arm-wt-22k/lib_src/eas_wtengine.c - platform/external/sonivox - Git at Google

 /*----------------------------------------------------------------------------
  *
  * File:
  * eas_wtengine.c
  *
  * Contents and purpose:
  * This file contains the critical synthesizer components that need to
  * be optimized for best performance.
  *
  * Copyright Sonic Network Inc. 2004-2005

  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  *
  *----------------------------------------------------------------------------
  * Revision Control:
  *   $Revision: 844 $
  *   $Date: 2007-08-23 14:33:32 -0700 (Thu, 23 Aug 2007) $
  *----------------------------------------------------------------------------
 */

 /*------------------------------------
  * includes
  *------------------------------------
 */
 #include "log/log.h"
 #include <cutils/log.h>

 #include "eas_types.h"
 #include "eas_math.h"
 #include "eas_audioconst.h"
 #include "eas_sndlib.h"
 #include "eas_wtengine.h"
 #include "eas_mixer.h"

 /*----------------------------------------------------------------------------
  * prototypes
  *----------------------------------------------------------------------------
 */
 extern void WT_NoiseGenerator (S_WT_VOICE *pWTVoice, S_WT_INT_FRAME *pWTIntFrame);
 extern void WT_VoiceGain (S_WT_VOICE *pWTVoice, S_WT_INT_FRAME *pWTIntFrame);

 #if defined(_OPTIMIZED_MONO)
 extern void WT_InterpolateMono (S_WT_VOICE *pWTVoice, S_WT_INT_FRAME *pWTIntFrame);
 #else
 extern void WT_InterpolateNoLoop (S_WT_VOICE *pWTVoice, S_WT_INT_FRAME *pWTIntFrame);
 extern void WT_Interpolate (S_WT_VOICE *pWTVoice, S_WT_INT_FRAME *pWTIntFrame);
 #endif

 #if defined(_FILTER_ENABLED)
 extern void WT_VoiceFilter (S_FILTER_CONTROL*pFilter, S_WT_INT_FRAME *pWTIntFrame);
 #endif

 #if defined(_OPTIMIZED_MONO) || !defined(NATIVE_EAS_KERNEL)
 /*----------------------------------------------------------------------------
  * WT_VoiceGain
  *----------------------------------------------------------------------------
  * Purpose:
  * Output gain for individual voice
  *
  * Inputs:
  *
  * Outputs:
  *
  *----------------------------------------------------------------------------
 */
 /*lint -esym(715, pWTVoice) reserved for future use */
 void WT_VoiceGain (S_WT_VOICE *pWTVoice, S_WT_INT_FRAME *pWTIntFrame)
 {
     EAS_I32 *pMixBuffer;
     EAS_PCM *pInputBuffer;
     EAS_I32 gain;
     EAS_I32 gainIncrement;
     EAS_I32 tmp0;
     EAS_I32 tmp1;
     EAS_I32 tmp2;
     EAS_I32 numSamples;

 #if (NUM_OUTPUT_CHANNELS == 2)
     EAS_I32 gainLeft, gainRight;
 #endif

     /* initialize some local variables */
     numSamples = pWTIntFrame->numSamples;
     if (numSamples <= 0) {
         ALOGE("b/26366256");
         android_errorWriteLog(0x534e4554, "26366256");
         return;
     }
     pMixBuffer = pWTIntFrame->pMixBuffer;
     pInputBuffer = pWTIntFrame->pAudioBuffer;

     /*lint -e{703} <avoid multiply for performance>*/
     gainIncrement = (pWTIntFrame->frame.gainTarget - pWTIntFrame->prevGain) << (16 - SYNTH_UPDATE_PERIOD_IN_BITS);
     if (gainIncrement < 0)
         gainIncrement++;
     /*lint -e{703} <avoid multiply for performance>*/
     gain = pWTIntFrame->prevGain << 16;

 #if (NUM_OUTPUT_CHANNELS == 2)
     gainLeft = pWTVoice->gainLeft;
     gainRight = pWTVoice->gainRight;
 #endif

     while (numSamples--) {

         /* incremental gain step to prevent zipper noise */
         tmp0 = *pInputBuffer++;
         gain += gainIncrement;
         /*lint -e{704} <avoid divide>*/
         tmp2 = gain >> 16;

         /* scale sample by gain */
         tmp2 *= tmp0;


         /* stereo output */
 #if (NUM_OUTPUT_CHANNELS == 2)
         /*lint -e{704} <avoid divide>*/
         tmp2 = tmp2 >> 14;

         /* get the current sample in the final mix buffer */
         tmp1 = *pMixBuffer;

         /* left channel */
         tmp0 = tmp2 * gainLeft;
         /*lint -e{704} <avoid divide>*/
         tmp0 = tmp0 >> NUM_MIXER_GUARD_BITS;
         tmp1 += tmp0;
         *pMixBuffer++ = tmp1;

         /* get the current sample in the final mix buffer */
         tmp1 = *pMixBuffer;

         /* right channel */
         tmp0 = tmp2 * gainRight;
         /*lint -e{704} <avoid divide>*/
         tmp0 = tmp0 >> NUM_MIXER_GUARD_BITS;
         tmp1 += tmp0;
         *pMixBuffer++ = tmp1;

         /* mono output */
 #else

         /* get the current sample in the final mix buffer */
         tmp1 = *pMixBuffer;
         /*lint -e{704} <avoid divide>*/
         tmp2 = tmp2 >> (NUM_MIXER_GUARD_BITS - 1);
         tmp1 += tmp2;
         *pMixBuffer++ = tmp1;
 #endif

     }
 }
 #endif

 #ifndef NATIVE_EAS_KERNEL
 /*----------------------------------------------------------------------------
  * WT_Interpolate
  *----------------------------------------------------------------------------
  * Purpose:
  * Interpolation engine for wavetable synth
  *
  * Inputs:
  *
  * Outputs:
  *
  *----------------------------------------------------------------------------
 */
 void WT_Interpolate (S_WT_VOICE *pWTVoice, S_WT_INT_FRAME *pWTIntFrame)
 {
     EAS_PCM *pOutputBuffer;
     EAS_I32 phaseInc;
     EAS_I32 phaseFrac;
     EAS_I32 acc0;
     const EAS_SAMPLE *pSamples;
     const EAS_SAMPLE *loopEnd;
     EAS_I32 samp1;
     EAS_I32 samp2;
     EAS_I32 numSamples;

