/export/starexec/sandbox/solver/bin/starexec_run_standard /export/starexec/sandbox/benchmark/theBenchmark.itrs /export/starexec/sandbox/output/output_files


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YES
proof of /export/starexec/sandbox/benchmark/theBenchmark.itrs
# AProVE Commit ID: 794c25de1cacf0d048858bcd21c9a779e1221865 marcel 20200619 unpublished dirty


Termination of the given ITRS could be proven:

(0) ITRS
(1) ITRStoIDPProof [EQUIVALENT, 0 ms]
(2) IDP
(3) UsableRulesProof [EQUIVALENT, 0 ms]
(4) IDP
(5) IDPNonInfProof [SOUND, 184 ms]
(6) IDP
(7) IDependencyGraphProof [EQUIVALENT, 0 ms]
(8) TRUE


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(0)
Obligation:
ITRS problem:

The following function symbols are pre-defined:
<<<
 & 	~ 	Bwand: (Integer, Integer) -> Integer
 >= 	~ 	Ge: (Integer, Integer) -> Boolean
 | 	~ 	Bwor: (Integer, Integer) -> Integer
 / 	~ 	Div: (Integer, Integer) -> Integer
 != 	~ 	Neq: (Integer, Integer) -> Boolean
 && 	~ 	Land: (Boolean, Boolean) -> Boolean
 ! 	~ 	Lnot: (Boolean) -> Boolean
 = 	~ 	Eq: (Integer, Integer) -> Boolean
 <= 	~ 	Le: (Integer, Integer) -> Boolean
 ^ 	~ 	Bwxor: (Integer, Integer) -> Integer
 % 	~ 	Mod: (Integer, Integer) -> Integer
 > 	~ 	Gt: (Integer, Integer) -> Boolean
 + 	~ 	Add: (Integer, Integer) -> Integer
 -1 	~ 	UnaryMinus: (Integer) -> Integer
 < 	~ 	Lt: (Integer, Integer) -> Boolean
 || 	~ 	Lor: (Boolean, Boolean) -> Boolean
 - 	~ 	Sub: (Integer, Integer) -> Integer
 ~ 	~ 	Bwnot: (Integer) -> Integer
 * 	~ 	Mul: (Integer, Integer) -> Integer
>>>

The TRS R consists of the following rules:
eval(x, y) -> Cond_eval(x > y, x, y)
Cond_eval(TRUE, x, y) -> eval(x - 1, y)
The set Q consists of the following terms:
eval(x0, x1)
Cond_eval(TRUE, x0, x1)

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

(1) ITRStoIDPProof (EQUIVALENT)
Added dependency pairs
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(2)
Obligation:
IDP problem:
The following function symbols are pre-defined:
<<<
 & 	~ 	Bwand: (Integer, Integer) -> Integer
 >= 	~ 	Ge: (Integer, Integer) -> Boolean
 | 	~ 	Bwor: (Integer, Integer) -> Integer
 / 	~ 	Div: (Integer, Integer) -> Integer
 != 	~ 	Neq: (Integer, Integer) -> Boolean
 && 	~ 	Land: (Boolean, Boolean) -> Boolean
 ! 	~ 	Lnot: (Boolean) -> Boolean
 = 	~ 	Eq: (Integer, Integer) -> Boolean
 <= 	~ 	Le: (Integer, Integer) -> Boolean
 ^ 	~ 	Bwxor: (Integer, Integer) -> Integer
 % 	~ 	Mod: (Integer, Integer) -> Integer
 > 	~ 	Gt: (Integer, Integer) -> Boolean
 + 	~ 	Add: (Integer, Integer) -> Integer
 -1 	~ 	UnaryMinus: (Integer) -> Integer
 < 	~ 	Lt: (Integer, Integer) -> Boolean
 || 	~ 	Lor: (Boolean, Boolean) -> Boolean
 - 	~ 	Sub: (Integer, Integer) -> Integer
 ~ 	~ 	Bwnot: (Integer) -> Integer
 * 	~ 	Mul: (Integer, Integer) -> Integer
>>>


