Intelligent Systems



  • Motivation

  • Technical Solution

    • Introduction to Theorem Proving and Resolution

    • Description Logics

    • Logic Programming

  • Summary

  • References



  • Basic results of mathematical logic show:
    • We can do logical reasoning with a limited set of simple (computable) rules in restricted formal languages like First-order Logic (FOL)
    • Computers can do reasoning

  • FOL is interesting for this purpose because:
    • It is expressive enough to capture many foundational theorems of mathematics
    • Many real-world problems can be formalized in FOL
    • It is the most expressive logic that one can adequately approach with automated theorem proving techniques


  • Due to its theoretical properties (decidability & complexity) First-Order Logic is not always an ideal solution
  • This motivates research towards formalisms with more practically oriented computitional properties and expressivity
    • Description Logics
      • Syntactic fragments of FOL
      • Focus on decidability and optimized algorithms key reasoning tasks (terminological reasoning / schema reasoning)
    • Logic Programming
      • Provides different expressivity than classical FOL (non-monotonic reasoning with non-classical negation)
      • Provides a very intuitive way to model knowledge
      • Efficient reasoning procedures for large data-sets


    Theorem Proving and Resolution, Description Logics, and Logic Programming


    Introduction to Theorem Proving and Resolution

Introduction – Basic Notions

  • A proof system is collection of inference rules of the form:

    P 1 … P n



    where C is a conclusion sequent, and P i ‘s are premises sequents .

    • If an infererence rule does not have any premises that are taken to be true (called an axiom ), its conclusion automatically holds.
    • Example:
      Modus Ponens: From P, P → Q infer Q,
      Universal instantiation: From (∀x)p(x) infer p(A)
  • Theorems:
    • Expressions that can be derived from the axioms and the rules of inference.

Resolution - Principle

  • Resolution is a refutation system .

    • To prove a statement we attempt to refute its negation

  • Basic idea: Given a consistent set of axioms KB and goal sentence Q , we want to show that KB Q

    • This means that every interpretation I that satisfies KB also satisfies Q

    • Any interpretation I only satisfies either Q or ¬ Q, but not both

    • Therefore, if in fact KB Q holds , an interpretation that satisfies KB , satisfies Q and does not satisfy ¬ Q

        Hence KB { ¬ Q } is unsatisfiable, i.e., it is false under all interpretations

Resolution - Principle

  • Resolution commonly requires sentences to be in clause normal form (also called conjunctive normal form or CNF)
    • A clause is a disjunction of literals (implicitly universally quantified)
      • E.g. : l1 ∨ … ∨ ln
    • A formula in clause normal form conjunction of a set of clauses
      • E.g.: C1 ∧ … ∧ Cn = (ln ∨ … ∨ lm) ∧ … ∧ (li ∨ … ∨ lj)
  • High level steps in a resolution proof:
    • Put the premises or axioms into clause normal form (CNF)
    • Add the negation of the to be proven statement, in clause form, to the set of axioms
    • Resolve these clauses together, using the resolution rule , producing new clauses that logically follow from them
    • Derive a contradiction by generating the empty clause.
    • The substitutions used to produce the empty clause are those under which the opposite of the negated goal is true

Resolution - The Resolution Rule

  • The resolution rule is a single inference that produces a new clause implied by two clauses (called the parent clauses) containing complementary literals

    • Two literals are said to be complements if one is the negation of the other (in the following, ai is taken to be the complement to bj).
    • The resulting clause contains all the literals that do not have complements. Formally:

    • Where a1, …, an, b1, …, bm are literals, and ai is the complement to bj
  • The clause produced by the resolution rule is called the resolvent of the two input clauses.
    • A literal and its negation produce a resolvent only if they unify under some substitution σ.
    • σ Is then applied to the resolvent

Resolution - The Resolution Rule

  • When the two initial clauses contain more than one pair of complementary literals, the resolution rule can be applied (independently) for each such pair

    • However, only the pair of literals that are resolved upon can be removed: All other pairs of literals remain in the resolvent clause

  • Modus ponens (see last lecture) can be seen as a special case of resolution of a one-literal clause and a two-literal clause

  • Example: Given clauses

    • P(x, f(a)) v P(x, f(y)) v Q(y) and ¬P(z, f(a)) v ¬ Q(z)

    • P(x, f(a)) and ¬P(z, f(a)) unify with substitution σ = {x/z}

    • Therefore, we derive the resolvent clause (to which σ is applied):

    • P(z, f(y)) v Q(y) v ¬ Q(z)

Resolution – Complete Resolution Algorithm

  1. Convert all the propositions of a knowledge base KB to clause normal form (CNF)

  2. Negate Q (the to be proven statement) and convert the result to clause form. Add it to the set of clauses obtained in step 1.

