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lvzhengyang
abc
Commits
c65e08f9
Unverified
Commit
c65e08f9
authored
Sep 19, 2022
by
alanminko
Committed by
GitHub
Sep 19, 2022
Browse files
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Merge pull request #178 from MyskYko/ttopt
Import ttopt
parents
b69f4396
96b9ef2c
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src/aig/gia/giaTtopt.cpp
+1207
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src/aig/gia/module.make
+1
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src/base/abci/abc.c
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src/aig/gia/giaTtopt.cpp
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c65e08f9
// Author : Yukio Miyasaka
#include <iostream>
#include <fstream>
#include <string>
#include <vector>
#include <list>
#include <algorithm>
#include <numeric>
#include <random>
#include <cassert>
#include <map>
#include <bitset>
#include <unordered_map>
#include "gia.h"
ABC_NAMESPACE_IMPL_START
namespace
Ttopt
{
struct
PairHasher
{
std
::
size_t
operator
()(
const
std
::
pair
<
int
,
int
>
&
k
)
const
{
std
::
hash
<
int
>
hasher
;
std
::
size_t
seed
=
hasher
(
k
.
first
)
+
0x9e3779b9
;
seed
=
hasher
(
k
.
second
)
+
0x9e3779b9
+
(
seed
<<
6
)
+
(
seed
>>
2
);
return
seed
;
}
};
class
TruthTable
{
public
:
const
int
ww
=
64
;
// word width
const
int
lww
=
6
;
// log word width
typedef
std
::
bitset
<
64
>
bsw
;
int
nInputs
;
int
nSize
;
int
nTotalSize
;
int
nOutputs
;
std
::
vector
<
word
>
t
;
std
::
vector
<
std
::
vector
<
int
>
>
vvIndices
;
std
::
vector
<
std
::
vector
<
int
>
>
vvRedundantIndices
;
std
::
vector
<
int
>
vLevels
;
std
::
vector
<
std
::
vector
<
word
>
>
savedt
;
std
::
vector
<
std
::
vector
<
std
::
vector
<
int
>
>
>
vvIndicesSaved
;
std
::
vector
<
std
::
vector
<
std
::
vector
<
int
>
>
>
vvRedundantIndicesSaved
;
std
::
vector
<
std
::
vector
<
int
>
>
vLevelsSaved
;
std
::
mt19937
rng
;
static
const
word
ones
[];
static
const
word
swapmask
[];
TruthTable
(
int
nInputs
,
int
nOutputs
)
:
nInputs
(
nInputs
),
nOutputs
(
nOutputs
)
{
if
(
nInputs
>=
lww
)
{
nSize
=
1
<<
(
nInputs
-
lww
);
nTotalSize
=
nSize
*
nOutputs
;
t
.
resize
(
nTotalSize
);
}
else
{
nSize
=
0
;
nTotalSize
=
((
1
<<
nInputs
)
*
nOutputs
+
ww
-
1
)
/
ww
;
t
.
resize
(
nTotalSize
);
}
vLevels
.
resize
(
nInputs
);
std
::
iota
(
vLevels
.
begin
(),
vLevels
.
end
(),
0
);
}
std
::
string
BinaryToString
(
int
bin
,
int
size
)
{
std
::
string
str
;
for
(
int
i
=
0
;
i
<
size
;
i
++
)
{
str
+=
(
bin
&
1
)
+
'0'
;
bin
=
bin
>>
1
;
}
return
str
;
}
void
GeneratePla
(
std
::
string
filename
)
{
std
::
ofstream
f
(
filename
);
f
<<
".i "
<<
nInputs
<<
std
::
endl
;
f
<<
".o "
<<
nOutputs
<<
std
::
endl
;
if
(
nSize
)
{
for
(
int
index
=
0
;
index
<
nSize
;
index
++
)
{
for
(
int
pos
=
0
;
pos
<
ww
;
pos
++
)
{
int
pat
=
(
index
<<
lww
)
+
pos
;
f
<<
BinaryToString
(
pat
,
nInputs
)
<<
" "
;
for
(
int
i
=
0
;
i
<
nOutputs
;
i
++
)
{
f
<<
((
t
[
nSize
*
i
+
index
]
>>
pos
)
&
1
);
}
f
<<
std
::
endl
;
}
}
}
else
{
for
(
int
pos
=
0
;
pos
<
(
1
<<
nInputs
);
pos
++
)
{
f
<<
BinaryToString
(
pos
,
nInputs
)
<<
" "
;
for
(
int
i
=
0
;
i
<
nOutputs
;
i
++
)
{
int
padding
=
i
*
(
1
<<
nInputs
);
f
<<
((
t
[
padding
/
ww
]
>>
(
pos
+
padding
%
ww
))
&
1
);
}
f
<<
std
::
endl
;
}
}
}
virtual
void
Save
(
uint
i
)
{
if
(
savedt
.
size
()
<
i
+
1
)
{
savedt
.
resize
(
i
+
1
);
vLevelsSaved
.
resize
(
i
+
1
);
}
savedt
[
i
]
=
t
;
vLevelsSaved
[
i
]
=
vLevels
;
}
virtual
void
Load
(
uint
i
)
{
assert
(
i
<
savedt
.
size
());
t
=
savedt
[
i
];
vLevels
=
vLevelsSaved
[
i
];
}
virtual
void
SaveIndices
(
uint
i
)
{
if
(
vvIndicesSaved
.
size
()
<
i
+
1
)
{
vvIndicesSaved
.
resize
(
i
+
1
);
vvRedundantIndicesSaved
.
resize
(
i
+
1
);
}
vvIndicesSaved
[
i
]
=
vvIndices
;
vvRedundantIndicesSaved
[
i
]
=
vvRedundantIndices
;
}
virtual
void
LoadIndices
(
uint
i
)
{
vvIndices
=
vvIndicesSaved
[
i
];
vvRedundantIndices
=
vvRedundantIndicesSaved
[
i
];
}
word
GetValue
(
int
index_lev
,
int
lev
)
{
assert
(
index_lev
>=
0
);
assert
(
nInputs
-
lev
<=
lww
);
int
logwidth
=
nInputs
-
lev
;
int
index
=
index_lev
>>
(
lww
-
logwidth
);
int
pos
=
(
index_lev
%
(
1
<<
(
lww
-
logwidth
)))
<<
logwidth
;
return
(
t
[
index
]
>>
pos
)
&
ones
[
logwidth
];
}
int
IsEq
(
int
index1
,
int
index2
,
int
lev
,
bool
fCompl
=
false
)
{
assert
(
index1
>=
0
);
assert
(
index2
>=
0
);
int
logwidth
=
nInputs
-
lev
;
bool
fEq
=
true
;
if
(
logwidth
>
lww
)
{
int
nScopeSize
=
1
<<
(
logwidth
-
lww
);
for
(
int
i
=
0
;
i
<
nScopeSize
&&
(
fEq
||
fCompl
);
i
++
)
{
fEq
&=
t
[
nScopeSize
*
index1
+
i
]
==
t
[
nScopeSize
*
index2
+
i
];
fCompl
&=
t
[
nScopeSize
*
index1
+
i
]
==
~
t
[
nScopeSize
*
index2
+
i
];
}
}
else
{
word
value
=
GetValue
(
index1
,
lev
)
^
GetValue
(
index2
,
lev
);
fEq
&=
!
value
;
fCompl
&=
!
(
value
^
ones
[
logwidth
]);
}
return
2
*
fCompl
+
fEq
;
}
bool
Imply
(
int
index1
,
int
index2
,
int
lev
)
{
assert
(
index1
>=
0
);
assert
(
index2
>=
0
);
int
logwidth
=
nInputs
-
lev
;
if
(
logwidth
>
lww
)
{
int
nScopeSize
=
1
<<
(
logwidth
-
lww
);
for
(
int
i
=
0
;
i
<
nScopeSize
;
i
++
)
{
if
(
t
[
nScopeSize
*
index1
+
i
]
&
~
t
[
nScopeSize
*
index2
+
i
])
{
return
false
;
}
}
return
true
;
}
return
!
