Certification Problem

Input (COPS 1653)

We consider the TRS containing the following rules:

c	→	f(a,h(b))	(1)
f(h(f(f(a,a),h(a))),g(f(x,g(b))))	→	c	(2)
c	→	c	(3)
g(g(a))	→	f(h(g(f(c,c))),f(f(g(c),a),g(f(a,a))))	(4)
f(x,y)	→	f(y,x)	(5)

The underlying signature is as follows:

{c/0, f/2, a/0, h/1, b/0, g/1}

Property / Task

Prove or disprove confluence.

Answer / Result

Yes.

Proof (by csi @ CoCo 2022)

1 Redundant Rules Transformation

To prove that the TRS is (non-)confluent, we show (non-)confluence of the following modified system:

f(x,y)	→	f(y,x)	(5)
g(g(a))	→	f(h(g(f(c,c))),f(f(g(c),a),g(f(a,a))))	(4)
f(h(f(f(a,a),h(a))),g(f(x,g(b))))	→	c	(2)
c	→	f(a,h(b))	(1)

All redundant rules that were added or removed can be simulated in 1 steps .

1.1 Redundant Rules Transformation

To prove that the TRS is (non-)confluent, we show (non-)confluence of the following modified system:

f(x,y)	→	f(y,x)	(5)
g(g(a))	→	f(h(g(f(c,c))),f(f(g(c),a),g(f(a,a))))	(4)
f(h(f(f(a,a),h(a))),g(f(x,g(b))))	→	c	(2)
c	→	f(a,h(b))	(1)
f(h(f(f(a,a),h(a))),g(f(g(b),x)))	→	c	(6)
f(h(f(h(a),f(a,a))),g(f(x,g(b))))	→	c	(7)
f(g(f(x,g(b))),h(f(f(a,a),h(a))))	→	c	(8)
f(g(f(x61,g(b))),h(f(f(a,a),h(a))))	→	c	(9)

All redundant rules that were added or removed can be simulated in 2 steps .

1.1.1 Redundant Rules Transformation

To prove that the TRS is (non-)confluent, we show (non-)confluence of the following modified system:

f(g(f(x61,g(b))),h(f(f(a,a),h(a))))	→	c	(9)
f(h(f(h(a),f(a,a))),g(f(x,g(b))))	→	c	(7)
f(h(f(f(a,a),h(a))),g(f(g(b),x)))	→	c	(6)
c	→	f(a,h(b))	(1)
f(h(f(f(a,a),h(a))),g(f(x,g(b))))	→	c	(2)
g(g(a))	→	f(h(g(f(c,c))),f(f(g(c),a),g(f(a,a))))	(4)
f(x,y)	→	f(y,x)	(5)

All redundant rules that were added or removed can be simulated in 1 steps .

1.1.1.1 Redundant Rules Transformation

To prove that the TRS is (non-)confluent, we show (non-)confluence of the following modified system:

f(g(f(x61,g(b))),h(f(f(a,a),h(a))))	→	c	(9)
f(h(f(h(a),f(a,a))),g(f(x,g(b))))	→	c	(7)
f(h(f(f(a,a),h(a))),g(f(g(b),x)))	→	c	(6)
c	→	f(a,h(b))	(1)
f(h(f(f(a,a),h(a))),g(f(x,g(b))))	→	c	(2)
g(g(a))	→	f(h(g(f(c,c))),f(f(g(c),a),g(f(a,a))))	(4)
f(x,y)	→	f(y,x)	(5)
f(h(f(h(a),f(a,a))),g(f(g(b),x)))	→	c	(10)
f(g(f(g(b),x)),h(f(f(a,a),h(a))))	→	c	(11)
f(g(f(x,g(b))),h(f(h(a),f(a,a))))	→	c	(12)
f(g(f(x61,g(b))),h(f(h(a),f(a,a))))	→	c	(13)
f(g(f(g(b),x61)),h(f(f(a,a),h(a))))	→	c	(14)
f(g(f(g(b),x383)),h(f(f(a,a),h(a))))	→	c	(15)
f(g(f(x381,g(b))),h(f(h(a),f(a,a))))	→	c	(16)

All redundant rules that were added or removed can be simulated in 2 steps .

