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removed experimental wavelet codec
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3d9e3e8b7c
commit
c5cd701d4c
@ -1,267 +0,0 @@
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#pragma once
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#include <vector>
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#include <string.h>
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#include <stdlib.h>
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#include <stdexcept>
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#include <math.h>
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#ifdef USE_SSE_INSTRUCTIONS
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#include <Math/sse_block.h>
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#endif
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template<class FLOAT> class DaubechyWavelets
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{
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public:
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typedef enum { DWT_DAUB02=2, DWT_DAUB04=4, DWT_DAUB12=12, DWT_DAUB20=20 } WaveletType ;
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typedef enum { DWT_FORWARD=1, DWT_BACKWARD=0 } TransformType ;
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static void DWT2D(FLOAT *data,unsigned long int W,unsigned long int H,WaveletType type,TransformType tr)
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{
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unsigned long int nn[2] = {W,H} ;
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wtn(&data[-1], &nn[-1],2, tr, waveletFilter(type), pwt) ;
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}
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static void DWT1D(FLOAT *data,unsigned long int W,WaveletType type,TransformType tr)
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{
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unsigned long int nn[1] = {W} ;
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wtn(&data[-1], &nn[-1],1, tr, waveletFilter(type), pwt) ;
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}
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private:
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class wavefilt
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{
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public:
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wavefilt(int n)
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{
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int k;
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FLOAT sig = -1.0;
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static const FLOAT c2[5]={ 0.0, sqrt(2.0)/2.0, sqrt(2.0)/2.0, 0.0, 0.0 };
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static const FLOAT c4[5]={ 0.0, 0.4829629131445341, 0.8365163037378079, 0.2241438680420134,-0.1294095225512604 };
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static const FLOAT c12[13]={0.0,0.111540743350, 0.494623890398, 0.751133908021,
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0.315250351709,-0.226264693965,-0.129766867567,
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0.097501605587, 0.027522865530,-0.031582039318,
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0.000553842201, 0.004777257511,-0.001077301085};
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static const FLOAT c20[21]={0.0,0.026670057901, 0.188176800078, 0.527201188932,
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0.688459039454, 0.281172343661,-0.249846424327,
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-0.195946274377, 0.127369340336, 0.093057364604,
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-0.071394147166,-0.029457536822, 0.033212674059,
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0.003606553567,-0.010733175483, 0.001395351747,
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0.001992405295,-0.000685856695,-0.000116466855,
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0.000093588670,-0.000013264203 };
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ncof= (n==2)?4:n;
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const FLOAT *tmpcc ;
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cc.resize(ncof+1) ;
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cr.resize(ncof+1) ;
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if (n == 2)
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{
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tmpcc=c2;
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cc[1] = tmpcc[1] ;
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cc[2] = tmpcc[2] ;
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cc[3] = 0.0f ;
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cc[4] = 0.0f ;
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cr[1] = tmpcc[1] ;
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cr[2] =-tmpcc[2] ;
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cr[3] = 0.0f ;
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cr[4] = 0.0f ;
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ioff = joff = -1 ;
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}
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else
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{
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if (n == 4)
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tmpcc=c4;
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else if (n == 12)
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tmpcc=c12;
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else if (n == 20)
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tmpcc=c20;
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else
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throw std::runtime_error("unimplemented value n in pwtset");
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for (k=1;k<=n;k++)
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{
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cc[k] = tmpcc[k] ;
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cr[ncof+1-k]=sig*tmpcc[k];
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sig = -sig;
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}
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ioff = joff = -(n >> 1);
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}
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}
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~wavefilt() {}
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int ncof,ioff,joff;
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std::vector<FLOAT> cc;