(
GetValue
(
index1
,
lev
)
&
(
GetValue
(
index2
,
lev
)
^
ones
[
logwidth
]));
}
int
BDDNodeCountLevel
(
int
lev
)
{
return
vvIndices
[
lev
].
size
()
-
vvRedundantIndices
[
lev
].
size
();
}
int
BDDNodeCount
()
{
int
count
=
1
;
// const node
for
(
int
i
=
0
;
i
<
nInputs
;
i
++
)
{
count
+=
BDDNodeCountLevel
(
i
);
}
return
count
;
}
int
BDDFind
(
int
index
,
int
lev
)
{
int
logwidth
=
nInputs
-
lev
;
if
(
logwidth
>
lww
)
{
int
nScopeSize
=
1
<<
(
logwidth
-
lww
);
bool
fZero
=
true
;
bool
fOne
=
true
;
for
(
int
i
=
0
;
i
<
nScopeSize
&&
(
fZero
||
fOne
);
i
++
)
{
word
value
=
t
[
nScopeSize
*
index
+
i
];
fZero
&=
!
value
;
fOne
&=
!
(
~
value
);
}
if
(
fZero
||
fOne
)
{
return
-
2
^
fOne
;
}
for
(
uint
j
=
0
;
j
<
vvIndices
[
lev
].
size
();
j
++
)
{
int
index2
=
vvIndices
[
lev
][
j
];
bool
fEq
=
true
;
bool
fCompl
=
true
;
for
(
int
i
=
0
;
i
<
nScopeSize
&&
(
fEq
||
fCompl
);
i
++
)
{
fEq
&=
t
[
nScopeSize
*
index
+
i
]
==
t
[
nScopeSize
*
index2
+
i
];
fCompl
&=
t
[
nScopeSize
*
index
+
i
]
==
~
t
[
nScopeSize
*
index2
+
i
];
}
if
(
fEq
||
fCompl
)
{
return
(
j
<<
1
)
^
fCompl
;
}
}
}
else
{
word
value
=
GetValue
(
index
,
lev
);
if
(
!
value
)
{
return
-
2
;
}
if
(
!
(
value
^
ones
[
logwidth
]))
{
return
-
1
;
}
for
(
uint
j
=
0
;
j
<
vvIndices
[
lev
].
size
();
j
++
)
{
int
index2
=
vvIndices
[
lev
][
j
];
word
value2
=
value
^
GetValue
(
index2
,
lev
);
if
(
!
(
value2
))
{
return
j
<<
1
;
}
if
(
!
(
value2
^
ones
[
logwidth
]))
{
return
(
j
<<
1
)
^
1
;
}
}
}
return
-
3
;
}
virtual
int
BDDBuildOne
(
int
index
,
int
lev
)
{
int
r
=
BDDFind
(
index
,
lev
);
if
(
r
>=
-
2
)
{
return
r
;
}
vvIndices
[
lev
].
push_back
(
index
);
return
(
vvIndices
[
lev
].
size
()
-
1
)
<<
1
;
}
virtual
void
BDDBuildStartup
()
{
vvIndices
.
clear
();
vvIndices
.
resize
(
nInputs
);
vvRedundantIndices
.
clear
();
vvRedundantIndices
.
resize
(
nInputs
);
for
(
int
i
=
0
;
i
<
nOutputs
;
i
++
)
{
BDDBuildOne
(
i
,
0
);
}
}
virtual
void
BDDBuildLevel
(
int
lev
)
{
for
(
int
index
:
vvIndices
[
lev
-
1
])
{
int
cof0
=
BDDBuildOne
(
index
<<
1
,
lev
);
int
cof1
=
BDDBuildOne
((
index
<<
1
)
^
1
,
lev
);
if
(
cof0
==
cof1
)
{
vvRedundantIndices
[
lev
-
1
].
push_back
(
index
);
}
}
}
virtual
int
BDDBuild
()
{
BDDBuildStartup
();
for
(
int
i
=
1
;
i
<
nInputs
;
i
++
)
{
BDDBuildLevel
(
i
);
}
return
BDDNodeCount
();
}
virtual
int
BDDRebuild
(
int
lev
)
{
vvIndices
[
lev
].
clear
();
vvIndices
[
lev
+
1
].
clear
();
for
(
int
i
=
lev
;
i
<
lev
+
2
;
i
++
)
{
if
(
!
i
)
{
for
(
int
j
=
0
;
j
<
nOutputs
;
j
++
)
{
BDDBuildOne
(
j
,
0
);
}
}
else
{
vvRedundantIndices
[
i
-
1
].
clear
();
BDDBuildLevel
(
i
);
}
}
if
(
lev
<
nInputs
-
2
)
{
vvRedundantIndices
[
lev
+
1
].
clear
();
for
(
int
index
:
vvIndices
[
lev
+
1
])
{
if
(
IsEq
(
index
<<
1
,
(
index
<<
1
)
^
1
,
lev
+
2
))
{
vvRedundantIndices
[
lev
+
1
].
push_back
(
index
);
}
}
}
return
BDDNodeCount
();
}
virtual
void
Swap
(
int
lev
)
{
assert
(
lev
<
nInputs
-
1
);
auto
it0
=
std
::
find
(
vLevels
.
begin
(),
vLevels
.
end
(),
lev
);
auto
it1
=
std
::
find
(
vLevels
.
begin
(),
vLevels
.
end
(),
lev
+
1
);
std
::
swap
(
*
it0
,
*
it1
);
if
(
nInputs
-
lev
-
1
>
lww
)
{
int
nScopeSize
=
1
<<
(
nInputs
-
lev
-
2
-
lww
);
for
(
int
i
=
nScopeSize
;
i
<
nTotalSize
;
i
+=
(
nScopeSize
<<
2
))
{
for
(
int
j
=
0
;
j
<
nScopeSize
;
j
++
)
{
std
::
swap
(
t
[
i
+
j
],
t
[
i
+
nScopeSize
+
j
]);
}
}
}
else
if
(
nInputs
-
lev
-
1
==
lww
)
{
for
(
int
i
=
0
;
i
<
nTotalSize
;
i
+=
2
)
{
t
[
i
+
1
]
^=
t
[
i
]
>>
(
ww
/
2
);
t
[
i
]
^=
t
[
i
+
1
]
<<
(
ww
/
2
);
t
[
i
+
1
]
^=
t
[
i
]
>>
(
ww
/
2
);
}
}
else
{
for
(
int
i
=
0
;
i
<
nTotalSize
;
i
++
)
{
int
d
=
nInputs
-
lev
-
2
;
int
shamt
=
1
<<
d
;
t
[
i
]
^=
(
t
[
i
]
>>
shamt
)
&
swapmask
[
d
];
t
[
i
]
^=
(
t
[
i
]
&
swapmask
[
d
])
<<
shamt
;
t
[
i
]
^=
(
t
[
i
]
>>
shamt
)
&
swapmask
[
d
];
}
}
}
void
SwapIndex
(
int
&
index
,
int
d
)
{
if
((
index
>>
d
)
%
4
==
1
)
{
index
+=
1
<<
d
;
}
else
if
((
index
>>
d
)
%
4
==
2
)
{
index
-=
1
<<
d
;
}
}
virtual
int
BDDSwap
(
int
lev
)
{
Swap
(
lev
);
for
(
int
i
=
lev
+
2
;
i
<
nInputs
;
i
++
)
{
for
(
uint
j
=
0
;
j
<
vvIndices
[
i
].
size
();
j
++
)
{
SwapIndex
(
vvIndices
[
i
][
j
],
i
-
(
lev
+
2
));
}
}
// swapping vvRedundantIndices is unnecessary for node counting
return
BDDRebuild
(
lev
);
}
int
SiftReo
()
{
int
best
=
BDDBuild
();
Save
(
0
);
SaveIndices
(
0
);
std
::
vector
<
int
>
vars
(
nInputs
);
std
::
iota
(
vars
.
begin
(),
vars
.
end
(),
0
);
std
::
sort
(
vars
.
begin
(),
vars
.
end
(),
[
&
](
int
i1
,
int
i2
)
{
return
BDDNodeCountLevel
(
vLevels
[
i1
])
>
BDDNodeCountLevel
(
vLevels
[
i2
]);});
bool
turn
=
true
;
for
(
int
var
:
vars
)
{
bool
updated
=
false
;
int
lev
=
vLevels
[
var
];
for
(
int
i
=
lev
;
i
<
nInputs
-
1
;
i
++
)
{
int
count
=
BDDSwap
(
i
);
if
(
best
>
count
)
{
best
=
count
;
updated
=
true
;
Save
(
turn
);
SaveIndices
(
turn
);
}
}
if
(
lev
)
{
Load
(
!
turn
);
LoadIndices
(
!
turn
);
for
(
int
i
=
lev
-
1
;
i
>=
0
;
i
--
)
{
int
count
=
BDDSwap
(
i
);
if
(
best
>
count
)
{
best
=
count
;
updated
=
true
;
Save
(
turn
);
SaveIndices
(
turn
);
}
}
}
turn
^=
updated
;
Load
(
!