  3. Repeat until either a contradiction is found, no progress can be made, or a predetermined amount of effort has been expended:

        a) Select two clauses. Call these the parent clauses.

        b) Resolve them together using the resolution rule . The resolvent will be the disjunction of all the literals of both parent clauses with appropriate substitutions.

        c) If the resolvent is the empty clause , then a contradiction has been found. If it is not, then add it to the set of clauses available to the procedure.

Resolution – Algorithm in Pseudocode

procedure resolution-refutation(KB, Q)
    ;; KB a set of consistent, true sentences
    ;; Q is a goal sentence that we want to derive
    ;; return success if KB ⊢ Q, and failure otherwise
    KB = union(KB, ¬Q)
    while false not in KB do
      pick 2 sentences, S1 and S2, in KB that contain literals that unify
          if none return "failure“
      resolvent = resolution-rule(S1, S2)
      KB = union(KB, resolvnt)
    return "success"

Resolution - Converting to Clause Normal Form

  • Resolution expects input in clause normal form
  • Step 1: Eliminate the logical connectives → and ↔
    • a b = (a b) (b a)
    • a b = ¬ a ∨ b
  • Step 2: Reduce the scope of negation
    • ¬ ( ¬ a) = a
    • ¬ (a b) = ¬ a ¬ b
    • ¬ (a b) = ¬ a ¬ b
    • ¬ ( X) a(X) = ( X) ¬ a(X)
    • ¬ ( X) b(X) = ( X) ¬ b(X)

Resolution - Converting to Clause Normal Form

  • Step 3: Standardize by renaming all variables so that variables bound by different quantifiers have unique names

    • ( X) a(X) ( X) b(X) = ( X) a(X) ( Y) b(Y)

  • Step 4: Move all quantifiers to the left to obtain a prenex normal form

    • A formula is inn prenex normal form if it is written as a string of quantifiers followed by a quantifier-free part

  • Step 5: Eliminate existential quantifiers by using skolemization

Resolution - Converting to Clause Normal Form

  • Step 5: Skolemization
    • Skolem constant
      • (∃X)(dog(X)) may be replaced by dog(fido) where the name fido is picked from the domain of definition of X to represent that individual X.
    • Skolem function
      • If the predicate has more than one argument and the existentially quantified variable is within the scope of universally quantified variables, the existential variable must be a function of those other variables.
        (∀X)(∃Y)(mother(X,Y)) ⇒ (∀X)mother(X,m(X))
        (∀X)(∀Y)(∃Z)(∀W)(foo (X,Y,Z,W))
        ⇒ (∀X)(∀Y)(∀W)(foo(X,Y,f(X,Y),w))

Resolution - Converting to Clause Normal Form

  • Step 6: Drop all universal quantifiers
  • Step 7: Convert the expression to the conjunctions of disjuncts
      (a ∧ b) ∨ (c ∧ d)
      = (a ∨ (c ∧ d)) ∧ (b ∨ (c ∧ d))
      = (a ∨ c) ∧ (a ∨ d) ∧ (b ∨ c) ∧ (b ∨ d)
  • step 8: Split each conjunction into a separate clauses, which are just a disjunction of negated and nonnegated predicates, called literals
  • step 9: Rename so that no variable symbol appears in more than one clause.
        (∀X)(a(X) ∧ b(X)) = (∀X)a(X) ∧ (∀ Y)b(Y)

Resolution - Complete Example

  • (Nearly) Classical example: Prove “Fido will die.” from the statements
    • “Fido is a dog.”
    • “All dogs are animals.”
    • “All animals will die.”
    • Changing premises to predicates
      • (x) (dog(X) animal(X))
      • dog(fido)
    • Modus Ponens and {fido/X}
      • animal(fido)
      • (Y) (animal(Y) die(Y))
    • Modus Ponens and {fido/Y}
      • die(fido)

