(0) Obligation:
Runtime Complexity TRS:
The TRS R consists of the following rules:
active(from(X)) → mark(cons(X, from(s(X))))
active(sel(0, cons(X, XS))) → mark(X)
active(sel(s(N), cons(X, XS))) → mark(sel(N, XS))
active(minus(X, 0)) → mark(0)
active(minus(s(X), s(Y))) → mark(minus(X, Y))
active(quot(0, s(Y))) → mark(0)
active(quot(s(X), s(Y))) → mark(s(quot(minus(X, Y), s(Y))))
active(zWquot(XS, nil)) → mark(nil)
active(zWquot(nil, XS)) → mark(nil)
active(zWquot(cons(X, XS), cons(Y, YS))) → mark(cons(quot(X, Y), zWquot(XS, YS)))
active(from(X)) → from(active(X))
active(cons(X1, X2)) → cons(active(X1), X2)
active(s(X)) → s(active(X))
active(sel(X1, X2)) → sel(active(X1), X2)
active(sel(X1, X2)) → sel(X1, active(X2))
active(minus(X1, X2)) → minus(active(X1), X2)
active(minus(X1, X2)) → minus(X1, active(X2))
active(quot(X1, X2)) → quot(active(X1), X2)
active(quot(X1, X2)) → quot(X1, active(X2))
active(zWquot(X1, X2)) → zWquot(active(X1), X2)
active(zWquot(X1, X2)) → zWquot(X1, active(X2))
from(mark(X)) → mark(from(X))
cons(mark(X1), X2) → mark(cons(X1, X2))
s(mark(X)) → mark(s(X))
sel(mark(X1), X2) → mark(sel(X1, X2))
sel(X1, mark(X2)) → mark(sel(X1, X2))
minus(mark(X1), X2) → mark(minus(X1, X2))
minus(X1, mark(X2)) → mark(minus(X1, X2))
quot(mark(X1), X2) → mark(quot(X1, X2))
quot(X1, mark(X2)) → mark(quot(X1, X2))
zWquot(mark(X1), X2) → mark(zWquot(X1, X2))
zWquot(X1, mark(X2)) → mark(zWquot(X1, X2))
proper(from(X)) → from(proper(X))
proper(cons(X1, X2)) → cons(proper(X1), proper(X2))
proper(s(X)) → s(proper(X))
proper(sel(X1, X2)) → sel(proper(X1), proper(X2))
proper(0) → ok(0)
proper(minus(X1, X2)) → minus(proper(X1), proper(X2))
proper(quot(X1, X2)) → quot(proper(X1), proper(X2))
proper(zWquot(X1, X2)) → zWquot(proper(X1), proper(X2))
proper(nil) → ok(nil)
from(ok(X)) → ok(from(X))
cons(ok(X1), ok(X2)) → ok(cons(X1, X2))
s(ok(X)) → ok(s(X))
sel(ok(X1), ok(X2)) → ok(sel(X1, X2))
minus(ok(X1), ok(X2)) → ok(minus(X1, X2))
quot(ok(X1), ok(X2)) → ok(quot(X1, X2))
zWquot(ok(X1), ok(X2)) → ok(zWquot(X1, X2))
top(mark(X)) → top(proper(X))
top(ok(X)) → top(active(X))
Rewrite Strategy: FULL
(1) DecreasingLoopProof (EQUIVALENT transformation)
The following loop(s) give(s) rise to the lower bound Ω(n1):
The rewrite sequence
from(mark(X)) →+ mark(from(X))
gives rise to a decreasing loop by considering the right hand sides subterm at position [0].
The pumping substitution is [X / mark(X)].
The result substitution is [ ].
(2) BOUNDS(n^1, INF)
(3) RenamingProof (EQUIVALENT transformation)
Renamed function symbols to avoid clashes with predefined symbol.
(4) Obligation:
Runtime Complexity Relative TRS:
The TRS R consists of the following rules:
active(from(X)) → mark(cons(X, from(s(X))))
active(sel(0', cons(X, XS))) → mark(X)
active(sel(s(N), cons(X, XS))) → mark(sel(N, XS))
active(minus(X, 0')) → mark(0')
active(minus(s(X), s(Y))) → mark(minus(X, Y))
active(quot(0', s(Y))) → mark(0')
active(quot(s(X), s(Y))) → mark(s(quot(minus(X, Y), s(Y))))
active(zWquot(XS, nil)) → mark(nil)
active(zWquot(nil, XS)) → mark(nil)
active(zWquot(cons(X, XS), cons(Y, YS))) → mark(cons(quot(X, Y), zWquot(XS, YS)))
active(from(X)) → from(active(X))
active(cons(X1, X2)) → cons(active(X1), X2)
active(s(X)) → s(active(X))
active(sel(X1, X2)) → sel(active(X1), X2)
active(sel(X1, X2)) → sel(X1, active(X2))
active(minus(X1, X2)) → minus(active(X1), X2)
active(minus(X1, X2)) → minus(X1, active(X2))
active(quot(X1, X2)) → quot(active(X1), X2)
active(quot(X1, X2)) → quot(X1, active(X2))
active(zWquot(X1, X2)) → zWquot(active(X1), X2)
active(zWquot(X1, X2)) → zWquot(X1, active(X2))
from(mark(X)) → mark(from(X))
cons(mark(X1), X2) → mark(cons(X1, X2))
s(mark(X)) → mark(s(X))
sel(mark(X1), X2) → mark(sel(X1, X2))
sel(X1, mark(X2)) → mark(sel(X1, X2))
minus(mark(X1), X2) → mark(minus(X1, X2))
minus(X1, mark(X2)) → mark(minus(X1, X2))
quot(mark(X1), X2) → mark(quot(X1, X2))
quot(X1, mark(X2)) → mark(quot(X1, X2))
zWquot(mark(X1), X2) → mark(zWquot(X1, X2))
zWquot(X1, mark(X2)) → mark(zWquot(X1, X2))
proper(from(X)) → from(proper(X))
proper(cons(X1, X2)) → cons(proper(X1), proper(X2))
proper(s(X)) → s(proper(X))
proper(sel(X1, X2)) → sel(proper(X1), proper(X2))
proper(0') → ok(0')
proper(minus(X1, X2)) → minus(proper(X1), proper(X2))
proper(quot(X1, X2)) → quot(proper(X1), proper(X2))
proper(zWquot(X1, X2)) → zWquot(proper(X1), proper(X2))
proper(nil) → ok(nil)
from(ok(X)) → ok(from(X))
cons(ok(X1), ok(X2)) → ok(cons(X1, X2))
s(ok(X)) → ok(s(X))
sel(ok(X1), ok(X2)) → ok(sel(X1, X2))
minus(ok(X1), ok(X2)) → ok(minus(X1, X2))
quot(ok(X1), ok(X2)) → ok(quot(X1, X2))
zWquot(ok(X1), ok(X2)) → ok(zWquot(X1, X2))
top(mark(X)) → top(proper(X))
top(ok(X)) → top(active(X))
S is empty.
Rewrite Strategy: FULL
(5) TypeInferenceProof (BOTH BOUNDS(ID, ID) transformation)
Infered types.
