0.00/0.17	YES
0.00/0.18	We consider the system theBenchmark.
0.00/0.18	
0.00/0.18	  Alphabet:
0.00/0.18	
0.00/0.18	    !fac3220 : [a * a] --> a 
0.00/0.18	    !facdiv : [a * a] --> a 
0.00/0.18	    !facdot : [a * a] --> a 
0.00/0.18	    cons : [c * d] --> d 
0.00/0.18	    e : [] --> a 
0.00/0.18	    false : [] --> b 
0.00/0.18	    filter : [c -> b * d] --> d 
0.00/0.18	    filter2 : [b * c -> b * c * d] --> d 
0.00/0.18	    map : [c -> c * d] --> d 
0.00/0.18	    nil : [] --> d 
0.00/0.18	    true : [] --> b 
0.00/0.18	
0.00/0.18	  Rules:
0.00/0.18	
0.00/0.18	    !fac3220(x, x) => e 
0.00/0.18	    !fac3220(e, x) => x 
0.00/0.18	    !fac3220(x, !facdot(x, y)) => y 
0.00/0.18	    !fac3220(!facdiv(x, y), x) => y 
0.00/0.18	    !facdiv(x, x) => e 
0.00/0.18	    !facdiv(x, e) => x 
0.00/0.18	    !facdiv(!facdot(x, y), y) => x 
0.00/0.18	    !facdiv(x, !fac3220(y, x)) => y 
0.00/0.18	    !facdot(e, x) => x 
0.00/0.18	    !facdot(x, e) => x 
0.00/0.18	    !facdot(x, !fac3220(x, y)) => y 
0.00/0.18	    !facdot(!facdiv(x, y), y) => x 
0.00/0.18	    map(f, nil) => nil 
0.00/0.18	    map(f, cons(x, y)) => cons(f x, map(f, y)) 
0.00/0.18	    filter(f, nil) => nil 
0.00/0.18	    filter(f, cons(x, y)) => filter2(f x, f, x, y) 
0.00/0.18	    filter2(true, f, x, y) => cons(x, filter(f, y)) 
0.00/0.18	    filter2(false, f, x, y) => filter(f, y) 
0.00/0.18	
0.00/0.18	This AFS is converted to an AFSM simply by replacing all free variables by meta-variables (with arity 0).
0.00/0.18	
0.00/0.18	We use rule removal, following [Kop12, Theorem 2.23].
0.00/0.18	
0.00/0.18	This gives the following requirements (possibly using Theorems 2.25 and 2.26 in [Kop12]):
0.00/0.18	
0.00/0.18	  !fac3220(X, X) >? e 
0.00/0.18	  !fac3220(e, X) >? X 
0.00/0.18	  !fac3220(X, !facdot(X, Y)) >? Y 
0.00/0.18	  !fac3220(!facdiv(X, Y), X) >? Y 
0.00/0.18	  !facdiv(X, X) >? e 
0.00/0.18	  !facdiv(X, e) >? X 
0.00/0.18	  !facdiv(!facdot(X, Y), Y) >? X 
0.00/0.18	  !facdiv(X, !fac3220(Y, X)) >? Y 
0.00/0.18	  !facdot(e, X) >? X 
0.00/0.18	  !facdot(X, e) >? X 
0.00/0.18	  !facdot(X, !fac3220(X, Y)) >? Y 
0.00/0.18	  !facdot(!facdiv(X, Y), Y) >? X 
0.00/0.18	  map(F, nil) >? nil 
0.00/0.18	  map(F, cons(X, Y)) >? cons(F X, map(F, Y)) 
0.00/0.18	  filter(F, nil) >? nil 
0.00/0.18	  filter(F, cons(X, Y)) >? filter2(F X, F, X, Y) 
0.00/0.18	  filter2(true, F, X, Y) >? cons(X, filter(F, Y)) 
0.00/0.18	  filter2(false, F, X, Y) >? filter(F, Y) 
0.00/0.18	
0.00/0.18	We orient these requirements with a polynomial interpretation in the natural numbers.
