/*

* This source code is public domain.

*

* Authors: Olivier Lapicque <olivierl@jps.net>

* Markus Fick <webmaster@mark-f.de> spline + fir-resampler

*/

#include "stdafx.h"

#include "sndfile.h"

#include <math.h>

#ifdef MSC_VER

#pragma bss_seg(".modplug")

#endif

// Front Mix Buffer (Also room for interleaved rear mix)

int MixSoundBuffer[MIXBUFFERSIZE*4];

// Reverb Mix Buffer

#ifndef MODPLUG_NO_REVERB

int MixReverbBuffer[MIXBUFFERSIZE*2];

extern UINT gnReverbSend;

#endif

#ifndef MODPLUG_FASTSOUNDLIB

int MixRearBuffer[MIXBUFFERSIZE*2];

float MixFloatBuffer[MIXBUFFERSIZE*2];

#endif

#ifdef MSC_VER

#pragma bss_seg()

#endif

extern LONG gnDryROfsVol;

extern LONG gnDryLOfsVol;

extern LONG gnRvbROfsVol;

extern LONG gnRvbLOfsVol;

// 4x256 taps polyphase FIR resampling filter

extern short int gFastSinc[];

extern short int gKaiserSinc[]; // 8-taps polyphase

/*

*-----------------------------------------------------------------------------

cubic spline interpolation doc,

(derived from "digital image warping", g. wolberg)

interpolation polynomial: f(x) = A3*(x-floor(x))**3 + A2*(x-floor(x))**2 +

A1*(x-floor(x)) + A0

with Y = equispaced data points (dist=1), YD = first derivates of data points and IP = floor(x)

the A[0..3] can be found by solving

A0 = Y[IP]

A1 = YD[IP]

A2 = 3*(Y[IP+1]-Y[IP])-2.0*YD[IP]-YD[IP+1]

A3 = -2.0 * (Y[IP+1]-Y[IP]) + YD[IP] - YD[IP+1]

with the first derivates as

YD[IP] = 0.5 * (Y[IP+1] - Y[IP-1]);

YD[IP+1] = 0.5 * (Y[IP+2] - Y[IP])

the coefs becomes

A0 = Y[IP]

A1 = YD[IP]

= 0.5*(Y[IP+1] - Y[IP-1]);

A2 = 3.0*(Y[IP+1]-Y[IP])-2.0*YD[IP]-YD[IP+1]

= 3.0*(Y[IP+1]-Y[IP]) - 0.5*2.0*(Y[IP+1]-Y[IP-1]) - 0.5*(Y[IP+2]-Y[IP])

= 3.0*Y[IP+1] - 3.0*Y[IP] - Y[IP+1] + Y[IP-1] - 0.5*Y[IP+2] + 0.5*Y[IP]

= -0.5*Y[IP+2] + 2.0 * Y[IP+1] - 2.5*Y[IP] + Y[IP-1]

= Y[IP-1] + 2 * Y[IP+1] - 0.5 * (5.0 * Y[IP] + Y[IP+2])

A3 = -2.0*(Y[IP+1]-Y[IP]) + YD[IP] + YD[IP+1]

= -2.0*Y[IP+1] + 2.0*Y[IP] + 0.5*(Y[IP+1]-Y[IP-1]) + 0.5*(Y[IP+2]-Y[IP])

= -2.0*Y[IP+1] + 2.0*Y[IP] + 0.5*Y[IP+1] - 0.5*Y[IP-1] + 0.5*Y[IP+2] - 0.5*Y[IP]

= 0.5 * Y[IP+2] - 1.5 * Y[IP+1] + 1.5 * Y[IP] - 0.5 * Y[IP-1]

= 0.5 * (3.0 * (Y[IP] - Y[IP+1]) - Y[IP-1] + YP[IP+2])

then interpolated data value is (horner rule)

out = (((A3*x)+A2)*x+A1)*x+A0

this gives parts of data points Y[IP-1] to Y[IP+2] of

part x**3 x**2 x**1 x**0

Y[IP-1] -0.5 1 -0.5 0

Y[IP] 1.5 -2.5 0 1

Y[IP+1] -1.5 2 0.5 0

Y[IP+2] 0.5 -0.5 0 0

*---------------------------------------------------------------------------

*/

// number of bits used to scale spline coefs

#define SPLINE_QUANTBITS 14

#define SPLINE_QUANTSCALE (1L<<SPLINE_QUANTBITS)

#define SPLINE_8SHIFT (SPLINE_QUANTBITS-8)

#define SPLINE_16SHIFT (SPLINE_QUANTBITS)

// forces coefsset to unity gain

#define SPLINE_CLAMPFORUNITY

// log2(number) of precalculated splines (range is [4..14])

#define SPLINE_FRACBITS 10

#define SPLINE_LUTLEN (1L<<SPLINE_FRACBITS)

class CzCUBICSPLINE

{ public:

CzCUBICSPLINE( );

~CzCUBICSPLINE( );

static signed short lut[4*(1L<<SPLINE_FRACBITS)];

};

signed short CzCUBICSPLINE::lut[4*(1L<<SPLINE_FRACBITS)];

CzCUBICSPLINE::CzCUBICSPLINE( )

{ int _LIi;

int _LLen = (1L<<SPLINE_FRACBITS);

float _LFlen = 1.0f / (float)_LLen;

float _LScale = (float)SPLINE_QUANTSCALE;

for(_LIi=0;_LIi<_LLen;_LIi++)

{ float _LCm1, _LC0, _LC1, _LC2;

float _LX = ((float)_LIi)*_LFlen;

int _LSum,_LIdx = _LIi<<2;

_LCm1 = (float)floor( 0.5 + _LScale*(-0.5*_LX*_LX*_LX + 1.0*_LX*_LX - 0.5*_LX ) );