(6) Obligation:
TRS:
Rules:
active(from(X)) → mark(cons(X, from(s(X))))
active(sel(0', cons(X, XS))) → mark(X)
active(sel(s(N), cons(X, XS))) → mark(sel(N, XS))
active(minus(X, 0')) → mark(0')
active(minus(s(X), s(Y))) → mark(minus(X, Y))
active(quot(0', s(Y))) → mark(0')
active(quot(s(X), s(Y))) → mark(s(quot(minus(X, Y), s(Y))))
active(zWquot(XS, nil)) → mark(nil)
active(zWquot(nil, XS)) → mark(nil)
active(zWquot(cons(X, XS), cons(Y, YS))) → mark(cons(quot(X, Y), zWquot(XS, YS)))
active(from(X)) → from(active(X))
active(cons(X1, X2)) → cons(active(X1), X2)
active(s(X)) → s(active(X))
active(sel(X1, X2)) → sel(active(X1), X2)
active(sel(X1, X2)) → sel(X1, active(X2))
active(minus(X1, X2)) → minus(active(X1), X2)
active(minus(X1, X2)) → minus(X1, active(X2))
active(quot(X1, X2)) → quot(active(X1), X2)
active(quot(X1, X2)) → quot(X1, active(X2))
active(zWquot(X1, X2)) → zWquot(active(X1), X2)
active(zWquot(X1, X2)) → zWquot(X1, active(X2))
from(mark(X)) → mark(from(X))
cons(mark(X1), X2) → mark(cons(X1, X2))
s(mark(X)) → mark(s(X))
sel(mark(X1), X2) → mark(sel(X1, X2))
sel(X1, mark(X2)) → mark(sel(X1, X2))
minus(mark(X1), X2) → mark(minus(X1, X2))
minus(X1, mark(X2)) → mark(minus(X1, X2))
quot(mark(X1), X2) → mark(quot(X1, X2))
quot(X1, mark(X2)) → mark(quot(X1, X2))
zWquot(mark(X1), X2) → mark(zWquot(X1, X2))
zWquot(X1, mark(X2)) → mark(zWquot(X1, X2))
proper(from(X)) → from(proper(X))
proper(cons(X1, X2)) → cons(proper(X1), proper(X2))
proper(s(X)) → s(proper(X))
proper(sel(X1, X2)) → sel(proper(X1), proper(X2))
proper(0') → ok(0')
proper(minus(X1, X2)) → minus(proper(X1), proper(X2))
proper(quot(X1, X2)) → quot(proper(X1), proper(X2))
proper(zWquot(X1, X2)) → zWquot(proper(X1), proper(X2))
proper(nil) → ok(nil)
from(ok(X)) → ok(from(X))
cons(ok(X1), ok(X2)) → ok(cons(X1, X2))
s(ok(X)) → ok(s(X))
sel(ok(X1), ok(X2)) → ok(sel(X1, X2))
minus(ok(X1), ok(X2)) → ok(minus(X1, X2))
quot(ok(X1), ok(X2)) → ok(quot(X1, X2))
zWquot(ok(X1), ok(X2)) → ok(zWquot(X1, X2))
top(mark(X)) → top(proper(X))
top(ok(X)) → top(active(X))
Types:
active :: mark:0':nil:ok → mark:0':nil:ok
from :: mark:0':nil:ok → mark:0':nil:ok
mark :: mark:0':nil:ok → mark:0':nil:ok
cons :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
s :: mark:0':nil:ok → mark:0':nil:ok
sel :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
0' :: mark:0':nil:ok
minus :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
quot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
zWquot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
nil :: mark:0':nil:ok
proper :: mark:0':nil:ok → mark:0':nil:ok
ok :: mark:0':nil:ok → mark:0':nil:ok
top :: mark:0':nil:ok → top
hole_mark:0':nil:ok1_0 :: mark:0':nil:ok
hole_top2_0 :: top
gen_mark:0':nil:ok3_0 :: Nat → mark:0':nil:ok
(7) OrderProof (LOWER BOUND(ID) transformation)
Heuristically decided to analyse the following defined symbols:
active,
cons,
from,
s,
sel,
minus,
quot,
zWquot,
proper,
topThey will be analysed ascendingly in the following order:
cons < active
from < active
s < active
sel < active
minus < active
quot < active
zWquot < active
active < top
cons < proper
from < proper
s < proper
sel < proper
minus < proper
quot < proper
zWquot < proper
proper < top
(8) Obligation:
TRS:
Rules:
active(
from(
X)) →
mark(
cons(
X,
from(
s(
X))))
active(
sel(
0',
cons(
X,
XS))) →
mark(
X)
active(
sel(
s(
N),
cons(
X,
XS))) →
mark(
sel(
N,
XS))
active(
minus(
X,
0')) →
mark(
0')
active(
minus(
s(
X),
s(
Y))) →
mark(
minus(
X,
Y))
active(
quot(
0',
s(
Y))) →
mark(
0')
active(
quot(
s(
X),
s(
Y))) →
mark(
s(
quot(
minus(
X,
Y),
s(
Y))))
active(
zWquot(
XS,
nil)) →
mark(
nil)
active(
zWquot(
nil,
XS)) →
mark(
nil)
active(
zWquot(
cons(
X,
XS),
cons(
Y,
YS))) →
mark(
cons(
quot(
X,
Y),
zWquot(
XS,
YS)))
active(
from(
X)) →
from(
active(
X))
active(
cons(
X1,
X2)) →
cons(
active(
X1),
X2)
active(
s(
X)) →
s(
active(
X))
active(
sel(
X1,
X2)) →
sel(
active(
X1),
X2)
active(
sel(
X1,
X2)) →
sel(
X1,
active(
X2))
active(
minus(
X1,
X2)) →
minus(
active(
X1),
X2)
active(
minus(
X1,
X2)) →
minus(
X1,
active(
X2))
active(
quot(
X1,
X2)) →
quot(
active(
X1),
X2)
active(
quot(
X1,
X2)) →
quot(
X1,
active(
X2))
active(
zWquot(
X1,
X2)) →
zWquot(
active(
X1),
X2)
active(
zWquot(
X1,
X2)) →
zWquot(
X1,
active(
X2))
from(
mark(
X)) →
mark(
from(
X))
cons(
mark(
X1),
X2) →
mark(
cons(
X1,
X2))
s(
mark(
X)) →
mark(
s(
X))
sel(
mark(
X1),
X2) →
mark(
sel(
X1,
X2))
sel(
X1,
mark(
X2)) →
mark(
sel(
X1,
X2))
minus(
mark(
X1),
X2) →
mark(
minus(
X1,
X2))
minus(
X1,
mark(
X2)) →
mark(
minus(
X1,
X2))
quot(
mark(
X1),
X2) →
mark(
quot(
X1,
X2))
quot(
X1,
mark(
X2)) →
mark(
quot(
X1,
X2))
zWquot(
mark(
X1),
X2) →
mark(
zWquot(
X1,
X2))
zWquot(
X1,
mark(
X2)) →
mark(
zWquot(
X1,
X2))
proper(
from(
X)) →
from(
proper(
X))
proper(
cons(
X1,
X2)) →
cons(
proper(
X1),
proper(
X2))
proper(
s(
X)) →
s(
proper(
X))
proper(
sel(
X1,
X2)) →
sel(
proper(
X1),
proper(
X2))
proper(
0') →
ok(
0')
proper(
minus(
X1,
X2)) →
minus(
proper(
X1),
proper(
X2))
proper(
quot(
X1,
X2)) →
quot(
proper(
X1),
proper(
X2))
proper(
zWquot(
X1,
X2)) →
zWquot(
proper(
X1),
proper(
X2))
proper(
nil) →
ok(
nil)
from(
ok(
X)) →
ok(
from(
X))
cons(
ok(
X1),
ok(
X2)) →
ok(
cons(
X1,
X2))
s(
ok(
X)) →
ok(
s(
X))
sel(
ok(
X1),
ok(
X2)) →
ok(
sel(
X1,
X2))
minus(
ok(
X1),
ok(
X2)) →
ok(
minus(
X1,
X2))
quot(
ok(
X1),
ok(
X2)) →
ok(
quot(
X1,
X2))
zWquot(
ok(
X1),
ok(
X2)) →
ok(
zWquot(
X1,
X2))
top(
mark(
X)) →
top(
proper(
X))
top(
ok(
X)) →
top(
active(
X))
Types:
active :: mark:0':nil:ok → mark:0':nil:ok
from :: mark:0':nil:ok → mark:0':nil:ok
mark :: mark:0':nil:ok → mark:0':nil:ok
cons :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
s :: mark:0':nil:ok → mark:0':nil:ok
sel :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
0' :: mark:0':nil:ok
minus :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
quot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
zWquot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
nil :: mark:0':nil:ok
proper :: mark:0':nil:ok → mark:0':nil:ok
ok :: mark:0':nil:ok → mark:0':nil:ok
top :: mark:0':nil:ok → top
hole_mark:0':nil:ok1_0 :: mark:0':nil:ok
hole_top2_0 :: top
gen_mark:0':nil:ok3_0 :: Nat → mark:0':nil:ok
Generator Equations:
gen_mark:0':nil:ok3_0(0) ⇔ 0'
gen_mark:0':nil:ok3_0(+(x, 1)) ⇔ mark(gen_mark:0':nil:ok3_0(x))
The following defined symbols remain to be analysed:
cons, active, from, s, sel, minus, quot, zWquot, proper, top
They will be analysed ascendingly in the following order:
cons < active
from < active
s < active
sel < active
minus < active
quot < active
zWquot < active
active < top
cons < proper
from < proper
s < proper
sel < proper
minus < proper
quot < proper
zWquot < proper
proper < top
(9) NoRewriteLemmaProof (LOWER BOUND(ID) transformation)
Could not prove a rewrite lemma for the defined symbol cons.
