public class LeUserDefRec {
	public static void main(String[] args) {
		int x = args[0].length();
		int y = args[1].length();
		le(x, y);
	}

	public static boolean le(int x, int y) {
		if (x > 0 && y > 0) {
			return le(x-1, y-1);
		} else {
			return (x == 0);
		}
	}
}

(1) JBC2FIG (SOUND transformation)

Constructed FIGraph.

(3) FIGtoITRSProof (SOUND transformation)

Transformed FIGraph SCCs to IDPs. Logs:

---

Log for SCC 0:

Generated 15 rules for P and 19 rules for R.

Combined rules. Obtained 1 rules for P and 4 rules for R.

Filtered ground terms:

415_0_le_LE(x1, x2, x3, x4) → 415_0_le_LE(x2, x3, x4)
Cond_415_0_le_LE(x1, x2, x3, x4, x5) → Cond_415_0_le_LE(x1, x3, x4, x5)
689_0_le_Return(x1, x2) → 689_0_le_Return(x2)
643_0_le_Return(x1, x2) → 643_0_le_Return
616_0_le_Return(x1) → 616_0_le_Return

Filtered duplicate args:

415_0_le_LE(x1, x2, x3) → 415_0_le_LE(x2, x3)
Cond_415_0_le_LE(x1, x2, x3, x4) → Cond_415_0_le_LE(x1, x3, x4)

Filtered unneeded arguments:

681_1_le_InvokeMethod(x1, x2, x3, x4) → 681_1_le_InvokeMethod(x1, x3, x4)

Combined rules. Obtained 1 rules for P and 4 rules for R.

Finished conversion. Obtained 1 rules for P and 4 rules for R. System has predefined symbols.

(5) IDPNonInfProof (SOUND transformation)

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 415_0_LE_LE(x1, x0) → COND_415_0_LE_LE(&&(>(x1, 0), >(x0, 0)), x1, x0) the following chains were created:

• We consider the chain 415_0_LE_LE(x1[0], x0[0]) → COND_415_0_LE_LE(&&(>(x1[0], 0), >(x0[0], 0)), x1[0], x0[0]), COND_415_0_LE_LE(TRUE, x1[1], x0[1]) → 415_0_LE_LE(-(x1[1], 1), -(x0[1], 1)) which results in the following constraint:
  

  (1)    (&&(>(x1[0], 0), >(x0[0], 0))=TRUE∧x1[0]=x1[1]∧x0[0]=x0[1] ⇒ 415_0_LE_LE(x1[0], x0[0])≥NonInfC∧415_0_LE_LE(x1[0], x0[0])≥COND_415_0_LE_LE(&&(>(x1[0], 0), >(x0[0], 0)), x1[0], x0[0])∧(U^Increasing(COND_415_0_LE_LE(&&(>(x1[0], 0), >(x0[0], 0)), x1[0], x0[0])), ≥))

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

  (2)    (>(x1[0], 0)=TRUE∧>(x0[0], 0)=TRUE ⇒ 415_0_LE_LE(x1[0], x0[0])≥NonInfC∧415_0_LE_LE(x1[0], x0[0])≥COND_415_0_LE_LE(&&(>(x1[0], 0), >(x0[0], 0)), x1[0], x0[0])∧(U^Increasing(COND_415_0_LE_LE(&&(>(x1[0], 0), >(x0[0], 0)), x1[0], x0[0])), ≥))

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

  (3)    (x1[0] + [-1] ≥ 0∧x0[0] + [-1] ≥ 0 ⇒ (U^Increasing(COND_415_0_LE_LE(&&(>(x1[0], 0), >(x0[0], 0)), x1[0], x0[0])), ≥)∧[bni_14 + (-1)Bound*bni_14] + [(2)bni_14]x0[0] + [(2)bni_14]x1[0] ≥ 0∧[(-1)bso_15] ≥ 0)

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

  (4)    (x1[0] + [-1] ≥ 0∧x0[0] + [-1] ≥ 0 ⇒ (U^Increasing(COND_415_0_LE_LE(&&(>(x1[0], 0), >(x0[0], 0)), x1[0], x0[0])), ≥)∧[bni_14 + (-1)Bound*bni_14] + [(2)bni_14]x0[0] + [(2)bni_14]x1[0] ≥ 0∧[(-1)bso_15] ≥ 0)

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

  (5)    (x1[0] + [-1] ≥ 0∧x0[0] + [-1] ≥ 0 ⇒ (U^Increasing(COND_415_0_LE_LE(&&(>(x1[0], 0), >(x0[0], 0)), x1[0], x0[0])), ≥)∧[bni_14 + (-1)Bound*bni_14] + [(2)bni_14]x0[0] + [(2)bni_14]x1[0] ≥ 0∧[(-1)bso_15] ≥ 0)

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

  (6)    (x1[0] ≥ 0∧x0[0] + [-1] ≥ 0 ⇒ (U^Increasing(COND_415_0_LE_LE(&&(>(x1[0], 0), >(x0[0], 0)), x1[0], x0[0])), ≥)∧[(3)bni_14 + (-1)Bound*bni_14] + [(2)bni_14]x0[0] + [(2)bni_14]x1[0] ≥ 0∧[(-1)bso_15] ≥ 0)

