WORST_CASE(?,O(n^2)) * Step 1: InnermostRuleRemoval WORST_CASE(?,O(n^2)) + Considered Problem: - Strict TRS: 0() -> n__0() U11(tt(),N) -> activate(N) U21(tt(),M,N) -> s(plus(activate(N),activate(M))) U31(tt()) -> 0() U41(tt(),M,N) -> plus(x(activate(N),activate(M)),activate(N)) activate(X) -> X activate(n__0()) -> 0() activate(n__isNat(X)) -> isNat(X) activate(n__plus(X1,X2)) -> plus(activate(X1),activate(X2)) activate(n__s(X)) -> s(activate(X)) activate(n__x(X1,X2)) -> x(activate(X1),activate(X2)) and(tt(),X) -> activate(X) isNat(X) -> n__isNat(X) isNat(n__0()) -> tt() isNat(n__plus(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) -> isNat(activate(V1)) isNat(n__x(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) plus(N,0()) -> U11(isNat(N),N) plus(N,s(M)) -> U21(and(isNat(M),n__isNat(N)),M,N) plus(X1,X2) -> n__plus(X1,X2) s(X) -> n__s(X) x(N,0()) -> U31(isNat(N)) x(N,s(M)) -> U41(and(isNat(M),n__isNat(N)),M,N) x(X1,X2) -> n__x(X1,X2) - Signature: {0/0,U11/2,U21/3,U31/1,U41/3,activate/1,and/2,isNat/1,plus/2,s/1,x/2} / {n__0/0,n__isNat/1,n__plus/2,n__s/1 ,n__x/2,tt/0} - Obligation: innermost runtime complexity wrt. defined symbols {0,U11,U21,U31,U41,activate,and,isNat,plus,s ,x} and constructors {n__0,n__isNat,n__plus,n__s,n__x,tt} + Applied Processor: InnermostRuleRemoval + Details: Arguments of following rules are not normal-forms. plus(N,0()) -> U11(isNat(N),N) plus(N,s(M)) -> U21(and(isNat(M),n__isNat(N)),M,N) x(N,0()) -> U31(isNat(N)) x(N,s(M)) -> U41(and(isNat(M),n__isNat(N)),M,N) All above mentioned rules can be savely removed. * Step 2: WeightGap WORST_CASE(?,O(n^2)) + Considered Problem: - Strict TRS: 0() -> n__0() U11(tt(),N) -> activate(N) U21(tt(),M,N) -> s(plus(activate(N),activate(M))) U31(tt()) -> 0() U41(tt(),M,N) -> plus(x(activate(N),activate(M)),activate(N)) activate(X) -> X activate(n__0()) -> 0() activate(n__isNat(X)) -> isNat(X) activate(n__plus(X1,X2)) -> plus(activate(X1),activate(X2)) activate(n__s(X)) -> s(activate(X)) activate(n__x(X1,X2)) -> x(activate(X1),activate(X2)) and(tt(),X) -> activate(X) isNat(X) -> n__isNat(X) isNat(n__0()) -> tt() isNat(n__plus(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) -> isNat(activate(V1)) isNat(n__x(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) -> n__plus(X1,X2) s(X) -> n__s(X) x(X1,X2) -> n__x(X1,X2) - Signature: {0/0,U11/2,U21/3,U31/1,U41/3,activate/1,and/2,isNat/1,plus/2,s/1,x/2} / {n__0/0,n__isNat/1,n__plus/2,n__s/1 ,n__x/2,tt/0} - Obligation: innermost runtime complexity wrt. defined symbols {0,U11,U21,U31,U41,activate,and,isNat,plus,s ,x} and constructors {n__0,n__isNat,n__plus,n__s,n__x,tt} + Applied Processor: WeightGap {wgDimension = 1, wgDegree = 1, wgKind = Algebraic, wgUArgs = UArgs, wgOn = WgOnAny} + Details: The weightgap principle applies using the following nonconstant growth matrix-interpretation: We apply a matrix interpretation of kind constructor based matrix interpretation: The following argument positions are considered usable: uargs(and) = {1,2}, uargs(isNat) = {1}, uargs(n__isNat) = {1}, uargs(plus) = {1,2}, uargs(s) = {1}, uargs(x) = {1,2} Following symbols are considered usable: all TcT has computed the following interpretation: p(0) = [0] p(U11) = [1] x2 + [0] p(U21) = [1] x2 + [1] x3 + [0] p(U31) = [0] p(U41) = [1] x2 + [2] x3 + [0] p(activate) = [1] x1 + [0] p(and) = [1] x1 + [1] x2 + [0] p(isNat) = [1] x1 + [0] p(n__0) = [0] p(n__isNat) = [1] x1 + [0] p(n__plus) = [1] x1 + [1] x2 + [0] p(n__s) = [1] x1 + [0] p(n__x) = [1] x1 + [1] x2 + [0] p(plus) = [1] x1 + [1] x2 + [3] p(s) = [1] x1 + [0] p(tt) = [0] p(x) = [1] x1 + [1] x2 + [1] Following rules are strictly oriented: plus(X1,X2) = [1] X1 + [1] X2 + [3] > [1] X1 + [1] X2 + [0] = n__plus(X1,X2) x(X1,X2) = [1] X1 + [1] X2 + [1] > [1] X1 + [1] X2 + [0] = n__x(X1,X2) Following rules are (at-least) weakly oriented: 0() = [0] >= [0] = n__0() U11(tt(),N) = [1] N + [0] >= [1] N + [0] = activate(N) U21(tt(),M,N) = [1] M + [1] N + [0] >= [1] M + [1] N + [3] = s(plus(activate(N),activate(M))) U31(tt()) = [0] >= [0] = 0() U41(tt(),M,N) = [1] M + [2] N + [0] >= [1] M + [2] N + [4] = plus(x(activate(N),activate(M)),activate(N)) activate(X) = [1] X + [0] >= [1] X + [0] = X activate(n__0()) = [0] >= [0] = 0() activate(n__isNat(X)) = [1] X + [0] >= [1] X + [0] = isNat(X) activate(n__plus(X1,X2)) = [1] X1 + [1] X2 + [0] >= [1] X1 + [1] X2 + [3] = plus(activate(X1),activate(X2)) activate(n__s(X)) = [1] X + [0] >= [1] X + [0] = s(activate(X)) activate(n__x(X1,X2)) = [1] X1 + [1] X2 + [0] >= [1] X1 + [1] X2 + [1] = x(activate(X1),activate(X2)) and(tt(),X) = [1] X + [0] >= [1] X + [0] = activate(X) isNat(X) = [1] X + [0] >= [1] X + [0] = n__isNat(X) isNat(n__0()) = [0] >= [0] = tt() isNat(n__plus(V1,V2)) = [1] V1 + [1] V2 + [0] >= [1] V1 + [1] V2 + [0] = and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) = [1] V1 + [0] >= [1] V1 + [0] = isNat(activate(V1)) isNat(n__x(V1,V2)) = [1] V1 + [1] V2 + [0] >= [1] V1 + [1] V2 + [0] = and(isNat(activate(V1)),n__isNat(activate(V2))) s(X) = [1] X + [0] >= [1] X + [0] = n__s(X) Further, it can be verified that all rules not oriented are covered by the weightgap condition. * Step 3: WeightGap WORST_CASE(?,O(n^2)) + Considered Problem: - Strict TRS: 0() -> n__0() U11(tt(),N) -> activate(N) U21(tt(),M,N) -> s(plus(activate(N),activate(M))) U31(tt()) -> 0() U41(tt(),M,N) -> plus(x(activate(N),activate(M)),activate(N)) activate(X) -> X activate(n__0()) -> 0() activate(n__isNat(X)) -> isNat(X) activate(n__plus(X1,X2)) -> plus(activate(X1),activate(X2)) activate(n__s(X)) -> s(activate(X)) activate(n__x(X1,X2)) -> x(activate(X1),activate(X2)) and(tt(),X) -> activate(X) isNat(X) -> n__isNat(X) isNat(n__0()) -> tt() isNat(n__plus(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) -> isNat(activate(V1)) isNat(n__x(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) s(X) -> n__s(X) - Weak TRS: plus(X1,X2) -> n__plus(X1,X2) x(X1,X2) -> n__x(X1,X2) - Signature: {0/0,U11/2,U21/3,U31/1,U41/3,activate/1,and/2,isNat/1,plus/2,s/1,x/2} / {n__0/0,n__isNat/1,n__plus/2,n__s/1 ,n__x/2,tt/0} - Obligation: innermost runtime complexity wrt. defined symbols {0,U11,U21,U31,U41,activate,and,isNat,plus,s ,x} and constructors {n__0,n__isNat,n__plus,n__s,n__x,tt} + Applied Processor: WeightGap {wgDimension = 1, wgDegree = 1, wgKind = Algebraic, wgUArgs = UArgs, wgOn = WgOnAny} + Details: The weightgap principle applies using the following nonconstant growth matrix-interpretation: We apply a matrix interpretation of kind constructor based matrix interpretation: The following argument positions are considered usable: uargs(and) = {1,2}, uargs(isNat) = {1}, uargs(n__isNat) = {1}, uargs(plus) = {1,2}, uargs(s) = {1}, uargs(x) = {1,2} Following symbols are considered usable: all TcT has computed the following interpretation: p(0) = [0] p(U11) = [1] x2 + [0] p(U21) = [1] x2 + [1] x3 + [0] p(U31) = [0] p(U41) = [1] x2 + [2] x3 + [0] p(activate) = [1] x1 + [0] p(and) = [1] x1 + [1] x2 + [3] p(isNat) = [1] x1 + [0] p(n__0) = [0] p(n__isNat) = [1] x1 + [0] p(n__plus) = [1] x1 + [1] x2 + [1] p(n__s) = [1] x1 + [0] p(n__x) = [1] x1 + [1] x2 + [0] p(plus) = [1] x1 + [1] x2 + [1] p(s) = [1] x1 + [5] p(tt) = [0] p(x) = [1] x1 + [1] x2 + [0] Following rules are strictly oriented: and(tt(),X) = [1] X + [3] > [1] X + [0] = activate(X) s(X) = [1] X + [5] > [1] X + [0] = n__s(X) Following rules are (at-least) weakly oriented: 0() = [0] >= [0] = n__0() U11(tt(),N) = [1] N + [0] >= [1] N + [0] = activate(N) U21(tt(),M,N) = [1] M + [1] N + [0] >= [1] M + [1] N + [6] = s(plus(activate(N),activate(M))) U31(tt()) = [0] >= [0] = 0() U41(tt(),M,N) = [1] M + [2] N + [0] >= [1] M + [2] N + [1] = plus(x(activate(N),activate(M)),activate(N)) activate(X) = [1] X + [0] >= [1] X + [0] = X activate(n__0()) = [0] >= [0] = 0() activate(n__isNat(X)) = [1] X + [0] >= [1] X + [0] = isNat(X) activate(n__plus(X1,X2)) = [1] X1 + [1] X2 + [1] >= [1] X1 + [1] X2 + [1] = plus(activate(X1),activate(X2)) activate(n__s(X)) = [1] X + [0] >= [1] X + [5] = s(activate(X)) activate(n__x(X1,X2)) = [1] X1 + [1] X2 + [0] >= [1] X1 + [1] X2 + [0] = x(activate(X1),activate(X2)) isNat(X) = [1] X + [0] >= [1] X + [0] = n__isNat(X) isNat(n__0()) = [0] >= [0] = tt() isNat(n__plus(V1,V2)) = [1] V1 + [1] V2 + [1] >= [1] V1 + [1] V2 + [3] = and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) = [1] V1 + [0] >= [1] V1 + [0] = isNat(activate(V1)) isNat(n__x(V1,V2)) = [1] V1 + [1] V2 + [0] >= [1] V1 + [1] V2 + [3] = and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) = [1] X1 + [1] X2 + [1] >= [1] X1 + [1] X2 + [1] = n__plus(X1,X2) x(X1,X2) = [1] X1 + [1] X2 + [0] >= [1] X1 + [1] X2 + [0] = n__x(X1,X2) Further, it can be verified that all rules not oriented are covered by the weightgap condition. * Step 4: WeightGap WORST_CASE(?,O(n^2)) + Considered Problem: - Strict TRS: 0() -> n__0() U11(tt(),N) -> activate(N) U21(tt(),M,N) -> s(plus(activate(N),activate(M))) U31(tt()) -> 0() U41(tt(),M,N) -> plus(x(activate(N),activate(M)),activate(N)) activate(X) -> X activate(n__0()) -> 0() activate(n__isNat(X)) -> isNat(X) activate(n__plus(X1,X2)) -> plus(activate(X1),activate(X2)) activate(n__s(X)) -> s(activate(X)) activate(n__x(X1,X2)) -> x(activate(X1),activate(X2)) isNat(X) -> n__isNat(X) isNat(n__0()) -> tt() isNat(n__plus(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) -> isNat(activate(V1)) isNat(n__x(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) - Weak TRS: and(tt(),X) -> activate(X) plus(X1,X2) -> n__plus(X1,X2) s(X) -> n__s(X) x(X1,X2) -> n__x(X1,X2) - Signature: {0/0,U11/2,U21/3,U31/1,U41/3,activate/1,and/2,isNat/1,plus/2,s/1,x/2} / {n__0/0,n__isNat/1,n__plus/2,n__s/1 ,n__x/2,tt/0} - Obligation: innermost runtime complexity wrt. defined symbols {0,U11,U21,U31,U41,activate,and,isNat,plus,s ,x} and constructors {n__0,n__isNat,n__plus,n__s,n__x,tt} + Applied Processor: WeightGap {wgDimension = 1, wgDegree = 1, wgKind = Algebraic, wgUArgs = UArgs, wgOn = WgOnAny} + Details: The weightgap principle applies using the following nonconstant growth matrix-interpretation: We apply a matrix interpretation of kind constructor based matrix interpretation: The following argument positions are considered usable: uargs(and) = {1,2}, uargs(isNat) = {1}, uargs(n__isNat) = {1}, uargs(plus) = {1,2}, uargs(s) = {1}, uargs(x) = {1,2} Following symbols are considered usable: all TcT has computed the following interpretation: p(0) = [0] p(U11) = [1] x2 + [0] p(U21) = [1] x2 + [1] x3 + [0] p(U31) = [0] p(U41) = [1] x1 + [1] x2 + [2] x3 + [5] p(activate) = [1] x1 + [0] p(and) = [1] x1 + [1] x2 + [3] p(isNat) = [1] x1 + [0] p(n__0) = [1] p(n__isNat) = [1] x1 + [0] p(n__plus) = [1] x1 + [1] x2 + [0] p(n__s) = [1] x1 + [0] p(n__x) = [1] x1 + [1] x2 + [0] p(plus) = [1] x1 + [1] x2 + [0] p(s) = [1] x1 + [7] p(tt) = [4] p(x) = [1] x1 + [1] x2 + [0] Following rules are strictly oriented: U41(tt(),M,N) = [1] M + [2] N + [9] > [1] M + [2] N + [0] = plus(x(activate(N),activate(M)),activate(N)) activate(n__0()) = [1] > [0] = 0() Following rules are (at-least) weakly oriented: 0() = [0] >= [1] = n__0() U11(tt(),N) = [1] N + [0] >= [1] N + [0] = activate(N) U21(tt(),M,N) = [1] M + [1] N + [0] >= [1] M + [1] N + [7] = s(plus(activate(N),activate(M))) U31(tt()) = [0] >= [0] = 0() activate(X) = [1] X + [0] >= [1] X + [0] = X activate(n__isNat(X)) = [1] X + [0] >= [1] X + [0] = isNat(X) activate(n__plus(X1,X2)) = [1] X1 + [1] X2 + [0] >= [1] X1 + [1] X2 + [0] = plus(activate(X1),activate(X2)) activate(n__s(X)) = [1] X + [0] >= [1] X + [7] = s(activate(X)) activate(n__x(X1,X2)) = [1] X1 + [1] X2 + [0] >= [1] X1 + [1] X2 + [0] = x(activate(X1),activate(X2)) and(tt(),X) = [1] X + [7] >= [1] X + [0] = activate(X) isNat(X) = [1] X + [0] >= [1] X + [0] = n__isNat(X) isNat(n__0()) = [1] >= [4] = tt() isNat(n__plus(V1,V2)) = [1] V1 + [1] V2 + [0] >= [1] V1 + [1] V2 + [3] = and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) = [1] V1 + [0] >= [1] V1 + [0] = isNat(activate(V1)) isNat(n__x(V1,V2)) = [1] V1 + [1] V2 + [0] >= [1] V1 + [1] V2 + [3] = and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) = [1] X1 + [1] X2 + [0] >= [1] X1 + [1] X2 + [0] = n__plus(X1,X2) s(X) = [1] X + [7] >= [1] X + [0] = n__s(X) x(X1,X2) = [1] X1 + [1] X2 + [0] >= [1] X1 + [1] X2 + [0] = n__x(X1,X2) Further, it can be verified that all rules not oriented are covered by the weightgap condition. * Step 5: WeightGap WORST_CASE(?,O(n^2)) + Considered Problem: - Strict TRS: 0() -> n__0() U11(tt(),N) -> activate(N) U21(tt(),M,N) -> s(plus(activate(N),activate(M))) U31(tt()) -> 0() activate(X) -> X activate(n__isNat(X)) -> isNat(X) activate(n__plus(X1,X2)) -> plus(activate(X1),activate(X2)) activate(n__s(X)) -> s(activate(X)) activate(n__x(X1,X2)) -> x(activate(X1),activate(X2)) isNat(X) -> n__isNat(X) isNat(n__0()) -> tt() isNat(n__plus(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) -> isNat(activate(V1)) isNat(n__x(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) - Weak TRS: U41(tt(),M,N) -> plus(x(activate(N),activate(M)),activate(N)) activate(n__0()) -> 0() and(tt(),X) -> activate(X) plus(X1,X2) -> n__plus(X1,X2) s(X) -> n__s(X) x(X1,X2) -> n__x(X1,X2) - Signature: {0/0,U11/2,U21/3,U31/1,U41/3,activate/1,and/2,isNat/1,plus/2,s/1,x/2} / {n__0/0,n__isNat/1,n__plus/2,n__s/1 ,n__x/2,tt/0} - Obligation: innermost runtime complexity wrt. defined symbols {0,U11,U21,U31,U41,activate,and,isNat,plus,s ,x} and constructors {n__0,n__isNat,n__plus,n__s,n__x,tt} + Applied Processor: WeightGap {wgDimension = 1, wgDegree = 1, wgKind = Algebraic, wgUArgs = UArgs, wgOn = WgOnAny} + Details: The weightgap principle applies using the following nonconstant growth matrix-interpretation: We apply a matrix interpretation of kind constructor based matrix interpretation: The following argument positions are considered usable: uargs(and) = {1,2}, uargs(isNat) = {1}, uargs(n__isNat) = {1}, uargs(plus) = {1,2}, uargs(s) = {1}, uargs(x) = {1,2} Following symbols are considered usable: all TcT has computed the following interpretation: p(0) = [0] p(U11) = [1] x2 + [0] p(U21) = [1] x2 + [1] x3 + [0] p(U31) = [0] p(U41) = [1] x2 + [2] x3 + [7] p(activate) = [1] x1 + [0] p(and) = [1] x1 + [1] x2 + [0] p(isNat) = [1] x1 + [4] p(n__0) = [0] p(n__isNat) = [1] x1 + [7] p(n__plus) = [1] x1 + [1] x2 + [3] p(n__s) = [1] x1 + [0] p(n__x) = [1] x1 + [1] x2 + [2] p(plus) = [1] x1 + [1] x2 + [3] p(s) = [1] x1 + [1] p(tt) = [0] p(x) = [1] x1 + [1] x2 + [4] Following rules are strictly oriented: activate(n__isNat(X)) = [1] X + [7] > [1] X + [4] = isNat(X) isNat(n__0()) = [4] > [0] = tt() Following rules are (at-least) weakly oriented: 0() = [0] >= [0] = n__0() U11(tt(),N) = [1] N + [0] >= [1] N + [0] = activate(N) U21(tt(),M,N) = [1] M + [1] N + [0] >= [1] M + [1] N + [4] = s(plus(activate(N),activate(M))) U31(tt()) = [0] >= [0] = 0() U41(tt(),M,N) = [1] M + [2] N + [7] >= [1] M + [2] N + [7] = plus(x(activate(N),activate(M)),activate(N)) activate(X) = [1] X + [0] >= [1] X + [0] = X activate(n__0()) = [0] >= [0] = 0() activate(n__plus(X1,X2)) = [1] X1 + [1] X2 + [3] >= [1] X1 + [1] X2 + [3] = plus(activate(X1),activate(X2)) activate(n__s(X)) = [1] X + [0] >= [1] X + [1] = s(activate(X)) activate(n__x(X1,X2)) = [1] X1 + [1] X2 + [2] >= [1] X1 + [1] X2 + [4] = x(activate(X1),activate(X2)) and(tt(),X) = [1] X + [0] >= [1] X + [0] = activate(X) isNat(X) = [1] X + [4] >= [1] X + [7] = n__isNat(X) isNat(n__plus(V1,V2)) = [1] V1 + [1] V2 + [7] >= [1] V1 + [1] V2 + [11] = and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) = [1] V1 + [4] >= [1] V1 + [4] = isNat(activate(V1)) isNat(n__x(V1,V2)) = [1] V1 + [1] V2 + [6] >= [1] V1 + [1] V2 + [11] = and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) = [1] X1 + [1] X2 + [3] >= [1] X1 + [1] X2 + [3] = n__plus(X1,X2) s(X) = [1] X + [1] >= [1] X + [0] = n__s(X) x(X1,X2) = [1] X1 + [1] X2 + [4] >= [1] X1 + [1] X2 + [2] = n__x(X1,X2) Further, it can be verified that all rules not oriented are covered by the weightgap condition. * Step 6: WeightGap WORST_CASE(?,O(n^2)) + Considered Problem: - Strict TRS: 0() -> n__0() U11(tt(),N) -> activate(N) U21(tt(),M,N) -> s(plus(activate(N),activate(M))) U31(tt()) -> 0() activate(X) -> X activate(n__plus(X1,X2)) -> plus(activate(X1),activate(X2)) activate(n__s(X)) -> s(activate(X)) activate(n__x(X1,X2)) -> x(activate(X1),activate(X2)) isNat(X) -> n__isNat(X) isNat(n__plus(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) -> isNat(activate(V1)) isNat(n__x(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) - Weak TRS: U41(tt(),M,N) -> plus(x(activate(N),activate(M)),activate(N)) activate(n__0()) -> 0() activate(n__isNat(X)) -> isNat(X) and(tt(),X) -> activate(X) isNat(n__0()) -> tt() plus(X1,X2) -> n__plus(X1,X2) s(X) -> n__s(X) x(X1,X2) -> n__x(X1,X2) - Signature: {0/0,U11/2,U21/3,U31/1,U41/3,activate/1,and/2,isNat/1,plus/2,s/1,x/2} / {n__0/0,n__isNat/1,n__plus/2,n__s/1 ,n__x/2,tt/0} - Obligation: innermost runtime complexity wrt. defined symbols {0,U11,U21,U31,U41,activate,and,isNat,plus,s ,x} and constructors {n__0,n__isNat,n__plus,n__s,n__x,tt} + Applied Processor: WeightGap {wgDimension = 1, wgDegree = 1, wgKind = Algebraic, wgUArgs = UArgs, wgOn = WgOnAny} + Details: The weightgap principle applies using the following nonconstant growth matrix-interpretation: We apply a matrix interpretation of kind constructor based matrix interpretation: The following argument positions are considered usable: uargs(and) = {1,2}, uargs(isNat) = {1}, uargs(n__isNat) = {1}, uargs(plus) = {1,2}, uargs(s) = {1}, uargs(x) = {1,2} Following symbols are considered usable: all TcT has computed the following interpretation: p(0) = [1] p(U11) = [4] x1 + [1] x2 + [0] p(U21) = [1] x2 + [1] x3 + [2] p(U31) = [2] x1 + [0] p(U41) = [1] x2 + [2] x3 + [5] p(activate) = [1] x1 + [0] p(and) = [1] x1 + [1] x2 + [1] p(isNat) = [1] x1 + [1] p(n__0) = [1] p(n__isNat) = [1] x1 + [2] p(n__plus) = [1] x1 + [1] x2 + [0] p(n__s) = [1] x1 + [6] p(n__x) = [1] x1 + [1] x2 + [5] p(plus) = [1] x1 + [1] x2 + [0] p(s) = [1] x1 + [6] p(tt) = [2] p(x) = [1] x1 + [1] x2 + [5] Following rules are strictly oriented: U11(tt(),N) = [1] N + [8] > [1] N + [0] = activate(N) U31(tt()) = [4] > [1] = 0() isNat(n__s(V1)) = [1] V1 + [7] > [1] V1 + [1] = isNat(activate(V1)) isNat(n__x(V1,V2)) = [1] V1 + [1] V2 + [6] > [1] V1 + [1] V2 + [4] = and(isNat(activate(V1)),n__isNat(activate(V2))) Following rules are (at-least) weakly oriented: 0() = [1] >= [1] = n__0() U21(tt(),M,N) = [1] M + [1] N + [2] >= [1] M + [1] N + [6] = s(plus(activate(N),activate(M))) U41(tt(),M,N) = [1] M + [2] N + [5] >= [1] M + [2] N + [5] = plus(x(activate(N),activate(M)),activate(N)) activate(X) = [1] X + [0] >= [1] X + [0] = X activate(n__0()) = [1] >= [1] = 0() activate(n__isNat(X)) = [1] X + [2] >= [1] X + [1] = isNat(X) activate(n__plus(X1,X2)) = [1] X1 + [1] X2 + [0] >= [1] X1 + [1] X2 + [0] = plus(activate(X1),activate(X2)) activate(n__s(X)) = [1] X + [6] >= [1] X + [6] = s(activate(X)) activate(n__x(X1,X2)) = [1] X1 + [1] X2 + [5] >= [1] X1 + [1] X2 + [5] = x(activate(X1),activate(X2)) and(tt(),X) = [1] X + [3] >= [1] X + [0] = activate(X) isNat(X) = [1] X + [1] >= [1] X + [2] = n__isNat(X) isNat(n__0()) = [2] >= [2] = tt() isNat(n__plus(V1,V2)) = [1] V1 + [1] V2 + [1] >= [1] V1 + [1] V2 + [4] = and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) = [1] X1 + [1] X2 + [0] >= [1] X1 + [1] X2 + [0] = n__plus(X1,X2) s(X) = [1] X + [6] >= [1] X + [6] = n__s(X) x(X1,X2) = [1] X1 + [1] X2 + [5] >= [1] X1 + [1] X2 + [5] = n__x(X1,X2) Further, it can be verified that all rules not oriented are covered by the weightgap condition. * Step 7: WeightGap WORST_CASE(?,O(n^2)) + Considered Problem: - Strict TRS: 0() -> n__0() U21(tt(),M,N) -> s(plus(activate(N),activate(M))) activate(X) -> X activate(n__plus(X1,X2)) -> plus(activate(X1),activate(X2)) activate(n__s(X)) -> s(activate(X)) activate(n__x(X1,X2)) -> x(activate(X1),activate(X2)) isNat(X) -> n__isNat(X) isNat(n__plus(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) - Weak TRS: U11(tt(),N) -> activate(N) U31(tt()) -> 0() U41(tt(),M,N) -> plus(x(activate(N),activate(M)),activate(N)) activate(n__0()) -> 0() activate(n__isNat(X)) -> isNat(X) and(tt(),X) -> activate(X) isNat(n__0()) -> tt() isNat(n__s(V1)) -> isNat(activate(V1)) isNat(n__x(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) -> n__plus(X1,X2) s(X) -> n__s(X) x(X1,X2) -> n__x(X1,X2) - Signature: {0/0,U11/2,U21/3,U31/1,U41/3,activate/1,and/2,isNat/1,plus/2,s/1,x/2} / {n__0/0,n__isNat/1,n__plus/2,n__s/1 ,n__x/2,tt/0} - Obligation: innermost runtime complexity wrt. defined symbols {0,U11,U21,U31,U41,activate,and,isNat,plus,s ,x} and constructors {n__0,n__isNat,n__plus,n__s,n__x,tt} + Applied Processor: WeightGap {wgDimension = 1, wgDegree = 1, wgKind = Algebraic, wgUArgs = UArgs, wgOn = WgOnAny} + Details: The weightgap principle applies using the following nonconstant growth matrix-interpretation: We apply a matrix interpretation of kind constructor based matrix interpretation: The following argument positions are considered usable: uargs(and) = {1,2}, uargs(isNat) = {1}, uargs(n__isNat) = {1}, uargs(plus) = {1,2}, uargs(s) = {1}, uargs(x) = {1,2} Following symbols are considered usable: all TcT has computed the following interpretation: p(0) = [0] p(U11) = [5] x2 + [2] p(U21) = [1] x1 + [1] x2 + [4] x3 + [7] p(U31) = [4] x1 + [4] p(U41) = [1] x2 + [3] x3 + [5] p(activate) = [1] x1 + [0] p(and) = [1] x1 + [1] x2 + [0] p(isNat) = [1] x1 + [0] p(n__0) = [0] p(n__isNat) = [1] x1 + [0] p(n__plus) = [1] x1 + [1] x2 + [0] p(n__s) = [1] x1 + [0] p(n__x) = [1] x1 + [1] x2 + [0] p(plus) = [1] x1 + [1] x2 + [0] p(s) = [1] x1 + [2] p(tt) = [0] p(x) = [1] x1 + [1] x2 + [5] Following rules are strictly oriented: U21(tt(),M,N) = [1] M + [4] N + [7] > [1] M + [1] N + [2] = s(plus(activate(N),activate(M))) Following rules are (at-least) weakly oriented: 0() = [0] >= [0] = n__0() U11(tt(),N) = [5] N + [2] >= [1] N + [0] = activate(N) U31(tt()) = [4] >= [0] = 0() U41(tt(),M,N) = [1] M + [3] N + [5] >= [1] M + [2] N + [5] = plus(x(activate(N),activate(M)),activate(N)) activate(X) = [1] X + [0] >= [1] X + [0] = X activate(n__0()) = [0] >= [0] = 0() activate(n__isNat(X)) = [1] X + [0] >= [1] X + [0] = isNat(X) activate(n__plus(X1,X2)) = [1] X1 + [1] X2 + [0] >= [1] X1 + [1] X2 + [0] = plus(activate(X1),activate(X2)) activate(n__s(X)) = [1] X + [0] >= [1] X + [2] = s(activate(X)) activate(n__x(X1,X2)) = [1] X1 + [1] X2 + [0] >= [1] X1 + [1] X2 + [5] = x(activate(X1),activate(X2)) and(tt(),X) = [1] X + [0] >= [1] X + [0] = activate(X) isNat(X) = [1] X + [0] >= [1] X + [0] = n__isNat(X) isNat(n__0()) = [0] >= [0] = tt() isNat(n__plus(V1,V2)) = [1] V1 + [1] V2 + [0] >= [1] V1 + [1] V2 + [0] = and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) = [1] V1 + [0] >= [1] V1 + [0] = isNat(activate(V1)) isNat(n__x(V1,V2)) = [1] V1 + [1] V2 + [0] >= [1] V1 + [1] V2 + [0] = and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) = [1] X1 + [1] X2 + [0] >= [1] X1 + [1] X2 + [0] = n__plus(X1,X2) s(X) = [1] X + [2] >= [1] X + [0] = n__s(X) x(X1,X2) = [1] X1 + [1] X2 + [5] >= [1] X1 + [1] X2 + [0] = n__x(X1,X2) Further, it can be verified that all rules not oriented are covered by the weightgap condition. * Step 8: WeightGap WORST_CASE(?,O(n^2)) + Considered Problem: - Strict TRS: 0() -> n__0() activate(X) -> X activate(n__plus(X1,X2)) -> plus(activate(X1),activate(X2)) activate(n__s(X)) -> s(activate(X)) activate(n__x(X1,X2)) -> x(activate(X1),activate(X2)) isNat(X) -> n__isNat(X) isNat(n__plus(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) - Weak TRS: U11(tt(),N) -> activate(N) U21(tt(),M,N) -> s(plus(activate(N),activate(M))) U31(tt()) -> 0() U41(tt(),M,N) -> plus(x(activate(N),activate(M)),activate(N)) activate(n__0()) -> 0() activate(n__isNat(X)) -> isNat(X) and(tt(),X) -> activate(X) isNat(n__0()) -> tt() isNat(n__s(V1)) -> isNat(activate(V1)) isNat(n__x(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) -> n__plus(X1,X2) s(X) -> n__s(X) x(X1,X2) -> n__x(X1,X2) - Signature: {0/0,U11/2,U21/3,U31/1,U41/3,activate/1,and/2,isNat/1,plus/2,s/1,x/2} / {n__0/0,n__isNat/1,n__plus/2,n__s/1 ,n__x/2,tt/0} - Obligation: innermost runtime complexity wrt. defined symbols {0,U11,U21,U31,U41,activate,and,isNat,plus,s ,x} and constructors {n__0,n__isNat,n__plus,n__s,n__x,tt} + Applied Processor: WeightGap {wgDimension = 1, wgDegree = 1, wgKind = Algebraic, wgUArgs = UArgs, wgOn = WgOnAny} + Details: The weightgap principle applies using the following nonconstant growth matrix-interpretation: We apply a matrix interpretation of kind constructor based matrix interpretation: The following argument positions are considered usable: uargs(and) = {1,2}, uargs(isNat) = {1}, uargs(n__isNat) = {1}, uargs(plus) = {1,2}, uargs(s) = {1}, uargs(x) = {1,2} Following symbols are considered usable: all TcT has computed the following interpretation: p(0) = [0] p(U11) = [1] x2 + [0] p(U21) = [1] x2 + [1] x3 + [3] p(U31) = [0] p(U41) = [1] x2 + [2] x3 + [3] p(activate) = [1] x1 + [0] p(and) = [1] x1 + [1] x2 + [0] p(isNat) = [1] x1 + [0] p(n__0) = [0] p(n__isNat) = [1] x1 + [0] p(n__plus) = [1] x1 + [1] x2 + [3] p(n__s) = [1] x1 + [0] p(n__x) = [1] x1 + [1] x2 + [0] p(plus) = [1] x1 + [1] x2 + [3] p(s) = [1] x1 + [0] p(tt) = [0] p(x) = [1] x1 + [1] x2 + [0] Following rules are strictly oriented: isNat(n__plus(V1,V2)) = [1] V1 + [1] V2 + [3] > [1] V1 + [1] V2 + [0] = and(isNat(activate(V1)),n__isNat(activate(V2))) Following rules are (at-least) weakly oriented: 0() = [0] >= [0] = n__0() U11(tt(),N) = [1] N + [0] >= [1] N + [0] = activate(N) U21(tt(),M,N) = [1] M + [1] N + [3] >= [1] M + [1] N + [3] = s(plus(activate(N),activate(M))) U31(tt()) = [0] >= [0] = 0() U41(tt(),M,N) = [1] M + [2] N + [3] >= [1] M + [2] N + [3] = plus(x(activate(N),activate(M)),activate(N)) activate(X) = [1] X + [0] >= [1] X + [0] = X activate(n__0()) = [0] >= [0] = 0() activate(n__isNat(X)) = [1] X + [0] >= [1] X + [0] = isNat(X) activate(n__plus(X1,X2)) = [1] X1 + [1] X2 + [3] >= [1] X1 + [1] X2 + [3] = plus(activate(X1),activate(X2)) activate(n__s(X)) = [1] X + [0] >= [1] X + [0] = s(activate(X)) activate(n__x(X1,X2)) = [1] X1 + [1] X2 + [0] >= [1] X1 + [1] X2 + [0] = x(activate(X1),activate(X2)) and(tt(),X) = [1] X + [0] >= [1] X + [0] = activate(X) isNat(X) = [1] X + [0] >= [1] X + [0] = n__isNat(X) isNat(n__0()) = [0] >= [0] = tt() isNat(n__s(V1)) = [1] V1 + [0] >= [1] V1 + [0] = isNat(activate(V1)) isNat(n__x(V1,V2)) = [1] V1 + [1] V2 + [0] >= [1] V1 + [1] V2 + [0] = and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) = [1] X1 + [1] X2 + [3] >= [1] X1 + [1] X2 + [3] = n__plus(X1,X2) s(X) = [1] X + [0] >= [1] X + [0] = n__s(X) x(X1,X2) = [1] X1 + [1] X2 + [0] >= [1] X1 + [1] X2 + [0] = n__x(X1,X2) Further, it can be verified that all rules not oriented are covered by the weightgap condition. * Step 9: WeightGap WORST_CASE(?,O(n^2)) + Considered Problem: - Strict TRS: 0() -> n__0() activate(X) -> X activate(n__plus(X1,X2)) -> plus(activate(X1),activate(X2)) activate(n__s(X)) -> s(activate(X)) activate(n__x(X1,X2)) -> x(activate(X1),activate(X2)) isNat(X) -> n__isNat(X) - Weak TRS: U11(tt(),N) -> activate(N) U21(tt(),M,N) -> s(plus(activate(N),activate(M))) U31(tt()) -> 0() U41(tt(),M,N) -> plus(x(activate(N),activate(M)),activate(N)) activate(n__0()) -> 0() activate(n__isNat(X)) -> isNat(X) and(tt(),X) -> activate(X) isNat(n__0()) -> tt() isNat(n__plus(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) -> isNat(activate(V1)) isNat(n__x(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) -> n__plus(X1,X2) s(X) -> n__s(X) x(X1,X2) -> n__x(X1,X2) - Signature: {0/0,U11/2,U21/3,U31/1,U41/3,activate/1,and/2,isNat/1,plus/2,s/1,x/2} / {n__0/0,n__isNat/1,n__plus/2,n__s/1 ,n__x/2,tt/0} - Obligation: innermost runtime complexity wrt. defined symbols {0,U11,U21,U31,U41,activate,and,isNat,plus,s ,x} and constructors {n__0,n__isNat,n__plus,n__s,n__x,tt} + Applied Processor: WeightGap {wgDimension = 1, wgDegree = 1, wgKind = Algebraic, wgUArgs = UArgs, wgOn = WgOnAny} + Details: The weightgap principle applies using the following nonconstant growth matrix-interpretation: We apply a matrix interpretation of kind constructor based matrix interpretation: The following argument positions are considered usable: uargs(and) = {1,2}, uargs(isNat) = {1}, uargs(n__isNat) = {1}, uargs(plus) = {1,2}, uargs(s) = {1}, uargs(x) = {1,2} Following symbols are considered usable: all TcT has computed the following interpretation: p(0) = [5] p(U11) = [1] x1 + [4] x2 + [5] p(U21) = [2] x1 + [1] x2 + [1] x3 + [2] p(U31) = [1] x1 + [6] p(U41) = [1] x1 + [4] x2 + [4] x3 + [5] p(activate) = [1] x1 + [1] p(and) = [1] x1 + [1] x2 + [0] p(isNat) = [1] x1 + [0] p(n__0) = [4] p(n__isNat) = [1] x1 + [0] p(n__plus) = [1] x1 + [1] x2 + [2] p(n__s) = [1] x1 + [1] p(n__x) = [1] x1 + [1] x2 + [4] p(plus) = [1] x1 + [1] x2 + [2] p(s) = [1] x1 + [2] p(tt) = [4] p(x) = [1] x1 + [1] x2 + [4] Following rules are strictly oriented: 0() = [5] > [4] = n__0() activate(X) = [1] X + [1] > [1] X + [0] = X Following rules are (at-least) weakly oriented: U11(tt(),N) = [4] N + [9] >= [1] N + [1] = activate(N) U21(tt(),M,N) = [1] M + [1] N + [10] >= [1] M + [1] N + [6] = s(plus(activate(N),activate(M))) U31(tt()) = [10] >= [5] = 0() U41(tt(),M,N) = [4] M + [4] N + [9] >= [1] M + [2] N + [9] = plus(x(activate(N),activate(M)),activate(N)) activate(n__0()) = [5] >= [5] = 0() activate(n__isNat(X)) = [1] X + [1] >= [1] X + [0] = isNat(X) activate(n__plus(X1,X2)) = [1] X1 + [1] X2 + [3] >= [1] X1 + [1] X2 + [4] = plus(activate(X1),activate(X2)) activate(n__s(X)) = [1] X + [2] >= [1] X + [3] = s(activate(X)) activate(n__x(X1,X2)) = [1] X1 + [1] X2 + [5] >= [1] X1 + [1] X2 + [6] = x(activate(X1),activate(X2)) and(tt(),X) = [1] X + [4] >= [1] X + [1] = activate(X) isNat(X) = [1] X + [0] >= [1] X + [0] = n__isNat(X) isNat(n__0()) = [4] >= [4] = tt() isNat(n__plus(V1,V2)) = [1] V1 + [1] V2 + [2] >= [1] V1 + [1] V2 + [2] = and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) = [1] V1 + [1] >= [1] V1 + [1] = isNat(activate(V1)) isNat(n__x(V1,V2)) = [1] V1 + [1] V2 + [4] >= [1] V1 + [1] V2 + [2] = and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) = [1] X1 + [1] X2 + [2] >= [1] X1 + [1] X2 + [2] = n__plus(X1,X2) s(X) = [1] X + [2] >= [1] X + [1] = n__s(X) x(X1,X2) = [1] X1 + [1] X2 + [4] >= [1] X1 + [1] X2 + [4] = n__x(X1,X2) Further, it can be verified that all rules not oriented are covered by the weightgap condition. * Step 10: WeightGap WORST_CASE(?,O(n^2)) + Considered Problem: - Strict TRS: activate(n__plus(X1,X2)) -> plus(activate(X1),activate(X2)) activate(n__s(X)) -> s(activate(X)) activate(n__x(X1,X2)) -> x(activate(X1),activate(X2)) isNat(X) -> n__isNat(X) - Weak TRS: 0() -> n__0() U11(tt(),N) -> activate(N) U21(tt(),M,N) -> s(plus(activate(N),activate(M))) U31(tt()) -> 0() U41(tt(),M,N) -> plus(x(activate(N),activate(M)),activate(N)) activate(X) -> X activate(n__0()) -> 0() activate(n__isNat(X)) -> isNat(X) and(tt(),X) -> activate(X) isNat(n__0()) -> tt() isNat(n__plus(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) -> isNat(activate(V1)) isNat(n__x(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) -> n__plus(X1,X2) s(X) -> n__s(X) x(X1,X2) -> n__x(X1,X2) - Signature: {0/0,U11/2,U21/3,U31/1,U41/3,activate/1,and/2,isNat/1,plus/2,s/1,x/2} / {n__0/0,n__isNat/1,n__plus/2,n__s/1 ,n__x/2,tt/0} - Obligation: innermost runtime complexity wrt. defined symbols {0,U11,U21,U31,U41,activate,and,isNat,plus,s ,x} and constructors {n__0,n__isNat,n__plus,n__s,n__x,tt} + Applied Processor: WeightGap {wgDimension = 1, wgDegree = 1, wgKind = Algebraic, wgUArgs = UArgs, wgOn = WgOnAny} + Details: The weightgap principle applies using the following nonconstant growth matrix-interpretation: We apply a matrix interpretation of kind constructor based matrix interpretation: The following argument positions are considered usable: uargs(and) = {1,2}, uargs(isNat) = {1}, uargs(n__isNat) = {1}, uargs(plus) = {1,2}, uargs(s) = {1}, uargs(x) = {1,2} Following symbols are considered usable: all TcT has computed the following interpretation: p(0) = [1] p(U11) = [2] x1 + [5] x2 + [0] p(U21) = [5] x1 + [5] x2 + [1] x3 + [7] p(U31) = [1] p(U41) = [5] x1 + [2] x2 + [4] x3 + [6] p(activate) = [1] x1 + [1] p(and) = [1] x1 + [1] x2 + [1] p(isNat) = [1] x1 + [1] p(n__0) = [1] p(n__isNat) = [1] x1 + [0] p(n__plus) = [1] x1 + [1] x2 + [4] p(n__s) = [1] x1 + [3] p(n__x) = [1] x1 + [1] x2 + [3] p(plus) = [1] x1 + [1] x2 + [4] p(s) = [1] x1 + [3] p(tt) = [1] p(x) = [1] x1 + [1] x2 + [4] Following rules are strictly oriented: isNat(X) = [1] X + [1] > [1] X + [0] = n__isNat(X) Following rules are (at-least) weakly oriented: 0() = [1] >= [1] = n__0() U11(tt(),N) = [5] N + [2] >= [1] N + [1] = activate(N) U21(tt(),M,N) = [5] M + [1] N + [12] >= [1] M + [1] N + [9] = s(plus(activate(N),activate(M))) U31(tt()) = [1] >= [1] = 0() U41(tt(),M,N) = [2] M + [4] N + [11] >= [1] M + [2] N + [11] = plus(x(activate(N),activate(M)),activate(N)) activate(X) = [1] X + [1] >= [1] X + [0] = X activate(n__0()) = [2] >= [1] = 0() activate(n__isNat(X)) = [1] X + [1] >= [1] X + [1] = isNat(X) activate(n__plus(X1,X2)) = [1] X1 + [1] X2 + [5] >= [1] X1 + [1] X2 + [6] = plus(activate(X1),activate(X2)) activate(n__s(X)) = [1] X + [4] >= [1] X + [4] = s(activate(X)) activate(n__x(X1,X2)) = [1] X1 + [1] X2 + [4] >= [1] X1 + [1] X2 + [6] = x(activate(X1),activate(X2)) and(tt(),X) = [1] X + [2] >= [1] X + [1] = activate(X) isNat(n__0()) = [2] >= [1] = tt() isNat(n__plus(V1,V2)) = [1] V1 + [1] V2 + [5] >= [1] V1 + [1] V2 + [4] = and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) = [1] V1 + [4] >= [1] V1 + [2] = isNat(activate(V1)) isNat(n__x(V1,V2)) = [1] V1 + [1] V2 + [4] >= [1] V1 + [1] V2 + [4] = and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) = [1] X1 + [1] X2 + [4] >= [1] X1 + [1] X2 + [4] = n__plus(X1,X2) s(X) = [1] X + [3] >= [1] X + [3] = n__s(X) x(X1,X2) = [1] X1 + [1] X2 + [4] >= [1] X1 + [1] X2 + [3] = n__x(X1,X2) Further, it can be verified that all rules not oriented are covered by the weightgap condition. * Step 11: NaturalMI WORST_CASE(?,O(n^2)) + Considered Problem: - Strict TRS: activate(n__plus(X1,X2)) -> plus(activate(X1),activate(X2)) activate(n__s(X)) -> s(activate(X)) activate(n__x(X1,X2)) -> x(activate(X1),activate(X2)) - Weak TRS: 0() -> n__0() U11(tt(),N) -> activate(N) U21(tt(),M,N) -> s(plus(activate(N),activate(M))) U31(tt()) -> 0() U41(tt(),M,N) -> plus(x(activate(N),activate(M)),activate(N)) activate(X) -> X activate(n__0()) -> 0() activate(n__isNat(X)) -> isNat(X) and(tt(),X) -> activate(X) isNat(X) -> n__isNat(X) isNat(n__0()) -> tt() isNat(n__plus(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) -> isNat(activate(V1)) isNat(n__x(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) -> n__plus(X1,X2) s(X) -> n__s(X) x(X1,X2) -> n__x(X1,X2) - Signature: {0/0,U11/2,U21/3,U31/1,U41/3,activate/1,and/2,isNat/1,plus/2,s/1,x/2} / {n__0/0,n__isNat/1,n__plus/2,n__s/1 ,n__x/2,tt/0} - Obligation: innermost runtime complexity wrt. defined symbols {0,U11,U21,U31,U41,activate,and,isNat,plus,s ,x} and constructors {n__0,n__isNat,n__plus,n__s,n__x,tt} + Applied Processor: NaturalMI {miDimension = 2, miDegree = 2, miKind = Algebraic, uargs = UArgs, urules = URules, selector = Just any strict-rules} + Details: We apply a matrix interpretation of kind constructor based matrix interpretation: The following argument positions are considered usable: uargs(and) = {1,2}, uargs(isNat) = {1}, uargs(n__isNat) = {1}, uargs(plus) = {1,2}, uargs(s) = {1}, uargs(x) = {1,2} Following symbols are considered usable: {0,U11,U21,U31,U41,activate,and,isNat,plus,s,x} TcT has computed the following interpretation: p(0) = [2] [0] p(U11) = [2 1] x1 + [1 1] x2 + [1] [4 1] [1 2] [0] p(U21) = [0 0] x1 + [1 4] x2 + [1 4] x3 + [0] [3 1] [4 1] [2 1] [0] p(U31) = [6 0] x1 + [3] [2 0] [1] p(U41) = [5 0] x1 + [1 7] x2 + [4 7] x3 + [3] [3 4] [1 4] [0 2] [4] p(activate) = [1 1] x1 + [0] [0 1] [0] p(and) = [1 2] x1 + [1 4] x2 + [0] [0 1] [0 4] [0] p(isNat) = [1 0] x1 + [0] [0 0] [0] p(n__0) = [2] [0] p(n__isNat) = [1 0] x1 + [0] [0 0] [0] p(n__plus) = [1 2] x1 + [1 2] x2 + [0] [0 1] [0 1] [0] p(n__s) = [1 1] x1 + [0] [0 