turn
);
LoadIndices
(
!
turn
);
}
return
best
;
}
void
Reo
(
std
::
vector
<
int
>
vLevelsNew
)
{
for
(
int
i
=
0
;
i
<
nInputs
;
i
++
)
{
int
var
=
std
::
find
(
vLevelsNew
.
begin
(),
vLevelsNew
.
end
(),
i
)
-
vLevelsNew
.
begin
();
int
lev
=
vLevels
[
var
];
if
(
lev
<
i
)
{
for
(
int
j
=
lev
;
j
<
i
;
j
++
)
{
Swap
(
j
);
}
}
else
if
(
lev
>
i
)
{
for
(
int
j
=
lev
-
1
;
j
>=
i
;
j
--
)
{
Swap
(
j
);
}
}
}
assert
(
vLevels
==
vLevelsNew
);
}
int
RandomSiftReo
(
int
nRound
)
{
int
best
=
SiftReo
();
Save
(
2
);
for
(
int
i
=
0
;
i
<
nRound
;
i
++
)
{
std
::
vector
<
int
>
vLevelsNew
(
nInputs
);
std
::
iota
(
vLevelsNew
.
begin
(),
vLevelsNew
.
end
(),
0
);
std
::
shuffle
(
vLevelsNew
.
begin
(),
vLevelsNew
.
end
(),
rng
);
Reo
(
vLevelsNew
);
int
r
=
SiftReo
();
if
(
best
>
r
)
{
best
=
r
;
Save
(
2
);
}
}
Load
(
2
);
return
best
;
}
int
BDDGenerateAigRec
(
Gia_Man_t
*
pNew
,
std
::
vector
<
int
>
const
&
vInputs
,
std
::
vector
<
std
::
vector
<
int
>
>
&
vvNodes
,
int
index
,
int
lev
)
{
int
r
=
BDDFind
(
index
,
lev
);
if
(
r
>=
0
)
{
return
vvNodes
[
lev
][
r
>>
1
]
^
(
r
&
1
);
}
if
(
r
>=
-
2
)
{
return
r
+
2
;
}
int
cof0
=
BDDGenerateAigRec
(
pNew
,
vInputs
,
vvNodes
,
index
<<
1
,
lev
+
1
);
int
cof1
=
BDDGenerateAigRec
(
pNew
,
vInputs
,
vvNodes
,
(
index
<<
1
)
^
1
,
lev
+
1
);
if
(
cof0
==
cof1
)
{
return
cof0
;
}
int
node
;
if
(
Imply
(
index
<<
1
,
(
index
<<
1
)
^
1
,
lev
+
1
))
{
node
=
Gia_ManHashOr
(
pNew
,
Gia_ManHashAnd
(
pNew
,
vInputs
[
lev
],
cof1
),
cof0
);
}
else
if
(
Imply
((
index
<<
1
)
^
1
,
index
<<
1
,
lev
+
1
))
{
node
=
Gia_ManHashOr
(
pNew
,
Gia_ManHashAnd
(
pNew
,
vInputs
[
lev
]
^
1
,
cof0
),
cof1
);
}
else
{
node
=
Gia_ManHashMux
(
pNew
,
vInputs
[
lev
],
cof1
,
cof0
);
}
vvIndices
[
lev
].
push_back
(
index
);
vvNodes
[
lev
].
push_back
(
node
);
return
node
;
}
virtual
void
BDDGenerateAig
(
Gia_Man_t
*
pNew
,
Vec_Int_t
*
vSupp
)
{
vvIndices
.
clear
();
vvIndices
.
resize
(
nInputs
);
std
::
vector
<
std
::
vector
<
int
>
>
vvNodes
(
nInputs
);
std
::
vector
<
int
>
vInputs
(
nInputs
);
for
(
int
i
=
0
;
i
<
nInputs
;
i
++
)
{
vInputs
[
vLevels
[
i
]]
=
Vec_IntEntry
(
vSupp
,
nInputs
-
i
-
1
)
<<
1
;
}
for
(
int
i
=
0
;
i
<
nOutputs
;
i
++
)
{
int
node
=
BDDGenerateAigRec
(
pNew
,
vInputs
,
vvNodes
,
i
,
0
);
Gia_ManAppendCo
(
pNew
,
node
);
}
}
};
const
word
TruthTable
::
ones
[
7
]
=
{
ABC_CONST
(
0x0000000000000001
),
ABC_CONST
(
0x0000000000000003
),
ABC_CONST
(
0x000000000000000f
),
ABC_CONST
(
0x00000000000000ff
),
ABC_CONST
(
0x000000000000ffff
),
ABC_CONST
(
0x00000000ffffffff
),
ABC_CONST
(
0xffffffffffffffff
)};
const
word
TruthTable
::
swapmask
[
5
]
=
{
ABC_CONST
(
0x2222222222222222
),
ABC_CONST
(
0x0c0c0c0c0c0c0c0c
),
ABC_CONST
(
0x00f000f000f000f0
),
ABC_CONST
(
0x0000ff000000ff00
),
ABC_CONST
(
0x00000000ffff0000
)};
class
TruthTableReo
:
public
TruthTable
{
public
:
bool
fBuilt
=
false
;
std
::
vector
<
std
::
vector
<
int
>
>
vvChildren
;
std
::
vector
<
std
::
vector
<
std
::
vector
<
int
>
>
>
vvChildrenSaved
;
TruthTableReo
(
int
nInputs
,
int
nOutputs
)
:
TruthTable
(
nInputs
,
nOutputs
)
{}
void
Save
(
uint
i
)
override
{
if
(
vLevelsSaved
.
size
()
<
i
+
1
)
{
vLevelsSaved
.
resize
(
i
+
1
);
}
vLevelsSaved
[
i
]
=
vLevels
;
}
void
Load
(
uint
i
)
override
{
assert
(
i
<
vLevelsSaved
.
size
());
vLevels
=
vLevelsSaved
[
i
];
}
void
SaveIndices
(
uint
i
)
override
{
TruthTable
::
SaveIndices
(
i
);
if
(
vvChildrenSaved
.
size
()
<
i
+
1
)
{
vvChildrenSaved
.
resize
(
i
+
1
);
}
vvChildrenSaved
[
i
]
=
vvChildren
;
}
void
LoadIndices
(
uint
i
)
override
{
TruthTable
::
LoadIndices
(
i
);
vvChildren
=
vvChildrenSaved
[
i
];
}
void
BDDBuildStartup
()
override
{
vvChildren
.
clear
();
vvChildren
.
resize
(
nInputs
);
TruthTable
::
BDDBuildStartup
();
}
void
BDDBuildLevel
(
int
lev
)
override
{
for
(
int
index
:
vvIndices
[
lev
-
1
])
{
int
cof0
=
BDDBuildOne
(
index
<<
1
,
lev
);
int
cof1
=
BDDBuildOne
((
index
<<
1
)
^
1
,
lev
);
vvChildren
[
lev
-
1
].
push_back
(
cof0
);
vvChildren
[
lev
-
1
].
push_back
(
cof1
);
if
(
cof0
==
cof1
)
{
vvRedundantIndices
[
lev
-
1
].
push_back
(
index
);
}
}
}
int
BDDBuild
()
override
{
if
(
fBuilt
)
{
return
BDDNodeCount
();
}
fBuilt
=
true
;
BDDBuildStartup
();
for
(
int
i
=
1
;
i
<
nInputs
+
1
;
i
++
)
{
BDDBuildLevel
(
i
);
}
return
BDDNodeCount
();
}
int
BDDRebuildOne
(
int
index
,
int
cof0
,
int
cof1
,
int
lev
,
std
::
unordered_map
<
std
::
pair
<
int
,
int
>
,
int
,
PairHasher
>
&
unique
,
std
::
vector
<
int
>
&
vChildrenLow
)
{
if
(
cof0
<
0
&&
cof0
==
cof1
)
{
return
cof0
;
}
bool
fCompl
=
cof0
&
1
;
if
(
fCompl
)
{
cof0
^=
1
;
cof1
^=
1
;
}
if
(
unique
.
count
({
cof0
,
cof1
}))
{
return
(
unique
[{
cof0
,
cof1
}]
<<
1
)
^
fCompl
;
}
vvIndices
[
lev
].
push_back
(
index
);
unique
[{
cof0
,
cof1
}]
=
vvIndices
[
lev
].
size
()
-
1
;
vChildrenLow
.