Resolution – Complete Example

  • Equivalent proof by Resolution
    • Convert predicates to clause normal form
      Predicate form
      Clause form
      1. (x) (dog(X) animal(X))
      ¬ dog(X) animal(X)
      2. dog(fido)
      3. (Y) (animal(Y) die(Y))
      ¬ animal(Y) die(Y)
    • Negate the conclusion
      4. ¬ die(fido)                      ¬ die(fido)

Resolution - Complete Example

Resolution – Further Considerations

  • Resolution can be used to establish that a given sentence is entailed by a set of axioms
    • However, it cannot , in general, be used to generate all logical consequences of a set axioms
    • Also, the resolution cannot be used to prove that a given sentence is not entailed by a set of axioms

  • Resolution defines a search space
    • The decision which clauses will be resolved against which others define the operators in the space
    • A search method is required

  • Worst case: Resolution is exponential in the number of clauses to resolve

Resolution – Strategies

  • Order of clause combination is important

    • N clauses N2 ways of combinations or checking to see whether they can be combined

    • Search heuristics are very important in resolution proof procedures

  • Strategies

    • Breadth-First Strategy

    • Set of Support Strategy

    • Unit Preference Strategy

    • Linear Input Form Strategy

Concrete System: Prover9

  • First-Order theorem prover
    • Homepage:
    • Successor of the well known “Otter” theorem prover
    • Under active development, available for several platforms and released under the GPL
    • Graphical user-interface and extensive documentation make Prover 9 comparatively user friendly
  • Core of system builds on resolution / paramodulation as inference method
  • Prover9 works in parallel with external component „Mace4“
    • Mace4 searches for finite models and counterexamples
    • This helps to avoid wasting time searching for a proof by first finding a counterexample

Concrete System: Prover9 Input

Concrete System: Prover9 Proof

Concrete System: Prover9 Options

Limitations of First-OrderTheorem Proving

  • Entailment: KB ⊧ Q
    • Entailment is a relation that is concerned with the semantics of statements
    • Q is entailed by KB (a set of premises or assumptions) if and only if there is no logically possible world in which Q is false while all the premises in KB are true

  • Entailment for FOL is only semi-decidable : If a conclusion follows from premises, then a complete proof system (like resolution) will find a proof.
    • If there’s a proof, we’ll halt with it (eventually)
    • However, If there is no proof (i.e. a statement does not follow from a set of premises), the attempt to prove it may never halt

Limitations of First-OrderTheorem Proving

  • From a practical point of view this is problematic
    • We cannot distinguish between the non-existence of a proof or the failure of an implementation to simply find a proof in reasonable time.
    • Theoretical completeness of an inference procedure does not make a difference in this cases
      • Does a proof simply take too long or will the computation never halt anyway?

  • Due to its complexity and remaining limitations FOL is often not suitable for practical applications

  • Often less expressive (but decideable) formalisms or formalisms with different expressivity are more suitable:
    • Description Logics
    • Logic Programming


Description Logic

  • Most Description Logics are based on a 2-variable fragment of First Order Logic
    • Classes (concepts) correspond to unary predicates
    • Properties correspond to binary predicates
  • Restrictions in general:
    • Quantifiers range over no more than 2 variables
    • Transitive properties are an exception to this rule
    • No function symbols (decidability!)
  • Most DLs are decidable and usually have decision procedures for key reasoning tasks
  • DLs have more efficient decision problems than First Order Logic
  • We later show the very basic DL ALC as example
    • More complex DLs work in the same basic way but have different expressivity

Description Logic Syntax

  • Concepts/classes (unary predicates/formulae with one free variable)

    • E.g. Person, Female

  • Roles (binary predicates/formulae with two free variables)

    • E.g. hasChild

  • Individuals (constants)

    • E.g. Mary, John

  • Constructors allow to form more complex concepts/roles

    • Union ⊔: Man ⊔ Woman

    • Intersection ⊓ : Doctor ⊓ Mother

    • Existential restriction ∃: ∃hasChild.Doctor (some child is a doctor)

    • Value(universal) restriction ∀: ∀hasChild.Doctor (all children are doctors)

    • Complement /negation¬: Man ⊑ ¬Mother

    • Number restriction ≥n, ≤n

  • Axioms

    • Subsumption ⊑ : Mother ⊑ Parent

Description Logic Syntax - Concepts

  • Classes/concepts are actually a set of individuals

  • We can distinguish different types of concepts:

    • Atomic concepts: Cannot be further decomposed (i.e. Person)

    • Incomplete concepts (defined by ⊑)

    • Complete concepts (defined by ≡)

  • Example incomplete concept defintion:

    • Man ⊑ Person ⊓ Male

    • Intended meaning: If an individual is a man, we can conclude that it is a person and male.