1.1.1.1.1 Redundant Rules Transformation

To prove that the TRS is (non-)confluent, we show (non-)confluence of the following modified system:

f(g(f(x381,g(b))),h(f(h(a),f(a,a))))	→	c	(16)
f(g(f(g(b),x383)),h(f(f(a,a),h(a))))	→	c	(15)
f(h(f(h(a),f(a,a))),g(f(g(b),x)))	→	c	(10)
f(x,y)	→	f(y,x)	(5)
g(g(a))	→	f(h(g(f(c,c))),f(f(g(c),a),g(f(a,a))))	(4)
f(h(f(f(a,a),h(a))),g(f(x,g(b))))	→	c	(2)
c	→	f(a,h(b))	(1)
f(h(f(f(a,a),h(a))),g(f(g(b),x)))	→	c	(6)
f(h(f(h(a),f(a,a))),g(f(x,g(b))))	→	c	(7)
f(g(f(x61,g(b))),h(f(f(a,a),h(a))))	→	c	(9)

All redundant rules that were added or removed can be simulated in 1 steps .

1.1.1.1.1.1 Redundant Rules Transformation

To prove that the TRS is (non-)confluent, we show (non-)confluence of the following modified system:

f(g(f(x381,g(b))),h(f(h(a),f(a,a))))	→	c	(16)
f(g(f(g(b),x383)),h(f(f(a,a),h(a))))	→	c	(15)
f(h(f(h(a),f(a,a))),g(f(g(b),x)))	→	c	(10)
f(x,y)	→	f(y,x)	(5)
g(g(a))	→	f(h(g(f(c,c))),f(f(g(c),a),g(f(a,a))))	(4)
f(h(f(f(a,a),h(a))),g(f(x,g(b))))	→	c	(2)
c	→	f(a,h(b))	(1)
f(h(f(f(a,a),h(a))),g(f(g(b),x)))	→	c	(6)
f(h(f(h(a),f(a,a))),g(f(x,g(b))))	→	c	(7)
f(g(f(x61,g(b))),h(f(f(a,a),h(a))))	→	c	(9)
f(g(f(g(b),x)),h(f(h(a),f(a,a))))	→	c	(17)
f(g(f(g(b),x383)),h(f(h(a),f(a,a))))	→	c	(18)
f(g(f(g(b),x381)),h(f(h(a),f(a,a))))	→	c	(19)
f(g(f(g(b),x1222)),h(f(h(a),f(a,a))))	→	c	(20)

All redundant rules that were added or removed can be simulated in 2 steps .

1.1.1.1.1.1.1 Critical Pair Closing System

Confluence is proven using the following terminating critical-pair-closing-system R:

f(h(f(h(a),f(a,a))),g(f(x,g(b))))	→	c	(7)
f(h(f(f(a,a),h(a))),g(f(g(b),x)))	→	c	(6)
f(g(f(g(b),x)),h(f(h(a),f(a,a))))	→	c	(17)
f(g(f(x61,g(b))),h(f(f(a,a),h(a))))	→	c	(9)
f(g(f(x381,g(b))),h(f(h(a),f(a,a))))	→	c	(16)
f(g(f(g(b),x383)),h(f(f(a,a),h(a))))	→	c	(15)
f(h(f(h(a),f(a,a))),g(f(g(b),x)))	→	c	(10)
f(h(f(f(a,a),h(a))),g(f(x,g(b))))	→	c	(2)

1.1.1.1.1.1.1.1 Rule Removal

Using the linear polynomial interpretation over the naturals

[f(x₁, x₂)]	=	1 · x₁ + 1 · x₂ + 0
[a]	=	0
[h(x₁)]	=	4 · x₁ + 0
[g(x₁)]	=	2 · x₁ + 2
[c]	=	0
[b]	=	2

all of the following rules can be deleted.

f(h(f(h(a),f(a,a))),g(f(x,g(b))))	→	c	(7)
f(h(f(f(a,a),h(a))),g(f(g(b),x)))	→	c	(6)
f(g(f(g(b),x)),h(f(h(a),f(a,a))))	→	c	(17)
f(g(f(x61,g(b))),h(f(f(a,a),h(a))))	→	c	(9)
f(g(f(x381,g(b))),h(f(h(a),f(a,a))))	→	c	(16)
f(g(f(g(b),x383)),h(f(f(a,a),h(a))))	→	c	(15)
f(h(f(h(a),f(a,a))),g(f(g(b),x)))	→	c	(10)
f(h(f(f(a,a),h(a))),g(f(x,g(b))))	→	c	(2)

1.1.1.1.1.1.1.1.1 R is empty

There are no rules in the TRS. Hence, it is terminating.