_LC0 = (float)floor( 0.5 + _LScale*( 1.5*_LX*_LX*_LX - 2.5*_LX*_LX + 1.0 ) );

_LC1 = (float)floor( 0.5 + _LScale*(-1.5*_LX*_LX*_LX + 2.0*_LX*_LX + 0.5*_LX ) );

_LC2 = (float)floor( 0.5 + _LScale*( 0.5*_LX*_LX*_LX - 0.5*_LX*_LX) );

lut[_LIdx+0] = (signed short)( (_LCm1 < -_LScale) ? -_LScale : ((_LCm1 > _LScale) ? _LScale : _LCm1) );

lut[_LIdx+1] = (signed short)( (_LC0 < -_LScale) ? -_LScale : ((_LC0 > _LScale) ? _LScale : _LC0 ) );

lut[_LIdx+2] = (signed short)( (_LC1 < -_LScale) ? -_LScale : ((_LC1 > _LScale) ? _LScale : _LC1 ) );

lut[_LIdx+3] = (signed short)( (_LC2 < -_LScale) ? -_LScale : ((_LC2 > _LScale) ? _LScale : _LC2 ) );

#ifdef SPLINE_CLAMPFORUNITY

_LSum = lut[_LIdx+0]+lut[_LIdx+1]+lut[_LIdx+2]+lut[_LIdx+3];

if( _LSum != SPLINE_QUANTSCALE )

{ int _LMax = _LIdx;

if( lut[_LIdx+1]>lut[_LMax] ) _LMax = _LIdx+1;

if( lut[_LIdx+2]>lut[_LMax] ) _LMax = _LIdx+2;

if( lut[_LIdx+3]>lut[_LMax] ) _LMax = _LIdx+3;

lut[_LMax] += ((signed short)SPLINE_QUANTSCALE-_LSum);

}

#endif

}

}

CzCUBICSPLINE::~CzCUBICSPLINE( )

{ // nothing todo

}

CzCUBICSPLINE sspline;

/*

------------------------------------------------------------------------------

fir interpolation doc,

(derived from "an engineer's guide to fir digital filters", n.j. loy)

calculate coefficients for ideal lowpass filter (with cutoff = fc in

0..1 (mapped to 0..nyquist))

c[-N..N] = (i==0) ? fc : sin(fc*pi*i)/(pi*i)

then apply selected window to coefficients

c[-N..N] *= w(0..N)

with n in 2*N and w(n) being a window function (see loy)

then calculate gain and scale filter coefs to have unity gain.

------------------------------------------------------------------------------

*/

// quantizer scale of window coefs

#define WFIR_QUANTBITS 15

#define WFIR_QUANTSCALE (1L<<WFIR_QUANTBITS)

#define WFIR_8SHIFT (WFIR_QUANTBITS-8)

#define WFIR_16BITSHIFT (WFIR_QUANTBITS)

// log2(number)-1 of precalculated taps range is [4..12]

#define WFIR_FRACBITS 10

#define WFIR_LUTLEN ((1L<<(WFIR_FRACBITS+1))+1)

// number of samples in window

#define WFIR_LOG2WIDTH 3

#define WFIR_WIDTH (1L<<WFIR_LOG2WIDTH)

#define WFIR_SMPSPERWING ((WFIR_WIDTH-1)>>1)

// cutoff (1.0 == pi/2)

#define WFIR_CUTOFF 0.90f

// wfir type

#define WFIR_HANN 0

#define WFIR_HAMMING 1

#define WFIR_BLACKMANEXACT 2

#define WFIR_BLACKMAN3T61 3

#define WFIR_BLACKMAN3T67 4

#define WFIR_BLACKMAN4T92 5

#define WFIR_BLACKMAN4T74 6

#define WFIR_KAISER4T 7

#define WFIR_TYPE WFIR_BLACKMANEXACT

// wfir help

#ifndef M_zPI

#define M_zPI 3.1415926535897932384626433832795

#endif

#define M_zEPS 1e-8

#define M_zBESSELEPS 1e-21

class CzWINDOWEDFIR

{

public:

CzWINDOWEDFIR( );

~CzWINDOWEDFIR( );

float coef( int _PCnr, float _POfs, float _PCut, int _PWidth, int _PType )

//OLD args to coef: float _PPos, float _PFc, int _PLen )

{

double _LWidthM1 = _PWidth-1;

double _LWidthM1Half = 0.5*_LWidthM1;

double _LPosU = ((double)_PCnr - _POfs);

double _LPos = _LPosU-_LWidthM1Half;

double _LPIdl = 2.0*M_zPI/_LWidthM1;

double _LWc,_LSi;

if( fabs(_LPos)<M_zEPS ) {

_LWc = 1.0;

_LSi = _PCut;

} else {

switch( _PType )

{

case WFIR_HANN:

_LWc = 0.50 - 0.50 * cos(_LPIdl*_LPosU);

break;

case WFIR_HAMMING:

_LWc = 0.54 - 0.46 * cos(_LPIdl*_LPosU);

break;

case WFIR_BLACKMANEXACT:

_LWc = 0.42 - 0.50 * cos(_LPIdl*_LPosU) +

0.08 * cos(2.0*_LPIdl*_LPosU);

break;

case WFIR_BLACKMAN3T61:

_LWc = 0.44959 - 0.49364 * cos(_LPIdl*_LPosU) +

0.05677 * cos(2.0*_LPIdl*_LPosU);

break;

case WFIR_BLACKMAN3T67:

_LWc = 0.42323 - 0.49755 * cos(_LPIdl*_LPosU) +

0.07922 * cos(2.0*_LPIdl*_LPosU);

break;

case WFIR_BLACKMAN4T92:

_LWc = 0.35875 - 0.48829 * cos(_LPIdl*_LPosU) +

0.14128 * cos(2.0*_LPIdl*_LPosU) -

0.01168 * cos(3.0*_LPIdl*_LPosU);

break;

case WFIR_BLACKMAN4T74:

_LWc = 0.40217 - 0.49703 * cos(_LPIdl*_LPosU) +

0.09392 * cos(2.0*_LPIdl*_LPosU) -

0.00183 * cos(3.0*_LPIdl*_LPosU);

break;

case WFIR_KAISER4T:

_LWc = 0.40243 - 0.49804 * cos(_LPIdl*_LPosU) +

0.09831 * cos(2.0*_LPIdl*_LPosU) -

0.00122 * cos(3.0*_LPIdl*_LPosU);

break;

default:

_LWc = 1.0;

break;

}

_LPos *= M_zPI;

_LSi = sin(_PCut*_LPos)/_LPos;

}

return (float)(_LWc*_LSi);

}

static signed short lut[WFIR_LUTLEN*WFIR_WIDTH];

};

signed short CzWINDOWEDFIR::lut[WFIR_LUTLEN*WFIR_WIDTH];

CzWINDOWEDFIR::CzWINDOWEDFIR()

{

int _LPcl;

float _LPcllen = (float)(1L<<WFIR_FRACBITS); // number of precalculated lines for 0..1 (-1..0)

float _LNorm = 1.0f / (float)(2.0f * _LPcllen);

float _LCut = WFIR_CUTOFF;

float _LScale = (float)WFIR_QUANTSCALE;

for( _LPcl=0;_LPcl<WFIR_LUTLEN;_LPcl++ )

{

float _LGain,_LCoefs[WFIR_WIDTH];

float _LOfs = ((float)_LPcl-_LPcllen)*_LNorm;

int _LCc,_LIdx = _LPcl<<WFIR_LOG2WIDTH;

for( _LCc=0,_LGain=0.0f;_LCc<WFIR_WIDTH;_LCc++ )

{ _LGain += (_LCoefs[_LCc] = coef( _LCc, _LOfs, _LCut, WFIR_WIDTH, WFIR_TYPE ));

}

_LGain = 1.0f/_LGain;

for( _LCc=0;_LCc<WFIR_WIDTH;_LCc++ )

{ float _LCoef = (float)floor( 0.5 + _LScale*_LCoefs[_LCc]*_LGain );

lut[_LIdx+_LCc] = (signed short)( (_LCoef<-_LScale)?-_LScale:((_LCoef>_LScale)?_LScale:_LCoef) );

}

}

}

CzWINDOWEDFIR::~CzWINDOWEDFIR()

{ // nothing todo

}

CzWINDOWEDFIR sfir;

// ----------------------------------------------------------------------------

// MIXING MACROS

// ----------------------------------------------------------------------------

#define SNDMIX_BEGINSAMPLELOOP8\

register MODCHANNEL * const pChn = pChannel;\

nPos = pChn->nPosLo;\

const signed char *p = (signed char *)(pChn->pCurrentSample+pChn->nPos);\

if (pChn->dwFlags & CHN_STEREO) p += pChn->nPos;\

int *pvol = pbuffer;\

do {

#define SNDMIX_BEGINSAMPLELOOP16\

register MODCHANNEL * const pChn = pChannel;\

nPos = pChn->nPosLo;\

const signed short *p = (signed short *)(pChn->pCurrentSample+(pChn->nPos*2));\

if (pChn->dwFlags & CHN_STEREO) p += pChn->nPos;\

int *pvol = pbuffer;\

do {

#define SNDMIX_ENDSAMPLELOOP\

nPos += pChn->nInc;\

} while (pvol < pbufmax);\

pChn->nPos += nPos >> 16;\

pChn->nPosLo = nPos & 0xFFFF;

#define SNDMIX_ENDSAMPLELOOP8 SNDMIX_ENDSAMPLELOOP

#define SNDMIX_ENDSAMPLELOOP16 SNDMIX_ENDSAMPLELOOP

//////////////////////////////////////////////////////////////////////////////

// Mono

// No interpolation

#define SNDMIX_GETMONOVOL8NOIDO\

int vol = p[nPos >> 16] << 8;

#define SNDMIX_GETMONOVOL16NOIDO\

int vol = p[nPos >> 16];

// Linear Interpolation

#define SNDMIX_GETMONOVOL8LINEAR\

int poshi = nPos >> 16;\

int poslo = (nPos >> 8) & 0xFF;\

int srcvol = p[poshi];\

int destvol = p[poshi+1];\

int vol = (srcvol<<8) + ((int)(poslo * (destvol - srcvol)));

#define SNDMIX_GETMONOVOL16LINEAR\

int poshi = nPos >> 16;\

int poslo = (nPos >> 8) & 0xFF;\

int srcvol = p[poshi];\

int destvol = p[poshi+1];\

int vol = srcvol + ((int)(poslo * (destvol - srcvol)) >> 8);

// spline interpolation (2 guard bits should be enough???)

#define SPLINE_FRACSHIFT ((16-SPLINE_FRACBITS)-2)

#define SPLINE_FRACMASK (((1L<<(16-SPLINE_FRACSHIFT))-1)&~3)

#define SNDMIX_GETMONOVOL8SPLINE \

int poshi = nPos >> 16; \

int poslo = (nPos >> SPLINE_FRACSHIFT) & SPLINE_FRACMASK; \

int vol = (CzCUBICSPLINE::lut[poslo ]*(int)p[poshi-1] + \

CzCUBICSPLINE::lut[poslo+1]*(int)p[poshi ] + \

CzCUBICSPLINE::lut[poslo+3]*(int)p[poshi+2] + \

CzCUBICSPLINE::lut[poslo+2]*(int)p[poshi+1]) >> SPLINE_8SHIFT;