    • Man(x) ⇒ Person(x) ∧ Male(x)

  • Example complete concept definition:

    • Man ≡ Person ⊓ Male

    • Intended meaning: Every individual which is a male person is a man, and every man is a male person.

    • Man(x) ⇔ Person(x) ∧ Male(x)

Description Logic Syntax- Roles

  • Roles relate to individuals to each other
    • I.e. directedBy(Pool Sharks, Edwin Middleton), hasChild(Jonny, Sue)

  • Roles have a domain and a range

  • Example:
    • Domain(directedBy, Movie)
    • Range(directedBy, Person)
    • Given the above definitions we can conclude that Pool Sharks is a move and that Edwin Middleton is (was) a person.

  • Functional Roles
    • Roles which have exactly one value
    • Usually used with primitive datavalues
    • A special case of (unqualified) number restriction ≤1 R

Description Logic Syntax- Roles

  • Transitive Roles
    • Example: hasAncestor
      Simple in a rule language: hasAncestor(X,Z) :- hasAncestor(X,Y), hasAncestor(Y,Z).
    • Requires more than one variable!
    • Transitivity can be captured in DLs by role hierarchies and transitive roles:

  • Symmetric Roles
    • Roles which hold in both directions
    • I.e. hasSpouse, hasSibling
  • Inverse Roles
    • Roles are directed, but each role can have an inverse
    • I.e. hasParent ≡ hasChild
      hasChild(X,Y) hasChild(Y,X)

Description Logic Knowledge Bases

  • Typically a DL knowledge base (KB) consists of two components
    • Tbox (terminology): A set of inclusion/equivalence axioms denoting the conceptual schema/vocabulary of a domain
      • Bear ⊑ Animal ⊓ Large
      • transitive(hasAncestor)
      • hasChild ≡ hasParent

    • Abox (assertions): Axioms, which describe concrete instance data and holds assertions about individuals
      • hasAncestor(Susan, Granny)
      • Bear(Winni Puh)

  • From a theoretical point of view this division is arbitrary but it is a useful simplification

A basic Description Logic - ALC

  • Smallest propositionally closed DL is ALC
    • Only atomic roles
    • Concept constructors: ⊔ , ⊓, ¬
    • Restricted use of quantifiers: ∃, ∀

  • “Propositionally closed” Logic in general:
    • Provides (implicitly or explicitly) conjunction, union and negation of class descriptions

  • Example:
    • Person ⊓ ∀hasChild.(Doctor ⊔ ∃hasChild.Doctor)

A basic Description Logic - ALC

  • What can we express in ALC?
  • ALC concept descriptions can be constructed as following:

A basic Description Logic - ALC

  • Individual assertions :
    • a ∈ C
    • Mary is a Woman.

  • Role assertions:
    • 〈a, b〉 ∈ R
    • E.g. Marry loves Peter.

  • Axioms:
    • C ⊑ D
    • C ≡ D, because C ≡ D ⇔ C ⊑ D and D ⊑ C
    • E.g.: A Dog is an animal. A man is a male Person.

The Description Logic Family

  • Description Logics are actually a family of related logics
    • Difference in expressivity and features, as well as complexity of inference
  • Description Logics follow a naming schema according to their features
    • ALC = Attributive Language with Complements
    • S often used for ALC extended with transitive roles
  • Additional letters indicate other extensions, e.g.:
    • H for role hierarchy
    • O for nominals, singleton classes
    • I for inverse roles (e.g., isChildOf ≡ hasChild–)
    • N for number restrictions
    • Q for qualified number restrictions
    • F for functional properties
    • R for limited complex role inclusion axioms, role disjointness
    • (D) for datatype support

Description Logic - Semantics

  • Semantics follow standard FOL model theory

    • Description Logics are a fragment of FOL

  • The vocabulary is the set of names (concepts and roles) used

    • I.e. Mother, Father, Person, knows, isRelatedTo, hasChild, …

  • An interpretation I is a tuple (∆I, ⋅I)

    • I is the domain (a set)

    • I is a mapping that maps:

