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|
/**CFile****************************************************************
FileName [darLib.c]
SystemName [ABC: Logic synthesis and verification system.]
PackageName [DAG-aware AIG rewriting.]
Synopsis [Library of AIG subgraphs used for rewriting.]
Author [Alan Mishchenko]
Affiliation [UC Berkeley]
Date [Ver. 1.0. Started - April 28, 2007.]
Revision [$Id: darLib.c,v 1.00 2007/04/28 00:00:00 alanmi Exp $]
***********************************************************************/
#include "darInt.h"
#include "src/aig/gia/gia.h"
#include "dar.h"
ABC_NAMESPACE_IMPL_START
////////////////////////////////////////////////////////////////////////
/// DECLARATIONS ///
////////////////////////////////////////////////////////////////////////
typedef struct Dar_Lib_t_ Dar_Lib_t;
typedef struct Dar_LibObj_t_ Dar_LibObj_t;
typedef struct Dar_LibDat_t_ Dar_LibDat_t;
struct Dar_LibObj_t_ // library object (2 words)
{
unsigned Fan0 : 16; // the first fanin
unsigned Fan1 : 16; // the second fanin
unsigned fCompl0 : 1; // the first compl attribute
unsigned fCompl1 : 1; // the second compl attribute
unsigned fPhase : 1; // the phase of the node
unsigned fTerm : 1; // indicates a PI
unsigned Num : 28; // internal use
};
struct Dar_LibDat_t_ // library object data
{
union {
Aig_Obj_t * pFunc; // the corresponding AIG node if it exists
int iGunc; }; // the corresponding AIG node if it exists
int Level; // level of this node after it is constructured
int TravId; // traversal ID of the library object data
float dProb; // probability of the node being 1
unsigned char fMffc; // set to one if node is part of MFFC
unsigned char nLats[3]; // the number of latches on the input/output stem
};
struct Dar_Lib_t_ // library
{
// objects
Dar_LibObj_t * pObjs; // the set of library objects
int nObjs; // the number of objects used
int iObj; // the current object
// structures by class
int nSubgr[222]; // the number of subgraphs by class
int * pSubgr[222]; // the subgraphs for each class
int * pSubgrMem; // memory for subgraph pointers
int nSubgrTotal; // the total number of subgraph
// structure priorities
int * pPriosMem; // memory for priority of structures
int * pPrios[222]; // pointers to the priority numbers
// structure places in the priorities
int * pPlaceMem; // memory for places of structures in the priority lists
int * pPlace[222]; // pointers to the places numbers
// structure scores
int * pScoreMem; // memory for scores of structures
int * pScore[222]; // pointers to the scores numbers
// nodes by class
int nNodes[222]; // the number of nodes by class
int * pNodes[222]; // the nodes for each class
int * pNodesMem; // memory for nodes pointers
int nNodesTotal; // the total number of nodes
// prepared library
int nSubgraphs;
int nNodes0Max;
// nodes by class
int nNodes0[222]; // the number of nodes by class
int * pNodes0[222]; // the nodes for each class
int * pNodes0Mem; // memory for nodes pointers
int nNodes0Total; // the total number of nodes
// structures by class
int nSubgr0[222]; // the number of subgraphs by class
int * pSubgr0[222]; // the subgraphs for each class
int * pSubgr0Mem; // memory for subgraph pointers
int nSubgr0Total; // the total number of subgraph
// object data
Dar_LibDat_t * pDatas;
int nDatas;
// information about NPN classes
char ** pPerms4;
unsigned short * puCanons;
char * pPhases;
char * pPerms;
unsigned char * pMap;
};
static Dar_Lib_t * s_DarLib = NULL;
static inline Dar_LibObj_t * Dar_LibObj( Dar_Lib_t * p, int Id ) { return p->pObjs + Id; }
static inline int Dar_LibObjTruth( Dar_LibObj_t * pObj ) { return pObj->Num < (0xFFFF & ~pObj->Num) ? pObj->Num : (0xFFFF & ~pObj->Num); }
////////////////////////////////////////////////////////////////////////
/// FUNCTION DEFINITIONS ///
////////////////////////////////////////////////////////////////////////
/**Function*************************************************************
Synopsis [Starts the library.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Dar_Lib_t * Dar_LibAlloc( int nObjs )
{
unsigned uTruths[4] = { 0xAAAA, 0xCCCC, 0xF0F0, 0xFF00 };
Dar_Lib_t * p;
int i;//, clk = clock();
p = ABC_ALLOC( Dar_Lib_t, 1 );
memset( p, 0, sizeof(Dar_Lib_t) );
// allocate objects
p->nObjs = nObjs;
p->pObjs = ABC_ALLOC( Dar_LibObj_t, nObjs );
memset( p->pObjs, 0, sizeof(Dar_LibObj_t) * nObjs );
// allocate canonical data
p->pPerms4 = Dar_Permutations( 4 );
Dar_Truth4VarNPN( &p->puCanons, &p->pPhases, &p->pPerms, &p->pMap );
// start the elementary objects
p->iObj = 4;
for ( i = 0; i < 4; i++ )
{
p->pObjs[i].fTerm = 1;
p->pObjs[i].Num = uTruths[i];
}
// ABC_PRT( "Library start", clock() - clk );
return p;
}
