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lvzhengyang
abc
Commits
12b70d49
Commit
12b70d49
authored
Oct 17, 2011
by
Alan Mishchenko
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Changes to CNF generation code.
parent
6f0b87dd
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7 changed files
with
839 additions
and
18 deletions
+839
-18
abclib.dsp
+4
-0
src/aig/aig/aig.h
+16
-7
src/aig/cnf/cnf.h
+2
-0
src/aig/cnf/cnfFast.c
+772
-0
src/aig/cnf/module.make
+1
-0
src/base/abci/abcDar.c
+18
-5
src/base/io/io.c
+26
-6
No files found.
abclib.dsp
View file @
12b70d49
...
...
@@ -2971,6 +2971,10 @@ SOURCE=.\src\aig\cnf\cnfData.c
# End Source File
# Begin Source File
SOURCE=.\src\aig\cnf\cnfFast.c
# End Source File
# Begin Source File
SOURCE=.\src\aig\cnf\cnfMan.c
# End Source File
# Begin Source File
...
...
src/aig/aig/aig.h
View file @
12b70d49
...
...
@@ -410,24 +410,33 @@ static inline void Aig_ManRecycleMemory( Aig_Man_t * p, Aig_Obj_t * pEntry )
// iterator over the primary inputs
#define Aig_ManForEachPi( p, pObj, i ) \
Vec_PtrForEachEntry( Aig_Obj_t *, p->vPis, pObj, i )
#define Aig_ManForEachPiReverse( p, pObj, i ) \
Vec_PtrForEachEntryReverse( Aig_Obj_t *, p->vPis, pObj, i )
// iterator over the primary outputs
#define Aig_ManForEachPo( p, pObj, i ) \
Vec_PtrForEachEntry( Aig_Obj_t *, p->vPos, pObj, i )
// iterator over the assertions
#define Aig_ManForEachAssert( p, pObj, i ) \
Vec_PtrForEachEntryStart( Aig_Obj_t *, p->vPos, pObj, i, Aig_ManPoNum(p)-p->nAsserts )
// iterator over all objects, including those currently not used
#define Aig_ManForEachPoReverse( p, pObj, i ) \
Vec_PtrForEachEntryReverse( Aig_Obj_t *, p->vPos, pObj, i )
// iterators over all objects, including those currently not used
#define Aig_ManForEachObj( p, pObj, i ) \
Vec_PtrForEachEntry( Aig_Obj_t *, p->vObjs, pObj, i ) if ( (pObj) == NULL ) {} else
// iterator over the objects whose IDs are stored in an array
#define Aig_ManForEachObjVec( vIds, p, pObj, i ) \
#define Aig_ManForEachObjReverse( p, pObj, i ) \
Vec_PtrForEachEntryReverse( Aig_Obj_t *, p->vObjs, pObj, i ) if ( (pObj) == NULL ) {} else
// iterators over the objects whose IDs are stored in an array
#define Aig_ManForEachObjVec( vIds, p, pObj, i ) \
for ( i = 0; i < Vec_IntSize(vIds) && (((pObj) = Aig_ManObj(p, Vec_IntEntry(vIds,i))), 1); i++ )
// iterator over all nodes
#define Aig_ManForEachObjVecReverse( vIds, p, pObj, i ) \
for ( i = Vec_IntSize(vIds) - 1; i >= 0 && (((pObj) = Aig_ManObj(p, Vec_IntEntry(vIds,i))), 1); i-- )
// iterators over all nodes
#define Aig_ManForEachNode( p, pObj, i ) \
Vec_PtrForEachEntry( Aig_Obj_t *, p->vObjs, pObj, i ) if ( (pObj) == NULL || !Aig_ObjIsNode(pObj) ) {} else
#define Aig_ManForEachNodeReverse( p, pObj, i ) \
Vec_PtrForEachEntryReverse( Aig_Obj_t *, p->vObjs, pObj, i ) if ( (pObj) == NULL || !Aig_ObjIsNode(pObj) ) {} else
// iterator over all nodes
#define Aig_ManForEachExor( p, pObj, i ) \
Vec_PtrForEachEntry( Aig_Obj_t *, p->vObjs, pObj, i ) if ( (pObj) == NULL || !Aig_ObjIsExor(pObj) ) {} else
#define Aig_ManForEachExorReverse( p, pObj, i ) \
Vec_PtrForEachEntryReverse( Aig_Obj_t *, p->vObjs, pObj, i ) if ( (pObj) == NULL || !Aig_ObjIsExor(pObj) ) {} else
// these two procedures are only here for the use inside the iterator
static
inline
int
Aig_ObjFanout0Int
(
Aig_Man_t
*
p
,
int
ObjId
)
{
assert
(
ObjId
<
p
->
nFansAlloc
);
return
p
->
pFanData
[
5
*
ObjId
];
}
...
...
src/aig/cnf/cnf.h
View file @
12b70d49
...
...
@@ -138,6 +138,8 @@ extern void Cnf_CutUpdateRefs( Cnf_Man_t * p, Cnf_Cut_t * pCut, Cnf_C
extern
Cnf_Cut_t
*
Cnf_CutCompose
(
Cnf_Man_t
*
p
,
Cnf_Cut_t
*
pCut
,
Cnf_Cut_t
*
pCutFan
,
int
iFan
);
/*=== cnfData.c ========================================================*/
extern
void
Cnf_ReadMsops
(
char
**
ppSopSizes
,
char
***
ppSops
);
/*=== cnfData.c ========================================================*/
extern
Cnf_Dat_t
*
Cnf_DeriveFast
(
Aig_Man_t
*
p
,
int
nOutputs
);
/*=== cnfMan.c ========================================================*/
extern
Cnf_Man_t
*
Cnf_ManStart
();
extern
void
Cnf_ManStop
(
Cnf_Man_t
*
p
);
...
