ref: 4c269a5cf3dabe54417e90a00f6bffce1fef52b0
dir: /src/ft2_mix.c/
#include <stdint.h> #include <stdbool.h> #include "ft2_header.h" #include "ft2_mix.h" #include "ft2_mix_macros.h" /* --------------------- fixed-point audio channel mixer --------------------- This file has separate routines for EVERY possible sampling variation: Interpolation, volume ramping, 8-bit, 16-bit, no loop, loop, bidi loop. 24 mixing routines in total. Every voice has a function pointer set to the according mixing routine on sample trigger (from replayer, but set in audio thread), using a function pointer look-up table. All voices are always cleared (thread safe) when changing any of the above states from the GUI, so no problem there with deprecated cached function pointers. Mixing macros can be found in ft2_mix_macros.h. Yes, this is a HUGE mess, and I hope you don't need to modify it. If it's not broken, don't try to fix it! */ /* ----------------------------------------------------------------------- */ /* 8-BIT MIXING ROUTINES */ /* ----------------------------------------------------------------------- */ static void mix8bNoLoop(voice_t *v, uint32_t numSamples) { const int8_t *CDA_LinearAdr; bool mixInMono; int32_t realPos, sample, *audioMixL, *audioMixR, CDA_BytesLeft; register const int8_t *smpPtr; register int32_t CDA_LVol, CDA_RVol; register uint32_t pos, delta; uint32_t i, samplesToMix; GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_OPTIMIZATION_NO_LOOP return; } GET_MIXER_VARS GET_DELTA SET_BASE8 CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM CDA_BytesLeft -= samplesToMix; if (mixInMono) { if (samplesToMix & 1) { RENDER_8BIT_SMP_MONO INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_MONO INC_POS RENDER_8BIT_SMP_MONO INC_POS } } else { if (samplesToMix & 1) { RENDER_8BIT_SMP INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP INC_POS RENDER_8BIT_SMP INC_POS } } HANDLE_SAMPLE_END } SET_BACK_MIXER_POS } static void mix8bLoop(voice_t *v, uint32_t numSamples) { const int8_t *CDA_LinearAdr; bool mixInMono; int32_t realPos, sample, *audioMixL, *audioMixR, CDA_BytesLeft; register const int8_t *smpPtr; register int32_t CDA_LVol, CDA_RVol; register uint32_t pos, delta; uint32_t i, samplesToMix; GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_OPTIMIZATION_LOOP return; } GET_MIXER_VARS GET_DELTA SET_BASE8 CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM CDA_BytesLeft -= samplesToMix; if (mixInMono) { if (samplesToMix & 1) { RENDER_8BIT_SMP_MONO INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_MONO INC_POS RENDER_8BIT_SMP_MONO INC_POS } } else { if (samplesToMix & 1) { RENDER_8BIT_SMP INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP INC_POS RENDER_8BIT_SMP INC_POS } } WRAP_LOOP } SET_BACK_MIXER_POS } static void mix8bBidiLoop(voice_t *v, uint32_t numSamples) { bool mixInMono; const int8_t *CDA_LinearAdr, *CDA_LinAdrRev; int32_t realPos, sample, *audioMixL, *audioMixR, CDA_BytesLeft; register const int8_t *smpPtr; register int32_t CDA_LVol, CDA_RVol, CDA_IPValL, CDA_IPValH; register uint32_t pos; uint32_t delta, i, samplesToMix; GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_OPTIMIZATION_BIDI_LOOP return; } GET_MIXER_VARS SET_BASE8_BIDI CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM CDA_BytesLeft -= samplesToMix; START_BIDI if (mixInMono) { if (samplesToMix & 1) { RENDER_8BIT_SMP_MONO INC_POS_BIDI } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_MONO INC_POS_BIDI RENDER_8BIT_SMP_MONO INC_POS_BIDI } } else { if (samplesToMix & 1) { RENDER_8BIT_SMP INC_POS_BIDI } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP INC_POS_BIDI RENDER_8BIT_SMP INC_POS_BIDI } } END_BIDI WRAP_BIDI_LOOP } SET_BACK_MIXER_POS } static void mix8bNoLoopIntrp(voice_t *v, uint32_t numSamples) { const int8_t *CDA_LinearAdr; bool mixInMono; int32_t realPos, sample, sample2, *audioMixL, *audioMixR, CDA_BytesLeft; register const int8_t *smpPtr; register int32_t CDA_LVol, CDA_RVol; register uint32_t pos, delta; uint32_t i, samplesToMix; #ifndef LERPMIX int32_t sample3; #endif GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_OPTIMIZATION_NO_LOOP return; } GET_MIXER_VARS GET_DELTA SET_BASE8 CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM CDA_BytesLeft -= samplesToMix; if (mixInMono) { if (samplesToMix & 1) { RENDER_8BIT_SMP_MONO_INTRP INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_MONO_INTRP INC_POS RENDER_8BIT_SMP_MONO_INTRP INC_POS } } else { if (samplesToMix & 1) { RENDER_8BIT_SMP_INTRP INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_INTRP INC_POS RENDER_8BIT_SMP_INTRP INC_POS } } HANDLE_SAMPLE_END } SET_BACK_MIXER_POS } static void mix8bLoopIntrp(voice_t *v, uint32_t numSamples) { const int8_t *CDA_LinearAdr; bool mixInMono; int32_t realPos, sample, sample2, *audioMixL, *audioMixR, CDA_BytesLeft; register const int8_t *smpPtr; register int32_t CDA_LVol, CDA_RVol; register uint32_t pos, delta; uint32_t i, samplesToMix; #ifndef LERPMIX int32_t sample3; #endif GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_OPTIMIZATION_LOOP return; } GET_MIXER_VARS GET_DELTA SET_BASE8 CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM CDA_BytesLeft -= samplesToMix; if (mixInMono) { if (samplesToMix & 1) { RENDER_8BIT_SMP_MONO_INTRP INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_MONO_INTRP INC_POS RENDER_8BIT_SMP_MONO_INTRP INC_POS } } else { if (samplesToMix & 1) { RENDER_8BIT_SMP_INTRP INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_INTRP INC_POS RENDER_8BIT_SMP_INTRP INC_POS } } WRAP_LOOP } SET_BACK_MIXER_POS } static void mix8bBidiLoopIntrp(voice_t *v, uint32_t numSamples) { bool mixInMono; const int8_t *CDA_LinearAdr, *CDA_LinAdrRev; int32_t realPos, sample, sample2, *audioMixL, *audioMixR, CDA_BytesLeft; register const int8_t *smpPtr; register int32_t CDA_LVol, CDA_RVol, CDA_IPValL, CDA_IPValH; register uint32_t pos; uint32_t delta, i, samplesToMix; #ifndef LERPMIX int32_t sample3; #endif GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_OPTIMIZATION_BIDI_LOOP return; } GET_MIXER_VARS SET_BASE8_BIDI CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM CDA_BytesLeft -= samplesToMix; START_BIDI if (mixInMono) { if (samplesToMix & 1) { RENDER_8BIT_SMP_MONO_INTRP INC_POS_BIDI } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_MONO_INTRP INC_POS_BIDI RENDER_8BIT_SMP_MONO_INTRP INC_POS_BIDI } } else { if (samplesToMix & 1) { RENDER_8BIT_SMP_INTRP INC_POS_BIDI } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_INTRP