The following domains are used:
   Integer

The ITRS R consists of the following rules:
eval(x, y) -> Cond_eval(x > y, x, y)
Cond_eval(TRUE, x, y) -> eval(x - 1, y)

The integer pair graph contains the following rules and edges:
(0): EVAL(x[0], y[0]) -> COND_EVAL(x[0] > y[0], x[0], y[0])
(1): COND_EVAL(TRUE, x[1], y[1]) -> EVAL(x[1] - 1, y[1])

   (0) -> (1), if (x[0] > y[0]  & x[0] ->^* x[1] & y[0] ->^* y[1])
   (1) -> (0), if (x[1] - 1 ->^* x[0] & y[1] ->^* y[0])

The set Q consists of the following terms:
eval(x0, x1)
Cond_eval(TRUE, x0, x1)

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(3) UsableRulesProof (EQUIVALENT)
As all Q-normal forms are R-normal forms we are in the innermost case. Hence, by the usable rules processor [LPAR04] we can delete all non-usable rules [FROCOS05] from R.
----------------------------------------

(4)
Obligation:
IDP problem:
The following function symbols are pre-defined:
<<<
 & 	~ 	Bwand: (Integer, Integer) -> Integer
 >= 	~ 	Ge: (Integer, Integer) -> Boolean
 | 	~ 	Bwor: (Integer, Integer) -> Integer
 / 	~ 	Div: (Integer, Integer) -> Integer
 != 	~ 	Neq: (Integer, Integer) -> Boolean
 && 	~ 	Land: (Boolean, Boolean) -> Boolean
 ! 	~ 	Lnot: (Boolean) -> Boolean
 = 	~ 	Eq: (Integer, Integer) -> Boolean
 <= 	~ 	Le: (Integer, Integer) -> Boolean
 ^ 	~ 	Bwxor: (Integer, Integer) -> Integer
 % 	~ 	Mod: (Integer, Integer) -> Integer
 > 	~ 	Gt: (Integer, Integer) -> Boolean
 + 	~ 	Add: (Integer, Integer) -> Integer
 -1 	~ 	UnaryMinus: (Integer) -> Integer
 < 	~ 	Lt: (Integer, Integer) -> Boolean
 || 	~ 	Lor: (Boolean, Boolean) -> Boolean
 - 	~ 	Sub: (Integer, Integer) -> Integer
 ~ 	~ 	Bwnot: (Integer) -> Integer
 * 	~ 	Mul: (Integer, Integer) -> Integer
>>>


The following domains are used:
   Integer

R is empty.

The integer pair graph contains the following rules and edges:
(0): EVAL(x[0], y[0]) -> COND_EVAL(x[0] > y[0], x[0], y[0])
(1): COND_EVAL(TRUE, x[1], y[1]) -> EVAL(x[1] - 1, y[1])

   (0) -> (1), if (x[0] > y[0]  & x[0] ->^* x[1] & y[0] ->^* y[1])
   (1) -> (0), if (x[1] - 1 ->^* x[0] & y[1] ->^* y[0])

The set Q consists of the following terms:
eval(x0, x1)
Cond_eval(TRUE, x0, x1)

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

(5) IDPNonInfProof (SOUND)
Used the following options for this NonInfProof:

IDPGPoloSolver:
Range: [(-1,2)]
IsNat: false
Interpretation Shape Heuristic: aprove.DPFramework.IDPProblem.Processors.nonInf.poly.IdpDefaultShapeHeuristic@af554ec
Constraint Generator: NonInfConstraintGenerator:
PathGenerator: MetricPathGenerator:
Max Left Steps: 1
Max Right Steps: 1



The constraints were generated the following way:

The DP Problem is simplified using the Induction Calculus [NONINF] with the following steps:

Note that final constraints are written in bold face.



