'Weak Dependency Graph [60.0]' ------------------------------ Answer: YES(?,O(n^1)) Input Problem: innermost runtime-complexity with respect to Rules: { a(x1) -> b(x1) , a(b(x1)) -> x1 , c(c(b(x1))) -> a(c(a(c(c(x1)))))} Details: We have computed the following set of weak (innermost) dependency pairs: { a^#(x1) -> c_0() , a^#(b(x1)) -> c_1() , c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1))))))} The usable rules are: { a(x1) -> b(x1) , a(b(x1)) -> x1 , c(c(b(x1))) -> a(c(a(c(c(x1)))))} The estimated dependency graph contains the following edges: {c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1))))))} ==> {a^#(b(x1)) -> c_1()} {c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1))))))} ==> {a^#(x1) -> c_0()} We consider the following path(s): 1) { c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1)))))) , a^#(b(x1)) -> c_1()} The usable rules for this path are the following: { a(x1) -> b(x1) , a(b(x1)) -> x1 , c(c(b(x1))) -> a(c(a(c(c(x1)))))} We have applied the subprocessor on the union of usable rules and weak (innermost) dependency pairs. 'Weight Gap Principle' ---------------------- Answer: YES(?,O(n^1)) Input Problem: innermost runtime-complexity with respect to Rules: { a(x1) -> b(x1) , a(b(x1)) -> x1 , c(c(b(x1))) -> a(c(a(c(c(x1))))) , c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1)))))) , a^#(b(x1)) -> c_1()} Details: We apply the weight gap principle, strictly orienting the rules { a(x1) -> b(x1) , a(b(x1)) -> x1} and weakly orienting the rules {} using the following strongly linear interpretation: Processor 'Matrix Interpretation' oriented the following rules strictly: { a(x1) -> b(x1) , a(b(x1)) -> x1} Details: Interpretation Functions: a(x1) = [1] x1 + [1] b(x1) = [1] x1 + [0] c(x1) = [1] x1 + [0] a^#(x1) = [1] x1 + [0] c_0() = [0] c_1() = [0] c^#(x1) = [1] x1 + [1] c_2(x1) = [1] x1 + [0] Finally we apply the subprocessor We apply the weight gap principle, strictly orienting the rules {c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1))))))} and weakly orienting the rules { a(x1) -> b(x1) , a(b(x1)) -> x1} using the following strongly linear interpretation: Processor 'Matrix Interpretation' oriented the following rules strictly: {c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1))))))} Details: Interpretation Functions: a(x1) = [1] x1 + [0] b(x1) = [1] x1 + [0] c(x1) = [1] x1 + [0] a^#(x1) = [1] x1 + [0] c_0() = [0] c_1() = [0] c^#(x1) = [1] x1 + [1] c_2(x1) = [1] x1 + [0] Finally we apply the subprocessor We apply the weight gap principle, strictly orienting the rules {a^#(b(x1)) -> c_1()} and weakly orienting the rules { c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1)))))) , a(x1) -> b(x1) , a(b(x1)) -> x1} using the following strongly linear interpretation: Processor 'Matrix Interpretation' oriented the following rules strictly: {a^#(b(x1)) -> c_1()} Details: Interpretation Functions: a(x1) = [1] x1 + [0] b(x1) = [1] x1 + [0] c(x1) = [1] x1 + [0] a^#(x1) = [1] x1 + [1] c_0() = [0] c_1() = [0] c^#(x1) = [1] x1 + [1] c_2(x1) = [1] x1 + [0] Finally we apply the subprocessor 'fastest of 'combine', 'Bounds with default enrichment', 'Bounds with default enrichment'' ------------------------------------------------------------------------------------------ Answer: YES(?,O(n^1)) Input Problem: innermost relative runtime-complexity with respect to Strict Rules: {c(c(b(x1))) -> a(c(a(c(c(x1)))))} Weak Rules: { a^#(b(x1)) -> c_1() , c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1)))))) , a(x1) -> b(x1) , a(b(x1)) -> x1} Details: The problem was solved by processor 'Bounds with default enrichment': 'Bounds with default enrichment' -------------------------------- Answer: YES(?,O(n^1)) Input Problem: innermost relative runtime-complexity with respect to Strict Rules: {c(c(b(x1))) -> a(c(a(c(c(x1)))))} Weak Rules: { a^#(b(x1)) -> c_1() , c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1)))))) , a(x1) -> b(x1) , a(b(x1)) -> x1} Details: The problem is Match-bounded by 0. The enriched problem is compatible with the following automaton: { b_0(2) -> 2 , a^#_0(2) -> 1 , c_1_0() -> 1 , c^#_0(2) -> 1} 2) { c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1)))))) , a^#(x1) -> c_0()} The usable rules for this path are the following: { a(x1) -> b(x1) , a(b(x1)) -> x1 , c(c(b(x1))) -> a(c(a(c(c(x1)))))} We have applied the subprocessor on the union of usable rules and weak (innermost) dependency pairs. 