Termination w.r.t. Q of the following Term Rewriting System could be proven:
Q restricted rewrite system:
The TRS R consists of the following rules:
a(b(x1)) → b(c(a(x1)))
b(c(x1)) → c(b(b(x1)))
b(a(x1)) → a(c(b(x1)))
Q is empty.
↳ QTRS
↳ QTRS Reverse
↳ QTRS Reverse
↳ DependencyPairsProof
Q restricted rewrite system:
The TRS R consists of the following rules:
a(b(x1)) → b(c(a(x1)))
b(c(x1)) → c(b(b(x1)))
b(a(x1)) → a(c(b(x1)))
Q is empty.
We have reversed the following QTRS:
The set of rules R is
a(b(x1)) → b(c(a(x1)))
b(c(x1)) → c(b(b(x1)))
b(a(x1)) → a(c(b(x1)))
The set Q is empty.
We have obtained the following QTRS:
b(a(x)) → a(c(b(x)))
c(b(x)) → b(b(c(x)))
a(b(x)) → b(c(a(x)))
The set Q is empty.
↳ QTRS
↳ QTRS Reverse
↳ QTRS
↳ QTRS Reverse
↳ DependencyPairsProof
Q restricted rewrite system:
The TRS R consists of the following rules:
b(a(x)) → a(c(b(x)))
c(b(x)) → b(b(c(x)))
a(b(x)) → b(c(a(x)))
Q is empty.
We have reversed the following QTRS:
The set of rules R is
a(b(x1)) → b(c(a(x1)))
b(c(x1)) → c(b(b(x1)))
b(a(x1)) → a(c(b(x1)))
The set Q is empty.
We have obtained the following QTRS:
b(a(x)) → a(c(b(x)))
c(b(x)) → b(b(c(x)))
a(b(x)) → b(c(a(x)))
The set Q is empty.
↳ QTRS
↳ QTRS Reverse
↳ QTRS Reverse
↳ QTRS
↳ DependencyPairsProof
Q restricted rewrite system:
The TRS R consists of the following rules:
b(a(x)) → a(c(b(x)))
c(b(x)) → b(b(c(x)))
a(b(x)) → b(c(a(x)))
Q is empty.
Using Dependency Pairs [1,15] we result in the following initial DP problem:
Q DP problem:
The TRS P consists of the following rules:
A(b(x1)) → B(c(a(x1)))
B(a(x1)) → A(c(b(x1)))
B(a(x1)) → B(x1)
B(c(x1)) → B(x1)
B(c(x1)) → B(b(x1))
A(b(x1)) → A(x1)
The TRS R consists of the following rules:
a(b(x1)) → b(c(a(x1)))
b(c(x1)) → c(b(b(x1)))
b(a(x1)) → a(c(b(x1)))
Q is empty.
We have to consider all minimal (P,Q,R)-chains.
↳ QTRS
↳ QTRS Reverse
↳ QTRS Reverse
↳ DependencyPairsProof
↳ QDP
↳ DependencyGraphProof
Q DP problem:
The TRS P consists of the following rules:
A(b(x1)) → B(c(a(x1)))
B(a(x1)) → A(c(b(x1)))
B(a(x1)) → B(x1)
B(c(x1)) → B(x1)
B(c(x1)) → B(b(x1))
A(b(x1)) → A(x1)
The TRS R consists of the following rules:
a(b(x1)) → b(c(a(x1)))
b(c(x1)) → c(b(b(x1)))
b(a(x1)) → a(c(b(x1)))
Q is empty.
We have to consider all minimal (P,Q,R)-chains.
The approximation of the Dependency Graph [15,17,22] contains 2 SCCs with 2 less nodes.
↳ QTRS
↳ QTRS Reverse
↳ QTRS Reverse
↳ DependencyPairsProof
↳ QDP
↳ DependencyGraphProof
↳ AND
↳ QDP
↳ UsableRulesProof
↳ UsableRulesProof
↳ QDP
Q DP problem:
The TRS P consists of the following rules:
B(a(x1)) → B(x1)
B(c(x1)) → B(b(x1))
B(c(x1)) → B(x1)
The TRS R consists of the following rules:
a(b(x1)) → b(c(a(x1)))
b(c(x1)) → c(b(b(x1)))
b(a(x1)) → a(c(b(x1)))
Q is empty.
We have to consider all minimal (P,Q,R)-chains.
We can use the usable rules and reduction pair processor [15] with the Ce-compatible extension of the polynomial order that maps every function symbol to the sum of its argument. Then, we can delete all non-usable rules [17] from R.
