/**CFile****************************************************************
FileName [wlc.c]
SystemName [ABC: Logic synthesis and verification system.]
PackageName [Verilog parser.]
Synopsis [Parses several flavors of word-level Verilog.]
Author [Alan Mishchenko]
Affiliation [UC Berkeley]
Date [Ver. 1.0. Started - August 22, 2014.]
Revision [$Id: wlc.c,v 1.00 2014/09/12 00:00:00 alanmi Exp $]
***********************************************************************/
#include "wlc.h"
#include "sat/bsat/satStore.h"
ABC_NAMESPACE_IMPL_START
////////////////////////////////////////////////////////////////////////
/// DECLARATIONS ///
////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////
/// FUNCTION DEFINITIONS ///
////////////////////////////////////////////////////////////////////////
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Wlc_GenerateCodeMax4( int nBits )
{
int nWidth, nSteps, i;
FILE * pFile = fopen( "max4.v", "wb" );
if ( pFile == NULL )
return;
for ( nSteps = 0, nWidth = 1; nWidth < nBits; nWidth *= 3, nSteps++ );
fprintf( pFile, "module max4 ( a, b, c, d, res, addr );\n\n" );
fprintf( pFile, " input [%d:0] a, b, c, d;\n", nBits-1 );
fprintf( pFile, " output [%d:0] res;\n", nBits-1 );
fprintf( pFile, " output [1:0] addr;\n\n" );
fprintf( pFile, " wire [%d:0] A = a;\n", nWidth-1 );
fprintf( pFile, " wire [%d:0] B = b;\n", nWidth-1 );
fprintf( pFile, " wire [%d:0] C = c;\n", nWidth-1 );
fprintf( pFile, " wire [%d:0] D = d;\n\n", nWidth-1 );
fprintf( pFile, " wire AB, AC, AD, BC, BD, CD;\n\n" );
fprintf( pFile, " comp( A, B, AB );\n" );
fprintf( pFile, " comp( A, C, AC );\n" );
fprintf( pFile, " comp( A, D, AD );\n" );
fprintf( pFile, " comp( B, C, BC );\n" );
fprintf( pFile, " comp( B, D, BD );\n" );
fprintf( pFile, " comp( C, D, CD );\n\n" );
fprintf( pFile, " assign addr = AB ? (CD ? (AC ? 2\'b00 : 2\'b10) : (AD ? 2\'b00 : 2\'b11)) : (CD ? (BC ? 2\'b01 : 2\'b10) : (BD ? 2\'b01 : 2\'b11));\n\n" );
fprintf( pFile, " assign res = addr[1] ? (addr[1] ? d : c) : (addr[0] ? b : a);\n\n" );
fprintf( pFile, "endmodule\n\n\n" );
fprintf( pFile, "module comp ( a, b, res );\n\n" );
fprintf( pFile, " input [%d:0] a, b;\n", nWidth-1 );
fprintf( pFile, " output res;\n" );
fprintf( pFile, " wire res2;\n\n" );
fprintf( pFile, " wire [%d:0] A = a & ~b;\n", nWidth-1 );
fprintf( pFile, " wire [%d:0] B = ~a & b;\n\n", nWidth-1 );
fprintf( pFile, " comp0( A, B, res, res2 );\n\n" );
fprintf( pFile, "endmodule\n\n\n" );
for ( i = 0; i < nSteps; i++ )
{
fprintf( pFile, "module comp%d ( a, b, yes, no );\n\n", i );
fprintf( pFile, " input [%d:0] a, b;\n", nWidth-1 );
fprintf( pFile, " output yes, no;\n\n", nWidth/3-1 );
fprintf( pFile, " wire [2:0] y, n;\n\n" );
