The Runtime Complexity (full) of the given CpxTRS could be proven to be BOUNDS(n^2, INF).

0 CpxTRS
1 DecreasingLoopProof (⇔, 1090 ms)
2 BOUNDS(n^1, INF)
3 RenamingProof (⇔, 0 ms)
4 CpxRelTRS
5 TypeInferenceProof (BOTH BOUNDS(ID, ID), 0 ms)
6 typed CpxTrs
7 OrderProof (LOWER BOUND(ID), 0 ms)
8 typed CpxTrs
9 RewriteLemmaProof (LOWER BOUND(ID), 166 ms)
10 BEST
11 typed CpxTrs
12 RewriteLemmaProof (LOWER BOUND(ID), 680 ms)
13 BEST
14 typed CpxTrs
15 RewriteLemmaProof (LOWER BOUND(ID), 532 ms)
16 BEST
17 typed CpxTrs
18 RewriteLemmaProof (LOWER BOUND(ID), 178 ms)
19 BEST
20 typed CpxTrs
21 LowerBoundsProof (⇔, 0 ms)
22 BOUNDS(n^2, INF)
23 typed CpxTrs
24 LowerBoundsProof (⇔, 0 ms)
25 BOUNDS(n^2, INF)
26 typed CpxTrs
27 LowerBoundsProof (⇔, 0 ms)
28 BOUNDS(n^1, INF)
29 typed CpxTrs
30 LowerBoundsProof (⇔, 0 ms)
31 BOUNDS(n^1, INF)
32 typed CpxTrs
33 LowerBoundsProof (⇔, 0 ms)
34 BOUNDS(n^1, INF)

(0) Obligation:

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

Term_sub(Case(m, xi, n), s) → Frozen(m, Sum_sub(xi, s), n, s)
Frozen(m, Sum_constant(Left), n, s) → Term_sub(m, s)
Frozen(m, Sum_constant(Right), n, s) → Term_sub(n, s)
Frozen(m, Sum_term_var(xi), n, s) → Case(Term_sub(m, s), xi, Term_sub(n, s))
Term_sub(Term_app(m, n), s) → Term_app(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_pair(m, n), s) → Term_pair(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_inl(m), s) → Term_inl(Term_sub(m, s))
Term_sub(Term_inr(m), s) → Term_inr(Term_sub(m, s))
Term_sub(Term_var(x), Id) → Term_var(x)
Term_sub(Term_var(x), Cons_usual(y, m, s)) → m
Term_sub(Term_var(x), Cons_usual(y, m, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_var(x), Cons_sum(xi, k, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_sub(m, s), t) → Term_sub(m, Concat(s, t))
Sum_sub(xi, Id) → Sum_term_var(xi)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_constant(k)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_sub(xi, s)
Sum_sub(xi, Cons_usual(y, m, s)) → Sum_sub(xi, s)
Concat(Concat(s, t), u) → Concat(s, Concat(t, u))
Concat(Cons_usual(x, m, s), t) → Cons_usual(x, Term_sub(m, t), Concat(s, t))
Concat(Cons_sum(xi, k, s), t) → Cons_sum(xi, k, Concat(s, t))
Concat(Id, s) → s

Rewrite Strategy: FULL

(1) DecreasingLoopProof (EQUIVALENT transformation)

The following loop(s) give(s) rise to the lower bound Ω(n1):
The rewrite sequence
Term_sub(Case(m, xi, n), Id) →+ Case(Term_sub(m, Id), xi, Term_sub(n, Id))
gives rise to a decreasing loop by considering the right hand sides subterm at position [0].
The pumping substitution is [m / Case(m, xi, n)].
The result substitution is [ ].

(2) BOUNDS(n^1, INF)

(3) RenamingProof (EQUIVALENT transformation)

Renamed function symbols to avoid clashes with predefined symbol.

(4) Obligation:

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

Term_sub(Case(m, xi, n), s) → Frozen(m, Sum_sub(xi, s), n, s)
Frozen(m, Sum_constant(Left), n, s) → Term_sub(m, s)
Frozen(m, Sum_constant(Right), n, s) → Term_sub(n, s)
Frozen(m, Sum_term_var(xi), n, s) → Case(Term_sub(m, s), xi, Term_sub(n, s))
Term_sub(Term_app(m, n), s) → Term_app(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_pair(m, n), s) → Term_pair(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_inl(m), s) → Term_inl(Term_sub(m, s))
Term_sub(Term_inr(m), s) → Term_inr(Term_sub(m, s))
Term_sub(Term_var(x), Id) → Term_var(x)
Term_sub(Term_var(x), Cons_usual(y, m, s)) → m
Term_sub(Term_var(x), Cons_usual(y, m, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_var(x), Cons_sum(xi, k, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_sub(m, s), t) → Term_sub(m, Concat(s, t))
Sum_sub(xi, Id) → Sum_term_var(xi)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_constant(k)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_sub(xi, s)
Sum_sub(xi, Cons_usual(y, m, s)) → Sum_sub(xi, s)
Concat(Concat(s, t), u) → Concat(s, Concat(t, u))
Concat(Cons_usual(x, m, s), t) → Cons_usual(x, Term_sub(m, t), Concat(s, t))
Concat(Cons_sum(xi, k, s), t) → Cons_sum(xi, k, Concat(s, t))
Concat(Id, s) → s

S is empty.
Rewrite Strategy: FULL

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

Infered types.

