We consider the system fuhkop12rta1. Alphabet: app : [list * list] --> list cons : [nat * list] --> list hshuffle : [nat -> nat * list] --> list nil : [] --> list reverse : [list] --> list Rules: app(nil, x) => x app(cons(x, y), z) => cons(x, app(y, z)) reverse(nil) => nil reverse(cons(x, y)) => app(reverse(y), cons(x, nil)) hshuffle(f, nil) => nil hshuffle(f, cons(x, y)) => cons(f x, hshuffle(f, reverse(y))) This AFS is converted to an AFSM simply by replacing all free variables by meta-variables (with arity 0). We use the dependency pair framework as described in [Kop12, Ch. 6/7], with dynamic dependency pairs. After applying [Kop12, Thm. 7.22] to denote collapsing dependency pairs in an extended form, we thus obtain the following dependency pair problem (P_0, R_0, minimal, formative): Dependency Pairs P_0: 0] app#(cons(X, Y), Z) =#> app#(Y, Z) 1] reverse#(cons(X, Y)) =#> app#(reverse(Y), cons(X, nil)) 2] reverse#(cons(X, Y)) =#> reverse#(Y) 3] hshuffle#(F, cons(X, Y)) =#> F(X) 4] hshuffle#(F, cons(X, Y)) =#> hshuffle#(F, reverse(Y)) 5] hshuffle#(F, cons(X, Y)) =#> reverse#(Y) Rules R_0: app(nil, X) => X app(cons(X, Y), Z) => cons(X, app(Y, Z)) reverse(nil) => nil reverse(cons(X, Y)) => app(reverse(Y), cons(X, nil)) hshuffle(F, nil) => nil hshuffle(F, cons(X, Y)) => cons(F X, hshuffle(F, reverse(Y))) Thus, the original system is terminating if (P_0, R_0, minimal, formative) is finite. We consider the dependency pair problem (P_0, R_0, minimal, formative). We place the elements of P in a dependency graph approximation G (see e.g. [Kop12, Thm. 7.27, 7.29], as follows: * 0 : 0 * 1 : 0 * 2 : 1, 2 * 3 : 0, 1, 2, 3, 4, 5 * 4 : 3, 4, 5 * 5 : 1, 2 This graph has the following strongly connected components: P_1: app#(cons(X, Y), Z) =#> app#(Y, Z) P_2: reverse#(cons(X, Y)) =#> reverse#(Y) P_3: hshuffle#(F, cons(X, Y)) =#> F(X) hshuffle#(F, cons(X, Y)) =#> hshuffle#(F, reverse(Y)) By [Kop12, Thm. 7.31], we may replace any dependency pair problem (P_0, R_0, m, f) by (P_1, R_0, m, f), (P_2, R_0, m, f) and (P_3, R_0, m, f). Thus, the original system is terminating if each of (P_1, R_0, minimal, formative), (P_2, R_0, minimal, formative) and (P_3, R_0, minimal, formative) is finite. We consider the dependency pair problem (P_3, R_0, minimal, formative). We will use the reduction pair processor [Kop12, Thm. 7.16]. As the system is abstraction-simple and the formative flag is set, it suffices to find a tagged reduction pair [Kop12, Def. 6.70]. Thus, we must orient: hshuffle#(F, cons(X, Y)) >? F(X) hshuffle#(F, cons(X, Y)) >? hshuffle#(F, reverse(Y)) app(nil, X) >= X app(cons(X, Y), Z) >= cons(X, app(Y, Z)) reverse(nil) >= nil reverse(cons(X, Y)) >= app(reverse(Y), cons(X, nil)) hshuffle(F, nil) >= nil hshuffle(F, cons(X, Y)) >= cons(F X, hshuffle(F, reverse(Y))) We orient these requirements with a polynomial interpretation in the natural numbers. The following interpretation satisfies the requirements: app = \y0y1.y0 + y1 cons = \y0y1.1 + y0 + y1 hshuffle = \G0y1.y1 + 2y1G0(y1) hshuffle# = \G0y1.3 + 2y1 + y1G0(y1) nil = 0 reverse = \y0.y0 Using this interpretation, the requirements translate to: [[hshuffle#(_F0, cons(_x1, _x2))]] = 5 + 2x1 + 2x2 + F0(1 + x1 + x2) + x1F0(1 + x1 + x2) + x2F0(1 + x1 + x2) > F0(x1) = [[_F0(_x1)]] [[hshuffle#(_F0, cons(_x1, _x2))]] = 5 + 2x1 + 2x2 + F0(1 + x1 + x2) + x1F0(1 + x1 + x2) + x2F0(1 + x1 + x2) > 3 + 2x2 + x2F0(x2) = [[hshuffle#(_F0, reverse(_x2))]] [[app(nil, _x0)]] = x0 >= x0 = [[_x0]] [[app(cons(_x0, _x1), _x2)]] = 1 + x0 + x1 + x2 >= 1 + x0 + x1 + x2 = [[cons(_x0, app(_x1, _x2))]] [[reverse(nil)]] = 0 >= 0 = [[nil]] [[reverse(cons(_x0, _x1))]] = 1 + x0 + x1 >= 1 + x0 + x1 = [[app(reverse(_x1), cons(_x0, nil))]] [[hshuffle(_F0, nil)]] = 0 >= 0 = [[nil]] [[hshuffle(_F0, cons(_x1, _x2))]] = 1 + x1 + x2 + 2x1F0(1 + x1 + x2) + 2x2F0(1 + x1 + x2) + 2F0(1 + x1 + x2) >= 1 + x2 + 2x2F0(x2) + max(x1, F0(x1)) = [[cons(_F0 _x1, hshuffle(_F0, reverse(_x2)))]] By the observations in [Kop12, Sec. 6.6], this reduction pair suffices; we may thus replace a dependency pair problem (P_3, R_0) by ({}, R_0). By the empty set processor [Kop12, Thm. 7.15] this problem may be immediately removed. Thus, the original system is terminating if each of (P_1, R_0, minimal, formative) and (P_2, R_0, minimal, formative) is finite. We consider the dependency pair problem (P_2, R_0, minimal, formative). We apply the subterm criterion with the following projection function: nu(reverse#) = 1 Thus, we can orient the dependency pairs as follows: nu(reverse#(cons(X, Y))) = cons(X, Y) |> Y = nu(reverse#(Y)) By [Kop12, Thm. 7.35], we may replace a dependency pair problem (P_2, R_0, minimal, f) by ({}, R_0, minimal, f). By the empty set processor [Kop12, Thm. 7.15] this problem may be immediately removed. Thus, the original system is terminating if (P_1, R_0, minimal, formative) is finite. We consider the dependency pair problem (P_1, R_0, minimal, formative). We apply the subterm criterion with the following projection function: nu(app#) = 1 Thus, we can orient the dependency pairs as follows: nu(app#(cons(X, Y), Z)) = cons(X, Y) |> Y = nu(app#(Y, Z)) By [Kop12, Thm. 7.35], we may replace a dependency pair problem (P_1, R_0, minimal, f) by ({}, R_0, minimal, f). By the empty set processor [Kop12, Thm. 7.15] this problem may be immediately removed. As all dependency pair problems were succesfully simplified with sound (and complete) processors until nothing remained, we conclude termination. +++ Citations +++ [Kop12] C. Kop. Higher Order Termination. PhD Thesis, 2012.