/**Function*************************************************************
Synopsis [Frees the library.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Dar_LibFree( Dar_Lib_t * p )
{
ABC_FREE( p->pObjs );
ABC_FREE( p->pDatas );
ABC_FREE( p->pNodesMem );
ABC_FREE( p->pNodes0Mem );
ABC_FREE( p->pSubgrMem );
ABC_FREE( p->pSubgr0Mem );
ABC_FREE( p->pPriosMem );
ABC_FREE( p->pPlaceMem );
ABC_FREE( p->pScoreMem );
ABC_FREE( p->pPerms4 );
ABC_FREE( p->puCanons );
ABC_FREE( p->pPhases );
ABC_FREE( p->pPerms );
ABC_FREE( p->pMap );
ABC_FREE( p );
}
/**Function*************************************************************
Synopsis [Returns canonical truth tables.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Dar_LibReturnClass( unsigned uTruth )
{
return s_DarLib->pMap[uTruth & 0xffff];
}
/**Function*************************************************************
Synopsis [Returns canonical truth tables.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Dar_LibReturnCanonicals( unsigned * pCanons )
{
int Visits[222] = {0};
int i, k;
// find canonical truth tables
for ( i = k = 0; i < (1<<16); i++ )
if ( !Visits[s_DarLib->pMap[i]] )
{
Visits[s_DarLib->pMap[i]] = 1;
pCanons[k++] = ((i<<16) | i);
}
assert( k == 222 );
}
/**Function*************************************************************
Synopsis [Adds one AND to the library.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Dar_LibAddNode( Dar_Lib_t * p, int Id0, int Id1, int fCompl0, int fCompl1 )
{
Dar_LibObj_t * pFan0 = Dar_LibObj( p, Id0 );
Dar_LibObj_t * pFan1 = Dar_LibObj( p, Id1 );
Dar_LibObj_t * pObj = p->pObjs + p->iObj++;
pObj->Fan0 = Id0;
pObj->Fan1 = Id1;
pObj->fCompl0 = fCompl0;
pObj->fCompl1 = fCompl1;
pObj->fPhase = (fCompl0 ^ pFan0->fPhase) & (fCompl1 ^ pFan1->fPhase);
pObj->Num = 0xFFFF & (fCompl0? ~pFan0->Num : pFan0->Num) & (fCompl1? ~pFan1->Num : pFan1->Num);
}
/**Function*************************************************************
Synopsis [Adds one AND to the library.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Dar_LibSetup_rec( Dar_Lib_t * p, Dar_LibObj_t * pObj, int Class, int fCollect )
{
if ( pObj->fTerm || (int)pObj->Num == Class )
return;
pObj->Num = Class;
Dar_LibSetup_rec( p, Dar_LibObj(p, pObj->Fan0), Class, fCollect );
Dar_LibSetup_rec( p, Dar_LibObj(p, pObj->Fan1), Class, fCollect );
if ( fCollect )
p->pNodes[Class][ p->nNodes[Class]++ ] = pObj-p->pObjs;
else
p->nNodes[Class]++;
}
/**Function*************************************************************
Synopsis [Adds one AND to the library.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Dar_LibSetup( Dar_Lib_t * p, Vec_Int_t * vOuts, Vec_Int_t * vPrios )
{
int fTraining = 0;
Dar_LibObj_t * pObj;
int nNodesTotal, uTruth, Class, Out, i, k;
assert( p->iObj == p->nObjs );
// count the number of representatives of each class
for ( i = 0; i < 222; i++ )
p->nSubgr[i] = p->nNodes[i] = 0;
Vec_IntForEachEntry( vOuts, Out, i )
{
pObj = Dar_LibObj( p, Out );
uTruth = Dar_LibObjTruth( pObj );
Class = p->pMap[uTruth];
p->nSubgr[Class]++;
}
// allocate memory for the roots of each class
p->pSubgrMem = ABC_ALLOC( int, Vec_IntSize(vOuts) );
p->pSubgr0Mem = ABC_ALLOC( int, Vec_IntSize(vOuts) );
p->nSubgrTotal = 0;
for ( i = 0; i < 222; i++ )
{
p->pSubgr[i] = p->pSubgrMem + p->nSubgrTotal;
p->pSubgr0[i] = p->pSubgr0Mem + p->nSubgrTotal;
p->nSubgrTotal += p->nSubgr[i];
p->nSubgr[i] = 0;
}
assert( p->nSubgrTotal == Vec_IntSize(vOuts) );
// add the outputs to storage
Vec_IntForEachEntry( vOuts, Out, i )
{
pObj = Dar_LibObj( p, Out );
uTruth = Dar_LibObjTruth( pObj );
Class = p->pMap[uTruth];
p->pSubgr[Class][ p->nSubgr[Class]++ ] = Out;
}
if ( fTraining )
{
// allocate memory for the priority of roots of each class
p->pPriosMem = ABC_ALLOC( int, Vec_IntSize(vOuts) );
p->nSubgrTotal = 0;
for ( i = 0; i < 222; i++ )
{
p->pPrios[i] = p->pPriosMem + p->nSubgrTotal;
p->nSubgrTotal += p->nSubgr[i];
for ( k = 0; k < p->nSubgr[i]; k++ )
p->pPrios[i][k] = k;
}
assert( p->nSubgrTotal == Vec_IntSize(vOuts) );
// allocate memory for the priority of roots of each class
p->pPlaceMem = ABC_ALLOC( int, Vec_IntSize(vOuts) );
p->nSubgrTotal = 0;
for ( i = 0; i < 222; i++ )
{
p->pPlace[i] = p->pPlaceMem + p->nSubgrTotal;
p->nSubgrTotal += p->nSubgr[i];
for ( k = 0; k < p->nSubgr[i]; k++ )
p->pPlace[i][k] = k;
}
assert( p->nSubgrTotal == Vec_IntSize(vOuts) );
// allocate memory for the priority of roots of each class
p->pScoreMem = ABC_ALLOC( int, Vec_IntSize(vOuts) );
p->nSubgrTotal = 0;
for ( i = 0; i < 222; i++ )
{
p->pScore[i] = p->pScoreMem + p->nSubgrTotal;
p->nSubgrTotal += p->nSubgr[i];
for ( k = 0; k < p->nSubgr[i]; k++ )
p->pScore[i][k] = 0;
}
assert( p->nSubgrTotal == Vec_IntSize(vOuts) );
}
else
{
int Counter = 0;