      • Names of objects (individuals) to elements of the domain

      • Names of unary predicates (classes/concepts) to subsets of the domain

      • Names of binary predicates (properties/roles) to subsets of ∆I x ∆I

Description Logic - Semantics

  • The semantics of DL are based on standard First Order Model theory

  • A translation is usually very straightforward, according to the following correspondences (for ALC):

    • A description is translated to a first-order formula with one free variable

    • An individual assertion is translated to a ground atomic formula

    • An axiom is translated to an implication, closed under universal implication

  • More complex DLs can be handled in a similar way

Description Logic - Semantics

  • Mapping ALC to First Order Logic:

Description Logic - Reasoning

  • Main reasoning tasks for DL systems:

    • Satisfiability : Check if the assertions in a KB have a model

    • Instance checking : Check if an instance belongs to a certain concept

    • Concept satisfiability : Check if the definition of a concept can be satisfied

    • Subsumption : Check if a concept A subsumes a concept B (if every individual of a concept B is also of concept A)

    • Equivalence : A ≡ B ⇔ B ⊑ A and A ⊑ B

    • Retrieval : Retrieve a set of instances that belong to a certain concept

Description Logic - Reasoning

  • Reasoning Task are typically reduced to KB satisfiability sat(A) w.r.t. to a knowledge base A

    • Instance checking : instance(a,C, A) ⇔¬sat(A ⋃ {a: ¬ C})

    • Concept satisfiability : csat(C) ⇔ sat(A ⋃ {a: ¬ C})

    • Concept subsumption : B ⊑ A ⇔ A ⋃ {¬B ⊓ C} is not satisfiable ⇔ ¬sat(A ⋃ {¬B ⊓ C})

    • Retrieval : Instance checking for each instance in the Abox

  • Note: Reduction of reasoning tasks to one another in polynomial time only in propositionally closed logics

  • DL reasoners typically employ tableaux algorithms to check satisfiability of a knowledge base

Concrete System: Pellet

  • Description Logic reasoner
    • Homepage:
    • Written in Java and available from Dual-licensed AGPL license for open-source applications
    • Proprietary license available for commercial applications
  • Sound and complete reasoner aimed at OWL-DL inference based on tableaux procedure
    • Covers all constructs in OWL-DL
    • Supporting major part of OWL 2 specification
  • Integrates with popular toolkits and editors
    • E.g. Jena, Protege, TopBraid Composer
  • Comprehensive hands-on tutorial available:

Concrete System: Pellet

  • Pellet supports expected standard DL reasoning tasks

    • Consistency, classification, realization

    • Conjunctive query answering

    • Concept satisfiability

  • Additionally Pellet supports:

    • SPARQL-DL queries

    • Datatype reasoning

      • User-defined datatypes

      • N-ary datatype predicates

    • Rules support (DL-safe SWRL rules)

    • Explanation and debugging features

      • Axiom pinpointing service

Concrete System: Pellet

  • Explanation & Debugging support

    • Motivation: It is hard to understand large and/or complex ontologies

  • Examples:

    • Why is a specific subclass relation inferred?

    • Why is an ontology inconsistent?

  • Pellet provides axiom pinpointing service:

    • For any inference, returns the (minimal set of) source axioms that cause the inference

  • Applications can track additional provenance information

  • Axiom pinpointing is the first step to explanations

    • Precise justifications (pinpoint parts of axioms) are ongoing work in Pellet‘s developement

Concrete System: Pellet

  • Pellet is integrated in OwlSight and performs classification of loaded ontologies
    • Lightweight , web-based ontology browser:

Concrete System: Pellet

  • Classification Results in the Protege Editor


Logic Programming

  • What is Logic Programming?
  • Various different perspectives and definitions possible:
    • Computations as deduction
      • Use formal logic to express data and programs
    • Theorem Proving
      • Logic programs evaluated by a theorem prover
      • Derivation of answer from a set of initial axioms
    • High level (non-precedural) programming language
      • Logic programs do not specifcy control flow
      • Instead of specifying how something should be computed, one states what should be computed
    • Procedural interpretation of a declarative specification of a problem
      • A LP systems procedurally interprets (in some way) a general declarative statement which only defines truth conditions that should hold

Logic Programming Basics

  • Logic Programming is based on a subset of First Order Logic called Horn Logic

  • Horn Logic can serve as a simple KR formalism and allows to express

    • IF <condition> THEN <result> rules

  • Under certain restrictions reasoning over knowledge bases based on such rules is decideable (in contrast to general ATP within First Order Logic)

