The Runtime Complexity (full) of the given CpxTRS could be proven to be BOUNDS(n^1, INF).

0 CpxTRS
1 RenamingProof (⇔, 0 ms)
2 CpxRelTRS
3 TypeInferenceProof (BOTH BOUNDS(ID, ID), 0 ms)
4 typed CpxTrs
5 OrderProof (LOWER BOUND(ID), 6 ms)
6 typed CpxTrs
7 RewriteLemmaProof (LOWER BOUND(ID), 391 ms)
8 BEST
9 typed CpxTrs
10 RewriteLemmaProof (LOWER BOUND(ID), 122 ms)
11 BEST
12 typed CpxTrs
13 RewriteLemmaProof (LOWER BOUND(ID), 86 ms)
14 BEST
15 typed CpxTrs
16 NoRewriteLemmaProof (LOWER BOUND(ID), 0 ms)
17 typed CpxTrs
18 NoRewriteLemmaProof (LOWER BOUND(ID), 0 ms)
19 typed CpxTrs
20 NoRewriteLemmaProof (LOWER BOUND(ID), 0 ms)
21 typed CpxTrs
22 LowerBoundsProof (⇔, 0 ms)
23 BOUNDS(n^1, INF)
24 typed CpxTrs
25 LowerBoundsProof (⇔, 0 ms)
26 BOUNDS(n^1, INF)
27 typed CpxTrs
28 LowerBoundsProof (⇔, 0 ms)
29 BOUNDS(n^1, INF)
30 typed CpxTrs
31 LowerBoundsProof (⇔, 0 ms)
32 BOUNDS(n^1, INF)

(0) Obligation:

Runtime Complexity TRS:
The TRS R consists of the following rules:

active(__(__(X, Y), Z)) → mark(__(X, __(Y, Z)))
active(__(X, nil)) → mark(X)
active(__(nil, X)) → mark(X)
active(and(tt, X)) → mark(X)
active(isNePal(__(I, __(P, I)))) → mark(tt)
active(__(X1, X2)) → __(active(X1), X2)
active(__(X1, X2)) → __(X1, active(X2))
active(and(X1, X2)) → and(active(X1), X2)
active(isNePal(X)) → isNePal(active(X))
__(mark(X1), X2) → mark(__(X1, X2))
__(X1, mark(X2)) → mark(__(X1, X2))
and(mark(X1), X2) → mark(and(X1, X2))
isNePal(mark(X)) → mark(isNePal(X))
proper(__(X1, X2)) → __(proper(X1), proper(X2))
proper(nil) → ok(nil)
proper(and(X1, X2)) → and(proper(X1), proper(X2))
proper(tt) → ok(tt)
proper(isNePal(X)) → isNePal(proper(X))
__(ok(X1), ok(X2)) → ok(__(X1, X2))
and(ok(X1), ok(X2)) → ok(and(X1, X2))
isNePal(ok(X)) → ok(isNePal(X))
top(mark(X)) → top(proper(X))
top(ok(X)) → top(active(X))

Rewrite Strategy: FULL

(1) RenamingProof (EQUIVALENT transformation)

Renamed function symbols to avoid clashes with predefined symbol.

(2) Obligation:

Runtime Complexity Relative TRS:
The TRS R consists of the following rules:

active(__(__(X, Y), Z)) → mark(__(X, __(Y, Z)))
active(__(X, nil)) → mark(X)
active(__(nil, X)) → mark(X)
active(and(tt, X)) → mark(X)
active(isNePal(__(I, __(P, I)))) → mark(tt)
active(__(X1, X2)) → __(active(X1), X2)
active(__(X1, X2)) → __(X1, active(X2))
active(and(X1, X2)) → and(active(X1), X2)
active(isNePal(X)) → isNePal(active(X))
__(mark(X1), X2) → mark(__(X1, X2))
__(X1, mark(X2)) → mark(__(X1, X2))
and(mark(X1), X2) → mark(and(X1, X2))
isNePal(mark(X)) → mark(isNePal(X))
proper(__(X1, X2)) → __(proper(X1), proper(X2))
proper(nil) → ok(nil)
proper(and(X1, X2)) → and(proper(X1), proper(X2))
proper(tt) → ok(tt)
proper(isNePal(X)) → isNePal(proper(X))
__(ok(X1), ok(X2)) → ok(__(X1, X2))
and(ok(X1), ok(X2)) → ok(and(X1, X2))
isNePal(ok(X)) → ok(isNePal(X))
top(mark(X)) → top(proper(X))
top(ok(X)) → top(active(X))

S is empty.
Rewrite Strategy: FULL

(3) TypeInferenceProof (BOTH BOUNDS(ID, ID) transformation)

Infered types.

