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|
/**CFile****************************************************************
FileName [lucky.c]
SystemName [ABC: Logic synthesis and verification system.]
PackageName [Semi-canonical form computation package.]
Synopsis [Truth table minimization procedures.]
Author [Jake]
Date [Started - August 2012]
***********************************************************************/
#include "luckyInt.h"
ABC_NAMESPACE_IMPL_START
int memCompare(word* x, word* y, int nVars)
{
int i;
for(i=Kit_TruthWordNum_64bit( nVars )-1;i>=0;i--)
{
if(x[i]==y[i])
continue;
else if(x[i]>y[i])
return 1;
else
return -1;
}
return 0;
}
///////sort Word* a///////////////////////////////////////////////////////////////////////////////////////////////////////
int compareWords1 (const void * a, const void * b)
{
if( *(word*)a > *(word*)b )
return 1;
else
return( *(word*)a < *(word*)b ) ? -1: 0;
}
void sortAndUnique1(word* a, Abc_TtStore_t* p)
{
int i, count=1, WordsN = p->nFuncs;
word tempWord;
qsort(a,WordsN,sizeof(word),compareWords1);
tempWord = a[0];
for(i=1;i<WordsN;i++)
if(tempWord != a[i])
{
a[count] = a[i];
tempWord = a[i];
count++;
}
p->nFuncs = count;
}
//////////sort Word** a//////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
int compareWords2 (const void ** x, const void ** y)
{
if(**(word**)x > **(word**)y)
return 1;
else if(**(word**)x < **(word**)y)
return -1;
else
return 0;
}
int compareWords (const void ** a, const void ** b)
{
if( memcmp(*(word**)a,*(word**)b,sizeof(word)*1) > 0 )
return 1;
else
return ( memcmp(*(word**)a,*(word**)b,sizeof(word)*1) < 0 ) ? -1: 0;
}
int compareWords3 (const void ** x, const void ** y)
{
return memCompare(*(word**)x, *(word**)y, 16);
}
void sortAndUnique(word** a, Abc_TtStore_t* p)
{
int i, count=1, WordsPtrN = p->nFuncs;
word* tempWordPtr;
qsort(a,WordsPtrN,sizeof(word*),(int(*)(const void *,const void *))compareWords3);
tempWordPtr = a[0];
for(i=1;i<WordsPtrN;i++)
if(memcmp(a[i],tempWordPtr,sizeof(word)*(p->nWords)) != 0)
{
a[count] = a[i];
tempWordPtr = a[i];
count++;
}
p->nFuncs = count;
}
///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
typedef struct
{
int totalCycles;
int maxNCycles;
int minNCycles;
}cycleCtr;
cycleCtr* setCycleCtrPtr()
{
cycleCtr* x = (cycleCtr*) malloc(sizeof(cycleCtr));
x->totalCycles=0;
x->maxNCycles=0;
x->minNCycles=111111111;
return x;
}
void freeCycleCtr(cycleCtr* x)
{
free(x);
}
word** makeArray(Abc_TtStore_t* p)
{
int i;
word** a;
a = (word**)malloc(sizeof(word*)*(p->nFuncs));
for(i=0;i<p->nFuncs;i++)
{
a[i] = (word*)malloc(sizeof(word)*(p->nWords));
memcpy(a[i],p->pFuncs[i],sizeof(word)*(p->nWords));
}
return a;
}
void freeArray(word** a,Abc_TtStore_t* p)
{
int i;
for(i=0;i<p->nFuncs;i++)
free(a[i]);
free(a);
}
word* makeArrayB(word** a, int nFuncs)
{
int i;
word* b;
b = (word*)malloc(sizeof(word)*(nFuncs));
for(i=0;i<nFuncs;i++)
b[i] = a[i][0];
return b;
}
void freeArrayB(word* b)
{
free(b);
}
////////////////////////////////////////////////////////////////////////////////////////
// if highest bit in F ( all ones min term ) is one => inverse
// if pInOnt changed(minimized) by function return 1 if not 0
// int minimalInitialFlip_propper(word* pInOut, word* pDuplicat, int nVars)
// {
// word oneWord=1;
// Kit_TruthCopy_64bit( pDuplicat, pInOut, nVars );
// Kit_TruthNot_64bit( pDuplicat, nVars );
// if( memCompare(pDuplicat,pInOut,nVars) == -1)
// {
// Kit_TruthCopy_64bit(pInOut, pDuplicat, nVars );
// return 1;
// }
// return 0;
// }
// int minimalFlip(word* pInOut, word* pMinimal, word* PDuplicat, int nVars)
// {
// int i;
// int blockSize = Kit_TruthWordNum_64bit( nVars )*sizeof(word);
// memcpy(pMinimal, pInOut, blockSize);
// memcpy(PDuplicat, pInOut, blockSize);
