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abc
Commit 73b8d1dd by Alan Mishchenko
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Version abc60419

parent c1710767
Showing with 1388 additions and 165 deletions
abc.dsp
......@@ -502,7 +502,11 @@ SOURCE=.\src\base\io\ioWritePla.c
# End Source File
# Begin Source File
SOURCE=.\src\base\io\ioWriteVerilog.c
SOURCE=.\src\base\io\ioWriteVer.c
# End Source File
# Begin Source File
SOURCE=.\src\base\io\ioWriteVerAux.c
# End Source File
# End Group
# Begin Group "main"
......@@ -1302,6 +1306,10 @@ SOURCE=.\src\opt\cut\cutCut.c
# End Source File
# Begin Source File
SOURCE=.\src\opt\cut\cutExpand.c
# End Source File
# Begin Source File
SOURCE=.\src\opt\cut\cutInt.h
# End Source File
# Begin Source File
......
src/base/abc/abcAig.c
......@@ -743,6 +743,7 @@ void Abc_AigReplace( Abc_Aig_t * pMan, Abc_Obj_t * pOld, Abc_Obj_t * pNew, bool
if ( fUpdateLevel )
{
Abc_AigUpdateLevel_int( pMan );
if ( pMan->pNtkAig->vLevelsR )
Abc_AigUpdateLevelR_int( pMan );
}
}
......@@ -819,10 +820,13 @@ void Abc_AigReplace_int( Abc_Aig_t * pMan, Abc_Obj_t * pOld, Abc_Obj_t * pNew, i
pFanout->fMarkA = 1;
Vec_VecPush( pMan->vLevels, pFanout->Level, pFanout );
// schedule the updated fanout for updating reverse level
if ( pMan->pNtkAig->vLevelsR )
{
assert( pFanout->fMarkB == 0 );
pFanout->fMarkB = 1;
Vec_VecPush( pMan->vLevelsR, Abc_NodeReadReverseLevel(pFanout), pFanout );
}
}
// the fanout has changed, update EXOR status of its fanouts
Abc_ObjForEachFanout( pFanout, pFanoutFanout, v )
......
src/base/abc/abcObj.c
......@@ -235,7 +235,7 @@ void Abc_NtkDeleteObj( Abc_Obj_t * pObj )
}
else if ( Abc_ObjIsPo(pObj) )
{
assert( Abc_NtkPoNum(pObj->pNtk) == 1 );
assert( Abc_NtkPoNum(pObj->pNtk) > 0 );
Vec_PtrRemove( pObj->pNtk->vCos, pObj );
pObj->pNtk->nPos--;
// add the name to the table
......
src/base/abci/abc.c
......@@ -69,6 +69,7 @@ static int Abc_CommandRr ( Abc_Frame_t * pAbc, int argc, char ** argv
static int Abc_CommandLogic ( Abc_Frame_t * pAbc, int argc, char ** argv );
static int Abc_CommandMiter ( Abc_Frame_t * pAbc, int argc, char ** argv );
static int Abc_CommandDemiter ( Abc_Frame_t * pAbc, int argc, char ** argv );
static int Abc_CommandOrPos ( Abc_Frame_t * pAbc, int argc, char ** argv );
static int Abc_CommandFrames ( Abc_Frame_t * pAbc, int argc, char ** argv );
static int Abc_CommandSop ( Abc_Frame_t * pAbc, int argc, char ** argv );
static int Abc_CommandBdd ( Abc_Frame_t * pAbc, int argc, char ** argv );
......@@ -178,6 +179,7 @@ void Abc_Init( Abc_Frame_t * pAbc )
// Cmd_CommandAdd( pAbc, "Various", "logic", Abc_CommandLogic, 1 );
Cmd_CommandAdd( pAbc, "Various", "miter", Abc_CommandMiter, 1 );
Cmd_CommandAdd( pAbc, "Various", "demiter", Abc_CommandDemiter, 1 );
Cmd_CommandAdd( pAbc, "Various", "orpos", Abc_CommandOrPos, 1 );
Cmd_CommandAdd( pAbc, "Various", "frames", Abc_CommandFrames, 1 );
Cmd_CommandAdd( pAbc, "Various", "sop", Abc_CommandSop, 0 );
Cmd_CommandAdd( pAbc, "Various", "bdd", Abc_CommandBdd, 0 );
......@@ -2866,8 +2868,8 @@ int Abc_CommandRr( Abc_Frame_t * pAbc, int argc, char ** argv )
usage:
fprintf( pErr, "usage: rr [-W NM] [-fvh]\n" );
fprintf( pErr, "\t performs redundancy removal in the current network\n" );
fprintf( pErr, "\t-W NM : window size as the number of TFI (N) and TFO (M) logic levels [default = %d%d]\n", nFaninLevels, nFanoutLevels );
fprintf( pErr, "\t removes combinational redundancies in the current network\n" );
fprintf( pErr, "\t-W NM : window size: TFI (N) and TFO (M) logic levels [default = %d%d]\n", nFaninLevels, nFanoutLevels );
fprintf( pErr, "\t-f : toggle RR w.r.t. fanouts [default = %s]\n", fUseFanouts? "yes": "no" );
fprintf( pErr, "\t-v : toggle verbose printout [default = %s]\n", fVerbose? "yes": "no" );
fprintf( pErr, "\t-h : print the command usage\n");
......@@ -3027,10 +3029,10 @@ usage:
int Abc_CommandDemiter( Abc_Frame_t * pAbc, int argc, char ** argv )
{
FILE * pOut, * pErr;
Abc_Ntk_t * pNtk, * pNtkRes;
Abc_Ntk_t * pNtk;//, * pNtkRes;
int fComb;
int c;
extern Abc_Ntk_t * Abc_NtkDemiter( Abc_Ntk_t * pNtk );
extern int Abc_NtkDemiter( Abc_Ntk_t * pNtk );
pNtk = Abc_FrameReadNtk(pAbc);
pOut = Abc_FrameReadOut(pAbc);
......@@ -3062,17 +3064,16 @@ int Abc_CommandDemiter( Abc_Frame_t * pAbc, int argc, char ** argv )
return 1;
}
if ( !Abc_ObjFanin0(Abc_NtkPo(pNtk,0))->fExor )
if ( !Abc_NodeIsExorType(Abc_ObjFanin0(Abc_NtkPo(pNtk,0))) )
{
fprintf( pErr, "The miter's PO is not an EXOR.\n" );
return 1;
}
// get the new network
pNtkRes = Abc_NtkDemiter( pNtk );
if ( pNtkRes == NULL )
if ( !Abc_NtkDemiter( pNtk ) )
{
fprintf( pErr, "Miter computation has failed.\n" );
fprintf( pErr, "Demitering has failed.\n" );
return 1;
}
// replace the current network
......@@ -3098,6 +3099,79 @@ usage:
SeeAlso []
***********************************************************************/
int Abc_CommandOrPos( Abc_Frame_t * pAbc, int argc, char ** argv )
{
FILE * pOut, * pErr;
Abc_Ntk_t * pNtk;//, * pNtkRes;
int fComb;
int c;
extern int Abc_NtkOrPos( Abc_Ntk_t * pNtk );
pNtk = Abc_FrameReadNtk(pAbc);
pOut = Abc_FrameReadOut(pAbc);
pErr = Abc_FrameReadErr(pAbc);
// set defaults
Extra_UtilGetoptReset();
while ( ( c = Extra_UtilGetopt( argc, argv, "ch" ) ) != EOF )
{
switch ( c )
{
case 'c':
fComb ^= 1;
break;
default:
goto usage;
}
}
if ( !Abc_NtkIsStrash(pNtk) )
{
fprintf( pErr, "The network is not strashed.\n" );
return 1;
}
if ( Abc_NtkPoNum(pNtk) == 1 )
{
fprintf( pErr, "The network already has one PO.\n" );
return 1;
}
if ( Abc_NtkLatchNum(pNtk) )
{
fprintf( pErr, "The miter has latches. ORing is not performed.\n" );
return 1;
}
// get the new network
if ( !Abc_NtkOrPos( pNtk ) )
{
fprintf( pErr, "ORing the POs has failed.\n" );
return 1;
}
// replace the current network
// Abc_FrameReplaceCurrentNetwork( pAbc, pNtkRes );
return 0;
usage:
fprintf( pErr, "usage: orpos [-h]\n" );
fprintf( pErr, "\t creates single-output miter by ORing the POs of the current network\n" );
// fprintf( pErr, "\t-c : computes combinational miter (latches as POs) [default = %s]\n", fComb? "yes": "no" );
fprintf( pErr, "\t-h : print the command usage\n");
return 1;
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Abc_CommandFrames( Abc_Frame_t * pAbc, int argc, char ** argv )
{
FILE * pOut, * pErr;
......@@ -4540,15 +4614,15 @@ int Abc_CommandTest( Abc_Frame_t * pAbc, int argc, char ** argv )
// Cut_CellDumpToFile();
// else
// Cut_CellPrecompute();
// Cut_CellLoad();
Cut_CellLoad();
/*
{
Abc_Ntk_t * pNtkRes;
extern Abc_Ntk_t * Abc_NtkTopmost( Abc_Ntk_t * pNtk, int nLevels );
pNtkRes = Abc_NtkTopmost( pNtk, nLevels );
Abc_FrameReplaceCurrentNetwork( pAbc, pNtkRes );
}
*/
return 0;
usage:
......
src/base/abci/abcFraig.c
......@@ -704,6 +704,7 @@ Abc_Ntk_t * Abc_NtkFraigRestore()
Fraig_Params_t Params;
Abc_Ntk_t * pStore, * pFraig;
int nWords1, nWords2, nWordsMin;
int clk = clock();
// get the stored network
pStore = Abc_FrameReadNtkStore();
......@@ -740,6 +741,7 @@ Abc_Ntk_t * Abc_NtkFraigRestore()
// Fraig_ManReportChoices( p );
// transform it into FRAIG
pFraig = Abc_NtkFraig( pStore, &Params, 1, 0 );
PRT( "Total fraiging time", clock() - clk );
if ( pFraig == NULL )
return NULL;
Abc_NtkDelete( pStore );
......
src/base/abci/abcMiter.c
......@@ -957,7 +957,7 @@ void Abc_NtkAddFrame2( Abc_Ntk_t * pNtkFrames, Abc_Ntk_t * pNtk, int iFrame, Vec
/**Function*************************************************************
Synopsis [Derives the timeframes of the network.]
