Bomba is an Answer Set Programming dialect in the form of a Scala DSL. It is intended, currently, as a prototype to experiment with possible syntax and semantic variants, as well as language integration.
- If your build system is m2-compatible, you can now get bomba directly out of Central.
Just add it to your dependencies:
- SBT:
libraryDependencies += org.bomba-lang % bomba % 0.3.1
- Maven:
<dependency> <groupId>org.bomba-lang</groupId> <artifactId>bomba</artifactId> <version>0.3.1</version> </dependency>
- Otherwise:
mvn clean package- Add the resulting JAR to the build path of your project.
- Add:
to your Scala import statements.
import org.bomba_lang.proto._
- IMPORTANT: add the
macro-paradisecompiler plugin to your Maven/SBT build - as described in the macro documentation.
The syntax is similar to other Answer Set Programming dialects.
A literal is of the form
name(x1,...,xn)
-name(x1,...,xn)where n >= 0 (if n=0, the parenthesis are optional), and x1,...,xn are of the type Any. - means "strong negation".
An xm (1 <= m <= n) of type Symbol (e.g. 'X ), is a variable.
A rule is of the form
hP1 v ... v hPl :- bP1 & ... & bPm & ~nbP1 & ... & ~nbPn
hP1 ∨ ... ∨ hPl ⟵ bP1 ∧ ... ∧ bPm ∧ ~nbP1 ∧ ... ∧ ~nbPnwhere hP1,...,hPl, bP1,...,bPm, nbP1,...,nbPn are literals. ~ means "default negation".
A special subtype of rules are constraints - rules with an empty head, i.e.:
Nil :- bP1 & ... & bPm & ~nbP1 & ... & ~nbPn
⊥ ⟵ bP1 ∧ ... ∧ bPm ∧ ~nbP1 ∧ ... ∧ ~nbPnTheir intuitive meaning is: "this should never happen"/"if this rule fires, then the answer is invalid".
A program is a Scala code block of the form
@bomba
val progName = {
r1
...
rn
}where r1,...,rn are rules. Note that:
- the rules are treated as standard Scala expressions, i.e. they must be either in
separate lines, or separated with
;when on the same line. - the names of the literals "shadow" any nameds (
vals,defs, etc.) in the program's local scope. An exception isNilfor constraints (see above).
Note: yes, this means you can use Unicode symbols for logical operators in your program!
Semantics depend on the solver used. The current reference implementation, org.bomba_lang.proto.NaiveSolver, uses standard
disjunctive semantics, with the Ferrari and Lifschitz resolution variant for strong negation. To generate all answer sets, use:
program.solveThe idiomatic way of interfacing your logic programs with the rest of your code is to define your "oracle" program, and then inject the data you wish to provide in the solve method, e.g.:
@bomba
val oracle = {...}
@bomba
val data = {...}
oracle.solve(data)Here's the source from the main class of the demo project, to give you an idea of the syntax and semantics:
package org.bomba_lang.bomba_demo
import org.bomba_lang.proto._
object Demo {
def main(args: Array[String]): Unit = {
@bomba
val prog1 = { z(1, 2) }
println(prog1)
@bomba
val prog2 = {
y v z
}
println(prog2.solve)
@bomba
val prog3 = {
rain :- wet
wet
}
println(prog3.solve)
println("canonical program extension")
@bomba
val r0 = {
rain :- wet
}
println(r0.solve)
@bomba
val r1 = {
wet
}
println(r0.solve(r1))
println("-------------------")
println("canonical program extension with default negation")
@bomba
val rn0 = {
rain :- wet & ~sprinkler
}
println(r0.solve)
@bomba
val rn1 = {
wet
}
println(rn0.solve(rn1))
@bomba
val rn2 = {
wet
sprinkler
}
println(rn0.solve(rn2))
println("-------------------")
println("variables")
@bomba
val varProg = {
x(1)
y(2)
z('X, 'Y) :- x('X) & y('Y)
}
println("Ungrounded: " + varProg)
val varProgGround = new GroundProgram(varProg)
println("Grounded: " + varProgGround)
println("Result: " + varProgGround.solve)
println("-------------------")
println("Constraints")
@bomba
val constProg = {
x
Nil :- x
}
println(constProg)
println(constProg.solve) //empty set (*no* answer sets)
println("-------------------")
println("\"Formal\" notation")
@bomba
val formalProg = {
a ∨ b ⟵ x ∧ y ∧ z
⊥ ⟵ z ∧ d
}
println(formalProg)
}
}All welcome.