(4) Obligation:

TRS:
Rules:
active(__(__(X, Y), Z)) → mark(__(X, __(Y, Z)))
active(__(X, nil)) → mark(X)
active(__(nil, X)) → mark(X)
active(and(tt, X)) → mark(X)
active(isNePal(__(I, __(P, I)))) → mark(tt)
active(__(X1, X2)) → __(active(X1), X2)
active(__(X1, X2)) → __(X1, active(X2))
active(and(X1, X2)) → and(active(X1), X2)
active(isNePal(X)) → isNePal(active(X))
__(mark(X1), X2) → mark(__(X1, X2))
__(X1, mark(X2)) → mark(__(X1, X2))
and(mark(X1), X2) → mark(and(X1, X2))
isNePal(mark(X)) → mark(isNePal(X))
proper(__(X1, X2)) → __(proper(X1), proper(X2))
proper(nil) → ok(nil)
proper(and(X1, X2)) → and(proper(X1), proper(X2))
proper(tt) → ok(tt)
proper(isNePal(X)) → isNePal(proper(X))
__(ok(X1), ok(X2)) → ok(__(X1, X2))
and(ok(X1), ok(X2)) → ok(and(X1, X2))
isNePal(ok(X)) → ok(isNePal(X))
top(mark(X)) → top(proper(X))
top(ok(X)) → top(active(X))

Types:
active :: mark:nil:tt:ok → mark:nil:tt:ok
__ :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
mark :: mark:nil:tt:ok → mark:nil:tt:ok
nil :: mark:nil:tt:ok
and :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
tt :: mark:nil:tt:ok
isNePal :: mark:nil:tt:ok → mark:nil:tt:ok
proper :: mark:nil:tt:ok → mark:nil:tt:ok
ok :: mark:nil:tt:ok → mark:nil:tt:ok
top :: mark:nil:tt:ok → top
hole_mark:nil:tt:ok1_0 :: mark:nil:tt:ok
hole_top2_0 :: top
gen_mark:nil:tt:ok3_0 :: Nat → mark:nil:tt:ok

(5) OrderProof (LOWER BOUND(ID) transformation)

Heuristically decided to analyse the following defined symbols:
active, __, and, isNePal, proper, top

They will be analysed ascendingly in the following order:
__ < active
and < active
isNePal < active
active < top
__ < proper
and < proper
isNePal < proper
proper < top

(6) Obligation:

TRS:
Rules:
active(__(__(X, Y), Z)) → mark(__(X, __(Y, Z)))
active(__(X, nil)) → mark(X)
active(__(nil, X)) → mark(X)
active(and(tt, X)) → mark(X)
active(isNePal(__(I, __(P, I)))) → mark(tt)
active(__(X1, X2)) → __(active(X1), X2)
active(__(X1, X2)) → __(X1, active(X2))
active(and(X1, X2)) → and(active(X1), X2)
active(isNePal(X)) → isNePal(active(X))
__(mark(X1), X2) → mark(__(X1, X2))
__(X1, mark(X2)) → mark(__(X1, X2))
and(mark(X1), X2) → mark(and(X1, X2))
isNePal(mark(X)) → mark(isNePal(X))
proper(__(X1, X2)) → __(proper(X1), proper(X2))
proper(nil) → ok(nil)
proper(and(X1, X2)) → and(proper(X1), proper(X2))
proper(tt) → ok(tt)
proper(isNePal(X)) → isNePal(proper(X))
__(ok(X1), ok(X2)) → ok(__(X1, X2))
and(ok(X1), ok(X2)) → ok(and(X1, X2))
isNePal(ok(X)) → ok(isNePal(X))
top(mark(X)) → top(proper(X))
top(ok(X)) → top(active(X))

Types:
active :: mark:nil:tt:ok → mark:nil:tt:ok
__ :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
mark :: mark:nil:tt:ok → mark:nil:tt:ok
nil :: mark:nil:tt:ok
and :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
tt :: mark:nil:tt:ok
isNePal :: mark:nil:tt:ok → mark:nil:tt:ok
proper :: mark:nil:tt:ok → mark:nil:tt:ok
ok :: mark:nil:tt:ok → mark:nil:tt:ok
top :: mark:nil:tt:ok → top
hole_mark:nil:tt:ok1_0 :: mark:nil:tt:ok
hole_top2_0 :: top
gen_mark:nil:tt:ok3_0 :: Nat → mark:nil:tt:ok

Generator Equations:
gen_mark:nil:tt:ok3_0(0) ⇔ nil
gen_mark:nil:tt:ok3_0(+(x, 1)) ⇔ mark(gen_mark:nil:tt:ok3_0(x))