     /* initialize some local variables */
     numSamples = pWTIntFrame->numSamples;
     if (numSamples <= 0) {
         ALOGE("b/26366256");
         android_errorWriteLog(0x534e4554, "26366256");
         return;
     }
     pOutputBuffer = pWTIntFrame->pAudioBuffer;

     loopEnd = (const EAS_SAMPLE*) pWTVoice->loopEnd + 1;
     pSamples = (const EAS_SAMPLE*) pWTVoice->phaseAccum;
     /*lint -e{713} truncation is OK */
     phaseFrac = pWTVoice->phaseFrac;
     phaseInc = pWTIntFrame->frame.phaseIncrement;

     /* fetch adjacent samples */
 #if defined(_8_BIT_SAMPLES)
     /*lint -e{701} <avoid multiply for performance>*/
     samp1 = pSamples[0] << 8;
     /*lint -e{701} <avoid multiply for performance>*/
     samp2 = pSamples[1] << 8;
 #else
     samp1 = pSamples[0];
     samp2 = pSamples[1];
 #endif

     while (numSamples--) {

         /* linear interpolation */
         acc0 = samp2 - samp1;
         acc0 = acc0 * phaseFrac;
         /*lint -e{704} <avoid divide>*/
         acc0 = samp1 + (acc0 >> NUM_PHASE_FRAC_BITS);

         /* save new output sample in buffer */
         /*lint -e{704} <avoid divide>*/
         *pOutputBuffer++ = (EAS_I16)(acc0 >> 2);

         /* increment phase */
         phaseFrac += phaseInc;
         /*lint -e{704} <avoid divide>*/
         acc0 = phaseFrac >> NUM_PHASE_FRAC_BITS;

         /* next sample */
         if (acc0 > 0) {

             /* advance sample pointer */
             pSamples += acc0;
             phaseFrac = (EAS_I32)((EAS_U32)phaseFrac & PHASE_FRAC_MASK);

             /* check for loop end */
             acc0 = (EAS_I32) (pSamples - loopEnd);
             if (acc0 >= 0)
                 pSamples = (const EAS_SAMPLE*) pWTVoice->loopStart + acc0;

             /* fetch new samples */
 #if defined(_8_BIT_SAMPLES)
             /*lint -e{701} <avoid multiply for performance>*/
             samp1 = pSamples[0] << 8;
             /*lint -e{701} <avoid multiply for performance>*/
             samp2 = pSamples[1] << 8;
 #else
             samp1 = pSamples[0];
             samp2 = pSamples[1];
 #endif
         }
     }

     /* save pointer and phase */
     pWTVoice->phaseAccum = (EAS_U32) pSamples;
     pWTVoice->phaseFrac = (EAS_U32) phaseFrac;
 }
 #endif

 #ifndef NATIVE_EAS_KERNEL
 /*----------------------------------------------------------------------------
  * WT_InterpolateNoLoop
  *----------------------------------------------------------------------------
  * Purpose:
  * Interpolation engine for wavetable synth
  *
  * Inputs:
  *
  * Outputs:
  *
  *----------------------------------------------------------------------------
 */
 void WT_InterpolateNoLoop (S_WT_VOICE *pWTVoice, S_WT_INT_FRAME *pWTIntFrame)
 {
     EAS_PCM *pOutputBuffer;
     EAS_I32 phaseInc;
     EAS_I32 phaseFrac;
     EAS_I32 acc0;
     const EAS_SAMPLE *pSamples;
     EAS_I32 samp1;
     EAS_I32 samp2;
     EAS_I32 numSamples;

     /* initialize some local variables */
     numSamples = pWTIntFrame->numSamples;
     if (numSamples <= 0) {
         ALOGE("b/26366256");
         android_errorWriteLog(0x534e4554, "26366256");
         return;
     }
     pOutputBuffer = pWTIntFrame->pAudioBuffer;

     phaseInc = pWTIntFrame->frame.phaseIncrement;
     pSamples = (const EAS_SAMPLE*) pWTVoice->phaseAccum;
     phaseFrac = (EAS_I32)pWTVoice->phaseFrac;

     /* fetch adjacent samples */
 #if defined(_8_BIT_SAMPLES)
     /*lint -e{701} <avoid multiply for performance>*/
     samp1 = pSamples[0] << 8;
     /*lint -e{701} <avoid multiply for performance>*/
     samp2 = pSamples[1] << 8;
 #else
     samp1 = pSamples[0];
     samp2 = pSamples[1];
 #endif

     while (numSamples--) {


         /* linear interpolation */
         acc0 = samp2 - samp1;
         acc0 = acc0 * phaseFrac;
         /*lint -e{704} <avoid divide>*/
         acc0 = samp1 + (acc0 >> NUM_PHASE_FRAC_BITS);

         /* save new output sample in buffer */
         /*lint -e{704} <avoid divide>*/
         *pOutputBuffer++ = (EAS_I16)(acc0 >> 2);

         /* increment phase */
         phaseFrac += phaseInc;
         /*lint -e{704} <avoid divide>*/
         acc0 = phaseFrac >> NUM_PHASE_FRAC_BITS;

         /* next sample */
         if (acc0 > 0) {

             /* advance sample pointer */
             pSamples += acc0;
             phaseFrac = (EAS_I32)((EAS_U32)phaseFrac & PHASE_FRAC_MASK);

             /* fetch new samples */
 #if defined(_8_BIT_SAMPLES)
             /*lint -e{701} <avoid multiply for performance>*/
             samp1 = pSamples[0] << 8;
             /*lint -e{701} <avoid multiply for performance>*/
             samp2 = pSamples[1] << 8;
 #else
             samp1 = pSamples[0];
             samp2 = pSamples[1];
 #endif
         }
     }

     /* save pointer and phase */
     pWTVoice->phaseAccum = (EAS_U32) pSamples;
     pWTVoice->phaseFrac = (EAS_U32) phaseFrac;
 }
 #endif

