We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^2)).

Strict Trs:
  { overlap(Nil(), ys) -> False()
  , overlap(Cons(x, xs), ys) ->
    overlap[Ite][True][Ite](member(x, ys), Cons(x, xs), ys)
  , member(x, Nil()) -> False()
  , member(x', Cons(x, xs)) ->
    member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
  , notEmpty(Nil()) -> False()
  , notEmpty(Cons(x, xs)) -> True()
  , goal(xs, ys) -> overlap(xs, ys) }
Weak Trs:
  { member[Ite][True][Ite](True(), x, xs) -> True()
  , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
    member(x', xs)
  , !EQ(S(x), S(y)) -> !EQ(x, y)
  , !EQ(S(x), 0()) -> False()
  , !EQ(0(), S(y)) -> False()
  , !EQ(0(), 0()) -> True()
  , overlap[Ite][True][Ite](True(), xs, ys) -> True()
  , overlap[Ite][True][Ite](False(), Cons(x, xs), ys) ->
    overlap(xs, ys) }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^2))

We add the following dependency tuples:

Strict DPs:
  { overlap^#(Nil(), ys) -> c_1()
  , overlap^#(Cons(x, xs), ys) ->
    c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
        member^#(x, ys))
  , member^#(x, Nil()) -> c_3()
  , member^#(x', Cons(x, xs)) ->
    c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)),
        !EQ^#(x, x'))
  , notEmpty^#(Nil()) -> c_5()
  , notEmpty^#(Cons(x, xs)) -> c_6()
  , goal^#(xs, ys) -> c_7(overlap^#(xs, ys)) }
Weak DPs:
  { overlap[Ite][True][Ite]^#(True(), xs, ys) -> c_14()
  , overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
    c_15(overlap^#(xs, ys))
  , member[Ite][True][Ite]^#(True(), x, xs) -> c_8()
  , member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
    c_9(member^#(x', xs))
  , !EQ^#(S(x), S(y)) -> c_10(!EQ^#(x, y))
  , !EQ^#(S(x), 0()) -> c_11()
  , !EQ^#(0(), S(y)) -> c_12()
  , !EQ^#(0(), 0()) -> c_13() }

and mark the set of starting terms.

We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^2)).

Strict DPs:
  { overlap^#(Nil(), ys) -> c_1()
  , overlap^#(Cons(x, xs), ys) ->
    c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
        member^#(x, ys))
  , member^#(x, Nil()) -> c_3()
  , member^#(x', Cons(x, xs)) ->
    c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)),
        !EQ^#(x, x'))
  , notEmpty^#(Nil()) -> c_5()
  , notEmpty^#(Cons(x, xs)) -> c_6()
  , goal^#(xs, ys) -> c_7(overlap^#(xs, ys)) }
Weak DPs:
  { overlap[Ite][True][Ite]^#(True(), xs, ys) -> c_14()
  , overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
    c_15(overlap^#(xs, ys))
  , member[Ite][True][Ite]^#(True(), x, xs) -> c_8()
  , member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
    c_9(member^#(x', xs))
  , !EQ^#(S(x), S(y)) -> c_10(!EQ^#(x, y))
  , !EQ^#(S(x), 0()) -> c_11()
  , !EQ^#(0(), S(y)) -> c_12()
  , !EQ^#(0(), 0()) -> c_13() }
Weak Trs:
  { member[Ite][True][Ite](True(), x, xs) -> True()
  , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
    member(x', xs)
  , overlap(Nil(), ys) -> False()
  , overlap(Cons(x, xs), ys) ->
    overlap[Ite][True][Ite](member(x, ys), Cons(x, xs), ys)
  , member(x, Nil()) -> False()
  , member(x', Cons(x, xs)) ->
    member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
  , !EQ(S(x), S(y)) -> !EQ(x, y)
  , !EQ(S(x), 0()) -> False()
  , !EQ(0(), S(y)) -> False()
  , !EQ(0(), 0()) -> True()
  , notEmpty(Nil()) -> False()
  , notEmpty(Cons(x, xs)) -> True()
  , overlap[Ite][True][Ite](True(), xs, ys) -> True()
  , overlap[Ite][True][Ite](False(), Cons(x, xs), ys) ->
    overlap(xs, ys)
  , goal(xs, ys) -> overlap(xs, ys) }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^2))

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

  DPs:
    { 1: overlap^#(Nil(), ys) -> c_1()
    , 2: overlap^#(Cons(x, xs), ys) ->
         c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
             member^#(x, ys))
    , 3: member^#(x, Nil()) -> c_3()
    , 4: member^#(x', Cons(x, xs)) ->
         c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)),
             !EQ^#(x, x'))
    , 5: notEmpty^#(Nil()) -> c_5()
    , 6: notEmpty^#(Cons(x, xs)) -> c_6()
    , 7: goal^#(xs, ys) -> c_7(overlap^#(xs, ys))
    , 8: overlap[Ite][True][Ite]^#(True(), xs, ys) -> c_14()
    , 9: overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
         c_15(overlap^#(xs, ys))
    , 10: member[Ite][True][Ite]^#(True(), x, xs) -> c_8()
    , 11: member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
          c_9(member^#(x', xs))
    , 12: !EQ^#(S(x), S(y)) -> c_10(!EQ^#(x, y))
    , 13: !EQ^#(S(x), 0()) -> c_11()
    , 14: !EQ^#(0(), S(y)) -> c_12()
    , 15: !EQ^#(0(), 0()) -> c_13() }

We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^2)).