The following defined symbols remain to be analysed:
__, active, and, isNePal, proper, top

They will be analysed ascendingly in the following order:
__ < active
and < active
isNePal < active
active < top
__ < proper
and < proper
isNePal < proper
proper < top

(7) RewriteLemmaProof (LOWER BOUND(ID) transformation)

Proved the following rewrite lemma:
__(gen_mark:nil:tt:ok3_0(+(1, n5_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n50)

Induction Base:
__(gen_mark:nil:tt:ok3_0(+(1, 0)), gen_mark:nil:tt:ok3_0(b))

Induction Step:
__(gen_mark:nil:tt:ok3_0(+(1, +(n5_0, 1))), gen_mark:nil:tt:ok3_0(b)) →RΩ(1)
mark(__(gen_mark:nil:tt:ok3_0(+(1, n5_0)), gen_mark:nil:tt:ok3_0(b))) →IH
mark(*4_0)

We have rt ∈ Ω(n1) and sz ∈ O(n). Thus, we have ircR ∈ Ω(n).

(8) Complex Obligation (BEST)

(9) Obligation:

TRS:
Rules:
active(__(__(X, Y), Z)) → mark(__(X, __(Y, Z)))
active(__(X, nil)) → mark(X)
active(__(nil, X)) → mark(X)
active(and(tt, X)) → mark(X)
active(isNePal(__(I, __(P, I)))) → mark(tt)
active(__(X1, X2)) → __(active(X1), X2)
active(__(X1, X2)) → __(X1, active(X2))
active(and(X1, X2)) → and(active(X1), X2)
active(isNePal(X)) → isNePal(active(X))
__(mark(X1), X2) → mark(__(X1, X2))
__(X1, mark(X2)) → mark(__(X1, X2))
and(mark(X1), X2) → mark(and(X1, X2))
isNePal(mark(X)) → mark(isNePal(X))
proper(__(X1, X2)) → __(proper(X1), proper(X2))
proper(nil) → ok(nil)
proper(and(X1, X2)) → and(proper(X1), proper(X2))
proper(tt) → ok(tt)
proper(isNePal(X)) → isNePal(proper(X))
__(ok(X1), ok(X2)) → ok(__(X1, X2))
and(ok(X1), ok(X2)) → ok(and(X1, X2))
isNePal(ok(X)) → ok(isNePal(X))
top(mark(X)) → top(proper(X))
top(ok(X)) → top(active(X))

Types:
active :: mark:nil:tt:ok → mark:nil:tt:ok
__ :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
mark :: mark:nil:tt:ok → mark:nil:tt:ok
nil :: mark:nil:tt:ok
and :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
tt :: mark:nil:tt:ok
isNePal :: mark:nil:tt:ok → mark:nil:tt:ok
proper :: mark:nil:tt:ok → mark:nil:tt:ok
ok :: mark:nil:tt:ok → mark:nil:tt:ok
top :: mark:nil:tt:ok → top
hole_mark:nil:tt:ok1_0 :: mark:nil:tt:ok
hole_top2_0 :: top
gen_mark:nil:tt:ok3_0 :: Nat → mark:nil:tt:ok

Lemmas:
__(gen_mark:nil:tt:ok3_0(+(1, n5_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n50)

Generator Equations:
gen_mark:nil:tt:ok3_0(0) ⇔ nil
gen_mark:nil:tt:ok3_0(+(x, 1)) ⇔ mark(gen_mark:nil:tt:ok3_0(x))

The following defined symbols remain to be analysed:
and, active, isNePal, proper, top

They will be analysed ascendingly in the following order:
and < active
isNePal < active
active < top
and < proper
isNePal < proper
proper < top

(10) RewriteLemmaProof (LOWER BOUND(ID) transformation)

Proved the following rewrite lemma:
and(gen_mark:nil:tt:ok3_0(+(1, n1017_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n10170)

Induction Base:
and(gen_mark:nil:tt:ok3_0(+(1, 0)), gen_mark:nil:tt:ok3_0(b))

Induction Step:
and(gen_mark:nil:tt:ok3_0(+(1, +(n1017_0, 1))), gen_mark:nil:tt:ok3_0(b)) →RΩ(1)
mark(and(gen_mark:nil:tt:ok3_0(+(1, n1017_0)), gen_mark:nil:tt:ok3_0(b))) →IH
mark(*4_0)

We have rt ∈ Ω(n1) and sz ∈ O(n). Thus, we have ircR ∈ Ω(n).