#define SNDMIX_GETMONOVOL16SPLINE \

int poshi = nPos >> 16; \

int poslo = (nPos >> SPLINE_FRACSHIFT) & SPLINE_FRACMASK; \

int vol = (CzCUBICSPLINE::lut[poslo ]*(int)p[poshi-1] + \

CzCUBICSPLINE::lut[poslo+1]*(int)p[poshi ] + \

CzCUBICSPLINE::lut[poslo+3]*(int)p[poshi+2] + \

CzCUBICSPLINE::lut[poslo+2]*(int)p[poshi+1]) >> SPLINE_16SHIFT;

// fir interpolation

#define WFIR_FRACSHIFT (16-(WFIR_FRACBITS+1+WFIR_LOG2WIDTH))

#define WFIR_FRACMASK ((((1L<<(17-WFIR_FRACSHIFT))-1)&~((1L<<WFIR_LOG2WIDTH)-1)))

#define WFIR_FRACHALVE (1L<<(16-(WFIR_FRACBITS+2)))

#define SNDMIX_GETMONOVOL8FIRFILTER \

int poshi = nPos >> 16;\

int poslo = (nPos & 0xFFFF);\

int firidx = ((poslo+WFIR_FRACHALVE)>>WFIR_FRACSHIFT) & WFIR_FRACMASK; \

int vol = (CzWINDOWEDFIR::lut[firidx+0]*(int)p[poshi+1-4]); \

vol += (CzWINDOWEDFIR::lut[firidx+1]*(int)p[poshi+2-4]); \

vol += (CzWINDOWEDFIR::lut[firidx+2]*(int)p[poshi+3-4]); \

vol += (CzWINDOWEDFIR::lut[firidx+3]*(int)p[poshi+4-4]); \

vol += (CzWINDOWEDFIR::lut[firidx+4]*(int)p[poshi+5-4]); \

vol += (CzWINDOWEDFIR::lut[firidx+5]*(int)p[poshi+6-4]); \

vol += (CzWINDOWEDFIR::lut[firidx+6]*(int)p[poshi+7-4]); \

vol += (CzWINDOWEDFIR::lut[firidx+7]*(int)p[poshi+8-4]); \

vol >>= WFIR_8SHIFT;

#define SNDMIX_GETMONOVOL16FIRFILTER \

int poshi = nPos >> 16;\

int poslo = (nPos & 0xFFFF);\

int firidx = ((poslo+WFIR_FRACHALVE)>>WFIR_FRACSHIFT) & WFIR_FRACMASK; \

int vol1 = (CzWINDOWEDFIR::lut[firidx+0]*(int)p[poshi+1-4]); \

vol1 += (CzWINDOWEDFIR::lut[firidx+1]*(int)p[poshi+2-4]); \

vol1 += (CzWINDOWEDFIR::lut[firidx+2]*(int)p[poshi+3-4]); \

vol1 += (CzWINDOWEDFIR::lut[firidx+3]*(int)p[poshi+4-4]); \

int vol2 = (CzWINDOWEDFIR::lut[firidx+4]*(int)p[poshi+5-4]); \

vol2 += (CzWINDOWEDFIR::lut[firidx+5]*(int)p[poshi+6-4]); \

vol2 += (CzWINDOWEDFIR::lut[firidx+6]*(int)p[poshi+7-4]); \

vol2 += (CzWINDOWEDFIR::lut[firidx+7]*(int)p[poshi+8-4]); \

int vol = ((vol1>>1)+(vol2>>1)) >> (WFIR_16BITSHIFT-1);

/////////////////////////////////////////////////////////////////////////////

// Stereo

// No interpolation

#define SNDMIX_GETSTEREOVOL8NOIDO\

int vol_l = p[(nPos>>16)*2] << 8;\

int vol_r = p[(nPos>>16)*2+1] << 8;

#define SNDMIX_GETSTEREOVOL16NOIDO\

int vol_l = p[(nPos>>16)*2];\

int vol_r = p[(nPos>>16)*2+1];

// Linear Interpolation

#define SNDMIX_GETSTEREOVOL8LINEAR\

int poshi = nPos >> 16;\

int poslo = (nPos >> 8) & 0xFF;\

int srcvol_l = p[poshi*2];\

int vol_l = (srcvol_l<<8) + ((int)(poslo * (p[poshi*2+2] - srcvol_l)));\

int srcvol_r = p[poshi*2+1];\

int vol_r = (srcvol_r<<8) + ((int)(poslo * (p[poshi*2+3] - srcvol_r)));

#define SNDMIX_GETSTEREOVOL16LINEAR\

int poshi = nPos >> 16;\

int poslo = (nPos >> 8) & 0xFF;\

int srcvol_l = p[poshi*2];\

int vol_l = srcvol_l + ((int)(poslo * (p[poshi*2+2] - srcvol_l)) >> 8);\

int srcvol_r = p[poshi*2+1];\

int vol_r = srcvol_r + ((int)(poslo * (p[poshi*2+3] - srcvol_r)) >> 8);\

// Spline Interpolation

#define SNDMIX_GETSTEREOVOL8SPLINE \

int poshi = nPos >> 16; \

int poslo = (nPos >> SPLINE_FRACSHIFT) & SPLINE_FRACMASK; \

int vol_l = (CzCUBICSPLINE::lut[poslo ]*(int)p[(poshi-1)*2 ] + \

CzCUBICSPLINE::lut[poslo+1]*(int)p[(poshi )*2 ] + \

CzCUBICSPLINE::lut[poslo+2]*(int)p[(poshi+1)*2 ] + \

CzCUBICSPLINE::lut[poslo+3]*(int)p[(poshi+2)*2 ]) >> SPLINE_8SHIFT; \

int vol_r = (CzCUBICSPLINE::lut[poslo ]*(int)p[(poshi-1)*2+1] + \

CzCUBICSPLINE::lut[poslo+1]*(int)p[(poshi )*2+1] + \

CzCUBICSPLINE::lut[poslo+2]*(int)p[(poshi+1)*2+1] + \

CzCUBICSPLINE::lut[poslo+3]*(int)p[(poshi+2)*2+1]) >> SPLINE_8SHIFT;

