Rationals

Value Members

1. final def !=(arg0: Any): Boolean

   

   Definition Classes

   AnyRef → Any

2. final def ##(): Int

   

   Definition Classes

   AnyRef → Any

3. final def ==(arg0: Any): Boolean

   

   Definition Classes

   AnyRef → Any

4. object Fraction

   

   Extractor for fractions, where numerator and denominator are expressions from the underlying ring

   Extractor for fractions, where numerator and denominator are expressions from the underlying ring

   Definition Classes

   Fractions

5. object FractionSort extends ProxySort

   

   Definition Classes

   Fractions

6. def additiveGroup: Group with Abelian with SymbolicTimes

   

   Addition gives rise to an Abelian group

   Addition gives rise to an Abelian group

   Definition Classes

   PseudoRing

7. final def asInstanceOf[T0]: T0

   

   Definition Classes

   Any

8. val axioms: Formula

   

   Axioms defining the theory; such axioms are simply added as formulae to the problem to be proven, and thus handled using the standard reasoning techniques (including e-matching).

   Axioms defining the theory; such axioms are simply added as formulae to the problem to be proven, and thus handled using the standard reasoning techniques (including e-matching).

   Definition Classes

   Fractions → Theory

9. def clone(): AnyRef

   

   Attributes

   protected[java.lang]

   Definition Classes

   AnyRef

   Annotations

   @throws( ... )

10. val denom: IFunction

    

    Function used internally to represent the unique denominator for all fractions

    Function used internally to represent the unique denominator for all fractions

    Definition Classes

    Fractions

11. val dependencies: List[nia.GroebnerMultiplication.type]

    

    Optionally, other theories that this theory depends on.

    Optionally, other theories that this theory depends on. Specified dependencies will be loaded before this theory, but the preprocessors of the dependencies will be called after the preprocessor of this theory.

    Definition Classes

    Rationals → Theory

12. def div(s: ITerm, t: ITerm): ITerm

    

    Division operation

    Division operation

    Definition Classes

    Fractions → RingWithDivision

13. val dom: Sort

    

    Domain of the ring

    Domain of the ring

    Definition Classes

    Fractions → PseudoRing

14. final def eq(arg0: AnyRef): Boolean

    

    Definition Classes

    AnyRef

15. def equals(arg0: Any): Boolean

    

    Definition Classes

    AnyRef → Any

16. def evalFun(f: IFunApp): Option[ITerm]

    

    Optionally, a function evaluating theory functions applied to concrete arguments, represented as constructor terms.

    Optionally, a function evaluating theory functions applied to concrete arguments, represented as constructor terms.

    Definition Classes

    Theory

17. def evalPred(p: IAtom): Option[Boolean]

    

    Optionally, a function evaluating theory predicates applied to concrete arguments, represented as constructor terms.

    Optionally, a function evaluating theory predicates applied to concrete arguments, represented as constructor terms.

    Definition Classes

    Theory

18. def extend(order: TermOrder): TermOrder

    

    Add the symbols defined by this theory to the order

    Add the symbols defined by this theory to the order

    Definition Classes

    Theory

19. def finalize(): Unit

    

    Attributes

    protected[java.lang]

    Definition Classes

    AnyRef

    Annotations

    @throws( classOf[java.lang.Throwable] )

20. val frac: IFunction

    

    Function to represent fractions, where numerator and denominator are expressions from the underlying ring

    Function to represent fractions, where numerator and denominator are expressions from the underlying ring

    Definition Classes

    Fractions

21. val functionPredicateMapping: List[(IFunction, Predicate)]

    

    Mapping of interpreted functions to interpreted predicates, used translating input ASTs to internal ASTs (the latter only containing predicates).

    Mapping of interpreted functions to interpreted predicates, used translating input ASTs to internal ASTs (the latter only containing predicates).

    Definition Classes

    Fractions → Theory

22. val functionalPredicates: Set[Predicate]

    

    Information which of the predicates satisfy the functionality axiom; at some internal points, such predicates can be handled more efficiently

    Information which of the predicates satisfy the functionality axiom; at some internal points, such predicates can be handled more efficiently

    Definition Classes

    Fractions → Theory

23. val functions: List[IFunction]

    

    Interpreted functions of the theory

    Interpreted functions of the theory

    Definition Classes

    Fractions → Theory

24. def generateDecoderData(model: Conjunction): Option[TheoryDecoderData]

    

    If this theory defines any Theory.Decoder, which can translate model data into some theory-specific representation, this function can be overridden to pre-compute required data from a model.