if ( i == nSteps - 1 )
{
fprintf( pFile, " assign y = a;\n" );
fprintf( pFile, " assign n = b;\n\n" );
}
else
{
fprintf( pFile, " wire [%d:0] A0 = a[%d:%d];\n", nWidth/3-1, nWidth/3-1, 0 );
fprintf( pFile, " wire [%d:0] A1 = a[%d:%d];\n", nWidth/3-1, 2*nWidth/3-1, nWidth/3 );
fprintf( pFile, " wire [%d:0] A2 = a[%d:%d];\n\n", nWidth/3-1, nWidth-1, 2*nWidth/3 );
fprintf( pFile, " wire [%d:0] B0 = b[%d:%d];\n", nWidth/3-1, nWidth/3-1, 0 );
fprintf( pFile, " wire [%d:0] B1 = b[%d:%d];\n", nWidth/3-1, 2*nWidth/3-1, nWidth/3 );
fprintf( pFile, " wire [%d:0] B2 = b[%d:%d];\n\n", nWidth/3-1, nWidth-1, 2*nWidth/3 );
fprintf( pFile, " comp%d( A0, B0, y[0], n[0] );\n", i+1 );
fprintf( pFile, " comp%d( A1, B1, y[1], n[1] );\n", i+1 );
fprintf( pFile, " comp%d( A2, B2, y[2], n[2] );\n\n", i+1 );
}
fprintf( pFile, " assign yes = y[0] | (~y[0] & ~n[0] & y[1]) | (~y[0] & ~n[0] & ~y[1] & ~n[1] & y[2]);\n" );
fprintf( pFile, " assign no = n[0] | (~y[0] & ~n[0] & n[1]) | (~y[0] & ~n[0] & ~y[1] & ~n[1] & n[2]);\n\n" );
fprintf( pFile, "endmodule\n\n\n" );
nWidth /= 3;
}
fclose( pFile );
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Wlc_BlastFullAdderCtrlCnf( sat_solver * pSat, int a, int ac, int b, int c, int * pc, int * ps, int * piVars )
{
int Cnf[12][6] = { // xabc cs // abc cs
{ -1, 0, 0, 0, 0, 0 }, // -000 00 // 000 00
{ -1, 0, 0, 1, 0, 1 }, // -001 01 // 001 01
{ -1, 0, 1, 0, 0, 1 }, // -010 01 // 010 01
{ -1, 0, 1, 1, 1, 0 }, // -011 10 // 011 10
{ 0,-1, 0, 0, 0, 0 }, // 0-00 00
{ 0,-1, 0, 1, 0, 1 }, // 0-01 01
{ 0,-1, 1, 0, 0, 1 }, // 0-10 01
{ 0,-1, 1, 1, 1, 0 }, // 0-11 10
{ 1, 1, 0, 0, 0, 1 }, // 1100 01 // 100 01
{ 1, 1, 0, 1, 1, 0 }, // 1101 10 // 101 10
{ 1, 1, 1, 0, 1, 0 }, // 1110 10 // 110 10
{ 1, 1, 1, 1, 1, 1 } // 1111 11 // 111 11
};
int pVars[6] = {a, ac, b, c, *piVars, *piVars+1};
int i, v, nLits, pLits[6];
for ( i = 0; i < 12; i++ )
{
nLits = 0;
for ( v = 0; v < 6; v++ )
{
if ( Cnf[i][v] == -1 )
continue;
if ( pVars[v] == 0 ) // const 0
{
if ( Cnf[i][v] == 0 )
continue;
if ( Cnf[i][v] == 1 )
break;
}
if ( pVars[v] == -1 ) // const -1
{
if ( Cnf[i][v] == 0 )
break;
if ( Cnf[i][v] == 1 )
continue;
}
pLits[nLits++] = Abc_Var2Lit( pVars[v], Cnf[i][v] );
}
if ( v < 6 )
continue;
assert( nLits > 2 );
sat_solver_addclause( pSat, pLits, pLits + nLits );
}
*pc = (*piVars)++;
*ps = (*piVars)++;
}
void Wlc_BlastMultiplierCnf( sat_solver * pSat, int * pArgA, int * pArgB, int nArgA, int nArgB, Vec_Int_t * vTemp, Vec_Int_t * vRes, int * piVars )
{
int * pRes, * pArgC, * pArgS, a, b, Carry = 0;
assert( nArgA > 0 && nArgB > 0 );
// prepare result
Vec_IntFill( vRes, nArgA + nArgB, 0 );
pRes = Vec_IntArray( vRes );
