Termination Proof using AProVE

Term Rewriting System R:
[YS, X, XS, X1, X2, Y, L]
app(nil, YS) -> YS
app(cons(X, XS), YS) -> cons(X, n_{_app}(activate(XS), YS))
app(X1, X2) -> n_{_app}(X1, X2)
from(X) -> cons(X, n_{_from}(s(X)))
from(X) -> n_{_from}(X)
zWadr(nil, YS) -> nil
zWadr(XS, nil) -> nil
zWadr(cons(X, XS), cons(Y, YS)) -> cons(app(Y, cons(X, n_{_nil})), n_{_zWadr}(activate(XS), activate(YS)))
zWadr(X1, X2) -> n_{_zWadr}(X1, X2)
prefix(L) -> cons(nil, n_{_zWadr}(L, prefix(L)))
nil -> n_{_nil}
activate(n_{_app}(X1, X2)) -> app(X1, X2)
activate(n_{_from}(X)) -> from(X)
activate(n_{_nil}) -> nil
activate(n_{_zWadr}(X1, X2)) -> zWadr(X1, X2)
activate(X) -> X

Termination of R to be shown.

     ↳Dependency Pair Analysis

R contains the following Dependency Pairs:

APP(cons(X, XS), YS) -> ACTIVATE(XS)
ZWADR(cons(X, XS), cons(Y, YS)) -> APP(Y, cons(X, n_{_nil}))
ZWADR(cons(X, XS), cons(Y, YS)) -> ACTIVATE(XS)
ZWADR(cons(X, XS), cons(Y, YS)) -> ACTIVATE(YS)
PREFIX(L) -> NIL
PREFIX(L) -> PREFIX(L)
ACTIVATE(n_{_app}(X1, X2)) -> APP(X1, X2)
ACTIVATE(n_{_from}(X)) -> FROM(X)
ACTIVATE(n_{_nil}) -> NIL
ACTIVATE(n_{_zWadr}(X1, X2)) -> ZWADR(X1, X2)

Furthermore, R contains two SCCs.

     ↳DPs

       →DP Problem 1

         ↳Size-Change Principle

       →DP Problem 2

         ↳MRR

Dependency Pairs:

ZWADR(cons(X, XS), cons(Y, YS)) -> ACTIVATE(YS)
ZWADR(cons(X, XS), cons(Y, YS)) -> ACTIVATE(XS)
ZWADR(cons(X, XS), cons(Y, YS)) -> APP(Y, cons(X, n_{_nil}))
ACTIVATE(n_{_zWadr}(X1, X2)) -> ZWADR(X1, X2)
ACTIVATE(n_{_app}(X1, X2)) -> APP(X1, X2)
APP(cons(X, XS), YS) -> ACTIVATE(XS)

Rules:

app(nil, YS) -> YS
app(cons(X, XS), YS) -> cons(X, n_{_app}(activate(XS), YS))
app(X1, X2) -> n_{_app}(X1, X2)
from(X) -> cons(X, n_{_from}(s(X)))
from(X) -> n_{_from}(X)
zWadr(nil, YS) -> nil
zWadr(XS, nil) -> nil
zWadr(cons(X, XS), cons(Y, YS)) -> cons(app(Y, cons(X, n_{_nil})), n_{_zWadr}(activate(XS), activate(YS)))
zWadr(X1, X2) -> n_{_zWadr}(X1, X2)
prefix(L) -> cons(nil, n_{_zWadr}(L, prefix(L)))
nil -> n_{_nil}
activate(n_{_app}(X1, X2)) -> app(X1, X2)
activate(n_{_from}(X)) -> from(X)
activate(n_{_nil}) -> nil
activate(n_{_zWadr}(X1, X2)) -> zWadr(X1, X2)
activate(X) -> X

We number the DPs as follows:

ZWADR(cons(X, XS), cons(Y, YS)) -> ACTIVATE(YS)
ZWADR(cons(X, XS), cons(Y, YS)) -> ACTIVATE(XS)
ZWADR(cons(X, XS), cons(Y, YS)) -> APP(Y, cons(X, n_{_nil}))
ACTIVATE(n_{_zWadr}(X1, X2)) -> ZWADR(X1, X2)
ACTIVATE(n_{_app}(X1, X2)) -> APP(X1, X2)
APP(cons(X, XS), YS) -> ACTIVATE(XS)

and get the following Size-Change Graph(s):