(10) Obligation:
TRS:
Rules:
active(
from(
X)) →
mark(
cons(
X,
from(
s(
X))))
active(
sel(
0',
cons(
X,
XS))) →
mark(
X)
active(
sel(
s(
N),
cons(
X,
XS))) →
mark(
sel(
N,
XS))
active(
minus(
X,
0')) →
mark(
0')
active(
minus(
s(
X),
s(
Y))) →
mark(
minus(
X,
Y))
active(
quot(
0',
s(
Y))) →
mark(
0')
active(
quot(
s(
X),
s(
Y))) →
mark(
s(
quot(
minus(
X,
Y),
s(
Y))))
active(
zWquot(
XS,
nil)) →
mark(
nil)
active(
zWquot(
nil,
XS)) →
mark(
nil)
active(
zWquot(
cons(
X,
XS),
cons(
Y,
YS))) →
mark(
cons(
quot(
X,
Y),
zWquot(
XS,
YS)))
active(
from(
X)) →
from(
active(
X))
active(
cons(
X1,
X2)) →
cons(
active(
X1),
X2)
active(
s(
X)) →
s(
active(
X))
active(
sel(
X1,
X2)) →
sel(
active(
X1),
X2)
active(
sel(
X1,
X2)) →
sel(
X1,
active(
X2))
active(
minus(
X1,
X2)) →
minus(
active(
X1),
X2)
active(
minus(
X1,
X2)) →
minus(
X1,
active(
X2))
active(
quot(
X1,
X2)) →
quot(
active(
X1),
X2)
active(
quot(
X1,
X2)) →
quot(
X1,
active(
X2))
active(
zWquot(
X1,
X2)) →
zWquot(
active(
X1),
X2)
active(
zWquot(
X1,
X2)) →
zWquot(
X1,
active(
X2))
from(
mark(
X)) →
mark(
from(
X))
cons(
mark(
X1),
X2) →
mark(
cons(
X1,
X2))
s(
mark(
X)) →
mark(
s(
X))
sel(
mark(
X1),
X2) →
mark(
sel(
X1,
X2))
sel(
X1,
mark(
X2)) →
mark(
sel(
X1,
X2))
minus(
mark(
X1),
X2) →
mark(
minus(
X1,
X2))
minus(
X1,
mark(
X2)) →
mark(
minus(
X1,
X2))
quot(
mark(
X1),
X2) →
mark(
quot(
X1,
X2))
quot(
X1,
mark(
X2)) →
mark(
quot(
X1,
X2))
zWquot(
mark(
X1),
X2) →
mark(
zWquot(
X1,
X2))
zWquot(
X1,
mark(
X2)) →
mark(
zWquot(
X1,
X2))
proper(
from(
X)) →
from(
proper(
X))
proper(
cons(
X1,
X2)) →
cons(
proper(
X1),
proper(
X2))
proper(
s(
X)) →
s(
proper(
X))
proper(
sel(
X1,
X2)) →
sel(
proper(
X1),
proper(
X2))
proper(
0') →
ok(
0')
proper(
minus(
X1,
X2)) →
minus(
proper(
X1),
proper(
X2))
proper(
quot(
X1,
X2)) →
quot(
proper(
X1),
proper(
X2))
proper(
zWquot(
X1,
X2)) →
zWquot(
proper(
X1),
proper(
X2))
proper(
nil) →
ok(
nil)
from(
ok(
X)) →
ok(
from(
X))
cons(
ok(
X1),
ok(
X2)) →
ok(
cons(
X1,
X2))
s(
ok(
X)) →
ok(
s(
X))
sel(
ok(
X1),
ok(
X2)) →
ok(
sel(
X1,
X2))
minus(
ok(
X1),
ok(
X2)) →
ok(
minus(
X1,
X2))
quot(
ok(
X1),
ok(
X2)) →
ok(
quot(
X1,
X2))
zWquot(
ok(
X1),
ok(
X2)) →
ok(
zWquot(
X1,
X2))
top(
mark(
X)) →
top(
proper(
X))
top(
ok(
X)) →
top(
active(
X))
Types:
active :: mark:0':nil:ok → mark:0':nil:ok
from :: mark:0':nil:ok → mark:0':nil:ok
mark :: mark:0':nil:ok → mark:0':nil:ok
cons :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
s :: mark:0':nil:ok → mark:0':nil:ok
sel :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
0' :: mark:0':nil:ok
minus :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
quot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
zWquot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
nil :: mark:0':nil:ok
proper :: mark:0':nil:ok → mark:0':nil:ok
ok :: mark:0':nil:ok → mark:0':nil:ok
top :: mark:0':nil:ok → top
hole_mark:0':nil:ok1_0 :: mark:0':nil:ok
hole_top2_0 :: top
gen_mark:0':nil:ok3_0 :: Nat → mark:0':nil:ok
Generator Equations:
gen_mark:0':nil:ok3_0(0) ⇔ 0'
gen_mark:0':nil:ok3_0(+(x, 1)) ⇔ mark(gen_mark:0':nil:ok3_0(x))
The following defined symbols remain to be analysed:
from, active, s, sel, minus, quot, zWquot, proper, top
They will be analysed ascendingly in the following order:
from < active
s < active
sel < active
minus < active
quot < active
zWquot < active
active < top
from < proper
s < proper
sel < proper
minus < proper
quot < proper
zWquot < proper
proper < top
(11) NoRewriteLemmaProof (LOWER BOUND(ID) transformation)
Could not prove a rewrite lemma for the defined symbol from.
(12) Obligation:
TRS:
Rules:
active(
from(
X)) →
mark(
cons(
X,
from(
s(
X))))
active(
sel(
0',
cons(
X,
XS))) →
mark(
X)
active(
sel(
s(
N),
cons(
X,
XS))) →
mark(
sel(
N,
XS))
active(
minus(
X,
0')) →
mark(
0')
active(
minus(
s(
X),
s(
Y))) →
mark(
minus(
X,
Y))
active(
quot(
0',
s(
Y))) →
mark(
0')
active(
quot(
s(
X),
s(
Y))) →
mark(
s(
quot(
minus(
X,
Y),
s(
Y))))
active(
zWquot(
XS,
nil)) →
mark(
nil)
active(
zWquot(
nil,
XS)) →
mark(
nil)
active(
zWquot(
cons(
X,
XS),
cons(
Y,
YS))) →
mark(
cons(
quot(
X,
Y),
zWquot(
XS,
YS)))
active(
from(
X)) →
from(
active(
X))
active(
cons(
X1,
X2)) →
cons(
active(
X1),
X2)
active(
s(
X)) →
s(
active(
X))
active(
sel(
X1,
X2)) →
sel(
active(
X1),
X2)
active(
sel(
X1,
X2)) →
sel(
X1,
active(
X2))
active(
minus(
X1,
X2)) →
minus(
active(
X1),
X2)
active(
minus(
X1,
X2)) →
minus(
X1,
active(
X2))
active(
quot(
X1,
X2)) →
quot(
active(
X1),
X2)
active(
quot(
X1,
X2)) →
quot(
X1,
active(
X2))
active(
zWquot(
X1,
X2)) →
zWquot(
active(
X1),
X2)
active(
zWquot(
X1,
X2)) →
zWquot(
X1,
active(
X2))
from(
mark(
X)) →
mark(
from(
X))
cons(
mark(
X1),
X2) →
mark(
cons(
X1,
X2))
s(
mark(
X)) →
mark(
s(
X))
sel(
mark(
X1),
X2) →
mark(
sel(
X1,
X2))
sel(
X1,
mark(
X2)) →
mark(
sel(
X1,
X2))
minus(
mark(
X1),
X2) →
mark(
minus(
X1,
X2))
minus(
X1,
mark(
X2)) →
mark(
minus(
X1,
X2))
quot(
mark(
X1),
X2) →
mark(
quot(
X1,
X2))
quot(
X1,
mark(
X2)) →
mark(
quot(
X1,
X2))
zWquot(
mark(
X1),
X2) →
mark(
zWquot(
X1,
X2))
zWquot(
X1,
mark(
X2)) →
mark(
zWquot(
X1,
X2))
proper(
from(
X)) →
from(
proper(
X))
proper(
cons(
X1,
X2)) →
cons(
proper(
X1),
proper(
X2))
proper(
s(
X)) →
s(
proper(
X))
proper(
sel(
X1,
X2)) →
sel(
proper(
X1),
proper(
X2))
proper(
0') →
ok(
0')
proper(
minus(
X1,
X2)) →
minus(
proper(
X1),
proper(
X2))
proper(
quot(
X1,
X2)) →
quot(
proper(
X1),
proper(
X2))
proper(
zWquot(
X1,
X2)) →
zWquot(
proper(
X1),
proper(
X2))
proper(
nil) →
ok(
nil)
from(
ok(
X)) →
ok(
from(
X))
cons(
ok(
X1),
ok(
X2)) →
ok(
cons(
X1,
X2))
s(
ok(
X)) →
ok(
s(
X))
sel(
ok(
X1),
ok(
X2)) →
ok(
sel(
X1,
X2))
minus(
ok(
X1),
ok(
X2)) →
ok(
minus(
X1,
X2))
quot(
ok(
X1),
ok(
X2)) →
ok(
quot(
X1,
X2))
zWquot(
ok(
X1),
ok(
X2)) →
ok(
zWquot(
X1,
X2))
top(
mark(
X)) →
top(
proper(
X))
top(
ok(
X)) →
top(
active(
X))
Types:
active :: mark:0':nil:ok → mark:0':nil:ok
from :: mark:0':nil:ok → mark:0':nil:ok
mark :: mark:0':nil:ok → mark:0':nil:ok
cons :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
s :: mark:0':nil:ok → mark:0':nil:ok
sel :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
0' :: mark:0':nil:ok
minus :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
quot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
zWquot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
nil :: mark:0':nil:ok
proper :: mark:0':nil:ok → mark:0':nil:ok
ok :: mark:0':nil:ok → mark:0':nil:ok
top :: mark:0':nil:ok → top
hole_mark:0':nil:ok1_0 :: mark:0':nil:ok
hole_top2_0 :: top
gen_mark:0':nil:ok3_0 :: Nat → mark:0':nil:ok
Generator Equations:
gen_mark:0':nil:ok3_0(0) ⇔ 0'
gen_mark:0':nil:ok3_0(+(x, 1)) ⇔ mark(gen_mark:0':nil:ok3_0(x))
The following defined symbols remain to be analysed:
s, active, sel, minus, quot, zWquot, proper, top
They will be analysed ascendingly in the following order:
s < active
sel < active
minus < active
quot < active
zWquot < active
active < top
s < proper
sel < proper
minus < proper
quot < proper
zWquot < proper
proper < top
(13) NoRewriteLemmaProof (LOWER BOUND(ID) transformation)
Could not prove a rewrite lemma for the defined symbol s.
