/export/starexec/sandbox/solver/bin/starexec_run_rcdcRelativeAlsoLower /export/starexec/sandbox/benchmark/theBenchmark.xml /export/starexec/sandbox/output/output_files


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WORST_CASE(Omega(n^1), ?)
proof of /export/starexec/sandbox/benchmark/theBenchmark.xml
# AProVE Commit ID: 794c25de1cacf0d048858bcd21c9a779e1221865 marcel 20200619 unpublished dirty


The Derivational Complexity (full) of the given DCpxTrs could be proven to be BOUNDS(n^1, INF).

(0) DCpxTrs
(1) DerivationalComplexityToRuntimeComplexityProof [BOTH BOUNDS(ID, ID), 0 ms]
(2) CpxRelTRS
(3) SInnermostTerminationProof [BOTH CONCRETE BOUNDS(ID, ID), 198 ms]
(4) CpxRelTRS
(5) RenamingProof [BOTH BOUNDS(ID, ID), 0 ms]
(6) CpxRelTRS
(7) TypeInferenceProof [BOTH BOUNDS(ID, ID), 0 ms]
(8) typed CpxTrs
(9) OrderProof [LOWER BOUND(ID), 0 ms]
(10) typed CpxTrs
(11) RewriteLemmaProof [LOWER BOUND(ID), 440 ms]
(12) BEST
    (13) proven lower bound
        (14) LowerBoundPropagationProof [FINISHED, 0 ms]
        (15) BOUNDS(n^1, INF)
    (16) typed CpxTrs
        (17) RewriteLemmaProof [LOWER BOUND(ID), 128 ms]
        (18) BOUNDS(1, INF)


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(0)
Obligation:
The Derivational Complexity (full) of the given DCpxTrs could be proven to be BOUNDS(n^1, INF).


The TRS R consists of the following rules:

   a(x1) -> x1
   a(b(x1)) -> b(c(a(x1)))
   c(c(x1)) -> b(a(c(a(x1))))

S is empty.
Rewrite Strategy: FULL
----------------------------------------

(1) DerivationalComplexityToRuntimeComplexityProof (BOTH BOUNDS(ID, ID))
The following rules have been added to S to convert the given derivational complexity problem to a runtime complexity problem:

   encArg(b(x_1)) -> b(encArg(x_1))
   encArg(cons_a(x_1)) -> a(encArg(x_1))
   encArg(cons_c(x_1)) -> c(encArg(x_1))
   encode_a(x_1) -> a(encArg(x_1))
   encode_b(x_1) -> b(encArg(x_1))
   encode_c(x_1) -> c(encArg(x_1))


----------------------------------------

(2)
Obligation:
The Runtime Complexity (full) of the given CpxRelTRS could be proven to be BOUNDS(n^1, INF).


The TRS R consists of the following rules:

   a(x1) -> x1
   a(b(x1)) -> b(c(a(x1)))
   c(c(x1)) -> b(a(c(a(x1))))

The (relative) TRS S consists of the following rules:

   encArg(b(x_1)) -> b(encArg(x_1))
   encArg(cons_a(x_1)) -> a(encArg(x_1))
   encArg(cons_c(x_1)) -> c(encArg(x_1))
   encode_a(x_1) -> a(encArg(x_1))
   encode_b(x_1) -> b(encArg(x_1))
   encode_c(x_1) -> c(encArg(x_1))

Rewrite Strategy: FULL
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(3) SInnermostTerminationProof (BOTH CONCRETE BOUNDS(ID, ID))
proved innermost termination of relative rules
----------------------------------------

(4)
Obligation:
The Runtime Complexity (full) of the given CpxRelTRS could be proven to be BOUNDS(n^1, INF).


The TRS R consists of the following rules:

   a(x1) -> x1
   a(b(x1)) -> b(c(a(x1)))
   c(c(x1)) -> b(a(c(a(x1))))

The (relative) TRS S consists of the following rules:

   encArg(b(x_1)) -> b(encArg(x_1))
   encArg(cons_a(x_1)) -> a(encArg(x_1))
   encArg(cons_c(x_1)) -> c(encArg(x_1))
   encode_a(x_1) -> a(encArg(x_1))
   encode_b(x_1) -> b(encArg(x_1))
   encode_c(x_1) -> c(encArg(x_1))

Rewrite Strategy: FULL
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(5) RenamingProof (BOTH BOUNDS(ID, ID))
Renamed function symbols to avoid clashes with predefined symbol.
----------------------------------------

(6)
Obligation:
The Runtime Complexity (full) of the given CpxRelTRS could be proven to be BOUNDS(n^1, INF).