↳ QTRS
↳ QTRS Reverse
↳ QTRS Reverse
↳ DependencyPairsProof
↳ QDP
↳ DependencyGraphProof
↳ AND
↳ QDP
↳ UsableRulesProof
↳ QDP
↳ MNOCProof
↳ UsableRulesProof
↳ QDP
Q DP problem:
The TRS P consists of the following rules:
B(a(x1)) → B(x1)
B(c(x1)) → B(x1)
B(c(x1)) → B(b(x1))
The TRS R consists of the following rules:
b(c(x1)) → c(b(b(x1)))
b(a(x1)) → a(c(b(x1)))
Q is empty.
We have to consider all minimal (P,Q,R)-chains.
We use the modular non-overlap check [15] to enlarge Q to all left-hand sides of R.
↳ QTRS
↳ QTRS Reverse
↳ QTRS Reverse
↳ DependencyPairsProof
↳ QDP
↳ DependencyGraphProof
↳ AND
↳ QDP
↳ UsableRulesProof
↳ QDP
↳ MNOCProof
↳ QDP
↳ MNOCProof
↳ UsableRulesProof
↳ QDP
Q DP problem:
The TRS P consists of the following rules:
B(a(x1)) → B(x1)
B(c(x1)) → B(b(x1))
B(c(x1)) → B(x1)
The TRS R consists of the following rules:
b(c(x1)) → c(b(b(x1)))
b(a(x1)) → a(c(b(x1)))
The set Q consists of the following terms:
b(c(x0))
b(a(x0))
We have to consider all minimal (P,Q,R)-chains.
We use the modular non-overlap check [17] to decrease Q to the empty set.
↳ QTRS
↳ QTRS Reverse
↳ QTRS Reverse
↳ DependencyPairsProof
↳ QDP
↳ DependencyGraphProof
↳ AND
↳ QDP
↳ UsableRulesProof
↳ QDP
↳ MNOCProof
↳ QDP
↳ MNOCProof
↳ QDP
↳ UsableRulesProof
↳ QDP
Q DP problem:
The TRS P consists of the following rules:
B(a(x1)) → B(x1)
B(c(x1)) → B(x1)
B(c(x1)) → B(b(x1))
The TRS R consists of the following rules:
b(c(x1)) → c(b(b(x1)))
b(a(x1)) → a(c(b(x1)))
Q is empty.
We have to consider all (P,Q,R)-chains.
We can use the usable rules and reduction pair processor [15] with the Ce-compatible extension of the polynomial order that maps every function symbol to the sum of its argument. Then, we can delete all non-usable rules [17] from R.
↳ QTRS
↳ QTRS Reverse
↳ QTRS Reverse
↳ DependencyPairsProof
↳ QDP
↳ DependencyGraphProof
↳ AND
↳ QDP
↳ UsableRulesProof
↳ UsableRulesProof
↳ QDP
↳ MNOCProof
↳ QDP
Q DP problem:
The TRS P consists of the following rules:
B(a(x1)) → B(x1)
B(c(x1)) → B(x1)
B(c(x1)) → B(b(x1))
The TRS R consists of the following rules:
b(c(x1)) → c(b(b(x1)))
b(a(x1)) → a(c(b(x1)))
Q is empty.
We have to consider all minimal (P,Q,R)-chains.
We use the modular non-overlap check [15] to enlarge Q to all left-hand sides of R.
↳ QTRS
↳ QTRS Reverse
↳ QTRS Reverse
↳ DependencyPairsProof
↳ QDP
↳ DependencyGraphProof
↳ AND
↳ QDP
↳ UsableRulesProof
↳ UsableRulesProof
↳ QDP
↳ MNOCProof
↳ QDP
↳ RuleRemovalProof
↳ QDP
Q DP problem:
The TRS P consists of the following rules:
B(a(x1)) → B(x1)
B(c(x1)) → B(b(x1))
B(c(x1)) → B(x1)
The TRS R consists of the following rules:
b(c(x1)) → c(b(b(x1)))
b(a(x1)) → a(c(b(x1)))
The set Q consists of the following terms:
b(c(x0))
b(a(x0))
We have to consider all minimal (P,Q,R)-chains.
By using the rule removal processor [15] with the following polynomial ordering [25], at least one Dependency Pair or term rewrite system rule of this QDP problem can be strictly oriented.
Strictly oriented dependency pairs:
B(a(x1)) → B(x1)
Used ordering: POLO with Polynomial interpretation [25]:
POL(B(x1)) = x1
POL(a(x1)) = 1 + 2·x1
POL(b(x1)) = x1
POL(c(x1)) = x1
↳ QTRS
↳ QTRS Reverse
↳ QTRS Reverse
↳ DependencyPairsProof
↳ QDP
↳ DependencyGraphProof
↳ AND
↳ QDP
↳ UsableRulesProof
↳ UsableRulesProof
↳ QDP
↳ MNOCProof
↳ QDP
↳ RuleRemovalProof
↳ QDP
↳ QDPOrderProof
↳ QDP
Q DP problem:
The TRS P consists of the following rules:
B(c(x1)) → B(x1)
B(c(x1)) → B(b(x1))
The TRS R consists of the following rules:
b(c(x1)) → c(b(b(x1)))
b(a(x1)) → a(c(b(x1)))
The set Q consists of the following terms:
b(c(x0))
b(a(x0))
We have to consider all minimal (P,Q,R)-chains.
