#include #include #include #include //////////////////////////////////////////////////////////////////////////////////////////////////// TEST_CASE("[translation] Rules are translated correctly", "[translation]") { std::stringstream input; std::stringstream output; std::stringstream errors; anthem::output::Logger logger(output, errors); anthem::Context context = {logger, {}}; context.simplify = false; context.complete = false; SECTION("simple example 1") { input << "p(1..5)."; anthem::translate("input", input, context); REQUIRE(output.str() == "(V1 in 1..5 -> p(V1))\n"); } SECTION("simple example 2") { input << "p(N) :- N = 1..5."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in N and exists X1, X2 (X1 in N and X2 in 1..5 and X1 = X2)) -> p(V1))\n"); } SECTION("simple example 3") { input << "p(N + 1) :- q(N)."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in (N + 1) and exists X1 (X1 in N and q(X1))) -> p(V1))\n"); } SECTION("n-ary head") { input << "p(N, 1, 2) :- N = 1..5."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in N and V2 in 1 and V3 in 2 and exists X1, X2 (X1 in N and X2 in 1..5 and X1 = X2)) -> p(V1, V2, V3))\n"); } SECTION("disjunctive head") { // TODO: check why order of disjunctive literals is inverted input << "q(3, N); p(N, 1, 2) :- N = 1..5."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in N and V2 in 1 and V3 in 2 and V4 in 3 and V5 in N and exists X1, X2 (X1 in N and X2 in 1..5 and X1 = X2)) -> (p(V1, V2, V3) or q(V4, V5)))\n"); } SECTION("disjunctive head (alternative syntax)") { // TODO: check why order of disjunctive literals is inverted input << "q(3, N), p(N, 1, 2) :- N = 1..5."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in N and V2 in 1 and V3 in 2 and V4 in 3 and V5 in N and exists X1, X2 (X1 in N and X2 in 1..5 and X1 = X2)) -> (p(V1, V2, V3) or q(V4, V5)))\n"); } SECTION("escaping conflicting variable names") { input << "p(X1, V1, A1) :- q(X1), q(V1), q(A1)."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in _X1 and V2 in _V1 and V3 in _A1 and exists X1 (X1 in _X1 and q(X1)) and exists X2 (X2 in _V1 and q(X2)) and exists X3 (X3 in _A1 and q(X3))) -> p(V1, V2, V3))\n"); } SECTION("fact") { input << "p(42)."; anthem::translate("input", input, context); REQUIRE(output.str() == "(V1 in 42 -> p(V1))\n"); } SECTION("0-ary fact") { input << "p."; anthem::translate("input", input, context); REQUIRE(output.str() == "(#true -> p)\n"); } SECTION("function") { input << ":- not p(I), I = 1..n."; anthem::translate("input", input, context); REQUIRE(output.str() == "((exists X1 (X1 in I and not p(X1)) and exists X2, X3 (X2 in I and X3 in 1..n and X2 = X3)) -> #false)\n"); } SECTION("disjunctive fact (no arguments)") { input << "q; p."; anthem::translate("input", input, context); REQUIRE(output.str() == "(#true -> (p or q))\n"); } SECTION("disjunctive fact (arguments)") { input << "q; p(42)."; anthem::translate("input", input, context); REQUIRE(output.str() == "(V1 in 42 -> (p(V1) or q))\n"); } SECTION("integrity constraint (no arguments)") { input << ":- p, q."; anthem::translate("input", input, context); REQUIRE(output.str() == "((p and q) -> #false)\n"); } SECTION("contradiction") { input << ":-."; anthem::translate("input", input, context); REQUIRE(output.str() == "(#true -> #false)\n"); } SECTION("integrity constraint (arguments)") { input << ":- p(42), q."; anthem::translate("input", input, context); REQUIRE(output.str() == "((exists X1 (X1 in 42 and p(X1)) and q) -> #false)\n"); } SECTION("inf/sup") { input << "p(X, #inf) :- q(X, #sup)."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in X and V2 in #inf and exists X1, X2 (X1 in X and X2 in #sup and q(X1, X2))) -> p(V1, V2))\n"); } SECTION("strings") { input << "p(X, \"foo\") :- q(X, \"bar\")."