// for(i=0;i<nVars;i++)
// {
// Kit_TruthChangePhase_64bit( pInOut, nVars, i );
// if( memCompare(pMinimal,pInOut,nVars) == 1)
// memcpy(pMinimal, pInOut, blockSize);
// memcpy(pInOut,PDuplicat,blockSize);
// }
// memcpy(pInOut,pMinimal,blockSize);
// if(memCompare(pMinimal,PDuplicat,nVars) == 0)
// return 0;
// else
// return 1;
// }
// int minimalSwap(word* pInOut, word* pMinimal, word* PDuplicat, int nVars)
// {
// int i;
// int blockSize = Kit_TruthWordNum_64bit( nVars )*sizeof(word);
// memcpy(pMinimal, pInOut, blockSize);
// memcpy(PDuplicat, pInOut, blockSize);
// for(i=0;i<nVars-1;i++)
// {
// Kit_TruthSwapAdjacentVars_64bit( pInOut, nVars, i );
// if(memCompare(pMinimal,pInOut,nVars) == 1)
// memcpy(pMinimal, pInOut, blockSize);
// memcpy(pInOut,PDuplicat,blockSize);
// }
// memcpy(pInOut,pMinimal,blockSize);
// if(memCompare(pMinimal,PDuplicat,nVars) == 0)
// return 0;
// else
// return 1;
// }
//
// void luckyCanonicizer(word* pInOut, word* pAux, word* pAux1, int nVars, cycleCtr* cCtr)
// {
// int counter=1, cycles=0;
// assert( nVars <= 16 );
// while(counter>0 ) // && cycles < 10 if we wanna limit cycles
// {
// counter=0;
// counter += minimalInitialFlip(pInOut, nVars);
// counter += minimalFlip(pInOut, pAux, pAux1, nVars);
// counter += minimalSwap(pInOut, pAux, pAux1, nVars);
// cCtr->totalCycles++;
// cycles++;
// }
// if(cycles < cCtr->minNCycles)
// cCtr->minNCycles = cycles;
// else if(cycles > cCtr->maxNCycles)
// cCtr->maxNCycles = cycles;
// }
// runs paralel F and ~F in luckyCanonicizer
// void luckyCanonicizer2(word* pInOut, word* pAux, word* pAux1, word* temp, int nVars)
// {
// int nWords = Kit_TruthWordNum_64bit( nVars );
// int counter=1, nOnes;
// assert( nVars <= 16 );
// nOnes = Kit_TruthCountOnes_64bit(pInOut, nVars);
//
// if ( (nOnes*2 == nWords * 32) )
// {
// Kit_TruthCopy_64bit( temp, pInOut, nVars );
// Kit_TruthNot_64bit( temp, nVars );
// luckyCanonicizer1_simple(pInOut, pAux, pAux1, nVars);
// luckyCanonicizer1_simple(temp, pAux, pAux1, nVars);
// if( memCompare(temp,pInOut,nVars) == -1)
// Kit_TruthCopy_64bit(pInOut, temp, nVars );
// return;
// }
// while(counter>0 ) // && cycles < 10 if we wanna limit cycles
// {
// counter=0;
// counter += minimalInitialFlip_propper(pInOut, pAux, nVars);
// counter += minimalFlip1(pInOut, pAux, pAux1, nVars);
// counter += minimalSwap1(pInOut, pAux, pAux1, nVars);
// }
// }
// same as luckyCanonicizer + cycleCtr stutistics
// void luckyCanonicizer1(word* pInOut, word* pAux, word* pAux1, int nVars, cycleCtr* cCtr)
// {
// int counter=1, cycles=0;
// assert( nVars <= 16 );
// while(counter>0 ) // && cycles < 10 if we wanna limit cycles
// {
// counter=0;
// counter += minimalInitialFlip1(pInOut, nVars);
// counter += minimalFlip1(pInOut, pAux, pAux1, nVars);
// counter += minimalSwap1(pInOut, pAux, pAux1, nVars);
// cCtr->totalCycles++;
// cycles++;
// }
// if(cycles < cCtr->minNCycles)
// cCtr->minNCycles = cycles;
// else if(cycles > cCtr->maxNCycles)
// cCtr->maxNCycles = cycles;
// }
// luckyCanonicizer
void printCCtrInfo(cycleCtr* cCtr, int nFuncs)
{
printf("maxNCycles = %d\n",cCtr->maxNCycles);
printf("minNCycles = %d\n",cCtr->minNCycles);
printf("average NCycles = %.3f\n",cCtr->totalCycles/(double)nFuncs);
}
////////////////////////////////////////New Faster versoin/////////////////////////////////////////////////////////
// if highest bit in F ( all ones min term ) is one => inverse
// returns: if pInOnt changed(minimized) by function return 1 if not 0
int minimalInitialFlip1(word* pInOut, int nVars)
{
word oneWord=1;
if( (pInOut[Kit_TruthWordNum_64bit( nVars ) -1]>>63) & oneWord )
{
Kit_TruthNot_64bit( pInOut, nVars );
return 1;
}
return 0;
}
// compare F with F1 = (F with changed phase in one of the vars).
