Certification Problem

Input (TPDB SRS_Standard/Zantema_04/z005)

The rewrite relation of the following TRS is considered.

a(c(b(x1)))	→	b(a(b(a(x1))))	(1)
b(x1)	→	c(a(c(x1)))	(2)
a(a(x1))	→	a(b(c(a(x1))))	(3)

Property / Task

Prove or disprove termination.

Answer / Result

Yes.

Proof (by AProVE @ termCOMP 2023)

1 String Reversal

Since only unary symbols occur, one can reverse all terms and obtains the TRS

b(c(a(x1)))	→	a(b(a(b(x1))))	(4)
b(x1)	→	c(a(c(x1)))	(2)
a(a(x1))	→	a(c(b(a(x1))))	(5)

1.1 Closure Under Flat Contexts

Using the flat contexts

{b(☐), c(☐), a(☐)}

We obtain the transformed TRS

a(a(x1))	→	a(c(b(a(x1))))	(5)
b(b(c(a(x1))))	→	b(a(b(a(b(x1)))))	(6)
c(b(c(a(x1))))	→	c(a(b(a(b(x1)))))	(7)
a(b(c(a(x1))))	→	a(a(b(a(b(x1)))))	(8)
b(b(x1))	→	b(c(a(c(x1))))	(9)
c(b(x1))	→	c(c(a(c(x1))))	(10)
a(b(x1))	→	a(c(a(c(x1))))	(11)

1.1.1 Semantic Labeling

Root-labeling is applied.

We obtain the labeled TRS

a_a(a_a(x1))	→	a_c(c_b(b_a(a_a(x1))))	(12)
a_a(a_c(x1))	→	a_c(c_b(b_a(a_c(x1))))	(13)
a_a(a_b(x1))	→	a_c(c_b(b_a(a_b(x1))))	(14)
b_b(b_c(c_a(a_a(x1))))	→	b_a(a_b(b_a(a_b(b_a(x1)))))	(15)
b_b(b_c(c_a(a_c(x1))))	→	b_a(a_b(b_a(a_b(b_c(x1)))))	(16)
b_b(b_c(c_a(a_b(x1))))	→	b_a(a_b(b_a(a_b(b_b(x1)))))	(17)
c_b(b_c(c_a(a_a(x1))))	→	c_a(a_b(b_a(a_b(b_a(x1)))))	(18)
c_b(b_c(c_a(a_c(x1))))	→	c_a(a_b(b_a(a_b(b_c(x1)))))	(19)
c_b(b_c(c_a(a_b(x1))))	→	c_a(a_b(b_a(a_b(b_b(x1)))))	(20)
a_b(b_c(c_a(a_a(x1))))	→	a_a(a_b(b_a(a_b(b_a(x1)))))	(21)
a_b(b_c(c_a(a_c(x1))))	→	a_a(a_b(b_a(a_b(b_c(x1)))))	(22)
a_b(b_c(c_a(a_b(x1))))	→	a_a(a_b(b_a(a_b(b_b(x1)))))	(23)
b_b(b_a(x1))	→	b_c(c_a(a_c(c_a(x1))))	(24)
b_b(b_c(x1))	→	b_c(c_a(a_c(c_c(x1))))	(25)
b_b(b_b(x1))	→	b_c(c_a(a_c(c_b(x1))))	(26)
c_b(b_a(x1))	→	c_c(c_a(a_c(c_a(x1))))	(27)
c_b(b_c(x1))	→	c_c(c_a(a_c(c_c(x1))))	(28)
c_b(b_b(x1))	→	c_c(c_a(a_c(c_b(x1))))	(29)
a_b(b_a(x1))	→	a_c(c_a(a_c(c_a(x1))))	(30)
a_b(b_c(x1))	→	a_c(c_a(a_c(c_c(x1))))	(31)
a_b(b_b(x1))	→	a_c(c_a(a_c(c_b(x1))))	(32)

1.1.1.1 Rule Removal

Using the linear polynomial interpretation over the naturals

[a_a(x₁)]	=	1 · x₁
[a_c(x₁)]	=	1 · x₁
[c_b(x₁)]	=	1 · x₁
[b_a(x₁)]	=	1 · x₁
[a_b(x₁)]	=	1 · x₁
[b_b(x₁)]	=	1 · x₁ + 1
[b_c(x₁)]	=	1 · x₁ + 1
[c_a(x₁)]	=	1 · x₁
[c_c(x₁)]	=	1 · x₁

all of the following rules can be deleted.