(14) Obligation:
TRS:
Rules:
active(
from(
X)) →
mark(
cons(
X,
from(
s(
X))))
active(
sel(
0',
cons(
X,
XS))) →
mark(
X)
active(
sel(
s(
N),
cons(
X,
XS))) →
mark(
sel(
N,
XS))
active(
minus(
X,
0')) →
mark(
0')
active(
minus(
s(
X),
s(
Y))) →
mark(
minus(
X,
Y))
active(
quot(
0',
s(
Y))) →
mark(
0')
active(
quot(
s(
X),
s(
Y))) →
mark(
s(
quot(
minus(
X,
Y),
s(
Y))))
active(
zWquot(
XS,
nil)) →
mark(
nil)
active(
zWquot(
nil,
XS)) →
mark(
nil)
active(
zWquot(
cons(
X,
XS),
cons(
Y,
YS))) →
mark(
cons(
quot(
X,
Y),
zWquot(
XS,
YS)))
active(
from(
X)) →
from(
active(
X))
active(
cons(
X1,
X2)) →
cons(
active(
X1),
X2)
active(
s(
X)) →
s(
active(
X))
active(
sel(
X1,
X2)) →
sel(
active(
X1),
X2)
active(
sel(
X1,
X2)) →
sel(
X1,
active(
X2))
active(
minus(
X1,
X2)) →
minus(
active(
X1),
X2)
active(
minus(
X1,
X2)) →
minus(
X1,
active(
X2))
active(
quot(
X1,
X2)) →
quot(
active(
X1),
X2)
active(
quot(
X1,
X2)) →
quot(
X1,
active(
X2))
active(
zWquot(
X1,
X2)) →
zWquot(
active(
X1),
X2)
active(
zWquot(
X1,
X2)) →
zWquot(
X1,
active(
X2))
from(
mark(
X)) →
mark(
from(
X))
cons(
mark(
X1),
X2) →
mark(
cons(
X1,
X2))
s(
mark(
X)) →
mark(
s(
X))
sel(
mark(
X1),
X2) →
mark(
sel(
X1,
X2))
sel(
X1,
mark(
X2)) →
mark(
sel(
X1,
X2))
minus(
mark(
X1),
X2) →
mark(
minus(
X1,
X2))
minus(
X1,
mark(
X2)) →
mark(
minus(
X1,
X2))
quot(
mark(
X1),
X2) →
mark(
quot(
X1,
X2))
quot(
X1,
mark(
X2)) →
mark(
quot(
X1,
X2))
zWquot(
mark(
X1),
X2) →
mark(
zWquot(
X1,
X2))
zWquot(
X1,
mark(
X2)) →
mark(
zWquot(
X1,
X2))
proper(
from(
X)) →
from(
proper(
X))
proper(
cons(
X1,
X2)) →
cons(
proper(
X1),
proper(
X2))
proper(
s(
X)) →
s(
proper(
X))
proper(
sel(
X1,
X2)) →
sel(
proper(
X1),
proper(
X2))
proper(
0') →
ok(
0')
proper(
minus(
X1,
X2)) →
minus(
proper(
X1),
proper(
X2))
proper(
quot(
X1,
X2)) →
quot(
proper(
X1),
proper(
X2))
proper(
zWquot(
X1,
X2)) →
zWquot(
proper(
X1),
proper(
X2))
proper(
nil) →
ok(
nil)
from(
ok(
X)) →
ok(
from(
X))
cons(
ok(
X1),
ok(
X2)) →
ok(
cons(
X1,
X2))
s(
ok(
X)) →
ok(
s(
X))
sel(
ok(
X1),
ok(
X2)) →
ok(
sel(
X1,
X2))
minus(
ok(
X1),
ok(
X2)) →
ok(
minus(
X1,
X2))
quot(
ok(
X1),
ok(
X2)) →
ok(
quot(
X1,
X2))
zWquot(
ok(
X1),
ok(
X2)) →
ok(
zWquot(
X1,
X2))
top(
mark(
X)) →
top(
proper(
X))
top(
ok(
X)) →
top(
active(
X))
Types:
active :: mark:0':nil:ok → mark:0':nil:ok
from :: mark:0':nil:ok → mark:0':nil:ok
mark :: mark:0':nil:ok → mark:0':nil:ok
cons :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
s :: mark:0':nil:ok → mark:0':nil:ok
sel :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
0' :: mark:0':nil:ok
minus :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
quot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
zWquot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
nil :: mark:0':nil:ok
proper :: mark:0':nil:ok → mark:0':nil:ok
ok :: mark:0':nil:ok → mark:0':nil:ok
top :: mark:0':nil:ok → top
hole_mark:0':nil:ok1_0 :: mark:0':nil:ok
hole_top2_0 :: top
gen_mark:0':nil:ok3_0 :: Nat → mark:0':nil:ok
Generator Equations:
gen_mark:0':nil:ok3_0(0) ⇔ 0'
gen_mark:0':nil:ok3_0(+(x, 1)) ⇔ mark(gen_mark:0':nil:ok3_0(x))
The following defined symbols remain to be analysed:
sel, active, minus, quot, zWquot, proper, top
They will be analysed ascendingly in the following order:
sel < active
minus < active
quot < active
zWquot < active
active < top
sel < proper
minus < proper
quot < proper
zWquot < proper
proper < top
(15) NoRewriteLemmaProof (LOWER BOUND(ID) transformation)
Could not prove a rewrite lemma for the defined symbol sel.