Logic Programming Basics – Horn Logic

  • Syntactically a LP rule is a First Order Logic Horn Clause
  • The semantics of LP are different form the standard Tarski style FOL semantics (details later)
    • Herbrand semantics differ from FOL smeantics in the structures it considers to be models (details later)
      → Minimal model semantics
  • A FOL Horn clause is a disjunction of literals with one positive literal, with all variables universally quantified:
    • (∀) ¬C1 ∨ … ∨ ¬Cn ∨ H
  • This can be rewritten to closer correspond to a rule-like form:
    • (∀) C1 ∧ … ∧ Cn → H
  • In LP systems usually the following (non First Order Logic) syntax is used:
    • H :- C1,...,Cn
  • Such rules can be evaluated very efficiently , since the resolution of two Horn clauses is a again a Horn clause

Logic Programming – Syntax

  • The LP vocabulary consists of:
    • Constants: b, cow, “somestring”
    • Predicates: p, loves
    • Function symbols: f, fatherOf
    • Variables: x, y
  • Terms can be:
    • Constants
    • Variables
    • Constructed terms (i.e. function symbol with arguments)
  • Examples:
    • cow, b, Jonny,
    • loves(John)

Logic Programming – Syntax

  • From terms and predicates we can build atoms:
    • For n-ary predicate symbol p and terms t1, ..., tn, p(t1, ..., tn) is an atom
    • A ground atom is an atom without variables
  • Examples:
    • p(x)
    • loves(Jonny, Mary), worksAt(Jonny, SomeCompany)
    • worksAt(loves(Mary), SomeCompany)
  • Literals
    • A literal is a an atom or its negation
    • A positive literal is an atom
    • A negative literal is a negated atom
    • A ground literals is a literal without variables

Logic Programming – Syntax

  • Rules
    • Given a rule of the form H :- B1,...,Bn we call
      • H the head of the rule (its consequent)
      • B1 …. Bn the body of the rule (the antecedent or conditions)
    • The head of the rule consists of one positive literal H
    • The body of the rule consists of a number of literals B1, ..., Bn
    • B1, …, Bn are also called subgoals
  • Examples:
    • parent(x) :- hasChild(x,y)
    • father(x) :- parent(x), male(x)
    • hasAunt(z,y) :- hasSister(x,y), hasChild(x,z)

Logic Programming – Syntax

  • Facts denote assertions about the world:
    • A rule without a body (no conditions)
    • A ground atom
  • Examples:
    • hasChild(Jonny, Sue)
    • Male(Jonny)).
  • Queries allow to ask questions about the knowledge base:
    • Denoted as a rule without a head:
      • ?- B1,...,Bn.
  • Examples:
    • ? - hasSister(Jonny,y), hasChild(Jonny , z) gives all the sisters and children of Jonny
    • ? - hasAunt(Mary,y) gives all the aunts of Mary
    • ?- father(Jonny) ansers if Jonny is a father

Logic Programming – Semantics

  • There are two main approaches to define the semantics of LP
      1. Model theoretic semantics
      2. Computional semanitcs
  • Model-theoretic semantics
    • Defines the meaning of a model in terms of its minimal Herbrand model
  • Computational semantics (proof theoretic semantics)
    • Define the semantics in terms of an evaluation strategy which describes how to compute a model
  • These two semantics are different in style, but agree on the minimal model
  • LP semantics is only equivalent to standard FOL semantics
    • Concerning ground entailment
    • As long as LP is not extended with negation

Logic Programming – Semantics

  • Semantics of LP vs Semantics of FOL
    • Semantics LP defined in terms of minimal Herbrand model
      • Only one minimal model
    • Semantics FOL defined in terms of First-Order models
      • Typically, infinitely many First-Order models
    • The minimal Herbrand model is a First-Order model
    • Every Herbrand model is a First-Order model
    • There exist First-Order models which are not Herbrand models
  • Example:
    • p(a), p(x) → q(x)
    • The Minimal Herbrand model: {p(a), q(a)}
    • This is actually the only Herbrand model!
    • First-Order models: {p(a), q(a)}, {p(a), q(a), p(b)}, etc.