Synopsis [Splits the miter into two logic cones combined by an EXOR]
Description []
......@@ -966,7 +966,7 @@ void Abc_NtkAddFrame2( Abc_Ntk_t * pNtkFrames, Abc_Ntk_t * pNtk, int iFrame, Vec
SeeAlso []
***********************************************************************/
Abc_Ntk_t * Abc_NtkDemiter( Abc_Ntk_t * pNtk )
int Abc_NtkDemiter( Abc_Ntk_t * pNtk )
{
Abc_Obj_t * pNodeC, * pNodeA, * pNodeB, * pNode;
Abc_Obj_t * pPoNew;
......@@ -975,22 +975,33 @@ Abc_Ntk_t * Abc_NtkDemiter( Abc_Ntk_t * pNtk )
assert( Abc_NtkIsStrash(pNtk) );
assert( Abc_NtkPoNum(pNtk) == 1 );
assert( Abc_ObjFanin0(Abc_NtkPo(pNtk,0))->fExor );
if ( !Abc_NodeIsExorType(Abc_ObjFanin0(Abc_NtkPo(pNtk,0))) )
{
printf( "The root of the miter is not an EXOR gate.\n" );
return 0;
}
pNodeC = Abc_NodeRecognizeMux( Abc_ObjFanin0(Abc_NtkPo(pNtk,0)), &pNodeA, &pNodeB );
assert( Abc_ObjRegular(pNodeA) == Abc_ObjRegular(pNodeB) );
if ( Abc_ObjFaninC0(Abc_NtkPo(pNtk,0)) )
{
pNodeA = Abc_ObjNot(pNodeA);
pNodeB = Abc_ObjNot(pNodeB);
}
// add the PO corresponding to control input
pPoNew = Abc_NtkCreatePo( pNtk );
Abc_ObjAddFanin( pPoNew, pNodeC );
Abc_NtkLogicStoreName( pPoNew, "addOut1" );
// add the PO corresponding to other input
pPoNew = Abc_NtkCreatePo( pNtk );
Abc_ObjAddFanin( pPoNew, Abc_ObjRegular(pNodeA) );
Abc_ObjAddFanin( pPoNew, pNodeB );
Abc_NtkLogicStoreName( pPoNew, "addOut2" );
// mark the nodes in the first cone
pNodeA = Abc_ObjRegular(pNodeA);
pNodeB = Abc_ObjRegular(pNodeB);
vNodes1 = Abc_NtkDfsNodes( pNtk, &pNodeC, 1 );
vNodes2 = Abc_NtkDfsNodes( pNtk, &pNodeA, 1 );
vNodes2 = Abc_NtkDfsNodes( pNtk, &pNodeB, 1 );
Vec_PtrForEachEntry( vNodes1, pNode, i )
pNode->fMarkA = 1;
......@@ -1003,9 +1014,45 @@ Abc_Ntk_t * Abc_NtkDemiter( Abc_Ntk_t * pNtk )
printf( "First cone = %6d. Second cone = %6d. Common = %6d.\n", vNodes1->nSize, vNodes2->nSize, nCommon );
Vec_PtrFree( vNodes1 );
Vec_PtrFree( vNodes2 );
return 1;
}
/**Function*************************************************************
Synopsis [ORs the outputs.]
return pNtk;
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Abc_NtkOrPos( Abc_Ntk_t * pNtk )
{
Abc_Obj_t * pNode, * pMiter;
int i;
assert( Abc_NtkIsStrash(pNtk) );
assert( Abc_NtkLatchNum(pNtk) == 0 );
// OR the POs
pMiter = Abc_ObjNot( Abc_NtkConst1(pNtk) );
Abc_NtkForEachPo( pNtk, pNode, i )
pMiter = Abc_AigOr( pNtk->pManFunc, pMiter, Abc_ObjChild0(pNode) );
// remove the POs and their names
for ( i = Abc_NtkPoNum(pNtk) - 1; i >= 0; i-- )
Abc_NtkDeleteObj( Abc_NtkPo(pNtk, i) );
assert( Abc_NtkPoNum(pNtk) == 0 );
// create the new PO
pNode = Abc_NtkCreatePo( pNtk );
Abc_ObjAddFanin( pNode, pMiter );
Abc_NtkLogicStoreName( pNode, "miter" );
// make sure that everything is okay
if ( !Abc_NtkCheck( pNtk ) )
{
printf( "Abc_NtkOrPos: The network check has failed.\n" );
return 0;
}
return 1;
}
////////////////////////////////////////////////////////////////////////
......
src/base/abci/abcPrint.c
......@@ -70,10 +70,10 @@ void Abc_NtkPrintStats( FILE * pFile, Abc_Ntk_t * pNtk, int fFactored )
fprintf( pFile, " (choice = %d)", Num );
if ( Num = Abc_NtkGetExorNum(pNtk) )
fprintf( pFile, " (exor = %d)", Num );
if ( Num2 = Abc_NtkGetMuxNum(pNtk) )
fprintf( pFile, " (mux = %d)", Num2-Num );
if ( Num2 )
fprintf( pFile, " (other = %d)", Abc_NtkNodeNum(pNtk)-3*Num2 );
// if ( Num2 = Abc_NtkGetMuxNum(pNtk) )
// fprintf( pFile, " (mux = %d)", Num2-Num );
// if ( Num2 )
// fprintf( pFile, " (other = %d)", Abc_NtkNodeNum(pNtk)-3*Num2 );
}
else
fprintf( pFile, " nd = %5d", Abc_NtkNodeNum(pNtk) );
......@@ -110,11 +110,9 @@ void Abc_NtkPrintStats( FILE * pFile, Abc_Ntk_t * pNtk, int fFactored )
FILE * pTable;
pTable = fopen( "stats.txt", "a+" );
fprintf( pTable, "%s ", pNtk->pName );
fprintf( pTable, "%4d ", Abc_NtkPiNum(pNtk) );
fprintf( pTable, "%4d ", Abc_NtkPoNum(pNtk) );
// fprintf( pTable, "%4d ", Abc_NtkLatchNum(pNtk) );
fprintf( pTable, "%6d ", Abc_NtkNodeNum(pNtk) );
fprintf( pTable, "%6d ", Abc_AigGetLevelNum(pNtk) );
fprintf( pTable, "%d ", Abc_NtkPiNum(pNtk) );
fprintf( pTable, "%d ", Abc_NtkNodeNum(pNtk) );
fprintf( pTable, "%d ", Abc_AigGetLevelNum(pNtk) );
fprintf( pTable, "\n" );
fclose( pTable );
}
......
src/base/abci/abcRr.c
......@@ -20,6 +20,7 @@
#include "abc.h"
#include "fraig.h"
#include "sim.h"
////////////////////////////////////////////////////////////////////////
/// DECLARATIONS ///
......@@ -47,21 +48,34 @@ struct Abc_RRMan_t_
// the miter
Abc_Ntk_t * pMiter; // the miter derived from the window
Prove_Params_t * pParams; // the miter proving parameters
// statistical variables
int nNodesOld; // the old number of nodes
int nLevelsOld; // the old number of levels
int nEdgesTried; // the number of nodes tried
int nEdgesRemoved; // the number of nodes proved
int timeWindow; // the time to construct the window
int timeMiter; // the time to construct the miter
int timeProve; // the time to prove the miter
int timeUpdate; // the network update time
int timeTotal; // the total runtime
};
static Abc_RRMan_t * Abc_RRManStart();
static void Abc_RRManStop( Abc_RRMan_t * p );
static void Abc_RRManPrintStats( Abc_RRMan_t * p );
static void Abc_RRManClean( Abc_RRMan_t * p );
static int Abc_NtkRRProve( Abc_RRMan_t * p );
static int Abc_NtkRRUpdate( Abc_Ntk_t * pNtk, Abc_Obj_t * pNode, Abc_Obj_t * pFanin, Abc_Obj_t * pFanout );
static int Abc_NtkRRWindow( Abc_RRMan_t * p );
static int Abc_NtkRRTfi_int( Vec_Ptr_t * vFaninLeaves, int LevelLimit );
static int Abc_NtkRRTfo_int( Vec_Ptr_t * vFanoutRoots, int LevelLimit, Abc_Obj_t * pEdgeFanin, Abc_Obj_t * pEdgeFanout );
static int Abc_NtkRRTfi_int( Vec_Ptr_t * vLeaves, int LevelLimit );
static int Abc_NtkRRTfo_int( Vec_Ptr_t * vLeaves, Vec_Ptr_t * vRoots, int LevelLimit, Abc_Obj_t * pEdgeFanin, Abc_Obj_t * pEdgeFanout );
static int Abc_NtkRRTfo_rec( Abc_Obj_t * pNode, Vec_Ptr_t * vRoots, int LevelLimit );
static void Abc_NtkRRTfi_rec( Abc_Obj_t * pNode, Vec_Ptr_t * vLeaves, Vec_Ptr_t * vCone );
static void Abc_NtkRRTfi_rec( Abc_Obj_t * pNode, Vec_Ptr_t * vLeaves, Vec_Ptr_t * vCone, int LevelLimit );
static Abc_Ntk_t * Abc_NtkWindow( Abc_Ntk_t * pNtk, Vec_Ptr_t * vLeaves, Vec_Ptr_t * vCone, Vec_Ptr_t * vRoots );
static void Abc_NtkRRSimulateStart( Abc_Ntk_t * pNtk );
static void Abc_NtkRRSimulateStop( Abc_Ntk_t * pNtk );
////////////////////////////////////////////////////////////////////////
/// FUNCTION DEFINITIONS ///
......@@ -83,14 +97,18 @@ int Abc_NtkRR( Abc_Ntk_t * pNtk, int nFaninLevels, int nFanoutLevels, int fUseFa
ProgressBar * pProgress;
Abc_RRMan_t * p;
Abc_Obj_t * pNode, * pFanin, * pFanout;
int i, k, m, nNodes;
int i, k, m, nNodes, RetValue, clk, clkTotal = clock();
// start the manager
p = Abc_RRManStart( nFaninLevels, nFanoutLevels );
p->pNtk = pNtk;
p->nFaninLevels = nFaninLevels;
p->nFanoutLevels = nFanoutLevels;
p->nNodesOld = Abc_NtkNodeNum(pNtk);
p->nLevelsOld = Abc_AigGetLevelNum(pNtk);
// go through the nodes
Abc_NtkCleanCopy(pNtk);
nNodes = Abc_NtkObjNumMax(pNtk);
Abc_NtkRRSimulateStart(pNtk);
pProgress = Extra_ProgressBarStart( stdout, nNodes );
Abc_NtkForEachNode( pNtk, pNode, i )
{
......@@ -109,36 +127,87 @@ int Abc_NtkRR( Abc_Ntk_t * pNtk, int nFaninLevels, int nFanoutLevels, int fUseFa
{
Abc_ObjForEachFanin( pNode, pFanin, k )
{
// skip the nodes with only one fanout (tree nodes)
if ( Abc_ObjFanoutNum(pFanin) == 1 )
continue;
/*
if ( pFanin->Id == 228 && pNode->Id == 2649 )
{
int k = 0;
}
*/
p->nEdgesTried++;
Abc_RRManClean( p );
p->pNode = pNode;
p->pFanin = pFanin;
p->pFanout = NULL;
if ( !Abc_NtkRRWindow( p ) )
clk = clock();
RetValue = Abc_NtkRRWindow( p );
p->timeWindow += clock() - clk;
if ( !RetValue )
continue;
if ( !Abc_NtkRRProve( p ) )
/*
if ( pFanin->Id == 228 && pNode->Id == 2649 )
{
Abc_NtkShowAig( p->pWnd, 0 );
}
*/
clk = clock();
RetValue = Abc_NtkRRProve( p );
p->timeMiter += clock() - clk;
if ( !RetValue )
continue;
//printf( "%d -> %d (%d)\n", pFanin->Id, pNode->Id, k );
clk = clock();
Abc_NtkRRUpdate( pNtk, p->pNode, p->pFanin, p->pFanout );
p->timeUpdate += clock() - clk;
p->nEdgesRemoved++;
break;
}
continue;
}
// use the fanouts
Abc_ObjForEachFanout( pNode, pFanout, m )
Abc_ObjForEachFanin( pNode, pFanin, k )
Abc_ObjForEachFanout( pNode, pFanout, m )
{
// skip the nodes with only one fanout (tree nodes)
// if ( Abc_ObjFanoutNum(pFanin) == 1 && Abc_ObjFanoutNum(pNode) == 1 )
// continue;
p->nEdgesTried++;
Abc_RRManClean( p );
p->pNode = pNode;
p->pFanin = pFanin;
p->pFanout = pFanout;
if ( !Abc_NtkRRWindow( p ) )
clk = clock();
RetValue = Abc_NtkRRWindow( p );
p->timeWindow += clock() - clk;
if ( !RetValue )
continue;
if ( !Abc_NtkRRProve( p ) )
clk = clock();
RetValue = Abc_NtkRRProve( p );
p->timeMiter += clock() - clk;
if ( !RetValue )
continue;
clk = clock();
Abc_NtkRRUpdate( pNtk, p->pNode, p->pFanin, p->pFanout );
p->timeUpdate += clock() - clk;
p->nEdgesRemoved++;
break;
}
}
Abc_NtkRRSimulateStop(pNtk);
Extra_ProgressBarStop( pProgress );
p->timeTotal = clock() - clkTotal;
if ( fVerbose )
Abc_RRManPrintStats( p );
Abc_RRManStop( p );
// put the nodes into the DFS order and reassign their IDs
Abc_NtkReassignIds( pNtk );
......@@ -204,6 +273,33 @@ void Abc_RRManStop( Abc_RRMan_t * p )
/**Function*************************************************************
Synopsis [Stop the manager.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Abc_RRManPrintStats( Abc_RRMan_t * p )
{
double Ratio = 100.0*(p->nNodesOld - Abc_NtkNodeNum(p->pNtk))/p->nNodesOld;
printf( "Redundancy removal statistics:\n" );
printf( "Edges tried = %6d.\n", p->nEdgesTried );
printf( "Edges removed = %6d. (%5.2f %%)\n", p->nEdgesRemoved, 100.0*p->nEdgesRemoved/p->nEdgesTried );
printf( "Node gain = %6d. (%5.2f %%)\n", p->nNodesOld - Abc_NtkNodeNum(p->pNtk), Ratio );
printf( "Level gain = %6d.\n", p->nLevelsOld - Abc_AigGetLevelNum(p->pNtk) );
PRT( "Windowing ", p->timeWindow );
PRT( "Miter ", p->timeMiter );
PRT( " Construct ", p->timeMiter - p->timeProve );
PRT( " Prove ", p->timeProve );
PRT( "Update ", p->timeUpdate );
PRT( "TOTAL ", p->timeTotal );
}
/**Function*************************************************************
Synopsis [Clean the manager.]