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std::vector<FLOAT> cr;
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} ;
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static const wavefilt& waveletFilter(WaveletType type)
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{
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static wavefilt *daub02filt = NULL ;
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static wavefilt *daub04filt = NULL ;
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static wavefilt *daub12filt = NULL ;
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static wavefilt *daub20filt = NULL ;
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switch(type)
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{
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case DWT_DAUB02: if(daub02filt == NULL)
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daub02filt = new wavefilt(2) ;
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return *daub02filt ;
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case DWT_DAUB04: if(daub04filt == NULL)
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daub04filt = new wavefilt(4) ;
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return *daub04filt ;
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case DWT_DAUB12: if(daub12filt == NULL)
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daub12filt = new wavefilt(12) ;
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return *daub12filt ;
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case DWT_DAUB20: if(daub20filt == NULL)
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daub20filt = new wavefilt(20) ;
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return *daub20filt ;
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default:
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throw std::runtime_error("Unknown wavelet type.") ;
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}
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}
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static void pwt(FLOAT a[], unsigned long n, int isign,const wavefilt& wfilt)
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{
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/********************** BEGIN SIGNED PART *************************/
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/** md5sum = 2b9e1e38ac690f50806873cdb4a061ea **/
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/** Validation date = 08/10/10 **/
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/******************************************************************/
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unsigned long i,ii,ni,nj ;
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if (n < 4)
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return;
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FLOAT *wksp=new FLOAT[n+1];//vector(1,n);
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FLOAT ai,ai1 ;
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unsigned long int nmod=wfilt.ncof*n;
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unsigned long int n1=n-1;
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unsigned long int nh=n >> 1;
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memset(wksp,0,(n+1)*sizeof(FLOAT)) ;
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if (isign == DWT_FORWARD)
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for (ii=1,i=1;i<=n;i+=2,ii++)
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{
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ni=i+nmod+wfilt.ioff;
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nj=i+nmod+wfilt.joff;
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#ifdef USE_SSE_INSTRUCTIONS
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#warning Using SSE2 Instruction set for wavelet internal loops
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for (int k=1;k<=wfilt.ncof;k+=4)
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{
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int jf=ni+k;
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int jr=nj+k;
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sse_block w1(wfilt.cc[k],wfilt.cc[k+1],wfilt.cc[k+2],wfilt.cc[k+3]) ;
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sse_block w2(wfilt.cr[k],wfilt.cr[k+1],wfilt.cr[k+2],wfilt.cr[k+3]) ;
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sse_block a1( a[1+((jf+0)&n1)], a[1+((jf+1)&n1)], a[1+((jf+2)&n1)], a[1+((jf+3)&n1)]) ;
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sse_block a2( a[1+((jr+0)&n1)], a[1+((jr+1)&n1)], a[1+((jr+2)&n1)], a[1+((jr+3)&n1)]) ;
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sse_block wk1( w1*a1 ) ;
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sse_block wk2( w2*a2 ) ;
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wksp[ii ] += wk1.sum() ;
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wksp[ii+nh] += wk2.sum() ;
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}
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#else
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for (int k=1;k<=wfilt.ncof;k++)
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{
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int jf=n1 & (ni+k);
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int jr=n1 & (nj+k);
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wksp[ii] += wfilt.cc[k]*a[jf+1];
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wksp[ii+nh] += wfilt.cr[k]*a[jr+1];
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}
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#endif
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}
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else
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for (ii=1,i=1;i<=n;i+=2,ii++)
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{
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ai=a[ii];
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ai1=a[ii+nh];
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ni=i+nmod+wfilt.ioff;
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nj=i+nmod+wfilt.joff;
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#ifdef USE_SSE_INSTRUCTIONS
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sse_block ai_sse( ai,ai,ai,ai ) ;
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sse_block ai1_sse( ai1,ai1,ai1,ai1 ) ;
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for (int k=1;k<=wfilt.ncof;k+=4)
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{
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int jf=ni+k ;
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int jr=nj+k ; // in fact we have jf==jr, so the code is simpler.
