YES
We show the termination of the TRS R:
le(|0|(),y) -> true()
le(s(x),|0|()) -> false()
le(s(x),s(y)) -> le(x,y)
minus(|0|(),y) -> |0|()
minus(s(x),y) -> if_minus(le(s(x),y),s(x),y)
if_minus(true(),s(x),y) -> |0|()
if_minus(false(),s(x),y) -> s(minus(x,y))
quot(|0|(),s(y)) -> |0|()
quot(s(x),s(y)) -> s(quot(minus(x,y),s(y)))
log(s(|0|())) -> |0|()
log(s(s(x))) -> s(log(s(quot(x,s(s(|0|()))))))
-- SCC decomposition.
Consider the dependency pair problem (P, R), where P consists of
p1: le#(s(x),s(y)) -> le#(x,y)
p2: minus#(s(x),y) -> if_minus#(le(s(x),y),s(x),y)
p3: minus#(s(x),y) -> le#(s(x),y)
p4: if_minus#(false(),s(x),y) -> minus#(x,y)
p5: quot#(s(x),s(y)) -> quot#(minus(x,y),s(y))
p6: quot#(s(x),s(y)) -> minus#(x,y)
p7: log#(s(s(x))) -> log#(s(quot(x,s(s(|0|())))))
p8: log#(s(s(x))) -> quot#(x,s(s(|0|())))
and R consists of:
r1: le(|0|(),y) -> true()
r2: le(s(x),|0|()) -> false()
r3: le(s(x),s(y)) -> le(x,y)
r4: minus(|0|(),y) -> |0|()
r5: minus(s(x),y) -> if_minus(le(s(x),y),s(x),y)
r6: if_minus(true(),s(x),y) -> |0|()
r7: if_minus(false(),s(x),y) -> s(minus(x,y))
r8: quot(|0|(),s(y)) -> |0|()
r9: quot(s(x),s(y)) -> s(quot(minus(x,y),s(y)))
r10: log(s(|0|())) -> |0|()
r11: log(s(s(x))) -> s(log(s(quot(x,s(s(|0|()))))))
The estimated dependency graph contains the following SCCs:
{p7}
{p5}
{p2, p4}
{p1}
-- Reduction pair.
Consider the dependency pair problem (P, R), where P consists of
p1: log#(s(s(x))) -> log#(s(quot(x,s(s(|0|())))))
and R consists of:
r1: le(|0|(),y) -> true()
r2: le(s(x),|0|()) -> false()
r3: le(s(x),s(y)) -> le(x,y)
r4: minus(|0|(),y) -> |0|()
r5: minus(s(x),y) -> if_minus(le(s(x),y),s(x),y)
r6: if_minus(true(),s(x),y) -> |0|()
r7: if_minus(false(),s(x),y) -> s(minus(x,y))
r8: quot(|0|(),s(y)) -> |0|()
r9: quot(s(x),s(y)) -> s(quot(minus(x,y),s(y)))
r10: log(s(|0|())) -> |0|()
r11: log(s(s(x))) -> s(log(s(quot(x,s(s(|0|()))))))
The set of usable rules consists of
r1, r2, r3, r4, r5, r6, r7, r8, r9
Take the reduction pair:
lexicographic combination of reduction pairs:
1. matrix interpretations:
carrier: N^1
order: standard order
interpretations:
log#_A(x1) = x1
s_A(x1) = x1 + 2
quot_A(x1,x2) = x1 + 1
|0|_A() = 1
le_A(x1,x2) = x1 + 1
true_A() = 1
false_A() = 1
if_minus_A(x1,x2,x3) = x2
minus_A(x1,x2) = x1
2. matrix interpretations:
carrier: N^1
order: standard order
interpretations:
log#_A(x1) = x1
s_A(x1) = 0
quot_A(x1,x2) = x1 + 1
|0|_A() = 2
le_A(x1,x2) = 2
true_A() = 1
false_A() = 3
if_minus_A(x1,x2,x3) = 1
minus_A(x1,x2) = 3
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: quot#(s(x),s(y)) -> quot#(minus(x,y),s(y))
and R consists of:
r1: le(|0|(),y) -> true()
r2: le(s(x),|0|()) -> false()
r3: le(s(x),s(y)) -> le(x,y)
r4: minus(|0|(),y) -> |0|()
r5: minus(s(x),y) -> if_minus(le(s(x),y),s(x),y)
r6: if_minus(true(),s(x),y) -> |0|()
r7: if_minus(false(),s(x),y) -> s(minus(x,y))
