Global Constraints

Toby Walsh National ICT Australia and University of New South Wales www.cse.unsw.edu.au/~tw Global Constraints

Course outline • Introduction • All Different • Lex ordering • Value precedence • Complexity • GAC-Schema • Soft Global Constraints • Global Grammar Constraints • Roots Constraint • Range Constraint • Slide Constraint • Global Constraints on Sets

Global grammar constraints • Often easy to specify a global constraint • ALLDIFFERENT([X1,..Xn]) iff Xi=/=Xj for i<j • Difficult to build an efficient and effective propagator • Especially if we want global reasoning

Global grammar constraints • Promising direction initiated is to specify constraints via automata/grammar • Sequence of variables = string in some formal language • Satisfying assignment = string accepted by the grammar/automata Global constraints meets formal language theory

REGULAR constraint • REGULAR(A,[X1,..Xn]) holds iff • X1 .. Xn is a string accepted by the deterministic finite automaton A • Proposed by Pesant at CP 2004 • GAC algorithm using dynamic programming • However, DP is not needed since simple ternary encoding is just as efficient and effective

REGULAR constraint • Deterministic finite automaton (DFA) • <Q,Sigma,T,q0,F> • Q is finite set of states • Sigma is alphabet (from which strings formed) • T is transition function: Q x Sigma -> Q • q0 is starting state • F subseteq Q are accepting states • DFAs accept precisely regular languages • Regular language can be specified by rules of the form: NonTerminal -> Terminal | Terminal NonTerminal

REGULAR constraint • DFAs accept precisely regular languages • Regular language can be specified by rules of the form: NonTerminal -> Terminal NonTerminal -> Terminal NonTerminal • Alternatively given by regular expressions • More limited than BNF which can express context-free grammars

REGULAR constraint • Deterministic finite automation (DFA) 5 tuple <Q,Sigma,T,q0,F> where • Q is finite set of states • Sigma is alphabet (from which strings formed) • T is transition function: Q x Sigma -> Q • q0 is starting state • F subseteq Q are accepting states

REGULAR constraint • Regular language • S -> 0 | 0A| AB | 1B | 1 • A -> 0 | 0A • B -> 1 | 1B • DFA • Q={q0,q1,q2,q3} • Sigma={0.1} • T(q0,0)=q0. T(q0,1)=q1 • T(q1,0)=q2, T(q1,1)=q1 • T(q2,0)=q2, T(q2,1)=q3 • T(q3,0)=T(q3,1)=q3 • F={q0,q1,q2}

REGULAR constraint • Regular language • S -> A | AB | ABA | BA | B • A -> 0 | 0A • B -> 1 | 1B • DFA • Q={q0,q1,q2,q3} • Sigma={0.1} • T(q0,0)=q0. T(q0,1)=q1 • T(q1,0)=q2, T(q1,1)=q1 • T(q2,0)=q2, T(q2,1)=q3 • T(q3,0)=T(q3,1)=q3 • F={q0,q1,q2} This is the CONTIGUITY global constraint

REGULAR constraint • Many global constraints are instances of REGULAR • AMONG • CONTIGUITY • LEX • PRECEDENCE • STRETCH • .. • Domain consistency can be enforced in O(ndQ) time using dynamic programming

REGULAR constraint • REGULAR constraint can be encoded into ternary constraints • Introduce Qi+1 • state of the DFA after the ith transition • Then post sequence of constraints • C(Xi,Qi,Qi+1) iff DFA goes from state Qi to Qi+1 on symbol Xi

REGULAR constraint • REGULAR constraint can be encoded into ternary constraints • Constraint graph is Berge-acyclic • Constraints only overlap on one variable • Enforcing GAC on ternary constraints achieves GAC on REGULAR in O(ndQ) time

REGULAR constraint • PRECEDENCE([X1,..Xn]) iff • min({i | Xi=j or i=n+1}) < min({i | Xi=k or i=n+2}) for all j<k • DFA has one state for each value plus a single non-accepting state, fail • State represents largest value so far used • T(Si,vj)=Si if j<=i • T(Si,vj)=Sj if j=i+1 • T(Si,vj)=fail if j>i+1 • T(fail,v)=fail

REGULAR constraint • PRECEDENCE([X1,..Xn]) iff • min({i | Xi=j or i=n+1}) < min({i | Xi=k or i=n+2}) for all j<k • DFA has one state for each value plus a single non-accepting state, fail • State represents largest value so far used • T(Si,vj)=Si if j<i • T(Si,vj)=Sj if j=i+1 • T(Si,vj)=fail if j>i+1 • T(fail,v)=fail • REGULAR encoding of this is just these transition constraints (can ignore fail)

REGULAR constraint • STRETCH([X1,..Xn]) holds iff • Any stretch of consecutive values is between shortest(v) and longest(v) length • Any change (v1,v2) is in some permitted set, P • For example, you can only have 3 consecutive night shifts and a night shift must be followed by a day off

REGULAR constraint • STRETCH([X1,..Xn]) holds iff • Any stretch of consecutive values is between shortest(v) and longest(v) length • Any change (v1,v2) is in some permitted set, P • DFA • Qi is <last value, length of current stretch> • Q0= <dummy,0> • T(<a,q>,a)=<a,q+1> if q+1<=longest(a) • T(<a,q>,b)=<b,1> if (a,b) in P and q>=shortest(a) • All states are accepting