The TRS R consists of the following rules:

   a(x1) -> x1
   a(b(x1)) -> b(c(a(x1)))
   c(c(x1)) -> b(a(c(a(x1))))

The (relative) TRS S consists of the following rules:

   encArg(b(x_1)) -> b(encArg(x_1))
   encArg(cons_a(x_1)) -> a(encArg(x_1))
   encArg(cons_c(x_1)) -> c(encArg(x_1))
   encode_a(x_1) -> a(encArg(x_1))
   encode_b(x_1) -> b(encArg(x_1))
   encode_c(x_1) -> c(encArg(x_1))

Rewrite Strategy: FULL
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(7) TypeInferenceProof (BOTH BOUNDS(ID, ID))
Infered types.
----------------------------------------

(8)
Obligation:
TRS:
Rules:
a(x1) -> x1
a(b(x1)) -> b(c(a(x1)))
c(c(x1)) -> b(a(c(a(x1))))
encArg(b(x_1)) -> b(encArg(x_1))
encArg(cons_a(x_1)) -> a(encArg(x_1))
encArg(cons_c(x_1)) -> c(encArg(x_1))
encode_a(x_1) -> a(encArg(x_1))
encode_b(x_1) -> b(encArg(x_1))
encode_c(x_1) -> c(encArg(x_1))

Types:
a :: b:cons_a:cons_c -> b:cons_a:cons_c
b :: b:cons_a:cons_c -> b:cons_a:cons_c
c :: b:cons_a:cons_c -> b:cons_a:cons_c
encArg :: b:cons_a:cons_c -> b:cons_a:cons_c
cons_a :: b:cons_a:cons_c -> b:cons_a:cons_c
cons_c :: b:cons_a:cons_c -> b:cons_a:cons_c
encode_a :: b:cons_a:cons_c -> b:cons_a:cons_c
encode_b :: b:cons_a:cons_c -> b:cons_a:cons_c
encode_c :: b:cons_a:cons_c -> b:cons_a:cons_c
hole_b:cons_a:cons_c1_0 :: b:cons_a:cons_c
gen_b:cons_a:cons_c2_0 :: Nat -> b:cons_a:cons_c

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(9) OrderProof (LOWER BOUND(ID))
Heuristically decided to analyse the following defined symbols:
a, c, encArg

They will be analysed ascendingly in the following order:
a = c
a < encArg
c < encArg

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(10)
Obligation:
TRS:
Rules:
a(x1) -> x1
a(b(x1)) -> b(c(a(x1)))
c(c(x1)) -> b(a(c(a(x1))))
encArg(b(x_1)) -> b(encArg(x_1))
encArg(cons_a(x_1)) -> a(encArg(x_1))
encArg(cons_c(x_1)) -> c(encArg(x_1))
encode_a(x_1) -> a(encArg(x_1))
encode_b(x_1) -> b(encArg(x_1))
encode_c(x_1) -> c(encArg(x_1))

Types:
a :: b:cons_a:cons_c -> b:cons_a:cons_c
b :: b:cons_a:cons_c -> b:cons_a:cons_c
c :: b:cons_a:cons_c -> b:cons_a:cons_c
encArg :: b:cons_a:cons_c -> b:cons_a:cons_c
cons_a :: b:cons_a:cons_c -> b:cons_a:cons_c
cons_c :: b:cons_a:cons_c -> b:cons_a:cons_c
encode_a :: b:cons_a:cons_c -> b:cons_a:cons_c
encode_b :: b:cons_a:cons_c -> b:cons_a:cons_c
encode_c :: b:cons_a:cons_c -> b:cons_a:cons_c
hole_b:cons_a:cons_c1_0 :: b:cons_a:cons_c
gen_b:cons_a:cons_c2_0 :: Nat -> b:cons_a:cons_c


Generator Equations:
gen_b:cons_a:cons_c2_0(0) <=> hole_b:cons_a:cons_c1_0
gen_b:cons_a:cons_c2_0(+(x, 1)) <=> b(gen_b:cons_a:cons_c2_0(x))


The following defined symbols remain to be analysed:
c, a, encArg

They will be analysed ascendingly in the following order:
a = c
a < encArg
c < encArg

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(11) RewriteLemmaProof (LOWER BOUND(ID))
Proved the following rewrite lemma:
a(gen_b:cons_a:cons_c2_0(+(1, n8_0))) -> *3_0, rt in Omega(n8_0)

Induction Base:
a(gen_b:cons_a:cons_c2_0(+(1, 0)))

Induction Step:
a(gen_b:cons_a:cons_c2_0(+(1, +(n8_0, 1)))) ->_R^Omega(1)
b(c(a(gen_b:cons_a:cons_c2_0(+(1, n8_0))))) ->_IH
b(c(*3_0))

We have rt in Omega(n^1) and sz in O(n). Thus, we have irc_R in Omega(n).
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(12)
Complex Obligation (BEST)

