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Foundations of Constraint Processing, Spring 2009
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Foundations of Constraint ProcessingCSCE421/821, Spring 2009
www.cse.unl.edu/~choueiry/S09-421-821/All questions: cse421@cse.unl.edu
Berthe Y. Choueiry (Shu-we-ri)Avery Hall, Room 360
choueiry@cse.unl.edu Tel: +1(402)472-5444
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Properties & Algorithms
Foundations of Constraint Processing, Spring 2009
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Outline1. Global properties
2. Local properties– Binary CSPs Dechter Sections 3.1, 3.2, 3.3, 3.4
– Non-Binary CSPs Dechter Sections 3.5.1, 8.1
3. Effects of Consistency Algorithms– Domain filtering– Constraint filtering– Constraint synthesis
4. Beyond finite, crisp CSPs– Continuous domains Dechter Sections 3.5.3
– Weighted CSPs
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Global Consistency Properties
• Minimality & Decomposability – Originally defined for binary CSPs– Easily extendable to non-binary CSPs
• Minimality Dechter Definition 2.6
– Every constraint is as tight as it can be– Minimality n-consistency– In DB, the relations are said to “join completely”
• Decomposability– Every consistent partial solution can be terminated backtrack
free – Decomposability ≡ strong n-consistency
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Foundations of Constraint Processing, Spring 2009
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Outline1. Global properties
2. Local properties– Binary CSPs– Non-Binary CSPs
3. Effects– Domain filtering– Constraint filtering– Constraint synthesis
4. Beyond finite, crisp CSPs– Continuous domains– Weighted CSPs
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Foundations of Constraint Processing, Spring 2009
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Local Properties: Binary CSPs
• Classical ones– Arc, path, i, strong i, (i,j)-consistency
• More recently – Singleton Arc Consistency– Inverse Consistency– Neighborhood Inverse Consistency– (Conservative) Dual consistency
• Special Constraints
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Classical Local Consistency: Properties
• Arc consistency– Every vvp can be extended to a partial solution of length 2
• Path consistency– Every partial solution of length 2 can be extended to a partial
solution of length 3
• i-consistency– Every partial solution of length (i-1) can be extended to a partial
solution of length i
• (i,j)-consistency– Every partial solution of length i can be extended to a partial
solution of length i+j
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Classical Local Consistency: Algorithms
• Arc consistency: – AC-1, 2, 3, …, 7, AC-2001, AC-*, …– Effect: domain filtering– Complexity: in n2
• Path consistency– PC-1, 2, 3, …, 8, PC2001, PPC, …– Effect: adds binary constraints, modifies the width of network– Complexity: in n3
• i-consistency– Dechter Figure 3.14 & 3.15– Effect: adds constraints of arity i-1, modifies the arity of network– Complexity: in ni
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Local Properties: Binary CSPs
• Classical ones– Arc, path, i, strong i, (i,j)-consistency
• More recently – Singleton Arc Consistency– Inverse Consistency– Neighborhood Inverse Consistency– (Conservative) Dual consistency
• Special Constraints
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Singleton Arc Consistency (SAC)
• Property: The CSP is AC for every vvp• (Sketchy) Algorithm Repeat until no change occurs
Repeat for each variable Repeat for each value in domain
Assign this value to this variable. If the CSP is AC, keep the value. Otherwise, remove it.
• Effect: domain filtering• Note
– Proposed by Debruyne & Bessière, IJCAI 97– Quite expensive, but can be quite effective
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Inverse Consistency
• Path Inverse Consistency (PIC)– Equivalent to (1,2)-consistency
• Inverse m-consistency– Equivalent to (1,m)-consistency
• Neighborhood Inverse Consistency (NIC)– Every vvp participates in a solution in the CSP
induced by its neighborhood
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Neighborhood Inverse Consistency (NIC): Algorithm
Repeat until no change occurs
Repeat for each variable
Consider only the neighborhood of the variable
Repeat for each value for the variable
If the value appears in a complete solution for the neighborhood, then keep it.
Otherwise, remove it.• Effect: domain filtering• Note
– Proposed by Freuder & Elfe, AAAI 96– Very effective, very expensive
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Foundations of Constraint Processing, Spring 2009
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Summary: Binary CSPs
• Arc, path, i-consistency
• (i,j)-consistency
• SAC
• PIC
• (1,m)-consistency
• NIC
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Foundations of Constraint Processing, Spring 2009
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Local Properties: Binary CSPs
• Classical ones– Arc, path, i, strong i, (i,j)-consistency
• More recently – Singleton Arc Consistency– Inverse Consistency– Neighborhood Inverse Consistency– (Conservative) Dual consistency
• Special Constraints
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Foundations of Constraint Processing, Spring 2009
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AC for Special Constraints [Van Hentenryck et al. AIJ 92] • Specialized AC algorithms exist for special constraints• Functional
A constraint C is functional with respect to a domain D iff for all vD (respectively wD) there exists at most one wD (respectively vD) such that C(v,w)
• Anti-functional
A constraint C is anti-functional with respect to a domain D iff C is functional with respect to D
• Monotonic
A constraint C is monotonic with respect to a domain D iff there exists a total ordering on D such that, for all v and wD, C(v,w) holds implies C(v’,w)’ holds for all values all v’ and w’D such that v’ v and w’ w
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Foundations of Constraint Processing, Spring 2009
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Outline1. Global properties
2. Local properties– Binary CSPs– Non-Binary CSPs
3. Effects of Consistency Algorithms– Domain filtering– Constraint filtering– Constraint synthesis
4. Beyond finite, crisp CSPs– Continuous domains– Weighted CSPs
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How about Non-binary CSPs?
