let R be the TRS under consideration
f(_1,n__g(_1),_2) -> f(activate(_2),activate(_2),activate(_2)) is in elim_R(R)
let r0 be the right-hand side of this rule
p0 = 0 is a position in r0
we have r0|p0 = activate(_2)
activate(_3) -> _3 is in R
let l'0 be the left-hand side of this rule
theta0 = {_2/_3} is a mgu of r0|p0 and l'0
==> f(_1,n__g(_1),_2) -> f(_2,activate(_2),activate(_2)) is in EU_R^1
let r1 be the right-hand side of this rule
p1 = 1 is a position in r1
we have r1|p1 = activate(_2)
activate(_3) -> _3 is in R
let l'1 be the left-hand side of this rule
theta1 = {_2/_3} is a mgu of r1|p1 and l'1
==> f(_1,n__g(_1),_2) -> f(_2,_2,activate(_2)) is in EU_R^2
let r2 be the right-hand side of this rule
p2 = 2 is a position in r2
we have r2|p2 = activate(_2)
activate(_3) -> _3 is in R
let l'2 be the left-hand side of this rule
theta2 = {_2/_3} is a mgu of r2|p2 and l'2
==> f(_1,n__g(_1),_2) -> f(_2,_2,_2) is in EU_R^3
let r3 be the right-hand side of this rule
p3 = 0 is a position in r3
we have r3|p3 = _2
g(b) -> c is in R
let l'3 be the left-hand side of this rule
theta3 = {_2/g(b)} is a mgu of r3|p3 and l'3
==> f(_1,n__g(_1),g(b)) -> f(c,g(b),g(b)) is in EU_R^4
let r4 be the right-hand side of this rule
p4 = 1 is a position in r4
we have r4|p4 = g(b)
g(_2) -> n__g(_2) is in R
let l'4 be the left-hand side of this rule
theta4 = {_2/b} is a mgu of r4|p4 and l'4
==> f(_1,n__g(_1),g(b)) -> f(c,n__g(b),g(b)) is in EU_R^5
let r5 be the right-hand side of this rule
p5 = 1.0 is a position in r5
we have r5|p5 = b
b -> c is in R
let l'5 be the left-hand side of this rule
theta5 = {} is a mgu of r5|p5 and l'5
==> f(_1,n__g(_1),g(b)) -> f(c,n__g(c),g(b)) is in EU_R^6
let l be the left-hand side and r be the right-hand side of this rule
let p = epsilon
let theta = {_1/c}
let theta' = {}
we have r|p = f(c,n__g(c),g(b)) and
theta'(theta(l)) = theta(r|p)
so, theta(l) = f(c,n__g(c),g(b)) is non-terminating w.r.t. R
Termination disproved by the forward process
proof stopped at iteration i=6, depth k=2
179 rule(s) generated