#define SNDMIX_GETSTEREOVOL16SPLINE \

int poshi = nPos >> 16; \

int poslo = (nPos >> SPLINE_FRACSHIFT) & SPLINE_FRACMASK; \

int vol_l = (CzCUBICSPLINE::lut[poslo ]*(int)p[(poshi-1)*2 ] + \

CzCUBICSPLINE::lut[poslo+1]*(int)p[(poshi )*2 ] + \

CzCUBICSPLINE::lut[poslo+2]*(int)p[(poshi+1)*2 ] + \

CzCUBICSPLINE::lut[poslo+3]*(int)p[(poshi+2)*2 ]) >> SPLINE_16SHIFT; \

int vol_r = (CzCUBICSPLINE::lut[poslo ]*(int)p[(poshi-1)*2+1] + \

CzCUBICSPLINE::lut[poslo+1]*(int)p[(poshi )*2+1] + \

CzCUBICSPLINE::lut[poslo+2]*(int)p[(poshi+1)*2+1] + \

CzCUBICSPLINE::lut[poslo+3]*(int)p[(poshi+2)*2+1]) >> SPLINE_16SHIFT;

// fir interpolation

#define SNDMIX_GETSTEREOVOL8FIRFILTER \

int poshi = nPos >> 16;\

int poslo = (nPos & 0xFFFF);\

int firidx = ((poslo+WFIR_FRACHALVE)>>WFIR_FRACSHIFT) & WFIR_FRACMASK; \

int vol_l = (CzWINDOWEDFIR::lut[firidx+0]*(int)p[(poshi+1-4)*2 ]); \

vol_l += (CzWINDOWEDFIR::lut[firidx+1]*(int)p[(poshi+2-4)*2 ]); \

vol_l += (CzWINDOWEDFIR::lut[firidx+2]*(int)p[(poshi+3-4)*2 ]); \

vol_l += (CzWINDOWEDFIR::lut[firidx+3]*(int)p[(poshi+4-4)*2 ]); \

vol_l += (CzWINDOWEDFIR::lut[firidx+4]*(int)p[(poshi+5-4)*2 ]); \

vol_l += (CzWINDOWEDFIR::lut[firidx+5]*(int)p[(poshi+6-4)*2 ]); \

vol_l += (CzWINDOWEDFIR::lut[firidx+6]*(int)p[(poshi+7-4)*2 ]); \

vol_l += (CzWINDOWEDFIR::lut[firidx+7]*(int)p[(poshi+8-4)*2 ]); \

vol_l >>= WFIR_8SHIFT; \

int vol_r = (CzWINDOWEDFIR::lut[firidx+0]*(int)p[(poshi+1-4)*2+1]); \

vol_r += (CzWINDOWEDFIR::lut[firidx+1]*(int)p[(poshi+2-4)*2+1]); \

vol_r += (CzWINDOWEDFIR::lut[firidx+2]*(int)p[(poshi+3-4)*2+1]); \

vol_r += (CzWINDOWEDFIR::lut[firidx+3]*(int)p[(poshi+4-4)*2+1]); \

vol_r += (CzWINDOWEDFIR::lut[firidx+4]*(int)p[(poshi+5-4)*2+1]); \

vol_r += (CzWINDOWEDFIR::lut[firidx+5]*(int)p[(poshi+6-4)*2+1]); \

vol_r += (CzWINDOWEDFIR::lut[firidx+6]*(int)p[(poshi+7-4)*2+1]); \

vol_r += (CzWINDOWEDFIR::lut[firidx+7]*(int)p[(poshi+8-4)*2+1]); \

vol_r >>= WFIR_8SHIFT;

#define SNDMIX_GETSTEREOVOL16FIRFILTER \

int poshi = nPos >> 16;\

int poslo = (nPos & 0xFFFF);\

int firidx = ((poslo+WFIR_FRACHALVE)>>WFIR_FRACSHIFT) & WFIR_FRACMASK; \

int vol1_l = (CzWINDOWEDFIR::lut[firidx+0]*(int)p[(poshi+1-4)*2 ]); \

vol1_l += (CzWINDOWEDFIR::lut[firidx+1]*(int)p[(poshi+2-4)*2 ]); \

vol1_l += (CzWINDOWEDFIR::lut[firidx+2]*(int)p[(poshi+3-4)*2 ]); \

vol1_l += (CzWINDOWEDFIR::lut[firidx+3]*(int)p[(poshi+4-4)*2 ]); \

int vol2_l = (CzWINDOWEDFIR::lut[firidx+4]*(int)p[(poshi+5-4)*2 ]); \

vol2_l += (CzWINDOWEDFIR::lut[firidx+5]*(int)p[(poshi+6-4)*2 ]); \

vol2_l += (CzWINDOWEDFIR::lut[firidx+6]*(int)p[(poshi+7-4)*2 ]); \

vol2_l += (CzWINDOWEDFIR::lut[firidx+7]*(int)p[(poshi+8-4)*2 ]); \

int vol_l = ((vol1_l>>1)+(vol2_l>>1)) >> (WFIR_16BITSHIFT-1); \

int vol1_r = (CzWINDOWEDFIR::lut[firidx+0]*(int)p[(poshi+1-4)*2+1]); \

vol1_r += (CzWINDOWEDFIR::lut[firidx+1]*(int)p[(poshi+2-4)*2+1]); \

vol1_r += (CzWINDOWEDFIR::lut[firidx+2]*(int)p[(poshi+3-4)*2+1]); \

vol1_r += (CzWINDOWEDFIR::lut[firidx+3]*(int)p[(poshi+4-4)*2+1]); \

int vol2_r = (CzWINDOWEDFIR::lut[firidx+4]*(int)p[(poshi+5-4)*2+1]); \

vol2_r += (CzWINDOWEDFIR::lut[firidx+5]*(int)p[(poshi+6-4)*2+1]); \

vol2_r += (CzWINDOWEDFIR::lut[firidx+6]*(int)p[(poshi+7-4)*2+1]); \

vol2_r += (CzWINDOWEDFIR::lut[firidx+7]*(int)p[(poshi+8-4)*2+1]); \

int vol_r = ((vol1_r>>1)+(vol2_r>>1)) >> (WFIR_16BITSHIFT-1);