(11) Complex Obligation (BEST)

(12) Obligation:

TRS:
Rules:
active(__(__(X, Y), Z)) → mark(__(X, __(Y, Z)))
active(__(X, nil)) → mark(X)
active(__(nil, X)) → mark(X)
active(and(tt, X)) → mark(X)
active(isNePal(__(I, __(P, I)))) → mark(tt)
active(__(X1, X2)) → __(active(X1), X2)
active(__(X1, X2)) → __(X1, active(X2))
active(and(X1, X2)) → and(active(X1), X2)
active(isNePal(X)) → isNePal(active(X))
__(mark(X1), X2) → mark(__(X1, X2))
__(X1, mark(X2)) → mark(__(X1, X2))
and(mark(X1), X2) → mark(and(X1, X2))
isNePal(mark(X)) → mark(isNePal(X))
proper(__(X1, X2)) → __(proper(X1), proper(X2))
proper(nil) → ok(nil)
proper(and(X1, X2)) → and(proper(X1), proper(X2))
proper(tt) → ok(tt)
proper(isNePal(X)) → isNePal(proper(X))
__(ok(X1), ok(X2)) → ok(__(X1, X2))
and(ok(X1), ok(X2)) → ok(and(X1, X2))
isNePal(ok(X)) → ok(isNePal(X))
top(mark(X)) → top(proper(X))
top(ok(X)) → top(active(X))

Types:
active :: mark:nil:tt:ok → mark:nil:tt:ok
__ :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
mark :: mark:nil:tt:ok → mark:nil:tt:ok
nil :: mark:nil:tt:ok
and :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
tt :: mark:nil:tt:ok
isNePal :: mark:nil:tt:ok → mark:nil:tt:ok
proper :: mark:nil:tt:ok → mark:nil:tt:ok
ok :: mark:nil:tt:ok → mark:nil:tt:ok
top :: mark:nil:tt:ok → top
hole_mark:nil:tt:ok1_0 :: mark:nil:tt:ok
hole_top2_0 :: top
gen_mark:nil:tt:ok3_0 :: Nat → mark:nil:tt:ok

Lemmas:
__(gen_mark:nil:tt:ok3_0(+(1, n5_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n50)
and(gen_mark:nil:tt:ok3_0(+(1, n1017_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n10170)

Generator Equations:
gen_mark:nil:tt:ok3_0(0) ⇔ nil
gen_mark:nil:tt:ok3_0(+(x, 1)) ⇔ mark(gen_mark:nil:tt:ok3_0(x))

The following defined symbols remain to be analysed:
isNePal, active, proper, top

They will be analysed ascendingly in the following order:
isNePal < active
active < top
isNePal < proper
proper < top

(13) RewriteLemmaProof (LOWER BOUND(ID) transformation)

Proved the following rewrite lemma:
isNePal(gen_mark:nil:tt:ok3_0(+(1, n2134_0))) → *4_0, rt ∈ Ω(n21340)

Induction Base:
isNePal(gen_mark:nil:tt:ok3_0(+(1, 0)))

Induction Step:
isNePal(gen_mark:nil:tt:ok3_0(+(1, +(n2134_0, 1)))) →RΩ(1)
mark(isNePal(gen_mark:nil:tt:ok3_0(+(1, n2134_0)))) →IH
mark(*4_0)

We have rt ∈ Ω(n1) and sz ∈ O(n). Thus, we have ircR ∈ Ω(n).

(14) Complex Obligation (BEST)

(15) Obligation:

TRS:
Rules:
active(__(__(X, Y), Z)) → mark(__(X, __(Y, Z)))
active(__(X, nil)) → mark(X)
active(__(nil, X)) → mark(X)
active(and(tt, X)) → mark(X)
active(isNePal(__(I, __(P, I)))) → mark(tt)
active(__(X1, X2)) → __(active(X1), X2)
active(__(X1, X2)) → __(X1, active(X2))
active(and(X1, X2)) → and(active(X1), X2)
active(isNePal(X)) → isNePal(active(X))
__(mark(X1), X2) → mark(__(X1, X2))
__(X1, mark(X2)) → mark(__(X1, X2))
and(mark(X1), X2) → mark(and(X1, X2))
isNePal(mark(X)) → mark(isNePal(X))
proper(__(X1, X2)) → __(proper(X1), proper(X2))
proper(nil) → ok(nil)
proper(and(X1, X2)) → and(proper(X1), proper(X2))
proper(tt) → ok(tt)
proper(isNePal(X)) → isNePal(proper(X))
__(ok(X1), ok(X2)) → ok(__(X1, X2))
and(ok(X1), ok(X2)) → ok(and(X1, X2))
isNePal(ok(X)) → ok(isNePal(X))
top(mark(X)) → top(proper(X))
top(ok(X)) → top(active(X))