(6) Obligation:

TRS:
Rules:
Term_sub(Case(m, xi, n), s) → Frozen(m, Sum_sub(xi, s), n, s)
Frozen(m, Sum_constant(Left), n, s) → Term_sub(m, s)
Frozen(m, Sum_constant(Right), n, s) → Term_sub(n, s)
Frozen(m, Sum_term_var(xi), n, s) → Case(Term_sub(m, s), xi, Term_sub(n, s))
Term_sub(Term_app(m, n), s) → Term_app(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_pair(m, n), s) → Term_pair(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_inl(m), s) → Term_inl(Term_sub(m, s))
Term_sub(Term_inr(m), s) → Term_inr(Term_sub(m, s))
Term_sub(Term_var(x), Id) → Term_var(x)
Term_sub(Term_var(x), Cons_usual(y, m, s)) → m
Term_sub(Term_var(x), Cons_usual(y, m, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_var(x), Cons_sum(xi, k, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_sub(m, s), t) → Term_sub(m, Concat(s, t))
Sum_sub(xi, Id) → Sum_term_var(xi)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_constant(k)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_sub(xi, s)
Sum_sub(xi, Cons_usual(y, m, s)) → Sum_sub(xi, s)
Concat(Concat(s, t), u) → Concat(s, Concat(t, u))
Concat(Cons_usual(x, m, s), t) → Cons_usual(x, Term_sub(m, t), Concat(s, t))
Concat(Cons_sum(xi, k, s), t) → Cons_sum(xi, k, Concat(s, t))
Concat(Id, s) → s

Types:
Term_sub :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Case :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → a → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Frozen :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Sum_constant:Sum_term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Sum_sub :: a → Id:Cons_usual:Cons_sum → Sum_constant:Sum_term_var
Sum_constant :: Left:Right → Sum_constant:Sum_term_var
Left :: Left:Right
Right :: Left:Right
Sum_term_var :: a → Sum_constant:Sum_term_var
Term_app :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_pair :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inl :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inr :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_var :: b → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Id :: Id:Cons_usual:Cons_sum
Cons_usual :: c → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Cons_sum :: d → Left:Right → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Concat :: Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
hole_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var1_0 :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
hole_Id:Cons_usual:Cons_sum2_0 :: Id:Cons_usual:Cons_sum
hole_a3_0 :: a
hole_Sum_constant:Sum_term_var4_0 :: Sum_constant:Sum_term_var
hole_Left:Right5_0 :: Left:Right
hole_b6_0 :: b
hole_c7_0 :: c
hole_d8_0 :: d
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0 :: Nat → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
gen_Id:Cons_usual:Cons_sum10_0 :: Nat → Id:Cons_usual:Cons_sum

(7) OrderProof (LOWER BOUND(ID) transformation)

Heuristically decided to analyse the following defined symbols:
Term_sub, Sum_sub, Concat

They will be analysed ascendingly in the following order:
Sum_sub < Term_sub
Term_sub = Concat

(8) Obligation:

TRS:
Rules:
Term_sub(Case(m, xi, n), s) → Frozen(m, Sum_sub(xi, s), n, s)
Frozen(m, Sum_constant(Left), n, s) → Term_sub(m, s)
Frozen(m, Sum_constant(Right), n, s) → Term_sub(n, s)
Frozen(m, Sum_term_var(xi), n, s) → Case(Term_sub(m, s), xi, Term_sub(n, s))
Term_sub(Term_app(m, n), s) → Term_app(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_pair(m, n), s) → Term_pair(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_inl(m), s) → Term_inl(Term_sub(m, s))
Term_sub(Term_inr(m), s) → Term_inr(Term_sub(m, s))
Term_sub(Term_var(x), Id) → Term_var(x)
Term_sub(Term_var(x), Cons_usual(y, m, s)) → m
Term_sub(Term_var(x), Cons_usual(y, m, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_var(x), Cons_sum(xi, k, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_sub(m, s), t) → Term_sub(m, Concat(s, t))
Sum_sub(xi, Id) → Sum_term_var(xi)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_constant(k)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_sub(xi, s)
Sum_sub(xi, Cons_usual(y, m, s)) → Sum_sub(xi, s)
Concat(Concat(s, t), u) → Concat(s, Concat(t, u))
Concat(Cons_usual(x, m, s), t) → Cons_usual(x, Term_sub(m, t), Concat(s, t))
Concat(Cons_sum(xi, k, s), t) → Cons_sum(xi, k, Concat(s, t))
Concat(Id, s) → s

Types:
Term_sub :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Case :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → a → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Frozen :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Sum_constant:Sum_term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Sum_sub :: a → Id:Cons_usual:Cons_sum → Sum_constant:Sum_term_var
Sum_constant :: Left:Right → Sum_constant:Sum_term_var
Left :: Left:Right
Right :: Left:Right
Sum_term_var :: a → Sum_constant:Sum_term_var
Term_app :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_pair :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inl :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inr :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_var :: b → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Id :: Id:Cons_usual:Cons_sum
Cons_usual :: c → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Cons_sum :: d → Left:Right → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Concat :: Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
hole_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var1_0 :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
hole_Id:Cons_usual:Cons_sum2_0 :: Id:Cons_usual:Cons_sum
hole_a3_0 :: a
hole_Sum_constant:Sum_term_var4_0 :: Sum_constant:Sum_term_var
hole_Left:Right5_0 :: Left:Right
hole_b6_0 :: b
hole_c7_0 :: c
hole_d8_0 :: d
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0 :: Nat → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
gen_Id:Cons_usual:Cons_sum10_0 :: Nat → Id:Cons_usual:Cons_sum

Generator Equations:
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0) ⇔ Term_var(hole_b6_0)
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(+(x, 1)) ⇔ Case(Term_var(hole_b6_0), hole_a3_0, gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(x))
gen_Id:Cons_usual:Cons_sum10_0(0) ⇔ Id
gen_Id:Cons_usual:Cons_sum10_0(+(x, 1)) ⇔ Cons_usual(hole_c7_0, Term_var(hole_b6_0), gen_Id:Cons_usual:Cons_sum10_0(x))

The following defined symbols remain to be analysed:
Sum_sub, Term_sub, Concat

They will be analysed ascendingly in the following order:
Sum_sub < Term_sub
Term_sub = Concat

(9) RewriteLemmaProof (LOWER BOUND(ID) transformation)

Proved the following rewrite lemma:
Sum_sub(hole_a3_0, gen_Id:Cons_usual:Cons_sum10_0(n12_0)) → Sum_term_var(hole_a3_0), rt ∈ Ω(1 + n120)

Induction Base:
Sum_sub(hole_a3_0, gen_Id:Cons_usual:Cons_sum10_0(0)) →RΩ(1)
Sum_term_var(hole_a3_0)