/////////////////////////////////////////////////////////////////////////////

#define SNDMIX_STOREMONOVOL\

pvol[0] += vol * pChn->nRightVol;\

pvol[1] += vol * pChn->nLeftVol;\

pvol += 2;

#define SNDMIX_STORESTEREOVOL\

pvol[0] += vol_l * pChn->nRightVol;\

pvol[1] += vol_r * pChn->nLeftVol;\

pvol += 2;

#define SNDMIX_STOREFASTMONOVOL\

int v = vol * pChn->nRightVol;\

pvol[0] += v;\

pvol[1] += v;\

pvol += 2;

#define SNDMIX_RAMPMONOVOL\

nRampLeftVol += pChn->nLeftRamp;\

nRampRightVol += pChn->nRightRamp;\

pvol[0] += vol * (nRampRightVol >> VOLUMERAMPPRECISION);\

pvol[1] += vol * (nRampLeftVol >> VOLUMERAMPPRECISION);\

pvol += 2;

#define SNDMIX_RAMPFASTMONOVOL\

nRampRightVol += pChn->nRightRamp;\

int fastvol = vol * (nRampRightVol >> VOLUMERAMPPRECISION);\

pvol[0] += fastvol;\

pvol[1] += fastvol;\

pvol += 2;

#define SNDMIX_RAMPSTEREOVOL\

nRampLeftVol += pChn->nLeftRamp;\

nRampRightVol += pChn->nRightRamp;\

pvol[0] += vol_l * (nRampRightVol >> VOLUMERAMPPRECISION);\

pvol[1] += vol_r * (nRampLeftVol >> VOLUMERAMPPRECISION);\

pvol += 2;

///////////////////////////////////////////////////

// Resonant Filters

// Mono

#define MIX_BEGIN_FILTER\

int fy1 = pChannel->nFilter_Y1;\

int fy2 = pChannel->nFilter_Y2;\

#define MIX_END_FILTER\

pChannel->nFilter_Y1 = fy1;\

pChannel->nFilter_Y2 = fy2;

#define SNDMIX_PROCESSFILTER\

vol = (vol * pChn->nFilter_A0 + fy1 * pChn->nFilter_B0 + fy2 * pChn->nFilter_B1 + 4096) >> 13;\

fy2 = fy1;\

fy1 = vol;\

// Stereo

#define MIX_BEGIN_STEREO_FILTER\

int fy1 = pChannel->nFilter_Y1;\

int fy2 = pChannel->nFilter_Y2;\

int fy3 = pChannel->nFilter_Y3;\

int fy4 = pChannel->nFilter_Y4;\

#define MIX_END_STEREO_FILTER\

pChannel->nFilter_Y1 = fy1;\

pChannel->nFilter_Y2 = fy2;\

pChannel->nFilter_Y3 = fy3;\

pChannel->nFilter_Y4 = fy4;\

#define SNDMIX_PROCESSSTEREOFILTER\

vol_l = (vol_l * pChn->nFilter_A0 + fy1 * pChn->nFilter_B0 + fy2 * pChn->nFilter_B1 + 4096) >> 13;\

vol_r = (vol_r * pChn->nFilter_A0 + fy3 * pChn->nFilter_B0 + fy4 * pChn->nFilter_B1 + 4096) >> 13;\

fy2 = fy1; fy1 = vol_l;\

fy4 = fy3; fy3 = vol_r;\

//////////////////////////////////////////////////////////

// Interfaces

typedef VOID (MPPASMCALL * LPMIXINTERFACE)(MODCHANNEL *, int *, int *);

#define BEGIN_MIX_INTERFACE(func)\

VOID MPPASMCALL func(MODCHANNEL *pChannel, int *pbuffer, int *pbufmax)\

{\

LONG nPos;

#define END_MIX_INTERFACE()\

SNDMIX_ENDSAMPLELOOP\

}

// Volume Ramps

#define BEGIN_RAMPMIX_INTERFACE(func)\

BEGIN_MIX_INTERFACE(func)\

LONG nRampRightVol = pChannel->nRampRightVol;\

LONG nRampLeftVol = pChannel->nRampLeftVol;

#define END_RAMPMIX_INTERFACE()\

SNDMIX_ENDSAMPLELOOP\

pChannel->nRampRightVol = nRampRightVol;\

pChannel->nRightVol = nRampRightVol >> VOLUMERAMPPRECISION;\

pChannel->nRampLeftVol = nRampLeftVol;\

pChannel->nLeftVol = nRampLeftVol >> VOLUMERAMPPRECISION;\

}

#define BEGIN_FASTRAMPMIX_INTERFACE(func)\

BEGIN_MIX_INTERFACE(func)\

LONG nRampRightVol = pChannel->nRampRightVol;