...
src/aig/cnf/cnfFast.c
0 → 100644
View file @
12b70d49
/**CFile****************************************************************
FileName [cnfFast.c]
SystemName [ABC: Logic synthesis and verification system.]
PackageName [AIG-to-CNF conversion.]
Synopsis []
Author [Alan Mishchenko]
Affiliation [UC Berkeley]
Date [Ver. 1.0. Started - April 28, 2007.]
Revision [$Id: cnfFast.c,v 1.00 2007/04/28 00:00:00 alanmi Exp $]
***********************************************************************/
#include "cnf.h"
#include "kit.h"
#include "satSolver.h"
ABC_NAMESPACE_IMPL_START
////////////////////////////////////////////////////////////////////////
/// DECLARATIONS ///
////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////
/// FUNCTION DEFINITIONS ///
////////////////////////////////////////////////////////////////////////
/**Function*************************************************************
Synopsis [Detects multi-input gate rooted at this node.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void
Cnf_CollectSuper_rec
(
Aig_Obj_t
*
pRoot
,
Aig_Obj_t
*
pObj
,
Vec_Ptr_t
*
vSuper
,
int
fStopCompl
)
{
if
(
pRoot
!=
pObj
&&
(
pObj
->
fMarkA
||
(
fStopCompl
&&
Aig_IsComplement
(
pObj
)))
)
{
Vec_PtrPushUnique
(
vSuper
,
fStopCompl
?
pObj
:
Aig_Regular
(
pObj
)
);
return
;
}
assert
(
Aig_ObjIsNode
(
pObj
)
);
if
(
fStopCompl
)
{
Cnf_CollectSuper_rec
(
pRoot
,
Aig_ObjChild0
(
pObj
),
vSuper
,
1
);
Cnf_CollectSuper_rec
(
pRoot
,
Aig_ObjChild1
(
pObj
),
vSuper
,
1
);
}
else
{
Cnf_CollectSuper_rec
(
pRoot
,
Aig_ObjFanin0
(
pObj
),
vSuper
,
0
);
Cnf_CollectSuper_rec
(
pRoot
,
Aig_ObjFanin1
(
pObj
),
vSuper
,
0
);
}
}
/**Function*************************************************************
Synopsis [Detects multi-input gate rooted at this node.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void
Cnf_CollectSuper
(
Aig_Obj_t
*
pRoot
,
Vec_Ptr_t
*
vSuper
,
int
fStopCompl
)
{
assert
(
!
Aig_IsComplement
(
pRoot
)
);
Vec_PtrClear
(
vSuper
);
Cnf_CollectSuper_rec
(
pRoot
,
pRoot
,
vSuper
,
fStopCompl
);
}
/**Function*************************************************************
Synopsis [Collects nodes inside the cone.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void
Cnf_CollectVolume_rec
(
Aig_Man_t
*
p
,
Aig_Obj_t
*
pObj
,
Vec_Ptr_t
*
vNodes
)
{
if
(
Aig_ObjIsTravIdCurrent
(
p
,
pObj
)
)
return
;
Aig_ObjSetTravIdCurrent
(
p
,
pObj
);
assert
(
Aig_ObjIsNode
(
pObj
)
);
Cnf_CollectVolume_rec
(
p
,
Aig_ObjFanin0
(
pObj
),
vNodes
);
Cnf_CollectVolume_rec
(
p
,
Aig_ObjFanin1
(
pObj
),
vNodes
);
Vec_PtrPush
(
vNodes
,
pObj
);
}
/**Function*************************************************************
Synopsis [Collects nodes inside the cone.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void
Cnf_CollectVolume
(
Aig_Man_t
*
p
,
Aig_Obj_t
*
pRoot
,
Vec_Ptr_t
*
vLeaves
,
Vec_Ptr_t
*
vNodes
)
{
Aig_Obj_t
*
pObj
;
int
i
;
Aig_ManIncrementTravId
(
p
);
Vec_PtrForEachEntry
(
Aig_Obj_t
*
,
vLeaves
,
pObj
,
i
)
Aig_ObjSetTravIdCurrent
(
p
,
pObj
);
Vec_PtrClear
(
vNodes
);
Cnf_CollectVolume_rec
(
p
,
pRoot
,
vNodes
);
}
/**Function*************************************************************
Synopsis [Derive truth table.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
word
Cnf_CutDeriveTruth
(
Aig_Man_t
*
p
,
Vec_Ptr_t
*
vLeaves
,
Vec_Ptr_t
*
vNodes
)
{
static
word
Truth6
[
6
]
=
{
0xAAAAAAAAAAAAAAAA
,
0xCCCCCCCCCCCCCCCC
,
0xF0F0F0F0F0F0F0F0
,
0xFF00FF00FF00FF00
,
0xFFFF0000FFFF0000
,
0xFFFFFFFF00000000
};
static
word
C
[
2
]
=
{
0
,
~
0
};
static
word
S
[
256
];
Aig_Obj_t
*
pObj
;
int
i
;
assert
(
Vec_PtrSize
(
vLeaves
)
<=
6
&&
Vec_PtrSize
(
vNodes
)
>
0
);
assert
(
Vec_PtrSize
(
vLeaves
)
+
Vec_PtrSize
(
vNodes
)
<=
256
);
Vec_PtrForEachEntry
(
Aig_Obj_t
*
,
vLeaves
,
pObj
,
i
)
{
pObj
->
iData
=
i
;
S
[
pObj
->
iData
]
=
Truth6
[
i
];
}
Vec_PtrForEachEntry
(
Aig_Obj_t
*
,
vNodes
,
pObj
,
i
)
{
pObj
->
iData
=
Vec_PtrSize
(
vLeaves
)
+
i
;
S
[
pObj
->
iData
]
=
(
S
[
Aig_ObjFanin0
(
pObj
)
->
iData
]
^
C
[
Aig_ObjFaninC0
(
pObj
)])
&
(
S
[
Aig_ObjFanin1
(
pObj
)
->
iData
]
^
C
[
Aig_ObjFaninC1
(
pObj
)]);
}
return
S
[
pObj
->
iData
];
}
/**Function*************************************************************
Synopsis [Marks AIG for CNF computation.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void
Cnf_DeriveFastMark_
(
Aig_Man_t
*
p
)
{
Vec_Ptr_t
*
vLeaves
,
*
vNodes
;
Aig_Obj_t
*
pObj
,
*
pObjC
,
*
pObj0
,
*
pObj1
;
int
i
,
k
;
// mark CIs
Aig_ManForEachPi
(
p
,
pObj
,
i
)
pObj
->
fMarkA
=
1
;
// mark CO drivers
Aig_ManForEachPo
(
p
,
pObj
,
i
)
Aig_ObjFanin0
(
pObj
)
->
fMarkA
=
1
;
// mark roots/leaves of MUX/XOR with MarkA
// mark internal nodes of MUX/XOR with MarkB
Aig_ManForEachNode
(
p
,
pObj
,
i
)
{
if
(
!