Types:
active :: mark:nil:tt:ok → mark:nil:tt:ok
__ :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
mark :: mark:nil:tt:ok → mark:nil:tt:ok
nil :: mark:nil:tt:ok
and :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
tt :: mark:nil:tt:ok
isNePal :: mark:nil:tt:ok → mark:nil:tt:ok
proper :: mark:nil:tt:ok → mark:nil:tt:ok
ok :: mark:nil:tt:ok → mark:nil:tt:ok
top :: mark:nil:tt:ok → top
hole_mark:nil:tt:ok1_0 :: mark:nil:tt:ok
hole_top2_0 :: top
gen_mark:nil:tt:ok3_0 :: Nat → mark:nil:tt:ok

Lemmas:
__(gen_mark:nil:tt:ok3_0(+(1, n5_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n50)
and(gen_mark:nil:tt:ok3_0(+(1, n1017_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n10170)
isNePal(gen_mark:nil:tt:ok3_0(+(1, n2134_0))) → *4_0, rt ∈ Ω(n21340)

Generator Equations:
gen_mark:nil:tt:ok3_0(0) ⇔ nil
gen_mark:nil:tt:ok3_0(+(x, 1)) ⇔ mark(gen_mark:nil:tt:ok3_0(x))

The following defined symbols remain to be analysed:
active, proper, top

They will be analysed ascendingly in the following order:
active < top
proper < top

(16) NoRewriteLemmaProof (LOWER BOUND(ID) transformation)

Could not prove a rewrite lemma for the defined symbol active.

(17) Obligation:

TRS:
Rules:
active(__(__(X, Y), Z)) → mark(__(X, __(Y, Z)))
active(__(X, nil)) → mark(X)
active(__(nil, X)) → mark(X)
active(and(tt, X)) → mark(X)
active(isNePal(__(I, __(P, I)))) → mark(tt)
active(__(X1, X2)) → __(active(X1), X2)
active(__(X1, X2)) → __(X1, active(X2))
active(and(X1, X2)) → and(active(X1), X2)
active(isNePal(X)) → isNePal(active(X))
__(mark(X1), X2) → mark(__(X1, X2))
__(X1, mark(X2)) → mark(__(X1, X2))
and(mark(X1), X2) → mark(and(X1, X2))
isNePal(mark(X)) → mark(isNePal(X))
proper(__(X1, X2)) → __(proper(X1), proper(X2))
proper(nil) → ok(nil)
proper(and(X1, X2)) → and(proper(X1), proper(X2))
proper(tt) → ok(tt)
proper(isNePal(X)) → isNePal(proper(X))
__(ok(X1), ok(X2)) → ok(__(X1, X2))
and(ok(X1), ok(X2)) → ok(and(X1, X2))
isNePal(ok(X)) → ok(isNePal(X))
top(mark(X)) → top(proper(X))
top(ok(X)) → top(active(X))

Types:
active :: mark:nil:tt:ok → mark:nil:tt:ok
__ :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
mark :: mark:nil:tt:ok → mark:nil:tt:ok
nil :: mark:nil:tt:ok
and :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
tt :: mark:nil:tt:ok
isNePal :: mark:nil:tt:ok → mark:nil:tt:ok
proper :: mark:nil:tt:ok → mark:nil:tt:ok
ok :: mark:nil:tt:ok → mark:nil:tt:ok
top :: mark:nil:tt:ok → top
hole_mark:nil:tt:ok1_0 :: mark:nil:tt:ok
hole_top2_0 :: top
gen_mark:nil:tt:ok3_0 :: Nat → mark:nil:tt:ok

Lemmas:
__(gen_mark:nil:tt:ok3_0(+(1, n5_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n50)
and(gen_mark:nil:tt:ok3_0(+(1, n1017_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n10170)
isNePal(gen_mark:nil:tt:ok3_0(+(1, n2134_0))) → *4_0, rt ∈ Ω(n21340)

Generator Equations:
gen_mark:nil:tt:ok3_0(0) ⇔ nil
gen_mark:nil:tt:ok3_0(+(x, 1)) ⇔ mark(gen_mark:nil:tt:ok3_0(x))

The following defined symbols remain to be analysed:
proper, top

They will be analysed ascendingly in the following order:
proper < top

(18) NoRewriteLemmaProof (LOWER BOUND(ID) transformation)

Could not prove a rewrite lemma for the defined symbol proper.