#define END_FASTRAMPMIX_INTERFACE()\

SNDMIX_ENDSAMPLELOOP\

pChannel->nRampRightVol = nRampRightVol;\

pChannel->nRampLeftVol = nRampRightVol;\

pChannel->nRightVol = nRampRightVol >> VOLUMERAMPPRECISION;\

pChannel->nLeftVol = pChannel->nRightVol;\

}

// Mono Resonant Filters

#define BEGIN_MIX_FLT_INTERFACE(func)\

BEGIN_MIX_INTERFACE(func)\

MIX_BEGIN_FILTER

#define END_MIX_FLT_INTERFACE()\

SNDMIX_ENDSAMPLELOOP\

MIX_END_FILTER\

}

#define BEGIN_RAMPMIX_FLT_INTERFACE(func)\

BEGIN_MIX_INTERFACE(func)\

LONG nRampRightVol = pChannel->nRampRightVol;\

LONG nRampLeftVol = pChannel->nRampLeftVol;\

MIX_BEGIN_FILTER

#define END_RAMPMIX_FLT_INTERFACE()\

SNDMIX_ENDSAMPLELOOP\

MIX_END_FILTER\

pChannel->nRampRightVol = nRampRightVol;\

pChannel->nRightVol = nRampRightVol >> VOLUMERAMPPRECISION;\

pChannel->nRampLeftVol = nRampLeftVol;\

pChannel->nLeftVol = nRampLeftVol >> VOLUMERAMPPRECISION;\

}

// Stereo Resonant Filters

#define BEGIN_MIX_STFLT_INTERFACE(func)\

BEGIN_MIX_INTERFACE(func)\

MIX_BEGIN_STEREO_FILTER

#define END_MIX_STFLT_INTERFACE()\

SNDMIX_ENDSAMPLELOOP\

MIX_END_STEREO_FILTER\

}

#define BEGIN_RAMPMIX_STFLT_INTERFACE(func)\

BEGIN_MIX_INTERFACE(func)\

LONG nRampRightVol = pChannel->nRampRightVol;\

LONG nRampLeftVol = pChannel->nRampLeftVol;\

MIX_BEGIN_STEREO_FILTER

#define END_RAMPMIX_STFLT_INTERFACE()\

SNDMIX_ENDSAMPLELOOP\

MIX_END_STEREO_FILTER\

pChannel->nRampRightVol = nRampRightVol;\

pChannel->nRightVol = nRampRightVol >> VOLUMERAMPPRECISION;\

pChannel->nRampLeftVol = nRampLeftVol;\

pChannel->nLeftVol = nRampLeftVol >> VOLUMERAMPPRECISION;\

}

/////////////////////////////////////////////////////

//

void MPPASMCALL X86_InitMixBuffer(int *pBuffer, UINT nSamples);

void MPPASMCALL X86_EndChannelOfs(MODCHANNEL *pChannel, int *pBuffer, UINT nSamples);

void MPPASMCALL X86_StereoFill(int *pBuffer, UINT nSamples, LPLONG lpROfs, LPLONG lpLOfs);

void X86_StereoMixToFloat(const int *, float *, float *, UINT nCount);

void X86_FloatToStereoMix(const float *pIn1, const float *pIn2, int *pOut, UINT nCount);

/////////////////////////////////////////////////////

// Mono samples functions

BEGIN_MIX_INTERFACE(Mono8BitMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8NOIDO

SNDMIX_STOREMONOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(Mono16BitMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16NOIDO

SNDMIX_STOREMONOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(Mono8BitLinearMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8LINEAR

SNDMIX_STOREMONOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(Mono16BitLinearMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16LINEAR

SNDMIX_STOREMONOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(Mono8BitSplineMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8SPLINE

SNDMIX_STOREMONOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(Mono16BitSplineMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16SPLINE

SNDMIX_STOREMONOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(Mono8BitFirFilterMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8FIRFILTER

SNDMIX_STOREMONOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(Mono16BitFirFilterMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16FIRFILTER

SNDMIX_STOREMONOVOL

END_MIX_INTERFACE()

// Volume Ramps

BEGIN_RAMPMIX_INTERFACE(Mono8BitRampMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8NOIDO

SNDMIX_RAMPMONOVOL

END_RAMPMIX_INTERFACE()

BEGIN_RAMPMIX_INTERFACE(Mono16BitRampMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16NOIDO

SNDMIX_RAMPMONOVOL

END_RAMPMIX_INTERFACE()

BEGIN_RAMPMIX_INTERFACE(Mono8BitLinearRampMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8LINEAR

SNDMIX_RAMPMONOVOL

END_RAMPMIX_INTERFACE()

BEGIN_RAMPMIX_INTERFACE(Mono16BitLinearRampMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16LINEAR

SNDMIX_RAMPMONOVOL

END_RAMPMIX_INTERFACE()

BEGIN_RAMPMIX_INTERFACE(Mono8BitSplineRampMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8SPLINE

SNDMIX_RAMPMONOVOL

END_RAMPMIX_INTERFACE()

BEGIN_RAMPMIX_INTERFACE(Mono16BitSplineRampMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16SPLINE

SNDMIX_RAMPMONOVOL

END_RAMPMIX_INTERFACE()

BEGIN_RAMPMIX_INTERFACE(Mono8BitFirFilterRampMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8FIRFILTER

SNDMIX_RAMPMONOVOL

END_RAMPMIX_INTERFACE()

BEGIN_RAMPMIX_INTERFACE(Mono16BitFirFilterRampMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16FIRFILTER

SNDMIX_RAMPMONOVOL

END_RAMPMIX_INTERFACE()

//////////////////////////////////////////////////////

// Fast mono mix for leftvol=rightvol (1 less imul)

BEGIN_MIX_INTERFACE(FastMono8BitMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8NOIDO

SNDMIX_STOREFASTMONOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(FastMono16BitMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16NOIDO

SNDMIX_STOREFASTMONOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(FastMono8BitLinearMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8LINEAR

SNDMIX_STOREFASTMONOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(FastMono16BitLinearMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16LINEAR

SNDMIX_STOREFASTMONOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(FastMono8BitSplineMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8SPLINE

SNDMIX_STOREFASTMONOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(FastMono16BitSplineMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16SPLINE