1] [0] p(n__x) = [1 1] x1 + [1 4] x2 + [0] [0 1] [0 1] [3] p(plus) = [1 2] x1 + [1 2] x2 + [0] [0 1] [0 1] [0] p(s) = [1 1] x1 + [0] [0 1] [0] p(tt) = [2] [0] p(x) = [1 1] x1 + [1 4] x2 + [0] [0 1] [0 1] [3] Following rules are strictly oriented: activate(n__x(X1,X2)) = [1 2] X1 + [1 5] X2 + [3] [0 1] [0 1] [3] > [1 2] X1 + [1 5] X2 + [0] [0 1] [0 1] [3] = x(activate(X1),activate(X2)) Following rules are (at-least) weakly oriented: 0() = [2] [0] >= [2] [0] = n__0() U11(tt(),N) = [1 1] N + [5] [1 2] [8] >= [1 1] N + [0] [0 1] [0] = activate(N) U21(tt(),M,N) = [1 4] M + [1 4] N + [0] [4 1] [2 1] [6] >= [1 4] M + [1 4] N + [0] [0 1] [0 1] [0] = s(plus(activate(N),activate(M))) U31(tt()) = [15] [5] >= [2] [0] = 0() U41(tt(),M,N) = [1 7] M + [4 7] N + [13] [1 4] [0 2] [10] >= [1 7] M + [2 7] N + [6] [0 1] [0 2] [3] = plus(x(activate(N),activate(M)),activate(N)) activate(X) = [1 1] X + [0] [0 1] [0] >= [1 0] X + [0] [0 1] [0] = X activate(n__0()) = [2] [0] >= [2] [0] = 0() activate(n__isNat(X)) = [1 0] X + [0] [0 0] [0] >= [1 0] X + [0] [0 0] [0] = isNat(X) activate(n__plus(X1,X2)) = [1 3] X1 + [1 3] X2 + [0] [0 1] [0 1] [0] >= [1 3] X1 + [1 3] X2 + [0] [0 1] [0 1] [0] = plus(activate(X1),activate(X2)) activate(n__s(X)) = [1 2] X + [0] [0 1] [0] >= [1 2] X + [0] [0 1] [0] = s(activate(X)) and(tt(),X) = [1 4] X + [2] [0 4] [0] >= [1 1] X + [0] [0 1] [0] = activate(X) isNat(X) = [1 0] X + [0] [0 0] [0] >= [1 0] X + [0] [0 0] [0] = n__isNat(X) isNat(n__0()) = [2] [0] >= [2] [0] = tt() isNat(n__plus(V1,V2)) = [1 2] V1 + [1 2] V2 + [0] [0 0] [0 0] [0] >= [1 1] V1 + [1 1] V2 + [0] [0 0] [0 0] [0] = and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) = [1 1] V1 + [0] [0 0] [0] >= [1 1] V1 + [0] [0 0] [0] = isNat(activate(V1)) isNat(n__x(V1,V2)) = [1 1] V1 + [1 4] V2 + [0] [0 0] [0 0] [0] >= [1 1] V1 + [1 1] V2 + [0] [0 0] [0 0] [0] = and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) = [1 2] X1 + [1 2] X2 + [0] [0 1] [0 1] [0] >= [1 2] X1 + [1 2] X2 + [0] [0 1] [0 1] [0] = n__plus(X1,X2) s(X) = [1 1] X + [0] [0 1] [0] >= [1 1] X + [0] [0 1] [0] = n__s(X) x(X1,X2) = [1 1] X1 + [1 4] X2 + [0] [0 1] [0 1] [3] >= [1 1] X1 + [1 4] X2 + [0] [0 1] [0 1] [3] = n__x(X1,X2) * Step 12: NaturalMI WORST_CASE(?,O(n^2)) + Considered Problem: - Strict TRS: activate(n__plus(X1,X2)) -> plus(activate(X1),activate(X2)) activate(n__s(X)) -> s(activate(X)) - Weak TRS: 0() -> n__0() U11(tt(),N) -> activate(N) U21(tt(),M,N) -> s(plus(activate(N),activate(M))) U31(tt()) -> 0() U41(tt(),M,N) -> plus(x(activate(N),activate(M)),activate(N)) activate(X) -> X activate(n__0()) -> 0() activate(n__isNat(X)) -> isNat(X) activate(n__x(X1,X2)) -> x(activate(X1),activate(X2)) and(tt(),X) -> activate(X) isNat(X) -> n__isNat(X) isNat(n__0()) -> tt() isNat(n__plus(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) -> isNat(activate(V1)) isNat(n__x(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) -> n__plus(X1,X2) s(X) -> n__s(X) x(X1,X2) -> n__x(X1,X2) - Signature: {0/0,U11/2,U21/3,U31/1,U41/3,activate/1,and/2,isNat/1,plus/2,s/1,x/2} / {n__0/0,n__isNat/1,n__plus/2,n__s/1 ,n__x/2,tt/0} - Obligation: innermost runtime complexity wrt. defined symbols {0,U11,U21,U31,U41,activate,and,isNat,plus,s ,x} and constructors {n__0,n__isNat,n__plus,n__s,n__x,tt} + Applied Processor: NaturalMI {miDimension = 2, miDegree = 2, miKind = Algebraic, uargs = UArgs, urules = URules, selector = Just any strict-rules} + Details: We apply a matrix interpretation of kind constructor based matrix interpretation: The following argument positions are considered usable: uargs(and) = {1,2}, uargs(isNat) = {1}, uargs(n__isNat) = {1}, uargs(plus) = {1,2}, uargs(s) = {1}, uargs(x) = {1,2} Following symbols are considered usable: {0,U11,U21,U31,U41,activate,and,isNat,plus,s,x} TcT has computed the following interpretation: p(0) = [4] [0] p(U11) = [0 0] x1 + [2 1] x2 + [4] [0 1] [0 1] [2] p(U21) = [1 1] x1 + [2 3] x2 + [4 3] x3 + [0] [0 1] [0 4] [1 4] [7] p(U31) = [0 0] x1 + [4] [1 2] [0] p(U41) = [0 0] x1 + [1 3] x2 + [3 5] x3 + [3] [0 1] [0 1] [1 4] [4] p(activate) = [1 1] x1 + [0] [0 1] [0] p(and) = [1 1] x1 + [1 1] x2 + [0] [0 0] [0 2] [0] p(isNat) = [1 0] x1 + [0] [0 0] [0] p(n__0) = [4] [0] p(n__isNat) = [1 0] x1 + [0] [0 0] [0] p(n__plus) = [1 1] x1 + [1 1] x2 + [0] [0 1] [0 1] [0] p(n__s) = [1 1] x1 + [0] [0 1] [4] p(n__x) = [1 1] x1 + [1 1] x2 + [0] [0 1] [0 1] [2] p(plus) = [1 1] x1 + [1 1] x2 + [0] [0 1] [0 1] [0] p(s) = [1 1] x1 + [0] [0 1] [4] p(tt) = [0] [0] p(x) = [1 1] x1 + [1 1] x2 + [1] [0 1] [0 1] [2] Following rules are strictly oriented: activate(n__s(X)) = [1 2] X + [4] [0 1] [4] > [1 2] X + [0] [0 1] [4] = s(activate(X)) Following rules are (at-least) weakly oriented: 0() = [4] [0] >= [4] [0] = n__0() U11(tt(),N) = [2 1] N + [4] [0 1] [2] >= [1 1] N + [0] [0 1] [0] = activate(N) U21(tt(),M,N) = [2 3] M + [4 3] N + [0] [0 4] [1 4] [7] >= [1 3] M + [1 3] N + [0] [0 1] [0 1] [4] = s(plus(activate(N),activate(M))) U31(tt()) = [4] [0] >= [4] [0] = 0() U41(tt(),M,N) = [1 3] M + [3 5] N + [3] [0 1] [1 4] [4] >= [1 3] M + [2 5] N + [3] [0 1] [0 2] [2] = plus(x(activate(N),activate(M)),activate(N)) activate(X) = [1 1] X + [0] [0 1] [0] >= [1 0] X + [0] [0 1] [0] = X activate(n__0()) = [4] [0] >= [4] [0] = 0() activate(n__isNat(X)) = [1 0] X + [0] [0 0] [0] >= [1 0] X + [0] [0 0] [0] = isNat(X) activate(n__plus(X1,X2)) = [1 2] X1 + [1 2] X2 + [0] [0 1] [0 1] [0] >= [1 2] X1 + [1 2] X2 + [0] [0 1] [0 1] [0] = plus(activate(X1),activate(X2)) activate(n__x(X1,X2)) = [1 2] X1 + [1 2] X2 + [2] [0 1] [0 1] [2] >= [1 2] X1 + [1 2] X2 + [1] [0 1] [0 1] [2] = x(activate(X1),activate(X2)) and(tt(),X) = [1 1] X + [0] [0 2] [0] >= [1 1] X + [0] [0 1] [0] = activate(X) isNat(X) = [1 0] X + [0] [0 0] [0] >= [1 0] X + [0] [0 0] [0] = n__isNat(X) isNat(n__0()) = [4] [0] >= [0] [0] = tt() isNat(n__plus(V1,V2)) = [1 1] V1 + [1 1] V2 + [0] [0 0] [0 0] [0] >= [1 1] V1 + [1 1] V2 + [0] [0 0] [0 0] [0] = and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) = [1 1] V1 + [0] [0 0] [0] >= [1 1] V1 + [0] [0 