/**CFile**************************************************************** FileName [fxuCreate.c] PackageName [MVSIS 2.0: Multi-valued logic synthesis system.] Synopsis [Create matrix from covers and covers from matrix.] Author [MVSIS Group] Affiliation [UC Berkeley] Date [Ver. 1.0. Started - February 1, 2003.] Revision [$Id: fxuCreate.c,v 1.0 2003/02/01 00:00:00 alanmi Exp $] ***********************************************************************/ #include "fxuInt.h" #include "fxu.h" ABC_NAMESPACE_IMPL_START //////////////////////////////////////////////////////////////////////// /// DECLARATIONS /// //////////////////////////////////////////////////////////////////////// static void Fxu_CreateMatrixAddCube( Fxu_Matrix * p, Fxu_Cube * pCube, char * pSopCube, Vec_Int_t * vFanins, int * pOrder ); static int Fxu_CreateMatrixLitCompare( int * ptrX, int * ptrY ); static void Fxu_CreateCoversNode( Fxu_Matrix * p, Fxu_Data_t * pData, int iNode, Fxu_Cube * pCubeFirst, Fxu_Cube * pCubeNext ); static Fxu_Cube * Fxu_CreateCoversFirstCube( Fxu_Matrix * p, Fxu_Data_t * pData, int iNode ); static int * s_pLits; extern int Fxu_PreprocessCubePairs( Fxu_Matrix * p, Vec_Ptr_t * vCovers, int nPairsTotal, int nPairsMax ); //////////////////////////////////////////////////////////////////////// /// FUNCTION DEFINITIONS /// //////////////////////////////////////////////////////////////////////// /**Function************************************************************* Synopsis [Creates the sparse matrix from the array of SOPs.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ Fxu_Matrix * Fxu_CreateMatrix( Fxu_Data_t * pData ) { Fxu_Matrix * p; Fxu_Var * pVar; Fxu_Cube * pCubeFirst, * pCubeNew; Fxu_Cube * pCube1, * pCube2; Vec_Int_t * vFanins; char * pSopCover; char * pSopCube; int * pOrder, nBitsMax; int i, v, c; int nCubesTotal; int nPairsTotal; int nPairsStore; int nCubes; int iCube, iPair; int nFanins; // collect all sorts of statistics nCubesTotal = 0; nPairsTotal = 0; nPairsStore = 0; nBitsMax = -1; for ( i = 0; i < pData->nNodesOld; i++ ) if ( (pSopCover = (char *)pData->vSops->pArray[i]) ) { nCubes = Abc_SopGetCubeNum( pSopCover ); nFanins = Abc_SopGetVarNum( pSopCover ); assert( nFanins > 1 && nCubes > 0 ); nCubesTotal += nCubes; nPairsTotal += nCubes * (nCubes - 1) / 2; nPairsStore += nCubes * nCubes; if ( nBitsMax < nFanins ) nBitsMax = nFanins; } if ( nBitsMax <= 0 ) { printf( "The current network does not have SOPs to perform extraction.\n" ); return NULL; } if ( nPairsStore > 50000000 ) { printf( "The problem is too large to be solved by \"fxu\" (%d cubes and %d cube pairs)\n", nCubesTotal, nPairsStore ); return NULL; } // start the matrix p = Fxu_MatrixAllocate(); // create the column labels p->ppVars = ABC_ALLOC( Fxu_Var *, 2 * (pData->nNodesOld + pData->nNodesExt) ); for ( i = 0; i < 2 * pData->nNodesOld; i++ ) p->ppVars[i] = Fxu_MatrixAddVar( p ); // allocate storage for all cube pairs at once p->pppPairs = ABC_ALLOC( Fxu_Pair **, nCubesTotal + 100 ); p->ppPairs = ABC_ALLOC( Fxu_Pair *, nPairsStore + 100 ); memset( p->ppPairs, 0, sizeof(Fxu_Pair *) * nPairsStore ); iCube = 0; iPair = 0; for ( i = 0; i < pData->nNodesOld; i++ ) if ( (pSopCover = (char *)pData->vSops->pArray[i]) ) { // get the number of cubes nCubes = Abc_SopGetCubeNum( pSopCover ); // get the new var in the matrix pVar = p->ppVars[2*i+1]; // assign the pair storage pVar->nCubes = nCubes; if ( nCubes > 0 ) { pVar->ppPairs = p->pppPairs + iCube; pVar->ppPairs[0] = p->ppPairs + iPair; for ( v = 1; v < nCubes; v++ ) pVar->ppPairs[v] = pVar->ppPairs[v-1] + nCubes; } // update iCube += nCubes; iPair += nCubes * nCubes; } assert( iCube == nCubesTotal ); assert( iPair == nPairsStore ); // allocate room for the reordered literals pOrder = ABC_ALLOC( int, nBitsMax ); // create the rows for ( i = 0; i < pData->nNodesOld; i++ ) if ( (pSopCover = (char *)pData->vSops->pArray[i]) ) { // get the new var in the matrix pVar = p->ppVars[2*i+1]; // here we sort the literals of the cover // in the increasing order of the numbers of the corresponding nodes // because literals should be added to the matrix in this order vFanins = (Vec_Int_t *)pData->vFanins->pArray[i]; s_pLits = vFanins->pArray; // start the variable order nFanins = Abc_SopGetVarNum( pSopCover ); for ( v = 0; v < nFanins; v++ ) pOrder[v] = v; // reorder the fanins qsort( (void *)pOrder, nFanins, sizeof(int),(int (*)(const void *, const void *))Fxu_CreateMatrixLitCompare); assert( s_pLits[ pOrder[0] ] < s_pLits[ pOrder[nFanins-1] ] ); // create the corresponding cubes in the matrix pCubeFirst = NULL; c = 0; Abc_SopForEachCube( pSopCover, nFanins, pSopCube ) { // create the cube pCubeNew = Fxu_MatrixAddCube( p, pVar, c++ ); Fxu_CreateMatrixAddCube( p, pCubeNew, pSopCube, vFanins, pOrder ); if ( pCubeFirst == NULL ) pCubeFirst = pCubeNew; pCubeNew->pFirst = pCubeFirst; } // set the first cube of this var pVar->pFirst = pCubeFirst; // create the divisors without preprocessing if ( nPairsTotal <= pData->nPairsMax ) { for ( pCube1 = pCubeFirst; pCube1; pCube1 = pCube1->pNext ) for ( pCube2 = pCube1? pCube1->pNext: NULL; pCube2; pCube2 = pCube2->pNext ) Fxu_MatrixAddDivisor( p, pCube1, pCube2 ); } } ABC_FREE( pOrder ); // consider the case when cube pairs should be preprocessed // before adding them to the set of divisors // if ( pData->fVerbose ) // printf( "The total number of cube pairs is %d.\n", nPairsTotal ); if ( nPairsTotal > 10000000 ) { printf( "The total number of cube pairs of the network is more than 10,000,000.\n" ); printf( "Command \"fx\" takes a long time to run in such cases. It is suggested\n" ); printf( "that the user changes the network by reducing the size of logic node and\n" ); printf( "consequently the number of cube pairs to be processed by this command.\n" ); printf( "It can be achieved as follows: \"st; if -K \" or \"st; renode -s -K \"\n" ); printf( "as a proprocessing step, while selecting as approapriate.\n" ); return NULL; } if ( nPairsTotal > pData->nPairsMax ) if ( !Fxu_PreprocessCubePairs( p, pData->vSops, nPairsTotal, pData->nPairsMax ) ) return NULL; // if ( pData->fVerbose ) // printf( "Only %d best cube pairs will be used by the fast extract command.\n", pData->nPairsMax ); if ( p->lVars.nItems > 1000000 ) { printf( "The total number of variables is more than 1,000,000.\n" ); printf( "Command \"fx\" takes a long time to run in such cases. It is suggested\n" ); printf( "that the user changes the network by reducing the size of logic node and\n" ); printf( "consequently the number of cube pairs to be processed by this command.