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lvzhengyang
abc
Commits
08bb54f3
Commit
08bb54f3
authored
Dec 02, 2013
by
Alan Mishchenko
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New canonical DSD form.
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08bb54f3
/**CFile****************************************************************
FileName [dauDsd2.c]
SystemName [ABC: Logic synthesis and verification system.]
PackageName [DAG-aware unmapping.]
Synopsis [Disjoint-support decomposition.]
Author [Alan Mishchenko]
Affiliation [UC Berkeley]
Date [Ver. 1.0. Started - June 20, 2005.]
Revision [$Id: dauDsd2.c,v 1.00 2005/06/20 00:00:00 alanmi Exp $]
***********************************************************************/
#include "dauInt.h"
#include "misc/util/utilTruth.h"
ABC_NAMESPACE_IMPL_START
////////////////////////////////////////////////////////////////////////
/// DECLARATIONS ///
////////////////////////////////////////////////////////////////////////
#include DSD_MAX_VAR 12
#include DSD_MAX_WRD ((DSD_MAX_VAR > 6) ? (1 << (DSD_MAX_VAR-6)) : 1)
typedef
struct
Dua_Obj_t_
Dua_Obj_t
;
struct
Dua_Obj_t_
{
int
Type
;
// dec type (1=var; 2=and; 3=xor; 4=mux; 5=prime)
int
nFans
;
// fanin count
char
pFans
[
DSD_MAX_VAR
];
// fanins
};
typedef
struct
Dua_Dsd_t_
Dua_Dsd_t
;
struct
Dua_Dsd_t_
{
int
nSupp
;
// original variables
int
nVars
;
// remaining variables
int
nWords
;
// largest non-dec prime
int
nObjs
;
// object count
int
iRoot
;
// the root of the tree
Dua_Obj_t
pObjs
[
DSD_MAX_VAR
];
// objects
word
pTruth
[
DSD_MAX_WRD
];
// original/current truth table
};
////////////////////////////////////////////////////////////////////////
/// FUNCTION DEFINITIONS ///
////////////////////////////////////////////////////////////////////////
/**Function*************************************************************
Synopsis [Makes the fCof1-th cofactor of iVar the 0-th cofactor.]
Description [Variable iVar becomes last varaible; others shift back.
Only the 0-th cofactor is computed.]
SideEffects []
SeeAlso []
***********************************************************************/
static
inline
word
Abc_Tt6HalfUnShuffleVars
(
word
t
,
int
iVar
,
int
fCof1
)
{
static
word
Masks
[
6
]
=
{
ABC_CONST
(
0x5555555555555555
),
ABC_CONST
(
0x3333333333333333
),
ABC_CONST
(
0x0F0F0F0F0F0F0F0F
),
ABC_CONST
(
0x00FF00FF00FF00FF
),
ABC_CONST
(
0x0000FFFF0000FFFF
),
ABC_CONST
(
0x00000000FFFFFFFF
)
};
int
v
,
s
=
(
1
<<
iVar
);
t
=
(
t
>>
(
fCof1
?
