@Test
public void testPathRecursiveUnpacking() {
// use an encoder where it is possible to store 2 weights per edge
FlagEncoder encoder = new Bike2WeightFlagEncoder();
ShortestWeighting weighting = new ShortestWeighting(encoder);
EncodingManager em = new EncodingManager(encoder);
GraphHopperStorage ghStorage =
createGHStorage(em, Collections.<Weighting>singleton(weighting), false);
CHGraphImpl g2 = (CHGraphImpl) ghStorage.getGraph(CHGraph.class, weighting);
g2.edge(0, 1, 1, true);
EdgeIteratorState iter1_1 = g2.edge(0, 2, 1.4, false);
EdgeIteratorState iter1_2 = g2.edge(2, 5, 1.4, false);
g2.edge(1, 2, 1, true);
g2.edge(1, 3, 3, true);
g2.edge(2, 3, 1, true);
g2.edge(4, 3, 1, true);
g2.edge(2, 5, 1.4, true);
g2.edge(3, 5, 1, true);
g2.edge(5, 6, 1, true);
g2.edge(4, 6, 1, true);
g2.edge(6, 7, 1, true);
EdgeIteratorState iter2_2 = g2.edge(5, 7);
iter2_2.setDistance(1.4).setFlags(encoder.setProperties(10, true, false));
ghStorage.freeze();
// simulate preparation
CHEdgeIteratorState iter2_1 = g2.shortcut(0, 5);
iter2_1.setDistance(2.8).setFlags(encoder.setProperties(10, true, false));
iter2_1.setSkippedEdges(iter1_1.getEdge(), iter1_2.getEdge());
CHEdgeIteratorState tmp = g2.shortcut(0, 7);
tmp.setDistance(4.2).setFlags(encoder.setProperties(10, true, false));
tmp.setSkippedEdges(iter2_1.getEdge(), iter2_2.getEdge());
g2.setLevel(1, 0);
g2.setLevel(3, 1);
g2.setLevel(4, 2);
g2.setLevel(6, 3);
g2.setLevel(2, 4);
g2.setLevel(5, 5);
g2.setLevel(7, 6);
g2.setLevel(0, 7);
AlgorithmOptions opts = new AlgorithmOptions(AlgorithmOptions.DIJKSTRA_BI, encoder, weighting);
Path p =
new PrepareContractionHierarchies(
new GHDirectory("", DAType.RAM_INT),
ghStorage,
g2,
encoder,
weighting,
TraversalMode.NODE_BASED)
.createAlgo(g2, opts)
.calcPath(0, 7);
assertEquals(Helper.createTList(0, 2, 5, 7), p.calcNodes());
assertEquals(1064, p.getTime());
assertEquals(4.2, p.getDistance(), 1e-5);
}
@Test
public void testTurnFlagEncoding_withCosts() {
FlagEncoder tmpEncoder = new CarFlagEncoder(8, 5, 127);
EncodingManager em = new EncodingManager(tmpEncoder);
long flags_r0 = tmpEncoder.getTurnFlags(true, 0);
long flags_0 = tmpEncoder.getTurnFlags(false, 0);
assertTrue(Double.isInfinite(tmpEncoder.getTurnCost(flags_r0)));
assertEquals(0, tmpEncoder.getTurnCost(flags_0), 1e-1);
assertTrue(tmpEncoder.isTurnRestricted(flags_r0));
assertFalse(tmpEncoder.isTurnRestricted(flags_0));
long flags_r20 = tmpEncoder.getTurnFlags(true, 0);
long flags_20 = tmpEncoder.getTurnFlags(false, 20);
assertTrue(Double.isInfinite(tmpEncoder.getTurnCost(flags_r20)));
assertEquals(20, tmpEncoder.getTurnCost(flags_20), 1e-1);
assertTrue(tmpEncoder.isTurnRestricted(flags_r20));
assertFalse(tmpEncoder.isTurnRestricted(flags_20));
long flags_r220 = tmpEncoder.getTurnFlags(true, 0);
try {
tmpEncoder.getTurnFlags(false, 220);
assertTrue(false);
} catch (Exception ex) {
}
assertTrue(Double.isInfinite(tmpEncoder.getTurnCost(flags_r220)));
assertTrue(tmpEncoder.isTurnRestricted(flags_r220));
}
@Test
public void testTurnFlagEncoding_noCosts() {
FlagEncoder tmpEnc = new CarFlagEncoder(8, 5, 0);
EncodingManager em = new EncodingManager(tmpEnc);
long flags_r0 = tmpEnc.getTurnFlags(true, 0);
long flags_0 = tmpEnc.getTurnFlags(false, 0);
long flags_r20 = tmpEnc.getTurnFlags(true, 0);
long flags_20 = tmpEnc.getTurnFlags(false, 20);
assertEquals(0, tmpEnc.getTurnCost(flags_r0), 1e-1);
assertEquals(0, tmpEnc.getTurnCost(flags_0), 1e-1);
assertEquals(0, tmpEnc.getTurnCost(flags_r20), 1e-1);
assertEquals(0, tmpEnc.getTurnCost(flags_20), 1e-1);
assertFalse(tmpEnc.isTurnRestricted(flags_r0));
assertFalse(tmpEnc.isTurnRestricted(flags_0));
assertFalse(tmpEnc.isTurnRestricted(flags_r20));
assertFalse(tmpEnc.isTurnRestricted(flags_20));
}