Description []
......@@ -243,11 +339,17 @@ void Abc_RRManClean( Abc_RRMan_t * p )
int Abc_NtkRRProve( Abc_RRMan_t * p )
{
Abc_Ntk_t * pWndCopy;
int RetValue;
int RetValue, clk;
// Abc_NtkShowAig( p->pWnd, 0 );
pWndCopy = Abc_NtkDup( p->pWnd );
Abc_NtkRRUpdate( pWndCopy, p->pNode->pCopy, p->pFanin->pCopy, p->pFanout? p->pFanout->pCopy : NULL );
Abc_NtkRRUpdate( pWndCopy, p->pNode->pCopy->pCopy, p->pFanin->pCopy->pCopy, p->pFanout? p->pFanout->pCopy->pCopy : NULL );
if ( !Abc_NtkIsDfsOrdered(pWndCopy) )
Abc_NtkReassignIds(pWndCopy);
p->pMiter = Abc_NtkMiter( p->pWnd, pWndCopy, 1 );
Abc_NtkDelete( pWndCopy );
clk = clock();
RetValue = Abc_NtkMiterProve( &p->pMiter, p->pParams );
p->timeProve += clock() - clk;
if ( RetValue == 1 )
return 1;
return 0;
......@@ -257,7 +359,9 @@ int Abc_NtkRRProve( Abc_RRMan_t * p )
Synopsis [Updates the network after redundancy removal.]
Description []
Description [This procedure assumes that non-control value of the fanin
was proved redundant. It is okay to concentrate on non-control values
because the control values can be seen as redundancy of the fanout edge.]
SideEffects []
......@@ -280,7 +384,7 @@ int Abc_NtkRRUpdate( Abc_Ntk_t * pNtk, Abc_Obj_t * pNode, Abc_Obj_t * pFanin, Ab
// replace
if ( pFanout == NULL )
{
Abc_AigReplace( pNtk->pManFunc, pNode, pNodeNew, 0 );
Abc_AigReplace( pNtk->pManFunc, pNode, pNodeNew, 1 );
return 1;
}
// find the fanout after redundancy removal
......@@ -290,7 +394,7 @@ int Abc_NtkRRUpdate( Abc_Ntk_t * pNtk, Abc_Obj_t * pNode, Abc_Obj_t * pFanin, Ab
pFanoutNew = Abc_AigAnd( pNtk->pManFunc, Abc_ObjNotCond(pNodeNew,Abc_ObjFaninC1(pFanout)), Abc_ObjChild0(pFanout) );
else assert( 0 );
// replace
Abc_AigReplace( pNtk->pManFunc, pFanout, pFanoutNew, 0 );
Abc_AigReplace( pNtk->pManFunc, pFanout, pFanoutNew, 1 );
return 1;
}
......@@ -310,59 +414,50 @@ int Abc_NtkRRUpdate( Abc_Ntk_t * pNtk, Abc_Obj_t * pNode, Abc_Obj_t * pFanin, Ab
***********************************************************************/
int Abc_NtkRRWindow( Abc_RRMan_t * p )
{
Abc_Obj_t * pObj, * pFanout, * pEdgeFanin, * pEdgeFanout;
int i, k;
Abc_Obj_t * pObj, * pEdgeFanin, * pEdgeFanout;
int i, LevelMin, LevelMax, RetValue;
// get the edge
pEdgeFanout = p->pFanout? p->pFanout : p->pNode;
pEdgeFanin = p->pFanout? p->pNode : p->pFanin;
// get the minimum and maximum levels of the window
LevelMin = ABC_MAX( 0, ((int)p->pFanin->Level) - p->nFaninLevels );
LevelMax = (int)pEdgeFanout->Level + p->nFanoutLevels;
// start the TFI leaves with the fanin
Abc_NtkIncrementTravId( p->pNtk );
Abc_NodeSetTravIdCurrent( p->pFanin );
Vec_PtrPush( p->vFaninLeaves, p->pFanin );
// mark the TFI cone and collect the leaves down to the given level
while ( Abc_NtkRRTfi_int(p->vFaninLeaves, p->pFanin->Level - p->nFaninLevels) );
while ( Abc_NtkRRTfi_int(p->vFaninLeaves, LevelMin) );
// collect the TFO cone of the leaves
// mark the leaves with the new TravId
Abc_NtkIncrementTravId( p->pNtk );
Vec_PtrForEachEntry( p->vFaninLeaves, pObj, i )
{
Abc_ObjForEachFanout( pObj, pFanout, k )
{
if ( !Abc_ObjIsNode(pFanout) )
continue;
if ( pFanout->Level > pEdgeFanout->Level + p->nFanoutLevels )
continue;
if ( Abc_NodeIsTravIdCurrent(pFanout) )
continue;
Abc_NodeSetTravIdCurrent( pFanout );
Vec_PtrPush( p->vFanoutRoots, pFanout );
}
}
// mark the TFO cone and collect the leaves up to the given level (while skipping the edge)
while ( Abc_NtkRRTfo_int(p->vFanoutRoots, pEdgeFanout->Level + p->nFanoutLevels, pEdgeFanin, pEdgeFanout) );
// unmark the nodes
Vec_PtrForEachEntry( p->vFanoutRoots, pObj, i )
pObj->fMarkA = 0;
Abc_NodeSetTravIdCurrent( pObj );
// traverse the TFO cone of the leaves (while skipping the edge)
// (a) mark the nodes in the cone using the current TravId
// (b) collect the nodes that have external fanouts into p->vFanoutRoots
while ( Abc_NtkRRTfo_int(p->vFaninLeaves, p->vFanoutRoots, LevelMax, pEdgeFanin, pEdgeFanout) );
// mark the current roots
Abc_NtkIncrementTravId( p->pNtk );
// mark the fanout roots
Vec_PtrForEachEntry( p->vFanoutRoots, pObj, i )
Abc_NodeSetTravIdCurrent( pObj );
pObj->fMarkA = 1;
// collect roots reachable from the fanout (p->vRoots)
if ( !Abc_NtkRRTfo_rec( pEdgeFanout, p->vRoots, pEdgeFanout->Level + p->nFanoutLevels + 5 ) )
RetValue = Abc_NtkRRTfo_rec( pEdgeFanout, p->vRoots, LevelMax + 1 );
// unmark the fanout roots
Vec_PtrForEachEntry( p->vFanoutRoots, pObj, i )
pObj->fMarkA = 0;
// return if the window is infeasible
if ( RetValue == 0 )
return 0;
// collect the DFS-ordered new cone (p->vCone) and new leaves (p->vLeaves)
// using the previous marks coming from the TFO cone
Abc_NtkIncrementTravId( p->pNtk );
Vec_PtrForEachEntry( p->vRoots, pObj, i )
Abc_NtkRRTfi_rec( pObj, p->vLeaves, p->vCone );
// unmark the nodes
Vec_PtrForEachEntry( p->vCone, pObj, i )
pObj->fMarkA = 0;
Vec_PtrForEachEntry( p->vLeaves, pObj, i )
pObj->fMarkA = 0;
Abc_NtkRRTfi_rec( pObj, p->vLeaves, p->vCone, LevelMin );
// create a new network
p->pWnd = Abc_NtkWindow( p->pNtk, p->vLeaves, p->vCone, p->vRoots );
......@@ -380,21 +475,22 @@ int Abc_NtkRRWindow( Abc_RRMan_t * p )
SeeAlso []
***********************************************************************/
int Abc_NtkRRTfi_int( Vec_Ptr_t * vFaninLeaves, int LevelLimit )
int Abc_NtkRRTfi_int( Vec_Ptr_t * vLeaves, int LevelLimit )
{
Abc_Obj_t * pObj, * pNext;
int i, k, LevelMax, nSize;
assert( LevelLimit >= 0 );
// find the maximum level of leaves
LevelMax = 0;
Vec_PtrForEachEntry( vFaninLeaves, pObj, i )
Vec_PtrForEachEntry( vLeaves, pObj, i )
if ( LevelMax < (int)pObj->Level )
LevelMax = pObj->Level;
// if the nodes are all PIs, LevelMax == 0
if ( LevelMax == 0 || LevelMax <= LevelLimit )
if ( LevelMax <= LevelLimit )
return 0;
// expand the nodes with the minimum level
nSize = Vec_PtrSize(vFaninLeaves);
Vec_PtrForEachEntryStop( vFaninLeaves, pObj, i, nSize )
nSize = Vec_PtrSize(vLeaves);
Vec_PtrForEachEntryStop( vLeaves, pObj, i, nSize )
{
if ( LevelMax != (int)pObj->Level )
continue;
......@@ -403,18 +499,20 @@ int Abc_NtkRRTfi_int( Vec_Ptr_t * vFaninLeaves, int LevelLimit )
if ( Abc_NodeIsTravIdCurrent(pNext) )
continue;
Abc_NodeSetTravIdCurrent( pNext );
Vec_PtrPush( vFaninLeaves, pNext );
Vec_PtrPush( vLeaves, pNext );
}
}
// remove old nodes (cannot remove a PI)
k = 0;
Vec_PtrForEachEntry( vFaninLeaves, pObj, i )
Vec_PtrForEachEntry( vLeaves, pObj, i )
{
if ( LevelMax == (int)pObj->Level )
continue;
Vec_PtrWriteEntry( vFaninLeaves, k++, pObj );
Vec_PtrWriteEntry( vLeaves, k++, pObj );
}
Vec_PtrShrink( vFaninLeaves, k );
Vec_PtrShrink( vLeaves, k );
if ( Vec_PtrSize(vLeaves) > 2000 )
return 0;
return 1;
}
......@@ -429,60 +527,56 @@ int Abc_NtkRRTfi_int( Vec_Ptr_t * vFaninLeaves, int LevelLimit )
SeeAlso []
***********************************************************************/
int Abc_NtkRRTfo_int( Vec_Ptr_t * vFanoutRoots, int LevelLimit, Abc_Obj_t * pEdgeFanin, Abc_Obj_t * pEdgeFanout )