Induction Step:
Sum_sub(hole_a3_0, gen_Id:Cons_usual:Cons_sum10_0(+(n12_0, 1))) →RΩ(1)
Sum_sub(hole_a3_0, gen_Id:Cons_usual:Cons_sum10_0(n12_0)) →IH
Sum_term_var(hole_a3_0)

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

(10) Complex Obligation (BEST)

(11) Obligation:

TRS:
Rules:
Term_sub(Case(m, xi, n), s) → Frozen(m, Sum_sub(xi, s), n, s)
Frozen(m, Sum_constant(Left), n, s) → Term_sub(m, s)
Frozen(m, Sum_constant(Right), n, s) → Term_sub(n, s)
Frozen(m, Sum_term_var(xi), n, s) → Case(Term_sub(m, s), xi, Term_sub(n, s))
Term_sub(Term_app(m, n), s) → Term_app(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_pair(m, n), s) → Term_pair(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_inl(m), s) → Term_inl(Term_sub(m, s))
Term_sub(Term_inr(m), s) → Term_inr(Term_sub(m, s))
Term_sub(Term_var(x), Id) → Term_var(x)
Term_sub(Term_var(x), Cons_usual(y, m, s)) → m
Term_sub(Term_var(x), Cons_usual(y, m, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_var(x), Cons_sum(xi, k, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_sub(m, s), t) → Term_sub(m, Concat(s, t))
Sum_sub(xi, Id) → Sum_term_var(xi)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_constant(k)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_sub(xi, s)
Sum_sub(xi, Cons_usual(y, m, s)) → Sum_sub(xi, s)
Concat(Concat(s, t), u) → Concat(s, Concat(t, u))
Concat(Cons_usual(x, m, s), t) → Cons_usual(x, Term_sub(m, t), Concat(s, t))
Concat(Cons_sum(xi, k, s), t) → Cons_sum(xi, k, Concat(s, t))
Concat(Id, s) → s

Types:
Term_sub :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Case :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → a → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Frozen :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Sum_constant:Sum_term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Sum_sub :: a → Id:Cons_usual:Cons_sum → Sum_constant:Sum_term_var
Sum_constant :: Left:Right → Sum_constant:Sum_term_var
Left :: Left:Right
Right :: Left:Right
Sum_term_var :: a → Sum_constant:Sum_term_var
Term_app :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_pair :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inl :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inr :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_var :: b → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Id :: Id:Cons_usual:Cons_sum
Cons_usual :: c → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Cons_sum :: d → Left:Right → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Concat :: Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
hole_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var1_0 :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
hole_Id:Cons_usual:Cons_sum2_0 :: Id:Cons_usual:Cons_sum
hole_a3_0 :: a
hole_Sum_constant:Sum_term_var4_0 :: Sum_constant:Sum_term_var
hole_Left:Right5_0 :: Left:Right
hole_b6_0 :: b
hole_c7_0 :: c
hole_d8_0 :: d
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0 :: Nat → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
gen_Id:Cons_usual:Cons_sum10_0 :: Nat → Id:Cons_usual:Cons_sum

Lemmas:
Sum_sub(hole_a3_0, gen_Id:Cons_usual:Cons_sum10_0(n12_0)) → Sum_term_var(hole_a3_0), rt ∈ Ω(1 + n120)

Generator Equations:
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0) ⇔ Term_var(hole_b6_0)
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(+(x, 1)) ⇔ Case(Term_var(hole_b6_0), hole_a3_0, gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(x))
gen_Id:Cons_usual:Cons_sum10_0(0) ⇔ Id
gen_Id:Cons_usual:Cons_sum10_0(+(x, 1)) ⇔ Cons_usual(hole_c7_0, Term_var(hole_b6_0), gen_Id:Cons_usual:Cons_sum10_0(x))

The following defined symbols remain to be analysed:
Concat, Term_sub

They will be analysed ascendingly in the following order:
Term_sub = Concat

(12) RewriteLemmaProof (LOWER BOUND(ID) transformation)

Proved the following rewrite lemma:
Concat(gen_Id:Cons_usual:Cons_sum10_0(n635_0), gen_Id:Cons_usual:Cons_sum10_0(0)) → gen_Id:Cons_usual:Cons_sum10_0(n635_0), rt ∈ Ω(1 + n6350)

Induction Base:
Concat(gen_Id:Cons_usual:Cons_sum10_0(0), gen_Id:Cons_usual:Cons_sum10_0(0)) →RΩ(1)
gen_Id:Cons_usual:Cons_sum10_0(0)

Induction Step:
Concat(gen_Id:Cons_usual:Cons_sum10_0(+(n635_0, 1)), gen_Id:Cons_usual:Cons_sum10_0(0)) →RΩ(1)
Cons_usual(hole_c7_0, Term_sub(Term_var(hole_b6_0), gen_Id:Cons_usual:Cons_sum10_0(0)), Concat(gen_Id:Cons_usual:Cons_sum10_0(n635_0), gen_Id:Cons_usual:Cons_sum10_0(0))) →RΩ(1)
Cons_usual(hole_c7_0, Term_var(hole_b6_0), Concat(gen_Id:Cons_usual:Cons_sum10_0(n635_0), gen_Id:Cons_usual:Cons_sum10_0(0))) →IH
Cons_usual(hole_c7_0, Term_var(hole_b6_0), gen_Id:Cons_usual:Cons_sum10_0(c636_0))

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

(13) Complex Obligation (BEST)

(14) Obligation:

TRS:
Rules:
Term_sub(Case(m, xi, n), s) → Frozen(m, Sum_sub(xi, s), n, s)
Frozen(m, Sum_constant(Left), n, s) → Term_sub(m, s)
Frozen(m, Sum_constant(Right), n, s) → Term_sub(n, s)
Frozen(m, Sum_term_var(xi), n, s) → Case(Term_sub(m, s), xi, Term_sub(n, s))
Term_sub(Term_app(m, n), s) → Term_app(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_pair(m, n), s) → Term_pair(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_inl(m), s) → Term_inl(Term_sub(m, s))
Term_sub(Term_inr(m), s) → Term_inr(Term_sub(m, s))
Term_sub(Term_var(x), Id) → Term_var(x)
Term_sub(Term_var(x), Cons_usual(y, m, s)) → m
Term_sub(Term_var(x), Cons_usual(y, m, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_var(x), Cons_sum(xi, k, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_sub(m, s), t) → Term_sub(m, Concat(s, t))
Sum_sub(xi, Id) → Sum_term_var(xi)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_constant(k)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_sub(xi, s)
Sum_sub(xi, Cons_usual(y, m, s)) → Sum_sub(xi, s)
Concat(Concat(s, t), u) → Concat(s, Concat(t, u))
Concat(Cons_usual(x, m, s), t) → Cons_usual(x, Term_sub(m, t), Concat(s, t))
Concat(Cons_sum(xi, k, s), t) → Cons_sum(xi, k, Concat(s, t))
Concat(Id, s) → s

Types:
Term_sub :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Case :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → a → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Frozen :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Sum_constant:Sum_term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Sum_sub :: a → Id:Cons_usual:Cons_sum → Sum_constant:Sum_term_var
Sum_constant :: Left:Right → Sum_constant:Sum_term_var
Left :: Left:Right
Right :: Left:Right
Sum_term_var :: a → Sum_constant:Sum_term_var
Term_app :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_pair :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inl :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inr :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_var :: b → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Id :: Id:Cons_usual:Cons_sum
Cons_usual :: c → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Cons_sum :: d → Left:Right → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Concat :: Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
hole_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var1_0 :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
hole_Id:Cons_usual:Cons_sum2_0 :: Id:Cons_usual:Cons_sum
hole_a3_0 :: a
hole_Sum_constant:Sum_term_var4_0 :: Sum_constant:Sum_term_var
hole_Left:Right5_0 :: Left:Right
hole_b6_0 :: b
hole_c7_0 :: c
hole_d8_0 :: d
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0 :: Nat → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
gen_Id:Cons_usual:Cons_sum10_0 :: Nat → Id:Cons_usual:Cons_sum

Lemmas:
Sum_sub(hole_a3_0, gen_Id:Cons_usual:Cons_sum10_0(n12_0)) → Sum_term_var(hole_a3_0), rt ∈ Ω(1 + n120)
Concat(gen_Id:Cons_usual:Cons_sum10_0(n635_0), gen_Id:Cons_usual:Cons_sum10_0(0)) → gen_Id:Cons_usual:Cons_sum10_0(n635_0), rt ∈ Ω(1 + n6350)

Generator Equations:
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0) ⇔ Term_var(hole_b6_0)
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(+(x, 1)) ⇔ Case(Term_var(hole_b6_0), hole_a3_0, gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(x))
gen_Id:Cons_usual:Cons_sum10_0(0) ⇔ Id
gen_Id:Cons_usual:Cons_sum10_0(+(x, 1)) ⇔ Cons_usual(hole_c7_0, Term_var(hole_b6_0), gen_Id:Cons_usual:Cons_sum10_0(x))

The following defined symbols remain to be analysed:
Term_sub

They will be analysed ascendingly in the following order:
Term_sub = Concat

(15) RewriteLemmaProof (LOWER BOUND(ID) transformation)

Proved the following rewrite lemma:
Term_sub(gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0), gen_Id:Cons_usual:Cons_sum10_0(n250880_0)) → gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0), rt ∈ Ω(1 + n2508800)

Induction Base:
Term_sub(gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0), gen_Id:Cons_usual:Cons_sum10_0(0)) →RΩ(1)
Term_var(hole_b6_0)

Induction Step:
Term_sub(gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0), gen_Id:Cons_usual:Cons_sum10_0(+(n250880_0, 1))) →RΩ(1)
Term_sub(Term_var(hole_b6_0), gen_Id:Cons_usual:Cons_sum10_0(n250880_0)) →IH
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0)

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

(16) Complex Obligation (BEST)

(17) Obligation:

TRS:
Rules:
Term_sub(Case(m, xi, n), s) → Frozen(m, Sum_sub(xi, s), n, s)
Frozen(m, Sum_constant(Left), n, s) → Term_sub(m, s)
Frozen(m, Sum_constant(Right), n, s) → Term_sub(n, s)
Frozen(m, Sum_term_var(xi), n, s) → Case(Term_sub(m, s), xi, Term_sub(n, s))
Term_sub(Term_app(m, n), s) → Term_app(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_pair(m, n), s) → Term_pair(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_inl(m), s) → Term_inl(Term_sub(m, s))
Term_sub(Term_inr(m), s) → Term_inr(Term_sub(m, s))
Term_sub(Term_var(x), Id) → Term_var(x)
Term_sub(Term_var(x), Cons_usual(y, m, s)) → m
Term_sub(Term_var(x), Cons_usual(y, m, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_var(x), Cons_sum(xi, k, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_sub(m, s), t) → Term_sub(m, Concat(s, t))
Sum_sub(xi, Id) → Sum_term_var(xi)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_constant(k)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_sub(xi, s)
Sum_sub(xi, Cons_usual(y, m, s)) → Sum_sub(xi, s)
Concat(Concat(s, t), u) → Concat(s, Concat(t, u))
Concat(Cons_usual(x, m, s), t) → Cons_usual(x, Term_sub(m, t), Concat(s, t))
Concat(Cons_sum(xi, k, s), t) → Cons_sum(xi, k, Concat(s, t))
Concat(Id, s) → s

Types:
Term_sub :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Case :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → a → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Frozen :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Sum_constant:Sum_term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Sum_sub :: a → Id:Cons_usual:Cons_sum → Sum_constant:Sum_term_var
Sum_constant :: Left:Right → Sum_constant:Sum_term_var
Left :: Left:Right
Right :: Left:Right
Sum_term_var :: a → Sum_constant:Sum_term_var
Term_app :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_pair :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inl :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inr :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_var :: b → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Id :: Id:Cons_usual:Cons_sum
Cons_usual :: c → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Cons_sum :: d → Left:Right → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Concat :: Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
hole_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var1_0 :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
hole_Id:Cons_usual:Cons_sum2_0 :: Id:Cons_usual:Cons_sum
hole_a3_0 :: a
hole_Sum_constant:Sum_term_var4_0 :: Sum_constant:Sum_term_var
hole_Left:Right5_0 :: Left:Right
hole_b6_0 :: b
hole_c7_0 :: c
hole_d8_0 :: d
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0 :: Nat → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
gen_Id:Cons_usual:Cons_sum10_0 :: Nat → Id:Cons_usual:Cons_sum