Strict DPs:
  { overlap^#(Nil(), ys) -> c_1()
  , overlap^#(Cons(x, xs), ys) ->
    c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
        member^#(x, ys))
  , member^#(x, Nil()) -> c_3()
  , member^#(x', Cons(x, xs)) ->
    c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)),
        !EQ^#(x, x'))
  , goal^#(xs, ys) -> c_7(overlap^#(xs, ys)) }
Weak DPs:
  { overlap[Ite][True][Ite]^#(True(), xs, ys) -> c_14()
  , overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
    c_15(overlap^#(xs, ys))
  , member[Ite][True][Ite]^#(True(), x, xs) -> c_8()
  , member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
    c_9(member^#(x', xs))
  , !EQ^#(S(x), S(y)) -> c_10(!EQ^#(x, y))
  , !EQ^#(S(x), 0()) -> c_11()
  , !EQ^#(0(), S(y)) -> c_12()
  , !EQ^#(0(), 0()) -> c_13()
  , notEmpty^#(Nil()) -> c_5()
  , notEmpty^#(Cons(x, xs)) -> c_6() }
Weak Trs:
  { member[Ite][True][Ite](True(), x, xs) -> True()
  , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
    member(x', xs)
  , overlap(Nil(), ys) -> False()
  , overlap(Cons(x, xs), ys) ->
    overlap[Ite][True][Ite](member(x, ys), Cons(x, xs), ys)
  , member(x, Nil()) -> False()
  , member(x', Cons(x, xs)) ->
    member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
  , !EQ(S(x), S(y)) -> !EQ(x, y)
  , !EQ(S(x), 0()) -> False()
  , !EQ(0(), S(y)) -> False()
  , !EQ(0(), 0()) -> True()
  , notEmpty(Nil()) -> False()
  , notEmpty(Cons(x, xs)) -> True()
  , overlap[Ite][True][Ite](True(), xs, ys) -> True()
  , overlap[Ite][True][Ite](False(), Cons(x, xs), ys) ->
    overlap(xs, ys)
  , goal(xs, ys) -> overlap(xs, ys) }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^2))

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

{ overlap[Ite][True][Ite]^#(True(), xs, ys) -> c_14()
, member[Ite][True][Ite]^#(True(), x, xs) -> c_8()
, !EQ^#(S(x), S(y)) -> c_10(!EQ^#(x, y))
, !EQ^#(S(x), 0()) -> c_11()
, !EQ^#(0(), S(y)) -> c_12()
, !EQ^#(0(), 0()) -> c_13()
, notEmpty^#(Nil()) -> c_5()
, notEmpty^#(Cons(x, xs)) -> c_6() }

We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^2)).

Strict DPs:
  { overlap^#(Nil(), ys) -> c_1()
  , overlap^#(Cons(x, xs), ys) ->
    c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
        member^#(x, ys))
  , member^#(x, Nil()) -> c_3()
  , member^#(x', Cons(x, xs)) ->
    c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)),
        !EQ^#(x, x'))
  , goal^#(xs, ys) -> c_7(overlap^#(xs, ys)) }
Weak DPs:
  { overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
    c_15(overlap^#(xs, ys))
  , member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
    c_9(member^#(x', xs)) }
Weak Trs:
  { member[Ite][True][Ite](True(), x, xs) -> True()
  , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
    member(x', xs)
  , overlap(Nil(), ys) -> False()
  , overlap(Cons(x, xs), ys) ->
    overlap[Ite][True][Ite](member(x, ys), Cons(x, xs), ys)
  , member(x, Nil()) -> False()
  , member(x', Cons(x, xs)) ->
    member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
  , !EQ(S(x), S(y)) -> !EQ(x, y)
  , !EQ(S(x), 0()) -> False()
  , !EQ(0(), S(y)) -> False()
  , !EQ(0(), 0()) -> True()
  , notEmpty(Nil()) -> False()
  , notEmpty(Cons(x, xs)) -> True()
  , overlap[Ite][True][Ite](True(), xs, ys) -> True()
  , overlap[Ite][True][Ite](False(), Cons(x, xs), ys) ->
    overlap(xs, ys)
  , goal(xs, ys) -> overlap(xs, ys) }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^2))

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

  { member^#(x', Cons(x, xs)) ->
    c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)),
        !EQ^#(x, x')) }

We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^2)).

Strict DPs:
  { overlap^#(Nil(), ys) -> c_1()
  , overlap^#(Cons(x, xs), ys) ->
    c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
        member^#(x, ys))
  , member^#(x, Nil()) -> c_3()
  , member^#(x', Cons(x, xs)) ->
    c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)))
  , goal^#(xs, ys) -> c_5(overlap^#(xs, ys)) }
Weak DPs:
  { overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
    c_6(overlap^#(xs, ys))
  , member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
    c_7(member^#(x', xs)) }
Weak Trs:
  { member[Ite][True][Ite](True(), x, xs) -> True()
  , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
    member(x', xs)
  , overlap(Nil(), ys) -> False()
  , overlap(Cons(x, xs), ys) ->
    overlap[Ite][True][Ite](member(x, ys), Cons(x, xs), ys)
  , member(x, Nil()) -> False()
  , member(x', Cons(x, xs)) ->
    member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
  , !EQ(S(x), S(y)) -> !EQ(x, y)
  , !EQ(S(x), 0()) -> False()
  , !EQ(0(), S(y)) -> False()
  , !EQ(0(), 0()) -> True()
  , notEmpty(Nil()) -> False()
  , notEmpty(Cons(x, xs)) -> True()
  , overlap[Ite][True][Ite](True(), xs, ys) -> True()
  , overlap[Ite][True][Ite](False(), Cons(x, xs), ys) ->
    overlap(xs, ys)
  , goal(xs, ys) -> overlap(xs, ys) }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^2))