int Abc_NtkRRTfo_int( Vec_Ptr_t * vLeaves, Vec_Ptr_t * vRoots, int LevelLimit, Abc_Obj_t * pEdgeFanin, Abc_Obj_t * pEdgeFanout )
{
Abc_Obj_t * pObj, * pNext;
int i, k, LevelMin, nSize;
// find the minimum level of roots
int i, k, LevelMin, nSize, fObjIsRoot;
// find the minimum level of leaves
LevelMin = ABC_INFINITY;
Vec_PtrForEachEntry( vFanoutRoots, pObj, i )
if ( Abc_ObjIsNode(pObj) && !pObj->fMarkA && LevelMin > (int)pObj->Level )
Vec_PtrForEachEntry( vLeaves, pObj, i )
if ( LevelMin > (int)pObj->Level )
LevelMin = pObj->Level;
// if the nodes are all POs, LevelMin == ABC_INFINITY
if ( LevelMin == ABC_INFINITY || LevelMin > LevelLimit )
// if the minimum level exceed the limit, we are done
if ( LevelMin > LevelLimit )
return 0;
// expand the nodes with the minimum level
nSize = Vec_PtrSize(vFanoutRoots);
Vec_PtrForEachEntryStop( vFanoutRoots, pObj, i, nSize )
nSize = Vec_PtrSize(vLeaves);
Vec_PtrForEachEntryStop( vLeaves, pObj, i, nSize )
{
if ( LevelMin != (int)pObj->Level )
continue;
fObjIsRoot = 0;
Abc_ObjForEachFanout( pObj, pNext, k )
{
if ( !Abc_ObjIsNode(pNext) || pNext->Level > (unsigned)LevelLimit )
// check if the fanout is outside of the cone
if ( Abc_ObjIsCo(pNext) || pNext->Level > (unsigned)LevelLimit )
{
pObj->fMarkA = 1;
fObjIsRoot = 1;
continue;
}
// skip the edge under check
if ( pObj == pEdgeFanin && pNext == pEdgeFanout )
continue;
// skip the visited fanouts
if ( Abc_NodeIsTravIdCurrent(pNext) )
continue;
Abc_NodeSetTravIdCurrent( pNext );
Vec_PtrPush( vFanoutRoots, pNext );
Vec_PtrPush( vLeaves, pNext );
}
if ( fObjIsRoot )
Vec_PtrPush( vRoots, pObj );
}
// remove old nodes
k = 0;
Vec_PtrForEachEntry( vFanoutRoots, pObj, i )
Vec_PtrForEachEntry( vLeaves, pObj, i )
{
if ( LevelMin == (int)pObj->Level )
{
// check if the node has external fanouts
Abc_ObjForEachFanout( pObj, pNext, k )
{
if ( pObj == pEdgeFanin && pNext == pEdgeFanout )
continue;
if ( !Abc_NodeIsTravIdCurrent(pNext) )
break;
}
// if external fanout is found, do not remove the node
if ( pNext )
continue;
Vec_PtrWriteEntry( vLeaves, k++, pObj );
}
Vec_PtrWriteEntry( vFanoutRoots, k++, pObj );
}
Vec_PtrShrink( vFanoutRoots, k );
Vec_PtrShrink( vLeaves, k );
if ( Vec_PtrSize(vLeaves) > 2000 )
return 0;
return 1;
}
......@@ -490,7 +584,8 @@ int Abc_NtkRRTfo_int( Vec_Ptr_t * vFanoutRoots, int LevelLimit, Abc_Obj_t * pEdg
Synopsis [Collects the roots in the TFO of the node.]
Description []
Description [Note that this procedure can be improved by
marking and skipping the visited nodes.]
SideEffects []
......@@ -501,14 +596,18 @@ int Abc_NtkRRTfo_rec( Abc_Obj_t * pNode, Vec_Ptr_t * vRoots, int LevelLimit )
{
Abc_Obj_t * pFanout;
int i;
// if we encountered a node outside of the TFO cone of the fanins, quit
if ( Abc_ObjIsCo(pNode) || pNode->Level > (unsigned)LevelLimit )
return 0;
if ( Abc_NodeIsTravIdCurrent(pNode) )
// if we encountered a node on the boundary, add it to the roots
if ( pNode->fMarkA )
{
Vec_PtrPushUnique( vRoots, pNode );
return 1;
}
// mark the node with the current TravId (needed to have all internal nodes marked)
Abc_NodeSetTravIdCurrent( pNode );
// traverse the fanouts
Abc_ObjForEachFanout( pNode, pFanout, i )
if ( !Abc_NtkRRTfo_rec( pFanout, vRoots, LevelLimit ) )
return 0;
......@@ -517,7 +616,7 @@ int Abc_NtkRRTfo_rec( Abc_Obj_t * pNode, Vec_Ptr_t * vRoots, int LevelLimit )
/**Function*************************************************************
Synopsis []
Synopsis [Collects the leaves and cone of the roots.]
Description []
......@@ -526,22 +625,26 @@ int Abc_NtkRRTfo_rec( Abc_Obj_t * pNode, Vec_Ptr_t * vRoots, int LevelLimit )
SeeAlso []
***********************************************************************/
void Abc_NtkRRTfi_rec( Abc_Obj_t * pNode, Vec_Ptr_t * vLeaves, Vec_Ptr_t * vCone )
void Abc_NtkRRTfi_rec( Abc_Obj_t * pNode, Vec_Ptr_t * vLeaves, Vec_Ptr_t * vCone, int LevelLimit )
{
Abc_Obj_t * pFanin;
int i;
// skip visited nodes
if ( pNode->fMarkA )
if ( Abc_NodeIsTravIdCurrent(pNode) )
return;
pNode->fMarkA = 1;
// add the node if it was not visited in the previus run
if ( !Abc_NodeIsTravIdPrevious(pNode) )
// add node to leaves if it is not in TFI cone of the leaves (marked before) or below the limit
if ( !Abc_NodeIsTravIdPrevious(pNode) || (int)pNode->Level <= LevelLimit )
{
Abc_NodeSetTravIdCurrent( pNode );
Vec_PtrPush( vLeaves, pNode );
return;
}
// mark the node as visited
Abc_NodeSetTravIdCurrent( pNode );
// call for the node's fanins
Abc_ObjForEachFanin( pNode, pFanin, i )
Abc_NtkRRTfi_rec( pFanin, vLeaves, vCone );
Abc_NtkRRTfi_rec( pFanin, vLeaves, vCone, LevelLimit );
// add the node to the cone in topological order
Vec_PtrPush( vCone, pNode );
}
......@@ -560,6 +663,7 @@ Abc_Ntk_t * Abc_NtkWindow( Abc_Ntk_t * pNtk, Vec_Ptr_t * vLeaves, Vec_Ptr_t * vC
{
Abc_Ntk_t * pNtkNew;
Abc_Obj_t * pObj;
int fCheck = 1;
int i;
assert( Abc_NtkIsStrash(pNtk) );
// start the network
......@@ -581,12 +685,15 @@ Abc_Ntk_t * Abc_NtkWindow( Abc_Ntk_t * pNtk, Vec_Ptr_t * vLeaves, Vec_Ptr_t * vC
Vec_PtrSize(vCone) - Abc_NtkNodeNum(pNtkNew) );
// create the POs
Vec_PtrForEachEntry( vRoots, pObj, i )
{
assert( !Abc_ObjIsComplement(pObj->pCopy) );
Abc_ObjAddFanin( Abc_NtkCreatePo(pNtkNew), pObj->pCopy );
}
// add the PI/PO names
Abc_NtkAddDummyPiNames( pNtkNew );
Abc_NtkAddDummyPoNames( pNtkNew );
// check
if ( !Abc_NtkCheck( pNtkNew ) )
if ( fCheck && !Abc_NtkCheck( pNtkNew ) )
{
printf( "Abc_NtkWindow: The network check has failed.\n" );
return NULL;
......@@ -594,6 +701,288 @@ Abc_Ntk_t * Abc_NtkWindow( Abc_Ntk_t * pNtk, Vec_Ptr_t * vLeaves, Vec_Ptr_t * vC
return pNtkNew;
}
/**Function*************************************************************
Synopsis [Starts simulation to detect non-redundant edges.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Abc_NtkRRSimulateStart( Abc_Ntk_t * pNtk )
{
Abc_Obj_t * pObj;
unsigned uData, uData0, uData1;
int i;
Abc_NtkConst1(pNtk)->pData = (void *)~((unsigned)0);
Abc_NtkForEachCi( pNtk, pObj, i )
pObj->pData = (void *)SIM_RANDOM_UNSIGNED;
Abc_NtkForEachNode( pNtk, pObj, i )
{
if ( i == 0 ) continue;
uData0 = (unsigned)Abc_ObjFanin0(pObj)->pData;
uData1 = (unsigned)Abc_ObjFanin1(pObj)->pData;
uData = Abc_ObjFaninC0(pObj)? ~uData0 : uData0;
uData &= Abc_ObjFaninC1(pObj)? ~uData1 : uData1;
assert( pObj->pData == NULL );
pObj->pData = (void *)uData;
}
}
/**Function*************************************************************
Synopsis [Stops simulation to detect non-redundant edges.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Abc_NtkRRSimulateStop( Abc_Ntk_t * pNtk )
{
Abc_Obj_t * pObj;
int i;
Abc_NtkForEachObj( pNtk, pObj, i )
pObj->pData = NULL;
}
static void Sim_TraverseNodes_rec( Abc_Obj_t * pRoot, Vec_Str_t * vTargets, Vec_Ptr_t * vNodes );
static void Sim_CollectNodes_rec( Abc_Obj_t * pRoot, Vec_Ptr_t * vField );
static void Sim_SimulateCollected( Vec_Str_t * vTargets, Vec_Ptr_t * vNodes, Vec_Ptr_t * vField );