// allocate memory for the priority of roots of each class
p->pPriosMem = ABC_ALLOC( int, Vec_IntSize(vOuts) );
p->nSubgrTotal = 0;
for ( i = 0; i < 222; i++ )
{
p->pPrios[i] = p->pPriosMem + p->nSubgrTotal;
p->nSubgrTotal += p->nSubgr[i];
for ( k = 0; k < p->nSubgr[i]; k++ )
p->pPrios[i][k] = Vec_IntEntry(vPrios, Counter++);
}
assert( p->nSubgrTotal == Vec_IntSize(vOuts) );
assert( Counter == Vec_IntSize(vPrios) );
}
// create traversal IDs
for ( i = 0; i < p->iObj; i++ )
Dar_LibObj(p, i)->Num = 0xff;
// count nodes in each class
for ( i = 0; i < 222; i++ )
for ( k = 0; k < p->nSubgr[i]; k++ )
Dar_LibSetup_rec( p, Dar_LibObj(p, p->pSubgr[i][k]), i, 0 );
// count the total number of nodes
p->nNodesTotal = 0;
for ( i = 0; i < 222; i++ )
p->nNodesTotal += p->nNodes[i];
// allocate memory for the nodes of each class
p->pNodesMem = ABC_ALLOC( int, p->nNodesTotal );
p->pNodes0Mem = ABC_ALLOC( int, p->nNodesTotal );
p->nNodesTotal = 0;
for ( i = 0; i < 222; i++ )
{
p->pNodes[i] = p->pNodesMem + p->nNodesTotal;
p->pNodes0[i] = p->pNodes0Mem + p->nNodesTotal;
p->nNodesTotal += p->nNodes[i];
p->nNodes[i] = 0;
}
// create traversal IDs
for ( i = 0; i < p->iObj; i++ )
Dar_LibObj(p, i)->Num = 0xff;
// add the nodes to storage
nNodesTotal = 0;
for ( i = 0; i < 222; i++ )
{
for ( k = 0; k < p->nSubgr[i]; k++ )
Dar_LibSetup_rec( p, Dar_LibObj(p, p->pSubgr[i][k]), i, 1 );
nNodesTotal += p->nNodes[i];
//printf( "Class %3d : Subgraphs = %4d. Nodes = %5d.\n", i, p->nSubgr[i], p->nNodes[i] );
}
assert( nNodesTotal == p->nNodesTotal );
// prepare the number of the PI nodes
for ( i = 0; i < 4; i++ )
Dar_LibObj(p, i)->Num = i;
}
/**Function*************************************************************
Synopsis [Starts the library.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Dar_LibCreateData( Dar_Lib_t * p, int nDatas )
{
if ( p->nDatas == nDatas )
return;
ABC_FREE( p->pDatas );
// allocate datas
p->nDatas = nDatas;
p->pDatas = ABC_ALLOC( Dar_LibDat_t, nDatas );
memset( p->pDatas, 0, sizeof(Dar_LibDat_t) * nDatas );
}
/**Function*************************************************************
Synopsis [Adds one AND to the library.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Dar_LibSetup0_rec( Dar_Lib_t * p, Dar_LibObj_t * pObj, int Class, int fCollect )
{
if ( pObj->fTerm || (int)pObj->Num == Class )
return;
pObj->Num = Class;
Dar_LibSetup0_rec( p, Dar_LibObj(p, pObj->Fan0), Class, fCollect );
Dar_LibSetup0_rec( p, Dar_LibObj(p, pObj->Fan1), Class, fCollect );
if ( fCollect )
p->pNodes0[Class][ p->nNodes0[Class]++ ] = pObj-p->pObjs;
else
p->nNodes0[Class]++;
}
/**Function*************************************************************
Synopsis [Starts the library.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Dar_LibPrepare( int nSubgraphs )
{
Dar_Lib_t * p = s_DarLib;
int i, k, nNodes0Total;
if ( p->nSubgraphs == nSubgraphs )
return;
// favor special classes:
// 1 : F = (!d*!c*!b*!a)
// 4 : F = (!d*!c*!(b*a))
// 12 : F = (!d*!(c*!(!b*!a)))
// 20 : F = (!d*!(c*b*a))
// set the subgraph counters
p->nSubgr0Total = 0;
for ( i = 0; i < 222; i++ )
{
// if ( i == 1 || i == 4 || i == 12 || i == 20 ) // special classes
if ( i == 1 ) // special classes
p->nSubgr0[i] = p->nSubgr[i];
else
p->nSubgr0[i] = Abc_MinInt( p->nSubgr[i], nSubgraphs );
p->nSubgr0Total += p->nSubgr0[i];
for ( k = 0; k < p->nSubgr0[i]; k++ )
p->pSubgr0[i][k] = p->pSubgr[i][ p->pPrios[i][k] ];
}
// count the number of nodes
// clean node counters
for ( i = 0; i < 222; i++ )
p->nNodes0[i] = 0;
// create traversal IDs
for ( i = 0; i < p->iObj; i++ )
Dar_LibObj(p, i)->Num = 0xff;
// count nodes in each class
// count the total number of nodes and the largest class
p->nNodes0Total = 0;
p->nNodes0Max = 0;
for ( i = 0; i < 222; i++ )
{
for ( k = 0; k < p->nSubgr0[i]; k++ )
Dar_LibSetup0_rec( p, Dar_LibObj(p, p->pSubgr0[i][k]), i, 0 );
p->nNodes0Total += p->nNodes0[i];
p->nNodes0Max = Abc_MaxInt( p->nNodes0Max, p->nNodes0[i] );
}
// clean node counters
for ( i = 0; i < 222; i++ )
p->nNodes0[i] = 0;
// create traversal IDs
for ( i = 0; i < p->iObj; i++ )
Dar_LibObj(p, i)->Num = 0xff;
// add the nodes to storage
nNodes0Total = 0;
for ( i = 0; i < 222; i++ )
{
for ( k = 0; k < p->nSubgr0[i]; k++ )
Dar_LibSetup0_rec( p, Dar_LibObj(p, p->pSubgr0[i][k]), i, 1 );
nNodes0Total += p->nNodes0[i];
}
assert( nNodes0Total == p->nNodes0Total );
// prepare the number of the PI nodes
for ( i = 0; i < 4; i++ )
Dar_LibObj(p, i)->Num = i;
// realloc the datas
Dar_LibCreateData( p, p->nNodes0Max + 32 );
// allocated more because Dar_LibBuildBest() sometimes requires more entries
}
/**Function*************************************************************