Logic Programming – Semantics

  • Recall:
    • Terms not containing any variables are ground terms
    • Atoms not containing any variables are ground atoms
  • The Herbrand Universe U is the set of all ground terms which can be formed from
    • Constancts in a program
    • Function symbols in a program
  • Example: a, b, c, f(a)
  • The Herbrand Base B is the set of all ground atoms which can be built from
    • Predicate symbols in a program
    • Ground terms from U
  • Example: p(a), q(b), q(f(a))

Logic Programming – Semantics

  • A Herbrand Interpretation I is a subset of the Herbrand Base B for a program

    • The domain of a Herbrand interpretation is the Herbrand Universe U

    • Constants are assigned to themselves

    • Every function symbol is interpreted as the function that applies it

      • If f is an n-ary function symbol (n>0) then the mapping from Un to U defined by (t1, …, tn) → f(t1, …, tn) is assigned to f

Logic Programming – Semantics

  • A Herbrand Model M is a Herbrand Interpretation which makes every formula true, so:
    • Every fact from the program is in M
    • For every rule in the program: If every positive literal in the body is in M, then the literal in the head is also in M
  • The model of a Logic Program P is the minimal Herbrand Model
    • This least Herbrand Model is the intersection of all Herbrand Models
    • Every program has a Herbrand Model. Thus every model also has a minimal Herbrand Model.
    • This model is uniquely defined only for programs without negation
    ⇒ A very intuitive and easy way to capture the semantics of LP
  • As soon as negation is allowed a unique minimal model is not guaranteed anymore

Logic Programming - Negation

  • How do we handle negation in Logic Programs?
  • Horn Logic only permits negation in limited form
    • Consider (∀) ¬C1 ∨ … ∨ ¬Cn ∨ H
  • Special solution: Negation-as-failure (NAF):
    • Whenever a fact is not entailed by the knowledge base, its negation is entailed
    • This is a form of “Default reasoning”
    • This introduces non-monotonic behavior (previous conclusions might need to be revised during the inference process)
  • NAF is not classical negation and pushes LP beyond classical First Order Logic
  • This allows a form of negation in rules:
    • (∀) C1 ∧ … ∧ Ci ∧ not Cn → H
    • H :- B1, … Bi, not Bn

Logic Programming - Negation

  • Logic Programs can also contain recursion

  • Example:
    • ancestor (x,y) :- hasParent(x, y)
    • ancestor(x,z) :- ancestor(x,y), ancestor(y,z).

  • This is a problem as soon as negation is allowed since the minimal model is not uniquely defined anymore

  • It is useful to consider this using a dependency graph
    • A predicate is a node in the graph
    • There is a directed edge between predicates q and p if they occur in a rule where q occurs in the head and p in the body.
    • If the dependency graph contains a cycle then the program is recursive

Logic Programming - Negation

  • As soon as negation is allowed, cycles in a dependency graph become problematic.
      • Example: What is the meaning of win(x) :- not win(x) ?

  • A Solution: Stratification
    • Mark edges with negation in the dependency graph
    • Separate predicates which are connected through a positive edge in a individual stratum
    • Strata can be (partially) ordered
    • If each predicate occurs only in one stratum, then the program is called stratifiable
    • Each stratum can be evaluated as usual and independently from other strata

      → This guarantees a unique interpretation of a Logic Program using negation

Logic Programming - Subsets

  • Classical Logic Programming
    • Allows function symbols
    • Does not allow negation
    • Is turing complete

  • Full Logic Programming is not decideable
    • Prolog programs are not guaranteed to terminate

  • Several ways to guarantee the evaluation of a Logic Program
    • One is to enforce syntactical restrictions
    • This results in subsets of full logic programming
    • Datalog is such a subset

Logic Programming - Datalog

  • Datalog is a syntactic subset of Prolog
    • Originally a rule and query language for deductive databases

  • Considers knowledge bases to have two parts
    • Extensional Database (EDB) consists of facts

    • Intentional Database(IDB) consists of non-ground rules

  • Restrictions:

    1. Datalog disallows function symbols

    2. Imposes stratification restrictions on the use of recursion + negation

    3. Allows only range restricted variables ( safe variables )

  • Safe Variables:
    • Only allows range restricted variables, i.e. each variable in the conclusion of a rule must also appear in a not negated clause in the premise of this rule.
    • This limits evaluation of variables to finitely many possible bindings

Logic Programming - Reasoning Tasks

  • The typical reasoning task for LP systems is query answering
    • Ground queries, i.e. ?- loves(Mary, Joe)
    • Non-ground query, i.e. ?- loves(Mary, x)