0
:
s
))
&
Masks
[
iVar
];
for
(
v
=
iVar
,
s
=
(
1
<<
v
);
v
<
5
;
v
++
,
s
<<=
1
)
t
=
((
t
>>
s
)
|
t
)
&
Masks
[
v
+
1
];
return
t
;
}
static
inline
void
Abc_TtHalfUnShuffleVars
(
word
*
pTruth
,
int
nVars
,
int
iVar
,
int
jVar
,
int
fCof1
)
{
int
w
,
nWords
=
Abc_TtWordNum
(
nVars
);
if
(
iVar
==
jVar
)
return
;
assert
(
iVar
<
jVar
);
if
(
iVar
<
5
)
{
for
(
w
=
0
;
w
<
nWords
;
w
++
)
pTruth
[
w
]
=
Abc_Tt6HalfUnShuffleVars
(
pTruth
[
w
],
iVar
,
fCof1
);
iVar
=
5
;
}
if
(
jVar
<
6
)
{
for
(
w
=
0
;
w
<
nWords
;
w
++
)
pTruth
[
w
]
=
(
pTruth
[
w
]
<<
32
)
|
pTruth
[
w
];
return
;
}
if
(
iVar
==
5
)
{
unsigned
*
pTruthU
=
(
unsigned
*
)
pTruth
;
for
(
w
=
0
;
w
<
nWords
;
w
+=
2
)
pTruthU
[
w
]
=
pTruthU
[
w
+
1
];
iVar
=
6
;
}
{
word
*
pLimit
=
pTruth
+
nWords
;
int
i
,
iStep
=
Abc_TtWordNum
(
iVar
);
int
j
,
jStep
=
Abc_TtWordNum
(
jVar
);
for
(
;
pTruth
<
pLimit
;
pTruth
+=
jStep
)
for
(
i
=
0
;
i
<
jStep
;
i
+=
iStep
)
for
(
j
=
0
;
j
<
iStep
;
j
++
)
pTruth
[
w
++
]
=
pTruth
[
iStep
+
i
+
j
];
assert
(
w
==
(
nWords
>>
1
)
);
return
;
}
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void
Dua_DsdInit
(
Dua_Dsd_t
*
pRes
,
word
*
pTruth
,
int
nVars
)
{
int
i
;
pRes
->
nSupp
=
nVars
;
pRes
->
nVars
=
nVars
;
pRes
->
nWords
=
Abc_TtWordNum
(
nVars
);
pRes
->
nObjs
=
1
;
pRes
->
iRoot
=
Abc_Var2Lit
(
0
,
0
);
pRes
->
pObjs
[
0
].
Type
=
5
;
pRes
->
pObjs
[
0
].
nFans
=
nVars
;
for
(
i
=
0
;
i
<
nVars
;
i
++
)
pRes
->
pObjs
[
0
].
pFans
[
i
]
=
(
char
)
Abc_Var2Lit
(
i
,
0
);
memcpy
(
pRes
->
pTruth
,
pTruth
,
sizeof
(
word
)
*
pRes
->
nWords
);
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
// returns 1 if the truth table was complemented
int
Dua_DsdTryConst
(
word
*
pTruth
,
int
nVars
)
{
if
(
!
(
pTruth
[
0
]
&
1
)
)
return
0
;
Abc_TtNot
(
pTruth
,
Abc_TtWordNum
(
nVars
)
);
return
1
;
}
int
Dua_DsdTryVar
(
word
*
pTruth
,
int
nWords
,
int
iVar
)
{
int
nWordsI
=
Abc_TtWordNum
(
iVar
);
word
c0
=
(
iVar
<
6
)
?
Abc_Tt6Cofactor0
(
pTruth
[
0
],
iVar
)
:
pTruth
[
0
];
word
c1
=
(
iVar
<
6
)
?
Abc_Tt6Cofactor1
(
pTruth
[
0
],
iVar
)
:
pTruth
[
nWords
];
if
(
c0
!=
c1
)
{
if
(
c1
<
c0
&&
c1
<
~
c1
)
// flip
{
Abc_TtFlip
(
pTruth
,
nWords
,
iVar
);
return
0
;
}
if
(
~
c1
<
c0
&&
~
c1
<
c1
)
// flip and compl
{
Abc_TtFlipNot
(
pTruth
,
nWords
,
iVar
);
return
1
;
}
}
if
(
iVar
<
6
)
{
word
*
pLimit
=
pTruth
+
nWords
;
for
(
pTruth
++
;
pTruth
<
pLimit
;
pTruth
++
)
{
c0
=
Abc_Tt6Cofactor0
(
pTruth
[
0
],
iVar
);
c1
=
Abc_Tt6Cofactor1
(
pTruth
[
0
],
iVar
);
if
(
c0
==
c1
)
continue
;
if
(
c0
<
c1
)
return
0
;
for
(
;
pTruth
<
pLimit
;
pTruth
++
)
pTruth
[
0
]
=
Abc_Tt6Flip
(
pTruth
[
0
],
iVar
);
return