INC_POS_BIDI RENDER_8BIT_SMP_INTRP INC_POS_BIDI } } END_BIDI WRAP_BIDI_LOOP } SET_BACK_MIXER_POS } static void mix8bRampNoLoop(voice_t *v, uint32_t numSamples) { const int8_t *CDA_LinearAdr; bool mixInMono; int32_t realPos, sample, *audioMixL, *audioMixR, CDA_BytesLeft, CDA_LVolIP, CDA_RVolIP; register const int8_t *smpPtr; register int32_t CDA_LVol, CDA_RVol; register uint32_t pos, delta; uint32_t i, samplesToMix; if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_OPTIMIZATION_NO_LOOP return; } GET_MIXER_VARS_RAMP GET_DELTA SET_BASE8 CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM LIMIT_MIX_NUM_RAMP CDA_BytesLeft -= samplesToMix; GET_VOL if (mixInMono) { if (samplesToMix & 1) { RENDER_8BIT_SMP_MONO VOLUME_RAMPING INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_MONO VOLUME_RAMPING INC_POS RENDER_8BIT_SMP_MONO VOLUME_RAMPING INC_POS } } else { if (samplesToMix & 1) { RENDER_8BIT_SMP VOLUME_RAMPING INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP VOLUME_RAMPING INC_POS RENDER_8BIT_SMP VOLUME_RAMPING INC_POS } } SET_VOL_BACK HANDLE_SAMPLE_END } SET_BACK_MIXER_POS } static void mix8bRampLoop(voice_t *v, uint32_t numSamples) { const int8_t *CDA_LinearAdr; bool mixInMono; int32_t realPos, sample, *audioMixL, *audioMixR, CDA_BytesLeft, CDA_LVolIP, CDA_RVolIP; register const int8_t *smpPtr; register int32_t CDA_LVol, CDA_RVol; register uint32_t pos, delta; uint32_t i, samplesToMix; if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_OPTIMIZATION_LOOP return; } GET_MIXER_VARS_RAMP GET_DELTA SET_BASE8 CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM LIMIT_MIX_NUM_RAMP CDA_BytesLeft -= samplesToMix; GET_VOL if (mixInMono) { if (samplesToMix & 1) { RENDER_8BIT_SMP VOLUME_RAMPING INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_MONO VOLUME_RAMPING INC_POS RENDER_8BIT_SMP_MONO VOLUME_RAMPING INC_POS } } else { if (samplesToMix & 1) { RENDER_8BIT_SMP VOLUME_RAMPING INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP VOLUME_RAMPING INC_POS RENDER_8BIT_SMP VOLUME_RAMPING INC_POS } } SET_VOL_BACK WRAP_LOOP } SET_BACK_MIXER_POS } static void mix8bRampBidiLoop(voice_t *v, uint32_t numSamples) { bool mixInMono; const int8_t *CDA_LinearAdr, *CDA_LinAdrRev; int32_t realPos, sample, *audioMixL, *audioMixR, CDA_BytesLeft, CDA_LVolIP, CDA_RVolIP; register const int8_t *smpPtr; register int32_t CDA_LVol, CDA_RVol, CDA_IPValL, CDA_IPValH; register uint32_t pos; uint32_t delta, i, samplesToMix; if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_OPTIMIZATION_BIDI_LOOP return; } GET_MIXER_VARS_RAMP SET_BASE8_BIDI CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM LIMIT_MIX_NUM_RAMP CDA_BytesLeft -= samplesToMix; GET_VOL START_BIDI if (mixInMono) { if (samplesToMix & 1) { RENDER_8BIT_SMP_MONO VOLUME_RAMPING INC_POS_BIDI } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_MONO VOLUME_RAMPING INC_POS_BIDI RENDER_8BIT_SMP_MONO VOLUME_RAMPING INC_POS_BIDI } } else { if (samplesToMix & 1) { RENDER_8BIT_SMP VOLUME_RAMPING INC_POS_BIDI } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP VOLUME_RAMPING INC_POS_BIDI RENDER_8BIT_SMP VOLUME_RAMPING INC_POS_BIDI } } END_BIDI SET_VOL_BACK WRAP_BIDI_LOOP } SET_BACK_MIXER_POS } static void