### (0) Obligation:

Runtime Complexity TRS:
The TRS R consists of the following rules:

from(X) → cons(X, n__from(s(X)))
2ndspos(0, Z) → rnil
2ndspos(s(N), cons(X, n__cons(Y, Z))) → rcons(posrecip(activate(Y)), 2ndsneg(N, activate(Z)))
2ndsneg(0, Z) → rnil
2ndsneg(s(N), cons(X, n__cons(Y, Z))) → rcons(negrecip(activate(Y)), 2ndspos(N, activate(Z)))
pi(X) → 2ndspos(X, from(0))
plus(0, Y) → Y
plus(s(X), Y) → s(plus(X, Y))
times(0, Y) → 0
times(s(X), Y) → plus(Y, times(X, Y))
square(X) → times(X, X)
from(X) → n__from(X)
cons(X1, X2) → n__cons(X1, X2)
activate(n__from(X)) → from(X)
activate(n__cons(X1, X2)) → cons(X1, X2)
activate(X) → X

Rewrite Strategy: INNERMOST

### (1) CpxTrsToCdtProof (BOTH BOUNDS(ID, ID) transformation)

Converted Cpx (relative) TRS to CDT

### (2) Obligation:

Complexity Dependency Tuples Problem
Rules:

from(z0) → cons(z0, n__from(s(z0)))
from(z0) → n__from(z0)
2ndspos(0, z0) → rnil
2ndspos(s(z0), cons(z1, n__cons(z2, z3))) → rcons(posrecip(activate(z2)), 2ndsneg(z0, activate(z3)))
2ndsneg(0, z0) → rnil
2ndsneg(s(z0), cons(z1, n__cons(z2, z3))) → rcons(negrecip(activate(z2)), 2ndspos(z0, activate(z3)))
pi(z0) → 2ndspos(z0, from(0))
plus(0, z0) → z0
plus(s(z0), z1) → s(plus(z0, z1))
times(0, z0) → 0
times(s(z0), z1) → plus(z1, times(z0, z1))
square(z0) → times(z0, z0)
cons(z0, z1) → n__cons(z0, z1)
activate(n__from(z0)) → from(z0)
activate(n__cons(z0, z1)) → cons(z0, z1)
activate(z0) → z0
Tuples:

FROM(z0) → c(CONS(z0, n__from(s(z0))))
FROM(z0) → c1
2NDSPOS(0, z0) → c2
2NDSPOS(s(z0), cons(z1, n__cons(z2, z3))) → c3(ACTIVATE(z2), 2NDSNEG(z0, activate(z3)), ACTIVATE(z3))
2NDSNEG(0, z0) → c4
2NDSNEG(s(z0), cons(z1, n__cons(z2, z3))) → c5(ACTIVATE(z2), 2NDSPOS(z0, activate(z3)), ACTIVATE(z3))
PI(z0) → c6(2NDSPOS(z0, from(0)), FROM(0))
PLUS(0, z0) → c7
PLUS(s(z0), z1) → c8(PLUS(z0, z1))
TIMES(0, z0) → c9
TIMES(s(z0), z1) → c10(PLUS(z1, times(z0, z1)), TIMES(z0, z1))
SQUARE(z0) → c11(TIMES(z0, z0))
CONS(z0, z1) → c12
ACTIVATE(n__from(z0)) → c13(FROM(z0))
ACTIVATE(n__cons(z0, z1)) → c14(CONS(z0, z1))
ACTIVATE(z0) → c15
S tuples:

FROM(z0) → c(CONS(z0, n__from(s(z0))))
FROM(z0) → c1
2NDSPOS(0, z0) → c2
2NDSPOS(s(z0), cons(z1, n__cons(z2, z3))) → c3(ACTIVATE(z2), 2NDSNEG(z0, activate(z3)), ACTIVATE(z3))
2NDSNEG(0, z0) → c4
2NDSNEG(s(z0), cons(z1, n__cons(z2, z3))) → c5(ACTIVATE(z2), 2NDSPOS(z0, activate(z3)), ACTIVATE(z3))
PI(z0) → c6(2NDSPOS(z0, from(0)), FROM(0))
PLUS(0, z0) → c7
PLUS(s(z0), z1) → c8(PLUS(z0, z1))
TIMES(0, z0) → c9
TIMES(s(z0), z1) → c10(PLUS(z1, times(z0, z1)), TIMES(z0, z1))
SQUARE(z0) → c11(TIMES(z0, z0))
CONS(z0, z1) → c12
ACTIVATE(n__from(z0)) → c13(FROM(z0))
ACTIVATE(n__cons(z0, z1)) → c14(CONS(z0, z1))
ACTIVATE(z0) → c15
K tuples:none
Defined Rule Symbols:

from, 2ndspos, 2ndsneg, pi, plus, times, square, cons, activate

Defined Pair Symbols:

FROM, 2NDSPOS, 2NDSNEG, PI, PLUS, TIMES, SQUARE, CONS, ACTIVATE

Compound Symbols:

c, c1, c2, c3, c4, c5, c6, c7, c8, c9, c10, c11, c12, c13, c14, c15

### (3) CdtLeafRemovalProof (ComplexityIfPolyImplication transformation)

SQUARE(z0) → c11(TIMES(z0, z0))
Removed 13 trailing nodes:

ACTIVATE(z0) → c15
2NDSNEG(s(z0), cons(z1, n__cons(z2, z3))) → c5(ACTIVATE(z2), 2NDSPOS(z0, activate(z3)), ACTIVATE(z3))
CONS(z0, z1) → c12
TIMES(0, z0) → c9
ACTIVATE(n__from(z0)) → c13(FROM(z0))
PI(z0) → c6(2NDSPOS(z0, from(0)), FROM(0))
PLUS(0, z0) → c7
ACTIVATE(n__cons(z0, z1)) → c14(CONS(z0, z1))
FROM(z0) → c(CONS(z0, n__from(s(z0))))
FROM(z0) → c1
2NDSNEG(0, z0) → c4
2NDSPOS(0, z0) → c2
2NDSPOS(s(z0), cons(z1, n__cons(z2, z3))) → c3(ACTIVATE(z2), 2NDSNEG(z0, activate(z3)), ACTIVATE(z3))

### (4) Obligation:

Complexity Dependency Tuples Problem
Rules:

from(z0) → cons(z0, n__from(s(z0)))
from(z0) → n__from(z0)
2ndspos(0, z0) → rnil
2ndspos(s(z0), cons(z1, n__cons(z2, z3))) → rcons(posrecip(activate(z2)), 2ndsneg(z0, activate(z3)))
2ndsneg(0, z0) → rnil
2ndsneg(s(z0), cons(z1, n__cons(z2, z3))) → rcons(negrecip(activate(z2)), 2ndspos(z0, activate(z3)))
pi(z0) → 2ndspos(z0, from(0))
plus(0, z0) → z0
plus(s(z0), z1) → s(plus(z0, z1))
times(0, z0) → 0
times(s(z0), z1) → plus(z1, times(z0, z1))
square(z0) → times(z0, z0)
cons(z0, z1) → n__cons(z0, z1)
activate(n__from(z0)) → from(z0)
activate(n__cons(z0, z1)) → cons(z0, z1)
activate(z0) → z0
Tuples:

PLUS(s(z0), z1) → c8(PLUS(z0, z1))
TIMES(s(z0), z1) → c10(PLUS(z1, times(z0, z1)), TIMES(z0, z1))
S tuples:

PLUS(s(z0), z1) → c8(PLUS(z0, z1))
TIMES(s(z0), z1) → c10(PLUS(z1, times(z0, z1)), TIMES(z0, z1))
K tuples:none
Defined Rule Symbols:

from, 2ndspos, 2ndsneg, pi, plus, times, square, cons, activate

Defined Pair Symbols:

PLUS, TIMES

Compound Symbols:

c8, c10

### (5) CdtUsableRulesProof (EQUIVALENT transformation)

The following rules are not usable and were removed:

from(z0) → cons(z0, n__from(s(z0)))
from(z0) → n__from(z0)
2ndspos(0, z0) → rnil
2ndspos(s(z0), cons(z1, n__cons(z2, z3))) → rcons(posrecip(activate(z2)), 2ndsneg(z0, activate(z3)))
2ndsneg(0, z0) → rnil
2ndsneg(s(z0), cons(z1, n__cons(z2, z3))) → rcons(negrecip(activate(z2)), 2ndspos(z0, activate(z3)))
pi(z0) → 2ndspos(z0, from(0))
square(z0) → times(z0, z0)
cons(z0, z1) → n__cons(z0, z1)
activate(n__from(z0)) → from(z0)
activate(n__cons(z0, z1)) → cons(z0, z1)
activate(z0) → z0