Aig_ObjIsMuxType
(
pObj
)
)
continue
;
pObjC
=
Aig_ObjRecognizeMux
(
pObj
,
&
pObj1
,
&
pObj0
);
Aig_Regular
(
pObjC
)
->
fMarkA
=
1
;
Aig_Regular
(
pObj1
)
->
fMarkA
=
1
;
Aig_Regular
(
pObj0
)
->
fMarkA
=
1
;
Aig_ObjFanin0
(
pObj
)
->
fMarkB
=
1
;
Aig_ObjFanin1
(
pObj
)
->
fMarkB
=
1
;
}
// mark nodes with many fanouts or pointed to by a complemented edge
Aig_ManForEachNode
(
p
,
pObj
,
i
)
{
if
(
Aig_ObjRefs
(
pObj
)
>
1
)
pObj
->
fMarkA
=
1
;
if
(
Aig_ObjFaninC0
(
pObj
)
)
Aig_ObjFanin0
(
pObj
)
->
fMarkA
=
1
;
if
(
Aig_ObjFaninC1
(
pObj
)
)
Aig_ObjFanin1
(
pObj
)
->
fMarkA
=
1
;
}
// clean internal nodes of MUX/XOR
Aig_ManForEachNode
(
p
,
pObj
,
i
)
{
if
(
pObj
->
fMarkB
)
pObj
->
fMarkB
=
pObj
->
fMarkA
=
0
;
// pObj->fMarkB = 0;
}
// remove nodes those fanins are used
Aig_ManForEachNode
(
p
,
pObj
,
i
)
if
(
pObj
->
fMarkA
&&
Aig_ObjFanin0
(
pObj
)
->
fMarkA
&&
Aig_ObjFanin1
(
pObj
)
->
fMarkA
)
pObj
->
fMarkA
=
0
;
// mark CO drivers
Aig_ManForEachPo
(
p
,
pObj
,
i
)
Aig_ObjFanin0
(
pObj
)
->
fMarkA
=
1
;
/*
// if node has multiple fanout
Aig_ManForEachNode( p, pObj, i )
{
if ( Aig_ObjRefs(pObj) == 1 )
continue;
if ( Aig_ObjRefs(pObj) == 2 && Aig_ObjFanin0(pObj)->fMarkA && Aig_ObjFanin1(pObj)->fMarkA )
continue;
pObj->fMarkA = 1;
}
*/
// consider large cuts and mark inputs that are
vLeaves
=
Vec_PtrAlloc
(
100
);
vNodes
=
Vec_PtrAlloc
(
100
);
/*
while ( 1 )
{
int fChanges = 0;
Aig_ManForEachNode( p, pObj, i )
{
if ( !pObj->fMarkA )
continue;
if ( Aig_ObjRefs(pObj) == 1 )
continue;
Cnf_CollectSuper( pObj, vLeaves, 1 );
if ( Vec_PtrSize(vLeaves) <= 6 )
continue;
Vec_PtrForEachEntry( Aig_Obj_t *, vLeaves, pObjC, k )
{
if ( Aig_Regular(pObjC)->fMarkA == 0 )
fChanges = 1;
Aig_Regular(pObjC)->fMarkA = 1;
}
}
printf( "Round 1 \n" );
if ( !fChanges )
break;
}
*/
while
(
1
)
{
int
fChanges
=
0
;
Aig_ManForEachNode
(
p
,
pObj
,
i
)
{
if
(
!
pObj
->
fMarkA
)
continue
;
Cnf_CollectSuper
(
pObj
,
vLeaves
,
0
);
if
(
Vec_PtrSize
(
vLeaves
)
<=
6
)
continue
;
Cnf_CollectVolume
(
p
,
pObj
,
vLeaves
,
vNodes
);
Vec_PtrForEachEntry
(
Aig_Obj_t
*
,
vNodes
,
pObjC
,
k
)
{
if
(
Aig_ObjFaninC0
(
pObjC
)
&&
!
Aig_ObjFanin0
(
pObjC
)
->
fMarkA
)
{
Aig_ObjFanin0
(
pObjC
)
->
fMarkA
=
1
;
// printf( "%d ", Aig_ObjFaninId0(pObjC) );
fChanges
=
1
;
}
if
(
Aig_ObjFaninC1
(
pObjC
)
&&
!
