The DPLL/Davis-Putnam-Logemann-Loveland algorithm is a complete, backtracking-based algorithm for deciding the satisfiability of propositional logic formulae in conjunctive normal form, i. Backtracking is a type of Algorithm that is a refinement of Brute force search. In Mathematics, Computing, Linguistics and related subjects an algorithm is a sequence of finite instructions often used for Calculation This is a technical mathematical article about the area of mathematical logic variously known as "propositional calculus" or "propositional logic" In Boolean logic, a Formula is in conjunctive normal form (CNF or cnf if it is a conjunction of clauses, where a clause is a disjunction e. for solving the CNF-SAT problem.
It was introduced in 1962 by Martin Davis, Hilary Putnam, George Logemann and Donald W. Year 1962 ( MCMLXII) was a Common year starting on Monday (the link is to a full 1962 calendar of the Gregorian calendar. This page is on the mathematician For the former tennis player see Martin Davis (tennis. Hilary Whitehall Putnam (born July 31 1926 is an American Philosopher who has been a central figure in Western philosophy since the 1960s especially in Philosophy Loveland, and is a refinement of the earlier Davis-Putnam algorithm, which is a resolution-based procedure developed by Davis and Putnam in 1960. The Davis–Putnam algorithm was developed by Martin Davis and Hilary Putnam for checking the validity of a First-order logic formula Year 1960 ( MCMLX) was a Leap year starting on Friday (link will display full calendar of the Gregorian calendar. Especially in older publications, the Davis-Logemann-Loveland algorithm is often referred to as the “Davis-Putnam method” or the “DP algorithm”. Other common names that maintain the distinction are DLL and DPLL.
DPLL is a highly efficient procedure, and after more than 40 years still forms the basis for most efficient complete SAT solvers, as well as for many theorem provers for fragments of first-order logic. Automated theorem proving ( ATP) or automated deduction, currently the most well-developed subfield of Automated reasoning (AR is the First-order logic (FOL is a formal Deductive system used in mathematics philosophy linguistics and computer science
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The algorithm
The basic backtracking algorithm runs by choosing a literal, assigning a truth value to it, simplifying the formula and then recursively checking if the simplified formula is satisfiable; if this is the case, the original formula is satisfiable; otherwise, the same recursive check is done assuming the opposite truth value. This is known as the splitting rule, as it splits the problem into two simpler sub-problems. The simplification step essentially removes all clauses which become true under the assignment from the formula, and all literals that become false from the remaining clauses.
The DPLL algorithm enhances over the backtracking algorithm by the eager use of the following rules at each step:
- Unit propagation
- If a clause is a unit clause, i. Unit propagation ( UP) or the one-literal rule ( OLR) is a Procedure of Automated theorem proving that can simplify a set of (usually e. it contains only a single unassigned literal, this clause can only be satisfied by assigning the necessary value to make this literal true. Thus, no choice is necessary. In practice, this often leads to deterministic cascades of units, thus avoiding a large part of the naive search space.
- Pure literal elimination
- If a propositional variable occurs with only one polarity in the formula, it is called pure. In Mathematical logic, a propositional variable (also called a sentential variable or sentential letter) is a Variable which can either be Pure literals can always be assigned in a way that makes all clauses containing them true. Thus, these clauses do not constrain the search anymore and can be deleted. While this optimization is part of the original DPLL algorithm, most current implementations omit it, as the effect for efficient implementations now is negligible or, due to the overhead for detecting purity, even negative.
Unsatisfiability of a given partial assignment is detected if one clause becomes empty, i. e. if all its variables have been assigned in a way that makes the corresponding literals false. Satisfiability of the formula is detected either when all variables are assigned without generating the empty clause, or, in modern implementations, if all clauses are satisfied. Unsatisfiability of the complete formula can only be detected after exhaustive search.
The DPLL algorithm can be summarized in the following pseudocode, where Φ is the CNF formula:
function DPLL(Φ)
if Φ is a consistent set of literals
then return true;
if Φ contains an empty clause
then return false;
for every unit clause l in Φ
Φ=unit-propagate(l, Φ);
for every literal l that occurs pure in Φ
Φ=pure-literal-assign(l, Φ);
l := choose-literal(Φ);
return DPLL(ΦΛl) OR DPLL(ΦΛnot(l));
In this pseudocode, unit-propagate(l, Φ) and pure-literal-assign(l, Φ) are functions that return the result of applying unit propagation and the pure literal rule, respectively, to the literal l and the formula Φ. In other words, they replace every occurrence of l with "true" and every occurrence of not l with "false" in the formula Φ, and simplify the resulting formula. The pseudocode DPLL function only returns whether the final assignment satisfies the formula or not. In a real implementation, the partial satisfying assignment typically is also returned on success; this can be derived from the consistent set of literals of the first if statement of the function.
The Davis-Logemann-Loveland algorithm depends on the choice of branching literal, which is the literal considered in the backtracking step. As a result, this is not exactly an algorithm, but rather a family of algorithms, one for each possible way of choosing the branching literal. Efficiency is strongly affected by the choice of the branching literal: there exist instances for which the running time is constant or exponential depending on the choice of the branching literals.
Current work
Current work on improving the algorithm has been done on three directions: defining different policies for choosing the branching literals; defining new data structures to make the algorithm faster, especially the part on unit propagation; and defining variants of the basic backtracking algorithm. The latter direction include non-chronological backtracking and clause learning. In Logic, a clause is a disjunction of literals. In Propositional logic, clausesare usually written as follows where the symbols l_i These refinements describe a method of backtracking after reaching a conflict clause which "learns" the root causes (assignments to variables) of the conflict in order to avoid reaching the same conflict again.
See also
References
- Davis, Martin; Putnam, Hillary (1960). The Davis–Putnam algorithm was developed by Martin Davis and Hilary Putnam for checking the validity of a First-order logic formula Chaff is an Algorithm for solving instances of the Boolean satisfiability problem in programming In Computer science, proof complexity is a measure of efficiency of Automated theorem proving methods that is based on the size of the proofs they produce This page is on the mathematician For the former tennis player see Martin Davis (tennis. Hilary Whitehall Putnam (born July 31 1926 is an American Philosopher who has been a central figure in Western philosophy since the 1960s especially in Philosophy "A Computing Procedure for Quantification Theory". Journal of the ACM 7 (1): 201–215. The Journal of the ACM ( JACM) is the leading Scientific journal of the Association for Computing Machinery (ACM in the broad area of doi:. A digital object identifier ( DOI) is a permanent identifier given to an Electronic document.
- Davis, Martin; Logemann, George, and Loveland, Donald (1962). "A Machine Program for Theorem Proving". Communications of the ACM 5 (7): 394–397. Communications of the ACM ( CACM) is the flagship monthly Journal of the Association for Computing Machinery (ACM doi:. A digital object identifier ( DOI) is a permanent identifier given to an Electronic document.
- Ouyang, Ming (1998). "How Good Are Branching Rules in DPLL?". Discrete Applied Mathematics 89 (1–3): 281–286. doi:. A digital object identifier ( DOI) is a permanent identifier given to an Electronic document.
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