(19) Obligation:

TRS:
Rules:
active(__(__(X, Y), Z)) → mark(__(X, __(Y, Z)))
active(__(X, nil)) → mark(X)
active(__(nil, X)) → mark(X)
active(and(tt, X)) → mark(X)
active(isNePal(__(I, __(P, I)))) → mark(tt)
active(__(X1, X2)) → __(active(X1), X2)
active(__(X1, X2)) → __(X1, active(X2))
active(and(X1, X2)) → and(active(X1), X2)
active(isNePal(X)) → isNePal(active(X))
__(mark(X1), X2) → mark(__(X1, X2))
__(X1, mark(X2)) → mark(__(X1, X2))
and(mark(X1), X2) → mark(and(X1, X2))
isNePal(mark(X)) → mark(isNePal(X))
proper(__(X1, X2)) → __(proper(X1), proper(X2))
proper(nil) → ok(nil)
proper(and(X1, X2)) → and(proper(X1), proper(X2))
proper(tt) → ok(tt)
proper(isNePal(X)) → isNePal(proper(X))
__(ok(X1), ok(X2)) → ok(__(X1, X2))
and(ok(X1), ok(X2)) → ok(and(X1, X2))
isNePal(ok(X)) → ok(isNePal(X))
top(mark(X)) → top(proper(X))
top(ok(X)) → top(active(X))

Types:
active :: mark:nil:tt:ok → mark:nil:tt:ok
__ :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
mark :: mark:nil:tt:ok → mark:nil:tt:ok
nil :: mark:nil:tt:ok
and :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
tt :: mark:nil:tt:ok
isNePal :: mark:nil:tt:ok → mark:nil:tt:ok
proper :: mark:nil:tt:ok → mark:nil:tt:ok
ok :: mark:nil:tt:ok → mark:nil:tt:ok
top :: mark:nil:tt:ok → top
hole_mark:nil:tt:ok1_0 :: mark:nil:tt:ok
hole_top2_0 :: top
gen_mark:nil:tt:ok3_0 :: Nat → mark:nil:tt:ok

Lemmas:
__(gen_mark:nil:tt:ok3_0(+(1, n5_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n50)
and(gen_mark:nil:tt:ok3_0(+(1, n1017_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n10170)
isNePal(gen_mark:nil:tt:ok3_0(+(1, n2134_0))) → *4_0, rt ∈ Ω(n21340)

Generator Equations:
gen_mark:nil:tt:ok3_0(0) ⇔ nil
gen_mark:nil:tt:ok3_0(+(x, 1)) ⇔ mark(gen_mark:nil:tt:ok3_0(x))

The following defined symbols remain to be analysed:
top

(20) NoRewriteLemmaProof (LOWER BOUND(ID) transformation)

Could not prove a rewrite lemma for the defined symbol top.

(21) Obligation:

TRS:
Rules:
active(__(__(X, Y), Z)) → mark(__(X, __(Y, Z)))
active(__(X, nil)) → mark(X)
active(__(nil, X)) → mark(X)
active(and(tt, X)) → mark(X)
active(isNePal(__(I, __(P, I)))) → mark(tt)
active(__(X1, X2)) → __(active(X1), X2)
active(__(X1, X2)) → __(X1, active(X2))
active(and(X1, X2)) → and(active(X1), X2)
active(isNePal(X)) → isNePal(active(X))
__(mark(X1), X2) → mark(__(X1, X2))
__(X1, mark(X2)) → mark(__(X1, X2))
and(mark(X1), X2) → mark(and(X1, X2))
isNePal(mark(X)) → mark(isNePal(X))
proper(__(X1, X2)) → __(proper(X1), proper(X2))
proper(nil) → ok(nil)
proper(and(X1, X2)) → and(proper(X1), proper(X2))
proper(tt) → ok(tt)
proper(isNePal(X)) → isNePal(proper(X))
__(ok(X1), ok(X2)) → ok(__(X1, X2))
and(ok(X1), ok(X2)) → ok(and(X1, X2))
isNePal(ok(X)) → ok(isNePal(X))
top(mark(X)) → top(proper(X))
top(ok(X)) → top(active(X))

Types:
active :: mark:nil:tt:ok → mark:nil:tt:ok
__ :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
mark :: mark:nil:tt:ok → mark:nil:tt:ok
nil :: mark:nil:tt:ok
and :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
tt :: mark:nil:tt:ok
isNePal :: mark:nil:tt:ok → mark:nil:tt:ok
proper :: mark:nil:tt:ok → mark:nil:tt:ok
ok :: mark:nil:tt:ok → mark:nil:tt:ok
top :: mark:nil:tt:ok → top
hole_mark:nil:tt:ok1_0 :: mark:nil:tt:ok
hole_top2_0 :: top
gen_mark:nil:tt:ok3_0 :: Nat → mark:nil:tt:ok

Lemmas:
__(gen_mark:nil:tt:ok3_0(+(1, n5_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n50)
and(gen_mark:nil:tt:ok3_0(+(1, n1017_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n10170)
isNePal(gen_mark:nil:tt:ok3_0(+(1, n2134_0))) → *4_0, rt ∈ Ω(n21340)

Generator Equations:
gen_mark:nil:tt:ok3_0(0) ⇔ nil
gen_mark:nil:tt:ok3_0(+(x, 1)) ⇔ mark(gen_mark:nil:tt:ok3_0(x))

No more defined symbols left to analyse.

