/* s_mix.c - portable code to mix sounds Copyright (C) 2009 Uncle Mike This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. 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. */ #include "common.h" #include "sound.h" #include "client.h" #define IPAINTBUFFER 0 #define IROOMBUFFER 1 #define ISTREAMBUFFER 2 #define FILTERTYPE_NONE 0 #define FILTERTYPE_LINEAR 1 #define FILTERTYPE_CUBIC 2 #define CCHANVOLUMES 2 #define SND_SCALE_BITS 7 #define SND_SCALE_SHIFT (8 - SND_SCALE_BITS) #define SND_SCALE_LEVELS (1 << SND_SCALE_BITS) portable_samplepair_t *g_curpaintbuffer; portable_samplepair_t streambuffer[(PAINTBUFFER_SIZE+1)]; portable_samplepair_t paintbuffer[(PAINTBUFFER_SIZE+1)]; portable_samplepair_t roombuffer[(PAINTBUFFER_SIZE+1)]; portable_samplepair_t facingbuffer[(PAINTBUFFER_SIZE+1)]; portable_samplepair_t temppaintbuffer[(PAINTBUFFER_SIZE+1)]; paintbuffer_t paintbuffers[CPAINTBUFFERS]; int snd_scaletable[SND_SCALE_LEVELS][256]; void S_InitScaletable( void ) { int i, j; for( i = 0; i < SND_SCALE_LEVELS; i++ ) { for( j = 0; j < 256; j++ ) snd_scaletable[i][j] = ((signed char)j) * i * (1<> 1) - 1); while( lpaintedtime < endtime ) { // handle recirculating buffer issues lpos = lpaintedtime & sampleMask; snd_out = (short *)pbuf + (lpos << 1); snd_linear_count = (dma.samples>>1) - lpos; if( lpaintedtime + snd_linear_count > endtime ) snd_linear_count = endtime - lpaintedtime; snd_linear_count <<= 1; // write a linear blast of samples for( i = 0; i < snd_linear_count; i += 2 ) { val = (snd_p[i+0] * 256) >> 8; if( val > 0x7fff ) snd_out[i+0] = 0x7fff; else if( val < (short)0x8000 ) snd_out[i+0] = (short)0x8000; else snd_out[i+0] = val; val = (snd_p[i+1] * 256) >> 8; if( val > 0x7fff ) snd_out[i+1] = 0x7fff; else if( val < (short)0x8000 ) snd_out[i+1] = (short)0x8000; else snd_out[i+1] = val; } snd_p += snd_linear_count; lpaintedtime += (snd_linear_count >> 1); } } //=============================================================================== // Mix buffer (paintbuffer) management routines //=============================================================================== // Activate a paintbuffer. All active paintbuffers are mixed in parallel within // MIX_MixChannelsToPaintbuffer, according to flags _inline void MIX_ActivatePaintbuffer( int ipaintbuffer ) { Assert( ipaintbuffer < CPAINTBUFFERS ); paintbuffers[ipaintbuffer].factive = true; } // don't mix into this paintbuffer _inline void MIX_DeactivatePaintbuffer( int ipaintbuffer ) { Assert( ipaintbuffer < CPAINTBUFFERS ); paintbuffers[ipaintbuffer].factive = false; } _inline void MIX_SetCurrentPaintbuffer( int ipaintbuffer ) { Assert( ipaintbuffer < CPAINTBUFFERS ); g_curpaintbuffer = paintbuffers[ipaintbuffer].pbuf; Assert( g_curpaintbuffer != NULL ); } _inline int MIX_GetCurrentPaintbufferIndex( void ) { int i; for( i = 0; i < CPAINTBUFFERS; i++ ) { if( g_curpaintbuffer == paintbuffers[i].pbuf ) return i; } return 0; } _inline paintbuffer_t *MIX_GetCurrentPaintbufferPtr( void ) { int ipaint = MIX_GetCurrentPaintbufferIndex(); Assert( ipaint < CPAINTBUFFERS ); return &paintbuffers[ipaint]; } // Don't mix into any paintbuffers _inline void MIX_DeactivateAllPaintbuffers( void ) { int i; for( i = 0; i < CPAINTBUFFERS; i++ ) paintbuffers[i].factive = false; } // set upsampling filter indexes back to 0 _inline void MIX_ResetPaintbufferFilterCounters( void ) { int i; for( i = 0; i < CPAINTBUFFERS; i++ ) paintbuffers[i].ifilter = FILTERTYPE_NONE; } _inline void MIX_ResetPaintbufferFilterCounter( int ipaintbuffer ) { Assert( ipaintbuffer < CPAINTBUFFERS ); paintbuffers[ipaintbuffer].ifilter = 0; } // return pointer to front paintbuffer pbuf, given index _inline portable_samplepair_t *MIX_GetPFrontFromIPaint( int ipaintbuffer ) { Assert( ipaintbuffer < CPAINTBUFFERS ); return paintbuffers[ipaintbuffer].pbuf; } _inline paintbuffer_t *MIX_GetPPaintFromIPaint( int ipaint ) { Assert( ipaint < CPAINTBUFFERS ); return &paintbuffers[ipaint]; } void MIX_FreeAllPaintbuffers( void ) { // clear paintbuffer structs memset( paintbuffers, 0, CPAINTBUFFERS * sizeof( paintbuffer_t )); } // Initialize paintbuffers array, set current paint buffer to main output buffer IPAINTBUFFER void MIX_InitAllPaintbuffers( void ) { // clear paintbuffer structs memset( paintbuffers, 0, CPAINTBUFFERS * sizeof( paintbuffer_t )); paintbuffers[IPAINTBUFFER].pbuf = paintbuffer; paintbuffers[IROOMBUFFER].pbuf = roombuffer; paintbuffers[ISTREAMBUFFER].pbuf = streambuffer; MIX_SetCurrentPaintbuffer( IPAINTBUFFER ); } /* =============================================================================== CHANNEL MIXING =============================================================================== */ void S_PaintMonoFrom8( portable_samplepair_t *pbuf, int *volume, byte *pData, int outCount ) { int *lscale, *rscale; int i, data; lscale = snd_scaletable[volume[0] >> SND_SCALE_SHIFT]; rscale = snd_scaletable[volume[1] >> SND_SCALE_SHIFT]; for( i = 0; i < outCount; i++ ) { data = pData[i]; pbuf[i].left += lscale[data]; pbuf[i].right += rscale[data]; } } void S_PaintStereoFrom8( portable_samplepair_t *pbuf, int *volume, byte *pData, int outCount ) { int *lscale, *rscale; uint left, right; word *data; int i; lscale = snd_scaletable[volume[0] >> SND_SCALE_SHIFT]; rscale = snd_scaletable[volume[1] >> SND_SCALE_SHIFT]; data = (word *)pData; for( i = 0; i < outCount; i++, data++ ) { left = (byte)((*data & 0x00FF)); right = (byte)((*data & 0xFF00) >> 8); pbuf[i].left += lscale[left]; pbuf[i].right += rscale[right]; } } void S_PaintMonoFrom16( portable_samplepair_t *pbuf, int *volume, short *pData, int outCount ) { int left, right; int i, data; for( i = 0; i < outCount; i++ ) { data = pData[i]; left = ( data * volume[0]) >> 8; right = (data * volume[1]) >> 8; pbuf[i].left += left; pbuf[i].right += right; } } void S_PaintStereoFrom16( portable_samplepair_t *pbuf, int *volume, short *pData, int outCount ) { uint *data; int left, right; int i; data = (uint *)pData; for( i = 0; i < outCount; i++, data++ ) { left = (signed short)((*data & 0x0000FFFF)); right = (signed short)((*data & 0xFFFF0000) >> 16); left = (left * volume[0]) >> 8; right = (right * volume[1]) >> 8; pbuf[i].left += left; pbuf[i].right += right; } } void S_Mix8MonoTimeCompress( portable_samplepair_t *pbuf, int *volume, byte *pData, int inputOffset, uint rateScale, int outCount, int timecompress ) { } void S_Mix8Mono( portable_samplepair_t *pbuf, int *volume, byte *pData, int inputOffset, uint rateScale, int outCount, int timecompress ) { int i, sampleIndex = 0; uint sampleFrac = inputOffset; int *lscale, *rscale; if( timecompress != 0 ) { S_Mix8MonoTimeCompress( pbuf, volume, pData, inputOffset, rateScale, outCount, timecompress ); // return; } // Not using pitch shift? if( rateScale == FIX( 1 )) { S_PaintMonoFrom8( pbuf, volume, pData, outCount ); return; } lscale = snd_scaletable[volume[0] >> SND_SCALE_SHIFT]; rscale = snd_scaletable[volume[1] >> SND_SCALE_SHIFT]; for( i = 0; i < outCount; i++ ) { pbuf[i].left += lscale[pData[sampleIndex]]; pbuf[i].right += rscale[pData[sampleIndex]]; sampleFrac += rateScale; sampleIndex += FIX_INTPART( sampleFrac ); sampleFrac = FIX_FRACPART( sampleFrac ); } } void S_Mix8Stereo( portable_samplepair_t *pbuf, int *volume, byte *pData, int inputOffset, uint rateScale, int outCount ) { int i, sampleIndex = 0; uint sampleFrac = inputOffset; int *lscale, *rscale; // Not using pitch shift? if( rateScale == FIX( 1 )) { S_PaintStereoFrom8( pbuf, volume, pData, outCount ); return; } lscale = snd_scaletable[volume[0] >> SND_SCALE_SHIFT]; rscale = snd_scaletable[volume[1] >> SND_SCALE_SHIFT]; for( i = 0; i < outCount; i++ ) { pbuf[i].left += lscale[pData[sampleIndex+0]]; pbuf[i].right += rscale[pData[sampleIndex+1]]; sampleFrac += rateScale; sampleIndex += FIX_INTPART( sampleFrac )<<1; sampleFrac = FIX_FRACPART( sampleFrac ); } } void S_Mix16Mono( portable_samplepair_t *pbuf, int *volume, short *pData, int inputOffset, uint rateScale, int outCount ) { int i, sampleIndex = 0; uint sampleFrac = inputOffset; // Not using pitch shift? if( rateScale == FIX( 1 )) { S_PaintMonoFrom16( pbuf, volume, pData, outCount ); return; } for( i = 0; i < outCount; i++ ) { pbuf[i].left += (volume[0] * (int)( pData[sampleIndex] ))>>8; pbuf[i].right += (volume[1] * (int)( pData[sampleIndex] ))>>8; sampleFrac += rateScale; sampleIndex += FIX_INTPART( sampleFrac ); sampleFrac = FIX_FRACPART( sampleFrac ); } } void S_Mix16Stereo( portable_samplepair_t *pbuf, int *volume, short *pData, int inputOffset, uint rateScale, int outCount ) { int i, sampleIndex = 0; uint sampleFrac = inputOffset; // Not using pitch shift? if( rateScale == FIX( 1 )) { S_PaintStereoFrom16( pbuf, volume, pData, outCount ); return; } for( i = 0; i < outCount; i++ ) { pbuf[i].left += (volume[0] * (int)( pData[sampleIndex+0] ))>>8; pbuf[i].right += (volume[1] * (int)( pData[sampleIndex+1] ))>>8; sampleFrac += rateScale; sampleIndex += FIX_INTPART(sampleFrac)<<1; sampleFrac = FIX_FRACPART(sampleFrac); } } void S_MixChannel( channel_t *pChannel, void *pData, int outputOffset, int inputOffset, uint fracRate, int outCount, int timecompress ) { int pvol[CCHANVOLUMES]; paintbuffer_t *ppaint = MIX_GetCurrentPaintbufferPtr(); wavdata_t *pSource = pChannel->sfx->cache; portable_samplepair_t *pbuf; Assert( pSource != NULL ); pvol[0] = bound( 0, pChannel->leftvol, 255 ); pvol[1] = bound( 0, pChannel->rightvol, 255 ); pbuf = ppaint->pbuf + outputOffset; if( pSource->channels == 1 ) { if( pSource->width == 1 ) S_Mix8Mono( pbuf, pvol, pData, inputOffset, fracRate, outCount, timecompress ); else S_Mix16Mono( pbuf, pvol, (short *)pData, inputOffset, fracRate, outCount ); } else { if( pSource->width == 1 ) S_Mix8Stereo( pbuf, pvol, pData, inputOffset, fracRate, outCount ); else S_Mix16Stereo( pbuf, pvol, (short *)pData, inputOffset, fracRate, outCount ); } } int S_MixDataToDevice( channel_t *pChannel, int sampleCount, int outRate, int outOffset, int timeCompress ) { // save this to compute total output int startingOffset = outOffset; float inputRate = ( pChannel->pitch * pChannel->sfx->cache->rate ); float rate = inputRate / outRate; // shouldn't be playing this if finished, but return if we are if( pChannel->pMixer.finished ) return 0; // If we are terminating this wave prematurely, then make sure we detect the limit if( pChannel->pMixer.forcedEndSample ) { // how many total input samples will we need? int samplesRequired = (int)(sampleCount * rate); // will this hit the end? if( pChannel->pMixer.sample + samplesRequired >= pChannel->pMixer.forcedEndSample ) { // yes, mark finished and truncate the sample request pChannel->pMixer.finished = true; sampleCount = (int)((pChannel->pMixer.forcedEndSample - pChannel->pMixer.sample) / rate ); } } while( sampleCount > 0 ) { int availableSamples, outSampleCount; wavdata_t *pSource = pChannel->sfx->cache; qboolean use_loop = pChannel->use_loop; void *pData = NULL; double sampleFrac; int i, j; // compute number of input samples required double end = pChannel->pMixer.sample + rate * sampleCount; int inputSampleCount = (int)(ceil( end ) - floor( pChannel->pMixer.sample )); availableSamples = S_GetOutputData( pSource, &pData, pChannel->pMixer.sample, inputSampleCount, use_loop ); // none available, bail out if( !availableSamples ) break; sampleFrac = pChannel->pMixer.sample - floor( pChannel->pMixer.sample ); if( availableSamples < inputSampleCount ) { // how many samples are there given the number of input samples and the rate. outSampleCount = (int)ceil(( availableSamples - sampleFrac ) / rate ); } else { outSampleCount = sampleCount; } // Verify that we won't get a buffer overrun. Assert( floor( sampleFrac + rate * ( outSampleCount - 1 )) <= availableSamples ); // save current paintbuffer j = MIX_GetCurrentPaintbufferIndex(); for( i = 0; i < CPAINTBUFFERS; i++ ) { if( !paintbuffers[i].factive ) continue; // mix chan into all active paintbuffers MIX_SetCurrentPaintbuffer( i ); S_MixChannel( pChannel, pData, outOffset, FIX_FLOAT( sampleFrac ), FIX_FLOAT( rate ), outSampleCount, timeCompress ); } MIX_SetCurrentPaintbuffer( j ); pChannel->pMixer.sample += outSampleCount * rate; outOffset += outSampleCount; sampleCount -= outSampleCount; } // Did we run out of samples? if so, mark finished if( sampleCount > 0 ) { pChannel->pMixer.finished = true; } // total number of samples mixed !!! at the output clock rate !!! return outOffset - startingOffset; } qboolean S_ShouldContinueMixing( channel_t *ch ) { if( ch->isSentence ) { if( ch->currentWord ) return true; return false; } return !ch->pMixer.finished; } // Mix all channels into active paintbuffers until paintbuffer is full or 'endtime' is reached. // endtime: time in 44khz samples to mix // rate: ignore samples which are not natively at this rate (for multipass mixing/filtering) // if rate == SOUND_ALL_RATES then mix all samples this pass // flags: if SOUND_MIX_DRY, then mix only samples with channel flagged as 'dry' // outputRate: target mix rate for all samples. Note, if outputRate = SOUND_DMA_SPEED, then // this routine will fill the paintbuffer to endtime. Otherwise, fewer samples are mixed. // if( endtime - paintedtime ) is not aligned on boundaries of 4, // we'll miss data if outputRate < SOUND_DMA_SPEED! void MIX_MixChannelsToPaintbuffer( int endtime, int rate, int outputRate ) { channel_t *ch; wavdata_t *pSource; int i, sampleCount; qboolean bZeroVolume; // mix each channel into paintbuffer ch = channels; // validate parameters Assert( outputRate <= SOUND_DMA_SPEED ); // make sure we're not discarding data Assert( !