/**Function*************************************************************
Synopsis [Simulation to detect non-redundant edges.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Vec_Str_t * Abc_NtkRRSimulate( Abc_Ntk_t * pNtk )
{
Vec_Ptr_t * vNodes, * vField;
Vec_Str_t * vTargets;
Abc_Obj_t * pObj;
unsigned uData, uData0, uData1;
int PrevCi, Phase, i, k;
// start the candidates
vTargets = Vec_StrStart( Abc_NtkObjNumMax(pNtk) + 1 );
Abc_NtkForEachNode( pNtk, pObj, i )
{
Phase = ((Abc_ObjFanoutNum(Abc_ObjFanin1(pObj)) > 1) << 1);
Phase |= (Abc_ObjFanoutNum(Abc_ObjFanin0(pObj)) > 1);
Vec_StrWriteEntry( vTargets, pObj->Id, (char)Phase );
}
// simulate patters and store them in copy
Abc_NtkConst1(pNtk)->pCopy = (Abc_Obj_t *)~((unsigned)0);
Abc_NtkForEachCi( pNtk, pObj, i )
pObj->pCopy = (Abc_Obj_t *)SIM_RANDOM_UNSIGNED;
Abc_NtkForEachNode( pNtk, pObj, i )
{
if ( i == 0 ) continue;
uData0 = (unsigned)Abc_ObjFanin0(pObj)->pData;
uData1 = (unsigned)Abc_ObjFanin1(pObj)->pData;
uData = Abc_ObjFaninC0(pObj)? ~uData0 : uData0;
uData &= Abc_ObjFaninC1(pObj)? ~uData1 : uData1;
pObj->pCopy = (Abc_Obj_t *)uData;
}
// store the result in data
Abc_NtkForEachCo( pNtk, pObj, i )
{
uData0 = (unsigned)Abc_ObjFanin0(pObj)->pData;
if ( Abc_ObjFaninC0(pObj) )
pObj->pData = (void *)~uData0;
else
pObj->pData = (void *)uData0;
}
// refine the candidates
for ( PrevCi = 0; PrevCi < Abc_NtkCiNum(pNtk); PrevCi = i )
{
vNodes = Vec_PtrAlloc( 10 );
Abc_NtkIncrementTravId( pNtk );
for ( i = PrevCi; i < Abc_NtkCiNum(pNtk); i++ )
{
Sim_TraverseNodes_rec( Abc_NtkCi(pNtk, i), vTargets, vNodes );
if ( Vec_PtrSize(vNodes) > 128 )
break;
}
// collect the marked nodes in the topological order
vField = Vec_PtrAlloc( 10 );
Abc_NtkIncrementTravId( pNtk );
Abc_NtkForEachCo( pNtk, pObj, k )
Sim_CollectNodes_rec( pObj, vField );
// simulate these nodes
Sim_SimulateCollected( vTargets, vNodes, vField );
// prepare for the next loop
Vec_PtrFree( vNodes );
}
// clean
Abc_NtkForEachObj( pNtk, pObj, i )
pObj->pData = NULL;
return vTargets;
}
/**Function*************************************************************
Synopsis [Collects nodes starting from the given node.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Sim_TraverseNodes_rec( Abc_Obj_t * pRoot, Vec_Str_t * vTargets, Vec_Ptr_t * vNodes )
{
Abc_Obj_t * pFanout;
char Entry;
int k;
if ( Abc_NodeIsTravIdCurrent(pRoot) )
return;
Abc_NodeSetTravIdCurrent( pRoot );
// save the reached targets
Entry = Vec_StrEntry(vTargets, pRoot->Id);
if ( Entry & 1 )
Vec_PtrPush( vNodes, Abc_ObjNot(pRoot) );
if ( Entry & 2 )
Vec_PtrPush( vNodes, pRoot );
// explore the fanouts
Abc_ObjForEachFanout( pRoot, pFanout, k )
Sim_TraverseNodes_rec( pFanout, vTargets, vNodes );
}
/**Function*************************************************************
Synopsis [Collects nodes starting from the given node.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Sim_CollectNodes_rec( Abc_Obj_t * pRoot, Vec_Ptr_t * vField )
{
Abc_Obj_t * pFanin;
int i;
if ( Abc_NodeIsTravIdCurrent(pRoot) )
return;
if ( !Abc_NodeIsTravIdPrevious(pRoot) )
return;
Abc_NodeSetTravIdCurrent( pRoot );
Abc_ObjForEachFanin( pRoot, pFanin, i )
Sim_CollectNodes_rec( pFanin, vField );
if ( !Abc_ObjIsCo(pRoot) )
pRoot->pData = (void *)Vec_PtrSize(vField);
Vec_PtrPush( vField, pRoot );
}
/**Function*************************************************************
Synopsis [Simulate the given nodes.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Sim_SimulateCollected( Vec_Str_t * vTargets, Vec_Ptr_t * vNodes, Vec_Ptr_t * vField )
{
Abc_Obj_t * pObj, * pFanin0, * pFanin1, * pDisproved;
Vec_Ptr_t * vSims;
unsigned * pUnsigned, * pUnsignedF;
int i, k, Phase, fCompl;
// get simulation info
vSims = Sim_UtilInfoAlloc( Vec_PtrSize(vField), Vec_PtrSize(vNodes), 0 );
// simulate the nodes
Vec_PtrForEachEntry( vField, pObj, i )
{
if ( Abc_ObjIsCi(pObj) )
{
pUnsigned = Vec_PtrEntry( vSims, i );
for ( k = 0; k < Vec_PtrSize(vNodes); k++ )
pUnsigned[k] = (unsigned)pObj->pCopy;
continue;
}
if ( Abc_ObjIsCo(pObj) )
{
pUnsigned = Vec_PtrEntry( vSims, i );
pUnsignedF = Vec_PtrEntry( vSims, (int)Abc_ObjFanin0(pObj)->pData );
if ( Abc_ObjFaninC0(pObj) )
for ( k = 0; k < Vec_PtrSize(vNodes); k++ )
pUnsigned[k] = ~pUnsignedF[k];
else
for ( k = 0; k < Vec_PtrSize(vNodes); k++ )
pUnsigned[k] = pUnsignedF[k];
// update targets
for ( k = 0; k < Vec_PtrSize(vNodes); k++ )
{
if ( pUnsigned[k] == (unsigned)pObj->pData )
continue;
pDisproved = Vec_PtrEntry( vNodes, k );
fCompl = Abc_ObjIsComplement(pDisproved);
pDisproved = Abc_ObjRegular(pDisproved);
Phase = Vec_StrEntry( vTargets, pDisproved->Id );
if ( fCompl )
Phase = (Phase & 2);
else
Phase = (Phase & 1);
Vec_StrWriteEntry( vTargets, pDisproved->Id, (char)Phase );
}
continue;
}
// simulate the node
pFanin0 = Abc_ObjFanin0(pObj);
pFanin1 = Abc_ObjFanin1(pObj);
}
}
/*
{
unsigned uData;
if ( pFanin == Abc_ObjFanin0(pNode) )
{
uData = (unsigned)Abc_ObjFanin1(pNode)->pData;
uData = Abc_ObjFaninC1(pNode)? ~uData : uData;
}
else if ( pFanin == Abc_ObjFanin1(pNode) )
{
uData = (unsigned)Abc_ObjFanin0(pNode)->pData;
uData = Abc_ObjFaninC0(pNode)? ~uData : uData;
}
uData ^= (unsigned)pNode->pData;
// Extra_PrintBinary( stdout, &uData, 32 ); printf( "\n" );
if ( Extra_WordCountOnes(uData) > 8 )
continue;
}
*/
////////////////////////////////////////////////////////////////////////
/// END OF FILE ///
////////////////////////////////////////////////////////////////////////
......
src/base/cmd/cmd.c
......@@ -168,6 +168,14 @@ int CmdCommandTime( Abc_Frame_t * pAbc, int argc, char **argv )
pAbc->TimeTotal += pAbc->TimeCommand;
fprintf( pAbc->Out, "elapse: %3.2f seconds, total: %3.2f seconds\n",
(float)pAbc->TimeCommand / CLOCKS_PER_SEC, (float)pAbc->TimeTotal / CLOCKS_PER_SEC );
/*
{
FILE * pTable;
pTable = fopen( "runtimes.txt", "a+" );
fprintf( pTable, "%4.2f\n", (float)pAbc->TimeCommand / CLOCKS_PER_SEC );
fclose( pTable );
}
*/
pAbc->TimeCommand = 0;
return 0;
......
src/base/io/ioReadBlif.c
......@@ -212,6 +212,12 @@ Abc_Ntk_t * Io_ReadBlifNetworkOne( Io_ReadBlif_t * p )
// read the model name
if ( strcmp( p->vTokens->pArray[0], ".model" ) == 0 )
pNtk->pName = Extra_UtilStrsav( p->vTokens->pArray[1] );
else if ( strcmp( p->vTokens->pArray[0], ".exdc" ) != 0 )
{
printf( "%s: File parsing skipped after line %d (\"%s\").\n", p->pFileName,
Extra_FileReaderGetLineNumber(p->pReader, 0), p->vTokens->pArray[0] );
return NULL;
}
// read the inputs/outputs
pProgress = Extra_ProgressBarStart( stdout, Extra_FileReaderGetFileSize(p->pReader) );
......
src/base/io/ioWriteVer.c 0 → 100644
/**CFile****************************************************************
FileName [ioWriteVerilog.c]
SystemName [ABC: Logic synthesis and verification system.]
PackageName [Command processing package.]
Synopsis [Procedures to output a special subset of Verilog.]
Author [Alan Mishchenko]
Affiliation [UC Berkeley]
Date [Ver. 1.0. Started - June 20, 2005.]