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sse_block w1(wksp[1+((jf+0) & n1)],wksp[1+((jf+1) & n1)],wksp[1+((jf+2) & n1)],wksp[1+((jf+3) & n1)]) ;
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w1 += sse_block(wfilt.cc[k+0],wfilt.cc[k+1],wfilt.cc[k+2],wfilt.cc[k+3]) * ai_sse ;
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w1 += sse_block(wfilt.cr[k+0],wfilt.cr[k+1],wfilt.cr[k+2],wfilt.cr[k+3]) * ai1_sse ;
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wksp[1+((jr+0) & n1)] = w1[0] ;
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wksp[1+((jr+1) & n1)] = w1[1] ;
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wksp[1+((jr+2) & n1)] = w1[2] ;
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wksp[1+((jr+3) & n1)] = w1[3] ;
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}
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#else
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for (int k=1;k<=wfilt.ncof;++k)
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{
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wksp[(n1 & (ni+k))+1] += wfilt.cc[k]*ai;
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wksp[(n1 & (nj+k))+1] += wfilt.cr[k]*ai1;
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}
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#endif
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}
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for (uint j=1;j<=n;j++)
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a[j]=wksp[j];
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delete[] wksp ;//free_vector(wksp,1,n);
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/********************** END SIGNED PART *************************/
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}
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static void wtn(FLOAT a[], unsigned long nn[], int ndim, int isign, const wavefilt& w,void (*wtstep)(FLOAT [], unsigned long, int,const wavefilt&))
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{
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unsigned long i1,i2,i3,k,n,nnew,nprev=1,nt,ntot=1;
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int idim;
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FLOAT *wksp;
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for (idim=1;idim<=ndim;idim++)
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ntot *= nn[idim];
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wksp=new FLOAT[ntot+1] ; //vector(1,ntot);
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for (idim=1;idim<=ndim;idim++)
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{
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n=nn[idim];
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nnew=n*nprev;
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if (n > 4)
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for (i2=0;i2<ntot;i2+=nnew)
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for (i1=1;i1<=nprev;i1++)
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{
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for (i3=i1+i2,k=1;k<=n;k++,i3+=nprev) wksp[k]=a[i3];
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if(isign == DWT_FORWARD)
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for(nt=n;nt>=4;nt >>= 1)
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(*wtstep)(wksp,nt,isign,w);
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else
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for(nt=4;nt<=n;nt <<= 1)
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(*wtstep)(wksp,nt,isign,w);
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for (i3=i1+i2,k=1;k<=n;k++,i3+=nprev) a[i3]=wksp[k];
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}
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nprev=nnew;
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}
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delete[] wksp ;//free_vector(wksp,1,ntot);
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}
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};
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@ -8,7 +8,6 @@
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#include "VideoProcessor.h"
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#include "QVideoDevice.h"
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#include "DaubechyWavelets.h"
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#include <math.h>
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@ -31,7 +30,6 @@ VideoProcessor::VideoProcessor()
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_decoded_output_device = NULL ;
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//_encoding_current_codec = VIDEO_PROCESSOR_CODEC_ID_JPEG_VIDEO;
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//_encoding_current_codec = VIDEO_PROCESSOR_CODEC_ID_DDWT_VIDEO;
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_encoding_current_codec = VIDEO_PROCESSOR_CODEC_ID_MPEG_VIDEO;
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_estimated_bandwidth_in = 0 ;
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@ -66,8 +64,6 @@ bool VideoProcessor::processImage(const QImage& img)
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{
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case VIDEO_PROCESSOR_CODEC_ID_JPEG_VIDEO: codec = &_jpeg_video_codec ;
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break ;
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case VIDEO_PROCESSOR_CODEC_ID_DDWT_VIDEO: codec = &_ddwt_video_codec ;
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break ;
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case VIDEO_PROCESSOR_CODEC_ID_MPEG_VIDEO: codec = &_mpeg_video_codec ;
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break ;
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default:
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@ -159,8 +155,6 @@ void VideoProcessor::receiveEncodedData(const RsVOIPDataChunk& chunk)
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{
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case VIDEO_PROCESSOR_CODEC_ID_JPEG_VIDEO: codec = &_jpeg_video_codec ;
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break ;
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case VIDEO_PROCESSOR_CODEC_ID_DDWT_VIDEO: codec = &_ddwt_video_codec ;
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break ;
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case VIDEO_PROCESSOR_CODEC_ID_MPEG_VIDEO: codec = &_mpeg_video_codec ;
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break ;
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default:
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@ -317,234 +311,6 @@ bool JPEGVideo::encodeData(const QImage& image,uint32_t /* size_hint */,RsVOIPDa
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return true ;
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}
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bool WaveletVideo::encodeData(const QImage& image, uint32_t target_encoding_bitrate, RsVOIPDataChunk& voip_chunk)
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{
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static const int WAVELET_IMG_SIZE = 128 ;
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static const float W_THRESHOLD = 0.005 ; // low quality
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//static const float W_THRESHOLD = 0.0001; // high quality
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//static const float W_THRESHOLD = 0.0005; // medium quality
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static const int W2 = WAVELET_IMG_SIZE ;
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static const int H2 = WAVELET_IMG_SIZE ;
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assert(image.width() == W2) ;
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assert(image.height() == H2) ;
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float *temp = new float[W2*H2] ;
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std::cerr << " codec type: wavelets." << std::endl;
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// We should perform some interpolation here ;-)
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//
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for(int i=0;i<W2*H2;++i)
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temp[i] = (0.3*image.constBits()[4*i+1] + 0.59*image.constBits()[4*i+2] + 0.11*image.constBits()[4*i+3]) / 255.0 ;
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std::cerr << " resized image to B&W " << W2 << "x" << H2 << std::endl;
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DaubechyWavelets<float>::DWT2D(temp,W2,H2,DaubechyWavelets<float>::DWT_DAUB12,DaubechyWavelets<float>::DWT_FORWARD) ;
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// Now estimate the max energy in the W coefs, and only keep the largest.