We replace rewrite rules by usable rules:

  Weak Usable Rules:
    { member[Ite][True][Ite](True(), x, xs) -> True()
    , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
      member(x', xs)
    , member(x, Nil()) -> False()
    , member(x', Cons(x, xs)) ->
      member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
    , !EQ(S(x), S(y)) -> !EQ(x, y)
    , !EQ(S(x), 0()) -> False()
    , !EQ(0(), S(y)) -> False()
    , !EQ(0(), 0()) -> True() }

We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^2)).

Strict DPs:
  { overlap^#(Nil(), ys) -> c_1()
  , overlap^#(Cons(x, xs), ys) ->
    c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
        member^#(x, ys))
  , member^#(x, Nil()) -> c_3()
  , member^#(x', Cons(x, xs)) ->
    c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)))
  , goal^#(xs, ys) -> c_5(overlap^#(xs, ys)) }
Weak DPs:
  { overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
    c_6(overlap^#(xs, ys))
  , member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
    c_7(member^#(x', xs)) }
Weak Trs:
  { member[Ite][True][Ite](True(), x, xs) -> True()
  , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
    member(x', xs)
  , member(x, Nil()) -> False()
  , member(x', Cons(x, xs)) ->
    member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
  , !EQ(S(x), S(y)) -> !EQ(x, y)
  , !EQ(S(x), 0()) -> False()
  , !EQ(0(), S(y)) -> False()
  , !EQ(0(), 0()) -> True() }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^2))

Consider the dependency graph

  1: overlap^#(Nil(), ys) -> c_1()
  
  2: overlap^#(Cons(x, xs), ys) ->
     c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
         member^#(x, ys))
     -->_1 overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
           c_6(overlap^#(xs, ys)) :6
     -->_2 member^#(x', Cons(x, xs)) ->
           c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs))) :4
     -->_2 member^#(x, Nil()) -> c_3() :3
  
  3: member^#(x, Nil()) -> c_3()
  
  4: member^#(x', Cons(x, xs)) ->
     c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)))
     -->_1 member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
           c_7(member^#(x', xs)) :7
  
  5: goal^#(xs, ys) -> c_5(overlap^#(xs, ys))
     -->_1 overlap^#(Cons(x, xs), ys) ->
           c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
               member^#(x, ys)) :2
     -->_1 overlap^#(Nil(), ys) -> c_1() :1
  
  6: overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
     c_6(overlap^#(xs, ys))
     -->_1 overlap^#(Cons(x, xs), ys) ->
           c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
               member^#(x, ys)) :2
     -->_1 overlap^#(Nil(), ys) -> c_1() :1
  
  7: member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
     c_7(member^#(x', xs))
     -->_1 member^#(x', Cons(x, xs)) ->
           c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs))) :4
     -->_1 member^#(x, Nil()) -> c_3() :3
  

Following roots of the dependency graph are removed, as the
considered set of starting terms is closed under reduction with
respect to these rules (modulo compound contexts).

  { goal^#(xs, ys) -> c_5(overlap^#(xs, ys)) }


We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^2)).

Strict DPs:
  { overlap^#(Nil(), ys) -> c_1()
  , overlap^#(Cons(x, xs), ys) ->
    c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
        member^#(x, ys))
  , member^#(x, Nil()) -> c_3()
  , member^#(x', Cons(x, xs)) ->
    c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs))) }
Weak DPs:
  { overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
    c_6(overlap^#(xs, ys))
  , member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
    c_7(member^#(x', xs)) }
Weak Trs:
  { member[Ite][True][Ite](True(), x, xs) -> True()
  , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
    member(x', xs)
  , member(x, Nil()) -> False()
  , member(x', Cons(x, xs)) ->
    member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
  , !EQ(S(x), S(y)) -> !EQ(x, y)
  , !EQ(S(x), 0()) -> False()
  , !EQ(0(), S(y)) -> False()
  , !EQ(0(), 0()) -> True() }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^2))

We use the processor 'matrix interpretation of dimension 1' to
orient following rules strictly.

DPs:
  { 1: overlap^#(Nil(), ys) -> c_1() }
Trs: { member[Ite][True][Ite](True(), x, xs) -> True() }

Sub-proof:
----------
  The following argument positions are usable:
    Uargs(c_2) = {1, 2}, Uargs(c_4) = {1}, Uargs(c_6) = {1},
    Uargs(c_7) = {1}
  
  TcT has computed the following constructor-restricted matrix
  interpretation. Note that the diagonal of the component-wise maxima
  of interpretation-entries (of constructors) contains no more than 0
  non-zero entries.
  