push_back
(
cof0
);
vChildrenLow
.
push_back
(
cof1
);
if
(
cof0
==
cof1
)
{
vvRedundantIndices
[
lev
].
push_back
(
index
);
}
return
((
vvIndices
[
lev
].
size
()
-
1
)
<<
1
)
^
fCompl
;
}
int
BDDRebuild
(
int
lev
)
override
{
vvRedundantIndices
[
lev
].
clear
();
vvRedundantIndices
[
lev
+
1
].
clear
();
std
::
vector
<
int
>
vChildrenHigh
;
std
::
vector
<
int
>
vChildrenLow
;
std
::
unordered_map
<
std
::
pair
<
int
,
int
>
,
int
,
PairHasher
>
unique
;
unique
.
reserve
(
2
*
vvIndices
[
lev
+
1
].
size
());
vvIndices
[
lev
+
1
].
clear
();
for
(
uint
i
=
0
;
i
<
vvIndices
[
lev
].
size
();
i
++
)
{
int
index
=
vvIndices
[
lev
][
i
];
int
cof0index
=
vvChildren
[
lev
][
i
+
i
]
>>
1
;
int
cof1index
=
vvChildren
[
lev
][
i
+
i
+
1
]
>>
1
;
bool
cof0c
=
vvChildren
[
lev
][
i
+
i
]
&
1
;
bool
cof1c
=
vvChildren
[
lev
][
i
+
i
+
1
]
&
1
;
int
cof00
,
cof01
,
cof10
,
cof11
;
if
(
cof0index
<
0
)
{
cof00
=
-
2
^
cof0c
;
cof01
=
-
2
^
cof0c
;
}
else
{
cof00
=
vvChildren
[
lev
+
1
][
cof0index
+
cof0index
]
^
cof0c
;
cof01
=
vvChildren
[
lev
+
1
][
cof0index
+
cof0index
+
1
]
^
cof0c
;
}
if
(
cof1index
<
0
)
{
cof10
=
-
2
^
cof1c
;
cof11
=
-
2
^
cof1c
;
}
else
{
cof10
=
vvChildren
[
lev
+
1
][
cof1index
+
cof1index
]
^
cof1c
;
cof11
=
vvChildren
[
lev
+
1
][
cof1index
+
cof1index
+
1
]
^
cof1c
;
}
int
newcof0
=
BDDRebuildOne
(
index
<<
1
,
cof00
,
cof10
,
lev
+
1
,
unique
,
vChildrenLow
);
int
newcof1
=
BDDRebuildOne
((
index
<<
1
)
^
1
,
cof01
,
cof11
,
lev
+
1
,
unique
,
vChildrenLow
);
vChildrenHigh
.
push_back
(
newcof0
);
vChildrenHigh
.
push_back
(
newcof1
);
if
(
newcof0
==
newcof1
)
{
vvRedundantIndices
[
lev
].
push_back
(
index
);
}
}
vvChildren
[
lev
]
=
vChildrenHigh
;
vvChildren
[
lev
+
1
]
=
vChildrenLow
;
return
BDDNodeCount
();
}
void
Swap
(
int
lev
)
override
{
assert
(
lev
<
nInputs
-
1
);
auto
it0
=
std
::
find
(
vLevels
.
begin
(),
vLevels
.
end
(),
lev
);
auto
it1
=
std
::
find
(
vLevels
.
begin
(),
vLevels
.
end
(),
lev
+
1
);
std
::
swap
(
*
it0
,
*
it1
);
BDDRebuild
(
lev
);
}
int
BDDSwap
(
int
lev
)
override
{
Swap
(
lev
);
return
BDDNodeCount
();
}
virtual
void
BDDGenerateAig
(
Gia_Man_t
*
pNew
,
Vec_Int_t
*
vSupp
)
override
{
abort
();
}
};
class
TruthTableRewrite
:
public
TruthTable
{
public
:
TruthTableRewrite
(
int
nInputs
,
int
nOutputs
)
:
TruthTable
(
nInputs
,
nOutputs
)
{}
void
SetValue
(
int
index_lev
,
int
lev
,
word
value
)
{
assert
(
index_lev
>=
0
);
assert
(
nInputs
-
lev
<=
lww
);
int
logwidth
=
nInputs
-
lev
;
int
index
=
index_lev
>>
(
lww
-
logwidth
);
int
pos
=
(
index_lev
%
(
1
<<
(
lww
-
logwidth
)))
<<
logwidth
;
t
[
index
]
&=
~
(
ones
[
logwidth
]
<<
pos
);
t
[
index
]
^=
value
<<
pos
;
}
void
CopyFunc
(
int
index1
,
int
index2
,
int
lev
,
bool
fCompl
)
{
assert
(
index1
>=
0
);
int
logwidth
=
nInputs
-
lev
;
if
(
logwidth
>
lww
)
{
int
nScopeSize
=
1
<<
(
logwidth
-
lww
);
if
(
!
fCompl
)
{
if
(
index2
<
0
)
{
for
(
int
i
=
0
;
i
<
nScopeSize
;
i
++
)
{
t
[
nScopeSize
*
index1
+
i
]
=
0
;
}
}
else
{
for
(
int
i
=
0
;
i
<
nScopeSize
;
i
++
)
{
t
[
nScopeSize
*
index1
+
i
]
=
t
[
nScopeSize
*
index2
+
i
];
}
}
}
else
{
if
(
index2
<
0
)
{
for
(
int
i
=
0
;
i
<
nScopeSize
;
i
++
)
{
t
[
nScopeSize
*
index1
+
i
]
=
ones
[
lww
];
}
}
else
{
for
(
int
i
=
0
;
i
<
nScopeSize
;
i
++
)
{
t
[
nScopeSize
*
index1
+
i
]
=
~
t
[
nScopeSize
*
index2
+
i
];
}
}
}
}
else
{
word
value
=
0
;
if
(
index2
>=
0
)
{
value
=
GetValue
(
index2
,
lev
);
}
if
(
fCompl
)
{
value
^=
ones
[
logwidth
];
}
SetValue
(
index1
,
lev
,
value
);
}
}
void
ShiftToMajority
(
int
index
,
int
lev
)
{
assert
(
index
>=
0
);
int
logwidth
=
nInputs
-
lev
;
int
count
=
0
;
if
(
logwidth
>
lww
)
{
int
nScopeSize
=
1
<<
(
logwidth
-
lww
);
for
(
int
i
=
0
;
i
<
nScopeSize
;
i
++
)
{
count
+=
bsw
(
t
[
nScopeSize
*
index
+
i
]).
count
();
}
}
else
{
count
=
bsw
(
GetValue
(
index
,
lev
)).
count
();
}
bool
majority
=
count
>
(
1
<<
(
logwidth
-
1
));
CopyFunc
(
index
,
-
1
,
lev
,
majority
);
}
};
class
TruthTableCare
:
public
TruthTableRewrite
{
public
:
std
::
vector
<
word
>
originalt
;
std
::
vector
<
word
>
caret
;
std
::
vector
<
word
>
care
;
std
::
vector
<
std
::
vector
<
std
::
pair
<
int
,
int
>
>
>
vvMergedIndices
;
std
::
vector
<
std
::
vector
<
word
>
>
savedcare
;
std
::
vector
<
std
::
vector
<
std
::
vector
<
std
::
pair
<
int
,
int
>
>
>
>
vvMergedIndicesSaved
;
TruthTableCare
(
int
nInputs
,
int
nOutputs
)
:
TruthTableRewrite
(
nInputs
,
nOutputs
)
{
if
(
nSize
)
{
care
.
resize
(
nSize
);
}
else
{
care
.
resize
(
1
);
}
}
void
Save
(
uint
i
)
override
{
TruthTable
::
Save
(
i
);
if
(
savedcare
.
size
()
<
i
+
1
)
{
savedcare
.
resize
(
i
+
1
);
}
savedcare
[
i
]
=
care
;
}
void
Load
(
uint
i
)
override
{
TruthTable
::
Load
(
i
);
care
=
savedcare
[
i
];
}
void
SaveIndices
(
uint
i
)
override
{
TruthTable
::
SaveIndices
(
i
);
if
(
vvMergedIndicesSaved
.
size
()
<
i
+
1
)
{
vvMergedIndicesSaved
.