(16) Obligation:
TRS:
Rules:
active(
from(
X)) →
mark(
cons(
X,
from(
s(
X))))
active(
sel(
0',
cons(
X,
XS))) →
mark(
X)
active(
sel(
s(
N),
cons(
X,
XS))) →
mark(
sel(
N,
XS))
active(
minus(
X,
0')) →
mark(
0')
active(
minus(
s(
X),
s(
Y))) →
mark(
minus(
X,
Y))
active(
quot(
0',
s(
Y))) →
mark(
0')
active(
quot(
s(
X),
s(
Y))) →
mark(
s(
quot(
minus(
X,
Y),
s(
Y))))
active(
zWquot(
XS,
nil)) →
mark(
nil)
active(
zWquot(
nil,
XS)) →
mark(
nil)
active(
zWquot(
cons(
X,
XS),
cons(
Y,
YS))) →
mark(
cons(
quot(
X,
Y),
zWquot(
XS,
YS)))
active(
from(
X)) →
from(
active(
X))
active(
cons(
X1,
X2)) →
cons(
active(
X1),
X2)
active(
s(
X)) →
s(
active(
X))
active(
sel(
X1,
X2)) →
sel(
active(
X1),
X2)
active(
sel(
X1,
X2)) →
sel(
X1,
active(
X2))
active(
minus(
X1,
X2)) →
minus(
active(
X1),
X2)
active(
minus(
X1,
X2)) →
minus(
X1,
active(
X2))
active(
quot(
X1,
X2)) →
quot(
active(
X1),
X2)
active(
quot(
X1,
X2)) →
quot(
X1,
active(
X2))
active(
zWquot(
X1,
X2)) →
zWquot(
active(
X1),
X2)
active(
zWquot(
X1,
X2)) →
zWquot(
X1,
active(
X2))
from(
mark(
X)) →
mark(
from(
X))
cons(
mark(
X1),
X2) →
mark(
cons(
X1,
X2))
s(
mark(
X)) →
mark(
s(
X))
sel(
mark(
X1),
X2) →
mark(
sel(
X1,
X2))
sel(
X1,
mark(
X2)) →
mark(
sel(
X1,
X2))
minus(
mark(
X1),
X2) →
mark(
minus(
X1,
X2))
minus(
X1,
mark(
X2)) →
mark(
minus(
X1,
X2))
quot(
mark(
X1),
X2) →
mark(
quot(
X1,
X2))
quot(
X1,
mark(
X2)) →
mark(
quot(
X1,
X2))
zWquot(
mark(
X1),
X2) →
mark(
zWquot(
X1,
X2))
zWquot(
X1,
mark(
X2)) →
mark(
zWquot(
X1,
X2))
proper(
from(
X)) →
from(
proper(
X))
proper(
cons(
X1,
X2)) →
cons(
proper(
X1),
proper(
X2))
proper(
s(
X)) →
s(
proper(
X))
proper(
sel(
X1,
X2)) →
sel(
proper(
X1),
proper(
X2))
proper(
0') →
ok(
0')
proper(
minus(
X1,
X2)) →
minus(
proper(
X1),
proper(
X2))
proper(
quot(
X1,
X2)) →
quot(
proper(
X1),
proper(
X2))
proper(
zWquot(
X1,
X2)) →
zWquot(
proper(
X1),
proper(
X2))
proper(
nil) →
ok(
nil)
from(
ok(
X)) →
ok(
from(
X))
cons(
ok(
X1),
ok(
X2)) →
ok(
cons(
X1,
X2))
s(
ok(
X)) →
ok(
s(
X))
sel(
ok(
X1),
ok(
X2)) →
ok(
sel(
X1,
X2))
minus(
ok(
X1),
ok(
X2)) →
ok(
minus(
X1,
X2))
quot(
ok(
X1),
ok(
X2)) →
ok(
quot(
X1,
X2))
zWquot(
ok(
X1),
ok(
X2)) →
ok(
zWquot(
X1,
X2))
top(
mark(
X)) →
top(
proper(
X))
top(
ok(
X)) →
top(
active(
X))
Types:
active :: mark:0':nil:ok → mark:0':nil:ok
from :: mark:0':nil:ok → mark:0':nil:ok
mark :: mark:0':nil:ok → mark:0':nil:ok
cons :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
s :: mark:0':nil:ok → mark:0':nil:ok
sel :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
0' :: mark:0':nil:ok
minus :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
quot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
zWquot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
nil :: mark:0':nil:ok
proper :: mark:0':nil:ok → mark:0':nil:ok
ok :: mark:0':nil:ok → mark:0':nil:ok
top :: mark:0':nil:ok → top
hole_mark:0':nil:ok1_0 :: mark:0':nil:ok
hole_top2_0 :: top
gen_mark:0':nil:ok3_0 :: Nat → mark:0':nil:ok
Generator Equations:
gen_mark:0':nil:ok3_0(0) ⇔ 0'
gen_mark:0':nil:ok3_0(+(x, 1)) ⇔ mark(gen_mark:0':nil:ok3_0(x))
The following defined symbols remain to be analysed:
minus, active, quot, zWquot, proper, top
They will be analysed ascendingly in the following order:
minus < active
quot < active
zWquot < active
active < top
minus < proper
quot < proper
zWquot < proper
proper < top
(17) NoRewriteLemmaProof (LOWER BOUND(ID) transformation)
Could not prove a rewrite lemma for the defined symbol minus.
(18) Obligation:
TRS:
Rules:
active(
from(
X)) →
mark(
cons(
X,
from(
s(
X))))
active(
sel(
0',
cons(
X,
XS))) →
mark(
X)
active(
sel(
s(
N),
cons(
X,
XS))) →
mark(
sel(
N,
XS))
active(
minus(
X,
0')) →
mark(
0')
active(
minus(
s(
X),
s(
Y))) →
mark(
minus(
X,
Y))
active(
quot(
0',
s(
Y))) →
mark(
0')
active(
quot(
s(
X),
s(
Y))) →
mark(
s(
quot(
minus(
X,
Y),
s(
Y))))
active(
zWquot(
XS,
nil)) →
mark(
nil)
active(
zWquot(
nil,
XS)) →
mark(
nil)
active(
zWquot(
cons(
X,
XS),
cons(
Y,
YS))) →
mark(
cons(
quot(
X,
Y),
zWquot(
XS,
YS)))
active(
from(
X)) →
from(
active(
X))
active(
cons(
X1,
X2)) →
cons(
active(
X1),
X2)
active(
s(
X)) →
s(
active(
X))
active(
sel(
X1,
X2)) →
sel(
active(
X1),
X2)
active(
sel(
X1,
X2)) →
sel(
X1,
active(
X2))
active(
minus(
X1,
X2)) →
minus(
active(
X1),
X2)
active(
minus(
X1,
X2)) →
minus(
X1,
active(
X2))
active(
quot(
X1,
X2)) →
quot(
active(
X1),
X2)
active(
quot(
X1,
X2)) →
quot(
X1,
active(
X2))
active(
zWquot(
X1,
X2)) →
zWquot(
active(
X1),
X2)
active(
zWquot(
X1,
X2)) →
zWquot(
X1,
active(
X2))
from(
mark(
X)) →
mark(
from(
X))
cons(
mark(
X1),
X2) →
mark(
cons(
X1,
X2))
s(
mark(
X)) →
mark(
s(
X))
sel(
mark(
X1),
X2) →
mark(
sel(
X1,
X2))
sel(
X1,
mark(
X2)) →
mark(
sel(
X1,
X2))
minus(
mark(
X1),
X2) →
mark(
minus(
X1,
X2))
minus(
X1,
mark(
X2)) →
mark(
minus(
X1,
X2))
quot(
mark(
X1),
X2) →
mark(
quot(
X1,
X2))
quot(
X1,
mark(
X2)) →
mark(
quot(
X1,
X2))
zWquot(
mark(
X1),
X2) →
mark(
zWquot(
X1,
X2))
zWquot(
X1,
mark(
X2)) →
mark(
zWquot(
X1,
X2))
proper(
from(
X)) →
from(
proper(
X))
proper(
cons(
X1,
X2)) →
cons(
proper(
X1),
proper(
X2))
proper(
s(
X)) →
s(
proper(
X))
proper(
sel(
X1,
X2)) →
sel(
proper(
X1),
proper(
X2))
proper(
0') →
ok(
0')
proper(
minus(
X1,
X2)) →
minus(
proper(
X1),
proper(
X2))
proper(
quot(
X1,
X2)) →
quot(
proper(
X1),
proper(
X2))
proper(
zWquot(
X1,
X2)) →
zWquot(
proper(
X1),
proper(
X2))
proper(
nil) →
ok(
nil)
from(
ok(
X)) →
ok(
from(
X))
cons(
ok(
X1),
ok(
X2)) →
ok(
cons(
X1,
X2))
s(
ok(
X)) →
ok(
s(
X))
sel(
ok(
X1),
ok(
X2)) →
ok(
sel(
X1,
X2))
minus(
ok(
X1),
ok(
X2)) →
ok(
minus(
X1,
X2))
quot(
ok(
X1),
ok(
X2)) →
ok(
quot(
X1,
X2))
zWquot(
ok(
X1),
ok(
X2)) →
ok(
zWquot(
X1,
X2))
top(
mark(
X)) →
top(
proper(
X))
top(
ok(
X)) →
top(
active(
X))
Types:
active :: mark:0':nil:ok → mark:0':nil:ok
from :: mark:0':nil:ok → mark:0':nil:ok
mark :: mark:0':nil:ok → mark:0':nil:ok
cons :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
s :: mark:0':nil:ok → mark:0':nil:ok
sel :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
0' :: mark:0':nil:ok
minus :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
quot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
zWquot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
nil :: mark:0':nil:ok
proper :: mark:0':nil:ok → mark:0':nil:ok
ok :: mark:0':nil:ok → mark:0':nil:ok
top :: mark:0':nil:ok → top
hole_mark:0':nil:ok1_0 :: mark:0':nil:ok
hole_top2_0 :: top
gen_mark:0':nil:ok3_0 :: Nat → mark:0':nil:ok
Generator Equations:
gen_mark:0':nil:ok3_0(0) ⇔ 0'
gen_mark:0':nil:ok3_0(+(x, 1)) ⇔ mark(gen_mark:0':nil:ok3_0(x))
The following defined symbols remain to be analysed:
quot, active, zWquot, proper, top
They will be analysed ascendingly in the following order:
quot < active
zWquot < active
active < top
quot < proper
zWquot < proper
proper < top
(19) NoRewriteLemmaProof (LOWER BOUND(ID) transformation)
Could not prove a rewrite lemma for the defined symbol quot.
