_hw_params_test_format(pcm,hwparams,SND_PCM_FORMAT_S16_LE)==0) {
alsa_capture_format[card].format=SND_PCM_FORMAT_S16_LE;
LogLine(RDConfig::LogDebug," Format = 16 bit little-endian");
}
else {
LogLine(RDConfig::LogErr,
" Neither 16 nor 32 bit little-endian formats available,");
LogLine(RDConfig::LogErr,
" aborting initialization of device.");
return false;
}
}
snd_pcm_hw_params_set_format(pcm,hwparams,alsa_capture_format[card].format);
//
// Sample Rate
//
if(alsa_play_format[card].sample_rate>0) {
sr=alsa_play_format[card].sample_rate;
}
else {
sr=system_sample_rate;
}
snd_pcm_hw_params_set_rate_near(pcm,hwparams,&sr,&dir);
if((sr<(system_sample_rate-RD_ALSA_SAMPLE_RATE_TOLERANCE))||
(sr>(system_sample_rate+RD_ALSA_SAMPLE_RATE_TOLERANCE))) {
LogLine(RDConfig::LogErr,
QString().sprintf(" Asked for sample rate %u, got %u",
system_sample_rate,sr));
LogLine(RDConfig::LogErr," Sample rate unsupported by device");
return false;
}
alsa_capture_format[card].sample_rate=sr;
LogLine(RDConfig::LogNotice,QString().sprintf(" SampleRate = %u",sr));
//
// Channels
//
if(rd_config->alsaChannelsPerPcm()<0) {
alsa_capture_format[card].channels=rd_config->channels()*RD_MAX_PORTS;
}
else {
alsa_capture_format[card].channels=rd_config->alsaChannelsPerPcm();
}
snd_pcm_hw_params_set_channels_near(pcm,hwparams,
&alsa_capture_format[card].channels);
alsa_play_format[card].capture_channels=alsa_capture_format[card].channels;
LogLine(RDConfig::LogDebug,QString().
sprintf(" Aggregate Channels = %u",
alsa_capture_format[card].channels));
//
// Buffer Size
//
alsa_capture_format[card].periods=rd_config->alsaPeriodQuantity();
snd_pcm_hw_params_set_periods_near(pcm,hwparams,
&alsa_capture_format[card].periods,&dir);
LogLine(RDConfig::LogDebug,QString().sprintf(" Periods = %u",
alsa_capture_format[card].periods));
alsa_capture_format[card].buffer_size=
alsa_capture_format[card].periods*rd_config->alsaPeriodSize();
snd_pcm_hw_params_set_buffer_size_near(pcm,hwparams,
&alsa_capture_format[card].buffer_size);
LogLine(RDConfig::LogDebug,QString().sprintf(" BufferSize = %u frames",
(unsigned)alsa_capture_format[card].buffer_size));
//
// Fire It Up
//
if((err=snd_pcm_hw_params(pcm,hwparams))<0) {
LogLine(RDConfig::LogErr,QString().sprintf(" Device Error: %s,",
(const char *)snd_strerror(err)));
LogLine(RDConfig::LogErr," aborting initialization of device.");
return false;
}
LogLine(RDConfig::LogNotice," Device started successfully");
switch(alsa_capture_format[card].format) {
case SND_PCM_FORMAT_S16_LE:
alsa_capture_format[card].card_buffer_size=
alsa_capture_format[card].buffer_size*
alsa_capture_format[card].channels*2;
break;
case SND_PCM_FORMAT_S32_LE:
alsa_capture_format[card].card_buffer_size=
alsa_capture_format[card].buffer_size*
alsa_capture_format[card].channels*4;
break;
default:
break;
}
alsa_capture_format[card].card_buffer=
new char[alsa_capture_format[card].card_buffer_size];
alsa_capture_format[card].passthrough_buffer=
new char[alsa_capture_format[card].card_buffer_size];
alsa_capture_format[card].pcm=pcm;
alsa_capture_format[card].card=card;
//
// Set Wake-up Timing
//
snd_pcm_sw_params_alloca(&swparams);
snd_pcm_sw_params_current(pcm,swparams);
snd_pcm_sw_params_set_avail_min(pcm,swparams,rd_config->alsaPeriodSize());
if((err=snd_pcm_sw_params(pcm,swparams))<0) {