// prepare intermediate storage
Vec_IntFill( vTemp, 2 * nArgA, 0 );
pArgC = Vec_IntArray( vTemp );
pArgS = pArgC + nArgA;
// create matrix
for ( b = 0; b < nArgB; b++ )
for ( a = 0; a < nArgA; a++ )
Wlc_BlastFullAdderCtrlCnf( pSat, pArgA[a], pArgB[b], pArgS[a], pArgC[a], &pArgC[a], a ? &pArgS[a-1] : &pRes[b], piVars );
// final addition
pArgS[nArgA-1] = 0;
for ( a = 0; a < nArgA; a++ )
Wlc_BlastFullAdderCtrlCnf( pSat, -1, pArgC[a], pArgS[a], Carry, &Carry, &pRes[nArgB+a], piVars );
}
sat_solver * Wlc_BlastMultiplierCnfMain( int nBits )
{
Vec_Int_t * vRes1 = Vec_IntAlloc( 2*nBits );
Vec_Int_t * vRes2 = Vec_IntAlloc( 2*nBits );
Vec_Int_t * vTemp = Vec_IntAlloc( 2*nBits );
int * pArgA = ABC_ALLOC( int, nBits );
int * pArgB = ABC_ALLOC( int, nBits );
int i, Ent1, Ent2, nVars = 1 + 2*nBits;
int nVarsAll = 1 + 4*nBits + 4*nBits*(nBits + 1);
sat_solver * pSat = sat_solver_new();
sat_solver_setnvars( pSat, nVarsAll );
for ( i = 0; i < nBits; i++ )
pArgA[i] = 1 + i, pArgB[i] = 1 + nBits + i;
Wlc_BlastMultiplierCnf( pSat, pArgA, pArgB, nBits, nBits, vTemp, vRes1, &nVars );
for ( i = 0; i < nBits; i++ )
pArgA[i] = 1 + nBits + i, pArgB[i] = 1 + i;
Wlc_BlastMultiplierCnf( pSat, pArgA, pArgB, nBits, nBits, vTemp, vRes2, &nVars );
Vec_IntClear( vTemp );
Vec_IntForEachEntryTwo( vRes1, vRes2, Ent1, Ent2, i )
{
Vec_IntPush( vTemp, Abc_Var2Lit(nVars, 0) );
sat_solver_add_xor( pSat, Ent1, Ent2, nVars++, 0 );
}
assert( nVars == nVarsAll );
sat_solver_addclause( pSat, Vec_IntArray(vTemp), Vec_IntLimit(vTemp) );
ABC_FREE( pArgA );
ABC_FREE( pArgB );
Vec_IntFree( vRes1 );
Vec_IntFree( vRes2 );
Vec_IntFree( vTemp );
return pSat;
}
void Wlc_BlastMultiplierCnfTest( int nBits )
{
abctime clk = Abc_Clock();
sat_solver * pSat = Wlc_BlastMultiplierCnfMain( nBits );
int i, status = sat_solver_solve( pSat, NULL, NULL, 0, 0, 0, 0 );
Sat_SolverWriteDimacs( pSat, "test_mult.cnf", NULL, NULL, 0 );
for ( i = 0; i < sat_solver_nvars(pSat); i++ )
printf( "%d=%d ", i, sat_solver_var_value(pSat, i) );
printf( "\n" );
printf( "Verifying for %d bits: %s ", nBits, status == l_True ? "SAT" : "UNSAT" );
Abc_PrintTime( 1, "Time", Abc_Clock() - clk );
sat_solver_delete( pSat );
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Vec_Int_t * Wlc_ManGenAdderN( Gia_Man_t * p, int nLits, int * pLitsA, int * pLitsB, int Carry )
{
extern void Wlc_BlastFullAdder( Gia_Man_t * pNew, int a, int b, int c, int * pc, int * ps );
Vec_Int_t * vRes = Vec_IntStart( nLits + 1 );
int i, * pRes = Vec_IntArray(vRes);
for ( i = 0; i < nLits; i++ )
Wlc_BlastFullAdder( p, pLitsA[i], pLitsB[i], Carry, &Carry, &pRes[i] );
pRes[nLits] = Carry;
return vRes;
}
Vec_Int_t * Wlc_ManGenAdder2_rec( Gia_Man_t * p, int nLits, int * pLitsA, int * pLitsB, int Carry, int Size )
