void Start()
{
_pauseEnabled = false;
AudioListener.volume = 1;
_playerScript = Player.GetComponent <PlayerMovement>();
_worldScript = World.GetComponent <PathGeneration>();
}
private void CreateMiniCentroid()
{
for (int i = 0; i < miniCentroidCount; i++)
{
GameObject clone = Instantiate(cluster.miniCentroid) as GameObject;
clone.transform.SetParent(transform);
clone.transform.position = transform.position;
MiniCentroid mini = clone.GetComponent <MiniCentroid>();
mini.SetMainCentroid(this);
miniCentroid.Add(mini);
}
path = new PathGeneration(miniCentroid);
}
void Start()
{
singleton = Singleton.Instance();
tourDirections = Canvas.GetComponentInChildren <PathGeneration>();
}
// Creates every floor tile for a given room.
// Room r - the room to have its floor tiles created
// GameObject floor - the floor tile prefab to be created. See CreateDoor for notes about this.
// float baseX, baseZ - the beginning of a maze. Position at which the 0, 0 room's floor tile will go.
// float size - the size of a floor tile. Used for positioning with relative indices in room objects.
private void CreateFloors(Room r, GameObject floor, float baseX, float baseZ, float size, HashSet <Room> inclusions)
{
IEnumerator <Vector2> enumer = r.Space.GetEnumerator();
enumer.MoveNext();
Vector2 first = enumer.Current;
float minX = first.x;
float minY = first.y;
foreach (Vector2 point in r.Space)
{
if (point.x < minX)
{
minX = point.x;
}
if (point.y < minY)
{
minY = point.y;
}
}
List <Vector2> aspTiles = new List <Vector2>();
List <Vector2> aspStartPoints = new List <Vector2>();
foreach (Vector2 point in r.Space)
{
aspTiles.Add(new Vector2(point.x - minX, point.y - minY));
}
foreach (Room adj in r.Adj)
{
if (inclusions.Contains(adj))
{
aspStartPoints.AddRange(ConnectingPoints(r, adj, minX, minY));
}
}
foreach (Vector2 pt in r.Space)
{
foreach (Connection c in connections)
{
if (c.Point.x - baseX == pt.x && c.Point.y - baseZ == pt.y)
{
float x = 0;
float y = 0;
switch (c.Dir)
{
case Direction.Up:
x = (pt.x - minX) * GridSizeOfEachTile + (GridSizeOfEachTile / 2);
y = (pt.y - minY) * GridSizeOfEachTile + GridSizeOfEachTile - 1;
break;
case Direction.Down:
x = (pt.x - minX) * GridSizeOfEachTile + (GridSizeOfEachTile / 2);
y = (pt.y - minY) * GridSizeOfEachTile;
break;
case Direction.Left:
x = (pt.x - minX) * GridSizeOfEachTile;
y = (pt.y - minY) * GridSizeOfEachTile + (GridSizeOfEachTile / 2);
break;
case Direction.Right:
x = (pt.x - minX) * GridSizeOfEachTile + GridSizeOfEachTile - 1;
y = (pt.y - minY) * GridSizeOfEachTile + (GridSizeOfEachTile / 2);
break;
}
aspStartPoints.Add(new Vector2(x, y));
}
}
}
//Debug.Log("Creating floors for room " + r.Id);
IEnumerator <Vector2> pointEnumer = r.Space.GetEnumerator();
pointEnumer.MoveNext();
//Debug.Log("Room " + r.Id + "contains a point " + pointEnumer.Current);
//Debug.Log("room " + r.Id + " has " + r.Space.Count + " rooms");
//Debug.Log("TIles");
foreach (Vector2 v in aspTiles)
{
//Debug.Log(v);
}
//Debug.Log("start points");
foreach (Vector2 v in aspStartPoints)
{
//Debug.Log(v);
}
GeneratedPath p = PathGeneration.RunPathGeneration(aspTiles, aspStartPoints, NumModels, GridSizeOfEachTile, aspTiles.Count * (2 * (int)GridSizeOfEachTile - 1), Random.Range(0, 2));
List <Vector2> points = p.Spaces;
HashSet <Vector2> rampPoints = new HashSet <Vector2>(p.Ramps);
//Debug.Log("Now laying tiles...");
//Debug.Log("BaseX: " + baseX);
//Debug.Log("BaseZ: " + baseZ);
//Debug.Log("MinY: " + minY);
//Debug.Log("MinX: " + minX);
//Debug.Log("Size: " + size);
float scale = 1 / GridSizeOfEachTile;
Debug.Log(scale);
//Center to edge of a tile
float offset = TileWidth / 2;
float indexMultiple = 10 / GridSizeOfEachTile;
foreach (Vector2 v in points)
{
if (!rampPoints.Contains(v))
{
float basePositionX = minX * size + baseX * size;
float basePositionY = minY * size + baseZ * size;
// Now with 100% fewer magic numbers!
float offsetX = v.x * indexMultiple - offset * (1 - 1 / (float)GridSizeOfEachTile);
float offsetY = v.y * indexMultiple - offset * (1 - 1 / (float)GridSizeOfEachTile);
Vector3 pos = new Vector3(basePositionX + offsetX, 0, basePositionY + offsetY);
GameObject g = Instantiate(FloorTilePiece, pos, Quaternion.identity);
g.transform.localScale = new Vector3(g.transform.localScale.x * scale, 1, g.transform.localScale.z * scale);
}
}
if (p.Ramps.Count > 0)
{
for (int i = 0; i < p.Ramps.Count; i += 3)
{
Vector2 avg = AveragePoint(p.Ramps, i, i + 3);
float basePositionX = minX * size + baseX * size;
float basePositionY = minY * size + baseZ * size;
// magic numbers are BAD GABE WHY YOU DO THIS
// currently they're magic for GridSize=4
// They're magic because I don't actually know what their values are supposed to be.
float offsetX = avg.x * indexMultiple - offset * (1 - 1 / (float)GridSizeOfEachTile);
float offsetY = avg.y * indexMultiple - offset * (1 - 1 / (float)GridSizeOfEachTile);
Vector3 pos = new Vector3(basePositionX + offsetX, 0, basePositionY + offsetY);
GameObject g = Instantiate(Ramp, pos, DirectionOfPoints(p.Ramps, i));
g.transform.localScale = new Vector3(g.transform.localScale.x * scale, 1, g.transform.localScale.x * scale);
}
}
//foreach (Vector2 point in r.Space)
//{
// float x = point.x * size + baseX * size;
// float y = 0;
// float z = point.y * size + baseZ * size;
// floors.Add(Instantiate(floor, new Vector3(x, y, z), Quaternion.identity));
//}
}