 #if defined(_FILTER_ENABLED) && !defined(NATIVE_EAS_KERNEL)
 /*----------------------------------------------------------------------------
  * WT_VoiceFilter
  *----------------------------------------------------------------------------
  * Purpose:
  * Implements a 2-pole filter
  *
  * Inputs:
  *
  * Outputs:
  *
  *----------------------------------------------------------------------------
 */
 void WT_VoiceFilter (S_FILTER_CONTROL *pFilter, S_WT_INT_FRAME *pWTIntFrame)
 {
     EAS_PCM *pAudioBuffer;
     EAS_I32 k;
     EAS_I32 b1;
     EAS_I32 b2;
     EAS_I32 z1;
     EAS_I32 z2;
     EAS_I32 acc0;
     EAS_I32 acc1;
     EAS_I32 numSamples;

     /* initialize some local variables */
     numSamples = pWTIntFrame->numSamples;
     if (numSamples <= 0) {
         ALOGE("b/26366256");
         android_errorWriteLog(0x534e4554, "26366256");
         return;
     }
     pAudioBuffer = pWTIntFrame->pAudioBuffer;

     z1 = pFilter->z1;
     z2 = pFilter->z2;
     b1 = -pWTIntFrame->frame.b1;

     /*lint -e{702} <avoid divide> */
     b2 = -pWTIntFrame->frame.b2 >> 1;

     /*lint -e{702} <avoid divide> */
     k = pWTIntFrame->frame.k >> 1;

     while (numSamples--)
     {

         /* do filter calculations */
         acc0 = *pAudioBuffer;
         acc1 = z1 * b1;
         acc1 += z2 * b2;
         acc0 = acc1 + k * acc0;
         z2 = z1;

         /*lint -e{702} <avoid divide> */
         z1 = acc0 >> 14;
         *pAudioBuffer++ = (EAS_I16) z1;
     }

     /* save delay values     */
     pFilter->z1 = (EAS_I16) z1;
     pFilter->z2 = (EAS_I16) z2;
 }
 #endif

 /*----------------------------------------------------------------------------
  * WT_NoiseGenerator
  *----------------------------------------------------------------------------
  * Purpose:
  * Generate pseudo-white noise using PRNG and interpolation engine
  *
  * Inputs:
  *
  * Outputs:
  *
  * Notes:
  * This output is scaled -12dB to prevent saturation in the filter. For a
  * high quality synthesizer, the output can be set to full scale, however
  * if the filter is used, it can overflow with certain coefficients. In this
  * case, either a saturation operation should take in the filter before
  * scaling back to 16 bits or the signal path should be increased to 18 bits
  * or more.
  *----------------------------------------------------------------------------
 */
  void WT_NoiseGenerator (S_WT_VOICE *pWTVoice, S_WT_INT_FRAME *pWTIntFrame)
  {
     EAS_PCM *pOutputBuffer;
     EAS_I32 phaseInc;
     EAS_I32 tmp0;
     EAS_I32 tmp1;
     EAS_I32 nInterpolatedSample;
     EAS_I32 numSamples;

     /* initialize some local variables */
     numSamples = pWTIntFrame->numSamples;
     if (numSamples <= 0) {
         ALOGE("b/26366256");
         android_errorWriteLog(0x534e4554, "26366256");
         return;
     }
     pOutputBuffer = pWTIntFrame->pAudioBuffer;
     phaseInc = pWTIntFrame->frame.phaseIncrement;

     /* get last two samples generated */
     /*lint -e{704} <avoid divide for performance>*/
     tmp0 = (EAS_I32) (pWTVoice->phaseAccum) >> 18;
     /*lint -e{704} <avoid divide for performance>*/
     tmp1 = (EAS_I32) (pWTVoice->loopEnd) >> 18;

     /* generate a buffer of noise */
     while (numSamples--) {
         nInterpolatedSample = MULT_AUDIO_COEF( tmp0, (PHASE_ONE - pWTVoice->phaseFrac));
         nInterpolatedSample += MULT_AUDIO_COEF( tmp1, pWTVoice->phaseFrac);
         *pOutputBuffer++ = (EAS_PCM) nInterpolatedSample;

         /* update PRNG */
         pWTVoice->phaseFrac += (EAS_U32) phaseInc;
         if (GET_PHASE_INT_PART(pWTVoice->phaseFrac))    {
             tmp0 = tmp1;
             pWTVoice->phaseAccum = pWTVoice->loopEnd;
             pWTVoice->loopEnd = (5 * pWTVoice->loopEnd + 1);
             tmp1 = (EAS_I32) (pWTVoice->loopEnd) >> 18;
             pWTVoice->phaseFrac = GET_PHASE_FRAC_PART(pWTVoice->phaseFrac);
         }

     }
 }

 #ifndef _OPTIMIZED_MONO
 /*----------------------------------------------------------------------------
  * WT_ProcessVoice
  *----------------------------------------------------------------------------
  * Purpose:
  * This routine does the block processing for one voice. It is isolated
  * from the main synth code to allow for various implementation-specific
  * optimizations. It calls the interpolator, filter, and gain routines
  * appropriate for a particular configuration.
  *
  * Inputs:
  *
  * Outputs:
  *
  * Notes:
  *----------------------------------------------------------------------------
 */
 void WT_ProcessVoice (S_WT_VOICE *pWTVoice, S_WT_INT_FRAME *pWTIntFrame)
 {

     /* use noise generator */
     if (pWTVoice->loopStart == WT_NOISE_GENERATOR)
         WT_NoiseGenerator(pWTVoice, pWTIntFrame);

     /* generate interpolated samples for looped waves */
     else if (pWTVoice->loopStart != pWTVoice->loopEnd)
         WT_Interpolate(pWTVoice, pWTIntFrame);

     /* generate interpolated samples for unlooped waves */
     else
     {
         WT_InterpolateNoLoop(pWTVoice, pWTIntFrame);
     }

 #ifdef _FILTER_ENABLED
     if (pWTIntFrame->frame.k != 0)
         WT_VoiceFilter(&pWTVoice->filter, pWTIntFrame);
 #endif

