anthem/tests/TestCompletion.cpp
Patrick Lühne 6d7b91c391
Add new simplification rule
This adds the rule “(F <-> (F and G)) === (F -> G)” to the
simplification rule tableau.
2018-04-10 22:34:47 +02:00

180 lines
3.6 KiB
C++

#include <catch.hpp>
#include <sstream>
#include <anthem/AST.h>
#include <anthem/Context.h>
#include <anthem/Translation.h>
////////////////////////////////////////////////////////////////////////////////////////////////////
TEST_CASE("[completion] Rules are completed", "[completion]")
{
std::stringstream input;
std::stringstream output;
std::stringstream errors;
anthem::output::Logger logger(output, errors);
anthem::Context context(std::move(logger));
context.performSimplification = true;
context.performCompletion = true;
SECTION("predicate in single rule head")
{
input << "p :- q.";
anthem::translate("input", input, context);
CHECK(output.str() ==
"(p <-> q)\n"
"not q\n");
}
SECTION("predicate in multiple rule heads")
{
input <<
"p :- q.\n"
"p :- r.\n"
"p :- s.";
anthem::translate("input", input, context);
CHECK(output.str() ==
"(p <-> (q or r or s))\n"
"not q\n"
"not r\n"
"not s\n");
}
SECTION("multiple predicates are correctly separated")
{
input <<
"p :- s.\n"
"q :- t.\n"
"p :- q.\n"
"r :- t.\n"
"q :- r.";
anthem::translate("input", input, context);
CHECK(output.str() ==
"(p <-> (s or q))\n"
"(q <-> (t or r))\n"
"(r <-> t)\n"
"not s\n"
"not t\n");
}
SECTION("integrity constraints")
{
input <<
":- q.\n"
":- r(5).\n"
":- s(N).\n"
"#false :- t.\n"
"#false :- u(5).";
anthem::translate("input", input, context);
CHECK(output.str() ==
"not q\n"
"forall V1 not r(V1)\n"
"forall V2 not s(V2)\n"
"not t\n"
"forall V3 not u(V3)\n"
"not q\n"
"not r(5)\n"
"forall U1 not s(U1)\n"
"not t\n"
"not u(5)\n");
}
SECTION("Booleans")
{
input <<
"#true :- #true.\n"
"#true :- #false.\n"
"#false :- #true.\n"
"#false :- #false.\n";
anthem::translate("input", input, context);
CHECK(output.str() ==
"not #true\n"
"not #false\n");
}
SECTION("facts")
{
input <<
"q.\n"
"r.\n"
"s :- #true.\n"
"t :- #true.";
anthem::translate("input", input, context);
CHECK(output.str() ==
"q\n"
"r\n"
"s\n"
"t\n");
}
SECTION("nested arguments")
{
input <<
"f(f(f(f(f(X))))) :- f(X).\n"
"f(1..5).";
anthem::translate("input", input, context);
CHECK(output.str() ==
"forall V1 (f(V1) <-> (exists U1 (V1 = f(f(f(f(U1)))) and f(U1)) or V1 in 1..5))\n");
}
SECTION("useless implications")
{
input <<
"#true :- p, q(N), t(1, 2).\n"
"#true.\n"
"v :- #false.";
anthem::translate("input", input, context);
CHECK(output.str() ==
"not p\n"
"forall V1 not q(V1)\n"
"forall V2, V3 not t(V2, V3)\n"
"not v\n");
}
SECTION("Schur number example")
{
input <<
"{in(1..n, 1..r)}.\n"
"covered(I) :- in(I, S).\n"
":- I = 1..n, not covered(I).\n"
":- in(I, S), in(J, S), in(I + J, S).";
anthem::translate("input", input, context);
CHECK(output.str() ==
"forall V1 (covered(V1) <-> exists U1 in(V1, U1))\n"
"forall V2, V3 (in(V2, V3) -> (V2 in 1..n and V3 in 1..r))\n"
"forall U2 not (U2 in 1..n and not covered(U2))\n"
"forall U3, U4, U5 not (in(U3, U4) and in(U5, U4) and exists X1 (X1 in (U3 + U5) and in(X1, U4)))\n");
}
SECTION("binary operations with multiple variables")
{
input << "a(X, Y) :- b(c(X + Y), d(1 + Y)).";
anthem::translate("input", input, context);
CHECK(output.str() ==
"forall V1, V2 (a(V1, V2) <-> b(c((V1 + V2)), d((1 + V2))))\n"
"forall V3, V4 not b(V3, V4)\n");
}
SECTION("predicate with more than one argument")
{
input << "p(X, Y, Z).";
anthem::translate("input", input, context);
// TODO: simplify further
CHECK(output.str() ==
"forall V1, V2, V3 (p(V1, V2, V3) <-> #true)\n");
}
}