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/**CFile****************************************************************
FileName [fxuPrint.c]
PackageName [MVSIS 2.0: Multi-valued logic synthesis system.]
Synopsis [Various printing procedures.]
Author [MVSIS Group]
Affiliation [UC Berkeley]
Date [Ver. 1.0. Started - February 1, 2003.]
Revision [$Id: fxuPrint.c,v 1.0 2003/02/01 00:00:00 alanmi Exp $]
***********************************************************************/
#include "fxuInt.h"
////////////////////////////////////////////////////////////////////////
/// DECLARATIONS ///
////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////
/// FUNCTION DEFINITIONS ///
////////////////////////////////////////////////////////////////////////
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Fxu_MatrixPrint( FILE * pFile, Fxu_Matrix * p )
{
Fxu_Var * pVar;
Fxu_Cube * pCube;
Fxu_Double * pDiv;
Fxu_Single * pSingle;
Fxu_Lit * pLit;
Fxu_Pair * pPair;
int i, LastNum;
int fStdout;
fStdout = 1;
if ( pFile == NULL )
{
pFile = fopen( "matrix.txt", "w" );
fStdout = 0;
}
fprintf( pFile, "Matrix has %d vars, %d cubes, %d literals, %d divisors.\n",
p->lVars.nItems, p->lCubes.nItems, p->nEntries, p->nDivs );
fprintf( pFile, "Divisors selected so far: single = %d, double = %d.\n",
p->nDivs1, p->nDivs2 );
fprintf( pFile, "\n" );
// print the numbers on top of the matrix
for ( i = 0; i < 12; i++ )
fprintf( pFile, " " );
Fxu_MatrixForEachVariable( p, pVar )
fprintf( pFile, "%d", pVar->iVar % 10 );
fprintf( pFile, "\n" );
// print the rows
Fxu_MatrixForEachCube( p, pCube )
{
fprintf( pFile, "%4d", pCube->iCube );
fprintf( pFile, " " );
fprintf( pFile, "%4d", pCube->pVar->iVar );
fprintf( pFile, " " );
// print the literals
LastNum = -1;
Fxu_CubeForEachLiteral( pCube, pLit )
{
for ( i = LastNum + 1; i < pLit->pVar->iVar; i++ )
fprintf( pFile, "." );
fprintf( pFile, "1" );
LastNum = i;
}
for ( i = LastNum + 1; i < p->lVars.nItems; i++ )
fprintf( pFile, "." );
fprintf( pFile, "\n" );
}
fprintf( pFile, "\n" );
// print the double-cube divisors
fprintf( pFile, "The double divisors are:\n" );
Fxu_MatrixForEachDouble( p, pDiv, i )
{
fprintf( pFile, "Divisor #%3d (lit=%d,%d) (w=%2d): ",
pDiv->Num, pDiv->lPairs.pHead->nLits1,
pDiv->lPairs.pHead->nLits2, pDiv->Weight );
Fxu_DoubleForEachPair( pDiv, pPair )
fprintf( pFile, " <%d, %d> (b=%d)",
pPair->pCube1->iCube, pPair->pCube2->iCube, pPair->nBase );
fprintf( pFile, "\n" );
}
fprintf( pFile, "\n" );
// print the divisors associated with each cube
fprintf( pFile, "The cubes are:\n" );
Fxu_MatrixForEachCube( p, pCube )
{
fprintf( pFile, "Cube #%3d: ", pCube->iCube );
if ( pCube->pVar->ppPairs )
Fxu_CubeForEachPair( pCube, pPair, i )
fprintf( pFile, " <%d %d> (d=%d) (b=%d)",
pPair->iCube1, pPair->iCube2, pPair->pDiv->Num, pPair->nBase );
fprintf( pFile, "\n" );
}
fprintf( pFile, "\n" );
// print the single-cube divisors
fprintf( pFile, "The single divisors are:\n" );
Fxu_MatrixForEachSingle( p, pSingle )
{
fprintf( pFile, "Single-cube divisor #%5d: Var1 = %4d. Var2 = %4d. Weight = %2d\n",
pSingle->Num, pSingle->pVar1->iVar, pSingle->pVar2->iVar, pSingle->Weight );
}
fprintf( pFile, "\n" );
/*
{
int Index;
fprintf( pFile, "Distribution of divisors in the hash table:\n" );
for ( Index = 0; Index < p->nTableSize; Index++ )
fprintf( pFile, " %d", p->pTable[Index].nItems );
fprintf( pFile, "\n" );
}
*/
if ( !fStdout )
fclose( pFile );
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Fxu_MatrixPrintDivisorProfile( FILE * pFile, Fxu_Matrix * p )
{
Fxu_Double * pDiv;
int WeightMax;
int * pProfile;
int Counter1; // the number of -1 weight
int CounterL; // the number of less than -1 weight
int i;
WeightMax = Fxu_HeapDoubleReadMaxWeight( p->pHeapDouble );
pProfile = ABC_ALLOC( int, (WeightMax + 1) );
memset( pProfile, 0, sizeof(int) * (WeightMax + 1) );
Counter1 = 0;
CounterL = 0;
Fxu_MatrixForEachDouble( p, pDiv, i )
{
assert( pDiv->Weight <= WeightMax );
if ( pDiv->Weight == -1 )
Counter1++;
else if ( pDiv->Weight < 0 )
CounterL++;
else
pProfile[ pDiv->Weight ]++;
}
fprintf( pFile, "The double divisors profile:\n" );
fprintf( pFile, "Weight < -1 divisors = %6d\n", CounterL );
fprintf( pFile, "Weight -1 divisors = %6d\n", Counter1 );
for ( i = 0; i <= WeightMax; i++ )
if ( pProfile[i] )
fprintf( pFile, "Weight %3d divisors = %6d\n", i, pProfile[i] );
fprintf( pFile, "End of divisor profile printout\n" );
ABC_FREE( pProfile );
}
////////////////////////////////////////////////////////////////////////
/// END OF FILE ///
////////////////////////////////////////////////////////////////////////
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