 //2 TEST NEW MIXER FUNCTION
 #ifdef UNIFIED_MIXER
     {
         EAS_I32 gainLeft, gainIncLeft;

 #if (NUM_OUTPUT_CHANNELS == 2)
         EAS_I32 gainRight, gainIncRight;
 #endif

         gainLeft = (pWTIntFrame->prevGain * pWTVoice->gainLeft) << 1;
         gainIncLeft = (((pWTIntFrame->frame.gainTarget * pWTVoice->gainLeft) << 1) - gainLeft) >> SYNTH_UPDATE_PERIOD_IN_BITS;

 #if (NUM_OUTPUT_CHANNELS == 2)
         gainRight = (pWTIntFrame->prevGain * pWTVoice->gainRight) << 1;
         gainIncRight = (((pWTIntFrame->frame.gainTarget * pWTVoice->gainRight) << 1) - gainRight) >> SYNTH_UPDATE_PERIOD_IN_BITS;
         EAS_MixStream(
             pWTIntFrame->pAudioBuffer,
             pWTIntFrame->pMixBuffer,
             pWTIntFrame->numSamples,
             gainLeft,
             gainRight,
             gainIncLeft,
             gainIncRight,
             MIX_FLAGS_STEREO_OUTPUT);

 #else
         EAS_MixStream(
             pWTIntFrame->pAudioBuffer,
             pWTIntFrame->pMixBuffer,
             pWTIntFrame->numSamples,
             gainLeft,
             0,
             gainIncLeft,
             0,
             0);
 #endif
     }

 #else
     /* apply gain, and left and right gain */
     WT_VoiceGain(pWTVoice, pWTIntFrame);
 #endif
 }
 #endif

 #if defined(_OPTIMIZED_MONO) && !defined(NATIVE_EAS_KERNEL)
 /*----------------------------------------------------------------------------
  * WT_InterpolateMono
  *----------------------------------------------------------------------------
  * Purpose:
  * A C version of the sample interpolation + gain routine, optimized for mono.
  * It's not pretty, but it matches the assembly code exactly.
  *
  * Inputs:
  *
  * Outputs:
  *
  * Notes:
  *----------------------------------------------------------------------------
 */
 void WT_InterpolateMono (S_WT_VOICE *pWTVoice, S_WT_INT_FRAME *pWTIntFrame)
 {
     EAS_I32 *pMixBuffer;
     const EAS_I8 *pLoopEnd;
     const EAS_I8 *pCurrentPhaseInt;
     EAS_I32 numSamples;
     EAS_I32 gain;
     EAS_I32 gainIncrement;
     EAS_I32 currentPhaseFrac;
     EAS_I32 phaseInc;
     EAS_I32 tmp0;
     EAS_I32 tmp1;
     EAS_I32 tmp2;
     EAS_I8 *pLoopStart;

     numSamples = pWTIntFrame->numSamples;
     if (numSamples <= 0) {
         ALOGE("b/26366256");
         android_errorWriteLog(0x534e4554, "26366256");
         return;
     }
     pMixBuffer = pWTIntFrame->pMixBuffer;

     /* calculate gain increment */
     gainIncrement = (pWTIntFrame->gainTarget - pWTIntFrame->prevGain) << (16 - SYNTH_UPDATE_PERIOD_IN_BITS);
     if (gainIncrement < 0)
         gainIncrement++;
     gain = pWTIntFrame->prevGain << 16;

     pCurrentPhaseInt = pWTVoice->pPhaseAccum;
     currentPhaseFrac = pWTVoice->phaseFrac;
     phaseInc = pWTIntFrame->phaseIncrement;

     pLoopStart = pWTVoice->pLoopStart;
     pLoopEnd = pWTVoice->pLoopEnd + 1;

 InterpolationLoop:
     tmp0 = (EAS_I32)(pCurrentPhaseInt - pLoopEnd);
     if (tmp0 >= 0)
         pCurrentPhaseInt = pLoopStart + tmp0;

     tmp0 = *pCurrentPhaseInt;
     tmp1 = *(pCurrentPhaseInt + 1);

     tmp2 = phaseInc + currentPhaseFrac;

     tmp1 = tmp1 - tmp0;
     tmp1 = tmp1 * currentPhaseFrac;

     tmp1 = tmp0 + (tmp1 >> NUM_EG1_FRAC_BITS);

     pCurrentPhaseInt += (tmp2 >> NUM_PHASE_FRAC_BITS);
     currentPhaseFrac = tmp2 & PHASE_FRAC_MASK;

     gain += gainIncrement;
     tmp2 = (gain >> SYNTH_UPDATE_PERIOD_IN_BITS);

     tmp0 = *pMixBuffer;
     tmp2 = tmp1 * tmp2;
     tmp2 = (tmp2 >> 9);
     tmp0 = tmp2 + tmp0;
     *pMixBuffer++ = tmp0;

     numSamples--;
     if (numSamples > 0)
         goto InterpolationLoop;

     pWTVoice->pPhaseAccum = pCurrentPhaseInt;
     pWTVoice->phaseFrac = currentPhaseFrac;
     /*lint -e{702} <avoid divide>*/
     pWTVoice->gain = (EAS_I16)(gain >> SYNTH_UPDATE_PERIOD_IN_BITS);
 }
 #endif

 #ifdef _OPTIMIZED_MONO
 /*----------------------------------------------------------------------------
  * WT_ProcessVoice
  *----------------------------------------------------------------------------
  * Purpose:
  * This routine does the block processing for one voice. It is isolated
  * from the main synth code to allow for various implementation-specific
  * optimizations. It calls the interpolator, filter, and gain routines
  * appropriate for a particular configuration.
  *
  * Inputs:
  *
  * Outputs:
  *
  * Notes:
  * This special version works handles an optimized mono-only signal
  * without filters
  *----------------------------------------------------------------------------
 */
 void WT_ProcessVoice (S_WT_VOICE *pWTVoice, S_WT_INT_FRAME *pWTIntFrame)
 {

     /* use noise generator */
     if (pWTVoice->loopStart== WT_NOISE_GENERATOR)
     {
         WT_NoiseGenerator(pWTVoice, pWTIntFrame);
         WT_VoiceGain(pWTVoice, pWTIntFrame);
     }