  • Non-ground queries can be reduced to a series of ground queries
    • ?- loves(Mary, x)
    • Replace x by every possible value

  • In Logic Programming ground queries are equivalent to entailment of facts
    • Answering ?- loves(Mary, Joe) w.r.t. a knowledge base A is equivalent to checking

      A ⊧ loves(Mary, Joe)

Concrete Logic Programming System: IRIS

  • Java based Datalog reasoner
    • Developed at STI Innsbruck
    • Freely available open source project
    • Homepage:

  • Extensions:
    • Stratified / Well-founded default negation
    • XML Schema data types
    • Various built-in predicates (Equality, inequality, assignment, unification, comparison, type checking, arithmetic, regular expressions,... )

  • Highly modular and includes different reasoning strategies
    • Bottom-up evaluation with Magic Sets optimizations (forward-chaining)
    • Top-down evaluation by SLDNF resolution (backward-chaining)

Concrete Logic Programming System: IRIS

  • An example of a concrete combination of components within IRIS:
    • Program Optimization
      • Rewriting techniques from deductive DB research (e.g. Magic sets rewriting)
    • Safety Processing & Stratification
      • Ensure specific syntactic restrictions
    • Rule Re-ordering
      • Minimize evaluation effort based on dependencies between expressions
    • Rule Optimizations
      • Join condition optimization
      • Literal re-ordering
    • Rule compilation
      • Pre-indexing
      • Creation of „views“ on required parts of information

Concrete Logic Programming System: IRIS

  • Example program (also see online demo at
      isMale(?x) :- man(?x).
      isFemale(?x) :- woman(?x).
      isMale(?y) :- hasSon(?x,?y).
  • Query:
  • Output:
      Init time: 14ms
      Query: ?- isMale(?x). ==>> 2 rows in 1ms
      Variables: ?x

Concrete Logic Programming System: IRIS

  • IRIS performing computations using semi-naiv evaluation in combination with stratification and complex datatypes


Theorem Proving Summary

  • Resolution is a sound and complete inference procedure for First-Order Logic

  • Due to its complexity and remaining limitations FOL is often not suitable for practical applications

  • Often formalisms expressivity and complexity results are more appropriate:

    • Description Logics

    • Logic Programming

Description Logic Summary

  • Description Logics are a syntactic fragment of First Order Logic, based on basic building blocks
    • Concepts
    • Roles
    • Individuals

  • Limited constructs for building complex concepts, roles, etc.
    • Many different Description Logics exist, depending on choice of constructs

  • Inference in Description Logics focuses on consistency checking and classification
    • Main reasoning task: Subsumption
    • Usually reasoning tasks in DLs can all be reduced to satisfiablity checking

  • Efficient Tbox (schema) reasoning
  • ABox reasoning (query answering) do not scale so well

Logic Programming Summary

  • Logic Programming (without negation) is syntactically equivalent to Horn subset of First Order Logic
  • The semantics of a Logic Program are however based on its minimal Herbrand Model

  • Logic Programming comes in various variants for different applications (as programming language, for knowledge representation)
    • Full Logic Programming including function symbols is not decidable
    • Datalog is a syntactic restriction of LP, with desirable computational properties
    • Negation-as-failure introduced non-monotonic behavior and pushes LP beyond the expressivity of First Order Logic

  • A typical inference task for LP engines is conjunctive query answering


References and Further Information

  • Mandatory Reading:
    • Schöning, U., Logic for Computer Scientists (2nd edition), 2008, Birkhäuser
      • Chapter 1 & 2:Normal Forms, Resolution
      • Chapter 3: Horn Logic, Logic Programming
    • Baader, F. et al., The Description Logic Handbook, 2007, Cambridge University Press
      • Chapter 2: Basic Description Logics
  • Further Reading:
    • Lloyd, J.W. , Foundations of logic programming, 1984, Springer
    • Robinson, A. and Voronkov, A. Handbook of Automated Reasoning, Volume I, 2001, MIT Press
      • Chapter 2: Resolution Theorem Proving
    • Ullman, J. D., Principles of Database and Knowledge-Base Systems, Volume I, 1988, Computer Science Press
      • Chapter 3: Logic as a Data Model (Logic Programming & Datalog)
  • Wikipedia links:


Creator: OlliG


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