LogLine(RDConfig::LogErr,QString().sprintf("ALSA Device %s: %s",
(const char *)dev,
(const char *)snd_strerror(err)));
return false;
}
//
// Start the Callback
//
pthread_attr_init(&pthread_attr);
/*
if(use_realtime) {
pthread_attr_setschedpolicy(&pthread_attr,SCHED_FIFO);
}
*/
alsa_capture_format[card].exiting = false;
pthread_create(&alsa_capture_format[card].thread,&pthread_attr,
AlsaCaptureCallback,&alsa_capture_format[card]);
return true;
}
bool MainObject::AlsaStartPlayDevice(QString &dev,int card,snd_pcm_t *pcm)
{
snd_pcm_hw_params_t *hwparams;
snd_pcm_sw_params_t *swparams;
int dir;
int err;
pthread_attr_t pthread_attr;
unsigned sr;
memset(&alsa_play_format[card],0,sizeof(struct alsa_format));
snd_pcm_hw_params_alloca(&hwparams);
snd_pcm_hw_params_any(pcm,hwparams);
LogLine(RDConfig::LogNotice,QString().sprintf("Starting ALSA Play Device %s:",
(const char *)dev));
//
// Access Type
//
if(snd_pcm_hw_params_test_access(pcm,hwparams,
SND_PCM_ACCESS_RW_INTERLEAVED)<0) {
LogLine(RDConfig::LogErr," Interleaved access not supported,");
LogLine(RDConfig::LogErr," aborting initialization of device.");
return false;
}
snd_pcm_hw_params_set_access(pcm,hwparams,SND_PCM_ACCESS_RW_INTERLEAVED);
//
// Sample Format
//
if(snd_pcm_hw_params_test_format(pcm,hwparams,SND_PCM_FORMAT_S32_LE)==0) {
alsa_play_format[card].format=SND_PCM_FORMAT_S32_LE;
LogLine(RDConfig::LogDebug," Format = 32 bit little-endian");
}
else {
if(snd_pcm_hw_params_test_format(pcm,hwparams,SND_PCM_FORMAT_S16_LE)==0) {
alsa_play_format[card].format=SND_PCM_FORMAT_S16_LE;
LogLine(RDConfig::LogDebug," Format = 16 bit little-endian");
}
else {
LogLine(RDConfig::LogErr,
" Neither 16 nor 32 bit little-endian formats available,");
LogLine(RDConfig::LogErr," aborting initialization of device.");
return false;
}
}
snd_pcm_hw_params_set_format(pcm,hwparams,alsa_play_format[card].format);
//
// Sample Rate
//
sr=system_sample_rate;
snd_pcm_hw_params_set_rate_near(pcm,hwparams,&sr,&dir);
if((sr<(system_sample_rate-RD_ALSA_SAMPLE_RATE_TOLERANCE))||
(sr>(system_sample_rate+RD_ALSA_SAMPLE_RATE_TOLERANCE))) {
LogLine(RDConfig::LogErr,
QString().sprintf(" Asked for sample rate %u, got %u",
system_sample_rate,sr));
LogLine(RDConfig::LogErr," Sample rate unsupported by device");
return false;
}
alsa_play_format[card].sample_rate=sr;
LogLine(RDConfig::LogDebug,QString().sprintf(" SampleRate = %u",sr));
//
// Channels
//
if(rd_config->alsaChannelsPerPcm()<0) {
alsa_play_format[card].channels=rd_config->channels()*RD_MAX_PORTS;
}
else {
alsa_play_format[card].channels=rd_config->alsaChannelsPerPcm();
}
snd_pcm_hw_params_set_channels_near(pcm,hwparams,
&alsa_play_format[card].channels);
LogLine(RDConfig::LogDebug,QString().sprintf(" Aggregate Channels = %u",
alsa_play_format[card].channels));
//
// Buffer Size
//
alsa_play_format[card].periods=rd_config->alsaPeriodQuantity();
snd_pcm_hw_params_set_periods_near(pcm,hwparams,
&alsa_play_format[card].periods,&dir);
LogLine(RDConfig::LogDebug,QString().sprintf(" Periods = %u",
alsa_play_format[card].periods));
alsa_play_format[card].buffer_size=
alsa_play_format[card].periods*rd_config->alsaPeriodSize();
snd_pcm_hw_params_set_buffer_size_near(pcm,hwparams,
&alsa_play_format[card].buffer_size);
LogLine(RDConfig::LogDebug,QString().
