YES
We show the termination of the TRS R:
double(|0|()) -> |0|()
double(s(x)) -> s(s(double(x)))
half(|0|()) -> |0|()
half(s(|0|())) -> |0|()
half(s(s(x))) -> s(half(x))
-(x,|0|()) -> x
-(s(x),s(y)) -> -(x,y)
if(|0|(),y,z) -> y
if(s(x),y,z) -> z
half(double(x)) -> x
-- SCC decomposition.
Consider the dependency pair problem (P, R), where P consists of
p1: double#(s(x)) -> double#(x)
p2: half#(s(s(x))) -> half#(x)
p3: -#(s(x),s(y)) -> -#(x,y)
and R consists of:
r1: double(|0|()) -> |0|()
r2: double(s(x)) -> s(s(double(x)))
r3: half(|0|()) -> |0|()
r4: half(s(|0|())) -> |0|()
r5: half(s(s(x))) -> s(half(x))
r6: -(x,|0|()) -> x
r7: -(s(x),s(y)) -> -(x,y)
r8: if(|0|(),y,z) -> y
r9: if(s(x),y,z) -> z
r10: half(double(x)) -> x
The estimated dependency graph contains the following SCCs:
{p1}
{p2}
{p3}
-- Reduction pair.
Consider the dependency pair problem (P, R), where P consists of
p1: double#(s(x)) -> double#(x)
and R consists of:
r1: double(|0|()) -> |0|()
r2: double(s(x)) -> s(s(double(x)))
r3: half(|0|()) -> |0|()
r4: half(s(|0|())) -> |0|()
r5: half(s(s(x))) -> s(half(x))
r6: -(x,|0|()) -> x
r7: -(s(x),s(y)) -> -(x,y)
r8: if(|0|(),y,z) -> y
r9: if(s(x),y,z) -> z
r10: half(double(x)) -> x
The set of usable rules consists of
(no rules)
Take the monotone reduction pair:
lexicographic combination of reduction pairs:
1. lexicographic path order with precedence:
precedence:
s > double#
argument filter:
pi(double#) = [1]
pi(s) = [1]
2. lexicographic path order with precedence:
precedence:
s > double#
argument filter:
pi(double#) = [1]
pi(s) = [1]
3. lexicographic path order with precedence:
precedence:
s > double#
argument filter:
pi(double#) = [1]
pi(s) = [1]
The next rules are strictly ordered:
p1
r1, r2, r3, r4, r5, r6, r7, r8, r9, r10
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: half#(s(s(x))) -> half#(x)
and R consists of:
r1: double(|0|()) -> |0|()
r2: double(s(x)) -> s(s(double(x)))
r3: half(|0|()) -> |0|()
r4: half(s(|0|())) -> |0|()
r5: half(s(s(x))) -> s(half(x))
r6: -(x,|0|()) -> x
r7: -(s(x),s(y)) -> -(x,y)
r8: if(|0|(),y,z) -> y
r9: if(s(x),y,z) -> z
r10: half(double(x)) -> x
The set of usable rules consists of
(no rules)
Take the monotone reduction pair:
lexicographic combination of reduction pairs:
1. lexicographic path order with precedence:
precedence:
s > half#
argument filter:
pi(half#) = [1]
pi(s) = [1]
2. lexicographic path order with precedence:
precedence:
s > half#
argument filter:
pi(half#) = [1]
pi(s) = [1]
3. lexicographic path order with precedence:
precedence:
s > half#
argument filter:
pi(half#) = [1]
pi(s) = [1]
The next rules are strictly ordered:
p1
r1, r2, r3, r4, r5, r6, r7, r8, r9, r10
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: -#(s(x),s(y)) -> -#(x,y)
and R consists of:
r1: double(|0|()) -> |0|()
r2: double(s(x)) -> s(s(double(x)))
r3: half(|0|()) -> |0|()
r4: half(s(|0|())) -> |0|()
r5: half(s(s(x))) -> s(half(x))
r6: -(x,|0|()) -> x
r7: -(s(x),s(y)) -> -(x,y)
r8: if(|0|(),y,z) -> y
r9: if(s(x),y,z) -> z
r10: half(double(x)) -> x
The set of usable rules consists of
(no rules)
Take the reduction pair:
lexicographic combination of reduction pairs:
1. lexicographic path order with precedence:
precedence:
s > -#
argument filter:
pi(-#) = 1
pi(s) = [1]
2. lexicographic path order with precedence:
precedence:
s > -#
argument filter:
pi(-#) = 1
pi(s) = 1
3. lexicographic path order with precedence:
precedence:
s > -#
argument filter:
pi(-#) = 1
pi(s) = [1]
The next rules are strictly ordered:
p1
We remove them from the problem. Then no dependency pair remains.