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Title: Recovering and Exploiting Structural Knowledge from CNF Formulas

1
Recovering and Exploiting Structural
Knowledge from CNF Formulas

Presenter Ashique
2
What the paper talks about

The motivation behind the research on efficient
SAT solvers
Useful structural knowledge can be lost due to
CNF representation
Extracting gates out of the CNF formula is a step
to recover that underlying structure
Graphical representation of clauses facilitates
such extraction
Other techniques that minimizes the number of
Gates
Techniques that eliminate clauses and variables

3
Couple of definitions

An equation or gate is of the form y f( x1 ,x2
,x3 ,xn) where f is a standard connective
among ?, ?, ? and where y and xi are
propositional variables.
y is called the output variable (definable) and
xi s are called input variables.
A propositional variable z is an output variable
for a set of gates iff z is an output variable of
at least one gate in the set.
An input variable for a set of gates is an input
variable of a gate which is not an output
variable of the set of gates.

4
Graph of clauses
5
Partial graph of clauses
6
Extraction of Æ and Ç gates
7
Computational complexity

8
Exploiting structure knowledge

Once the gates are extracted various properties
are used to minimize the number of gates,
simplify them and reduce the number of clauses
and variables
All these reductions prune the search space

9
Properties of , gates

, is commutative and associative
(a , a , B) is equivalent to B
(a , b , c) is equivalent to ( a , b , c)
( a , b , c) is equivalent to ( a , b , c)
(l , A1), (l , A2), (l , Am) is SAT iff (A1 ,
A2) (Am-1 , Am) is SAT
Let ? be a set of gates, B ½ ? a set of
equivalence gates, b 2 B such that its output
variable y occurs only in B and ? the set of
gates obtained by the substitution of y with its
definition and removing b from ? , then ? is
satisfiable is ? is satisfiable
Let S be a set of gates, any equivalence gate of
S containing a literal which does not occur
elsewhere in S, can be removed from S without
loss of satisfiability.

10
Properties Æ and Ç gates

11
Simplication of remaining clause sets

Blocked clause A clause c of a CNF formula S is
blocked iff there is a literal l ? c such that
for all c' ? S with l ? c' the resolvent of c
and c' is tautological.
Let c be a clause belonging to a CNF formula S
such that c is blocked. S is satisfiable iff
S\c is satisfiable.

12
nf-blocked clause

A clause c belonging to a CNF formula S is
non-fundamental iff c is either tautological or
is subsumed by another clause from S.
A clause c belonging to a CNF formula S is
nf-blocked iff there exists a literal l from c
such that. there does not exist any resolvent in
l, or such that all resolvents are not
fundamental.
Let c be a clause belonging to a CNF formula S
s.t. c is nf-blocked. S is satifiable iff S\c
is satisfiable.

13
nf-blocked example continued

14
Variable elimination using nf-blocked clause

Any clause c from a CNF formula S can be
nf-blocked, introducing additional clauses in S.
Transitive closure of two-literal clauses
In order to eliminate a variable, we just need to
nf-block all clauses where it occurs

15
Some more reduction techniques

A clause c belonging to a CNF formula ? is
redundant iff ? \c ² c.
A clause c from a CNF formula S is u-redundant
iff the unsatisfiability of
S ? c can be obtained using unit
propagation.
Let ? be a CNF formula, a subsuming resolvent is
a resolvent from two clauses from ? that subsumes
at least one clause of ? .

16
How costly is it?

17
Performance vis-à-vis other algorithms

18
The reason behind such performance

19
Future directions