Synopsis [Reads library from array.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Dar_Lib_t * Dar_LibRead()
{
Vec_Int_t * vObjs, * vOuts, * vPrios;
Dar_Lib_t * p;
int i;
// read nodes and outputs
vObjs = Dar_LibReadNodes();
vOuts = Dar_LibReadOuts();
vPrios = Dar_LibReadPrios();
// create library
p = Dar_LibAlloc( Vec_IntSize(vObjs)/2 + 4 );
// create nodes
for ( i = 0; i < vObjs->nSize; i += 2 )
Dar_LibAddNode( p, vObjs->pArray[i] >> 1, vObjs->pArray[i+1] >> 1,
vObjs->pArray[i] & 1, vObjs->pArray[i+1] & 1 );
// create outputs
Dar_LibSetup( p, vOuts, vPrios );
Vec_IntFree( vObjs );
Vec_IntFree( vOuts );
Vec_IntFree( vPrios );
return p;
}
/**Function*************************************************************
Synopsis [Starts the library.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Dar_LibStart()
{
// int clk = clock();
assert( s_DarLib == NULL );
s_DarLib = Dar_LibRead();
// printf( "The 4-input library started with %d nodes and %d subgraphs. ", s_DarLib->nObjs - 4, s_DarLib->nSubgrTotal );
// ABC_PRT( "Time", clock() - clk );
}
/**Function*************************************************************
Synopsis [Stops the library.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Dar_LibStop()
{
assert( s_DarLib != NULL );
Dar_LibFree( s_DarLib );
s_DarLib = NULL;
}
/**Function*************************************************************
Synopsis [Updates the score of the class and adjusts the priority of this class.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Dar_LibIncrementScore( int Class, int Out, int Gain )
{
int * pPrios = s_DarLib->pPrios[Class]; // pPrios[i] = Out
int * pPlace = s_DarLib->pPlace[Class]; // pPlace[Out] = i
int * pScore = s_DarLib->pScore[Class]; // score of Out
int Out2;
assert( Class >= 0 && Class < 222 );
assert( Out >= 0 && Out < s_DarLib->nSubgr[Class] );
assert( pPlace[pPrios[Out]] == Out );
// increment the score
pScore[Out] += Gain;
// move the out in the order
while ( pPlace[Out] > 0 && pScore[Out] > pScore[ pPrios[pPlace[Out]-1] ] )
{
// get the previous output in the priority list
Out2 = pPrios[pPlace[Out]-1];
// swap Out and Out2
pPlace[Out]--;
pPlace[Out2]++;
pPrios[pPlace[Out]] = Out;
pPrios[pPlace[Out2]] = Out2;
}
}
/**Function*************************************************************
Synopsis [Prints out the priorities into the file.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Dar_LibDumpPriorities()
{
int i, k, Out, Out2, Counter = 0, Printed = 0;
printf( "\nOutput priorities (total = %d):\n", s_DarLib->nSubgrTotal );
for ( i = 0; i < 222; i++ )
{
// printf( "Class%d: ", i );
for ( k = 0; k < s_DarLib->nSubgr[i]; k++ )
{
Out = s_DarLib->pPrios[i][k];
Out2 = k == 0 ? Out : s_DarLib->pPrios[i][k-1];
assert( s_DarLib->pScore[i][Out2] >= s_DarLib->pScore[i][Out] );
// printf( "%d(%d), ", Out, s_DarLib->pScore[i][Out] );
printf( "%d, ", Out );
Printed++;
if ( ++Counter == 15 )
{
printf( "\n" );
Counter = 0;
}
}
}
printf( "\n" );
assert( Printed == s_DarLib->nSubgrTotal );
}
/**Function*************************************************************
Synopsis [Matches the cut with its canonical form.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Dar_LibCutMatch( Dar_Man_t * p, Dar_Cut_t * pCut )
{
Aig_Obj_t * pFanin;
unsigned uPhase;
char * pPerm;
int i;
assert( pCut->nLeaves == 4 );
// get the fanin permutation
uPhase = s_DarLib->pPhases[pCut->uTruth];
pPerm = s_DarLib->pPerms4[ (int)s_DarLib->pPerms[pCut->uTruth] ];
// collect fanins with the corresponding permutation/phase
for ( i = 0; i < (int)pCut->nLeaves; i++ )
{
pFanin = Aig_ManObj( p->pAig, pCut->pLeaves[ (int)pPerm[i] ] );
if ( pFanin == NULL )
{
p->nCutsBad++;
return 0;
}
pFanin = Aig_NotCond(pFanin, ((uPhase >> i) & 1) );
s_DarLib->pDatas[i].pFunc = pFanin;
s_DarLib->pDatas[i].Level = Aig_Regular(pFanin)->Level;
// copy the propability of node being one
if ( p->pPars->fPower )
{
float Prob = Abc_Int2Float( Vec_IntEntry( p->pAig->vProbs, Aig_ObjId(Aig_Regular(pFanin)) ) );
s_DarLib->pDatas[i].dProb = Aig_IsComplement(pFanin)? 1.0-Prob : Prob;
}
}
p->nCutsGood++;
return 1;
}
/**Function*************************************************************
Synopsis [Marks the MFFC of the node.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Dar_LibCutMarkMffc( Aig_Man_t * p, Aig_Obj_t * pRoot, int nLeaves, float * pPower )
{
int i, nNodes;
// mark the cut leaves
for ( i = 0; i < nLeaves; i++ )
Aig_Regular(s_DarLib->pDatas[i].pFunc)->nRefs++;
// label MFFC with current ID
nNodes = Aig_NodeMffcLabel( p, pRoot, pPower );
// unmark the cut leaves
for ( i = 0; i < nLeaves; i++ )
Aig_Regular(s_DarLib->pDatas[i].pFunc)->nRefs--;
return nNodes;
}
/**Function*************************************************************
Synopsis [Evaluates one cut.]