Lemmas:
Sum_sub(hole_a3_0, gen_Id:Cons_usual:Cons_sum10_0(n12_0)) → Sum_term_var(hole_a3_0), rt ∈ Ω(1 + n120)
Concat(gen_Id:Cons_usual:Cons_sum10_0(n635_0), gen_Id:Cons_usual:Cons_sum10_0(0)) → gen_Id:Cons_usual:Cons_sum10_0(n635_0), rt ∈ Ω(1 + n6350)
Term_sub(gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0), gen_Id:Cons_usual:Cons_sum10_0(n250880_0)) → gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0), rt ∈ Ω(1 + n2508800)

Generator Equations:
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0) ⇔ Term_var(hole_b6_0)
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(+(x, 1)) ⇔ Case(Term_var(hole_b6_0), hole_a3_0, gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(x))
gen_Id:Cons_usual:Cons_sum10_0(0) ⇔ Id
gen_Id:Cons_usual:Cons_sum10_0(+(x, 1)) ⇔ Cons_usual(hole_c7_0, Term_var(hole_b6_0), gen_Id:Cons_usual:Cons_sum10_0(x))

The following defined symbols remain to be analysed:
Concat

They will be analysed ascendingly in the following order:
Term_sub = Concat

(18) RewriteLemmaProof (LOWER BOUND(ID) transformation)

Proved the following rewrite lemma:
Concat(gen_Id:Cons_usual:Cons_sum10_0(n531920_0), gen_Id:Cons_usual:Cons_sum10_0(b)) → gen_Id:Cons_usual:Cons_sum10_0(+(n531920_0, b)), rt ∈ Ω(1 + b·n5319200 + n5319200)

Induction Base:
Concat(gen_Id:Cons_usual:Cons_sum10_0(0), gen_Id:Cons_usual:Cons_sum10_0(b)) →RΩ(1)
gen_Id:Cons_usual:Cons_sum10_0(b)

Induction Step:
Concat(gen_Id:Cons_usual:Cons_sum10_0(+(n531920_0, 1)), gen_Id:Cons_usual:Cons_sum10_0(b)) →RΩ(1)
Cons_usual(hole_c7_0, Term_sub(Term_var(hole_b6_0), gen_Id:Cons_usual:Cons_sum10_0(b)), Concat(gen_Id:Cons_usual:Cons_sum10_0(n531920_0), gen_Id:Cons_usual:Cons_sum10_0(b))) →LΩ(1 + b)
Cons_usual(hole_c7_0, gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0), Concat(gen_Id:Cons_usual:Cons_sum10_0(n531920_0), gen_Id:Cons_usual:Cons_sum10_0(b))) →IH
Cons_usual(hole_c7_0, gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0), gen_Id:Cons_usual:Cons_sum10_0(+(b, c531921_0)))

We have rt ∈ Ω(n2) and sz ∈ O(n). Thus, we have ircR ∈ Ω(n2).

(19) Complex Obligation (BEST)

(20) Obligation:

TRS:
Rules:
Term_sub(Case(m, xi, n), s) → Frozen(m, Sum_sub(xi, s), n, s)
Frozen(m, Sum_constant(Left), n, s) → Term_sub(m, s)
Frozen(m, Sum_constant(Right), n, s) → Term_sub(n, s)
Frozen(m, Sum_term_var(xi), n, s) → Case(Term_sub(m, s), xi, Term_sub(n, s))
Term_sub(Term_app(m, n), s) → Term_app(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_pair(m, n), s) → Term_pair(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_inl(m), s) → Term_inl(Term_sub(m, s))
Term_sub(Term_inr(m), s) → Term_inr(Term_sub(m, s))
Term_sub(Term_var(x), Id) → Term_var(x)
Term_sub(Term_var(x), Cons_usual(y, m, s)) → m
Term_sub(Term_var(x), Cons_usual(y, m, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_var(x), Cons_sum(xi, k, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_sub(m, s), t) → Term_sub(m, Concat(s, t))
Sum_sub(xi, Id) → Sum_term_var(xi)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_constant(k)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_sub(xi, s)
Sum_sub(xi, Cons_usual(y, m, s)) → Sum_sub(xi, s)
Concat(Concat(s, t), u) → Concat(s, Concat(t, u))
Concat(Cons_usual(x, m, s), t) → Cons_usual(x, Term_sub(m, t), Concat(s, t))
Concat(Cons_sum(xi, k, s), t) → Cons_sum(xi, k, Concat(s, t))
Concat(Id, s) → s

Types:
Term_sub :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Case :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → a → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Frozen :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Sum_constant:Sum_term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Sum_sub :: a → Id:Cons_usual:Cons_sum → Sum_constant:Sum_term_var
Sum_constant :: Left:Right → Sum_constant:Sum_term_var
Left :: Left:Right
Right :: Left:Right
Sum_term_var :: a → Sum_constant:Sum_term_var
Term_app :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_pair :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inl :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inr :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_var :: b → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Id :: Id:Cons_usual:Cons_sum
Cons_usual :: c → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Cons_sum :: d → Left:Right → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Concat :: Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
hole_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var1_0 :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
hole_Id:Cons_usual:Cons_sum2_0 :: Id:Cons_usual:Cons_sum
hole_a3_0 :: a
hole_Sum_constant:Sum_term_var4_0 :: Sum_constant:Sum_term_var
hole_Left:Right5_0 :: Left:Right
hole_b6_0 :: b
hole_c7_0 :: c
hole_d8_0 :: d
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0 :: Nat → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
gen_Id:Cons_usual:Cons_sum10_0 :: Nat → Id:Cons_usual:Cons_sum