\n" ); printf( "It can be achieved as follows: \"st; if -K \" or \"st; renode -s -K \"\n" ); printf( "as a proprocessing step, while selecting as approapriate.\n" ); return NULL; } // add the var pairs to the heap Fxu_MatrixComputeSingles( p, pData->fUse0, pData->nSingleMax ); // print stats if ( pData->fVerbose ) { double Density; Density = ((double)p->nEntries) / p->lVars.nItems / p->lCubes.nItems; fprintf( stdout, "Matrix: [vars x cubes] = [%d x %d] ", p->lVars.nItems, p->lCubes.nItems ); fprintf( stdout, "Lits = %d Density = %.5f%%\n", p->nEntries, Density ); fprintf( stdout, "1-cube divs = %6d. (Total = %6d) ", p->lSingles.nItems, p->nSingleTotal ); fprintf( stdout, "2-cube divs = %6d. (Total = %6d)", p->nDivsTotal, nPairsTotal ); fprintf( stdout, "\n" ); } // Fxu_MatrixPrint( stdout, p ); return p; } /**Function************************************************************* Synopsis [Adds one cube with literals to the matrix.] Description [Create the cube and literals in the matrix corresponding to the given cube in the SOP cover. Co-singleton transform is performed here.] SideEffects [] SeeAlso [] ***********************************************************************/ void Fxu_CreateMatrixAddCube( Fxu_Matrix * p, Fxu_Cube * pCube, char * pSopCube, Vec_Int_t * vFanins, int * pOrder ) { Fxu_Var * pVar; int Value, i; // add literals to the matrix Abc_CubeForEachVar( pSopCube, Value, i ) { Value = pSopCube[pOrder[i]]; if ( Value == '0' ) { pVar = p->ppVars[ 2 * vFanins->pArray[pOrder[i]] + 1 ]; // CST Fxu_MatrixAddLiteral( p, pCube, pVar ); } else if ( Value == '1' ) { pVar = p->ppVars[ 2 * vFanins->pArray[pOrder[i]] ]; // CST Fxu_MatrixAddLiteral( p, pCube, pVar ); } } } /**Function************************************************************* Synopsis [Creates the new array of Sop covers from the sparse matrix.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ void Fxu_CreateCovers( Fxu_Matrix * p, Fxu_Data_t * pData ) { Fxu_Cube * pCube, * pCubeFirst, * pCubeNext; char * pSopCover; int iNode, n; // get the first cube of the first internal node pCubeFirst = Fxu_CreateCoversFirstCube( p, pData, 0 ); // go through the internal nodes for ( n = 0; n < pData->nNodesOld; n++ ) if ( (pSopCover = (char *)pData->vSops->pArray[n]) ) { // get the number of this node iNode = n; // get the next first cube pCubeNext = Fxu_CreateCoversFirstCube( p, pData, iNode + 1 ); // check if there any new variables in these cubes for ( pCube = pCubeFirst; pCube != pCubeNext; pCube = pCube->pNext ) if ( pCube->lLits.pTail && pCube->lLits.pTail->iVar >= 2 * pData->nNodesOld ) break; if ( pCube != pCubeNext ) Fxu_CreateCoversNode( p, pData, iNode, pCubeFirst, pCubeNext ); // update the first cube pCubeFirst = pCubeNext; } // add the covers for the extracted nodes for ( n = 0; n < pData->nNodesNew; n++ ) { // get the number of this node iNode = pData->nNodesOld + n; // get the next first cube pCubeNext = Fxu_CreateCoversFirstCube( p, pData, iNode + 1 ); // the node should be added Fxu_CreateCoversNode( p, pData, iNode, pCubeFirst, pCubeNext ); // update the first cube pCubeFirst = pCubeNext; } } /**Function************************************************************* Synopsis [Create Sop covers for one node that has changed.