    If this theory defines any Theory.Decoder, which can translate model data into some theory-specific representation, this function can be overridden to pre-compute required data from a model.

    Definition Classes

    Theory

25. def geq(s: ITerm, t: ITerm): IFormula

    

    Greater-than-or-equal operator

    Greater-than-or-equal operator

    Definition Classes

    RingWithOrder

26. final def getClass(): Class[_]

    

    Definition Classes

    AnyRef → Any

27. def gt(s: ITerm, t: ITerm): IFormula

    

    Greater-than operator

    Greater-than operator

    Definition Classes

    RingWithOrder

28. def hashCode(): Int

    

    Definition Classes

    AnyRef → Any

29. def iPostprocess(f: IFormula, signature: Signature): IFormula

    

    Optionally, a post-processor that is applied to formulas output by the prover, for instance to interpolants or the result of quantifier elimination.

    Optionally, a post-processor that is applied to formulas output by the prover, for instance to interpolants or the result of quantifier elimination. This method will be applied to the formula after calling Internal2Inputabsy.

    Definition Classes

    Theory

30. def iPreprocess(f: IFormula, signature: Signature): (IFormula, Signature)

    

    Optionally, a pre-processor that is applied to formulas over this theory, prior to sending the formula to a prover.

    Optionally, a pre-processor that is applied to formulas over this theory, prior to sending the formula to a prover. This method will be applied very early in the translation process.

    Definition Classes

    Fractions → Theory

31. def individualsStream: Option[Stream[ITerm]]

    

    Optionally, a stream of the constructor terms for this domain can be defined (e.g., the fractions with co-prime numerator and denominator).

    Optionally, a stream of the constructor terms for this domain can be defined (e.g., the fractions with co-prime numerator and denominator).

    Attributes

    protected

    Definition Classes

    Rationals → Fractions

32. val int: IFunction

    

    Function to embed integers in the ring of fractions

    Function to embed integers in the ring of fractions

    Definition Classes

    Fractions

33. def int2ring(s: ITerm): ITerm

    

    Conversion of an integer term to a ring term

    Conversion of an integer term to a ring term

    Definition Classes

    Fractions → PseudoRing

34. def inverse(s: ITerm): ITerm

    

    Definition Classes

    Field

35. final def isInstanceOf[T0]: Boolean

    

    Definition Classes

    Any

36. def isInt(s: ITerm): IFormula

    

    Test whether a rational is integer.

    Test whether a rational is integer.

    Definition Classes

    Rationals → RingWithIntConversions

37. def isSoundForSat(theories: Seq[Theory], config: Theory.SatSoundnessConfig.Value): Boolean

    

    Check whether we can tell that the given combination of theories is sound for checking satisfiability of a problem, i.e., if proof construction ends up in a dead end, can it be concluded that a problem is satisfiable.

    Check whether we can tell that the given combination of theories is sound for checking satisfiability of a problem, i.e., if proof construction ends up in a dead end, can it be concluded that a problem is satisfiable.

    Definition Classes

    Fractions → Theory

38. def leq(s: ITerm, t: ITerm): IFormula

    

    Less-than-or-equal operator

    Less-than-or-equal operator

    Definition Classes

    Rationals → RingWithOrder

39. def lt(s: ITerm, t: ITerm): IFormula

    

    Less-than operator

    Less-than operator

    Definition Classes

    Rationals → RingWithOrder

40. def minus(s: ITerm): ITerm

    

    Additive inverses

    Additive inverses

    Definition Classes

    Fractions → PseudoRing

41. def minus(s: ITerm, t: ITerm): ITerm

    

    Difference between two terms

    Difference between two terms

    Definition Classes

    PseudoRing

42. def mul(s: ITerm, t: ITerm): ITerm

    

    Ring multiplication

    Ring multiplication

    Definition Classes

    Fractions → PseudoRing

43. def multiplicativeGroup: Group with Abelian

    

    Non-zero elements now give rise to an Abelian group

    Non-zero elements now give rise to an Abelian group

    Definition Classes

    Field

44. def multiplicativeMonoid: Monoid with Abelian

    

    Multiplication gives rise to an Abelian monoid

    Multiplication gives rise to an Abelian monoid

    Definition Classes

    CommutativeRing → Ring

45. final def ne(arg0: AnyRef): Boolean

    

    Definition Classes

    AnyRef

46. final def notify(): Unit

    

    Definition Classes

    AnyRef

47. final def notifyAll(): Unit

    

    Definition Classes

    AnyRef

48. val one: ITerm

    

    The one element of this ring

    The one element of this ring

    Definition Classes

    Fractions → PseudoRing

49. val plugin: None.type

    

    Optionally, a plug-in implementing reasoning in this theory

    Optionally, a plug-in implementing reasoning in this theory

    Definition Classes

    Fractions → Theory

50. def plus(s: ITerm, t: ITerm): ITerm

    

    Ring addition

    Ring addition

    Definition Classes

    Fractions → PseudoRing

51. def postSimplifiers: Seq[(IExpression) ⇒ IExpression]

    

    Optionally, simplifiers that are applied to formulas output by the prover, for instance to interpolants or the result of quantifier.