Revision [$Id: ioWriteVerilog.c,v 1.00 2005/06/20 00:00:00 alanmi Exp $]
***********************************************************************/
#include "io.h"
#include "main.h"
#include "mio.h"
////////////////////////////////////////////////////////////////////////
/// DECLARATIONS ///
////////////////////////////////////////////////////////////////////////
static void Io_WriteVerilogInt( FILE * pFile, Abc_Ntk_t * pNtk );
static void Io_WriteVerilogPis( FILE * pFile, Abc_Ntk_t * pNtk, int Start );
static void Io_WriteVerilogPos( FILE * pFile, Abc_Ntk_t * pNtk, int Start );
static void Io_WriteVerilogWires( FILE * pFile, Abc_Ntk_t * pNtk, int Start );
static void Io_WriteVerilogRegs( FILE * pFile, Abc_Ntk_t * pNtk, int Start );
static void Io_WriteVerilogGates( FILE * pFile, Abc_Ntk_t * pNtk );
static void Io_WriteVerilogNodes( FILE * pFile, Abc_Ntk_t * pNtk );
static void Io_WriteVerilogArgs( FILE * pFile, Abc_Obj_t * pObj, int nInMax, int fPadZeros );
static void Io_WriteVerilogLatches( FILE * pFile, Abc_Ntk_t * pNtk );
static int Io_WriteVerilogCheckNtk( Abc_Ntk_t * pNtk );
static char * Io_WriteVerilogGetName( Abc_Obj_t * pObj );
////////////////////////////////////////////////////////////////////////
/// FUNCTION DEFINITIONS ///
////////////////////////////////////////////////////////////////////////
/**Function*************************************************************
Synopsis [Write verilog.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Io_WriteVerilog( Abc_Ntk_t * pNtk, char * pFileName )
{
FILE * pFile;
if ( !(Abc_NtkIsNetlist(pNtk) && (Abc_NtkHasMapping(pNtk) || Io_WriteVerilogCheckNtk(pNtk))) )
{
printf( "Io_WriteVerilog(): Can produce Verilog for a subset of logic networks.\n" );
printf( "The network should be either an AIG or a network after technology mapping.\n" );
printf( "The current network is not in the subset; the output files is not written.\n" );
return;
}
// start the output stream
pFile = fopen( pFileName, "w" );
if ( pFile == NULL )
{
fprintf( stdout, "Io_WriteVerilog(): Cannot open the output file \"%s\".\n", pFileName );
return;
}
// write the equations for the network
Io_WriteVerilogInt( pFile, pNtk );
fprintf( pFile, "\n" );
fclose( pFile );
}
/**Function*************************************************************
Synopsis [Writes verilog.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Io_WriteVerilogInt( FILE * pFile, Abc_Ntk_t * pNtk )
{
// write inputs and outputs
fprintf( pFile, "// Benchmark \"%s\" written by ABC on %s\n", pNtk->pName, Extra_TimeStamp() );
fprintf( pFile, "module %s ( gclk,\n ", Abc_NtkName(pNtk) );
Io_WriteVerilogPis( pFile, pNtk, 3 );
fprintf( pFile, ",\n " );
Io_WriteVerilogPos( pFile, pNtk, 3 );
fprintf( pFile, " );\n" );
// write inputs, outputs, registers, and wires
fprintf( pFile, " input gclk," );
Io_WriteVerilogPis( pFile, pNtk, 10 );
fprintf( pFile, ";\n" );
fprintf( pFile, " output" );
Io_WriteVerilogPos( pFile, pNtk, 5 );
fprintf( pFile, ";\n" );
if ( Abc_NtkLatchNum(pNtk) > 0 )
{
fprintf( pFile, " reg" );
Io_WriteVerilogRegs( pFile, pNtk, 4 );
fprintf( pFile, ";\n" );
}
fprintf( pFile, " wire" );
Io_WriteVerilogWires( pFile, pNtk, 4 );
fprintf( pFile, ";\n" );
// write registers
Io_WriteVerilogLatches( pFile, pNtk );
// write the nodes
if ( Abc_NtkHasMapping(pNtk) )
Io_WriteVerilogGates( pFile, pNtk );
else
Io_WriteVerilogNodes( pFile, pNtk );
// finalize the file
fprintf( pFile, "endmodule\n\n" );
fclose( pFile );
}
/**Function*************************************************************
Synopsis [Writes the primary inputs.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Io_WriteVerilogPis( FILE * pFile, Abc_Ntk_t * pNtk, int Start )
{
Abc_Obj_t * pTerm, * pNet;
int LineLength;
int AddedLength;
int NameCounter;
int i;
LineLength = Start;
NameCounter = 0;
Abc_NtkForEachPi( pNtk, pTerm, i )
{
pNet = Abc_ObjFanout0(pTerm);
// get the line length after this name is written
AddedLength = strlen(Abc_ObjName(pNet)) + 2;
if ( NameCounter && LineLength + AddedLength + 3 > IO_WRITE_LINE_LENGTH )
{ // write the line extender
fprintf( pFile, "\n " );
// reset the line length
LineLength = 3;
NameCounter = 0;
}
fprintf( pFile, " %s%s", Abc_ObjName(pNet), (i==Abc_NtkPiNum(pNtk)-1)? "" : "," );
LineLength += AddedLength;
NameCounter++;
}
}
/**Function*************************************************************
Synopsis [Writes the primary outputs.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Io_WriteVerilogPos( FILE * pFile, Abc_Ntk_t * pNtk, int Start )
{
Abc_Obj_t * pTerm, * pNet;
int LineLength;
int AddedLength;
int NameCounter;
int i;
LineLength = Start;
NameCounter = 0;
Abc_NtkForEachPo( pNtk, pTerm, i )
{
pNet = Abc_ObjFanin0(pTerm);
// get the line length after this name is written
AddedLength = strlen(Abc_ObjName(pNet)) + 2;
if ( NameCounter && LineLength + AddedLength + 3 > IO_WRITE_LINE_LENGTH )
{ // write the line extender
fprintf( pFile, "\n " );
// reset the line length
LineLength = 3;
NameCounter = 0;
}
fprintf( pFile, " %s%s", Abc_ObjName(pNet), (i==Abc_NtkPoNum(pNtk)-1)? "" : "," );
LineLength += AddedLength;
NameCounter++;
}
}
/**Function*************************************************************
Synopsis [Writes the wires.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Io_WriteVerilogWires( FILE * pFile, Abc_Ntk_t * pNtk, int Start )
{
Abc_Obj_t * pTerm, * pNet;
int LineLength;
int AddedLength;
int NameCounter;
int i, Counter, nNodes;
// count the number of wires
nNodes = 0;
Abc_NtkForEachNode( pNtk, pTerm, i )
{
if ( i == 0 )
continue;
pNet = Abc_ObjFanout0(pTerm);
if ( Abc_ObjIsCo(Abc_ObjFanout0(pNet)) )
continue;
nNodes++;
}
// write the wires
Counter = 0;
LineLength = Start;
NameCounter = 0;
Abc_NtkForEachNode( pNtk, pTerm, i )
{
if ( i == 0 )
continue;
pNet = Abc_ObjFanout0(pTerm);
if ( Abc_ObjIsCo(Abc_ObjFanout0(pNet)) )
continue;
Counter++;
// get the line length after this name is written
AddedLength = strlen(Abc_ObjName(pNet)) + 2;
if ( NameCounter && LineLength + AddedLength + 3 > IO_WRITE_LINE_LENGTH )
{ // write the line extender
fprintf( pFile, "\n " );
// reset the line length
LineLength = 3;
NameCounter = 0;
}
fprintf( pFile, " %s%s", Io_WriteVerilogGetName(pNet), (Counter==nNodes)? "" : "," );
LineLength += AddedLength;
NameCounter++;
}
}
/**Function*************************************************************
Synopsis [Writes the regs.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Io_WriteVerilogRegs( FILE * pFile, Abc_Ntk_t * pNtk, int Start )
{
Abc_Obj_t * pLatch, * pNet;
int LineLength;
int AddedLength;
int NameCounter;
int i, Counter, nNodes;
// count the number of latches
nNodes = Abc_NtkLatchNum(pNtk);
// write the wires
Counter = 0;
LineLength = Start;
NameCounter = 0;
Abc_NtkForEachLatch( pNtk, pLatch, i )
{
pNet = Abc_ObjFanout0(pLatch);
Counter++;
// get the line length after this name is written
AddedLength = strlen(Abc_ObjName(pNet)) + 2;
if ( NameCounter && LineLength + AddedLength + 3 > IO_WRITE_LINE_LENGTH )
{ // write the line extender
fprintf( pFile, "\n " );
// reset the line length
LineLength = 3;
NameCounter = 0;
}
fprintf( pFile, " %s%s", Io_WriteVerilogGetName(pNet), (Counter==nNodes)? "" : "," );
LineLength += AddedLength;
NameCounter++;
}
}
/**Function*************************************************************
Synopsis [Writes the latches.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Io_WriteVerilogLatches( FILE * pFile, Abc_Ntk_t * pNtk )
{
Abc_Obj_t * pLatch;
int i;
Abc_NtkForEachLatch( pNtk, pLatch, i )
{
if ( Abc_LatchInit(pLatch) == ABC_INIT_ZERO )
fprintf( pFile, " initial begin %s = 1\'b0; end\n", Abc_ObjName(Abc_ObjFanout0(pLatch)) );
else if ( Abc_LatchInit(pLatch) == ABC_INIT_ONE )
fprintf( pFile, " initial begin %s = 1\'b1; end\n", Abc_ObjName(Abc_ObjFanout0(pLatch)) );
fprintf( pFile, " always@(posedge gclk) begin %s", Abc_ObjName(Abc_ObjFanout0(pLatch)) );
fprintf( pFile, " = %s; end\n", Abc_ObjName(Abc_ObjFanin0(pLatch)) );
}
}
/**Function*************************************************************
Synopsis [Writes the gates.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Io_WriteVerilogGates( FILE * pFile, Abc_Ntk_t * pNtk )
{
Mio_Gate_t * pGate;
Mio_Pin_t * pGatePin;
Abc_Obj_t * pObj;
int i, k, Counter, nDigits, nFanins;
Counter = 1;
nDigits = Extra_Base10Log( Abc_NtkNodeNum(pNtk) );
Abc_NtkForEachNode( pNtk, pObj, i )
{
pGate = pObj->pData;
nFanins = Abc_ObjFaninNum(pObj);
fprintf( pFile, " %s g%0*d", Mio_GateReadName(pGate), nDigits, Counter++ );
fprintf( pFile, "(.%s (%s),", Mio_GateReadOutName(pGate), Io_WriteVerilogGetName(Abc_ObjFanout0(pObj)) );
for ( pGatePin = Mio_GateReadPins(pGate), k = 0; pGatePin; pGatePin = Mio_PinReadNext(pGatePin), k++ )
fprintf( pFile, " .%s (%s)%s", Mio_PinReadName(pGatePin), Io_WriteVerilogGetName(Abc_ObjFanin(pObj,k)), k==nFanins-1? "":"," );
fprintf( pFile, ");\n" );
}
}
/**Function*************************************************************
Synopsis [Writes the nodes.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Io_WriteVerilogNodes( FILE * pFile, Abc_Ntk_t * pNtk )
{
Abc_Obj_t * pObj, * pFanin;
int i, k, nFanins;
char * pName;
Abc_NtkForEachNode( pNtk, pObj, i )
{
assert( Abc_SopGetCubeNum(pObj->pData) == 1 );
nFanins = Abc_ObjFaninNum(pObj);
if ( nFanins == 0 )
{
fprintf( pFile, " assign %s = 1'b%d;\n", Io_WriteVerilogGetName(Abc_ObjFanout0(pObj)), !Abc_SopIsComplement(pObj->pData) );
continue;
}
if ( nFanins == 1 )
{
pName = Abc_SopIsInv(pObj->pData)? "not" : "and";
fprintf( pFile, " %s(%s, ", pName, Io_WriteVerilogGetName(Abc_ObjFanout0(pObj)) );
fprintf( pFile, "%s);\n", Io_WriteVerilogGetName(Abc_ObjFanin0(pObj)) );
continue;
}
pName = Abc_SopIsComplement(pObj->pData)? "or" : "and";
fprintf( pFile, " %s(%s, ", pName, Io_WriteVerilogGetName(Abc_ObjFanout0(pObj)) );
Abc_ObjForEachFanin( pObj, pFanin, k )
fprintf( pFile, "%s%s", Io_WriteVerilogGetName(pFanin), (k==nFanins-1? "" : ", ") );
fprintf( pFile, ");\n" );
}
}
/**Function*************************************************************
Synopsis [Writes the inputs.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void Io_WriteVerilogArgs( FILE * pFile, Abc_Obj_t * pObj, int nInMax, int fPadZeros )
{
Abc_Obj_t * pFanin;
int i, Counter = 2;
fprintf( pFile, "(.z (%s)", Io_WriteVerilogGetName(Abc_ObjFanout0(pObj)) );
Abc_ObjForEachFanin( pObj, pFanin, i )
{
if ( Counter++ % 4 == 0 )
fprintf( pFile, "\n " );
fprintf( pFile, " .i%d (%s)", i+1, Io_WriteVerilogGetName(Abc_ObjFanin(pObj,i)) );
}
for ( ; i < nInMax; i++ )
{
if ( Counter++ % 4 == 0 )
fprintf( pFile, "\n " );
fprintf( pFile, " .i%d (%s)", i+1, fPadZeros? "1\'b0" : "1\'b1" );
}
fprintf( pFile, ");\n" );
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int Io_WriteVerilogCheckNtk( Abc_Ntk_t * pNtk )
{
