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winamp/Src/nsv/nsvplay/audiostub.cpp

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2024-09-24 12:54:57 +00:00
#include <windows.h>
#include "audiostub.h"
#define CAPTION "NSV Player Sound Output Error"
#define MAX(x,y) (( y ) < ( x ) ? ( x ) : ( y ))
#define MIN(x,y) (( x ) < ( y ) ? ( x ) : ( y ))
#define S_MINSIZE (1<<28)
#define MAX_NUM_BLOCKS 8
#define NUM_BLOCKS 8
#define BUFSIZE_MS 1500
#define BLOCKSIZE_MAX 32768
#define BLOCKSIZE_MIN 8192
int g_audio_use_mixer=0;
class PCM_AudioOut : public IAudioOutput
{
public:
PCM_AudioOut(int samplerate, int numchannels, int bitspersamp);
~PCM_AudioOut();
int canwrite(); // returns bytes writeable
void write(void *_buf, int len);
unsigned int getpos();
unsigned int getwritepos();
void flush(unsigned int time_ms);
void pause(int pause);
int isplaying(void);
void setvolume(int volume);
void setpan(int pan);
int open_success() { return init; }
void getdescstr(char *buf)
{
*buf=0;
if (g_srate && g_nch) wsprintf(buf,"%dkHz %s",g_srate/1000,g_nch==2?"stereo":"mono");
}
private:
DWORD ThreadP();
void _setvol(void);
static DWORD WINAPI _threadproc(LPVOID p);
static void CALLBACK cbFunc(HWAVEOUT hwo,UINT uMsg,DWORD dwInstance,DWORD dwParam1,DWORD dwParam2)
{
if (uMsg == WOM_DONE) { ReleaseSemaphore((HANDLE)dwInstance,1,NULL);}
}
void do_set_blocksizes(void);
void do_samples_altvol(char *in, int blen);
int init;
int min_blocksize;
int max_blocksize;
int ispcnt;
int num_blocks;
char *g_buffer, *g_buffer_write, *g_buffer_read;
int g_buffer_length, g_buffer_valid,g_buffer_inlength;
HWAVEOUT g_hWaveOut;
WAVEHDR g_wave_headers[MAX_NUM_BLOCKS];
int g_bps,g_nch,g_srate;
volatile int g_pause, g_wavecnt, g_prebuf,g_writeall, g_quit_flag,g_writetime_bytes, g_outtime_bytes, g_outtime_interp;
HANDLE g_hSem,g_hEvent, g_hThread;
CRITICAL_SECTION g_cs;
int g_bytes_per_sec;
int a_v,a_p;
unsigned char *g_vol_table;
};
PCM_AudioOut::PCM_AudioOut(int samplerate, int numchannels, int bitspersamp)
{
init=0;
a_v=255;
a_p=0;
num_blocks=0;
g_buffer_valid=g_buffer_inlength=0;
g_hWaveOut=NULL;
memset(g_wave_headers,0,sizeof(g_wave_headers));
g_hSem=g_hEvent=g_hThread=0;
int x;
DWORD id;
MMRESULT res;
WAVEFORMATEX wfx={WAVE_FORMAT_PCM,numchannels,samplerate,samplerate*numchannels*(bitspersamp/8),
numchannels*(bitspersamp/8),bitspersamp};
g_bps=bitspersamp;
g_nch=numchannels;
g_srate=samplerate;
g_bytes_per_sec=wfx.nAvgBytesPerSec;
{
char *p=(char*)g_wave_headers;
int n=sizeof(g_wave_headers);
while (n--) *p++=0;
}
g_buffer_length = MulDiv(g_bytes_per_sec, BUFSIZE_MS, 1000);
g_buffer_length &= ~1023;
if (g_buffer_length < 4096) g_buffer_length=4096;
g_buffer=(char *)GlobalAlloc(GMEM_FIXED,g_buffer_length+min(65536,g_buffer_length));
if (g_buffer == NULL)
{
MessageBox(NULL,"Error allocating buffer", CAPTION,MB_OK|MB_ICONSTOP);