Description [Returns the best gain.]
SideEffects []
SeeAlso []
***********************************************************************/
void Dar_LibObjPrint_rec( Dar_LibObj_t * pObj )
{
if ( pObj->fTerm )
{
printf( "%c", 'a' + (int)(pObj - s_DarLib->pObjs) );
return;
}
printf( "(" );
Dar_LibObjPrint_rec( Dar_LibObj(s_DarLib, pObj->Fan0) );
if ( pObj->fCompl0 )
printf( "\'" );
Dar_LibObjPrint_rec( Dar_LibObj(s_DarLib, pObj->Fan1) );
if ( pObj->fCompl0 )
printf( "\'" );
printf( ")" );
}
/**Function*************************************************************
Synopsis [Assigns numbers to the nodes of one class.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Dar_LibEvalAssignNums( Dar_Man_t * p, int Class, Aig_Obj_t * pRoot )
{
Dar_LibObj_t * pObj;
Dar_LibDat_t * pData, * pData0, * pData1;
Aig_Obj_t * pFanin0, * pFanin1;
int i;
for ( i = 0; i < s_DarLib->nNodes0[Class]; i++ )
{
// get one class node, assign its temporary number and set its data
pObj = Dar_LibObj(s_DarLib, s_DarLib->pNodes0[Class][i]);
pObj->Num = 4 + i;
assert( (int)pObj->Num < s_DarLib->nNodes0Max + 4 );
pData = s_DarLib->pDatas + pObj->Num;
pData->fMffc = 0;
pData->pFunc = NULL;
pData->TravId = 0xFFFF;
// explore the fanins
assert( (int)Dar_LibObj(s_DarLib, pObj->Fan0)->Num < s_DarLib->nNodes0Max + 4 );
assert( (int)Dar_LibObj(s_DarLib, pObj->Fan1)->Num < s_DarLib->nNodes0Max + 4 );
pData0 = s_DarLib->pDatas + Dar_LibObj(s_DarLib, pObj->Fan0)->Num;
pData1 = s_DarLib->pDatas + Dar_LibObj(s_DarLib, pObj->Fan1)->Num;
pData->Level = 1 + Abc_MaxInt(pData0->Level, pData1->Level);
if ( pData0->pFunc == NULL || pData1->pFunc == NULL )
continue;
pFanin0 = Aig_NotCond( pData0->pFunc, pObj->fCompl0 );
pFanin1 = Aig_NotCond( pData1->pFunc, pObj->fCompl1 );
if ( Aig_Regular(pFanin0) == pRoot || Aig_Regular(pFanin1) == pRoot )
continue;
pData->pFunc = Aig_TableLookupTwo( p->pAig, pFanin0, pFanin1 );
if ( pData->pFunc )
{
// update the level to be more accurate
pData->Level = Aig_Regular(pData->pFunc)->Level;
// mark the node if it is part of MFFC
pData->fMffc = Aig_ObjIsTravIdCurrent(p->pAig, Aig_Regular(pData->pFunc));
// assign the probability
if ( p->pPars->fPower )
{
float Prob = Abc_Int2Float( Vec_IntEntry( p->pAig->vProbs, Aig_ObjId(Aig_Regular(pData->pFunc)) ) );
pData->dProb = Aig_IsComplement(pData->pFunc)? 1.0-Prob : Prob;
}
}
}
}
/**Function*************************************************************
Synopsis [Evaluates one cut.]
Description [Returns the best gain.]
SideEffects []
SeeAlso []
***********************************************************************/
int Dar_LibEval_rec( Dar_LibObj_t * pObj, int Out, int nNodesSaved, int Required, float * pPower )
{
Dar_LibDat_t * pData;
float Power0, Power1;
int Area;
if ( pPower )
*pPower = (float)0.0;
pData = s_DarLib->pDatas + pObj->Num;
if ( pData->TravId == Out )
return 0;
pData->TravId = Out;
if ( pObj->fTerm )
{
if ( pPower )
*pPower = pData->dProb;
return 0;
}
assert( pObj->Num > 3 );
if ( pData->Level > Required )
return 0xff;
if ( pData->pFunc && !pData->fMffc )
{
if ( pPower )
*pPower = pData->dProb;
return 0;
}
// this is a new node - get a bound on the area of its branches
nNodesSaved--;
Area = Dar_LibEval_rec( Dar_LibObj(s_DarLib, pObj->Fan0), Out, nNodesSaved, Required+1, pPower? &Power0 : NULL );
if ( Area > nNodesSaved )
return 0xff;
Area += Dar_LibEval_rec( Dar_LibObj(s_DarLib, pObj->Fan1), Out, nNodesSaved, Required+1, pPower? &Power1 : NULL );
if ( Area > nNodesSaved )
return 0xff;
if ( pPower )
{
Dar_LibDat_t * pData0 = s_DarLib->pDatas + Dar_LibObj(s_DarLib, pObj->Fan0)->Num;
Dar_LibDat_t * pData1 = s_DarLib->pDatas + Dar_LibObj(s_DarLib, pObj->Fan1)->Num;
pData->dProb = (pObj->fCompl0? 1.0 - pData0->dProb : pData0->dProb)*
(pObj->fCompl1? 1.0 - pData1->dProb : pData1->dProb);
*pPower = Power0 + 2.0 * pData0->dProb * (1.0 - pData0->dProb) +
Power1 + 2.0 * pData1->dProb * (1.0 - pData1->dProb);
}
return Area + 1;
}
/**Function*************************************************************
Synopsis [Evaluates one cut.]
