YES
We show the termination of the TRS R:
app(nil(),k) -> k
app(l,nil()) -> l
app(cons(x,l),k) -> cons(x,app(l,k))
sum(cons(x,nil())) -> cons(x,nil())
sum(cons(x,cons(y,l))) -> sum(cons(plus(x,y),l))
sum(app(l,cons(x,cons(y,k)))) -> sum(app(l,sum(cons(x,cons(y,k)))))
plus(|0|(),y) -> y
plus(s(x),y) -> s(plus(x,y))
-- SCC decomposition.
Consider the dependency pair problem (P, R), where P consists of
p1: app#(cons(x,l),k) -> app#(l,k)
p2: sum#(cons(x,cons(y,l))) -> sum#(cons(plus(x,y),l))
p3: sum#(cons(x,cons(y,l))) -> plus#(x,y)
p4: sum#(app(l,cons(x,cons(y,k)))) -> sum#(app(l,sum(cons(x,cons(y,k)))))
p5: sum#(app(l,cons(x,cons(y,k)))) -> app#(l,sum(cons(x,cons(y,k))))
p6: sum#(app(l,cons(x,cons(y,k)))) -> sum#(cons(x,cons(y,k)))
p7: plus#(s(x),y) -> plus#(x,y)
and R consists of:
r1: app(nil(),k) -> k
r2: app(l,nil()) -> l
r3: app(cons(x,l),k) -> cons(x,app(l,k))
r4: sum(cons(x,nil())) -> cons(x,nil())
r5: sum(cons(x,cons(y,l))) -> sum(cons(plus(x,y),l))
r6: sum(app(l,cons(x,cons(y,k)))) -> sum(app(l,sum(cons(x,cons(y,k)))))
r7: plus(|0|(),y) -> y
r8: plus(s(x),y) -> s(plus(x,y))
The estimated dependency graph contains the following SCCs:
{p4}
{p1}
{p2}
{p7}
-- Reduction pair.
Consider the dependency pair problem (P, R), where P consists of
p1: sum#(app(l,cons(x,cons(y,k)))) -> sum#(app(l,sum(cons(x,cons(y,k)))))
and R consists of:
r1: app(nil(),k) -> k
r2: app(l,nil()) -> l
r3: app(cons(x,l),k) -> cons(x,app(l,k))
r4: sum(cons(x,nil())) -> cons(x,nil())
r5: sum(cons(x,cons(y,l))) -> sum(cons(plus(x,y),l))
r6: sum(app(l,cons(x,cons(y,k)))) -> sum(app(l,sum(cons(x,cons(y,k)))))
r7: plus(|0|(),y) -> y
r8: plus(s(x),y) -> s(plus(x,y))
The set of usable rules consists of
r1, r2, r3, r4, r5, r7, r8
Take the reduction pair:
lexicographic combination of reduction pairs:
1. matrix interpretations:
carrier: N^2
order: standard order
interpretations:
sum#_A(x1) = ((0,1),(0,0)) x1
app_A(x1,x2) = x1 + x2 + (1,1)
cons_A(x1,x2) = x2 + (1,2)
sum_A(x1) = ((0,1),(1,0)) x1 + (0,2)
nil_A() = (1,1)
plus_A(x1,x2) = x2 + (1,0)
|0|_A() = (1,1)
s_A(x1) = x1
2. matrix interpretations:
carrier: N^2
order: standard order
interpretations:
sum#_A(x1) = (0,0)
app_A(x1,x2) = x1 + (1,1)
cons_A(x1,x2) = (1,1)
sum_A(x1) = (0,0)
nil_A() = (1,1)
plus_A(x1,x2) = x2 + (2,1)
|0|_A() = (1,1)
s_A(x1) = (1,1)
The next rules are strictly ordered:
p1
We remove them from the problem. Then no dependency pair remains.
-- Reduction pair.
