* Step 1: Sum WORST_CASE(Omega(n^1),?)
+ Considered Problem:
- Strict TRS:
activate(X) -> X
activate(n__from(X)) -> from(X)
activate(n__zWquot(X1,X2)) -> zWquot(X1,X2)
from(X) -> cons(X,n__from(s(X)))
from(X) -> n__from(X)
minus(X,0()) -> 0()
minus(s(X),s(Y)) -> minus(X,Y)
quot(0(),s(Y)) -> 0()
quot(s(X),s(Y)) -> s(quot(minus(X,Y),s(Y)))
sel(0(),cons(X,XS)) -> X
sel(s(N),cons(X,XS)) -> sel(N,activate(XS))
zWquot(X1,X2) -> n__zWquot(X1,X2)
zWquot(XS,nil()) -> nil()
zWquot(cons(X,XS),cons(Y,YS)) -> cons(quot(X,Y),n__zWquot(activate(XS),activate(YS)))
zWquot(nil(),XS) -> nil()
- Signature:
{activate/1,from/1,minus/2,quot/2,sel/2,zWquot/2} / {0/0,cons/2,n__from/1,n__zWquot/2,nil/0,s/1}
- Obligation:
innermost runtime complexity wrt. defined symbols {activate,from,minus,quot,sel,zWquot} and constructors {0
,cons,n__from,n__zWquot,nil,s}
+ Applied Processor:
Sum {left = someStrategy, right = someStrategy}
+ Details:
()
* Step 2: DecreasingLoops WORST_CASE(Omega(n^1),?)
+ Considered Problem:
- Strict TRS:
activate(X) -> X
activate(n__from(X)) -> from(X)
activate(n__zWquot(X1,X2)) -> zWquot(X1,X2)
from(X) -> cons(X,n__from(s(X)))
from(X) -> n__from(X)
minus(X,0()) -> 0()
minus(s(X),s(Y)) -> minus(X,Y)
quot(0(),s(Y)) -> 0()
quot(s(X),s(Y)) -> s(quot(minus(X,Y),s(Y)))
sel(0(),cons(X,XS)) -> X
sel(s(N),cons(X,XS)) -> sel(N,activate(XS))
zWquot(X1,X2) -> n__zWquot(X1,X2)
zWquot(XS,nil()) -> nil()
zWquot(cons(X,XS),cons(Y,YS)) -> cons(quot(X,Y),n__zWquot(activate(XS),activate(YS)))
zWquot(nil(),XS) -> nil()
- Signature:
{activate/1,from/1,minus/2,quot/2,sel/2,zWquot/2} / {0/0,cons/2,n__from/1,n__zWquot/2,nil/0,s/1}
- Obligation:
innermost runtime complexity wrt. defined symbols {activate,from,minus,quot,sel,zWquot} and constructors {0
,cons,n__from,n__zWquot,nil,s}
+ Applied Processor:
DecreasingLoops {bound = AnyLoop, narrow = 10}
+ Details:
The system has following decreasing Loops:
minus(x,y){x -> s(x),y -> s(y)} =
minus(s(x),s(y)) ->^+ minus(x,y)
= C[minus(x,y) = minus(x,y){}]
WORST_CASE(Omega(n^1),?)