    Optionally, simplifiers that are applied to formulas output by the prover, for instance to interpolants or the result of quantifier. Such simplifiers are invoked by with ap.parser.Simplifier.

    Definition Classes

    Theory

52. def postprocess(f: Conjunction, order: TermOrder): Conjunction

    

    Optionally, a post-processor that is applied to formulas output by the prover, for instance to interpolants or the result of quantifier elimination.

    Optionally, a post-processor that is applied to formulas output by the prover, for instance to interpolants or the result of quantifier elimination. This method will be applied to the raw formulas, before calling Internal2Inputabsy.

    Definition Classes

    Theory

53. val predicateMatchConfig: PredicateMatchConfig

    

    Information how interpreted predicates should be handled for e-matching.

    Information how interpreted predicates should be handled for e-matching.

    Definition Classes

    Fractions → Theory

54. val predicates: Seq[Predicate]

    

    Interpreted predicates of the theory

    Interpreted predicates of the theory

    Definition Classes

    Fractions → Theory

55. def preprocess(f: Conjunction, order: TermOrder): Conjunction

    

    Optionally, a pre-processor that is applied to formulas over this theory, prior to sending the formula to a prover.

    Optionally, a pre-processor that is applied to formulas over this theory, prior to sending the formula to a prover.

    Definition Classes

    Theory

56. def product(terms: ITerm*): ITerm

    

    N-ary sums

    N-ary sums

    Definition Classes

    PseudoRing

57. val reducerPlugin: ReducerPluginFactory

    

    Optionally, a plugin for the reducer applied to formulas both before and during proving.

    Optionally, a plugin for the reducer applied to formulas both before and during proving.

    Definition Classes

    Theory

58. def ring2int(s: ITerm): ITerm

    

    Conversion of a rational term to an integer term, the floor operator.

    Conversion of a rational term to an integer term, the floor operator.

    Definition Classes

    Rationals → RingWithIntConversions

59. def simplifyFraction(n: ITerm, d: ITerm): (ITerm, ITerm)

    

    Method that can be overwritten in sub-classes to term concrete fractions into canonical form.

    Method that can be overwritten in sub-classes to term concrete fractions into canonical form.

    Attributes

    protected

    Definition Classes

    Rationals → Fractions

60. val singleInstantiationPredicates: Set[Predicate]

    

    When instantiating existentially quantifier formulas, EX phi, at most one instantiation is necessary provided that all predicates in phi are contained in this set.

    When instantiating existentially quantifier formulas, EX phi, at most one instantiation is necessary provided that all predicates in phi are contained in this set.

    Definition Classes

    Theory

61. def summation(terms: ITerm*): ITerm

    

    N-ary sums

    N-ary sums

    Definition Classes

    PseudoRing

62. final def synchronized[T0](arg0: ⇒ T0): T0

    

    Definition Classes

    AnyRef

63. def times(num: IdealInt, s: ITerm): ITerm

    

    num * s

    num * s

    Definition Classes

    Fractions → PseudoRing

64. def toString(): String

    

    Definition Classes

    Fractions → PseudoRing → AnyRef → Any

65. val totalityAxioms: Conjunction

    

    Additional axioms that are included if the option +genTotalityAxioms is given to Princess.

    Additional axioms that are included if the option +genTotalityAxioms is given to Princess.

    Definition Classes

    Fractions → Theory

66. val triggerRelevantFunctions: Set[IFunction]

    

    A list of functions that should be considered in automatic trigger generation

    A list of functions that should be considered in automatic trigger generation

    Definition Classes

    Fractions → Theory

67. final def wait(): Unit

    

    Definition Classes

    AnyRef

    Annotations

    @throws( ... )

68. final def wait(arg0: Long, arg1: Int): Unit

    

    Definition Classes

    AnyRef

    Annotations

    @throws( ... )

69. final def wait(arg0: Long): Unit

    

    Definition Classes

    AnyRef

    Annotations

    @throws( ... )

70. val zero: ITerm

    

    The zero element of this ring

    The zero element of this ring

    Definition Classes

    Fractions → PseudoRing