0] [0] = isNat(activate(V1)) isNat(n__x(V1,V2)) = [1 1] V1 + [1 1] V2 + [0] [0 0] [0 0] [0] >= [1 1] V1 + [1 1] V2 + [0] [0 0] [0 0] [0] = and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) = [1 1] X1 + [1 1] X2 + [0] [0 1] [0 1] [0] >= [1 1] X1 + [1 1] X2 + [0] [0 1] [0 1] [0] = n__plus(X1,X2) s(X) = [1 1] X + [0] [0 1] [4] >= [1 1] X + [0] [0 1] [4] = n__s(X) x(X1,X2) = [1 1] X1 + [1 1] X2 + [1] [0 1] [0 1] [2] >= [1 1] X1 + [1 1] X2 + [0] [0 1] [0 1] [2] = n__x(X1,X2) * Step 13: NaturalMI WORST_CASE(?,O(n^2)) + Considered Problem: - Strict TRS: activate(n__plus(X1,X2)) -> plus(activate(X1),activate(X2)) - Weak TRS: 0() -> n__0() U11(tt(),N) -> activate(N) U21(tt(),M,N) -> s(plus(activate(N),activate(M))) U31(tt()) -> 0() U41(tt(),M,N) -> plus(x(activate(N),activate(M)),activate(N)) activate(X) -> X activate(n__0()) -> 0() activate(n__isNat(X)) -> isNat(X) activate(n__s(X)) -> s(activate(X)) activate(n__x(X1,X2)) -> x(activate(X1),activate(X2)) and(tt(),X) -> activate(X) isNat(X) -> n__isNat(X) isNat(n__0()) -> tt() isNat(n__plus(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) -> isNat(activate(V1)) isNat(n__x(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) -> n__plus(X1,X2) s(X) -> n__s(X) x(X1,X2) -> n__x(X1,X2) - Signature: {0/0,U11/2,U21/3,U31/1,U41/3,activate/1,and/2,isNat/1,plus/2,s/1,x/2} / {n__0/0,n__isNat/1,n__plus/2,n__s/1 ,n__x/2,tt/0} - Obligation: innermost runtime complexity wrt. defined symbols {0,U11,U21,U31,U41,activate,and,isNat,plus,s ,x} and constructors {n__0,n__isNat,n__plus,n__s,n__x,tt} + Applied Processor: NaturalMI {miDimension = 2, miDegree = 2, miKind = Algebraic, uargs = UArgs, urules = URules, selector = Just any strict-rules} + Details: We apply a matrix interpretation of kind constructor based matrix interpretation: The following argument positions are considered usable: uargs(and) = {1,2}, uargs(isNat) = {1}, uargs(n__isNat) = {1}, uargs(plus) = {1,2}, uargs(s) = {1}, uargs(x) = {1,2} Following symbols are considered usable: {0,U11,U21,U31,U41,activate,and,isNat,plus,s,x} TcT has computed the following interpretation: p(0) = [5] [2] p(U11) = [2 2] x1 + [1 1] x2 + [1] [0 4] [4 1] [3] p(U21) = [1 1] x1 + [1 4] x2 + [4 6] x3 + [4] [0 2] [0 4] [0 1] [6] p(U31) = [2 1] x1 + [1] [0 2] [1] p(U41) = [3 0] x1 + [1 5] x2 + [4 7] x3 + [0] [2 0] [0 1] [1 2] [4] p(activate) = [1 1] x1 + [0] [0 1] [0] p(and) = [1 0] x1 + [1 1] x2 + [4] [0 1] [0 1] [0] p(isNat) = [1 0] x1 + [0] [0 1] [0] p(n__0) = [5] [2] p(n__isNat) = [1 0] x1 + [0] [0 1] [0] p(n__plus) = [1 2] x1 + [1 2] x2 + [4] [0 1] [0 1] [2] p(n__s) = [1 1] x1 + [4] [0 1] [1] p(n__x) = [1 1] x1 + [1 2] x2 + [6] [0 1] [0 1] [0] p(plus) = [1 2] x1 + [1 2] x2 + [4] [0 1] [0 1] [2] p(s) = [1 1] x1 + [4] [0 1] [1] p(tt) = [5] [1] p(x) = [1 1] x1 + [1 2] x2 + [6] [0 1] [0 1] [0] Following rules are strictly oriented: activate(n__plus(X1,X2)) = [1 3] X1 + [1 3] X2 + [6] [0 1] [0 1] [2] > [1 3] X1 + [1 3] X2 + [4] [0 1] [0 1] [2] = plus(activate(X1),activate(X2)) Following rules are (at-least) weakly oriented: 0() = [5] [2] >= [5] [2] = n__0() U11(tt(),N) = [1 1] N + [13] [4 1] [7] >= [1 1] N + [0] [0 1] [0] = activate(N) U21(tt(),M,N) = [1 4] M + [4 6] N + [10] [0 4] [0 1] [8] >= [1 4] M + [1 4] N + [10] [0 1] [0 1] [3] = s(plus(activate(N),activate(M))) U31(tt()) = [12] [3] >= [5] [2] = 0() U41(tt(),M,N) = [1 5] M + [4 7] N + [15] [0 1] [1 2] [14] >= [1 5] M + [2 7] N + [10] [0 1] [0 2] [2] = plus(x(activate(N),activate(M)),activate(N)) activate(X) = [1 1] X + [0] [0 1] [0] >= [1 0] X + [0] [0 1] [0] = X activate(n__0()) = [7] [2] >= [5] [2] = 0() activate(n__isNat(X)) = [1 1] X + [0] [0 1] [0] >= [1 0] X + [0] [0 1] [0] = isNat(X) activate(n__s(X)) = [1 2] X + [5] [0 1] [1] >= [1 2] X + [4] [0 1] [1] = s(activate(X)) activate(n__x(X1,X2)) = [1 2] X1 + [1 3] X2 + [6] [0 1] [0 1] [0] >= [1 2] X1 + [1 3] X2 + [6] [0 1] [0 1] [0] = x(activate(X1),activate(X2)) and(tt(),X) = [1 1] X + [9] [0 1] [1] >= [1 1] X + [0] [0 1] [0] = activate(X) isNat(X) = [1 0] X + [0] [0 1] [0] >= [1 0] X + [0] [0 1] [0] = n__isNat(X) isNat(n__0()) = [5] [2] >= [5] [1] = tt() isNat(n__plus(V1,V2)) = [1 2] V1 + [1 2] V2 + [4] [0 1] [0 1] [2] >= [1 1] V1 + [1 2] V2 + [4] [0 1] [0 1] [0] = and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) = [1 1] V1 + [4] [0 1] [1] >= [1 1] V1 + [0] [0 1] [0] = isNat(activate(V1)) isNat(n__x(V1,V2)) = [1 1] V1 + [1 2] V2 + [6] [0 1] [0 1] [0] >= [1 1] V1 + [1 2] V2 + [4] [0 1] [0 1] [0] = and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) = [1 2] X1 + [1 2] X2 + [4] [0 1] [0 1] [2] >= [1 2] X1 + [1 2] X2 + [4] [0 1] [0 1] [2] = n__plus(X1,X2) s(X) = [1 1] X + [4] [0 1] [1] >= [1 1] X + [4] [0 1] [1] = n__s(X) x(X1,X2) = [1 1] X1 + [1 2] X2 + [6] [0 1] [0 1] [0] >= [1 1] X1 + [1 2] X2 + [6] [0 1] [0 1] [0] = n__x(X1,X2) * Step 14: EmptyProcessor WORST_CASE(?,O(1)) + Considered Problem: - Weak TRS: 0() -> n__0() U11(tt(),N) -> activate(N) U21(tt(),M,N) -> s(plus(activate(N),activate(M))) U31(tt()) -> 0() U41(tt(),M,N) -> plus(x(activate(N),activate(M)),activate(N)) activate(X) -> X activate(n__0()) -> 0() activate(n__isNat(X)) -> isNat(X) activate(n__plus(X1,X2)) -> plus(activate(X1),activate(X2)) activate(n__s(X)) -> s(activate(X)) activate(n__x(X1,X2)) -> x(activate(X1),activate(X2)) and(tt(),X) -> activate(X) isNat(X) -> n__isNat(X) isNat(n__0()) -> tt() isNat(n__plus(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) isNat(n__s(V1)) -> isNat(activate(V1)) isNat(n__x(V1,V2)) -> and(isNat(activate(V1)),n__isNat(activate(V2))) plus(X1,X2) -> n__plus(X1,X2) s(X) -> n__s(X) x(X1,X2) -> n__x(X1,X2) - Signature: {0/0,U11/2,U21/3,U31/1,U41/3,activate/1,and/2,isNat/1,plus/2,s/1,x/2} / {n__0/0,n__isNat/1,n__plus/2,n__s/1 ,n__x/2,tt/0} - Obligation: innermost runtime complexity wrt. defined symbols {0,U11,U21,U31,U41,activate,and,isNat,plus,s ,x} and constructors {n__0,n__isNat,n__plus,n__s,n__x,tt} + Applied Processor: EmptyProcessor + Details: The problem is already closed. The intended complexity is O(1). WORST_CASE(?,O(n^2))