(( endtime - paintedtime ) & 0x3 ) || ( outputRate == SOUND_DMA_SPEED )); // 44k: try to mix this many samples at outputRate sampleCount = ( endtime - paintedtime ) / ( SOUND_DMA_SPEED / outputRate ); if( sampleCount <= 0 ) return; for( i = 0; i < total_channels; i++, ch++ ) { if( !ch->sfx ) continue; // NOTE: background map is allow both type sounds: menu and game if( !cl.background ) { if( cls.key_dest == key_console && ch->localsound ) { // play, playvol } else if(( s_listener.inmenu || s_listener.paused ) && !ch->localsound ) { // play only local sounds, keep pause for other continue; } else if( !s_listener.inmenu && !s_listener.active && !ch->staticsound ) { // play only ambient sounds, keep pause for other continue; } } else if( cls.key_dest == key_console ) continue; // silent mode in console pSource = S_LoadSound( ch->sfx ); // Don't mix sound data for sounds with zero volume. If it's a non-looping sound, // just remove the sound when its volume goes to zero. bZeroVolume = !ch->leftvol && !ch->rightvol; if( !bZeroVolume ) { // this values matched with GoldSrc if( ch->leftvol < 8 && ch->rightvol < 8 ) bZeroVolume = true; } if( !pSource || ( bZeroVolume && pSource->loopStart == -1 )) { if( !pSource ) { S_FreeChannel( ch ); continue; } } else if( bZeroVolume ) { continue; } // multipass mixing - only mix samples of specified sample rate switch( rate ) { case SOUND_11k: case SOUND_22k: case SOUND_44k: if( rate != pSource->rate ) continue; break; default: break; } // get playback pitch if( ch->isSentence ) ch->pitch = VOX_ModifyPitch( ch, ch->basePitch * 0.01f ); else ch->pitch = ch->basePitch * 0.01f; if( CL_GetEntityByIndex( ch->entnum ) && ( ch->entchannel == CHAN_VOICE )) { if( pSource->width == 1 ) SND_MoveMouth8( ch, pSource, sampleCount ); else SND_MoveMouth16( ch, pSource, sampleCount ); } // mix channel to all active paintbuffers. // NOTE: must be called once per channel only - consecutive calls retrieve additional data. if( ch->isSentence ) VOX_MixDataToDevice( ch, sampleCount, outputRate, 0 ); else S_MixDataToDevice( ch, sampleCount, outputRate, 0, 0 ); if( !S_ShouldContinueMixing( ch )) { S_FreeChannel( ch ); } } } // pass in index -1...count+2, return pointer to source sample in either paintbuffer or delay buffer _inline portable_samplepair_t *S_GetNextpFilter( int i, portable_samplepair_t *pbuffer, portable_samplepair_t *pfiltermem ) { // The delay buffer is assumed to precede the paintbuffer by 6 duplicated samples if( i == -1 ) return (&(pfiltermem[0])); if( i == 0 ) return (&(pfiltermem[1])); if( i == 1 ) return (&(pfiltermem[2])); // return from paintbuffer, where samples are doubled. // even samples are to be replaced with interpolated value. return (&(pbuffer[(i-2) * 2 + 1])); } // pass forward over passed in buffer and cubic interpolate all odd samples // pbuffer: buffer to filter (in place) // prevfilter: filter memory. NOTE: this must match the filtertype ie: filtercubic[] for FILTERTYPE_CUBIC // if NULL then perform no filtering. // count: how many samples to upsample. will become count*2 samples in buffer, in place. void S_Interpolate2xCubic( portable_samplepair_t *pbuffer, portable_samplepair_t *pfiltermem, int cfltmem, int count ) { // implement cubic interpolation on 2x upsampled buffer. Effectively delays buffer contents by 2 samples. // pbuffer: contains samples at 0, 2, 4, 6... // temppaintbuffer is temp buffer, same size as paintbuffer, used to store processed values // count: number of samples to process in buffer ie: how many samples at 0, 2, 4, 6... // finpos is the fractional, inpos the integer part. // finpos = 0.5 for upsampling by 2x // inpos is the position of the sample // xm1 = x [inpos - 1]; // x0 = x [inpos + 0]; // x1 = x [inpos + 1]; // x2 = x [inpos + 2]; // a = (3 * (x0-x1) - xm1 + x2) / 2; // b = 2*x1 + xm1 - (5*x0 + x2) / 2; // c = (x1 - xm1) / 2; // y [outpos] = (((a * finpos) + b) * finpos + c) * finpos + x0; int i, upCount = count << 1; int a, b, c; int xm1, x0, x1, x2; portable_samplepair_t *psamp0; portable_samplepair_t *psamp1; portable_samplepair_t *psamp2; portable_samplepair_t *psamp3; int outpos = 0; Assert( upCount <= PAINTBUFFER_SIZE ); // pfiltermem holds 6 samples from previous buffer pass // process 'count' samples for( i = 0; i < count; i++) { // get source sample pointer psamp0 = S_GetNextpFilter( i-1, pbuffer, pfiltermem ); psamp1 = S_GetNextpFilter( i+0, pbuffer, pfiltermem ); psamp2 = S_GetNextpFilter( i+1, pbuffer, pfiltermem ); psamp3 = S_GetNextpFilter( i+2, pbuffer, pfiltermem ); // write out original sample to interpolation buffer temppaintbuffer[outpos++] = *psamp1; // get all left samples for interpolation window xm1 = psamp0->left; x0 = psamp1->left; x1 = psamp2->left; x2 = psamp3->left; // interpolate a = (3 * (x0-x1) - xm1 + x2) / 2; b = 2*x1 + xm1 - (5*x0 + x2) / 2; c = (x1 - xm1) / 2; // write out interpolated sample temppaintbuffer[outpos].left = a/8 + b/4 + c/2 + x0; // get all right samples for window xm1 = psamp0->right; x0 = psamp1->right; x1 = psamp2->right; x2 = psamp3->right; // interpolate a = (3 * (x0-x1) - xm1 + x2) / 2; b = 2*x1 + xm1 - (5*x0 + x2) / 2; c = (x1 - xm1) / 2; // write out interpolated sample, increment output counter temppaintbuffer[outpos++].right = a/8 + b/4 + c/2 + x0; Assert( outpos <= ( sizeof( temppaintbuffer ) / sizeof( temppaintbuffer[0] ))); } Assert( cfltmem >= 3 ); // save last 3 samples from paintbuffer pfiltermem[0] = pbuffer[upCount - 5]; pfiltermem[1] = pbuffer[upCount - 3]; pfiltermem[2] = pbuffer[upCount - 1]; // copy temppaintbuffer back into paintbuffer for( i = 0; i < upCount; i++ ) pbuffer[i] = temppaintbuffer[i]; } // pass forward over passed in buffer and linearly interpolate all odd samples // pbuffer: buffer to filter (in place) // prevfilter: filter memory. NOTE: this must match the filtertype ie: filterlinear[] for FILTERTYPE_LINEAR // if NULL then perform no filtering. // count: how many samples to upsample. will become count*2 samples in buffer, in place. void S_Interpolate2xLinear( portable_samplepair_t *pbuffer, portable_samplepair_t *pfiltermem, int cfltmem, int count ) { int i, upCount = count<<1; Assert( upCount <= PAINTBUFFER_SIZE ); Assert( cfltmem >= 1 ); // use interpolation value from previous mix pbuffer[0].left = (pfiltermem->left + pbuffer[0].left) >> 1; pbuffer[0].right = (pfiltermem->right + pbuffer[0].right) >> 1; for( i = 2; i < upCount; i += 2 ) { // use linear interpolation for upsampling pbuffer[i].left = (pbuffer[i].left + pbuffer[i-1].left) >> 1; pbuffer[i].right = (pbuffer[i].right + pbuffer[i-1].right) >> 1; } // save last value to be played out in buffer *pfiltermem = pbuffer[upCount - 1]; } // upsample by 2x, optionally using interpolation // count: how many samples to upsample. will become count*2 samples in buffer, in place. // pbuffer: buffer to upsample into (in place) // pfiltermem: filter memory. NOTE: this must match the filtertype ie: filterlinear[] for FILTERTYPE_LINEAR // if NULL then perform no filtering. // cfltmem: max number of sample pairs filter can use // filtertype: FILTERTYPE_NONE, _LINEAR, _CUBIC etc. Must match prevfilter. void S_MixBufferUpsample2x( int count, portable_samplepair_t *pbuffer, portable_samplepair_t *pfiltermem, int cfltmem, int filtertype ) { int upCount = count<<1; int i, j; // reverse through buffer, duplicating contents for 'count' samples for( i = upCount - 1, j = count - 1; j >= 0; i-=2, j-- ) { pbuffer[i] = pbuffer[j]; pbuffer[i-1] = pbuffer[j]; } // pass forward through buffer, interpolate all even slots switch( filtertype ) { case FILTERTYPE_LINEAR: S_Interpolate2xLinear( pbuffer, pfiltermem, cfltmem, count ); break; case FILTERTYPE_CUBIC: S_Interpolate2xCubic( pbuffer, pfiltermem, cfltmem, count ); break; default: // no filter break; } } // zero out all paintbuffers void MIX_ClearAllPaintBuffers( int SampleCount, qboolean clearFilters ) { int count = min( SampleCount, PAINTBUFFER_SIZE ); int i; // zero out all paintbuffer data (ignore sampleCount) for( i = 0; i < CPAINTBUFFERS; i++ ) { if( paintbuffers[i].pbuf != NULL ) memset( paintbuffers[i].pbuf, 0, (count+1) * sizeof( portable_samplepair_t )); if( clearFilters ) { memset( paintbuffers[i].fltmem, 0, sizeof( paintbuffers[i].fltmem )); } } if( clearFilters ) { MIX_ResetPaintbufferFilterCounters(); } } // mixes pbuf1 + pbuf2 into pbuf3, count samples // fgain is output gain 0-1.0 // NOTE: pbuf3 may equal pbuf1 or pbuf2! void MIX_MixPaintbuffers( int ibuf1, int ibuf2, int ibuf3, int count, float fgain ) { portable_samplepair_t *pbuf1, *pbuf2, *pbuf3; int i, gain; gain = 256 * fgain; Assert( count <= PAINTBUFFER_SIZE ); Assert( ibuf1 < CPAINTBUFFERS ); Assert( ibuf2 < CPAINTBUFFERS ); Assert( ibuf3 < CPAINTBUFFERS ); pbuf1 = paintbuffers[ibuf1].pbuf; pbuf2 = paintbuffers[ibuf2].pbuf; pbuf3 = paintbuffers[ibuf3].pbuf; // destination buffer stereo - average n chans down to stereo // destination 2ch: // pb1 2ch + pb2 2ch -> pb3 2ch // pb1 2ch + pb2 (4ch->2ch) -> pb3 2ch // pb1 (4ch->2ch) + pb2 (4ch->2ch) -> pb3 2ch // mix front channels for( i = 0; i < count; i++ ) { pbuf3[i].left = pbuf1[i].left; pbuf3[i].right = pbuf1[i].right; pbuf3[i].left += (pbuf2[i].left * gain) >> 8; pbuf3[i].right += (pbuf2[i].right * gain) >> 8; } } void MIX_CompressPaintbuffer( int ipaint, int count ) { portable_samplepair_t *pbuf; paintbuffer_t *ppaint; int i; ppaint = MIX_GetPPaintFromIPaint( ipaint ); pbuf = ppaint->pbuf; for( i = 0; i < count; i++, pbuf++ ) { pbuf->left = CLIP( pbuf->left ); pbuf->right = CLIP( pbuf->right ); } } void S_MixUpsample( int sampleCount, int filtertype ) { paintbuffer_t *ppaint = MIX_GetCurrentPaintbufferPtr(); int ifilter = ppaint->ifilter; Assert( ifilter < CPAINTFILTERS ); S_MixBufferUpsample2x( sampleCount, ppaint->pbuf, &(ppaint->fltmem[ifilter][0]), CPAINTFILTERMEM, filtertype ); // make sure on next upsample pass for this paintbuffer, new filter memory is used ppaint->ifilter++; } void MIX_MixStreamBuffer( int end ) { portable_samplepair_t *pbuf; rawchan_t *ch; pbuf = MIX_GetPFrontFromIPaint( ISTREAMBUFFER ); ch = S_FindRawChannel( S_RAW_SOUND_BACKGROUNDTRACK, false ); // clear the paint buffer if( s_listener.paused || !ch || ch->s_rawend < paintedtime ) { memset( pbuf, 0, (end - paintedtime) * sizeof( portable_samplepair_t )); } else { int i, stop; // copy from the streaming sound source stop = (end < ch->s_rawend) ? end : ch->s_rawend; for( i = paintedtime; i < stop; i++ ) { pbuf[i-paintedtime].left = ( ch->rawsamples[i & ( ch->max_samples - 1 )].left * ch->leftvol ) >> 8; pbuf[i-paintedtime].right = ( ch->rawsamples[i & ( ch->max_samples - 1 )].right * ch->rightvol ) >> 8; } for( ; i < end; i++ ) pbuf[i-paintedtime].left = pbuf[i-paintedtime].right = 0; } } void MIX_MixRawSamplesBuffer( int end ) { portable_samplepair_t *pbuf; uint i, j, stop; pbuf = MIX_GetCurrentPaintbufferPtr()->pbuf; if( s_listener.paused ) return; // paint in the raw channels for( i = 0; i < MAX_RAW_CHANNELS; i++ ) { // copy from the streaming sound source rawchan_t *ch = raw_channels[i]; // background track should be mixing into another