     /* or generate interpolated samples */
     else
     {
         WT_InterpolateMono(pWTVoice, pWTIntFrame);
     }
 }
 #endif
	/*----------------------------------------------------------------------------
	*
	* File:
	* eas_wtengine.c
	*
	* Contents and purpose:
	* This file contains the critical synthesizer components that need to
	* be optimized for best performance.
	*
	* Copyright Sonic Network Inc. 2004-2005

	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*
	*----------------------------------------------------------------------------
	* Revision Control:
	* $Revision: 844 $
	* $Date: 2007-08-23 14:33:32 -0700 (Thu, 23 Aug 2007) $
	*----------------------------------------------------------------------------
	*/

	/*------------------------------------
	* includes
	*------------------------------------
	*/
	#include "log/log.h"
	#include <cutils/log.h>

	#include "eas_types.h"
	#include "eas_math.h"
	#include "eas_audioconst.h"
	#include "eas_sndlib.h"
	#include "eas_wtengine.h"
	#include "eas_mixer.h"

	/*----------------------------------------------------------------------------
	* prototypes
	*----------------------------------------------------------------------------
	*/
	extern void WT_NoiseGenerator (S_WT_VOICE pWTVoice, S_WT_INT_FRAME pWTIntFrame);
	extern void WT_VoiceGain (S_WT_VOICE pWTVoice, S_WT_INT_FRAME pWTIntFrame);

	#if defined(_OPTIMIZED_MONO)
	extern void WT_InterpolateMono (S_WT_VOICE pWTVoice, S_WT_INT_FRAME pWTIntFrame);
	#else
	extern void WT_InterpolateNoLoop (S_WT_VOICE pWTVoice, S_WT_INT_FRAME pWTIntFrame);
	extern void WT_Interpolate (S_WT_VOICE pWTVoice, S_WT_INT_FRAME pWTIntFrame);
	#endif

	#if defined(_FILTER_ENABLED)
	extern void WT_VoiceFilter (S_FILTER_CONTROLpFilter, S_WT_INT_FRAME pWTIntFrame);
	#endif

	#if defined(_OPTIMIZED_MONO) \|\| !defined(NATIVE_EAS_KERNEL)
	/*----------------------------------------------------------------------------
	* WT_VoiceGain
	*----------------------------------------------------------------------------
	* Purpose:
	* Output gain for individual voice
	*
	* Inputs:
	*
	* Outputs:
	*
	*----------------------------------------------------------------------------
	*/
	/lint -esym(715, pWTVoice) reserved for future use /
	void WT_VoiceGain (S_WT_VOICE pWTVoice, S_WT_INT_FRAME pWTIntFrame)
	{
	EAS_I32 *pMixBuffer;
	EAS_PCM *pInputBuffer;
	EAS_I32 gain;
	EAS_I32 gainIncrement;
	EAS_I32 tmp0;
	EAS_I32 tmp1;
	EAS_I32 tmp2;
	EAS_I32 numSamples;

	#if (NUM_OUTPUT_CHANNELS == 2)
	EAS_I32 gainLeft, gainRight;
	#endif

	/* initialize some local variables */
	numSamples = pWTIntFrame->numSamples;
	if (numSamples <= 0) {
	ALOGE("b/26366256");
	android_errorWriteLog(0x534e4554, "26366256");
	return;
	}
	pMixBuffer = pWTIntFrame->pMixBuffer;
	pInputBuffer = pWTIntFrame->pAudioBuffer;

	/lint -e{703} <avoid multiply for performance>/
	gainIncrement = (pWTIntFrame->frame.gainTarget - pWTIntFrame->prevGain) << (16 - SYNTH_UPDATE_PERIOD_IN_BITS);
	if (gainIncrement < 0)
	gainIncrement++;
	/lint -e{703} <avoid multiply for performance>/
	gain = pWTIntFrame->prevGain << 16;

	#if (NUM_OUTPUT_CHANNELS == 2)
	gainLeft = pWTVoice->gainLeft;
	gainRight = pWTVoice->gainRight;
	#endif

	while (numSamples--) {

	/* incremental gain step to prevent zipper noise */
	tmp0 = *pInputBuffer++;
	gain += gainIncrement;
	/lint -e{704} <avoid divide>/
	tmp2 = gain >> 16;

	/* scale sample by gain */
	tmp2 *= tmp0;


	/* stereo output */
	#if (NUM_OUTPUT_CHANNELS == 2)
	/lint -e{704} <avoid divide>/
	tmp2 = tmp2 >> 14;

	/* get the current sample in the final mix buffer */
	tmp1 = *pMixBuffer;

	/* left channel */
	tmp0 = tmp2 * gainLeft;
	/lint -e{704} <avoid divide>/
	tmp0 = tmp0 >> NUM_MIXER_GUARD_BITS;
	tmp1 += tmp0;
	*pMixBuffer++ = tmp1;

	/* get the current sample in the final mix buffer */
	tmp1 = *pMixBuffer;

	/* right channel */
	tmp0 = tmp2 * gainRight;
	/lint -e{704} <avoid divide>/
	tmp0 = tmp0 >> NUM_MIXER_GUARD_BITS;
	tmp1 += tmp0;
	*pMixBuffer++ = tmp1;

	/* mono output */
	#else

	/* get the current sample in the final mix buffer */
	tmp1 = *pMixBuffer;
	/lint -e{704} <avoid divide>/
	tmp2 = tmp2 >> (NUM_MIXER_GUARD_BITS - 1);
	tmp1 += tmp2;
	*pMixBuffer++ = tmp1;
	#endif

	}
	}
	#endif

	#ifndef NATIVE_EAS_KERNEL
	/*----------------------------------------------------------------------------
	* WT_Interpolate
	*----------------------------------------------------------------------------
	* Purpose:
	* Interpolation engine for wavetable synth
	*
	* Inputs:
	*
	* Outputs:
	*
	*----------------------------------------------------------------------------
	*/
	void WT_Interpolate (S_WT_VOICE pWTVoice, S_WT_INT_FRAME pWTIntFrame)
	{
	EAS_PCM *pOutputBuffer;
	EAS_I32 phaseInc;
	EAS_I32 phaseFrac;
	EAS_I32 acc0;
	const EAS_SAMPLE *pSamples;
	const EAS_SAMPLE *loopEnd;
	EAS_I32 samp1;
	EAS_I32 samp2;
	EAS_I32 numSamples;