• (Almost) all properties (& algorithms) discussed so far were restricted to binary CSPs
• Consistency properties for non-binary CSPs are the topic of current research
• Mainly, properties and algorithms for:1. Domain filtering techniques (a.k.a. domain reduction, domain
propagation)• Do not change ‘topology’ of network (width/arity)• Do not modify constraints definitions
2. Relational m-consistency
[Dechter, Chap 8]
• Add constraints/change constraint definitions
Foundations of Constraint Processing, Spring 2009
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Non-Binary CSPs1. Domain filtering
– Generalized Arc Consistency (GAC) Dechter 3.5.1– Singleton Generalized Arc Consistency (SGAC)– maxRPWC, rPIC, RPWC, etc. [Bessiere et al., 08]
2. Relational consistency– (strong) Relational m-consistency
• Relational Arc-Consistency (R1C)• Relational Path-Consistency (R2C)
– Relational (i,m)-consistency• i = 1, Relational (1,m)-consistency is a domain filtering technique• i=1 and m=2, Relational (1,m)-consistency is known as rPIC
– Relational (*,m)-consistency (m-wise consistency)
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• First introduced by [Mohr & Masini, ECAI 88]• Every value in the domain of every variable has a support in every
constraint in the problem• In every constraint, every vvp participates in a consistent tuple (can
be extended to all other variables in the scope of the constraint)
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Generalized Arc-Consistency : Property
Foundations of Constraint Processing, Spring 2009
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Generalized Arc-Consistency: Algorithm1• (Sketchy) Algorithm
– Project the constraint on each of the variables in its scope to tighten the domain of the variable.
– As domains are filtered, filter the constraint
– Repeat the above until quiescence
• When constraint is not defined in extension, GAC may be problematic (e.g., NP-hard in TCSP)
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Generalized Arc-Consistency: Algorithm2• Another (Sketchy) Algorithm
– Iterate over every combination of a variable and a constraint where it appears (V x, Ci)
– For every value for Vx, identify a support for this value in C i, where a support is a tuple where all vvps in the tuple are alive
– Repeat the above until quiescence
• Does not filter the constraints• Check GAC2001 [Bessière et al., AIJ05]
• When constraint is not defined in extension, GAC may be problematic (e.g., NP-hard in TCSP)
Foundations of Constraint Processing, Spring 2009
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SGAC• Idea: Similar to SAC• (Sketchy) Algorithm
Repeat until quiescence
For each vvp
Assign the vvp; Enforce GAC on the CSP;
If CSP is GAC, keep the vvp, else remove it
• Note– Costly in practice, but polynomial as long as GAC is polynomial– SGAC has been empirically shown to solve every known 9x9
Sudoku puzzle
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Relational Consistency
• Dechter generalizes consistency Dechter 8.1.1
properties to non-binary constraints – Relational m-consistency
• Relational 1-consistency relational arc-consistency• Relational 2-consistency relational path-consistency
– Relational (i,m)-consistency• Relational (1,1)consistency GAC
• m-wise consistency (Databases)– Relational (*,m)-consistency
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Relational 1-Consistency Dechter Def 8.1
• Property– For every constraint C– Let k be the arity of C– Every consistent partial solution of length k-1 – Can be extended to a consistent partial solution of length k
• (Sketchy) Algorithm Dechter Equation (8.2), (8.3)
– For each constraint C, generate all constraints of arity k-1 by• Joining C with the domain of each variable x in scope of C and
• Projecting result on remaining variables (possibly intersecting with existing constraints)
• Effect: Adds a huge number of new constraints• Complexity: polynomial in the largest scope
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Relational 2-Consistency Dechter Def 8.2
• Property– For every two constraint C1 and C2
– Let s = scope(C1) scope(C2)
– Every consistent partial solution of length |s| -1
– Can be extended to a consistent partial solution of length |s|
• (Sketchy) Algorithm Dechter Equation (8.4)
– For each constraints C1 and C2, generate all constraints of arity |s| -1 by
• Joining C1, C2, and the domain of a variable (in C1 and C2 ) and• Projecting the result on remaining variables
• Effect: Adds a huge number of new constraints
• Complexity: polynomial in the largest |s|
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Relational m-Consistency Dechter Def 8.3
• Property– For every m constraints C1 , C2 , .., Cm
– Let s = im scope(Ci)
– Every consistent partial solution of length |s| -1
– Can be extended to a consistent partial solution of length |s|
• (Sketchy) Algorithm Dechter Equation (8.5)
– For each m constraints, generate all constraints of arity |s| -1 by• Joining the m constraints and the domain of a variable (at the
intersection of their scopes) and