buffer if( !ch || ch->entnum == S_RAW_SOUND_BACKGROUNDTRACK ) continue; // not audible if( !ch->leftvol && !ch->rightvol ) continue; stop = (end < ch->s_rawend) ? end : ch->s_rawend; for( j = paintedtime; j < stop; j++ ) { pbuf[j-paintedtime].left += ( ch->rawsamples[j & ( ch->max_samples - 1 )].left * ch->leftvol ) >> 8; pbuf[j-paintedtime].right += ( ch->rawsamples[j & ( ch->max_samples - 1 )].right * ch->rightvol ) >> 8; } } } // upsample and mix sounds into final 44khz versions of: // IROOMBUFFER, IFACINGBUFFER, IFACINGAWAY // dsp fx are then applied to these buffers by the caller. // caller also remixes all into final IPAINTBUFFER output. void MIX_UpsampleAllPaintbuffers( int end, int count ) { // process stream buffer MIX_MixStreamBuffer( end ); // 11khz sounds are mixed into 3 buffers based on distance from listener, and facing direction // These buffers are facing, facingaway, room // These 3 mixed buffers are then each upsampled to 22khz. // 22khz sounds are mixed into the 3 buffers based on distance from listener, and facing direction // These 3 mixed buffers are then each upsampled to 44khz. // 44khz sounds are mixed into the 3 buffers based on distance from listener, and facing direction MIX_DeactivateAllPaintbuffers(); // set paintbuffer upsample filter indices to 0 MIX_ResetPaintbufferFilterCounters(); // only mix to roombuffer if dsp fx are on KDB: perf MIX_ActivatePaintbuffer( IROOMBUFFER ); // operates on MIX_MixChannelsToPaintbuffer // mix 11khz sounds: MIX_MixChannelsToPaintbuffer( end, SOUND_11k, SOUND_11k ); // upsample all 11khz buffers by 2x // only upsample roombuffer if dsp fx are on KDB: perf MIX_SetCurrentPaintbuffer( IROOMBUFFER ); // operates on MixUpSample S_MixUpsample( count / ( SOUND_DMA_SPEED / SOUND_11k ), s_lerping->value ); // mix 22khz sounds: MIX_MixChannelsToPaintbuffer( end, SOUND_22k, SOUND_22k ); // upsample all 22khz buffers by 2x // only upsample roombuffer if dsp fx are on KDB: perf MIX_SetCurrentPaintbuffer( IROOMBUFFER ); S_MixUpsample( count / ( SOUND_DMA_SPEED / SOUND_22k ), s_lerping->value ); // mix all 44khz sounds to all active paintbuffers MIX_MixChannelsToPaintbuffer( end, SOUND_44k, SOUND_DMA_SPEED ); // mix raw samples from the video streams MIX_SetCurrentPaintbuffer( IROOMBUFFER ); MIX_MixRawSamplesBuffer( end ); MIX_DeactivateAllPaintbuffers(); MIX_SetCurrentPaintbuffer( IPAINTBUFFER ); } void MIX_PaintChannels( int endtime ) { int end, count; CheckNewDspPresets(); while( paintedtime < endtime ) { // if paintbuffer is smaller than DMA buffer end = endtime; if( endtime - paintedtime > PAINTBUFFER_SIZE ) end = paintedtime + PAINTBUFFER_SIZE; // number of 44khz samples to mix into paintbuffer, up to paintbuffer size count = end - paintedtime; // clear the all mix buffers MIX_ClearAllPaintBuffers( count, false ); MIX_UpsampleAllPaintbuffers( end, count ); // process all sounds with DSP DSP_Process( idsp_room, MIX_GetPFrontFromIPaint( IROOMBUFFER ), count ); // add music or soundtrack from movie (no dsp) MIX_MixPaintbuffers( IPAINTBUFFER, IROOMBUFFER, IPAINTBUFFER, count, S_GetMasterVolume() ); // add music or soundtrack from movie (no dsp) MIX_MixPaintbuffers( IPAINTBUFFER, ISTREAMBUFFER, IPAINTBUFFER, count, S_GetMusicVolume() ); // clip all values > 16 bit down to 16 bit MIX_CompressPaintbuffer( IPAINTBUFFER, count ); // transfer IPAINTBUFFER paintbuffer out to DMA buffer MIX_SetCurrentPaintbuffer( IPAINTBUFFER ); // transfer out according to DMA format S_TransferPaintBuffer( end ); paintedtime = end; } }