(20) Obligation:
TRS:
Rules:
active(
from(
X)) →
mark(
cons(
X,
from(
s(
X))))
active(
sel(
0',
cons(
X,
XS))) →
mark(
X)
active(
sel(
s(
N),
cons(
X,
XS))) →
mark(
sel(
N,
XS))
active(
minus(
X,
0')) →
mark(
0')
active(
minus(
s(
X),
s(
Y))) →
mark(
minus(
X,
Y))
active(
quot(
0',
s(
Y))) →
mark(
0')
active(
quot(
s(
X),
s(
Y))) →
mark(
s(
quot(
minus(
X,
Y),
s(
Y))))
active(
zWquot(
XS,
nil)) →
mark(
nil)
active(
zWquot(
nil,
XS)) →
mark(
nil)
active(
zWquot(
cons(
X,
XS),
cons(
Y,
YS))) →
mark(
cons(
quot(
X,
Y),
zWquot(
XS,
YS)))
active(
from(
X)) →
from(
active(
X))
active(
cons(
X1,
X2)) →
cons(
active(
X1),
X2)
active(
s(
X)) →
s(
active(
X))
active(
sel(
X1,
X2)) →
sel(
active(
X1),
X2)
active(
sel(
X1,
X2)) →
sel(
X1,
active(
X2))
active(
minus(
X1,
X2)) →
minus(
active(
X1),
X2)
active(
minus(
X1,
X2)) →
minus(
X1,
active(
X2))
active(
quot(
X1,
X2)) →
quot(
active(
X1),
X2)
active(
quot(
X1,
X2)) →
quot(
X1,
active(
X2))
active(
zWquot(
X1,
X2)) →
zWquot(
active(
X1),
X2)
active(
zWquot(
X1,
X2)) →
zWquot(
X1,
active(
X2))
from(
mark(
X)) →
mark(
from(
X))
cons(
mark(
X1),
X2) →
mark(
cons(
X1,
X2))
s(
mark(
X)) →
mark(
s(
X))
sel(
mark(
X1),
X2) →
mark(
sel(
X1,
X2))
sel(
X1,
mark(
X2)) →
mark(
sel(
X1,
X2))
minus(
mark(
X1),
X2) →
mark(
minus(
X1,
X2))
minus(
X1,
mark(
X2)) →
mark(
minus(
X1,
X2))
quot(
mark(
X1),
X2) →
mark(
quot(
X1,
X2))
quot(
X1,
mark(
X2)) →
mark(
quot(
X1,
X2))
zWquot(
mark(
X1),
X2) →
mark(
zWquot(
X1,
X2))
zWquot(
X1,
mark(
X2)) →
mark(
zWquot(
X1,
X2))
proper(
from(
X)) →
from(
proper(
X))
proper(
cons(
X1,
X2)) →
cons(
proper(
X1),
proper(
X2))
proper(
s(
X)) →
s(
proper(
X))
proper(
sel(
X1,
X2)) →
sel(
proper(
X1),
proper(
X2))
proper(
0') →
ok(
0')
proper(
minus(
X1,
X2)) →
minus(
proper(
X1),
proper(
X2))
proper(
quot(
X1,
X2)) →
quot(
proper(
X1),
proper(
X2))
proper(
zWquot(
X1,
X2)) →
zWquot(
proper(
X1),
proper(
X2))
proper(
nil) →
ok(
nil)
from(
ok(
X)) →
ok(
from(
X))
cons(
ok(
X1),
ok(
X2)) →
ok(
cons(
X1,
X2))
s(
ok(
X)) →
ok(
s(
X))
sel(
ok(
X1),
ok(
X2)) →
ok(
sel(
X1,
X2))
minus(
ok(
X1),
ok(
X2)) →
ok(
minus(
X1,
X2))
quot(
ok(
X1),
ok(
X2)) →
ok(
quot(
X1,
X2))
zWquot(
ok(
X1),
ok(
X2)) →
ok(
zWquot(
X1,
X2))
top(
mark(
X)) →
top(
proper(
X))
top(
ok(
X)) →
top(
active(
X))
Types:
active :: mark:0':nil:ok → mark:0':nil:ok
from :: mark:0':nil:ok → mark:0':nil:ok
mark :: mark:0':nil:ok → mark:0':nil:ok
cons :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
s :: mark:0':nil:ok → mark:0':nil:ok
sel :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
0' :: mark:0':nil:ok
minus :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
quot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
zWquot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
nil :: mark:0':nil:ok
proper :: mark:0':nil:ok → mark:0':nil:ok
ok :: mark:0':nil:ok → mark:0':nil:ok
top :: mark:0':nil:ok → top
hole_mark:0':nil:ok1_0 :: mark:0':nil:ok
hole_top2_0 :: top
gen_mark:0':nil:ok3_0 :: Nat → mark:0':nil:ok
Generator Equations:
gen_mark:0':nil:ok3_0(0) ⇔ 0'
gen_mark:0':nil:ok3_0(+(x, 1)) ⇔ mark(gen_mark:0':nil:ok3_0(x))
The following defined symbols remain to be analysed:
zWquot, active, proper, top
They will be analysed ascendingly in the following order:
zWquot < active
active < top
zWquot < proper
proper < top
(21) NoRewriteLemmaProof (LOWER BOUND(ID) transformation)
Could not prove a rewrite lemma for the defined symbol zWquot.
(22) Obligation:
TRS:
Rules:
active(
from(
X)) →
mark(
cons(
X,
from(
s(
X))))
active(
sel(
0',
cons(
X,
XS))) →
mark(
X)
active(
sel(
s(
N),
cons(
X,
XS))) →
mark(
sel(
N,
XS))
active(
minus(
X,
0')) →
mark(
0')
active(
minus(
s(
X),
s(
Y))) →
mark(
minus(
X,
Y))
active(
quot(
0',
s(
Y))) →
mark(
0')
active(
quot(
s(
X),
s(
Y))) →
mark(
s(
quot(
minus(
X,
Y),
s(
Y))))
active(
zWquot(
XS,
nil)) →
mark(
nil)
active(
zWquot(
nil,
XS)) →
mark(
nil)
active(
zWquot(
cons(
X,
XS),
cons(
Y,
YS))) →
mark(
cons(
quot(
X,
Y),
zWquot(
XS,
YS)))
active(
from(
X)) →
from(
active(
X))
active(
cons(
X1,
X2)) →
cons(
active(
X1),
X2)
active(
s(
X)) →
s(
active(
X))
active(
sel(
X1,
X2)) →
sel(
active(
X1),
X2)
active(
sel(
X1,
X2)) →
sel(
X1,
active(
X2))
active(
minus(
X1,
X2)) →
minus(
active(
X1),
X2)
active(
minus(
X1,
X2)) →
minus(
X1,
active(
X2))
active(
quot(
X1,
X2)) →
quot(
active(
X1),
X2)
active(
quot(
X1,
X2)) →
quot(
X1,
active(
X2))
active(
zWquot(
X1,
X2)) →
zWquot(
active(
X1),
X2)
active(
zWquot(
X1,
X2)) →
zWquot(
X1,
active(
X2))
from(
mark(
X)) →
mark(
from(
X))
cons(
mark(
X1),
X2) →
mark(
cons(
X1,
X2))
s(
mark(
X)) →
mark(
s(
X))
sel(
mark(
X1),
X2) →
mark(
sel(
X1,
X2))
sel(
X1,
mark(
X2)) →
mark(
sel(
X1,
X2))
minus(
mark(
X1),
X2) →
mark(
minus(
X1,
X2))
minus(
X1,
mark(
X2)) →
mark(
minus(
X1,
X2))
quot(
mark(
X1),
X2) →
mark(
quot(
X1,
X2))
quot(
X1,
mark(
X2)) →
mark(
quot(
X1,
X2))
zWquot(
mark(
X1),
X2) →
mark(
zWquot(
X1,
X2))
zWquot(
X1,
mark(
X2)) →
mark(
zWquot(
X1,
X2))
proper(
from(
X)) →
from(
proper(
X))
proper(
cons(
X1,
X2)) →
cons(
proper(
X1),
proper(
X2))
proper(
s(
X)) →
s(
proper(
X))
proper(
sel(
X1,
X2)) →
sel(
proper(
X1),
proper(
X2))
proper(
0') →
ok(
0')
proper(
minus(
X1,
X2)) →
minus(
proper(
X1),
proper(
X2))
proper(
quot(
X1,
X2)) →
quot(
proper(
X1),
proper(
X2))
proper(
zWquot(
X1,
X2)) →
zWquot(
proper(
X1),
proper(
X2))
proper(
nil) →
ok(
nil)
from(
ok(
X)) →
ok(
from(
X))
cons(
ok(
X1),
ok(
X2)) →
ok(
cons(
X1,
X2))
s(
ok(
X)) →
ok(
s(
X))
sel(
ok(
X1),
ok(
X2)) →
ok(
sel(
X1,
X2))
minus(
ok(
X1),
ok(
X2)) →
ok(
minus(
X1,
X2))
quot(
ok(
X1),
ok(
X2)) →
ok(
quot(
X1,
X2))
zWquot(
ok(
X1),
ok(
X2)) →
ok(
zWquot(
X1,
X2))
top(
mark(
X)) →
top(
proper(
X))
top(
ok(
X)) →
top(
active(
X))
Types:
active :: mark:0':nil:ok → mark:0':nil:ok
from :: mark:0':nil:ok → mark:0':nil:ok
mark :: mark:0':nil:ok → mark:0':nil:ok
cons :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
s :: mark:0':nil:ok → mark:0':nil:ok
sel :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
0' :: mark:0':nil:ok
minus :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
quot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
zWquot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
nil :: mark:0':nil:ok
proper :: mark:0':nil:ok → mark:0':nil:ok
ok :: mark:0':nil:ok → mark:0':nil:ok
top :: mark:0':nil:ok → top
hole_mark:0':nil:ok1_0 :: mark:0':nil:ok
hole_top2_0 :: top
gen_mark:0':nil:ok3_0 :: Nat → mark:0':nil:ok
Generator Equations:
gen_mark:0':nil:ok3_0(0) ⇔ 0'
gen_mark:0':nil:ok3_0(+(x, 1)) ⇔ mark(gen_mark:0':nil:ok3_0(x))
The following defined symbols remain to be analysed:
active, proper, top
They will be analysed ascendingly in the following order:
active < top
proper < top
(23) NoRewriteLemmaProof (LOWER BOUND(ID) transformation)
Could not prove a rewrite lemma for the defined symbol active.