                                     [True] = [0]                  
                                                                   
                                      [Nil] = [3]                  
                                                                   
       [member[Ite][True][Ite]](x1, x2, x3) = [3]                  
                                                                   
                           [member](x1, x2) = [3]                  
                                                                   
                              [!EQ](x1, x2) = [0]                  
                                                                   
                                    [S](x1) = [0]                  
                                                                   
                             [Cons](x1, x2) = [0]                  
                                                                   
                                        [0] = [0]                  
                                                                   
                                    [False] = [3]                  
                                                                   
                        [overlap^#](x1, x2) = [3]                  
                                                                   
    [overlap[Ite][True][Ite]^#](x1, x2, x3) = [1] x1 + [6] x2 + [0]
                                                                   
                         [member^#](x1, x2) = [0]                  
                                                                   
     [member[Ite][True][Ite]^#](x1, x2, x3) = [0]                  
                                                                   
                                      [c_1] = [0]                  
                                                                   
                              [c_2](x1, x2) = [1] x1 + [2] x2 + [0]
                                                                   
                                      [c_3] = [0]                  
                                                                   
                                  [c_4](x1) = [4] x1 + [0]         
                                                                   
                                  [c_6](x1) = [1] x1 + [0]         
                                                                   
                                  [c_7](x1) = [2] x1 + [0]         
  
  The order satisfies the following ordering constraints:
  
                  [member[Ite][True][Ite](True(), x, xs)] =  [3]                                                            
                                                          >  [0]                                                            
                                                          =  [True()]                                                       
                                                                                                                            
       [member[Ite][True][Ite](False(), x', Cons(x, xs))] =  [3]                                                            
                                                          >= [3]                                                            
                                                          =  [member(x', xs)]                                               
                                                                                                                            
                                       [member(x, Nil())] =  [3]                                                            
                                                          >= [3]                                                            
                                                          =  [False()]                                                      
                                                                                                                            
                                [member(x', Cons(x, xs))] =  [3]                                                            
                                                          >= [3]                                                            
                                                          =  [member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))]          
                                                                                                                            
                                        [!EQ(S(x), S(y))] =  [0]                                                            
                                                          >= [0]                                                            
                                                          =  [!EQ(x, y)]                                                    
                                                                                                                            
                                         [!EQ(S(x), 0())] =  [0]                                                            
                                                          ?  [3]                                                            
                                                          =  [False()]                                                      
                                                                                                                            
                                         [!EQ(0(), S(y))] =  [0]                                                            
                                                          ?  [3]                                                            
                                                          =  [False()]                                                      
                                                                                                                            
                                          [!EQ(0(), 0())] =  [0]                                                            
                                                          >= [0]                                                            
                                                          =  [True()]                                                       
                                                                                                                            
                                   [overlap^#(Nil(), ys)] =  [3]                                                            
                                                          >  [0]                                                            
                                                          =  [c_1()]                                                        
                                                                                                                            
                             [overlap^#(Cons(x, xs), ys)] =  [3]                                                            
                                                          >= [3]                                                            
                                                          =  [c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
                                                                  member^#(x, ys))]                                         
                                                                                                                            
    [overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys)] =  [3]                                                            
                                                          >= [3]                                                            
                                                          =  [c_6(overlap^#(xs, ys))]                                       
                                                                                                                            
                                     [member^#(x, Nil())] =  [0]                                                            
                                                          >= [0]                                                            
                                                          =  [c_3()]                                                        
                                                                                                                            
                              [member^#(x', Cons(x, xs))] =  [0]                                                            
                                                          >= [0]                                                            
                                                          =  [c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)))]   
                                                                                                                            
     [member[Ite][True][Ite]^#(False(), x', Cons(x, xs))] =  [0]                                                            
                                                          >= [0]                                                            
                                                          =  [c_7(member^#(x', xs))]                                        
                                                                                                                            

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(n^2)).

Strict DPs:
  { overlap^#(Cons(x, xs), ys) ->
    c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
        member^#(x, ys))
  , member^#(x, Nil()) -> c_3()
  , member^#(x', Cons(x, xs)) ->
    c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs))) }
Weak DPs:
  { overlap^#(Nil(), ys) -> c_1()
  , overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
    c_6(overlap^#(xs, ys))
  , member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
    c_7(member^#(x', xs)) }
Weak Trs:
  { member[Ite][True][Ite](True(), x, xs) -> True()
  , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
    member(x', xs)
  , member(x, Nil()) -> False()
  , member(x', Cons(x, xs)) ->
    member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
  , !EQ(S(x), S(y)) -> !EQ(x, y)
  , !EQ(S(x), 0()) -> False()
  , !EQ(0(), S(y)) -> False()
  , !EQ(0(), 0()) -> True() }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^2))

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

{ overlap^#(Nil(), ys) -> c_1() }

We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^2)).

Strict DPs:
  { overlap^#(Cons(x, xs), ys) ->
    c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
        member^#(x, ys))
  , member^#(x, Nil()) -> c_3()
  , member^#(x', Cons(x, xs)) ->
    c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs))) }
Weak DPs:
  { overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
    c_6(overlap^#(xs, ys))
  , member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
    c_7(member^#(x', xs)) }
Weak Trs:
  { member[Ite][True][Ite](True(), x, xs) -> True()
  , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
    member(x', xs)
  , member(x, Nil()) -> False()
  , member(x', Cons(x, xs)) ->
    member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
  , !EQ(S(x), S(y)) -> !EQ(x, y)
  , !EQ(S(x), 0()) -> False()
  , !EQ(0(), S(y)) -> False()
  , !EQ(0(), 0()) -> True() }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^2))

We use the processor 'matrix interpretation of dimension 1' to
orient following rules strictly.