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in X and V2 in \"foo\" and exists X1, X2 (X1 in X and X2 in \"bar\" and q(X1, X2))) -> p(V1, V2))\n"); } SECTION("tuples") { input << "p(X, (1, 2, 3)) :- q(X, (4, 5))."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in X and V2 in (1, 2, 3) and exists X1, X2 (X1 in X and X2 in (4, 5) and q(X1, X2))) -> p(V1, V2))\n"); } SECTION("1-ary tuples") { input << "p(X, (1,)) :- q(X, (2,))."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in X and V2 in (1,) and exists X1, X2 (X1 in X and X2 in (2,) and q(X1, X2))) -> p(V1, V2))\n"); } SECTION("intervals") { input << "p(X, 1..10) :- q(X, 6..12)."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in X and V2 in 1..10 and exists X1, X2 (X1 in X and X2 in 6..12 and q(X1, X2))) -> p(V1, V2))\n"); } SECTION("comparisons") { input << "p(M, N, O, P) :- M < N, P != O."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in M and V2 in N and V3 in O and V4 in P and exists X1, X2 (X1 in M and X2 in N and X1 < X2) and exists X3, X4 (X3 in P and X4 in O and X3 != X4)) -> p(V1, V2, V3, V4))\n"); } SECTION("single negation") { input << "not p(X, 1) :- not q(X, 2)."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in X and V2 in 1 and exists X1, X2 (X1 in X and X2 in 2 and not q(X1, X2))) -> not p(V1, V2))\n"); } SECTION("variable numbering") { // TODO: check why order of disjunctive literals is inverted input << "f; q(A1, A2); p(A3, r(A4)); g(g(A5)) :- g(A3), f, q(A4, A1), p(A2, A5)."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in _A1 and V2 in _A2 and V3 in _A3 and V4 in r(_A4) and V5 in g(_A5)" " and exists X1 (X1 in _A3 and g(X1)) and f and exists X2, X3 (X2 in _A4 and X3 in _A1 and q(X2, X3)) and exists X4, X5 (X4 in _A2 and X5 in _A5 and p(X4, X5)))" " -> (q(V1, V2) or p(V3, V4) or g(V5) or f))\n"); } SECTION("nested functions") { input << "p(q(s(t(X1))), u(X2)) :- u(v(w(X2)), z(X1))."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in q(s(t(_X1))) and V2 in u(_X2) and exists X1, X2 (X1 in v(w(_X2)) and X2 in z(_X1) and u(X1, X2))) -> p(V1, V2))\n"); } SECTION("choice rule (simple)") { input << "{p}."; anthem::translate("input", input, context); REQUIRE(output.str() == "(p -> p)\n"); } SECTION("choice rule (two elements)") { input << "{p; q}."; anthem::translate("input", input, context); REQUIRE(output.str() == "(p -> p)\n(q -> q)\n"); } SECTION("choice rule (n-ary elements)") { input << "{p(1..3, N); q(2..4)}."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in 1..3 and V2 in N and V3 in 2..4 and p(V1, V2)) -> p(V1, V2))\n((V1 in 1..3 and V2 in N and V3 in 2..4 and q(V3)) -> q(V3))\n"); } SECTION("choice rule with body") { input << "{p(M, N); q(P)} :- s(M, N, P)."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in M and V2 in N and V3 in P and exists X1, X2, X3 (X1 in M and X2 in N and X3 in P and s(X1, X2, X3)) and p(V1, V2)) -> p(V1, V2))\n((V1 in M and V2 in N and V3 in P and exists X1, X2, X3 (X1 in M and X2 in N and X3 in P and s(X1, X2, X3)) and q(V3)) -> q(V3))\n"); } SECTION("choice rule with negation") { input << "{not p(X, 1)} :- not q(X, 2)."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in X and V2 in 1 and exists X1, X2 (X1 in X and X2 in 2 and not q(X1, X2)) and not p(V1, V2)) -> not p(V1, V2))\n"); } SECTION("choice rule with negation (two elements)") { input << "{not p(X, 1); not s} :- not q(X, 2)."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in X and V2 in 1 and exists X1, X2 (X1 in X and X2 in 2 and not q(X1, X2)) and not p(V1, V2)) -> not p(V1, V2))\n((V1 in X and V2 in 1 and exists X1, X2 (X1 in X and X2 in 2 and not q(X1, X2)) and not s) -> not s)\n"); } SECTION("anonymous variables") { input << "p(_, _) :- q(_, _)."; anthem::translate("input", input, context); REQUIRE(output.str() == "((V1 in A1 and V2 in A2 and exists X1, X2 (X1 in A3 and X2 in A4 and q(X1, X2))) -> p(V1, V2))\n"); } }