Lemmas:
Sum_sub(hole_a3_0, gen_Id:Cons_usual:Cons_sum10_0(n12_0)) → Sum_term_var(hole_a3_0), rt ∈ Ω(1 + n120)
Concat(gen_Id:Cons_usual:Cons_sum10_0(n531920_0), gen_Id:Cons_usual:Cons_sum10_0(b)) → gen_Id:Cons_usual:Cons_sum10_0(+(n531920_0, b)), rt ∈ Ω(1 + b·n5319200 + n5319200)
Term_sub(gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0), gen_Id:Cons_usual:Cons_sum10_0(n250880_0)) → gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0), rt ∈ Ω(1 + n2508800)

Generator Equations:
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0) ⇔ Term_var(hole_b6_0)
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(+(x, 1)) ⇔ Case(Term_var(hole_b6_0), hole_a3_0, gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(x))
gen_Id:Cons_usual:Cons_sum10_0(0) ⇔ Id
gen_Id:Cons_usual:Cons_sum10_0(+(x, 1)) ⇔ Cons_usual(hole_c7_0, Term_var(hole_b6_0), gen_Id:Cons_usual:Cons_sum10_0(x))

No more defined symbols left to analyse.

(21) LowerBoundsProof (EQUIVALENT transformation)

The lowerbound Ω(n2) was proven with the following lemma:
Concat(gen_Id:Cons_usual:Cons_sum10_0(n531920_0), gen_Id:Cons_usual:Cons_sum10_0(b)) → gen_Id:Cons_usual:Cons_sum10_0(+(n531920_0, b)), rt ∈ Ω(1 + b·n5319200 + n5319200)

(22) BOUNDS(n^2, INF)

(23) Obligation:

TRS:
Rules:
Term_sub(Case(m, xi, n), s) → Frozen(m, Sum_sub(xi, s), n, s)
Frozen(m, Sum_constant(Left), n, s) → Term_sub(m, s)
Frozen(m, Sum_constant(Right), n, s) → Term_sub(n, s)
Frozen(m, Sum_term_var(xi), n, s) → Case(Term_sub(m, s), xi, Term_sub(n, s))
Term_sub(Term_app(m, n), s) → Term_app(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_pair(m, n), s) → Term_pair(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_inl(m), s) → Term_inl(Term_sub(m, s))
Term_sub(Term_inr(m), s) → Term_inr(Term_sub(m, s))
Term_sub(Term_var(x), Id) → Term_var(x)
Term_sub(Term_var(x), Cons_usual(y, m, s)) → m
Term_sub(Term_var(x), Cons_usual(y, m, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_var(x), Cons_sum(xi, k, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_sub(m, s), t) → Term_sub(m, Concat(s, t))
Sum_sub(xi, Id) → Sum_term_var(xi)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_constant(k)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_sub(xi, s)
Sum_sub(xi, Cons_usual(y, m, s)) → Sum_sub(xi, s)
Concat(Concat(s, t), u) → Concat(s, Concat(t, u))
Concat(Cons_usual(x, m, s), t) → Cons_usual(x, Term_sub(m, t), Concat(s, t))
Concat(Cons_sum(xi, k, s), t) → Cons_sum(xi, k, Concat(s, t))
Concat(Id, s) → s

Types:
Term_sub :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Case :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → a → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Frozen :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Sum_constant:Sum_term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Sum_sub :: a → Id:Cons_usual:Cons_sum → Sum_constant:Sum_term_var
Sum_constant :: Left:Right → Sum_constant:Sum_term_var
Left :: Left:Right
Right :: Left:Right
Sum_term_var :: a → Sum_constant:Sum_term_var
Term_app :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_pair :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inl :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inr :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_var :: b → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Id :: Id:Cons_usual:Cons_sum
Cons_usual :: c → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Cons_sum :: d → Left:Right → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Concat :: Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
hole_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var1_0 :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
hole_Id:Cons_usual:Cons_sum2_0 :: Id:Cons_usual:Cons_sum
hole_a3_0 :: a
hole_Sum_constant:Sum_term_var4_0 :: Sum_constant:Sum_term_var
hole_Left:Right5_0 :: Left:Right
hole_b6_0 :: b
hole_c7_0 :: c
hole_d8_0 :: d
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0 :: Nat → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
gen_Id:Cons_usual:Cons_sum10_0 :: Nat → Id:Cons_usual:Cons_sum

Lemmas:
Sum_sub(hole_a3_0, gen_Id:Cons_usual:Cons_sum10_0(n12_0)) → Sum_term_var(hole_a3_0), rt ∈ Ω(1 + n120)
Concat(gen_Id:Cons_usual:Cons_sum10_0(n531920_0), gen_Id:Cons_usual:Cons_sum10_0(b)) → gen_Id:Cons_usual:Cons_sum10_0(+(n531920_0, b)), rt ∈ Ω(1 + b·n5319200 + n5319200)
Term_sub(gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0), gen_Id:Cons_usual:Cons_sum10_0(n250880_0)) → gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0), rt ∈ Ω(1 + n2508800)

Generator Equations:
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0) ⇔ Term_var(hole_b6_0)
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(+(x, 1)) ⇔ Case(Term_var(hole_b6_0), hole_a3_0, gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(x))
gen_Id:Cons_usual:Cons_sum10_0(0) ⇔ Id
gen_Id:Cons_usual:Cons_sum10_0(+(x, 1)) ⇔ Cons_usual(hole_c7_0, Term_var(hole_b6_0), gen_Id:Cons_usual:Cons_sum10_0(x))

No more defined symbols left to analyse.