{
Vec_Int_t * vRes, * vRes0, * vRes1, * vRes2; int i, iCtrl;
if ( nLits == Size )
return Wlc_ManGenAdderN( p, nLits, pLitsA, pLitsB, Carry );
vRes0 = Wlc_ManGenAdder2_rec( p, nLits/2, pLitsA, pLitsB, Carry, Size );
vRes1 = Wlc_ManGenAdder2_rec( p, nLits/2, pLitsA + nLits/2, pLitsB + nLits/2, 0, Size );
vRes2 = Wlc_ManGenAdder2_rec( p, nLits/2, pLitsA + nLits/2, pLitsB + nLits/2, 1, Size );
vRes = Vec_IntAlloc( nLits + 1 );
Vec_IntAppend( vRes, vRes0 );
iCtrl = Vec_IntPop( vRes );
for ( i = 0; i <= nLits/2; i++ )
Vec_IntPush( vRes, Gia_ManHashMux(p, iCtrl, Vec_IntEntry(vRes2, i), Vec_IntEntry(vRes1, i)) );
assert( Vec_IntSize(vRes) == nLits + 1 );
Vec_IntFree( vRes0 );
Vec_IntFree( vRes1 );
Vec_IntFree( vRes2 );
return vRes;
}
Gia_Man_t * Wlc_ManGenAdder2( int nBits, int Size, int fSigned )
{
Gia_Man_t * pTemp, * pNew; int n, i, iLit, nBitsAll;
Vec_Int_t * vOuts, * vLits = Vec_IntAlloc( 1000 );
pNew = Gia_ManStart( 1000 );
pNew->pName = Abc_UtilStrsav( "adder" );
for ( nBitsAll = Size; nBitsAll < nBits; nBitsAll *= 2 )
;
for ( n = 0; n < 2; n++ )
{
for ( i = 0; i < nBits; i++ )
Vec_IntPush( vLits, Gia_ManAppendCi(pNew) );
for ( ; i < nBitsAll; i++ )
Vec_IntPush( vLits, fSigned ? Vec_IntEntry(vLits, nBits-1) : 0 );
}
Gia_ManHashAlloc( pNew );
vOuts = Wlc_ManGenAdder2_rec( pNew, nBitsAll, Vec_IntEntryP(vLits, 0), Vec_IntEntryP(vLits, Vec_IntSize(vLits)/2), 0, Size );
Gia_ManHashStop( pNew );
Vec_IntForEachEntry( vOuts, iLit, i )
Gia_ManAppendCo( pNew, iLit );
Vec_IntFree( vLits );
Vec_IntFree( vOuts );
pNew = Gia_ManCleanup( pTemp = pNew );
Gia_ManStop( pTemp );
return pNew;
}
Vec_Int_t * Wlc_ManGenAdder_rec( Gia_Man_t * p, int nLits, int * pLitsA, int * pLitsB, int Carry, int Size )
{
Vec_Int_t * vRes, * vRes0, * vRes1, * vRes2, * vRes3, * vRes4; int i, iCtrl;
if ( nLits == Size )
return Wlc_ManGenAdderN( p, nLits, pLitsA, pLitsB, Carry );
assert( nLits % 3 == 0 );
vRes0 = Wlc_ManGenAdder_rec( p, nLits/3, pLitsA + 0*nLits/3, pLitsB + 0*nLits/3, Carry, Size );
vRes1 = Wlc_ManGenAdder_rec( p, nLits/3, pLitsA + 1*nLits/3, pLitsB + 1*nLits/3, 0, Size );
vRes2 = Wlc_ManGenAdder_rec( p, nLits/3, pLitsA + 1*nLits/3, pLitsB + 1*nLits/3, 1, Size );
vRes3 = Wlc_ManGenAdder_rec( p, nLits/3, pLitsA + 2*nLits/3, pLitsB + 2*nLits/3, 0, Size );
vRes4 = Wlc_ManGenAdder_rec( p, nLits/3, pLitsA + 2*nLits/3, pLitsB + 2*nLits/3, 1, Size );
vRes = Vec_IntAlloc( nLits + 1 );
Vec_IntAppend( vRes, vRes0 );
iCtrl = Vec_IntPop( vRes );
for ( i = 0; i <= nLits/3; i++ )
Vec_IntPush( vRes, Gia_ManHashMux(p, iCtrl, Vec_IntEntry(vRes2, i), Vec_IntEntry(vRes1, i)) );
iCtrl = Vec_IntPop( vRes );
for ( i = 0; i <= nLits/3; i++ )