DPs:
  { 2: member^#(x, Nil()) -> c_3() }
Trs:
  { member[Ite][True][Ite](True(), x, xs) -> True()
  , member(x, Nil()) -> False()
  , !EQ(S(x), 0()) -> False()
  , !EQ(0(), S(y)) -> False()
  , !EQ(0(), 0()) -> True() }

Sub-proof:
----------
  The following argument positions are usable:
    Uargs(c_2) = {1, 2}, Uargs(c_4) = {1}, Uargs(c_6) = {1},
    Uargs(c_7) = {1}
  
  TcT has computed the following constructor-based matrix
  interpretation satisfying not(EDA).
  
                                     [True] = [0]                           
                                                                            
                                      [Nil] = [3]                           
                                                                            
       [member[Ite][True][Ite]](x1, x2, x3) = [1]                           
                                                                            
                           [member](x1, x2) = [1]                           
                                                                            
                              [!EQ](x1, x2) = [1]                           
                                                                            
                                    [S](x1) = [1] x1 + [0]                  
                                                                            
                             [Cons](x1, x2) = [1] x2 + [4]                  
                                                                            
                                        [0] = [0]                           
                                                                            
                                    [False] = [0]                           
                                                                            
                        [overlap^#](x1, x2) = [1] x1 + [2] x2 + [4]         
                                                                            
    [overlap[Ite][True][Ite]^#](x1, x2, x3) = [1] x1 + [1] x2 + [2] x3 + [0]
                                                                            
                         [member^#](x1, x2) = [2]                           
                                                                            
     [member[Ite][True][Ite]^#](x1, x2, x3) = [2]                           
                                                                            
                                      [c_1] = [0]                           
                                                                            
                              [c_2](x1, x2) = [1] x1 + [1] x2 + [1]         
                                                                            
                                      [c_3] = [1]                           
                                                                            
                                  [c_4](x1) = [1] x1 + [0]                  
                                                                            
                                  [c_6](x1) = [1] x1 + [0]                  
                                                                            
                                  [c_7](x1) = [1] x1 + [0]                  
  
  The order satisfies the following ordering constraints:
  
                  [member[Ite][True][Ite](True(), x, xs)] =  [1]                                                            
                                                          >  [0]                                                            
                                                          =  [True()]                                                       
                                                                                                                            
       [member[Ite][True][Ite](False(), x', Cons(x, xs))] =  [1]                                                            
                                                          >= [1]                                                            
                                                          =  [member(x', xs)]                                               
                                                                                                                            
                                       [member(x, Nil())] =  [1]                                                            
                                                          >  [0]                                                            
                                                          =  [False()]                                                      
                                                                                                                            
                                [member(x', Cons(x, xs))] =  [1]                                                            
                                                          >= [1]                                                            
                                                          =  [member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))]          
                                                                                                                            
                                        [!EQ(S(x), S(y))] =  [1]                                                            
                                                          >= [1]                                                            
                                                          =  [!EQ(x, y)]                                                    
                                                                                                                            
                                         [!EQ(S(x), 0())] =  [1]                                                            
                                                          >  [0]                                                            
                                                          =  [False()]                                                      
                                                                                                                            
                                         [!EQ(0(), S(y))] =  [1]                                                            
                                                          >  [0]                                                            
                                                          =  [False()]                                                      
                                                                                                                            
                                          [!EQ(0(), 0())] =  [1]                                                            
                                                          >  [0]                                                            
                                                          =  [True()]                                                       
                                                                                                                            
                             [overlap^#(Cons(x, xs), ys)] =  [1] xs + [2] ys + [8]                                          
                                                          >= [1] xs + [2] ys + [8]                                          
                                                          =  [c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
                                                                  member^#(x, ys))]                                         
                                                                                                                            
    [overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys)] =  [1] xs + [2] ys + [4]                                          
                                                          >= [1] xs + [2] ys + [4]                                          
                                                          =  [c_6(overlap^#(xs, ys))]                                       
                                                                                                                            
                                     [member^#(x, Nil())] =  [2]                                                            
                                                          >  [1]                                                            
                                                          =  [c_3()]                                                        
                                                                                                                            
                              [member^#(x', Cons(x, xs))] =  [2]                                                            
                                                          >= [2]                                                            
                                                          =  [c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)))]   
                                                                                                                            
     [member[Ite][True][Ite]^#(False(), x', Cons(x, xs))] =  [2]                                                            
                                                          >= [2]                                                            
                                                          =  [c_7(member^#(x', xs))]                                        
                                                                                                                            

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(n^2)).

Strict DPs:
  { overlap^#(Cons(x, xs), ys) ->
    c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
        member^#(x, ys))
  , member^#(x', Cons(x, xs)) ->
    c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs))) }
Weak DPs:
  { overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
    c_6(overlap^#(xs, ys))
  , member^#(x, Nil()) -> c_3()
  , member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
    c_7(member^#(x', xs)) }
Weak Trs:
  { member[Ite][True][Ite](True(), x, xs) -> True()
  , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
    member(x', xs)
  , member(x, Nil()) -> False()
  , member(x', Cons(x, xs)) ->
    member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
  , !EQ(S(x), S(y)) -> !EQ(x, y)
  , !EQ(S(x), 0()) -> False()
  , !EQ(0(), S(y)) -> False()
  , !EQ(0(), 0()) -> True() }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^2))

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

{ member^#(x, Nil()) -> c_3() }

We are left with following problem, upon which TcT provides the
certificate YES(O(1),O(n^2)).