Aig_ObjFanin1
(
pObjC
)
->
fMarkA
)
{
Aig_ObjFanin1
(
pObjC
)
->
fMarkA
=
1
;
// printf( "%d ", Aig_ObjFaninId1(pObjC) );
fChanges
=
1
;
}
}
}
printf
(
"Round 2
\n
"
);
if
(
!
fChanges
)
break
;
}
Vec_PtrFree
(
vLeaves
);
Vec_PtrFree
(
vNodes
);
}
/**Function*************************************************************
Synopsis [Marks AIG for CNF computation.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void
Cnf_DeriveFastMark
(
Aig_Man_t
*
p
)
{
Vec_Ptr_t
*
vLeaves
,
*
vNodes
;
Aig_Obj_t
*
pObj
,
*
pObjC
,
*
pObj0
,
*
pObj1
;
int
i
,
k
,
Counter
;
Aig_ManCleanMarkAB
(
p
);
// mark CIs
Aig_ManForEachPi
(
p
,
pObj
,
i
)
pObj
->
fMarkA
=
1
;
// mark CO drivers
Aig_ManForEachPo
(
p
,
pObj
,
i
)
Aig_ObjFanin0
(
pObj
)
->
fMarkA
=
1
;
Aig_ManForEachNode
(
p
,
pObj
,
i
)
{
// mark nodes with many fanouts
if
(
Aig_ObjRefs
(
pObj
)
>
1
)
pObj
->
fMarkA
=
1
;
// mark nodes pointed to by a complemented edge
if
(
Aig_ObjFaninC0
(
pObj
)
)
Aig_ObjFanin0
(
pObj
)
->
fMarkA
=
1
;
if
(
Aig_ObjFaninC1
(
pObj
)
)
Aig_ObjFanin1
(
pObj
)
->
fMarkA
=
1
;
// mark roots/leaves of MUX/XOR with MarkA
// mark internal nodes of MUX/XOR with MarkB
if
(
!
Aig_ObjIsMuxType
(
pObj
)
)
continue
;
pObjC
=
Aig_ObjRecognizeMux
(
pObj
,
&
pObj1
,
&
pObj0
);
Aig_Regular
(
pObjC
)
->
fMarkA
=
1
;
Aig_Regular
(
pObj1
)
->
fMarkA
=
1
;
Aig_Regular
(
pObj0
)
->
fMarkA
=
1
;
Aig_ObjFanin0
(
pObj
)
->
fMarkB
=
1
;
Aig_ObjFanin1
(
pObj
)
->
fMarkB
=
1
;
}
// clean internal nodes of MUX/XOR
Aig_ManForEachNode
(
p
,
pObj
,
i
)
{
if
(
!
pObj
->
fMarkB
)
continue
;
pObj
->
fMarkB
=
0
;
if
(
Aig_ObjRefs
(
pObj
)
==
1
)
pObj
->
fMarkA
=
0
;
}
// remove nodes those fanins are used
Aig_ManForEachNode
(
p
,
pObj
,
i
)
if
(
pObj
->
fMarkA
&&
Aig_ObjFanin0
(
pObj
)
->
fMarkA
&&
Aig_ObjFanin1
(
pObj
)
->
fMarkA
)
pObj
->
fMarkA
=
0
;
// mark CO drivers
Aig_ManForEachPo
(
p
,
pObj
,
i
)
Aig_ObjFanin0
(
pObj
)
->
fMarkA
=
1
;
vLeaves
=
Vec_PtrAlloc
(
100
);
vNodes
=
Vec_PtrAlloc
(
100
);
while
(
1
)
{
int
nChanges
=
0
;
Aig_ManForEachNode
(
p
,
pObj
,
i
)
{
if
(
!
pObj
->
fMarkA
)
continue
;
Cnf_CollectSuper
(
pObj
,
vLeaves
,
0
);
if
(
Vec_PtrSize
(
vLeaves
)
<=
6
)
continue
;
Cnf_CollectVolume
(
p
,
pObj
,
vLeaves
,
vNodes
);
Vec_PtrForEachEntry
(
Aig_Obj_t
*
,
vNodes
,
pObjC
,
k
)
{
if
(
Aig_ObjFaninC0
(
pObjC
)
&&
!
Aig_ObjFanin0
(
pObjC
)
->
fMarkA
)
{
Aig_ObjFanin0
(
pObjC
)
->
fMarkA
=
1
;
// printf( "%d ", Aig_ObjFaninId0(pObjC) );
nChanges
++
;
}
if
(
Aig_ObjFaninC1
(
pObjC
)
&&
!
Aig_ObjFanin1
(
pObjC
)
->
fMarkA
)
{
Aig_ObjFanin1
(
pObjC
)
->
fMarkA
=
1
;
// printf( "%d ", Aig_ObjFaninId1(pObjC) );
nChanges
++
;
}
}
}
printf
(
"Made %d gate changes
\n
"
,
nChanges
);
if
(
!
nChanges
)
break
;
}
// check CO drivers
Counter
=
0
;
Aig_ManForEachPo
(
p
,
pObj
,
i
)
Counter
+=
!
Aig_ObjFanin0
(
pObj
)
->
fMarkA
;
printf
(
"PO-driver rule is violated %d times.
\n
"
,
Counter
);
// check that the AND-gates are fine
Counter
=
0
;
Aig_ManForEachNode
(
p
,
pObj
,
i
)
{
assert
(
pObj
->
fMarkB
==
0
);
if
(
!
pObj
->
fMarkA
)
continue
;
Cnf_CollectSuper
(
pObj
,
vLeaves
,
0
);
if
(
Vec_PtrSize
(
vLeaves
)
<=
6
)
continue
;
Cnf_CollectVolume
(
p
,
pObj
,
vLeaves
,
vNodes
);
Vec_PtrForEachEntry
(
Aig_Obj_t
*
,
vNodes
,
pObj1
,
k
)
{
if
(
Aig_ObjFaninC0
(
pObj1
)
&&
!
Aig_ObjFanin0
(
pObj1
)
->
fMarkA
)
Counter
++
;
if
(
Aig_ObjFaninC1
(
pObj1
)
&&
!
Aig_ObjFanin1
(
pObj1
)
->
fMarkA
)
Counter
++
;
}
}
Vec_PtrFree
(
vLeaves
);
Vec_PtrFree
(
vNodes
);
printf
(
"AND-gate rule is violated %d times.