(24) Obligation:
TRS:
Rules:
active(
from(
X)) →
mark(
cons(
X,
from(
s(
X))))
active(
sel(
0',
cons(
X,
XS))) →
mark(
X)
active(
sel(
s(
N),
cons(
X,
XS))) →
mark(
sel(
N,
XS))
active(
minus(
X,
0')) →
mark(
0')
active(
minus(
s(
X),
s(
Y))) →
mark(
minus(
X,
Y))
active(
quot(
0',
s(
Y))) →
mark(
0')
active(
quot(
s(
X),
s(
Y))) →
mark(
s(
quot(
minus(
X,
Y),
s(
Y))))
active(
zWquot(
XS,
nil)) →
mark(
nil)
active(
zWquot(
nil,
XS)) →
mark(
nil)
active(
zWquot(
cons(
X,
XS),
cons(
Y,
YS))) →
mark(
cons(
quot(
X,
Y),
zWquot(
XS,
YS)))
active(
from(
X)) →
from(
active(
X))
active(
cons(
X1,
X2)) →
cons(
active(
X1),
X2)
active(
s(
X)) →
s(
active(
X))
active(
sel(
X1,
X2)) →
sel(
active(
X1),
X2)
active(
sel(
X1,
X2)) →
sel(
X1,
active(
X2))
active(
minus(
X1,
X2)) →
minus(
active(
X1),
X2)
active(
minus(
X1,
X2)) →
minus(
X1,
active(
X2))
active(
quot(
X1,
X2)) →
quot(
active(
X1),
X2)
active(
quot(
X1,
X2)) →
quot(
X1,
active(
X2))
active(
zWquot(
X1,
X2)) →
zWquot(
active(
X1),
X2)
active(
zWquot(
X1,
X2)) →
zWquot(
X1,
active(
X2))
from(
mark(
X)) →
mark(
from(
X))
cons(
mark(
X1),
X2) →
mark(
cons(
X1,
X2))
s(
mark(
X)) →
mark(
s(
X))
sel(
mark(
X1),
X2) →
mark(
sel(
X1,
X2))
sel(
X1,
mark(
X2)) →
mark(
sel(
X1,
X2))
minus(
mark(
X1),
X2) →
mark(
minus(
X1,
X2))
minus(
X1,
mark(
X2)) →
mark(
minus(
X1,
X2))
quot(
mark(
X1),
X2) →
mark(
quot(
X1,
X2))
quot(
X1,
mark(
X2)) →
mark(
quot(
X1,
X2))
zWquot(
mark(
X1),
X2) →
mark(
zWquot(
X1,
X2))
zWquot(
X1,
mark(
X2)) →
mark(
zWquot(
X1,
X2))
proper(
from(
X)) →
from(
proper(
X))
proper(
cons(
X1,
X2)) →
cons(
proper(
X1),
proper(
X2))
proper(
s(
X)) →
s(
proper(
X))
proper(
sel(
X1,
X2)) →
sel(
proper(
X1),
proper(
X2))
proper(
0') →
ok(
0')
proper(
minus(
X1,
X2)) →
minus(
proper(
X1),
proper(
X2))
proper(
quot(
X1,
X2)) →
quot(
proper(
X1),
proper(
X2))
proper(
zWquot(
X1,
X2)) →
zWquot(
proper(
X1),
proper(
X2))
proper(
nil) →
ok(
nil)
from(
ok(
X)) →
ok(
from(
X))
cons(
ok(
X1),
ok(
X2)) →
ok(
cons(
X1,
X2))
s(
ok(
X)) →
ok(
s(
X))
sel(
ok(
X1),
ok(
X2)) →
ok(
sel(
X1,
X2))
minus(
ok(
X1),
ok(
X2)) →
ok(
minus(
X1,
X2))
quot(
ok(
X1),
ok(
X2)) →
ok(
quot(
X1,
X2))
zWquot(
ok(
X1),
ok(
X2)) →
ok(
zWquot(
X1,
X2))
top(
mark(
X)) →
top(
proper(
X))
top(
ok(
X)) →
top(
active(
X))
Types:
active :: mark:0':nil:ok → mark:0':nil:ok
from :: mark:0':nil:ok → mark:0':nil:ok
mark :: mark:0':nil:ok → mark:0':nil:ok
cons :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
s :: mark:0':nil:ok → mark:0':nil:ok
sel :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
0' :: mark:0':nil:ok
minus :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
quot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
zWquot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
nil :: mark:0':nil:ok
proper :: mark:0':nil:ok → mark:0':nil:ok
ok :: mark:0':nil:ok → mark:0':nil:ok
top :: mark:0':nil:ok → top
hole_mark:0':nil:ok1_0 :: mark:0':nil:ok
hole_top2_0 :: top
gen_mark:0':nil:ok3_0 :: Nat → mark:0':nil:ok
Generator Equations:
gen_mark:0':nil:ok3_0(0) ⇔ 0'
gen_mark:0':nil:ok3_0(+(x, 1)) ⇔ mark(gen_mark:0':nil:ok3_0(x))
The following defined symbols remain to be analysed:
proper, top
They will be analysed ascendingly in the following order:
proper < top
(25) NoRewriteLemmaProof (LOWER BOUND(ID) transformation)
Could not prove a rewrite lemma for the defined symbol proper.