	/* initialize some local variables */
	numSamples = pWTIntFrame->numSamples;
	if (numSamples <= 0) {
	ALOGE("b/26366256");
	android_errorWriteLog(0x534e4554, "26366256");
	return;
	}
	pOutputBuffer = pWTIntFrame->pAudioBuffer;

	loopEnd = (const EAS_SAMPLE*) pWTVoice->loopEnd + 1;
	pSamples = (const EAS_SAMPLE*) pWTVoice->phaseAccum;
	/lint -e{713} truncation is OK /
	phaseFrac = pWTVoice->phaseFrac;
	phaseInc = pWTIntFrame->frame.phaseIncrement;

	/* fetch adjacent samples */
	#if defined(_8_BIT_SAMPLES)
	/lint -e{701} <avoid multiply for performance>/
	samp1 = pSamples[0] << 8;
	/lint -e{701} <avoid multiply for performance>/
	samp2 = pSamples[1] << 8;
	#else
	samp1 = pSamples[0];
	samp2 = pSamples[1];
	#endif

	while (numSamples--) {

	/* linear interpolation */
	acc0 = samp2 - samp1;
	acc0 = acc0 * phaseFrac;
	/lint -e{704} <avoid divide>/
	acc0 = samp1 + (acc0 >> NUM_PHASE_FRAC_BITS);

	/* save new output sample in buffer */
	/lint -e{704} <avoid divide>/
	*pOutputBuffer++ = (EAS_I16)(acc0 >> 2);

	/* increment phase */
	phaseFrac += phaseInc;
	/lint -e{704} <avoid divide>/
	acc0 = phaseFrac >> NUM_PHASE_FRAC_BITS;

	/* next sample */
	if (acc0 > 0) {

	/* advance sample pointer */
	pSamples += acc0;
	phaseFrac = (EAS_I32)((EAS_U32)phaseFrac & PHASE_FRAC_MASK);

	/* check for loop end */
	acc0 = (EAS_I32) (pSamples - loopEnd);
	if (acc0 >= 0)
	pSamples = (const EAS_SAMPLE*) pWTVoice->loopStart + acc0;

	/* fetch new samples */
	#if defined(_8_BIT_SAMPLES)
	/lint -e{701} <avoid multiply for performance>/
	samp1 = pSamples[0] << 8;
	/lint -e{701} <avoid multiply for performance>/
	samp2 = pSamples[1] << 8;
	#else
	samp1 = pSamples[0];
	samp2 = pSamples[1];
	#endif
	}
	}

	/* save pointer and phase */
	pWTVoice->phaseAccum = (EAS_U32) pSamples;
	pWTVoice->phaseFrac = (EAS_U32) phaseFrac;
	}
	#endif

	#ifndef NATIVE_EAS_KERNEL
	/*----------------------------------------------------------------------------
	* WT_InterpolateNoLoop
	*----------------------------------------------------------------------------
	* Purpose:
	* Interpolation engine for wavetable synth
	*
	* Inputs:
	*
	* Outputs:
	*
	*----------------------------------------------------------------------------
	*/
	void WT_InterpolateNoLoop (S_WT_VOICE pWTVoice, S_WT_INT_FRAME pWTIntFrame)
	{
	EAS_PCM *pOutputBuffer;
	EAS_I32 phaseInc;
	EAS_I32 phaseFrac;
	EAS_I32 acc0;
	const EAS_SAMPLE *pSamples;
	EAS_I32 samp1;
	EAS_I32 samp2;
	EAS_I32 numSamples;

	/* initialize some local variables */
	numSamples = pWTIntFrame->numSamples;
	if (numSamples <= 0) {
	ALOGE("b/26366256");
	android_errorWriteLog(0x534e4554, "26366256");
	return;
	}
	pOutputBuffer = pWTIntFrame->pAudioBuffer;

	phaseInc = pWTIntFrame->frame.phaseIncrement;
	pSamples = (const EAS_SAMPLE*) pWTVoice->phaseAccum;
	phaseFrac = (EAS_I32)pWTVoice->phaseFrac;

	/* fetch adjacent samples */
	#if defined(_8_BIT_SAMPLES)
	/lint -e{701} <avoid multiply for performance>/
	samp1 = pSamples[0] << 8;
	/lint -e{701} <avoid multiply for performance>/
	samp2 = pSamples[1] << 8;
	#else
	samp1 = pSamples[0];
	samp2 = pSamples[1];
	#endif

	while (numSamples--) {


	/* linear interpolation */
	acc0 = samp2 - samp1;
	acc0 = acc0 * phaseFrac;
	/lint -e{704} <avoid divide>/
	acc0 = samp1 + (acc0 >> NUM_PHASE_FRAC_BITS);

	/* save new output sample in buffer */
	/lint -e{704} <avoid divide>/
	*pOutputBuffer++ = (EAS_I16)(acc0 >> 2);

	/* increment phase */
	phaseFrac += phaseInc;
	/lint -e{704} <avoid divide>/
	acc0 = phaseFrac >> NUM_PHASE_FRAC_BITS;

	/* next sample */
	if (acc0 > 0) {

	/* advance sample pointer */
	pSamples += acc0;
	phaseFrac = (EAS_I32)((EAS_U32)phaseFrac & PHASE_FRAC_MASK);

	/* fetch new samples */
	#if defined(_8_BIT_SAMPLES)
	/lint -e{701} <avoid multiply for performance>/
	samp1 = pSamples[0] << 8;
	/lint -e{701} <avoid multiply for performance>/
	samp2 = pSamples[1] << 8;
	#else
	samp1 = pSamples[0];
	samp2 = pSamples[1];
	#endif
	}
	}

	/* save pointer and phase */
	pWTVoice->phaseAccum = (EAS_U32) pSamples;
	pWTVoice->phaseFrac = (EAS_U32) phaseFrac;
	}
	#endif