Consider the dependency pair problem (P, R), where P consists of
p1: app#(cons(x,l),k) -> app#(l,k)
and R consists of:
r1: app(nil(),k) -> k
r2: app(l,nil()) -> l
r3: app(cons(x,l),k) -> cons(x,app(l,k))
r4: sum(cons(x,nil())) -> cons(x,nil())
r5: sum(cons(x,cons(y,l))) -> sum(cons(plus(x,y),l))
r6: sum(app(l,cons(x,cons(y,k)))) -> sum(app(l,sum(cons(x,cons(y,k)))))
r7: plus(|0|(),y) -> y
r8: plus(s(x),y) -> s(plus(x,y))
The set of usable rules consists of
(no rules)
Take the reduction pair:
lexicographic combination of reduction pairs:
1. matrix interpretations:
carrier: N^2
order: standard order
interpretations:
app#_A(x1,x2) = ((1,1),(1,1)) x1 + x2
cons_A(x1,x2) = ((1,1),(1,1)) x1 + ((1,1),(1,1)) x2 + (1,1)
2. matrix interpretations:
carrier: N^2
order: standard order
interpretations:
app#_A(x1,x2) = ((0,1),(1,0)) x1 + x2
cons_A(x1,x2) = ((0,1),(0,1)) x1 + ((0,0),(1,0)) x2 + (1,1)
The next rules are strictly ordered:
p1
We remove them from the problem. Then no dependency pair remains.
-- Reduction pair.
Consider the dependency pair problem (P, R), where P consists of
p1: sum#(cons(x,cons(y,l))) -> sum#(cons(plus(x,y),l))
and R consists of:
r1: app(nil(),k) -> k
r2: app(l,nil()) -> l
r3: app(cons(x,l),k) -> cons(x,app(l,k))
r4: sum(cons(x,nil())) -> cons(x,nil())
r5: sum(cons(x,cons(y,l))) -> sum(cons(plus(x,y),l))
r6: sum(app(l,cons(x,cons(y,k)))) -> sum(app(l,sum(cons(x,cons(y,k)))))
r7: plus(|0|(),y) -> y
r8: plus(s(x),y) -> s(plus(x,y))
The set of usable rules consists of
r7, r8
Take the reduction pair:
lexicographic combination of reduction pairs:
1. matrix interpretations:
carrier: N^2
order: standard order
interpretations:
sum#_A(x1) = x1
cons_A(x1,x2) = x1 + x2 + (2,1)
plus_A(x1,x2) = ((1,0),(1,0)) x1 + ((1,0),(1,1)) x2 + (1,1)
|0|_A() = (1,1)
s_A(x1) = x1 + (1,1)
2. matrix interpretations:
carrier: N^2
order: standard order
interpretations:
sum#_A(x1) = (0,0)
cons_A(x1,x2) = ((1,1),(0,1)) x1 + ((0,0),(1,0)) x2 + (1,0)
plus_A(x1,x2) = x1 + ((1,0),(1,0)) x2 + (2,1)
|0|_A() = (1,1)
s_A(x1) = ((0,1),(0,0)) x1 + (1,1)
The next rules are strictly ordered:
p1
We remove them from the problem. Then no dependency pair remains.
-- Reduction pair.
Consider the dependency pair problem (P, R), where P consists of
p1: plus#(s(x),y) -> plus#(x,y)
and R consists of:
r1: app(nil(),k) -> k
r2: app(l,nil()) -> l
r3: app(cons(x,l),k) -> cons(x,app(l,k))
r4: sum(cons(x,nil())) -> cons(x,nil())
r5: sum(cons(x,cons(y,l))) -> sum(cons(plus(x,y),l))
r6: sum(app(l,cons(x,cons(y,k)))) -> sum(app(l,sum(cons(x,cons(y,k)))))
r7: plus(|0|(),y) -> y
r8: plus(s(x),y) -> s(plus(x,y))
The set of usable rules consists of
(no rules)
Take the monotone reduction pair:
lexicographic combination of reduction pairs:
1. matrix interpretations:
carrier: N^2
order: standard order
interpretations:
plus#_A(x1,x2) = ((1,1),(1,0)) x1 + x2
s_A(x1) = ((1,1),(1,1)) x1 + (1,1)
2. matrix interpretations:
carrier: N^2
order: standard order
interpretations:
plus#_A(x1,x2) = ((1,1),(1,1)) x1 + x2
s_A(x1) = ((1,1),(1,1)) x1 + (1,1)
The next rules are strictly ordered:
p1
r1, r2, r3, r4, r5, r6, r7, r8
We remove them from the problem. Then no dependency pair remains.