Vec_IntPush( vRes, Gia_ManHashMux(p, iCtrl, Vec_IntEntry(vRes4, i), Vec_IntEntry(vRes3, i)) );
assert( Vec_IntSize(vRes) == nLits + 1 );
Vec_IntFree( vRes0 );
Vec_IntFree( vRes1 );
Vec_IntFree( vRes2 );
Vec_IntFree( vRes3 );
Vec_IntFree( vRes4 );
return vRes;
}
Gia_Man_t * Wlc_ManGenAdder( int nBits )
{
Gia_Man_t * pTemp, * pNew; int n, i, iLit, nBitsAll;
Vec_Int_t * vOuts, * vLits = Vec_IntAlloc( 1000 );
pNew = Gia_ManStart( 1000 );
pNew->pName = Abc_UtilStrsav( "adder" );
for ( nBitsAll = 3; nBitsAll < nBits; nBitsAll *= 3 )
;
for ( n = 0; n < 2; n++ )
{
for ( i = 0; i < nBits; i++ )
Vec_IntPush( vLits, Gia_ManAppendCi(pNew) );
for ( ; i < nBitsAll; i++ )
Vec_IntPush( vLits, 0 );
}
Gia_ManHashAlloc( pNew );
vOuts = Wlc_ManGenAdder_rec( pNew, nBitsAll, Vec_IntEntryP(vLits, 0), Vec_IntEntryP(vLits, Vec_IntSize(vLits)/2), 0, 3 );
Gia_ManHashStop( pNew );
Vec_IntForEachEntryStop( vOuts, iLit, i, nBits+1 )
Gia_ManAppendCo( pNew, iLit );
Vec_IntFree( vLits );
Vec_IntFree( vOuts );
pNew = Gia_ManCleanup( pTemp = pNew );
Gia_ManStop( pTemp );
return pNew;
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Wlc_BuildOne32( Gia_Man_t * p, int * pLitIn, int * pLitOut )
{
Wlc_BlastFullAdder( p, pLitIn[0], pLitIn[1], pLitIn[2], &pLitIn[5], &pLitOut[0] );
Wlc_BlastFullAdder( p, pLitIn[3], pLitIn[4], pLitIn[5], &pLitOut[2], &pLitOut[1] );
}
void Wlc_BuildOne51( Gia_Man_t * p, int * pLitIn, int * pLitOut )
{
int Lit00, Lit01, Lit11;
Wlc_BlastFullAdder( p, pLitIn[0], pLitIn[1], pLitIn[2], &Lit01, &Lit00 );
Wlc_BlastFullAdder( p, pLitIn[3], pLitIn[4], Lit00, &Lit11, &pLitOut[0] );
Wlc_BlastFullAdder( p, pLitIn[5], Lit01, Lit11, &pLitOut[2], &pLitOut[1] );
}
void Wlc_BuildOne6( Gia_Man_t * p, int * pLitIn, int Const1, int * pLitOut )
{
int Lit00, Lit01, Lit10, Lit11, Lit12;
Wlc_BlastFullAdder( p, pLitIn[0], pLitIn[1], pLitIn[2], &Lit01, &Lit00 );
Wlc_BlastFullAdder( p, pLitIn[3], pLitIn[4], pLitIn[5], &Lit11, &Lit10 );
Wlc_BlastFullAdder( p, Lit00, Lit10, Const1, &Lit12, &pLitOut[0] );
Wlc_BlastFullAdder( p, Lit01, Lit11, Lit12, &pLitOut[2],&pLitOut[1] );
}
Vec_Wec_t * Wlc_ManGenTree_iter( Gia_Man_t * p, Vec_Wec_t * vBits, int * pCounter )
{
Vec_Wec_t * vBitsNew = Vec_WecStart( Vec_WecSize(vBits) );
int i, k, pLitsIn[16], pLitsOut[16], Count = 0, fSimple = Vec_WecMaxLevelSize(vBits) <= 3;
for ( i = 0; i < Vec_WecSize(vBits)-1; i++ )
{
Vec_Int_t * vBits0 = Vec_WecEntry(vBits, i);
Vec_Int_t * vBits1 = Vec_WecEntry(vBits, i+1);
if ( fSimple )
{
assert( Vec_IntSize(vBits0) <= 3 );
for ( k = 0; Vec_IntSize(vBits0) > 0; k++ )
pLitsIn[k] = Vec_IntPop( vBits0 );
for ( ; k < 3; k++ )
pLitsIn[k] = 0;
assert( k == 3 );