Description [Returns the best gain.]
SideEffects []
SeeAlso []
***********************************************************************/
void Dar_LibEval( Dar_Man_t * p, Aig_Obj_t * pRoot, Dar_Cut_t * pCut, int Required, int * pnMffcSize )
{
int fTraining = 0;
float PowerSaved, PowerAdded;
Dar_LibObj_t * pObj;
int Out, k, Class, nNodesSaved, nNodesAdded, nNodesGained, clk;
clk = clock();
if ( pCut->nLeaves != 4 )
return;
// check if the cut exits and assigns leaves and their levels
if ( !Dar_LibCutMatch(p, pCut) )
return;
// mark MFFC of the node
nNodesSaved = Dar_LibCutMarkMffc( p->pAig, pRoot, pCut->nLeaves, p->pPars->fPower? &PowerSaved : NULL );
// evaluate the cut
Class = s_DarLib->pMap[pCut->uTruth];
Dar_LibEvalAssignNums( p, Class, pRoot );
// profile outputs by their savings
p->nTotalSubgs += s_DarLib->nSubgr0[Class];
p->ClassSubgs[Class] += s_DarLib->nSubgr0[Class];
for ( Out = 0; Out < s_DarLib->nSubgr0[Class]; Out++ )
{
pObj = Dar_LibObj(s_DarLib, s_DarLib->pSubgr0[Class][Out]);
if ( Aig_Regular(s_DarLib->pDatas[pObj->Num].pFunc) == pRoot )
continue;
nNodesAdded = Dar_LibEval_rec( pObj, Out, nNodesSaved - !p->pPars->fUseZeros, Required, p->pPars->fPower? &PowerAdded : NULL );
nNodesGained = nNodesSaved - nNodesAdded;
if ( p->pPars->fPower && PowerSaved < PowerAdded )
continue;
if ( fTraining && nNodesGained >= 0 )
Dar_LibIncrementScore( Class, Out, nNodesGained + 1 );
if ( nNodesGained < 0 || (nNodesGained == 0 && !p->pPars->fUseZeros) )
continue;
if ( nNodesGained < p->GainBest ||
(nNodesGained == p->GainBest && s_DarLib->pDatas[pObj->Num].Level >= p->LevelBest) )
continue;
// remember this possibility
Vec_PtrClear( p->vLeavesBest );
for ( k = 0; k < (int)pCut->nLeaves; k++ )
Vec_PtrPush( p->vLeavesBest, s_DarLib->pDatas[k].pFunc );
p->OutBest = s_DarLib->pSubgr0[Class][Out];
p->OutNumBest = Out;
p->LevelBest = s_DarLib->pDatas[pObj->Num].Level;
p->GainBest = nNodesGained;
p->ClassBest = Class;
assert( p->LevelBest <= Required );
*pnMffcSize = nNodesSaved;
}
clk = clock() - clk;
p->ClassTimes[Class] += clk;
p->timeEval += clk;
}
/**Function*************************************************************
Synopsis [Clears the fields of the nodes used in this cut.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Dar_LibBuildClear_rec( Dar_LibObj_t * pObj, int * pCounter )
{
if ( pObj->fTerm )
return;
pObj->Num = (*pCounter)++;
s_DarLib->pDatas[ pObj->Num ].pFunc = NULL;
Dar_LibBuildClear_rec( Dar_LibObj(s_DarLib, pObj->Fan0), pCounter );
Dar_LibBuildClear_rec( Dar_LibObj(s_DarLib, pObj->Fan1), pCounter );
}
/**Function*************************************************************
Synopsis [Reconstructs the best cut.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Aig_Obj_t * Dar_LibBuildBest_rec( Dar_Man_t * p, Dar_LibObj_t * pObj )
{
Aig_Obj_t * pFanin0, * pFanin1;
Dar_LibDat_t * pData = s_DarLib->pDatas + pObj->Num;
if ( pData->pFunc )
return pData->pFunc;
pFanin0 = Dar_LibBuildBest_rec( p, Dar_LibObj(s_DarLib, pObj->Fan0) );
pFanin1 = Dar_LibBuildBest_rec( p, Dar_LibObj(s_DarLib, pObj->Fan1) );
pFanin0 = Aig_NotCond( pFanin0, pObj->fCompl0 );
pFanin1 = Aig_NotCond( pFanin1, pObj->fCompl1 );
pData->pFunc = Aig_And( p->pAig, pFanin0, pFanin1 );
// assert( pData->Level == (int)Aig_Regular(pData->pFunc)->Level );
return pData->pFunc;
}
/**Function*************************************************************
Synopsis [Reconstructs the best cut.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Aig_Obj_t * Dar_LibBuildBest( Dar_Man_t * p )
{
int i, Counter = 4;
for ( i = 0; i < Vec_PtrSize(p->vLeavesBest); i++ )
s_DarLib->pDatas[i].pFunc = (Aig_Obj_t *)Vec_PtrEntry( p->vLeavesBest, i );
Dar_LibBuildClear_rec( Dar_LibObj(s_DarLib, p->OutBest), &Counter );
return Dar_LibBuildBest_rec( p, Dar_LibObj(s_DarLib, p->OutBest) );
}
