WORST_CASE(?,O(1))
* Step 1: LocalSizeboundsProc WORST_CASE(?,O(1))
+ Considered Problem:
Rules:
0. f0(A) -> f5(0) True (1,1)
1. f5(A) -> f5(1 + A) [1 >= A] (?,1)
2. f5(A) -> f13(A) [A >= 2 && 0 >= 1 + B] (?,1)
3. f5(A) -> f13(A) [A >= 2] (?,1)
Signature:
{(f0,1);(f13,1);(f5,1)}
Flow Graph:
[0->{1,2,3},1->{1,2,3},2->{},3->{}]
+ Applied Processor:
LocalSizeboundsProc
+ Details:
LocalSizebounds generated; rvgraph
(<0,0,A>, 0, .= 0)
(<1,0,A>, 1 + A, .+ 1)
(<2,0,A>, A, .= 0)
(<3,0,A>, A, .= 0)
* Step 2: SizeboundsProc WORST_CASE(?,O(1))
+ Considered Problem:
Rules:
0. f0(A) -> f5(0) True (1,1)
1. f5(A) -> f5(1 + A) [1 >= A] (?,1)
2. f5(A) -> f13(A) [A >= 2 && 0 >= 1 + B] (?,1)
3. f5(A) -> f13(A) [A >= 2] (?,1)
Signature:
{(f0,1);(f13,1);(f5,1)}
Flow Graph:
[0->{1,2,3},1->{1,2,3},2->{},3->{}]
Sizebounds:
(<0,0,A>, ?)
(<1,0,A>, ?)
(<2,0,A>, ?)
(<3,0,A>, ?)
+ Applied Processor:
SizeboundsProc
+ Details:
Sizebounds computed:
(<0,0,A>, 0)
(<1,0,A>, 2)
(<2,0,A>, 2)
(<3,0,A>, 2)
* Step 3: UnsatPaths WORST_CASE(?,O(1))
+ Considered Problem:
Rules:
0. f0(A) -> f5(0) True (1,1)
1. f5(A) -> f5(1 + A) [1 >= A] (?,1)
2. f5(A) -> f13(A) [A >= 2 && 0 >= 1 + B] (?,1)
3. f5(A) -> f13(A) [A >= 2] (?,1)
Signature:
{(f0,1);(f13,1);(f5,1)}
Flow Graph:
[0->{1,2,3},1->{1,2,3},2->{},3->{}]
Sizebounds:
(<0,0,A>, 0)
(<1,0,A>, 2)
(<2,0,A>, 2)
(<3,0,A>, 2)
+ Applied Processor:
UnsatPaths
+ Details:
We remove following edges from the transition graph: [(0,2),(0,3)]
* Step 4: LeafRules WORST_CASE(?,O(1))
+ Considered Problem:
Rules:
0. f0(A) -> f5(0) True (1,1)
1. f5(A) -> f5(1 + A) [1 >= A] (?,1)
2. f5(A) -> f13(A) [A >= 2 && 0 >= 1 + B] (?,1)
3. f5(A) -> f13(A) [A >= 2] (?,1)
Signature:
{(f0,1);(f13,1);(f5,1)}
Flow Graph:
[0->{1},1->{1,2,3},2->{},3->{}]
Sizebounds:
(<0,0,A>, 0)
(<1,0,A>, 2)
(<2,0,A>, 2)
(<3,0,A>, 2)
+ Applied Processor:
LeafRules
+ Details:
The following transitions are estimated by its predecessors and are removed [2,3]
* Step 5: PolyRank WORST_CASE(?,O(1))
+ Considered Problem:
Rules:
0. f0(A) -> f5(0) True (1,1)
1. f5(A) -> f5(1 + A) [1 >= A] (?,1)
Signature:
{(f0,1);(f13,1);(f5,1)}
Flow Graph:
[0->{1},1->{1}]
Sizebounds:
(<0,0,A>, 0)
(<1,0,A>, 2)
+ Applied Processor:
PolyRank {useFarkas = True, withSizebounds = [], shape = Linear}
+ Details:
We apply a polynomial interpretation of shape linear:
p(f0) = 2
p(f5) = 2 + -1*x1
The following rules are strictly oriented:
[1 >= A] ==>
f5(A) = 2 + -1*A
> 1 + -1*A
= f5(1 + A)
The following rules are weakly oriented:
True ==>
f0(A) = 2
>= 2
= f5(0)
* Step 6: KnowledgePropagation WORST_CASE(?,O(1))
+ Considered Problem:
Rules:
0. f0(A) -> f5(0) True (1,1)
1. f5(A) -> f5(1 + A) [1 >= A] (2,1)
Signature:
{(f0,1);(f13,1);(f5,1)}
Flow Graph:
[0->{1},1->{1}]
Sizebounds:
(<0,0,A>, 0)
(<1,0,A>, 2)
+ Applied Processor:
KnowledgePropagation
+ Details:
The problem is already solved.
WORST_CASE(?,O(1))