We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^1)).

Strict Trs:
  { a__f(X, X) -> a__f(a(), b())
  , a__f(X1, X2) -> f(X1, X2)
  , a__b() -> a()
  , a__b() -> b()
  , mark(a()) -> a()
  , mark(b()) -> a__b()
  , mark(f(X1, X2)) -> a__f(mark(X1), X2) }
Obligation:
  runtime complexity
Answer:
  YES(O(1),O(n^1))

The input is overlay and right-linear. Switching to innermost
rewriting.

We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^1)).

Strict Trs:
  { a__f(X, X) -> a__f(a(), b())
  , a__f(X1, X2) -> f(X1, X2)
  , a__b() -> a()
  , a__b() -> b()
  , mark(a()) -> a()
  , mark(b()) -> a__b()
  , mark(f(X1, X2)) -> a__f(mark(X1), X2) }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^1))

We add the following dependency tuples:

Strict DPs:
  { a__f^#(X, X) -> c_1(a__f^#(a(), b()))
  , a__f^#(X1, X2) -> c_2()
  , a__b^#() -> c_3()
  , a__b^#() -> c_4()
  , mark^#(a()) -> c_5()
  , mark^#(b()) -> c_6(a__b^#())
  , mark^#(f(X1, X2)) -> c_7(a__f^#(mark(X1), X2), mark^#(X1)) }

and mark the set of starting terms.

We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^1)).

Strict DPs:
  { a__f^#(X, X) -> c_1(a__f^#(a(), b()))
  , a__f^#(X1, X2) -> c_2()
  , a__b^#() -> c_3()
  , a__b^#() -> c_4()
  , mark^#(a()) -> c_5()
  , mark^#(b()) -> c_6(a__b^#())
  , mark^#(f(X1, X2)) -> c_7(a__f^#(mark(X1), X2), mark^#(X1)) }
Weak Trs:
  { a__f(X, X) -> a__f(a(), b())
  , a__f(X1, X2) -> f(X1, X2)
  , a__b() -> a()
  , a__b() -> b()
  , mark(a()) -> a()
  , mark(b()) -> a__b()
  , mark(f(X1, X2)) -> a__f(mark(X1), X2) }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^1))

We estimate the number of application of {2,3,4,5} by applications
of Pre({2,3,4,5}) = {1,6,7}. Here rules are labeled as follows:

  DPs:
    { 1: a__f^#(X, X) -> c_1(a__f^#(a(), b()))
    , 2: a__f^#(X1, X2) -> c_2()
    , 3: a__b^#() -> c_3()
    , 4: a__b^#() -> c_4()
    , 5: mark^#(a()) -> c_5()
    , 6: mark^#(b()) -> c_6(a__b^#())
    , 7: mark^#(f(X1, X2)) -> c_7(a__f^#(mark(X1), X2), mark^#(X1)) }

We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^1)).

Strict DPs:
  { a__f^#(X, X) -> c_1(a__f^#(a(), b()))
  , mark^#(b()) -> c_6(a__b^#())
  , mark^#(f(X1, X2)) -> c_7(a__f^#(mark(X1), X2), mark^#(X1)) }
Weak DPs:
  { a__f^#(X1, X2) -> c_2()
  , a__b^#() -> c_3()
  , a__b^#() -> c_4()
  , mark^#(a()) -> c_5() }
Weak Trs:
  { a__f(X, X) -> a__f(a(), b())
  , a__f(X1, X2) -> f(X1, X2)
  , a__b() -> a()
  , a__b() -> b()
  , mark(a()) -> a()
  , mark(b()) -> a__b()
  , mark(f(X1, X2)) -> a__f(mark(X1), X2) }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^1))

We estimate the number of application of {1,2} by applications of
Pre({1,2}) = {3}. Here rules are labeled as follows:

  DPs:
    { 1: a__f^#(X, X) -> c_1(a__f^#(a(), b()))
    , 2: mark^#(b()) -> c_6(a__b^#())
    , 3: mark^#(f(X1, X2)) -> c_7(a__f^#(mark(X1), X2), mark^#(X1))
    , 4: a__f^#(X1, X2) -> c_2()
    , 5: a__b^#() -> c_3()
    , 6: a__b^#() -> c_4()
    , 7: mark^#(a()) -> c_5() }

We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^1)).

