public static void HaveEqualEquatorEdgePermutation(CubieCube expected, CubieCube actual)
{
CubingAssert.HasFourEquatorEdges(expected);
CubingAssert.HasFourEquatorEdges(actual);
IEnumerator <(Edge edge, int index)> enumerator1 = expected.EdgePermutation.Select((edge, index) => (edge, index)).GetEnumerator();
IEnumerator <(Edge edge, int index)> enumerator2 = actual.EdgePermutation.Select((edge, index) => (edge, index)).GetEnumerator();
for (int equatorEdge = 0; equatorEdge < Constants.NumEquatorEdges; equatorEdge++)
{
while (enumerator1.MoveNext() && enumerator1.Current.edge < Edge.FR)
{
;
}
while (enumerator2.MoveNext() && enumerator2.Current.edge < Edge.FR)
{
;
}
if (enumerator1.Current.edge != enumerator2.Current.edge)
{
throw new AssertFailedException("The two cubes do not have the same equator edge permutation: " +
enumerator1.Current.edge + " at index " + enumerator1.Current.index + " of " + nameof(expected) + " is not equal to " +
enumerator2.Current.edge + " at index " + enumerator2.Current.index + " of " + nameof(actual) + ".");
}
}
}
public void EquatorPermutationCoordTest() //Tests GetEquatorPermutationCoord, SetEquatorPermutationCoord
{
Random random = new Random(7777777);
int length = 50;
int repetitions = 50;
//if solved permutation corresponds to the coordinate 0
//SetEquatorPermutationCoord()
CubieCube expected = CubieCube.CreateSolved();
CubieCube result = CubieCube.FromAlg(Alg.FromRandomMoves(length, random));
Coordinates.SetEquatorOrder(result, 0);
CubingAssert.HaveEqualEquatorEdgePermutation(expected, result);
expected = CubieCube.FromAlg(Alg.FromString("R2 L2"));
result = CubieCube.FromAlg(Alg.FromRandomMoves(length, random));
Coordinates.SetEquatorOrder(result, Coordinates.NumEquatorOrders - 1);
//GetEquatorPermutationCoord()
result = CubieCube.CreateSolved();
Assert.AreEqual(0, Coordinates.GetEquatorOrder(result));
result.ApplyAlg(Alg.FromString("F' R' B' D' L2"));
Assert.AreEqual(0, Coordinates.GetEquatorOrder(result));
//apply B1
int expectedCoord = 17;
CubieCube cube = CubieCube.CreateSolved();
cube.ApplyMove(Move.B1);
int resultCoord = Coordinates.GetEquatorOrder(cube);
Assert.AreEqual(expectedCoord, resultCoord);
//apply B2
expectedCoord = 6;
cube = CubieCube.CreateSolved();
cube.ApplyMove(Move.B2);
resultCoord = Coordinates.GetEquatorOrder(cube);
Assert.AreEqual(expectedCoord, resultCoord);
//if applying GetEquatorPermutationCoord() and SetEquatorPermutationCoord() results in the same array as at the beginning
for (int repetition = 0; repetition < repetitions; repetition++)
{
expected = CubieCube.FromAlg(Alg.FromRandomMoves(length, random));
result = CubieCube.CreateSolved();
int coord = Coordinates.GetEquatorOrder(expected);
Coordinates.SetEquatorOrder(result, coord);
CubingAssert.HaveEqualEquatorEdgePermutation(expected, result);
}
//exceptions
Assert.ThrowsException <ArgumentNullException>(() => Coordinates.GetEquatorOrder(null));
Assert.ThrowsException <ArgumentNullException>(() => Coordinates.SetEquatorOrder(null, 0));
Assert.ThrowsException <ArgumentOutOfRangeException>(() => Coordinates.SetEquatorOrder(CubieCube.CreateSolved(), -1));
Assert.ThrowsException <ArgumentOutOfRangeException>(() => Coordinates.SetEquatorOrder(CubieCube.CreateSolved(), Coordinates.NumEquatorOrders));
}