### (6) Obligation:

Complexity Dependency Tuples Problem
Rules:

times(0, z0) → 0
times(s(z0), z1) → plus(z1, times(z0, z1))
plus(0, z0) → z0
plus(s(z0), z1) → s(plus(z0, z1))
Tuples:

PLUS(s(z0), z1) → c8(PLUS(z0, z1))
TIMES(s(z0), z1) → c10(PLUS(z1, times(z0, z1)), TIMES(z0, z1))
S tuples:

PLUS(s(z0), z1) → c8(PLUS(z0, z1))
TIMES(s(z0), z1) → c10(PLUS(z1, times(z0, z1)), TIMES(z0, z1))
K tuples:none
Defined Rule Symbols:

times, plus

Defined Pair Symbols:

PLUS, TIMES

Compound Symbols:

c8, c10

### (7) CdtRuleRemovalProof (UPPER BOUND (ADD(O(n^1))) transformation)

Found a reduction pair which oriented the following tuples strictly. Hence they can be removed from S.

TIMES(s(z0), z1) → c10(PLUS(z1, times(z0, z1)), TIMES(z0, z1))
We considered the (Usable) Rules:none
And the Tuples:

PLUS(s(z0), z1) → c8(PLUS(z0, z1))
TIMES(s(z0), z1) → c10(PLUS(z1, times(z0, z1)), TIMES(z0, z1))
The order we found is given by the following interpretation:
Polynomial interpretation :

POL(0) = [3]
POL(PLUS(x1, x2)) = [5]
POL(TIMES(x1, x2)) = [4]x1
POL(c10(x1, x2)) = x1 + x2
POL(c8(x1)) = x1
POL(plus(x1, x2)) = [2] + [2]x1 + [2]x2
POL(s(x1)) = [4] + x1
POL(times(x1, x2)) = [2] + [3]x1 + [3]x2

### (8) Obligation:

Complexity Dependency Tuples Problem
Rules:

times(0, z0) → 0
times(s(z0), z1) → plus(z1, times(z0, z1))
plus(0, z0) → z0
plus(s(z0), z1) → s(plus(z0, z1))
Tuples:

PLUS(s(z0), z1) → c8(PLUS(z0, z1))
TIMES(s(z0), z1) → c10(PLUS(z1, times(z0, z1)), TIMES(z0, z1))
S tuples:

PLUS(s(z0), z1) → c8(PLUS(z0, z1))
K tuples:

TIMES(s(z0), z1) → c10(PLUS(z1, times(z0, z1)), TIMES(z0, z1))
Defined Rule Symbols:

times, plus

Defined Pair Symbols:

PLUS, TIMES

Compound Symbols:

c8, c10

### (9) CdtRuleRemovalProof (UPPER BOUND (ADD(O(n^2))) transformation)

Found a reduction pair which oriented the following tuples strictly. Hence they can be removed from S.

PLUS(s(z0), z1) → c8(PLUS(z0, z1))
We considered the (Usable) Rules:none
And the Tuples:

PLUS(s(z0), z1) → c8(PLUS(z0, z1))
TIMES(s(z0), z1) → c10(PLUS(z1, times(z0, z1)), TIMES(z0, z1))
The order we found is given by the following interpretation:
Polynomial interpretation :

POL(0) = 0
POL(PLUS(x1, x2)) = x1
POL(TIMES(x1, x2)) = [2]x1·x2 + [2]x12
POL(c10(x1, x2)) = x1 + x2
POL(c8(x1)) = x1
POL(plus(x1, x2)) = 0
POL(s(x1)) = [2] + x1
POL(times(x1, x2)) = 0

### (10) Obligation:

Complexity Dependency Tuples Problem
Rules:

times(0, z0) → 0
times(s(z0), z1) → plus(z1, times(z0, z1))
plus(0, z0) → z0
plus(s(z0), z1) → s(plus(z0, z1))
Tuples:

PLUS(s(z0), z1) → c8(PLUS(z0, z1))
TIMES(s(z0), z1) → c10(PLUS(z1, times(z0, z1)), TIMES(z0, z1))
S tuples:none
K tuples:

TIMES(s(z0), z1) → c10(PLUS(z1, times(z0, z1)), TIMES(z0, z1))
PLUS(s(z0), z1) → c8(PLUS(z0, z1))
Defined Rule Symbols:

times, plus

Defined Pair Symbols:

PLUS, TIMES

Compound Symbols:

c8, c10

### (11) SIsEmptyProof (BOTH BOUNDS(ID, ID) transformation)

The set S is empty