We use the reduction pair processor [15].
The following pairs can be oriented strictly and are deleted.
B(c(x1)) → B(x1)
B(c(x1)) → B(b(x1))
The remaining pairs can at least be oriented weakly.
none
Used ordering: Polynomial Order [21,25] with Interpretation:
POL( c(x1) ) = x1 + 1
POL( b(x1) ) = x1
POL( B(x1) ) = x1 + 1
POL( a(x1) ) = max{0, -1}
The following usable rules [17] were oriented:
b(c(x1)) → c(b(b(x1)))
b(a(x1)) → a(c(b(x1)))
↳ QTRS
↳ QTRS Reverse
↳ QTRS Reverse
↳ DependencyPairsProof
↳ QDP
↳ DependencyGraphProof
↳ AND
↳ QDP
↳ UsableRulesProof
↳ UsableRulesProof
↳ QDP
↳ MNOCProof
↳ QDP
↳ RuleRemovalProof
↳ QDP
↳ QDPOrderProof
↳ QDP
↳ PisEmptyProof
↳ QDP
Q DP problem:
P is empty.
The TRS R consists of the following rules:
b(c(x1)) → c(b(b(x1)))
b(a(x1)) → a(c(b(x1)))
The set Q consists of the following terms:
b(c(x0))
b(a(x0))
We have to consider all minimal (P,Q,R)-chains.
The TRS P is empty. Hence, there is no (P,Q,R) chain.
↳ QTRS
↳ QTRS Reverse
↳ QTRS Reverse
↳ DependencyPairsProof
↳ QDP
↳ DependencyGraphProof
↳ AND
↳ QDP
↳ QDP
↳ UsableRulesProof
↳ UsableRulesProof
Q DP problem:
The TRS P consists of the following rules:
A(b(x1)) → A(x1)
The TRS R consists of the following rules:
a(b(x1)) → b(c(a(x1)))
b(c(x1)) → c(b(b(x1)))
b(a(x1)) → a(c(b(x1)))
Q is empty.
We have to consider all minimal (P,Q,R)-chains.
We can use the usable rules and reduction pair processor [15] with the Ce-compatible extension of the polynomial order that maps every function symbol to the sum of its argument. Then, we can delete all non-usable rules [17] from R.
↳ QTRS
↳ QTRS Reverse
↳ QTRS Reverse
↳ DependencyPairsProof
↳ QDP
↳ DependencyGraphProof
↳ AND
↳ QDP
↳ QDP
↳ UsableRulesProof
↳ QDP
↳ UsableRulesReductionPairsProof
↳ UsableRulesProof
Q DP problem:
The TRS P consists of the following rules:
A(b(x1)) → A(x1)
R is empty.
Q is empty.
We have to consider all minimal (P,Q,R)-chains.
By using the usable rules with reduction pair processor [15] with a polynomial ordering [25], all dependency pairs and the corresponding usable rules [17] can be oriented non-strictly. All non-usable rules are removed, and those dependency pairs and usable rules that have been oriented strictly or contain non-usable symbols in their left-hand side are removed as well.
The following dependency pairs can be deleted:
A(b(x1)) → A(x1)
No rules are removed from R.
Used ordering: POLO with Polynomial interpretation [25]:
POL(A(x1)) = 2·x1
POL(b(x1)) = 2·x1
↳ QTRS
↳ QTRS Reverse
↳ QTRS Reverse
↳ DependencyPairsProof
↳ QDP
↳ DependencyGraphProof
↳ AND
↳ QDP
↳ QDP
↳ UsableRulesProof
↳ QDP
↳ UsableRulesReductionPairsProof
↳ QDP
↳ PisEmptyProof
↳ UsableRulesProof
Q DP problem:
P is empty.
R is empty.
Q is empty.
We have to consider all minimal (P,Q,R)-chains.
The TRS P is empty. Hence, there is no (P,Q,R) chain.
We can use the usable rules and reduction pair processor [15] with the Ce-compatible extension of the polynomial order that maps every function symbol to the sum of its argument. Then, we can delete all non-usable rules [17] from R.
↳ QTRS
↳ QTRS Reverse
↳ QTRS Reverse
↳ DependencyPairsProof
↳ QDP
↳ DependencyGraphProof
↳ AND
↳ QDP
↳ QDP
↳ UsableRulesProof
↳ UsableRulesProof
↳ QDP
Q DP problem:
The TRS P consists of the following rules:
A(b(x1)) → A(x1)
R is empty.
Q is empty.
We have to consider all minimal (P,Q,R)-chains.