return;
}
g_prebuf=g_buffer_length/4;
g_buffer_read=g_buffer_write=g_buffer;
g_wavecnt=g_pause=g_writeall=g_buffer_valid=g_writetime_bytes=g_outtime_bytes=g_buffer_inlength=0;
g_quit_flag=0;
g_vol_table=NULL;
do_set_blocksizes();
g_hSem=CreateSemaphore(NULL,0,256,NULL);
for (x = 0; (res=waveOutOpen(&g_hWaveOut,WAVE_MAPPER,&wfx,(DWORD)cbFunc,(DWORD)g_hSem,CALLBACK_FUNCTION))==MMSYSERR_ALLOCATED && x<10; x ++)
Sleep(100);
if (res != MMSYSERR_NOERROR)
{
char t[512];
waveOutGetErrorText(res,t,sizeof(t));
MessageBox(NULL,t, CAPTION,MB_OK|MB_ICONSTOP);
GlobalFree((HGLOBAL) g_buffer);
CloseHandle(g_hSem);
g_buffer = NULL;
return;
}
ispcnt=0;
g_outtime_interp=GetTickCount();
g_hEvent=CreateEvent(NULL,FALSE,FALSE,NULL);
InitializeCriticalSection(&g_cs);
g_hThread=CreateThread(NULL,0,_threadproc,(void*)this,0,&id);
SetThreadPriority(g_hThread,THREAD_PRIORITY_HIGHEST);
init=1;
}
void PCM_AudioOut::do_set_blocksizes(void)
{
int t,t2,t4;
t=(MulDiv(BLOCKSIZE_MIN,g_bytes_per_sec,44100)+1023)&~1023;
if (t<1024) t=1024;
if (t>32768) t=32768;
t2=(MulDiv(BLOCKSIZE_MAX,g_bytes_per_sec,44100*4)+1023)&~1023;
if (t2 < t) t2 = t;
if (t2 > 65536) t2=65536;
t4 = NUM_BLOCKS;
num_blocks=t4;
max_blocksize=t2;
min_blocksize=t;
}
PCM_AudioOut::~PCM_AudioOut(void)
{
if (init)
{
int x;
g_quit_flag=1;
SetEvent(g_hEvent);
while (g_quit_flag == 1) Sleep(70);
waveOutReset(g_hWaveOut);
for (x = 0; x < MAX_NUM_BLOCKS; x++)
if (g_wave_headers[x].dwFlags & WHDR_PREPARED)
waveOutUnprepareHeader(g_hWaveOut,&g_wave_headers[x],sizeof(g_wave_headers[0]));
if (waveOutClose(g_hWaveOut) != MMSYSERR_NOERROR)
{
MessageBox(NULL,"Error closing sound device.",CAPTION,MB_OK);
}
if (g_buffer) GlobalFree((HGLOBAL) g_buffer);
DeleteCriticalSection(&g_cs);
CloseHandle(g_hThread);
CloseHandle(g_hSem);
CloseHandle(g_hEvent);
if(g_vol_table) GlobalFree((HGLOBAL)g_vol_table);
}
}
void PCM_AudioOut::write(void *_buf, int len)
{
char *buf=(char *)_buf;
int l2;
if (len > 8192) len=8192;
l2=(g_buffer_write+len)-(g_buffer+g_buffer_length);
if (len <= 0 || !buf)
{
g_writeall=1;
//g_prebuf=0;
SetEvent(g_hEvent);
return;
}
ispcnt=0;
g_writeall=0;
if (l2 > 0)
{
int l1=len-l2;
memcpy(g_buffer_write,buf,l1);
memcpy(g_buffer,buf+l1,l2);
g_buffer_write=g_buffer+l2;
}
else
{
memcpy(g_buffer_write,buf,len);
g_buffer_write += len;
if (g_buffer_write == g_buffer+g_buffer_length) g_buffer_write=g_buffer;
}
EnterCriticalSection(&g_cs);
g_buffer_valid+=len;
LeaveCriticalSection(&g_cs);
g_writetime_bytes+=len;
if (g_wavecnt < num_blocks)
{
SetEvent(g_hEvent);
}
return;
}
int PCM_AudioOut::canwrite(void)
{
int t=(g_buffer_length-g_buffer_valid);
if (g_wavecnt==0)
{
SetEvent(g_hEvent);
}
if (t>8192) t=8192; // RG: since write() caps the # of bytes at 8192, this should reflect that! otherwise, if we call write() with too many bytes, it throws the extra away and we'll never know it.
