LMPO
YES(?,ELEMENTARY)
We consider the following Problem:
Strict Trs:
{ f(X) -> g(n__h(n__f(X)))
, h(X) -> n__h(X)
, f(X) -> n__f(X)
, activate(n__h(X)) -> h(activate(X))
, activate(n__f(X)) -> f(activate(X))
, activate(X) -> X}
StartTerms: basic terms
Strategy: innermost
Certificate: YES(?,ELEMENTARY)
Proof:
The input was oriented with the instance of
Lightweight Multiset Path Order () as induced by the safe mapping
safe(f) = {1}, safe(g) = {1}, safe(n__h) = {1}, safe(n__f) = {1},
safe(h) = {1}, safe(activate) = {}
and precedence
activate > f, activate > h .
Following symbols are considered recursive:
{f, h, activate}
The recursion depth is 2 .
For your convenience, here are the oriented rules in predicative
notation (possibly applying argument filtering):
Strict DPs: {}
Weak DPs : {}
Strict Trs:
{ f(; X) -> g(; n__h(; n__f(; X)))
, h(; X) -> n__h(; X)
, f(; X) -> n__f(; X)
, activate(n__h(; X);) -> h(; activate(X;))
, activate(n__f(; X);) -> f(; activate(X;))
, activate(X;) -> X}
Weak Trs : {}
Hurray, we answered YES(?,ELEMENTARY)
MPO
YES(?,PRIMREC)
We consider the following Problem:
Strict Trs:
{ f(X) -> g(n__h(n__f(X)))
, h(X) -> n__h(X)
, f(X) -> n__f(X)
, activate(n__h(X)) -> h(activate(X))
, activate(n__f(X)) -> f(activate(X))
, activate(X) -> X}
StartTerms: basic terms
Strategy: innermost
Certificate: YES(?,PRIMREC)
Proof:
The input was oriented with the instance of
'multiset path orders' as induced by the precedence
f > g, f > n__h, f > n__f, h > n__h, activate > f, activate > h .
Hurray, we answered YES(?,PRIMREC)
POP*
YES(?,POLY)
We consider the following Problem:
Strict Trs:
{ f(X) -> g(n__h(n__f(X)))
, h(X) -> n__h(X)
, f(X) -> n__f(X)
, activate(n__h(X)) -> h(activate(X))
, activate(n__f(X)) -> f(activate(X))
, activate(X) -> X}
StartTerms: basic terms
Strategy: innermost
Certificate: YES(?,POLY)
Proof:
The input was oriented with the instance of
Polynomial Path Order () as induced by the safe mapping
safe(f) = {1}, safe(g) = {1}, safe(n__h) = {1}, safe(n__f) = {1},
safe(h) = {1}, safe(activate) = {}
and precedence
activate > f, activate > h .
Following symbols are considered recursive:
{f, h, activate}
The recursion depth is 2 .
For your convenience, here are the oriented rules in predicative
notation (possibly applying argument filtering):
Strict DPs: {}
Weak DPs : {}
Strict Trs:
{ f(; X) -> g(; n__h(; n__f(; X)))
, h(; X) -> n__h(; X)
, f(; X) -> n__f(; X)
, activate(n__h(; X);) -> h(; activate(X;))
, activate(n__f(; X);) -> f(; activate(X;))
, activate(X;) -> X}
Weak Trs : {}
Hurray, we answered YES(?,POLY)
POP* (PS)
YES(?,POLY)
We consider the following Problem:
Strict Trs:
{ f(X) -> g(n__h(n__f(X)))
, h(X) -> n__h(X)
, f(X) -> n__f(X)
, activate(n__h(X)) -> h(activate(X))
, activate(n__f(X)) -> f(activate(X))
, activate(X) -> X}
StartTerms: basic terms
Strategy: innermost
Certificate: YES(?,POLY)
Proof:
The input was oriented with the instance of
Polynomial Path Order (PS) as induced by the safe mapping
safe(f) = {1}, safe(g) = {1}, safe(n__h) = {1}, safe(n__f) = {1},
safe(h) = {1}, safe(activate) = {}
and precedence
activate > f, activate > h .
Following symbols are considered recursive:
{f, h, activate}
The recursion depth is 2 .
For your convenience, here are the oriented rules in predicative
notation (possibly applying argument filtering):
Strict DPs: {}
Weak DPs : {}
Strict Trs:
{ f(; X) -> g(; n__h(; n__f(; X)))
, h(; X) -> n__h(; X)
, f(; X) -> n__f(; X)
, activate(n__h(; X);) -> h(; activate(X;))
, activate(n__f(; X);) -> f(; activate(X;))
, activate(X;) -> X}
Weak Trs : {}
Hurray, we answered YES(?,POLY)
Small POP*
YES(?,O(n^1))
We consider the following Problem:
Strict Trs:
{ f(X) -> g(n__h(n__f(X)))
, h(X) -> n__h(X)
, f(X) -> n__f(X)
, activate(n__h(X)) -> h(activate(X))
, activate(n__f(X)) -> f(activate(X))
, activate(X) -> X}
StartTerms: basic terms
Strategy: innermost
Certificate: YES(?,O(n^1))
Proof:
The input was oriented with the instance of
Small Polynomial Path Order (WSC,
Nat 1-bounded) as induced by the safe mapping
safe(f) = {1}, safe(g) = {1}, safe(n__h) = {1}, safe(n__f) = {1},
safe(h) = {1}, safe(activate) = {}
and precedence
activate > f, activate > h .
Following symbols are considered recursive:
{activate}
The recursion depth is 1 .
For your convenience, here are the oriented rules in predicative
notation (possibly applying argument filtering):
Strict DPs: {}
Weak DPs : {}
Strict Trs:
{ f(; X) -> g(; n__h(; n__f(; X)))
, h(; X) -> n__h(; X)
, f(; X) -> n__f(; X)
, activate(n__h(; X);) -> h(; activate(X;))
, activate(n__f(; X);) -> f(; activate(X;))
, activate(X;) -> X}
Weak Trs : {}
Hurray, we answered YES(?,O(n^1))
Small POP* (PS)
YES(?,O(n^1))
We consider the following Problem:
Strict Trs:
{ f(X) -> g(n__h(n__f(X)))
, h(X) -> n__h(X)
, f(X) -> n__f(X)
, activate(n__h(X)) -> h(activate(X))
, activate(n__f(X)) -> f(activate(X))
, activate(X) -> X}
StartTerms: basic terms
Strategy: innermost
Certificate: YES(?,O(n^1))
Proof:
The input was oriented with the instance of
Small Polynomial Path Order (WSC,
PS,
Nat 1-bounded) as induced by the safe mapping
safe(f) = {1}, safe(g) = {1}, safe(n__h) = {1}, safe(n__f) = {1},
safe(h) = {1}, safe(activate) = {}
and precedence
activate > f, activate > h .
Following symbols are considered recursive:
{activate}
The recursion depth is 1 .
For your convenience, here are the oriented rules in predicative
notation (possibly applying argument filtering):
Strict DPs: {}
Weak DPs : {}
Strict Trs:
{ f(; X) -> g(; n__h(; n__f(; X)))
, h(; X) -> n__h(; X)
, f(; X) -> n__f(; X)
, activate(n__h(; X);) -> h(; activate(X;))
, activate(n__f(; X);) -> f(; activate(X;))
, activate(X;) -> X}
Weak Trs : {}
Hurray, we answered YES(?,O(n^1))