Wlc_BlastFullAdder( p, pLitsIn[0], pLitsIn[1], pLitsIn[2], &pLitsOut[1], &pLitsOut[0] );
Vec_WecPush( vBitsNew, i+0, pLitsOut[0] );
Vec_WecPush( vBitsNew, i+1, pLitsOut[1] );
Count += 2;
continue;
}
while ( Vec_IntSize(vBits0) >= 6 )
{
for ( k = 0; k < 6; k++ )
pLitsIn[k] = Vec_IntPop( vBits0 );
assert( k == 6 );
Wlc_BuildOne6( p, pLitsIn, 0, pLitsOut );
Vec_WecPush( vBitsNew, i+0, pLitsOut[0] );
Vec_WecPush( vBitsNew, i+1, pLitsOut[1] );
Vec_WecPush( vBitsNew, i+2, pLitsOut[2] );
Count += 3;
}
if ( Vec_IntSize(vBits0) == 5 && Vec_IntSize(vBits1) > 0 )
{
for ( k = 0; Vec_IntSize(vBits0) > 0; k++ )
pLitsIn[k] = Vec_IntPop( vBits0 );
pLitsIn[k++] = Vec_IntPop( vBits1 );
assert( k == 6 );
Wlc_BuildOne51( p, pLitsIn, pLitsOut );
Vec_WecPush( vBitsNew, i+0, pLitsOut[0] );
Vec_WecPush( vBitsNew, i+1, pLitsOut[1] );
Vec_WecPush( vBitsNew, i+2, pLitsOut[2] );
Count += 3;
}
if ( Vec_IntSize(vBits0) == 5 && Vec_IntSize(vBits1) == 0 )
{
for ( k = 0; Vec_IntSize(vBits0) > 0; k++ )
pLitsIn[k] = Vec_IntPop( vBits0 );
pLitsIn[k++] = 0;
assert( k == 6 );
Wlc_BuildOne6( p, pLitsIn, 0, pLitsOut );
Vec_WecPush( vBitsNew, i+0, pLitsOut[0] );
Vec_WecPush( vBitsNew, i+1, pLitsOut[1] );
Vec_WecPush( vBitsNew, i+2, pLitsOut[2] );
Count += 3;
}
if ( Vec_IntSize(vBits0) == 4 && Vec_IntSize(vBits1) > 0 )
{
for ( k = 0; Vec_IntSize(vBits0) > 0; k++ )
pLitsIn[k] = Vec_IntPop( vBits0 );
pLitsIn[k++] = 0;
pLitsIn[k++] = Vec_IntPop( vBits1 );
assert( k == 6 );
Wlc_BuildOne51( p, pLitsIn, pLitsOut );
Vec_WecPush( vBitsNew, i+0, pLitsOut[0] );
Vec_WecPush( vBitsNew, i+1, pLitsOut[1] );
Vec_WecPush( vBitsNew, i+2, pLitsOut[2] );
Count += 3;
}
if ( Vec_IntSize(vBits0) == 3 && Vec_IntSize(vBits1) >= 2 )
{
for ( k = 0; Vec_IntSize(vBits0) > 0; k++ )
pLitsIn[k] = Vec_IntPop( vBits0 );
pLitsIn[k++] = Vec_IntPop( vBits1 );
pLitsIn[k++] = Vec_IntPop( vBits1 );
assert( k == 5 );
Wlc_BuildOne32( p, pLitsIn, pLitsOut );
Vec_WecPush( vBitsNew, i+0, pLitsOut[0] );
Vec_WecPush( vBitsNew, i+1, pLitsOut[1] );
Vec_WecPush( vBitsNew, i+2, pLitsOut[2] );
Count += 3;
}
if ( Vec_IntSize(vBits0) >= 3 )
{
for ( k = 0; k < 3; k++ )
pLitsIn[k] = Vec_IntPop( vBits0 );
assert( k == 3 );
Wlc_BlastFullAdder( p, pLitsIn[0], pLitsIn[1], pLitsIn[2], &pLitsOut[1], &pLitsOut[0] );
Vec_WecPush( vBitsNew, i+0, pLitsOut[0] );
Vec_WecPush( vBitsNew, i+1, pLitsOut[1] );
Count += 2;
}
/*
if ( Vec_IntSize(vBits0) == 2 )
{
Vec_IntClear( vBits0 );
Vec_WecPush( vBitsNew, i+0, 0 );
Vec_WecPush( vBitsNew, i+1, 0 );
Count += 2;
}
*/
for ( k = 0; Vec_IntSize(vBits0) > 0; k++ )
Vec_WecPush( vBitsNew, i, Vec_IntPop(vBits0) );
}
if ( pCounter )
*pCounter = Count;
return vBitsNew;
}
void Wlc_ManGenTreeOne( Gia_Man_t * pNew, Vec_Wec_t * vBits0, int fMult, int fVerbose )