/**Function*************************************************************
Synopsis [Matches the cut with its canonical form.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Dar2_LibCutMatch( Gia_Man_t * p, Vec_Int_t * vCutLits, unsigned uTruth )
{
unsigned uPhase;
char * pPerm;
int i;
assert( Vec_IntSize(vCutLits) == 4 );
// get the fanin permutation
uPhase = s_DarLib->pPhases[uTruth];
pPerm = s_DarLib->pPerms4[ (int)s_DarLib->pPerms[uTruth] ];
// collect fanins with the corresponding permutation/phase
for ( i = 0; i < Vec_IntSize(vCutLits); i++ )
{
// pFanin = Gia_ManObj( p, pCut->pLeaves[ (int)pPerm[i] ] );
// pFanin = Gia_ManObj( p, Vec_IntEntry( vCutLits, (int)pPerm[i] ) );
// pFanin = Gia_ObjFromLit( p, Vec_IntEntry( vCutLits, (int)pPerm[i] ) );
s_DarLib->pDatas[i].iGunc = Abc_LitNotCond( Vec_IntEntry(vCutLits, (int)pPerm[i]), ((uPhase >> i) & 1) );
s_DarLib->pDatas[i].Level = Gia_ObjLevel( p, Gia_Regular(Gia_ObjFromLit(p, s_DarLib->pDatas[i].iGunc)) );
}
return 1;
}
/**Function*************************************************************
Synopsis [Assigns numbers to the nodes of one class.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Dar2_LibEvalAssignNums( Gia_Man_t * p, int Class )
{
Dar_LibObj_t * pObj;
Dar_LibDat_t * pData, * pData0, * pData1;
int iFanin0, iFanin1, i, iLit;
for ( i = 0; i < s_DarLib->nNodes0[Class]; i++ )
{
// get one class node, assign its temporary number and set its data
pObj = Dar_LibObj(s_DarLib, s_DarLib->pNodes0[Class][i]);
pObj->Num = 4 + i;
assert( (int)pObj->Num < s_DarLib->nNodes0Max + 4 );
pData = s_DarLib->pDatas + pObj->Num;
pData->fMffc = 0;
pData->iGunc = -1;
pData->TravId = 0xFFFF;
// explore the fanins
assert( (int)Dar_LibObj(s_DarLib, pObj->Fan0)->Num < s_DarLib->nNodes0Max + 4 );
assert( (int)Dar_LibObj(s_DarLib, pObj->Fan1)->Num < s_DarLib->nNodes0Max + 4 );
pData0 = s_DarLib->pDatas + Dar_LibObj(s_DarLib, pObj->Fan0)->Num;
pData1 = s_DarLib->pDatas + Dar_LibObj(s_DarLib, pObj->Fan1)->Num;
pData->Level = 1 + Abc_MaxInt(pData0->Level, pData1->Level);
if ( pData0->iGunc == -1 || pData1->iGunc == -1 )
continue;
iFanin0 = Abc_LitNotCond( pData0->iGunc, pObj->fCompl0 );
iFanin1 = Abc_LitNotCond( pData1->iGunc, pObj->fCompl1 );
// compute the resulting literal
if ( iFanin0 == 0 || iFanin1 == 0 || iFanin0 == Abc_LitNot(iFanin1) )
iLit = 0;
else if ( iFanin0 == 1 || iFanin0 == iFanin1 )
iLit = iFanin1;
else if ( iFanin1 == 1 )
iLit = iFanin0;
else
{
iLit = Gia_ManHashLookup( p, Gia_ObjFromLit(p, iFanin0), Gia_ObjFromLit(p, iFanin1) );
if ( iLit == 0 )
iLit = -1;
}
pData->iGunc = iLit;
if ( pData->iGunc >= 0 )
{
// update the level to be more accurate
pData->Level = Gia_ObjLevel( p, Gia_Regular(Gia_ObjFromLit(p, pData->iGunc)) );
// mark the node if it is part of MFFC
// pData->fMffc = Gia_ObjIsTravIdCurrentArray(p, Gia_Regular(pData->pGunc));
}
}
}
/**Function*************************************************************
Synopsis [Evaluates one cut.]
Description [Returns the best gain.]
SideEffects []
SeeAlso []
***********************************************************************/
int Dar2_LibEval_rec( Dar_LibObj_t * pObj, int Out )
{
Dar_LibDat_t * pData;
int Area;
pData = s_DarLib->pDatas + pObj->Num;
if ( pData->TravId == Out )
return 0;
pData->TravId = Out;
if ( pObj->fTerm )
return 0;
assert( pObj->Num > 3 );
if ( pData->iGunc >= 0 )//&& !pData->fMffc )
return 0;
// this is a new node - get a bound on the area of its branches
// nNodesSaved--;
Area = Dar2_LibEval_rec( Dar_LibObj(s_DarLib, pObj->Fan0), Out );
// if ( Area > nNodesSaved )
// return 0xff;
Area += Dar2_LibEval_rec( Dar_LibObj(s_DarLib, pObj->Fan1), Out );
// if ( Area > nNodesSaved )
// return 0xff;
return Area + 1;
}
/**Function*************************************************************
Synopsis [Evaluates one cut.]
Description [Returns the best gain.]