Strict DPs:
  { overlap^#(Cons(x, xs), ys) ->
    c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
        member^#(x, ys))
  , member^#(x', Cons(x, xs)) ->
    c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs))) }
Weak DPs:
  { overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
    c_6(overlap^#(xs, ys))
  , member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
    c_7(member^#(x', xs)) }
Weak Trs:
  { member[Ite][True][Ite](True(), x, xs) -> True()
  , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
    member(x', xs)
  , member(x, Nil()) -> False()
  , member(x', Cons(x, xs)) ->
    member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
  , !EQ(S(x), S(y)) -> !EQ(x, y)
  , !EQ(S(x), 0()) -> False()
  , !EQ(0(), S(y)) -> False()
  , !EQ(0(), 0()) -> True() }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^2))

We decompose the input problem according to the dependency graph
into the upper component

  { overlap^#(Cons(x, xs), ys) ->
    c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
        member^#(x, ys))
  , overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
    c_6(overlap^#(xs, ys)) }

and lower component

  { member^#(x', Cons(x, xs)) ->
    c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)))
  , member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
    c_7(member^#(x', xs)) }

Further, following extension rules are added to the lower
component.

{ overlap^#(Cons(x, xs), ys) ->
  overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys)
, overlap^#(Cons(x, xs), ys) -> member^#(x, ys)
, overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
  overlap^#(xs, ys) }

TcT solves the upper component with certificate YES(O(1),O(n^1)).

Sub-proof:
----------
  We are left with following problem, upon which TcT provides the
  certificate YES(O(1),O(n^1)).
  
  Strict DPs:
    { overlap^#(Cons(x, xs), ys) ->
      c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
          member^#(x, ys)) }
  Weak DPs:
    { overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
      c_6(overlap^#(xs, ys)) }
  Weak Trs:
    { member[Ite][True][Ite](True(), x, xs) -> True()
    , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
      member(x', xs)
    , member(x, Nil()) -> False()
    , member(x', Cons(x, xs)) ->
      member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
    , !EQ(S(x), S(y)) -> !EQ(x, y)
    , !EQ(S(x), 0()) -> False()
    , !EQ(0(), S(y)) -> False()
    , !EQ(0(), 0()) -> True() }
  Obligation:
    innermost runtime complexity
  Answer:
    YES(O(1),O(n^1))
  
  We use the processor 'matrix interpretation of dimension 1' to
  orient following rules strictly.
  
  DPs:
    { 1: overlap^#(Cons(x, xs), ys) ->
         c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
             member^#(x, ys)) }
  
  Sub-proof:
  ----------
    The following argument positions are usable:
      Uargs(c_2) = {1}, Uargs(c_6) = {1}
    
    TcT has computed the following constructor-based matrix
    interpretation satisfying not(EDA).
    
                                       [True] = [0]                  
                                                                     
                                        [Nil] = [0]                  
                                                                     
         [member[Ite][True][Ite]](x1, x2, x3) = [3] x2 + [0]         
                                                                     
                             [member](x1, x2) = [0]                  
                                                                     
                                [!EQ](x1, x2) = [0]                  
                                                                     
                                      [S](x1) = [1] x1 + [0]         
                                                                     
                               [Cons](x1, x2) = [1] x2 + [2]         
                                                                     
                                          [0] = [0]                  
                                                                     
                                      [False] = [0]                  
                                                                     
                          [overlap^#](x1, x2) = [4] x1 + [4] x2 + [5]
                                                                     
      [overlap[Ite][True][Ite]^#](x1, x2, x3) = [4] x2 + [4] x3 + [1]
                                                                     
                           [member^#](x1, x2) = [1]                  
                                                                     
                                [c_2](x1, x2) = [1] x1 + [1] x2 + [0]
                                                                     
                                    [c_6](x1) = [1] x1 + [4]         
    
    The order satisfies the following ordering constraints:
    
                    [member[Ite][True][Ite](True(), x, xs)] =  [3] x + [0]                                                    
                                                            >= [0]                                                            
                                                            =  [True()]                                                       
                                                                                                                              
         [member[Ite][True][Ite](False(), x', Cons(x, xs))] =  [3] x' + [0]                                                   
                                                            >= [0]                                                            
                                                            =  [member(x', xs)]                                               
                                                                                                                              
                                         [member(x, Nil())] =  [0]                                                            
                                                            >= [0]                                                            
                                                            =  [False()]                                                      
                                                                                                                              
                                  [member(x', Cons(x, xs))] =  [0]                                                            
                                                            ?  [3] x' + [0]                                                   
                                                            =  [member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))]          
                                                                                                                              
                                          [!EQ(S(x), S(y))] =  [0]                                                            
                                                            >= [0]                                                            
                                                            =  [!EQ(x, y)]                                                    
                                                                                                                              
                                           [!EQ(S(x), 0())] =  [0]                                                            
                                                            >= [0]                                                            
                                                            =  [False()]                                                      
                                                                                                                              
                                           [!EQ(0(), S(y))] =  [0]                                                            
                                                            >= [0]                                                            
                                                            =  [False()]                                                      
                                                                                                                              
                                            [!EQ(0(), 0())] =  [0]                                                            
                                                            >= [0]                                                            
                                                            =  [True()]                                                       
                                                                                                                              
