MAYBE * Step 1: InnermostRuleRemoval MAYBE + Considered Problem: - Strict TRS: f(f(x)) -> b() f(g(a())) -> f(s(g(b()))) g(x) -> f(g(x)) - Signature: {f/1,g/1} / {a/0,b/0,s/1} - Obligation: innermost runtime complexity wrt. defined symbols {f,g} and constructors {a,b,s} + Applied Processor: InnermostRuleRemoval + Details: Arguments of following rules are not normal-forms. f(g(a())) -> f(s(g(b()))) All above mentioned rules can be savely removed. * Step 2: DependencyPairs MAYBE + Considered Problem: - Strict TRS: f(f(x)) -> b() g(x) -> f(g(x)) - Signature: {f/1,g/1} / {a/0,b/0,s/1} - Obligation: innermost runtime complexity wrt. defined symbols {f,g} and constructors {a,b,s} + Applied Processor: DependencyPairs {dpKind_ = DT} + Details: We add the following dependency tuples: Strict DPs f#(f(x)) -> c_1() g#(x) -> c_2(f#(g(x)),g#(x)) Weak DPs and mark the set of starting terms. * Step 3: PredecessorEstimation MAYBE + Considered Problem: - Strict DPs: f#(f(x)) -> c_1() g#(x) -> c_2(f#(g(x)),g#(x)) - Weak TRS: f(f(x)) -> b() g(x) -> f(g(x)) - Signature: {f/1,g/1,f#/1,g#/1} / {a/0,b/0,s/1,c_1/0,c_2/2} - Obligation: innermost runtime complexity wrt. defined symbols {f#,g#} and constructors {a,b,s} + Applied Processor: PredecessorEstimation {onSelection = all simple predecessor estimation selector} + Details: We estimate the number of application of {1} by application of Pre({1}) = {2}. Here rules are labelled as follows: 1: f#(f(x)) -> c_1() 2: g#(x) -> c_2(f#(g(x)),g#(x)) * Step 4: RemoveWeakSuffixes MAYBE + Considered Problem: - Strict DPs: g#(x) -> c_2(f#(g(x)),g#(x)) - Weak DPs: f#(f(x)) -> c_1() - Weak TRS: f(f(x)) -> b() g(x) -> f(g(x)) - Signature: {f/1,g/1,f#/1,g#/1} / {a/0,b/0,s/1,c_1/0,c_2/2} - Obligation: innermost runtime complexity wrt. defined symbols {f#,g#} and constructors {a,b,s} + Applied Processor: RemoveWeakSuffixes + Details: Consider the dependency graph 1:S:g#(x) -> c_2(f#(g(x)),g#(x)) -->_1 f#(f(x)) -> c_1():2 -->_2 g#(x) -> c_2(f#(g(x)),g#(x)):1 2:W:f#(f(x)) -> c_1() The following weak DPs constitute a sub-graph of the DG that is closed under successors. The DPs are removed. 2: f#(f(x)) -> c_1() * Step 5: SimplifyRHS MAYBE + Considered Problem: - Strict DPs: g#(x) -> c_2(f#(g(x)),g#(x)) - Weak TRS: f(f(x)) -> b() g(x) -> f(g(x)) - Signature: {f/1,g/1,f#/1,g#/1} / {a/0,b/0,s/1,c_1/0,c_2/2} - Obligation: innermost runtime complexity wrt. defined symbols {f#,g#} and constructors {a,b,s} + Applied Processor: SimplifyRHS + Details: Consider the dependency graph 1:S:g#(x) -> c_2(f#(g(x)),g#(x)) -->_2 g#(x) -> c_2(f#(g(x)),g#(x)):1 Due to missing edges in the depndency graph, the right-hand sides of following rules could be simplified: g#(x) -> c_2(g#(x)) * Step 6: UsableRules MAYBE + Considered Problem: - Strict DPs: g#(x) -> c_2(g#(x)) - Weak TRS: f(f(x)) -> b() g(x) -> f(g(x)) - Signature: {f/1,g/1,f#/1,g#/1} / {a/0,b/0,s/1,c_1/0,c_2/1} - Obligation: innermost runtime complexity wrt. defined symbols {f#,g#} and constructors {a,b,s} + Applied Processor: UsableRules + Details: We replace rewrite rules by usable rules: g#(x) -> c_2(g#(x)) * Step 7: Failure MAYBE + Considered Problem: - Strict DPs: g#(x) -> c_2(g#(x)) - Signature: {f/1,g/1,f#/1,g#/1} / {a/0,b/0,s/1,c_1/0,c_2/1} - Obligation: innermost runtime complexity wrt. defined symbols {f#,g#} and constructors {a,b,s} + Applied Processor: EmptyProcessor + Details: The problem is still open. MAYBE