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float mx = 0.0f ;
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for(int i=0;i<W2*H2;++i)
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if(mx < fabsf(temp[i]))
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mx = fabs(temp[i]) ;
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mx *= 1.1; // This avoids quantisation problems with wavelet coefs when they get too close to mx.
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std::cerr << " max wavelet coef : " << mx << std::endl;
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std::vector<uint16_t> compressed_values ;
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compressed_values.reserve(W2*H2) ;
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for(int i=0;i<W2*H2;++i)
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if(fabs(temp[i]) >= W_THRESHOLD*mx) // This needs to be improved. Wavelets do not all have the same visual impact.
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{
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// add one value, using 16 bits for coordinates and 16 bits for the value.
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compressed_values.push_back((uint16_t)i) ;
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compressed_values.push_back(quantize_16b(temp[i],mx)) ;
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//float f2 = from_quantized_16b(quantize_16b(temp[i],mx),mx) ;
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//if(fabs(f2 - temp[i]) >= 0.01*(fabs(temp[i])+fabs(f2)))
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//std::cerr << " before: " << temp[i] << ", quantised=" << quantize_16b(temp[i],mx)<< ", after: " << f2 << std::endl;
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}
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delete[] temp ;
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// Serialise all values into a memory buffer. This needs to be taken care of because of endian issues.
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int compressed_size = 4 + compressed_values.size()*2 ;
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std::cerr << " threshold : " << W_THRESHOLD << std::endl;
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std::cerr << " values kept: " << compressed_values.size()/2 << std::endl;
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std::cerr << " compression: " << compressed_size/float(W2*H2*3)*100 << " %" << std::endl;
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voip_chunk.data = malloc(HEADER_SIZE + compressed_size) ;
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// build header
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uint32_t flags = 0 ;
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((unsigned char *)voip_chunk.data)[0] = VideoProcessor::VIDEO_PROCESSOR_CODEC_ID_DDWT_VIDEO & 0xff ;
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((unsigned char *)voip_chunk.data)[1] = (VideoProcessor::VIDEO_PROCESSOR_CODEC_ID_DDWT_VIDEO >> 8) & 0xff ;
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((unsigned char *)voip_chunk.data)[2] = flags & 0xff ;
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((unsigned char *)voip_chunk.data)[3] = (flags >> 8) & 0xff ;
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unsigned char *compressed_mem = &((unsigned char *)voip_chunk.data)[HEADER_SIZE] ;
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serialise_ufloat(compressed_mem,mx) ;
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for(uint32_t i=0;i<compressed_values.size();++i)
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{
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compressed_mem[4 + 2*i+0] = compressed_values[i] & 0xff ;
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compressed_mem[4 + 2*i+1] = compressed_values[i] >> 8 ;
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}
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voip_chunk.type = RsVOIPDataChunk::RS_VOIP_DATA_TYPE_VIDEO ;
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voip_chunk.size = HEADER_SIZE + compressed_size ;
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return true ;
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}
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bool WaveletVideo::decodeData(const RsVOIPDataChunk& chunk,QImage& image)
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{
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static const int WAVELET_IMG_SIZE = 128 ;
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static const int W2 = WAVELET_IMG_SIZE ;
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static const int H2 = WAVELET_IMG_SIZE ;
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float *temp = new float[W2*H2] ;
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const unsigned char *compressed_mem = &static_cast<const unsigned char *>(chunk.data)[HEADER_SIZE] ;
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int compressed_size = chunk.size - HEADER_SIZE;
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memset(temp,0,W2*H2*sizeof(float)) ;
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float M = deserialise_ufloat(compressed_mem);
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|
||||
#ifdef VOIP_CODEC_DEBUG
|
||||
std::cerr << " codec type: wavelets." << std::endl;
|
||||
std::cerr << " max coef: " << M << std::endl;
|
||||
#endif
|
||||
|
||||
for(int i=4;i<compressed_size;i+=4)
|
||||
{
|
||||
// read all values. first 2 bytes: image coordinates.
