libcm/vop/cmVectOps.c

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2012-10-30 03:52:39 +00:00
#include "cmPrefix.h"
#include "cmGlobal.h"
#include "cmFloatTypes.h"
#include "cmComplexTypes.h"
#include "cmRpt.h"
#include "cmErr.h"
#include "cmCtx.h"
#include "cmMem.h"
#include "cmMallocDebug.h"
#include "cmLinkedHeap.h"
#include "cmSymTbl.h"
#include "cmMath.h"
#ifdef OS_LINUX
#include <cblas.h>
#endif
#include "cmAudioFile.h"
#include "cmFileSys.h"
#include "cmProcObj.h"
#include "cmProcTemplate.h"
#include "cmProc.h"
#include "cmVectOps.h"
#define cmVectOpsTemplateCode_h
#define cmVectOpsRICode_h
#include "cmVectOpsTemplateMain.h"
void cmVOU_VPrint( cmRpt_t* rpt, const char* fmt, ... )
{
va_list vl;
va_start(vl,fmt);
if( rpt == NULL )
vprintf(fmt,vl);
else
cmRptVPrintf(rpt,fmt,vl);
va_end(vl);
}
void cmVOI_Print( cmRpt_t* rpt, unsigned rn, unsigned cn, const int* sbp )
{
unsigned fieldWidth = cmDefaultFieldWidth;
if( fieldWidth < 0 )
fieldWidth = 10;
unsigned ri,ci;
for(ri=0; ri<rn; ++ri)
{
for(ci=0; ci<cn; ++ci )
cmVOU_VPrint(rpt,"%*i ",fieldWidth,sbp[ (ci*rn) + ri ]);
if( cn > 0 )
cmVOU_VPrint(rpt,"\n");
}
}
void cmVOU_Print( cmRpt_t* rpt, unsigned rn, unsigned cn, const unsigned* sbp )
{
unsigned fieldWidth = cmDefaultFieldWidth;
if( fieldWidth < 0 )
fieldWidth = 10;
unsigned ri,ci;
for(ri=0; ri<rn; ++ri)
{
for(ci=0; ci<cn; ++ci )
cmVOU_VPrint(rpt,"%*u ",fieldWidth,sbp[ (ci*rn) + ri ]);
if( cn > 0 )
cmVOU_VPrint(rpt,"\n");
}
}
void cmVOI_PrintL( const char* label, cmRpt_t* rpt, unsigned rn, unsigned cn, const int* sp )
{
cmVOU_VPrint(rpt,"%s ",label);
return cmVOI_Print(rpt,rn,cn,sp);
}
void cmVOU_PrintL( const char* label, cmRpt_t* rpt, unsigned rn, unsigned cn, const unsigned* sp )
{
cmVOU_VPrint(rpt,"%s ",label);
return cmVOU_Print(rpt,rn,cn,sp);
}
unsigned* cmVOU_Mod( unsigned* dbp, unsigned dn, unsigned modVal )
{
const unsigned* dep = dbp + dn;
unsigned* dp = dbp;
while( dbp < dep )
*dbp++ %= modVal;
return dp;
}
unsigned* cmVOU_Hist( unsigned* hbp, unsigned hn, const unsigned* sbp, unsigned sn )
{
const unsigned* sep = sbp + sn;
unsigned* rp = hbp;
memset(hbp,0,hn * sizeof(*hbp));
while( sbp < sep )
{
assert( *sbp < hn );
++hbp[ *sbp++ ];
}
return rp;
}
unsigned* cmVOU_Random( unsigned* vbp, unsigned vn, unsigned maxValue )
{
unsigned* rp = vbp;
const unsigned* vep = vbp + vn;
while( vbp < vep )
*vbp++ = rand() % (maxValue+1);
return rp;
}
unsigned* cmVOU_UniqueRandom( unsigned* dV, unsigned dN, unsigned maxValue )
{
assert( dN < maxValue );
if( dN == 0 )
return dV;
// if maxValue is less than twice dN then use cmVOU_RandomSeq() to
// generate the random numbers. This is intended to avoid a situation
// where the attempt to generate a unique random number is confined
// to an decreasing range of possible target values - as would occur
// if dN==maxValue.
