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Line 1: {{Short description\|Form of second-order logic}} In [[mathematical logic]], '''monadic second-order logic''' ('''MSO''') is the fragment of [[~~Second-order logic\|~~second-order logic]] where the second-order quantification is limited to quantification over sets.<ref>{{cite book\|first1=Bruno\|last1=Courcelle\|author1-link=Bruno Courcelle\|first2=Joost\|last2=Engelfriet\| title=Graph Structure and Monadic Second-Order Logic: A Language-Theoretic Approach\| publisher=Cambridge University Press\|date=2012-01-01\|isbn=978-0521898331\|url=http://dl.acm.org/citation.cfm?id=2414243\|~~accessdate~~access-date=2016-09-15}}</ref> It is particularly important in the [[logic of graphs]], because of [[Courcelle's theorem]], which provides algorithms for evaluating monadic second-order formulas over graphs of bounded [[treewidth]]. It is also of fundamental importance in [[automata theory]], where the [[Büchi–Elgot–Trakhtenbrot theorem]] gives a logical characterization of the [[regular language]]s. Second-order logic allows quantification over [[Predicate (mathematical logic)\|predicates]]. However, MSO is the [[Fragment (logic)\|fragment]] in which second-order quantification is limited to monadic predicates (predicates having a single argument). This is often described as quantification over "sets" because monadic predicates are equivalent in expressive power to sets (the set of elements for which the predicate is true). == Variants == Monadic second-order logic comes in two variants. In the variant considered over structures such as graphs and in Courcelle's theorem, the formula may involve non-monadic predicates (in this case the binary edge predicate <math>E(x, y)</math>), but quantification is restricted to be over monadic predicates only. In the variant considered in automata theory and the Büchi–Elgot–Trakhtenbrot theorem, all predicates, including those in the formula itself, must be monadic, with the exceptions of equality (<math>=</math>) and ordering (<math><</math>) relations. == Computational complexity of evaluation == Line 20 ⟶ 25: \| publisher = Institute of Electrical and Electronics Engineers \| title = Proceedings of the Eighth Annual Structure in Complexity Theory Conference \| year = 1993\| s2cid = 32740047 }}.</ref> The existence of an analogous pair of complementary problems, only one of which has an existential second-order formula (without the restriction to monadic formulas) is equivalent to the inequality of NP and [[coNP]], an open question in computational complexity. By contrast, when we wish to check whether a Boolean MSO formula is satisfied by an input finite [[tree (data structure)\|tree]], this problem can be solved in linear time in the tree, by translating the Boolean MSO formula to a [[tree automaton]]<ref>{{Cite journal\|~~last~~last1=Thatcher\|~~first~~first1=J. W.\|last2=Wright\|first2=J. B.\|date=1968-03-01\|title=Generalized finite automata theory with an application to a decision problem of second-order logic\|journal=Mathematical Systems Theory\|language=en\|volume=2\|issue=1\|pages=57–81\|doi=10.1007/BF01691346\|s2cid=31513761\|issn=1433-0490\|ref=ThatcherWright}}</ref> and evaluating the automaton on the tree. In terms of the query, however, the complexity of this process is generally [[nonelementary problem\|nonelementary]].<ref name=":0">{{Cite journal\|last=Meyer\|first=Albert R.\|date=1975\|editor-last=Parikh\|editor-first=Rohit\|title=Weak monadic second order theory of {{sic\|succes\|or\|hide=y}} is not elementary-recursive\|journal=Logic Colloquium\|series=Lecture Notes in Mathematics\|language=en\|publisher=Springer Berlin Heidelberg\|pages=132–154\|doi=10.1007/bfb0064872\|isbn=9783540374831}}</ref> Thanks to [[Courcelle's theorem]], we can also evaluate a Boolean MSO formula in linear time on an input graph if the [[treewidth]] of the graph is bounded by a constant. For MSO formulas that have [[free variable]]s, when the input data is a tree or has bounded treewidth, there are efficient [[enumeration algorithm]]s to produce the set of all solutions,<ref>{{Cite journal\|last=Bagan\|first=Guillaume\|date=2006\|editor-last=Ésik\|editor-first=Zoltán\|title=MSO Queries on Tree Decomposable Structures Are Computable with Linear Delay\|journal=Computer Science Logic\|volume=4207\|series=Lecture Notes in Computer Science\|language=en\|publisher=Springer Berlin Heidelberg\|pages=167–181\|doi=10.1007/11874683_11\|isbn=9783540454595}}</ref>, ensuring that the input data is preprocessed in linear time and that each solution is then produced in a delay linear in the size of each solution, i.e., constant-delay in the common case where all free variables of the query are first-order variables (i.e., they do not represent sets). There are also efficient algorithms for counting the number of solutions of the MSO formula in that case.