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pffastconv.c
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pffastconv.c
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/*
Copyright (c) 2019 Hayati Ayguen ( [email protected] )
*/
#include "pffastconv.h"
#include "pffft.h"
#include <stdlib.h>
#include <stdint.h>
#include <stdio.h>
#include <math.h>
#include <assert.h>
#include <string.h>
#define FASTCONV_DBG_OUT 0
/* detect compiler flavour */
#if defined(_MSC_VER)
# define RESTRICT __restrict
#pragma warning( disable : 4244 4305 4204 4456 )
#elif defined(__GNUC__)
# define RESTRICT __restrict
#endif
void *pffastconv_malloc(size_t nb_bytes)
{
return pffft_aligned_malloc(nb_bytes);
}
void pffastconv_free(void *p)
{
pffft_aligned_free(p);
}
int pffastconv_simd_size()
{
return pffft_simd_size();
}
struct PFFASTCONV_Setup
{
float * Xt; /* input == x in time domain - copy for alignment */
float * Xf; /* input == X in freq domain */
float * Hf; /* filterCoeffs == H in freq domain */
float * Mf; /* input * filterCoeffs in freq domain */
PFFFT_Setup *st;
int filterLen; /* convolution length */
int Nfft; /* FFT/block length */
int flags;
float scale;
};
PFFASTCONV_Setup * pffastconv_new_setup( const float * filterCoeffs, int filterLen, int * blockLen, int flags )
{
PFFASTCONV_Setup * s = NULL;
const int cplxFactor = ( (flags & PFFASTCONV_CPLX_INP_OUT) && (flags & PFFASTCONV_CPLX_SINGLE_FFT) ) ? 2 : 1;
const int minFftLen = 2*pffft_simd_size()*pffft_simd_size();
int i, Nfft = 2 * pffft_next_power_of_two(filterLen -1);
#if FASTCONV_DBG_OUT
const int iOldBlkLen = *blockLen;
#endif
if ( Nfft < minFftLen )
Nfft = minFftLen;
if ( flags & PFFASTCONV_CPLX_FILTER )
return NULL;
s = pffastconv_malloc( sizeof(struct PFFASTCONV_Setup) );
if ( *blockLen > Nfft ) {
Nfft = *blockLen;
Nfft = pffft_next_power_of_two(Nfft);
}
*blockLen = Nfft; /* this is in (complex) samples */
Nfft *= cplxFactor;
if ( (flags & PFFASTCONV_DIRECT_INP) && !(flags & PFFASTCONV_CPLX_INP_OUT) )
s->Xt = NULL;
else
s->Xt = pffastconv_malloc((unsigned)Nfft * sizeof(float));
s->Xf = pffastconv_malloc((unsigned)Nfft * sizeof(float));
s->Hf = pffastconv_malloc((unsigned)Nfft * sizeof(float));
s->Mf = pffastconv_malloc((unsigned)Nfft * sizeof(float));
s->st = pffft_new_setup(Nfft, PFFFT_REAL); /* with complex: we do 2 x fft() */
s->filterLen = filterLen; /* filterLen == convolution length == length of impulse response */
if ( cplxFactor == 2 )
s->filterLen = 2 * filterLen - 1;
s->Nfft = Nfft; /* FFT/block length */
s->flags = flags;
s->scale = (float)( 1.0 / Nfft );
memset( s->Xt, 0, (unsigned)Nfft * sizeof(float) );
if ( flags & PFFASTCONV_CORRELATION ) {
for ( i = 0; i < filterLen; ++i )
s->Xt[ ( Nfft - cplxFactor * i ) & (Nfft -1) ] = filterCoeffs[ i ];
} else {
for ( i = 0; i < filterLen; ++i )
s->Xt[ ( Nfft - cplxFactor * i ) & (Nfft -1) ] = filterCoeffs[ filterLen - 1 - i ];
}
pffft_transform(s->st, s->Xt, s->Hf, /* tmp = */ s->Mf, PFFFT_FORWARD);
#if FASTCONV_DBG_OUT
printf("\n fastConvSetup(filterLen = %d, blockLen %d) --> blockLen %d, OutLen = %d\n"
, filterLen, iOldBlkLen, *blockLen, Nfft - filterLen +1 );
#endif
return s;
}
void pffastconv_destroy_setup( PFFASTCONV_Setup * s )
{
if (!s)
return;
pffft_destroy_setup(s->st);
pffastconv_free(s->Mf);
pffastconv_free(s->Hf);
pffastconv_free(s->Xf);
if ( s->Xt )
pffastconv_free(s->Xt);
pffastconv_free(s);
}
int pffastconv_apply(PFFASTCONV_Setup * s, const float *input_, int cplxInputLen, float *output_, int applyFlush)
{
const float * RESTRICT X = input_;
float * RESTRICT Y = output_;