	#if defined(_FILTER_ENABLED) && !defined(NATIVE_EAS_KERNEL)
	/*----------------------------------------------------------------------------
	* WT_VoiceFilter
	*----------------------------------------------------------------------------
	* Purpose:
	* Implements a 2-pole filter
	*
	* Inputs:
	*
	* Outputs:
	*
	*----------------------------------------------------------------------------
	*/
	void WT_VoiceFilter (S_FILTER_CONTROL pFilter, S_WT_INT_FRAME pWTIntFrame)
	{
	EAS_PCM *pAudioBuffer;
	EAS_I32 k;
	EAS_I32 b1;
	EAS_I32 b2;
	EAS_I32 z1;
	EAS_I32 z2;
	EAS_I32 acc0;
	EAS_I32 acc1;
	EAS_I32 numSamples;

	/* initialize some local variables */
	numSamples = pWTIntFrame->numSamples;
	if (numSamples <= 0) {
	ALOGE("b/26366256");
	android_errorWriteLog(0x534e4554, "26366256");
	return;
	}
	pAudioBuffer = pWTIntFrame->pAudioBuffer;

	z1 = pFilter->z1;
	z2 = pFilter->z2;
	b1 = -pWTIntFrame->frame.b1;

	/lint -e{702} <avoid divide> /
	b2 = -pWTIntFrame->frame.b2 >> 1;

	/lint -e{702} <avoid divide> /
	k = pWTIntFrame->frame.k >> 1;

	while (numSamples--)
	{

	/* do filter calculations */
	acc0 = *pAudioBuffer;
	acc1 = z1 * b1;
	acc1 += z2 * b2;
	acc0 = acc1 + k * acc0;
	z2 = z1;

	/lint -e{702} <avoid divide> /
	z1 = acc0 >> 14;
	*pAudioBuffer++ = (EAS_I16) z1;
	}

	/* save delay values */
	pFilter->z1 = (EAS_I16) z1;
	pFilter->z2 = (EAS_I16) z2;
	}
	#endif

	/*----------------------------------------------------------------------------
	* WT_NoiseGenerator
	*----------------------------------------------------------------------------
	* Purpose:
	* Generate pseudo-white noise using PRNG and interpolation engine
	*
	* Inputs:
	*
	* Outputs:
	*
	* Notes:
	* This output is scaled -12dB to prevent saturation in the filter. For a
	* high quality synthesizer, the output can be set to full scale, however
	* if the filter is used, it can overflow with certain coefficients. In this
	* case, either a saturation operation should take in the filter before
	* scaling back to 16 bits or the signal path should be increased to 18 bits
	* or more.
	*----------------------------------------------------------------------------
	*/
	void WT_NoiseGenerator (S_WT_VOICE pWTVoice, S_WT_INT_FRAME pWTIntFrame)
	{
	EAS_PCM *pOutputBuffer;
	EAS_I32 phaseInc;
	EAS_I32 tmp0;
	EAS_I32 tmp1;
	EAS_I32 nInterpolatedSample;
	EAS_I32 numSamples;

	/* initialize some local variables */
	numSamples = pWTIntFrame->numSamples;
	if (numSamples <= 0) {
	ALOGE("b/26366256");
	android_errorWriteLog(0x534e4554, "26366256");
	return;
	}
	pOutputBuffer = pWTIntFrame->pAudioBuffer;
	phaseInc = pWTIntFrame->frame.phaseIncrement;

	/* get last two samples generated */
	/lint -e{704} <avoid divide for performance>/
	tmp0 = (EAS_I32) (pWTVoice->phaseAccum) >> 18;
	/lint -e{704} <avoid divide for performance>/
	tmp1 = (EAS_I32) (pWTVoice->loopEnd) >> 18;

	/* generate a buffer of noise */
	while (numSamples--) {
	nInterpolatedSample = MULT_AUDIO_COEF( tmp0, (PHASE_ONE - pWTVoice->phaseFrac));
	nInterpolatedSample += MULT_AUDIO_COEF( tmp1, pWTVoice->phaseFrac);
	*pOutputBuffer++ = (EAS_PCM) nInterpolatedSample;

	/* update PRNG */
	pWTVoice->phaseFrac += (EAS_U32) phaseInc;
	if (GET_PHASE_INT_PART(pWTVoice->phaseFrac)) {
	tmp0 = tmp1;
	pWTVoice->phaseAccum = pWTVoice->loopEnd;
	pWTVoice->loopEnd = (5 * pWTVoice->loopEnd + 1);
	tmp1 = (EAS_I32) (pWTVoice->loopEnd) >> 18;
	pWTVoice->phaseFrac = GET_PHASE_FRAC_PART(pWTVoice->phaseFrac);
	}

	}
	}

	#ifndef _OPTIMIZED_MONO
	/*----------------------------------------------------------------------------
	* WT_ProcessVoice
	*----------------------------------------------------------------------------
	* Purpose:
	* This routine does the block processing for one voice. It is isolated
	* from the main synth code to allow for various implementation-specific
	* optimizations. It calls the interpolator, filter, and gain routines
	* appropriate for a particular configuration.
	*
	* Inputs:
	*
	* Outputs:
	*
	* Notes:
	*----------------------------------------------------------------------------
	*/
	void WT_ProcessVoice (S_WT_VOICE pWTVoice, S_WT_INT_FRAME pWTIntFrame)
	{

	/* use noise generator */
	if (pWTVoice->loopStart == WT_NOISE_GENERATOR)
	WT_NoiseGenerator(pWTVoice, pWTIntFrame);

	/* generate interpolated samples for looped waves */
	else if (pWTVoice->loopStart != pWTVoice->loopEnd)
	WT_Interpolate(pWTVoice, pWTIntFrame);

	/* generate interpolated samples for unlooped waves */
	else
	{
	WT_InterpolateNoLoop(pWTVoice, pWTIntFrame);
	}

	#ifdef _FILTER_ENABLED
	if (pWTIntFrame->frame.k != 0)
	WT_VoiceFilter(&pWTVoice->filter, pWTIntFrame);
	#endif

	//2 TEST NEW MIXER FUNCTION
	#ifdef UNIFIED_MIXER
	{
	EAS_I32 gainLeft, gainIncLeft;