                               [overlap^#(Cons(x, xs), ys)] =  [4] xs + [4] ys + [13]                                         
                                                            >  [4] xs + [4] ys + [10]                                         
                                                            =  [c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
                                                                    member^#(x, ys))]                                         
                                                                                                                              
      [overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys)] =  [4] xs + [4] ys + [9]                                          
                                                            >= [4] xs + [4] ys + [9]                                          
                                                            =  [c_6(overlap^#(xs, ys))]                                       
                                                                                                                              
  
  We return to the main proof. Consider the set of all dependency
  pairs
  
  :
    { 1: overlap^#(Cons(x, xs), ys) ->
         c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
             member^#(x, ys))
    , 2: overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
         c_6(overlap^#(xs, ys)) }
  
  Processor 'matrix interpretation of dimension 1' induces the
  complexity certificate YES(?,O(n^1)) on application of dependency
  pairs {1}. These cover all (indirect) predecessors of dependency
  pairs {1,2}, their number of application is equally bounded. The
  dependency pairs are shifted into the weak component.
  
  We are left with following problem, upon which TcT provides the
  certificate YES(O(1),O(1)).
  
  Weak DPs:
    { overlap^#(Cons(x, xs), ys) ->
      c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
          member^#(x, ys))
    , overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
      c_6(overlap^#(xs, ys)) }
  Weak Trs:
    { member[Ite][True][Ite](True(), x, xs) -> True()
    , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
      member(x', xs)
    , member(x, Nil()) -> False()
    , member(x', Cons(x, xs)) ->
      member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
    , !EQ(S(x), S(y)) -> !EQ(x, y)
    , !EQ(S(x), 0()) -> False()
    , !EQ(0(), S(y)) -> False()
    , !EQ(0(), 0()) -> True() }
  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.
  
  { overlap^#(Cons(x, xs), ys) ->
    c_2(overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys),
        member^#(x, ys))
  , overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
    c_6(overlap^#(xs, ys)) }
  
  We are left with following problem, upon which TcT provides the
  certificate YES(O(1),O(1)).
  
  Weak Trs:
    { member[Ite][True][Ite](True(), x, xs) -> True()
    , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
      member(x', xs)
    , member(x, Nil()) -> False()
    , member(x', Cons(x, xs)) ->
      member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
    , !EQ(S(x), S(y)) -> !EQ(x, y)
    , !EQ(S(x), 0()) -> False()
    , !EQ(0(), S(y)) -> False()
    , !EQ(0(), 0()) -> True() }
  Obligation:
    innermost runtime complexity
  Answer:
    YES(O(1),O(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(1)).
  
  Rules: Empty
  Obligation:
    innermost runtime complexity
  Answer:
    YES(O(1),O(1))
  
  Empty rules are trivially bounded

We return to the main proof.

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

Strict DPs:
  { member^#(x', Cons(x, xs)) ->
    c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs))) }
Weak DPs:
  { overlap^#(Cons(x, xs), ys) ->
    overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys)
  , overlap^#(Cons(x, xs), ys) -> member^#(x, ys)
  , overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
    overlap^#(xs, ys)
  , member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
    c_7(member^#(x', xs)) }
Weak Trs:
  { member[Ite][True][Ite](True(), x, xs) -> True()
  , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
    member(x', xs)
  , member(x, Nil()) -> False()
  , member(x', Cons(x, xs)) ->
    member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
  , !EQ(S(x), S(y)) -> !EQ(x, y)
  , !EQ(S(x), 0()) -> False()
  , !EQ(0(), S(y)) -> False()
  , !EQ(0(), 0()) -> True() }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(n^1))

We use the processor 'matrix interpretation of dimension 1' to
orient following rules strictly.

DPs:
  { 1: member^#(x', Cons(x, xs)) ->
       c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)))
  , 3: overlap^#(Cons(x, xs), ys) -> member^#(x, ys)
  , 4: overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
       overlap^#(xs, ys)
  , 5: member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
       c_7(member^#(x', xs)) }

Sub-proof:
----------
  The following argument positions are usable:
    Uargs(c_4) = {1}, Uargs(c_7) = {1}
  
  TcT has computed the following constructor-based matrix
  interpretation satisfying not(EDA).
  
                                     [True] = [0]                  
                                                                   
                                      [Nil] = [0]                  
                                                                   
       [member[Ite][True][Ite]](x1, x2, x3) = [3] x2 + [0]         
                                                                   
                           [member](x1, x2) = [0]                  
                                                                   
                              [!EQ](x1, x2) = [0]                  
                                                                   
                                    [S](x1) = [1] x1 + [0]         
                                                                   
                             [Cons](x1, x2) = [1] x2 + [4]         
                                                                   
                                        [0] = [0]                  
                                                                   
                                    [False] = [0]                  
                                                                   
                        [overlap^#](x1, x2) = [2] x1 + [7] x2 + [0]
                                                                   
    [overlap[Ite][True][Ite]^#](x1, x2, x3) = [2] x2 + [7] x3 + [0]
                                                                   
                         [member^#](x1, x2) = [1] x2 + [4]         
                                                                   
     [member[Ite][True][Ite]^#](x1, x2, x3) = [1] x3 + [3]         
                                                                   
                                  [c_4](x1) = [1] x1 + [0]         
                                                                   
                                  [c_7](x1) = [1] x1 + [0]         
  
  The order satisfies the following ordering constraints:
  
