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

0 CpxTRS
1 DecreasingLoopProof (⇔, 94 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), 4 ms)
8 typed CpxTrs
9 RewriteLemmaProof (LOWER BOUND(ID), 486 ms)
10 BEST
11 typed CpxTrs
12 LowerBoundsProof (⇔, 0 ms)
13 BOUNDS(n^1, INF)
14 typed CpxTrs
15 LowerBoundsProof (⇔, 0 ms)
16 BOUNDS(n^1, INF)

(0) Obligation:

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

+(+(x, y), z) → +(x, +(y, z))
+(f(x), f(y)) → f(+(x, y))
+(f(x), +(f(y), z)) → +(f(+(x, y)), z)

Rewrite Strategy: FULL

(1) DecreasingLoopProof (EQUIVALENT transformation)

The following loop(s) give(s) rise to the lower bound Ω(n1):
The rewrite sequence
+(f(x), f(y)) →+ f(+(x, y))
gives rise to a decreasing loop by considering the right hand sides subterm at position [0].
The pumping substitution is [x / f(x), y / f(y)].
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:

+'(+'(x, y), z) → +'(x, +'(y, z))
+'(f(x), f(y)) → f(+'(x, y))
+'(f(x), +'(f(y), z)) → +'(f(+'(x, y)), z)

S is empty.
Rewrite Strategy: FULL

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

Infered types.

(6) Obligation:

TRS:
Rules:
+'(+'(x, y), z) → +'(x, +'(y, z))
+'(f(x), f(y)) → f(+'(x, y))
+'(f(x), +'(f(y), z)) → +'(f(+'(x, y)), z)

Types:
+' :: f → f → f
f :: f → f
hole_f1_0 :: f
gen_f2_0 :: Nat → f

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

Heuristically decided to analyse the following defined symbols:
+'

(8) Obligation:

TRS:
Rules:
+'(+'(x, y), z) → +'(x, +'(y, z))
+'(f(x), f(y)) → f(+'(x, y))
+'(f(x), +'(f(y), z)) → +'(f(+'(x, y)), z)

Types:
+' :: f → f → f
f :: f → f
hole_f1_0 :: f
gen_f2_0 :: Nat → f

Generator Equations:
gen_f2_0(0) ⇔ hole_f1_0
gen_f2_0(+(x, 1)) ⇔ f(gen_f2_0(x))

The following defined symbols remain to be analysed:
+'

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

Proved the following rewrite lemma:
+'(gen_f2_0(+(1, n4_0)), gen_f2_0(+(1, n4_0))) → *3_0, rt ∈ Ω(n40)

Induction Base:
+'(gen_f2_0(+(1, 0)), gen_f2_0(+(1, 0)))

Induction Step:
+'(gen_f2_0(+(1, +(n4_0, 1))), gen_f2_0(+(1, +(n4_0, 1)))) →RΩ(1)
f(+'(gen_f2_0(+(1, n4_0)), gen_f2_0(+(1, n4_0)))) →IH
f(*3_0)

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

(10) Complex Obligation (BEST)

(11) Obligation:

TRS:
Rules:
+'(+'(x, y), z) → +'(x, +'(y, z))
+'(f(x), f(y)) → f(+'(x, y))
+'(f(x), +'(f(y), z)) → +'(f(+'(x, y)), z)

Types:
+' :: f → f → f
f :: f → f
hole_f1_0 :: f
gen_f2_0 :: Nat → f

Lemmas:
+'(gen_f2_0(+(1, n4_0)), gen_f2_0(+(1, n4_0))) → *3_0, rt ∈ Ω(n40)

Generator Equations:
gen_f2_0(0) ⇔ hole_f1_0
gen_f2_0(+(x, 1)) ⇔ f(gen_f2_0(x))

No more defined symbols left to analyse.

(12) LowerBoundsProof (EQUIVALENT transformation)

The lowerbound Ω(n1) was proven with the following lemma:
+'(gen_f2_0(+(1, n4_0)), gen_f2_0(+(1, n4_0))) → *3_0, rt ∈ Ω(n40)

(13) BOUNDS(n^1, INF)

(14) Obligation:

TRS:
Rules:
+'(+'(x, y), z) → +'(x, +'(y, z))
+'(f(x), f(y)) → f(+'(x, y))
+'(f(x), +'(f(y), z)) → +'(f(+'(x, y)), z)

Types:
+' :: f → f → f
f :: f → f
hole_f1_0 :: f
gen_f2_0 :: Nat → f

Lemmas:
+'(gen_f2_0(+(1, n4_0)), gen_f2_0(+(1, n4_0))) → *3_0, rt ∈ Ω(n40)

Generator Equations:
gen_f2_0(0) ⇔ hole_f1_0
gen_f2_0(+(x, 1)) ⇔ f(gen_f2_0(x))

No more defined symbols left to analyse.

(15) LowerBoundsProof (EQUIVALENT transformation)

The lowerbound Ω(n1) was proven with the following lemma:
+'(gen_f2_0(+(1, n4_0)), gen_f2_0(+(1, n4_0))) → *3_0, rt ∈ Ω(n40)

(16) BOUNDS(n^1, INF)