For Pair EVAL(x, y) -> COND_EVAL(>(x, y), x, y) the following chains were created:
*We consider the chain EVAL(x[0], y[0]) -> COND_EVAL(>(x[0], y[0]), x[0], y[0]), COND_EVAL(TRUE, x[1], y[1]) -> EVAL(-(x[1], 1), y[1]) which results in the following constraint:

(1)    (>(x[0], y[0])=TRUE & x[0]=x[1] & y[0]=y[1]  ==>  EVAL(x[0], y[0])_>=_NonInfC & EVAL(x[0], y[0])_>=_COND_EVAL(>(x[0], y[0]), x[0], y[0]) & (U^Increasing(COND_EVAL(>(x[0], y[0]), x[0], y[0])), >=))



We simplified constraint (1) using rule (IV) which results in the following new constraint:

(2)    (>(x[0], y[0])=TRUE  ==>  EVAL(x[0], y[0])_>=_NonInfC & EVAL(x[0], y[0])_>=_COND_EVAL(>(x[0], y[0]), x[0], y[0]) & (U^Increasing(COND_EVAL(>(x[0], y[0]), x[0], y[0])), >=))



We simplified constraint (2) using rule (POLY_CONSTRAINTS) which results in the following new constraint:

(3)    (x[0] + [-1] + [-1]y[0] >= 0  ==>  (U^Increasing(COND_EVAL(>(x[0], y[0]), x[0], y[0])), >=) & [(-1)bni_11 + (-1)Bound*bni_11] + [(-1)bni_11]y[0] + [bni_11]x[0] >= 0 & [(-1)bso_12] >= 0)



We simplified constraint (3) using rule (IDP_POLY_SIMPLIFY) which results in the following new constraint:

(4)    (x[0] + [-1] + [-1]y[0] >= 0  ==>  (U^Increasing(COND_EVAL(>(x[0], y[0]), x[0], y[0])), >=) & [(-1)bni_11 + (-1)Bound*bni_11] + [(-1)bni_11]y[0] + [bni_11]x[0] >= 0 & [(-1)bso_12] >= 0)



We simplified constraint (4) using rule (POLY_REMOVE_MIN_MAX) which results in the following new constraint:

(5)    (x[0] + [-1] + [-1]y[0] >= 0  ==>  (U^Increasing(COND_EVAL(>(x[0], y[0]), x[0], y[0])), >=) & [(-1)bni_11 + (-1)Bound*bni_11] + [(-1)bni_11]y[0] + [bni_11]x[0] >= 0 & [(-1)bso_12] >= 0)



We simplified constraint (5) using rule (IDP_SMT_SPLIT) which results in the following new constraint:

(6)    (x[0] >= 0  ==>  (U^Increasing(COND_EVAL(>(x[0], y[0]), x[0], y[0])), >=) & [(-1)Bound*bni_11] + [bni_11]x[0] >= 0 & [(-1)bso_12] >= 0)



We simplified constraint (6) using rule (IDP_SMT_SPLIT) which results in the following new constraints:

(7)    (x[0] >= 0 & y[0] >= 0  ==>  (U^Increasing(COND_EVAL(>(x[0], y[0]), x[0], y[0])), >=) & [(-1)Bound*bni_11] + [bni_11]x[0] >= 0 & [(-1)bso_12] >= 0)

(8)    (x[0] >= 0 & y[0] >= 0  ==>  (U^Increasing(COND_EVAL(>(x[0], y[0]), x[0], y[0])), >=) & [(-1)Bound*bni_11] + [bni_11]x[0] >= 0 & [(-1)bso_12] >= 0)








For Pair COND_EVAL(TRUE, x, y) -> EVAL(-(x, 1), y) the following chains were created:
*We consider the chain EVAL(x[0], y[0]) -> COND_EVAL(>(x[0], y[0]), x[0], y[0]), COND_EVAL(TRUE, x[1], y[1]) -> EVAL(-(x[1], 1), y[1]), EVAL(x[0], y[0]) -> COND_EVAL(>(x[0], y[0]), x[0], y[0]) which results in the following constraint:

(1)    (>(x[0], y[0])=TRUE & x[0]=x[1] & y[0]=y[1] & -(x[1], 1)=x[0]1 & y[1]=y[0]1  ==>  COND_EVAL(TRUE, x[1], y[1])_>=_NonInfC & COND_EVAL(TRUE, x[1], y[1])_>=_EVAL(-(x[1], 1), y[1]) & (U^Increasing(EVAL(-(x[1], 1), y[1])), >=))



We simplified constraint (1) using rules (III), (IV) which results in the following new constraint:

(2)    (>(x[0], y[0])=TRUE  ==>  COND_EVAL(TRUE, x[0], y[0])_>=_NonInfC & COND_EVAL(TRUE, x[0], y[0])_>=_EVAL(-(x[0], 1), y[0]) & (U^Increasing(EVAL(-(x[1], 1), y[1])), >=))



We simplified constraint (2) using rule (POLY_CONSTRAINTS) which results in the following new constraint:

(3)    (x[0] + [-1] + [-1]y[0] >= 0  ==>  (U^Increasing(EVAL(-(x[1], 1), y[1])), >=) & [(-1)bni_13 + (-1)Bound*bni_13] + [(-1)bni_13]y[0] + [bni_13]x[0] >= 0 & [1 + (-1)bso_14] >= 0)



We simplified constraint (3) using rule (IDP_POLY_SIMPLIFY) which results in the following new constraint:

(4)    (x[0] + [-1] + [-1]y[0] >= 0  ==>  (U^Increasing(EVAL(-(x[1], 1), y[1])), >=) & [(-1)bni_13 + (-1)Bound*bni_13] + [(-1)bni_13]y[0] + [bni_13]x[0] >= 0 & [1 + (-1)bso_14] >= 0)



We simplified constraint (4) using rule (POLY_REMOVE_MIN_MAX) which results in the following new constraint:

(5)    (x[0] + [-1] + [-1]y[0] >= 0  ==>  (U^Increasing(EVAL(-(x[1], 1), y[1])), >=) & [(-1)bni_13 + (-1)Bound*bni_13] + [(-1)bni_13]y[0] + [bni_13]x[0] >= 0 & [1 + (-1)bso_14] >= 0)



We simplified constraint (5) using rule (IDP_SMT_SPLIT) which results in the following new constraint:

(6)    (x[0] >= 0  ==>  (U^Increasing(EVAL(-(x[1], 1), y[1])), >=) & [(-1)Bound*bni_13] + [bni_13]x[0] >= 0 & [1 + (-1)bso_14] >= 0)



We simplified constraint (6) using rule (IDP_SMT_SPLIT) which results in the following new constraints:

(7)    (x[0] >= 0 & y[0] >= 0  ==>  (U^Increasing(EVAL(-(x[1], 1), y[1])), >=) & [(-1)Bound*bni_13] + [bni_13]x[0] >= 0 & [1 + (-1)bso_14] >= 0)

(8)    (x[0] >= 0 & y[0] >= 0  ==>  (U^Increasing(EVAL(-(x[1], 1), y[1])), >=) & [(-1)Bound*bni_13] + [bni_13]x[0] >= 0 & [1 + (-1)bso_14] >= 0)








To summarize, we get the following constraints P__>=_ for the following pairs.

*EVAL(x, y) -> COND_EVAL(>(x, y), x, y)

*(x[0] >= 0 & y[0] >= 0  ==>  (U^Increasing(COND_EVAL(>(x[0], y[0]), x[0], y[0])), >=) & [(-1)Bound*bni_11] + [bni_11]x[0] >= 0 & [(-1)bso_12] >= 0)


*(x[0] >= 0 & y[0] >= 0  ==>  (U^Increasing(COND_EVAL(>(x[0], y[0]), x[0], y[0])), >=) & [(-1)Bound*bni_11] + [bni_11]x[0] >= 0 & [(-1)bso_12] >= 0)