sprintf(" BufferSize = %u frames",
(unsigned)alsa_play_format[card].buffer_size));
//
// Fire It Up
//
if((err=snd_pcm_hw_params(pcm,hwparams))<0) {
LogLine(RDConfig::LogErr,QString().sprintf(" Device Error: %s,",
(const char *)snd_strerror(err)));
LogLine(RDConfig::LogErr," aborting initialization of device.");
return false;
}
LogLine(RDConfig::LogNotice," Device started successfully");
switch(alsa_play_format[card].format) {
case SND_PCM_FORMAT_S16_LE:
alsa_play_format[card].card_buffer_size=
alsa_play_format[card].buffer_size*alsa_play_format[card].channels*2;
break;
case SND_PCM_FORMAT_S32_LE:
alsa_play_format[card].card_buffer_size=
alsa_play_format[card].buffer_size*alsa_play_format[card].channels*4;
break;
default:
break;
}
alsa_play_format[card].card_buffer=
new char[alsa_play_format[card].card_buffer_size];
alsa_play_format[card].passthrough_buffer=
new char[alsa_play_format[card].card_buffer_size];
alsa_play_format[card].pcm=pcm;
alsa_play_format[card].card=card;
//
// Set Wake-up Timing
//
snd_pcm_sw_params_alloca(&swparams);
snd_pcm_sw_params_current(pcm,swparams);
snd_pcm_sw_params_set_avail_min(pcm,swparams,rd_config->alsaPeriodSize());
if((err=snd_pcm_sw_params(pcm,swparams))<0) {
LogLine(RDConfig::LogErr,QString().sprintf("ALSA Device %s: %s",
(const char *)dev,
(const char *)snd_strerror(err)));
return false;
}
//
// Start the Callback
//
pthread_attr_init(&pthread_attr);
/*
if(use_realtime) {
pthread_attr_setschedpolicy(&pthread_attr,SCHED_FIFO);
}
*/
alsa_play_format[card].exiting = false;
pthread_create(&alsa_play_format[card].thread,&pthread_attr,
AlsaPlayCallback,&alsa_play_format[card]);
return true;
}
int MainObject::GetAlsaOutputStream(int card)
{
for(int i=0;i<RD_MAX_STREAMS;i++) {
if(alsa_play_ring[card][i]==NULL) {
alsa_play_ring[card][i]=new RDRingBuffer(RINGBUFFER_SIZE);
return i;
}
}
return -1;
}
void MainObject::FreeAlsaOutputStream(int card,int stream)
{
delete alsa_play_ring[card][stream];
alsa_play_ring[card][stream]=NULL;
}
void MainObject::EmptyAlsaInputStream(int card,int stream)
{
unsigned n=alsa_record_ring[card][stream]->
read((char *)alsa_wave_buffer,alsa_record_ring[card][stream]->
readSpace());
WriteAlsaBuffer(card,stream,alsa_wave_buffer,n);
}
void MainObject::WriteAlsaBuffer(int card,int stream,int16_t *buffer,unsigned len)
{
ssize_t s;
unsigned char mpeg[2048];
unsigned frames;
unsigned n;
frames=len/(2*alsa_record_wave[card][stream]->getChannels());
alsa_samples_recorded[card][stream]+=frames;
switch(alsa_record_wave[card][stream]->getFormatTag()) {
case WAVE_FORMAT_PCM:
switch(alsa_record_wave[card][stream]->getBitsPerSample()) {
case 16: // PCM16
alsa_record_wave[card][stream]->writeWave(buffer,len);
break;
case 24: // PCM24
for(unsigned i=0;i<(len/2);i++) {
alsa_wave24_buffer[3*i]=0; // FIXME: we lose eight bits here!
alsa_wave24_buffer[3*i+1]=((uint8_t *)buffer)[2*i];
alsa_wave24_buffer[3*i+2]=((uint8_t *)buffer)[2*i+1];
}
alsa_record_wave[card][stream]->writeWave(alsa_wave24_buffer,3*len/2);
break;
}
break;
case WAVE_FORMAT_MPEG:
#ifdef HAVE_TWOLAME
for(unsigned i=0;i<frames;i+=1152) {
if((i+1152)>frames) {
n=frames-i;
}
else {
n=1152;
}
if((s=twolame_encode_buffer_interleaved(twolame_lameopts[card][stream],
buffer+i*alsa_record_wave[card][stream]->getChannels(),
n,mpeg,2048))>=0) {
alsa_record_wave[card][stream]->writeWave(mpeg,s);
}
else {
LogLine(RDConfig::LogErr,QString().