0
;
}
}
else
{
for
(
;
pTruth
<
pLimit
;
pTruth
+=
(
nWordsI
<<
1
)
)
for
(
w
=
0
;
w
<
nWordsI
;
w
++
)
{
c0
=
pTruth
[
0
];
c1
=
pTruth
[
nWordsI
];
if
(
c0
==
c1
)
continue
;
if
(
c0
<
c1
)
return
0
;
for
(
;
pTruth
<
pLimit
;
pTruth
+=
(
nWordsI
<<
1
)
)
for
(
;
w
<
nWordsI
;
w
++
)
ABC_SWAP
(
word
,
pTruth
[
0
],
pTruth
[
nWordsI
]
);
return
0
;
}
}
assert
(
0
);
return
-
1
;
}
int
Dua_DsdCheckCof0Const0
(
word
*
pTruth
,
int
nWords
,
int
iVar
)
{
if
(
nWords
==
1
)
return
(
pTruth
[
0
]
&
s_Truths6Neg
[
iVar
])
==
0
;
if
(
iVar
<=
5
)
{
int
w
;
for
(
w
=
0
;
w
<
nWords
;
w
++
)
if
(
(
pTruth
[
w
]
&
s_Truths6Neg
[
iVar
])
)
return
0
;
return
1
;
}
else
// if ( iVar > 5 )
{
word
*
pLimit
=
pTruth
+
nWords
;
int
i
,
iStep
=
Abc_TtWordNum
(
iVar
);
for
(
;
pTruth
<
pLimit
;
pTruth
+=
(
iStep
<<
1
)
)
for
(
i
=
0
;
i
<
iStep
;
i
++
)
if
(
pTruth
[
i
]
)
return
0
;
return
1
;
}
}
int
Dua_DsdCheckCofsEqualNot
(
word
*
pTruth
,
int
nWords
,
int
iVar
)
{
if
(
nWords
==
1
)
return
(
pTruth
[
0
]
&
s_Truths6Neg
[
iVar
])
==
((
~
pTruth
[
0
]
&
s_Truths6
[
iVar
])
>>
(
1
<<
iVar
));
if
(
iVar
<=
5
)
{
int
w
,
shift
=
(
1
<<
iVar
);
for
(
w
=
0
;
w
<
nWords
;
w
++
)
if
(
(
pTruth
[
w
]
&
s_Truths6Neg
[
iVar
])
!=
((
~
pTruth
[
w
]
&
s_Truths6
[
iVar
])
>>
shift
)
)
return
0
;
return
1
;
}
else
// if ( iVar > 5 )
{
word
*
pLimit
=
pTruth
+
nWords
;
int
i
,
iStep
=
Abc_TtWordNum
(
iVar
);
for
(
;
pTruth
<
pLimit
;
pTruth
+=
(
iStep
<<
1
)
)
for
(
i
=
0
;
i
<
iStep
;
i
++
)
if
(
pTruth
[
i
]
!=
~
pTruth
[
i
+
iStep
]
)
return
0
;
return
1
;
}
}
int
Dua_DsdOneVar
(
Dua_Dsd_t
*
pRes
)
{
int
v
,
fCompl
,
fChange
=
1
;
fCompl
=
Dua_DsdTryConst
(
pRes
->
pTruth
,
pRes
->
nWords
);
while
(
fChange
&&
pRes
->
nVars
>
2
)
{
fChange
=
0
;
for
(
v
=
0
;
v
<
pRes
->
nVars
;
v
++
)
{
fCompl
^=
Dua_DsdTryVar
(
pRes
->
pTruth
,
pRes
->
nWords
,
v
);
if
(
Dua_DsdCheckCof0Const0
(
pRes
->
pTruth
,
pRes
->
nWords
,
v
)
)
{
fChange
=
1
;
// record AND(v, F)
}
else
if
(
Dua_DsdCheckCofsEqualNot
(
pRes
->
pTruth
,
pRes
->
nWords
,
v
)
)
{
fChange
=
1
;
// record XOR(v, F)
}
}
}
return
fCompl
;
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int
Dua_DsdTrySwap
(
word
*
pTruth
,
int
nWords
,
int
iVar
)
{
static
word
s_PMasks
[
5
][
3
]
=
{
{
ABC_CONST
(
0x9999999999999999
),
ABC_CONST
(
0x2222222222222222
),
ABC_CONST
(
0x4444444444444444
)
},
{
ABC_CONST
(
0xC3C3C3C3C3C3C3C3
),
ABC_CONST
(
0x0C0C0C0C0C0C0C0C
),
ABC_CONST
(
0x3030303030303030
)
},
{
ABC_CONST
(
0xF00FF00FF00FF00F
),
ABC_CONST
(
0x00F000F000F000F0
),
ABC_CONST
(
0x0F000F000F000F00
)
},
{
ABC_CONST
(
0xFF0000FFFF0000FF
),
ABC_CONST
(
0x0000FF000000FF00
),
ABC_CONST
(
0x00FF000000FF0000