Abc_Obj_t * pObj;
int i;
Abc_NtkForEachNode( pNtk, pObj, i )
{
if ( Abc_SopGetCubeNum(pObj->pData) > 1 )
{
printf( "Node %s contains a cover with more than one cube.\n", Abc_ObjName(pObj) );
return 0;
}
}
return 1;
}
/**Function*************************************************************
Synopsis [Prepares the name for writing the Verilog file.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
char * Io_WriteVerilogGetName( Abc_Obj_t * pObj )
{
static char Buffer[20];
char * pName;
pName = Abc_ObjName(pObj);
if ( pName[0] != '[' )
return pName;
// replace the brackets; as a result, the length of the name does not change
strcpy( Buffer, pName );
Buffer[0] = 'x';
Buffer[strlen(Buffer)-1] = 'x';
return Buffer;
}
////////////////////////////////////////////////////////////////////////
/// END OF FILE ///
////////////////////////////////////////////////////////////////////////
src/base/io/ioWriteVerilog.c src/base/io/ioWriteVerAux.c
......@@ -24,14 +24,14 @@
/// DECLARATIONS ///
////////////////////////////////////////////////////////////////////////
static void Io_WriteVerilogInt( FILE * pFile, Abc_Ntk_t * pNtk );
static void Io_WriteVerilogPis( FILE * pFile, Abc_Ntk_t * pNtk, int Start );
static void Io_WriteVerilogPos( FILE * pFile, Abc_Ntk_t * pNtk, int Start );
static void Io_WriteVerilogWires( FILE * pFile, Abc_Ntk_t * pNtk, int Start );
static void Io_WriteVerilogNodes( FILE * pFile, Abc_Ntk_t * pNtk );
static void Io_WriteVerilogArgs( FILE * pFile, Abc_Obj_t * pObj, int nInMax, int fPadZeros );
static int Io_WriteVerilogCheckNtk( Abc_Ntk_t * pNtk );
static char * Io_WriteVerilogGetName( Abc_Obj_t * pObj );
static void Io_WriteVerilogAuxInt( FILE * pFile, Abc_Ntk_t * pNtk );
static void Io_WriteVerilogAuxPis( FILE * pFile, Abc_Ntk_t * pNtk, int Start );
static void Io_WriteVerilogAuxPos( FILE * pFile, Abc_Ntk_t * pNtk, int Start );
static void Io_WriteVerilogAuxWires( FILE * pFile, Abc_Ntk_t * pNtk, int Start );
static void Io_WriteVerilogAuxNodes( FILE * pFile, Abc_Ntk_t * pNtk );
static void Io_WriteVerilogAuxArgs( FILE * pFile, Abc_Obj_t * pObj, int nInMax, int fPadZeros );
static int Io_WriteVerilogAuxCheckNtk( Abc_Ntk_t * pNtk );
static char * Io_WriteVerilogAuxGetName( Abc_Obj_t * pObj );
////////////////////////////////////////////////////////////////////////
/// FUNCTION DEFINITIONS ///
......@@ -48,30 +48,30 @@ static char * Io_WriteVerilogGetName( Abc_Obj_t * pObj );
SeeAlso []
***********************************************************************/
void Io_WriteVerilog( Abc_Ntk_t * pNtk, char * pFileName )
void Io_WriteVerilogAux( Abc_Ntk_t * pNtk, char * pFileName )
{
FILE * pFile;
if ( !Abc_NtkIsSopNetlist(pNtk) || !Io_WriteVerilogCheckNtk(pNtk) )
if ( !Abc_NtkIsSopNetlist(pNtk) || !Io_WriteVerilogAuxCheckNtk(pNtk) )
{
printf( "Io_WriteVerilog(): Can write Verilog for a very special subset of logic networks.\n" );
printf( "Io_WriteVerilogAux(): Can write Verilog for a very special subset of logic networks.\n" );
printf( "The current network is not in the subset; writing Verilog is not performed.\n" );
return;
}
if ( Abc_NtkLatchNum(pNtk) > 0 )
printf( "Io_WriteVerilog(): Warning: only combinational portion is being written.\n" );
printf( "Io_WriteVerilogAux(): Warning: only combinational portion is being written.\n" );
// start the output stream
pFile = fopen( pFileName, "w" );
if ( pFile == NULL )
{
fprintf( stdout, "Io_WriteVerilog(): Cannot open the output file \"%s\".\n", pFileName );
fprintf( stdout, "Io_WriteVerilogAux(): Cannot open the output file \"%s\".\n", pFileName );
return;
}
// write the equations for the network
Io_WriteVerilogInt( pFile, pNtk );
Io_WriteVerilogAuxInt( pFile, pNtk );
fprintf( pFile, "\n" );
fclose( pFile );
}
......@@ -87,27 +87,27 @@ void Io_WriteVerilog( Abc_Ntk_t * pNtk, char * pFileName )
SeeAlso []
***********************************************************************/
void Io_WriteVerilogInt( FILE * pFile, Abc_Ntk_t * pNtk )
void Io_WriteVerilogAuxInt( FILE * pFile, Abc_Ntk_t * pNtk )
{
// write inputs and outputs
fprintf( pFile, "// Benchmark \"%s\" written by ABC on %s\n", pNtk->pName, Extra_TimeStamp() );
fprintf( pFile, "module %s (\n ", Abc_NtkName(pNtk) );
Io_WriteVerilogPis( pFile, pNtk, 3 );
Io_WriteVerilogAuxPis( pFile, pNtk, 3 );
fprintf( pFile, ",\n " );
Io_WriteVerilogPos( pFile, pNtk, 3 );
Io_WriteVerilogAuxPos( pFile, pNtk, 3 );
fprintf( pFile, " );\n" );
// write inputs, outputs and wires
fprintf( pFile, " input" );
Io_WriteVerilogPis( pFile, pNtk, 5 );
Io_WriteVerilogAuxPis( pFile, pNtk, 5 );
fprintf( pFile, ";\n" );
fprintf( pFile, " output" );
Io_WriteVerilogPos( pFile, pNtk, 5 );
Io_WriteVerilogAuxPos( pFile, pNtk, 5 );
fprintf( pFile, ";\n" );
fprintf( pFile, " wire" );
Io_WriteVerilogWires( pFile, pNtk, 4 );
Io_WriteVerilogAuxWires( pFile, pNtk, 4 );
fprintf( pFile, ";\n" );
// write the nodes
Io_WriteVerilogNodes( pFile, pNtk );
Io_WriteVerilogAuxNodes( pFile, pNtk );
// finalize the file
fprintf( pFile, "endmodule\n\n" );
fclose( pFile );
......@@ -124,7 +124,7 @@ void Io_WriteVerilogInt( FILE * pFile, Abc_Ntk_t * pNtk )
SeeAlso []
***********************************************************************/
void Io_WriteVerilogPis( FILE * pFile, Abc_Ntk_t * pNtk, int Start )
void Io_WriteVerilogAuxPis( FILE * pFile, Abc_Ntk_t * pNtk, int Start )
{
Abc_Obj_t * pTerm, * pNet;
int LineLength;
......@@ -163,7 +163,7 @@ void Io_WriteVerilogPis( FILE * pFile, Abc_Ntk_t * pNtk, int Start )
SeeAlso []
***********************************************************************/
void Io_WriteVerilogPos( FILE * pFile, Abc_Ntk_t * pNtk, int Start )
void Io_WriteVerilogAuxPos( FILE * pFile, Abc_Ntk_t * pNtk, int Start )
{
Abc_Obj_t * pTerm, * pNet;
int LineLength;
......@@ -202,7 +202,7 @@ void Io_WriteVerilogPos( FILE * pFile, Abc_Ntk_t * pNtk, int Start )
SeeAlso []
***********************************************************************/
void Io_WriteVerilogWires( FILE * pFile, Abc_Ntk_t * pNtk, int Start )
void Io_WriteVerilogAuxWires( FILE * pFile, Abc_Ntk_t * pNtk, int Start )
{
Abc_Obj_t * pTerm, * pNet;
int LineLength;
......@@ -243,7 +243,7 @@ void Io_WriteVerilogWires( FILE * pFile, Abc_Ntk_t * pNtk, int Start )
LineLength = 3;
NameCounter = 0;
}
fprintf( pFile, " %s%s", Io_WriteVerilogGetName(pNet), (Counter==nNodes)? "" : "," );
fprintf( pFile, " %s%s", Io_WriteVerilogAuxGetName(pNet), (Counter==nNodes)? "" : "," );
LineLength += AddedLength;
NameCounter++;
}
......@@ -260,7 +260,7 @@ void Io_WriteVerilogWires( FILE * pFile, Abc_Ntk_t * pNtk, int Start )
SeeAlso []
***********************************************************************/
void Io_WriteVerilogNodes( FILE * pFile, Abc_Ntk_t * pNtk )
void Io_WriteVerilogAuxNodes( FILE * pFile, Abc_Ntk_t * pNtk )
{
Abc_Obj_t * pObj;
int i, nCubes, nFanins, Counter, nDigits, fPadZeros;
......@@ -284,62 +284,62 @@ void Io_WriteVerilogNodes( FILE * pFile, Abc_Ntk_t * pNtk )
if ( nCubes == 0 )
{
fprintf( pFile, " ts_gnd g%0*d ", nDigits, Counter++ );
Io_WriteVerilogArgs( pFile, pObj, 0, fPadZeros );
Io_WriteVerilogAuxArgs( pFile, pObj, 0, fPadZeros );
}
else if ( nCubes == 1 && nFanins == 0 )
{
fprintf( pFile, " ts_vdd g%0*d ", nDigits, Counter++ );
Io_WriteVerilogArgs( pFile, pObj, 0, fPadZeros );
Io_WriteVerilogAuxArgs( pFile, pObj, 0, fPadZeros );
}
else if ( nFanins == 1 && Abc_SopIsInv(pObj->pData) )
{
fprintf( pFile, " ts_inv g%0*d ", nDigits, Counter++ );
Io_WriteVerilogArgs( pFile, pObj, 1, fPadZeros );
Io_WriteVerilogAuxArgs( pFile, pObj, 1, fPadZeros );
}
else if ( nFanins == 1 )
{
fprintf( pFile, " ts_buf g%0*d ", nDigits, Counter++ );
Io_WriteVerilogArgs( pFile, pObj, 1, fPadZeros );
Io_WriteVerilogAuxArgs( pFile, pObj, 1, fPadZeros );
}
else if ( nFanins <= 4 )
{
fprintf( pFile, " %s%d g%0*d ", pName, 4, nDigits, Counter++ );
Io_WriteVerilogArgs( pFile, pObj, 4, fPadZeros );
Io_WriteVerilogAuxArgs( pFile, pObj, 4, fPadZeros );
}
else if ( nFanins <= 6 )
{
fprintf( pFile, " %s%d g%0*d ", pName, 6, nDigits, Counter++ );
Io_WriteVerilogArgs( pFile, pObj, 6, fPadZeros );
Io_WriteVerilogAuxArgs( pFile, pObj, 6, fPadZeros );
}
else if ( nFanins == 7 )
{
fprintf( pFile, " %s%d g%0*d ", pName, 7, nDigits, Counter++ );
Io_WriteVerilogArgs( pFile, pObj, 7, fPadZeros );
Io_WriteVerilogAuxArgs( pFile, pObj, 7, fPadZeros );
}
else if ( nFanins == 8 )
{
fprintf( pFile, " %s%d g%0*d ", pName, 8, nDigits, Counter++ );
Io_WriteVerilogArgs( pFile, pObj, 8, fPadZeros );
Io_WriteVerilogAuxArgs( pFile, pObj, 8, fPadZeros );
}
else if ( nFanins <= 16 )
{
fprintf( pFile, " %s%d g%0*d ", pName, 16, nDigits, Counter++ );
Io_WriteVerilogArgs( pFile, pObj, 16, fPadZeros );
Io_WriteVerilogAuxArgs( pFile, pObj, 16, fPadZeros );
}
else if ( nFanins <= 32 )
{
fprintf( pFile, " %s%d g%0*d ", pName, 32, nDigits, Counter++ );
Io_WriteVerilogArgs( pFile, pObj, 32, fPadZeros );
Io_WriteVerilogAuxArgs( pFile, pObj, 32, fPadZeros );
}
else if ( nFanins <= 64 )
{
fprintf( pFile, " %s%d g%0*d ", pName, 64, nDigits, Counter++ );
Io_WriteVerilogArgs( pFile, pObj, 64, fPadZeros );
Io_WriteVerilogAuxArgs( pFile, pObj, 64, fPadZeros );
}
else if ( nFanins <= 128 )
{
fprintf( pFile, " %s%d g%0*d ", pName, 128, nDigits, Counter++ );
Io_WriteVerilogArgs( pFile, pObj, 128, fPadZeros );
Io_WriteVerilogAuxArgs( pFile, pObj, 128, fPadZeros );
}
}
}
......@@ -355,16 +355,16 @@ void Io_WriteVerilogNodes( FILE * pFile, Abc_Ntk_t * pNtk )
SeeAlso []
***********************************************************************/
void Io_WriteVerilogArgs( FILE * pFile, Abc_Obj_t * pObj, int nInMax, int fPadZeros )
void Io_WriteVerilogAuxArgs( FILE * pFile, Abc_Obj_t * pObj, int nInMax, int fPadZeros )
{
Abc_Obj_t * pFanin;
int i, Counter = 2;
fprintf( pFile, "(.z (%s)", Io_WriteVerilogGetName(Abc_ObjFanout0(pObj)) );
fprintf( pFile, "(.z (%s)", Io_WriteVerilogAuxGetName(Abc_ObjFanout0(pObj)) );
Abc_ObjForEachFanin( pObj, pFanin, i )
{
if ( Counter++ % 4 == 0 )
fprintf( pFile, "\n " );
fprintf( pFile, " .i%d (%s)", i+1, Io_WriteVerilogGetName(Abc_ObjFanin(pObj,i)) );
fprintf( pFile, " .i%d (%s)", i+1, Io_WriteVerilogAuxGetName(Abc_ObjFanin(pObj,i)) );
}
for ( ; i < nInMax; i++ )
{
......@@ -386,7 +386,7 @@ void Io_WriteVerilogArgs( FILE * pFile, Abc_Obj_t * pObj, int nInMax, int fPadZe
SeeAlso []
***********************************************************************/
int Io_WriteVerilogCheckNtk( Abc_Ntk_t * pNtk )
int Io_WriteVerilogAuxCheckNtk( Abc_Ntk_t * pNtk )
{
Abc_Obj_t * pObj;
char * pSop;
......@@ -423,7 +423,7 @@ int Io_WriteVerilogCheckNtk( Abc_Ntk_t * pNtk )
SeeAlso []
***********************************************************************/
char * Io_WriteVerilogGetName( Abc_Obj_t * pObj )
char * Io_WriteVerilogAuxGetName( Abc_Obj_t * pObj )
{
static char Buffer[20];
char * pName;
......