resize
(
i
+
1
);
}
vvMergedIndicesSaved
[
i
]
=
vvMergedIndices
;
}
void
LoadIndices
(
uint
i
)
override
{
TruthTable
::
LoadIndices
(
i
);
vvMergedIndices
=
vvMergedIndicesSaved
[
i
];
}
void
Swap
(
int
lev
)
override
{
TruthTable
::
Swap
(
lev
);
if
(
nInputs
-
lev
-
1
>
lww
)
{
int
nScopeSize
=
1
<<
(
nInputs
-
lev
-
2
-
lww
);
for
(
int
i
=
nScopeSize
;
i
<
nSize
;
i
+=
(
nScopeSize
<<
2
))
{
for
(
int
j
=
0
;
j
<
nScopeSize
;
j
++
)
{
std
::
swap
(
care
[
i
+
j
],
care
[
i
+
nScopeSize
+
j
]);
}
}
}
else
if
(
nInputs
-
lev
-
1
==
lww
)
{
for
(
int
i
=
0
;
i
<
nSize
;
i
+=
2
)
{
care
[
i
+
1
]
^=
care
[
i
]
>>
(
ww
/
2
);
care
[
i
]
^=
care
[
i
+
1
]
<<
(
ww
/
2
);
care
[
i
+
1
]
^=
care
[
i
]
>>
(
ww
/
2
);
}
}
else
{
for
(
int
i
=
0
;
i
<
nSize
||
(
i
==
0
&&
!
nSize
);
i
++
)
{
int
d
=
nInputs
-
lev
-
2
;
int
shamt
=
1
<<
d
;
care
[
i
]
^=
(
care
[
i
]
>>
shamt
)
&
swapmask
[
d
];
care
[
i
]
^=
(
care
[
i
]
&
swapmask
[
d
])
<<
shamt
;
care
[
i
]
^=
(
care
[
i
]
>>
shamt
)
&
swapmask
[
d
];
}
}
}
void
RestoreCare
()
{
caret
.
clear
();
if
(
nSize
)
{
for
(
int
i
=
0
;
i
<
nOutputs
;
i
++
)
{
caret
.
insert
(
caret
.
end
(),
care
.
begin
(),
care
.
end
());
}
}
else
{
caret
.
resize
(
nTotalSize
);
for
(
int
i
=
0
;
i
<
nOutputs
;
i
++
)
{
int
padding
=
i
*
(
1
<<
nInputs
);
caret
[
padding
/
ww
]
|=
care
[
0
]
<<
(
padding
%
ww
);
}
}
}
word
GetCare
(
int
index_lev
,
int
lev
)
{
assert
(
index_lev
>=
0
);
assert
(
nInputs
-
lev
<=
lww
);
int
logwidth
=
nInputs
-
lev
;
int
index
=
index_lev
>>
(
lww
-
logwidth
);
int
pos
=
(
index_lev
%
(
1
<<
(
lww
-
logwidth
)))
<<
logwidth
;
return
(
caret
[
index
]
>>
pos
)
&
ones
[
logwidth
];
}
void
CopyFuncMasked
(
int
index1
,
int
index2
,
int
lev
,
bool
fCompl
)
{
assert
(
index1
>=
0
);
assert
(
index2
>=
0
);
int
logwidth
=
nInputs
-
lev
;
if
(
logwidth
>
lww
)
{
int
nScopeSize
=
1
<<
(
logwidth
-
lww
);
for
(
int
i
=
0
;
i
<
nScopeSize
;
i
++
)
{
word
value
=
t
[
nScopeSize
*
index2
+
i
];
if
(
fCompl
)
{
value
=
~
value
;
}
word
cvalue
=
caret
[
nScopeSize
*
index2
+
i
];
t
[
nScopeSize
*
index1
+
i
]
&=
~
cvalue
;
t
[
nScopeSize
*
index1
+
i
]
|=
cvalue
&
value
;
}
}
else
{
word
one
=
ones
[
logwidth
];
word
value1
=
GetValue
(
index1
,
lev
);
word
value2
=
GetValue
(
index2
,
lev
);
if
(
fCompl
)
{
value2
^=
one
;
}
word
cvalue
=
GetCare
(
index2
,
lev
);
value1
&=
cvalue
^
one
;
value1
|=
cvalue
&
value2
;
SetValue
(
index1
,
lev
,
value1
);
}
}
bool
IsDC
(
int
index
,
int
lev
)
{
if
(
nInputs
-
lev
>
lww
)
{
int
nScopeSize
=
1
<<
(
nInputs
-
lev
-
lww
);
for
(
int
i
=
0
;
i
<
nScopeSize
;
i
++
)
{
if
(
caret
[
nScopeSize
*
index
+
i
])
{
return
false
;
}
}
}
else
if
(
GetCare
(
index
,
lev
))
{
return
false
;
}
return
true
;
}
int
Include
(
int
index1
,
int
index2
,
int
lev
,
bool
fCompl
)
{
assert
(
index1
>=
0
);
assert
(
index2
>=
0
);
int
logwidth
=
nInputs
-
lev
;
bool
fEq
=
true
;
if
(
logwidth
>
lww
)
{
int
nScopeSize
=
1
<<
(
logwidth
-
lww
);
for
(
int
i
=
0
;
i
<
nScopeSize
&&
(
fEq
||
fCompl
);
i
++
)
{
word
cvalue
=
caret
[
nScopeSize
*
index2
+
i
];
if
(
~
caret
[
nScopeSize
*
index1
+
i
]
&
cvalue
)
{
return
0
;
}
word
value
=
t
[
nScopeSize
*
index1
+
i
]
^
t
[
nScopeSize
*
index2
+
i
];
fEq
&=
!
(
value
&
cvalue
);
fCompl
&=
!
(
~
value
&
cvalue
);
}
}
else
{
word
cvalue
=
GetCare
(
index2
,
lev
);
if
((
GetCare
(
index1
,
lev
)
^
ones
[
logwidth
])
&
cvalue
)
{
return
0
;
}
word
value
=
GetValue
(
index1
,
lev
)
^
GetValue
(
index2
,
lev
);
fEq
&=
!
(
value
&
cvalue
);
fCompl
&=
!
((
value
^
ones
[
logwidth
])
&
cvalue
);
}
return
2
*
fCompl
+
fEq
;
}
int
Intersect
(
int
index1
,
int
index2
,
int
lev
,
bool
fCompl
,
bool
fEq
=
true
)
{
assert
(
index1
>=
0
);
assert
(
index2
>=
0
);
int
logwidth
=
nInputs
-
lev
;
if
(
logwidth
>
lww
)
{
int
nScopeSize
=
1
<<
(
logwidth
-
lww
);
for
(
int
i
=
0
;
i
<
nScopeSize
&&
(
fEq
||
fCompl
);
i
++
)
{
word
value
=
t
[
nScopeSize
*
index1
+
i
]
^
t
[
nScopeSize
*
index2
+
i
];
word
cvalue
=
caret
[
nScopeSize
*
index1
+
i
]
&
caret
[
nScopeSize
*
index2
+
i
];
fEq
&=
!
(
value
&
cvalue
);
fCompl
&=
!
(
~
value
&
cvalue
);
}
}
else
{
word
value
=
GetValue
(
index1
,
lev
)
^
GetValue
(
index2
,
lev
);
word
cvalue
=
GetCare
(
index1
,
lev
)
&
GetCare
(
index2
,
lev
);
fEq
&=
!
(
value
&
cvalue
);
fCompl
&=
!
((
value
^
ones
[
logwidth
])
&
cvalue
);
}
return
2
*
fCompl
+
fEq
;
}
void
MergeCare
(
int
index1
,
int
index2
,
int
lev
)
{
assert
(
index1
>=
0
);
assert
(
index2
>=
0
);
int
logwidth
=
nInputs
-
lev
;
if
(
logwidth
>
lww
)
{
int
nScopeSize
=
1
<<
(
logwidth
-
lww
);
for
(
int
i
=
0
;
i
<
nScopeSize
;
i
++
)
{
caret
[
nScopeSize
*
index1
+
i
]
|=
caret
[
nScopeSize
*
index2
+
i
];
}
}
else
{
word
value
=
GetCare
(
index2
,
lev
);
int
index
=
index1
>>
(
lww
-
logwidth
);
int
pos
=
(
index1
%
(
1
<<
(
lww
-
logwidth
)))
<<
logwidth
;
caret
[
index
]
|=
value
<<
pos
;
}
}
void
Merge
(
int
index1
,
int
index2
,
int
lev
,
bool
fCompl
)
{
MergeCare
(
index1
,
index2
,
lev
);
vvMergedIndices
[
lev
].