return t;
}
int PCM_AudioOut::isplaying(void)
{
if (g_wavecnt==0)
{
SetEvent(g_hEvent);
}
if (ispcnt < 7) ispcnt++;
if (g_buffer_valid < MIN(g_buffer_length/2,min_blocksize) && ispcnt==7)
{
g_writeall=1;
g_prebuf=0;
}
return (g_wavecnt>0) || (g_buffer_valid>0);
}
void PCM_AudioOut::pause(int pause)
{
if (g_hWaveOut)
{
int lastp=g_pause;
g_pause=pause;
if (pause == lastp) return;
if (g_pause)
waveOutPause(g_hWaveOut);
else
{
waveOutRestart(g_hWaveOut);
g_outtime_interp=GetTickCount();
SetEvent(g_hEvent);
}
}
}
void PCM_AudioOut::_setvol(void)
{
DWORD vol, vo2, gv;
if (g_hWaveOut)
{
a_v=MIN(255,MAX(a_v,0));
a_p=MIN(127,MAX(a_p,-127));
vo2 = vol = (a_v*65535) / 255;
if (a_p > 0)
{
vol *= (127-a_p);
vol /= 127;
}
else if (a_p < 0)
{
vo2 *= (127+a_p);
vo2 /= 127;
}
gv=vol|(vo2<<16);
if(g_audio_use_mixer) {
if(g_vol_table) {
EnterCriticalSection(&g_cs);
GlobalFree((HGLOBAL)g_vol_table);
g_vol_table=NULL;
LeaveCriticalSection(&g_cs);
}
waveOutSetVolume(g_hWaveOut,gv);
} else {
EnterCriticalSection(&g_cs);
if(!g_vol_table) {
int l=(g_bps==8)?512:(4*32769);
g_vol_table=(unsigned char *)GlobalAlloc(GPTR,l);
}
//compute volume lookup table
int x;
if (g_bps==8) {
if (g_nch==1) for (x = 0; x < 256; x ++) g_vol_table[x] = (x*a_v)/256;
else for (x = 0; x < 256; x ++)
{
g_vol_table[x] = (x*(int)vol)/65536;
g_vol_table[x+256] = (x*(int)vo2)/65536;
}
} else {
short *vol_tab16 = (short *)g_vol_table;
if (g_nch==1) for (x = 0; x < 32769; x ++) vol_tab16[x] = -(x*a_v)/256;
else for (x = 0; x < 32769; x ++)
{
vol_tab16[x] = -(x*(int)vol)/65536;
vol_tab16[x+32769] = -(x*(int)vo2)/65536;
}
}
LeaveCriticalSection(&g_cs);
}
}
}
void PCM_AudioOut::flush(unsigned int time_ms)
{
int x;
EnterCriticalSection(&g_cs);
g_outtime_bytes=g_writetime_bytes=MulDiv(time_ms,g_bytes_per_sec,1000);
waveOutReset(g_hWaveOut);
for (x = 0; x < MAX_NUM_BLOCKS; x++)
if ((g_wave_headers[x].dwFlags & WHDR_PREPARED))
{
waveOutUnprepareHeader(g_hWaveOut,&g_wave_headers[x],sizeof(g_wave_headers[0]));
g_wave_headers[x].dwFlags =0;
}
while (WaitForSingleObject(g_hSem,0)==WAIT_OBJECT_0);
g_prebuf=g_buffer_length/8;
g_buffer_read=g_buffer_write=g_buffer;
g_writeall=g_wavecnt=g_buffer_valid=g_buffer_inlength=0;
ispcnt=0;
LeaveCriticalSection(&g_cs);
}
unsigned int PCM_AudioOut::getwritepos(void)
{
return MulDiv(g_writetime_bytes,1000,g_bytes_per_sec);
}
unsigned int PCM_AudioOut::getpos(void)
{
unsigned int t;
if (!g_pause)
{
t=GetTickCount()-g_outtime_interp;
if (t > 1000) t=1000;
}
else t=0;
return t+MulDiv(g_outtime_bytes,1000,g_bytes_per_sec);
}
DWORD WINAPI PCM_AudioOut::_threadproc(LPVOID p)
{
return ((PCM_AudioOut *)p)->ThreadP();
}
DWORD PCM_AudioOut::ThreadP()
{
HANDLE hs[2]={g_hSem,g_hEvent};
while (1)
{
int i;
i=WaitForMultipleObjects(2,hs,FALSE,INFINITE);
if (g_quit_flag) break;
if (i == WAIT_OBJECT_0)
{
int x;
for (x = 0; x < MAX_NUM_BLOCKS && !(g_wave_headers[x].dwFlags & WHDR_DONE); x++);
if (x < MAX_NUM_BLOCKS)
{
EnterCriticalSection(&g_cs);
if (g_wave_headers[x].dwFlags & WHDR_DONE)
{
int r=g_wave_headers[x].dwBufferLength;
g_outtime_interp=GetTickCount();