{
extern int Wlc_BlastAdder( Gia_Man_t * pNew, int * pAdd0, int * pAdd1, int nBits, int Carry ); // result is in pAdd0
Vec_Wec_t * vTemp, * vBits = Vec_WecDup( vBits0 );
Vec_Int_t * vOuts = Vec_IntAlloc( 1000 ), * vOuts2;
Vec_Int_t * vLits0 = Vec_IntAlloc( 1000 );
Vec_Int_t * vLits1 = Vec_IntAlloc( 1000 );
int i, iLit, nBitsAll = 0, CounterAll = 0, Counter = 1;
for ( i = 0; Counter && i < 1000; i++ )
{
if ( fVerbose ) printf( "LEVEL %d\n", i );
if ( fVerbose ) Vec_WecPrint( vBits, 0 );
if ( Vec_WecMaxLevelSize(vBits) <= 2 )
break;
vBits = Wlc_ManGenTree_iter( pNew, vTemp = vBits, &Counter );
Vec_WecFree( vTemp );
CounterAll += Counter;
}
printf( "Total count = %d.\n", CounterAll );
if ( !fMult )
{
int Carry;
/*
Vec_WecForEachLevel( vBits, vOuts2, i )
{
if ( i == 10 )
break;
if ( i == 0 )
{
assert( Vec_IntSize(vOuts2) == 1 );
Vec_IntPush( vOuts, Vec_IntPop(vOuts2) );
continue;
}
assert( Vec_IntSize(vOuts2) == 1 || Vec_IntSize(vOuts2) == 2 );
Vec_IntPush( vLits0, Vec_IntPop(vOuts2) );
if ( Vec_IntSize(vOuts2) == 1 )
Vec_IntPush( vLits1, Vec_IntPop(vOuts2) );
else
{
Vec_IntPush( vLits1, 0 );
}
}
assert( Vec_IntSize(vLits0) == 9 );
assert( Vec_IntSize(vLits1) == 9 );
*/
Vec_WecForEachLevel( vBits, vOuts2, i )
{
if ( Vec_IntSize(vOuts2) == 0 )
break;
assert( Vec_IntSize(vOuts2) == 1 || Vec_IntSize(vOuts2) == 2 );
Vec_IntPush( vLits0, Vec_IntPop(vOuts2) );
if ( Vec_IntSize(vOuts2) == 1 )
Vec_IntPush( vLits1, Vec_IntPop(vOuts2) );
else
Vec_IntPush( vLits1, 0 );
}
printf( "The adder size is %d.\n", Vec_IntSize(vLits0) );
Vec_IntShrink( vLits0, 11 );
Vec_IntShrink( vLits1, 11 );
// vOuts2 = Wlc_ManGenAdder_rec( pNew, 9, Vec_IntArray(vLits0), Vec_IntArray(vLits1), 0, 3 );
// Vec_IntAppend( vOuts, vOuts2 );
// Vec_IntFree( vOuts2 );
Carry = Wlc_BlastAdder( pNew, Vec_IntArray(vLits0), Vec_IntArray(vLits1), 11, 0 );
Vec_IntAppend( vOuts, vLits0 );
Vec_IntPush( vOuts, Carry );
Gia_ManAppendCo( pNew, Vec_IntEntry(vOuts, 11) );
}
else
{
Vec_WecForEachLevel( vBits, vOuts2, i )
{
if ( Vec_IntSize(vOuts2) == 0 )
break;
assert( Vec_IntSize(vOuts2) == 1 || Vec_IntSize(vOuts2) == 2 );
Vec_IntPush( vLits0, Vec_IntPop(vOuts2) );
if ( Vec_IntSize(vOuts2) == 1 )
Vec_IntPush( vLits1, Vec_IntPop(vOuts2) );
else
Vec_IntPush( vLits1, 0 );
}
printf( "The adder size is %d.\n", Vec_IntSize(vLits0) );
Vec_IntShrink( vLits0, Gia_ManCiNum(pNew)+1 ); // mult
Vec_IntShrink( vLits1, Gia_ManCiNum(pNew)+1 ); // mult
for ( nBitsAll = 3; nBitsAll < Vec_IntSize(vLits0); nBitsAll *= 3 )
;
for ( i = Vec_IntSize(vLits0); i < nBitsAll; i++ )
{
Vec_IntPush( vLits0, 0 );
Vec_IntPush( vLits1, 0 );
}
assert( Vec_IntSize(vLits0) == nBitsAll );
assert( Vec_IntSize(vLits1) == nBitsAll );