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(13)
Obligation:
Proved the lower bound n^1 for the following obligation:

TRS:
Rules:
a(x1) -> x1
a(b(x1)) -> b(c(a(x1)))
c(c(x1)) -> b(a(c(a(x1))))
encArg(b(x_1)) -> b(encArg(x_1))
encArg(cons_a(x_1)) -> a(encArg(x_1))
encArg(cons_c(x_1)) -> c(encArg(x_1))
encode_a(x_1) -> a(encArg(x_1))
encode_b(x_1) -> b(encArg(x_1))
encode_c(x_1) -> c(encArg(x_1))

Types:
a :: b:cons_a:cons_c -> b:cons_a:cons_c
b :: b:cons_a:cons_c -> b:cons_a:cons_c
c :: b:cons_a:cons_c -> b:cons_a:cons_c
encArg :: b:cons_a:cons_c -> b:cons_a:cons_c
cons_a :: b:cons_a:cons_c -> b:cons_a:cons_c
cons_c :: b:cons_a:cons_c -> b:cons_a:cons_c
encode_a :: b:cons_a:cons_c -> b:cons_a:cons_c
encode_b :: b:cons_a:cons_c -> b:cons_a:cons_c
encode_c :: b:cons_a:cons_c -> b:cons_a:cons_c
hole_b:cons_a:cons_c1_0 :: b:cons_a:cons_c
gen_b:cons_a:cons_c2_0 :: Nat -> b:cons_a:cons_c


Generator Equations:
gen_b:cons_a:cons_c2_0(0) <=> hole_b:cons_a:cons_c1_0
gen_b:cons_a:cons_c2_0(+(x, 1)) <=> b(gen_b:cons_a:cons_c2_0(x))


The following defined symbols remain to be analysed:
a, encArg

They will be analysed ascendingly in the following order:
a = c
a < encArg
c < encArg

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(14) LowerBoundPropagationProof (FINISHED)
Propagated lower bound.
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(15)
BOUNDS(n^1, INF)

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(16)
Obligation:
TRS:
Rules:
a(x1) -> x1
a(b(x1)) -> b(c(a(x1)))
c(c(x1)) -> b(a(c(a(x1))))
encArg(b(x_1)) -> b(encArg(x_1))
encArg(cons_a(x_1)) -> a(encArg(x_1))
encArg(cons_c(x_1)) -> c(encArg(x_1))
encode_a(x_1) -> a(encArg(x_1))
encode_b(x_1) -> b(encArg(x_1))
encode_c(x_1) -> c(encArg(x_1))

Types:
a :: b:cons_a:cons_c -> b:cons_a:cons_c
b :: b:cons_a:cons_c -> b:cons_a:cons_c
c :: b:cons_a:cons_c -> b:cons_a:cons_c
encArg :: b:cons_a:cons_c -> b:cons_a:cons_c
cons_a :: b:cons_a:cons_c -> b:cons_a:cons_c
cons_c :: b:cons_a:cons_c -> b:cons_a:cons_c
encode_a :: b:cons_a:cons_c -> b:cons_a:cons_c
encode_b :: b:cons_a:cons_c -> b:cons_a:cons_c
encode_c :: b:cons_a:cons_c -> b:cons_a:cons_c
hole_b:cons_a:cons_c1_0 :: b:cons_a:cons_c
gen_b:cons_a:cons_c2_0 :: Nat -> b:cons_a:cons_c


Lemmas:
a(gen_b:cons_a:cons_c2_0(+(1, n8_0))) -> *3_0, rt in Omega(n8_0)


Generator Equations:
gen_b:cons_a:cons_c2_0(0) <=> hole_b:cons_a:cons_c1_0
gen_b:cons_a:cons_c2_0(+(x, 1)) <=> b(gen_b:cons_a:cons_c2_0(x))


The following defined symbols remain to be analysed:
c, encArg

They will be analysed ascendingly in the following order:
a = c
a < encArg
c < encArg

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(17) RewriteLemmaProof (LOWER BOUND(ID))
Proved the following rewrite lemma:
encArg(gen_b:cons_a:cons_c2_0(+(1, n242_0))) -> *3_0, rt in Omega(0)

Induction Base:
encArg(gen_b:cons_a:cons_c2_0(+(1, 0)))

Induction Step:
encArg(gen_b:cons_a:cons_c2_0(+(1, +(n242_0, 1)))) ->_R^Omega(0)
b(encArg(gen_b:cons_a:cons_c2_0(+(1, n242_0)))) ->_IH
b(*3_0)

We have rt in Omega(1) and sz in O(n). Thus, we have irc_R in Omega(n^0).
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(18)
BOUNDS(1, INF)