SideEffects []
SeeAlso []
***********************************************************************/
int Dar2_LibEval( Gia_Man_t * p, Vec_Int_t * vCutLits, unsigned uTruth, int fKeepLevel, Vec_Int_t * vLeavesBest2 )
{
int p_OutBest = -1;
int p_OutNumBest = -1;
int p_LevelBest = 1000000;
int p_GainBest = -1000000;
int p_ClassBest = -1;
// int fTraining = 0;
Dar_LibObj_t * pObj;
int Out, k, Class, nNodesSaved, nNodesAdded, nNodesGained, clk;
clk = clock();
assert( Vec_IntSize(vCutLits) == 4 );
assert( (uTruth >> 16) == 0 );
// check if the cut exits and assigns leaves and their levels
if ( !Dar2_LibCutMatch(p, vCutLits, uTruth) )
return -1;
// mark MFFC of the node
// nNodesSaved = Dar2_LibCutMarkMffc( p->pAig, pRoot, pCut->nLeaves, p->pPars->fPower? &PowerSaved : NULL );
nNodesSaved = 0;
// evaluate the cut
Class = s_DarLib->pMap[uTruth];
Dar2_LibEvalAssignNums( p, Class );
// profile outputs by their savings
// p->nTotalSubgs += s_DarLib->nSubgr0[Class];
// p->ClassSubgs[Class] += s_DarLib->nSubgr0[Class];
for ( Out = 0; Out < s_DarLib->nSubgr0[Class]; Out++ )
{
pObj = Dar_LibObj(s_DarLib, s_DarLib->pSubgr0[Class][Out]);
// nNodesAdded = Dar2_LibEval_rec( pObj, Out, nNodesSaved - !p->pPars->fUseZeros, Required, p->pPars->fPower? &PowerAdded : NULL );
nNodesAdded = Dar2_LibEval_rec( pObj, Out );
nNodesGained = nNodesSaved - nNodesAdded;
if ( fKeepLevel )
{
if ( s_DarLib->pDatas[pObj->Num].Level > p_LevelBest ||
(s_DarLib->pDatas[pObj->Num].Level == p_LevelBest && nNodesGained <= p_GainBest) )
continue;
}
else
{
if ( nNodesGained < p_GainBest ||
(nNodesGained == p_GainBest && s_DarLib->pDatas[pObj->Num].Level >= p_LevelBest) )
continue;
}
// remember this possibility
Vec_IntClear( vLeavesBest2 );
for ( k = 0; k < Vec_IntSize(vCutLits); k++ )
Vec_IntPush( vLeavesBest2, s_DarLib->pDatas[k].iGunc );
p_OutBest = s_DarLib->pSubgr0[Class][Out];
p_OutNumBest = Out;
p_LevelBest = s_DarLib->pDatas[pObj->Num].Level;
p_GainBest = nNodesGained;
p_ClassBest = Class;
// assert( p_LevelBest <= Required );
}
//clk = clock() - clk;
//p->ClassTimes[Class] += clk;
//p->timeEval += clk;
assert( p_OutBest != -1 );
return p_OutBest;
}
/**Function*************************************************************
Synopsis [Clears the fields of the nodes used i this cut.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Dar2_LibBuildClear_rec( Dar_LibObj_t * pObj, int * pCounter )
{
if ( pObj->fTerm )
return;
pObj->Num = (*pCounter)++;
s_DarLib->pDatas[ pObj->Num ].iGunc = -1;
Dar2_LibBuildClear_rec( Dar_LibObj(s_DarLib, pObj->Fan0), pCounter );
Dar2_LibBuildClear_rec( Dar_LibObj(s_DarLib, pObj->Fan1), pCounter );
}
/**Function*************************************************************
Synopsis [Reconstructs the best cut.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Dar2_LibBuildBest_rec( Gia_Man_t * p, Dar_LibObj_t * pObj )
{
Gia_Obj_t * pNode;
Dar_LibDat_t * pData;
int iFanin0, iFanin1;
pData = s_DarLib->pDatas + pObj->Num;
if ( pData->iGunc >= 0 )
return pData->iGunc;
iFanin0 = Dar2_LibBuildBest_rec( p, Dar_LibObj(s_DarLib, pObj->Fan0) );
iFanin1 = Dar2_LibBuildBest_rec( p, Dar_LibObj(s_DarLib, pObj->Fan1) );
iFanin0 = Abc_LitNotCond( iFanin0, pObj->fCompl0 );
iFanin1 = Abc_LitNotCond( iFanin1, pObj->fCompl1 );
pData->iGunc = Gia_ManHashAnd( p, iFanin0, iFanin1 );
pNode = Gia_ManObj( p, Abc_Lit2Var(pData->iGunc) );
if ( Gia_ObjIsAnd( pNode ) )
Gia_ObjSetAndLevel( p, pNode );
Gia_ObjSetPhase( pNode );
return pData->iGunc;
}
/**Function*************************************************************
Synopsis [Reconstructs the best cut.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Dar2_LibBuildBest( Gia_Man_t * p, Vec_Int_t * vLeavesBest2, int OutBest )
{
int i, iLeaf, Counter = 4;
assert( Vec_IntSize(vLeavesBest2) == 4 );
Vec_IntForEachEntry( vLeavesBest2, iLeaf, i )
s_DarLib->pDatas[i].iGunc = iLeaf;
Dar2_LibBuildClear_rec( Dar_LibObj(s_DarLib, OutBest), &Counter );
return Dar2_LibBuildBest_rec( p, Dar_LibObj(s_DarLib, OutBest) );
}
/**Function*************************************************************
Synopsis [Evaluate and build the new node.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Dar_LibEvalBuild( Gia_Man_t * p, Vec_Int_t * vCutLits, unsigned uTruth, int fKeepLevel, Vec_Int_t * vLeavesBest2 )
{
int OutBest = Dar2_LibEval( p, vCutLits, uTruth, fKeepLevel, vLeavesBest2 );
return Dar2_LibBuildBest( p, vLeavesBest2, OutBest );
}
////////////////////////////////////////////////////////////////////////
/// END OF FILE ///
////////////////////////////////////////////////////////////////////////
ABC_NAMESPACE_IMPL_END
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