vOuts2 = Wlc_ManGenAdder_rec( pNew, nBitsAll, Vec_IntArray(vLits0), Vec_IntArray(vLits1), 0, 3 );
Vec_IntAppend( vOuts, vOuts2 );
Vec_IntFree( vOuts2 );
//Carry = Wlc_BlastAdder( pNew, Vec_IntArray(vLits0), Vec_IntArray(vLits1), nBitsAll, 0 );
//Vec_IntAppend( vOuts, vLits0 );
//Vec_IntPush( vOuts, Carry );
Vec_IntShrink( vOuts, Gia_ManCiNum(pNew) ); // mult
//Vec_IntShrink( vOuts, Gia_ManCiNum(pNew)/2 );
Vec_IntForEachEntry( vOuts, iLit, i )
Gia_ManAppendCo( pNew, iLit );
}
Vec_IntFree( vOuts );
Vec_IntFree( vLits0 );
Vec_IntFree( vLits1 );
Vec_WecFree( vBits );
}
Gia_Man_t * Wlc_ManGenTree( int nInputs, int Value, int nBits, int fVerbose )
{
Gia_Man_t * pTemp, * pNew; int i, Counter = 0;
Vec_Wec_t * vBits = Vec_WecStart( nBits+2 );
for ( i = 0; i < nBits+2; i++ )
Vec_WecPush( vBits, i, (Value >> i) & 1 );
pNew = Gia_ManStart( 1000 );
pNew->pName = Abc_UtilStrsav( "tree" );
for ( i = 0; i < nInputs; i++ )
Vec_WecPush( vBits, 0, Gia_ManAppendCi(pNew) );
Gia_ManHashAlloc( pNew );
Wlc_ManGenTreeOne( pNew, vBits, 0, fVerbose );
Gia_ManHashStop( pNew );
Vec_WecFree( vBits );
pNew = Gia_ManCleanup( pTemp = pNew );
Gia_ManStop( pTemp );
return pNew;
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Gia_Man_t * Wlc_ManGenProd( int nInputs, int fVerbose )
{
extern void Wlc_BlastBooth( Gia_Man_t * pNew, int * pArgA, int * pArgB, int nArgA, int nArgB, Vec_Int_t * vRes, int fSigned, int fCla, Vec_Wec_t ** pvProds );
extern void Wlc_BlastMultiplier3( Gia_Man_t * pNew, int * pArgA, int * pArgB, int nArgA, int nArgB, Vec_Int_t * vRes, int fSigned, int fCla, Vec_Wec_t ** pvProds );
Vec_Int_t * vIns = Vec_IntAlloc( 2*nInputs );
Gia_Man_t * pTemp, * pNew;
Vec_Wec_t * vProds; int i;
pNew = Gia_ManStart( 1000 );
pNew->pName = Abc_UtilStrsav( "tree" );
for ( i = 0; i < 2*nInputs; i++ )
Vec_IntPush( vIns, Gia_ManAppendCi(pNew) );
//for ( i = 0; i < nInputs; i++ )
// Vec_IntPush( vIns, Gia_ManAppendCi(pNew) );
//for ( i = 0; i < nInputs; i++ )
// Vec_IntPush( vIns, Vec_IntEntry(vIns, i) );
Gia_ManHashAlloc( pNew );
Wlc_BlastBooth( pNew, Vec_IntArray(vIns), Vec_IntArray(vIns)+nInputs, nInputs, nInputs, NULL, 0, 0, &vProds );
//Wlc_BlastMultiplier3( pNew, Vec_IntArray(vIns), Vec_IntArray(vIns)+nInputs, nInputs, nInputs, NULL, 0, 0, &vProds );
//Vec_WecPrint( vProds, 0 );
Wlc_ManGenTreeOne( pNew, vProds, 1, fVerbose );
Gia_ManHashStop( pNew );
Vec_WecFree( vProds );
Vec_IntFree( vIns );
pNew = Gia_ManCleanup( pTemp = pNew );
Gia_ManStop( pTemp );
return pNew;
}
////////////////////////////////////////////////////////////////////////
/// END OF FILE ///
////////////////////////////////////////////////////////////////////////
ABC_NAMESPACE_IMPL_END