\n
"
,
Counter
);
}
/**Function*************************************************************
Synopsis [Counts the number of clauses.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int
Cnf_CutCountClauses
(
Aig_Man_t
*
p
,
Vec_Ptr_t
*
vLeaves
,
Vec_Ptr_t
*
vNodes
,
Vec_Int_t
*
vCover
)
{
word
Truth
;
Aig_Obj_t
*
pObj
;
int
i
,
RetValue
,
nSize
=
0
;
if
(
Vec_PtrSize
(
vLeaves
)
>
6
)
{
// make sure this is an AND gate
Vec_PtrForEachEntry
(
Aig_Obj_t
*
,
vNodes
,
pObj
,
i
)
{
if
(
Aig_ObjFaninC0
(
pObj
)
&&
!
Aig_ObjFanin0
(
pObj
)
->
fMarkA
)
printf
(
"Unusual 1!
\n
"
);
if
(
Aig_ObjFaninC1
(
pObj
)
&&
!
Aig_ObjFanin1
(
pObj
)
->
fMarkA
)
printf
(
"Unusual 2!
\n
"
);
continue
;
assert
(
!
Aig_ObjFaninC0
(
pObj
)
||
Aig_ObjFanin0
(
pObj
)
->
fMarkA
);
assert
(
!
Aig_ObjFaninC1
(
pObj
)
||
Aig_ObjFanin1
(
pObj
)
->
fMarkA
);
}
return
Vec_PtrSize
(
vLeaves
)
+
1
;
}
Truth
=
Cnf_CutDeriveTruth
(
p
,
vLeaves
,
vNodes
);
RetValue
=
Kit_TruthIsop
(
(
unsigned
*
)
&
Truth
,
Vec_PtrSize
(
vLeaves
),
vCover
,
0
);
assert
(
RetValue
>=
0
);
nSize
+=
Vec_IntSize
(
vCover
);
Truth
=
~
Truth
;
RetValue
=
Kit_TruthIsop
(
(
unsigned
*
)
&
Truth
,
Vec_PtrSize
(
vLeaves
),
vCover
,
0
);
assert
(
RetValue
>=
0
);
nSize
+=
Vec_IntSize
(
vCover
);
return
nSize
;
}
/**Function*************************************************************
Synopsis [Counts the size of the CNF, assuming marks are set.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int
Cnf_CountCnfSize
(
Aig_Man_t
*
p
)
{
Vec_Ptr_t
*
vLeaves
,
*
vNodes
;
Vec_Int_t
*
vCover
;
Aig_Obj_t
*
pObj
;
int
nVars
=
0
,
nClauses
=
0
;
int
i
,
nSize
;
vLeaves
=
Vec_PtrAlloc
(
100
);
vNodes
=
Vec_PtrAlloc
(
100
);
vCover
=
Vec_IntAlloc
(
1
<<
16
);
Aig_ManForEachObj
(
p
,
pObj
,
i
)
nVars
+=
pObj
->
fMarkA
;
Aig_ManForEachNode
(
p
,
pObj
,
i
)
{
if
(
!
pObj
->
fMarkA
)
continue
;
Cnf_CollectSuper
(
pObj
,
vLeaves
,
0
);
Cnf_CollectVolume
(
p
,
pObj
,
vLeaves
,
vNodes
);
assert
(
pObj
==
Vec_PtrEntryLast
(
vNodes
)
);
nSize
=
Cnf_CutCountClauses
(
p
,
vLeaves
,
vNodes
,
vCover
);
// printf( "%d(%d) ", Vec_PtrSize(vLeaves), nSize );
nClauses
+=
nSize
;
}
// printf( "\n" );
printf
(
"Vars = %d Clauses = %d
\n
"
,
nVars
,
nClauses
);
Vec_PtrFree
(
vLeaves
);
Vec_PtrFree
(
vNodes
);
Vec_IntFree
(
vCover
);
return
nClauses
;
}
/**Function*************************************************************
Synopsis [Derives CNF from the marked AIG.]
Description [Assumes that marking is such that when we traverse from each
marked node, the logic cone has 6 inputs or less, or it is a multi-input AND.]
SideEffects []
SeeAlso []
***********************************************************************/
Cnf_Dat_t
*
Cnf_DeriveFastClauses
(
Aig_Man_t
*
p
,
int
nOutputs
)
{
Cnf_Dat_t
*
pCnf
;
Vec_Int_t
*
vLits
,
*
vClas
,
*
vMap
;
Vec_Ptr_t
*
vLeaves
,
*
vNodes
;
Vec_Int_t
*
vCover
;
Aig_Obj_t
*
pObj
,
*
pLeaf
;
int
i
,
c
,
k
,
nVars
,
Cube
,
Entry
,
OutLit
,
DriLit
,
RetValue
;
word
Truth
;
vLits
=
Vec_IntAlloc
(
1
<<
16
);
vClas
=
Vec_IntAlloc
(
1
<<
12
);
vMap
=
Vec_IntStartFull
(
Aig_ManObjNumMax
(
p
)
);
// assign variables for the outputs
nVars
=
1
;
if
(
nOutputs
)
{
if
(
Aig_ManRegNum
(
p
)
==
0
)
{
assert
(
nOutputs
==
Aig_ManPoNum
(
p
)
);
Aig_ManForEachPo
(
p
,
pObj
,
i
)
Vec_IntWriteEntry
(
vMap
,
Aig_ObjId
(
pObj
),
nVars
++
);
}
else
{
assert
(
nOutputs
==
Aig_ManRegNum
(
p
)
);
Aig_ManForEachLiSeq
(
p
,
pObj
,
i
)
Vec_IntWriteEntry
(
vMap
,
Aig_ObjId
(
pObj
),
nVars
++
);
}
}
// assign variables to the internal nodes
Aig_ManForEachNodeReverse
(
p
,
pObj
,
i
)
if
(
pObj
->
fMarkA
)
Vec_IntWriteEntry
(
vMap
,
Aig_ObjId
(
pObj
),
nVars
++
);
// assign variables to the PIs and constant node
Aig_ManForEachPi
(
p
,
pObj
,
i
)
Vec_IntWriteEntry
(
vMap
,
Aig_ObjId
(
pObj
),
nVars
++
);
Vec_IntWriteEntry
(
vMap
,
Aig_ObjId
(
Aig_ManConst1
(
p
)),
nVars
++
);
// create clauses
vLeaves
=
Vec_PtrAlloc
(
100
);
vNodes
=
Vec_PtrAlloc
(
100
);
vCover
=
Vec_IntAlloc
(
1
<<
16
);
Aig_ManForEachNodeReverse
(
p
,
pObj
,
i
)
{
if
(
!