// keeps smaller.
// same for all vars in F.
// returns: if pInOnt changed(minimized) by function return 1 if not 0
int minimalFlip1(word* pInOut, word* pMinimal, word* PDuplicat, int nVars)
{
int i;
int blockSize = Kit_TruthWordNum_64bit( nVars )*sizeof(word);
memcpy(pMinimal, pInOut, blockSize);
memcpy(PDuplicat, pInOut, blockSize);
Kit_TruthChangePhase_64bit( pInOut, nVars, 0 );
for(i=1;i<nVars;i++)
{
if( memCompare(pMinimal,pInOut,nVars) == 1)
{
memcpy(pMinimal, pInOut, blockSize);
Kit_TruthChangePhase_64bit( pInOut, nVars, i );
}
else
{
memcpy(pInOut, pMinimal, blockSize);
Kit_TruthChangePhase_64bit( pInOut, nVars, i );
}
}
if( memCompare(pMinimal,pInOut,nVars) == -1)
memcpy(pInOut, pMinimal, blockSize);
if(memcmp(pInOut,PDuplicat,blockSize) == 0)
return 0;
else
return 1;
}
// compare F with F1 = (F with swapped two adjacent vars).
// keeps smaller.
// same for all vars in F.
// returns: if pInOnt changed(minimized) by function return 1 if not 0
int minimalSwap1(word* pInOut, word* pMinimal, word* PDuplicat, int nVars)
{
int i;
int blockSize = Kit_TruthWordNum_64bit( nVars )*sizeof(word);
memcpy(pMinimal, pInOut, blockSize);
memcpy(PDuplicat, pInOut, blockSize);
Kit_TruthSwapAdjacentVars_64bit( pInOut, nVars, 0 );
for(i=1;i<nVars-1;i++)
{
if( memCompare(pMinimal,pInOut,nVars) == 1)
{
memcpy(pMinimal, pInOut, blockSize);
Kit_TruthSwapAdjacentVars_64bit( pInOut, nVars, i );
}
else
{
memcpy(pInOut, pMinimal, blockSize);
Kit_TruthSwapAdjacentVars_64bit( pInOut, nVars, i );
}
}
if( memCompare(pMinimal,pInOut,nVars) == -1)
memcpy(pInOut, pMinimal, blockSize);
if(memcmp(pInOut,PDuplicat,blockSize) == 0)
return 0;
else
return 1;
}
// if highest bit in F ( all ones min term ) is one => inverse
// returns: if pInOnt changed(minimized) by function return 1 if not 0
int minimalInitialFlip(word* pInOut, int nVars, unsigned* p_uCanonPhase)
{
word oneWord=1;
if( (pInOut[Kit_TruthWordNum_64bit( nVars ) -1]>>63) & oneWord )
{
Kit_TruthNot_64bit( pInOut, nVars );
*p_uCanonPhase ^= (1 << nVars);
return 1;
}
return 0;
}
// compare F with F1 = (F with changed phase in one of the vars).
// keeps smaller.
// same for all vars in F.