'Weight Gap Principle' ---------------------- Answer: YES(?,O(n^1)) Input Problem: innermost runtime-complexity with respect to Rules: { a(x1) -> b(x1) , a(b(x1)) -> x1 , c(c(b(x1))) -> a(c(a(c(c(x1))))) , c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1)))))) , a^#(x1) -> c_0()} Details: We apply the weight gap principle, strictly orienting the rules { a(x1) -> b(x1) , a(b(x1)) -> x1} and weakly orienting the rules {} using the following strongly linear interpretation: Processor 'Matrix Interpretation' oriented the following rules strictly: { a(x1) -> b(x1) , a(b(x1)) -> x1} Details: Interpretation Functions: a(x1) = [1] x1 + [1] b(x1) = [1] x1 + [0] c(x1) = [1] x1 + [0] a^#(x1) = [1] x1 + [0] c_0() = [0] c_1() = [0] c^#(x1) = [1] x1 + [1] c_2(x1) = [1] x1 + [0] Finally we apply the subprocessor We apply the weight gap principle, strictly orienting the rules {c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1))))))} and weakly orienting the rules { a(x1) -> b(x1) , a(b(x1)) -> x1} using the following strongly linear interpretation: Processor 'Matrix Interpretation' oriented the following rules strictly: {c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1))))))} Details: Interpretation Functions: a(x1) = [1] x1 + [0] b(x1) = [1] x1 + [0] c(x1) = [1] x1 + [0] a^#(x1) = [1] x1 + [0] c_0() = [0] c_1() = [0] c^#(x1) = [1] x1 + [1] c_2(x1) = [1] x1 + [0] Finally we apply the subprocessor We apply the weight gap principle, strictly orienting the rules {a^#(x1) -> c_0()} and weakly orienting the rules { c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1)))))) , a(x1) -> b(x1) , a(b(x1)) -> x1} using the following strongly linear interpretation: Processor 'Matrix Interpretation' oriented the following rules strictly: {a^#(x1) -> c_0()} Details: Interpretation Functions: a(x1) = [1] x1 + [0] b(x1) = [1] x1 + [0] c(x1) = [1] x1 + [0] a^#(x1) = [1] x1 + [1] c_0() = [0] c_1() = [0] c^#(x1) = [1] x1 + [4] c_2(x1) = [1] x1 + [2] Finally we apply the subprocessor 'fastest of 'combine', 'Bounds with default enrichment', 'Bounds with default enrichment'' ------------------------------------------------------------------------------------------ Answer: YES(?,O(n^1)) Input Problem: innermost relative runtime-complexity with respect to Strict Rules: {c(c(b(x1))) -> a(c(a(c(c(x1)))))} Weak Rules: { a^#(x1) -> c_0() , c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1)))))) , a(x1) -> b(x1) , a(b(x1)) -> x1} Details: The problem was solved by processor 'Bounds with default enrichment': 'Bounds with default enrichment' -------------------------------- Answer: YES(?,O(n^1)) Input Problem: innermost relative runtime-complexity with respect to Strict Rules: {c(c(b(x1))) -> a(c(a(c(c(x1)))))} Weak Rules: { a^#(x1) -> c_0() , c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1)))))) , a(x1) -> b(x1) , a(b(x1)) -> x1} Details: The problem is Match-bounded by 0. The enriched problem is compatible with the following automaton: { b_0(2) -> 2 , a^#_0(2) -> 4 , c_0_0() -> 4 , c^#_0(2) -> 7} 3) {c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1))))))} The usable rules for this path are the following: { a(x1) -> b(x1) , a(b(x1)) -> x1 , c(c(b(x1))) -> a(c(a(c(c(x1)))))} We have applied the subprocessor on the union of usable rules and weak (innermost) dependency pairs. 'Weight Gap Principle' ---------------------- Answer: YES(?,O(n^1)) Input Problem: innermost runtime-complexity with respect to Rules: { a(x1) -> b(x1) , a(b(x1)) -> x1 , c(c(b(x1))) -> a(c(a(c(c(x1))))) , c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1))))))} Details: We apply the weight gap principle, strictly orienting the rules { a(x1) -> b(x1) , a(b(x1)) -> x1} and weakly orienting the rules {} using the following strongly linear interpretation: Processor 'Matrix Interpretation' oriented the following rules strictly: { a(x1) -> b(x1) , a(b(x1)) -> x1} Details: Interpretation Functions: a(x1) = [1] x1 + [1] b(x1) = [1] x1 + [0] c(x1) = [1] x1 + [0] a^#(x1) = [1] x1 + [0] c_0() = [0] c_1() = [0] c^#(x1) = [1] x1 + [1] c_2(x1) = [1] x1 + [0] Finally we apply the subprocessor We apply the weight gap principle, strictly orienting the rules {c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1))))))} and weakly orienting the rules { a(x1) -> b(x1) , a(b(x1)) -> x1} using the following strongly linear interpretation: Processor 'Matrix Interpretation' oriented the following rules strictly: {c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1))))))} Details: Interpretation Functions: a(x1) = [1] x1 + [0] b(x1) = [1] x1 + [0] c(x1) = [1] x1 + [0] a^#(x1) = [1] x1 + [0] c_0() = [0] c_1() = [0] c^#(x1) = [1] x1 + [1] c_2(x1) = [1] x1 + [0] Finally we apply the subprocessor 'fastest of 'combine', 'Bounds with default enrichment', 'Bounds with default enrichment'' ------------------------------------------------------------------------------------------ Answer: YES(?,O(n^1)) Input Problem: innermost relative runtime-complexity with respect to Strict Rules: {c(c(b(x1))) -> a(c(a(c(c(x1)))))} Weak Rules: { c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1)))))) , a(x1) -> b(x1) , a(b(x1)) -> x1} Details: The problem was solved by processor 'Bounds with default enrichment': 'Bounds with default enrichment' -------------------------------- Answer: YES(?,O(n^1)) Input Problem: innermost relative runtime-complexity with respect to Strict Rules: {c(c(b(x1))) -> a(c(a(c(c(x1)))))} Weak Rules: { c^#(c(b(x1))) -> c_2(a^#(c(a(c(c(x1)))))) , a(x1) -> b(x1) , a(b(x1)) -> x1} Details: The problem is Match-bounded by 0. The enriched problem is compatible with the following automaton: { b_0(2) -> 2 , a^#_0(2) -> 4 , c^#_0(2) -> 7}