mix8bRampNoLoopIntrp(voice_t *v, uint32_t numSamples) { const int8_t *CDA_LinearAdr; bool mixInMono; int32_t realPos, sample, sample2, *audioMixL, *audioMixR, CDA_BytesLeft, CDA_LVolIP, CDA_RVolIP; register const int8_t *smpPtr; register int32_t CDA_LVol, CDA_RVol; register uint32_t pos, delta; uint32_t i, samplesToMix; #ifndef LERPMIX int32_t sample3; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_OPTIMIZATION_NO_LOOP return; } GET_MIXER_VARS_RAMP GET_DELTA SET_BASE8 CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM LIMIT_MIX_NUM_RAMP CDA_BytesLeft -= samplesToMix; GET_VOL if (mixInMono) { if (samplesToMix & 1) { RENDER_8BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS RENDER_8BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS } } else { if (samplesToMix & 1) { RENDER_8BIT_SMP_INTRP VOLUME_RAMPING INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_INTRP VOLUME_RAMPING INC_POS RENDER_8BIT_SMP_INTRP VOLUME_RAMPING INC_POS } } SET_VOL_BACK HANDLE_SAMPLE_END } SET_BACK_MIXER_POS } static void mix8bRampLoopIntrp(voice_t *v, uint32_t numSamples) { const int8_t *CDA_LinearAdr; bool mixInMono; int32_t realPos, sample, sample2, *audioMixL, *audioMixR, CDA_BytesLeft, CDA_LVolIP, CDA_RVolIP; register const int8_t *smpPtr; register int32_t CDA_LVol, CDA_RVol; register uint32_t pos, delta; uint32_t i, samplesToMix; #ifndef LERPMIX int32_t sample3; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_OPTIMIZATION_LOOP return; } GET_MIXER_VARS_RAMP GET_DELTA SET_BASE8 CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM LIMIT_MIX_NUM_RAMP CDA_BytesLeft -= samplesToMix; GET_VOL if (mixInMono) { if (samplesToMix & 1) { RENDER_8BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS RENDER_8BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS } } else { if (samplesToMix & 1) { RENDER_8BIT_SMP_INTRP VOLUME_RAMPING INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_INTRP VOLUME_RAMPING INC_POS RENDER_8BIT_SMP_INTRP VOLUME_RAMPING INC_POS } } SET_VOL_BACK WRAP_LOOP } SET_BACK_MIXER_POS } static void mix8bRampBidiLoopIntrp(voice_t *v, uint32_t numSamples) { bool mixInMono; const int8_t *CDA_LinearAdr, *CDA_LinAdrRev; int32_t realPos, sample, sample2, *audioMixL, *audioMixR, CDA_BytesLeft, CDA_LVolIP, CDA_RVolIP; register const int8_t *smpPtr; register int32_t CDA_LVol, CDA_RVol, CDA_IPValL, CDA_IPValH; register uint32_t pos; uint32_t delta, i, samplesToMix; #ifndef LERPMIX int32_t sample3; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_OPTIMIZATION_BIDI_LOOP return; } GET_MIXER_VARS_RAMP SET_BASE8_BIDI CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM LIMIT_MIX_NUM_RAMP CDA_BytesLeft -= samplesToMix; GET_VOL START_BIDI if (mixInMono) { if (samplesToMix & 1) { RENDER_8BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS_BIDI } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS_BIDI RENDER_8BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS_BIDI } } else { if (samplesToMix & 1) { RENDER_8BIT_SMP_INTRP VOLUME_RAMPING INC_POS_BIDI } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_8BIT_SMP_INTRP VOLUME_RAMPING INC_POS_BIDI RENDER_8BIT_SMP_INTRP VOLUME_RAMPING INC_POS_BIDI } } END_BIDI SET_VOL_BACK WRAP_BIDI_LOOP } SET_BACK_MIXER_POS } /* ----------------------------------------------------------------------- */ /* 16-BIT MIXING ROUTINES */ /* ----------------------------------------------------------------------- */ static void mix16bNoLoop(voice_t *v, uint32_t numSamples) { bool mixInMono; const int16_t *CDA_LinearAdr; int32_t realPos, sample, *audioMixL, *audioMixR, CDA_BytesLeft; register const int16_t *smpPtr; register int32_t CDA_LVol, CDA_RVol; register uint32_t pos, delta; uint32_t i, samplesToMix; GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_OPTIMIZATION_NO_LOOP return; } GET_MIXER_VARS GET_DELTA SET_BASE16 CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM CDA_BytesLeft -= samplesToMix; if (mixInMono) { if (samplesToMix & 1) { RENDER_16BIT_SMP_MONO INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_MONO INC_POS RENDER_16BIT_SMP_MONO INC_POS } } else { if (samplesToMix & 1) { RENDER_16BIT_SMP INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP INC_POS RENDER_16BIT_SMP INC_POS } } HANDLE_SAMPLE_END } SET_BACK_MIXER_POS } static void mix16bLoop(voice_t *v, uint32_t numSamples) { bool mixInMono; const int16_t *CDA_LinearAdr; int32_t realPos, sample, *audioMixL, *audioMixR, CDA_BytesLeft; register const int16_t *smpPtr; register int32_t CDA_LVol, CDA_RVol; register uint32_t pos, delta; uint32_t i, samplesToMix; GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_OPTIMIZATION_LOOP return; } GET_MIXER_VARS GET_DELTA SET_BASE16 CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM CDA_BytesLeft -= samplesToMix; if (mixInMono) { if (samplesToMix & 1) { RENDER_16BIT_SMP_MONO INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_MONO INC_POS RENDER_16BIT_SMP_MONO INC_POS } } else { if (samplesToMix & 1) { RENDER_16BIT_SMP INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP INC_POS RENDER_16BIT_SMP INC_POS } } WRAP_LOOP } SET_BACK_MIXER_POS } static void mix16bBidiLoop(voice_t *v, uint32_t numSamples) { bool mixInMono; const int16_t *CDA_LinearAdr, *CDA_LinAdrRev; int32_t realPos, sample, *audioMixL, *audioMixR, CDA_BytesLeft; register const int16_t *smpPtr; register int32_t CDA_LVol, CDA_RVol, CDA_IPValL, CDA_IPValH; register uint32_t pos; uint32_t delta, i, samplesToMix; GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_OPTIMIZATION_BIDI_LOOP return; } GET_MIXER_VARS SET_BASE16_BIDI CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM CDA_BytesLeft -= samplesToMix; START_BIDI if (mixInMono) { if (samplesToMix & 1) { RENDER_16BIT_SMP_MONO INC_POS_BIDI } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_MONO INC_POS_BIDI RENDER_16BIT_SMP_MONO INC_POS_BIDI } } else { if (samplesToMix & 1) { RENDER_16BIT_SMP INC_POS_BIDI } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP INC_POS_BIDI RENDER_16BIT_SMP INC_POS_BIDI } } END_BIDI WRAP_BIDI_LOOP } SET_BACK_MIXER_POS } static void mix16bNoLoopIntrp(voice_t *v, uint32_t numSamples) { bool mixInMono; const int16_t *CDA_LinearAdr; int32_t realPos, sample, sample2, *audioMixL, *audioMixR, CDA_BytesLeft; register const int16_t *smpPtr; register int32_t CDA_LVol, CDA_RVol; register uint32_t pos, delta; uint32_t i, samplesToMix; #ifndef LERPMIX int32_t sample3; #endif GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_OPTIMIZATION_NO_LOOP