push_back
({(
index1
<<
1
)
^
fCompl
,
index2
});
}
int
BDDBuildOne
(
int
index
,
int
lev
)
override
{
int
r
=
BDDFind
(
index
,
lev
);
if
(
r
>=
-
2
)
{
if
(
r
>=
0
)
{
Merge
(
vvIndices
[
lev
][
r
>>
1
],
index
,
lev
,
r
&
1
);
}
return
r
;
}
vvIndices
[
lev
].
push_back
(
index
);
return
(
vvIndices
[
lev
].
size
()
-
1
)
<<
1
;
}
void
CompleteMerge
()
{
for
(
int
i
=
nInputs
-
1
;
i
>=
0
;
i
--
)
{
for
(
auto
it
=
vvMergedIndices
[
i
].
rbegin
();
it
!=
vvMergedIndices
[
i
].
rend
();
it
++
)
{
CopyFunc
((
*
it
).
second
,
(
*
it
).
first
>>
1
,
i
,
(
*
it
).
first
&
1
);
}
}
}
void
BDDBuildStartup
()
override
{
RestoreCare
();
vvIndices
.
clear
();
vvIndices
.
resize
(
nInputs
);
vvRedundantIndices
.
clear
();
vvRedundantIndices
.
resize
(
nInputs
);
vvMergedIndices
.
clear
();
vvMergedIndices
.
resize
(
nInputs
);
for
(
int
i
=
0
;
i
<
nOutputs
;
i
++
)
{
if
(
!
IsDC
(
i
,
0
))
{
BDDBuildOne
(
i
,
0
);
}
}
}
virtual
void
BDDRebuildByMerge
(
int
lev
)
{
for
(
auto
&
p
:
vvMergedIndices
[
lev
])
{
MergeCare
(
p
.
first
>>
1
,
p
.
second
,
lev
);
}
}
int
BDDRebuild
(
int
lev
)
override
{
RestoreCare
();
for
(
int
i
=
lev
;
i
<
nInputs
;
i
++
)
{
vvIndices
[
i
].
clear
();
vvMergedIndices
[
i
].
clear
();
if
(
i
)
{
vvRedundantIndices
[
i
-
1
].
clear
();
}
}
for
(
int
i
=
0
;
i
<
lev
;
i
++
)
{
BDDRebuildByMerge
(
i
);
}
for
(
int
i
=
lev
;
i
<
nInputs
;
i
++
)
{
if
(
!
i
)
{
for
(
int
j
=
0
;
j
<
nOutputs
;
j
++
)
{
if
(
!
IsDC
(
j
,
0
))
{
BDDBuildOne
(
j
,
0
);
}
}
}
else
{
BDDBuildLevel
(
i
);
}
}
return
BDDNodeCount
();
}
int
BDDSwap
(
int
lev
)
override
{
Swap
(
lev
);
return
BDDRebuild
(
lev
);
}
void
OptimizationStartup
()
{
originalt
=
t
;
RestoreCare
();
vvIndices
.
clear
();
vvIndices
.
resize
(
nInputs
);
vvMergedIndices
.
clear
();
vvMergedIndices
.
resize
(
nInputs
);
for
(
int
i
=
0
;
i
<
nOutputs
;
i
++
)
{
if
(
!
IsDC
(
i
,
0
))
{
BDDBuildOne
(
i
,
0
);
}
else
{
ShiftToMajority
(
i
,
0
);
}
}
}
virtual
void
Optimize
()
{
OptimizationStartup
();
for
(
int
i
=
1
;
i
<
nInputs
;
i
++
)
{
for
(
int
index
:
vvIndices
[
i
-
1
])
{
BDDBuildOne
(
index
<<
1
,
i
);
BDDBuildOne
((
index
<<
1
)
^
1
,
i
);
}
}
CompleteMerge
();
}
};
class
TruthTableLevelTSM
:
public
TruthTableCare
{
public
:
TruthTableLevelTSM
(
int
nInputs
,
int
nOutputs
)
:
TruthTableCare
(
nInputs
,
nOutputs
)
{}
int
BDDFindTSM
(
int
index
,
int
lev
)
{
int
logwidth
=
nInputs
-
lev
;
if
(
logwidth
>
lww
)
{
int
nScopeSize
=
1
<<
(
logwidth
-
lww
);
bool
fZero
=
true
;
bool
fOne
=
true
;
for
(
int
i
=
0
;
i
<
nScopeSize
&&
(
fZero
||
fOne
);
i
++
)
{
word
value
=
t
[
nScopeSize
*
index
+
i
];
word
cvalue
=
caret
[
nScopeSize
*
index
+
i
];
fZero
&=
!
(
value
&
cvalue
);
fOne
&=
!
(
~
value
&
cvalue
);
}
if
(
fZero
||
fOne
)
{
return
-
2
^
fOne
;
}
for
(
int
index2
:
vvIndices
[
lev
])
{
bool
fEq
=
true
;
bool
fCompl
=
true
;
for
(
int
i
=
0
;
i
<
nScopeSize
&&
(
fEq
||
fCompl
);
i
++
)
{
word
value
=
t
[
nScopeSize
*
index
+
i
]
^
t
[
nScopeSize
*
index2
+
i
];
word
cvalue
=
caret
[
nScopeSize
*
index
+
i
]
&
caret
[
nScopeSize
*
index2
+
i
];
fEq
&=
!
(
value
&
cvalue
);
fCompl
&=
!
(
~
value
&
cvalue
);
}
if
(
fEq
||
fCompl
)
{
return
(
index2
<<
1
)
^
!
fEq
;
}
}
}
else
{
word
one
=
ones
[
logwidth
];
word
value
=
GetValue
(
index
,
lev
);
word
cvalue
=
GetCare
(
index
,
lev
);
if
(
!
(
value
&
cvalue
))
{
return
-
2
;
}
if
(
!
((
value
^
one
)
&
cvalue
))
{
return
-
1
;
}
for
(
int
index2
:
vvIndices
[
lev
])
{
word
value2
=
value
^
GetValue
(
index2
,
lev
);
word
cvalue2
=
cvalue
&
GetCare
(
index2
,
lev
);
if
(
!
(
value2
&
cvalue2
))
{
return
index2
<<
1
;
}
if
(
!
((
value2
^
one
)
&
cvalue2
))
{
return
(
index2
<<
1
)
^
1
;
}
}
}
return
-
3
;
}
int
BDDBuildOne
(
int
index
,
int
lev
)
override
{
int
r
=
BDDFindTSM
(
index
,
lev
);
if
(
r
>=
-
2
)
{
if
(
r
>=
0
)
{
CopyFuncMasked
(
r
>>
1
,
index
,
lev
,
r
&
1
);
Merge
(
r
>>
1
,
index
,
lev
,
r
&
1
);
}
else
{
vvMergedIndices
[
lev
].
push_back
({
r
,
index
});
}
return
r
;
}
vvIndices
[
lev
].
push_back
(
index
);
return
index
<<
1
;
}
int
BDDBuild
()
override
{
TruthTable
::
Save
(
3
);
int
r
=
TruthTable
::
BDDBuild
();
TruthTable
::
Load
(
3
);
return
r
;
}
void
BDDRebuildByMerge
(
int
lev
)
override
{
for
(
auto
&
p
:
vvMergedIndices
[
lev
])
{
if
(
p
.
first
>=
0
)
{
CopyFuncMasked
(
p
.
first
>>
1
,
p
.
second
,
lev
,
p
.
first
&
1
);
MergeCare
(
p
.
first
>>
1
,
p
.
second
,
lev
);
}
}
}
int
BDDRebuild
(
int
lev
)
override
{
TruthTable
::
Save
(
3
);
int
r
=
TruthTableCare
::
BDDRebuild
(
lev
);
TruthTable
::
Load
(
3
);
return
r
;
}
};
}
extern
"C"
Vec_Int_t
*
Gia_ManCollectSuppNew
(
Gia_Man_t
*
p
,
int
iOut
,
int
nOuts
);
extern
"C"
Gia_Man_t
*
Gia_ManTtopt
(
Gia_Man_t
*
p
,
int
nIns
,
int
nOuts
,
int
nRounds
)
{
Gia_Man_t
*
pNew
;
Gia_Obj_t
*
pObj
;
Vec_Int_t
*
vSupp
;
word
v
;
word
*
pTruth
;
int
i
,
g
,
k
,
nInputs
;
Gia_ManLevelNum
(
p
);
pNew
=
Gia_ManStart
(
Gia_ManObjNum
(
p
)
);
pNew
->
pName
=
Abc_UtilStrsav
(
p
->
pName
);
pNew
->
pSpec
=
Abc_UtilStrsav
(
p
->
pSpec
);
Gia_ManForEachCi
(
p
,
pObj
,
k
)
Gia_ManAppendCi
(
pNew
);
Gia_ObjComputeTruthTableStart
(
p
,
nIns
);
Gia_ManHashStart
(
pNew
);
for
(
g
=
0
;
g
<
Gia_ManCoNum
(
p
);
g
+=
nOuts
)
{
vSupp
=
Gia_ManCollectSuppNew
(
p
,
g
,
nOuts
);
nInputs
=
Vec_IntSize
(
vSupp
);
Ttopt
::
TruthTableReo
tt
(
nInputs
,
nOuts
);
for
(
k
=
0
;
k
<
nOuts
;
k
++
)
{
pObj
=
Gia_ManCo
(
p
,
g
+
k
);
pTruth
=
Gia_ObjComputeTruthTableCut
(
p
,
Gia_ObjFanin0
(
pObj
),
vSupp
);
if
(
nInputs
>=
6
)
for
(
i
=
0
;
i
<
tt
.
nSize
;
i
++
)
tt
.
t
[
i
+
tt
.
nSize
*
k
]
=
Gia_ObjFaninC0
(
pObj
)
?
