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

le(0, y) → true
le(s(x), 0) → false
le(s(x), s(y)) → le(x, y)
minus(x, 0) → x
minus(s(x), s(y)) → minus(x, y)
mod(0, y) → 0
mod(s(x), 0) → 0
mod(s(x), s(y)) → if_mod(le(y, x), s(x), s(y))
if_mod(true, s(x), s(y)) → mod(minus(x, y), s(y))
if_mod(false, s(x), s(y)) → s(x)

Rewrite Strategy: INNERMOST


Renamed function symbols to avoid clashes with predefined symbol.


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


le'(0', y) → true'
le'(s'(x), 0') → false'
le'(s'(x), s'(y)) → le'(x, y)
minus'(x, 0') → x
minus'(s'(x), s'(y)) → minus'(x, y)
mod'(0', y) → 0'
mod'(s'(x), 0') → 0'
mod'(s'(x), s'(y)) → if_mod'(le'(y, x), s'(x), s'(y))
if_mod'(true', s'(x), s'(y)) → mod'(minus'(x, y), s'(y))
if_mod'(false', s'(x), s'(y)) → s'(x)

Rewrite Strategy: INNERMOST


Infered types.


Rules:
le'(0', y) → true'
le'(s'(x), 0') → false'
le'(s'(x), s'(y)) → le'(x, y)
minus'(x, 0') → x
minus'(s'(x), s'(y)) → minus'(x, y)
mod'(0', y) → 0'
mod'(s'(x), 0') → 0'
mod'(s'(x), s'(y)) → if_mod'(le'(y, x), s'(x), s'(y))
if_mod'(true', s'(x), s'(y)) → mod'(minus'(x, y), s'(y))
if_mod'(false', s'(x), s'(y)) → s'(x)

Types:
le' :: 0':s' → 0':s' → true':false'
0' :: 0':s'
true' :: true':false'
s' :: 0':s' → 0':s'
false' :: true':false'
minus' :: 0':s' → 0':s' → 0':s'
mod' :: 0':s' → 0':s' → 0':s'
if_mod' :: true':false' → 0':s' → 0':s' → 0':s'
_hole_true':false'1 :: true':false'
_hole_0':s'2 :: 0':s'
_gen_0':s'3 :: Nat → 0':s'


Heuristically decided to analyse the following defined symbols:
le', minus', mod'

They will be analysed ascendingly in the following order:
le' < mod'
minus' < mod'


Rules:
le'(0', y) → true'
le'(s'(x), 0') → false'
le'(s'(x), s'(y)) → le'(x, y)
minus'(x, 0') → x
minus'(s'(x), s'(y)) → minus'(x, y)
mod'(0', y) → 0'
mod'(s'(x), 0') → 0'
mod'(s'(x), s'(y)) → if_mod'(le'(y, x), s'(x), s'(y))
if_mod'(true', s'(x), s'(y)) → mod'(minus'(x, y), s'(y))
if_mod'(false', s'(x), s'(y)) → s'(x)

Types:
le' :: 0':s' → 0':s' → true':false'
0' :: 0':s'
true' :: true':false'
s' :: 0':s' → 0':s'
false' :: true':false'
minus' :: 0':s' → 0':s' → 0':s'
mod' :: 0':s' → 0':s' → 0':s'
if_mod' :: true':false' → 0':s' → 0':s' → 0':s'
_hole_true':false'1 :: true':false'
_hole_0':s'2 :: 0':s'
_gen_0':s'3 :: Nat → 0':s'

Generator Equations:
_gen_0':s'3(0) ⇔ 0'
_gen_0':s'3(+(x, 1)) ⇔ s'(_gen_0':s'3(x))

The following defined symbols remain to be analysed:
le', minus', mod'

They will be analysed ascendingly in the following order:
le' < mod'
minus' < mod'


Proved the following rewrite lemma:
le'(_gen_0':s'3(_n5), _gen_0':s'3(_n5)) → true', rt ∈ Ω(1 + n5)

Induction Base:
le'(_gen_0':s'3(0), _gen_0':s'3(0)) →RΩ(1)
true'

Induction Step:
le'(_gen_0':s'3(+(_$n6, 1)), _gen_0':s'3(+(_$n6, 1))) →RΩ(1)
le'(_gen_0':s'3(_$n6), _gen_0':s'3(_$n6)) →IH
true'

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


Rules:
le'(0', y) → true'
le'(s'(x), 0') → false'
le'(s'(x), s'(y)) → le'(x, y)
minus'(x, 0') → x
minus'(s'(x), s'(y)) → minus'(x, y)
mod'(0', y) → 0'
mod'(s'(x), 0') → 0'
mod'(s'(x), s'(y)) → if_mod'(le'(y, x), s'(x), s'(y))
if_mod'(true', s'(x), s'(y)) → mod'(minus'(x, y), s'(y))
if_mod'(false', s'(x), s'(y)) → s'(x)