const int Nfft = s->Nfft;
const int filterLen = s->filterLen;
const int flags = s->flags;
const int cplxFactor = ( (flags & PFFASTCONV_CPLX_INP_OUT) && (flags & PFFASTCONV_CPLX_SINGLE_FFT) ) ? 2 : 1;
const int inputLen = cplxFactor * cplxInputLen;
int inpOff, procLen, numOut = 0, j, part, cplxOff;
/* applyFlush != 0:
* inputLen - inpOff -filterLen + 1 > 0
* <=> inputLen -filterLen + 1 > inpOff
* <=> inpOff < inputLen -filterLen + 1
*
* applyFlush == 0:
* inputLen - inpOff >= Nfft
* <=> inputLen - Nfft >= inpOff
* <=> inpOff <= inputLen - Nfft
* <=> inpOff < inputLen - Nfft + 1
*/
if ( cplxFactor == 2 )
{
const int maxOff = applyFlush ? (inputLen -filterLen + 1) : (inputLen - Nfft + 1);
#if 0
printf( "*** inputLen %d, filterLen %d, Nfft %d => maxOff %d\n", inputLen, filterLen, Nfft, maxOff);
#endif
for ( inpOff = 0; inpOff < maxOff; inpOff += numOut )
{
procLen = ( (inputLen - inpOff) >= Nfft ) ? Nfft : (inputLen - inpOff);
numOut = ( procLen - filterLen + 1 ) & ( ~1 );
if (!numOut)
break;
#if 0
if (!inpOff)
printf("*** inpOff = %d, numOut = %d\n", inpOff, numOut);
if (inpOff + filterLen + 2 >= maxOff )
printf("*** inpOff = %d, inpOff + numOut = %d\n", inpOff, inpOff + numOut);
#endif
if ( flags & PFFASTCONV_DIRECT_INP )
{
pffft_transform(s->st, X + inpOff, s->Xf, /* tmp = */ s->Mf, PFFFT_FORWARD);
}
else
{
memcpy( s->Xt, X + inpOff, (unsigned)procLen * sizeof(float) );
if ( procLen < Nfft )
memset( s->Xt + procLen, 0, (unsigned)(Nfft - procLen) * sizeof(float) );
pffft_transform(s->st, s->Xt, s->Xf, /* tmp = */ s->Mf, PFFFT_FORWARD);
}
pffft_zconvolve_no_accu(s->st, s->Xf, s->Hf, /* tmp = */ s->Mf, s->scale);
if ( flags & PFFASTCONV_DIRECT_OUT )
{
pffft_transform(s->st, s->Mf, Y + inpOff, s->Xf, PFFFT_BACKWARD);
}
else
{
pffft_transform(s->st, s->Mf, s->Xf, /* tmp = */ s->Xt, PFFFT_BACKWARD);
memcpy( Y + inpOff, s->Xf, (unsigned)numOut * sizeof(float) );
}
}
return inpOff / cplxFactor;
}
else
{
const int maxOff = applyFlush ? (inputLen -filterLen + 1) : (inputLen - Nfft + 1);
const int numParts = (flags & PFFASTCONV_CPLX_INP_OUT) ? 2 : 1;
for ( inpOff = 0; inpOff < maxOff; inpOff += numOut )
{
procLen = ( (inputLen - inpOff) >= Nfft ) ? Nfft : (inputLen - inpOff);
numOut = procLen - filterLen + 1;
for ( part = 0; part < numParts; ++part ) /* iterate per real/imag component */
{
if ( flags & PFFASTCONV_CPLX_INP_OUT )
{
cplxOff = 2 * inpOff + part;
for ( j = 0; j < procLen; ++j )
s->Xt[j] = X[cplxOff + 2 * j];
if ( procLen < Nfft )
memset( s->Xt + procLen, 0, (unsigned)(Nfft - procLen) * sizeof(float) );
pffft_transform(s->st, s->Xt, s->Xf, /* tmp = */ s->Mf, PFFFT_FORWARD);
}
else if ( flags & PFFASTCONV_DIRECT_INP )
{
pffft_transform(s->st, X + inpOff, s->Xf, /* tmp = */ s->Mf, PFFFT_FORWARD);
}
else
{
memcpy( s->Xt, X + inpOff, (unsigned)procLen * sizeof(float) );
if ( procLen < Nfft )
memset( s->Xt + procLen, 0, (unsigned)(Nfft - procLen) * sizeof(float) );
pffft_transform(s->st, s->Xt, s->Xf, /* tmp = */ s->Mf, PFFFT_FORWARD);
}
pffft_zconvolve_no_accu(s->st, s->Xf, s->Hf, /* tmp = */ s->Mf, s->scale);
if ( flags & PFFASTCONV_CPLX_INP_OUT )
{
pffft_transform(s->st, s->Mf, s->Xf, /* tmp = */ s->Xt, PFFFT_BACKWARD);
cplxOff = 2 * inpOff + part;
for ( j = 0; j < numOut; ++j )
Y[ cplxOff + 2 * j ] = s->Xf[j];
}
else if ( flags & PFFASTCONV_DIRECT_OUT )
{
pffft_transform(s->st, s->Mf, Y + inpOff, s->Xf, PFFFT_BACKWARD);
}
else
{
pffft_transform(s->st, s->Mf, s->Xf, /* tmp = */ s->Xt, PFFFT_BACKWARD);
memcpy( Y + inpOff, s->Xf, (unsigned)numOut * sizeof(float) );
}
}
}
return inpOff;
}
}