return; } GET_MIXER_VARS GET_DELTA SET_BASE16 CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM CDA_BytesLeft -= samplesToMix; if (mixInMono) { if (samplesToMix & 1) { RENDER_16BIT_SMP_MONO_INTRP INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_MONO_INTRP INC_POS RENDER_16BIT_SMP_MONO_INTRP INC_POS } } else { if (samplesToMix & 1) { RENDER_16BIT_SMP_INTRP INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_INTRP INC_POS RENDER_16BIT_SMP_INTRP INC_POS } } HANDLE_SAMPLE_END } SET_BACK_MIXER_POS } static void mix16bLoopIntrp(voice_t *v, uint32_t numSamples) { bool mixInMono; const int16_t *CDA_LinearAdr; int32_t realPos, sample, sample2, *audioMixL, *audioMixR, CDA_BytesLeft; register const int16_t *smpPtr; register int32_t CDA_LVol, CDA_RVol; register uint32_t pos, delta; uint32_t i, samplesToMix; #ifndef LERPMIX int32_t sample3; #endif GET_VOL if ((CDA_LVol| CDA_RVol) == 0) { VOL0_OPTIMIZATION_LOOP return; } GET_MIXER_VARS GET_DELTA SET_BASE16 CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM CDA_BytesLeft -= samplesToMix; if (mixInMono) { if (samplesToMix & 1) { RENDER_16BIT_SMP_MONO_INTRP INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_MONO_INTRP INC_POS RENDER_16BIT_SMP_MONO_INTRP INC_POS } } else { if (samplesToMix & 1) { RENDER_16BIT_SMP_INTRP INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_INTRP INC_POS RENDER_16BIT_SMP_INTRP INC_POS } } WRAP_LOOP } SET_BACK_MIXER_POS } static void mix16bBidiLoopIntrp(voice_t *v, uint32_t numSamples) { bool mixInMono; const int16_t *CDA_LinearAdr, *CDA_LinAdrRev; int32_t realPos, sample, sample2, *audioMixL, *audioMixR, CDA_BytesLeft; register const int16_t *smpPtr; register int32_t CDA_LVol, CDA_RVol, CDA_IPValL, CDA_IPValH; register uint32_t pos; uint32_t delta, i, samplesToMix; #ifndef LERPMIX int32_t sample3; #endif GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_OPTIMIZATION_BIDI_LOOP return; } GET_MIXER_VARS SET_BASE16_BIDI CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM CDA_BytesLeft -= samplesToMix; START_BIDI if (mixInMono) { if (samplesToMix & 1) { RENDER_16BIT_SMP_MONO_INTRP INC_POS_BIDI } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_MONO_INTRP INC_POS_BIDI RENDER_16BIT_SMP_MONO_INTRP INC_POS_BIDI } } else { if (samplesToMix & 1) { RENDER_16BIT_SMP_INTRP INC_POS_BIDI } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_INTRP INC_POS_BIDI RENDER_16BIT_SMP_INTRP INC_POS_BIDI } } END_BIDI WRAP_BIDI_LOOP } SET_BACK_MIXER_POS } static void mix16bRampNoLoop(voice_t *v, uint32_t numSamples) { bool mixInMono; const int16_t *CDA_LinearAdr; int32_t realPos, sample, *audioMixL, *audioMixR, CDA_BytesLeft, CDA_LVolIP, CDA_RVolIP; register const int16_t *smpPtr; register int32_t CDA_LVol, CDA_RVol; register uint32_t pos, delta; uint32_t i, samplesToMix; if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_OPTIMIZATION_NO_LOOP return; } GET_MIXER_VARS_RAMP GET_DELTA SET_BASE16 CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM LIMIT_MIX_NUM_RAMP CDA_BytesLeft -= samplesToMix; GET_VOL if (mixInMono) { if (samplesToMix & 1) { RENDER_16BIT_SMP_MONO VOLUME_RAMPING INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_MONO VOLUME_RAMPING INC_POS RENDER_16BIT_SMP_MONO VOLUME_RAMPING INC_POS } } else { if (samplesToMix & 1) { RENDER_16BIT_SMP VOLUME_RAMPING INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP VOLUME_RAMPING INC_POS RENDER_16BIT_SMP VOLUME_RAMPING INC_POS } } SET_VOL_BACK HANDLE_SAMPLE_END } SET_BACK_MIXER_POS } static void mix16bRampLoop(voice_t *v, uint32_t numSamples) { bool mixInMono; const int16_t *CDA_LinearAdr; int32_t realPos, sample, *audioMixL, *audioMixR, CDA_BytesLeft, CDA_LVolIP, CDA_RVolIP; register const int16_t *smpPtr; register int32_t CDA_LVol, CDA_RVol; register uint32_t pos, delta; uint32_t i, samplesToMix; if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_OPTIMIZATION_LOOP return; } GET_MIXER_VARS_RAMP GET_DELTA SET_BASE16 CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM LIMIT_MIX_NUM_RAMP CDA_BytesLeft -= samplesToMix; GET_VOL if (mixInMono) { if (samplesToMix & 1) { RENDER_16BIT_SMP_MONO VOLUME_RAMPING INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_MONO VOLUME_RAMPING INC_POS RENDER_16BIT_SMP_MONO VOLUME_RAMPING INC_POS } } else { if (samplesToMix & 1) { RENDER_16BIT_SMP VOLUME_RAMPING INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP VOLUME_RAMPING INC_POS RENDER_16BIT_SMP VOLUME_RAMPING INC_POS } } SET_VOL_BACK WRAP_LOOP } SET_BACK_MIXER_POS } static void mix16bRampBidiLoop(voice_t *v, uint32_t numSamples) { bool mixInMono; const int16_t *CDA_LinearAdr, *CDA_LinAdrRev; int32_t realPos, sample, *audioMixL, *audioMixR, CDA_BytesLeft, CDA_LVolIP, CDA_RVolIP; register const int16_t *smpPtr; register int32_t CDA_LVol, CDA_RVol, CDA_IPValL, CDA_IPValH; register uint32_t pos; uint32_t delta, i, samplesToMix; if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_OPTIMIZATION_BIDI_LOOP return; } GET_MIXER_VARS_RAMP SET_BASE16_BIDI CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM LIMIT_MIX_NUM_RAMP CDA_BytesLeft -= samplesToMix; GET_VOL START_BIDI if (mixInMono) { if (samplesToMix & 1) { RENDER_16BIT_SMP_MONO VOLUME_RAMPING INC_POS_BIDI } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_MONO VOLUME_RAMPING INC_POS_BIDI RENDER_16BIT_SMP_MONO VOLUME_RAMPING INC_POS_BIDI } } else { if (samplesToMix & 1) { RENDER_16BIT_SMP VOLUME_RAMPING INC_POS_BIDI } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP VOLUME_RAMPING INC_POS_BIDI RENDER_16BIT_SMP VOLUME_RAMPING INC_POS_BIDI } } END_BIDI SET_VOL_BACK WRAP_BIDI_LOOP } SET_BACK_MIXER_POS } static void mix16bRampNoLoopIntrp(voice_t *v, uint32_t numSamples) { bool mixInMono; const int16_t *CDA_LinearAdr; int32_t realPos, sample, sample2, *audioMixL, *audioMixR, CDA_BytesLeft, CDA_LVolIP, CDA_RVolIP; register const int16_t *smpPtr; register int32_t CDA_LVol, CDA_RVol; register uint32_t pos, delta; uint32_t i, samplesToMix; #ifndef LERPMIX int32_t sample3; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_OPTIMIZATION_NO_LOOP return; } GET_MIXER_VARS_RAMP GET_DELTA SET_BASE16 CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM LIMIT_MIX_NUM_RAMP CDA_BytesLeft -= samplesToMix; GET_VOL if (mixInMono) { if (samplesToMix & 1) { RENDER_16BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS RENDER_16BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS } } else { if (samplesToMix & 1) { RENDER_16BIT_SMP_INTRP VOLUME_RAMPING INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_INTRP VOLUME_RAMPING INC_POS RENDER_16BIT_SMP_INTRP VOLUME_RAMPING INC_POS } } SET_VOL_BACK HANDLE_SAMPLE_END } SET_BACK_MIXER_POS } static void mix16bRampLoopIntrp(voice_t *v, uint32_t numSamples) { bool mixInMono; const int16_t *CDA_LinearAdr; int32_t realPos, sample, sample2, *audioMixL, *audioMixR, CDA_BytesLeft, CDA_LVolIP, CDA_RVolIP; register const int16_t *smpPtr; register int32_t CDA_LVol, CDA_RVol; register uint32_t pos, delta; uint32_t i, samplesToMix; #ifndef LERPMIX int32_t sample3; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_OPTIMIZATION_LOOP return; } GET_MIXER_VARS_RAMP GET_DELTA SET_BASE16 CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM LIMIT_MIX_NUM_RAMP CDA_BytesLeft -= samplesToMix; GET_VOL if (mixInMono) { if (samplesToMix & 1) { RENDER_16BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS RENDER_16BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS } } else { if (samplesToMix & 1) { RENDER_16BIT_SMP_INTRP VOLUME_RAMPING INC_POS } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_INTRP VOLUME_RAMPING INC_POS RENDER_16BIT_SMP_INTRP VOLUME_RAMPING INC_POS } } SET_VOL_BACK WRAP_LOOP } SET_BACK_MIXER_POS } static void mix16bRampBidiLoopIntrp(voice_t *v, uint32_t numSamples) { bool mixInMono; const int16_t *CDA_LinearAdr, *CDA_LinAdrRev; int32_t realPos, sample, sample2, *audioMixL, *audioMixR, CDA_BytesLeft, CDA_LVolIP, CDA_RVolIP; register const int16_t *smpPtr; register int32_t CDA_LVol, CDA_RVol, CDA_IPValL, CDA_IPValH; register uint32_t pos; uint32_t delta, i, samplesToMix; #ifndef LERPMIX int32_t sample3; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_OPTIMIZATION_BIDI_LOOP return; } GET_MIXER_VARS_RAMP SET_BASE16_BIDI CDA_BytesLeft = numSamples; while (CDA_BytesLeft > 0) { LIMIT_MIX_NUM LIMIT_MIX_NUM_RAMP CDA_BytesLeft -= samplesToMix; GET_VOL START_BIDI if (mixInMono) { if (samplesToMix & 1) { RENDER_16BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS_BIDI } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS_BIDI RENDER_16BIT_SMP_MONO_INTRP VOLUME_RAMPING INC_POS_BIDI } } else { if (samplesToMix & 1) { RENDER_16BIT_SMP_INTRP VOLUME_RAMPING INC_POS_BIDI } samplesToMix >>= 1; for (i = 0; i < samplesToMix; i++) { RENDER_16BIT_SMP_INTRP VOLUME_RAMPING INC_POS_BIDI RENDER_16BIT_SMP_INTRP VOLUME_RAMPING INC_POS_BIDI } } END_BIDI SET_VOL_BACK WRAP_BIDI_LOOP } SET_BACK_MIXER_POS } // ----------------------------------------------------------------------- const mixRoutine mixRoutineTable[24] = { (mixRoutine)mix8bNoLoop, (mixRoutine)mix8bLoop, (mixRoutine)mix8bBidiLoop, (mixRoutine)mix8bNoLoopIntrp, (mixRoutine)mix8bLoopIntrp, (mixRoutine)mix8bBidiLoopIntrp, (mixRoutine)mix8bRampNoLoop, (mixRoutine)mix8bRampLoop, (mixRoutine)mix8bRampBidiLoop, (mixRoutine)mix8bRampNoLoopIntrp, (mixRoutine)mix8bRampLoopIntrp, (mixRoutine)mix8bRampBidiLoopIntrp, (mixRoutine)mix16bNoLoop, (mixRoutine)mix16bLoop, (mixRoutine)mix16bBidiLoop, (mixRoutine)mix16bNoLoopIntrp, (mixRoutine)mix16bLoopIntrp, (mixRoutine)mix16bBidiLoopIntrp, (mixRoutine)mix16bRampNoLoop, (mixRoutine)mix16bRampLoop, (mixRoutine)mix16bRampBidiLoop, (mixRoutine)mix16bRampNoLoopIntrp, (mixRoutine)mix16bRampLoopIntrp, (mixRoutine)mix16bRampBidiLoopIntrp };