b_b(b_c(c_a(a_a(x1))))	→	b_a(a_b(b_a(a_b(b_a(x1)))))	(15)
b_b(b_c(c_a(a_c(x1))))	→	b_a(a_b(b_a(a_b(b_c(x1)))))	(16)
b_b(b_c(c_a(a_b(x1))))	→	b_a(a_b(b_a(a_b(b_b(x1)))))	(17)
c_b(b_c(c_a(a_a(x1))))	→	c_a(a_b(b_a(a_b(b_a(x1)))))	(18)
a_b(b_c(c_a(a_a(x1))))	→	a_a(a_b(b_a(a_b(b_a(x1)))))	(21)
b_b(b_c(x1))	→	b_c(c_a(a_c(c_c(x1))))	(25)
b_b(b_b(x1))	→	b_c(c_a(a_c(c_b(x1))))	(26)
c_b(b_c(x1))	→	c_c(c_a(a_c(c_c(x1))))	(28)
c_b(b_b(x1))	→	c_c(c_a(a_c(c_b(x1))))	(29)
a_b(b_c(x1))	→	a_c(c_a(a_c(c_c(x1))))	(31)
a_b(b_b(x1))	→	a_c(c_a(a_c(c_b(x1))))	(32)

1.1.1.1.1 Dependency Pair Transformation

The following set of initial dependency pairs has been identified.

a_a^#(a_a(x1))	→	c_b^#(b_a(a_a(x1)))	(33)
a_a^#(a_c(x1))	→	c_b^#(b_a(a_c(x1)))	(34)
a_a^#(a_b(x1))	→	c_b^#(b_a(a_b(x1)))	(35)
c_b^#(b_c(c_a(a_c(x1))))	→	a_b^#(b_a(a_b(b_c(x1))))	(36)
c_b^#(b_c(c_a(a_c(x1))))	→	a_b^#(b_c(x1))	(37)
c_b^#(b_c(c_a(a_b(x1))))	→	a_b^#(b_a(a_b(b_b(x1))))	(38)
c_b^#(b_c(c_a(a_b(x1))))	→	a_b^#(b_b(x1))	(39)
c_b^#(b_c(c_a(a_b(x1))))	→	b_b^#(x1)	(40)
a_b^#(b_c(c_a(a_c(x1))))	→	a_a^#(a_b(b_a(a_b(b_c(x1)))))	(41)
a_b^#(b_c(c_a(a_c(x1))))	→	a_b^#(b_a(a_b(b_c(x1))))	(42)
a_b^#(b_c(c_a(a_c(x1))))	→	a_b^#(b_c(x1))	(43)
a_b^#(b_c(c_a(a_b(x1))))	→	a_a^#(a_b(b_a(a_b(b_b(x1)))))	(44)
a_b^#(b_c(c_a(a_b(x1))))	→	a_b^#(b_a(a_b(b_b(x1))))	(45)
a_b^#(b_c(c_a(a_b(x1))))	→	a_b^#(b_b(x1))	(46)
a_b^#(b_c(c_a(a_b(x1))))	→	b_b^#(x1)	(47)

1.1.1.1.1.1 Dependency Graph Processor

The dependency pairs are split into 1 component.

The 1^st component contains the pair

a_b^#(b_c(c_a(a_b(x1)))) → a_b^#(b_b(x1)) (46)

a_b^#(b_c(c_a(a_c(x1)))) → a_b^#(b_c(x1)) (43)

1.1.1.1.1.1.1 Monotonic Reduction Pair Processor with Usable Rules
Using the linear polynomial interpretation over the naturals

[b_b(x₁)] = 1 · x₁

[b_a(x₁)] = 1 · x₁

[b_c(x₁)] = 1 · x₁

[c_a(x₁)] = 1 · x₁

[a_c(x₁)] = 1 · x₁

[a_b(x₁)] = 1 · x₁

[a_b^#(x₁)] = 1 · x₁

together with the usable rule
b_b(b_a(x1)) → b_c(c_a(a_c(c_a(x1)))) (24)
(w.r.t. the implicit argument filter of the reduction pair), the rule could be deleted.
1.1.1.1.1.1.1.1 Switch to Innermost Termination
The TRS does not have overlaps with the pairs and is locally confluent:
20
Hence, it suffices to show innermost termination in the following.
1.1.1.1.1.1.1.1.1 Reduction Pair Processor
Using the linear polynomial interpretation over the naturals

[a_b^#(x₁)] = 1 · x₁

[b_c(x₁)] = 1 · x₁

[c_a(x₁)] = 1 + 1 · x₁

[a_b(x₁)] = 1 + 1 · x₁

[b_b(x₁)] = 1 + 1 · x₁

[a_c(x₁)] = 1 · x₁

[b_a(x₁)] = 1 + 1 · x₁

the pairs

a_b^#(b_c(c_a(a_b(x1)))) → a_b^#(b_b(x1)) (46)

a_b^#(b_c(c_a(a_c(x1)))) → a_b^#(b_c(x1)) (43)

could be deleted.
1.1.1.1.1.1.1.1.1.1 P is empty
There are no pairs anymore.