|
||||
// next two bytes: value.
|
||||
//
|
||||
uint16_t indx = compressed_mem[i+0] + (compressed_mem[i+1] << 8) ;
|
||||
uint16_t encv = compressed_mem[i+2] + (compressed_mem[i+3] << 8) ;
|
||||
|
||||
float f = from_quantized_16b(encv,M) ;
|
||||
|
||||
temp[indx] = f ;
|
||||
}
|
||||
#ifdef VOIP_CODEC_DEBUG
|
||||
std::cerr << " values read: " << compressed_size/4-1 << std::endl;
|
||||
#endif
|
||||
|
||||
DaubechyWavelets<float>::DWT2D(temp,W2,H2,DaubechyWavelets<float>::DWT_DAUB12,DaubechyWavelets<float>::DWT_BACKWARD) ;
|
||||
|
||||
#ifdef VOIP_CODEC_DEBUG
|
||||
std::cerr << " resizing image to: " << w << "x" << h << std::endl;
|
||||
#endif
|
||||
|
||||
image = QImage(W2,H2,QImage::Format_RGB32) ;
|
||||
|
||||
int indx = 0 ;
|
||||
|
||||
for(int j=0;j<H2;++j)
|
||||
for(int i=0;i<W2;++i,++indx)
|
||||
{
|
||||
uint32_t val = std::min(255,std::max(0,(int)(255*temp[indx]))) ;
|
||||
|
||||
QRgb rgb = (0xff << 24) + (val << 16) + (val << 8) + val ;
|
||||
|
||||
image.setPixel(i,j,rgb);
|
||||
}
|
||||
|
||||
delete[] temp ;
|
||||
return true ;
|
||||
}
|
||||
|
||||
uint16_t WaveletVideo::quantize_16b(float x,float M)
|
||||
{
|
||||
// Do the quantization into
|
||||
// x = M * (m * 2^{-p} / 2^10)
|
||||
//
|
||||
// where m is coded on 10 bits (0->1023), and p is coded on 6 bits (0->63).
|
||||
// Packing [mp] into a 16bit uint16_t. M is the maximum coefficient over the quantization
|
||||
// process.