{2, 1}	,	{2, 1}
2	>	1

{2, 1}	,	{2, 1}
1	>	1

{3}	,	{3}
2	>	1

{4}	,	{4}
1	>	1
1	>	2

{5}	,	{5}
1	>	1
1	>	2

{6}	,	{6}
1	>	1

which lead(s) to this/these maximal multigraph(s):

{2, 1}	,	{4}
2	>	1
2	>	2

{6}	,	{5}
1	>	1
1	>	2

{5}	,	{6}
1	>	1

{4}	,	{2, 1}
1	>	1

{2, 1}	,	{4}
1	>	1
1	>	2

{6}	,	{3}
1	>	1

{4}	,	{6}
1	>	1

{3}	,	{4}
2	>	1
2	>	2

{5}	,	{2, 1}
1	>	1

D_P: empty set
Oriented Rules: none

We used the order Homeomorphic Embedding Order with Non-Strict Precedence.

trivial

with Argument Filtering System:

cons(x₁, x₂) -> cons(x₁, x₂)
n_{_zWadr}(x₁, x₂) -> n_{_zWadr}(x₁, x₂)
n_{_app}(x₁, x₂) -> n_{_app}(x₁, x₂)

We obtain no new DP problems.

     ↳DPs

       →DP Problem 1

         ↳SCP

       →DP Problem 2

         ↳Modular Removal of Rules

Dependency Pair:

PREFIX(L) -> PREFIX(L)

Rules:

app(nil, YS) -> YS
app(cons(X, XS), YS) -> cons(X, n_{_app}(activate(XS), YS))
app(X1, X2) -> n_{_app}(X1, X2)
from(X) -> cons(X, n_{_from}(s(X)))
from(X) -> n_{_from}(X)
zWadr(nil, YS) -> nil
zWadr(XS, nil) -> nil
zWadr(cons(X, XS), cons(Y, YS)) -> cons(app(Y, cons(X, n_{_nil})), n_{_zWadr}(activate(XS), activate(YS)))
zWadr(X1, X2) -> n_{_zWadr}(X1, X2)
prefix(L) -> cons(nil, n_{_zWadr}(L, prefix(L)))
nil -> n_{_nil}
activate(n_{_app}(X1, X2)) -> app(X1, X2)
activate(n_{_from}(X)) -> from(X)
activate(n_{_nil}) -> nil
activate(n_{_zWadr}(X1, X2)) -> zWadr(X1, X2)
activate(X) -> X

We have the following set of usable rules: none
To remove rules and DPs from this DP problem we used the following monotonic and C_E-compatible order: Polynomial ordering.
Polynomial interpretation:

POL(PREFIX(x₁)) = x₁

We have the following set D of usable symbols: {PREFIX}
No Dependency Pairs can be deleted.
16 non usable rules have been deleted.

The result of this processor delivers one new DP problem.

     ↳DPs

       →DP Problem 1

         ↳SCP

       →DP Problem 2

         ↳MRR

           →DP Problem 3

             ↳Non-Overlappingness Check

Dependency Pair:

PREFIX(L) -> PREFIX(L)

Rule:

none

R does not overlap into P. Moreover, R is locally confluent (all critical pairs are trivially joinable).Hence we can switch to innermost.
The transformation is resulting in one subcycle:

     ↳DPs

       →DP Problem 1

         ↳SCP

       →DP Problem 2

         ↳MRR

           →DP Problem 3

             ↳NOC

...

               →DP Problem 4

                 ↳Non Termination

Dependency Pair:

PREFIX(L) -> PREFIX(L)

Rule:

none

Strategy:

innermost

Found an infinite P-chain over R:
P =

PREFIX(L) -> PREFIX(L)

R = none

s = PREFIX(L')
evaluates to t =PREFIX(L')

Thus, s starts an infinite chain.

Non-Termination of R could be shown.
Duration:
0:08 minutes