(24) LowerBoundsProof (EQUIVALENT transformation)

The lowerbound Ω(n2) was proven with the following lemma:
Concat(gen_Id:Cons_usual:Cons_sum10_0(n531920_0), gen_Id:Cons_usual:Cons_sum10_0(b)) → gen_Id:Cons_usual:Cons_sum10_0(+(n531920_0, b)), rt ∈ Ω(1 + b·n5319200 + n5319200)

(25) BOUNDS(n^2, INF)

(26) Obligation:

TRS:
Rules:
Term_sub(Case(m, xi, n), s) → Frozen(m, Sum_sub(xi, s), n, s)
Frozen(m, Sum_constant(Left), n, s) → Term_sub(m, s)
Frozen(m, Sum_constant(Right), n, s) → Term_sub(n, s)
Frozen(m, Sum_term_var(xi), n, s) → Case(Term_sub(m, s), xi, Term_sub(n, s))
Term_sub(Term_app(m, n), s) → Term_app(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_pair(m, n), s) → Term_pair(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_inl(m), s) → Term_inl(Term_sub(m, s))
Term_sub(Term_inr(m), s) → Term_inr(Term_sub(m, s))
Term_sub(Term_var(x), Id) → Term_var(x)
Term_sub(Term_var(x), Cons_usual(y, m, s)) → m
Term_sub(Term_var(x), Cons_usual(y, m, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_var(x), Cons_sum(xi, k, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_sub(m, s), t) → Term_sub(m, Concat(s, t))
Sum_sub(xi, Id) → Sum_term_var(xi)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_constant(k)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_sub(xi, s)
Sum_sub(xi, Cons_usual(y, m, s)) → Sum_sub(xi, s)
Concat(Concat(s, t), u) → Concat(s, Concat(t, u))
Concat(Cons_usual(x, m, s), t) → Cons_usual(x, Term_sub(m, t), Concat(s, t))
Concat(Cons_sum(xi, k, s), t) → Cons_sum(xi, k, Concat(s, t))
Concat(Id, s) → s

Types:
Term_sub :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Case :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → a → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Frozen :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Sum_constant:Sum_term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Sum_sub :: a → Id:Cons_usual:Cons_sum → Sum_constant:Sum_term_var
Sum_constant :: Left:Right → Sum_constant:Sum_term_var
Left :: Left:Right
Right :: Left:Right
Sum_term_var :: a → Sum_constant:Sum_term_var
Term_app :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_pair :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inl :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inr :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_var :: b → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Id :: Id:Cons_usual:Cons_sum
Cons_usual :: c → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Cons_sum :: d → Left:Right → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Concat :: Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
hole_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var1_0 :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
hole_Id:Cons_usual:Cons_sum2_0 :: Id:Cons_usual:Cons_sum
hole_a3_0 :: a
hole_Sum_constant:Sum_term_var4_0 :: Sum_constant:Sum_term_var
hole_Left:Right5_0 :: Left:Right
hole_b6_0 :: b
hole_c7_0 :: c
hole_d8_0 :: d
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0 :: Nat → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
gen_Id:Cons_usual:Cons_sum10_0 :: Nat → Id:Cons_usual:Cons_sum

Lemmas:
Sum_sub(hole_a3_0, gen_Id:Cons_usual:Cons_sum10_0(n12_0)) → Sum_term_var(hole_a3_0), rt ∈ Ω(1 + n120)
Concat(gen_Id:Cons_usual:Cons_sum10_0(n635_0), gen_Id:Cons_usual:Cons_sum10_0(0)) → gen_Id:Cons_usual:Cons_sum10_0(n635_0), rt ∈ Ω(1 + n6350)
Term_sub(gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0), gen_Id:Cons_usual:Cons_sum10_0(n250880_0)) → gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0), rt ∈ Ω(1 + n2508800)

Generator Equations:
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0) ⇔ Term_var(hole_b6_0)
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(+(x, 1)) ⇔ Case(Term_var(hole_b6_0), hole_a3_0, gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(x))
gen_Id:Cons_usual:Cons_sum10_0(0) ⇔ Id
gen_Id:Cons_usual:Cons_sum10_0(+(x, 1)) ⇔ Cons_usual(hole_c7_0, Term_var(hole_b6_0), gen_Id:Cons_usual:Cons_sum10_0(x))

No more defined symbols left to analyse.

(27) LowerBoundsProof (EQUIVALENT transformation)

The lowerbound Ω(n1) was proven with the following lemma:
Sum_sub(hole_a3_0, gen_Id:Cons_usual:Cons_sum10_0(n12_0)) → Sum_term_var(hole_a3_0), rt ∈ Ω(1 + n120)

(28) BOUNDS(n^1, INF)

(29) Obligation:

TRS:
Rules:
Term_sub(Case(m, xi, n), s) → Frozen(m, Sum_sub(xi, s), n, s)
Frozen(m, Sum_constant(Left), n, s) → Term_sub(m, s)
Frozen(m, Sum_constant(Right), n, s) → Term_sub(n, s)
Frozen(m, Sum_term_var(xi), n, s) → Case(Term_sub(m, s), xi, Term_sub(n, s))
Term_sub(Term_app(m, n), s) → Term_app(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_pair(m, n), s) → Term_pair(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_inl(m), s) → Term_inl(Term_sub(m, s))
Term_sub(Term_inr(m), s) → Term_inr(Term_sub(m, s))
Term_sub(Term_var(x), Id) → Term_var(x)
Term_sub(Term_var(x), Cons_usual(y, m, s)) → m
Term_sub(Term_var(x), Cons_usual(y, m, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_var(x), Cons_sum(xi, k, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_sub(m, s), t) → Term_sub(m, Concat(s, t))
Sum_sub(xi, Id) → Sum_term_var(xi)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_constant(k)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_sub(xi, s)
Sum_sub(xi, Cons_usual(y, m, s)) → Sum_sub(xi, s)
Concat(Concat(s, t), u) → Concat(s, Concat(t, u))
Concat(Cons_usual(x, m, s), t) → Cons_usual(x, Term_sub(m, t), Concat(s, t))
Concat(Cons_sum(xi, k, s), t) → Cons_sum(xi, k, Concat(s, t))
Concat(Id, s) → s