*COND_EVAL(TRUE, x, y) -> EVAL(-(x, 1), y)

*(x[0] >= 0 & y[0] >= 0  ==>  (U^Increasing(EVAL(-(x[1], 1), y[1])), >=) & [(-1)Bound*bni_13] + [bni_13]x[0] >= 0 & [1 + (-1)bso_14] >= 0)


*(x[0] >= 0 & y[0] >= 0  ==>  (U^Increasing(EVAL(-(x[1], 1), y[1])), >=) & [(-1)Bound*bni_13] + [bni_13]x[0] >= 0 & [1 + (-1)bso_14] >= 0)








The constraints for P_> respective P_bound are constructed from P__>=_ where we just replace every occurence of "t _>=_ s" in P__>=_ by  "t > s" respective "t _>=_ c". Here c stands for the fresh constant used for P_bound. 

Using the following integer polynomial ordering the  resulting constraints can be solved 

Polynomial interpretation over integers[POLO]:

   POL(TRUE) = 0
   POL(FALSE) = 0
   POL(EVAL(x_1, x_2)) = [-1] + [-1]x_2 + x_1
   POL(COND_EVAL(x_1, x_2, x_3)) = [-1] + [-1]x_3 + x_2
   POL(>(x_1, x_2)) = [-1]
   POL(-(x_1, x_2)) = x_1 + [-1]x_2
   POL(1) = [1]


The following pairs are in P_>:


   COND_EVAL(TRUE, x[1], y[1]) -> EVAL(-(x[1], 1), y[1])


The following pairs are in P_bound:


   EVAL(x[0], y[0]) -> COND_EVAL(>(x[0], y[0]), x[0], y[0])
   COND_EVAL(TRUE, x[1], y[1]) -> EVAL(-(x[1], 1), y[1])


The following pairs are in P_>=:


   EVAL(x[0], y[0]) -> COND_EVAL(>(x[0], y[0]), x[0], y[0])


There are no usable rules.
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(6)
Obligation:
IDP problem:
The following function symbols are pre-defined:
<<<
 & 	~ 	Bwand: (Integer, Integer) -> Integer
 >= 	~ 	Ge: (Integer, Integer) -> Boolean
 | 	~ 	Bwor: (Integer, Integer) -> Integer
 / 	~ 	Div: (Integer, Integer) -> Integer
 != 	~ 	Neq: (Integer, Integer) -> Boolean
 && 	~ 	Land: (Boolean, Boolean) -> Boolean
 ! 	~ 	Lnot: (Boolean) -> Boolean
 = 	~ 	Eq: (Integer, Integer) -> Boolean
 <= 	~ 	Le: (Integer, Integer) -> Boolean
 ^ 	~ 	Bwxor: (Integer, Integer) -> Integer
 % 	~ 	Mod: (Integer, Integer) -> Integer
 > 	~ 	Gt: (Integer, Integer) -> Boolean
 + 	~ 	Add: (Integer, Integer) -> Integer
 -1 	~ 	UnaryMinus: (Integer) -> Integer
 < 	~ 	Lt: (Integer, Integer) -> Boolean
 || 	~ 	Lor: (Boolean, Boolean) -> Boolean
 - 	~ 	Sub: (Integer, Integer) -> Integer
 ~ 	~ 	Bwnot: (Integer) -> Integer
 * 	~ 	Mul: (Integer, Integer) -> Integer
>>>


The following domains are used:
   Integer

R is empty.

The integer pair graph contains the following rules and edges:
(0): EVAL(x[0], y[0]) -> COND_EVAL(x[0] > y[0], x[0], y[0])


The set Q consists of the following terms:
eval(x0, x1)
Cond_eval(TRUE, x0, x1)

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(7) IDependencyGraphProof (EQUIVALENT)
The approximation of the Dependency Graph [LPAR04,FROCOS05,EDGSTAR] contains 0 SCCs with 1 less node.
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(8)
TRUE