)
},
{
ABC_CONST
(
0xFFFF00000000FFFF
),
ABC_CONST
(
0x00000000FFFF0000
),
ABC_CONST
(
0x0000FFFF00000000
)
}
};
if
(
iVar
<
5
)
{
int
Shift
=
(
1
<<
iVar
);
word
c01
,
c10
,
*
pLimit
=
pTruth
+
nWords
;
for
(
;
pTruth
<
pLimit
;
pTruth
++
)
{
c01
=
(
pTruth
[
0
]
&
s_PMasks
[
iVar
][
1
]);
c10
=
(
pTruth
[
0
]
&
s_PMasks
[
iVar
][
2
])
>>
Shift
;
if
(
c01
==
c10
)
continue
;
if
(
c01
<
c10
)
return
0
;
pTruth
[
0
]
=
(
pTruth
[
0
]
&
s_PMasks
[
iVar
][
0
])
|
((
pTruth
[
0
]
&
s_PMasks
[
iVar
][
1
])
<<
Shift
)
|
((
pTruth
[
0
]
&
s_PMasks
[
iVar
][
2
])
>>
Shift
);
return
1
;
}
}
else
if
(
iVar
==
5
)
{
unsigned
*
pTruthU
=
(
unsigned
*
)
pTruth
;
unsigned
*
pLimitU
=
(
unsigned
*
)(
pTruth
+
nWords
);
for
(
;
pTruthU
<
pLimitU
;
pTruthU
+=
4
)
{
c01
=
pTruthU
[
1
];
c10
=
pTruthU
[
2
];
if
(
c01
==
c10
)
continue
;
if
(
c01
<
c10
)
return
0
;
for
(
;
pTruthU
<
pLimitU
;
pTruthU
+=
4
)
ABC_SWAP
(
unsigned
,
pTruthU
[
1
],
pTruthU
[
2
]
);
return
1
;
}
}
else
// if ( iVar > 5 )
{
word
*
pLimit
=
pTruth
+
nWords
;
int
i
,
iStep
=
Abc_TtWordNum
(
iVar
);
for
(
;
pTruth
<
pLimit
;
pTruth
+=
4
*
iStep
)
for
(
i
=
0
;
i
<
iStep
;
i
++
)
{
c01
=
pTruth
[
i
+
iStep
];
c10
=
pTruth
[
i
+
2
*
iStep
];
if
(
c01
==
c10
)
continue
;
if
(
c01
<
c10
)
return
0
;
for
(
;
pTruth
<
pLimit
;
pTruth
+=
4
*
iStep
)
for
(
;
i
<
iStep
;
i
++
)
ABC_SWAP
(
word
,
pTruth
[
1
],
pTruth
[
2
]
);
return
1
;
}
}
return
2
;
}
int
Dua_DsdCheckDecomp
(
word
*
pTruth
,
int
nWords
,
int
iVar
)
{
static
word
s_PMasks
[
5
][
4
]
=
{
{
ABC_CONST
(
0x1111111111111111
),
ABC_CONST
(
0x2222222222222222
),
ABC_CONST
(
0x4444444444444444
),
ABC_CONST
(
0x8888888888888888
)
},
{
ABC_CONST
(
0x0303030303030303
),
ABC_CONST
(
0x0C0C0C0C0C0C0C0C
),
ABC_CONST
(
0x3030303030303030
),
ABC_CONST
(
0xC0C0C0C0C0C0C0C0
)
},
{
ABC_CONST
(
0x000F000F000F000F
),
ABC_CONST
(
0x00F000F000F000F0
),
ABC_CONST
(
0x0F000F000F000F00
),
ABC_CONST
(
0xF000F000F000F000
)
},
{
ABC_CONST
(
0x000000FF000000FF
),
ABC_CONST
(
0x0000FF000000FF00
),
ABC_CONST
(
0x00FF000000FF0000
),
ABC_CONST
(
0xFF000000FF000000
)
},
{
ABC_CONST
(
0x000000000000FFFF
),
ABC_CONST
(
0x00000000FFFF0000
),
ABC_CONST
(
0x0000FFFF00000000
),
ABC_CONST
(
0xFFFF000000000000
)
}
};
int
fC0eC1
=
1
,
fC0eC3
=
1
;
if
(
iVar
<
5
)
{
int
Shift
=
(
1
<<
iVar
);
word
c01
,
c10
,
*
pLimit
=
pTruth
+
nWords
;
for
(
;
pTruth
<
pLimit
;
pTruth
++
)
{
if
(
fC0eC1
&&
(
pTruth
[
0
]
&
s_PMasks
[
iVar
][
0
])
!=
((
pTruth
[
0
]
&
s_PMasks
[
iVar
][
1
])
>>
Shift
)
)
fC0eC1
=
0
;
if
(
fC0eC3
&&
(
pTruth
[
0
]
&
s_PMasks
[
iVar
][
0
])
!=
((
pTruth
[
0
]
&
s_PMasks
[
iVar
][
3
])
>>
(
3
*
Shift
))
)
fC0eC3
=
0
;
if
(
!