src/base/io/module.make
......@@ -17,4 +17,5 @@ SRC += src/base/io/io.c \
src/base/io/ioWriteGml.c \
src/base/io/ioWriteList.c \
src/base/io/ioWritePla.c \
src/base/io/ioWriteVerilog.c
src/base/io/ioWriteVer.c \
src/base/io/ioWriteVerAux.c
src/opt/cut/cutExpand.c 0 → 100644
/**CFile****************************************************************
FileName [cutExpand.c]
SystemName [ABC: Logic synthesis and verification system.]
PackageName [K-feasible cut computation package.]
Synopsis [Computes the truth table of the cut after expansion.]
Author [Alan Mishchenko]
Affiliation [UC Berkeley]
Date [Ver. 1.0. Started - June 20, 2005.]
Revision [$Id: cutExpand.c,v 1.00 2005/06/20 00:00:00 alanmi Exp $]
***********************************************************************/
#include "cutInt.h"
////////////////////////////////////////////////////////////////////////
/// DECLARATIONS ///
////////////////////////////////////////////////////////////////////////
#define CUT_CELL_MVAR 9
////////////////////////////////////////////////////////////////////////
/// FUNCTION DEFINITIONS ///
////////////////////////////////////////////////////////////////////////
/**Function*************************************************************
Synopsis [Computes the stretching phase of the cut w.r.t. the merged cut.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
static inline unsigned Cut_TruthPhase( Cut_Cut_t * pCut, Cut_Cut_t * pCut1 )
{
unsigned uPhase = 0;
int i, k;
for ( i = k = 0; i < (int)pCut->nLeaves; i++ )
{
if ( k == (int)pCut1->nLeaves )
break;
if ( pCut->pLeaves[i] < pCut1->pLeaves[k] )
continue;
assert( pCut->pLeaves[i] == pCut1->pLeaves[k] );
uPhase |= (1 << i);
k++;
}
return uPhase;
}
/**Function*************************************************************
Synopsis [Computes the truth table of the composition of cuts.]
Description [Inputs are:
- a factor cut (truth table is stored inside)
- a node in the factor cut
- a tree cut to be substituted (truth table is stored inside)
- the resulting cut (truth table will be filled in).
Note that all cuts, including the resulting one, should be already
computed and the nodes should be stored in the ascending order.]
SideEffects []
SeeAlso []
***********************************************************************/
void Cut_TruthCompose( Cut_Cut_t * pCutF, int Node, Cut_Cut_t * pCutT, Cut_Cut_t * pCutRes )
{
static unsigned uCof0[1<<(CUT_CELL_MVAR-5)];
static unsigned uCof1[1<<(CUT_CELL_MVAR-5)];
static unsigned uTemp[1<<(CUT_CELL_MVAR-5)];
unsigned * pIn, * pOut, * pTemp;
unsigned uPhase;
int NodeIndex, i, k;
// sanity checks
assert( pCutF->nVarsMax == pCutT->nVarsMax );
assert( pCutF->nVarsMax == pCutRes->nVarsMax );
assert( pCutF->nVarsMax <= CUT_CELL_MVAR );
// the factor cut (pCutF) should have its nodes sorted in the ascending order
assert( pCutF->nLeaves <= pCutF->nVarsMax );
for ( i = 0; i < (int)pCutF->nLeaves - 1; i++ )
assert( pCutF->pLeaves[i] < pCutF->pLeaves[i+1] );
// the tree cut (pCutT) should have its nodes sorted in the ascending order
assert( pCutT->nLeaves <= pCutT->nVarsMax );
for ( i = 0; i < (int)pCutT->nLeaves - 1; i++ )
assert( pCutT->pLeaves[i] < pCutT->pLeaves[i+1] );
// the resulting cut (pCutRes) should have its nodes sorted in the ascending order
assert( pCutRes->nLeaves <= pCutRes->nVarsMax );
for ( i = 0; i < (int)pCutRes->nLeaves - 1; i++ )
assert( pCutRes->pLeaves[i] < pCutRes->pLeaves[i+1] );
// make sure that every node in pCutF (except Node) appears in pCutRes
for ( i = 0; i < (int)pCutF->nLeaves; i++ )
{
if ( pCutF->pLeaves[i] == Node )
continue;
for ( k = 0; k < (int)pCutRes->nLeaves; k++ )
if ( pCutF->pLeaves[i] == pCutRes->pLeaves[k] )
break;
assert( k < (int)pCutRes->nLeaves ); // node i from pCutF is not found in pCutRes!!!
}
// make sure that every node in pCutT appears in pCutRes
for ( i = 0; i < (int)pCutT->nLeaves; i++ )
{
for ( k = 0; k < (int)pCutRes->nLeaves; k++ )
if ( pCutT->pLeaves[i] == pCutRes->pLeaves[k] )
break;
assert( k < (int)pCutRes->nLeaves ); // node i from pCutT is not found in pCutRes!!!
}
// find the index of the given node in the factor cut
NodeIndex = -1;
for ( NodeIndex = 0; NodeIndex < (int)pCutF->nLeaves; NodeIndex++ )
if ( pCutF->pLeaves[NodeIndex] == Node )
break;
assert( NodeIndex >= 0 ); // Node should be in pCutF
// copy the truth table
Extra_TruthCopy( uTemp, Cut_CutReadTruth(pCutF), pCutF->nLeaves );
// bubble-move the NodeIndex variable to be the last one (the most significant one)
pIn = uTemp; pOut = uCof0; // uCof0 is used for temporary storage here
for ( i = NodeIndex; i < (int)pCutF->nLeaves - 1; i++ )
{
Extra_TruthSwapAdjacentVars( pOut, pIn, pCutF->nLeaves, i );
pTemp = pIn; pIn = pOut; pOut = pTemp;
}
if ( (pCutF->nLeaves - 1 - NodeIndex) & 1 )
Extra_TruthCopy( pOut, pIn, pCutF->nLeaves );
// the result of stretching is in uTemp
// cofactor the factor cut with respect to the node
Extra_TruthCopy( uCof0, uTemp, pCutF->nLeaves );
Extra_TruthCofactor0( uCof0, pCutF->nLeaves, pCutF->nLeaves-1 );
Extra_TruthCopy( uCof1, uTemp, pCutF->nLeaves );
Extra_TruthCofactor1( uCof1, pCutF->nLeaves, pCutF->nLeaves-1 );
// temporarily shrink the factor cut's variables by removing Node
for ( i = NodeIndex; i < (int)pCutF->nLeaves - 1; i++ )
pCutF->pLeaves[i] = pCutF->pLeaves[i+1];
pCutF->nLeaves--;
// spread out the cofactors' truth tables to the same var order as the resulting cut
uPhase = Cut_TruthPhase(pCutRes, pCutF);
assert( Extra_WordCountOnes(uPhase) == (int)pCutF->nLeaves );
Extra_TruthStretch( uTemp, uCof0, pCutF->nLeaves, pCutF->nVarsMax, uPhase );
Extra_TruthCopy( uCof0, uTemp, pCutF->nVarsMax );
Extra_TruthStretch( uTemp, uCof1, pCutF->nLeaves, pCutF->nVarsMax, uPhase );
Extra_TruthCopy( uCof1, uTemp, pCutF->nVarsMax );
// spread out the tree cut's truth table to the same var order as the resulting cut
uPhase = Cut_TruthPhase(pCutRes, pCutT);
assert( Extra_WordCountOnes(uPhase) == (int)pCutT->nLeaves );
Extra_TruthStretch( uTemp, Cut_CutReadTruth(pCutT), pCutT->nLeaves, pCutT->nVarsMax, uPhase );
// create the resulting truth table
pTemp = Cut_CutReadTruth(pCutRes);
for ( i = Extra_TruthWordNum(pCutRes->nLeaves)-1; i >= 0; i-- )
pTemp[i] = (uCof0[i] & ~uTemp[i]) | (uCof1[i] & uTemp[i]);
// undo the removal of the node from the cut
for ( i = (int)pCutF->nLeaves - 1; i >= NodeIndex; --i )
pCutF->pLeaves[i+1] = pCutF->pLeaves[i];
pCutF->pLeaves[NodeIndex] = Node;
pCutF->nLeaves++;
}
////////////////////////////////////////////////////////////////////////
/// END OF FILE ///
////////////////////////////////////////////////////////////////////////
src/opt/cut/cutPre22.c
......@@ -203,6 +203,11 @@ void Cut_CellLoad()
*/
// add to the table
p->nTotal++;
// Extra_PrintHexadecimal( stdout, pCell->uTruth, pCell->nVars ); printf( "\n" );
// if ( p->nTotal == 500 )
// break;
if ( !Cut_CellTableLookup( p, pCell ) ) // new cell
p->nGood++;
}
......
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