SNDMIX_STOREFASTMONOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(FastMono8BitFirFilterMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8FIRFILTER

SNDMIX_STOREFASTMONOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(FastMono16BitFirFilterMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16FIRFILTER

SNDMIX_STOREFASTMONOVOL

END_MIX_INTERFACE()

// Fast Ramps

BEGIN_FASTRAMPMIX_INTERFACE(FastMono8BitRampMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8NOIDO

SNDMIX_RAMPFASTMONOVOL

END_FASTRAMPMIX_INTERFACE()

BEGIN_FASTRAMPMIX_INTERFACE(FastMono16BitRampMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16NOIDO

SNDMIX_RAMPFASTMONOVOL

END_FASTRAMPMIX_INTERFACE()

BEGIN_FASTRAMPMIX_INTERFACE(FastMono8BitLinearRampMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8LINEAR

SNDMIX_RAMPFASTMONOVOL

END_FASTRAMPMIX_INTERFACE()

BEGIN_FASTRAMPMIX_INTERFACE(FastMono16BitLinearRampMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16LINEAR

SNDMIX_RAMPFASTMONOVOL

END_FASTRAMPMIX_INTERFACE()

BEGIN_FASTRAMPMIX_INTERFACE(FastMono8BitSplineRampMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8SPLINE

SNDMIX_RAMPFASTMONOVOL

END_FASTRAMPMIX_INTERFACE()

BEGIN_FASTRAMPMIX_INTERFACE(FastMono16BitSplineRampMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16SPLINE

SNDMIX_RAMPFASTMONOVOL

END_FASTRAMPMIX_INTERFACE()

BEGIN_FASTRAMPMIX_INTERFACE(FastMono8BitFirFilterRampMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8FIRFILTER

SNDMIX_RAMPFASTMONOVOL

END_FASTRAMPMIX_INTERFACE()

BEGIN_FASTRAMPMIX_INTERFACE(FastMono16BitFirFilterRampMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16FIRFILTER

SNDMIX_RAMPFASTMONOVOL

END_FASTRAMPMIX_INTERFACE()

//////////////////////////////////////////////////////

// Stereo samples

BEGIN_MIX_INTERFACE(Stereo8BitMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETSTEREOVOL8NOIDO

SNDMIX_STORESTEREOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(Stereo16BitMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETSTEREOVOL16NOIDO

SNDMIX_STORESTEREOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(Stereo8BitLinearMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETSTEREOVOL8LINEAR

SNDMIX_STORESTEREOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(Stereo16BitLinearMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETSTEREOVOL16LINEAR

SNDMIX_STORESTEREOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(Stereo8BitSplineMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETSTEREOVOL8SPLINE

SNDMIX_STORESTEREOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(Stereo16BitSplineMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETSTEREOVOL16SPLINE

SNDMIX_STORESTEREOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(Stereo8BitFirFilterMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETSTEREOVOL8FIRFILTER

SNDMIX_STORESTEREOVOL

END_MIX_INTERFACE()

BEGIN_MIX_INTERFACE(Stereo16BitFirFilterMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETSTEREOVOL16FIRFILTER

SNDMIX_STORESTEREOVOL

END_MIX_INTERFACE()

// Volume Ramps

BEGIN_RAMPMIX_INTERFACE(Stereo8BitRampMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETSTEREOVOL8NOIDO

SNDMIX_RAMPSTEREOVOL

END_RAMPMIX_INTERFACE()

BEGIN_RAMPMIX_INTERFACE(Stereo16BitRampMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETSTEREOVOL16NOIDO

SNDMIX_RAMPSTEREOVOL

END_RAMPMIX_INTERFACE()

BEGIN_RAMPMIX_INTERFACE(Stereo8BitLinearRampMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETSTEREOVOL8LINEAR

SNDMIX_RAMPSTEREOVOL

END_RAMPMIX_INTERFACE()

BEGIN_RAMPMIX_INTERFACE(Stereo16BitLinearRampMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETSTEREOVOL16LINEAR

SNDMIX_RAMPSTEREOVOL

END_RAMPMIX_INTERFACE()

BEGIN_RAMPMIX_INTERFACE(Stereo8BitSplineRampMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETSTEREOVOL8SPLINE

SNDMIX_RAMPSTEREOVOL

END_RAMPMIX_INTERFACE()

BEGIN_RAMPMIX_INTERFACE(Stereo16BitSplineRampMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETSTEREOVOL16SPLINE

SNDMIX_RAMPSTEREOVOL

END_RAMPMIX_INTERFACE()

BEGIN_RAMPMIX_INTERFACE(Stereo8BitFirFilterRampMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETSTEREOVOL8FIRFILTER

SNDMIX_RAMPSTEREOVOL

END_RAMPMIX_INTERFACE()

BEGIN_RAMPMIX_INTERFACE(Stereo16BitFirFilterRampMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETSTEREOVOL16FIRFILTER

SNDMIX_RAMPSTEREOVOL

END_RAMPMIX_INTERFACE()

//////////////////////////////////////////////////////

// Resonant Filter Mix

#ifndef NO_FILTER

// Mono Filter Mix

BEGIN_MIX_FLT_INTERFACE(FilterMono8BitMix)

SNDMIX_BEGINSAMPLELOOP8

SNDMIX_GETMONOVOL8NOIDO

SNDMIX_PROCESSFILTER

SNDMIX_STOREMONOVOL

END_MIX_FLT_INTERFACE()

BEGIN_MIX_FLT_INTERFACE(FilterMono16BitMix)

SNDMIX_BEGINSAMPLELOOP16

SNDMIX_GETMONOVOL16NOIDO

SNDMIX_PROCESSFILTER

SNDMIX_STOREMONOVOL

END_MIX_FLT_INTERFACE()