// returns: if pInOnt changed(minimized) by function return 1 if not 0
int minimalFlip(word* pInOut, word* pMinimal, word* PDuplicat, int nVars, unsigned* p_uCanonPhase)
{
int i;
unsigned minTemp = *p_uCanonPhase;
int blockSize = Kit_TruthWordNum_64bit( nVars )*sizeof(word);
memcpy(pMinimal, pInOut, blockSize);
memcpy(PDuplicat, pInOut, blockSize); //////////////need one more unsigned!!!!!!!!!!!!!
Kit_TruthChangePhase_64bit( pInOut, nVars, 0 );
*p_uCanonPhase ^= (unsigned)1;
for(i=1;i<nVars;i++)
{
if( memCompare(pMinimal,pInOut,nVars) == 1)
{
memcpy(pMinimal, pInOut, blockSize);
minTemp = *p_uCanonPhase;
}
else
{
memcpy(pInOut, pMinimal, blockSize);
*p_uCanonPhase = minTemp;
}
Kit_TruthChangePhase_64bit( pInOut, nVars, i );
*p_uCanonPhase ^= (1 << i);
}
if( memCompare(pMinimal,pInOut,nVars) == -1)
{
memcpy(pInOut, pMinimal, blockSize);
*p_uCanonPhase = minTemp;
}
if(memcmp(pInOut,PDuplicat,blockSize) == 0)
return 0;
else
return 1;
}
// swaps iVar and iVar+1 elements in pCanonPerm ant p_uCanonPhase
void swapInfoAdjacentVars(int iVar, char * pCanonPerm, unsigned* p_uCanonPhase)
{
char Temp = pCanonPerm[iVar];
pCanonPerm[iVar] = pCanonPerm[iVar+1];
pCanonPerm[iVar+1] = Temp;
// if the polarity of variables is different, swap them
if ( ((*p_uCanonPhase & (1 << iVar)) > 0) != ((*p_uCanonPhase & (1 << (iVar+1))) > 0) )
{
*p_uCanonPhase ^= (1 << iVar);
*p_uCanonPhase ^= (1 << (iVar+1));
}
}
// compare F with F1 = (F with swapped two adjacent vars).
// keeps smaller.
// same for all vars in F.
// returns: if pInOnt changed(minimized) by function return 1 if not 0
/*
// this version is buggy and is fixed below
int minimalSwap(word* pInOut, word* pMinimal, word* PDuplicat, int nVars, char * pCanonPerm, char * tempArray, unsigned* p_uCanonPhase)
{
int i;
int blockSizeWord = Kit_TruthWordNum_64bit( nVars )*sizeof(word);
int blockSizeChar = nVars *sizeof(char);
memcpy(pMinimal, pInOut, blockSizeWord);
memcpy(PDuplicat, pInOut, blockSizeWord);
memcpy(tempArray, pCanonPerm, blockSizeChar);
Kit_TruthSwapAdjacentVars_64bit( pInOut, nVars, 0 );
swapInfoAdjacentVars(0, pCanonPerm, p_uCanonPhase);
for(i=1;i<nVars-1;i++)
{
if( memCompare(pMinimal,pInOut,nVars) == 1)
{
memcpy(pMinimal, pInOut, blockSizeWord);
memcpy(tempArray, pCanonPerm, blockSizeChar);
}
else
{
memcpy(pInOut, pMinimal, blockSizeWord);
memcpy(pCanonPerm, tempArray, blockSizeChar);
}
Kit_TruthSwapAdjacentVars_64bit( pInOut, nVars, i );
swapInfoAdjacentVars(i, pCanonPerm, p_uCanonPhase);
}
if( memCompare(pMinimal,pInOut,nVars) == -1)
{
memcpy(pInOut, pMinimal, blockSizeWord);
memcpy(pCanonPerm, tempArray, blockSizeChar);
}
if(memcmp(pInOut,PDuplicat,blockSizeWord) == 0)
return 0;
else
return 1;
}
*/
int minimalSwap(word* pInOut, word* pMinimal, word* PDuplicat, int nVars, char * pCanonPerm, char * tempArray, unsigned* p_uCanonPhase)
{
int i;
int blockSizeWord = Kit_TruthWordNum_64bit( nVars )*sizeof(word);
int blockSizeChar = nVars *sizeof(char);
unsigned TempuCanonPhase = *p_uCanonPhase;
memcpy(pMinimal, pInOut, blockSizeWord);
memcpy(PDuplicat, pInOut, blockSizeWord);
memcpy(tempArray, pCanonPerm, blockSizeChar);