|
||||
//
|
||||
// So this represents numbers from M * 1 * 2^{-73} to M
|
||||
//
|
||||
// All calculatoins are performed on x/M*2^10
|
||||
//
|
||||
static const float LOG2 = log(2.0f) ;
|
||||
|
||||
int m,p ;
|
||||
|
||||
if(fabs(x) < 1e-8*M)
|
||||
{
|
||||
m = 0 ;
|
||||
p = 0 ;
|
||||
}
|
||||
else
|
||||
{
|
||||
float log2f = log(fabsf(x)/M)/LOG2 ;
|
||||
int mexp = (int)floor(MANTISSE_BITS - log2f) ;
|
||||
|
||||
m = (int)floor(pow(2.0f,mexp+log2f)) ;
|
||||
p = mexp ;
|
||||
|
||||
if(p > (1<<EXPONENT_BITS)-1)
|
||||
m=0 ;
|
||||
}
|
||||
|
||||
return (uint16_t)(p & ((1<<EXPONENT_BITS)-1)) + (uint16_t)((m & ((1<<MANTISSE_BITS)-1)) << EXPONENT_BITS) + ((x<0.0)?32768:0);
|
||||
}
|
||||
|
||||
float WaveletVideo::from_quantized_16b(uint16_t n,float M)
|
||||
{
|
||||
M *= (n&32768)?-1:1 ;
|
||||
|
||||
n &= 32767 ;
|
||||
uint32_t p = n & ((1<<EXPONENT_BITS)-1) ;
|
||||
uint32_t m = (n & (((1<<MANTISSE_BITS)-1) << EXPONENT_BITS)) >> EXPONENT_BITS ;
|
||||
|
||||
if(p > 10)
|
||||
return M * m / 1024.0f / (float)(1 << (p-10)) ;
|
||||
else
|
||||
return M * m / (float)(1 << p) ;
|
||||
}
|
||||
|
||||
void WaveletVideo::serialise_ufloat(unsigned char *mem, float f)
|
||||
{
|
||||
if(f < 0.0f)
|
||||
{
|
||||
std::cerr << "(EE) Cannot serialise invalid negative float value " << f << " in " << __PRETTY_FUNCTION__ << std::endl;
|
||||
return ;
|
||||
}
|
||||
// This serialisation is quite accurate. The max relative error is approx.
|
||||
// 0.01% and most of the time less than 1e-05% The error is well distributed
|
||||
// over numbers also.
|
||||
//
|
||||
uint32_t n = (f < 1e-7)?(~(uint32_t)0): ((uint32_t)( (1.0f/(1.0f+f) * (~(uint32_t)0)))) ;
|
||||
|
||||
mem[0] = n & 0xff ; n >>= 8 ;
|
||||
mem[1] = n & 0xff ; n >>= 8 ;
|
||||
mem[2] = n & 0xff ; n >>= 8 ;
|
||||
mem[3] = n & 0xff ;
|
||||
}
|
||||
float WaveletVideo::deserialise_ufloat(const unsigned char *mem)
|
||||
{
|
||||
uint32_t n = mem[3] ;
|
||||
n = (n << 8) + mem[2] ;
|
||||
n = (n << 8) + mem[1] ;
|
||||
n = (n << 8) + mem[0] ;
|
||||
|
||||
return 1.0f/ ( n/(float)(~(uint32_t)0)) - 1.0f ;
|
||||
}
|
||||
|
||||
FFmpegVideo::FFmpegVideo()
|
||||
{
|
||||
// Encoding
|
||||
|
@ -41,26 +41,6 @@ private:
|
||||
uint32_t _encoded_ref_frame_count ;
|
||||
};
|
||||
|
||||
class WaveletVideo: public VideoCodec
|
||||
{
|
||||
public:
|
||||
WaveletVideo() {}
|
||||
|
||||
protected:
|
||||
virtual bool encodeData(const QImage& Image, uint32_t target_encoding_bitrate, RsVOIPDataChunk& chunk) ;
|
||||
virtual bool decodeData(const RsVOIPDataChunk& chunk,QImage& image) ;
|
||||
private:
|
||||
|
||||
static const int MANTISSE_BITS = 9 ;
|
||||
static const int EXPONENT_BITS = 6 ;
|
||||
|
||||
static void serialise_ufloat(unsigned char *mem, float f);
|
||||
static float deserialise_ufloat(const unsigned char *mem);
|
||||
|
||||
static float from_quantized_16b(uint16_t n, float M);
|
||||
static uint16_t quantize_16b(float x, float M);
|
||||
};
|
||||
|
||||
struct AVCodec ;
|
||||
struct AVCodecContext ;
|
||||
struct AVFrame ;
|
||||
@ -152,7 +132,6 @@ class VideoProcessor
|
||||
// =====================================================================================
|
||||
|
||||
JPEGVideo _jpeg_video_codec ;
|
||||
WaveletVideo _ddwt_video_codec ;
|
||||
FFmpegVideo _mpeg_video_codec ;
|
||||
|
||||
uint16_t _encoding_current_codec ;
|
||||
|
Loading…
Reference in New Issue
Block a user