pObj
->
fMarkA
)
continue
;
OutLit
=
toLit
(
Vec_IntEntry
(
vMap
,
Aig_ObjId
(
pObj
))
);
// detect cone
Cnf_CollectSuper
(
pObj
,
vLeaves
,
0
);
Cnf_CollectVolume
(
p
,
pObj
,
vLeaves
,
vNodes
);
assert
(
pObj
==
Vec_PtrEntryLast
(
vNodes
)
);
// check if this is an AND-gate
Vec_PtrForEachEntry
(
Aig_Obj_t
*
,
vNodes
,
pLeaf
,
k
)
{
if
(
Aig_ObjFaninC0
(
pLeaf
)
&&
!
Aig_ObjFanin0
(
pLeaf
)
->
fMarkA
)
break
;
if
(
Aig_ObjFaninC1
(
pLeaf
)
&&
!
Aig_ObjFanin1
(
pLeaf
)
->
fMarkA
)
break
;
}
if
(
k
==
Vec_PtrSize
(
vNodes
)
)
{
Cnf_CollectSuper
(
pObj
,
vLeaves
,
1
);
// write big clause
Vec_IntPush
(
vClas
,
Vec_IntSize
(
vLits
)
);
Vec_IntPush
(
vLits
,
OutLit
);
Vec_PtrForEachEntry
(
Aig_Obj_t
*
,
vLeaves
,
pLeaf
,
k
)
Vec_IntPush
(
vLits
,
toLitCond
(
Vec_IntEntry
(
vMap
,
Aig_ObjId
(
Aig_Regular
(
pLeaf
))),
!
Aig_IsComplement
(
pLeaf
))
);
// write small clauses
Vec_PtrForEachEntry
(
Aig_Obj_t
*
,
vLeaves
,
pLeaf
,
k
)
{
Vec_IntPush
(
vClas
,
Vec_IntSize
(
vLits
)
);
Vec_IntPush
(
vLits
,
lit_neg
(
OutLit
)
);
Vec_IntPush
(
vLits
,
toLitCond
(
Vec_IntEntry
(
vMap
,
Aig_ObjId
(
Aig_Regular
(
pLeaf
))),
Aig_IsComplement
(
pLeaf
))
);
}
continue
;
}
assert
(
Vec_PtrSize
(
vLeaves
)
<=
6
);
Truth
=
Cnf_CutDeriveTruth
(
p
,
vLeaves
,
vNodes
);
if
(
Truth
==
0
||
Truth
==
~
0
)
{
assert
(
RetValue
==
0
);
Vec_IntPush
(
vClas
,
Vec_IntSize
(
vLits
)
);
Vec_IntPush
(
vLits
,
(
Truth
==
0
)
?
lit_neg
(
OutLit
)
:
OutLit
);
continue
;
}
RetValue
=
Kit_TruthIsop
(
(
unsigned
*
)
&
Truth
,
Vec_PtrSize
(
vLeaves
),
vCover
,
0
);
assert
(
RetValue
>=
0
);
Vec_IntForEachEntry
(
vCover
,
Cube
,
c
)
{
Vec_IntPush
(
vClas
,
Vec_IntSize
(
vLits
)
);
Vec_IntPush
(
vLits
,
OutLit
);
for
(
k
=
0
;
k
<
Vec_PtrSize
(
vLeaves
);
k
++
,
Cube
>>=
2
)
{
if
(
(
Cube
&
3
)
==
0
)
continue
;
assert
(
(
Cube
&
3
)
!=
3
);
Vec_IntPush
(
vLits
,
toLitCond
(
Vec_IntEntry
(
vMap
,
Aig_ObjId
(
Vec_PtrEntry
(
vLeaves
,
k
))),
(
Cube
&
3
)
!=
1
)
);
}
}
Truth
=
~
Truth
;
RetValue
=
Kit_TruthIsop
(
(
unsigned
*
)
&
Truth
,
Vec_PtrSize
(
vLeaves
),
vCover
,
0
);
assert
(
RetValue
>=
0
);
Vec_IntForEachEntry
(
vCover
,
Cube
,
c
)
{
Vec_IntPush
(
vClas
,
Vec_IntSize
(
vLits
)
);
Vec_IntPush
(
vLits
,
lit_neg
(
OutLit
)
);
for
(
k
=
0
;
k
<
Vec_PtrSize
(
vLeaves
);
k
++
,
Cube
>>=
2
)
{
if
(
(
Cube
&
3
)
==
0
)
continue
;
assert
(
(
Cube
&
3
)
!=
3
);
Vec_IntPush
(
vLits
,
toLitCond
(
Vec_IntEntry
(
vMap
,
Aig_ObjId
(
Vec_PtrEntry
(
vLeaves
,
k
))),
(
Cube
&
3
)
==
1
)
);
}
}
}
Vec_PtrFree
(
vLeaves
);
Vec_PtrFree
(
vNodes
);
Vec_IntFree
(
vCover
);
// create clauses for the outputs
Aig_ManForEachPo
(
p
,
pObj
,
i
)
{
DriLit
=
toLitCond
(
Vec_IntEntry
(
vMap
,
Aig_ObjFaninId0
(
pObj
)),
Aig_ObjFaninC0
(
pObj
)
);
if
(
i
<
Aig_ManPoNum
(
p
)
-
nOutputs
)
{
Vec_IntPush
(
vClas
,
Vec_IntSize
(
vLits
)
);
Vec_IntPush
(
vLits
,
DriLit
);
}
else
{
OutLit
=
toLit
(
Vec_IntEntry
(
vMap
,
Aig_ObjId
(
pObj
))
);
// first clause
Vec_IntPush
(
vClas
,
Vec_IntSize
(
vLits
)
);
Vec_IntPush
(