fC0eC1
&&
!
fC0eC3
)
return
0
;
}
}
if
(
iVar
==
5
)
{
unsigned
*
pTruthU
=
(
unsigned
*
)
pTruth
;
unsigned
*
pLimitU
=
(
unsigned
*
)(
pTruth
+
nWords
);
for
(
;
pTruthU
<
pLimitU
;
pTruthU
+=
4
)
{
if
(
fC0eC1
&&
pTruthU
[
0
]
!=
pTruthU
[
1
]
)
fC0eC1
=
0
;
if
(
fC0eC3
&&
pTruthU
[
0
]
!=
pTruthU
[
3
]
)
fC0eC3
=
0
;
if
(
!
fC0eC1
&&
!
fC0eC3
)
return
0
;
}
}
else
// if ( iVar > 5 )
{
word
*
pLimit
=
pTruth
+
nWords
;
int
i
,
iStep
=
Abc_TtWordNum
(
iVar
);
for
(
;
pTruth
<
pLimit
;
pTruth
+=
4
*
iStep
)
for
(
i
=
0
;
i
<
iStep
;
i
++
)
{
if
(
fC0eC1
&&
pTruth
[
0
]
!=
pTruth
[
1
]
)
fC0eC1
=
0
;
if
(
fC0eC3
&&
pTruth
[
0
]
!=
pTruth
[
3
]
)
fC0eC3
=
0
;
if
(
!
fC0eC1
&&
!
fC0eC3
)
return
0
;
}
}
assert
(
fC0eC1
!=
fC0eC3
);
return
fC0eC1
?
1
:
2
;
}
// returns 1 if decomposition detected
int
Dua_DsdTwoVars
(
Dua_Dsd_t
*
pRes
)
{
int
v
,
RetValue
,
fChange
=
1
;
while
(
fChange
&&
pRes
->
nVars
>
2
)
{
fChange
=
0
;
for
(
v
=
0
;
v
<
pRes
->
nVars
-
1
;
v
++
)
{
RetValue
=
Dua_DsdTrySwap
(
pRes
->
pTruth
,
pRes
->
nWords
,
v
);
if
(
RetValue
==
1
)
fChange
=
1
;
if
(
RetValue
!=
2
)
continue
;
// vars are symmetric, check decomp
RetValue
=
Dua_DsdCheckDecomp
(
pRes
->
pTruth
,
pRes
->
nWords
,
v
);
if
(
RetValue
==
0
)
continue
;
if
(
RetValue
==
1
)
{
fChange
=
1
;
// record AND(a, b)
}
else
{
fChange
=
1
;
// record XOR(a, b)
}
}
}
}
/**Function*************************************************************
Synopsis [Check DSD for bound-set [iVar; jVar).]
Description [Return D-func if decomposable.]
