ref: eaee288d876e3dd4e2fc0fa7ee9ab17bf8d1eb6c
dir: /src/ft2_mix.c/
#include <stdint.h> #include <stdbool.h> #include "ft2_mix.h" #include "ft2_mix_macros.h" #include "ft2_intrp_table.h" /* ** --------------------- 32-bit fixed-point audio channel mixer --------------------- ** (Note: Mixing macros can be found in ft2_mix_macros.h) ** ** 8bitbubsy: This is mostly ported from the i386-asm 32-bit mixer that was introduced ** in FT2.08 (MS-DOS). It has been changed and improved quite a bit, though... ** Instead of 2-tap linear interpolation, it has 4-tap cubic spline interpolation. ** For x86_64: Fixed-point precision is 32.32 instead of 16.16 ** ** This file has separate routines for EVERY possible sampling variation: ** Interpolation on/off, volume ramping on/off, 8-bit, 16-bit, no loop, loop, pingpong. ** (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 & pointers are always thread-safely cleared when changing any ** of the above attributes from the GUI, to prevent possible thread-related issues. ** ** There's one problem with the 4-tap cubic spline resampling interpolation... ** On looped samples where loopStart>0, the splines are not correct when reading ** from the loopStart (or +1?) sample point. The difference in audio is very minor, ** so it's not a big problem. It just has to stay like this the way the mixer works. ** In cases where loopStart=0, the sample before index 0 (yes, we allocate enough ** data and pre-increment main pointer to support negative look-up), is already ** pre-fixed so that the splines will be correct. ** ---------------------------------------------------------------------------------- */ /* ----------------------------------------------------------------------- */ /* 8-BIT MIXING ROUTINES */ /* ----------------------------------------------------------------------- */ static void mix8bNoLoop(voice_t *v, uint32_t numSamples) { const int8_t *CDA_LinearAdr, *smpPtr; int32_t realPos, sample, *audioMixL, *audioMixR; int32_t CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos; #else uint32_t pos; #endif GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_MIXING_NO_LOOP return; } GET_MIXER_VARS 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, *smpPtr;; int32_t realPos, sample, *audioMixL, *audioMixR; int32_t CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos; #else uint32_t pos; #endif GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_MIXING_LOOP return; } GET_MIXER_VARS 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) { const int8_t *CDA_LinearAdr, *CDA_LinAdrRev, *smpPtr; int32_t realPos, sample, *audioMixL, *audioMixR; int32_t CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos, delta; #else uint32_t pos, delta; #endif GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_MIXING_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, *smpPtr; int32_t realPos, sample, sample2, sample3, sample4, *audioMixL, *audioMixR; int32_t CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos; #else uint32_t pos; #endif GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_MIXING_NO_LOOP return; } GET_MIXER_VARS 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, *smpPtr; int32_t realPos, sample, sample2, sample3, sample4, *audioMixL, *audioMixR; int32_t CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos; #else uint32_t pos; #endif GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_MIXING_LOOP return; } GET_MIXER_VARS 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) { const int8_t *CDA_LinearAdr, *CDA_LinAdrRev, *smpPtr; int32_t realPos, sample, sample2, sample3, sample4, *audioMixL, *audioMixR; int32_t CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos, delta; #else uint32_t pos, delta; #endif GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_MIXING_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, *smpPtr; int32_t realPos, sample, *audioMixL, *audioMixR; int32_t CDA_LVolIP, CDA_RVolIP, CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos; #else uint32_t pos; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_MIXING_NO_LOOP return; } GET_MIXER_VARS_RAMP 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, *smpPtr; int32_t realPos, sample, *audioMixL, *audioMixR; int32_t CDA_LVolIP, CDA_RVolIP, CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos; #else uint32_t pos; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_MIXING_LOOP return; } GET_MIXER_VARS_RAMP 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) { const int8_t *CDA_LinearAdr, *CDA_LinAdrRev, *smpPtr; int32_t realPos, sample, *audioMixL, *audioMixR; int32_t CDA_LVolIP, CDA_RVolIP, CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos, delta; #else uint32_t pos, delta; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_MIXING_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, *smpPtr; int32_t realPos, sample, sample2, sample3, sample4, *audioMixL, *audioMixR; int32_t CDA_LVolIP, CDA_RVolIP, CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos; #else uint32_t pos; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_MIXING_NO_LOOP