0.00/0.18	
0.00/0.18	The following interpretation satisfies the requirements:
0.00/0.18	
0.00/0.18	  !fac3220 = \y0y1.3 + y0 + 2y1 
0.00/0.18	  !facdiv = \y0y1.3 + y0 + y1 
0.00/0.18	  !facdot = \y0y1.3 + y0 + 2y1 
0.00/0.18	  cons = \y0y1.3 + y0 + y1 
0.00/0.18	  e = 0 
0.00/0.18	  false = 3 
0.00/0.18	  filter = \G0y1.1 + 3y1 + 2G0(0) + 3y1G0(y1) 
0.00/0.18	  filter2 = \y0G1y2y3.y2 + 2y0 + 3y3 + G1(0) + G1(y2) + 3y3G1(y3) 
0.00/0.18	  map = \G0y1.3y1 + G0(y1) + 2y1G0(y1) 
0.00/0.18	  nil = 0 
0.00/0.18	  true = 3 
0.00/0.18	
0.00/0.18	Using this interpretation, the requirements translate to:
0.00/0.18	
0.00/0.18	  [[!fac3220(_x0, _x0)]] = 3 + 3x0 > 0 = [[e]] 
0.00/0.18	  [[!fac3220(e, _x0)]] = 3 + 2x0 > x0 = [[_x0]] 
0.00/0.18	  [[!fac3220(_x0, !facdot(_x0, _x1))]] = 9 + 3x0 + 4x1 > x1 = [[_x1]] 
0.00/0.18	  [[!fac3220(!facdiv(_x0, _x1), _x0)]] = 6 + x1 + 3x0 > x1 = [[_x1]] 
0.00/0.18	  [[!facdiv(_x0, _x0)]] = 3 + 2x0 > 0 = [[e]] 
0.00/0.18	  [[!facdiv(_x0, e)]] = 3 + x0 > x0 = [[_x0]] 
0.00/0.18	  [[!facdiv(!facdot(_x0, _x1), _x1)]] = 6 + x0 + 3x1 > x0 = [[_x0]] 
0.00/0.18	  [[!facdiv(_x0, !fac3220(_x1, _x0))]] = 6 + x1 + 3x0 > x1 = [[_x1]] 
0.00/0.18	  [[!facdot(e, _x0)]] = 3 + 2x0 > x0 = [[_x0]] 
0.00/0.18	  [[!facdot(_x0, e)]] = 3 + x0 > x0 = [[_x0]] 
0.00/0.18	  [[!facdot(_x0, !fac3220(_x0, _x1))]] = 9 + 3x0 + 4x1 > x1 = [[_x1]] 
0.00/0.18	  [[!facdot(!facdiv(_x0, _x1), _x1)]] = 6 + x0 + 3x1 > x0 = [[_x0]] 
0.00/0.18	  [[map(_F0, nil)]] = F0(0) >= 0 = [[nil]] 
0.00/0.18	  [[map(_F0, cons(_x1, _x2))]] = 9 + 3x1 + 3x2 + 2x1F0(3 + x1 + x2) + 2x2F0(3 + x1 + x2) + 7F0(3 + x1 + x2) > 3 + x1 + 3x2 + F0(x1) + F0(x2) + 2x2F0(x2) = [[cons(_F0 _x1, map(_F0, _x2))]] 
0.00/0.18	  [[filter(_F0, nil)]] = 1 + 2F0(0) > 0 = [[nil]] 
0.00/0.18	  [[filter(_F0, cons(_x1, _x2))]] = 10 + 3x1 + 3x2 + 2F0(0) + 3x1F0(3 + x1 + x2) + 3x2F0(3 + x1 + x2) + 9F0(3 + x1 + x2) > 3x1 + 3x2 + F0(0) + 3x2F0(x2) + 3F0(x1) = [[filter2(_F0 _x1, _F0, _x1, _x2)]] 
0.00/0.18	  [[filter2(true, _F0, _x1, _x2)]] = 6 + x1 + 3x2 + F0(0) + F0(x1) + 3x2F0(x2) > 4 + x1 + 3x2 + 2F0(0) + 3x2F0(x2) = [[cons(_x1, filter(_F0, _x2))]] 
0.00/0.18	  [[filter2(false, _F0, _x1, _x2)]] = 6 + x1 + 3x2 + F0(0) + F0(x1) + 3x2F0(x2) > 1 + 3x2 + 2F0(0) + 3x2F0(x2) = [[filter(_F0, _x2)]] 
0.00/0.18	
0.00/0.18	We can thus remove the following rules:
0.00/0.18	
0.00/0.18	  !fac3220(X, X) => e 
0.00/0.18	  !fac3220(e, X) => X 
0.00/0.18	  !fac3220(X, !facdot(X, Y)) => Y 
0.00/0.18	  !fac3220(!facdiv(X, Y), X) => Y 
0.00/0.18	  !facdiv(X, X) => e 
0.00/0.18	  !facdiv(X, e) => X 
0.00/0.18	  !facdiv(!facdot(X, Y), Y) => X 
0.00/0.18	  !facdiv(X, !fac3220(Y, X)) => Y 
0.00/0.18	  !facdot(e, X) => X 
0.00/0.18	  !facdot(X, e) => X 
0.00/0.18	  !facdot(X, !fac3220(X, Y)) => Y 
0.00/0.18	  !facdot(!facdiv(X, Y), Y) => X 
0.00/0.18	  map(F, cons(X, Y)) => cons(F X, map(F, Y)) 
0.00/0.18	  filter(F, nil) => nil 
0.00/0.18	  filter(F, cons(X, Y)) => filter2(F X, F, X, Y) 
0.00/0.18	  filter2(true, F, X, Y) => cons(X, filter(F, Y)) 
0.00/0.18	  filter2(false, F, X, Y) => filter(F, Y) 
0.00/0.18	
0.00/0.18	We use rule removal, following [Kop12, Theorem 2.23].
0.00/0.18	
0.00/0.18	This gives the following requirements (possibly using Theorems 2.25 and 2.26 in [Kop12]):
0.00/0.18	
0.00/0.18	  map(F, nil) >? nil 
0.00/0.18	
0.00/0.18	We orient these requirements with a polynomial interpretation in the natural numbers.
0.00/0.18	
0.00/0.18	The following interpretation satisfies the requirements:
0.00/0.18	
0.00/0.18	  map = \G0y1.3 + 3y1 + G0(0) 
0.00/0.18	  nil = 0 
0.00/0.18	
0.00/0.18	Using this interpretation, the requirements translate to:
0.00/0.18	
0.00/0.18	  [[map(_F0, nil)]] = 3 + F0(0) > 0 = [[nil]] 
0.00/0.18	
0.00/0.18	We can thus remove the following rules:
0.00/0.18	
0.00/0.18	  map(F, nil) => nil 
0.00/0.18	
0.00/0.18	All rules were succesfully removed.  Thus, termination of the original system has been reduced to termination of the beta-rule, which is well-known to hold.
0.00/0.18	
0.00/0.18	
0.00/0.18	+++ Citations +++
0.00/0.18	
0.00/0.18	[Kop12]  C. Kop.  Higher Order Termination.  PhD Thesis, 2012.
0.00/0.18	EOF