SideEffects []
SeeAlso []
***********************************************************************/
word
Dua_DsdRangeVars
(
word
*
pTruth
,
int
nVars
,
int
iVar
,
int
jVar
,
int
fPerform
)
{
int
Part
,
nParts
=
1
<<
(
nVars
-
jVar
);
int
Mint
,
nMints
=
1
<<
(
jVar
-
iVar
);
word
MaskOne
,
MaskAll
=
0
;
assert
(
jVar
-
iVar
>
2
);
assert
(
jVar
-
iVar
<
7
);
if
(
iVar
<
6
)
{
int
Shift
=
6
-
iVar
,
MaskF
=
(
1
<<
Shift
)
-
1
,
iMint
=
0
;
word
MaskFF
=
(((
word
)
1
)
<<
(
1
<<
iVar
))
-
1
;
word
Cof0
,
Cof1
,
Value
;
for
(
Part
=
0
;
Part
<
nParts
;
Part
++
)
{
MaskOne
=
0
;
Cof0
=
Cof1
=
~
(
word
)
0
;
for
(
Mint
=
0
;
Mint
<
nMints
;
Mint
++
,
iMint
++
)
{
Value
=
(
pTruth
[
iMint
>>
Shift
]
>>
((
iMint
&
MaskF
)
<<
iVar
))
&
MaskFF
;
if
(
!~
Cof0
||
Cof0
==
Value
)
Cof0
=
Value
;
else
if
(
!~
Cof1
||
Cof1
==
Value
)
{
Cof1
=
Value
;
MaskOne
|=
((
word
)
1
)
<<
Mint
;
}
else
return
0
;
}
if
(
Part
==
0
)
MaskAll
=
MaskOne
;
else
if
(
MaskAll
!=
MaskOne
)
return
0
;
if
(
fPerform
)
{
assert
(
~
Cof0
&&
~
Cof1
);
Mint
=
2
*
Part
;
Value
=
(
pTruth
[
Mint
>>
Shift
]
>>
((
Mint
&
MaskF
)
<<
nVarsF
))
&
MaskFF
;
pTruth
[
Mint
>>
Shift
]
^=
(
Value
^
Cof0
)
<<
((
Mint
&
MaskF
)
<<
nVarsF
)
Mint
=
2
*
Part
+
1
;
Value
=
(
pTruth
[
Mint
>>
Shift
]
>>
((
Mint
&
MaskF
)
<<
nVarsF
))
&
MaskFF
;
pTruth
[
Mint
>>
Shift
]
^=
(
Value
^
Cof1
)
<<
((
Mint
&
MaskF
)
<<
nVarsF
)
}
}
// stretch
if
(
nVars
-
(
jVar
-
iVar
)
+
1
<
6
)
pTruth
[
0
]
=
Abc_Tt6Stretch
(
pTruth
[
0
],
nVars
-
(
jVar
-
iVar
)
+
1
);
}
else
{
int
nWordsF
=
Abc_TtWordNum
(
iVar
);
int
iWord
=
0
,
nBytes
=
sizeof
(
word
)
*
nWordsF
;
word
*
pCof0
,
*
pCof1
;
for
(
Part
=
0
;
Part
<
nParts
;
Part
++
)
{
MaskOne
=
0
;
pCof0
=
pCof1
=
NULL
;
for
(
Mint
=
0
;
Mint
<
nMints
;
Mint
++
,
iWord
+=
nWordsF
)
{
if
(
!
pCof0
||
!
memcmp
(
pCof0
,
pTruth
+
iWord
,
nBytes
)
)
pCof0
=
pTruth
+
iWord
;
else
if
(
!
pCof1
||
!
memcmp
(
pCof1
,
pTruth
+
iWord
,
nBytes
)
)
{
pCof1
=
pTruth
+
iWord
;
MaskOne
|=
((
word
)
1
)
<<
Mint
;
}
else
return
0
;
}
if
(
Part
==
0
)
MaskAll
=
MaskOne
;
else
if
(
MaskAll
!=
MaskOne
)
return
0
;
if
(
fPerform
)
{
assert
(
pCof0
&&
pCof1
);
memcpy
(
pTruth
+
(
2
*
Part
+
0
)
*
nWordsF
,
pCof0
,
nBytes
);
memcpy
(
pTruth
+
(
2
*
Part
+
1
)
*
nWordsF
,
pCof1
,
nBytes
);
}
}
}
return
MaskAll
;
}
/**Function*************************************************************
Synopsis [Check DSD for bound-set [0; iVar).]
Description [Return D-func if decomposable.]