Strict DPs:
  { mark^#(f(X1, X2)) -> c_7(a__f^#(mark(X1), X2), mark^#(X1)) }
Weak DPs:
  { a__f^#(X, X) -> c_1(a__f^#(a(), b()))
  , a__f^#(X1, X2) -> c_2()
  , a__b^#() -> c_3()
  , a__b^#() -> c_4()
  , mark^#(a()) -> c_5()
  , mark^#(b()) -> c_6(a__b^#()) }
Weak Trs:
  { a__f(X, X) -> a__f(a(), b())
  , a__f(X1, X2) -> f(X1, X2)
  , a__b() -> a()
  , a__b() -> b()
  , mark(a()) -> a()
  , mark(b()) -> a__b()
  , mark(f(X1, X2)) -> a__f(mark(X1), X2) }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^1))

The following weak DPs constitute a sub-graph of the DG that is
closed under successors. The DPs are removed.

{ a__f^#(X, X) -> c_1(a__f^#(a(), b()))
, a__f^#(X1, X2) -> c_2()
, a__b^#() -> c_3()
, a__b^#() -> c_4()
, mark^#(a()) -> c_5()
, mark^#(b()) -> c_6(a__b^#()) }

We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^1)).

Strict DPs:
  { mark^#(f(X1, X2)) -> c_7(a__f^#(mark(X1), X2), mark^#(X1)) }
Weak Trs:
  { a__f(X, X) -> a__f(a(), b())
  , a__f(X1, X2) -> f(X1, X2)
  , a__b() -> a()
  , a__b() -> b()
  , mark(a()) -> a()
  , mark(b()) -> a__b()
  , mark(f(X1, X2)) -> a__f(mark(X1), X2) }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^1))

Due to missing edges in the dependency-graph, the right-hand sides
of following rules could be simplified:

  { mark^#(f(X1, X2)) -> c_7(a__f^#(mark(X1), X2), mark^#(X1)) }

We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^1)).

Strict DPs: { mark^#(f(X1, X2)) -> c_1(mark^#(X1)) }
Weak Trs:
  { a__f(X, X) -> a__f(a(), b())
  , a__f(X1, X2) -> f(X1, X2)
  , a__b() -> a()
  , a__b() -> b()
  , mark(a()) -> a()
  , mark(b()) -> a__b()
  , mark(f(X1, X2)) -> a__f(mark(X1), X2) }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^1))

No rule is usable, rules are removed from the input problem.

We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^1)).

Strict DPs: { mark^#(f(X1, X2)) -> c_1(mark^#(X1)) }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^1))

We use the processor 'Small Polynomial Path Order (PS,1-bounded)'
to orient following rules strictly.

DPs:
  { 1: mark^#(f(X1, X2)) -> c_1(mark^#(X1)) }

Sub-proof:
----------
  The input was oriented with the instance of 'Small Polynomial Path
  Order (PS,1-bounded)' as induced by the safe mapping
  
   safe(f) = {1, 2}, safe(mark^#) = {}, safe(c_1) = {}
  
  and precedence
  
   empty .
  
  Following symbols are considered recursive:
  
   {mark^#}
  
  The recursion depth is 1.
  
  Further, following argument filtering is employed:
  
   pi(f) = [1], pi(mark^#) = [1], pi(c_1) = [1]
  
  Usable defined function symbols are a subset of:
  
   {mark^#}
  
  For your convenience, here are the satisfied ordering constraints:
  
    pi(mark^#(f(X1, X2))) = mark^#(f(; X1);)   
                          > c_1(mark^#(X1;);)  
                          = pi(c_1(mark^#(X1)))
                                               

The strictly oriented rules are moved into the weak component.

We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(1)).

Weak DPs: { mark^#(f(X1, X2)) -> c_1(mark^#(X1)) }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(1))

The following weak DPs constitute a sub-graph of the DG that is
closed under successors. The DPs are removed.

{ mark^#(f(X1, X2)) -> c_1(mark^#(X1)) }

We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(1)).

Rules: Empty
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(1))

Empty rules are trivially bounded

Hurray, we answered YES(O(1),O(n^1))