YES Problem 1: (VAR v_NonEmpty:S x1:S) (RULES a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) ) Problem 1: Dependency Pairs Processor: -> Pairs: A(a(x1:S)) -> A(b(c(a(x1:S)))) A(a(x1:S)) -> B(c(a(x1:S))) A(c(b(x1:S))) -> A(b(a(x1:S))) A(c(b(x1:S))) -> A(x1:S) A(c(b(x1:S))) -> B(a(b(a(x1:S)))) A(c(b(x1:S))) -> B(a(x1:S)) B(x1:S) -> A(c(x1:S)) -> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) Problem 1: SCC Processor: -> Pairs: A(a(x1:S)) -> A(b(c(a(x1:S)))) A(a(x1:S)) -> B(c(a(x1:S))) A(c(b(x1:S))) -> A(b(a(x1:S))) A(c(b(x1:S))) -> A(x1:S) A(c(b(x1:S))) -> B(a(b(a(x1:S)))) A(c(b(x1:S))) -> B(a(x1:S)) B(x1:S) -> A(c(x1:S)) -> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) ->Strongly Connected Components: ->->Cycle: ->->-> Pairs: A(a(x1:S)) -> A(b(c(a(x1:S)))) A(a(x1:S)) -> B(c(a(x1:S))) A(c(b(x1:S))) -> A(b(a(x1:S))) A(c(b(x1:S))) -> A(x1:S) A(c(b(x1:S))) -> B(a(b(a(x1:S)))) A(c(b(x1:S))) -> B(a(x1:S)) B(x1:S) -> A(c(x1:S)) ->->-> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) Problem 1: Reduction Pair Processor: -> Pairs: A(a(x1:S)) -> A(b(c(a(x1:S)))) A(a(x1:S)) -> B(c(a(x1:S))) A(c(b(x1:S))) -> A(b(a(x1:S))) A(c(b(x1:S))) -> A(x1:S) A(c(b(x1:S))) -> B(a(b(a(x1:S)))) A(c(b(x1:S))) -> B(a(x1:S)) B(x1:S) -> A(c(x1:S)) -> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) -> Usable rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) ->Interpretation type: Linear ->Coefficients: Natural Numbers ->Dimension: 2 ->Bound: 1 ->Interpretation: [a](X) = [1 0;1 0].X [b](X) = [0 1;1 0].X + [0;1] [c](X) = [0 1;0 0].X [A](X) = [1 0;1 0].X + [0;1] [B](X) = [0 1;0 1].X + [0;1] Problem 1: SCC Processor: -> Pairs: A(a(x1:S)) -> A(b(c(a(x1:S)))) A(a(x1:S)) -> B(c(a(x1:S))) A(c(b(x1:S))) -> A(x1:S) A(c(b(x1:S))) -> B(a(b(a(x1:S)))) A(c(b(x1:S))) -> B(a(x1:S)) B(x1:S) -> A(c(x1:S)) -> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) ->Strongly Connected Components: ->->Cycle: ->->-> Pairs: A(a(x1:S)) -> A(b(c(a(x1:S)))) A(a(x1:S)) -> B(c(a(x1:S))) A(c(b(x1:S))) -> A(x1:S) A(c(b(x1:S))) -> B(a(b(a(x1:S)))) A(c(b(x1:S))) -> B(a(x1:S)) B(x1:S) -> A(c(x1:S)) ->->-> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) Problem 1: Reduction Pair Processor: -> Pairs: A(a(x1:S)) -> A(b(c(a(x1:S)))) A(a(x1:S)) -> B(c(a(x1:S))) A(c(b(x1:S))) -> A(x1:S) A(c(b(x1:S))) -> B(a(b(a(x1:S)))) A(c(b(x1:S))) -> B(a(x1:S)) B(x1:S) -> A(c(x1:S)) -> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) -> Usable rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) ->Interpretation type: Linear ->Coefficients: Natural Numbers ->Dimension: 2 ->Bound: 1 ->Interpretation: [a](X) = [0 1;0 1].X [b](X) = [0 1;1 0].X + [1;0] [c](X) = [0 0;1 0].X [A](X) = [0 1;0 1].X + [1;1] [B](X) = [1 0;1 0].X + [1;1] Problem 1: SCC Processor: -> Pairs: A(a(x1:S)) -> A(b(c(a(x1:S)))) A(a(x1:S)) -> B(c(a(x1:S))) A(c(b(x1:S))) -> B(a(b(a(x1:S)))) A(c(b(x1:S))) -> B(a(x1:S)) B(x1:S) -> A(c(x1:S)) -> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) ->Strongly Connected Components: ->->Cycle: ->->-> Pairs: A(c(b(x1:S))) -> B(a(b(a(x1:S)))) A(c(b(x1:S))) -> B(a(x1:S)) B(x1:S) -> A(c(x1:S)) ->->-> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) ->->Cycle: ->->-> Pairs: A(a(x1:S)) -> A(b(c(a(x1:S)))) ->->-> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) The problem is decomposed in 2 subproblems. Problem 1.1: Reduction Pair Processor: -> Pairs: A(c(b(x1:S))) -> B(a(b(a(x1:S)))) A(c(b(x1:S))) -> B(a(x1:S)) B(x1:S) -> A(c(x1:S)) -> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) -> Usable rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) ->Interpretation type: Linear ->Coefficients: Natural Numbers ->Dimension: 2 ->Bound: 1 ->Interpretation: [a](X) = [1 0;1 0].X [b](X) = [0 1;1 0].X + [0;1] [c](X) = [0 1;0 0].X [A](X) = [1 0;0 0].X + [1;0] [B](X) = [0 1;0 0].X + [1;0] Problem 1.1: SCC Processor: -> Pairs: A(c(b(x1:S))) -> B(a(x1:S)) B(x1:S) -> A(c(x1:S)) -> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) ->Strongly Connected Components: ->->Cycle: ->->-> Pairs: A(c(b(x1:S))) -> B(a(x1:S)) B(x1:S) -> A(c(x1:S)) ->->-> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) Problem 1.1: Reduction Pair Processor: -> Pairs: A(c(b(x1:S))) -> B(a(x1:S)) B(x1:S) -> A(c(x1:S)) -> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) -> Usable rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) ->Interpretation type: Linear ->Coefficients: Natural Numbers ->Dimension: 2 ->Bound: 1 ->Interpretation: [a](X) = [0 1;0 1].X [b](X) = [0 1;1 0].X + [1;0] [c](X) = [0 0;1 0].X [A](X) = [0 1;0 1].X + [1;1] [B](X) = [1 0;1 0].X + [1;1] Problem 1.1: SCC Processor: -> Pairs: B(x1:S) -> A(c(x1:S)) -> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) ->Strongly Connected Components: There is no strongly connected component The problem is finite. Problem 1.2: Reduction Pair Processor: -> Pairs: A(a(x1:S)) -> A(b(c(a(x1:S)))) -> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) -> Usable rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) ->Interpretation type: Linear ->Coefficients: Natural Numbers ->Dimension: 1 ->Bound: 2 ->Interpretation: [a](X) = 2.X + 2 [b](X) = 1 [c](X) = 0 [A](X) = X Problem 1.2: SCC Processor: -> Pairs: Empty -> Rules: a(a(x1:S)) -> a(b(c(a(x1:S)))) a(c(b(x1:S))) -> b(a(b(a(x1:S)))) b(x1:S) -> c(a(c(x1:S))) ->Strongly Connected Components: There is no strongly connected component The problem is finite.