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

  (7)    (x1[0] ≥ 0∧x0[0] ≥ 0 ⇒ (U^Increasing(COND_415_0_LE_LE(&&(>(x1[0], 0), >(x0[0], 0)), x1[0], x0[0])), ≥)∧[(5)bni_14 + (-1)Bound*bni_14] + [(2)bni_14]x0[0] + [(2)bni_14]x1[0] ≥ 0∧[(-1)bso_15] ≥ 0)

  
  
  

For Pair COND_415_0_LE_LE(TRUE, x1, x0) → 415_0_LE_LE(-(x1, 1), -(x0, 1)) the following chains were created:

• We consider the chain COND_415_0_LE_LE(TRUE, x1[1], x0[1]) → 415_0_LE_LE(-(x1[1], 1), -(x0[1], 1)) which results in the following constraint:
  

  (8)    (COND_415_0_LE_LE(TRUE, x1[1], x0[1])≥NonInfC∧COND_415_0_LE_LE(TRUE, x1[1], x0[1])≥415_0_LE_LE(-(x1[1], 1), -(x0[1], 1))∧(U^Increasing(415_0_LE_LE(-(x1[1], 1), -(x0[1], 1))), ≥))

  
  
  We simplified constraint (8) using rule (POLY_CONSTRAINTS) which results in the following new constraint:
  

  (9)    ((U^Increasing(415_0_LE_LE(-(x1[1], 1), -(x0[1], 1))), ≥)∧[4 + (-1)bso_17] ≥ 0)

  
  
  We simplified constraint (9) using rule (IDP_POLY_SIMPLIFY) which results in the following new constraint:
  

  (10)    ((U^Increasing(415_0_LE_LE(-(x1[1], 1), -(x0[1], 1))), ≥)∧[4 + (-1)bso_17] ≥ 0)

  
  
  We simplified constraint (10) using rule (POLY_REMOVE_MIN_MAX) which results in the following new constraint:
  

  (11)    ((U^Increasing(415_0_LE_LE(-(x1[1], 1), -(x0[1], 1))), ≥)∧[4 + (-1)bso_17] ≥ 0)

  
  
  We simplified constraint (11) using rule (IDP_UNRESTRICTED_VARS) which results in the following new constraint:
  

  (12)    ((U^Increasing(415_0_LE_LE(-(x1[1], 1), -(x0[1], 1))), ≥)∧0 = 0∧0 = 0∧[4 + (-1)bso_17] ≥ 0)

  
  
  

To summarize, we get the following constraints P_≥ for the following pairs.

• 415_0_LE_LE(x1, x0) → COND_415_0_LE_LE(&&(>(x1, 0), >(x0, 0)), x1, x0)
  
  • (x1[0] ≥ 0∧x0[0] ≥ 0 ⇒ (U^Increasing(COND_415_0_LE_LE(&&(>(x1[0], 0), >(x0[0], 0)), x1[0], x0[0])), ≥)∧[(5)bni_14 + (-1)Bound*bni_14] + [(2)bni_14]x0[0] + [(2)bni_14]x1[0] ≥ 0∧[(-1)bso_15] ≥ 0)
    
  
  
• COND_415_0_LE_LE(TRUE, x1, x0) → 415_0_LE_LE(-(x1, 1), -(x0, 1))
  
  • ((U^Increasing(415_0_LE_LE(-(x1[1], 1), -(x0[1], 1))), ≥)∧0 = 0∧0 = 0∧[4 + (-1)bso_17] ≥ 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(415_0_le_LE(x₁, x₂)) = [-1]   
POL(0) = 0   
POL(616_0_le_Return) = [-1]   
POL(681_1_le_InvokeMethod(x₁, x₂, x₃)) = [-1]   
POL(689_0_le_Return(x₁)) = [-1]   
POL(643_0_le_Return) = [-1]   
POL(415_0_LE_LE(x₁, x₂)) = [1] + [2]x₂ + [2]x₁   
POL(COND_415_0_LE_LE(x₁, x₂, x₃)) = [1] + [2]x₃ + [2]x₂   
POL(&&(x₁, x₂)) = [-1]   
POL(>(x₁, x₂)) = [-1]   
POL(-(x₁, x₂)) = x₁ + [-1]x₂   
POL(1) = [1]   

The following pairs are in P_>:

COND_415_0_LE_LE(TRUE, x1[1], x0[1]) → 415_0_LE_LE(-(x1[1], 1), -(x0[1], 1))

The following pairs are in P_bound:

415_0_LE_LE(x1[0], x0[0]) → COND_415_0_LE_LE(&&(>(x1[0], 0), >(x0[0], 0)), x1[0], x0[0])

The following pairs are in P_≥:

415_0_LE_LE(x1[0], x0[0]) → COND_415_0_LE_LE(&&(>(x1[0], 0), >(x0[0], 0)), x1[0], x0[0])

There are no usable rules.

(8) IDependencyGraphProof (EQUIVALENT transformation)

The approximation of the Dependency Graph [LPAR04,FROCOS05,EDGSTAR] contains 0 SCCs with 1 less node.

(11) IDependencyGraphProof (EQUIVALENT transformation)

The approximation of the Dependency Graph [LPAR04,FROCOS05,EDGSTAR] contains 0 SCCs with 1 less node.