Tableau algorithm for ALCQ

This is a tableau-based reasoning algorithm for ALCQ description logic, implemented in rust. For information on ALCQ and the corresponding tableau algorithm refer to An Overview of Tableau Algorithms for Description Logics.

Features

• Checking for subsumption and consistency
• Supported expansion rules:
  • "and"-rule expansion
  • "or"-rule expansion
  • "only"-rule expansion (i.e. for a universal quantifier)
  • "some"-rule expansion (i.e. for an existential quantifier)
  • "at-least"-rule expansion
  • "at-most"-rule expansion
  • "choose"-rule expansion
  • GCI expansion
• Parsing from files with a convenient input format
• Conversion to NNF
• (Quite) arbitrary concept/relation names
• Interdependent definitions expansion
• Concept definitions and concept subsumptions in TBox
• Blocking with caring about the order (to prevent cycling blocking)
• It feels fast (but I have not tested it on large datasets)

Installation

To install the library, you should first install rust and cargo. After that, just pull the project and build it with cargo (omit --realease flag if you want to build a debug version, but note that it goes without any optimizations):

git clone https://github.com/universome/dl-reasoner
cd dl-reasoner
cargo build --release

Usage

Note: refer to examples section for more information. For simplicity, below we assume that dl-reasoner executable is located in ./target/release/dl-reasoner (since it is located there by default after running the installation).

Checking consistency

To check for consistency you should run check-consistency subcommand and provide two arguments: a path to a file with ABox axioms and a path to a file with TBox axioms.

./target/release/dl-reasoner check-consistency path-to-abox.txt path-to-tbox.txt

Checking subsumption

To check if a subsumption is valid, you should put the subsumption you want to check into your path-to-tbox.txt file and run check-subsumption subcommand:

./target/release/dl-reasoner check-subsumption path-to-tbox.txt

Input format

Note: refer to examples for more details.

Concept format

ABox and TBox files share the same concept format. Concepts have the following format:

• atomic concept: ConceptName
• conjunction: and (ConceptA ConceptB ConceptC <...etc...>)
• disjunction: or (ConceptA ConceptB ConceptC <...etc...>)
• negation: not Concept
• universal quantifier: only relationName Concept
• existential quantifier: some relationName Concept
• at-least concept: >= 123 relationName Concept
• at-most concept: <= 123 relationName Concept

You can aggregate nested concepts with the format above. For example:

and (IsStudent (<= 2 isChildOf IsProfessor) IsHuman)

Notes:

• if you use non-atomic concepts somewhere (like (<= 2 isChildOf IsProfessor) in the example above), you must wrap them into brackets!
• Top concept has name __TOP__

ABox concept axiom format

Concept axioms are based on the concept format and have the format MyConcept[x]. This implies that concept MyConcept is appled to individual x. You can have a compound concept axiom, like (>= 123 myRelation (and (A B C)))[x].

ABox relation axiom format

Relation axiom is the simplest one. It has the format relationName[x,y] and means that we have a relation relationName between individuals x and y.

TBox definition format

Definition in a TBox has the format ConceptName == SomeConceptDefinition.

TBox inclusion format

Definition in a TBox has the format SomeConceptA -> SomeConceptB.

Examples

Checking consistency

Example 1

Imagine, that we have the following ABox:

ABox = {hasChild(joe,ann), hasChild(joe,eva), hasChild(joe,mary), ParentWithMax2Children(joe)}

with respect to TBox:

TBox = {ParentWithMax2Children ≡≤ 2HasChild.⊤}

We want to check our ABox for consistency and find a corresponding model (if such exists). For this, we convert ABox in a way that is described in input format section:

hasChild[joe, ann]
hasChild[joe, eva]
hasChild[joe, mary]
ParentWithMax2Children[joe]

And we write TBox as:

ParentWithMax2Children == (<= 2 hasChild __TOP__)

After that we run the reasoner with check-consistency command:

./target/release/dl-reasoner check-consistency examples/find-model-1/abox.txt examples/find-model-1/tbox.txt