(22) LowerBoundsProof (EQUIVALENT transformation)

The lowerbound Ω(n1) was proven with the following lemma:
__(gen_mark:nil:tt:ok3_0(+(1, n5_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n50)

(23) BOUNDS(n^1, INF)

(24) Obligation:

TRS:
Rules:
active(__(__(X, Y), Z)) → mark(__(X, __(Y, Z)))
active(__(X, nil)) → mark(X)
active(__(nil, X)) → mark(X)
active(and(tt, X)) → mark(X)
active(isNePal(__(I, __(P, I)))) → mark(tt)
active(__(X1, X2)) → __(active(X1), X2)
active(__(X1, X2)) → __(X1, active(X2))
active(and(X1, X2)) → and(active(X1), X2)
active(isNePal(X)) → isNePal(active(X))
__(mark(X1), X2) → mark(__(X1, X2))
__(X1, mark(X2)) → mark(__(X1, X2))
and(mark(X1), X2) → mark(and(X1, X2))
isNePal(mark(X)) → mark(isNePal(X))
proper(__(X1, X2)) → __(proper(X1), proper(X2))
proper(nil) → ok(nil)
proper(and(X1, X2)) → and(proper(X1), proper(X2))
proper(tt) → ok(tt)
proper(isNePal(X)) → isNePal(proper(X))
__(ok(X1), ok(X2)) → ok(__(X1, X2))
and(ok(X1), ok(X2)) → ok(and(X1, X2))
isNePal(ok(X)) → ok(isNePal(X))
top(mark(X)) → top(proper(X))
top(ok(X)) → top(active(X))

Types:
active :: mark:nil:tt:ok → mark:nil:tt:ok
__ :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
mark :: mark:nil:tt:ok → mark:nil:tt:ok
nil :: mark:nil:tt:ok
and :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
tt :: mark:nil:tt:ok
isNePal :: mark:nil:tt:ok → mark:nil:tt:ok
proper :: mark:nil:tt:ok → mark:nil:tt:ok
ok :: mark:nil:tt:ok → mark:nil:tt:ok
top :: mark:nil:tt:ok → top
hole_mark:nil:tt:ok1_0 :: mark:nil:tt:ok
hole_top2_0 :: top
gen_mark:nil:tt:ok3_0 :: Nat → mark:nil:tt:ok

Lemmas:
__(gen_mark:nil:tt:ok3_0(+(1, n5_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n50)
and(gen_mark:nil:tt:ok3_0(+(1, n1017_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n10170)
isNePal(gen_mark:nil:tt:ok3_0(+(1, n2134_0))) → *4_0, rt ∈ Ω(n21340)

Generator Equations:
gen_mark:nil:tt:ok3_0(0) ⇔ nil
gen_mark:nil:tt:ok3_0(+(x, 1)) ⇔ mark(gen_mark:nil:tt:ok3_0(x))

No more defined symbols left to analyse.

(25) LowerBoundsProof (EQUIVALENT transformation)

The lowerbound Ω(n1) was proven with the following lemma:
__(gen_mark:nil:tt:ok3_0(+(1, n5_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n50)

(26) BOUNDS(n^1, INF)

(27) Obligation:

TRS:
Rules:
active(__(__(X, Y), Z)) → mark(__(X, __(Y, Z)))
active(__(X, nil)) → mark(X)
active(__(nil, X)) → mark(X)
active(and(tt, X)) → mark(X)
active(isNePal(__(I, __(P, I)))) → mark(tt)
active(__(X1, X2)) → __(active(X1), X2)
active(__(X1, X2)) → __(X1, active(X2))
active(and(X1, X2)) → and(active(X1), X2)
active(isNePal(X)) → isNePal(active(X))
__(mark(X1), X2) → mark(__(X1, X2))
__(X1, mark(X2)) → mark(__(X1, X2))
and(mark(X1), X2) → mark(and(X1, X2))
isNePal(mark(X)) → mark(isNePal(X))
proper(__(X1, X2)) → __(proper(X1), proper(X2))
proper(nil) → ok(nil)
proper(and(X1, X2)) → and(proper(X1), proper(X2))
proper(tt) → ok(tt)
proper(isNePal(X)) → isNePal(proper(X))
__(ok(X1), ok(X2)) → ok(__(X1, X2))
and(ok(X1), ok(X2)) → ok(and(X1, X2))
isNePal(ok(X)) → ok(isNePal(X))
top(mark(X)) → top(proper(X))
top(ok(X)) → top(active(X))