~
pTruth
[
i
]
:
pTruth
[
i
];
else
{
i
=
k
*
(
1
<<
nInputs
);
v
=
(
Gia_ObjFaninC0
(
pObj
)
?
~
pTruth
[
0
]
:
pTruth
[
0
])
&
tt
.
ones
[
nInputs
];
tt
.
t
[
i
/
tt
.
ww
]
|=
v
<<
(
i
%
tt
.
ww
);
}
}
tt
.
RandomSiftReo
(
nRounds
);
Ttopt
::
TruthTable
tt2
(
nInputs
,
nOuts
);
tt2
.
t
=
tt
.
t
;
tt2
.
Reo
(
tt
.
vLevels
);
tt2
.
BDDGenerateAig
(
pNew
,
vSupp
);
Vec_IntFree
(
vSupp
);
}
Gia_ObjComputeTruthTableStop
(
p
);
Gia_ManHashStop
(
pNew
);
Gia_ManSetRegNum
(
pNew
,
Gia_ManRegNum
(
p
)
);
return
pNew
;
}
extern
"C"
word
*
Gia_ManCountFraction
(
Gia_Man_t
*
p
,
Vec_Wrd_t
*
vSimI
,
Vec_Int_t
*
vSupp
,
int
Thresh
,
int
fVerbose
,
int
*
pCare
);
extern
"C"
Gia_Man_t
*
Gia_ManTtoptCare
(
Gia_Man_t
*
p
,
int
nIns
,
int
nOuts
,
int
nRounds
,
char
*
pFileName
,
int
nRarity
)
{
int
fVerbose
=
0
;
Gia_Man_t
*
pNew
;
Gia_Obj_t
*
pObj
;
Vec_Int_t
*
vSupp
;
word
v
;
word
*
pTruth
,
*
pCare
;
int
i
,
g
,
k
,
nInputs
;
Vec_Wrd_t
*
vSimI
=
Vec_WrdReadBin
(
pFileName
,
fVerbose
);
Gia_ManLevelNum
(
p
);
pNew
=
Gia_ManStart
(
Gia_ManObjNum
(
p
)
);
pNew
->
pName
=
Abc_UtilStrsav
(
p
->
pName
);
pNew
->
pSpec
=
Abc_UtilStrsav
(
p
->
pSpec
);
Gia_ManForEachCi
(
p
,
pObj
,
k
)
Gia_ManAppendCi
(
pNew
);
Gia_ObjComputeTruthTableStart
(
p
,
nIns
);
Gia_ManHashStart
(
pNew
);
for
(
g
=
0
;
g
<
Gia_ManCoNum
(
p
);
g
+=
nOuts
)
{
vSupp
=
Gia_ManCollectSuppNew
(
p
,
g
,
nOuts
);
nInputs
=
Vec_IntSize
(
vSupp
);
Ttopt
::
TruthTableLevelTSM
tt
(
nInputs
,
nOuts
);
for
(
k
=
0
;
k
<
nOuts
;
k
++
)
{
pObj
=
Gia_ManCo
(
p
,
g
+
k
);
pTruth
=
Gia_ObjComputeTruthTableCut
(
p
,
Gia_ObjFanin0
(
pObj
),
vSupp
);
if
(
nInputs
>=
6
)
for
(
i
=
0
;
i
<
tt
.
nSize
;
i
++
)
tt
.
t
[
i
+
tt
.
nSize
*
k
]
=
Gia_ObjFaninC0
(
pObj
)
?
~
pTruth
[
i
]
:
pTruth
[
i
];
else
{
i
=
k
*
(
1
<<
nInputs
);
v
=
(
Gia_ObjFaninC0
(
pObj
)
?
~
pTruth
[
0
]
:
pTruth
[
0
])
&
tt
.
ones
[
nInputs
];
tt
.
t
[
i
/
tt
.
ww
]
|=
v
<<
(
i
%
tt
.
ww
);
}
}
i
=
1
<<
Vec_IntSize
(
vSupp
);
pCare
=
Gia_ManCountFraction
(
p
,
vSimI
,
vSupp
,
nRarity
,
fVerbose
,
&
i
);
tt
.
care
[
0
]
=
pCare
[
0
];
for
(
i
=
1
;
i
<
tt
.
nSize
;
i
++
)
tt
.
care
[
i
]
=
pCare
[
i
];
ABC_FREE
(
pCare
);
tt
.
RandomSiftReo
(
nRounds
);
tt
.
Optimize
();
tt
.
BDDGenerateAig
(
pNew
,
vSupp
);
Vec_IntFree
(
vSupp
);
}
Gia_ObjComputeTruthTableStop
(
p
);
Gia_ManHashStop
(
pNew
);
Gia_ManSetRegNum
(
pNew
,
Gia_ManRegNum
(
p
)
);
Vec_WrdFreeP
(
&
vSimI
);
return
pNew
;
}
ABC_NAMESPACE_IMPL_END
src/aig/gia/module.make
View file @
c65e08f9
...
@@ -105,5 +105,6 @@ SRC += src/aig/gia/giaAig.c \
...
@@ -105,5 +105,6 @@ SRC += src/aig/gia/giaAig.c \
src/aig/gia/giaTis.c
\
src/aig/gia/giaTis.c
\
src/aig/gia/giaTruth.c
\
src/aig/gia/giaTruth.c
\
src/aig/gia/giaTsim.c
\
src/aig/gia/giaTsim.c
\
src/aig/gia/giaTtopt.cpp
\
src/aig/gia/giaUnate.c
\
src/aig/gia/giaUnate.c
\
src/aig/gia/giaUtil.c
src/aig/gia/giaUtil.c
src/base/abci/abc.c
View file @
c65e08f9
...
@@ -499,6 +499,7 @@ static int Abc_CommandAbc9LNetRead ( Abc_Frame_t * pAbc, int argc, cha
...
@@ -499,6 +499,7 @@ static int Abc_CommandAbc9LNetRead ( Abc_Frame_t * pAbc, int argc, cha
static
int
Abc_CommandAbc9LNetSim
(
Abc_Frame_t
*
pAbc
,
int
argc
,
char
**
argv
);
static
int
Abc_CommandAbc9LNetSim
(
Abc_Frame_t
*
pAbc
,
int
argc
,
char
**
argv
);
static
int
Abc_CommandAbc9LNetEval
(
Abc_Frame_t
*
pAbc
,
int
argc
,
char
**
argv
);
static
int
Abc_CommandAbc9LNetEval
(
Abc_Frame_t
*
pAbc
,
int
argc
,
char
**
argv
);
static
int
Abc_CommandAbc9LNetOpt
(
Abc_Frame_t
*
pAbc
,
int
argc
,
char
**
argv
);
static
int
Abc_CommandAbc9LNetOpt
(
Abc_Frame_t
*
pAbc
,
int
argc
,
char
**
argv
);
static
int
Abc_CommandAbc9Ttopt
(
Abc_Frame_t
*
pAbc
,
int
argc
,
char
**
argv
);
static
int
Abc_CommandAbc9LNetMap
(
Abc_Frame_t
*
pAbc
,
int
argc
,
char
**
argv
);
static
int
Abc_CommandAbc9LNetMap
(
Abc_Frame_t
*
pAbc
,
int
argc
,
char
**
argv
);
static
int
Abc_CommandAbc9Unmap
(
Abc_Frame_t
*
pAbc
,
int
argc
,
char
**
argv
);
static
int
Abc_CommandAbc9Unmap
(
Abc_Frame_t
*
pAbc
,
int
argc
,
char
**
argv
);
static
int
Abc_CommandAbc9Struct
(
Abc_Frame_t
*
pAbc
,
int
argc
,
char
**
argv
);
static
int
Abc_CommandAbc9Struct
(
Abc_Frame_t
*
pAbc
,
int
argc
,
char
**
argv
);
...