This finds a model for us:

[INFO] Expanding TBox definitions...
[INFO] Applying expanded TBox definitions to an ABox...
[INFO] Applying expanded TBox definitions to GCIs...
[INFO] Aggregating GCIs into a single one...
[INFO] Found a model!
[INFO] Model:
 - Individuals: mary, joe, ann
 - Concepts:
 - Relations: hasChild(joe, ann), hasChild(joe, mary)
 - Replacements: eva = mary
[INFO] Running time: 1.412092ms

As one can see, we did replacement "eva -> mary" which made our ABox consistent. Corresponding abox.txt and tbox.txt are located in examples/find-model-1 directory.

Example 2

Imagine now, that we are given the following ABox and TBox:

ABox = {r(a,b), r(b,d), r(d,c), r(a,c), r(c,d), A(d)}
TBox = {}

And we want to check if individual a an instance of the concept:

∃r.((A ⊓ ∃r.A) ⊔ (¬A ⊓ ∃r.∃r.¬A))

For this, we extend our ABox with the concept axiom:

ABox = ABox ∪ {(∃r.((A ⊓ ∃r.A) ⊔ (¬A ⊓ ∃r.∃r.¬A)))(a)}

and check it for consistency. Corresponding abox.txt and tbox.txt are provided in examples/find-model-2 directory. Running check-consistency command

./target/release/dl-reasoner check-consistency examples/find-model-1/abox.txt examples/find-model-1/tbox.txt

gives output:

[INFO] Expanding TBox definitions...
[INFO] Applying expanded TBox definitions to an ABox...
[INFO] Applying expanded TBox definitions to GCIs...
[INFO] Aggregating GCIs into a single one...
[INFO] No model was found.
[INFO] Running time: 5.080364ms

Which means that a is not an instance of that concept.

Checking subsumption

In the examples below we will assume that our "real" TBox is empty. If you want ot use a non-empty one, then you should add the relevant definitions and negated GCIs into the same tbox.txt file with your subsumption (sorry for that).

Example 1

Imagine, that we want to check consistency of the following subsumption with respect to an empty TBox:

∀r.∀s.A ⊓ ∃r.∀s.B ⊓ ∀r.∃s.C ⊑ ∃r.∃s.(A ⊓ B ⊓ C)

Again, we write tbox.txt the following way (as described in input format section):

(and ((only r (only s A)) (some r (only s B)) (only r (some s C)))) -> some r (some s (and (A B C)))

and then we run the reasoner with check-subsumption command:

./target/release/dl-reasoner check-subsumption examples/subsumption-1/tbox.txt

Our reasoner has successfully checked the subsumption:

[INFO] Expanding TBox definitions...
[INFO] Applying expanded TBox definitions to GCIs...
[INFO] Aggregating GCIs into a single one...
[INFO] Subsumption is valid.
[INFO] Running time: 2.881441ms

Example 2

We want to check the following subsumption:

∀r.∀s.A ⊓ (∃r.∀s.¬A ⊔ ∀r.∃s.B) ⊑ ∀r.∃s.(A ⊓ B) ⊔ ∃r.∀s.¬B

Adding missing brackets and translating it to the format that is suitable for parsing, we get the following tbox.txt:

and ((only r (only s A)) (or ((some r (only s not A)) (only r (some s B))))) -> or ((only r (some s (and (A B)))) (some r (only s (not B))))

Now, we can run the reasoning:

./target/release/dl-reasoner check-subsumption examples/subsumption-2/tbox.txt

In this example, the provided subsumption is also valid and we get the output:

[INFO] Expanding TBox definitions...
[INFO] Applying expanded TBox definitions to GCIs...
[INFO] Aggregating GCIs into a single one...
[INFO] Subsumption is valid.
[INFO] Running time: 7.958508ms

As one can noted, all these examples ran in under 10ms which I suppose is quite fast.

TODO

• tests
• print error messages instead of just panicking
• remove unnecessary heap allocations
• backtracking