	#if (NUM_OUTPUT_CHANNELS == 2)
	EAS_I32 gainRight, gainIncRight;
	#endif

	gainLeft = (pWTIntFrame->prevGain * pWTVoice->gainLeft) << 1;
	gainIncLeft = (((pWTIntFrame->frame.gainTarget * pWTVoice->gainLeft) << 1) - gainLeft) >> SYNTH_UPDATE_PERIOD_IN_BITS;

	#if (NUM_OUTPUT_CHANNELS == 2)
	gainRight = (pWTIntFrame->prevGain * pWTVoice->gainRight) << 1;
	gainIncRight = (((pWTIntFrame->frame.gainTarget * pWTVoice->gainRight) << 1) - gainRight) >> SYNTH_UPDATE_PERIOD_IN_BITS;
	EAS_MixStream(
	pWTIntFrame->pAudioBuffer,
	pWTIntFrame->pMixBuffer,
	pWTIntFrame->numSamples,
	gainLeft,
	gainRight,
	gainIncLeft,
	gainIncRight,
	MIX_FLAGS_STEREO_OUTPUT);

	#else
	EAS_MixStream(
	pWTIntFrame->pAudioBuffer,
	pWTIntFrame->pMixBuffer,
	pWTIntFrame->numSamples,
	gainLeft,
	0,
	gainIncLeft,
	0,
	0);
	#endif
	}

	#else
	/* apply gain, and left and right gain */
	WT_VoiceGain(pWTVoice, pWTIntFrame);
	#endif
	}
	#endif

	#if defined(_OPTIMIZED_MONO) && !defined(NATIVE_EAS_KERNEL)
	/*----------------------------------------------------------------------------
	* WT_InterpolateMono
	*----------------------------------------------------------------------------
	* Purpose:
	* A C version of the sample interpolation + gain routine, optimized for mono.
	* It's not pretty, but it matches the assembly code exactly.
	*
	* Inputs:
	*
	* Outputs:
	*
	* Notes:
	*----------------------------------------------------------------------------
	*/
	void WT_InterpolateMono (S_WT_VOICE pWTVoice, S_WT_INT_FRAME pWTIntFrame)
	{
	EAS_I32 *pMixBuffer;
	const EAS_I8 *pLoopEnd;
	const EAS_I8 *pCurrentPhaseInt;
	EAS_I32 numSamples;
	EAS_I32 gain;
	EAS_I32 gainIncrement;
	EAS_I32 currentPhaseFrac;
	EAS_I32 phaseInc;
	EAS_I32 tmp0;
	EAS_I32 tmp1;
	EAS_I32 tmp2;
	EAS_I8 *pLoopStart;

	numSamples = pWTIntFrame->numSamples;
	if (numSamples <= 0) {
	ALOGE("b/26366256");
	android_errorWriteLog(0x534e4554, "26366256");
	return;
	}
	pMixBuffer = pWTIntFrame->pMixBuffer;

	/* calculate gain increment */
	gainIncrement = (pWTIntFrame->gainTarget - pWTIntFrame->prevGain) << (16 - SYNTH_UPDATE_PERIOD_IN_BITS);
	if (gainIncrement < 0)
	gainIncrement++;
	gain = pWTIntFrame->prevGain << 16;

	pCurrentPhaseInt = pWTVoice->pPhaseAccum;
	currentPhaseFrac = pWTVoice->phaseFrac;
	phaseInc = pWTIntFrame->phaseIncrement;

	pLoopStart = pWTVoice->pLoopStart;
	pLoopEnd = pWTVoice->pLoopEnd + 1;

	InterpolationLoop:
	tmp0 = (EAS_I32)(pCurrentPhaseInt - pLoopEnd);
	if (tmp0 >= 0)
	pCurrentPhaseInt = pLoopStart + tmp0;

	tmp0 = *pCurrentPhaseInt;
	tmp1 = *(pCurrentPhaseInt + 1);

	tmp2 = phaseInc + currentPhaseFrac;

	tmp1 = tmp1 - tmp0;
	tmp1 = tmp1 * currentPhaseFrac;

	tmp1 = tmp0 + (tmp1 >> NUM_EG1_FRAC_BITS);

	pCurrentPhaseInt += (tmp2 >> NUM_PHASE_FRAC_BITS);
	currentPhaseFrac = tmp2 & PHASE_FRAC_MASK;

	gain += gainIncrement;
	tmp2 = (gain >> SYNTH_UPDATE_PERIOD_IN_BITS);

	tmp0 = *pMixBuffer;
	tmp2 = tmp1 * tmp2;
	tmp2 = (tmp2 >> 9);
	tmp0 = tmp2 + tmp0;
	*pMixBuffer++ = tmp0;

	numSamples--;
	if (numSamples > 0)
	goto InterpolationLoop;

	pWTVoice->pPhaseAccum = pCurrentPhaseInt;
	pWTVoice->phaseFrac = currentPhaseFrac;
	/lint -e{702} <avoid divide>/
	pWTVoice->gain = (EAS_I16)(gain >> SYNTH_UPDATE_PERIOD_IN_BITS);
	}
	#endif

	#ifdef _OPTIMIZED_MONO
	/*----------------------------------------------------------------------------
	* WT_ProcessVoice
	*----------------------------------------------------------------------------
	* Purpose:
	* This routine does the block processing for one voice. It is isolated
	* from the main synth code to allow for various implementation-specific
	* optimizations. It calls the interpolator, filter, and gain routines
	* appropriate for a particular configuration.
	*
	* Inputs:
	*
	* Outputs:
	*
	* Notes:
	* This special version works handles an optimized mono-only signal
	* without filters
	*----------------------------------------------------------------------------
	*/
	void WT_ProcessVoice (S_WT_VOICE pWTVoice, S_WT_INT_FRAME pWTIntFrame)
	{

	/* use noise generator */
	if (pWTVoice->loopStart== WT_NOISE_GENERATOR)
	{
	WT_NoiseGenerator(pWTVoice, pWTIntFrame);
	WT_VoiceGain(pWTVoice, pWTIntFrame);
	}

	/* or generate interpolated samples */
	else
	{
	WT_InterpolateMono(pWTVoice, pWTIntFrame);
	}
	}
	#endif