if( maxValue / dN <= 2 )
{
unsigned* v = cmMemAllocZ( unsigned, maxValue+1 );
cmVOU_RandomSeq(v,maxValue+1);
cmVOU_Copy(dV,dN,v);
cmMemPtrFree(&v);
}
unsigned* tV = cmMemAllocZ( unsigned, dN );
unsigned i = 0;
unsigned j = 0;
unsigned n = dN;
while(n)
{
// generate a set of random integers
cmVOU_Random(tV,n,maxValue);
// store each unique random int
for(j=0; j<n; ++j)
if( cmVOU_Count(dV,i,tV[j]) == 0 )
dV[i++] = tV[j];
n = dN - i;
}
cmMemPtrFree(&tV);
return dV;
}
int cmVOU_Compare(const void* p0, const void* p1)
{ return *(unsigned*)p0 < *(unsigned*)p1; }
unsigned* cmVOU_RandomSeq( unsigned* vbp, unsigned vn )
{
unsigned i,j;
unsigned* r = cmMemAllocZ( unsigned, vn );
// generate a list of random values
for(i=0; i<vn; ++i)
{
r[i] = rand();
vbp[i] = r[i];
}
// sort the random number list
qsort(r,vn,sizeof(unsigned),cmVOU_Compare);
// set vbp[i] to the index of the matching value in r[]
for(i=0; i<vn; ++i)
for(j=0; j<vn; ++j)
if( vbp[i] == r[j] )
{
vbp[i] = j;
break;
}
cmMemPtrFree(&r);
return vbp;
}
cmReal_t cmVOU_Mean(const unsigned* sp, unsigned sn )
{
cmReal_t sum = (cmReal_t)cmVOU_Sum(sp,sn);
return sum/sn;
}
cmReal_t cmVOU_Variance(const unsigned* sp, unsigned sn, const cmReal_t* meanPtr)
{
if( sn <= 1 )
return 0;
cmReal_t sum = 0;
cmReal_t mv = meanPtr==NULL ? cmVOU_Mean(sp,sn) : *meanPtr;
const unsigned* bp = sp;
const unsigned* ep = sp + sn;
for(; bp < ep; ++bp )
sum += (((cmReal_t)*bp)-mv) * (((cmReal_t)*bp)-mv);
return sum / (sn-1);
}
cmReal_t cmVOI_Mean(const int* sp, unsigned sn )
{
cmReal_t sum = (cmReal_t)cmVOI_Sum(sp,sn);
return sum/sn;
}
cmReal_t cmVOI_Variance(const int* sp, unsigned sn, const cmReal_t* meanPtr)
{
if( sn <= 1 )
return 0;
cmReal_t sum = 0;
cmReal_t mv = meanPtr==NULL ? cmVOI_Mean(sp,sn) : *meanPtr;
const int* bp = sp;
const int* ep = sp + sn;
for(; bp < ep; ++bp )
sum += (((cmReal_t)*bp)-mv) * (((cmReal_t)*bp)-mv);
return sum / (sn-1);
}
// dbp[1,dn] = v[1,vn] * m[vn,dn]
cmComplexR_t* cmVORC_MultVVM( cmComplexR_t* dbp, unsigned dn, const cmComplexR_t* vp, unsigned vn, const cmComplexR_t* mp )
{
cmComplexR_t alpha = 1.0 + (I*0);
cmComplexR_t beta = 0.0 + (I*0);
unsigned drn = 1;
unsigned dcn = dn;
unsigned n = vn;
cblas_zgemm( CblasColMajor, CblasNoTrans, CblasNoTrans, drn, dcn, n, &alpha, vp, drn, mp, n, &beta, dbp, drn );
return dbp;
}