Types:
active :: mark:nil:tt:ok → mark:nil:tt:ok
__ :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
mark :: mark:nil:tt:ok → mark:nil:tt:ok
nil :: mark:nil:tt:ok
and :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
tt :: mark:nil:tt:ok
isNePal :: mark:nil:tt:ok → mark:nil:tt:ok
proper :: mark:nil:tt:ok → mark:nil:tt:ok
ok :: mark:nil:tt:ok → mark:nil:tt:ok
top :: mark:nil:tt:ok → top
hole_mark:nil:tt:ok1_0 :: mark:nil:tt:ok
hole_top2_0 :: top
gen_mark:nil:tt:ok3_0 :: Nat → mark:nil:tt:ok

Lemmas:
__(gen_mark:nil:tt:ok3_0(+(1, n5_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n50)
and(gen_mark:nil:tt:ok3_0(+(1, n1017_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n10170)

Generator Equations:
gen_mark:nil:tt:ok3_0(0) ⇔ nil
gen_mark:nil:tt:ok3_0(+(x, 1)) ⇔ mark(gen_mark:nil:tt:ok3_0(x))

No more defined symbols left to analyse.

(28) LowerBoundsProof (EQUIVALENT transformation)

The lowerbound Ω(n1) was proven with the following lemma:
__(gen_mark:nil:tt:ok3_0(+(1, n5_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n50)

(29) BOUNDS(n^1, INF)

(30) Obligation:

TRS:
Rules:
active(__(__(X, Y), Z)) → mark(__(X, __(Y, Z)))
active(__(X, nil)) → mark(X)
active(__(nil, X)) → mark(X)
active(and(tt, X)) → mark(X)
active(isNePal(__(I, __(P, I)))) → mark(tt)
active(__(X1, X2)) → __(active(X1), X2)
active(__(X1, X2)) → __(X1, active(X2))
active(and(X1, X2)) → and(active(X1), X2)
active(isNePal(X)) → isNePal(active(X))
__(mark(X1), X2) → mark(__(X1, X2))
__(X1, mark(X2)) → mark(__(X1, X2))
and(mark(X1), X2) → mark(and(X1, X2))
isNePal(mark(X)) → mark(isNePal(X))
proper(__(X1, X2)) → __(proper(X1), proper(X2))
proper(nil) → ok(nil)
proper(and(X1, X2)) → and(proper(X1), proper(X2))
proper(tt) → ok(tt)
proper(isNePal(X)) → isNePal(proper(X))
__(ok(X1), ok(X2)) → ok(__(X1, X2))
and(ok(X1), ok(X2)) → ok(and(X1, X2))
isNePal(ok(X)) → ok(isNePal(X))
top(mark(X)) → top(proper(X))
top(ok(X)) → top(active(X))

Types:
active :: mark:nil:tt:ok → mark:nil:tt:ok
__ :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
mark :: mark:nil:tt:ok → mark:nil:tt:ok
nil :: mark:nil:tt:ok
and :: mark:nil:tt:ok → mark:nil:tt:ok → mark:nil:tt:ok
tt :: mark:nil:tt:ok
isNePal :: mark:nil:tt:ok → mark:nil:tt:ok
proper :: mark:nil:tt:ok → mark:nil:tt:ok
ok :: mark:nil:tt:ok → mark:nil:tt:ok
top :: mark:nil:tt:ok → top
hole_mark:nil:tt:ok1_0 :: mark:nil:tt:ok
hole_top2_0 :: top
gen_mark:nil:tt:ok3_0 :: Nat → mark:nil:tt:ok

Lemmas:
__(gen_mark:nil:tt:ok3_0(+(1, n5_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n50)

Generator Equations:
gen_mark:nil:tt:ok3_0(0) ⇔ nil
gen_mark:nil:tt:ok3_0(+(x, 1)) ⇔ mark(gen_mark:nil:tt:ok3_0(x))

No more defined symbols left to analyse.

(31) LowerBoundsProof (EQUIVALENT transformation)

The lowerbound Ω(n1) was proven with the following lemma:
__(gen_mark:nil:tt:ok3_0(+(1, n5_0)), gen_mark:nil:tt:ok3_0(b)) → *4_0, rt ∈ Ω(n50)

(32) BOUNDS(n^1, INF)