<ref>{{Cite journal\|~~last~~last1=Arnborg\|~~first~~first1=Stefan\|last2=Lagergren\|first2=Jens\|last3=Seese\|first3=Detlef\|date=1991-06-01\|title=Easy problems for tree-decomposable graphs\|journal=Journal of Algorithms\|volume=12\|issue=2\|pages=308–340\|doi=10.1016/0196-6774(91)90006-K\|issn=0196-6774}}</ref> == Decidability and complexity of satisfiability == ~~== Satisfiability ==~~ The satisfiability problem for monadic second-order logic is undecidable in general because this logic subsumes [[first-order logic]]. ~~The monadic second order theory of the infinite complete [[binary tree]], called S2S, is [[decidability (logic)\|decidable]]. As a consequence of this result, the following theories are decidable:~~ The monadic second-order theory of the infinite complete [[binary tree]], called [[S2S (mathematics)\|S2S]], is [[decidability (logic)\|decidable]].<ref>{{Cite journal\|last=Rabin\|first=Michael O.\|date=1969\|title=Decidability of Second-Order Theories and Automata on Infinite Trees\|url=https://www.jstor.org/stable/1995086\|journal=[[Transactions of the American Mathematical Society]]\|volume=141\|pages=1–35\|doi=10.2307/1995086\|jstor=1995086\|issn=0002-9947\|url-access=subscription}}</ref> As a consequence of this result, the following theories are decidable: * The monadic second-order theory of trees. * The monadic second -order theory of <math>\mathbb{N}</math> under successor (S1S). * ~~wS2S~~WS2S and ~~wS1S~~WS1S, which restrict quantification to finite subsets (weak monadic second -order logic). Note that for binary numbers (represented by subsets), addition is definable even in ~~wS1S~~WS1S. For each of these theories (S2S, S1S, ~~wS2S~~WS2S, ~~wS1S~~WS1S), the complexity of the decision problem is [[nonelementary problem\|nonelementary]].<ref name=":0" /><ref>{{Cite journal\|last1=Stockmeyer\|first1=Larry\|last2=Meyer\|first2=Albert R.\|date=2002-11-01\|title=Cosmological lower bound on the circuit complexity of a small problem in logic\|url=https://doi.org/10.1145/602220.602223\|journal=[[Journal of the ACM]]\|volume=49\|issue=6\|pages=753–784\|doi=10.1145/602220.602223\|s2cid=15515064\|issn=0004-5411\|url-access=subscription}}</ref> === Use of satisfiability of MSO on trees in verification === Monadic second-order logic of trees has applications in [[formal verification]]. Decision procedures for MSO satisfiability<ref>{{Cite journal\|last1=Henriksen\|first1=Jesper G.\|last2=Jensen\|first2=Jakob\|last3=Jørgensen\|first3=Michael\|last4=Klarlund\|first4=Nils\|last5=Paige\|first5=Robert\|last6=Rauhe\|first6=Theis\|last7=Sandholm\|first7=Anders\|date=1995\|editor-last=Brinksma\|editor-first=E.\|editor2-last=Cleaveland\|editor2-first=W. R.\|editor3-last=Larsen\|editor3-first=K. G.\|editor4-last=Margaria\|editor4-first=T.\|editor4-link=Tiziana Margaria\|editor5-last=Steffen\|editor5-first=B.\|title=Mona: Monadic second-order logic in practice\|journal=Tools and Algorithms for the Construction and Analysis of Systems\|series=Lecture Notes in Computer Science\|volume=1019\|language=en\|___location=Berlin, Heidelberg\|publisher=Springer\|pages=89–110\|doi=10.1007/3-540-60630-0_5\|isbn=978-3-540-48509-4\|doi-access=free}}</ref><ref>{{Cite journal\|last1=Fiedor\|first1=Tomáš\|last2=Holík\|first2=Lukáš\|last3=Lengál\|first3=Ondřej\|last4=Vojnar\|first4=Tomáš\|date=2019-04-01\|title=Nested antichains for WS1S\|url=https://doi.org/10.1007/s00236-018-0331-z\|journal=Acta Informatica\|language=en\|volume=56\|issue=3\|pages=205–228\|doi=10.1007/s00236-018-0331-z\|s2cid=57189727\|issn=1432-0525\|url-access=subscription}}</ref><ref>{{Cite journal\|last1=Traytel\|first1=Dmitriy\|last2=Nipkow\|first2=Tobias\|date=2013-09-25\|title=Verified decision procedures for MSO on words based on derivatives of regular expressions\|url=https://doi.org/10.1145/2544174.2500612\|journal=ACM SIGPLAN Notices\|volume=48\|issue=9\|pages=3–f12\|doi=10.1145/2544174.2500612\|issn=0362-1340\|hdl=20.500.11850/106053\|hdl-access=free\|url-access=subscription}}</ref> have been used to prove properties of programs manipulating linked [[data structures]],<ref>{{Cite book\|last1=Møller\|first1=Anders\|last2=Schwartzbach\|first2=Michael I.\|title=Proceedings of the ACM SIGPLAN 2001 conference on Programming language design and implementation \|chapter=The pointer assertion logic engine \|date=2001-05-01\|chapter-url=https://doi.org/10.1145/378795.378851\|series=PLDI '01\|___location=Snowbird, Utah, USA\|publisher=Association for Computing Machinery\|pages=221–231\|doi=10.1145/378795.378851\|isbn=978-1-58113-414-8\|s2cid=11476928}}</ref> as a form of [[Shape analysis (program analysis)\|shape analysis]], and for [[symbolic reasoning]] in [[hardware verification]].<ref>{{Cite journal\|last1=Basin\|first1=David\|last2=Klarlund\|first2=Nils\|date=1998-11-01\|title=Automata based symbolic reasoning in hardware verification\|url=https://doi.org/10.1023/A:1008644009416\|journal=Formal Methods in System Design\|volume=13\|issue=3\|pages=255–288\|doi=10.1023/A:1008644009416\|issn=0925-9856\|url-access=subscription}}</ref> ==See also== * [[Descriptive complexity theory]] * [[Monadic predicate calculus]] * [[Second-order logic]] ==References== {{reflist}} {{Mathematical logic}} [[Category:Mathematical logic]] ~~{{Logic-stub}}~~