vLits
,
OutLit
);
Vec_IntPush
(
vLits
,
lit_neg
(
DriLit
)
);
// second clause
Vec_IntPush
(
vClas
,
Vec_IntSize
(
vLits
)
);
Vec_IntPush
(
vLits
,
lit_neg
(
OutLit
)
);
Vec_IntPush
(
vLits
,
DriLit
);
}
}
// write the constant literal
OutLit
=
toLit
(
Vec_IntEntry
(
vMap
,
Aig_ObjId
(
Aig_ManConst1
(
p
)))
);
Vec_IntPush
(
vClas
,
Vec_IntSize
(
vLits
)
);
Vec_IntPush
(
vLits
,
OutLit
);
// create structure
pCnf
=
ABC_CALLOC
(
Cnf_Dat_t
,
1
);
pCnf
->
pMan
=
p
;
pCnf
->
nVars
=
nVars
;
pCnf
->
nLiterals
=
Vec_IntSize
(
vLits
);
pCnf
->
nClauses
=
Vec_IntSize
(
vClas
);
pCnf
->
pClauses
=
ABC_ALLOC
(
int
*
,
pCnf
->
nClauses
+
1
);
pCnf
->
pClauses
[
0
]
=
Vec_IntReleaseArray
(
vLits
);
Vec_IntForEachEntry
(
vClas
,
Entry
,
i
)
pCnf
->
pClauses
[
i
]
=
pCnf
->
pClauses
[
0
]
+
Entry
;
pCnf
->
pClauses
[
pCnf
->
nClauses
]
=
pCnf
->
pClauses
[
0
]
+
pCnf
->
nLiterals
;
pCnf
->
pVarNums
=
Vec_IntReleaseArray
(
vMap
);
// cleanup
Vec_IntFree
(
vLits
);
Vec_IntFree
(
vClas
);
Vec_IntFree
(
vMap
);
return
pCnf
;
}
/**Function*************************************************************
Synopsis [Fast CNF computation.]
Description []
SideEffects []
SeeAlso []
***********************************************************************/
Cnf_Dat_t
*
Cnf_DeriveFast
(
Aig_Man_t
*
p
,
int
nOutputs
)
{
Cnf_Dat_t
*
pCnf
=
NULL
;
int
clk
,
clkTotal
=
clock
();
printf
(
"
\n
"
);
Aig_ManCleanMarkAB
(
p
);
// create initial marking
clk
=
clock
();
Cnf_DeriveFastMark
(
p
);
Abc_PrintTime
(
1
,
"Marking"
,
clock
()
-
clk
);
// compute CNF size
clk
=
clock
();
pCnf
=
Cnf_DeriveFastClauses
(
p
,
nOutputs
);
Abc_PrintTime
(
1
,
"Clauses"
,
clock
()
-
clk
);
// derive the resulting CNF
Aig_ManCleanMarkA
(
p
);
Abc_PrintTime
(
1
,
"TOTAL "
,
clock
()
-
clkTotal
);
printf
(
"Vars = %6d. Clauses = %7d. Literals = %8d.
\n
"
,
pCnf
->
nVars
,
pCnf
->
nClauses
,
pCnf
->
nLiterals
);
// Cnf_DataFree( pCnf );
// pCnf = NULL;
return
pCnf
;
}
////////////////////////////////////////////////////////////////////////
/// END OF FILE ///
////////////////////////////////////////////////////////////////////////
ABC_NAMESPACE_IMPL_END
src/aig/cnf/module.make
View file @
12b70d49
SRC
+=
src/aig/cnf/cnfCore.c
\
src/aig/cnf/cnfCut.c
\
src/aig/cnf/cnfData.c
\
src/aig/cnf/cnfFast.c
\
src/aig/cnf/cnfMan.c
\
src/aig/cnf/cnfMap.c
\
src/aig/cnf/cnfPost.c
\
...
...
src/base/abci/abcDar.c
View file @
12b70d49
...
...
@@ -1172,13 +1172,14 @@ Abc_Ntk_t * Abc_NtkConstructFromCnf( Abc_Ntk_t * pNtk, Cnf_Man_t * p, Vec_Ptr_t
SeeAlso []
***********************************************************************/
Abc_Ntk_t
*
Abc_NtkDarToCnf
(
Abc_Ntk_t
*
pNtk
,
char
*
pFileName
)
Abc_Ntk_t
*
Abc_NtkDarToCnf
(
Abc_Ntk_t
*
pNtk
,
char
*
pFileName
,
int
fFastAlgo
,
int
fChangePol
,
int
fVerbose
)
{
Vec_Ptr_t
*
vMapped
=
NULL
;
Aig_Man_t
*
pMan
;
Cnf_Man_t
*
pManCnf
=
NULL
;
Cnf_Dat_t
*
pCnf
;
Abc_Ntk_t
*
pNtkNew
=
NULL
;
int
clk
=
clock
();
assert
(
Abc_NtkIsStrash
(
pNtk
)
);
// convert to the AIG manager
...
...