@@ -1249,6 +1250,7 @@ void Abc_Init( Abc_Frame_t * pAbc )
...
@@ -1249,6 +1250,7 @@ void Abc_Init( Abc_Frame_t * pAbc )
Cmd_CommandAdd
(
pAbc
,
"ABC9"
,
"&lnetsim"
,
Abc_CommandAbc9LNetSim
,
0
);
Cmd_CommandAdd
(
pAbc
,
"ABC9"
,
"&lnetsim"
,
Abc_CommandAbc9LNetSim
,
0
);
Cmd_CommandAdd
(
pAbc
,
"ABC9"
,
"&lneteval"
,
Abc_CommandAbc9LNetEval
,
0
);
Cmd_CommandAdd
(
pAbc
,
"ABC9"
,
"&lneteval"
,
Abc_CommandAbc9LNetEval
,
0
);
Cmd_CommandAdd
(
pAbc
,
"ABC9"
,
"&lnetopt"
,
Abc_CommandAbc9LNetOpt
,
0
);
Cmd_CommandAdd
(
pAbc
,
"ABC9"
,
"&lnetopt"
,
Abc_CommandAbc9LNetOpt
,
0
);
Cmd_CommandAdd
(
pAbc
,
"ABC9"
,
"&ttopt"
,
Abc_CommandAbc9Ttopt
,
0
);
Cmd_CommandAdd
(
pAbc
,
"ABC9"
,
"&lnetmap"
,
Abc_CommandAbc9LNetMap
,
0
);
Cmd_CommandAdd
(
pAbc
,
"ABC9"
,
"&lnetmap"
,
Abc_CommandAbc9LNetMap
,
0
);
Cmd_CommandAdd
(
pAbc
,
"ABC9"
,
"&unmap"
,
Abc_CommandAbc9Unmap
,
0
);
Cmd_CommandAdd
(
pAbc
,
"ABC9"
,
"&unmap"
,
Abc_CommandAbc9Unmap
,
0
);
Cmd_CommandAdd
(
pAbc
,
"ABC9"
,
"&struct"
,
Abc_CommandAbc9Struct
,
0
);
Cmd_CommandAdd
(
pAbc
,
"ABC9"
,
"&struct"
,
Abc_CommandAbc9Struct
,
0
);
...
@@ -42202,6 +42204,113 @@ usage:
...
@@ -42202,6 +42204,113 @@ usage:
SeeAlso []
SeeAlso []
***********************************************************************/
***********************************************************************/
int
Abc_CommandAbc9Ttopt
(
Abc_Frame_t
*
pAbc
,
int
argc
,
char
**
argv
)
{
extern
Gia_Man_t
*
Gia_ManTtopt
(
Gia_Man_t
*
p
,
int
nIns
,
int
nOuts
,
int
nRounds
);
extern
Gia_Man_t
*
Gia_ManTtoptCare
(
Gia_Man_t
*
p
,
int
nIns
,
int
nOuts
,
int
nRounds
,
char
*
pFileName
,
int
nRarity
);
Gia_Man_t
*
pTemp
;
char
*
pFileName
=
NULL
;
int
c
,
nIns
=
6
,
nOuts
=
2
,
Limit
=
0
,
nRounds
=
20
,
fVerbose
=
0
;
Extra_UtilGetoptReset
();
while
(
(
c
=
Extra_UtilGetopt
(
argc
,
argv
,
"IORXvh"
)
)
!=
EOF
)
{
switch
(
c
)
{
case
'I'
:
if
(
globalUtilOptind
>=
argc
)
{
Abc_Print
(
-
1
,
"Command line switch
\"
-I
\"
should be followed by a positive integer.
\n
"
);
goto
usage
;
}
nIns
=
atoi
(
argv
[
globalUtilOptind
]);
globalUtilOptind
++
;
break
;
case
'O'
:
if
(
globalUtilOptind
>=
argc
)
{
Abc_Print
(
-
1
,
"Command line switch
\"
-O
\"
should be followed by a positive integer.
\n
"
);
goto
usage
;
}
nOuts
=
atoi
(
argv
[
globalUtilOptind
]);
globalUtilOptind
++
;
break
;
case
'R'
:
if
(
globalUtilOptind
>=
argc
)
{
Abc_Print
(
-
1
,
"Command line switch
\"
-R
\"
should be followed by a positive integer.
\n
"
);
goto
usage
;
}
Limit
=
atoi
(
argv
[
globalUtilOptind
]);
globalUtilOptind
++
;
break
;
case
'X'
:
if
(
globalUtilOptind
>=
argc
)
{
Abc_Print
(
-
1
,
"Command line switch
\"
-X
\"
should be followed by a positive integer.
\n
"
);
goto
usage
;
}
nRounds
=
atoi
(
argv
[
globalUtilOptind
]);
globalUtilOptind
++
;
break
;
case
'v'
:
fVerbose
^=
1
;
break
;
case
'h'
:
default:
goto
usage
;
}
}
if
(
argc
>
globalUtilOptind
+
1
)
{
return
0
;
}
if
(
pAbc
->
pGia
==
NULL
)
{
Abc_Print
(
-
1
,
"Empty GIA network.
\n
"
);
return
1
;
}
if
(
argc
==
globalUtilOptind
+
1
)
{
FILE
*
pFile
=
fopen
(
argv
[
globalUtilOptind
],
"rb"
);
if
(
pFile
==
NULL
)
{
Abc_Print
(
-
1
,
"Abc_CommandAbc9BCore(): Cannot open file
\"
%s
\"
for reading the simulation information.
\n
"
,
argv
[
globalUtilOptind
]
);
return
0
;
}
fclose
(
pFile
);
pFileName
=
argv
[
globalUtilOptind
];
}
if
(
pFileName
)
pTemp
=
Gia_ManTtoptCare
(
pAbc
->
pGia
,
nIns
,
nOuts
,
nRounds
,
pFileName
,
Limit
);
else
pTemp
=
Gia_ManTtopt
(
pAbc
->
pGia
,
nIns
,
nOuts
,
nRounds
);
Abc_FrameUpdateGia
(
pAbc
,
pTemp
);
return
0
;
usage:
Abc_Print
(
-
2
,
"usage: &ttopt [-IORX num] [-vh] <file>
\n
"
);
Abc_Print
(
-
2
,
"
\t
performs specialized AIG optimization
\n
"
);
Abc_Print
(
-
2
,
"
\t
-I num : the input support size [default = %d]
\n
"
,
nIns
);
Abc_Print
(
-
2
,
"
\t
-O num : the output group size [default = %d]
\n
"
,
nOuts
);
Abc_Print
(
-
2
,
"
\t
-R num : patterns are cares starting this value [default = %d]
\n
"
,
Limit
);
Abc_Print
(
-
2
,
"
\t
-X num : the number of optimization rounds [default = %d]
\n
"
,
nRounds
);
Abc_Print
(
-
2
,
"
\t
-v : toggles verbose output [default = %s]
\n
"
,
fVerbose
?
"yes"
:
"no"
);
Abc_Print
(
-
2
,
"
\t
-h : prints the command usage
\n
"
);
Abc_Print
(
-
2
,
"
\t
<file> : file name with simulation information
\n
"
);
return
1
;
}
/**Function*************************************************************
Synopsis []
Description []
SideEffects []
SeeAlso []
***********************************************************************/
int
Abc_CommandAbc9LNetMap
(
Abc_Frame_t
*
pAbc
,
int
argc
,
char
**
argv
)
int
Abc_CommandAbc9LNetMap
(
Abc_Frame_t
*
pAbc
,
int
argc
,
char
**
argv
)
{
{
extern
Abc_Ntk_t
*
Gia_ManPerformLNetMap
(
Gia_Man_t
*
p
,
int
GroupSize
,
int
fUseFixed
,
int
fTryNew
,
int
fVerbose
);
extern
Abc_Ntk_t
*
Gia_ManPerformLNetMap
(
Gia_Man_t
*
p
,
int
GroupSize
,
int
fUseFixed
,
int
fTryNew
,
int
fVerbose
);
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