sprintf("TwoLAME encode error, card: %d, stream: %d",card,stream));
}
}
#endif // HAVE_TWOLAME
break;
}
}
void MainObject::FillAlsaOutputStream(int card,int stream)
{
unsigned mpeg_frames=0;
unsigned frame_offset=0;
int m=0;
int n=0;
double ratio=0.0;
int free=(alsa_play_ring[card][stream]->writeSpace()-1);
if(free<=0) {
return;
}
ratio=(double)alsa_play_format[card].sample_rate/
(double)alsa_play_wave[card][stream]->getSamplesPerSec();
switch(alsa_play_wave[card][stream]->getFormatTag()) {
case WAVE_FORMAT_PCM:
case WAVE_FORMAT_VORBIS:
switch(alsa_play_wave[card][stream]->getBitsPerSample()) {
case 16: // PCM16
free=(int)((double)free/ratio)/(2*alsa_output_channels[card][stream])*
(2*alsa_output_channels[card][stream]);
n=alsa_play_wave[card][stream]->readWave(alsa_wave_buffer,free);
if(n!=free) {
alsa_eof[card][stream]=true;
alsa_stop_timer[card][stream]->stop();
}
break;
case 24: // PCM24
free=(int)((double)free/ratio)/(2*alsa_output_channels[card][stream])*
(2*alsa_output_channels[card][stream]);
n=2*alsa_play_wave[card][stream]->readWave(alsa_wave24_buffer,3*free/2)/3;
if(n!=free) {
alsa_eof[card][stream]=true;
alsa_stop_timer[card][stream]->stop();
break;
}
for(int i=0;i<n/2;i++) {
((uint8_t *)alsa_wave_buffer)[2*i]=alsa_wave24_buffer[3*i+1];
((uint8_t *)alsa_wave_buffer)[2*i+1]=alsa_wave24_buffer[3*i+2];
}
}
break;
case WAVE_FORMAT_MPEG:
#ifdef HAVE_MAD
mpeg_frames=free/(2304*alsa_output_channels[card][stream]);
free=mpeg_frames*2304*alsa_output_channels[card][stream];
for(unsigned i=0;i<mpeg_frames;i++) {
m=alsa_play_wave[card][stream]->
readWave(mad_mpeg[card][stream]+mad_left_over[card][stream],
mad_frame_size[card][stream]);
if(m==mad_frame_size[card][stream]) {
mad_stream_buffer(&mad_stream[card][stream],mad_mpeg[card][stream],
m+mad_left_over[card][stream]);
while(mad_frame_decode(&mad_frame[card][stream],
&mad_stream[card][stream])==0) {
mad_synth_frame(&mad_synth[card][stream],&mad_frame[card][stream]);
n+=(2*alsa_output_channels[card][stream]*
mad_synth[card][stream].pcm.length);
for(int j=0;j<mad_synth[card][stream].pcm.length;j++) {
for(int k=0;k<mad_synth[card][stream].pcm.channels;k++) {
alsa_wave_buffer[frame_offset+
j*mad_synth[card][stream].pcm.channels+k]=
(int16_t)(32768.0*mad_f_todouble(mad_synth[card][stream].
pcm.samples[k][j]));
}
}
frame_offset+=(mad_synth[card][stream].pcm.length*
mad_synth[card][stream].pcm.channels);
}
}
else { // End-of-file, read out last samples
if(!alsa_eof[card][stream]) {
memset(mad_mpeg[card][stream]+mad_left_over[card][stream],0,
MAD_BUFFER_GUARD);
mad_stream_buffer(&mad_stream[card][stream],
mad_mpeg[card][stream],
MAD_BUFFER_GUARD+mad_left_over[card][stream]);
if(mad_frame_decode(&mad_frame[card][stream],
&mad_stream[card][stream])==0) {
mad_synth_frame(&mad_synth[card][stream],
&mad_frame[card][stream]);
n+=(alsa_output_channels[card][stream]*
mad_synth[card][stream].pcm.length);
for(int j=0;j<mad_synth[card][stream].pcm.length;j++) {
for(int k=0;k<mad_synth[card][stream].pcm.channels;k++) {
alsa_wave_buffer[frame_offset+
j*mad_synth[card][stream].pcm.channels+k]=
(int16_t)(32768.0*mad_f_todouble(mad_synth[card][stream].
pcm.samples[k][j]));
}
}
}
}
alsa_eof[card][stream]=true;
alsa_stop_timer[card][stream]->stop();
continue;
}
mad_left_over[card][stream]=
mad_stream[card][stream].bufend-mad_stream[card][stream].next_frame;
memmove(mad_mpeg[card][stream],mad_stream[card][stream].next_frame,
mad_left_over[card][stream]);
}
#endif // HAVE_MAD
break;
}
alsa_play_ring[card][stream]->write((char *)alsa_wave_buffer,n);
}
#endif // ALSA
void MainObject::AlsaClock()
{
#ifdef ALSA
for(int i=0;i<RD_MAX_CARDS;i++) {
if(cae_driver[i]==RDStation::Alsa) {
for(int j=0;j<RD_MAX_STREAMS;j++) {
if(alsa_stopping[i][j]) {
alsa_stopping[i][j]=false;
alsa_eof[i][j]=false;
alsa_playing[i][j]=false;
printf("stop card: %d stream: %d\n",i,j);
statePlayUpdate(i,j,2);
}
if(alsa_playing[i][j]) {
FillAlsaOutputStream(i,j);
}
}
for(int j=0;j<RD_MAX_PORTS;j++) {
if(alsa_recording[i][j]) {
EmptyAlsaInputStream(i,j);
}
}
}
}
#endif // ALSA
}