Kit_TruthSwapAdjacentVars_64bit( pInOut, nVars, 0 );
swapInfoAdjacentVars(0, pCanonPerm, p_uCanonPhase);
for(i=1;i<nVars-1;i++)
{
if( memCompare(pMinimal,pInOut,nVars) == 1)
{
memcpy(pMinimal, pInOut, blockSizeWord);
memcpy(tempArray, pCanonPerm, blockSizeChar);
TempuCanonPhase = *p_uCanonPhase;
}
else
{
memcpy(pInOut, pMinimal, blockSizeWord);
memcpy(pCanonPerm, tempArray, blockSizeChar);
*p_uCanonPhase = TempuCanonPhase;
}
Kit_TruthSwapAdjacentVars_64bit( pInOut, nVars, i );
swapInfoAdjacentVars(i, pCanonPerm, p_uCanonPhase);
}
if( memCompare(pMinimal,pInOut,nVars) == -1)
{
memcpy(pInOut, pMinimal, blockSizeWord);
memcpy(pCanonPerm, tempArray, blockSizeChar);
*p_uCanonPhase = TempuCanonPhase;
}
if(memcmp(pInOut,PDuplicat,blockSizeWord) == 0)
return 0;
else
return 1;
}
//////////////// functions below just for Alan if he want to double check my program//////////////////////////////////
/////////////////You need swap_ij function or analogical one//////////////////////////////////////////////////////////
/*
void swapAndFlip(word* pAfter, int nVars, int iVarInPosition, int jVar, char * pCanonPerm, unsigned* pUCanonPhase)
{
int Temp;
swap_ij(pAfter, nVars, iVarInPosition, jVar);
Temp = pCanonPerm[iVarInPosition];
pCanonPerm[iVarInPosition] = pCanonPerm[jVar];
pCanonPerm[jVar] = Temp;
if ( ((*pUCanonPhase & (1 << iVarInPosition)) > 0) != ((*pUCanonPhase & (1 << jVar)) > 0) )
{
*pUCanonPhase ^= (1 << iVarInPosition);
*pUCanonPhase ^= (1 << jVar);
}
if(*pUCanonPhase>>iVarInPosition & (unsigned)1 == 1)
Kit_TruthChangePhase_64bit( pAfter, nVars, iVarInPosition );
}
int luckyCheck(word* pAfter, word* pBefore, int nVars, char * pCanonPerm, unsigned uCanonPhase)
{
int i,j;
char tempChar;
for(j=0;j<nVars;j++)
{
tempChar = 'a'+ j;
for(i=j;i<nVars;i++)
{
if(tempChar != pCanonPerm[i])
continue;
swapAndFlip(pAfter , nVars, j, i, pCanonPerm, &uCanonPhase);
break;
}
}
if(uCanonPhase>>nVars & (unsigned)1 == 1)
Kit_TruthNot_64bit(pAfter, nVars );
if(memcmp(pAfter, pBefore, Kit_TruthWordNum_64bit( nVars )*sizeof(word)) == 0)
return 0;
else
return 1;
}
*/
//////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
void luckyCanonicizer(word* pInOut, word* pAux, word* pAux1, int nVars, char * pCanonPerm, char * tempArray, unsigned* p_uCanonPhase)
{
int counter=1;
assert( nVars <= 16 );
while(counter>0 ) // && cycles < 10 if we wanna limit cycles
{
counter=0;
counter += minimalInitialFlip(pInOut, nVars, p_uCanonPhase);
counter += minimalFlip(pInOut, pAux, pAux1, nVars, p_uCanonPhase);
counter += minimalSwap(pInOut, pAux, pAux1, nVars, pCanonPerm, tempArray, p_uCanonPhase);
}
}
// tries to find minimal F till F at the beginning of the loop is the same as at the end - irreducible
unsigned luckyCanonicizer1_simple(word* pInOut, word* pAux, word* pAux1, int nVars, char * pCanonPerm, unsigned CanonPhase)
{
int counter=1;
assert( nVars <= 16 );
while(counter>0 ) // && cycles < 10 if we wanna limit cycles
{
counter=0;
counter += minimalInitialFlip1(pInOut, nVars);
counter += minimalFlip1(pInOut, pAux, pAux1, nVars);
counter += minimalSwap1(pInOut, pAux, pAux1, nVars);
}
return CanonPhase;
}