r8: quot(|0|(),s(y)) -> |0|()
r9: quot(s(x),s(y)) -> s(quot(minus(x,y),s(y)))
r10: log(s(|0|())) -> |0|()
r11: log(s(s(x))) -> s(log(s(quot(x,s(s(|0|()))))))
The set of usable rules consists of
r1, r2, r3, r4, r5, r6, r7
Take the reduction pair:
lexicographic combination of reduction pairs:
1. matrix interpretations:
carrier: N^1
order: standard order
interpretations:
quot#_A(x1,x2) = x1 + x2
s_A(x1) = x1 + 3
minus_A(x1,x2) = x1 + 2
le_A(x1,x2) = 2
|0|_A() = 0
true_A() = 1
false_A() = 2
if_minus_A(x1,x2,x3) = x1 + x2
2. matrix interpretations:
carrier: N^1
order: standard order
interpretations:
quot#_A(x1,x2) = x1 + x2
s_A(x1) = 1
minus_A(x1,x2) = 3
le_A(x1,x2) = 1
|0|_A() = 1
true_A() = 2
false_A() = 1
if_minus_A(x1,x2,x3) = 2
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: if_minus#(false(),s(x),y) -> minus#(x,y)
p2: minus#(s(x),y) -> if_minus#(le(s(x),y),s(x),y)
and R consists of:
r1: le(|0|(),y) -> true()
r2: le(s(x),|0|()) -> false()
r3: le(s(x),s(y)) -> le(x,y)
r4: minus(|0|(),y) -> |0|()
r5: minus(s(x),y) -> if_minus(le(s(x),y),s(x),y)
r6: if_minus(true(),s(x),y) -> |0|()
r7: if_minus(false(),s(x),y) -> s(minus(x,y))
r8: quot(|0|(),s(y)) -> |0|()
r9: quot(s(x),s(y)) -> s(quot(minus(x,y),s(y)))
r10: log(s(|0|())) -> |0|()
r11: log(s(s(x))) -> s(log(s(quot(x,s(s(|0|()))))))
The set of usable rules consists of
r1, r2, r3
Take the reduction pair:
lexicographic combination of reduction pairs:
1. matrix interpretations:
carrier: N^1
order: standard order
interpretations:
if_minus#_A(x1,x2,x3) = x2
false_A() = 1
s_A(x1) = x1 + 2
minus#_A(x1,x2) = x1 + 1
le_A(x1,x2) = x1 + x2
|0|_A() = 1
true_A() = 0
2. matrix interpretations:
carrier: N^1
order: standard order
interpretations:
if_minus#_A(x1,x2,x3) = 0
false_A() = 3
s_A(x1) = x1 + 1
minus#_A(x1,x2) = x1 + 1
le_A(x1,x2) = x1 + x2
|0|_A() = 1
true_A() = 2
The next rules are strictly ordered:
p1, p2
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: le#(s(x),s(y)) -> le#(x,y)
and R consists of:
r1: le(|0|(),y) -> true()
r2: le(s(x),|0|()) -> false()
r3: le(s(x),s(y)) -> le(x,y)
r4: minus(|0|(),y) -> |0|()
r5: minus(s(x),y) -> if_minus(le(s(x),y),s(x),y)
r6: if_minus(true(),s(x),y) -> |0|()
r7: if_minus(false(),s(x),y) -> s(minus(x,y))
r8: quot(|0|(),s(y)) -> |0|()
r9: quot(s(x),s(y)) -> s(quot(minus(x,y),s(y)))
r10: log(s(|0|())) -> |0|()
r11: log(s(s(x))) -> s(log(s(quot(x,s(s(|0|()))))))
The set of usable rules consists of
(no rules)
Take the reduction pair:
lexicographic combination of reduction pairs:
1. matrix interpretations:
carrier: N^1
order: standard order
interpretations:
le#_A(x1,x2) = x1 + x2
s_A(x1) = x1 + 1
2. matrix interpretations:
carrier: N^1
order: standard order
interpretations:
le#_A(x1,x2) = 0
s_A(x1) = x1 + 1
The next rules are strictly ordered:
p1
We remove them from the problem. Then no dependency pair remains.