• Projecting the result on remaining variables
• Effect: Adds a huge number of new constraints• Complexity: polynomial in the sum of largest 2 scopes
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Relational (i,m)-Consistency Dechter Def 8.4
• Property– For every m constraints C1 , C2 , .., Cm
– Let s = im scope(Ci)
– Every consistent partial solution of length i– Can be extended to a consistent partial solution of length |s|
• Algorithm Dechter Fig 8.1
– For each m constraints, generate all constraints of arity i by
• Joining the m constraints and the domain of a variable (at the intersection of their scopes) and
• Projecting the result on every combination of i variables
• Effect: Adds a huge number of new constraints, except for i=1• Complexity: exponential in s (largest union of scope of m constraints)
in time and space
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m-wise consistency• Property
– For every set of m constraints,– Every tuple in each constraint appears in a consistent solution to the m
constraints– That is, each constraint is as tight as it can be for the set of m constraints
• (Sketchy) Algorithm
Repeat until quiescence
Join each set of m constraints
Project it on each existing constraint to filter the constraint
• Effect: Filters the constraints, w/o introducing new constraints
• Note:– Defined in DB: pairwise consistency, relations join completely– Woodward defined R(*,m)C + new algorithms that are linear space, currently
under evaluation
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Foundations of Constraint Processing, Spring 2009
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Summary: Non-Binary CSPs1. Domain filtering
– Generalized Arc Consistency (GAC)– Singleton Generalized Arc Consistency (SGAC)– maxRPWC, rPIC, RPWC, etc. [Bessiere et al., 08]
2. Relational consistency– (strong) Relational m-consistency
• Relational Arc-Consistency (R1C)• Relational Path-Consistency (R2C)
– Relational (i,m)-consistency• i = 1, Relational (1,m)-consistency is a domain filtering technique• i=1 and m=2, Relational (1,m)-consistency is known as rPIC
– Relational (*,m)-consistency (m-wise consistency)
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Foundations of Constraint Processing, Spring 2009
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Outline1. Global properties
2. Local properties– Binary CSPs– Non-Binary CSPs
3. Effects of Consistency Algorithms– Domain filtering– Constraint filtering– Constraint synthesis
4. Beyond finite, crisp CSPs– Continuous domains– Weighted CSPs
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Foundations of Constraint Processing, Spring 2009
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Effects of Consistency Algorithms
• Filter the domains– Old algorithms: AC-*, GAC-*, etc.– New algorithms: maxRPWC, R(1,m)C, etc.
• Filter the constraints– New algorithms: R(*,m)C
• Add new constraints to the problem– Old algorithms: PC-2, etc.– i-consistency (i>2), (i,j)-C, RmC, R(i,m)C – Example: Solving the CSPs by Constraint Synthesis
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Solving CSPs by Constraint synthesis [Freuder 78]
• From i=2 to i=n, – achieve i-consistency by using (i-1)-arity
constraints to synthesize i-arity constraints, – then use the i-ary constraints to filter
constraints of arity i-1, i-2, etc.
• Process ends – with a unique n-ary constraint – whose tuples are all the solutions to the CSP
Foundations of Constraint Processing, Spring 2009
More on Constraint Consistency
Outline1. Global properties
2. Local properties– Binary CSPs– Non-Binary CSPs
3. Effects of Consistency Algorithms– Domain filtering– Constraint filtering– Constraint synthesis
4. Beyond finite, crisp CSPs– Continuous domains– Weighted CSPs
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Box Consistency (on interval constraints)
• Domains are (continuous) intervals – Historically also called: continuous CSPs, continuous domains
• Domains are infinite: – We cannot enumerate consistent values/tuples– [Davis, AIJ 87] (see recommended reading) showed that even
AC may be incomplete or not terminate
• We apply consistency (usually, arc-consistency) on the boundaries of the interval
• Sometimes, domains are split, so that boundaries can be further filtered
Foundations of Constraint Processing, Spring 2009
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Weighted CSPs• Weighted CSPs
– Tuples have weights in [0,m], m: intolerable cost– Costs are added ab=min{m,a+b}
• Soft Arc Consistency (Cooper, de Givry, Schiex, etc.)
– VAC: Virtual Arc Consistency– EDAC: Existential Directional Arc Consistency– OSAC: Optimal Soft Arc Consistency
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Foundations of Constraint Processing, Spring 2009
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Summary1. Global properties
2. Local properties– Binary CSPs– Non-Binary CSPs
3. Effects of Consistency Algorithms– Domain filtering– Constraint filtering– Constraint synthesis
4. Beyond finite, crisp CSPs– Continuous domains– Weighted CSPs
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