void luckyCanonicizer_final(word* pInOut, word* pAux, word* pAux1, int nVars)
{
Kit_TruthSemiCanonicize_Yasha_simple( pInOut, nVars, NULL );
luckyCanonicizer1_simple(pInOut, pAux, pAux1, nVars, NULL, 0);
}
// this procedure calls internal canoniziers
// it returns canonical phase (as return value) and canonical permutation (in pCanonPerm)
unsigned Kit_TruthSemiCanonicize_new_internal( word * pInOut, int nVars, char * pCanonPerm )
{
word pAux[1024], pAux1[1024];
char tempArray[16];
unsigned CanonPhase;
assert( nVars <= 16 );
CanonPhase = Kit_TruthSemiCanonicize_Yasha( pInOut, nVars, pCanonPerm );
luckyCanonicizer(pInOut, pAux, pAux1, nVars, pCanonPerm, tempArray, &CanonPhase);
return CanonPhase;
}
// this procedure is translates truth table from 'unsingeds' into 'words'
unsigned Kit_TruthSemiCanonicize_new( unsigned * pInOut, unsigned * pAux, int nVars, char * pCanonPerm )
{
unsigned Result;
if ( nVars < 6 )
{
word Temp = ((word)pInOut[0] << 32) | (word)pInOut[0];
Result = Kit_TruthSemiCanonicize_new_internal( &Temp, nVars, pCanonPerm );
pInOut[0] = (unsigned)Temp;
}
else
Result = Kit_TruthSemiCanonicize_new_internal( (word *)pInOut, nVars, pCanonPerm );
return Result;
}
// compile main() procedure only if running outside of ABC environment
#ifndef _RUNNING_ABC_
int main ()
{
// char * pFileInput = "nonDSDfunc06var1M.txt";
// char * pFileInput1 = "partDSDfunc06var1M.txt";
// char * pFileInput2 = "fullDSDfunc06var1M.txt";
// char * pFileInput = "nonDSDfunc10var100K.txt";
// char * pFileInput1 = "partDSDfunc10var100K.txt";
// char * pFileInput2 = "fullDSDfunc10var100K.txt";
// char * pFileInput = "partDSDfunc12var100K.txt";
// char * pFileInput = "nonDSDfunc12var100K.txt";
// char * pFileInput1 = "partDSDfunc12var100K.txt";
// char * pFileInput2 = "fullDSDfunc12var100K.txt";
// char * pFileInput = "nonDSDfunc14var10K.txt";
// char * pFileInput1 = "partDSDfunc14var10K.txt";
// char * pFileInput2 = "fullDSDfunc14var10K.txt";
char * pFileInput = "nonDSDfunc16var10K.txt";
char * pFileInput1 = "partDSDfunc16var10K.txt";
char * pFileInput2 = "fullDSDfunc16var10K.txt";
int i, j, tempNF;
char** charArray;
word** a, ** b;
Abc_TtStore_t* p;
word * pAux, * pAux1;
int * pStore;
// cycleCtr* cCtr;
charArray = (char**)malloc(sizeof(char*)*3);
charArray[0] = pFileInput;
charArray[1] = pFileInput1;
charArray[2] = pFileInput2;
for(j=0;j<3;j++)
{
p = setTtStore(charArray[j]);
// p = setTtStore(pFileInput);
a = makeArray(p);
b = makeArray(p);
// cCtr = setCycleCtrPtr();
pAux = (word*)malloc(sizeof(word)*(p->nWords));
pAux1 = (word*)malloc(sizeof(word)*(p->nWords));
pStore = (int*)malloc(sizeof(int)*(p->nVars));
printf("In %s Fs at start = %d\n",charArray[j],p->nFuncs);
tempNF = p->nFuncs;
TimePrint("start");
for(i=0;i<p->nFuncs;i++)
luckyCanonicizer_final(a[i], pAux, pAux1, p->nVars, pStore);
TimePrint("done with A");
sortAndUnique(a, p);
printf("F left in A final = %d\n",p->nFuncs);
freeArray(a,p);
TimePrint("Done with sort");
// delete data-structures
free(pAux);
free(pAux1);
free(pStore);
// freeCycleCtr(cCtr);
Abc_TruthStoreFree( p );
}
return 0;
}
#endif
ABC_NAMESPACE_IMPL_END
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