                  [member[Ite][True][Ite](True(), x, xs)] =  [3] x + [0]                                                 
                                                          >= [0]                                                         
                                                          =  [True()]                                                    
                                                                                                                         
       [member[Ite][True][Ite](False(), x', Cons(x, xs))] =  [3] x' + [0]                                                
                                                          >= [0]                                                         
                                                          =  [member(x', xs)]                                            
                                                                                                                         
                                       [member(x, Nil())] =  [0]                                                         
                                                          >= [0]                                                         
                                                          =  [False()]                                                   
                                                                                                                         
                                [member(x', Cons(x, xs))] =  [0]                                                         
                                                          ?  [3] x' + [0]                                                
                                                          =  [member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))]       
                                                                                                                         
                                        [!EQ(S(x), S(y))] =  [0]                                                         
                                                          >= [0]                                                         
                                                          =  [!EQ(x, y)]                                                 
                                                                                                                         
                                         [!EQ(S(x), 0())] =  [0]                                                         
                                                          >= [0]                                                         
                                                          =  [False()]                                                   
                                                                                                                         
                                         [!EQ(0(), S(y))] =  [0]                                                         
                                                          >= [0]                                                         
                                                          =  [False()]                                                   
                                                                                                                         
                                          [!EQ(0(), 0())] =  [0]                                                         
                                                          >= [0]                                                         
                                                          =  [True()]                                                    
                                                                                                                         
                             [overlap^#(Cons(x, xs), ys)] =  [2] xs + [7] ys + [8]                                       
                                                          >= [2] xs + [7] ys + [8]                                       
                                                          =  [overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys)] 
                                                                                                                         
                             [overlap^#(Cons(x, xs), ys)] =  [2] xs + [7] ys + [8]                                       
                                                          >  [1] ys + [4]                                                
                                                          =  [member^#(x, ys)]                                           
                                                                                                                         
    [overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys)] =  [2] xs + [7] ys + [8]                                       
                                                          >  [2] xs + [7] ys + [0]                                       
                                                          =  [overlap^#(xs, ys)]                                         
                                                                                                                         
                              [member^#(x', Cons(x, xs))] =  [1] xs + [8]                                                
                                                          >  [1] xs + [7]                                                
                                                          =  [c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)))]
                                                                                                                         
     [member[Ite][True][Ite]^#(False(), x', Cons(x, xs))] =  [1] xs + [7]                                                
                                                          >  [1] xs + [4]                                                
                                                          =  [c_7(member^#(x', xs))]                                     
                                                                                                                         

We return to the main proof. Consider the set of all dependency
pairs

:
  { 1: member^#(x', Cons(x, xs)) ->
       c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)))
  , 2: overlap^#(Cons(x, xs), ys) ->
       overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys)
  , 3: overlap^#(Cons(x, xs), ys) -> member^#(x, ys)
  , 4: overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
       overlap^#(xs, ys)
  , 5: member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
       c_7(member^#(x', xs)) }

Processor 'matrix interpretation of dimension 1' induces the
complexity certificate YES(?,O(n^1)) on application of dependency
pairs {1,3,4,5}. These cover all (indirect) predecessors of
dependency pairs {1,2,3,4,5}, their number of application is
equally bounded. The dependency pairs are shifted into the weak
component.

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

Weak DPs:
  { overlap^#(Cons(x, xs), ys) ->
    overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys)
  , overlap^#(Cons(x, xs), ys) -> member^#(x, ys)
  , overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
    overlap^#(xs, ys)
  , member^#(x', Cons(x, xs)) ->
    c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)))
  , member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
    c_7(member^#(x', xs)) }
Weak Trs:
  { member[Ite][True][Ite](True(), x, xs) -> True()
  , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
    member(x', xs)
  , member(x, Nil()) -> False()
  , member(x', Cons(x, xs)) ->
    member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
  , !EQ(S(x), S(y)) -> !EQ(x, y)
  , !EQ(S(x), 0()) -> False()
  , !EQ(0(), S(y)) -> False()
  , !EQ(0(), 0()) -> True() }
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.

{ overlap^#(Cons(x, xs), ys) ->
  overlap[Ite][True][Ite]^#(member(x, ys), Cons(x, xs), ys)
, overlap^#(Cons(x, xs), ys) -> member^#(x, ys)
, overlap[Ite][True][Ite]^#(False(), Cons(x, xs), ys) ->
  overlap^#(xs, ys)
, member^#(x', Cons(x, xs)) ->
  c_4(member[Ite][True][Ite]^#(!EQ(x, x'), x', Cons(x, xs)))
, member[Ite][True][Ite]^#(False(), x', Cons(x, xs)) ->
  c_7(member^#(x', xs)) }

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

Weak Trs:
  { member[Ite][True][Ite](True(), x, xs) -> True()
  , member[Ite][True][Ite](False(), x', Cons(x, xs)) ->
    member(x', xs)
  , member(x, Nil()) -> False()
  , member(x', Cons(x, xs)) ->
    member[Ite][True][Ite](!EQ(x, x'), x', Cons(x, xs))
  , !EQ(S(x), S(y)) -> !EQ(x, y)
  , !EQ(S(x), 0()) -> False()
  , !EQ(0(), S(y)) -> False()
  , !EQ(0(), 0()) -> True() }
Obligation:
  innermost runtime complexity
Answer:
  YES(O(1),O(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(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^2))