(26) Obligation:
TRS:
Rules:
active(
from(
X)) →
mark(
cons(
X,
from(
s(
X))))
active(
sel(
0',
cons(
X,
XS))) →
mark(
X)
active(
sel(
s(
N),
cons(
X,
XS))) →
mark(
sel(
N,
XS))
active(
minus(
X,
0')) →
mark(
0')
active(
minus(
s(
X),
s(
Y))) →
mark(
minus(
X,
Y))
active(
quot(
0',
s(
Y))) →
mark(
0')
active(
quot(
s(
X),
s(
Y))) →
mark(
s(
quot(
minus(
X,
Y),
s(
Y))))
active(
zWquot(
XS,
nil)) →
mark(
nil)
active(
zWquot(
nil,
XS)) →
mark(
nil)
active(
zWquot(
cons(
X,
XS),
cons(
Y,
YS))) →
mark(
cons(
quot(
X,
Y),
zWquot(
XS,
YS)))
active(
from(
X)) →
from(
active(
X))
active(
cons(
X1,
X2)) →
cons(
active(
X1),
X2)
active(
s(
X)) →
s(
active(
X))
active(
sel(
X1,
X2)) →
sel(
active(
X1),
X2)
active(
sel(
X1,
X2)) →
sel(
X1,
active(
X2))
active(
minus(
X1,
X2)) →
minus(
active(
X1),
X2)
active(
minus(
X1,
X2)) →
minus(
X1,
active(
X2))
active(
quot(
X1,
X2)) →
quot(
active(
X1),
X2)
active(
quot(
X1,
X2)) →
quot(
X1,
active(
X2))
active(
zWquot(
X1,
X2)) →
zWquot(
active(
X1),
X2)
active(
zWquot(
X1,
X2)) →
zWquot(
X1,
active(
X2))
from(
mark(
X)) →
mark(
from(
X))
cons(
mark(
X1),
X2) →
mark(
cons(
X1,
X2))
s(
mark(
X)) →
mark(
s(
X))
sel(
mark(
X1),
X2) →
mark(
sel(
X1,
X2))
sel(
X1,
mark(
X2)) →
mark(
sel(
X1,
X2))
minus(
mark(
X1),
X2) →
mark(
minus(
X1,
X2))
minus(
X1,
mark(
X2)) →
mark(
minus(
X1,
X2))
quot(
mark(
X1),
X2) →
mark(
quot(
X1,
X2))
quot(
X1,
mark(
X2)) →
mark(
quot(
X1,
X2))
zWquot(
mark(
X1),
X2) →
mark(
zWquot(
X1,
X2))
zWquot(
X1,
mark(
X2)) →
mark(
zWquot(
X1,
X2))
proper(
from(
X)) →
from(
proper(
X))
proper(
cons(
X1,
X2)) →
cons(
proper(
X1),
proper(
X2))
proper(
s(
X)) →
s(
proper(
X))
proper(
sel(
X1,
X2)) →
sel(
proper(
X1),
proper(
X2))
proper(
0') →
ok(
0')
proper(
minus(
X1,
X2)) →
minus(
proper(
X1),
proper(
X2))
proper(
quot(
X1,
X2)) →
quot(
proper(
X1),
proper(
X2))
proper(
zWquot(
X1,
X2)) →
zWquot(
proper(
X1),
proper(
X2))
proper(
nil) →
ok(
nil)
from(
ok(
X)) →
ok(
from(
X))
cons(
ok(
X1),
ok(
X2)) →
ok(
cons(
X1,
X2))
s(
ok(
X)) →
ok(
s(
X))
sel(
ok(
X1),
ok(
X2)) →
ok(
sel(
X1,
X2))
minus(
ok(
X1),
ok(
X2)) →
ok(
minus(
X1,
X2))
quot(
ok(
X1),
ok(
X2)) →
ok(
quot(
X1,
X2))
zWquot(
ok(
X1),
ok(
X2)) →
ok(
zWquot(
X1,
X2))
top(
mark(
X)) →
top(
proper(
X))
top(
ok(
X)) →
top(
active(
X))
Types:
active :: mark:0':nil:ok → mark:0':nil:ok
from :: mark:0':nil:ok → mark:0':nil:ok
mark :: mark:0':nil:ok → mark:0':nil:ok
cons :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
s :: mark:0':nil:ok → mark:0':nil:ok
sel :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
0' :: mark:0':nil:ok
minus :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
quot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
zWquot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
nil :: mark:0':nil:ok
proper :: mark:0':nil:ok → mark:0':nil:ok
ok :: mark:0':nil:ok → mark:0':nil:ok
top :: mark:0':nil:ok → top
hole_mark:0':nil:ok1_0 :: mark:0':nil:ok
hole_top2_0 :: top
gen_mark:0':nil:ok3_0 :: Nat → mark:0':nil:ok
Generator Equations:
gen_mark:0':nil:ok3_0(0) ⇔ 0'
gen_mark:0':nil:ok3_0(+(x, 1)) ⇔ mark(gen_mark:0':nil:ok3_0(x))
The following defined symbols remain to be analysed:
top
(27) NoRewriteLemmaProof (LOWER BOUND(ID) transformation)
Could not prove a rewrite lemma for the defined symbol top.
(28) Obligation:
TRS:
Rules:
active(
from(
X)) →
mark(
cons(
X,
from(
s(
X))))
active(
sel(
0',
cons(
X,
XS))) →
mark(
X)
active(
sel(
s(
N),
cons(
X,
XS))) →
mark(
sel(
N,
XS))
active(
minus(
X,
0')) →
mark(
0')
active(
minus(
s(
X),
s(
Y))) →
mark(
minus(
X,
Y))
active(
quot(
0',
s(
Y))) →
mark(
0')
active(
quot(
s(
X),
s(
Y))) →
mark(
s(
quot(
minus(
X,
Y),
s(
Y))))
active(
zWquot(
XS,
nil)) →
mark(
nil)
active(
zWquot(
nil,
XS)) →
mark(
nil)
active(
zWquot(
cons(
X,
XS),
cons(
Y,
YS))) →
mark(
cons(
quot(
X,
Y),
zWquot(
XS,
YS)))
active(
from(
X)) →
from(
active(
X))
active(
cons(
X1,
X2)) →
cons(
active(
X1),
X2)
active(
s(
X)) →
s(
active(
X))
active(
sel(
X1,
X2)) →
sel(
active(
X1),
X2)
active(
sel(
X1,
X2)) →
sel(
X1,
active(
X2))
active(
minus(
X1,
X2)) →
minus(
active(
X1),
X2)
active(
minus(
X1,
X2)) →
minus(
X1,
active(
X2))
active(
quot(
X1,
X2)) →
quot(
active(
X1),
X2)
active(
quot(
X1,
X2)) →
quot(
X1,
active(
X2))
active(
zWquot(
X1,
X2)) →
zWquot(
active(
X1),
X2)
active(
zWquot(
X1,
X2)) →
zWquot(
X1,
active(
X2))
from(
mark(
X)) →
mark(
from(
X))
cons(
mark(
X1),
X2) →
mark(
cons(
X1,
X2))
s(
mark(
X)) →
mark(
s(
X))
sel(
mark(
X1),
X2) →
mark(
sel(
X1,
X2))
sel(
X1,
mark(
X2)) →
mark(
sel(
X1,
X2))
minus(
mark(
X1),
X2) →
mark(
minus(
X1,
X2))
minus(
X1,
mark(
X2)) →
mark(
minus(
X1,
X2))
quot(
mark(
X1),
X2) →
mark(
quot(
X1,
X2))
quot(
X1,
mark(
X2)) →
mark(
quot(
X1,
X2))
zWquot(
mark(
X1),
X2) →
mark(
zWquot(
X1,
X2))
zWquot(
X1,
mark(
X2)) →
mark(
zWquot(
X1,
X2))
proper(
from(
X)) →
from(
proper(
X))
proper(
cons(
X1,
X2)) →
cons(
proper(
X1),
proper(
X2))
proper(
s(
X)) →
s(
proper(
X))
proper(
sel(
X1,
X2)) →
sel(
proper(
X1),
proper(
X2))
proper(
0') →
ok(
0')
proper(
minus(
X1,
X2)) →
minus(
proper(
X1),
proper(
X2))
proper(
quot(
X1,
X2)) →
quot(
proper(
X1),
proper(
X2))
proper(
zWquot(
X1,
X2)) →
zWquot(
proper(
X1),
proper(
X2))
proper(
nil) →
ok(
nil)
from(
ok(
X)) →
ok(
from(
X))
cons(
ok(
X1),
ok(
X2)) →
ok(
cons(
X1,
X2))
s(
ok(
X)) →
ok(
s(
X))
sel(
ok(
X1),
ok(
X2)) →
ok(
sel(
X1,
X2))
minus(
ok(
X1),
ok(
X2)) →
ok(
minus(
X1,
X2))
quot(
ok(
X1),
ok(
X2)) →
ok(
quot(
X1,
X2))
zWquot(
ok(
X1),
ok(
X2)) →
ok(
zWquot(
X1,
X2))
top(
mark(
X)) →
top(
proper(
X))
top(
ok(
X)) →
top(
active(
X))
Types:
active :: mark:0':nil:ok → mark:0':nil:ok
from :: mark:0':nil:ok → mark:0':nil:ok
mark :: mark:0':nil:ok → mark:0':nil:ok
cons :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
s :: mark:0':nil:ok → mark:0':nil:ok
sel :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
0' :: mark:0':nil:ok
minus :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
quot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
zWquot :: mark:0':nil:ok → mark:0':nil:ok → mark:0':nil:ok
nil :: mark:0':nil:ok
proper :: mark:0':nil:ok → mark:0':nil:ok
ok :: mark:0':nil:ok → mark:0':nil:ok
top :: mark:0':nil:ok → top
hole_mark:0':nil:ok1_0 :: mark:0':nil:ok
hole_top2_0 :: top
gen_mark:0':nil:ok3_0 :: Nat → mark:0':nil:ok
Generator Equations:
gen_mark:0':nil:ok3_0(0) ⇔ 0'
gen_mark:0':nil:ok3_0(+(x, 1)) ⇔ mark(gen_mark:0':nil:ok3_0(x))
No more defined symbols left to analyse.