@@ -1192,12 +1193,25 @@ Abc_Ntk_t * Abc_NtkDarToCnf( Abc_Ntk_t * pNtk, char * pFileName )
return
NULL
;
}
// perform balance
if
(
fVerbose
)
Aig_ManPrintStats
(
pMan
);
// derive CNF
pCnf
=
Cnf_Derive
(
pMan
,
0
);
Cnf_DataTranformPolarity
(
pCnf
,
0
);
printf
(
"Vars = %6d. Clauses = %7d. Literals = %8d.
\n
"
,
pCnf
->
nVars
,
pCnf
->
nClauses
,
pCnf
->
nLiterals
);
if
(
fFastAlgo
)
pCnf
=
Cnf_DeriveFast
(
pMan
,
0
);
else
pCnf
=
Cnf_Derive
(
pMan
,
0
);
// adjust polarity
if
(
fChangePol
)
Cnf_DataTranformPolarity
(
pCnf
,
0
);
// print stats
if
(
fVerbose
)
{
printf
(
"Vars = %6d. Clauses = %7d. Literals = %8d. "
,
pCnf
->
nVars
,
pCnf
->
nClauses
,
pCnf
->
nLiterals
);
Abc_PrintTime
(
1
,
"Time"
,
clock
()
-
clk
);
}
/*
// write the network for verification
...
...
@@ -1210,7 +1224,6 @@ Abc_Ntk_t * Abc_NtkDarToCnf( Abc_Ntk_t * pNtk, char * pFileName )
Cnf_DataWriteIntoFile
(
pCnf
,
pFileName
,
0
);
Cnf_DataFree
(
pCnf
);
Cnf_ClearMemory
();
Aig_ManStop
(
pMan
);
return
pNtkNew
;
}
...
...
src/base/io/io.c
View file @
12b70d49
...
...
@@ -1865,23 +1865,38 @@ int IoCommandWriteCnf( Abc_Frame_t * pAbc, int argc, char **argv )
{
char
*
pFileName
;
int
c
;
int
fAllPrimes
;
int
fNewAlgo
;
extern
Abc_Ntk_t
*
Abc_NtkDarToCnf
(
Abc_Ntk_t
*
pNtk
,
char
*
pFileName
);
int
fFastAlgo
;
int
fAllPrimes
;
int
fChangePol
;
int
fVerbose
;
extern
Abc_Ntk_t
*
Abc_NtkDarToCnf
(
Abc_Ntk_t
*
pNtk
,
char
*
pFileName
,
int
fFastAlgo
,
int
fChangePol
,
int
fVerbose
);
fNewAlgo
=
1
;
fFastAlgo
=
0
;
fAllPrimes
=
0
;
fChangePol
=
1
;
fVerbose
=
0
;
Extra_UtilGetoptReset
();
while
(
(
c
=
Extra_UtilGetopt
(
argc
,
argv
,
"n
p
h"
)
)
!=
EOF
)
while
(
(
c
=
Extra_UtilGetopt
(
argc
,
argv
,
"n
fpcv
h"
)
)
!=
EOF
)
{
switch
(
c
)
{
case
'n'
:
fNewAlgo
^=
1
;
break
;
case
'f'
:
fFastAlgo
^=
1
;
break
;
case
'p'
:
fAllPrimes
^=
1
;
break
;
case
'c'
:
fChangePol
^=
1
;
break
;
case
'v'
:
fVerbose
^=
1
;
break
;
case
'h'
:
goto
usage
;
default:
...
...
@@ -1904,8 +1919,10 @@ int IoCommandWriteCnf( Abc_Frame_t * pAbc, int argc, char **argv )
printf
(
"Warning: Selected option to write all primes has no effect when deriving CNF from AIG.
\n
"
);
}
// call the corresponding file writer
if
(
fNewAlgo
)
Abc_NtkDarToCnf
(
pAbc
->
pNtkCur
,
pFileName
);
if
(
fFastAlgo
)
Abc_NtkDarToCnf
(
pAbc
->
pNtkCur
,
pFileName
,
1
,
fChangePol
,
fVerbose
);
else
if
(
fNewAlgo
)
Abc_NtkDarToCnf
(
pAbc
->
pNtkCur
,
pFileName
,
0
,
fChangePol
,
fVerbose
);
else
if
(
fAllPrimes
)
Io_WriteCnf
(
pAbc
->
pNtkCur
,
pFileName
,
1
);
else
...
...
@@ -1913,10 +1930,13 @@ int IoCommandWriteCnf( Abc_Frame_t * pAbc, int argc, char **argv )
return
0
;
usage:
fprintf
(
pAbc
->
Err
,
"usage: write_cnf [-n
p
h] <file>
\n
"
);
fprintf
(
pAbc
->
Err
,
"usage: write_cnf [-n
fpcv
h] <file>
\n
"
);
fprintf
(
pAbc
->
Err
,
"
\t
writes the miter cone into a CNF file
\n
"
);
fprintf
(
pAbc
->
Err
,
"
\t
-n : toggle using new algorithm [default = %s]
\n
"
,
fNewAlgo
?
"yes"
:
"no"
);
fprintf
(
pAbc
->
Err
,
"
\t
-f : toggle using fast algorithm [default = %s]
\n
"
,
fFastAlgo
?
"yes"
:
"no"
);
fprintf
(
pAbc
->
Err
,
"
\t
-p : toggle using all primes to enhance implicativity [default = %s]
\n
"
,
fAllPrimes
?
"yes"
:
"no"
);
fprintf
(
pAbc
->
Err
,
"
\t
-c : toggle adjasting polarity of internal variables [default = %s]
\n
"
,
fChangePol
?
"yes"
:
"no"
);
fprintf
(
pAbc
->
Err
,
"
\t
-v : toggle printing verbose information [default = %s]
\n
"
,
fVerbose
?
"yes"
:
"no"
);
fprintf
(
pAbc
->
Err
,
"
\t
-h : print the help massage
\n
"
);
fprintf
(
pAbc
->
Err
,
"
\t
file : the name of the file to write
\n
"
);
return
1
;
...
...
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