SideEffects []
SeeAlso []
***********************************************************************/
int
Dua_DsdRangeVars0
(
word
*
pTruth
,
int
nVars
,
int
iVar
,
int
fPerform
)
{
int
i
,
nParts
=
1
<<
(
nVars
-
iVar
);
assert
(
iVar
>
2
&&
iVar
<
nVars
);
if
(
iVar
==
3
)
{
unsigned
char
*
pTruthP
=
(
unsigned
char
*
)
pTruth
,
Dfunc
=
pTruthP
[
0
];
for
(
i
=
1
;
i
<
nParts
;
i
++
)
if
(
pTruthP
[
i
]
!=
Dfunc
&&
pTruthP
[
i
]
!=
~
Dfunc
)
return
0
;
}
else
if
(
iVar
==
4
)
{
unsigned
short
*
pTruthP
=
(
unsigned
short
*
)
pTruth
,
Dfunc
=
pTruthP
[
0
];
for
(
i
=
1
;
i
<
nParts
;
i
++
)
if
(
pTruthP
[
i
]
!=
Dfunc
&&
pTruthP
[
i
]
!=
~
Dfunc
)
return
0
;
}
else
if
(
iVar
==
5
)
{
unsigned
int
*
pTruthP
=
(
unsigned
int
*
)
pTruth
,
Dfunc
=
pTruthP
[
0
];
for
(
i
=
1
;
i
<
nParts
;
i
++
)
if
(
pTruthP
[
i
]
!=
Dfunc
&&
pTruthP
[
i
]
!=
~
Dfunc
)
return
0
;
}
else
{
int
nStep
=
1
<<
(
6
-
iVar
);
assert
(
iVar
>=
6
);
for
(
i
=
1
;
i
<
nParts
;
i
++
)
if
(
!
Abc_TtEqual
(
pTruth
,
pTruth
+
i
*
nStep
,
nStep
)
&&
!
Abc_TtEqualNot
(
pTruth
,
pTruth
+
i
*
nStep
,
nStep
)
)
return
0
;
}
return
1
;
}
void
Dua_DsdRangeVars0Derive
(
word
*
pTruth
,
int
nVars
,
int
iVar
)
{
int
i
,
nParts
=
1
<<
(
nVars
-
iVar
);
assert
(
iVar
>
2
&&
iVar
<
nVars
);
if
(
iVar
==
3
)
{
unsigned
char
*
pTruthP
=
(
unsigned
char
*
)
pTruth
,
Dfunc
=
pTruthP
[
0
];
for
(
i
=
0
;
i
<
nParts
;
i
++
)
if
(
Abc_TtGetBit
(
pTruth
,
i
)
^
(
pTruthP
[
i
]
!=
Dfunc
)
)
Abc_TtXorBit
(
pTruth
,
i
);
}
else
if
(
iVar
==
4
)
{
unsigned
short
*
pTruthP
=
(
unsigned
short
*
)
pTruth
,
Dfunc
=
pTruthP
[
0
];
for
(
i
=
0
;
i
<
nParts
;
i
++
)
if
(
Abc_TtGetBit
(
pTruth
,
i
)
^
(
pTruthP
[
i
]
!=
Dfunc
)
)
Abc_TtXorBit
(
pTruth
,
i
);
}
else
if
(
iVar
==
5
)
{
unsigned
int
*
pTruthP
=
(
unsigned
int
*
)
pTruth
,
Dfunc
=
pTruthP
[
0
];
for
(
i
=
0
;
i
<
nParts
;
i
++
)
if
(
Abc_TtGetBit
(
pTruth
,
i
)
^
(
pTruthP
[
i
]
!=
Dfunc
)
)
Abc_TtXorBit
(
pTruth
,
i
);
}
else
{
word
Dfunc
=
pTruth
[
0
];
assert
(
iVar
==
6
);
for
(
i
=
0
;
i
<
nParts
;
i
++
)
if
(
Abc_TtGetBit
(
pTruth
,
i
)
^
(
pTruth
[
i
]
!=
Dfunc
)
)
Abc_TtXorBit
(
pTruth
,
i
);
}
// stretch
if
(
nVars
-
iVar
+
1
<
6
)
pTruth
[
0
]
=
Abc_Tt6Stretch
(
pTruth
[
0
],
nVars
-
iVar
+
1
<
6
);
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
void
Dua_DsdTest
(
word
*
pTruth
,
int
nVar
)
{
Dua_Dsd_t
Res
,
*
pRes
=
&
Res
;
Dua_DsdInit
(
pRes
,
pTruth
,
nVars
);
}
////////////////////////////////////////////////////////////////////////
/// END OF FILE ///
////////////////////////////////////////////////////////////////////////
ABC_NAMESPACE_IMPL_END
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