/export/starexec/sandbox2/solver/bin/starexec_run_HigherOrder /export/starexec/sandbox2/benchmark/theBenchmark.xml /export/starexec/sandbox2/output/output_files -------------------------------------------------------------------------------- YES We consider the system theBenchmark. Alphabet: dom : [N * N * N] --> N eval : [N * N] --> N fun : [N -> N * N * N] --> N o : [] --> N s : [N] --> N Rules: eval(fun(f, x, y), z) => f dom(x, y, z) dom(s(x), s(y), s(z)) => s(dom(x, y, z)) dom(o, s(x), s(y)) => s(dom(o, x, y)) dom(x, y, o) => x dom(o, o, x) => o This AFS is converted to an AFSM simply by replacing all free variables by meta-variables (with arity 0). We observe that the rules contain a first-order subset: dom(s(X), s(Y), s(Z)) => s(dom(X, Y, Z)) dom(o, s(X), s(Y)) => s(dom(o, X, Y)) dom(X, Y, o) => X dom(o, o, X) => o Moreover, the system is finitely branching. Thus, by [Kop12, Thm. 7.55], we may omit all first-order dependency pairs from the dependency pair problem (DP(R), R) if this first-order part is Ce-terminating when seen as a many-sorted first-order TRS. According to the external first-order termination prover, this system is indeed Ce-terminating: || proof of resources/system.trs || # AProVE Commit ID: d84c10301d352dfd14de2104819581f4682260f5 fuhs 20130616 || || || Termination w.r.t. Q of the given QTRS could be proven: || || (0) QTRS || (1) QTRSRRRProof [EQUIVALENT] || (2) QTRS || (3) RisEmptyProof [EQUIVALENT] || (4) YES || || || ---------------------------------------- || || (0) || Obligation: || Q restricted rewrite system: || The TRS R consists of the following rules: || || dom(s(%X), s(%Y), s(%Z)) -> s(dom(%X, %Y, %Z)) || dom(o, s(%X), s(%Y)) -> s(dom(o, %X, %Y)) || dom(%X, %Y, o) -> %X || dom(o, o, %X) -> o || ~PAIR(%X, %Y) -> %X || ~PAIR(%X, %Y) -> %Y || || Q is empty. || || ---------------------------------------- || || (1) QTRSRRRProof (EQUIVALENT) || Used ordering: || Polynomial interpretation [POLO]: || || POL(dom(x_1, x_2, x_3)) = 1 + 2*x_1 + 2*x_2 + x_3 || POL(o) = 2 || POL(s(x_1)) = 1 + x_1 || POL(~PAIR(x_1, x_2)) = 2 + x_1 + x_2 || With this ordering the following rules can be removed by the rule removal processor [LPAR04] because they are oriented strictly: || || dom(s(%X), s(%Y), s(%Z)) -> s(dom(%X, %Y, %Z)) || dom(o, s(%X), s(%Y)) -> s(dom(o, %X, %Y)) || dom(%X, %Y, o) -> %X || dom(o, o, %X) -> o || ~PAIR(%X, %Y) -> %X || ~PAIR(%X, %Y) -> %Y || || || || || ---------------------------------------- || || (2) || Obligation: || Q restricted rewrite system: || R is empty. || Q is empty. || || ---------------------------------------- || || (3) RisEmptyProof (EQUIVALENT) || The TRS R is empty. Hence, termination is trivially proven. || ---------------------------------------- || || (4) || YES || 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] eval#(fun(F, X, Y), Z) =#> F(dom(X, Y, Z)) 1] eval#(fun(F, X, Y), Z) =#> dom#(X, Y, Z) Rules R_0: eval(fun(F, X, Y), Z) => F dom(X, Y, Z) dom(s(X), s(Y), s(Z)) => s(dom(X, Y, Z)) dom(o, s(X), s(Y)) => s(dom(o, X, Y)) dom(X, Y, o) => X dom(o, o, X) => o 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 * 1 : This graph has the following strongly connected components: P_1: eval#(fun(F, X, Y), Z) =#> F(dom(X, Y, Z)) 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). 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). The formative rules of (P_1, R_0) are R_1 ::= eval(fun(F, X, Y), Z) => F dom(X, Y, Z) dom(X, Y, o) => X dom(o, o, X) => o By [Kop12, Thm. 7.17], we may replace the dependency pair problem (P_1, R_0, minimal, formative) by (P_1, R_1, minimal, formative). Thus, the original system is terminating if (P_1, R_1, minimal, formative) is finite. We consider the dependency pair problem (P_1, R_1, 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: eval#(fun(F, X, Y), Z) >? F(dom(X, Y, Z)) eval(fun(F, X, Y), Z) >= F dom(X, Y, Z) dom(X, Y, o) >= X dom(o, o, X) >= o We orient these requirements with a polynomial interpretation in the natural numbers. The following interpretation satisfies the requirements: dom = \y0y1y2.y0 eval = \y0y1.3 + 3y0 eval# = \y0y1.3 + y0 fun = \G0y1y2.3 + y1 + G0(y1) o = 0 Using this interpretation, the requirements translate to: [[eval#(fun(_F0, _x1, _x2), _x3)]] = 6 + x1 + F0(x1) > F0(x1) = [[_F0(dom(_x1, _x2, _x3))]] [[eval(fun(_F0, _x1, _x2), _x3)]] = 12 + 3x1 + 3F0(x1) >= max(x1, F0(x1)) = [[_F0 dom(_x1, _x2, _x3)]] [[dom(_x0, _x1, o)]] = x0 >= x0 = [[_x0]] [[dom(o, o, _x0)]] = 0 >= 0 = [[o]] By the observations in [Kop12, Sec. 6.6], this reduction pair suffices; we may thus replace a dependency pair problem (P_1, R_1) by ({}, R_1). 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.