return; } GET_MIXER_VARS_RAMP 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, *smpPtr; int32_t realPos, sample, sample2, sample3, sample4, *audioMixL, *audioMixR; int32_t CDA_LVolIP, CDA_RVolIP, CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos; #else uint32_t pos; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_MIXING_LOOP return; } GET_MIXER_VARS_RAMP 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) { const int8_t *CDA_LinearAdr, *CDA_LinAdrRev, *smpPtr; int32_t realPos, sample, sample2, sample3, sample4, *audioMixL, *audioMixR; int32_t CDA_LVolIP, CDA_RVolIP, CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos, delta; #else uint32_t pos, delta; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_MIXING_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) { const int16_t *CDA_LinearAdr, *smpPtr; int32_t realPos, sample, *audioMixL, *audioMixR; int32_t CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos; #else uint32_t pos; #endif GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_MIXING_NO_LOOP return; } GET_MIXER_VARS 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) { const int16_t *CDA_LinearAdr, *smpPtr; int32_t realPos, sample, *audioMixL, *audioMixR; int32_t CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos; #else uint32_t pos; #endif GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_MIXING_LOOP return; } GET_MIXER_VARS 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) { const int16_t *CDA_LinearAdr, *CDA_LinAdrRev, *smpPtr; int32_t realPos, sample, *audioMixL, *audioMixR; int32_t CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos, delta; #else uint32_t pos, delta; #endif GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_MIXING_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) { const int16_t *CDA_LinearAdr, *smpPtr; int32_t realPos, sample, sample2, sample3, sample4, *audioMixL, *audioMixR; int32_t CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos; #else uint32_t pos; #endif GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_MIXING_NO_LOOP return; } GET_MIXER_VARS 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) { const int16_t *CDA_LinearAdr, *smpPtr; int32_t realPos, sample, sample2, sample3, sample4, *audioMixL, *audioMixR; int32_t CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos; #else uint32_t pos; #endif GET_VOL if ((CDA_LVol| CDA_RVol) == 0) { VOL0_MIXING_LOOP return; } GET_MIXER_VARS 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) { const int16_t *CDA_LinearAdr, *CDA_LinAdrRev, *smpPtr; int32_t realPos, sample, sample2, sample3, sample4, *audioMixL, *audioMixR; int32_t CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos, delta; #else uint32_t pos, delta; #endif GET_VOL if ((CDA_LVol | CDA_RVol) == 0) { VOL0_MIXING_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) { const int16_t *CDA_LinearAdr, *smpPtr; int32_t realPos, sample, *audioMixL, *audioMixR; int32_t CDA_LVolIP, CDA_RVolIP, CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos; #else uint32_t pos; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_MIXING_NO_LOOP return; } GET_MIXER_VARS_RAMP 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) { const int16_t *CDA_LinearAdr, *smpPtr; int32_t realPos, sample, *audioMixL, *audioMixR; int32_t CDA_LVolIP, CDA_RVolIP, CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos; #else uint32_t pos; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_MIXING_LOOP return; } GET_MIXER_VARS_RAMP 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) { const int16_t *CDA_LinearAdr, *CDA_LinAdrRev, *smpPtr; int32_t realPos, sample, *audioMixL, *audioMixR; int32_t CDA_LVolIP, CDA_RVolIP, CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos, delta; #else uint32_t pos, delta; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_MIXING_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) { const int16_t *CDA_LinearAdr, *smpPtr; int32_t realPos, sample, sample2, sample3, sample4, *audioMixL, *audioMixR; int32_t CDA_LVolIP, CDA_RVolIP, CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos; #else uint32_t pos; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_MIXING_NO_LOOP return; } GET_MIXER_VARS_RAMP 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) { const int16_t *CDA_LinearAdr, *smpPtr; int32_t realPos, sample, sample2, sample3, sample4, *audioMixL, *audioMixR; int32_t CDA_LVolIP, CDA_RVolIP, CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos; #else uint32_t pos; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_MIXING_LOOP return; } GET_MIXER_VARS_RAMP 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) { const int16_t *CDA_LinearAdr, *CDA_LinAdrRev, *smpPtr; int32_t realPos, sample, sample2, sample3, sample4, *audioMixL, *audioMixR; int32_t CDA_LVolIP, CDA_RVolIP, CDA_LVol, CDA_RVol; uint32_t i, samplesToMix, CDA_BytesLeft; #if defined _WIN64 || defined __amd64__ uint64_t pos, delta; #else uint32_t pos, delta; #endif if ((v->SLVol1 | v->SRVol1 | v->SLVol2 | v->SRVol2) == 0) { VOL0_MIXING_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 };