Types:
Term_sub :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Case :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → a → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Frozen :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Sum_constant:Sum_term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Sum_sub :: a → Id:Cons_usual:Cons_sum → Sum_constant:Sum_term_var
Sum_constant :: Left:Right → Sum_constant:Sum_term_var
Left :: Left:Right
Right :: Left:Right
Sum_term_var :: a → Sum_constant:Sum_term_var
Term_app :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_pair :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inl :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inr :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_var :: b → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Id :: Id:Cons_usual:Cons_sum
Cons_usual :: c → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Cons_sum :: d → Left:Right → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Concat :: Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
hole_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var1_0 :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
hole_Id:Cons_usual:Cons_sum2_0 :: Id:Cons_usual:Cons_sum
hole_a3_0 :: a
hole_Sum_constant:Sum_term_var4_0 :: Sum_constant:Sum_term_var
hole_Left:Right5_0 :: Left:Right
hole_b6_0 :: b
hole_c7_0 :: c
hole_d8_0 :: d
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0 :: Nat → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
gen_Id:Cons_usual:Cons_sum10_0 :: Nat → Id:Cons_usual:Cons_sum

Lemmas:
Sum_sub(hole_a3_0, gen_Id:Cons_usual:Cons_sum10_0(n12_0)) → Sum_term_var(hole_a3_0), rt ∈ Ω(1 + n120)
Concat(gen_Id:Cons_usual:Cons_sum10_0(n635_0), gen_Id:Cons_usual:Cons_sum10_0(0)) → gen_Id:Cons_usual:Cons_sum10_0(n635_0), rt ∈ Ω(1 + n6350)

Generator Equations:
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0) ⇔ Term_var(hole_b6_0)
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(+(x, 1)) ⇔ Case(Term_var(hole_b6_0), hole_a3_0, gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(x))
gen_Id:Cons_usual:Cons_sum10_0(0) ⇔ Id
gen_Id:Cons_usual:Cons_sum10_0(+(x, 1)) ⇔ Cons_usual(hole_c7_0, Term_var(hole_b6_0), gen_Id:Cons_usual:Cons_sum10_0(x))

No more defined symbols left to analyse.

(30) LowerBoundsProof (EQUIVALENT transformation)

The lowerbound Ω(n1) was proven with the following lemma:
Sum_sub(hole_a3_0, gen_Id:Cons_usual:Cons_sum10_0(n12_0)) → Sum_term_var(hole_a3_0), rt ∈ Ω(1 + n120)

(31) BOUNDS(n^1, INF)

(32) Obligation:

TRS:
Rules:
Term_sub(Case(m, xi, n), s) → Frozen(m, Sum_sub(xi, s), n, s)
Frozen(m, Sum_constant(Left), n, s) → Term_sub(m, s)
Frozen(m, Sum_constant(Right), n, s) → Term_sub(n, s)
Frozen(m, Sum_term_var(xi), n, s) → Case(Term_sub(m, s), xi, Term_sub(n, s))
Term_sub(Term_app(m, n), s) → Term_app(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_pair(m, n), s) → Term_pair(Term_sub(m, s), Term_sub(n, s))
Term_sub(Term_inl(m), s) → Term_inl(Term_sub(m, s))
Term_sub(Term_inr(m), s) → Term_inr(Term_sub(m, s))
Term_sub(Term_var(x), Id) → Term_var(x)
Term_sub(Term_var(x), Cons_usual(y, m, s)) → m
Term_sub(Term_var(x), Cons_usual(y, m, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_var(x), Cons_sum(xi, k, s)) → Term_sub(Term_var(x), s)
Term_sub(Term_sub(m, s), t) → Term_sub(m, Concat(s, t))
Sum_sub(xi, Id) → Sum_term_var(xi)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_constant(k)
Sum_sub(xi, Cons_sum(psi, k, s)) → Sum_sub(xi, s)
Sum_sub(xi, Cons_usual(y, m, s)) → Sum_sub(xi, s)
Concat(Concat(s, t), u) → Concat(s, Concat(t, u))
Concat(Cons_usual(x, m, s), t) → Cons_usual(x, Term_sub(m, t), Concat(s, t))
Concat(Cons_sum(xi, k, s), t) → Cons_sum(xi, k, Concat(s, t))
Concat(Id, s) → s

Types:
Term_sub :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Case :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → a → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Frozen :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Sum_constant:Sum_term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Sum_sub :: a → Id:Cons_usual:Cons_sum → Sum_constant:Sum_term_var
Sum_constant :: Left:Right → Sum_constant:Sum_term_var
Left :: Left:Right
Right :: Left:Right
Sum_term_var :: a → Sum_constant:Sum_term_var
Term_app :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_pair :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inl :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_inr :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Term_var :: b → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
Id :: Id:Cons_usual:Cons_sum
Cons_usual :: c → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Cons_sum :: d → Left:Right → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
Concat :: Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum → Id:Cons_usual:Cons_sum
hole_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var1_0 :: Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
hole_Id:Cons_usual:Cons_sum2_0 :: Id:Cons_usual:Cons_sum
hole_a3_0 :: a
hole_Sum_constant:Sum_term_var4_0 :: Sum_constant:Sum_term_var
hole_Left:Right5_0 :: Left:Right
hole_b6_0 :: b
hole_c7_0 :: c
hole_d8_0 :: d
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0 :: Nat → Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var
gen_Id:Cons_usual:Cons_sum10_0 :: Nat → Id:Cons_usual:Cons_sum

Lemmas:
Sum_sub(hole_a3_0, gen_Id:Cons_usual:Cons_sum10_0(n12_0)) → Sum_term_var(hole_a3_0), rt ∈ Ω(1 + n120)

Generator Equations:
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(0) ⇔ Term_var(hole_b6_0)
gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(+(x, 1)) ⇔ Case(Term_var(hole_b6_0), hole_a3_0, gen_Case:Term_app:Term_pair:Term_inl:Term_inr:Term_var9_0(x))
gen_Id:Cons_usual:Cons_sum10_0(0) ⇔ Id
gen_Id:Cons_usual:Cons_sum10_0(+(x, 1)) ⇔ Cons_usual(hole_c7_0, Term_var(hole_b6_0), gen_Id:Cons_usual:Cons_sum10_0(x))

No more defined symbols left to analyse.

(33) LowerBoundsProof (EQUIVALENT transformation)

The lowerbound Ω(n1) was proven with the following lemma:
Sum_sub(hole_a3_0, gen_Id:Cons_usual:Cons_sum10_0(n12_0)) → Sum_term_var(hole_a3_0), rt ∈ Ω(1 + n120)

(34) BOUNDS(n^1, INF)