g_buffer_valid -=r;
g_buffer_inlength-=r;
g_outtime_bytes +=r;
waveOutUnprepareHeader(g_hWaveOut,&g_wave_headers[x],sizeof(g_wave_headers[0]));
g_wave_headers[x].dwFlags=0;
g_wavecnt--;
i++;
}
LeaveCriticalSection(&g_cs);
}
}
if (i == WAIT_OBJECT_0+1 && !g_pause)
{
int l;
int m;
int t=num_blocks;
EnterCriticalSection(&g_cs);
l=g_buffer_valid-g_buffer_inlength;
LeaveCriticalSection(&g_cs);
again:
if (g_quit_flag) break;
if (g_writeall && l<max_blocksize)
{
ispcnt=0;
g_writeall=0;
m=1;
}
else
{
m=MAX(MIN(g_buffer_length/2,min_blocksize),g_prebuf);
l&=~1023;
}
if (l >= m && g_wavecnt < t)
{
int x;
if (l > max_blocksize) l=max_blocksize;
for (x = 0; x < t && (g_wave_headers[x].dwFlags & WHDR_PREPARED); x++);
if (x < t)
{
int ml=(g_buffer+g_buffer_length)-g_buffer_read;
if (l > g_buffer_length) l=g_buffer_length;
if (l>ml)
{
int addlen=l-ml;
if (addlen > 65536) addlen=65536;
if (addlen > g_buffer_length) addlen=g_buffer_length;
memcpy(g_buffer+g_buffer_length,g_buffer,addlen);
}
g_wave_headers[x].dwBufferLength=l;
g_wave_headers[x].lpData=g_buffer_read;
if (waveOutPrepareHeader(g_hWaveOut,&g_wave_headers[x],sizeof(g_wave_headers[0])) == MMSYSERR_NOERROR)
{
do_samples_altvol(g_wave_headers[x].lpData,g_wave_headers[x].dwBufferLength);
if (waveOutWrite(g_hWaveOut,&g_wave_headers[x],sizeof(g_wave_headers[0])) == MMSYSERR_NOERROR)
{
g_prebuf=0;
g_wavecnt++;
g_buffer_inlength += l;
g_buffer_read += l;
if (g_buffer_read >= g_buffer+g_buffer_length) g_buffer_read-=g_buffer_length;
if (g_wavecnt < t)
{
EnterCriticalSection(&g_cs);
l=g_buffer_valid-g_buffer_inlength;
LeaveCriticalSection(&g_cs);
if (l >= m) goto again;
}
}
else
{
waveOutUnprepareHeader(g_hWaveOut,&g_wave_headers[x],sizeof(g_wave_headers[0]));
g_wave_headers[x].dwFlags=0;
}
}
else g_wave_headers[x].dwFlags=0;
}
}
}
}
g_quit_flag=2;
return 0;
}
void PCM_AudioOut::do_samples_altvol(char *in, int blen)
{
if ((a_v != 255 || a_p) && g_vol_table)
{
EnterCriticalSection(&g_cs);
if (g_bps == 8)
{
unsigned char *i=(unsigned char *)in;
int x = blen;
if (g_nch==1)
{
while (x--) { *i = g_vol_table[*i]; i ++; }
}
else
{
x>>=1;
while (x--)
{
i[0] = g_vol_table[i[0]];
i[1] = g_vol_table[i[1] + 256];
i+=2;
}
}
}
else if (g_bps == 16)
{
short *i = (short *) in;
short *tab= (short *)g_vol_table;
int x = blen>>1;
if (g_nch==1)
{
while (x--)
{
int a = i[0];
if (a <= 0) i[0] = tab[-a];
else i[0] = -tab[a];
i++;
}
}
else
{
x>>=1;
while (x--)
{
int a = i[0];
if (a <= 0) i[0] = tab[-a];
else i[0] = -tab[a];
a=i[1];
if (a <= 0) i[1] = tab[32769-a];
else i[1] = -tab[32769+a];
i+=2;
}
}
}
LeaveCriticalSection(&g_cs);
}
}
void PCM_AudioOut::setvolume(int volume)
{
if (volume >= 0 && volume <= 255) a_v=volume;
_setvol();
}
void PCM_AudioOut::setpan(int pan)
{
if (pan >= -255 && pan <= 255) a_p=pan;
_setvol();
}
IAudioOutput *PCMOUT_CREATE(unsigned int outfmt[8])
{
if (outfmt[0] != NSV_MAKETYPE('P','C','M',' ') ||
!outfmt[1] || !outfmt[2] || !outfmt[3]) return NULL;
PCM_AudioOut *p=new PCM_AudioOut(outfmt[1],outfmt[2],outfmt[3]);
if (p->open_success()) return p;
delete p;
return NULL;
}