NFA constraint • Automaton does not need to be deterministic • Non-deterministic finite automaton (NFA) still only accept regular languages • But may require exponentially fewer states • Important as O(ndQ) running time for propagator • E.g. 0* (1|2)* 2 (1|2)^k 0* • Where 0=closed, 1=production, 2=maintenance • Can use the same ternary encoding

Soft REGULAR constraint • May wish to be “near” to a regular string • Near could be • Hamming distance • Edit distance • SoftREGULAR(A,[X1,..Xn],N) holds iff • X1..Xn is at distance N from a string accepted by the finite automaton A • Can encode this into a sequence of 5-ary constraints

Soft REGULAR constraint • SoftREGULAR(A,[X1,..Xn],N) • Consider Hamming distance (edit distance similar though a little more complex) • Qi+1 is state of automaton after the ith transition • Di+1 is Hamming distance up to the ith variable • Post sequence of constraints • C(Xi,Qi,Qi+1,Di,Di+1) where • Di+1=Di if T(Xi,Qi)=Qi+1 else Di+1=1+Di

Soft REGULAR constraint • SoftREGULAR(A,[X1,..Xn],N) • To propagate • Dynamic programming • Pass support along sequence • Just post the 5-ary constraints • Accept less than GAC • Tuple up the variables

Cyclic forms of REGULAR • REGULAR+(A,[X1,..,Xn]) • X1 .. XnX1 is accepted by A • Can convert into REGULAR by increasing states by factor of d where d is number of initial symbols • qi => (qi,d) • T(qi,a)=qj => T((qi,d),a)=(qj,d) • T(q0,d)=qk => T(q0,d)=(qk,d) • Thereby pass along value taken by X1 so it can be checked on last transition

Cyclic forms of REGULAR • REGULARo(A,[X1,..,Xn]) • Xi .. X1+(i+n-1)mod n is accepted by A for each 1<=i<=n • Can decompose into n instances of the REGULAR constraint • However, this hinders propagation • Suppose A accepts just alternating sequences of 0 and 1 • Xi in {0,1} and REGULARo(A,[X1,X2.X3]) • Unfortunately enforcing GAC on REGULARo is NP-hard

Cyclic forms of REGULAR • REGULARo(A,[X1,..,Xn]) • Reduction from Hamiltonian cycle • Consider polynomial sized automaton A1 that accepts any sequence in which the 1st character is never repeated • Consider polynomial sized automaton A2 that accepts any walk in a graph • T(a,b)=b iff (a,b) in edges of graph • Consider polynomial sized automaton A1 intersect A2 • This accepts only those strings corresponding to Hamiltonian cycles

Other generalizations of REGULAR • REGULAR FIX(A,[X1,..Xn],[B1,..Bm]) iff • REGULAR(A,[X1,..Xn]) and Bi=1 iff exists j. Xj=I • Certain values must occur within the sequence • For example, there must be a maintenance shift • Unfortunately NP-hard to enforce GAC on this

Other generalizations of REGULAR • REGULAR FIX(A,[X1,..Xn],[B1,..Bm]) • Simple reduction from Hamiltonian path • Automaton A accepts any walk on a graph • n=m and Bi=1 for all i

Chomsky hierarchy • Regular languages • Context-free languages • Context-sensitive languages • ..

Chomsky hierarchy • Regular languages • GAC propagator in O(ndQ) time • Conext-free languages • GAC propagator in O(n^3) time and O(n^2) space • Asymptotically optimal as same as parsing! • Conext-sensitive languages • Checking if a string is in the language PSPACE-complete • Undecidable to know if empty string in grammar and thus to detect domain wipeout and enforce GAC!

Context-free grammars • Possible applications • Hierarchy configuration • Bioinformatics • Natual language parsing • … • CFG(G,[X1,…Xn]) holds iff • X1 .. Xn is a string accepted by the context free grammar G

Context-free grammars • CFG(G,[X1,…Xn]) • Consider a block stacking example • S -> NP | P | PN | NPN • N -> n | nN • P -> aa | bb | aPa | bPb • These rules give n* w rev(w) n* where w is (a|b)* • Not expressible using a regular language • Chomsky normal form • Non-terminal -> Terminal • Non-terminal -> Non-terminal Non-terminal

Context-free grammars • CFG(G,[X1,…Xn]) • Example with X1 in {n,a}, X2 in {b}, X3 in {a,b} and X4 in {n,a} • Enforcing GAC on CFG prunes X3=a • Only supports are nbbn and abba

CFG propagator • Adapt CYK parser • Works on Chomsky normal form • Non-terminal -> Terminal • Non-terminal -> Non-terminal Non-terminal • Using dynamic programming • Computes V[i,j], set of possible parsings for the ith to the jth symbols

CFG propagator • Adapt CYK parser which uses dynamic programming • For i=1 to n do • V[i,1]:={A | A->a in G, a in dom(Xi) • For j=2 to n do • For i=1 to n-j+1 do • V[i,j]:={} • For k=1 to j-1 do • V[i,j]:=V[i,j] u {A|A->BC in G, • B in V[i,k], C in V[i+k,j-k]} • If not(S in V[1,n]) then “unsat”

Conclusions • Global grammar constraints • Specify wide range of global constraints • Provide efficient and effective propagators automatically • Nice marriage of formal language theory and constraint programming!

Global Constraints