Types:
le' :: 0':s' → 0':s' → true':false'
0' :: 0':s'
true' :: true':false'
s' :: 0':s' → 0':s'
false' :: true':false'
minus' :: 0':s' → 0':s' → 0':s'
mod' :: 0':s' → 0':s' → 0':s'
if_mod' :: true':false' → 0':s' → 0':s' → 0':s'
_hole_true':false'1 :: true':false'
_hole_0':s'2 :: 0':s'
_gen_0':s'3 :: Nat → 0':s'

Lemmas:
le'(_gen_0':s'3(_n5), _gen_0':s'3(_n5)) → true', rt ∈ Ω(1 + n5)

Generator Equations:
_gen_0':s'3(0) ⇔ 0'
_gen_0':s'3(+(x, 1)) ⇔ s'(_gen_0':s'3(x))

The following defined symbols remain to be analysed:
minus', mod'

They will be analysed ascendingly in the following order:
minus' < mod'


Proved the following rewrite lemma:
minus'(_gen_0':s'3(_n533), _gen_0':s'3(_n533)) → _gen_0':s'3(0), rt ∈ Ω(1 + n533)

Induction Base:
minus'(_gen_0':s'3(0), _gen_0':s'3(0)) →RΩ(1)
_gen_0':s'3(0)

Induction Step:
minus'(_gen_0':s'3(+(_$n534, 1)), _gen_0':s'3(+(_$n534, 1))) →RΩ(1)
minus'(_gen_0':s'3(_$n534), _gen_0':s'3(_$n534)) →IH
_gen_0':s'3(0)

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


Rules:
le'(0', y) → true'
le'(s'(x), 0') → false'
le'(s'(x), s'(y)) → le'(x, y)
minus'(x, 0') → x
minus'(s'(x), s'(y)) → minus'(x, y)
mod'(0', y) → 0'
mod'(s'(x), 0') → 0'
mod'(s'(x), s'(y)) → if_mod'(le'(y, x), s'(x), s'(y))
if_mod'(true', s'(x), s'(y)) → mod'(minus'(x, y), s'(y))
if_mod'(false', s'(x), s'(y)) → s'(x)

Types:
le' :: 0':s' → 0':s' → true':false'
0' :: 0':s'
true' :: true':false'
s' :: 0':s' → 0':s'
false' :: true':false'
minus' :: 0':s' → 0':s' → 0':s'
mod' :: 0':s' → 0':s' → 0':s'
if_mod' :: true':false' → 0':s' → 0':s' → 0':s'
_hole_true':false'1 :: true':false'
_hole_0':s'2 :: 0':s'
_gen_0':s'3 :: Nat → 0':s'

Lemmas:
le'(_gen_0':s'3(_n5), _gen_0':s'3(_n5)) → true', rt ∈ Ω(1 + n5)
minus'(_gen_0':s'3(_n533), _gen_0':s'3(_n533)) → _gen_0':s'3(0), rt ∈ Ω(1 + n533)

Generator Equations:
_gen_0':s'3(0) ⇔ 0'
_gen_0':s'3(+(x, 1)) ⇔ s'(_gen_0':s'3(x))

The following defined symbols remain to be analysed:
mod'


Could not prove a rewrite lemma for the defined symbol mod'.


Rules:
le'(0', y) → true'
le'(s'(x), 0') → false'
le'(s'(x), s'(y)) → le'(x, y)
minus'(x, 0') → x
minus'(s'(x), s'(y)) → minus'(x, y)
mod'(0', y) → 0'
mod'(s'(x), 0') → 0'
mod'(s'(x), s'(y)) → if_mod'(le'(y, x), s'(x), s'(y))
if_mod'(true', s'(x), s'(y)) → mod'(minus'(x, y), s'(y))
if_mod'(false', s'(x), s'(y)) → s'(x)

Types:
le' :: 0':s' → 0':s' → true':false'
0' :: 0':s'
true' :: true':false'
s' :: 0':s' → 0':s'
false' :: true':false'
minus' :: 0':s' → 0':s' → 0':s'
mod' :: 0':s' → 0':s' → 0':s'
if_mod' :: true':false' → 0':s' → 0':s' → 0':s'
_hole_true':false'1 :: true':false'
_hole_0':s'2 :: 0':s'
_gen_0':s'3 :: Nat → 0':s'

Lemmas:
le'(_gen_0':s'3(_n5), _gen_0':s'3(_n5)) → true', rt ∈ Ω(1 + n5)
minus'(_gen_0':s'3(_n533), _gen_0':s'3(_n533)) → _gen_0':s'3(0), rt ∈ Ω(1 + n533)

Generator Equations:
_gen_0':s'3(0) ⇔ 0'
_gen_0':s'3(+(x, 1)) ⇔ s'(_gen_0':s'3(x))

No more defined symbols left to analyse.


The lowerbound Ω(n) was proven with the following lemma:
le'(_gen_0':s'3(_n5), _gen_0':s'3(_n5)) → true', rt ∈ Ω(1 + n5)