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ void Fxu_CreateCoversNode( Fxu_Matrix * p, Fxu_Data_t * pData, int iNode, Fxu_Cube * pCubeFirst, Fxu_Cube * pCubeNext ) { Vec_Int_t * vInputsNew; char * pSopCover, * pSopCube; Fxu_Var * pVar; Fxu_Cube * pCube; Fxu_Lit * pLit; int iNum, nCubes, v; // collect positive polarity variable in the cubes between pCubeFirst and pCubeNext Fxu_MatrixRingVarsStart( p ); for ( pCube = pCubeFirst; pCube != pCubeNext; pCube = pCube->pNext ) for ( pLit = pCube->lLits.pHead; pLit; pLit = pLit->pHNext ) { pVar = p->ppVars[ 2 * (pLit->pVar->iVar/2) + 1 ]; if ( pVar->pOrder == NULL ) Fxu_MatrixRingVarsAdd( p, pVar ); } Fxu_MatrixRingVarsStop( p ); // collect the variable numbers vInputsNew = Vec_IntAlloc( 4 ); Fxu_MatrixForEachVarInRing( p, pVar ) Vec_IntPush( vInputsNew, pVar->iVar / 2 ); Fxu_MatrixRingVarsUnmark( p ); // sort the vars by their number Vec_IntSort( vInputsNew, 0 ); // mark the vars with their numbers in the sorted array for ( v = 0; v < vInputsNew->nSize; v++ ) { p->ppVars[ 2 * vInputsNew->pArray[v] + 0 ]->lLits.nItems = v; // hack - reuse lLits.nItems p->ppVars[ 2 * vInputsNew->pArray[v] + 1 ]->lLits.nItems = v; // hack - reuse lLits.nItems } // count the number of cubes nCubes = 0; for ( pCube = pCubeFirst; pCube != pCubeNext; pCube = pCube->pNext ) if ( pCube->lLits.nItems ) nCubes++; // allocate room for the new cover pSopCover = Abc_SopStart( pData->pManSop, nCubes, vInputsNew->nSize ); // set the correct polarity of the cover if ( iNode < pData->nNodesOld && Abc_SopGetPhase( (char *)pData->vSops->pArray[iNode] ) == 0 ) Abc_SopComplement( pSopCover ); // add the cubes nCubes = 0; for ( pCube = pCubeFirst; pCube != pCubeNext; pCube = pCube->pNext ) { if ( pCube->lLits.nItems == 0 ) continue; // get hold of the SOP cube pSopCube = pSopCover + nCubes * (vInputsNew->nSize + 3); // insert literals for ( pLit = pCube->lLits.pHead; pLit; pLit = pLit->pHNext ) { iNum = pLit->pVar->lLits.nItems; // hack - reuse lLits.nItems assert( iNum < vInputsNew->nSize ); if ( pLit->pVar->iVar / 2 < pData->nNodesOld ) pSopCube[iNum] = (pLit->pVar->iVar & 1)? '0' : '1'; // reverse CST else pSopCube[iNum] = (pLit->pVar->iVar & 1)? '1' : '0'; // no CST } // count the cube nCubes++; } assert( nCubes == Abc_SopGetCubeNum(pSopCover) ); // set the new cover and the array of fanins pData->vSopsNew->pArray[iNode] = pSopCover; pData->vFaninsNew->pArray[iNode] = vInputsNew; } /**Function************************************************************* Synopsis [Adds the var to storage.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ Fxu_Cube * Fxu_CreateCoversFirstCube( Fxu_Matrix * p, Fxu_Data_t * pData, int iVar ) { int v; for ( v = iVar; v < pData->nNodesOld + pData->nNodesNew; v++ ) if ( p->ppVars[ 2*v + 1 ]->pFirst ) return p->ppVars[ 2*v + 1 ]->pFirst; return NULL; } /**Function************************************************************* Synopsis [Compares the vars by their number.] Description [] SideEffects [] SeeAlso [] ***********************************************************************/ int Fxu_CreateMatrixLitCompare( int * ptrX, int * ptrY ) { return s_pLits[*ptrX] - s_pLits[*ptrY]; } //////////////////////////////////////////////////////////////////////// /// END OF FILE /// //////////////////////////////////////////////////////////////////////// ABC_NAMESPACE_IMPL_END